quiet warnings
[heimdal.git] / lib / sqlite / sqlite3.c
blobd04fa3801ebe22611675f742c42c5e54ceee3eed
1 /******************************************************************************
2 ** This file is an amalgamation of many separate C source files from SQLite
3 ** version 3.7.8. By combining all the individual C code files into this
4 ** single large file, the entire code can be compiled as a single translation
5 ** unit. This allows many compilers to do optimizations that would not be
6 ** possible if the files were compiled separately. Performance improvements
7 ** of 5% or more are commonly seen when SQLite is compiled as a single
8 ** translation unit.
9 **
10 ** This file is all you need to compile SQLite. To use SQLite in other
11 ** programs, you need this file and the "sqlite3.h" header file that defines
12 ** the programming interface to the SQLite library. (If you do not have
13 ** the "sqlite3.h" header file at hand, you will find a copy embedded within
14 ** the text of this file. Search for "Begin file sqlite3.h" to find the start
15 ** of the embedded sqlite3.h header file.) Additional code files may be needed
16 ** if you want a wrapper to interface SQLite with your choice of programming
17 ** language. The code for the "sqlite3" command-line shell is also in a
18 ** separate file. This file contains only code for the core SQLite library.
20 #define SQLITE_CORE 1
21 #define SQLITE_AMALGAMATION 1
22 #ifndef SQLITE_PRIVATE
23 # define SQLITE_PRIVATE static
24 #endif
25 #ifndef SQLITE_API
26 # define SQLITE_API
27 #endif
28 /************** Begin file sqliteInt.h ***************************************/
30 ** 2001 September 15
32 ** The author disclaims copyright to this source code. In place of
33 ** a legal notice, here is a blessing:
35 ** May you do good and not evil.
36 ** May you find forgiveness for yourself and forgive others.
37 ** May you share freely, never taking more than you give.
39 *************************************************************************
40 ** Internal interface definitions for SQLite.
43 #ifndef _SQLITEINT_H_
44 #define _SQLITEINT_H_
47 ** These #defines should enable >2GB file support on POSIX if the
48 ** underlying operating system supports it. If the OS lacks
49 ** large file support, or if the OS is windows, these should be no-ops.
51 ** Ticket #2739: The _LARGEFILE_SOURCE macro must appear before any
52 ** system #includes. Hence, this block of code must be the very first
53 ** code in all source files.
55 ** Large file support can be disabled using the -DSQLITE_DISABLE_LFS switch
56 ** on the compiler command line. This is necessary if you are compiling
57 ** on a recent machine (ex: Red Hat 7.2) but you want your code to work
58 ** on an older machine (ex: Red Hat 6.0). If you compile on Red Hat 7.2
59 ** without this option, LFS is enable. But LFS does not exist in the kernel
60 ** in Red Hat 6.0, so the code won't work. Hence, for maximum binary
61 ** portability you should omit LFS.
63 ** Similar is true for Mac OS X. LFS is only supported on Mac OS X 9 and later.
65 #ifndef SQLITE_DISABLE_LFS
66 # define _LARGE_FILE 1
67 # ifndef _FILE_OFFSET_BITS
68 # define _FILE_OFFSET_BITS 64
69 # endif
70 # define _LARGEFILE_SOURCE 1
71 #endif
74 ** Include the configuration header output by 'configure' if we're using the
75 ** autoconf-based build
77 #ifdef _HAVE_SQLITE_CONFIG_H
78 #include "config.h"
79 #endif
81 /************** Include sqliteLimit.h in the middle of sqliteInt.h ***********/
82 /************** Begin file sqliteLimit.h *************************************/
84 ** 2007 May 7
86 ** The author disclaims copyright to this source code. In place of
87 ** a legal notice, here is a blessing:
89 ** May you do good and not evil.
90 ** May you find forgiveness for yourself and forgive others.
91 ** May you share freely, never taking more than you give.
93 *************************************************************************
94 **
95 ** This file defines various limits of what SQLite can process.
99 ** The maximum length of a TEXT or BLOB in bytes. This also
100 ** limits the size of a row in a table or index.
102 ** The hard limit is the ability of a 32-bit signed integer
103 ** to count the size: 2^31-1 or 2147483647.
105 #ifndef SQLITE_MAX_LENGTH
106 # define SQLITE_MAX_LENGTH 1000000000
107 #endif
110 ** This is the maximum number of
112 ** * Columns in a table
113 ** * Columns in an index
114 ** * Columns in a view
115 ** * Terms in the SET clause of an UPDATE statement
116 ** * Terms in the result set of a SELECT statement
117 ** * Terms in the GROUP BY or ORDER BY clauses of a SELECT statement.
118 ** * Terms in the VALUES clause of an INSERT statement
120 ** The hard upper limit here is 32676. Most database people will
121 ** tell you that in a well-normalized database, you usually should
122 ** not have more than a dozen or so columns in any table. And if
123 ** that is the case, there is no point in having more than a few
124 ** dozen values in any of the other situations described above.
126 #ifndef SQLITE_MAX_COLUMN
127 # define SQLITE_MAX_COLUMN 2000
128 #endif
131 ** The maximum length of a single SQL statement in bytes.
133 ** It used to be the case that setting this value to zero would
134 ** turn the limit off. That is no longer true. It is not possible
135 ** to turn this limit off.
137 #ifndef SQLITE_MAX_SQL_LENGTH
138 # define SQLITE_MAX_SQL_LENGTH 1000000000
139 #endif
142 ** The maximum depth of an expression tree. This is limited to
143 ** some extent by SQLITE_MAX_SQL_LENGTH. But sometime you might
144 ** want to place more severe limits on the complexity of an
145 ** expression.
147 ** A value of 0 used to mean that the limit was not enforced.
148 ** But that is no longer true. The limit is now strictly enforced
149 ** at all times.
151 #ifndef SQLITE_MAX_EXPR_DEPTH
152 # define SQLITE_MAX_EXPR_DEPTH 1000
153 #endif
156 ** The maximum number of terms in a compound SELECT statement.
157 ** The code generator for compound SELECT statements does one
158 ** level of recursion for each term. A stack overflow can result
159 ** if the number of terms is too large. In practice, most SQL
160 ** never has more than 3 or 4 terms. Use a value of 0 to disable
161 ** any limit on the number of terms in a compount SELECT.
163 #ifndef SQLITE_MAX_COMPOUND_SELECT
164 # define SQLITE_MAX_COMPOUND_SELECT 500
165 #endif
168 ** The maximum number of opcodes in a VDBE program.
169 ** Not currently enforced.
171 #ifndef SQLITE_MAX_VDBE_OP
172 # define SQLITE_MAX_VDBE_OP 25000
173 #endif
176 ** The maximum number of arguments to an SQL function.
178 #ifndef SQLITE_MAX_FUNCTION_ARG
179 # define SQLITE_MAX_FUNCTION_ARG 127
180 #endif
183 ** The maximum number of in-memory pages to use for the main database
184 ** table and for temporary tables. The SQLITE_DEFAULT_CACHE_SIZE
186 #ifndef SQLITE_DEFAULT_CACHE_SIZE
187 # define SQLITE_DEFAULT_CACHE_SIZE 2000
188 #endif
189 #ifndef SQLITE_DEFAULT_TEMP_CACHE_SIZE
190 # define SQLITE_DEFAULT_TEMP_CACHE_SIZE 500
191 #endif
194 ** The default number of frames to accumulate in the log file before
195 ** checkpointing the database in WAL mode.
197 #ifndef SQLITE_DEFAULT_WAL_AUTOCHECKPOINT
198 # define SQLITE_DEFAULT_WAL_AUTOCHECKPOINT 1000
199 #endif
202 ** The maximum number of attached databases. This must be between 0
203 ** and 62. The upper bound on 62 is because a 64-bit integer bitmap
204 ** is used internally to track attached databases.
206 #ifndef SQLITE_MAX_ATTACHED
207 # define SQLITE_MAX_ATTACHED 10
208 #endif
212 ** The maximum value of a ?nnn wildcard that the parser will accept.
214 #ifndef SQLITE_MAX_VARIABLE_NUMBER
215 # define SQLITE_MAX_VARIABLE_NUMBER 999
216 #endif
218 /* Maximum page size. The upper bound on this value is 65536. This a limit
219 ** imposed by the use of 16-bit offsets within each page.
221 ** Earlier versions of SQLite allowed the user to change this value at
222 ** compile time. This is no longer permitted, on the grounds that it creates
223 ** a library that is technically incompatible with an SQLite library
224 ** compiled with a different limit. If a process operating on a database
225 ** with a page-size of 65536 bytes crashes, then an instance of SQLite
226 ** compiled with the default page-size limit will not be able to rollback
227 ** the aborted transaction. This could lead to database corruption.
229 #ifdef SQLITE_MAX_PAGE_SIZE
230 # undef SQLITE_MAX_PAGE_SIZE
231 #endif
232 #define SQLITE_MAX_PAGE_SIZE 65536
236 ** The default size of a database page.
238 #ifndef SQLITE_DEFAULT_PAGE_SIZE
239 # define SQLITE_DEFAULT_PAGE_SIZE 1024
240 #endif
241 #if SQLITE_DEFAULT_PAGE_SIZE>SQLITE_MAX_PAGE_SIZE
242 # undef SQLITE_DEFAULT_PAGE_SIZE
243 # define SQLITE_DEFAULT_PAGE_SIZE SQLITE_MAX_PAGE_SIZE
244 #endif
247 ** Ordinarily, if no value is explicitly provided, SQLite creates databases
248 ** with page size SQLITE_DEFAULT_PAGE_SIZE. However, based on certain
249 ** device characteristics (sector-size and atomic write() support),
250 ** SQLite may choose a larger value. This constant is the maximum value
251 ** SQLite will choose on its own.
253 #ifndef SQLITE_MAX_DEFAULT_PAGE_SIZE
254 # define SQLITE_MAX_DEFAULT_PAGE_SIZE 8192
255 #endif
256 #if SQLITE_MAX_DEFAULT_PAGE_SIZE>SQLITE_MAX_PAGE_SIZE
257 # undef SQLITE_MAX_DEFAULT_PAGE_SIZE
258 # define SQLITE_MAX_DEFAULT_PAGE_SIZE SQLITE_MAX_PAGE_SIZE
259 #endif
263 ** Maximum number of pages in one database file.
265 ** This is really just the default value for the max_page_count pragma.
266 ** This value can be lowered (or raised) at run-time using that the
267 ** max_page_count macro.
269 #ifndef SQLITE_MAX_PAGE_COUNT
270 # define SQLITE_MAX_PAGE_COUNT 1073741823
271 #endif
274 ** Maximum length (in bytes) of the pattern in a LIKE or GLOB
275 ** operator.
277 #ifndef SQLITE_MAX_LIKE_PATTERN_LENGTH
278 # define SQLITE_MAX_LIKE_PATTERN_LENGTH 50000
279 #endif
282 ** Maximum depth of recursion for triggers.
284 ** A value of 1 means that a trigger program will not be able to itself
285 ** fire any triggers. A value of 0 means that no trigger programs at all
286 ** may be executed.
288 #ifndef SQLITE_MAX_TRIGGER_DEPTH
289 # define SQLITE_MAX_TRIGGER_DEPTH 1000
290 #endif
292 /************** End of sqliteLimit.h *****************************************/
293 /************** Continuing where we left off in sqliteInt.h ******************/
295 /* Disable nuisance warnings on Borland compilers */
296 #if defined(__BORLANDC__)
297 #pragma warn -rch /* unreachable code */
298 #pragma warn -ccc /* Condition is always true or false */
299 #pragma warn -aus /* Assigned value is never used */
300 #pragma warn -csu /* Comparing signed and unsigned */
301 #pragma warn -spa /* Suspicious pointer arithmetic */
302 #endif
304 /* Needed for various definitions... */
305 #ifndef _GNU_SOURCE
306 # define _GNU_SOURCE
307 #endif
310 ** Include standard header files as necessary
312 #ifdef HAVE_STDINT_H
313 #include <stdint.h>
314 #endif
315 #ifdef HAVE_INTTYPES_H
316 #include <inttypes.h>
317 #endif
320 ** The number of samples of an index that SQLite takes in order to
321 ** construct a histogram of the table content when running ANALYZE
322 ** and with SQLITE_ENABLE_STAT2
324 #define SQLITE_INDEX_SAMPLES 10
327 ** The following macros are used to cast pointers to integers and
328 ** integers to pointers. The way you do this varies from one compiler
329 ** to the next, so we have developed the following set of #if statements
330 ** to generate appropriate macros for a wide range of compilers.
332 ** The correct "ANSI" way to do this is to use the intptr_t type.
333 ** Unfortunately, that typedef is not available on all compilers, or
334 ** if it is available, it requires an #include of specific headers
335 ** that vary from one machine to the next.
337 ** Ticket #3860: The llvm-gcc-4.2 compiler from Apple chokes on
338 ** the ((void*)&((char*)0)[X]) construct. But MSVC chokes on ((void*)(X)).
339 ** So we have to define the macros in different ways depending on the
340 ** compiler.
342 #if defined(__PTRDIFF_TYPE__) /* This case should work for GCC */
343 # define SQLITE_INT_TO_PTR(X) ((void*)(__PTRDIFF_TYPE__)(X))
344 # define SQLITE_PTR_TO_INT(X) ((int)(__PTRDIFF_TYPE__)(X))
345 #elif !defined(__GNUC__) /* Works for compilers other than LLVM */
346 # define SQLITE_INT_TO_PTR(X) ((void*)&((char*)0)[X])
347 # define SQLITE_PTR_TO_INT(X) ((int)(((char*)X)-(char*)0))
348 #elif defined(HAVE_STDINT_H) /* Use this case if we have ANSI headers */
349 # define SQLITE_INT_TO_PTR(X) ((void*)(intptr_t)(X))
350 # define SQLITE_PTR_TO_INT(X) ((int)(intptr_t)(X))
351 #else /* Generates a warning - but it always works */
352 # define SQLITE_INT_TO_PTR(X) ((void*)(X))
353 # define SQLITE_PTR_TO_INT(X) ((int)(X))
354 #endif
357 ** The SQLITE_THREADSAFE macro must be defined as 0, 1, or 2.
358 ** 0 means mutexes are permanently disable and the library is never
359 ** threadsafe. 1 means the library is serialized which is the highest
360 ** level of threadsafety. 2 means the libary is multithreaded - multiple
361 ** threads can use SQLite as long as no two threads try to use the same
362 ** database connection at the same time.
364 ** Older versions of SQLite used an optional THREADSAFE macro.
365 ** We support that for legacy.
367 #if !defined(SQLITE_THREADSAFE)
368 #if defined(THREADSAFE)
369 # define SQLITE_THREADSAFE THREADSAFE
370 #else
371 # define SQLITE_THREADSAFE 1 /* IMP: R-07272-22309 */
372 #endif
373 #endif
376 ** The SQLITE_DEFAULT_MEMSTATUS macro must be defined as either 0 or 1.
377 ** It determines whether or not the features related to
378 ** SQLITE_CONFIG_MEMSTATUS are available by default or not. This value can
379 ** be overridden at runtime using the sqlite3_config() API.
381 #if !defined(SQLITE_DEFAULT_MEMSTATUS)
382 # define SQLITE_DEFAULT_MEMSTATUS 1
383 #endif
386 ** Exactly one of the following macros must be defined in order to
387 ** specify which memory allocation subsystem to use.
389 ** SQLITE_SYSTEM_MALLOC // Use normal system malloc()
390 ** SQLITE_WIN32_MALLOC // Use Win32 native heap API
391 ** SQLITE_MEMDEBUG // Debugging version of system malloc()
393 ** On Windows, if the SQLITE_WIN32_MALLOC_VALIDATE macro is defined and the
394 ** assert() macro is enabled, each call into the Win32 native heap subsystem
395 ** will cause HeapValidate to be called. If heap validation should fail, an
396 ** assertion will be triggered.
398 ** (Historical note: There used to be several other options, but we've
399 ** pared it down to just these two.)
401 ** If none of the above are defined, then set SQLITE_SYSTEM_MALLOC as
402 ** the default.
404 #if defined(SQLITE_SYSTEM_MALLOC)+defined(SQLITE_WIN32_MALLOC)+defined(SQLITE_MEMDEBUG)>1
405 # error "At most one of the following compile-time configuration options\
406 is allows: SQLITE_SYSTEM_MALLOC, SQLITE_WIN32_MALLOC, SQLITE_MEMDEBUG"
407 #endif
408 #if defined(SQLITE_SYSTEM_MALLOC)+defined(SQLITE_WIN32_MALLOC)+defined(SQLITE_MEMDEBUG)==0
409 # define SQLITE_SYSTEM_MALLOC 1
410 #endif
413 ** If SQLITE_MALLOC_SOFT_LIMIT is not zero, then try to keep the
414 ** sizes of memory allocations below this value where possible.
416 #if !defined(SQLITE_MALLOC_SOFT_LIMIT)
417 # define SQLITE_MALLOC_SOFT_LIMIT 1024
418 #endif
421 ** We need to define _XOPEN_SOURCE as follows in order to enable
422 ** recursive mutexes on most Unix systems. But Mac OS X is different.
423 ** The _XOPEN_SOURCE define causes problems for Mac OS X we are told,
424 ** so it is omitted there. See ticket #2673.
426 ** Later we learn that _XOPEN_SOURCE is poorly or incorrectly
427 ** implemented on some systems. So we avoid defining it at all
428 ** if it is already defined or if it is unneeded because we are
429 ** not doing a threadsafe build. Ticket #2681.
431 ** See also ticket #2741.
433 #if !defined(_XOPEN_SOURCE) && !defined(__DARWIN__) && !defined(__APPLE__) && SQLITE_THREADSAFE
434 #ifdef __sun
435 # define _XOPEN_SOURCE 600
436 #else
437 # define _XOPEN_SOURCE 500 /* Needed to enable pthread recursive mutexes */
438 #endif
439 #endif
442 ** The TCL headers are only needed when compiling the TCL bindings.
444 #if defined(SQLITE_TCL) || defined(TCLSH)
445 # include <tcl.h>
446 #endif
449 ** Many people are failing to set -DNDEBUG=1 when compiling SQLite.
450 ** Setting NDEBUG makes the code smaller and run faster. So the following
451 ** lines are added to automatically set NDEBUG unless the -DSQLITE_DEBUG=1
452 ** option is set. Thus NDEBUG becomes an opt-in rather than an opt-out
453 ** feature.
455 #if !defined(NDEBUG) && !defined(SQLITE_DEBUG)
456 # define NDEBUG 1
457 #endif
460 ** The testcase() macro is used to aid in coverage testing. When
461 ** doing coverage testing, the condition inside the argument to
462 ** testcase() must be evaluated both true and false in order to
463 ** get full branch coverage. The testcase() macro is inserted
464 ** to help ensure adequate test coverage in places where simple
465 ** condition/decision coverage is inadequate. For example, testcase()
466 ** can be used to make sure boundary values are tested. For
467 ** bitmask tests, testcase() can be used to make sure each bit
468 ** is significant and used at least once. On switch statements
469 ** where multiple cases go to the same block of code, testcase()
470 ** can insure that all cases are evaluated.
473 #ifdef SQLITE_COVERAGE_TEST
474 SQLITE_PRIVATE void sqlite3Coverage(int);
475 # define testcase(X) if( X ){ sqlite3Coverage(__LINE__); }
476 #else
477 # define testcase(X)
478 #endif
481 ** The TESTONLY macro is used to enclose variable declarations or
482 ** other bits of code that are needed to support the arguments
483 ** within testcase() and assert() macros.
485 #if !defined(NDEBUG) || defined(SQLITE_COVERAGE_TEST)
486 # define TESTONLY(X) X
487 #else
488 # define TESTONLY(X)
489 #endif
492 ** Sometimes we need a small amount of code such as a variable initialization
493 ** to setup for a later assert() statement. We do not want this code to
494 ** appear when assert() is disabled. The following macro is therefore
495 ** used to contain that setup code. The "VVA" acronym stands for
496 ** "Verification, Validation, and Accreditation". In other words, the
497 ** code within VVA_ONLY() will only run during verification processes.
499 #ifndef NDEBUG
500 # define VVA_ONLY(X) X
501 #else
502 # define VVA_ONLY(X)
503 #endif
506 ** The ALWAYS and NEVER macros surround boolean expressions which
507 ** are intended to always be true or false, respectively. Such
508 ** expressions could be omitted from the code completely. But they
509 ** are included in a few cases in order to enhance the resilience
510 ** of SQLite to unexpected behavior - to make the code "self-healing"
511 ** or "ductile" rather than being "brittle" and crashing at the first
512 ** hint of unplanned behavior.
514 ** In other words, ALWAYS and NEVER are added for defensive code.
516 ** When doing coverage testing ALWAYS and NEVER are hard-coded to
517 ** be true and false so that the unreachable code then specify will
518 ** not be counted as untested code.
520 #if defined(SQLITE_COVERAGE_TEST)
521 # define ALWAYS(X) (1)
522 # define NEVER(X) (0)
523 #elif !defined(NDEBUG)
524 # define ALWAYS(X) ((X)?1:(assert(0),0))
525 # define NEVER(X) ((X)?(assert(0),1):0)
526 #else
527 # define ALWAYS(X) (X)
528 # define NEVER(X) (X)
529 #endif
532 ** Return true (non-zero) if the input is a integer that is too large
533 ** to fit in 32-bits. This macro is used inside of various testcase()
534 ** macros to verify that we have tested SQLite for large-file support.
536 #define IS_BIG_INT(X) (((X)&~(i64)0xffffffff)!=0)
539 ** The macro unlikely() is a hint that surrounds a boolean
540 ** expression that is usually false. Macro likely() surrounds
541 ** a boolean expression that is usually true. GCC is able to
542 ** use these hints to generate better code, sometimes.
544 #if defined(__GNUC__) && 0
545 # define likely(X) __builtin_expect((X),1)
546 # define unlikely(X) __builtin_expect((X),0)
547 #else
548 # define likely(X) !!(X)
549 # define unlikely(X) !!(X)
550 #endif
552 /************** Include sqlite3.h in the middle of sqliteInt.h ***************/
553 /************** Begin file sqlite3.h *****************************************/
555 ** 2001 September 15
557 ** The author disclaims copyright to this source code. In place of
558 ** a legal notice, here is a blessing:
560 ** May you do good and not evil.
561 ** May you find forgiveness for yourself and forgive others.
562 ** May you share freely, never taking more than you give.
564 *************************************************************************
565 ** This header file defines the interface that the SQLite library
566 ** presents to client programs. If a C-function, structure, datatype,
567 ** or constant definition does not appear in this file, then it is
568 ** not a published API of SQLite, is subject to change without
569 ** notice, and should not be referenced by programs that use SQLite.
571 ** Some of the definitions that are in this file are marked as
572 ** "experimental". Experimental interfaces are normally new
573 ** features recently added to SQLite. We do not anticipate changes
574 ** to experimental interfaces but reserve the right to make minor changes
575 ** if experience from use "in the wild" suggest such changes are prudent.
577 ** The official C-language API documentation for SQLite is derived
578 ** from comments in this file. This file is the authoritative source
579 ** on how SQLite interfaces are suppose to operate.
581 ** The name of this file under configuration management is "sqlite.h.in".
582 ** The makefile makes some minor changes to this file (such as inserting
583 ** the version number) and changes its name to "sqlite3.h" as
584 ** part of the build process.
586 #ifndef _SQLITE3_H_
587 #define _SQLITE3_H_
588 #include <stdarg.h> /* Needed for the definition of va_list */
591 ** Make sure we can call this stuff from C++.
593 #if 0
594 extern "C" {
595 #endif
599 ** Add the ability to override 'extern'
601 #ifndef SQLITE_EXTERN
602 # define SQLITE_EXTERN extern
603 #endif
605 #ifndef SQLITE_API
606 # define SQLITE_API
607 #endif
611 ** These no-op macros are used in front of interfaces to mark those
612 ** interfaces as either deprecated or experimental. New applications
613 ** should not use deprecated interfaces - they are support for backwards
614 ** compatibility only. Application writers should be aware that
615 ** experimental interfaces are subject to change in point releases.
617 ** These macros used to resolve to various kinds of compiler magic that
618 ** would generate warning messages when they were used. But that
619 ** compiler magic ended up generating such a flurry of bug reports
620 ** that we have taken it all out and gone back to using simple
621 ** noop macros.
623 #define SQLITE_DEPRECATED
624 #define SQLITE_EXPERIMENTAL
627 ** Ensure these symbols were not defined by some previous header file.
629 #ifdef SQLITE_VERSION
630 # undef SQLITE_VERSION
631 #endif
632 #ifdef SQLITE_VERSION_NUMBER
633 # undef SQLITE_VERSION_NUMBER
634 #endif
637 ** CAPI3REF: Compile-Time Library Version Numbers
639 ** ^(The [SQLITE_VERSION] C preprocessor macro in the sqlite3.h header
640 ** evaluates to a string literal that is the SQLite version in the
641 ** format "X.Y.Z" where X is the major version number (always 3 for
642 ** SQLite3) and Y is the minor version number and Z is the release number.)^
643 ** ^(The [SQLITE_VERSION_NUMBER] C preprocessor macro resolves to an integer
644 ** with the value (X*1000000 + Y*1000 + Z) where X, Y, and Z are the same
645 ** numbers used in [SQLITE_VERSION].)^
646 ** The SQLITE_VERSION_NUMBER for any given release of SQLite will also
647 ** be larger than the release from which it is derived. Either Y will
648 ** be held constant and Z will be incremented or else Y will be incremented
649 ** and Z will be reset to zero.
651 ** Since version 3.6.18, SQLite source code has been stored in the
652 ** <a href="http://www.fossil-scm.org/">Fossil configuration management
653 ** system</a>. ^The SQLITE_SOURCE_ID macro evaluates to
654 ** a string which identifies a particular check-in of SQLite
655 ** within its configuration management system. ^The SQLITE_SOURCE_ID
656 ** string contains the date and time of the check-in (UTC) and an SHA1
657 ** hash of the entire source tree.
659 ** See also: [sqlite3_libversion()],
660 ** [sqlite3_libversion_number()], [sqlite3_sourceid()],
661 ** [sqlite_version()] and [sqlite_source_id()].
663 #define SQLITE_VERSION "3.7.8"
664 #define SQLITE_VERSION_NUMBER 3007008
665 #define SQLITE_SOURCE_ID "2011-09-19 14:49:19 3e0da808d2f5b4d12046e05980ca04578f581177"
668 ** CAPI3REF: Run-Time Library Version Numbers
669 ** KEYWORDS: sqlite3_version, sqlite3_sourceid
671 ** These interfaces provide the same information as the [SQLITE_VERSION],
672 ** [SQLITE_VERSION_NUMBER], and [SQLITE_SOURCE_ID] C preprocessor macros
673 ** but are associated with the library instead of the header file. ^(Cautious
674 ** programmers might include assert() statements in their application to
675 ** verify that values returned by these interfaces match the macros in
676 ** the header, and thus insure that the application is
677 ** compiled with matching library and header files.
679 ** <blockquote><pre>
680 ** assert( sqlite3_libversion_number()==SQLITE_VERSION_NUMBER );
681 ** assert( strcmp(sqlite3_sourceid(),SQLITE_SOURCE_ID)==0 );
682 ** assert( strcmp(sqlite3_libversion(),SQLITE_VERSION)==0 );
683 ** </pre></blockquote>)^
685 ** ^The sqlite3_version[] string constant contains the text of [SQLITE_VERSION]
686 ** macro. ^The sqlite3_libversion() function returns a pointer to the
687 ** to the sqlite3_version[] string constant. The sqlite3_libversion()
688 ** function is provided for use in DLLs since DLL users usually do not have
689 ** direct access to string constants within the DLL. ^The
690 ** sqlite3_libversion_number() function returns an integer equal to
691 ** [SQLITE_VERSION_NUMBER]. ^The sqlite3_sourceid() function returns
692 ** a pointer to a string constant whose value is the same as the
693 ** [SQLITE_SOURCE_ID] C preprocessor macro.
695 ** See also: [sqlite_version()] and [sqlite_source_id()].
697 SQLITE_API const char sqlite3_version[] = SQLITE_VERSION;
698 SQLITE_API const char *sqlite3_libversion(void);
699 SQLITE_API const char *sqlite3_sourceid(void);
700 SQLITE_API int sqlite3_libversion_number(void);
703 ** CAPI3REF: Run-Time Library Compilation Options Diagnostics
705 ** ^The sqlite3_compileoption_used() function returns 0 or 1
706 ** indicating whether the specified option was defined at
707 ** compile time. ^The SQLITE_ prefix may be omitted from the
708 ** option name passed to sqlite3_compileoption_used().
710 ** ^The sqlite3_compileoption_get() function allows iterating
711 ** over the list of options that were defined at compile time by
712 ** returning the N-th compile time option string. ^If N is out of range,
713 ** sqlite3_compileoption_get() returns a NULL pointer. ^The SQLITE_
714 ** prefix is omitted from any strings returned by
715 ** sqlite3_compileoption_get().
717 ** ^Support for the diagnostic functions sqlite3_compileoption_used()
718 ** and sqlite3_compileoption_get() may be omitted by specifying the
719 ** [SQLITE_OMIT_COMPILEOPTION_DIAGS] option at compile time.
721 ** See also: SQL functions [sqlite_compileoption_used()] and
722 ** [sqlite_compileoption_get()] and the [compile_options pragma].
724 #ifndef SQLITE_OMIT_COMPILEOPTION_DIAGS
725 SQLITE_API int sqlite3_compileoption_used(const char *zOptName);
726 SQLITE_API const char *sqlite3_compileoption_get(int N);
727 #endif
730 ** CAPI3REF: Test To See If The Library Is Threadsafe
732 ** ^The sqlite3_threadsafe() function returns zero if and only if
733 ** SQLite was compiled mutexing code omitted due to the
734 ** [SQLITE_THREADSAFE] compile-time option being set to 0.
736 ** SQLite can be compiled with or without mutexes. When
737 ** the [SQLITE_THREADSAFE] C preprocessor macro is 1 or 2, mutexes
738 ** are enabled and SQLite is threadsafe. When the
739 ** [SQLITE_THREADSAFE] macro is 0,
740 ** the mutexes are omitted. Without the mutexes, it is not safe
741 ** to use SQLite concurrently from more than one thread.
743 ** Enabling mutexes incurs a measurable performance penalty.
744 ** So if speed is of utmost importance, it makes sense to disable
745 ** the mutexes. But for maximum safety, mutexes should be enabled.
746 ** ^The default behavior is for mutexes to be enabled.
748 ** This interface can be used by an application to make sure that the
749 ** version of SQLite that it is linking against was compiled with
750 ** the desired setting of the [SQLITE_THREADSAFE] macro.
752 ** This interface only reports on the compile-time mutex setting
753 ** of the [SQLITE_THREADSAFE] flag. If SQLite is compiled with
754 ** SQLITE_THREADSAFE=1 or =2 then mutexes are enabled by default but
755 ** can be fully or partially disabled using a call to [sqlite3_config()]
756 ** with the verbs [SQLITE_CONFIG_SINGLETHREAD], [SQLITE_CONFIG_MULTITHREAD],
757 ** or [SQLITE_CONFIG_MUTEX]. ^(The return value of the
758 ** sqlite3_threadsafe() function shows only the compile-time setting of
759 ** thread safety, not any run-time changes to that setting made by
760 ** sqlite3_config(). In other words, the return value from sqlite3_threadsafe()
761 ** is unchanged by calls to sqlite3_config().)^
763 ** See the [threading mode] documentation for additional information.
765 SQLITE_API int sqlite3_threadsafe(void);
768 ** CAPI3REF: Database Connection Handle
769 ** KEYWORDS: {database connection} {database connections}
771 ** Each open SQLite database is represented by a pointer to an instance of
772 ** the opaque structure named "sqlite3". It is useful to think of an sqlite3
773 ** pointer as an object. The [sqlite3_open()], [sqlite3_open16()], and
774 ** [sqlite3_open_v2()] interfaces are its constructors, and [sqlite3_close()]
775 ** is its destructor. There are many other interfaces (such as
776 ** [sqlite3_prepare_v2()], [sqlite3_create_function()], and
777 ** [sqlite3_busy_timeout()] to name but three) that are methods on an
778 ** sqlite3 object.
780 typedef struct sqlite3 sqlite3;
783 ** CAPI3REF: 64-Bit Integer Types
784 ** KEYWORDS: sqlite_int64 sqlite_uint64
786 ** Because there is no cross-platform way to specify 64-bit integer types
787 ** SQLite includes typedefs for 64-bit signed and unsigned integers.
789 ** The sqlite3_int64 and sqlite3_uint64 are the preferred type definitions.
790 ** The sqlite_int64 and sqlite_uint64 types are supported for backwards
791 ** compatibility only.
793 ** ^The sqlite3_int64 and sqlite_int64 types can store integer values
794 ** between -9223372036854775808 and +9223372036854775807 inclusive. ^The
795 ** sqlite3_uint64 and sqlite_uint64 types can store integer values
796 ** between 0 and +18446744073709551615 inclusive.
798 #ifdef SQLITE_INT64_TYPE
799 typedef SQLITE_INT64_TYPE sqlite_int64;
800 typedef unsigned SQLITE_INT64_TYPE sqlite_uint64;
801 #elif defined(_MSC_VER) || defined(__BORLANDC__)
802 typedef __int64 sqlite_int64;
803 typedef unsigned __int64 sqlite_uint64;
804 #else
805 typedef long long int sqlite_int64;
806 typedef unsigned long long int sqlite_uint64;
807 #endif
808 typedef sqlite_int64 sqlite3_int64;
809 typedef sqlite_uint64 sqlite3_uint64;
812 ** If compiling for a processor that lacks floating point support,
813 ** substitute integer for floating-point.
815 #ifdef SQLITE_OMIT_FLOATING_POINT
816 # define double sqlite3_int64
817 #endif
820 ** CAPI3REF: Closing A Database Connection
822 ** ^The sqlite3_close() routine is the destructor for the [sqlite3] object.
823 ** ^Calls to sqlite3_close() return SQLITE_OK if the [sqlite3] object is
824 ** successfully destroyed and all associated resources are deallocated.
826 ** Applications must [sqlite3_finalize | finalize] all [prepared statements]
827 ** and [sqlite3_blob_close | close] all [BLOB handles] associated with
828 ** the [sqlite3] object prior to attempting to close the object. ^If
829 ** sqlite3_close() is called on a [database connection] that still has
830 ** outstanding [prepared statements] or [BLOB handles], then it returns
831 ** SQLITE_BUSY.
833 ** ^If [sqlite3_close()] is invoked while a transaction is open,
834 ** the transaction is automatically rolled back.
836 ** The C parameter to [sqlite3_close(C)] must be either a NULL
837 ** pointer or an [sqlite3] object pointer obtained
838 ** from [sqlite3_open()], [sqlite3_open16()], or
839 ** [sqlite3_open_v2()], and not previously closed.
840 ** ^Calling sqlite3_close() with a NULL pointer argument is a
841 ** harmless no-op.
843 SQLITE_API int sqlite3_close(sqlite3 *);
846 ** The type for a callback function.
847 ** This is legacy and deprecated. It is included for historical
848 ** compatibility and is not documented.
850 typedef int (*sqlite3_callback)(void*,int,char**, char**);
853 ** CAPI3REF: One-Step Query Execution Interface
855 ** The sqlite3_exec() interface is a convenience wrapper around
856 ** [sqlite3_prepare_v2()], [sqlite3_step()], and [sqlite3_finalize()],
857 ** that allows an application to run multiple statements of SQL
858 ** without having to use a lot of C code.
860 ** ^The sqlite3_exec() interface runs zero or more UTF-8 encoded,
861 ** semicolon-separate SQL statements passed into its 2nd argument,
862 ** in the context of the [database connection] passed in as its 1st
863 ** argument. ^If the callback function of the 3rd argument to
864 ** sqlite3_exec() is not NULL, then it is invoked for each result row
865 ** coming out of the evaluated SQL statements. ^The 4th argument to
866 ** sqlite3_exec() is relayed through to the 1st argument of each
867 ** callback invocation. ^If the callback pointer to sqlite3_exec()
868 ** is NULL, then no callback is ever invoked and result rows are
869 ** ignored.
871 ** ^If an error occurs while evaluating the SQL statements passed into
872 ** sqlite3_exec(), then execution of the current statement stops and
873 ** subsequent statements are skipped. ^If the 5th parameter to sqlite3_exec()
874 ** is not NULL then any error message is written into memory obtained
875 ** from [sqlite3_malloc()] and passed back through the 5th parameter.
876 ** To avoid memory leaks, the application should invoke [sqlite3_free()]
877 ** on error message strings returned through the 5th parameter of
878 ** of sqlite3_exec() after the error message string is no longer needed.
879 ** ^If the 5th parameter to sqlite3_exec() is not NULL and no errors
880 ** occur, then sqlite3_exec() sets the pointer in its 5th parameter to
881 ** NULL before returning.
883 ** ^If an sqlite3_exec() callback returns non-zero, the sqlite3_exec()
884 ** routine returns SQLITE_ABORT without invoking the callback again and
885 ** without running any subsequent SQL statements.
887 ** ^The 2nd argument to the sqlite3_exec() callback function is the
888 ** number of columns in the result. ^The 3rd argument to the sqlite3_exec()
889 ** callback is an array of pointers to strings obtained as if from
890 ** [sqlite3_column_text()], one for each column. ^If an element of a
891 ** result row is NULL then the corresponding string pointer for the
892 ** sqlite3_exec() callback is a NULL pointer. ^The 4th argument to the
893 ** sqlite3_exec() callback is an array of pointers to strings where each
894 ** entry represents the name of corresponding result column as obtained
895 ** from [sqlite3_column_name()].
897 ** ^If the 2nd parameter to sqlite3_exec() is a NULL pointer, a pointer
898 ** to an empty string, or a pointer that contains only whitespace and/or
899 ** SQL comments, then no SQL statements are evaluated and the database
900 ** is not changed.
902 ** Restrictions:
904 ** <ul>
905 ** <li> The application must insure that the 1st parameter to sqlite3_exec()
906 ** is a valid and open [database connection].
907 ** <li> The application must not close [database connection] specified by
908 ** the 1st parameter to sqlite3_exec() while sqlite3_exec() is running.
909 ** <li> The application must not modify the SQL statement text passed into
910 ** the 2nd parameter of sqlite3_exec() while sqlite3_exec() is running.
911 ** </ul>
913 SQLITE_API int sqlite3_exec(
914 sqlite3*, /* An open database */
915 const char *sql, /* SQL to be evaluated */
916 int (*callback)(void*,int,char**,char**), /* Callback function */
917 void *, /* 1st argument to callback */
918 char **errmsg /* Error msg written here */
922 ** CAPI3REF: Result Codes
923 ** KEYWORDS: SQLITE_OK {error code} {error codes}
924 ** KEYWORDS: {result code} {result codes}
926 ** Many SQLite functions return an integer result code from the set shown
927 ** here in order to indicates success or failure.
929 ** New error codes may be added in future versions of SQLite.
931 ** See also: [SQLITE_IOERR_READ | extended result codes],
932 ** [sqlite3_vtab_on_conflict()] [SQLITE_ROLLBACK | result codes].
934 #define SQLITE_OK 0 /* Successful result */
935 /* beginning-of-error-codes */
936 #define SQLITE_ERROR 1 /* SQL error or missing database */
937 #define SQLITE_INTERNAL 2 /* Internal logic error in SQLite */
938 #define SQLITE_PERM 3 /* Access permission denied */
939 #define SQLITE_ABORT 4 /* Callback routine requested an abort */
940 #define SQLITE_BUSY 5 /* The database file is locked */
941 #define SQLITE_LOCKED 6 /* A table in the database is locked */
942 #define SQLITE_NOMEM 7 /* A malloc() failed */
943 #define SQLITE_READONLY 8 /* Attempt to write a readonly database */
944 #define SQLITE_INTERRUPT 9 /* Operation terminated by sqlite3_interrupt()*/
945 #define SQLITE_IOERR 10 /* Some kind of disk I/O error occurred */
946 #define SQLITE_CORRUPT 11 /* The database disk image is malformed */
947 #define SQLITE_NOTFOUND 12 /* Unknown opcode in sqlite3_file_control() */
948 #define SQLITE_FULL 13 /* Insertion failed because database is full */
949 #define SQLITE_CANTOPEN 14 /* Unable to open the database file */
950 #define SQLITE_PROTOCOL 15 /* Database lock protocol error */
951 #define SQLITE_EMPTY 16 /* Database is empty */
952 #define SQLITE_SCHEMA 17 /* The database schema changed */
953 #define SQLITE_TOOBIG 18 /* String or BLOB exceeds size limit */
954 #define SQLITE_CONSTRAINT 19 /* Abort due to constraint violation */
955 #define SQLITE_MISMATCH 20 /* Data type mismatch */
956 #define SQLITE_MISUSE 21 /* Library used incorrectly */
957 #define SQLITE_NOLFS 22 /* Uses OS features not supported on host */
958 #define SQLITE_AUTH 23 /* Authorization denied */
959 #define SQLITE_FORMAT 24 /* Auxiliary database format error */
960 #define SQLITE_RANGE 25 /* 2nd parameter to sqlite3_bind out of range */
961 #define SQLITE_NOTADB 26 /* File opened that is not a database file */
962 #define SQLITE_ROW 100 /* sqlite3_step() has another row ready */
963 #define SQLITE_DONE 101 /* sqlite3_step() has finished executing */
964 /* end-of-error-codes */
967 ** CAPI3REF: Extended Result Codes
968 ** KEYWORDS: {extended error code} {extended error codes}
969 ** KEYWORDS: {extended result code} {extended result codes}
971 ** In its default configuration, SQLite API routines return one of 26 integer
972 ** [SQLITE_OK | result codes]. However, experience has shown that many of
973 ** these result codes are too coarse-grained. They do not provide as
974 ** much information about problems as programmers might like. In an effort to
975 ** address this, newer versions of SQLite (version 3.3.8 and later) include
976 ** support for additional result codes that provide more detailed information
977 ** about errors. The extended result codes are enabled or disabled
978 ** on a per database connection basis using the
979 ** [sqlite3_extended_result_codes()] API.
981 ** Some of the available extended result codes are listed here.
982 ** One may expect the number of extended result codes will be expand
983 ** over time. Software that uses extended result codes should expect
984 ** to see new result codes in future releases of SQLite.
986 ** The SQLITE_OK result code will never be extended. It will always
987 ** be exactly zero.
989 #define SQLITE_IOERR_READ (SQLITE_IOERR | (1<<8))
990 #define SQLITE_IOERR_SHORT_READ (SQLITE_IOERR | (2<<8))
991 #define SQLITE_IOERR_WRITE (SQLITE_IOERR | (3<<8))
992 #define SQLITE_IOERR_FSYNC (SQLITE_IOERR | (4<<8))
993 #define SQLITE_IOERR_DIR_FSYNC (SQLITE_IOERR | (5<<8))
994 #define SQLITE_IOERR_TRUNCATE (SQLITE_IOERR | (6<<8))
995 #define SQLITE_IOERR_FSTAT (SQLITE_IOERR | (7<<8))
996 #define SQLITE_IOERR_UNLOCK (SQLITE_IOERR | (8<<8))
997 #define SQLITE_IOERR_RDLOCK (SQLITE_IOERR | (9<<8))
998 #define SQLITE_IOERR_DELETE (SQLITE_IOERR | (10<<8))
999 #define SQLITE_IOERR_BLOCKED (SQLITE_IOERR | (11<<8))
1000 #define SQLITE_IOERR_NOMEM (SQLITE_IOERR | (12<<8))
1001 #define SQLITE_IOERR_ACCESS (SQLITE_IOERR | (13<<8))
1002 #define SQLITE_IOERR_CHECKRESERVEDLOCK (SQLITE_IOERR | (14<<8))
1003 #define SQLITE_IOERR_LOCK (SQLITE_IOERR | (15<<8))
1004 #define SQLITE_IOERR_CLOSE (SQLITE_IOERR | (16<<8))
1005 #define SQLITE_IOERR_DIR_CLOSE (SQLITE_IOERR | (17<<8))
1006 #define SQLITE_IOERR_SHMOPEN (SQLITE_IOERR | (18<<8))
1007 #define SQLITE_IOERR_SHMSIZE (SQLITE_IOERR | (19<<8))
1008 #define SQLITE_IOERR_SHMLOCK (SQLITE_IOERR | (20<<8))
1009 #define SQLITE_IOERR_SHMMAP (SQLITE_IOERR | (21<<8))
1010 #define SQLITE_IOERR_SEEK (SQLITE_IOERR | (22<<8))
1011 #define SQLITE_LOCKED_SHAREDCACHE (SQLITE_LOCKED | (1<<8))
1012 #define SQLITE_BUSY_RECOVERY (SQLITE_BUSY | (1<<8))
1013 #define SQLITE_CANTOPEN_NOTEMPDIR (SQLITE_CANTOPEN | (1<<8))
1014 #define SQLITE_CORRUPT_VTAB (SQLITE_CORRUPT | (1<<8))
1015 #define SQLITE_READONLY_RECOVERY (SQLITE_READONLY | (1<<8))
1016 #define SQLITE_READONLY_CANTLOCK (SQLITE_READONLY | (2<<8))
1019 ** CAPI3REF: Flags For File Open Operations
1021 ** These bit values are intended for use in the
1022 ** 3rd parameter to the [sqlite3_open_v2()] interface and
1023 ** in the 4th parameter to the [sqlite3_vfs.xOpen] method.
1025 #define SQLITE_OPEN_READONLY 0x00000001 /* Ok for sqlite3_open_v2() */
1026 #define SQLITE_OPEN_READWRITE 0x00000002 /* Ok for sqlite3_open_v2() */
1027 #define SQLITE_OPEN_CREATE 0x00000004 /* Ok for sqlite3_open_v2() */
1028 #define SQLITE_OPEN_DELETEONCLOSE 0x00000008 /* VFS only */
1029 #define SQLITE_OPEN_EXCLUSIVE 0x00000010 /* VFS only */
1030 #define SQLITE_OPEN_AUTOPROXY 0x00000020 /* VFS only */
1031 #define SQLITE_OPEN_URI 0x00000040 /* Ok for sqlite3_open_v2() */
1032 #define SQLITE_OPEN_MAIN_DB 0x00000100 /* VFS only */
1033 #define SQLITE_OPEN_TEMP_DB 0x00000200 /* VFS only */
1034 #define SQLITE_OPEN_TRANSIENT_DB 0x00000400 /* VFS only */
1035 #define SQLITE_OPEN_MAIN_JOURNAL 0x00000800 /* VFS only */
1036 #define SQLITE_OPEN_TEMP_JOURNAL 0x00001000 /* VFS only */
1037 #define SQLITE_OPEN_SUBJOURNAL 0x00002000 /* VFS only */
1038 #define SQLITE_OPEN_MASTER_JOURNAL 0x00004000 /* VFS only */
1039 #define SQLITE_OPEN_NOMUTEX 0x00008000 /* Ok for sqlite3_open_v2() */
1040 #define SQLITE_OPEN_FULLMUTEX 0x00010000 /* Ok for sqlite3_open_v2() */
1041 #define SQLITE_OPEN_SHAREDCACHE 0x00020000 /* Ok for sqlite3_open_v2() */
1042 #define SQLITE_OPEN_PRIVATECACHE 0x00040000 /* Ok for sqlite3_open_v2() */
1043 #define SQLITE_OPEN_WAL 0x00080000 /* VFS only */
1045 /* Reserved: 0x00F00000 */
1048 ** CAPI3REF: Device Characteristics
1050 ** The xDeviceCharacteristics method of the [sqlite3_io_methods]
1051 ** object returns an integer which is a vector of the these
1052 ** bit values expressing I/O characteristics of the mass storage
1053 ** device that holds the file that the [sqlite3_io_methods]
1054 ** refers to.
1056 ** The SQLITE_IOCAP_ATOMIC property means that all writes of
1057 ** any size are atomic. The SQLITE_IOCAP_ATOMICnnn values
1058 ** mean that writes of blocks that are nnn bytes in size and
1059 ** are aligned to an address which is an integer multiple of
1060 ** nnn are atomic. The SQLITE_IOCAP_SAFE_APPEND value means
1061 ** that when data is appended to a file, the data is appended
1062 ** first then the size of the file is extended, never the other
1063 ** way around. The SQLITE_IOCAP_SEQUENTIAL property means that
1064 ** information is written to disk in the same order as calls
1065 ** to xWrite().
1067 #define SQLITE_IOCAP_ATOMIC 0x00000001
1068 #define SQLITE_IOCAP_ATOMIC512 0x00000002
1069 #define SQLITE_IOCAP_ATOMIC1K 0x00000004
1070 #define SQLITE_IOCAP_ATOMIC2K 0x00000008
1071 #define SQLITE_IOCAP_ATOMIC4K 0x00000010
1072 #define SQLITE_IOCAP_ATOMIC8K 0x00000020
1073 #define SQLITE_IOCAP_ATOMIC16K 0x00000040
1074 #define SQLITE_IOCAP_ATOMIC32K 0x00000080
1075 #define SQLITE_IOCAP_ATOMIC64K 0x00000100
1076 #define SQLITE_IOCAP_SAFE_APPEND 0x00000200
1077 #define SQLITE_IOCAP_SEQUENTIAL 0x00000400
1078 #define SQLITE_IOCAP_UNDELETABLE_WHEN_OPEN 0x00000800
1081 ** CAPI3REF: File Locking Levels
1083 ** SQLite uses one of these integer values as the second
1084 ** argument to calls it makes to the xLock() and xUnlock() methods
1085 ** of an [sqlite3_io_methods] object.
1087 #define SQLITE_LOCK_NONE 0
1088 #define SQLITE_LOCK_SHARED 1
1089 #define SQLITE_LOCK_RESERVED 2
1090 #define SQLITE_LOCK_PENDING 3
1091 #define SQLITE_LOCK_EXCLUSIVE 4
1094 ** CAPI3REF: Synchronization Type Flags
1096 ** When SQLite invokes the xSync() method of an
1097 ** [sqlite3_io_methods] object it uses a combination of
1098 ** these integer values as the second argument.
1100 ** When the SQLITE_SYNC_DATAONLY flag is used, it means that the
1101 ** sync operation only needs to flush data to mass storage. Inode
1102 ** information need not be flushed. If the lower four bits of the flag
1103 ** equal SQLITE_SYNC_NORMAL, that means to use normal fsync() semantics.
1104 ** If the lower four bits equal SQLITE_SYNC_FULL, that means
1105 ** to use Mac OS X style fullsync instead of fsync().
1107 ** Do not confuse the SQLITE_SYNC_NORMAL and SQLITE_SYNC_FULL flags
1108 ** with the [PRAGMA synchronous]=NORMAL and [PRAGMA synchronous]=FULL
1109 ** settings. The [synchronous pragma] determines when calls to the
1110 ** xSync VFS method occur and applies uniformly across all platforms.
1111 ** The SQLITE_SYNC_NORMAL and SQLITE_SYNC_FULL flags determine how
1112 ** energetic or rigorous or forceful the sync operations are and
1113 ** only make a difference on Mac OSX for the default SQLite code.
1114 ** (Third-party VFS implementations might also make the distinction
1115 ** between SQLITE_SYNC_NORMAL and SQLITE_SYNC_FULL, but among the
1116 ** operating systems natively supported by SQLite, only Mac OSX
1117 ** cares about the difference.)
1119 #define SQLITE_SYNC_NORMAL 0x00002
1120 #define SQLITE_SYNC_FULL 0x00003
1121 #define SQLITE_SYNC_DATAONLY 0x00010
1124 ** CAPI3REF: OS Interface Open File Handle
1126 ** An [sqlite3_file] object represents an open file in the
1127 ** [sqlite3_vfs | OS interface layer]. Individual OS interface
1128 ** implementations will
1129 ** want to subclass this object by appending additional fields
1130 ** for their own use. The pMethods entry is a pointer to an
1131 ** [sqlite3_io_methods] object that defines methods for performing
1132 ** I/O operations on the open file.
1134 typedef struct sqlite3_file sqlite3_file;
1135 struct sqlite3_file {
1136 const struct sqlite3_io_methods *pMethods; /* Methods for an open file */
1140 ** CAPI3REF: OS Interface File Virtual Methods Object
1142 ** Every file opened by the [sqlite3_vfs.xOpen] method populates an
1143 ** [sqlite3_file] object (or, more commonly, a subclass of the
1144 ** [sqlite3_file] object) with a pointer to an instance of this object.
1145 ** This object defines the methods used to perform various operations
1146 ** against the open file represented by the [sqlite3_file] object.
1148 ** If the [sqlite3_vfs.xOpen] method sets the sqlite3_file.pMethods element
1149 ** to a non-NULL pointer, then the sqlite3_io_methods.xClose method
1150 ** may be invoked even if the [sqlite3_vfs.xOpen] reported that it failed. The
1151 ** only way to prevent a call to xClose following a failed [sqlite3_vfs.xOpen]
1152 ** is for the [sqlite3_vfs.xOpen] to set the sqlite3_file.pMethods element
1153 ** to NULL.
1155 ** The flags argument to xSync may be one of [SQLITE_SYNC_NORMAL] or
1156 ** [SQLITE_SYNC_FULL]. The first choice is the normal fsync().
1157 ** The second choice is a Mac OS X style fullsync. The [SQLITE_SYNC_DATAONLY]
1158 ** flag may be ORed in to indicate that only the data of the file
1159 ** and not its inode needs to be synced.
1161 ** The integer values to xLock() and xUnlock() are one of
1162 ** <ul>
1163 ** <li> [SQLITE_LOCK_NONE],
1164 ** <li> [SQLITE_LOCK_SHARED],
1165 ** <li> [SQLITE_LOCK_RESERVED],
1166 ** <li> [SQLITE_LOCK_PENDING], or
1167 ** <li> [SQLITE_LOCK_EXCLUSIVE].
1168 ** </ul>
1169 ** xLock() increases the lock. xUnlock() decreases the lock.
1170 ** The xCheckReservedLock() method checks whether any database connection,
1171 ** either in this process or in some other process, is holding a RESERVED,
1172 ** PENDING, or EXCLUSIVE lock on the file. It returns true
1173 ** if such a lock exists and false otherwise.
1175 ** The xFileControl() method is a generic interface that allows custom
1176 ** VFS implementations to directly control an open file using the
1177 ** [sqlite3_file_control()] interface. The second "op" argument is an
1178 ** integer opcode. The third argument is a generic pointer intended to
1179 ** point to a structure that may contain arguments or space in which to
1180 ** write return values. Potential uses for xFileControl() might be
1181 ** functions to enable blocking locks with timeouts, to change the
1182 ** locking strategy (for example to use dot-file locks), to inquire
1183 ** about the status of a lock, or to break stale locks. The SQLite
1184 ** core reserves all opcodes less than 100 for its own use.
1185 ** A [SQLITE_FCNTL_LOCKSTATE | list of opcodes] less than 100 is available.
1186 ** Applications that define a custom xFileControl method should use opcodes
1187 ** greater than 100 to avoid conflicts. VFS implementations should
1188 ** return [SQLITE_NOTFOUND] for file control opcodes that they do not
1189 ** recognize.
1191 ** The xSectorSize() method returns the sector size of the
1192 ** device that underlies the file. The sector size is the
1193 ** minimum write that can be performed without disturbing
1194 ** other bytes in the file. The xDeviceCharacteristics()
1195 ** method returns a bit vector describing behaviors of the
1196 ** underlying device:
1198 ** <ul>
1199 ** <li> [SQLITE_IOCAP_ATOMIC]
1200 ** <li> [SQLITE_IOCAP_ATOMIC512]
1201 ** <li> [SQLITE_IOCAP_ATOMIC1K]
1202 ** <li> [SQLITE_IOCAP_ATOMIC2K]
1203 ** <li> [SQLITE_IOCAP_ATOMIC4K]
1204 ** <li> [SQLITE_IOCAP_ATOMIC8K]
1205 ** <li> [SQLITE_IOCAP_ATOMIC16K]
1206 ** <li> [SQLITE_IOCAP_ATOMIC32K]
1207 ** <li> [SQLITE_IOCAP_ATOMIC64K]
1208 ** <li> [SQLITE_IOCAP_SAFE_APPEND]
1209 ** <li> [SQLITE_IOCAP_SEQUENTIAL]
1210 ** </ul>
1212 ** The SQLITE_IOCAP_ATOMIC property means that all writes of
1213 ** any size are atomic. The SQLITE_IOCAP_ATOMICnnn values
1214 ** mean that writes of blocks that are nnn bytes in size and
1215 ** are aligned to an address which is an integer multiple of
1216 ** nnn are atomic. The SQLITE_IOCAP_SAFE_APPEND value means
1217 ** that when data is appended to a file, the data is appended
1218 ** first then the size of the file is extended, never the other
1219 ** way around. The SQLITE_IOCAP_SEQUENTIAL property means that
1220 ** information is written to disk in the same order as calls
1221 ** to xWrite().
1223 ** If xRead() returns SQLITE_IOERR_SHORT_READ it must also fill
1224 ** in the unread portions of the buffer with zeros. A VFS that
1225 ** fails to zero-fill short reads might seem to work. However,
1226 ** failure to zero-fill short reads will eventually lead to
1227 ** database corruption.
1229 typedef struct sqlite3_io_methods sqlite3_io_methods;
1230 struct sqlite3_io_methods {
1231 int iVersion;
1232 int (*xClose)(sqlite3_file*);
1233 int (*xRead)(sqlite3_file*, void*, int iAmt, sqlite3_int64 iOfst);
1234 int (*xWrite)(sqlite3_file*, const void*, int iAmt, sqlite3_int64 iOfst);
1235 int (*xTruncate)(sqlite3_file*, sqlite3_int64 size);
1236 int (*xSync)(sqlite3_file*, int flags);
1237 int (*xFileSize)(sqlite3_file*, sqlite3_int64 *pSize);
1238 int (*xLock)(sqlite3_file*, int);
1239 int (*xUnlock)(sqlite3_file*, int);
1240 int (*xCheckReservedLock)(sqlite3_file*, int *pResOut);
1241 int (*xFileControl)(sqlite3_file*, int op, void *pArg);
1242 int (*xSectorSize)(sqlite3_file*);
1243 int (*xDeviceCharacteristics)(sqlite3_file*);
1244 /* Methods above are valid for version 1 */
1245 int (*xShmMap)(sqlite3_file*, int iPg, int pgsz, int, void volatile**);
1246 int (*xShmLock)(sqlite3_file*, int offset, int n, int flags);
1247 void (*xShmBarrier)(sqlite3_file*);
1248 int (*xShmUnmap)(sqlite3_file*, int deleteFlag);
1249 /* Methods above are valid for version 2 */
1250 /* Additional methods may be added in future releases */
1254 ** CAPI3REF: Standard File Control Opcodes
1256 ** These integer constants are opcodes for the xFileControl method
1257 ** of the [sqlite3_io_methods] object and for the [sqlite3_file_control()]
1258 ** interface.
1260 ** The [SQLITE_FCNTL_LOCKSTATE] opcode is used for debugging. This
1261 ** opcode causes the xFileControl method to write the current state of
1262 ** the lock (one of [SQLITE_LOCK_NONE], [SQLITE_LOCK_SHARED],
1263 ** [SQLITE_LOCK_RESERVED], [SQLITE_LOCK_PENDING], or [SQLITE_LOCK_EXCLUSIVE])
1264 ** into an integer that the pArg argument points to. This capability
1265 ** is used during testing and only needs to be supported when SQLITE_TEST
1266 ** is defined.
1268 ** The [SQLITE_FCNTL_SIZE_HINT] opcode is used by SQLite to give the VFS
1269 ** layer a hint of how large the database file will grow to be during the
1270 ** current transaction. This hint is not guaranteed to be accurate but it
1271 ** is often close. The underlying VFS might choose to preallocate database
1272 ** file space based on this hint in order to help writes to the database
1273 ** file run faster.
1275 ** The [SQLITE_FCNTL_CHUNK_SIZE] opcode is used to request that the VFS
1276 ** extends and truncates the database file in chunks of a size specified
1277 ** by the user. The fourth argument to [sqlite3_file_control()] should
1278 ** point to an integer (type int) containing the new chunk-size to use
1279 ** for the nominated database. Allocating database file space in large
1280 ** chunks (say 1MB at a time), may reduce file-system fragmentation and
1281 ** improve performance on some systems.
1283 ** The [SQLITE_FCNTL_FILE_POINTER] opcode is used to obtain a pointer
1284 ** to the [sqlite3_file] object associated with a particular database
1285 ** connection. See the [sqlite3_file_control()] documentation for
1286 ** additional information.
1288 ** ^(The [SQLITE_FCNTL_SYNC_OMITTED] opcode is generated internally by
1289 ** SQLite and sent to all VFSes in place of a call to the xSync method
1290 ** when the database connection has [PRAGMA synchronous] set to OFF.)^
1291 ** Some specialized VFSes need this signal in order to operate correctly
1292 ** when [PRAGMA synchronous | PRAGMA synchronous=OFF] is set, but most
1293 ** VFSes do not need this signal and should silently ignore this opcode.
1294 ** Applications should not call [sqlite3_file_control()] with this
1295 ** opcode as doing so may disrupt the operation of the specialized VFSes
1296 ** that do require it.
1298 ** ^The [SQLITE_FCNTL_WIN32_AV_RETRY] opcode is used to configure automatic
1299 ** retry counts and intervals for certain disk I/O operations for the
1300 ** windows [VFS] in order to work to provide robustness against
1301 ** anti-virus programs. By default, the windows VFS will retry file read,
1302 ** file write, and file delete opertions up to 10 times, with a delay
1303 ** of 25 milliseconds before the first retry and with the delay increasing
1304 ** by an additional 25 milliseconds with each subsequent retry. This
1305 ** opcode allows those to values (10 retries and 25 milliseconds of delay)
1306 ** to be adjusted. The values are changed for all database connections
1307 ** within the same process. The argument is a pointer to an array of two
1308 ** integers where the first integer i the new retry count and the second
1309 ** integer is the delay. If either integer is negative, then the setting
1310 ** is not changed but instead the prior value of that setting is written
1311 ** into the array entry, allowing the current retry settings to be
1312 ** interrogated. The zDbName parameter is ignored.
1314 ** ^The [SQLITE_FCNTL_PERSIST_WAL] opcode is used to set or query the
1315 ** persistent [WAL | Write AHead Log] setting. By default, the auxiliary
1316 ** write ahead log and shared memory files used for transaction control
1317 ** are automatically deleted when the latest connection to the database
1318 ** closes. Setting persistent WAL mode causes those files to persist after
1319 ** close. Persisting the files is useful when other processes that do not
1320 ** have write permission on the directory containing the database file want
1321 ** to read the database file, as the WAL and shared memory files must exist
1322 ** in order for the database to be readable. The fourth parameter to
1323 ** [sqlite3_file_control()] for this opcode should be a pointer to an integer.
1324 ** That integer is 0 to disable persistent WAL mode or 1 to enable persistent
1325 ** WAL mode. If the integer is -1, then it is overwritten with the current
1326 ** WAL persistence setting.
1329 #define SQLITE_FCNTL_LOCKSTATE 1
1330 #define SQLITE_GET_LOCKPROXYFILE 2
1331 #define SQLITE_SET_LOCKPROXYFILE 3
1332 #define SQLITE_LAST_ERRNO 4
1333 #define SQLITE_FCNTL_SIZE_HINT 5
1334 #define SQLITE_FCNTL_CHUNK_SIZE 6
1335 #define SQLITE_FCNTL_FILE_POINTER 7
1336 #define SQLITE_FCNTL_SYNC_OMITTED 8
1337 #define SQLITE_FCNTL_WIN32_AV_RETRY 9
1338 #define SQLITE_FCNTL_PERSIST_WAL 10
1341 ** CAPI3REF: Mutex Handle
1343 ** The mutex module within SQLite defines [sqlite3_mutex] to be an
1344 ** abstract type for a mutex object. The SQLite core never looks
1345 ** at the internal representation of an [sqlite3_mutex]. It only
1346 ** deals with pointers to the [sqlite3_mutex] object.
1348 ** Mutexes are created using [sqlite3_mutex_alloc()].
1350 typedef struct sqlite3_mutex sqlite3_mutex;
1353 ** CAPI3REF: OS Interface Object
1355 ** An instance of the sqlite3_vfs object defines the interface between
1356 ** the SQLite core and the underlying operating system. The "vfs"
1357 ** in the name of the object stands for "virtual file system". See
1358 ** the [VFS | VFS documentation] for further information.
1360 ** The value of the iVersion field is initially 1 but may be larger in
1361 ** future versions of SQLite. Additional fields may be appended to this
1362 ** object when the iVersion value is increased. Note that the structure
1363 ** of the sqlite3_vfs object changes in the transaction between
1364 ** SQLite version 3.5.9 and 3.6.0 and yet the iVersion field was not
1365 ** modified.
1367 ** The szOsFile field is the size of the subclassed [sqlite3_file]
1368 ** structure used by this VFS. mxPathname is the maximum length of
1369 ** a pathname in this VFS.
1371 ** Registered sqlite3_vfs objects are kept on a linked list formed by
1372 ** the pNext pointer. The [sqlite3_vfs_register()]
1373 ** and [sqlite3_vfs_unregister()] interfaces manage this list
1374 ** in a thread-safe way. The [sqlite3_vfs_find()] interface
1375 ** searches the list. Neither the application code nor the VFS
1376 ** implementation should use the pNext pointer.
1378 ** The pNext field is the only field in the sqlite3_vfs
1379 ** structure that SQLite will ever modify. SQLite will only access
1380 ** or modify this field while holding a particular static mutex.
1381 ** The application should never modify anything within the sqlite3_vfs
1382 ** object once the object has been registered.
1384 ** The zName field holds the name of the VFS module. The name must
1385 ** be unique across all VFS modules.
1387 ** [[sqlite3_vfs.xOpen]]
1388 ** ^SQLite guarantees that the zFilename parameter to xOpen
1389 ** is either a NULL pointer or string obtained
1390 ** from xFullPathname() with an optional suffix added.
1391 ** ^If a suffix is added to the zFilename parameter, it will
1392 ** consist of a single "-" character followed by no more than
1393 ** 10 alphanumeric and/or "-" characters.
1394 ** ^SQLite further guarantees that
1395 ** the string will be valid and unchanged until xClose() is
1396 ** called. Because of the previous sentence,
1397 ** the [sqlite3_file] can safely store a pointer to the
1398 ** filename if it needs to remember the filename for some reason.
1399 ** If the zFilename parameter to xOpen is a NULL pointer then xOpen
1400 ** must invent its own temporary name for the file. ^Whenever the
1401 ** xFilename parameter is NULL it will also be the case that the
1402 ** flags parameter will include [SQLITE_OPEN_DELETEONCLOSE].
1404 ** The flags argument to xOpen() includes all bits set in
1405 ** the flags argument to [sqlite3_open_v2()]. Or if [sqlite3_open()]
1406 ** or [sqlite3_open16()] is used, then flags includes at least
1407 ** [SQLITE_OPEN_READWRITE] | [SQLITE_OPEN_CREATE].
1408 ** If xOpen() opens a file read-only then it sets *pOutFlags to
1409 ** include [SQLITE_OPEN_READONLY]. Other bits in *pOutFlags may be set.
1411 ** ^(SQLite will also add one of the following flags to the xOpen()
1412 ** call, depending on the object being opened:
1414 ** <ul>
1415 ** <li> [SQLITE_OPEN_MAIN_DB]
1416 ** <li> [SQLITE_OPEN_MAIN_JOURNAL]
1417 ** <li> [SQLITE_OPEN_TEMP_DB]
1418 ** <li> [SQLITE_OPEN_TEMP_JOURNAL]
1419 ** <li> [SQLITE_OPEN_TRANSIENT_DB]
1420 ** <li> [SQLITE_OPEN_SUBJOURNAL]
1421 ** <li> [SQLITE_OPEN_MASTER_JOURNAL]
1422 ** <li> [SQLITE_OPEN_WAL]
1423 ** </ul>)^
1425 ** The file I/O implementation can use the object type flags to
1426 ** change the way it deals with files. For example, an application
1427 ** that does not care about crash recovery or rollback might make
1428 ** the open of a journal file a no-op. Writes to this journal would
1429 ** also be no-ops, and any attempt to read the journal would return
1430 ** SQLITE_IOERR. Or the implementation might recognize that a database
1431 ** file will be doing page-aligned sector reads and writes in a random
1432 ** order and set up its I/O subsystem accordingly.
1434 ** SQLite might also add one of the following flags to the xOpen method:
1436 ** <ul>
1437 ** <li> [SQLITE_OPEN_DELETEONCLOSE]
1438 ** <li> [SQLITE_OPEN_EXCLUSIVE]
1439 ** </ul>
1441 ** The [SQLITE_OPEN_DELETEONCLOSE] flag means the file should be
1442 ** deleted when it is closed. ^The [SQLITE_OPEN_DELETEONCLOSE]
1443 ** will be set for TEMP databases and their journals, transient
1444 ** databases, and subjournals.
1446 ** ^The [SQLITE_OPEN_EXCLUSIVE] flag is always used in conjunction
1447 ** with the [SQLITE_OPEN_CREATE] flag, which are both directly
1448 ** analogous to the O_EXCL and O_CREAT flags of the POSIX open()
1449 ** API. The SQLITE_OPEN_EXCLUSIVE flag, when paired with the
1450 ** SQLITE_OPEN_CREATE, is used to indicate that file should always
1451 ** be created, and that it is an error if it already exists.
1452 ** It is <i>not</i> used to indicate the file should be opened
1453 ** for exclusive access.
1455 ** ^At least szOsFile bytes of memory are allocated by SQLite
1456 ** to hold the [sqlite3_file] structure passed as the third
1457 ** argument to xOpen. The xOpen method does not have to
1458 ** allocate the structure; it should just fill it in. Note that
1459 ** the xOpen method must set the sqlite3_file.pMethods to either
1460 ** a valid [sqlite3_io_methods] object or to NULL. xOpen must do
1461 ** this even if the open fails. SQLite expects that the sqlite3_file.pMethods
1462 ** element will be valid after xOpen returns regardless of the success
1463 ** or failure of the xOpen call.
1465 ** [[sqlite3_vfs.xAccess]]
1466 ** ^The flags argument to xAccess() may be [SQLITE_ACCESS_EXISTS]
1467 ** to test for the existence of a file, or [SQLITE_ACCESS_READWRITE] to
1468 ** test whether a file is readable and writable, or [SQLITE_ACCESS_READ]
1469 ** to test whether a file is at least readable. The file can be a
1470 ** directory.
1472 ** ^SQLite will always allocate at least mxPathname+1 bytes for the
1473 ** output buffer xFullPathname. The exact size of the output buffer
1474 ** is also passed as a parameter to both methods. If the output buffer
1475 ** is not large enough, [SQLITE_CANTOPEN] should be returned. Since this is
1476 ** handled as a fatal error by SQLite, vfs implementations should endeavor
1477 ** to prevent this by setting mxPathname to a sufficiently large value.
1479 ** The xRandomness(), xSleep(), xCurrentTime(), and xCurrentTimeInt64()
1480 ** interfaces are not strictly a part of the filesystem, but they are
1481 ** included in the VFS structure for completeness.
1482 ** The xRandomness() function attempts to return nBytes bytes
1483 ** of good-quality randomness into zOut. The return value is
1484 ** the actual number of bytes of randomness obtained.
1485 ** The xSleep() method causes the calling thread to sleep for at
1486 ** least the number of microseconds given. ^The xCurrentTime()
1487 ** method returns a Julian Day Number for the current date and time as
1488 ** a floating point value.
1489 ** ^The xCurrentTimeInt64() method returns, as an integer, the Julian
1490 ** Day Number multiplied by 86400000 (the number of milliseconds in
1491 ** a 24-hour day).
1492 ** ^SQLite will use the xCurrentTimeInt64() method to get the current
1493 ** date and time if that method is available (if iVersion is 2 or
1494 ** greater and the function pointer is not NULL) and will fall back
1495 ** to xCurrentTime() if xCurrentTimeInt64() is unavailable.
1497 ** ^The xSetSystemCall(), xGetSystemCall(), and xNestSystemCall() interfaces
1498 ** are not used by the SQLite core. These optional interfaces are provided
1499 ** by some VFSes to facilitate testing of the VFS code. By overriding
1500 ** system calls with functions under its control, a test program can
1501 ** simulate faults and error conditions that would otherwise be difficult
1502 ** or impossible to induce. The set of system calls that can be overridden
1503 ** varies from one VFS to another, and from one version of the same VFS to the
1504 ** next. Applications that use these interfaces must be prepared for any
1505 ** or all of these interfaces to be NULL or for their behavior to change
1506 ** from one release to the next. Applications must not attempt to access
1507 ** any of these methods if the iVersion of the VFS is less than 3.
1509 typedef struct sqlite3_vfs sqlite3_vfs;
1510 typedef void (*sqlite3_syscall_ptr)(void);
1511 struct sqlite3_vfs {
1512 int iVersion; /* Structure version number (currently 3) */
1513 int szOsFile; /* Size of subclassed sqlite3_file */
1514 int mxPathname; /* Maximum file pathname length */
1515 sqlite3_vfs *pNext; /* Next registered VFS */
1516 const char *zName; /* Name of this virtual file system */
1517 void *pAppData; /* Pointer to application-specific data */
1518 int (*xOpen)(sqlite3_vfs*, const char *zName, sqlite3_file*,
1519 int flags, int *pOutFlags);
1520 int (*xDelete)(sqlite3_vfs*, const char *zName, int syncDir);
1521 int (*xAccess)(sqlite3_vfs*, const char *zName, int flags, int *pResOut);
1522 int (*xFullPathname)(sqlite3_vfs*, const char *zName, int nOut, char *zOut);
1523 void *(*xDlOpen)(sqlite3_vfs*, const char *zFilename);
1524 void (*xDlError)(sqlite3_vfs*, int nByte, char *zErrMsg);
1525 void (*(*xDlSym)(sqlite3_vfs*,void*, const char *zSymbol))(void);
1526 void (*xDlClose)(sqlite3_vfs*, void*);
1527 int (*xRandomness)(sqlite3_vfs*, int nByte, char *zOut);
1528 int (*xSleep)(sqlite3_vfs*, int microseconds);
1529 int (*xCurrentTime)(sqlite3_vfs*, double*);
1530 int (*xGetLastError)(sqlite3_vfs*, int, char *);
1532 ** The methods above are in version 1 of the sqlite_vfs object
1533 ** definition. Those that follow are added in version 2 or later
1535 int (*xCurrentTimeInt64)(sqlite3_vfs*, sqlite3_int64*);
1537 ** The methods above are in versions 1 and 2 of the sqlite_vfs object.
1538 ** Those below are for version 3 and greater.
1540 int (*xSetSystemCall)(sqlite3_vfs*, const char *zName, sqlite3_syscall_ptr);
1541 sqlite3_syscall_ptr (*xGetSystemCall)(sqlite3_vfs*, const char *zName);
1542 const char *(*xNextSystemCall)(sqlite3_vfs*, const char *zName);
1544 ** The methods above are in versions 1 through 3 of the sqlite_vfs object.
1545 ** New fields may be appended in figure versions. The iVersion
1546 ** value will increment whenever this happens.
1551 ** CAPI3REF: Flags for the xAccess VFS method
1553 ** These integer constants can be used as the third parameter to
1554 ** the xAccess method of an [sqlite3_vfs] object. They determine
1555 ** what kind of permissions the xAccess method is looking for.
1556 ** With SQLITE_ACCESS_EXISTS, the xAccess method
1557 ** simply checks whether the file exists.
1558 ** With SQLITE_ACCESS_READWRITE, the xAccess method
1559 ** checks whether the named directory is both readable and writable
1560 ** (in other words, if files can be added, removed, and renamed within
1561 ** the directory).
1562 ** The SQLITE_ACCESS_READWRITE constant is currently used only by the
1563 ** [temp_store_directory pragma], though this could change in a future
1564 ** release of SQLite.
1565 ** With SQLITE_ACCESS_READ, the xAccess method
1566 ** checks whether the file is readable. The SQLITE_ACCESS_READ constant is
1567 ** currently unused, though it might be used in a future release of
1568 ** SQLite.
1570 #define SQLITE_ACCESS_EXISTS 0
1571 #define SQLITE_ACCESS_READWRITE 1 /* Used by PRAGMA temp_store_directory */
1572 #define SQLITE_ACCESS_READ 2 /* Unused */
1575 ** CAPI3REF: Flags for the xShmLock VFS method
1577 ** These integer constants define the various locking operations
1578 ** allowed by the xShmLock method of [sqlite3_io_methods]. The
1579 ** following are the only legal combinations of flags to the
1580 ** xShmLock method:
1582 ** <ul>
1583 ** <li> SQLITE_SHM_LOCK | SQLITE_SHM_SHARED
1584 ** <li> SQLITE_SHM_LOCK | SQLITE_SHM_EXCLUSIVE
1585 ** <li> SQLITE_SHM_UNLOCK | SQLITE_SHM_SHARED
1586 ** <li> SQLITE_SHM_UNLOCK | SQLITE_SHM_EXCLUSIVE
1587 ** </ul>
1589 ** When unlocking, the same SHARED or EXCLUSIVE flag must be supplied as
1590 ** was given no the corresponding lock.
1592 ** The xShmLock method can transition between unlocked and SHARED or
1593 ** between unlocked and EXCLUSIVE. It cannot transition between SHARED
1594 ** and EXCLUSIVE.
1596 #define SQLITE_SHM_UNLOCK 1
1597 #define SQLITE_SHM_LOCK 2
1598 #define SQLITE_SHM_SHARED 4
1599 #define SQLITE_SHM_EXCLUSIVE 8
1602 ** CAPI3REF: Maximum xShmLock index
1604 ** The xShmLock method on [sqlite3_io_methods] may use values
1605 ** between 0 and this upper bound as its "offset" argument.
1606 ** The SQLite core will never attempt to acquire or release a
1607 ** lock outside of this range
1609 #define SQLITE_SHM_NLOCK 8
1613 ** CAPI3REF: Initialize The SQLite Library
1615 ** ^The sqlite3_initialize() routine initializes the
1616 ** SQLite library. ^The sqlite3_shutdown() routine
1617 ** deallocates any resources that were allocated by sqlite3_initialize().
1618 ** These routines are designed to aid in process initialization and
1619 ** shutdown on embedded systems. Workstation applications using
1620 ** SQLite normally do not need to invoke either of these routines.
1622 ** A call to sqlite3_initialize() is an "effective" call if it is
1623 ** the first time sqlite3_initialize() is invoked during the lifetime of
1624 ** the process, or if it is the first time sqlite3_initialize() is invoked
1625 ** following a call to sqlite3_shutdown(). ^(Only an effective call
1626 ** of sqlite3_initialize() does any initialization. All other calls
1627 ** are harmless no-ops.)^
1629 ** A call to sqlite3_shutdown() is an "effective" call if it is the first
1630 ** call to sqlite3_shutdown() since the last sqlite3_initialize(). ^(Only
1631 ** an effective call to sqlite3_shutdown() does any deinitialization.
1632 ** All other valid calls to sqlite3_shutdown() are harmless no-ops.)^
1634 ** The sqlite3_initialize() interface is threadsafe, but sqlite3_shutdown()
1635 ** is not. The sqlite3_shutdown() interface must only be called from a
1636 ** single thread. All open [database connections] must be closed and all
1637 ** other SQLite resources must be deallocated prior to invoking
1638 ** sqlite3_shutdown().
1640 ** Among other things, ^sqlite3_initialize() will invoke
1641 ** sqlite3_os_init(). Similarly, ^sqlite3_shutdown()
1642 ** will invoke sqlite3_os_end().
1644 ** ^The sqlite3_initialize() routine returns [SQLITE_OK] on success.
1645 ** ^If for some reason, sqlite3_initialize() is unable to initialize
1646 ** the library (perhaps it is unable to allocate a needed resource such
1647 ** as a mutex) it returns an [error code] other than [SQLITE_OK].
1649 ** ^The sqlite3_initialize() routine is called internally by many other
1650 ** SQLite interfaces so that an application usually does not need to
1651 ** invoke sqlite3_initialize() directly. For example, [sqlite3_open()]
1652 ** calls sqlite3_initialize() so the SQLite library will be automatically
1653 ** initialized when [sqlite3_open()] is called if it has not be initialized
1654 ** already. ^However, if SQLite is compiled with the [SQLITE_OMIT_AUTOINIT]
1655 ** compile-time option, then the automatic calls to sqlite3_initialize()
1656 ** are omitted and the application must call sqlite3_initialize() directly
1657 ** prior to using any other SQLite interface. For maximum portability,
1658 ** it is recommended that applications always invoke sqlite3_initialize()
1659 ** directly prior to using any other SQLite interface. Future releases
1660 ** of SQLite may require this. In other words, the behavior exhibited
1661 ** when SQLite is compiled with [SQLITE_OMIT_AUTOINIT] might become the
1662 ** default behavior in some future release of SQLite.
1664 ** The sqlite3_os_init() routine does operating-system specific
1665 ** initialization of the SQLite library. The sqlite3_os_end()
1666 ** routine undoes the effect of sqlite3_os_init(). Typical tasks
1667 ** performed by these routines include allocation or deallocation
1668 ** of static resources, initialization of global variables,
1669 ** setting up a default [sqlite3_vfs] module, or setting up
1670 ** a default configuration using [sqlite3_config()].
1672 ** The application should never invoke either sqlite3_os_init()
1673 ** or sqlite3_os_end() directly. The application should only invoke
1674 ** sqlite3_initialize() and sqlite3_shutdown(). The sqlite3_os_init()
1675 ** interface is called automatically by sqlite3_initialize() and
1676 ** sqlite3_os_end() is called by sqlite3_shutdown(). Appropriate
1677 ** implementations for sqlite3_os_init() and sqlite3_os_end()
1678 ** are built into SQLite when it is compiled for Unix, Windows, or OS/2.
1679 ** When [custom builds | built for other platforms]
1680 ** (using the [SQLITE_OS_OTHER=1] compile-time
1681 ** option) the application must supply a suitable implementation for
1682 ** sqlite3_os_init() and sqlite3_os_end(). An application-supplied
1683 ** implementation of sqlite3_os_init() or sqlite3_os_end()
1684 ** must return [SQLITE_OK] on success and some other [error code] upon
1685 ** failure.
1687 SQLITE_API int sqlite3_initialize(void);
1688 SQLITE_API int sqlite3_shutdown(void);
1689 SQLITE_API int sqlite3_os_init(void);
1690 SQLITE_API int sqlite3_os_end(void);
1693 ** CAPI3REF: Configuring The SQLite Library
1695 ** The sqlite3_config() interface is used to make global configuration
1696 ** changes to SQLite in order to tune SQLite to the specific needs of
1697 ** the application. The default configuration is recommended for most
1698 ** applications and so this routine is usually not necessary. It is
1699 ** provided to support rare applications with unusual needs.
1701 ** The sqlite3_config() interface is not threadsafe. The application
1702 ** must insure that no other SQLite interfaces are invoked by other
1703 ** threads while sqlite3_config() is running. Furthermore, sqlite3_config()
1704 ** may only be invoked prior to library initialization using
1705 ** [sqlite3_initialize()] or after shutdown by [sqlite3_shutdown()].
1706 ** ^If sqlite3_config() is called after [sqlite3_initialize()] and before
1707 ** [sqlite3_shutdown()] then it will return SQLITE_MISUSE.
1708 ** Note, however, that ^sqlite3_config() can be called as part of the
1709 ** implementation of an application-defined [sqlite3_os_init()].
1711 ** The first argument to sqlite3_config() is an integer
1712 ** [configuration option] that determines
1713 ** what property of SQLite is to be configured. Subsequent arguments
1714 ** vary depending on the [configuration option]
1715 ** in the first argument.
1717 ** ^When a configuration option is set, sqlite3_config() returns [SQLITE_OK].
1718 ** ^If the option is unknown or SQLite is unable to set the option
1719 ** then this routine returns a non-zero [error code].
1721 SQLITE_API int sqlite3_config(int, ...);
1724 ** CAPI3REF: Configure database connections
1726 ** The sqlite3_db_config() interface is used to make configuration
1727 ** changes to a [database connection]. The interface is similar to
1728 ** [sqlite3_config()] except that the changes apply to a single
1729 ** [database connection] (specified in the first argument).
1731 ** The second argument to sqlite3_db_config(D,V,...) is the
1732 ** [SQLITE_DBCONFIG_LOOKASIDE | configuration verb] - an integer code
1733 ** that indicates what aspect of the [database connection] is being configured.
1734 ** Subsequent arguments vary depending on the configuration verb.
1736 ** ^Calls to sqlite3_db_config() return SQLITE_OK if and only if
1737 ** the call is considered successful.
1739 SQLITE_API int sqlite3_db_config(sqlite3*, int op, ...);
1742 ** CAPI3REF: Memory Allocation Routines
1744 ** An instance of this object defines the interface between SQLite
1745 ** and low-level memory allocation routines.
1747 ** This object is used in only one place in the SQLite interface.
1748 ** A pointer to an instance of this object is the argument to
1749 ** [sqlite3_config()] when the configuration option is
1750 ** [SQLITE_CONFIG_MALLOC] or [SQLITE_CONFIG_GETMALLOC].
1751 ** By creating an instance of this object
1752 ** and passing it to [sqlite3_config]([SQLITE_CONFIG_MALLOC])
1753 ** during configuration, an application can specify an alternative
1754 ** memory allocation subsystem for SQLite to use for all of its
1755 ** dynamic memory needs.
1757 ** Note that SQLite comes with several [built-in memory allocators]
1758 ** that are perfectly adequate for the overwhelming majority of applications
1759 ** and that this object is only useful to a tiny minority of applications
1760 ** with specialized memory allocation requirements. This object is
1761 ** also used during testing of SQLite in order to specify an alternative
1762 ** memory allocator that simulates memory out-of-memory conditions in
1763 ** order to verify that SQLite recovers gracefully from such
1764 ** conditions.
1766 ** The xMalloc, xRealloc, and xFree methods must work like the
1767 ** malloc(), realloc() and free() functions from the standard C library.
1768 ** ^SQLite guarantees that the second argument to
1769 ** xRealloc is always a value returned by a prior call to xRoundup.
1771 ** xSize should return the allocated size of a memory allocation
1772 ** previously obtained from xMalloc or xRealloc. The allocated size
1773 ** is always at least as big as the requested size but may be larger.
1775 ** The xRoundup method returns what would be the allocated size of
1776 ** a memory allocation given a particular requested size. Most memory
1777 ** allocators round up memory allocations at least to the next multiple
1778 ** of 8. Some allocators round up to a larger multiple or to a power of 2.
1779 ** Every memory allocation request coming in through [sqlite3_malloc()]
1780 ** or [sqlite3_realloc()] first calls xRoundup. If xRoundup returns 0,
1781 ** that causes the corresponding memory allocation to fail.
1783 ** The xInit method initializes the memory allocator. (For example,
1784 ** it might allocate any require mutexes or initialize internal data
1785 ** structures. The xShutdown method is invoked (indirectly) by
1786 ** [sqlite3_shutdown()] and should deallocate any resources acquired
1787 ** by xInit. The pAppData pointer is used as the only parameter to
1788 ** xInit and xShutdown.
1790 ** SQLite holds the [SQLITE_MUTEX_STATIC_MASTER] mutex when it invokes
1791 ** the xInit method, so the xInit method need not be threadsafe. The
1792 ** xShutdown method is only called from [sqlite3_shutdown()] so it does
1793 ** not need to be threadsafe either. For all other methods, SQLite
1794 ** holds the [SQLITE_MUTEX_STATIC_MEM] mutex as long as the
1795 ** [SQLITE_CONFIG_MEMSTATUS] configuration option is turned on (which
1796 ** it is by default) and so the methods are automatically serialized.
1797 ** However, if [SQLITE_CONFIG_MEMSTATUS] is disabled, then the other
1798 ** methods must be threadsafe or else make their own arrangements for
1799 ** serialization.
1801 ** SQLite will never invoke xInit() more than once without an intervening
1802 ** call to xShutdown().
1804 typedef struct sqlite3_mem_methods sqlite3_mem_methods;
1805 struct sqlite3_mem_methods {
1806 void *(*xMalloc)(int); /* Memory allocation function */
1807 void (*xFree)(void*); /* Free a prior allocation */
1808 void *(*xRealloc)(void*,int); /* Resize an allocation */
1809 int (*xSize)(void*); /* Return the size of an allocation */
1810 int (*xRoundup)(int); /* Round up request size to allocation size */
1811 int (*xInit)(void*); /* Initialize the memory allocator */
1812 void (*xShutdown)(void*); /* Deinitialize the memory allocator */
1813 void *pAppData; /* Argument to xInit() and xShutdown() */
1817 ** CAPI3REF: Configuration Options
1818 ** KEYWORDS: {configuration option}
1820 ** These constants are the available integer configuration options that
1821 ** can be passed as the first argument to the [sqlite3_config()] interface.
1823 ** New configuration options may be added in future releases of SQLite.
1824 ** Existing configuration options might be discontinued. Applications
1825 ** should check the return code from [sqlite3_config()] to make sure that
1826 ** the call worked. The [sqlite3_config()] interface will return a
1827 ** non-zero [error code] if a discontinued or unsupported configuration option
1828 ** is invoked.
1830 ** <dl>
1831 ** [[SQLITE_CONFIG_SINGLETHREAD]] <dt>SQLITE_CONFIG_SINGLETHREAD</dt>
1832 ** <dd>There are no arguments to this option. ^This option sets the
1833 ** [threading mode] to Single-thread. In other words, it disables
1834 ** all mutexing and puts SQLite into a mode where it can only be used
1835 ** by a single thread. ^If SQLite is compiled with
1836 ** the [SQLITE_THREADSAFE | SQLITE_THREADSAFE=0] compile-time option then
1837 ** it is not possible to change the [threading mode] from its default
1838 ** value of Single-thread and so [sqlite3_config()] will return
1839 ** [SQLITE_ERROR] if called with the SQLITE_CONFIG_SINGLETHREAD
1840 ** configuration option.</dd>
1842 ** [[SQLITE_CONFIG_MULTITHREAD]] <dt>SQLITE_CONFIG_MULTITHREAD</dt>
1843 ** <dd>There are no arguments to this option. ^This option sets the
1844 ** [threading mode] to Multi-thread. In other words, it disables
1845 ** mutexing on [database connection] and [prepared statement] objects.
1846 ** The application is responsible for serializing access to
1847 ** [database connections] and [prepared statements]. But other mutexes
1848 ** are enabled so that SQLite will be safe to use in a multi-threaded
1849 ** environment as long as no two threads attempt to use the same
1850 ** [database connection] at the same time. ^If SQLite is compiled with
1851 ** the [SQLITE_THREADSAFE | SQLITE_THREADSAFE=0] compile-time option then
1852 ** it is not possible to set the Multi-thread [threading mode] and
1853 ** [sqlite3_config()] will return [SQLITE_ERROR] if called with the
1854 ** SQLITE_CONFIG_MULTITHREAD configuration option.</dd>
1856 ** [[SQLITE_CONFIG_SERIALIZED]] <dt>SQLITE_CONFIG_SERIALIZED</dt>
1857 ** <dd>There are no arguments to this option. ^This option sets the
1858 ** [threading mode] to Serialized. In other words, this option enables
1859 ** all mutexes including the recursive
1860 ** mutexes on [database connection] and [prepared statement] objects.
1861 ** In this mode (which is the default when SQLite is compiled with
1862 ** [SQLITE_THREADSAFE=1]) the SQLite library will itself serialize access
1863 ** to [database connections] and [prepared statements] so that the
1864 ** application is free to use the same [database connection] or the
1865 ** same [prepared statement] in different threads at the same time.
1866 ** ^If SQLite is compiled with
1867 ** the [SQLITE_THREADSAFE | SQLITE_THREADSAFE=0] compile-time option then
1868 ** it is not possible to set the Serialized [threading mode] and
1869 ** [sqlite3_config()] will return [SQLITE_ERROR] if called with the
1870 ** SQLITE_CONFIG_SERIALIZED configuration option.</dd>
1872 ** [[SQLITE_CONFIG_MALLOC]] <dt>SQLITE_CONFIG_MALLOC</dt>
1873 ** <dd> ^(This option takes a single argument which is a pointer to an
1874 ** instance of the [sqlite3_mem_methods] structure. The argument specifies
1875 ** alternative low-level memory allocation routines to be used in place of
1876 ** the memory allocation routines built into SQLite.)^ ^SQLite makes
1877 ** its own private copy of the content of the [sqlite3_mem_methods] structure
1878 ** before the [sqlite3_config()] call returns.</dd>
1880 ** [[SQLITE_CONFIG_GETMALLOC]] <dt>SQLITE_CONFIG_GETMALLOC</dt>
1881 ** <dd> ^(This option takes a single argument which is a pointer to an
1882 ** instance of the [sqlite3_mem_methods] structure. The [sqlite3_mem_methods]
1883 ** structure is filled with the currently defined memory allocation routines.)^
1884 ** This option can be used to overload the default memory allocation
1885 ** routines with a wrapper that simulations memory allocation failure or
1886 ** tracks memory usage, for example. </dd>
1888 ** [[SQLITE_CONFIG_MEMSTATUS]] <dt>SQLITE_CONFIG_MEMSTATUS</dt>
1889 ** <dd> ^This option takes single argument of type int, interpreted as a
1890 ** boolean, which enables or disables the collection of memory allocation
1891 ** statistics. ^(When memory allocation statistics are disabled, the
1892 ** following SQLite interfaces become non-operational:
1893 ** <ul>
1894 ** <li> [sqlite3_memory_used()]
1895 ** <li> [sqlite3_memory_highwater()]
1896 ** <li> [sqlite3_soft_heap_limit64()]
1897 ** <li> [sqlite3_status()]
1898 ** </ul>)^
1899 ** ^Memory allocation statistics are enabled by default unless SQLite is
1900 ** compiled with [SQLITE_DEFAULT_MEMSTATUS]=0 in which case memory
1901 ** allocation statistics are disabled by default.
1902 ** </dd>
1904 ** [[SQLITE_CONFIG_SCRATCH]] <dt>SQLITE_CONFIG_SCRATCH</dt>
1905 ** <dd> ^This option specifies a static memory buffer that SQLite can use for
1906 ** scratch memory. There are three arguments: A pointer an 8-byte
1907 ** aligned memory buffer from which the scratch allocations will be
1908 ** drawn, the size of each scratch allocation (sz),
1909 ** and the maximum number of scratch allocations (N). The sz
1910 ** argument must be a multiple of 16.
1911 ** The first argument must be a pointer to an 8-byte aligned buffer
1912 ** of at least sz*N bytes of memory.
1913 ** ^SQLite will use no more than two scratch buffers per thread. So
1914 ** N should be set to twice the expected maximum number of threads.
1915 ** ^SQLite will never require a scratch buffer that is more than 6
1916 ** times the database page size. ^If SQLite needs needs additional
1917 ** scratch memory beyond what is provided by this configuration option, then
1918 ** [sqlite3_malloc()] will be used to obtain the memory needed.</dd>
1920 ** [[SQLITE_CONFIG_PAGECACHE]] <dt>SQLITE_CONFIG_PAGECACHE</dt>
1921 ** <dd> ^This option specifies a static memory buffer that SQLite can use for
1922 ** the database page cache with the default page cache implementation.
1923 ** This configuration should not be used if an application-define page
1924 ** cache implementation is loaded using the SQLITE_CONFIG_PCACHE option.
1925 ** There are three arguments to this option: A pointer to 8-byte aligned
1926 ** memory, the size of each page buffer (sz), and the number of pages (N).
1927 ** The sz argument should be the size of the largest database page
1928 ** (a power of two between 512 and 32768) plus a little extra for each
1929 ** page header. ^The page header size is 20 to 40 bytes depending on
1930 ** the host architecture. ^It is harmless, apart from the wasted memory,
1931 ** to make sz a little too large. The first
1932 ** argument should point to an allocation of at least sz*N bytes of memory.
1933 ** ^SQLite will use the memory provided by the first argument to satisfy its
1934 ** memory needs for the first N pages that it adds to cache. ^If additional
1935 ** page cache memory is needed beyond what is provided by this option, then
1936 ** SQLite goes to [sqlite3_malloc()] for the additional storage space.
1937 ** The pointer in the first argument must
1938 ** be aligned to an 8-byte boundary or subsequent behavior of SQLite
1939 ** will be undefined.</dd>
1941 ** [[SQLITE_CONFIG_HEAP]] <dt>SQLITE_CONFIG_HEAP</dt>
1942 ** <dd> ^This option specifies a static memory buffer that SQLite will use
1943 ** for all of its dynamic memory allocation needs beyond those provided
1944 ** for by [SQLITE_CONFIG_SCRATCH] and [SQLITE_CONFIG_PAGECACHE].
1945 ** There are three arguments: An 8-byte aligned pointer to the memory,
1946 ** the number of bytes in the memory buffer, and the minimum allocation size.
1947 ** ^If the first pointer (the memory pointer) is NULL, then SQLite reverts
1948 ** to using its default memory allocator (the system malloc() implementation),
1949 ** undoing any prior invocation of [SQLITE_CONFIG_MALLOC]. ^If the
1950 ** memory pointer is not NULL and either [SQLITE_ENABLE_MEMSYS3] or
1951 ** [SQLITE_ENABLE_MEMSYS5] are defined, then the alternative memory
1952 ** allocator is engaged to handle all of SQLites memory allocation needs.
1953 ** The first pointer (the memory pointer) must be aligned to an 8-byte
1954 ** boundary or subsequent behavior of SQLite will be undefined.
1955 ** The minimum allocation size is capped at 2^12. Reasonable values
1956 ** for the minimum allocation size are 2^5 through 2^8.</dd>
1958 ** [[SQLITE_CONFIG_MUTEX]] <dt>SQLITE_CONFIG_MUTEX</dt>
1959 ** <dd> ^(This option takes a single argument which is a pointer to an
1960 ** instance of the [sqlite3_mutex_methods] structure. The argument specifies
1961 ** alternative low-level mutex routines to be used in place
1962 ** the mutex routines built into SQLite.)^ ^SQLite makes a copy of the
1963 ** content of the [sqlite3_mutex_methods] structure before the call to
1964 ** [sqlite3_config()] returns. ^If SQLite is compiled with
1965 ** the [SQLITE_THREADSAFE | SQLITE_THREADSAFE=0] compile-time option then
1966 ** the entire mutexing subsystem is omitted from the build and hence calls to
1967 ** [sqlite3_config()] with the SQLITE_CONFIG_MUTEX configuration option will
1968 ** return [SQLITE_ERROR].</dd>
1970 ** [[SQLITE_CONFIG_GETMUTEX]] <dt>SQLITE_CONFIG_GETMUTEX</dt>
1971 ** <dd> ^(This option takes a single argument which is a pointer to an
1972 ** instance of the [sqlite3_mutex_methods] structure. The
1973 ** [sqlite3_mutex_methods]
1974 ** structure is filled with the currently defined mutex routines.)^
1975 ** This option can be used to overload the default mutex allocation
1976 ** routines with a wrapper used to track mutex usage for performance
1977 ** profiling or testing, for example. ^If SQLite is compiled with
1978 ** the [SQLITE_THREADSAFE | SQLITE_THREADSAFE=0] compile-time option then
1979 ** the entire mutexing subsystem is omitted from the build and hence calls to
1980 ** [sqlite3_config()] with the SQLITE_CONFIG_GETMUTEX configuration option will
1981 ** return [SQLITE_ERROR].</dd>
1983 ** [[SQLITE_CONFIG_LOOKASIDE]] <dt>SQLITE_CONFIG_LOOKASIDE</dt>
1984 ** <dd> ^(This option takes two arguments that determine the default
1985 ** memory allocation for the lookaside memory allocator on each
1986 ** [database connection]. The first argument is the
1987 ** size of each lookaside buffer slot and the second is the number of
1988 ** slots allocated to each database connection.)^ ^(This option sets the
1989 ** <i>default</i> lookaside size. The [SQLITE_DBCONFIG_LOOKASIDE]
1990 ** verb to [sqlite3_db_config()] can be used to change the lookaside
1991 ** configuration on individual connections.)^ </dd>
1993 ** [[SQLITE_CONFIG_PCACHE]] <dt>SQLITE_CONFIG_PCACHE</dt>
1994 ** <dd> ^(This option takes a single argument which is a pointer to
1995 ** an [sqlite3_pcache_methods] object. This object specifies the interface
1996 ** to a custom page cache implementation.)^ ^SQLite makes a copy of the
1997 ** object and uses it for page cache memory allocations.</dd>
1999 ** [[SQLITE_CONFIG_GETPCACHE]] <dt>SQLITE_CONFIG_GETPCACHE</dt>
2000 ** <dd> ^(This option takes a single argument which is a pointer to an
2001 ** [sqlite3_pcache_methods] object. SQLite copies of the current
2002 ** page cache implementation into that object.)^ </dd>
2004 ** [[SQLITE_CONFIG_LOG]] <dt>SQLITE_CONFIG_LOG</dt>
2005 ** <dd> ^The SQLITE_CONFIG_LOG option takes two arguments: a pointer to a
2006 ** function with a call signature of void(*)(void*,int,const char*),
2007 ** and a pointer to void. ^If the function pointer is not NULL, it is
2008 ** invoked by [sqlite3_log()] to process each logging event. ^If the
2009 ** function pointer is NULL, the [sqlite3_log()] interface becomes a no-op.
2010 ** ^The void pointer that is the second argument to SQLITE_CONFIG_LOG is
2011 ** passed through as the first parameter to the application-defined logger
2012 ** function whenever that function is invoked. ^The second parameter to
2013 ** the logger function is a copy of the first parameter to the corresponding
2014 ** [sqlite3_log()] call and is intended to be a [result code] or an
2015 ** [extended result code]. ^The third parameter passed to the logger is
2016 ** log message after formatting via [sqlite3_snprintf()].
2017 ** The SQLite logging interface is not reentrant; the logger function
2018 ** supplied by the application must not invoke any SQLite interface.
2019 ** In a multi-threaded application, the application-defined logger
2020 ** function must be threadsafe. </dd>
2022 ** [[SQLITE_CONFIG_URI]] <dt>SQLITE_CONFIG_URI
2023 ** <dd> This option takes a single argument of type int. If non-zero, then
2024 ** URI handling is globally enabled. If the parameter is zero, then URI handling
2025 ** is globally disabled. If URI handling is globally enabled, all filenames
2026 ** passed to [sqlite3_open()], [sqlite3_open_v2()], [sqlite3_open16()] or
2027 ** specified as part of [ATTACH] commands are interpreted as URIs, regardless
2028 ** of whether or not the [SQLITE_OPEN_URI] flag is set when the database
2029 ** connection is opened. If it is globally disabled, filenames are
2030 ** only interpreted as URIs if the SQLITE_OPEN_URI flag is set when the
2031 ** database connection is opened. By default, URI handling is globally
2032 ** disabled. The default value may be changed by compiling with the
2033 ** [SQLITE_USE_URI] symbol defined.
2034 ** </dl>
2036 #define SQLITE_CONFIG_SINGLETHREAD 1 /* nil */
2037 #define SQLITE_CONFIG_MULTITHREAD 2 /* nil */
2038 #define SQLITE_CONFIG_SERIALIZED 3 /* nil */
2039 #define SQLITE_CONFIG_MALLOC 4 /* sqlite3_mem_methods* */
2040 #define SQLITE_CONFIG_GETMALLOC 5 /* sqlite3_mem_methods* */
2041 #define SQLITE_CONFIG_SCRATCH 6 /* void*, int sz, int N */
2042 #define SQLITE_CONFIG_PAGECACHE 7 /* void*, int sz, int N */
2043 #define SQLITE_CONFIG_HEAP 8 /* void*, int nByte, int min */
2044 #define SQLITE_CONFIG_MEMSTATUS 9 /* boolean */
2045 #define SQLITE_CONFIG_MUTEX 10 /* sqlite3_mutex_methods* */
2046 #define SQLITE_CONFIG_GETMUTEX 11 /* sqlite3_mutex_methods* */
2047 /* previously SQLITE_CONFIG_CHUNKALLOC 12 which is now unused. */
2048 #define SQLITE_CONFIG_LOOKASIDE 13 /* int int */
2049 #define SQLITE_CONFIG_PCACHE 14 /* sqlite3_pcache_methods* */
2050 #define SQLITE_CONFIG_GETPCACHE 15 /* sqlite3_pcache_methods* */
2051 #define SQLITE_CONFIG_LOG 16 /* xFunc, void* */
2052 #define SQLITE_CONFIG_URI 17 /* int */
2055 ** CAPI3REF: Database Connection Configuration Options
2057 ** These constants are the available integer configuration options that
2058 ** can be passed as the second argument to the [sqlite3_db_config()] interface.
2060 ** New configuration options may be added in future releases of SQLite.
2061 ** Existing configuration options might be discontinued. Applications
2062 ** should check the return code from [sqlite3_db_config()] to make sure that
2063 ** the call worked. ^The [sqlite3_db_config()] interface will return a
2064 ** non-zero [error code] if a discontinued or unsupported configuration option
2065 ** is invoked.
2067 ** <dl>
2068 ** <dt>SQLITE_DBCONFIG_LOOKASIDE</dt>
2069 ** <dd> ^This option takes three additional arguments that determine the
2070 ** [lookaside memory allocator] configuration for the [database connection].
2071 ** ^The first argument (the third parameter to [sqlite3_db_config()] is a
2072 ** pointer to a memory buffer to use for lookaside memory.
2073 ** ^The first argument after the SQLITE_DBCONFIG_LOOKASIDE verb
2074 ** may be NULL in which case SQLite will allocate the
2075 ** lookaside buffer itself using [sqlite3_malloc()]. ^The second argument is the
2076 ** size of each lookaside buffer slot. ^The third argument is the number of
2077 ** slots. The size of the buffer in the first argument must be greater than
2078 ** or equal to the product of the second and third arguments. The buffer
2079 ** must be aligned to an 8-byte boundary. ^If the second argument to
2080 ** SQLITE_DBCONFIG_LOOKASIDE is not a multiple of 8, it is internally
2081 ** rounded down to the next smaller multiple of 8. ^(The lookaside memory
2082 ** configuration for a database connection can only be changed when that
2083 ** connection is not currently using lookaside memory, or in other words
2084 ** when the "current value" returned by
2085 ** [sqlite3_db_status](D,[SQLITE_CONFIG_LOOKASIDE],...) is zero.
2086 ** Any attempt to change the lookaside memory configuration when lookaside
2087 ** memory is in use leaves the configuration unchanged and returns
2088 ** [SQLITE_BUSY].)^</dd>
2090 ** <dt>SQLITE_DBCONFIG_ENABLE_FKEY</dt>
2091 ** <dd> ^This option is used to enable or disable the enforcement of
2092 ** [foreign key constraints]. There should be two additional arguments.
2093 ** The first argument is an integer which is 0 to disable FK enforcement,
2094 ** positive to enable FK enforcement or negative to leave FK enforcement
2095 ** unchanged. The second parameter is a pointer to an integer into which
2096 ** is written 0 or 1 to indicate whether FK enforcement is off or on
2097 ** following this call. The second parameter may be a NULL pointer, in
2098 ** which case the FK enforcement setting is not reported back. </dd>
2100 ** <dt>SQLITE_DBCONFIG_ENABLE_TRIGGER</dt>
2101 ** <dd> ^This option is used to enable or disable [CREATE TRIGGER | triggers].
2102 ** There should be two additional arguments.
2103 ** The first argument is an integer which is 0 to disable triggers,
2104 ** positive to enable triggers or negative to leave the setting unchanged.
2105 ** The second parameter is a pointer to an integer into which
2106 ** is written 0 or 1 to indicate whether triggers are disabled or enabled
2107 ** following this call. The second parameter may be a NULL pointer, in
2108 ** which case the trigger setting is not reported back. </dd>
2110 ** </dl>
2112 #define SQLITE_DBCONFIG_LOOKASIDE 1001 /* void* int int */
2113 #define SQLITE_DBCONFIG_ENABLE_FKEY 1002 /* int int* */
2114 #define SQLITE_DBCONFIG_ENABLE_TRIGGER 1003 /* int int* */
2118 ** CAPI3REF: Enable Or Disable Extended Result Codes
2120 ** ^The sqlite3_extended_result_codes() routine enables or disables the
2121 ** [extended result codes] feature of SQLite. ^The extended result
2122 ** codes are disabled by default for historical compatibility.
2124 SQLITE_API int sqlite3_extended_result_codes(sqlite3*, int onoff);
2127 ** CAPI3REF: Last Insert Rowid
2129 ** ^Each entry in an SQLite table has a unique 64-bit signed
2130 ** integer key called the [ROWID | "rowid"]. ^The rowid is always available
2131 ** as an undeclared column named ROWID, OID, or _ROWID_ as long as those
2132 ** names are not also used by explicitly declared columns. ^If
2133 ** the table has a column of type [INTEGER PRIMARY KEY] then that column
2134 ** is another alias for the rowid.
2136 ** ^This routine returns the [rowid] of the most recent
2137 ** successful [INSERT] into the database from the [database connection]
2138 ** in the first argument. ^As of SQLite version 3.7.7, this routines
2139 ** records the last insert rowid of both ordinary tables and [virtual tables].
2140 ** ^If no successful [INSERT]s
2141 ** have ever occurred on that database connection, zero is returned.
2143 ** ^(If an [INSERT] occurs within a trigger or within a [virtual table]
2144 ** method, then this routine will return the [rowid] of the inserted
2145 ** row as long as the trigger or virtual table method is running.
2146 ** But once the trigger or virtual table method ends, the value returned
2147 ** by this routine reverts to what it was before the trigger or virtual
2148 ** table method began.)^
2150 ** ^An [INSERT] that fails due to a constraint violation is not a
2151 ** successful [INSERT] and does not change the value returned by this
2152 ** routine. ^Thus INSERT OR FAIL, INSERT OR IGNORE, INSERT OR ROLLBACK,
2153 ** and INSERT OR ABORT make no changes to the return value of this
2154 ** routine when their insertion fails. ^(When INSERT OR REPLACE
2155 ** encounters a constraint violation, it does not fail. The
2156 ** INSERT continues to completion after deleting rows that caused
2157 ** the constraint problem so INSERT OR REPLACE will always change
2158 ** the return value of this interface.)^
2160 ** ^For the purposes of this routine, an [INSERT] is considered to
2161 ** be successful even if it is subsequently rolled back.
2163 ** This function is accessible to SQL statements via the
2164 ** [last_insert_rowid() SQL function].
2166 ** If a separate thread performs a new [INSERT] on the same
2167 ** database connection while the [sqlite3_last_insert_rowid()]
2168 ** function is running and thus changes the last insert [rowid],
2169 ** then the value returned by [sqlite3_last_insert_rowid()] is
2170 ** unpredictable and might not equal either the old or the new
2171 ** last insert [rowid].
2173 SQLITE_API sqlite3_int64 sqlite3_last_insert_rowid(sqlite3*);
2176 ** CAPI3REF: Count The Number Of Rows Modified
2178 ** ^This function returns the number of database rows that were changed
2179 ** or inserted or deleted by the most recently completed SQL statement
2180 ** on the [database connection] specified by the first parameter.
2181 ** ^(Only changes that are directly specified by the [INSERT], [UPDATE],
2182 ** or [DELETE] statement are counted. Auxiliary changes caused by
2183 ** triggers or [foreign key actions] are not counted.)^ Use the
2184 ** [sqlite3_total_changes()] function to find the total number of changes
2185 ** including changes caused by triggers and foreign key actions.
2187 ** ^Changes to a view that are simulated by an [INSTEAD OF trigger]
2188 ** are not counted. Only real table changes are counted.
2190 ** ^(A "row change" is a change to a single row of a single table
2191 ** caused by an INSERT, DELETE, or UPDATE statement. Rows that
2192 ** are changed as side effects of [REPLACE] constraint resolution,
2193 ** rollback, ABORT processing, [DROP TABLE], or by any other
2194 ** mechanisms do not count as direct row changes.)^
2196 ** A "trigger context" is a scope of execution that begins and
2197 ** ends with the script of a [CREATE TRIGGER | trigger].
2198 ** Most SQL statements are
2199 ** evaluated outside of any trigger. This is the "top level"
2200 ** trigger context. If a trigger fires from the top level, a
2201 ** new trigger context is entered for the duration of that one
2202 ** trigger. Subtriggers create subcontexts for their duration.
2204 ** ^Calling [sqlite3_exec()] or [sqlite3_step()] recursively does
2205 ** not create a new trigger context.
2207 ** ^This function returns the number of direct row changes in the
2208 ** most recent INSERT, UPDATE, or DELETE statement within the same
2209 ** trigger context.
2211 ** ^Thus, when called from the top level, this function returns the
2212 ** number of changes in the most recent INSERT, UPDATE, or DELETE
2213 ** that also occurred at the top level. ^(Within the body of a trigger,
2214 ** the sqlite3_changes() interface can be called to find the number of
2215 ** changes in the most recently completed INSERT, UPDATE, or DELETE
2216 ** statement within the body of the same trigger.
2217 ** However, the number returned does not include changes
2218 ** caused by subtriggers since those have their own context.)^
2220 ** See also the [sqlite3_total_changes()] interface, the
2221 ** [count_changes pragma], and the [changes() SQL function].
2223 ** If a separate thread makes changes on the same database connection
2224 ** while [sqlite3_changes()] is running then the value returned
2225 ** is unpredictable and not meaningful.
2227 SQLITE_API int sqlite3_changes(sqlite3*);
2230 ** CAPI3REF: Total Number Of Rows Modified
2232 ** ^This function returns the number of row changes caused by [INSERT],
2233 ** [UPDATE] or [DELETE] statements since the [database connection] was opened.
2234 ** ^(The count returned by sqlite3_total_changes() includes all changes
2235 ** from all [CREATE TRIGGER | trigger] contexts and changes made by
2236 ** [foreign key actions]. However,
2237 ** the count does not include changes used to implement [REPLACE] constraints,
2238 ** do rollbacks or ABORT processing, or [DROP TABLE] processing. The
2239 ** count does not include rows of views that fire an [INSTEAD OF trigger],
2240 ** though if the INSTEAD OF trigger makes changes of its own, those changes
2241 ** are counted.)^
2242 ** ^The sqlite3_total_changes() function counts the changes as soon as
2243 ** the statement that makes them is completed (when the statement handle
2244 ** is passed to [sqlite3_reset()] or [sqlite3_finalize()]).
2246 ** See also the [sqlite3_changes()] interface, the
2247 ** [count_changes pragma], and the [total_changes() SQL function].
2249 ** If a separate thread makes changes on the same database connection
2250 ** while [sqlite3_total_changes()] is running then the value
2251 ** returned is unpredictable and not meaningful.
2253 SQLITE_API int sqlite3_total_changes(sqlite3*);
2256 ** CAPI3REF: Interrupt A Long-Running Query
2258 ** ^This function causes any pending database operation to abort and
2259 ** return at its earliest opportunity. This routine is typically
2260 ** called in response to a user action such as pressing "Cancel"
2261 ** or Ctrl-C where the user wants a long query operation to halt
2262 ** immediately.
2264 ** ^It is safe to call this routine from a thread different from the
2265 ** thread that is currently running the database operation. But it
2266 ** is not safe to call this routine with a [database connection] that
2267 ** is closed or might close before sqlite3_interrupt() returns.
2269 ** ^If an SQL operation is very nearly finished at the time when
2270 ** sqlite3_interrupt() is called, then it might not have an opportunity
2271 ** to be interrupted and might continue to completion.
2273 ** ^An SQL operation that is interrupted will return [SQLITE_INTERRUPT].
2274 ** ^If the interrupted SQL operation is an INSERT, UPDATE, or DELETE
2275 ** that is inside an explicit transaction, then the entire transaction
2276 ** will be rolled back automatically.
2278 ** ^The sqlite3_interrupt(D) call is in effect until all currently running
2279 ** SQL statements on [database connection] D complete. ^Any new SQL statements
2280 ** that are started after the sqlite3_interrupt() call and before the
2281 ** running statements reaches zero are interrupted as if they had been
2282 ** running prior to the sqlite3_interrupt() call. ^New SQL statements
2283 ** that are started after the running statement count reaches zero are
2284 ** not effected by the sqlite3_interrupt().
2285 ** ^A call to sqlite3_interrupt(D) that occurs when there are no running
2286 ** SQL statements is a no-op and has no effect on SQL statements
2287 ** that are started after the sqlite3_interrupt() call returns.
2289 ** If the database connection closes while [sqlite3_interrupt()]
2290 ** is running then bad things will likely happen.
2292 SQLITE_API void sqlite3_interrupt(sqlite3*);
2295 ** CAPI3REF: Determine If An SQL Statement Is Complete
2297 ** These routines are useful during command-line input to determine if the
2298 ** currently entered text seems to form a complete SQL statement or
2299 ** if additional input is needed before sending the text into
2300 ** SQLite for parsing. ^These routines return 1 if the input string
2301 ** appears to be a complete SQL statement. ^A statement is judged to be
2302 ** complete if it ends with a semicolon token and is not a prefix of a
2303 ** well-formed CREATE TRIGGER statement. ^Semicolons that are embedded within
2304 ** string literals or quoted identifier names or comments are not
2305 ** independent tokens (they are part of the token in which they are
2306 ** embedded) and thus do not count as a statement terminator. ^Whitespace
2307 ** and comments that follow the final semicolon are ignored.
2309 ** ^These routines return 0 if the statement is incomplete. ^If a
2310 ** memory allocation fails, then SQLITE_NOMEM is returned.
2312 ** ^These routines do not parse the SQL statements thus
2313 ** will not detect syntactically incorrect SQL.
2315 ** ^(If SQLite has not been initialized using [sqlite3_initialize()] prior
2316 ** to invoking sqlite3_complete16() then sqlite3_initialize() is invoked
2317 ** automatically by sqlite3_complete16(). If that initialization fails,
2318 ** then the return value from sqlite3_complete16() will be non-zero
2319 ** regardless of whether or not the input SQL is complete.)^
2321 ** The input to [sqlite3_complete()] must be a zero-terminated
2322 ** UTF-8 string.
2324 ** The input to [sqlite3_complete16()] must be a zero-terminated
2325 ** UTF-16 string in native byte order.
2327 SQLITE_API int sqlite3_complete(const char *sql);
2328 SQLITE_API int sqlite3_complete16(const void *sql);
2331 ** CAPI3REF: Register A Callback To Handle SQLITE_BUSY Errors
2333 ** ^This routine sets a callback function that might be invoked whenever
2334 ** an attempt is made to open a database table that another thread
2335 ** or process has locked.
2337 ** ^If the busy callback is NULL, then [SQLITE_BUSY] or [SQLITE_IOERR_BLOCKED]
2338 ** is returned immediately upon encountering the lock. ^If the busy callback
2339 ** is not NULL, then the callback might be invoked with two arguments.
2341 ** ^The first argument to the busy handler is a copy of the void* pointer which
2342 ** is the third argument to sqlite3_busy_handler(). ^The second argument to
2343 ** the busy handler callback is the number of times that the busy handler has
2344 ** been invoked for this locking event. ^If the
2345 ** busy callback returns 0, then no additional attempts are made to
2346 ** access the database and [SQLITE_BUSY] or [SQLITE_IOERR_BLOCKED] is returned.
2347 ** ^If the callback returns non-zero, then another attempt
2348 ** is made to open the database for reading and the cycle repeats.
2350 ** The presence of a busy handler does not guarantee that it will be invoked
2351 ** when there is lock contention. ^If SQLite determines that invoking the busy
2352 ** handler could result in a deadlock, it will go ahead and return [SQLITE_BUSY]
2353 ** or [SQLITE_IOERR_BLOCKED] instead of invoking the busy handler.
2354 ** Consider a scenario where one process is holding a read lock that
2355 ** it is trying to promote to a reserved lock and
2356 ** a second process is holding a reserved lock that it is trying
2357 ** to promote to an exclusive lock. The first process cannot proceed
2358 ** because it is blocked by the second and the second process cannot
2359 ** proceed because it is blocked by the first. If both processes
2360 ** invoke the busy handlers, neither will make any progress. Therefore,
2361 ** SQLite returns [SQLITE_BUSY] for the first process, hoping that this
2362 ** will induce the first process to release its read lock and allow
2363 ** the second process to proceed.
2365 ** ^The default busy callback is NULL.
2367 ** ^The [SQLITE_BUSY] error is converted to [SQLITE_IOERR_BLOCKED]
2368 ** when SQLite is in the middle of a large transaction where all the
2369 ** changes will not fit into the in-memory cache. SQLite will
2370 ** already hold a RESERVED lock on the database file, but it needs
2371 ** to promote this lock to EXCLUSIVE so that it can spill cache
2372 ** pages into the database file without harm to concurrent
2373 ** readers. ^If it is unable to promote the lock, then the in-memory
2374 ** cache will be left in an inconsistent state and so the error
2375 ** code is promoted from the relatively benign [SQLITE_BUSY] to
2376 ** the more severe [SQLITE_IOERR_BLOCKED]. ^This error code promotion
2377 ** forces an automatic rollback of the changes. See the
2378 ** <a href="/cvstrac/wiki?p=CorruptionFollowingBusyError">
2379 ** CorruptionFollowingBusyError</a> wiki page for a discussion of why
2380 ** this is important.
2382 ** ^(There can only be a single busy handler defined for each
2383 ** [database connection]. Setting a new busy handler clears any
2384 ** previously set handler.)^ ^Note that calling [sqlite3_busy_timeout()]
2385 ** will also set or clear the busy handler.
2387 ** The busy callback should not take any actions which modify the
2388 ** database connection that invoked the busy handler. Any such actions
2389 ** result in undefined behavior.
2391 ** A busy handler must not close the database connection
2392 ** or [prepared statement] that invoked the busy handler.
2394 SQLITE_API int sqlite3_busy_handler(sqlite3*, int(*)(void*,int), void*);
2397 ** CAPI3REF: Set A Busy Timeout
2399 ** ^This routine sets a [sqlite3_busy_handler | busy handler] that sleeps
2400 ** for a specified amount of time when a table is locked. ^The handler
2401 ** will sleep multiple times until at least "ms" milliseconds of sleeping
2402 ** have accumulated. ^After at least "ms" milliseconds of sleeping,
2403 ** the handler returns 0 which causes [sqlite3_step()] to return
2404 ** [SQLITE_BUSY] or [SQLITE_IOERR_BLOCKED].
2406 ** ^Calling this routine with an argument less than or equal to zero
2407 ** turns off all busy handlers.
2409 ** ^(There can only be a single busy handler for a particular
2410 ** [database connection] any any given moment. If another busy handler
2411 ** was defined (using [sqlite3_busy_handler()]) prior to calling
2412 ** this routine, that other busy handler is cleared.)^
2414 SQLITE_API int sqlite3_busy_timeout(sqlite3*, int ms);
2417 ** CAPI3REF: Convenience Routines For Running Queries
2419 ** This is a legacy interface that is preserved for backwards compatibility.
2420 ** Use of this interface is not recommended.
2422 ** Definition: A <b>result table</b> is memory data structure created by the
2423 ** [sqlite3_get_table()] interface. A result table records the
2424 ** complete query results from one or more queries.
2426 ** The table conceptually has a number of rows and columns. But
2427 ** these numbers are not part of the result table itself. These
2428 ** numbers are obtained separately. Let N be the number of rows
2429 ** and M be the number of columns.
2431 ** A result table is an array of pointers to zero-terminated UTF-8 strings.
2432 ** There are (N+1)*M elements in the array. The first M pointers point
2433 ** to zero-terminated strings that contain the names of the columns.
2434 ** The remaining entries all point to query results. NULL values result
2435 ** in NULL pointers. All other values are in their UTF-8 zero-terminated
2436 ** string representation as returned by [sqlite3_column_text()].
2438 ** A result table might consist of one or more memory allocations.
2439 ** It is not safe to pass a result table directly to [sqlite3_free()].
2440 ** A result table should be deallocated using [sqlite3_free_table()].
2442 ** ^(As an example of the result table format, suppose a query result
2443 ** is as follows:
2445 ** <blockquote><pre>
2446 ** Name | Age
2447 ** -----------------------
2448 ** Alice | 43
2449 ** Bob | 28
2450 ** Cindy | 21
2451 ** </pre></blockquote>
2453 ** There are two column (M==2) and three rows (N==3). Thus the
2454 ** result table has 8 entries. Suppose the result table is stored
2455 ** in an array names azResult. Then azResult holds this content:
2457 ** <blockquote><pre>
2458 ** azResult&#91;0] = "Name";
2459 ** azResult&#91;1] = "Age";
2460 ** azResult&#91;2] = "Alice";
2461 ** azResult&#91;3] = "43";
2462 ** azResult&#91;4] = "Bob";
2463 ** azResult&#91;5] = "28";
2464 ** azResult&#91;6] = "Cindy";
2465 ** azResult&#91;7] = "21";
2466 ** </pre></blockquote>)^
2468 ** ^The sqlite3_get_table() function evaluates one or more
2469 ** semicolon-separated SQL statements in the zero-terminated UTF-8
2470 ** string of its 2nd parameter and returns a result table to the
2471 ** pointer given in its 3rd parameter.
2473 ** After the application has finished with the result from sqlite3_get_table(),
2474 ** it must pass the result table pointer to sqlite3_free_table() in order to
2475 ** release the memory that was malloced. Because of the way the
2476 ** [sqlite3_malloc()] happens within sqlite3_get_table(), the calling
2477 ** function must not try to call [sqlite3_free()] directly. Only
2478 ** [sqlite3_free_table()] is able to release the memory properly and safely.
2480 ** The sqlite3_get_table() interface is implemented as a wrapper around
2481 ** [sqlite3_exec()]. The sqlite3_get_table() routine does not have access
2482 ** to any internal data structures of SQLite. It uses only the public
2483 ** interface defined here. As a consequence, errors that occur in the
2484 ** wrapper layer outside of the internal [sqlite3_exec()] call are not
2485 ** reflected in subsequent calls to [sqlite3_errcode()] or
2486 ** [sqlite3_errmsg()].
2488 SQLITE_API int sqlite3_get_table(
2489 sqlite3 *db, /* An open database */
2490 const char *zSql, /* SQL to be evaluated */
2491 char ***pazResult, /* Results of the query */
2492 int *pnRow, /* Number of result rows written here */
2493 int *pnColumn, /* Number of result columns written here */
2494 char **pzErrmsg /* Error msg written here */
2496 SQLITE_API void sqlite3_free_table(char **result);
2499 ** CAPI3REF: Formatted String Printing Functions
2501 ** These routines are work-alikes of the "printf()" family of functions
2502 ** from the standard C library.
2504 ** ^The sqlite3_mprintf() and sqlite3_vmprintf() routines write their
2505 ** results into memory obtained from [sqlite3_malloc()].
2506 ** The strings returned by these two routines should be
2507 ** released by [sqlite3_free()]. ^Both routines return a
2508 ** NULL pointer if [sqlite3_malloc()] is unable to allocate enough
2509 ** memory to hold the resulting string.
2511 ** ^(The sqlite3_snprintf() routine is similar to "snprintf()" from
2512 ** the standard C library. The result is written into the
2513 ** buffer supplied as the second parameter whose size is given by
2514 ** the first parameter. Note that the order of the
2515 ** first two parameters is reversed from snprintf().)^ This is an
2516 ** historical accident that cannot be fixed without breaking
2517 ** backwards compatibility. ^(Note also that sqlite3_snprintf()
2518 ** returns a pointer to its buffer instead of the number of
2519 ** characters actually written into the buffer.)^ We admit that
2520 ** the number of characters written would be a more useful return
2521 ** value but we cannot change the implementation of sqlite3_snprintf()
2522 ** now without breaking compatibility.
2524 ** ^As long as the buffer size is greater than zero, sqlite3_snprintf()
2525 ** guarantees that the buffer is always zero-terminated. ^The first
2526 ** parameter "n" is the total size of the buffer, including space for
2527 ** the zero terminator. So the longest string that can be completely
2528 ** written will be n-1 characters.
2530 ** ^The sqlite3_vsnprintf() routine is a varargs version of sqlite3_snprintf().
2532 ** These routines all implement some additional formatting
2533 ** options that are useful for constructing SQL statements.
2534 ** All of the usual printf() formatting options apply. In addition, there
2535 ** is are "%q", "%Q", and "%z" options.
2537 ** ^(The %q option works like %s in that it substitutes a null-terminated
2538 ** string from the argument list. But %q also doubles every '\'' character.
2539 ** %q is designed for use inside a string literal.)^ By doubling each '\''
2540 ** character it escapes that character and allows it to be inserted into
2541 ** the string.
2543 ** For example, assume the string variable zText contains text as follows:
2545 ** <blockquote><pre>
2546 ** char *zText = "It's a happy day!";
2547 ** </pre></blockquote>
2549 ** One can use this text in an SQL statement as follows:
2551 ** <blockquote><pre>
2552 ** char *zSQL = sqlite3_mprintf("INSERT INTO table VALUES('%q')", zText);
2553 ** sqlite3_exec(db, zSQL, 0, 0, 0);
2554 ** sqlite3_free(zSQL);
2555 ** </pre></blockquote>
2557 ** Because the %q format string is used, the '\'' character in zText
2558 ** is escaped and the SQL generated is as follows:
2560 ** <blockquote><pre>
2561 ** INSERT INTO table1 VALUES('It''s a happy day!')
2562 ** </pre></blockquote>
2564 ** This is correct. Had we used %s instead of %q, the generated SQL
2565 ** would have looked like this:
2567 ** <blockquote><pre>
2568 ** INSERT INTO table1 VALUES('It's a happy day!');
2569 ** </pre></blockquote>
2571 ** This second example is an SQL syntax error. As a general rule you should
2572 ** always use %q instead of %s when inserting text into a string literal.
2574 ** ^(The %Q option works like %q except it also adds single quotes around
2575 ** the outside of the total string. Additionally, if the parameter in the
2576 ** argument list is a NULL pointer, %Q substitutes the text "NULL" (without
2577 ** single quotes).)^ So, for example, one could say:
2579 ** <blockquote><pre>
2580 ** char *zSQL = sqlite3_mprintf("INSERT INTO table VALUES(%Q)", zText);
2581 ** sqlite3_exec(db, zSQL, 0, 0, 0);
2582 ** sqlite3_free(zSQL);
2583 ** </pre></blockquote>
2585 ** The code above will render a correct SQL statement in the zSQL
2586 ** variable even if the zText variable is a NULL pointer.
2588 ** ^(The "%z" formatting option works like "%s" but with the
2589 ** addition that after the string has been read and copied into
2590 ** the result, [sqlite3_free()] is called on the input string.)^
2592 SQLITE_API char *sqlite3_mprintf(const char*,...);
2593 SQLITE_API char *sqlite3_vmprintf(const char*, va_list);
2594 SQLITE_API char *sqlite3_snprintf(int,char*,const char*, ...);
2595 SQLITE_API char *sqlite3_vsnprintf(int,char*,const char*, va_list);
2598 ** CAPI3REF: Memory Allocation Subsystem
2600 ** The SQLite core uses these three routines for all of its own
2601 ** internal memory allocation needs. "Core" in the previous sentence
2602 ** does not include operating-system specific VFS implementation. The
2603 ** Windows VFS uses native malloc() and free() for some operations.
2605 ** ^The sqlite3_malloc() routine returns a pointer to a block
2606 ** of memory at least N bytes in length, where N is the parameter.
2607 ** ^If sqlite3_malloc() is unable to obtain sufficient free
2608 ** memory, it returns a NULL pointer. ^If the parameter N to
2609 ** sqlite3_malloc() is zero or negative then sqlite3_malloc() returns
2610 ** a NULL pointer.
2612 ** ^Calling sqlite3_free() with a pointer previously returned
2613 ** by sqlite3_malloc() or sqlite3_realloc() releases that memory so
2614 ** that it might be reused. ^The sqlite3_free() routine is
2615 ** a no-op if is called with a NULL pointer. Passing a NULL pointer
2616 ** to sqlite3_free() is harmless. After being freed, memory
2617 ** should neither be read nor written. Even reading previously freed
2618 ** memory might result in a segmentation fault or other severe error.
2619 ** Memory corruption, a segmentation fault, or other severe error
2620 ** might result if sqlite3_free() is called with a non-NULL pointer that
2621 ** was not obtained from sqlite3_malloc() or sqlite3_realloc().
2623 ** ^(The sqlite3_realloc() interface attempts to resize a
2624 ** prior memory allocation to be at least N bytes, where N is the
2625 ** second parameter. The memory allocation to be resized is the first
2626 ** parameter.)^ ^ If the first parameter to sqlite3_realloc()
2627 ** is a NULL pointer then its behavior is identical to calling
2628 ** sqlite3_malloc(N) where N is the second parameter to sqlite3_realloc().
2629 ** ^If the second parameter to sqlite3_realloc() is zero or
2630 ** negative then the behavior is exactly the same as calling
2631 ** sqlite3_free(P) where P is the first parameter to sqlite3_realloc().
2632 ** ^sqlite3_realloc() returns a pointer to a memory allocation
2633 ** of at least N bytes in size or NULL if sufficient memory is unavailable.
2634 ** ^If M is the size of the prior allocation, then min(N,M) bytes
2635 ** of the prior allocation are copied into the beginning of buffer returned
2636 ** by sqlite3_realloc() and the prior allocation is freed.
2637 ** ^If sqlite3_realloc() returns NULL, then the prior allocation
2638 ** is not freed.
2640 ** ^The memory returned by sqlite3_malloc() and sqlite3_realloc()
2641 ** is always aligned to at least an 8 byte boundary, or to a
2642 ** 4 byte boundary if the [SQLITE_4_BYTE_ALIGNED_MALLOC] compile-time
2643 ** option is used.
2645 ** In SQLite version 3.5.0 and 3.5.1, it was possible to define
2646 ** the SQLITE_OMIT_MEMORY_ALLOCATION which would cause the built-in
2647 ** implementation of these routines to be omitted. That capability
2648 ** is no longer provided. Only built-in memory allocators can be used.
2650 ** The Windows OS interface layer calls
2651 ** the system malloc() and free() directly when converting
2652 ** filenames between the UTF-8 encoding used by SQLite
2653 ** and whatever filename encoding is used by the particular Windows
2654 ** installation. Memory allocation errors are detected, but
2655 ** they are reported back as [SQLITE_CANTOPEN] or
2656 ** [SQLITE_IOERR] rather than [SQLITE_NOMEM].
2658 ** The pointer arguments to [sqlite3_free()] and [sqlite3_realloc()]
2659 ** must be either NULL or else pointers obtained from a prior
2660 ** invocation of [sqlite3_malloc()] or [sqlite3_realloc()] that have
2661 ** not yet been released.
2663 ** The application must not read or write any part of
2664 ** a block of memory after it has been released using
2665 ** [sqlite3_free()] or [sqlite3_realloc()].
2667 SQLITE_API void *sqlite3_malloc(int);
2668 SQLITE_API void *sqlite3_realloc(void*, int);
2669 SQLITE_API void sqlite3_free(void*);
2672 ** CAPI3REF: Memory Allocator Statistics
2674 ** SQLite provides these two interfaces for reporting on the status
2675 ** of the [sqlite3_malloc()], [sqlite3_free()], and [sqlite3_realloc()]
2676 ** routines, which form the built-in memory allocation subsystem.
2678 ** ^The [sqlite3_memory_used()] routine returns the number of bytes
2679 ** of memory currently outstanding (malloced but not freed).
2680 ** ^The [sqlite3_memory_highwater()] routine returns the maximum
2681 ** value of [sqlite3_memory_used()] since the high-water mark
2682 ** was last reset. ^The values returned by [sqlite3_memory_used()] and
2683 ** [sqlite3_memory_highwater()] include any overhead
2684 ** added by SQLite in its implementation of [sqlite3_malloc()],
2685 ** but not overhead added by the any underlying system library
2686 ** routines that [sqlite3_malloc()] may call.
2688 ** ^The memory high-water mark is reset to the current value of
2689 ** [sqlite3_memory_used()] if and only if the parameter to
2690 ** [sqlite3_memory_highwater()] is true. ^The value returned
2691 ** by [sqlite3_memory_highwater(1)] is the high-water mark
2692 ** prior to the reset.
2694 SQLITE_API sqlite3_int64 sqlite3_memory_used(void);
2695 SQLITE_API sqlite3_int64 sqlite3_memory_highwater(int resetFlag);
2698 ** CAPI3REF: Pseudo-Random Number Generator
2700 ** SQLite contains a high-quality pseudo-random number generator (PRNG) used to
2701 ** select random [ROWID | ROWIDs] when inserting new records into a table that
2702 ** already uses the largest possible [ROWID]. The PRNG is also used for
2703 ** the build-in random() and randomblob() SQL functions. This interface allows
2704 ** applications to access the same PRNG for other purposes.
2706 ** ^A call to this routine stores N bytes of randomness into buffer P.
2708 ** ^The first time this routine is invoked (either internally or by
2709 ** the application) the PRNG is seeded using randomness obtained
2710 ** from the xRandomness method of the default [sqlite3_vfs] object.
2711 ** ^On all subsequent invocations, the pseudo-randomness is generated
2712 ** internally and without recourse to the [sqlite3_vfs] xRandomness
2713 ** method.
2715 SQLITE_API void sqlite3_randomness(int N, void *P);
2718 ** CAPI3REF: Compile-Time Authorization Callbacks
2720 ** ^This routine registers an authorizer callback with a particular
2721 ** [database connection], supplied in the first argument.
2722 ** ^The authorizer callback is invoked as SQL statements are being compiled
2723 ** by [sqlite3_prepare()] or its variants [sqlite3_prepare_v2()],
2724 ** [sqlite3_prepare16()] and [sqlite3_prepare16_v2()]. ^At various
2725 ** points during the compilation process, as logic is being created
2726 ** to perform various actions, the authorizer callback is invoked to
2727 ** see if those actions are allowed. ^The authorizer callback should
2728 ** return [SQLITE_OK] to allow the action, [SQLITE_IGNORE] to disallow the
2729 ** specific action but allow the SQL statement to continue to be
2730 ** compiled, or [SQLITE_DENY] to cause the entire SQL statement to be
2731 ** rejected with an error. ^If the authorizer callback returns
2732 ** any value other than [SQLITE_IGNORE], [SQLITE_OK], or [SQLITE_DENY]
2733 ** then the [sqlite3_prepare_v2()] or equivalent call that triggered
2734 ** the authorizer will fail with an error message.
2736 ** When the callback returns [SQLITE_OK], that means the operation
2737 ** requested is ok. ^When the callback returns [SQLITE_DENY], the
2738 ** [sqlite3_prepare_v2()] or equivalent call that triggered the
2739 ** authorizer will fail with an error message explaining that
2740 ** access is denied.
2742 ** ^The first parameter to the authorizer callback is a copy of the third
2743 ** parameter to the sqlite3_set_authorizer() interface. ^The second parameter
2744 ** to the callback is an integer [SQLITE_COPY | action code] that specifies
2745 ** the particular action to be authorized. ^The third through sixth parameters
2746 ** to the callback are zero-terminated strings that contain additional
2747 ** details about the action to be authorized.
2749 ** ^If the action code is [SQLITE_READ]
2750 ** and the callback returns [SQLITE_IGNORE] then the
2751 ** [prepared statement] statement is constructed to substitute
2752 ** a NULL value in place of the table column that would have
2753 ** been read if [SQLITE_OK] had been returned. The [SQLITE_IGNORE]
2754 ** return can be used to deny an untrusted user access to individual
2755 ** columns of a table.
2756 ** ^If the action code is [SQLITE_DELETE] and the callback returns
2757 ** [SQLITE_IGNORE] then the [DELETE] operation proceeds but the
2758 ** [truncate optimization] is disabled and all rows are deleted individually.
2760 ** An authorizer is used when [sqlite3_prepare | preparing]
2761 ** SQL statements from an untrusted source, to ensure that the SQL statements
2762 ** do not try to access data they are not allowed to see, or that they do not
2763 ** try to execute malicious statements that damage the database. For
2764 ** example, an application may allow a user to enter arbitrary
2765 ** SQL queries for evaluation by a database. But the application does
2766 ** not want the user to be able to make arbitrary changes to the
2767 ** database. An authorizer could then be put in place while the
2768 ** user-entered SQL is being [sqlite3_prepare | prepared] that
2769 ** disallows everything except [SELECT] statements.
2771 ** Applications that need to process SQL from untrusted sources
2772 ** might also consider lowering resource limits using [sqlite3_limit()]
2773 ** and limiting database size using the [max_page_count] [PRAGMA]
2774 ** in addition to using an authorizer.
2776 ** ^(Only a single authorizer can be in place on a database connection
2777 ** at a time. Each call to sqlite3_set_authorizer overrides the
2778 ** previous call.)^ ^Disable the authorizer by installing a NULL callback.
2779 ** The authorizer is disabled by default.
2781 ** The authorizer callback must not do anything that will modify
2782 ** the database connection that invoked the authorizer callback.
2783 ** Note that [sqlite3_prepare_v2()] and [sqlite3_step()] both modify their
2784 ** database connections for the meaning of "modify" in this paragraph.
2786 ** ^When [sqlite3_prepare_v2()] is used to prepare a statement, the
2787 ** statement might be re-prepared during [sqlite3_step()] due to a
2788 ** schema change. Hence, the application should ensure that the
2789 ** correct authorizer callback remains in place during the [sqlite3_step()].
2791 ** ^Note that the authorizer callback is invoked only during
2792 ** [sqlite3_prepare()] or its variants. Authorization is not
2793 ** performed during statement evaluation in [sqlite3_step()], unless
2794 ** as stated in the previous paragraph, sqlite3_step() invokes
2795 ** sqlite3_prepare_v2() to reprepare a statement after a schema change.
2797 SQLITE_API int sqlite3_set_authorizer(
2798 sqlite3*,
2799 int (*xAuth)(void*,int,const char*,const char*,const char*,const char*),
2800 void *pUserData
2804 ** CAPI3REF: Authorizer Return Codes
2806 ** The [sqlite3_set_authorizer | authorizer callback function] must
2807 ** return either [SQLITE_OK] or one of these two constants in order
2808 ** to signal SQLite whether or not the action is permitted. See the
2809 ** [sqlite3_set_authorizer | authorizer documentation] for additional
2810 ** information.
2812 ** Note that SQLITE_IGNORE is also used as a [SQLITE_ROLLBACK | return code]
2813 ** from the [sqlite3_vtab_on_conflict()] interface.
2815 #define SQLITE_DENY 1 /* Abort the SQL statement with an error */
2816 #define SQLITE_IGNORE 2 /* Don't allow access, but don't generate an error */
2819 ** CAPI3REF: Authorizer Action Codes
2821 ** The [sqlite3_set_authorizer()] interface registers a callback function
2822 ** that is invoked to authorize certain SQL statement actions. The
2823 ** second parameter to the callback is an integer code that specifies
2824 ** what action is being authorized. These are the integer action codes that
2825 ** the authorizer callback may be passed.
2827 ** These action code values signify what kind of operation is to be
2828 ** authorized. The 3rd and 4th parameters to the authorization
2829 ** callback function will be parameters or NULL depending on which of these
2830 ** codes is used as the second parameter. ^(The 5th parameter to the
2831 ** authorizer callback is the name of the database ("main", "temp",
2832 ** etc.) if applicable.)^ ^The 6th parameter to the authorizer callback
2833 ** is the name of the inner-most trigger or view that is responsible for
2834 ** the access attempt or NULL if this access attempt is directly from
2835 ** top-level SQL code.
2837 /******************************************* 3rd ************ 4th ***********/
2838 #define SQLITE_CREATE_INDEX 1 /* Index Name Table Name */
2839 #define SQLITE_CREATE_TABLE 2 /* Table Name NULL */
2840 #define SQLITE_CREATE_TEMP_INDEX 3 /* Index Name Table Name */
2841 #define SQLITE_CREATE_TEMP_TABLE 4 /* Table Name NULL */
2842 #define SQLITE_CREATE_TEMP_TRIGGER 5 /* Trigger Name Table Name */
2843 #define SQLITE_CREATE_TEMP_VIEW 6 /* View Name NULL */
2844 #define SQLITE_CREATE_TRIGGER 7 /* Trigger Name Table Name */
2845 #define SQLITE_CREATE_VIEW 8 /* View Name NULL */
2846 #define SQLITE_DELETE 9 /* Table Name NULL */
2847 #define SQLITE_DROP_INDEX 10 /* Index Name Table Name */
2848 #define SQLITE_DROP_TABLE 11 /* Table Name NULL */
2849 #define SQLITE_DROP_TEMP_INDEX 12 /* Index Name Table Name */
2850 #define SQLITE_DROP_TEMP_TABLE 13 /* Table Name NULL */
2851 #define SQLITE_DROP_TEMP_TRIGGER 14 /* Trigger Name Table Name */
2852 #define SQLITE_DROP_TEMP_VIEW 15 /* View Name NULL */
2853 #define SQLITE_DROP_TRIGGER 16 /* Trigger Name Table Name */
2854 #define SQLITE_DROP_VIEW 17 /* View Name NULL */
2855 #define SQLITE_INSERT 18 /* Table Name NULL */
2856 #define SQLITE_PRAGMA 19 /* Pragma Name 1st arg or NULL */
2857 #define SQLITE_READ 20 /* Table Name Column Name */
2858 #define SQLITE_SELECT 21 /* NULL NULL */
2859 #define SQLITE_TRANSACTION 22 /* Operation NULL */
2860 #define SQLITE_UPDATE 23 /* Table Name Column Name */
2861 #define SQLITE_ATTACH 24 /* Filename NULL */
2862 #define SQLITE_DETACH 25 /* Database Name NULL */
2863 #define SQLITE_ALTER_TABLE 26 /* Database Name Table Name */
2864 #define SQLITE_REINDEX 27 /* Index Name NULL */
2865 #define SQLITE_ANALYZE 28 /* Table Name NULL */
2866 #define SQLITE_CREATE_VTABLE 29 /* Table Name Module Name */
2867 #define SQLITE_DROP_VTABLE 30 /* Table Name Module Name */
2868 #define SQLITE_FUNCTION 31 /* NULL Function Name */
2869 #define SQLITE_SAVEPOINT 32 /* Operation Savepoint Name */
2870 #define SQLITE_COPY 0 /* No longer used */
2873 ** CAPI3REF: Tracing And Profiling Functions
2875 ** These routines register callback functions that can be used for
2876 ** tracing and profiling the execution of SQL statements.
2878 ** ^The callback function registered by sqlite3_trace() is invoked at
2879 ** various times when an SQL statement is being run by [sqlite3_step()].
2880 ** ^The sqlite3_trace() callback is invoked with a UTF-8 rendering of the
2881 ** SQL statement text as the statement first begins executing.
2882 ** ^(Additional sqlite3_trace() callbacks might occur
2883 ** as each triggered subprogram is entered. The callbacks for triggers
2884 ** contain a UTF-8 SQL comment that identifies the trigger.)^
2886 ** ^The callback function registered by sqlite3_profile() is invoked
2887 ** as each SQL statement finishes. ^The profile callback contains
2888 ** the original statement text and an estimate of wall-clock time
2889 ** of how long that statement took to run. ^The profile callback
2890 ** time is in units of nanoseconds, however the current implementation
2891 ** is only capable of millisecond resolution so the six least significant
2892 ** digits in the time are meaningless. Future versions of SQLite
2893 ** might provide greater resolution on the profiler callback. The
2894 ** sqlite3_profile() function is considered experimental and is
2895 ** subject to change in future versions of SQLite.
2897 SQLITE_API void *sqlite3_trace(sqlite3*, void(*xTrace)(void*,const char*), void*);
2898 SQLITE_API SQLITE_EXPERIMENTAL void *sqlite3_profile(sqlite3*,
2899 void(*xProfile)(void*,const char*,sqlite3_uint64), void*);
2902 ** CAPI3REF: Query Progress Callbacks
2904 ** ^The sqlite3_progress_handler(D,N,X,P) interface causes the callback
2905 ** function X to be invoked periodically during long running calls to
2906 ** [sqlite3_exec()], [sqlite3_step()] and [sqlite3_get_table()] for
2907 ** database connection D. An example use for this
2908 ** interface is to keep a GUI updated during a large query.
2910 ** ^The parameter P is passed through as the only parameter to the
2911 ** callback function X. ^The parameter N is the number of
2912 ** [virtual machine instructions] that are evaluated between successive
2913 ** invocations of the callback X.
2915 ** ^Only a single progress handler may be defined at one time per
2916 ** [database connection]; setting a new progress handler cancels the
2917 ** old one. ^Setting parameter X to NULL disables the progress handler.
2918 ** ^The progress handler is also disabled by setting N to a value less
2919 ** than 1.
2921 ** ^If the progress callback returns non-zero, the operation is
2922 ** interrupted. This feature can be used to implement a
2923 ** "Cancel" button on a GUI progress dialog box.
2925 ** The progress handler callback must not do anything that will modify
2926 ** the database connection that invoked the progress handler.
2927 ** Note that [sqlite3_prepare_v2()] and [sqlite3_step()] both modify their
2928 ** database connections for the meaning of "modify" in this paragraph.
2931 SQLITE_API void sqlite3_progress_handler(sqlite3*, int, int(*)(void*), void*);
2934 ** CAPI3REF: Opening A New Database Connection
2936 ** ^These routines open an SQLite database file as specified by the
2937 ** filename argument. ^The filename argument is interpreted as UTF-8 for
2938 ** sqlite3_open() and sqlite3_open_v2() and as UTF-16 in the native byte
2939 ** order for sqlite3_open16(). ^(A [database connection] handle is usually
2940 ** returned in *ppDb, even if an error occurs. The only exception is that
2941 ** if SQLite is unable to allocate memory to hold the [sqlite3] object,
2942 ** a NULL will be written into *ppDb instead of a pointer to the [sqlite3]
2943 ** object.)^ ^(If the database is opened (and/or created) successfully, then
2944 ** [SQLITE_OK] is returned. Otherwise an [error code] is returned.)^ ^The
2945 ** [sqlite3_errmsg()] or [sqlite3_errmsg16()] routines can be used to obtain
2946 ** an English language description of the error following a failure of any
2947 ** of the sqlite3_open() routines.
2949 ** ^The default encoding for the database will be UTF-8 if
2950 ** sqlite3_open() or sqlite3_open_v2() is called and
2951 ** UTF-16 in the native byte order if sqlite3_open16() is used.
2953 ** Whether or not an error occurs when it is opened, resources
2954 ** associated with the [database connection] handle should be released by
2955 ** passing it to [sqlite3_close()] when it is no longer required.
2957 ** The sqlite3_open_v2() interface works like sqlite3_open()
2958 ** except that it accepts two additional parameters for additional control
2959 ** over the new database connection. ^(The flags parameter to
2960 ** sqlite3_open_v2() can take one of
2961 ** the following three values, optionally combined with the
2962 ** [SQLITE_OPEN_NOMUTEX], [SQLITE_OPEN_FULLMUTEX], [SQLITE_OPEN_SHAREDCACHE],
2963 ** [SQLITE_OPEN_PRIVATECACHE], and/or [SQLITE_OPEN_URI] flags:)^
2965 ** <dl>
2966 ** ^(<dt>[SQLITE_OPEN_READONLY]</dt>
2967 ** <dd>The database is opened in read-only mode. If the database does not
2968 ** already exist, an error is returned.</dd>)^
2970 ** ^(<dt>[SQLITE_OPEN_READWRITE]</dt>
2971 ** <dd>The database is opened for reading and writing if possible, or reading
2972 ** only if the file is write protected by the operating system. In either
2973 ** case the database must already exist, otherwise an error is returned.</dd>)^
2975 ** ^(<dt>[SQLITE_OPEN_READWRITE] | [SQLITE_OPEN_CREATE]</dt>
2976 ** <dd>The database is opened for reading and writing, and is created if
2977 ** it does not already exist. This is the behavior that is always used for
2978 ** sqlite3_open() and sqlite3_open16().</dd>)^
2979 ** </dl>
2981 ** If the 3rd parameter to sqlite3_open_v2() is not one of the
2982 ** combinations shown above optionally combined with other
2983 ** [SQLITE_OPEN_READONLY | SQLITE_OPEN_* bits]
2984 ** then the behavior is undefined.
2986 ** ^If the [SQLITE_OPEN_NOMUTEX] flag is set, then the database connection
2987 ** opens in the multi-thread [threading mode] as long as the single-thread
2988 ** mode has not been set at compile-time or start-time. ^If the
2989 ** [SQLITE_OPEN_FULLMUTEX] flag is set then the database connection opens
2990 ** in the serialized [threading mode] unless single-thread was
2991 ** previously selected at compile-time or start-time.
2992 ** ^The [SQLITE_OPEN_SHAREDCACHE] flag causes the database connection to be
2993 ** eligible to use [shared cache mode], regardless of whether or not shared
2994 ** cache is enabled using [sqlite3_enable_shared_cache()]. ^The
2995 ** [SQLITE_OPEN_PRIVATECACHE] flag causes the database connection to not
2996 ** participate in [shared cache mode] even if it is enabled.
2998 ** ^The fourth parameter to sqlite3_open_v2() is the name of the
2999 ** [sqlite3_vfs] object that defines the operating system interface that
3000 ** the new database connection should use. ^If the fourth parameter is
3001 ** a NULL pointer then the default [sqlite3_vfs] object is used.
3003 ** ^If the filename is ":memory:", then a private, temporary in-memory database
3004 ** is created for the connection. ^This in-memory database will vanish when
3005 ** the database connection is closed. Future versions of SQLite might
3006 ** make use of additional special filenames that begin with the ":" character.
3007 ** It is recommended that when a database filename actually does begin with
3008 ** a ":" character you should prefix the filename with a pathname such as
3009 ** "./" to avoid ambiguity.
3011 ** ^If the filename is an empty string, then a private, temporary
3012 ** on-disk database will be created. ^This private database will be
3013 ** automatically deleted as soon as the database connection is closed.
3015 ** [[URI filenames in sqlite3_open()]] <h3>URI Filenames</h3>
3017 ** ^If [URI filename] interpretation is enabled, and the filename argument
3018 ** begins with "file:", then the filename is interpreted as a URI. ^URI
3019 ** filename interpretation is enabled if the [SQLITE_OPEN_URI] flag is
3020 ** set in the fourth argument to sqlite3_open_v2(), or if it has
3021 ** been enabled globally using the [SQLITE_CONFIG_URI] option with the
3022 ** [sqlite3_config()] method or by the [SQLITE_USE_URI] compile-time option.
3023 ** As of SQLite version 3.7.7, URI filename interpretation is turned off
3024 ** by default, but future releases of SQLite might enable URI filename
3025 ** interpretation by default. See "[URI filenames]" for additional
3026 ** information.
3028 ** URI filenames are parsed according to RFC 3986. ^If the URI contains an
3029 ** authority, then it must be either an empty string or the string
3030 ** "localhost". ^If the authority is not an empty string or "localhost", an
3031 ** error is returned to the caller. ^The fragment component of a URI, if
3032 ** present, is ignored.
3034 ** ^SQLite uses the path component of the URI as the name of the disk file
3035 ** which contains the database. ^If the path begins with a '/' character,
3036 ** then it is interpreted as an absolute path. ^If the path does not begin
3037 ** with a '/' (meaning that the authority section is omitted from the URI)
3038 ** then the path is interpreted as a relative path.
3039 ** ^On windows, the first component of an absolute path
3040 ** is a drive specification (e.g. "C:").
3042 ** [[core URI query parameters]]
3043 ** The query component of a URI may contain parameters that are interpreted
3044 ** either by SQLite itself, or by a [VFS | custom VFS implementation].
3045 ** SQLite interprets the following three query parameters:
3047 ** <ul>
3048 ** <li> <b>vfs</b>: ^The "vfs" parameter may be used to specify the name of
3049 ** a VFS object that provides the operating system interface that should
3050 ** be used to access the database file on disk. ^If this option is set to
3051 ** an empty string the default VFS object is used. ^Specifying an unknown
3052 ** VFS is an error. ^If sqlite3_open_v2() is used and the vfs option is
3053 ** present, then the VFS specified by the option takes precedence over
3054 ** the value passed as the fourth parameter to sqlite3_open_v2().
3056 ** <li> <b>mode</b>: ^(The mode parameter may be set to either "ro", "rw" or
3057 ** "rwc". Attempting to set it to any other value is an error)^.
3058 ** ^If "ro" is specified, then the database is opened for read-only
3059 ** access, just as if the [SQLITE_OPEN_READONLY] flag had been set in the
3060 ** third argument to sqlite3_prepare_v2(). ^If the mode option is set to
3061 ** "rw", then the database is opened for read-write (but not create)
3062 ** access, as if SQLITE_OPEN_READWRITE (but not SQLITE_OPEN_CREATE) had
3063 ** been set. ^Value "rwc" is equivalent to setting both
3064 ** SQLITE_OPEN_READWRITE and SQLITE_OPEN_CREATE. ^If sqlite3_open_v2() is
3065 ** used, it is an error to specify a value for the mode parameter that is
3066 ** less restrictive than that specified by the flags passed as the third
3067 ** parameter.
3069 ** <li> <b>cache</b>: ^The cache parameter may be set to either "shared" or
3070 ** "private". ^Setting it to "shared" is equivalent to setting the
3071 ** SQLITE_OPEN_SHAREDCACHE bit in the flags argument passed to
3072 ** sqlite3_open_v2(). ^Setting the cache parameter to "private" is
3073 ** equivalent to setting the SQLITE_OPEN_PRIVATECACHE bit.
3074 ** ^If sqlite3_open_v2() is used and the "cache" parameter is present in
3075 ** a URI filename, its value overrides any behaviour requested by setting
3076 ** SQLITE_OPEN_PRIVATECACHE or SQLITE_OPEN_SHAREDCACHE flag.
3077 ** </ul>
3079 ** ^Specifying an unknown parameter in the query component of a URI is not an
3080 ** error. Future versions of SQLite might understand additional query
3081 ** parameters. See "[query parameters with special meaning to SQLite]" for
3082 ** additional information.
3084 ** [[URI filename examples]] <h3>URI filename examples</h3>
3086 ** <table border="1" align=center cellpadding=5>
3087 ** <tr><th> URI filenames <th> Results
3088 ** <tr><td> file:data.db <td>
3089 ** Open the file "data.db" in the current directory.
3090 ** <tr><td> file:/home/fred/data.db<br>
3091 ** file:///home/fred/data.db <br>
3092 ** file://localhost/home/fred/data.db <br> <td>
3093 ** Open the database file "/home/fred/data.db".
3094 ** <tr><td> file://darkstar/home/fred/data.db <td>
3095 ** An error. "darkstar" is not a recognized authority.
3096 ** <tr><td style="white-space:nowrap">
3097 ** file:///C:/Documents%20and%20Settings/fred/Desktop/data.db
3098 ** <td> Windows only: Open the file "data.db" on fred's desktop on drive
3099 ** C:. Note that the %20 escaping in this example is not strictly
3100 ** necessary - space characters can be used literally
3101 ** in URI filenames.
3102 ** <tr><td> file:data.db?mode=ro&cache=private <td>
3103 ** Open file "data.db" in the current directory for read-only access.
3104 ** Regardless of whether or not shared-cache mode is enabled by
3105 ** default, use a private cache.
3106 ** <tr><td> file:/home/fred/data.db?vfs=unix-nolock <td>
3107 ** Open file "/home/fred/data.db". Use the special VFS "unix-nolock".
3108 ** <tr><td> file:data.db?mode=readonly <td>
3109 ** An error. "readonly" is not a valid option for the "mode" parameter.
3110 ** </table>
3112 ** ^URI hexadecimal escape sequences (%HH) are supported within the path and
3113 ** query components of a URI. A hexadecimal escape sequence consists of a
3114 ** percent sign - "%" - followed by exactly two hexadecimal digits
3115 ** specifying an octet value. ^Before the path or query components of a
3116 ** URI filename are interpreted, they are encoded using UTF-8 and all
3117 ** hexadecimal escape sequences replaced by a single byte containing the
3118 ** corresponding octet. If this process generates an invalid UTF-8 encoding,
3119 ** the results are undefined.
3121 ** <b>Note to Windows users:</b> The encoding used for the filename argument
3122 ** of sqlite3_open() and sqlite3_open_v2() must be UTF-8, not whatever
3123 ** codepage is currently defined. Filenames containing international
3124 ** characters must be converted to UTF-8 prior to passing them into
3125 ** sqlite3_open() or sqlite3_open_v2().
3127 SQLITE_API int sqlite3_open(
3128 const char *filename, /* Database filename (UTF-8) */
3129 sqlite3 **ppDb /* OUT: SQLite db handle */
3131 SQLITE_API int sqlite3_open16(
3132 const void *filename, /* Database filename (UTF-16) */
3133 sqlite3 **ppDb /* OUT: SQLite db handle */
3135 SQLITE_API int sqlite3_open_v2(
3136 const char *filename, /* Database filename (UTF-8) */
3137 sqlite3 **ppDb, /* OUT: SQLite db handle */
3138 int flags, /* Flags */
3139 const char *zVfs /* Name of VFS module to use */
3143 ** CAPI3REF: Obtain Values For URI Parameters
3145 ** This is a utility routine, useful to VFS implementations, that checks
3146 ** to see if a database file was a URI that contained a specific query
3147 ** parameter, and if so obtains the value of the query parameter.
3149 ** The zFilename argument is the filename pointer passed into the xOpen()
3150 ** method of a VFS implementation. The zParam argument is the name of the
3151 ** query parameter we seek. This routine returns the value of the zParam
3152 ** parameter if it exists. If the parameter does not exist, this routine
3153 ** returns a NULL pointer.
3155 ** If the zFilename argument to this function is not a pointer that SQLite
3156 ** passed into the xOpen VFS method, then the behavior of this routine
3157 ** is undefined and probably undesirable.
3159 SQLITE_API const char *sqlite3_uri_parameter(const char *zFilename, const char *zParam);
3163 ** CAPI3REF: Error Codes And Messages
3165 ** ^The sqlite3_errcode() interface returns the numeric [result code] or
3166 ** [extended result code] for the most recent failed sqlite3_* API call
3167 ** associated with a [database connection]. If a prior API call failed
3168 ** but the most recent API call succeeded, the return value from
3169 ** sqlite3_errcode() is undefined. ^The sqlite3_extended_errcode()
3170 ** interface is the same except that it always returns the
3171 ** [extended result code] even when extended result codes are
3172 ** disabled.
3174 ** ^The sqlite3_errmsg() and sqlite3_errmsg16() return English-language
3175 ** text that describes the error, as either UTF-8 or UTF-16 respectively.
3176 ** ^(Memory to hold the error message string is managed internally.
3177 ** The application does not need to worry about freeing the result.
3178 ** However, the error string might be overwritten or deallocated by
3179 ** subsequent calls to other SQLite interface functions.)^
3181 ** When the serialized [threading mode] is in use, it might be the
3182 ** case that a second error occurs on a separate thread in between
3183 ** the time of the first error and the call to these interfaces.
3184 ** When that happens, the second error will be reported since these
3185 ** interfaces always report the most recent result. To avoid
3186 ** this, each thread can obtain exclusive use of the [database connection] D
3187 ** by invoking [sqlite3_mutex_enter]([sqlite3_db_mutex](D)) before beginning
3188 ** to use D and invoking [sqlite3_mutex_leave]([sqlite3_db_mutex](D)) after
3189 ** all calls to the interfaces listed here are completed.
3191 ** If an interface fails with SQLITE_MISUSE, that means the interface
3192 ** was invoked incorrectly by the application. In that case, the
3193 ** error code and message may or may not be set.
3195 SQLITE_API int sqlite3_errcode(sqlite3 *db);
3196 SQLITE_API int sqlite3_extended_errcode(sqlite3 *db);
3197 SQLITE_API const char *sqlite3_errmsg(sqlite3*);
3198 SQLITE_API const void *sqlite3_errmsg16(sqlite3*);
3201 ** CAPI3REF: SQL Statement Object
3202 ** KEYWORDS: {prepared statement} {prepared statements}
3204 ** An instance of this object represents a single SQL statement.
3205 ** This object is variously known as a "prepared statement" or a
3206 ** "compiled SQL statement" or simply as a "statement".
3208 ** The life of a statement object goes something like this:
3210 ** <ol>
3211 ** <li> Create the object using [sqlite3_prepare_v2()] or a related
3212 ** function.
3213 ** <li> Bind values to [host parameters] using the sqlite3_bind_*()
3214 ** interfaces.
3215 ** <li> Run the SQL by calling [sqlite3_step()] one or more times.
3216 ** <li> Reset the statement using [sqlite3_reset()] then go back
3217 ** to step 2. Do this zero or more times.
3218 ** <li> Destroy the object using [sqlite3_finalize()].
3219 ** </ol>
3221 ** Refer to documentation on individual methods above for additional
3222 ** information.
3224 typedef struct sqlite3_stmt sqlite3_stmt;
3227 ** CAPI3REF: Run-time Limits
3229 ** ^(This interface allows the size of various constructs to be limited
3230 ** on a connection by connection basis. The first parameter is the
3231 ** [database connection] whose limit is to be set or queried. The
3232 ** second parameter is one of the [limit categories] that define a
3233 ** class of constructs to be size limited. The third parameter is the
3234 ** new limit for that construct.)^
3236 ** ^If the new limit is a negative number, the limit is unchanged.
3237 ** ^(For each limit category SQLITE_LIMIT_<i>NAME</i> there is a
3238 ** [limits | hard upper bound]
3239 ** set at compile-time by a C preprocessor macro called
3240 ** [limits | SQLITE_MAX_<i>NAME</i>].
3241 ** (The "_LIMIT_" in the name is changed to "_MAX_".))^
3242 ** ^Attempts to increase a limit above its hard upper bound are
3243 ** silently truncated to the hard upper bound.
3245 ** ^Regardless of whether or not the limit was changed, the
3246 ** [sqlite3_limit()] interface returns the prior value of the limit.
3247 ** ^Hence, to find the current value of a limit without changing it,
3248 ** simply invoke this interface with the third parameter set to -1.
3250 ** Run-time limits are intended for use in applications that manage
3251 ** both their own internal database and also databases that are controlled
3252 ** by untrusted external sources. An example application might be a
3253 ** web browser that has its own databases for storing history and
3254 ** separate databases controlled by JavaScript applications downloaded
3255 ** off the Internet. The internal databases can be given the
3256 ** large, default limits. Databases managed by external sources can
3257 ** be given much smaller limits designed to prevent a denial of service
3258 ** attack. Developers might also want to use the [sqlite3_set_authorizer()]
3259 ** interface to further control untrusted SQL. The size of the database
3260 ** created by an untrusted script can be contained using the
3261 ** [max_page_count] [PRAGMA].
3263 ** New run-time limit categories may be added in future releases.
3265 SQLITE_API int sqlite3_limit(sqlite3*, int id, int newVal);
3268 ** CAPI3REF: Run-Time Limit Categories
3269 ** KEYWORDS: {limit category} {*limit categories}
3271 ** These constants define various performance limits
3272 ** that can be lowered at run-time using [sqlite3_limit()].
3273 ** The synopsis of the meanings of the various limits is shown below.
3274 ** Additional information is available at [limits | Limits in SQLite].
3276 ** <dl>
3277 ** [[SQLITE_LIMIT_LENGTH]] ^(<dt>SQLITE_LIMIT_LENGTH</dt>
3278 ** <dd>The maximum size of any string or BLOB or table row, in bytes.<dd>)^
3280 ** [[SQLITE_LIMIT_SQL_LENGTH]] ^(<dt>SQLITE_LIMIT_SQL_LENGTH</dt>
3281 ** <dd>The maximum length of an SQL statement, in bytes.</dd>)^
3283 ** [[SQLITE_LIMIT_COLUMN]] ^(<dt>SQLITE_LIMIT_COLUMN</dt>
3284 ** <dd>The maximum number of columns in a table definition or in the
3285 ** result set of a [SELECT] or the maximum number of columns in an index
3286 ** or in an ORDER BY or GROUP BY clause.</dd>)^
3288 ** [[SQLITE_LIMIT_EXPR_DEPTH]] ^(<dt>SQLITE_LIMIT_EXPR_DEPTH</dt>
3289 ** <dd>The maximum depth of the parse tree on any expression.</dd>)^
3291 ** [[SQLITE_LIMIT_COMPOUND_SELECT]] ^(<dt>SQLITE_LIMIT_COMPOUND_SELECT</dt>
3292 ** <dd>The maximum number of terms in a compound SELECT statement.</dd>)^
3294 ** [[SQLITE_LIMIT_VDBE_OP]] ^(<dt>SQLITE_LIMIT_VDBE_OP</dt>
3295 ** <dd>The maximum number of instructions in a virtual machine program
3296 ** used to implement an SQL statement. This limit is not currently
3297 ** enforced, though that might be added in some future release of
3298 ** SQLite.</dd>)^
3300 ** [[SQLITE_LIMIT_FUNCTION_ARG]] ^(<dt>SQLITE_LIMIT_FUNCTION_ARG</dt>
3301 ** <dd>The maximum number of arguments on a function.</dd>)^
3303 ** [[SQLITE_LIMIT_ATTACHED]] ^(<dt>SQLITE_LIMIT_ATTACHED</dt>
3304 ** <dd>The maximum number of [ATTACH | attached databases].)^</dd>
3306 ** [[SQLITE_LIMIT_LIKE_PATTERN_LENGTH]]
3307 ** ^(<dt>SQLITE_LIMIT_LIKE_PATTERN_LENGTH</dt>
3308 ** <dd>The maximum length of the pattern argument to the [LIKE] or
3309 ** [GLOB] operators.</dd>)^
3311 ** [[SQLITE_LIMIT_VARIABLE_NUMBER]]
3312 ** ^(<dt>SQLITE_LIMIT_VARIABLE_NUMBER</dt>
3313 ** <dd>The maximum index number of any [parameter] in an SQL statement.)^
3315 ** [[SQLITE_LIMIT_TRIGGER_DEPTH]] ^(<dt>SQLITE_LIMIT_TRIGGER_DEPTH</dt>
3316 ** <dd>The maximum depth of recursion for triggers.</dd>)^
3317 ** </dl>
3319 #define SQLITE_LIMIT_LENGTH 0
3320 #define SQLITE_LIMIT_SQL_LENGTH 1
3321 #define SQLITE_LIMIT_COLUMN 2
3322 #define SQLITE_LIMIT_EXPR_DEPTH 3
3323 #define SQLITE_LIMIT_COMPOUND_SELECT 4
3324 #define SQLITE_LIMIT_VDBE_OP 5
3325 #define SQLITE_LIMIT_FUNCTION_ARG 6
3326 #define SQLITE_LIMIT_ATTACHED 7
3327 #define SQLITE_LIMIT_LIKE_PATTERN_LENGTH 8
3328 #define SQLITE_LIMIT_VARIABLE_NUMBER 9
3329 #define SQLITE_LIMIT_TRIGGER_DEPTH 10
3332 ** CAPI3REF: Compiling An SQL Statement
3333 ** KEYWORDS: {SQL statement compiler}
3335 ** To execute an SQL query, it must first be compiled into a byte-code
3336 ** program using one of these routines.
3338 ** The first argument, "db", is a [database connection] obtained from a
3339 ** prior successful call to [sqlite3_open()], [sqlite3_open_v2()] or
3340 ** [sqlite3_open16()]. The database connection must not have been closed.
3342 ** The second argument, "zSql", is the statement to be compiled, encoded
3343 ** as either UTF-8 or UTF-16. The sqlite3_prepare() and sqlite3_prepare_v2()
3344 ** interfaces use UTF-8, and sqlite3_prepare16() and sqlite3_prepare16_v2()
3345 ** use UTF-16.
3347 ** ^If the nByte argument is less than zero, then zSql is read up to the
3348 ** first zero terminator. ^If nByte is non-negative, then it is the maximum
3349 ** number of bytes read from zSql. ^When nByte is non-negative, the
3350 ** zSql string ends at either the first '\000' or '\u0000' character or
3351 ** the nByte-th byte, whichever comes first. If the caller knows
3352 ** that the supplied string is nul-terminated, then there is a small
3353 ** performance advantage to be gained by passing an nByte parameter that
3354 ** is equal to the number of bytes in the input string <i>including</i>
3355 ** the nul-terminator bytes.
3357 ** ^If pzTail is not NULL then *pzTail is made to point to the first byte
3358 ** past the end of the first SQL statement in zSql. These routines only
3359 ** compile the first statement in zSql, so *pzTail is left pointing to
3360 ** what remains uncompiled.
3362 ** ^*ppStmt is left pointing to a compiled [prepared statement] that can be
3363 ** executed using [sqlite3_step()]. ^If there is an error, *ppStmt is set
3364 ** to NULL. ^If the input text contains no SQL (if the input is an empty
3365 ** string or a comment) then *ppStmt is set to NULL.
3366 ** The calling procedure is responsible for deleting the compiled
3367 ** SQL statement using [sqlite3_finalize()] after it has finished with it.
3368 ** ppStmt may not be NULL.
3370 ** ^On success, the sqlite3_prepare() family of routines return [SQLITE_OK];
3371 ** otherwise an [error code] is returned.
3373 ** The sqlite3_prepare_v2() and sqlite3_prepare16_v2() interfaces are
3374 ** recommended for all new programs. The two older interfaces are retained
3375 ** for backwards compatibility, but their use is discouraged.
3376 ** ^In the "v2" interfaces, the prepared statement
3377 ** that is returned (the [sqlite3_stmt] object) contains a copy of the
3378 ** original SQL text. This causes the [sqlite3_step()] interface to
3379 ** behave differently in three ways:
3381 ** <ol>
3382 ** <li>
3383 ** ^If the database schema changes, instead of returning [SQLITE_SCHEMA] as it
3384 ** always used to do, [sqlite3_step()] will automatically recompile the SQL
3385 ** statement and try to run it again.
3386 ** </li>
3388 ** <li>
3389 ** ^When an error occurs, [sqlite3_step()] will return one of the detailed
3390 ** [error codes] or [extended error codes]. ^The legacy behavior was that
3391 ** [sqlite3_step()] would only return a generic [SQLITE_ERROR] result code
3392 ** and the application would have to make a second call to [sqlite3_reset()]
3393 ** in order to find the underlying cause of the problem. With the "v2" prepare
3394 ** interfaces, the underlying reason for the error is returned immediately.
3395 ** </li>
3397 ** <li>
3398 ** ^If the specific value bound to [parameter | host parameter] in the
3399 ** WHERE clause might influence the choice of query plan for a statement,
3400 ** then the statement will be automatically recompiled, as if there had been
3401 ** a schema change, on the first [sqlite3_step()] call following any change
3402 ** to the [sqlite3_bind_text | bindings] of that [parameter].
3403 ** ^The specific value of WHERE-clause [parameter] might influence the
3404 ** choice of query plan if the parameter is the left-hand side of a [LIKE]
3405 ** or [GLOB] operator or if the parameter is compared to an indexed column
3406 ** and the [SQLITE_ENABLE_STAT2] compile-time option is enabled.
3407 ** the
3408 ** </li>
3409 ** </ol>
3411 SQLITE_API int sqlite3_prepare(
3412 sqlite3 *db, /* Database handle */
3413 const char *zSql, /* SQL statement, UTF-8 encoded */
3414 int nByte, /* Maximum length of zSql in bytes. */
3415 sqlite3_stmt **ppStmt, /* OUT: Statement handle */
3416 const char **pzTail /* OUT: Pointer to unused portion of zSql */
3418 SQLITE_API int sqlite3_prepare_v2(
3419 sqlite3 *db, /* Database handle */
3420 const char *zSql, /* SQL statement, UTF-8 encoded */
3421 int nByte, /* Maximum length of zSql in bytes. */
3422 sqlite3_stmt **ppStmt, /* OUT: Statement handle */
3423 const char **pzTail /* OUT: Pointer to unused portion of zSql */
3425 SQLITE_API int sqlite3_prepare16(
3426 sqlite3 *db, /* Database handle */
3427 const void *zSql, /* SQL statement, UTF-16 encoded */
3428 int nByte, /* Maximum length of zSql in bytes. */
3429 sqlite3_stmt **ppStmt, /* OUT: Statement handle */
3430 const void **pzTail /* OUT: Pointer to unused portion of zSql */
3432 SQLITE_API int sqlite3_prepare16_v2(
3433 sqlite3 *db, /* Database handle */
3434 const void *zSql, /* SQL statement, UTF-16 encoded */
3435 int nByte, /* Maximum length of zSql in bytes. */
3436 sqlite3_stmt **ppStmt, /* OUT: Statement handle */
3437 const void **pzTail /* OUT: Pointer to unused portion of zSql */
3441 ** CAPI3REF: Retrieving Statement SQL
3443 ** ^This interface can be used to retrieve a saved copy of the original
3444 ** SQL text used to create a [prepared statement] if that statement was
3445 ** compiled using either [sqlite3_prepare_v2()] or [sqlite3_prepare16_v2()].
3447 SQLITE_API const char *sqlite3_sql(sqlite3_stmt *pStmt);
3450 ** CAPI3REF: Determine If An SQL Statement Writes The Database
3452 ** ^The sqlite3_stmt_readonly(X) interface returns true (non-zero) if
3453 ** and only if the [prepared statement] X makes no direct changes to
3454 ** the content of the database file.
3456 ** Note that [application-defined SQL functions] or
3457 ** [virtual tables] might change the database indirectly as a side effect.
3458 ** ^(For example, if an application defines a function "eval()" that
3459 ** calls [sqlite3_exec()], then the following SQL statement would
3460 ** change the database file through side-effects:
3462 ** <blockquote><pre>
3463 ** SELECT eval('DELETE FROM t1') FROM t2;
3464 ** </pre></blockquote>
3466 ** But because the [SELECT] statement does not change the database file
3467 ** directly, sqlite3_stmt_readonly() would still return true.)^
3469 ** ^Transaction control statements such as [BEGIN], [COMMIT], [ROLLBACK],
3470 ** [SAVEPOINT], and [RELEASE] cause sqlite3_stmt_readonly() to return true,
3471 ** since the statements themselves do not actually modify the database but
3472 ** rather they control the timing of when other statements modify the
3473 ** database. ^The [ATTACH] and [DETACH] statements also cause
3474 ** sqlite3_stmt_readonly() to return true since, while those statements
3475 ** change the configuration of a database connection, they do not make
3476 ** changes to the content of the database files on disk.
3478 SQLITE_API int sqlite3_stmt_readonly(sqlite3_stmt *pStmt);
3481 ** CAPI3REF: Dynamically Typed Value Object
3482 ** KEYWORDS: {protected sqlite3_value} {unprotected sqlite3_value}
3484 ** SQLite uses the sqlite3_value object to represent all values
3485 ** that can be stored in a database table. SQLite uses dynamic typing
3486 ** for the values it stores. ^Values stored in sqlite3_value objects
3487 ** can be integers, floating point values, strings, BLOBs, or NULL.
3489 ** An sqlite3_value object may be either "protected" or "unprotected".
3490 ** Some interfaces require a protected sqlite3_value. Other interfaces
3491 ** will accept either a protected or an unprotected sqlite3_value.
3492 ** Every interface that accepts sqlite3_value arguments specifies
3493 ** whether or not it requires a protected sqlite3_value.
3495 ** The terms "protected" and "unprotected" refer to whether or not
3496 ** a mutex is held. An internal mutex is held for a protected
3497 ** sqlite3_value object but no mutex is held for an unprotected
3498 ** sqlite3_value object. If SQLite is compiled to be single-threaded
3499 ** (with [SQLITE_THREADSAFE=0] and with [sqlite3_threadsafe()] returning 0)
3500 ** or if SQLite is run in one of reduced mutex modes
3501 ** [SQLITE_CONFIG_SINGLETHREAD] or [SQLITE_CONFIG_MULTITHREAD]
3502 ** then there is no distinction between protected and unprotected
3503 ** sqlite3_value objects and they can be used interchangeably. However,
3504 ** for maximum code portability it is recommended that applications
3505 ** still make the distinction between protected and unprotected
3506 ** sqlite3_value objects even when not strictly required.
3508 ** ^The sqlite3_value objects that are passed as parameters into the
3509 ** implementation of [application-defined SQL functions] are protected.
3510 ** ^The sqlite3_value object returned by
3511 ** [sqlite3_column_value()] is unprotected.
3512 ** Unprotected sqlite3_value objects may only be used with
3513 ** [sqlite3_result_value()] and [sqlite3_bind_value()].
3514 ** The [sqlite3_value_blob | sqlite3_value_type()] family of
3515 ** interfaces require protected sqlite3_value objects.
3517 typedef struct Mem sqlite3_value;
3520 ** CAPI3REF: SQL Function Context Object
3522 ** The context in which an SQL function executes is stored in an
3523 ** sqlite3_context object. ^A pointer to an sqlite3_context object
3524 ** is always first parameter to [application-defined SQL functions].
3525 ** The application-defined SQL function implementation will pass this
3526 ** pointer through into calls to [sqlite3_result_int | sqlite3_result()],
3527 ** [sqlite3_aggregate_context()], [sqlite3_user_data()],
3528 ** [sqlite3_context_db_handle()], [sqlite3_get_auxdata()],
3529 ** and/or [sqlite3_set_auxdata()].
3531 typedef struct sqlite3_context sqlite3_context;
3534 ** CAPI3REF: Binding Values To Prepared Statements
3535 ** KEYWORDS: {host parameter} {host parameters} {host parameter name}
3536 ** KEYWORDS: {SQL parameter} {SQL parameters} {parameter binding}
3538 ** ^(In the SQL statement text input to [sqlite3_prepare_v2()] and its variants,
3539 ** literals may be replaced by a [parameter] that matches one of following
3540 ** templates:
3542 ** <ul>
3543 ** <li> ?
3544 ** <li> ?NNN
3545 ** <li> :VVV
3546 ** <li> @VVV
3547 ** <li> $VVV
3548 ** </ul>
3550 ** In the templates above, NNN represents an integer literal,
3551 ** and VVV represents an alphanumeric identifier.)^ ^The values of these
3552 ** parameters (also called "host parameter names" or "SQL parameters")
3553 ** can be set using the sqlite3_bind_*() routines defined here.
3555 ** ^The first argument to the sqlite3_bind_*() routines is always
3556 ** a pointer to the [sqlite3_stmt] object returned from
3557 ** [sqlite3_prepare_v2()] or its variants.
3559 ** ^The second argument is the index of the SQL parameter to be set.
3560 ** ^The leftmost SQL parameter has an index of 1. ^When the same named
3561 ** SQL parameter is used more than once, second and subsequent
3562 ** occurrences have the same index as the first occurrence.
3563 ** ^The index for named parameters can be looked up using the
3564 ** [sqlite3_bind_parameter_index()] API if desired. ^The index
3565 ** for "?NNN" parameters is the value of NNN.
3566 ** ^The NNN value must be between 1 and the [sqlite3_limit()]
3567 ** parameter [SQLITE_LIMIT_VARIABLE_NUMBER] (default value: 999).
3569 ** ^The third argument is the value to bind to the parameter.
3571 ** ^(In those routines that have a fourth argument, its value is the
3572 ** number of bytes in the parameter. To be clear: the value is the
3573 ** number of <u>bytes</u> in the value, not the number of characters.)^
3574 ** ^If the fourth parameter is negative, the length of the string is
3575 ** the number of bytes up to the first zero terminator.
3577 ** ^The fifth argument to sqlite3_bind_blob(), sqlite3_bind_text(), and
3578 ** sqlite3_bind_text16() is a destructor used to dispose of the BLOB or
3579 ** string after SQLite has finished with it. ^The destructor is called
3580 ** to dispose of the BLOB or string even if the call to sqlite3_bind_blob(),
3581 ** sqlite3_bind_text(), or sqlite3_bind_text16() fails.
3582 ** ^If the fifth argument is
3583 ** the special value [SQLITE_STATIC], then SQLite assumes that the
3584 ** information is in static, unmanaged space and does not need to be freed.
3585 ** ^If the fifth argument has the value [SQLITE_TRANSIENT], then
3586 ** SQLite makes its own private copy of the data immediately, before
3587 ** the sqlite3_bind_*() routine returns.
3589 ** ^The sqlite3_bind_zeroblob() routine binds a BLOB of length N that
3590 ** is filled with zeroes. ^A zeroblob uses a fixed amount of memory
3591 ** (just an integer to hold its size) while it is being processed.
3592 ** Zeroblobs are intended to serve as placeholders for BLOBs whose
3593 ** content is later written using
3594 ** [sqlite3_blob_open | incremental BLOB I/O] routines.
3595 ** ^A negative value for the zeroblob results in a zero-length BLOB.
3597 ** ^If any of the sqlite3_bind_*() routines are called with a NULL pointer
3598 ** for the [prepared statement] or with a prepared statement for which
3599 ** [sqlite3_step()] has been called more recently than [sqlite3_reset()],
3600 ** then the call will return [SQLITE_MISUSE]. If any sqlite3_bind_()
3601 ** routine is passed a [prepared statement] that has been finalized, the
3602 ** result is undefined and probably harmful.
3604 ** ^Bindings are not cleared by the [sqlite3_reset()] routine.
3605 ** ^Unbound parameters are interpreted as NULL.
3607 ** ^The sqlite3_bind_* routines return [SQLITE_OK] on success or an
3608 ** [error code] if anything goes wrong.
3609 ** ^[SQLITE_RANGE] is returned if the parameter
3610 ** index is out of range. ^[SQLITE_NOMEM] is returned if malloc() fails.
3612 ** See also: [sqlite3_bind_parameter_count()],
3613 ** [sqlite3_bind_parameter_name()], and [sqlite3_bind_parameter_index()].
3615 SQLITE_API int sqlite3_bind_blob(sqlite3_stmt*, int, const void*, int n, void(*)(void*));
3616 SQLITE_API int sqlite3_bind_double(sqlite3_stmt*, int, double);
3617 SQLITE_API int sqlite3_bind_int(sqlite3_stmt*, int, int);
3618 SQLITE_API int sqlite3_bind_int64(sqlite3_stmt*, int, sqlite3_int64);
3619 SQLITE_API int sqlite3_bind_null(sqlite3_stmt*, int);
3620 SQLITE_API int sqlite3_bind_text(sqlite3_stmt*, int, const char*, int n, void(*)(void*));
3621 SQLITE_API int sqlite3_bind_text16(sqlite3_stmt*, int, const void*, int, void(*)(void*));
3622 SQLITE_API int sqlite3_bind_value(sqlite3_stmt*, int, const sqlite3_value*);
3623 SQLITE_API int sqlite3_bind_zeroblob(sqlite3_stmt*, int, int n);
3626 ** CAPI3REF: Number Of SQL Parameters
3628 ** ^This routine can be used to find the number of [SQL parameters]
3629 ** in a [prepared statement]. SQL parameters are tokens of the
3630 ** form "?", "?NNN", ":AAA", "$AAA", or "@AAA" that serve as
3631 ** placeholders for values that are [sqlite3_bind_blob | bound]
3632 ** to the parameters at a later time.
3634 ** ^(This routine actually returns the index of the largest (rightmost)
3635 ** parameter. For all forms except ?NNN, this will correspond to the
3636 ** number of unique parameters. If parameters of the ?NNN form are used,
3637 ** there may be gaps in the list.)^
3639 ** See also: [sqlite3_bind_blob|sqlite3_bind()],
3640 ** [sqlite3_bind_parameter_name()], and
3641 ** [sqlite3_bind_parameter_index()].
3643 SQLITE_API int sqlite3_bind_parameter_count(sqlite3_stmt*);
3646 ** CAPI3REF: Name Of A Host Parameter
3648 ** ^The sqlite3_bind_parameter_name(P,N) interface returns
3649 ** the name of the N-th [SQL parameter] in the [prepared statement] P.
3650 ** ^(SQL parameters of the form "?NNN" or ":AAA" or "@AAA" or "$AAA"
3651 ** have a name which is the string "?NNN" or ":AAA" or "@AAA" or "$AAA"
3652 ** respectively.
3653 ** In other words, the initial ":" or "$" or "@" or "?"
3654 ** is included as part of the name.)^
3655 ** ^Parameters of the form "?" without a following integer have no name
3656 ** and are referred to as "nameless" or "anonymous parameters".
3658 ** ^The first host parameter has an index of 1, not 0.
3660 ** ^If the value N is out of range or if the N-th parameter is
3661 ** nameless, then NULL is returned. ^The returned string is
3662 ** always in UTF-8 encoding even if the named parameter was
3663 ** originally specified as UTF-16 in [sqlite3_prepare16()] or
3664 ** [sqlite3_prepare16_v2()].
3666 ** See also: [sqlite3_bind_blob|sqlite3_bind()],
3667 ** [sqlite3_bind_parameter_count()], and
3668 ** [sqlite3_bind_parameter_index()].
3670 SQLITE_API const char *sqlite3_bind_parameter_name(sqlite3_stmt*, int);
3673 ** CAPI3REF: Index Of A Parameter With A Given Name
3675 ** ^Return the index of an SQL parameter given its name. ^The
3676 ** index value returned is suitable for use as the second
3677 ** parameter to [sqlite3_bind_blob|sqlite3_bind()]. ^A zero
3678 ** is returned if no matching parameter is found. ^The parameter
3679 ** name must be given in UTF-8 even if the original statement
3680 ** was prepared from UTF-16 text using [sqlite3_prepare16_v2()].
3682 ** See also: [sqlite3_bind_blob|sqlite3_bind()],
3683 ** [sqlite3_bind_parameter_count()], and
3684 ** [sqlite3_bind_parameter_index()].
3686 SQLITE_API int sqlite3_bind_parameter_index(sqlite3_stmt*, const char *zName);
3689 ** CAPI3REF: Reset All Bindings On A Prepared Statement
3691 ** ^Contrary to the intuition of many, [sqlite3_reset()] does not reset
3692 ** the [sqlite3_bind_blob | bindings] on a [prepared statement].
3693 ** ^Use this routine to reset all host parameters to NULL.
3695 SQLITE_API int sqlite3_clear_bindings(sqlite3_stmt*);
3698 ** CAPI3REF: Number Of Columns In A Result Set
3700 ** ^Return the number of columns in the result set returned by the
3701 ** [prepared statement]. ^This routine returns 0 if pStmt is an SQL
3702 ** statement that does not return data (for example an [UPDATE]).
3704 ** See also: [sqlite3_data_count()]
3706 SQLITE_API int sqlite3_column_count(sqlite3_stmt *pStmt);
3709 ** CAPI3REF: Column Names In A Result Set
3711 ** ^These routines return the name assigned to a particular column
3712 ** in the result set of a [SELECT] statement. ^The sqlite3_column_name()
3713 ** interface returns a pointer to a zero-terminated UTF-8 string
3714 ** and sqlite3_column_name16() returns a pointer to a zero-terminated
3715 ** UTF-16 string. ^The first parameter is the [prepared statement]
3716 ** that implements the [SELECT] statement. ^The second parameter is the
3717 ** column number. ^The leftmost column is number 0.
3719 ** ^The returned string pointer is valid until either the [prepared statement]
3720 ** is destroyed by [sqlite3_finalize()] or until the statement is automatically
3721 ** reprepared by the first call to [sqlite3_step()] for a particular run
3722 ** or until the next call to
3723 ** sqlite3_column_name() or sqlite3_column_name16() on the same column.
3725 ** ^If sqlite3_malloc() fails during the processing of either routine
3726 ** (for example during a conversion from UTF-8 to UTF-16) then a
3727 ** NULL pointer is returned.
3729 ** ^The name of a result column is the value of the "AS" clause for
3730 ** that column, if there is an AS clause. If there is no AS clause
3731 ** then the name of the column is unspecified and may change from
3732 ** one release of SQLite to the next.
3734 SQLITE_API const char *sqlite3_column_name(sqlite3_stmt*, int N);
3735 SQLITE_API const void *sqlite3_column_name16(sqlite3_stmt*, int N);
3738 ** CAPI3REF: Source Of Data In A Query Result
3740 ** ^These routines provide a means to determine the database, table, and
3741 ** table column that is the origin of a particular result column in
3742 ** [SELECT] statement.
3743 ** ^The name of the database or table or column can be returned as
3744 ** either a UTF-8 or UTF-16 string. ^The _database_ routines return
3745 ** the database name, the _table_ routines return the table name, and
3746 ** the origin_ routines return the column name.
3747 ** ^The returned string is valid until the [prepared statement] is destroyed
3748 ** using [sqlite3_finalize()] or until the statement is automatically
3749 ** reprepared by the first call to [sqlite3_step()] for a particular run
3750 ** or until the same information is requested
3751 ** again in a different encoding.
3753 ** ^The names returned are the original un-aliased names of the
3754 ** database, table, and column.
3756 ** ^The first argument to these interfaces is a [prepared statement].
3757 ** ^These functions return information about the Nth result column returned by
3758 ** the statement, where N is the second function argument.
3759 ** ^The left-most column is column 0 for these routines.
3761 ** ^If the Nth column returned by the statement is an expression or
3762 ** subquery and is not a column value, then all of these functions return
3763 ** NULL. ^These routine might also return NULL if a memory allocation error
3764 ** occurs. ^Otherwise, they return the name of the attached database, table,
3765 ** or column that query result column was extracted from.
3767 ** ^As with all other SQLite APIs, those whose names end with "16" return
3768 ** UTF-16 encoded strings and the other functions return UTF-8.
3770 ** ^These APIs are only available if the library was compiled with the
3771 ** [SQLITE_ENABLE_COLUMN_METADATA] C-preprocessor symbol.
3773 ** If two or more threads call one or more of these routines against the same
3774 ** prepared statement and column at the same time then the results are
3775 ** undefined.
3777 ** If two or more threads call one or more
3778 ** [sqlite3_column_database_name | column metadata interfaces]
3779 ** for the same [prepared statement] and result column
3780 ** at the same time then the results are undefined.
3782 SQLITE_API const char *sqlite3_column_database_name(sqlite3_stmt*,int);
3783 SQLITE_API const void *sqlite3_column_database_name16(sqlite3_stmt*,int);
3784 SQLITE_API const char *sqlite3_column_table_name(sqlite3_stmt*,int);
3785 SQLITE_API const void *sqlite3_column_table_name16(sqlite3_stmt*,int);
3786 SQLITE_API const char *sqlite3_column_origin_name(sqlite3_stmt*,int);
3787 SQLITE_API const void *sqlite3_column_origin_name16(sqlite3_stmt*,int);
3790 ** CAPI3REF: Declared Datatype Of A Query Result
3792 ** ^(The first parameter is a [prepared statement].
3793 ** If this statement is a [SELECT] statement and the Nth column of the
3794 ** returned result set of that [SELECT] is a table column (not an
3795 ** expression or subquery) then the declared type of the table
3796 ** column is returned.)^ ^If the Nth column of the result set is an
3797 ** expression or subquery, then a NULL pointer is returned.
3798 ** ^The returned string is always UTF-8 encoded.
3800 ** ^(For example, given the database schema:
3802 ** CREATE TABLE t1(c1 VARIANT);
3804 ** and the following statement to be compiled:
3806 ** SELECT c1 + 1, c1 FROM t1;
3808 ** this routine would return the string "VARIANT" for the second result
3809 ** column (i==1), and a NULL pointer for the first result column (i==0).)^
3811 ** ^SQLite uses dynamic run-time typing. ^So just because a column
3812 ** is declared to contain a particular type does not mean that the
3813 ** data stored in that column is of the declared type. SQLite is
3814 ** strongly typed, but the typing is dynamic not static. ^Type
3815 ** is associated with individual values, not with the containers
3816 ** used to hold those values.
3818 SQLITE_API const char *sqlite3_column_decltype(sqlite3_stmt*,int);
3819 SQLITE_API const void *sqlite3_column_decltype16(sqlite3_stmt*,int);
3822 ** CAPI3REF: Evaluate An SQL Statement
3824 ** After a [prepared statement] has been prepared using either
3825 ** [sqlite3_prepare_v2()] or [sqlite3_prepare16_v2()] or one of the legacy
3826 ** interfaces [sqlite3_prepare()] or [sqlite3_prepare16()], this function
3827 ** must be called one or more times to evaluate the statement.
3829 ** The details of the behavior of the sqlite3_step() interface depend
3830 ** on whether the statement was prepared using the newer "v2" interface
3831 ** [sqlite3_prepare_v2()] and [sqlite3_prepare16_v2()] or the older legacy
3832 ** interface [sqlite3_prepare()] and [sqlite3_prepare16()]. The use of the
3833 ** new "v2" interface is recommended for new applications but the legacy
3834 ** interface will continue to be supported.
3836 ** ^In the legacy interface, the return value will be either [SQLITE_BUSY],
3837 ** [SQLITE_DONE], [SQLITE_ROW], [SQLITE_ERROR], or [SQLITE_MISUSE].
3838 ** ^With the "v2" interface, any of the other [result codes] or
3839 ** [extended result codes] might be returned as well.
3841 ** ^[SQLITE_BUSY] means that the database engine was unable to acquire the
3842 ** database locks it needs to do its job. ^If the statement is a [COMMIT]
3843 ** or occurs outside of an explicit transaction, then you can retry the
3844 ** statement. If the statement is not a [COMMIT] and occurs within an
3845 ** explicit transaction then you should rollback the transaction before
3846 ** continuing.
3848 ** ^[SQLITE_DONE] means that the statement has finished executing
3849 ** successfully. sqlite3_step() should not be called again on this virtual
3850 ** machine without first calling [sqlite3_reset()] to reset the virtual
3851 ** machine back to its initial state.
3853 ** ^If the SQL statement being executed returns any data, then [SQLITE_ROW]
3854 ** is returned each time a new row of data is ready for processing by the
3855 ** caller. The values may be accessed using the [column access functions].
3856 ** sqlite3_step() is called again to retrieve the next row of data.
3858 ** ^[SQLITE_ERROR] means that a run-time error (such as a constraint
3859 ** violation) has occurred. sqlite3_step() should not be called again on
3860 ** the VM. More information may be found by calling [sqlite3_errmsg()].
3861 ** ^With the legacy interface, a more specific error code (for example,
3862 ** [SQLITE_INTERRUPT], [SQLITE_SCHEMA], [SQLITE_CORRUPT], and so forth)
3863 ** can be obtained by calling [sqlite3_reset()] on the
3864 ** [prepared statement]. ^In the "v2" interface,
3865 ** the more specific error code is returned directly by sqlite3_step().
3867 ** [SQLITE_MISUSE] means that the this routine was called inappropriately.
3868 ** Perhaps it was called on a [prepared statement] that has
3869 ** already been [sqlite3_finalize | finalized] or on one that had
3870 ** previously returned [SQLITE_ERROR] or [SQLITE_DONE]. Or it could
3871 ** be the case that the same database connection is being used by two or
3872 ** more threads at the same moment in time.
3874 ** For all versions of SQLite up to and including 3.6.23.1, a call to
3875 ** [sqlite3_reset()] was required after sqlite3_step() returned anything
3876 ** other than [SQLITE_ROW] before any subsequent invocation of
3877 ** sqlite3_step(). Failure to reset the prepared statement using
3878 ** [sqlite3_reset()] would result in an [SQLITE_MISUSE] return from
3879 ** sqlite3_step(). But after version 3.6.23.1, sqlite3_step() began
3880 ** calling [sqlite3_reset()] automatically in this circumstance rather
3881 ** than returning [SQLITE_MISUSE]. This is not considered a compatibility
3882 ** break because any application that ever receives an SQLITE_MISUSE error
3883 ** is broken by definition. The [SQLITE_OMIT_AUTORESET] compile-time option
3884 ** can be used to restore the legacy behavior.
3886 ** <b>Goofy Interface Alert:</b> In the legacy interface, the sqlite3_step()
3887 ** API always returns a generic error code, [SQLITE_ERROR], following any
3888 ** error other than [SQLITE_BUSY] and [SQLITE_MISUSE]. You must call
3889 ** [sqlite3_reset()] or [sqlite3_finalize()] in order to find one of the
3890 ** specific [error codes] that better describes the error.
3891 ** We admit that this is a goofy design. The problem has been fixed
3892 ** with the "v2" interface. If you prepare all of your SQL statements
3893 ** using either [sqlite3_prepare_v2()] or [sqlite3_prepare16_v2()] instead
3894 ** of the legacy [sqlite3_prepare()] and [sqlite3_prepare16()] interfaces,
3895 ** then the more specific [error codes] are returned directly
3896 ** by sqlite3_step(). The use of the "v2" interface is recommended.
3898 SQLITE_API int sqlite3_step(sqlite3_stmt*);
3901 ** CAPI3REF: Number of columns in a result set
3903 ** ^The sqlite3_data_count(P) interface returns the number of columns in the
3904 ** current row of the result set of [prepared statement] P.
3905 ** ^If prepared statement P does not have results ready to return
3906 ** (via calls to the [sqlite3_column_int | sqlite3_column_*()] of
3907 ** interfaces) then sqlite3_data_count(P) returns 0.
3908 ** ^The sqlite3_data_count(P) routine also returns 0 if P is a NULL pointer.
3910 ** See also: [sqlite3_column_count()]
3912 SQLITE_API int sqlite3_data_count(sqlite3_stmt *pStmt);
3915 ** CAPI3REF: Fundamental Datatypes
3916 ** KEYWORDS: SQLITE_TEXT
3918 ** ^(Every value in SQLite has one of five fundamental datatypes:
3920 ** <ul>
3921 ** <li> 64-bit signed integer
3922 ** <li> 64-bit IEEE floating point number
3923 ** <li> string
3924 ** <li> BLOB
3925 ** <li> NULL
3926 ** </ul>)^
3928 ** These constants are codes for each of those types.
3930 ** Note that the SQLITE_TEXT constant was also used in SQLite version 2
3931 ** for a completely different meaning. Software that links against both
3932 ** SQLite version 2 and SQLite version 3 should use SQLITE3_TEXT, not
3933 ** SQLITE_TEXT.
3935 #define SQLITE_INTEGER 1
3936 #define SQLITE_FLOAT 2
3937 #define SQLITE_BLOB 4
3938 #define SQLITE_NULL 5
3939 #ifdef SQLITE_TEXT
3940 # undef SQLITE_TEXT
3941 #else
3942 # define SQLITE_TEXT 3
3943 #endif
3944 #define SQLITE3_TEXT 3
3947 ** CAPI3REF: Result Values From A Query
3948 ** KEYWORDS: {column access functions}
3950 ** These routines form the "result set" interface.
3952 ** ^These routines return information about a single column of the current
3953 ** result row of a query. ^In every case the first argument is a pointer
3954 ** to the [prepared statement] that is being evaluated (the [sqlite3_stmt*]
3955 ** that was returned from [sqlite3_prepare_v2()] or one of its variants)
3956 ** and the second argument is the index of the column for which information
3957 ** should be returned. ^The leftmost column of the result set has the index 0.
3958 ** ^The number of columns in the result can be determined using
3959 ** [sqlite3_column_count()].
3961 ** If the SQL statement does not currently point to a valid row, or if the
3962 ** column index is out of range, the result is undefined.
3963 ** These routines may only be called when the most recent call to
3964 ** [sqlite3_step()] has returned [SQLITE_ROW] and neither
3965 ** [sqlite3_reset()] nor [sqlite3_finalize()] have been called subsequently.
3966 ** If any of these routines are called after [sqlite3_reset()] or
3967 ** [sqlite3_finalize()] or after [sqlite3_step()] has returned
3968 ** something other than [SQLITE_ROW], the results are undefined.
3969 ** If [sqlite3_step()] or [sqlite3_reset()] or [sqlite3_finalize()]
3970 ** are called from a different thread while any of these routines
3971 ** are pending, then the results are undefined.
3973 ** ^The sqlite3_column_type() routine returns the
3974 ** [SQLITE_INTEGER | datatype code] for the initial data type
3975 ** of the result column. ^The returned value is one of [SQLITE_INTEGER],
3976 ** [SQLITE_FLOAT], [SQLITE_TEXT], [SQLITE_BLOB], or [SQLITE_NULL]. The value
3977 ** returned by sqlite3_column_type() is only meaningful if no type
3978 ** conversions have occurred as described below. After a type conversion,
3979 ** the value returned by sqlite3_column_type() is undefined. Future
3980 ** versions of SQLite may change the behavior of sqlite3_column_type()
3981 ** following a type conversion.
3983 ** ^If the result is a BLOB or UTF-8 string then the sqlite3_column_bytes()
3984 ** routine returns the number of bytes in that BLOB or string.
3985 ** ^If the result is a UTF-16 string, then sqlite3_column_bytes() converts
3986 ** the string to UTF-8 and then returns the number of bytes.
3987 ** ^If the result is a numeric value then sqlite3_column_bytes() uses
3988 ** [sqlite3_snprintf()] to convert that value to a UTF-8 string and returns
3989 ** the number of bytes in that string.
3990 ** ^If the result is NULL, then sqlite3_column_bytes() returns zero.
3992 ** ^If the result is a BLOB or UTF-16 string then the sqlite3_column_bytes16()
3993 ** routine returns the number of bytes in that BLOB or string.
3994 ** ^If the result is a UTF-8 string, then sqlite3_column_bytes16() converts
3995 ** the string to UTF-16 and then returns the number of bytes.
3996 ** ^If the result is a numeric value then sqlite3_column_bytes16() uses
3997 ** [sqlite3_snprintf()] to convert that value to a UTF-16 string and returns
3998 ** the number of bytes in that string.
3999 ** ^If the result is NULL, then sqlite3_column_bytes16() returns zero.
4001 ** ^The values returned by [sqlite3_column_bytes()] and
4002 ** [sqlite3_column_bytes16()] do not include the zero terminators at the end
4003 ** of the string. ^For clarity: the values returned by
4004 ** [sqlite3_column_bytes()] and [sqlite3_column_bytes16()] are the number of
4005 ** bytes in the string, not the number of characters.
4007 ** ^Strings returned by sqlite3_column_text() and sqlite3_column_text16(),
4008 ** even empty strings, are always zero terminated. ^The return
4009 ** value from sqlite3_column_blob() for a zero-length BLOB is a NULL pointer.
4011 ** ^The object returned by [sqlite3_column_value()] is an
4012 ** [unprotected sqlite3_value] object. An unprotected sqlite3_value object
4013 ** may only be used with [sqlite3_bind_value()] and [sqlite3_result_value()].
4014 ** If the [unprotected sqlite3_value] object returned by
4015 ** [sqlite3_column_value()] is used in any other way, including calls
4016 ** to routines like [sqlite3_value_int()], [sqlite3_value_text()],
4017 ** or [sqlite3_value_bytes()], then the behavior is undefined.
4019 ** These routines attempt to convert the value where appropriate. ^For
4020 ** example, if the internal representation is FLOAT and a text result
4021 ** is requested, [sqlite3_snprintf()] is used internally to perform the
4022 ** conversion automatically. ^(The following table details the conversions
4023 ** that are applied:
4025 ** <blockquote>
4026 ** <table border="1">
4027 ** <tr><th> Internal<br>Type <th> Requested<br>Type <th> Conversion
4029 ** <tr><td> NULL <td> INTEGER <td> Result is 0
4030 ** <tr><td> NULL <td> FLOAT <td> Result is 0.0
4031 ** <tr><td> NULL <td> TEXT <td> Result is NULL pointer
4032 ** <tr><td> NULL <td> BLOB <td> Result is NULL pointer
4033 ** <tr><td> INTEGER <td> FLOAT <td> Convert from integer to float
4034 ** <tr><td> INTEGER <td> TEXT <td> ASCII rendering of the integer
4035 ** <tr><td> INTEGER <td> BLOB <td> Same as INTEGER->TEXT
4036 ** <tr><td> FLOAT <td> INTEGER <td> Convert from float to integer
4037 ** <tr><td> FLOAT <td> TEXT <td> ASCII rendering of the float
4038 ** <tr><td> FLOAT <td> BLOB <td> Same as FLOAT->TEXT
4039 ** <tr><td> TEXT <td> INTEGER <td> Use atoi()
4040 ** <tr><td> TEXT <td> FLOAT <td> Use atof()
4041 ** <tr><td> TEXT <td> BLOB <td> No change
4042 ** <tr><td> BLOB <td> INTEGER <td> Convert to TEXT then use atoi()
4043 ** <tr><td> BLOB <td> FLOAT <td> Convert to TEXT then use atof()
4044 ** <tr><td> BLOB <td> TEXT <td> Add a zero terminator if needed
4045 ** </table>
4046 ** </blockquote>)^
4048 ** The table above makes reference to standard C library functions atoi()
4049 ** and atof(). SQLite does not really use these functions. It has its
4050 ** own equivalent internal routines. The atoi() and atof() names are
4051 ** used in the table for brevity and because they are familiar to most
4052 ** C programmers.
4054 ** Note that when type conversions occur, pointers returned by prior
4055 ** calls to sqlite3_column_blob(), sqlite3_column_text(), and/or
4056 ** sqlite3_column_text16() may be invalidated.
4057 ** Type conversions and pointer invalidations might occur
4058 ** in the following cases:
4060 ** <ul>
4061 ** <li> The initial content is a BLOB and sqlite3_column_text() or
4062 ** sqlite3_column_text16() is called. A zero-terminator might
4063 ** need to be added to the string.</li>
4064 ** <li> The initial content is UTF-8 text and sqlite3_column_bytes16() or
4065 ** sqlite3_column_text16() is called. The content must be converted
4066 ** to UTF-16.</li>
4067 ** <li> The initial content is UTF-16 text and sqlite3_column_bytes() or
4068 ** sqlite3_column_text() is called. The content must be converted
4069 ** to UTF-8.</li>
4070 ** </ul>
4072 ** ^Conversions between UTF-16be and UTF-16le are always done in place and do
4073 ** not invalidate a prior pointer, though of course the content of the buffer
4074 ** that the prior pointer references will have been modified. Other kinds
4075 ** of conversion are done in place when it is possible, but sometimes they
4076 ** are not possible and in those cases prior pointers are invalidated.
4078 ** The safest and easiest to remember policy is to invoke these routines
4079 ** in one of the following ways:
4081 ** <ul>
4082 ** <li>sqlite3_column_text() followed by sqlite3_column_bytes()</li>
4083 ** <li>sqlite3_column_blob() followed by sqlite3_column_bytes()</li>
4084 ** <li>sqlite3_column_text16() followed by sqlite3_column_bytes16()</li>
4085 ** </ul>
4087 ** In other words, you should call sqlite3_column_text(),
4088 ** sqlite3_column_blob(), or sqlite3_column_text16() first to force the result
4089 ** into the desired format, then invoke sqlite3_column_bytes() or
4090 ** sqlite3_column_bytes16() to find the size of the result. Do not mix calls
4091 ** to sqlite3_column_text() or sqlite3_column_blob() with calls to
4092 ** sqlite3_column_bytes16(), and do not mix calls to sqlite3_column_text16()
4093 ** with calls to sqlite3_column_bytes().
4095 ** ^The pointers returned are valid until a type conversion occurs as
4096 ** described above, or until [sqlite3_step()] or [sqlite3_reset()] or
4097 ** [sqlite3_finalize()] is called. ^The memory space used to hold strings
4098 ** and BLOBs is freed automatically. Do <b>not</b> pass the pointers returned
4099 ** [sqlite3_column_blob()], [sqlite3_column_text()], etc. into
4100 ** [sqlite3_free()].
4102 ** ^(If a memory allocation error occurs during the evaluation of any
4103 ** of these routines, a default value is returned. The default value
4104 ** is either the integer 0, the floating point number 0.0, or a NULL
4105 ** pointer. Subsequent calls to [sqlite3_errcode()] will return
4106 ** [SQLITE_NOMEM].)^
4108 SQLITE_API const void *sqlite3_column_blob(sqlite3_stmt*, int iCol);
4109 SQLITE_API int sqlite3_column_bytes(sqlite3_stmt*, int iCol);
4110 SQLITE_API int sqlite3_column_bytes16(sqlite3_stmt*, int iCol);
4111 SQLITE_API double sqlite3_column_double(sqlite3_stmt*, int iCol);
4112 SQLITE_API int sqlite3_column_int(sqlite3_stmt*, int iCol);
4113 SQLITE_API sqlite3_int64 sqlite3_column_int64(sqlite3_stmt*, int iCol);
4114 SQLITE_API const unsigned char *sqlite3_column_text(sqlite3_stmt*, int iCol);
4115 SQLITE_API const void *sqlite3_column_text16(sqlite3_stmt*, int iCol);
4116 SQLITE_API int sqlite3_column_type(sqlite3_stmt*, int iCol);
4117 SQLITE_API sqlite3_value *sqlite3_column_value(sqlite3_stmt*, int iCol);
4120 ** CAPI3REF: Destroy A Prepared Statement Object
4122 ** ^The sqlite3_finalize() function is called to delete a [prepared statement].
4123 ** ^If the most recent evaluation of the statement encountered no errors
4124 ** or if the statement is never been evaluated, then sqlite3_finalize() returns
4125 ** SQLITE_OK. ^If the most recent evaluation of statement S failed, then
4126 ** sqlite3_finalize(S) returns the appropriate [error code] or
4127 ** [extended error code].
4129 ** ^The sqlite3_finalize(S) routine can be called at any point during
4130 ** the life cycle of [prepared statement] S:
4131 ** before statement S is ever evaluated, after
4132 ** one or more calls to [sqlite3_reset()], or after any call
4133 ** to [sqlite3_step()] regardless of whether or not the statement has
4134 ** completed execution.
4136 ** ^Invoking sqlite3_finalize() on a NULL pointer is a harmless no-op.
4138 ** The application must finalize every [prepared statement] in order to avoid
4139 ** resource leaks. It is a grievous error for the application to try to use
4140 ** a prepared statement after it has been finalized. Any use of a prepared
4141 ** statement after it has been finalized can result in undefined and
4142 ** undesirable behavior such as segfaults and heap corruption.
4144 SQLITE_API int sqlite3_finalize(sqlite3_stmt *pStmt);
4147 ** CAPI3REF: Reset A Prepared Statement Object
4149 ** The sqlite3_reset() function is called to reset a [prepared statement]
4150 ** object back to its initial state, ready to be re-executed.
4151 ** ^Any SQL statement variables that had values bound to them using
4152 ** the [sqlite3_bind_blob | sqlite3_bind_*() API] retain their values.
4153 ** Use [sqlite3_clear_bindings()] to reset the bindings.
4155 ** ^The [sqlite3_reset(S)] interface resets the [prepared statement] S
4156 ** back to the beginning of its program.
4158 ** ^If the most recent call to [sqlite3_step(S)] for the
4159 ** [prepared statement] S returned [SQLITE_ROW] or [SQLITE_DONE],
4160 ** or if [sqlite3_step(S)] has never before been called on S,
4161 ** then [sqlite3_reset(S)] returns [SQLITE_OK].
4163 ** ^If the most recent call to [sqlite3_step(S)] for the
4164 ** [prepared statement] S indicated an error, then
4165 ** [sqlite3_reset(S)] returns an appropriate [error code].
4167 ** ^The [sqlite3_reset(S)] interface does not change the values
4168 ** of any [sqlite3_bind_blob|bindings] on the [prepared statement] S.
4170 SQLITE_API int sqlite3_reset(sqlite3_stmt *pStmt);
4173 ** CAPI3REF: Create Or Redefine SQL Functions
4174 ** KEYWORDS: {function creation routines}
4175 ** KEYWORDS: {application-defined SQL function}
4176 ** KEYWORDS: {application-defined SQL functions}
4178 ** ^These functions (collectively known as "function creation routines")
4179 ** are used to add SQL functions or aggregates or to redefine the behavior
4180 ** of existing SQL functions or aggregates. The only differences between
4181 ** these routines are the text encoding expected for
4182 ** the second parameter (the name of the function being created)
4183 ** and the presence or absence of a destructor callback for
4184 ** the application data pointer.
4186 ** ^The first parameter is the [database connection] to which the SQL
4187 ** function is to be added. ^If an application uses more than one database
4188 ** connection then application-defined SQL functions must be added
4189 ** to each database connection separately.
4191 ** ^The second parameter is the name of the SQL function to be created or
4192 ** redefined. ^The length of the name is limited to 255 bytes in a UTF-8
4193 ** representation, exclusive of the zero-terminator. ^Note that the name
4194 ** length limit is in UTF-8 bytes, not characters nor UTF-16 bytes.
4195 ** ^Any attempt to create a function with a longer name
4196 ** will result in [SQLITE_MISUSE] being returned.
4198 ** ^The third parameter (nArg)
4199 ** is the number of arguments that the SQL function or
4200 ** aggregate takes. ^If this parameter is -1, then the SQL function or
4201 ** aggregate may take any number of arguments between 0 and the limit
4202 ** set by [sqlite3_limit]([SQLITE_LIMIT_FUNCTION_ARG]). If the third
4203 ** parameter is less than -1 or greater than 127 then the behavior is
4204 ** undefined.
4206 ** ^The fourth parameter, eTextRep, specifies what
4207 ** [SQLITE_UTF8 | text encoding] this SQL function prefers for
4208 ** its parameters. Every SQL function implementation must be able to work
4209 ** with UTF-8, UTF-16le, or UTF-16be. But some implementations may be
4210 ** more efficient with one encoding than another. ^An application may
4211 ** invoke sqlite3_create_function() or sqlite3_create_function16() multiple
4212 ** times with the same function but with different values of eTextRep.
4213 ** ^When multiple implementations of the same function are available, SQLite
4214 ** will pick the one that involves the least amount of data conversion.
4215 ** If there is only a single implementation which does not care what text
4216 ** encoding is used, then the fourth argument should be [SQLITE_ANY].
4218 ** ^(The fifth parameter is an arbitrary pointer. The implementation of the
4219 ** function can gain access to this pointer using [sqlite3_user_data()].)^
4221 ** ^The sixth, seventh and eighth parameters, xFunc, xStep and xFinal, are
4222 ** pointers to C-language functions that implement the SQL function or
4223 ** aggregate. ^A scalar SQL function requires an implementation of the xFunc
4224 ** callback only; NULL pointers must be passed as the xStep and xFinal
4225 ** parameters. ^An aggregate SQL function requires an implementation of xStep
4226 ** and xFinal and NULL pointer must be passed for xFunc. ^To delete an existing
4227 ** SQL function or aggregate, pass NULL pointers for all three function
4228 ** callbacks.
4230 ** ^(If the ninth parameter to sqlite3_create_function_v2() is not NULL,
4231 ** then it is destructor for the application data pointer.
4232 ** The destructor is invoked when the function is deleted, either by being
4233 ** overloaded or when the database connection closes.)^
4234 ** ^The destructor is also invoked if the call to
4235 ** sqlite3_create_function_v2() fails.
4236 ** ^When the destructor callback of the tenth parameter is invoked, it
4237 ** is passed a single argument which is a copy of the application data
4238 ** pointer which was the fifth parameter to sqlite3_create_function_v2().
4240 ** ^It is permitted to register multiple implementations of the same
4241 ** functions with the same name but with either differing numbers of
4242 ** arguments or differing preferred text encodings. ^SQLite will use
4243 ** the implementation that most closely matches the way in which the
4244 ** SQL function is used. ^A function implementation with a non-negative
4245 ** nArg parameter is a better match than a function implementation with
4246 ** a negative nArg. ^A function where the preferred text encoding
4247 ** matches the database encoding is a better
4248 ** match than a function where the encoding is different.
4249 ** ^A function where the encoding difference is between UTF16le and UTF16be
4250 ** is a closer match than a function where the encoding difference is
4251 ** between UTF8 and UTF16.
4253 ** ^Built-in functions may be overloaded by new application-defined functions.
4255 ** ^An application-defined function is permitted to call other
4256 ** SQLite interfaces. However, such calls must not
4257 ** close the database connection nor finalize or reset the prepared
4258 ** statement in which the function is running.
4260 SQLITE_API int sqlite3_create_function(
4261 sqlite3 *db,
4262 const char *zFunctionName,
4263 int nArg,
4264 int eTextRep,
4265 void *pApp,
4266 void (*xFunc)(sqlite3_context*,int,sqlite3_value**),
4267 void (*xStep)(sqlite3_context*,int,sqlite3_value**),
4268 void (*xFinal)(sqlite3_context*)
4270 SQLITE_API int sqlite3_create_function16(
4271 sqlite3 *db,
4272 const void *zFunctionName,
4273 int nArg,
4274 int eTextRep,
4275 void *pApp,
4276 void (*xFunc)(sqlite3_context*,int,sqlite3_value**),
4277 void (*xStep)(sqlite3_context*,int,sqlite3_value**),
4278 void (*xFinal)(sqlite3_context*)
4280 SQLITE_API int sqlite3_create_function_v2(
4281 sqlite3 *db,
4282 const char *zFunctionName,
4283 int nArg,
4284 int eTextRep,
4285 void *pApp,
4286 void (*xFunc)(sqlite3_context*,int,sqlite3_value**),
4287 void (*xStep)(sqlite3_context*,int,sqlite3_value**),
4288 void (*xFinal)(sqlite3_context*),
4289 void(*xDestroy)(void*)
4293 ** CAPI3REF: Text Encodings
4295 ** These constant define integer codes that represent the various
4296 ** text encodings supported by SQLite.
4298 #define SQLITE_UTF8 1
4299 #define SQLITE_UTF16LE 2
4300 #define SQLITE_UTF16BE 3
4301 #define SQLITE_UTF16 4 /* Use native byte order */
4302 #define SQLITE_ANY 5 /* sqlite3_create_function only */
4303 #define SQLITE_UTF16_ALIGNED 8 /* sqlite3_create_collation only */
4306 ** CAPI3REF: Deprecated Functions
4307 ** DEPRECATED
4309 ** These functions are [deprecated]. In order to maintain
4310 ** backwards compatibility with older code, these functions continue
4311 ** to be supported. However, new applications should avoid
4312 ** the use of these functions. To help encourage people to avoid
4313 ** using these functions, we are not going to tell you what they do.
4315 #ifndef SQLITE_OMIT_DEPRECATED
4316 SQLITE_API SQLITE_DEPRECATED int sqlite3_aggregate_count(sqlite3_context*);
4317 SQLITE_API SQLITE_DEPRECATED int sqlite3_expired(sqlite3_stmt*);
4318 SQLITE_API SQLITE_DEPRECATED int sqlite3_transfer_bindings(sqlite3_stmt*, sqlite3_stmt*);
4319 SQLITE_API SQLITE_DEPRECATED int sqlite3_global_recover(void);
4320 SQLITE_API SQLITE_DEPRECATED void sqlite3_thread_cleanup(void);
4321 SQLITE_API SQLITE_DEPRECATED int sqlite3_memory_alarm(void(*)(void*,sqlite3_int64,int),void*,sqlite3_int64);
4322 #endif
4325 ** CAPI3REF: Obtaining SQL Function Parameter Values
4327 ** The C-language implementation of SQL functions and aggregates uses
4328 ** this set of interface routines to access the parameter values on
4329 ** the function or aggregate.
4331 ** The xFunc (for scalar functions) or xStep (for aggregates) parameters
4332 ** to [sqlite3_create_function()] and [sqlite3_create_function16()]
4333 ** define callbacks that implement the SQL functions and aggregates.
4334 ** The 3rd parameter to these callbacks is an array of pointers to
4335 ** [protected sqlite3_value] objects. There is one [sqlite3_value] object for
4336 ** each parameter to the SQL function. These routines are used to
4337 ** extract values from the [sqlite3_value] objects.
4339 ** These routines work only with [protected sqlite3_value] objects.
4340 ** Any attempt to use these routines on an [unprotected sqlite3_value]
4341 ** object results in undefined behavior.
4343 ** ^These routines work just like the corresponding [column access functions]
4344 ** except that these routines take a single [protected sqlite3_value] object
4345 ** pointer instead of a [sqlite3_stmt*] pointer and an integer column number.
4347 ** ^The sqlite3_value_text16() interface extracts a UTF-16 string
4348 ** in the native byte-order of the host machine. ^The
4349 ** sqlite3_value_text16be() and sqlite3_value_text16le() interfaces
4350 ** extract UTF-16 strings as big-endian and little-endian respectively.
4352 ** ^(The sqlite3_value_numeric_type() interface attempts to apply
4353 ** numeric affinity to the value. This means that an attempt is
4354 ** made to convert the value to an integer or floating point. If
4355 ** such a conversion is possible without loss of information (in other
4356 ** words, if the value is a string that looks like a number)
4357 ** then the conversion is performed. Otherwise no conversion occurs.
4358 ** The [SQLITE_INTEGER | datatype] after conversion is returned.)^
4360 ** Please pay particular attention to the fact that the pointer returned
4361 ** from [sqlite3_value_blob()], [sqlite3_value_text()], or
4362 ** [sqlite3_value_text16()] can be invalidated by a subsequent call to
4363 ** [sqlite3_value_bytes()], [sqlite3_value_bytes16()], [sqlite3_value_text()],
4364 ** or [sqlite3_value_text16()].
4366 ** These routines must be called from the same thread as
4367 ** the SQL function that supplied the [sqlite3_value*] parameters.
4369 SQLITE_API const void *sqlite3_value_blob(sqlite3_value*);
4370 SQLITE_API int sqlite3_value_bytes(sqlite3_value*);
4371 SQLITE_API int sqlite3_value_bytes16(sqlite3_value*);
4372 SQLITE_API double sqlite3_value_double(sqlite3_value*);
4373 SQLITE_API int sqlite3_value_int(sqlite3_value*);
4374 SQLITE_API sqlite3_int64 sqlite3_value_int64(sqlite3_value*);
4375 SQLITE_API const unsigned char *sqlite3_value_text(sqlite3_value*);
4376 SQLITE_API const void *sqlite3_value_text16(sqlite3_value*);
4377 SQLITE_API const void *sqlite3_value_text16le(sqlite3_value*);
4378 SQLITE_API const void *sqlite3_value_text16be(sqlite3_value*);
4379 SQLITE_API int sqlite3_value_type(sqlite3_value*);
4380 SQLITE_API int sqlite3_value_numeric_type(sqlite3_value*);
4383 ** CAPI3REF: Obtain Aggregate Function Context
4385 ** Implementations of aggregate SQL functions use this
4386 ** routine to allocate memory for storing their state.
4388 ** ^The first time the sqlite3_aggregate_context(C,N) routine is called
4389 ** for a particular aggregate function, SQLite
4390 ** allocates N of memory, zeroes out that memory, and returns a pointer
4391 ** to the new memory. ^On second and subsequent calls to
4392 ** sqlite3_aggregate_context() for the same aggregate function instance,
4393 ** the same buffer is returned. Sqlite3_aggregate_context() is normally
4394 ** called once for each invocation of the xStep callback and then one
4395 ** last time when the xFinal callback is invoked. ^(When no rows match
4396 ** an aggregate query, the xStep() callback of the aggregate function
4397 ** implementation is never called and xFinal() is called exactly once.
4398 ** In those cases, sqlite3_aggregate_context() might be called for the
4399 ** first time from within xFinal().)^
4401 ** ^The sqlite3_aggregate_context(C,N) routine returns a NULL pointer if N is
4402 ** less than or equal to zero or if a memory allocate error occurs.
4404 ** ^(The amount of space allocated by sqlite3_aggregate_context(C,N) is
4405 ** determined by the N parameter on first successful call. Changing the
4406 ** value of N in subsequent call to sqlite3_aggregate_context() within
4407 ** the same aggregate function instance will not resize the memory
4408 ** allocation.)^
4410 ** ^SQLite automatically frees the memory allocated by
4411 ** sqlite3_aggregate_context() when the aggregate query concludes.
4413 ** The first parameter must be a copy of the
4414 ** [sqlite3_context | SQL function context] that is the first parameter
4415 ** to the xStep or xFinal callback routine that implements the aggregate
4416 ** function.
4418 ** This routine must be called from the same thread in which
4419 ** the aggregate SQL function is running.
4421 SQLITE_API void *sqlite3_aggregate_context(sqlite3_context*, int nBytes);
4424 ** CAPI3REF: User Data For Functions
4426 ** ^The sqlite3_user_data() interface returns a copy of
4427 ** the pointer that was the pUserData parameter (the 5th parameter)
4428 ** of the [sqlite3_create_function()]
4429 ** and [sqlite3_create_function16()] routines that originally
4430 ** registered the application defined function.
4432 ** This routine must be called from the same thread in which
4433 ** the application-defined function is running.
4435 SQLITE_API void *sqlite3_user_data(sqlite3_context*);
4438 ** CAPI3REF: Database Connection For Functions
4440 ** ^The sqlite3_context_db_handle() interface returns a copy of
4441 ** the pointer to the [database connection] (the 1st parameter)
4442 ** of the [sqlite3_create_function()]
4443 ** and [sqlite3_create_function16()] routines that originally
4444 ** registered the application defined function.
4446 SQLITE_API sqlite3 *sqlite3_context_db_handle(sqlite3_context*);
4449 ** CAPI3REF: Function Auxiliary Data
4451 ** The following two functions may be used by scalar SQL functions to
4452 ** associate metadata with argument values. If the same value is passed to
4453 ** multiple invocations of the same SQL function during query execution, under
4454 ** some circumstances the associated metadata may be preserved. This may
4455 ** be used, for example, to add a regular-expression matching scalar
4456 ** function. The compiled version of the regular expression is stored as
4457 ** metadata associated with the SQL value passed as the regular expression
4458 ** pattern. The compiled regular expression can be reused on multiple
4459 ** invocations of the same function so that the original pattern string
4460 ** does not need to be recompiled on each invocation.
4462 ** ^The sqlite3_get_auxdata() interface returns a pointer to the metadata
4463 ** associated by the sqlite3_set_auxdata() function with the Nth argument
4464 ** value to the application-defined function. ^If no metadata has been ever
4465 ** been set for the Nth argument of the function, or if the corresponding
4466 ** function parameter has changed since the meta-data was set,
4467 ** then sqlite3_get_auxdata() returns a NULL pointer.
4469 ** ^The sqlite3_set_auxdata() interface saves the metadata
4470 ** pointed to by its 3rd parameter as the metadata for the N-th
4471 ** argument of the application-defined function. Subsequent
4472 ** calls to sqlite3_get_auxdata() might return this data, if it has
4473 ** not been destroyed.
4474 ** ^If it is not NULL, SQLite will invoke the destructor
4475 ** function given by the 4th parameter to sqlite3_set_auxdata() on
4476 ** the metadata when the corresponding function parameter changes
4477 ** or when the SQL statement completes, whichever comes first.
4479 ** SQLite is free to call the destructor and drop metadata on any
4480 ** parameter of any function at any time. ^The only guarantee is that
4481 ** the destructor will be called before the metadata is dropped.
4483 ** ^(In practice, metadata is preserved between function calls for
4484 ** expressions that are constant at compile time. This includes literal
4485 ** values and [parameters].)^
4487 ** These routines must be called from the same thread in which
4488 ** the SQL function is running.
4490 SQLITE_API void *sqlite3_get_auxdata(sqlite3_context*, int N);
4491 SQLITE_API void sqlite3_set_auxdata(sqlite3_context*, int N, void*, void (*)(void*));
4495 ** CAPI3REF: Constants Defining Special Destructor Behavior
4497 ** These are special values for the destructor that is passed in as the
4498 ** final argument to routines like [sqlite3_result_blob()]. ^If the destructor
4499 ** argument is SQLITE_STATIC, it means that the content pointer is constant
4500 ** and will never change. It does not need to be destroyed. ^The
4501 ** SQLITE_TRANSIENT value means that the content will likely change in
4502 ** the near future and that SQLite should make its own private copy of
4503 ** the content before returning.
4505 ** The typedef is necessary to work around problems in certain
4506 ** C++ compilers. See ticket #2191.
4508 typedef void (*sqlite3_destructor_type)(void*);
4509 #define SQLITE_STATIC ((sqlite3_destructor_type)0)
4510 #define SQLITE_TRANSIENT ((sqlite3_destructor_type)-1)
4513 ** CAPI3REF: Setting The Result Of An SQL Function
4515 ** These routines are used by the xFunc or xFinal callbacks that
4516 ** implement SQL functions and aggregates. See
4517 ** [sqlite3_create_function()] and [sqlite3_create_function16()]
4518 ** for additional information.
4520 ** These functions work very much like the [parameter binding] family of
4521 ** functions used to bind values to host parameters in prepared statements.
4522 ** Refer to the [SQL parameter] documentation for additional information.
4524 ** ^The sqlite3_result_blob() interface sets the result from
4525 ** an application-defined function to be the BLOB whose content is pointed
4526 ** to by the second parameter and which is N bytes long where N is the
4527 ** third parameter.
4529 ** ^The sqlite3_result_zeroblob() interfaces set the result of
4530 ** the application-defined function to be a BLOB containing all zero
4531 ** bytes and N bytes in size, where N is the value of the 2nd parameter.
4533 ** ^The sqlite3_result_double() interface sets the result from
4534 ** an application-defined function to be a floating point value specified
4535 ** by its 2nd argument.
4537 ** ^The sqlite3_result_error() and sqlite3_result_error16() functions
4538 ** cause the implemented SQL function to throw an exception.
4539 ** ^SQLite uses the string pointed to by the
4540 ** 2nd parameter of sqlite3_result_error() or sqlite3_result_error16()
4541 ** as the text of an error message. ^SQLite interprets the error
4542 ** message string from sqlite3_result_error() as UTF-8. ^SQLite
4543 ** interprets the string from sqlite3_result_error16() as UTF-16 in native
4544 ** byte order. ^If the third parameter to sqlite3_result_error()
4545 ** or sqlite3_result_error16() is negative then SQLite takes as the error
4546 ** message all text up through the first zero character.
4547 ** ^If the third parameter to sqlite3_result_error() or
4548 ** sqlite3_result_error16() is non-negative then SQLite takes that many
4549 ** bytes (not characters) from the 2nd parameter as the error message.
4550 ** ^The sqlite3_result_error() and sqlite3_result_error16()
4551 ** routines make a private copy of the error message text before
4552 ** they return. Hence, the calling function can deallocate or
4553 ** modify the text after they return without harm.
4554 ** ^The sqlite3_result_error_code() function changes the error code
4555 ** returned by SQLite as a result of an error in a function. ^By default,
4556 ** the error code is SQLITE_ERROR. ^A subsequent call to sqlite3_result_error()
4557 ** or sqlite3_result_error16() resets the error code to SQLITE_ERROR.
4559 ** ^The sqlite3_result_toobig() interface causes SQLite to throw an error
4560 ** indicating that a string or BLOB is too long to represent.
4562 ** ^The sqlite3_result_nomem() interface causes SQLite to throw an error
4563 ** indicating that a memory allocation failed.
4565 ** ^The sqlite3_result_int() interface sets the return value
4566 ** of the application-defined function to be the 32-bit signed integer
4567 ** value given in the 2nd argument.
4568 ** ^The sqlite3_result_int64() interface sets the return value
4569 ** of the application-defined function to be the 64-bit signed integer
4570 ** value given in the 2nd argument.
4572 ** ^The sqlite3_result_null() interface sets the return value
4573 ** of the application-defined function to be NULL.
4575 ** ^The sqlite3_result_text(), sqlite3_result_text16(),
4576 ** sqlite3_result_text16le(), and sqlite3_result_text16be() interfaces
4577 ** set the return value of the application-defined function to be
4578 ** a text string which is represented as UTF-8, UTF-16 native byte order,
4579 ** UTF-16 little endian, or UTF-16 big endian, respectively.
4580 ** ^SQLite takes the text result from the application from
4581 ** the 2nd parameter of the sqlite3_result_text* interfaces.
4582 ** ^If the 3rd parameter to the sqlite3_result_text* interfaces
4583 ** is negative, then SQLite takes result text from the 2nd parameter
4584 ** through the first zero character.
4585 ** ^If the 3rd parameter to the sqlite3_result_text* interfaces
4586 ** is non-negative, then as many bytes (not characters) of the text
4587 ** pointed to by the 2nd parameter are taken as the application-defined
4588 ** function result.
4589 ** ^If the 4th parameter to the sqlite3_result_text* interfaces
4590 ** or sqlite3_result_blob is a non-NULL pointer, then SQLite calls that
4591 ** function as the destructor on the text or BLOB result when it has
4592 ** finished using that result.
4593 ** ^If the 4th parameter to the sqlite3_result_text* interfaces or to
4594 ** sqlite3_result_blob is the special constant SQLITE_STATIC, then SQLite
4595 ** assumes that the text or BLOB result is in constant space and does not
4596 ** copy the content of the parameter nor call a destructor on the content
4597 ** when it has finished using that result.
4598 ** ^If the 4th parameter to the sqlite3_result_text* interfaces
4599 ** or sqlite3_result_blob is the special constant SQLITE_TRANSIENT
4600 ** then SQLite makes a copy of the result into space obtained from
4601 ** from [sqlite3_malloc()] before it returns.
4603 ** ^The sqlite3_result_value() interface sets the result of
4604 ** the application-defined function to be a copy the
4605 ** [unprotected sqlite3_value] object specified by the 2nd parameter. ^The
4606 ** sqlite3_result_value() interface makes a copy of the [sqlite3_value]
4607 ** so that the [sqlite3_value] specified in the parameter may change or
4608 ** be deallocated after sqlite3_result_value() returns without harm.
4609 ** ^A [protected sqlite3_value] object may always be used where an
4610 ** [unprotected sqlite3_value] object is required, so either
4611 ** kind of [sqlite3_value] object can be used with this interface.
4613 ** If these routines are called from within the different thread
4614 ** than the one containing the application-defined function that received
4615 ** the [sqlite3_context] pointer, the results are undefined.
4617 SQLITE_API void sqlite3_result_blob(sqlite3_context*, const void*, int, void(*)(void*));
4618 SQLITE_API void sqlite3_result_double(sqlite3_context*, double);
4619 SQLITE_API void sqlite3_result_error(sqlite3_context*, const char*, int);
4620 SQLITE_API void sqlite3_result_error16(sqlite3_context*, const void*, int);
4621 SQLITE_API void sqlite3_result_error_toobig(sqlite3_context*);
4622 SQLITE_API void sqlite3_result_error_nomem(sqlite3_context*);
4623 SQLITE_API void sqlite3_result_error_code(sqlite3_context*, int);
4624 SQLITE_API void sqlite3_result_int(sqlite3_context*, int);
4625 SQLITE_API void sqlite3_result_int64(sqlite3_context*, sqlite3_int64);
4626 SQLITE_API void sqlite3_result_null(sqlite3_context*);
4627 SQLITE_API void sqlite3_result_text(sqlite3_context*, const char*, int, void(*)(void*));
4628 SQLITE_API void sqlite3_result_text16(sqlite3_context*, const void*, int, void(*)(void*));
4629 SQLITE_API void sqlite3_result_text16le(sqlite3_context*, const void*, int,void(*)(void*));
4630 SQLITE_API void sqlite3_result_text16be(sqlite3_context*, const void*, int,void(*)(void*));
4631 SQLITE_API void sqlite3_result_value(sqlite3_context*, sqlite3_value*);
4632 SQLITE_API void sqlite3_result_zeroblob(sqlite3_context*, int n);
4635 ** CAPI3REF: Define New Collating Sequences
4637 ** ^These functions add, remove, or modify a [collation] associated
4638 ** with the [database connection] specified as the first argument.
4640 ** ^The name of the collation is a UTF-8 string
4641 ** for sqlite3_create_collation() and sqlite3_create_collation_v2()
4642 ** and a UTF-16 string in native byte order for sqlite3_create_collation16().
4643 ** ^Collation names that compare equal according to [sqlite3_strnicmp()] are
4644 ** considered to be the same name.
4646 ** ^(The third argument (eTextRep) must be one of the constants:
4647 ** <ul>
4648 ** <li> [SQLITE_UTF8],
4649 ** <li> [SQLITE_UTF16LE],
4650 ** <li> [SQLITE_UTF16BE],
4651 ** <li> [SQLITE_UTF16], or
4652 ** <li> [SQLITE_UTF16_ALIGNED].
4653 ** </ul>)^
4654 ** ^The eTextRep argument determines the encoding of strings passed
4655 ** to the collating function callback, xCallback.
4656 ** ^The [SQLITE_UTF16] and [SQLITE_UTF16_ALIGNED] values for eTextRep
4657 ** force strings to be UTF16 with native byte order.
4658 ** ^The [SQLITE_UTF16_ALIGNED] value for eTextRep forces strings to begin
4659 ** on an even byte address.
4661 ** ^The fourth argument, pArg, is an application data pointer that is passed
4662 ** through as the first argument to the collating function callback.
4664 ** ^The fifth argument, xCallback, is a pointer to the collating function.
4665 ** ^Multiple collating functions can be registered using the same name but
4666 ** with different eTextRep parameters and SQLite will use whichever
4667 ** function requires the least amount of data transformation.
4668 ** ^If the xCallback argument is NULL then the collating function is
4669 ** deleted. ^When all collating functions having the same name are deleted,
4670 ** that collation is no longer usable.
4672 ** ^The collating function callback is invoked with a copy of the pArg
4673 ** application data pointer and with two strings in the encoding specified
4674 ** by the eTextRep argument. The collating function must return an
4675 ** integer that is negative, zero, or positive
4676 ** if the first string is less than, equal to, or greater than the second,
4677 ** respectively. A collating function must always return the same answer
4678 ** given the same inputs. If two or more collating functions are registered
4679 ** to the same collation name (using different eTextRep values) then all
4680 ** must give an equivalent answer when invoked with equivalent strings.
4681 ** The collating function must obey the following properties for all
4682 ** strings A, B, and C:
4684 ** <ol>
4685 ** <li> If A==B then B==A.
4686 ** <li> If A==B and B==C then A==C.
4687 ** <li> If A&lt;B THEN B&gt;A.
4688 ** <li> If A&lt;B and B&lt;C then A&lt;C.
4689 ** </ol>
4691 ** If a collating function fails any of the above constraints and that
4692 ** collating function is registered and used, then the behavior of SQLite
4693 ** is undefined.
4695 ** ^The sqlite3_create_collation_v2() works like sqlite3_create_collation()
4696 ** with the addition that the xDestroy callback is invoked on pArg when
4697 ** the collating function is deleted.
4698 ** ^Collating functions are deleted when they are overridden by later
4699 ** calls to the collation creation functions or when the
4700 ** [database connection] is closed using [sqlite3_close()].
4702 ** ^The xDestroy callback is <u>not</u> called if the
4703 ** sqlite3_create_collation_v2() function fails. Applications that invoke
4704 ** sqlite3_create_collation_v2() with a non-NULL xDestroy argument should
4705 ** check the return code and dispose of the application data pointer
4706 ** themselves rather than expecting SQLite to deal with it for them.
4707 ** This is different from every other SQLite interface. The inconsistency
4708 ** is unfortunate but cannot be changed without breaking backwards
4709 ** compatibility.
4711 ** See also: [sqlite3_collation_needed()] and [sqlite3_collation_needed16()].
4713 SQLITE_API int sqlite3_create_collation(
4714 sqlite3*,
4715 const char *zName,
4716 int eTextRep,
4717 void *pArg,
4718 int(*xCompare)(void*,int,const void*,int,const void*)
4720 SQLITE_API int sqlite3_create_collation_v2(
4721 sqlite3*,
4722 const char *zName,
4723 int eTextRep,
4724 void *pArg,
4725 int(*xCompare)(void*,int,const void*,int,const void*),
4726 void(*xDestroy)(void*)
4728 SQLITE_API int sqlite3_create_collation16(
4729 sqlite3*,
4730 const void *zName,
4731 int eTextRep,
4732 void *pArg,
4733 int(*xCompare)(void*,int,const void*,int,const void*)
4737 ** CAPI3REF: Collation Needed Callbacks
4739 ** ^To avoid having to register all collation sequences before a database
4740 ** can be used, a single callback function may be registered with the
4741 ** [database connection] to be invoked whenever an undefined collation
4742 ** sequence is required.
4744 ** ^If the function is registered using the sqlite3_collation_needed() API,
4745 ** then it is passed the names of undefined collation sequences as strings
4746 ** encoded in UTF-8. ^If sqlite3_collation_needed16() is used,
4747 ** the names are passed as UTF-16 in machine native byte order.
4748 ** ^A call to either function replaces the existing collation-needed callback.
4750 ** ^(When the callback is invoked, the first argument passed is a copy
4751 ** of the second argument to sqlite3_collation_needed() or
4752 ** sqlite3_collation_needed16(). The second argument is the database
4753 ** connection. The third argument is one of [SQLITE_UTF8], [SQLITE_UTF16BE],
4754 ** or [SQLITE_UTF16LE], indicating the most desirable form of the collation
4755 ** sequence function required. The fourth parameter is the name of the
4756 ** required collation sequence.)^
4758 ** The callback function should register the desired collation using
4759 ** [sqlite3_create_collation()], [sqlite3_create_collation16()], or
4760 ** [sqlite3_create_collation_v2()].
4762 SQLITE_API int sqlite3_collation_needed(
4763 sqlite3*,
4764 void*,
4765 void(*)(void*,sqlite3*,int eTextRep,const char*)
4767 SQLITE_API int sqlite3_collation_needed16(
4768 sqlite3*,
4769 void*,
4770 void(*)(void*,sqlite3*,int eTextRep,const void*)
4773 #ifdef SQLITE_HAS_CODEC
4775 ** Specify the key for an encrypted database. This routine should be
4776 ** called right after sqlite3_open().
4778 ** The code to implement this API is not available in the public release
4779 ** of SQLite.
4781 SQLITE_API int sqlite3_key(
4782 sqlite3 *db, /* Database to be rekeyed */
4783 const void *pKey, int nKey /* The key */
4787 ** Change the key on an open database. If the current database is not
4788 ** encrypted, this routine will encrypt it. If pNew==0 or nNew==0, the
4789 ** database is decrypted.
4791 ** The code to implement this API is not available in the public release
4792 ** of SQLite.
4794 SQLITE_API int sqlite3_rekey(
4795 sqlite3 *db, /* Database to be rekeyed */
4796 const void *pKey, int nKey /* The new key */
4800 ** Specify the activation key for a SEE database. Unless
4801 ** activated, none of the SEE routines will work.
4803 SQLITE_API void sqlite3_activate_see(
4804 const char *zPassPhrase /* Activation phrase */
4806 #endif
4808 #ifdef SQLITE_ENABLE_CEROD
4810 ** Specify the activation key for a CEROD database. Unless
4811 ** activated, none of the CEROD routines will work.
4813 SQLITE_API void sqlite3_activate_cerod(
4814 const char *zPassPhrase /* Activation phrase */
4816 #endif
4819 ** CAPI3REF: Suspend Execution For A Short Time
4821 ** The sqlite3_sleep() function causes the current thread to suspend execution
4822 ** for at least a number of milliseconds specified in its parameter.
4824 ** If the operating system does not support sleep requests with
4825 ** millisecond time resolution, then the time will be rounded up to
4826 ** the nearest second. The number of milliseconds of sleep actually
4827 ** requested from the operating system is returned.
4829 ** ^SQLite implements this interface by calling the xSleep()
4830 ** method of the default [sqlite3_vfs] object. If the xSleep() method
4831 ** of the default VFS is not implemented correctly, or not implemented at
4832 ** all, then the behavior of sqlite3_sleep() may deviate from the description
4833 ** in the previous paragraphs.
4835 SQLITE_API int sqlite3_sleep(int);
4838 ** CAPI3REF: Name Of The Folder Holding Temporary Files
4840 ** ^(If this global variable is made to point to a string which is
4841 ** the name of a folder (a.k.a. directory), then all temporary files
4842 ** created by SQLite when using a built-in [sqlite3_vfs | VFS]
4843 ** will be placed in that directory.)^ ^If this variable
4844 ** is a NULL pointer, then SQLite performs a search for an appropriate
4845 ** temporary file directory.
4847 ** It is not safe to read or modify this variable in more than one
4848 ** thread at a time. It is not safe to read or modify this variable
4849 ** if a [database connection] is being used at the same time in a separate
4850 ** thread.
4851 ** It is intended that this variable be set once
4852 ** as part of process initialization and before any SQLite interface
4853 ** routines have been called and that this variable remain unchanged
4854 ** thereafter.
4856 ** ^The [temp_store_directory pragma] may modify this variable and cause
4857 ** it to point to memory obtained from [sqlite3_malloc]. ^Furthermore,
4858 ** the [temp_store_directory pragma] always assumes that any string
4859 ** that this variable points to is held in memory obtained from
4860 ** [sqlite3_malloc] and the pragma may attempt to free that memory
4861 ** using [sqlite3_free].
4862 ** Hence, if this variable is modified directly, either it should be
4863 ** made NULL or made to point to memory obtained from [sqlite3_malloc]
4864 ** or else the use of the [temp_store_directory pragma] should be avoided.
4866 SQLITE_API char *sqlite3_temp_directory;
4869 ** CAPI3REF: Test For Auto-Commit Mode
4870 ** KEYWORDS: {autocommit mode}
4872 ** ^The sqlite3_get_autocommit() interface returns non-zero or
4873 ** zero if the given database connection is or is not in autocommit mode,
4874 ** respectively. ^Autocommit mode is on by default.
4875 ** ^Autocommit mode is disabled by a [BEGIN] statement.
4876 ** ^Autocommit mode is re-enabled by a [COMMIT] or [ROLLBACK].
4878 ** If certain kinds of errors occur on a statement within a multi-statement
4879 ** transaction (errors including [SQLITE_FULL], [SQLITE_IOERR],
4880 ** [SQLITE_NOMEM], [SQLITE_BUSY], and [SQLITE_INTERRUPT]) then the
4881 ** transaction might be rolled back automatically. The only way to
4882 ** find out whether SQLite automatically rolled back the transaction after
4883 ** an error is to use this function.
4885 ** If another thread changes the autocommit status of the database
4886 ** connection while this routine is running, then the return value
4887 ** is undefined.
4889 SQLITE_API int sqlite3_get_autocommit(sqlite3*);
4892 ** CAPI3REF: Find The Database Handle Of A Prepared Statement
4894 ** ^The sqlite3_db_handle interface returns the [database connection] handle
4895 ** to which a [prepared statement] belongs. ^The [database connection]
4896 ** returned by sqlite3_db_handle is the same [database connection]
4897 ** that was the first argument
4898 ** to the [sqlite3_prepare_v2()] call (or its variants) that was used to
4899 ** create the statement in the first place.
4901 SQLITE_API sqlite3 *sqlite3_db_handle(sqlite3_stmt*);
4904 ** CAPI3REF: Find the next prepared statement
4906 ** ^This interface returns a pointer to the next [prepared statement] after
4907 ** pStmt associated with the [database connection] pDb. ^If pStmt is NULL
4908 ** then this interface returns a pointer to the first prepared statement
4909 ** associated with the database connection pDb. ^If no prepared statement
4910 ** satisfies the conditions of this routine, it returns NULL.
4912 ** The [database connection] pointer D in a call to
4913 ** [sqlite3_next_stmt(D,S)] must refer to an open database
4914 ** connection and in particular must not be a NULL pointer.
4916 SQLITE_API sqlite3_stmt *sqlite3_next_stmt(sqlite3 *pDb, sqlite3_stmt *pStmt);
4919 ** CAPI3REF: Commit And Rollback Notification Callbacks
4921 ** ^The sqlite3_commit_hook() interface registers a callback
4922 ** function to be invoked whenever a transaction is [COMMIT | committed].
4923 ** ^Any callback set by a previous call to sqlite3_commit_hook()
4924 ** for the same database connection is overridden.
4925 ** ^The sqlite3_rollback_hook() interface registers a callback
4926 ** function to be invoked whenever a transaction is [ROLLBACK | rolled back].
4927 ** ^Any callback set by a previous call to sqlite3_rollback_hook()
4928 ** for the same database connection is overridden.
4929 ** ^The pArg argument is passed through to the callback.
4930 ** ^If the callback on a commit hook function returns non-zero,
4931 ** then the commit is converted into a rollback.
4933 ** ^The sqlite3_commit_hook(D,C,P) and sqlite3_rollback_hook(D,C,P) functions
4934 ** return the P argument from the previous call of the same function
4935 ** on the same [database connection] D, or NULL for
4936 ** the first call for each function on D.
4938 ** The callback implementation must not do anything that will modify
4939 ** the database connection that invoked the callback. Any actions
4940 ** to modify the database connection must be deferred until after the
4941 ** completion of the [sqlite3_step()] call that triggered the commit
4942 ** or rollback hook in the first place.
4943 ** Note that [sqlite3_prepare_v2()] and [sqlite3_step()] both modify their
4944 ** database connections for the meaning of "modify" in this paragraph.
4946 ** ^Registering a NULL function disables the callback.
4948 ** ^When the commit hook callback routine returns zero, the [COMMIT]
4949 ** operation is allowed to continue normally. ^If the commit hook
4950 ** returns non-zero, then the [COMMIT] is converted into a [ROLLBACK].
4951 ** ^The rollback hook is invoked on a rollback that results from a commit
4952 ** hook returning non-zero, just as it would be with any other rollback.
4954 ** ^For the purposes of this API, a transaction is said to have been
4955 ** rolled back if an explicit "ROLLBACK" statement is executed, or
4956 ** an error or constraint causes an implicit rollback to occur.
4957 ** ^The rollback callback is not invoked if a transaction is
4958 ** automatically rolled back because the database connection is closed.
4960 ** See also the [sqlite3_update_hook()] interface.
4962 SQLITE_API void *sqlite3_commit_hook(sqlite3*, int(*)(void*), void*);
4963 SQLITE_API void *sqlite3_rollback_hook(sqlite3*, void(*)(void *), void*);
4966 ** CAPI3REF: Data Change Notification Callbacks
4968 ** ^The sqlite3_update_hook() interface registers a callback function
4969 ** with the [database connection] identified by the first argument
4970 ** to be invoked whenever a row is updated, inserted or deleted.
4971 ** ^Any callback set by a previous call to this function
4972 ** for the same database connection is overridden.
4974 ** ^The second argument is a pointer to the function to invoke when a
4975 ** row is updated, inserted or deleted.
4976 ** ^The first argument to the callback is a copy of the third argument
4977 ** to sqlite3_update_hook().
4978 ** ^The second callback argument is one of [SQLITE_INSERT], [SQLITE_DELETE],
4979 ** or [SQLITE_UPDATE], depending on the operation that caused the callback
4980 ** to be invoked.
4981 ** ^The third and fourth arguments to the callback contain pointers to the
4982 ** database and table name containing the affected row.
4983 ** ^The final callback parameter is the [rowid] of the row.
4984 ** ^In the case of an update, this is the [rowid] after the update takes place.
4986 ** ^(The update hook is not invoked when internal system tables are
4987 ** modified (i.e. sqlite_master and sqlite_sequence).)^
4989 ** ^In the current implementation, the update hook
4990 ** is not invoked when duplication rows are deleted because of an
4991 ** [ON CONFLICT | ON CONFLICT REPLACE] clause. ^Nor is the update hook
4992 ** invoked when rows are deleted using the [truncate optimization].
4993 ** The exceptions defined in this paragraph might change in a future
4994 ** release of SQLite.
4996 ** The update hook implementation must not do anything that will modify
4997 ** the database connection that invoked the update hook. Any actions
4998 ** to modify the database connection must be deferred until after the
4999 ** completion of the [sqlite3_step()] call that triggered the update hook.
5000 ** Note that [sqlite3_prepare_v2()] and [sqlite3_step()] both modify their
5001 ** database connections for the meaning of "modify" in this paragraph.
5003 ** ^The sqlite3_update_hook(D,C,P) function
5004 ** returns the P argument from the previous call
5005 ** on the same [database connection] D, or NULL for
5006 ** the first call on D.
5008 ** See also the [sqlite3_commit_hook()] and [sqlite3_rollback_hook()]
5009 ** interfaces.
5011 SQLITE_API void *sqlite3_update_hook(
5012 sqlite3*,
5013 void(*)(void *,int ,char const *,char const *,sqlite3_int64),
5014 void*
5018 ** CAPI3REF: Enable Or Disable Shared Pager Cache
5019 ** KEYWORDS: {shared cache}
5021 ** ^(This routine enables or disables the sharing of the database cache
5022 ** and schema data structures between [database connection | connections]
5023 ** to the same database. Sharing is enabled if the argument is true
5024 ** and disabled if the argument is false.)^
5026 ** ^Cache sharing is enabled and disabled for an entire process.
5027 ** This is a change as of SQLite version 3.5.0. In prior versions of SQLite,
5028 ** sharing was enabled or disabled for each thread separately.
5030 ** ^(The cache sharing mode set by this interface effects all subsequent
5031 ** calls to [sqlite3_open()], [sqlite3_open_v2()], and [sqlite3_open16()].
5032 ** Existing database connections continue use the sharing mode
5033 ** that was in effect at the time they were opened.)^
5035 ** ^(This routine returns [SQLITE_OK] if shared cache was enabled or disabled
5036 ** successfully. An [error code] is returned otherwise.)^
5038 ** ^Shared cache is disabled by default. But this might change in
5039 ** future releases of SQLite. Applications that care about shared
5040 ** cache setting should set it explicitly.
5042 ** See Also: [SQLite Shared-Cache Mode]
5044 SQLITE_API int sqlite3_enable_shared_cache(int);
5047 ** CAPI3REF: Attempt To Free Heap Memory
5049 ** ^The sqlite3_release_memory() interface attempts to free N bytes
5050 ** of heap memory by deallocating non-essential memory allocations
5051 ** held by the database library. Memory used to cache database
5052 ** pages to improve performance is an example of non-essential memory.
5053 ** ^sqlite3_release_memory() returns the number of bytes actually freed,
5054 ** which might be more or less than the amount requested.
5055 ** ^The sqlite3_release_memory() routine is a no-op returning zero
5056 ** if SQLite is not compiled with [SQLITE_ENABLE_MEMORY_MANAGEMENT].
5058 SQLITE_API int sqlite3_release_memory(int);
5061 ** CAPI3REF: Impose A Limit On Heap Size
5063 ** ^The sqlite3_soft_heap_limit64() interface sets and/or queries the
5064 ** soft limit on the amount of heap memory that may be allocated by SQLite.
5065 ** ^SQLite strives to keep heap memory utilization below the soft heap
5066 ** limit by reducing the number of pages held in the page cache
5067 ** as heap memory usages approaches the limit.
5068 ** ^The soft heap limit is "soft" because even though SQLite strives to stay
5069 ** below the limit, it will exceed the limit rather than generate
5070 ** an [SQLITE_NOMEM] error. In other words, the soft heap limit
5071 ** is advisory only.
5073 ** ^The return value from sqlite3_soft_heap_limit64() is the size of
5074 ** the soft heap limit prior to the call. ^If the argument N is negative
5075 ** then no change is made to the soft heap limit. Hence, the current
5076 ** size of the soft heap limit can be determined by invoking
5077 ** sqlite3_soft_heap_limit64() with a negative argument.
5079 ** ^If the argument N is zero then the soft heap limit is disabled.
5081 ** ^(The soft heap limit is not enforced in the current implementation
5082 ** if one or more of following conditions are true:
5084 ** <ul>
5085 ** <li> The soft heap limit is set to zero.
5086 ** <li> Memory accounting is disabled using a combination of the
5087 ** [sqlite3_config]([SQLITE_CONFIG_MEMSTATUS],...) start-time option and
5088 ** the [SQLITE_DEFAULT_MEMSTATUS] compile-time option.
5089 ** <li> An alternative page cache implementation is specified using
5090 ** [sqlite3_config]([SQLITE_CONFIG_PCACHE],...).
5091 ** <li> The page cache allocates from its own memory pool supplied
5092 ** by [sqlite3_config]([SQLITE_CONFIG_PAGECACHE],...) rather than
5093 ** from the heap.
5094 ** </ul>)^
5096 ** Beginning with SQLite version 3.7.3, the soft heap limit is enforced
5097 ** regardless of whether or not the [SQLITE_ENABLE_MEMORY_MANAGEMENT]
5098 ** compile-time option is invoked. With [SQLITE_ENABLE_MEMORY_MANAGEMENT],
5099 ** the soft heap limit is enforced on every memory allocation. Without
5100 ** [SQLITE_ENABLE_MEMORY_MANAGEMENT], the soft heap limit is only enforced
5101 ** when memory is allocated by the page cache. Testing suggests that because
5102 ** the page cache is the predominate memory user in SQLite, most
5103 ** applications will achieve adequate soft heap limit enforcement without
5104 ** the use of [SQLITE_ENABLE_MEMORY_MANAGEMENT].
5106 ** The circumstances under which SQLite will enforce the soft heap limit may
5107 ** changes in future releases of SQLite.
5109 SQLITE_API sqlite3_int64 sqlite3_soft_heap_limit64(sqlite3_int64 N);
5112 ** CAPI3REF: Deprecated Soft Heap Limit Interface
5113 ** DEPRECATED
5115 ** This is a deprecated version of the [sqlite3_soft_heap_limit64()]
5116 ** interface. This routine is provided for historical compatibility
5117 ** only. All new applications should use the
5118 ** [sqlite3_soft_heap_limit64()] interface rather than this one.
5120 SQLITE_API SQLITE_DEPRECATED void sqlite3_soft_heap_limit(int N);
5124 ** CAPI3REF: Extract Metadata About A Column Of A Table
5126 ** ^This routine returns metadata about a specific column of a specific
5127 ** database table accessible using the [database connection] handle
5128 ** passed as the first function argument.
5130 ** ^The column is identified by the second, third and fourth parameters to
5131 ** this function. ^The second parameter is either the name of the database
5132 ** (i.e. "main", "temp", or an attached database) containing the specified
5133 ** table or NULL. ^If it is NULL, then all attached databases are searched
5134 ** for the table using the same algorithm used by the database engine to
5135 ** resolve unqualified table references.
5137 ** ^The third and fourth parameters to this function are the table and column
5138 ** name of the desired column, respectively. Neither of these parameters
5139 ** may be NULL.
5141 ** ^Metadata is returned by writing to the memory locations passed as the 5th
5142 ** and subsequent parameters to this function. ^Any of these arguments may be
5143 ** NULL, in which case the corresponding element of metadata is omitted.
5145 ** ^(<blockquote>
5146 ** <table border="1">
5147 ** <tr><th> Parameter <th> Output<br>Type <th> Description
5149 ** <tr><td> 5th <td> const char* <td> Data type
5150 ** <tr><td> 6th <td> const char* <td> Name of default collation sequence
5151 ** <tr><td> 7th <td> int <td> True if column has a NOT NULL constraint
5152 ** <tr><td> 8th <td> int <td> True if column is part of the PRIMARY KEY
5153 ** <tr><td> 9th <td> int <td> True if column is [AUTOINCREMENT]
5154 ** </table>
5155 ** </blockquote>)^
5157 ** ^The memory pointed to by the character pointers returned for the
5158 ** declaration type and collation sequence is valid only until the next
5159 ** call to any SQLite API function.
5161 ** ^If the specified table is actually a view, an [error code] is returned.
5163 ** ^If the specified column is "rowid", "oid" or "_rowid_" and an
5164 ** [INTEGER PRIMARY KEY] column has been explicitly declared, then the output
5165 ** parameters are set for the explicitly declared column. ^(If there is no
5166 ** explicitly declared [INTEGER PRIMARY KEY] column, then the output
5167 ** parameters are set as follows:
5169 ** <pre>
5170 ** data type: "INTEGER"
5171 ** collation sequence: "BINARY"
5172 ** not null: 0
5173 ** primary key: 1
5174 ** auto increment: 0
5175 ** </pre>)^
5177 ** ^(This function may load one or more schemas from database files. If an
5178 ** error occurs during this process, or if the requested table or column
5179 ** cannot be found, an [error code] is returned and an error message left
5180 ** in the [database connection] (to be retrieved using sqlite3_errmsg()).)^
5182 ** ^This API is only available if the library was compiled with the
5183 ** [SQLITE_ENABLE_COLUMN_METADATA] C-preprocessor symbol defined.
5185 SQLITE_API int sqlite3_table_column_metadata(
5186 sqlite3 *db, /* Connection handle */
5187 const char *zDbName, /* Database name or NULL */
5188 const char *zTableName, /* Table name */
5189 const char *zColumnName, /* Column name */
5190 char const **pzDataType, /* OUTPUT: Declared data type */
5191 char const **pzCollSeq, /* OUTPUT: Collation sequence name */
5192 int *pNotNull, /* OUTPUT: True if NOT NULL constraint exists */
5193 int *pPrimaryKey, /* OUTPUT: True if column part of PK */
5194 int *pAutoinc /* OUTPUT: True if column is auto-increment */
5198 ** CAPI3REF: Load An Extension
5200 ** ^This interface loads an SQLite extension library from the named file.
5202 ** ^The sqlite3_load_extension() interface attempts to load an
5203 ** SQLite extension library contained in the file zFile.
5205 ** ^The entry point is zProc.
5206 ** ^zProc may be 0, in which case the name of the entry point
5207 ** defaults to "sqlite3_extension_init".
5208 ** ^The sqlite3_load_extension() interface returns
5209 ** [SQLITE_OK] on success and [SQLITE_ERROR] if something goes wrong.
5210 ** ^If an error occurs and pzErrMsg is not 0, then the
5211 ** [sqlite3_load_extension()] interface shall attempt to
5212 ** fill *pzErrMsg with error message text stored in memory
5213 ** obtained from [sqlite3_malloc()]. The calling function
5214 ** should free this memory by calling [sqlite3_free()].
5216 ** ^Extension loading must be enabled using
5217 ** [sqlite3_enable_load_extension()] prior to calling this API,
5218 ** otherwise an error will be returned.
5220 ** See also the [load_extension() SQL function].
5222 SQLITE_API int sqlite3_load_extension(
5223 sqlite3 *db, /* Load the extension into this database connection */
5224 const char *zFile, /* Name of the shared library containing extension */
5225 const char *zProc, /* Entry point. Derived from zFile if 0 */
5226 char **pzErrMsg /* Put error message here if not 0 */
5230 ** CAPI3REF: Enable Or Disable Extension Loading
5232 ** ^So as not to open security holes in older applications that are
5233 ** unprepared to deal with extension loading, and as a means of disabling
5234 ** extension loading while evaluating user-entered SQL, the following API
5235 ** is provided to turn the [sqlite3_load_extension()] mechanism on and off.
5237 ** ^Extension loading is off by default. See ticket #1863.
5238 ** ^Call the sqlite3_enable_load_extension() routine with onoff==1
5239 ** to turn extension loading on and call it with onoff==0 to turn
5240 ** it back off again.
5242 SQLITE_API int sqlite3_enable_load_extension(sqlite3 *db, int onoff);
5245 ** CAPI3REF: Automatically Load Statically Linked Extensions
5247 ** ^This interface causes the xEntryPoint() function to be invoked for
5248 ** each new [database connection] that is created. The idea here is that
5249 ** xEntryPoint() is the entry point for a statically linked SQLite extension
5250 ** that is to be automatically loaded into all new database connections.
5252 ** ^(Even though the function prototype shows that xEntryPoint() takes
5253 ** no arguments and returns void, SQLite invokes xEntryPoint() with three
5254 ** arguments and expects and integer result as if the signature of the
5255 ** entry point where as follows:
5257 ** <blockquote><pre>
5258 ** &nbsp; int xEntryPoint(
5259 ** &nbsp; sqlite3 *db,
5260 ** &nbsp; const char **pzErrMsg,
5261 ** &nbsp; const struct sqlite3_api_routines *pThunk
5262 ** &nbsp; );
5263 ** </pre></blockquote>)^
5265 ** If the xEntryPoint routine encounters an error, it should make *pzErrMsg
5266 ** point to an appropriate error message (obtained from [sqlite3_mprintf()])
5267 ** and return an appropriate [error code]. ^SQLite ensures that *pzErrMsg
5268 ** is NULL before calling the xEntryPoint(). ^SQLite will invoke
5269 ** [sqlite3_free()] on *pzErrMsg after xEntryPoint() returns. ^If any
5270 ** xEntryPoint() returns an error, the [sqlite3_open()], [sqlite3_open16()],
5271 ** or [sqlite3_open_v2()] call that provoked the xEntryPoint() will fail.
5273 ** ^Calling sqlite3_auto_extension(X) with an entry point X that is already
5274 ** on the list of automatic extensions is a harmless no-op. ^No entry point
5275 ** will be called more than once for each database connection that is opened.
5277 ** See also: [sqlite3_reset_auto_extension()].
5279 SQLITE_API int sqlite3_auto_extension(void (*xEntryPoint)(void));
5282 ** CAPI3REF: Reset Automatic Extension Loading
5284 ** ^This interface disables all automatic extensions previously
5285 ** registered using [sqlite3_auto_extension()].
5287 SQLITE_API void sqlite3_reset_auto_extension(void);
5290 ** The interface to the virtual-table mechanism is currently considered
5291 ** to be experimental. The interface might change in incompatible ways.
5292 ** If this is a problem for you, do not use the interface at this time.
5294 ** When the virtual-table mechanism stabilizes, we will declare the
5295 ** interface fixed, support it indefinitely, and remove this comment.
5299 ** Structures used by the virtual table interface
5301 typedef struct sqlite3_vtab sqlite3_vtab;
5302 typedef struct sqlite3_index_info sqlite3_index_info;
5303 typedef struct sqlite3_vtab_cursor sqlite3_vtab_cursor;
5304 typedef struct sqlite3_module sqlite3_module;
5307 ** CAPI3REF: Virtual Table Object
5308 ** KEYWORDS: sqlite3_module {virtual table module}
5310 ** This structure, sometimes called a "virtual table module",
5311 ** defines the implementation of a [virtual tables].
5312 ** This structure consists mostly of methods for the module.
5314 ** ^A virtual table module is created by filling in a persistent
5315 ** instance of this structure and passing a pointer to that instance
5316 ** to [sqlite3_create_module()] or [sqlite3_create_module_v2()].
5317 ** ^The registration remains valid until it is replaced by a different
5318 ** module or until the [database connection] closes. The content
5319 ** of this structure must not change while it is registered with
5320 ** any database connection.
5322 struct sqlite3_module {
5323 int iVersion;
5324 int (*xCreate)(sqlite3*, void *pAux,
5325 int argc, const char *const*argv,
5326 sqlite3_vtab **ppVTab, char**);
5327 int (*xConnect)(sqlite3*, void *pAux,
5328 int argc, const char *const*argv,
5329 sqlite3_vtab **ppVTab, char**);
5330 int (*xBestIndex)(sqlite3_vtab *pVTab, sqlite3_index_info*);
5331 int (*xDisconnect)(sqlite3_vtab *pVTab);
5332 int (*xDestroy)(sqlite3_vtab *pVTab);
5333 int (*xOpen)(sqlite3_vtab *pVTab, sqlite3_vtab_cursor **ppCursor);
5334 int (*xClose)(sqlite3_vtab_cursor*);
5335 int (*xFilter)(sqlite3_vtab_cursor*, int idxNum, const char *idxStr,
5336 int argc, sqlite3_value **argv);
5337 int (*xNext)(sqlite3_vtab_cursor*);
5338 int (*xEof)(sqlite3_vtab_cursor*);
5339 int (*xColumn)(sqlite3_vtab_cursor*, sqlite3_context*, int);
5340 int (*xRowid)(sqlite3_vtab_cursor*, sqlite3_int64 *pRowid);
5341 int (*xUpdate)(sqlite3_vtab *, int, sqlite3_value **, sqlite3_int64 *);
5342 int (*xBegin)(sqlite3_vtab *pVTab);
5343 int (*xSync)(sqlite3_vtab *pVTab);
5344 int (*xCommit)(sqlite3_vtab *pVTab);
5345 int (*xRollback)(sqlite3_vtab *pVTab);
5346 int (*xFindFunction)(sqlite3_vtab *pVtab, int nArg, const char *zName,
5347 void (**pxFunc)(sqlite3_context*,int,sqlite3_value**),
5348 void **ppArg);
5349 int (*xRename)(sqlite3_vtab *pVtab, const char *zNew);
5350 /* The methods above are in version 1 of the sqlite_module object. Those
5351 ** below are for version 2 and greater. */
5352 int (*xSavepoint)(sqlite3_vtab *pVTab, int);
5353 int (*xRelease)(sqlite3_vtab *pVTab, int);
5354 int (*xRollbackTo)(sqlite3_vtab *pVTab, int);
5358 ** CAPI3REF: Virtual Table Indexing Information
5359 ** KEYWORDS: sqlite3_index_info
5361 ** The sqlite3_index_info structure and its substructures is used as part
5362 ** of the [virtual table] interface to
5363 ** pass information into and receive the reply from the [xBestIndex]
5364 ** method of a [virtual table module]. The fields under **Inputs** are the
5365 ** inputs to xBestIndex and are read-only. xBestIndex inserts its
5366 ** results into the **Outputs** fields.
5368 ** ^(The aConstraint[] array records WHERE clause constraints of the form:
5370 ** <blockquote>column OP expr</blockquote>
5372 ** where OP is =, &lt;, &lt;=, &gt;, or &gt;=.)^ ^(The particular operator is
5373 ** stored in aConstraint[].op using one of the
5374 ** [SQLITE_INDEX_CONSTRAINT_EQ | SQLITE_INDEX_CONSTRAINT_ values].)^
5375 ** ^(The index of the column is stored in
5376 ** aConstraint[].iColumn.)^ ^(aConstraint[].usable is TRUE if the
5377 ** expr on the right-hand side can be evaluated (and thus the constraint
5378 ** is usable) and false if it cannot.)^
5380 ** ^The optimizer automatically inverts terms of the form "expr OP column"
5381 ** and makes other simplifications to the WHERE clause in an attempt to
5382 ** get as many WHERE clause terms into the form shown above as possible.
5383 ** ^The aConstraint[] array only reports WHERE clause terms that are
5384 ** relevant to the particular virtual table being queried.
5386 ** ^Information about the ORDER BY clause is stored in aOrderBy[].
5387 ** ^Each term of aOrderBy records a column of the ORDER BY clause.
5389 ** The [xBestIndex] method must fill aConstraintUsage[] with information
5390 ** about what parameters to pass to xFilter. ^If argvIndex>0 then
5391 ** the right-hand side of the corresponding aConstraint[] is evaluated
5392 ** and becomes the argvIndex-th entry in argv. ^(If aConstraintUsage[].omit
5393 ** is true, then the constraint is assumed to be fully handled by the
5394 ** virtual table and is not checked again by SQLite.)^
5396 ** ^The idxNum and idxPtr values are recorded and passed into the
5397 ** [xFilter] method.
5398 ** ^[sqlite3_free()] is used to free idxPtr if and only if
5399 ** needToFreeIdxPtr is true.
5401 ** ^The orderByConsumed means that output from [xFilter]/[xNext] will occur in
5402 ** the correct order to satisfy the ORDER BY clause so that no separate
5403 ** sorting step is required.
5405 ** ^The estimatedCost value is an estimate of the cost of doing the
5406 ** particular lookup. A full scan of a table with N entries should have
5407 ** a cost of N. A binary search of a table of N entries should have a
5408 ** cost of approximately log(N).
5410 struct sqlite3_index_info {
5411 /* Inputs */
5412 int nConstraint; /* Number of entries in aConstraint */
5413 struct sqlite3_index_constraint {
5414 int iColumn; /* Column on left-hand side of constraint */
5415 unsigned char op; /* Constraint operator */
5416 unsigned char usable; /* True if this constraint is usable */
5417 int iTermOffset; /* Used internally - xBestIndex should ignore */
5418 } *aConstraint; /* Table of WHERE clause constraints */
5419 int nOrderBy; /* Number of terms in the ORDER BY clause */
5420 struct sqlite3_index_orderby {
5421 int iColumn; /* Column number */
5422 unsigned char desc; /* True for DESC. False for ASC. */
5423 } *aOrderBy; /* The ORDER BY clause */
5424 /* Outputs */
5425 struct sqlite3_index_constraint_usage {
5426 int argvIndex; /* if >0, constraint is part of argv to xFilter */
5427 unsigned char omit; /* Do not code a test for this constraint */
5428 } *aConstraintUsage;
5429 int idxNum; /* Number used to identify the index */
5430 char *idxStr; /* String, possibly obtained from sqlite3_malloc */
5431 int needToFreeIdxStr; /* Free idxStr using sqlite3_free() if true */
5432 int orderByConsumed; /* True if output is already ordered */
5433 double estimatedCost; /* Estimated cost of using this index */
5437 ** CAPI3REF: Virtual Table Constraint Operator Codes
5439 ** These macros defined the allowed values for the
5440 ** [sqlite3_index_info].aConstraint[].op field. Each value represents
5441 ** an operator that is part of a constraint term in the wHERE clause of
5442 ** a query that uses a [virtual table].
5444 #define SQLITE_INDEX_CONSTRAINT_EQ 2
5445 #define SQLITE_INDEX_CONSTRAINT_GT 4
5446 #define SQLITE_INDEX_CONSTRAINT_LE 8
5447 #define SQLITE_INDEX_CONSTRAINT_LT 16
5448 #define SQLITE_INDEX_CONSTRAINT_GE 32
5449 #define SQLITE_INDEX_CONSTRAINT_MATCH 64
5452 ** CAPI3REF: Register A Virtual Table Implementation
5454 ** ^These routines are used to register a new [virtual table module] name.
5455 ** ^Module names must be registered before
5456 ** creating a new [virtual table] using the module and before using a
5457 ** preexisting [virtual table] for the module.
5459 ** ^The module name is registered on the [database connection] specified
5460 ** by the first parameter. ^The name of the module is given by the
5461 ** second parameter. ^The third parameter is a pointer to
5462 ** the implementation of the [virtual table module]. ^The fourth
5463 ** parameter is an arbitrary client data pointer that is passed through
5464 ** into the [xCreate] and [xConnect] methods of the virtual table module
5465 ** when a new virtual table is be being created or reinitialized.
5467 ** ^The sqlite3_create_module_v2() interface has a fifth parameter which
5468 ** is a pointer to a destructor for the pClientData. ^SQLite will
5469 ** invoke the destructor function (if it is not NULL) when SQLite
5470 ** no longer needs the pClientData pointer. ^The destructor will also
5471 ** be invoked if the call to sqlite3_create_module_v2() fails.
5472 ** ^The sqlite3_create_module()
5473 ** interface is equivalent to sqlite3_create_module_v2() with a NULL
5474 ** destructor.
5476 SQLITE_API int sqlite3_create_module(
5477 sqlite3 *db, /* SQLite connection to register module with */
5478 const char *zName, /* Name of the module */
5479 const sqlite3_module *p, /* Methods for the module */
5480 void *pClientData /* Client data for xCreate/xConnect */
5482 SQLITE_API int sqlite3_create_module_v2(
5483 sqlite3 *db, /* SQLite connection to register module with */
5484 const char *zName, /* Name of the module */
5485 const sqlite3_module *p, /* Methods for the module */
5486 void *pClientData, /* Client data for xCreate/xConnect */
5487 void(*xDestroy)(void*) /* Module destructor function */
5491 ** CAPI3REF: Virtual Table Instance Object
5492 ** KEYWORDS: sqlite3_vtab
5494 ** Every [virtual table module] implementation uses a subclass
5495 ** of this object to describe a particular instance
5496 ** of the [virtual table]. Each subclass will
5497 ** be tailored to the specific needs of the module implementation.
5498 ** The purpose of this superclass is to define certain fields that are
5499 ** common to all module implementations.
5501 ** ^Virtual tables methods can set an error message by assigning a
5502 ** string obtained from [sqlite3_mprintf()] to zErrMsg. The method should
5503 ** take care that any prior string is freed by a call to [sqlite3_free()]
5504 ** prior to assigning a new string to zErrMsg. ^After the error message
5505 ** is delivered up to the client application, the string will be automatically
5506 ** freed by sqlite3_free() and the zErrMsg field will be zeroed.
5508 struct sqlite3_vtab {
5509 const sqlite3_module *pModule; /* The module for this virtual table */
5510 int nRef; /* NO LONGER USED */
5511 char *zErrMsg; /* Error message from sqlite3_mprintf() */
5512 /* Virtual table implementations will typically add additional fields */
5516 ** CAPI3REF: Virtual Table Cursor Object
5517 ** KEYWORDS: sqlite3_vtab_cursor {virtual table cursor}
5519 ** Every [virtual table module] implementation uses a subclass of the
5520 ** following structure to describe cursors that point into the
5521 ** [virtual table] and are used
5522 ** to loop through the virtual table. Cursors are created using the
5523 ** [sqlite3_module.xOpen | xOpen] method of the module and are destroyed
5524 ** by the [sqlite3_module.xClose | xClose] method. Cursors are used
5525 ** by the [xFilter], [xNext], [xEof], [xColumn], and [xRowid] methods
5526 ** of the module. Each module implementation will define
5527 ** the content of a cursor structure to suit its own needs.
5529 ** This superclass exists in order to define fields of the cursor that
5530 ** are common to all implementations.
5532 struct sqlite3_vtab_cursor {
5533 sqlite3_vtab *pVtab; /* Virtual table of this cursor */
5534 /* Virtual table implementations will typically add additional fields */
5538 ** CAPI3REF: Declare The Schema Of A Virtual Table
5540 ** ^The [xCreate] and [xConnect] methods of a
5541 ** [virtual table module] call this interface
5542 ** to declare the format (the names and datatypes of the columns) of
5543 ** the virtual tables they implement.
5545 SQLITE_API int sqlite3_declare_vtab(sqlite3*, const char *zSQL);
5548 ** CAPI3REF: Overload A Function For A Virtual Table
5550 ** ^(Virtual tables can provide alternative implementations of functions
5551 ** using the [xFindFunction] method of the [virtual table module].
5552 ** But global versions of those functions
5553 ** must exist in order to be overloaded.)^
5555 ** ^(This API makes sure a global version of a function with a particular
5556 ** name and number of parameters exists. If no such function exists
5557 ** before this API is called, a new function is created.)^ ^The implementation
5558 ** of the new function always causes an exception to be thrown. So
5559 ** the new function is not good for anything by itself. Its only
5560 ** purpose is to be a placeholder function that can be overloaded
5561 ** by a [virtual table].
5563 SQLITE_API int sqlite3_overload_function(sqlite3*, const char *zFuncName, int nArg);
5566 ** The interface to the virtual-table mechanism defined above (back up
5567 ** to a comment remarkably similar to this one) is currently considered
5568 ** to be experimental. The interface might change in incompatible ways.
5569 ** If this is a problem for you, do not use the interface at this time.
5571 ** When the virtual-table mechanism stabilizes, we will declare the
5572 ** interface fixed, support it indefinitely, and remove this comment.
5576 ** CAPI3REF: A Handle To An Open BLOB
5577 ** KEYWORDS: {BLOB handle} {BLOB handles}
5579 ** An instance of this object represents an open BLOB on which
5580 ** [sqlite3_blob_open | incremental BLOB I/O] can be performed.
5581 ** ^Objects of this type are created by [sqlite3_blob_open()]
5582 ** and destroyed by [sqlite3_blob_close()].
5583 ** ^The [sqlite3_blob_read()] and [sqlite3_blob_write()] interfaces
5584 ** can be used to read or write small subsections of the BLOB.
5585 ** ^The [sqlite3_blob_bytes()] interface returns the size of the BLOB in bytes.
5587 typedef struct sqlite3_blob sqlite3_blob;
5590 ** CAPI3REF: Open A BLOB For Incremental I/O
5592 ** ^(This interfaces opens a [BLOB handle | handle] to the BLOB located
5593 ** in row iRow, column zColumn, table zTable in database zDb;
5594 ** in other words, the same BLOB that would be selected by:
5596 ** <pre>
5597 ** SELECT zColumn FROM zDb.zTable WHERE [rowid] = iRow;
5598 ** </pre>)^
5600 ** ^If the flags parameter is non-zero, then the BLOB is opened for read
5601 ** and write access. ^If it is zero, the BLOB is opened for read access.
5602 ** ^It is not possible to open a column that is part of an index or primary
5603 ** key for writing. ^If [foreign key constraints] are enabled, it is
5604 ** not possible to open a column that is part of a [child key] for writing.
5606 ** ^Note that the database name is not the filename that contains
5607 ** the database but rather the symbolic name of the database that
5608 ** appears after the AS keyword when the database is connected using [ATTACH].
5609 ** ^For the main database file, the database name is "main".
5610 ** ^For TEMP tables, the database name is "temp".
5612 ** ^(On success, [SQLITE_OK] is returned and the new [BLOB handle] is written
5613 ** to *ppBlob. Otherwise an [error code] is returned and *ppBlob is set
5614 ** to be a null pointer.)^
5615 ** ^This function sets the [database connection] error code and message
5616 ** accessible via [sqlite3_errcode()] and [sqlite3_errmsg()] and related
5617 ** functions. ^Note that the *ppBlob variable is always initialized in a
5618 ** way that makes it safe to invoke [sqlite3_blob_close()] on *ppBlob
5619 ** regardless of the success or failure of this routine.
5621 ** ^(If the row that a BLOB handle points to is modified by an
5622 ** [UPDATE], [DELETE], or by [ON CONFLICT] side-effects
5623 ** then the BLOB handle is marked as "expired".
5624 ** This is true if any column of the row is changed, even a column
5625 ** other than the one the BLOB handle is open on.)^
5626 ** ^Calls to [sqlite3_blob_read()] and [sqlite3_blob_write()] for
5627 ** an expired BLOB handle fail with a return code of [SQLITE_ABORT].
5628 ** ^(Changes written into a BLOB prior to the BLOB expiring are not
5629 ** rolled back by the expiration of the BLOB. Such changes will eventually
5630 ** commit if the transaction continues to completion.)^
5632 ** ^Use the [sqlite3_blob_bytes()] interface to determine the size of
5633 ** the opened blob. ^The size of a blob may not be changed by this
5634 ** interface. Use the [UPDATE] SQL command to change the size of a
5635 ** blob.
5637 ** ^The [sqlite3_bind_zeroblob()] and [sqlite3_result_zeroblob()] interfaces
5638 ** and the built-in [zeroblob] SQL function can be used, if desired,
5639 ** to create an empty, zero-filled blob in which to read or write using
5640 ** this interface.
5642 ** To avoid a resource leak, every open [BLOB handle] should eventually
5643 ** be released by a call to [sqlite3_blob_close()].
5645 SQLITE_API int sqlite3_blob_open(
5646 sqlite3*,
5647 const char *zDb,
5648 const char *zTable,
5649 const char *zColumn,
5650 sqlite3_int64 iRow,
5651 int flags,
5652 sqlite3_blob **ppBlob
5656 ** CAPI3REF: Move a BLOB Handle to a New Row
5658 ** ^This function is used to move an existing blob handle so that it points
5659 ** to a different row of the same database table. ^The new row is identified
5660 ** by the rowid value passed as the second argument. Only the row can be
5661 ** changed. ^The database, table and column on which the blob handle is open
5662 ** remain the same. Moving an existing blob handle to a new row can be
5663 ** faster than closing the existing handle and opening a new one.
5665 ** ^(The new row must meet the same criteria as for [sqlite3_blob_open()] -
5666 ** it must exist and there must be either a blob or text value stored in
5667 ** the nominated column.)^ ^If the new row is not present in the table, or if
5668 ** it does not contain a blob or text value, or if another error occurs, an
5669 ** SQLite error code is returned and the blob handle is considered aborted.
5670 ** ^All subsequent calls to [sqlite3_blob_read()], [sqlite3_blob_write()] or
5671 ** [sqlite3_blob_reopen()] on an aborted blob handle immediately return
5672 ** SQLITE_ABORT. ^Calling [sqlite3_blob_bytes()] on an aborted blob handle
5673 ** always returns zero.
5675 ** ^This function sets the database handle error code and message.
5677 SQLITE_API SQLITE_EXPERIMENTAL int sqlite3_blob_reopen(sqlite3_blob *, sqlite3_int64);
5680 ** CAPI3REF: Close A BLOB Handle
5682 ** ^Closes an open [BLOB handle].
5684 ** ^Closing a BLOB shall cause the current transaction to commit
5685 ** if there are no other BLOBs, no pending prepared statements, and the
5686 ** database connection is in [autocommit mode].
5687 ** ^If any writes were made to the BLOB, they might be held in cache
5688 ** until the close operation if they will fit.
5690 ** ^(Closing the BLOB often forces the changes
5691 ** out to disk and so if any I/O errors occur, they will likely occur
5692 ** at the time when the BLOB is closed. Any errors that occur during
5693 ** closing are reported as a non-zero return value.)^
5695 ** ^(The BLOB is closed unconditionally. Even if this routine returns
5696 ** an error code, the BLOB is still closed.)^
5698 ** ^Calling this routine with a null pointer (such as would be returned
5699 ** by a failed call to [sqlite3_blob_open()]) is a harmless no-op.
5701 SQLITE_API int sqlite3_blob_close(sqlite3_blob *);
5704 ** CAPI3REF: Return The Size Of An Open BLOB
5706 ** ^Returns the size in bytes of the BLOB accessible via the
5707 ** successfully opened [BLOB handle] in its only argument. ^The
5708 ** incremental blob I/O routines can only read or overwriting existing
5709 ** blob content; they cannot change the size of a blob.
5711 ** This routine only works on a [BLOB handle] which has been created
5712 ** by a prior successful call to [sqlite3_blob_open()] and which has not
5713 ** been closed by [sqlite3_blob_close()]. Passing any other pointer in
5714 ** to this routine results in undefined and probably undesirable behavior.
5716 SQLITE_API int sqlite3_blob_bytes(sqlite3_blob *);
5719 ** CAPI3REF: Read Data From A BLOB Incrementally
5721 ** ^(This function is used to read data from an open [BLOB handle] into a
5722 ** caller-supplied buffer. N bytes of data are copied into buffer Z
5723 ** from the open BLOB, starting at offset iOffset.)^
5725 ** ^If offset iOffset is less than N bytes from the end of the BLOB,
5726 ** [SQLITE_ERROR] is returned and no data is read. ^If N or iOffset is
5727 ** less than zero, [SQLITE_ERROR] is returned and no data is read.
5728 ** ^The size of the blob (and hence the maximum value of N+iOffset)
5729 ** can be determined using the [sqlite3_blob_bytes()] interface.
5731 ** ^An attempt to read from an expired [BLOB handle] fails with an
5732 ** error code of [SQLITE_ABORT].
5734 ** ^(On success, sqlite3_blob_read() returns SQLITE_OK.
5735 ** Otherwise, an [error code] or an [extended error code] is returned.)^
5737 ** This routine only works on a [BLOB handle] which has been created
5738 ** by a prior successful call to [sqlite3_blob_open()] and which has not
5739 ** been closed by [sqlite3_blob_close()]. Passing any other pointer in
5740 ** to this routine results in undefined and probably undesirable behavior.
5742 ** See also: [sqlite3_blob_write()].
5744 SQLITE_API int sqlite3_blob_read(sqlite3_blob *, void *Z, int N, int iOffset);
5747 ** CAPI3REF: Write Data Into A BLOB Incrementally
5749 ** ^This function is used to write data into an open [BLOB handle] from a
5750 ** caller-supplied buffer. ^N bytes of data are copied from the buffer Z
5751 ** into the open BLOB, starting at offset iOffset.
5753 ** ^If the [BLOB handle] passed as the first argument was not opened for
5754 ** writing (the flags parameter to [sqlite3_blob_open()] was zero),
5755 ** this function returns [SQLITE_READONLY].
5757 ** ^This function may only modify the contents of the BLOB; it is
5758 ** not possible to increase the size of a BLOB using this API.
5759 ** ^If offset iOffset is less than N bytes from the end of the BLOB,
5760 ** [SQLITE_ERROR] is returned and no data is written. ^If N is
5761 ** less than zero [SQLITE_ERROR] is returned and no data is written.
5762 ** The size of the BLOB (and hence the maximum value of N+iOffset)
5763 ** can be determined using the [sqlite3_blob_bytes()] interface.
5765 ** ^An attempt to write to an expired [BLOB handle] fails with an
5766 ** error code of [SQLITE_ABORT]. ^Writes to the BLOB that occurred
5767 ** before the [BLOB handle] expired are not rolled back by the
5768 ** expiration of the handle, though of course those changes might
5769 ** have been overwritten by the statement that expired the BLOB handle
5770 ** or by other independent statements.
5772 ** ^(On success, sqlite3_blob_write() returns SQLITE_OK.
5773 ** Otherwise, an [error code] or an [extended error code] is returned.)^
5775 ** This routine only works on a [BLOB handle] which has been created
5776 ** by a prior successful call to [sqlite3_blob_open()] and which has not
5777 ** been closed by [sqlite3_blob_close()]. Passing any other pointer in
5778 ** to this routine results in undefined and probably undesirable behavior.
5780 ** See also: [sqlite3_blob_read()].
5782 SQLITE_API int sqlite3_blob_write(sqlite3_blob *, const void *z, int n, int iOffset);
5785 ** CAPI3REF: Virtual File System Objects
5787 ** A virtual filesystem (VFS) is an [sqlite3_vfs] object
5788 ** that SQLite uses to interact
5789 ** with the underlying operating system. Most SQLite builds come with a
5790 ** single default VFS that is appropriate for the host computer.
5791 ** New VFSes can be registered and existing VFSes can be unregistered.
5792 ** The following interfaces are provided.
5794 ** ^The sqlite3_vfs_find() interface returns a pointer to a VFS given its name.
5795 ** ^Names are case sensitive.
5796 ** ^Names are zero-terminated UTF-8 strings.
5797 ** ^If there is no match, a NULL pointer is returned.
5798 ** ^If zVfsName is NULL then the default VFS is returned.
5800 ** ^New VFSes are registered with sqlite3_vfs_register().
5801 ** ^Each new VFS becomes the default VFS if the makeDflt flag is set.
5802 ** ^The same VFS can be registered multiple times without injury.
5803 ** ^To make an existing VFS into the default VFS, register it again
5804 ** with the makeDflt flag set. If two different VFSes with the
5805 ** same name are registered, the behavior is undefined. If a
5806 ** VFS is registered with a name that is NULL or an empty string,
5807 ** then the behavior is undefined.
5809 ** ^Unregister a VFS with the sqlite3_vfs_unregister() interface.
5810 ** ^(If the default VFS is unregistered, another VFS is chosen as
5811 ** the default. The choice for the new VFS is arbitrary.)^
5813 SQLITE_API sqlite3_vfs *sqlite3_vfs_find(const char *zVfsName);
5814 SQLITE_API int sqlite3_vfs_register(sqlite3_vfs*, int makeDflt);
5815 SQLITE_API int sqlite3_vfs_unregister(sqlite3_vfs*);
5818 ** CAPI3REF: Mutexes
5820 ** The SQLite core uses these routines for thread
5821 ** synchronization. Though they are intended for internal
5822 ** use by SQLite, code that links against SQLite is
5823 ** permitted to use any of these routines.
5825 ** The SQLite source code contains multiple implementations
5826 ** of these mutex routines. An appropriate implementation
5827 ** is selected automatically at compile-time. ^(The following
5828 ** implementations are available in the SQLite core:
5830 ** <ul>
5831 ** <li> SQLITE_MUTEX_OS2
5832 ** <li> SQLITE_MUTEX_PTHREAD
5833 ** <li> SQLITE_MUTEX_W32
5834 ** <li> SQLITE_MUTEX_NOOP
5835 ** </ul>)^
5837 ** ^The SQLITE_MUTEX_NOOP implementation is a set of routines
5838 ** that does no real locking and is appropriate for use in
5839 ** a single-threaded application. ^The SQLITE_MUTEX_OS2,
5840 ** SQLITE_MUTEX_PTHREAD, and SQLITE_MUTEX_W32 implementations
5841 ** are appropriate for use on OS/2, Unix, and Windows.
5843 ** ^(If SQLite is compiled with the SQLITE_MUTEX_APPDEF preprocessor
5844 ** macro defined (with "-DSQLITE_MUTEX_APPDEF=1"), then no mutex
5845 ** implementation is included with the library. In this case the
5846 ** application must supply a custom mutex implementation using the
5847 ** [SQLITE_CONFIG_MUTEX] option of the sqlite3_config() function
5848 ** before calling sqlite3_initialize() or any other public sqlite3_
5849 ** function that calls sqlite3_initialize().)^
5851 ** ^The sqlite3_mutex_alloc() routine allocates a new
5852 ** mutex and returns a pointer to it. ^If it returns NULL
5853 ** that means that a mutex could not be allocated. ^SQLite
5854 ** will unwind its stack and return an error. ^(The argument
5855 ** to sqlite3_mutex_alloc() is one of these integer constants:
5857 ** <ul>
5858 ** <li> SQLITE_MUTEX_FAST
5859 ** <li> SQLITE_MUTEX_RECURSIVE
5860 ** <li> SQLITE_MUTEX_STATIC_MASTER
5861 ** <li> SQLITE_MUTEX_STATIC_MEM
5862 ** <li> SQLITE_MUTEX_STATIC_MEM2
5863 ** <li> SQLITE_MUTEX_STATIC_PRNG
5864 ** <li> SQLITE_MUTEX_STATIC_LRU
5865 ** <li> SQLITE_MUTEX_STATIC_LRU2
5866 ** </ul>)^
5868 ** ^The first two constants (SQLITE_MUTEX_FAST and SQLITE_MUTEX_RECURSIVE)
5869 ** cause sqlite3_mutex_alloc() to create
5870 ** a new mutex. ^The new mutex is recursive when SQLITE_MUTEX_RECURSIVE
5871 ** is used but not necessarily so when SQLITE_MUTEX_FAST is used.
5872 ** The mutex implementation does not need to make a distinction
5873 ** between SQLITE_MUTEX_RECURSIVE and SQLITE_MUTEX_FAST if it does
5874 ** not want to. ^SQLite will only request a recursive mutex in
5875 ** cases where it really needs one. ^If a faster non-recursive mutex
5876 ** implementation is available on the host platform, the mutex subsystem
5877 ** might return such a mutex in response to SQLITE_MUTEX_FAST.
5879 ** ^The other allowed parameters to sqlite3_mutex_alloc() (anything other
5880 ** than SQLITE_MUTEX_FAST and SQLITE_MUTEX_RECURSIVE) each return
5881 ** a pointer to a static preexisting mutex. ^Six static mutexes are
5882 ** used by the current version of SQLite. Future versions of SQLite
5883 ** may add additional static mutexes. Static mutexes are for internal
5884 ** use by SQLite only. Applications that use SQLite mutexes should
5885 ** use only the dynamic mutexes returned by SQLITE_MUTEX_FAST or
5886 ** SQLITE_MUTEX_RECURSIVE.
5888 ** ^Note that if one of the dynamic mutex parameters (SQLITE_MUTEX_FAST
5889 ** or SQLITE_MUTEX_RECURSIVE) is used then sqlite3_mutex_alloc()
5890 ** returns a different mutex on every call. ^But for the static
5891 ** mutex types, the same mutex is returned on every call that has
5892 ** the same type number.
5894 ** ^The sqlite3_mutex_free() routine deallocates a previously
5895 ** allocated dynamic mutex. ^SQLite is careful to deallocate every
5896 ** dynamic mutex that it allocates. The dynamic mutexes must not be in
5897 ** use when they are deallocated. Attempting to deallocate a static
5898 ** mutex results in undefined behavior. ^SQLite never deallocates
5899 ** a static mutex.
5901 ** ^The sqlite3_mutex_enter() and sqlite3_mutex_try() routines attempt
5902 ** to enter a mutex. ^If another thread is already within the mutex,
5903 ** sqlite3_mutex_enter() will block and sqlite3_mutex_try() will return
5904 ** SQLITE_BUSY. ^The sqlite3_mutex_try() interface returns [SQLITE_OK]
5905 ** upon successful entry. ^(Mutexes created using
5906 ** SQLITE_MUTEX_RECURSIVE can be entered multiple times by the same thread.
5907 ** In such cases the,
5908 ** mutex must be exited an equal number of times before another thread
5909 ** can enter.)^ ^(If the same thread tries to enter any other
5910 ** kind of mutex more than once, the behavior is undefined.
5911 ** SQLite will never exhibit
5912 ** such behavior in its own use of mutexes.)^
5914 ** ^(Some systems (for example, Windows 95) do not support the operation
5915 ** implemented by sqlite3_mutex_try(). On those systems, sqlite3_mutex_try()
5916 ** will always return SQLITE_BUSY. The SQLite core only ever uses
5917 ** sqlite3_mutex_try() as an optimization so this is acceptable behavior.)^
5919 ** ^The sqlite3_mutex_leave() routine exits a mutex that was
5920 ** previously entered by the same thread. ^(The behavior
5921 ** is undefined if the mutex is not currently entered by the
5922 ** calling thread or is not currently allocated. SQLite will
5923 ** never do either.)^
5925 ** ^If the argument to sqlite3_mutex_enter(), sqlite3_mutex_try(), or
5926 ** sqlite3_mutex_leave() is a NULL pointer, then all three routines
5927 ** behave as no-ops.
5929 ** See also: [sqlite3_mutex_held()] and [sqlite3_mutex_notheld()].
5931 SQLITE_API sqlite3_mutex *sqlite3_mutex_alloc(int);
5932 SQLITE_API void sqlite3_mutex_free(sqlite3_mutex*);
5933 SQLITE_API void sqlite3_mutex_enter(sqlite3_mutex*);
5934 SQLITE_API int sqlite3_mutex_try(sqlite3_mutex*);
5935 SQLITE_API void sqlite3_mutex_leave(sqlite3_mutex*);
5938 ** CAPI3REF: Mutex Methods Object
5940 ** An instance of this structure defines the low-level routines
5941 ** used to allocate and use mutexes.
5943 ** Usually, the default mutex implementations provided by SQLite are
5944 ** sufficient, however the user has the option of substituting a custom
5945 ** implementation for specialized deployments or systems for which SQLite
5946 ** does not provide a suitable implementation. In this case, the user
5947 ** creates and populates an instance of this structure to pass
5948 ** to sqlite3_config() along with the [SQLITE_CONFIG_MUTEX] option.
5949 ** Additionally, an instance of this structure can be used as an
5950 ** output variable when querying the system for the current mutex
5951 ** implementation, using the [SQLITE_CONFIG_GETMUTEX] option.
5953 ** ^The xMutexInit method defined by this structure is invoked as
5954 ** part of system initialization by the sqlite3_initialize() function.
5955 ** ^The xMutexInit routine is called by SQLite exactly once for each
5956 ** effective call to [sqlite3_initialize()].
5958 ** ^The xMutexEnd method defined by this structure is invoked as
5959 ** part of system shutdown by the sqlite3_shutdown() function. The
5960 ** implementation of this method is expected to release all outstanding
5961 ** resources obtained by the mutex methods implementation, especially
5962 ** those obtained by the xMutexInit method. ^The xMutexEnd()
5963 ** interface is invoked exactly once for each call to [sqlite3_shutdown()].
5965 ** ^(The remaining seven methods defined by this structure (xMutexAlloc,
5966 ** xMutexFree, xMutexEnter, xMutexTry, xMutexLeave, xMutexHeld and
5967 ** xMutexNotheld) implement the following interfaces (respectively):
5969 ** <ul>
5970 ** <li> [sqlite3_mutex_alloc()] </li>
5971 ** <li> [sqlite3_mutex_free()] </li>
5972 ** <li> [sqlite3_mutex_enter()] </li>
5973 ** <li> [sqlite3_mutex_try()] </li>
5974 ** <li> [sqlite3_mutex_leave()] </li>
5975 ** <li> [sqlite3_mutex_held()] </li>
5976 ** <li> [sqlite3_mutex_notheld()] </li>
5977 ** </ul>)^
5979 ** The only difference is that the public sqlite3_XXX functions enumerated
5980 ** above silently ignore any invocations that pass a NULL pointer instead
5981 ** of a valid mutex handle. The implementations of the methods defined
5982 ** by this structure are not required to handle this case, the results
5983 ** of passing a NULL pointer instead of a valid mutex handle are undefined
5984 ** (i.e. it is acceptable to provide an implementation that segfaults if
5985 ** it is passed a NULL pointer).
5987 ** The xMutexInit() method must be threadsafe. ^It must be harmless to
5988 ** invoke xMutexInit() multiple times within the same process and without
5989 ** intervening calls to xMutexEnd(). Second and subsequent calls to
5990 ** xMutexInit() must be no-ops.
5992 ** ^xMutexInit() must not use SQLite memory allocation ([sqlite3_malloc()]
5993 ** and its associates). ^Similarly, xMutexAlloc() must not use SQLite memory
5994 ** allocation for a static mutex. ^However xMutexAlloc() may use SQLite
5995 ** memory allocation for a fast or recursive mutex.
5997 ** ^SQLite will invoke the xMutexEnd() method when [sqlite3_shutdown()] is
5998 ** called, but only if the prior call to xMutexInit returned SQLITE_OK.
5999 ** If xMutexInit fails in any way, it is expected to clean up after itself
6000 ** prior to returning.
6002 typedef struct sqlite3_mutex_methods sqlite3_mutex_methods;
6003 struct sqlite3_mutex_methods {
6004 int (*xMutexInit)(void);
6005 int (*xMutexEnd)(void);
6006 sqlite3_mutex *(*xMutexAlloc)(int);
6007 void (*xMutexFree)(sqlite3_mutex *);
6008 void (*xMutexEnter)(sqlite3_mutex *);
6009 int (*xMutexTry)(sqlite3_mutex *);
6010 void (*xMutexLeave)(sqlite3_mutex *);
6011 int (*xMutexHeld)(sqlite3_mutex *);
6012 int (*xMutexNotheld)(sqlite3_mutex *);
6016 ** CAPI3REF: Mutex Verification Routines
6018 ** The sqlite3_mutex_held() and sqlite3_mutex_notheld() routines
6019 ** are intended for use inside assert() statements. ^The SQLite core
6020 ** never uses these routines except inside an assert() and applications
6021 ** are advised to follow the lead of the core. ^The SQLite core only
6022 ** provides implementations for these routines when it is compiled
6023 ** with the SQLITE_DEBUG flag. ^External mutex implementations
6024 ** are only required to provide these routines if SQLITE_DEBUG is
6025 ** defined and if NDEBUG is not defined.
6027 ** ^These routines should return true if the mutex in their argument
6028 ** is held or not held, respectively, by the calling thread.
6030 ** ^The implementation is not required to provided versions of these
6031 ** routines that actually work. If the implementation does not provide working
6032 ** versions of these routines, it should at least provide stubs that always
6033 ** return true so that one does not get spurious assertion failures.
6035 ** ^If the argument to sqlite3_mutex_held() is a NULL pointer then
6036 ** the routine should return 1. This seems counter-intuitive since
6037 ** clearly the mutex cannot be held if it does not exist. But
6038 ** the reason the mutex does not exist is because the build is not
6039 ** using mutexes. And we do not want the assert() containing the
6040 ** call to sqlite3_mutex_held() to fail, so a non-zero return is
6041 ** the appropriate thing to do. ^The sqlite3_mutex_notheld()
6042 ** interface should also return 1 when given a NULL pointer.
6044 #ifndef NDEBUG
6045 SQLITE_API int sqlite3_mutex_held(sqlite3_mutex*);
6046 SQLITE_API int sqlite3_mutex_notheld(sqlite3_mutex*);
6047 #endif
6050 ** CAPI3REF: Mutex Types
6052 ** The [sqlite3_mutex_alloc()] interface takes a single argument
6053 ** which is one of these integer constants.
6055 ** The set of static mutexes may change from one SQLite release to the
6056 ** next. Applications that override the built-in mutex logic must be
6057 ** prepared to accommodate additional static mutexes.
6059 #define SQLITE_MUTEX_FAST 0
6060 #define SQLITE_MUTEX_RECURSIVE 1
6061 #define SQLITE_MUTEX_STATIC_MASTER 2
6062 #define SQLITE_MUTEX_STATIC_MEM 3 /* sqlite3_malloc() */
6063 #define SQLITE_MUTEX_STATIC_MEM2 4 /* NOT USED */
6064 #define SQLITE_MUTEX_STATIC_OPEN 4 /* sqlite3BtreeOpen() */
6065 #define SQLITE_MUTEX_STATIC_PRNG 5 /* sqlite3_random() */
6066 #define SQLITE_MUTEX_STATIC_LRU 6 /* lru page list */
6067 #define SQLITE_MUTEX_STATIC_LRU2 7 /* NOT USED */
6068 #define SQLITE_MUTEX_STATIC_PMEM 7 /* sqlite3PageMalloc() */
6071 ** CAPI3REF: Retrieve the mutex for a database connection
6073 ** ^This interface returns a pointer the [sqlite3_mutex] object that
6074 ** serializes access to the [database connection] given in the argument
6075 ** when the [threading mode] is Serialized.
6076 ** ^If the [threading mode] is Single-thread or Multi-thread then this
6077 ** routine returns a NULL pointer.
6079 SQLITE_API sqlite3_mutex *sqlite3_db_mutex(sqlite3*);
6082 ** CAPI3REF: Low-Level Control Of Database Files
6084 ** ^The [sqlite3_file_control()] interface makes a direct call to the
6085 ** xFileControl method for the [sqlite3_io_methods] object associated
6086 ** with a particular database identified by the second argument. ^The
6087 ** name of the database is "main" for the main database or "temp" for the
6088 ** TEMP database, or the name that appears after the AS keyword for
6089 ** databases that are added using the [ATTACH] SQL command.
6090 ** ^A NULL pointer can be used in place of "main" to refer to the
6091 ** main database file.
6092 ** ^The third and fourth parameters to this routine
6093 ** are passed directly through to the second and third parameters of
6094 ** the xFileControl method. ^The return value of the xFileControl
6095 ** method becomes the return value of this routine.
6097 ** ^The SQLITE_FCNTL_FILE_POINTER value for the op parameter causes
6098 ** a pointer to the underlying [sqlite3_file] object to be written into
6099 ** the space pointed to by the 4th parameter. ^The SQLITE_FCNTL_FILE_POINTER
6100 ** case is a short-circuit path which does not actually invoke the
6101 ** underlying sqlite3_io_methods.xFileControl method.
6103 ** ^If the second parameter (zDbName) does not match the name of any
6104 ** open database file, then SQLITE_ERROR is returned. ^This error
6105 ** code is not remembered and will not be recalled by [sqlite3_errcode()]
6106 ** or [sqlite3_errmsg()]. The underlying xFileControl method might
6107 ** also return SQLITE_ERROR. There is no way to distinguish between
6108 ** an incorrect zDbName and an SQLITE_ERROR return from the underlying
6109 ** xFileControl method.
6111 ** See also: [SQLITE_FCNTL_LOCKSTATE]
6113 SQLITE_API int sqlite3_file_control(sqlite3*, const char *zDbName, int op, void*);
6116 ** CAPI3REF: Testing Interface
6118 ** ^The sqlite3_test_control() interface is used to read out internal
6119 ** state of SQLite and to inject faults into SQLite for testing
6120 ** purposes. ^The first parameter is an operation code that determines
6121 ** the number, meaning, and operation of all subsequent parameters.
6123 ** This interface is not for use by applications. It exists solely
6124 ** for verifying the correct operation of the SQLite library. Depending
6125 ** on how the SQLite library is compiled, this interface might not exist.
6127 ** The details of the operation codes, their meanings, the parameters
6128 ** they take, and what they do are all subject to change without notice.
6129 ** Unlike most of the SQLite API, this function is not guaranteed to
6130 ** operate consistently from one release to the next.
6132 SQLITE_API int sqlite3_test_control(int op, ...);
6135 ** CAPI3REF: Testing Interface Operation Codes
6137 ** These constants are the valid operation code parameters used
6138 ** as the first argument to [sqlite3_test_control()].
6140 ** These parameters and their meanings are subject to change
6141 ** without notice. These values are for testing purposes only.
6142 ** Applications should not use any of these parameters or the
6143 ** [sqlite3_test_control()] interface.
6145 #define SQLITE_TESTCTRL_FIRST 5
6146 #define SQLITE_TESTCTRL_PRNG_SAVE 5
6147 #define SQLITE_TESTCTRL_PRNG_RESTORE 6
6148 #define SQLITE_TESTCTRL_PRNG_RESET 7
6149 #define SQLITE_TESTCTRL_BITVEC_TEST 8
6150 #define SQLITE_TESTCTRL_FAULT_INSTALL 9
6151 #define SQLITE_TESTCTRL_BENIGN_MALLOC_HOOKS 10
6152 #define SQLITE_TESTCTRL_PENDING_BYTE 11
6153 #define SQLITE_TESTCTRL_ASSERT 12
6154 #define SQLITE_TESTCTRL_ALWAYS 13
6155 #define SQLITE_TESTCTRL_RESERVE 14
6156 #define SQLITE_TESTCTRL_OPTIMIZATIONS 15
6157 #define SQLITE_TESTCTRL_ISKEYWORD 16
6158 #define SQLITE_TESTCTRL_PGHDRSZ 17
6159 #define SQLITE_TESTCTRL_SCRATCHMALLOC 18
6160 #define SQLITE_TESTCTRL_LOCALTIME_FAULT 19
6161 #define SQLITE_TESTCTRL_LAST 19
6164 ** CAPI3REF: SQLite Runtime Status
6166 ** ^This interface is used to retrieve runtime status information
6167 ** about the performance of SQLite, and optionally to reset various
6168 ** highwater marks. ^The first argument is an integer code for
6169 ** the specific parameter to measure. ^(Recognized integer codes
6170 ** are of the form [status parameters | SQLITE_STATUS_...].)^
6171 ** ^The current value of the parameter is returned into *pCurrent.
6172 ** ^The highest recorded value is returned in *pHighwater. ^If the
6173 ** resetFlag is true, then the highest record value is reset after
6174 ** *pHighwater is written. ^(Some parameters do not record the highest
6175 ** value. For those parameters
6176 ** nothing is written into *pHighwater and the resetFlag is ignored.)^
6177 ** ^(Other parameters record only the highwater mark and not the current
6178 ** value. For these latter parameters nothing is written into *pCurrent.)^
6180 ** ^The sqlite3_status() routine returns SQLITE_OK on success and a
6181 ** non-zero [error code] on failure.
6183 ** This routine is threadsafe but is not atomic. This routine can be
6184 ** called while other threads are running the same or different SQLite
6185 ** interfaces. However the values returned in *pCurrent and
6186 ** *pHighwater reflect the status of SQLite at different points in time
6187 ** and it is possible that another thread might change the parameter
6188 ** in between the times when *pCurrent and *pHighwater are written.
6190 ** See also: [sqlite3_db_status()]
6192 SQLITE_API int sqlite3_status(int op, int *pCurrent, int *pHighwater, int resetFlag);
6196 ** CAPI3REF: Status Parameters
6197 ** KEYWORDS: {status parameters}
6199 ** These integer constants designate various run-time status parameters
6200 ** that can be returned by [sqlite3_status()].
6202 ** <dl>
6203 ** [[SQLITE_STATUS_MEMORY_USED]] ^(<dt>SQLITE_STATUS_MEMORY_USED</dt>
6204 ** <dd>This parameter is the current amount of memory checked out
6205 ** using [sqlite3_malloc()], either directly or indirectly. The
6206 ** figure includes calls made to [sqlite3_malloc()] by the application
6207 ** and internal memory usage by the SQLite library. Scratch memory
6208 ** controlled by [SQLITE_CONFIG_SCRATCH] and auxiliary page-cache
6209 ** memory controlled by [SQLITE_CONFIG_PAGECACHE] is not included in
6210 ** this parameter. The amount returned is the sum of the allocation
6211 ** sizes as reported by the xSize method in [sqlite3_mem_methods].</dd>)^
6213 ** [[SQLITE_STATUS_MALLOC_SIZE]] ^(<dt>SQLITE_STATUS_MALLOC_SIZE</dt>
6214 ** <dd>This parameter records the largest memory allocation request
6215 ** handed to [sqlite3_malloc()] or [sqlite3_realloc()] (or their
6216 ** internal equivalents). Only the value returned in the
6217 ** *pHighwater parameter to [sqlite3_status()] is of interest.
6218 ** The value written into the *pCurrent parameter is undefined.</dd>)^
6220 ** [[SQLITE_STATUS_MALLOC_COUNT]] ^(<dt>SQLITE_STATUS_MALLOC_COUNT</dt>
6221 ** <dd>This parameter records the number of separate memory allocations
6222 ** currently checked out.</dd>)^
6224 ** [[SQLITE_STATUS_PAGECACHE_USED]] ^(<dt>SQLITE_STATUS_PAGECACHE_USED</dt>
6225 ** <dd>This parameter returns the number of pages used out of the
6226 ** [pagecache memory allocator] that was configured using
6227 ** [SQLITE_CONFIG_PAGECACHE]. The
6228 ** value returned is in pages, not in bytes.</dd>)^
6230 ** [[SQLITE_STATUS_PAGECACHE_OVERFLOW]]
6231 ** ^(<dt>SQLITE_STATUS_PAGECACHE_OVERFLOW</dt>
6232 ** <dd>This parameter returns the number of bytes of page cache
6233 ** allocation which could not be satisfied by the [SQLITE_CONFIG_PAGECACHE]
6234 ** buffer and where forced to overflow to [sqlite3_malloc()]. The
6235 ** returned value includes allocations that overflowed because they
6236 ** where too large (they were larger than the "sz" parameter to
6237 ** [SQLITE_CONFIG_PAGECACHE]) and allocations that overflowed because
6238 ** no space was left in the page cache.</dd>)^
6240 ** [[SQLITE_STATUS_PAGECACHE_SIZE]] ^(<dt>SQLITE_STATUS_PAGECACHE_SIZE</dt>
6241 ** <dd>This parameter records the largest memory allocation request
6242 ** handed to [pagecache memory allocator]. Only the value returned in the
6243 ** *pHighwater parameter to [sqlite3_status()] is of interest.
6244 ** The value written into the *pCurrent parameter is undefined.</dd>)^
6246 ** [[SQLITE_STATUS_SCRATCH_USED]] ^(<dt>SQLITE_STATUS_SCRATCH_USED</dt>
6247 ** <dd>This parameter returns the number of allocations used out of the
6248 ** [scratch memory allocator] configured using
6249 ** [SQLITE_CONFIG_SCRATCH]. The value returned is in allocations, not
6250 ** in bytes. Since a single thread may only have one scratch allocation
6251 ** outstanding at time, this parameter also reports the number of threads
6252 ** using scratch memory at the same time.</dd>)^
6254 ** [[SQLITE_STATUS_SCRATCH_OVERFLOW]] ^(<dt>SQLITE_STATUS_SCRATCH_OVERFLOW</dt>
6255 ** <dd>This parameter returns the number of bytes of scratch memory
6256 ** allocation which could not be satisfied by the [SQLITE_CONFIG_SCRATCH]
6257 ** buffer and where forced to overflow to [sqlite3_malloc()]. The values
6258 ** returned include overflows because the requested allocation was too
6259 ** larger (that is, because the requested allocation was larger than the
6260 ** "sz" parameter to [SQLITE_CONFIG_SCRATCH]) and because no scratch buffer
6261 ** slots were available.
6262 ** </dd>)^
6264 ** [[SQLITE_STATUS_SCRATCH_SIZE]] ^(<dt>SQLITE_STATUS_SCRATCH_SIZE</dt>
6265 ** <dd>This parameter records the largest memory allocation request
6266 ** handed to [scratch memory allocator]. Only the value returned in the
6267 ** *pHighwater parameter to [sqlite3_status()] is of interest.
6268 ** The value written into the *pCurrent parameter is undefined.</dd>)^
6270 ** [[SQLITE_STATUS_PARSER_STACK]] ^(<dt>SQLITE_STATUS_PARSER_STACK</dt>
6271 ** <dd>This parameter records the deepest parser stack. It is only
6272 ** meaningful if SQLite is compiled with [YYTRACKMAXSTACKDEPTH].</dd>)^
6273 ** </dl>
6275 ** New status parameters may be added from time to time.
6277 #define SQLITE_STATUS_MEMORY_USED 0
6278 #define SQLITE_STATUS_PAGECACHE_USED 1
6279 #define SQLITE_STATUS_PAGECACHE_OVERFLOW 2
6280 #define SQLITE_STATUS_SCRATCH_USED 3
6281 #define SQLITE_STATUS_SCRATCH_OVERFLOW 4
6282 #define SQLITE_STATUS_MALLOC_SIZE 5
6283 #define SQLITE_STATUS_PARSER_STACK 6
6284 #define SQLITE_STATUS_PAGECACHE_SIZE 7
6285 #define SQLITE_STATUS_SCRATCH_SIZE 8
6286 #define SQLITE_STATUS_MALLOC_COUNT 9
6289 ** CAPI3REF: Database Connection Status
6291 ** ^This interface is used to retrieve runtime status information
6292 ** about a single [database connection]. ^The first argument is the
6293 ** database connection object to be interrogated. ^The second argument
6294 ** is an integer constant, taken from the set of
6295 ** [SQLITE_DBSTATUS options], that
6296 ** determines the parameter to interrogate. The set of
6297 ** [SQLITE_DBSTATUS options] is likely
6298 ** to grow in future releases of SQLite.
6300 ** ^The current value of the requested parameter is written into *pCur
6301 ** and the highest instantaneous value is written into *pHiwtr. ^If
6302 ** the resetFlg is true, then the highest instantaneous value is
6303 ** reset back down to the current value.
6305 ** ^The sqlite3_db_status() routine returns SQLITE_OK on success and a
6306 ** non-zero [error code] on failure.
6308 ** See also: [sqlite3_status()] and [sqlite3_stmt_status()].
6310 SQLITE_API int sqlite3_db_status(sqlite3*, int op, int *pCur, int *pHiwtr, int resetFlg);
6313 ** CAPI3REF: Status Parameters for database connections
6314 ** KEYWORDS: {SQLITE_DBSTATUS options}
6316 ** These constants are the available integer "verbs" that can be passed as
6317 ** the second argument to the [sqlite3_db_status()] interface.
6319 ** New verbs may be added in future releases of SQLite. Existing verbs
6320 ** might be discontinued. Applications should check the return code from
6321 ** [sqlite3_db_status()] to make sure that the call worked.
6322 ** The [sqlite3_db_status()] interface will return a non-zero error code
6323 ** if a discontinued or unsupported verb is invoked.
6325 ** <dl>
6326 ** [[SQLITE_DBSTATUS_LOOKASIDE_USED]] ^(<dt>SQLITE_DBSTATUS_LOOKASIDE_USED</dt>
6327 ** <dd>This parameter returns the number of lookaside memory slots currently
6328 ** checked out.</dd>)^
6330 ** [[SQLITE_DBSTATUS_LOOKASIDE_HIT]] ^(<dt>SQLITE_DBSTATUS_LOOKASIDE_HIT</dt>
6331 ** <dd>This parameter returns the number malloc attempts that were
6332 ** satisfied using lookaside memory. Only the high-water value is meaningful;
6333 ** the current value is always zero.)^
6335 ** [[SQLITE_DBSTATUS_LOOKASIDE_MISS_SIZE]]
6336 ** ^(<dt>SQLITE_DBSTATUS_LOOKASIDE_MISS_SIZE</dt>
6337 ** <dd>This parameter returns the number malloc attempts that might have
6338 ** been satisfied using lookaside memory but failed due to the amount of
6339 ** memory requested being larger than the lookaside slot size.
6340 ** Only the high-water value is meaningful;
6341 ** the current value is always zero.)^
6343 ** [[SQLITE_DBSTATUS_LOOKASIDE_MISS_FULL]]
6344 ** ^(<dt>SQLITE_DBSTATUS_LOOKASIDE_MISS_FULL</dt>
6345 ** <dd>This parameter returns the number malloc attempts that might have
6346 ** been satisfied using lookaside memory but failed due to all lookaside
6347 ** memory already being in use.
6348 ** Only the high-water value is meaningful;
6349 ** the current value is always zero.)^
6351 ** [[SQLITE_DBSTATUS_CACHE_USED]] ^(<dt>SQLITE_DBSTATUS_CACHE_USED</dt>
6352 ** <dd>This parameter returns the approximate number of of bytes of heap
6353 ** memory used by all pager caches associated with the database connection.)^
6354 ** ^The highwater mark associated with SQLITE_DBSTATUS_CACHE_USED is always 0.
6356 ** [[SQLITE_DBSTATUS_SCHEMA_USED]] ^(<dt>SQLITE_DBSTATUS_SCHEMA_USED</dt>
6357 ** <dd>This parameter returns the approximate number of of bytes of heap
6358 ** memory used to store the schema for all databases associated
6359 ** with the connection - main, temp, and any [ATTACH]-ed databases.)^
6360 ** ^The full amount of memory used by the schemas is reported, even if the
6361 ** schema memory is shared with other database connections due to
6362 ** [shared cache mode] being enabled.
6363 ** ^The highwater mark associated with SQLITE_DBSTATUS_SCHEMA_USED is always 0.
6365 ** [[SQLITE_DBSTATUS_STMT_USED]] ^(<dt>SQLITE_DBSTATUS_STMT_USED</dt>
6366 ** <dd>This parameter returns the approximate number of of bytes of heap
6367 ** and lookaside memory used by all prepared statements associated with
6368 ** the database connection.)^
6369 ** ^The highwater mark associated with SQLITE_DBSTATUS_STMT_USED is always 0.
6370 ** </dd>
6371 ** </dl>
6373 #define SQLITE_DBSTATUS_LOOKASIDE_USED 0
6374 #define SQLITE_DBSTATUS_CACHE_USED 1
6375 #define SQLITE_DBSTATUS_SCHEMA_USED 2
6376 #define SQLITE_DBSTATUS_STMT_USED 3
6377 #define SQLITE_DBSTATUS_LOOKASIDE_HIT 4
6378 #define SQLITE_DBSTATUS_LOOKASIDE_MISS_SIZE 5
6379 #define SQLITE_DBSTATUS_LOOKASIDE_MISS_FULL 6
6380 #define SQLITE_DBSTATUS_MAX 6 /* Largest defined DBSTATUS */
6384 ** CAPI3REF: Prepared Statement Status
6386 ** ^(Each prepared statement maintains various
6387 ** [SQLITE_STMTSTATUS counters] that measure the number
6388 ** of times it has performed specific operations.)^ These counters can
6389 ** be used to monitor the performance characteristics of the prepared
6390 ** statements. For example, if the number of table steps greatly exceeds
6391 ** the number of table searches or result rows, that would tend to indicate
6392 ** that the prepared statement is using a full table scan rather than
6393 ** an index.
6395 ** ^(This interface is used to retrieve and reset counter values from
6396 ** a [prepared statement]. The first argument is the prepared statement
6397 ** object to be interrogated. The second argument
6398 ** is an integer code for a specific [SQLITE_STMTSTATUS counter]
6399 ** to be interrogated.)^
6400 ** ^The current value of the requested counter is returned.
6401 ** ^If the resetFlg is true, then the counter is reset to zero after this
6402 ** interface call returns.
6404 ** See also: [sqlite3_status()] and [sqlite3_db_status()].
6406 SQLITE_API int sqlite3_stmt_status(sqlite3_stmt*, int op,int resetFlg);
6409 ** CAPI3REF: Status Parameters for prepared statements
6410 ** KEYWORDS: {SQLITE_STMTSTATUS counter} {SQLITE_STMTSTATUS counters}
6412 ** These preprocessor macros define integer codes that name counter
6413 ** values associated with the [sqlite3_stmt_status()] interface.
6414 ** The meanings of the various counters are as follows:
6416 ** <dl>
6417 ** [[SQLITE_STMTSTATUS_FULLSCAN_STEP]] <dt>SQLITE_STMTSTATUS_FULLSCAN_STEP</dt>
6418 ** <dd>^This is the number of times that SQLite has stepped forward in
6419 ** a table as part of a full table scan. Large numbers for this counter
6420 ** may indicate opportunities for performance improvement through
6421 ** careful use of indices.</dd>
6423 ** [[SQLITE_STMTSTATUS_SORT]] <dt>SQLITE_STMTSTATUS_SORT</dt>
6424 ** <dd>^This is the number of sort operations that have occurred.
6425 ** A non-zero value in this counter may indicate an opportunity to
6426 ** improvement performance through careful use of indices.</dd>
6428 ** [[SQLITE_STMTSTATUS_AUTOINDEX]] <dt>SQLITE_STMTSTATUS_AUTOINDEX</dt>
6429 ** <dd>^This is the number of rows inserted into transient indices that
6430 ** were created automatically in order to help joins run faster.
6431 ** A non-zero value in this counter may indicate an opportunity to
6432 ** improvement performance by adding permanent indices that do not
6433 ** need to be reinitialized each time the statement is run.</dd>
6435 ** </dl>
6437 #define SQLITE_STMTSTATUS_FULLSCAN_STEP 1
6438 #define SQLITE_STMTSTATUS_SORT 2
6439 #define SQLITE_STMTSTATUS_AUTOINDEX 3
6442 ** CAPI3REF: Custom Page Cache Object
6444 ** The sqlite3_pcache type is opaque. It is implemented by
6445 ** the pluggable module. The SQLite core has no knowledge of
6446 ** its size or internal structure and never deals with the
6447 ** sqlite3_pcache object except by holding and passing pointers
6448 ** to the object.
6450 ** See [sqlite3_pcache_methods] for additional information.
6452 typedef struct sqlite3_pcache sqlite3_pcache;
6455 ** CAPI3REF: Application Defined Page Cache.
6456 ** KEYWORDS: {page cache}
6458 ** ^(The [sqlite3_config]([SQLITE_CONFIG_PCACHE], ...) interface can
6459 ** register an alternative page cache implementation by passing in an
6460 ** instance of the sqlite3_pcache_methods structure.)^
6461 ** In many applications, most of the heap memory allocated by
6462 ** SQLite is used for the page cache.
6463 ** By implementing a
6464 ** custom page cache using this API, an application can better control
6465 ** the amount of memory consumed by SQLite, the way in which
6466 ** that memory is allocated and released, and the policies used to
6467 ** determine exactly which parts of a database file are cached and for
6468 ** how long.
6470 ** The alternative page cache mechanism is an
6471 ** extreme measure that is only needed by the most demanding applications.
6472 ** The built-in page cache is recommended for most uses.
6474 ** ^(The contents of the sqlite3_pcache_methods structure are copied to an
6475 ** internal buffer by SQLite within the call to [sqlite3_config]. Hence
6476 ** the application may discard the parameter after the call to
6477 ** [sqlite3_config()] returns.)^
6479 ** [[the xInit() page cache method]]
6480 ** ^(The xInit() method is called once for each effective
6481 ** call to [sqlite3_initialize()])^
6482 ** (usually only once during the lifetime of the process). ^(The xInit()
6483 ** method is passed a copy of the sqlite3_pcache_methods.pArg value.)^
6484 ** The intent of the xInit() method is to set up global data structures
6485 ** required by the custom page cache implementation.
6486 ** ^(If the xInit() method is NULL, then the
6487 ** built-in default page cache is used instead of the application defined
6488 ** page cache.)^
6490 ** [[the xShutdown() page cache method]]
6491 ** ^The xShutdown() method is called by [sqlite3_shutdown()].
6492 ** It can be used to clean up
6493 ** any outstanding resources before process shutdown, if required.
6494 ** ^The xShutdown() method may be NULL.
6496 ** ^SQLite automatically serializes calls to the xInit method,
6497 ** so the xInit method need not be threadsafe. ^The
6498 ** xShutdown method is only called from [sqlite3_shutdown()] so it does
6499 ** not need to be threadsafe either. All other methods must be threadsafe
6500 ** in multithreaded applications.
6502 ** ^SQLite will never invoke xInit() more than once without an intervening
6503 ** call to xShutdown().
6505 ** [[the xCreate() page cache methods]]
6506 ** ^SQLite invokes the xCreate() method to construct a new cache instance.
6507 ** SQLite will typically create one cache instance for each open database file,
6508 ** though this is not guaranteed. ^The
6509 ** first parameter, szPage, is the size in bytes of the pages that must
6510 ** be allocated by the cache. ^szPage will not be a power of two. ^szPage
6511 ** will the page size of the database file that is to be cached plus an
6512 ** increment (here called "R") of less than 250. SQLite will use the
6513 ** extra R bytes on each page to store metadata about the underlying
6514 ** database page on disk. The value of R depends
6515 ** on the SQLite version, the target platform, and how SQLite was compiled.
6516 ** ^(R is constant for a particular build of SQLite. Except, there are two
6517 ** distinct values of R when SQLite is compiled with the proprietary
6518 ** ZIPVFS extension.)^ ^The second argument to
6519 ** xCreate(), bPurgeable, is true if the cache being created will
6520 ** be used to cache database pages of a file stored on disk, or
6521 ** false if it is used for an in-memory database. The cache implementation
6522 ** does not have to do anything special based with the value of bPurgeable;
6523 ** it is purely advisory. ^On a cache where bPurgeable is false, SQLite will
6524 ** never invoke xUnpin() except to deliberately delete a page.
6525 ** ^In other words, calls to xUnpin() on a cache with bPurgeable set to
6526 ** false will always have the "discard" flag set to true.
6527 ** ^Hence, a cache created with bPurgeable false will
6528 ** never contain any unpinned pages.
6530 ** [[the xCachesize() page cache method]]
6531 ** ^(The xCachesize() method may be called at any time by SQLite to set the
6532 ** suggested maximum cache-size (number of pages stored by) the cache
6533 ** instance passed as the first argument. This is the value configured using
6534 ** the SQLite "[PRAGMA cache_size]" command.)^ As with the bPurgeable
6535 ** parameter, the implementation is not required to do anything with this
6536 ** value; it is advisory only.
6538 ** [[the xPagecount() page cache methods]]
6539 ** The xPagecount() method must return the number of pages currently
6540 ** stored in the cache, both pinned and unpinned.
6542 ** [[the xFetch() page cache methods]]
6543 ** The xFetch() method locates a page in the cache and returns a pointer to
6544 ** the page, or a NULL pointer.
6545 ** A "page", in this context, means a buffer of szPage bytes aligned at an
6546 ** 8-byte boundary. The page to be fetched is determined by the key. ^The
6547 ** minimum key value is 1. After it has been retrieved using xFetch, the page
6548 ** is considered to be "pinned".
6550 ** If the requested page is already in the page cache, then the page cache
6551 ** implementation must return a pointer to the page buffer with its content
6552 ** intact. If the requested page is not already in the cache, then the
6553 ** cache implementation should use the value of the createFlag
6554 ** parameter to help it determined what action to take:
6556 ** <table border=1 width=85% align=center>
6557 ** <tr><th> createFlag <th> Behaviour when page is not already in cache
6558 ** <tr><td> 0 <td> Do not allocate a new page. Return NULL.
6559 ** <tr><td> 1 <td> Allocate a new page if it easy and convenient to do so.
6560 ** Otherwise return NULL.
6561 ** <tr><td> 2 <td> Make every effort to allocate a new page. Only return
6562 ** NULL if allocating a new page is effectively impossible.
6563 ** </table>
6565 ** ^(SQLite will normally invoke xFetch() with a createFlag of 0 or 1. SQLite
6566 ** will only use a createFlag of 2 after a prior call with a createFlag of 1
6567 ** failed.)^ In between the to xFetch() calls, SQLite may
6568 ** attempt to unpin one or more cache pages by spilling the content of
6569 ** pinned pages to disk and synching the operating system disk cache.
6571 ** [[the xUnpin() page cache method]]
6572 ** ^xUnpin() is called by SQLite with a pointer to a currently pinned page
6573 ** as its second argument. If the third parameter, discard, is non-zero,
6574 ** then the page must be evicted from the cache.
6575 ** ^If the discard parameter is
6576 ** zero, then the page may be discarded or retained at the discretion of
6577 ** page cache implementation. ^The page cache implementation
6578 ** may choose to evict unpinned pages at any time.
6580 ** The cache must not perform any reference counting. A single
6581 ** call to xUnpin() unpins the page regardless of the number of prior calls
6582 ** to xFetch().
6584 ** [[the xRekey() page cache methods]]
6585 ** The xRekey() method is used to change the key value associated with the
6586 ** page passed as the second argument. If the cache
6587 ** previously contains an entry associated with newKey, it must be
6588 ** discarded. ^Any prior cache entry associated with newKey is guaranteed not
6589 ** to be pinned.
6591 ** When SQLite calls the xTruncate() method, the cache must discard all
6592 ** existing cache entries with page numbers (keys) greater than or equal
6593 ** to the value of the iLimit parameter passed to xTruncate(). If any
6594 ** of these pages are pinned, they are implicitly unpinned, meaning that
6595 ** they can be safely discarded.
6597 ** [[the xDestroy() page cache method]]
6598 ** ^The xDestroy() method is used to delete a cache allocated by xCreate().
6599 ** All resources associated with the specified cache should be freed. ^After
6600 ** calling the xDestroy() method, SQLite considers the [sqlite3_pcache*]
6601 ** handle invalid, and will not use it with any other sqlite3_pcache_methods
6602 ** functions.
6604 typedef struct sqlite3_pcache_methods sqlite3_pcache_methods;
6605 struct sqlite3_pcache_methods {
6606 void *pArg;
6607 int (*xInit)(void*);
6608 void (*xShutdown)(void*);
6609 sqlite3_pcache *(*xCreate)(int szPage, int bPurgeable);
6610 void (*xCachesize)(sqlite3_pcache*, int nCachesize);
6611 int (*xPagecount)(sqlite3_pcache*);
6612 void *(*xFetch)(sqlite3_pcache*, unsigned key, int createFlag);
6613 void (*xUnpin)(sqlite3_pcache*, void*, int discard);
6614 void (*xRekey)(sqlite3_pcache*, void*, unsigned oldKey, unsigned newKey);
6615 void (*xTruncate)(sqlite3_pcache*, unsigned iLimit);
6616 void (*xDestroy)(sqlite3_pcache*);
6620 ** CAPI3REF: Online Backup Object
6622 ** The sqlite3_backup object records state information about an ongoing
6623 ** online backup operation. ^The sqlite3_backup object is created by
6624 ** a call to [sqlite3_backup_init()] and is destroyed by a call to
6625 ** [sqlite3_backup_finish()].
6627 ** See Also: [Using the SQLite Online Backup API]
6629 typedef struct sqlite3_backup sqlite3_backup;
6632 ** CAPI3REF: Online Backup API.
6634 ** The backup API copies the content of one database into another.
6635 ** It is useful either for creating backups of databases or
6636 ** for copying in-memory databases to or from persistent files.
6638 ** See Also: [Using the SQLite Online Backup API]
6640 ** ^SQLite holds a write transaction open on the destination database file
6641 ** for the duration of the backup operation.
6642 ** ^The source database is read-locked only while it is being read;
6643 ** it is not locked continuously for the entire backup operation.
6644 ** ^Thus, the backup may be performed on a live source database without
6645 ** preventing other database connections from
6646 ** reading or writing to the source database while the backup is underway.
6648 ** ^(To perform a backup operation:
6649 ** <ol>
6650 ** <li><b>sqlite3_backup_init()</b> is called once to initialize the
6651 ** backup,
6652 ** <li><b>sqlite3_backup_step()</b> is called one or more times to transfer
6653 ** the data between the two databases, and finally
6654 ** <li><b>sqlite3_backup_finish()</b> is called to release all resources
6655 ** associated with the backup operation.
6656 ** </ol>)^
6657 ** There should be exactly one call to sqlite3_backup_finish() for each
6658 ** successful call to sqlite3_backup_init().
6660 ** [[sqlite3_backup_init()]] <b>sqlite3_backup_init()</b>
6662 ** ^The D and N arguments to sqlite3_backup_init(D,N,S,M) are the
6663 ** [database connection] associated with the destination database
6664 ** and the database name, respectively.
6665 ** ^The database name is "main" for the main database, "temp" for the
6666 ** temporary database, or the name specified after the AS keyword in
6667 ** an [ATTACH] statement for an attached database.
6668 ** ^The S and M arguments passed to
6669 ** sqlite3_backup_init(D,N,S,M) identify the [database connection]
6670 ** and database name of the source database, respectively.
6671 ** ^The source and destination [database connections] (parameters S and D)
6672 ** must be different or else sqlite3_backup_init(D,N,S,M) will fail with
6673 ** an error.
6675 ** ^If an error occurs within sqlite3_backup_init(D,N,S,M), then NULL is
6676 ** returned and an error code and error message are stored in the
6677 ** destination [database connection] D.
6678 ** ^The error code and message for the failed call to sqlite3_backup_init()
6679 ** can be retrieved using the [sqlite3_errcode()], [sqlite3_errmsg()], and/or
6680 ** [sqlite3_errmsg16()] functions.
6681 ** ^A successful call to sqlite3_backup_init() returns a pointer to an
6682 ** [sqlite3_backup] object.
6683 ** ^The [sqlite3_backup] object may be used with the sqlite3_backup_step() and
6684 ** sqlite3_backup_finish() functions to perform the specified backup
6685 ** operation.
6687 ** [[sqlite3_backup_step()]] <b>sqlite3_backup_step()</b>
6689 ** ^Function sqlite3_backup_step(B,N) will copy up to N pages between
6690 ** the source and destination databases specified by [sqlite3_backup] object B.
6691 ** ^If N is negative, all remaining source pages are copied.
6692 ** ^If sqlite3_backup_step(B,N) successfully copies N pages and there
6693 ** are still more pages to be copied, then the function returns [SQLITE_OK].
6694 ** ^If sqlite3_backup_step(B,N) successfully finishes copying all pages
6695 ** from source to destination, then it returns [SQLITE_DONE].
6696 ** ^If an error occurs while running sqlite3_backup_step(B,N),
6697 ** then an [error code] is returned. ^As well as [SQLITE_OK] and
6698 ** [SQLITE_DONE], a call to sqlite3_backup_step() may return [SQLITE_READONLY],
6699 ** [SQLITE_NOMEM], [SQLITE_BUSY], [SQLITE_LOCKED], or an
6700 ** [SQLITE_IOERR_ACCESS | SQLITE_IOERR_XXX] extended error code.
6702 ** ^(The sqlite3_backup_step() might return [SQLITE_READONLY] if
6703 ** <ol>
6704 ** <li> the destination database was opened read-only, or
6705 ** <li> the destination database is using write-ahead-log journaling
6706 ** and the destination and source page sizes differ, or
6707 ** <li> the destination database is an in-memory database and the
6708 ** destination and source page sizes differ.
6709 ** </ol>)^
6711 ** ^If sqlite3_backup_step() cannot obtain a required file-system lock, then
6712 ** the [sqlite3_busy_handler | busy-handler function]
6713 ** is invoked (if one is specified). ^If the
6714 ** busy-handler returns non-zero before the lock is available, then
6715 ** [SQLITE_BUSY] is returned to the caller. ^In this case the call to
6716 ** sqlite3_backup_step() can be retried later. ^If the source
6717 ** [database connection]
6718 ** is being used to write to the source database when sqlite3_backup_step()
6719 ** is called, then [SQLITE_LOCKED] is returned immediately. ^Again, in this
6720 ** case the call to sqlite3_backup_step() can be retried later on. ^(If
6721 ** [SQLITE_IOERR_ACCESS | SQLITE_IOERR_XXX], [SQLITE_NOMEM], or
6722 ** [SQLITE_READONLY] is returned, then
6723 ** there is no point in retrying the call to sqlite3_backup_step(). These
6724 ** errors are considered fatal.)^ The application must accept
6725 ** that the backup operation has failed and pass the backup operation handle
6726 ** to the sqlite3_backup_finish() to release associated resources.
6728 ** ^The first call to sqlite3_backup_step() obtains an exclusive lock
6729 ** on the destination file. ^The exclusive lock is not released until either
6730 ** sqlite3_backup_finish() is called or the backup operation is complete
6731 ** and sqlite3_backup_step() returns [SQLITE_DONE]. ^Every call to
6732 ** sqlite3_backup_step() obtains a [shared lock] on the source database that
6733 ** lasts for the duration of the sqlite3_backup_step() call.
6734 ** ^Because the source database is not locked between calls to
6735 ** sqlite3_backup_step(), the source database may be modified mid-way
6736 ** through the backup process. ^If the source database is modified by an
6737 ** external process or via a database connection other than the one being
6738 ** used by the backup operation, then the backup will be automatically
6739 ** restarted by the next call to sqlite3_backup_step(). ^If the source
6740 ** database is modified by the using the same database connection as is used
6741 ** by the backup operation, then the backup database is automatically
6742 ** updated at the same time.
6744 ** [[sqlite3_backup_finish()]] <b>sqlite3_backup_finish()</b>
6746 ** When sqlite3_backup_step() has returned [SQLITE_DONE], or when the
6747 ** application wishes to abandon the backup operation, the application
6748 ** should destroy the [sqlite3_backup] by passing it to sqlite3_backup_finish().
6749 ** ^The sqlite3_backup_finish() interfaces releases all
6750 ** resources associated with the [sqlite3_backup] object.
6751 ** ^If sqlite3_backup_step() has not yet returned [SQLITE_DONE], then any
6752 ** active write-transaction on the destination database is rolled back.
6753 ** The [sqlite3_backup] object is invalid
6754 ** and may not be used following a call to sqlite3_backup_finish().
6756 ** ^The value returned by sqlite3_backup_finish is [SQLITE_OK] if no
6757 ** sqlite3_backup_step() errors occurred, regardless or whether or not
6758 ** sqlite3_backup_step() completed.
6759 ** ^If an out-of-memory condition or IO error occurred during any prior
6760 ** sqlite3_backup_step() call on the same [sqlite3_backup] object, then
6761 ** sqlite3_backup_finish() returns the corresponding [error code].
6763 ** ^A return of [SQLITE_BUSY] or [SQLITE_LOCKED] from sqlite3_backup_step()
6764 ** is not a permanent error and does not affect the return value of
6765 ** sqlite3_backup_finish().
6767 ** [[sqlite3_backup__remaining()]] [[sqlite3_backup_pagecount()]]
6768 ** <b>sqlite3_backup_remaining() and sqlite3_backup_pagecount()</b>
6770 ** ^Each call to sqlite3_backup_step() sets two values inside
6771 ** the [sqlite3_backup] object: the number of pages still to be backed
6772 ** up and the total number of pages in the source database file.
6773 ** The sqlite3_backup_remaining() and sqlite3_backup_pagecount() interfaces
6774 ** retrieve these two values, respectively.
6776 ** ^The values returned by these functions are only updated by
6777 ** sqlite3_backup_step(). ^If the source database is modified during a backup
6778 ** operation, then the values are not updated to account for any extra
6779 ** pages that need to be updated or the size of the source database file
6780 ** changing.
6782 ** <b>Concurrent Usage of Database Handles</b>
6784 ** ^The source [database connection] may be used by the application for other
6785 ** purposes while a backup operation is underway or being initialized.
6786 ** ^If SQLite is compiled and configured to support threadsafe database
6787 ** connections, then the source database connection may be used concurrently
6788 ** from within other threads.
6790 ** However, the application must guarantee that the destination
6791 ** [database connection] is not passed to any other API (by any thread) after
6792 ** sqlite3_backup_init() is called and before the corresponding call to
6793 ** sqlite3_backup_finish(). SQLite does not currently check to see
6794 ** if the application incorrectly accesses the destination [database connection]
6795 ** and so no error code is reported, but the operations may malfunction
6796 ** nevertheless. Use of the destination database connection while a
6797 ** backup is in progress might also also cause a mutex deadlock.
6799 ** If running in [shared cache mode], the application must
6800 ** guarantee that the shared cache used by the destination database
6801 ** is not accessed while the backup is running. In practice this means
6802 ** that the application must guarantee that the disk file being
6803 ** backed up to is not accessed by any connection within the process,
6804 ** not just the specific connection that was passed to sqlite3_backup_init().
6806 ** The [sqlite3_backup] object itself is partially threadsafe. Multiple
6807 ** threads may safely make multiple concurrent calls to sqlite3_backup_step().
6808 ** However, the sqlite3_backup_remaining() and sqlite3_backup_pagecount()
6809 ** APIs are not strictly speaking threadsafe. If they are invoked at the
6810 ** same time as another thread is invoking sqlite3_backup_step() it is
6811 ** possible that they return invalid values.
6813 SQLITE_API sqlite3_backup *sqlite3_backup_init(
6814 sqlite3 *pDest, /* Destination database handle */
6815 const char *zDestName, /* Destination database name */
6816 sqlite3 *pSource, /* Source database handle */
6817 const char *zSourceName /* Source database name */
6819 SQLITE_API int sqlite3_backup_step(sqlite3_backup *p, int nPage);
6820 SQLITE_API int sqlite3_backup_finish(sqlite3_backup *p);
6821 SQLITE_API int sqlite3_backup_remaining(sqlite3_backup *p);
6822 SQLITE_API int sqlite3_backup_pagecount(sqlite3_backup *p);
6825 ** CAPI3REF: Unlock Notification
6827 ** ^When running in shared-cache mode, a database operation may fail with
6828 ** an [SQLITE_LOCKED] error if the required locks on the shared-cache or
6829 ** individual tables within the shared-cache cannot be obtained. See
6830 ** [SQLite Shared-Cache Mode] for a description of shared-cache locking.
6831 ** ^This API may be used to register a callback that SQLite will invoke
6832 ** when the connection currently holding the required lock relinquishes it.
6833 ** ^This API is only available if the library was compiled with the
6834 ** [SQLITE_ENABLE_UNLOCK_NOTIFY] C-preprocessor symbol defined.
6836 ** See Also: [Using the SQLite Unlock Notification Feature].
6838 ** ^Shared-cache locks are released when a database connection concludes
6839 ** its current transaction, either by committing it or rolling it back.
6841 ** ^When a connection (known as the blocked connection) fails to obtain a
6842 ** shared-cache lock and SQLITE_LOCKED is returned to the caller, the
6843 ** identity of the database connection (the blocking connection) that
6844 ** has locked the required resource is stored internally. ^After an
6845 ** application receives an SQLITE_LOCKED error, it may call the
6846 ** sqlite3_unlock_notify() method with the blocked connection handle as
6847 ** the first argument to register for a callback that will be invoked
6848 ** when the blocking connections current transaction is concluded. ^The
6849 ** callback is invoked from within the [sqlite3_step] or [sqlite3_close]
6850 ** call that concludes the blocking connections transaction.
6852 ** ^(If sqlite3_unlock_notify() is called in a multi-threaded application,
6853 ** there is a chance that the blocking connection will have already
6854 ** concluded its transaction by the time sqlite3_unlock_notify() is invoked.
6855 ** If this happens, then the specified callback is invoked immediately,
6856 ** from within the call to sqlite3_unlock_notify().)^
6858 ** ^If the blocked connection is attempting to obtain a write-lock on a
6859 ** shared-cache table, and more than one other connection currently holds
6860 ** a read-lock on the same table, then SQLite arbitrarily selects one of
6861 ** the other connections to use as the blocking connection.
6863 ** ^(There may be at most one unlock-notify callback registered by a
6864 ** blocked connection. If sqlite3_unlock_notify() is called when the
6865 ** blocked connection already has a registered unlock-notify callback,
6866 ** then the new callback replaces the old.)^ ^If sqlite3_unlock_notify() is
6867 ** called with a NULL pointer as its second argument, then any existing
6868 ** unlock-notify callback is canceled. ^The blocked connections
6869 ** unlock-notify callback may also be canceled by closing the blocked
6870 ** connection using [sqlite3_close()].
6872 ** The unlock-notify callback is not reentrant. If an application invokes
6873 ** any sqlite3_xxx API functions from within an unlock-notify callback, a
6874 ** crash or deadlock may be the result.
6876 ** ^Unless deadlock is detected (see below), sqlite3_unlock_notify() always
6877 ** returns SQLITE_OK.
6879 ** <b>Callback Invocation Details</b>
6881 ** When an unlock-notify callback is registered, the application provides a
6882 ** single void* pointer that is passed to the callback when it is invoked.
6883 ** However, the signature of the callback function allows SQLite to pass
6884 ** it an array of void* context pointers. The first argument passed to
6885 ** an unlock-notify callback is a pointer to an array of void* pointers,
6886 ** and the second is the number of entries in the array.
6888 ** When a blocking connections transaction is concluded, there may be
6889 ** more than one blocked connection that has registered for an unlock-notify
6890 ** callback. ^If two or more such blocked connections have specified the
6891 ** same callback function, then instead of invoking the callback function
6892 ** multiple times, it is invoked once with the set of void* context pointers
6893 ** specified by the blocked connections bundled together into an array.
6894 ** This gives the application an opportunity to prioritize any actions
6895 ** related to the set of unblocked database connections.
6897 ** <b>Deadlock Detection</b>
6899 ** Assuming that after registering for an unlock-notify callback a
6900 ** database waits for the callback to be issued before taking any further
6901 ** action (a reasonable assumption), then using this API may cause the
6902 ** application to deadlock. For example, if connection X is waiting for
6903 ** connection Y's transaction to be concluded, and similarly connection
6904 ** Y is waiting on connection X's transaction, then neither connection
6905 ** will proceed and the system may remain deadlocked indefinitely.
6907 ** To avoid this scenario, the sqlite3_unlock_notify() performs deadlock
6908 ** detection. ^If a given call to sqlite3_unlock_notify() would put the
6909 ** system in a deadlocked state, then SQLITE_LOCKED is returned and no
6910 ** unlock-notify callback is registered. The system is said to be in
6911 ** a deadlocked state if connection A has registered for an unlock-notify
6912 ** callback on the conclusion of connection B's transaction, and connection
6913 ** B has itself registered for an unlock-notify callback when connection
6914 ** A's transaction is concluded. ^Indirect deadlock is also detected, so
6915 ** the system is also considered to be deadlocked if connection B has
6916 ** registered for an unlock-notify callback on the conclusion of connection
6917 ** C's transaction, where connection C is waiting on connection A. ^Any
6918 ** number of levels of indirection are allowed.
6920 ** <b>The "DROP TABLE" Exception</b>
6922 ** When a call to [sqlite3_step()] returns SQLITE_LOCKED, it is almost
6923 ** always appropriate to call sqlite3_unlock_notify(). There is however,
6924 ** one exception. When executing a "DROP TABLE" or "DROP INDEX" statement,
6925 ** SQLite checks if there are any currently executing SELECT statements
6926 ** that belong to the same connection. If there are, SQLITE_LOCKED is
6927 ** returned. In this case there is no "blocking connection", so invoking
6928 ** sqlite3_unlock_notify() results in the unlock-notify callback being
6929 ** invoked immediately. If the application then re-attempts the "DROP TABLE"
6930 ** or "DROP INDEX" query, an infinite loop might be the result.
6932 ** One way around this problem is to check the extended error code returned
6933 ** by an sqlite3_step() call. ^(If there is a blocking connection, then the
6934 ** extended error code is set to SQLITE_LOCKED_SHAREDCACHE. Otherwise, in
6935 ** the special "DROP TABLE/INDEX" case, the extended error code is just
6936 ** SQLITE_LOCKED.)^
6938 SQLITE_API int sqlite3_unlock_notify(
6939 sqlite3 *pBlocked, /* Waiting connection */
6940 void (*xNotify)(void **apArg, int nArg), /* Callback function to invoke */
6941 void *pNotifyArg /* Argument to pass to xNotify */
6946 ** CAPI3REF: String Comparison
6948 ** ^The [sqlite3_strnicmp()] API allows applications and extensions to
6949 ** compare the contents of two buffers containing UTF-8 strings in a
6950 ** case-independent fashion, using the same definition of case independence
6951 ** that SQLite uses internally when comparing identifiers.
6953 SQLITE_API int sqlite3_strnicmp(const char *, const char *, int);
6956 ** CAPI3REF: Error Logging Interface
6958 ** ^The [sqlite3_log()] interface writes a message into the error log
6959 ** established by the [SQLITE_CONFIG_LOG] option to [sqlite3_config()].
6960 ** ^If logging is enabled, the zFormat string and subsequent arguments are
6961 ** used with [sqlite3_snprintf()] to generate the final output string.
6963 ** The sqlite3_log() interface is intended for use by extensions such as
6964 ** virtual tables, collating functions, and SQL functions. While there is
6965 ** nothing to prevent an application from calling sqlite3_log(), doing so
6966 ** is considered bad form.
6968 ** The zFormat string must not be NULL.
6970 ** To avoid deadlocks and other threading problems, the sqlite3_log() routine
6971 ** will not use dynamically allocated memory. The log message is stored in
6972 ** a fixed-length buffer on the stack. If the log message is longer than
6973 ** a few hundred characters, it will be truncated to the length of the
6974 ** buffer.
6976 SQLITE_API void sqlite3_log(int iErrCode, const char *zFormat, ...);
6979 ** CAPI3REF: Write-Ahead Log Commit Hook
6981 ** ^The [sqlite3_wal_hook()] function is used to register a callback that
6982 ** will be invoked each time a database connection commits data to a
6983 ** [write-ahead log] (i.e. whenever a transaction is committed in
6984 ** [journal_mode | journal_mode=WAL mode]).
6986 ** ^The callback is invoked by SQLite after the commit has taken place and
6987 ** the associated write-lock on the database released, so the implementation
6988 ** may read, write or [checkpoint] the database as required.
6990 ** ^The first parameter passed to the callback function when it is invoked
6991 ** is a copy of the third parameter passed to sqlite3_wal_hook() when
6992 ** registering the callback. ^The second is a copy of the database handle.
6993 ** ^The third parameter is the name of the database that was written to -
6994 ** either "main" or the name of an [ATTACH]-ed database. ^The fourth parameter
6995 ** is the number of pages currently in the write-ahead log file,
6996 ** including those that were just committed.
6998 ** The callback function should normally return [SQLITE_OK]. ^If an error
6999 ** code is returned, that error will propagate back up through the
7000 ** SQLite code base to cause the statement that provoked the callback
7001 ** to report an error, though the commit will have still occurred. If the
7002 ** callback returns [SQLITE_ROW] or [SQLITE_DONE], or if it returns a value
7003 ** that does not correspond to any valid SQLite error code, the results
7004 ** are undefined.
7006 ** A single database handle may have at most a single write-ahead log callback
7007 ** registered at one time. ^Calling [sqlite3_wal_hook()] replaces any
7008 ** previously registered write-ahead log callback. ^Note that the
7009 ** [sqlite3_wal_autocheckpoint()] interface and the
7010 ** [wal_autocheckpoint pragma] both invoke [sqlite3_wal_hook()] and will
7011 ** those overwrite any prior [sqlite3_wal_hook()] settings.
7013 SQLITE_API void *sqlite3_wal_hook(
7014 sqlite3*,
7015 int(*)(void *,sqlite3*,const char*,int),
7016 void*
7020 ** CAPI3REF: Configure an auto-checkpoint
7022 ** ^The [sqlite3_wal_autocheckpoint(D,N)] is a wrapper around
7023 ** [sqlite3_wal_hook()] that causes any database on [database connection] D
7024 ** to automatically [checkpoint]
7025 ** after committing a transaction if there are N or
7026 ** more frames in the [write-ahead log] file. ^Passing zero or
7027 ** a negative value as the nFrame parameter disables automatic
7028 ** checkpoints entirely.
7030 ** ^The callback registered by this function replaces any existing callback
7031 ** registered using [sqlite3_wal_hook()]. ^Likewise, registering a callback
7032 ** using [sqlite3_wal_hook()] disables the automatic checkpoint mechanism
7033 ** configured by this function.
7035 ** ^The [wal_autocheckpoint pragma] can be used to invoke this interface
7036 ** from SQL.
7038 ** ^Every new [database connection] defaults to having the auto-checkpoint
7039 ** enabled with a threshold of 1000 or [SQLITE_DEFAULT_WAL_AUTOCHECKPOINT]
7040 ** pages. The use of this interface
7041 ** is only necessary if the default setting is found to be suboptimal
7042 ** for a particular application.
7044 SQLITE_API int sqlite3_wal_autocheckpoint(sqlite3 *db, int N);
7047 ** CAPI3REF: Checkpoint a database
7049 ** ^The [sqlite3_wal_checkpoint(D,X)] interface causes database named X
7050 ** on [database connection] D to be [checkpointed]. ^If X is NULL or an
7051 ** empty string, then a checkpoint is run on all databases of
7052 ** connection D. ^If the database connection D is not in
7053 ** [WAL | write-ahead log mode] then this interface is a harmless no-op.
7055 ** ^The [wal_checkpoint pragma] can be used to invoke this interface
7056 ** from SQL. ^The [sqlite3_wal_autocheckpoint()] interface and the
7057 ** [wal_autocheckpoint pragma] can be used to cause this interface to be
7058 ** run whenever the WAL reaches a certain size threshold.
7060 ** See also: [sqlite3_wal_checkpoint_v2()]
7062 SQLITE_API int sqlite3_wal_checkpoint(sqlite3 *db, const char *zDb);
7065 ** CAPI3REF: Checkpoint a database
7067 ** Run a checkpoint operation on WAL database zDb attached to database
7068 ** handle db. The specific operation is determined by the value of the
7069 ** eMode parameter:
7071 ** <dl>
7072 ** <dt>SQLITE_CHECKPOINT_PASSIVE<dd>
7073 ** Checkpoint as many frames as possible without waiting for any database
7074 ** readers or writers to finish. Sync the db file if all frames in the log
7075 ** are checkpointed. This mode is the same as calling
7076 ** sqlite3_wal_checkpoint(). The busy-handler callback is never invoked.
7078 ** <dt>SQLITE_CHECKPOINT_FULL<dd>
7079 ** This mode blocks (calls the busy-handler callback) until there is no
7080 ** database writer and all readers are reading from the most recent database
7081 ** snapshot. It then checkpoints all frames in the log file and syncs the
7082 ** database file. This call blocks database writers while it is running,
7083 ** but not database readers.
7085 ** <dt>SQLITE_CHECKPOINT_RESTART<dd>
7086 ** This mode works the same way as SQLITE_CHECKPOINT_FULL, except after
7087 ** checkpointing the log file it blocks (calls the busy-handler callback)
7088 ** until all readers are reading from the database file only. This ensures
7089 ** that the next client to write to the database file restarts the log file
7090 ** from the beginning. This call blocks database writers while it is running,
7091 ** but not database readers.
7092 ** </dl>
7094 ** If pnLog is not NULL, then *pnLog is set to the total number of frames in
7095 ** the log file before returning. If pnCkpt is not NULL, then *pnCkpt is set to
7096 ** the total number of checkpointed frames (including any that were already
7097 ** checkpointed when this function is called). *pnLog and *pnCkpt may be
7098 ** populated even if sqlite3_wal_checkpoint_v2() returns other than SQLITE_OK.
7099 ** If no values are available because of an error, they are both set to -1
7100 ** before returning to communicate this to the caller.
7102 ** All calls obtain an exclusive "checkpoint" lock on the database file. If
7103 ** any other process is running a checkpoint operation at the same time, the
7104 ** lock cannot be obtained and SQLITE_BUSY is returned. Even if there is a
7105 ** busy-handler configured, it will not be invoked in this case.
7107 ** The SQLITE_CHECKPOINT_FULL and RESTART modes also obtain the exclusive
7108 ** "writer" lock on the database file. If the writer lock cannot be obtained
7109 ** immediately, and a busy-handler is configured, it is invoked and the writer
7110 ** lock retried until either the busy-handler returns 0 or the lock is
7111 ** successfully obtained. The busy-handler is also invoked while waiting for
7112 ** database readers as described above. If the busy-handler returns 0 before
7113 ** the writer lock is obtained or while waiting for database readers, the
7114 ** checkpoint operation proceeds from that point in the same way as
7115 ** SQLITE_CHECKPOINT_PASSIVE - checkpointing as many frames as possible
7116 ** without blocking any further. SQLITE_BUSY is returned in this case.
7118 ** If parameter zDb is NULL or points to a zero length string, then the
7119 ** specified operation is attempted on all WAL databases. In this case the
7120 ** values written to output parameters *pnLog and *pnCkpt are undefined. If
7121 ** an SQLITE_BUSY error is encountered when processing one or more of the
7122 ** attached WAL databases, the operation is still attempted on any remaining
7123 ** attached databases and SQLITE_BUSY is returned to the caller. If any other
7124 ** error occurs while processing an attached database, processing is abandoned
7125 ** and the error code returned to the caller immediately. If no error
7126 ** (SQLITE_BUSY or otherwise) is encountered while processing the attached
7127 ** databases, SQLITE_OK is returned.
7129 ** If database zDb is the name of an attached database that is not in WAL
7130 ** mode, SQLITE_OK is returned and both *pnLog and *pnCkpt set to -1. If
7131 ** zDb is not NULL (or a zero length string) and is not the name of any
7132 ** attached database, SQLITE_ERROR is returned to the caller.
7134 SQLITE_API int sqlite3_wal_checkpoint_v2(
7135 sqlite3 *db, /* Database handle */
7136 const char *zDb, /* Name of attached database (or NULL) */
7137 int eMode, /* SQLITE_CHECKPOINT_* value */
7138 int *pnLog, /* OUT: Size of WAL log in frames */
7139 int *pnCkpt /* OUT: Total number of frames checkpointed */
7143 ** CAPI3REF: Checkpoint operation parameters
7145 ** These constants can be used as the 3rd parameter to
7146 ** [sqlite3_wal_checkpoint_v2()]. See the [sqlite3_wal_checkpoint_v2()]
7147 ** documentation for additional information about the meaning and use of
7148 ** each of these values.
7150 #define SQLITE_CHECKPOINT_PASSIVE 0
7151 #define SQLITE_CHECKPOINT_FULL 1
7152 #define SQLITE_CHECKPOINT_RESTART 2
7155 ** CAPI3REF: Virtual Table Interface Configuration
7157 ** This function may be called by either the [xConnect] or [xCreate] method
7158 ** of a [virtual table] implementation to configure
7159 ** various facets of the virtual table interface.
7161 ** If this interface is invoked outside the context of an xConnect or
7162 ** xCreate virtual table method then the behavior is undefined.
7164 ** At present, there is only one option that may be configured using
7165 ** this function. (See [SQLITE_VTAB_CONSTRAINT_SUPPORT].) Further options
7166 ** may be added in the future.
7168 SQLITE_API int sqlite3_vtab_config(sqlite3*, int op, ...);
7171 ** CAPI3REF: Virtual Table Configuration Options
7173 ** These macros define the various options to the
7174 ** [sqlite3_vtab_config()] interface that [virtual table] implementations
7175 ** can use to customize and optimize their behavior.
7177 ** <dl>
7178 ** <dt>SQLITE_VTAB_CONSTRAINT_SUPPORT
7179 ** <dd>Calls of the form
7180 ** [sqlite3_vtab_config](db,SQLITE_VTAB_CONSTRAINT_SUPPORT,X) are supported,
7181 ** where X is an integer. If X is zero, then the [virtual table] whose
7182 ** [xCreate] or [xConnect] method invoked [sqlite3_vtab_config()] does not
7183 ** support constraints. In this configuration (which is the default) if
7184 ** a call to the [xUpdate] method returns [SQLITE_CONSTRAINT], then the entire
7185 ** statement is rolled back as if [ON CONFLICT | OR ABORT] had been
7186 ** specified as part of the users SQL statement, regardless of the actual
7187 ** ON CONFLICT mode specified.
7189 ** If X is non-zero, then the virtual table implementation guarantees
7190 ** that if [xUpdate] returns [SQLITE_CONSTRAINT], it will do so before
7191 ** any modifications to internal or persistent data structures have been made.
7192 ** If the [ON CONFLICT] mode is ABORT, FAIL, IGNORE or ROLLBACK, SQLite
7193 ** is able to roll back a statement or database transaction, and abandon
7194 ** or continue processing the current SQL statement as appropriate.
7195 ** If the ON CONFLICT mode is REPLACE and the [xUpdate] method returns
7196 ** [SQLITE_CONSTRAINT], SQLite handles this as if the ON CONFLICT mode
7197 ** had been ABORT.
7199 ** Virtual table implementations that are required to handle OR REPLACE
7200 ** must do so within the [xUpdate] method. If a call to the
7201 ** [sqlite3_vtab_on_conflict()] function indicates that the current ON
7202 ** CONFLICT policy is REPLACE, the virtual table implementation should
7203 ** silently replace the appropriate rows within the xUpdate callback and
7204 ** return SQLITE_OK. Or, if this is not possible, it may return
7205 ** SQLITE_CONSTRAINT, in which case SQLite falls back to OR ABORT
7206 ** constraint handling.
7207 ** </dl>
7209 #define SQLITE_VTAB_CONSTRAINT_SUPPORT 1
7212 ** CAPI3REF: Determine The Virtual Table Conflict Policy
7214 ** This function may only be called from within a call to the [xUpdate] method
7215 ** of a [virtual table] implementation for an INSERT or UPDATE operation. ^The
7216 ** value returned is one of [SQLITE_ROLLBACK], [SQLITE_IGNORE], [SQLITE_FAIL],
7217 ** [SQLITE_ABORT], or [SQLITE_REPLACE], according to the [ON CONFLICT] mode
7218 ** of the SQL statement that triggered the call to the [xUpdate] method of the
7219 ** [virtual table].
7221 SQLITE_API int sqlite3_vtab_on_conflict(sqlite3 *);
7224 ** CAPI3REF: Conflict resolution modes
7226 ** These constants are returned by [sqlite3_vtab_on_conflict()] to
7227 ** inform a [virtual table] implementation what the [ON CONFLICT] mode
7228 ** is for the SQL statement being evaluated.
7230 ** Note that the [SQLITE_IGNORE] constant is also used as a potential
7231 ** return value from the [sqlite3_set_authorizer()] callback and that
7232 ** [SQLITE_ABORT] is also a [result code].
7234 #define SQLITE_ROLLBACK 1
7235 /* #define SQLITE_IGNORE 2 // Also used by sqlite3_authorizer() callback */
7236 #define SQLITE_FAIL 3
7237 /* #define SQLITE_ABORT 4 // Also an error code */
7238 #define SQLITE_REPLACE 5
7243 ** Undo the hack that converts floating point types to integer for
7244 ** builds on processors without floating point support.
7246 #ifdef SQLITE_OMIT_FLOATING_POINT
7247 # undef double
7248 #endif
7250 #if 0
7251 } /* End of the 'extern "C"' block */
7252 #endif
7253 #endif
7256 ** 2010 August 30
7258 ** The author disclaims copyright to this source code. In place of
7259 ** a legal notice, here is a blessing:
7261 ** May you do good and not evil.
7262 ** May you find forgiveness for yourself and forgive others.
7263 ** May you share freely, never taking more than you give.
7265 *************************************************************************
7268 #ifndef _SQLITE3RTREE_H_
7269 #define _SQLITE3RTREE_H_
7272 #if 0
7273 extern "C" {
7274 #endif
7276 typedef struct sqlite3_rtree_geometry sqlite3_rtree_geometry;
7279 ** Register a geometry callback named zGeom that can be used as part of an
7280 ** R-Tree geometry query as follows:
7282 ** SELECT ... FROM <rtree> WHERE <rtree col> MATCH $zGeom(... params ...)
7284 SQLITE_API int sqlite3_rtree_geometry_callback(
7285 sqlite3 *db,
7286 const char *zGeom,
7287 int (*xGeom)(sqlite3_rtree_geometry *, int nCoord, double *aCoord, int *pRes),
7288 void *pContext
7293 ** A pointer to a structure of the following type is passed as the first
7294 ** argument to callbacks registered using rtree_geometry_callback().
7296 struct sqlite3_rtree_geometry {
7297 void *pContext; /* Copy of pContext passed to s_r_g_c() */
7298 int nParam; /* Size of array aParam[] */
7299 double *aParam; /* Parameters passed to SQL geom function */
7300 void *pUser; /* Callback implementation user data */
7301 void (*xDelUser)(void *); /* Called by SQLite to clean up pUser */
7305 #if 0
7306 } /* end of the 'extern "C"' block */
7307 #endif
7309 #endif /* ifndef _SQLITE3RTREE_H_ */
7312 /************** End of sqlite3.h *********************************************/
7313 /************** Continuing where we left off in sqliteInt.h ******************/
7314 /************** Include hash.h in the middle of sqliteInt.h ******************/
7315 /************** Begin file hash.h ********************************************/
7317 ** 2001 September 22
7319 ** The author disclaims copyright to this source code. In place of
7320 ** a legal notice, here is a blessing:
7322 ** May you do good and not evil.
7323 ** May you find forgiveness for yourself and forgive others.
7324 ** May you share freely, never taking more than you give.
7326 *************************************************************************
7327 ** This is the header file for the generic hash-table implemenation
7328 ** used in SQLite.
7330 #ifndef _SQLITE_HASH_H_
7331 #define _SQLITE_HASH_H_
7333 /* Forward declarations of structures. */
7334 typedef struct Hash Hash;
7335 typedef struct HashElem HashElem;
7337 /* A complete hash table is an instance of the following structure.
7338 ** The internals of this structure are intended to be opaque -- client
7339 ** code should not attempt to access or modify the fields of this structure
7340 ** directly. Change this structure only by using the routines below.
7341 ** However, some of the "procedures" and "functions" for modifying and
7342 ** accessing this structure are really macros, so we can't really make
7343 ** this structure opaque.
7345 ** All elements of the hash table are on a single doubly-linked list.
7346 ** Hash.first points to the head of this list.
7348 ** There are Hash.htsize buckets. Each bucket points to a spot in
7349 ** the global doubly-linked list. The contents of the bucket are the
7350 ** element pointed to plus the next _ht.count-1 elements in the list.
7352 ** Hash.htsize and Hash.ht may be zero. In that case lookup is done
7353 ** by a linear search of the global list. For small tables, the
7354 ** Hash.ht table is never allocated because if there are few elements
7355 ** in the table, it is faster to do a linear search than to manage
7356 ** the hash table.
7358 struct Hash {
7359 unsigned int htsize; /* Number of buckets in the hash table */
7360 unsigned int count; /* Number of entries in this table */
7361 HashElem *first; /* The first element of the array */
7362 struct _ht { /* the hash table */
7363 int count; /* Number of entries with this hash */
7364 HashElem *chain; /* Pointer to first entry with this hash */
7365 } *ht;
7368 /* Each element in the hash table is an instance of the following
7369 ** structure. All elements are stored on a single doubly-linked list.
7371 ** Again, this structure is intended to be opaque, but it can't really
7372 ** be opaque because it is used by macros.
7374 struct HashElem {
7375 HashElem *next, *prev; /* Next and previous elements in the table */
7376 void *data; /* Data associated with this element */
7377 const char *pKey; int nKey; /* Key associated with this element */
7381 ** Access routines. To delete, insert a NULL pointer.
7383 SQLITE_PRIVATE void sqlite3HashInit(Hash*);
7384 SQLITE_PRIVATE void *sqlite3HashInsert(Hash*, const char *pKey, int nKey, void *pData);
7385 SQLITE_PRIVATE void *sqlite3HashFind(const Hash*, const char *pKey, int nKey);
7386 SQLITE_PRIVATE void sqlite3HashClear(Hash*);
7389 ** Macros for looping over all elements of a hash table. The idiom is
7390 ** like this:
7392 ** Hash h;
7393 ** HashElem *p;
7394 ** ...
7395 ** for(p=sqliteHashFirst(&h); p; p=sqliteHashNext(p)){
7396 ** SomeStructure *pData = sqliteHashData(p);
7397 ** // do something with pData
7398 ** }
7400 #define sqliteHashFirst(H) ((H)->first)
7401 #define sqliteHashNext(E) ((E)->next)
7402 #define sqliteHashData(E) ((E)->data)
7403 /* #define sqliteHashKey(E) ((E)->pKey) // NOT USED */
7404 /* #define sqliteHashKeysize(E) ((E)->nKey) // NOT USED */
7407 ** Number of entries in a hash table
7409 /* #define sqliteHashCount(H) ((H)->count) // NOT USED */
7411 #endif /* _SQLITE_HASH_H_ */
7413 /************** End of hash.h ************************************************/
7414 /************** Continuing where we left off in sqliteInt.h ******************/
7415 /************** Include parse.h in the middle of sqliteInt.h *****************/
7416 /************** Begin file parse.h *******************************************/
7417 #define TK_SEMI 1
7418 #define TK_EXPLAIN 2
7419 #define TK_QUERY 3
7420 #define TK_PLAN 4
7421 #define TK_BEGIN 5
7422 #define TK_TRANSACTION 6
7423 #define TK_DEFERRED 7
7424 #define TK_IMMEDIATE 8
7425 #define TK_EXCLUSIVE 9
7426 #define TK_COMMIT 10
7427 #define TK_END 11
7428 #define TK_ROLLBACK 12
7429 #define TK_SAVEPOINT 13
7430 #define TK_RELEASE 14
7431 #define TK_TO 15
7432 #define TK_TABLE 16
7433 #define TK_CREATE 17
7434 #define TK_IF 18
7435 #define TK_NOT 19
7436 #define TK_EXISTS 20
7437 #define TK_TEMP 21
7438 #define TK_LP 22
7439 #define TK_RP 23
7440 #define TK_AS 24
7441 #define TK_COMMA 25
7442 #define TK_ID 26
7443 #define TK_INDEXED 27
7444 #define TK_ABORT 28
7445 #define TK_ACTION 29
7446 #define TK_AFTER 30
7447 #define TK_ANALYZE 31
7448 #define TK_ASC 32
7449 #define TK_ATTACH 33
7450 #define TK_BEFORE 34
7451 #define TK_BY 35
7452 #define TK_CASCADE 36
7453 #define TK_CAST 37
7454 #define TK_COLUMNKW 38
7455 #define TK_CONFLICT 39
7456 #define TK_DATABASE 40
7457 #define TK_DESC 41
7458 #define TK_DETACH 42
7459 #define TK_EACH 43
7460 #define TK_FAIL 44
7461 #define TK_FOR 45
7462 #define TK_IGNORE 46
7463 #define TK_INITIALLY 47
7464 #define TK_INSTEAD 48
7465 #define TK_LIKE_KW 49
7466 #define TK_MATCH 50
7467 #define TK_NO 51
7468 #define TK_KEY 52
7469 #define TK_OF 53
7470 #define TK_OFFSET 54
7471 #define TK_PRAGMA 55
7472 #define TK_RAISE 56
7473 #define TK_REPLACE 57
7474 #define TK_RESTRICT 58
7475 #define TK_ROW 59
7476 #define TK_TRIGGER 60
7477 #define TK_VACUUM 61
7478 #define TK_VIEW 62
7479 #define TK_VIRTUAL 63
7480 #define TK_REINDEX 64
7481 #define TK_RENAME 65
7482 #define TK_CTIME_KW 66
7483 #define TK_ANY 67
7484 #define TK_OR 68
7485 #define TK_AND 69
7486 #define TK_IS 70
7487 #define TK_BETWEEN 71
7488 #define TK_IN 72
7489 #define TK_ISNULL 73
7490 #define TK_NOTNULL 74
7491 #define TK_NE 75
7492 #define TK_EQ 76
7493 #define TK_GT 77
7494 #define TK_LE 78
7495 #define TK_LT 79
7496 #define TK_GE 80
7497 #define TK_ESCAPE 81
7498 #define TK_BITAND 82
7499 #define TK_BITOR 83
7500 #define TK_LSHIFT 84
7501 #define TK_RSHIFT 85
7502 #define TK_PLUS 86
7503 #define TK_MINUS 87
7504 #define TK_STAR 88
7505 #define TK_SLASH 89
7506 #define TK_REM 90
7507 #define TK_CONCAT 91
7508 #define TK_COLLATE 92
7509 #define TK_BITNOT 93
7510 #define TK_STRING 94
7511 #define TK_JOIN_KW 95
7512 #define TK_CONSTRAINT 96
7513 #define TK_DEFAULT 97
7514 #define TK_NULL 98
7515 #define TK_PRIMARY 99
7516 #define TK_UNIQUE 100
7517 #define TK_CHECK 101
7518 #define TK_REFERENCES 102
7519 #define TK_AUTOINCR 103
7520 #define TK_ON 104
7521 #define TK_INSERT 105
7522 #define TK_DELETE 106
7523 #define TK_UPDATE 107
7524 #define TK_SET 108
7525 #define TK_DEFERRABLE 109
7526 #define TK_FOREIGN 110
7527 #define TK_DROP 111
7528 #define TK_UNION 112
7529 #define TK_ALL 113
7530 #define TK_EXCEPT 114
7531 #define TK_INTERSECT 115
7532 #define TK_SELECT 116
7533 #define TK_DISTINCT 117
7534 #define TK_DOT 118
7535 #define TK_FROM 119
7536 #define TK_JOIN 120
7537 #define TK_USING 121
7538 #define TK_ORDER 122
7539 #define TK_GROUP 123
7540 #define TK_HAVING 124
7541 #define TK_LIMIT 125
7542 #define TK_WHERE 126
7543 #define TK_INTO 127
7544 #define TK_VALUES 128
7545 #define TK_INTEGER 129
7546 #define TK_FLOAT 130
7547 #define TK_BLOB 131
7548 #define TK_REGISTER 132
7549 #define TK_VARIABLE 133
7550 #define TK_CASE 134
7551 #define TK_WHEN 135
7552 #define TK_THEN 136
7553 #define TK_ELSE 137
7554 #define TK_INDEX 138
7555 #define TK_ALTER 139
7556 #define TK_ADD 140
7557 #define TK_TO_TEXT 141
7558 #define TK_TO_BLOB 142
7559 #define TK_TO_NUMERIC 143
7560 #define TK_TO_INT 144
7561 #define TK_TO_REAL 145
7562 #define TK_ISNOT 146
7563 #define TK_END_OF_FILE 147
7564 #define TK_ILLEGAL 148
7565 #define TK_SPACE 149
7566 #define TK_UNCLOSED_STRING 150
7567 #define TK_FUNCTION 151
7568 #define TK_COLUMN 152
7569 #define TK_AGG_FUNCTION 153
7570 #define TK_AGG_COLUMN 154
7571 #define TK_CONST_FUNC 155
7572 #define TK_UMINUS 156
7573 #define TK_UPLUS 157
7575 /************** End of parse.h ***********************************************/
7576 /************** Continuing where we left off in sqliteInt.h ******************/
7577 #include <stdio.h>
7578 #include <stdlib.h>
7579 #include <string.h>
7580 #include <assert.h>
7581 #include <stddef.h>
7584 ** If compiling for a processor that lacks floating point support,
7585 ** substitute integer for floating-point
7587 #ifdef SQLITE_OMIT_FLOATING_POINT
7588 # define double sqlite_int64
7589 # define float sqlite_int64
7590 # define LONGDOUBLE_TYPE sqlite_int64
7591 # ifndef SQLITE_BIG_DBL
7592 # define SQLITE_BIG_DBL (((sqlite3_int64)1)<<50)
7593 # endif
7594 # define SQLITE_OMIT_DATETIME_FUNCS 1
7595 # define SQLITE_OMIT_TRACE 1
7596 # undef SQLITE_MIXED_ENDIAN_64BIT_FLOAT
7597 # undef SQLITE_HAVE_ISNAN
7598 #endif
7599 #ifndef SQLITE_BIG_DBL
7600 # define SQLITE_BIG_DBL (1e99)
7601 #endif
7604 ** OMIT_TEMPDB is set to 1 if SQLITE_OMIT_TEMPDB is defined, or 0
7605 ** afterward. Having this macro allows us to cause the C compiler
7606 ** to omit code used by TEMP tables without messy #ifndef statements.
7608 #ifdef SQLITE_OMIT_TEMPDB
7609 #define OMIT_TEMPDB 1
7610 #else
7611 #define OMIT_TEMPDB 0
7612 #endif
7615 ** The "file format" number is an integer that is incremented whenever
7616 ** the VDBE-level file format changes. The following macros define the
7617 ** the default file format for new databases and the maximum file format
7618 ** that the library can read.
7620 #define SQLITE_MAX_FILE_FORMAT 4
7621 #ifndef SQLITE_DEFAULT_FILE_FORMAT
7622 # define SQLITE_DEFAULT_FILE_FORMAT 1
7623 #endif
7626 ** Determine whether triggers are recursive by default. This can be
7627 ** changed at run-time using a pragma.
7629 #ifndef SQLITE_DEFAULT_RECURSIVE_TRIGGERS
7630 # define SQLITE_DEFAULT_RECURSIVE_TRIGGERS 0
7631 #endif
7634 ** Provide a default value for SQLITE_TEMP_STORE in case it is not specified
7635 ** on the command-line
7637 #ifndef SQLITE_TEMP_STORE
7638 # define SQLITE_TEMP_STORE 1
7639 #endif
7642 ** GCC does not define the offsetof() macro so we'll have to do it
7643 ** ourselves.
7645 #ifndef offsetof
7646 #define offsetof(STRUCTURE,FIELD) ((int)((char*)&((STRUCTURE*)0)->FIELD))
7647 #endif
7650 ** Check to see if this machine uses EBCDIC. (Yes, believe it or
7651 ** not, there are still machines out there that use EBCDIC.)
7653 #if 'A' == '\301'
7654 # define SQLITE_EBCDIC 1
7655 #else
7656 # define SQLITE_ASCII 1
7657 #endif
7660 ** Integers of known sizes. These typedefs might change for architectures
7661 ** where the sizes very. Preprocessor macros are available so that the
7662 ** types can be conveniently redefined at compile-type. Like this:
7664 ** cc '-DUINTPTR_TYPE=long long int' ...
7666 #ifndef UINT32_TYPE
7667 # ifdef HAVE_UINT32_T
7668 # define UINT32_TYPE uint32_t
7669 # else
7670 # define UINT32_TYPE unsigned int
7671 # endif
7672 #endif
7673 #ifndef UINT16_TYPE
7674 # ifdef HAVE_UINT16_T
7675 # define UINT16_TYPE uint16_t
7676 # else
7677 # define UINT16_TYPE unsigned short int
7678 # endif
7679 #endif
7680 #ifndef INT16_TYPE
7681 # ifdef HAVE_INT16_T
7682 # define INT16_TYPE int16_t
7683 # else
7684 # define INT16_TYPE short int
7685 # endif
7686 #endif
7687 #ifndef UINT8_TYPE
7688 # ifdef HAVE_UINT8_T
7689 # define UINT8_TYPE uint8_t
7690 # else
7691 # define UINT8_TYPE unsigned char
7692 # endif
7693 #endif
7694 #ifndef INT8_TYPE
7695 # ifdef HAVE_INT8_T
7696 # define INT8_TYPE int8_t
7697 # else
7698 # define INT8_TYPE signed char
7699 # endif
7700 #endif
7701 #ifndef LONGDOUBLE_TYPE
7702 # define LONGDOUBLE_TYPE long double
7703 #endif
7704 typedef sqlite_int64 i64; /* 8-byte signed integer */
7705 typedef sqlite_uint64 u64; /* 8-byte unsigned integer */
7706 typedef UINT32_TYPE u32; /* 4-byte unsigned integer */
7707 typedef UINT16_TYPE u16; /* 2-byte unsigned integer */
7708 typedef INT16_TYPE i16; /* 2-byte signed integer */
7709 typedef UINT8_TYPE u8; /* 1-byte unsigned integer */
7710 typedef INT8_TYPE i8; /* 1-byte signed integer */
7713 ** SQLITE_MAX_U32 is a u64 constant that is the maximum u64 value
7714 ** that can be stored in a u32 without loss of data. The value
7715 ** is 0x00000000ffffffff. But because of quirks of some compilers, we
7716 ** have to specify the value in the less intuitive manner shown:
7718 #define SQLITE_MAX_U32 ((((u64)1)<<32)-1)
7721 ** Macros to determine whether the machine is big or little endian,
7722 ** evaluated at runtime.
7724 #ifdef SQLITE_AMALGAMATION
7725 SQLITE_PRIVATE const int sqlite3one = 1;
7726 #else
7727 SQLITE_PRIVATE const int sqlite3one;
7728 #endif
7729 #if defined(i386) || defined(__i386__) || defined(_M_IX86)\
7730 || defined(__x86_64) || defined(__x86_64__)
7731 # define SQLITE_BIGENDIAN 0
7732 # define SQLITE_LITTLEENDIAN 1
7733 # define SQLITE_UTF16NATIVE SQLITE_UTF16LE
7734 #else
7735 # define SQLITE_BIGENDIAN (*(char *)(&sqlite3one)==0)
7736 # define SQLITE_LITTLEENDIAN (*(char *)(&sqlite3one)==1)
7737 # define SQLITE_UTF16NATIVE (SQLITE_BIGENDIAN?SQLITE_UTF16BE:SQLITE_UTF16LE)
7738 #endif
7741 ** Constants for the largest and smallest possible 64-bit signed integers.
7742 ** These macros are designed to work correctly on both 32-bit and 64-bit
7743 ** compilers.
7745 #define LARGEST_INT64 (0xffffffff|(((i64)0x7fffffff)<<32))
7746 #define SMALLEST_INT64 (((i64)-1) - LARGEST_INT64)
7749 ** Round up a number to the next larger multiple of 8. This is used
7750 ** to force 8-byte alignment on 64-bit architectures.
7752 #define ROUND8(x) (((x)+7)&~7)
7755 ** Round down to the nearest multiple of 8
7757 #define ROUNDDOWN8(x) ((x)&~7)
7760 ** Assert that the pointer X is aligned to an 8-byte boundary. This
7761 ** macro is used only within assert() to verify that the code gets
7762 ** all alignment restrictions correct.
7764 ** Except, if SQLITE_4_BYTE_ALIGNED_MALLOC is defined, then the
7765 ** underlying malloc() implemention might return us 4-byte aligned
7766 ** pointers. In that case, only verify 4-byte alignment.
7768 #ifdef SQLITE_4_BYTE_ALIGNED_MALLOC
7769 # define EIGHT_BYTE_ALIGNMENT(X) ((((char*)(X) - (char*)0)&3)==0)
7770 #else
7771 # define EIGHT_BYTE_ALIGNMENT(X) ((((char*)(X) - (char*)0)&7)==0)
7772 #endif
7776 ** An instance of the following structure is used to store the busy-handler
7777 ** callback for a given sqlite handle.
7779 ** The sqlite.busyHandler member of the sqlite struct contains the busy
7780 ** callback for the database handle. Each pager opened via the sqlite
7781 ** handle is passed a pointer to sqlite.busyHandler. The busy-handler
7782 ** callback is currently invoked only from within pager.c.
7784 typedef struct BusyHandler BusyHandler;
7785 struct BusyHandler {
7786 int (*xFunc)(void *,int); /* The busy callback */
7787 void *pArg; /* First arg to busy callback */
7788 int nBusy; /* Incremented with each busy call */
7792 ** Name of the master database table. The master database table
7793 ** is a special table that holds the names and attributes of all
7794 ** user tables and indices.
7796 #define MASTER_NAME "sqlite_master"
7797 #define TEMP_MASTER_NAME "sqlite_temp_master"
7800 ** The root-page of the master database table.
7802 #define MASTER_ROOT 1
7805 ** The name of the schema table.
7807 #define SCHEMA_TABLE(x) ((!OMIT_TEMPDB)&&(x==1)?TEMP_MASTER_NAME:MASTER_NAME)
7810 ** A convenience macro that returns the number of elements in
7811 ** an array.
7813 #define ArraySize(X) ((int)(sizeof(X)/sizeof(X[0])))
7816 ** The following value as a destructor means to use sqlite3DbFree().
7817 ** This is an internal extension to SQLITE_STATIC and SQLITE_TRANSIENT.
7819 #define SQLITE_DYNAMIC ((sqlite3_destructor_type)sqlite3DbFree)
7822 ** When SQLITE_OMIT_WSD is defined, it means that the target platform does
7823 ** not support Writable Static Data (WSD) such as global and static variables.
7824 ** All variables must either be on the stack or dynamically allocated from
7825 ** the heap. When WSD is unsupported, the variable declarations scattered
7826 ** throughout the SQLite code must become constants instead. The SQLITE_WSD
7827 ** macro is used for this purpose. And instead of referencing the variable
7828 ** directly, we use its constant as a key to lookup the run-time allocated
7829 ** buffer that holds real variable. The constant is also the initializer
7830 ** for the run-time allocated buffer.
7832 ** In the usual case where WSD is supported, the SQLITE_WSD and GLOBAL
7833 ** macros become no-ops and have zero performance impact.
7835 #ifdef SQLITE_OMIT_WSD
7836 #define SQLITE_WSD const
7837 #define GLOBAL(t,v) (*(t*)sqlite3_wsd_find((void*)&(v), sizeof(v)))
7838 #define sqlite3GlobalConfig GLOBAL(struct Sqlite3Config, sqlite3Config)
7839 SQLITE_API int sqlite3_wsd_init(int N, int J);
7840 SQLITE_API void *sqlite3_wsd_find(void *K, int L);
7841 #else
7842 #define SQLITE_WSD
7843 #define GLOBAL(t,v) v
7844 #define sqlite3GlobalConfig sqlite3Config
7845 #endif
7848 ** The following macros are used to suppress compiler warnings and to
7849 ** make it clear to human readers when a function parameter is deliberately
7850 ** left unused within the body of a function. This usually happens when
7851 ** a function is called via a function pointer. For example the
7852 ** implementation of an SQL aggregate step callback may not use the
7853 ** parameter indicating the number of arguments passed to the aggregate,
7854 ** if it knows that this is enforced elsewhere.
7856 ** When a function parameter is not used at all within the body of a function,
7857 ** it is generally named "NotUsed" or "NotUsed2" to make things even clearer.
7858 ** However, these macros may also be used to suppress warnings related to
7859 ** parameters that may or may not be used depending on compilation options.
7860 ** For example those parameters only used in assert() statements. In these
7861 ** cases the parameters are named as per the usual conventions.
7863 #define UNUSED_PARAMETER(x) (void)(x)
7864 #define UNUSED_PARAMETER2(x,y) UNUSED_PARAMETER(x),UNUSED_PARAMETER(y)
7867 ** Forward references to structures
7869 typedef struct AggInfo AggInfo;
7870 typedef struct AuthContext AuthContext;
7871 typedef struct AutoincInfo AutoincInfo;
7872 typedef struct Bitvec Bitvec;
7873 typedef struct CollSeq CollSeq;
7874 typedef struct Column Column;
7875 typedef struct Db Db;
7876 typedef struct Schema Schema;
7877 typedef struct Expr Expr;
7878 typedef struct ExprList ExprList;
7879 typedef struct ExprSpan ExprSpan;
7880 typedef struct FKey FKey;
7881 typedef struct FuncDestructor FuncDestructor;
7882 typedef struct FuncDef FuncDef;
7883 typedef struct FuncDefHash FuncDefHash;
7884 typedef struct IdList IdList;
7885 typedef struct Index Index;
7886 typedef struct IndexSample IndexSample;
7887 typedef struct KeyClass KeyClass;
7888 typedef struct KeyInfo KeyInfo;
7889 typedef struct Lookaside Lookaside;
7890 typedef struct LookasideSlot LookasideSlot;
7891 typedef struct Module Module;
7892 typedef struct NameContext NameContext;
7893 typedef struct Parse Parse;
7894 typedef struct RowSet RowSet;
7895 typedef struct Savepoint Savepoint;
7896 typedef struct Select Select;
7897 typedef struct SrcList SrcList;
7898 typedef struct StrAccum StrAccum;
7899 typedef struct Table Table;
7900 typedef struct TableLock TableLock;
7901 typedef struct Token Token;
7902 typedef struct Trigger Trigger;
7903 typedef struct TriggerPrg TriggerPrg;
7904 typedef struct TriggerStep TriggerStep;
7905 typedef struct UnpackedRecord UnpackedRecord;
7906 typedef struct VTable VTable;
7907 typedef struct VtabCtx VtabCtx;
7908 typedef struct Walker Walker;
7909 typedef struct WherePlan WherePlan;
7910 typedef struct WhereInfo WhereInfo;
7911 typedef struct WhereLevel WhereLevel;
7914 ** Defer sourcing vdbe.h and btree.h until after the "u8" and
7915 ** "BusyHandler" typedefs. vdbe.h also requires a few of the opaque
7916 ** pointer types (i.e. FuncDef) defined above.
7918 /************** Include btree.h in the middle of sqliteInt.h *****************/
7919 /************** Begin file btree.h *******************************************/
7921 ** 2001 September 15
7923 ** The author disclaims copyright to this source code. In place of
7924 ** a legal notice, here is a blessing:
7926 ** May you do good and not evil.
7927 ** May you find forgiveness for yourself and forgive others.
7928 ** May you share freely, never taking more than you give.
7930 *************************************************************************
7931 ** This header file defines the interface that the sqlite B-Tree file
7932 ** subsystem. See comments in the source code for a detailed description
7933 ** of what each interface routine does.
7935 #ifndef _BTREE_H_
7936 #define _BTREE_H_
7938 /* TODO: This definition is just included so other modules compile. It
7939 ** needs to be revisited.
7941 #define SQLITE_N_BTREE_META 10
7944 ** If defined as non-zero, auto-vacuum is enabled by default. Otherwise
7945 ** it must be turned on for each database using "PRAGMA auto_vacuum = 1".
7947 #ifndef SQLITE_DEFAULT_AUTOVACUUM
7948 #define SQLITE_DEFAULT_AUTOVACUUM 0
7949 #endif
7951 #define BTREE_AUTOVACUUM_NONE 0 /* Do not do auto-vacuum */
7952 #define BTREE_AUTOVACUUM_FULL 1 /* Do full auto-vacuum */
7953 #define BTREE_AUTOVACUUM_INCR 2 /* Incremental vacuum */
7956 ** Forward declarations of structure
7958 typedef struct Btree Btree;
7959 typedef struct BtCursor BtCursor;
7960 typedef struct BtShared BtShared;
7963 SQLITE_PRIVATE int sqlite3BtreeOpen(
7964 sqlite3_vfs *pVfs, /* VFS to use with this b-tree */
7965 const char *zFilename, /* Name of database file to open */
7966 sqlite3 *db, /* Associated database connection */
7967 Btree **ppBtree, /* Return open Btree* here */
7968 int flags, /* Flags */
7969 int vfsFlags /* Flags passed through to VFS open */
7972 /* The flags parameter to sqlite3BtreeOpen can be the bitwise or of the
7973 ** following values.
7975 ** NOTE: These values must match the corresponding PAGER_ values in
7976 ** pager.h.
7978 #define BTREE_OMIT_JOURNAL 1 /* Do not create or use a rollback journal */
7979 #define BTREE_NO_READLOCK 2 /* Omit readlocks on readonly files */
7980 #define BTREE_MEMORY 4 /* This is an in-memory DB */
7981 #define BTREE_SINGLE 8 /* The file contains at most 1 b-tree */
7982 #define BTREE_UNORDERED 16 /* Use of a hash implementation is OK */
7984 SQLITE_PRIVATE int sqlite3BtreeClose(Btree*);
7985 SQLITE_PRIVATE int sqlite3BtreeSetCacheSize(Btree*,int);
7986 SQLITE_PRIVATE int sqlite3BtreeSetSafetyLevel(Btree*,int,int,int);
7987 SQLITE_PRIVATE int sqlite3BtreeSyncDisabled(Btree*);
7988 SQLITE_PRIVATE int sqlite3BtreeSetPageSize(Btree *p, int nPagesize, int nReserve, int eFix);
7989 SQLITE_PRIVATE int sqlite3BtreeGetPageSize(Btree*);
7990 SQLITE_PRIVATE int sqlite3BtreeMaxPageCount(Btree*,int);
7991 SQLITE_PRIVATE u32 sqlite3BtreeLastPage(Btree*);
7992 SQLITE_PRIVATE int sqlite3BtreeSecureDelete(Btree*,int);
7993 SQLITE_PRIVATE int sqlite3BtreeGetReserve(Btree*);
7994 SQLITE_PRIVATE int sqlite3BtreeSetAutoVacuum(Btree *, int);
7995 SQLITE_PRIVATE int sqlite3BtreeGetAutoVacuum(Btree *);
7996 SQLITE_PRIVATE int sqlite3BtreeBeginTrans(Btree*,int);
7997 SQLITE_PRIVATE int sqlite3BtreeCommitPhaseOne(Btree*, const char *zMaster);
7998 SQLITE_PRIVATE int sqlite3BtreeCommitPhaseTwo(Btree*, int);
7999 SQLITE_PRIVATE int sqlite3BtreeCommit(Btree*);
8000 SQLITE_PRIVATE int sqlite3BtreeRollback(Btree*);
8001 SQLITE_PRIVATE int sqlite3BtreeBeginStmt(Btree*,int);
8002 SQLITE_PRIVATE int sqlite3BtreeCreateTable(Btree*, int*, int flags);
8003 SQLITE_PRIVATE int sqlite3BtreeIsInTrans(Btree*);
8004 SQLITE_PRIVATE int sqlite3BtreeIsInReadTrans(Btree*);
8005 SQLITE_PRIVATE int sqlite3BtreeIsInBackup(Btree*);
8006 SQLITE_PRIVATE void *sqlite3BtreeSchema(Btree *, int, void(*)(void *));
8007 SQLITE_PRIVATE int sqlite3BtreeSchemaLocked(Btree *pBtree);
8008 SQLITE_PRIVATE int sqlite3BtreeLockTable(Btree *pBtree, int iTab, u8 isWriteLock);
8009 SQLITE_PRIVATE int sqlite3BtreeSavepoint(Btree *, int, int);
8011 SQLITE_PRIVATE const char *sqlite3BtreeGetFilename(Btree *);
8012 SQLITE_PRIVATE const char *sqlite3BtreeGetJournalname(Btree *);
8013 SQLITE_PRIVATE int sqlite3BtreeCopyFile(Btree *, Btree *);
8015 SQLITE_PRIVATE int sqlite3BtreeIncrVacuum(Btree *);
8017 /* The flags parameter to sqlite3BtreeCreateTable can be the bitwise OR
8018 ** of the flags shown below.
8020 ** Every SQLite table must have either BTREE_INTKEY or BTREE_BLOBKEY set.
8021 ** With BTREE_INTKEY, the table key is a 64-bit integer and arbitrary data
8022 ** is stored in the leaves. (BTREE_INTKEY is used for SQL tables.) With
8023 ** BTREE_BLOBKEY, the key is an arbitrary BLOB and no content is stored
8024 ** anywhere - the key is the content. (BTREE_BLOBKEY is used for SQL
8025 ** indices.)
8027 #define BTREE_INTKEY 1 /* Table has only 64-bit signed integer keys */
8028 #define BTREE_BLOBKEY 2 /* Table has keys only - no data */
8030 SQLITE_PRIVATE int sqlite3BtreeDropTable(Btree*, int, int*);
8031 SQLITE_PRIVATE int sqlite3BtreeClearTable(Btree*, int, int*);
8032 SQLITE_PRIVATE void sqlite3BtreeTripAllCursors(Btree*, int);
8034 SQLITE_PRIVATE void sqlite3BtreeGetMeta(Btree *pBtree, int idx, u32 *pValue);
8035 SQLITE_PRIVATE int sqlite3BtreeUpdateMeta(Btree*, int idx, u32 value);
8038 ** The second parameter to sqlite3BtreeGetMeta or sqlite3BtreeUpdateMeta
8039 ** should be one of the following values. The integer values are assigned
8040 ** to constants so that the offset of the corresponding field in an
8041 ** SQLite database header may be found using the following formula:
8043 ** offset = 36 + (idx * 4)
8045 ** For example, the free-page-count field is located at byte offset 36 of
8046 ** the database file header. The incr-vacuum-flag field is located at
8047 ** byte offset 64 (== 36+4*7).
8049 #define BTREE_FREE_PAGE_COUNT 0
8050 #define BTREE_SCHEMA_VERSION 1
8051 #define BTREE_FILE_FORMAT 2
8052 #define BTREE_DEFAULT_CACHE_SIZE 3
8053 #define BTREE_LARGEST_ROOT_PAGE 4
8054 #define BTREE_TEXT_ENCODING 5
8055 #define BTREE_USER_VERSION 6
8056 #define BTREE_INCR_VACUUM 7
8058 SQLITE_PRIVATE int sqlite3BtreeCursor(
8059 Btree*, /* BTree containing table to open */
8060 int iTable, /* Index of root page */
8061 int wrFlag, /* 1 for writing. 0 for read-only */
8062 struct KeyInfo*, /* First argument to compare function */
8063 BtCursor *pCursor /* Space to write cursor structure */
8065 SQLITE_PRIVATE int sqlite3BtreeCursorSize(void);
8066 SQLITE_PRIVATE void sqlite3BtreeCursorZero(BtCursor*);
8068 SQLITE_PRIVATE int sqlite3BtreeCloseCursor(BtCursor*);
8069 SQLITE_PRIVATE int sqlite3BtreeMovetoUnpacked(
8070 BtCursor*,
8071 UnpackedRecord *pUnKey,
8072 i64 intKey,
8073 int bias,
8074 int *pRes
8076 SQLITE_PRIVATE int sqlite3BtreeCursorHasMoved(BtCursor*, int*);
8077 SQLITE_PRIVATE int sqlite3BtreeDelete(BtCursor*);
8078 SQLITE_PRIVATE int sqlite3BtreeInsert(BtCursor*, const void *pKey, i64 nKey,
8079 const void *pData, int nData,
8080 int nZero, int bias, int seekResult);
8081 SQLITE_PRIVATE int sqlite3BtreeFirst(BtCursor*, int *pRes);
8082 SQLITE_PRIVATE int sqlite3BtreeLast(BtCursor*, int *pRes);
8083 SQLITE_PRIVATE int sqlite3BtreeNext(BtCursor*, int *pRes);
8084 SQLITE_PRIVATE int sqlite3BtreeEof(BtCursor*);
8085 SQLITE_PRIVATE int sqlite3BtreePrevious(BtCursor*, int *pRes);
8086 SQLITE_PRIVATE int sqlite3BtreeKeySize(BtCursor*, i64 *pSize);
8087 SQLITE_PRIVATE int sqlite3BtreeKey(BtCursor*, u32 offset, u32 amt, void*);
8088 SQLITE_PRIVATE const void *sqlite3BtreeKeyFetch(BtCursor*, int *pAmt);
8089 SQLITE_PRIVATE const void *sqlite3BtreeDataFetch(BtCursor*, int *pAmt);
8090 SQLITE_PRIVATE int sqlite3BtreeDataSize(BtCursor*, u32 *pSize);
8091 SQLITE_PRIVATE int sqlite3BtreeData(BtCursor*, u32 offset, u32 amt, void*);
8092 SQLITE_PRIVATE void sqlite3BtreeSetCachedRowid(BtCursor*, sqlite3_int64);
8093 SQLITE_PRIVATE sqlite3_int64 sqlite3BtreeGetCachedRowid(BtCursor*);
8095 SQLITE_PRIVATE char *sqlite3BtreeIntegrityCheck(Btree*, int *aRoot, int nRoot, int, int*);
8096 SQLITE_PRIVATE struct Pager *sqlite3BtreePager(Btree*);
8098 SQLITE_PRIVATE int sqlite3BtreePutData(BtCursor*, u32 offset, u32 amt, void*);
8099 SQLITE_PRIVATE void sqlite3BtreeCacheOverflow(BtCursor *);
8100 SQLITE_PRIVATE void sqlite3BtreeClearCursor(BtCursor *);
8102 SQLITE_PRIVATE int sqlite3BtreeSetVersion(Btree *pBt, int iVersion);
8104 #ifndef NDEBUG
8105 SQLITE_PRIVATE int sqlite3BtreeCursorIsValid(BtCursor*);
8106 #endif
8108 #ifndef SQLITE_OMIT_BTREECOUNT
8109 SQLITE_PRIVATE int sqlite3BtreeCount(BtCursor *, i64 *);
8110 #endif
8112 #ifdef SQLITE_TEST
8113 SQLITE_PRIVATE int sqlite3BtreeCursorInfo(BtCursor*, int*, int);
8114 SQLITE_PRIVATE void sqlite3BtreeCursorList(Btree*);
8115 #endif
8117 #ifndef SQLITE_OMIT_WAL
8118 SQLITE_PRIVATE int sqlite3BtreeCheckpoint(Btree*, int, int *, int *);
8119 #endif
8122 ** If we are not using shared cache, then there is no need to
8123 ** use mutexes to access the BtShared structures. So make the
8124 ** Enter and Leave procedures no-ops.
8126 #ifndef SQLITE_OMIT_SHARED_CACHE
8127 SQLITE_PRIVATE void sqlite3BtreeEnter(Btree*);
8128 SQLITE_PRIVATE void sqlite3BtreeEnterAll(sqlite3*);
8129 #else
8130 # define sqlite3BtreeEnter(X)
8131 # define sqlite3BtreeEnterAll(X)
8132 #endif
8134 #if !defined(SQLITE_OMIT_SHARED_CACHE) && SQLITE_THREADSAFE
8135 SQLITE_PRIVATE int sqlite3BtreeSharable(Btree*);
8136 SQLITE_PRIVATE void sqlite3BtreeLeave(Btree*);
8137 SQLITE_PRIVATE void sqlite3BtreeEnterCursor(BtCursor*);
8138 SQLITE_PRIVATE void sqlite3BtreeLeaveCursor(BtCursor*);
8139 SQLITE_PRIVATE void sqlite3BtreeLeaveAll(sqlite3*);
8140 #ifndef NDEBUG
8141 /* These routines are used inside assert() statements only. */
8142 SQLITE_PRIVATE int sqlite3BtreeHoldsMutex(Btree*);
8143 SQLITE_PRIVATE int sqlite3BtreeHoldsAllMutexes(sqlite3*);
8144 SQLITE_PRIVATE int sqlite3SchemaMutexHeld(sqlite3*,int,Schema*);
8145 #endif
8146 #else
8148 # define sqlite3BtreeSharable(X) 0
8149 # define sqlite3BtreeLeave(X)
8150 # define sqlite3BtreeEnterCursor(X)
8151 # define sqlite3BtreeLeaveCursor(X)
8152 # define sqlite3BtreeLeaveAll(X)
8154 # define sqlite3BtreeHoldsMutex(X) 1
8155 # define sqlite3BtreeHoldsAllMutexes(X) 1
8156 # define sqlite3SchemaMutexHeld(X,Y,Z) 1
8157 #endif
8160 #endif /* _BTREE_H_ */
8162 /************** End of btree.h ***********************************************/
8163 /************** Continuing where we left off in sqliteInt.h ******************/
8164 /************** Include vdbe.h in the middle of sqliteInt.h ******************/
8165 /************** Begin file vdbe.h ********************************************/
8167 ** 2001 September 15
8169 ** The author disclaims copyright to this source code. In place of
8170 ** a legal notice, here is a blessing:
8172 ** May you do good and not evil.
8173 ** May you find forgiveness for yourself and forgive others.
8174 ** May you share freely, never taking more than you give.
8176 *************************************************************************
8177 ** Header file for the Virtual DataBase Engine (VDBE)
8179 ** This header defines the interface to the virtual database engine
8180 ** or VDBE. The VDBE implements an abstract machine that runs a
8181 ** simple program to access and modify the underlying database.
8183 #ifndef _SQLITE_VDBE_H_
8184 #define _SQLITE_VDBE_H_
8185 /* #include <stdio.h> */
8188 ** A single VDBE is an opaque structure named "Vdbe". Only routines
8189 ** in the source file sqliteVdbe.c are allowed to see the insides
8190 ** of this structure.
8192 typedef struct Vdbe Vdbe;
8195 ** The names of the following types declared in vdbeInt.h are required
8196 ** for the VdbeOp definition.
8198 typedef struct VdbeFunc VdbeFunc;
8199 typedef struct Mem Mem;
8200 typedef struct SubProgram SubProgram;
8203 ** A single instruction of the virtual machine has an opcode
8204 ** and as many as three operands. The instruction is recorded
8205 ** as an instance of the following structure:
8207 struct VdbeOp {
8208 u8 opcode; /* What operation to perform */
8209 signed char p4type; /* One of the P4_xxx constants for p4 */
8210 u8 opflags; /* Mask of the OPFLG_* flags in opcodes.h */
8211 u8 p5; /* Fifth parameter is an unsigned character */
8212 int p1; /* First operand */
8213 int p2; /* Second parameter (often the jump destination) */
8214 int p3; /* The third parameter */
8215 union { /* fourth parameter */
8216 int i; /* Integer value if p4type==P4_INT32 */
8217 void *p; /* Generic pointer */
8218 char *z; /* Pointer to data for string (char array) types */
8219 i64 *pI64; /* Used when p4type is P4_INT64 */
8220 double *pReal; /* Used when p4type is P4_REAL */
8221 FuncDef *pFunc; /* Used when p4type is P4_FUNCDEF */
8222 VdbeFunc *pVdbeFunc; /* Used when p4type is P4_VDBEFUNC */
8223 CollSeq *pColl; /* Used when p4type is P4_COLLSEQ */
8224 Mem *pMem; /* Used when p4type is P4_MEM */
8225 VTable *pVtab; /* Used when p4type is P4_VTAB */
8226 KeyInfo *pKeyInfo; /* Used when p4type is P4_KEYINFO */
8227 int *ai; /* Used when p4type is P4_INTARRAY */
8228 SubProgram *pProgram; /* Used when p4type is P4_SUBPROGRAM */
8229 int (*xAdvance)(BtCursor *, int *);
8230 } p4;
8231 #ifdef SQLITE_DEBUG
8232 char *zComment; /* Comment to improve readability */
8233 #endif
8234 #ifdef VDBE_PROFILE
8235 int cnt; /* Number of times this instruction was executed */
8236 u64 cycles; /* Total time spent executing this instruction */
8237 #endif
8239 typedef struct VdbeOp VdbeOp;
8243 ** A sub-routine used to implement a trigger program.
8245 struct SubProgram {
8246 VdbeOp *aOp; /* Array of opcodes for sub-program */
8247 int nOp; /* Elements in aOp[] */
8248 int nMem; /* Number of memory cells required */
8249 int nCsr; /* Number of cursors required */
8250 void *token; /* id that may be used to recursive triggers */
8251 SubProgram *pNext; /* Next sub-program already visited */
8255 ** A smaller version of VdbeOp used for the VdbeAddOpList() function because
8256 ** it takes up less space.
8258 struct VdbeOpList {
8259 u8 opcode; /* What operation to perform */
8260 signed char p1; /* First operand */
8261 signed char p2; /* Second parameter (often the jump destination) */
8262 signed char p3; /* Third parameter */
8264 typedef struct VdbeOpList VdbeOpList;
8267 ** Allowed values of VdbeOp.p4type
8269 #define P4_NOTUSED 0 /* The P4 parameter is not used */
8270 #define P4_DYNAMIC (-1) /* Pointer to a string obtained from sqliteMalloc() */
8271 #define P4_STATIC (-2) /* Pointer to a static string */
8272 #define P4_COLLSEQ (-4) /* P4 is a pointer to a CollSeq structure */
8273 #define P4_FUNCDEF (-5) /* P4 is a pointer to a FuncDef structure */
8274 #define P4_KEYINFO (-6) /* P4 is a pointer to a KeyInfo structure */
8275 #define P4_VDBEFUNC (-7) /* P4 is a pointer to a VdbeFunc structure */
8276 #define P4_MEM (-8) /* P4 is a pointer to a Mem* structure */
8277 #define P4_TRANSIENT 0 /* P4 is a pointer to a transient string */
8278 #define P4_VTAB (-10) /* P4 is a pointer to an sqlite3_vtab structure */
8279 #define P4_MPRINTF (-11) /* P4 is a string obtained from sqlite3_mprintf() */
8280 #define P4_REAL (-12) /* P4 is a 64-bit floating point value */
8281 #define P4_INT64 (-13) /* P4 is a 64-bit signed integer */
8282 #define P4_INT32 (-14) /* P4 is a 32-bit signed integer */
8283 #define P4_INTARRAY (-15) /* P4 is a vector of 32-bit integers */
8284 #define P4_SUBPROGRAM (-18) /* P4 is a pointer to a SubProgram structure */
8285 #define P4_ADVANCE (-19) /* P4 is a pointer to BtreeNext() or BtreePrev() */
8287 /* When adding a P4 argument using P4_KEYINFO, a copy of the KeyInfo structure
8288 ** is made. That copy is freed when the Vdbe is finalized. But if the
8289 ** argument is P4_KEYINFO_HANDOFF, the passed in pointer is used. It still
8290 ** gets freed when the Vdbe is finalized so it still should be obtained
8291 ** from a single sqliteMalloc(). But no copy is made and the calling
8292 ** function should *not* try to free the KeyInfo.
8294 #define P4_KEYINFO_HANDOFF (-16)
8295 #define P4_KEYINFO_STATIC (-17)
8298 ** The Vdbe.aColName array contains 5n Mem structures, where n is the
8299 ** number of columns of data returned by the statement.
8301 #define COLNAME_NAME 0
8302 #define COLNAME_DECLTYPE 1
8303 #define COLNAME_DATABASE 2
8304 #define COLNAME_TABLE 3
8305 #define COLNAME_COLUMN 4
8306 #ifdef SQLITE_ENABLE_COLUMN_METADATA
8307 # define COLNAME_N 5 /* Number of COLNAME_xxx symbols */
8308 #else
8309 # ifdef SQLITE_OMIT_DECLTYPE
8310 # define COLNAME_N 1 /* Store only the name */
8311 # else
8312 # define COLNAME_N 2 /* Store the name and decltype */
8313 # endif
8314 #endif
8317 ** The following macro converts a relative address in the p2 field
8318 ** of a VdbeOp structure into a negative number so that
8319 ** sqlite3VdbeAddOpList() knows that the address is relative. Calling
8320 ** the macro again restores the address.
8322 #define ADDR(X) (-1-(X))
8325 ** The makefile scans the vdbe.c source file and creates the "opcodes.h"
8326 ** header file that defines a number for each opcode used by the VDBE.
8328 /************** Include opcodes.h in the middle of vdbe.h ********************/
8329 /************** Begin file opcodes.h *****************************************/
8330 /* Automatically generated. Do not edit */
8331 /* See the mkopcodeh.awk script for details */
8332 #define OP_Goto 1
8333 #define OP_Gosub 2
8334 #define OP_Return 3
8335 #define OP_Yield 4
8336 #define OP_HaltIfNull 5
8337 #define OP_Halt 6
8338 #define OP_Integer 7
8339 #define OP_Int64 8
8340 #define OP_Real 130 /* same as TK_FLOAT */
8341 #define OP_String8 94 /* same as TK_STRING */
8342 #define OP_String 9
8343 #define OP_Null 10
8344 #define OP_Blob 11
8345 #define OP_Variable 12
8346 #define OP_Move 13
8347 #define OP_Copy 14
8348 #define OP_SCopy 15
8349 #define OP_ResultRow 16
8350 #define OP_Concat 91 /* same as TK_CONCAT */
8351 #define OP_Add 86 /* same as TK_PLUS */
8352 #define OP_Subtract 87 /* same as TK_MINUS */
8353 #define OP_Multiply 88 /* same as TK_STAR */
8354 #define OP_Divide 89 /* same as TK_SLASH */
8355 #define OP_Remainder 90 /* same as TK_REM */
8356 #define OP_CollSeq 17
8357 #define OP_Function 18
8358 #define OP_BitAnd 82 /* same as TK_BITAND */
8359 #define OP_BitOr 83 /* same as TK_BITOR */
8360 #define OP_ShiftLeft 84 /* same as TK_LSHIFT */
8361 #define OP_ShiftRight 85 /* same as TK_RSHIFT */
8362 #define OP_AddImm 20
8363 #define OP_MustBeInt 21
8364 #define OP_RealAffinity 22
8365 #define OP_ToText 141 /* same as TK_TO_TEXT */
8366 #define OP_ToBlob 142 /* same as TK_TO_BLOB */
8367 #define OP_ToNumeric 143 /* same as TK_TO_NUMERIC*/
8368 #define OP_ToInt 144 /* same as TK_TO_INT */
8369 #define OP_ToReal 145 /* same as TK_TO_REAL */
8370 #define OP_Eq 76 /* same as TK_EQ */
8371 #define OP_Ne 75 /* same as TK_NE */
8372 #define OP_Lt 79 /* same as TK_LT */
8373 #define OP_Le 78 /* same as TK_LE */
8374 #define OP_Gt 77 /* same as TK_GT */
8375 #define OP_Ge 80 /* same as TK_GE */
8376 #define OP_Permutation 23
8377 #define OP_Compare 24
8378 #define OP_Jump 25
8379 #define OP_And 69 /* same as TK_AND */
8380 #define OP_Or 68 /* same as TK_OR */
8381 #define OP_Not 19 /* same as TK_NOT */
8382 #define OP_BitNot 93 /* same as TK_BITNOT */
8383 #define OP_Once 26
8384 #define OP_If 27
8385 #define OP_IfNot 28
8386 #define OP_IsNull 73 /* same as TK_ISNULL */
8387 #define OP_NotNull 74 /* same as TK_NOTNULL */
8388 #define OP_Column 29
8389 #define OP_Affinity 30
8390 #define OP_MakeRecord 31
8391 #define OP_Count 32
8392 #define OP_Savepoint 33
8393 #define OP_AutoCommit 34
8394 #define OP_Transaction 35
8395 #define OP_ReadCookie 36
8396 #define OP_SetCookie 37
8397 #define OP_VerifyCookie 38
8398 #define OP_OpenRead 39
8399 #define OP_OpenWrite 40
8400 #define OP_OpenAutoindex 41
8401 #define OP_OpenEphemeral 42
8402 #define OP_SorterOpen 43
8403 #define OP_OpenPseudo 44
8404 #define OP_Close 45
8405 #define OP_SeekLt 46
8406 #define OP_SeekLe 47
8407 #define OP_SeekGe 48
8408 #define OP_SeekGt 49
8409 #define OP_Seek 50
8410 #define OP_NotFound 51
8411 #define OP_Found 52
8412 #define OP_IsUnique 53
8413 #define OP_NotExists 54
8414 #define OP_Sequence 55
8415 #define OP_NewRowid 56
8416 #define OP_Insert 57
8417 #define OP_InsertInt 58
8418 #define OP_Delete 59
8419 #define OP_ResetCount 60
8420 #define OP_SorterCompare 61
8421 #define OP_SorterData 62
8422 #define OP_RowKey 63
8423 #define OP_RowData 64
8424 #define OP_Rowid 65
8425 #define OP_NullRow 66
8426 #define OP_Last 67
8427 #define OP_SorterSort 70
8428 #define OP_Sort 71
8429 #define OP_Rewind 72
8430 #define OP_SorterNext 81
8431 #define OP_Prev 92
8432 #define OP_Next 95
8433 #define OP_SorterInsert 96
8434 #define OP_IdxInsert 97
8435 #define OP_IdxDelete 98
8436 #define OP_IdxRowid 99
8437 #define OP_IdxLT 100
8438 #define OP_IdxGE 101
8439 #define OP_Destroy 102
8440 #define OP_Clear 103
8441 #define OP_CreateIndex 104
8442 #define OP_CreateTable 105
8443 #define OP_ParseSchema 106
8444 #define OP_LoadAnalysis 107
8445 #define OP_DropTable 108
8446 #define OP_DropIndex 109
8447 #define OP_DropTrigger 110
8448 #define OP_IntegrityCk 111
8449 #define OP_RowSetAdd 112
8450 #define OP_RowSetRead 113
8451 #define OP_RowSetTest 114
8452 #define OP_Program 115
8453 #define OP_Param 116
8454 #define OP_FkCounter 117
8455 #define OP_FkIfZero 118
8456 #define OP_MemMax 119
8457 #define OP_IfPos 120
8458 #define OP_IfNeg 121
8459 #define OP_IfZero 122
8460 #define OP_AggStep 123
8461 #define OP_AggFinal 124
8462 #define OP_Checkpoint 125
8463 #define OP_JournalMode 126
8464 #define OP_Vacuum 127
8465 #define OP_IncrVacuum 128
8466 #define OP_Expire 129
8467 #define OP_TableLock 131
8468 #define OP_VBegin 132
8469 #define OP_VCreate 133
8470 #define OP_VDestroy 134
8471 #define OP_VOpen 135
8472 #define OP_VFilter 136
8473 #define OP_VColumn 137
8474 #define OP_VNext 138
8475 #define OP_VRename 139
8476 #define OP_VUpdate 140
8477 #define OP_Pagecount 146
8478 #define OP_MaxPgcnt 147
8479 #define OP_Trace 148
8480 #define OP_Noop 149
8481 #define OP_Explain 150
8484 /* Properties such as "out2" or "jump" that are specified in
8485 ** comments following the "case" for each opcode in the vdbe.c
8486 ** are encoded into bitvectors as follows:
8488 #define OPFLG_JUMP 0x0001 /* jump: P2 holds jmp target */
8489 #define OPFLG_OUT2_PRERELEASE 0x0002 /* out2-prerelease: */
8490 #define OPFLG_IN1 0x0004 /* in1: P1 is an input */
8491 #define OPFLG_IN2 0x0008 /* in2: P2 is an input */
8492 #define OPFLG_IN3 0x0010 /* in3: P3 is an input */
8493 #define OPFLG_OUT2 0x0020 /* out2: P2 is an output */
8494 #define OPFLG_OUT3 0x0040 /* out3: P3 is an output */
8495 #define OPFLG_INITIALIZER {\
8496 /* 0 */ 0x00, 0x01, 0x05, 0x04, 0x04, 0x10, 0x00, 0x02,\
8497 /* 8 */ 0x02, 0x02, 0x02, 0x02, 0x02, 0x00, 0x24, 0x24,\
8498 /* 16 */ 0x00, 0x00, 0x00, 0x24, 0x04, 0x05, 0x04, 0x00,\
8499 /* 24 */ 0x00, 0x01, 0x05, 0x05, 0x05, 0x00, 0x00, 0x00,\
8500 /* 32 */ 0x02, 0x00, 0x00, 0x00, 0x02, 0x10, 0x00, 0x00,\
8501 /* 40 */ 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x11, 0x11,\
8502 /* 48 */ 0x11, 0x11, 0x08, 0x11, 0x11, 0x11, 0x11, 0x02,\
8503 /* 56 */ 0x02, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00,\
8504 /* 64 */ 0x00, 0x02, 0x00, 0x01, 0x4c, 0x4c, 0x01, 0x01,\
8505 /* 72 */ 0x01, 0x05, 0x05, 0x15, 0x15, 0x15, 0x15, 0x15,\
8506 /* 80 */ 0x15, 0x01, 0x4c, 0x4c, 0x4c, 0x4c, 0x4c, 0x4c,\
8507 /* 88 */ 0x4c, 0x4c, 0x4c, 0x4c, 0x01, 0x24, 0x02, 0x01,\
8508 /* 96 */ 0x08, 0x08, 0x00, 0x02, 0x01, 0x01, 0x02, 0x00,\
8509 /* 104 */ 0x02, 0x02, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00,\
8510 /* 112 */ 0x0c, 0x45, 0x15, 0x01, 0x02, 0x00, 0x01, 0x08,\
8511 /* 120 */ 0x05, 0x05, 0x05, 0x00, 0x00, 0x00, 0x02, 0x00,\
8512 /* 128 */ 0x01, 0x00, 0x02, 0x00, 0x00, 0x00, 0x00, 0x00,\
8513 /* 136 */ 0x01, 0x00, 0x01, 0x00, 0x00, 0x04, 0x04, 0x04,\
8514 /* 144 */ 0x04, 0x04, 0x02, 0x02, 0x00, 0x00, 0x00,}
8516 /************** End of opcodes.h *********************************************/
8517 /************** Continuing where we left off in vdbe.h ***********************/
8520 ** Prototypes for the VDBE interface. See comments on the implementation
8521 ** for a description of what each of these routines does.
8523 SQLITE_PRIVATE Vdbe *sqlite3VdbeCreate(sqlite3*);
8524 SQLITE_PRIVATE int sqlite3VdbeAddOp0(Vdbe*,int);
8525 SQLITE_PRIVATE int sqlite3VdbeAddOp1(Vdbe*,int,int);
8526 SQLITE_PRIVATE int sqlite3VdbeAddOp2(Vdbe*,int,int,int);
8527 SQLITE_PRIVATE int sqlite3VdbeAddOp3(Vdbe*,int,int,int,int);
8528 SQLITE_PRIVATE int sqlite3VdbeAddOp4(Vdbe*,int,int,int,int,const char *zP4,int);
8529 SQLITE_PRIVATE int sqlite3VdbeAddOp4Int(Vdbe*,int,int,int,int,int);
8530 SQLITE_PRIVATE int sqlite3VdbeAddOpList(Vdbe*, int nOp, VdbeOpList const *aOp);
8531 SQLITE_PRIVATE void sqlite3VdbeAddParseSchemaOp(Vdbe*,int,char*);
8532 SQLITE_PRIVATE void sqlite3VdbeChangeP1(Vdbe*, u32 addr, int P1);
8533 SQLITE_PRIVATE void sqlite3VdbeChangeP2(Vdbe*, u32 addr, int P2);
8534 SQLITE_PRIVATE void sqlite3VdbeChangeP3(Vdbe*, u32 addr, int P3);
8535 SQLITE_PRIVATE void sqlite3VdbeChangeP5(Vdbe*, u8 P5);
8536 SQLITE_PRIVATE void sqlite3VdbeJumpHere(Vdbe*, int addr);
8537 SQLITE_PRIVATE void sqlite3VdbeChangeToNoop(Vdbe*, int addr);
8538 SQLITE_PRIVATE void sqlite3VdbeChangeP4(Vdbe*, int addr, const char *zP4, int N);
8539 SQLITE_PRIVATE void sqlite3VdbeUsesBtree(Vdbe*, int);
8540 SQLITE_PRIVATE VdbeOp *sqlite3VdbeGetOp(Vdbe*, int);
8541 SQLITE_PRIVATE int sqlite3VdbeMakeLabel(Vdbe*);
8542 SQLITE_PRIVATE void sqlite3VdbeRunOnlyOnce(Vdbe*);
8543 SQLITE_PRIVATE void sqlite3VdbeDelete(Vdbe*);
8544 SQLITE_PRIVATE void sqlite3VdbeDeleteObject(sqlite3*,Vdbe*);
8545 SQLITE_PRIVATE void sqlite3VdbeMakeReady(Vdbe*,Parse*);
8546 SQLITE_PRIVATE int sqlite3VdbeFinalize(Vdbe*);
8547 SQLITE_PRIVATE void sqlite3VdbeResolveLabel(Vdbe*, int);
8548 SQLITE_PRIVATE int sqlite3VdbeCurrentAddr(Vdbe*);
8549 #ifdef SQLITE_DEBUG
8550 SQLITE_PRIVATE int sqlite3VdbeAssertMayAbort(Vdbe *, int);
8551 SQLITE_PRIVATE void sqlite3VdbeTrace(Vdbe*,FILE*);
8552 #endif
8553 SQLITE_PRIVATE void sqlite3VdbeResetStepResult(Vdbe*);
8554 SQLITE_PRIVATE void sqlite3VdbeRewind(Vdbe*);
8555 SQLITE_PRIVATE int sqlite3VdbeReset(Vdbe*);
8556 SQLITE_PRIVATE void sqlite3VdbeSetNumCols(Vdbe*,int);
8557 SQLITE_PRIVATE int sqlite3VdbeSetColName(Vdbe*, int, int, const char *, void(*)(void*));
8558 SQLITE_PRIVATE void sqlite3VdbeCountChanges(Vdbe*);
8559 SQLITE_PRIVATE sqlite3 *sqlite3VdbeDb(Vdbe*);
8560 SQLITE_PRIVATE void sqlite3VdbeSetSql(Vdbe*, const char *z, int n, int);
8561 SQLITE_PRIVATE void sqlite3VdbeSwap(Vdbe*,Vdbe*);
8562 SQLITE_PRIVATE VdbeOp *sqlite3VdbeTakeOpArray(Vdbe*, int*, int*);
8563 SQLITE_PRIVATE sqlite3_value *sqlite3VdbeGetValue(Vdbe*, int, u8);
8564 SQLITE_PRIVATE void sqlite3VdbeSetVarmask(Vdbe*, int);
8565 #ifndef SQLITE_OMIT_TRACE
8566 SQLITE_PRIVATE char *sqlite3VdbeExpandSql(Vdbe*, const char*);
8567 #endif
8569 SQLITE_PRIVATE void sqlite3VdbeRecordUnpack(KeyInfo*,int,const void*,UnpackedRecord*);
8570 SQLITE_PRIVATE int sqlite3VdbeRecordCompare(int,const void*,UnpackedRecord*);
8571 SQLITE_PRIVATE UnpackedRecord *sqlite3VdbeAllocUnpackedRecord(KeyInfo *, char *, int, char **);
8573 #ifndef SQLITE_OMIT_TRIGGER
8574 SQLITE_PRIVATE void sqlite3VdbeLinkSubProgram(Vdbe *, SubProgram *);
8575 #endif
8578 #ifndef NDEBUG
8579 SQLITE_PRIVATE void sqlite3VdbeComment(Vdbe*, const char*, ...);
8580 # define VdbeComment(X) sqlite3VdbeComment X
8581 SQLITE_PRIVATE void sqlite3VdbeNoopComment(Vdbe*, const char*, ...);
8582 # define VdbeNoopComment(X) sqlite3VdbeNoopComment X
8583 #else
8584 # define VdbeComment(X)
8585 # define VdbeNoopComment(X)
8586 #endif
8588 #endif
8590 /************** End of vdbe.h ************************************************/
8591 /************** Continuing where we left off in sqliteInt.h ******************/
8592 /************** Include pager.h in the middle of sqliteInt.h *****************/
8593 /************** Begin file pager.h *******************************************/
8595 ** 2001 September 15
8597 ** The author disclaims copyright to this source code. In place of
8598 ** a legal notice, here is a blessing:
8600 ** May you do good and not evil.
8601 ** May you find forgiveness for yourself and forgive others.
8602 ** May you share freely, never taking more than you give.
8604 *************************************************************************
8605 ** This header file defines the interface that the sqlite page cache
8606 ** subsystem. The page cache subsystem reads and writes a file a page
8607 ** at a time and provides a journal for rollback.
8610 #ifndef _PAGER_H_
8611 #define _PAGER_H_
8614 ** Default maximum size for persistent journal files. A negative
8615 ** value means no limit. This value may be overridden using the
8616 ** sqlite3PagerJournalSizeLimit() API. See also "PRAGMA journal_size_limit".
8618 #ifndef SQLITE_DEFAULT_JOURNAL_SIZE_LIMIT
8619 #define SQLITE_DEFAULT_JOURNAL_SIZE_LIMIT -1
8620 #endif
8623 ** The type used to represent a page number. The first page in a file
8624 ** is called page 1. 0 is used to represent "not a page".
8626 typedef u32 Pgno;
8629 ** Each open file is managed by a separate instance of the "Pager" structure.
8631 typedef struct Pager Pager;
8634 ** Handle type for pages.
8636 typedef struct PgHdr DbPage;
8639 ** Page number PAGER_MJ_PGNO is never used in an SQLite database (it is
8640 ** reserved for working around a windows/posix incompatibility). It is
8641 ** used in the journal to signify that the remainder of the journal file
8642 ** is devoted to storing a master journal name - there are no more pages to
8643 ** roll back. See comments for function writeMasterJournal() in pager.c
8644 ** for details.
8646 #define PAGER_MJ_PGNO(x) ((Pgno)((PENDING_BYTE/((x)->pageSize))+1))
8649 ** Allowed values for the flags parameter to sqlite3PagerOpen().
8651 ** NOTE: These values must match the corresponding BTREE_ values in btree.h.
8653 #define PAGER_OMIT_JOURNAL 0x0001 /* Do not use a rollback journal */
8654 #define PAGER_NO_READLOCK 0x0002 /* Omit readlocks on readonly files */
8655 #define PAGER_MEMORY 0x0004 /* In-memory database */
8658 ** Valid values for the second argument to sqlite3PagerLockingMode().
8660 #define PAGER_LOCKINGMODE_QUERY -1
8661 #define PAGER_LOCKINGMODE_NORMAL 0
8662 #define PAGER_LOCKINGMODE_EXCLUSIVE 1
8665 ** Numeric constants that encode the journalmode.
8667 #define PAGER_JOURNALMODE_QUERY (-1) /* Query the value of journalmode */
8668 #define PAGER_JOURNALMODE_DELETE 0 /* Commit by deleting journal file */
8669 #define PAGER_JOURNALMODE_PERSIST 1 /* Commit by zeroing journal header */
8670 #define PAGER_JOURNALMODE_OFF 2 /* Journal omitted. */
8671 #define PAGER_JOURNALMODE_TRUNCATE 3 /* Commit by truncating journal */
8672 #define PAGER_JOURNALMODE_MEMORY 4 /* In-memory journal file */
8673 #define PAGER_JOURNALMODE_WAL 5 /* Use write-ahead logging */
8676 ** The remainder of this file contains the declarations of the functions
8677 ** that make up the Pager sub-system API. See source code comments for
8678 ** a detailed description of each routine.
8681 /* Open and close a Pager connection. */
8682 SQLITE_PRIVATE int sqlite3PagerOpen(
8683 sqlite3_vfs*,
8684 Pager **ppPager,
8685 const char*,
8686 int,
8687 int,
8688 int,
8689 void(*)(DbPage*)
8691 SQLITE_PRIVATE int sqlite3PagerClose(Pager *pPager);
8692 SQLITE_PRIVATE int sqlite3PagerReadFileheader(Pager*, int, unsigned char*);
8694 /* Functions used to configure a Pager object. */
8695 SQLITE_PRIVATE void sqlite3PagerSetBusyhandler(Pager*, int(*)(void *), void *);
8696 SQLITE_PRIVATE int sqlite3PagerSetPagesize(Pager*, u32*, int);
8697 SQLITE_PRIVATE int sqlite3PagerMaxPageCount(Pager*, int);
8698 SQLITE_PRIVATE void sqlite3PagerSetCachesize(Pager*, int);
8699 SQLITE_PRIVATE void sqlite3PagerSetSafetyLevel(Pager*,int,int,int);
8700 SQLITE_PRIVATE int sqlite3PagerLockingMode(Pager *, int);
8701 SQLITE_PRIVATE int sqlite3PagerSetJournalMode(Pager *, int);
8702 SQLITE_PRIVATE int sqlite3PagerGetJournalMode(Pager*);
8703 SQLITE_PRIVATE int sqlite3PagerOkToChangeJournalMode(Pager*);
8704 SQLITE_PRIVATE i64 sqlite3PagerJournalSizeLimit(Pager *, i64);
8705 SQLITE_PRIVATE sqlite3_backup **sqlite3PagerBackupPtr(Pager*);
8707 /* Functions used to obtain and release page references. */
8708 SQLITE_PRIVATE int sqlite3PagerAcquire(Pager *pPager, Pgno pgno, DbPage **ppPage, int clrFlag);
8709 #define sqlite3PagerGet(A,B,C) sqlite3PagerAcquire(A,B,C,0)
8710 SQLITE_PRIVATE DbPage *sqlite3PagerLookup(Pager *pPager, Pgno pgno);
8711 SQLITE_PRIVATE void sqlite3PagerRef(DbPage*);
8712 SQLITE_PRIVATE void sqlite3PagerUnref(DbPage*);
8714 /* Operations on page references. */
8715 SQLITE_PRIVATE int sqlite3PagerWrite(DbPage*);
8716 SQLITE_PRIVATE void sqlite3PagerDontWrite(DbPage*);
8717 SQLITE_PRIVATE int sqlite3PagerMovepage(Pager*,DbPage*,Pgno,int);
8718 SQLITE_PRIVATE int sqlite3PagerPageRefcount(DbPage*);
8719 SQLITE_PRIVATE void *sqlite3PagerGetData(DbPage *);
8720 SQLITE_PRIVATE void *sqlite3PagerGetExtra(DbPage *);
8722 /* Functions used to manage pager transactions and savepoints. */
8723 SQLITE_PRIVATE void sqlite3PagerPagecount(Pager*, int*);
8724 SQLITE_PRIVATE int sqlite3PagerBegin(Pager*, int exFlag, int);
8725 SQLITE_PRIVATE int sqlite3PagerCommitPhaseOne(Pager*,const char *zMaster, int);
8726 SQLITE_PRIVATE int sqlite3PagerExclusiveLock(Pager*);
8727 SQLITE_PRIVATE int sqlite3PagerSync(Pager *pPager);
8728 SQLITE_PRIVATE int sqlite3PagerCommitPhaseTwo(Pager*);
8729 SQLITE_PRIVATE int sqlite3PagerRollback(Pager*);
8730 SQLITE_PRIVATE int sqlite3PagerOpenSavepoint(Pager *pPager, int n);
8731 SQLITE_PRIVATE int sqlite3PagerSavepoint(Pager *pPager, int op, int iSavepoint);
8732 SQLITE_PRIVATE int sqlite3PagerSharedLock(Pager *pPager);
8734 SQLITE_PRIVATE int sqlite3PagerCheckpoint(Pager *pPager, int, int*, int*);
8735 SQLITE_PRIVATE int sqlite3PagerWalSupported(Pager *pPager);
8736 SQLITE_PRIVATE int sqlite3PagerWalCallback(Pager *pPager);
8737 SQLITE_PRIVATE int sqlite3PagerOpenWal(Pager *pPager, int *pisOpen);
8738 SQLITE_PRIVATE int sqlite3PagerCloseWal(Pager *pPager);
8740 /* Functions used to query pager state and configuration. */
8741 SQLITE_PRIVATE u8 sqlite3PagerIsreadonly(Pager*);
8742 SQLITE_PRIVATE int sqlite3PagerRefcount(Pager*);
8743 SQLITE_PRIVATE int sqlite3PagerMemUsed(Pager*);
8744 SQLITE_PRIVATE const char *sqlite3PagerFilename(Pager*);
8745 SQLITE_PRIVATE const sqlite3_vfs *sqlite3PagerVfs(Pager*);
8746 SQLITE_PRIVATE sqlite3_file *sqlite3PagerFile(Pager*);
8747 SQLITE_PRIVATE const char *sqlite3PagerJournalname(Pager*);
8748 SQLITE_PRIVATE int sqlite3PagerNosync(Pager*);
8749 SQLITE_PRIVATE void *sqlite3PagerTempSpace(Pager*);
8750 SQLITE_PRIVATE int sqlite3PagerIsMemdb(Pager*);
8752 /* Functions used to truncate the database file. */
8753 SQLITE_PRIVATE void sqlite3PagerTruncateImage(Pager*,Pgno);
8755 #if defined(SQLITE_HAS_CODEC) && !defined(SQLITE_OMIT_WAL)
8756 SQLITE_PRIVATE void *sqlite3PagerCodec(DbPage *);
8757 #endif
8759 /* Functions to support testing and debugging. */
8760 #if !defined(NDEBUG) || defined(SQLITE_TEST)
8761 SQLITE_PRIVATE Pgno sqlite3PagerPagenumber(DbPage*);
8762 SQLITE_PRIVATE int sqlite3PagerIswriteable(DbPage*);
8763 #endif
8764 #ifdef SQLITE_TEST
8765 SQLITE_PRIVATE int *sqlite3PagerStats(Pager*);
8766 SQLITE_PRIVATE void sqlite3PagerRefdump(Pager*);
8767 void disable_simulated_io_errors(void);
8768 void enable_simulated_io_errors(void);
8769 #else
8770 # define disable_simulated_io_errors()
8771 # define enable_simulated_io_errors()
8772 #endif
8774 #endif /* _PAGER_H_ */
8776 /************** End of pager.h ***********************************************/
8777 /************** Continuing where we left off in sqliteInt.h ******************/
8778 /************** Include pcache.h in the middle of sqliteInt.h ****************/
8779 /************** Begin file pcache.h ******************************************/
8781 ** 2008 August 05
8783 ** The author disclaims copyright to this source code. In place of
8784 ** a legal notice, here is a blessing:
8786 ** May you do good and not evil.
8787 ** May you find forgiveness for yourself and forgive others.
8788 ** May you share freely, never taking more than you give.
8790 *************************************************************************
8791 ** This header file defines the interface that the sqlite page cache
8792 ** subsystem.
8795 #ifndef _PCACHE_H_
8797 typedef struct PgHdr PgHdr;
8798 typedef struct PCache PCache;
8801 ** Every page in the cache is controlled by an instance of the following
8802 ** structure.
8804 struct PgHdr {
8805 void *pData; /* Content of this page */
8806 void *pExtra; /* Extra content */
8807 PgHdr *pDirty; /* Transient list of dirty pages */
8808 Pgno pgno; /* Page number for this page */
8809 Pager *pPager; /* The pager this page is part of */
8810 #ifdef SQLITE_CHECK_PAGES
8811 u32 pageHash; /* Hash of page content */
8812 #endif
8813 u16 flags; /* PGHDR flags defined below */
8815 /**********************************************************************
8816 ** Elements above are public. All that follows is private to pcache.c
8817 ** and should not be accessed by other modules.
8819 i16 nRef; /* Number of users of this page */
8820 PCache *pCache; /* Cache that owns this page */
8822 PgHdr *pDirtyNext; /* Next element in list of dirty pages */
8823 PgHdr *pDirtyPrev; /* Previous element in list of dirty pages */
8826 /* Bit values for PgHdr.flags */
8827 #define PGHDR_DIRTY 0x002 /* Page has changed */
8828 #define PGHDR_NEED_SYNC 0x004 /* Fsync the rollback journal before
8829 ** writing this page to the database */
8830 #define PGHDR_NEED_READ 0x008 /* Content is unread */
8831 #define PGHDR_REUSE_UNLIKELY 0x010 /* A hint that reuse is unlikely */
8832 #define PGHDR_DONT_WRITE 0x020 /* Do not write content to disk */
8834 /* Initialize and shutdown the page cache subsystem */
8835 SQLITE_PRIVATE int sqlite3PcacheInitialize(void);
8836 SQLITE_PRIVATE void sqlite3PcacheShutdown(void);
8838 /* Page cache buffer management:
8839 ** These routines implement SQLITE_CONFIG_PAGECACHE.
8841 SQLITE_PRIVATE void sqlite3PCacheBufferSetup(void *, int sz, int n);
8843 /* Create a new pager cache.
8844 ** Under memory stress, invoke xStress to try to make pages clean.
8845 ** Only clean and unpinned pages can be reclaimed.
8847 SQLITE_PRIVATE void sqlite3PcacheOpen(
8848 int szPage, /* Size of every page */
8849 int szExtra, /* Extra space associated with each page */
8850 int bPurgeable, /* True if pages are on backing store */
8851 int (*xStress)(void*, PgHdr*), /* Call to try to make pages clean */
8852 void *pStress, /* Argument to xStress */
8853 PCache *pToInit /* Preallocated space for the PCache */
8856 /* Modify the page-size after the cache has been created. */
8857 SQLITE_PRIVATE void sqlite3PcacheSetPageSize(PCache *, int);
8859 /* Return the size in bytes of a PCache object. Used to preallocate
8860 ** storage space.
8862 SQLITE_PRIVATE int sqlite3PcacheSize(void);
8864 /* One release per successful fetch. Page is pinned until released.
8865 ** Reference counted.
8867 SQLITE_PRIVATE int sqlite3PcacheFetch(PCache*, Pgno, int createFlag, PgHdr**);
8868 SQLITE_PRIVATE void sqlite3PcacheRelease(PgHdr*);
8870 SQLITE_PRIVATE void sqlite3PcacheDrop(PgHdr*); /* Remove page from cache */
8871 SQLITE_PRIVATE void sqlite3PcacheMakeDirty(PgHdr*); /* Make sure page is marked dirty */
8872 SQLITE_PRIVATE void sqlite3PcacheMakeClean(PgHdr*); /* Mark a single page as clean */
8873 SQLITE_PRIVATE void sqlite3PcacheCleanAll(PCache*); /* Mark all dirty list pages as clean */
8875 /* Change a page number. Used by incr-vacuum. */
8876 SQLITE_PRIVATE void sqlite3PcacheMove(PgHdr*, Pgno);
8878 /* Remove all pages with pgno>x. Reset the cache if x==0 */
8879 SQLITE_PRIVATE void sqlite3PcacheTruncate(PCache*, Pgno x);
8881 /* Get a list of all dirty pages in the cache, sorted by page number */
8882 SQLITE_PRIVATE PgHdr *sqlite3PcacheDirtyList(PCache*);
8884 /* Reset and close the cache object */
8885 SQLITE_PRIVATE void sqlite3PcacheClose(PCache*);
8887 /* Clear flags from pages of the page cache */
8888 SQLITE_PRIVATE void sqlite3PcacheClearSyncFlags(PCache *);
8890 /* Discard the contents of the cache */
8891 SQLITE_PRIVATE void sqlite3PcacheClear(PCache*);
8893 /* Return the total number of outstanding page references */
8894 SQLITE_PRIVATE int sqlite3PcacheRefCount(PCache*);
8896 /* Increment the reference count of an existing page */
8897 SQLITE_PRIVATE void sqlite3PcacheRef(PgHdr*);
8899 SQLITE_PRIVATE int sqlite3PcachePageRefcount(PgHdr*);
8901 /* Return the total number of pages stored in the cache */
8902 SQLITE_PRIVATE int sqlite3PcachePagecount(PCache*);
8904 #if defined(SQLITE_CHECK_PAGES) || defined(SQLITE_DEBUG)
8905 /* Iterate through all dirty pages currently stored in the cache. This
8906 ** interface is only available if SQLITE_CHECK_PAGES is defined when the
8907 ** library is built.
8909 SQLITE_PRIVATE void sqlite3PcacheIterateDirty(PCache *pCache, void (*xIter)(PgHdr *));
8910 #endif
8912 /* Set and get the suggested cache-size for the specified pager-cache.
8914 ** If no global maximum is configured, then the system attempts to limit
8915 ** the total number of pages cached by purgeable pager-caches to the sum
8916 ** of the suggested cache-sizes.
8918 SQLITE_PRIVATE void sqlite3PcacheSetCachesize(PCache *, int);
8919 #ifdef SQLITE_TEST
8920 SQLITE_PRIVATE int sqlite3PcacheGetCachesize(PCache *);
8921 #endif
8923 #ifdef SQLITE_ENABLE_MEMORY_MANAGEMENT
8924 /* Try to return memory used by the pcache module to the main memory heap */
8925 SQLITE_PRIVATE int sqlite3PcacheReleaseMemory(int);
8926 #endif
8928 #ifdef SQLITE_TEST
8929 SQLITE_PRIVATE void sqlite3PcacheStats(int*,int*,int*,int*);
8930 #endif
8932 SQLITE_PRIVATE void sqlite3PCacheSetDefault(void);
8934 #endif /* _PCACHE_H_ */
8936 /************** End of pcache.h **********************************************/
8937 /************** Continuing where we left off in sqliteInt.h ******************/
8939 /************** Include os.h in the middle of sqliteInt.h ********************/
8940 /************** Begin file os.h **********************************************/
8942 ** 2001 September 16
8944 ** The author disclaims copyright to this source code. In place of
8945 ** a legal notice, here is a blessing:
8947 ** May you do good and not evil.
8948 ** May you find forgiveness for yourself and forgive others.
8949 ** May you share freely, never taking more than you give.
8951 ******************************************************************************
8953 ** This header file (together with is companion C source-code file
8954 ** "os.c") attempt to abstract the underlying operating system so that
8955 ** the SQLite library will work on both POSIX and windows systems.
8957 ** This header file is #include-ed by sqliteInt.h and thus ends up
8958 ** being included by every source file.
8960 #ifndef _SQLITE_OS_H_
8961 #define _SQLITE_OS_H_
8964 ** Figure out if we are dealing with Unix, Windows, or some other
8965 ** operating system. After the following block of preprocess macros,
8966 ** all of SQLITE_OS_UNIX, SQLITE_OS_WIN, SQLITE_OS_OS2, and SQLITE_OS_OTHER
8967 ** will defined to either 1 or 0. One of the four will be 1. The other
8968 ** three will be 0.
8970 #if defined(SQLITE_OS_OTHER)
8971 # if SQLITE_OS_OTHER==1
8972 # undef SQLITE_OS_UNIX
8973 # define SQLITE_OS_UNIX 0
8974 # undef SQLITE_OS_WIN
8975 # define SQLITE_OS_WIN 0
8976 # undef SQLITE_OS_OS2
8977 # define SQLITE_OS_OS2 0
8978 # else
8979 # undef SQLITE_OS_OTHER
8980 # endif
8981 #endif
8982 #if !defined(SQLITE_OS_UNIX) && !defined(SQLITE_OS_OTHER)
8983 # define SQLITE_OS_OTHER 0
8984 # ifndef SQLITE_OS_WIN
8985 # if defined(_WIN32) || defined(WIN32) || defined(__CYGWIN__) || defined(__MINGW32__) || defined(__BORLANDC__)
8986 # define SQLITE_OS_WIN 1
8987 # define SQLITE_OS_UNIX 0
8988 # define SQLITE_OS_OS2 0
8989 # elif defined(__EMX__) || defined(_OS2) || defined(OS2) || defined(_OS2_) || defined(__OS2__)
8990 # define SQLITE_OS_WIN 0
8991 # define SQLITE_OS_UNIX 0
8992 # define SQLITE_OS_OS2 1
8993 # else
8994 # define SQLITE_OS_WIN 0
8995 # define SQLITE_OS_UNIX 1
8996 # define SQLITE_OS_OS2 0
8997 # endif
8998 # else
8999 # define SQLITE_OS_UNIX 0
9000 # define SQLITE_OS_OS2 0
9001 # endif
9002 #else
9003 # ifndef SQLITE_OS_WIN
9004 # define SQLITE_OS_WIN 0
9005 # endif
9006 #endif
9009 ** Determine if we are dealing with WindowsCE - which has a much
9010 ** reduced API.
9012 #if defined(_WIN32_WCE)
9013 # define SQLITE_OS_WINCE 1
9014 #else
9015 # define SQLITE_OS_WINCE 0
9016 #endif
9020 ** Define the maximum size of a temporary filename
9022 #if SQLITE_OS_WIN
9023 # include <windows.h>
9024 # define SQLITE_TEMPNAME_SIZE (MAX_PATH+50)
9025 #elif SQLITE_OS_OS2
9026 # if (__GNUC__ > 3 || __GNUC__ == 3 && __GNUC_MINOR__ >= 3) && defined(OS2_HIGH_MEMORY)
9027 # include <os2safe.h> /* has to be included before os2.h for linking to work */
9028 # endif
9029 # define INCL_DOSDATETIME
9030 # define INCL_DOSFILEMGR
9031 # define INCL_DOSERRORS
9032 # define INCL_DOSMISC
9033 # define INCL_DOSPROCESS
9034 # define INCL_DOSMODULEMGR
9035 # define INCL_DOSSEMAPHORES
9036 # include <os2.h>
9037 # include <uconv.h>
9038 # define SQLITE_TEMPNAME_SIZE (CCHMAXPATHCOMP)
9039 #else
9040 # define SQLITE_TEMPNAME_SIZE 200
9041 #endif
9043 /* If the SET_FULLSYNC macro is not defined above, then make it
9044 ** a no-op
9046 #ifndef SET_FULLSYNC
9047 # define SET_FULLSYNC(x,y)
9048 #endif
9051 ** The default size of a disk sector
9053 #ifndef SQLITE_DEFAULT_SECTOR_SIZE
9054 # define SQLITE_DEFAULT_SECTOR_SIZE 512
9055 #endif
9058 ** Temporary files are named starting with this prefix followed by 16 random
9059 ** alphanumeric characters, and no file extension. They are stored in the
9060 ** OS's standard temporary file directory, and are deleted prior to exit.
9061 ** If sqlite is being embedded in another program, you may wish to change the
9062 ** prefix to reflect your program's name, so that if your program exits
9063 ** prematurely, old temporary files can be easily identified. This can be done
9064 ** using -DSQLITE_TEMP_FILE_PREFIX=myprefix_ on the compiler command line.
9066 ** 2006-10-31: The default prefix used to be "sqlite_". But then
9067 ** Mcafee started using SQLite in their anti-virus product and it
9068 ** started putting files with the "sqlite" name in the c:/temp folder.
9069 ** This annoyed many windows users. Those users would then do a
9070 ** Google search for "sqlite", find the telephone numbers of the
9071 ** developers and call to wake them up at night and complain.
9072 ** For this reason, the default name prefix is changed to be "sqlite"
9073 ** spelled backwards. So the temp files are still identified, but
9074 ** anybody smart enough to figure out the code is also likely smart
9075 ** enough to know that calling the developer will not help get rid
9076 ** of the file.
9078 #ifndef SQLITE_TEMP_FILE_PREFIX
9079 # define SQLITE_TEMP_FILE_PREFIX "etilqs_"
9080 #endif
9083 ** The following values may be passed as the second argument to
9084 ** sqlite3OsLock(). The various locks exhibit the following semantics:
9086 ** SHARED: Any number of processes may hold a SHARED lock simultaneously.
9087 ** RESERVED: A single process may hold a RESERVED lock on a file at
9088 ** any time. Other processes may hold and obtain new SHARED locks.
9089 ** PENDING: A single process may hold a PENDING lock on a file at
9090 ** any one time. Existing SHARED locks may persist, but no new
9091 ** SHARED locks may be obtained by other processes.
9092 ** EXCLUSIVE: An EXCLUSIVE lock precludes all other locks.
9094 ** PENDING_LOCK may not be passed directly to sqlite3OsLock(). Instead, a
9095 ** process that requests an EXCLUSIVE lock may actually obtain a PENDING
9096 ** lock. This can be upgraded to an EXCLUSIVE lock by a subsequent call to
9097 ** sqlite3OsLock().
9099 #define NO_LOCK 0
9100 #define SHARED_LOCK 1
9101 #define RESERVED_LOCK 2
9102 #define PENDING_LOCK 3
9103 #define EXCLUSIVE_LOCK 4
9106 ** File Locking Notes: (Mostly about windows but also some info for Unix)
9108 ** We cannot use LockFileEx() or UnlockFileEx() on Win95/98/ME because
9109 ** those functions are not available. So we use only LockFile() and
9110 ** UnlockFile().
9112 ** LockFile() prevents not just writing but also reading by other processes.
9113 ** A SHARED_LOCK is obtained by locking a single randomly-chosen
9114 ** byte out of a specific range of bytes. The lock byte is obtained at
9115 ** random so two separate readers can probably access the file at the
9116 ** same time, unless they are unlucky and choose the same lock byte.
9117 ** An EXCLUSIVE_LOCK is obtained by locking all bytes in the range.
9118 ** There can only be one writer. A RESERVED_LOCK is obtained by locking
9119 ** a single byte of the file that is designated as the reserved lock byte.
9120 ** A PENDING_LOCK is obtained by locking a designated byte different from
9121 ** the RESERVED_LOCK byte.
9123 ** On WinNT/2K/XP systems, LockFileEx() and UnlockFileEx() are available,
9124 ** which means we can use reader/writer locks. When reader/writer locks
9125 ** are used, the lock is placed on the same range of bytes that is used
9126 ** for probabilistic locking in Win95/98/ME. Hence, the locking scheme
9127 ** will support two or more Win95 readers or two or more WinNT readers.
9128 ** But a single Win95 reader will lock out all WinNT readers and a single
9129 ** WinNT reader will lock out all other Win95 readers.
9131 ** The following #defines specify the range of bytes used for locking.
9132 ** SHARED_SIZE is the number of bytes available in the pool from which
9133 ** a random byte is selected for a shared lock. The pool of bytes for
9134 ** shared locks begins at SHARED_FIRST.
9136 ** The same locking strategy and
9137 ** byte ranges are used for Unix. This leaves open the possiblity of having
9138 ** clients on win95, winNT, and unix all talking to the same shared file
9139 ** and all locking correctly. To do so would require that samba (or whatever
9140 ** tool is being used for file sharing) implements locks correctly between
9141 ** windows and unix. I'm guessing that isn't likely to happen, but by
9142 ** using the same locking range we are at least open to the possibility.
9144 ** Locking in windows is manditory. For this reason, we cannot store
9145 ** actual data in the bytes used for locking. The pager never allocates
9146 ** the pages involved in locking therefore. SHARED_SIZE is selected so
9147 ** that all locks will fit on a single page even at the minimum page size.
9148 ** PENDING_BYTE defines the beginning of the locks. By default PENDING_BYTE
9149 ** is set high so that we don't have to allocate an unused page except
9150 ** for very large databases. But one should test the page skipping logic
9151 ** by setting PENDING_BYTE low and running the entire regression suite.
9153 ** Changing the value of PENDING_BYTE results in a subtly incompatible
9154 ** file format. Depending on how it is changed, you might not notice
9155 ** the incompatibility right away, even running a full regression test.
9156 ** The default location of PENDING_BYTE is the first byte past the
9157 ** 1GB boundary.
9160 #ifdef SQLITE_OMIT_WSD
9161 # define PENDING_BYTE (0x40000000)
9162 #else
9163 # define PENDING_BYTE sqlite3PendingByte
9164 #endif
9165 #define RESERVED_BYTE (PENDING_BYTE+1)
9166 #define SHARED_FIRST (PENDING_BYTE+2)
9167 #define SHARED_SIZE 510
9170 ** Wrapper around OS specific sqlite3_os_init() function.
9172 SQLITE_PRIVATE int sqlite3OsInit(void);
9175 ** Functions for accessing sqlite3_file methods
9177 SQLITE_PRIVATE int sqlite3OsClose(sqlite3_file*);
9178 SQLITE_PRIVATE int sqlite3OsRead(sqlite3_file*, void*, int amt, i64 offset);
9179 SQLITE_PRIVATE int sqlite3OsWrite(sqlite3_file*, const void*, int amt, i64 offset);
9180 SQLITE_PRIVATE int sqlite3OsTruncate(sqlite3_file*, i64 size);
9181 SQLITE_PRIVATE int sqlite3OsSync(sqlite3_file*, int);
9182 SQLITE_PRIVATE int sqlite3OsFileSize(sqlite3_file*, i64 *pSize);
9183 SQLITE_PRIVATE int sqlite3OsLock(sqlite3_file*, int);
9184 SQLITE_PRIVATE int sqlite3OsUnlock(sqlite3_file*, int);
9185 SQLITE_PRIVATE int sqlite3OsCheckReservedLock(sqlite3_file *id, int *pResOut);
9186 SQLITE_PRIVATE int sqlite3OsFileControl(sqlite3_file*,int,void*);
9187 #define SQLITE_FCNTL_DB_UNCHANGED 0xca093fa0
9188 SQLITE_PRIVATE int sqlite3OsSectorSize(sqlite3_file *id);
9189 SQLITE_PRIVATE int sqlite3OsDeviceCharacteristics(sqlite3_file *id);
9190 SQLITE_PRIVATE int sqlite3OsShmMap(sqlite3_file *,int,int,int,void volatile **);
9191 SQLITE_PRIVATE int sqlite3OsShmLock(sqlite3_file *id, int, int, int);
9192 SQLITE_PRIVATE void sqlite3OsShmBarrier(sqlite3_file *id);
9193 SQLITE_PRIVATE int sqlite3OsShmUnmap(sqlite3_file *id, int);
9196 ** Functions for accessing sqlite3_vfs methods
9198 SQLITE_PRIVATE int sqlite3OsOpen(sqlite3_vfs *, const char *, sqlite3_file*, int, int *);
9199 SQLITE_PRIVATE int sqlite3OsDelete(sqlite3_vfs *, const char *, int);
9200 SQLITE_PRIVATE int sqlite3OsAccess(sqlite3_vfs *, const char *, int, int *pResOut);
9201 SQLITE_PRIVATE int sqlite3OsFullPathname(sqlite3_vfs *, const char *, int, char *);
9202 #ifndef SQLITE_OMIT_LOAD_EXTENSION
9203 SQLITE_PRIVATE void *sqlite3OsDlOpen(sqlite3_vfs *, const char *);
9204 SQLITE_PRIVATE void sqlite3OsDlError(sqlite3_vfs *, int, char *);
9205 SQLITE_PRIVATE void (*sqlite3OsDlSym(sqlite3_vfs *, void *, const char *))(void);
9206 SQLITE_PRIVATE void sqlite3OsDlClose(sqlite3_vfs *, void *);
9207 #endif /* SQLITE_OMIT_LOAD_EXTENSION */
9208 SQLITE_PRIVATE int sqlite3OsRandomness(sqlite3_vfs *, int, char *);
9209 SQLITE_PRIVATE int sqlite3OsSleep(sqlite3_vfs *, int);
9210 SQLITE_PRIVATE int sqlite3OsCurrentTimeInt64(sqlite3_vfs *, sqlite3_int64*);
9213 ** Convenience functions for opening and closing files using
9214 ** sqlite3_malloc() to obtain space for the file-handle structure.
9216 SQLITE_PRIVATE int sqlite3OsOpenMalloc(sqlite3_vfs *, const char *, sqlite3_file **, int,int*);
9217 SQLITE_PRIVATE int sqlite3OsCloseFree(sqlite3_file *);
9219 #endif /* _SQLITE_OS_H_ */
9221 /************** End of os.h **************************************************/
9222 /************** Continuing where we left off in sqliteInt.h ******************/
9223 /************** Include mutex.h in the middle of sqliteInt.h *****************/
9224 /************** Begin file mutex.h *******************************************/
9226 ** 2007 August 28
9228 ** The author disclaims copyright to this source code. In place of
9229 ** a legal notice, here is a blessing:
9231 ** May you do good and not evil.
9232 ** May you find forgiveness for yourself and forgive others.
9233 ** May you share freely, never taking more than you give.
9235 *************************************************************************
9237 ** This file contains the common header for all mutex implementations.
9238 ** The sqliteInt.h header #includes this file so that it is available
9239 ** to all source files. We break it out in an effort to keep the code
9240 ** better organized.
9242 ** NOTE: source files should *not* #include this header file directly.
9243 ** Source files should #include the sqliteInt.h file and let that file
9244 ** include this one indirectly.
9249 ** Figure out what version of the code to use. The choices are
9251 ** SQLITE_MUTEX_OMIT No mutex logic. Not even stubs. The
9252 ** mutexes implemention cannot be overridden
9253 ** at start-time.
9255 ** SQLITE_MUTEX_NOOP For single-threaded applications. No
9256 ** mutual exclusion is provided. But this
9257 ** implementation can be overridden at
9258 ** start-time.
9260 ** SQLITE_MUTEX_PTHREADS For multi-threaded applications on Unix.
9262 ** SQLITE_MUTEX_W32 For multi-threaded applications on Win32.
9264 ** SQLITE_MUTEX_OS2 For multi-threaded applications on OS/2.
9266 #if !SQLITE_THREADSAFE
9267 # define SQLITE_MUTEX_OMIT
9268 #endif
9269 #if SQLITE_THREADSAFE && !defined(SQLITE_MUTEX_NOOP)
9270 # if SQLITE_OS_UNIX
9271 # define SQLITE_MUTEX_PTHREADS
9272 # elif SQLITE_OS_WIN
9273 # define SQLITE_MUTEX_W32
9274 # elif SQLITE_OS_OS2
9275 # define SQLITE_MUTEX_OS2
9276 # else
9277 # define SQLITE_MUTEX_NOOP
9278 # endif
9279 #endif
9281 #ifdef SQLITE_MUTEX_OMIT
9283 ** If this is a no-op implementation, implement everything as macros.
9285 #define sqlite3_mutex_alloc(X) ((sqlite3_mutex*)8)
9286 #define sqlite3_mutex_free(X)
9287 #define sqlite3_mutex_enter(X)
9288 #define sqlite3_mutex_try(X) SQLITE_OK
9289 #define sqlite3_mutex_leave(X)
9290 #define sqlite3_mutex_held(X) ((void)(X),1)
9291 #define sqlite3_mutex_notheld(X) ((void)(X),1)
9292 #define sqlite3MutexAlloc(X) ((sqlite3_mutex*)8)
9293 #define sqlite3MutexInit() SQLITE_OK
9294 #define sqlite3MutexEnd()
9295 #endif /* defined(SQLITE_MUTEX_OMIT) */
9297 /************** End of mutex.h ***********************************************/
9298 /************** Continuing where we left off in sqliteInt.h ******************/
9302 ** Each database file to be accessed by the system is an instance
9303 ** of the following structure. There are normally two of these structures
9304 ** in the sqlite.aDb[] array. aDb[0] is the main database file and
9305 ** aDb[1] is the database file used to hold temporary tables. Additional
9306 ** databases may be attached.
9308 struct Db {
9309 char *zName; /* Name of this database */
9310 Btree *pBt; /* The B*Tree structure for this database file */
9311 u8 inTrans; /* 0: not writable. 1: Transaction. 2: Checkpoint */
9312 u8 safety_level; /* How aggressive at syncing data to disk */
9313 Schema *pSchema; /* Pointer to database schema (possibly shared) */
9317 ** An instance of the following structure stores a database schema.
9319 ** Most Schema objects are associated with a Btree. The exception is
9320 ** the Schema for the TEMP databaes (sqlite3.aDb[1]) which is free-standing.
9321 ** In shared cache mode, a single Schema object can be shared by multiple
9322 ** Btrees that refer to the same underlying BtShared object.
9324 ** Schema objects are automatically deallocated when the last Btree that
9325 ** references them is destroyed. The TEMP Schema is manually freed by
9326 ** sqlite3_close().
9328 ** A thread must be holding a mutex on the corresponding Btree in order
9329 ** to access Schema content. This implies that the thread must also be
9330 ** holding a mutex on the sqlite3 connection pointer that owns the Btree.
9331 ** For a TEMP Schema, only the connection mutex is required.
9333 struct Schema {
9334 int schema_cookie; /* Database schema version number for this file */
9335 int iGeneration; /* Generation counter. Incremented with each change */
9336 Hash tblHash; /* All tables indexed by name */
9337 Hash idxHash; /* All (named) indices indexed by name */
9338 Hash trigHash; /* All triggers indexed by name */
9339 Hash fkeyHash; /* All foreign keys by referenced table name */
9340 Table *pSeqTab; /* The sqlite_sequence table used by AUTOINCREMENT */
9341 u8 file_format; /* Schema format version for this file */
9342 u8 enc; /* Text encoding used by this database */
9343 u16 flags; /* Flags associated with this schema */
9344 int cache_size; /* Number of pages to use in the cache */
9348 ** These macros can be used to test, set, or clear bits in the
9349 ** Db.pSchema->flags field.
9351 #define DbHasProperty(D,I,P) (((D)->aDb[I].pSchema->flags&(P))==(P))
9352 #define DbHasAnyProperty(D,I,P) (((D)->aDb[I].pSchema->flags&(P))!=0)
9353 #define DbSetProperty(D,I,P) (D)->aDb[I].pSchema->flags|=(P)
9354 #define DbClearProperty(D,I,P) (D)->aDb[I].pSchema->flags&=~(P)
9357 ** Allowed values for the DB.pSchema->flags field.
9359 ** The DB_SchemaLoaded flag is set after the database schema has been
9360 ** read into internal hash tables.
9362 ** DB_UnresetViews means that one or more views have column names that
9363 ** have been filled out. If the schema changes, these column names might
9364 ** changes and so the view will need to be reset.
9366 #define DB_SchemaLoaded 0x0001 /* The schema has been loaded */
9367 #define DB_UnresetViews 0x0002 /* Some views have defined column names */
9368 #define DB_Empty 0x0004 /* The file is empty (length 0 bytes) */
9371 ** The number of different kinds of things that can be limited
9372 ** using the sqlite3_limit() interface.
9374 #define SQLITE_N_LIMIT (SQLITE_LIMIT_TRIGGER_DEPTH+1)
9377 ** Lookaside malloc is a set of fixed-size buffers that can be used
9378 ** to satisfy small transient memory allocation requests for objects
9379 ** associated with a particular database connection. The use of
9380 ** lookaside malloc provides a significant performance enhancement
9381 ** (approx 10%) by avoiding numerous malloc/free requests while parsing
9382 ** SQL statements.
9384 ** The Lookaside structure holds configuration information about the
9385 ** lookaside malloc subsystem. Each available memory allocation in
9386 ** the lookaside subsystem is stored on a linked list of LookasideSlot
9387 ** objects.
9389 ** Lookaside allocations are only allowed for objects that are associated
9390 ** with a particular database connection. Hence, schema information cannot
9391 ** be stored in lookaside because in shared cache mode the schema information
9392 ** is shared by multiple database connections. Therefore, while parsing
9393 ** schema information, the Lookaside.bEnabled flag is cleared so that
9394 ** lookaside allocations are not used to construct the schema objects.
9396 struct Lookaside {
9397 u16 sz; /* Size of each buffer in bytes */
9398 u8 bEnabled; /* False to disable new lookaside allocations */
9399 u8 bMalloced; /* True if pStart obtained from sqlite3_malloc() */
9400 int nOut; /* Number of buffers currently checked out */
9401 int mxOut; /* Highwater mark for nOut */
9402 int anStat[3]; /* 0: hits. 1: size misses. 2: full misses */
9403 LookasideSlot *pFree; /* List of available buffers */
9404 void *pStart; /* First byte of available memory space */
9405 void *pEnd; /* First byte past end of available space */
9407 struct LookasideSlot {
9408 LookasideSlot *pNext; /* Next buffer in the list of free buffers */
9412 ** A hash table for function definitions.
9414 ** Hash each FuncDef structure into one of the FuncDefHash.a[] slots.
9415 ** Collisions are on the FuncDef.pHash chain.
9417 struct FuncDefHash {
9418 FuncDef *a[23]; /* Hash table for functions */
9422 ** Each database connection is an instance of the following structure.
9424 ** The sqlite.lastRowid records the last insert rowid generated by an
9425 ** insert statement. Inserts on views do not affect its value. Each
9426 ** trigger has its own context, so that lastRowid can be updated inside
9427 ** triggers as usual. The previous value will be restored once the trigger
9428 ** exits. Upon entering a before or instead of trigger, lastRowid is no
9429 ** longer (since after version 2.8.12) reset to -1.
9431 ** The sqlite.nChange does not count changes within triggers and keeps no
9432 ** context. It is reset at start of sqlite3_exec.
9433 ** The sqlite.lsChange represents the number of changes made by the last
9434 ** insert, update, or delete statement. It remains constant throughout the
9435 ** length of a statement and is then updated by OP_SetCounts. It keeps a
9436 ** context stack just like lastRowid so that the count of changes
9437 ** within a trigger is not seen outside the trigger. Changes to views do not
9438 ** affect the value of lsChange.
9439 ** The sqlite.csChange keeps track of the number of current changes (since
9440 ** the last statement) and is used to update sqlite_lsChange.
9442 ** The member variables sqlite.errCode, sqlite.zErrMsg and sqlite.zErrMsg16
9443 ** store the most recent error code and, if applicable, string. The
9444 ** internal function sqlite3Error() is used to set these variables
9445 ** consistently.
9447 struct sqlite3 {
9448 sqlite3_vfs *pVfs; /* OS Interface */
9449 int nDb; /* Number of backends currently in use */
9450 Db *aDb; /* All backends */
9451 int flags; /* Miscellaneous flags. See below */
9452 unsigned int openFlags; /* Flags passed to sqlite3_vfs.xOpen() */
9453 int errCode; /* Most recent error code (SQLITE_*) */
9454 int errMask; /* & result codes with this before returning */
9455 u8 autoCommit; /* The auto-commit flag. */
9456 u8 temp_store; /* 1: file 2: memory 0: default */
9457 u8 mallocFailed; /* True if we have seen a malloc failure */
9458 u8 dfltLockMode; /* Default locking-mode for attached dbs */
9459 signed char nextAutovac; /* Autovac setting after VACUUM if >=0 */
9460 u8 suppressErr; /* Do not issue error messages if true */
9461 u8 vtabOnConflict; /* Value to return for s3_vtab_on_conflict() */
9462 int nextPagesize; /* Pagesize after VACUUM if >0 */
9463 int nTable; /* Number of tables in the database */
9464 CollSeq *pDfltColl; /* The default collating sequence (BINARY) */
9465 i64 lastRowid; /* ROWID of most recent insert (see above) */
9466 u32 magic; /* Magic number for detect library misuse */
9467 int nChange; /* Value returned by sqlite3_changes() */
9468 int nTotalChange; /* Value returned by sqlite3_total_changes() */
9469 sqlite3_mutex *mutex; /* Connection mutex */
9470 int aLimit[SQLITE_N_LIMIT]; /* Limits */
9471 struct sqlite3InitInfo { /* Information used during initialization */
9472 int iDb; /* When back is being initialized */
9473 int newTnum; /* Rootpage of table being initialized */
9474 u8 busy; /* TRUE if currently initializing */
9475 u8 orphanTrigger; /* Last statement is orphaned TEMP trigger */
9476 } init;
9477 int nExtension; /* Number of loaded extensions */
9478 void **aExtension; /* Array of shared library handles */
9479 struct Vdbe *pVdbe; /* List of active virtual machines */
9480 int activeVdbeCnt; /* Number of VDBEs currently executing */
9481 int writeVdbeCnt; /* Number of active VDBEs that are writing */
9482 int vdbeExecCnt; /* Number of nested calls to VdbeExec() */
9483 void (*xTrace)(void*,const char*); /* Trace function */
9484 void *pTraceArg; /* Argument to the trace function */
9485 void (*xProfile)(void*,const char*,u64); /* Profiling function */
9486 void *pProfileArg; /* Argument to profile function */
9487 void *pCommitArg; /* Argument to xCommitCallback() */
9488 int (*xCommitCallback)(void*); /* Invoked at every commit. */
9489 void *pRollbackArg; /* Argument to xRollbackCallback() */
9490 void (*xRollbackCallback)(void*); /* Invoked at every commit. */
9491 void *pUpdateArg;
9492 void (*xUpdateCallback)(void*,int, const char*,const char*,sqlite_int64);
9493 #ifndef SQLITE_OMIT_WAL
9494 int (*xWalCallback)(void *, sqlite3 *, const char *, int);
9495 void *pWalArg;
9496 #endif
9497 void(*xCollNeeded)(void*,sqlite3*,int eTextRep,const char*);
9498 void(*xCollNeeded16)(void*,sqlite3*,int eTextRep,const void*);
9499 void *pCollNeededArg;
9500 sqlite3_value *pErr; /* Most recent error message */
9501 char *zErrMsg; /* Most recent error message (UTF-8 encoded) */
9502 char *zErrMsg16; /* Most recent error message (UTF-16 encoded) */
9503 union {
9504 volatile int isInterrupted; /* True if sqlite3_interrupt has been called */
9505 double notUsed1; /* Spacer */
9506 } u1;
9507 Lookaside lookaside; /* Lookaside malloc configuration */
9508 #ifndef SQLITE_OMIT_AUTHORIZATION
9509 int (*xAuth)(void*,int,const char*,const char*,const char*,const char*);
9510 /* Access authorization function */
9511 void *pAuthArg; /* 1st argument to the access auth function */
9512 #endif
9513 #ifndef SQLITE_OMIT_PROGRESS_CALLBACK
9514 int (*xProgress)(void *); /* The progress callback */
9515 void *pProgressArg; /* Argument to the progress callback */
9516 int nProgressOps; /* Number of opcodes for progress callback */
9517 #endif
9518 #ifndef SQLITE_OMIT_VIRTUALTABLE
9519 Hash aModule; /* populated by sqlite3_create_module() */
9520 VtabCtx *pVtabCtx; /* Context for active vtab connect/create */
9521 VTable **aVTrans; /* Virtual tables with open transactions */
9522 int nVTrans; /* Allocated size of aVTrans */
9523 VTable *pDisconnect; /* Disconnect these in next sqlite3_prepare() */
9524 #endif
9525 FuncDefHash aFunc; /* Hash table of connection functions */
9526 Hash aCollSeq; /* All collating sequences */
9527 BusyHandler busyHandler; /* Busy callback */
9528 int busyTimeout; /* Busy handler timeout, in msec */
9529 Db aDbStatic[2]; /* Static space for the 2 default backends */
9530 Savepoint *pSavepoint; /* List of active savepoints */
9531 int nSavepoint; /* Number of non-transaction savepoints */
9532 int nStatement; /* Number of nested statement-transactions */
9533 u8 isTransactionSavepoint; /* True if the outermost savepoint is a TS */
9534 i64 nDeferredCons; /* Net deferred constraints this transaction. */
9535 int *pnBytesFreed; /* If not NULL, increment this in DbFree() */
9537 #ifdef SQLITE_ENABLE_UNLOCK_NOTIFY
9538 /* The following variables are all protected by the STATIC_MASTER
9539 ** mutex, not by sqlite3.mutex. They are used by code in notify.c.
9541 ** When X.pUnlockConnection==Y, that means that X is waiting for Y to
9542 ** unlock so that it can proceed.
9544 ** When X.pBlockingConnection==Y, that means that something that X tried
9545 ** tried to do recently failed with an SQLITE_LOCKED error due to locks
9546 ** held by Y.
9548 sqlite3 *pBlockingConnection; /* Connection that caused SQLITE_LOCKED */
9549 sqlite3 *pUnlockConnection; /* Connection to watch for unlock */
9550 void *pUnlockArg; /* Argument to xUnlockNotify */
9551 void (*xUnlockNotify)(void **, int); /* Unlock notify callback */
9552 sqlite3 *pNextBlocked; /* Next in list of all blocked connections */
9553 #endif
9557 ** A macro to discover the encoding of a database.
9559 #define ENC(db) ((db)->aDb[0].pSchema->enc)
9562 ** Possible values for the sqlite3.flags.
9564 #define SQLITE_VdbeTrace 0x00000100 /* True to trace VDBE execution */
9565 #define SQLITE_InternChanges 0x00000200 /* Uncommitted Hash table changes */
9566 #define SQLITE_FullColNames 0x00000400 /* Show full column names on SELECT */
9567 #define SQLITE_ShortColNames 0x00000800 /* Show short columns names */
9568 #define SQLITE_CountRows 0x00001000 /* Count rows changed by INSERT, */
9569 /* DELETE, or UPDATE and return */
9570 /* the count using a callback. */
9571 #define SQLITE_NullCallback 0x00002000 /* Invoke the callback once if the */
9572 /* result set is empty */
9573 #define SQLITE_SqlTrace 0x00004000 /* Debug print SQL as it executes */
9574 #define SQLITE_VdbeListing 0x00008000 /* Debug listings of VDBE programs */
9575 #define SQLITE_WriteSchema 0x00010000 /* OK to update SQLITE_MASTER */
9576 #define SQLITE_NoReadlock 0x00020000 /* Readlocks are omitted when
9577 ** accessing read-only databases */
9578 #define SQLITE_IgnoreChecks 0x00040000 /* Do not enforce check constraints */
9579 #define SQLITE_ReadUncommitted 0x0080000 /* For shared-cache mode */
9580 #define SQLITE_LegacyFileFmt 0x00100000 /* Create new databases in format 1 */
9581 #define SQLITE_FullFSync 0x00200000 /* Use full fsync on the backend */
9582 #define SQLITE_CkptFullFSync 0x00400000 /* Use full fsync for checkpoint */
9583 #define SQLITE_RecoveryMode 0x00800000 /* Ignore schema errors */
9584 #define SQLITE_ReverseOrder 0x01000000 /* Reverse unordered SELECTs */
9585 #define SQLITE_RecTriggers 0x02000000 /* Enable recursive triggers */
9586 #define SQLITE_ForeignKeys 0x04000000 /* Enforce foreign key constraints */
9587 #define SQLITE_AutoIndex 0x08000000 /* Enable automatic indexes */
9588 #define SQLITE_PreferBuiltin 0x10000000 /* Preference to built-in funcs */
9589 #define SQLITE_LoadExtension 0x20000000 /* Enable load_extension */
9590 #define SQLITE_EnableTrigger 0x40000000 /* True to enable triggers */
9593 ** Bits of the sqlite3.flags field that are used by the
9594 ** sqlite3_test_control(SQLITE_TESTCTRL_OPTIMIZATIONS,...) interface.
9595 ** These must be the low-order bits of the flags field.
9597 #define SQLITE_QueryFlattener 0x01 /* Disable query flattening */
9598 #define SQLITE_ColumnCache 0x02 /* Disable the column cache */
9599 #define SQLITE_IndexSort 0x04 /* Disable indexes for sorting */
9600 #define SQLITE_IndexSearch 0x08 /* Disable indexes for searching */
9601 #define SQLITE_IndexCover 0x10 /* Disable index covering table */
9602 #define SQLITE_GroupByOrder 0x20 /* Disable GROUPBY cover of ORDERBY */
9603 #define SQLITE_FactorOutConst 0x40 /* Disable factoring out constants */
9604 #define SQLITE_IdxRealAsInt 0x80 /* Store REAL as INT in indices */
9605 #define SQLITE_DistinctOpt 0x80 /* DISTINCT using indexes */
9606 #define SQLITE_OptMask 0xff /* Mask of all disablable opts */
9609 ** Possible values for the sqlite.magic field.
9610 ** The numbers are obtained at random and have no special meaning, other
9611 ** than being distinct from one another.
9613 #define SQLITE_MAGIC_OPEN 0xa029a697 /* Database is open */
9614 #define SQLITE_MAGIC_CLOSED 0x9f3c2d33 /* Database is closed */
9615 #define SQLITE_MAGIC_SICK 0x4b771290 /* Error and awaiting close */
9616 #define SQLITE_MAGIC_BUSY 0xf03b7906 /* Database currently in use */
9617 #define SQLITE_MAGIC_ERROR 0xb5357930 /* An SQLITE_MISUSE error occurred */
9620 ** Each SQL function is defined by an instance of the following
9621 ** structure. A pointer to this structure is stored in the sqlite.aFunc
9622 ** hash table. When multiple functions have the same name, the hash table
9623 ** points to a linked list of these structures.
9625 struct FuncDef {
9626 i16 nArg; /* Number of arguments. -1 means unlimited */
9627 u8 iPrefEnc; /* Preferred text encoding (SQLITE_UTF8, 16LE, 16BE) */
9628 u8 flags; /* Some combination of SQLITE_FUNC_* */
9629 void *pUserData; /* User data parameter */
9630 FuncDef *pNext; /* Next function with same name */
9631 void (*xFunc)(sqlite3_context*,int,sqlite3_value**); /* Regular function */
9632 void (*xStep)(sqlite3_context*,int,sqlite3_value**); /* Aggregate step */
9633 void (*xFinalize)(sqlite3_context*); /* Aggregate finalizer */
9634 char *zName; /* SQL name of the function. */
9635 FuncDef *pHash; /* Next with a different name but the same hash */
9636 FuncDestructor *pDestructor; /* Reference counted destructor function */
9640 ** This structure encapsulates a user-function destructor callback (as
9641 ** configured using create_function_v2()) and a reference counter. When
9642 ** create_function_v2() is called to create a function with a destructor,
9643 ** a single object of this type is allocated. FuncDestructor.nRef is set to
9644 ** the number of FuncDef objects created (either 1 or 3, depending on whether
9645 ** or not the specified encoding is SQLITE_ANY). The FuncDef.pDestructor
9646 ** member of each of the new FuncDef objects is set to point to the allocated
9647 ** FuncDestructor.
9649 ** Thereafter, when one of the FuncDef objects is deleted, the reference
9650 ** count on this object is decremented. When it reaches 0, the destructor
9651 ** is invoked and the FuncDestructor structure freed.
9653 struct FuncDestructor {
9654 int nRef;
9655 void (*xDestroy)(void *);
9656 void *pUserData;
9660 ** Possible values for FuncDef.flags
9662 #define SQLITE_FUNC_LIKE 0x01 /* Candidate for the LIKE optimization */
9663 #define SQLITE_FUNC_CASE 0x02 /* Case-sensitive LIKE-type function */
9664 #define SQLITE_FUNC_EPHEM 0x04 /* Ephemeral. Delete with VDBE */
9665 #define SQLITE_FUNC_NEEDCOLL 0x08 /* sqlite3GetFuncCollSeq() might be called */
9666 #define SQLITE_FUNC_PRIVATE 0x10 /* Allowed for internal use only */
9667 #define SQLITE_FUNC_COUNT 0x20 /* Built-in count(*) aggregate */
9668 #define SQLITE_FUNC_COALESCE 0x40 /* Built-in coalesce() or ifnull() function */
9671 ** The following three macros, FUNCTION(), LIKEFUNC() and AGGREGATE() are
9672 ** used to create the initializers for the FuncDef structures.
9674 ** FUNCTION(zName, nArg, iArg, bNC, xFunc)
9675 ** Used to create a scalar function definition of a function zName
9676 ** implemented by C function xFunc that accepts nArg arguments. The
9677 ** value passed as iArg is cast to a (void*) and made available
9678 ** as the user-data (sqlite3_user_data()) for the function. If
9679 ** argument bNC is true, then the SQLITE_FUNC_NEEDCOLL flag is set.
9681 ** AGGREGATE(zName, nArg, iArg, bNC, xStep, xFinal)
9682 ** Used to create an aggregate function definition implemented by
9683 ** the C functions xStep and xFinal. The first four parameters
9684 ** are interpreted in the same way as the first 4 parameters to
9685 ** FUNCTION().
9687 ** LIKEFUNC(zName, nArg, pArg, flags)
9688 ** Used to create a scalar function definition of a function zName
9689 ** that accepts nArg arguments and is implemented by a call to C
9690 ** function likeFunc. Argument pArg is cast to a (void *) and made
9691 ** available as the function user-data (sqlite3_user_data()). The
9692 ** FuncDef.flags variable is set to the value passed as the flags
9693 ** parameter.
9695 #define FUNCTION(zName, nArg, iArg, bNC, xFunc) \
9696 {nArg, SQLITE_UTF8, bNC*SQLITE_FUNC_NEEDCOLL, \
9697 SQLITE_INT_TO_PTR(iArg), 0, xFunc, 0, 0, #zName, 0, 0}
9698 #define STR_FUNCTION(zName, nArg, pArg, bNC, xFunc) \
9699 {nArg, SQLITE_UTF8, bNC*SQLITE_FUNC_NEEDCOLL, \
9700 pArg, 0, xFunc, 0, 0, #zName, 0, 0}
9701 #define LIKEFUNC(zName, nArg, arg, flags) \
9702 {nArg, SQLITE_UTF8, flags, (void *)arg, 0, likeFunc, 0, 0, #zName, 0, 0}
9703 #define AGGREGATE(zName, nArg, arg, nc, xStep, xFinal) \
9704 {nArg, SQLITE_UTF8, nc*SQLITE_FUNC_NEEDCOLL, \
9705 SQLITE_INT_TO_PTR(arg), 0, 0, xStep,xFinal,#zName,0,0}
9708 ** All current savepoints are stored in a linked list starting at
9709 ** sqlite3.pSavepoint. The first element in the list is the most recently
9710 ** opened savepoint. Savepoints are added to the list by the vdbe
9711 ** OP_Savepoint instruction.
9713 struct Savepoint {
9714 char *zName; /* Savepoint name (nul-terminated) */
9715 i64 nDeferredCons; /* Number of deferred fk violations */
9716 Savepoint *pNext; /* Parent savepoint (if any) */
9720 ** The following are used as the second parameter to sqlite3Savepoint(),
9721 ** and as the P1 argument to the OP_Savepoint instruction.
9723 #define SAVEPOINT_BEGIN 0
9724 #define SAVEPOINT_RELEASE 1
9725 #define SAVEPOINT_ROLLBACK 2
9729 ** Each SQLite module (virtual table definition) is defined by an
9730 ** instance of the following structure, stored in the sqlite3.aModule
9731 ** hash table.
9733 struct Module {
9734 const sqlite3_module *pModule; /* Callback pointers */
9735 const char *zName; /* Name passed to create_module() */
9736 void *pAux; /* pAux passed to create_module() */
9737 void (*xDestroy)(void *); /* Module destructor function */
9741 ** information about each column of an SQL table is held in an instance
9742 ** of this structure.
9744 struct Column {
9745 char *zName; /* Name of this column */
9746 Expr *pDflt; /* Default value of this column */
9747 char *zDflt; /* Original text of the default value */
9748 char *zType; /* Data type for this column */
9749 char *zColl; /* Collating sequence. If NULL, use the default */
9750 u8 notNull; /* True if there is a NOT NULL constraint */
9751 u8 isPrimKey; /* True if this column is part of the PRIMARY KEY */
9752 char affinity; /* One of the SQLITE_AFF_... values */
9753 #ifndef SQLITE_OMIT_VIRTUALTABLE
9754 u8 isHidden; /* True if this column is 'hidden' */
9755 #endif
9759 ** A "Collating Sequence" is defined by an instance of the following
9760 ** structure. Conceptually, a collating sequence consists of a name and
9761 ** a comparison routine that defines the order of that sequence.
9763 ** There may two separate implementations of the collation function, one
9764 ** that processes text in UTF-8 encoding (CollSeq.xCmp) and another that
9765 ** processes text encoded in UTF-16 (CollSeq.xCmp16), using the machine
9766 ** native byte order. When a collation sequence is invoked, SQLite selects
9767 ** the version that will require the least expensive encoding
9768 ** translations, if any.
9770 ** The CollSeq.pUser member variable is an extra parameter that passed in
9771 ** as the first argument to the UTF-8 comparison function, xCmp.
9772 ** CollSeq.pUser16 is the equivalent for the UTF-16 comparison function,
9773 ** xCmp16.
9775 ** If both CollSeq.xCmp and CollSeq.xCmp16 are NULL, it means that the
9776 ** collating sequence is undefined. Indices built on an undefined
9777 ** collating sequence may not be read or written.
9779 struct CollSeq {
9780 char *zName; /* Name of the collating sequence, UTF-8 encoded */
9781 u8 enc; /* Text encoding handled by xCmp() */
9782 u8 type; /* One of the SQLITE_COLL_... values below */
9783 void *pUser; /* First argument to xCmp() */
9784 int (*xCmp)(void*,int, const void*, int, const void*);
9785 void (*xDel)(void*); /* Destructor for pUser */
9789 ** Allowed values of CollSeq.type:
9791 #define SQLITE_COLL_BINARY 1 /* The default memcmp() collating sequence */
9792 #define SQLITE_COLL_NOCASE 2 /* The built-in NOCASE collating sequence */
9793 #define SQLITE_COLL_REVERSE 3 /* The built-in REVERSE collating sequence */
9794 #define SQLITE_COLL_USER 0 /* Any other user-defined collating sequence */
9797 ** A sort order can be either ASC or DESC.
9799 #define SQLITE_SO_ASC 0 /* Sort in ascending order */
9800 #define SQLITE_SO_DESC 1 /* Sort in ascending order */
9803 ** Column affinity types.
9805 ** These used to have mnemonic name like 'i' for SQLITE_AFF_INTEGER and
9806 ** 't' for SQLITE_AFF_TEXT. But we can save a little space and improve
9807 ** the speed a little by numbering the values consecutively.
9809 ** But rather than start with 0 or 1, we begin with 'a'. That way,
9810 ** when multiple affinity types are concatenated into a string and
9811 ** used as the P4 operand, they will be more readable.
9813 ** Note also that the numeric types are grouped together so that testing
9814 ** for a numeric type is a single comparison.
9816 #define SQLITE_AFF_TEXT 'a'
9817 #define SQLITE_AFF_NONE 'b'
9818 #define SQLITE_AFF_NUMERIC 'c'
9819 #define SQLITE_AFF_INTEGER 'd'
9820 #define SQLITE_AFF_REAL 'e'
9822 #define sqlite3IsNumericAffinity(X) ((X)>=SQLITE_AFF_NUMERIC)
9825 ** The SQLITE_AFF_MASK values masks off the significant bits of an
9826 ** affinity value.
9828 #define SQLITE_AFF_MASK 0x67
9831 ** Additional bit values that can be ORed with an affinity without
9832 ** changing the affinity.
9834 #define SQLITE_JUMPIFNULL 0x08 /* jumps if either operand is NULL */
9835 #define SQLITE_STOREP2 0x10 /* Store result in reg[P2] rather than jump */
9836 #define SQLITE_NULLEQ 0x80 /* NULL=NULL */
9839 ** An object of this type is created for each virtual table present in
9840 ** the database schema.
9842 ** If the database schema is shared, then there is one instance of this
9843 ** structure for each database connection (sqlite3*) that uses the shared
9844 ** schema. This is because each database connection requires its own unique
9845 ** instance of the sqlite3_vtab* handle used to access the virtual table
9846 ** implementation. sqlite3_vtab* handles can not be shared between
9847 ** database connections, even when the rest of the in-memory database
9848 ** schema is shared, as the implementation often stores the database
9849 ** connection handle passed to it via the xConnect() or xCreate() method
9850 ** during initialization internally. This database connection handle may
9851 ** then be used by the virtual table implementation to access real tables
9852 ** within the database. So that they appear as part of the callers
9853 ** transaction, these accesses need to be made via the same database
9854 ** connection as that used to execute SQL operations on the virtual table.
9856 ** All VTable objects that correspond to a single table in a shared
9857 ** database schema are initially stored in a linked-list pointed to by
9858 ** the Table.pVTable member variable of the corresponding Table object.
9859 ** When an sqlite3_prepare() operation is required to access the virtual
9860 ** table, it searches the list for the VTable that corresponds to the
9861 ** database connection doing the preparing so as to use the correct
9862 ** sqlite3_vtab* handle in the compiled query.
9864 ** When an in-memory Table object is deleted (for example when the
9865 ** schema is being reloaded for some reason), the VTable objects are not
9866 ** deleted and the sqlite3_vtab* handles are not xDisconnect()ed
9867 ** immediately. Instead, they are moved from the Table.pVTable list to
9868 ** another linked list headed by the sqlite3.pDisconnect member of the
9869 ** corresponding sqlite3 structure. They are then deleted/xDisconnected
9870 ** next time a statement is prepared using said sqlite3*. This is done
9871 ** to avoid deadlock issues involving multiple sqlite3.mutex mutexes.
9872 ** Refer to comments above function sqlite3VtabUnlockList() for an
9873 ** explanation as to why it is safe to add an entry to an sqlite3.pDisconnect
9874 ** list without holding the corresponding sqlite3.mutex mutex.
9876 ** The memory for objects of this type is always allocated by
9877 ** sqlite3DbMalloc(), using the connection handle stored in VTable.db as
9878 ** the first argument.
9880 struct VTable {
9881 sqlite3 *db; /* Database connection associated with this table */
9882 Module *pMod; /* Pointer to module implementation */
9883 sqlite3_vtab *pVtab; /* Pointer to vtab instance */
9884 int nRef; /* Number of pointers to this structure */
9885 u8 bConstraint; /* True if constraints are supported */
9886 int iSavepoint; /* Depth of the SAVEPOINT stack */
9887 VTable *pNext; /* Next in linked list (see above) */
9891 ** Each SQL table is represented in memory by an instance of the
9892 ** following structure.
9894 ** Table.zName is the name of the table. The case of the original
9895 ** CREATE TABLE statement is stored, but case is not significant for
9896 ** comparisons.
9898 ** Table.nCol is the number of columns in this table. Table.aCol is a
9899 ** pointer to an array of Column structures, one for each column.
9901 ** If the table has an INTEGER PRIMARY KEY, then Table.iPKey is the index of
9902 ** the column that is that key. Otherwise Table.iPKey is negative. Note
9903 ** that the datatype of the PRIMARY KEY must be INTEGER for this field to
9904 ** be set. An INTEGER PRIMARY KEY is used as the rowid for each row of
9905 ** the table. If a table has no INTEGER PRIMARY KEY, then a random rowid
9906 ** is generated for each row of the table. TF_HasPrimaryKey is set if
9907 ** the table has any PRIMARY KEY, INTEGER or otherwise.
9909 ** Table.tnum is the page number for the root BTree page of the table in the
9910 ** database file. If Table.iDb is the index of the database table backend
9911 ** in sqlite.aDb[]. 0 is for the main database and 1 is for the file that
9912 ** holds temporary tables and indices. If TF_Ephemeral is set
9913 ** then the table is stored in a file that is automatically deleted
9914 ** when the VDBE cursor to the table is closed. In this case Table.tnum
9915 ** refers VDBE cursor number that holds the table open, not to the root
9916 ** page number. Transient tables are used to hold the results of a
9917 ** sub-query that appears instead of a real table name in the FROM clause
9918 ** of a SELECT statement.
9920 struct Table {
9921 char *zName; /* Name of the table or view */
9922 int iPKey; /* If not negative, use aCol[iPKey] as the primary key */
9923 int nCol; /* Number of columns in this table */
9924 Column *aCol; /* Information about each column */
9925 Index *pIndex; /* List of SQL indexes on this table. */
9926 int tnum; /* Root BTree node for this table (see note above) */
9927 unsigned nRowEst; /* Estimated rows in table - from sqlite_stat1 table */
9928 Select *pSelect; /* NULL for tables. Points to definition if a view. */
9929 u16 nRef; /* Number of pointers to this Table */
9930 u8 tabFlags; /* Mask of TF_* values */
9931 u8 keyConf; /* What to do in case of uniqueness conflict on iPKey */
9932 FKey *pFKey; /* Linked list of all foreign keys in this table */
9933 char *zColAff; /* String defining the affinity of each column */
9934 #ifndef SQLITE_OMIT_CHECK
9935 Expr *pCheck; /* The AND of all CHECK constraints */
9936 #endif
9937 #ifndef SQLITE_OMIT_ALTERTABLE
9938 int addColOffset; /* Offset in CREATE TABLE stmt to add a new column */
9939 #endif
9940 #ifndef SQLITE_OMIT_VIRTUALTABLE
9941 VTable *pVTable; /* List of VTable objects. */
9942 int nModuleArg; /* Number of arguments to the module */
9943 char **azModuleArg; /* Text of all module args. [0] is module name */
9944 #endif
9945 Trigger *pTrigger; /* List of triggers stored in pSchema */
9946 Schema *pSchema; /* Schema that contains this table */
9947 Table *pNextZombie; /* Next on the Parse.pZombieTab list */
9951 ** Allowed values for Tabe.tabFlags.
9953 #define TF_Readonly 0x01 /* Read-only system table */
9954 #define TF_Ephemeral 0x02 /* An ephemeral table */
9955 #define TF_HasPrimaryKey 0x04 /* Table has a primary key */
9956 #define TF_Autoincrement 0x08 /* Integer primary key is autoincrement */
9957 #define TF_Virtual 0x10 /* Is a virtual table */
9958 #define TF_NeedMetadata 0x20 /* aCol[].zType and aCol[].pColl missing */
9963 ** Test to see whether or not a table is a virtual table. This is
9964 ** done as a macro so that it will be optimized out when virtual
9965 ** table support is omitted from the build.
9967 #ifndef SQLITE_OMIT_VIRTUALTABLE
9968 # define IsVirtual(X) (((X)->tabFlags & TF_Virtual)!=0)
9969 # define IsHiddenColumn(X) ((X)->isHidden)
9970 #else
9971 # define IsVirtual(X) 0
9972 # define IsHiddenColumn(X) 0
9973 #endif
9976 ** Each foreign key constraint is an instance of the following structure.
9978 ** A foreign key is associated with two tables. The "from" table is
9979 ** the table that contains the REFERENCES clause that creates the foreign
9980 ** key. The "to" table is the table that is named in the REFERENCES clause.
9981 ** Consider this example:
9983 ** CREATE TABLE ex1(
9984 ** a INTEGER PRIMARY KEY,
9985 ** b INTEGER CONSTRAINT fk1 REFERENCES ex2(x)
9986 ** );
9988 ** For foreign key "fk1", the from-table is "ex1" and the to-table is "ex2".
9990 ** Each REFERENCES clause generates an instance of the following structure
9991 ** which is attached to the from-table. The to-table need not exist when
9992 ** the from-table is created. The existence of the to-table is not checked.
9994 struct FKey {
9995 Table *pFrom; /* Table containing the REFERENCES clause (aka: Child) */
9996 FKey *pNextFrom; /* Next foreign key in pFrom */
9997 char *zTo; /* Name of table that the key points to (aka: Parent) */
9998 FKey *pNextTo; /* Next foreign key on table named zTo */
9999 FKey *pPrevTo; /* Previous foreign key on table named zTo */
10000 int nCol; /* Number of columns in this key */
10001 /* EV: R-30323-21917 */
10002 u8 isDeferred; /* True if constraint checking is deferred till COMMIT */
10003 u8 aAction[2]; /* ON DELETE and ON UPDATE actions, respectively */
10004 Trigger *apTrigger[2]; /* Triggers for aAction[] actions */
10005 struct sColMap { /* Mapping of columns in pFrom to columns in zTo */
10006 int iFrom; /* Index of column in pFrom */
10007 char *zCol; /* Name of column in zTo. If 0 use PRIMARY KEY */
10008 } aCol[1]; /* One entry for each of nCol column s */
10012 ** SQLite supports many different ways to resolve a constraint
10013 ** error. ROLLBACK processing means that a constraint violation
10014 ** causes the operation in process to fail and for the current transaction
10015 ** to be rolled back. ABORT processing means the operation in process
10016 ** fails and any prior changes from that one operation are backed out,
10017 ** but the transaction is not rolled back. FAIL processing means that
10018 ** the operation in progress stops and returns an error code. But prior
10019 ** changes due to the same operation are not backed out and no rollback
10020 ** occurs. IGNORE means that the particular row that caused the constraint
10021 ** error is not inserted or updated. Processing continues and no error
10022 ** is returned. REPLACE means that preexisting database rows that caused
10023 ** a UNIQUE constraint violation are removed so that the new insert or
10024 ** update can proceed. Processing continues and no error is reported.
10026 ** RESTRICT, SETNULL, and CASCADE actions apply only to foreign keys.
10027 ** RESTRICT is the same as ABORT for IMMEDIATE foreign keys and the
10028 ** same as ROLLBACK for DEFERRED keys. SETNULL means that the foreign
10029 ** key is set to NULL. CASCADE means that a DELETE or UPDATE of the
10030 ** referenced table row is propagated into the row that holds the
10031 ** foreign key.
10033 ** The following symbolic values are used to record which type
10034 ** of action to take.
10036 #define OE_None 0 /* There is no constraint to check */
10037 #define OE_Rollback 1 /* Fail the operation and rollback the transaction */
10038 #define OE_Abort 2 /* Back out changes but do no rollback transaction */
10039 #define OE_Fail 3 /* Stop the operation but leave all prior changes */
10040 #define OE_Ignore 4 /* Ignore the error. Do not do the INSERT or UPDATE */
10041 #define OE_Replace 5 /* Delete existing record, then do INSERT or UPDATE */
10043 #define OE_Restrict 6 /* OE_Abort for IMMEDIATE, OE_Rollback for DEFERRED */
10044 #define OE_SetNull 7 /* Set the foreign key value to NULL */
10045 #define OE_SetDflt 8 /* Set the foreign key value to its default */
10046 #define OE_Cascade 9 /* Cascade the changes */
10048 #define OE_Default 99 /* Do whatever the default action is */
10052 ** An instance of the following structure is passed as the first
10053 ** argument to sqlite3VdbeKeyCompare and is used to control the
10054 ** comparison of the two index keys.
10056 struct KeyInfo {
10057 sqlite3 *db; /* The database connection */
10058 u8 enc; /* Text encoding - one of the SQLITE_UTF* values */
10059 u16 nField; /* Number of entries in aColl[] */
10060 u8 *aSortOrder; /* Sort order for each column. May be NULL */
10061 CollSeq *aColl[1]; /* Collating sequence for each term of the key */
10065 ** An instance of the following structure holds information about a
10066 ** single index record that has already been parsed out into individual
10067 ** values.
10069 ** A record is an object that contains one or more fields of data.
10070 ** Records are used to store the content of a table row and to store
10071 ** the key of an index. A blob encoding of a record is created by
10072 ** the OP_MakeRecord opcode of the VDBE and is disassembled by the
10073 ** OP_Column opcode.
10075 ** This structure holds a record that has already been disassembled
10076 ** into its constituent fields.
10078 struct UnpackedRecord {
10079 KeyInfo *pKeyInfo; /* Collation and sort-order information */
10080 u16 nField; /* Number of entries in apMem[] */
10081 u16 flags; /* Boolean settings. UNPACKED_... below */
10082 i64 rowid; /* Used by UNPACKED_PREFIX_SEARCH */
10083 Mem *aMem; /* Values */
10087 ** Allowed values of UnpackedRecord.flags
10089 #define UNPACKED_NEED_FREE 0x0001 /* Memory is from sqlite3Malloc() */
10090 #define UNPACKED_NEED_DESTROY 0x0002 /* apMem[]s should all be destroyed */
10091 #define UNPACKED_IGNORE_ROWID 0x0004 /* Ignore trailing rowid on key1 */
10092 #define UNPACKED_INCRKEY 0x0008 /* Make this key an epsilon larger */
10093 #define UNPACKED_PREFIX_MATCH 0x0010 /* A prefix match is considered OK */
10094 #define UNPACKED_PREFIX_SEARCH 0x0020 /* A prefix match is considered OK */
10097 ** Each SQL index is represented in memory by an
10098 ** instance of the following structure.
10100 ** The columns of the table that are to be indexed are described
10101 ** by the aiColumn[] field of this structure. For example, suppose
10102 ** we have the following table and index:
10104 ** CREATE TABLE Ex1(c1 int, c2 int, c3 text);
10105 ** CREATE INDEX Ex2 ON Ex1(c3,c1);
10107 ** In the Table structure describing Ex1, nCol==3 because there are
10108 ** three columns in the table. In the Index structure describing
10109 ** Ex2, nColumn==2 since 2 of the 3 columns of Ex1 are indexed.
10110 ** The value of aiColumn is {2, 0}. aiColumn[0]==2 because the
10111 ** first column to be indexed (c3) has an index of 2 in Ex1.aCol[].
10112 ** The second column to be indexed (c1) has an index of 0 in
10113 ** Ex1.aCol[], hence Ex2.aiColumn[1]==0.
10115 ** The Index.onError field determines whether or not the indexed columns
10116 ** must be unique and what to do if they are not. When Index.onError=OE_None,
10117 ** it means this is not a unique index. Otherwise it is a unique index
10118 ** and the value of Index.onError indicate the which conflict resolution
10119 ** algorithm to employ whenever an attempt is made to insert a non-unique
10120 ** element.
10122 struct Index {
10123 char *zName; /* Name of this index */
10124 int nColumn; /* Number of columns in the table used by this index */
10125 int *aiColumn; /* Which columns are used by this index. 1st is 0 */
10126 unsigned *aiRowEst; /* Result of ANALYZE: Est. rows selected by each column */
10127 Table *pTable; /* The SQL table being indexed */
10128 int tnum; /* Page containing root of this index in database file */
10129 u8 onError; /* OE_Abort, OE_Ignore, OE_Replace, or OE_None */
10130 u8 autoIndex; /* True if is automatically created (ex: by UNIQUE) */
10131 u8 bUnordered; /* Use this index for == or IN queries only */
10132 char *zColAff; /* String defining the affinity of each column */
10133 Index *pNext; /* The next index associated with the same table */
10134 Schema *pSchema; /* Schema containing this index */
10135 u8 *aSortOrder; /* Array of size Index.nColumn. True==DESC, False==ASC */
10136 char **azColl; /* Array of collation sequence names for index */
10137 IndexSample *aSample; /* Array of SQLITE_INDEX_SAMPLES samples */
10141 ** Each sample stored in the sqlite_stat2 table is represented in memory
10142 ** using a structure of this type.
10144 struct IndexSample {
10145 union {
10146 char *z; /* Value if eType is SQLITE_TEXT or SQLITE_BLOB */
10147 double r; /* Value if eType is SQLITE_FLOAT or SQLITE_INTEGER */
10148 } u;
10149 u8 eType; /* SQLITE_NULL, SQLITE_INTEGER ... etc. */
10150 u8 nByte; /* Size in byte of text or blob. */
10154 ** Each token coming out of the lexer is an instance of
10155 ** this structure. Tokens are also used as part of an expression.
10157 ** Note if Token.z==0 then Token.dyn and Token.n are undefined and
10158 ** may contain random values. Do not make any assumptions about Token.dyn
10159 ** and Token.n when Token.z==0.
10161 struct Token {
10162 const char *z; /* Text of the token. Not NULL-terminated! */
10163 unsigned int n; /* Number of characters in this token */
10167 ** An instance of this structure contains information needed to generate
10168 ** code for a SELECT that contains aggregate functions.
10170 ** If Expr.op==TK_AGG_COLUMN or TK_AGG_FUNCTION then Expr.pAggInfo is a
10171 ** pointer to this structure. The Expr.iColumn field is the index in
10172 ** AggInfo.aCol[] or AggInfo.aFunc[] of information needed to generate
10173 ** code for that node.
10175 ** AggInfo.pGroupBy and AggInfo.aFunc.pExpr point to fields within the
10176 ** original Select structure that describes the SELECT statement. These
10177 ** fields do not need to be freed when deallocating the AggInfo structure.
10179 struct AggInfo {
10180 u8 directMode; /* Direct rendering mode means take data directly
10181 ** from source tables rather than from accumulators */
10182 u8 useSortingIdx; /* In direct mode, reference the sorting index rather
10183 ** than the source table */
10184 int sortingIdx; /* Cursor number of the sorting index */
10185 int sortingIdxPTab; /* Cursor number of pseudo-table */
10186 ExprList *pGroupBy; /* The group by clause */
10187 int nSortingColumn; /* Number of columns in the sorting index */
10188 struct AggInfo_col { /* For each column used in source tables */
10189 Table *pTab; /* Source table */
10190 int iTable; /* Cursor number of the source table */
10191 int iColumn; /* Column number within the source table */
10192 int iSorterColumn; /* Column number in the sorting index */
10193 int iMem; /* Memory location that acts as accumulator */
10194 Expr *pExpr; /* The original expression */
10195 } *aCol;
10196 int nColumn; /* Number of used entries in aCol[] */
10197 int nColumnAlloc; /* Number of slots allocated for aCol[] */
10198 int nAccumulator; /* Number of columns that show through to the output.
10199 ** Additional columns are used only as parameters to
10200 ** aggregate functions */
10201 struct AggInfo_func { /* For each aggregate function */
10202 Expr *pExpr; /* Expression encoding the function */
10203 FuncDef *pFunc; /* The aggregate function implementation */
10204 int iMem; /* Memory location that acts as accumulator */
10205 int iDistinct; /* Ephemeral table used to enforce DISTINCT */
10206 } *aFunc;
10207 int nFunc; /* Number of entries in aFunc[] */
10208 int nFuncAlloc; /* Number of slots allocated for aFunc[] */
10212 ** The datatype ynVar is a signed integer, either 16-bit or 32-bit.
10213 ** Usually it is 16-bits. But if SQLITE_MAX_VARIABLE_NUMBER is greater
10214 ** than 32767 we have to make it 32-bit. 16-bit is preferred because
10215 ** it uses less memory in the Expr object, which is a big memory user
10216 ** in systems with lots of prepared statements. And few applications
10217 ** need more than about 10 or 20 variables. But some extreme users want
10218 ** to have prepared statements with over 32767 variables, and for them
10219 ** the option is available (at compile-time).
10221 #if SQLITE_MAX_VARIABLE_NUMBER<=32767
10222 typedef i16 ynVar;
10223 #else
10224 typedef int ynVar;
10225 #endif
10228 ** Each node of an expression in the parse tree is an instance
10229 ** of this structure.
10231 ** Expr.op is the opcode. The integer parser token codes are reused
10232 ** as opcodes here. For example, the parser defines TK_GE to be an integer
10233 ** code representing the ">=" operator. This same integer code is reused
10234 ** to represent the greater-than-or-equal-to operator in the expression
10235 ** tree.
10237 ** If the expression is an SQL literal (TK_INTEGER, TK_FLOAT, TK_BLOB,
10238 ** or TK_STRING), then Expr.token contains the text of the SQL literal. If
10239 ** the expression is a variable (TK_VARIABLE), then Expr.token contains the
10240 ** variable name. Finally, if the expression is an SQL function (TK_FUNCTION),
10241 ** then Expr.token contains the name of the function.
10243 ** Expr.pRight and Expr.pLeft are the left and right subexpressions of a
10244 ** binary operator. Either or both may be NULL.
10246 ** Expr.x.pList is a list of arguments if the expression is an SQL function,
10247 ** a CASE expression or an IN expression of the form "<lhs> IN (<y>, <z>...)".
10248 ** Expr.x.pSelect is used if the expression is a sub-select or an expression of
10249 ** the form "<lhs> IN (SELECT ...)". If the EP_xIsSelect bit is set in the
10250 ** Expr.flags mask, then Expr.x.pSelect is valid. Otherwise, Expr.x.pList is
10251 ** valid.
10253 ** An expression of the form ID or ID.ID refers to a column in a table.
10254 ** For such expressions, Expr.op is set to TK_COLUMN and Expr.iTable is
10255 ** the integer cursor number of a VDBE cursor pointing to that table and
10256 ** Expr.iColumn is the column number for the specific column. If the
10257 ** expression is used as a result in an aggregate SELECT, then the
10258 ** value is also stored in the Expr.iAgg column in the aggregate so that
10259 ** it can be accessed after all aggregates are computed.
10261 ** If the expression is an unbound variable marker (a question mark
10262 ** character '?' in the original SQL) then the Expr.iTable holds the index
10263 ** number for that variable.
10265 ** If the expression is a subquery then Expr.iColumn holds an integer
10266 ** register number containing the result of the subquery. If the
10267 ** subquery gives a constant result, then iTable is -1. If the subquery
10268 ** gives a different answer at different times during statement processing
10269 ** then iTable is the address of a subroutine that computes the subquery.
10271 ** If the Expr is of type OP_Column, and the table it is selecting from
10272 ** is a disk table or the "old.*" pseudo-table, then pTab points to the
10273 ** corresponding table definition.
10275 ** ALLOCATION NOTES:
10277 ** Expr objects can use a lot of memory space in database schema. To
10278 ** help reduce memory requirements, sometimes an Expr object will be
10279 ** truncated. And to reduce the number of memory allocations, sometimes
10280 ** two or more Expr objects will be stored in a single memory allocation,
10281 ** together with Expr.zToken strings.
10283 ** If the EP_Reduced and EP_TokenOnly flags are set when
10284 ** an Expr object is truncated. When EP_Reduced is set, then all
10285 ** the child Expr objects in the Expr.pLeft and Expr.pRight subtrees
10286 ** are contained within the same memory allocation. Note, however, that
10287 ** the subtrees in Expr.x.pList or Expr.x.pSelect are always separately
10288 ** allocated, regardless of whether or not EP_Reduced is set.
10290 struct Expr {
10291 u8 op; /* Operation performed by this node */
10292 char affinity; /* The affinity of the column or 0 if not a column */
10293 u16 flags; /* Various flags. EP_* See below */
10294 union {
10295 char *zToken; /* Token value. Zero terminated and dequoted */
10296 int iValue; /* Non-negative integer value if EP_IntValue */
10297 } u;
10299 /* If the EP_TokenOnly flag is set in the Expr.flags mask, then no
10300 ** space is allocated for the fields below this point. An attempt to
10301 ** access them will result in a segfault or malfunction.
10302 *********************************************************************/
10304 Expr *pLeft; /* Left subnode */
10305 Expr *pRight; /* Right subnode */
10306 union {
10307 ExprList *pList; /* Function arguments or in "<expr> IN (<expr-list)" */
10308 Select *pSelect; /* Used for sub-selects and "<expr> IN (<select>)" */
10309 } x;
10310 CollSeq *pColl; /* The collation type of the column or 0 */
10312 /* If the EP_Reduced flag is set in the Expr.flags mask, then no
10313 ** space is allocated for the fields below this point. An attempt to
10314 ** access them will result in a segfault or malfunction.
10315 *********************************************************************/
10317 int iTable; /* TK_COLUMN: cursor number of table holding column
10318 ** TK_REGISTER: register number
10319 ** TK_TRIGGER: 1 -> new, 0 -> old */
10320 ynVar iColumn; /* TK_COLUMN: column index. -1 for rowid.
10321 ** TK_VARIABLE: variable number (always >= 1). */
10322 i16 iAgg; /* Which entry in pAggInfo->aCol[] or ->aFunc[] */
10323 i16 iRightJoinTable; /* If EP_FromJoin, the right table of the join */
10324 u8 flags2; /* Second set of flags. EP2_... */
10325 u8 op2; /* If a TK_REGISTER, the original value of Expr.op */
10326 AggInfo *pAggInfo; /* Used by TK_AGG_COLUMN and TK_AGG_FUNCTION */
10327 Table *pTab; /* Table for TK_COLUMN expressions. */
10328 #if SQLITE_MAX_EXPR_DEPTH>0
10329 int nHeight; /* Height of the tree headed by this node */
10330 #endif
10334 ** The following are the meanings of bits in the Expr.flags field.
10336 #define EP_FromJoin 0x0001 /* Originated in ON or USING clause of a join */
10337 #define EP_Agg 0x0002 /* Contains one or more aggregate functions */
10338 #define EP_Resolved 0x0004 /* IDs have been resolved to COLUMNs */
10339 #define EP_Error 0x0008 /* Expression contains one or more errors */
10340 #define EP_Distinct 0x0010 /* Aggregate function with DISTINCT keyword */
10341 #define EP_VarSelect 0x0020 /* pSelect is correlated, not constant */
10342 #define EP_DblQuoted 0x0040 /* token.z was originally in "..." */
10343 #define EP_InfixFunc 0x0080 /* True for an infix function: LIKE, GLOB, etc */
10344 #define EP_ExpCollate 0x0100 /* Collating sequence specified explicitly */
10345 #define EP_FixedDest 0x0200 /* Result needed in a specific register */
10346 #define EP_IntValue 0x0400 /* Integer value contained in u.iValue */
10347 #define EP_xIsSelect 0x0800 /* x.pSelect is valid (otherwise x.pList is) */
10349 #define EP_Reduced 0x1000 /* Expr struct is EXPR_REDUCEDSIZE bytes only */
10350 #define EP_TokenOnly 0x2000 /* Expr struct is EXPR_TOKENONLYSIZE bytes only */
10351 #define EP_Static 0x4000 /* Held in memory not obtained from malloc() */
10354 ** The following are the meanings of bits in the Expr.flags2 field.
10356 #define EP2_MallocedToken 0x0001 /* Need to sqlite3DbFree() Expr.zToken */
10357 #define EP2_Irreducible 0x0002 /* Cannot EXPRDUP_REDUCE this Expr */
10360 ** The pseudo-routine sqlite3ExprSetIrreducible sets the EP2_Irreducible
10361 ** flag on an expression structure. This flag is used for VV&A only. The
10362 ** routine is implemented as a macro that only works when in debugging mode,
10363 ** so as not to burden production code.
10365 #ifdef SQLITE_DEBUG
10366 # define ExprSetIrreducible(X) (X)->flags2 |= EP2_Irreducible
10367 #else
10368 # define ExprSetIrreducible(X)
10369 #endif
10372 ** These macros can be used to test, set, or clear bits in the
10373 ** Expr.flags field.
10375 #define ExprHasProperty(E,P) (((E)->flags&(P))==(P))
10376 #define ExprHasAnyProperty(E,P) (((E)->flags&(P))!=0)
10377 #define ExprSetProperty(E,P) (E)->flags|=(P)
10378 #define ExprClearProperty(E,P) (E)->flags&=~(P)
10381 ** Macros to determine the number of bytes required by a normal Expr
10382 ** struct, an Expr struct with the EP_Reduced flag set in Expr.flags
10383 ** and an Expr struct with the EP_TokenOnly flag set.
10385 #define EXPR_FULLSIZE sizeof(Expr) /* Full size */
10386 #define EXPR_REDUCEDSIZE offsetof(Expr,iTable) /* Common features */
10387 #define EXPR_TOKENONLYSIZE offsetof(Expr,pLeft) /* Fewer features */
10390 ** Flags passed to the sqlite3ExprDup() function. See the header comment
10391 ** above sqlite3ExprDup() for details.
10393 #define EXPRDUP_REDUCE 0x0001 /* Used reduced-size Expr nodes */
10396 ** A list of expressions. Each expression may optionally have a
10397 ** name. An expr/name combination can be used in several ways, such
10398 ** as the list of "expr AS ID" fields following a "SELECT" or in the
10399 ** list of "ID = expr" items in an UPDATE. A list of expressions can
10400 ** also be used as the argument to a function, in which case the a.zName
10401 ** field is not used.
10403 struct ExprList {
10404 int nExpr; /* Number of expressions on the list */
10405 int nAlloc; /* Number of entries allocated below */
10406 int iECursor; /* VDBE Cursor associated with this ExprList */
10407 struct ExprList_item {
10408 Expr *pExpr; /* The list of expressions */
10409 char *zName; /* Token associated with this expression */
10410 char *zSpan; /* Original text of the expression */
10411 u8 sortOrder; /* 1 for DESC or 0 for ASC */
10412 u8 done; /* A flag to indicate when processing is finished */
10413 u16 iCol; /* For ORDER BY, column number in result set */
10414 u16 iAlias; /* Index into Parse.aAlias[] for zName */
10415 } *a; /* One entry for each expression */
10419 ** An instance of this structure is used by the parser to record both
10420 ** the parse tree for an expression and the span of input text for an
10421 ** expression.
10423 struct ExprSpan {
10424 Expr *pExpr; /* The expression parse tree */
10425 const char *zStart; /* First character of input text */
10426 const char *zEnd; /* One character past the end of input text */
10430 ** An instance of this structure can hold a simple list of identifiers,
10431 ** such as the list "a,b,c" in the following statements:
10433 ** INSERT INTO t(a,b,c) VALUES ...;
10434 ** CREATE INDEX idx ON t(a,b,c);
10435 ** CREATE TRIGGER trig BEFORE UPDATE ON t(a,b,c) ...;
10437 ** The IdList.a.idx field is used when the IdList represents the list of
10438 ** column names after a table name in an INSERT statement. In the statement
10440 ** INSERT INTO t(a,b,c) ...
10442 ** If "a" is the k-th column of table "t", then IdList.a[0].idx==k.
10444 struct IdList {
10445 struct IdList_item {
10446 char *zName; /* Name of the identifier */
10447 int idx; /* Index in some Table.aCol[] of a column named zName */
10448 } *a;
10449 int nId; /* Number of identifiers on the list */
10450 int nAlloc; /* Number of entries allocated for a[] below */
10454 ** The bitmask datatype defined below is used for various optimizations.
10456 ** Changing this from a 64-bit to a 32-bit type limits the number of
10457 ** tables in a join to 32 instead of 64. But it also reduces the size
10458 ** of the library by 738 bytes on ix86.
10460 typedef u64 Bitmask;
10463 ** The number of bits in a Bitmask. "BMS" means "BitMask Size".
10465 #define BMS ((int)(sizeof(Bitmask)*8))
10468 ** The following structure describes the FROM clause of a SELECT statement.
10469 ** Each table or subquery in the FROM clause is a separate element of
10470 ** the SrcList.a[] array.
10472 ** With the addition of multiple database support, the following structure
10473 ** can also be used to describe a particular table such as the table that
10474 ** is modified by an INSERT, DELETE, or UPDATE statement. In standard SQL,
10475 ** such a table must be a simple name: ID. But in SQLite, the table can
10476 ** now be identified by a database name, a dot, then the table name: ID.ID.
10478 ** The jointype starts out showing the join type between the current table
10479 ** and the next table on the list. The parser builds the list this way.
10480 ** But sqlite3SrcListShiftJoinType() later shifts the jointypes so that each
10481 ** jointype expresses the join between the table and the previous table.
10483 ** In the colUsed field, the high-order bit (bit 63) is set if the table
10484 ** contains more than 63 columns and the 64-th or later column is used.
10486 struct SrcList {
10487 i16 nSrc; /* Number of tables or subqueries in the FROM clause */
10488 i16 nAlloc; /* Number of entries allocated in a[] below */
10489 struct SrcList_item {
10490 char *zDatabase; /* Name of database holding this table */
10491 char *zName; /* Name of the table */
10492 char *zAlias; /* The "B" part of a "A AS B" phrase. zName is the "A" */
10493 Table *pTab; /* An SQL table corresponding to zName */
10494 Select *pSelect; /* A SELECT statement used in place of a table name */
10495 int addrFillSub; /* Address of subroutine to manifest a subquery */
10496 int regReturn; /* Register holding return address of addrFillSub */
10497 u8 jointype; /* Type of join between this able and the previous */
10498 u8 notIndexed; /* True if there is a NOT INDEXED clause */
10499 u8 isCorrelated; /* True if sub-query is correlated */
10500 #ifndef SQLITE_OMIT_EXPLAIN
10501 u8 iSelectId; /* If pSelect!=0, the id of the sub-select in EQP */
10502 #endif
10503 int iCursor; /* The VDBE cursor number used to access this table */
10504 Expr *pOn; /* The ON clause of a join */
10505 IdList *pUsing; /* The USING clause of a join */
10506 Bitmask colUsed; /* Bit N (1<<N) set if column N of pTab is used */
10507 char *zIndex; /* Identifier from "INDEXED BY <zIndex>" clause */
10508 Index *pIndex; /* Index structure corresponding to zIndex, if any */
10509 } a[1]; /* One entry for each identifier on the list */
10513 ** Permitted values of the SrcList.a.jointype field
10515 #define JT_INNER 0x0001 /* Any kind of inner or cross join */
10516 #define JT_CROSS 0x0002 /* Explicit use of the CROSS keyword */
10517 #define JT_NATURAL 0x0004 /* True for a "natural" join */
10518 #define JT_LEFT 0x0008 /* Left outer join */
10519 #define JT_RIGHT 0x0010 /* Right outer join */
10520 #define JT_OUTER 0x0020 /* The "OUTER" keyword is present */
10521 #define JT_ERROR 0x0040 /* unknown or unsupported join type */
10525 ** A WherePlan object holds information that describes a lookup
10526 ** strategy.
10528 ** This object is intended to be opaque outside of the where.c module.
10529 ** It is included here only so that that compiler will know how big it
10530 ** is. None of the fields in this object should be used outside of
10531 ** the where.c module.
10533 ** Within the union, pIdx is only used when wsFlags&WHERE_INDEXED is true.
10534 ** pTerm is only used when wsFlags&WHERE_MULTI_OR is true. And pVtabIdx
10535 ** is only used when wsFlags&WHERE_VIRTUALTABLE is true. It is never the
10536 ** case that more than one of these conditions is true.
10538 struct WherePlan {
10539 u32 wsFlags; /* WHERE_* flags that describe the strategy */
10540 u32 nEq; /* Number of == constraints */
10541 double nRow; /* Estimated number of rows (for EQP) */
10542 union {
10543 Index *pIdx; /* Index when WHERE_INDEXED is true */
10544 struct WhereTerm *pTerm; /* WHERE clause term for OR-search */
10545 sqlite3_index_info *pVtabIdx; /* Virtual table index to use */
10546 } u;
10550 ** For each nested loop in a WHERE clause implementation, the WhereInfo
10551 ** structure contains a single instance of this structure. This structure
10552 ** is intended to be private the the where.c module and should not be
10553 ** access or modified by other modules.
10555 ** The pIdxInfo field is used to help pick the best index on a
10556 ** virtual table. The pIdxInfo pointer contains indexing
10557 ** information for the i-th table in the FROM clause before reordering.
10558 ** All the pIdxInfo pointers are freed by whereInfoFree() in where.c.
10559 ** All other information in the i-th WhereLevel object for the i-th table
10560 ** after FROM clause ordering.
10562 struct WhereLevel {
10563 WherePlan plan; /* query plan for this element of the FROM clause */
10564 int iLeftJoin; /* Memory cell used to implement LEFT OUTER JOIN */
10565 int iTabCur; /* The VDBE cursor used to access the table */
10566 int iIdxCur; /* The VDBE cursor used to access pIdx */
10567 int addrBrk; /* Jump here to break out of the loop */
10568 int addrNxt; /* Jump here to start the next IN combination */
10569 int addrCont; /* Jump here to continue with the next loop cycle */
10570 int addrFirst; /* First instruction of interior of the loop */
10571 u8 iFrom; /* Which entry in the FROM clause */
10572 u8 op, p5; /* Opcode and P5 of the opcode that ends the loop */
10573 int p1, p2; /* Operands of the opcode used to ends the loop */
10574 union { /* Information that depends on plan.wsFlags */
10575 struct {
10576 int nIn; /* Number of entries in aInLoop[] */
10577 struct InLoop {
10578 int iCur; /* The VDBE cursor used by this IN operator */
10579 int addrInTop; /* Top of the IN loop */
10580 } *aInLoop; /* Information about each nested IN operator */
10581 } in; /* Used when plan.wsFlags&WHERE_IN_ABLE */
10582 } u;
10584 /* The following field is really not part of the current level. But
10585 ** we need a place to cache virtual table index information for each
10586 ** virtual table in the FROM clause and the WhereLevel structure is
10587 ** a convenient place since there is one WhereLevel for each FROM clause
10588 ** element.
10590 sqlite3_index_info *pIdxInfo; /* Index info for n-th source table */
10594 ** Flags appropriate for the wctrlFlags parameter of sqlite3WhereBegin()
10595 ** and the WhereInfo.wctrlFlags member.
10597 #define WHERE_ORDERBY_NORMAL 0x0000 /* No-op */
10598 #define WHERE_ORDERBY_MIN 0x0001 /* ORDER BY processing for min() func */
10599 #define WHERE_ORDERBY_MAX 0x0002 /* ORDER BY processing for max() func */
10600 #define WHERE_ONEPASS_DESIRED 0x0004 /* Want to do one-pass UPDATE/DELETE */
10601 #define WHERE_DUPLICATES_OK 0x0008 /* Ok to return a row more than once */
10602 #define WHERE_OMIT_OPEN 0x0010 /* Table cursors are already open */
10603 #define WHERE_OMIT_CLOSE 0x0020 /* Omit close of table & index cursors */
10604 #define WHERE_FORCE_TABLE 0x0040 /* Do not use an index-only search */
10605 #define WHERE_ONETABLE_ONLY 0x0080 /* Only code the 1st table in pTabList */
10608 ** The WHERE clause processing routine has two halves. The
10609 ** first part does the start of the WHERE loop and the second
10610 ** half does the tail of the WHERE loop. An instance of
10611 ** this structure is returned by the first half and passed
10612 ** into the second half to give some continuity.
10614 struct WhereInfo {
10615 Parse *pParse; /* Parsing and code generating context */
10616 u16 wctrlFlags; /* Flags originally passed to sqlite3WhereBegin() */
10617 u8 okOnePass; /* Ok to use one-pass algorithm for UPDATE or DELETE */
10618 u8 untestedTerms; /* Not all WHERE terms resolved by outer loop */
10619 u8 eDistinct;
10620 SrcList *pTabList; /* List of tables in the join */
10621 int iTop; /* The very beginning of the WHERE loop */
10622 int iContinue; /* Jump here to continue with next record */
10623 int iBreak; /* Jump here to break out of the loop */
10624 int nLevel; /* Number of nested loop */
10625 struct WhereClause *pWC; /* Decomposition of the WHERE clause */
10626 double savedNQueryLoop; /* pParse->nQueryLoop outside the WHERE loop */
10627 double nRowOut; /* Estimated number of output rows */
10628 WhereLevel a[1]; /* Information about each nest loop in WHERE */
10631 #define WHERE_DISTINCT_UNIQUE 1
10632 #define WHERE_DISTINCT_ORDERED 2
10635 ** A NameContext defines a context in which to resolve table and column
10636 ** names. The context consists of a list of tables (the pSrcList) field and
10637 ** a list of named expression (pEList). The named expression list may
10638 ** be NULL. The pSrc corresponds to the FROM clause of a SELECT or
10639 ** to the table being operated on by INSERT, UPDATE, or DELETE. The
10640 ** pEList corresponds to the result set of a SELECT and is NULL for
10641 ** other statements.
10643 ** NameContexts can be nested. When resolving names, the inner-most
10644 ** context is searched first. If no match is found, the next outer
10645 ** context is checked. If there is still no match, the next context
10646 ** is checked. This process continues until either a match is found
10647 ** or all contexts are check. When a match is found, the nRef member of
10648 ** the context containing the match is incremented.
10650 ** Each subquery gets a new NameContext. The pNext field points to the
10651 ** NameContext in the parent query. Thus the process of scanning the
10652 ** NameContext list corresponds to searching through successively outer
10653 ** subqueries looking for a match.
10655 struct NameContext {
10656 Parse *pParse; /* The parser */
10657 SrcList *pSrcList; /* One or more tables used to resolve names */
10658 ExprList *pEList; /* Optional list of named expressions */
10659 int nRef; /* Number of names resolved by this context */
10660 int nErr; /* Number of errors encountered while resolving names */
10661 u8 allowAgg; /* Aggregate functions allowed here */
10662 u8 hasAgg; /* True if aggregates are seen */
10663 u8 isCheck; /* True if resolving names in a CHECK constraint */
10664 int nDepth; /* Depth of subquery recursion. 1 for no recursion */
10665 AggInfo *pAggInfo; /* Information about aggregates at this level */
10666 NameContext *pNext; /* Next outer name context. NULL for outermost */
10670 ** An instance of the following structure contains all information
10671 ** needed to generate code for a single SELECT statement.
10673 ** nLimit is set to -1 if there is no LIMIT clause. nOffset is set to 0.
10674 ** If there is a LIMIT clause, the parser sets nLimit to the value of the
10675 ** limit and nOffset to the value of the offset (or 0 if there is not
10676 ** offset). But later on, nLimit and nOffset become the memory locations
10677 ** in the VDBE that record the limit and offset counters.
10679 ** addrOpenEphm[] entries contain the address of OP_OpenEphemeral opcodes.
10680 ** These addresses must be stored so that we can go back and fill in
10681 ** the P4_KEYINFO and P2 parameters later. Neither the KeyInfo nor
10682 ** the number of columns in P2 can be computed at the same time
10683 ** as the OP_OpenEphm instruction is coded because not
10684 ** enough information about the compound query is known at that point.
10685 ** The KeyInfo for addrOpenTran[0] and [1] contains collating sequences
10686 ** for the result set. The KeyInfo for addrOpenTran[2] contains collating
10687 ** sequences for the ORDER BY clause.
10689 struct Select {
10690 ExprList *pEList; /* The fields of the result */
10691 u8 op; /* One of: TK_UNION TK_ALL TK_INTERSECT TK_EXCEPT */
10692 char affinity; /* MakeRecord with this affinity for SRT_Set */
10693 u16 selFlags; /* Various SF_* values */
10694 SrcList *pSrc; /* The FROM clause */
10695 Expr *pWhere; /* The WHERE clause */
10696 ExprList *pGroupBy; /* The GROUP BY clause */
10697 Expr *pHaving; /* The HAVING clause */
10698 ExprList *pOrderBy; /* The ORDER BY clause */
10699 Select *pPrior; /* Prior select in a compound select statement */
10700 Select *pNext; /* Next select to the left in a compound */
10701 Select *pRightmost; /* Right-most select in a compound select statement */
10702 Expr *pLimit; /* LIMIT expression. NULL means not used. */
10703 Expr *pOffset; /* OFFSET expression. NULL means not used. */
10704 int iLimit, iOffset; /* Memory registers holding LIMIT & OFFSET counters */
10705 int addrOpenEphm[3]; /* OP_OpenEphem opcodes related to this select */
10706 double nSelectRow; /* Estimated number of result rows */
10710 ** Allowed values for Select.selFlags. The "SF" prefix stands for
10711 ** "Select Flag".
10713 #define SF_Distinct 0x0001 /* Output should be DISTINCT */
10714 #define SF_Resolved 0x0002 /* Identifiers have been resolved */
10715 #define SF_Aggregate 0x0004 /* Contains aggregate functions */
10716 #define SF_UsesEphemeral 0x0008 /* Uses the OpenEphemeral opcode */
10717 #define SF_Expanded 0x0010 /* sqlite3SelectExpand() called on this */
10718 #define SF_HasTypeInfo 0x0020 /* FROM subqueries have Table metadata */
10719 #define SF_UseSorter 0x0040 /* Sort using a sorter */
10723 ** The results of a select can be distributed in several ways. The
10724 ** "SRT" prefix means "SELECT Result Type".
10726 #define SRT_Union 1 /* Store result as keys in an index */
10727 #define SRT_Except 2 /* Remove result from a UNION index */
10728 #define SRT_Exists 3 /* Store 1 if the result is not empty */
10729 #define SRT_Discard 4 /* Do not save the results anywhere */
10731 /* The ORDER BY clause is ignored for all of the above */
10732 #define IgnorableOrderby(X) ((X->eDest)<=SRT_Discard)
10734 #define SRT_Output 5 /* Output each row of result */
10735 #define SRT_Mem 6 /* Store result in a memory cell */
10736 #define SRT_Set 7 /* Store results as keys in an index */
10737 #define SRT_Table 8 /* Store result as data with an automatic rowid */
10738 #define SRT_EphemTab 9 /* Create transient tab and store like SRT_Table */
10739 #define SRT_Coroutine 10 /* Generate a single row of result */
10742 ** A structure used to customize the behavior of sqlite3Select(). See
10743 ** comments above sqlite3Select() for details.
10745 typedef struct SelectDest SelectDest;
10746 struct SelectDest {
10747 u8 eDest; /* How to dispose of the results */
10748 u8 affinity; /* Affinity used when eDest==SRT_Set */
10749 int iParm; /* A parameter used by the eDest disposal method */
10750 int iMem; /* Base register where results are written */
10751 int nMem; /* Number of registers allocated */
10755 ** During code generation of statements that do inserts into AUTOINCREMENT
10756 ** tables, the following information is attached to the Table.u.autoInc.p
10757 ** pointer of each autoincrement table to record some side information that
10758 ** the code generator needs. We have to keep per-table autoincrement
10759 ** information in case inserts are down within triggers. Triggers do not
10760 ** normally coordinate their activities, but we do need to coordinate the
10761 ** loading and saving of autoincrement information.
10763 struct AutoincInfo {
10764 AutoincInfo *pNext; /* Next info block in a list of them all */
10765 Table *pTab; /* Table this info block refers to */
10766 int iDb; /* Index in sqlite3.aDb[] of database holding pTab */
10767 int regCtr; /* Memory register holding the rowid counter */
10771 ** Size of the column cache
10773 #ifndef SQLITE_N_COLCACHE
10774 # define SQLITE_N_COLCACHE 10
10775 #endif
10778 ** At least one instance of the following structure is created for each
10779 ** trigger that may be fired while parsing an INSERT, UPDATE or DELETE
10780 ** statement. All such objects are stored in the linked list headed at
10781 ** Parse.pTriggerPrg and deleted once statement compilation has been
10782 ** completed.
10784 ** A Vdbe sub-program that implements the body and WHEN clause of trigger
10785 ** TriggerPrg.pTrigger, assuming a default ON CONFLICT clause of
10786 ** TriggerPrg.orconf, is stored in the TriggerPrg.pProgram variable.
10787 ** The Parse.pTriggerPrg list never contains two entries with the same
10788 ** values for both pTrigger and orconf.
10790 ** The TriggerPrg.aColmask[0] variable is set to a mask of old.* columns
10791 ** accessed (or set to 0 for triggers fired as a result of INSERT
10792 ** statements). Similarly, the TriggerPrg.aColmask[1] variable is set to
10793 ** a mask of new.* columns used by the program.
10795 struct TriggerPrg {
10796 Trigger *pTrigger; /* Trigger this program was coded from */
10797 int orconf; /* Default ON CONFLICT policy */
10798 SubProgram *pProgram; /* Program implementing pTrigger/orconf */
10799 u32 aColmask[2]; /* Masks of old.*, new.* columns accessed */
10800 TriggerPrg *pNext; /* Next entry in Parse.pTriggerPrg list */
10804 ** The yDbMask datatype for the bitmask of all attached databases.
10806 #if SQLITE_MAX_ATTACHED>30
10807 typedef sqlite3_uint64 yDbMask;
10808 #else
10809 typedef unsigned int yDbMask;
10810 #endif
10813 ** An SQL parser context. A copy of this structure is passed through
10814 ** the parser and down into all the parser action routine in order to
10815 ** carry around information that is global to the entire parse.
10817 ** The structure is divided into two parts. When the parser and code
10818 ** generate call themselves recursively, the first part of the structure
10819 ** is constant but the second part is reset at the beginning and end of
10820 ** each recursion.
10822 ** The nTableLock and aTableLock variables are only used if the shared-cache
10823 ** feature is enabled (if sqlite3Tsd()->useSharedData is true). They are
10824 ** used to store the set of table-locks required by the statement being
10825 ** compiled. Function sqlite3TableLock() is used to add entries to the
10826 ** list.
10828 struct Parse {
10829 sqlite3 *db; /* The main database structure */
10830 int rc; /* Return code from execution */
10831 char *zErrMsg; /* An error message */
10832 Vdbe *pVdbe; /* An engine for executing database bytecode */
10833 u8 colNamesSet; /* TRUE after OP_ColumnName has been issued to pVdbe */
10834 u8 nameClash; /* A permanent table name clashes with temp table name */
10835 u8 checkSchema; /* Causes schema cookie check after an error */
10836 u8 nested; /* Number of nested calls to the parser/code generator */
10837 u8 parseError; /* True after a parsing error. Ticket #1794 */
10838 u8 nTempReg; /* Number of temporary registers in aTempReg[] */
10839 u8 nTempInUse; /* Number of aTempReg[] currently checked out */
10840 int aTempReg[8]; /* Holding area for temporary registers */
10841 int nRangeReg; /* Size of the temporary register block */
10842 int iRangeReg; /* First register in temporary register block */
10843 int nErr; /* Number of errors seen */
10844 int nTab; /* Number of previously allocated VDBE cursors */
10845 int nMem; /* Number of memory cells used so far */
10846 int nSet; /* Number of sets used so far */
10847 int ckBase; /* Base register of data during check constraints */
10848 int iCacheLevel; /* ColCache valid when aColCache[].iLevel<=iCacheLevel */
10849 int iCacheCnt; /* Counter used to generate aColCache[].lru values */
10850 u8 nColCache; /* Number of entries in the column cache */
10851 u8 iColCache; /* Next entry of the cache to replace */
10852 struct yColCache {
10853 int iTable; /* Table cursor number */
10854 int iColumn; /* Table column number */
10855 u8 tempReg; /* iReg is a temp register that needs to be freed */
10856 int iLevel; /* Nesting level */
10857 int iReg; /* Reg with value of this column. 0 means none. */
10858 int lru; /* Least recently used entry has the smallest value */
10859 } aColCache[SQLITE_N_COLCACHE]; /* One for each column cache entry */
10860 yDbMask writeMask; /* Start a write transaction on these databases */
10861 yDbMask cookieMask; /* Bitmask of schema verified databases */
10862 u8 isMultiWrite; /* True if statement may affect/insert multiple rows */
10863 u8 mayAbort; /* True if statement may throw an ABORT exception */
10864 int cookieGoto; /* Address of OP_Goto to cookie verifier subroutine */
10865 int cookieValue[SQLITE_MAX_ATTACHED+2]; /* Values of cookies to verify */
10866 #ifndef SQLITE_OMIT_SHARED_CACHE
10867 int nTableLock; /* Number of locks in aTableLock */
10868 TableLock *aTableLock; /* Required table locks for shared-cache mode */
10869 #endif
10870 int regRowid; /* Register holding rowid of CREATE TABLE entry */
10871 int regRoot; /* Register holding root page number for new objects */
10872 AutoincInfo *pAinc; /* Information about AUTOINCREMENT counters */
10873 int nMaxArg; /* Max args passed to user function by sub-program */
10875 /* Information used while coding trigger programs. */
10876 Parse *pToplevel; /* Parse structure for main program (or NULL) */
10877 Table *pTriggerTab; /* Table triggers are being coded for */
10878 u32 oldmask; /* Mask of old.* columns referenced */
10879 u32 newmask; /* Mask of new.* columns referenced */
10880 u8 eTriggerOp; /* TK_UPDATE, TK_INSERT or TK_DELETE */
10881 u8 eOrconf; /* Default ON CONFLICT policy for trigger steps */
10882 u8 disableTriggers; /* True to disable triggers */
10883 double nQueryLoop; /* Estimated number of iterations of a query */
10885 /* Above is constant between recursions. Below is reset before and after
10886 ** each recursion */
10888 int nVar; /* Number of '?' variables seen in the SQL so far */
10889 int nzVar; /* Number of available slots in azVar[] */
10890 char **azVar; /* Pointers to names of parameters */
10891 Vdbe *pReprepare; /* VM being reprepared (sqlite3Reprepare()) */
10892 int nAlias; /* Number of aliased result set columns */
10893 int nAliasAlloc; /* Number of allocated slots for aAlias[] */
10894 int *aAlias; /* Register used to hold aliased result */
10895 u8 explain; /* True if the EXPLAIN flag is found on the query */
10896 Token sNameToken; /* Token with unqualified schema object name */
10897 Token sLastToken; /* The last token parsed */
10898 const char *zTail; /* All SQL text past the last semicolon parsed */
10899 Table *pNewTable; /* A table being constructed by CREATE TABLE */
10900 Trigger *pNewTrigger; /* Trigger under construct by a CREATE TRIGGER */
10901 const char *zAuthContext; /* The 6th parameter to db->xAuth callbacks */
10902 #ifndef SQLITE_OMIT_VIRTUALTABLE
10903 Token sArg; /* Complete text of a module argument */
10904 u8 declareVtab; /* True if inside sqlite3_declare_vtab() */
10905 int nVtabLock; /* Number of virtual tables to lock */
10906 Table **apVtabLock; /* Pointer to virtual tables needing locking */
10907 #endif
10908 int nHeight; /* Expression tree height of current sub-select */
10909 Table *pZombieTab; /* List of Table objects to delete after code gen */
10910 TriggerPrg *pTriggerPrg; /* Linked list of coded triggers */
10912 #ifndef SQLITE_OMIT_EXPLAIN
10913 int iSelectId;
10914 int iNextSelectId;
10915 #endif
10918 #ifdef SQLITE_OMIT_VIRTUALTABLE
10919 #define IN_DECLARE_VTAB 0
10920 #else
10921 #define IN_DECLARE_VTAB (pParse->declareVtab)
10922 #endif
10925 ** An instance of the following structure can be declared on a stack and used
10926 ** to save the Parse.zAuthContext value so that it can be restored later.
10928 struct AuthContext {
10929 const char *zAuthContext; /* Put saved Parse.zAuthContext here */
10930 Parse *pParse; /* The Parse structure */
10934 ** Bitfield flags for P5 value in OP_Insert and OP_Delete
10936 #define OPFLAG_NCHANGE 0x01 /* Set to update db->nChange */
10937 #define OPFLAG_LASTROWID 0x02 /* Set to update db->lastRowid */
10938 #define OPFLAG_ISUPDATE 0x04 /* This OP_Insert is an sql UPDATE */
10939 #define OPFLAG_APPEND 0x08 /* This is likely to be an append */
10940 #define OPFLAG_USESEEKRESULT 0x10 /* Try to avoid a seek in BtreeInsert() */
10941 #define OPFLAG_CLEARCACHE 0x20 /* Clear pseudo-table cache in OP_Column */
10944 * Each trigger present in the database schema is stored as an instance of
10945 * struct Trigger.
10947 * Pointers to instances of struct Trigger are stored in two ways.
10948 * 1. In the "trigHash" hash table (part of the sqlite3* that represents the
10949 * database). This allows Trigger structures to be retrieved by name.
10950 * 2. All triggers associated with a single table form a linked list, using the
10951 * pNext member of struct Trigger. A pointer to the first element of the
10952 * linked list is stored as the "pTrigger" member of the associated
10953 * struct Table.
10955 * The "step_list" member points to the first element of a linked list
10956 * containing the SQL statements specified as the trigger program.
10958 struct Trigger {
10959 char *zName; /* The name of the trigger */
10960 char *table; /* The table or view to which the trigger applies */
10961 u8 op; /* One of TK_DELETE, TK_UPDATE, TK_INSERT */
10962 u8 tr_tm; /* One of TRIGGER_BEFORE, TRIGGER_AFTER */
10963 Expr *pWhen; /* The WHEN clause of the expression (may be NULL) */
10964 IdList *pColumns; /* If this is an UPDATE OF <column-list> trigger,
10965 the <column-list> is stored here */
10966 Schema *pSchema; /* Schema containing the trigger */
10967 Schema *pTabSchema; /* Schema containing the table */
10968 TriggerStep *step_list; /* Link list of trigger program steps */
10969 Trigger *pNext; /* Next trigger associated with the table */
10973 ** A trigger is either a BEFORE or an AFTER trigger. The following constants
10974 ** determine which.
10976 ** If there are multiple triggers, you might of some BEFORE and some AFTER.
10977 ** In that cases, the constants below can be ORed together.
10979 #define TRIGGER_BEFORE 1
10980 #define TRIGGER_AFTER 2
10983 * An instance of struct TriggerStep is used to store a single SQL statement
10984 * that is a part of a trigger-program.
10986 * Instances of struct TriggerStep are stored in a singly linked list (linked
10987 * using the "pNext" member) referenced by the "step_list" member of the
10988 * associated struct Trigger instance. The first element of the linked list is
10989 * the first step of the trigger-program.
10991 * The "op" member indicates whether this is a "DELETE", "INSERT", "UPDATE" or
10992 * "SELECT" statement. The meanings of the other members is determined by the
10993 * value of "op" as follows:
10995 * (op == TK_INSERT)
10996 * orconf -> stores the ON CONFLICT algorithm
10997 * pSelect -> If this is an INSERT INTO ... SELECT ... statement, then
10998 * this stores a pointer to the SELECT statement. Otherwise NULL.
10999 * target -> A token holding the quoted name of the table to insert into.
11000 * pExprList -> If this is an INSERT INTO ... VALUES ... statement, then
11001 * this stores values to be inserted. Otherwise NULL.
11002 * pIdList -> If this is an INSERT INTO ... (<column-names>) VALUES ...
11003 * statement, then this stores the column-names to be
11004 * inserted into.
11006 * (op == TK_DELETE)
11007 * target -> A token holding the quoted name of the table to delete from.
11008 * pWhere -> The WHERE clause of the DELETE statement if one is specified.
11009 * Otherwise NULL.
11011 * (op == TK_UPDATE)
11012 * target -> A token holding the quoted name of the table to update rows of.
11013 * pWhere -> The WHERE clause of the UPDATE statement if one is specified.
11014 * Otherwise NULL.
11015 * pExprList -> A list of the columns to update and the expressions to update
11016 * them to. See sqlite3Update() documentation of "pChanges"
11017 * argument.
11020 struct TriggerStep {
11021 u8 op; /* One of TK_DELETE, TK_UPDATE, TK_INSERT, TK_SELECT */
11022 u8 orconf; /* OE_Rollback etc. */
11023 Trigger *pTrig; /* The trigger that this step is a part of */
11024 Select *pSelect; /* SELECT statment or RHS of INSERT INTO .. SELECT ... */
11025 Token target; /* Target table for DELETE, UPDATE, INSERT */
11026 Expr *pWhere; /* The WHERE clause for DELETE or UPDATE steps */
11027 ExprList *pExprList; /* SET clause for UPDATE. VALUES clause for INSERT */
11028 IdList *pIdList; /* Column names for INSERT */
11029 TriggerStep *pNext; /* Next in the link-list */
11030 TriggerStep *pLast; /* Last element in link-list. Valid for 1st elem only */
11034 ** The following structure contains information used by the sqliteFix...
11035 ** routines as they walk the parse tree to make database references
11036 ** explicit.
11038 typedef struct DbFixer DbFixer;
11039 struct DbFixer {
11040 Parse *pParse; /* The parsing context. Error messages written here */
11041 const char *zDb; /* Make sure all objects are contained in this database */
11042 const char *zType; /* Type of the container - used for error messages */
11043 const Token *pName; /* Name of the container - used for error messages */
11047 ** An objected used to accumulate the text of a string where we
11048 ** do not necessarily know how big the string will be in the end.
11050 struct StrAccum {
11051 sqlite3 *db; /* Optional database for lookaside. Can be NULL */
11052 char *zBase; /* A base allocation. Not from malloc. */
11053 char *zText; /* The string collected so far */
11054 int nChar; /* Length of the string so far */
11055 int nAlloc; /* Amount of space allocated in zText */
11056 int mxAlloc; /* Maximum allowed string length */
11057 u8 mallocFailed; /* Becomes true if any memory allocation fails */
11058 u8 useMalloc; /* 0: none, 1: sqlite3DbMalloc, 2: sqlite3_malloc */
11059 u8 tooBig; /* Becomes true if string size exceeds limits */
11063 ** A pointer to this structure is used to communicate information
11064 ** from sqlite3Init and OP_ParseSchema into the sqlite3InitCallback.
11066 typedef struct {
11067 sqlite3 *db; /* The database being initialized */
11068 int iDb; /* 0 for main database. 1 for TEMP, 2.. for ATTACHed */
11069 char **pzErrMsg; /* Error message stored here */
11070 int rc; /* Result code stored here */
11071 } InitData;
11074 ** Structure containing global configuration data for the SQLite library.
11076 ** This structure also contains some state information.
11078 struct Sqlite3Config {
11079 int bMemstat; /* True to enable memory status */
11080 int bCoreMutex; /* True to enable core mutexing */
11081 int bFullMutex; /* True to enable full mutexing */
11082 int bOpenUri; /* True to interpret filenames as URIs */
11083 int mxStrlen; /* Maximum string length */
11084 int szLookaside; /* Default lookaside buffer size */
11085 int nLookaside; /* Default lookaside buffer count */
11086 sqlite3_mem_methods m; /* Low-level memory allocation interface */
11087 sqlite3_mutex_methods mutex; /* Low-level mutex interface */
11088 sqlite3_pcache_methods pcache; /* Low-level page-cache interface */
11089 void *pHeap; /* Heap storage space */
11090 int nHeap; /* Size of pHeap[] */
11091 int mnReq, mxReq; /* Min and max heap requests sizes */
11092 void *pScratch; /* Scratch memory */
11093 int szScratch; /* Size of each scratch buffer */
11094 int nScratch; /* Number of scratch buffers */
11095 void *pPage; /* Page cache memory */
11096 int szPage; /* Size of each page in pPage[] */
11097 int nPage; /* Number of pages in pPage[] */
11098 int mxParserStack; /* maximum depth of the parser stack */
11099 int sharedCacheEnabled; /* true if shared-cache mode enabled */
11100 /* The above might be initialized to non-zero. The following need to always
11101 ** initially be zero, however. */
11102 int isInit; /* True after initialization has finished */
11103 int inProgress; /* True while initialization in progress */
11104 int isMutexInit; /* True after mutexes are initialized */
11105 int isMallocInit; /* True after malloc is initialized */
11106 int isPCacheInit; /* True after malloc is initialized */
11107 sqlite3_mutex *pInitMutex; /* Mutex used by sqlite3_initialize() */
11108 int nRefInitMutex; /* Number of users of pInitMutex */
11109 void (*xLog)(void*,int,const char*); /* Function for logging */
11110 void *pLogArg; /* First argument to xLog() */
11111 int bLocaltimeFault; /* True to fail localtime() calls */
11115 ** Context pointer passed down through the tree-walk.
11117 struct Walker {
11118 int (*xExprCallback)(Walker*, Expr*); /* Callback for expressions */
11119 int (*xSelectCallback)(Walker*,Select*); /* Callback for SELECTs */
11120 Parse *pParse; /* Parser context. */
11121 union { /* Extra data for callback */
11122 NameContext *pNC; /* Naming context */
11123 int i; /* Integer value */
11124 } u;
11127 /* Forward declarations */
11128 SQLITE_PRIVATE int sqlite3WalkExpr(Walker*, Expr*);
11129 SQLITE_PRIVATE int sqlite3WalkExprList(Walker*, ExprList*);
11130 SQLITE_PRIVATE int sqlite3WalkSelect(Walker*, Select*);
11131 SQLITE_PRIVATE int sqlite3WalkSelectExpr(Walker*, Select*);
11132 SQLITE_PRIVATE int sqlite3WalkSelectFrom(Walker*, Select*);
11135 ** Return code from the parse-tree walking primitives and their
11136 ** callbacks.
11138 #define WRC_Continue 0 /* Continue down into children */
11139 #define WRC_Prune 1 /* Omit children but continue walking siblings */
11140 #define WRC_Abort 2 /* Abandon the tree walk */
11143 ** Assuming zIn points to the first byte of a UTF-8 character,
11144 ** advance zIn to point to the first byte of the next UTF-8 character.
11146 #define SQLITE_SKIP_UTF8(zIn) { \
11147 if( (*(zIn++))>=0xc0 ){ \
11148 while( (*zIn & 0xc0)==0x80 ){ zIn++; } \
11153 ** The SQLITE_*_BKPT macros are substitutes for the error codes with
11154 ** the same name but without the _BKPT suffix. These macros invoke
11155 ** routines that report the line-number on which the error originated
11156 ** using sqlite3_log(). The routines also provide a convenient place
11157 ** to set a debugger breakpoint.
11159 SQLITE_PRIVATE int sqlite3CorruptError(int);
11160 SQLITE_PRIVATE int sqlite3MisuseError(int);
11161 SQLITE_PRIVATE int sqlite3CantopenError(int);
11162 #define SQLITE_CORRUPT_BKPT sqlite3CorruptError(__LINE__)
11163 #define SQLITE_MISUSE_BKPT sqlite3MisuseError(__LINE__)
11164 #define SQLITE_CANTOPEN_BKPT sqlite3CantopenError(__LINE__)
11168 ** FTS4 is really an extension for FTS3. It is enabled using the
11169 ** SQLITE_ENABLE_FTS3 macro. But to avoid confusion we also all
11170 ** the SQLITE_ENABLE_FTS4 macro to serve as an alisse for SQLITE_ENABLE_FTS3.
11172 #if defined(SQLITE_ENABLE_FTS4) && !defined(SQLITE_ENABLE_FTS3)
11173 # define SQLITE_ENABLE_FTS3
11174 #endif
11177 ** The ctype.h header is needed for non-ASCII systems. It is also
11178 ** needed by FTS3 when FTS3 is included in the amalgamation.
11180 #if !defined(SQLITE_ASCII) || \
11181 (defined(SQLITE_ENABLE_FTS3) && defined(SQLITE_AMALGAMATION))
11182 # include <ctype.h>
11183 #endif
11186 ** The following macros mimic the standard library functions toupper(),
11187 ** isspace(), isalnum(), isdigit() and isxdigit(), respectively. The
11188 ** sqlite versions only work for ASCII characters, regardless of locale.
11190 #ifdef SQLITE_ASCII
11191 # define sqlite3Toupper(x) ((x)&~(sqlite3CtypeMap[(unsigned char)(x)]&0x20))
11192 # define sqlite3Isspace(x) (sqlite3CtypeMap[(unsigned char)(x)]&0x01)
11193 # define sqlite3Isalnum(x) (sqlite3CtypeMap[(unsigned char)(x)]&0x06)
11194 # define sqlite3Isalpha(x) (sqlite3CtypeMap[(unsigned char)(x)]&0x02)
11195 # define sqlite3Isdigit(x) (sqlite3CtypeMap[(unsigned char)(x)]&0x04)
11196 # define sqlite3Isxdigit(x) (sqlite3CtypeMap[(unsigned char)(x)]&0x08)
11197 # define sqlite3Tolower(x) (sqlite3UpperToLower[(unsigned char)(x)])
11198 #else
11199 # define sqlite3Toupper(x) toupper((unsigned char)(x))
11200 # define sqlite3Isspace(x) isspace((unsigned char)(x))
11201 # define sqlite3Isalnum(x) isalnum((unsigned char)(x))
11202 # define sqlite3Isalpha(x) isalpha((unsigned char)(x))
11203 # define sqlite3Isdigit(x) isdigit((unsigned char)(x))
11204 # define sqlite3Isxdigit(x) isxdigit((unsigned char)(x))
11205 # define sqlite3Tolower(x) tolower((unsigned char)(x))
11206 #endif
11209 ** Internal function prototypes
11211 SQLITE_PRIVATE int sqlite3StrICmp(const char *, const char *);
11212 SQLITE_PRIVATE int sqlite3Strlen30(const char*);
11213 #define sqlite3StrNICmp sqlite3_strnicmp
11215 SQLITE_PRIVATE int sqlite3MallocInit(void);
11216 SQLITE_PRIVATE void sqlite3MallocEnd(void);
11217 SQLITE_PRIVATE void *sqlite3Malloc(int);
11218 SQLITE_PRIVATE void *sqlite3MallocZero(int);
11219 SQLITE_PRIVATE void *sqlite3DbMallocZero(sqlite3*, int);
11220 SQLITE_PRIVATE void *sqlite3DbMallocRaw(sqlite3*, int);
11221 SQLITE_PRIVATE char *sqlite3DbStrDup(sqlite3*,const char*);
11222 SQLITE_PRIVATE char *sqlite3DbStrNDup(sqlite3*,const char*, int);
11223 SQLITE_PRIVATE void *sqlite3Realloc(void*, int);
11224 SQLITE_PRIVATE void *sqlite3DbReallocOrFree(sqlite3 *, void *, int);
11225 SQLITE_PRIVATE void *sqlite3DbRealloc(sqlite3 *, void *, int);
11226 SQLITE_PRIVATE void sqlite3DbFree(sqlite3*, void*);
11227 SQLITE_PRIVATE int sqlite3MallocSize(void*);
11228 SQLITE_PRIVATE int sqlite3DbMallocSize(sqlite3*, void*);
11229 SQLITE_PRIVATE void *sqlite3ScratchMalloc(int);
11230 SQLITE_PRIVATE void sqlite3ScratchFree(void*);
11231 SQLITE_PRIVATE void *sqlite3PageMalloc(int);
11232 SQLITE_PRIVATE void sqlite3PageFree(void*);
11233 SQLITE_PRIVATE void sqlite3MemSetDefault(void);
11234 SQLITE_PRIVATE void sqlite3BenignMallocHooks(void (*)(void), void (*)(void));
11235 SQLITE_PRIVATE int sqlite3HeapNearlyFull(void);
11238 ** On systems with ample stack space and that support alloca(), make
11239 ** use of alloca() to obtain space for large automatic objects. By default,
11240 ** obtain space from malloc().
11242 ** The alloca() routine never returns NULL. This will cause code paths
11243 ** that deal with sqlite3StackAlloc() failures to be unreachable.
11245 #ifdef SQLITE_USE_ALLOCA
11246 # define sqlite3StackAllocRaw(D,N) alloca(N)
11247 # define sqlite3StackAllocZero(D,N) memset(alloca(N), 0, N)
11248 # define sqlite3StackFree(D,P)
11249 #else
11250 # define sqlite3StackAllocRaw(D,N) sqlite3DbMallocRaw(D,N)
11251 # define sqlite3StackAllocZero(D,N) sqlite3DbMallocZero(D,N)
11252 # define sqlite3StackFree(D,P) sqlite3DbFree(D,P)
11253 #endif
11255 #ifdef SQLITE_ENABLE_MEMSYS3
11256 SQLITE_PRIVATE const sqlite3_mem_methods *sqlite3MemGetMemsys3(void);
11257 #endif
11258 #ifdef SQLITE_ENABLE_MEMSYS5
11259 SQLITE_PRIVATE const sqlite3_mem_methods *sqlite3MemGetMemsys5(void);
11260 #endif
11263 #ifndef SQLITE_MUTEX_OMIT
11264 SQLITE_PRIVATE sqlite3_mutex_methods const *sqlite3DefaultMutex(void);
11265 SQLITE_PRIVATE sqlite3_mutex_methods const *sqlite3NoopMutex(void);
11266 SQLITE_PRIVATE sqlite3_mutex *sqlite3MutexAlloc(int);
11267 SQLITE_PRIVATE int sqlite3MutexInit(void);
11268 SQLITE_PRIVATE int sqlite3MutexEnd(void);
11269 #endif
11271 SQLITE_PRIVATE int sqlite3StatusValue(int);
11272 SQLITE_PRIVATE void sqlite3StatusAdd(int, int);
11273 SQLITE_PRIVATE void sqlite3StatusSet(int, int);
11275 #ifndef SQLITE_OMIT_FLOATING_POINT
11276 SQLITE_PRIVATE int sqlite3IsNaN(double);
11277 #else
11278 # define sqlite3IsNaN(X) 0
11279 #endif
11281 SQLITE_PRIVATE void sqlite3VXPrintf(StrAccum*, int, const char*, va_list);
11282 #ifndef SQLITE_OMIT_TRACE
11283 SQLITE_PRIVATE void sqlite3XPrintf(StrAccum*, const char*, ...);
11284 #endif
11285 SQLITE_PRIVATE char *sqlite3MPrintf(sqlite3*,const char*, ...);
11286 SQLITE_PRIVATE char *sqlite3VMPrintf(sqlite3*,const char*, va_list);
11287 SQLITE_PRIVATE char *sqlite3MAppendf(sqlite3*,char*,const char*,...);
11288 #if defined(SQLITE_TEST) || defined(SQLITE_DEBUG)
11289 SQLITE_PRIVATE void sqlite3DebugPrintf(const char*, ...);
11290 #endif
11291 #if defined(SQLITE_TEST)
11292 SQLITE_PRIVATE void *sqlite3TestTextToPtr(const char*);
11293 #endif
11294 SQLITE_PRIVATE void sqlite3SetString(char **, sqlite3*, const char*, ...);
11295 SQLITE_PRIVATE void sqlite3ErrorMsg(Parse*, const char*, ...);
11296 SQLITE_PRIVATE int sqlite3Dequote(char*);
11297 SQLITE_PRIVATE int sqlite3KeywordCode(const unsigned char*, int);
11298 SQLITE_PRIVATE int sqlite3RunParser(Parse*, const char*, char **);
11299 SQLITE_PRIVATE void sqlite3FinishCoding(Parse*);
11300 SQLITE_PRIVATE int sqlite3GetTempReg(Parse*);
11301 SQLITE_PRIVATE void sqlite3ReleaseTempReg(Parse*,int);
11302 SQLITE_PRIVATE int sqlite3GetTempRange(Parse*,int);
11303 SQLITE_PRIVATE void sqlite3ReleaseTempRange(Parse*,int,int);
11304 SQLITE_PRIVATE Expr *sqlite3ExprAlloc(sqlite3*,int,const Token*,int);
11305 SQLITE_PRIVATE Expr *sqlite3Expr(sqlite3*,int,const char*);
11306 SQLITE_PRIVATE void sqlite3ExprAttachSubtrees(sqlite3*,Expr*,Expr*,Expr*);
11307 SQLITE_PRIVATE Expr *sqlite3PExpr(Parse*, int, Expr*, Expr*, const Token*);
11308 SQLITE_PRIVATE Expr *sqlite3ExprAnd(sqlite3*,Expr*, Expr*);
11309 SQLITE_PRIVATE Expr *sqlite3ExprFunction(Parse*,ExprList*, Token*);
11310 SQLITE_PRIVATE void sqlite3ExprAssignVarNumber(Parse*, Expr*);
11311 SQLITE_PRIVATE void sqlite3ExprDelete(sqlite3*, Expr*);
11312 SQLITE_PRIVATE ExprList *sqlite3ExprListAppend(Parse*,ExprList*,Expr*);
11313 SQLITE_PRIVATE void sqlite3ExprListSetName(Parse*,ExprList*,Token*,int);
11314 SQLITE_PRIVATE void sqlite3ExprListSetSpan(Parse*,ExprList*,ExprSpan*);
11315 SQLITE_PRIVATE void sqlite3ExprListDelete(sqlite3*, ExprList*);
11316 SQLITE_PRIVATE int sqlite3Init(sqlite3*, char**);
11317 SQLITE_PRIVATE int sqlite3InitCallback(void*, int, char**, char**);
11318 SQLITE_PRIVATE void sqlite3Pragma(Parse*,Token*,Token*,Token*,int);
11319 SQLITE_PRIVATE void sqlite3ResetInternalSchema(sqlite3*, int);
11320 SQLITE_PRIVATE void sqlite3BeginParse(Parse*,int);
11321 SQLITE_PRIVATE void sqlite3CommitInternalChanges(sqlite3*);
11322 SQLITE_PRIVATE Table *sqlite3ResultSetOfSelect(Parse*,Select*);
11323 SQLITE_PRIVATE void sqlite3OpenMasterTable(Parse *, int);
11324 SQLITE_PRIVATE void sqlite3StartTable(Parse*,Token*,Token*,int,int,int,int);
11325 SQLITE_PRIVATE void sqlite3AddColumn(Parse*,Token*);
11326 SQLITE_PRIVATE void sqlite3AddNotNull(Parse*, int);
11327 SQLITE_PRIVATE void sqlite3AddPrimaryKey(Parse*, ExprList*, int, int, int);
11328 SQLITE_PRIVATE void sqlite3AddCheckConstraint(Parse*, Expr*);
11329 SQLITE_PRIVATE void sqlite3AddColumnType(Parse*,Token*);
11330 SQLITE_PRIVATE void sqlite3AddDefaultValue(Parse*,ExprSpan*);
11331 SQLITE_PRIVATE void sqlite3AddCollateType(Parse*, Token*);
11332 SQLITE_PRIVATE void sqlite3EndTable(Parse*,Token*,Token*,Select*);
11333 SQLITE_PRIVATE int sqlite3ParseUri(const char*,const char*,unsigned int*,
11334 sqlite3_vfs**,char**,char **);
11336 SQLITE_PRIVATE Bitvec *sqlite3BitvecCreate(u32);
11337 SQLITE_PRIVATE int sqlite3BitvecTest(Bitvec*, u32);
11338 SQLITE_PRIVATE int sqlite3BitvecSet(Bitvec*, u32);
11339 SQLITE_PRIVATE void sqlite3BitvecClear(Bitvec*, u32, void*);
11340 SQLITE_PRIVATE void sqlite3BitvecDestroy(Bitvec*);
11341 SQLITE_PRIVATE u32 sqlite3BitvecSize(Bitvec*);
11342 SQLITE_PRIVATE int sqlite3BitvecBuiltinTest(int,int*);
11344 SQLITE_PRIVATE RowSet *sqlite3RowSetInit(sqlite3*, void*, unsigned int);
11345 SQLITE_PRIVATE void sqlite3RowSetClear(RowSet*);
11346 SQLITE_PRIVATE void sqlite3RowSetInsert(RowSet*, i64);
11347 SQLITE_PRIVATE int sqlite3RowSetTest(RowSet*, u8 iBatch, i64);
11348 SQLITE_PRIVATE int sqlite3RowSetNext(RowSet*, i64*);
11350 SQLITE_PRIVATE void sqlite3CreateView(Parse*,Token*,Token*,Token*,Select*,int,int);
11352 #if !defined(SQLITE_OMIT_VIEW) || !defined(SQLITE_OMIT_VIRTUALTABLE)
11353 SQLITE_PRIVATE int sqlite3ViewGetColumnNames(Parse*,Table*);
11354 #else
11355 # define sqlite3ViewGetColumnNames(A,B) 0
11356 #endif
11358 SQLITE_PRIVATE void sqlite3DropTable(Parse*, SrcList*, int, int);
11359 SQLITE_PRIVATE void sqlite3DeleteTable(sqlite3*, Table*);
11360 #ifndef SQLITE_OMIT_AUTOINCREMENT
11361 SQLITE_PRIVATE void sqlite3AutoincrementBegin(Parse *pParse);
11362 SQLITE_PRIVATE void sqlite3AutoincrementEnd(Parse *pParse);
11363 #else
11364 # define sqlite3AutoincrementBegin(X)
11365 # define sqlite3AutoincrementEnd(X)
11366 #endif
11367 SQLITE_PRIVATE void sqlite3Insert(Parse*, SrcList*, ExprList*, Select*, IdList*, int);
11368 SQLITE_PRIVATE void *sqlite3ArrayAllocate(sqlite3*,void*,int,int,int*,int*,int*);
11369 SQLITE_PRIVATE IdList *sqlite3IdListAppend(sqlite3*, IdList*, Token*);
11370 SQLITE_PRIVATE int sqlite3IdListIndex(IdList*,const char*);
11371 SQLITE_PRIVATE SrcList *sqlite3SrcListEnlarge(sqlite3*, SrcList*, int, int);
11372 SQLITE_PRIVATE SrcList *sqlite3SrcListAppend(sqlite3*, SrcList*, Token*, Token*);
11373 SQLITE_PRIVATE SrcList *sqlite3SrcListAppendFromTerm(Parse*, SrcList*, Token*, Token*,
11374 Token*, Select*, Expr*, IdList*);
11375 SQLITE_PRIVATE void sqlite3SrcListIndexedBy(Parse *, SrcList *, Token *);
11376 SQLITE_PRIVATE int sqlite3IndexedByLookup(Parse *, struct SrcList_item *);
11377 SQLITE_PRIVATE void sqlite3SrcListShiftJoinType(SrcList*);
11378 SQLITE_PRIVATE void sqlite3SrcListAssignCursors(Parse*, SrcList*);
11379 SQLITE_PRIVATE void sqlite3IdListDelete(sqlite3*, IdList*);
11380 SQLITE_PRIVATE void sqlite3SrcListDelete(sqlite3*, SrcList*);
11381 SQLITE_PRIVATE Index *sqlite3CreateIndex(Parse*,Token*,Token*,SrcList*,ExprList*,int,Token*,
11382 Token*, int, int);
11383 SQLITE_PRIVATE void sqlite3DropIndex(Parse*, SrcList*, int);
11384 SQLITE_PRIVATE int sqlite3Select(Parse*, Select*, SelectDest*);
11385 SQLITE_PRIVATE Select *sqlite3SelectNew(Parse*,ExprList*,SrcList*,Expr*,ExprList*,
11386 Expr*,ExprList*,int,Expr*,Expr*);
11387 SQLITE_PRIVATE void sqlite3SelectDelete(sqlite3*, Select*);
11388 SQLITE_PRIVATE Table *sqlite3SrcListLookup(Parse*, SrcList*);
11389 SQLITE_PRIVATE int sqlite3IsReadOnly(Parse*, Table*, int);
11390 SQLITE_PRIVATE void sqlite3OpenTable(Parse*, int iCur, int iDb, Table*, int);
11391 #if defined(SQLITE_ENABLE_UPDATE_DELETE_LIMIT) && !defined(SQLITE_OMIT_SUBQUERY)
11392 SQLITE_PRIVATE Expr *sqlite3LimitWhere(Parse *, SrcList *, Expr *, ExprList *, Expr *, Expr *, char *);
11393 #endif
11394 SQLITE_PRIVATE void sqlite3DeleteFrom(Parse*, SrcList*, Expr*);
11395 SQLITE_PRIVATE void sqlite3Update(Parse*, SrcList*, ExprList*, Expr*, int);
11396 SQLITE_PRIVATE WhereInfo *sqlite3WhereBegin(Parse*, SrcList*, Expr*, ExprList**,ExprList*,u16);
11397 SQLITE_PRIVATE void sqlite3WhereEnd(WhereInfo*);
11398 SQLITE_PRIVATE int sqlite3ExprCodeGetColumn(Parse*, Table*, int, int, int);
11399 SQLITE_PRIVATE void sqlite3ExprCodeGetColumnOfTable(Vdbe*, Table*, int, int, int);
11400 SQLITE_PRIVATE void sqlite3ExprCodeMove(Parse*, int, int, int);
11401 SQLITE_PRIVATE void sqlite3ExprCodeCopy(Parse*, int, int, int);
11402 SQLITE_PRIVATE void sqlite3ExprCacheStore(Parse*, int, int, int);
11403 SQLITE_PRIVATE void sqlite3ExprCachePush(Parse*);
11404 SQLITE_PRIVATE void sqlite3ExprCachePop(Parse*, int);
11405 SQLITE_PRIVATE void sqlite3ExprCacheRemove(Parse*, int, int);
11406 SQLITE_PRIVATE void sqlite3ExprCacheClear(Parse*);
11407 SQLITE_PRIVATE void sqlite3ExprCacheAffinityChange(Parse*, int, int);
11408 SQLITE_PRIVATE int sqlite3ExprCode(Parse*, Expr*, int);
11409 SQLITE_PRIVATE int sqlite3ExprCodeTemp(Parse*, Expr*, int*);
11410 SQLITE_PRIVATE int sqlite3ExprCodeTarget(Parse*, Expr*, int);
11411 SQLITE_PRIVATE int sqlite3ExprCodeAndCache(Parse*, Expr*, int);
11412 SQLITE_PRIVATE void sqlite3ExprCodeConstants(Parse*, Expr*);
11413 SQLITE_PRIVATE int sqlite3ExprCodeExprList(Parse*, ExprList*, int, int);
11414 SQLITE_PRIVATE void sqlite3ExprIfTrue(Parse*, Expr*, int, int);
11415 SQLITE_PRIVATE void sqlite3ExprIfFalse(Parse*, Expr*, int, int);
11416 SQLITE_PRIVATE Table *sqlite3FindTable(sqlite3*,const char*, const char*);
11417 SQLITE_PRIVATE Table *sqlite3LocateTable(Parse*,int isView,const char*, const char*);
11418 SQLITE_PRIVATE Index *sqlite3FindIndex(sqlite3*,const char*, const char*);
11419 SQLITE_PRIVATE void sqlite3UnlinkAndDeleteTable(sqlite3*,int,const char*);
11420 SQLITE_PRIVATE void sqlite3UnlinkAndDeleteIndex(sqlite3*,int,const char*);
11421 SQLITE_PRIVATE void sqlite3Vacuum(Parse*);
11422 SQLITE_PRIVATE int sqlite3RunVacuum(char**, sqlite3*);
11423 SQLITE_PRIVATE char *sqlite3NameFromToken(sqlite3*, Token*);
11424 SQLITE_PRIVATE int sqlite3ExprCompare(Expr*, Expr*);
11425 SQLITE_PRIVATE int sqlite3ExprListCompare(ExprList*, ExprList*);
11426 SQLITE_PRIVATE void sqlite3ExprAnalyzeAggregates(NameContext*, Expr*);
11427 SQLITE_PRIVATE void sqlite3ExprAnalyzeAggList(NameContext*,ExprList*);
11428 SQLITE_PRIVATE Vdbe *sqlite3GetVdbe(Parse*);
11429 SQLITE_PRIVATE void sqlite3PrngSaveState(void);
11430 SQLITE_PRIVATE void sqlite3PrngRestoreState(void);
11431 SQLITE_PRIVATE void sqlite3PrngResetState(void);
11432 SQLITE_PRIVATE void sqlite3RollbackAll(sqlite3*);
11433 SQLITE_PRIVATE void sqlite3CodeVerifySchema(Parse*, int);
11434 SQLITE_PRIVATE void sqlite3CodeVerifyNamedSchema(Parse*, const char *zDb);
11435 SQLITE_PRIVATE void sqlite3BeginTransaction(Parse*, int);
11436 SQLITE_PRIVATE void sqlite3CommitTransaction(Parse*);
11437 SQLITE_PRIVATE void sqlite3RollbackTransaction(Parse*);
11438 SQLITE_PRIVATE void sqlite3Savepoint(Parse*, int, Token*);
11439 SQLITE_PRIVATE void sqlite3CloseSavepoints(sqlite3 *);
11440 SQLITE_PRIVATE int sqlite3ExprIsConstant(Expr*);
11441 SQLITE_PRIVATE int sqlite3ExprIsConstantNotJoin(Expr*);
11442 SQLITE_PRIVATE int sqlite3ExprIsConstantOrFunction(Expr*);
11443 SQLITE_PRIVATE int sqlite3ExprIsInteger(Expr*, int*);
11444 SQLITE_PRIVATE int sqlite3ExprCanBeNull(const Expr*);
11445 SQLITE_PRIVATE void sqlite3ExprCodeIsNullJump(Vdbe*, const Expr*, int, int);
11446 SQLITE_PRIVATE int sqlite3ExprNeedsNoAffinityChange(const Expr*, char);
11447 SQLITE_PRIVATE int sqlite3IsRowid(const char*);
11448 SQLITE_PRIVATE void sqlite3GenerateRowDelete(Parse*, Table*, int, int, int, Trigger *, int);
11449 SQLITE_PRIVATE void sqlite3GenerateRowIndexDelete(Parse*, Table*, int, int*);
11450 SQLITE_PRIVATE int sqlite3GenerateIndexKey(Parse*, Index*, int, int, int);
11451 SQLITE_PRIVATE void sqlite3GenerateConstraintChecks(Parse*,Table*,int,int,
11452 int*,int,int,int,int,int*);
11453 SQLITE_PRIVATE void sqlite3CompleteInsertion(Parse*, Table*, int, int, int*, int, int, int);
11454 SQLITE_PRIVATE int sqlite3OpenTableAndIndices(Parse*, Table*, int, int);
11455 SQLITE_PRIVATE void sqlite3BeginWriteOperation(Parse*, int, int);
11456 SQLITE_PRIVATE void sqlite3MultiWrite(Parse*);
11457 SQLITE_PRIVATE void sqlite3MayAbort(Parse*);
11458 SQLITE_PRIVATE void sqlite3HaltConstraint(Parse*, int, char*, int);
11459 SQLITE_PRIVATE Expr *sqlite3ExprDup(sqlite3*,Expr*,int);
11460 SQLITE_PRIVATE ExprList *sqlite3ExprListDup(sqlite3*,ExprList*,int);
11461 SQLITE_PRIVATE SrcList *sqlite3SrcListDup(sqlite3*,SrcList*,int);
11462 SQLITE_PRIVATE IdList *sqlite3IdListDup(sqlite3*,IdList*);
11463 SQLITE_PRIVATE Select *sqlite3SelectDup(sqlite3*,Select*,int);
11464 SQLITE_PRIVATE void sqlite3FuncDefInsert(FuncDefHash*, FuncDef*);
11465 SQLITE_PRIVATE FuncDef *sqlite3FindFunction(sqlite3*,const char*,int,int,u8,int);
11466 SQLITE_PRIVATE void sqlite3RegisterBuiltinFunctions(sqlite3*);
11467 SQLITE_PRIVATE void sqlite3RegisterDateTimeFunctions(void);
11468 SQLITE_PRIVATE void sqlite3RegisterGlobalFunctions(void);
11469 SQLITE_PRIVATE int sqlite3SafetyCheckOk(sqlite3*);
11470 SQLITE_PRIVATE int sqlite3SafetyCheckSickOrOk(sqlite3*);
11471 SQLITE_PRIVATE void sqlite3ChangeCookie(Parse*, int);
11473 #if !defined(SQLITE_OMIT_VIEW) && !defined(SQLITE_OMIT_TRIGGER)
11474 SQLITE_PRIVATE void sqlite3MaterializeView(Parse*, Table*, Expr*, int);
11475 #endif
11477 #ifndef SQLITE_OMIT_TRIGGER
11478 SQLITE_PRIVATE void sqlite3BeginTrigger(Parse*, Token*,Token*,int,int,IdList*,SrcList*,
11479 Expr*,int, int);
11480 SQLITE_PRIVATE void sqlite3FinishTrigger(Parse*, TriggerStep*, Token*);
11481 SQLITE_PRIVATE void sqlite3DropTrigger(Parse*, SrcList*, int);
11482 SQLITE_PRIVATE void sqlite3DropTriggerPtr(Parse*, Trigger*);
11483 SQLITE_PRIVATE Trigger *sqlite3TriggersExist(Parse *, Table*, int, ExprList*, int *pMask);
11484 SQLITE_PRIVATE Trigger *sqlite3TriggerList(Parse *, Table *);
11485 SQLITE_PRIVATE void sqlite3CodeRowTrigger(Parse*, Trigger *, int, ExprList*, int, Table *,
11486 int, int, int);
11487 SQLITE_PRIVATE void sqlite3CodeRowTriggerDirect(Parse *, Trigger *, Table *, int, int, int);
11488 void sqliteViewTriggers(Parse*, Table*, Expr*, int, ExprList*);
11489 SQLITE_PRIVATE void sqlite3DeleteTriggerStep(sqlite3*, TriggerStep*);
11490 SQLITE_PRIVATE TriggerStep *sqlite3TriggerSelectStep(sqlite3*,Select*);
11491 SQLITE_PRIVATE TriggerStep *sqlite3TriggerInsertStep(sqlite3*,Token*, IdList*,
11492 ExprList*,Select*,u8);
11493 SQLITE_PRIVATE TriggerStep *sqlite3TriggerUpdateStep(sqlite3*,Token*,ExprList*, Expr*, u8);
11494 SQLITE_PRIVATE TriggerStep *sqlite3TriggerDeleteStep(sqlite3*,Token*, Expr*);
11495 SQLITE_PRIVATE void sqlite3DeleteTrigger(sqlite3*, Trigger*);
11496 SQLITE_PRIVATE void sqlite3UnlinkAndDeleteTrigger(sqlite3*,int,const char*);
11497 SQLITE_PRIVATE u32 sqlite3TriggerColmask(Parse*,Trigger*,ExprList*,int,int,Table*,int);
11498 # define sqlite3ParseToplevel(p) ((p)->pToplevel ? (p)->pToplevel : (p))
11499 #else
11500 # define sqlite3TriggersExist(B,C,D,E,F) 0
11501 # define sqlite3DeleteTrigger(A,B)
11502 # define sqlite3DropTriggerPtr(A,B)
11503 # define sqlite3UnlinkAndDeleteTrigger(A,B,C)
11504 # define sqlite3CodeRowTrigger(A,B,C,D,E,F,G,H,I)
11505 # define sqlite3CodeRowTriggerDirect(A,B,C,D,E,F)
11506 # define sqlite3TriggerList(X, Y) 0
11507 # define sqlite3ParseToplevel(p) p
11508 # define sqlite3TriggerColmask(A,B,C,D,E,F,G) 0
11509 #endif
11511 SQLITE_PRIVATE int sqlite3JoinType(Parse*, Token*, Token*, Token*);
11512 SQLITE_PRIVATE void sqlite3CreateForeignKey(Parse*, ExprList*, Token*, ExprList*, int);
11513 SQLITE_PRIVATE void sqlite3DeferForeignKey(Parse*, int);
11514 #ifndef SQLITE_OMIT_AUTHORIZATION
11515 SQLITE_PRIVATE void sqlite3AuthRead(Parse*,Expr*,Schema*,SrcList*);
11516 SQLITE_PRIVATE int sqlite3AuthCheck(Parse*,int, const char*, const char*, const char*);
11517 SQLITE_PRIVATE void sqlite3AuthContextPush(Parse*, AuthContext*, const char*);
11518 SQLITE_PRIVATE void sqlite3AuthContextPop(AuthContext*);
11519 SQLITE_PRIVATE int sqlite3AuthReadCol(Parse*, const char *, const char *, int);
11520 #else
11521 # define sqlite3AuthRead(a,b,c,d)
11522 # define sqlite3AuthCheck(a,b,c,d,e) SQLITE_OK
11523 # define sqlite3AuthContextPush(a,b,c)
11524 # define sqlite3AuthContextPop(a) ((void)(a))
11525 #endif
11526 SQLITE_PRIVATE void sqlite3Attach(Parse*, Expr*, Expr*, Expr*);
11527 SQLITE_PRIVATE void sqlite3Detach(Parse*, Expr*);
11528 SQLITE_PRIVATE int sqlite3FixInit(DbFixer*, Parse*, int, const char*, const Token*);
11529 SQLITE_PRIVATE int sqlite3FixSrcList(DbFixer*, SrcList*);
11530 SQLITE_PRIVATE int sqlite3FixSelect(DbFixer*, Select*);
11531 SQLITE_PRIVATE int sqlite3FixExpr(DbFixer*, Expr*);
11532 SQLITE_PRIVATE int sqlite3FixExprList(DbFixer*, ExprList*);
11533 SQLITE_PRIVATE int sqlite3FixTriggerStep(DbFixer*, TriggerStep*);
11534 SQLITE_PRIVATE int sqlite3AtoF(const char *z, double*, int, u8);
11535 SQLITE_PRIVATE int sqlite3GetInt32(const char *, int*);
11536 SQLITE_PRIVATE int sqlite3Atoi(const char*);
11537 SQLITE_PRIVATE int sqlite3Utf16ByteLen(const void *pData, int nChar);
11538 SQLITE_PRIVATE int sqlite3Utf8CharLen(const char *pData, int nByte);
11539 SQLITE_PRIVATE u32 sqlite3Utf8Read(const u8*, const u8**);
11542 ** Routines to read and write variable-length integers. These used to
11543 ** be defined locally, but now we use the varint routines in the util.c
11544 ** file. Code should use the MACRO forms below, as the Varint32 versions
11545 ** are coded to assume the single byte case is already handled (which
11546 ** the MACRO form does).
11548 SQLITE_PRIVATE int sqlite3PutVarint(unsigned char*, u64);
11549 SQLITE_PRIVATE int sqlite3PutVarint32(unsigned char*, u32);
11550 SQLITE_PRIVATE u8 sqlite3GetVarint(const unsigned char *, u64 *);
11551 SQLITE_PRIVATE u8 sqlite3GetVarint32(const unsigned char *, u32 *);
11552 SQLITE_PRIVATE int sqlite3VarintLen(u64 v);
11555 ** The header of a record consists of a sequence variable-length integers.
11556 ** These integers are almost always small and are encoded as a single byte.
11557 ** The following macros take advantage this fact to provide a fast encode
11558 ** and decode of the integers in a record header. It is faster for the common
11559 ** case where the integer is a single byte. It is a little slower when the
11560 ** integer is two or more bytes. But overall it is faster.
11562 ** The following expressions are equivalent:
11564 ** x = sqlite3GetVarint32( A, &B );
11565 ** x = sqlite3PutVarint32( A, B );
11567 ** x = getVarint32( A, B );
11568 ** x = putVarint32( A, B );
11571 #define getVarint32(A,B) (u8)((*(A)<(u8)0x80) ? ((B) = (u32)*(A)),1 : sqlite3GetVarint32((A), (u32 *)&(B)))
11572 #define putVarint32(A,B) (u8)(((u32)(B)<(u32)0x80) ? (*(A) = (unsigned char)(B)),1 : sqlite3PutVarint32((A), (B)))
11573 #define getVarint sqlite3GetVarint
11574 #define putVarint sqlite3PutVarint
11577 SQLITE_PRIVATE const char *sqlite3IndexAffinityStr(Vdbe *, Index *);
11578 SQLITE_PRIVATE void sqlite3TableAffinityStr(Vdbe *, Table *);
11579 SQLITE_PRIVATE char sqlite3CompareAffinity(Expr *pExpr, char aff2);
11580 SQLITE_PRIVATE int sqlite3IndexAffinityOk(Expr *pExpr, char idx_affinity);
11581 SQLITE_PRIVATE char sqlite3ExprAffinity(Expr *pExpr);
11582 SQLITE_PRIVATE int sqlite3Atoi64(const char*, i64*, int, u8);
11583 SQLITE_PRIVATE void sqlite3Error(sqlite3*, int, const char*,...);
11584 SQLITE_PRIVATE void *sqlite3HexToBlob(sqlite3*, const char *z, int n);
11585 SQLITE_PRIVATE u8 sqlite3HexToInt(int h);
11586 SQLITE_PRIVATE int sqlite3TwoPartName(Parse *, Token *, Token *, Token **);
11587 SQLITE_PRIVATE const char *sqlite3ErrStr(int);
11588 SQLITE_PRIVATE int sqlite3ReadSchema(Parse *pParse);
11589 SQLITE_PRIVATE CollSeq *sqlite3FindCollSeq(sqlite3*,u8 enc, const char*,int);
11590 SQLITE_PRIVATE CollSeq *sqlite3LocateCollSeq(Parse *pParse, const char*zName);
11591 SQLITE_PRIVATE CollSeq *sqlite3ExprCollSeq(Parse *pParse, Expr *pExpr);
11592 SQLITE_PRIVATE Expr *sqlite3ExprSetColl(Expr*, CollSeq*);
11593 SQLITE_PRIVATE Expr *sqlite3ExprSetCollByToken(Parse *pParse, Expr*, Token*);
11594 SQLITE_PRIVATE int sqlite3CheckCollSeq(Parse *, CollSeq *);
11595 SQLITE_PRIVATE int sqlite3CheckObjectName(Parse *, const char *);
11596 SQLITE_PRIVATE void sqlite3VdbeSetChanges(sqlite3 *, int);
11597 SQLITE_PRIVATE int sqlite3AddInt64(i64*,i64);
11598 SQLITE_PRIVATE int sqlite3SubInt64(i64*,i64);
11599 SQLITE_PRIVATE int sqlite3MulInt64(i64*,i64);
11600 SQLITE_PRIVATE int sqlite3AbsInt32(int);
11601 #ifdef SQLITE_ENABLE_8_3_NAMES
11602 SQLITE_PRIVATE void sqlite3FileSuffix3(const char*, char*);
11603 #else
11604 # define sqlite3FileSuffix3(X,Y)
11605 #endif
11606 SQLITE_PRIVATE u8 sqlite3GetBoolean(const char *z);
11608 SQLITE_PRIVATE const void *sqlite3ValueText(sqlite3_value*, u8);
11609 SQLITE_PRIVATE int sqlite3ValueBytes(sqlite3_value*, u8);
11610 SQLITE_PRIVATE void sqlite3ValueSetStr(sqlite3_value*, int, const void *,u8,
11611 void(*)(void*));
11612 SQLITE_PRIVATE void sqlite3ValueFree(sqlite3_value*);
11613 SQLITE_PRIVATE sqlite3_value *sqlite3ValueNew(sqlite3 *);
11614 SQLITE_PRIVATE char *sqlite3Utf16to8(sqlite3 *, const void*, int, u8);
11615 #ifdef SQLITE_ENABLE_STAT2
11616 SQLITE_PRIVATE char *sqlite3Utf8to16(sqlite3 *, u8, char *, int, int *);
11617 #endif
11618 SQLITE_PRIVATE int sqlite3ValueFromExpr(sqlite3 *, Expr *, u8, u8, sqlite3_value **);
11619 SQLITE_PRIVATE void sqlite3ValueApplyAffinity(sqlite3_value *, u8, u8);
11620 #ifndef SQLITE_AMALGAMATION
11621 SQLITE_PRIVATE const unsigned char sqlite3OpcodeProperty[];
11622 SQLITE_PRIVATE const unsigned char sqlite3UpperToLower[];
11623 SQLITE_PRIVATE const unsigned char sqlite3CtypeMap[];
11624 SQLITE_PRIVATE const Token sqlite3IntTokens[];
11625 SQLITE_PRIVATE SQLITE_WSD struct Sqlite3Config sqlite3Config;
11626 SQLITE_PRIVATE SQLITE_WSD FuncDefHash sqlite3GlobalFunctions;
11627 #ifndef SQLITE_OMIT_WSD
11628 SQLITE_PRIVATE int sqlite3PendingByte;
11629 #endif
11630 #endif
11631 SQLITE_PRIVATE void sqlite3RootPageMoved(sqlite3*, int, int, int);
11632 SQLITE_PRIVATE void sqlite3Reindex(Parse*, Token*, Token*);
11633 SQLITE_PRIVATE void sqlite3AlterFunctions(void);
11634 SQLITE_PRIVATE void sqlite3AlterRenameTable(Parse*, SrcList*, Token*);
11635 SQLITE_PRIVATE int sqlite3GetToken(const unsigned char *, int *);
11636 SQLITE_PRIVATE void sqlite3NestedParse(Parse*, const char*, ...);
11637 SQLITE_PRIVATE void sqlite3ExpirePreparedStatements(sqlite3*);
11638 SQLITE_PRIVATE int sqlite3CodeSubselect(Parse *, Expr *, int, int);
11639 SQLITE_PRIVATE void sqlite3SelectPrep(Parse*, Select*, NameContext*);
11640 SQLITE_PRIVATE int sqlite3ResolveExprNames(NameContext*, Expr*);
11641 SQLITE_PRIVATE void sqlite3ResolveSelectNames(Parse*, Select*, NameContext*);
11642 SQLITE_PRIVATE int sqlite3ResolveOrderGroupBy(Parse*, Select*, ExprList*, const char*);
11643 SQLITE_PRIVATE void sqlite3ColumnDefault(Vdbe *, Table *, int, int);
11644 SQLITE_PRIVATE void sqlite3AlterFinishAddColumn(Parse *, Token *);
11645 SQLITE_PRIVATE void sqlite3AlterBeginAddColumn(Parse *, SrcList *);
11646 SQLITE_PRIVATE CollSeq *sqlite3GetCollSeq(sqlite3*, u8, CollSeq *, const char*);
11647 SQLITE_PRIVATE char sqlite3AffinityType(const char*);
11648 SQLITE_PRIVATE void sqlite3Analyze(Parse*, Token*, Token*);
11649 SQLITE_PRIVATE int sqlite3InvokeBusyHandler(BusyHandler*);
11650 SQLITE_PRIVATE int sqlite3FindDb(sqlite3*, Token*);
11651 SQLITE_PRIVATE int sqlite3FindDbName(sqlite3 *, const char *);
11652 SQLITE_PRIVATE int sqlite3AnalysisLoad(sqlite3*,int iDB);
11653 SQLITE_PRIVATE void sqlite3DeleteIndexSamples(sqlite3*,Index*);
11654 SQLITE_PRIVATE void sqlite3DefaultRowEst(Index*);
11655 SQLITE_PRIVATE void sqlite3RegisterLikeFunctions(sqlite3*, int);
11656 SQLITE_PRIVATE int sqlite3IsLikeFunction(sqlite3*,Expr*,int*,char*);
11657 SQLITE_PRIVATE void sqlite3MinimumFileFormat(Parse*, int, int);
11658 SQLITE_PRIVATE void sqlite3SchemaClear(void *);
11659 SQLITE_PRIVATE Schema *sqlite3SchemaGet(sqlite3 *, Btree *);
11660 SQLITE_PRIVATE int sqlite3SchemaToIndex(sqlite3 *db, Schema *);
11661 SQLITE_PRIVATE KeyInfo *sqlite3IndexKeyinfo(Parse *, Index *);
11662 SQLITE_PRIVATE int sqlite3CreateFunc(sqlite3 *, const char *, int, int, void *,
11663 void (*)(sqlite3_context*,int,sqlite3_value **),
11664 void (*)(sqlite3_context*,int,sqlite3_value **), void (*)(sqlite3_context*),
11665 FuncDestructor *pDestructor
11667 SQLITE_PRIVATE int sqlite3ApiExit(sqlite3 *db, int);
11668 SQLITE_PRIVATE int sqlite3OpenTempDatabase(Parse *);
11670 SQLITE_PRIVATE void sqlite3StrAccumInit(StrAccum*, char*, int, int);
11671 SQLITE_PRIVATE void sqlite3StrAccumAppend(StrAccum*,const char*,int);
11672 SQLITE_PRIVATE char *sqlite3StrAccumFinish(StrAccum*);
11673 SQLITE_PRIVATE void sqlite3StrAccumReset(StrAccum*);
11674 SQLITE_PRIVATE void sqlite3SelectDestInit(SelectDest*,int,int);
11675 SQLITE_PRIVATE Expr *sqlite3CreateColumnExpr(sqlite3 *, SrcList *, int, int);
11677 SQLITE_PRIVATE void sqlite3BackupRestart(sqlite3_backup *);
11678 SQLITE_PRIVATE void sqlite3BackupUpdate(sqlite3_backup *, Pgno, const u8 *);
11681 ** The interface to the LEMON-generated parser
11683 SQLITE_PRIVATE void *sqlite3ParserAlloc(void*(*)(size_t));
11684 SQLITE_PRIVATE void sqlite3ParserFree(void*, void(*)(void*));
11685 SQLITE_PRIVATE void sqlite3Parser(void*, int, Token, Parse*);
11686 #ifdef YYTRACKMAXSTACKDEPTH
11687 SQLITE_PRIVATE int sqlite3ParserStackPeak(void*);
11688 #endif
11690 SQLITE_PRIVATE void sqlite3AutoLoadExtensions(sqlite3*);
11691 #ifndef SQLITE_OMIT_LOAD_EXTENSION
11692 SQLITE_PRIVATE void sqlite3CloseExtensions(sqlite3*);
11693 #else
11694 # define sqlite3CloseExtensions(X)
11695 #endif
11697 #ifndef SQLITE_OMIT_SHARED_CACHE
11698 SQLITE_PRIVATE void sqlite3TableLock(Parse *, int, int, u8, const char *);
11699 #else
11700 #define sqlite3TableLock(v,w,x,y,z)
11701 #endif
11703 #ifdef SQLITE_TEST
11704 SQLITE_PRIVATE int sqlite3Utf8To8(unsigned char*);
11705 #endif
11707 #ifdef SQLITE_OMIT_VIRTUALTABLE
11708 # define sqlite3VtabClear(Y)
11709 # define sqlite3VtabSync(X,Y) SQLITE_OK
11710 # define sqlite3VtabRollback(X)
11711 # define sqlite3VtabCommit(X)
11712 # define sqlite3VtabInSync(db) 0
11713 # define sqlite3VtabLock(X)
11714 # define sqlite3VtabUnlock(X)
11715 # define sqlite3VtabUnlockList(X)
11716 # define sqlite3VtabSavepoint(X, Y, Z) SQLITE_OK
11717 #else
11718 SQLITE_PRIVATE void sqlite3VtabClear(sqlite3 *db, Table*);
11719 SQLITE_PRIVATE int sqlite3VtabSync(sqlite3 *db, char **);
11720 SQLITE_PRIVATE int sqlite3VtabRollback(sqlite3 *db);
11721 SQLITE_PRIVATE int sqlite3VtabCommit(sqlite3 *db);
11722 SQLITE_PRIVATE void sqlite3VtabLock(VTable *);
11723 SQLITE_PRIVATE void sqlite3VtabUnlock(VTable *);
11724 SQLITE_PRIVATE void sqlite3VtabUnlockList(sqlite3*);
11725 SQLITE_PRIVATE int sqlite3VtabSavepoint(sqlite3 *, int, int);
11726 # define sqlite3VtabInSync(db) ((db)->nVTrans>0 && (db)->aVTrans==0)
11727 #endif
11728 SQLITE_PRIVATE void sqlite3VtabMakeWritable(Parse*,Table*);
11729 SQLITE_PRIVATE void sqlite3VtabBeginParse(Parse*, Token*, Token*, Token*);
11730 SQLITE_PRIVATE void sqlite3VtabFinishParse(Parse*, Token*);
11731 SQLITE_PRIVATE void sqlite3VtabArgInit(Parse*);
11732 SQLITE_PRIVATE void sqlite3VtabArgExtend(Parse*, Token*);
11733 SQLITE_PRIVATE int sqlite3VtabCallCreate(sqlite3*, int, const char *, char **);
11734 SQLITE_PRIVATE int sqlite3VtabCallConnect(Parse*, Table*);
11735 SQLITE_PRIVATE int sqlite3VtabCallDestroy(sqlite3*, int, const char *);
11736 SQLITE_PRIVATE int sqlite3VtabBegin(sqlite3 *, VTable *);
11737 SQLITE_PRIVATE FuncDef *sqlite3VtabOverloadFunction(sqlite3 *,FuncDef*, int nArg, Expr*);
11738 SQLITE_PRIVATE void sqlite3InvalidFunction(sqlite3_context*,int,sqlite3_value**);
11739 SQLITE_PRIVATE int sqlite3VdbeParameterIndex(Vdbe*, const char*, int);
11740 SQLITE_PRIVATE int sqlite3TransferBindings(sqlite3_stmt *, sqlite3_stmt *);
11741 SQLITE_PRIVATE int sqlite3Reprepare(Vdbe*);
11742 SQLITE_PRIVATE void sqlite3ExprListCheckLength(Parse*, ExprList*, const char*);
11743 SQLITE_PRIVATE CollSeq *sqlite3BinaryCompareCollSeq(Parse *, Expr *, Expr *);
11744 SQLITE_PRIVATE int sqlite3TempInMemory(const sqlite3*);
11745 SQLITE_PRIVATE VTable *sqlite3GetVTable(sqlite3*, Table*);
11746 SQLITE_PRIVATE const char *sqlite3JournalModename(int);
11747 SQLITE_PRIVATE int sqlite3Checkpoint(sqlite3*, int, int, int*, int*);
11748 SQLITE_PRIVATE int sqlite3WalDefaultHook(void*,sqlite3*,const char*,int);
11750 /* Declarations for functions in fkey.c. All of these are replaced by
11751 ** no-op macros if OMIT_FOREIGN_KEY is defined. In this case no foreign
11752 ** key functionality is available. If OMIT_TRIGGER is defined but
11753 ** OMIT_FOREIGN_KEY is not, only some of the functions are no-oped. In
11754 ** this case foreign keys are parsed, but no other functionality is
11755 ** provided (enforcement of FK constraints requires the triggers sub-system).
11757 #if !defined(SQLITE_OMIT_FOREIGN_KEY) && !defined(SQLITE_OMIT_TRIGGER)
11758 SQLITE_PRIVATE void sqlite3FkCheck(Parse*, Table*, int, int);
11759 SQLITE_PRIVATE void sqlite3FkDropTable(Parse*, SrcList *, Table*);
11760 SQLITE_PRIVATE void sqlite3FkActions(Parse*, Table*, ExprList*, int);
11761 SQLITE_PRIVATE int sqlite3FkRequired(Parse*, Table*, int*, int);
11762 SQLITE_PRIVATE u32 sqlite3FkOldmask(Parse*, Table*);
11763 SQLITE_PRIVATE FKey *sqlite3FkReferences(Table *);
11764 #else
11765 #define sqlite3FkActions(a,b,c,d)
11766 #define sqlite3FkCheck(a,b,c,d)
11767 #define sqlite3FkDropTable(a,b,c)
11768 #define sqlite3FkOldmask(a,b) 0
11769 #define sqlite3FkRequired(a,b,c,d) 0
11770 #endif
11771 #ifndef SQLITE_OMIT_FOREIGN_KEY
11772 SQLITE_PRIVATE void sqlite3FkDelete(sqlite3 *, Table*);
11773 #else
11774 #define sqlite3FkDelete(a,b)
11775 #endif
11779 ** Available fault injectors. Should be numbered beginning with 0.
11781 #define SQLITE_FAULTINJECTOR_MALLOC 0
11782 #define SQLITE_FAULTINJECTOR_COUNT 1
11785 ** The interface to the code in fault.c used for identifying "benign"
11786 ** malloc failures. This is only present if SQLITE_OMIT_BUILTIN_TEST
11787 ** is not defined.
11789 #ifndef SQLITE_OMIT_BUILTIN_TEST
11790 SQLITE_PRIVATE void sqlite3BeginBenignMalloc(void);
11791 SQLITE_PRIVATE void sqlite3EndBenignMalloc(void);
11792 #else
11793 #define sqlite3BeginBenignMalloc()
11794 #define sqlite3EndBenignMalloc()
11795 #endif
11797 #define IN_INDEX_ROWID 1
11798 #define IN_INDEX_EPH 2
11799 #define IN_INDEX_INDEX 3
11800 SQLITE_PRIVATE int sqlite3FindInIndex(Parse *, Expr *, int*);
11802 #ifdef SQLITE_ENABLE_ATOMIC_WRITE
11803 SQLITE_PRIVATE int sqlite3JournalOpen(sqlite3_vfs *, const char *, sqlite3_file *, int, int);
11804 SQLITE_PRIVATE int sqlite3JournalSize(sqlite3_vfs *);
11805 SQLITE_PRIVATE int sqlite3JournalCreate(sqlite3_file *);
11806 #else
11807 #define sqlite3JournalSize(pVfs) ((pVfs)->szOsFile)
11808 #endif
11810 SQLITE_PRIVATE void sqlite3MemJournalOpen(sqlite3_file *);
11811 SQLITE_PRIVATE int sqlite3MemJournalSize(void);
11812 SQLITE_PRIVATE int sqlite3IsMemJournal(sqlite3_file *);
11814 #if SQLITE_MAX_EXPR_DEPTH>0
11815 SQLITE_PRIVATE void sqlite3ExprSetHeight(Parse *pParse, Expr *p);
11816 SQLITE_PRIVATE int sqlite3SelectExprHeight(Select *);
11817 SQLITE_PRIVATE int sqlite3ExprCheckHeight(Parse*, int);
11818 #else
11819 #define sqlite3ExprSetHeight(x,y)
11820 #define sqlite3SelectExprHeight(x) 0
11821 #define sqlite3ExprCheckHeight(x,y)
11822 #endif
11824 SQLITE_PRIVATE u32 sqlite3Get4byte(const u8*);
11825 SQLITE_PRIVATE void sqlite3Put4byte(u8*, u32);
11827 #ifdef SQLITE_ENABLE_UNLOCK_NOTIFY
11828 SQLITE_PRIVATE void sqlite3ConnectionBlocked(sqlite3 *, sqlite3 *);
11829 SQLITE_PRIVATE void sqlite3ConnectionUnlocked(sqlite3 *db);
11830 SQLITE_PRIVATE void sqlite3ConnectionClosed(sqlite3 *db);
11831 #else
11832 #define sqlite3ConnectionBlocked(x,y)
11833 #define sqlite3ConnectionUnlocked(x)
11834 #define sqlite3ConnectionClosed(x)
11835 #endif
11837 #ifdef SQLITE_DEBUG
11838 SQLITE_PRIVATE void sqlite3ParserTrace(FILE*, char *);
11839 #endif
11842 ** If the SQLITE_ENABLE IOTRACE exists then the global variable
11843 ** sqlite3IoTrace is a pointer to a printf-like routine used to
11844 ** print I/O tracing messages.
11846 #ifdef SQLITE_ENABLE_IOTRACE
11847 # define IOTRACE(A) if( sqlite3IoTrace ){ sqlite3IoTrace A; }
11848 SQLITE_PRIVATE void sqlite3VdbeIOTraceSql(Vdbe*);
11849 SQLITE_PRIVATE void (*sqlite3IoTrace)(const char*,...);
11850 #else
11851 # define IOTRACE(A)
11852 # define sqlite3VdbeIOTraceSql(X)
11853 #endif
11856 ** These routines are available for the mem2.c debugging memory allocator
11857 ** only. They are used to verify that different "types" of memory
11858 ** allocations are properly tracked by the system.
11860 ** sqlite3MemdebugSetType() sets the "type" of an allocation to one of
11861 ** the MEMTYPE_* macros defined below. The type must be a bitmask with
11862 ** a single bit set.
11864 ** sqlite3MemdebugHasType() returns true if any of the bits in its second
11865 ** argument match the type set by the previous sqlite3MemdebugSetType().
11866 ** sqlite3MemdebugHasType() is intended for use inside assert() statements.
11868 ** sqlite3MemdebugNoType() returns true if none of the bits in its second
11869 ** argument match the type set by the previous sqlite3MemdebugSetType().
11871 ** Perhaps the most important point is the difference between MEMTYPE_HEAP
11872 ** and MEMTYPE_LOOKASIDE. If an allocation is MEMTYPE_LOOKASIDE, that means
11873 ** it might have been allocated by lookaside, except the allocation was
11874 ** too large or lookaside was already full. It is important to verify
11875 ** that allocations that might have been satisfied by lookaside are not
11876 ** passed back to non-lookaside free() routines. Asserts such as the
11877 ** example above are placed on the non-lookaside free() routines to verify
11878 ** this constraint.
11880 ** All of this is no-op for a production build. It only comes into
11881 ** play when the SQLITE_MEMDEBUG compile-time option is used.
11883 #ifdef SQLITE_MEMDEBUG
11884 SQLITE_PRIVATE void sqlite3MemdebugSetType(void*,u8);
11885 SQLITE_PRIVATE int sqlite3MemdebugHasType(void*,u8);
11886 SQLITE_PRIVATE int sqlite3MemdebugNoType(void*,u8);
11887 #else
11888 # define sqlite3MemdebugSetType(X,Y) /* no-op */
11889 # define sqlite3MemdebugHasType(X,Y) 1
11890 # define sqlite3MemdebugNoType(X,Y) 1
11891 #endif
11892 #define MEMTYPE_HEAP 0x01 /* General heap allocations */
11893 #define MEMTYPE_LOOKASIDE 0x02 /* Might have been lookaside memory */
11894 #define MEMTYPE_SCRATCH 0x04 /* Scratch allocations */
11895 #define MEMTYPE_PCACHE 0x08 /* Page cache allocations */
11896 #define MEMTYPE_DB 0x10 /* Uses sqlite3DbMalloc, not sqlite_malloc */
11898 #endif /* _SQLITEINT_H_ */
11900 /************** End of sqliteInt.h *******************************************/
11901 /************** Begin file global.c ******************************************/
11903 ** 2008 June 13
11905 ** The author disclaims copyright to this source code. In place of
11906 ** a legal notice, here is a blessing:
11908 ** May you do good and not evil.
11909 ** May you find forgiveness for yourself and forgive others.
11910 ** May you share freely, never taking more than you give.
11912 *************************************************************************
11914 ** This file contains definitions of global variables and contants.
11917 /* An array to map all upper-case characters into their corresponding
11918 ** lower-case character.
11920 ** SQLite only considers US-ASCII (or EBCDIC) characters. We do not
11921 ** handle case conversions for the UTF character set since the tables
11922 ** involved are nearly as big or bigger than SQLite itself.
11924 SQLITE_PRIVATE const unsigned char sqlite3UpperToLower[] = {
11925 #ifdef SQLITE_ASCII
11926 0, 1, 2, 3, 4, 5, 6, 7, 8, 9, 10, 11, 12, 13, 14, 15, 16, 17,
11927 18, 19, 20, 21, 22, 23, 24, 25, 26, 27, 28, 29, 30, 31, 32, 33, 34, 35,
11928 36, 37, 38, 39, 40, 41, 42, 43, 44, 45, 46, 47, 48, 49, 50, 51, 52, 53,
11929 54, 55, 56, 57, 58, 59, 60, 61, 62, 63, 64, 97, 98, 99,100,101,102,103,
11930 104,105,106,107,108,109,110,111,112,113,114,115,116,117,118,119,120,121,
11931 122, 91, 92, 93, 94, 95, 96, 97, 98, 99,100,101,102,103,104,105,106,107,
11932 108,109,110,111,112,113,114,115,116,117,118,119,120,121,122,123,124,125,
11933 126,127,128,129,130,131,132,133,134,135,136,137,138,139,140,141,142,143,
11934 144,145,146,147,148,149,150,151,152,153,154,155,156,157,158,159,160,161,
11935 162,163,164,165,166,167,168,169,170,171,172,173,174,175,176,177,178,179,
11936 180,181,182,183,184,185,186,187,188,189,190,191,192,193,194,195,196,197,
11937 198,199,200,201,202,203,204,205,206,207,208,209,210,211,212,213,214,215,
11938 216,217,218,219,220,221,222,223,224,225,226,227,228,229,230,231,232,233,
11939 234,235,236,237,238,239,240,241,242,243,244,245,246,247,248,249,250,251,
11940 252,253,254,255
11941 #endif
11942 #ifdef SQLITE_EBCDIC
11943 0, 1, 2, 3, 4, 5, 6, 7, 8, 9, 10, 11, 12, 13, 14, 15, /* 0x */
11944 16, 17, 18, 19, 20, 21, 22, 23, 24, 25, 26, 27, 28, 29, 30, 31, /* 1x */
11945 32, 33, 34, 35, 36, 37, 38, 39, 40, 41, 42, 43, 44, 45, 46, 47, /* 2x */
11946 48, 49, 50, 51, 52, 53, 54, 55, 56, 57, 58, 59, 60, 61, 62, 63, /* 3x */
11947 64, 65, 66, 67, 68, 69, 70, 71, 72, 73, 74, 75, 76, 77, 78, 79, /* 4x */
11948 80, 81, 82, 83, 84, 85, 86, 87, 88, 89, 90, 91, 92, 93, 94, 95, /* 5x */
11949 96, 97, 66, 67, 68, 69, 70, 71, 72, 73,106,107,108,109,110,111, /* 6x */
11950 112, 81, 82, 83, 84, 85, 86, 87, 88, 89,122,123,124,125,126,127, /* 7x */
11951 128,129,130,131,132,133,134,135,136,137,138,139,140,141,142,143, /* 8x */
11952 144,145,146,147,148,149,150,151,152,153,154,155,156,157,156,159, /* 9x */
11953 160,161,162,163,164,165,166,167,168,169,170,171,140,141,142,175, /* Ax */
11954 176,177,178,179,180,181,182,183,184,185,186,187,188,189,190,191, /* Bx */
11955 192,129,130,131,132,133,134,135,136,137,202,203,204,205,206,207, /* Cx */
11956 208,145,146,147,148,149,150,151,152,153,218,219,220,221,222,223, /* Dx */
11957 224,225,162,163,164,165,166,167,168,169,232,203,204,205,206,207, /* Ex */
11958 239,240,241,242,243,244,245,246,247,248,249,219,220,221,222,255, /* Fx */
11959 #endif
11963 ** The following 256 byte lookup table is used to support SQLites built-in
11964 ** equivalents to the following standard library functions:
11966 ** isspace() 0x01
11967 ** isalpha() 0x02
11968 ** isdigit() 0x04
11969 ** isalnum() 0x06
11970 ** isxdigit() 0x08
11971 ** toupper() 0x20
11972 ** SQLite identifier character 0x40
11974 ** Bit 0x20 is set if the mapped character requires translation to upper
11975 ** case. i.e. if the character is a lower-case ASCII character.
11976 ** If x is a lower-case ASCII character, then its upper-case equivalent
11977 ** is (x - 0x20). Therefore toupper() can be implemented as:
11979 ** (x & ~(map[x]&0x20))
11981 ** Standard function tolower() is implemented using the sqlite3UpperToLower[]
11982 ** array. tolower() is used more often than toupper() by SQLite.
11984 ** Bit 0x40 is set if the character non-alphanumeric and can be used in an
11985 ** SQLite identifier. Identifiers are alphanumerics, "_", "$", and any
11986 ** non-ASCII UTF character. Hence the test for whether or not a character is
11987 ** part of an identifier is 0x46.
11989 ** SQLite's versions are identical to the standard versions assuming a
11990 ** locale of "C". They are implemented as macros in sqliteInt.h.
11992 #ifdef SQLITE_ASCII
11993 SQLITE_PRIVATE const unsigned char sqlite3CtypeMap[256] = {
11994 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, /* 00..07 ........ */
11995 0x00, 0x01, 0x01, 0x01, 0x01, 0x01, 0x00, 0x00, /* 08..0f ........ */
11996 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, /* 10..17 ........ */
11997 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, /* 18..1f ........ */
11998 0x01, 0x00, 0x00, 0x00, 0x40, 0x00, 0x00, 0x00, /* 20..27 !"#$%&' */
11999 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, /* 28..2f ()*+,-./ */
12000 0x0c, 0x0c, 0x0c, 0x0c, 0x0c, 0x0c, 0x0c, 0x0c, /* 30..37 01234567 */
12001 0x0c, 0x0c, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, /* 38..3f 89:;<=>? */
12003 0x00, 0x0a, 0x0a, 0x0a, 0x0a, 0x0a, 0x0a, 0x02, /* 40..47 @ABCDEFG */
12004 0x02, 0x02, 0x02, 0x02, 0x02, 0x02, 0x02, 0x02, /* 48..4f HIJKLMNO */
12005 0x02, 0x02, 0x02, 0x02, 0x02, 0x02, 0x02, 0x02, /* 50..57 PQRSTUVW */
12006 0x02, 0x02, 0x02, 0x00, 0x00, 0x00, 0x00, 0x40, /* 58..5f XYZ[\]^_ */
12007 0x00, 0x2a, 0x2a, 0x2a, 0x2a, 0x2a, 0x2a, 0x22, /* 60..67 `abcdefg */
12008 0x22, 0x22, 0x22, 0x22, 0x22, 0x22, 0x22, 0x22, /* 68..6f hijklmno */
12009 0x22, 0x22, 0x22, 0x22, 0x22, 0x22, 0x22, 0x22, /* 70..77 pqrstuvw */
12010 0x22, 0x22, 0x22, 0x00, 0x00, 0x00, 0x00, 0x00, /* 78..7f xyz{|}~. */
12012 0x40, 0x40, 0x40, 0x40, 0x40, 0x40, 0x40, 0x40, /* 80..87 ........ */
12013 0x40, 0x40, 0x40, 0x40, 0x40, 0x40, 0x40, 0x40, /* 88..8f ........ */
12014 0x40, 0x40, 0x40, 0x40, 0x40, 0x40, 0x40, 0x40, /* 90..97 ........ */
12015 0x40, 0x40, 0x40, 0x40, 0x40, 0x40, 0x40, 0x40, /* 98..9f ........ */
12016 0x40, 0x40, 0x40, 0x40, 0x40, 0x40, 0x40, 0x40, /* a0..a7 ........ */
12017 0x40, 0x40, 0x40, 0x40, 0x40, 0x40, 0x40, 0x40, /* a8..af ........ */
12018 0x40, 0x40, 0x40, 0x40, 0x40, 0x40, 0x40, 0x40, /* b0..b7 ........ */
12019 0x40, 0x40, 0x40, 0x40, 0x40, 0x40, 0x40, 0x40, /* b8..bf ........ */
12021 0x40, 0x40, 0x40, 0x40, 0x40, 0x40, 0x40, 0x40, /* c0..c7 ........ */
12022 0x40, 0x40, 0x40, 0x40, 0x40, 0x40, 0x40, 0x40, /* c8..cf ........ */
12023 0x40, 0x40, 0x40, 0x40, 0x40, 0x40, 0x40, 0x40, /* d0..d7 ........ */
12024 0x40, 0x40, 0x40, 0x40, 0x40, 0x40, 0x40, 0x40, /* d8..df ........ */
12025 0x40, 0x40, 0x40, 0x40, 0x40, 0x40, 0x40, 0x40, /* e0..e7 ........ */
12026 0x40, 0x40, 0x40, 0x40, 0x40, 0x40, 0x40, 0x40, /* e8..ef ........ */
12027 0x40, 0x40, 0x40, 0x40, 0x40, 0x40, 0x40, 0x40, /* f0..f7 ........ */
12028 0x40, 0x40, 0x40, 0x40, 0x40, 0x40, 0x40, 0x40 /* f8..ff ........ */
12030 #endif
12032 #ifndef SQLITE_USE_URI
12033 # define SQLITE_USE_URI 0
12034 #endif
12037 ** The following singleton contains the global configuration for
12038 ** the SQLite library.
12040 SQLITE_PRIVATE SQLITE_WSD struct Sqlite3Config sqlite3Config = {
12041 SQLITE_DEFAULT_MEMSTATUS, /* bMemstat */
12042 1, /* bCoreMutex */
12043 SQLITE_THREADSAFE==1, /* bFullMutex */
12044 SQLITE_USE_URI, /* bOpenUri */
12045 0x7ffffffe, /* mxStrlen */
12046 128, /* szLookaside */
12047 500, /* nLookaside */
12048 {0,0,0,0,0,0,0,0}, /* m */
12049 {0,0,0,0,0,0,0,0,0}, /* mutex */
12050 {0,0,0,0,0,0,0,0,0,0,0}, /* pcache */
12051 (void*)0, /* pHeap */
12052 0, /* nHeap */
12053 0, 0, /* mnHeap, mxHeap */
12054 (void*)0, /* pScratch */
12055 0, /* szScratch */
12056 0, /* nScratch */
12057 (void*)0, /* pPage */
12058 0, /* szPage */
12059 0, /* nPage */
12060 0, /* mxParserStack */
12061 0, /* sharedCacheEnabled */
12062 /* All the rest should always be initialized to zero */
12063 0, /* isInit */
12064 0, /* inProgress */
12065 0, /* isMutexInit */
12066 0, /* isMallocInit */
12067 0, /* isPCacheInit */
12068 0, /* pInitMutex */
12069 0, /* nRefInitMutex */
12070 0, /* xLog */
12071 0, /* pLogArg */
12072 0, /* bLocaltimeFault */
12077 ** Hash table for global functions - functions common to all
12078 ** database connections. After initialization, this table is
12079 ** read-only.
12081 SQLITE_PRIVATE SQLITE_WSD FuncDefHash sqlite3GlobalFunctions;
12084 ** Constant tokens for values 0 and 1.
12086 SQLITE_PRIVATE const Token sqlite3IntTokens[] = {
12087 { "0", 1 },
12088 { "1", 1 }
12093 ** The value of the "pending" byte must be 0x40000000 (1 byte past the
12094 ** 1-gibabyte boundary) in a compatible database. SQLite never uses
12095 ** the database page that contains the pending byte. It never attempts
12096 ** to read or write that page. The pending byte page is set assign
12097 ** for use by the VFS layers as space for managing file locks.
12099 ** During testing, it is often desirable to move the pending byte to
12100 ** a different position in the file. This allows code that has to
12101 ** deal with the pending byte to run on files that are much smaller
12102 ** than 1 GiB. The sqlite3_test_control() interface can be used to
12103 ** move the pending byte.
12105 ** IMPORTANT: Changing the pending byte to any value other than
12106 ** 0x40000000 results in an incompatible database file format!
12107 ** Changing the pending byte during operating results in undefined
12108 ** and dileterious behavior.
12110 #ifndef SQLITE_OMIT_WSD
12111 SQLITE_PRIVATE int sqlite3PendingByte = 0x40000000;
12112 #endif
12115 ** Properties of opcodes. The OPFLG_INITIALIZER macro is
12116 ** created by mkopcodeh.awk during compilation. Data is obtained
12117 ** from the comments following the "case OP_xxxx:" statements in
12118 ** the vdbe.c file.
12120 SQLITE_PRIVATE const unsigned char sqlite3OpcodeProperty[] = OPFLG_INITIALIZER;
12122 /************** End of global.c **********************************************/
12123 /************** Begin file ctime.c *******************************************/
12125 ** 2010 February 23
12127 ** The author disclaims copyright to this source code. In place of
12128 ** a legal notice, here is a blessing:
12130 ** May you do good and not evil.
12131 ** May you find forgiveness for yourself and forgive others.
12132 ** May you share freely, never taking more than you give.
12134 *************************************************************************
12136 ** This file implements routines used to report what compile-time options
12137 ** SQLite was built with.
12140 #ifndef SQLITE_OMIT_COMPILEOPTION_DIAGS
12144 ** An array of names of all compile-time options. This array should
12145 ** be sorted A-Z.
12147 ** This array looks large, but in a typical installation actually uses
12148 ** only a handful of compile-time options, so most times this array is usually
12149 ** rather short and uses little memory space.
12151 static const char * const azCompileOpt[] = {
12153 /* These macros are provided to "stringify" the value of the define
12154 ** for those options in which the value is meaningful. */
12155 #define CTIMEOPT_VAL_(opt) #opt
12156 #define CTIMEOPT_VAL(opt) CTIMEOPT_VAL_(opt)
12158 #ifdef SQLITE_32BIT_ROWID
12159 "32BIT_ROWID",
12160 #endif
12161 #ifdef SQLITE_4_BYTE_ALIGNED_MALLOC
12162 "4_BYTE_ALIGNED_MALLOC",
12163 #endif
12164 #ifdef SQLITE_CASE_SENSITIVE_LIKE
12165 "CASE_SENSITIVE_LIKE",
12166 #endif
12167 #ifdef SQLITE_CHECK_PAGES
12168 "CHECK_PAGES",
12169 #endif
12170 #ifdef SQLITE_COVERAGE_TEST
12171 "COVERAGE_TEST",
12172 #endif
12173 #ifdef SQLITE_DEBUG
12174 "DEBUG",
12175 #endif
12176 #ifdef SQLITE_DEFAULT_LOCKING_MODE
12177 "DEFAULT_LOCKING_MODE=" CTIMEOPT_VAL(SQLITE_DEFAULT_LOCKING_MODE),
12178 #endif
12179 #ifdef SQLITE_DISABLE_DIRSYNC
12180 "DISABLE_DIRSYNC",
12181 #endif
12182 #ifdef SQLITE_DISABLE_LFS
12183 "DISABLE_LFS",
12184 #endif
12185 #ifdef SQLITE_ENABLE_ATOMIC_WRITE
12186 "ENABLE_ATOMIC_WRITE",
12187 #endif
12188 #ifdef SQLITE_ENABLE_CEROD
12189 "ENABLE_CEROD",
12190 #endif
12191 #ifdef SQLITE_ENABLE_COLUMN_METADATA
12192 "ENABLE_COLUMN_METADATA",
12193 #endif
12194 #ifdef SQLITE_ENABLE_EXPENSIVE_ASSERT
12195 "ENABLE_EXPENSIVE_ASSERT",
12196 #endif
12197 #ifdef SQLITE_ENABLE_FTS1
12198 "ENABLE_FTS1",
12199 #endif
12200 #ifdef SQLITE_ENABLE_FTS2
12201 "ENABLE_FTS2",
12202 #endif
12203 #ifdef SQLITE_ENABLE_FTS3
12204 "ENABLE_FTS3",
12205 #endif
12206 #ifdef SQLITE_ENABLE_FTS3_PARENTHESIS
12207 "ENABLE_FTS3_PARENTHESIS",
12208 #endif
12209 #ifdef SQLITE_ENABLE_FTS4
12210 "ENABLE_FTS4",
12211 #endif
12212 #ifdef SQLITE_ENABLE_ICU
12213 "ENABLE_ICU",
12214 #endif
12215 #ifdef SQLITE_ENABLE_IOTRACE
12216 "ENABLE_IOTRACE",
12217 #endif
12218 #ifdef SQLITE_ENABLE_LOAD_EXTENSION
12219 "ENABLE_LOAD_EXTENSION",
12220 #endif
12221 #ifdef SQLITE_ENABLE_LOCKING_STYLE
12222 "ENABLE_LOCKING_STYLE=" CTIMEOPT_VAL(SQLITE_ENABLE_LOCKING_STYLE),
12223 #endif
12224 #ifdef SQLITE_ENABLE_MEMORY_MANAGEMENT
12225 "ENABLE_MEMORY_MANAGEMENT",
12226 #endif
12227 #ifdef SQLITE_ENABLE_MEMSYS3
12228 "ENABLE_MEMSYS3",
12229 #endif
12230 #ifdef SQLITE_ENABLE_MEMSYS5
12231 "ENABLE_MEMSYS5",
12232 #endif
12233 #ifdef SQLITE_ENABLE_OVERSIZE_CELL_CHECK
12234 "ENABLE_OVERSIZE_CELL_CHECK",
12235 #endif
12236 #ifdef SQLITE_ENABLE_RTREE
12237 "ENABLE_RTREE",
12238 #endif
12239 #ifdef SQLITE_ENABLE_STAT2
12240 "ENABLE_STAT2",
12241 #endif
12242 #ifdef SQLITE_ENABLE_UNLOCK_NOTIFY
12243 "ENABLE_UNLOCK_NOTIFY",
12244 #endif
12245 #ifdef SQLITE_ENABLE_UPDATE_DELETE_LIMIT
12246 "ENABLE_UPDATE_DELETE_LIMIT",
12247 #endif
12248 #ifdef SQLITE_HAS_CODEC
12249 "HAS_CODEC",
12250 #endif
12251 #ifdef SQLITE_HAVE_ISNAN
12252 "HAVE_ISNAN",
12253 #endif
12254 #ifdef SQLITE_HOMEGROWN_RECURSIVE_MUTEX
12255 "HOMEGROWN_RECURSIVE_MUTEX",
12256 #endif
12257 #ifdef SQLITE_IGNORE_AFP_LOCK_ERRORS
12258 "IGNORE_AFP_LOCK_ERRORS",
12259 #endif
12260 #ifdef SQLITE_IGNORE_FLOCK_LOCK_ERRORS
12261 "IGNORE_FLOCK_LOCK_ERRORS",
12262 #endif
12263 #ifdef SQLITE_INT64_TYPE
12264 "INT64_TYPE",
12265 #endif
12266 #ifdef SQLITE_LOCK_TRACE
12267 "LOCK_TRACE",
12268 #endif
12269 #ifdef SQLITE_MAX_SCHEMA_RETRY
12270 "MAX_SCHEMA_RETRY=" CTIMEOPT_VAL(SQLITE_MAX_SCHEMA_RETRY),
12271 #endif
12272 #ifdef SQLITE_MEMDEBUG
12273 "MEMDEBUG",
12274 #endif
12275 #ifdef SQLITE_MIXED_ENDIAN_64BIT_FLOAT
12276 "MIXED_ENDIAN_64BIT_FLOAT",
12277 #endif
12278 #ifdef SQLITE_NO_SYNC
12279 "NO_SYNC",
12280 #endif
12281 #ifdef SQLITE_OMIT_ALTERTABLE
12282 "OMIT_ALTERTABLE",
12283 #endif
12284 #ifdef SQLITE_OMIT_ANALYZE
12285 "OMIT_ANALYZE",
12286 #endif
12287 #ifdef SQLITE_OMIT_ATTACH
12288 "OMIT_ATTACH",
12289 #endif
12290 #ifdef SQLITE_OMIT_AUTHORIZATION
12291 "OMIT_AUTHORIZATION",
12292 #endif
12293 #ifdef SQLITE_OMIT_AUTOINCREMENT
12294 "OMIT_AUTOINCREMENT",
12295 #endif
12296 #ifdef SQLITE_OMIT_AUTOINIT
12297 "OMIT_AUTOINIT",
12298 #endif
12299 #ifdef SQLITE_OMIT_AUTOMATIC_INDEX
12300 "OMIT_AUTOMATIC_INDEX",
12301 #endif
12302 #ifdef SQLITE_OMIT_AUTORESET
12303 "OMIT_AUTORESET",
12304 #endif
12305 #ifdef SQLITE_OMIT_AUTOVACUUM
12306 "OMIT_AUTOVACUUM",
12307 #endif
12308 #ifdef SQLITE_OMIT_BETWEEN_OPTIMIZATION
12309 "OMIT_BETWEEN_OPTIMIZATION",
12310 #endif
12311 #ifdef SQLITE_OMIT_BLOB_LITERAL
12312 "OMIT_BLOB_LITERAL",
12313 #endif
12314 #ifdef SQLITE_OMIT_BTREECOUNT
12315 "OMIT_BTREECOUNT",
12316 #endif
12317 #ifdef SQLITE_OMIT_BUILTIN_TEST
12318 "OMIT_BUILTIN_TEST",
12319 #endif
12320 #ifdef SQLITE_OMIT_CAST
12321 "OMIT_CAST",
12322 #endif
12323 #ifdef SQLITE_OMIT_CHECK
12324 "OMIT_CHECK",
12325 #endif
12326 /* // redundant
12327 ** #ifdef SQLITE_OMIT_COMPILEOPTION_DIAGS
12328 ** "OMIT_COMPILEOPTION_DIAGS",
12329 ** #endif
12331 #ifdef SQLITE_OMIT_COMPLETE
12332 "OMIT_COMPLETE",
12333 #endif
12334 #ifdef SQLITE_OMIT_COMPOUND_SELECT
12335 "OMIT_COMPOUND_SELECT",
12336 #endif
12337 #ifdef SQLITE_OMIT_DATETIME_FUNCS
12338 "OMIT_DATETIME_FUNCS",
12339 #endif
12340 #ifdef SQLITE_OMIT_DECLTYPE
12341 "OMIT_DECLTYPE",
12342 #endif
12343 #ifdef SQLITE_OMIT_DEPRECATED
12344 "OMIT_DEPRECATED",
12345 #endif
12346 #ifdef SQLITE_OMIT_DISKIO
12347 "OMIT_DISKIO",
12348 #endif
12349 #ifdef SQLITE_OMIT_EXPLAIN
12350 "OMIT_EXPLAIN",
12351 #endif
12352 #ifdef SQLITE_OMIT_FLAG_PRAGMAS
12353 "OMIT_FLAG_PRAGMAS",
12354 #endif
12355 #ifdef SQLITE_OMIT_FLOATING_POINT
12356 "OMIT_FLOATING_POINT",
12357 #endif
12358 #ifdef SQLITE_OMIT_FOREIGN_KEY
12359 "OMIT_FOREIGN_KEY",
12360 #endif
12361 #ifdef SQLITE_OMIT_GET_TABLE
12362 "OMIT_GET_TABLE",
12363 #endif
12364 #ifdef SQLITE_OMIT_INCRBLOB
12365 "OMIT_INCRBLOB",
12366 #endif
12367 #ifdef SQLITE_OMIT_INTEGRITY_CHECK
12368 "OMIT_INTEGRITY_CHECK",
12369 #endif
12370 #ifdef SQLITE_OMIT_LIKE_OPTIMIZATION
12371 "OMIT_LIKE_OPTIMIZATION",
12372 #endif
12373 #ifdef SQLITE_OMIT_LOAD_EXTENSION
12374 "OMIT_LOAD_EXTENSION",
12375 #endif
12376 #ifdef SQLITE_OMIT_LOCALTIME
12377 "OMIT_LOCALTIME",
12378 #endif
12379 #ifdef SQLITE_OMIT_LOOKASIDE
12380 "OMIT_LOOKASIDE",
12381 #endif
12382 #ifdef SQLITE_OMIT_MEMORYDB
12383 "OMIT_MEMORYDB",
12384 #endif
12385 #ifdef SQLITE_OMIT_MERGE_SORT
12386 "OMIT_MERGE_SORT",
12387 #endif
12388 #ifdef SQLITE_OMIT_OR_OPTIMIZATION
12389 "OMIT_OR_OPTIMIZATION",
12390 #endif
12391 #ifdef SQLITE_OMIT_PAGER_PRAGMAS
12392 "OMIT_PAGER_PRAGMAS",
12393 #endif
12394 #ifdef SQLITE_OMIT_PRAGMA
12395 "OMIT_PRAGMA",
12396 #endif
12397 #ifdef SQLITE_OMIT_PROGRESS_CALLBACK
12398 "OMIT_PROGRESS_CALLBACK",
12399 #endif
12400 #ifdef SQLITE_OMIT_QUICKBALANCE
12401 "OMIT_QUICKBALANCE",
12402 #endif
12403 #ifdef SQLITE_OMIT_REINDEX
12404 "OMIT_REINDEX",
12405 #endif
12406 #ifdef SQLITE_OMIT_SCHEMA_PRAGMAS
12407 "OMIT_SCHEMA_PRAGMAS",
12408 #endif
12409 #ifdef SQLITE_OMIT_SCHEMA_VERSION_PRAGMAS
12410 "OMIT_SCHEMA_VERSION_PRAGMAS",
12411 #endif
12412 #ifdef SQLITE_OMIT_SHARED_CACHE
12413 "OMIT_SHARED_CACHE",
12414 #endif
12415 #ifdef SQLITE_OMIT_SUBQUERY
12416 "OMIT_SUBQUERY",
12417 #endif
12418 #ifdef SQLITE_OMIT_TCL_VARIABLE
12419 "OMIT_TCL_VARIABLE",
12420 #endif
12421 #ifdef SQLITE_OMIT_TEMPDB
12422 "OMIT_TEMPDB",
12423 #endif
12424 #ifdef SQLITE_OMIT_TRACE
12425 "OMIT_TRACE",
12426 #endif
12427 #ifdef SQLITE_OMIT_TRIGGER
12428 "OMIT_TRIGGER",
12429 #endif
12430 #ifdef SQLITE_OMIT_TRUNCATE_OPTIMIZATION
12431 "OMIT_TRUNCATE_OPTIMIZATION",
12432 #endif
12433 #ifdef SQLITE_OMIT_UTF16
12434 "OMIT_UTF16",
12435 #endif
12436 #ifdef SQLITE_OMIT_VACUUM
12437 "OMIT_VACUUM",
12438 #endif
12439 #ifdef SQLITE_OMIT_VIEW
12440 "OMIT_VIEW",
12441 #endif
12442 #ifdef SQLITE_OMIT_VIRTUALTABLE
12443 "OMIT_VIRTUALTABLE",
12444 #endif
12445 #ifdef SQLITE_OMIT_WAL
12446 "OMIT_WAL",
12447 #endif
12448 #ifdef SQLITE_OMIT_WSD
12449 "OMIT_WSD",
12450 #endif
12451 #ifdef SQLITE_OMIT_XFER_OPT
12452 "OMIT_XFER_OPT",
12453 #endif
12454 #ifdef SQLITE_PAGECACHE_BLOCKALLOC
12455 "PAGECACHE_BLOCKALLOC",
12456 #endif
12457 #ifdef SQLITE_PERFORMANCE_TRACE
12458 "PERFORMANCE_TRACE",
12459 #endif
12460 #ifdef SQLITE_PROXY_DEBUG
12461 "PROXY_DEBUG",
12462 #endif
12463 #ifdef SQLITE_SECURE_DELETE
12464 "SECURE_DELETE",
12465 #endif
12466 #ifdef SQLITE_SMALL_STACK
12467 "SMALL_STACK",
12468 #endif
12469 #ifdef SQLITE_SOUNDEX
12470 "SOUNDEX",
12471 #endif
12472 #ifdef SQLITE_TCL
12473 "TCL",
12474 #endif
12475 #ifdef SQLITE_TEMP_STORE
12476 "TEMP_STORE=" CTIMEOPT_VAL(SQLITE_TEMP_STORE),
12477 #endif
12478 #ifdef SQLITE_TEST
12479 "TEST",
12480 #endif
12481 #ifdef SQLITE_THREADSAFE
12482 "THREADSAFE=" CTIMEOPT_VAL(SQLITE_THREADSAFE),
12483 #endif
12484 #ifdef SQLITE_USE_ALLOCA
12485 "USE_ALLOCA",
12486 #endif
12487 #ifdef SQLITE_ZERO_MALLOC
12488 "ZERO_MALLOC"
12489 #endif
12493 ** Given the name of a compile-time option, return true if that option
12494 ** was used and false if not.
12496 ** The name can optionally begin with "SQLITE_" but the "SQLITE_" prefix
12497 ** is not required for a match.
12499 SQLITE_API int sqlite3_compileoption_used(const char *zOptName){
12500 int i, n;
12501 if( sqlite3StrNICmp(zOptName, "SQLITE_", 7)==0 ) zOptName += 7;
12502 n = sqlite3Strlen30(zOptName);
12504 /* Since ArraySize(azCompileOpt) is normally in single digits, a
12505 ** linear search is adequate. No need for a binary search. */
12506 for(i=0; i<ArraySize(azCompileOpt); i++){
12507 if( (sqlite3StrNICmp(zOptName, azCompileOpt[i], n)==0)
12508 && ( (azCompileOpt[i][n]==0) || (azCompileOpt[i][n]=='=') ) ) return 1;
12510 return 0;
12514 ** Return the N-th compile-time option string. If N is out of range,
12515 ** return a NULL pointer.
12517 SQLITE_API const char *sqlite3_compileoption_get(int N){
12518 if( N>=0 && N<ArraySize(azCompileOpt) ){
12519 return azCompileOpt[N];
12521 return 0;
12524 #endif /* SQLITE_OMIT_COMPILEOPTION_DIAGS */
12526 /************** End of ctime.c ***********************************************/
12527 /************** Begin file status.c ******************************************/
12529 ** 2008 June 18
12531 ** The author disclaims copyright to this source code. In place of
12532 ** a legal notice, here is a blessing:
12534 ** May you do good and not evil.
12535 ** May you find forgiveness for yourself and forgive others.
12536 ** May you share freely, never taking more than you give.
12538 *************************************************************************
12540 ** This module implements the sqlite3_status() interface and related
12541 ** functionality.
12543 /************** Include vdbeInt.h in the middle of status.c ******************/
12544 /************** Begin file vdbeInt.h *****************************************/
12546 ** 2003 September 6
12548 ** The author disclaims copyright to this source code. In place of
12549 ** a legal notice, here is a blessing:
12551 ** May you do good and not evil.
12552 ** May you find forgiveness for yourself and forgive others.
12553 ** May you share freely, never taking more than you give.
12555 *************************************************************************
12556 ** This is the header file for information that is private to the
12557 ** VDBE. This information used to all be at the top of the single
12558 ** source code file "vdbe.c". When that file became too big (over
12559 ** 6000 lines long) it was split up into several smaller files and
12560 ** this header information was factored out.
12562 #ifndef _VDBEINT_H_
12563 #define _VDBEINT_H_
12566 ** SQL is translated into a sequence of instructions to be
12567 ** executed by a virtual machine. Each instruction is an instance
12568 ** of the following structure.
12570 typedef struct VdbeOp Op;
12573 ** Boolean values
12575 typedef unsigned char Bool;
12577 /* Opaque type used by code in vdbesort.c */
12578 typedef struct VdbeSorter VdbeSorter;
12581 ** A cursor is a pointer into a single BTree within a database file.
12582 ** The cursor can seek to a BTree entry with a particular key, or
12583 ** loop over all entries of the Btree. You can also insert new BTree
12584 ** entries or retrieve the key or data from the entry that the cursor
12585 ** is currently pointing to.
12587 ** Every cursor that the virtual machine has open is represented by an
12588 ** instance of the following structure.
12590 struct VdbeCursor {
12591 BtCursor *pCursor; /* The cursor structure of the backend */
12592 Btree *pBt; /* Separate file holding temporary table */
12593 KeyInfo *pKeyInfo; /* Info about index keys needed by index cursors */
12594 int iDb; /* Index of cursor database in db->aDb[] (or -1) */
12595 int pseudoTableReg; /* Register holding pseudotable content. */
12596 int nField; /* Number of fields in the header */
12597 Bool zeroed; /* True if zeroed out and ready for reuse */
12598 Bool rowidIsValid; /* True if lastRowid is valid */
12599 Bool atFirst; /* True if pointing to first entry */
12600 Bool useRandomRowid; /* Generate new record numbers semi-randomly */
12601 Bool nullRow; /* True if pointing to a row with no data */
12602 Bool deferredMoveto; /* A call to sqlite3BtreeMoveto() is needed */
12603 Bool isTable; /* True if a table requiring integer keys */
12604 Bool isIndex; /* True if an index containing keys only - no data */
12605 Bool isOrdered; /* True if the underlying table is BTREE_UNORDERED */
12606 Bool isSorter; /* True if a new-style sorter */
12607 sqlite3_vtab_cursor *pVtabCursor; /* The cursor for a virtual table */
12608 const sqlite3_module *pModule; /* Module for cursor pVtabCursor */
12609 i64 seqCount; /* Sequence counter */
12610 i64 movetoTarget; /* Argument to the deferred sqlite3BtreeMoveto() */
12611 i64 lastRowid; /* Last rowid from a Next or NextIdx operation */
12612 VdbeSorter *pSorter; /* Sorter object for OP_SorterOpen cursors */
12614 /* Result of last sqlite3BtreeMoveto() done by an OP_NotExists or
12615 ** OP_IsUnique opcode on this cursor. */
12616 int seekResult;
12618 /* Cached information about the header for the data record that the
12619 ** cursor is currently pointing to. Only valid if cacheStatus matches
12620 ** Vdbe.cacheCtr. Vdbe.cacheCtr will never take on the value of
12621 ** CACHE_STALE and so setting cacheStatus=CACHE_STALE guarantees that
12622 ** the cache is out of date.
12624 ** aRow might point to (ephemeral) data for the current row, or it might
12625 ** be NULL.
12627 u32 cacheStatus; /* Cache is valid if this matches Vdbe.cacheCtr */
12628 int payloadSize; /* Total number of bytes in the record */
12629 u32 *aType; /* Type values for all entries in the record */
12630 u32 *aOffset; /* Cached offsets to the start of each columns data */
12631 u8 *aRow; /* Data for the current row, if all on one page */
12633 typedef struct VdbeCursor VdbeCursor;
12636 ** When a sub-program is executed (OP_Program), a structure of this type
12637 ** is allocated to store the current value of the program counter, as
12638 ** well as the current memory cell array and various other frame specific
12639 ** values stored in the Vdbe struct. When the sub-program is finished,
12640 ** these values are copied back to the Vdbe from the VdbeFrame structure,
12641 ** restoring the state of the VM to as it was before the sub-program
12642 ** began executing.
12644 ** The memory for a VdbeFrame object is allocated and managed by a memory
12645 ** cell in the parent (calling) frame. When the memory cell is deleted or
12646 ** overwritten, the VdbeFrame object is not freed immediately. Instead, it
12647 ** is linked into the Vdbe.pDelFrame list. The contents of the Vdbe.pDelFrame
12648 ** list is deleted when the VM is reset in VdbeHalt(). The reason for doing
12649 ** this instead of deleting the VdbeFrame immediately is to avoid recursive
12650 ** calls to sqlite3VdbeMemRelease() when the memory cells belonging to the
12651 ** child frame are released.
12653 ** The currently executing frame is stored in Vdbe.pFrame. Vdbe.pFrame is
12654 ** set to NULL if the currently executing frame is the main program.
12656 typedef struct VdbeFrame VdbeFrame;
12657 struct VdbeFrame {
12658 Vdbe *v; /* VM this frame belongs to */
12659 int pc; /* Program Counter in parent (calling) frame */
12660 Op *aOp; /* Program instructions for parent frame */
12661 int nOp; /* Size of aOp array */
12662 Mem *aMem; /* Array of memory cells for parent frame */
12663 int nMem; /* Number of entries in aMem */
12664 VdbeCursor **apCsr; /* Array of Vdbe cursors for parent frame */
12665 u16 nCursor; /* Number of entries in apCsr */
12666 void *token; /* Copy of SubProgram.token */
12667 int nChildMem; /* Number of memory cells for child frame */
12668 int nChildCsr; /* Number of cursors for child frame */
12669 i64 lastRowid; /* Last insert rowid (sqlite3.lastRowid) */
12670 int nChange; /* Statement changes (Vdbe.nChanges) */
12671 VdbeFrame *pParent; /* Parent of this frame, or NULL if parent is main */
12674 #define VdbeFrameMem(p) ((Mem *)&((u8 *)p)[ROUND8(sizeof(VdbeFrame))])
12677 ** A value for VdbeCursor.cacheValid that means the cache is always invalid.
12679 #define CACHE_STALE 0
12682 ** Internally, the vdbe manipulates nearly all SQL values as Mem
12683 ** structures. Each Mem struct may cache multiple representations (string,
12684 ** integer etc.) of the same value.
12686 struct Mem {
12687 sqlite3 *db; /* The associated database connection */
12688 char *z; /* String or BLOB value */
12689 double r; /* Real value */
12690 union {
12691 i64 i; /* Integer value used when MEM_Int is set in flags */
12692 int nZero; /* Used when bit MEM_Zero is set in flags */
12693 FuncDef *pDef; /* Used only when flags==MEM_Agg */
12694 RowSet *pRowSet; /* Used only when flags==MEM_RowSet */
12695 VdbeFrame *pFrame; /* Used when flags==MEM_Frame */
12696 } u;
12697 int n; /* Number of characters in string value, excluding '\0' */
12698 u16 flags; /* Some combination of MEM_Null, MEM_Str, MEM_Dyn, etc. */
12699 u8 type; /* One of SQLITE_NULL, SQLITE_TEXT, SQLITE_INTEGER, etc */
12700 u8 enc; /* SQLITE_UTF8, SQLITE_UTF16BE, SQLITE_UTF16LE */
12701 #ifdef SQLITE_DEBUG
12702 Mem *pScopyFrom; /* This Mem is a shallow copy of pScopyFrom */
12703 void *pFiller; /* So that sizeof(Mem) is a multiple of 8 */
12704 #endif
12705 void (*xDel)(void *); /* If not null, call this function to delete Mem.z */
12706 char *zMalloc; /* Dynamic buffer allocated by sqlite3_malloc() */
12709 /* One or more of the following flags are set to indicate the validOK
12710 ** representations of the value stored in the Mem struct.
12712 ** If the MEM_Null flag is set, then the value is an SQL NULL value.
12713 ** No other flags may be set in this case.
12715 ** If the MEM_Str flag is set then Mem.z points at a string representation.
12716 ** Usually this is encoded in the same unicode encoding as the main
12717 ** database (see below for exceptions). If the MEM_Term flag is also
12718 ** set, then the string is nul terminated. The MEM_Int and MEM_Real
12719 ** flags may coexist with the MEM_Str flag.
12721 #define MEM_Null 0x0001 /* Value is NULL */
12722 #define MEM_Str 0x0002 /* Value is a string */
12723 #define MEM_Int 0x0004 /* Value is an integer */
12724 #define MEM_Real 0x0008 /* Value is a real number */
12725 #define MEM_Blob 0x0010 /* Value is a BLOB */
12726 #define MEM_RowSet 0x0020 /* Value is a RowSet object */
12727 #define MEM_Frame 0x0040 /* Value is a VdbeFrame object */
12728 #define MEM_Invalid 0x0080 /* Value is undefined */
12729 #define MEM_TypeMask 0x00ff /* Mask of type bits */
12731 /* Whenever Mem contains a valid string or blob representation, one of
12732 ** the following flags must be set to determine the memory management
12733 ** policy for Mem.z. The MEM_Term flag tells us whether or not the
12734 ** string is \000 or \u0000 terminated
12736 #define MEM_Term 0x0200 /* String rep is nul terminated */
12737 #define MEM_Dyn 0x0400 /* Need to call sqliteFree() on Mem.z */
12738 #define MEM_Static 0x0800 /* Mem.z points to a static string */
12739 #define MEM_Ephem 0x1000 /* Mem.z points to an ephemeral string */
12740 #define MEM_Agg 0x2000 /* Mem.z points to an agg function context */
12741 #define MEM_Zero 0x4000 /* Mem.i contains count of 0s appended to blob */
12742 #ifdef SQLITE_OMIT_INCRBLOB
12743 #undef MEM_Zero
12744 #define MEM_Zero 0x0000
12745 #endif
12748 ** Clear any existing type flags from a Mem and replace them with f
12750 #define MemSetTypeFlag(p, f) \
12751 ((p)->flags = ((p)->flags&~(MEM_TypeMask|MEM_Zero))|f)
12754 ** Return true if a memory cell is not marked as invalid. This macro
12755 ** is for use inside assert() statements only.
12757 #ifdef SQLITE_DEBUG
12758 #define memIsValid(M) ((M)->flags & MEM_Invalid)==0
12759 #endif
12762 /* A VdbeFunc is just a FuncDef (defined in sqliteInt.h) that contains
12763 ** additional information about auxiliary information bound to arguments
12764 ** of the function. This is used to implement the sqlite3_get_auxdata()
12765 ** and sqlite3_set_auxdata() APIs. The "auxdata" is some auxiliary data
12766 ** that can be associated with a constant argument to a function. This
12767 ** allows functions such as "regexp" to compile their constant regular
12768 ** expression argument once and reused the compiled code for multiple
12769 ** invocations.
12771 struct VdbeFunc {
12772 FuncDef *pFunc; /* The definition of the function */
12773 int nAux; /* Number of entries allocated for apAux[] */
12774 struct AuxData {
12775 void *pAux; /* Aux data for the i-th argument */
12776 void (*xDelete)(void *); /* Destructor for the aux data */
12777 } apAux[1]; /* One slot for each function argument */
12781 ** The "context" argument for a installable function. A pointer to an
12782 ** instance of this structure is the first argument to the routines used
12783 ** implement the SQL functions.
12785 ** There is a typedef for this structure in sqlite.h. So all routines,
12786 ** even the public interface to SQLite, can use a pointer to this structure.
12787 ** But this file is the only place where the internal details of this
12788 ** structure are known.
12790 ** This structure is defined inside of vdbeInt.h because it uses substructures
12791 ** (Mem) which are only defined there.
12793 struct sqlite3_context {
12794 FuncDef *pFunc; /* Pointer to function information. MUST BE FIRST */
12795 VdbeFunc *pVdbeFunc; /* Auxilary data, if created. */
12796 Mem s; /* The return value is stored here */
12797 Mem *pMem; /* Memory cell used to store aggregate context */
12798 int isError; /* Error code returned by the function. */
12799 CollSeq *pColl; /* Collating sequence */
12803 ** An instance of the virtual machine. This structure contains the complete
12804 ** state of the virtual machine.
12806 ** The "sqlite3_stmt" structure pointer that is returned by sqlite3_prepare()
12807 ** is really a pointer to an instance of this structure.
12809 ** The Vdbe.inVtabMethod variable is set to non-zero for the duration of
12810 ** any virtual table method invocations made by the vdbe program. It is
12811 ** set to 2 for xDestroy method calls and 1 for all other methods. This
12812 ** variable is used for two purposes: to allow xDestroy methods to execute
12813 ** "DROP TABLE" statements and to prevent some nasty side effects of
12814 ** malloc failure when SQLite is invoked recursively by a virtual table
12815 ** method function.
12817 struct Vdbe {
12818 sqlite3 *db; /* The database connection that owns this statement */
12819 Op *aOp; /* Space to hold the virtual machine's program */
12820 Mem *aMem; /* The memory locations */
12821 Mem **apArg; /* Arguments to currently executing user function */
12822 Mem *aColName; /* Column names to return */
12823 Mem *pResultSet; /* Pointer to an array of results */
12824 int nMem; /* Number of memory locations currently allocated */
12825 int nOp; /* Number of instructions in the program */
12826 int nOpAlloc; /* Number of slots allocated for aOp[] */
12827 int nLabel; /* Number of labels used */
12828 int nLabelAlloc; /* Number of slots allocated in aLabel[] */
12829 int *aLabel; /* Space to hold the labels */
12830 u16 nResColumn; /* Number of columns in one row of the result set */
12831 u16 nCursor; /* Number of slots in apCsr[] */
12832 u32 magic; /* Magic number for sanity checking */
12833 char *zErrMsg; /* Error message written here */
12834 Vdbe *pPrev,*pNext; /* Linked list of VDBEs with the same Vdbe.db */
12835 VdbeCursor **apCsr; /* One element of this array for each open cursor */
12836 Mem *aVar; /* Values for the OP_Variable opcode. */
12837 char **azVar; /* Name of variables */
12838 ynVar nVar; /* Number of entries in aVar[] */
12839 ynVar nzVar; /* Number of entries in azVar[] */
12840 u32 cacheCtr; /* VdbeCursor row cache generation counter */
12841 int pc; /* The program counter */
12842 int rc; /* Value to return */
12843 u8 errorAction; /* Recovery action to do in case of an error */
12844 u8 explain; /* True if EXPLAIN present on SQL command */
12845 u8 changeCntOn; /* True to update the change-counter */
12846 u8 expired; /* True if the VM needs to be recompiled */
12847 u8 runOnlyOnce; /* Automatically expire on reset */
12848 u8 minWriteFileFormat; /* Minimum file format for writable database files */
12849 u8 inVtabMethod; /* See comments above */
12850 u8 usesStmtJournal; /* True if uses a statement journal */
12851 u8 readOnly; /* True for read-only statements */
12852 u8 isPrepareV2; /* True if prepared with prepare_v2() */
12853 int nChange; /* Number of db changes made since last reset */
12854 yDbMask btreeMask; /* Bitmask of db->aDb[] entries referenced */
12855 yDbMask lockMask; /* Subset of btreeMask that requires a lock */
12856 int iStatement; /* Statement number (or 0 if has not opened stmt) */
12857 int aCounter[3]; /* Counters used by sqlite3_stmt_status() */
12858 #ifndef SQLITE_OMIT_TRACE
12859 i64 startTime; /* Time when query started - used for profiling */
12860 #endif
12861 i64 nFkConstraint; /* Number of imm. FK constraints this VM */
12862 i64 nStmtDefCons; /* Number of def. constraints when stmt started */
12863 char *zSql; /* Text of the SQL statement that generated this */
12864 void *pFree; /* Free this when deleting the vdbe */
12865 #ifdef SQLITE_DEBUG
12866 FILE *trace; /* Write an execution trace here, if not NULL */
12867 #endif
12868 VdbeFrame *pFrame; /* Parent frame */
12869 VdbeFrame *pDelFrame; /* List of frame objects to free on VM reset */
12870 int nFrame; /* Number of frames in pFrame list */
12871 u32 expmask; /* Binding to these vars invalidates VM */
12872 SubProgram *pProgram; /* Linked list of all sub-programs used by VM */
12876 ** The following are allowed values for Vdbe.magic
12878 #define VDBE_MAGIC_INIT 0x26bceaa5 /* Building a VDBE program */
12879 #define VDBE_MAGIC_RUN 0xbdf20da3 /* VDBE is ready to execute */
12880 #define VDBE_MAGIC_HALT 0x519c2973 /* VDBE has completed execution */
12881 #define VDBE_MAGIC_DEAD 0xb606c3c8 /* The VDBE has been deallocated */
12884 ** Function prototypes
12886 SQLITE_PRIVATE void sqlite3VdbeFreeCursor(Vdbe *, VdbeCursor*);
12887 void sqliteVdbePopStack(Vdbe*,int);
12888 SQLITE_PRIVATE int sqlite3VdbeCursorMoveto(VdbeCursor*);
12889 #if defined(SQLITE_DEBUG) || defined(VDBE_PROFILE)
12890 SQLITE_PRIVATE void sqlite3VdbePrintOp(FILE*, int, Op*);
12891 #endif
12892 SQLITE_PRIVATE u32 sqlite3VdbeSerialTypeLen(u32);
12893 SQLITE_PRIVATE u32 sqlite3VdbeSerialType(Mem*, int);
12894 SQLITE_PRIVATE u32 sqlite3VdbeSerialPut(unsigned char*, int, Mem*, int);
12895 SQLITE_PRIVATE u32 sqlite3VdbeSerialGet(const unsigned char*, u32, Mem*);
12896 SQLITE_PRIVATE void sqlite3VdbeDeleteAuxData(VdbeFunc*, int);
12898 int sqlite2BtreeKeyCompare(BtCursor *, const void *, int, int, int *);
12899 SQLITE_PRIVATE int sqlite3VdbeIdxKeyCompare(VdbeCursor*,UnpackedRecord*,int*);
12900 SQLITE_PRIVATE int sqlite3VdbeIdxRowid(sqlite3*, BtCursor *, i64 *);
12901 SQLITE_PRIVATE int sqlite3MemCompare(const Mem*, const Mem*, const CollSeq*);
12902 SQLITE_PRIVATE int sqlite3VdbeExec(Vdbe*);
12903 SQLITE_PRIVATE int sqlite3VdbeList(Vdbe*);
12904 SQLITE_PRIVATE int sqlite3VdbeHalt(Vdbe*);
12905 SQLITE_PRIVATE int sqlite3VdbeChangeEncoding(Mem *, int);
12906 SQLITE_PRIVATE int sqlite3VdbeMemTooBig(Mem*);
12907 SQLITE_PRIVATE int sqlite3VdbeMemCopy(Mem*, const Mem*);
12908 SQLITE_PRIVATE void sqlite3VdbeMemShallowCopy(Mem*, const Mem*, int);
12909 SQLITE_PRIVATE void sqlite3VdbeMemMove(Mem*, Mem*);
12910 SQLITE_PRIVATE int sqlite3VdbeMemNulTerminate(Mem*);
12911 SQLITE_PRIVATE int sqlite3VdbeMemSetStr(Mem*, const char*, int, u8, void(*)(void*));
12912 SQLITE_PRIVATE void sqlite3VdbeMemSetInt64(Mem*, i64);
12913 #ifdef SQLITE_OMIT_FLOATING_POINT
12914 # define sqlite3VdbeMemSetDouble sqlite3VdbeMemSetInt64
12915 #else
12916 SQLITE_PRIVATE void sqlite3VdbeMemSetDouble(Mem*, double);
12917 #endif
12918 SQLITE_PRIVATE void sqlite3VdbeMemSetNull(Mem*);
12919 SQLITE_PRIVATE void sqlite3VdbeMemSetZeroBlob(Mem*,int);
12920 SQLITE_PRIVATE void sqlite3VdbeMemSetRowSet(Mem*);
12921 SQLITE_PRIVATE int sqlite3VdbeMemMakeWriteable(Mem*);
12922 SQLITE_PRIVATE int sqlite3VdbeMemStringify(Mem*, int);
12923 SQLITE_PRIVATE i64 sqlite3VdbeIntValue(Mem*);
12924 SQLITE_PRIVATE int sqlite3VdbeMemIntegerify(Mem*);
12925 SQLITE_PRIVATE double sqlite3VdbeRealValue(Mem*);
12926 SQLITE_PRIVATE void sqlite3VdbeIntegerAffinity(Mem*);
12927 SQLITE_PRIVATE int sqlite3VdbeMemRealify(Mem*);
12928 SQLITE_PRIVATE int sqlite3VdbeMemNumerify(Mem*);
12929 SQLITE_PRIVATE int sqlite3VdbeMemFromBtree(BtCursor*,int,int,int,Mem*);
12930 SQLITE_PRIVATE void sqlite3VdbeMemRelease(Mem *p);
12931 SQLITE_PRIVATE void sqlite3VdbeMemReleaseExternal(Mem *p);
12932 #define MemReleaseExt(X) \
12933 if((X)->flags&(MEM_Agg|MEM_Dyn|MEM_RowSet|MEM_Frame)) \
12934 sqlite3VdbeMemReleaseExternal(X);
12935 SQLITE_PRIVATE int sqlite3VdbeMemFinalize(Mem*, FuncDef*);
12936 SQLITE_PRIVATE const char *sqlite3OpcodeName(int);
12937 SQLITE_PRIVATE int sqlite3VdbeMemGrow(Mem *pMem, int n, int preserve);
12938 SQLITE_PRIVATE int sqlite3VdbeCloseStatement(Vdbe *, int);
12939 SQLITE_PRIVATE void sqlite3VdbeFrameDelete(VdbeFrame*);
12940 SQLITE_PRIVATE int sqlite3VdbeFrameRestore(VdbeFrame *);
12941 SQLITE_PRIVATE void sqlite3VdbeMemStoreType(Mem *pMem);
12943 #ifdef SQLITE_OMIT_MERGE_SORT
12944 # define sqlite3VdbeSorterInit(Y,Z) SQLITE_OK
12945 # define sqlite3VdbeSorterWrite(X,Y,Z) SQLITE_OK
12946 # define sqlite3VdbeSorterClose(Y,Z)
12947 # define sqlite3VdbeSorterRowkey(Y,Z) SQLITE_OK
12948 # define sqlite3VdbeSorterRewind(X,Y,Z) SQLITE_OK
12949 # define sqlite3VdbeSorterNext(X,Y,Z) SQLITE_OK
12950 # define sqlite3VdbeSorterCompare(X,Y,Z) SQLITE_OK
12951 #else
12952 SQLITE_PRIVATE int sqlite3VdbeSorterInit(sqlite3 *, VdbeCursor *);
12953 SQLITE_PRIVATE void sqlite3VdbeSorterClose(sqlite3 *, VdbeCursor *);
12954 SQLITE_PRIVATE int sqlite3VdbeSorterRowkey(VdbeCursor *, Mem *);
12955 SQLITE_PRIVATE int sqlite3VdbeSorterNext(sqlite3 *, VdbeCursor *, int *);
12956 SQLITE_PRIVATE int sqlite3VdbeSorterRewind(sqlite3 *, VdbeCursor *, int *);
12957 SQLITE_PRIVATE int sqlite3VdbeSorterWrite(sqlite3 *, VdbeCursor *, Mem *);
12958 SQLITE_PRIVATE int sqlite3VdbeSorterCompare(VdbeCursor *, Mem *, int *);
12959 #endif
12961 #if !defined(SQLITE_OMIT_SHARED_CACHE) && SQLITE_THREADSAFE>0
12962 SQLITE_PRIVATE void sqlite3VdbeEnter(Vdbe*);
12963 SQLITE_PRIVATE void sqlite3VdbeLeave(Vdbe*);
12964 #else
12965 # define sqlite3VdbeEnter(X)
12966 # define sqlite3VdbeLeave(X)
12967 #endif
12969 #ifdef SQLITE_DEBUG
12970 SQLITE_PRIVATE void sqlite3VdbeMemPrepareToChange(Vdbe*,Mem*);
12971 #endif
12973 #ifndef SQLITE_OMIT_FOREIGN_KEY
12974 SQLITE_PRIVATE int sqlite3VdbeCheckFk(Vdbe *, int);
12975 #else
12976 # define sqlite3VdbeCheckFk(p,i) 0
12977 #endif
12979 SQLITE_PRIVATE int sqlite3VdbeMemTranslate(Mem*, u8);
12980 #ifdef SQLITE_DEBUG
12981 SQLITE_PRIVATE void sqlite3VdbePrintSql(Vdbe*);
12982 SQLITE_PRIVATE void sqlite3VdbeMemPrettyPrint(Mem *pMem, char *zBuf);
12983 #endif
12984 SQLITE_PRIVATE int sqlite3VdbeMemHandleBom(Mem *pMem);
12986 #ifndef SQLITE_OMIT_INCRBLOB
12987 SQLITE_PRIVATE int sqlite3VdbeMemExpandBlob(Mem *);
12988 #else
12989 #define sqlite3VdbeMemExpandBlob(x) SQLITE_OK
12990 #endif
12992 #endif /* !defined(_VDBEINT_H_) */
12994 /************** End of vdbeInt.h *********************************************/
12995 /************** Continuing where we left off in status.c *********************/
12998 ** Variables in which to record status information.
13000 typedef struct sqlite3StatType sqlite3StatType;
13001 static SQLITE_WSD struct sqlite3StatType {
13002 int nowValue[10]; /* Current value */
13003 int mxValue[10]; /* Maximum value */
13004 } sqlite3Stat = { {0,}, {0,} };
13007 /* The "wsdStat" macro will resolve to the status information
13008 ** state vector. If writable static data is unsupported on the target,
13009 ** we have to locate the state vector at run-time. In the more common
13010 ** case where writable static data is supported, wsdStat can refer directly
13011 ** to the "sqlite3Stat" state vector declared above.
13013 #ifdef SQLITE_OMIT_WSD
13014 # define wsdStatInit sqlite3StatType *x = &GLOBAL(sqlite3StatType,sqlite3Stat)
13015 # define wsdStat x[0]
13016 #else
13017 # define wsdStatInit
13018 # define wsdStat sqlite3Stat
13019 #endif
13022 ** Return the current value of a status parameter.
13024 SQLITE_PRIVATE int sqlite3StatusValue(int op){
13025 wsdStatInit;
13026 assert( op>=0 && op<ArraySize(wsdStat.nowValue) );
13027 return wsdStat.nowValue[op];
13031 ** Add N to the value of a status record. It is assumed that the
13032 ** caller holds appropriate locks.
13034 SQLITE_PRIVATE void sqlite3StatusAdd(int op, int N){
13035 wsdStatInit;
13036 assert( op>=0 && op<ArraySize(wsdStat.nowValue) );
13037 wsdStat.nowValue[op] += N;
13038 if( wsdStat.nowValue[op]>wsdStat.mxValue[op] ){
13039 wsdStat.mxValue[op] = wsdStat.nowValue[op];
13044 ** Set the value of a status to X.
13046 SQLITE_PRIVATE void sqlite3StatusSet(int op, int X){
13047 wsdStatInit;
13048 assert( op>=0 && op<ArraySize(wsdStat.nowValue) );
13049 wsdStat.nowValue[op] = X;
13050 if( wsdStat.nowValue[op]>wsdStat.mxValue[op] ){
13051 wsdStat.mxValue[op] = wsdStat.nowValue[op];
13056 ** Query status information.
13058 ** This implementation assumes that reading or writing an aligned
13059 ** 32-bit integer is an atomic operation. If that assumption is not true,
13060 ** then this routine is not threadsafe.
13062 SQLITE_API int sqlite3_status(int op, int *pCurrent, int *pHighwater, int resetFlag){
13063 wsdStatInit;
13064 if( op<0 || op>=ArraySize(wsdStat.nowValue) ){
13065 return SQLITE_MISUSE_BKPT;
13067 *pCurrent = wsdStat.nowValue[op];
13068 *pHighwater = wsdStat.mxValue[op];
13069 if( resetFlag ){
13070 wsdStat.mxValue[op] = wsdStat.nowValue[op];
13072 return SQLITE_OK;
13076 ** Query status information for a single database connection
13078 SQLITE_API int sqlite3_db_status(
13079 sqlite3 *db, /* The database connection whose status is desired */
13080 int op, /* Status verb */
13081 int *pCurrent, /* Write current value here */
13082 int *pHighwater, /* Write high-water mark here */
13083 int resetFlag /* Reset high-water mark if true */
13085 int rc = SQLITE_OK; /* Return code */
13086 sqlite3_mutex_enter(db->mutex);
13087 switch( op ){
13088 case SQLITE_DBSTATUS_LOOKASIDE_USED: {
13089 *pCurrent = db->lookaside.nOut;
13090 *pHighwater = db->lookaside.mxOut;
13091 if( resetFlag ){
13092 db->lookaside.mxOut = db->lookaside.nOut;
13094 break;
13097 case SQLITE_DBSTATUS_LOOKASIDE_HIT:
13098 case SQLITE_DBSTATUS_LOOKASIDE_MISS_SIZE:
13099 case SQLITE_DBSTATUS_LOOKASIDE_MISS_FULL: {
13100 testcase( op==SQLITE_DBSTATUS_LOOKASIDE_HIT );
13101 testcase( op==SQLITE_DBSTATUS_LOOKASIDE_MISS_SIZE );
13102 testcase( op==SQLITE_DBSTATUS_LOOKASIDE_MISS_FULL );
13103 assert( (op-SQLITE_DBSTATUS_LOOKASIDE_HIT)>=0 );
13104 assert( (op-SQLITE_DBSTATUS_LOOKASIDE_HIT)<3 );
13105 *pCurrent = 0;
13106 *pHighwater = db->lookaside.anStat[op - SQLITE_DBSTATUS_LOOKASIDE_HIT];
13107 if( resetFlag ){
13108 db->lookaside.anStat[op - SQLITE_DBSTATUS_LOOKASIDE_HIT] = 0;
13110 break;
13114 ** Return an approximation for the amount of memory currently used
13115 ** by all pagers associated with the given database connection. The
13116 ** highwater mark is meaningless and is returned as zero.
13118 case SQLITE_DBSTATUS_CACHE_USED: {
13119 int totalUsed = 0;
13120 int i;
13121 sqlite3BtreeEnterAll(db);
13122 for(i=0; i<db->nDb; i++){
13123 Btree *pBt = db->aDb[i].pBt;
13124 if( pBt ){
13125 Pager *pPager = sqlite3BtreePager(pBt);
13126 totalUsed += sqlite3PagerMemUsed(pPager);
13129 sqlite3BtreeLeaveAll(db);
13130 *pCurrent = totalUsed;
13131 *pHighwater = 0;
13132 break;
13136 ** *pCurrent gets an accurate estimate of the amount of memory used
13137 ** to store the schema for all databases (main, temp, and any ATTACHed
13138 ** databases. *pHighwater is set to zero.
13140 case SQLITE_DBSTATUS_SCHEMA_USED: {
13141 int i; /* Used to iterate through schemas */
13142 int nByte = 0; /* Used to accumulate return value */
13144 sqlite3BtreeEnterAll(db);
13145 db->pnBytesFreed = &nByte;
13146 for(i=0; i<db->nDb; i++){
13147 Schema *pSchema = db->aDb[i].pSchema;
13148 if( ALWAYS(pSchema!=0) ){
13149 HashElem *p;
13151 nByte += sqlite3GlobalConfig.m.xRoundup(sizeof(HashElem)) * (
13152 pSchema->tblHash.count
13153 + pSchema->trigHash.count
13154 + pSchema->idxHash.count
13155 + pSchema->fkeyHash.count
13157 nByte += sqlite3MallocSize(pSchema->tblHash.ht);
13158 nByte += sqlite3MallocSize(pSchema->trigHash.ht);
13159 nByte += sqlite3MallocSize(pSchema->idxHash.ht);
13160 nByte += sqlite3MallocSize(pSchema->fkeyHash.ht);
13162 for(p=sqliteHashFirst(&pSchema->trigHash); p; p=sqliteHashNext(p)){
13163 sqlite3DeleteTrigger(db, (Trigger*)sqliteHashData(p));
13165 for(p=sqliteHashFirst(&pSchema->tblHash); p; p=sqliteHashNext(p)){
13166 sqlite3DeleteTable(db, (Table *)sqliteHashData(p));
13170 db->pnBytesFreed = 0;
13171 sqlite3BtreeLeaveAll(db);
13173 *pHighwater = 0;
13174 *pCurrent = nByte;
13175 break;
13179 ** *pCurrent gets an accurate estimate of the amount of memory used
13180 ** to store all prepared statements.
13181 ** *pHighwater is set to zero.
13183 case SQLITE_DBSTATUS_STMT_USED: {
13184 struct Vdbe *pVdbe; /* Used to iterate through VMs */
13185 int nByte = 0; /* Used to accumulate return value */
13187 db->pnBytesFreed = &nByte;
13188 for(pVdbe=db->pVdbe; pVdbe; pVdbe=pVdbe->pNext){
13189 sqlite3VdbeDeleteObject(db, pVdbe);
13191 db->pnBytesFreed = 0;
13193 *pHighwater = 0;
13194 *pCurrent = nByte;
13196 break;
13199 default: {
13200 rc = SQLITE_ERROR;
13203 sqlite3_mutex_leave(db->mutex);
13204 return rc;
13207 /************** End of status.c **********************************************/
13208 /************** Begin file date.c ********************************************/
13210 ** 2003 October 31
13212 ** The author disclaims copyright to this source code. In place of
13213 ** a legal notice, here is a blessing:
13215 ** May you do good and not evil.
13216 ** May you find forgiveness for yourself and forgive others.
13217 ** May you share freely, never taking more than you give.
13219 *************************************************************************
13220 ** This file contains the C functions that implement date and time
13221 ** functions for SQLite.
13223 ** There is only one exported symbol in this file - the function
13224 ** sqlite3RegisterDateTimeFunctions() found at the bottom of the file.
13225 ** All other code has file scope.
13227 ** SQLite processes all times and dates as Julian Day numbers. The
13228 ** dates and times are stored as the number of days since noon
13229 ** in Greenwich on November 24, 4714 B.C. according to the Gregorian
13230 ** calendar system.
13232 ** 1970-01-01 00:00:00 is JD 2440587.5
13233 ** 2000-01-01 00:00:00 is JD 2451544.5
13235 ** This implemention requires years to be expressed as a 4-digit number
13236 ** which means that only dates between 0000-01-01 and 9999-12-31 can
13237 ** be represented, even though julian day numbers allow a much wider
13238 ** range of dates.
13240 ** The Gregorian calendar system is used for all dates and times,
13241 ** even those that predate the Gregorian calendar. Historians usually
13242 ** use the Julian calendar for dates prior to 1582-10-15 and for some
13243 ** dates afterwards, depending on locale. Beware of this difference.
13245 ** The conversion algorithms are implemented based on descriptions
13246 ** in the following text:
13248 ** Jean Meeus
13249 ** Astronomical Algorithms, 2nd Edition, 1998
13250 ** ISBM 0-943396-61-1
13251 ** Willmann-Bell, Inc
13252 ** Richmond, Virginia (USA)
13254 /* #include <stdlib.h> */
13255 /* #include <assert.h> */
13256 #include <time.h>
13258 #ifndef SQLITE_OMIT_DATETIME_FUNCS
13262 ** A structure for holding a single date and time.
13264 typedef struct DateTime DateTime;
13265 struct DateTime {
13266 sqlite3_int64 iJD; /* The julian day number times 86400000 */
13267 int Y, M, D; /* Year, month, and day */
13268 int h, m; /* Hour and minutes */
13269 int tz; /* Timezone offset in minutes */
13270 double s; /* Seconds */
13271 char validYMD; /* True (1) if Y,M,D are valid */
13272 char validHMS; /* True (1) if h,m,s are valid */
13273 char validJD; /* True (1) if iJD is valid */
13274 char validTZ; /* True (1) if tz is valid */
13279 ** Convert zDate into one or more integers. Additional arguments
13280 ** come in groups of 5 as follows:
13282 ** N number of digits in the integer
13283 ** min minimum allowed value of the integer
13284 ** max maximum allowed value of the integer
13285 ** nextC first character after the integer
13286 ** pVal where to write the integers value.
13288 ** Conversions continue until one with nextC==0 is encountered.
13289 ** The function returns the number of successful conversions.
13291 static int getDigits(const char *zDate, ...){
13292 va_list ap;
13293 int val;
13294 int N;
13295 int min;
13296 int max;
13297 int nextC;
13298 int *pVal;
13299 int cnt = 0;
13300 va_start(ap, zDate);
13302 N = va_arg(ap, int);
13303 min = va_arg(ap, int);
13304 max = va_arg(ap, int);
13305 nextC = va_arg(ap, int);
13306 pVal = va_arg(ap, int*);
13307 val = 0;
13308 while( N-- ){
13309 if( !sqlite3Isdigit(*zDate) ){
13310 goto end_getDigits;
13312 val = val*10 + *zDate - '0';
13313 zDate++;
13315 if( val<min || val>max || (nextC!=0 && nextC!=*zDate) ){
13316 goto end_getDigits;
13318 *pVal = val;
13319 zDate++;
13320 cnt++;
13321 }while( nextC );
13322 end_getDigits:
13323 va_end(ap);
13324 return cnt;
13328 ** Parse a timezone extension on the end of a date-time.
13329 ** The extension is of the form:
13331 ** (+/-)HH:MM
13333 ** Or the "zulu" notation:
13335 ** Z
13337 ** If the parse is successful, write the number of minutes
13338 ** of change in p->tz and return 0. If a parser error occurs,
13339 ** return non-zero.
13341 ** A missing specifier is not considered an error.
13343 static int parseTimezone(const char *zDate, DateTime *p){
13344 int sgn = 0;
13345 int nHr, nMn;
13346 int c;
13347 while( sqlite3Isspace(*zDate) ){ zDate++; }
13348 p->tz = 0;
13349 c = *zDate;
13350 if( c=='-' ){
13351 sgn = -1;
13352 }else if( c=='+' ){
13353 sgn = +1;
13354 }else if( c=='Z' || c=='z' ){
13355 zDate++;
13356 goto zulu_time;
13357 }else{
13358 return c!=0;
13360 zDate++;
13361 if( getDigits(zDate, 2, 0, 14, ':', &nHr, 2, 0, 59, 0, &nMn)!=2 ){
13362 return 1;
13364 zDate += 5;
13365 p->tz = sgn*(nMn + nHr*60);
13366 zulu_time:
13367 while( sqlite3Isspace(*zDate) ){ zDate++; }
13368 return *zDate!=0;
13372 ** Parse times of the form HH:MM or HH:MM:SS or HH:MM:SS.FFFF.
13373 ** The HH, MM, and SS must each be exactly 2 digits. The
13374 ** fractional seconds FFFF can be one or more digits.
13376 ** Return 1 if there is a parsing error and 0 on success.
13378 static int parseHhMmSs(const char *zDate, DateTime *p){
13379 int h, m, s;
13380 double ms = 0.0;
13381 if( getDigits(zDate, 2, 0, 24, ':', &h, 2, 0, 59, 0, &m)!=2 ){
13382 return 1;
13384 zDate += 5;
13385 if( *zDate==':' ){
13386 zDate++;
13387 if( getDigits(zDate, 2, 0, 59, 0, &s)!=1 ){
13388 return 1;
13390 zDate += 2;
13391 if( *zDate=='.' && sqlite3Isdigit(zDate[1]) ){
13392 double rScale = 1.0;
13393 zDate++;
13394 while( sqlite3Isdigit(*zDate) ){
13395 ms = ms*10.0 + *zDate - '0';
13396 rScale *= 10.0;
13397 zDate++;
13399 ms /= rScale;
13401 }else{
13402 s = 0;
13404 p->validJD = 0;
13405 p->validHMS = 1;
13406 p->h = h;
13407 p->m = m;
13408 p->s = s + ms;
13409 if( parseTimezone(zDate, p) ) return 1;
13410 p->validTZ = (p->tz!=0)?1:0;
13411 return 0;
13415 ** Convert from YYYY-MM-DD HH:MM:SS to julian day. We always assume
13416 ** that the YYYY-MM-DD is according to the Gregorian calendar.
13418 ** Reference: Meeus page 61
13420 static void computeJD(DateTime *p){
13421 int Y, M, D, A, B, X1, X2;
13423 if( p->validJD ) return;
13424 if( p->validYMD ){
13425 Y = p->Y;
13426 M = p->M;
13427 D = p->D;
13428 }else{
13429 Y = 2000; /* If no YMD specified, assume 2000-Jan-01 */
13430 M = 1;
13431 D = 1;
13433 if( M<=2 ){
13434 Y--;
13435 M += 12;
13437 A = Y/100;
13438 B = 2 - A + (A/4);
13439 X1 = 36525*(Y+4716)/100;
13440 X2 = 306001*(M+1)/10000;
13441 p->iJD = (sqlite3_int64)((X1 + X2 + D + B - 1524.5 ) * 86400000);
13442 p->validJD = 1;
13443 if( p->validHMS ){
13444 p->iJD += p->h*3600000 + p->m*60000 + (sqlite3_int64)(p->s*1000);
13445 if( p->validTZ ){
13446 p->iJD -= p->tz*60000;
13447 p->validYMD = 0;
13448 p->validHMS = 0;
13449 p->validTZ = 0;
13455 ** Parse dates of the form
13457 ** YYYY-MM-DD HH:MM:SS.FFF
13458 ** YYYY-MM-DD HH:MM:SS
13459 ** YYYY-MM-DD HH:MM
13460 ** YYYY-MM-DD
13462 ** Write the result into the DateTime structure and return 0
13463 ** on success and 1 if the input string is not a well-formed
13464 ** date.
13466 static int parseYyyyMmDd(const char *zDate, DateTime *p){
13467 int Y, M, D, neg;
13469 if( zDate[0]=='-' ){
13470 zDate++;
13471 neg = 1;
13472 }else{
13473 neg = 0;
13475 if( getDigits(zDate,4,0,9999,'-',&Y,2,1,12,'-',&M,2,1,31,0,&D)!=3 ){
13476 return 1;
13478 zDate += 10;
13479 while( sqlite3Isspace(*zDate) || 'T'==*(u8*)zDate ){ zDate++; }
13480 if( parseHhMmSs(zDate, p)==0 ){
13481 /* We got the time */
13482 }else if( *zDate==0 ){
13483 p->validHMS = 0;
13484 }else{
13485 return 1;
13487 p->validJD = 0;
13488 p->validYMD = 1;
13489 p->Y = neg ? -Y : Y;
13490 p->M = M;
13491 p->D = D;
13492 if( p->validTZ ){
13493 computeJD(p);
13495 return 0;
13499 ** Set the time to the current time reported by the VFS
13501 static void setDateTimeToCurrent(sqlite3_context *context, DateTime *p){
13502 sqlite3 *db = sqlite3_context_db_handle(context);
13503 sqlite3OsCurrentTimeInt64(db->pVfs, &p->iJD);
13504 p->validJD = 1;
13508 ** Attempt to parse the given string into a Julian Day Number. Return
13509 ** the number of errors.
13511 ** The following are acceptable forms for the input string:
13513 ** YYYY-MM-DD HH:MM:SS.FFF +/-HH:MM
13514 ** DDDD.DD
13515 ** now
13517 ** In the first form, the +/-HH:MM is always optional. The fractional
13518 ** seconds extension (the ".FFF") is optional. The seconds portion
13519 ** (":SS.FFF") is option. The year and date can be omitted as long
13520 ** as there is a time string. The time string can be omitted as long
13521 ** as there is a year and date.
13523 static int parseDateOrTime(
13524 sqlite3_context *context,
13525 const char *zDate,
13526 DateTime *p
13528 double r;
13529 if( parseYyyyMmDd(zDate,p)==0 ){
13530 return 0;
13531 }else if( parseHhMmSs(zDate, p)==0 ){
13532 return 0;
13533 }else if( sqlite3StrICmp(zDate,"now")==0){
13534 setDateTimeToCurrent(context, p);
13535 return 0;
13536 }else if( sqlite3AtoF(zDate, &r, sqlite3Strlen30(zDate), SQLITE_UTF8) ){
13537 p->iJD = (sqlite3_int64)(r*86400000.0 + 0.5);
13538 p->validJD = 1;
13539 return 0;
13541 return 1;
13545 ** Compute the Year, Month, and Day from the julian day number.
13547 static void computeYMD(DateTime *p){
13548 int Z, A, B, C, D, E, X1;
13549 if( p->validYMD ) return;
13550 if( !p->validJD ){
13551 p->Y = 2000;
13552 p->M = 1;
13553 p->D = 1;
13554 }else{
13555 Z = (int)((p->iJD + 43200000)/86400000);
13556 A = (int)((Z - 1867216.25)/36524.25);
13557 A = Z + 1 + A - (A/4);
13558 B = A + 1524;
13559 C = (int)((B - 122.1)/365.25);
13560 D = (36525*C)/100;
13561 E = (int)((B-D)/30.6001);
13562 X1 = (int)(30.6001*E);
13563 p->D = B - D - X1;
13564 p->M = E<14 ? E-1 : E-13;
13565 p->Y = p->M>2 ? C - 4716 : C - 4715;
13567 p->validYMD = 1;
13571 ** Compute the Hour, Minute, and Seconds from the julian day number.
13573 static void computeHMS(DateTime *p){
13574 int s;
13575 if( p->validHMS ) return;
13576 computeJD(p);
13577 s = (int)((p->iJD + 43200000) % 86400000);
13578 p->s = s/1000.0;
13579 s = (int)p->s;
13580 p->s -= s;
13581 p->h = s/3600;
13582 s -= p->h*3600;
13583 p->m = s/60;
13584 p->s += s - p->m*60;
13585 p->validHMS = 1;
13589 ** Compute both YMD and HMS
13591 static void computeYMD_HMS(DateTime *p){
13592 computeYMD(p);
13593 computeHMS(p);
13597 ** Clear the YMD and HMS and the TZ
13599 static void clearYMD_HMS_TZ(DateTime *p){
13600 p->validYMD = 0;
13601 p->validHMS = 0;
13602 p->validTZ = 0;
13606 ** On recent Windows platforms, the localtime_s() function is available
13607 ** as part of the "Secure CRT". It is essentially equivalent to
13608 ** localtime_r() available under most POSIX platforms, except that the
13609 ** order of the parameters is reversed.
13611 ** See http://msdn.microsoft.com/en-us/library/a442x3ye(VS.80).aspx.
13613 ** If the user has not indicated to use localtime_r() or localtime_s()
13614 ** already, check for an MSVC build environment that provides
13615 ** localtime_s().
13617 #if !defined(HAVE_LOCALTIME_R) && !defined(HAVE_LOCALTIME_S) && \
13618 defined(_MSC_VER) && defined(_CRT_INSECURE_DEPRECATE)
13619 #define HAVE_LOCALTIME_S 1
13620 #endif
13622 #ifndef SQLITE_OMIT_LOCALTIME
13624 ** The following routine implements the rough equivalent of localtime_r()
13625 ** using whatever operating-system specific localtime facility that
13626 ** is available. This routine returns 0 on success and
13627 ** non-zero on any kind of error.
13629 ** If the sqlite3GlobalConfig.bLocaltimeFault variable is true then this
13630 ** routine will always fail.
13632 static int osLocaltime(time_t *t, struct tm *pTm){
13633 int rc;
13634 #if (!defined(HAVE_LOCALTIME_R) || !HAVE_LOCALTIME_R) \
13635 && (!defined(HAVE_LOCALTIME_S) || !HAVE_LOCALTIME_S)
13636 struct tm *pX;
13637 #if SQLITE_THREADSAFE>0
13638 sqlite3_mutex *mutex = sqlite3MutexAlloc(SQLITE_MUTEX_STATIC_MASTER);
13639 #endif
13640 sqlite3_mutex_enter(mutex);
13641 pX = localtime(t);
13642 #ifndef SQLITE_OMIT_BUILTIN_TEST
13643 if( sqlite3GlobalConfig.bLocaltimeFault ) pX = 0;
13644 #endif
13645 if( pX ) *pTm = *pX;
13646 sqlite3_mutex_leave(mutex);
13647 rc = pX==0;
13648 #else
13649 #ifndef SQLITE_OMIT_BUILTIN_TEST
13650 if( sqlite3GlobalConfig.bLocaltimeFault ) return 1;
13651 #endif
13652 #if defined(HAVE_LOCALTIME_R) && HAVE_LOCALTIME_R
13653 rc = localtime_r(t, pTm)==0;
13654 #else
13655 rc = localtime_s(pTm, t);
13656 #endif /* HAVE_LOCALTIME_R */
13657 #endif /* HAVE_LOCALTIME_R || HAVE_LOCALTIME_S */
13658 return rc;
13660 #endif /* SQLITE_OMIT_LOCALTIME */
13663 #ifndef SQLITE_OMIT_LOCALTIME
13665 ** Compute the difference (in milliseconds) between localtime and UTC
13666 ** (a.k.a. GMT) for the time value p where p is in UTC. If no error occurs,
13667 ** return this value and set *pRc to SQLITE_OK.
13669 ** Or, if an error does occur, set *pRc to SQLITE_ERROR. The returned value
13670 ** is undefined in this case.
13672 static sqlite3_int64 localtimeOffset(
13673 DateTime *p, /* Date at which to calculate offset */
13674 sqlite3_context *pCtx, /* Write error here if one occurs */
13675 int *pRc /* OUT: Error code. SQLITE_OK or ERROR */
13677 DateTime x, y;
13678 time_t t;
13679 struct tm sLocal;
13681 /* Initialize the contents of sLocal to avoid a compiler warning. */
13682 memset(&sLocal, 0, sizeof(sLocal));
13684 x = *p;
13685 computeYMD_HMS(&x);
13686 if( x.Y<1971 || x.Y>=2038 ){
13687 x.Y = 2000;
13688 x.M = 1;
13689 x.D = 1;
13690 x.h = 0;
13691 x.m = 0;
13692 x.s = 0.0;
13693 } else {
13694 int s = (int)(x.s + 0.5);
13695 x.s = s;
13697 x.tz = 0;
13698 x.validJD = 0;
13699 computeJD(&x);
13700 t = (time_t)(x.iJD/1000 - 21086676*(i64)10000);
13701 if( osLocaltime(&t, &sLocal) ){
13702 sqlite3_result_error(pCtx, "local time unavailable", -1);
13703 *pRc = SQLITE_ERROR;
13704 return 0;
13706 y.Y = sLocal.tm_year + 1900;
13707 y.M = sLocal.tm_mon + 1;
13708 y.D = sLocal.tm_mday;
13709 y.h = sLocal.tm_hour;
13710 y.m = sLocal.tm_min;
13711 y.s = sLocal.tm_sec;
13712 y.validYMD = 1;
13713 y.validHMS = 1;
13714 y.validJD = 0;
13715 y.validTZ = 0;
13716 computeJD(&y);
13717 *pRc = SQLITE_OK;
13718 return y.iJD - x.iJD;
13720 #endif /* SQLITE_OMIT_LOCALTIME */
13723 ** Process a modifier to a date-time stamp. The modifiers are
13724 ** as follows:
13726 ** NNN days
13727 ** NNN hours
13728 ** NNN minutes
13729 ** NNN.NNNN seconds
13730 ** NNN months
13731 ** NNN years
13732 ** start of month
13733 ** start of year
13734 ** start of week
13735 ** start of day
13736 ** weekday N
13737 ** unixepoch
13738 ** localtime
13739 ** utc
13741 ** Return 0 on success and 1 if there is any kind of error. If the error
13742 ** is in a system call (i.e. localtime()), then an error message is written
13743 ** to context pCtx. If the error is an unrecognized modifier, no error is
13744 ** written to pCtx.
13746 static int parseModifier(sqlite3_context *pCtx, const char *zMod, DateTime *p){
13747 int rc = 1;
13748 int n;
13749 double r;
13750 char *z, zBuf[30];
13751 z = zBuf;
13752 for(n=0; n<ArraySize(zBuf)-1 && zMod[n]; n++){
13753 z[n] = (char)sqlite3UpperToLower[(u8)zMod[n]];
13755 z[n] = 0;
13756 switch( z[0] ){
13757 #ifndef SQLITE_OMIT_LOCALTIME
13758 case 'l': {
13759 /* localtime
13761 ** Assuming the current time value is UTC (a.k.a. GMT), shift it to
13762 ** show local time.
13764 if( strcmp(z, "localtime")==0 ){
13765 computeJD(p);
13766 p->iJD += localtimeOffset(p, pCtx, &rc);
13767 clearYMD_HMS_TZ(p);
13769 break;
13771 #endif
13772 case 'u': {
13774 ** unixepoch
13776 ** Treat the current value of p->iJD as the number of
13777 ** seconds since 1970. Convert to a real julian day number.
13779 if( strcmp(z, "unixepoch")==0 && p->validJD ){
13780 p->iJD = (p->iJD + 43200)/86400 + 21086676*(i64)10000000;
13781 clearYMD_HMS_TZ(p);
13782 rc = 0;
13784 #ifndef SQLITE_OMIT_LOCALTIME
13785 else if( strcmp(z, "utc")==0 ){
13786 sqlite3_int64 c1;
13787 computeJD(p);
13788 c1 = localtimeOffset(p, pCtx, &rc);
13789 if( rc==SQLITE_OK ){
13790 p->iJD -= c1;
13791 clearYMD_HMS_TZ(p);
13792 p->iJD += c1 - localtimeOffset(p, pCtx, &rc);
13795 #endif
13796 break;
13798 case 'w': {
13800 ** weekday N
13802 ** Move the date to the same time on the next occurrence of
13803 ** weekday N where 0==Sunday, 1==Monday, and so forth. If the
13804 ** date is already on the appropriate weekday, this is a no-op.
13806 if( strncmp(z, "weekday ", 8)==0
13807 && sqlite3AtoF(&z[8], &r, sqlite3Strlen30(&z[8]), SQLITE_UTF8)
13808 && (n=(int)r)==r && n>=0 && r<7 ){
13809 sqlite3_int64 Z;
13810 computeYMD_HMS(p);
13811 p->validTZ = 0;
13812 p->validJD = 0;
13813 computeJD(p);
13814 Z = ((p->iJD + 129600000)/86400000) % 7;
13815 if( Z>n ) Z -= 7;
13816 p->iJD += (n - Z)*86400000;
13817 clearYMD_HMS_TZ(p);
13818 rc = 0;
13820 break;
13822 case 's': {
13824 ** start of TTTTT
13826 ** Move the date backwards to the beginning of the current day,
13827 ** or month or year.
13829 if( strncmp(z, "start of ", 9)!=0 ) break;
13830 z += 9;
13831 computeYMD(p);
13832 p->validHMS = 1;
13833 p->h = p->m = 0;
13834 p->s = 0.0;
13835 p->validTZ = 0;
13836 p->validJD = 0;
13837 if( strcmp(z,"month")==0 ){
13838 p->D = 1;
13839 rc = 0;
13840 }else if( strcmp(z,"year")==0 ){
13841 computeYMD(p);
13842 p->M = 1;
13843 p->D = 1;
13844 rc = 0;
13845 }else if( strcmp(z,"day")==0 ){
13846 rc = 0;
13848 break;
13850 case '+':
13851 case '-':
13852 case '0':
13853 case '1':
13854 case '2':
13855 case '3':
13856 case '4':
13857 case '5':
13858 case '6':
13859 case '7':
13860 case '8':
13861 case '9': {
13862 double rRounder;
13863 for(n=1; z[n] && z[n]!=':' && !sqlite3Isspace(z[n]); n++){}
13864 if( !sqlite3AtoF(z, &r, n, SQLITE_UTF8) ){
13865 rc = 1;
13866 break;
13868 if( z[n]==':' ){
13869 /* A modifier of the form (+|-)HH:MM:SS.FFF adds (or subtracts) the
13870 ** specified number of hours, minutes, seconds, and fractional seconds
13871 ** to the time. The ".FFF" may be omitted. The ":SS.FFF" may be
13872 ** omitted.
13874 const char *z2 = z;
13875 DateTime tx;
13876 sqlite3_int64 day;
13877 if( !sqlite3Isdigit(*z2) ) z2++;
13878 memset(&tx, 0, sizeof(tx));
13879 if( parseHhMmSs(z2, &tx) ) break;
13880 computeJD(&tx);
13881 tx.iJD -= 43200000;
13882 day = tx.iJD/86400000;
13883 tx.iJD -= day*86400000;
13884 if( z[0]=='-' ) tx.iJD = -tx.iJD;
13885 computeJD(p);
13886 clearYMD_HMS_TZ(p);
13887 p->iJD += tx.iJD;
13888 rc = 0;
13889 break;
13891 z += n;
13892 while( sqlite3Isspace(*z) ) z++;
13893 n = sqlite3Strlen30(z);
13894 if( n>10 || n<3 ) break;
13895 if( z[n-1]=='s' ){ z[n-1] = 0; n--; }
13896 computeJD(p);
13897 rc = 0;
13898 rRounder = r<0 ? -0.5 : +0.5;
13899 if( n==3 && strcmp(z,"day")==0 ){
13900 p->iJD += (sqlite3_int64)(r*86400000.0 + rRounder);
13901 }else if( n==4 && strcmp(z,"hour")==0 ){
13902 p->iJD += (sqlite3_int64)(r*(86400000.0/24.0) + rRounder);
13903 }else if( n==6 && strcmp(z,"minute")==0 ){
13904 p->iJD += (sqlite3_int64)(r*(86400000.0/(24.0*60.0)) + rRounder);
13905 }else if( n==6 && strcmp(z,"second")==0 ){
13906 p->iJD += (sqlite3_int64)(r*(86400000.0/(24.0*60.0*60.0)) + rRounder);
13907 }else if( n==5 && strcmp(z,"month")==0 ){
13908 int x, y;
13909 computeYMD_HMS(p);
13910 p->M += (int)r;
13911 x = p->M>0 ? (p->M-1)/12 : (p->M-12)/12;
13912 p->Y += x;
13913 p->M -= x*12;
13914 p->validJD = 0;
13915 computeJD(p);
13916 y = (int)r;
13917 if( y!=r ){
13918 p->iJD += (sqlite3_int64)((r - y)*30.0*86400000.0 + rRounder);
13920 }else if( n==4 && strcmp(z,"year")==0 ){
13921 int y = (int)r;
13922 computeYMD_HMS(p);
13923 p->Y += y;
13924 p->validJD = 0;
13925 computeJD(p);
13926 if( y!=r ){
13927 p->iJD += (sqlite3_int64)((r - y)*365.0*86400000.0 + rRounder);
13929 }else{
13930 rc = 1;
13932 clearYMD_HMS_TZ(p);
13933 break;
13935 default: {
13936 break;
13939 return rc;
13943 ** Process time function arguments. argv[0] is a date-time stamp.
13944 ** argv[1] and following are modifiers. Parse them all and write
13945 ** the resulting time into the DateTime structure p. Return 0
13946 ** on success and 1 if there are any errors.
13948 ** If there are zero parameters (if even argv[0] is undefined)
13949 ** then assume a default value of "now" for argv[0].
13951 static int isDate(
13952 sqlite3_context *context,
13953 int argc,
13954 sqlite3_value **argv,
13955 DateTime *p
13957 int i;
13958 const unsigned char *z;
13959 int eType;
13960 memset(p, 0, sizeof(*p));
13961 if( argc==0 ){
13962 setDateTimeToCurrent(context, p);
13963 }else if( (eType = sqlite3_value_type(argv[0]))==SQLITE_FLOAT
13964 || eType==SQLITE_INTEGER ){
13965 p->iJD = (sqlite3_int64)(sqlite3_value_double(argv[0])*86400000.0 + 0.5);
13966 p->validJD = 1;
13967 }else{
13968 z = sqlite3_value_text(argv[0]);
13969 if( !z || parseDateOrTime(context, (char*)z, p) ){
13970 return 1;
13973 for(i=1; i<argc; i++){
13974 z = sqlite3_value_text(argv[i]);
13975 if( z==0 || parseModifier(context, (char*)z, p) ) return 1;
13977 return 0;
13982 ** The following routines implement the various date and time functions
13983 ** of SQLite.
13987 ** julianday( TIMESTRING, MOD, MOD, ...)
13989 ** Return the julian day number of the date specified in the arguments
13991 static void juliandayFunc(
13992 sqlite3_context *context,
13993 int argc,
13994 sqlite3_value **argv
13996 DateTime x;
13997 if( isDate(context, argc, argv, &x)==0 ){
13998 computeJD(&x);
13999 sqlite3_result_double(context, x.iJD/86400000.0);
14004 ** datetime( TIMESTRING, MOD, MOD, ...)
14006 ** Return YYYY-MM-DD HH:MM:SS
14008 static void datetimeFunc(
14009 sqlite3_context *context,
14010 int argc,
14011 sqlite3_value **argv
14013 DateTime x;
14014 if( isDate(context, argc, argv, &x)==0 ){
14015 char zBuf[100];
14016 computeYMD_HMS(&x);
14017 sqlite3_snprintf(sizeof(zBuf), zBuf, "%04d-%02d-%02d %02d:%02d:%02d",
14018 x.Y, x.M, x.D, x.h, x.m, (int)(x.s));
14019 sqlite3_result_text(context, zBuf, -1, SQLITE_TRANSIENT);
14024 ** time( TIMESTRING, MOD, MOD, ...)
14026 ** Return HH:MM:SS
14028 static void timeFunc(
14029 sqlite3_context *context,
14030 int argc,
14031 sqlite3_value **argv
14033 DateTime x;
14034 if( isDate(context, argc, argv, &x)==0 ){
14035 char zBuf[100];
14036 computeHMS(&x);
14037 sqlite3_snprintf(sizeof(zBuf), zBuf, "%02d:%02d:%02d", x.h, x.m, (int)x.s);
14038 sqlite3_result_text(context, zBuf, -1, SQLITE_TRANSIENT);
14043 ** date( TIMESTRING, MOD, MOD, ...)
14045 ** Return YYYY-MM-DD
14047 static void dateFunc(
14048 sqlite3_context *context,
14049 int argc,
14050 sqlite3_value **argv
14052 DateTime x;
14053 if( isDate(context, argc, argv, &x)==0 ){
14054 char zBuf[100];
14055 computeYMD(&x);
14056 sqlite3_snprintf(sizeof(zBuf), zBuf, "%04d-%02d-%02d", x.Y, x.M, x.D);
14057 sqlite3_result_text(context, zBuf, -1, SQLITE_TRANSIENT);
14062 ** strftime( FORMAT, TIMESTRING, MOD, MOD, ...)
14064 ** Return a string described by FORMAT. Conversions as follows:
14066 ** %d day of month
14067 ** %f ** fractional seconds SS.SSS
14068 ** %H hour 00-24
14069 ** %j day of year 000-366
14070 ** %J ** Julian day number
14071 ** %m month 01-12
14072 ** %M minute 00-59
14073 ** %s seconds since 1970-01-01
14074 ** %S seconds 00-59
14075 ** %w day of week 0-6 sunday==0
14076 ** %W week of year 00-53
14077 ** %Y year 0000-9999
14078 ** %% %
14080 static void strftimeFunc(
14081 sqlite3_context *context,
14082 int argc,
14083 sqlite3_value **argv
14085 DateTime x;
14086 u64 n;
14087 size_t i,j;
14088 char *z;
14089 sqlite3 *db;
14090 const char *zFmt = (const char*)sqlite3_value_text(argv[0]);
14091 char zBuf[100];
14092 if( zFmt==0 || isDate(context, argc-1, argv+1, &x) ) return;
14093 db = sqlite3_context_db_handle(context);
14094 for(i=0, n=1; zFmt[i]; i++, n++){
14095 if( zFmt[i]=='%' ){
14096 switch( zFmt[i+1] ){
14097 case 'd':
14098 case 'H':
14099 case 'm':
14100 case 'M':
14101 case 'S':
14102 case 'W':
14103 n++;
14104 /* fall thru */
14105 case 'w':
14106 case '%':
14107 break;
14108 case 'f':
14109 n += 8;
14110 break;
14111 case 'j':
14112 n += 3;
14113 break;
14114 case 'Y':
14115 n += 8;
14116 break;
14117 case 's':
14118 case 'J':
14119 n += 50;
14120 break;
14121 default:
14122 return; /* ERROR. return a NULL */
14124 i++;
14127 testcase( n==sizeof(zBuf)-1 );
14128 testcase( n==sizeof(zBuf) );
14129 testcase( n==(u64)db->aLimit[SQLITE_LIMIT_LENGTH]+1 );
14130 testcase( n==(u64)db->aLimit[SQLITE_LIMIT_LENGTH] );
14131 if( n<sizeof(zBuf) ){
14132 z = zBuf;
14133 }else if( n>(u64)db->aLimit[SQLITE_LIMIT_LENGTH] ){
14134 sqlite3_result_error_toobig(context);
14135 return;
14136 }else{
14137 z = sqlite3DbMallocRaw(db, (int)n);
14138 if( z==0 ){
14139 sqlite3_result_error_nomem(context);
14140 return;
14143 computeJD(&x);
14144 computeYMD_HMS(&x);
14145 for(i=j=0; zFmt[i]; i++){
14146 if( zFmt[i]!='%' ){
14147 z[j++] = zFmt[i];
14148 }else{
14149 i++;
14150 switch( zFmt[i] ){
14151 case 'd': sqlite3_snprintf(3, &z[j],"%02d",x.D); j+=2; break;
14152 case 'f': {
14153 double s = x.s;
14154 if( s>59.999 ) s = 59.999;
14155 sqlite3_snprintf(7, &z[j],"%06.3f", s);
14156 j += sqlite3Strlen30(&z[j]);
14157 break;
14159 case 'H': sqlite3_snprintf(3, &z[j],"%02d",x.h); j+=2; break;
14160 case 'W': /* Fall thru */
14161 case 'j': {
14162 int nDay; /* Number of days since 1st day of year */
14163 DateTime y = x;
14164 y.validJD = 0;
14165 y.M = 1;
14166 y.D = 1;
14167 computeJD(&y);
14168 nDay = (int)((x.iJD-y.iJD+43200000)/86400000);
14169 if( zFmt[i]=='W' ){
14170 int wd; /* 0=Monday, 1=Tuesday, ... 6=Sunday */
14171 wd = (int)(((x.iJD+43200000)/86400000)%7);
14172 sqlite3_snprintf(3, &z[j],"%02d",(nDay+7-wd)/7);
14173 j += 2;
14174 }else{
14175 sqlite3_snprintf(4, &z[j],"%03d",nDay+1);
14176 j += 3;
14178 break;
14180 case 'J': {
14181 sqlite3_snprintf(20, &z[j],"%.16g",x.iJD/86400000.0);
14182 j+=sqlite3Strlen30(&z[j]);
14183 break;
14185 case 'm': sqlite3_snprintf(3, &z[j],"%02d",x.M); j+=2; break;
14186 case 'M': sqlite3_snprintf(3, &z[j],"%02d",x.m); j+=2; break;
14187 case 's': {
14188 sqlite3_snprintf(30,&z[j],"%lld",
14189 (i64)(x.iJD/1000 - 21086676*(i64)10000));
14190 j += sqlite3Strlen30(&z[j]);
14191 break;
14193 case 'S': sqlite3_snprintf(3,&z[j],"%02d",(int)x.s); j+=2; break;
14194 case 'w': {
14195 z[j++] = (char)(((x.iJD+129600000)/86400000) % 7) + '0';
14196 break;
14198 case 'Y': {
14199 sqlite3_snprintf(5,&z[j],"%04d",x.Y); j+=sqlite3Strlen30(&z[j]);
14200 break;
14202 default: z[j++] = '%'; break;
14206 z[j] = 0;
14207 sqlite3_result_text(context, z, -1,
14208 z==zBuf ? SQLITE_TRANSIENT : SQLITE_DYNAMIC);
14212 ** current_time()
14214 ** This function returns the same value as time('now').
14216 static void ctimeFunc(
14217 sqlite3_context *context,
14218 int NotUsed,
14219 sqlite3_value **NotUsed2
14221 UNUSED_PARAMETER2(NotUsed, NotUsed2);
14222 timeFunc(context, 0, 0);
14226 ** current_date()
14228 ** This function returns the same value as date('now').
14230 static void cdateFunc(
14231 sqlite3_context *context,
14232 int NotUsed,
14233 sqlite3_value **NotUsed2
14235 UNUSED_PARAMETER2(NotUsed, NotUsed2);
14236 dateFunc(context, 0, 0);
14240 ** current_timestamp()
14242 ** This function returns the same value as datetime('now').
14244 static void ctimestampFunc(
14245 sqlite3_context *context,
14246 int NotUsed,
14247 sqlite3_value **NotUsed2
14249 UNUSED_PARAMETER2(NotUsed, NotUsed2);
14250 datetimeFunc(context, 0, 0);
14252 #endif /* !defined(SQLITE_OMIT_DATETIME_FUNCS) */
14254 #ifdef SQLITE_OMIT_DATETIME_FUNCS
14256 ** If the library is compiled to omit the full-scale date and time
14257 ** handling (to get a smaller binary), the following minimal version
14258 ** of the functions current_time(), current_date() and current_timestamp()
14259 ** are included instead. This is to support column declarations that
14260 ** include "DEFAULT CURRENT_TIME" etc.
14262 ** This function uses the C-library functions time(), gmtime()
14263 ** and strftime(). The format string to pass to strftime() is supplied
14264 ** as the user-data for the function.
14266 static void currentTimeFunc(
14267 sqlite3_context *context,
14268 int argc,
14269 sqlite3_value **argv
14271 time_t t;
14272 char *zFormat = (char *)sqlite3_user_data(context);
14273 sqlite3 *db;
14274 sqlite3_int64 iT;
14275 char zBuf[20];
14277 UNUSED_PARAMETER(argc);
14278 UNUSED_PARAMETER(argv);
14280 db = sqlite3_context_db_handle(context);
14281 sqlite3OsCurrentTimeInt64(db->pVfs, &iT);
14282 t = iT/1000 - 10000*(sqlite3_int64)21086676;
14283 #ifdef HAVE_GMTIME_R
14285 struct tm sNow;
14286 gmtime_r(&t, &sNow);
14287 strftime(zBuf, 20, zFormat, &sNow);
14289 #else
14291 struct tm *pTm;
14292 sqlite3_mutex_enter(sqlite3MutexAlloc(SQLITE_MUTEX_STATIC_MASTER));
14293 pTm = gmtime(&t);
14294 strftime(zBuf, 20, zFormat, pTm);
14295 sqlite3_mutex_leave(sqlite3MutexAlloc(SQLITE_MUTEX_STATIC_MASTER));
14297 #endif
14299 sqlite3_result_text(context, zBuf, -1, SQLITE_TRANSIENT);
14301 #endif
14304 ** This function registered all of the above C functions as SQL
14305 ** functions. This should be the only routine in this file with
14306 ** external linkage.
14308 SQLITE_PRIVATE void sqlite3RegisterDateTimeFunctions(void){
14309 static SQLITE_WSD FuncDef aDateTimeFuncs[] = {
14310 #ifndef SQLITE_OMIT_DATETIME_FUNCS
14311 FUNCTION(julianday, -1, 0, 0, juliandayFunc ),
14312 FUNCTION(date, -1, 0, 0, dateFunc ),
14313 FUNCTION(time, -1, 0, 0, timeFunc ),
14314 FUNCTION(datetime, -1, 0, 0, datetimeFunc ),
14315 FUNCTION(strftime, -1, 0, 0, strftimeFunc ),
14316 FUNCTION(current_time, 0, 0, 0, ctimeFunc ),
14317 FUNCTION(current_timestamp, 0, 0, 0, ctimestampFunc),
14318 FUNCTION(current_date, 0, 0, 0, cdateFunc ),
14319 #else
14320 STR_FUNCTION(current_time, 0, "%H:%M:%S", 0, currentTimeFunc),
14321 STR_FUNCTION(current_date, 0, "%Y-%m-%d", 0, currentTimeFunc),
14322 STR_FUNCTION(current_timestamp, 0, "%Y-%m-%d %H:%M:%S", 0, currentTimeFunc),
14323 #endif
14325 int i;
14326 FuncDefHash *pHash = &GLOBAL(FuncDefHash, sqlite3GlobalFunctions);
14327 FuncDef *aFunc = (FuncDef*)&GLOBAL(FuncDef, aDateTimeFuncs);
14329 for(i=0; i<ArraySize(aDateTimeFuncs); i++){
14330 sqlite3FuncDefInsert(pHash, &aFunc[i]);
14334 /************** End of date.c ************************************************/
14335 /************** Begin file os.c **********************************************/
14337 ** 2005 November 29
14339 ** The author disclaims copyright to this source code. In place of
14340 ** a legal notice, here is a blessing:
14342 ** May you do good and not evil.
14343 ** May you find forgiveness for yourself and forgive others.
14344 ** May you share freely, never taking more than you give.
14346 ******************************************************************************
14348 ** This file contains OS interface code that is common to all
14349 ** architectures.
14351 #define _SQLITE_OS_C_ 1
14352 #undef _SQLITE_OS_C_
14355 ** The default SQLite sqlite3_vfs implementations do not allocate
14356 ** memory (actually, os_unix.c allocates a small amount of memory
14357 ** from within OsOpen()), but some third-party implementations may.
14358 ** So we test the effects of a malloc() failing and the sqlite3OsXXX()
14359 ** function returning SQLITE_IOERR_NOMEM using the DO_OS_MALLOC_TEST macro.
14361 ** The following functions are instrumented for malloc() failure
14362 ** testing:
14364 ** sqlite3OsOpen()
14365 ** sqlite3OsRead()
14366 ** sqlite3OsWrite()
14367 ** sqlite3OsSync()
14368 ** sqlite3OsLock()
14371 #if defined(SQLITE_TEST)
14372 SQLITE_API int sqlite3_memdebug_vfs_oom_test = 1;
14373 #define DO_OS_MALLOC_TEST(x) \
14374 if (sqlite3_memdebug_vfs_oom_test && (!x || !sqlite3IsMemJournal(x))) { \
14375 void *pTstAlloc = sqlite3Malloc(10); \
14376 if (!pTstAlloc) return SQLITE_IOERR_NOMEM; \
14377 sqlite3_free(pTstAlloc); \
14379 #else
14380 #define DO_OS_MALLOC_TEST(x)
14381 #endif
14384 ** The following routines are convenience wrappers around methods
14385 ** of the sqlite3_file object. This is mostly just syntactic sugar. All
14386 ** of this would be completely automatic if SQLite were coded using
14387 ** C++ instead of plain old C.
14389 SQLITE_PRIVATE int sqlite3OsClose(sqlite3_file *pId){
14390 int rc = SQLITE_OK;
14391 if( pId->pMethods ){
14392 rc = pId->pMethods->xClose(pId);
14393 pId->pMethods = 0;
14395 return rc;
14397 SQLITE_PRIVATE int sqlite3OsRead(sqlite3_file *id, void *pBuf, int amt, i64 offset){
14398 DO_OS_MALLOC_TEST(id);
14399 return id->pMethods->xRead(id, pBuf, amt, offset);
14401 SQLITE_PRIVATE int sqlite3OsWrite(sqlite3_file *id, const void *pBuf, int amt, i64 offset){
14402 DO_OS_MALLOC_TEST(id);
14403 return id->pMethods->xWrite(id, pBuf, amt, offset);
14405 SQLITE_PRIVATE int sqlite3OsTruncate(sqlite3_file *id, i64 size){
14406 return id->pMethods->xTruncate(id, size);
14408 SQLITE_PRIVATE int sqlite3OsSync(sqlite3_file *id, int flags){
14409 DO_OS_MALLOC_TEST(id);
14410 return id->pMethods->xSync(id, flags);
14412 SQLITE_PRIVATE int sqlite3OsFileSize(sqlite3_file *id, i64 *pSize){
14413 DO_OS_MALLOC_TEST(id);
14414 return id->pMethods->xFileSize(id, pSize);
14416 SQLITE_PRIVATE int sqlite3OsLock(sqlite3_file *id, int lockType){
14417 DO_OS_MALLOC_TEST(id);
14418 return id->pMethods->xLock(id, lockType);
14420 SQLITE_PRIVATE int sqlite3OsUnlock(sqlite3_file *id, int lockType){
14421 return id->pMethods->xUnlock(id, lockType);
14423 SQLITE_PRIVATE int sqlite3OsCheckReservedLock(sqlite3_file *id, int *pResOut){
14424 DO_OS_MALLOC_TEST(id);
14425 return id->pMethods->xCheckReservedLock(id, pResOut);
14427 SQLITE_PRIVATE int sqlite3OsFileControl(sqlite3_file *id, int op, void *pArg){
14428 return id->pMethods->xFileControl(id, op, pArg);
14430 SQLITE_PRIVATE int sqlite3OsSectorSize(sqlite3_file *id){
14431 int (*xSectorSize)(sqlite3_file*) = id->pMethods->xSectorSize;
14432 return (xSectorSize ? xSectorSize(id) : SQLITE_DEFAULT_SECTOR_SIZE);
14434 SQLITE_PRIVATE int sqlite3OsDeviceCharacteristics(sqlite3_file *id){
14435 return id->pMethods->xDeviceCharacteristics(id);
14437 SQLITE_PRIVATE int sqlite3OsShmLock(sqlite3_file *id, int offset, int n, int flags){
14438 return id->pMethods->xShmLock(id, offset, n, flags);
14440 SQLITE_PRIVATE void sqlite3OsShmBarrier(sqlite3_file *id){
14441 id->pMethods->xShmBarrier(id);
14443 SQLITE_PRIVATE int sqlite3OsShmUnmap(sqlite3_file *id, int deleteFlag){
14444 return id->pMethods->xShmUnmap(id, deleteFlag);
14446 SQLITE_PRIVATE int sqlite3OsShmMap(
14447 sqlite3_file *id, /* Database file handle */
14448 int iPage,
14449 int pgsz,
14450 int bExtend, /* True to extend file if necessary */
14451 void volatile **pp /* OUT: Pointer to mapping */
14453 return id->pMethods->xShmMap(id, iPage, pgsz, bExtend, pp);
14457 ** The next group of routines are convenience wrappers around the
14458 ** VFS methods.
14460 SQLITE_PRIVATE int sqlite3OsOpen(
14461 sqlite3_vfs *pVfs,
14462 const char *zPath,
14463 sqlite3_file *pFile,
14464 int flags,
14465 int *pFlagsOut
14467 int rc;
14468 DO_OS_MALLOC_TEST(0);
14469 /* 0x87f3f is a mask of SQLITE_OPEN_ flags that are valid to be passed
14470 ** down into the VFS layer. Some SQLITE_OPEN_ flags (for example,
14471 ** SQLITE_OPEN_FULLMUTEX or SQLITE_OPEN_SHAREDCACHE) are blocked before
14472 ** reaching the VFS. */
14473 rc = pVfs->xOpen(pVfs, zPath, pFile, flags & 0x87f7f, pFlagsOut);
14474 assert( rc==SQLITE_OK || pFile->pMethods==0 );
14475 return rc;
14477 SQLITE_PRIVATE int sqlite3OsDelete(sqlite3_vfs *pVfs, const char *zPath, int dirSync){
14478 return pVfs->xDelete(pVfs, zPath, dirSync);
14480 SQLITE_PRIVATE int sqlite3OsAccess(
14481 sqlite3_vfs *pVfs,
14482 const char *zPath,
14483 int flags,
14484 int *pResOut
14486 DO_OS_MALLOC_TEST(0);
14487 return pVfs->xAccess(pVfs, zPath, flags, pResOut);
14489 SQLITE_PRIVATE int sqlite3OsFullPathname(
14490 sqlite3_vfs *pVfs,
14491 const char *zPath,
14492 int nPathOut,
14493 char *zPathOut
14495 zPathOut[0] = 0;
14496 return pVfs->xFullPathname(pVfs, zPath, nPathOut, zPathOut);
14498 #ifndef SQLITE_OMIT_LOAD_EXTENSION
14499 SQLITE_PRIVATE void *sqlite3OsDlOpen(sqlite3_vfs *pVfs, const char *zPath){
14500 return pVfs->xDlOpen(pVfs, zPath);
14502 SQLITE_PRIVATE void sqlite3OsDlError(sqlite3_vfs *pVfs, int nByte, char *zBufOut){
14503 pVfs->xDlError(pVfs, nByte, zBufOut);
14505 SQLITE_PRIVATE void (*sqlite3OsDlSym(sqlite3_vfs *pVfs, void *pHdle, const char *zSym))(void){
14506 return pVfs->xDlSym(pVfs, pHdle, zSym);
14508 SQLITE_PRIVATE void sqlite3OsDlClose(sqlite3_vfs *pVfs, void *pHandle){
14509 pVfs->xDlClose(pVfs, pHandle);
14511 #endif /* SQLITE_OMIT_LOAD_EXTENSION */
14512 SQLITE_PRIVATE int sqlite3OsRandomness(sqlite3_vfs *pVfs, int nByte, char *zBufOut){
14513 return pVfs->xRandomness(pVfs, nByte, zBufOut);
14515 SQLITE_PRIVATE int sqlite3OsSleep(sqlite3_vfs *pVfs, int nMicro){
14516 return pVfs->xSleep(pVfs, nMicro);
14518 SQLITE_PRIVATE int sqlite3OsCurrentTimeInt64(sqlite3_vfs *pVfs, sqlite3_int64 *pTimeOut){
14519 int rc;
14520 /* IMPLEMENTATION-OF: R-49045-42493 SQLite will use the xCurrentTimeInt64()
14521 ** method to get the current date and time if that method is available
14522 ** (if iVersion is 2 or greater and the function pointer is not NULL) and
14523 ** will fall back to xCurrentTime() if xCurrentTimeInt64() is
14524 ** unavailable.
14526 if( pVfs->iVersion>=2 && pVfs->xCurrentTimeInt64 ){
14527 rc = pVfs->xCurrentTimeInt64(pVfs, pTimeOut);
14528 }else{
14529 double r;
14530 rc = pVfs->xCurrentTime(pVfs, &r);
14531 *pTimeOut = (sqlite3_int64)(r*86400000.0);
14533 return rc;
14536 SQLITE_PRIVATE int sqlite3OsOpenMalloc(
14537 sqlite3_vfs *pVfs,
14538 const char *zFile,
14539 sqlite3_file **ppFile,
14540 int flags,
14541 int *pOutFlags
14543 int rc = SQLITE_NOMEM;
14544 sqlite3_file *pFile;
14545 pFile = (sqlite3_file *)sqlite3MallocZero(pVfs->szOsFile);
14546 if( pFile ){
14547 rc = sqlite3OsOpen(pVfs, zFile, pFile, flags, pOutFlags);
14548 if( rc!=SQLITE_OK ){
14549 sqlite3_free(pFile);
14550 }else{
14551 *ppFile = pFile;
14554 return rc;
14556 SQLITE_PRIVATE int sqlite3OsCloseFree(sqlite3_file *pFile){
14557 int rc = SQLITE_OK;
14558 assert( pFile );
14559 rc = sqlite3OsClose(pFile);
14560 sqlite3_free(pFile);
14561 return rc;
14565 ** This function is a wrapper around the OS specific implementation of
14566 ** sqlite3_os_init(). The purpose of the wrapper is to provide the
14567 ** ability to simulate a malloc failure, so that the handling of an
14568 ** error in sqlite3_os_init() by the upper layers can be tested.
14570 SQLITE_PRIVATE int sqlite3OsInit(void){
14571 void *p = sqlite3_malloc(10);
14572 if( p==0 ) return SQLITE_NOMEM;
14573 sqlite3_free(p);
14574 return sqlite3_os_init();
14578 ** The list of all registered VFS implementations.
14580 static sqlite3_vfs * SQLITE_WSD vfsList = 0;
14581 #define vfsList GLOBAL(sqlite3_vfs *, vfsList)
14584 ** Locate a VFS by name. If no name is given, simply return the
14585 ** first VFS on the list.
14587 SQLITE_API sqlite3_vfs *sqlite3_vfs_find(const char *zVfs){
14588 sqlite3_vfs *pVfs = 0;
14589 #if SQLITE_THREADSAFE
14590 sqlite3_mutex *mutex;
14591 #endif
14592 #ifndef SQLITE_OMIT_AUTOINIT
14593 int rc = sqlite3_initialize();
14594 if( rc ) return 0;
14595 #endif
14596 #if SQLITE_THREADSAFE
14597 mutex = sqlite3MutexAlloc(SQLITE_MUTEX_STATIC_MASTER);
14598 #endif
14599 sqlite3_mutex_enter(mutex);
14600 for(pVfs = vfsList; pVfs; pVfs=pVfs->pNext){
14601 if( zVfs==0 ) break;
14602 if( strcmp(zVfs, pVfs->zName)==0 ) break;
14604 sqlite3_mutex_leave(mutex);
14605 return pVfs;
14609 ** Unlink a VFS from the linked list
14611 static void vfsUnlink(sqlite3_vfs *pVfs){
14612 assert( sqlite3_mutex_held(sqlite3MutexAlloc(SQLITE_MUTEX_STATIC_MASTER)) );
14613 if( pVfs==0 ){
14614 /* No-op */
14615 }else if( vfsList==pVfs ){
14616 vfsList = pVfs->pNext;
14617 }else if( vfsList ){
14618 sqlite3_vfs *p = vfsList;
14619 while( p->pNext && p->pNext!=pVfs ){
14620 p = p->pNext;
14622 if( p->pNext==pVfs ){
14623 p->pNext = pVfs->pNext;
14629 ** Register a VFS with the system. It is harmless to register the same
14630 ** VFS multiple times. The new VFS becomes the default if makeDflt is
14631 ** true.
14633 SQLITE_API int sqlite3_vfs_register(sqlite3_vfs *pVfs, int makeDflt){
14634 sqlite3_mutex *mutex = 0;
14635 #ifndef SQLITE_OMIT_AUTOINIT
14636 int rc = sqlite3_initialize();
14637 if( rc ) return rc;
14638 #endif
14639 mutex = sqlite3MutexAlloc(SQLITE_MUTEX_STATIC_MASTER);
14640 sqlite3_mutex_enter(mutex);
14641 vfsUnlink(pVfs);
14642 if( makeDflt || vfsList==0 ){
14643 pVfs->pNext = vfsList;
14644 vfsList = pVfs;
14645 }else{
14646 pVfs->pNext = vfsList->pNext;
14647 vfsList->pNext = pVfs;
14649 assert(vfsList);
14650 sqlite3_mutex_leave(mutex);
14651 return SQLITE_OK;
14655 ** Unregister a VFS so that it is no longer accessible.
14657 SQLITE_API int sqlite3_vfs_unregister(sqlite3_vfs *pVfs){
14658 #if SQLITE_THREADSAFE
14659 sqlite3_mutex *mutex = sqlite3MutexAlloc(SQLITE_MUTEX_STATIC_MASTER);
14660 #endif
14661 sqlite3_mutex_enter(mutex);
14662 vfsUnlink(pVfs);
14663 sqlite3_mutex_leave(mutex);
14664 return SQLITE_OK;
14667 /************** End of os.c **************************************************/
14668 /************** Begin file fault.c *******************************************/
14670 ** 2008 Jan 22
14672 ** The author disclaims copyright to this source code. In place of
14673 ** a legal notice, here is a blessing:
14675 ** May you do good and not evil.
14676 ** May you find forgiveness for yourself and forgive others.
14677 ** May you share freely, never taking more than you give.
14679 *************************************************************************
14681 ** This file contains code to support the concept of "benign"
14682 ** malloc failures (when the xMalloc() or xRealloc() method of the
14683 ** sqlite3_mem_methods structure fails to allocate a block of memory
14684 ** and returns 0).
14686 ** Most malloc failures are non-benign. After they occur, SQLite
14687 ** abandons the current operation and returns an error code (usually
14688 ** SQLITE_NOMEM) to the user. However, sometimes a fault is not necessarily
14689 ** fatal. For example, if a malloc fails while resizing a hash table, this
14690 ** is completely recoverable simply by not carrying out the resize. The
14691 ** hash table will continue to function normally. So a malloc failure
14692 ** during a hash table resize is a benign fault.
14696 #ifndef SQLITE_OMIT_BUILTIN_TEST
14699 ** Global variables.
14701 typedef struct BenignMallocHooks BenignMallocHooks;
14702 static SQLITE_WSD struct BenignMallocHooks {
14703 void (*xBenignBegin)(void);
14704 void (*xBenignEnd)(void);
14705 } sqlite3Hooks = { 0, 0 };
14707 /* The "wsdHooks" macro will resolve to the appropriate BenignMallocHooks
14708 ** structure. If writable static data is unsupported on the target,
14709 ** we have to locate the state vector at run-time. In the more common
14710 ** case where writable static data is supported, wsdHooks can refer directly
14711 ** to the "sqlite3Hooks" state vector declared above.
14713 #ifdef SQLITE_OMIT_WSD
14714 # define wsdHooksInit \
14715 BenignMallocHooks *x = &GLOBAL(BenignMallocHooks,sqlite3Hooks)
14716 # define wsdHooks x[0]
14717 #else
14718 # define wsdHooksInit
14719 # define wsdHooks sqlite3Hooks
14720 #endif
14724 ** Register hooks to call when sqlite3BeginBenignMalloc() and
14725 ** sqlite3EndBenignMalloc() are called, respectively.
14727 SQLITE_PRIVATE void sqlite3BenignMallocHooks(
14728 void (*xBenignBegin)(void),
14729 void (*xBenignEnd)(void)
14731 wsdHooksInit;
14732 wsdHooks.xBenignBegin = xBenignBegin;
14733 wsdHooks.xBenignEnd = xBenignEnd;
14737 ** This (sqlite3EndBenignMalloc()) is called by SQLite code to indicate that
14738 ** subsequent malloc failures are benign. A call to sqlite3EndBenignMalloc()
14739 ** indicates that subsequent malloc failures are non-benign.
14741 SQLITE_PRIVATE void sqlite3BeginBenignMalloc(void){
14742 wsdHooksInit;
14743 if( wsdHooks.xBenignBegin ){
14744 wsdHooks.xBenignBegin();
14747 SQLITE_PRIVATE void sqlite3EndBenignMalloc(void){
14748 wsdHooksInit;
14749 if( wsdHooks.xBenignEnd ){
14750 wsdHooks.xBenignEnd();
14754 #endif /* #ifndef SQLITE_OMIT_BUILTIN_TEST */
14756 /************** End of fault.c ***********************************************/
14757 /************** Begin file mem0.c ********************************************/
14759 ** 2008 October 28
14761 ** The author disclaims copyright to this source code. In place of
14762 ** a legal notice, here is a blessing:
14764 ** May you do good and not evil.
14765 ** May you find forgiveness for yourself and forgive others.
14766 ** May you share freely, never taking more than you give.
14768 *************************************************************************
14770 ** This file contains a no-op memory allocation drivers for use when
14771 ** SQLITE_ZERO_MALLOC is defined. The allocation drivers implemented
14772 ** here always fail. SQLite will not operate with these drivers. These
14773 ** are merely placeholders. Real drivers must be substituted using
14774 ** sqlite3_config() before SQLite will operate.
14778 ** This version of the memory allocator is the default. It is
14779 ** used when no other memory allocator is specified using compile-time
14780 ** macros.
14782 #ifdef SQLITE_ZERO_MALLOC
14785 ** No-op versions of all memory allocation routines
14787 static void *sqlite3MemMalloc(int nByte){ return 0; }
14788 static void sqlite3MemFree(void *pPrior){ return; }
14789 static void *sqlite3MemRealloc(void *pPrior, int nByte){ return 0; }
14790 static int sqlite3MemSize(void *pPrior){ return 0; }
14791 static int sqlite3MemRoundup(int n){ return n; }
14792 static int sqlite3MemInit(void *NotUsed){ return SQLITE_OK; }
14793 static void sqlite3MemShutdown(void *NotUsed){ return; }
14796 ** This routine is the only routine in this file with external linkage.
14798 ** Populate the low-level memory allocation function pointers in
14799 ** sqlite3GlobalConfig.m with pointers to the routines in this file.
14801 SQLITE_PRIVATE void sqlite3MemSetDefault(void){
14802 static const sqlite3_mem_methods defaultMethods = {
14803 sqlite3MemMalloc,
14804 sqlite3MemFree,
14805 sqlite3MemRealloc,
14806 sqlite3MemSize,
14807 sqlite3MemRoundup,
14808 sqlite3MemInit,
14809 sqlite3MemShutdown,
14812 sqlite3_config(SQLITE_CONFIG_MALLOC, &defaultMethods);
14815 #endif /* SQLITE_ZERO_MALLOC */
14817 /************** End of mem0.c ************************************************/
14818 /************** Begin file mem1.c ********************************************/
14820 ** 2007 August 14
14822 ** The author disclaims copyright to this source code. In place of
14823 ** a legal notice, here is a blessing:
14825 ** May you do good and not evil.
14826 ** May you find forgiveness for yourself and forgive others.
14827 ** May you share freely, never taking more than you give.
14829 *************************************************************************
14831 ** This file contains low-level memory allocation drivers for when
14832 ** SQLite will use the standard C-library malloc/realloc/free interface
14833 ** to obtain the memory it needs.
14835 ** This file contains implementations of the low-level memory allocation
14836 ** routines specified in the sqlite3_mem_methods object.
14840 ** This version of the memory allocator is the default. It is
14841 ** used when no other memory allocator is specified using compile-time
14842 ** macros.
14844 #ifdef SQLITE_SYSTEM_MALLOC
14847 ** Like malloc(), but remember the size of the allocation
14848 ** so that we can find it later using sqlite3MemSize().
14850 ** For this low-level routine, we are guaranteed that nByte>0 because
14851 ** cases of nByte<=0 will be intercepted and dealt with by higher level
14852 ** routines.
14854 static void *sqlite3MemMalloc(int nByte){
14855 sqlite3_int64 *p;
14856 assert( nByte>0 );
14857 nByte = ROUND8(nByte);
14858 p = malloc( nByte+8 );
14859 if( p ){
14860 p[0] = nByte;
14861 p++;
14862 }else{
14863 testcase( sqlite3GlobalConfig.xLog!=0 );
14864 sqlite3_log(SQLITE_NOMEM, "failed to allocate %u bytes of memory", nByte);
14866 return (void *)p;
14870 ** Like free() but works for allocations obtained from sqlite3MemMalloc()
14871 ** or sqlite3MemRealloc().
14873 ** For this low-level routine, we already know that pPrior!=0 since
14874 ** cases where pPrior==0 will have been intecepted and dealt with
14875 ** by higher-level routines.
14877 static void sqlite3MemFree(void *pPrior){
14878 sqlite3_int64 *p = (sqlite3_int64*)pPrior;
14879 assert( pPrior!=0 );
14880 p--;
14881 free(p);
14885 ** Report the allocated size of a prior return from xMalloc()
14886 ** or xRealloc().
14888 static int sqlite3MemSize(void *pPrior){
14889 sqlite3_int64 *p;
14890 if( pPrior==0 ) return 0;
14891 p = (sqlite3_int64*)pPrior;
14892 p--;
14893 return (int)p[0];
14897 ** Like realloc(). Resize an allocation previously obtained from
14898 ** sqlite3MemMalloc().
14900 ** For this low-level interface, we know that pPrior!=0. Cases where
14901 ** pPrior==0 while have been intercepted by higher-level routine and
14902 ** redirected to xMalloc. Similarly, we know that nByte>0 becauses
14903 ** cases where nByte<=0 will have been intercepted by higher-level
14904 ** routines and redirected to xFree.
14906 static void *sqlite3MemRealloc(void *pPrior, int nByte){
14907 sqlite3_int64 *p = (sqlite3_int64*)pPrior;
14908 assert( pPrior!=0 && nByte>0 );
14909 assert( nByte==ROUND8(nByte) ); /* EV: R-46199-30249 */
14910 p--;
14911 p = realloc(p, nByte+8 );
14912 if( p ){
14913 p[0] = nByte;
14914 p++;
14915 }else{
14916 testcase( sqlite3GlobalConfig.xLog!=0 );
14917 sqlite3_log(SQLITE_NOMEM,
14918 "failed memory resize %u to %u bytes",
14919 sqlite3MemSize(pPrior), nByte);
14921 return (void*)p;
14925 ** Round up a request size to the next valid allocation size.
14927 static int sqlite3MemRoundup(int n){
14928 return ROUND8(n);
14932 ** Initialize this module.
14934 static int sqlite3MemInit(void *NotUsed){
14935 UNUSED_PARAMETER(NotUsed);
14936 return SQLITE_OK;
14940 ** Deinitialize this module.
14942 static void sqlite3MemShutdown(void *NotUsed){
14943 UNUSED_PARAMETER(NotUsed);
14944 return;
14948 ** This routine is the only routine in this file with external linkage.
14950 ** Populate the low-level memory allocation function pointers in
14951 ** sqlite3GlobalConfig.m with pointers to the routines in this file.
14953 SQLITE_PRIVATE void sqlite3MemSetDefault(void){
14954 static const sqlite3_mem_methods defaultMethods = {
14955 sqlite3MemMalloc,
14956 sqlite3MemFree,
14957 sqlite3MemRealloc,
14958 sqlite3MemSize,
14959 sqlite3MemRoundup,
14960 sqlite3MemInit,
14961 sqlite3MemShutdown,
14964 sqlite3_config(SQLITE_CONFIG_MALLOC, &defaultMethods);
14967 #endif /* SQLITE_SYSTEM_MALLOC */
14969 /************** End of mem1.c ************************************************/
14970 /************** Begin file mem2.c ********************************************/
14972 ** 2007 August 15
14974 ** The author disclaims copyright to this source code. In place of
14975 ** a legal notice, here is a blessing:
14977 ** May you do good and not evil.
14978 ** May you find forgiveness for yourself and forgive others.
14979 ** May you share freely, never taking more than you give.
14981 *************************************************************************
14983 ** This file contains low-level memory allocation drivers for when
14984 ** SQLite will use the standard C-library malloc/realloc/free interface
14985 ** to obtain the memory it needs while adding lots of additional debugging
14986 ** information to each allocation in order to help detect and fix memory
14987 ** leaks and memory usage errors.
14989 ** This file contains implementations of the low-level memory allocation
14990 ** routines specified in the sqlite3_mem_methods object.
14994 ** This version of the memory allocator is used only if the
14995 ** SQLITE_MEMDEBUG macro is defined
14997 #ifdef SQLITE_MEMDEBUG
15000 ** The backtrace functionality is only available with GLIBC
15002 #ifdef __GLIBC__
15003 extern int backtrace(void**,int);
15004 extern void backtrace_symbols_fd(void*const*,int,int);
15005 #else
15006 # define backtrace(A,B) 1
15007 # define backtrace_symbols_fd(A,B,C)
15008 #endif
15009 /* #include <stdio.h> */
15012 ** Each memory allocation looks like this:
15014 ** ------------------------------------------------------------------------
15015 ** | Title | backtrace pointers | MemBlockHdr | allocation | EndGuard |
15016 ** ------------------------------------------------------------------------
15018 ** The application code sees only a pointer to the allocation. We have
15019 ** to back up from the allocation pointer to find the MemBlockHdr. The
15020 ** MemBlockHdr tells us the size of the allocation and the number of
15021 ** backtrace pointers. There is also a guard word at the end of the
15022 ** MemBlockHdr.
15024 struct MemBlockHdr {
15025 i64 iSize; /* Size of this allocation */
15026 struct MemBlockHdr *pNext, *pPrev; /* Linked list of all unfreed memory */
15027 char nBacktrace; /* Number of backtraces on this alloc */
15028 char nBacktraceSlots; /* Available backtrace slots */
15029 u8 nTitle; /* Bytes of title; includes '\0' */
15030 u8 eType; /* Allocation type code */
15031 int iForeGuard; /* Guard word for sanity */
15035 ** Guard words
15037 #define FOREGUARD 0x80F5E153
15038 #define REARGUARD 0xE4676B53
15041 ** Number of malloc size increments to track.
15043 #define NCSIZE 1000
15046 ** All of the static variables used by this module are collected
15047 ** into a single structure named "mem". This is to keep the
15048 ** static variables organized and to reduce namespace pollution
15049 ** when this module is combined with other in the amalgamation.
15051 static struct {
15054 ** Mutex to control access to the memory allocation subsystem.
15056 sqlite3_mutex *mutex;
15059 ** Head and tail of a linked list of all outstanding allocations
15061 struct MemBlockHdr *pFirst;
15062 struct MemBlockHdr *pLast;
15065 ** The number of levels of backtrace to save in new allocations.
15067 int nBacktrace;
15068 void (*xBacktrace)(int, int, void **);
15071 ** Title text to insert in front of each block
15073 int nTitle; /* Bytes of zTitle to save. Includes '\0' and padding */
15074 char zTitle[100]; /* The title text */
15077 ** sqlite3MallocDisallow() increments the following counter.
15078 ** sqlite3MallocAllow() decrements it.
15080 int disallow; /* Do not allow memory allocation */
15083 ** Gather statistics on the sizes of memory allocations.
15084 ** nAlloc[i] is the number of allocation attempts of i*8
15085 ** bytes. i==NCSIZE is the number of allocation attempts for
15086 ** sizes more than NCSIZE*8 bytes.
15088 int nAlloc[NCSIZE]; /* Total number of allocations */
15089 int nCurrent[NCSIZE]; /* Current number of allocations */
15090 int mxCurrent[NCSIZE]; /* Highwater mark for nCurrent */
15092 } mem;
15096 ** Adjust memory usage statistics
15098 static void adjustStats(int iSize, int increment){
15099 int i = ROUND8(iSize)/8;
15100 if( i>NCSIZE-1 ){
15101 i = NCSIZE - 1;
15103 if( increment>0 ){
15104 mem.nAlloc[i]++;
15105 mem.nCurrent[i]++;
15106 if( mem.nCurrent[i]>mem.mxCurrent[i] ){
15107 mem.mxCurrent[i] = mem.nCurrent[i];
15109 }else{
15110 mem.nCurrent[i]--;
15111 assert( mem.nCurrent[i]>=0 );
15116 ** Given an allocation, find the MemBlockHdr for that allocation.
15118 ** This routine checks the guards at either end of the allocation and
15119 ** if they are incorrect it asserts.
15121 static struct MemBlockHdr *sqlite3MemsysGetHeader(void *pAllocation){
15122 struct MemBlockHdr *p;
15123 int *pInt;
15124 u8 *pU8;
15125 int nReserve;
15127 p = (struct MemBlockHdr*)pAllocation;
15128 p--;
15129 assert( p->iForeGuard==(int)FOREGUARD );
15130 nReserve = ROUND8(p->iSize);
15131 pInt = (int*)pAllocation;
15132 pU8 = (u8*)pAllocation;
15133 assert( pInt[nReserve/sizeof(int)]==(int)REARGUARD );
15134 /* This checks any of the "extra" bytes allocated due
15135 ** to rounding up to an 8 byte boundary to ensure
15136 ** they haven't been overwritten.
15138 while( nReserve-- > p->iSize ) assert( pU8[nReserve]==0x65 );
15139 return p;
15143 ** Return the number of bytes currently allocated at address p.
15145 static int sqlite3MemSize(void *p){
15146 struct MemBlockHdr *pHdr;
15147 if( !p ){
15148 return 0;
15150 pHdr = sqlite3MemsysGetHeader(p);
15151 return pHdr->iSize;
15155 ** Initialize the memory allocation subsystem.
15157 static int sqlite3MemInit(void *NotUsed){
15158 UNUSED_PARAMETER(NotUsed);
15159 assert( (sizeof(struct MemBlockHdr)&7) == 0 );
15160 if( !sqlite3GlobalConfig.bMemstat ){
15161 /* If memory status is enabled, then the malloc.c wrapper will already
15162 ** hold the STATIC_MEM mutex when the routines here are invoked. */
15163 mem.mutex = sqlite3MutexAlloc(SQLITE_MUTEX_STATIC_MEM);
15165 return SQLITE_OK;
15169 ** Deinitialize the memory allocation subsystem.
15171 static void sqlite3MemShutdown(void *NotUsed){
15172 UNUSED_PARAMETER(NotUsed);
15173 mem.mutex = 0;
15177 ** Round up a request size to the next valid allocation size.
15179 static int sqlite3MemRoundup(int n){
15180 return ROUND8(n);
15184 ** Fill a buffer with pseudo-random bytes. This is used to preset
15185 ** the content of a new memory allocation to unpredictable values and
15186 ** to clear the content of a freed allocation to unpredictable values.
15188 static void randomFill(char *pBuf, int nByte){
15189 unsigned int x, y, r;
15190 x = SQLITE_PTR_TO_INT(pBuf);
15191 y = nByte | 1;
15192 while( nByte >= 4 ){
15193 x = (x>>1) ^ (-(x&1) & 0xd0000001);
15194 y = y*1103515245 + 12345;
15195 r = x ^ y;
15196 *(int*)pBuf = r;
15197 pBuf += 4;
15198 nByte -= 4;
15200 while( nByte-- > 0 ){
15201 x = (x>>1) ^ (-(x&1) & 0xd0000001);
15202 y = y*1103515245 + 12345;
15203 r = x ^ y;
15204 *(pBuf++) = r & 0xff;
15209 ** Allocate nByte bytes of memory.
15211 static void *sqlite3MemMalloc(int nByte){
15212 struct MemBlockHdr *pHdr;
15213 void **pBt;
15214 char *z;
15215 int *pInt;
15216 void *p = 0;
15217 int totalSize;
15218 int nReserve;
15219 sqlite3_mutex_enter(mem.mutex);
15220 assert( mem.disallow==0 );
15221 nReserve = ROUND8(nByte);
15222 totalSize = nReserve + sizeof(*pHdr) + sizeof(int) +
15223 mem.nBacktrace*sizeof(void*) + mem.nTitle;
15224 p = malloc(totalSize);
15225 if( p ){
15226 z = p;
15227 pBt = (void**)&z[mem.nTitle];
15228 pHdr = (struct MemBlockHdr*)&pBt[mem.nBacktrace];
15229 pHdr->pNext = 0;
15230 pHdr->pPrev = mem.pLast;
15231 if( mem.pLast ){
15232 mem.pLast->pNext = pHdr;
15233 }else{
15234 mem.pFirst = pHdr;
15236 mem.pLast = pHdr;
15237 pHdr->iForeGuard = FOREGUARD;
15238 pHdr->eType = MEMTYPE_HEAP;
15239 pHdr->nBacktraceSlots = mem.nBacktrace;
15240 pHdr->nTitle = mem.nTitle;
15241 if( mem.nBacktrace ){
15242 void *aAddr[40];
15243 pHdr->nBacktrace = backtrace(aAddr, mem.nBacktrace+1)-1;
15244 memcpy(pBt, &aAddr[1], pHdr->nBacktrace*sizeof(void*));
15245 assert(pBt[0]);
15246 if( mem.xBacktrace ){
15247 mem.xBacktrace(nByte, pHdr->nBacktrace-1, &aAddr[1]);
15249 }else{
15250 pHdr->nBacktrace = 0;
15252 if( mem.nTitle ){
15253 memcpy(z, mem.zTitle, mem.nTitle);
15255 pHdr->iSize = nByte;
15256 adjustStats(nByte, +1);
15257 pInt = (int*)&pHdr[1];
15258 pInt[nReserve/sizeof(int)] = REARGUARD;
15259 randomFill((char*)pInt, nByte);
15260 memset(((char*)pInt)+nByte, 0x65, nReserve-nByte);
15261 p = (void*)pInt;
15263 sqlite3_mutex_leave(mem.mutex);
15264 return p;
15268 ** Free memory.
15270 static void sqlite3MemFree(void *pPrior){
15271 struct MemBlockHdr *pHdr;
15272 void **pBt;
15273 char *z;
15274 assert( sqlite3GlobalConfig.bMemstat || sqlite3GlobalConfig.bCoreMutex==0
15275 || mem.mutex!=0 );
15276 pHdr = sqlite3MemsysGetHeader(pPrior);
15277 pBt = (void**)pHdr;
15278 pBt -= pHdr->nBacktraceSlots;
15279 sqlite3_mutex_enter(mem.mutex);
15280 if( pHdr->pPrev ){
15281 assert( pHdr->pPrev->pNext==pHdr );
15282 pHdr->pPrev->pNext = pHdr->pNext;
15283 }else{
15284 assert( mem.pFirst==pHdr );
15285 mem.pFirst = pHdr->pNext;
15287 if( pHdr->pNext ){
15288 assert( pHdr->pNext->pPrev==pHdr );
15289 pHdr->pNext->pPrev = pHdr->pPrev;
15290 }else{
15291 assert( mem.pLast==pHdr );
15292 mem.pLast = pHdr->pPrev;
15294 z = (char*)pBt;
15295 z -= pHdr->nTitle;
15296 adjustStats(pHdr->iSize, -1);
15297 randomFill(z, sizeof(void*)*pHdr->nBacktraceSlots + sizeof(*pHdr) +
15298 pHdr->iSize + sizeof(int) + pHdr->nTitle);
15299 free(z);
15300 sqlite3_mutex_leave(mem.mutex);
15304 ** Change the size of an existing memory allocation.
15306 ** For this debugging implementation, we *always* make a copy of the
15307 ** allocation into a new place in memory. In this way, if the
15308 ** higher level code is using pointer to the old allocation, it is
15309 ** much more likely to break and we are much more liking to find
15310 ** the error.
15312 static void *sqlite3MemRealloc(void *pPrior, int nByte){
15313 struct MemBlockHdr *pOldHdr;
15314 void *pNew;
15315 assert( mem.disallow==0 );
15316 assert( (nByte & 7)==0 ); /* EV: R-46199-30249 */
15317 pOldHdr = sqlite3MemsysGetHeader(pPrior);
15318 pNew = sqlite3MemMalloc(nByte);
15319 if( pNew ){
15320 memcpy(pNew, pPrior, nByte<pOldHdr->iSize ? nByte : pOldHdr->iSize);
15321 if( nByte>pOldHdr->iSize ){
15322 randomFill(&((char*)pNew)[pOldHdr->iSize], nByte - pOldHdr->iSize);
15324 sqlite3MemFree(pPrior);
15326 return pNew;
15330 ** Populate the low-level memory allocation function pointers in
15331 ** sqlite3GlobalConfig.m with pointers to the routines in this file.
15333 SQLITE_PRIVATE void sqlite3MemSetDefault(void){
15334 static const sqlite3_mem_methods defaultMethods = {
15335 sqlite3MemMalloc,
15336 sqlite3MemFree,
15337 sqlite3MemRealloc,
15338 sqlite3MemSize,
15339 sqlite3MemRoundup,
15340 sqlite3MemInit,
15341 sqlite3MemShutdown,
15344 sqlite3_config(SQLITE_CONFIG_MALLOC, &defaultMethods);
15348 ** Set the "type" of an allocation.
15350 SQLITE_PRIVATE void sqlite3MemdebugSetType(void *p, u8 eType){
15351 if( p && sqlite3GlobalConfig.m.xMalloc==sqlite3MemMalloc ){
15352 struct MemBlockHdr *pHdr;
15353 pHdr = sqlite3MemsysGetHeader(p);
15354 assert( pHdr->iForeGuard==FOREGUARD );
15355 pHdr->eType = eType;
15360 ** Return TRUE if the mask of type in eType matches the type of the
15361 ** allocation p. Also return true if p==NULL.
15363 ** This routine is designed for use within an assert() statement, to
15364 ** verify the type of an allocation. For example:
15366 ** assert( sqlite3MemdebugHasType(p, MEMTYPE_DB) );
15368 SQLITE_PRIVATE int sqlite3MemdebugHasType(void *p, u8 eType){
15369 int rc = 1;
15370 if( p && sqlite3GlobalConfig.m.xMalloc==sqlite3MemMalloc ){
15371 struct MemBlockHdr *pHdr;
15372 pHdr = sqlite3MemsysGetHeader(p);
15373 assert( pHdr->iForeGuard==FOREGUARD ); /* Allocation is valid */
15374 if( (pHdr->eType&eType)==0 ){
15375 rc = 0;
15378 return rc;
15382 ** Return TRUE if the mask of type in eType matches no bits of the type of the
15383 ** allocation p. Also return true if p==NULL.
15385 ** This routine is designed for use within an assert() statement, to
15386 ** verify the type of an allocation. For example:
15388 ** assert( sqlite3MemdebugNoType(p, MEMTYPE_DB) );
15390 SQLITE_PRIVATE int sqlite3MemdebugNoType(void *p, u8 eType){
15391 int rc = 1;
15392 if( p && sqlite3GlobalConfig.m.xMalloc==sqlite3MemMalloc ){
15393 struct MemBlockHdr *pHdr;
15394 pHdr = sqlite3MemsysGetHeader(p);
15395 assert( pHdr->iForeGuard==FOREGUARD ); /* Allocation is valid */
15396 if( (pHdr->eType&eType)!=0 ){
15397 rc = 0;
15400 return rc;
15404 ** Set the number of backtrace levels kept for each allocation.
15405 ** A value of zero turns off backtracing. The number is always rounded
15406 ** up to a multiple of 2.
15408 SQLITE_PRIVATE void sqlite3MemdebugBacktrace(int depth){
15409 if( depth<0 ){ depth = 0; }
15410 if( depth>20 ){ depth = 20; }
15411 depth = (depth+1)&0xfe;
15412 mem.nBacktrace = depth;
15415 SQLITE_PRIVATE void sqlite3MemdebugBacktraceCallback(void (*xBacktrace)(int, int, void **)){
15416 mem.xBacktrace = xBacktrace;
15420 ** Set the title string for subsequent allocations.
15422 SQLITE_PRIVATE void sqlite3MemdebugSettitle(const char *zTitle){
15423 unsigned int n = sqlite3Strlen30(zTitle) + 1;
15424 sqlite3_mutex_enter(mem.mutex);
15425 if( n>=sizeof(mem.zTitle) ) n = sizeof(mem.zTitle)-1;
15426 memcpy(mem.zTitle, zTitle, n);
15427 mem.zTitle[n] = 0;
15428 mem.nTitle = ROUND8(n);
15429 sqlite3_mutex_leave(mem.mutex);
15432 SQLITE_PRIVATE void sqlite3MemdebugSync(){
15433 struct MemBlockHdr *pHdr;
15434 for(pHdr=mem.pFirst; pHdr; pHdr=pHdr->pNext){
15435 void **pBt = (void**)pHdr;
15436 pBt -= pHdr->nBacktraceSlots;
15437 mem.xBacktrace(pHdr->iSize, pHdr->nBacktrace-1, &pBt[1]);
15442 ** Open the file indicated and write a log of all unfreed memory
15443 ** allocations into that log.
15445 SQLITE_PRIVATE void sqlite3MemdebugDump(const char *zFilename){
15446 FILE *out;
15447 struct MemBlockHdr *pHdr;
15448 void **pBt;
15449 int i;
15450 out = fopen(zFilename, "w");
15451 if( out==0 ){
15452 fprintf(stderr, "** Unable to output memory debug output log: %s **\n",
15453 zFilename);
15454 return;
15456 for(pHdr=mem.pFirst; pHdr; pHdr=pHdr->pNext){
15457 char *z = (char*)pHdr;
15458 z -= pHdr->nBacktraceSlots*sizeof(void*) + pHdr->nTitle;
15459 fprintf(out, "**** %lld bytes at %p from %s ****\n",
15460 pHdr->iSize, &pHdr[1], pHdr->nTitle ? z : "???");
15461 if( pHdr->nBacktrace ){
15462 fflush(out);
15463 pBt = (void**)pHdr;
15464 pBt -= pHdr->nBacktraceSlots;
15465 backtrace_symbols_fd(pBt, pHdr->nBacktrace, fileno(out));
15466 fprintf(out, "\n");
15469 fprintf(out, "COUNTS:\n");
15470 for(i=0; i<NCSIZE-1; i++){
15471 if( mem.nAlloc[i] ){
15472 fprintf(out, " %5d: %10d %10d %10d\n",
15473 i*8, mem.nAlloc[i], mem.nCurrent[i], mem.mxCurrent[i]);
15476 if( mem.nAlloc[NCSIZE-1] ){
15477 fprintf(out, " %5d: %10d %10d %10d\n",
15478 NCSIZE*8-8, mem.nAlloc[NCSIZE-1],
15479 mem.nCurrent[NCSIZE-1], mem.mxCurrent[NCSIZE-1]);
15481 fclose(out);
15485 ** Return the number of times sqlite3MemMalloc() has been called.
15487 SQLITE_PRIVATE int sqlite3MemdebugMallocCount(){
15488 int i;
15489 int nTotal = 0;
15490 for(i=0; i<NCSIZE; i++){
15491 nTotal += mem.nAlloc[i];
15493 return nTotal;
15497 #endif /* SQLITE_MEMDEBUG */
15499 /************** End of mem2.c ************************************************/
15500 /************** Begin file mem3.c ********************************************/
15502 ** 2007 October 14
15504 ** The author disclaims copyright to this source code. In place of
15505 ** a legal notice, here is a blessing:
15507 ** May you do good and not evil.
15508 ** May you find forgiveness for yourself and forgive others.
15509 ** May you share freely, never taking more than you give.
15511 *************************************************************************
15512 ** This file contains the C functions that implement a memory
15513 ** allocation subsystem for use by SQLite.
15515 ** This version of the memory allocation subsystem omits all
15516 ** use of malloc(). The SQLite user supplies a block of memory
15517 ** before calling sqlite3_initialize() from which allocations
15518 ** are made and returned by the xMalloc() and xRealloc()
15519 ** implementations. Once sqlite3_initialize() has been called,
15520 ** the amount of memory available to SQLite is fixed and cannot
15521 ** be changed.
15523 ** This version of the memory allocation subsystem is included
15524 ** in the build only if SQLITE_ENABLE_MEMSYS3 is defined.
15528 ** This version of the memory allocator is only built into the library
15529 ** SQLITE_ENABLE_MEMSYS3 is defined. Defining this symbol does not
15530 ** mean that the library will use a memory-pool by default, just that
15531 ** it is available. The mempool allocator is activated by calling
15532 ** sqlite3_config().
15534 #ifdef SQLITE_ENABLE_MEMSYS3
15537 ** Maximum size (in Mem3Blocks) of a "small" chunk.
15539 #define MX_SMALL 10
15543 ** Number of freelist hash slots
15545 #define N_HASH 61
15548 ** A memory allocation (also called a "chunk") consists of two or
15549 ** more blocks where each block is 8 bytes. The first 8 bytes are
15550 ** a header that is not returned to the user.
15552 ** A chunk is two or more blocks that is either checked out or
15553 ** free. The first block has format u.hdr. u.hdr.size4x is 4 times the
15554 ** size of the allocation in blocks if the allocation is free.
15555 ** The u.hdr.size4x&1 bit is true if the chunk is checked out and
15556 ** false if the chunk is on the freelist. The u.hdr.size4x&2 bit
15557 ** is true if the previous chunk is checked out and false if the
15558 ** previous chunk is free. The u.hdr.prevSize field is the size of
15559 ** the previous chunk in blocks if the previous chunk is on the
15560 ** freelist. If the previous chunk is checked out, then
15561 ** u.hdr.prevSize can be part of the data for that chunk and should
15562 ** not be read or written.
15564 ** We often identify a chunk by its index in mem3.aPool[]. When
15565 ** this is done, the chunk index refers to the second block of
15566 ** the chunk. In this way, the first chunk has an index of 1.
15567 ** A chunk index of 0 means "no such chunk" and is the equivalent
15568 ** of a NULL pointer.
15570 ** The second block of free chunks is of the form u.list. The
15571 ** two fields form a double-linked list of chunks of related sizes.
15572 ** Pointers to the head of the list are stored in mem3.aiSmall[]
15573 ** for smaller chunks and mem3.aiHash[] for larger chunks.
15575 ** The second block of a chunk is user data if the chunk is checked
15576 ** out. If a chunk is checked out, the user data may extend into
15577 ** the u.hdr.prevSize value of the following chunk.
15579 typedef struct Mem3Block Mem3Block;
15580 struct Mem3Block {
15581 union {
15582 struct {
15583 u32 prevSize; /* Size of previous chunk in Mem3Block elements */
15584 u32 size4x; /* 4x the size of current chunk in Mem3Block elements */
15585 } hdr;
15586 struct {
15587 u32 next; /* Index in mem3.aPool[] of next free chunk */
15588 u32 prev; /* Index in mem3.aPool[] of previous free chunk */
15589 } list;
15590 } u;
15594 ** All of the static variables used by this module are collected
15595 ** into a single structure named "mem3". This is to keep the
15596 ** static variables organized and to reduce namespace pollution
15597 ** when this module is combined with other in the amalgamation.
15599 static SQLITE_WSD struct Mem3Global {
15601 ** Memory available for allocation. nPool is the size of the array
15602 ** (in Mem3Blocks) pointed to by aPool less 2.
15604 u32 nPool;
15605 Mem3Block *aPool;
15608 ** True if we are evaluating an out-of-memory callback.
15610 int alarmBusy;
15613 ** Mutex to control access to the memory allocation subsystem.
15615 sqlite3_mutex *mutex;
15618 ** The minimum amount of free space that we have seen.
15620 u32 mnMaster;
15623 ** iMaster is the index of the master chunk. Most new allocations
15624 ** occur off of this chunk. szMaster is the size (in Mem3Blocks)
15625 ** of the current master. iMaster is 0 if there is not master chunk.
15626 ** The master chunk is not in either the aiHash[] or aiSmall[].
15628 u32 iMaster;
15629 u32 szMaster;
15632 ** Array of lists of free blocks according to the block size
15633 ** for smaller chunks, or a hash on the block size for larger
15634 ** chunks.
15636 u32 aiSmall[MX_SMALL-1]; /* For sizes 2 through MX_SMALL, inclusive */
15637 u32 aiHash[N_HASH]; /* For sizes MX_SMALL+1 and larger */
15638 } mem3 = { 97535575 };
15640 #define mem3 GLOBAL(struct Mem3Global, mem3)
15643 ** Unlink the chunk at mem3.aPool[i] from list it is currently
15644 ** on. *pRoot is the list that i is a member of.
15646 static void memsys3UnlinkFromList(u32 i, u32 *pRoot){
15647 u32 next = mem3.aPool[i].u.list.next;
15648 u32 prev = mem3.aPool[i].u.list.prev;
15649 assert( sqlite3_mutex_held(mem3.mutex) );
15650 if( prev==0 ){
15651 *pRoot = next;
15652 }else{
15653 mem3.aPool[prev].u.list.next = next;
15655 if( next ){
15656 mem3.aPool[next].u.list.prev = prev;
15658 mem3.aPool[i].u.list.next = 0;
15659 mem3.aPool[i].u.list.prev = 0;
15663 ** Unlink the chunk at index i from
15664 ** whatever list is currently a member of.
15666 static void memsys3Unlink(u32 i){
15667 u32 size, hash;
15668 assert( sqlite3_mutex_held(mem3.mutex) );
15669 assert( (mem3.aPool[i-1].u.hdr.size4x & 1)==0 );
15670 assert( i>=1 );
15671 size = mem3.aPool[i-1].u.hdr.size4x/4;
15672 assert( size==mem3.aPool[i+size-1].u.hdr.prevSize );
15673 assert( size>=2 );
15674 if( size <= MX_SMALL ){
15675 memsys3UnlinkFromList(i, &mem3.aiSmall[size-2]);
15676 }else{
15677 hash = size % N_HASH;
15678 memsys3UnlinkFromList(i, &mem3.aiHash[hash]);
15683 ** Link the chunk at mem3.aPool[i] so that is on the list rooted
15684 ** at *pRoot.
15686 static void memsys3LinkIntoList(u32 i, u32 *pRoot){
15687 assert( sqlite3_mutex_held(mem3.mutex) );
15688 mem3.aPool[i].u.list.next = *pRoot;
15689 mem3.aPool[i].u.list.prev = 0;
15690 if( *pRoot ){
15691 mem3.aPool[*pRoot].u.list.prev = i;
15693 *pRoot = i;
15697 ** Link the chunk at index i into either the appropriate
15698 ** small chunk list, or into the large chunk hash table.
15700 static void memsys3Link(u32 i){
15701 u32 size, hash;
15702 assert( sqlite3_mutex_held(mem3.mutex) );
15703 assert( i>=1 );
15704 assert( (mem3.aPool[i-1].u.hdr.size4x & 1)==0 );
15705 size = mem3.aPool[i-1].u.hdr.size4x/4;
15706 assert( size==mem3.aPool[i+size-1].u.hdr.prevSize );
15707 assert( size>=2 );
15708 if( size <= MX_SMALL ){
15709 memsys3LinkIntoList(i, &mem3.aiSmall[size-2]);
15710 }else{
15711 hash = size % N_HASH;
15712 memsys3LinkIntoList(i, &mem3.aiHash[hash]);
15717 ** If the STATIC_MEM mutex is not already held, obtain it now. The mutex
15718 ** will already be held (obtained by code in malloc.c) if
15719 ** sqlite3GlobalConfig.bMemStat is true.
15721 static void memsys3Enter(void){
15722 if( sqlite3GlobalConfig.bMemstat==0 && mem3.mutex==0 ){
15723 mem3.mutex = sqlite3MutexAlloc(SQLITE_MUTEX_STATIC_MEM);
15725 sqlite3_mutex_enter(mem3.mutex);
15727 static void memsys3Leave(void){
15728 sqlite3_mutex_leave(mem3.mutex);
15732 ** Called when we are unable to satisfy an allocation of nBytes.
15734 static void memsys3OutOfMemory(int nByte){
15735 if( !mem3.alarmBusy ){
15736 mem3.alarmBusy = 1;
15737 assert( sqlite3_mutex_held(mem3.mutex) );
15738 sqlite3_mutex_leave(mem3.mutex);
15739 sqlite3_release_memory(nByte);
15740 sqlite3_mutex_enter(mem3.mutex);
15741 mem3.alarmBusy = 0;
15747 ** Chunk i is a free chunk that has been unlinked. Adjust its
15748 ** size parameters for check-out and return a pointer to the
15749 ** user portion of the chunk.
15751 static void *memsys3Checkout(u32 i, u32 nBlock){
15752 u32 x;
15753 assert( sqlite3_mutex_held(mem3.mutex) );
15754 assert( i>=1 );
15755 assert( mem3.aPool[i-1].u.hdr.size4x/4==nBlock );
15756 assert( mem3.aPool[i+nBlock-1].u.hdr.prevSize==nBlock );
15757 x = mem3.aPool[i-1].u.hdr.size4x;
15758 mem3.aPool[i-1].u.hdr.size4x = nBlock*4 | 1 | (x&2);
15759 mem3.aPool[i+nBlock-1].u.hdr.prevSize = nBlock;
15760 mem3.aPool[i+nBlock-1].u.hdr.size4x |= 2;
15761 return &mem3.aPool[i];
15765 ** Carve a piece off of the end of the mem3.iMaster free chunk.
15766 ** Return a pointer to the new allocation. Or, if the master chunk
15767 ** is not large enough, return 0.
15769 static void *memsys3FromMaster(u32 nBlock){
15770 assert( sqlite3_mutex_held(mem3.mutex) );
15771 assert( mem3.szMaster>=nBlock );
15772 if( nBlock>=mem3.szMaster-1 ){
15773 /* Use the entire master */
15774 void *p = memsys3Checkout(mem3.iMaster, mem3.szMaster);
15775 mem3.iMaster = 0;
15776 mem3.szMaster = 0;
15777 mem3.mnMaster = 0;
15778 return p;
15779 }else{
15780 /* Split the master block. Return the tail. */
15781 u32 newi, x;
15782 newi = mem3.iMaster + mem3.szMaster - nBlock;
15783 assert( newi > mem3.iMaster+1 );
15784 mem3.aPool[mem3.iMaster+mem3.szMaster-1].u.hdr.prevSize = nBlock;
15785 mem3.aPool[mem3.iMaster+mem3.szMaster-1].u.hdr.size4x |= 2;
15786 mem3.aPool[newi-1].u.hdr.size4x = nBlock*4 + 1;
15787 mem3.szMaster -= nBlock;
15788 mem3.aPool[newi-1].u.hdr.prevSize = mem3.szMaster;
15789 x = mem3.aPool[mem3.iMaster-1].u.hdr.size4x & 2;
15790 mem3.aPool[mem3.iMaster-1].u.hdr.size4x = mem3.szMaster*4 | x;
15791 if( mem3.szMaster < mem3.mnMaster ){
15792 mem3.mnMaster = mem3.szMaster;
15794 return (void*)&mem3.aPool[newi];
15799 ** *pRoot is the head of a list of free chunks of the same size
15800 ** or same size hash. In other words, *pRoot is an entry in either
15801 ** mem3.aiSmall[] or mem3.aiHash[].
15803 ** This routine examines all entries on the given list and tries
15804 ** to coalesce each entries with adjacent free chunks.
15806 ** If it sees a chunk that is larger than mem3.iMaster, it replaces
15807 ** the current mem3.iMaster with the new larger chunk. In order for
15808 ** this mem3.iMaster replacement to work, the master chunk must be
15809 ** linked into the hash tables. That is not the normal state of
15810 ** affairs, of course. The calling routine must link the master
15811 ** chunk before invoking this routine, then must unlink the (possibly
15812 ** changed) master chunk once this routine has finished.
15814 static void memsys3Merge(u32 *pRoot){
15815 u32 iNext, prev, size, i, x;
15817 assert( sqlite3_mutex_held(mem3.mutex) );
15818 for(i=*pRoot; i>0; i=iNext){
15819 iNext = mem3.aPool[i].u.list.next;
15820 size = mem3.aPool[i-1].u.hdr.size4x;
15821 assert( (size&1)==0 );
15822 if( (size&2)==0 ){
15823 memsys3UnlinkFromList(i, pRoot);
15824 assert( i > mem3.aPool[i-1].u.hdr.prevSize );
15825 prev = i - mem3.aPool[i-1].u.hdr.prevSize;
15826 if( prev==iNext ){
15827 iNext = mem3.aPool[prev].u.list.next;
15829 memsys3Unlink(prev);
15830 size = i + size/4 - prev;
15831 x = mem3.aPool[prev-1].u.hdr.size4x & 2;
15832 mem3.aPool[prev-1].u.hdr.size4x = size*4 | x;
15833 mem3.aPool[prev+size-1].u.hdr.prevSize = size;
15834 memsys3Link(prev);
15835 i = prev;
15836 }else{
15837 size /= 4;
15839 if( size>mem3.szMaster ){
15840 mem3.iMaster = i;
15841 mem3.szMaster = size;
15847 ** Return a block of memory of at least nBytes in size.
15848 ** Return NULL if unable.
15850 ** This function assumes that the necessary mutexes, if any, are
15851 ** already held by the caller. Hence "Unsafe".
15853 static void *memsys3MallocUnsafe(int nByte){
15854 u32 i;
15855 u32 nBlock;
15856 u32 toFree;
15858 assert( sqlite3_mutex_held(mem3.mutex) );
15859 assert( sizeof(Mem3Block)==8 );
15860 if( nByte<=12 ){
15861 nBlock = 2;
15862 }else{
15863 nBlock = (nByte + 11)/8;
15865 assert( nBlock>=2 );
15867 /* STEP 1:
15868 ** Look for an entry of the correct size in either the small
15869 ** chunk table or in the large chunk hash table. This is
15870 ** successful most of the time (about 9 times out of 10).
15872 if( nBlock <= MX_SMALL ){
15873 i = mem3.aiSmall[nBlock-2];
15874 if( i>0 ){
15875 memsys3UnlinkFromList(i, &mem3.aiSmall[nBlock-2]);
15876 return memsys3Checkout(i, nBlock);
15878 }else{
15879 int hash = nBlock % N_HASH;
15880 for(i=mem3.aiHash[hash]; i>0; i=mem3.aPool[i].u.list.next){
15881 if( mem3.aPool[i-1].u.hdr.size4x/4==nBlock ){
15882 memsys3UnlinkFromList(i, &mem3.aiHash[hash]);
15883 return memsys3Checkout(i, nBlock);
15888 /* STEP 2:
15889 ** Try to satisfy the allocation by carving a piece off of the end
15890 ** of the master chunk. This step usually works if step 1 fails.
15892 if( mem3.szMaster>=nBlock ){
15893 return memsys3FromMaster(nBlock);
15897 /* STEP 3:
15898 ** Loop through the entire memory pool. Coalesce adjacent free
15899 ** chunks. Recompute the master chunk as the largest free chunk.
15900 ** Then try again to satisfy the allocation by carving a piece off
15901 ** of the end of the master chunk. This step happens very
15902 ** rarely (we hope!)
15904 for(toFree=nBlock*16; toFree<(mem3.nPool*16); toFree *= 2){
15905 memsys3OutOfMemory(toFree);
15906 if( mem3.iMaster ){
15907 memsys3Link(mem3.iMaster);
15908 mem3.iMaster = 0;
15909 mem3.szMaster = 0;
15911 for(i=0; i<N_HASH; i++){
15912 memsys3Merge(&mem3.aiHash[i]);
15914 for(i=0; i<MX_SMALL-1; i++){
15915 memsys3Merge(&mem3.aiSmall[i]);
15917 if( mem3.szMaster ){
15918 memsys3Unlink(mem3.iMaster);
15919 if( mem3.szMaster>=nBlock ){
15920 return memsys3FromMaster(nBlock);
15925 /* If none of the above worked, then we fail. */
15926 return 0;
15930 ** Free an outstanding memory allocation.
15932 ** This function assumes that the necessary mutexes, if any, are
15933 ** already held by the caller. Hence "Unsafe".
15935 static void memsys3FreeUnsafe(void *pOld){
15936 Mem3Block *p = (Mem3Block*)pOld;
15937 int i;
15938 u32 size, x;
15939 assert( sqlite3_mutex_held(mem3.mutex) );
15940 assert( p>mem3.aPool && p<&mem3.aPool[mem3.nPool] );
15941 i = p - mem3.aPool;
15942 assert( (mem3.aPool[i-1].u.hdr.size4x&1)==1 );
15943 size = mem3.aPool[i-1].u.hdr.size4x/4;
15944 assert( i+size<=mem3.nPool+1 );
15945 mem3.aPool[i-1].u.hdr.size4x &= ~1;
15946 mem3.aPool[i+size-1].u.hdr.prevSize = size;
15947 mem3.aPool[i+size-1].u.hdr.size4x &= ~2;
15948 memsys3Link(i);
15950 /* Try to expand the master using the newly freed chunk */
15951 if( mem3.iMaster ){
15952 while( (mem3.aPool[mem3.iMaster-1].u.hdr.size4x&2)==0 ){
15953 size = mem3.aPool[mem3.iMaster-1].u.hdr.prevSize;
15954 mem3.iMaster -= size;
15955 mem3.szMaster += size;
15956 memsys3Unlink(mem3.iMaster);
15957 x = mem3.aPool[mem3.iMaster-1].u.hdr.size4x & 2;
15958 mem3.aPool[mem3.iMaster-1].u.hdr.size4x = mem3.szMaster*4 | x;
15959 mem3.aPool[mem3.iMaster+mem3.szMaster-1].u.hdr.prevSize = mem3.szMaster;
15961 x = mem3.aPool[mem3.iMaster-1].u.hdr.size4x & 2;
15962 while( (mem3.aPool[mem3.iMaster+mem3.szMaster-1].u.hdr.size4x&1)==0 ){
15963 memsys3Unlink(mem3.iMaster+mem3.szMaster);
15964 mem3.szMaster += mem3.aPool[mem3.iMaster+mem3.szMaster-1].u.hdr.size4x/4;
15965 mem3.aPool[mem3.iMaster-1].u.hdr.size4x = mem3.szMaster*4 | x;
15966 mem3.aPool[mem3.iMaster+mem3.szMaster-1].u.hdr.prevSize = mem3.szMaster;
15972 ** Return the size of an outstanding allocation, in bytes. The
15973 ** size returned omits the 8-byte header overhead. This only
15974 ** works for chunks that are currently checked out.
15976 static int memsys3Size(void *p){
15977 Mem3Block *pBlock;
15978 if( p==0 ) return 0;
15979 pBlock = (Mem3Block*)p;
15980 assert( (pBlock[-1].u.hdr.size4x&1)!=0 );
15981 return (pBlock[-1].u.hdr.size4x&~3)*2 - 4;
15985 ** Round up a request size to the next valid allocation size.
15987 static int memsys3Roundup(int n){
15988 if( n<=12 ){
15989 return 12;
15990 }else{
15991 return ((n+11)&~7) - 4;
15996 ** Allocate nBytes of memory.
15998 static void *memsys3Malloc(int nBytes){
15999 sqlite3_int64 *p;
16000 assert( nBytes>0 ); /* malloc.c filters out 0 byte requests */
16001 memsys3Enter();
16002 p = memsys3MallocUnsafe(nBytes);
16003 memsys3Leave();
16004 return (void*)p;
16008 ** Free memory.
16010 static void memsys3Free(void *pPrior){
16011 assert( pPrior );
16012 memsys3Enter();
16013 memsys3FreeUnsafe(pPrior);
16014 memsys3Leave();
16018 ** Change the size of an existing memory allocation
16020 static void *memsys3Realloc(void *pPrior, int nBytes){
16021 int nOld;
16022 void *p;
16023 if( pPrior==0 ){
16024 return sqlite3_malloc(nBytes);
16026 if( nBytes<=0 ){
16027 sqlite3_free(pPrior);
16028 return 0;
16030 nOld = memsys3Size(pPrior);
16031 if( nBytes<=nOld && nBytes>=nOld-128 ){
16032 return pPrior;
16034 memsys3Enter();
16035 p = memsys3MallocUnsafe(nBytes);
16036 if( p ){
16037 if( nOld<nBytes ){
16038 memcpy(p, pPrior, nOld);
16039 }else{
16040 memcpy(p, pPrior, nBytes);
16042 memsys3FreeUnsafe(pPrior);
16044 memsys3Leave();
16045 return p;
16049 ** Initialize this module.
16051 static int memsys3Init(void *NotUsed){
16052 UNUSED_PARAMETER(NotUsed);
16053 if( !sqlite3GlobalConfig.pHeap ){
16054 return SQLITE_ERROR;
16057 /* Store a pointer to the memory block in global structure mem3. */
16058 assert( sizeof(Mem3Block)==8 );
16059 mem3.aPool = (Mem3Block *)sqlite3GlobalConfig.pHeap;
16060 mem3.nPool = (sqlite3GlobalConfig.nHeap / sizeof(Mem3Block)) - 2;
16062 /* Initialize the master block. */
16063 mem3.szMaster = mem3.nPool;
16064 mem3.mnMaster = mem3.szMaster;
16065 mem3.iMaster = 1;
16066 mem3.aPool[0].u.hdr.size4x = (mem3.szMaster<<2) + 2;
16067 mem3.aPool[mem3.nPool].u.hdr.prevSize = mem3.nPool;
16068 mem3.aPool[mem3.nPool].u.hdr.size4x = 1;
16070 return SQLITE_OK;
16074 ** Deinitialize this module.
16076 static void memsys3Shutdown(void *NotUsed){
16077 UNUSED_PARAMETER(NotUsed);
16078 mem3.mutex = 0;
16079 return;
16085 ** Open the file indicated and write a log of all unfreed memory
16086 ** allocations into that log.
16088 SQLITE_PRIVATE void sqlite3Memsys3Dump(const char *zFilename){
16089 #ifdef SQLITE_DEBUG
16090 FILE *out;
16091 u32 i, j;
16092 u32 size;
16093 if( zFilename==0 || zFilename[0]==0 ){
16094 out = stdout;
16095 }else{
16096 out = fopen(zFilename, "w");
16097 if( out==0 ){
16098 fprintf(stderr, "** Unable to output memory debug output log: %s **\n",
16099 zFilename);
16100 return;
16103 memsys3Enter();
16104 fprintf(out, "CHUNKS:\n");
16105 for(i=1; i<=mem3.nPool; i+=size/4){
16106 size = mem3.aPool[i-1].u.hdr.size4x;
16107 if( size/4<=1 ){
16108 fprintf(out, "%p size error\n", &mem3.aPool[i]);
16109 assert( 0 );
16110 break;
16112 if( (size&1)==0 && mem3.aPool[i+size/4-1].u.hdr.prevSize!=size/4 ){
16113 fprintf(out, "%p tail size does not match\n", &mem3.aPool[i]);
16114 assert( 0 );
16115 break;
16117 if( ((mem3.aPool[i+size/4-1].u.hdr.size4x&2)>>1)!=(size&1) ){
16118 fprintf(out, "%p tail checkout bit is incorrect\n", &mem3.aPool[i]);
16119 assert( 0 );
16120 break;
16122 if( size&1 ){
16123 fprintf(out, "%p %6d bytes checked out\n", &mem3.aPool[i], (size/4)*8-8);
16124 }else{
16125 fprintf(out, "%p %6d bytes free%s\n", &mem3.aPool[i], (size/4)*8-8,
16126 i==mem3.iMaster ? " **master**" : "");
16129 for(i=0; i<MX_SMALL-1; i++){
16130 if( mem3.aiSmall[i]==0 ) continue;
16131 fprintf(out, "small(%2d):", i);
16132 for(j = mem3.aiSmall[i]; j>0; j=mem3.aPool[j].u.list.next){
16133 fprintf(out, " %p(%d)", &mem3.aPool[j],
16134 (mem3.aPool[j-1].u.hdr.size4x/4)*8-8);
16136 fprintf(out, "\n");
16138 for(i=0; i<N_HASH; i++){
16139 if( mem3.aiHash[i]==0 ) continue;
16140 fprintf(out, "hash(%2d):", i);
16141 for(j = mem3.aiHash[i]; j>0; j=mem3.aPool[j].u.list.next){
16142 fprintf(out, " %p(%d)", &mem3.aPool[j],
16143 (mem3.aPool[j-1].u.hdr.size4x/4)*8-8);
16145 fprintf(out, "\n");
16147 fprintf(out, "master=%d\n", mem3.iMaster);
16148 fprintf(out, "nowUsed=%d\n", mem3.nPool*8 - mem3.szMaster*8);
16149 fprintf(out, "mxUsed=%d\n", mem3.nPool*8 - mem3.mnMaster*8);
16150 sqlite3_mutex_leave(mem3.mutex);
16151 if( out==stdout ){
16152 fflush(stdout);
16153 }else{
16154 fclose(out);
16156 #else
16157 UNUSED_PARAMETER(zFilename);
16158 #endif
16162 ** This routine is the only routine in this file with external
16163 ** linkage.
16165 ** Populate the low-level memory allocation function pointers in
16166 ** sqlite3GlobalConfig.m with pointers to the routines in this file. The
16167 ** arguments specify the block of memory to manage.
16169 ** This routine is only called by sqlite3_config(), and therefore
16170 ** is not required to be threadsafe (it is not).
16172 SQLITE_PRIVATE const sqlite3_mem_methods *sqlite3MemGetMemsys3(void){
16173 static const sqlite3_mem_methods mempoolMethods = {
16174 memsys3Malloc,
16175 memsys3Free,
16176 memsys3Realloc,
16177 memsys3Size,
16178 memsys3Roundup,
16179 memsys3Init,
16180 memsys3Shutdown,
16183 return &mempoolMethods;
16186 #endif /* SQLITE_ENABLE_MEMSYS3 */
16188 /************** End of mem3.c ************************************************/
16189 /************** Begin file mem5.c ********************************************/
16191 ** 2007 October 14
16193 ** The author disclaims copyright to this source code. In place of
16194 ** a legal notice, here is a blessing:
16196 ** May you do good and not evil.
16197 ** May you find forgiveness for yourself and forgive others.
16198 ** May you share freely, never taking more than you give.
16200 *************************************************************************
16201 ** This file contains the C functions that implement a memory
16202 ** allocation subsystem for use by SQLite.
16204 ** This version of the memory allocation subsystem omits all
16205 ** use of malloc(). The application gives SQLite a block of memory
16206 ** before calling sqlite3_initialize() from which allocations
16207 ** are made and returned by the xMalloc() and xRealloc()
16208 ** implementations. Once sqlite3_initialize() has been called,
16209 ** the amount of memory available to SQLite is fixed and cannot
16210 ** be changed.
16212 ** This version of the memory allocation subsystem is included
16213 ** in the build only if SQLITE_ENABLE_MEMSYS5 is defined.
16215 ** This memory allocator uses the following algorithm:
16217 ** 1. All memory allocations sizes are rounded up to a power of 2.
16219 ** 2. If two adjacent free blocks are the halves of a larger block,
16220 ** then the two blocks are coalesed into the single larger block.
16222 ** 3. New memory is allocated from the first available free block.
16224 ** This algorithm is described in: J. M. Robson. "Bounds for Some Functions
16225 ** Concerning Dynamic Storage Allocation". Journal of the Association for
16226 ** Computing Machinery, Volume 21, Number 8, July 1974, pages 491-499.
16228 ** Let n be the size of the largest allocation divided by the minimum
16229 ** allocation size (after rounding all sizes up to a power of 2.) Let M
16230 ** be the maximum amount of memory ever outstanding at one time. Let
16231 ** N be the total amount of memory available for allocation. Robson
16232 ** proved that this memory allocator will never breakdown due to
16233 ** fragmentation as long as the following constraint holds:
16235 ** N >= M*(1 + log2(n)/2) - n + 1
16237 ** The sqlite3_status() logic tracks the maximum values of n and M so
16238 ** that an application can, at any time, verify this constraint.
16242 ** This version of the memory allocator is used only when
16243 ** SQLITE_ENABLE_MEMSYS5 is defined.
16245 #ifdef SQLITE_ENABLE_MEMSYS5
16248 ** A minimum allocation is an instance of the following structure.
16249 ** Larger allocations are an array of these structures where the
16250 ** size of the array is a power of 2.
16252 ** The size of this object must be a power of two. That fact is
16253 ** verified in memsys5Init().
16255 typedef struct Mem5Link Mem5Link;
16256 struct Mem5Link {
16257 int next; /* Index of next free chunk */
16258 int prev; /* Index of previous free chunk */
16262 ** Maximum size of any allocation is ((1<<LOGMAX)*mem5.szAtom). Since
16263 ** mem5.szAtom is always at least 8 and 32-bit integers are used,
16264 ** it is not actually possible to reach this limit.
16266 #define LOGMAX 30
16269 ** Masks used for mem5.aCtrl[] elements.
16271 #define CTRL_LOGSIZE 0x1f /* Log2 Size of this block */
16272 #define CTRL_FREE 0x20 /* True if not checked out */
16275 ** All of the static variables used by this module are collected
16276 ** into a single structure named "mem5". This is to keep the
16277 ** static variables organized and to reduce namespace pollution
16278 ** when this module is combined with other in the amalgamation.
16280 static SQLITE_WSD struct Mem5Global {
16282 ** Memory available for allocation
16284 int szAtom; /* Smallest possible allocation in bytes */
16285 int nBlock; /* Number of szAtom sized blocks in zPool */
16286 u8 *zPool; /* Memory available to be allocated */
16289 ** Mutex to control access to the memory allocation subsystem.
16291 sqlite3_mutex *mutex;
16294 ** Performance statistics
16296 u64 nAlloc; /* Total number of calls to malloc */
16297 u64 totalAlloc; /* Total of all malloc calls - includes internal frag */
16298 u64 totalExcess; /* Total internal fragmentation */
16299 u32 currentOut; /* Current checkout, including internal fragmentation */
16300 u32 currentCount; /* Current number of distinct checkouts */
16301 u32 maxOut; /* Maximum instantaneous currentOut */
16302 u32 maxCount; /* Maximum instantaneous currentCount */
16303 u32 maxRequest; /* Largest allocation (exclusive of internal frag) */
16306 ** Lists of free blocks. aiFreelist[0] is a list of free blocks of
16307 ** size mem5.szAtom. aiFreelist[1] holds blocks of size szAtom*2.
16308 ** and so forth.
16310 int aiFreelist[LOGMAX+1];
16313 ** Space for tracking which blocks are checked out and the size
16314 ** of each block. One byte per block.
16316 u8 *aCtrl;
16318 } mem5;
16321 ** Access the static variable through a macro for SQLITE_OMIT_WSD
16323 #define mem5 GLOBAL(struct Mem5Global, mem5)
16326 ** Assuming mem5.zPool is divided up into an array of Mem5Link
16327 ** structures, return a pointer to the idx-th such lik.
16329 #define MEM5LINK(idx) ((Mem5Link *)(&mem5.zPool[(idx)*mem5.szAtom]))
16332 ** Unlink the chunk at mem5.aPool[i] from list it is currently
16333 ** on. It should be found on mem5.aiFreelist[iLogsize].
16335 static void memsys5Unlink(int i, int iLogsize){
16336 int next, prev;
16337 assert( i>=0 && i<mem5.nBlock );
16338 assert( iLogsize>=0 && iLogsize<=LOGMAX );
16339 assert( (mem5.aCtrl[i] & CTRL_LOGSIZE)==iLogsize );
16341 next = MEM5LINK(i)->next;
16342 prev = MEM5LINK(i)->prev;
16343 if( prev<0 ){
16344 mem5.aiFreelist[iLogsize] = next;
16345 }else{
16346 MEM5LINK(prev)->next = next;
16348 if( next>=0 ){
16349 MEM5LINK(next)->prev = prev;
16354 ** Link the chunk at mem5.aPool[i] so that is on the iLogsize
16355 ** free list.
16357 static void memsys5Link(int i, int iLogsize){
16358 int x;
16359 assert( sqlite3_mutex_held(mem5.mutex) );
16360 assert( i>=0 && i<mem5.nBlock );
16361 assert( iLogsize>=0 && iLogsize<=LOGMAX );
16362 assert( (mem5.aCtrl[i] & CTRL_LOGSIZE)==iLogsize );
16364 x = MEM5LINK(i)->next = mem5.aiFreelist[iLogsize];
16365 MEM5LINK(i)->prev = -1;
16366 if( x>=0 ){
16367 assert( x<mem5.nBlock );
16368 MEM5LINK(x)->prev = i;
16370 mem5.aiFreelist[iLogsize] = i;
16374 ** If the STATIC_MEM mutex is not already held, obtain it now. The mutex
16375 ** will already be held (obtained by code in malloc.c) if
16376 ** sqlite3GlobalConfig.bMemStat is true.
16378 static void memsys5Enter(void){
16379 sqlite3_mutex_enter(mem5.mutex);
16381 static void memsys5Leave(void){
16382 sqlite3_mutex_leave(mem5.mutex);
16386 ** Return the size of an outstanding allocation, in bytes. The
16387 ** size returned omits the 8-byte header overhead. This only
16388 ** works for chunks that are currently checked out.
16390 static int memsys5Size(void *p){
16391 int iSize = 0;
16392 if( p ){
16393 int i = ((u8 *)p-mem5.zPool)/mem5.szAtom;
16394 assert( i>=0 && i<mem5.nBlock );
16395 iSize = mem5.szAtom * (1 << (mem5.aCtrl[i]&CTRL_LOGSIZE));
16397 return iSize;
16401 ** Find the first entry on the freelist iLogsize. Unlink that
16402 ** entry and return its index.
16404 static int memsys5UnlinkFirst(int iLogsize){
16405 int i;
16406 int iFirst;
16408 assert( iLogsize>=0 && iLogsize<=LOGMAX );
16409 i = iFirst = mem5.aiFreelist[iLogsize];
16410 assert( iFirst>=0 );
16411 while( i>0 ){
16412 if( i<iFirst ) iFirst = i;
16413 i = MEM5LINK(i)->next;
16415 memsys5Unlink(iFirst, iLogsize);
16416 return iFirst;
16420 ** Return a block of memory of at least nBytes in size.
16421 ** Return NULL if unable. Return NULL if nBytes==0.
16423 ** The caller guarantees that nByte positive.
16425 ** The caller has obtained a mutex prior to invoking this
16426 ** routine so there is never any chance that two or more
16427 ** threads can be in this routine at the same time.
16429 static void *memsys5MallocUnsafe(int nByte){
16430 int i; /* Index of a mem5.aPool[] slot */
16431 int iBin; /* Index into mem5.aiFreelist[] */
16432 int iFullSz; /* Size of allocation rounded up to power of 2 */
16433 int iLogsize; /* Log2 of iFullSz/POW2_MIN */
16435 /* nByte must be a positive */
16436 assert( nByte>0 );
16438 /* Keep track of the maximum allocation request. Even unfulfilled
16439 ** requests are counted */
16440 if( (u32)nByte>mem5.maxRequest ){
16441 mem5.maxRequest = nByte;
16444 /* Abort if the requested allocation size is larger than the largest
16445 ** power of two that we can represent using 32-bit signed integers.
16447 if( nByte > 0x40000000 ){
16448 return 0;
16451 /* Round nByte up to the next valid power of two */
16452 for(iFullSz=mem5.szAtom, iLogsize=0; iFullSz<nByte; iFullSz *= 2, iLogsize++){}
16454 /* Make sure mem5.aiFreelist[iLogsize] contains at least one free
16455 ** block. If not, then split a block of the next larger power of
16456 ** two in order to create a new free block of size iLogsize.
16458 for(iBin=iLogsize; mem5.aiFreelist[iBin]<0 && iBin<=LOGMAX; iBin++){}
16459 if( iBin>LOGMAX ){
16460 testcase( sqlite3GlobalConfig.xLog!=0 );
16461 sqlite3_log(SQLITE_NOMEM, "failed to allocate %u bytes", nByte);
16462 return 0;
16464 i = memsys5UnlinkFirst(iBin);
16465 while( iBin>iLogsize ){
16466 int newSize;
16468 iBin--;
16469 newSize = 1 << iBin;
16470 mem5.aCtrl[i+newSize] = CTRL_FREE | iBin;
16471 memsys5Link(i+newSize, iBin);
16473 mem5.aCtrl[i] = iLogsize;
16475 /* Update allocator performance statistics. */
16476 mem5.nAlloc++;
16477 mem5.totalAlloc += iFullSz;
16478 mem5.totalExcess += iFullSz - nByte;
16479 mem5.currentCount++;
16480 mem5.currentOut += iFullSz;
16481 if( mem5.maxCount<mem5.currentCount ) mem5.maxCount = mem5.currentCount;
16482 if( mem5.maxOut<mem5.currentOut ) mem5.maxOut = mem5.currentOut;
16484 /* Return a pointer to the allocated memory. */
16485 return (void*)&mem5.zPool[i*mem5.szAtom];
16489 ** Free an outstanding memory allocation.
16491 static void memsys5FreeUnsafe(void *pOld){
16492 u32 size, iLogsize;
16493 int iBlock;
16495 /* Set iBlock to the index of the block pointed to by pOld in
16496 ** the array of mem5.szAtom byte blocks pointed to by mem5.zPool.
16498 iBlock = ((u8 *)pOld-mem5.zPool)/mem5.szAtom;
16500 /* Check that the pointer pOld points to a valid, non-free block. */
16501 assert( iBlock>=0 && iBlock<mem5.nBlock );
16502 assert( ((u8 *)pOld-mem5.zPool)%mem5.szAtom==0 );
16503 assert( (mem5.aCtrl[iBlock] & CTRL_FREE)==0 );
16505 iLogsize = mem5.aCtrl[iBlock] & CTRL_LOGSIZE;
16506 size = 1<<iLogsize;
16507 assert( iBlock+size-1<(u32)mem5.nBlock );
16509 mem5.aCtrl[iBlock] |= CTRL_FREE;
16510 mem5.aCtrl[iBlock+size-1] |= CTRL_FREE;
16511 assert( mem5.currentCount>0 );
16512 assert( mem5.currentOut>=(size*mem5.szAtom) );
16513 mem5.currentCount--;
16514 mem5.currentOut -= size*mem5.szAtom;
16515 assert( mem5.currentOut>0 || mem5.currentCount==0 );
16516 assert( mem5.currentCount>0 || mem5.currentOut==0 );
16518 mem5.aCtrl[iBlock] = CTRL_FREE | iLogsize;
16519 while( ALWAYS(iLogsize<LOGMAX) ){
16520 int iBuddy;
16521 if( (iBlock>>iLogsize) & 1 ){
16522 iBuddy = iBlock - size;
16523 }else{
16524 iBuddy = iBlock + size;
16526 assert( iBuddy>=0 );
16527 if( (iBuddy+(1<<iLogsize))>mem5.nBlock ) break;
16528 if( mem5.aCtrl[iBuddy]!=(CTRL_FREE | iLogsize) ) break;
16529 memsys5Unlink(iBuddy, iLogsize);
16530 iLogsize++;
16531 if( iBuddy<iBlock ){
16532 mem5.aCtrl[iBuddy] = CTRL_FREE | iLogsize;
16533 mem5.aCtrl[iBlock] = 0;
16534 iBlock = iBuddy;
16535 }else{
16536 mem5.aCtrl[iBlock] = CTRL_FREE | iLogsize;
16537 mem5.aCtrl[iBuddy] = 0;
16539 size *= 2;
16541 memsys5Link(iBlock, iLogsize);
16545 ** Allocate nBytes of memory
16547 static void *memsys5Malloc(int nBytes){
16548 sqlite3_int64 *p = 0;
16549 if( nBytes>0 ){
16550 memsys5Enter();
16551 p = memsys5MallocUnsafe(nBytes);
16552 memsys5Leave();
16554 return (void*)p;
16558 ** Free memory.
16560 ** The outer layer memory allocator prevents this routine from
16561 ** being called with pPrior==0.
16563 static void memsys5Free(void *pPrior){
16564 assert( pPrior!=0 );
16565 memsys5Enter();
16566 memsys5FreeUnsafe(pPrior);
16567 memsys5Leave();
16571 ** Change the size of an existing memory allocation.
16573 ** The outer layer memory allocator prevents this routine from
16574 ** being called with pPrior==0.
16576 ** nBytes is always a value obtained from a prior call to
16577 ** memsys5Round(). Hence nBytes is always a non-negative power
16578 ** of two. If nBytes==0 that means that an oversize allocation
16579 ** (an allocation larger than 0x40000000) was requested and this
16580 ** routine should return 0 without freeing pPrior.
16582 static void *memsys5Realloc(void *pPrior, int nBytes){
16583 int nOld;
16584 void *p;
16585 assert( pPrior!=0 );
16586 assert( (nBytes&(nBytes-1))==0 ); /* EV: R-46199-30249 */
16587 assert( nBytes>=0 );
16588 if( nBytes==0 ){
16589 return 0;
16591 nOld = memsys5Size(pPrior);
16592 if( nBytes<=nOld ){
16593 return pPrior;
16595 memsys5Enter();
16596 p = memsys5MallocUnsafe(nBytes);
16597 if( p ){
16598 memcpy(p, pPrior, nOld);
16599 memsys5FreeUnsafe(pPrior);
16601 memsys5Leave();
16602 return p;
16606 ** Round up a request size to the next valid allocation size. If
16607 ** the allocation is too large to be handled by this allocation system,
16608 ** return 0.
16610 ** All allocations must be a power of two and must be expressed by a
16611 ** 32-bit signed integer. Hence the largest allocation is 0x40000000
16612 ** or 1073741824 bytes.
16614 static int memsys5Roundup(int n){
16615 int iFullSz;
16616 if( n > 0x40000000 ) return 0;
16617 for(iFullSz=mem5.szAtom; iFullSz<n; iFullSz *= 2);
16618 return iFullSz;
16622 ** Return the ceiling of the logarithm base 2 of iValue.
16624 ** Examples: memsys5Log(1) -> 0
16625 ** memsys5Log(2) -> 1
16626 ** memsys5Log(4) -> 2
16627 ** memsys5Log(5) -> 3
16628 ** memsys5Log(8) -> 3
16629 ** memsys5Log(9) -> 4
16631 static int memsys5Log(int iValue){
16632 int iLog;
16633 for(iLog=0; (iLog<(int)((sizeof(int)*8)-1)) && (1<<iLog)<iValue; iLog++);
16634 return iLog;
16638 ** Initialize the memory allocator.
16640 ** This routine is not threadsafe. The caller must be holding a mutex
16641 ** to prevent multiple threads from entering at the same time.
16643 static int memsys5Init(void *NotUsed){
16644 int ii; /* Loop counter */
16645 int nByte; /* Number of bytes of memory available to this allocator */
16646 u8 *zByte; /* Memory usable by this allocator */
16647 int nMinLog; /* Log base 2 of minimum allocation size in bytes */
16648 int iOffset; /* An offset into mem5.aCtrl[] */
16650 UNUSED_PARAMETER(NotUsed);
16652 /* For the purposes of this routine, disable the mutex */
16653 mem5.mutex = 0;
16655 /* The size of a Mem5Link object must be a power of two. Verify that
16656 ** this is case.
16658 assert( (sizeof(Mem5Link)&(sizeof(Mem5Link)-1))==0 );
16660 nByte = sqlite3GlobalConfig.nHeap;
16661 zByte = (u8*)sqlite3GlobalConfig.pHeap;
16662 assert( zByte!=0 ); /* sqlite3_config() does not allow otherwise */
16664 /* boundaries on sqlite3GlobalConfig.mnReq are enforced in sqlite3_config() */
16665 nMinLog = memsys5Log(sqlite3GlobalConfig.mnReq);
16666 mem5.szAtom = (1<<nMinLog);
16667 while( (int)sizeof(Mem5Link)>mem5.szAtom ){
16668 mem5.szAtom = mem5.szAtom << 1;
16671 mem5.nBlock = (nByte / (mem5.szAtom+sizeof(u8)));
16672 mem5.zPool = zByte;
16673 mem5.aCtrl = (u8 *)&mem5.zPool[mem5.nBlock*mem5.szAtom];
16675 for(ii=0; ii<=LOGMAX; ii++){
16676 mem5.aiFreelist[ii] = -1;
16679 iOffset = 0;
16680 for(ii=LOGMAX; ii>=0; ii--){
16681 int nAlloc = (1<<ii);
16682 if( (iOffset+nAlloc)<=mem5.nBlock ){
16683 mem5.aCtrl[iOffset] = ii | CTRL_FREE;
16684 memsys5Link(iOffset, ii);
16685 iOffset += nAlloc;
16687 assert((iOffset+nAlloc)>mem5.nBlock);
16690 /* If a mutex is required for normal operation, allocate one */
16691 if( sqlite3GlobalConfig.bMemstat==0 ){
16692 mem5.mutex = sqlite3MutexAlloc(SQLITE_MUTEX_STATIC_MEM);
16695 return SQLITE_OK;
16699 ** Deinitialize this module.
16701 static void memsys5Shutdown(void *NotUsed){
16702 UNUSED_PARAMETER(NotUsed);
16703 mem5.mutex = 0;
16704 return;
16707 #ifdef SQLITE_TEST
16709 ** Open the file indicated and write a log of all unfreed memory
16710 ** allocations into that log.
16712 SQLITE_PRIVATE void sqlite3Memsys5Dump(const char *zFilename){
16713 FILE *out;
16714 int i, j, n;
16715 int nMinLog;
16717 if( zFilename==0 || zFilename[0]==0 ){
16718 out = stdout;
16719 }else{
16720 out = fopen(zFilename, "w");
16721 if( out==0 ){
16722 fprintf(stderr, "** Unable to output memory debug output log: %s **\n",
16723 zFilename);
16724 return;
16727 memsys5Enter();
16728 nMinLog = memsys5Log(mem5.szAtom);
16729 for(i=0; i<=LOGMAX && i+nMinLog<32; i++){
16730 for(n=0, j=mem5.aiFreelist[i]; j>=0; j = MEM5LINK(j)->next, n++){}
16731 fprintf(out, "freelist items of size %d: %d\n", mem5.szAtom << i, n);
16733 fprintf(out, "mem5.nAlloc = %llu\n", mem5.nAlloc);
16734 fprintf(out, "mem5.totalAlloc = %llu\n", mem5.totalAlloc);
16735 fprintf(out, "mem5.totalExcess = %llu\n", mem5.totalExcess);
16736 fprintf(out, "mem5.currentOut = %u\n", mem5.currentOut);
16737 fprintf(out, "mem5.currentCount = %u\n", mem5.currentCount);
16738 fprintf(out, "mem5.maxOut = %u\n", mem5.maxOut);
16739 fprintf(out, "mem5.maxCount = %u\n", mem5.maxCount);
16740 fprintf(out, "mem5.maxRequest = %u\n", mem5.maxRequest);
16741 memsys5Leave();
16742 if( out==stdout ){
16743 fflush(stdout);
16744 }else{
16745 fclose(out);
16748 #endif
16751 ** This routine is the only routine in this file with external
16752 ** linkage. It returns a pointer to a static sqlite3_mem_methods
16753 ** struct populated with the memsys5 methods.
16755 SQLITE_PRIVATE const sqlite3_mem_methods *sqlite3MemGetMemsys5(void){
16756 static const sqlite3_mem_methods memsys5Methods = {
16757 memsys5Malloc,
16758 memsys5Free,
16759 memsys5Realloc,
16760 memsys5Size,
16761 memsys5Roundup,
16762 memsys5Init,
16763 memsys5Shutdown,
16766 return &memsys5Methods;
16769 #endif /* SQLITE_ENABLE_MEMSYS5 */
16771 /************** End of mem5.c ************************************************/
16772 /************** Begin file mutex.c *******************************************/
16774 ** 2007 August 14
16776 ** The author disclaims copyright to this source code. In place of
16777 ** a legal notice, here is a blessing:
16779 ** May you do good and not evil.
16780 ** May you find forgiveness for yourself and forgive others.
16781 ** May you share freely, never taking more than you give.
16783 *************************************************************************
16784 ** This file contains the C functions that implement mutexes.
16786 ** This file contains code that is common across all mutex implementations.
16789 #if defined(SQLITE_DEBUG) && !defined(SQLITE_MUTEX_OMIT)
16791 ** For debugging purposes, record when the mutex subsystem is initialized
16792 ** and uninitialized so that we can assert() if there is an attempt to
16793 ** allocate a mutex while the system is uninitialized.
16795 static SQLITE_WSD int mutexIsInit = 0;
16796 #endif /* SQLITE_DEBUG */
16799 #ifndef SQLITE_MUTEX_OMIT
16801 ** Initialize the mutex system.
16803 SQLITE_PRIVATE int sqlite3MutexInit(void){
16804 int rc = SQLITE_OK;
16805 if( !sqlite3GlobalConfig.mutex.xMutexAlloc ){
16806 /* If the xMutexAlloc method has not been set, then the user did not
16807 ** install a mutex implementation via sqlite3_config() prior to
16808 ** sqlite3_initialize() being called. This block copies pointers to
16809 ** the default implementation into the sqlite3GlobalConfig structure.
16811 sqlite3_mutex_methods const *pFrom;
16812 sqlite3_mutex_methods *pTo = &sqlite3GlobalConfig.mutex;
16814 if( sqlite3GlobalConfig.bCoreMutex ){
16815 pFrom = sqlite3DefaultMutex();
16816 }else{
16817 pFrom = sqlite3NoopMutex();
16819 memcpy(pTo, pFrom, offsetof(sqlite3_mutex_methods, xMutexAlloc));
16820 memcpy(&pTo->xMutexFree, &pFrom->xMutexFree,
16821 sizeof(*pTo) - offsetof(sqlite3_mutex_methods, xMutexFree));
16822 pTo->xMutexAlloc = pFrom->xMutexAlloc;
16824 rc = sqlite3GlobalConfig.mutex.xMutexInit();
16826 #ifdef SQLITE_DEBUG
16827 GLOBAL(int, mutexIsInit) = 1;
16828 #endif
16830 return rc;
16834 ** Shutdown the mutex system. This call frees resources allocated by
16835 ** sqlite3MutexInit().
16837 SQLITE_PRIVATE int sqlite3MutexEnd(void){
16838 int rc = SQLITE_OK;
16839 if( sqlite3GlobalConfig.mutex.xMutexEnd ){
16840 rc = sqlite3GlobalConfig.mutex.xMutexEnd();
16843 #ifdef SQLITE_DEBUG
16844 GLOBAL(int, mutexIsInit) = 0;
16845 #endif
16847 return rc;
16851 ** Retrieve a pointer to a static mutex or allocate a new dynamic one.
16853 SQLITE_API sqlite3_mutex *sqlite3_mutex_alloc(int id){
16854 #ifndef SQLITE_OMIT_AUTOINIT
16855 if( sqlite3_initialize() ) return 0;
16856 #endif
16857 return sqlite3GlobalConfig.mutex.xMutexAlloc(id);
16860 SQLITE_PRIVATE sqlite3_mutex *sqlite3MutexAlloc(int id){
16861 if( !sqlite3GlobalConfig.bCoreMutex ){
16862 return 0;
16864 assert( GLOBAL(int, mutexIsInit) );
16865 return sqlite3GlobalConfig.mutex.xMutexAlloc(id);
16869 ** Free a dynamic mutex.
16871 SQLITE_API void sqlite3_mutex_free(sqlite3_mutex *p){
16872 if( p ){
16873 sqlite3GlobalConfig.mutex.xMutexFree(p);
16878 ** Obtain the mutex p. If some other thread already has the mutex, block
16879 ** until it can be obtained.
16881 SQLITE_API void sqlite3_mutex_enter(sqlite3_mutex *p){
16882 if( p ){
16883 sqlite3GlobalConfig.mutex.xMutexEnter(p);
16888 ** Obtain the mutex p. If successful, return SQLITE_OK. Otherwise, if another
16889 ** thread holds the mutex and it cannot be obtained, return SQLITE_BUSY.
16891 SQLITE_API int sqlite3_mutex_try(sqlite3_mutex *p){
16892 int rc = SQLITE_OK;
16893 if( p ){
16894 return sqlite3GlobalConfig.mutex.xMutexTry(p);
16896 return rc;
16900 ** The sqlite3_mutex_leave() routine exits a mutex that was previously
16901 ** entered by the same thread. The behavior is undefined if the mutex
16902 ** is not currently entered. If a NULL pointer is passed as an argument
16903 ** this function is a no-op.
16905 SQLITE_API void sqlite3_mutex_leave(sqlite3_mutex *p){
16906 if( p ){
16907 sqlite3GlobalConfig.mutex.xMutexLeave(p);
16911 #ifndef NDEBUG
16913 ** The sqlite3_mutex_held() and sqlite3_mutex_notheld() routine are
16914 ** intended for use inside assert() statements.
16916 SQLITE_API int sqlite3_mutex_held(sqlite3_mutex *p){
16917 return p==0 || sqlite3GlobalConfig.mutex.xMutexHeld(p);
16919 SQLITE_API int sqlite3_mutex_notheld(sqlite3_mutex *p){
16920 return p==0 || sqlite3GlobalConfig.mutex.xMutexNotheld(p);
16922 #endif
16924 #endif /* SQLITE_MUTEX_OMIT */
16926 /************** End of mutex.c ***********************************************/
16927 /************** Begin file mutex_noop.c **************************************/
16929 ** 2008 October 07
16931 ** The author disclaims copyright to this source code. In place of
16932 ** a legal notice, here is a blessing:
16934 ** May you do good and not evil.
16935 ** May you find forgiveness for yourself and forgive others.
16936 ** May you share freely, never taking more than you give.
16938 *************************************************************************
16939 ** This file contains the C functions that implement mutexes.
16941 ** This implementation in this file does not provide any mutual
16942 ** exclusion and is thus suitable for use only in applications
16943 ** that use SQLite in a single thread. The routines defined
16944 ** here are place-holders. Applications can substitute working
16945 ** mutex routines at start-time using the
16947 ** sqlite3_config(SQLITE_CONFIG_MUTEX,...)
16949 ** interface.
16951 ** If compiled with SQLITE_DEBUG, then additional logic is inserted
16952 ** that does error checking on mutexes to make sure they are being
16953 ** called correctly.
16956 #ifndef SQLITE_MUTEX_OMIT
16958 #ifndef SQLITE_DEBUG
16960 ** Stub routines for all mutex methods.
16962 ** This routines provide no mutual exclusion or error checking.
16964 static int noopMutexInit(void){ return SQLITE_OK; }
16965 static int noopMutexEnd(void){ return SQLITE_OK; }
16966 static sqlite3_mutex *noopMutexAlloc(int id){
16967 UNUSED_PARAMETER(id);
16968 return (sqlite3_mutex*)8;
16970 static void noopMutexFree(sqlite3_mutex *p){ UNUSED_PARAMETER(p); return; }
16971 static void noopMutexEnter(sqlite3_mutex *p){ UNUSED_PARAMETER(p); return; }
16972 static int noopMutexTry(sqlite3_mutex *p){
16973 UNUSED_PARAMETER(p);
16974 return SQLITE_OK;
16976 static void noopMutexLeave(sqlite3_mutex *p){ UNUSED_PARAMETER(p); return; }
16978 SQLITE_PRIVATE sqlite3_mutex_methods const *sqlite3NoopMutex(void){
16979 static const sqlite3_mutex_methods sMutex = {
16980 noopMutexInit,
16981 noopMutexEnd,
16982 noopMutexAlloc,
16983 noopMutexFree,
16984 noopMutexEnter,
16985 noopMutexTry,
16986 noopMutexLeave,
16992 return &sMutex;
16994 #endif /* !SQLITE_DEBUG */
16996 #ifdef SQLITE_DEBUG
16998 ** In this implementation, error checking is provided for testing
16999 ** and debugging purposes. The mutexes still do not provide any
17000 ** mutual exclusion.
17004 ** The mutex object
17006 typedef struct sqlite3_debug_mutex {
17007 int id; /* The mutex type */
17008 int cnt; /* Number of entries without a matching leave */
17009 } sqlite3_debug_mutex;
17012 ** The sqlite3_mutex_held() and sqlite3_mutex_notheld() routine are
17013 ** intended for use inside assert() statements.
17015 static int debugMutexHeld(sqlite3_mutex *pX){
17016 sqlite3_debug_mutex *p = (sqlite3_debug_mutex*)pX;
17017 return p==0 || p->cnt>0;
17019 static int debugMutexNotheld(sqlite3_mutex *pX){
17020 sqlite3_debug_mutex *p = (sqlite3_debug_mutex*)pX;
17021 return p==0 || p->cnt==0;
17025 ** Initialize and deinitialize the mutex subsystem.
17027 static int debugMutexInit(void){ return SQLITE_OK; }
17028 static int debugMutexEnd(void){ return SQLITE_OK; }
17031 ** The sqlite3_mutex_alloc() routine allocates a new
17032 ** mutex and returns a pointer to it. If it returns NULL
17033 ** that means that a mutex could not be allocated.
17035 static sqlite3_mutex *debugMutexAlloc(int id){
17036 static sqlite3_debug_mutex aStatic[6];
17037 sqlite3_debug_mutex *pNew = 0;
17038 switch( id ){
17039 case SQLITE_MUTEX_FAST:
17040 case SQLITE_MUTEX_RECURSIVE: {
17041 pNew = sqlite3Malloc(sizeof(*pNew));
17042 if( pNew ){
17043 pNew->id = id;
17044 pNew->cnt = 0;
17046 break;
17048 default: {
17049 assert( id-2 >= 0 );
17050 assert( id-2 < (int)(sizeof(aStatic)/sizeof(aStatic[0])) );
17051 pNew = &aStatic[id-2];
17052 pNew->id = id;
17053 break;
17056 return (sqlite3_mutex*)pNew;
17060 ** This routine deallocates a previously allocated mutex.
17062 static void debugMutexFree(sqlite3_mutex *pX){
17063 sqlite3_debug_mutex *p = (sqlite3_debug_mutex*)pX;
17064 assert( p->cnt==0 );
17065 assert( p->id==SQLITE_MUTEX_FAST || p->id==SQLITE_MUTEX_RECURSIVE );
17066 sqlite3_free(p);
17070 ** The sqlite3_mutex_enter() and sqlite3_mutex_try() routines attempt
17071 ** to enter a mutex. If another thread is already within the mutex,
17072 ** sqlite3_mutex_enter() will block and sqlite3_mutex_try() will return
17073 ** SQLITE_BUSY. The sqlite3_mutex_try() interface returns SQLITE_OK
17074 ** upon successful entry. Mutexes created using SQLITE_MUTEX_RECURSIVE can
17075 ** be entered multiple times by the same thread. In such cases the,
17076 ** mutex must be exited an equal number of times before another thread
17077 ** can enter. If the same thread tries to enter any other kind of mutex
17078 ** more than once, the behavior is undefined.
17080 static void debugMutexEnter(sqlite3_mutex *pX){
17081 sqlite3_debug_mutex *p = (sqlite3_debug_mutex*)pX;
17082 assert( p->id==SQLITE_MUTEX_RECURSIVE || debugMutexNotheld(pX) );
17083 p->cnt++;
17085 static int debugMutexTry(sqlite3_mutex *pX){
17086 sqlite3_debug_mutex *p = (sqlite3_debug_mutex*)pX;
17087 assert( p->id==SQLITE_MUTEX_RECURSIVE || debugMutexNotheld(pX) );
17088 p->cnt++;
17089 return SQLITE_OK;
17093 ** The sqlite3_mutex_leave() routine exits a mutex that was
17094 ** previously entered by the same thread. The behavior
17095 ** is undefined if the mutex is not currently entered or
17096 ** is not currently allocated. SQLite will never do either.
17098 static void debugMutexLeave(sqlite3_mutex *pX){
17099 sqlite3_debug_mutex *p = (sqlite3_debug_mutex*)pX;
17100 assert( debugMutexHeld(pX) );
17101 p->cnt--;
17102 assert( p->id==SQLITE_MUTEX_RECURSIVE || debugMutexNotheld(pX) );
17105 SQLITE_PRIVATE sqlite3_mutex_methods const *sqlite3NoopMutex(void){
17106 static const sqlite3_mutex_methods sMutex = {
17107 debugMutexInit,
17108 debugMutexEnd,
17109 debugMutexAlloc,
17110 debugMutexFree,
17111 debugMutexEnter,
17112 debugMutexTry,
17113 debugMutexLeave,
17115 debugMutexHeld,
17116 debugMutexNotheld
17119 return &sMutex;
17121 #endif /* SQLITE_DEBUG */
17124 ** If compiled with SQLITE_MUTEX_NOOP, then the no-op mutex implementation
17125 ** is used regardless of the run-time threadsafety setting.
17127 #ifdef SQLITE_MUTEX_NOOP
17128 SQLITE_PRIVATE sqlite3_mutex_methods const *sqlite3DefaultMutex(void){
17129 return sqlite3NoopMutex();
17131 #endif /* SQLITE_MUTEX_NOOP */
17132 #endif /* SQLITE_MUTEX_OMIT */
17134 /************** End of mutex_noop.c ******************************************/
17135 /************** Begin file mutex_os2.c ***************************************/
17137 ** 2007 August 28
17139 ** The author disclaims copyright to this source code. In place of
17140 ** a legal notice, here is a blessing:
17142 ** May you do good and not evil.
17143 ** May you find forgiveness for yourself and forgive others.
17144 ** May you share freely, never taking more than you give.
17146 *************************************************************************
17147 ** This file contains the C functions that implement mutexes for OS/2
17151 ** The code in this file is only used if SQLITE_MUTEX_OS2 is defined.
17152 ** See the mutex.h file for details.
17154 #ifdef SQLITE_MUTEX_OS2
17156 /********************** OS/2 Mutex Implementation **********************
17158 ** This implementation of mutexes is built using the OS/2 API.
17162 ** The mutex object
17163 ** Each recursive mutex is an instance of the following structure.
17165 struct sqlite3_mutex {
17166 HMTX mutex; /* Mutex controlling the lock */
17167 int id; /* Mutex type */
17168 #ifdef SQLITE_DEBUG
17169 int trace; /* True to trace changes */
17170 #endif
17173 #ifdef SQLITE_DEBUG
17174 #define SQLITE3_MUTEX_INITIALIZER { 0, 0, 0 }
17175 #else
17176 #define SQLITE3_MUTEX_INITIALIZER { 0, 0 }
17177 #endif
17180 ** Initialize and deinitialize the mutex subsystem.
17182 static int os2MutexInit(void){ return SQLITE_OK; }
17183 static int os2MutexEnd(void){ return SQLITE_OK; }
17186 ** The sqlite3_mutex_alloc() routine allocates a new
17187 ** mutex and returns a pointer to it. If it returns NULL
17188 ** that means that a mutex could not be allocated.
17189 ** SQLite will unwind its stack and return an error. The argument
17190 ** to sqlite3_mutex_alloc() is one of these integer constants:
17192 ** <ul>
17193 ** <li> SQLITE_MUTEX_FAST
17194 ** <li> SQLITE_MUTEX_RECURSIVE
17195 ** <li> SQLITE_MUTEX_STATIC_MASTER
17196 ** <li> SQLITE_MUTEX_STATIC_MEM
17197 ** <li> SQLITE_MUTEX_STATIC_MEM2
17198 ** <li> SQLITE_MUTEX_STATIC_PRNG
17199 ** <li> SQLITE_MUTEX_STATIC_LRU
17200 ** <li> SQLITE_MUTEX_STATIC_LRU2
17201 ** </ul>
17203 ** The first two constants cause sqlite3_mutex_alloc() to create
17204 ** a new mutex. The new mutex is recursive when SQLITE_MUTEX_RECURSIVE
17205 ** is used but not necessarily so when SQLITE_MUTEX_FAST is used.
17206 ** The mutex implementation does not need to make a distinction
17207 ** between SQLITE_MUTEX_RECURSIVE and SQLITE_MUTEX_FAST if it does
17208 ** not want to. But SQLite will only request a recursive mutex in
17209 ** cases where it really needs one. If a faster non-recursive mutex
17210 ** implementation is available on the host platform, the mutex subsystem
17211 ** might return such a mutex in response to SQLITE_MUTEX_FAST.
17213 ** The other allowed parameters to sqlite3_mutex_alloc() each return
17214 ** a pointer to a static preexisting mutex. Six static mutexes are
17215 ** used by the current version of SQLite. Future versions of SQLite
17216 ** may add additional static mutexes. Static mutexes are for internal
17217 ** use by SQLite only. Applications that use SQLite mutexes should
17218 ** use only the dynamic mutexes returned by SQLITE_MUTEX_FAST or
17219 ** SQLITE_MUTEX_RECURSIVE.
17221 ** Note that if one of the dynamic mutex parameters (SQLITE_MUTEX_FAST
17222 ** or SQLITE_MUTEX_RECURSIVE) is used then sqlite3_mutex_alloc()
17223 ** returns a different mutex on every call. But for the static
17224 ** mutex types, the same mutex is returned on every call that has
17225 ** the same type number.
17227 static sqlite3_mutex *os2MutexAlloc(int iType){
17228 sqlite3_mutex *p = NULL;
17229 switch( iType ){
17230 case SQLITE_MUTEX_FAST:
17231 case SQLITE_MUTEX_RECURSIVE: {
17232 p = sqlite3MallocZero( sizeof(*p) );
17233 if( p ){
17234 p->id = iType;
17235 if( DosCreateMutexSem( 0, &p->mutex, 0, FALSE ) != NO_ERROR ){
17236 sqlite3_free( p );
17237 p = NULL;
17240 break;
17242 default: {
17243 static volatile int isInit = 0;
17244 static sqlite3_mutex staticMutexes[6] = {
17245 SQLITE3_MUTEX_INITIALIZER,
17246 SQLITE3_MUTEX_INITIALIZER,
17247 SQLITE3_MUTEX_INITIALIZER,
17248 SQLITE3_MUTEX_INITIALIZER,
17249 SQLITE3_MUTEX_INITIALIZER,
17250 SQLITE3_MUTEX_INITIALIZER,
17252 if ( !isInit ){
17253 APIRET rc;
17254 PTIB ptib;
17255 PPIB ppib;
17256 HMTX mutex;
17257 char name[32];
17258 DosGetInfoBlocks( &ptib, &ppib );
17259 sqlite3_snprintf( sizeof(name), name, "\\SEM32\\SQLITE%04x",
17260 ppib->pib_ulpid );
17261 while( !isInit ){
17262 mutex = 0;
17263 rc = DosCreateMutexSem( name, &mutex, 0, FALSE);
17264 if( rc == NO_ERROR ){
17265 unsigned int i;
17266 if( !isInit ){
17267 for( i = 0; i < sizeof(staticMutexes)/sizeof(staticMutexes[0]); i++ ){
17268 DosCreateMutexSem( 0, &staticMutexes[i].mutex, 0, FALSE );
17270 isInit = 1;
17272 DosCloseMutexSem( mutex );
17273 }else if( rc == ERROR_DUPLICATE_NAME ){
17274 DosSleep( 1 );
17275 }else{
17276 return p;
17280 assert( iType-2 >= 0 );
17281 assert( iType-2 < sizeof(staticMutexes)/sizeof(staticMutexes[0]) );
17282 p = &staticMutexes[iType-2];
17283 p->id = iType;
17284 break;
17287 return p;
17292 ** This routine deallocates a previously allocated mutex.
17293 ** SQLite is careful to deallocate every mutex that it allocates.
17295 static void os2MutexFree(sqlite3_mutex *p){
17296 #ifdef SQLITE_DEBUG
17297 TID tid;
17298 PID pid;
17299 ULONG ulCount;
17300 DosQueryMutexSem(p->mutex, &pid, &tid, &ulCount);
17301 assert( ulCount==0 );
17302 assert( p->id==SQLITE_MUTEX_FAST || p->id==SQLITE_MUTEX_RECURSIVE );
17303 #endif
17304 DosCloseMutexSem( p->mutex );
17305 sqlite3_free( p );
17308 #ifdef SQLITE_DEBUG
17310 ** The sqlite3_mutex_held() and sqlite3_mutex_notheld() routine are
17311 ** intended for use inside assert() statements.
17313 static int os2MutexHeld(sqlite3_mutex *p){
17314 TID tid;
17315 PID pid;
17316 ULONG ulCount;
17317 PTIB ptib;
17318 DosQueryMutexSem(p->mutex, &pid, &tid, &ulCount);
17319 if( ulCount==0 || ( ulCount>1 && p->id!=SQLITE_MUTEX_RECURSIVE ) )
17320 return 0;
17321 DosGetInfoBlocks(&ptib, NULL);
17322 return tid==ptib->tib_ptib2->tib2_ultid;
17324 static int os2MutexNotheld(sqlite3_mutex *p){
17325 TID tid;
17326 PID pid;
17327 ULONG ulCount;
17328 PTIB ptib;
17329 DosQueryMutexSem(p->mutex, &pid, &tid, &ulCount);
17330 if( ulCount==0 )
17331 return 1;
17332 DosGetInfoBlocks(&ptib, NULL);
17333 return tid!=ptib->tib_ptib2->tib2_ultid;
17335 static void os2MutexTrace(sqlite3_mutex *p, char *pAction){
17336 TID tid;
17337 PID pid;
17338 ULONG ulCount;
17339 DosQueryMutexSem(p->mutex, &pid, &tid, &ulCount);
17340 printf("%s mutex %p (%d) with nRef=%ld\n", pAction, (void*)p, p->trace, ulCount);
17342 #endif
17345 ** The sqlite3_mutex_enter() and sqlite3_mutex_try() routines attempt
17346 ** to enter a mutex. If another thread is already within the mutex,
17347 ** sqlite3_mutex_enter() will block and sqlite3_mutex_try() will return
17348 ** SQLITE_BUSY. The sqlite3_mutex_try() interface returns SQLITE_OK
17349 ** upon successful entry. Mutexes created using SQLITE_MUTEX_RECURSIVE can
17350 ** be entered multiple times by the same thread. In such cases the,
17351 ** mutex must be exited an equal number of times before another thread
17352 ** can enter. If the same thread tries to enter any other kind of mutex
17353 ** more than once, the behavior is undefined.
17355 static void os2MutexEnter(sqlite3_mutex *p){
17356 assert( p->id==SQLITE_MUTEX_RECURSIVE || os2MutexNotheld(p) );
17357 DosRequestMutexSem(p->mutex, SEM_INDEFINITE_WAIT);
17358 #ifdef SQLITE_DEBUG
17359 if( p->trace ) os2MutexTrace(p, "enter");
17360 #endif
17362 static int os2MutexTry(sqlite3_mutex *p){
17363 int rc = SQLITE_BUSY;
17364 assert( p->id==SQLITE_MUTEX_RECURSIVE || os2MutexNotheld(p) );
17365 if( DosRequestMutexSem(p->mutex, SEM_IMMEDIATE_RETURN) == NO_ERROR ) {
17366 rc = SQLITE_OK;
17367 #ifdef SQLITE_DEBUG
17368 if( p->trace ) os2MutexTrace(p, "try");
17369 #endif
17371 return rc;
17375 ** The sqlite3_mutex_leave() routine exits a mutex that was
17376 ** previously entered by the same thread. The behavior
17377 ** is undefined if the mutex is not currently entered or
17378 ** is not currently allocated. SQLite will never do either.
17380 static void os2MutexLeave(sqlite3_mutex *p){
17381 assert( os2MutexHeld(p) );
17382 DosReleaseMutexSem(p->mutex);
17383 #ifdef SQLITE_DEBUG
17384 if( p->trace ) os2MutexTrace(p, "leave");
17385 #endif
17388 SQLITE_PRIVATE sqlite3_mutex_methods const *sqlite3DefaultMutex(void){
17389 static const sqlite3_mutex_methods sMutex = {
17390 os2MutexInit,
17391 os2MutexEnd,
17392 os2MutexAlloc,
17393 os2MutexFree,
17394 os2MutexEnter,
17395 os2MutexTry,
17396 os2MutexLeave,
17397 #ifdef SQLITE_DEBUG
17398 os2MutexHeld,
17399 os2MutexNotheld
17400 #else
17403 #endif
17406 return &sMutex;
17408 #endif /* SQLITE_MUTEX_OS2 */
17410 /************** End of mutex_os2.c *******************************************/
17411 /************** Begin file mutex_unix.c **************************************/
17413 ** 2007 August 28
17415 ** The author disclaims copyright to this source code. In place of
17416 ** a legal notice, here is a blessing:
17418 ** May you do good and not evil.
17419 ** May you find forgiveness for yourself and forgive others.
17420 ** May you share freely, never taking more than you give.
17422 *************************************************************************
17423 ** This file contains the C functions that implement mutexes for pthreads
17427 ** The code in this file is only used if we are compiling threadsafe
17428 ** under unix with pthreads.
17430 ** Note that this implementation requires a version of pthreads that
17431 ** supports recursive mutexes.
17433 #ifdef SQLITE_MUTEX_PTHREADS
17435 #include <pthread.h>
17438 ** The sqlite3_mutex.id, sqlite3_mutex.nRef, and sqlite3_mutex.owner fields
17439 ** are necessary under two condidtions: (1) Debug builds and (2) using
17440 ** home-grown mutexes. Encapsulate these conditions into a single #define.
17442 #if defined(SQLITE_DEBUG) || defined(SQLITE_HOMEGROWN_RECURSIVE_MUTEX)
17443 # define SQLITE_MUTEX_NREF 1
17444 #else
17445 # define SQLITE_MUTEX_NREF 0
17446 #endif
17449 ** Each recursive mutex is an instance of the following structure.
17451 struct sqlite3_mutex {
17452 pthread_mutex_t mutex; /* Mutex controlling the lock */
17453 #if SQLITE_MUTEX_NREF
17454 int id; /* Mutex type */
17455 volatile int nRef; /* Number of entrances */
17456 volatile pthread_t owner; /* Thread that is within this mutex */
17457 int trace; /* True to trace changes */
17458 #endif
17460 #if SQLITE_MUTEX_NREF
17461 #define SQLITE3_MUTEX_INITIALIZER { PTHREAD_MUTEX_INITIALIZER, 0, 0, (pthread_t)0, 0 }
17462 #else
17463 #define SQLITE3_MUTEX_INITIALIZER { PTHREAD_MUTEX_INITIALIZER }
17464 #endif
17467 ** The sqlite3_mutex_held() and sqlite3_mutex_notheld() routine are
17468 ** intended for use only inside assert() statements. On some platforms,
17469 ** there might be race conditions that can cause these routines to
17470 ** deliver incorrect results. In particular, if pthread_equal() is
17471 ** not an atomic operation, then these routines might delivery
17472 ** incorrect results. On most platforms, pthread_equal() is a
17473 ** comparison of two integers and is therefore atomic. But we are
17474 ** told that HPUX is not such a platform. If so, then these routines
17475 ** will not always work correctly on HPUX.
17477 ** On those platforms where pthread_equal() is not atomic, SQLite
17478 ** should be compiled without -DSQLITE_DEBUG and with -DNDEBUG to
17479 ** make sure no assert() statements are evaluated and hence these
17480 ** routines are never called.
17482 #if !defined(NDEBUG) || defined(SQLITE_DEBUG)
17483 static int pthreadMutexHeld(sqlite3_mutex *p){
17484 return (p->nRef!=0 && pthread_equal(p->owner, pthread_self()));
17486 static int pthreadMutexNotheld(sqlite3_mutex *p){
17487 return p->nRef==0 || pthread_equal(p->owner, pthread_self())==0;
17489 #endif
17492 ** Initialize and deinitialize the mutex subsystem.
17494 static int pthreadMutexInit(void){ return SQLITE_OK; }
17495 static int pthreadMutexEnd(void){ return SQLITE_OK; }
17498 ** The sqlite3_mutex_alloc() routine allocates a new
17499 ** mutex and returns a pointer to it. If it returns NULL
17500 ** that means that a mutex could not be allocated. SQLite
17501 ** will unwind its stack and return an error. The argument
17502 ** to sqlite3_mutex_alloc() is one of these integer constants:
17504 ** <ul>
17505 ** <li> SQLITE_MUTEX_FAST
17506 ** <li> SQLITE_MUTEX_RECURSIVE
17507 ** <li> SQLITE_MUTEX_STATIC_MASTER
17508 ** <li> SQLITE_MUTEX_STATIC_MEM
17509 ** <li> SQLITE_MUTEX_STATIC_MEM2
17510 ** <li> SQLITE_MUTEX_STATIC_PRNG
17511 ** <li> SQLITE_MUTEX_STATIC_LRU
17512 ** <li> SQLITE_MUTEX_STATIC_PMEM
17513 ** </ul>
17515 ** The first two constants cause sqlite3_mutex_alloc() to create
17516 ** a new mutex. The new mutex is recursive when SQLITE_MUTEX_RECURSIVE
17517 ** is used but not necessarily so when SQLITE_MUTEX_FAST is used.
17518 ** The mutex implementation does not need to make a distinction
17519 ** between SQLITE_MUTEX_RECURSIVE and SQLITE_MUTEX_FAST if it does
17520 ** not want to. But SQLite will only request a recursive mutex in
17521 ** cases where it really needs one. If a faster non-recursive mutex
17522 ** implementation is available on the host platform, the mutex subsystem
17523 ** might return such a mutex in response to SQLITE_MUTEX_FAST.
17525 ** The other allowed parameters to sqlite3_mutex_alloc() each return
17526 ** a pointer to a static preexisting mutex. Six static mutexes are
17527 ** used by the current version of SQLite. Future versions of SQLite
17528 ** may add additional static mutexes. Static mutexes are for internal
17529 ** use by SQLite only. Applications that use SQLite mutexes should
17530 ** use only the dynamic mutexes returned by SQLITE_MUTEX_FAST or
17531 ** SQLITE_MUTEX_RECURSIVE.
17533 ** Note that if one of the dynamic mutex parameters (SQLITE_MUTEX_FAST
17534 ** or SQLITE_MUTEX_RECURSIVE) is used then sqlite3_mutex_alloc()
17535 ** returns a different mutex on every call. But for the static
17536 ** mutex types, the same mutex is returned on every call that has
17537 ** the same type number.
17539 static sqlite3_mutex *pthreadMutexAlloc(int iType){
17540 static sqlite3_mutex staticMutexes[] = {
17541 SQLITE3_MUTEX_INITIALIZER,
17542 SQLITE3_MUTEX_INITIALIZER,
17543 SQLITE3_MUTEX_INITIALIZER,
17544 SQLITE3_MUTEX_INITIALIZER,
17545 SQLITE3_MUTEX_INITIALIZER,
17546 SQLITE3_MUTEX_INITIALIZER
17548 sqlite3_mutex *p;
17549 switch( iType ){
17550 case SQLITE_MUTEX_RECURSIVE: {
17551 p = sqlite3MallocZero( sizeof(*p) );
17552 if( p ){
17553 #ifdef SQLITE_HOMEGROWN_RECURSIVE_MUTEX
17554 /* If recursive mutexes are not available, we will have to
17555 ** build our own. See below. */
17556 pthread_mutex_init(&p->mutex, 0);
17557 #else
17558 /* Use a recursive mutex if it is available */
17559 pthread_mutexattr_t recursiveAttr;
17560 pthread_mutexattr_init(&recursiveAttr);
17561 pthread_mutexattr_settype(&recursiveAttr, PTHREAD_MUTEX_RECURSIVE);
17562 pthread_mutex_init(&p->mutex, &recursiveAttr);
17563 pthread_mutexattr_destroy(&recursiveAttr);
17564 #endif
17565 #if SQLITE_MUTEX_NREF
17566 p->id = iType;
17567 #endif
17569 break;
17571 case SQLITE_MUTEX_FAST: {
17572 p = sqlite3MallocZero( sizeof(*p) );
17573 if( p ){
17574 #if SQLITE_MUTEX_NREF
17575 p->id = iType;
17576 #endif
17577 pthread_mutex_init(&p->mutex, 0);
17579 break;
17581 default: {
17582 assert( iType-2 >= 0 );
17583 assert( iType-2 < ArraySize(staticMutexes) );
17584 p = &staticMutexes[iType-2];
17585 #if SQLITE_MUTEX_NREF
17586 p->id = iType;
17587 #endif
17588 break;
17591 return p;
17596 ** This routine deallocates a previously
17597 ** allocated mutex. SQLite is careful to deallocate every
17598 ** mutex that it allocates.
17600 static void pthreadMutexFree(sqlite3_mutex *p){
17601 assert( p->nRef==0 );
17602 assert( p->id==SQLITE_MUTEX_FAST || p->id==SQLITE_MUTEX_RECURSIVE );
17603 pthread_mutex_destroy(&p->mutex);
17604 sqlite3_free(p);
17608 ** The sqlite3_mutex_enter() and sqlite3_mutex_try() routines attempt
17609 ** to enter a mutex. If another thread is already within the mutex,
17610 ** sqlite3_mutex_enter() will block and sqlite3_mutex_try() will return
17611 ** SQLITE_BUSY. The sqlite3_mutex_try() interface returns SQLITE_OK
17612 ** upon successful entry. Mutexes created using SQLITE_MUTEX_RECURSIVE can
17613 ** be entered multiple times by the same thread. In such cases the,
17614 ** mutex must be exited an equal number of times before another thread
17615 ** can enter. If the same thread tries to enter any other kind of mutex
17616 ** more than once, the behavior is undefined.
17618 static void pthreadMutexEnter(sqlite3_mutex *p){
17619 assert( p->id==SQLITE_MUTEX_RECURSIVE || pthreadMutexNotheld(p) );
17621 #ifdef SQLITE_HOMEGROWN_RECURSIVE_MUTEX
17622 /* If recursive mutexes are not available, then we have to grow
17623 ** our own. This implementation assumes that pthread_equal()
17624 ** is atomic - that it cannot be deceived into thinking self
17625 ** and p->owner are equal if p->owner changes between two values
17626 ** that are not equal to self while the comparison is taking place.
17627 ** This implementation also assumes a coherent cache - that
17628 ** separate processes cannot read different values from the same
17629 ** address at the same time. If either of these two conditions
17630 ** are not met, then the mutexes will fail and problems will result.
17633 pthread_t self = pthread_self();
17634 if( p->nRef>0 && pthread_equal(p->owner, self) ){
17635 p->nRef++;
17636 }else{
17637 pthread_mutex_lock(&p->mutex);
17638 assert( p->nRef==0 );
17639 p->owner = self;
17640 p->nRef = 1;
17643 #else
17644 /* Use the built-in recursive mutexes if they are available.
17646 pthread_mutex_lock(&p->mutex);
17647 #if SQLITE_MUTEX_NREF
17648 assert( p->nRef>0 || p->owner==0 );
17649 p->owner = pthread_self();
17650 p->nRef++;
17651 #endif
17652 #endif
17654 #ifdef SQLITE_DEBUG
17655 if( p->trace ){
17656 printf("enter mutex %p (%d) with nRef=%d\n", p, p->trace, p->nRef);
17658 #endif
17660 static int pthreadMutexTry(sqlite3_mutex *p){
17661 int rc;
17662 assert( p->id==SQLITE_MUTEX_RECURSIVE || pthreadMutexNotheld(p) );
17664 #ifdef SQLITE_HOMEGROWN_RECURSIVE_MUTEX
17665 /* If recursive mutexes are not available, then we have to grow
17666 ** our own. This implementation assumes that pthread_equal()
17667 ** is atomic - that it cannot be deceived into thinking self
17668 ** and p->owner are equal if p->owner changes between two values
17669 ** that are not equal to self while the comparison is taking place.
17670 ** This implementation also assumes a coherent cache - that
17671 ** separate processes cannot read different values from the same
17672 ** address at the same time. If either of these two conditions
17673 ** are not met, then the mutexes will fail and problems will result.
17676 pthread_t self = pthread_self();
17677 if( p->nRef>0 && pthread_equal(p->owner, self) ){
17678 p->nRef++;
17679 rc = SQLITE_OK;
17680 }else if( pthread_mutex_trylock(&p->mutex)==0 ){
17681 assert( p->nRef==0 );
17682 p->owner = self;
17683 p->nRef = 1;
17684 rc = SQLITE_OK;
17685 }else{
17686 rc = SQLITE_BUSY;
17689 #else
17690 /* Use the built-in recursive mutexes if they are available.
17692 if( pthread_mutex_trylock(&p->mutex)==0 ){
17693 #if SQLITE_MUTEX_NREF
17694 p->owner = pthread_self();
17695 p->nRef++;
17696 #endif
17697 rc = SQLITE_OK;
17698 }else{
17699 rc = SQLITE_BUSY;
17701 #endif
17703 #ifdef SQLITE_DEBUG
17704 if( rc==SQLITE_OK && p->trace ){
17705 printf("enter mutex %p (%d) with nRef=%d\n", p, p->trace, p->nRef);
17707 #endif
17708 return rc;
17712 ** The sqlite3_mutex_leave() routine exits a mutex that was
17713 ** previously entered by the same thread. The behavior
17714 ** is undefined if the mutex is not currently entered or
17715 ** is not currently allocated. SQLite will never do either.
17717 static void pthreadMutexLeave(sqlite3_mutex *p){
17718 assert( pthreadMutexHeld(p) );
17719 #if SQLITE_MUTEX_NREF
17720 p->nRef--;
17721 if( p->nRef==0 ) p->owner = 0;
17722 #endif
17723 assert( p->nRef==0 || p->id==SQLITE_MUTEX_RECURSIVE );
17725 #ifdef SQLITE_HOMEGROWN_RECURSIVE_MUTEX
17726 if( p->nRef==0 ){
17727 pthread_mutex_unlock(&p->mutex);
17729 #else
17730 pthread_mutex_unlock(&p->mutex);
17731 #endif
17733 #ifdef SQLITE_DEBUG
17734 if( p->trace ){
17735 printf("leave mutex %p (%d) with nRef=%d\n", p, p->trace, p->nRef);
17737 #endif
17740 SQLITE_PRIVATE sqlite3_mutex_methods const *sqlite3DefaultMutex(void){
17741 static const sqlite3_mutex_methods sMutex = {
17742 pthreadMutexInit,
17743 pthreadMutexEnd,
17744 pthreadMutexAlloc,
17745 pthreadMutexFree,
17746 pthreadMutexEnter,
17747 pthreadMutexTry,
17748 pthreadMutexLeave,
17749 #ifdef SQLITE_DEBUG
17750 pthreadMutexHeld,
17751 pthreadMutexNotheld
17752 #else
17755 #endif
17758 return &sMutex;
17761 #endif /* SQLITE_MUTEX_PTHREAD */
17763 /************** End of mutex_unix.c ******************************************/
17764 /************** Begin file mutex_w32.c ***************************************/
17766 ** 2007 August 14
17768 ** The author disclaims copyright to this source code. In place of
17769 ** a legal notice, here is a blessing:
17771 ** May you do good and not evil.
17772 ** May you find forgiveness for yourself and forgive others.
17773 ** May you share freely, never taking more than you give.
17775 *************************************************************************
17776 ** This file contains the C functions that implement mutexes for win32
17780 ** The code in this file is only used if we are compiling multithreaded
17781 ** on a win32 system.
17783 #ifdef SQLITE_MUTEX_W32
17786 ** Each recursive mutex is an instance of the following structure.
17788 struct sqlite3_mutex {
17789 CRITICAL_SECTION mutex; /* Mutex controlling the lock */
17790 int id; /* Mutex type */
17791 #ifdef SQLITE_DEBUG
17792 volatile int nRef; /* Number of enterances */
17793 volatile DWORD owner; /* Thread holding this mutex */
17794 int trace; /* True to trace changes */
17795 #endif
17797 #define SQLITE_W32_MUTEX_INITIALIZER { 0 }
17798 #ifdef SQLITE_DEBUG
17799 #define SQLITE3_MUTEX_INITIALIZER { SQLITE_W32_MUTEX_INITIALIZER, 0, 0L, (DWORD)0, 0 }
17800 #else
17801 #define SQLITE3_MUTEX_INITIALIZER { SQLITE_W32_MUTEX_INITIALIZER, 0 }
17802 #endif
17805 ** Return true (non-zero) if we are running under WinNT, Win2K, WinXP,
17806 ** or WinCE. Return false (zero) for Win95, Win98, or WinME.
17808 ** Here is an interesting observation: Win95, Win98, and WinME lack
17809 ** the LockFileEx() API. But we can still statically link against that
17810 ** API as long as we don't call it win running Win95/98/ME. A call to
17811 ** this routine is used to determine if the host is Win95/98/ME or
17812 ** WinNT/2K/XP so that we will know whether or not we can safely call
17813 ** the LockFileEx() API.
17815 ** mutexIsNT() is only used for the TryEnterCriticalSection() API call,
17816 ** which is only available if your application was compiled with
17817 ** _WIN32_WINNT defined to a value >= 0x0400. Currently, the only
17818 ** call to TryEnterCriticalSection() is #ifdef'ed out, so #ifdef
17819 ** this out as well.
17821 #if 0
17822 #if SQLITE_OS_WINCE
17823 # define mutexIsNT() (1)
17824 #else
17825 static int mutexIsNT(void){
17826 static int osType = 0;
17827 if( osType==0 ){
17828 OSVERSIONINFO sInfo;
17829 sInfo.dwOSVersionInfoSize = sizeof(sInfo);
17830 GetVersionEx(&sInfo);
17831 osType = sInfo.dwPlatformId==VER_PLATFORM_WIN32_NT ? 2 : 1;
17833 return osType==2;
17835 #endif /* SQLITE_OS_WINCE */
17836 #endif
17838 #ifdef SQLITE_DEBUG
17840 ** The sqlite3_mutex_held() and sqlite3_mutex_notheld() routine are
17841 ** intended for use only inside assert() statements.
17843 static int winMutexHeld(sqlite3_mutex *p){
17844 return p->nRef!=0 && p->owner==GetCurrentThreadId();
17846 static int winMutexNotheld2(sqlite3_mutex *p, DWORD tid){
17847 return p->nRef==0 || p->owner!=tid;
17849 static int winMutexNotheld(sqlite3_mutex *p){
17850 DWORD tid = GetCurrentThreadId();
17851 return winMutexNotheld2(p, tid);
17853 #endif
17857 ** Initialize and deinitialize the mutex subsystem.
17859 static sqlite3_mutex winMutex_staticMutexes[6] = {
17860 SQLITE3_MUTEX_INITIALIZER,
17861 SQLITE3_MUTEX_INITIALIZER,
17862 SQLITE3_MUTEX_INITIALIZER,
17863 SQLITE3_MUTEX_INITIALIZER,
17864 SQLITE3_MUTEX_INITIALIZER,
17865 SQLITE3_MUTEX_INITIALIZER
17867 static int winMutex_isInit = 0;
17868 /* As winMutexInit() and winMutexEnd() are called as part
17869 ** of the sqlite3_initialize and sqlite3_shutdown()
17870 ** processing, the "interlocked" magic is probably not
17871 ** strictly necessary.
17873 static long winMutex_lock = 0;
17875 static int winMutexInit(void){
17876 /* The first to increment to 1 does actual initialization */
17877 if( InterlockedCompareExchange(&winMutex_lock, 1, 0)==0 ){
17878 int i;
17879 for(i=0; i<ArraySize(winMutex_staticMutexes); i++){
17880 InitializeCriticalSection(&winMutex_staticMutexes[i].mutex);
17882 winMutex_isInit = 1;
17883 }else{
17884 /* Someone else is in the process of initing the static mutexes */
17885 while( !winMutex_isInit ){
17886 Sleep(1);
17889 return SQLITE_OK;
17892 static int winMutexEnd(void){
17893 /* The first to decrement to 0 does actual shutdown
17894 ** (which should be the last to shutdown.) */
17895 if( InterlockedCompareExchange(&winMutex_lock, 0, 1)==1 ){
17896 if( winMutex_isInit==1 ){
17897 int i;
17898 for(i=0; i<ArraySize(winMutex_staticMutexes); i++){
17899 DeleteCriticalSection(&winMutex_staticMutexes[i].mutex);
17901 winMutex_isInit = 0;
17904 return SQLITE_OK;
17908 ** The sqlite3_mutex_alloc() routine allocates a new
17909 ** mutex and returns a pointer to it. If it returns NULL
17910 ** that means that a mutex could not be allocated. SQLite
17911 ** will unwind its stack and return an error. The argument
17912 ** to sqlite3_mutex_alloc() is one of these integer constants:
17914 ** <ul>
17915 ** <li> SQLITE_MUTEX_FAST
17916 ** <li> SQLITE_MUTEX_RECURSIVE
17917 ** <li> SQLITE_MUTEX_STATIC_MASTER
17918 ** <li> SQLITE_MUTEX_STATIC_MEM
17919 ** <li> SQLITE_MUTEX_STATIC_MEM2
17920 ** <li> SQLITE_MUTEX_STATIC_PRNG
17921 ** <li> SQLITE_MUTEX_STATIC_LRU
17922 ** <li> SQLITE_MUTEX_STATIC_PMEM
17923 ** </ul>
17925 ** The first two constants cause sqlite3_mutex_alloc() to create
17926 ** a new mutex. The new mutex is recursive when SQLITE_MUTEX_RECURSIVE
17927 ** is used but not necessarily so when SQLITE_MUTEX_FAST is used.
17928 ** The mutex implementation does not need to make a distinction
17929 ** between SQLITE_MUTEX_RECURSIVE and SQLITE_MUTEX_FAST if it does
17930 ** not want to. But SQLite will only request a recursive mutex in
17931 ** cases where it really needs one. If a faster non-recursive mutex
17932 ** implementation is available on the host platform, the mutex subsystem
17933 ** might return such a mutex in response to SQLITE_MUTEX_FAST.
17935 ** The other allowed parameters to sqlite3_mutex_alloc() each return
17936 ** a pointer to a static preexisting mutex. Six static mutexes are
17937 ** used by the current version of SQLite. Future versions of SQLite
17938 ** may add additional static mutexes. Static mutexes are for internal
17939 ** use by SQLite only. Applications that use SQLite mutexes should
17940 ** use only the dynamic mutexes returned by SQLITE_MUTEX_FAST or
17941 ** SQLITE_MUTEX_RECURSIVE.
17943 ** Note that if one of the dynamic mutex parameters (SQLITE_MUTEX_FAST
17944 ** or SQLITE_MUTEX_RECURSIVE) is used then sqlite3_mutex_alloc()
17945 ** returns a different mutex on every call. But for the static
17946 ** mutex types, the same mutex is returned on every call that has
17947 ** the same type number.
17949 static sqlite3_mutex *winMutexAlloc(int iType){
17950 sqlite3_mutex *p;
17952 switch( iType ){
17953 case SQLITE_MUTEX_FAST:
17954 case SQLITE_MUTEX_RECURSIVE: {
17955 p = sqlite3MallocZero( sizeof(*p) );
17956 if( p ){
17957 #ifdef SQLITE_DEBUG
17958 p->id = iType;
17959 #endif
17960 InitializeCriticalSection(&p->mutex);
17962 break;
17964 default: {
17965 assert( winMutex_isInit==1 );
17966 assert( iType-2 >= 0 );
17967 assert( iType-2 < ArraySize(winMutex_staticMutexes) );
17968 p = &winMutex_staticMutexes[iType-2];
17969 #ifdef SQLITE_DEBUG
17970 p->id = iType;
17971 #endif
17972 break;
17975 return p;
17980 ** This routine deallocates a previously
17981 ** allocated mutex. SQLite is careful to deallocate every
17982 ** mutex that it allocates.
17984 static void winMutexFree(sqlite3_mutex *p){
17985 assert( p );
17986 assert( p->nRef==0 && p->owner==0 );
17987 assert( p->id==SQLITE_MUTEX_FAST || p->id==SQLITE_MUTEX_RECURSIVE );
17988 DeleteCriticalSection(&p->mutex);
17989 sqlite3_free(p);
17993 ** The sqlite3_mutex_enter() and sqlite3_mutex_try() routines attempt
17994 ** to enter a mutex. If another thread is already within the mutex,
17995 ** sqlite3_mutex_enter() will block and sqlite3_mutex_try() will return
17996 ** SQLITE_BUSY. The sqlite3_mutex_try() interface returns SQLITE_OK
17997 ** upon successful entry. Mutexes created using SQLITE_MUTEX_RECURSIVE can
17998 ** be entered multiple times by the same thread. In such cases the,
17999 ** mutex must be exited an equal number of times before another thread
18000 ** can enter. If the same thread tries to enter any other kind of mutex
18001 ** more than once, the behavior is undefined.
18003 static void winMutexEnter(sqlite3_mutex *p){
18004 #ifdef SQLITE_DEBUG
18005 DWORD tid = GetCurrentThreadId();
18006 assert( p->id==SQLITE_MUTEX_RECURSIVE || winMutexNotheld2(p, tid) );
18007 #endif
18008 EnterCriticalSection(&p->mutex);
18009 #ifdef SQLITE_DEBUG
18010 assert( p->nRef>0 || p->owner==0 );
18011 p->owner = tid;
18012 p->nRef++;
18013 if( p->trace ){
18014 printf("enter mutex %p (%d) with nRef=%d\n", p, p->trace, p->nRef);
18016 #endif
18018 static int winMutexTry(sqlite3_mutex *p){
18019 #ifndef NDEBUG
18020 DWORD tid = GetCurrentThreadId();
18021 #endif
18022 int rc = SQLITE_BUSY;
18023 assert( p->id==SQLITE_MUTEX_RECURSIVE || winMutexNotheld2(p, tid) );
18025 ** The sqlite3_mutex_try() routine is very rarely used, and when it
18026 ** is used it is merely an optimization. So it is OK for it to always
18027 ** fail.
18029 ** The TryEnterCriticalSection() interface is only available on WinNT.
18030 ** And some windows compilers complain if you try to use it without
18031 ** first doing some #defines that prevent SQLite from building on Win98.
18032 ** For that reason, we will omit this optimization for now. See
18033 ** ticket #2685.
18035 #if 0
18036 if( mutexIsNT() && TryEnterCriticalSection(&p->mutex) ){
18037 p->owner = tid;
18038 p->nRef++;
18039 rc = SQLITE_OK;
18041 #else
18042 UNUSED_PARAMETER(p);
18043 #endif
18044 #ifdef SQLITE_DEBUG
18045 if( rc==SQLITE_OK && p->trace ){
18046 printf("try mutex %p (%d) with nRef=%d\n", p, p->trace, p->nRef);
18048 #endif
18049 return rc;
18053 ** The sqlite3_mutex_leave() routine exits a mutex that was
18054 ** previously entered by the same thread. The behavior
18055 ** is undefined if the mutex is not currently entered or
18056 ** is not currently allocated. SQLite will never do either.
18058 static void winMutexLeave(sqlite3_mutex *p){
18059 #ifndef NDEBUG
18060 DWORD tid = GetCurrentThreadId();
18061 assert( p->nRef>0 );
18062 assert( p->owner==tid );
18063 p->nRef--;
18064 if( p->nRef==0 ) p->owner = 0;
18065 assert( p->nRef==0 || p->id==SQLITE_MUTEX_RECURSIVE );
18066 #endif
18067 LeaveCriticalSection(&p->mutex);
18068 #ifdef SQLITE_DEBUG
18069 if( p->trace ){
18070 printf("leave mutex %p (%d) with nRef=%d\n", p, p->trace, p->nRef);
18072 #endif
18075 SQLITE_PRIVATE sqlite3_mutex_methods const *sqlite3DefaultMutex(void){
18076 static const sqlite3_mutex_methods sMutex = {
18077 winMutexInit,
18078 winMutexEnd,
18079 winMutexAlloc,
18080 winMutexFree,
18081 winMutexEnter,
18082 winMutexTry,
18083 winMutexLeave,
18084 #ifdef SQLITE_DEBUG
18085 winMutexHeld,
18086 winMutexNotheld
18087 #else
18090 #endif
18093 return &sMutex;
18095 #endif /* SQLITE_MUTEX_W32 */
18097 /************** End of mutex_w32.c *******************************************/
18098 /************** Begin file malloc.c ******************************************/
18100 ** 2001 September 15
18102 ** The author disclaims copyright to this source code. In place of
18103 ** a legal notice, here is a blessing:
18105 ** May you do good and not evil.
18106 ** May you find forgiveness for yourself and forgive others.
18107 ** May you share freely, never taking more than you give.
18109 *************************************************************************
18111 ** Memory allocation functions used throughout sqlite.
18113 /* #include <stdarg.h> */
18116 ** Attempt to release up to n bytes of non-essential memory currently
18117 ** held by SQLite. An example of non-essential memory is memory used to
18118 ** cache database pages that are not currently in use.
18120 SQLITE_API int sqlite3_release_memory(int n){
18121 #ifdef SQLITE_ENABLE_MEMORY_MANAGEMENT
18122 return sqlite3PcacheReleaseMemory(n);
18123 #else
18124 /* IMPLEMENTATION-OF: R-34391-24921 The sqlite3_release_memory() routine
18125 ** is a no-op returning zero if SQLite is not compiled with
18126 ** SQLITE_ENABLE_MEMORY_MANAGEMENT. */
18127 UNUSED_PARAMETER(n);
18128 return 0;
18129 #endif
18133 ** An instance of the following object records the location of
18134 ** each unused scratch buffer.
18136 typedef struct ScratchFreeslot {
18137 struct ScratchFreeslot *pNext; /* Next unused scratch buffer */
18138 } ScratchFreeslot;
18141 ** State information local to the memory allocation subsystem.
18143 static SQLITE_WSD struct Mem0Global {
18144 sqlite3_mutex *mutex; /* Mutex to serialize access */
18147 ** The alarm callback and its arguments. The mem0.mutex lock will
18148 ** be held while the callback is running. Recursive calls into
18149 ** the memory subsystem are allowed, but no new callbacks will be
18150 ** issued.
18152 sqlite3_int64 alarmThreshold;
18153 void (*alarmCallback)(void*, sqlite3_int64,int);
18154 void *alarmArg;
18157 ** Pointers to the end of sqlite3GlobalConfig.pScratch memory
18158 ** (so that a range test can be used to determine if an allocation
18159 ** being freed came from pScratch) and a pointer to the list of
18160 ** unused scratch allocations.
18162 void *pScratchEnd;
18163 ScratchFreeslot *pScratchFree;
18164 u32 nScratchFree;
18167 ** True if heap is nearly "full" where "full" is defined by the
18168 ** sqlite3_soft_heap_limit() setting.
18170 int nearlyFull;
18171 } mem0 = { 0, 0, 0, 0, 0, 0, 0, 0 };
18173 #define mem0 GLOBAL(struct Mem0Global, mem0)
18176 ** This routine runs when the memory allocator sees that the
18177 ** total memory allocation is about to exceed the soft heap
18178 ** limit.
18180 static void softHeapLimitEnforcer(
18181 void *NotUsed,
18182 sqlite3_int64 NotUsed2,
18183 int allocSize
18185 UNUSED_PARAMETER2(NotUsed, NotUsed2);
18186 sqlite3_release_memory(allocSize);
18190 ** Change the alarm callback
18192 static int sqlite3MemoryAlarm(
18193 void(*xCallback)(void *pArg, sqlite3_int64 used,int N),
18194 void *pArg,
18195 sqlite3_int64 iThreshold
18197 int nUsed;
18198 sqlite3_mutex_enter(mem0.mutex);
18199 mem0.alarmCallback = xCallback;
18200 mem0.alarmArg = pArg;
18201 mem0.alarmThreshold = iThreshold;
18202 nUsed = sqlite3StatusValue(SQLITE_STATUS_MEMORY_USED);
18203 mem0.nearlyFull = (iThreshold>0 && iThreshold<=nUsed);
18204 sqlite3_mutex_leave(mem0.mutex);
18205 return SQLITE_OK;
18208 #ifndef SQLITE_OMIT_DEPRECATED
18210 ** Deprecated external interface. Internal/core SQLite code
18211 ** should call sqlite3MemoryAlarm.
18213 SQLITE_API int sqlite3_memory_alarm(
18214 void(*xCallback)(void *pArg, sqlite3_int64 used,int N),
18215 void *pArg,
18216 sqlite3_int64 iThreshold
18218 return sqlite3MemoryAlarm(xCallback, pArg, iThreshold);
18220 #endif
18223 ** Set the soft heap-size limit for the library. Passing a zero or
18224 ** negative value indicates no limit.
18226 SQLITE_API sqlite3_int64 sqlite3_soft_heap_limit64(sqlite3_int64 n){
18227 sqlite3_int64 priorLimit;
18228 sqlite3_int64 excess;
18229 #ifndef SQLITE_OMIT_AUTOINIT
18230 sqlite3_initialize();
18231 #endif
18232 sqlite3_mutex_enter(mem0.mutex);
18233 priorLimit = mem0.alarmThreshold;
18234 sqlite3_mutex_leave(mem0.mutex);
18235 if( n<0 ) return priorLimit;
18236 if( n>0 ){
18237 sqlite3MemoryAlarm(softHeapLimitEnforcer, 0, n);
18238 }else{
18239 sqlite3MemoryAlarm(0, 0, 0);
18241 excess = sqlite3_memory_used() - n;
18242 if( excess>0 ) sqlite3_release_memory((int)(excess & 0x7fffffff));
18243 return priorLimit;
18245 SQLITE_API void sqlite3_soft_heap_limit(int n){
18246 if( n<0 ) n = 0;
18247 sqlite3_soft_heap_limit64(n);
18251 ** Initialize the memory allocation subsystem.
18253 SQLITE_PRIVATE int sqlite3MallocInit(void){
18254 if( sqlite3GlobalConfig.m.xMalloc==0 ){
18255 sqlite3MemSetDefault();
18257 memset(&mem0, 0, sizeof(mem0));
18258 if( sqlite3GlobalConfig.bCoreMutex ){
18259 mem0.mutex = sqlite3MutexAlloc(SQLITE_MUTEX_STATIC_MEM);
18261 if( sqlite3GlobalConfig.pScratch && sqlite3GlobalConfig.szScratch>=100
18262 && sqlite3GlobalConfig.nScratch>0 ){
18263 int i, n, sz;
18264 ScratchFreeslot *pSlot;
18265 sz = ROUNDDOWN8(sqlite3GlobalConfig.szScratch);
18266 sqlite3GlobalConfig.szScratch = sz;
18267 pSlot = (ScratchFreeslot*)sqlite3GlobalConfig.pScratch;
18268 n = sqlite3GlobalConfig.nScratch;
18269 mem0.pScratchFree = pSlot;
18270 mem0.nScratchFree = n;
18271 for(i=0; i<n-1; i++){
18272 pSlot->pNext = (ScratchFreeslot*)(sz+(char*)pSlot);
18273 pSlot = pSlot->pNext;
18275 pSlot->pNext = 0;
18276 mem0.pScratchEnd = (void*)&pSlot[1];
18277 }else{
18278 mem0.pScratchEnd = 0;
18279 sqlite3GlobalConfig.pScratch = 0;
18280 sqlite3GlobalConfig.szScratch = 0;
18281 sqlite3GlobalConfig.nScratch = 0;
18283 if( sqlite3GlobalConfig.pPage==0 || sqlite3GlobalConfig.szPage<512
18284 || sqlite3GlobalConfig.nPage<1 ){
18285 sqlite3GlobalConfig.pPage = 0;
18286 sqlite3GlobalConfig.szPage = 0;
18287 sqlite3GlobalConfig.nPage = 0;
18289 return sqlite3GlobalConfig.m.xInit(sqlite3GlobalConfig.m.pAppData);
18293 ** Return true if the heap is currently under memory pressure - in other
18294 ** words if the amount of heap used is close to the limit set by
18295 ** sqlite3_soft_heap_limit().
18297 SQLITE_PRIVATE int sqlite3HeapNearlyFull(void){
18298 return mem0.nearlyFull;
18302 ** Deinitialize the memory allocation subsystem.
18304 SQLITE_PRIVATE void sqlite3MallocEnd(void){
18305 if( sqlite3GlobalConfig.m.xShutdown ){
18306 sqlite3GlobalConfig.m.xShutdown(sqlite3GlobalConfig.m.pAppData);
18308 memset(&mem0, 0, sizeof(mem0));
18312 ** Return the amount of memory currently checked out.
18314 SQLITE_API sqlite3_int64 sqlite3_memory_used(void){
18315 int n, mx;
18316 sqlite3_int64 res;
18317 sqlite3_status(SQLITE_STATUS_MEMORY_USED, &n, &mx, 0);
18318 res = (sqlite3_int64)n; /* Work around bug in Borland C. Ticket #3216 */
18319 return res;
18323 ** Return the maximum amount of memory that has ever been
18324 ** checked out since either the beginning of this process
18325 ** or since the most recent reset.
18327 SQLITE_API sqlite3_int64 sqlite3_memory_highwater(int resetFlag){
18328 int n, mx;
18329 sqlite3_int64 res;
18330 sqlite3_status(SQLITE_STATUS_MEMORY_USED, &n, &mx, resetFlag);
18331 res = (sqlite3_int64)mx; /* Work around bug in Borland C. Ticket #3216 */
18332 return res;
18336 ** Trigger the alarm
18338 static void sqlite3MallocAlarm(int nByte){
18339 void (*xCallback)(void*,sqlite3_int64,int);
18340 sqlite3_int64 nowUsed;
18341 void *pArg;
18342 if( mem0.alarmCallback==0 ) return;
18343 xCallback = mem0.alarmCallback;
18344 nowUsed = sqlite3StatusValue(SQLITE_STATUS_MEMORY_USED);
18345 pArg = mem0.alarmArg;
18346 mem0.alarmCallback = 0;
18347 sqlite3_mutex_leave(mem0.mutex);
18348 xCallback(pArg, nowUsed, nByte);
18349 sqlite3_mutex_enter(mem0.mutex);
18350 mem0.alarmCallback = xCallback;
18351 mem0.alarmArg = pArg;
18355 ** Do a memory allocation with statistics and alarms. Assume the
18356 ** lock is already held.
18358 static int mallocWithAlarm(int n, void **pp){
18359 int nFull;
18360 void *p;
18361 assert( sqlite3_mutex_held(mem0.mutex) );
18362 nFull = sqlite3GlobalConfig.m.xRoundup(n);
18363 sqlite3StatusSet(SQLITE_STATUS_MALLOC_SIZE, n);
18364 if( mem0.alarmCallback!=0 ){
18365 int nUsed = sqlite3StatusValue(SQLITE_STATUS_MEMORY_USED);
18366 if( nUsed >= mem0.alarmThreshold - nFull ){
18367 mem0.nearlyFull = 1;
18368 sqlite3MallocAlarm(nFull);
18369 }else{
18370 mem0.nearlyFull = 0;
18373 p = sqlite3GlobalConfig.m.xMalloc(nFull);
18374 #ifdef SQLITE_ENABLE_MEMORY_MANAGEMENT
18375 if( p==0 && mem0.alarmCallback ){
18376 sqlite3MallocAlarm(nFull);
18377 p = sqlite3GlobalConfig.m.xMalloc(nFull);
18379 #endif
18380 if( p ){
18381 nFull = sqlite3MallocSize(p);
18382 sqlite3StatusAdd(SQLITE_STATUS_MEMORY_USED, nFull);
18383 sqlite3StatusAdd(SQLITE_STATUS_MALLOC_COUNT, 1);
18385 *pp = p;
18386 return nFull;
18390 ** Allocate memory. This routine is like sqlite3_malloc() except that it
18391 ** assumes the memory subsystem has already been initialized.
18393 SQLITE_PRIVATE void *sqlite3Malloc(int n){
18394 void *p;
18395 if( n<=0 /* IMP: R-65312-04917 */
18396 || n>=0x7fffff00
18398 /* A memory allocation of a number of bytes which is near the maximum
18399 ** signed integer value might cause an integer overflow inside of the
18400 ** xMalloc(). Hence we limit the maximum size to 0x7fffff00, giving
18401 ** 255 bytes of overhead. SQLite itself will never use anything near
18402 ** this amount. The only way to reach the limit is with sqlite3_malloc() */
18403 p = 0;
18404 }else if( sqlite3GlobalConfig.bMemstat ){
18405 sqlite3_mutex_enter(mem0.mutex);
18406 mallocWithAlarm(n, &p);
18407 sqlite3_mutex_leave(mem0.mutex);
18408 }else{
18409 p = sqlite3GlobalConfig.m.xMalloc(n);
18411 assert( EIGHT_BYTE_ALIGNMENT(p) ); /* IMP: R-04675-44850 */
18412 return p;
18416 ** This version of the memory allocation is for use by the application.
18417 ** First make sure the memory subsystem is initialized, then do the
18418 ** allocation.
18420 SQLITE_API void *sqlite3_malloc(int n){
18421 #ifndef SQLITE_OMIT_AUTOINIT
18422 if( sqlite3_initialize() ) return 0;
18423 #endif
18424 return sqlite3Malloc(n);
18428 ** Each thread may only have a single outstanding allocation from
18429 ** xScratchMalloc(). We verify this constraint in the single-threaded
18430 ** case by setting scratchAllocOut to 1 when an allocation
18431 ** is outstanding clearing it when the allocation is freed.
18433 #if SQLITE_THREADSAFE==0 && !defined(NDEBUG)
18434 static int scratchAllocOut = 0;
18435 #endif
18439 ** Allocate memory that is to be used and released right away.
18440 ** This routine is similar to alloca() in that it is not intended
18441 ** for situations where the memory might be held long-term. This
18442 ** routine is intended to get memory to old large transient data
18443 ** structures that would not normally fit on the stack of an
18444 ** embedded processor.
18446 SQLITE_PRIVATE void *sqlite3ScratchMalloc(int n){
18447 void *p;
18448 assert( n>0 );
18450 sqlite3_mutex_enter(mem0.mutex);
18451 if( mem0.nScratchFree && sqlite3GlobalConfig.szScratch>=n ){
18452 p = mem0.pScratchFree;
18453 mem0.pScratchFree = mem0.pScratchFree->pNext;
18454 mem0.nScratchFree--;
18455 sqlite3StatusAdd(SQLITE_STATUS_SCRATCH_USED, 1);
18456 sqlite3StatusSet(SQLITE_STATUS_SCRATCH_SIZE, n);
18457 sqlite3_mutex_leave(mem0.mutex);
18458 }else{
18459 if( sqlite3GlobalConfig.bMemstat ){
18460 sqlite3StatusSet(SQLITE_STATUS_SCRATCH_SIZE, n);
18461 n = mallocWithAlarm(n, &p);
18462 if( p ) sqlite3StatusAdd(SQLITE_STATUS_SCRATCH_OVERFLOW, n);
18463 sqlite3_mutex_leave(mem0.mutex);
18464 }else{
18465 sqlite3_mutex_leave(mem0.mutex);
18466 p = sqlite3GlobalConfig.m.xMalloc(n);
18468 sqlite3MemdebugSetType(p, MEMTYPE_SCRATCH);
18470 assert( sqlite3_mutex_notheld(mem0.mutex) );
18473 #if SQLITE_THREADSAFE==0 && !defined(NDEBUG)
18474 /* Verify that no more than two scratch allocations per thread
18475 ** are outstanding at one time. (This is only checked in the
18476 ** single-threaded case since checking in the multi-threaded case
18477 ** would be much more complicated.) */
18478 assert( scratchAllocOut<=1 );
18479 if( p ) scratchAllocOut++;
18480 #endif
18482 return p;
18484 SQLITE_PRIVATE void sqlite3ScratchFree(void *p){
18485 if( p ){
18487 #if SQLITE_THREADSAFE==0 && !defined(NDEBUG)
18488 /* Verify that no more than two scratch allocation per thread
18489 ** is outstanding at one time. (This is only checked in the
18490 ** single-threaded case since checking in the multi-threaded case
18491 ** would be much more complicated.) */
18492 assert( scratchAllocOut>=1 && scratchAllocOut<=2 );
18493 scratchAllocOut--;
18494 #endif
18496 if( p>=sqlite3GlobalConfig.pScratch && p<mem0.pScratchEnd ){
18497 /* Release memory from the SQLITE_CONFIG_SCRATCH allocation */
18498 ScratchFreeslot *pSlot;
18499 pSlot = (ScratchFreeslot*)p;
18500 sqlite3_mutex_enter(mem0.mutex);
18501 pSlot->pNext = mem0.pScratchFree;
18502 mem0.pScratchFree = pSlot;
18503 mem0.nScratchFree++;
18504 assert( mem0.nScratchFree <= (u32)sqlite3GlobalConfig.nScratch );
18505 sqlite3StatusAdd(SQLITE_STATUS_SCRATCH_USED, -1);
18506 sqlite3_mutex_leave(mem0.mutex);
18507 }else{
18508 /* Release memory back to the heap */
18509 assert( sqlite3MemdebugHasType(p, MEMTYPE_SCRATCH) );
18510 assert( sqlite3MemdebugNoType(p, ~MEMTYPE_SCRATCH) );
18511 sqlite3MemdebugSetType(p, MEMTYPE_HEAP);
18512 if( sqlite3GlobalConfig.bMemstat ){
18513 int iSize = sqlite3MallocSize(p);
18514 sqlite3_mutex_enter(mem0.mutex);
18515 sqlite3StatusAdd(SQLITE_STATUS_SCRATCH_OVERFLOW, -iSize);
18516 sqlite3StatusAdd(SQLITE_STATUS_MEMORY_USED, -iSize);
18517 sqlite3StatusAdd(SQLITE_STATUS_MALLOC_COUNT, -1);
18518 sqlite3GlobalConfig.m.xFree(p);
18519 sqlite3_mutex_leave(mem0.mutex);
18520 }else{
18521 sqlite3GlobalConfig.m.xFree(p);
18528 ** TRUE if p is a lookaside memory allocation from db
18530 #ifndef SQLITE_OMIT_LOOKASIDE
18531 static int isLookaside(sqlite3 *db, void *p){
18532 return p && p>=db->lookaside.pStart && p<db->lookaside.pEnd;
18534 #else
18535 #define isLookaside(A,B) 0
18536 #endif
18539 ** Return the size of a memory allocation previously obtained from
18540 ** sqlite3Malloc() or sqlite3_malloc().
18542 SQLITE_PRIVATE int sqlite3MallocSize(void *p){
18543 assert( sqlite3MemdebugHasType(p, MEMTYPE_HEAP) );
18544 assert( sqlite3MemdebugNoType(p, MEMTYPE_DB) );
18545 return sqlite3GlobalConfig.m.xSize(p);
18547 SQLITE_PRIVATE int sqlite3DbMallocSize(sqlite3 *db, void *p){
18548 assert( db==0 || sqlite3_mutex_held(db->mutex) );
18549 if( db && isLookaside(db, p) ){
18550 return db->lookaside.sz;
18551 }else{
18552 assert( sqlite3MemdebugHasType(p, MEMTYPE_DB) );
18553 assert( sqlite3MemdebugHasType(p, MEMTYPE_LOOKASIDE|MEMTYPE_HEAP) );
18554 assert( db!=0 || sqlite3MemdebugNoType(p, MEMTYPE_LOOKASIDE) );
18555 return sqlite3GlobalConfig.m.xSize(p);
18560 ** Free memory previously obtained from sqlite3Malloc().
18562 SQLITE_API void sqlite3_free(void *p){
18563 if( p==0 ) return; /* IMP: R-49053-54554 */
18564 assert( sqlite3MemdebugNoType(p, MEMTYPE_DB) );
18565 assert( sqlite3MemdebugHasType(p, MEMTYPE_HEAP) );
18566 if( sqlite3GlobalConfig.bMemstat ){
18567 sqlite3_mutex_enter(mem0.mutex);
18568 sqlite3StatusAdd(SQLITE_STATUS_MEMORY_USED, -sqlite3MallocSize(p));
18569 sqlite3StatusAdd(SQLITE_STATUS_MALLOC_COUNT, -1);
18570 sqlite3GlobalConfig.m.xFree(p);
18571 sqlite3_mutex_leave(mem0.mutex);
18572 }else{
18573 sqlite3GlobalConfig.m.xFree(p);
18578 ** Free memory that might be associated with a particular database
18579 ** connection.
18581 SQLITE_PRIVATE void sqlite3DbFree(sqlite3 *db, void *p){
18582 assert( db==0 || sqlite3_mutex_held(db->mutex) );
18583 if( db ){
18584 if( db->pnBytesFreed ){
18585 *db->pnBytesFreed += sqlite3DbMallocSize(db, p);
18586 return;
18588 if( isLookaside(db, p) ){
18589 LookasideSlot *pBuf = (LookasideSlot*)p;
18590 pBuf->pNext = db->lookaside.pFree;
18591 db->lookaside.pFree = pBuf;
18592 db->lookaside.nOut--;
18593 return;
18596 assert( sqlite3MemdebugHasType(p, MEMTYPE_DB) );
18597 assert( sqlite3MemdebugHasType(p, MEMTYPE_LOOKASIDE|MEMTYPE_HEAP) );
18598 assert( db!=0 || sqlite3MemdebugNoType(p, MEMTYPE_LOOKASIDE) );
18599 sqlite3MemdebugSetType(p, MEMTYPE_HEAP);
18600 sqlite3_free(p);
18604 ** Change the size of an existing memory allocation
18606 SQLITE_PRIVATE void *sqlite3Realloc(void *pOld, int nBytes){
18607 int nOld, nNew, nDiff;
18608 void *pNew;
18609 if( pOld==0 ){
18610 return sqlite3Malloc(nBytes); /* IMP: R-28354-25769 */
18612 if( nBytes<=0 ){
18613 sqlite3_free(pOld); /* IMP: R-31593-10574 */
18614 return 0;
18616 if( nBytes>=0x7fffff00 ){
18617 /* The 0x7ffff00 limit term is explained in comments on sqlite3Malloc() */
18618 return 0;
18620 nOld = sqlite3MallocSize(pOld);
18621 /* IMPLEMENTATION-OF: R-46199-30249 SQLite guarantees that the second
18622 ** argument to xRealloc is always a value returned by a prior call to
18623 ** xRoundup. */
18624 nNew = sqlite3GlobalConfig.m.xRoundup(nBytes);
18625 if( nOld==nNew ){
18626 pNew = pOld;
18627 }else if( sqlite3GlobalConfig.bMemstat ){
18628 sqlite3_mutex_enter(mem0.mutex);
18629 sqlite3StatusSet(SQLITE_STATUS_MALLOC_SIZE, nBytes);
18630 nDiff = nNew - nOld;
18631 if( sqlite3StatusValue(SQLITE_STATUS_MEMORY_USED) >=
18632 mem0.alarmThreshold-nDiff ){
18633 sqlite3MallocAlarm(nDiff);
18635 assert( sqlite3MemdebugHasType(pOld, MEMTYPE_HEAP) );
18636 assert( sqlite3MemdebugNoType(pOld, ~MEMTYPE_HEAP) );
18637 pNew = sqlite3GlobalConfig.m.xRealloc(pOld, nNew);
18638 if( pNew==0 && mem0.alarmCallback ){
18639 sqlite3MallocAlarm(nBytes);
18640 pNew = sqlite3GlobalConfig.m.xRealloc(pOld, nNew);
18642 if( pNew ){
18643 nNew = sqlite3MallocSize(pNew);
18644 sqlite3StatusAdd(SQLITE_STATUS_MEMORY_USED, nNew-nOld);
18646 sqlite3_mutex_leave(mem0.mutex);
18647 }else{
18648 pNew = sqlite3GlobalConfig.m.xRealloc(pOld, nNew);
18650 assert( EIGHT_BYTE_ALIGNMENT(pNew) ); /* IMP: R-04675-44850 */
18651 return pNew;
18655 ** The public interface to sqlite3Realloc. Make sure that the memory
18656 ** subsystem is initialized prior to invoking sqliteRealloc.
18658 SQLITE_API void *sqlite3_realloc(void *pOld, int n){
18659 #ifndef SQLITE_OMIT_AUTOINIT
18660 if( sqlite3_initialize() ) return 0;
18661 #endif
18662 return sqlite3Realloc(pOld, n);
18667 ** Allocate and zero memory.
18669 SQLITE_PRIVATE void *sqlite3MallocZero(int n){
18670 void *p = sqlite3Malloc(n);
18671 if( p ){
18672 memset(p, 0, n);
18674 return p;
18678 ** Allocate and zero memory. If the allocation fails, make
18679 ** the mallocFailed flag in the connection pointer.
18681 SQLITE_PRIVATE void *sqlite3DbMallocZero(sqlite3 *db, int n){
18682 void *p = sqlite3DbMallocRaw(db, n);
18683 if( p ){
18684 memset(p, 0, n);
18686 return p;
18690 ** Allocate and zero memory. If the allocation fails, make
18691 ** the mallocFailed flag in the connection pointer.
18693 ** If db!=0 and db->mallocFailed is true (indicating a prior malloc
18694 ** failure on the same database connection) then always return 0.
18695 ** Hence for a particular database connection, once malloc starts
18696 ** failing, it fails consistently until mallocFailed is reset.
18697 ** This is an important assumption. There are many places in the
18698 ** code that do things like this:
18700 ** int *a = (int*)sqlite3DbMallocRaw(db, 100);
18701 ** int *b = (int*)sqlite3DbMallocRaw(db, 200);
18702 ** if( b ) a[10] = 9;
18704 ** In other words, if a subsequent malloc (ex: "b") worked, it is assumed
18705 ** that all prior mallocs (ex: "a") worked too.
18707 SQLITE_PRIVATE void *sqlite3DbMallocRaw(sqlite3 *db, int n){
18708 void *p;
18709 assert( db==0 || sqlite3_mutex_held(db->mutex) );
18710 assert( db==0 || db->pnBytesFreed==0 );
18711 #ifndef SQLITE_OMIT_LOOKASIDE
18712 if( db ){
18713 LookasideSlot *pBuf;
18714 if( db->mallocFailed ){
18715 return 0;
18717 if( db->lookaside.bEnabled ){
18718 if( n>db->lookaside.sz ){
18719 db->lookaside.anStat[1]++;
18720 }else if( (pBuf = db->lookaside.pFree)==0 ){
18721 db->lookaside.anStat[2]++;
18722 }else{
18723 db->lookaside.pFree = pBuf->pNext;
18724 db->lookaside.nOut++;
18725 db->lookaside.anStat[0]++;
18726 if( db->lookaside.nOut>db->lookaside.mxOut ){
18727 db->lookaside.mxOut = db->lookaside.nOut;
18729 return (void*)pBuf;
18733 #else
18734 if( db && db->mallocFailed ){
18735 return 0;
18737 #endif
18738 p = sqlite3Malloc(n);
18739 if( !p && db ){
18740 db->mallocFailed = 1;
18742 sqlite3MemdebugSetType(p, MEMTYPE_DB |
18743 ((db && db->lookaside.bEnabled) ? MEMTYPE_LOOKASIDE : MEMTYPE_HEAP));
18744 return p;
18748 ** Resize the block of memory pointed to by p to n bytes. If the
18749 ** resize fails, set the mallocFailed flag in the connection object.
18751 SQLITE_PRIVATE void *sqlite3DbRealloc(sqlite3 *db, void *p, int n){
18752 void *pNew = 0;
18753 assert( db!=0 );
18754 assert( sqlite3_mutex_held(db->mutex) );
18755 if( db->mallocFailed==0 ){
18756 if( p==0 ){
18757 return sqlite3DbMallocRaw(db, n);
18759 if( isLookaside(db, p) ){
18760 if( n<=db->lookaside.sz ){
18761 return p;
18763 pNew = sqlite3DbMallocRaw(db, n);
18764 if( pNew ){
18765 memcpy(pNew, p, db->lookaside.sz);
18766 sqlite3DbFree(db, p);
18768 }else{
18769 assert( sqlite3MemdebugHasType(p, MEMTYPE_DB) );
18770 assert( sqlite3MemdebugHasType(p, MEMTYPE_LOOKASIDE|MEMTYPE_HEAP) );
18771 sqlite3MemdebugSetType(p, MEMTYPE_HEAP);
18772 pNew = sqlite3_realloc(p, n);
18773 if( !pNew ){
18774 sqlite3MemdebugSetType(p, MEMTYPE_DB|MEMTYPE_HEAP);
18775 db->mallocFailed = 1;
18777 sqlite3MemdebugSetType(pNew, MEMTYPE_DB |
18778 (db->lookaside.bEnabled ? MEMTYPE_LOOKASIDE : MEMTYPE_HEAP));
18781 return pNew;
18785 ** Attempt to reallocate p. If the reallocation fails, then free p
18786 ** and set the mallocFailed flag in the database connection.
18788 SQLITE_PRIVATE void *sqlite3DbReallocOrFree(sqlite3 *db, void *p, int n){
18789 void *pNew;
18790 pNew = sqlite3DbRealloc(db, p, n);
18791 if( !pNew ){
18792 sqlite3DbFree(db, p);
18794 return pNew;
18798 ** Make a copy of a string in memory obtained from sqliteMalloc(). These
18799 ** functions call sqlite3MallocRaw() directly instead of sqliteMalloc(). This
18800 ** is because when memory debugging is turned on, these two functions are
18801 ** called via macros that record the current file and line number in the
18802 ** ThreadData structure.
18804 SQLITE_PRIVATE char *sqlite3DbStrDup(sqlite3 *db, const char *z){
18805 char *zNew;
18806 size_t n;
18807 if( z==0 ){
18808 return 0;
18810 n = sqlite3Strlen30(z) + 1;
18811 assert( (n&0x7fffffff)==n );
18812 zNew = sqlite3DbMallocRaw(db, (int)n);
18813 if( zNew ){
18814 memcpy(zNew, z, n);
18816 return zNew;
18818 SQLITE_PRIVATE char *sqlite3DbStrNDup(sqlite3 *db, const char *z, int n){
18819 char *zNew;
18820 if( z==0 ){
18821 return 0;
18823 assert( (n&0x7fffffff)==n );
18824 zNew = sqlite3DbMallocRaw(db, n+1);
18825 if( zNew ){
18826 memcpy(zNew, z, n);
18827 zNew[n] = 0;
18829 return zNew;
18833 ** Create a string from the zFromat argument and the va_list that follows.
18834 ** Store the string in memory obtained from sqliteMalloc() and make *pz
18835 ** point to that string.
18837 SQLITE_PRIVATE void sqlite3SetString(char **pz, sqlite3 *db, const char *zFormat, ...){
18838 va_list ap;
18839 char *z;
18841 va_start(ap, zFormat);
18842 z = sqlite3VMPrintf(db, zFormat, ap);
18843 va_end(ap);
18844 sqlite3DbFree(db, *pz);
18845 *pz = z;
18850 ** This function must be called before exiting any API function (i.e.
18851 ** returning control to the user) that has called sqlite3_malloc or
18852 ** sqlite3_realloc.
18854 ** The returned value is normally a copy of the second argument to this
18855 ** function. However, if a malloc() failure has occurred since the previous
18856 ** invocation SQLITE_NOMEM is returned instead.
18858 ** If the first argument, db, is not NULL and a malloc() error has occurred,
18859 ** then the connection error-code (the value returned by sqlite3_errcode())
18860 ** is set to SQLITE_NOMEM.
18862 SQLITE_PRIVATE int sqlite3ApiExit(sqlite3* db, int rc){
18863 /* If the db handle is not NULL, then we must hold the connection handle
18864 ** mutex here. Otherwise the read (and possible write) of db->mallocFailed
18865 ** is unsafe, as is the call to sqlite3Error().
18867 assert( !db || sqlite3_mutex_held(db->mutex) );
18868 if( db && (db->mallocFailed || rc==SQLITE_IOERR_NOMEM) ){
18869 sqlite3Error(db, SQLITE_NOMEM, 0);
18870 db->mallocFailed = 0;
18871 rc = SQLITE_NOMEM;
18873 return rc & (db ? db->errMask : 0xff);
18876 /************** End of malloc.c **********************************************/
18877 /************** Begin file printf.c ******************************************/
18879 ** The "printf" code that follows dates from the 1980's. It is in
18880 ** the public domain. The original comments are included here for
18881 ** completeness. They are very out-of-date but might be useful as
18882 ** an historical reference. Most of the "enhancements" have been backed
18883 ** out so that the functionality is now the same as standard printf().
18885 **************************************************************************
18887 ** The following modules is an enhanced replacement for the "printf" subroutines
18888 ** found in the standard C library. The following enhancements are
18889 ** supported:
18891 ** + Additional functions. The standard set of "printf" functions
18892 ** includes printf, fprintf, sprintf, vprintf, vfprintf, and
18893 ** vsprintf. This module adds the following:
18895 ** * snprintf -- Works like sprintf, but has an extra argument
18896 ** which is the size of the buffer written to.
18898 ** * mprintf -- Similar to sprintf. Writes output to memory
18899 ** obtained from malloc.
18901 ** * xprintf -- Calls a function to dispose of output.
18903 ** * nprintf -- No output, but returns the number of characters
18904 ** that would have been output by printf.
18906 ** * A v- version (ex: vsnprintf) of every function is also
18907 ** supplied.
18909 ** + A few extensions to the formatting notation are supported:
18911 ** * The "=" flag (similar to "-") causes the output to be
18912 ** be centered in the appropriately sized field.
18914 ** * The %b field outputs an integer in binary notation.
18916 ** * The %c field now accepts a precision. The character output
18917 ** is repeated by the number of times the precision specifies.
18919 ** * The %' field works like %c, but takes as its character the
18920 ** next character of the format string, instead of the next
18921 ** argument. For example, printf("%.78'-") prints 78 minus
18922 ** signs, the same as printf("%.78c",'-').
18924 ** + When compiled using GCC on a SPARC, this version of printf is
18925 ** faster than the library printf for SUN OS 4.1.
18927 ** + All functions are fully reentrant.
18932 ** Conversion types fall into various categories as defined by the
18933 ** following enumeration.
18935 #define etRADIX 1 /* Integer types. %d, %x, %o, and so forth */
18936 #define etFLOAT 2 /* Floating point. %f */
18937 #define etEXP 3 /* Exponentional notation. %e and %E */
18938 #define etGENERIC 4 /* Floating or exponential, depending on exponent. %g */
18939 #define etSIZE 5 /* Return number of characters processed so far. %n */
18940 #define etSTRING 6 /* Strings. %s */
18941 #define etDYNSTRING 7 /* Dynamically allocated strings. %z */
18942 #define etPERCENT 8 /* Percent symbol. %% */
18943 #define etCHARX 9 /* Characters. %c */
18944 /* The rest are extensions, not normally found in printf() */
18945 #define etSQLESCAPE 10 /* Strings with '\'' doubled. %q */
18946 #define etSQLESCAPE2 11 /* Strings with '\'' doubled and enclosed in '',
18947 NULL pointers replaced by SQL NULL. %Q */
18948 #define etTOKEN 12 /* a pointer to a Token structure */
18949 #define etSRCLIST 13 /* a pointer to a SrcList */
18950 #define etPOINTER 14 /* The %p conversion */
18951 #define etSQLESCAPE3 15 /* %w -> Strings with '\"' doubled */
18952 #define etORDINAL 16 /* %r -> 1st, 2nd, 3rd, 4th, etc. English only */
18954 #define etINVALID 0 /* Any unrecognized conversion type */
18958 ** An "etByte" is an 8-bit unsigned value.
18960 typedef unsigned char etByte;
18963 ** Each builtin conversion character (ex: the 'd' in "%d") is described
18964 ** by an instance of the following structure
18966 typedef struct et_info { /* Information about each format field */
18967 char fmttype; /* The format field code letter */
18968 etByte base; /* The base for radix conversion */
18969 etByte flags; /* One or more of FLAG_ constants below */
18970 etByte type; /* Conversion paradigm */
18971 etByte charset; /* Offset into aDigits[] of the digits string */
18972 etByte prefix; /* Offset into aPrefix[] of the prefix string */
18973 } et_info;
18976 ** Allowed values for et_info.flags
18978 #define FLAG_SIGNED 1 /* True if the value to convert is signed */
18979 #define FLAG_INTERN 2 /* True if for internal use only */
18980 #define FLAG_STRING 4 /* Allow infinity precision */
18984 ** The following table is searched linearly, so it is good to put the
18985 ** most frequently used conversion types first.
18987 static const char aDigits[] = "0123456789ABCDEF0123456789abcdef";
18988 static const char aPrefix[] = "-x0\000X0";
18989 static const et_info fmtinfo[] = {
18990 { 'd', 10, 1, etRADIX, 0, 0 },
18991 { 's', 0, 4, etSTRING, 0, 0 },
18992 { 'g', 0, 1, etGENERIC, 30, 0 },
18993 { 'z', 0, 4, etDYNSTRING, 0, 0 },
18994 { 'q', 0, 4, etSQLESCAPE, 0, 0 },
18995 { 'Q', 0, 4, etSQLESCAPE2, 0, 0 },
18996 { 'w', 0, 4, etSQLESCAPE3, 0, 0 },
18997 { 'c', 0, 0, etCHARX, 0, 0 },
18998 { 'o', 8, 0, etRADIX, 0, 2 },
18999 { 'u', 10, 0, etRADIX, 0, 0 },
19000 { 'x', 16, 0, etRADIX, 16, 1 },
19001 { 'X', 16, 0, etRADIX, 0, 4 },
19002 #ifndef SQLITE_OMIT_FLOATING_POINT
19003 { 'f', 0, 1, etFLOAT, 0, 0 },
19004 { 'e', 0, 1, etEXP, 30, 0 },
19005 { 'E', 0, 1, etEXP, 14, 0 },
19006 { 'G', 0, 1, etGENERIC, 14, 0 },
19007 #endif
19008 { 'i', 10, 1, etRADIX, 0, 0 },
19009 { 'n', 0, 0, etSIZE, 0, 0 },
19010 { '%', 0, 0, etPERCENT, 0, 0 },
19011 { 'p', 16, 0, etPOINTER, 0, 1 },
19013 /* All the rest have the FLAG_INTERN bit set and are thus for internal
19014 ** use only */
19015 { 'T', 0, 2, etTOKEN, 0, 0 },
19016 { 'S', 0, 2, etSRCLIST, 0, 0 },
19017 { 'r', 10, 3, etORDINAL, 0, 0 },
19021 ** If SQLITE_OMIT_FLOATING_POINT is defined, then none of the floating point
19022 ** conversions will work.
19024 #ifndef SQLITE_OMIT_FLOATING_POINT
19026 ** "*val" is a double such that 0.1 <= *val < 10.0
19027 ** Return the ascii code for the leading digit of *val, then
19028 ** multiply "*val" by 10.0 to renormalize.
19030 ** Example:
19031 ** input: *val = 3.14159
19032 ** output: *val = 1.4159 function return = '3'
19034 ** The counter *cnt is incremented each time. After counter exceeds
19035 ** 16 (the number of significant digits in a 64-bit float) '0' is
19036 ** always returned.
19038 static char et_getdigit(LONGDOUBLE_TYPE *val, int *cnt){
19039 int digit;
19040 LONGDOUBLE_TYPE d;
19041 if( (*cnt)++ >= 16 ) return '0';
19042 digit = (int)*val;
19043 d = digit;
19044 digit += '0';
19045 *val = (*val - d)*10.0;
19046 return (char)digit;
19048 #endif /* SQLITE_OMIT_FLOATING_POINT */
19051 ** Append N space characters to the given string buffer.
19053 static void appendSpace(StrAccum *pAccum, int N){
19054 static const char zSpaces[] = " ";
19055 while( N>=(int)sizeof(zSpaces)-1 ){
19056 sqlite3StrAccumAppend(pAccum, zSpaces, sizeof(zSpaces)-1);
19057 N -= sizeof(zSpaces)-1;
19059 if( N>0 ){
19060 sqlite3StrAccumAppend(pAccum, zSpaces, N);
19065 ** On machines with a small stack size, you can redefine the
19066 ** SQLITE_PRINT_BUF_SIZE to be less than 350.
19068 #ifndef SQLITE_PRINT_BUF_SIZE
19069 # if defined(SQLITE_SMALL_STACK)
19070 # define SQLITE_PRINT_BUF_SIZE 50
19071 # else
19072 # define SQLITE_PRINT_BUF_SIZE 350
19073 # endif
19074 #endif
19075 #define etBUFSIZE SQLITE_PRINT_BUF_SIZE /* Size of the output buffer */
19078 ** The root program. All variations call this core.
19080 ** INPUTS:
19081 ** func This is a pointer to a function taking three arguments
19082 ** 1. A pointer to anything. Same as the "arg" parameter.
19083 ** 2. A pointer to the list of characters to be output
19084 ** (Note, this list is NOT null terminated.)
19085 ** 3. An integer number of characters to be output.
19086 ** (Note: This number might be zero.)
19088 ** arg This is the pointer to anything which will be passed as the
19089 ** first argument to "func". Use it for whatever you like.
19091 ** fmt This is the format string, as in the usual print.
19093 ** ap This is a pointer to a list of arguments. Same as in
19094 ** vfprint.
19096 ** OUTPUTS:
19097 ** The return value is the total number of characters sent to
19098 ** the function "func". Returns -1 on a error.
19100 ** Note that the order in which automatic variables are declared below
19101 ** seems to make a big difference in determining how fast this beast
19102 ** will run.
19104 SQLITE_PRIVATE void sqlite3VXPrintf(
19105 StrAccum *pAccum, /* Accumulate results here */
19106 int useExtended, /* Allow extended %-conversions */
19107 const char *fmt, /* Format string */
19108 va_list ap /* arguments */
19110 int c; /* Next character in the format string */
19111 char *bufpt; /* Pointer to the conversion buffer */
19112 int precision; /* Precision of the current field */
19113 int length; /* Length of the field */
19114 int idx; /* A general purpose loop counter */
19115 int width; /* Width of the current field */
19116 etByte flag_leftjustify; /* True if "-" flag is present */
19117 etByte flag_plussign; /* True if "+" flag is present */
19118 etByte flag_blanksign; /* True if " " flag is present */
19119 etByte flag_alternateform; /* True if "#" flag is present */
19120 etByte flag_altform2; /* True if "!" flag is present */
19121 etByte flag_zeropad; /* True if field width constant starts with zero */
19122 etByte flag_long; /* True if "l" flag is present */
19123 etByte flag_longlong; /* True if the "ll" flag is present */
19124 etByte done; /* Loop termination flag */
19125 sqlite_uint64 longvalue; /* Value for integer types */
19126 LONGDOUBLE_TYPE realvalue; /* Value for real types */
19127 const et_info *infop; /* Pointer to the appropriate info structure */
19128 char buf[etBUFSIZE]; /* Conversion buffer */
19129 char prefix; /* Prefix character. "+" or "-" or " " or '\0'. */
19130 etByte xtype = 0; /* Conversion paradigm */
19131 char *zExtra; /* Extra memory used for etTCLESCAPE conversions */
19132 #ifndef SQLITE_OMIT_FLOATING_POINT
19133 int exp, e2; /* exponent of real numbers */
19134 double rounder; /* Used for rounding floating point values */
19135 etByte flag_dp; /* True if decimal point should be shown */
19136 etByte flag_rtz; /* True if trailing zeros should be removed */
19137 etByte flag_exp; /* True to force display of the exponent */
19138 int nsd; /* Number of significant digits returned */
19139 #endif
19141 length = 0;
19142 bufpt = 0;
19143 for(; (c=(*fmt))!=0; ++fmt){
19144 if( c!='%' ){
19145 int amt;
19146 bufpt = (char *)fmt;
19147 amt = 1;
19148 while( (c=(*++fmt))!='%' && c!=0 ) amt++;
19149 sqlite3StrAccumAppend(pAccum, bufpt, amt);
19150 if( c==0 ) break;
19152 if( (c=(*++fmt))==0 ){
19153 sqlite3StrAccumAppend(pAccum, "%", 1);
19154 break;
19156 /* Find out what flags are present */
19157 flag_leftjustify = flag_plussign = flag_blanksign =
19158 flag_alternateform = flag_altform2 = flag_zeropad = 0;
19159 done = 0;
19161 switch( c ){
19162 case '-': flag_leftjustify = 1; break;
19163 case '+': flag_plussign = 1; break;
19164 case ' ': flag_blanksign = 1; break;
19165 case '#': flag_alternateform = 1; break;
19166 case '!': flag_altform2 = 1; break;
19167 case '0': flag_zeropad = 1; break;
19168 default: done = 1; break;
19170 }while( !done && (c=(*++fmt))!=0 );
19171 /* Get the field width */
19172 width = 0;
19173 if( c=='*' ){
19174 width = va_arg(ap,int);
19175 if( width<0 ){
19176 flag_leftjustify = 1;
19177 width = -width;
19179 c = *++fmt;
19180 }else{
19181 while( c>='0' && c<='9' ){
19182 width = width*10 + c - '0';
19183 c = *++fmt;
19186 if( width > etBUFSIZE-10 ){
19187 width = etBUFSIZE-10;
19189 /* Get the precision */
19190 if( c=='.' ){
19191 precision = 0;
19192 c = *++fmt;
19193 if( c=='*' ){
19194 precision = va_arg(ap,int);
19195 if( precision<0 ) precision = -precision;
19196 c = *++fmt;
19197 }else{
19198 while( c>='0' && c<='9' ){
19199 precision = precision*10 + c - '0';
19200 c = *++fmt;
19203 }else{
19204 precision = -1;
19206 /* Get the conversion type modifier */
19207 if( c=='l' ){
19208 flag_long = 1;
19209 c = *++fmt;
19210 if( c=='l' ){
19211 flag_longlong = 1;
19212 c = *++fmt;
19213 }else{
19214 flag_longlong = 0;
19216 }else{
19217 flag_long = flag_longlong = 0;
19219 /* Fetch the info entry for the field */
19220 infop = &fmtinfo[0];
19221 xtype = etINVALID;
19222 for(idx=0; idx<ArraySize(fmtinfo); idx++){
19223 if( c==fmtinfo[idx].fmttype ){
19224 infop = &fmtinfo[idx];
19225 if( useExtended || (infop->flags & FLAG_INTERN)==0 ){
19226 xtype = infop->type;
19227 }else{
19228 return;
19230 break;
19233 zExtra = 0;
19236 /* Limit the precision to prevent overflowing buf[] during conversion */
19237 if( precision>etBUFSIZE-40 && (infop->flags & FLAG_STRING)==0 ){
19238 precision = etBUFSIZE-40;
19242 ** At this point, variables are initialized as follows:
19244 ** flag_alternateform TRUE if a '#' is present.
19245 ** flag_altform2 TRUE if a '!' is present.
19246 ** flag_plussign TRUE if a '+' is present.
19247 ** flag_leftjustify TRUE if a '-' is present or if the
19248 ** field width was negative.
19249 ** flag_zeropad TRUE if the width began with 0.
19250 ** flag_long TRUE if the letter 'l' (ell) prefixed
19251 ** the conversion character.
19252 ** flag_longlong TRUE if the letter 'll' (ell ell) prefixed
19253 ** the conversion character.
19254 ** flag_blanksign TRUE if a ' ' is present.
19255 ** width The specified field width. This is
19256 ** always non-negative. Zero is the default.
19257 ** precision The specified precision. The default
19258 ** is -1.
19259 ** xtype The class of the conversion.
19260 ** infop Pointer to the appropriate info struct.
19262 switch( xtype ){
19263 case etPOINTER:
19264 flag_longlong = sizeof(char*)==sizeof(i64);
19265 flag_long = sizeof(char*)==sizeof(long int);
19266 /* Fall through into the next case */
19267 case etORDINAL:
19268 case etRADIX:
19269 if( infop->flags & FLAG_SIGNED ){
19270 i64 v;
19271 if( flag_longlong ){
19272 v = va_arg(ap,i64);
19273 }else if( flag_long ){
19274 v = va_arg(ap,long int);
19275 }else{
19276 v = va_arg(ap,int);
19278 if( v<0 ){
19279 if( v==SMALLEST_INT64 ){
19280 longvalue = ((u64)1)<<63;
19281 }else{
19282 longvalue = -v;
19284 prefix = '-';
19285 }else{
19286 longvalue = v;
19287 if( flag_plussign ) prefix = '+';
19288 else if( flag_blanksign ) prefix = ' ';
19289 else prefix = 0;
19291 }else{
19292 if( flag_longlong ){
19293 longvalue = va_arg(ap,u64);
19294 }else if( flag_long ){
19295 longvalue = va_arg(ap,unsigned long int);
19296 }else{
19297 longvalue = va_arg(ap,unsigned int);
19299 prefix = 0;
19301 if( longvalue==0 ) flag_alternateform = 0;
19302 if( flag_zeropad && precision<width-(prefix!=0) ){
19303 precision = width-(prefix!=0);
19305 bufpt = &buf[etBUFSIZE-1];
19306 if( xtype==etORDINAL ){
19307 static const char zOrd[] = "thstndrd";
19308 int x = (int)(longvalue % 10);
19309 if( x>=4 || (longvalue/10)%10==1 ){
19310 x = 0;
19312 buf[etBUFSIZE-3] = zOrd[x*2];
19313 buf[etBUFSIZE-2] = zOrd[x*2+1];
19314 bufpt -= 2;
19317 register const char *cset; /* Use registers for speed */
19318 register int base;
19319 cset = &aDigits[infop->charset];
19320 base = infop->base;
19321 do{ /* Convert to ascii */
19322 *(--bufpt) = cset[longvalue%base];
19323 longvalue = longvalue/base;
19324 }while( longvalue>0 );
19326 length = (int)(&buf[etBUFSIZE-1]-bufpt);
19327 for(idx=precision-length; idx>0; idx--){
19328 *(--bufpt) = '0'; /* Zero pad */
19330 if( prefix ) *(--bufpt) = prefix; /* Add sign */
19331 if( flag_alternateform && infop->prefix ){ /* Add "0" or "0x" */
19332 const char *pre;
19333 char x;
19334 pre = &aPrefix[infop->prefix];
19335 for(; (x=(*pre))!=0; pre++) *(--bufpt) = x;
19337 length = (int)(&buf[etBUFSIZE-1]-bufpt);
19338 break;
19339 case etFLOAT:
19340 case etEXP:
19341 case etGENERIC:
19342 realvalue = va_arg(ap,double);
19343 #ifdef SQLITE_OMIT_FLOATING_POINT
19344 length = 0;
19345 #else
19346 if( precision<0 ) precision = 6; /* Set default precision */
19347 if( precision>etBUFSIZE/2-10 ) precision = etBUFSIZE/2-10;
19348 if( realvalue<0.0 ){
19349 realvalue = -realvalue;
19350 prefix = '-';
19351 }else{
19352 if( flag_plussign ) prefix = '+';
19353 else if( flag_blanksign ) prefix = ' ';
19354 else prefix = 0;
19356 if( xtype==etGENERIC && precision>0 ) precision--;
19357 #if 0
19358 /* Rounding works like BSD when the constant 0.4999 is used. Wierd! */
19359 for(idx=precision, rounder=0.4999; idx>0; idx--, rounder*=0.1);
19360 #else
19361 /* It makes more sense to use 0.5 */
19362 for(idx=precision, rounder=0.5; idx>0; idx--, rounder*=0.1){}
19363 #endif
19364 if( xtype==etFLOAT ) realvalue += rounder;
19365 /* Normalize realvalue to within 10.0 > realvalue >= 1.0 */
19366 exp = 0;
19367 if( sqlite3IsNaN((double)realvalue) ){
19368 bufpt = "NaN";
19369 length = 3;
19370 break;
19372 if( realvalue>0.0 ){
19373 while( realvalue>=1e32 && exp<=350 ){ realvalue *= 1e-32; exp+=32; }
19374 while( realvalue>=1e8 && exp<=350 ){ realvalue *= 1e-8; exp+=8; }
19375 while( realvalue>=10.0 && exp<=350 ){ realvalue *= 0.1; exp++; }
19376 while( realvalue<1e-8 ){ realvalue *= 1e8; exp-=8; }
19377 while( realvalue<1.0 ){ realvalue *= 10.0; exp--; }
19378 if( exp>350 ){
19379 if( prefix=='-' ){
19380 bufpt = "-Inf";
19381 }else if( prefix=='+' ){
19382 bufpt = "+Inf";
19383 }else{
19384 bufpt = "Inf";
19386 length = sqlite3Strlen30(bufpt);
19387 break;
19390 bufpt = buf;
19392 ** If the field type is etGENERIC, then convert to either etEXP
19393 ** or etFLOAT, as appropriate.
19395 flag_exp = xtype==etEXP;
19396 if( xtype!=etFLOAT ){
19397 realvalue += rounder;
19398 if( realvalue>=10.0 ){ realvalue *= 0.1; exp++; }
19400 if( xtype==etGENERIC ){
19401 flag_rtz = !flag_alternateform;
19402 if( exp<-4 || exp>precision ){
19403 xtype = etEXP;
19404 }else{
19405 precision = precision - exp;
19406 xtype = etFLOAT;
19408 }else{
19409 flag_rtz = 0;
19411 if( xtype==etEXP ){
19412 e2 = 0;
19413 }else{
19414 e2 = exp;
19416 nsd = 0;
19417 flag_dp = (precision>0 ?1:0) | flag_alternateform | flag_altform2;
19418 /* The sign in front of the number */
19419 if( prefix ){
19420 *(bufpt++) = prefix;
19422 /* Digits prior to the decimal point */
19423 if( e2<0 ){
19424 *(bufpt++) = '0';
19425 }else{
19426 for(; e2>=0; e2--){
19427 *(bufpt++) = et_getdigit(&realvalue,&nsd);
19430 /* The decimal point */
19431 if( flag_dp ){
19432 *(bufpt++) = '.';
19434 /* "0" digits after the decimal point but before the first
19435 ** significant digit of the number */
19436 for(e2++; e2<0; precision--, e2++){
19437 assert( precision>0 );
19438 *(bufpt++) = '0';
19440 /* Significant digits after the decimal point */
19441 while( (precision--)>0 ){
19442 *(bufpt++) = et_getdigit(&realvalue,&nsd);
19444 /* Remove trailing zeros and the "." if no digits follow the "." */
19445 if( flag_rtz && flag_dp ){
19446 while( bufpt[-1]=='0' ) *(--bufpt) = 0;
19447 assert( bufpt>buf );
19448 if( bufpt[-1]=='.' ){
19449 if( flag_altform2 ){
19450 *(bufpt++) = '0';
19451 }else{
19452 *(--bufpt) = 0;
19456 /* Add the "eNNN" suffix */
19457 if( flag_exp || xtype==etEXP ){
19458 *(bufpt++) = aDigits[infop->charset];
19459 if( exp<0 ){
19460 *(bufpt++) = '-'; exp = -exp;
19461 }else{
19462 *(bufpt++) = '+';
19464 if( exp>=100 ){
19465 *(bufpt++) = (char)((exp/100)+'0'); /* 100's digit */
19466 exp %= 100;
19468 *(bufpt++) = (char)(exp/10+'0'); /* 10's digit */
19469 *(bufpt++) = (char)(exp%10+'0'); /* 1's digit */
19471 *bufpt = 0;
19473 /* The converted number is in buf[] and zero terminated. Output it.
19474 ** Note that the number is in the usual order, not reversed as with
19475 ** integer conversions. */
19476 length = (int)(bufpt-buf);
19477 bufpt = buf;
19479 /* Special case: Add leading zeros if the flag_zeropad flag is
19480 ** set and we are not left justified */
19481 if( flag_zeropad && !flag_leftjustify && length < width){
19482 int i;
19483 int nPad = width - length;
19484 for(i=width; i>=nPad; i--){
19485 bufpt[i] = bufpt[i-nPad];
19487 i = prefix!=0;
19488 while( nPad-- ) bufpt[i++] = '0';
19489 length = width;
19491 #endif /* !defined(SQLITE_OMIT_FLOATING_POINT) */
19492 break;
19493 case etSIZE:
19494 *(va_arg(ap,int*)) = pAccum->nChar;
19495 length = width = 0;
19496 break;
19497 case etPERCENT:
19498 buf[0] = '%';
19499 bufpt = buf;
19500 length = 1;
19501 break;
19502 case etCHARX:
19503 c = va_arg(ap,int);
19504 buf[0] = (char)c;
19505 if( precision>=0 ){
19506 for(idx=1; idx<precision; idx++) buf[idx] = (char)c;
19507 length = precision;
19508 }else{
19509 length =1;
19511 bufpt = buf;
19512 break;
19513 case etSTRING:
19514 case etDYNSTRING:
19515 bufpt = va_arg(ap,char*);
19516 if( bufpt==0 ){
19517 bufpt = "";
19518 }else if( xtype==etDYNSTRING ){
19519 zExtra = bufpt;
19521 if( precision>=0 ){
19522 for(length=0; length<precision && bufpt[length]; length++){}
19523 }else{
19524 length = sqlite3Strlen30(bufpt);
19526 break;
19527 case etSQLESCAPE:
19528 case etSQLESCAPE2:
19529 case etSQLESCAPE3: {
19530 int i, j, k, n, isnull;
19531 int needQuote;
19532 char ch;
19533 char q = ((xtype==etSQLESCAPE3)?'"':'\''); /* Quote character */
19534 char *escarg = va_arg(ap,char*);
19535 isnull = escarg==0;
19536 if( isnull ) escarg = (xtype==etSQLESCAPE2 ? "NULL" : "(NULL)");
19537 k = precision;
19538 for(i=n=0; k!=0 && (ch=escarg[i])!=0; i++, k--){
19539 if( ch==q ) n++;
19541 needQuote = !isnull && xtype==etSQLESCAPE2;
19542 n += i + 1 + needQuote*2;
19543 if( n>etBUFSIZE ){
19544 bufpt = zExtra = sqlite3Malloc( n );
19545 if( bufpt==0 ){
19546 pAccum->mallocFailed = 1;
19547 return;
19549 }else{
19550 bufpt = buf;
19552 j = 0;
19553 if( needQuote ) bufpt[j++] = q;
19554 k = i;
19555 for(i=0; i<k; i++){
19556 bufpt[j++] = ch = escarg[i];
19557 if( ch==q ) bufpt[j++] = ch;
19559 if( needQuote ) bufpt[j++] = q;
19560 bufpt[j] = 0;
19561 length = j;
19562 /* The precision in %q and %Q means how many input characters to
19563 ** consume, not the length of the output...
19564 ** if( precision>=0 && precision<length ) length = precision; */
19565 break;
19567 case etTOKEN: {
19568 Token *pToken = va_arg(ap, Token*);
19569 if( pToken ){
19570 sqlite3StrAccumAppend(pAccum, (const char*)pToken->z, pToken->n);
19572 length = width = 0;
19573 break;
19575 case etSRCLIST: {
19576 SrcList *pSrc = va_arg(ap, SrcList*);
19577 int k = va_arg(ap, int);
19578 struct SrcList_item *pItem = &pSrc->a[k];
19579 assert( k>=0 && k<pSrc->nSrc );
19580 if( pItem->zDatabase ){
19581 sqlite3StrAccumAppend(pAccum, pItem->zDatabase, -1);
19582 sqlite3StrAccumAppend(pAccum, ".", 1);
19584 sqlite3StrAccumAppend(pAccum, pItem->zName, -1);
19585 length = width = 0;
19586 break;
19588 default: {
19589 assert( xtype==etINVALID );
19590 return;
19592 }/* End switch over the format type */
19594 ** The text of the conversion is pointed to by "bufpt" and is
19595 ** "length" characters long. The field width is "width". Do
19596 ** the output.
19598 if( !flag_leftjustify ){
19599 register int nspace;
19600 nspace = width-length;
19601 if( nspace>0 ){
19602 appendSpace(pAccum, nspace);
19605 if( length>0 ){
19606 sqlite3StrAccumAppend(pAccum, bufpt, length);
19608 if( flag_leftjustify ){
19609 register int nspace;
19610 nspace = width-length;
19611 if( nspace>0 ){
19612 appendSpace(pAccum, nspace);
19615 if( zExtra ){
19616 sqlite3_free(zExtra);
19618 }/* End for loop over the format string */
19619 } /* End of function */
19622 ** Append N bytes of text from z to the StrAccum object.
19624 SQLITE_PRIVATE void sqlite3StrAccumAppend(StrAccum *p, const char *z, int N){
19625 assert( z!=0 || N==0 );
19626 if( p->tooBig | p->mallocFailed ){
19627 testcase(p->tooBig);
19628 testcase(p->mallocFailed);
19629 return;
19631 if( N<0 ){
19632 N = sqlite3Strlen30(z);
19634 if( N==0 || NEVER(z==0) ){
19635 return;
19637 if( p->nChar+N >= p->nAlloc ){
19638 char *zNew;
19639 if( !p->useMalloc ){
19640 p->tooBig = 1;
19641 N = p->nAlloc - p->nChar - 1;
19642 if( N<=0 ){
19643 return;
19645 }else{
19646 char *zOld = (p->zText==p->zBase ? 0 : p->zText);
19647 i64 szNew = p->nChar;
19648 szNew += N + 1;
19649 if( szNew > p->mxAlloc ){
19650 sqlite3StrAccumReset(p);
19651 p->tooBig = 1;
19652 return;
19653 }else{
19654 p->nAlloc = (int)szNew;
19656 if( p->useMalloc==1 ){
19657 zNew = sqlite3DbRealloc(p->db, zOld, p->nAlloc);
19658 }else{
19659 zNew = sqlite3_realloc(zOld, p->nAlloc);
19661 if( zNew ){
19662 if( zOld==0 ) memcpy(zNew, p->zText, p->nChar);
19663 p->zText = zNew;
19664 }else{
19665 p->mallocFailed = 1;
19666 sqlite3StrAccumReset(p);
19667 return;
19671 memcpy(&p->zText[p->nChar], z, N);
19672 p->nChar += N;
19676 ** Finish off a string by making sure it is zero-terminated.
19677 ** Return a pointer to the resulting string. Return a NULL
19678 ** pointer if any kind of error was encountered.
19680 SQLITE_PRIVATE char *sqlite3StrAccumFinish(StrAccum *p){
19681 if( p->zText ){
19682 p->zText[p->nChar] = 0;
19683 if( p->useMalloc && p->zText==p->zBase ){
19684 if( p->useMalloc==1 ){
19685 p->zText = sqlite3DbMallocRaw(p->db, p->nChar+1 );
19686 }else{
19687 p->zText = sqlite3_malloc(p->nChar+1);
19689 if( p->zText ){
19690 memcpy(p->zText, p->zBase, p->nChar+1);
19691 }else{
19692 p->mallocFailed = 1;
19696 return p->zText;
19700 ** Reset an StrAccum string. Reclaim all malloced memory.
19702 SQLITE_PRIVATE void sqlite3StrAccumReset(StrAccum *p){
19703 if( p->zText!=p->zBase ){
19704 if( p->useMalloc==1 ){
19705 sqlite3DbFree(p->db, p->zText);
19706 }else{
19707 sqlite3_free(p->zText);
19710 p->zText = 0;
19714 ** Initialize a string accumulator
19716 SQLITE_PRIVATE void sqlite3StrAccumInit(StrAccum *p, char *zBase, int n, int mx){
19717 p->zText = p->zBase = zBase;
19718 p->db = 0;
19719 p->nChar = 0;
19720 p->nAlloc = n;
19721 p->mxAlloc = mx;
19722 p->useMalloc = 1;
19723 p->tooBig = 0;
19724 p->mallocFailed = 0;
19728 ** Print into memory obtained from sqliteMalloc(). Use the internal
19729 ** %-conversion extensions.
19731 SQLITE_PRIVATE char *sqlite3VMPrintf(sqlite3 *db, const char *zFormat, va_list ap){
19732 char *z;
19733 char zBase[SQLITE_PRINT_BUF_SIZE];
19734 StrAccum acc;
19735 assert( db!=0 );
19736 sqlite3StrAccumInit(&acc, zBase, sizeof(zBase),
19737 db->aLimit[SQLITE_LIMIT_LENGTH]);
19738 acc.db = db;
19739 sqlite3VXPrintf(&acc, 1, zFormat, ap);
19740 z = sqlite3StrAccumFinish(&acc);
19741 if( acc.mallocFailed ){
19742 db->mallocFailed = 1;
19744 return z;
19748 ** Print into memory obtained from sqliteMalloc(). Use the internal
19749 ** %-conversion extensions.
19751 SQLITE_PRIVATE char *sqlite3MPrintf(sqlite3 *db, const char *zFormat, ...){
19752 va_list ap;
19753 char *z;
19754 va_start(ap, zFormat);
19755 z = sqlite3VMPrintf(db, zFormat, ap);
19756 va_end(ap);
19757 return z;
19761 ** Like sqlite3MPrintf(), but call sqlite3DbFree() on zStr after formatting
19762 ** the string and before returnning. This routine is intended to be used
19763 ** to modify an existing string. For example:
19765 ** x = sqlite3MPrintf(db, x, "prefix %s suffix", x);
19768 SQLITE_PRIVATE char *sqlite3MAppendf(sqlite3 *db, char *zStr, const char *zFormat, ...){
19769 va_list ap;
19770 char *z;
19771 va_start(ap, zFormat);
19772 z = sqlite3VMPrintf(db, zFormat, ap);
19773 va_end(ap);
19774 sqlite3DbFree(db, zStr);
19775 return z;
19779 ** Print into memory obtained from sqlite3_malloc(). Omit the internal
19780 ** %-conversion extensions.
19782 SQLITE_API char *sqlite3_vmprintf(const char *zFormat, va_list ap){
19783 char *z;
19784 char zBase[SQLITE_PRINT_BUF_SIZE];
19785 StrAccum acc;
19786 #ifndef SQLITE_OMIT_AUTOINIT
19787 if( sqlite3_initialize() ) return 0;
19788 #endif
19789 sqlite3StrAccumInit(&acc, zBase, sizeof(zBase), SQLITE_MAX_LENGTH);
19790 acc.useMalloc = 2;
19791 sqlite3VXPrintf(&acc, 0, zFormat, ap);
19792 z = sqlite3StrAccumFinish(&acc);
19793 return z;
19797 ** Print into memory obtained from sqlite3_malloc()(). Omit the internal
19798 ** %-conversion extensions.
19800 SQLITE_API char *sqlite3_mprintf(const char *zFormat, ...){
19801 va_list ap;
19802 char *z;
19803 #ifndef SQLITE_OMIT_AUTOINIT
19804 if( sqlite3_initialize() ) return 0;
19805 #endif
19806 va_start(ap, zFormat);
19807 z = sqlite3_vmprintf(zFormat, ap);
19808 va_end(ap);
19809 return z;
19813 ** sqlite3_snprintf() works like snprintf() except that it ignores the
19814 ** current locale settings. This is important for SQLite because we
19815 ** are not able to use a "," as the decimal point in place of "." as
19816 ** specified by some locales.
19818 ** Oops: The first two arguments of sqlite3_snprintf() are backwards
19819 ** from the snprintf() standard. Unfortunately, it is too late to change
19820 ** this without breaking compatibility, so we just have to live with the
19821 ** mistake.
19823 ** sqlite3_vsnprintf() is the varargs version.
19825 SQLITE_API char *sqlite3_vsnprintf(int n, char *zBuf, const char *zFormat, va_list ap){
19826 StrAccum acc;
19827 if( n<=0 ) return zBuf;
19828 sqlite3StrAccumInit(&acc, zBuf, n, 0);
19829 acc.useMalloc = 0;
19830 sqlite3VXPrintf(&acc, 0, zFormat, ap);
19831 return sqlite3StrAccumFinish(&acc);
19833 SQLITE_API char *sqlite3_snprintf(int n, char *zBuf, const char *zFormat, ...){
19834 char *z;
19835 va_list ap;
19836 va_start(ap,zFormat);
19837 z = sqlite3_vsnprintf(n, zBuf, zFormat, ap);
19838 va_end(ap);
19839 return z;
19843 ** This is the routine that actually formats the sqlite3_log() message.
19844 ** We house it in a separate routine from sqlite3_log() to avoid using
19845 ** stack space on small-stack systems when logging is disabled.
19847 ** sqlite3_log() must render into a static buffer. It cannot dynamically
19848 ** allocate memory because it might be called while the memory allocator
19849 ** mutex is held.
19851 static void renderLogMsg(int iErrCode, const char *zFormat, va_list ap){
19852 StrAccum acc; /* String accumulator */
19853 char zMsg[SQLITE_PRINT_BUF_SIZE*3]; /* Complete log message */
19855 sqlite3StrAccumInit(&acc, zMsg, sizeof(zMsg), 0);
19856 acc.useMalloc = 0;
19857 sqlite3VXPrintf(&acc, 0, zFormat, ap);
19858 sqlite3GlobalConfig.xLog(sqlite3GlobalConfig.pLogArg, iErrCode,
19859 sqlite3StrAccumFinish(&acc));
19863 ** Format and write a message to the log if logging is enabled.
19865 SQLITE_API void sqlite3_log(int iErrCode, const char *zFormat, ...){
19866 va_list ap; /* Vararg list */
19867 if( sqlite3GlobalConfig.xLog ){
19868 va_start(ap, zFormat);
19869 renderLogMsg(iErrCode, zFormat, ap);
19870 va_end(ap);
19874 #if defined(SQLITE_DEBUG)
19876 ** A version of printf() that understands %lld. Used for debugging.
19877 ** The printf() built into some versions of windows does not understand %lld
19878 ** and segfaults if you give it a long long int.
19880 SQLITE_PRIVATE void sqlite3DebugPrintf(const char *zFormat, ...){
19881 va_list ap;
19882 StrAccum acc;
19883 char zBuf[500];
19884 sqlite3StrAccumInit(&acc, zBuf, sizeof(zBuf), 0);
19885 acc.useMalloc = 0;
19886 va_start(ap,zFormat);
19887 sqlite3VXPrintf(&acc, 0, zFormat, ap);
19888 va_end(ap);
19889 sqlite3StrAccumFinish(&acc);
19890 fprintf(stdout,"%s", zBuf);
19891 fflush(stdout);
19893 #endif
19895 #ifndef SQLITE_OMIT_TRACE
19897 ** variable-argument wrapper around sqlite3VXPrintf().
19899 SQLITE_PRIVATE void sqlite3XPrintf(StrAccum *p, const char *zFormat, ...){
19900 va_list ap;
19901 va_start(ap,zFormat);
19902 sqlite3VXPrintf(p, 1, zFormat, ap);
19903 va_end(ap);
19905 #endif
19907 /************** End of printf.c **********************************************/
19908 /************** Begin file random.c ******************************************/
19910 ** 2001 September 15
19912 ** The author disclaims copyright to this source code. In place of
19913 ** a legal notice, here is a blessing:
19915 ** May you do good and not evil.
19916 ** May you find forgiveness for yourself and forgive others.
19917 ** May you share freely, never taking more than you give.
19919 *************************************************************************
19920 ** This file contains code to implement a pseudo-random number
19921 ** generator (PRNG) for SQLite.
19923 ** Random numbers are used by some of the database backends in order
19924 ** to generate random integer keys for tables or random filenames.
19928 /* All threads share a single random number generator.
19929 ** This structure is the current state of the generator.
19931 static SQLITE_WSD struct sqlite3PrngType {
19932 unsigned char isInit; /* True if initialized */
19933 unsigned char i, j; /* State variables */
19934 unsigned char s[256]; /* State variables */
19935 } sqlite3Prng;
19938 ** Get a single 8-bit random value from the RC4 PRNG. The Mutex
19939 ** must be held while executing this routine.
19941 ** Why not just use a library random generator like lrand48() for this?
19942 ** Because the OP_NewRowid opcode in the VDBE depends on having a very
19943 ** good source of random numbers. The lrand48() library function may
19944 ** well be good enough. But maybe not. Or maybe lrand48() has some
19945 ** subtle problems on some systems that could cause problems. It is hard
19946 ** to know. To minimize the risk of problems due to bad lrand48()
19947 ** implementations, SQLite uses this random number generator based
19948 ** on RC4, which we know works very well.
19950 ** (Later): Actually, OP_NewRowid does not depend on a good source of
19951 ** randomness any more. But we will leave this code in all the same.
19953 static u8 randomByte(void){
19954 unsigned char t;
19957 /* The "wsdPrng" macro will resolve to the pseudo-random number generator
19958 ** state vector. If writable static data is unsupported on the target,
19959 ** we have to locate the state vector at run-time. In the more common
19960 ** case where writable static data is supported, wsdPrng can refer directly
19961 ** to the "sqlite3Prng" state vector declared above.
19963 #ifdef SQLITE_OMIT_WSD
19964 struct sqlite3PrngType *p = &GLOBAL(struct sqlite3PrngType, sqlite3Prng);
19965 # define wsdPrng p[0]
19966 #else
19967 # define wsdPrng sqlite3Prng
19968 #endif
19971 /* Initialize the state of the random number generator once,
19972 ** the first time this routine is called. The seed value does
19973 ** not need to contain a lot of randomness since we are not
19974 ** trying to do secure encryption or anything like that...
19976 ** Nothing in this file or anywhere else in SQLite does any kind of
19977 ** encryption. The RC4 algorithm is being used as a PRNG (pseudo-random
19978 ** number generator) not as an encryption device.
19980 if( !wsdPrng.isInit ){
19981 int i;
19982 char k[256];
19983 wsdPrng.j = 0;
19984 wsdPrng.i = 0;
19985 sqlite3OsRandomness(sqlite3_vfs_find(0), 256, k);
19986 for(i=0; i<256; i++){
19987 wsdPrng.s[i] = (u8)i;
19989 for(i=0; i<256; i++){
19990 wsdPrng.j += wsdPrng.s[i] + k[i];
19991 t = wsdPrng.s[wsdPrng.j];
19992 wsdPrng.s[wsdPrng.j] = wsdPrng.s[i];
19993 wsdPrng.s[i] = t;
19995 wsdPrng.isInit = 1;
19998 /* Generate and return single random byte
20000 wsdPrng.i++;
20001 t = wsdPrng.s[wsdPrng.i];
20002 wsdPrng.j += t;
20003 wsdPrng.s[wsdPrng.i] = wsdPrng.s[wsdPrng.j];
20004 wsdPrng.s[wsdPrng.j] = t;
20005 t += wsdPrng.s[wsdPrng.i];
20006 return wsdPrng.s[t];
20010 ** Return N random bytes.
20012 SQLITE_API void sqlite3_randomness(int N, void *pBuf){
20013 unsigned char *zBuf = pBuf;
20014 #if SQLITE_THREADSAFE
20015 sqlite3_mutex *mutex = sqlite3MutexAlloc(SQLITE_MUTEX_STATIC_PRNG);
20016 #endif
20017 sqlite3_mutex_enter(mutex);
20018 while( N-- ){
20019 *(zBuf++) = randomByte();
20021 sqlite3_mutex_leave(mutex);
20024 #ifndef SQLITE_OMIT_BUILTIN_TEST
20026 ** For testing purposes, we sometimes want to preserve the state of
20027 ** PRNG and restore the PRNG to its saved state at a later time, or
20028 ** to reset the PRNG to its initial state. These routines accomplish
20029 ** those tasks.
20031 ** The sqlite3_test_control() interface calls these routines to
20032 ** control the PRNG.
20034 static SQLITE_WSD struct sqlite3PrngType sqlite3SavedPrng;
20035 SQLITE_PRIVATE void sqlite3PrngSaveState(void){
20036 memcpy(
20037 &GLOBAL(struct sqlite3PrngType, sqlite3SavedPrng),
20038 &GLOBAL(struct sqlite3PrngType, sqlite3Prng),
20039 sizeof(sqlite3Prng)
20042 SQLITE_PRIVATE void sqlite3PrngRestoreState(void){
20043 memcpy(
20044 &GLOBAL(struct sqlite3PrngType, sqlite3Prng),
20045 &GLOBAL(struct sqlite3PrngType, sqlite3SavedPrng),
20046 sizeof(sqlite3Prng)
20049 SQLITE_PRIVATE void sqlite3PrngResetState(void){
20050 GLOBAL(struct sqlite3PrngType, sqlite3Prng).isInit = 0;
20052 #endif /* SQLITE_OMIT_BUILTIN_TEST */
20054 /************** End of random.c **********************************************/
20055 /************** Begin file utf.c *********************************************/
20057 ** 2004 April 13
20059 ** The author disclaims copyright to this source code. In place of
20060 ** a legal notice, here is a blessing:
20062 ** May you do good and not evil.
20063 ** May you find forgiveness for yourself and forgive others.
20064 ** May you share freely, never taking more than you give.
20066 *************************************************************************
20067 ** This file contains routines used to translate between UTF-8,
20068 ** UTF-16, UTF-16BE, and UTF-16LE.
20070 ** Notes on UTF-8:
20072 ** Byte-0 Byte-1 Byte-2 Byte-3 Value
20073 ** 0xxxxxxx 00000000 00000000 0xxxxxxx
20074 ** 110yyyyy 10xxxxxx 00000000 00000yyy yyxxxxxx
20075 ** 1110zzzz 10yyyyyy 10xxxxxx 00000000 zzzzyyyy yyxxxxxx
20076 ** 11110uuu 10uuzzzz 10yyyyyy 10xxxxxx 000uuuuu zzzzyyyy yyxxxxxx
20079 ** Notes on UTF-16: (with wwww+1==uuuuu)
20081 ** Word-0 Word-1 Value
20082 ** 110110ww wwzzzzyy 110111yy yyxxxxxx 000uuuuu zzzzyyyy yyxxxxxx
20083 ** zzzzyyyy yyxxxxxx 00000000 zzzzyyyy yyxxxxxx
20086 ** BOM or Byte Order Mark:
20087 ** 0xff 0xfe little-endian utf-16 follows
20088 ** 0xfe 0xff big-endian utf-16 follows
20091 /* #include <assert.h> */
20093 #ifndef SQLITE_AMALGAMATION
20095 ** The following constant value is used by the SQLITE_BIGENDIAN and
20096 ** SQLITE_LITTLEENDIAN macros.
20098 SQLITE_PRIVATE const int sqlite3one = 1;
20099 #endif /* SQLITE_AMALGAMATION */
20102 ** This lookup table is used to help decode the first byte of
20103 ** a multi-byte UTF8 character.
20105 static const unsigned char sqlite3Utf8Trans1[] = {
20106 0x00, 0x01, 0x02, 0x03, 0x04, 0x05, 0x06, 0x07,
20107 0x08, 0x09, 0x0a, 0x0b, 0x0c, 0x0d, 0x0e, 0x0f,
20108 0x10, 0x11, 0x12, 0x13, 0x14, 0x15, 0x16, 0x17,
20109 0x18, 0x19, 0x1a, 0x1b, 0x1c, 0x1d, 0x1e, 0x1f,
20110 0x00, 0x01, 0x02, 0x03, 0x04, 0x05, 0x06, 0x07,
20111 0x08, 0x09, 0x0a, 0x0b, 0x0c, 0x0d, 0x0e, 0x0f,
20112 0x00, 0x01, 0x02, 0x03, 0x04, 0x05, 0x06, 0x07,
20113 0x00, 0x01, 0x02, 0x03, 0x00, 0x01, 0x00, 0x00,
20117 #define WRITE_UTF8(zOut, c) { \
20118 if( c<0x00080 ){ \
20119 *zOut++ = (u8)(c&0xFF); \
20121 else if( c<0x00800 ){ \
20122 *zOut++ = 0xC0 + (u8)((c>>6)&0x1F); \
20123 *zOut++ = 0x80 + (u8)(c & 0x3F); \
20125 else if( c<0x10000 ){ \
20126 *zOut++ = 0xE0 + (u8)((c>>12)&0x0F); \
20127 *zOut++ = 0x80 + (u8)((c>>6) & 0x3F); \
20128 *zOut++ = 0x80 + (u8)(c & 0x3F); \
20129 }else{ \
20130 *zOut++ = 0xF0 + (u8)((c>>18) & 0x07); \
20131 *zOut++ = 0x80 + (u8)((c>>12) & 0x3F); \
20132 *zOut++ = 0x80 + (u8)((c>>6) & 0x3F); \
20133 *zOut++ = 0x80 + (u8)(c & 0x3F); \
20137 #define WRITE_UTF16LE(zOut, c) { \
20138 if( c<=0xFFFF ){ \
20139 *zOut++ = (u8)(c&0x00FF); \
20140 *zOut++ = (u8)((c>>8)&0x00FF); \
20141 }else{ \
20142 *zOut++ = (u8)(((c>>10)&0x003F) + (((c-0x10000)>>10)&0x00C0)); \
20143 *zOut++ = (u8)(0x00D8 + (((c-0x10000)>>18)&0x03)); \
20144 *zOut++ = (u8)(c&0x00FF); \
20145 *zOut++ = (u8)(0x00DC + ((c>>8)&0x03)); \
20149 #define WRITE_UTF16BE(zOut, c) { \
20150 if( c<=0xFFFF ){ \
20151 *zOut++ = (u8)((c>>8)&0x00FF); \
20152 *zOut++ = (u8)(c&0x00FF); \
20153 }else{ \
20154 *zOut++ = (u8)(0x00D8 + (((c-0x10000)>>18)&0x03)); \
20155 *zOut++ = (u8)(((c>>10)&0x003F) + (((c-0x10000)>>10)&0x00C0)); \
20156 *zOut++ = (u8)(0x00DC + ((c>>8)&0x03)); \
20157 *zOut++ = (u8)(c&0x00FF); \
20161 #define READ_UTF16LE(zIn, TERM, c){ \
20162 c = (*zIn++); \
20163 c += ((*zIn++)<<8); \
20164 if( c>=0xD800 && c<0xE000 && TERM ){ \
20165 int c2 = (*zIn++); \
20166 c2 += ((*zIn++)<<8); \
20167 c = (c2&0x03FF) + ((c&0x003F)<<10) + (((c&0x03C0)+0x0040)<<10); \
20171 #define READ_UTF16BE(zIn, TERM, c){ \
20172 c = ((*zIn++)<<8); \
20173 c += (*zIn++); \
20174 if( c>=0xD800 && c<0xE000 && TERM ){ \
20175 int c2 = ((*zIn++)<<8); \
20176 c2 += (*zIn++); \
20177 c = (c2&0x03FF) + ((c&0x003F)<<10) + (((c&0x03C0)+0x0040)<<10); \
20182 ** Translate a single UTF-8 character. Return the unicode value.
20184 ** During translation, assume that the byte that zTerm points
20185 ** is a 0x00.
20187 ** Write a pointer to the next unread byte back into *pzNext.
20189 ** Notes On Invalid UTF-8:
20191 ** * This routine never allows a 7-bit character (0x00 through 0x7f) to
20192 ** be encoded as a multi-byte character. Any multi-byte character that
20193 ** attempts to encode a value between 0x00 and 0x7f is rendered as 0xfffd.
20195 ** * This routine never allows a UTF16 surrogate value to be encoded.
20196 ** If a multi-byte character attempts to encode a value between
20197 ** 0xd800 and 0xe000 then it is rendered as 0xfffd.
20199 ** * Bytes in the range of 0x80 through 0xbf which occur as the first
20200 ** byte of a character are interpreted as single-byte characters
20201 ** and rendered as themselves even though they are technically
20202 ** invalid characters.
20204 ** * This routine accepts an infinite number of different UTF8 encodings
20205 ** for unicode values 0x80 and greater. It do not change over-length
20206 ** encodings to 0xfffd as some systems recommend.
20208 #define READ_UTF8(zIn, zTerm, c) \
20209 c = *(zIn++); \
20210 if( c>=0xc0 ){ \
20211 c = sqlite3Utf8Trans1[c-0xc0]; \
20212 while( zIn!=zTerm && (*zIn & 0xc0)==0x80 ){ \
20213 c = (c<<6) + (0x3f & *(zIn++)); \
20215 if( c<0x80 \
20216 || (c&0xFFFFF800)==0xD800 \
20217 || (c&0xFFFFFFFE)==0xFFFE ){ c = 0xFFFD; } \
20219 SQLITE_PRIVATE u32 sqlite3Utf8Read(
20220 const unsigned char *zIn, /* First byte of UTF-8 character */
20221 const unsigned char **pzNext /* Write first byte past UTF-8 char here */
20223 unsigned int c;
20225 /* Same as READ_UTF8() above but without the zTerm parameter.
20226 ** For this routine, we assume the UTF8 string is always zero-terminated.
20228 c = *(zIn++);
20229 if( c>=0xc0 ){
20230 c = sqlite3Utf8Trans1[c-0xc0];
20231 while( (*zIn & 0xc0)==0x80 ){
20232 c = (c<<6) + (0x3f & *(zIn++));
20234 if( c<0x80
20235 || (c&0xFFFFF800)==0xD800
20236 || (c&0xFFFFFFFE)==0xFFFE ){ c = 0xFFFD; }
20238 *pzNext = zIn;
20239 return c;
20246 ** If the TRANSLATE_TRACE macro is defined, the value of each Mem is
20247 ** printed on stderr on the way into and out of sqlite3VdbeMemTranslate().
20249 /* #define TRANSLATE_TRACE 1 */
20251 #ifndef SQLITE_OMIT_UTF16
20253 ** This routine transforms the internal text encoding used by pMem to
20254 ** desiredEnc. It is an error if the string is already of the desired
20255 ** encoding, or if *pMem does not contain a string value.
20257 SQLITE_PRIVATE int sqlite3VdbeMemTranslate(Mem *pMem, u8 desiredEnc){
20258 int len; /* Maximum length of output string in bytes */
20259 unsigned char *zOut; /* Output buffer */
20260 unsigned char *zIn; /* Input iterator */
20261 unsigned char *zTerm; /* End of input */
20262 unsigned char *z; /* Output iterator */
20263 unsigned int c;
20265 assert( pMem->db==0 || sqlite3_mutex_held(pMem->db->mutex) );
20266 assert( pMem->flags&MEM_Str );
20267 assert( pMem->enc!=desiredEnc );
20268 assert( pMem->enc!=0 );
20269 assert( pMem->n>=0 );
20271 #if defined(TRANSLATE_TRACE) && defined(SQLITE_DEBUG)
20273 char zBuf[100];
20274 sqlite3VdbeMemPrettyPrint(pMem, zBuf);
20275 fprintf(stderr, "INPUT: %s\n", zBuf);
20277 #endif
20279 /* If the translation is between UTF-16 little and big endian, then
20280 ** all that is required is to swap the byte order. This case is handled
20281 ** differently from the others.
20283 if( pMem->enc!=SQLITE_UTF8 && desiredEnc!=SQLITE_UTF8 ){
20284 u8 temp;
20285 int rc;
20286 rc = sqlite3VdbeMemMakeWriteable(pMem);
20287 if( rc!=SQLITE_OK ){
20288 assert( rc==SQLITE_NOMEM );
20289 return SQLITE_NOMEM;
20291 zIn = (u8*)pMem->z;
20292 zTerm = &zIn[pMem->n&~1];
20293 while( zIn<zTerm ){
20294 temp = *zIn;
20295 *zIn = *(zIn+1);
20296 zIn++;
20297 *zIn++ = temp;
20299 pMem->enc = desiredEnc;
20300 goto translate_out;
20303 /* Set len to the maximum number of bytes required in the output buffer. */
20304 if( desiredEnc==SQLITE_UTF8 ){
20305 /* When converting from UTF-16, the maximum growth results from
20306 ** translating a 2-byte character to a 4-byte UTF-8 character.
20307 ** A single byte is required for the output string
20308 ** nul-terminator.
20310 pMem->n &= ~1;
20311 len = pMem->n * 2 + 1;
20312 }else{
20313 /* When converting from UTF-8 to UTF-16 the maximum growth is caused
20314 ** when a 1-byte UTF-8 character is translated into a 2-byte UTF-16
20315 ** character. Two bytes are required in the output buffer for the
20316 ** nul-terminator.
20318 len = pMem->n * 2 + 2;
20321 /* Set zIn to point at the start of the input buffer and zTerm to point 1
20322 ** byte past the end.
20324 ** Variable zOut is set to point at the output buffer, space obtained
20325 ** from sqlite3_malloc().
20327 zIn = (u8*)pMem->z;
20328 zTerm = &zIn[pMem->n];
20329 zOut = sqlite3DbMallocRaw(pMem->db, len);
20330 if( !zOut ){
20331 return SQLITE_NOMEM;
20333 z = zOut;
20335 if( pMem->enc==SQLITE_UTF8 ){
20336 if( desiredEnc==SQLITE_UTF16LE ){
20337 /* UTF-8 -> UTF-16 Little-endian */
20338 while( zIn<zTerm ){
20339 /* c = sqlite3Utf8Read(zIn, zTerm, (const u8**)&zIn); */
20340 READ_UTF8(zIn, zTerm, c);
20341 WRITE_UTF16LE(z, c);
20343 }else{
20344 assert( desiredEnc==SQLITE_UTF16BE );
20345 /* UTF-8 -> UTF-16 Big-endian */
20346 while( zIn<zTerm ){
20347 /* c = sqlite3Utf8Read(zIn, zTerm, (const u8**)&zIn); */
20348 READ_UTF8(zIn, zTerm, c);
20349 WRITE_UTF16BE(z, c);
20352 pMem->n = (int)(z - zOut);
20353 *z++ = 0;
20354 }else{
20355 assert( desiredEnc==SQLITE_UTF8 );
20356 if( pMem->enc==SQLITE_UTF16LE ){
20357 /* UTF-16 Little-endian -> UTF-8 */
20358 while( zIn<zTerm ){
20359 READ_UTF16LE(zIn, zIn<zTerm, c);
20360 WRITE_UTF8(z, c);
20362 }else{
20363 /* UTF-16 Big-endian -> UTF-8 */
20364 while( zIn<zTerm ){
20365 READ_UTF16BE(zIn, zIn<zTerm, c);
20366 WRITE_UTF8(z, c);
20369 pMem->n = (int)(z - zOut);
20371 *z = 0;
20372 assert( (pMem->n+(desiredEnc==SQLITE_UTF8?1:2))<=len );
20374 sqlite3VdbeMemRelease(pMem);
20375 pMem->flags &= ~(MEM_Static|MEM_Dyn|MEM_Ephem);
20376 pMem->enc = desiredEnc;
20377 pMem->flags |= (MEM_Term|MEM_Dyn);
20378 pMem->z = (char*)zOut;
20379 pMem->zMalloc = pMem->z;
20381 translate_out:
20382 #if defined(TRANSLATE_TRACE) && defined(SQLITE_DEBUG)
20384 char zBuf[100];
20385 sqlite3VdbeMemPrettyPrint(pMem, zBuf);
20386 fprintf(stderr, "OUTPUT: %s\n", zBuf);
20388 #endif
20389 return SQLITE_OK;
20393 ** This routine checks for a byte-order mark at the beginning of the
20394 ** UTF-16 string stored in *pMem. If one is present, it is removed and
20395 ** the encoding of the Mem adjusted. This routine does not do any
20396 ** byte-swapping, it just sets Mem.enc appropriately.
20398 ** The allocation (static, dynamic etc.) and encoding of the Mem may be
20399 ** changed by this function.
20401 SQLITE_PRIVATE int sqlite3VdbeMemHandleBom(Mem *pMem){
20402 int rc = SQLITE_OK;
20403 u8 bom = 0;
20405 assert( pMem->n>=0 );
20406 if( pMem->n>1 ){
20407 u8 b1 = *(u8 *)pMem->z;
20408 u8 b2 = *(((u8 *)pMem->z) + 1);
20409 if( b1==0xFE && b2==0xFF ){
20410 bom = SQLITE_UTF16BE;
20412 if( b1==0xFF && b2==0xFE ){
20413 bom = SQLITE_UTF16LE;
20417 if( bom ){
20418 rc = sqlite3VdbeMemMakeWriteable(pMem);
20419 if( rc==SQLITE_OK ){
20420 pMem->n -= 2;
20421 memmove(pMem->z, &pMem->z[2], pMem->n);
20422 pMem->z[pMem->n] = '\0';
20423 pMem->z[pMem->n+1] = '\0';
20424 pMem->flags |= MEM_Term;
20425 pMem->enc = bom;
20428 return rc;
20430 #endif /* SQLITE_OMIT_UTF16 */
20433 ** pZ is a UTF-8 encoded unicode string. If nByte is less than zero,
20434 ** return the number of unicode characters in pZ up to (but not including)
20435 ** the first 0x00 byte. If nByte is not less than zero, return the
20436 ** number of unicode characters in the first nByte of pZ (or up to
20437 ** the first 0x00, whichever comes first).
20439 SQLITE_PRIVATE int sqlite3Utf8CharLen(const char *zIn, int nByte){
20440 int r = 0;
20441 const u8 *z = (const u8*)zIn;
20442 const u8 *zTerm;
20443 if( nByte>=0 ){
20444 zTerm = &z[nByte];
20445 }else{
20446 zTerm = (const u8*)(-1);
20448 assert( z<=zTerm );
20449 while( *z!=0 && z<zTerm ){
20450 SQLITE_SKIP_UTF8(z);
20451 r++;
20453 return r;
20456 /* This test function is not currently used by the automated test-suite.
20457 ** Hence it is only available in debug builds.
20459 #if defined(SQLITE_TEST) && defined(SQLITE_DEBUG)
20461 ** Translate UTF-8 to UTF-8.
20463 ** This has the effect of making sure that the string is well-formed
20464 ** UTF-8. Miscoded characters are removed.
20466 ** The translation is done in-place and aborted if the output
20467 ** overruns the input.
20469 SQLITE_PRIVATE int sqlite3Utf8To8(unsigned char *zIn){
20470 unsigned char *zOut = zIn;
20471 unsigned char *zStart = zIn;
20472 u32 c;
20474 while( zIn[0] && zOut<=zIn ){
20475 c = sqlite3Utf8Read(zIn, (const u8**)&zIn);
20476 if( c!=0xfffd ){
20477 WRITE_UTF8(zOut, c);
20480 *zOut = 0;
20481 return (int)(zOut - zStart);
20483 #endif
20485 #ifndef SQLITE_OMIT_UTF16
20487 ** Convert a UTF-16 string in the native encoding into a UTF-8 string.
20488 ** Memory to hold the UTF-8 string is obtained from sqlite3_malloc and must
20489 ** be freed by the calling function.
20491 ** NULL is returned if there is an allocation error.
20493 SQLITE_PRIVATE char *sqlite3Utf16to8(sqlite3 *db, const void *z, int nByte, u8 enc){
20494 Mem m;
20495 memset(&m, 0, sizeof(m));
20496 m.db = db;
20497 sqlite3VdbeMemSetStr(&m, z, nByte, enc, SQLITE_STATIC);
20498 sqlite3VdbeChangeEncoding(&m, SQLITE_UTF8);
20499 if( db->mallocFailed ){
20500 sqlite3VdbeMemRelease(&m);
20501 m.z = 0;
20503 assert( (m.flags & MEM_Term)!=0 || db->mallocFailed );
20504 assert( (m.flags & MEM_Str)!=0 || db->mallocFailed );
20505 assert( (m.flags & MEM_Dyn)!=0 || db->mallocFailed );
20506 assert( m.z || db->mallocFailed );
20507 return m.z;
20511 ** Convert a UTF-8 string to the UTF-16 encoding specified by parameter
20512 ** enc. A pointer to the new string is returned, and the value of *pnOut
20513 ** is set to the length of the returned string in bytes. The call should
20514 ** arrange to call sqlite3DbFree() on the returned pointer when it is
20515 ** no longer required.
20517 ** If a malloc failure occurs, NULL is returned and the db.mallocFailed
20518 ** flag set.
20520 #ifdef SQLITE_ENABLE_STAT2
20521 SQLITE_PRIVATE char *sqlite3Utf8to16(sqlite3 *db, u8 enc, char *z, int n, int *pnOut){
20522 Mem m;
20523 memset(&m, 0, sizeof(m));
20524 m.db = db;
20525 sqlite3VdbeMemSetStr(&m, z, n, SQLITE_UTF8, SQLITE_STATIC);
20526 if( sqlite3VdbeMemTranslate(&m, enc) ){
20527 assert( db->mallocFailed );
20528 return 0;
20530 assert( m.z==m.zMalloc );
20531 *pnOut = m.n;
20532 return m.z;
20534 #endif
20537 ** zIn is a UTF-16 encoded unicode string at least nChar characters long.
20538 ** Return the number of bytes in the first nChar unicode characters
20539 ** in pZ. nChar must be non-negative.
20541 SQLITE_PRIVATE int sqlite3Utf16ByteLen(const void *zIn, int nChar){
20542 int c;
20543 unsigned char const *z = zIn;
20544 int n = 0;
20546 if( SQLITE_UTF16NATIVE==SQLITE_UTF16BE ){
20547 while( n<nChar ){
20548 READ_UTF16BE(z, 1, c);
20549 n++;
20551 }else{
20552 while( n<nChar ){
20553 READ_UTF16LE(z, 1, c);
20554 n++;
20557 return (int)(z-(unsigned char const *)zIn);
20560 #if defined(SQLITE_TEST)
20562 ** This routine is called from the TCL test function "translate_selftest".
20563 ** It checks that the primitives for serializing and deserializing
20564 ** characters in each encoding are inverses of each other.
20566 SQLITE_PRIVATE void sqlite3UtfSelfTest(void){
20567 unsigned int i, t;
20568 unsigned char zBuf[20];
20569 unsigned char *z;
20570 int n;
20571 unsigned int c;
20573 for(i=0; i<0x00110000; i++){
20574 z = zBuf;
20575 WRITE_UTF8(z, i);
20576 n = (int)(z-zBuf);
20577 assert( n>0 && n<=4 );
20578 z[0] = 0;
20579 z = zBuf;
20580 c = sqlite3Utf8Read(z, (const u8**)&z);
20581 t = i;
20582 if( i>=0xD800 && i<=0xDFFF ) t = 0xFFFD;
20583 if( (i&0xFFFFFFFE)==0xFFFE ) t = 0xFFFD;
20584 assert( c==t );
20585 assert( (z-zBuf)==n );
20587 for(i=0; i<0x00110000; i++){
20588 if( i>=0xD800 && i<0xE000 ) continue;
20589 z = zBuf;
20590 WRITE_UTF16LE(z, i);
20591 n = (int)(z-zBuf);
20592 assert( n>0 && n<=4 );
20593 z[0] = 0;
20594 z = zBuf;
20595 READ_UTF16LE(z, 1, c);
20596 assert( c==i );
20597 assert( (z-zBuf)==n );
20599 for(i=0; i<0x00110000; i++){
20600 if( i>=0xD800 && i<0xE000 ) continue;
20601 z = zBuf;
20602 WRITE_UTF16BE(z, i);
20603 n = (int)(z-zBuf);
20604 assert( n>0 && n<=4 );
20605 z[0] = 0;
20606 z = zBuf;
20607 READ_UTF16BE(z, 1, c);
20608 assert( c==i );
20609 assert( (z-zBuf)==n );
20612 #endif /* SQLITE_TEST */
20613 #endif /* SQLITE_OMIT_UTF16 */
20615 /************** End of utf.c *************************************************/
20616 /************** Begin file util.c ********************************************/
20618 ** 2001 September 15
20620 ** The author disclaims copyright to this source code. In place of
20621 ** a legal notice, here is a blessing:
20623 ** May you do good and not evil.
20624 ** May you find forgiveness for yourself and forgive others.
20625 ** May you share freely, never taking more than you give.
20627 *************************************************************************
20628 ** Utility functions used throughout sqlite.
20630 ** This file contains functions for allocating memory, comparing
20631 ** strings, and stuff like that.
20634 /* #include <stdarg.h> */
20635 #ifdef SQLITE_HAVE_ISNAN
20636 # include <math.h>
20637 #endif
20640 ** Routine needed to support the testcase() macro.
20642 #ifdef SQLITE_COVERAGE_TEST
20643 SQLITE_PRIVATE void sqlite3Coverage(int x){
20644 static unsigned dummy = 0;
20645 dummy += (unsigned)x;
20647 #endif
20649 #ifndef SQLITE_OMIT_FLOATING_POINT
20651 ** Return true if the floating point value is Not a Number (NaN).
20653 ** Use the math library isnan() function if compiled with SQLITE_HAVE_ISNAN.
20654 ** Otherwise, we have our own implementation that works on most systems.
20656 SQLITE_PRIVATE int sqlite3IsNaN(double x){
20657 int rc; /* The value return */
20658 #if !defined(SQLITE_HAVE_ISNAN)
20660 ** Systems that support the isnan() library function should probably
20661 ** make use of it by compiling with -DSQLITE_HAVE_ISNAN. But we have
20662 ** found that many systems do not have a working isnan() function so
20663 ** this implementation is provided as an alternative.
20665 ** This NaN test sometimes fails if compiled on GCC with -ffast-math.
20666 ** On the other hand, the use of -ffast-math comes with the following
20667 ** warning:
20669 ** This option [-ffast-math] should never be turned on by any
20670 ** -O option since it can result in incorrect output for programs
20671 ** which depend on an exact implementation of IEEE or ISO
20672 ** rules/specifications for math functions.
20674 ** Under MSVC, this NaN test may fail if compiled with a floating-
20675 ** point precision mode other than /fp:precise. From the MSDN
20676 ** documentation:
20678 ** The compiler [with /fp:precise] will properly handle comparisons
20679 ** involving NaN. For example, x != x evaluates to true if x is NaN
20680 ** ...
20682 #ifdef __FAST_MATH__
20683 # error SQLite will not work correctly with the -ffast-math option of GCC.
20684 #endif
20685 volatile double y = x;
20686 volatile double z = y;
20687 rc = (y!=z);
20688 #else /* if defined(SQLITE_HAVE_ISNAN) */
20689 rc = isnan(x);
20690 #endif /* SQLITE_HAVE_ISNAN */
20691 testcase( rc );
20692 return rc;
20694 #endif /* SQLITE_OMIT_FLOATING_POINT */
20697 ** Compute a string length that is limited to what can be stored in
20698 ** lower 30 bits of a 32-bit signed integer.
20700 ** The value returned will never be negative. Nor will it ever be greater
20701 ** than the actual length of the string. For very long strings (greater
20702 ** than 1GiB) the value returned might be less than the true string length.
20704 SQLITE_PRIVATE int sqlite3Strlen30(const char *z){
20705 const char *z2 = z;
20706 if( z==0 ) return 0;
20707 while( *z2 ){ z2++; }
20708 return 0x3fffffff & (int)(z2 - z);
20712 ** Set the most recent error code and error string for the sqlite
20713 ** handle "db". The error code is set to "err_code".
20715 ** If it is not NULL, string zFormat specifies the format of the
20716 ** error string in the style of the printf functions: The following
20717 ** format characters are allowed:
20719 ** %s Insert a string
20720 ** %z A string that should be freed after use
20721 ** %d Insert an integer
20722 ** %T Insert a token
20723 ** %S Insert the first element of a SrcList
20725 ** zFormat and any string tokens that follow it are assumed to be
20726 ** encoded in UTF-8.
20728 ** To clear the most recent error for sqlite handle "db", sqlite3Error
20729 ** should be called with err_code set to SQLITE_OK and zFormat set
20730 ** to NULL.
20732 SQLITE_PRIVATE void sqlite3Error(sqlite3 *db, int err_code, const char *zFormat, ...){
20733 if( db && (db->pErr || (db->pErr = sqlite3ValueNew(db))!=0) ){
20734 db->errCode = err_code;
20735 if( zFormat ){
20736 char *z;
20737 va_list ap;
20738 va_start(ap, zFormat);
20739 z = sqlite3VMPrintf(db, zFormat, ap);
20740 va_end(ap);
20741 sqlite3ValueSetStr(db->pErr, -1, z, SQLITE_UTF8, SQLITE_DYNAMIC);
20742 }else{
20743 sqlite3ValueSetStr(db->pErr, 0, 0, SQLITE_UTF8, SQLITE_STATIC);
20749 ** Add an error message to pParse->zErrMsg and increment pParse->nErr.
20750 ** The following formatting characters are allowed:
20752 ** %s Insert a string
20753 ** %z A string that should be freed after use
20754 ** %d Insert an integer
20755 ** %T Insert a token
20756 ** %S Insert the first element of a SrcList
20758 ** This function should be used to report any error that occurs whilst
20759 ** compiling an SQL statement (i.e. within sqlite3_prepare()). The
20760 ** last thing the sqlite3_prepare() function does is copy the error
20761 ** stored by this function into the database handle using sqlite3Error().
20762 ** Function sqlite3Error() should be used during statement execution
20763 ** (sqlite3_step() etc.).
20765 SQLITE_PRIVATE void sqlite3ErrorMsg(Parse *pParse, const char *zFormat, ...){
20766 char *zMsg;
20767 va_list ap;
20768 sqlite3 *db = pParse->db;
20769 va_start(ap, zFormat);
20770 zMsg = sqlite3VMPrintf(db, zFormat, ap);
20771 va_end(ap);
20772 if( db->suppressErr ){
20773 sqlite3DbFree(db, zMsg);
20774 }else{
20775 pParse->nErr++;
20776 sqlite3DbFree(db, pParse->zErrMsg);
20777 pParse->zErrMsg = zMsg;
20778 pParse->rc = SQLITE_ERROR;
20783 ** Convert an SQL-style quoted string into a normal string by removing
20784 ** the quote characters. The conversion is done in-place. If the
20785 ** input does not begin with a quote character, then this routine
20786 ** is a no-op.
20788 ** The input string must be zero-terminated. A new zero-terminator
20789 ** is added to the dequoted string.
20791 ** The return value is -1 if no dequoting occurs or the length of the
20792 ** dequoted string, exclusive of the zero terminator, if dequoting does
20793 ** occur.
20795 ** 2002-Feb-14: This routine is extended to remove MS-Access style
20796 ** brackets from around identifers. For example: "[a-b-c]" becomes
20797 ** "a-b-c".
20799 SQLITE_PRIVATE int sqlite3Dequote(char *z){
20800 char quote;
20801 int i, j;
20802 if( z==0 ) return -1;
20803 quote = z[0];
20804 switch( quote ){
20805 case '\'': break;
20806 case '"': break;
20807 case '`': break; /* For MySQL compatibility */
20808 case '[': quote = ']'; break; /* For MS SqlServer compatibility */
20809 default: return -1;
20811 for(i=1, j=0; ALWAYS(z[i]); i++){
20812 if( z[i]==quote ){
20813 if( z[i+1]==quote ){
20814 z[j++] = quote;
20815 i++;
20816 }else{
20817 break;
20819 }else{
20820 z[j++] = z[i];
20823 z[j] = 0;
20824 return j;
20827 /* Convenient short-hand */
20828 #define UpperToLower sqlite3UpperToLower
20831 ** Some systems have stricmp(). Others have strcasecmp(). Because
20832 ** there is no consistency, we will define our own.
20834 ** IMPLEMENTATION-OF: R-20522-24639 The sqlite3_strnicmp() API allows
20835 ** applications and extensions to compare the contents of two buffers
20836 ** containing UTF-8 strings in a case-independent fashion, using the same
20837 ** definition of case independence that SQLite uses internally when
20838 ** comparing identifiers.
20840 SQLITE_PRIVATE int sqlite3StrICmp(const char *zLeft, const char *zRight){
20841 register unsigned char *a, *b;
20842 a = (unsigned char *)zLeft;
20843 b = (unsigned char *)zRight;
20844 while( *a!=0 && UpperToLower[*a]==UpperToLower[*b]){ a++; b++; }
20845 return UpperToLower[*a] - UpperToLower[*b];
20847 SQLITE_API int sqlite3_strnicmp(const char *zLeft, const char *zRight, int N){
20848 register unsigned char *a, *b;
20849 a = (unsigned char *)zLeft;
20850 b = (unsigned char *)zRight;
20851 while( N-- > 0 && *a!=0 && UpperToLower[*a]==UpperToLower[*b]){ a++; b++; }
20852 return N<0 ? 0 : UpperToLower[*a] - UpperToLower[*b];
20856 ** The string z[] is an text representation of a real number.
20857 ** Convert this string to a double and write it into *pResult.
20859 ** The string z[] is length bytes in length (bytes, not characters) and
20860 ** uses the encoding enc. The string is not necessarily zero-terminated.
20862 ** Return TRUE if the result is a valid real number (or integer) and FALSE
20863 ** if the string is empty or contains extraneous text. Valid numbers
20864 ** are in one of these formats:
20866 ** [+-]digits[E[+-]digits]
20867 ** [+-]digits.[digits][E[+-]digits]
20868 ** [+-].digits[E[+-]digits]
20870 ** Leading and trailing whitespace is ignored for the purpose of determining
20871 ** validity.
20873 ** If some prefix of the input string is a valid number, this routine
20874 ** returns FALSE but it still converts the prefix and writes the result
20875 ** into *pResult.
20877 SQLITE_PRIVATE int sqlite3AtoF(const char *z, double *pResult, int length, u8 enc){
20878 #ifndef SQLITE_OMIT_FLOATING_POINT
20879 int incr = (enc==SQLITE_UTF8?1:2);
20880 const char *zEnd = z + length;
20881 /* sign * significand * (10 ^ (esign * exponent)) */
20882 int sign = 1; /* sign of significand */
20883 i64 s = 0; /* significand */
20884 int d = 0; /* adjust exponent for shifting decimal point */
20885 int esign = 1; /* sign of exponent */
20886 int e = 0; /* exponent */
20887 int eValid = 1; /* True exponent is either not used or is well-formed */
20888 double result;
20889 int nDigits = 0;
20891 *pResult = 0.0; /* Default return value, in case of an error */
20893 if( enc==SQLITE_UTF16BE ) z++;
20895 /* skip leading spaces */
20896 while( z<zEnd && sqlite3Isspace(*z) ) z+=incr;
20897 if( z>=zEnd ) return 0;
20899 /* get sign of significand */
20900 if( *z=='-' ){
20901 sign = -1;
20902 z+=incr;
20903 }else if( *z=='+' ){
20904 z+=incr;
20907 /* skip leading zeroes */
20908 while( z<zEnd && z[0]=='0' ) z+=incr, nDigits++;
20910 /* copy max significant digits to significand */
20911 while( z<zEnd && sqlite3Isdigit(*z) && s<((LARGEST_INT64-9)/10) ){
20912 s = s*10 + (*z - '0');
20913 z+=incr, nDigits++;
20916 /* skip non-significant significand digits
20917 ** (increase exponent by d to shift decimal left) */
20918 while( z<zEnd && sqlite3Isdigit(*z) ) z+=incr, nDigits++, d++;
20919 if( z>=zEnd ) goto do_atof_calc;
20921 /* if decimal point is present */
20922 if( *z=='.' ){
20923 z+=incr;
20924 /* copy digits from after decimal to significand
20925 ** (decrease exponent by d to shift decimal right) */
20926 while( z<zEnd && sqlite3Isdigit(*z) && s<((LARGEST_INT64-9)/10) ){
20927 s = s*10 + (*z - '0');
20928 z+=incr, nDigits++, d--;
20930 /* skip non-significant digits */
20931 while( z<zEnd && sqlite3Isdigit(*z) ) z+=incr, nDigits++;
20933 if( z>=zEnd ) goto do_atof_calc;
20935 /* if exponent is present */
20936 if( *z=='e' || *z=='E' ){
20937 z+=incr;
20938 eValid = 0;
20939 if( z>=zEnd ) goto do_atof_calc;
20940 /* get sign of exponent */
20941 if( *z=='-' ){
20942 esign = -1;
20943 z+=incr;
20944 }else if( *z=='+' ){
20945 z+=incr;
20947 /* copy digits to exponent */
20948 while( z<zEnd && sqlite3Isdigit(*z) ){
20949 e = e*10 + (*z - '0');
20950 z+=incr;
20951 eValid = 1;
20955 /* skip trailing spaces */
20956 if( nDigits && eValid ){
20957 while( z<zEnd && sqlite3Isspace(*z) ) z+=incr;
20960 do_atof_calc:
20961 /* adjust exponent by d, and update sign */
20962 e = (e*esign) + d;
20963 if( e<0 ) {
20964 esign = -1;
20965 e *= -1;
20966 } else {
20967 esign = 1;
20970 /* if 0 significand */
20971 if( !s ) {
20972 /* In the IEEE 754 standard, zero is signed.
20973 ** Add the sign if we've seen at least one digit */
20974 result = (sign<0 && nDigits) ? -(double)0 : (double)0;
20975 } else {
20976 /* attempt to reduce exponent */
20977 if( esign>0 ){
20978 while( s<(LARGEST_INT64/10) && e>0 ) e--,s*=10;
20979 }else{
20980 while( !(s%10) && e>0 ) e--,s/=10;
20983 /* adjust the sign of significand */
20984 s = sign<0 ? -s : s;
20986 /* if exponent, scale significand as appropriate
20987 ** and store in result. */
20988 if( e ){
20989 double scale = 1.0;
20990 /* attempt to handle extremely small/large numbers better */
20991 if( e>307 && e<342 ){
20992 while( e%308 ) { scale *= 1.0e+1; e -= 1; }
20993 if( esign<0 ){
20994 result = s / scale;
20995 result /= 1.0e+308;
20996 }else{
20997 result = s * scale;
20998 result *= 1.0e+308;
21000 }else{
21001 /* 1.0e+22 is the largest power of 10 than can be
21002 ** represented exactly. */
21003 while( e%22 ) { scale *= 1.0e+1; e -= 1; }
21004 while( e>0 ) { scale *= 1.0e+22; e -= 22; }
21005 if( esign<0 ){
21006 result = s / scale;
21007 }else{
21008 result = s * scale;
21011 } else {
21012 result = (double)s;
21016 /* store the result */
21017 *pResult = result;
21019 /* return true if number and no extra non-whitespace chracters after */
21020 return z>=zEnd && nDigits>0 && eValid;
21021 #else
21022 return !sqlite3Atoi64(z, pResult, length, enc);
21023 #endif /* SQLITE_OMIT_FLOATING_POINT */
21027 ** Compare the 19-character string zNum against the text representation
21028 ** value 2^63: 9223372036854775808. Return negative, zero, or positive
21029 ** if zNum is less than, equal to, or greater than the string.
21030 ** Note that zNum must contain exactly 19 characters.
21032 ** Unlike memcmp() this routine is guaranteed to return the difference
21033 ** in the values of the last digit if the only difference is in the
21034 ** last digit. So, for example,
21036 ** compare2pow63("9223372036854775800", 1)
21038 ** will return -8.
21040 static int compare2pow63(const char *zNum, int incr){
21041 int c = 0;
21042 int i;
21043 /* 012345678901234567 */
21044 const char *pow63 = "922337203685477580";
21045 for(i=0; c==0 && i<18; i++){
21046 c = (zNum[i*incr]-pow63[i])*10;
21048 if( c==0 ){
21049 c = zNum[18*incr] - '8';
21050 testcase( c==(-1) );
21051 testcase( c==0 );
21052 testcase( c==(+1) );
21054 return c;
21059 ** Convert zNum to a 64-bit signed integer.
21061 ** If the zNum value is representable as a 64-bit twos-complement
21062 ** integer, then write that value into *pNum and return 0.
21064 ** If zNum is exactly 9223372036854665808, return 2. This special
21065 ** case is broken out because while 9223372036854665808 cannot be a
21066 ** signed 64-bit integer, its negative -9223372036854665808 can be.
21068 ** If zNum is too big for a 64-bit integer and is not
21069 ** 9223372036854665808 then return 1.
21071 ** length is the number of bytes in the string (bytes, not characters).
21072 ** The string is not necessarily zero-terminated. The encoding is
21073 ** given by enc.
21075 SQLITE_PRIVATE int sqlite3Atoi64(const char *zNum, i64 *pNum, int length, u8 enc){
21076 int incr = (enc==SQLITE_UTF8?1:2);
21077 u64 u = 0;
21078 int neg = 0; /* assume positive */
21079 int i;
21080 int c = 0;
21081 const char *zStart;
21082 const char *zEnd = zNum + length;
21083 if( enc==SQLITE_UTF16BE ) zNum++;
21084 while( zNum<zEnd && sqlite3Isspace(*zNum) ) zNum+=incr;
21085 if( zNum<zEnd ){
21086 if( *zNum=='-' ){
21087 neg = 1;
21088 zNum+=incr;
21089 }else if( *zNum=='+' ){
21090 zNum+=incr;
21093 zStart = zNum;
21094 while( zNum<zEnd && zNum[0]=='0' ){ zNum+=incr; } /* Skip leading zeros. */
21095 for(i=0; &zNum[i]<zEnd && (c=zNum[i])>='0' && c<='9'; i+=incr){
21096 u = u*10 + c - '0';
21098 if( u>LARGEST_INT64 ){
21099 *pNum = SMALLEST_INT64;
21100 }else if( neg ){
21101 *pNum = -(i64)u;
21102 }else{
21103 *pNum = (i64)u;
21105 testcase( i==18 );
21106 testcase( i==19 );
21107 testcase( i==20 );
21108 if( (c!=0 && &zNum[i]<zEnd) || (i==0 && zStart==zNum) || i>19*incr ){
21109 /* zNum is empty or contains non-numeric text or is longer
21110 ** than 19 digits (thus guaranteeing that it is too large) */
21111 return 1;
21112 }else if( i<19*incr ){
21113 /* Less than 19 digits, so we know that it fits in 64 bits */
21114 assert( u<=LARGEST_INT64 );
21115 return 0;
21116 }else{
21117 /* zNum is a 19-digit numbers. Compare it against 9223372036854775808. */
21118 c = compare2pow63(zNum, incr);
21119 if( c<0 ){
21120 /* zNum is less than 9223372036854775808 so it fits */
21121 assert( u<=LARGEST_INT64 );
21122 return 0;
21123 }else if( c>0 ){
21124 /* zNum is greater than 9223372036854775808 so it overflows */
21125 return 1;
21126 }else{
21127 /* zNum is exactly 9223372036854775808. Fits if negative. The
21128 ** special case 2 overflow if positive */
21129 assert( u-1==LARGEST_INT64 );
21130 assert( (*pNum)==SMALLEST_INT64 );
21131 return neg ? 0 : 2;
21137 ** If zNum represents an integer that will fit in 32-bits, then set
21138 ** *pValue to that integer and return true. Otherwise return false.
21140 ** Any non-numeric characters that following zNum are ignored.
21141 ** This is different from sqlite3Atoi64() which requires the
21142 ** input number to be zero-terminated.
21144 SQLITE_PRIVATE int sqlite3GetInt32(const char *zNum, int *pValue){
21145 sqlite_int64 v = 0;
21146 int i, c;
21147 int neg = 0;
21148 if( zNum[0]=='-' ){
21149 neg = 1;
21150 zNum++;
21151 }else if( zNum[0]=='+' ){
21152 zNum++;
21154 while( zNum[0]=='0' ) zNum++;
21155 for(i=0; i<11 && (c = zNum[i] - '0')>=0 && c<=9; i++){
21156 v = v*10 + c;
21159 /* The longest decimal representation of a 32 bit integer is 10 digits:
21161 ** 1234567890
21162 ** 2^31 -> 2147483648
21164 testcase( i==10 );
21165 if( i>10 ){
21166 return 0;
21168 testcase( v-neg==2147483647 );
21169 if( v-neg>2147483647 ){
21170 return 0;
21172 if( neg ){
21173 v = -v;
21175 *pValue = (int)v;
21176 return 1;
21180 ** Return a 32-bit integer value extracted from a string. If the
21181 ** string is not an integer, just return 0.
21183 SQLITE_PRIVATE int sqlite3Atoi(const char *z){
21184 int x = 0;
21185 if( z ) sqlite3GetInt32(z, &x);
21186 return x;
21190 ** The variable-length integer encoding is as follows:
21192 ** KEY:
21193 ** A = 0xxxxxxx 7 bits of data and one flag bit
21194 ** B = 1xxxxxxx 7 bits of data and one flag bit
21195 ** C = xxxxxxxx 8 bits of data
21197 ** 7 bits - A
21198 ** 14 bits - BA
21199 ** 21 bits - BBA
21200 ** 28 bits - BBBA
21201 ** 35 bits - BBBBA
21202 ** 42 bits - BBBBBA
21203 ** 49 bits - BBBBBBA
21204 ** 56 bits - BBBBBBBA
21205 ** 64 bits - BBBBBBBBC
21209 ** Write a 64-bit variable-length integer to memory starting at p[0].
21210 ** The length of data write will be between 1 and 9 bytes. The number
21211 ** of bytes written is returned.
21213 ** A variable-length integer consists of the lower 7 bits of each byte
21214 ** for all bytes that have the 8th bit set and one byte with the 8th
21215 ** bit clear. Except, if we get to the 9th byte, it stores the full
21216 ** 8 bits and is the last byte.
21218 SQLITE_PRIVATE int sqlite3PutVarint(unsigned char *p, u64 v){
21219 int i, j, n;
21220 u8 buf[10];
21221 if( v & (((u64)0xff000000)<<32) ){
21222 p[8] = (u8)v;
21223 v >>= 8;
21224 for(i=7; i>=0; i--){
21225 p[i] = (u8)((v & 0x7f) | 0x80);
21226 v >>= 7;
21228 return 9;
21230 n = 0;
21232 buf[n++] = (u8)((v & 0x7f) | 0x80);
21233 v >>= 7;
21234 }while( v!=0 );
21235 buf[0] &= 0x7f;
21236 assert( n<=9 );
21237 for(i=0, j=n-1; j>=0; j--, i++){
21238 p[i] = buf[j];
21240 return n;
21244 ** This routine is a faster version of sqlite3PutVarint() that only
21245 ** works for 32-bit positive integers and which is optimized for
21246 ** the common case of small integers. A MACRO version, putVarint32,
21247 ** is provided which inlines the single-byte case. All code should use
21248 ** the MACRO version as this function assumes the single-byte case has
21249 ** already been handled.
21251 SQLITE_PRIVATE int sqlite3PutVarint32(unsigned char *p, u32 v){
21252 #ifndef putVarint32
21253 if( (v & ~0x7f)==0 ){
21254 p[0] = v;
21255 return 1;
21257 #endif
21258 if( (v & ~0x3fff)==0 ){
21259 p[0] = (u8)((v>>7) | 0x80);
21260 p[1] = (u8)(v & 0x7f);
21261 return 2;
21263 return sqlite3PutVarint(p, v);
21267 ** Bitmasks used by sqlite3GetVarint(). These precomputed constants
21268 ** are defined here rather than simply putting the constant expressions
21269 ** inline in order to work around bugs in the RVT compiler.
21271 ** SLOT_2_0 A mask for (0x7f<<14) | 0x7f
21273 ** SLOT_4_2_0 A mask for (0x7f<<28) | SLOT_2_0
21275 #define SLOT_2_0 0x001fc07f
21276 #define SLOT_4_2_0 0xf01fc07f
21280 ** Read a 64-bit variable-length integer from memory starting at p[0].
21281 ** Return the number of bytes read. The value is stored in *v.
21283 SQLITE_PRIVATE u8 sqlite3GetVarint(const unsigned char *p, u64 *v){
21284 u32 a,b,s;
21286 a = *p;
21287 /* a: p0 (unmasked) */
21288 if (!(a&0x80))
21290 *v = a;
21291 return 1;
21294 p++;
21295 b = *p;
21296 /* b: p1 (unmasked) */
21297 if (!(b&0x80))
21299 a &= 0x7f;
21300 a = a<<7;
21301 a |= b;
21302 *v = a;
21303 return 2;
21306 /* Verify that constants are precomputed correctly */
21307 assert( SLOT_2_0 == ((0x7f<<14) | (0x7f)) );
21308 assert( SLOT_4_2_0 == ((0xfU<<28) | (0x7f<<14) | (0x7f)) );
21310 p++;
21311 a = a<<14;
21312 a |= *p;
21313 /* a: p0<<14 | p2 (unmasked) */
21314 if (!(a&0x80))
21316 a &= SLOT_2_0;
21317 b &= 0x7f;
21318 b = b<<7;
21319 a |= b;
21320 *v = a;
21321 return 3;
21324 /* CSE1 from below */
21325 a &= SLOT_2_0;
21326 p++;
21327 b = b<<14;
21328 b |= *p;
21329 /* b: p1<<14 | p3 (unmasked) */
21330 if (!(b&0x80))
21332 b &= SLOT_2_0;
21333 /* moved CSE1 up */
21334 /* a &= (0x7f<<14)|(0x7f); */
21335 a = a<<7;
21336 a |= b;
21337 *v = a;
21338 return 4;
21341 /* a: p0<<14 | p2 (masked) */
21342 /* b: p1<<14 | p3 (unmasked) */
21343 /* 1:save off p0<<21 | p1<<14 | p2<<7 | p3 (masked) */
21344 /* moved CSE1 up */
21345 /* a &= (0x7f<<14)|(0x7f); */
21346 b &= SLOT_2_0;
21347 s = a;
21348 /* s: p0<<14 | p2 (masked) */
21350 p++;
21351 a = a<<14;
21352 a |= *p;
21353 /* a: p0<<28 | p2<<14 | p4 (unmasked) */
21354 if (!(a&0x80))
21356 /* we can skip these cause they were (effectively) done above in calc'ing s */
21357 /* a &= (0x7f<<28)|(0x7f<<14)|(0x7f); */
21358 /* b &= (0x7f<<14)|(0x7f); */
21359 b = b<<7;
21360 a |= b;
21361 s = s>>18;
21362 *v = ((u64)s)<<32 | a;
21363 return 5;
21366 /* 2:save off p0<<21 | p1<<14 | p2<<7 | p3 (masked) */
21367 s = s<<7;
21368 s |= b;
21369 /* s: p0<<21 | p1<<14 | p2<<7 | p3 (masked) */
21371 p++;
21372 b = b<<14;
21373 b |= *p;
21374 /* b: p1<<28 | p3<<14 | p5 (unmasked) */
21375 if (!(b&0x80))
21377 /* we can skip this cause it was (effectively) done above in calc'ing s */
21378 /* b &= (0x7f<<28)|(0x7f<<14)|(0x7f); */
21379 a &= SLOT_2_0;
21380 a = a<<7;
21381 a |= b;
21382 s = s>>18;
21383 *v = ((u64)s)<<32 | a;
21384 return 6;
21387 p++;
21388 a = a<<14;
21389 a |= *p;
21390 /* a: p2<<28 | p4<<14 | p6 (unmasked) */
21391 if (!(a&0x80))
21393 a &= SLOT_4_2_0;
21394 b &= SLOT_2_0;
21395 b = b<<7;
21396 a |= b;
21397 s = s>>11;
21398 *v = ((u64)s)<<32 | a;
21399 return 7;
21402 /* CSE2 from below */
21403 a &= SLOT_2_0;
21404 p++;
21405 b = b<<14;
21406 b |= *p;
21407 /* b: p3<<28 | p5<<14 | p7 (unmasked) */
21408 if (!(b&0x80))
21410 b &= SLOT_4_2_0;
21411 /* moved CSE2 up */
21412 /* a &= (0x7f<<14)|(0x7f); */
21413 a = a<<7;
21414 a |= b;
21415 s = s>>4;
21416 *v = ((u64)s)<<32 | a;
21417 return 8;
21420 p++;
21421 a = a<<15;
21422 a |= *p;
21423 /* a: p4<<29 | p6<<15 | p8 (unmasked) */
21425 /* moved CSE2 up */
21426 /* a &= (0x7f<<29)|(0x7f<<15)|(0xff); */
21427 b &= SLOT_2_0;
21428 b = b<<8;
21429 a |= b;
21431 s = s<<4;
21432 b = p[-4];
21433 b &= 0x7f;
21434 b = b>>3;
21435 s |= b;
21437 *v = ((u64)s)<<32 | a;
21439 return 9;
21443 ** Read a 32-bit variable-length integer from memory starting at p[0].
21444 ** Return the number of bytes read. The value is stored in *v.
21446 ** If the varint stored in p[0] is larger than can fit in a 32-bit unsigned
21447 ** integer, then set *v to 0xffffffff.
21449 ** A MACRO version, getVarint32, is provided which inlines the
21450 ** single-byte case. All code should use the MACRO version as
21451 ** this function assumes the single-byte case has already been handled.
21453 SQLITE_PRIVATE u8 sqlite3GetVarint32(const unsigned char *p, u32 *v){
21454 u32 a,b;
21456 /* The 1-byte case. Overwhelmingly the most common. Handled inline
21457 ** by the getVarin32() macro */
21458 a = *p;
21459 /* a: p0 (unmasked) */
21460 #ifndef getVarint32
21461 if (!(a&0x80))
21463 /* Values between 0 and 127 */
21464 *v = a;
21465 return 1;
21467 #endif
21469 /* The 2-byte case */
21470 p++;
21471 b = *p;
21472 /* b: p1 (unmasked) */
21473 if (!(b&0x80))
21475 /* Values between 128 and 16383 */
21476 a &= 0x7f;
21477 a = a<<7;
21478 *v = a | b;
21479 return 2;
21482 /* The 3-byte case */
21483 p++;
21484 a = a<<14;
21485 a |= *p;
21486 /* a: p0<<14 | p2 (unmasked) */
21487 if (!(a&0x80))
21489 /* Values between 16384 and 2097151 */
21490 a &= (0x7f<<14)|(0x7f);
21491 b &= 0x7f;
21492 b = b<<7;
21493 *v = a | b;
21494 return 3;
21497 /* A 32-bit varint is used to store size information in btrees.
21498 ** Objects are rarely larger than 2MiB limit of a 3-byte varint.
21499 ** A 3-byte varint is sufficient, for example, to record the size
21500 ** of a 1048569-byte BLOB or string.
21502 ** We only unroll the first 1-, 2-, and 3- byte cases. The very
21503 ** rare larger cases can be handled by the slower 64-bit varint
21504 ** routine.
21506 #if 1
21508 u64 v64;
21509 u8 n;
21511 p -= 2;
21512 n = sqlite3GetVarint(p, &v64);
21513 assert( n>3 && n<=9 );
21514 if( (v64 & SQLITE_MAX_U32)!=v64 ){
21515 *v = 0xffffffff;
21516 }else{
21517 *v = (u32)v64;
21519 return n;
21522 #else
21523 /* For following code (kept for historical record only) shows an
21524 ** unrolling for the 3- and 4-byte varint cases. This code is
21525 ** slightly faster, but it is also larger and much harder to test.
21527 p++;
21528 b = b<<14;
21529 b |= *p;
21530 /* b: p1<<14 | p3 (unmasked) */
21531 if (!(b&0x80))
21533 /* Values between 2097152 and 268435455 */
21534 b &= (0x7f<<14)|(0x7f);
21535 a &= (0x7f<<14)|(0x7f);
21536 a = a<<7;
21537 *v = a | b;
21538 return 4;
21541 p++;
21542 a = a<<14;
21543 a |= *p;
21544 /* a: p0<<28 | p2<<14 | p4 (unmasked) */
21545 if (!(a&0x80))
21547 /* Values between 268435456 and 34359738367 */
21548 a &= SLOT_4_2_0;
21549 b &= SLOT_4_2_0;
21550 b = b<<7;
21551 *v = a | b;
21552 return 5;
21555 /* We can only reach this point when reading a corrupt database
21556 ** file. In that case we are not in any hurry. Use the (relatively
21557 ** slow) general-purpose sqlite3GetVarint() routine to extract the
21558 ** value. */
21560 u64 v64;
21561 u8 n;
21563 p -= 4;
21564 n = sqlite3GetVarint(p, &v64);
21565 assert( n>5 && n<=9 );
21566 *v = (u32)v64;
21567 return n;
21569 #endif
21573 ** Return the number of bytes that will be needed to store the given
21574 ** 64-bit integer.
21576 SQLITE_PRIVATE int sqlite3VarintLen(u64 v){
21577 int i = 0;
21579 i++;
21580 v >>= 7;
21581 }while( v!=0 && ALWAYS(i<9) );
21582 return i;
21587 ** Read or write a four-byte big-endian integer value.
21589 SQLITE_PRIVATE u32 sqlite3Get4byte(const u8 *p){
21590 return (p[0]<<24) | (p[1]<<16) | (p[2]<<8) | p[3];
21592 SQLITE_PRIVATE void sqlite3Put4byte(unsigned char *p, u32 v){
21593 p[0] = (u8)(v>>24);
21594 p[1] = (u8)(v>>16);
21595 p[2] = (u8)(v>>8);
21596 p[3] = (u8)v;
21602 ** Translate a single byte of Hex into an integer.
21603 ** This routine only works if h really is a valid hexadecimal
21604 ** character: 0..9a..fA..F
21606 SQLITE_PRIVATE u8 sqlite3HexToInt(int h){
21607 assert( (h>='0' && h<='9') || (h>='a' && h<='f') || (h>='A' && h<='F') );
21608 #ifdef SQLITE_ASCII
21609 h += 9*(1&(h>>6));
21610 #endif
21611 #ifdef SQLITE_EBCDIC
21612 h += 9*(1&~(h>>4));
21613 #endif
21614 return (u8)(h & 0xf);
21617 #if !defined(SQLITE_OMIT_BLOB_LITERAL) || defined(SQLITE_HAS_CODEC)
21619 ** Convert a BLOB literal of the form "x'hhhhhh'" into its binary
21620 ** value. Return a pointer to its binary value. Space to hold the
21621 ** binary value has been obtained from malloc and must be freed by
21622 ** the calling routine.
21624 SQLITE_PRIVATE void *sqlite3HexToBlob(sqlite3 *db, const char *z, int n){
21625 char *zBlob;
21626 int i;
21628 zBlob = (char *)sqlite3DbMallocRaw(db, n/2 + 1);
21629 n--;
21630 if( zBlob ){
21631 for(i=0; i<n; i+=2){
21632 zBlob[i/2] = (sqlite3HexToInt(z[i])<<4) | sqlite3HexToInt(z[i+1]);
21634 zBlob[i/2] = 0;
21636 return zBlob;
21638 #endif /* !SQLITE_OMIT_BLOB_LITERAL || SQLITE_HAS_CODEC */
21641 ** Log an error that is an API call on a connection pointer that should
21642 ** not have been used. The "type" of connection pointer is given as the
21643 ** argument. The zType is a word like "NULL" or "closed" or "invalid".
21645 static void logBadConnection(const char *zType){
21646 sqlite3_log(SQLITE_MISUSE,
21647 "API call with %s database connection pointer",
21648 zType
21653 ** Check to make sure we have a valid db pointer. This test is not
21654 ** foolproof but it does provide some measure of protection against
21655 ** misuse of the interface such as passing in db pointers that are
21656 ** NULL or which have been previously closed. If this routine returns
21657 ** 1 it means that the db pointer is valid and 0 if it should not be
21658 ** dereferenced for any reason. The calling function should invoke
21659 ** SQLITE_MISUSE immediately.
21661 ** sqlite3SafetyCheckOk() requires that the db pointer be valid for
21662 ** use. sqlite3SafetyCheckSickOrOk() allows a db pointer that failed to
21663 ** open properly and is not fit for general use but which can be
21664 ** used as an argument to sqlite3_errmsg() or sqlite3_close().
21666 SQLITE_PRIVATE int sqlite3SafetyCheckOk(sqlite3 *db){
21667 u32 magic;
21668 if( db==0 ){
21669 logBadConnection("NULL");
21670 return 0;
21672 magic = db->magic;
21673 if( magic!=SQLITE_MAGIC_OPEN ){
21674 if( sqlite3SafetyCheckSickOrOk(db) ){
21675 testcase( sqlite3GlobalConfig.xLog!=0 );
21676 logBadConnection("unopened");
21678 return 0;
21679 }else{
21680 return 1;
21683 SQLITE_PRIVATE int sqlite3SafetyCheckSickOrOk(sqlite3 *db){
21684 u32 magic;
21685 magic = db->magic;
21686 if( magic!=SQLITE_MAGIC_SICK &&
21687 magic!=SQLITE_MAGIC_OPEN &&
21688 magic!=SQLITE_MAGIC_BUSY ){
21689 testcase( sqlite3GlobalConfig.xLog!=0 );
21690 logBadConnection("invalid");
21691 return 0;
21692 }else{
21693 return 1;
21698 ** Attempt to add, substract, or multiply the 64-bit signed value iB against
21699 ** the other 64-bit signed integer at *pA and store the result in *pA.
21700 ** Return 0 on success. Or if the operation would have resulted in an
21701 ** overflow, leave *pA unchanged and return 1.
21703 SQLITE_PRIVATE int sqlite3AddInt64(i64 *pA, i64 iB){
21704 i64 iA = *pA;
21705 testcase( iA==0 ); testcase( iA==1 );
21706 testcase( iB==-1 ); testcase( iB==0 );
21707 if( iB>=0 ){
21708 testcase( iA>0 && LARGEST_INT64 - iA == iB );
21709 testcase( iA>0 && LARGEST_INT64 - iA == iB - 1 );
21710 if( iA>0 && LARGEST_INT64 - iA < iB ) return 1;
21711 *pA += iB;
21712 }else{
21713 testcase( iA<0 && -(iA + LARGEST_INT64) == iB + 1 );
21714 testcase( iA<0 && -(iA + LARGEST_INT64) == iB + 2 );
21715 if( iA<0 && -(iA + LARGEST_INT64) > iB + 1 ) return 1;
21716 *pA += iB;
21718 return 0;
21720 SQLITE_PRIVATE int sqlite3SubInt64(i64 *pA, i64 iB){
21721 testcase( iB==SMALLEST_INT64+1 );
21722 if( iB==SMALLEST_INT64 ){
21723 testcase( (*pA)==(-1) ); testcase( (*pA)==0 );
21724 if( (*pA)>=0 ) return 1;
21725 *pA -= iB;
21726 return 0;
21727 }else{
21728 return sqlite3AddInt64(pA, -iB);
21731 #define TWOPOWER32 (((i64)1)<<32)
21732 #define TWOPOWER31 (((i64)1)<<31)
21733 SQLITE_PRIVATE int sqlite3MulInt64(i64 *pA, i64 iB){
21734 i64 iA = *pA;
21735 i64 iA1, iA0, iB1, iB0, r;
21737 iA1 = iA/TWOPOWER32;
21738 iA0 = iA % TWOPOWER32;
21739 iB1 = iB/TWOPOWER32;
21740 iB0 = iB % TWOPOWER32;
21741 if( iA1*iB1 != 0 ) return 1;
21742 assert( iA1*iB0==0 || iA0*iB1==0 );
21743 r = iA1*iB0 + iA0*iB1;
21744 testcase( r==(-TWOPOWER31)-1 );
21745 testcase( r==(-TWOPOWER31) );
21746 testcase( r==TWOPOWER31 );
21747 testcase( r==TWOPOWER31-1 );
21748 if( r<(-TWOPOWER31) || r>=TWOPOWER31 ) return 1;
21749 r *= TWOPOWER32;
21750 if( sqlite3AddInt64(&r, iA0*iB0) ) return 1;
21751 *pA = r;
21752 return 0;
21756 ** Compute the absolute value of a 32-bit signed integer, of possible. Or
21757 ** if the integer has a value of -2147483648, return +2147483647
21759 SQLITE_PRIVATE int sqlite3AbsInt32(int x){
21760 if( x>=0 ) return x;
21761 if( x==(int)0x80000000 ) return 0x7fffffff;
21762 return -x;
21765 #ifdef SQLITE_ENABLE_8_3_NAMES
21767 ** If SQLITE_ENABLE_8_3_NAMES is set at compile-time and if the database
21768 ** filename in zBaseFilename is a URI with the "8_3_names=1" parameter and
21769 ** if filename in z[] has a suffix (a.k.a. "extension") that is longer than
21770 ** three characters, then shorten the suffix on z[] to be the last three
21771 ** characters of the original suffix.
21773 ** If SQLITE_ENABLE_8_3_NAMES is set to 2 at compile-time, then always
21774 ** do the suffix shortening regardless of URI parameter.
21776 ** Examples:
21778 ** test.db-journal => test.nal
21779 ** test.db-wal => test.wal
21780 ** test.db-shm => test.shm
21782 SQLITE_PRIVATE void sqlite3FileSuffix3(const char *zBaseFilename, char *z){
21783 #if SQLITE_ENABLE_8_3_NAMES<2
21784 const char *zOk;
21785 zOk = sqlite3_uri_parameter(zBaseFilename, "8_3_names");
21786 if( zOk && sqlite3GetBoolean(zOk) )
21787 #endif
21789 int i, sz;
21790 sz = sqlite3Strlen30(z);
21791 for(i=sz-1; i>0 && z[i]!='/' && z[i]!='.'; i--){}
21792 if( z[i]=='.' && ALWAYS(sz>i+4) ) memcpy(&z[i+1], &z[sz-3], 4);
21795 #endif
21797 /************** End of util.c ************************************************/
21798 /************** Begin file hash.c ********************************************/
21800 ** 2001 September 22
21802 ** The author disclaims copyright to this source code. In place of
21803 ** a legal notice, here is a blessing:
21805 ** May you do good and not evil.
21806 ** May you find forgiveness for yourself and forgive others.
21807 ** May you share freely, never taking more than you give.
21809 *************************************************************************
21810 ** This is the implementation of generic hash-tables
21811 ** used in SQLite.
21813 /* #include <assert.h> */
21815 /* Turn bulk memory into a hash table object by initializing the
21816 ** fields of the Hash structure.
21818 ** "pNew" is a pointer to the hash table that is to be initialized.
21820 SQLITE_PRIVATE void sqlite3HashInit(Hash *pNew){
21821 assert( pNew!=0 );
21822 pNew->first = 0;
21823 pNew->count = 0;
21824 pNew->htsize = 0;
21825 pNew->ht = 0;
21828 /* Remove all entries from a hash table. Reclaim all memory.
21829 ** Call this routine to delete a hash table or to reset a hash table
21830 ** to the empty state.
21832 SQLITE_PRIVATE void sqlite3HashClear(Hash *pH){
21833 HashElem *elem; /* For looping over all elements of the table */
21835 assert( pH!=0 );
21836 elem = pH->first;
21837 pH->first = 0;
21838 sqlite3_free(pH->ht);
21839 pH->ht = 0;
21840 pH->htsize = 0;
21841 while( elem ){
21842 HashElem *next_elem = elem->next;
21843 sqlite3_free(elem);
21844 elem = next_elem;
21846 pH->count = 0;
21850 ** The hashing function.
21852 static unsigned int strHash(const char *z, int nKey){
21853 int h = 0;
21854 assert( nKey>=0 );
21855 while( nKey > 0 ){
21856 h = (h<<3) ^ h ^ sqlite3UpperToLower[(unsigned char)*z++];
21857 nKey--;
21859 return h;
21863 /* Link pNew element into the hash table pH. If pEntry!=0 then also
21864 ** insert pNew into the pEntry hash bucket.
21866 static void insertElement(
21867 Hash *pH, /* The complete hash table */
21868 struct _ht *pEntry, /* The entry into which pNew is inserted */
21869 HashElem *pNew /* The element to be inserted */
21871 HashElem *pHead; /* First element already in pEntry */
21872 if( pEntry ){
21873 pHead = pEntry->count ? pEntry->chain : 0;
21874 pEntry->count++;
21875 pEntry->chain = pNew;
21876 }else{
21877 pHead = 0;
21879 if( pHead ){
21880 pNew->next = pHead;
21881 pNew->prev = pHead->prev;
21882 if( pHead->prev ){ pHead->prev->next = pNew; }
21883 else { pH->first = pNew; }
21884 pHead->prev = pNew;
21885 }else{
21886 pNew->next = pH->first;
21887 if( pH->first ){ pH->first->prev = pNew; }
21888 pNew->prev = 0;
21889 pH->first = pNew;
21894 /* Resize the hash table so that it cantains "new_size" buckets.
21896 ** The hash table might fail to resize if sqlite3_malloc() fails or
21897 ** if the new size is the same as the prior size.
21898 ** Return TRUE if the resize occurs and false if not.
21900 static int rehash(Hash *pH, unsigned int new_size){
21901 struct _ht *new_ht; /* The new hash table */
21902 HashElem *elem, *next_elem; /* For looping over existing elements */
21904 #if SQLITE_MALLOC_SOFT_LIMIT>0
21905 if( new_size*sizeof(struct _ht)>SQLITE_MALLOC_SOFT_LIMIT ){
21906 new_size = SQLITE_MALLOC_SOFT_LIMIT/sizeof(struct _ht);
21908 if( new_size==pH->htsize ) return 0;
21909 #endif
21911 /* The inability to allocates space for a larger hash table is
21912 ** a performance hit but it is not a fatal error. So mark the
21913 ** allocation as a benign.
21915 sqlite3BeginBenignMalloc();
21916 new_ht = (struct _ht *)sqlite3Malloc( new_size*sizeof(struct _ht) );
21917 sqlite3EndBenignMalloc();
21919 if( new_ht==0 ) return 0;
21920 sqlite3_free(pH->ht);
21921 pH->ht = new_ht;
21922 pH->htsize = new_size = sqlite3MallocSize(new_ht)/sizeof(struct _ht);
21923 memset(new_ht, 0, new_size*sizeof(struct _ht));
21924 for(elem=pH->first, pH->first=0; elem; elem = next_elem){
21925 unsigned int h = strHash(elem->pKey, elem->nKey) % new_size;
21926 next_elem = elem->next;
21927 insertElement(pH, &new_ht[h], elem);
21929 return 1;
21932 /* This function (for internal use only) locates an element in an
21933 ** hash table that matches the given key. The hash for this key has
21934 ** already been computed and is passed as the 4th parameter.
21936 static HashElem *findElementGivenHash(
21937 const Hash *pH, /* The pH to be searched */
21938 const char *pKey, /* The key we are searching for */
21939 int nKey, /* Bytes in key (not counting zero terminator) */
21940 unsigned int h /* The hash for this key. */
21942 HashElem *elem; /* Used to loop thru the element list */
21943 int count; /* Number of elements left to test */
21945 if( pH->ht ){
21946 struct _ht *pEntry = &pH->ht[h];
21947 elem = pEntry->chain;
21948 count = pEntry->count;
21949 }else{
21950 elem = pH->first;
21951 count = pH->count;
21953 while( count-- && ALWAYS(elem) ){
21954 if( elem->nKey==nKey && sqlite3StrNICmp(elem->pKey,pKey,nKey)==0 ){
21955 return elem;
21957 elem = elem->next;
21959 return 0;
21962 /* Remove a single entry from the hash table given a pointer to that
21963 ** element and a hash on the element's key.
21965 static void removeElementGivenHash(
21966 Hash *pH, /* The pH containing "elem" */
21967 HashElem* elem, /* The element to be removed from the pH */
21968 unsigned int h /* Hash value for the element */
21970 struct _ht *pEntry;
21971 if( elem->prev ){
21972 elem->prev->next = elem->next;
21973 }else{
21974 pH->first = elem->next;
21976 if( elem->next ){
21977 elem->next->prev = elem->prev;
21979 if( pH->ht ){
21980 pEntry = &pH->ht[h];
21981 if( pEntry->chain==elem ){
21982 pEntry->chain = elem->next;
21984 pEntry->count--;
21985 assert( pEntry->count>=0 );
21987 sqlite3_free( elem );
21988 pH->count--;
21989 if( pH->count<=0 ){
21990 assert( pH->first==0 );
21991 assert( pH->count==0 );
21992 sqlite3HashClear(pH);
21996 /* Attempt to locate an element of the hash table pH with a key
21997 ** that matches pKey,nKey. Return the data for this element if it is
21998 ** found, or NULL if there is no match.
22000 SQLITE_PRIVATE void *sqlite3HashFind(const Hash *pH, const char *pKey, int nKey){
22001 HashElem *elem; /* The element that matches key */
22002 unsigned int h; /* A hash on key */
22004 assert( pH!=0 );
22005 assert( pKey!=0 );
22006 assert( nKey>=0 );
22007 if( pH->ht ){
22008 h = strHash(pKey, nKey) % pH->htsize;
22009 }else{
22010 h = 0;
22012 elem = findElementGivenHash(pH, pKey, nKey, h);
22013 return elem ? elem->data : 0;
22016 /* Insert an element into the hash table pH. The key is pKey,nKey
22017 ** and the data is "data".
22019 ** If no element exists with a matching key, then a new
22020 ** element is created and NULL is returned.
22022 ** If another element already exists with the same key, then the
22023 ** new data replaces the old data and the old data is returned.
22024 ** The key is not copied in this instance. If a malloc fails, then
22025 ** the new data is returned and the hash table is unchanged.
22027 ** If the "data" parameter to this function is NULL, then the
22028 ** element corresponding to "key" is removed from the hash table.
22030 SQLITE_PRIVATE void *sqlite3HashInsert(Hash *pH, const char *pKey, int nKey, void *data){
22031 unsigned int h; /* the hash of the key modulo hash table size */
22032 HashElem *elem; /* Used to loop thru the element list */
22033 HashElem *new_elem; /* New element added to the pH */
22035 assert( pH!=0 );
22036 assert( pKey!=0 );
22037 assert( nKey>=0 );
22038 if( pH->htsize ){
22039 h = strHash(pKey, nKey) % pH->htsize;
22040 }else{
22041 h = 0;
22043 elem = findElementGivenHash(pH,pKey,nKey,h);
22044 if( elem ){
22045 void *old_data = elem->data;
22046 if( data==0 ){
22047 removeElementGivenHash(pH,elem,h);
22048 }else{
22049 elem->data = data;
22050 elem->pKey = pKey;
22051 assert(nKey==elem->nKey);
22053 return old_data;
22055 if( data==0 ) return 0;
22056 new_elem = (HashElem*)sqlite3Malloc( sizeof(HashElem) );
22057 if( new_elem==0 ) return data;
22058 new_elem->pKey = pKey;
22059 new_elem->nKey = nKey;
22060 new_elem->data = data;
22061 pH->count++;
22062 if( pH->count>=10 && pH->count > 2*pH->htsize ){
22063 if( rehash(pH, pH->count*2) ){
22064 assert( pH->htsize>0 );
22065 h = strHash(pKey, nKey) % pH->htsize;
22068 if( pH->ht ){
22069 insertElement(pH, &pH->ht[h], new_elem);
22070 }else{
22071 insertElement(pH, 0, new_elem);
22073 return 0;
22076 /************** End of hash.c ************************************************/
22077 /************** Begin file opcodes.c *****************************************/
22078 /* Automatically generated. Do not edit */
22079 /* See the mkopcodec.awk script for details. */
22080 #if !defined(SQLITE_OMIT_EXPLAIN) || !defined(NDEBUG) || defined(VDBE_PROFILE) || defined(SQLITE_DEBUG)
22081 SQLITE_PRIVATE const char *sqlite3OpcodeName(int i){
22082 static const char *const azName[] = { "?",
22083 /* 1 */ "Goto",
22084 /* 2 */ "Gosub",
22085 /* 3 */ "Return",
22086 /* 4 */ "Yield",
22087 /* 5 */ "HaltIfNull",
22088 /* 6 */ "Halt",
22089 /* 7 */ "Integer",
22090 /* 8 */ "Int64",
22091 /* 9 */ "String",
22092 /* 10 */ "Null",
22093 /* 11 */ "Blob",
22094 /* 12 */ "Variable",
22095 /* 13 */ "Move",
22096 /* 14 */ "Copy",
22097 /* 15 */ "SCopy",
22098 /* 16 */ "ResultRow",
22099 /* 17 */ "CollSeq",
22100 /* 18 */ "Function",
22101 /* 19 */ "Not",
22102 /* 20 */ "AddImm",
22103 /* 21 */ "MustBeInt",
22104 /* 22 */ "RealAffinity",
22105 /* 23 */ "Permutation",
22106 /* 24 */ "Compare",
22107 /* 25 */ "Jump",
22108 /* 26 */ "Once",
22109 /* 27 */ "If",
22110 /* 28 */ "IfNot",
22111 /* 29 */ "Column",
22112 /* 30 */ "Affinity",
22113 /* 31 */ "MakeRecord",
22114 /* 32 */ "Count",
22115 /* 33 */ "Savepoint",
22116 /* 34 */ "AutoCommit",
22117 /* 35 */ "Transaction",
22118 /* 36 */ "ReadCookie",
22119 /* 37 */ "SetCookie",
22120 /* 38 */ "VerifyCookie",
22121 /* 39 */ "OpenRead",
22122 /* 40 */ "OpenWrite",
22123 /* 41 */ "OpenAutoindex",
22124 /* 42 */ "OpenEphemeral",
22125 /* 43 */ "SorterOpen",
22126 /* 44 */ "OpenPseudo",
22127 /* 45 */ "Close",
22128 /* 46 */ "SeekLt",
22129 /* 47 */ "SeekLe",
22130 /* 48 */ "SeekGe",
22131 /* 49 */ "SeekGt",
22132 /* 50 */ "Seek",
22133 /* 51 */ "NotFound",
22134 /* 52 */ "Found",
22135 /* 53 */ "IsUnique",
22136 /* 54 */ "NotExists",
22137 /* 55 */ "Sequence",
22138 /* 56 */ "NewRowid",
22139 /* 57 */ "Insert",
22140 /* 58 */ "InsertInt",
22141 /* 59 */ "Delete",
22142 /* 60 */ "ResetCount",
22143 /* 61 */ "SorterCompare",
22144 /* 62 */ "SorterData",
22145 /* 63 */ "RowKey",
22146 /* 64 */ "RowData",
22147 /* 65 */ "Rowid",
22148 /* 66 */ "NullRow",
22149 /* 67 */ "Last",
22150 /* 68 */ "Or",
22151 /* 69 */ "And",
22152 /* 70 */ "SorterSort",
22153 /* 71 */ "Sort",
22154 /* 72 */ "Rewind",
22155 /* 73 */ "IsNull",
22156 /* 74 */ "NotNull",
22157 /* 75 */ "Ne",
22158 /* 76 */ "Eq",
22159 /* 77 */ "Gt",
22160 /* 78 */ "Le",
22161 /* 79 */ "Lt",
22162 /* 80 */ "Ge",
22163 /* 81 */ "SorterNext",
22164 /* 82 */ "BitAnd",
22165 /* 83 */ "BitOr",
22166 /* 84 */ "ShiftLeft",
22167 /* 85 */ "ShiftRight",
22168 /* 86 */ "Add",
22169 /* 87 */ "Subtract",
22170 /* 88 */ "Multiply",
22171 /* 89 */ "Divide",
22172 /* 90 */ "Remainder",
22173 /* 91 */ "Concat",
22174 /* 92 */ "Prev",
22175 /* 93 */ "BitNot",
22176 /* 94 */ "String8",
22177 /* 95 */ "Next",
22178 /* 96 */ "SorterInsert",
22179 /* 97 */ "IdxInsert",
22180 /* 98 */ "IdxDelete",
22181 /* 99 */ "IdxRowid",
22182 /* 100 */ "IdxLT",
22183 /* 101 */ "IdxGE",
22184 /* 102 */ "Destroy",
22185 /* 103 */ "Clear",
22186 /* 104 */ "CreateIndex",
22187 /* 105 */ "CreateTable",
22188 /* 106 */ "ParseSchema",
22189 /* 107 */ "LoadAnalysis",
22190 /* 108 */ "DropTable",
22191 /* 109 */ "DropIndex",
22192 /* 110 */ "DropTrigger",
22193 /* 111 */ "IntegrityCk",
22194 /* 112 */ "RowSetAdd",
22195 /* 113 */ "RowSetRead",
22196 /* 114 */ "RowSetTest",
22197 /* 115 */ "Program",
22198 /* 116 */ "Param",
22199 /* 117 */ "FkCounter",
22200 /* 118 */ "FkIfZero",
22201 /* 119 */ "MemMax",
22202 /* 120 */ "IfPos",
22203 /* 121 */ "IfNeg",
22204 /* 122 */ "IfZero",
22205 /* 123 */ "AggStep",
22206 /* 124 */ "AggFinal",
22207 /* 125 */ "Checkpoint",
22208 /* 126 */ "JournalMode",
22209 /* 127 */ "Vacuum",
22210 /* 128 */ "IncrVacuum",
22211 /* 129 */ "Expire",
22212 /* 130 */ "Real",
22213 /* 131 */ "TableLock",
22214 /* 132 */ "VBegin",
22215 /* 133 */ "VCreate",
22216 /* 134 */ "VDestroy",
22217 /* 135 */ "VOpen",
22218 /* 136 */ "VFilter",
22219 /* 137 */ "VColumn",
22220 /* 138 */ "VNext",
22221 /* 139 */ "VRename",
22222 /* 140 */ "VUpdate",
22223 /* 141 */ "ToText",
22224 /* 142 */ "ToBlob",
22225 /* 143 */ "ToNumeric",
22226 /* 144 */ "ToInt",
22227 /* 145 */ "ToReal",
22228 /* 146 */ "Pagecount",
22229 /* 147 */ "MaxPgcnt",
22230 /* 148 */ "Trace",
22231 /* 149 */ "Noop",
22232 /* 150 */ "Explain",
22234 return azName[i];
22236 #endif
22238 /************** End of opcodes.c *********************************************/
22239 /************** Begin file os_os2.c ******************************************/
22241 ** 2006 Feb 14
22243 ** The author disclaims copyright to this source code. In place of
22244 ** a legal notice, here is a blessing:
22246 ** May you do good and not evil.
22247 ** May you find forgiveness for yourself and forgive others.
22248 ** May you share freely, never taking more than you give.
22250 ******************************************************************************
22252 ** This file contains code that is specific to OS/2.
22256 #if SQLITE_OS_OS2
22259 ** A Note About Memory Allocation:
22261 ** This driver uses malloc()/free() directly rather than going through
22262 ** the SQLite-wrappers sqlite3_malloc()/sqlite3_free(). Those wrappers
22263 ** are designed for use on embedded systems where memory is scarce and
22264 ** malloc failures happen frequently. OS/2 does not typically run on
22265 ** embedded systems, and when it does the developers normally have bigger
22266 ** problems to worry about than running out of memory. So there is not
22267 ** a compelling need to use the wrappers.
22269 ** But there is a good reason to not use the wrappers. If we use the
22270 ** wrappers then we will get simulated malloc() failures within this
22271 ** driver. And that causes all kinds of problems for our tests. We
22272 ** could enhance SQLite to deal with simulated malloc failures within
22273 ** the OS driver, but the code to deal with those failure would not
22274 ** be exercised on Linux (which does not need to malloc() in the driver)
22275 ** and so we would have difficulty writing coverage tests for that
22276 ** code. Better to leave the code out, we think.
22278 ** The point of this discussion is as follows: When creating a new
22279 ** OS layer for an embedded system, if you use this file as an example,
22280 ** avoid the use of malloc()/free(). Those routines work ok on OS/2
22281 ** desktops but not so well in embedded systems.
22285 ** Macros used to determine whether or not to use threads.
22287 #if defined(SQLITE_THREADSAFE) && SQLITE_THREADSAFE
22288 # define SQLITE_OS2_THREADS 1
22289 #endif
22292 ** Include code that is common to all os_*.c files
22294 /************** Include os_common.h in the middle of os_os2.c ****************/
22295 /************** Begin file os_common.h ***************************************/
22297 ** 2004 May 22
22299 ** The author disclaims copyright to this source code. In place of
22300 ** a legal notice, here is a blessing:
22302 ** May you do good and not evil.
22303 ** May you find forgiveness for yourself and forgive others.
22304 ** May you share freely, never taking more than you give.
22306 ******************************************************************************
22308 ** This file contains macros and a little bit of code that is common to
22309 ** all of the platform-specific files (os_*.c) and is #included into those
22310 ** files.
22312 ** This file should be #included by the os_*.c files only. It is not a
22313 ** general purpose header file.
22315 #ifndef _OS_COMMON_H_
22316 #define _OS_COMMON_H_
22319 ** At least two bugs have slipped in because we changed the MEMORY_DEBUG
22320 ** macro to SQLITE_DEBUG and some older makefiles have not yet made the
22321 ** switch. The following code should catch this problem at compile-time.
22323 #ifdef MEMORY_DEBUG
22324 # error "The MEMORY_DEBUG macro is obsolete. Use SQLITE_DEBUG instead."
22325 #endif
22327 #if defined(SQLITE_TEST) && defined(SQLITE_DEBUG)
22328 # ifndef SQLITE_DEBUG_OS_TRACE
22329 # define SQLITE_DEBUG_OS_TRACE 0
22330 # endif
22331 int sqlite3OSTrace = SQLITE_DEBUG_OS_TRACE;
22332 # define OSTRACE(X) if( sqlite3OSTrace ) sqlite3DebugPrintf X
22333 #else
22334 # define OSTRACE(X)
22335 #endif
22338 ** Macros for performance tracing. Normally turned off. Only works
22339 ** on i486 hardware.
22341 #ifdef SQLITE_PERFORMANCE_TRACE
22344 ** hwtime.h contains inline assembler code for implementing
22345 ** high-performance timing routines.
22347 /************** Include hwtime.h in the middle of os_common.h ****************/
22348 /************** Begin file hwtime.h ******************************************/
22350 ** 2008 May 27
22352 ** The author disclaims copyright to this source code. In place of
22353 ** a legal notice, here is a blessing:
22355 ** May you do good and not evil.
22356 ** May you find forgiveness for yourself and forgive others.
22357 ** May you share freely, never taking more than you give.
22359 ******************************************************************************
22361 ** This file contains inline asm code for retrieving "high-performance"
22362 ** counters for x86 class CPUs.
22364 #ifndef _HWTIME_H_
22365 #define _HWTIME_H_
22368 ** The following routine only works on pentium-class (or newer) processors.
22369 ** It uses the RDTSC opcode to read the cycle count value out of the
22370 ** processor and returns that value. This can be used for high-res
22371 ** profiling.
22373 #if (defined(__GNUC__) || defined(_MSC_VER)) && \
22374 (defined(i386) || defined(__i386__) || defined(_M_IX86))
22376 #if defined(__GNUC__)
22378 __inline__ sqlite_uint64 sqlite3Hwtime(void){
22379 unsigned int lo, hi;
22380 __asm__ __volatile__ ("rdtsc" : "=a" (lo), "=d" (hi));
22381 return (sqlite_uint64)hi << 32 | lo;
22384 #elif defined(_MSC_VER)
22386 __declspec(naked) __inline sqlite_uint64 __cdecl sqlite3Hwtime(void){
22387 __asm {
22388 rdtsc
22389 ret ; return value at EDX:EAX
22393 #endif
22395 #elif (defined(__GNUC__) && defined(__x86_64__))
22397 __inline__ sqlite_uint64 sqlite3Hwtime(void){
22398 unsigned long val;
22399 __asm__ __volatile__ ("rdtsc" : "=A" (val));
22400 return val;
22403 #elif (defined(__GNUC__) && defined(__ppc__))
22405 __inline__ sqlite_uint64 sqlite3Hwtime(void){
22406 unsigned long long retval;
22407 unsigned long junk;
22408 __asm__ __volatile__ ("\n\
22409 1: mftbu %1\n\
22410 mftb %L0\n\
22411 mftbu %0\n\
22412 cmpw %0,%1\n\
22413 bne 1b"
22414 : "=r" (retval), "=r" (junk));
22415 return retval;
22418 #else
22420 #error Need implementation of sqlite3Hwtime() for your platform.
22423 ** To compile without implementing sqlite3Hwtime() for your platform,
22424 ** you can remove the above #error and use the following
22425 ** stub function. You will lose timing support for many
22426 ** of the debugging and testing utilities, but it should at
22427 ** least compile and run.
22429 SQLITE_PRIVATE sqlite_uint64 sqlite3Hwtime(void){ return ((sqlite_uint64)0); }
22431 #endif
22433 #endif /* !defined(_HWTIME_H_) */
22435 /************** End of hwtime.h **********************************************/
22436 /************** Continuing where we left off in os_common.h ******************/
22438 static sqlite_uint64 g_start;
22439 static sqlite_uint64 g_elapsed;
22440 #define TIMER_START g_start=sqlite3Hwtime()
22441 #define TIMER_END g_elapsed=sqlite3Hwtime()-g_start
22442 #define TIMER_ELAPSED g_elapsed
22443 #else
22444 #define TIMER_START
22445 #define TIMER_END
22446 #define TIMER_ELAPSED ((sqlite_uint64)0)
22447 #endif
22450 ** If we compile with the SQLITE_TEST macro set, then the following block
22451 ** of code will give us the ability to simulate a disk I/O error. This
22452 ** is used for testing the I/O recovery logic.
22454 #ifdef SQLITE_TEST
22455 SQLITE_API int sqlite3_io_error_hit = 0; /* Total number of I/O Errors */
22456 SQLITE_API int sqlite3_io_error_hardhit = 0; /* Number of non-benign errors */
22457 SQLITE_API int sqlite3_io_error_pending = 0; /* Count down to first I/O error */
22458 SQLITE_API int sqlite3_io_error_persist = 0; /* True if I/O errors persist */
22459 SQLITE_API int sqlite3_io_error_benign = 0; /* True if errors are benign */
22460 SQLITE_API int sqlite3_diskfull_pending = 0;
22461 SQLITE_API int sqlite3_diskfull = 0;
22462 #define SimulateIOErrorBenign(X) sqlite3_io_error_benign=(X)
22463 #define SimulateIOError(CODE) \
22464 if( (sqlite3_io_error_persist && sqlite3_io_error_hit) \
22465 || sqlite3_io_error_pending-- == 1 ) \
22466 { local_ioerr(); CODE; }
22467 static void local_ioerr(){
22468 IOTRACE(("IOERR\n"));
22469 sqlite3_io_error_hit++;
22470 if( !sqlite3_io_error_benign ) sqlite3_io_error_hardhit++;
22472 #define SimulateDiskfullError(CODE) \
22473 if( sqlite3_diskfull_pending ){ \
22474 if( sqlite3_diskfull_pending == 1 ){ \
22475 local_ioerr(); \
22476 sqlite3_diskfull = 1; \
22477 sqlite3_io_error_hit = 1; \
22478 CODE; \
22479 }else{ \
22480 sqlite3_diskfull_pending--; \
22483 #else
22484 #define SimulateIOErrorBenign(X)
22485 #define SimulateIOError(A)
22486 #define SimulateDiskfullError(A)
22487 #endif
22490 ** When testing, keep a count of the number of open files.
22492 #ifdef SQLITE_TEST
22493 SQLITE_API int sqlite3_open_file_count = 0;
22494 #define OpenCounter(X) sqlite3_open_file_count+=(X)
22495 #else
22496 #define OpenCounter(X)
22497 #endif
22499 #endif /* !defined(_OS_COMMON_H_) */
22501 /************** End of os_common.h *******************************************/
22502 /************** Continuing where we left off in os_os2.c *********************/
22504 /* Forward references */
22505 typedef struct os2File os2File; /* The file structure */
22506 typedef struct os2ShmNode os2ShmNode; /* A shared descritive memory node */
22507 typedef struct os2ShmLink os2ShmLink; /* A connection to shared-memory */
22510 ** The os2File structure is subclass of sqlite3_file specific for the OS/2
22511 ** protability layer.
22513 struct os2File {
22514 const sqlite3_io_methods *pMethod; /* Always the first entry */
22515 HFILE h; /* Handle for accessing the file */
22516 int flags; /* Flags provided to os2Open() */
22517 int locktype; /* Type of lock currently held on this file */
22518 int szChunk; /* Chunk size configured by FCNTL_CHUNK_SIZE */
22519 char *zFullPathCp; /* Full path name of this file */
22520 os2ShmLink *pShmLink; /* Instance of shared memory on this file */
22523 #define LOCK_TIMEOUT 10L /* the default locking timeout */
22526 ** Missing from some versions of the OS/2 toolkit -
22527 ** used to allocate from high memory if possible
22529 #ifndef OBJ_ANY
22530 # define OBJ_ANY 0x00000400
22531 #endif
22533 /*****************************************************************************
22534 ** The next group of routines implement the I/O methods specified
22535 ** by the sqlite3_io_methods object.
22536 ******************************************************************************/
22539 ** Close a file.
22541 static int os2Close( sqlite3_file *id ){
22542 APIRET rc;
22543 os2File *pFile = (os2File*)id;
22545 assert( id!=0 );
22546 OSTRACE(( "CLOSE %d (%s)\n", pFile->h, pFile->zFullPathCp ));
22548 rc = DosClose( pFile->h );
22550 if( pFile->flags & SQLITE_OPEN_DELETEONCLOSE )
22551 DosForceDelete( (PSZ)pFile->zFullPathCp );
22553 free( pFile->zFullPathCp );
22554 pFile->zFullPathCp = NULL;
22555 pFile->locktype = NO_LOCK;
22556 pFile->h = (HFILE)-1;
22557 pFile->flags = 0;
22559 OpenCounter( -1 );
22560 return rc == NO_ERROR ? SQLITE_OK : SQLITE_IOERR;
22564 ** Read data from a file into a buffer. Return SQLITE_OK if all
22565 ** bytes were read successfully and SQLITE_IOERR if anything goes
22566 ** wrong.
22568 static int os2Read(
22569 sqlite3_file *id, /* File to read from */
22570 void *pBuf, /* Write content into this buffer */
22571 int amt, /* Number of bytes to read */
22572 sqlite3_int64 offset /* Begin reading at this offset */
22574 ULONG fileLocation = 0L;
22575 ULONG got;
22576 os2File *pFile = (os2File*)id;
22577 assert( id!=0 );
22578 SimulateIOError( return SQLITE_IOERR_READ );
22579 OSTRACE(( "READ %d lock=%d\n", pFile->h, pFile->locktype ));
22580 if( DosSetFilePtr(pFile->h, offset, FILE_BEGIN, &fileLocation) != NO_ERROR ){
22581 return SQLITE_IOERR;
22583 if( DosRead( pFile->h, pBuf, amt, &got ) != NO_ERROR ){
22584 return SQLITE_IOERR_READ;
22586 if( got == (ULONG)amt )
22587 return SQLITE_OK;
22588 else {
22589 /* Unread portions of the input buffer must be zero-filled */
22590 memset(&((char*)pBuf)[got], 0, amt-got);
22591 return SQLITE_IOERR_SHORT_READ;
22596 ** Write data from a buffer into a file. Return SQLITE_OK on success
22597 ** or some other error code on failure.
22599 static int os2Write(
22600 sqlite3_file *id, /* File to write into */
22601 const void *pBuf, /* The bytes to be written */
22602 int amt, /* Number of bytes to write */
22603 sqlite3_int64 offset /* Offset into the file to begin writing at */
22605 ULONG fileLocation = 0L;
22606 APIRET rc = NO_ERROR;
22607 ULONG wrote;
22608 os2File *pFile = (os2File*)id;
22609 assert( id!=0 );
22610 SimulateIOError( return SQLITE_IOERR_WRITE );
22611 SimulateDiskfullError( return SQLITE_FULL );
22612 OSTRACE(( "WRITE %d lock=%d\n", pFile->h, pFile->locktype ));
22613 if( DosSetFilePtr(pFile->h, offset, FILE_BEGIN, &fileLocation) != NO_ERROR ){
22614 return SQLITE_IOERR;
22616 assert( amt>0 );
22617 while( amt > 0 &&
22618 ( rc = DosWrite( pFile->h, (PVOID)pBuf, amt, &wrote ) ) == NO_ERROR &&
22619 wrote > 0
22621 amt -= wrote;
22622 pBuf = &((char*)pBuf)[wrote];
22625 return ( rc != NO_ERROR || amt > (int)wrote ) ? SQLITE_FULL : SQLITE_OK;
22629 ** Truncate an open file to a specified size
22631 static int os2Truncate( sqlite3_file *id, i64 nByte ){
22632 APIRET rc;
22633 os2File *pFile = (os2File*)id;
22634 assert( id!=0 );
22635 OSTRACE(( "TRUNCATE %d %lld\n", pFile->h, nByte ));
22636 SimulateIOError( return SQLITE_IOERR_TRUNCATE );
22638 /* If the user has configured a chunk-size for this file, truncate the
22639 ** file so that it consists of an integer number of chunks (i.e. the
22640 ** actual file size after the operation may be larger than the requested
22641 ** size).
22643 if( pFile->szChunk ){
22644 nByte = ((nByte + pFile->szChunk - 1)/pFile->szChunk) * pFile->szChunk;
22647 rc = DosSetFileSize( pFile->h, nByte );
22648 return rc == NO_ERROR ? SQLITE_OK : SQLITE_IOERR_TRUNCATE;
22651 #ifdef SQLITE_TEST
22653 ** Count the number of fullsyncs and normal syncs. This is used to test
22654 ** that syncs and fullsyncs are occuring at the right times.
22656 SQLITE_API int sqlite3_sync_count = 0;
22657 SQLITE_API int sqlite3_fullsync_count = 0;
22658 #endif
22661 ** Make sure all writes to a particular file are committed to disk.
22663 static int os2Sync( sqlite3_file *id, int flags ){
22664 os2File *pFile = (os2File*)id;
22665 OSTRACE(( "SYNC %d lock=%d\n", pFile->h, pFile->locktype ));
22666 #ifdef SQLITE_TEST
22667 if( flags & SQLITE_SYNC_FULL){
22668 sqlite3_fullsync_count++;
22670 sqlite3_sync_count++;
22671 #endif
22672 /* If we compiled with the SQLITE_NO_SYNC flag, then syncing is a
22673 ** no-op
22675 #ifdef SQLITE_NO_SYNC
22676 UNUSED_PARAMETER(pFile);
22677 return SQLITE_OK;
22678 #else
22679 return DosResetBuffer( pFile->h ) == NO_ERROR ? SQLITE_OK : SQLITE_IOERR;
22680 #endif
22684 ** Determine the current size of a file in bytes
22686 static int os2FileSize( sqlite3_file *id, sqlite3_int64 *pSize ){
22687 APIRET rc = NO_ERROR;
22688 FILESTATUS3 fsts3FileInfo;
22689 memset(&fsts3FileInfo, 0, sizeof(fsts3FileInfo));
22690 assert( id!=0 );
22691 SimulateIOError( return SQLITE_IOERR_FSTAT );
22692 rc = DosQueryFileInfo( ((os2File*)id)->h, FIL_STANDARD, &fsts3FileInfo, sizeof(FILESTATUS3) );
22693 if( rc == NO_ERROR ){
22694 *pSize = fsts3FileInfo.cbFile;
22695 return SQLITE_OK;
22696 }else{
22697 return SQLITE_IOERR_FSTAT;
22702 ** Acquire a reader lock.
22704 static int getReadLock( os2File *pFile ){
22705 FILELOCK LockArea,
22706 UnlockArea;
22707 APIRET res;
22708 memset(&LockArea, 0, sizeof(LockArea));
22709 memset(&UnlockArea, 0, sizeof(UnlockArea));
22710 LockArea.lOffset = SHARED_FIRST;
22711 LockArea.lRange = SHARED_SIZE;
22712 UnlockArea.lOffset = 0L;
22713 UnlockArea.lRange = 0L;
22714 res = DosSetFileLocks( pFile->h, &UnlockArea, &LockArea, LOCK_TIMEOUT, 1L );
22715 OSTRACE(( "GETREADLOCK %d res=%d\n", pFile->h, res ));
22716 return res;
22720 ** Undo a readlock
22722 static int unlockReadLock( os2File *id ){
22723 FILELOCK LockArea,
22724 UnlockArea;
22725 APIRET res;
22726 memset(&LockArea, 0, sizeof(LockArea));
22727 memset(&UnlockArea, 0, sizeof(UnlockArea));
22728 LockArea.lOffset = 0L;
22729 LockArea.lRange = 0L;
22730 UnlockArea.lOffset = SHARED_FIRST;
22731 UnlockArea.lRange = SHARED_SIZE;
22732 res = DosSetFileLocks( id->h, &UnlockArea, &LockArea, LOCK_TIMEOUT, 1L );
22733 OSTRACE(( "UNLOCK-READLOCK file handle=%d res=%d?\n", id->h, res ));
22734 return res;
22738 ** Lock the file with the lock specified by parameter locktype - one
22739 ** of the following:
22741 ** (1) SHARED_LOCK
22742 ** (2) RESERVED_LOCK
22743 ** (3) PENDING_LOCK
22744 ** (4) EXCLUSIVE_LOCK
22746 ** Sometimes when requesting one lock state, additional lock states
22747 ** are inserted in between. The locking might fail on one of the later
22748 ** transitions leaving the lock state different from what it started but
22749 ** still short of its goal. The following chart shows the allowed
22750 ** transitions and the inserted intermediate states:
22752 ** UNLOCKED -> SHARED
22753 ** SHARED -> RESERVED
22754 ** SHARED -> (PENDING) -> EXCLUSIVE
22755 ** RESERVED -> (PENDING) -> EXCLUSIVE
22756 ** PENDING -> EXCLUSIVE
22758 ** This routine will only increase a lock. The os2Unlock() routine
22759 ** erases all locks at once and returns us immediately to locking level 0.
22760 ** It is not possible to lower the locking level one step at a time. You
22761 ** must go straight to locking level 0.
22763 static int os2Lock( sqlite3_file *id, int locktype ){
22764 int rc = SQLITE_OK; /* Return code from subroutines */
22765 APIRET res = NO_ERROR; /* Result of an OS/2 lock call */
22766 int newLocktype; /* Set pFile->locktype to this value before exiting */
22767 int gotPendingLock = 0;/* True if we acquired a PENDING lock this time */
22768 FILELOCK LockArea,
22769 UnlockArea;
22770 os2File *pFile = (os2File*)id;
22771 memset(&LockArea, 0, sizeof(LockArea));
22772 memset(&UnlockArea, 0, sizeof(UnlockArea));
22773 assert( pFile!=0 );
22774 OSTRACE(( "LOCK %d %d was %d\n", pFile->h, locktype, pFile->locktype ));
22776 /* If there is already a lock of this type or more restrictive on the
22777 ** os2File, do nothing. Don't use the end_lock: exit path, as
22778 ** sqlite3_mutex_enter() hasn't been called yet.
22780 if( pFile->locktype>=locktype ){
22781 OSTRACE(( "LOCK %d %d ok (already held)\n", pFile->h, locktype ));
22782 return SQLITE_OK;
22785 /* Make sure the locking sequence is correct
22787 assert( pFile->locktype!=NO_LOCK || locktype==SHARED_LOCK );
22788 assert( locktype!=PENDING_LOCK );
22789 assert( locktype!=RESERVED_LOCK || pFile->locktype==SHARED_LOCK );
22791 /* Lock the PENDING_LOCK byte if we need to acquire a PENDING lock or
22792 ** a SHARED lock. If we are acquiring a SHARED lock, the acquisition of
22793 ** the PENDING_LOCK byte is temporary.
22795 newLocktype = pFile->locktype;
22796 if( pFile->locktype==NO_LOCK
22797 || (locktype==EXCLUSIVE_LOCK && pFile->locktype==RESERVED_LOCK)
22799 LockArea.lOffset = PENDING_BYTE;
22800 LockArea.lRange = 1L;
22801 UnlockArea.lOffset = 0L;
22802 UnlockArea.lRange = 0L;
22804 /* wait longer than LOCK_TIMEOUT here not to have to try multiple times */
22805 res = DosSetFileLocks( pFile->h, &UnlockArea, &LockArea, 100L, 0L );
22806 if( res == NO_ERROR ){
22807 gotPendingLock = 1;
22808 OSTRACE(( "LOCK %d pending lock boolean set. res=%d\n", pFile->h, res ));
22812 /* Acquire a shared lock
22814 if( locktype==SHARED_LOCK && res == NO_ERROR ){
22815 assert( pFile->locktype==NO_LOCK );
22816 res = getReadLock(pFile);
22817 if( res == NO_ERROR ){
22818 newLocktype = SHARED_LOCK;
22820 OSTRACE(( "LOCK %d acquire shared lock. res=%d\n", pFile->h, res ));
22823 /* Acquire a RESERVED lock
22825 if( locktype==RESERVED_LOCK && res == NO_ERROR ){
22826 assert( pFile->locktype==SHARED_LOCK );
22827 LockArea.lOffset = RESERVED_BYTE;
22828 LockArea.lRange = 1L;
22829 UnlockArea.lOffset = 0L;
22830 UnlockArea.lRange = 0L;
22831 res = DosSetFileLocks( pFile->h, &UnlockArea, &LockArea, LOCK_TIMEOUT, 0L );
22832 if( res == NO_ERROR ){
22833 newLocktype = RESERVED_LOCK;
22835 OSTRACE(( "LOCK %d acquire reserved lock. res=%d\n", pFile->h, res ));
22838 /* Acquire a PENDING lock
22840 if( locktype==EXCLUSIVE_LOCK && res == NO_ERROR ){
22841 newLocktype = PENDING_LOCK;
22842 gotPendingLock = 0;
22843 OSTRACE(( "LOCK %d acquire pending lock. pending lock boolean unset.\n",
22844 pFile->h ));
22847 /* Acquire an EXCLUSIVE lock
22849 if( locktype==EXCLUSIVE_LOCK && res == NO_ERROR ){
22850 assert( pFile->locktype>=SHARED_LOCK );
22851 res = unlockReadLock(pFile);
22852 OSTRACE(( "unreadlock = %d\n", res ));
22853 LockArea.lOffset = SHARED_FIRST;
22854 LockArea.lRange = SHARED_SIZE;
22855 UnlockArea.lOffset = 0L;
22856 UnlockArea.lRange = 0L;
22857 res = DosSetFileLocks( pFile->h, &UnlockArea, &LockArea, LOCK_TIMEOUT, 0L );
22858 if( res == NO_ERROR ){
22859 newLocktype = EXCLUSIVE_LOCK;
22860 }else{
22861 OSTRACE(( "OS/2 error-code = %d\n", res ));
22862 getReadLock(pFile);
22864 OSTRACE(( "LOCK %d acquire exclusive lock. res=%d\n", pFile->h, res ));
22867 /* If we are holding a PENDING lock that ought to be released, then
22868 ** release it now.
22870 if( gotPendingLock && locktype==SHARED_LOCK ){
22871 int r;
22872 LockArea.lOffset = 0L;
22873 LockArea.lRange = 0L;
22874 UnlockArea.lOffset = PENDING_BYTE;
22875 UnlockArea.lRange = 1L;
22876 r = DosSetFileLocks( pFile->h, &UnlockArea, &LockArea, LOCK_TIMEOUT, 0L );
22877 OSTRACE(( "LOCK %d unlocking pending/is shared. r=%d\n", pFile->h, r ));
22880 /* Update the state of the lock has held in the file descriptor then
22881 ** return the appropriate result code.
22883 if( res == NO_ERROR ){
22884 rc = SQLITE_OK;
22885 }else{
22886 OSTRACE(( "LOCK FAILED %d trying for %d but got %d\n", pFile->h,
22887 locktype, newLocktype ));
22888 rc = SQLITE_BUSY;
22890 pFile->locktype = newLocktype;
22891 OSTRACE(( "LOCK %d now %d\n", pFile->h, pFile->locktype ));
22892 return rc;
22896 ** This routine checks if there is a RESERVED lock held on the specified
22897 ** file by this or any other process. If such a lock is held, return
22898 ** non-zero, otherwise zero.
22900 static int os2CheckReservedLock( sqlite3_file *id, int *pOut ){
22901 int r = 0;
22902 os2File *pFile = (os2File*)id;
22903 assert( pFile!=0 );
22904 if( pFile->locktype>=RESERVED_LOCK ){
22905 r = 1;
22906 OSTRACE(( "TEST WR-LOCK %d %d (local)\n", pFile->h, r ));
22907 }else{
22908 FILELOCK LockArea,
22909 UnlockArea;
22910 APIRET rc = NO_ERROR;
22911 memset(&LockArea, 0, sizeof(LockArea));
22912 memset(&UnlockArea, 0, sizeof(UnlockArea));
22913 LockArea.lOffset = RESERVED_BYTE;
22914 LockArea.lRange = 1L;
22915 UnlockArea.lOffset = 0L;
22916 UnlockArea.lRange = 0L;
22917 rc = DosSetFileLocks( pFile->h, &UnlockArea, &LockArea, LOCK_TIMEOUT, 0L );
22918 OSTRACE(( "TEST WR-LOCK %d lock reserved byte rc=%d\n", pFile->h, rc ));
22919 if( rc == NO_ERROR ){
22920 APIRET rcu = NO_ERROR; /* return code for unlocking */
22921 LockArea.lOffset = 0L;
22922 LockArea.lRange = 0L;
22923 UnlockArea.lOffset = RESERVED_BYTE;
22924 UnlockArea.lRange = 1L;
22925 rcu = DosSetFileLocks( pFile->h, &UnlockArea, &LockArea, LOCK_TIMEOUT, 0L );
22926 OSTRACE(( "TEST WR-LOCK %d unlock reserved byte r=%d\n", pFile->h, rcu ));
22928 r = !(rc == NO_ERROR);
22929 OSTRACE(( "TEST WR-LOCK %d %d (remote)\n", pFile->h, r ));
22931 *pOut = r;
22932 return SQLITE_OK;
22936 ** Lower the locking level on file descriptor id to locktype. locktype
22937 ** must be either NO_LOCK or SHARED_LOCK.
22939 ** If the locking level of the file descriptor is already at or below
22940 ** the requested locking level, this routine is a no-op.
22942 ** It is not possible for this routine to fail if the second argument
22943 ** is NO_LOCK. If the second argument is SHARED_LOCK then this routine
22944 ** might return SQLITE_IOERR;
22946 static int os2Unlock( sqlite3_file *id, int locktype ){
22947 int type;
22948 os2File *pFile = (os2File*)id;
22949 APIRET rc = SQLITE_OK;
22950 APIRET res = NO_ERROR;
22951 FILELOCK LockArea,
22952 UnlockArea;
22953 memset(&LockArea, 0, sizeof(LockArea));
22954 memset(&UnlockArea, 0, sizeof(UnlockArea));
22955 assert( pFile!=0 );
22956 assert( locktype<=SHARED_LOCK );
22957 OSTRACE(( "UNLOCK %d to %d was %d\n", pFile->h, locktype, pFile->locktype ));
22958 type = pFile->locktype;
22959 if( type>=EXCLUSIVE_LOCK ){
22960 LockArea.lOffset = 0L;
22961 LockArea.lRange = 0L;
22962 UnlockArea.lOffset = SHARED_FIRST;
22963 UnlockArea.lRange = SHARED_SIZE;
22964 res = DosSetFileLocks( pFile->h, &UnlockArea, &LockArea, LOCK_TIMEOUT, 0L );
22965 OSTRACE(( "UNLOCK %d exclusive lock res=%d\n", pFile->h, res ));
22966 if( locktype==SHARED_LOCK && getReadLock(pFile) != NO_ERROR ){
22967 /* This should never happen. We should always be able to
22968 ** reacquire the read lock */
22969 OSTRACE(( "UNLOCK %d to %d getReadLock() failed\n", pFile->h, locktype ));
22970 rc = SQLITE_IOERR_UNLOCK;
22973 if( type>=RESERVED_LOCK ){
22974 LockArea.lOffset = 0L;
22975 LockArea.lRange = 0L;
22976 UnlockArea.lOffset = RESERVED_BYTE;
22977 UnlockArea.lRange = 1L;
22978 res = DosSetFileLocks( pFile->h, &UnlockArea, &LockArea, LOCK_TIMEOUT, 0L );
22979 OSTRACE(( "UNLOCK %d reserved res=%d\n", pFile->h, res ));
22981 if( locktype==NO_LOCK && type>=SHARED_LOCK ){
22982 res = unlockReadLock(pFile);
22983 OSTRACE(( "UNLOCK %d is %d want %d res=%d\n",
22984 pFile->h, type, locktype, res ));
22986 if( type>=PENDING_LOCK ){
22987 LockArea.lOffset = 0L;
22988 LockArea.lRange = 0L;
22989 UnlockArea.lOffset = PENDING_BYTE;
22990 UnlockArea.lRange = 1L;
22991 res = DosSetFileLocks( pFile->h, &UnlockArea, &LockArea, LOCK_TIMEOUT, 0L );
22992 OSTRACE(( "UNLOCK %d pending res=%d\n", pFile->h, res ));
22994 pFile->locktype = locktype;
22995 OSTRACE(( "UNLOCK %d now %d\n", pFile->h, pFile->locktype ));
22996 return rc;
23000 ** Control and query of the open file handle.
23002 static int os2FileControl(sqlite3_file *id, int op, void *pArg){
23003 switch( op ){
23004 case SQLITE_FCNTL_LOCKSTATE: {
23005 *(int*)pArg = ((os2File*)id)->locktype;
23006 OSTRACE(( "FCNTL_LOCKSTATE %d lock=%d\n",
23007 ((os2File*)id)->h, ((os2File*)id)->locktype ));
23008 return SQLITE_OK;
23010 case SQLITE_FCNTL_CHUNK_SIZE: {
23011 ((os2File*)id)->szChunk = *(int*)pArg;
23012 return SQLITE_OK;
23014 case SQLITE_FCNTL_SIZE_HINT: {
23015 sqlite3_int64 sz = *(sqlite3_int64*)pArg;
23016 SimulateIOErrorBenign(1);
23017 os2Truncate(id, sz);
23018 SimulateIOErrorBenign(0);
23019 return SQLITE_OK;
23021 case SQLITE_FCNTL_SYNC_OMITTED: {
23022 return SQLITE_OK;
23025 return SQLITE_NOTFOUND;
23029 ** Return the sector size in bytes of the underlying block device for
23030 ** the specified file. This is almost always 512 bytes, but may be
23031 ** larger for some devices.
23033 ** SQLite code assumes this function cannot fail. It also assumes that
23034 ** if two files are created in the same file-system directory (i.e.
23035 ** a database and its journal file) that the sector size will be the
23036 ** same for both.
23038 static int os2SectorSize(sqlite3_file *id){
23039 UNUSED_PARAMETER(id);
23040 return SQLITE_DEFAULT_SECTOR_SIZE;
23044 ** Return a vector of device characteristics.
23046 static int os2DeviceCharacteristics(sqlite3_file *id){
23047 UNUSED_PARAMETER(id);
23048 return SQLITE_IOCAP_UNDELETABLE_WHEN_OPEN;
23053 ** Character set conversion objects used by conversion routines.
23055 static UconvObject ucUtf8 = NULL; /* convert between UTF-8 and UCS-2 */
23056 static UconvObject uclCp = NULL; /* convert between local codepage and UCS-2 */
23059 ** Helper function to initialize the conversion objects from and to UTF-8.
23061 static void initUconvObjects( void ){
23062 if( UniCreateUconvObject( UTF_8, &ucUtf8 ) != ULS_SUCCESS )
23063 ucUtf8 = NULL;
23064 if ( UniCreateUconvObject( (UniChar *)L"@path=yes", &uclCp ) != ULS_SUCCESS )
23065 uclCp = NULL;
23069 ** Helper function to free the conversion objects from and to UTF-8.
23071 static void freeUconvObjects( void ){
23072 if ( ucUtf8 )
23073 UniFreeUconvObject( ucUtf8 );
23074 if ( uclCp )
23075 UniFreeUconvObject( uclCp );
23076 ucUtf8 = NULL;
23077 uclCp = NULL;
23081 ** Helper function to convert UTF-8 filenames to local OS/2 codepage.
23082 ** The two-step process: first convert the incoming UTF-8 string
23083 ** into UCS-2 and then from UCS-2 to the current codepage.
23084 ** The returned char pointer has to be freed.
23086 static char *convertUtf8PathToCp( const char *in ){
23087 UniChar tempPath[CCHMAXPATH];
23088 char *out = (char *)calloc( CCHMAXPATH, 1 );
23090 if( !out )
23091 return NULL;
23093 if( !ucUtf8 || !uclCp )
23094 initUconvObjects();
23096 /* determine string for the conversion of UTF-8 which is CP1208 */
23097 if( UniStrToUcs( ucUtf8, tempPath, (char *)in, CCHMAXPATH ) != ULS_SUCCESS )
23098 return out; /* if conversion fails, return the empty string */
23100 /* conversion for current codepage which can be used for paths */
23101 UniStrFromUcs( uclCp, out, tempPath, CCHMAXPATH );
23103 return out;
23107 ** Helper function to convert filenames from local codepage to UTF-8.
23108 ** The two-step process: first convert the incoming codepage-specific
23109 ** string into UCS-2 and then from UCS-2 to the codepage of UTF-8.
23110 ** The returned char pointer has to be freed.
23112 ** This function is non-static to be able to use this in shell.c and
23113 ** similar applications that take command line arguments.
23115 char *convertCpPathToUtf8( const char *in ){
23116 UniChar tempPath[CCHMAXPATH];
23117 char *out = (char *)calloc( CCHMAXPATH, 1 );
23119 if( !out )
23120 return NULL;
23122 if( !ucUtf8 || !uclCp )
23123 initUconvObjects();
23125 /* conversion for current codepage which can be used for paths */
23126 if( UniStrToUcs( uclCp, tempPath, (char *)in, CCHMAXPATH ) != ULS_SUCCESS )
23127 return out; /* if conversion fails, return the empty string */
23129 /* determine string for the conversion of UTF-8 which is CP1208 */
23130 UniStrFromUcs( ucUtf8, out, tempPath, CCHMAXPATH );
23132 return out;
23136 #ifndef SQLITE_OMIT_WAL
23139 ** Use main database file for interprocess locking. If un-defined
23140 ** a separate file is created for this purpose. The file will be
23141 ** used only to set file locks. There will be no data written to it.
23143 #define SQLITE_OS2_NO_WAL_LOCK_FILE
23145 #if 0
23146 static void _ERR_TRACE( const char *fmt, ... ) {
23147 va_list ap;
23148 va_start(ap, fmt);
23149 vfprintf(stderr, fmt, ap);
23150 fflush(stderr);
23152 #define ERR_TRACE(rc, msg) \
23153 if( (rc) != SQLITE_OK ) _ERR_TRACE msg;
23154 #else
23155 #define ERR_TRACE(rc, msg)
23156 #endif
23159 ** Helper functions to obtain and relinquish the global mutex. The
23160 ** global mutex is used to protect os2ShmNodeList.
23162 ** Function os2ShmMutexHeld() is used to assert() that the global mutex
23163 ** is held when required. This function is only used as part of assert()
23164 ** statements. e.g.
23166 ** os2ShmEnterMutex()
23167 ** assert( os2ShmMutexHeld() );
23168 ** os2ShmLeaveMutex()
23170 static void os2ShmEnterMutex(void){
23171 sqlite3_mutex_enter(sqlite3MutexAlloc(SQLITE_MUTEX_STATIC_MASTER));
23173 static void os2ShmLeaveMutex(void){
23174 sqlite3_mutex_leave(sqlite3MutexAlloc(SQLITE_MUTEX_STATIC_MASTER));
23176 #ifdef SQLITE_DEBUG
23177 static int os2ShmMutexHeld(void) {
23178 return sqlite3_mutex_held(sqlite3MutexAlloc(SQLITE_MUTEX_STATIC_MASTER));
23180 int GetCurrentProcessId(void) {
23181 PPIB pib;
23182 DosGetInfoBlocks(NULL, &pib);
23183 return (int)pib->pib_ulpid;
23185 #endif
23188 ** Object used to represent a the shared memory area for a single log file.
23189 ** When multiple threads all reference the same log-summary, each thread has
23190 ** its own os2File object, but they all point to a single instance of this
23191 ** object. In other words, each log-summary is opened only once per process.
23193 ** os2ShmMutexHeld() must be true when creating or destroying
23194 ** this object or while reading or writing the following fields:
23196 ** nRef
23197 ** pNext
23199 ** The following fields are read-only after the object is created:
23201 ** szRegion
23202 ** hLockFile
23203 ** shmBaseName
23205 ** Either os2ShmNode.mutex must be held or os2ShmNode.nRef==0 and
23206 ** os2ShmMutexHeld() is true when reading or writing any other field
23207 ** in this structure.
23210 struct os2ShmNode {
23211 sqlite3_mutex *mutex; /* Mutex to access this object */
23212 os2ShmNode *pNext; /* Next in list of all os2ShmNode objects */
23214 int szRegion; /* Size of shared-memory regions */
23216 int nRegion; /* Size of array apRegion */
23217 void **apRegion; /* Array of pointers to shared-memory regions */
23219 int nRef; /* Number of os2ShmLink objects pointing to this */
23220 os2ShmLink *pFirst; /* First os2ShmLink object pointing to this */
23222 HFILE hLockFile; /* File used for inter-process memory locking */
23223 char shmBaseName[1]; /* Name of the memory object !!! must last !!! */
23228 ** Structure used internally by this VFS to record the state of an
23229 ** open shared memory connection.
23231 ** The following fields are initialized when this object is created and
23232 ** are read-only thereafter:
23234 ** os2Shm.pShmNode
23235 ** os2Shm.id
23237 ** All other fields are read/write. The os2Shm.pShmNode->mutex must be held
23238 ** while accessing any read/write fields.
23240 struct os2ShmLink {
23241 os2ShmNode *pShmNode; /* The underlying os2ShmNode object */
23242 os2ShmLink *pNext; /* Next os2Shm with the same os2ShmNode */
23243 u32 sharedMask; /* Mask of shared locks held */
23244 u32 exclMask; /* Mask of exclusive locks held */
23245 #ifdef SQLITE_DEBUG
23246 u8 id; /* Id of this connection with its os2ShmNode */
23247 #endif
23252 ** A global list of all os2ShmNode objects.
23254 ** The os2ShmMutexHeld() must be true while reading or writing this list.
23256 static os2ShmNode *os2ShmNodeList = NULL;
23259 ** Constants used for locking
23261 #ifdef SQLITE_OS2_NO_WAL_LOCK_FILE
23262 #define OS2_SHM_BASE (PENDING_BYTE + 0x10000) /* first lock byte */
23263 #else
23264 #define OS2_SHM_BASE ((22+SQLITE_SHM_NLOCK)*4) /* first lock byte */
23265 #endif
23267 #define OS2_SHM_DMS (OS2_SHM_BASE+SQLITE_SHM_NLOCK) /* deadman switch */
23270 ** Apply advisory locks for all n bytes beginning at ofst.
23272 #define _SHM_UNLCK 1 /* no lock */
23273 #define _SHM_RDLCK 2 /* shared lock, no wait */
23274 #define _SHM_WRLCK 3 /* exlusive lock, no wait */
23275 #define _SHM_WRLCK_WAIT 4 /* exclusive lock, wait */
23276 static int os2ShmSystemLock(
23277 os2ShmNode *pNode, /* Apply locks to this open shared-memory segment */
23278 int lockType, /* _SHM_UNLCK, _SHM_RDLCK, _SHM_WRLCK or _SHM_WRLCK_WAIT */
23279 int ofst, /* Offset to first byte to be locked/unlocked */
23280 int nByte /* Number of bytes to lock or unlock */
23282 APIRET rc;
23283 FILELOCK area;
23284 ULONG mode, timeout;
23286 /* Access to the os2ShmNode object is serialized by the caller */
23287 assert( sqlite3_mutex_held(pNode->mutex) || pNode->nRef==0 );
23289 mode = 1; /* shared lock */
23290 timeout = 0; /* no wait */
23291 area.lOffset = ofst;
23292 area.lRange = nByte;
23294 switch( lockType ) {
23295 case _SHM_WRLCK_WAIT:
23296 timeout = (ULONG)-1; /* wait forever */
23297 case _SHM_WRLCK:
23298 mode = 0; /* exclusive lock */
23299 case _SHM_RDLCK:
23300 rc = DosSetFileLocks(pNode->hLockFile,
23301 NULL, &area, timeout, mode);
23302 break;
23303 /* case _SHM_UNLCK: */
23304 default:
23305 rc = DosSetFileLocks(pNode->hLockFile,
23306 &area, NULL, 0, 0);
23307 break;
23310 OSTRACE(("SHM-LOCK %d %s %s 0x%08lx\n",
23311 pNode->hLockFile,
23312 rc==SQLITE_OK ? "ok" : "failed",
23313 lockType==_SHM_UNLCK ? "Unlock" : "Lock",
23314 rc));
23316 ERR_TRACE(rc, ("os2ShmSystemLock: %d %s\n", rc, pNode->shmBaseName))
23318 return ( rc == 0 ) ? SQLITE_OK : SQLITE_BUSY;
23322 ** Find an os2ShmNode in global list or allocate a new one, if not found.
23324 ** This is not a VFS shared-memory method; it is a utility function called
23325 ** by VFS shared-memory methods.
23327 static int os2OpenSharedMemory( os2File *fd, int szRegion ) {
23328 os2ShmLink *pLink;
23329 os2ShmNode *pNode;
23330 int cbShmName, rc = SQLITE_OK;
23331 char shmName[CCHMAXPATH + 30];
23332 #ifndef SQLITE_OS2_NO_WAL_LOCK_FILE
23333 ULONG action;
23334 #endif
23336 /* We need some additional space at the end to append the region number */
23337 cbShmName = sprintf(shmName, "\\SHAREMEM\\%s", fd->zFullPathCp );
23338 if( cbShmName >= CCHMAXPATH-8 )
23339 return SQLITE_IOERR_SHMOPEN;
23341 /* Replace colon in file name to form a valid shared memory name */
23342 shmName[10+1] = '!';
23344 /* Allocate link object (we free it later in case of failure) */
23345 pLink = sqlite3_malloc( sizeof(*pLink) );
23346 if( !pLink )
23347 return SQLITE_NOMEM;
23349 /* Access node list */
23350 os2ShmEnterMutex();
23352 /* Find node by it's shared memory base name */
23353 for( pNode = os2ShmNodeList;
23354 pNode && stricmp(shmName, pNode->shmBaseName) != 0;
23355 pNode = pNode->pNext ) ;
23357 /* Not found: allocate a new node */
23358 if( !pNode ) {
23359 pNode = sqlite3_malloc( sizeof(*pNode) + cbShmName );
23360 if( pNode ) {
23361 memset(pNode, 0, sizeof(*pNode) );
23362 pNode->szRegion = szRegion;
23363 pNode->hLockFile = (HFILE)-1;
23364 strcpy(pNode->shmBaseName, shmName);
23366 #ifdef SQLITE_OS2_NO_WAL_LOCK_FILE
23367 if( DosDupHandle(fd->h, &pNode->hLockFile) != 0 ) {
23368 #else
23369 sprintf(shmName, "%s-lck", fd->zFullPathCp);
23370 if( DosOpen((PSZ)shmName, &pNode->hLockFile, &action, 0, FILE_NORMAL,
23371 OPEN_ACTION_OPEN_IF_EXISTS | OPEN_ACTION_CREATE_IF_NEW,
23372 OPEN_ACCESS_READWRITE | OPEN_SHARE_DENYNONE |
23373 OPEN_FLAGS_NOINHERIT | OPEN_FLAGS_FAIL_ON_ERROR,
23374 NULL) != 0 ) {
23375 #endif
23376 sqlite3_free(pNode);
23377 rc = SQLITE_IOERR;
23378 } else {
23379 pNode->mutex = sqlite3_mutex_alloc(SQLITE_MUTEX_FAST);
23380 if( !pNode->mutex ) {
23381 sqlite3_free(pNode);
23382 rc = SQLITE_NOMEM;
23385 } else {
23386 rc = SQLITE_NOMEM;
23389 if( rc == SQLITE_OK ) {
23390 pNode->pNext = os2ShmNodeList;
23391 os2ShmNodeList = pNode;
23392 } else {
23393 pNode = NULL;
23395 } else if( pNode->szRegion != szRegion ) {
23396 rc = SQLITE_IOERR_SHMSIZE;
23397 pNode = NULL;
23400 if( pNode ) {
23401 sqlite3_mutex_enter(pNode->mutex);
23403 memset(pLink, 0, sizeof(*pLink));
23405 pLink->pShmNode = pNode;
23406 pLink->pNext = pNode->pFirst;
23407 pNode->pFirst = pLink;
23408 pNode->nRef++;
23410 fd->pShmLink = pLink;
23412 sqlite3_mutex_leave(pNode->mutex);
23414 } else {
23415 /* Error occured. Free our link object. */
23416 sqlite3_free(pLink);
23419 os2ShmLeaveMutex();
23421 ERR_TRACE(rc, ("os2OpenSharedMemory: %d %s\n", rc, fd->zFullPathCp))
23423 return rc;
23427 ** Purge the os2ShmNodeList list of all entries with nRef==0.
23429 ** This is not a VFS shared-memory method; it is a utility function called
23430 ** by VFS shared-memory methods.
23432 static void os2PurgeShmNodes( int deleteFlag ) {
23433 os2ShmNode *pNode;
23434 os2ShmNode **ppNode;
23436 os2ShmEnterMutex();
23438 ppNode = &os2ShmNodeList;
23440 while( *ppNode ) {
23441 pNode = *ppNode;
23443 if( pNode->nRef == 0 ) {
23444 *ppNode = pNode->pNext;
23446 if( pNode->apRegion ) {
23447 /* Prevent other processes from resizing the shared memory */
23448 os2ShmSystemLock(pNode, _SHM_WRLCK_WAIT, OS2_SHM_DMS, 1);
23450 while( pNode->nRegion-- ) {
23451 #ifdef SQLITE_DEBUG
23452 int rc =
23453 #endif
23454 DosFreeMem(pNode->apRegion[pNode->nRegion]);
23456 OSTRACE(("SHM-PURGE pid-%d unmap region=%d %s\n",
23457 (int)GetCurrentProcessId(), pNode->nRegion,
23458 rc == 0 ? "ok" : "failed"));
23461 /* Allow other processes to resize the shared memory */
23462 os2ShmSystemLock(pNode, _SHM_UNLCK, OS2_SHM_DMS, 1);
23464 sqlite3_free(pNode->apRegion);
23467 DosClose(pNode->hLockFile);
23469 #ifndef SQLITE_OS2_NO_WAL_LOCK_FILE
23470 if( deleteFlag ) {
23471 char fileName[CCHMAXPATH];
23472 /* Skip "\\SHAREMEM\\" */
23473 sprintf(fileName, "%s-lck", pNode->shmBaseName + 10);
23474 /* restore colon */
23475 fileName[1] = ':';
23477 DosForceDelete(fileName);
23479 #endif
23481 sqlite3_mutex_free(pNode->mutex);
23483 sqlite3_free(pNode);
23485 } else {
23486 ppNode = &pNode->pNext;
23490 os2ShmLeaveMutex();
23494 ** This function is called to obtain a pointer to region iRegion of the
23495 ** shared-memory associated with the database file id. Shared-memory regions
23496 ** are numbered starting from zero. Each shared-memory region is szRegion
23497 ** bytes in size.
23499 ** If an error occurs, an error code is returned and *pp is set to NULL.
23501 ** Otherwise, if the bExtend parameter is 0 and the requested shared-memory
23502 ** region has not been allocated (by any client, including one running in a
23503 ** separate process), then *pp is set to NULL and SQLITE_OK returned. If
23504 ** bExtend is non-zero and the requested shared-memory region has not yet
23505 ** been allocated, it is allocated by this function.
23507 ** If the shared-memory region has already been allocated or is allocated by
23508 ** this call as described above, then it is mapped into this processes
23509 ** address space (if it is not already), *pp is set to point to the mapped
23510 ** memory and SQLITE_OK returned.
23512 static int os2ShmMap(
23513 sqlite3_file *id, /* Handle open on database file */
23514 int iRegion, /* Region to retrieve */
23515 int szRegion, /* Size of regions */
23516 int bExtend, /* True to extend block if necessary */
23517 void volatile **pp /* OUT: Mapped memory */
23519 PVOID pvTemp;
23520 void **apRegion;
23521 os2ShmNode *pNode;
23522 int n, rc = SQLITE_OK;
23523 char shmName[CCHMAXPATH];
23524 os2File *pFile = (os2File*)id;
23526 *pp = NULL;
23528 if( !pFile->pShmLink )
23529 rc = os2OpenSharedMemory( pFile, szRegion );
23531 if( rc == SQLITE_OK ) {
23532 pNode = pFile->pShmLink->pShmNode ;
23534 sqlite3_mutex_enter(pNode->mutex);
23536 assert( szRegion==pNode->szRegion );
23538 /* Unmapped region ? */
23539 if( iRegion >= pNode->nRegion ) {
23540 /* Prevent other processes from resizing the shared memory */
23541 os2ShmSystemLock(pNode, _SHM_WRLCK_WAIT, OS2_SHM_DMS, 1);
23543 apRegion = sqlite3_realloc(
23544 pNode->apRegion, (iRegion + 1) * sizeof(apRegion[0]));
23546 if( apRegion ) {
23547 pNode->apRegion = apRegion;
23549 while( pNode->nRegion <= iRegion ) {
23550 sprintf(shmName, "%s-%u",
23551 pNode->shmBaseName, pNode->nRegion);
23553 if( DosGetNamedSharedMem(&pvTemp, (PSZ)shmName,
23554 PAG_READ | PAG_WRITE) != NO_ERROR ) {
23555 if( !bExtend )
23556 break;
23558 if( DosAllocSharedMem(&pvTemp, (PSZ)shmName, szRegion,
23559 PAG_READ | PAG_WRITE | PAG_COMMIT | OBJ_ANY) != NO_ERROR &&
23560 DosAllocSharedMem(&pvTemp, (PSZ)shmName, szRegion,
23561 PAG_READ | PAG_WRITE | PAG_COMMIT) != NO_ERROR ) {
23562 rc = SQLITE_NOMEM;
23563 break;
23567 apRegion[pNode->nRegion++] = pvTemp;
23570 /* zero out remaining entries */
23571 for( n = pNode->nRegion; n <= iRegion; n++ )
23572 pNode->apRegion[n] = NULL;
23574 /* Return this region (maybe zero) */
23575 *pp = pNode->apRegion[iRegion];
23576 } else {
23577 rc = SQLITE_NOMEM;
23580 /* Allow other processes to resize the shared memory */
23581 os2ShmSystemLock(pNode, _SHM_UNLCK, OS2_SHM_DMS, 1);
23583 } else {
23584 /* Region has been mapped previously */
23585 *pp = pNode->apRegion[iRegion];
23588 sqlite3_mutex_leave(pNode->mutex);
23591 ERR_TRACE(rc, ("os2ShmMap: %s iRgn = %d, szRgn = %d, bExt = %d : %d\n",
23592 pFile->zFullPathCp, iRegion, szRegion, bExtend, rc))
23594 return rc;
23598 ** Close a connection to shared-memory. Delete the underlying
23599 ** storage if deleteFlag is true.
23601 ** If there is no shared memory associated with the connection then this
23602 ** routine is a harmless no-op.
23604 static int os2ShmUnmap(
23605 sqlite3_file *id, /* The underlying database file */
23606 int deleteFlag /* Delete shared-memory if true */
23608 os2File *pFile = (os2File*)id;
23609 os2ShmLink *pLink = pFile->pShmLink;
23611 if( pLink ) {
23612 int nRef = -1;
23613 os2ShmLink **ppLink;
23614 os2ShmNode *pNode = pLink->pShmNode;
23616 sqlite3_mutex_enter(pNode->mutex);
23618 for( ppLink = &pNode->pFirst;
23619 *ppLink && *ppLink != pLink;
23620 ppLink = &(*ppLink)->pNext ) ;
23622 assert(*ppLink);
23624 if( *ppLink ) {
23625 *ppLink = pLink->pNext;
23626 nRef = --pNode->nRef;
23627 } else {
23628 ERR_TRACE(1, ("os2ShmUnmap: link not found ! %s\n",
23629 pNode->shmBaseName))
23632 pFile->pShmLink = NULL;
23633 sqlite3_free(pLink);
23635 sqlite3_mutex_leave(pNode->mutex);
23637 if( nRef == 0 )
23638 os2PurgeShmNodes( deleteFlag );
23641 return SQLITE_OK;
23645 ** Change the lock state for a shared-memory segment.
23647 ** Note that the relationship between SHAREd and EXCLUSIVE locks is a little
23648 ** different here than in posix. In xShmLock(), one can go from unlocked
23649 ** to shared and back or from unlocked to exclusive and back. But one may
23650 ** not go from shared to exclusive or from exclusive to shared.
23652 static int os2ShmLock(
23653 sqlite3_file *id, /* Database file holding the shared memory */
23654 int ofst, /* First lock to acquire or release */
23655 int n, /* Number of locks to acquire or release */
23656 int flags /* What to do with the lock */
23658 u32 mask; /* Mask of locks to take or release */
23659 int rc = SQLITE_OK; /* Result code */
23660 os2File *pFile = (os2File*)id;
23661 os2ShmLink *p = pFile->pShmLink; /* The shared memory being locked */
23662 os2ShmLink *pX; /* For looping over all siblings */
23663 os2ShmNode *pShmNode = p->pShmNode; /* Our node */
23665 assert( ofst>=0 && ofst+n<=SQLITE_SHM_NLOCK );
23666 assert( n>=1 );
23667 assert( flags==(SQLITE_SHM_LOCK | SQLITE_SHM_SHARED)
23668 || flags==(SQLITE_SHM_LOCK | SQLITE_SHM_EXCLUSIVE)
23669 || flags==(SQLITE_SHM_UNLOCK | SQLITE_SHM_SHARED)
23670 || flags==(SQLITE_SHM_UNLOCK | SQLITE_SHM_EXCLUSIVE) );
23671 assert( n==1 || (flags & SQLITE_SHM_EXCLUSIVE)!=0 );
23673 mask = (u32)((1U<<(ofst+n)) - (1U<<ofst));
23674 assert( n>1 || mask==(1<<ofst) );
23677 sqlite3_mutex_enter(pShmNode->mutex);
23679 if( flags & SQLITE_SHM_UNLOCK ){
23680 u32 allMask = 0; /* Mask of locks held by siblings */
23682 /* See if any siblings hold this same lock */
23683 for(pX=pShmNode->pFirst; pX; pX=pX->pNext){
23684 if( pX==p ) continue;
23685 assert( (pX->exclMask & (p->exclMask|p->sharedMask))==0 );
23686 allMask |= pX->sharedMask;
23689 /* Unlock the system-level locks */
23690 if( (mask & allMask)==0 ){
23691 rc = os2ShmSystemLock(pShmNode, _SHM_UNLCK, ofst+OS2_SHM_BASE, n);
23692 }else{
23693 rc = SQLITE_OK;
23696 /* Undo the local locks */
23697 if( rc==SQLITE_OK ){
23698 p->exclMask &= ~mask;
23699 p->sharedMask &= ~mask;
23701 }else if( flags & SQLITE_SHM_SHARED ){
23702 u32 allShared = 0; /* Union of locks held by connections other than "p" */
23704 /* Find out which shared locks are already held by sibling connections.
23705 ** If any sibling already holds an exclusive lock, go ahead and return
23706 ** SQLITE_BUSY.
23708 for(pX=pShmNode->pFirst; pX; pX=pX->pNext){
23709 if( (pX->exclMask & mask)!=0 ){
23710 rc = SQLITE_BUSY;
23711 break;
23713 allShared |= pX->sharedMask;
23716 /* Get shared locks at the system level, if necessary */
23717 if( rc==SQLITE_OK ){
23718 if( (allShared & mask)==0 ){
23719 rc = os2ShmSystemLock(pShmNode, _SHM_RDLCK, ofst+OS2_SHM_BASE, n);
23720 }else{
23721 rc = SQLITE_OK;
23725 /* Get the local shared locks */
23726 if( rc==SQLITE_OK ){
23727 p->sharedMask |= mask;
23729 }else{
23730 /* Make sure no sibling connections hold locks that will block this
23731 ** lock. If any do, return SQLITE_BUSY right away.
23733 for(pX=pShmNode->pFirst; pX; pX=pX->pNext){
23734 if( (pX->exclMask & mask)!=0 || (pX->sharedMask & mask)!=0 ){
23735 rc = SQLITE_BUSY;
23736 break;
23740 /* Get the exclusive locks at the system level. Then if successful
23741 ** also mark the local connection as being locked.
23743 if( rc==SQLITE_OK ){
23744 rc = os2ShmSystemLock(pShmNode, _SHM_WRLCK, ofst+OS2_SHM_BASE, n);
23745 if( rc==SQLITE_OK ){
23746 assert( (p->sharedMask & mask)==0 );
23747 p->exclMask |= mask;
23752 sqlite3_mutex_leave(pShmNode->mutex);
23754 OSTRACE(("SHM-LOCK shmid-%d, pid-%d got %03x,%03x %s\n",
23755 p->id, (int)GetCurrentProcessId(), p->sharedMask, p->exclMask,
23756 rc ? "failed" : "ok"));
23758 ERR_TRACE(rc, ("os2ShmLock: ofst = %d, n = %d, flags = 0x%x -> %d \n",
23759 ofst, n, flags, rc))
23761 return rc;
23765 ** Implement a memory barrier or memory fence on shared memory.
23767 ** All loads and stores begun before the barrier must complete before
23768 ** any load or store begun after the barrier.
23770 static void os2ShmBarrier(
23771 sqlite3_file *id /* Database file holding the shared memory */
23773 UNUSED_PARAMETER(id);
23774 os2ShmEnterMutex();
23775 os2ShmLeaveMutex();
23778 #else
23779 # define os2ShmMap 0
23780 # define os2ShmLock 0
23781 # define os2ShmBarrier 0
23782 # define os2ShmUnmap 0
23783 #endif /* #ifndef SQLITE_OMIT_WAL */
23787 ** This vector defines all the methods that can operate on an
23788 ** sqlite3_file for os2.
23790 static const sqlite3_io_methods os2IoMethod = {
23791 2, /* iVersion */
23792 os2Close, /* xClose */
23793 os2Read, /* xRead */
23794 os2Write, /* xWrite */
23795 os2Truncate, /* xTruncate */
23796 os2Sync, /* xSync */
23797 os2FileSize, /* xFileSize */
23798 os2Lock, /* xLock */
23799 os2Unlock, /* xUnlock */
23800 os2CheckReservedLock, /* xCheckReservedLock */
23801 os2FileControl, /* xFileControl */
23802 os2SectorSize, /* xSectorSize */
23803 os2DeviceCharacteristics, /* xDeviceCharacteristics */
23804 os2ShmMap, /* xShmMap */
23805 os2ShmLock, /* xShmLock */
23806 os2ShmBarrier, /* xShmBarrier */
23807 os2ShmUnmap /* xShmUnmap */
23811 /***************************************************************************
23812 ** Here ends the I/O methods that form the sqlite3_io_methods object.
23814 ** The next block of code implements the VFS methods.
23815 ****************************************************************************/
23818 ** Create a temporary file name in zBuf. zBuf must be big enough to
23819 ** hold at pVfs->mxPathname characters.
23821 static int getTempname(int nBuf, char *zBuf ){
23822 static const char zChars[] =
23823 "abcdefghijklmnopqrstuvwxyz"
23824 "ABCDEFGHIJKLMNOPQRSTUVWXYZ"
23825 "0123456789";
23826 int i, j;
23827 PSZ zTempPathCp;
23828 char zTempPath[CCHMAXPATH];
23829 ULONG ulDriveNum, ulDriveMap;
23831 /* It's odd to simulate an io-error here, but really this is just
23832 ** using the io-error infrastructure to test that SQLite handles this
23833 ** function failing.
23835 SimulateIOError( return SQLITE_IOERR );
23837 if( sqlite3_temp_directory ) {
23838 sqlite3_snprintf(CCHMAXPATH-30, zTempPath, "%s", sqlite3_temp_directory);
23839 } else if( DosScanEnv( (PSZ)"TEMP", &zTempPathCp ) == NO_ERROR ||
23840 DosScanEnv( (PSZ)"TMP", &zTempPathCp ) == NO_ERROR ||
23841 DosScanEnv( (PSZ)"TMPDIR", &zTempPathCp ) == NO_ERROR ) {
23842 char *zTempPathUTF = convertCpPathToUtf8( (char *)zTempPathCp );
23843 sqlite3_snprintf(CCHMAXPATH-30, zTempPath, "%s", zTempPathUTF);
23844 free( zTempPathUTF );
23845 } else if( DosQueryCurrentDisk( &ulDriveNum, &ulDriveMap ) == NO_ERROR ) {
23846 zTempPath[0] = (char)('A' + ulDriveNum - 1);
23847 zTempPath[1] = ':';
23848 zTempPath[2] = '\0';
23849 } else {
23850 zTempPath[0] = '\0';
23853 /* Strip off a trailing slashes or backslashes, otherwise we would get *
23854 * multiple (back)slashes which causes DosOpen() to fail. *
23855 * Trailing spaces are not allowed, either. */
23856 j = sqlite3Strlen30(zTempPath);
23857 while( j > 0 && ( zTempPath[j-1] == '\\' || zTempPath[j-1] == '/' ||
23858 zTempPath[j-1] == ' ' ) ){
23859 j--;
23861 zTempPath[j] = '\0';
23863 /* We use 20 bytes to randomize the name */
23864 sqlite3_snprintf(nBuf-22, zBuf,
23865 "%s\\"SQLITE_TEMP_FILE_PREFIX, zTempPath);
23866 j = sqlite3Strlen30(zBuf);
23867 sqlite3_randomness( 20, &zBuf[j] );
23868 for( i = 0; i < 20; i++, j++ ){
23869 zBuf[j] = zChars[ ((unsigned char)zBuf[j])%(sizeof(zChars)-1) ];
23871 zBuf[j] = 0;
23873 OSTRACE(( "TEMP FILENAME: %s\n", zBuf ));
23874 return SQLITE_OK;
23879 ** Turn a relative pathname into a full pathname. Write the full
23880 ** pathname into zFull[]. zFull[] will be at least pVfs->mxPathname
23881 ** bytes in size.
23883 static int os2FullPathname(
23884 sqlite3_vfs *pVfs, /* Pointer to vfs object */
23885 const char *zRelative, /* Possibly relative input path */
23886 int nFull, /* Size of output buffer in bytes */
23887 char *zFull /* Output buffer */
23889 char *zRelativeCp = convertUtf8PathToCp( zRelative );
23890 char zFullCp[CCHMAXPATH] = "\0";
23891 char *zFullUTF;
23892 APIRET rc = DosQueryPathInfo( (PSZ)zRelativeCp, FIL_QUERYFULLNAME,
23893 zFullCp, CCHMAXPATH );
23894 free( zRelativeCp );
23895 zFullUTF = convertCpPathToUtf8( zFullCp );
23896 sqlite3_snprintf( nFull, zFull, zFullUTF );
23897 free( zFullUTF );
23898 return rc == NO_ERROR ? SQLITE_OK : SQLITE_IOERR;
23903 ** Open a file.
23905 static int os2Open(
23906 sqlite3_vfs *pVfs, /* Not used */
23907 const char *zName, /* Name of the file (UTF-8) */
23908 sqlite3_file *id, /* Write the SQLite file handle here */
23909 int flags, /* Open mode flags */
23910 int *pOutFlags /* Status return flags */
23912 HFILE h;
23913 ULONG ulOpenFlags = 0;
23914 ULONG ulOpenMode = 0;
23915 ULONG ulAction = 0;
23916 ULONG rc;
23917 os2File *pFile = (os2File*)id;
23918 const char *zUtf8Name = zName;
23919 char *zNameCp;
23920 char zTmpname[CCHMAXPATH];
23922 int isExclusive = (flags & SQLITE_OPEN_EXCLUSIVE);
23923 int isCreate = (flags & SQLITE_OPEN_CREATE);
23924 int isReadWrite = (flags & SQLITE_OPEN_READWRITE);
23925 #ifndef NDEBUG
23926 int isDelete = (flags & SQLITE_OPEN_DELETEONCLOSE);
23927 int isReadonly = (flags & SQLITE_OPEN_READONLY);
23928 int eType = (flags & 0xFFFFFF00);
23929 int isOpenJournal = (isCreate && (
23930 eType==SQLITE_OPEN_MASTER_JOURNAL
23931 || eType==SQLITE_OPEN_MAIN_JOURNAL
23932 || eType==SQLITE_OPEN_WAL
23934 #endif
23936 UNUSED_PARAMETER(pVfs);
23937 assert( id!=0 );
23939 /* Check the following statements are true:
23941 ** (a) Exactly one of the READWRITE and READONLY flags must be set, and
23942 ** (b) if CREATE is set, then READWRITE must also be set, and
23943 ** (c) if EXCLUSIVE is set, then CREATE must also be set.
23944 ** (d) if DELETEONCLOSE is set, then CREATE must also be set.
23946 assert((isReadonly==0 || isReadWrite==0) && (isReadWrite || isReadonly));
23947 assert(isCreate==0 || isReadWrite);
23948 assert(isExclusive==0 || isCreate);
23949 assert(isDelete==0 || isCreate);
23951 /* The main DB, main journal, WAL file and master journal are never
23952 ** automatically deleted. Nor are they ever temporary files. */
23953 assert( (!isDelete && zName) || eType!=SQLITE_OPEN_MAIN_DB );
23954 assert( (!isDelete && zName) || eType!=SQLITE_OPEN_MAIN_JOURNAL );
23955 assert( (!isDelete && zName) || eType!=SQLITE_OPEN_MASTER_JOURNAL );
23956 assert( (!isDelete && zName) || eType!=SQLITE_OPEN_WAL );
23958 /* Assert that the upper layer has set one of the "file-type" flags. */
23959 assert( eType==SQLITE_OPEN_MAIN_DB || eType==SQLITE_OPEN_TEMP_DB
23960 || eType==SQLITE_OPEN_MAIN_JOURNAL || eType==SQLITE_OPEN_TEMP_JOURNAL
23961 || eType==SQLITE_OPEN_SUBJOURNAL || eType==SQLITE_OPEN_MASTER_JOURNAL
23962 || eType==SQLITE_OPEN_TRANSIENT_DB || eType==SQLITE_OPEN_WAL
23965 memset( pFile, 0, sizeof(*pFile) );
23966 pFile->h = (HFILE)-1;
23968 /* If the second argument to this function is NULL, generate a
23969 ** temporary file name to use
23971 if( !zUtf8Name ){
23972 assert(isDelete && !isOpenJournal);
23973 rc = getTempname(CCHMAXPATH, zTmpname);
23974 if( rc!=SQLITE_OK ){
23975 return rc;
23977 zUtf8Name = zTmpname;
23980 if( isReadWrite ){
23981 ulOpenMode |= OPEN_ACCESS_READWRITE;
23982 }else{
23983 ulOpenMode |= OPEN_ACCESS_READONLY;
23986 /* Open in random access mode for possibly better speed. Allow full
23987 ** sharing because file locks will provide exclusive access when needed.
23988 ** The handle should not be inherited by child processes and we don't
23989 ** want popups from the critical error handler.
23991 ulOpenMode |= OPEN_FLAGS_RANDOM | OPEN_SHARE_DENYNONE |
23992 OPEN_FLAGS_NOINHERIT | OPEN_FLAGS_FAIL_ON_ERROR;
23994 /* SQLITE_OPEN_EXCLUSIVE is used to make sure that a new file is
23995 ** created. SQLite doesn't use it to indicate "exclusive access"
23996 ** as it is usually understood.
23998 if( isExclusive ){
23999 /* Creates a new file, only if it does not already exist. */
24000 /* If the file exists, it fails. */
24001 ulOpenFlags |= OPEN_ACTION_CREATE_IF_NEW | OPEN_ACTION_FAIL_IF_EXISTS;
24002 }else if( isCreate ){
24003 /* Open existing file, or create if it doesn't exist */
24004 ulOpenFlags |= OPEN_ACTION_CREATE_IF_NEW | OPEN_ACTION_OPEN_IF_EXISTS;
24005 }else{
24006 /* Opens a file, only if it exists. */
24007 ulOpenFlags |= OPEN_ACTION_FAIL_IF_NEW | OPEN_ACTION_OPEN_IF_EXISTS;
24010 zNameCp = convertUtf8PathToCp( zUtf8Name );
24011 rc = DosOpen( (PSZ)zNameCp,
24013 &ulAction,
24015 FILE_NORMAL,
24016 ulOpenFlags,
24017 ulOpenMode,
24018 (PEAOP2)NULL );
24019 free( zNameCp );
24021 if( rc != NO_ERROR ){
24022 OSTRACE(( "OPEN Invalid handle rc=%d: zName=%s, ulAction=%#lx, ulFlags=%#lx, ulMode=%#lx\n",
24023 rc, zUtf8Name, ulAction, ulOpenFlags, ulOpenMode ));
24025 if( isReadWrite ){
24026 return os2Open( pVfs, zName, id,
24027 ((flags|SQLITE_OPEN_READONLY)&~(SQLITE_OPEN_CREATE|SQLITE_OPEN_READWRITE)),
24028 pOutFlags );
24029 }else{
24030 return SQLITE_CANTOPEN;
24034 if( pOutFlags ){
24035 *pOutFlags = isReadWrite ? SQLITE_OPEN_READWRITE : SQLITE_OPEN_READONLY;
24038 os2FullPathname( pVfs, zUtf8Name, sizeof( zTmpname ), zTmpname );
24039 pFile->zFullPathCp = convertUtf8PathToCp( zTmpname );
24040 pFile->pMethod = &os2IoMethod;
24041 pFile->flags = flags;
24042 pFile->h = h;
24044 OpenCounter(+1);
24045 OSTRACE(( "OPEN %d pOutFlags=%d\n", pFile->h, pOutFlags ));
24046 return SQLITE_OK;
24050 ** Delete the named file.
24052 static int os2Delete(
24053 sqlite3_vfs *pVfs, /* Not used on os2 */
24054 const char *zFilename, /* Name of file to delete */
24055 int syncDir /* Not used on os2 */
24057 APIRET rc;
24058 char *zFilenameCp;
24059 SimulateIOError( return SQLITE_IOERR_DELETE );
24060 zFilenameCp = convertUtf8PathToCp( zFilename );
24061 rc = DosDelete( (PSZ)zFilenameCp );
24062 free( zFilenameCp );
24063 OSTRACE(( "DELETE \"%s\"\n", zFilename ));
24064 return (rc == NO_ERROR ||
24065 rc == ERROR_FILE_NOT_FOUND ||
24066 rc == ERROR_PATH_NOT_FOUND ) ? SQLITE_OK : SQLITE_IOERR_DELETE;
24070 ** Check the existance and status of a file.
24072 static int os2Access(
24073 sqlite3_vfs *pVfs, /* Not used on os2 */
24074 const char *zFilename, /* Name of file to check */
24075 int flags, /* Type of test to make on this file */
24076 int *pOut /* Write results here */
24078 APIRET rc;
24079 FILESTATUS3 fsts3ConfigInfo;
24080 char *zFilenameCp;
24082 UNUSED_PARAMETER(pVfs);
24083 SimulateIOError( return SQLITE_IOERR_ACCESS; );
24085 zFilenameCp = convertUtf8PathToCp( zFilename );
24086 rc = DosQueryPathInfo( (PSZ)zFilenameCp, FIL_STANDARD,
24087 &fsts3ConfigInfo, sizeof(FILESTATUS3) );
24088 free( zFilenameCp );
24089 OSTRACE(( "ACCESS fsts3ConfigInfo.attrFile=%d flags=%d rc=%d\n",
24090 fsts3ConfigInfo.attrFile, flags, rc ));
24092 switch( flags ){
24093 case SQLITE_ACCESS_EXISTS:
24094 /* For an SQLITE_ACCESS_EXISTS query, treat a zero-length file
24095 ** as if it does not exist.
24097 if( fsts3ConfigInfo.cbFile == 0 )
24098 rc = ERROR_FILE_NOT_FOUND;
24099 break;
24100 case SQLITE_ACCESS_READ:
24101 break;
24102 case SQLITE_ACCESS_READWRITE:
24103 if( fsts3ConfigInfo.attrFile & FILE_READONLY )
24104 rc = ERROR_ACCESS_DENIED;
24105 break;
24106 default:
24107 rc = ERROR_FILE_NOT_FOUND;
24108 assert( !"Invalid flags argument" );
24111 *pOut = (rc == NO_ERROR);
24112 OSTRACE(( "ACCESS %s flags %d: rc=%d\n", zFilename, flags, *pOut ));
24114 return SQLITE_OK;
24118 #ifndef SQLITE_OMIT_LOAD_EXTENSION
24120 ** Interfaces for opening a shared library, finding entry points
24121 ** within the shared library, and closing the shared library.
24124 ** Interfaces for opening a shared library, finding entry points
24125 ** within the shared library, and closing the shared library.
24127 static void *os2DlOpen(sqlite3_vfs *pVfs, const char *zFilename){
24128 HMODULE hmod;
24129 APIRET rc;
24130 char *zFilenameCp = convertUtf8PathToCp(zFilename);
24131 rc = DosLoadModule(NULL, 0, (PSZ)zFilenameCp, &hmod);
24132 free(zFilenameCp);
24133 return rc != NO_ERROR ? 0 : (void*)hmod;
24136 ** A no-op since the error code is returned on the DosLoadModule call.
24137 ** os2Dlopen returns zero if DosLoadModule is not successful.
24139 static void os2DlError(sqlite3_vfs *pVfs, int nBuf, char *zBufOut){
24140 /* no-op */
24142 static void (*os2DlSym(sqlite3_vfs *pVfs, void *pHandle, const char *zSymbol))(void){
24143 PFN pfn;
24144 APIRET rc;
24145 rc = DosQueryProcAddr((HMODULE)pHandle, 0L, (PSZ)zSymbol, &pfn);
24146 if( rc != NO_ERROR ){
24147 /* if the symbol itself was not found, search again for the same
24148 * symbol with an extra underscore, that might be needed depending
24149 * on the calling convention */
24150 char _zSymbol[256] = "_";
24151 strncat(_zSymbol, zSymbol, 254);
24152 rc = DosQueryProcAddr((HMODULE)pHandle, 0L, (PSZ)_zSymbol, &pfn);
24154 return rc != NO_ERROR ? 0 : (void(*)(void))pfn;
24156 static void os2DlClose(sqlite3_vfs *pVfs, void *pHandle){
24157 DosFreeModule((HMODULE)pHandle);
24159 #else /* if SQLITE_OMIT_LOAD_EXTENSION is defined: */
24160 #define os2DlOpen 0
24161 #define os2DlError 0
24162 #define os2DlSym 0
24163 #define os2DlClose 0
24164 #endif
24168 ** Write up to nBuf bytes of randomness into zBuf.
24170 static int os2Randomness(sqlite3_vfs *pVfs, int nBuf, char *zBuf ){
24171 int n = 0;
24172 #if defined(SQLITE_TEST)
24173 n = nBuf;
24174 memset(zBuf, 0, nBuf);
24175 #else
24176 int i;
24177 PPIB ppib;
24178 PTIB ptib;
24179 DATETIME dt;
24180 static unsigned c = 0;
24181 /* Ordered by variation probability */
24182 static ULONG svIdx[6] = { QSV_MS_COUNT, QSV_TIME_LOW,
24183 QSV_MAXPRMEM, QSV_MAXSHMEM,
24184 QSV_TOTAVAILMEM, QSV_TOTRESMEM };
24186 /* 8 bytes; timezone and weekday don't increase the randomness much */
24187 if( (int)sizeof(dt)-3 <= nBuf - n ){
24188 c += 0x0100;
24189 DosGetDateTime(&dt);
24190 dt.year = (USHORT)((dt.year - 1900) | c);
24191 memcpy(&zBuf[n], &dt, sizeof(dt)-3);
24192 n += sizeof(dt)-3;
24195 /* 4 bytes; PIDs and TIDs are 16 bit internally, so combine them */
24196 if( (int)sizeof(ULONG) <= nBuf - n ){
24197 DosGetInfoBlocks(&ptib, &ppib);
24198 *(PULONG)&zBuf[n] = MAKELONG(ppib->pib_ulpid,
24199 ptib->tib_ptib2->tib2_ultid);
24200 n += sizeof(ULONG);
24203 /* Up to 6 * 4 bytes; variables depend on the system state */
24204 for( i = 0; i < 6 && (int)sizeof(ULONG) <= nBuf - n; i++ ){
24205 DosQuerySysInfo(svIdx[i], svIdx[i],
24206 (PULONG)&zBuf[n], sizeof(ULONG));
24207 n += sizeof(ULONG);
24209 #endif
24211 return n;
24215 ** Sleep for a little while. Return the amount of time slept.
24216 ** The argument is the number of microseconds we want to sleep.
24217 ** The return value is the number of microseconds of sleep actually
24218 ** requested from the underlying operating system, a number which
24219 ** might be greater than or equal to the argument, but not less
24220 ** than the argument.
24222 static int os2Sleep( sqlite3_vfs *pVfs, int microsec ){
24223 DosSleep( (microsec/1000) );
24224 return microsec;
24228 ** The following variable, if set to a non-zero value, becomes the result
24229 ** returned from sqlite3OsCurrentTime(). This is used for testing.
24231 #ifdef SQLITE_TEST
24232 SQLITE_API int sqlite3_current_time = 0;
24233 #endif
24236 ** Find the current time (in Universal Coordinated Time). Write into *piNow
24237 ** the current time and date as a Julian Day number times 86_400_000. In
24238 ** other words, write into *piNow the number of milliseconds since the Julian
24239 ** epoch of noon in Greenwich on November 24, 4714 B.C according to the
24240 ** proleptic Gregorian calendar.
24242 ** On success, return 0. Return 1 if the time and date cannot be found.
24244 static int os2CurrentTimeInt64(sqlite3_vfs *pVfs, sqlite3_int64 *piNow){
24245 #ifdef SQLITE_TEST
24246 static const sqlite3_int64 unixEpoch = 24405875*(sqlite3_int64)8640000;
24247 #endif
24248 int year, month, datepart, timepart;
24250 DATETIME dt;
24251 DosGetDateTime( &dt );
24253 year = dt.year;
24254 month = dt.month;
24256 /* Calculations from http://www.astro.keele.ac.uk/~rno/Astronomy/hjd.html
24257 ** http://www.astro.keele.ac.uk/~rno/Astronomy/hjd-0.1.c
24258 ** Calculate the Julian days
24260 datepart = (int)dt.day - 32076 +
24261 1461*(year + 4800 + (month - 14)/12)/4 +
24262 367*(month - 2 - (month - 14)/12*12)/12 -
24263 3*((year + 4900 + (month - 14)/12)/100)/4;
24265 /* Time in milliseconds, hours to noon added */
24266 timepart = 12*3600*1000 + dt.hundredths*10 + dt.seconds*1000 +
24267 ((int)dt.minutes + dt.timezone)*60*1000 + dt.hours*3600*1000;
24269 *piNow = (sqlite3_int64)datepart*86400*1000 + timepart;
24271 #ifdef SQLITE_TEST
24272 if( sqlite3_current_time ){
24273 *piNow = 1000*(sqlite3_int64)sqlite3_current_time + unixEpoch;
24275 #endif
24277 UNUSED_PARAMETER(pVfs);
24278 return 0;
24282 ** Find the current time (in Universal Coordinated Time). Write the
24283 ** current time and date as a Julian Day number into *prNow and
24284 ** return 0. Return 1 if the time and date cannot be found.
24286 static int os2CurrentTime( sqlite3_vfs *pVfs, double *prNow ){
24287 int rc;
24288 sqlite3_int64 i;
24289 rc = os2CurrentTimeInt64(pVfs, &i);
24290 if( !rc ){
24291 *prNow = i/86400000.0;
24293 return rc;
24297 ** The idea is that this function works like a combination of
24298 ** GetLastError() and FormatMessage() on windows (or errno and
24299 ** strerror_r() on unix). After an error is returned by an OS
24300 ** function, SQLite calls this function with zBuf pointing to
24301 ** a buffer of nBuf bytes. The OS layer should populate the
24302 ** buffer with a nul-terminated UTF-8 encoded error message
24303 ** describing the last IO error to have occurred within the calling
24304 ** thread.
24306 ** If the error message is too large for the supplied buffer,
24307 ** it should be truncated. The return value of xGetLastError
24308 ** is zero if the error message fits in the buffer, or non-zero
24309 ** otherwise (if the message was truncated). If non-zero is returned,
24310 ** then it is not necessary to include the nul-terminator character
24311 ** in the output buffer.
24313 ** Not supplying an error message will have no adverse effect
24314 ** on SQLite. It is fine to have an implementation that never
24315 ** returns an error message:
24317 ** int xGetLastError(sqlite3_vfs *pVfs, int nBuf, char *zBuf){
24318 ** assert(zBuf[0]=='\0');
24319 ** return 0;
24320 ** }
24322 ** However if an error message is supplied, it will be incorporated
24323 ** by sqlite into the error message available to the user using
24324 ** sqlite3_errmsg(), possibly making IO errors easier to debug.
24326 static int os2GetLastError(sqlite3_vfs *pVfs, int nBuf, char *zBuf){
24327 assert(zBuf[0]=='\0');
24328 return 0;
24332 ** Initialize and deinitialize the operating system interface.
24334 SQLITE_API int sqlite3_os_init(void){
24335 static sqlite3_vfs os2Vfs = {
24336 3, /* iVersion */
24337 sizeof(os2File), /* szOsFile */
24338 CCHMAXPATH, /* mxPathname */
24339 0, /* pNext */
24340 "os2", /* zName */
24341 0, /* pAppData */
24343 os2Open, /* xOpen */
24344 os2Delete, /* xDelete */
24345 os2Access, /* xAccess */
24346 os2FullPathname, /* xFullPathname */
24347 os2DlOpen, /* xDlOpen */
24348 os2DlError, /* xDlError */
24349 os2DlSym, /* xDlSym */
24350 os2DlClose, /* xDlClose */
24351 os2Randomness, /* xRandomness */
24352 os2Sleep, /* xSleep */
24353 os2CurrentTime, /* xCurrentTime */
24354 os2GetLastError, /* xGetLastError */
24355 os2CurrentTimeInt64, /* xCurrentTimeInt64 */
24356 0, /* xSetSystemCall */
24357 0, /* xGetSystemCall */
24358 0 /* xNextSystemCall */
24360 sqlite3_vfs_register(&os2Vfs, 1);
24361 initUconvObjects();
24362 /* sqlite3OSTrace = 1; */
24363 return SQLITE_OK;
24365 SQLITE_API int sqlite3_os_end(void){
24366 freeUconvObjects();
24367 return SQLITE_OK;
24370 #endif /* SQLITE_OS_OS2 */
24372 /************** End of os_os2.c **********************************************/
24373 /************** Begin file os_unix.c *****************************************/
24375 ** 2004 May 22
24377 ** The author disclaims copyright to this source code. In place of
24378 ** a legal notice, here is a blessing:
24380 ** May you do good and not evil.
24381 ** May you find forgiveness for yourself and forgive others.
24382 ** May you share freely, never taking more than you give.
24384 ******************************************************************************
24386 ** This file contains the VFS implementation for unix-like operating systems
24387 ** include Linux, MacOSX, *BSD, QNX, VxWorks, AIX, HPUX, and others.
24389 ** There are actually several different VFS implementations in this file.
24390 ** The differences are in the way that file locking is done. The default
24391 ** implementation uses Posix Advisory Locks. Alternative implementations
24392 ** use flock(), dot-files, various proprietary locking schemas, or simply
24393 ** skip locking all together.
24395 ** This source file is organized into divisions where the logic for various
24396 ** subfunctions is contained within the appropriate division. PLEASE
24397 ** KEEP THE STRUCTURE OF THIS FILE INTACT. New code should be placed
24398 ** in the correct division and should be clearly labeled.
24400 ** The layout of divisions is as follows:
24402 ** * General-purpose declarations and utility functions.
24403 ** * Unique file ID logic used by VxWorks.
24404 ** * Various locking primitive implementations (all except proxy locking):
24405 ** + for Posix Advisory Locks
24406 ** + for no-op locks
24407 ** + for dot-file locks
24408 ** + for flock() locking
24409 ** + for named semaphore locks (VxWorks only)
24410 ** + for AFP filesystem locks (MacOSX only)
24411 ** * sqlite3_file methods not associated with locking.
24412 ** * Definitions of sqlite3_io_methods objects for all locking
24413 ** methods plus "finder" functions for each locking method.
24414 ** * sqlite3_vfs method implementations.
24415 ** * Locking primitives for the proxy uber-locking-method. (MacOSX only)
24416 ** * Definitions of sqlite3_vfs objects for all locking methods
24417 ** plus implementations of sqlite3_os_init() and sqlite3_os_end().
24419 #if SQLITE_OS_UNIX /* This file is used on unix only */
24422 ** There are various methods for file locking used for concurrency
24423 ** control:
24425 ** 1. POSIX locking (the default),
24426 ** 2. No locking,
24427 ** 3. Dot-file locking,
24428 ** 4. flock() locking,
24429 ** 5. AFP locking (OSX only),
24430 ** 6. Named POSIX semaphores (VXWorks only),
24431 ** 7. proxy locking. (OSX only)
24433 ** Styles 4, 5, and 7 are only available of SQLITE_ENABLE_LOCKING_STYLE
24434 ** is defined to 1. The SQLITE_ENABLE_LOCKING_STYLE also enables automatic
24435 ** selection of the appropriate locking style based on the filesystem
24436 ** where the database is located.
24438 #if !defined(SQLITE_ENABLE_LOCKING_STYLE)
24439 # if defined(__APPLE__)
24440 # define SQLITE_ENABLE_LOCKING_STYLE 1
24441 # else
24442 # define SQLITE_ENABLE_LOCKING_STYLE 0
24443 # endif
24444 #endif
24447 ** Define the OS_VXWORKS pre-processor macro to 1 if building on
24448 ** vxworks, or 0 otherwise.
24450 #ifndef OS_VXWORKS
24451 # if defined(__RTP__) || defined(_WRS_KERNEL)
24452 # define OS_VXWORKS 1
24453 # else
24454 # define OS_VXWORKS 0
24455 # endif
24456 #endif
24459 ** These #defines should enable >2GB file support on Posix if the
24460 ** underlying operating system supports it. If the OS lacks
24461 ** large file support, these should be no-ops.
24463 ** Large file support can be disabled using the -DSQLITE_DISABLE_LFS switch
24464 ** on the compiler command line. This is necessary if you are compiling
24465 ** on a recent machine (ex: RedHat 7.2) but you want your code to work
24466 ** on an older machine (ex: RedHat 6.0). If you compile on RedHat 7.2
24467 ** without this option, LFS is enable. But LFS does not exist in the kernel
24468 ** in RedHat 6.0, so the code won't work. Hence, for maximum binary
24469 ** portability you should omit LFS.
24471 ** The previous paragraph was written in 2005. (This paragraph is written
24472 ** on 2008-11-28.) These days, all Linux kernels support large files, so
24473 ** you should probably leave LFS enabled. But some embedded platforms might
24474 ** lack LFS in which case the SQLITE_DISABLE_LFS macro might still be useful.
24476 #ifndef SQLITE_DISABLE_LFS
24477 # define _LARGE_FILE 1
24478 # ifndef _FILE_OFFSET_BITS
24479 # define _FILE_OFFSET_BITS 64
24480 # endif
24481 # define _LARGEFILE_SOURCE 1
24482 #endif
24485 ** standard include files.
24487 #include <sys/types.h>
24488 #include <sys/stat.h>
24489 #include <fcntl.h>
24490 #include <unistd.h>
24491 /* #include <time.h> */
24492 #include <sys/time.h>
24493 #include <errno.h>
24494 #ifndef SQLITE_OMIT_WAL
24495 #include <sys/mman.h>
24496 #endif
24498 #if SQLITE_ENABLE_LOCKING_STYLE
24499 # include <sys/ioctl.h>
24500 # if OS_VXWORKS
24501 # include <semaphore.h>
24502 # include <limits.h>
24503 # else
24504 # include <sys/file.h>
24505 # include <sys/param.h>
24506 # endif
24507 #endif /* SQLITE_ENABLE_LOCKING_STYLE */
24509 #if defined(__APPLE__) || (SQLITE_ENABLE_LOCKING_STYLE && !OS_VXWORKS)
24510 # include <sys/mount.h>
24511 #endif
24513 #ifdef HAVE_UTIME
24514 # include <utime.h>
24515 #endif
24518 ** Allowed values of unixFile.fsFlags
24520 #define SQLITE_FSFLAGS_IS_MSDOS 0x1
24523 ** If we are to be thread-safe, include the pthreads header and define
24524 ** the SQLITE_UNIX_THREADS macro.
24526 #if SQLITE_THREADSAFE
24527 /* # include <pthread.h> */
24528 # define SQLITE_UNIX_THREADS 1
24529 #endif
24532 ** Default permissions when creating a new file
24534 #ifndef SQLITE_DEFAULT_FILE_PERMISSIONS
24535 # define SQLITE_DEFAULT_FILE_PERMISSIONS 0644
24536 #endif
24539 ** Default permissions when creating auto proxy dir
24541 #ifndef SQLITE_DEFAULT_PROXYDIR_PERMISSIONS
24542 # define SQLITE_DEFAULT_PROXYDIR_PERMISSIONS 0755
24543 #endif
24546 ** Maximum supported path-length.
24548 #define MAX_PATHNAME 512
24551 ** Only set the lastErrno if the error code is a real error and not
24552 ** a normal expected return code of SQLITE_BUSY or SQLITE_OK
24554 #define IS_LOCK_ERROR(x) ((x != SQLITE_OK) && (x != SQLITE_BUSY))
24556 /* Forward references */
24557 typedef struct unixShm unixShm; /* Connection shared memory */
24558 typedef struct unixShmNode unixShmNode; /* Shared memory instance */
24559 typedef struct unixInodeInfo unixInodeInfo; /* An i-node */
24560 typedef struct UnixUnusedFd UnixUnusedFd; /* An unused file descriptor */
24563 ** Sometimes, after a file handle is closed by SQLite, the file descriptor
24564 ** cannot be closed immediately. In these cases, instances of the following
24565 ** structure are used to store the file descriptor while waiting for an
24566 ** opportunity to either close or reuse it.
24568 struct UnixUnusedFd {
24569 int fd; /* File descriptor to close */
24570 int flags; /* Flags this file descriptor was opened with */
24571 UnixUnusedFd *pNext; /* Next unused file descriptor on same file */
24575 ** The unixFile structure is subclass of sqlite3_file specific to the unix
24576 ** VFS implementations.
24578 typedef struct unixFile unixFile;
24579 struct unixFile {
24580 sqlite3_io_methods const *pMethod; /* Always the first entry */
24581 unixInodeInfo *pInode; /* Info about locks on this inode */
24582 int h; /* The file descriptor */
24583 unsigned char eFileLock; /* The type of lock held on this fd */
24584 unsigned char ctrlFlags; /* Behavioral bits. UNIXFILE_* flags */
24585 int lastErrno; /* The unix errno from last I/O error */
24586 void *lockingContext; /* Locking style specific state */
24587 UnixUnusedFd *pUnused; /* Pre-allocated UnixUnusedFd */
24588 const char *zPath; /* Name of the file */
24589 unixShm *pShm; /* Shared memory segment information */
24590 int szChunk; /* Configured by FCNTL_CHUNK_SIZE */
24591 #if SQLITE_ENABLE_LOCKING_STYLE
24592 int openFlags; /* The flags specified at open() */
24593 #endif
24594 #if SQLITE_ENABLE_LOCKING_STYLE || defined(__APPLE__)
24595 unsigned fsFlags; /* cached details from statfs() */
24596 #endif
24597 #if OS_VXWORKS
24598 int isDelete; /* Delete on close if true */
24599 struct vxworksFileId *pId; /* Unique file ID */
24600 #endif
24601 #ifndef NDEBUG
24602 /* The next group of variables are used to track whether or not the
24603 ** transaction counter in bytes 24-27 of database files are updated
24604 ** whenever any part of the database changes. An assertion fault will
24605 ** occur if a file is updated without also updating the transaction
24606 ** counter. This test is made to avoid new problems similar to the
24607 ** one described by ticket #3584.
24609 unsigned char transCntrChng; /* True if the transaction counter changed */
24610 unsigned char dbUpdate; /* True if any part of database file changed */
24611 unsigned char inNormalWrite; /* True if in a normal write operation */
24612 #endif
24613 #ifdef SQLITE_TEST
24614 /* In test mode, increase the size of this structure a bit so that
24615 ** it is larger than the struct CrashFile defined in test6.c.
24617 char aPadding[32];
24618 #endif
24622 ** Allowed values for the unixFile.ctrlFlags bitmask:
24624 #define UNIXFILE_EXCL 0x01 /* Connections from one process only */
24625 #define UNIXFILE_RDONLY 0x02 /* Connection is read only */
24626 #define UNIXFILE_PERSIST_WAL 0x04 /* Persistent WAL mode */
24627 #ifndef SQLITE_DISABLE_DIRSYNC
24628 # define UNIXFILE_DIRSYNC 0x08 /* Directory sync needed */
24629 #else
24630 # define UNIXFILE_DIRSYNC 0x00
24631 #endif
24634 ** Include code that is common to all os_*.c files
24636 /************** Include os_common.h in the middle of os_unix.c ***************/
24637 /************** Begin file os_common.h ***************************************/
24639 ** 2004 May 22
24641 ** The author disclaims copyright to this source code. In place of
24642 ** a legal notice, here is a blessing:
24644 ** May you do good and not evil.
24645 ** May you find forgiveness for yourself and forgive others.
24646 ** May you share freely, never taking more than you give.
24648 ******************************************************************************
24650 ** This file contains macros and a little bit of code that is common to
24651 ** all of the platform-specific files (os_*.c) and is #included into those
24652 ** files.
24654 ** This file should be #included by the os_*.c files only. It is not a
24655 ** general purpose header file.
24657 #ifndef _OS_COMMON_H_
24658 #define _OS_COMMON_H_
24661 ** At least two bugs have slipped in because we changed the MEMORY_DEBUG
24662 ** macro to SQLITE_DEBUG and some older makefiles have not yet made the
24663 ** switch. The following code should catch this problem at compile-time.
24665 #ifdef MEMORY_DEBUG
24666 # error "The MEMORY_DEBUG macro is obsolete. Use SQLITE_DEBUG instead."
24667 #endif
24669 #if defined(SQLITE_TEST) && defined(SQLITE_DEBUG)
24670 # ifndef SQLITE_DEBUG_OS_TRACE
24671 # define SQLITE_DEBUG_OS_TRACE 0
24672 # endif
24673 int sqlite3OSTrace = SQLITE_DEBUG_OS_TRACE;
24674 # define OSTRACE(X) if( sqlite3OSTrace ) sqlite3DebugPrintf X
24675 #else
24676 # define OSTRACE(X)
24677 #endif
24680 ** Macros for performance tracing. Normally turned off. Only works
24681 ** on i486 hardware.
24683 #ifdef SQLITE_PERFORMANCE_TRACE
24686 ** hwtime.h contains inline assembler code for implementing
24687 ** high-performance timing routines.
24689 /************** Include hwtime.h in the middle of os_common.h ****************/
24690 /************** Begin file hwtime.h ******************************************/
24692 ** 2008 May 27
24694 ** The author disclaims copyright to this source code. In place of
24695 ** a legal notice, here is a blessing:
24697 ** May you do good and not evil.
24698 ** May you find forgiveness for yourself and forgive others.
24699 ** May you share freely, never taking more than you give.
24701 ******************************************************************************
24703 ** This file contains inline asm code for retrieving "high-performance"
24704 ** counters for x86 class CPUs.
24706 #ifndef _HWTIME_H_
24707 #define _HWTIME_H_
24710 ** The following routine only works on pentium-class (or newer) processors.
24711 ** It uses the RDTSC opcode to read the cycle count value out of the
24712 ** processor and returns that value. This can be used for high-res
24713 ** profiling.
24715 #if (defined(__GNUC__) || defined(_MSC_VER)) && \
24716 (defined(i386) || defined(__i386__) || defined(_M_IX86))
24718 #if defined(__GNUC__)
24720 __inline__ sqlite_uint64 sqlite3Hwtime(void){
24721 unsigned int lo, hi;
24722 __asm__ __volatile__ ("rdtsc" : "=a" (lo), "=d" (hi));
24723 return (sqlite_uint64)hi << 32 | lo;
24726 #elif defined(_MSC_VER)
24728 __declspec(naked) __inline sqlite_uint64 __cdecl sqlite3Hwtime(void){
24729 __asm {
24730 rdtsc
24731 ret ; return value at EDX:EAX
24735 #endif
24737 #elif (defined(__GNUC__) && defined(__x86_64__))
24739 __inline__ sqlite_uint64 sqlite3Hwtime(void){
24740 unsigned long val;
24741 __asm__ __volatile__ ("rdtsc" : "=A" (val));
24742 return val;
24745 #elif (defined(__GNUC__) && defined(__ppc__))
24747 __inline__ sqlite_uint64 sqlite3Hwtime(void){
24748 unsigned long long retval;
24749 unsigned long junk;
24750 __asm__ __volatile__ ("\n\
24751 1: mftbu %1\n\
24752 mftb %L0\n\
24753 mftbu %0\n\
24754 cmpw %0,%1\n\
24755 bne 1b"
24756 : "=r" (retval), "=r" (junk));
24757 return retval;
24760 #else
24762 #error Need implementation of sqlite3Hwtime() for your platform.
24765 ** To compile without implementing sqlite3Hwtime() for your platform,
24766 ** you can remove the above #error and use the following
24767 ** stub function. You will lose timing support for many
24768 ** of the debugging and testing utilities, but it should at
24769 ** least compile and run.
24771 SQLITE_PRIVATE sqlite_uint64 sqlite3Hwtime(void){ return ((sqlite_uint64)0); }
24773 #endif
24775 #endif /* !defined(_HWTIME_H_) */
24777 /************** End of hwtime.h **********************************************/
24778 /************** Continuing where we left off in os_common.h ******************/
24780 static sqlite_uint64 g_start;
24781 static sqlite_uint64 g_elapsed;
24782 #define TIMER_START g_start=sqlite3Hwtime()
24783 #define TIMER_END g_elapsed=sqlite3Hwtime()-g_start
24784 #define TIMER_ELAPSED g_elapsed
24785 #else
24786 #define TIMER_START
24787 #define TIMER_END
24788 #define TIMER_ELAPSED ((sqlite_uint64)0)
24789 #endif
24792 ** If we compile with the SQLITE_TEST macro set, then the following block
24793 ** of code will give us the ability to simulate a disk I/O error. This
24794 ** is used for testing the I/O recovery logic.
24796 #ifdef SQLITE_TEST
24797 SQLITE_API int sqlite3_io_error_hit = 0; /* Total number of I/O Errors */
24798 SQLITE_API int sqlite3_io_error_hardhit = 0; /* Number of non-benign errors */
24799 SQLITE_API int sqlite3_io_error_pending = 0; /* Count down to first I/O error */
24800 SQLITE_API int sqlite3_io_error_persist = 0; /* True if I/O errors persist */
24801 SQLITE_API int sqlite3_io_error_benign = 0; /* True if errors are benign */
24802 SQLITE_API int sqlite3_diskfull_pending = 0;
24803 SQLITE_API int sqlite3_diskfull = 0;
24804 #define SimulateIOErrorBenign(X) sqlite3_io_error_benign=(X)
24805 #define SimulateIOError(CODE) \
24806 if( (sqlite3_io_error_persist && sqlite3_io_error_hit) \
24807 || sqlite3_io_error_pending-- == 1 ) \
24808 { local_ioerr(); CODE; }
24809 static void local_ioerr(){
24810 IOTRACE(("IOERR\n"));
24811 sqlite3_io_error_hit++;
24812 if( !sqlite3_io_error_benign ) sqlite3_io_error_hardhit++;
24814 #define SimulateDiskfullError(CODE) \
24815 if( sqlite3_diskfull_pending ){ \
24816 if( sqlite3_diskfull_pending == 1 ){ \
24817 local_ioerr(); \
24818 sqlite3_diskfull = 1; \
24819 sqlite3_io_error_hit = 1; \
24820 CODE; \
24821 }else{ \
24822 sqlite3_diskfull_pending--; \
24825 #else
24826 #define SimulateIOErrorBenign(X)
24827 #define SimulateIOError(A)
24828 #define SimulateDiskfullError(A)
24829 #endif
24832 ** When testing, keep a count of the number of open files.
24834 #ifdef SQLITE_TEST
24835 SQLITE_API int sqlite3_open_file_count = 0;
24836 #define OpenCounter(X) sqlite3_open_file_count+=(X)
24837 #else
24838 #define OpenCounter(X)
24839 #endif
24841 #endif /* !defined(_OS_COMMON_H_) */
24843 /************** End of os_common.h *******************************************/
24844 /************** Continuing where we left off in os_unix.c ********************/
24847 ** Define various macros that are missing from some systems.
24849 #ifndef O_LARGEFILE
24850 # define O_LARGEFILE 0
24851 #endif
24852 #ifdef SQLITE_DISABLE_LFS
24853 # undef O_LARGEFILE
24854 # define O_LARGEFILE 0
24855 #endif
24856 #ifndef O_NOFOLLOW
24857 # define O_NOFOLLOW 0
24858 #endif
24859 #ifndef O_BINARY
24860 # define O_BINARY 0
24861 #endif
24864 ** The threadid macro resolves to the thread-id or to 0. Used for
24865 ** testing and debugging only.
24867 #if SQLITE_THREADSAFE
24868 #define threadid pthread_self()
24869 #else
24870 #define threadid 0
24871 #endif
24874 ** Different Unix systems declare open() in different ways. Same use
24875 ** open(const char*,int,mode_t). Others use open(const char*,int,...).
24876 ** The difference is important when using a pointer to the function.
24878 ** The safest way to deal with the problem is to always use this wrapper
24879 ** which always has the same well-defined interface.
24881 static int posixOpen(const char *zFile, int flags, int mode){
24882 return open(zFile, flags, mode);
24885 /* Forward reference */
24886 static int openDirectory(const char*, int*);
24889 ** Many system calls are accessed through pointer-to-functions so that
24890 ** they may be overridden at runtime to facilitate fault injection during
24891 ** testing and sandboxing. The following array holds the names and pointers
24892 ** to all overrideable system calls.
24894 static struct unix_syscall {
24895 const char *zName; /* Name of the sytem call */
24896 sqlite3_syscall_ptr pCurrent; /* Current value of the system call */
24897 sqlite3_syscall_ptr pDefault; /* Default value */
24898 } aSyscall[] = {
24899 { "open", (sqlite3_syscall_ptr)posixOpen, 0 },
24900 #define osOpen ((int(*)(const char*,int,int))aSyscall[0].pCurrent)
24902 { "close", (sqlite3_syscall_ptr)close, 0 },
24903 #define osClose ((int(*)(int))aSyscall[1].pCurrent)
24905 { "access", (sqlite3_syscall_ptr)access, 0 },
24906 #define osAccess ((int(*)(const char*,int))aSyscall[2].pCurrent)
24908 { "getcwd", (sqlite3_syscall_ptr)getcwd, 0 },
24909 #define osGetcwd ((char*(*)(char*,size_t))aSyscall[3].pCurrent)
24911 { "stat", (sqlite3_syscall_ptr)stat, 0 },
24912 #define osStat ((int(*)(const char*,struct stat*))aSyscall[4].pCurrent)
24915 ** The DJGPP compiler environment looks mostly like Unix, but it
24916 ** lacks the fcntl() system call. So redefine fcntl() to be something
24917 ** that always succeeds. This means that locking does not occur under
24918 ** DJGPP. But it is DOS - what did you expect?
24920 #ifdef __DJGPP__
24921 { "fstat", 0, 0 },
24922 #define osFstat(a,b,c) 0
24923 #else
24924 { "fstat", (sqlite3_syscall_ptr)fstat, 0 },
24925 #define osFstat ((int(*)(int,struct stat*))aSyscall[5].pCurrent)
24926 #endif
24928 { "ftruncate", (sqlite3_syscall_ptr)ftruncate, 0 },
24929 #define osFtruncate ((int(*)(int,off_t))aSyscall[6].pCurrent)
24931 { "fcntl", (sqlite3_syscall_ptr)fcntl, 0 },
24932 #define osFcntl ((int(*)(int,int,...))aSyscall[7].pCurrent)
24934 { "read", (sqlite3_syscall_ptr)read, 0 },
24935 #define osRead ((ssize_t(*)(int,void*,size_t))aSyscall[8].pCurrent)
24937 #if defined(USE_PREAD) || SQLITE_ENABLE_LOCKING_STYLE
24938 { "pread", (sqlite3_syscall_ptr)pread, 0 },
24939 #else
24940 { "pread", (sqlite3_syscall_ptr)0, 0 },
24941 #endif
24942 #define osPread ((ssize_t(*)(int,void*,size_t,off_t))aSyscall[9].pCurrent)
24944 #if defined(USE_PREAD64)
24945 { "pread64", (sqlite3_syscall_ptr)pread64, 0 },
24946 #else
24947 { "pread64", (sqlite3_syscall_ptr)0, 0 },
24948 #endif
24949 #define osPread64 ((ssize_t(*)(int,void*,size_t,off_t))aSyscall[10].pCurrent)
24951 { "write", (sqlite3_syscall_ptr)write, 0 },
24952 #define osWrite ((ssize_t(*)(int,const void*,size_t))aSyscall[11].pCurrent)
24954 #if defined(USE_PREAD) || SQLITE_ENABLE_LOCKING_STYLE
24955 { "pwrite", (sqlite3_syscall_ptr)pwrite, 0 },
24956 #else
24957 { "pwrite", (sqlite3_syscall_ptr)0, 0 },
24958 #endif
24959 #define osPwrite ((ssize_t(*)(int,const void*,size_t,off_t))\
24960 aSyscall[12].pCurrent)
24962 #if defined(USE_PREAD64)
24963 { "pwrite64", (sqlite3_syscall_ptr)pwrite64, 0 },
24964 #else
24965 { "pwrite64", (sqlite3_syscall_ptr)0, 0 },
24966 #endif
24967 #define osPwrite64 ((ssize_t(*)(int,const void*,size_t,off_t))\
24968 aSyscall[13].pCurrent)
24970 #if SQLITE_ENABLE_LOCKING_STYLE
24971 { "fchmod", (sqlite3_syscall_ptr)fchmod, 0 },
24972 #else
24973 { "fchmod", (sqlite3_syscall_ptr)0, 0 },
24974 #endif
24975 #define osFchmod ((int(*)(int,mode_t))aSyscall[14].pCurrent)
24977 #if defined(HAVE_POSIX_FALLOCATE) && HAVE_POSIX_FALLOCATE
24978 { "fallocate", (sqlite3_syscall_ptr)posix_fallocate, 0 },
24979 #else
24980 { "fallocate", (sqlite3_syscall_ptr)0, 0 },
24981 #endif
24982 #define osFallocate ((int(*)(int,off_t,off_t))aSyscall[15].pCurrent)
24984 { "unlink", (sqlite3_syscall_ptr)unlink, 0 },
24985 #define osUnlink ((int(*)(const char*))aSyscall[16].pCurrent)
24987 { "openDirectory", (sqlite3_syscall_ptr)openDirectory, 0 },
24988 #define osOpenDirectory ((int(*)(const char*,int*))aSyscall[17].pCurrent)
24990 }; /* End of the overrideable system calls */
24993 ** This is the xSetSystemCall() method of sqlite3_vfs for all of the
24994 ** "unix" VFSes. Return SQLITE_OK opon successfully updating the
24995 ** system call pointer, or SQLITE_NOTFOUND if there is no configurable
24996 ** system call named zName.
24998 static int unixSetSystemCall(
24999 sqlite3_vfs *pNotUsed, /* The VFS pointer. Not used */
25000 const char *zName, /* Name of system call to override */
25001 sqlite3_syscall_ptr pNewFunc /* Pointer to new system call value */
25003 unsigned int i;
25004 int rc = SQLITE_NOTFOUND;
25006 UNUSED_PARAMETER(pNotUsed);
25007 if( zName==0 ){
25008 /* If no zName is given, restore all system calls to their default
25009 ** settings and return NULL
25011 rc = SQLITE_OK;
25012 for(i=0; i<sizeof(aSyscall)/sizeof(aSyscall[0]); i++){
25013 if( aSyscall[i].pDefault ){
25014 aSyscall[i].pCurrent = aSyscall[i].pDefault;
25017 }else{
25018 /* If zName is specified, operate on only the one system call
25019 ** specified.
25021 for(i=0; i<sizeof(aSyscall)/sizeof(aSyscall[0]); i++){
25022 if( strcmp(zName, aSyscall[i].zName)==0 ){
25023 if( aSyscall[i].pDefault==0 ){
25024 aSyscall[i].pDefault = aSyscall[i].pCurrent;
25026 rc = SQLITE_OK;
25027 if( pNewFunc==0 ) pNewFunc = aSyscall[i].pDefault;
25028 aSyscall[i].pCurrent = pNewFunc;
25029 break;
25033 return rc;
25037 ** Return the value of a system call. Return NULL if zName is not a
25038 ** recognized system call name. NULL is also returned if the system call
25039 ** is currently undefined.
25041 static sqlite3_syscall_ptr unixGetSystemCall(
25042 sqlite3_vfs *pNotUsed,
25043 const char *zName
25045 unsigned int i;
25047 UNUSED_PARAMETER(pNotUsed);
25048 for(i=0; i<sizeof(aSyscall)/sizeof(aSyscall[0]); i++){
25049 if( strcmp(zName, aSyscall[i].zName)==0 ) return aSyscall[i].pCurrent;
25051 return 0;
25055 ** Return the name of the first system call after zName. If zName==NULL
25056 ** then return the name of the first system call. Return NULL if zName
25057 ** is the last system call or if zName is not the name of a valid
25058 ** system call.
25060 static const char *unixNextSystemCall(sqlite3_vfs *p, const char *zName){
25061 int i = -1;
25063 UNUSED_PARAMETER(p);
25064 if( zName ){
25065 for(i=0; i<ArraySize(aSyscall)-1; i++){
25066 if( strcmp(zName, aSyscall[i].zName)==0 ) break;
25069 for(i++; i<ArraySize(aSyscall); i++){
25070 if( aSyscall[i].pCurrent!=0 ) return aSyscall[i].zName;
25072 return 0;
25076 ** Retry open() calls that fail due to EINTR
25078 static int robust_open(const char *z, int f, int m){
25079 int rc;
25080 do{ rc = osOpen(z,f,m); }while( rc<0 && errno==EINTR );
25081 return rc;
25085 ** Helper functions to obtain and relinquish the global mutex. The
25086 ** global mutex is used to protect the unixInodeInfo and
25087 ** vxworksFileId objects used by this file, all of which may be
25088 ** shared by multiple threads.
25090 ** Function unixMutexHeld() is used to assert() that the global mutex
25091 ** is held when required. This function is only used as part of assert()
25092 ** statements. e.g.
25094 ** unixEnterMutex()
25095 ** assert( unixMutexHeld() );
25096 ** unixEnterLeave()
25098 static void unixEnterMutex(void){
25099 sqlite3_mutex_enter(sqlite3MutexAlloc(SQLITE_MUTEX_STATIC_MASTER));
25101 static void unixLeaveMutex(void){
25102 sqlite3_mutex_leave(sqlite3MutexAlloc(SQLITE_MUTEX_STATIC_MASTER));
25104 #ifdef SQLITE_DEBUG
25105 static int unixMutexHeld(void) {
25106 return sqlite3_mutex_held(sqlite3MutexAlloc(SQLITE_MUTEX_STATIC_MASTER));
25108 #endif
25111 #ifdef SQLITE_DEBUG
25113 ** Helper function for printing out trace information from debugging
25114 ** binaries. This returns the string represetation of the supplied
25115 ** integer lock-type.
25117 static const char *azFileLock(int eFileLock){
25118 switch( eFileLock ){
25119 case NO_LOCK: return "NONE";
25120 case SHARED_LOCK: return "SHARED";
25121 case RESERVED_LOCK: return "RESERVED";
25122 case PENDING_LOCK: return "PENDING";
25123 case EXCLUSIVE_LOCK: return "EXCLUSIVE";
25125 return "ERROR";
25127 #endif
25129 #ifdef SQLITE_LOCK_TRACE
25131 ** Print out information about all locking operations.
25133 ** This routine is used for troubleshooting locks on multithreaded
25134 ** platforms. Enable by compiling with the -DSQLITE_LOCK_TRACE
25135 ** command-line option on the compiler. This code is normally
25136 ** turned off.
25138 static int lockTrace(int fd, int op, struct flock *p){
25139 char *zOpName, *zType;
25140 int s;
25141 int savedErrno;
25142 if( op==F_GETLK ){
25143 zOpName = "GETLK";
25144 }else if( op==F_SETLK ){
25145 zOpName = "SETLK";
25146 }else{
25147 s = osFcntl(fd, op, p);
25148 sqlite3DebugPrintf("fcntl unknown %d %d %d\n", fd, op, s);
25149 return s;
25151 if( p->l_type==F_RDLCK ){
25152 zType = "RDLCK";
25153 }else if( p->l_type==F_WRLCK ){
25154 zType = "WRLCK";
25155 }else if( p->l_type==F_UNLCK ){
25156 zType = "UNLCK";
25157 }else{
25158 assert( 0 );
25160 assert( p->l_whence==SEEK_SET );
25161 s = osFcntl(fd, op, p);
25162 savedErrno = errno;
25163 sqlite3DebugPrintf("fcntl %d %d %s %s %d %d %d %d\n",
25164 threadid, fd, zOpName, zType, (int)p->l_start, (int)p->l_len,
25165 (int)p->l_pid, s);
25166 if( s==(-1) && op==F_SETLK && (p->l_type==F_RDLCK || p->l_type==F_WRLCK) ){
25167 struct flock l2;
25168 l2 = *p;
25169 osFcntl(fd, F_GETLK, &l2);
25170 if( l2.l_type==F_RDLCK ){
25171 zType = "RDLCK";
25172 }else if( l2.l_type==F_WRLCK ){
25173 zType = "WRLCK";
25174 }else if( l2.l_type==F_UNLCK ){
25175 zType = "UNLCK";
25176 }else{
25177 assert( 0 );
25179 sqlite3DebugPrintf("fcntl-failure-reason: %s %d %d %d\n",
25180 zType, (int)l2.l_start, (int)l2.l_len, (int)l2.l_pid);
25182 errno = savedErrno;
25183 return s;
25185 #undef osFcntl
25186 #define osFcntl lockTrace
25187 #endif /* SQLITE_LOCK_TRACE */
25190 ** Retry ftruncate() calls that fail due to EINTR
25192 static int robust_ftruncate(int h, sqlite3_int64 sz){
25193 int rc;
25194 do{ rc = osFtruncate(h,sz); }while( rc<0 && errno==EINTR );
25195 return rc;
25199 ** This routine translates a standard POSIX errno code into something
25200 ** useful to the clients of the sqlite3 functions. Specifically, it is
25201 ** intended to translate a variety of "try again" errors into SQLITE_BUSY
25202 ** and a variety of "please close the file descriptor NOW" errors into
25203 ** SQLITE_IOERR
25205 ** Errors during initialization of locks, or file system support for locks,
25206 ** should handle ENOLCK, ENOTSUP, EOPNOTSUPP separately.
25208 static int sqliteErrorFromPosixError(int posixError, int sqliteIOErr) {
25209 switch (posixError) {
25210 #if 0
25211 /* At one point this code was not commented out. In theory, this branch
25212 ** should never be hit, as this function should only be called after
25213 ** a locking-related function (i.e. fcntl()) has returned non-zero with
25214 ** the value of errno as the first argument. Since a system call has failed,
25215 ** errno should be non-zero.
25217 ** Despite this, if errno really is zero, we still don't want to return
25218 ** SQLITE_OK. The system call failed, and *some* SQLite error should be
25219 ** propagated back to the caller. Commenting this branch out means errno==0
25220 ** will be handled by the "default:" case below.
25222 case 0:
25223 return SQLITE_OK;
25224 #endif
25226 case EAGAIN:
25227 case ETIMEDOUT:
25228 case EBUSY:
25229 case EINTR:
25230 case ENOLCK:
25231 /* random NFS retry error, unless during file system support
25232 * introspection, in which it actually means what it says */
25233 return SQLITE_BUSY;
25235 case EACCES:
25236 /* EACCES is like EAGAIN during locking operations, but not any other time*/
25237 if( (sqliteIOErr == SQLITE_IOERR_LOCK) ||
25238 (sqliteIOErr == SQLITE_IOERR_UNLOCK) ||
25239 (sqliteIOErr == SQLITE_IOERR_RDLOCK) ||
25240 (sqliteIOErr == SQLITE_IOERR_CHECKRESERVEDLOCK) ){
25241 return SQLITE_BUSY;
25243 /* else fall through */
25244 case EPERM:
25245 return SQLITE_PERM;
25247 /* EDEADLK is only possible if a call to fcntl(F_SETLKW) is made. And
25248 ** this module never makes such a call. And the code in SQLite itself
25249 ** asserts that SQLITE_IOERR_BLOCKED is never returned. For these reasons
25250 ** this case is also commented out. If the system does set errno to EDEADLK,
25251 ** the default SQLITE_IOERR_XXX code will be returned. */
25252 #if 0
25253 case EDEADLK:
25254 return SQLITE_IOERR_BLOCKED;
25255 #endif
25257 #if EOPNOTSUPP!=ENOTSUP
25258 case EOPNOTSUPP:
25259 /* something went terribly awry, unless during file system support
25260 * introspection, in which it actually means what it says */
25261 #endif
25262 #ifdef ENOTSUP
25263 case ENOTSUP:
25264 /* invalid fd, unless during file system support introspection, in which
25265 * it actually means what it says */
25266 #endif
25267 case EIO:
25268 case EBADF:
25269 case EINVAL:
25270 case ENOTCONN:
25271 case ENODEV:
25272 case ENXIO:
25273 case ENOENT:
25274 #ifdef ESTALE /* ESTALE is not defined on Interix systems */
25275 case ESTALE:
25276 #endif
25277 case ENOSYS:
25278 /* these should force the client to close the file and reconnect */
25280 default:
25281 return sqliteIOErr;
25287 /******************************************************************************
25288 ****************** Begin Unique File ID Utility Used By VxWorks ***************
25290 ** On most versions of unix, we can get a unique ID for a file by concatenating
25291 ** the device number and the inode number. But this does not work on VxWorks.
25292 ** On VxWorks, a unique file id must be based on the canonical filename.
25294 ** A pointer to an instance of the following structure can be used as a
25295 ** unique file ID in VxWorks. Each instance of this structure contains
25296 ** a copy of the canonical filename. There is also a reference count.
25297 ** The structure is reclaimed when the number of pointers to it drops to
25298 ** zero.
25300 ** There are never very many files open at one time and lookups are not
25301 ** a performance-critical path, so it is sufficient to put these
25302 ** structures on a linked list.
25304 struct vxworksFileId {
25305 struct vxworksFileId *pNext; /* Next in a list of them all */
25306 int nRef; /* Number of references to this one */
25307 int nName; /* Length of the zCanonicalName[] string */
25308 char *zCanonicalName; /* Canonical filename */
25311 #if OS_VXWORKS
25313 ** All unique filenames are held on a linked list headed by this
25314 ** variable:
25316 static struct vxworksFileId *vxworksFileList = 0;
25319 ** Simplify a filename into its canonical form
25320 ** by making the following changes:
25322 ** * removing any trailing and duplicate /
25323 ** * convert /./ into just /
25324 ** * convert /A/../ where A is any simple name into just /
25326 ** Changes are made in-place. Return the new name length.
25328 ** The original filename is in z[0..n-1]. Return the number of
25329 ** characters in the simplified name.
25331 static int vxworksSimplifyName(char *z, int n){
25332 int i, j;
25333 while( n>1 && z[n-1]=='/' ){ n--; }
25334 for(i=j=0; i<n; i++){
25335 if( z[i]=='/' ){
25336 if( z[i+1]=='/' ) continue;
25337 if( z[i+1]=='.' && i+2<n && z[i+2]=='/' ){
25338 i += 1;
25339 continue;
25341 if( z[i+1]=='.' && i+3<n && z[i+2]=='.' && z[i+3]=='/' ){
25342 while( j>0 && z[j-1]!='/' ){ j--; }
25343 if( j>0 ){ j--; }
25344 i += 2;
25345 continue;
25348 z[j++] = z[i];
25350 z[j] = 0;
25351 return j;
25355 ** Find a unique file ID for the given absolute pathname. Return
25356 ** a pointer to the vxworksFileId object. This pointer is the unique
25357 ** file ID.
25359 ** The nRef field of the vxworksFileId object is incremented before
25360 ** the object is returned. A new vxworksFileId object is created
25361 ** and added to the global list if necessary.
25363 ** If a memory allocation error occurs, return NULL.
25365 static struct vxworksFileId *vxworksFindFileId(const char *zAbsoluteName){
25366 struct vxworksFileId *pNew; /* search key and new file ID */
25367 struct vxworksFileId *pCandidate; /* For looping over existing file IDs */
25368 int n; /* Length of zAbsoluteName string */
25370 assert( zAbsoluteName[0]=='/' );
25371 n = (int)strlen(zAbsoluteName);
25372 pNew = sqlite3_malloc( sizeof(*pNew) + (n+1) );
25373 if( pNew==0 ) return 0;
25374 pNew->zCanonicalName = (char*)&pNew[1];
25375 memcpy(pNew->zCanonicalName, zAbsoluteName, n+1);
25376 n = vxworksSimplifyName(pNew->zCanonicalName, n);
25378 /* Search for an existing entry that matching the canonical name.
25379 ** If found, increment the reference count and return a pointer to
25380 ** the existing file ID.
25382 unixEnterMutex();
25383 for(pCandidate=vxworksFileList; pCandidate; pCandidate=pCandidate->pNext){
25384 if( pCandidate->nName==n
25385 && memcmp(pCandidate->zCanonicalName, pNew->zCanonicalName, n)==0
25387 sqlite3_free(pNew);
25388 pCandidate->nRef++;
25389 unixLeaveMutex();
25390 return pCandidate;
25394 /* No match was found. We will make a new file ID */
25395 pNew->nRef = 1;
25396 pNew->nName = n;
25397 pNew->pNext = vxworksFileList;
25398 vxworksFileList = pNew;
25399 unixLeaveMutex();
25400 return pNew;
25404 ** Decrement the reference count on a vxworksFileId object. Free
25405 ** the object when the reference count reaches zero.
25407 static void vxworksReleaseFileId(struct vxworksFileId *pId){
25408 unixEnterMutex();
25409 assert( pId->nRef>0 );
25410 pId->nRef--;
25411 if( pId->nRef==0 ){
25412 struct vxworksFileId **pp;
25413 for(pp=&vxworksFileList; *pp && *pp!=pId; pp = &((*pp)->pNext)){}
25414 assert( *pp==pId );
25415 *pp = pId->pNext;
25416 sqlite3_free(pId);
25418 unixLeaveMutex();
25420 #endif /* OS_VXWORKS */
25421 /*************** End of Unique File ID Utility Used By VxWorks ****************
25422 ******************************************************************************/
25425 /******************************************************************************
25426 *************************** Posix Advisory Locking ****************************
25428 ** POSIX advisory locks are broken by design. ANSI STD 1003.1 (1996)
25429 ** section 6.5.2.2 lines 483 through 490 specify that when a process
25430 ** sets or clears a lock, that operation overrides any prior locks set
25431 ** by the same process. It does not explicitly say so, but this implies
25432 ** that it overrides locks set by the same process using a different
25433 ** file descriptor. Consider this test case:
25435 ** int fd1 = open("./file1", O_RDWR|O_CREAT, 0644);
25436 ** int fd2 = open("./file2", O_RDWR|O_CREAT, 0644);
25438 ** Suppose ./file1 and ./file2 are really the same file (because
25439 ** one is a hard or symbolic link to the other) then if you set
25440 ** an exclusive lock on fd1, then try to get an exclusive lock
25441 ** on fd2, it works. I would have expected the second lock to
25442 ** fail since there was already a lock on the file due to fd1.
25443 ** But not so. Since both locks came from the same process, the
25444 ** second overrides the first, even though they were on different
25445 ** file descriptors opened on different file names.
25447 ** This means that we cannot use POSIX locks to synchronize file access
25448 ** among competing threads of the same process. POSIX locks will work fine
25449 ** to synchronize access for threads in separate processes, but not
25450 ** threads within the same process.
25452 ** To work around the problem, SQLite has to manage file locks internally
25453 ** on its own. Whenever a new database is opened, we have to find the
25454 ** specific inode of the database file (the inode is determined by the
25455 ** st_dev and st_ino fields of the stat structure that fstat() fills in)
25456 ** and check for locks already existing on that inode. When locks are
25457 ** created or removed, we have to look at our own internal record of the
25458 ** locks to see if another thread has previously set a lock on that same
25459 ** inode.
25461 ** (Aside: The use of inode numbers as unique IDs does not work on VxWorks.
25462 ** For VxWorks, we have to use the alternative unique ID system based on
25463 ** canonical filename and implemented in the previous division.)
25465 ** The sqlite3_file structure for POSIX is no longer just an integer file
25466 ** descriptor. It is now a structure that holds the integer file
25467 ** descriptor and a pointer to a structure that describes the internal
25468 ** locks on the corresponding inode. There is one locking structure
25469 ** per inode, so if the same inode is opened twice, both unixFile structures
25470 ** point to the same locking structure. The locking structure keeps
25471 ** a reference count (so we will know when to delete it) and a "cnt"
25472 ** field that tells us its internal lock status. cnt==0 means the
25473 ** file is unlocked. cnt==-1 means the file has an exclusive lock.
25474 ** cnt>0 means there are cnt shared locks on the file.
25476 ** Any attempt to lock or unlock a file first checks the locking
25477 ** structure. The fcntl() system call is only invoked to set a
25478 ** POSIX lock if the internal lock structure transitions between
25479 ** a locked and an unlocked state.
25481 ** But wait: there are yet more problems with POSIX advisory locks.
25483 ** If you close a file descriptor that points to a file that has locks,
25484 ** all locks on that file that are owned by the current process are
25485 ** released. To work around this problem, each unixInodeInfo object
25486 ** maintains a count of the number of pending locks on tha inode.
25487 ** When an attempt is made to close an unixFile, if there are
25488 ** other unixFile open on the same inode that are holding locks, the call
25489 ** to close() the file descriptor is deferred until all of the locks clear.
25490 ** The unixInodeInfo structure keeps a list of file descriptors that need to
25491 ** be closed and that list is walked (and cleared) when the last lock
25492 ** clears.
25494 ** Yet another problem: LinuxThreads do not play well with posix locks.
25496 ** Many older versions of linux use the LinuxThreads library which is
25497 ** not posix compliant. Under LinuxThreads, a lock created by thread
25498 ** A cannot be modified or overridden by a different thread B.
25499 ** Only thread A can modify the lock. Locking behavior is correct
25500 ** if the appliation uses the newer Native Posix Thread Library (NPTL)
25501 ** on linux - with NPTL a lock created by thread A can override locks
25502 ** in thread B. But there is no way to know at compile-time which
25503 ** threading library is being used. So there is no way to know at
25504 ** compile-time whether or not thread A can override locks on thread B.
25505 ** One has to do a run-time check to discover the behavior of the
25506 ** current process.
25508 ** SQLite used to support LinuxThreads. But support for LinuxThreads
25509 ** was dropped beginning with version 3.7.0. SQLite will still work with
25510 ** LinuxThreads provided that (1) there is no more than one connection
25511 ** per database file in the same process and (2) database connections
25512 ** do not move across threads.
25516 ** An instance of the following structure serves as the key used
25517 ** to locate a particular unixInodeInfo object.
25519 struct unixFileId {
25520 dev_t dev; /* Device number */
25521 #if OS_VXWORKS
25522 struct vxworksFileId *pId; /* Unique file ID for vxworks. */
25523 #else
25524 ino_t ino; /* Inode number */
25525 #endif
25529 ** An instance of the following structure is allocated for each open
25530 ** inode. Or, on LinuxThreads, there is one of these structures for
25531 ** each inode opened by each thread.
25533 ** A single inode can have multiple file descriptors, so each unixFile
25534 ** structure contains a pointer to an instance of this object and this
25535 ** object keeps a count of the number of unixFile pointing to it.
25537 struct unixInodeInfo {
25538 struct unixFileId fileId; /* The lookup key */
25539 int nShared; /* Number of SHARED locks held */
25540 unsigned char eFileLock; /* One of SHARED_LOCK, RESERVED_LOCK etc. */
25541 unsigned char bProcessLock; /* An exclusive process lock is held */
25542 int nRef; /* Number of pointers to this structure */
25543 unixShmNode *pShmNode; /* Shared memory associated with this inode */
25544 int nLock; /* Number of outstanding file locks */
25545 UnixUnusedFd *pUnused; /* Unused file descriptors to close */
25546 unixInodeInfo *pNext; /* List of all unixInodeInfo objects */
25547 unixInodeInfo *pPrev; /* .... doubly linked */
25548 #if SQLITE_ENABLE_LOCKING_STYLE
25549 unsigned long long sharedByte; /* for AFP simulated shared lock */
25550 #endif
25551 #if OS_VXWORKS
25552 sem_t *pSem; /* Named POSIX semaphore */
25553 char aSemName[MAX_PATHNAME+2]; /* Name of that semaphore */
25554 #endif
25558 ** A lists of all unixInodeInfo objects.
25560 static unixInodeInfo *inodeList = 0;
25564 ** This function - unixLogError_x(), is only ever called via the macro
25565 ** unixLogError().
25567 ** It is invoked after an error occurs in an OS function and errno has been
25568 ** set. It logs a message using sqlite3_log() containing the current value of
25569 ** errno and, if possible, the human-readable equivalent from strerror() or
25570 ** strerror_r().
25572 ** The first argument passed to the macro should be the error code that
25573 ** will be returned to SQLite (e.g. SQLITE_IOERR_DELETE, SQLITE_CANTOPEN).
25574 ** The two subsequent arguments should be the name of the OS function that
25575 ** failed (e.g. "unlink", "open") and the the associated file-system path,
25576 ** if any.
25578 #define unixLogError(a,b,c) unixLogErrorAtLine(a,b,c,__LINE__)
25579 static int unixLogErrorAtLine(
25580 int errcode, /* SQLite error code */
25581 const char *zFunc, /* Name of OS function that failed */
25582 const char *zPath, /* File path associated with error */
25583 int iLine /* Source line number where error occurred */
25585 char *zErr; /* Message from strerror() or equivalent */
25586 int iErrno = errno; /* Saved syscall error number */
25588 /* If this is not a threadsafe build (SQLITE_THREADSAFE==0), then use
25589 ** the strerror() function to obtain the human-readable error message
25590 ** equivalent to errno. Otherwise, use strerror_r().
25592 #if SQLITE_THREADSAFE && defined(HAVE_STRERROR_R)
25593 char aErr[80];
25594 memset(aErr, 0, sizeof(aErr));
25595 zErr = aErr;
25597 /* If STRERROR_R_CHAR_P (set by autoconf scripts) or __USE_GNU is defined,
25598 ** assume that the system provides the the GNU version of strerror_r() that
25599 ** returns a pointer to a buffer containing the error message. That pointer
25600 ** may point to aErr[], or it may point to some static storage somewhere.
25601 ** Otherwise, assume that the system provides the POSIX version of
25602 ** strerror_r(), which always writes an error message into aErr[].
25604 ** If the code incorrectly assumes that it is the POSIX version that is
25605 ** available, the error message will often be an empty string. Not a
25606 ** huge problem. Incorrectly concluding that the GNU version is available
25607 ** could lead to a segfault though.
25609 #if defined(STRERROR_R_CHAR_P) || defined(__USE_GNU)
25610 zErr =
25611 # endif
25612 strerror_r(iErrno, aErr, sizeof(aErr)-1);
25614 #elif SQLITE_THREADSAFE
25615 /* This is a threadsafe build, but strerror_r() is not available. */
25616 zErr = "";
25617 #else
25618 /* Non-threadsafe build, use strerror(). */
25619 zErr = strerror(iErrno);
25620 #endif
25622 assert( errcode!=SQLITE_OK );
25623 if( zPath==0 ) zPath = "";
25624 sqlite3_log(errcode,
25625 "os_unix.c:%d: (%d) %s(%s) - %s",
25626 iLine, iErrno, zFunc, zPath, zErr
25629 return errcode;
25633 ** Close a file descriptor.
25635 ** We assume that close() almost always works, since it is only in a
25636 ** very sick application or on a very sick platform that it might fail.
25637 ** If it does fail, simply leak the file descriptor, but do log the
25638 ** error.
25640 ** Note that it is not safe to retry close() after EINTR since the
25641 ** file descriptor might have already been reused by another thread.
25642 ** So we don't even try to recover from an EINTR. Just log the error
25643 ** and move on.
25645 static void robust_close(unixFile *pFile, int h, int lineno){
25646 if( osClose(h) ){
25647 unixLogErrorAtLine(SQLITE_IOERR_CLOSE, "close",
25648 pFile ? pFile->zPath : 0, lineno);
25653 ** Close all file descriptors accumuated in the unixInodeInfo->pUnused list.
25655 static void closePendingFds(unixFile *pFile){
25656 unixInodeInfo *pInode = pFile->pInode;
25657 UnixUnusedFd *p;
25658 UnixUnusedFd *pNext;
25659 for(p=pInode->pUnused; p; p=pNext){
25660 pNext = p->pNext;
25661 robust_close(pFile, p->fd, __LINE__);
25662 sqlite3_free(p);
25664 pInode->pUnused = 0;
25668 ** Release a unixInodeInfo structure previously allocated by findInodeInfo().
25670 ** The mutex entered using the unixEnterMutex() function must be held
25671 ** when this function is called.
25673 static void releaseInodeInfo(unixFile *pFile){
25674 unixInodeInfo *pInode = pFile->pInode;
25675 assert( unixMutexHeld() );
25676 if( ALWAYS(pInode) ){
25677 pInode->nRef--;
25678 if( pInode->nRef==0 ){
25679 assert( pInode->pShmNode==0 );
25680 closePendingFds(pFile);
25681 if( pInode->pPrev ){
25682 assert( pInode->pPrev->pNext==pInode );
25683 pInode->pPrev->pNext = pInode->pNext;
25684 }else{
25685 assert( inodeList==pInode );
25686 inodeList = pInode->pNext;
25688 if( pInode->pNext ){
25689 assert( pInode->pNext->pPrev==pInode );
25690 pInode->pNext->pPrev = pInode->pPrev;
25692 sqlite3_free(pInode);
25698 ** Given a file descriptor, locate the unixInodeInfo object that
25699 ** describes that file descriptor. Create a new one if necessary. The
25700 ** return value might be uninitialized if an error occurs.
25702 ** The mutex entered using the unixEnterMutex() function must be held
25703 ** when this function is called.
25705 ** Return an appropriate error code.
25707 static int findInodeInfo(
25708 unixFile *pFile, /* Unix file with file desc used in the key */
25709 unixInodeInfo **ppInode /* Return the unixInodeInfo object here */
25711 int rc; /* System call return code */
25712 int fd; /* The file descriptor for pFile */
25713 struct unixFileId fileId; /* Lookup key for the unixInodeInfo */
25714 struct stat statbuf; /* Low-level file information */
25715 unixInodeInfo *pInode = 0; /* Candidate unixInodeInfo object */
25717 assert( unixMutexHeld() );
25719 /* Get low-level information about the file that we can used to
25720 ** create a unique name for the file.
25722 fd = pFile->h;
25723 rc = osFstat(fd, &statbuf);
25724 if( rc!=0 ){
25725 pFile->lastErrno = errno;
25726 #ifdef EOVERFLOW
25727 if( pFile->lastErrno==EOVERFLOW ) return SQLITE_NOLFS;
25728 #endif
25729 return SQLITE_IOERR;
25732 #ifdef __APPLE__
25733 /* On OS X on an msdos filesystem, the inode number is reported
25734 ** incorrectly for zero-size files. See ticket #3260. To work
25735 ** around this problem (we consider it a bug in OS X, not SQLite)
25736 ** we always increase the file size to 1 by writing a single byte
25737 ** prior to accessing the inode number. The one byte written is
25738 ** an ASCII 'S' character which also happens to be the first byte
25739 ** in the header of every SQLite database. In this way, if there
25740 ** is a race condition such that another thread has already populated
25741 ** the first page of the database, no damage is done.
25743 if( statbuf.st_size==0 && (pFile->fsFlags & SQLITE_FSFLAGS_IS_MSDOS)!=0 ){
25744 do{ rc = osWrite(fd, "S", 1); }while( rc<0 && errno==EINTR );
25745 if( rc!=1 ){
25746 pFile->lastErrno = errno;
25747 return SQLITE_IOERR;
25749 rc = osFstat(fd, &statbuf);
25750 if( rc!=0 ){
25751 pFile->lastErrno = errno;
25752 return SQLITE_IOERR;
25755 #endif
25757 memset(&fileId, 0, sizeof(fileId));
25758 fileId.dev = statbuf.st_dev;
25759 #if OS_VXWORKS
25760 fileId.pId = pFile->pId;
25761 #else
25762 fileId.ino = statbuf.st_ino;
25763 #endif
25764 pInode = inodeList;
25765 while( pInode && memcmp(&fileId, &pInode->fileId, sizeof(fileId)) ){
25766 pInode = pInode->pNext;
25768 if( pInode==0 ){
25769 pInode = sqlite3_malloc( sizeof(*pInode) );
25770 if( pInode==0 ){
25771 return SQLITE_NOMEM;
25773 memset(pInode, 0, sizeof(*pInode));
25774 memcpy(&pInode->fileId, &fileId, sizeof(fileId));
25775 pInode->nRef = 1;
25776 pInode->pNext = inodeList;
25777 pInode->pPrev = 0;
25778 if( inodeList ) inodeList->pPrev = pInode;
25779 inodeList = pInode;
25780 }else{
25781 pInode->nRef++;
25783 *ppInode = pInode;
25784 return SQLITE_OK;
25789 ** This routine checks if there is a RESERVED lock held on the specified
25790 ** file by this or any other process. If such a lock is held, set *pResOut
25791 ** to a non-zero value otherwise *pResOut is set to zero. The return value
25792 ** is set to SQLITE_OK unless an I/O error occurs during lock checking.
25794 static int unixCheckReservedLock(sqlite3_file *id, int *pResOut){
25795 int rc = SQLITE_OK;
25796 int reserved = 0;
25797 unixFile *pFile = (unixFile*)id;
25799 SimulateIOError( return SQLITE_IOERR_CHECKRESERVEDLOCK; );
25801 assert( pFile );
25802 unixEnterMutex(); /* Because pFile->pInode is shared across threads */
25804 /* Check if a thread in this process holds such a lock */
25805 if( pFile->pInode->eFileLock>SHARED_LOCK ){
25806 reserved = 1;
25809 /* Otherwise see if some other process holds it.
25811 #ifndef __DJGPP__
25812 if( !reserved && !pFile->pInode->bProcessLock ){
25813 struct flock lock;
25814 lock.l_whence = SEEK_SET;
25815 lock.l_start = RESERVED_BYTE;
25816 lock.l_len = 1;
25817 lock.l_type = F_WRLCK;
25818 if( osFcntl(pFile->h, F_GETLK, &lock) ){
25819 rc = SQLITE_IOERR_CHECKRESERVEDLOCK;
25820 pFile->lastErrno = errno;
25821 } else if( lock.l_type!=F_UNLCK ){
25822 reserved = 1;
25825 #endif
25827 unixLeaveMutex();
25828 OSTRACE(("TEST WR-LOCK %d %d %d (unix)\n", pFile->h, rc, reserved));
25830 *pResOut = reserved;
25831 return rc;
25835 ** Attempt to set a system-lock on the file pFile. The lock is
25836 ** described by pLock.
25838 ** If the pFile was opened read/write from unix-excl, then the only lock
25839 ** ever obtained is an exclusive lock, and it is obtained exactly once
25840 ** the first time any lock is attempted. All subsequent system locking
25841 ** operations become no-ops. Locking operations still happen internally,
25842 ** in order to coordinate access between separate database connections
25843 ** within this process, but all of that is handled in memory and the
25844 ** operating system does not participate.
25846 ** This function is a pass-through to fcntl(F_SETLK) if pFile is using
25847 ** any VFS other than "unix-excl" or if pFile is opened on "unix-excl"
25848 ** and is read-only.
25850 ** Zero is returned if the call completes successfully, or -1 if a call
25851 ** to fcntl() fails. In this case, errno is set appropriately (by fcntl()).
25853 static int unixFileLock(unixFile *pFile, struct flock *pLock){
25854 int rc;
25855 unixInodeInfo *pInode = pFile->pInode;
25856 assert( unixMutexHeld() );
25857 assert( pInode!=0 );
25858 if( ((pFile->ctrlFlags & UNIXFILE_EXCL)!=0 || pInode->bProcessLock)
25859 && ((pFile->ctrlFlags & UNIXFILE_RDONLY)==0)
25861 if( pInode->bProcessLock==0 ){
25862 struct flock lock;
25863 assert( pInode->nLock==0 );
25864 lock.l_whence = SEEK_SET;
25865 lock.l_start = SHARED_FIRST;
25866 lock.l_len = SHARED_SIZE;
25867 lock.l_type = F_WRLCK;
25868 rc = osFcntl(pFile->h, F_SETLK, &lock);
25869 if( rc<0 ) return rc;
25870 pInode->bProcessLock = 1;
25871 pInode->nLock++;
25872 }else{
25873 rc = 0;
25875 }else{
25876 rc = osFcntl(pFile->h, F_SETLK, pLock);
25878 return rc;
25882 ** Lock the file with the lock specified by parameter eFileLock - one
25883 ** of the following:
25885 ** (1) SHARED_LOCK
25886 ** (2) RESERVED_LOCK
25887 ** (3) PENDING_LOCK
25888 ** (4) EXCLUSIVE_LOCK
25890 ** Sometimes when requesting one lock state, additional lock states
25891 ** are inserted in between. The locking might fail on one of the later
25892 ** transitions leaving the lock state different from what it started but
25893 ** still short of its goal. The following chart shows the allowed
25894 ** transitions and the inserted intermediate states:
25896 ** UNLOCKED -> SHARED
25897 ** SHARED -> RESERVED
25898 ** SHARED -> (PENDING) -> EXCLUSIVE
25899 ** RESERVED -> (PENDING) -> EXCLUSIVE
25900 ** PENDING -> EXCLUSIVE
25902 ** This routine will only increase a lock. Use the sqlite3OsUnlock()
25903 ** routine to lower a locking level.
25905 static int unixLock(sqlite3_file *id, int eFileLock){
25906 /* The following describes the implementation of the various locks and
25907 ** lock transitions in terms of the POSIX advisory shared and exclusive
25908 ** lock primitives (called read-locks and write-locks below, to avoid
25909 ** confusion with SQLite lock names). The algorithms are complicated
25910 ** slightly in order to be compatible with windows systems simultaneously
25911 ** accessing the same database file, in case that is ever required.
25913 ** Symbols defined in os.h indentify the 'pending byte' and the 'reserved
25914 ** byte', each single bytes at well known offsets, and the 'shared byte
25915 ** range', a range of 510 bytes at a well known offset.
25917 ** To obtain a SHARED lock, a read-lock is obtained on the 'pending
25918 ** byte'. If this is successful, a random byte from the 'shared byte
25919 ** range' is read-locked and the lock on the 'pending byte' released.
25921 ** A process may only obtain a RESERVED lock after it has a SHARED lock.
25922 ** A RESERVED lock is implemented by grabbing a write-lock on the
25923 ** 'reserved byte'.
25925 ** A process may only obtain a PENDING lock after it has obtained a
25926 ** SHARED lock. A PENDING lock is implemented by obtaining a write-lock
25927 ** on the 'pending byte'. This ensures that no new SHARED locks can be
25928 ** obtained, but existing SHARED locks are allowed to persist. A process
25929 ** does not have to obtain a RESERVED lock on the way to a PENDING lock.
25930 ** This property is used by the algorithm for rolling back a journal file
25931 ** after a crash.
25933 ** An EXCLUSIVE lock, obtained after a PENDING lock is held, is
25934 ** implemented by obtaining a write-lock on the entire 'shared byte
25935 ** range'. Since all other locks require a read-lock on one of the bytes
25936 ** within this range, this ensures that no other locks are held on the
25937 ** database.
25939 ** The reason a single byte cannot be used instead of the 'shared byte
25940 ** range' is that some versions of windows do not support read-locks. By
25941 ** locking a random byte from a range, concurrent SHARED locks may exist
25942 ** even if the locking primitive used is always a write-lock.
25944 int rc = SQLITE_OK;
25945 unixFile *pFile = (unixFile*)id;
25946 unixInodeInfo *pInode = pFile->pInode;
25947 struct flock lock;
25948 int tErrno = 0;
25950 assert( pFile );
25951 OSTRACE(("LOCK %d %s was %s(%s,%d) pid=%d (unix)\n", pFile->h,
25952 azFileLock(eFileLock), azFileLock(pFile->eFileLock),
25953 azFileLock(pInode->eFileLock), pInode->nShared , getpid()));
25955 /* If there is already a lock of this type or more restrictive on the
25956 ** unixFile, do nothing. Don't use the end_lock: exit path, as
25957 ** unixEnterMutex() hasn't been called yet.
25959 if( pFile->eFileLock>=eFileLock ){
25960 OSTRACE(("LOCK %d %s ok (already held) (unix)\n", pFile->h,
25961 azFileLock(eFileLock)));
25962 return SQLITE_OK;
25965 /* Make sure the locking sequence is correct.
25966 ** (1) We never move from unlocked to anything higher than shared lock.
25967 ** (2) SQLite never explicitly requests a pendig lock.
25968 ** (3) A shared lock is always held when a reserve lock is requested.
25970 assert( pFile->eFileLock!=NO_LOCK || eFileLock==SHARED_LOCK );
25971 assert( eFileLock!=PENDING_LOCK );
25972 assert( eFileLock!=RESERVED_LOCK || pFile->eFileLock==SHARED_LOCK );
25974 /* This mutex is needed because pFile->pInode is shared across threads
25976 unixEnterMutex();
25977 pInode = pFile->pInode;
25979 /* If some thread using this PID has a lock via a different unixFile*
25980 ** handle that precludes the requested lock, return BUSY.
25982 if( (pFile->eFileLock!=pInode->eFileLock &&
25983 (pInode->eFileLock>=PENDING_LOCK || eFileLock>SHARED_LOCK))
25985 rc = SQLITE_BUSY;
25986 goto end_lock;
25989 /* If a SHARED lock is requested, and some thread using this PID already
25990 ** has a SHARED or RESERVED lock, then increment reference counts and
25991 ** return SQLITE_OK.
25993 if( eFileLock==SHARED_LOCK &&
25994 (pInode->eFileLock==SHARED_LOCK || pInode->eFileLock==RESERVED_LOCK) ){
25995 assert( eFileLock==SHARED_LOCK );
25996 assert( pFile->eFileLock==0 );
25997 assert( pInode->nShared>0 );
25998 pFile->eFileLock = SHARED_LOCK;
25999 pInode->nShared++;
26000 pInode->nLock++;
26001 goto end_lock;
26005 /* A PENDING lock is needed before acquiring a SHARED lock and before
26006 ** acquiring an EXCLUSIVE lock. For the SHARED lock, the PENDING will
26007 ** be released.
26009 lock.l_len = 1L;
26010 lock.l_whence = SEEK_SET;
26011 if( eFileLock==SHARED_LOCK
26012 || (eFileLock==EXCLUSIVE_LOCK && pFile->eFileLock<PENDING_LOCK)
26014 lock.l_type = (eFileLock==SHARED_LOCK?F_RDLCK:F_WRLCK);
26015 lock.l_start = PENDING_BYTE;
26016 if( unixFileLock(pFile, &lock) ){
26017 tErrno = errno;
26018 rc = sqliteErrorFromPosixError(tErrno, SQLITE_IOERR_LOCK);
26019 if( rc!=SQLITE_BUSY ){
26020 pFile->lastErrno = tErrno;
26022 goto end_lock;
26027 /* If control gets to this point, then actually go ahead and make
26028 ** operating system calls for the specified lock.
26030 if( eFileLock==SHARED_LOCK ){
26031 assert( pInode->nShared==0 );
26032 assert( pInode->eFileLock==0 );
26033 assert( rc==SQLITE_OK );
26035 /* Now get the read-lock */
26036 lock.l_start = SHARED_FIRST;
26037 lock.l_len = SHARED_SIZE;
26038 if( unixFileLock(pFile, &lock) ){
26039 tErrno = errno;
26040 rc = sqliteErrorFromPosixError(tErrno, SQLITE_IOERR_LOCK);
26043 /* Drop the temporary PENDING lock */
26044 lock.l_start = PENDING_BYTE;
26045 lock.l_len = 1L;
26046 lock.l_type = F_UNLCK;
26047 if( unixFileLock(pFile, &lock) && rc==SQLITE_OK ){
26048 /* This could happen with a network mount */
26049 tErrno = errno;
26050 rc = SQLITE_IOERR_UNLOCK;
26053 if( rc ){
26054 if( rc!=SQLITE_BUSY ){
26055 pFile->lastErrno = tErrno;
26057 goto end_lock;
26058 }else{
26059 pFile->eFileLock = SHARED_LOCK;
26060 pInode->nLock++;
26061 pInode->nShared = 1;
26063 }else if( eFileLock==EXCLUSIVE_LOCK && pInode->nShared>1 ){
26064 /* We are trying for an exclusive lock but another thread in this
26065 ** same process is still holding a shared lock. */
26066 rc = SQLITE_BUSY;
26067 }else{
26068 /* The request was for a RESERVED or EXCLUSIVE lock. It is
26069 ** assumed that there is a SHARED or greater lock on the file
26070 ** already.
26072 assert( 0!=pFile->eFileLock );
26073 lock.l_type = F_WRLCK;
26075 assert( eFileLock==RESERVED_LOCK || eFileLock==EXCLUSIVE_LOCK );
26076 if( eFileLock==RESERVED_LOCK ){
26077 lock.l_start = RESERVED_BYTE;
26078 lock.l_len = 1L;
26079 }else{
26080 lock.l_start = SHARED_FIRST;
26081 lock.l_len = SHARED_SIZE;
26084 if( unixFileLock(pFile, &lock) ){
26085 tErrno = errno;
26086 rc = sqliteErrorFromPosixError(tErrno, SQLITE_IOERR_LOCK);
26087 if( rc!=SQLITE_BUSY ){
26088 pFile->lastErrno = tErrno;
26094 #ifndef NDEBUG
26095 /* Set up the transaction-counter change checking flags when
26096 ** transitioning from a SHARED to a RESERVED lock. The change
26097 ** from SHARED to RESERVED marks the beginning of a normal
26098 ** write operation (not a hot journal rollback).
26100 if( rc==SQLITE_OK
26101 && pFile->eFileLock<=SHARED_LOCK
26102 && eFileLock==RESERVED_LOCK
26104 pFile->transCntrChng = 0;
26105 pFile->dbUpdate = 0;
26106 pFile->inNormalWrite = 1;
26108 #endif
26111 if( rc==SQLITE_OK ){
26112 pFile->eFileLock = eFileLock;
26113 pInode->eFileLock = eFileLock;
26114 }else if( eFileLock==EXCLUSIVE_LOCK ){
26115 pFile->eFileLock = PENDING_LOCK;
26116 pInode->eFileLock = PENDING_LOCK;
26119 end_lock:
26120 unixLeaveMutex();
26121 OSTRACE(("LOCK %d %s %s (unix)\n", pFile->h, azFileLock(eFileLock),
26122 rc==SQLITE_OK ? "ok" : "failed"));
26123 return rc;
26127 ** Add the file descriptor used by file handle pFile to the corresponding
26128 ** pUnused list.
26130 static void setPendingFd(unixFile *pFile){
26131 unixInodeInfo *pInode = pFile->pInode;
26132 UnixUnusedFd *p = pFile->pUnused;
26133 p->pNext = pInode->pUnused;
26134 pInode->pUnused = p;
26135 pFile->h = -1;
26136 pFile->pUnused = 0;
26140 ** Lower the locking level on file descriptor pFile to eFileLock. eFileLock
26141 ** must be either NO_LOCK or SHARED_LOCK.
26143 ** If the locking level of the file descriptor is already at or below
26144 ** the requested locking level, this routine is a no-op.
26146 ** If handleNFSUnlock is true, then on downgrading an EXCLUSIVE_LOCK to SHARED
26147 ** the byte range is divided into 2 parts and the first part is unlocked then
26148 ** set to a read lock, then the other part is simply unlocked. This works
26149 ** around a bug in BSD NFS lockd (also seen on MacOSX 10.3+) that fails to
26150 ** remove the write lock on a region when a read lock is set.
26152 static int posixUnlock(sqlite3_file *id, int eFileLock, int handleNFSUnlock){
26153 unixFile *pFile = (unixFile*)id;
26154 unixInodeInfo *pInode;
26155 struct flock lock;
26156 int rc = SQLITE_OK;
26157 int h;
26159 assert( pFile );
26160 OSTRACE(("UNLOCK %d %d was %d(%d,%d) pid=%d (unix)\n", pFile->h, eFileLock,
26161 pFile->eFileLock, pFile->pInode->eFileLock, pFile->pInode->nShared,
26162 getpid()));
26164 assert( eFileLock<=SHARED_LOCK );
26165 if( pFile->eFileLock<=eFileLock ){
26166 return SQLITE_OK;
26168 unixEnterMutex();
26169 h = pFile->h;
26170 pInode = pFile->pInode;
26171 assert( pInode->nShared!=0 );
26172 if( pFile->eFileLock>SHARED_LOCK ){
26173 assert( pInode->eFileLock==pFile->eFileLock );
26174 SimulateIOErrorBenign(1);
26175 SimulateIOError( h=(-1) )
26176 SimulateIOErrorBenign(0);
26178 #ifndef NDEBUG
26179 /* When reducing a lock such that other processes can start
26180 ** reading the database file again, make sure that the
26181 ** transaction counter was updated if any part of the database
26182 ** file changed. If the transaction counter is not updated,
26183 ** other connections to the same file might not realize that
26184 ** the file has changed and hence might not know to flush their
26185 ** cache. The use of a stale cache can lead to database corruption.
26187 #if 0
26188 assert( pFile->inNormalWrite==0
26189 || pFile->dbUpdate==0
26190 || pFile->transCntrChng==1 );
26191 #endif
26192 pFile->inNormalWrite = 0;
26193 #endif
26195 /* downgrading to a shared lock on NFS involves clearing the write lock
26196 ** before establishing the readlock - to avoid a race condition we downgrade
26197 ** the lock in 2 blocks, so that part of the range will be covered by a
26198 ** write lock until the rest is covered by a read lock:
26199 ** 1: [WWWWW]
26200 ** 2: [....W]
26201 ** 3: [RRRRW]
26202 ** 4: [RRRR.]
26204 if( eFileLock==SHARED_LOCK ){
26206 #if !defined(__APPLE__) || !SQLITE_ENABLE_LOCKING_STYLE
26207 (void)handleNFSUnlock;
26208 assert( handleNFSUnlock==0 );
26209 #endif
26210 #if defined(__APPLE__) && SQLITE_ENABLE_LOCKING_STYLE
26211 if( handleNFSUnlock ){
26212 int tErrno; /* Error code from system call errors */
26213 off_t divSize = SHARED_SIZE - 1;
26215 lock.l_type = F_UNLCK;
26216 lock.l_whence = SEEK_SET;
26217 lock.l_start = SHARED_FIRST;
26218 lock.l_len = divSize;
26219 if( unixFileLock(pFile, &lock)==(-1) ){
26220 tErrno = errno;
26221 rc = SQLITE_IOERR_UNLOCK;
26222 if( IS_LOCK_ERROR(rc) ){
26223 pFile->lastErrno = tErrno;
26225 goto end_unlock;
26227 lock.l_type = F_RDLCK;
26228 lock.l_whence = SEEK_SET;
26229 lock.l_start = SHARED_FIRST;
26230 lock.l_len = divSize;
26231 if( unixFileLock(pFile, &lock)==(-1) ){
26232 tErrno = errno;
26233 rc = sqliteErrorFromPosixError(tErrno, SQLITE_IOERR_RDLOCK);
26234 if( IS_LOCK_ERROR(rc) ){
26235 pFile->lastErrno = tErrno;
26237 goto end_unlock;
26239 lock.l_type = F_UNLCK;
26240 lock.l_whence = SEEK_SET;
26241 lock.l_start = SHARED_FIRST+divSize;
26242 lock.l_len = SHARED_SIZE-divSize;
26243 if( unixFileLock(pFile, &lock)==(-1) ){
26244 tErrno = errno;
26245 rc = SQLITE_IOERR_UNLOCK;
26246 if( IS_LOCK_ERROR(rc) ){
26247 pFile->lastErrno = tErrno;
26249 goto end_unlock;
26251 }else
26252 #endif /* defined(__APPLE__) && SQLITE_ENABLE_LOCKING_STYLE */
26254 lock.l_type = F_RDLCK;
26255 lock.l_whence = SEEK_SET;
26256 lock.l_start = SHARED_FIRST;
26257 lock.l_len = SHARED_SIZE;
26258 if( unixFileLock(pFile, &lock) ){
26259 /* In theory, the call to unixFileLock() cannot fail because another
26260 ** process is holding an incompatible lock. If it does, this
26261 ** indicates that the other process is not following the locking
26262 ** protocol. If this happens, return SQLITE_IOERR_RDLOCK. Returning
26263 ** SQLITE_BUSY would confuse the upper layer (in practice it causes
26264 ** an assert to fail). */
26265 rc = SQLITE_IOERR_RDLOCK;
26266 pFile->lastErrno = errno;
26267 goto end_unlock;
26271 lock.l_type = F_UNLCK;
26272 lock.l_whence = SEEK_SET;
26273 lock.l_start = PENDING_BYTE;
26274 lock.l_len = 2L; assert( PENDING_BYTE+1==RESERVED_BYTE );
26275 if( unixFileLock(pFile, &lock)==0 ){
26276 pInode->eFileLock = SHARED_LOCK;
26277 }else{
26278 rc = SQLITE_IOERR_UNLOCK;
26279 pFile->lastErrno = errno;
26280 goto end_unlock;
26283 if( eFileLock==NO_LOCK ){
26284 /* Decrement the shared lock counter. Release the lock using an
26285 ** OS call only when all threads in this same process have released
26286 ** the lock.
26288 pInode->nShared--;
26289 if( pInode->nShared==0 ){
26290 lock.l_type = F_UNLCK;
26291 lock.l_whence = SEEK_SET;
26292 lock.l_start = lock.l_len = 0L;
26293 SimulateIOErrorBenign(1);
26294 SimulateIOError( h=(-1) )
26295 SimulateIOErrorBenign(0);
26296 if( unixFileLock(pFile, &lock)==0 ){
26297 pInode->eFileLock = NO_LOCK;
26298 }else{
26299 rc = SQLITE_IOERR_UNLOCK;
26300 pFile->lastErrno = errno;
26301 pInode->eFileLock = NO_LOCK;
26302 pFile->eFileLock = NO_LOCK;
26306 /* Decrement the count of locks against this same file. When the
26307 ** count reaches zero, close any other file descriptors whose close
26308 ** was deferred because of outstanding locks.
26310 pInode->nLock--;
26311 assert( pInode->nLock>=0 );
26312 if( pInode->nLock==0 ){
26313 closePendingFds(pFile);
26317 end_unlock:
26318 unixLeaveMutex();
26319 if( rc==SQLITE_OK ) pFile->eFileLock = eFileLock;
26320 return rc;
26324 ** Lower the locking level on file descriptor pFile to eFileLock. eFileLock
26325 ** must be either NO_LOCK or SHARED_LOCK.
26327 ** If the locking level of the file descriptor is already at or below
26328 ** the requested locking level, this routine is a no-op.
26330 static int unixUnlock(sqlite3_file *id, int eFileLock){
26331 return posixUnlock(id, eFileLock, 0);
26335 ** This function performs the parts of the "close file" operation
26336 ** common to all locking schemes. It closes the directory and file
26337 ** handles, if they are valid, and sets all fields of the unixFile
26338 ** structure to 0.
26340 ** It is *not* necessary to hold the mutex when this routine is called,
26341 ** even on VxWorks. A mutex will be acquired on VxWorks by the
26342 ** vxworksReleaseFileId() routine.
26344 static int closeUnixFile(sqlite3_file *id){
26345 unixFile *pFile = (unixFile*)id;
26346 if( pFile->h>=0 ){
26347 robust_close(pFile, pFile->h, __LINE__);
26348 pFile->h = -1;
26350 #if OS_VXWORKS
26351 if( pFile->pId ){
26352 if( pFile->isDelete ){
26353 osUnlink(pFile->pId->zCanonicalName);
26355 vxworksReleaseFileId(pFile->pId);
26356 pFile->pId = 0;
26358 #endif
26359 OSTRACE(("CLOSE %-3d\n", pFile->h));
26360 OpenCounter(-1);
26361 sqlite3_free(pFile->pUnused);
26362 memset(pFile, 0, sizeof(unixFile));
26363 return SQLITE_OK;
26367 ** Close a file.
26369 static int unixClose(sqlite3_file *id){
26370 int rc = SQLITE_OK;
26371 unixFile *pFile = (unixFile *)id;
26372 unixUnlock(id, NO_LOCK);
26373 unixEnterMutex();
26375 /* unixFile.pInode is always valid here. Otherwise, a different close
26376 ** routine (e.g. nolockClose()) would be called instead.
26378 assert( pFile->pInode->nLock>0 || pFile->pInode->bProcessLock==0 );
26379 if( ALWAYS(pFile->pInode) && pFile->pInode->nLock ){
26380 /* If there are outstanding locks, do not actually close the file just
26381 ** yet because that would clear those locks. Instead, add the file
26382 ** descriptor to pInode->pUnused list. It will be automatically closed
26383 ** when the last lock is cleared.
26385 setPendingFd(pFile);
26387 releaseInodeInfo(pFile);
26388 rc = closeUnixFile(id);
26389 unixLeaveMutex();
26390 return rc;
26393 /************** End of the posix advisory lock implementation *****************
26394 ******************************************************************************/
26396 /******************************************************************************
26397 ****************************** No-op Locking **********************************
26399 ** Of the various locking implementations available, this is by far the
26400 ** simplest: locking is ignored. No attempt is made to lock the database
26401 ** file for reading or writing.
26403 ** This locking mode is appropriate for use on read-only databases
26404 ** (ex: databases that are burned into CD-ROM, for example.) It can
26405 ** also be used if the application employs some external mechanism to
26406 ** prevent simultaneous access of the same database by two or more
26407 ** database connections. But there is a serious risk of database
26408 ** corruption if this locking mode is used in situations where multiple
26409 ** database connections are accessing the same database file at the same
26410 ** time and one or more of those connections are writing.
26413 static int nolockCheckReservedLock(sqlite3_file *NotUsed, int *pResOut){
26414 UNUSED_PARAMETER(NotUsed);
26415 *pResOut = 0;
26416 return SQLITE_OK;
26418 static int nolockLock(sqlite3_file *NotUsed, int NotUsed2){
26419 UNUSED_PARAMETER2(NotUsed, NotUsed2);
26420 return SQLITE_OK;
26422 static int nolockUnlock(sqlite3_file *NotUsed, int NotUsed2){
26423 UNUSED_PARAMETER2(NotUsed, NotUsed2);
26424 return SQLITE_OK;
26428 ** Close the file.
26430 static int nolockClose(sqlite3_file *id) {
26431 return closeUnixFile(id);
26434 /******************* End of the no-op lock implementation *********************
26435 ******************************************************************************/
26437 /******************************************************************************
26438 ************************* Begin dot-file Locking ******************************
26440 ** The dotfile locking implementation uses the existance of separate lock
26441 ** files in order to control access to the database. This works on just
26442 ** about every filesystem imaginable. But there are serious downsides:
26444 ** (1) There is zero concurrency. A single reader blocks all other
26445 ** connections from reading or writing the database.
26447 ** (2) An application crash or power loss can leave stale lock files
26448 ** sitting around that need to be cleared manually.
26450 ** Nevertheless, a dotlock is an appropriate locking mode for use if no
26451 ** other locking strategy is available.
26453 ** Dotfile locking works by creating a file in the same directory as the
26454 ** database and with the same name but with a ".lock" extension added.
26455 ** The existance of a lock file implies an EXCLUSIVE lock. All other lock
26456 ** types (SHARED, RESERVED, PENDING) are mapped into EXCLUSIVE.
26460 ** The file suffix added to the data base filename in order to create the
26461 ** lock file.
26463 #define DOTLOCK_SUFFIX ".lock"
26466 ** This routine checks if there is a RESERVED lock held on the specified
26467 ** file by this or any other process. If such a lock is held, set *pResOut
26468 ** to a non-zero value otherwise *pResOut is set to zero. The return value
26469 ** is set to SQLITE_OK unless an I/O error occurs during lock checking.
26471 ** In dotfile locking, either a lock exists or it does not. So in this
26472 ** variation of CheckReservedLock(), *pResOut is set to true if any lock
26473 ** is held on the file and false if the file is unlocked.
26475 static int dotlockCheckReservedLock(sqlite3_file *id, int *pResOut) {
26476 int rc = SQLITE_OK;
26477 int reserved = 0;
26478 unixFile *pFile = (unixFile*)id;
26480 SimulateIOError( return SQLITE_IOERR_CHECKRESERVEDLOCK; );
26482 assert( pFile );
26484 /* Check if a thread in this process holds such a lock */
26485 if( pFile->eFileLock>SHARED_LOCK ){
26486 /* Either this connection or some other connection in the same process
26487 ** holds a lock on the file. No need to check further. */
26488 reserved = 1;
26489 }else{
26490 /* The lock is held if and only if the lockfile exists */
26491 const char *zLockFile = (const char*)pFile->lockingContext;
26492 reserved = osAccess(zLockFile, 0)==0;
26494 OSTRACE(("TEST WR-LOCK %d %d %d (dotlock)\n", pFile->h, rc, reserved));
26495 *pResOut = reserved;
26496 return rc;
26500 ** Lock the file with the lock specified by parameter eFileLock - one
26501 ** of the following:
26503 ** (1) SHARED_LOCK
26504 ** (2) RESERVED_LOCK
26505 ** (3) PENDING_LOCK
26506 ** (4) EXCLUSIVE_LOCK
26508 ** Sometimes when requesting one lock state, additional lock states
26509 ** are inserted in between. The locking might fail on one of the later
26510 ** transitions leaving the lock state different from what it started but
26511 ** still short of its goal. The following chart shows the allowed
26512 ** transitions and the inserted intermediate states:
26514 ** UNLOCKED -> SHARED
26515 ** SHARED -> RESERVED
26516 ** SHARED -> (PENDING) -> EXCLUSIVE
26517 ** RESERVED -> (PENDING) -> EXCLUSIVE
26518 ** PENDING -> EXCLUSIVE
26520 ** This routine will only increase a lock. Use the sqlite3OsUnlock()
26521 ** routine to lower a locking level.
26523 ** With dotfile locking, we really only support state (4): EXCLUSIVE.
26524 ** But we track the other locking levels internally.
26526 static int dotlockLock(sqlite3_file *id, int eFileLock) {
26527 unixFile *pFile = (unixFile*)id;
26528 int fd;
26529 char *zLockFile = (char *)pFile->lockingContext;
26530 int rc = SQLITE_OK;
26533 /* If we have any lock, then the lock file already exists. All we have
26534 ** to do is adjust our internal record of the lock level.
26536 if( pFile->eFileLock > NO_LOCK ){
26537 pFile->eFileLock = eFileLock;
26538 /* Always update the timestamp on the old file */
26539 #ifdef HAVE_UTIME
26540 utime(zLockFile, NULL);
26541 #else
26542 utimes(zLockFile, NULL);
26543 #endif
26544 return SQLITE_OK;
26547 /* grab an exclusive lock */
26548 fd = robust_open(zLockFile,O_RDONLY|O_CREAT|O_EXCL,0600);
26549 if( fd<0 ){
26550 /* failed to open/create the file, someone else may have stolen the lock */
26551 int tErrno = errno;
26552 if( EEXIST == tErrno ){
26553 rc = SQLITE_BUSY;
26554 } else {
26555 rc = sqliteErrorFromPosixError(tErrno, SQLITE_IOERR_LOCK);
26556 if( IS_LOCK_ERROR(rc) ){
26557 pFile->lastErrno = tErrno;
26560 return rc;
26562 robust_close(pFile, fd, __LINE__);
26564 /* got it, set the type and return ok */
26565 pFile->eFileLock = eFileLock;
26566 return rc;
26570 ** Lower the locking level on file descriptor pFile to eFileLock. eFileLock
26571 ** must be either NO_LOCK or SHARED_LOCK.
26573 ** If the locking level of the file descriptor is already at or below
26574 ** the requested locking level, this routine is a no-op.
26576 ** When the locking level reaches NO_LOCK, delete the lock file.
26578 static int dotlockUnlock(sqlite3_file *id, int eFileLock) {
26579 unixFile *pFile = (unixFile*)id;
26580 char *zLockFile = (char *)pFile->lockingContext;
26582 assert( pFile );
26583 OSTRACE(("UNLOCK %d %d was %d pid=%d (dotlock)\n", pFile->h, eFileLock,
26584 pFile->eFileLock, getpid()));
26585 assert( eFileLock<=SHARED_LOCK );
26587 /* no-op if possible */
26588 if( pFile->eFileLock==eFileLock ){
26589 return SQLITE_OK;
26592 /* To downgrade to shared, simply update our internal notion of the
26593 ** lock state. No need to mess with the file on disk.
26595 if( eFileLock==SHARED_LOCK ){
26596 pFile->eFileLock = SHARED_LOCK;
26597 return SQLITE_OK;
26600 /* To fully unlock the database, delete the lock file */
26601 assert( eFileLock==NO_LOCK );
26602 if( osUnlink(zLockFile) ){
26603 int rc = 0;
26604 int tErrno = errno;
26605 if( ENOENT != tErrno ){
26606 rc = SQLITE_IOERR_UNLOCK;
26608 if( IS_LOCK_ERROR(rc) ){
26609 pFile->lastErrno = tErrno;
26611 return rc;
26613 pFile->eFileLock = NO_LOCK;
26614 return SQLITE_OK;
26618 ** Close a file. Make sure the lock has been released before closing.
26620 static int dotlockClose(sqlite3_file *id) {
26621 int rc;
26622 if( id ){
26623 unixFile *pFile = (unixFile*)id;
26624 dotlockUnlock(id, NO_LOCK);
26625 sqlite3_free(pFile->lockingContext);
26627 rc = closeUnixFile(id);
26628 return rc;
26630 /****************** End of the dot-file lock implementation *******************
26631 ******************************************************************************/
26633 /******************************************************************************
26634 ************************** Begin flock Locking ********************************
26636 ** Use the flock() system call to do file locking.
26638 ** flock() locking is like dot-file locking in that the various
26639 ** fine-grain locking levels supported by SQLite are collapsed into
26640 ** a single exclusive lock. In other words, SHARED, RESERVED, and
26641 ** PENDING locks are the same thing as an EXCLUSIVE lock. SQLite
26642 ** still works when you do this, but concurrency is reduced since
26643 ** only a single process can be reading the database at a time.
26645 ** Omit this section if SQLITE_ENABLE_LOCKING_STYLE is turned off or if
26646 ** compiling for VXWORKS.
26648 #if SQLITE_ENABLE_LOCKING_STYLE && !OS_VXWORKS
26651 ** Retry flock() calls that fail with EINTR
26653 #ifdef EINTR
26654 static int robust_flock(int fd, int op){
26655 int rc;
26656 do{ rc = flock(fd,op); }while( rc<0 && errno==EINTR );
26657 return rc;
26659 #else
26660 # define robust_flock(a,b) flock(a,b)
26661 #endif
26665 ** This routine checks if there is a RESERVED lock held on the specified
26666 ** file by this or any other process. If such a lock is held, set *pResOut
26667 ** to a non-zero value otherwise *pResOut is set to zero. The return value
26668 ** is set to SQLITE_OK unless an I/O error occurs during lock checking.
26670 static int flockCheckReservedLock(sqlite3_file *id, int *pResOut){
26671 int rc = SQLITE_OK;
26672 int reserved = 0;
26673 unixFile *pFile = (unixFile*)id;
26675 SimulateIOError( return SQLITE_IOERR_CHECKRESERVEDLOCK; );
26677 assert( pFile );
26679 /* Check if a thread in this process holds such a lock */
26680 if( pFile->eFileLock>SHARED_LOCK ){
26681 reserved = 1;
26684 /* Otherwise see if some other process holds it. */
26685 if( !reserved ){
26686 /* attempt to get the lock */
26687 int lrc = robust_flock(pFile->h, LOCK_EX | LOCK_NB);
26688 if( !lrc ){
26689 /* got the lock, unlock it */
26690 lrc = robust_flock(pFile->h, LOCK_UN);
26691 if ( lrc ) {
26692 int tErrno = errno;
26693 /* unlock failed with an error */
26694 lrc = SQLITE_IOERR_UNLOCK;
26695 if( IS_LOCK_ERROR(lrc) ){
26696 pFile->lastErrno = tErrno;
26697 rc = lrc;
26700 } else {
26701 int tErrno = errno;
26702 reserved = 1;
26703 /* someone else might have it reserved */
26704 lrc = sqliteErrorFromPosixError(tErrno, SQLITE_IOERR_LOCK);
26705 if( IS_LOCK_ERROR(lrc) ){
26706 pFile->lastErrno = tErrno;
26707 rc = lrc;
26711 OSTRACE(("TEST WR-LOCK %d %d %d (flock)\n", pFile->h, rc, reserved));
26713 #ifdef SQLITE_IGNORE_FLOCK_LOCK_ERRORS
26714 if( (rc & SQLITE_IOERR) == SQLITE_IOERR ){
26715 rc = SQLITE_OK;
26716 reserved=1;
26718 #endif /* SQLITE_IGNORE_FLOCK_LOCK_ERRORS */
26719 *pResOut = reserved;
26720 return rc;
26724 ** Lock the file with the lock specified by parameter eFileLock - one
26725 ** of the following:
26727 ** (1) SHARED_LOCK
26728 ** (2) RESERVED_LOCK
26729 ** (3) PENDING_LOCK
26730 ** (4) EXCLUSIVE_LOCK
26732 ** Sometimes when requesting one lock state, additional lock states
26733 ** are inserted in between. The locking might fail on one of the later
26734 ** transitions leaving the lock state different from what it started but
26735 ** still short of its goal. The following chart shows the allowed
26736 ** transitions and the inserted intermediate states:
26738 ** UNLOCKED -> SHARED
26739 ** SHARED -> RESERVED
26740 ** SHARED -> (PENDING) -> EXCLUSIVE
26741 ** RESERVED -> (PENDING) -> EXCLUSIVE
26742 ** PENDING -> EXCLUSIVE
26744 ** flock() only really support EXCLUSIVE locks. We track intermediate
26745 ** lock states in the sqlite3_file structure, but all locks SHARED or
26746 ** above are really EXCLUSIVE locks and exclude all other processes from
26747 ** access the file.
26749 ** This routine will only increase a lock. Use the sqlite3OsUnlock()
26750 ** routine to lower a locking level.
26752 static int flockLock(sqlite3_file *id, int eFileLock) {
26753 int rc = SQLITE_OK;
26754 unixFile *pFile = (unixFile*)id;
26756 assert( pFile );
26758 /* if we already have a lock, it is exclusive.
26759 ** Just adjust level and punt on outta here. */
26760 if (pFile->eFileLock > NO_LOCK) {
26761 pFile->eFileLock = eFileLock;
26762 return SQLITE_OK;
26765 /* grab an exclusive lock */
26767 if (robust_flock(pFile->h, LOCK_EX | LOCK_NB)) {
26768 int tErrno = errno;
26769 /* didn't get, must be busy */
26770 rc = sqliteErrorFromPosixError(tErrno, SQLITE_IOERR_LOCK);
26771 if( IS_LOCK_ERROR(rc) ){
26772 pFile->lastErrno = tErrno;
26774 } else {
26775 /* got it, set the type and return ok */
26776 pFile->eFileLock = eFileLock;
26778 OSTRACE(("LOCK %d %s %s (flock)\n", pFile->h, azFileLock(eFileLock),
26779 rc==SQLITE_OK ? "ok" : "failed"));
26780 #ifdef SQLITE_IGNORE_FLOCK_LOCK_ERRORS
26781 if( (rc & SQLITE_IOERR) == SQLITE_IOERR ){
26782 rc = SQLITE_BUSY;
26784 #endif /* SQLITE_IGNORE_FLOCK_LOCK_ERRORS */
26785 return rc;
26790 ** Lower the locking level on file descriptor pFile to eFileLock. eFileLock
26791 ** must be either NO_LOCK or SHARED_LOCK.
26793 ** If the locking level of the file descriptor is already at or below
26794 ** the requested locking level, this routine is a no-op.
26796 static int flockUnlock(sqlite3_file *id, int eFileLock) {
26797 unixFile *pFile = (unixFile*)id;
26799 assert( pFile );
26800 OSTRACE(("UNLOCK %d %d was %d pid=%d (flock)\n", pFile->h, eFileLock,
26801 pFile->eFileLock, getpid()));
26802 assert( eFileLock<=SHARED_LOCK );
26804 /* no-op if possible */
26805 if( pFile->eFileLock==eFileLock ){
26806 return SQLITE_OK;
26809 /* shared can just be set because we always have an exclusive */
26810 if (eFileLock==SHARED_LOCK) {
26811 pFile->eFileLock = eFileLock;
26812 return SQLITE_OK;
26815 /* no, really, unlock. */
26816 if( robust_flock(pFile->h, LOCK_UN) ){
26817 #ifdef SQLITE_IGNORE_FLOCK_LOCK_ERRORS
26818 return SQLITE_OK;
26819 #endif /* SQLITE_IGNORE_FLOCK_LOCK_ERRORS */
26820 return SQLITE_IOERR_UNLOCK;
26821 }else{
26822 pFile->eFileLock = NO_LOCK;
26823 return SQLITE_OK;
26828 ** Close a file.
26830 static int flockClose(sqlite3_file *id) {
26831 if( id ){
26832 flockUnlock(id, NO_LOCK);
26834 return closeUnixFile(id);
26837 #endif /* SQLITE_ENABLE_LOCKING_STYLE && !OS_VXWORK */
26839 /******************* End of the flock lock implementation *********************
26840 ******************************************************************************/
26842 /******************************************************************************
26843 ************************ Begin Named Semaphore Locking ************************
26845 ** Named semaphore locking is only supported on VxWorks.
26847 ** Semaphore locking is like dot-lock and flock in that it really only
26848 ** supports EXCLUSIVE locking. Only a single process can read or write
26849 ** the database file at a time. This reduces potential concurrency, but
26850 ** makes the lock implementation much easier.
26852 #if OS_VXWORKS
26855 ** This routine checks if there is a RESERVED lock held on the specified
26856 ** file by this or any other process. If such a lock is held, set *pResOut
26857 ** to a non-zero value otherwise *pResOut is set to zero. The return value
26858 ** is set to SQLITE_OK unless an I/O error occurs during lock checking.
26860 static int semCheckReservedLock(sqlite3_file *id, int *pResOut) {
26861 int rc = SQLITE_OK;
26862 int reserved = 0;
26863 unixFile *pFile = (unixFile*)id;
26865 SimulateIOError( return SQLITE_IOERR_CHECKRESERVEDLOCK; );
26867 assert( pFile );
26869 /* Check if a thread in this process holds such a lock */
26870 if( pFile->eFileLock>SHARED_LOCK ){
26871 reserved = 1;
26874 /* Otherwise see if some other process holds it. */
26875 if( !reserved ){
26876 sem_t *pSem = pFile->pInode->pSem;
26877 struct stat statBuf;
26879 if( sem_trywait(pSem)==-1 ){
26880 int tErrno = errno;
26881 if( EAGAIN != tErrno ){
26882 rc = sqliteErrorFromPosixError(tErrno, SQLITE_IOERR_CHECKRESERVEDLOCK);
26883 pFile->lastErrno = tErrno;
26884 } else {
26885 /* someone else has the lock when we are in NO_LOCK */
26886 reserved = (pFile->eFileLock < SHARED_LOCK);
26888 }else{
26889 /* we could have it if we want it */
26890 sem_post(pSem);
26893 OSTRACE(("TEST WR-LOCK %d %d %d (sem)\n", pFile->h, rc, reserved));
26895 *pResOut = reserved;
26896 return rc;
26900 ** Lock the file with the lock specified by parameter eFileLock - one
26901 ** of the following:
26903 ** (1) SHARED_LOCK
26904 ** (2) RESERVED_LOCK
26905 ** (3) PENDING_LOCK
26906 ** (4) EXCLUSIVE_LOCK
26908 ** Sometimes when requesting one lock state, additional lock states
26909 ** are inserted in between. The locking might fail on one of the later
26910 ** transitions leaving the lock state different from what it started but
26911 ** still short of its goal. The following chart shows the allowed
26912 ** transitions and the inserted intermediate states:
26914 ** UNLOCKED -> SHARED
26915 ** SHARED -> RESERVED
26916 ** SHARED -> (PENDING) -> EXCLUSIVE
26917 ** RESERVED -> (PENDING) -> EXCLUSIVE
26918 ** PENDING -> EXCLUSIVE
26920 ** Semaphore locks only really support EXCLUSIVE locks. We track intermediate
26921 ** lock states in the sqlite3_file structure, but all locks SHARED or
26922 ** above are really EXCLUSIVE locks and exclude all other processes from
26923 ** access the file.
26925 ** This routine will only increase a lock. Use the sqlite3OsUnlock()
26926 ** routine to lower a locking level.
26928 static int semLock(sqlite3_file *id, int eFileLock) {
26929 unixFile *pFile = (unixFile*)id;
26930 int fd;
26931 sem_t *pSem = pFile->pInode->pSem;
26932 int rc = SQLITE_OK;
26934 /* if we already have a lock, it is exclusive.
26935 ** Just adjust level and punt on outta here. */
26936 if (pFile->eFileLock > NO_LOCK) {
26937 pFile->eFileLock = eFileLock;
26938 rc = SQLITE_OK;
26939 goto sem_end_lock;
26942 /* lock semaphore now but bail out when already locked. */
26943 if( sem_trywait(pSem)==-1 ){
26944 rc = SQLITE_BUSY;
26945 goto sem_end_lock;
26948 /* got it, set the type and return ok */
26949 pFile->eFileLock = eFileLock;
26951 sem_end_lock:
26952 return rc;
26956 ** Lower the locking level on file descriptor pFile to eFileLock. eFileLock
26957 ** must be either NO_LOCK or SHARED_LOCK.
26959 ** If the locking level of the file descriptor is already at or below
26960 ** the requested locking level, this routine is a no-op.
26962 static int semUnlock(sqlite3_file *id, int eFileLock) {
26963 unixFile *pFile = (unixFile*)id;
26964 sem_t *pSem = pFile->pInode->pSem;
26966 assert( pFile );
26967 assert( pSem );
26968 OSTRACE(("UNLOCK %d %d was %d pid=%d (sem)\n", pFile->h, eFileLock,
26969 pFile->eFileLock, getpid()));
26970 assert( eFileLock<=SHARED_LOCK );
26972 /* no-op if possible */
26973 if( pFile->eFileLock==eFileLock ){
26974 return SQLITE_OK;
26977 /* shared can just be set because we always have an exclusive */
26978 if (eFileLock==SHARED_LOCK) {
26979 pFile->eFileLock = eFileLock;
26980 return SQLITE_OK;
26983 /* no, really unlock. */
26984 if ( sem_post(pSem)==-1 ) {
26985 int rc, tErrno = errno;
26986 rc = sqliteErrorFromPosixError(tErrno, SQLITE_IOERR_UNLOCK);
26987 if( IS_LOCK_ERROR(rc) ){
26988 pFile->lastErrno = tErrno;
26990 return rc;
26992 pFile->eFileLock = NO_LOCK;
26993 return SQLITE_OK;
26997 ** Close a file.
26999 static int semClose(sqlite3_file *id) {
27000 if( id ){
27001 unixFile *pFile = (unixFile*)id;
27002 semUnlock(id, NO_LOCK);
27003 assert( pFile );
27004 unixEnterMutex();
27005 releaseInodeInfo(pFile);
27006 unixLeaveMutex();
27007 closeUnixFile(id);
27009 return SQLITE_OK;
27012 #endif /* OS_VXWORKS */
27014 ** Named semaphore locking is only available on VxWorks.
27016 *************** End of the named semaphore lock implementation ****************
27017 ******************************************************************************/
27020 /******************************************************************************
27021 *************************** Begin AFP Locking *********************************
27023 ** AFP is the Apple Filing Protocol. AFP is a network filesystem found
27024 ** on Apple Macintosh computers - both OS9 and OSX.
27026 ** Third-party implementations of AFP are available. But this code here
27027 ** only works on OSX.
27030 #if defined(__APPLE__) && SQLITE_ENABLE_LOCKING_STYLE
27032 ** The afpLockingContext structure contains all afp lock specific state
27034 typedef struct afpLockingContext afpLockingContext;
27035 struct afpLockingContext {
27036 int reserved;
27037 const char *dbPath; /* Name of the open file */
27040 struct ByteRangeLockPB2
27042 unsigned long long offset; /* offset to first byte to lock */
27043 unsigned long long length; /* nbr of bytes to lock */
27044 unsigned long long retRangeStart; /* nbr of 1st byte locked if successful */
27045 unsigned char unLockFlag; /* 1 = unlock, 0 = lock */
27046 unsigned char startEndFlag; /* 1=rel to end of fork, 0=rel to start */
27047 int fd; /* file desc to assoc this lock with */
27050 #define afpfsByteRangeLock2FSCTL _IOWR('z', 23, struct ByteRangeLockPB2)
27053 ** This is a utility for setting or clearing a bit-range lock on an
27054 ** AFP filesystem.
27056 ** Return SQLITE_OK on success, SQLITE_BUSY on failure.
27058 static int afpSetLock(
27059 const char *path, /* Name of the file to be locked or unlocked */
27060 unixFile *pFile, /* Open file descriptor on path */
27061 unsigned long long offset, /* First byte to be locked */
27062 unsigned long long length, /* Number of bytes to lock */
27063 int setLockFlag /* True to set lock. False to clear lock */
27065 struct ByteRangeLockPB2 pb;
27066 int err;
27068 pb.unLockFlag = setLockFlag ? 0 : 1;
27069 pb.startEndFlag = 0;
27070 pb.offset = offset;
27071 pb.length = length;
27072 pb.fd = pFile->h;
27074 OSTRACE(("AFPSETLOCK [%s] for %d%s in range %llx:%llx\n",
27075 (setLockFlag?"ON":"OFF"), pFile->h, (pb.fd==-1?"[testval-1]":""),
27076 offset, length));
27077 err = fsctl(path, afpfsByteRangeLock2FSCTL, &pb, 0);
27078 if ( err==-1 ) {
27079 int rc;
27080 int tErrno = errno;
27081 OSTRACE(("AFPSETLOCK failed to fsctl() '%s' %d %s\n",
27082 path, tErrno, strerror(tErrno)));
27083 #ifdef SQLITE_IGNORE_AFP_LOCK_ERRORS
27084 rc = SQLITE_BUSY;
27085 #else
27086 rc = sqliteErrorFromPosixError(tErrno,
27087 setLockFlag ? SQLITE_IOERR_LOCK : SQLITE_IOERR_UNLOCK);
27088 #endif /* SQLITE_IGNORE_AFP_LOCK_ERRORS */
27089 if( IS_LOCK_ERROR(rc) ){
27090 pFile->lastErrno = tErrno;
27092 return rc;
27093 } else {
27094 return SQLITE_OK;
27099 ** This routine checks if there is a RESERVED lock held on the specified
27100 ** file by this or any other process. If such a lock is held, set *pResOut
27101 ** to a non-zero value otherwise *pResOut is set to zero. The return value
27102 ** is set to SQLITE_OK unless an I/O error occurs during lock checking.
27104 static int afpCheckReservedLock(sqlite3_file *id, int *pResOut){
27105 int rc = SQLITE_OK;
27106 int reserved = 0;
27107 unixFile *pFile = (unixFile*)id;
27108 afpLockingContext *context;
27110 SimulateIOError( return SQLITE_IOERR_CHECKRESERVEDLOCK; );
27112 assert( pFile );
27113 context = (afpLockingContext *) pFile->lockingContext;
27114 if( context->reserved ){
27115 *pResOut = 1;
27116 return SQLITE_OK;
27118 unixEnterMutex(); /* Because pFile->pInode is shared across threads */
27120 /* Check if a thread in this process holds such a lock */
27121 if( pFile->pInode->eFileLock>SHARED_LOCK ){
27122 reserved = 1;
27125 /* Otherwise see if some other process holds it.
27127 if( !reserved ){
27128 /* lock the RESERVED byte */
27129 int lrc = afpSetLock(context->dbPath, pFile, RESERVED_BYTE, 1,1);
27130 if( SQLITE_OK==lrc ){
27131 /* if we succeeded in taking the reserved lock, unlock it to restore
27132 ** the original state */
27133 lrc = afpSetLock(context->dbPath, pFile, RESERVED_BYTE, 1, 0);
27134 } else {
27135 /* if we failed to get the lock then someone else must have it */
27136 reserved = 1;
27138 if( IS_LOCK_ERROR(lrc) ){
27139 rc=lrc;
27143 unixLeaveMutex();
27144 OSTRACE(("TEST WR-LOCK %d %d %d (afp)\n", pFile->h, rc, reserved));
27146 *pResOut = reserved;
27147 return rc;
27151 ** Lock the file with the lock specified by parameter eFileLock - one
27152 ** of the following:
27154 ** (1) SHARED_LOCK
27155 ** (2) RESERVED_LOCK
27156 ** (3) PENDING_LOCK
27157 ** (4) EXCLUSIVE_LOCK
27159 ** Sometimes when requesting one lock state, additional lock states
27160 ** are inserted in between. The locking might fail on one of the later
27161 ** transitions leaving the lock state different from what it started but
27162 ** still short of its goal. The following chart shows the allowed
27163 ** transitions and the inserted intermediate states:
27165 ** UNLOCKED -> SHARED
27166 ** SHARED -> RESERVED
27167 ** SHARED -> (PENDING) -> EXCLUSIVE
27168 ** RESERVED -> (PENDING) -> EXCLUSIVE
27169 ** PENDING -> EXCLUSIVE
27171 ** This routine will only increase a lock. Use the sqlite3OsUnlock()
27172 ** routine to lower a locking level.
27174 static int afpLock(sqlite3_file *id, int eFileLock){
27175 int rc = SQLITE_OK;
27176 unixFile *pFile = (unixFile*)id;
27177 unixInodeInfo *pInode = pFile->pInode;
27178 afpLockingContext *context = (afpLockingContext *) pFile->lockingContext;
27180 assert( pFile );
27181 OSTRACE(("LOCK %d %s was %s(%s,%d) pid=%d (afp)\n", pFile->h,
27182 azFileLock(eFileLock), azFileLock(pFile->eFileLock),
27183 azFileLock(pInode->eFileLock), pInode->nShared , getpid()));
27185 /* If there is already a lock of this type or more restrictive on the
27186 ** unixFile, do nothing. Don't use the afp_end_lock: exit path, as
27187 ** unixEnterMutex() hasn't been called yet.
27189 if( pFile->eFileLock>=eFileLock ){
27190 OSTRACE(("LOCK %d %s ok (already held) (afp)\n", pFile->h,
27191 azFileLock(eFileLock)));
27192 return SQLITE_OK;
27195 /* Make sure the locking sequence is correct
27196 ** (1) We never move from unlocked to anything higher than shared lock.
27197 ** (2) SQLite never explicitly requests a pendig lock.
27198 ** (3) A shared lock is always held when a reserve lock is requested.
27200 assert( pFile->eFileLock!=NO_LOCK || eFileLock==SHARED_LOCK );
27201 assert( eFileLock!=PENDING_LOCK );
27202 assert( eFileLock!=RESERVED_LOCK || pFile->eFileLock==SHARED_LOCK );
27204 /* This mutex is needed because pFile->pInode is shared across threads
27206 unixEnterMutex();
27207 pInode = pFile->pInode;
27209 /* If some thread using this PID has a lock via a different unixFile*
27210 ** handle that precludes the requested lock, return BUSY.
27212 if( (pFile->eFileLock!=pInode->eFileLock &&
27213 (pInode->eFileLock>=PENDING_LOCK || eFileLock>SHARED_LOCK))
27215 rc = SQLITE_BUSY;
27216 goto afp_end_lock;
27219 /* If a SHARED lock is requested, and some thread using this PID already
27220 ** has a SHARED or RESERVED lock, then increment reference counts and
27221 ** return SQLITE_OK.
27223 if( eFileLock==SHARED_LOCK &&
27224 (pInode->eFileLock==SHARED_LOCK || pInode->eFileLock==RESERVED_LOCK) ){
27225 assert( eFileLock==SHARED_LOCK );
27226 assert( pFile->eFileLock==0 );
27227 assert( pInode->nShared>0 );
27228 pFile->eFileLock = SHARED_LOCK;
27229 pInode->nShared++;
27230 pInode->nLock++;
27231 goto afp_end_lock;
27234 /* A PENDING lock is needed before acquiring a SHARED lock and before
27235 ** acquiring an EXCLUSIVE lock. For the SHARED lock, the PENDING will
27236 ** be released.
27238 if( eFileLock==SHARED_LOCK
27239 || (eFileLock==EXCLUSIVE_LOCK && pFile->eFileLock<PENDING_LOCK)
27241 int failed;
27242 failed = afpSetLock(context->dbPath, pFile, PENDING_BYTE, 1, 1);
27243 if (failed) {
27244 rc = failed;
27245 goto afp_end_lock;
27249 /* If control gets to this point, then actually go ahead and make
27250 ** operating system calls for the specified lock.
27252 if( eFileLock==SHARED_LOCK ){
27253 int lrc1, lrc2, lrc1Errno = 0;
27254 long lk, mask;
27256 assert( pInode->nShared==0 );
27257 assert( pInode->eFileLock==0 );
27259 mask = (sizeof(long)==8) ? LARGEST_INT64 : 0x7fffffff;
27260 /* Now get the read-lock SHARED_LOCK */
27261 /* note that the quality of the randomness doesn't matter that much */
27262 lk = random();
27263 pInode->sharedByte = (lk & mask)%(SHARED_SIZE - 1);
27264 lrc1 = afpSetLock(context->dbPath, pFile,
27265 SHARED_FIRST+pInode->sharedByte, 1, 1);
27266 if( IS_LOCK_ERROR(lrc1) ){
27267 lrc1Errno = pFile->lastErrno;
27269 /* Drop the temporary PENDING lock */
27270 lrc2 = afpSetLock(context->dbPath, pFile, PENDING_BYTE, 1, 0);
27272 if( IS_LOCK_ERROR(lrc1) ) {
27273 pFile->lastErrno = lrc1Errno;
27274 rc = lrc1;
27275 goto afp_end_lock;
27276 } else if( IS_LOCK_ERROR(lrc2) ){
27277 rc = lrc2;
27278 goto afp_end_lock;
27279 } else if( lrc1 != SQLITE_OK ) {
27280 rc = lrc1;
27281 } else {
27282 pFile->eFileLock = SHARED_LOCK;
27283 pInode->nLock++;
27284 pInode->nShared = 1;
27286 }else if( eFileLock==EXCLUSIVE_LOCK && pInode->nShared>1 ){
27287 /* We are trying for an exclusive lock but another thread in this
27288 ** same process is still holding a shared lock. */
27289 rc = SQLITE_BUSY;
27290 }else{
27291 /* The request was for a RESERVED or EXCLUSIVE lock. It is
27292 ** assumed that there is a SHARED or greater lock on the file
27293 ** already.
27295 int failed = 0;
27296 assert( 0!=pFile->eFileLock );
27297 if (eFileLock >= RESERVED_LOCK && pFile->eFileLock < RESERVED_LOCK) {
27298 /* Acquire a RESERVED lock */
27299 failed = afpSetLock(context->dbPath, pFile, RESERVED_BYTE, 1,1);
27300 if( !failed ){
27301 context->reserved = 1;
27304 if (!failed && eFileLock == EXCLUSIVE_LOCK) {
27305 /* Acquire an EXCLUSIVE lock */
27307 /* Remove the shared lock before trying the range. we'll need to
27308 ** reestablish the shared lock if we can't get the afpUnlock
27310 if( !(failed = afpSetLock(context->dbPath, pFile, SHARED_FIRST +
27311 pInode->sharedByte, 1, 0)) ){
27312 int failed2 = SQLITE_OK;
27313 /* now attemmpt to get the exclusive lock range */
27314 failed = afpSetLock(context->dbPath, pFile, SHARED_FIRST,
27315 SHARED_SIZE, 1);
27316 if( failed && (failed2 = afpSetLock(context->dbPath, pFile,
27317 SHARED_FIRST + pInode->sharedByte, 1, 1)) ){
27318 /* Can't reestablish the shared lock. Sqlite can't deal, this is
27319 ** a critical I/O error
27321 rc = ((failed & SQLITE_IOERR) == SQLITE_IOERR) ? failed2 :
27322 SQLITE_IOERR_LOCK;
27323 goto afp_end_lock;
27325 }else{
27326 rc = failed;
27329 if( failed ){
27330 rc = failed;
27334 if( rc==SQLITE_OK ){
27335 pFile->eFileLock = eFileLock;
27336 pInode->eFileLock = eFileLock;
27337 }else if( eFileLock==EXCLUSIVE_LOCK ){
27338 pFile->eFileLock = PENDING_LOCK;
27339 pInode->eFileLock = PENDING_LOCK;
27342 afp_end_lock:
27343 unixLeaveMutex();
27344 OSTRACE(("LOCK %d %s %s (afp)\n", pFile->h, azFileLock(eFileLock),
27345 rc==SQLITE_OK ? "ok" : "failed"));
27346 return rc;
27350 ** Lower the locking level on file descriptor pFile to eFileLock. eFileLock
27351 ** must be either NO_LOCK or SHARED_LOCK.
27353 ** If the locking level of the file descriptor is already at or below
27354 ** the requested locking level, this routine is a no-op.
27356 static int afpUnlock(sqlite3_file *id, int eFileLock) {
27357 int rc = SQLITE_OK;
27358 unixFile *pFile = (unixFile*)id;
27359 unixInodeInfo *pInode;
27360 afpLockingContext *context = (afpLockingContext *) pFile->lockingContext;
27361 int skipShared = 0;
27362 #ifdef SQLITE_TEST
27363 int h = pFile->h;
27364 #endif
27366 assert( pFile );
27367 OSTRACE(("UNLOCK %d %d was %d(%d,%d) pid=%d (afp)\n", pFile->h, eFileLock,
27368 pFile->eFileLock, pFile->pInode->eFileLock, pFile->pInode->nShared,
27369 getpid()));
27371 assert( eFileLock<=SHARED_LOCK );
27372 if( pFile->eFileLock<=eFileLock ){
27373 return SQLITE_OK;
27375 unixEnterMutex();
27376 pInode = pFile->pInode;
27377 assert( pInode->nShared!=0 );
27378 if( pFile->eFileLock>SHARED_LOCK ){
27379 assert( pInode->eFileLock==pFile->eFileLock );
27380 SimulateIOErrorBenign(1);
27381 SimulateIOError( h=(-1) )
27382 SimulateIOErrorBenign(0);
27384 #ifndef NDEBUG
27385 /* When reducing a lock such that other processes can start
27386 ** reading the database file again, make sure that the
27387 ** transaction counter was updated if any part of the database
27388 ** file changed. If the transaction counter is not updated,
27389 ** other connections to the same file might not realize that
27390 ** the file has changed and hence might not know to flush their
27391 ** cache. The use of a stale cache can lead to database corruption.
27393 assert( pFile->inNormalWrite==0
27394 || pFile->dbUpdate==0
27395 || pFile->transCntrChng==1 );
27396 pFile->inNormalWrite = 0;
27397 #endif
27399 if( pFile->eFileLock==EXCLUSIVE_LOCK ){
27400 rc = afpSetLock(context->dbPath, pFile, SHARED_FIRST, SHARED_SIZE, 0);
27401 if( rc==SQLITE_OK && (eFileLock==SHARED_LOCK || pInode->nShared>1) ){
27402 /* only re-establish the shared lock if necessary */
27403 int sharedLockByte = SHARED_FIRST+pInode->sharedByte;
27404 rc = afpSetLock(context->dbPath, pFile, sharedLockByte, 1, 1);
27405 } else {
27406 skipShared = 1;
27409 if( rc==SQLITE_OK && pFile->eFileLock>=PENDING_LOCK ){
27410 rc = afpSetLock(context->dbPath, pFile, PENDING_BYTE, 1, 0);
27412 if( rc==SQLITE_OK && pFile->eFileLock>=RESERVED_LOCK && context->reserved ){
27413 rc = afpSetLock(context->dbPath, pFile, RESERVED_BYTE, 1, 0);
27414 if( !rc ){
27415 context->reserved = 0;
27418 if( rc==SQLITE_OK && (eFileLock==SHARED_LOCK || pInode->nShared>1)){
27419 pInode->eFileLock = SHARED_LOCK;
27422 if( rc==SQLITE_OK && eFileLock==NO_LOCK ){
27424 /* Decrement the shared lock counter. Release the lock using an
27425 ** OS call only when all threads in this same process have released
27426 ** the lock.
27428 unsigned long long sharedLockByte = SHARED_FIRST+pInode->sharedByte;
27429 pInode->nShared--;
27430 if( pInode->nShared==0 ){
27431 SimulateIOErrorBenign(1);
27432 SimulateIOError( h=(-1) )
27433 SimulateIOErrorBenign(0);
27434 if( !skipShared ){
27435 rc = afpSetLock(context->dbPath, pFile, sharedLockByte, 1, 0);
27437 if( !rc ){
27438 pInode->eFileLock = NO_LOCK;
27439 pFile->eFileLock = NO_LOCK;
27442 if( rc==SQLITE_OK ){
27443 pInode->nLock--;
27444 assert( pInode->nLock>=0 );
27445 if( pInode->nLock==0 ){
27446 closePendingFds(pFile);
27451 unixLeaveMutex();
27452 if( rc==SQLITE_OK ) pFile->eFileLock = eFileLock;
27453 return rc;
27457 ** Close a file & cleanup AFP specific locking context
27459 static int afpClose(sqlite3_file *id) {
27460 int rc = SQLITE_OK;
27461 if( id ){
27462 unixFile *pFile = (unixFile*)id;
27463 afpUnlock(id, NO_LOCK);
27464 unixEnterMutex();
27465 if( pFile->pInode && pFile->pInode->nLock ){
27466 /* If there are outstanding locks, do not actually close the file just
27467 ** yet because that would clear those locks. Instead, add the file
27468 ** descriptor to pInode->aPending. It will be automatically closed when
27469 ** the last lock is cleared.
27471 setPendingFd(pFile);
27473 releaseInodeInfo(pFile);
27474 sqlite3_free(pFile->lockingContext);
27475 rc = closeUnixFile(id);
27476 unixLeaveMutex();
27478 return rc;
27481 #endif /* defined(__APPLE__) && SQLITE_ENABLE_LOCKING_STYLE */
27483 ** The code above is the AFP lock implementation. The code is specific
27484 ** to MacOSX and does not work on other unix platforms. No alternative
27485 ** is available. If you don't compile for a mac, then the "unix-afp"
27486 ** VFS is not available.
27488 ********************* End of the AFP lock implementation **********************
27489 ******************************************************************************/
27491 /******************************************************************************
27492 *************************** Begin NFS Locking ********************************/
27494 #if defined(__APPLE__) && SQLITE_ENABLE_LOCKING_STYLE
27496 ** Lower the locking level on file descriptor pFile to eFileLock. eFileLock
27497 ** must be either NO_LOCK or SHARED_LOCK.
27499 ** If the locking level of the file descriptor is already at or below
27500 ** the requested locking level, this routine is a no-op.
27502 static int nfsUnlock(sqlite3_file *id, int eFileLock){
27503 return posixUnlock(id, eFileLock, 1);
27506 #endif /* defined(__APPLE__) && SQLITE_ENABLE_LOCKING_STYLE */
27508 ** The code above is the NFS lock implementation. The code is specific
27509 ** to MacOSX and does not work on other unix platforms. No alternative
27510 ** is available.
27512 ********************* End of the NFS lock implementation **********************
27513 ******************************************************************************/
27515 /******************************************************************************
27516 **************** Non-locking sqlite3_file methods *****************************
27518 ** The next division contains implementations for all methods of the
27519 ** sqlite3_file object other than the locking methods. The locking
27520 ** methods were defined in divisions above (one locking method per
27521 ** division). Those methods that are common to all locking modes
27522 ** are gather together into this division.
27526 ** Seek to the offset passed as the second argument, then read cnt
27527 ** bytes into pBuf. Return the number of bytes actually read.
27529 ** NB: If you define USE_PREAD or USE_PREAD64, then it might also
27530 ** be necessary to define _XOPEN_SOURCE to be 500. This varies from
27531 ** one system to another. Since SQLite does not define USE_PREAD
27532 ** any any form by default, we will not attempt to define _XOPEN_SOURCE.
27533 ** See tickets #2741 and #2681.
27535 ** To avoid stomping the errno value on a failed read the lastErrno value
27536 ** is set before returning.
27538 static int seekAndRead(unixFile *id, sqlite3_int64 offset, void *pBuf, int cnt){
27539 int got;
27540 #if (!defined(USE_PREAD) && !defined(USE_PREAD64))
27541 i64 newOffset;
27542 #endif
27543 TIMER_START;
27544 #if defined(USE_PREAD)
27545 do{ got = osPread(id->h, pBuf, cnt, offset); }while( got<0 && errno==EINTR );
27546 SimulateIOError( got = -1 );
27547 #elif defined(USE_PREAD64)
27548 do{ got = osPread64(id->h, pBuf, cnt, offset); }while( got<0 && errno==EINTR);
27549 SimulateIOError( got = -1 );
27550 #else
27551 newOffset = lseek(id->h, offset, SEEK_SET);
27552 SimulateIOError( newOffset-- );
27553 if( newOffset!=offset ){
27554 if( newOffset == -1 ){
27555 ((unixFile*)id)->lastErrno = errno;
27556 }else{
27557 ((unixFile*)id)->lastErrno = 0;
27559 return -1;
27561 do{ got = osRead(id->h, pBuf, cnt); }while( got<0 && errno==EINTR );
27562 #endif
27563 TIMER_END;
27564 if( got<0 ){
27565 ((unixFile*)id)->lastErrno = errno;
27567 OSTRACE(("READ %-3d %5d %7lld %llu\n", id->h, got, offset, TIMER_ELAPSED));
27568 return got;
27572 ** Read data from a file into a buffer. Return SQLITE_OK if all
27573 ** bytes were read successfully and SQLITE_IOERR if anything goes
27574 ** wrong.
27576 static int unixRead(
27577 sqlite3_file *id,
27578 void *pBuf,
27579 int amt,
27580 sqlite3_int64 offset
27582 unixFile *pFile = (unixFile *)id;
27583 int got;
27584 assert( id );
27586 /* If this is a database file (not a journal, master-journal or temp
27587 ** file), the bytes in the locking range should never be read or written. */
27588 #if 0
27589 assert( pFile->pUnused==0
27590 || offset>=PENDING_BYTE+512
27591 || offset+amt<=PENDING_BYTE
27593 #endif
27595 got = seekAndRead(pFile, offset, pBuf, amt);
27596 if( got==amt ){
27597 return SQLITE_OK;
27598 }else if( got<0 ){
27599 /* lastErrno set by seekAndRead */
27600 return SQLITE_IOERR_READ;
27601 }else{
27602 pFile->lastErrno = 0; /* not a system error */
27603 /* Unread parts of the buffer must be zero-filled */
27604 memset(&((char*)pBuf)[got], 0, amt-got);
27605 return SQLITE_IOERR_SHORT_READ;
27610 ** Seek to the offset in id->offset then read cnt bytes into pBuf.
27611 ** Return the number of bytes actually read. Update the offset.
27613 ** To avoid stomping the errno value on a failed write the lastErrno value
27614 ** is set before returning.
27616 static int seekAndWrite(unixFile *id, i64 offset, const void *pBuf, int cnt){
27617 int got;
27618 #if (!defined(USE_PREAD) && !defined(USE_PREAD64))
27619 i64 newOffset;
27620 #endif
27621 TIMER_START;
27622 #if defined(USE_PREAD)
27623 do{ got = osPwrite(id->h, pBuf, cnt, offset); }while( got<0 && errno==EINTR );
27624 #elif defined(USE_PREAD64)
27625 do{ got = osPwrite64(id->h, pBuf, cnt, offset);}while( got<0 && errno==EINTR);
27626 #else
27628 newOffset = lseek(id->h, offset, SEEK_SET);
27629 SimulateIOError( newOffset-- );
27630 if( newOffset!=offset ){
27631 if( newOffset == -1 ){
27632 ((unixFile*)id)->lastErrno = errno;
27633 }else{
27634 ((unixFile*)id)->lastErrno = 0;
27636 return -1;
27638 got = osWrite(id->h, pBuf, cnt);
27639 }while( got<0 && errno==EINTR );
27640 #endif
27641 TIMER_END;
27642 if( got<0 ){
27643 ((unixFile*)id)->lastErrno = errno;
27646 OSTRACE(("WRITE %-3d %5d %7lld %llu\n", id->h, got, offset, TIMER_ELAPSED));
27647 return got;
27652 ** Write data from a buffer into a file. Return SQLITE_OK on success
27653 ** or some other error code on failure.
27655 static int unixWrite(
27656 sqlite3_file *id,
27657 const void *pBuf,
27658 int amt,
27659 sqlite3_int64 offset
27661 unixFile *pFile = (unixFile*)id;
27662 int wrote = 0;
27663 assert( id );
27664 assert( amt>0 );
27666 /* If this is a database file (not a journal, master-journal or temp
27667 ** file), the bytes in the locking range should never be read or written. */
27668 #if 0
27669 assert( pFile->pUnused==0
27670 || offset>=PENDING_BYTE+512
27671 || offset+amt<=PENDING_BYTE
27673 #endif
27675 #ifndef NDEBUG
27676 /* If we are doing a normal write to a database file (as opposed to
27677 ** doing a hot-journal rollback or a write to some file other than a
27678 ** normal database file) then record the fact that the database
27679 ** has changed. If the transaction counter is modified, record that
27680 ** fact too.
27682 if( pFile->inNormalWrite ){
27683 pFile->dbUpdate = 1; /* The database has been modified */
27684 if( offset<=24 && offset+amt>=27 ){
27685 int rc;
27686 char oldCntr[4];
27687 SimulateIOErrorBenign(1);
27688 rc = seekAndRead(pFile, 24, oldCntr, 4);
27689 SimulateIOErrorBenign(0);
27690 if( rc!=4 || memcmp(oldCntr, &((char*)pBuf)[24-offset], 4)!=0 ){
27691 pFile->transCntrChng = 1; /* The transaction counter has changed */
27695 #endif
27697 while( amt>0 && (wrote = seekAndWrite(pFile, offset, pBuf, amt))>0 ){
27698 amt -= wrote;
27699 offset += wrote;
27700 pBuf = &((char*)pBuf)[wrote];
27702 SimulateIOError(( wrote=(-1), amt=1 ));
27703 SimulateDiskfullError(( wrote=0, amt=1 ));
27705 if( amt>0 ){
27706 if( wrote<0 && pFile->lastErrno!=ENOSPC ){
27707 /* lastErrno set by seekAndWrite */
27708 return SQLITE_IOERR_WRITE;
27709 }else{
27710 pFile->lastErrno = 0; /* not a system error */
27711 return SQLITE_FULL;
27715 return SQLITE_OK;
27718 #ifdef SQLITE_TEST
27720 ** Count the number of fullsyncs and normal syncs. This is used to test
27721 ** that syncs and fullsyncs are occurring at the right times.
27723 SQLITE_API int sqlite3_sync_count = 0;
27724 SQLITE_API int sqlite3_fullsync_count = 0;
27725 #endif
27728 ** We do not trust systems to provide a working fdatasync(). Some do.
27729 ** Others do no. To be safe, we will stick with the (slightly slower)
27730 ** fsync(). If you know that your system does support fdatasync() correctly,
27731 ** then simply compile with -Dfdatasync=fdatasync
27733 #if !defined(fdatasync)
27734 # define fdatasync fsync
27735 #endif
27738 ** Define HAVE_FULLFSYNC to 0 or 1 depending on whether or not
27739 ** the F_FULLFSYNC macro is defined. F_FULLFSYNC is currently
27740 ** only available on Mac OS X. But that could change.
27742 #ifdef F_FULLFSYNC
27743 # define HAVE_FULLFSYNC 1
27744 #else
27745 # define HAVE_FULLFSYNC 0
27746 #endif
27750 ** The fsync() system call does not work as advertised on many
27751 ** unix systems. The following procedure is an attempt to make
27752 ** it work better.
27754 ** The SQLITE_NO_SYNC macro disables all fsync()s. This is useful
27755 ** for testing when we want to run through the test suite quickly.
27756 ** You are strongly advised *not* to deploy with SQLITE_NO_SYNC
27757 ** enabled, however, since with SQLITE_NO_SYNC enabled, an OS crash
27758 ** or power failure will likely corrupt the database file.
27760 ** SQLite sets the dataOnly flag if the size of the file is unchanged.
27761 ** The idea behind dataOnly is that it should only write the file content
27762 ** to disk, not the inode. We only set dataOnly if the file size is
27763 ** unchanged since the file size is part of the inode. However,
27764 ** Ted Ts'o tells us that fdatasync() will also write the inode if the
27765 ** file size has changed. The only real difference between fdatasync()
27766 ** and fsync(), Ted tells us, is that fdatasync() will not flush the
27767 ** inode if the mtime or owner or other inode attributes have changed.
27768 ** We only care about the file size, not the other file attributes, so
27769 ** as far as SQLite is concerned, an fdatasync() is always adequate.
27770 ** So, we always use fdatasync() if it is available, regardless of
27771 ** the value of the dataOnly flag.
27773 static int full_fsync(int fd, int fullSync, int dataOnly){
27774 int rc;
27776 /* The following "ifdef/elif/else/" block has the same structure as
27777 ** the one below. It is replicated here solely to avoid cluttering
27778 ** up the real code with the UNUSED_PARAMETER() macros.
27780 #ifdef SQLITE_NO_SYNC
27781 UNUSED_PARAMETER(fd);
27782 UNUSED_PARAMETER(fullSync);
27783 UNUSED_PARAMETER(dataOnly);
27784 #elif HAVE_FULLFSYNC
27785 UNUSED_PARAMETER(dataOnly);
27786 #else
27787 UNUSED_PARAMETER(fullSync);
27788 UNUSED_PARAMETER(dataOnly);
27789 #endif
27791 /* Record the number of times that we do a normal fsync() and
27792 ** FULLSYNC. This is used during testing to verify that this procedure
27793 ** gets called with the correct arguments.
27795 #ifdef SQLITE_TEST
27796 if( fullSync ) sqlite3_fullsync_count++;
27797 sqlite3_sync_count++;
27798 #endif
27800 /* If we compiled with the SQLITE_NO_SYNC flag, then syncing is a
27801 ** no-op
27803 #ifdef SQLITE_NO_SYNC
27804 rc = SQLITE_OK;
27805 #elif HAVE_FULLFSYNC
27806 if( fullSync ){
27807 rc = osFcntl(fd, F_FULLFSYNC, 0);
27808 }else{
27809 rc = 1;
27811 /* If the FULLFSYNC failed, fall back to attempting an fsync().
27812 ** It shouldn't be possible for fullfsync to fail on the local
27813 ** file system (on OSX), so failure indicates that FULLFSYNC
27814 ** isn't supported for this file system. So, attempt an fsync
27815 ** and (for now) ignore the overhead of a superfluous fcntl call.
27816 ** It'd be better to detect fullfsync support once and avoid
27817 ** the fcntl call every time sync is called.
27819 if( rc ) rc = fsync(fd);
27821 #elif defined(__APPLE__)
27822 /* fdatasync() on HFS+ doesn't yet flush the file size if it changed correctly
27823 ** so currently we default to the macro that redefines fdatasync to fsync
27825 rc = fsync(fd);
27826 #else
27827 rc = fdatasync(fd);
27828 #if OS_VXWORKS
27829 if( rc==-1 && errno==ENOTSUP ){
27830 rc = fsync(fd);
27832 #endif /* OS_VXWORKS */
27833 #endif /* ifdef SQLITE_NO_SYNC elif HAVE_FULLFSYNC */
27835 if( OS_VXWORKS && rc!= -1 ){
27836 rc = 0;
27838 return rc;
27842 ** Open a file descriptor to the directory containing file zFilename.
27843 ** If successful, *pFd is set to the opened file descriptor and
27844 ** SQLITE_OK is returned. If an error occurs, either SQLITE_NOMEM
27845 ** or SQLITE_CANTOPEN is returned and *pFd is set to an undefined
27846 ** value.
27848 ** The directory file descriptor is used for only one thing - to
27849 ** fsync() a directory to make sure file creation and deletion events
27850 ** are flushed to disk. Such fsyncs are not needed on newer
27851 ** journaling filesystems, but are required on older filesystems.
27853 ** This routine can be overridden using the xSetSysCall interface.
27854 ** The ability to override this routine was added in support of the
27855 ** chromium sandbox. Opening a directory is a security risk (we are
27856 ** told) so making it overrideable allows the chromium sandbox to
27857 ** replace this routine with a harmless no-op. To make this routine
27858 ** a no-op, replace it with a stub that returns SQLITE_OK but leaves
27859 ** *pFd set to a negative number.
27861 ** If SQLITE_OK is returned, the caller is responsible for closing
27862 ** the file descriptor *pFd using close().
27864 static int openDirectory(const char *zFilename, int *pFd){
27865 int ii;
27866 int fd = -1;
27867 char zDirname[MAX_PATHNAME+1];
27869 sqlite3_snprintf(MAX_PATHNAME, zDirname, "%s", zFilename);
27870 for(ii=(int)strlen(zDirname); ii>1 && zDirname[ii]!='/'; ii--);
27871 if( ii>0 ){
27872 zDirname[ii] = '\0';
27873 fd = robust_open(zDirname, O_RDONLY|O_BINARY, 0);
27874 if( fd>=0 ){
27875 #ifdef FD_CLOEXEC
27876 osFcntl(fd, F_SETFD, osFcntl(fd, F_GETFD, 0) | FD_CLOEXEC);
27877 #endif
27878 OSTRACE(("OPENDIR %-3d %s\n", fd, zDirname));
27881 *pFd = fd;
27882 return (fd>=0?SQLITE_OK:unixLogError(SQLITE_CANTOPEN_BKPT, "open", zDirname));
27886 ** Make sure all writes to a particular file are committed to disk.
27888 ** If dataOnly==0 then both the file itself and its metadata (file
27889 ** size, access time, etc) are synced. If dataOnly!=0 then only the
27890 ** file data is synced.
27892 ** Under Unix, also make sure that the directory entry for the file
27893 ** has been created by fsync-ing the directory that contains the file.
27894 ** If we do not do this and we encounter a power failure, the directory
27895 ** entry for the journal might not exist after we reboot. The next
27896 ** SQLite to access the file will not know that the journal exists (because
27897 ** the directory entry for the journal was never created) and the transaction
27898 ** will not roll back - possibly leading to database corruption.
27900 static int unixSync(sqlite3_file *id, int flags){
27901 int rc;
27902 unixFile *pFile = (unixFile*)id;
27904 int isDataOnly = (flags&SQLITE_SYNC_DATAONLY);
27905 int isFullsync = (flags&0x0F)==SQLITE_SYNC_FULL;
27907 /* Check that one of SQLITE_SYNC_NORMAL or FULL was passed */
27908 assert((flags&0x0F)==SQLITE_SYNC_NORMAL
27909 || (flags&0x0F)==SQLITE_SYNC_FULL
27912 /* Unix cannot, but some systems may return SQLITE_FULL from here. This
27913 ** line is to test that doing so does not cause any problems.
27915 SimulateDiskfullError( return SQLITE_FULL );
27917 assert( pFile );
27918 OSTRACE(("SYNC %-3d\n", pFile->h));
27919 rc = full_fsync(pFile->h, isFullsync, isDataOnly);
27920 SimulateIOError( rc=1 );
27921 if( rc ){
27922 pFile->lastErrno = errno;
27923 return unixLogError(SQLITE_IOERR_FSYNC, "full_fsync", pFile->zPath);
27926 /* Also fsync the directory containing the file if the DIRSYNC flag
27927 ** is set. This is a one-time occurrance. Many systems (examples: AIX)
27928 ** are unable to fsync a directory, so ignore errors on the fsync.
27930 if( pFile->ctrlFlags & UNIXFILE_DIRSYNC ){
27931 int dirfd;
27932 OSTRACE(("DIRSYNC %s (have_fullfsync=%d fullsync=%d)\n", pFile->zPath,
27933 HAVE_FULLFSYNC, isFullsync));
27934 rc = osOpenDirectory(pFile->zPath, &dirfd);
27935 if( rc==SQLITE_OK && dirfd>=0 ){
27936 full_fsync(dirfd, 0, 0);
27937 robust_close(pFile, dirfd, __LINE__);
27938 }else if( rc==SQLITE_CANTOPEN ){
27939 rc = SQLITE_OK;
27941 pFile->ctrlFlags &= ~UNIXFILE_DIRSYNC;
27943 return rc;
27947 ** Truncate an open file to a specified size
27949 static int unixTruncate(sqlite3_file *id, i64 nByte){
27950 unixFile *pFile = (unixFile *)id;
27951 int rc;
27952 assert( pFile );
27953 SimulateIOError( return SQLITE_IOERR_TRUNCATE );
27955 /* If the user has configured a chunk-size for this file, truncate the
27956 ** file so that it consists of an integer number of chunks (i.e. the
27957 ** actual file size after the operation may be larger than the requested
27958 ** size).
27960 if( pFile->szChunk ){
27961 nByte = ((nByte + pFile->szChunk - 1)/pFile->szChunk) * pFile->szChunk;
27964 rc = robust_ftruncate(pFile->h, (off_t)nByte);
27965 if( rc ){
27966 pFile->lastErrno = errno;
27967 return unixLogError(SQLITE_IOERR_TRUNCATE, "ftruncate", pFile->zPath);
27968 }else{
27969 #ifndef NDEBUG
27970 /* If we are doing a normal write to a database file (as opposed to
27971 ** doing a hot-journal rollback or a write to some file other than a
27972 ** normal database file) and we truncate the file to zero length,
27973 ** that effectively updates the change counter. This might happen
27974 ** when restoring a database using the backup API from a zero-length
27975 ** source.
27977 if( pFile->inNormalWrite && nByte==0 ){
27978 pFile->transCntrChng = 1;
27980 #endif
27982 return SQLITE_OK;
27987 ** Determine the current size of a file in bytes
27989 static int unixFileSize(sqlite3_file *id, i64 *pSize){
27990 int rc;
27991 struct stat buf;
27992 assert( id );
27993 rc = osFstat(((unixFile*)id)->h, &buf);
27994 SimulateIOError( rc=1 );
27995 if( rc!=0 ){
27996 ((unixFile*)id)->lastErrno = errno;
27997 return SQLITE_IOERR_FSTAT;
27999 *pSize = buf.st_size;
28001 /* When opening a zero-size database, the findInodeInfo() procedure
28002 ** writes a single byte into that file in order to work around a bug
28003 ** in the OS-X msdos filesystem. In order to avoid problems with upper
28004 ** layers, we need to report this file size as zero even though it is
28005 ** really 1. Ticket #3260.
28007 if( *pSize==1 ) *pSize = 0;
28010 return SQLITE_OK;
28013 #if SQLITE_ENABLE_LOCKING_STYLE && defined(__APPLE__)
28015 ** Handler for proxy-locking file-control verbs. Defined below in the
28016 ** proxying locking division.
28018 static int proxyFileControl(sqlite3_file*,int,void*);
28019 #endif
28022 ** This function is called to handle the SQLITE_FCNTL_SIZE_HINT
28023 ** file-control operation. Enlarge the database to nBytes in size
28024 ** (rounded up to the next chunk-size). If the database is already
28025 ** nBytes or larger, this routine is a no-op.
28027 static int fcntlSizeHint(unixFile *pFile, i64 nByte){
28028 if( pFile->szChunk>0 ){
28029 i64 nSize; /* Required file size */
28030 struct stat buf; /* Used to hold return values of fstat() */
28032 if( osFstat(pFile->h, &buf) ) return SQLITE_IOERR_FSTAT;
28034 nSize = ((nByte+pFile->szChunk-1) / pFile->szChunk) * pFile->szChunk;
28035 if( nSize>(i64)buf.st_size ){
28037 #if defined(HAVE_POSIX_FALLOCATE) && HAVE_POSIX_FALLOCATE
28038 /* The code below is handling the return value of osFallocate()
28039 ** correctly. posix_fallocate() is defined to "returns zero on success,
28040 ** or an error number on failure". See the manpage for details. */
28041 int err;
28043 err = osFallocate(pFile->h, buf.st_size, nSize-buf.st_size);
28044 }while( err==EINTR );
28045 if( err ) return SQLITE_IOERR_WRITE;
28046 #else
28047 /* If the OS does not have posix_fallocate(), fake it. First use
28048 ** ftruncate() to set the file size, then write a single byte to
28049 ** the last byte in each block within the extended region. This
28050 ** is the same technique used by glibc to implement posix_fallocate()
28051 ** on systems that do not have a real fallocate() system call.
28053 int nBlk = buf.st_blksize; /* File-system block size */
28054 i64 iWrite; /* Next offset to write to */
28056 if( robust_ftruncate(pFile->h, nSize) ){
28057 pFile->lastErrno = errno;
28058 return unixLogError(SQLITE_IOERR_TRUNCATE, "ftruncate", pFile->zPath);
28060 iWrite = ((buf.st_size + 2*nBlk - 1)/nBlk)*nBlk-1;
28061 while( iWrite<nSize ){
28062 int nWrite = seekAndWrite(pFile, iWrite, "", 1);
28063 if( nWrite!=1 ) return SQLITE_IOERR_WRITE;
28064 iWrite += nBlk;
28066 #endif
28070 return SQLITE_OK;
28074 ** Information and control of an open file handle.
28076 static int unixFileControl(sqlite3_file *id, int op, void *pArg){
28077 unixFile *pFile = (unixFile*)id;
28078 switch( op ){
28079 case SQLITE_FCNTL_LOCKSTATE: {
28080 *(int*)pArg = pFile->eFileLock;
28081 return SQLITE_OK;
28083 case SQLITE_LAST_ERRNO: {
28084 *(int*)pArg = pFile->lastErrno;
28085 return SQLITE_OK;
28087 case SQLITE_FCNTL_CHUNK_SIZE: {
28088 pFile->szChunk = *(int *)pArg;
28089 return SQLITE_OK;
28091 case SQLITE_FCNTL_SIZE_HINT: {
28092 int rc;
28093 SimulateIOErrorBenign(1);
28094 rc = fcntlSizeHint(pFile, *(i64 *)pArg);
28095 SimulateIOErrorBenign(0);
28096 return rc;
28098 case SQLITE_FCNTL_PERSIST_WAL: {
28099 int bPersist = *(int*)pArg;
28100 if( bPersist<0 ){
28101 *(int*)pArg = (pFile->ctrlFlags & UNIXFILE_PERSIST_WAL)!=0;
28102 }else if( bPersist==0 ){
28103 pFile->ctrlFlags &= ~UNIXFILE_PERSIST_WAL;
28104 }else{
28105 pFile->ctrlFlags |= UNIXFILE_PERSIST_WAL;
28107 return SQLITE_OK;
28109 #ifndef NDEBUG
28110 /* The pager calls this method to signal that it has done
28111 ** a rollback and that the database is therefore unchanged and
28112 ** it hence it is OK for the transaction change counter to be
28113 ** unchanged.
28115 case SQLITE_FCNTL_DB_UNCHANGED: {
28116 ((unixFile*)id)->dbUpdate = 0;
28117 return SQLITE_OK;
28119 #endif
28120 #if SQLITE_ENABLE_LOCKING_STYLE && defined(__APPLE__)
28121 case SQLITE_SET_LOCKPROXYFILE:
28122 case SQLITE_GET_LOCKPROXYFILE: {
28123 return proxyFileControl(id,op,pArg);
28125 #endif /* SQLITE_ENABLE_LOCKING_STYLE && defined(__APPLE__) */
28126 case SQLITE_FCNTL_SYNC_OMITTED: {
28127 return SQLITE_OK; /* A no-op */
28130 return SQLITE_NOTFOUND;
28134 ** Return the sector size in bytes of the underlying block device for
28135 ** the specified file. This is almost always 512 bytes, but may be
28136 ** larger for some devices.
28138 ** SQLite code assumes this function cannot fail. It also assumes that
28139 ** if two files are created in the same file-system directory (i.e.
28140 ** a database and its journal file) that the sector size will be the
28141 ** same for both.
28143 static int unixSectorSize(sqlite3_file *NotUsed){
28144 UNUSED_PARAMETER(NotUsed);
28145 return SQLITE_DEFAULT_SECTOR_SIZE;
28149 ** Return the device characteristics for the file. This is always 0 for unix.
28151 static int unixDeviceCharacteristics(sqlite3_file *NotUsed){
28152 UNUSED_PARAMETER(NotUsed);
28153 return 0;
28156 #ifndef SQLITE_OMIT_WAL
28160 ** Object used to represent an shared memory buffer.
28162 ** When multiple threads all reference the same wal-index, each thread
28163 ** has its own unixShm object, but they all point to a single instance
28164 ** of this unixShmNode object. In other words, each wal-index is opened
28165 ** only once per process.
28167 ** Each unixShmNode object is connected to a single unixInodeInfo object.
28168 ** We could coalesce this object into unixInodeInfo, but that would mean
28169 ** every open file that does not use shared memory (in other words, most
28170 ** open files) would have to carry around this extra information. So
28171 ** the unixInodeInfo object contains a pointer to this unixShmNode object
28172 ** and the unixShmNode object is created only when needed.
28174 ** unixMutexHeld() must be true when creating or destroying
28175 ** this object or while reading or writing the following fields:
28177 ** nRef
28179 ** The following fields are read-only after the object is created:
28181 ** fid
28182 ** zFilename
28184 ** Either unixShmNode.mutex must be held or unixShmNode.nRef==0 and
28185 ** unixMutexHeld() is true when reading or writing any other field
28186 ** in this structure.
28188 struct unixShmNode {
28189 unixInodeInfo *pInode; /* unixInodeInfo that owns this SHM node */
28190 sqlite3_mutex *mutex; /* Mutex to access this object */
28191 char *zFilename; /* Name of the mmapped file */
28192 int h; /* Open file descriptor */
28193 int szRegion; /* Size of shared-memory regions */
28194 u16 nRegion; /* Size of array apRegion */
28195 u8 isReadonly; /* True if read-only */
28196 char **apRegion; /* Array of mapped shared-memory regions */
28197 int nRef; /* Number of unixShm objects pointing to this */
28198 unixShm *pFirst; /* All unixShm objects pointing to this */
28199 #ifdef SQLITE_DEBUG
28200 u8 exclMask; /* Mask of exclusive locks held */
28201 u8 sharedMask; /* Mask of shared locks held */
28202 u8 nextShmId; /* Next available unixShm.id value */
28203 #endif
28207 ** Structure used internally by this VFS to record the state of an
28208 ** open shared memory connection.
28210 ** The following fields are initialized when this object is created and
28211 ** are read-only thereafter:
28213 ** unixShm.pFile
28214 ** unixShm.id
28216 ** All other fields are read/write. The unixShm.pFile->mutex must be held
28217 ** while accessing any read/write fields.
28219 struct unixShm {
28220 unixShmNode *pShmNode; /* The underlying unixShmNode object */
28221 unixShm *pNext; /* Next unixShm with the same unixShmNode */
28222 u8 hasMutex; /* True if holding the unixShmNode mutex */
28223 u8 id; /* Id of this connection within its unixShmNode */
28224 u16 sharedMask; /* Mask of shared locks held */
28225 u16 exclMask; /* Mask of exclusive locks held */
28229 ** Constants used for locking
28231 #define UNIX_SHM_BASE ((22+SQLITE_SHM_NLOCK)*4) /* first lock byte */
28232 #define UNIX_SHM_DMS (UNIX_SHM_BASE+SQLITE_SHM_NLOCK) /* deadman switch */
28235 ** Apply posix advisory locks for all bytes from ofst through ofst+n-1.
28237 ** Locks block if the mask is exactly UNIX_SHM_C and are non-blocking
28238 ** otherwise.
28240 static int unixShmSystemLock(
28241 unixShmNode *pShmNode, /* Apply locks to this open shared-memory segment */
28242 int lockType, /* F_UNLCK, F_RDLCK, or F_WRLCK */
28243 int ofst, /* First byte of the locking range */
28244 int n /* Number of bytes to lock */
28246 struct flock f; /* The posix advisory locking structure */
28247 int rc = SQLITE_OK; /* Result code form fcntl() */
28249 /* Access to the unixShmNode object is serialized by the caller */
28250 assert( sqlite3_mutex_held(pShmNode->mutex) || pShmNode->nRef==0 );
28252 /* Shared locks never span more than one byte */
28253 assert( n==1 || lockType!=F_RDLCK );
28255 /* Locks are within range */
28256 assert( n>=1 && n<SQLITE_SHM_NLOCK );
28258 if( pShmNode->h>=0 ){
28259 /* Initialize the locking parameters */
28260 memset(&f, 0, sizeof(f));
28261 f.l_type = lockType;
28262 f.l_whence = SEEK_SET;
28263 f.l_start = ofst;
28264 f.l_len = n;
28266 rc = osFcntl(pShmNode->h, F_SETLK, &f);
28267 rc = (rc!=(-1)) ? SQLITE_OK : SQLITE_BUSY;
28270 /* Update the global lock state and do debug tracing */
28271 #ifdef SQLITE_DEBUG
28272 { u16 mask;
28273 OSTRACE(("SHM-LOCK "));
28274 mask = (1<<(ofst+n)) - (1<<ofst);
28275 if( rc==SQLITE_OK ){
28276 if( lockType==F_UNLCK ){
28277 OSTRACE(("unlock %d ok", ofst));
28278 pShmNode->exclMask &= ~mask;
28279 pShmNode->sharedMask &= ~mask;
28280 }else if( lockType==F_RDLCK ){
28281 OSTRACE(("read-lock %d ok", ofst));
28282 pShmNode->exclMask &= ~mask;
28283 pShmNode->sharedMask |= mask;
28284 }else{
28285 assert( lockType==F_WRLCK );
28286 OSTRACE(("write-lock %d ok", ofst));
28287 pShmNode->exclMask |= mask;
28288 pShmNode->sharedMask &= ~mask;
28290 }else{
28291 if( lockType==F_UNLCK ){
28292 OSTRACE(("unlock %d failed", ofst));
28293 }else if( lockType==F_RDLCK ){
28294 OSTRACE(("read-lock failed"));
28295 }else{
28296 assert( lockType==F_WRLCK );
28297 OSTRACE(("write-lock %d failed", ofst));
28300 OSTRACE((" - afterwards %03x,%03x\n",
28301 pShmNode->sharedMask, pShmNode->exclMask));
28303 #endif
28305 return rc;
28310 ** Purge the unixShmNodeList list of all entries with unixShmNode.nRef==0.
28312 ** This is not a VFS shared-memory method; it is a utility function called
28313 ** by VFS shared-memory methods.
28315 static void unixShmPurge(unixFile *pFd){
28316 unixShmNode *p = pFd->pInode->pShmNode;
28317 assert( unixMutexHeld() );
28318 if( p && p->nRef==0 ){
28319 int i;
28320 assert( p->pInode==pFd->pInode );
28321 sqlite3_mutex_free(p->mutex);
28322 for(i=0; i<p->nRegion; i++){
28323 if( p->h>=0 ){
28324 munmap(p->apRegion[i], p->szRegion);
28325 }else{
28326 sqlite3_free(p->apRegion[i]);
28329 sqlite3_free(p->apRegion);
28330 if( p->h>=0 ){
28331 robust_close(pFd, p->h, __LINE__);
28332 p->h = -1;
28334 p->pInode->pShmNode = 0;
28335 sqlite3_free(p);
28340 ** Open a shared-memory area associated with open database file pDbFd.
28341 ** This particular implementation uses mmapped files.
28343 ** The file used to implement shared-memory is in the same directory
28344 ** as the open database file and has the same name as the open database
28345 ** file with the "-shm" suffix added. For example, if the database file
28346 ** is "/home/user1/config.db" then the file that is created and mmapped
28347 ** for shared memory will be called "/home/user1/config.db-shm".
28349 ** Another approach to is to use files in /dev/shm or /dev/tmp or an
28350 ** some other tmpfs mount. But if a file in a different directory
28351 ** from the database file is used, then differing access permissions
28352 ** or a chroot() might cause two different processes on the same
28353 ** database to end up using different files for shared memory -
28354 ** meaning that their memory would not really be shared - resulting
28355 ** in database corruption. Nevertheless, this tmpfs file usage
28356 ** can be enabled at compile-time using -DSQLITE_SHM_DIRECTORY="/dev/shm"
28357 ** or the equivalent. The use of the SQLITE_SHM_DIRECTORY compile-time
28358 ** option results in an incompatible build of SQLite; builds of SQLite
28359 ** that with differing SQLITE_SHM_DIRECTORY settings attempt to use the
28360 ** same database file at the same time, database corruption will likely
28361 ** result. The SQLITE_SHM_DIRECTORY compile-time option is considered
28362 ** "unsupported" and may go away in a future SQLite release.
28364 ** When opening a new shared-memory file, if no other instances of that
28365 ** file are currently open, in this process or in other processes, then
28366 ** the file must be truncated to zero length or have its header cleared.
28368 ** If the original database file (pDbFd) is using the "unix-excl" VFS
28369 ** that means that an exclusive lock is held on the database file and
28370 ** that no other processes are able to read or write the database. In
28371 ** that case, we do not really need shared memory. No shared memory
28372 ** file is created. The shared memory will be simulated with heap memory.
28374 static int unixOpenSharedMemory(unixFile *pDbFd){
28375 struct unixShm *p = 0; /* The connection to be opened */
28376 struct unixShmNode *pShmNode; /* The underlying mmapped file */
28377 int rc; /* Result code */
28378 unixInodeInfo *pInode; /* The inode of fd */
28379 char *zShmFilename; /* Name of the file used for SHM */
28380 int nShmFilename; /* Size of the SHM filename in bytes */
28382 /* Allocate space for the new unixShm object. */
28383 p = sqlite3_malloc( sizeof(*p) );
28384 if( p==0 ) return SQLITE_NOMEM;
28385 memset(p, 0, sizeof(*p));
28386 assert( pDbFd->pShm==0 );
28388 /* Check to see if a unixShmNode object already exists. Reuse an existing
28389 ** one if present. Create a new one if necessary.
28391 unixEnterMutex();
28392 pInode = pDbFd->pInode;
28393 pShmNode = pInode->pShmNode;
28394 if( pShmNode==0 ){
28395 struct stat sStat; /* fstat() info for database file */
28397 /* Call fstat() to figure out the permissions on the database file. If
28398 ** a new *-shm file is created, an attempt will be made to create it
28399 ** with the same permissions. The actual permissions the file is created
28400 ** with are subject to the current umask setting.
28402 if( osFstat(pDbFd->h, &sStat) && pInode->bProcessLock==0 ){
28403 rc = SQLITE_IOERR_FSTAT;
28404 goto shm_open_err;
28407 #ifdef SQLITE_SHM_DIRECTORY
28408 nShmFilename = sizeof(SQLITE_SHM_DIRECTORY) + 30;
28409 #else
28410 nShmFilename = 5 + (int)strlen(pDbFd->zPath);
28411 #endif
28412 pShmNode = sqlite3_malloc( sizeof(*pShmNode) + nShmFilename );
28413 if( pShmNode==0 ){
28414 rc = SQLITE_NOMEM;
28415 goto shm_open_err;
28417 memset(pShmNode, 0, sizeof(*pShmNode));
28418 zShmFilename = pShmNode->zFilename = (char*)&pShmNode[1];
28419 #ifdef SQLITE_SHM_DIRECTORY
28420 sqlite3_snprintf(nShmFilename, zShmFilename,
28421 SQLITE_SHM_DIRECTORY "/sqlite-shm-%x-%x",
28422 (u32)sStat.st_ino, (u32)sStat.st_dev);
28423 #else
28424 sqlite3_snprintf(nShmFilename, zShmFilename, "%s-shm", pDbFd->zPath);
28425 sqlite3FileSuffix3(pDbFd->zPath, zShmFilename);
28426 #endif
28427 pShmNode->h = -1;
28428 pDbFd->pInode->pShmNode = pShmNode;
28429 pShmNode->pInode = pDbFd->pInode;
28430 pShmNode->mutex = sqlite3_mutex_alloc(SQLITE_MUTEX_FAST);
28431 if( pShmNode->mutex==0 ){
28432 rc = SQLITE_NOMEM;
28433 goto shm_open_err;
28436 if( pInode->bProcessLock==0 ){
28437 pShmNode->h = robust_open(zShmFilename, O_RDWR|O_CREAT,
28438 (sStat.st_mode & 0777));
28439 if( pShmNode->h<0 ){
28440 const char *zRO;
28441 zRO = sqlite3_uri_parameter(pDbFd->zPath, "readonly_shm");
28442 if( zRO && sqlite3GetBoolean(zRO) ){
28443 pShmNode->h = robust_open(zShmFilename, O_RDONLY,
28444 (sStat.st_mode & 0777));
28445 pShmNode->isReadonly = 1;
28447 if( pShmNode->h<0 ){
28448 rc = unixLogError(SQLITE_CANTOPEN_BKPT, "open", zShmFilename);
28449 goto shm_open_err;
28453 /* Check to see if another process is holding the dead-man switch.
28454 ** If not, truncate the file to zero length.
28456 rc = SQLITE_OK;
28457 if( unixShmSystemLock(pShmNode, F_WRLCK, UNIX_SHM_DMS, 1)==SQLITE_OK ){
28458 if( robust_ftruncate(pShmNode->h, 0) ){
28459 rc = unixLogError(SQLITE_IOERR_SHMOPEN, "ftruncate", zShmFilename);
28462 if( rc==SQLITE_OK ){
28463 rc = unixShmSystemLock(pShmNode, F_RDLCK, UNIX_SHM_DMS, 1);
28465 if( rc ) goto shm_open_err;
28469 /* Make the new connection a child of the unixShmNode */
28470 p->pShmNode = pShmNode;
28471 #ifdef SQLITE_DEBUG
28472 p->id = pShmNode->nextShmId++;
28473 #endif
28474 pShmNode->nRef++;
28475 pDbFd->pShm = p;
28476 unixLeaveMutex();
28478 /* The reference count on pShmNode has already been incremented under
28479 ** the cover of the unixEnterMutex() mutex and the pointer from the
28480 ** new (struct unixShm) object to the pShmNode has been set. All that is
28481 ** left to do is to link the new object into the linked list starting
28482 ** at pShmNode->pFirst. This must be done while holding the pShmNode->mutex
28483 ** mutex.
28485 sqlite3_mutex_enter(pShmNode->mutex);
28486 p->pNext = pShmNode->pFirst;
28487 pShmNode->pFirst = p;
28488 sqlite3_mutex_leave(pShmNode->mutex);
28489 return SQLITE_OK;
28491 /* Jump here on any error */
28492 shm_open_err:
28493 unixShmPurge(pDbFd); /* This call frees pShmNode if required */
28494 sqlite3_free(p);
28495 unixLeaveMutex();
28496 return rc;
28500 ** This function is called to obtain a pointer to region iRegion of the
28501 ** shared-memory associated with the database file fd. Shared-memory regions
28502 ** are numbered starting from zero. Each shared-memory region is szRegion
28503 ** bytes in size.
28505 ** If an error occurs, an error code is returned and *pp is set to NULL.
28507 ** Otherwise, if the bExtend parameter is 0 and the requested shared-memory
28508 ** region has not been allocated (by any client, including one running in a
28509 ** separate process), then *pp is set to NULL and SQLITE_OK returned. If
28510 ** bExtend is non-zero and the requested shared-memory region has not yet
28511 ** been allocated, it is allocated by this function.
28513 ** If the shared-memory region has already been allocated or is allocated by
28514 ** this call as described above, then it is mapped into this processes
28515 ** address space (if it is not already), *pp is set to point to the mapped
28516 ** memory and SQLITE_OK returned.
28518 static int unixShmMap(
28519 sqlite3_file *fd, /* Handle open on database file */
28520 int iRegion, /* Region to retrieve */
28521 int szRegion, /* Size of regions */
28522 int bExtend, /* True to extend file if necessary */
28523 void volatile **pp /* OUT: Mapped memory */
28525 unixFile *pDbFd = (unixFile*)fd;
28526 unixShm *p;
28527 unixShmNode *pShmNode;
28528 int rc = SQLITE_OK;
28530 /* If the shared-memory file has not yet been opened, open it now. */
28531 if( pDbFd->pShm==0 ){
28532 rc = unixOpenSharedMemory(pDbFd);
28533 if( rc!=SQLITE_OK ) return rc;
28536 p = pDbFd->pShm;
28537 pShmNode = p->pShmNode;
28538 sqlite3_mutex_enter(pShmNode->mutex);
28539 assert( szRegion==pShmNode->szRegion || pShmNode->nRegion==0 );
28540 assert( pShmNode->pInode==pDbFd->pInode );
28541 assert( pShmNode->h>=0 || pDbFd->pInode->bProcessLock==1 );
28542 assert( pShmNode->h<0 || pDbFd->pInode->bProcessLock==0 );
28544 if( pShmNode->nRegion<=iRegion ){
28545 char **apNew; /* New apRegion[] array */
28546 int nByte = (iRegion+1)*szRegion; /* Minimum required file size */
28547 struct stat sStat; /* Used by fstat() */
28549 pShmNode->szRegion = szRegion;
28551 if( pShmNode->h>=0 ){
28552 /* The requested region is not mapped into this processes address space.
28553 ** Check to see if it has been allocated (i.e. if the wal-index file is
28554 ** large enough to contain the requested region).
28556 if( osFstat(pShmNode->h, &sStat) ){
28557 rc = SQLITE_IOERR_SHMSIZE;
28558 goto shmpage_out;
28561 if( sStat.st_size<nByte ){
28562 /* The requested memory region does not exist. If bExtend is set to
28563 ** false, exit early. *pp will be set to NULL and SQLITE_OK returned.
28565 ** Alternatively, if bExtend is true, use ftruncate() to allocate
28566 ** the requested memory region.
28568 if( !bExtend ) goto shmpage_out;
28569 if( robust_ftruncate(pShmNode->h, nByte) ){
28570 rc = unixLogError(SQLITE_IOERR_SHMSIZE, "ftruncate",
28571 pShmNode->zFilename);
28572 goto shmpage_out;
28577 /* Map the requested memory region into this processes address space. */
28578 apNew = (char **)sqlite3_realloc(
28579 pShmNode->apRegion, (iRegion+1)*sizeof(char *)
28581 if( !apNew ){
28582 rc = SQLITE_IOERR_NOMEM;
28583 goto shmpage_out;
28585 pShmNode->apRegion = apNew;
28586 while(pShmNode->nRegion<=iRegion){
28587 void *pMem;
28588 if( pShmNode->h>=0 ){
28589 pMem = mmap(0, szRegion,
28590 pShmNode->isReadonly ? PROT_READ : PROT_READ|PROT_WRITE,
28591 MAP_SHARED, pShmNode->h, pShmNode->nRegion*szRegion
28593 if( pMem==MAP_FAILED ){
28594 rc = unixLogError(SQLITE_IOERR_SHMMAP, "mmap", pShmNode->zFilename);
28595 goto shmpage_out;
28597 }else{
28598 pMem = sqlite3_malloc(szRegion);
28599 if( pMem==0 ){
28600 rc = SQLITE_NOMEM;
28601 goto shmpage_out;
28603 memset(pMem, 0, szRegion);
28605 pShmNode->apRegion[pShmNode->nRegion] = pMem;
28606 pShmNode->nRegion++;
28610 shmpage_out:
28611 if( pShmNode->nRegion>iRegion ){
28612 *pp = pShmNode->apRegion[iRegion];
28613 }else{
28614 *pp = 0;
28616 if( pShmNode->isReadonly && rc==SQLITE_OK ) rc = SQLITE_READONLY;
28617 sqlite3_mutex_leave(pShmNode->mutex);
28618 return rc;
28622 ** Change the lock state for a shared-memory segment.
28624 ** Note that the relationship between SHAREd and EXCLUSIVE locks is a little
28625 ** different here than in posix. In xShmLock(), one can go from unlocked
28626 ** to shared and back or from unlocked to exclusive and back. But one may
28627 ** not go from shared to exclusive or from exclusive to shared.
28629 static int unixShmLock(
28630 sqlite3_file *fd, /* Database file holding the shared memory */
28631 int ofst, /* First lock to acquire or release */
28632 int n, /* Number of locks to acquire or release */
28633 int flags /* What to do with the lock */
28635 unixFile *pDbFd = (unixFile*)fd; /* Connection holding shared memory */
28636 unixShm *p = pDbFd->pShm; /* The shared memory being locked */
28637 unixShm *pX; /* For looping over all siblings */
28638 unixShmNode *pShmNode = p->pShmNode; /* The underlying file iNode */
28639 int rc = SQLITE_OK; /* Result code */
28640 u16 mask; /* Mask of locks to take or release */
28642 assert( pShmNode==pDbFd->pInode->pShmNode );
28643 assert( pShmNode->pInode==pDbFd->pInode );
28644 assert( ofst>=0 && ofst+n<=SQLITE_SHM_NLOCK );
28645 assert( n>=1 );
28646 assert( flags==(SQLITE_SHM_LOCK | SQLITE_SHM_SHARED)
28647 || flags==(SQLITE_SHM_LOCK | SQLITE_SHM_EXCLUSIVE)
28648 || flags==(SQLITE_SHM_UNLOCK | SQLITE_SHM_SHARED)
28649 || flags==(SQLITE_SHM_UNLOCK | SQLITE_SHM_EXCLUSIVE) );
28650 assert( n==1 || (flags & SQLITE_SHM_EXCLUSIVE)!=0 );
28651 assert( pShmNode->h>=0 || pDbFd->pInode->bProcessLock==1 );
28652 assert( pShmNode->h<0 || pDbFd->pInode->bProcessLock==0 );
28654 mask = (1<<(ofst+n)) - (1<<ofst);
28655 assert( n>1 || mask==(1<<ofst) );
28656 sqlite3_mutex_enter(pShmNode->mutex);
28657 if( flags & SQLITE_SHM_UNLOCK ){
28658 u16 allMask = 0; /* Mask of locks held by siblings */
28660 /* See if any siblings hold this same lock */
28661 for(pX=pShmNode->pFirst; pX; pX=pX->pNext){
28662 if( pX==p ) continue;
28663 assert( (pX->exclMask & (p->exclMask|p->sharedMask))==0 );
28664 allMask |= pX->sharedMask;
28667 /* Unlock the system-level locks */
28668 if( (mask & allMask)==0 ){
28669 rc = unixShmSystemLock(pShmNode, F_UNLCK, ofst+UNIX_SHM_BASE, n);
28670 }else{
28671 rc = SQLITE_OK;
28674 /* Undo the local locks */
28675 if( rc==SQLITE_OK ){
28676 p->exclMask &= ~mask;
28677 p->sharedMask &= ~mask;
28679 }else if( flags & SQLITE_SHM_SHARED ){
28680 u16 allShared = 0; /* Union of locks held by connections other than "p" */
28682 /* Find out which shared locks are already held by sibling connections.
28683 ** If any sibling already holds an exclusive lock, go ahead and return
28684 ** SQLITE_BUSY.
28686 for(pX=pShmNode->pFirst; pX; pX=pX->pNext){
28687 if( (pX->exclMask & mask)!=0 ){
28688 rc = SQLITE_BUSY;
28689 break;
28691 allShared |= pX->sharedMask;
28694 /* Get shared locks at the system level, if necessary */
28695 if( rc==SQLITE_OK ){
28696 if( (allShared & mask)==0 ){
28697 rc = unixShmSystemLock(pShmNode, F_RDLCK, ofst+UNIX_SHM_BASE, n);
28698 }else{
28699 rc = SQLITE_OK;
28703 /* Get the local shared locks */
28704 if( rc==SQLITE_OK ){
28705 p->sharedMask |= mask;
28707 }else{
28708 /* Make sure no sibling connections hold locks that will block this
28709 ** lock. If any do, return SQLITE_BUSY right away.
28711 for(pX=pShmNode->pFirst; pX; pX=pX->pNext){
28712 if( (pX->exclMask & mask)!=0 || (pX->sharedMask & mask)!=0 ){
28713 rc = SQLITE_BUSY;
28714 break;
28718 /* Get the exclusive locks at the system level. Then if successful
28719 ** also mark the local connection as being locked.
28721 if( rc==SQLITE_OK ){
28722 rc = unixShmSystemLock(pShmNode, F_WRLCK, ofst+UNIX_SHM_BASE, n);
28723 if( rc==SQLITE_OK ){
28724 assert( (p->sharedMask & mask)==0 );
28725 p->exclMask |= mask;
28729 sqlite3_mutex_leave(pShmNode->mutex);
28730 OSTRACE(("SHM-LOCK shmid-%d, pid-%d got %03x,%03x\n",
28731 p->id, getpid(), p->sharedMask, p->exclMask));
28732 return rc;
28736 ** Implement a memory barrier or memory fence on shared memory.
28738 ** All loads and stores begun before the barrier must complete before
28739 ** any load or store begun after the barrier.
28741 static void unixShmBarrier(
28742 sqlite3_file *fd /* Database file holding the shared memory */
28744 UNUSED_PARAMETER(fd);
28745 unixEnterMutex();
28746 unixLeaveMutex();
28750 ** Close a connection to shared-memory. Delete the underlying
28751 ** storage if deleteFlag is true.
28753 ** If there is no shared memory associated with the connection then this
28754 ** routine is a harmless no-op.
28756 static int unixShmUnmap(
28757 sqlite3_file *fd, /* The underlying database file */
28758 int deleteFlag /* Delete shared-memory if true */
28760 unixShm *p; /* The connection to be closed */
28761 unixShmNode *pShmNode; /* The underlying shared-memory file */
28762 unixShm **pp; /* For looping over sibling connections */
28763 unixFile *pDbFd; /* The underlying database file */
28765 pDbFd = (unixFile*)fd;
28766 p = pDbFd->pShm;
28767 if( p==0 ) return SQLITE_OK;
28768 pShmNode = p->pShmNode;
28770 assert( pShmNode==pDbFd->pInode->pShmNode );
28771 assert( pShmNode->pInode==pDbFd->pInode );
28773 /* Remove connection p from the set of connections associated
28774 ** with pShmNode */
28775 sqlite3_mutex_enter(pShmNode->mutex);
28776 for(pp=&pShmNode->pFirst; (*pp)!=p; pp = &(*pp)->pNext){}
28777 *pp = p->pNext;
28779 /* Free the connection p */
28780 sqlite3_free(p);
28781 pDbFd->pShm = 0;
28782 sqlite3_mutex_leave(pShmNode->mutex);
28784 /* If pShmNode->nRef has reached 0, then close the underlying
28785 ** shared-memory file, too */
28786 unixEnterMutex();
28787 assert( pShmNode->nRef>0 );
28788 pShmNode->nRef--;
28789 if( pShmNode->nRef==0 ){
28790 if( deleteFlag && pShmNode->h>=0 ) osUnlink(pShmNode->zFilename);
28791 unixShmPurge(pDbFd);
28793 unixLeaveMutex();
28795 return SQLITE_OK;
28799 #else
28800 # define unixShmMap 0
28801 # define unixShmLock 0
28802 # define unixShmBarrier 0
28803 # define unixShmUnmap 0
28804 #endif /* #ifndef SQLITE_OMIT_WAL */
28807 ** Here ends the implementation of all sqlite3_file methods.
28809 ********************** End sqlite3_file Methods *******************************
28810 ******************************************************************************/
28813 ** This division contains definitions of sqlite3_io_methods objects that
28814 ** implement various file locking strategies. It also contains definitions
28815 ** of "finder" functions. A finder-function is used to locate the appropriate
28816 ** sqlite3_io_methods object for a particular database file. The pAppData
28817 ** field of the sqlite3_vfs VFS objects are initialized to be pointers to
28818 ** the correct finder-function for that VFS.
28820 ** Most finder functions return a pointer to a fixed sqlite3_io_methods
28821 ** object. The only interesting finder-function is autolockIoFinder, which
28822 ** looks at the filesystem type and tries to guess the best locking
28823 ** strategy from that.
28825 ** For finder-funtion F, two objects are created:
28827 ** (1) The real finder-function named "FImpt()".
28829 ** (2) A constant pointer to this function named just "F".
28832 ** A pointer to the F pointer is used as the pAppData value for VFS
28833 ** objects. We have to do this instead of letting pAppData point
28834 ** directly at the finder-function since C90 rules prevent a void*
28835 ** from be cast into a function pointer.
28838 ** Each instance of this macro generates two objects:
28840 ** * A constant sqlite3_io_methods object call METHOD that has locking
28841 ** methods CLOSE, LOCK, UNLOCK, CKRESLOCK.
28843 ** * An I/O method finder function called FINDER that returns a pointer
28844 ** to the METHOD object in the previous bullet.
28846 #define IOMETHODS(FINDER, METHOD, VERSION, CLOSE, LOCK, UNLOCK, CKLOCK) \
28847 static const sqlite3_io_methods METHOD = { \
28848 VERSION, /* iVersion */ \
28849 CLOSE, /* xClose */ \
28850 unixRead, /* xRead */ \
28851 unixWrite, /* xWrite */ \
28852 unixTruncate, /* xTruncate */ \
28853 unixSync, /* xSync */ \
28854 unixFileSize, /* xFileSize */ \
28855 LOCK, /* xLock */ \
28856 UNLOCK, /* xUnlock */ \
28857 CKLOCK, /* xCheckReservedLock */ \
28858 unixFileControl, /* xFileControl */ \
28859 unixSectorSize, /* xSectorSize */ \
28860 unixDeviceCharacteristics, /* xDeviceCapabilities */ \
28861 unixShmMap, /* xShmMap */ \
28862 unixShmLock, /* xShmLock */ \
28863 unixShmBarrier, /* xShmBarrier */ \
28864 unixShmUnmap /* xShmUnmap */ \
28865 }; \
28866 static const sqlite3_io_methods *FINDER##Impl(const char *z, unixFile *p){ \
28867 UNUSED_PARAMETER(z); UNUSED_PARAMETER(p); \
28868 return &METHOD; \
28870 static const sqlite3_io_methods *(*const FINDER)(const char*,unixFile *p) \
28871 = FINDER##Impl;
28874 ** Here are all of the sqlite3_io_methods objects for each of the
28875 ** locking strategies. Functions that return pointers to these methods
28876 ** are also created.
28878 IOMETHODS(
28879 posixIoFinder, /* Finder function name */
28880 posixIoMethods, /* sqlite3_io_methods object name */
28881 2, /* shared memory is enabled */
28882 unixClose, /* xClose method */
28883 unixLock, /* xLock method */
28884 unixUnlock, /* xUnlock method */
28885 unixCheckReservedLock /* xCheckReservedLock method */
28887 IOMETHODS(
28888 nolockIoFinder, /* Finder function name */
28889 nolockIoMethods, /* sqlite3_io_methods object name */
28890 1, /* shared memory is disabled */
28891 nolockClose, /* xClose method */
28892 nolockLock, /* xLock method */
28893 nolockUnlock, /* xUnlock method */
28894 nolockCheckReservedLock /* xCheckReservedLock method */
28896 IOMETHODS(
28897 dotlockIoFinder, /* Finder function name */
28898 dotlockIoMethods, /* sqlite3_io_methods object name */
28899 1, /* shared memory is disabled */
28900 dotlockClose, /* xClose method */
28901 dotlockLock, /* xLock method */
28902 dotlockUnlock, /* xUnlock method */
28903 dotlockCheckReservedLock /* xCheckReservedLock method */
28906 #if SQLITE_ENABLE_LOCKING_STYLE && !OS_VXWORKS
28907 IOMETHODS(
28908 flockIoFinder, /* Finder function name */
28909 flockIoMethods, /* sqlite3_io_methods object name */
28910 1, /* shared memory is disabled */
28911 flockClose, /* xClose method */
28912 flockLock, /* xLock method */
28913 flockUnlock, /* xUnlock method */
28914 flockCheckReservedLock /* xCheckReservedLock method */
28916 #endif
28918 #if OS_VXWORKS
28919 IOMETHODS(
28920 semIoFinder, /* Finder function name */
28921 semIoMethods, /* sqlite3_io_methods object name */
28922 1, /* shared memory is disabled */
28923 semClose, /* xClose method */
28924 semLock, /* xLock method */
28925 semUnlock, /* xUnlock method */
28926 semCheckReservedLock /* xCheckReservedLock method */
28928 #endif
28930 #if defined(__APPLE__) && SQLITE_ENABLE_LOCKING_STYLE
28931 IOMETHODS(
28932 afpIoFinder, /* Finder function name */
28933 afpIoMethods, /* sqlite3_io_methods object name */
28934 1, /* shared memory is disabled */
28935 afpClose, /* xClose method */
28936 afpLock, /* xLock method */
28937 afpUnlock, /* xUnlock method */
28938 afpCheckReservedLock /* xCheckReservedLock method */
28940 #endif
28943 ** The proxy locking method is a "super-method" in the sense that it
28944 ** opens secondary file descriptors for the conch and lock files and
28945 ** it uses proxy, dot-file, AFP, and flock() locking methods on those
28946 ** secondary files. For this reason, the division that implements
28947 ** proxy locking is located much further down in the file. But we need
28948 ** to go ahead and define the sqlite3_io_methods and finder function
28949 ** for proxy locking here. So we forward declare the I/O methods.
28951 #if defined(__APPLE__) && SQLITE_ENABLE_LOCKING_STYLE
28952 static int proxyClose(sqlite3_file*);
28953 static int proxyLock(sqlite3_file*, int);
28954 static int proxyUnlock(sqlite3_file*, int);
28955 static int proxyCheckReservedLock(sqlite3_file*, int*);
28956 IOMETHODS(
28957 proxyIoFinder, /* Finder function name */
28958 proxyIoMethods, /* sqlite3_io_methods object name */
28959 1, /* shared memory is disabled */
28960 proxyClose, /* xClose method */
28961 proxyLock, /* xLock method */
28962 proxyUnlock, /* xUnlock method */
28963 proxyCheckReservedLock /* xCheckReservedLock method */
28965 #endif
28967 /* nfs lockd on OSX 10.3+ doesn't clear write locks when a read lock is set */
28968 #if defined(__APPLE__) && SQLITE_ENABLE_LOCKING_STYLE
28969 IOMETHODS(
28970 nfsIoFinder, /* Finder function name */
28971 nfsIoMethods, /* sqlite3_io_methods object name */
28972 1, /* shared memory is disabled */
28973 unixClose, /* xClose method */
28974 unixLock, /* xLock method */
28975 nfsUnlock, /* xUnlock method */
28976 unixCheckReservedLock /* xCheckReservedLock method */
28978 #endif
28980 #if defined(__APPLE__) && SQLITE_ENABLE_LOCKING_STYLE
28982 ** This "finder" function attempts to determine the best locking strategy
28983 ** for the database file "filePath". It then returns the sqlite3_io_methods
28984 ** object that implements that strategy.
28986 ** This is for MacOSX only.
28988 static const sqlite3_io_methods *autolockIoFinderImpl(
28989 const char *filePath, /* name of the database file */
28990 unixFile *pNew /* open file object for the database file */
28992 static const struct Mapping {
28993 const char *zFilesystem; /* Filesystem type name */
28994 const sqlite3_io_methods *pMethods; /* Appropriate locking method */
28995 } aMap[] = {
28996 { "hfs", &posixIoMethods },
28997 { "ufs", &posixIoMethods },
28998 { "afpfs", &afpIoMethods },
28999 { "smbfs", &afpIoMethods },
29000 { "webdav", &nolockIoMethods },
29001 { 0, 0 }
29003 int i;
29004 struct statfs fsInfo;
29005 struct flock lockInfo;
29007 if( !filePath ){
29008 /* If filePath==NULL that means we are dealing with a transient file
29009 ** that does not need to be locked. */
29010 return &nolockIoMethods;
29012 if( statfs(filePath, &fsInfo) != -1 ){
29013 if( fsInfo.f_flags & MNT_RDONLY ){
29014 return &nolockIoMethods;
29016 for(i=0; aMap[i].zFilesystem; i++){
29017 if( strcmp(fsInfo.f_fstypename, aMap[i].zFilesystem)==0 ){
29018 return aMap[i].pMethods;
29023 /* Default case. Handles, amongst others, "nfs".
29024 ** Test byte-range lock using fcntl(). If the call succeeds,
29025 ** assume that the file-system supports POSIX style locks.
29027 lockInfo.l_len = 1;
29028 lockInfo.l_start = 0;
29029 lockInfo.l_whence = SEEK_SET;
29030 lockInfo.l_type = F_RDLCK;
29031 if( osFcntl(pNew->h, F_GETLK, &lockInfo)!=-1 ) {
29032 if( strcmp(fsInfo.f_fstypename, "nfs")==0 ){
29033 return &nfsIoMethods;
29034 } else {
29035 return &posixIoMethods;
29037 }else{
29038 return &dotlockIoMethods;
29041 static const sqlite3_io_methods
29042 *(*const autolockIoFinder)(const char*,unixFile*) = autolockIoFinderImpl;
29044 #endif /* defined(__APPLE__) && SQLITE_ENABLE_LOCKING_STYLE */
29046 #if OS_VXWORKS && SQLITE_ENABLE_LOCKING_STYLE
29048 ** This "finder" function attempts to determine the best locking strategy
29049 ** for the database file "filePath". It then returns the sqlite3_io_methods
29050 ** object that implements that strategy.
29052 ** This is for VXWorks only.
29054 static const sqlite3_io_methods *autolockIoFinderImpl(
29055 const char *filePath, /* name of the database file */
29056 unixFile *pNew /* the open file object */
29058 struct flock lockInfo;
29060 if( !filePath ){
29061 /* If filePath==NULL that means we are dealing with a transient file
29062 ** that does not need to be locked. */
29063 return &nolockIoMethods;
29066 /* Test if fcntl() is supported and use POSIX style locks.
29067 ** Otherwise fall back to the named semaphore method.
29069 lockInfo.l_len = 1;
29070 lockInfo.l_start = 0;
29071 lockInfo.l_whence = SEEK_SET;
29072 lockInfo.l_type = F_RDLCK;
29073 if( osFcntl(pNew->h, F_GETLK, &lockInfo)!=-1 ) {
29074 return &posixIoMethods;
29075 }else{
29076 return &semIoMethods;
29079 static const sqlite3_io_methods
29080 *(*const autolockIoFinder)(const char*,unixFile*) = autolockIoFinderImpl;
29082 #endif /* OS_VXWORKS && SQLITE_ENABLE_LOCKING_STYLE */
29085 ** An abstract type for a pointer to a IO method finder function:
29087 typedef const sqlite3_io_methods *(*finder_type)(const char*,unixFile*);
29090 /****************************************************************************
29091 **************************** sqlite3_vfs methods ****************************
29093 ** This division contains the implementation of methods on the
29094 ** sqlite3_vfs object.
29098 ** Initialize the contents of the unixFile structure pointed to by pId.
29100 static int fillInUnixFile(
29101 sqlite3_vfs *pVfs, /* Pointer to vfs object */
29102 int h, /* Open file descriptor of file being opened */
29103 int syncDir, /* True to sync directory on first sync */
29104 sqlite3_file *pId, /* Write to the unixFile structure here */
29105 const char *zFilename, /* Name of the file being opened */
29106 int noLock, /* Omit locking if true */
29107 int isDelete, /* Delete on close if true */
29108 int isReadOnly /* True if the file is opened read-only */
29110 const sqlite3_io_methods *pLockingStyle;
29111 unixFile *pNew = (unixFile *)pId;
29112 int rc = SQLITE_OK;
29114 assert( pNew->pInode==NULL );
29116 /* Parameter isDelete is only used on vxworks. Express this explicitly
29117 ** here to prevent compiler warnings about unused parameters.
29119 UNUSED_PARAMETER(isDelete);
29121 /* Usually the path zFilename should not be a relative pathname. The
29122 ** exception is when opening the proxy "conch" file in builds that
29123 ** include the special Apple locking styles.
29125 #if defined(__APPLE__) && SQLITE_ENABLE_LOCKING_STYLE
29126 assert( zFilename==0 || zFilename[0]=='/'
29127 || pVfs->pAppData==(void*)&autolockIoFinder );
29128 #else
29129 assert( zFilename==0 || zFilename[0]=='/' );
29130 #endif
29132 OSTRACE(("OPEN %-3d %s\n", h, zFilename));
29133 pNew->h = h;
29134 pNew->zPath = zFilename;
29135 if( memcmp(pVfs->zName,"unix-excl",10)==0 ){
29136 pNew->ctrlFlags = UNIXFILE_EXCL;
29137 }else{
29138 pNew->ctrlFlags = 0;
29140 if( isReadOnly ){
29141 pNew->ctrlFlags |= UNIXFILE_RDONLY;
29143 if( syncDir ){
29144 pNew->ctrlFlags |= UNIXFILE_DIRSYNC;
29147 #if OS_VXWORKS
29148 pNew->pId = vxworksFindFileId(zFilename);
29149 if( pNew->pId==0 ){
29150 noLock = 1;
29151 rc = SQLITE_NOMEM;
29153 #endif
29155 if( noLock ){
29156 pLockingStyle = &nolockIoMethods;
29157 }else{
29158 pLockingStyle = (**(finder_type*)pVfs->pAppData)(zFilename, pNew);
29159 #if SQLITE_ENABLE_LOCKING_STYLE
29160 /* Cache zFilename in the locking context (AFP and dotlock override) for
29161 ** proxyLock activation is possible (remote proxy is based on db name)
29162 ** zFilename remains valid until file is closed, to support */
29163 pNew->lockingContext = (void*)zFilename;
29164 #endif
29167 if( pLockingStyle == &posixIoMethods
29168 #if defined(__APPLE__) && SQLITE_ENABLE_LOCKING_STYLE
29169 || pLockingStyle == &nfsIoMethods
29170 #endif
29172 unixEnterMutex();
29173 rc = findInodeInfo(pNew, &pNew->pInode);
29174 if( rc!=SQLITE_OK ){
29175 /* If an error occured in findInodeInfo(), close the file descriptor
29176 ** immediately, before releasing the mutex. findInodeInfo() may fail
29177 ** in two scenarios:
29179 ** (a) A call to fstat() failed.
29180 ** (b) A malloc failed.
29182 ** Scenario (b) may only occur if the process is holding no other
29183 ** file descriptors open on the same file. If there were other file
29184 ** descriptors on this file, then no malloc would be required by
29185 ** findInodeInfo(). If this is the case, it is quite safe to close
29186 ** handle h - as it is guaranteed that no posix locks will be released
29187 ** by doing so.
29189 ** If scenario (a) caused the error then things are not so safe. The
29190 ** implicit assumption here is that if fstat() fails, things are in
29191 ** such bad shape that dropping a lock or two doesn't matter much.
29193 robust_close(pNew, h, __LINE__);
29194 h = -1;
29196 unixLeaveMutex();
29199 #if SQLITE_ENABLE_LOCKING_STYLE && defined(__APPLE__)
29200 else if( pLockingStyle == &afpIoMethods ){
29201 /* AFP locking uses the file path so it needs to be included in
29202 ** the afpLockingContext.
29204 afpLockingContext *pCtx;
29205 pNew->lockingContext = pCtx = sqlite3_malloc( sizeof(*pCtx) );
29206 if( pCtx==0 ){
29207 rc = SQLITE_NOMEM;
29208 }else{
29209 /* NB: zFilename exists and remains valid until the file is closed
29210 ** according to requirement F11141. So we do not need to make a
29211 ** copy of the filename. */
29212 pCtx->dbPath = zFilename;
29213 pCtx->reserved = 0;
29214 srandomdev();
29215 unixEnterMutex();
29216 rc = findInodeInfo(pNew, &pNew->pInode);
29217 if( rc!=SQLITE_OK ){
29218 sqlite3_free(pNew->lockingContext);
29219 robust_close(pNew, h, __LINE__);
29220 h = -1;
29222 unixLeaveMutex();
29225 #endif
29227 else if( pLockingStyle == &dotlockIoMethods ){
29228 /* Dotfile locking uses the file path so it needs to be included in
29229 ** the dotlockLockingContext
29231 char *zLockFile;
29232 int nFilename;
29233 nFilename = (int)strlen(zFilename) + 6;
29234 zLockFile = (char *)sqlite3_malloc(nFilename);
29235 if( zLockFile==0 ){
29236 rc = SQLITE_NOMEM;
29237 }else{
29238 sqlite3_snprintf(nFilename, zLockFile, "%s" DOTLOCK_SUFFIX, zFilename);
29240 pNew->lockingContext = zLockFile;
29243 #if OS_VXWORKS
29244 else if( pLockingStyle == &semIoMethods ){
29245 /* Named semaphore locking uses the file path so it needs to be
29246 ** included in the semLockingContext
29248 unixEnterMutex();
29249 rc = findInodeInfo(pNew, &pNew->pInode);
29250 if( (rc==SQLITE_OK) && (pNew->pInode->pSem==NULL) ){
29251 char *zSemName = pNew->pInode->aSemName;
29252 int n;
29253 sqlite3_snprintf(MAX_PATHNAME, zSemName, "/%s.sem",
29254 pNew->pId->zCanonicalName);
29255 for( n=1; zSemName[n]; n++ )
29256 if( zSemName[n]=='/' ) zSemName[n] = '_';
29257 pNew->pInode->pSem = sem_open(zSemName, O_CREAT, 0666, 1);
29258 if( pNew->pInode->pSem == SEM_FAILED ){
29259 rc = SQLITE_NOMEM;
29260 pNew->pInode->aSemName[0] = '\0';
29263 unixLeaveMutex();
29265 #endif
29267 pNew->lastErrno = 0;
29268 #if OS_VXWORKS
29269 if( rc!=SQLITE_OK ){
29270 if( h>=0 ) robust_close(pNew, h, __LINE__);
29271 h = -1;
29272 osUnlink(zFilename);
29273 isDelete = 0;
29275 pNew->isDelete = isDelete;
29276 #endif
29277 if( rc!=SQLITE_OK ){
29278 if( h>=0 ) robust_close(pNew, h, __LINE__);
29279 }else{
29280 pNew->pMethod = pLockingStyle;
29281 OpenCounter(+1);
29283 return rc;
29287 ** Return the name of a directory in which to put temporary files.
29288 ** If no suitable temporary file directory can be found, return NULL.
29290 static const char *unixTempFileDir(void){
29291 static const char *azDirs[] = {
29294 "/var/tmp",
29295 "/usr/tmp",
29296 "/tmp",
29297 0 /* List terminator */
29299 unsigned int i;
29300 struct stat buf;
29301 const char *zDir = 0;
29303 azDirs[0] = sqlite3_temp_directory;
29304 if( !azDirs[1] ) azDirs[1] = getenv("TMPDIR");
29305 for(i=0; i<sizeof(azDirs)/sizeof(azDirs[0]); zDir=azDirs[i++]){
29306 if( zDir==0 ) continue;
29307 if( osStat(zDir, &buf) ) continue;
29308 if( !S_ISDIR(buf.st_mode) ) continue;
29309 if( osAccess(zDir, 07) ) continue;
29310 break;
29312 return zDir;
29316 ** Create a temporary file name in zBuf. zBuf must be allocated
29317 ** by the calling process and must be big enough to hold at least
29318 ** pVfs->mxPathname bytes.
29320 static int unixGetTempname(int nBuf, char *zBuf){
29321 static const unsigned char zChars[] =
29322 "abcdefghijklmnopqrstuvwxyz"
29323 "ABCDEFGHIJKLMNOPQRSTUVWXYZ"
29324 "0123456789";
29325 unsigned int i, j;
29326 const char *zDir;
29328 /* It's odd to simulate an io-error here, but really this is just
29329 ** using the io-error infrastructure to test that SQLite handles this
29330 ** function failing.
29332 SimulateIOError( return SQLITE_IOERR );
29334 zDir = unixTempFileDir();
29335 if( zDir==0 ) zDir = ".";
29337 /* Check that the output buffer is large enough for the temporary file
29338 ** name. If it is not, return SQLITE_ERROR.
29340 if( (strlen(zDir) + strlen(SQLITE_TEMP_FILE_PREFIX) + 17) >= (size_t)nBuf ){
29341 return SQLITE_ERROR;
29345 sqlite3_snprintf(nBuf-17, zBuf, "%s/"SQLITE_TEMP_FILE_PREFIX, zDir);
29346 j = (int)strlen(zBuf);
29347 sqlite3_randomness(15, &zBuf[j]);
29348 for(i=0; i<15; i++, j++){
29349 zBuf[j] = (char)zChars[ ((unsigned char)zBuf[j])%(sizeof(zChars)-1) ];
29351 zBuf[j] = 0;
29352 }while( osAccess(zBuf,0)==0 );
29353 return SQLITE_OK;
29356 #if SQLITE_ENABLE_LOCKING_STYLE && defined(__APPLE__)
29358 ** Routine to transform a unixFile into a proxy-locking unixFile.
29359 ** Implementation in the proxy-lock division, but used by unixOpen()
29360 ** if SQLITE_PREFER_PROXY_LOCKING is defined.
29362 static int proxyTransformUnixFile(unixFile*, const char*);
29363 #endif
29366 ** Search for an unused file descriptor that was opened on the database
29367 ** file (not a journal or master-journal file) identified by pathname
29368 ** zPath with SQLITE_OPEN_XXX flags matching those passed as the second
29369 ** argument to this function.
29371 ** Such a file descriptor may exist if a database connection was closed
29372 ** but the associated file descriptor could not be closed because some
29373 ** other file descriptor open on the same file is holding a file-lock.
29374 ** Refer to comments in the unixClose() function and the lengthy comment
29375 ** describing "Posix Advisory Locking" at the start of this file for
29376 ** further details. Also, ticket #4018.
29378 ** If a suitable file descriptor is found, then it is returned. If no
29379 ** such file descriptor is located, -1 is returned.
29381 static UnixUnusedFd *findReusableFd(const char *zPath, int flags){
29382 UnixUnusedFd *pUnused = 0;
29384 /* Do not search for an unused file descriptor on vxworks. Not because
29385 ** vxworks would not benefit from the change (it might, we're not sure),
29386 ** but because no way to test it is currently available. It is better
29387 ** not to risk breaking vxworks support for the sake of such an obscure
29388 ** feature. */
29389 #if !OS_VXWORKS
29390 struct stat sStat; /* Results of stat() call */
29392 /* A stat() call may fail for various reasons. If this happens, it is
29393 ** almost certain that an open() call on the same path will also fail.
29394 ** For this reason, if an error occurs in the stat() call here, it is
29395 ** ignored and -1 is returned. The caller will try to open a new file
29396 ** descriptor on the same path, fail, and return an error to SQLite.
29398 ** Even if a subsequent open() call does succeed, the consequences of
29399 ** not searching for a resusable file descriptor are not dire. */
29400 if( 0==osStat(zPath, &sStat) ){
29401 unixInodeInfo *pInode;
29403 unixEnterMutex();
29404 pInode = inodeList;
29405 while( pInode && (pInode->fileId.dev!=sStat.st_dev
29406 || pInode->fileId.ino!=sStat.st_ino) ){
29407 pInode = pInode->pNext;
29409 if( pInode ){
29410 UnixUnusedFd **pp;
29411 for(pp=&pInode->pUnused; *pp && (*pp)->flags!=flags; pp=&((*pp)->pNext));
29412 pUnused = *pp;
29413 if( pUnused ){
29414 *pp = pUnused->pNext;
29417 unixLeaveMutex();
29419 #endif /* if !OS_VXWORKS */
29420 return pUnused;
29424 ** This function is called by unixOpen() to determine the unix permissions
29425 ** to create new files with. If no error occurs, then SQLITE_OK is returned
29426 ** and a value suitable for passing as the third argument to open(2) is
29427 ** written to *pMode. If an IO error occurs, an SQLite error code is
29428 ** returned and the value of *pMode is not modified.
29430 ** If the file being opened is a temporary file, it is always created with
29431 ** the octal permissions 0600 (read/writable by owner only). If the file
29432 ** is a database or master journal file, it is created with the permissions
29433 ** mask SQLITE_DEFAULT_FILE_PERMISSIONS.
29435 ** Finally, if the file being opened is a WAL or regular journal file, then
29436 ** this function queries the file-system for the permissions on the
29437 ** corresponding database file and sets *pMode to this value. Whenever
29438 ** possible, WAL and journal files are created using the same permissions
29439 ** as the associated database file.
29441 ** If the SQLITE_ENABLE_8_3_NAMES option is enabled, then the
29442 ** original filename is unavailable. But 8_3_NAMES is only used for
29443 ** FAT filesystems and permissions do not matter there, so just use
29444 ** the default permissions.
29446 static int findCreateFileMode(
29447 const char *zPath, /* Path of file (possibly) being created */
29448 int flags, /* Flags passed as 4th argument to xOpen() */
29449 mode_t *pMode /* OUT: Permissions to open file with */
29451 int rc = SQLITE_OK; /* Return Code */
29452 *pMode = SQLITE_DEFAULT_FILE_PERMISSIONS;
29453 if( flags & (SQLITE_OPEN_WAL|SQLITE_OPEN_MAIN_JOURNAL) ){
29454 char zDb[MAX_PATHNAME+1]; /* Database file path */
29455 int nDb; /* Number of valid bytes in zDb */
29456 struct stat sStat; /* Output of stat() on database file */
29458 /* zPath is a path to a WAL or journal file. The following block derives
29459 ** the path to the associated database file from zPath. This block handles
29460 ** the following naming conventions:
29462 ** "<path to db>-journal"
29463 ** "<path to db>-wal"
29464 ** "<path to db>-journalNN"
29465 ** "<path to db>-walNN"
29467 ** where NN is a 4 digit decimal number. The NN naming schemes are
29468 ** used by the test_multiplex.c module.
29470 nDb = sqlite3Strlen30(zPath) - 1;
29471 while( nDb>0 && zPath[nDb]!='-' ) nDb--;
29472 if( nDb==0 ) return SQLITE_OK;
29473 memcpy(zDb, zPath, nDb);
29474 zDb[nDb] = '\0';
29476 if( 0==osStat(zDb, &sStat) ){
29477 *pMode = sStat.st_mode & 0777;
29478 }else{
29479 rc = SQLITE_IOERR_FSTAT;
29481 }else if( flags & SQLITE_OPEN_DELETEONCLOSE ){
29482 *pMode = 0600;
29484 return rc;
29488 ** Open the file zPath.
29490 ** Previously, the SQLite OS layer used three functions in place of this
29491 ** one:
29493 ** sqlite3OsOpenReadWrite();
29494 ** sqlite3OsOpenReadOnly();
29495 ** sqlite3OsOpenExclusive();
29497 ** These calls correspond to the following combinations of flags:
29499 ** ReadWrite() -> (READWRITE | CREATE)
29500 ** ReadOnly() -> (READONLY)
29501 ** OpenExclusive() -> (READWRITE | CREATE | EXCLUSIVE)
29503 ** The old OpenExclusive() accepted a boolean argument - "delFlag". If
29504 ** true, the file was configured to be automatically deleted when the
29505 ** file handle closed. To achieve the same effect using this new
29506 ** interface, add the DELETEONCLOSE flag to those specified above for
29507 ** OpenExclusive().
29509 static int unixOpen(
29510 sqlite3_vfs *pVfs, /* The VFS for which this is the xOpen method */
29511 const char *zPath, /* Pathname of file to be opened */
29512 sqlite3_file *pFile, /* The file descriptor to be filled in */
29513 int flags, /* Input flags to control the opening */
29514 int *pOutFlags /* Output flags returned to SQLite core */
29516 unixFile *p = (unixFile *)pFile;
29517 int fd = -1; /* File descriptor returned by open() */
29518 int openFlags = 0; /* Flags to pass to open() */
29519 int eType = flags&0xFFFFFF00; /* Type of file to open */
29520 int noLock; /* True to omit locking primitives */
29521 int rc = SQLITE_OK; /* Function Return Code */
29523 int isExclusive = (flags & SQLITE_OPEN_EXCLUSIVE);
29524 int isDelete = (flags & SQLITE_OPEN_DELETEONCLOSE);
29525 int isCreate = (flags & SQLITE_OPEN_CREATE);
29526 int isReadonly = (flags & SQLITE_OPEN_READONLY);
29527 int isReadWrite = (flags & SQLITE_OPEN_READWRITE);
29528 #if SQLITE_ENABLE_LOCKING_STYLE
29529 int isAutoProxy = (flags & SQLITE_OPEN_AUTOPROXY);
29530 #endif
29531 #if defined(__APPLE__) || SQLITE_ENABLE_LOCKING_STYLE
29532 struct statfs fsInfo;
29533 #endif
29535 /* If creating a master or main-file journal, this function will open
29536 ** a file-descriptor on the directory too. The first time unixSync()
29537 ** is called the directory file descriptor will be fsync()ed and close()d.
29539 int syncDir = (isCreate && (
29540 eType==SQLITE_OPEN_MASTER_JOURNAL
29541 || eType==SQLITE_OPEN_MAIN_JOURNAL
29542 || eType==SQLITE_OPEN_WAL
29545 /* If argument zPath is a NULL pointer, this function is required to open
29546 ** a temporary file. Use this buffer to store the file name in.
29548 char zTmpname[MAX_PATHNAME+1];
29549 const char *zName = zPath;
29551 /* Check the following statements are true:
29553 ** (a) Exactly one of the READWRITE and READONLY flags must be set, and
29554 ** (b) if CREATE is set, then READWRITE must also be set, and
29555 ** (c) if EXCLUSIVE is set, then CREATE must also be set.
29556 ** (d) if DELETEONCLOSE is set, then CREATE must also be set.
29558 assert((isReadonly==0 || isReadWrite==0) && (isReadWrite || isReadonly));
29559 assert(isCreate==0 || isReadWrite);
29560 assert(isExclusive==0 || isCreate);
29561 assert(isDelete==0 || isCreate);
29563 /* The main DB, main journal, WAL file and master journal are never
29564 ** automatically deleted. Nor are they ever temporary files. */
29565 assert( (!isDelete && zName) || eType!=SQLITE_OPEN_MAIN_DB );
29566 assert( (!isDelete && zName) || eType!=SQLITE_OPEN_MAIN_JOURNAL );
29567 assert( (!isDelete && zName) || eType!=SQLITE_OPEN_MASTER_JOURNAL );
29568 assert( (!isDelete && zName) || eType!=SQLITE_OPEN_WAL );
29570 /* Assert that the upper layer has set one of the "file-type" flags. */
29571 assert( eType==SQLITE_OPEN_MAIN_DB || eType==SQLITE_OPEN_TEMP_DB
29572 || eType==SQLITE_OPEN_MAIN_JOURNAL || eType==SQLITE_OPEN_TEMP_JOURNAL
29573 || eType==SQLITE_OPEN_SUBJOURNAL || eType==SQLITE_OPEN_MASTER_JOURNAL
29574 || eType==SQLITE_OPEN_TRANSIENT_DB || eType==SQLITE_OPEN_WAL
29577 memset(p, 0, sizeof(unixFile));
29579 if( eType==SQLITE_OPEN_MAIN_DB ){
29580 UnixUnusedFd *pUnused;
29581 pUnused = findReusableFd(zName, flags);
29582 if( pUnused ){
29583 fd = pUnused->fd;
29584 }else{
29585 pUnused = sqlite3_malloc(sizeof(*pUnused));
29586 if( !pUnused ){
29587 return SQLITE_NOMEM;
29590 p->pUnused = pUnused;
29591 }else if( !zName ){
29592 /* If zName is NULL, the upper layer is requesting a temp file. */
29593 assert(isDelete && !syncDir);
29594 rc = unixGetTempname(MAX_PATHNAME+1, zTmpname);
29595 if( rc!=SQLITE_OK ){
29596 return rc;
29598 zName = zTmpname;
29601 /* Determine the value of the flags parameter passed to POSIX function
29602 ** open(). These must be calculated even if open() is not called, as
29603 ** they may be stored as part of the file handle and used by the
29604 ** 'conch file' locking functions later on. */
29605 if( isReadonly ) openFlags |= O_RDONLY;
29606 if( isReadWrite ) openFlags |= O_RDWR;
29607 if( isCreate ) openFlags |= O_CREAT;
29608 if( isExclusive ) openFlags |= (O_EXCL|O_NOFOLLOW);
29609 openFlags |= (O_LARGEFILE|O_BINARY);
29611 if( fd<0 ){
29612 mode_t openMode; /* Permissions to create file with */
29613 rc = findCreateFileMode(zName, flags, &openMode);
29614 if( rc!=SQLITE_OK ){
29615 assert( !p->pUnused );
29616 assert( eType==SQLITE_OPEN_WAL || eType==SQLITE_OPEN_MAIN_JOURNAL );
29617 return rc;
29619 fd = robust_open(zName, openFlags, openMode);
29620 OSTRACE(("OPENX %-3d %s 0%o\n", fd, zName, openFlags));
29621 if( fd<0 && errno!=EISDIR && isReadWrite && !isExclusive ){
29622 /* Failed to open the file for read/write access. Try read-only. */
29623 flags &= ~(SQLITE_OPEN_READWRITE|SQLITE_OPEN_CREATE);
29624 openFlags &= ~(O_RDWR|O_CREAT);
29625 flags |= SQLITE_OPEN_READONLY;
29626 openFlags |= O_RDONLY;
29627 isReadonly = 1;
29628 fd = robust_open(zName, openFlags, openMode);
29630 if( fd<0 ){
29631 rc = unixLogError(SQLITE_CANTOPEN_BKPT, "open", zName);
29632 goto open_finished;
29635 assert( fd>=0 );
29636 if( pOutFlags ){
29637 *pOutFlags = flags;
29640 if( p->pUnused ){
29641 p->pUnused->fd = fd;
29642 p->pUnused->flags = flags;
29645 if( isDelete ){
29646 #if OS_VXWORKS
29647 zPath = zName;
29648 #else
29649 osUnlink(zName);
29650 #endif
29652 #if SQLITE_ENABLE_LOCKING_STYLE
29653 else{
29654 p->openFlags = openFlags;
29656 #endif
29658 #ifdef FD_CLOEXEC
29659 osFcntl(fd, F_SETFD, osFcntl(fd, F_GETFD, 0) | FD_CLOEXEC);
29660 #endif
29662 noLock = eType!=SQLITE_OPEN_MAIN_DB;
29665 #if defined(__APPLE__) || SQLITE_ENABLE_LOCKING_STYLE
29666 if( fstatfs(fd, &fsInfo) == -1 ){
29667 ((unixFile*)pFile)->lastErrno = errno;
29668 robust_close(p, fd, __LINE__);
29669 return SQLITE_IOERR_ACCESS;
29671 if (0 == strncmp("msdos", fsInfo.f_fstypename, 5)) {
29672 ((unixFile*)pFile)->fsFlags |= SQLITE_FSFLAGS_IS_MSDOS;
29674 #endif
29676 #if SQLITE_ENABLE_LOCKING_STYLE
29677 #if SQLITE_PREFER_PROXY_LOCKING
29678 isAutoProxy = 1;
29679 #endif
29680 if( isAutoProxy && (zPath!=NULL) && (!noLock) && pVfs->xOpen ){
29681 char *envforce = getenv("SQLITE_FORCE_PROXY_LOCKING");
29682 int useProxy = 0;
29684 /* SQLITE_FORCE_PROXY_LOCKING==1 means force always use proxy, 0 means
29685 ** never use proxy, NULL means use proxy for non-local files only. */
29686 if( envforce!=NULL ){
29687 useProxy = atoi(envforce)>0;
29688 }else{
29689 if( statfs(zPath, &fsInfo) == -1 ){
29690 /* In theory, the close(fd) call is sub-optimal. If the file opened
29691 ** with fd is a database file, and there are other connections open
29692 ** on that file that are currently holding advisory locks on it,
29693 ** then the call to close() will cancel those locks. In practice,
29694 ** we're assuming that statfs() doesn't fail very often. At least
29695 ** not while other file descriptors opened by the same process on
29696 ** the same file are working. */
29697 p->lastErrno = errno;
29698 robust_close(p, fd, __LINE__);
29699 rc = SQLITE_IOERR_ACCESS;
29700 goto open_finished;
29702 useProxy = !(fsInfo.f_flags&MNT_LOCAL);
29704 if( useProxy ){
29705 rc = fillInUnixFile(pVfs, fd, syncDir, pFile, zPath, noLock,
29706 isDelete, isReadonly);
29707 if( rc==SQLITE_OK ){
29708 rc = proxyTransformUnixFile((unixFile*)pFile, ":auto:");
29709 if( rc!=SQLITE_OK ){
29710 /* Use unixClose to clean up the resources added in fillInUnixFile
29711 ** and clear all the structure's references. Specifically,
29712 ** pFile->pMethods will be NULL so sqlite3OsClose will be a no-op
29714 unixClose(pFile);
29715 return rc;
29718 goto open_finished;
29721 #endif
29723 rc = fillInUnixFile(pVfs, fd, syncDir, pFile, zPath, noLock,
29724 isDelete, isReadonly);
29725 open_finished:
29726 if( rc!=SQLITE_OK ){
29727 sqlite3_free(p->pUnused);
29729 return rc;
29734 ** Delete the file at zPath. If the dirSync argument is true, fsync()
29735 ** the directory after deleting the file.
29737 static int unixDelete(
29738 sqlite3_vfs *NotUsed, /* VFS containing this as the xDelete method */
29739 const char *zPath, /* Name of file to be deleted */
29740 int dirSync /* If true, fsync() directory after deleting file */
29742 int rc = SQLITE_OK;
29743 UNUSED_PARAMETER(NotUsed);
29744 SimulateIOError(return SQLITE_IOERR_DELETE);
29745 if( osUnlink(zPath)==(-1) && errno!=ENOENT ){
29746 return unixLogError(SQLITE_IOERR_DELETE, "unlink", zPath);
29748 #ifndef SQLITE_DISABLE_DIRSYNC
29749 if( dirSync ){
29750 int fd;
29751 rc = osOpenDirectory(zPath, &fd);
29752 if( rc==SQLITE_OK ){
29753 #if OS_VXWORKS
29754 if( fsync(fd)==-1 )
29755 #else
29756 if( fsync(fd) )
29757 #endif
29759 rc = unixLogError(SQLITE_IOERR_DIR_FSYNC, "fsync", zPath);
29761 robust_close(0, fd, __LINE__);
29762 }else if( rc==SQLITE_CANTOPEN ){
29763 rc = SQLITE_OK;
29766 #endif
29767 return rc;
29771 ** Test the existance of or access permissions of file zPath. The
29772 ** test performed depends on the value of flags:
29774 ** SQLITE_ACCESS_EXISTS: Return 1 if the file exists
29775 ** SQLITE_ACCESS_READWRITE: Return 1 if the file is read and writable.
29776 ** SQLITE_ACCESS_READONLY: Return 1 if the file is readable.
29778 ** Otherwise return 0.
29780 static int unixAccess(
29781 sqlite3_vfs *NotUsed, /* The VFS containing this xAccess method */
29782 const char *zPath, /* Path of the file to examine */
29783 int flags, /* What do we want to learn about the zPath file? */
29784 int *pResOut /* Write result boolean here */
29786 int amode = 0;
29787 UNUSED_PARAMETER(NotUsed);
29788 SimulateIOError( return SQLITE_IOERR_ACCESS; );
29789 switch( flags ){
29790 case SQLITE_ACCESS_EXISTS:
29791 amode = F_OK;
29792 break;
29793 case SQLITE_ACCESS_READWRITE:
29794 amode = W_OK|R_OK;
29795 break;
29796 case SQLITE_ACCESS_READ:
29797 amode = R_OK;
29798 break;
29800 default:
29801 assert(!"Invalid flags argument");
29803 *pResOut = (osAccess(zPath, amode)==0);
29804 if( flags==SQLITE_ACCESS_EXISTS && *pResOut ){
29805 struct stat buf;
29806 if( 0==osStat(zPath, &buf) && buf.st_size==0 ){
29807 *pResOut = 0;
29810 return SQLITE_OK;
29815 ** Turn a relative pathname into a full pathname. The relative path
29816 ** is stored as a nul-terminated string in the buffer pointed to by
29817 ** zPath.
29819 ** zOut points to a buffer of at least sqlite3_vfs.mxPathname bytes
29820 ** (in this case, MAX_PATHNAME bytes). The full-path is written to
29821 ** this buffer before returning.
29823 static int unixFullPathname(
29824 sqlite3_vfs *pVfs, /* Pointer to vfs object */
29825 const char *zPath, /* Possibly relative input path */
29826 int nOut, /* Size of output buffer in bytes */
29827 char *zOut /* Output buffer */
29830 /* It's odd to simulate an io-error here, but really this is just
29831 ** using the io-error infrastructure to test that SQLite handles this
29832 ** function failing. This function could fail if, for example, the
29833 ** current working directory has been unlinked.
29835 SimulateIOError( return SQLITE_ERROR );
29837 assert( pVfs->mxPathname==MAX_PATHNAME );
29838 UNUSED_PARAMETER(pVfs);
29840 zOut[nOut-1] = '\0';
29841 if( zPath[0]=='/' ){
29842 sqlite3_snprintf(nOut, zOut, "%s", zPath);
29843 }else{
29844 int nCwd;
29845 if( osGetcwd(zOut, nOut-1)==0 ){
29846 return unixLogError(SQLITE_CANTOPEN_BKPT, "getcwd", zPath);
29848 nCwd = (int)strlen(zOut);
29849 sqlite3_snprintf(nOut-nCwd, &zOut[nCwd], "/%s", zPath);
29851 return SQLITE_OK;
29855 #ifndef SQLITE_OMIT_LOAD_EXTENSION
29857 ** Interfaces for opening a shared library, finding entry points
29858 ** within the shared library, and closing the shared library.
29860 #include <dlfcn.h>
29861 static void *unixDlOpen(sqlite3_vfs *NotUsed, const char *zFilename){
29862 UNUSED_PARAMETER(NotUsed);
29863 return dlopen(zFilename, RTLD_NOW | RTLD_GLOBAL);
29867 ** SQLite calls this function immediately after a call to unixDlSym() or
29868 ** unixDlOpen() fails (returns a null pointer). If a more detailed error
29869 ** message is available, it is written to zBufOut. If no error message
29870 ** is available, zBufOut is left unmodified and SQLite uses a default
29871 ** error message.
29873 static void unixDlError(sqlite3_vfs *NotUsed, int nBuf, char *zBufOut){
29874 const char *zErr;
29875 UNUSED_PARAMETER(NotUsed);
29876 unixEnterMutex();
29877 zErr = dlerror();
29878 if( zErr ){
29879 sqlite3_snprintf(nBuf, zBufOut, "%s", zErr);
29881 unixLeaveMutex();
29883 static void (*unixDlSym(sqlite3_vfs *NotUsed, void *p, const char*zSym))(void){
29885 ** GCC with -pedantic-errors says that C90 does not allow a void* to be
29886 ** cast into a pointer to a function. And yet the library dlsym() routine
29887 ** returns a void* which is really a pointer to a function. So how do we
29888 ** use dlsym() with -pedantic-errors?
29890 ** Variable x below is defined to be a pointer to a function taking
29891 ** parameters void* and const char* and returning a pointer to a function.
29892 ** We initialize x by assigning it a pointer to the dlsym() function.
29893 ** (That assignment requires a cast.) Then we call the function that
29894 ** x points to.
29896 ** This work-around is unlikely to work correctly on any system where
29897 ** you really cannot cast a function pointer into void*. But then, on the
29898 ** other hand, dlsym() will not work on such a system either, so we have
29899 ** not really lost anything.
29901 void (*(*x)(void*,const char*))(void);
29902 UNUSED_PARAMETER(NotUsed);
29903 x = (void(*(*)(void*,const char*))(void))dlsym;
29904 return (*x)(p, zSym);
29906 static void unixDlClose(sqlite3_vfs *NotUsed, void *pHandle){
29907 UNUSED_PARAMETER(NotUsed);
29908 dlclose(pHandle);
29910 #else /* if SQLITE_OMIT_LOAD_EXTENSION is defined: */
29911 #define unixDlOpen 0
29912 #define unixDlError 0
29913 #define unixDlSym 0
29914 #define unixDlClose 0
29915 #endif
29918 ** Write nBuf bytes of random data to the supplied buffer zBuf.
29920 static int unixRandomness(sqlite3_vfs *NotUsed, int nBuf, char *zBuf){
29921 UNUSED_PARAMETER(NotUsed);
29922 assert((size_t)nBuf>=(sizeof(time_t)+sizeof(int)));
29924 /* We have to initialize zBuf to prevent valgrind from reporting
29925 ** errors. The reports issued by valgrind are incorrect - we would
29926 ** prefer that the randomness be increased by making use of the
29927 ** uninitialized space in zBuf - but valgrind errors tend to worry
29928 ** some users. Rather than argue, it seems easier just to initialize
29929 ** the whole array and silence valgrind, even if that means less randomness
29930 ** in the random seed.
29932 ** When testing, initializing zBuf[] to zero is all we do. That means
29933 ** that we always use the same random number sequence. This makes the
29934 ** tests repeatable.
29936 memset(zBuf, 0, nBuf);
29937 #if !defined(SQLITE_TEST)
29939 int pid, fd;
29940 fd = robust_open("/dev/urandom", O_RDONLY, 0);
29941 if( fd<0 ){
29942 time_t t;
29943 time(&t);
29944 memcpy(zBuf, &t, sizeof(t));
29945 pid = getpid();
29946 memcpy(&zBuf[sizeof(t)], &pid, sizeof(pid));
29947 assert( sizeof(t)+sizeof(pid)<=(size_t)nBuf );
29948 nBuf = sizeof(t) + sizeof(pid);
29949 }else{
29950 do{ nBuf = osRead(fd, zBuf, nBuf); }while( nBuf<0 && errno==EINTR );
29951 robust_close(0, fd, __LINE__);
29954 #endif
29955 return nBuf;
29960 ** Sleep for a little while. Return the amount of time slept.
29961 ** The argument is the number of microseconds we want to sleep.
29962 ** The return value is the number of microseconds of sleep actually
29963 ** requested from the underlying operating system, a number which
29964 ** might be greater than or equal to the argument, but not less
29965 ** than the argument.
29967 static int unixSleep(sqlite3_vfs *NotUsed, int microseconds){
29968 #if OS_VXWORKS
29969 struct timespec sp;
29971 sp.tv_sec = microseconds / 1000000;
29972 sp.tv_nsec = (microseconds % 1000000) * 1000;
29973 nanosleep(&sp, NULL);
29974 UNUSED_PARAMETER(NotUsed);
29975 return microseconds;
29976 #elif defined(HAVE_USLEEP) && HAVE_USLEEP
29977 usleep(microseconds);
29978 UNUSED_PARAMETER(NotUsed);
29979 return microseconds;
29980 #else
29981 int seconds = (microseconds+999999)/1000000;
29982 sleep(seconds);
29983 UNUSED_PARAMETER(NotUsed);
29984 return seconds*1000000;
29985 #endif
29989 ** The following variable, if set to a non-zero value, is interpreted as
29990 ** the number of seconds since 1970 and is used to set the result of
29991 ** sqlite3OsCurrentTime() during testing.
29993 #ifdef SQLITE_TEST
29994 SQLITE_API int sqlite3_current_time = 0; /* Fake system time in seconds since 1970. */
29995 #endif
29998 ** Find the current time (in Universal Coordinated Time). Write into *piNow
29999 ** the current time and date as a Julian Day number times 86_400_000. In
30000 ** other words, write into *piNow the number of milliseconds since the Julian
30001 ** epoch of noon in Greenwich on November 24, 4714 B.C according to the
30002 ** proleptic Gregorian calendar.
30004 ** On success, return 0. Return 1 if the time and date cannot be found.
30006 static int unixCurrentTimeInt64(sqlite3_vfs *NotUsed, sqlite3_int64 *piNow){
30007 static const sqlite3_int64 unixEpoch = 24405875*(sqlite3_int64)8640000;
30008 #if defined(NO_GETTOD)
30009 time_t t;
30010 time(&t);
30011 *piNow = ((sqlite3_int64)t)*1000 + unixEpoch;
30012 #elif OS_VXWORKS
30013 struct timespec sNow;
30014 clock_gettime(CLOCK_REALTIME, &sNow);
30015 *piNow = unixEpoch + 1000*(sqlite3_int64)sNow.tv_sec + sNow.tv_nsec/1000000;
30016 #else
30017 struct timeval sNow;
30018 gettimeofday(&sNow, 0);
30019 *piNow = unixEpoch + 1000*(sqlite3_int64)sNow.tv_sec + sNow.tv_usec/1000;
30020 #endif
30022 #ifdef SQLITE_TEST
30023 if( sqlite3_current_time ){
30024 *piNow = 1000*(sqlite3_int64)sqlite3_current_time + unixEpoch;
30026 #endif
30027 UNUSED_PARAMETER(NotUsed);
30028 return 0;
30032 ** Find the current time (in Universal Coordinated Time). Write the
30033 ** current time and date as a Julian Day number into *prNow and
30034 ** return 0. Return 1 if the time and date cannot be found.
30036 static int unixCurrentTime(sqlite3_vfs *NotUsed, double *prNow){
30037 sqlite3_int64 i;
30038 UNUSED_PARAMETER(NotUsed);
30039 unixCurrentTimeInt64(0, &i);
30040 *prNow = i/86400000.0;
30041 return 0;
30045 ** We added the xGetLastError() method with the intention of providing
30046 ** better low-level error messages when operating-system problems come up
30047 ** during SQLite operation. But so far, none of that has been implemented
30048 ** in the core. So this routine is never called. For now, it is merely
30049 ** a place-holder.
30051 static int unixGetLastError(sqlite3_vfs *NotUsed, int NotUsed2, char *NotUsed3){
30052 UNUSED_PARAMETER(NotUsed);
30053 UNUSED_PARAMETER(NotUsed2);
30054 UNUSED_PARAMETER(NotUsed3);
30055 return 0;
30060 ************************ End of sqlite3_vfs methods ***************************
30061 ******************************************************************************/
30063 /******************************************************************************
30064 ************************** Begin Proxy Locking ********************************
30066 ** Proxy locking is a "uber-locking-method" in this sense: It uses the
30067 ** other locking methods on secondary lock files. Proxy locking is a
30068 ** meta-layer over top of the primitive locking implemented above. For
30069 ** this reason, the division that implements of proxy locking is deferred
30070 ** until late in the file (here) after all of the other I/O methods have
30071 ** been defined - so that the primitive locking methods are available
30072 ** as services to help with the implementation of proxy locking.
30074 ****
30076 ** The default locking schemes in SQLite use byte-range locks on the
30077 ** database file to coordinate safe, concurrent access by multiple readers
30078 ** and writers [http://sqlite.org/lockingv3.html]. The five file locking
30079 ** states (UNLOCKED, PENDING, SHARED, RESERVED, EXCLUSIVE) are implemented
30080 ** as POSIX read & write locks over fixed set of locations (via fsctl),
30081 ** on AFP and SMB only exclusive byte-range locks are available via fsctl
30082 ** with _IOWR('z', 23, struct ByteRangeLockPB2) to track the same 5 states.
30083 ** To simulate a F_RDLCK on the shared range, on AFP a randomly selected
30084 ** address in the shared range is taken for a SHARED lock, the entire
30085 ** shared range is taken for an EXCLUSIVE lock):
30087 ** PENDING_BYTE 0x40000000
30088 ** RESERVED_BYTE 0x40000001
30089 ** SHARED_RANGE 0x40000002 -> 0x40000200
30091 ** This works well on the local file system, but shows a nearly 100x
30092 ** slowdown in read performance on AFP because the AFP client disables
30093 ** the read cache when byte-range locks are present. Enabling the read
30094 ** cache exposes a cache coherency problem that is present on all OS X
30095 ** supported network file systems. NFS and AFP both observe the
30096 ** close-to-open semantics for ensuring cache coherency
30097 ** [http://nfs.sourceforge.net/#faq_a8], which does not effectively
30098 ** address the requirements for concurrent database access by multiple
30099 ** readers and writers
30100 ** [http://www.nabble.com/SQLite-on-NFS-cache-coherency-td15655701.html].
30102 ** To address the performance and cache coherency issues, proxy file locking
30103 ** changes the way database access is controlled by limiting access to a
30104 ** single host at a time and moving file locks off of the database file
30105 ** and onto a proxy file on the local file system.
30108 ** Using proxy locks
30109 ** -----------------
30111 ** C APIs
30113 ** sqlite3_file_control(db, dbname, SQLITE_SET_LOCKPROXYFILE,
30114 ** <proxy_path> | ":auto:");
30115 ** sqlite3_file_control(db, dbname, SQLITE_GET_LOCKPROXYFILE, &<proxy_path>);
30118 ** SQL pragmas
30120 ** PRAGMA [database.]lock_proxy_file=<proxy_path> | :auto:
30121 ** PRAGMA [database.]lock_proxy_file
30123 ** Specifying ":auto:" means that if there is a conch file with a matching
30124 ** host ID in it, the proxy path in the conch file will be used, otherwise
30125 ** a proxy path based on the user's temp dir
30126 ** (via confstr(_CS_DARWIN_USER_TEMP_DIR,...)) will be used and the
30127 ** actual proxy file name is generated from the name and path of the
30128 ** database file. For example:
30130 ** For database path "/Users/me/foo.db"
30131 ** The lock path will be "<tmpdir>/sqliteplocks/_Users_me_foo.db:auto:")
30133 ** Once a lock proxy is configured for a database connection, it can not
30134 ** be removed, however it may be switched to a different proxy path via
30135 ** the above APIs (assuming the conch file is not being held by another
30136 ** connection or process).
30139 ** How proxy locking works
30140 ** -----------------------
30142 ** Proxy file locking relies primarily on two new supporting files:
30144 ** * conch file to limit access to the database file to a single host
30145 ** at a time
30147 ** * proxy file to act as a proxy for the advisory locks normally
30148 ** taken on the database
30150 ** The conch file - to use a proxy file, sqlite must first "hold the conch"
30151 ** by taking an sqlite-style shared lock on the conch file, reading the
30152 ** contents and comparing the host's unique host ID (see below) and lock
30153 ** proxy path against the values stored in the conch. The conch file is
30154 ** stored in the same directory as the database file and the file name
30155 ** is patterned after the database file name as ".<databasename>-conch".
30156 ** If the conch file does not exist, or it's contents do not match the
30157 ** host ID and/or proxy path, then the lock is escalated to an exclusive
30158 ** lock and the conch file contents is updated with the host ID and proxy
30159 ** path and the lock is downgraded to a shared lock again. If the conch
30160 ** is held by another process (with a shared lock), the exclusive lock
30161 ** will fail and SQLITE_BUSY is returned.
30163 ** The proxy file - a single-byte file used for all advisory file locks
30164 ** normally taken on the database file. This allows for safe sharing
30165 ** of the database file for multiple readers and writers on the same
30166 ** host (the conch ensures that they all use the same local lock file).
30168 ** Requesting the lock proxy does not immediately take the conch, it is
30169 ** only taken when the first request to lock database file is made.
30170 ** This matches the semantics of the traditional locking behavior, where
30171 ** opening a connection to a database file does not take a lock on it.
30172 ** The shared lock and an open file descriptor are maintained until
30173 ** the connection to the database is closed.
30175 ** The proxy file and the lock file are never deleted so they only need
30176 ** to be created the first time they are used.
30178 ** Configuration options
30179 ** ---------------------
30181 ** SQLITE_PREFER_PROXY_LOCKING
30183 ** Database files accessed on non-local file systems are
30184 ** automatically configured for proxy locking, lock files are
30185 ** named automatically using the same logic as
30186 ** PRAGMA lock_proxy_file=":auto:"
30188 ** SQLITE_PROXY_DEBUG
30190 ** Enables the logging of error messages during host id file
30191 ** retrieval and creation
30193 ** LOCKPROXYDIR
30195 ** Overrides the default directory used for lock proxy files that
30196 ** are named automatically via the ":auto:" setting
30198 ** SQLITE_DEFAULT_PROXYDIR_PERMISSIONS
30200 ** Permissions to use when creating a directory for storing the
30201 ** lock proxy files, only used when LOCKPROXYDIR is not set.
30204 ** As mentioned above, when compiled with SQLITE_PREFER_PROXY_LOCKING,
30205 ** setting the environment variable SQLITE_FORCE_PROXY_LOCKING to 1 will
30206 ** force proxy locking to be used for every database file opened, and 0
30207 ** will force automatic proxy locking to be disabled for all database
30208 ** files (explicity calling the SQLITE_SET_LOCKPROXYFILE pragma or
30209 ** sqlite_file_control API is not affected by SQLITE_FORCE_PROXY_LOCKING).
30213 ** Proxy locking is only available on MacOSX
30215 #if defined(__APPLE__) && SQLITE_ENABLE_LOCKING_STYLE
30218 ** The proxyLockingContext has the path and file structures for the remote
30219 ** and local proxy files in it
30221 typedef struct proxyLockingContext proxyLockingContext;
30222 struct proxyLockingContext {
30223 unixFile *conchFile; /* Open conch file */
30224 char *conchFilePath; /* Name of the conch file */
30225 unixFile *lockProxy; /* Open proxy lock file */
30226 char *lockProxyPath; /* Name of the proxy lock file */
30227 char *dbPath; /* Name of the open file */
30228 int conchHeld; /* 1 if the conch is held, -1 if lockless */
30229 void *oldLockingContext; /* Original lockingcontext to restore on close */
30230 sqlite3_io_methods const *pOldMethod; /* Original I/O methods for close */
30234 ** The proxy lock file path for the database at dbPath is written into lPath,
30235 ** which must point to valid, writable memory large enough for a maxLen length
30236 ** file path.
30238 static int proxyGetLockPath(const char *dbPath, char *lPath, size_t maxLen){
30239 int len;
30240 int dbLen;
30241 int i;
30243 #ifdef LOCKPROXYDIR
30244 len = strlcpy(lPath, LOCKPROXYDIR, maxLen);
30245 #else
30246 # ifdef _CS_DARWIN_USER_TEMP_DIR
30248 if( !confstr(_CS_DARWIN_USER_TEMP_DIR, lPath, maxLen) ){
30249 OSTRACE(("GETLOCKPATH failed %s errno=%d pid=%d\n",
30250 lPath, errno, getpid()));
30251 return SQLITE_IOERR_LOCK;
30253 len = strlcat(lPath, "sqliteplocks", maxLen);
30255 # else
30256 len = strlcpy(lPath, "/tmp/", maxLen);
30257 # endif
30258 #endif
30260 if( lPath[len-1]!='/' ){
30261 len = strlcat(lPath, "/", maxLen);
30264 /* transform the db path to a unique cache name */
30265 dbLen = (int)strlen(dbPath);
30266 for( i=0; i<dbLen && (i+len+7)<(int)maxLen; i++){
30267 char c = dbPath[i];
30268 lPath[i+len] = (c=='/')?'_':c;
30270 lPath[i+len]='\0';
30271 strlcat(lPath, ":auto:", maxLen);
30272 OSTRACE(("GETLOCKPATH proxy lock path=%s pid=%d\n", lPath, getpid()));
30273 return SQLITE_OK;
30277 ** Creates the lock file and any missing directories in lockPath
30279 static int proxyCreateLockPath(const char *lockPath){
30280 int i, len;
30281 char buf[MAXPATHLEN];
30282 int start = 0;
30284 assert(lockPath!=NULL);
30285 /* try to create all the intermediate directories */
30286 len = (int)strlen(lockPath);
30287 buf[0] = lockPath[0];
30288 for( i=1; i<len; i++ ){
30289 if( lockPath[i] == '/' && (i - start > 0) ){
30290 /* only mkdir if leaf dir != "." or "/" or ".." */
30291 if( i-start>2 || (i-start==1 && buf[start] != '.' && buf[start] != '/')
30292 || (i-start==2 && buf[start] != '.' && buf[start+1] != '.') ){
30293 buf[i]='\0';
30294 if( mkdir(buf, SQLITE_DEFAULT_PROXYDIR_PERMISSIONS) ){
30295 int err=errno;
30296 if( err!=EEXIST ) {
30297 OSTRACE(("CREATELOCKPATH FAILED creating %s, "
30298 "'%s' proxy lock path=%s pid=%d\n",
30299 buf, strerror(err), lockPath, getpid()));
30300 return err;
30304 start=i+1;
30306 buf[i] = lockPath[i];
30308 OSTRACE(("CREATELOCKPATH proxy lock path=%s pid=%d\n", lockPath, getpid()));
30309 return 0;
30313 ** Create a new VFS file descriptor (stored in memory obtained from
30314 ** sqlite3_malloc) and open the file named "path" in the file descriptor.
30316 ** The caller is responsible not only for closing the file descriptor
30317 ** but also for freeing the memory associated with the file descriptor.
30319 static int proxyCreateUnixFile(
30320 const char *path, /* path for the new unixFile */
30321 unixFile **ppFile, /* unixFile created and returned by ref */
30322 int islockfile /* if non zero missing dirs will be created */
30324 int fd = -1;
30325 unixFile *pNew;
30326 int rc = SQLITE_OK;
30327 int openFlags = O_RDWR | O_CREAT;
30328 sqlite3_vfs dummyVfs;
30329 int terrno = 0;
30330 UnixUnusedFd *pUnused = NULL;
30332 /* 1. first try to open/create the file
30333 ** 2. if that fails, and this is a lock file (not-conch), try creating
30334 ** the parent directories and then try again.
30335 ** 3. if that fails, try to open the file read-only
30336 ** otherwise return BUSY (if lock file) or CANTOPEN for the conch file
30338 pUnused = findReusableFd(path, openFlags);
30339 if( pUnused ){
30340 fd = pUnused->fd;
30341 }else{
30342 pUnused = sqlite3_malloc(sizeof(*pUnused));
30343 if( !pUnused ){
30344 return SQLITE_NOMEM;
30347 if( fd<0 ){
30348 fd = robust_open(path, openFlags, SQLITE_DEFAULT_FILE_PERMISSIONS);
30349 terrno = errno;
30350 if( fd<0 && errno==ENOENT && islockfile ){
30351 if( proxyCreateLockPath(path) == SQLITE_OK ){
30352 fd = robust_open(path, openFlags, SQLITE_DEFAULT_FILE_PERMISSIONS);
30356 if( fd<0 ){
30357 openFlags = O_RDONLY;
30358 fd = robust_open(path, openFlags, SQLITE_DEFAULT_FILE_PERMISSIONS);
30359 terrno = errno;
30361 if( fd<0 ){
30362 if( islockfile ){
30363 return SQLITE_BUSY;
30365 switch (terrno) {
30366 case EACCES:
30367 return SQLITE_PERM;
30368 case EIO:
30369 return SQLITE_IOERR_LOCK; /* even though it is the conch */
30370 default:
30371 return SQLITE_CANTOPEN_BKPT;
30375 pNew = (unixFile *)sqlite3_malloc(sizeof(*pNew));
30376 if( pNew==NULL ){
30377 rc = SQLITE_NOMEM;
30378 goto end_create_proxy;
30380 memset(pNew, 0, sizeof(unixFile));
30381 pNew->openFlags = openFlags;
30382 memset(&dummyVfs, 0, sizeof(dummyVfs));
30383 dummyVfs.pAppData = (void*)&autolockIoFinder;
30384 dummyVfs.zName = "dummy";
30385 pUnused->fd = fd;
30386 pUnused->flags = openFlags;
30387 pNew->pUnused = pUnused;
30389 rc = fillInUnixFile(&dummyVfs, fd, 0, (sqlite3_file*)pNew, path, 0, 0, 0);
30390 if( rc==SQLITE_OK ){
30391 *ppFile = pNew;
30392 return SQLITE_OK;
30394 end_create_proxy:
30395 robust_close(pNew, fd, __LINE__);
30396 sqlite3_free(pNew);
30397 sqlite3_free(pUnused);
30398 return rc;
30401 #ifdef SQLITE_TEST
30402 /* simulate multiple hosts by creating unique hostid file paths */
30403 SQLITE_API int sqlite3_hostid_num = 0;
30404 #endif
30406 #define PROXY_HOSTIDLEN 16 /* conch file host id length */
30408 /* Not always defined in the headers as it ought to be */
30409 extern int gethostuuid(uuid_t id, const struct timespec *wait);
30411 /* get the host ID via gethostuuid(), pHostID must point to PROXY_HOSTIDLEN
30412 ** bytes of writable memory.
30414 static int proxyGetHostID(unsigned char *pHostID, int *pError){
30415 assert(PROXY_HOSTIDLEN == sizeof(uuid_t));
30416 memset(pHostID, 0, PROXY_HOSTIDLEN);
30417 #if defined(__MAX_OS_X_VERSION_MIN_REQUIRED)\
30418 && __MAC_OS_X_VERSION_MIN_REQUIRED<1050
30420 static const struct timespec timeout = {1, 0}; /* 1 sec timeout */
30421 if( gethostuuid(pHostID, &timeout) ){
30422 int err = errno;
30423 if( pError ){
30424 *pError = err;
30426 return SQLITE_IOERR;
30429 #else
30430 UNUSED_PARAMETER(pError);
30431 #endif
30432 #ifdef SQLITE_TEST
30433 /* simulate multiple hosts by creating unique hostid file paths */
30434 if( sqlite3_hostid_num != 0){
30435 pHostID[0] = (char)(pHostID[0] + (char)(sqlite3_hostid_num & 0xFF));
30437 #endif
30439 return SQLITE_OK;
30442 /* The conch file contains the header, host id and lock file path
30444 #define PROXY_CONCHVERSION 2 /* 1-byte header, 16-byte host id, path */
30445 #define PROXY_HEADERLEN 1 /* conch file header length */
30446 #define PROXY_PATHINDEX (PROXY_HEADERLEN+PROXY_HOSTIDLEN)
30447 #define PROXY_MAXCONCHLEN (PROXY_HEADERLEN+PROXY_HOSTIDLEN+MAXPATHLEN)
30450 ** Takes an open conch file, copies the contents to a new path and then moves
30451 ** it back. The newly created file's file descriptor is assigned to the
30452 ** conch file structure and finally the original conch file descriptor is
30453 ** closed. Returns zero if successful.
30455 static int proxyBreakConchLock(unixFile *pFile, uuid_t myHostID){
30456 proxyLockingContext *pCtx = (proxyLockingContext *)pFile->lockingContext;
30457 unixFile *conchFile = pCtx->conchFile;
30458 char tPath[MAXPATHLEN];
30459 char buf[PROXY_MAXCONCHLEN];
30460 char *cPath = pCtx->conchFilePath;
30461 size_t readLen = 0;
30462 size_t pathLen = 0;
30463 char errmsg[64] = "";
30464 int fd = -1;
30465 int rc = -1;
30466 UNUSED_PARAMETER(myHostID);
30468 /* create a new path by replace the trailing '-conch' with '-break' */
30469 pathLen = strlcpy(tPath, cPath, MAXPATHLEN);
30470 if( pathLen>MAXPATHLEN || pathLen<6 ||
30471 (strlcpy(&tPath[pathLen-5], "break", 6) != 5) ){
30472 sqlite3_snprintf(sizeof(errmsg),errmsg,"path error (len %d)",(int)pathLen);
30473 goto end_breaklock;
30475 /* read the conch content */
30476 readLen = osPread(conchFile->h, buf, PROXY_MAXCONCHLEN, 0);
30477 if( readLen<PROXY_PATHINDEX ){
30478 sqlite3_snprintf(sizeof(errmsg),errmsg,"read error (len %d)",(int)readLen);
30479 goto end_breaklock;
30481 /* write it out to the temporary break file */
30482 fd = robust_open(tPath, (O_RDWR|O_CREAT|O_EXCL),
30483 SQLITE_DEFAULT_FILE_PERMISSIONS);
30484 if( fd<0 ){
30485 sqlite3_snprintf(sizeof(errmsg), errmsg, "create failed (%d)", errno);
30486 goto end_breaklock;
30488 if( osPwrite(fd, buf, readLen, 0) != (ssize_t)readLen ){
30489 sqlite3_snprintf(sizeof(errmsg), errmsg, "write failed (%d)", errno);
30490 goto end_breaklock;
30492 if( rename(tPath, cPath) ){
30493 sqlite3_snprintf(sizeof(errmsg), errmsg, "rename failed (%d)", errno);
30494 goto end_breaklock;
30496 rc = 0;
30497 fprintf(stderr, "broke stale lock on %s\n", cPath);
30498 robust_close(pFile, conchFile->h, __LINE__);
30499 conchFile->h = fd;
30500 conchFile->openFlags = O_RDWR | O_CREAT;
30502 end_breaklock:
30503 if( rc ){
30504 if( fd>=0 ){
30505 osUnlink(tPath);
30506 robust_close(pFile, fd, __LINE__);
30508 fprintf(stderr, "failed to break stale lock on %s, %s\n", cPath, errmsg);
30510 return rc;
30513 /* Take the requested lock on the conch file and break a stale lock if the
30514 ** host id matches.
30516 static int proxyConchLock(unixFile *pFile, uuid_t myHostID, int lockType){
30517 proxyLockingContext *pCtx = (proxyLockingContext *)pFile->lockingContext;
30518 unixFile *conchFile = pCtx->conchFile;
30519 int rc = SQLITE_OK;
30520 int nTries = 0;
30521 struct timespec conchModTime;
30523 memset(&conchModTime, 0, sizeof(conchModTime));
30524 do {
30525 rc = conchFile->pMethod->xLock((sqlite3_file*)conchFile, lockType);
30526 nTries ++;
30527 if( rc==SQLITE_BUSY ){
30528 /* If the lock failed (busy):
30529 * 1st try: get the mod time of the conch, wait 0.5s and try again.
30530 * 2nd try: fail if the mod time changed or host id is different, wait
30531 * 10 sec and try again
30532 * 3rd try: break the lock unless the mod time has changed.
30534 struct stat buf;
30535 if( osFstat(conchFile->h, &buf) ){
30536 pFile->lastErrno = errno;
30537 return SQLITE_IOERR_LOCK;
30540 if( nTries==1 ){
30541 conchModTime = buf.st_mtimespec;
30542 usleep(500000); /* wait 0.5 sec and try the lock again*/
30543 continue;
30546 assert( nTries>1 );
30547 if( conchModTime.tv_sec != buf.st_mtimespec.tv_sec ||
30548 conchModTime.tv_nsec != buf.st_mtimespec.tv_nsec ){
30549 return SQLITE_BUSY;
30552 if( nTries==2 ){
30553 char tBuf[PROXY_MAXCONCHLEN];
30554 int len = osPread(conchFile->h, tBuf, PROXY_MAXCONCHLEN, 0);
30555 if( len<0 ){
30556 pFile->lastErrno = errno;
30557 return SQLITE_IOERR_LOCK;
30559 if( len>PROXY_PATHINDEX && tBuf[0]==(char)PROXY_CONCHVERSION){
30560 /* don't break the lock if the host id doesn't match */
30561 if( 0!=memcmp(&tBuf[PROXY_HEADERLEN], myHostID, PROXY_HOSTIDLEN) ){
30562 return SQLITE_BUSY;
30564 }else{
30565 /* don't break the lock on short read or a version mismatch */
30566 return SQLITE_BUSY;
30568 usleep(10000000); /* wait 10 sec and try the lock again */
30569 continue;
30572 assert( nTries==3 );
30573 if( 0==proxyBreakConchLock(pFile, myHostID) ){
30574 rc = SQLITE_OK;
30575 if( lockType==EXCLUSIVE_LOCK ){
30576 rc = conchFile->pMethod->xLock((sqlite3_file*)conchFile, SHARED_LOCK);
30578 if( !rc ){
30579 rc = conchFile->pMethod->xLock((sqlite3_file*)conchFile, lockType);
30583 } while( rc==SQLITE_BUSY && nTries<3 );
30585 return rc;
30588 /* Takes the conch by taking a shared lock and read the contents conch, if
30589 ** lockPath is non-NULL, the host ID and lock file path must match. A NULL
30590 ** lockPath means that the lockPath in the conch file will be used if the
30591 ** host IDs match, or a new lock path will be generated automatically
30592 ** and written to the conch file.
30594 static int proxyTakeConch(unixFile *pFile){
30595 proxyLockingContext *pCtx = (proxyLockingContext *)pFile->lockingContext;
30597 if( pCtx->conchHeld!=0 ){
30598 return SQLITE_OK;
30599 }else{
30600 unixFile *conchFile = pCtx->conchFile;
30601 uuid_t myHostID;
30602 int pError = 0;
30603 char readBuf[PROXY_MAXCONCHLEN];
30604 char lockPath[MAXPATHLEN];
30605 char *tempLockPath = NULL;
30606 int rc = SQLITE_OK;
30607 int createConch = 0;
30608 int hostIdMatch = 0;
30609 int readLen = 0;
30610 int tryOldLockPath = 0;
30611 int forceNewLockPath = 0;
30613 OSTRACE(("TAKECONCH %d for %s pid=%d\n", conchFile->h,
30614 (pCtx->lockProxyPath ? pCtx->lockProxyPath : ":auto:"), getpid()));
30616 rc = proxyGetHostID(myHostID, &pError);
30617 if( (rc&0xff)==SQLITE_IOERR ){
30618 pFile->lastErrno = pError;
30619 goto end_takeconch;
30621 rc = proxyConchLock(pFile, myHostID, SHARED_LOCK);
30622 if( rc!=SQLITE_OK ){
30623 goto end_takeconch;
30625 /* read the existing conch file */
30626 readLen = seekAndRead((unixFile*)conchFile, 0, readBuf, PROXY_MAXCONCHLEN);
30627 if( readLen<0 ){
30628 /* I/O error: lastErrno set by seekAndRead */
30629 pFile->lastErrno = conchFile->lastErrno;
30630 rc = SQLITE_IOERR_READ;
30631 goto end_takeconch;
30632 }else if( readLen<=(PROXY_HEADERLEN+PROXY_HOSTIDLEN) ||
30633 readBuf[0]!=(char)PROXY_CONCHVERSION ){
30634 /* a short read or version format mismatch means we need to create a new
30635 ** conch file.
30637 createConch = 1;
30639 /* if the host id matches and the lock path already exists in the conch
30640 ** we'll try to use the path there, if we can't open that path, we'll
30641 ** retry with a new auto-generated path
30643 do { /* in case we need to try again for an :auto: named lock file */
30645 if( !createConch && !forceNewLockPath ){
30646 hostIdMatch = !memcmp(&readBuf[PROXY_HEADERLEN], myHostID,
30647 PROXY_HOSTIDLEN);
30648 /* if the conch has data compare the contents */
30649 if( !pCtx->lockProxyPath ){
30650 /* for auto-named local lock file, just check the host ID and we'll
30651 ** use the local lock file path that's already in there
30653 if( hostIdMatch ){
30654 size_t pathLen = (readLen - PROXY_PATHINDEX);
30656 if( pathLen>=MAXPATHLEN ){
30657 pathLen=MAXPATHLEN-1;
30659 memcpy(lockPath, &readBuf[PROXY_PATHINDEX], pathLen);
30660 lockPath[pathLen] = 0;
30661 tempLockPath = lockPath;
30662 tryOldLockPath = 1;
30663 /* create a copy of the lock path if the conch is taken */
30664 goto end_takeconch;
30666 }else if( hostIdMatch
30667 && !strncmp(pCtx->lockProxyPath, &readBuf[PROXY_PATHINDEX],
30668 readLen-PROXY_PATHINDEX)
30670 /* conch host and lock path match */
30671 goto end_takeconch;
30675 /* if the conch isn't writable and doesn't match, we can't take it */
30676 if( (conchFile->openFlags&O_RDWR) == 0 ){
30677 rc = SQLITE_BUSY;
30678 goto end_takeconch;
30681 /* either the conch didn't match or we need to create a new one */
30682 if( !pCtx->lockProxyPath ){
30683 proxyGetLockPath(pCtx->dbPath, lockPath, MAXPATHLEN);
30684 tempLockPath = lockPath;
30685 /* create a copy of the lock path _only_ if the conch is taken */
30688 /* update conch with host and path (this will fail if other process
30689 ** has a shared lock already), if the host id matches, use the big
30690 ** stick.
30692 futimes(conchFile->h, NULL);
30693 if( hostIdMatch && !createConch ){
30694 if( conchFile->pInode && conchFile->pInode->nShared>1 ){
30695 /* We are trying for an exclusive lock but another thread in this
30696 ** same process is still holding a shared lock. */
30697 rc = SQLITE_BUSY;
30698 } else {
30699 rc = proxyConchLock(pFile, myHostID, EXCLUSIVE_LOCK);
30701 }else{
30702 rc = conchFile->pMethod->xLock((sqlite3_file*)conchFile, EXCLUSIVE_LOCK);
30704 if( rc==SQLITE_OK ){
30705 char writeBuffer[PROXY_MAXCONCHLEN];
30706 int writeSize = 0;
30708 writeBuffer[0] = (char)PROXY_CONCHVERSION;
30709 memcpy(&writeBuffer[PROXY_HEADERLEN], myHostID, PROXY_HOSTIDLEN);
30710 if( pCtx->lockProxyPath!=NULL ){
30711 strlcpy(&writeBuffer[PROXY_PATHINDEX], pCtx->lockProxyPath, MAXPATHLEN);
30712 }else{
30713 strlcpy(&writeBuffer[PROXY_PATHINDEX], tempLockPath, MAXPATHLEN);
30715 writeSize = PROXY_PATHINDEX + strlen(&writeBuffer[PROXY_PATHINDEX]);
30716 robust_ftruncate(conchFile->h, writeSize);
30717 rc = unixWrite((sqlite3_file *)conchFile, writeBuffer, writeSize, 0);
30718 fsync(conchFile->h);
30719 /* If we created a new conch file (not just updated the contents of a
30720 ** valid conch file), try to match the permissions of the database
30722 if( rc==SQLITE_OK && createConch ){
30723 struct stat buf;
30724 int err = osFstat(pFile->h, &buf);
30725 if( err==0 ){
30726 mode_t cmode = buf.st_mode&(S_IRUSR|S_IWUSR | S_IRGRP|S_IWGRP |
30727 S_IROTH|S_IWOTH);
30728 /* try to match the database file R/W permissions, ignore failure */
30729 #ifndef SQLITE_PROXY_DEBUG
30730 osFchmod(conchFile->h, cmode);
30731 #else
30733 rc = osFchmod(conchFile->h, cmode);
30734 }while( rc==(-1) && errno==EINTR );
30735 if( rc!=0 ){
30736 int code = errno;
30737 fprintf(stderr, "fchmod %o FAILED with %d %s\n",
30738 cmode, code, strerror(code));
30739 } else {
30740 fprintf(stderr, "fchmod %o SUCCEDED\n",cmode);
30742 }else{
30743 int code = errno;
30744 fprintf(stderr, "STAT FAILED[%d] with %d %s\n",
30745 err, code, strerror(code));
30746 #endif
30750 conchFile->pMethod->xUnlock((sqlite3_file*)conchFile, SHARED_LOCK);
30752 end_takeconch:
30753 OSTRACE(("TRANSPROXY: CLOSE %d\n", pFile->h));
30754 if( rc==SQLITE_OK && pFile->openFlags ){
30755 int fd;
30756 if( pFile->h>=0 ){
30757 robust_close(pFile, pFile->h, __LINE__);
30759 pFile->h = -1;
30760 fd = robust_open(pCtx->dbPath, pFile->openFlags,
30761 SQLITE_DEFAULT_FILE_PERMISSIONS);
30762 OSTRACE(("TRANSPROXY: OPEN %d\n", fd));
30763 if( fd>=0 ){
30764 pFile->h = fd;
30765 }else{
30766 rc=SQLITE_CANTOPEN_BKPT; /* SQLITE_BUSY? proxyTakeConch called
30767 during locking */
30770 if( rc==SQLITE_OK && !pCtx->lockProxy ){
30771 char *path = tempLockPath ? tempLockPath : pCtx->lockProxyPath;
30772 rc = proxyCreateUnixFile(path, &pCtx->lockProxy, 1);
30773 if( rc!=SQLITE_OK && rc!=SQLITE_NOMEM && tryOldLockPath ){
30774 /* we couldn't create the proxy lock file with the old lock file path
30775 ** so try again via auto-naming
30777 forceNewLockPath = 1;
30778 tryOldLockPath = 0;
30779 continue; /* go back to the do {} while start point, try again */
30782 if( rc==SQLITE_OK ){
30783 /* Need to make a copy of path if we extracted the value
30784 ** from the conch file or the path was allocated on the stack
30786 if( tempLockPath ){
30787 pCtx->lockProxyPath = sqlite3DbStrDup(0, tempLockPath);
30788 if( !pCtx->lockProxyPath ){
30789 rc = SQLITE_NOMEM;
30793 if( rc==SQLITE_OK ){
30794 pCtx->conchHeld = 1;
30796 if( pCtx->lockProxy->pMethod == &afpIoMethods ){
30797 afpLockingContext *afpCtx;
30798 afpCtx = (afpLockingContext *)pCtx->lockProxy->lockingContext;
30799 afpCtx->dbPath = pCtx->lockProxyPath;
30801 } else {
30802 conchFile->pMethod->xUnlock((sqlite3_file*)conchFile, NO_LOCK);
30804 OSTRACE(("TAKECONCH %d %s\n", conchFile->h,
30805 rc==SQLITE_OK?"ok":"failed"));
30806 return rc;
30807 } while (1); /* in case we need to retry the :auto: lock file -
30808 ** we should never get here except via the 'continue' call. */
30813 ** If pFile holds a lock on a conch file, then release that lock.
30815 static int proxyReleaseConch(unixFile *pFile){
30816 int rc = SQLITE_OK; /* Subroutine return code */
30817 proxyLockingContext *pCtx; /* The locking context for the proxy lock */
30818 unixFile *conchFile; /* Name of the conch file */
30820 pCtx = (proxyLockingContext *)pFile->lockingContext;
30821 conchFile = pCtx->conchFile;
30822 OSTRACE(("RELEASECONCH %d for %s pid=%d\n", conchFile->h,
30823 (pCtx->lockProxyPath ? pCtx->lockProxyPath : ":auto:"),
30824 getpid()));
30825 if( pCtx->conchHeld>0 ){
30826 rc = conchFile->pMethod->xUnlock((sqlite3_file*)conchFile, NO_LOCK);
30828 pCtx->conchHeld = 0;
30829 OSTRACE(("RELEASECONCH %d %s\n", conchFile->h,
30830 (rc==SQLITE_OK ? "ok" : "failed")));
30831 return rc;
30835 ** Given the name of a database file, compute the name of its conch file.
30836 ** Store the conch filename in memory obtained from sqlite3_malloc().
30837 ** Make *pConchPath point to the new name. Return SQLITE_OK on success
30838 ** or SQLITE_NOMEM if unable to obtain memory.
30840 ** The caller is responsible for ensuring that the allocated memory
30841 ** space is eventually freed.
30843 ** *pConchPath is set to NULL if a memory allocation error occurs.
30845 static int proxyCreateConchPathname(char *dbPath, char **pConchPath){
30846 int i; /* Loop counter */
30847 int len = (int)strlen(dbPath); /* Length of database filename - dbPath */
30848 char *conchPath; /* buffer in which to construct conch name */
30850 /* Allocate space for the conch filename and initialize the name to
30851 ** the name of the original database file. */
30852 *pConchPath = conchPath = (char *)sqlite3_malloc(len + 8);
30853 if( conchPath==0 ){
30854 return SQLITE_NOMEM;
30856 memcpy(conchPath, dbPath, len+1);
30858 /* now insert a "." before the last / character */
30859 for( i=(len-1); i>=0; i-- ){
30860 if( conchPath[i]=='/' ){
30861 i++;
30862 break;
30865 conchPath[i]='.';
30866 while ( i<len ){
30867 conchPath[i+1]=dbPath[i];
30868 i++;
30871 /* append the "-conch" suffix to the file */
30872 memcpy(&conchPath[i+1], "-conch", 7);
30873 assert( (int)strlen(conchPath) == len+7 );
30875 return SQLITE_OK;
30879 /* Takes a fully configured proxy locking-style unix file and switches
30880 ** the local lock file path
30882 static int switchLockProxyPath(unixFile *pFile, const char *path) {
30883 proxyLockingContext *pCtx = (proxyLockingContext*)pFile->lockingContext;
30884 char *oldPath = pCtx->lockProxyPath;
30885 int rc = SQLITE_OK;
30887 if( pFile->eFileLock!=NO_LOCK ){
30888 return SQLITE_BUSY;
30891 /* nothing to do if the path is NULL, :auto: or matches the existing path */
30892 if( !path || path[0]=='\0' || !strcmp(path, ":auto:") ||
30893 (oldPath && !strncmp(oldPath, path, MAXPATHLEN)) ){
30894 return SQLITE_OK;
30895 }else{
30896 unixFile *lockProxy = pCtx->lockProxy;
30897 pCtx->lockProxy=NULL;
30898 pCtx->conchHeld = 0;
30899 if( lockProxy!=NULL ){
30900 rc=lockProxy->pMethod->xClose((sqlite3_file *)lockProxy);
30901 if( rc ) return rc;
30902 sqlite3_free(lockProxy);
30904 sqlite3_free(oldPath);
30905 pCtx->lockProxyPath = sqlite3DbStrDup(0, path);
30908 return rc;
30912 ** pFile is a file that has been opened by a prior xOpen call. dbPath
30913 ** is a string buffer at least MAXPATHLEN+1 characters in size.
30915 ** This routine find the filename associated with pFile and writes it
30916 ** int dbPath.
30918 static int proxyGetDbPathForUnixFile(unixFile *pFile, char *dbPath){
30919 #if defined(__APPLE__)
30920 if( pFile->pMethod == &afpIoMethods ){
30921 /* afp style keeps a reference to the db path in the filePath field
30922 ** of the struct */
30923 assert( (int)strlen((char*)pFile->lockingContext)<=MAXPATHLEN );
30924 strlcpy(dbPath, ((afpLockingContext *)pFile->lockingContext)->dbPath, MAXPATHLEN);
30925 } else
30926 #endif
30927 if( pFile->pMethod == &dotlockIoMethods ){
30928 /* dot lock style uses the locking context to store the dot lock
30929 ** file path */
30930 int len = strlen((char *)pFile->lockingContext) - strlen(DOTLOCK_SUFFIX);
30931 memcpy(dbPath, (char *)pFile->lockingContext, len + 1);
30932 }else{
30933 /* all other styles use the locking context to store the db file path */
30934 assert( strlen((char*)pFile->lockingContext)<=MAXPATHLEN );
30935 strlcpy(dbPath, (char *)pFile->lockingContext, MAXPATHLEN);
30937 return SQLITE_OK;
30941 ** Takes an already filled in unix file and alters it so all file locking
30942 ** will be performed on the local proxy lock file. The following fields
30943 ** are preserved in the locking context so that they can be restored and
30944 ** the unix structure properly cleaned up at close time:
30945 ** ->lockingContext
30946 ** ->pMethod
30948 static int proxyTransformUnixFile(unixFile *pFile, const char *path) {
30949 proxyLockingContext *pCtx;
30950 char dbPath[MAXPATHLEN+1]; /* Name of the database file */
30951 char *lockPath=NULL;
30952 int rc = SQLITE_OK;
30954 if( pFile->eFileLock!=NO_LOCK ){
30955 return SQLITE_BUSY;
30957 proxyGetDbPathForUnixFile(pFile, dbPath);
30958 if( !path || path[0]=='\0' || !strcmp(path, ":auto:") ){
30959 lockPath=NULL;
30960 }else{
30961 lockPath=(char *)path;
30964 OSTRACE(("TRANSPROXY %d for %s pid=%d\n", pFile->h,
30965 (lockPath ? lockPath : ":auto:"), getpid()));
30967 pCtx = sqlite3_malloc( sizeof(*pCtx) );
30968 if( pCtx==0 ){
30969 return SQLITE_NOMEM;
30971 memset(pCtx, 0, sizeof(*pCtx));
30973 rc = proxyCreateConchPathname(dbPath, &pCtx->conchFilePath);
30974 if( rc==SQLITE_OK ){
30975 rc = proxyCreateUnixFile(pCtx->conchFilePath, &pCtx->conchFile, 0);
30976 if( rc==SQLITE_CANTOPEN && ((pFile->openFlags&O_RDWR) == 0) ){
30977 /* if (a) the open flags are not O_RDWR, (b) the conch isn't there, and
30978 ** (c) the file system is read-only, then enable no-locking access.
30979 ** Ugh, since O_RDONLY==0x0000 we test for !O_RDWR since unixOpen asserts
30980 ** that openFlags will have only one of O_RDONLY or O_RDWR.
30982 struct statfs fsInfo;
30983 struct stat conchInfo;
30984 int goLockless = 0;
30986 if( osStat(pCtx->conchFilePath, &conchInfo) == -1 ) {
30987 int err = errno;
30988 if( (err==ENOENT) && (statfs(dbPath, &fsInfo) != -1) ){
30989 goLockless = (fsInfo.f_flags&MNT_RDONLY) == MNT_RDONLY;
30992 if( goLockless ){
30993 pCtx->conchHeld = -1; /* read only FS/ lockless */
30994 rc = SQLITE_OK;
30998 if( rc==SQLITE_OK && lockPath ){
30999 pCtx->lockProxyPath = sqlite3DbStrDup(0, lockPath);
31002 if( rc==SQLITE_OK ){
31003 pCtx->dbPath = sqlite3DbStrDup(0, dbPath);
31004 if( pCtx->dbPath==NULL ){
31005 rc = SQLITE_NOMEM;
31008 if( rc==SQLITE_OK ){
31009 /* all memory is allocated, proxys are created and assigned,
31010 ** switch the locking context and pMethod then return.
31012 pCtx->oldLockingContext = pFile->lockingContext;
31013 pFile->lockingContext = pCtx;
31014 pCtx->pOldMethod = pFile->pMethod;
31015 pFile->pMethod = &proxyIoMethods;
31016 }else{
31017 if( pCtx->conchFile ){
31018 pCtx->conchFile->pMethod->xClose((sqlite3_file *)pCtx->conchFile);
31019 sqlite3_free(pCtx->conchFile);
31021 sqlite3DbFree(0, pCtx->lockProxyPath);
31022 sqlite3_free(pCtx->conchFilePath);
31023 sqlite3_free(pCtx);
31025 OSTRACE(("TRANSPROXY %d %s\n", pFile->h,
31026 (rc==SQLITE_OK ? "ok" : "failed")));
31027 return rc;
31032 ** This routine handles sqlite3_file_control() calls that are specific
31033 ** to proxy locking.
31035 static int proxyFileControl(sqlite3_file *id, int op, void *pArg){
31036 switch( op ){
31037 case SQLITE_GET_LOCKPROXYFILE: {
31038 unixFile *pFile = (unixFile*)id;
31039 if( pFile->pMethod == &proxyIoMethods ){
31040 proxyLockingContext *pCtx = (proxyLockingContext*)pFile->lockingContext;
31041 proxyTakeConch(pFile);
31042 if( pCtx->lockProxyPath ){
31043 *(const char **)pArg = pCtx->lockProxyPath;
31044 }else{
31045 *(const char **)pArg = ":auto: (not held)";
31047 } else {
31048 *(const char **)pArg = NULL;
31050 return SQLITE_OK;
31052 case SQLITE_SET_LOCKPROXYFILE: {
31053 unixFile *pFile = (unixFile*)id;
31054 int rc = SQLITE_OK;
31055 int isProxyStyle = (pFile->pMethod == &proxyIoMethods);
31056 if( pArg==NULL || (const char *)pArg==0 ){
31057 if( isProxyStyle ){
31058 /* turn off proxy locking - not supported */
31059 rc = SQLITE_ERROR /*SQLITE_PROTOCOL? SQLITE_MISUSE?*/;
31060 }else{
31061 /* turn off proxy locking - already off - NOOP */
31062 rc = SQLITE_OK;
31064 }else{
31065 const char *proxyPath = (const char *)pArg;
31066 if( isProxyStyle ){
31067 proxyLockingContext *pCtx =
31068 (proxyLockingContext*)pFile->lockingContext;
31069 if( !strcmp(pArg, ":auto:")
31070 || (pCtx->lockProxyPath &&
31071 !strncmp(pCtx->lockProxyPath, proxyPath, MAXPATHLEN))
31073 rc = SQLITE_OK;
31074 }else{
31075 rc = switchLockProxyPath(pFile, proxyPath);
31077 }else{
31078 /* turn on proxy file locking */
31079 rc = proxyTransformUnixFile(pFile, proxyPath);
31082 return rc;
31084 default: {
31085 assert( 0 ); /* The call assures that only valid opcodes are sent */
31088 /*NOTREACHED*/
31089 return SQLITE_ERROR;
31093 ** Within this division (the proxying locking implementation) the procedures
31094 ** above this point are all utilities. The lock-related methods of the
31095 ** proxy-locking sqlite3_io_method object follow.
31100 ** This routine checks if there is a RESERVED lock held on the specified
31101 ** file by this or any other process. If such a lock is held, set *pResOut
31102 ** to a non-zero value otherwise *pResOut is set to zero. The return value
31103 ** is set to SQLITE_OK unless an I/O error occurs during lock checking.
31105 static int proxyCheckReservedLock(sqlite3_file *id, int *pResOut) {
31106 unixFile *pFile = (unixFile*)id;
31107 int rc = proxyTakeConch(pFile);
31108 if( rc==SQLITE_OK ){
31109 proxyLockingContext *pCtx = (proxyLockingContext *)pFile->lockingContext;
31110 if( pCtx->conchHeld>0 ){
31111 unixFile *proxy = pCtx->lockProxy;
31112 return proxy->pMethod->xCheckReservedLock((sqlite3_file*)proxy, pResOut);
31113 }else{ /* conchHeld < 0 is lockless */
31114 pResOut=0;
31117 return rc;
31121 ** Lock the file with the lock specified by parameter eFileLock - one
31122 ** of the following:
31124 ** (1) SHARED_LOCK
31125 ** (2) RESERVED_LOCK
31126 ** (3) PENDING_LOCK
31127 ** (4) EXCLUSIVE_LOCK
31129 ** Sometimes when requesting one lock state, additional lock states
31130 ** are inserted in between. The locking might fail on one of the later
31131 ** transitions leaving the lock state different from what it started but
31132 ** still short of its goal. The following chart shows the allowed
31133 ** transitions and the inserted intermediate states:
31135 ** UNLOCKED -> SHARED
31136 ** SHARED -> RESERVED
31137 ** SHARED -> (PENDING) -> EXCLUSIVE
31138 ** RESERVED -> (PENDING) -> EXCLUSIVE
31139 ** PENDING -> EXCLUSIVE
31141 ** This routine will only increase a lock. Use the sqlite3OsUnlock()
31142 ** routine to lower a locking level.
31144 static int proxyLock(sqlite3_file *id, int eFileLock) {
31145 unixFile *pFile = (unixFile*)id;
31146 int rc = proxyTakeConch(pFile);
31147 if( rc==SQLITE_OK ){
31148 proxyLockingContext *pCtx = (proxyLockingContext *)pFile->lockingContext;
31149 if( pCtx->conchHeld>0 ){
31150 unixFile *proxy = pCtx->lockProxy;
31151 rc = proxy->pMethod->xLock((sqlite3_file*)proxy, eFileLock);
31152 pFile->eFileLock = proxy->eFileLock;
31153 }else{
31154 /* conchHeld < 0 is lockless */
31157 return rc;
31162 ** Lower the locking level on file descriptor pFile to eFileLock. eFileLock
31163 ** must be either NO_LOCK or SHARED_LOCK.
31165 ** If the locking level of the file descriptor is already at or below
31166 ** the requested locking level, this routine is a no-op.
31168 static int proxyUnlock(sqlite3_file *id, int eFileLock) {
31169 unixFile *pFile = (unixFile*)id;
31170 int rc = proxyTakeConch(pFile);
31171 if( rc==SQLITE_OK ){
31172 proxyLockingContext *pCtx = (proxyLockingContext *)pFile->lockingContext;
31173 if( pCtx->conchHeld>0 ){
31174 unixFile *proxy = pCtx->lockProxy;
31175 rc = proxy->pMethod->xUnlock((sqlite3_file*)proxy, eFileLock);
31176 pFile->eFileLock = proxy->eFileLock;
31177 }else{
31178 /* conchHeld < 0 is lockless */
31181 return rc;
31185 ** Close a file that uses proxy locks.
31187 static int proxyClose(sqlite3_file *id) {
31188 if( id ){
31189 unixFile *pFile = (unixFile*)id;
31190 proxyLockingContext *pCtx = (proxyLockingContext *)pFile->lockingContext;
31191 unixFile *lockProxy = pCtx->lockProxy;
31192 unixFile *conchFile = pCtx->conchFile;
31193 int rc = SQLITE_OK;
31195 if( lockProxy ){
31196 rc = lockProxy->pMethod->xUnlock((sqlite3_file*)lockProxy, NO_LOCK);
31197 if( rc ) return rc;
31198 rc = lockProxy->pMethod->xClose((sqlite3_file*)lockProxy);
31199 if( rc ) return rc;
31200 sqlite3_free(lockProxy);
31201 pCtx->lockProxy = 0;
31203 if( conchFile ){
31204 if( pCtx->conchHeld ){
31205 rc = proxyReleaseConch(pFile);
31206 if( rc ) return rc;
31208 rc = conchFile->pMethod->xClose((sqlite3_file*)conchFile);
31209 if( rc ) return rc;
31210 sqlite3_free(conchFile);
31212 sqlite3DbFree(0, pCtx->lockProxyPath);
31213 sqlite3_free(pCtx->conchFilePath);
31214 sqlite3DbFree(0, pCtx->dbPath);
31215 /* restore the original locking context and pMethod then close it */
31216 pFile->lockingContext = pCtx->oldLockingContext;
31217 pFile->pMethod = pCtx->pOldMethod;
31218 sqlite3_free(pCtx);
31219 return pFile->pMethod->xClose(id);
31221 return SQLITE_OK;
31226 #endif /* defined(__APPLE__) && SQLITE_ENABLE_LOCKING_STYLE */
31228 ** The proxy locking style is intended for use with AFP filesystems.
31229 ** And since AFP is only supported on MacOSX, the proxy locking is also
31230 ** restricted to MacOSX.
31233 ******************* End of the proxy lock implementation **********************
31234 ******************************************************************************/
31237 ** Initialize the operating system interface.
31239 ** This routine registers all VFS implementations for unix-like operating
31240 ** systems. This routine, and the sqlite3_os_end() routine that follows,
31241 ** should be the only routines in this file that are visible from other
31242 ** files.
31244 ** This routine is called once during SQLite initialization and by a
31245 ** single thread. The memory allocation and mutex subsystems have not
31246 ** necessarily been initialized when this routine is called, and so they
31247 ** should not be used.
31249 SQLITE_API int sqlite3_os_init(void){
31251 ** The following macro defines an initializer for an sqlite3_vfs object.
31252 ** The name of the VFS is NAME. The pAppData is a pointer to a pointer
31253 ** to the "finder" function. (pAppData is a pointer to a pointer because
31254 ** silly C90 rules prohibit a void* from being cast to a function pointer
31255 ** and so we have to go through the intermediate pointer to avoid problems
31256 ** when compiling with -pedantic-errors on GCC.)
31258 ** The FINDER parameter to this macro is the name of the pointer to the
31259 ** finder-function. The finder-function returns a pointer to the
31260 ** sqlite_io_methods object that implements the desired locking
31261 ** behaviors. See the division above that contains the IOMETHODS
31262 ** macro for addition information on finder-functions.
31264 ** Most finders simply return a pointer to a fixed sqlite3_io_methods
31265 ** object. But the "autolockIoFinder" available on MacOSX does a little
31266 ** more than that; it looks at the filesystem type that hosts the
31267 ** database file and tries to choose an locking method appropriate for
31268 ** that filesystem time.
31270 #define UNIXVFS(VFSNAME, FINDER) { \
31271 3, /* iVersion */ \
31272 sizeof(unixFile), /* szOsFile */ \
31273 MAX_PATHNAME, /* mxPathname */ \
31274 0, /* pNext */ \
31275 VFSNAME, /* zName */ \
31276 (void*)&FINDER, /* pAppData */ \
31277 unixOpen, /* xOpen */ \
31278 unixDelete, /* xDelete */ \
31279 unixAccess, /* xAccess */ \
31280 unixFullPathname, /* xFullPathname */ \
31281 unixDlOpen, /* xDlOpen */ \
31282 unixDlError, /* xDlError */ \
31283 unixDlSym, /* xDlSym */ \
31284 unixDlClose, /* xDlClose */ \
31285 unixRandomness, /* xRandomness */ \
31286 unixSleep, /* xSleep */ \
31287 unixCurrentTime, /* xCurrentTime */ \
31288 unixGetLastError, /* xGetLastError */ \
31289 unixCurrentTimeInt64, /* xCurrentTimeInt64 */ \
31290 unixSetSystemCall, /* xSetSystemCall */ \
31291 unixGetSystemCall, /* xGetSystemCall */ \
31292 unixNextSystemCall, /* xNextSystemCall */ \
31296 ** All default VFSes for unix are contained in the following array.
31298 ** Note that the sqlite3_vfs.pNext field of the VFS object is modified
31299 ** by the SQLite core when the VFS is registered. So the following
31300 ** array cannot be const.
31302 static sqlite3_vfs aVfs[] = {
31303 #if SQLITE_ENABLE_LOCKING_STYLE && (OS_VXWORKS || defined(__APPLE__))
31304 UNIXVFS("unix", autolockIoFinder ),
31305 #else
31306 UNIXVFS("unix", posixIoFinder ),
31307 #endif
31308 UNIXVFS("unix-none", nolockIoFinder ),
31309 UNIXVFS("unix-dotfile", dotlockIoFinder ),
31310 UNIXVFS("unix-excl", posixIoFinder ),
31311 #if OS_VXWORKS
31312 UNIXVFS("unix-namedsem", semIoFinder ),
31313 #endif
31314 #if SQLITE_ENABLE_LOCKING_STYLE
31315 UNIXVFS("unix-posix", posixIoFinder ),
31316 #if !OS_VXWORKS
31317 UNIXVFS("unix-flock", flockIoFinder ),
31318 #endif
31319 #endif
31320 #if SQLITE_ENABLE_LOCKING_STYLE && defined(__APPLE__)
31321 UNIXVFS("unix-afp", afpIoFinder ),
31322 UNIXVFS("unix-nfs", nfsIoFinder ),
31323 UNIXVFS("unix-proxy", proxyIoFinder ),
31324 #endif
31326 unsigned int i; /* Loop counter */
31328 /* Double-check that the aSyscall[] array has been constructed
31329 ** correctly. See ticket [bb3a86e890c8e96ab] */
31330 assert( ArraySize(aSyscall)==18 );
31332 /* Register all VFSes defined in the aVfs[] array */
31333 for(i=0; i<(sizeof(aVfs)/sizeof(sqlite3_vfs)); i++){
31334 sqlite3_vfs_register(&aVfs[i], i==0);
31336 return SQLITE_OK;
31340 ** Shutdown the operating system interface.
31342 ** Some operating systems might need to do some cleanup in this routine,
31343 ** to release dynamically allocated objects. But not on unix.
31344 ** This routine is a no-op for unix.
31346 SQLITE_API int sqlite3_os_end(void){
31347 return SQLITE_OK;
31350 #endif /* SQLITE_OS_UNIX */
31352 /************** End of os_unix.c *********************************************/
31353 /************** Begin file os_win.c ******************************************/
31355 ** 2004 May 22
31357 ** The author disclaims copyright to this source code. In place of
31358 ** a legal notice, here is a blessing:
31360 ** May you do good and not evil.
31361 ** May you find forgiveness for yourself and forgive others.
31362 ** May you share freely, never taking more than you give.
31364 ******************************************************************************
31366 ** This file contains code that is specific to windows.
31368 #if SQLITE_OS_WIN /* This file is used for windows only */
31372 ** A Note About Memory Allocation:
31374 ** This driver uses malloc()/free() directly rather than going through
31375 ** the SQLite-wrappers sqlite3_malloc()/sqlite3_free(). Those wrappers
31376 ** are designed for use on embedded systems where memory is scarce and
31377 ** malloc failures happen frequently. Win32 does not typically run on
31378 ** embedded systems, and when it does the developers normally have bigger
31379 ** problems to worry about than running out of memory. So there is not
31380 ** a compelling need to use the wrappers.
31382 ** But there is a good reason to not use the wrappers. If we use the
31383 ** wrappers then we will get simulated malloc() failures within this
31384 ** driver. And that causes all kinds of problems for our tests. We
31385 ** could enhance SQLite to deal with simulated malloc failures within
31386 ** the OS driver, but the code to deal with those failure would not
31387 ** be exercised on Linux (which does not need to malloc() in the driver)
31388 ** and so we would have difficulty writing coverage tests for that
31389 ** code. Better to leave the code out, we think.
31391 ** The point of this discussion is as follows: When creating a new
31392 ** OS layer for an embedded system, if you use this file as an example,
31393 ** avoid the use of malloc()/free(). Those routines work ok on windows
31394 ** desktops but not so well in embedded systems.
31397 #include <winbase.h>
31399 #ifdef __CYGWIN__
31400 # include <sys/cygwin.h>
31401 #endif
31404 ** Macros used to determine whether or not to use threads.
31406 #if defined(THREADSAFE) && THREADSAFE
31407 # define SQLITE_W32_THREADS 1
31408 #endif
31411 ** Include code that is common to all os_*.c files
31413 /************** Include os_common.h in the middle of os_win.c ****************/
31414 /************** Begin file os_common.h ***************************************/
31416 ** 2004 May 22
31418 ** The author disclaims copyright to this source code. In place of
31419 ** a legal notice, here is a blessing:
31421 ** May you do good and not evil.
31422 ** May you find forgiveness for yourself and forgive others.
31423 ** May you share freely, never taking more than you give.
31425 ******************************************************************************
31427 ** This file contains macros and a little bit of code that is common to
31428 ** all of the platform-specific files (os_*.c) and is #included into those
31429 ** files.
31431 ** This file should be #included by the os_*.c files only. It is not a
31432 ** general purpose header file.
31434 #ifndef _OS_COMMON_H_
31435 #define _OS_COMMON_H_
31438 ** At least two bugs have slipped in because we changed the MEMORY_DEBUG
31439 ** macro to SQLITE_DEBUG and some older makefiles have not yet made the
31440 ** switch. The following code should catch this problem at compile-time.
31442 #ifdef MEMORY_DEBUG
31443 # error "The MEMORY_DEBUG macro is obsolete. Use SQLITE_DEBUG instead."
31444 #endif
31446 #if defined(SQLITE_TEST) && defined(SQLITE_DEBUG)
31447 # ifndef SQLITE_DEBUG_OS_TRACE
31448 # define SQLITE_DEBUG_OS_TRACE 0
31449 # endif
31450 int sqlite3OSTrace = SQLITE_DEBUG_OS_TRACE;
31451 # define OSTRACE(X) if( sqlite3OSTrace ) sqlite3DebugPrintf X
31452 #else
31453 # define OSTRACE(X)
31454 #endif
31457 ** Macros for performance tracing. Normally turned off. Only works
31458 ** on i486 hardware.
31460 #ifdef SQLITE_PERFORMANCE_TRACE
31463 ** hwtime.h contains inline assembler code for implementing
31464 ** high-performance timing routines.
31466 /************** Include hwtime.h in the middle of os_common.h ****************/
31467 /************** Begin file hwtime.h ******************************************/
31469 ** 2008 May 27
31471 ** The author disclaims copyright to this source code. In place of
31472 ** a legal notice, here is a blessing:
31474 ** May you do good and not evil.
31475 ** May you find forgiveness for yourself and forgive others.
31476 ** May you share freely, never taking more than you give.
31478 ******************************************************************************
31480 ** This file contains inline asm code for retrieving "high-performance"
31481 ** counters for x86 class CPUs.
31483 #ifndef _HWTIME_H_
31484 #define _HWTIME_H_
31487 ** The following routine only works on pentium-class (or newer) processors.
31488 ** It uses the RDTSC opcode to read the cycle count value out of the
31489 ** processor and returns that value. This can be used for high-res
31490 ** profiling.
31492 #if (defined(__GNUC__) || defined(_MSC_VER)) && \
31493 (defined(i386) || defined(__i386__) || defined(_M_IX86))
31495 #if defined(__GNUC__)
31497 __inline__ sqlite_uint64 sqlite3Hwtime(void){
31498 unsigned int lo, hi;
31499 __asm__ __volatile__ ("rdtsc" : "=a" (lo), "=d" (hi));
31500 return (sqlite_uint64)hi << 32 | lo;
31503 #elif defined(_MSC_VER)
31505 __declspec(naked) __inline sqlite_uint64 __cdecl sqlite3Hwtime(void){
31506 __asm {
31507 rdtsc
31508 ret ; return value at EDX:EAX
31512 #endif
31514 #elif (defined(__GNUC__) && defined(__x86_64__))
31516 __inline__ sqlite_uint64 sqlite3Hwtime(void){
31517 unsigned long val;
31518 __asm__ __volatile__ ("rdtsc" : "=A" (val));
31519 return val;
31522 #elif (defined(__GNUC__) && defined(__ppc__))
31524 __inline__ sqlite_uint64 sqlite3Hwtime(void){
31525 unsigned long long retval;
31526 unsigned long junk;
31527 __asm__ __volatile__ ("\n\
31528 1: mftbu %1\n\
31529 mftb %L0\n\
31530 mftbu %0\n\
31531 cmpw %0,%1\n\
31532 bne 1b"
31533 : "=r" (retval), "=r" (junk));
31534 return retval;
31537 #else
31539 #error Need implementation of sqlite3Hwtime() for your platform.
31542 ** To compile without implementing sqlite3Hwtime() for your platform,
31543 ** you can remove the above #error and use the following
31544 ** stub function. You will lose timing support for many
31545 ** of the debugging and testing utilities, but it should at
31546 ** least compile and run.
31548 SQLITE_PRIVATE sqlite_uint64 sqlite3Hwtime(void){ return ((sqlite_uint64)0); }
31550 #endif
31552 #endif /* !defined(_HWTIME_H_) */
31554 /************** End of hwtime.h **********************************************/
31555 /************** Continuing where we left off in os_common.h ******************/
31557 static sqlite_uint64 g_start;
31558 static sqlite_uint64 g_elapsed;
31559 #define TIMER_START g_start=sqlite3Hwtime()
31560 #define TIMER_END g_elapsed=sqlite3Hwtime()-g_start
31561 #define TIMER_ELAPSED g_elapsed
31562 #else
31563 #define TIMER_START
31564 #define TIMER_END
31565 #define TIMER_ELAPSED ((sqlite_uint64)0)
31566 #endif
31569 ** If we compile with the SQLITE_TEST macro set, then the following block
31570 ** of code will give us the ability to simulate a disk I/O error. This
31571 ** is used for testing the I/O recovery logic.
31573 #ifdef SQLITE_TEST
31574 SQLITE_API int sqlite3_io_error_hit = 0; /* Total number of I/O Errors */
31575 SQLITE_API int sqlite3_io_error_hardhit = 0; /* Number of non-benign errors */
31576 SQLITE_API int sqlite3_io_error_pending = 0; /* Count down to first I/O error */
31577 SQLITE_API int sqlite3_io_error_persist = 0; /* True if I/O errors persist */
31578 SQLITE_API int sqlite3_io_error_benign = 0; /* True if errors are benign */
31579 SQLITE_API int sqlite3_diskfull_pending = 0;
31580 SQLITE_API int sqlite3_diskfull = 0;
31581 #define SimulateIOErrorBenign(X) sqlite3_io_error_benign=(X)
31582 #define SimulateIOError(CODE) \
31583 if( (sqlite3_io_error_persist && sqlite3_io_error_hit) \
31584 || sqlite3_io_error_pending-- == 1 ) \
31585 { local_ioerr(); CODE; }
31586 static void local_ioerr(){
31587 IOTRACE(("IOERR\n"));
31588 sqlite3_io_error_hit++;
31589 if( !sqlite3_io_error_benign ) sqlite3_io_error_hardhit++;
31591 #define SimulateDiskfullError(CODE) \
31592 if( sqlite3_diskfull_pending ){ \
31593 if( sqlite3_diskfull_pending == 1 ){ \
31594 local_ioerr(); \
31595 sqlite3_diskfull = 1; \
31596 sqlite3_io_error_hit = 1; \
31597 CODE; \
31598 }else{ \
31599 sqlite3_diskfull_pending--; \
31602 #else
31603 #define SimulateIOErrorBenign(X)
31604 #define SimulateIOError(A)
31605 #define SimulateDiskfullError(A)
31606 #endif
31609 ** When testing, keep a count of the number of open files.
31611 #ifdef SQLITE_TEST
31612 SQLITE_API int sqlite3_open_file_count = 0;
31613 #define OpenCounter(X) sqlite3_open_file_count+=(X)
31614 #else
31615 #define OpenCounter(X)
31616 #endif
31618 #endif /* !defined(_OS_COMMON_H_) */
31620 /************** End of os_common.h *******************************************/
31621 /************** Continuing where we left off in os_win.c *********************/
31624 ** Some microsoft compilers lack this definition.
31626 #ifndef INVALID_FILE_ATTRIBUTES
31627 # define INVALID_FILE_ATTRIBUTES ((DWORD)-1)
31628 #endif
31631 ** Determine if we are dealing with WindowsCE - which has a much
31632 ** reduced API.
31634 #if SQLITE_OS_WINCE
31635 # define AreFileApisANSI() 1
31636 # define FormatMessageW(a,b,c,d,e,f,g) 0
31637 #endif
31639 /* Forward references */
31640 typedef struct winShm winShm; /* A connection to shared-memory */
31641 typedef struct winShmNode winShmNode; /* A region of shared-memory */
31644 ** WinCE lacks native support for file locking so we have to fake it
31645 ** with some code of our own.
31647 #if SQLITE_OS_WINCE
31648 typedef struct winceLock {
31649 int nReaders; /* Number of reader locks obtained */
31650 BOOL bPending; /* Indicates a pending lock has been obtained */
31651 BOOL bReserved; /* Indicates a reserved lock has been obtained */
31652 BOOL bExclusive; /* Indicates an exclusive lock has been obtained */
31653 } winceLock;
31654 #endif
31657 ** The winFile structure is a subclass of sqlite3_file* specific to the win32
31658 ** portability layer.
31660 typedef struct winFile winFile;
31661 struct winFile {
31662 const sqlite3_io_methods *pMethod; /*** Must be first ***/
31663 sqlite3_vfs *pVfs; /* The VFS used to open this file */
31664 HANDLE h; /* Handle for accessing the file */
31665 u8 locktype; /* Type of lock currently held on this file */
31666 short sharedLockByte; /* Randomly chosen byte used as a shared lock */
31667 u8 bPersistWal; /* True to persist WAL files */
31668 DWORD lastErrno; /* The Windows errno from the last I/O error */
31669 DWORD sectorSize; /* Sector size of the device file is on */
31670 winShm *pShm; /* Instance of shared memory on this file */
31671 const char *zPath; /* Full pathname of this file */
31672 int szChunk; /* Chunk size configured by FCNTL_CHUNK_SIZE */
31673 #if SQLITE_OS_WINCE
31674 WCHAR *zDeleteOnClose; /* Name of file to delete when closing */
31675 HANDLE hMutex; /* Mutex used to control access to shared lock */
31676 HANDLE hShared; /* Shared memory segment used for locking */
31677 winceLock local; /* Locks obtained by this instance of winFile */
31678 winceLock *shared; /* Global shared lock memory for the file */
31679 #endif
31683 * If compiled with SQLITE_WIN32_MALLOC on Windows, we will use the
31684 * various Win32 API heap functions instead of our own.
31686 #ifdef SQLITE_WIN32_MALLOC
31688 * The initial size of the Win32-specific heap. This value may be zero.
31690 #ifndef SQLITE_WIN32_HEAP_INIT_SIZE
31691 # define SQLITE_WIN32_HEAP_INIT_SIZE ((SQLITE_DEFAULT_CACHE_SIZE) * \
31692 (SQLITE_DEFAULT_PAGE_SIZE) + 4194304)
31693 #endif
31696 * The maximum size of the Win32-specific heap. This value may be zero.
31698 #ifndef SQLITE_WIN32_HEAP_MAX_SIZE
31699 # define SQLITE_WIN32_HEAP_MAX_SIZE (0)
31700 #endif
31703 * The extra flags to use in calls to the Win32 heap APIs. This value may be
31704 * zero for the default behavior.
31706 #ifndef SQLITE_WIN32_HEAP_FLAGS
31707 # define SQLITE_WIN32_HEAP_FLAGS (0)
31708 #endif
31711 ** The winMemData structure stores information required by the Win32-specific
31712 ** sqlite3_mem_methods implementation.
31714 typedef struct winMemData winMemData;
31715 struct winMemData {
31716 #ifndef NDEBUG
31717 u32 magic; /* Magic number to detect structure corruption. */
31718 #endif
31719 HANDLE hHeap; /* The handle to our heap. */
31720 BOOL bOwned; /* Do we own the heap (i.e. destroy it on shutdown)? */
31723 #ifndef NDEBUG
31724 #define WINMEM_MAGIC 0x42b2830b
31725 #endif
31727 static struct winMemData win_mem_data = {
31728 #ifndef NDEBUG
31729 WINMEM_MAGIC,
31730 #endif
31731 NULL, FALSE
31734 #ifndef NDEBUG
31735 #define winMemAssertMagic() assert( win_mem_data.magic==WINMEM_MAGIC )
31736 #else
31737 #define winMemAssertMagic()
31738 #endif
31740 #define winMemGetHeap() win_mem_data.hHeap
31742 static void *winMemMalloc(int nBytes);
31743 static void winMemFree(void *pPrior);
31744 static void *winMemRealloc(void *pPrior, int nBytes);
31745 static int winMemSize(void *p);
31746 static int winMemRoundup(int n);
31747 static int winMemInit(void *pAppData);
31748 static void winMemShutdown(void *pAppData);
31750 SQLITE_PRIVATE const sqlite3_mem_methods *sqlite3MemGetWin32(void);
31751 #endif /* SQLITE_WIN32_MALLOC */
31754 ** Forward prototypes.
31756 static int getSectorSize(
31757 sqlite3_vfs *pVfs,
31758 const char *zRelative /* UTF-8 file name */
31762 ** The following variable is (normally) set once and never changes
31763 ** thereafter. It records whether the operating system is Win95
31764 ** or WinNT.
31766 ** 0: Operating system unknown.
31767 ** 1: Operating system is Win95.
31768 ** 2: Operating system is WinNT.
31770 ** In order to facilitate testing on a WinNT system, the test fixture
31771 ** can manually set this value to 1 to emulate Win98 behavior.
31773 #ifdef SQLITE_TEST
31774 SQLITE_API int sqlite3_os_type = 0;
31775 #else
31776 static int sqlite3_os_type = 0;
31777 #endif
31780 ** Return true (non-zero) if we are running under WinNT, Win2K, WinXP,
31781 ** or WinCE. Return false (zero) for Win95, Win98, or WinME.
31783 ** Here is an interesting observation: Win95, Win98, and WinME lack
31784 ** the LockFileEx() API. But we can still statically link against that
31785 ** API as long as we don't call it when running Win95/98/ME. A call to
31786 ** this routine is used to determine if the host is Win95/98/ME or
31787 ** WinNT/2K/XP so that we will know whether or not we can safely call
31788 ** the LockFileEx() API.
31790 #if SQLITE_OS_WINCE
31791 # define isNT() (1)
31792 #else
31793 static int isNT(void){
31794 if( sqlite3_os_type==0 ){
31795 OSVERSIONINFO sInfo;
31796 sInfo.dwOSVersionInfoSize = sizeof(sInfo);
31797 GetVersionEx(&sInfo);
31798 sqlite3_os_type = sInfo.dwPlatformId==VER_PLATFORM_WIN32_NT ? 2 : 1;
31800 return sqlite3_os_type==2;
31802 #endif /* SQLITE_OS_WINCE */
31804 #ifdef SQLITE_WIN32_MALLOC
31806 ** Allocate nBytes of memory.
31808 static void *winMemMalloc(int nBytes){
31809 HANDLE hHeap;
31810 void *p;
31812 winMemAssertMagic();
31813 hHeap = winMemGetHeap();
31814 assert( hHeap!=0 );
31815 assert( hHeap!=INVALID_HANDLE_VALUE );
31816 #ifdef SQLITE_WIN32_MALLOC_VALIDATE
31817 assert ( HeapValidate(hHeap, SQLITE_WIN32_HEAP_FLAGS, NULL) );
31818 #endif
31819 assert( nBytes>=0 );
31820 p = HeapAlloc(hHeap, SQLITE_WIN32_HEAP_FLAGS, (SIZE_T)nBytes);
31821 if( !p ){
31822 sqlite3_log(SQLITE_NOMEM, "failed to HeapAlloc %u bytes (%d), heap=%p",
31823 nBytes, GetLastError(), (void*)hHeap);
31825 return p;
31829 ** Free memory.
31831 static void winMemFree(void *pPrior){
31832 HANDLE hHeap;
31834 winMemAssertMagic();
31835 hHeap = winMemGetHeap();
31836 assert( hHeap!=0 );
31837 assert( hHeap!=INVALID_HANDLE_VALUE );
31838 #ifdef SQLITE_WIN32_MALLOC_VALIDATE
31839 assert ( HeapValidate(hHeap, SQLITE_WIN32_HEAP_FLAGS, pPrior) );
31840 #endif
31841 if( !pPrior ) return; /* Passing NULL to HeapFree is undefined. */
31842 if( !HeapFree(hHeap, SQLITE_WIN32_HEAP_FLAGS, pPrior) ){
31843 sqlite3_log(SQLITE_NOMEM, "failed to HeapFree block %p (%d), heap=%p",
31844 pPrior, GetLastError(), (void*)hHeap);
31849 ** Change the size of an existing memory allocation
31851 static void *winMemRealloc(void *pPrior, int nBytes){
31852 HANDLE hHeap;
31853 void *p;
31855 winMemAssertMagic();
31856 hHeap = winMemGetHeap();
31857 assert( hHeap!=0 );
31858 assert( hHeap!=INVALID_HANDLE_VALUE );
31859 #ifdef SQLITE_WIN32_MALLOC_VALIDATE
31860 assert ( HeapValidate(hHeap, SQLITE_WIN32_HEAP_FLAGS, pPrior) );
31861 #endif
31862 assert( nBytes>=0 );
31863 if( !pPrior ){
31864 p = HeapAlloc(hHeap, SQLITE_WIN32_HEAP_FLAGS, (SIZE_T)nBytes);
31865 }else{
31866 p = HeapReAlloc(hHeap, SQLITE_WIN32_HEAP_FLAGS, pPrior, (SIZE_T)nBytes);
31868 if( !p ){
31869 sqlite3_log(SQLITE_NOMEM, "failed to %s %u bytes (%d), heap=%p",
31870 pPrior ? "HeapReAlloc" : "HeapAlloc", nBytes, GetLastError(),
31871 (void*)hHeap);
31873 return p;
31877 ** Return the size of an outstanding allocation, in bytes.
31879 static int winMemSize(void *p){
31880 HANDLE hHeap;
31881 SIZE_T n;
31883 winMemAssertMagic();
31884 hHeap = winMemGetHeap();
31885 assert( hHeap!=0 );
31886 assert( hHeap!=INVALID_HANDLE_VALUE );
31887 #ifdef SQLITE_WIN32_MALLOC_VALIDATE
31888 assert ( HeapValidate(hHeap, SQLITE_WIN32_HEAP_FLAGS, NULL) );
31889 #endif
31890 if( !p ) return 0;
31891 n = HeapSize(hHeap, SQLITE_WIN32_HEAP_FLAGS, p);
31892 if( n==(SIZE_T)-1 ){
31893 sqlite3_log(SQLITE_NOMEM, "failed to HeapSize block %p (%d), heap=%p",
31894 p, GetLastError(), (void*)hHeap);
31895 return 0;
31897 return (int)n;
31901 ** Round up a request size to the next valid allocation size.
31903 static int winMemRoundup(int n){
31904 return n;
31908 ** Initialize this module.
31910 static int winMemInit(void *pAppData){
31911 winMemData *pWinMemData = (winMemData *)pAppData;
31913 if( !pWinMemData ) return SQLITE_ERROR;
31914 assert( pWinMemData->magic==WINMEM_MAGIC );
31915 if( !pWinMemData->hHeap ){
31916 pWinMemData->hHeap = HeapCreate(SQLITE_WIN32_HEAP_FLAGS,
31917 SQLITE_WIN32_HEAP_INIT_SIZE,
31918 SQLITE_WIN32_HEAP_MAX_SIZE);
31919 if( !pWinMemData->hHeap ){
31920 sqlite3_log(SQLITE_NOMEM,
31921 "failed to HeapCreate (%d), flags=%u, initSize=%u, maxSize=%u",
31922 GetLastError(), SQLITE_WIN32_HEAP_FLAGS, SQLITE_WIN32_HEAP_INIT_SIZE,
31923 SQLITE_WIN32_HEAP_MAX_SIZE);
31924 return SQLITE_NOMEM;
31926 pWinMemData->bOwned = TRUE;
31928 assert( pWinMemData->hHeap!=0 );
31929 assert( pWinMemData->hHeap!=INVALID_HANDLE_VALUE );
31930 #ifdef SQLITE_WIN32_MALLOC_VALIDATE
31931 assert( HeapValidate(pWinMemData->hHeap, SQLITE_WIN32_HEAP_FLAGS, NULL) );
31932 #endif
31933 return SQLITE_OK;
31937 ** Deinitialize this module.
31939 static void winMemShutdown(void *pAppData){
31940 winMemData *pWinMemData = (winMemData *)pAppData;
31942 if( !pWinMemData ) return;
31943 if( pWinMemData->hHeap ){
31944 assert( pWinMemData->hHeap!=INVALID_HANDLE_VALUE );
31945 #ifdef SQLITE_WIN32_MALLOC_VALIDATE
31946 assert( HeapValidate(pWinMemData->hHeap, SQLITE_WIN32_HEAP_FLAGS, NULL) );
31947 #endif
31948 if( pWinMemData->bOwned ){
31949 if( !HeapDestroy(pWinMemData->hHeap) ){
31950 sqlite3_log(SQLITE_NOMEM, "failed to HeapDestroy (%d), heap=%p",
31951 GetLastError(), (void*)pWinMemData->hHeap);
31953 pWinMemData->bOwned = FALSE;
31955 pWinMemData->hHeap = NULL;
31960 ** Populate the low-level memory allocation function pointers in
31961 ** sqlite3GlobalConfig.m with pointers to the routines in this file. The
31962 ** arguments specify the block of memory to manage.
31964 ** This routine is only called by sqlite3_config(), and therefore
31965 ** is not required to be threadsafe (it is not).
31967 SQLITE_PRIVATE const sqlite3_mem_methods *sqlite3MemGetWin32(void){
31968 static const sqlite3_mem_methods winMemMethods = {
31969 winMemMalloc,
31970 winMemFree,
31971 winMemRealloc,
31972 winMemSize,
31973 winMemRoundup,
31974 winMemInit,
31975 winMemShutdown,
31976 &win_mem_data
31978 return &winMemMethods;
31981 SQLITE_PRIVATE void sqlite3MemSetDefault(void){
31982 sqlite3_config(SQLITE_CONFIG_MALLOC, sqlite3MemGetWin32());
31984 #endif /* SQLITE_WIN32_MALLOC */
31987 ** Convert a UTF-8 string to microsoft unicode (UTF-16?).
31989 ** Space to hold the returned string is obtained from malloc.
31991 static WCHAR *utf8ToUnicode(const char *zFilename){
31992 int nChar;
31993 WCHAR *zWideFilename;
31995 nChar = MultiByteToWideChar(CP_UTF8, 0, zFilename, -1, NULL, 0);
31996 zWideFilename = malloc( nChar*sizeof(zWideFilename[0]) );
31997 if( zWideFilename==0 ){
31998 return 0;
32000 nChar = MultiByteToWideChar(CP_UTF8, 0, zFilename, -1, zWideFilename, nChar);
32001 if( nChar==0 ){
32002 free(zWideFilename);
32003 zWideFilename = 0;
32005 return zWideFilename;
32009 ** Convert microsoft unicode to UTF-8. Space to hold the returned string is
32010 ** obtained from malloc().
32012 static char *unicodeToUtf8(const WCHAR *zWideFilename){
32013 int nByte;
32014 char *zFilename;
32016 nByte = WideCharToMultiByte(CP_UTF8, 0, zWideFilename, -1, 0, 0, 0, 0);
32017 zFilename = malloc( nByte );
32018 if( zFilename==0 ){
32019 return 0;
32021 nByte = WideCharToMultiByte(CP_UTF8, 0, zWideFilename, -1, zFilename, nByte,
32022 0, 0);
32023 if( nByte == 0 ){
32024 free(zFilename);
32025 zFilename = 0;
32027 return zFilename;
32031 ** Convert an ansi string to microsoft unicode, based on the
32032 ** current codepage settings for file apis.
32034 ** Space to hold the returned string is obtained
32035 ** from malloc.
32037 static WCHAR *mbcsToUnicode(const char *zFilename){
32038 int nByte;
32039 WCHAR *zMbcsFilename;
32040 int codepage = AreFileApisANSI() ? CP_ACP : CP_OEMCP;
32042 nByte = MultiByteToWideChar(codepage, 0, zFilename, -1, NULL,0)*sizeof(WCHAR);
32043 zMbcsFilename = malloc( nByte*sizeof(zMbcsFilename[0]) );
32044 if( zMbcsFilename==0 ){
32045 return 0;
32047 nByte = MultiByteToWideChar(codepage, 0, zFilename, -1, zMbcsFilename, nByte);
32048 if( nByte==0 ){
32049 free(zMbcsFilename);
32050 zMbcsFilename = 0;
32052 return zMbcsFilename;
32056 ** Convert microsoft unicode to multibyte character string, based on the
32057 ** user's Ansi codepage.
32059 ** Space to hold the returned string is obtained from
32060 ** malloc().
32062 static char *unicodeToMbcs(const WCHAR *zWideFilename){
32063 int nByte;
32064 char *zFilename;
32065 int codepage = AreFileApisANSI() ? CP_ACP : CP_OEMCP;
32067 nByte = WideCharToMultiByte(codepage, 0, zWideFilename, -1, 0, 0, 0, 0);
32068 zFilename = malloc( nByte );
32069 if( zFilename==0 ){
32070 return 0;
32072 nByte = WideCharToMultiByte(codepage, 0, zWideFilename, -1, zFilename, nByte,
32073 0, 0);
32074 if( nByte == 0 ){
32075 free(zFilename);
32076 zFilename = 0;
32078 return zFilename;
32082 ** Convert multibyte character string to UTF-8. Space to hold the
32083 ** returned string is obtained from malloc().
32085 SQLITE_API char *sqlite3_win32_mbcs_to_utf8(const char *zFilename){
32086 char *zFilenameUtf8;
32087 WCHAR *zTmpWide;
32089 zTmpWide = mbcsToUnicode(zFilename);
32090 if( zTmpWide==0 ){
32091 return 0;
32093 zFilenameUtf8 = unicodeToUtf8(zTmpWide);
32094 free(zTmpWide);
32095 return zFilenameUtf8;
32099 ** Convert UTF-8 to multibyte character string. Space to hold the
32100 ** returned string is obtained from malloc().
32102 SQLITE_API char *sqlite3_win32_utf8_to_mbcs(const char *zFilename){
32103 char *zFilenameMbcs;
32104 WCHAR *zTmpWide;
32106 zTmpWide = utf8ToUnicode(zFilename);
32107 if( zTmpWide==0 ){
32108 return 0;
32110 zFilenameMbcs = unicodeToMbcs(zTmpWide);
32111 free(zTmpWide);
32112 return zFilenameMbcs;
32117 ** The return value of getLastErrorMsg
32118 ** is zero if the error message fits in the buffer, or non-zero
32119 ** otherwise (if the message was truncated).
32121 static int getLastErrorMsg(int nBuf, char *zBuf){
32122 /* FormatMessage returns 0 on failure. Otherwise it
32123 ** returns the number of TCHARs written to the output
32124 ** buffer, excluding the terminating null char.
32126 DWORD error = GetLastError();
32127 DWORD dwLen = 0;
32128 char *zOut = 0;
32130 if( isNT() ){
32131 WCHAR *zTempWide = NULL;
32132 dwLen = FormatMessageW(FORMAT_MESSAGE_ALLOCATE_BUFFER | FORMAT_MESSAGE_FROM_SYSTEM | FORMAT_MESSAGE_IGNORE_INSERTS,
32133 NULL,
32134 error,
32136 (LPWSTR) &zTempWide,
32139 if( dwLen > 0 ){
32140 /* allocate a buffer and convert to UTF8 */
32141 zOut = unicodeToUtf8(zTempWide);
32142 /* free the system buffer allocated by FormatMessage */
32143 LocalFree(zTempWide);
32145 /* isNT() is 1 if SQLITE_OS_WINCE==1, so this else is never executed.
32146 ** Since the ASCII version of these Windows API do not exist for WINCE,
32147 ** it's important to not reference them for WINCE builds.
32149 #if SQLITE_OS_WINCE==0
32150 }else{
32151 char *zTemp = NULL;
32152 dwLen = FormatMessageA(FORMAT_MESSAGE_ALLOCATE_BUFFER | FORMAT_MESSAGE_FROM_SYSTEM | FORMAT_MESSAGE_IGNORE_INSERTS,
32153 NULL,
32154 error,
32156 (LPSTR) &zTemp,
32159 if( dwLen > 0 ){
32160 /* allocate a buffer and convert to UTF8 */
32161 zOut = sqlite3_win32_mbcs_to_utf8(zTemp);
32162 /* free the system buffer allocated by FormatMessage */
32163 LocalFree(zTemp);
32165 #endif
32167 if( 0 == dwLen ){
32168 sqlite3_snprintf(nBuf, zBuf, "OsError 0x%x (%u)", error, error);
32169 }else{
32170 /* copy a maximum of nBuf chars to output buffer */
32171 sqlite3_snprintf(nBuf, zBuf, "%s", zOut);
32172 /* free the UTF8 buffer */
32173 free(zOut);
32175 return 0;
32180 ** This function - winLogErrorAtLine() - is only ever called via the macro
32181 ** winLogError().
32183 ** This routine is invoked after an error occurs in an OS function.
32184 ** It logs a message using sqlite3_log() containing the current value of
32185 ** error code and, if possible, the human-readable equivalent from
32186 ** FormatMessage.
32188 ** The first argument passed to the macro should be the error code that
32189 ** will be returned to SQLite (e.g. SQLITE_IOERR_DELETE, SQLITE_CANTOPEN).
32190 ** The two subsequent arguments should be the name of the OS function that
32191 ** failed and the the associated file-system path, if any.
32193 #define winLogError(a,b,c) winLogErrorAtLine(a,b,c,__LINE__)
32194 static int winLogErrorAtLine(
32195 int errcode, /* SQLite error code */
32196 const char *zFunc, /* Name of OS function that failed */
32197 const char *zPath, /* File path associated with error */
32198 int iLine /* Source line number where error occurred */
32200 char zMsg[500]; /* Human readable error text */
32201 int i; /* Loop counter */
32202 DWORD iErrno = GetLastError(); /* Error code */
32204 zMsg[0] = 0;
32205 getLastErrorMsg(sizeof(zMsg), zMsg);
32206 assert( errcode!=SQLITE_OK );
32207 if( zPath==0 ) zPath = "";
32208 for(i=0; zMsg[i] && zMsg[i]!='\r' && zMsg[i]!='\n'; i++){}
32209 zMsg[i] = 0;
32210 sqlite3_log(errcode,
32211 "os_win.c:%d: (%d) %s(%s) - %s",
32212 iLine, iErrno, zFunc, zPath, zMsg
32215 return errcode;
32219 ** The number of times that a ReadFile(), WriteFile(), and DeleteFile()
32220 ** will be retried following a locking error - probably caused by
32221 ** antivirus software. Also the initial delay before the first retry.
32222 ** The delay increases linearly with each retry.
32224 #ifndef SQLITE_WIN32_IOERR_RETRY
32225 # define SQLITE_WIN32_IOERR_RETRY 10
32226 #endif
32227 #ifndef SQLITE_WIN32_IOERR_RETRY_DELAY
32228 # define SQLITE_WIN32_IOERR_RETRY_DELAY 25
32229 #endif
32230 static int win32IoerrRetry = SQLITE_WIN32_IOERR_RETRY;
32231 static int win32IoerrRetryDelay = SQLITE_WIN32_IOERR_RETRY_DELAY;
32234 ** If a ReadFile() or WriteFile() error occurs, invoke this routine
32235 ** to see if it should be retried. Return TRUE to retry. Return FALSE
32236 ** to give up with an error.
32238 static int retryIoerr(int *pnRetry){
32239 DWORD e;
32240 if( *pnRetry>=win32IoerrRetry ){
32241 return 0;
32243 e = GetLastError();
32244 if( e==ERROR_ACCESS_DENIED ||
32245 e==ERROR_LOCK_VIOLATION ||
32246 e==ERROR_SHARING_VIOLATION ){
32247 Sleep(win32IoerrRetryDelay*(1+*pnRetry));
32248 ++*pnRetry;
32249 return 1;
32251 return 0;
32255 ** Log a I/O error retry episode.
32257 static void logIoerr(int nRetry){
32258 if( nRetry ){
32259 sqlite3_log(SQLITE_IOERR,
32260 "delayed %dms for lock/sharing conflict",
32261 win32IoerrRetryDelay*nRetry*(nRetry+1)/2
32266 #if SQLITE_OS_WINCE
32267 /*************************************************************************
32268 ** This section contains code for WinCE only.
32271 ** WindowsCE does not have a localtime() function. So create a
32272 ** substitute.
32274 /* #include <time.h> */
32275 struct tm *__cdecl localtime(const time_t *t)
32277 static struct tm y;
32278 FILETIME uTm, lTm;
32279 SYSTEMTIME pTm;
32280 sqlite3_int64 t64;
32281 t64 = *t;
32282 t64 = (t64 + 11644473600)*10000000;
32283 uTm.dwLowDateTime = (DWORD)(t64 & 0xFFFFFFFF);
32284 uTm.dwHighDateTime= (DWORD)(t64 >> 32);
32285 FileTimeToLocalFileTime(&uTm,&lTm);
32286 FileTimeToSystemTime(&lTm,&pTm);
32287 y.tm_year = pTm.wYear - 1900;
32288 y.tm_mon = pTm.wMonth - 1;
32289 y.tm_wday = pTm.wDayOfWeek;
32290 y.tm_mday = pTm.wDay;
32291 y.tm_hour = pTm.wHour;
32292 y.tm_min = pTm.wMinute;
32293 y.tm_sec = pTm.wSecond;
32294 return &y;
32297 /* This will never be called, but defined to make the code compile */
32298 #define GetTempPathA(a,b)
32300 #define LockFile(a,b,c,d,e) winceLockFile(&a, b, c, d, e)
32301 #define UnlockFile(a,b,c,d,e) winceUnlockFile(&a, b, c, d, e)
32302 #define LockFileEx(a,b,c,d,e,f) winceLockFileEx(&a, b, c, d, e, f)
32304 #define HANDLE_TO_WINFILE(a) (winFile*)&((char*)a)[-(int)offsetof(winFile,h)]
32307 ** Acquire a lock on the handle h
32309 static void winceMutexAcquire(HANDLE h){
32310 DWORD dwErr;
32311 do {
32312 dwErr = WaitForSingleObject(h, INFINITE);
32313 } while (dwErr != WAIT_OBJECT_0 && dwErr != WAIT_ABANDONED);
32316 ** Release a lock acquired by winceMutexAcquire()
32318 #define winceMutexRelease(h) ReleaseMutex(h)
32321 ** Create the mutex and shared memory used for locking in the file
32322 ** descriptor pFile
32324 static BOOL winceCreateLock(const char *zFilename, winFile *pFile){
32325 WCHAR *zTok;
32326 WCHAR *zName = utf8ToUnicode(zFilename);
32327 BOOL bInit = TRUE;
32329 /* Initialize the local lockdata */
32330 ZeroMemory(&pFile->local, sizeof(pFile->local));
32332 /* Replace the backslashes from the filename and lowercase it
32333 ** to derive a mutex name. */
32334 zTok = CharLowerW(zName);
32335 for (;*zTok;zTok++){
32336 if (*zTok == '\\') *zTok = '_';
32339 /* Create/open the named mutex */
32340 pFile->hMutex = CreateMutexW(NULL, FALSE, zName);
32341 if (!pFile->hMutex){
32342 pFile->lastErrno = GetLastError();
32343 winLogError(SQLITE_ERROR, "winceCreateLock1", zFilename);
32344 free(zName);
32345 return FALSE;
32348 /* Acquire the mutex before continuing */
32349 winceMutexAcquire(pFile->hMutex);
32351 /* Since the names of named mutexes, semaphores, file mappings etc are
32352 ** case-sensitive, take advantage of that by uppercasing the mutex name
32353 ** and using that as the shared filemapping name.
32355 CharUpperW(zName);
32356 pFile->hShared = CreateFileMappingW(INVALID_HANDLE_VALUE, NULL,
32357 PAGE_READWRITE, 0, sizeof(winceLock),
32358 zName);
32360 /* Set a flag that indicates we're the first to create the memory so it
32361 ** must be zero-initialized */
32362 if (GetLastError() == ERROR_ALREADY_EXISTS){
32363 bInit = FALSE;
32366 free(zName);
32368 /* If we succeeded in making the shared memory handle, map it. */
32369 if (pFile->hShared){
32370 pFile->shared = (winceLock*)MapViewOfFile(pFile->hShared,
32371 FILE_MAP_READ|FILE_MAP_WRITE, 0, 0, sizeof(winceLock));
32372 /* If mapping failed, close the shared memory handle and erase it */
32373 if (!pFile->shared){
32374 pFile->lastErrno = GetLastError();
32375 winLogError(SQLITE_ERROR, "winceCreateLock2", zFilename);
32376 CloseHandle(pFile->hShared);
32377 pFile->hShared = NULL;
32381 /* If shared memory could not be created, then close the mutex and fail */
32382 if (pFile->hShared == NULL){
32383 winceMutexRelease(pFile->hMutex);
32384 CloseHandle(pFile->hMutex);
32385 pFile->hMutex = NULL;
32386 return FALSE;
32389 /* Initialize the shared memory if we're supposed to */
32390 if (bInit) {
32391 ZeroMemory(pFile->shared, sizeof(winceLock));
32394 winceMutexRelease(pFile->hMutex);
32395 return TRUE;
32399 ** Destroy the part of winFile that deals with wince locks
32401 static void winceDestroyLock(winFile *pFile){
32402 if (pFile->hMutex){
32403 /* Acquire the mutex */
32404 winceMutexAcquire(pFile->hMutex);
32406 /* The following blocks should probably assert in debug mode, but they
32407 are to cleanup in case any locks remained open */
32408 if (pFile->local.nReaders){
32409 pFile->shared->nReaders --;
32411 if (pFile->local.bReserved){
32412 pFile->shared->bReserved = FALSE;
32414 if (pFile->local.bPending){
32415 pFile->shared->bPending = FALSE;
32417 if (pFile->local.bExclusive){
32418 pFile->shared->bExclusive = FALSE;
32421 /* De-reference and close our copy of the shared memory handle */
32422 UnmapViewOfFile(pFile->shared);
32423 CloseHandle(pFile->hShared);
32425 /* Done with the mutex */
32426 winceMutexRelease(pFile->hMutex);
32427 CloseHandle(pFile->hMutex);
32428 pFile->hMutex = NULL;
32433 ** An implementation of the LockFile() API of windows for wince
32435 static BOOL winceLockFile(
32436 HANDLE *phFile,
32437 DWORD dwFileOffsetLow,
32438 DWORD dwFileOffsetHigh,
32439 DWORD nNumberOfBytesToLockLow,
32440 DWORD nNumberOfBytesToLockHigh
32442 winFile *pFile = HANDLE_TO_WINFILE(phFile);
32443 BOOL bReturn = FALSE;
32445 UNUSED_PARAMETER(dwFileOffsetHigh);
32446 UNUSED_PARAMETER(nNumberOfBytesToLockHigh);
32448 if (!pFile->hMutex) return TRUE;
32449 winceMutexAcquire(pFile->hMutex);
32451 /* Wanting an exclusive lock? */
32452 if (dwFileOffsetLow == (DWORD)SHARED_FIRST
32453 && nNumberOfBytesToLockLow == (DWORD)SHARED_SIZE){
32454 if (pFile->shared->nReaders == 0 && pFile->shared->bExclusive == 0){
32455 pFile->shared->bExclusive = TRUE;
32456 pFile->local.bExclusive = TRUE;
32457 bReturn = TRUE;
32461 /* Want a read-only lock? */
32462 else if (dwFileOffsetLow == (DWORD)SHARED_FIRST &&
32463 nNumberOfBytesToLockLow == 1){
32464 if (pFile->shared->bExclusive == 0){
32465 pFile->local.nReaders ++;
32466 if (pFile->local.nReaders == 1){
32467 pFile->shared->nReaders ++;
32469 bReturn = TRUE;
32473 /* Want a pending lock? */
32474 else if (dwFileOffsetLow == (DWORD)PENDING_BYTE && nNumberOfBytesToLockLow == 1){
32475 /* If no pending lock has been acquired, then acquire it */
32476 if (pFile->shared->bPending == 0) {
32477 pFile->shared->bPending = TRUE;
32478 pFile->local.bPending = TRUE;
32479 bReturn = TRUE;
32483 /* Want a reserved lock? */
32484 else if (dwFileOffsetLow == (DWORD)RESERVED_BYTE && nNumberOfBytesToLockLow == 1){
32485 if (pFile->shared->bReserved == 0) {
32486 pFile->shared->bReserved = TRUE;
32487 pFile->local.bReserved = TRUE;
32488 bReturn = TRUE;
32492 winceMutexRelease(pFile->hMutex);
32493 return bReturn;
32497 ** An implementation of the UnlockFile API of windows for wince
32499 static BOOL winceUnlockFile(
32500 HANDLE *phFile,
32501 DWORD dwFileOffsetLow,
32502 DWORD dwFileOffsetHigh,
32503 DWORD nNumberOfBytesToUnlockLow,
32504 DWORD nNumberOfBytesToUnlockHigh
32506 winFile *pFile = HANDLE_TO_WINFILE(phFile);
32507 BOOL bReturn = FALSE;
32509 UNUSED_PARAMETER(dwFileOffsetHigh);
32510 UNUSED_PARAMETER(nNumberOfBytesToUnlockHigh);
32512 if (!pFile->hMutex) return TRUE;
32513 winceMutexAcquire(pFile->hMutex);
32515 /* Releasing a reader lock or an exclusive lock */
32516 if (dwFileOffsetLow == (DWORD)SHARED_FIRST){
32517 /* Did we have an exclusive lock? */
32518 if (pFile->local.bExclusive){
32519 assert(nNumberOfBytesToUnlockLow == (DWORD)SHARED_SIZE);
32520 pFile->local.bExclusive = FALSE;
32521 pFile->shared->bExclusive = FALSE;
32522 bReturn = TRUE;
32525 /* Did we just have a reader lock? */
32526 else if (pFile->local.nReaders){
32527 assert(nNumberOfBytesToUnlockLow == (DWORD)SHARED_SIZE || nNumberOfBytesToUnlockLow == 1);
32528 pFile->local.nReaders --;
32529 if (pFile->local.nReaders == 0)
32531 pFile->shared->nReaders --;
32533 bReturn = TRUE;
32537 /* Releasing a pending lock */
32538 else if (dwFileOffsetLow == (DWORD)PENDING_BYTE && nNumberOfBytesToUnlockLow == 1){
32539 if (pFile->local.bPending){
32540 pFile->local.bPending = FALSE;
32541 pFile->shared->bPending = FALSE;
32542 bReturn = TRUE;
32545 /* Releasing a reserved lock */
32546 else if (dwFileOffsetLow == (DWORD)RESERVED_BYTE && nNumberOfBytesToUnlockLow == 1){
32547 if (pFile->local.bReserved) {
32548 pFile->local.bReserved = FALSE;
32549 pFile->shared->bReserved = FALSE;
32550 bReturn = TRUE;
32554 winceMutexRelease(pFile->hMutex);
32555 return bReturn;
32559 ** An implementation of the LockFileEx() API of windows for wince
32561 static BOOL winceLockFileEx(
32562 HANDLE *phFile,
32563 DWORD dwFlags,
32564 DWORD dwReserved,
32565 DWORD nNumberOfBytesToLockLow,
32566 DWORD nNumberOfBytesToLockHigh,
32567 LPOVERLAPPED lpOverlapped
32569 UNUSED_PARAMETER(dwReserved);
32570 UNUSED_PARAMETER(nNumberOfBytesToLockHigh);
32572 /* If the caller wants a shared read lock, forward this call
32573 ** to winceLockFile */
32574 if (lpOverlapped->Offset == (DWORD)SHARED_FIRST &&
32575 dwFlags == 1 &&
32576 nNumberOfBytesToLockLow == (DWORD)SHARED_SIZE){
32577 return winceLockFile(phFile, SHARED_FIRST, 0, 1, 0);
32579 return FALSE;
32582 ** End of the special code for wince
32583 *****************************************************************************/
32584 #endif /* SQLITE_OS_WINCE */
32586 /*****************************************************************************
32587 ** The next group of routines implement the I/O methods specified
32588 ** by the sqlite3_io_methods object.
32589 ******************************************************************************/
32592 ** Some microsoft compilers lack this definition.
32594 #ifndef INVALID_SET_FILE_POINTER
32595 # define INVALID_SET_FILE_POINTER ((DWORD)-1)
32596 #endif
32599 ** Move the current position of the file handle passed as the first
32600 ** argument to offset iOffset within the file. If successful, return 0.
32601 ** Otherwise, set pFile->lastErrno and return non-zero.
32603 static int seekWinFile(winFile *pFile, sqlite3_int64 iOffset){
32604 LONG upperBits; /* Most sig. 32 bits of new offset */
32605 LONG lowerBits; /* Least sig. 32 bits of new offset */
32606 DWORD dwRet; /* Value returned by SetFilePointer() */
32608 upperBits = (LONG)((iOffset>>32) & 0x7fffffff);
32609 lowerBits = (LONG)(iOffset & 0xffffffff);
32611 /* API oddity: If successful, SetFilePointer() returns a dword
32612 ** containing the lower 32-bits of the new file-offset. Or, if it fails,
32613 ** it returns INVALID_SET_FILE_POINTER. However according to MSDN,
32614 ** INVALID_SET_FILE_POINTER may also be a valid new offset. So to determine
32615 ** whether an error has actually occured, it is also necessary to call
32616 ** GetLastError().
32618 dwRet = SetFilePointer(pFile->h, lowerBits, &upperBits, FILE_BEGIN);
32619 if( (dwRet==INVALID_SET_FILE_POINTER && GetLastError()!=NO_ERROR) ){
32620 pFile->lastErrno = GetLastError();
32621 winLogError(SQLITE_IOERR_SEEK, "seekWinFile", pFile->zPath);
32622 return 1;
32625 return 0;
32629 ** Close a file.
32631 ** It is reported that an attempt to close a handle might sometimes
32632 ** fail. This is a very unreasonable result, but windows is notorious
32633 ** for being unreasonable so I do not doubt that it might happen. If
32634 ** the close fails, we pause for 100 milliseconds and try again. As
32635 ** many as MX_CLOSE_ATTEMPT attempts to close the handle are made before
32636 ** giving up and returning an error.
32638 #define MX_CLOSE_ATTEMPT 3
32639 static int winClose(sqlite3_file *id){
32640 int rc, cnt = 0;
32641 winFile *pFile = (winFile*)id;
32643 assert( id!=0 );
32644 assert( pFile->pShm==0 );
32645 OSTRACE(("CLOSE %d\n", pFile->h));
32647 rc = CloseHandle(pFile->h);
32648 /* SimulateIOError( rc=0; cnt=MX_CLOSE_ATTEMPT; ); */
32649 }while( rc==0 && ++cnt < MX_CLOSE_ATTEMPT && (Sleep(100), 1) );
32650 #if SQLITE_OS_WINCE
32651 #define WINCE_DELETION_ATTEMPTS 3
32652 winceDestroyLock(pFile);
32653 if( pFile->zDeleteOnClose ){
32654 int cnt = 0;
32655 while(
32656 DeleteFileW(pFile->zDeleteOnClose)==0
32657 && GetFileAttributesW(pFile->zDeleteOnClose)!=0xffffffff
32658 && cnt++ < WINCE_DELETION_ATTEMPTS
32660 Sleep(100); /* Wait a little before trying again */
32662 free(pFile->zDeleteOnClose);
32664 #endif
32665 OSTRACE(("CLOSE %d %s\n", pFile->h, rc ? "ok" : "failed"));
32666 OpenCounter(-1);
32667 return rc ? SQLITE_OK
32668 : winLogError(SQLITE_IOERR_CLOSE, "winClose", pFile->zPath);
32672 ** Read data from a file into a buffer. Return SQLITE_OK if all
32673 ** bytes were read successfully and SQLITE_IOERR if anything goes
32674 ** wrong.
32676 static int winRead(
32677 sqlite3_file *id, /* File to read from */
32678 void *pBuf, /* Write content into this buffer */
32679 int amt, /* Number of bytes to read */
32680 sqlite3_int64 offset /* Begin reading at this offset */
32682 winFile *pFile = (winFile*)id; /* file handle */
32683 DWORD nRead; /* Number of bytes actually read from file */
32684 int nRetry = 0; /* Number of retrys */
32686 assert( id!=0 );
32687 SimulateIOError(return SQLITE_IOERR_READ);
32688 OSTRACE(("READ %d lock=%d\n", pFile->h, pFile->locktype));
32690 if( seekWinFile(pFile, offset) ){
32691 return SQLITE_FULL;
32693 while( !ReadFile(pFile->h, pBuf, amt, &nRead, 0) ){
32694 if( retryIoerr(&nRetry) ) continue;
32695 pFile->lastErrno = GetLastError();
32696 return winLogError(SQLITE_IOERR_READ, "winRead", pFile->zPath);
32698 logIoerr(nRetry);
32699 if( nRead<(DWORD)amt ){
32700 /* Unread parts of the buffer must be zero-filled */
32701 memset(&((char*)pBuf)[nRead], 0, amt-nRead);
32702 return SQLITE_IOERR_SHORT_READ;
32705 return SQLITE_OK;
32709 ** Write data from a buffer into a file. Return SQLITE_OK on success
32710 ** or some other error code on failure.
32712 static int winWrite(
32713 sqlite3_file *id, /* File to write into */
32714 const void *pBuf, /* The bytes to be written */
32715 int amt, /* Number of bytes to write */
32716 sqlite3_int64 offset /* Offset into the file to begin writing at */
32718 int rc; /* True if error has occured, else false */
32719 winFile *pFile = (winFile*)id; /* File handle */
32720 int nRetry = 0; /* Number of retries */
32722 assert( amt>0 );
32723 assert( pFile );
32724 SimulateIOError(return SQLITE_IOERR_WRITE);
32725 SimulateDiskfullError(return SQLITE_FULL);
32727 OSTRACE(("WRITE %d lock=%d\n", pFile->h, pFile->locktype));
32729 rc = seekWinFile(pFile, offset);
32730 if( rc==0 ){
32731 u8 *aRem = (u8 *)pBuf; /* Data yet to be written */
32732 int nRem = amt; /* Number of bytes yet to be written */
32733 DWORD nWrite; /* Bytes written by each WriteFile() call */
32735 while( nRem>0 ){
32736 if( !WriteFile(pFile->h, aRem, nRem, &nWrite, 0) ){
32737 if( retryIoerr(&nRetry) ) continue;
32738 break;
32740 if( nWrite<=0 ) break;
32741 aRem += nWrite;
32742 nRem -= nWrite;
32744 if( nRem>0 ){
32745 pFile->lastErrno = GetLastError();
32746 rc = 1;
32750 if( rc ){
32751 if( ( pFile->lastErrno==ERROR_HANDLE_DISK_FULL )
32752 || ( pFile->lastErrno==ERROR_DISK_FULL )){
32753 return SQLITE_FULL;
32755 return winLogError(SQLITE_IOERR_WRITE, "winWrite", pFile->zPath);
32756 }else{
32757 logIoerr(nRetry);
32759 return SQLITE_OK;
32763 ** Truncate an open file to a specified size
32765 static int winTruncate(sqlite3_file *id, sqlite3_int64 nByte){
32766 winFile *pFile = (winFile*)id; /* File handle object */
32767 int rc = SQLITE_OK; /* Return code for this function */
32769 assert( pFile );
32771 OSTRACE(("TRUNCATE %d %lld\n", pFile->h, nByte));
32772 SimulateIOError(return SQLITE_IOERR_TRUNCATE);
32774 /* If the user has configured a chunk-size for this file, truncate the
32775 ** file so that it consists of an integer number of chunks (i.e. the
32776 ** actual file size after the operation may be larger than the requested
32777 ** size).
32779 if( pFile->szChunk>0 ){
32780 nByte = ((nByte + pFile->szChunk - 1)/pFile->szChunk) * pFile->szChunk;
32783 /* SetEndOfFile() returns non-zero when successful, or zero when it fails. */
32784 if( seekWinFile(pFile, nByte) ){
32785 rc = winLogError(SQLITE_IOERR_TRUNCATE, "winTruncate1", pFile->zPath);
32786 }else if( 0==SetEndOfFile(pFile->h) ){
32787 pFile->lastErrno = GetLastError();
32788 rc = winLogError(SQLITE_IOERR_TRUNCATE, "winTruncate2", pFile->zPath);
32791 OSTRACE(("TRUNCATE %d %lld %s\n", pFile->h, nByte, rc ? "failed" : "ok"));
32792 return rc;
32795 #ifdef SQLITE_TEST
32797 ** Count the number of fullsyncs and normal syncs. This is used to test
32798 ** that syncs and fullsyncs are occuring at the right times.
32800 SQLITE_API int sqlite3_sync_count = 0;
32801 SQLITE_API int sqlite3_fullsync_count = 0;
32802 #endif
32805 ** Make sure all writes to a particular file are committed to disk.
32807 static int winSync(sqlite3_file *id, int flags){
32808 #ifndef SQLITE_NO_SYNC
32810 ** Used only when SQLITE_NO_SYNC is not defined.
32812 BOOL rc;
32813 #endif
32814 #if !defined(NDEBUG) || !defined(SQLITE_NO_SYNC) || \
32815 (defined(SQLITE_TEST) && defined(SQLITE_DEBUG))
32817 ** Used when SQLITE_NO_SYNC is not defined and by the assert() and/or
32818 ** OSTRACE() macros.
32820 winFile *pFile = (winFile*)id;
32821 #else
32822 UNUSED_PARAMETER(id);
32823 #endif
32825 assert( pFile );
32826 /* Check that one of SQLITE_SYNC_NORMAL or FULL was passed */
32827 assert((flags&0x0F)==SQLITE_SYNC_NORMAL
32828 || (flags&0x0F)==SQLITE_SYNC_FULL
32831 OSTRACE(("SYNC %d lock=%d\n", pFile->h, pFile->locktype));
32833 /* Unix cannot, but some systems may return SQLITE_FULL from here. This
32834 ** line is to test that doing so does not cause any problems.
32836 SimulateDiskfullError( return SQLITE_FULL );
32838 #ifndef SQLITE_TEST
32839 UNUSED_PARAMETER(flags);
32840 #else
32841 if( (flags&0x0F)==SQLITE_SYNC_FULL ){
32842 sqlite3_fullsync_count++;
32844 sqlite3_sync_count++;
32845 #endif
32847 /* If we compiled with the SQLITE_NO_SYNC flag, then syncing is a
32848 ** no-op
32850 #ifdef SQLITE_NO_SYNC
32851 return SQLITE_OK;
32852 #else
32853 rc = FlushFileBuffers(pFile->h);
32854 SimulateIOError( rc=FALSE );
32855 if( rc ){
32856 return SQLITE_OK;
32857 }else{
32858 pFile->lastErrno = GetLastError();
32859 return winLogError(SQLITE_IOERR_FSYNC, "winSync", pFile->zPath);
32861 #endif
32865 ** Determine the current size of a file in bytes
32867 static int winFileSize(sqlite3_file *id, sqlite3_int64 *pSize){
32868 DWORD upperBits;
32869 DWORD lowerBits;
32870 winFile *pFile = (winFile*)id;
32871 DWORD error;
32873 assert( id!=0 );
32874 SimulateIOError(return SQLITE_IOERR_FSTAT);
32875 lowerBits = GetFileSize(pFile->h, &upperBits);
32876 if( (lowerBits == INVALID_FILE_SIZE)
32877 && ((error = GetLastError()) != NO_ERROR) )
32879 pFile->lastErrno = error;
32880 return winLogError(SQLITE_IOERR_FSTAT, "winFileSize", pFile->zPath);
32882 *pSize = (((sqlite3_int64)upperBits)<<32) + lowerBits;
32883 return SQLITE_OK;
32887 ** LOCKFILE_FAIL_IMMEDIATELY is undefined on some Windows systems.
32889 #ifndef LOCKFILE_FAIL_IMMEDIATELY
32890 # define LOCKFILE_FAIL_IMMEDIATELY 1
32891 #endif
32894 ** Acquire a reader lock.
32895 ** Different API routines are called depending on whether or not this
32896 ** is Win95 or WinNT.
32898 static int getReadLock(winFile *pFile){
32899 int res;
32900 if( isNT() ){
32901 OVERLAPPED ovlp;
32902 ovlp.Offset = SHARED_FIRST;
32903 ovlp.OffsetHigh = 0;
32904 ovlp.hEvent = 0;
32905 res = LockFileEx(pFile->h, LOCKFILE_FAIL_IMMEDIATELY,
32906 0, SHARED_SIZE, 0, &ovlp);
32907 /* isNT() is 1 if SQLITE_OS_WINCE==1, so this else is never executed.
32909 #if SQLITE_OS_WINCE==0
32910 }else{
32911 int lk;
32912 sqlite3_randomness(sizeof(lk), &lk);
32913 pFile->sharedLockByte = (short)((lk & 0x7fffffff)%(SHARED_SIZE - 1));
32914 res = LockFile(pFile->h, SHARED_FIRST+pFile->sharedLockByte, 0, 1, 0);
32915 #endif
32917 if( res == 0 ){
32918 pFile->lastErrno = GetLastError();
32919 /* No need to log a failure to lock */
32921 return res;
32925 ** Undo a readlock
32927 static int unlockReadLock(winFile *pFile){
32928 int res;
32929 if( isNT() ){
32930 res = UnlockFile(pFile->h, SHARED_FIRST, 0, SHARED_SIZE, 0);
32931 /* isNT() is 1 if SQLITE_OS_WINCE==1, so this else is never executed.
32933 #if SQLITE_OS_WINCE==0
32934 }else{
32935 res = UnlockFile(pFile->h, SHARED_FIRST + pFile->sharedLockByte, 0, 1, 0);
32936 #endif
32938 if( res==0 && GetLastError()!=ERROR_NOT_LOCKED ){
32939 pFile->lastErrno = GetLastError();
32940 winLogError(SQLITE_IOERR_UNLOCK, "unlockReadLock", pFile->zPath);
32942 return res;
32946 ** Lock the file with the lock specified by parameter locktype - one
32947 ** of the following:
32949 ** (1) SHARED_LOCK
32950 ** (2) RESERVED_LOCK
32951 ** (3) PENDING_LOCK
32952 ** (4) EXCLUSIVE_LOCK
32954 ** Sometimes when requesting one lock state, additional lock states
32955 ** are inserted in between. The locking might fail on one of the later
32956 ** transitions leaving the lock state different from what it started but
32957 ** still short of its goal. The following chart shows the allowed
32958 ** transitions and the inserted intermediate states:
32960 ** UNLOCKED -> SHARED
32961 ** SHARED -> RESERVED
32962 ** SHARED -> (PENDING) -> EXCLUSIVE
32963 ** RESERVED -> (PENDING) -> EXCLUSIVE
32964 ** PENDING -> EXCLUSIVE
32966 ** This routine will only increase a lock. The winUnlock() routine
32967 ** erases all locks at once and returns us immediately to locking level 0.
32968 ** It is not possible to lower the locking level one step at a time. You
32969 ** must go straight to locking level 0.
32971 static int winLock(sqlite3_file *id, int locktype){
32972 int rc = SQLITE_OK; /* Return code from subroutines */
32973 int res = 1; /* Result of a windows lock call */
32974 int newLocktype; /* Set pFile->locktype to this value before exiting */
32975 int gotPendingLock = 0;/* True if we acquired a PENDING lock this time */
32976 winFile *pFile = (winFile*)id;
32977 DWORD error = NO_ERROR;
32979 assert( id!=0 );
32980 OSTRACE(("LOCK %d %d was %d(%d)\n",
32981 pFile->h, locktype, pFile->locktype, pFile->sharedLockByte));
32983 /* If there is already a lock of this type or more restrictive on the
32984 ** OsFile, do nothing. Don't use the end_lock: exit path, as
32985 ** sqlite3OsEnterMutex() hasn't been called yet.
32987 if( pFile->locktype>=locktype ){
32988 return SQLITE_OK;
32991 /* Make sure the locking sequence is correct
32993 assert( pFile->locktype!=NO_LOCK || locktype==SHARED_LOCK );
32994 assert( locktype!=PENDING_LOCK );
32995 assert( locktype!=RESERVED_LOCK || pFile->locktype==SHARED_LOCK );
32997 /* Lock the PENDING_LOCK byte if we need to acquire a PENDING lock or
32998 ** a SHARED lock. If we are acquiring a SHARED lock, the acquisition of
32999 ** the PENDING_LOCK byte is temporary.
33001 newLocktype = pFile->locktype;
33002 if( (pFile->locktype==NO_LOCK)
33003 || ( (locktype==EXCLUSIVE_LOCK)
33004 && (pFile->locktype==RESERVED_LOCK))
33006 int cnt = 3;
33007 while( cnt-->0 && (res = LockFile(pFile->h, PENDING_BYTE, 0, 1, 0))==0 ){
33008 /* Try 3 times to get the pending lock. The pending lock might be
33009 ** held by another reader process who will release it momentarily.
33011 OSTRACE(("could not get a PENDING lock. cnt=%d\n", cnt));
33012 Sleep(1);
33014 gotPendingLock = res;
33015 if( !res ){
33016 error = GetLastError();
33020 /* Acquire a shared lock
33022 if( locktype==SHARED_LOCK && res ){
33023 assert( pFile->locktype==NO_LOCK );
33024 res = getReadLock(pFile);
33025 if( res ){
33026 newLocktype = SHARED_LOCK;
33027 }else{
33028 error = GetLastError();
33032 /* Acquire a RESERVED lock
33034 if( locktype==RESERVED_LOCK && res ){
33035 assert( pFile->locktype==SHARED_LOCK );
33036 res = LockFile(pFile->h, RESERVED_BYTE, 0, 1, 0);
33037 if( res ){
33038 newLocktype = RESERVED_LOCK;
33039 }else{
33040 error = GetLastError();
33044 /* Acquire a PENDING lock
33046 if( locktype==EXCLUSIVE_LOCK && res ){
33047 newLocktype = PENDING_LOCK;
33048 gotPendingLock = 0;
33051 /* Acquire an EXCLUSIVE lock
33053 if( locktype==EXCLUSIVE_LOCK && res ){
33054 assert( pFile->locktype>=SHARED_LOCK );
33055 res = unlockReadLock(pFile);
33056 OSTRACE(("unreadlock = %d\n", res));
33057 res = LockFile(pFile->h, SHARED_FIRST, 0, SHARED_SIZE, 0);
33058 if( res ){
33059 newLocktype = EXCLUSIVE_LOCK;
33060 }else{
33061 error = GetLastError();
33062 OSTRACE(("error-code = %d\n", error));
33063 getReadLock(pFile);
33067 /* If we are holding a PENDING lock that ought to be released, then
33068 ** release it now.
33070 if( gotPendingLock && locktype==SHARED_LOCK ){
33071 UnlockFile(pFile->h, PENDING_BYTE, 0, 1, 0);
33074 /* Update the state of the lock has held in the file descriptor then
33075 ** return the appropriate result code.
33077 if( res ){
33078 rc = SQLITE_OK;
33079 }else{
33080 OSTRACE(("LOCK FAILED %d trying for %d but got %d\n", pFile->h,
33081 locktype, newLocktype));
33082 pFile->lastErrno = error;
33083 rc = SQLITE_BUSY;
33085 pFile->locktype = (u8)newLocktype;
33086 return rc;
33090 ** This routine checks if there is a RESERVED lock held on the specified
33091 ** file by this or any other process. If such a lock is held, return
33092 ** non-zero, otherwise zero.
33094 static int winCheckReservedLock(sqlite3_file *id, int *pResOut){
33095 int rc;
33096 winFile *pFile = (winFile*)id;
33098 SimulateIOError( return SQLITE_IOERR_CHECKRESERVEDLOCK; );
33100 assert( id!=0 );
33101 if( pFile->locktype>=RESERVED_LOCK ){
33102 rc = 1;
33103 OSTRACE(("TEST WR-LOCK %d %d (local)\n", pFile->h, rc));
33104 }else{
33105 rc = LockFile(pFile->h, RESERVED_BYTE, 0, 1, 0);
33106 if( rc ){
33107 UnlockFile(pFile->h, RESERVED_BYTE, 0, 1, 0);
33109 rc = !rc;
33110 OSTRACE(("TEST WR-LOCK %d %d (remote)\n", pFile->h, rc));
33112 *pResOut = rc;
33113 return SQLITE_OK;
33117 ** Lower the locking level on file descriptor id to locktype. locktype
33118 ** must be either NO_LOCK or SHARED_LOCK.
33120 ** If the locking level of the file descriptor is already at or below
33121 ** the requested locking level, this routine is a no-op.
33123 ** It is not possible for this routine to fail if the second argument
33124 ** is NO_LOCK. If the second argument is SHARED_LOCK then this routine
33125 ** might return SQLITE_IOERR;
33127 static int winUnlock(sqlite3_file *id, int locktype){
33128 int type;
33129 winFile *pFile = (winFile*)id;
33130 int rc = SQLITE_OK;
33131 assert( pFile!=0 );
33132 assert( locktype<=SHARED_LOCK );
33133 OSTRACE(("UNLOCK %d to %d was %d(%d)\n", pFile->h, locktype,
33134 pFile->locktype, pFile->sharedLockByte));
33135 type = pFile->locktype;
33136 if( type>=EXCLUSIVE_LOCK ){
33137 UnlockFile(pFile->h, SHARED_FIRST, 0, SHARED_SIZE, 0);
33138 if( locktype==SHARED_LOCK && !getReadLock(pFile) ){
33139 /* This should never happen. We should always be able to
33140 ** reacquire the read lock */
33141 rc = winLogError(SQLITE_IOERR_UNLOCK, "winUnlock", pFile->zPath);
33144 if( type>=RESERVED_LOCK ){
33145 UnlockFile(pFile->h, RESERVED_BYTE, 0, 1, 0);
33147 if( locktype==NO_LOCK && type>=SHARED_LOCK ){
33148 unlockReadLock(pFile);
33150 if( type>=PENDING_LOCK ){
33151 UnlockFile(pFile->h, PENDING_BYTE, 0, 1, 0);
33153 pFile->locktype = (u8)locktype;
33154 return rc;
33158 ** Control and query of the open file handle.
33160 static int winFileControl(sqlite3_file *id, int op, void *pArg){
33161 winFile *pFile = (winFile*)id;
33162 switch( op ){
33163 case SQLITE_FCNTL_LOCKSTATE: {
33164 *(int*)pArg = pFile->locktype;
33165 return SQLITE_OK;
33167 case SQLITE_LAST_ERRNO: {
33168 *(int*)pArg = (int)pFile->lastErrno;
33169 return SQLITE_OK;
33171 case SQLITE_FCNTL_CHUNK_SIZE: {
33172 pFile->szChunk = *(int *)pArg;
33173 return SQLITE_OK;
33175 case SQLITE_FCNTL_SIZE_HINT: {
33176 if( pFile->szChunk>0 ){
33177 sqlite3_int64 oldSz;
33178 int rc = winFileSize(id, &oldSz);
33179 if( rc==SQLITE_OK ){
33180 sqlite3_int64 newSz = *(sqlite3_int64*)pArg;
33181 if( newSz>oldSz ){
33182 SimulateIOErrorBenign(1);
33183 rc = winTruncate(id, newSz);
33184 SimulateIOErrorBenign(0);
33187 return rc;
33189 return SQLITE_OK;
33191 case SQLITE_FCNTL_PERSIST_WAL: {
33192 int bPersist = *(int*)pArg;
33193 if( bPersist<0 ){
33194 *(int*)pArg = pFile->bPersistWal;
33195 }else{
33196 pFile->bPersistWal = bPersist!=0;
33198 return SQLITE_OK;
33200 case SQLITE_FCNTL_SYNC_OMITTED: {
33201 return SQLITE_OK;
33203 case SQLITE_FCNTL_WIN32_AV_RETRY: {
33204 int *a = (int*)pArg;
33205 if( a[0]>0 ){
33206 win32IoerrRetry = a[0];
33207 }else{
33208 a[0] = win32IoerrRetry;
33210 if( a[1]>0 ){
33211 win32IoerrRetryDelay = a[1];
33212 }else{
33213 a[1] = win32IoerrRetryDelay;
33215 return SQLITE_OK;
33218 return SQLITE_NOTFOUND;
33222 ** Return the sector size in bytes of the underlying block device for
33223 ** the specified file. This is almost always 512 bytes, but may be
33224 ** larger for some devices.
33226 ** SQLite code assumes this function cannot fail. It also assumes that
33227 ** if two files are created in the same file-system directory (i.e.
33228 ** a database and its journal file) that the sector size will be the
33229 ** same for both.
33231 static int winSectorSize(sqlite3_file *id){
33232 assert( id!=0 );
33233 return (int)(((winFile*)id)->sectorSize);
33237 ** Return a vector of device characteristics.
33239 static int winDeviceCharacteristics(sqlite3_file *id){
33240 UNUSED_PARAMETER(id);
33241 return SQLITE_IOCAP_UNDELETABLE_WHEN_OPEN;
33244 #ifndef SQLITE_OMIT_WAL
33247 ** Windows will only let you create file view mappings
33248 ** on allocation size granularity boundaries.
33249 ** During sqlite3_os_init() we do a GetSystemInfo()
33250 ** to get the granularity size.
33252 SYSTEM_INFO winSysInfo;
33255 ** Helper functions to obtain and relinquish the global mutex. The
33256 ** global mutex is used to protect the winLockInfo objects used by
33257 ** this file, all of which may be shared by multiple threads.
33259 ** Function winShmMutexHeld() is used to assert() that the global mutex
33260 ** is held when required. This function is only used as part of assert()
33261 ** statements. e.g.
33263 ** winShmEnterMutex()
33264 ** assert( winShmMutexHeld() );
33265 ** winShmLeaveMutex()
33267 static void winShmEnterMutex(void){
33268 sqlite3_mutex_enter(sqlite3MutexAlloc(SQLITE_MUTEX_STATIC_MASTER));
33270 static void winShmLeaveMutex(void){
33271 sqlite3_mutex_leave(sqlite3MutexAlloc(SQLITE_MUTEX_STATIC_MASTER));
33273 #ifdef SQLITE_DEBUG
33274 static int winShmMutexHeld(void) {
33275 return sqlite3_mutex_held(sqlite3MutexAlloc(SQLITE_MUTEX_STATIC_MASTER));
33277 #endif
33280 ** Object used to represent a single file opened and mmapped to provide
33281 ** shared memory. When multiple threads all reference the same
33282 ** log-summary, each thread has its own winFile object, but they all
33283 ** point to a single instance of this object. In other words, each
33284 ** log-summary is opened only once per process.
33286 ** winShmMutexHeld() must be true when creating or destroying
33287 ** this object or while reading or writing the following fields:
33289 ** nRef
33290 ** pNext
33292 ** The following fields are read-only after the object is created:
33294 ** fid
33295 ** zFilename
33297 ** Either winShmNode.mutex must be held or winShmNode.nRef==0 and
33298 ** winShmMutexHeld() is true when reading or writing any other field
33299 ** in this structure.
33302 struct winShmNode {
33303 sqlite3_mutex *mutex; /* Mutex to access this object */
33304 char *zFilename; /* Name of the file */
33305 winFile hFile; /* File handle from winOpen */
33307 int szRegion; /* Size of shared-memory regions */
33308 int nRegion; /* Size of array apRegion */
33309 struct ShmRegion {
33310 HANDLE hMap; /* File handle from CreateFileMapping */
33311 void *pMap;
33312 } *aRegion;
33313 DWORD lastErrno; /* The Windows errno from the last I/O error */
33315 int nRef; /* Number of winShm objects pointing to this */
33316 winShm *pFirst; /* All winShm objects pointing to this */
33317 winShmNode *pNext; /* Next in list of all winShmNode objects */
33318 #ifdef SQLITE_DEBUG
33319 u8 nextShmId; /* Next available winShm.id value */
33320 #endif
33324 ** A global array of all winShmNode objects.
33326 ** The winShmMutexHeld() must be true while reading or writing this list.
33328 static winShmNode *winShmNodeList = 0;
33331 ** Structure used internally by this VFS to record the state of an
33332 ** open shared memory connection.
33334 ** The following fields are initialized when this object is created and
33335 ** are read-only thereafter:
33337 ** winShm.pShmNode
33338 ** winShm.id
33340 ** All other fields are read/write. The winShm.pShmNode->mutex must be held
33341 ** while accessing any read/write fields.
33343 struct winShm {
33344 winShmNode *pShmNode; /* The underlying winShmNode object */
33345 winShm *pNext; /* Next winShm with the same winShmNode */
33346 u8 hasMutex; /* True if holding the winShmNode mutex */
33347 u16 sharedMask; /* Mask of shared locks held */
33348 u16 exclMask; /* Mask of exclusive locks held */
33349 #ifdef SQLITE_DEBUG
33350 u8 id; /* Id of this connection with its winShmNode */
33351 #endif
33355 ** Constants used for locking
33357 #define WIN_SHM_BASE ((22+SQLITE_SHM_NLOCK)*4) /* first lock byte */
33358 #define WIN_SHM_DMS (WIN_SHM_BASE+SQLITE_SHM_NLOCK) /* deadman switch */
33361 ** Apply advisory locks for all n bytes beginning at ofst.
33363 #define _SHM_UNLCK 1
33364 #define _SHM_RDLCK 2
33365 #define _SHM_WRLCK 3
33366 static int winShmSystemLock(
33367 winShmNode *pFile, /* Apply locks to this open shared-memory segment */
33368 int lockType, /* _SHM_UNLCK, _SHM_RDLCK, or _SHM_WRLCK */
33369 int ofst, /* Offset to first byte to be locked/unlocked */
33370 int nByte /* Number of bytes to lock or unlock */
33372 OVERLAPPED ovlp;
33373 DWORD dwFlags;
33374 int rc = 0; /* Result code form Lock/UnlockFileEx() */
33376 /* Access to the winShmNode object is serialized by the caller */
33377 assert( sqlite3_mutex_held(pFile->mutex) || pFile->nRef==0 );
33379 /* Initialize the locking parameters */
33380 dwFlags = LOCKFILE_FAIL_IMMEDIATELY;
33381 if( lockType == _SHM_WRLCK ) dwFlags |= LOCKFILE_EXCLUSIVE_LOCK;
33383 memset(&ovlp, 0, sizeof(OVERLAPPED));
33384 ovlp.Offset = ofst;
33386 /* Release/Acquire the system-level lock */
33387 if( lockType==_SHM_UNLCK ){
33388 rc = UnlockFileEx(pFile->hFile.h, 0, nByte, 0, &ovlp);
33389 }else{
33390 rc = LockFileEx(pFile->hFile.h, dwFlags, 0, nByte, 0, &ovlp);
33393 if( rc!= 0 ){
33394 rc = SQLITE_OK;
33395 }else{
33396 pFile->lastErrno = GetLastError();
33397 rc = SQLITE_BUSY;
33400 OSTRACE(("SHM-LOCK %d %s %s 0x%08lx\n",
33401 pFile->hFile.h,
33402 rc==SQLITE_OK ? "ok" : "failed",
33403 lockType==_SHM_UNLCK ? "UnlockFileEx" : "LockFileEx",
33404 pFile->lastErrno));
33406 return rc;
33409 /* Forward references to VFS methods */
33410 static int winOpen(sqlite3_vfs*,const char*,sqlite3_file*,int,int*);
33411 static int winDelete(sqlite3_vfs *,const char*,int);
33414 ** Purge the winShmNodeList list of all entries with winShmNode.nRef==0.
33416 ** This is not a VFS shared-memory method; it is a utility function called
33417 ** by VFS shared-memory methods.
33419 static void winShmPurge(sqlite3_vfs *pVfs, int deleteFlag){
33420 winShmNode **pp;
33421 winShmNode *p;
33422 BOOL bRc;
33423 assert( winShmMutexHeld() );
33424 pp = &winShmNodeList;
33425 while( (p = *pp)!=0 ){
33426 if( p->nRef==0 ){
33427 int i;
33428 if( p->mutex ) sqlite3_mutex_free(p->mutex);
33429 for(i=0; i<p->nRegion; i++){
33430 bRc = UnmapViewOfFile(p->aRegion[i].pMap);
33431 OSTRACE(("SHM-PURGE pid-%d unmap region=%d %s\n",
33432 (int)GetCurrentProcessId(), i,
33433 bRc ? "ok" : "failed"));
33434 bRc = CloseHandle(p->aRegion[i].hMap);
33435 OSTRACE(("SHM-PURGE pid-%d close region=%d %s\n",
33436 (int)GetCurrentProcessId(), i,
33437 bRc ? "ok" : "failed"));
33439 if( p->hFile.h != INVALID_HANDLE_VALUE ){
33440 SimulateIOErrorBenign(1);
33441 winClose((sqlite3_file *)&p->hFile);
33442 SimulateIOErrorBenign(0);
33444 if( deleteFlag ){
33445 SimulateIOErrorBenign(1);
33446 winDelete(pVfs, p->zFilename, 0);
33447 SimulateIOErrorBenign(0);
33449 *pp = p->pNext;
33450 sqlite3_free(p->aRegion);
33451 sqlite3_free(p);
33452 }else{
33453 pp = &p->pNext;
33459 ** Open the shared-memory area associated with database file pDbFd.
33461 ** When opening a new shared-memory file, if no other instances of that
33462 ** file are currently open, in this process or in other processes, then
33463 ** the file must be truncated to zero length or have its header cleared.
33465 static int winOpenSharedMemory(winFile *pDbFd){
33466 struct winShm *p; /* The connection to be opened */
33467 struct winShmNode *pShmNode = 0; /* The underlying mmapped file */
33468 int rc; /* Result code */
33469 struct winShmNode *pNew; /* Newly allocated winShmNode */
33470 int nName; /* Size of zName in bytes */
33472 assert( pDbFd->pShm==0 ); /* Not previously opened */
33474 /* Allocate space for the new sqlite3_shm object. Also speculatively
33475 ** allocate space for a new winShmNode and filename.
33477 p = sqlite3_malloc( sizeof(*p) );
33478 if( p==0 ) return SQLITE_NOMEM;
33479 memset(p, 0, sizeof(*p));
33480 nName = sqlite3Strlen30(pDbFd->zPath);
33481 pNew = sqlite3_malloc( sizeof(*pShmNode) + nName + 15 );
33482 if( pNew==0 ){
33483 sqlite3_free(p);
33484 return SQLITE_NOMEM;
33486 memset(pNew, 0, sizeof(*pNew));
33487 pNew->zFilename = (char*)&pNew[1];
33488 sqlite3_snprintf(nName+15, pNew->zFilename, "%s-shm", pDbFd->zPath);
33489 sqlite3FileSuffix3(pDbFd->zPath, pNew->zFilename);
33491 /* Look to see if there is an existing winShmNode that can be used.
33492 ** If no matching winShmNode currently exists, create a new one.
33494 winShmEnterMutex();
33495 for(pShmNode = winShmNodeList; pShmNode; pShmNode=pShmNode->pNext){
33496 /* TBD need to come up with better match here. Perhaps
33497 ** use FILE_ID_BOTH_DIR_INFO Structure.
33499 if( sqlite3StrICmp(pShmNode->zFilename, pNew->zFilename)==0 ) break;
33501 if( pShmNode ){
33502 sqlite3_free(pNew);
33503 }else{
33504 pShmNode = pNew;
33505 pNew = 0;
33506 ((winFile*)(&pShmNode->hFile))->h = INVALID_HANDLE_VALUE;
33507 pShmNode->pNext = winShmNodeList;
33508 winShmNodeList = pShmNode;
33510 pShmNode->mutex = sqlite3_mutex_alloc(SQLITE_MUTEX_FAST);
33511 if( pShmNode->mutex==0 ){
33512 rc = SQLITE_NOMEM;
33513 goto shm_open_err;
33516 rc = winOpen(pDbFd->pVfs,
33517 pShmNode->zFilename, /* Name of the file (UTF-8) */
33518 (sqlite3_file*)&pShmNode->hFile, /* File handle here */
33519 SQLITE_OPEN_WAL | SQLITE_OPEN_READWRITE | SQLITE_OPEN_CREATE, /* Mode flags */
33521 if( SQLITE_OK!=rc ){
33522 rc = SQLITE_CANTOPEN_BKPT;
33523 goto shm_open_err;
33526 /* Check to see if another process is holding the dead-man switch.
33527 ** If not, truncate the file to zero length.
33529 if( winShmSystemLock(pShmNode, _SHM_WRLCK, WIN_SHM_DMS, 1)==SQLITE_OK ){
33530 rc = winTruncate((sqlite3_file *)&pShmNode->hFile, 0);
33531 if( rc!=SQLITE_OK ){
33532 rc = winLogError(SQLITE_IOERR_SHMOPEN, "winOpenShm", pDbFd->zPath);
33535 if( rc==SQLITE_OK ){
33536 winShmSystemLock(pShmNode, _SHM_UNLCK, WIN_SHM_DMS, 1);
33537 rc = winShmSystemLock(pShmNode, _SHM_RDLCK, WIN_SHM_DMS, 1);
33539 if( rc ) goto shm_open_err;
33542 /* Make the new connection a child of the winShmNode */
33543 p->pShmNode = pShmNode;
33544 #ifdef SQLITE_DEBUG
33545 p->id = pShmNode->nextShmId++;
33546 #endif
33547 pShmNode->nRef++;
33548 pDbFd->pShm = p;
33549 winShmLeaveMutex();
33551 /* The reference count on pShmNode has already been incremented under
33552 ** the cover of the winShmEnterMutex() mutex and the pointer from the
33553 ** new (struct winShm) object to the pShmNode has been set. All that is
33554 ** left to do is to link the new object into the linked list starting
33555 ** at pShmNode->pFirst. This must be done while holding the pShmNode->mutex
33556 ** mutex.
33558 sqlite3_mutex_enter(pShmNode->mutex);
33559 p->pNext = pShmNode->pFirst;
33560 pShmNode->pFirst = p;
33561 sqlite3_mutex_leave(pShmNode->mutex);
33562 return SQLITE_OK;
33564 /* Jump here on any error */
33565 shm_open_err:
33566 winShmSystemLock(pShmNode, _SHM_UNLCK, WIN_SHM_DMS, 1);
33567 winShmPurge(pDbFd->pVfs, 0); /* This call frees pShmNode if required */
33568 sqlite3_free(p);
33569 sqlite3_free(pNew);
33570 winShmLeaveMutex();
33571 return rc;
33575 ** Close a connection to shared-memory. Delete the underlying
33576 ** storage if deleteFlag is true.
33578 static int winShmUnmap(
33579 sqlite3_file *fd, /* Database holding shared memory */
33580 int deleteFlag /* Delete after closing if true */
33582 winFile *pDbFd; /* Database holding shared-memory */
33583 winShm *p; /* The connection to be closed */
33584 winShmNode *pShmNode; /* The underlying shared-memory file */
33585 winShm **pp; /* For looping over sibling connections */
33587 pDbFd = (winFile*)fd;
33588 p = pDbFd->pShm;
33589 if( p==0 ) return SQLITE_OK;
33590 pShmNode = p->pShmNode;
33592 /* Remove connection p from the set of connections associated
33593 ** with pShmNode */
33594 sqlite3_mutex_enter(pShmNode->mutex);
33595 for(pp=&pShmNode->pFirst; (*pp)!=p; pp = &(*pp)->pNext){}
33596 *pp = p->pNext;
33598 /* Free the connection p */
33599 sqlite3_free(p);
33600 pDbFd->pShm = 0;
33601 sqlite3_mutex_leave(pShmNode->mutex);
33603 /* If pShmNode->nRef has reached 0, then close the underlying
33604 ** shared-memory file, too */
33605 winShmEnterMutex();
33606 assert( pShmNode->nRef>0 );
33607 pShmNode->nRef--;
33608 if( pShmNode->nRef==0 ){
33609 winShmPurge(pDbFd->pVfs, deleteFlag);
33611 winShmLeaveMutex();
33613 return SQLITE_OK;
33617 ** Change the lock state for a shared-memory segment.
33619 static int winShmLock(
33620 sqlite3_file *fd, /* Database file holding the shared memory */
33621 int ofst, /* First lock to acquire or release */
33622 int n, /* Number of locks to acquire or release */
33623 int flags /* What to do with the lock */
33625 winFile *pDbFd = (winFile*)fd; /* Connection holding shared memory */
33626 winShm *p = pDbFd->pShm; /* The shared memory being locked */
33627 winShm *pX; /* For looping over all siblings */
33628 winShmNode *pShmNode = p->pShmNode;
33629 int rc = SQLITE_OK; /* Result code */
33630 u16 mask; /* Mask of locks to take or release */
33632 assert( ofst>=0 && ofst+n<=SQLITE_SHM_NLOCK );
33633 assert( n>=1 );
33634 assert( flags==(SQLITE_SHM_LOCK | SQLITE_SHM_SHARED)
33635 || flags==(SQLITE_SHM_LOCK | SQLITE_SHM_EXCLUSIVE)
33636 || flags==(SQLITE_SHM_UNLOCK | SQLITE_SHM_SHARED)
33637 || flags==(SQLITE_SHM_UNLOCK | SQLITE_SHM_EXCLUSIVE) );
33638 assert( n==1 || (flags & SQLITE_SHM_EXCLUSIVE)!=0 );
33640 mask = (u16)((1U<<(ofst+n)) - (1U<<ofst));
33641 assert( n>1 || mask==(1<<ofst) );
33642 sqlite3_mutex_enter(pShmNode->mutex);
33643 if( flags & SQLITE_SHM_UNLOCK ){
33644 u16 allMask = 0; /* Mask of locks held by siblings */
33646 /* See if any siblings hold this same lock */
33647 for(pX=pShmNode->pFirst; pX; pX=pX->pNext){
33648 if( pX==p ) continue;
33649 assert( (pX->exclMask & (p->exclMask|p->sharedMask))==0 );
33650 allMask |= pX->sharedMask;
33653 /* Unlock the system-level locks */
33654 if( (mask & allMask)==0 ){
33655 rc = winShmSystemLock(pShmNode, _SHM_UNLCK, ofst+WIN_SHM_BASE, n);
33656 }else{
33657 rc = SQLITE_OK;
33660 /* Undo the local locks */
33661 if( rc==SQLITE_OK ){
33662 p->exclMask &= ~mask;
33663 p->sharedMask &= ~mask;
33665 }else if( flags & SQLITE_SHM_SHARED ){
33666 u16 allShared = 0; /* Union of locks held by connections other than "p" */
33668 /* Find out which shared locks are already held by sibling connections.
33669 ** If any sibling already holds an exclusive lock, go ahead and return
33670 ** SQLITE_BUSY.
33672 for(pX=pShmNode->pFirst; pX; pX=pX->pNext){
33673 if( (pX->exclMask & mask)!=0 ){
33674 rc = SQLITE_BUSY;
33675 break;
33677 allShared |= pX->sharedMask;
33680 /* Get shared locks at the system level, if necessary */
33681 if( rc==SQLITE_OK ){
33682 if( (allShared & mask)==0 ){
33683 rc = winShmSystemLock(pShmNode, _SHM_RDLCK, ofst+WIN_SHM_BASE, n);
33684 }else{
33685 rc = SQLITE_OK;
33689 /* Get the local shared locks */
33690 if( rc==SQLITE_OK ){
33691 p->sharedMask |= mask;
33693 }else{
33694 /* Make sure no sibling connections hold locks that will block this
33695 ** lock. If any do, return SQLITE_BUSY right away.
33697 for(pX=pShmNode->pFirst; pX; pX=pX->pNext){
33698 if( (pX->exclMask & mask)!=0 || (pX->sharedMask & mask)!=0 ){
33699 rc = SQLITE_BUSY;
33700 break;
33704 /* Get the exclusive locks at the system level. Then if successful
33705 ** also mark the local connection as being locked.
33707 if( rc==SQLITE_OK ){
33708 rc = winShmSystemLock(pShmNode, _SHM_WRLCK, ofst+WIN_SHM_BASE, n);
33709 if( rc==SQLITE_OK ){
33710 assert( (p->sharedMask & mask)==0 );
33711 p->exclMask |= mask;
33715 sqlite3_mutex_leave(pShmNode->mutex);
33716 OSTRACE(("SHM-LOCK shmid-%d, pid-%d got %03x,%03x %s\n",
33717 p->id, (int)GetCurrentProcessId(), p->sharedMask, p->exclMask,
33718 rc ? "failed" : "ok"));
33719 return rc;
33723 ** Implement a memory barrier or memory fence on shared memory.
33725 ** All loads and stores begun before the barrier must complete before
33726 ** any load or store begun after the barrier.
33728 static void winShmBarrier(
33729 sqlite3_file *fd /* Database holding the shared memory */
33731 UNUSED_PARAMETER(fd);
33732 /* MemoryBarrier(); // does not work -- do not know why not */
33733 winShmEnterMutex();
33734 winShmLeaveMutex();
33738 ** This function is called to obtain a pointer to region iRegion of the
33739 ** shared-memory associated with the database file fd. Shared-memory regions
33740 ** are numbered starting from zero. Each shared-memory region is szRegion
33741 ** bytes in size.
33743 ** If an error occurs, an error code is returned and *pp is set to NULL.
33745 ** Otherwise, if the isWrite parameter is 0 and the requested shared-memory
33746 ** region has not been allocated (by any client, including one running in a
33747 ** separate process), then *pp is set to NULL and SQLITE_OK returned. If
33748 ** isWrite is non-zero and the requested shared-memory region has not yet
33749 ** been allocated, it is allocated by this function.
33751 ** If the shared-memory region has already been allocated or is allocated by
33752 ** this call as described above, then it is mapped into this processes
33753 ** address space (if it is not already), *pp is set to point to the mapped
33754 ** memory and SQLITE_OK returned.
33756 static int winShmMap(
33757 sqlite3_file *fd, /* Handle open on database file */
33758 int iRegion, /* Region to retrieve */
33759 int szRegion, /* Size of regions */
33760 int isWrite, /* True to extend file if necessary */
33761 void volatile **pp /* OUT: Mapped memory */
33763 winFile *pDbFd = (winFile*)fd;
33764 winShm *p = pDbFd->pShm;
33765 winShmNode *pShmNode;
33766 int rc = SQLITE_OK;
33768 if( !p ){
33769 rc = winOpenSharedMemory(pDbFd);
33770 if( rc!=SQLITE_OK ) return rc;
33771 p = pDbFd->pShm;
33773 pShmNode = p->pShmNode;
33775 sqlite3_mutex_enter(pShmNode->mutex);
33776 assert( szRegion==pShmNode->szRegion || pShmNode->nRegion==0 );
33778 if( pShmNode->nRegion<=iRegion ){
33779 struct ShmRegion *apNew; /* New aRegion[] array */
33780 int nByte = (iRegion+1)*szRegion; /* Minimum required file size */
33781 sqlite3_int64 sz; /* Current size of wal-index file */
33783 pShmNode->szRegion = szRegion;
33785 /* The requested region is not mapped into this processes address space.
33786 ** Check to see if it has been allocated (i.e. if the wal-index file is
33787 ** large enough to contain the requested region).
33789 rc = winFileSize((sqlite3_file *)&pShmNode->hFile, &sz);
33790 if( rc!=SQLITE_OK ){
33791 rc = winLogError(SQLITE_IOERR_SHMSIZE, "winShmMap1", pDbFd->zPath);
33792 goto shmpage_out;
33795 if( sz<nByte ){
33796 /* The requested memory region does not exist. If isWrite is set to
33797 ** zero, exit early. *pp will be set to NULL and SQLITE_OK returned.
33799 ** Alternatively, if isWrite is non-zero, use ftruncate() to allocate
33800 ** the requested memory region.
33802 if( !isWrite ) goto shmpage_out;
33803 rc = winTruncate((sqlite3_file *)&pShmNode->hFile, nByte);
33804 if( rc!=SQLITE_OK ){
33805 rc = winLogError(SQLITE_IOERR_SHMSIZE, "winShmMap2", pDbFd->zPath);
33806 goto shmpage_out;
33810 /* Map the requested memory region into this processes address space. */
33811 apNew = (struct ShmRegion *)sqlite3_realloc(
33812 pShmNode->aRegion, (iRegion+1)*sizeof(apNew[0])
33814 if( !apNew ){
33815 rc = SQLITE_IOERR_NOMEM;
33816 goto shmpage_out;
33818 pShmNode->aRegion = apNew;
33820 while( pShmNode->nRegion<=iRegion ){
33821 HANDLE hMap; /* file-mapping handle */
33822 void *pMap = 0; /* Mapped memory region */
33824 hMap = CreateFileMapping(pShmNode->hFile.h,
33825 NULL, PAGE_READWRITE, 0, nByte, NULL
33827 OSTRACE(("SHM-MAP pid-%d create region=%d nbyte=%d %s\n",
33828 (int)GetCurrentProcessId(), pShmNode->nRegion, nByte,
33829 hMap ? "ok" : "failed"));
33830 if( hMap ){
33831 int iOffset = pShmNode->nRegion*szRegion;
33832 int iOffsetShift = iOffset % winSysInfo.dwAllocationGranularity;
33833 pMap = MapViewOfFile(hMap, FILE_MAP_WRITE | FILE_MAP_READ,
33834 0, iOffset - iOffsetShift, szRegion + iOffsetShift
33836 OSTRACE(("SHM-MAP pid-%d map region=%d offset=%d size=%d %s\n",
33837 (int)GetCurrentProcessId(), pShmNode->nRegion, iOffset, szRegion,
33838 pMap ? "ok" : "failed"));
33840 if( !pMap ){
33841 pShmNode->lastErrno = GetLastError();
33842 rc = winLogError(SQLITE_IOERR_SHMMAP, "winShmMap3", pDbFd->zPath);
33843 if( hMap ) CloseHandle(hMap);
33844 goto shmpage_out;
33847 pShmNode->aRegion[pShmNode->nRegion].pMap = pMap;
33848 pShmNode->aRegion[pShmNode->nRegion].hMap = hMap;
33849 pShmNode->nRegion++;
33853 shmpage_out:
33854 if( pShmNode->nRegion>iRegion ){
33855 int iOffset = iRegion*szRegion;
33856 int iOffsetShift = iOffset % winSysInfo.dwAllocationGranularity;
33857 char *p = (char *)pShmNode->aRegion[iRegion].pMap;
33858 *pp = (void *)&p[iOffsetShift];
33859 }else{
33860 *pp = 0;
33862 sqlite3_mutex_leave(pShmNode->mutex);
33863 return rc;
33866 #else
33867 # define winShmMap 0
33868 # define winShmLock 0
33869 # define winShmBarrier 0
33870 # define winShmUnmap 0
33871 #endif /* #ifndef SQLITE_OMIT_WAL */
33874 ** Here ends the implementation of all sqlite3_file methods.
33876 ********************** End sqlite3_file Methods *******************************
33877 ******************************************************************************/
33880 ** This vector defines all the methods that can operate on an
33881 ** sqlite3_file for win32.
33883 static const sqlite3_io_methods winIoMethod = {
33884 2, /* iVersion */
33885 winClose, /* xClose */
33886 winRead, /* xRead */
33887 winWrite, /* xWrite */
33888 winTruncate, /* xTruncate */
33889 winSync, /* xSync */
33890 winFileSize, /* xFileSize */
33891 winLock, /* xLock */
33892 winUnlock, /* xUnlock */
33893 winCheckReservedLock, /* xCheckReservedLock */
33894 winFileControl, /* xFileControl */
33895 winSectorSize, /* xSectorSize */
33896 winDeviceCharacteristics, /* xDeviceCharacteristics */
33897 winShmMap, /* xShmMap */
33898 winShmLock, /* xShmLock */
33899 winShmBarrier, /* xShmBarrier */
33900 winShmUnmap /* xShmUnmap */
33903 /****************************************************************************
33904 **************************** sqlite3_vfs methods ****************************
33906 ** This division contains the implementation of methods on the
33907 ** sqlite3_vfs object.
33911 ** Convert a UTF-8 filename into whatever form the underlying
33912 ** operating system wants filenames in. Space to hold the result
33913 ** is obtained from malloc and must be freed by the calling
33914 ** function.
33916 static void *convertUtf8Filename(const char *zFilename){
33917 void *zConverted = 0;
33918 if( isNT() ){
33919 zConverted = utf8ToUnicode(zFilename);
33920 /* isNT() is 1 if SQLITE_OS_WINCE==1, so this else is never executed.
33922 #if SQLITE_OS_WINCE==0
33923 }else{
33924 zConverted = sqlite3_win32_utf8_to_mbcs(zFilename);
33925 #endif
33927 /* caller will handle out of memory */
33928 return zConverted;
33932 ** Create a temporary file name in zBuf. zBuf must be big enough to
33933 ** hold at pVfs->mxPathname characters.
33935 static int getTempname(int nBuf, char *zBuf){
33936 static char zChars[] =
33937 "abcdefghijklmnopqrstuvwxyz"
33938 "ABCDEFGHIJKLMNOPQRSTUVWXYZ"
33939 "0123456789";
33940 size_t i, j;
33941 char zTempPath[MAX_PATH+1];
33943 /* It's odd to simulate an io-error here, but really this is just
33944 ** using the io-error infrastructure to test that SQLite handles this
33945 ** function failing.
33947 SimulateIOError( return SQLITE_IOERR );
33949 if( sqlite3_temp_directory ){
33950 sqlite3_snprintf(MAX_PATH-30, zTempPath, "%s", sqlite3_temp_directory);
33951 }else if( isNT() ){
33952 char *zMulti;
33953 WCHAR zWidePath[MAX_PATH];
33954 GetTempPathW(MAX_PATH-30, zWidePath);
33955 zMulti = unicodeToUtf8(zWidePath);
33956 if( zMulti ){
33957 sqlite3_snprintf(MAX_PATH-30, zTempPath, "%s", zMulti);
33958 free(zMulti);
33959 }else{
33960 return SQLITE_NOMEM;
33962 /* isNT() is 1 if SQLITE_OS_WINCE==1, so this else is never executed.
33963 ** Since the ASCII version of these Windows API do not exist for WINCE,
33964 ** it's important to not reference them for WINCE builds.
33966 #if SQLITE_OS_WINCE==0
33967 }else{
33968 char *zUtf8;
33969 char zMbcsPath[MAX_PATH];
33970 GetTempPathA(MAX_PATH-30, zMbcsPath);
33971 zUtf8 = sqlite3_win32_mbcs_to_utf8(zMbcsPath);
33972 if( zUtf8 ){
33973 sqlite3_snprintf(MAX_PATH-30, zTempPath, "%s", zUtf8);
33974 free(zUtf8);
33975 }else{
33976 return SQLITE_NOMEM;
33978 #endif
33981 /* Check that the output buffer is large enough for the temporary file
33982 ** name. If it is not, return SQLITE_ERROR.
33984 if( (sqlite3Strlen30(zTempPath) + sqlite3Strlen30(SQLITE_TEMP_FILE_PREFIX) + 17) >= nBuf ){
33985 return SQLITE_ERROR;
33988 for(i=sqlite3Strlen30(zTempPath); i>0 && zTempPath[i-1]=='\\'; i--){}
33989 zTempPath[i] = 0;
33991 sqlite3_snprintf(nBuf-17, zBuf,
33992 "%s\\"SQLITE_TEMP_FILE_PREFIX, zTempPath);
33993 j = sqlite3Strlen30(zBuf);
33994 sqlite3_randomness(15, &zBuf[j]);
33995 for(i=0; i<15; i++, j++){
33996 zBuf[j] = (char)zChars[ ((unsigned char)zBuf[j])%(sizeof(zChars)-1) ];
33998 zBuf[j] = 0;
34000 OSTRACE(("TEMP FILENAME: %s\n", zBuf));
34001 return SQLITE_OK;
34005 ** Open a file.
34007 static int winOpen(
34008 sqlite3_vfs *pVfs, /* Not used */
34009 const char *zName, /* Name of the file (UTF-8) */
34010 sqlite3_file *id, /* Write the SQLite file handle here */
34011 int flags, /* Open mode flags */
34012 int *pOutFlags /* Status return flags */
34014 HANDLE h;
34015 DWORD dwDesiredAccess;
34016 DWORD dwShareMode;
34017 DWORD dwCreationDisposition;
34018 DWORD dwFlagsAndAttributes = 0;
34019 #if SQLITE_OS_WINCE
34020 int isTemp = 0;
34021 #endif
34022 winFile *pFile = (winFile*)id;
34023 void *zConverted; /* Filename in OS encoding */
34024 const char *zUtf8Name = zName; /* Filename in UTF-8 encoding */
34025 int cnt = 0;
34027 /* If argument zPath is a NULL pointer, this function is required to open
34028 ** a temporary file. Use this buffer to store the file name in.
34030 char zTmpname[MAX_PATH+1]; /* Buffer used to create temp filename */
34032 int rc = SQLITE_OK; /* Function Return Code */
34033 #if !defined(NDEBUG) || SQLITE_OS_WINCE
34034 int eType = flags&0xFFFFFF00; /* Type of file to open */
34035 #endif
34037 int isExclusive = (flags & SQLITE_OPEN_EXCLUSIVE);
34038 int isDelete = (flags & SQLITE_OPEN_DELETEONCLOSE);
34039 int isCreate = (flags & SQLITE_OPEN_CREATE);
34040 #ifndef NDEBUG
34041 int isReadonly = (flags & SQLITE_OPEN_READONLY);
34042 #endif
34043 int isReadWrite = (flags & SQLITE_OPEN_READWRITE);
34045 #ifndef NDEBUG
34046 int isOpenJournal = (isCreate && (
34047 eType==SQLITE_OPEN_MASTER_JOURNAL
34048 || eType==SQLITE_OPEN_MAIN_JOURNAL
34049 || eType==SQLITE_OPEN_WAL
34051 #endif
34053 /* Check the following statements are true:
34055 ** (a) Exactly one of the READWRITE and READONLY flags must be set, and
34056 ** (b) if CREATE is set, then READWRITE must also be set, and
34057 ** (c) if EXCLUSIVE is set, then CREATE must also be set.
34058 ** (d) if DELETEONCLOSE is set, then CREATE must also be set.
34060 assert((isReadonly==0 || isReadWrite==0) && (isReadWrite || isReadonly));
34061 assert(isCreate==0 || isReadWrite);
34062 assert(isExclusive==0 || isCreate);
34063 assert(isDelete==0 || isCreate);
34065 /* The main DB, main journal, WAL file and master journal are never
34066 ** automatically deleted. Nor are they ever temporary files. */
34067 assert( (!isDelete && zName) || eType!=SQLITE_OPEN_MAIN_DB );
34068 assert( (!isDelete && zName) || eType!=SQLITE_OPEN_MAIN_JOURNAL );
34069 assert( (!isDelete && zName) || eType!=SQLITE_OPEN_MASTER_JOURNAL );
34070 assert( (!isDelete && zName) || eType!=SQLITE_OPEN_WAL );
34072 /* Assert that the upper layer has set one of the "file-type" flags. */
34073 assert( eType==SQLITE_OPEN_MAIN_DB || eType==SQLITE_OPEN_TEMP_DB
34074 || eType==SQLITE_OPEN_MAIN_JOURNAL || eType==SQLITE_OPEN_TEMP_JOURNAL
34075 || eType==SQLITE_OPEN_SUBJOURNAL || eType==SQLITE_OPEN_MASTER_JOURNAL
34076 || eType==SQLITE_OPEN_TRANSIENT_DB || eType==SQLITE_OPEN_WAL
34079 assert( id!=0 );
34080 UNUSED_PARAMETER(pVfs);
34082 pFile->h = INVALID_HANDLE_VALUE;
34084 /* If the second argument to this function is NULL, generate a
34085 ** temporary file name to use
34087 if( !zUtf8Name ){
34088 assert(isDelete && !isOpenJournal);
34089 rc = getTempname(MAX_PATH+1, zTmpname);
34090 if( rc!=SQLITE_OK ){
34091 return rc;
34093 zUtf8Name = zTmpname;
34096 /* Convert the filename to the system encoding. */
34097 zConverted = convertUtf8Filename(zUtf8Name);
34098 if( zConverted==0 ){
34099 return SQLITE_NOMEM;
34102 if( isReadWrite ){
34103 dwDesiredAccess = GENERIC_READ | GENERIC_WRITE;
34104 }else{
34105 dwDesiredAccess = GENERIC_READ;
34108 /* SQLITE_OPEN_EXCLUSIVE is used to make sure that a new file is
34109 ** created. SQLite doesn't use it to indicate "exclusive access"
34110 ** as it is usually understood.
34112 if( isExclusive ){
34113 /* Creates a new file, only if it does not already exist. */
34114 /* If the file exists, it fails. */
34115 dwCreationDisposition = CREATE_NEW;
34116 }else if( isCreate ){
34117 /* Open existing file, or create if it doesn't exist */
34118 dwCreationDisposition = OPEN_ALWAYS;
34119 }else{
34120 /* Opens a file, only if it exists. */
34121 dwCreationDisposition = OPEN_EXISTING;
34124 dwShareMode = FILE_SHARE_READ | FILE_SHARE_WRITE;
34126 if( isDelete ){
34127 #if SQLITE_OS_WINCE
34128 dwFlagsAndAttributes = FILE_ATTRIBUTE_HIDDEN;
34129 isTemp = 1;
34130 #else
34131 dwFlagsAndAttributes = FILE_ATTRIBUTE_TEMPORARY
34132 | FILE_ATTRIBUTE_HIDDEN
34133 | FILE_FLAG_DELETE_ON_CLOSE;
34134 #endif
34135 }else{
34136 dwFlagsAndAttributes = FILE_ATTRIBUTE_NORMAL;
34138 /* Reports from the internet are that performance is always
34139 ** better if FILE_FLAG_RANDOM_ACCESS is used. Ticket #2699. */
34140 #if SQLITE_OS_WINCE
34141 dwFlagsAndAttributes |= FILE_FLAG_RANDOM_ACCESS;
34142 #endif
34144 if( isNT() ){
34145 while( (h = CreateFileW((WCHAR*)zConverted,
34146 dwDesiredAccess,
34147 dwShareMode, NULL,
34148 dwCreationDisposition,
34149 dwFlagsAndAttributes,
34150 NULL))==INVALID_HANDLE_VALUE &&
34151 retryIoerr(&cnt) ){}
34152 /* isNT() is 1 if SQLITE_OS_WINCE==1, so this else is never executed.
34153 ** Since the ASCII version of these Windows API do not exist for WINCE,
34154 ** it's important to not reference them for WINCE builds.
34156 #if SQLITE_OS_WINCE==0
34157 }else{
34158 while( (h = CreateFileA((char*)zConverted,
34159 dwDesiredAccess,
34160 dwShareMode, NULL,
34161 dwCreationDisposition,
34162 dwFlagsAndAttributes,
34163 NULL))==INVALID_HANDLE_VALUE &&
34164 retryIoerr(&cnt) ){}
34165 #endif
34168 logIoerr(cnt);
34170 OSTRACE(("OPEN %d %s 0x%lx %s\n",
34171 h, zName, dwDesiredAccess,
34172 h==INVALID_HANDLE_VALUE ? "failed" : "ok"));
34174 if( h==INVALID_HANDLE_VALUE ){
34175 pFile->lastErrno = GetLastError();
34176 winLogError(SQLITE_CANTOPEN, "winOpen", zUtf8Name);
34177 free(zConverted);
34178 if( isReadWrite ){
34179 return winOpen(pVfs, zName, id,
34180 ((flags|SQLITE_OPEN_READONLY)&~(SQLITE_OPEN_CREATE|SQLITE_OPEN_READWRITE)), pOutFlags);
34181 }else{
34182 return SQLITE_CANTOPEN_BKPT;
34186 if( pOutFlags ){
34187 if( isReadWrite ){
34188 *pOutFlags = SQLITE_OPEN_READWRITE;
34189 }else{
34190 *pOutFlags = SQLITE_OPEN_READONLY;
34194 memset(pFile, 0, sizeof(*pFile));
34195 pFile->pMethod = &winIoMethod;
34196 pFile->h = h;
34197 pFile->lastErrno = NO_ERROR;
34198 pFile->pVfs = pVfs;
34199 pFile->pShm = 0;
34200 pFile->zPath = zName;
34201 pFile->sectorSize = getSectorSize(pVfs, zUtf8Name);
34203 #if SQLITE_OS_WINCE
34204 if( isReadWrite && eType==SQLITE_OPEN_MAIN_DB
34205 && !winceCreateLock(zName, pFile)
34207 CloseHandle(h);
34208 free(zConverted);
34209 return SQLITE_CANTOPEN_BKPT;
34211 if( isTemp ){
34212 pFile->zDeleteOnClose = zConverted;
34213 }else
34214 #endif
34216 free(zConverted);
34219 OpenCounter(+1);
34220 return rc;
34224 ** Delete the named file.
34226 ** Note that windows does not allow a file to be deleted if some other
34227 ** process has it open. Sometimes a virus scanner or indexing program
34228 ** will open a journal file shortly after it is created in order to do
34229 ** whatever it does. While this other process is holding the
34230 ** file open, we will be unable to delete it. To work around this
34231 ** problem, we delay 100 milliseconds and try to delete again. Up
34232 ** to MX_DELETION_ATTEMPTs deletion attempts are run before giving
34233 ** up and returning an error.
34235 static int winDelete(
34236 sqlite3_vfs *pVfs, /* Not used on win32 */
34237 const char *zFilename, /* Name of file to delete */
34238 int syncDir /* Not used on win32 */
34240 int cnt = 0;
34241 int rc;
34242 void *zConverted;
34243 UNUSED_PARAMETER(pVfs);
34244 UNUSED_PARAMETER(syncDir);
34246 SimulateIOError(return SQLITE_IOERR_DELETE);
34247 zConverted = convertUtf8Filename(zFilename);
34248 if( zConverted==0 ){
34249 return SQLITE_NOMEM;
34251 if( isNT() ){
34252 rc = 1;
34253 while( GetFileAttributesW(zConverted)!=INVALID_FILE_ATTRIBUTES &&
34254 (rc = DeleteFileW(zConverted))==0 && retryIoerr(&cnt) ){}
34255 rc = rc ? SQLITE_OK : SQLITE_ERROR;
34256 /* isNT() is 1 if SQLITE_OS_WINCE==1, so this else is never executed.
34257 ** Since the ASCII version of these Windows API do not exist for WINCE,
34258 ** it's important to not reference them for WINCE builds.
34260 #if SQLITE_OS_WINCE==0
34261 }else{
34262 rc = 1;
34263 while( GetFileAttributesA(zConverted)!=INVALID_FILE_ATTRIBUTES &&
34264 (rc = DeleteFileA(zConverted))==0 && retryIoerr(&cnt) ){}
34265 rc = rc ? SQLITE_OK : SQLITE_ERROR;
34266 #endif
34268 if( rc ){
34269 rc = winLogError(SQLITE_IOERR_DELETE, "winDelete", zFilename);
34270 }else{
34271 logIoerr(cnt);
34273 free(zConverted);
34274 OSTRACE(("DELETE \"%s\" %s\n", zFilename, (rc ? "failed" : "ok" )));
34275 return rc;
34279 ** Check the existance and status of a file.
34281 static int winAccess(
34282 sqlite3_vfs *pVfs, /* Not used on win32 */
34283 const char *zFilename, /* Name of file to check */
34284 int flags, /* Type of test to make on this file */
34285 int *pResOut /* OUT: Result */
34287 DWORD attr;
34288 int rc = 0;
34289 void *zConverted;
34290 UNUSED_PARAMETER(pVfs);
34292 SimulateIOError( return SQLITE_IOERR_ACCESS; );
34293 zConverted = convertUtf8Filename(zFilename);
34294 if( zConverted==0 ){
34295 return SQLITE_NOMEM;
34297 if( isNT() ){
34298 int cnt = 0;
34299 WIN32_FILE_ATTRIBUTE_DATA sAttrData;
34300 memset(&sAttrData, 0, sizeof(sAttrData));
34301 while( !(rc = GetFileAttributesExW((WCHAR*)zConverted,
34302 GetFileExInfoStandard,
34303 &sAttrData)) && retryIoerr(&cnt) ){}
34304 if( rc ){
34305 /* For an SQLITE_ACCESS_EXISTS query, treat a zero-length file
34306 ** as if it does not exist.
34308 if( flags==SQLITE_ACCESS_EXISTS
34309 && sAttrData.nFileSizeHigh==0
34310 && sAttrData.nFileSizeLow==0 ){
34311 attr = INVALID_FILE_ATTRIBUTES;
34312 }else{
34313 attr = sAttrData.dwFileAttributes;
34315 }else{
34316 logIoerr(cnt);
34317 if( GetLastError()!=ERROR_FILE_NOT_FOUND ){
34318 winLogError(SQLITE_IOERR_ACCESS, "winAccess", zFilename);
34319 free(zConverted);
34320 return SQLITE_IOERR_ACCESS;
34321 }else{
34322 attr = INVALID_FILE_ATTRIBUTES;
34325 /* isNT() is 1 if SQLITE_OS_WINCE==1, so this else is never executed.
34326 ** Since the ASCII version of these Windows API do not exist for WINCE,
34327 ** it's important to not reference them for WINCE builds.
34329 #if SQLITE_OS_WINCE==0
34330 }else{
34331 attr = GetFileAttributesA((char*)zConverted);
34332 #endif
34334 free(zConverted);
34335 switch( flags ){
34336 case SQLITE_ACCESS_READ:
34337 case SQLITE_ACCESS_EXISTS:
34338 rc = attr!=INVALID_FILE_ATTRIBUTES;
34339 break;
34340 case SQLITE_ACCESS_READWRITE:
34341 rc = attr!=INVALID_FILE_ATTRIBUTES &&
34342 (attr & FILE_ATTRIBUTE_READONLY)==0;
34343 break;
34344 default:
34345 assert(!"Invalid flags argument");
34347 *pResOut = rc;
34348 return SQLITE_OK;
34353 ** Turn a relative pathname into a full pathname. Write the full
34354 ** pathname into zOut[]. zOut[] will be at least pVfs->mxPathname
34355 ** bytes in size.
34357 static int winFullPathname(
34358 sqlite3_vfs *pVfs, /* Pointer to vfs object */
34359 const char *zRelative, /* Possibly relative input path */
34360 int nFull, /* Size of output buffer in bytes */
34361 char *zFull /* Output buffer */
34364 #if defined(__CYGWIN__)
34365 SimulateIOError( return SQLITE_ERROR );
34366 UNUSED_PARAMETER(nFull);
34367 cygwin_conv_to_full_win32_path(zRelative, zFull);
34368 return SQLITE_OK;
34369 #endif
34371 #if SQLITE_OS_WINCE
34372 SimulateIOError( return SQLITE_ERROR );
34373 UNUSED_PARAMETER(nFull);
34374 /* WinCE has no concept of a relative pathname, or so I am told. */
34375 sqlite3_snprintf(pVfs->mxPathname, zFull, "%s", zRelative);
34376 return SQLITE_OK;
34377 #endif
34379 #if !SQLITE_OS_WINCE && !defined(__CYGWIN__)
34380 int nByte;
34381 void *zConverted;
34382 char *zOut;
34384 /* If this path name begins with "/X:", where "X" is any alphabetic
34385 ** character, discard the initial "/" from the pathname.
34387 if( zRelative[0]=='/' && sqlite3Isalpha(zRelative[1]) && zRelative[2]==':' ){
34388 zRelative++;
34391 /* It's odd to simulate an io-error here, but really this is just
34392 ** using the io-error infrastructure to test that SQLite handles this
34393 ** function failing. This function could fail if, for example, the
34394 ** current working directory has been unlinked.
34396 SimulateIOError( return SQLITE_ERROR );
34397 UNUSED_PARAMETER(nFull);
34398 zConverted = convertUtf8Filename(zRelative);
34399 if( isNT() ){
34400 WCHAR *zTemp;
34401 nByte = GetFullPathNameW((WCHAR*)zConverted, 0, 0, 0) + 3;
34402 zTemp = malloc( nByte*sizeof(zTemp[0]) );
34403 if( zTemp==0 ){
34404 free(zConverted);
34405 return SQLITE_NOMEM;
34407 GetFullPathNameW((WCHAR*)zConverted, nByte, zTemp, 0);
34408 free(zConverted);
34409 zOut = unicodeToUtf8(zTemp);
34410 free(zTemp);
34411 /* isNT() is 1 if SQLITE_OS_WINCE==1, so this else is never executed.
34412 ** Since the ASCII version of these Windows API do not exist for WINCE,
34413 ** it's important to not reference them for WINCE builds.
34415 #if SQLITE_OS_WINCE==0
34416 }else{
34417 char *zTemp;
34418 nByte = GetFullPathNameA((char*)zConverted, 0, 0, 0) + 3;
34419 zTemp = malloc( nByte*sizeof(zTemp[0]) );
34420 if( zTemp==0 ){
34421 free(zConverted);
34422 return SQLITE_NOMEM;
34424 GetFullPathNameA((char*)zConverted, nByte, zTemp, 0);
34425 free(zConverted);
34426 zOut = sqlite3_win32_mbcs_to_utf8(zTemp);
34427 free(zTemp);
34428 #endif
34430 if( zOut ){
34431 sqlite3_snprintf(pVfs->mxPathname, zFull, "%s", zOut);
34432 free(zOut);
34433 return SQLITE_OK;
34434 }else{
34435 return SQLITE_NOMEM;
34437 #endif
34441 ** Get the sector size of the device used to store
34442 ** file.
34444 static int getSectorSize(
34445 sqlite3_vfs *pVfs,
34446 const char *zRelative /* UTF-8 file name */
34448 DWORD bytesPerSector = SQLITE_DEFAULT_SECTOR_SIZE;
34449 /* GetDiskFreeSpace is not supported under WINCE */
34450 #if SQLITE_OS_WINCE
34451 UNUSED_PARAMETER(pVfs);
34452 UNUSED_PARAMETER(zRelative);
34453 #else
34454 char zFullpath[MAX_PATH+1];
34455 int rc;
34456 DWORD dwRet = 0;
34457 DWORD dwDummy;
34460 ** We need to get the full path name of the file
34461 ** to get the drive letter to look up the sector
34462 ** size.
34464 SimulateIOErrorBenign(1);
34465 rc = winFullPathname(pVfs, zRelative, MAX_PATH, zFullpath);
34466 SimulateIOErrorBenign(0);
34467 if( rc == SQLITE_OK )
34469 void *zConverted = convertUtf8Filename(zFullpath);
34470 if( zConverted ){
34471 if( isNT() ){
34472 /* trim path to just drive reference */
34473 WCHAR *p = zConverted;
34474 for(;*p;p++){
34475 if( *p == '\\' ){
34476 *p = '\0';
34477 break;
34480 dwRet = GetDiskFreeSpaceW((WCHAR*)zConverted,
34481 &dwDummy,
34482 &bytesPerSector,
34483 &dwDummy,
34484 &dwDummy);
34485 }else{
34486 /* trim path to just drive reference */
34487 char *p = (char *)zConverted;
34488 for(;*p;p++){
34489 if( *p == '\\' ){
34490 *p = '\0';
34491 break;
34494 dwRet = GetDiskFreeSpaceA((char*)zConverted,
34495 &dwDummy,
34496 &bytesPerSector,
34497 &dwDummy,
34498 &dwDummy);
34500 free(zConverted);
34502 if( !dwRet ){
34503 bytesPerSector = SQLITE_DEFAULT_SECTOR_SIZE;
34506 #endif
34507 return (int) bytesPerSector;
34510 #ifndef SQLITE_OMIT_LOAD_EXTENSION
34512 ** Interfaces for opening a shared library, finding entry points
34513 ** within the shared library, and closing the shared library.
34516 ** Interfaces for opening a shared library, finding entry points
34517 ** within the shared library, and closing the shared library.
34519 static void *winDlOpen(sqlite3_vfs *pVfs, const char *zFilename){
34520 HANDLE h;
34521 void *zConverted = convertUtf8Filename(zFilename);
34522 UNUSED_PARAMETER(pVfs);
34523 if( zConverted==0 ){
34524 return 0;
34526 if( isNT() ){
34527 h = LoadLibraryW((WCHAR*)zConverted);
34528 /* isNT() is 1 if SQLITE_OS_WINCE==1, so this else is never executed.
34529 ** Since the ASCII version of these Windows API do not exist for WINCE,
34530 ** it's important to not reference them for WINCE builds.
34532 #if SQLITE_OS_WINCE==0
34533 }else{
34534 h = LoadLibraryA((char*)zConverted);
34535 #endif
34537 free(zConverted);
34538 return (void*)h;
34540 static void winDlError(sqlite3_vfs *pVfs, int nBuf, char *zBufOut){
34541 UNUSED_PARAMETER(pVfs);
34542 getLastErrorMsg(nBuf, zBufOut);
34544 void (*winDlSym(sqlite3_vfs *pVfs, void *pHandle, const char *zSymbol))(void){
34545 UNUSED_PARAMETER(pVfs);
34546 #if SQLITE_OS_WINCE
34547 /* The GetProcAddressA() routine is only available on wince. */
34548 return (void(*)(void))GetProcAddressA((HANDLE)pHandle, zSymbol);
34549 #else
34550 /* All other windows platforms expect GetProcAddress() to take
34551 ** an Ansi string regardless of the _UNICODE setting */
34552 return (void(*)(void))GetProcAddress((HANDLE)pHandle, zSymbol);
34553 #endif
34555 void winDlClose(sqlite3_vfs *pVfs, void *pHandle){
34556 UNUSED_PARAMETER(pVfs);
34557 FreeLibrary((HANDLE)pHandle);
34559 #else /* if SQLITE_OMIT_LOAD_EXTENSION is defined: */
34560 #define winDlOpen 0
34561 #define winDlError 0
34562 #define winDlSym 0
34563 #define winDlClose 0
34564 #endif
34568 ** Write up to nBuf bytes of randomness into zBuf.
34570 static int winRandomness(sqlite3_vfs *pVfs, int nBuf, char *zBuf){
34571 int n = 0;
34572 UNUSED_PARAMETER(pVfs);
34573 #if defined(SQLITE_TEST)
34574 n = nBuf;
34575 memset(zBuf, 0, nBuf);
34576 #else
34577 if( sizeof(SYSTEMTIME)<=nBuf-n ){
34578 SYSTEMTIME x;
34579 GetSystemTime(&x);
34580 memcpy(&zBuf[n], &x, sizeof(x));
34581 n += sizeof(x);
34583 if( sizeof(DWORD)<=nBuf-n ){
34584 DWORD pid = GetCurrentProcessId();
34585 memcpy(&zBuf[n], &pid, sizeof(pid));
34586 n += sizeof(pid);
34588 if( sizeof(DWORD)<=nBuf-n ){
34589 DWORD cnt = GetTickCount();
34590 memcpy(&zBuf[n], &cnt, sizeof(cnt));
34591 n += sizeof(cnt);
34593 if( sizeof(LARGE_INTEGER)<=nBuf-n ){
34594 LARGE_INTEGER i;
34595 QueryPerformanceCounter(&i);
34596 memcpy(&zBuf[n], &i, sizeof(i));
34597 n += sizeof(i);
34599 #endif
34600 return n;
34605 ** Sleep for a little while. Return the amount of time slept.
34607 static int winSleep(sqlite3_vfs *pVfs, int microsec){
34608 Sleep((microsec+999)/1000);
34609 UNUSED_PARAMETER(pVfs);
34610 return ((microsec+999)/1000)*1000;
34614 ** The following variable, if set to a non-zero value, is interpreted as
34615 ** the number of seconds since 1970 and is used to set the result of
34616 ** sqlite3OsCurrentTime() during testing.
34618 #ifdef SQLITE_TEST
34619 SQLITE_API int sqlite3_current_time = 0; /* Fake system time in seconds since 1970. */
34620 #endif
34623 ** Find the current time (in Universal Coordinated Time). Write into *piNow
34624 ** the current time and date as a Julian Day number times 86_400_000. In
34625 ** other words, write into *piNow the number of milliseconds since the Julian
34626 ** epoch of noon in Greenwich on November 24, 4714 B.C according to the
34627 ** proleptic Gregorian calendar.
34629 ** On success, return 0. Return 1 if the time and date cannot be found.
34631 static int winCurrentTimeInt64(sqlite3_vfs *pVfs, sqlite3_int64 *piNow){
34632 /* FILETIME structure is a 64-bit value representing the number of
34633 100-nanosecond intervals since January 1, 1601 (= JD 2305813.5).
34635 FILETIME ft;
34636 static const sqlite3_int64 winFiletimeEpoch = 23058135*(sqlite3_int64)8640000;
34637 #ifdef SQLITE_TEST
34638 static const sqlite3_int64 unixEpoch = 24405875*(sqlite3_int64)8640000;
34639 #endif
34640 /* 2^32 - to avoid use of LL and warnings in gcc */
34641 static const sqlite3_int64 max32BitValue =
34642 (sqlite3_int64)2000000000 + (sqlite3_int64)2000000000 + (sqlite3_int64)294967296;
34644 #if SQLITE_OS_WINCE
34645 SYSTEMTIME time;
34646 GetSystemTime(&time);
34647 /* if SystemTimeToFileTime() fails, it returns zero. */
34648 if (!SystemTimeToFileTime(&time,&ft)){
34649 return 1;
34651 #else
34652 GetSystemTimeAsFileTime( &ft );
34653 #endif
34655 *piNow = winFiletimeEpoch +
34656 ((((sqlite3_int64)ft.dwHighDateTime)*max32BitValue) +
34657 (sqlite3_int64)ft.dwLowDateTime)/(sqlite3_int64)10000;
34659 #ifdef SQLITE_TEST
34660 if( sqlite3_current_time ){
34661 *piNow = 1000*(sqlite3_int64)sqlite3_current_time + unixEpoch;
34663 #endif
34664 UNUSED_PARAMETER(pVfs);
34665 return 0;
34669 ** Find the current time (in Universal Coordinated Time). Write the
34670 ** current time and date as a Julian Day number into *prNow and
34671 ** return 0. Return 1 if the time and date cannot be found.
34673 int winCurrentTime(sqlite3_vfs *pVfs, double *prNow){
34674 int rc;
34675 sqlite3_int64 i;
34676 rc = winCurrentTimeInt64(pVfs, &i);
34677 if( !rc ){
34678 *prNow = i/86400000.0;
34680 return rc;
34684 ** The idea is that this function works like a combination of
34685 ** GetLastError() and FormatMessage() on windows (or errno and
34686 ** strerror_r() on unix). After an error is returned by an OS
34687 ** function, SQLite calls this function with zBuf pointing to
34688 ** a buffer of nBuf bytes. The OS layer should populate the
34689 ** buffer with a nul-terminated UTF-8 encoded error message
34690 ** describing the last IO error to have occurred within the calling
34691 ** thread.
34693 ** If the error message is too large for the supplied buffer,
34694 ** it should be truncated. The return value of xGetLastError
34695 ** is zero if the error message fits in the buffer, or non-zero
34696 ** otherwise (if the message was truncated). If non-zero is returned,
34697 ** then it is not necessary to include the nul-terminator character
34698 ** in the output buffer.
34700 ** Not supplying an error message will have no adverse effect
34701 ** on SQLite. It is fine to have an implementation that never
34702 ** returns an error message:
34704 ** int xGetLastError(sqlite3_vfs *pVfs, int nBuf, char *zBuf){
34705 ** assert(zBuf[0]=='\0');
34706 ** return 0;
34707 ** }
34709 ** However if an error message is supplied, it will be incorporated
34710 ** by sqlite into the error message available to the user using
34711 ** sqlite3_errmsg(), possibly making IO errors easier to debug.
34713 static int winGetLastError(sqlite3_vfs *pVfs, int nBuf, char *zBuf){
34714 UNUSED_PARAMETER(pVfs);
34715 return getLastErrorMsg(nBuf, zBuf);
34721 ** Initialize and deinitialize the operating system interface.
34723 SQLITE_API int sqlite3_os_init(void){
34724 static sqlite3_vfs winVfs = {
34725 3, /* iVersion */
34726 sizeof(winFile), /* szOsFile */
34727 MAX_PATH, /* mxPathname */
34728 0, /* pNext */
34729 "win32", /* zName */
34730 0, /* pAppData */
34731 winOpen, /* xOpen */
34732 winDelete, /* xDelete */
34733 winAccess, /* xAccess */
34734 winFullPathname, /* xFullPathname */
34735 winDlOpen, /* xDlOpen */
34736 winDlError, /* xDlError */
34737 winDlSym, /* xDlSym */
34738 winDlClose, /* xDlClose */
34739 winRandomness, /* xRandomness */
34740 winSleep, /* xSleep */
34741 winCurrentTime, /* xCurrentTime */
34742 winGetLastError, /* xGetLastError */
34743 winCurrentTimeInt64, /* xCurrentTimeInt64 */
34744 0, /* xSetSystemCall */
34745 0, /* xGetSystemCall */
34746 0, /* xNextSystemCall */
34749 #ifndef SQLITE_OMIT_WAL
34750 /* get memory map allocation granularity */
34751 memset(&winSysInfo, 0, sizeof(SYSTEM_INFO));
34752 GetSystemInfo(&winSysInfo);
34753 assert(winSysInfo.dwAllocationGranularity > 0);
34754 #endif
34756 sqlite3_vfs_register(&winVfs, 1);
34757 return SQLITE_OK;
34759 SQLITE_API int sqlite3_os_end(void){
34760 return SQLITE_OK;
34763 #endif /* SQLITE_OS_WIN */
34765 /************** End of os_win.c **********************************************/
34766 /************** Begin file bitvec.c ******************************************/
34768 ** 2008 February 16
34770 ** The author disclaims copyright to this source code. In place of
34771 ** a legal notice, here is a blessing:
34773 ** May you do good and not evil.
34774 ** May you find forgiveness for yourself and forgive others.
34775 ** May you share freely, never taking more than you give.
34777 *************************************************************************
34778 ** This file implements an object that represents a fixed-length
34779 ** bitmap. Bits are numbered starting with 1.
34781 ** A bitmap is used to record which pages of a database file have been
34782 ** journalled during a transaction, or which pages have the "dont-write"
34783 ** property. Usually only a few pages are meet either condition.
34784 ** So the bitmap is usually sparse and has low cardinality.
34785 ** But sometimes (for example when during a DROP of a large table) most
34786 ** or all of the pages in a database can get journalled. In those cases,
34787 ** the bitmap becomes dense with high cardinality. The algorithm needs
34788 ** to handle both cases well.
34790 ** The size of the bitmap is fixed when the object is created.
34792 ** All bits are clear when the bitmap is created. Individual bits
34793 ** may be set or cleared one at a time.
34795 ** Test operations are about 100 times more common that set operations.
34796 ** Clear operations are exceedingly rare. There are usually between
34797 ** 5 and 500 set operations per Bitvec object, though the number of sets can
34798 ** sometimes grow into tens of thousands or larger. The size of the
34799 ** Bitvec object is the number of pages in the database file at the
34800 ** start of a transaction, and is thus usually less than a few thousand,
34801 ** but can be as large as 2 billion for a really big database.
34804 /* Size of the Bitvec structure in bytes. */
34805 #define BITVEC_SZ 512
34807 /* Round the union size down to the nearest pointer boundary, since that's how
34808 ** it will be aligned within the Bitvec struct. */
34809 #define BITVEC_USIZE (((BITVEC_SZ-(3*sizeof(u32)))/sizeof(Bitvec*))*sizeof(Bitvec*))
34811 /* Type of the array "element" for the bitmap representation.
34812 ** Should be a power of 2, and ideally, evenly divide into BITVEC_USIZE.
34813 ** Setting this to the "natural word" size of your CPU may improve
34814 ** performance. */
34815 #define BITVEC_TELEM u8
34816 /* Size, in bits, of the bitmap element. */
34817 #define BITVEC_SZELEM 8
34818 /* Number of elements in a bitmap array. */
34819 #define BITVEC_NELEM (BITVEC_USIZE/sizeof(BITVEC_TELEM))
34820 /* Number of bits in the bitmap array. */
34821 #define BITVEC_NBIT (BITVEC_NELEM*BITVEC_SZELEM)
34823 /* Number of u32 values in hash table. */
34824 #define BITVEC_NINT (BITVEC_USIZE/sizeof(u32))
34825 /* Maximum number of entries in hash table before
34826 ** sub-dividing and re-hashing. */
34827 #define BITVEC_MXHASH (BITVEC_NINT/2)
34828 /* Hashing function for the aHash representation.
34829 ** Empirical testing showed that the *37 multiplier
34830 ** (an arbitrary prime)in the hash function provided
34831 ** no fewer collisions than the no-op *1. */
34832 #define BITVEC_HASH(X) (((X)*1)%BITVEC_NINT)
34834 #define BITVEC_NPTR (BITVEC_USIZE/sizeof(Bitvec *))
34838 ** A bitmap is an instance of the following structure.
34840 ** This bitmap records the existance of zero or more bits
34841 ** with values between 1 and iSize, inclusive.
34843 ** There are three possible representations of the bitmap.
34844 ** If iSize<=BITVEC_NBIT, then Bitvec.u.aBitmap[] is a straight
34845 ** bitmap. The least significant bit is bit 1.
34847 ** If iSize>BITVEC_NBIT and iDivisor==0 then Bitvec.u.aHash[] is
34848 ** a hash table that will hold up to BITVEC_MXHASH distinct values.
34850 ** Otherwise, the value i is redirected into one of BITVEC_NPTR
34851 ** sub-bitmaps pointed to by Bitvec.u.apSub[]. Each subbitmap
34852 ** handles up to iDivisor separate values of i. apSub[0] holds
34853 ** values between 1 and iDivisor. apSub[1] holds values between
34854 ** iDivisor+1 and 2*iDivisor. apSub[N] holds values between
34855 ** N*iDivisor+1 and (N+1)*iDivisor. Each subbitmap is normalized
34856 ** to hold deal with values between 1 and iDivisor.
34858 struct Bitvec {
34859 u32 iSize; /* Maximum bit index. Max iSize is 4,294,967,296. */
34860 u32 nSet; /* Number of bits that are set - only valid for aHash
34861 ** element. Max is BITVEC_NINT. For BITVEC_SZ of 512,
34862 ** this would be 125. */
34863 u32 iDivisor; /* Number of bits handled by each apSub[] entry. */
34864 /* Should >=0 for apSub element. */
34865 /* Max iDivisor is max(u32) / BITVEC_NPTR + 1. */
34866 /* For a BITVEC_SZ of 512, this would be 34,359,739. */
34867 union {
34868 BITVEC_TELEM aBitmap[BITVEC_NELEM]; /* Bitmap representation */
34869 u32 aHash[BITVEC_NINT]; /* Hash table representation */
34870 Bitvec *apSub[BITVEC_NPTR]; /* Recursive representation */
34871 } u;
34875 ** Create a new bitmap object able to handle bits between 0 and iSize,
34876 ** inclusive. Return a pointer to the new object. Return NULL if
34877 ** malloc fails.
34879 SQLITE_PRIVATE Bitvec *sqlite3BitvecCreate(u32 iSize){
34880 Bitvec *p;
34881 assert( sizeof(*p)==BITVEC_SZ );
34882 p = sqlite3MallocZero( sizeof(*p) );
34883 if( p ){
34884 p->iSize = iSize;
34886 return p;
34890 ** Check to see if the i-th bit is set. Return true or false.
34891 ** If p is NULL (if the bitmap has not been created) or if
34892 ** i is out of range, then return false.
34894 SQLITE_PRIVATE int sqlite3BitvecTest(Bitvec *p, u32 i){
34895 if( p==0 ) return 0;
34896 if( i>p->iSize || i==0 ) return 0;
34897 i--;
34898 while( p->iDivisor ){
34899 u32 bin = i/p->iDivisor;
34900 i = i%p->iDivisor;
34901 p = p->u.apSub[bin];
34902 if (!p) {
34903 return 0;
34906 if( p->iSize<=BITVEC_NBIT ){
34907 return (p->u.aBitmap[i/BITVEC_SZELEM] & (1<<(i&(BITVEC_SZELEM-1))))!=0;
34908 } else{
34909 u32 h = BITVEC_HASH(i++);
34910 while( p->u.aHash[h] ){
34911 if( p->u.aHash[h]==i ) return 1;
34912 h = (h+1) % BITVEC_NINT;
34914 return 0;
34919 ** Set the i-th bit. Return 0 on success and an error code if
34920 ** anything goes wrong.
34922 ** This routine might cause sub-bitmaps to be allocated. Failing
34923 ** to get the memory needed to hold the sub-bitmap is the only
34924 ** that can go wrong with an insert, assuming p and i are valid.
34926 ** The calling function must ensure that p is a valid Bitvec object
34927 ** and that the value for "i" is within range of the Bitvec object.
34928 ** Otherwise the behavior is undefined.
34930 SQLITE_PRIVATE int sqlite3BitvecSet(Bitvec *p, u32 i){
34931 u32 h;
34932 if( p==0 ) return SQLITE_OK;
34933 assert( i>0 );
34934 assert( i<=p->iSize );
34935 i--;
34936 while((p->iSize > BITVEC_NBIT) && p->iDivisor) {
34937 u32 bin = i/p->iDivisor;
34938 i = i%p->iDivisor;
34939 if( p->u.apSub[bin]==0 ){
34940 p->u.apSub[bin] = sqlite3BitvecCreate( p->iDivisor );
34941 if( p->u.apSub[bin]==0 ) return SQLITE_NOMEM;
34943 p = p->u.apSub[bin];
34945 if( p->iSize<=BITVEC_NBIT ){
34946 p->u.aBitmap[i/BITVEC_SZELEM] |= 1 << (i&(BITVEC_SZELEM-1));
34947 return SQLITE_OK;
34949 h = BITVEC_HASH(i++);
34950 /* if there wasn't a hash collision, and this doesn't */
34951 /* completely fill the hash, then just add it without */
34952 /* worring about sub-dividing and re-hashing. */
34953 if( !p->u.aHash[h] ){
34954 if (p->nSet<(BITVEC_NINT-1)) {
34955 goto bitvec_set_end;
34956 } else {
34957 goto bitvec_set_rehash;
34960 /* there was a collision, check to see if it's already */
34961 /* in hash, if not, try to find a spot for it */
34962 do {
34963 if( p->u.aHash[h]==i ) return SQLITE_OK;
34964 h++;
34965 if( h>=BITVEC_NINT ) h = 0;
34966 } while( p->u.aHash[h] );
34967 /* we didn't find it in the hash. h points to the first */
34968 /* available free spot. check to see if this is going to */
34969 /* make our hash too "full". */
34970 bitvec_set_rehash:
34971 if( p->nSet>=BITVEC_MXHASH ){
34972 unsigned int j;
34973 int rc;
34974 u32 *aiValues = sqlite3StackAllocRaw(0, sizeof(p->u.aHash));
34975 if( aiValues==0 ){
34976 return SQLITE_NOMEM;
34977 }else{
34978 memcpy(aiValues, p->u.aHash, sizeof(p->u.aHash));
34979 memset(p->u.apSub, 0, sizeof(p->u.apSub));
34980 p->iDivisor = (p->iSize + BITVEC_NPTR - 1)/BITVEC_NPTR;
34981 rc = sqlite3BitvecSet(p, i);
34982 for(j=0; j<BITVEC_NINT; j++){
34983 if( aiValues[j] ) rc |= sqlite3BitvecSet(p, aiValues[j]);
34985 sqlite3StackFree(0, aiValues);
34986 return rc;
34989 bitvec_set_end:
34990 p->nSet++;
34991 p->u.aHash[h] = i;
34992 return SQLITE_OK;
34996 ** Clear the i-th bit.
34998 ** pBuf must be a pointer to at least BITVEC_SZ bytes of temporary storage
34999 ** that BitvecClear can use to rebuilt its hash table.
35001 SQLITE_PRIVATE void sqlite3BitvecClear(Bitvec *p, u32 i, void *pBuf){
35002 if( p==0 ) return;
35003 assert( i>0 );
35004 i--;
35005 while( p->iDivisor ){
35006 u32 bin = i/p->iDivisor;
35007 i = i%p->iDivisor;
35008 p = p->u.apSub[bin];
35009 if (!p) {
35010 return;
35013 if( p->iSize<=BITVEC_NBIT ){
35014 p->u.aBitmap[i/BITVEC_SZELEM] &= ~(1 << (i&(BITVEC_SZELEM-1)));
35015 }else{
35016 unsigned int j;
35017 u32 *aiValues = pBuf;
35018 memcpy(aiValues, p->u.aHash, sizeof(p->u.aHash));
35019 memset(p->u.aHash, 0, sizeof(p->u.aHash));
35020 p->nSet = 0;
35021 for(j=0; j<BITVEC_NINT; j++){
35022 if( aiValues[j] && aiValues[j]!=(i+1) ){
35023 u32 h = BITVEC_HASH(aiValues[j]-1);
35024 p->nSet++;
35025 while( p->u.aHash[h] ){
35026 h++;
35027 if( h>=BITVEC_NINT ) h = 0;
35029 p->u.aHash[h] = aiValues[j];
35036 ** Destroy a bitmap object. Reclaim all memory used.
35038 SQLITE_PRIVATE void sqlite3BitvecDestroy(Bitvec *p){
35039 if( p==0 ) return;
35040 if( p->iDivisor ){
35041 unsigned int i;
35042 for(i=0; i<BITVEC_NPTR; i++){
35043 sqlite3BitvecDestroy(p->u.apSub[i]);
35046 sqlite3_free(p);
35050 ** Return the value of the iSize parameter specified when Bitvec *p
35051 ** was created.
35053 SQLITE_PRIVATE u32 sqlite3BitvecSize(Bitvec *p){
35054 return p->iSize;
35057 #ifndef SQLITE_OMIT_BUILTIN_TEST
35059 ** Let V[] be an array of unsigned characters sufficient to hold
35060 ** up to N bits. Let I be an integer between 0 and N. 0<=I<N.
35061 ** Then the following macros can be used to set, clear, or test
35062 ** individual bits within V.
35064 #define SETBIT(V,I) V[I>>3] |= (1<<(I&7))
35065 #define CLEARBIT(V,I) V[I>>3] &= ~(1<<(I&7))
35066 #define TESTBIT(V,I) (V[I>>3]&(1<<(I&7)))!=0
35069 ** This routine runs an extensive test of the Bitvec code.
35071 ** The input is an array of integers that acts as a program
35072 ** to test the Bitvec. The integers are opcodes followed
35073 ** by 0, 1, or 3 operands, depending on the opcode. Another
35074 ** opcode follows immediately after the last operand.
35076 ** There are 6 opcodes numbered from 0 through 5. 0 is the
35077 ** "halt" opcode and causes the test to end.
35079 ** 0 Halt and return the number of errors
35080 ** 1 N S X Set N bits beginning with S and incrementing by X
35081 ** 2 N S X Clear N bits beginning with S and incrementing by X
35082 ** 3 N Set N randomly chosen bits
35083 ** 4 N Clear N randomly chosen bits
35084 ** 5 N S X Set N bits from S increment X in array only, not in bitvec
35086 ** The opcodes 1 through 4 perform set and clear operations are performed
35087 ** on both a Bitvec object and on a linear array of bits obtained from malloc.
35088 ** Opcode 5 works on the linear array only, not on the Bitvec.
35089 ** Opcode 5 is used to deliberately induce a fault in order to
35090 ** confirm that error detection works.
35092 ** At the conclusion of the test the linear array is compared
35093 ** against the Bitvec object. If there are any differences,
35094 ** an error is returned. If they are the same, zero is returned.
35096 ** If a memory allocation error occurs, return -1.
35098 SQLITE_PRIVATE int sqlite3BitvecBuiltinTest(int sz, int *aOp){
35099 Bitvec *pBitvec = 0;
35100 unsigned char *pV = 0;
35101 int rc = -1;
35102 int i, nx, pc, op;
35103 void *pTmpSpace;
35105 /* Allocate the Bitvec to be tested and a linear array of
35106 ** bits to act as the reference */
35107 pBitvec = sqlite3BitvecCreate( sz );
35108 pV = sqlite3_malloc( (sz+7)/8 + 1 );
35109 pTmpSpace = sqlite3_malloc(BITVEC_SZ);
35110 if( pBitvec==0 || pV==0 || pTmpSpace==0 ) goto bitvec_end;
35111 memset(pV, 0, (sz+7)/8 + 1);
35113 /* NULL pBitvec tests */
35114 sqlite3BitvecSet(0, 1);
35115 sqlite3BitvecClear(0, 1, pTmpSpace);
35117 /* Run the program */
35118 pc = 0;
35119 while( (op = aOp[pc])!=0 ){
35120 switch( op ){
35121 case 1:
35122 case 2:
35123 case 5: {
35124 nx = 4;
35125 i = aOp[pc+2] - 1;
35126 aOp[pc+2] += aOp[pc+3];
35127 break;
35129 case 3:
35130 case 4:
35131 default: {
35132 nx = 2;
35133 sqlite3_randomness(sizeof(i), &i);
35134 break;
35137 if( (--aOp[pc+1]) > 0 ) nx = 0;
35138 pc += nx;
35139 i = (i & 0x7fffffff)%sz;
35140 if( (op & 1)!=0 ){
35141 SETBIT(pV, (i+1));
35142 if( op!=5 ){
35143 if( sqlite3BitvecSet(pBitvec, i+1) ) goto bitvec_end;
35145 }else{
35146 CLEARBIT(pV, (i+1));
35147 sqlite3BitvecClear(pBitvec, i+1, pTmpSpace);
35151 /* Test to make sure the linear array exactly matches the
35152 ** Bitvec object. Start with the assumption that they do
35153 ** match (rc==0). Change rc to non-zero if a discrepancy
35154 ** is found.
35156 rc = sqlite3BitvecTest(0,0) + sqlite3BitvecTest(pBitvec, sz+1)
35157 + sqlite3BitvecTest(pBitvec, 0)
35158 + (sqlite3BitvecSize(pBitvec) - sz);
35159 for(i=1; i<=sz; i++){
35160 if( (TESTBIT(pV,i))!=sqlite3BitvecTest(pBitvec,i) ){
35161 rc = i;
35162 break;
35166 /* Free allocated structure */
35167 bitvec_end:
35168 sqlite3_free(pTmpSpace);
35169 sqlite3_free(pV);
35170 sqlite3BitvecDestroy(pBitvec);
35171 return rc;
35173 #endif /* SQLITE_OMIT_BUILTIN_TEST */
35175 /************** End of bitvec.c **********************************************/
35176 /************** Begin file pcache.c ******************************************/
35178 ** 2008 August 05
35180 ** The author disclaims copyright to this source code. In place of
35181 ** a legal notice, here is a blessing:
35183 ** May you do good and not evil.
35184 ** May you find forgiveness for yourself and forgive others.
35185 ** May you share freely, never taking more than you give.
35187 *************************************************************************
35188 ** This file implements that page cache.
35192 ** A complete page cache is an instance of this structure.
35194 struct PCache {
35195 PgHdr *pDirty, *pDirtyTail; /* List of dirty pages in LRU order */
35196 PgHdr *pSynced; /* Last synced page in dirty page list */
35197 int nRef; /* Number of referenced pages */
35198 int nMax; /* Configured cache size */
35199 int szPage; /* Size of every page in this cache */
35200 int szExtra; /* Size of extra space for each page */
35201 int bPurgeable; /* True if pages are on backing store */
35202 int (*xStress)(void*,PgHdr*); /* Call to try make a page clean */
35203 void *pStress; /* Argument to xStress */
35204 sqlite3_pcache *pCache; /* Pluggable cache module */
35205 PgHdr *pPage1; /* Reference to page 1 */
35209 ** Some of the assert() macros in this code are too expensive to run
35210 ** even during normal debugging. Use them only rarely on long-running
35211 ** tests. Enable the expensive asserts using the
35212 ** -DSQLITE_ENABLE_EXPENSIVE_ASSERT=1 compile-time option.
35214 #ifdef SQLITE_ENABLE_EXPENSIVE_ASSERT
35215 # define expensive_assert(X) assert(X)
35216 #else
35217 # define expensive_assert(X)
35218 #endif
35220 /********************************** Linked List Management ********************/
35222 #if !defined(NDEBUG) && defined(SQLITE_ENABLE_EXPENSIVE_ASSERT)
35224 ** Check that the pCache->pSynced variable is set correctly. If it
35225 ** is not, either fail an assert or return zero. Otherwise, return
35226 ** non-zero. This is only used in debugging builds, as follows:
35228 ** expensive_assert( pcacheCheckSynced(pCache) );
35230 static int pcacheCheckSynced(PCache *pCache){
35231 PgHdr *p;
35232 for(p=pCache->pDirtyTail; p!=pCache->pSynced; p=p->pDirtyPrev){
35233 assert( p->nRef || (p->flags&PGHDR_NEED_SYNC) );
35235 return (p==0 || p->nRef || (p->flags&PGHDR_NEED_SYNC)==0);
35237 #endif /* !NDEBUG && SQLITE_ENABLE_EXPENSIVE_ASSERT */
35240 ** Remove page pPage from the list of dirty pages.
35242 static void pcacheRemoveFromDirtyList(PgHdr *pPage){
35243 PCache *p = pPage->pCache;
35245 assert( pPage->pDirtyNext || pPage==p->pDirtyTail );
35246 assert( pPage->pDirtyPrev || pPage==p->pDirty );
35248 /* Update the PCache1.pSynced variable if necessary. */
35249 if( p->pSynced==pPage ){
35250 PgHdr *pSynced = pPage->pDirtyPrev;
35251 while( pSynced && (pSynced->flags&PGHDR_NEED_SYNC) ){
35252 pSynced = pSynced->pDirtyPrev;
35254 p->pSynced = pSynced;
35257 if( pPage->pDirtyNext ){
35258 pPage->pDirtyNext->pDirtyPrev = pPage->pDirtyPrev;
35259 }else{
35260 assert( pPage==p->pDirtyTail );
35261 p->pDirtyTail = pPage->pDirtyPrev;
35263 if( pPage->pDirtyPrev ){
35264 pPage->pDirtyPrev->pDirtyNext = pPage->pDirtyNext;
35265 }else{
35266 assert( pPage==p->pDirty );
35267 p->pDirty = pPage->pDirtyNext;
35269 pPage->pDirtyNext = 0;
35270 pPage->pDirtyPrev = 0;
35272 expensive_assert( pcacheCheckSynced(p) );
35276 ** Add page pPage to the head of the dirty list (PCache1.pDirty is set to
35277 ** pPage).
35279 static void pcacheAddToDirtyList(PgHdr *pPage){
35280 PCache *p = pPage->pCache;
35282 assert( pPage->pDirtyNext==0 && pPage->pDirtyPrev==0 && p->pDirty!=pPage );
35284 pPage->pDirtyNext = p->pDirty;
35285 if( pPage->pDirtyNext ){
35286 assert( pPage->pDirtyNext->pDirtyPrev==0 );
35287 pPage->pDirtyNext->pDirtyPrev = pPage;
35289 p->pDirty = pPage;
35290 if( !p->pDirtyTail ){
35291 p->pDirtyTail = pPage;
35293 if( !p->pSynced && 0==(pPage->flags&PGHDR_NEED_SYNC) ){
35294 p->pSynced = pPage;
35296 expensive_assert( pcacheCheckSynced(p) );
35300 ** Wrapper around the pluggable caches xUnpin method. If the cache is
35301 ** being used for an in-memory database, this function is a no-op.
35303 static void pcacheUnpin(PgHdr *p){
35304 PCache *pCache = p->pCache;
35305 if( pCache->bPurgeable ){
35306 if( p->pgno==1 ){
35307 pCache->pPage1 = 0;
35309 sqlite3GlobalConfig.pcache.xUnpin(pCache->pCache, p, 0);
35313 /*************************************************** General Interfaces ******
35315 ** Initialize and shutdown the page cache subsystem. Neither of these
35316 ** functions are threadsafe.
35318 SQLITE_PRIVATE int sqlite3PcacheInitialize(void){
35319 if( sqlite3GlobalConfig.pcache.xInit==0 ){
35320 /* IMPLEMENTATION-OF: R-26801-64137 If the xInit() method is NULL, then the
35321 ** built-in default page cache is used instead of the application defined
35322 ** page cache. */
35323 sqlite3PCacheSetDefault();
35325 return sqlite3GlobalConfig.pcache.xInit(sqlite3GlobalConfig.pcache.pArg);
35327 SQLITE_PRIVATE void sqlite3PcacheShutdown(void){
35328 if( sqlite3GlobalConfig.pcache.xShutdown ){
35329 /* IMPLEMENTATION-OF: R-26000-56589 The xShutdown() method may be NULL. */
35330 sqlite3GlobalConfig.pcache.xShutdown(sqlite3GlobalConfig.pcache.pArg);
35335 ** Return the size in bytes of a PCache object.
35337 SQLITE_PRIVATE int sqlite3PcacheSize(void){ return sizeof(PCache); }
35340 ** Create a new PCache object. Storage space to hold the object
35341 ** has already been allocated and is passed in as the p pointer.
35342 ** The caller discovers how much space needs to be allocated by
35343 ** calling sqlite3PcacheSize().
35345 SQLITE_PRIVATE void sqlite3PcacheOpen(
35346 int szPage, /* Size of every page */
35347 int szExtra, /* Extra space associated with each page */
35348 int bPurgeable, /* True if pages are on backing store */
35349 int (*xStress)(void*,PgHdr*),/* Call to try to make pages clean */
35350 void *pStress, /* Argument to xStress */
35351 PCache *p /* Preallocated space for the PCache */
35353 memset(p, 0, sizeof(PCache));
35354 p->szPage = szPage;
35355 p->szExtra = szExtra;
35356 p->bPurgeable = bPurgeable;
35357 p->xStress = xStress;
35358 p->pStress = pStress;
35359 p->nMax = 100;
35363 ** Change the page size for PCache object. The caller must ensure that there
35364 ** are no outstanding page references when this function is called.
35366 SQLITE_PRIVATE void sqlite3PcacheSetPageSize(PCache *pCache, int szPage){
35367 assert( pCache->nRef==0 && pCache->pDirty==0 );
35368 if( pCache->pCache ){
35369 sqlite3GlobalConfig.pcache.xDestroy(pCache->pCache);
35370 pCache->pCache = 0;
35371 pCache->pPage1 = 0;
35373 pCache->szPage = szPage;
35377 ** Try to obtain a page from the cache.
35379 SQLITE_PRIVATE int sqlite3PcacheFetch(
35380 PCache *pCache, /* Obtain the page from this cache */
35381 Pgno pgno, /* Page number to obtain */
35382 int createFlag, /* If true, create page if it does not exist already */
35383 PgHdr **ppPage /* Write the page here */
35385 PgHdr *pPage = 0;
35386 int eCreate;
35388 assert( pCache!=0 );
35389 assert( createFlag==1 || createFlag==0 );
35390 assert( pgno>0 );
35392 /* If the pluggable cache (sqlite3_pcache*) has not been allocated,
35393 ** allocate it now.
35395 if( !pCache->pCache && createFlag ){
35396 sqlite3_pcache *p;
35397 int nByte;
35398 nByte = pCache->szPage + pCache->szExtra + sizeof(PgHdr);
35399 p = sqlite3GlobalConfig.pcache.xCreate(nByte, pCache->bPurgeable);
35400 if( !p ){
35401 return SQLITE_NOMEM;
35403 sqlite3GlobalConfig.pcache.xCachesize(p, pCache->nMax);
35404 pCache->pCache = p;
35407 eCreate = createFlag * (1 + (!pCache->bPurgeable || !pCache->pDirty));
35408 if( pCache->pCache ){
35409 pPage = sqlite3GlobalConfig.pcache.xFetch(pCache->pCache, pgno, eCreate);
35412 if( !pPage && eCreate==1 ){
35413 PgHdr *pPg;
35415 /* Find a dirty page to write-out and recycle. First try to find a
35416 ** page that does not require a journal-sync (one with PGHDR_NEED_SYNC
35417 ** cleared), but if that is not possible settle for any other
35418 ** unreferenced dirty page.
35420 expensive_assert( pcacheCheckSynced(pCache) );
35421 for(pPg=pCache->pSynced;
35422 pPg && (pPg->nRef || (pPg->flags&PGHDR_NEED_SYNC));
35423 pPg=pPg->pDirtyPrev
35425 pCache->pSynced = pPg;
35426 if( !pPg ){
35427 for(pPg=pCache->pDirtyTail; pPg && pPg->nRef; pPg=pPg->pDirtyPrev);
35429 if( pPg ){
35430 int rc;
35431 #ifdef SQLITE_LOG_CACHE_SPILL
35432 sqlite3_log(SQLITE_FULL,
35433 "spill page %d making room for %d - cache used: %d/%d",
35434 pPg->pgno, pgno,
35435 sqlite3GlobalConfig.pcache.xPagecount(pCache->pCache),
35436 pCache->nMax);
35437 #endif
35438 rc = pCache->xStress(pCache->pStress, pPg);
35439 if( rc!=SQLITE_OK && rc!=SQLITE_BUSY ){
35440 return rc;
35444 pPage = sqlite3GlobalConfig.pcache.xFetch(pCache->pCache, pgno, 2);
35447 if( pPage ){
35448 if( !pPage->pData ){
35449 memset(pPage, 0, sizeof(PgHdr));
35450 pPage->pData = (void *)&pPage[1];
35451 pPage->pExtra = (void*)&((char *)pPage->pData)[pCache->szPage];
35452 memset(pPage->pExtra, 0, pCache->szExtra);
35453 pPage->pCache = pCache;
35454 pPage->pgno = pgno;
35456 assert( pPage->pCache==pCache );
35457 assert( pPage->pgno==pgno );
35458 assert( pPage->pData==(void *)&pPage[1] );
35459 assert( pPage->pExtra==(void *)&((char *)&pPage[1])[pCache->szPage] );
35461 if( 0==pPage->nRef ){
35462 pCache->nRef++;
35464 pPage->nRef++;
35465 if( pgno==1 ){
35466 pCache->pPage1 = pPage;
35469 *ppPage = pPage;
35470 return (pPage==0 && eCreate) ? SQLITE_NOMEM : SQLITE_OK;
35474 ** Decrement the reference count on a page. If the page is clean and the
35475 ** reference count drops to 0, then it is made elible for recycling.
35477 SQLITE_PRIVATE void sqlite3PcacheRelease(PgHdr *p){
35478 assert( p->nRef>0 );
35479 p->nRef--;
35480 if( p->nRef==0 ){
35481 PCache *pCache = p->pCache;
35482 pCache->nRef--;
35483 if( (p->flags&PGHDR_DIRTY)==0 ){
35484 pcacheUnpin(p);
35485 }else{
35486 /* Move the page to the head of the dirty list. */
35487 pcacheRemoveFromDirtyList(p);
35488 pcacheAddToDirtyList(p);
35494 ** Increase the reference count of a supplied page by 1.
35496 SQLITE_PRIVATE void sqlite3PcacheRef(PgHdr *p){
35497 assert(p->nRef>0);
35498 p->nRef++;
35502 ** Drop a page from the cache. There must be exactly one reference to the
35503 ** page. This function deletes that reference, so after it returns the
35504 ** page pointed to by p is invalid.
35506 SQLITE_PRIVATE void sqlite3PcacheDrop(PgHdr *p){
35507 PCache *pCache;
35508 assert( p->nRef==1 );
35509 if( p->flags&PGHDR_DIRTY ){
35510 pcacheRemoveFromDirtyList(p);
35512 pCache = p->pCache;
35513 pCache->nRef--;
35514 if( p->pgno==1 ){
35515 pCache->pPage1 = 0;
35517 sqlite3GlobalConfig.pcache.xUnpin(pCache->pCache, p, 1);
35521 ** Make sure the page is marked as dirty. If it isn't dirty already,
35522 ** make it so.
35524 SQLITE_PRIVATE void sqlite3PcacheMakeDirty(PgHdr *p){
35525 p->flags &= ~PGHDR_DONT_WRITE;
35526 assert( p->nRef>0 );
35527 if( 0==(p->flags & PGHDR_DIRTY) ){
35528 p->flags |= PGHDR_DIRTY;
35529 pcacheAddToDirtyList( p);
35534 ** Make sure the page is marked as clean. If it isn't clean already,
35535 ** make it so.
35537 SQLITE_PRIVATE void sqlite3PcacheMakeClean(PgHdr *p){
35538 if( (p->flags & PGHDR_DIRTY) ){
35539 pcacheRemoveFromDirtyList(p);
35540 p->flags &= ~(PGHDR_DIRTY|PGHDR_NEED_SYNC);
35541 if( p->nRef==0 ){
35542 pcacheUnpin(p);
35548 ** Make every page in the cache clean.
35550 SQLITE_PRIVATE void sqlite3PcacheCleanAll(PCache *pCache){
35551 PgHdr *p;
35552 while( (p = pCache->pDirty)!=0 ){
35553 sqlite3PcacheMakeClean(p);
35558 ** Clear the PGHDR_NEED_SYNC flag from all dirty pages.
35560 SQLITE_PRIVATE void sqlite3PcacheClearSyncFlags(PCache *pCache){
35561 PgHdr *p;
35562 for(p=pCache->pDirty; p; p=p->pDirtyNext){
35563 p->flags &= ~PGHDR_NEED_SYNC;
35565 pCache->pSynced = pCache->pDirtyTail;
35569 ** Change the page number of page p to newPgno.
35571 SQLITE_PRIVATE void sqlite3PcacheMove(PgHdr *p, Pgno newPgno){
35572 PCache *pCache = p->pCache;
35573 assert( p->nRef>0 );
35574 assert( newPgno>0 );
35575 sqlite3GlobalConfig.pcache.xRekey(pCache->pCache, p, p->pgno, newPgno);
35576 p->pgno = newPgno;
35577 if( (p->flags&PGHDR_DIRTY) && (p->flags&PGHDR_NEED_SYNC) ){
35578 pcacheRemoveFromDirtyList(p);
35579 pcacheAddToDirtyList(p);
35584 ** Drop every cache entry whose page number is greater than "pgno". The
35585 ** caller must ensure that there are no outstanding references to any pages
35586 ** other than page 1 with a page number greater than pgno.
35588 ** If there is a reference to page 1 and the pgno parameter passed to this
35589 ** function is 0, then the data area associated with page 1 is zeroed, but
35590 ** the page object is not dropped.
35592 SQLITE_PRIVATE void sqlite3PcacheTruncate(PCache *pCache, Pgno pgno){
35593 if( pCache->pCache ){
35594 PgHdr *p;
35595 PgHdr *pNext;
35596 for(p=pCache->pDirty; p; p=pNext){
35597 pNext = p->pDirtyNext;
35598 /* This routine never gets call with a positive pgno except right
35599 ** after sqlite3PcacheCleanAll(). So if there are dirty pages,
35600 ** it must be that pgno==0.
35602 assert( p->pgno>0 );
35603 if( ALWAYS(p->pgno>pgno) ){
35604 assert( p->flags&PGHDR_DIRTY );
35605 sqlite3PcacheMakeClean(p);
35608 if( pgno==0 && pCache->pPage1 ){
35609 memset(pCache->pPage1->pData, 0, pCache->szPage);
35610 pgno = 1;
35612 sqlite3GlobalConfig.pcache.xTruncate(pCache->pCache, pgno+1);
35617 ** Close a cache.
35619 SQLITE_PRIVATE void sqlite3PcacheClose(PCache *pCache){
35620 if( pCache->pCache ){
35621 sqlite3GlobalConfig.pcache.xDestroy(pCache->pCache);
35626 ** Discard the contents of the cache.
35628 SQLITE_PRIVATE void sqlite3PcacheClear(PCache *pCache){
35629 sqlite3PcacheTruncate(pCache, 0);
35633 ** Merge two lists of pages connected by pDirty and in pgno order.
35634 ** Do not both fixing the pDirtyPrev pointers.
35636 static PgHdr *pcacheMergeDirtyList(PgHdr *pA, PgHdr *pB){
35637 PgHdr result, *pTail;
35638 pTail = &result;
35639 while( pA && pB ){
35640 if( pA->pgno<pB->pgno ){
35641 pTail->pDirty = pA;
35642 pTail = pA;
35643 pA = pA->pDirty;
35644 }else{
35645 pTail->pDirty = pB;
35646 pTail = pB;
35647 pB = pB->pDirty;
35650 if( pA ){
35651 pTail->pDirty = pA;
35652 }else if( pB ){
35653 pTail->pDirty = pB;
35654 }else{
35655 pTail->pDirty = 0;
35657 return result.pDirty;
35661 ** Sort the list of pages in accending order by pgno. Pages are
35662 ** connected by pDirty pointers. The pDirtyPrev pointers are
35663 ** corrupted by this sort.
35665 ** Since there cannot be more than 2^31 distinct pages in a database,
35666 ** there cannot be more than 31 buckets required by the merge sorter.
35667 ** One extra bucket is added to catch overflow in case something
35668 ** ever changes to make the previous sentence incorrect.
35670 #define N_SORT_BUCKET 32
35671 static PgHdr *pcacheSortDirtyList(PgHdr *pIn){
35672 PgHdr *a[N_SORT_BUCKET], *p;
35673 int i;
35674 memset(a, 0, sizeof(a));
35675 while( pIn ){
35676 p = pIn;
35677 pIn = p->pDirty;
35678 p->pDirty = 0;
35679 for(i=0; ALWAYS(i<N_SORT_BUCKET-1); i++){
35680 if( a[i]==0 ){
35681 a[i] = p;
35682 break;
35683 }else{
35684 p = pcacheMergeDirtyList(a[i], p);
35685 a[i] = 0;
35688 if( NEVER(i==N_SORT_BUCKET-1) ){
35689 /* To get here, there need to be 2^(N_SORT_BUCKET) elements in
35690 ** the input list. But that is impossible.
35692 a[i] = pcacheMergeDirtyList(a[i], p);
35695 p = a[0];
35696 for(i=1; i<N_SORT_BUCKET; i++){
35697 p = pcacheMergeDirtyList(p, a[i]);
35699 return p;
35703 ** Return a list of all dirty pages in the cache, sorted by page number.
35705 SQLITE_PRIVATE PgHdr *sqlite3PcacheDirtyList(PCache *pCache){
35706 PgHdr *p;
35707 for(p=pCache->pDirty; p; p=p->pDirtyNext){
35708 p->pDirty = p->pDirtyNext;
35710 return pcacheSortDirtyList(pCache->pDirty);
35714 ** Return the total number of referenced pages held by the cache.
35716 SQLITE_PRIVATE int sqlite3PcacheRefCount(PCache *pCache){
35717 return pCache->nRef;
35721 ** Return the number of references to the page supplied as an argument.
35723 SQLITE_PRIVATE int sqlite3PcachePageRefcount(PgHdr *p){
35724 return p->nRef;
35728 ** Return the total number of pages in the cache.
35730 SQLITE_PRIVATE int sqlite3PcachePagecount(PCache *pCache){
35731 int nPage = 0;
35732 if( pCache->pCache ){
35733 nPage = sqlite3GlobalConfig.pcache.xPagecount(pCache->pCache);
35735 return nPage;
35738 #ifdef SQLITE_TEST
35740 ** Get the suggested cache-size value.
35742 SQLITE_PRIVATE int sqlite3PcacheGetCachesize(PCache *pCache){
35743 return pCache->nMax;
35745 #endif
35748 ** Set the suggested cache-size value.
35750 SQLITE_PRIVATE void sqlite3PcacheSetCachesize(PCache *pCache, int mxPage){
35751 pCache->nMax = mxPage;
35752 if( pCache->pCache ){
35753 sqlite3GlobalConfig.pcache.xCachesize(pCache->pCache, mxPage);
35757 #if defined(SQLITE_CHECK_PAGES) || defined(SQLITE_DEBUG)
35759 ** For all dirty pages currently in the cache, invoke the specified
35760 ** callback. This is only used if the SQLITE_CHECK_PAGES macro is
35761 ** defined.
35763 SQLITE_PRIVATE void sqlite3PcacheIterateDirty(PCache *pCache, void (*xIter)(PgHdr *)){
35764 PgHdr *pDirty;
35765 for(pDirty=pCache->pDirty; pDirty; pDirty=pDirty->pDirtyNext){
35766 xIter(pDirty);
35769 #endif
35771 /************** End of pcache.c **********************************************/
35772 /************** Begin file pcache1.c *****************************************/
35774 ** 2008 November 05
35776 ** The author disclaims copyright to this source code. In place of
35777 ** a legal notice, here is a blessing:
35779 ** May you do good and not evil.
35780 ** May you find forgiveness for yourself and forgive others.
35781 ** May you share freely, never taking more than you give.
35783 *************************************************************************
35785 ** This file implements the default page cache implementation (the
35786 ** sqlite3_pcache interface). It also contains part of the implementation
35787 ** of the SQLITE_CONFIG_PAGECACHE and sqlite3_release_memory() features.
35788 ** If the default page cache implementation is overriden, then neither of
35789 ** these two features are available.
35793 typedef struct PCache1 PCache1;
35794 typedef struct PgHdr1 PgHdr1;
35795 typedef struct PgFreeslot PgFreeslot;
35796 typedef struct PGroup PGroup;
35798 typedef struct PGroupBlock PGroupBlock;
35799 typedef struct PGroupBlockList PGroupBlockList;
35801 /* Each page cache (or PCache) belongs to a PGroup. A PGroup is a set
35802 ** of one or more PCaches that are able to recycle each others unpinned
35803 ** pages when they are under memory pressure. A PGroup is an instance of
35804 ** the following object.
35806 ** This page cache implementation works in one of two modes:
35808 ** (1) Every PCache is the sole member of its own PGroup. There is
35809 ** one PGroup per PCache.
35811 ** (2) There is a single global PGroup that all PCaches are a member
35812 ** of.
35814 ** Mode 1 uses more memory (since PCache instances are not able to rob
35815 ** unused pages from other PCaches) but it also operates without a mutex,
35816 ** and is therefore often faster. Mode 2 requires a mutex in order to be
35817 ** threadsafe, but is able recycle pages more efficient.
35819 ** For mode (1), PGroup.mutex is NULL. For mode (2) there is only a single
35820 ** PGroup which is the pcache1.grp global variable and its mutex is
35821 ** SQLITE_MUTEX_STATIC_LRU.
35823 struct PGroup {
35824 sqlite3_mutex *mutex; /* MUTEX_STATIC_LRU or NULL */
35825 int nMaxPage; /* Sum of nMax for purgeable caches */
35826 int nMinPage; /* Sum of nMin for purgeable caches */
35827 int mxPinned; /* nMaxpage + 10 - nMinPage */
35828 int nCurrentPage; /* Number of purgeable pages allocated */
35829 PgHdr1 *pLruHead, *pLruTail; /* LRU list of unpinned pages */
35830 #ifdef SQLITE_PAGECACHE_BLOCKALLOC
35831 int isBusy; /* Do not run ReleaseMemory() if true */
35832 PGroupBlockList *pBlockList; /* List of block-lists for this group */
35833 #endif
35837 ** If SQLITE_PAGECACHE_BLOCKALLOC is defined when the library is built,
35838 ** each PGroup structure has a linked list of the the following starting
35839 ** at PGroup.pBlockList. There is one entry for each distinct page-size
35840 ** currently used by members of the PGroup (i.e. 1024 bytes, 4096 bytes
35841 ** etc.). Variable PGroupBlockList.nByte is set to the actual allocation
35842 ** size requested by each pcache, which is the database page-size plus
35843 ** the various header structures used by the pcache, pager and btree layers.
35844 ** Usually around (pgsz+200) bytes.
35846 ** This size (pgsz+200) bytes is not allocated efficiently by some
35847 ** implementations of malloc. In particular, some implementations are only
35848 ** able to allocate blocks of memory chunks of 2^N bytes, where N is some
35849 ** integer value. Since the page-size is a power of 2, this means we
35850 ** end up wasting (pgsz-200) bytes in each allocation.
35852 ** If SQLITE_PAGECACHE_BLOCKALLOC is defined, the (pgsz+200) byte blocks
35853 ** are not allocated directly. Instead, blocks of roughly M*(pgsz+200) bytes
35854 ** are requested from malloc allocator. After a block is returned,
35855 ** sqlite3MallocSize() is used to determine how many (pgsz+200) byte
35856 ** allocations can fit in the space returned by malloc(). This value may
35857 ** be more than M.
35859 ** The blocks are stored in a doubly-linked list. Variable PGroupBlock.nEntry
35860 ** contains the number of allocations that will fit in the aData[] space.
35861 ** nEntry is limited to the number of bits in bitmask mUsed. If a slot
35862 ** within aData is in use, the corresponding bit in mUsed is set. Thus
35863 ** when (mUsed+1==(1 << nEntry)) the block is completely full.
35865 ** Each time a slot within a block is freed, the block is moved to the start
35866 ** of the linked-list. And if a block becomes completely full, then it is
35867 ** moved to the end of the list. As a result, when searching for a free
35868 ** slot, only the first block in the list need be examined. If it is full,
35869 ** then it is guaranteed that all blocks are full.
35871 struct PGroupBlockList {
35872 int nByte; /* Size of each allocation in bytes */
35873 PGroupBlock *pFirst; /* First PGroupBlock in list */
35874 PGroupBlock *pLast; /* Last PGroupBlock in list */
35875 PGroupBlockList *pNext; /* Next block-list attached to group */
35878 struct PGroupBlock {
35879 Bitmask mUsed; /* Mask of used slots */
35880 int nEntry; /* Maximum number of allocations in aData[] */
35881 u8 *aData; /* Pointer to data block */
35882 PGroupBlock *pNext; /* Next PGroupBlock in list */
35883 PGroupBlock *pPrev; /* Previous PGroupBlock in list */
35884 PGroupBlockList *pList; /* Owner list */
35887 /* Minimum value for PGroupBlock.nEntry */
35888 #define PAGECACHE_BLOCKALLOC_MINENTRY 15
35890 /* Each page cache is an instance of the following object. Every
35891 ** open database file (including each in-memory database and each
35892 ** temporary or transient database) has a single page cache which
35893 ** is an instance of this object.
35895 ** Pointers to structures of this type are cast and returned as
35896 ** opaque sqlite3_pcache* handles.
35898 struct PCache1 {
35899 /* Cache configuration parameters. Page size (szPage) and the purgeable
35900 ** flag (bPurgeable) are set when the cache is created. nMax may be
35901 ** modified at any time by a call to the pcache1CacheSize() method.
35902 ** The PGroup mutex must be held when accessing nMax.
35904 PGroup *pGroup; /* PGroup this cache belongs to */
35905 int szPage; /* Size of allocated pages in bytes */
35906 int bPurgeable; /* True if cache is purgeable */
35907 unsigned int nMin; /* Minimum number of pages reserved */
35908 unsigned int nMax; /* Configured "cache_size" value */
35909 unsigned int n90pct; /* nMax*9/10 */
35911 /* Hash table of all pages. The following variables may only be accessed
35912 ** when the accessor is holding the PGroup mutex.
35914 unsigned int nRecyclable; /* Number of pages in the LRU list */
35915 unsigned int nPage; /* Total number of pages in apHash */
35916 unsigned int nHash; /* Number of slots in apHash[] */
35917 PgHdr1 **apHash; /* Hash table for fast lookup by key */
35919 unsigned int iMaxKey; /* Largest key seen since xTruncate() */
35923 ** Each cache entry is represented by an instance of the following
35924 ** structure. A buffer of PgHdr1.pCache->szPage bytes is allocated
35925 ** directly before this structure in memory (see the PGHDR1_TO_PAGE()
35926 ** macro below).
35928 struct PgHdr1 {
35929 unsigned int iKey; /* Key value (page number) */
35930 PgHdr1 *pNext; /* Next in hash table chain */
35931 PCache1 *pCache; /* Cache that currently owns this page */
35932 PgHdr1 *pLruNext; /* Next in LRU list of unpinned pages */
35933 PgHdr1 *pLruPrev; /* Previous in LRU list of unpinned pages */
35937 ** Free slots in the allocator used to divide up the buffer provided using
35938 ** the SQLITE_CONFIG_PAGECACHE mechanism.
35940 struct PgFreeslot {
35941 PgFreeslot *pNext; /* Next free slot */
35945 ** Global data used by this cache.
35947 static SQLITE_WSD struct PCacheGlobal {
35948 PGroup grp; /* The global PGroup for mode (2) */
35950 /* Variables related to SQLITE_CONFIG_PAGECACHE settings. The
35951 ** szSlot, nSlot, pStart, pEnd, nReserve, and isInit values are all
35952 ** fixed at sqlite3_initialize() time and do not require mutex protection.
35953 ** The nFreeSlot and pFree values do require mutex protection.
35955 int isInit; /* True if initialized */
35956 int szSlot; /* Size of each free slot */
35957 int nSlot; /* The number of pcache slots */
35958 int nReserve; /* Try to keep nFreeSlot above this */
35959 void *pStart, *pEnd; /* Bounds of pagecache malloc range */
35960 /* Above requires no mutex. Use mutex below for variable that follow. */
35961 sqlite3_mutex *mutex; /* Mutex for accessing the following: */
35962 int nFreeSlot; /* Number of unused pcache slots */
35963 PgFreeslot *pFree; /* Free page blocks */
35964 /* The following value requires a mutex to change. We skip the mutex on
35965 ** reading because (1) most platforms read a 32-bit integer atomically and
35966 ** (2) even if an incorrect value is read, no great harm is done since this
35967 ** is really just an optimization. */
35968 int bUnderPressure; /* True if low on PAGECACHE memory */
35969 } pcache1_g;
35972 ** All code in this file should access the global structure above via the
35973 ** alias "pcache1". This ensures that the WSD emulation is used when
35974 ** compiling for systems that do not support real WSD.
35976 #define pcache1 (GLOBAL(struct PCacheGlobal, pcache1_g))
35979 ** When a PgHdr1 structure is allocated, the associated PCache1.szPage
35980 ** bytes of data are located directly before it in memory (i.e. the total
35981 ** size of the allocation is sizeof(PgHdr1)+PCache1.szPage byte). The
35982 ** PGHDR1_TO_PAGE() macro takes a pointer to a PgHdr1 structure as
35983 ** an argument and returns a pointer to the associated block of szPage
35984 ** bytes. The PAGE_TO_PGHDR1() macro does the opposite: its argument is
35985 ** a pointer to a block of szPage bytes of data and the return value is
35986 ** a pointer to the associated PgHdr1 structure.
35988 ** assert( PGHDR1_TO_PAGE(PAGE_TO_PGHDR1(pCache, X))==X );
35990 #define PGHDR1_TO_PAGE(p) (void*)(((char*)p) - p->pCache->szPage)
35991 #define PAGE_TO_PGHDR1(c, p) (PgHdr1*)(((char*)p) + c->szPage)
35994 ** Blocks used by the SQLITE_PAGECACHE_BLOCKALLOC blocks to store/retrieve
35995 ** a PGroupBlock pointer based on a pointer to a page buffer.
35997 #define PAGE_SET_BLOCKPTR(pCache, pPg, pBlock) \
35998 ( *(PGroupBlock **)&(((u8*)pPg)[sizeof(PgHdr1) + pCache->szPage]) = pBlock )
36000 #define PAGE_GET_BLOCKPTR(pCache, pPg) \
36001 ( *(PGroupBlock **)&(((u8*)pPg)[sizeof(PgHdr1) + pCache->szPage]) )
36005 ** Macros to enter and leave the PCache LRU mutex.
36007 #define pcache1EnterMutex(X) sqlite3_mutex_enter((X)->mutex)
36008 #define pcache1LeaveMutex(X) sqlite3_mutex_leave((X)->mutex)
36010 /******************************************************************************/
36011 /******** Page Allocation/SQLITE_CONFIG_PCACHE Related Functions **************/
36014 ** This function is called during initialization if a static buffer is
36015 ** supplied to use for the page-cache by passing the SQLITE_CONFIG_PAGECACHE
36016 ** verb to sqlite3_config(). Parameter pBuf points to an allocation large
36017 ** enough to contain 'n' buffers of 'sz' bytes each.
36019 ** This routine is called from sqlite3_initialize() and so it is guaranteed
36020 ** to be serialized already. There is no need for further mutexing.
36022 SQLITE_PRIVATE void sqlite3PCacheBufferSetup(void *pBuf, int sz, int n){
36023 if( pcache1.isInit ){
36024 PgFreeslot *p;
36025 sz = ROUNDDOWN8(sz);
36026 pcache1.szSlot = sz;
36027 pcache1.nSlot = pcache1.nFreeSlot = n;
36028 pcache1.nReserve = n>90 ? 10 : (n/10 + 1);
36029 pcache1.pStart = pBuf;
36030 pcache1.pFree = 0;
36031 pcache1.bUnderPressure = 0;
36032 while( n-- ){
36033 p = (PgFreeslot*)pBuf;
36034 p->pNext = pcache1.pFree;
36035 pcache1.pFree = p;
36036 pBuf = (void*)&((char*)pBuf)[sz];
36038 pcache1.pEnd = pBuf;
36043 ** Malloc function used within this file to allocate space from the buffer
36044 ** configured using sqlite3_config(SQLITE_CONFIG_PAGECACHE) option. If no
36045 ** such buffer exists or there is no space left in it, this function falls
36046 ** back to sqlite3Malloc().
36048 ** Multiple threads can run this routine at the same time. Global variables
36049 ** in pcache1 need to be protected via mutex.
36051 static void *pcache1Alloc(int nByte){
36052 void *p = 0;
36053 assert( sqlite3_mutex_notheld(pcache1.grp.mutex) );
36054 sqlite3StatusSet(SQLITE_STATUS_PAGECACHE_SIZE, nByte);
36055 if( nByte<=pcache1.szSlot ){
36056 sqlite3_mutex_enter(pcache1.mutex);
36057 p = (PgHdr1 *)pcache1.pFree;
36058 if( p ){
36059 pcache1.pFree = pcache1.pFree->pNext;
36060 pcache1.nFreeSlot--;
36061 pcache1.bUnderPressure = pcache1.nFreeSlot<pcache1.nReserve;
36062 assert( pcache1.nFreeSlot>=0 );
36063 sqlite3StatusAdd(SQLITE_STATUS_PAGECACHE_USED, 1);
36065 sqlite3_mutex_leave(pcache1.mutex);
36067 if( p==0 ){
36068 /* Memory is not available in the SQLITE_CONFIG_PAGECACHE pool. Get
36069 ** it from sqlite3Malloc instead.
36071 p = sqlite3Malloc(nByte);
36072 if( p ){
36073 int sz = sqlite3MallocSize(p);
36074 sqlite3_mutex_enter(pcache1.mutex);
36075 sqlite3StatusAdd(SQLITE_STATUS_PAGECACHE_OVERFLOW, sz);
36076 sqlite3_mutex_leave(pcache1.mutex);
36078 sqlite3MemdebugSetType(p, MEMTYPE_PCACHE);
36080 return p;
36084 ** Free an allocated buffer obtained from pcache1Alloc().
36086 static void pcache1Free(void *p){
36087 if( p==0 ) return;
36088 if( p>=pcache1.pStart && p<pcache1.pEnd ){
36089 PgFreeslot *pSlot;
36090 sqlite3_mutex_enter(pcache1.mutex);
36091 sqlite3StatusAdd(SQLITE_STATUS_PAGECACHE_USED, -1);
36092 pSlot = (PgFreeslot*)p;
36093 pSlot->pNext = pcache1.pFree;
36094 pcache1.pFree = pSlot;
36095 pcache1.nFreeSlot++;
36096 pcache1.bUnderPressure = pcache1.nFreeSlot<pcache1.nReserve;
36097 assert( pcache1.nFreeSlot<=pcache1.nSlot );
36098 sqlite3_mutex_leave(pcache1.mutex);
36099 }else{
36100 int iSize;
36101 assert( sqlite3MemdebugHasType(p, MEMTYPE_PCACHE) );
36102 sqlite3MemdebugSetType(p, MEMTYPE_HEAP);
36103 iSize = sqlite3MallocSize(p);
36104 sqlite3_mutex_enter(pcache1.mutex);
36105 sqlite3StatusAdd(SQLITE_STATUS_PAGECACHE_OVERFLOW, -iSize);
36106 sqlite3_mutex_leave(pcache1.mutex);
36107 sqlite3_free(p);
36111 #ifdef SQLITE_ENABLE_MEMORY_MANAGEMENT
36113 ** Return the size of a pcache allocation
36115 static int pcache1MemSize(void *p){
36116 if( p>=pcache1.pStart && p<pcache1.pEnd ){
36117 return pcache1.szSlot;
36118 }else{
36119 int iSize;
36120 assert( sqlite3MemdebugHasType(p, MEMTYPE_PCACHE) );
36121 sqlite3MemdebugSetType(p, MEMTYPE_HEAP);
36122 iSize = sqlite3MallocSize(p);
36123 sqlite3MemdebugSetType(p, MEMTYPE_PCACHE);
36124 return iSize;
36127 #endif /* SQLITE_ENABLE_MEMORY_MANAGEMENT */
36129 #ifdef SQLITE_PAGECACHE_BLOCKALLOC
36131 ** The block pBlock belongs to list pList but is not currently linked in.
36132 ** Insert it into the start of the list.
36134 static void addBlockToList(PGroupBlockList *pList, PGroupBlock *pBlock){
36135 pBlock->pPrev = 0;
36136 pBlock->pNext = pList->pFirst;
36137 pList->pFirst = pBlock;
36138 if( pBlock->pNext ){
36139 pBlock->pNext->pPrev = pBlock;
36140 }else{
36141 assert( pList->pLast==0 );
36142 pList->pLast = pBlock;
36147 ** If there are no blocks in the list headed by pList, remove pList
36148 ** from the pGroup->pBlockList list and free it with sqlite3_free().
36150 static void freeListIfEmpty(PGroup *pGroup, PGroupBlockList *pList){
36151 assert( sqlite3_mutex_held(pGroup->mutex) );
36152 if( pList->pFirst==0 ){
36153 PGroupBlockList **pp;
36154 for(pp=&pGroup->pBlockList; *pp!=pList; pp=&(*pp)->pNext);
36155 *pp = (*pp)->pNext;
36156 sqlite3_free(pList);
36159 #endif /* SQLITE_PAGECACHE_BLOCKALLOC */
36162 ** Allocate a new page object initially associated with cache pCache.
36164 static PgHdr1 *pcache1AllocPage(PCache1 *pCache){
36165 int nByte = sizeof(PgHdr1) + pCache->szPage;
36166 void *pPg = 0;
36167 PgHdr1 *p;
36169 #ifdef SQLITE_PAGECACHE_BLOCKALLOC
36170 PGroup *pGroup = pCache->pGroup;
36171 PGroupBlockList *pList;
36172 PGroupBlock *pBlock;
36173 int i;
36175 nByte += sizeof(PGroupBlockList *);
36176 nByte = ROUND8(nByte);
36178 for(pList=pGroup->pBlockList; pList; pList=pList->pNext){
36179 if( pList->nByte==nByte ) break;
36181 if( pList==0 ){
36182 PGroupBlockList *pNew;
36183 assert( pGroup->isBusy==0 );
36184 assert( sqlite3_mutex_held(pGroup->mutex) );
36185 pGroup->isBusy = 1; /* Disable sqlite3PcacheReleaseMemory() */
36186 pNew = (PGroupBlockList *)sqlite3MallocZero(sizeof(PGroupBlockList));
36187 pGroup->isBusy = 0; /* Reenable sqlite3PcacheReleaseMemory() */
36188 if( pNew==0 ){
36189 /* malloc() failure. Return early. */
36190 return 0;
36192 #ifdef SQLITE_DEBUG
36193 for(pList=pGroup->pBlockList; pList; pList=pList->pNext){
36194 assert( pList->nByte!=nByte );
36196 #endif
36197 pNew->nByte = nByte;
36198 pNew->pNext = pGroup->pBlockList;
36199 pGroup->pBlockList = pNew;
36200 pList = pNew;
36203 pBlock = pList->pFirst;
36204 if( pBlock==0 || pBlock->mUsed==(((Bitmask)1<<pBlock->nEntry)-1) ){
36205 int sz;
36207 /* Allocate a new block. Try to allocate enough space for the PGroupBlock
36208 ** structure and MINENTRY allocations of nByte bytes each. If the
36209 ** allocator returns more memory than requested, then more than MINENTRY
36210 ** allocations may fit in it. */
36211 assert( sqlite3_mutex_held(pGroup->mutex) );
36212 pcache1LeaveMutex(pCache->pGroup);
36213 sz = sizeof(PGroupBlock) + PAGECACHE_BLOCKALLOC_MINENTRY * nByte;
36214 pBlock = (PGroupBlock *)sqlite3Malloc(sz);
36215 pcache1EnterMutex(pCache->pGroup);
36217 if( !pBlock ){
36218 freeListIfEmpty(pGroup, pList);
36219 return 0;
36221 pBlock->nEntry = (sqlite3MallocSize(pBlock) - sizeof(PGroupBlock)) / nByte;
36222 if( pBlock->nEntry>=BMS ){
36223 pBlock->nEntry = BMS-1;
36225 pBlock->pList = pList;
36226 pBlock->mUsed = 0;
36227 pBlock->aData = (u8 *)&pBlock[1];
36228 addBlockToList(pList, pBlock);
36230 sz = sqlite3MallocSize(pBlock);
36231 sqlite3_mutex_enter(pcache1.mutex);
36232 sqlite3StatusAdd(SQLITE_STATUS_PAGECACHE_OVERFLOW, sz);
36233 sqlite3_mutex_leave(pcache1.mutex);
36236 for(i=0; pPg==0 && ALWAYS(i<pBlock->nEntry); i++){
36237 if( 0==(pBlock->mUsed & ((Bitmask)1<<i)) ){
36238 pBlock->mUsed |= ((Bitmask)1<<i);
36239 pPg = (void *)&pBlock->aData[pList->nByte * i];
36242 assert( pPg );
36243 PAGE_SET_BLOCKPTR(pCache, pPg, pBlock);
36245 /* If the block is now full, shift it to the end of the list */
36246 if( pBlock->mUsed==(((Bitmask)1<<pBlock->nEntry)-1) && pList->pLast!=pBlock ){
36247 assert( pList->pFirst==pBlock );
36248 assert( pBlock->pPrev==0 );
36249 assert( pList->pLast->pNext==0 );
36250 pList->pFirst = pBlock->pNext;
36251 pList->pFirst->pPrev = 0;
36252 pBlock->pPrev = pList->pLast;
36253 pBlock->pNext = 0;
36254 pList->pLast->pNext = pBlock;
36255 pList->pLast = pBlock;
36257 p = PAGE_TO_PGHDR1(pCache, pPg);
36258 if( pCache->bPurgeable ){
36259 pCache->pGroup->nCurrentPage++;
36261 #else
36262 /* The group mutex must be released before pcache1Alloc() is called. This
36263 ** is because it may call sqlite3_release_memory(), which assumes that
36264 ** this mutex is not held. */
36265 assert( sqlite3_mutex_held(pCache->pGroup->mutex) );
36266 pcache1LeaveMutex(pCache->pGroup);
36267 pPg = pcache1Alloc(nByte);
36268 pcache1EnterMutex(pCache->pGroup);
36269 if( pPg ){
36270 p = PAGE_TO_PGHDR1(pCache, pPg);
36271 if( pCache->bPurgeable ){
36272 pCache->pGroup->nCurrentPage++;
36274 }else{
36275 p = 0;
36277 #endif
36278 return p;
36282 ** Free a page object allocated by pcache1AllocPage().
36284 ** The pointer is allowed to be NULL, which is prudent. But it turns out
36285 ** that the current implementation happens to never call this routine
36286 ** with a NULL pointer, so we mark the NULL test with ALWAYS().
36288 static void pcache1FreePage(PgHdr1 *p){
36289 if( ALWAYS(p) ){
36290 PCache1 *pCache = p->pCache;
36291 void *pPg = PGHDR1_TO_PAGE(p);
36293 #ifdef SQLITE_PAGECACHE_BLOCKALLOC
36294 PGroupBlock *pBlock = PAGE_GET_BLOCKPTR(pCache, pPg);
36295 PGroupBlockList *pList = pBlock->pList;
36296 int i = ((u8 *)pPg - pBlock->aData) / pList->nByte;
36298 assert( pPg==(void *)&pBlock->aData[i*pList->nByte] );
36299 assert( pBlock->mUsed & ((Bitmask)1<<i) );
36300 pBlock->mUsed &= ~((Bitmask)1<<i);
36302 /* Remove the block from the list. If it is completely empty, free it.
36303 ** Or if it is not completely empty, re-insert it at the start of the
36304 ** list. */
36305 if( pList->pFirst==pBlock ){
36306 pList->pFirst = pBlock->pNext;
36307 if( pList->pFirst ) pList->pFirst->pPrev = 0;
36308 }else{
36309 pBlock->pPrev->pNext = pBlock->pNext;
36311 if( pList->pLast==pBlock ){
36312 pList->pLast = pBlock->pPrev;
36313 if( pList->pLast ) pList->pLast->pNext = 0;
36314 }else{
36315 pBlock->pNext->pPrev = pBlock->pPrev;
36318 if( pBlock->mUsed==0 ){
36319 PGroup *pGroup = p->pCache->pGroup;
36321 int sz = sqlite3MallocSize(pBlock);
36322 sqlite3_mutex_enter(pcache1.mutex);
36323 sqlite3StatusAdd(SQLITE_STATUS_PAGECACHE_OVERFLOW, -sz);
36324 sqlite3_mutex_leave(pcache1.mutex);
36325 freeListIfEmpty(pGroup, pList);
36326 sqlite3_free(pBlock);
36327 }else{
36328 addBlockToList(pList, pBlock);
36330 #else
36331 assert( sqlite3_mutex_held(p->pCache->pGroup->mutex) );
36332 pcache1Free(pPg);
36333 #endif
36334 if( pCache->bPurgeable ){
36335 pCache->pGroup->nCurrentPage--;
36341 ** Malloc function used by SQLite to obtain space from the buffer configured
36342 ** using sqlite3_config(SQLITE_CONFIG_PAGECACHE) option. If no such buffer
36343 ** exists, this function falls back to sqlite3Malloc().
36345 SQLITE_PRIVATE void *sqlite3PageMalloc(int sz){
36346 return pcache1Alloc(sz);
36350 ** Free an allocated buffer obtained from sqlite3PageMalloc().
36352 SQLITE_PRIVATE void sqlite3PageFree(void *p){
36353 pcache1Free(p);
36358 ** Return true if it desirable to avoid allocating a new page cache
36359 ** entry.
36361 ** If memory was allocated specifically to the page cache using
36362 ** SQLITE_CONFIG_PAGECACHE but that memory has all been used, then
36363 ** it is desirable to avoid allocating a new page cache entry because
36364 ** presumably SQLITE_CONFIG_PAGECACHE was suppose to be sufficient
36365 ** for all page cache needs and we should not need to spill the
36366 ** allocation onto the heap.
36368 ** Or, the heap is used for all page cache memory put the heap is
36369 ** under memory pressure, then again it is desirable to avoid
36370 ** allocating a new page cache entry in order to avoid stressing
36371 ** the heap even further.
36373 static int pcache1UnderMemoryPressure(PCache1 *pCache){
36374 if( pcache1.nSlot && pCache->szPage<=pcache1.szSlot ){
36375 return pcache1.bUnderPressure;
36376 }else{
36377 return sqlite3HeapNearlyFull();
36381 /******************************************************************************/
36382 /******** General Implementation Functions ************************************/
36385 ** This function is used to resize the hash table used by the cache passed
36386 ** as the first argument.
36388 ** The PCache mutex must be held when this function is called.
36390 static int pcache1ResizeHash(PCache1 *p){
36391 PgHdr1 **apNew;
36392 unsigned int nNew;
36393 unsigned int i;
36395 assert( sqlite3_mutex_held(p->pGroup->mutex) );
36397 nNew = p->nHash*2;
36398 if( nNew<256 ){
36399 nNew = 256;
36402 pcache1LeaveMutex(p->pGroup);
36403 if( p->nHash ){ sqlite3BeginBenignMalloc(); }
36404 apNew = (PgHdr1 **)sqlite3_malloc(sizeof(PgHdr1 *)*nNew);
36405 if( p->nHash ){ sqlite3EndBenignMalloc(); }
36406 pcache1EnterMutex(p->pGroup);
36407 if( apNew ){
36408 memset(apNew, 0, sizeof(PgHdr1 *)*nNew);
36409 for(i=0; i<p->nHash; i++){
36410 PgHdr1 *pPage;
36411 PgHdr1 *pNext = p->apHash[i];
36412 while( (pPage = pNext)!=0 ){
36413 unsigned int h = pPage->iKey % nNew;
36414 pNext = pPage->pNext;
36415 pPage->pNext = apNew[h];
36416 apNew[h] = pPage;
36419 sqlite3_free(p->apHash);
36420 p->apHash = apNew;
36421 p->nHash = nNew;
36424 return (p->apHash ? SQLITE_OK : SQLITE_NOMEM);
36428 ** This function is used internally to remove the page pPage from the
36429 ** PGroup LRU list, if is part of it. If pPage is not part of the PGroup
36430 ** LRU list, then this function is a no-op.
36432 ** The PGroup mutex must be held when this function is called.
36434 ** If pPage is NULL then this routine is a no-op.
36436 static void pcache1PinPage(PgHdr1 *pPage){
36437 PCache1 *pCache;
36438 PGroup *pGroup;
36440 if( pPage==0 ) return;
36441 pCache = pPage->pCache;
36442 pGroup = pCache->pGroup;
36443 assert( sqlite3_mutex_held(pGroup->mutex) );
36444 if( pPage->pLruNext || pPage==pGroup->pLruTail ){
36445 if( pPage->pLruPrev ){
36446 pPage->pLruPrev->pLruNext = pPage->pLruNext;
36448 if( pPage->pLruNext ){
36449 pPage->pLruNext->pLruPrev = pPage->pLruPrev;
36451 if( pGroup->pLruHead==pPage ){
36452 pGroup->pLruHead = pPage->pLruNext;
36454 if( pGroup->pLruTail==pPage ){
36455 pGroup->pLruTail = pPage->pLruPrev;
36457 pPage->pLruNext = 0;
36458 pPage->pLruPrev = 0;
36459 pPage->pCache->nRecyclable--;
36465 ** Remove the page supplied as an argument from the hash table
36466 ** (PCache1.apHash structure) that it is currently stored in.
36468 ** The PGroup mutex must be held when this function is called.
36470 static void pcache1RemoveFromHash(PgHdr1 *pPage){
36471 unsigned int h;
36472 PCache1 *pCache = pPage->pCache;
36473 PgHdr1 **pp;
36475 assert( sqlite3_mutex_held(pCache->pGroup->mutex) );
36476 h = pPage->iKey % pCache->nHash;
36477 for(pp=&pCache->apHash[h]; (*pp)!=pPage; pp=&(*pp)->pNext);
36478 *pp = (*pp)->pNext;
36480 pCache->nPage--;
36484 ** If there are currently more than nMaxPage pages allocated, try
36485 ** to recycle pages to reduce the number allocated to nMaxPage.
36487 static void pcache1EnforceMaxPage(PGroup *pGroup){
36488 assert( sqlite3_mutex_held(pGroup->mutex) );
36489 while( pGroup->nCurrentPage>pGroup->nMaxPage && pGroup->pLruTail ){
36490 PgHdr1 *p = pGroup->pLruTail;
36491 assert( p->pCache->pGroup==pGroup );
36492 pcache1PinPage(p);
36493 pcache1RemoveFromHash(p);
36494 pcache1FreePage(p);
36499 ** Discard all pages from cache pCache with a page number (key value)
36500 ** greater than or equal to iLimit. Any pinned pages that meet this
36501 ** criteria are unpinned before they are discarded.
36503 ** The PCache mutex must be held when this function is called.
36505 static void pcache1TruncateUnsafe(
36506 PCache1 *pCache, /* The cache to truncate */
36507 unsigned int iLimit /* Drop pages with this pgno or larger */
36509 TESTONLY( unsigned int nPage = 0; ) /* To assert pCache->nPage is correct */
36510 unsigned int h;
36511 assert( sqlite3_mutex_held(pCache->pGroup->mutex) );
36512 for(h=0; h<pCache->nHash; h++){
36513 PgHdr1 **pp = &pCache->apHash[h];
36514 PgHdr1 *pPage;
36515 while( (pPage = *pp)!=0 ){
36516 if( pPage->iKey>=iLimit ){
36517 pCache->nPage--;
36518 *pp = pPage->pNext;
36519 pcache1PinPage(pPage);
36520 pcache1FreePage(pPage);
36521 }else{
36522 pp = &pPage->pNext;
36523 TESTONLY( nPage++; )
36527 assert( pCache->nPage==nPage );
36530 /******************************************************************************/
36531 /******** sqlite3_pcache Methods **********************************************/
36534 ** Implementation of the sqlite3_pcache.xInit method.
36536 static int pcache1Init(void *NotUsed){
36537 UNUSED_PARAMETER(NotUsed);
36538 assert( pcache1.isInit==0 );
36539 memset(&pcache1, 0, sizeof(pcache1));
36540 if( sqlite3GlobalConfig.bCoreMutex ){
36541 pcache1.grp.mutex = sqlite3_mutex_alloc(SQLITE_MUTEX_STATIC_LRU);
36542 pcache1.mutex = sqlite3_mutex_alloc(SQLITE_MUTEX_STATIC_PMEM);
36544 pcache1.grp.mxPinned = 10;
36545 pcache1.isInit = 1;
36546 return SQLITE_OK;
36550 ** Implementation of the sqlite3_pcache.xShutdown method.
36551 ** Note that the static mutex allocated in xInit does
36552 ** not need to be freed.
36554 static void pcache1Shutdown(void *NotUsed){
36555 UNUSED_PARAMETER(NotUsed);
36556 assert( pcache1.isInit!=0 );
36557 memset(&pcache1, 0, sizeof(pcache1));
36561 ** Implementation of the sqlite3_pcache.xCreate method.
36563 ** Allocate a new cache.
36565 static sqlite3_pcache *pcache1Create(int szPage, int bPurgeable){
36566 PCache1 *pCache; /* The newly created page cache */
36567 PGroup *pGroup; /* The group the new page cache will belong to */
36568 int sz; /* Bytes of memory required to allocate the new cache */
36571 ** The seperateCache variable is true if each PCache has its own private
36572 ** PGroup. In other words, separateCache is true for mode (1) where no
36573 ** mutexing is required.
36575 ** * Always use a unified cache (mode-2) if ENABLE_MEMORY_MANAGEMENT
36577 ** * Always use a unified cache in single-threaded applications
36579 ** * Otherwise (if multi-threaded and ENABLE_MEMORY_MANAGEMENT is off)
36580 ** use separate caches (mode-1)
36582 #if defined(SQLITE_ENABLE_MEMORY_MANAGEMENT) || SQLITE_THREADSAFE==0
36583 const int separateCache = 0;
36584 #else
36585 int separateCache = sqlite3GlobalConfig.bCoreMutex>0;
36586 #endif
36588 sz = sizeof(PCache1) + sizeof(PGroup)*separateCache;
36589 pCache = (PCache1 *)sqlite3_malloc(sz);
36590 if( pCache ){
36591 memset(pCache, 0, sz);
36592 if( separateCache ){
36593 pGroup = (PGroup*)&pCache[1];
36594 pGroup->mxPinned = 10;
36595 }else{
36596 pGroup = &pcache1.grp;
36598 pCache->pGroup = pGroup;
36599 pCache->szPage = szPage;
36600 pCache->bPurgeable = (bPurgeable ? 1 : 0);
36601 if( bPurgeable ){
36602 pCache->nMin = 10;
36603 pcache1EnterMutex(pGroup);
36604 pGroup->nMinPage += pCache->nMin;
36605 pGroup->mxPinned = pGroup->nMaxPage + 10 - pGroup->nMinPage;
36606 pcache1LeaveMutex(pGroup);
36609 return (sqlite3_pcache *)pCache;
36613 ** Implementation of the sqlite3_pcache.xCachesize method.
36615 ** Configure the cache_size limit for a cache.
36617 static void pcache1Cachesize(sqlite3_pcache *p, int nMax){
36618 PCache1 *pCache = (PCache1 *)p;
36619 if( pCache->bPurgeable ){
36620 PGroup *pGroup = pCache->pGroup;
36621 pcache1EnterMutex(pGroup);
36622 pGroup->nMaxPage += (nMax - pCache->nMax);
36623 pGroup->mxPinned = pGroup->nMaxPage + 10 - pGroup->nMinPage;
36624 pCache->nMax = nMax;
36625 pCache->n90pct = pCache->nMax*9/10;
36626 pcache1EnforceMaxPage(pGroup);
36627 pcache1LeaveMutex(pGroup);
36632 ** Implementation of the sqlite3_pcache.xPagecount method.
36634 static int pcache1Pagecount(sqlite3_pcache *p){
36635 int n;
36636 PCache1 *pCache = (PCache1*)p;
36637 pcache1EnterMutex(pCache->pGroup);
36638 n = pCache->nPage;
36639 pcache1LeaveMutex(pCache->pGroup);
36640 return n;
36644 ** Implementation of the sqlite3_pcache.xFetch method.
36646 ** Fetch a page by key value.
36648 ** Whether or not a new page may be allocated by this function depends on
36649 ** the value of the createFlag argument. 0 means do not allocate a new
36650 ** page. 1 means allocate a new page if space is easily available. 2
36651 ** means to try really hard to allocate a new page.
36653 ** For a non-purgeable cache (a cache used as the storage for an in-memory
36654 ** database) there is really no difference between createFlag 1 and 2. So
36655 ** the calling function (pcache.c) will never have a createFlag of 1 on
36656 ** a non-purgable cache.
36658 ** There are three different approaches to obtaining space for a page,
36659 ** depending on the value of parameter createFlag (which may be 0, 1 or 2).
36661 ** 1. Regardless of the value of createFlag, the cache is searched for a
36662 ** copy of the requested page. If one is found, it is returned.
36664 ** 2. If createFlag==0 and the page is not already in the cache, NULL is
36665 ** returned.
36667 ** 3. If createFlag is 1, and the page is not already in the cache, then
36668 ** return NULL (do not allocate a new page) if any of the following
36669 ** conditions are true:
36671 ** (a) the number of pages pinned by the cache is greater than
36672 ** PCache1.nMax, or
36674 ** (b) the number of pages pinned by the cache is greater than
36675 ** the sum of nMax for all purgeable caches, less the sum of
36676 ** nMin for all other purgeable caches, or
36678 ** 4. If none of the first three conditions apply and the cache is marked
36679 ** as purgeable, and if one of the following is true:
36681 ** (a) The number of pages allocated for the cache is already
36682 ** PCache1.nMax, or
36684 ** (b) The number of pages allocated for all purgeable caches is
36685 ** already equal to or greater than the sum of nMax for all
36686 ** purgeable caches,
36688 ** (c) The system is under memory pressure and wants to avoid
36689 ** unnecessary pages cache entry allocations
36691 ** then attempt to recycle a page from the LRU list. If it is the right
36692 ** size, return the recycled buffer. Otherwise, free the buffer and
36693 ** proceed to step 5.
36695 ** 5. Otherwise, allocate and return a new page buffer.
36697 static void *pcache1Fetch(sqlite3_pcache *p, unsigned int iKey, int createFlag){
36698 int nPinned;
36699 PCache1 *pCache = (PCache1 *)p;
36700 PGroup *pGroup;
36701 PgHdr1 *pPage = 0;
36703 assert( pCache->bPurgeable || createFlag!=1 );
36704 assert( pCache->bPurgeable || pCache->nMin==0 );
36705 assert( pCache->bPurgeable==0 || pCache->nMin==10 );
36706 assert( pCache->nMin==0 || pCache->bPurgeable );
36707 pcache1EnterMutex(pGroup = pCache->pGroup);
36709 /* Step 1: Search the hash table for an existing entry. */
36710 if( pCache->nHash>0 ){
36711 unsigned int h = iKey % pCache->nHash;
36712 for(pPage=pCache->apHash[h]; pPage&&pPage->iKey!=iKey; pPage=pPage->pNext);
36715 /* Step 2: Abort if no existing page is found and createFlag is 0 */
36716 if( pPage || createFlag==0 ){
36717 pcache1PinPage(pPage);
36718 goto fetch_out;
36721 /* The pGroup local variable will normally be initialized by the
36722 ** pcache1EnterMutex() macro above. But if SQLITE_MUTEX_OMIT is defined,
36723 ** then pcache1EnterMutex() is a no-op, so we have to initialize the
36724 ** local variable here. Delaying the initialization of pGroup is an
36725 ** optimization: The common case is to exit the module before reaching
36726 ** this point.
36728 #ifdef SQLITE_MUTEX_OMIT
36729 pGroup = pCache->pGroup;
36730 #endif
36733 /* Step 3: Abort if createFlag is 1 but the cache is nearly full */
36734 nPinned = pCache->nPage - pCache->nRecyclable;
36735 assert( nPinned>=0 );
36736 assert( pGroup->mxPinned == pGroup->nMaxPage + 10 - pGroup->nMinPage );
36737 assert( pCache->n90pct == pCache->nMax*9/10 );
36738 if( createFlag==1 && (
36739 nPinned>=pGroup->mxPinned
36740 || nPinned>=(int)pCache->n90pct
36741 || pcache1UnderMemoryPressure(pCache)
36743 goto fetch_out;
36746 if( pCache->nPage>=pCache->nHash && pcache1ResizeHash(pCache) ){
36747 goto fetch_out;
36750 /* Step 4. Try to recycle a page. */
36751 if( pCache->bPurgeable && pGroup->pLruTail && (
36752 (pCache->nPage+1>=pCache->nMax)
36753 || pGroup->nCurrentPage>=pGroup->nMaxPage
36754 || pcache1UnderMemoryPressure(pCache)
36756 PCache1 *pOtherCache;
36757 pPage = pGroup->pLruTail;
36758 pcache1RemoveFromHash(pPage);
36759 pcache1PinPage(pPage);
36760 if( (pOtherCache = pPage->pCache)->szPage!=pCache->szPage ){
36761 pcache1FreePage(pPage);
36762 pPage = 0;
36763 }else{
36764 pGroup->nCurrentPage -=
36765 (pOtherCache->bPurgeable - pCache->bPurgeable);
36769 /* Step 5. If a usable page buffer has still not been found,
36770 ** attempt to allocate a new one.
36772 if( !pPage ){
36773 if( createFlag==1 ) sqlite3BeginBenignMalloc();
36774 pPage = pcache1AllocPage(pCache);
36775 if( createFlag==1 ) sqlite3EndBenignMalloc();
36778 if( pPage ){
36779 unsigned int h = iKey % pCache->nHash;
36780 pCache->nPage++;
36781 pPage->iKey = iKey;
36782 pPage->pNext = pCache->apHash[h];
36783 pPage->pCache = pCache;
36784 pPage->pLruPrev = 0;
36785 pPage->pLruNext = 0;
36786 *(void **)(PGHDR1_TO_PAGE(pPage)) = 0;
36787 pCache->apHash[h] = pPage;
36790 fetch_out:
36791 if( pPage && iKey>pCache->iMaxKey ){
36792 pCache->iMaxKey = iKey;
36794 pcache1LeaveMutex(pGroup);
36795 return (pPage ? PGHDR1_TO_PAGE(pPage) : 0);
36800 ** Implementation of the sqlite3_pcache.xUnpin method.
36802 ** Mark a page as unpinned (eligible for asynchronous recycling).
36804 static void pcache1Unpin(sqlite3_pcache *p, void *pPg, int reuseUnlikely){
36805 PCache1 *pCache = (PCache1 *)p;
36806 PgHdr1 *pPage = PAGE_TO_PGHDR1(pCache, pPg);
36807 PGroup *pGroup = pCache->pGroup;
36809 assert( pPage->pCache==pCache );
36810 pcache1EnterMutex(pGroup);
36812 /* It is an error to call this function if the page is already
36813 ** part of the PGroup LRU list.
36815 assert( pPage->pLruPrev==0 && pPage->pLruNext==0 );
36816 assert( pGroup->pLruHead!=pPage && pGroup->pLruTail!=pPage );
36818 if( reuseUnlikely || pGroup->nCurrentPage>pGroup->nMaxPage ){
36819 pcache1RemoveFromHash(pPage);
36820 pcache1FreePage(pPage);
36821 }else{
36822 /* Add the page to the PGroup LRU list. */
36823 if( pGroup->pLruHead ){
36824 pGroup->pLruHead->pLruPrev = pPage;
36825 pPage->pLruNext = pGroup->pLruHead;
36826 pGroup->pLruHead = pPage;
36827 }else{
36828 pGroup->pLruTail = pPage;
36829 pGroup->pLruHead = pPage;
36831 pCache->nRecyclable++;
36834 pcache1LeaveMutex(pCache->pGroup);
36838 ** Implementation of the sqlite3_pcache.xRekey method.
36840 static void pcache1Rekey(
36841 sqlite3_pcache *p,
36842 void *pPg,
36843 unsigned int iOld,
36844 unsigned int iNew
36846 PCache1 *pCache = (PCache1 *)p;
36847 PgHdr1 *pPage = PAGE_TO_PGHDR1(pCache, pPg);
36848 PgHdr1 **pp;
36849 unsigned int h;
36850 assert( pPage->iKey==iOld );
36851 assert( pPage->pCache==pCache );
36853 pcache1EnterMutex(pCache->pGroup);
36855 h = iOld%pCache->nHash;
36856 pp = &pCache->apHash[h];
36857 while( (*pp)!=pPage ){
36858 pp = &(*pp)->pNext;
36860 *pp = pPage->pNext;
36862 h = iNew%pCache->nHash;
36863 pPage->iKey = iNew;
36864 pPage->pNext = pCache->apHash[h];
36865 pCache->apHash[h] = pPage;
36866 if( iNew>pCache->iMaxKey ){
36867 pCache->iMaxKey = iNew;
36870 pcache1LeaveMutex(pCache->pGroup);
36874 ** Implementation of the sqlite3_pcache.xTruncate method.
36876 ** Discard all unpinned pages in the cache with a page number equal to
36877 ** or greater than parameter iLimit. Any pinned pages with a page number
36878 ** equal to or greater than iLimit are implicitly unpinned.
36880 static void pcache1Truncate(sqlite3_pcache *p, unsigned int iLimit){
36881 PCache1 *pCache = (PCache1 *)p;
36882 pcache1EnterMutex(pCache->pGroup);
36883 if( iLimit<=pCache->iMaxKey ){
36884 pcache1TruncateUnsafe(pCache, iLimit);
36885 pCache->iMaxKey = iLimit-1;
36887 pcache1LeaveMutex(pCache->pGroup);
36891 ** Implementation of the sqlite3_pcache.xDestroy method.
36893 ** Destroy a cache allocated using pcache1Create().
36895 static void pcache1Destroy(sqlite3_pcache *p){
36896 PCache1 *pCache = (PCache1 *)p;
36897 PGroup *pGroup = pCache->pGroup;
36898 assert( pCache->bPurgeable || (pCache->nMax==0 && pCache->nMin==0) );
36899 pcache1EnterMutex(pGroup);
36900 pcache1TruncateUnsafe(pCache, 0);
36901 pGroup->nMaxPage -= pCache->nMax;
36902 pGroup->nMinPage -= pCache->nMin;
36903 pGroup->mxPinned = pGroup->nMaxPage + 10 - pGroup->nMinPage;
36904 pcache1EnforceMaxPage(pGroup);
36905 pcache1LeaveMutex(pGroup);
36906 sqlite3_free(pCache->apHash);
36907 sqlite3_free(pCache);
36911 ** This function is called during initialization (sqlite3_initialize()) to
36912 ** install the default pluggable cache module, assuming the user has not
36913 ** already provided an alternative.
36915 SQLITE_PRIVATE void sqlite3PCacheSetDefault(void){
36916 static const sqlite3_pcache_methods defaultMethods = {
36917 0, /* pArg */
36918 pcache1Init, /* xInit */
36919 pcache1Shutdown, /* xShutdown */
36920 pcache1Create, /* xCreate */
36921 pcache1Cachesize, /* xCachesize */
36922 pcache1Pagecount, /* xPagecount */
36923 pcache1Fetch, /* xFetch */
36924 pcache1Unpin, /* xUnpin */
36925 pcache1Rekey, /* xRekey */
36926 pcache1Truncate, /* xTruncate */
36927 pcache1Destroy /* xDestroy */
36929 sqlite3_config(SQLITE_CONFIG_PCACHE, &defaultMethods);
36932 #ifdef SQLITE_ENABLE_MEMORY_MANAGEMENT
36934 ** This function is called to free superfluous dynamically allocated memory
36935 ** held by the pager system. Memory in use by any SQLite pager allocated
36936 ** by the current thread may be sqlite3_free()ed.
36938 ** nReq is the number of bytes of memory required. Once this much has
36939 ** been released, the function returns. The return value is the total number
36940 ** of bytes of memory released.
36942 SQLITE_PRIVATE int sqlite3PcacheReleaseMemory(int nReq){
36943 int nFree = 0;
36944 #ifdef SQLITE_PAGECACHE_BLOCKALLOC
36945 if( pcache1.grp.isBusy ) return 0;
36946 #endif
36947 assert( sqlite3_mutex_notheld(pcache1.grp.mutex) );
36948 assert( sqlite3_mutex_notheld(pcache1.mutex) );
36949 if( pcache1.pStart==0 ){
36950 PgHdr1 *p;
36951 pcache1EnterMutex(&pcache1.grp);
36952 while( (nReq<0 || nFree<nReq) && ((p=pcache1.grp.pLruTail)!=0) ){
36953 nFree += pcache1MemSize(PGHDR1_TO_PAGE(p));
36954 pcache1PinPage(p);
36955 pcache1RemoveFromHash(p);
36956 pcache1FreePage(p);
36958 pcache1LeaveMutex(&pcache1.grp);
36960 return nFree;
36962 #endif /* SQLITE_ENABLE_MEMORY_MANAGEMENT */
36964 #ifdef SQLITE_TEST
36966 ** This function is used by test procedures to inspect the internal state
36967 ** of the global cache.
36969 SQLITE_PRIVATE void sqlite3PcacheStats(
36970 int *pnCurrent, /* OUT: Total number of pages cached */
36971 int *pnMax, /* OUT: Global maximum cache size */
36972 int *pnMin, /* OUT: Sum of PCache1.nMin for purgeable caches */
36973 int *pnRecyclable /* OUT: Total number of pages available for recycling */
36975 PgHdr1 *p;
36976 int nRecyclable = 0;
36977 for(p=pcache1.grp.pLruHead; p; p=p->pLruNext){
36978 nRecyclable++;
36980 *pnCurrent = pcache1.grp.nCurrentPage;
36981 *pnMax = pcache1.grp.nMaxPage;
36982 *pnMin = pcache1.grp.nMinPage;
36983 *pnRecyclable = nRecyclable;
36985 #endif
36987 /************** End of pcache1.c *********************************************/
36988 /************** Begin file rowset.c ******************************************/
36990 ** 2008 December 3
36992 ** The author disclaims copyright to this source code. In place of
36993 ** a legal notice, here is a blessing:
36995 ** May you do good and not evil.
36996 ** May you find forgiveness for yourself and forgive others.
36997 ** May you share freely, never taking more than you give.
36999 *************************************************************************
37001 ** This module implements an object we call a "RowSet".
37003 ** The RowSet object is a collection of rowids. Rowids
37004 ** are inserted into the RowSet in an arbitrary order. Inserts
37005 ** can be intermixed with tests to see if a given rowid has been
37006 ** previously inserted into the RowSet.
37008 ** After all inserts are finished, it is possible to extract the
37009 ** elements of the RowSet in sorted order. Once this extraction
37010 ** process has started, no new elements may be inserted.
37012 ** Hence, the primitive operations for a RowSet are:
37014 ** CREATE
37015 ** INSERT
37016 ** TEST
37017 ** SMALLEST
37018 ** DESTROY
37020 ** The CREATE and DESTROY primitives are the constructor and destructor,
37021 ** obviously. The INSERT primitive adds a new element to the RowSet.
37022 ** TEST checks to see if an element is already in the RowSet. SMALLEST
37023 ** extracts the least value from the RowSet.
37025 ** The INSERT primitive might allocate additional memory. Memory is
37026 ** allocated in chunks so most INSERTs do no allocation. There is an
37027 ** upper bound on the size of allocated memory. No memory is freed
37028 ** until DESTROY.
37030 ** The TEST primitive includes a "batch" number. The TEST primitive
37031 ** will only see elements that were inserted before the last change
37032 ** in the batch number. In other words, if an INSERT occurs between
37033 ** two TESTs where the TESTs have the same batch nubmer, then the
37034 ** value added by the INSERT will not be visible to the second TEST.
37035 ** The initial batch number is zero, so if the very first TEST contains
37036 ** a non-zero batch number, it will see all prior INSERTs.
37038 ** No INSERTs may occurs after a SMALLEST. An assertion will fail if
37039 ** that is attempted.
37041 ** The cost of an INSERT is roughly constant. (Sometime new memory
37042 ** has to be allocated on an INSERT.) The cost of a TEST with a new
37043 ** batch number is O(NlogN) where N is the number of elements in the RowSet.
37044 ** The cost of a TEST using the same batch number is O(logN). The cost
37045 ** of the first SMALLEST is O(NlogN). Second and subsequent SMALLEST
37046 ** primitives are constant time. The cost of DESTROY is O(N).
37048 ** There is an added cost of O(N) when switching between TEST and
37049 ** SMALLEST primitives.
37054 ** Target size for allocation chunks.
37056 #define ROWSET_ALLOCATION_SIZE 1024
37059 ** The number of rowset entries per allocation chunk.
37061 #define ROWSET_ENTRY_PER_CHUNK \
37062 ((ROWSET_ALLOCATION_SIZE-8)/sizeof(struct RowSetEntry))
37065 ** Each entry in a RowSet is an instance of the following object.
37067 struct RowSetEntry {
37068 i64 v; /* ROWID value for this entry */
37069 struct RowSetEntry *pRight; /* Right subtree (larger entries) or list */
37070 struct RowSetEntry *pLeft; /* Left subtree (smaller entries) */
37074 ** RowSetEntry objects are allocated in large chunks (instances of the
37075 ** following structure) to reduce memory allocation overhead. The
37076 ** chunks are kept on a linked list so that they can be deallocated
37077 ** when the RowSet is destroyed.
37079 struct RowSetChunk {
37080 struct RowSetChunk *pNextChunk; /* Next chunk on list of them all */
37081 struct RowSetEntry aEntry[ROWSET_ENTRY_PER_CHUNK]; /* Allocated entries */
37085 ** A RowSet in an instance of the following structure.
37087 ** A typedef of this structure if found in sqliteInt.h.
37089 struct RowSet {
37090 struct RowSetChunk *pChunk; /* List of all chunk allocations */
37091 sqlite3 *db; /* The database connection */
37092 struct RowSetEntry *pEntry; /* List of entries using pRight */
37093 struct RowSetEntry *pLast; /* Last entry on the pEntry list */
37094 struct RowSetEntry *pFresh; /* Source of new entry objects */
37095 struct RowSetEntry *pTree; /* Binary tree of entries */
37096 u16 nFresh; /* Number of objects on pFresh */
37097 u8 isSorted; /* True if pEntry is sorted */
37098 u8 iBatch; /* Current insert batch */
37102 ** Turn bulk memory into a RowSet object. N bytes of memory
37103 ** are available at pSpace. The db pointer is used as a memory context
37104 ** for any subsequent allocations that need to occur.
37105 ** Return a pointer to the new RowSet object.
37107 ** It must be the case that N is sufficient to make a Rowset. If not
37108 ** an assertion fault occurs.
37110 ** If N is larger than the minimum, use the surplus as an initial
37111 ** allocation of entries available to be filled.
37113 SQLITE_PRIVATE RowSet *sqlite3RowSetInit(sqlite3 *db, void *pSpace, unsigned int N){
37114 RowSet *p;
37115 assert( N >= ROUND8(sizeof(*p)) );
37116 p = pSpace;
37117 p->pChunk = 0;
37118 p->db = db;
37119 p->pEntry = 0;
37120 p->pLast = 0;
37121 p->pTree = 0;
37122 p->pFresh = (struct RowSetEntry*)(ROUND8(sizeof(*p)) + (char*)p);
37123 p->nFresh = (u16)((N - ROUND8(sizeof(*p)))/sizeof(struct RowSetEntry));
37124 p->isSorted = 1;
37125 p->iBatch = 0;
37126 return p;
37130 ** Deallocate all chunks from a RowSet. This frees all memory that
37131 ** the RowSet has allocated over its lifetime. This routine is
37132 ** the destructor for the RowSet.
37134 SQLITE_PRIVATE void sqlite3RowSetClear(RowSet *p){
37135 struct RowSetChunk *pChunk, *pNextChunk;
37136 for(pChunk=p->pChunk; pChunk; pChunk = pNextChunk){
37137 pNextChunk = pChunk->pNextChunk;
37138 sqlite3DbFree(p->db, pChunk);
37140 p->pChunk = 0;
37141 p->nFresh = 0;
37142 p->pEntry = 0;
37143 p->pLast = 0;
37144 p->pTree = 0;
37145 p->isSorted = 1;
37149 ** Insert a new value into a RowSet.
37151 ** The mallocFailed flag of the database connection is set if a
37152 ** memory allocation fails.
37154 SQLITE_PRIVATE void sqlite3RowSetInsert(RowSet *p, i64 rowid){
37155 struct RowSetEntry *pEntry; /* The new entry */
37156 struct RowSetEntry *pLast; /* The last prior entry */
37157 assert( p!=0 );
37158 if( p->nFresh==0 ){
37159 struct RowSetChunk *pNew;
37160 pNew = sqlite3DbMallocRaw(p->db, sizeof(*pNew));
37161 if( pNew==0 ){
37162 return;
37164 pNew->pNextChunk = p->pChunk;
37165 p->pChunk = pNew;
37166 p->pFresh = pNew->aEntry;
37167 p->nFresh = ROWSET_ENTRY_PER_CHUNK;
37169 pEntry = p->pFresh++;
37170 p->nFresh--;
37171 pEntry->v = rowid;
37172 pEntry->pRight = 0;
37173 pLast = p->pLast;
37174 if( pLast ){
37175 if( p->isSorted && rowid<=pLast->v ){
37176 p->isSorted = 0;
37178 pLast->pRight = pEntry;
37179 }else{
37180 assert( p->pEntry==0 ); /* Fires if INSERT after SMALLEST */
37181 p->pEntry = pEntry;
37183 p->pLast = pEntry;
37187 ** Merge two lists of RowSetEntry objects. Remove duplicates.
37189 ** The input lists are connected via pRight pointers and are
37190 ** assumed to each already be in sorted order.
37192 static struct RowSetEntry *rowSetMerge(
37193 struct RowSetEntry *pA, /* First sorted list to be merged */
37194 struct RowSetEntry *pB /* Second sorted list to be merged */
37196 struct RowSetEntry head;
37197 struct RowSetEntry *pTail;
37199 pTail = &head;
37200 while( pA && pB ){
37201 assert( pA->pRight==0 || pA->v<=pA->pRight->v );
37202 assert( pB->pRight==0 || pB->v<=pB->pRight->v );
37203 if( pA->v<pB->v ){
37204 pTail->pRight = pA;
37205 pA = pA->pRight;
37206 pTail = pTail->pRight;
37207 }else if( pB->v<pA->v ){
37208 pTail->pRight = pB;
37209 pB = pB->pRight;
37210 pTail = pTail->pRight;
37211 }else{
37212 pA = pA->pRight;
37215 if( pA ){
37216 assert( pA->pRight==0 || pA->v<=pA->pRight->v );
37217 pTail->pRight = pA;
37218 }else{
37219 assert( pB==0 || pB->pRight==0 || pB->v<=pB->pRight->v );
37220 pTail->pRight = pB;
37222 return head.pRight;
37226 ** Sort all elements on the pEntry list of the RowSet into ascending order.
37228 static void rowSetSort(RowSet *p){
37229 unsigned int i;
37230 struct RowSetEntry *pEntry;
37231 struct RowSetEntry *aBucket[40];
37233 assert( p->isSorted==0 );
37234 memset(aBucket, 0, sizeof(aBucket));
37235 while( p->pEntry ){
37236 pEntry = p->pEntry;
37237 p->pEntry = pEntry->pRight;
37238 pEntry->pRight = 0;
37239 for(i=0; aBucket[i]; i++){
37240 pEntry = rowSetMerge(aBucket[i], pEntry);
37241 aBucket[i] = 0;
37243 aBucket[i] = pEntry;
37245 pEntry = 0;
37246 for(i=0; i<sizeof(aBucket)/sizeof(aBucket[0]); i++){
37247 pEntry = rowSetMerge(pEntry, aBucket[i]);
37249 p->pEntry = pEntry;
37250 p->pLast = 0;
37251 p->isSorted = 1;
37256 ** The input, pIn, is a binary tree (or subtree) of RowSetEntry objects.
37257 ** Convert this tree into a linked list connected by the pRight pointers
37258 ** and return pointers to the first and last elements of the new list.
37260 static void rowSetTreeToList(
37261 struct RowSetEntry *pIn, /* Root of the input tree */
37262 struct RowSetEntry **ppFirst, /* Write head of the output list here */
37263 struct RowSetEntry **ppLast /* Write tail of the output list here */
37265 assert( pIn!=0 );
37266 if( pIn->pLeft ){
37267 struct RowSetEntry *p;
37268 rowSetTreeToList(pIn->pLeft, ppFirst, &p);
37269 p->pRight = pIn;
37270 }else{
37271 *ppFirst = pIn;
37273 if( pIn->pRight ){
37274 rowSetTreeToList(pIn->pRight, &pIn->pRight, ppLast);
37275 }else{
37276 *ppLast = pIn;
37278 assert( (*ppLast)->pRight==0 );
37283 ** Convert a sorted list of elements (connected by pRight) into a binary
37284 ** tree with depth of iDepth. A depth of 1 means the tree contains a single
37285 ** node taken from the head of *ppList. A depth of 2 means a tree with
37286 ** three nodes. And so forth.
37288 ** Use as many entries from the input list as required and update the
37289 ** *ppList to point to the unused elements of the list. If the input
37290 ** list contains too few elements, then construct an incomplete tree
37291 ** and leave *ppList set to NULL.
37293 ** Return a pointer to the root of the constructed binary tree.
37295 static struct RowSetEntry *rowSetNDeepTree(
37296 struct RowSetEntry **ppList,
37297 int iDepth
37299 struct RowSetEntry *p; /* Root of the new tree */
37300 struct RowSetEntry *pLeft; /* Left subtree */
37301 if( *ppList==0 ){
37302 return 0;
37304 if( iDepth==1 ){
37305 p = *ppList;
37306 *ppList = p->pRight;
37307 p->pLeft = p->pRight = 0;
37308 return p;
37310 pLeft = rowSetNDeepTree(ppList, iDepth-1);
37311 p = *ppList;
37312 if( p==0 ){
37313 return pLeft;
37315 p->pLeft = pLeft;
37316 *ppList = p->pRight;
37317 p->pRight = rowSetNDeepTree(ppList, iDepth-1);
37318 return p;
37322 ** Convert a sorted list of elements into a binary tree. Make the tree
37323 ** as deep as it needs to be in order to contain the entire list.
37325 static struct RowSetEntry *rowSetListToTree(struct RowSetEntry *pList){
37326 int iDepth; /* Depth of the tree so far */
37327 struct RowSetEntry *p; /* Current tree root */
37328 struct RowSetEntry *pLeft; /* Left subtree */
37330 assert( pList!=0 );
37331 p = pList;
37332 pList = p->pRight;
37333 p->pLeft = p->pRight = 0;
37334 for(iDepth=1; pList; iDepth++){
37335 pLeft = p;
37336 p = pList;
37337 pList = p->pRight;
37338 p->pLeft = pLeft;
37339 p->pRight = rowSetNDeepTree(&pList, iDepth);
37341 return p;
37345 ** Convert the list in p->pEntry into a sorted list if it is not
37346 ** sorted already. If there is a binary tree on p->pTree, then
37347 ** convert it into a list too and merge it into the p->pEntry list.
37349 static void rowSetToList(RowSet *p){
37350 if( !p->isSorted ){
37351 rowSetSort(p);
37353 if( p->pTree ){
37354 struct RowSetEntry *pHead, *pTail;
37355 rowSetTreeToList(p->pTree, &pHead, &pTail);
37356 p->pTree = 0;
37357 p->pEntry = rowSetMerge(p->pEntry, pHead);
37362 ** Extract the smallest element from the RowSet.
37363 ** Write the element into *pRowid. Return 1 on success. Return
37364 ** 0 if the RowSet is already empty.
37366 ** After this routine has been called, the sqlite3RowSetInsert()
37367 ** routine may not be called again.
37369 SQLITE_PRIVATE int sqlite3RowSetNext(RowSet *p, i64 *pRowid){
37370 rowSetToList(p);
37371 if( p->pEntry ){
37372 *pRowid = p->pEntry->v;
37373 p->pEntry = p->pEntry->pRight;
37374 if( p->pEntry==0 ){
37375 sqlite3RowSetClear(p);
37377 return 1;
37378 }else{
37379 return 0;
37384 ** Check to see if element iRowid was inserted into the the rowset as
37385 ** part of any insert batch prior to iBatch. Return 1 or 0.
37387 SQLITE_PRIVATE int sqlite3RowSetTest(RowSet *pRowSet, u8 iBatch, sqlite3_int64 iRowid){
37388 struct RowSetEntry *p;
37389 if( iBatch!=pRowSet->iBatch ){
37390 if( pRowSet->pEntry ){
37391 rowSetToList(pRowSet);
37392 pRowSet->pTree = rowSetListToTree(pRowSet->pEntry);
37393 pRowSet->pEntry = 0;
37394 pRowSet->pLast = 0;
37396 pRowSet->iBatch = iBatch;
37398 p = pRowSet->pTree;
37399 while( p ){
37400 if( p->v<iRowid ){
37401 p = p->pRight;
37402 }else if( p->v>iRowid ){
37403 p = p->pLeft;
37404 }else{
37405 return 1;
37408 return 0;
37411 /************** End of rowset.c **********************************************/
37412 /************** Begin file pager.c *******************************************/
37414 ** 2001 September 15
37416 ** The author disclaims copyright to this source code. In place of
37417 ** a legal notice, here is a blessing:
37419 ** May you do good and not evil.
37420 ** May you find forgiveness for yourself and forgive others.
37421 ** May you share freely, never taking more than you give.
37423 *************************************************************************
37424 ** This is the implementation of the page cache subsystem or "pager".
37426 ** The pager is used to access a database disk file. It implements
37427 ** atomic commit and rollback through the use of a journal file that
37428 ** is separate from the database file. The pager also implements file
37429 ** locking to prevent two processes from writing the same database
37430 ** file simultaneously, or one process from reading the database while
37431 ** another is writing.
37433 #ifndef SQLITE_OMIT_DISKIO
37434 /************** Include wal.h in the middle of pager.c ***********************/
37435 /************** Begin file wal.h *********************************************/
37437 ** 2010 February 1
37439 ** The author disclaims copyright to this source code. In place of
37440 ** a legal notice, here is a blessing:
37442 ** May you do good and not evil.
37443 ** May you find forgiveness for yourself and forgive others.
37444 ** May you share freely, never taking more than you give.
37446 *************************************************************************
37447 ** This header file defines the interface to the write-ahead logging
37448 ** system. Refer to the comments below and the header comment attached to
37449 ** the implementation of each function in log.c for further details.
37452 #ifndef _WAL_H_
37453 #define _WAL_H_
37456 #ifdef SQLITE_OMIT_WAL
37457 # define sqlite3WalOpen(x,y,z) 0
37458 # define sqlite3WalLimit(x,y)
37459 # define sqlite3WalClose(w,x,y,z) 0
37460 # define sqlite3WalBeginReadTransaction(y,z) 0
37461 # define sqlite3WalEndReadTransaction(z)
37462 # define sqlite3WalRead(v,w,x,y,z) 0
37463 # define sqlite3WalDbsize(y) 0
37464 # define sqlite3WalBeginWriteTransaction(y) 0
37465 # define sqlite3WalEndWriteTransaction(x) 0
37466 # define sqlite3WalUndo(x,y,z) 0
37467 # define sqlite3WalSavepoint(y,z)
37468 # define sqlite3WalSavepointUndo(y,z) 0
37469 # define sqlite3WalFrames(u,v,w,x,y,z) 0
37470 # define sqlite3WalCheckpoint(r,s,t,u,v,w,x,y,z) 0
37471 # define sqlite3WalCallback(z) 0
37472 # define sqlite3WalExclusiveMode(y,z) 0
37473 # define sqlite3WalHeapMemory(z) 0
37474 #else
37476 #define WAL_SAVEPOINT_NDATA 4
37478 /* Connection to a write-ahead log (WAL) file.
37479 ** There is one object of this type for each pager.
37481 typedef struct Wal Wal;
37483 /* Open and close a connection to a write-ahead log. */
37484 SQLITE_PRIVATE int sqlite3WalOpen(sqlite3_vfs*, sqlite3_file*, const char *, int, i64, Wal**);
37485 SQLITE_PRIVATE int sqlite3WalClose(Wal *pWal, int sync_flags, int, u8 *);
37487 /* Set the limiting size of a WAL file. */
37488 SQLITE_PRIVATE void sqlite3WalLimit(Wal*, i64);
37490 /* Used by readers to open (lock) and close (unlock) a snapshot. A
37491 ** snapshot is like a read-transaction. It is the state of the database
37492 ** at an instant in time. sqlite3WalOpenSnapshot gets a read lock and
37493 ** preserves the current state even if the other threads or processes
37494 ** write to or checkpoint the WAL. sqlite3WalCloseSnapshot() closes the
37495 ** transaction and releases the lock.
37497 SQLITE_PRIVATE int sqlite3WalBeginReadTransaction(Wal *pWal, int *);
37498 SQLITE_PRIVATE void sqlite3WalEndReadTransaction(Wal *pWal);
37500 /* Read a page from the write-ahead log, if it is present. */
37501 SQLITE_PRIVATE int sqlite3WalRead(Wal *pWal, Pgno pgno, int *pInWal, int nOut, u8 *pOut);
37503 /* If the WAL is not empty, return the size of the database. */
37504 SQLITE_PRIVATE Pgno sqlite3WalDbsize(Wal *pWal);
37506 /* Obtain or release the WRITER lock. */
37507 SQLITE_PRIVATE int sqlite3WalBeginWriteTransaction(Wal *pWal);
37508 SQLITE_PRIVATE int sqlite3WalEndWriteTransaction(Wal *pWal);
37510 /* Undo any frames written (but not committed) to the log */
37511 SQLITE_PRIVATE int sqlite3WalUndo(Wal *pWal, int (*xUndo)(void *, Pgno), void *pUndoCtx);
37513 /* Return an integer that records the current (uncommitted) write
37514 ** position in the WAL */
37515 SQLITE_PRIVATE void sqlite3WalSavepoint(Wal *pWal, u32 *aWalData);
37517 /* Move the write position of the WAL back to iFrame. Called in
37518 ** response to a ROLLBACK TO command. */
37519 SQLITE_PRIVATE int sqlite3WalSavepointUndo(Wal *pWal, u32 *aWalData);
37521 /* Write a frame or frames to the log. */
37522 SQLITE_PRIVATE int sqlite3WalFrames(Wal *pWal, int, PgHdr *, Pgno, int, int);
37524 /* Copy pages from the log to the database file */
37525 SQLITE_PRIVATE int sqlite3WalCheckpoint(
37526 Wal *pWal, /* Write-ahead log connection */
37527 int eMode, /* One of PASSIVE, FULL and RESTART */
37528 int (*xBusy)(void*), /* Function to call when busy */
37529 void *pBusyArg, /* Context argument for xBusyHandler */
37530 int sync_flags, /* Flags to sync db file with (or 0) */
37531 int nBuf, /* Size of buffer nBuf */
37532 u8 *zBuf, /* Temporary buffer to use */
37533 int *pnLog, /* OUT: Number of frames in WAL */
37534 int *pnCkpt /* OUT: Number of backfilled frames in WAL */
37537 /* Return the value to pass to a sqlite3_wal_hook callback, the
37538 ** number of frames in the WAL at the point of the last commit since
37539 ** sqlite3WalCallback() was called. If no commits have occurred since
37540 ** the last call, then return 0.
37542 SQLITE_PRIVATE int sqlite3WalCallback(Wal *pWal);
37544 /* Tell the wal layer that an EXCLUSIVE lock has been obtained (or released)
37545 ** by the pager layer on the database file.
37547 SQLITE_PRIVATE int sqlite3WalExclusiveMode(Wal *pWal, int op);
37549 /* Return true if the argument is non-NULL and the WAL module is using
37550 ** heap-memory for the wal-index. Otherwise, if the argument is NULL or the
37551 ** WAL module is using shared-memory, return false.
37553 SQLITE_PRIVATE int sqlite3WalHeapMemory(Wal *pWal);
37555 #endif /* ifndef SQLITE_OMIT_WAL */
37556 #endif /* _WAL_H_ */
37558 /************** End of wal.h *************************************************/
37559 /************** Continuing where we left off in pager.c **********************/
37562 /******************* NOTES ON THE DESIGN OF THE PAGER ************************
37564 ** This comment block describes invariants that hold when using a rollback
37565 ** journal. These invariants do not apply for journal_mode=WAL,
37566 ** journal_mode=MEMORY, or journal_mode=OFF.
37568 ** Within this comment block, a page is deemed to have been synced
37569 ** automatically as soon as it is written when PRAGMA synchronous=OFF.
37570 ** Otherwise, the page is not synced until the xSync method of the VFS
37571 ** is called successfully on the file containing the page.
37573 ** Definition: A page of the database file is said to be "overwriteable" if
37574 ** one or more of the following are true about the page:
37576 ** (a) The original content of the page as it was at the beginning of
37577 ** the transaction has been written into the rollback journal and
37578 ** synced.
37580 ** (b) The page was a freelist leaf page at the start of the transaction.
37582 ** (c) The page number is greater than the largest page that existed in
37583 ** the database file at the start of the transaction.
37585 ** (1) A page of the database file is never overwritten unless one of the
37586 ** following are true:
37588 ** (a) The page and all other pages on the same sector are overwriteable.
37590 ** (b) The atomic page write optimization is enabled, and the entire
37591 ** transaction other than the update of the transaction sequence
37592 ** number consists of a single page change.
37594 ** (2) The content of a page written into the rollback journal exactly matches
37595 ** both the content in the database when the rollback journal was written
37596 ** and the content in the database at the beginning of the current
37597 ** transaction.
37599 ** (3) Writes to the database file are an integer multiple of the page size
37600 ** in length and are aligned on a page boundary.
37602 ** (4) Reads from the database file are either aligned on a page boundary and
37603 ** an integer multiple of the page size in length or are taken from the
37604 ** first 100 bytes of the database file.
37606 ** (5) All writes to the database file are synced prior to the rollback journal
37607 ** being deleted, truncated, or zeroed.
37609 ** (6) If a master journal file is used, then all writes to the database file
37610 ** are synced prior to the master journal being deleted.
37612 ** Definition: Two databases (or the same database at two points it time)
37613 ** are said to be "logically equivalent" if they give the same answer to
37614 ** all queries. Note in particular the the content of freelist leaf
37615 ** pages can be changed arbitarily without effecting the logical equivalence
37616 ** of the database.
37618 ** (7) At any time, if any subset, including the empty set and the total set,
37619 ** of the unsynced changes to a rollback journal are removed and the
37620 ** journal is rolled back, the resulting database file will be logical
37621 ** equivalent to the database file at the beginning of the transaction.
37623 ** (8) When a transaction is rolled back, the xTruncate method of the VFS
37624 ** is called to restore the database file to the same size it was at
37625 ** the beginning of the transaction. (In some VFSes, the xTruncate
37626 ** method is a no-op, but that does not change the fact the SQLite will
37627 ** invoke it.)
37629 ** (9) Whenever the database file is modified, at least one bit in the range
37630 ** of bytes from 24 through 39 inclusive will be changed prior to releasing
37631 ** the EXCLUSIVE lock, thus signaling other connections on the same
37632 ** database to flush their caches.
37634 ** (10) The pattern of bits in bytes 24 through 39 shall not repeat in less
37635 ** than one billion transactions.
37637 ** (11) A database file is well-formed at the beginning and at the conclusion
37638 ** of every transaction.
37640 ** (12) An EXCLUSIVE lock is held on the database file when writing to
37641 ** the database file.
37643 ** (13) A SHARED lock is held on the database file while reading any
37644 ** content out of the database file.
37646 ******************************************************************************/
37649 ** Macros for troubleshooting. Normally turned off
37651 #if 0
37652 int sqlite3PagerTrace=1; /* True to enable tracing */
37653 #define sqlite3DebugPrintf printf
37654 #define PAGERTRACE(X) if( sqlite3PagerTrace ){ sqlite3DebugPrintf X; }
37655 #else
37656 #define PAGERTRACE(X)
37657 #endif
37660 ** The following two macros are used within the PAGERTRACE() macros above
37661 ** to print out file-descriptors.
37663 ** PAGERID() takes a pointer to a Pager struct as its argument. The
37664 ** associated file-descriptor is returned. FILEHANDLEID() takes an sqlite3_file
37665 ** struct as its argument.
37667 #define PAGERID(p) ((int)(p->fd))
37668 #define FILEHANDLEID(fd) ((int)fd)
37671 ** The Pager.eState variable stores the current 'state' of a pager. A
37672 ** pager may be in any one of the seven states shown in the following
37673 ** state diagram.
37675 ** OPEN <------+------+
37676 ** | | |
37677 ** V | |
37678 ** +---------> READER-------+ |
37679 ** | | |
37680 ** | V |
37681 ** |<-------WRITER_LOCKED------> ERROR
37682 ** | | ^
37683 ** | V |
37684 ** |<------WRITER_CACHEMOD-------->|
37685 ** | | |
37686 ** | V |
37687 ** |<-------WRITER_DBMOD---------->|
37688 ** | | |
37689 ** | V |
37690 ** +<------WRITER_FINISHED-------->+
37693 ** List of state transitions and the C [function] that performs each:
37695 ** OPEN -> READER [sqlite3PagerSharedLock]
37696 ** READER -> OPEN [pager_unlock]
37698 ** READER -> WRITER_LOCKED [sqlite3PagerBegin]
37699 ** WRITER_LOCKED -> WRITER_CACHEMOD [pager_open_journal]
37700 ** WRITER_CACHEMOD -> WRITER_DBMOD [syncJournal]
37701 ** WRITER_DBMOD -> WRITER_FINISHED [sqlite3PagerCommitPhaseOne]
37702 ** WRITER_*** -> READER [pager_end_transaction]
37704 ** WRITER_*** -> ERROR [pager_error]
37705 ** ERROR -> OPEN [pager_unlock]
37708 ** OPEN:
37710 ** The pager starts up in this state. Nothing is guaranteed in this
37711 ** state - the file may or may not be locked and the database size is
37712 ** unknown. The database may not be read or written.
37714 ** * No read or write transaction is active.
37715 ** * Any lock, or no lock at all, may be held on the database file.
37716 ** * The dbSize, dbOrigSize and dbFileSize variables may not be trusted.
37718 ** READER:
37720 ** In this state all the requirements for reading the database in
37721 ** rollback (non-WAL) mode are met. Unless the pager is (or recently
37722 ** was) in exclusive-locking mode, a user-level read transaction is
37723 ** open. The database size is known in this state.
37725 ** A connection running with locking_mode=normal enters this state when
37726 ** it opens a read-transaction on the database and returns to state
37727 ** OPEN after the read-transaction is completed. However a connection
37728 ** running in locking_mode=exclusive (including temp databases) remains in
37729 ** this state even after the read-transaction is closed. The only way
37730 ** a locking_mode=exclusive connection can transition from READER to OPEN
37731 ** is via the ERROR state (see below).
37733 ** * A read transaction may be active (but a write-transaction cannot).
37734 ** * A SHARED or greater lock is held on the database file.
37735 ** * The dbSize variable may be trusted (even if a user-level read
37736 ** transaction is not active). The dbOrigSize and dbFileSize variables
37737 ** may not be trusted at this point.
37738 ** * If the database is a WAL database, then the WAL connection is open.
37739 ** * Even if a read-transaction is not open, it is guaranteed that
37740 ** there is no hot-journal in the file-system.
37742 ** WRITER_LOCKED:
37744 ** The pager moves to this state from READER when a write-transaction
37745 ** is first opened on the database. In WRITER_LOCKED state, all locks
37746 ** required to start a write-transaction are held, but no actual
37747 ** modifications to the cache or database have taken place.
37749 ** In rollback mode, a RESERVED or (if the transaction was opened with
37750 ** BEGIN EXCLUSIVE) EXCLUSIVE lock is obtained on the database file when
37751 ** moving to this state, but the journal file is not written to or opened
37752 ** to in this state. If the transaction is committed or rolled back while
37753 ** in WRITER_LOCKED state, all that is required is to unlock the database
37754 ** file.
37756 ** IN WAL mode, WalBeginWriteTransaction() is called to lock the log file.
37757 ** If the connection is running with locking_mode=exclusive, an attempt
37758 ** is made to obtain an EXCLUSIVE lock on the database file.
37760 ** * A write transaction is active.
37761 ** * If the connection is open in rollback-mode, a RESERVED or greater
37762 ** lock is held on the database file.
37763 ** * If the connection is open in WAL-mode, a WAL write transaction
37764 ** is open (i.e. sqlite3WalBeginWriteTransaction() has been successfully
37765 ** called).
37766 ** * The dbSize, dbOrigSize and dbFileSize variables are all valid.
37767 ** * The contents of the pager cache have not been modified.
37768 ** * The journal file may or may not be open.
37769 ** * Nothing (not even the first header) has been written to the journal.
37771 ** WRITER_CACHEMOD:
37773 ** A pager moves from WRITER_LOCKED state to this state when a page is
37774 ** first modified by the upper layer. In rollback mode the journal file
37775 ** is opened (if it is not already open) and a header written to the
37776 ** start of it. The database file on disk has not been modified.
37778 ** * A write transaction is active.
37779 ** * A RESERVED or greater lock is held on the database file.
37780 ** * The journal file is open and the first header has been written
37781 ** to it, but the header has not been synced to disk.
37782 ** * The contents of the page cache have been modified.
37784 ** WRITER_DBMOD:
37786 ** The pager transitions from WRITER_CACHEMOD into WRITER_DBMOD state
37787 ** when it modifies the contents of the database file. WAL connections
37788 ** never enter this state (since they do not modify the database file,
37789 ** just the log file).
37791 ** * A write transaction is active.
37792 ** * An EXCLUSIVE or greater lock is held on the database file.
37793 ** * The journal file is open and the first header has been written
37794 ** and synced to disk.
37795 ** * The contents of the page cache have been modified (and possibly
37796 ** written to disk).
37798 ** WRITER_FINISHED:
37800 ** It is not possible for a WAL connection to enter this state.
37802 ** A rollback-mode pager changes to WRITER_FINISHED state from WRITER_DBMOD
37803 ** state after the entire transaction has been successfully written into the
37804 ** database file. In this state the transaction may be committed simply
37805 ** by finalizing the journal file. Once in WRITER_FINISHED state, it is
37806 ** not possible to modify the database further. At this point, the upper
37807 ** layer must either commit or rollback the transaction.
37809 ** * A write transaction is active.
37810 ** * An EXCLUSIVE or greater lock is held on the database file.
37811 ** * All writing and syncing of journal and database data has finished.
37812 ** If no error occured, all that remains is to finalize the journal to
37813 ** commit the transaction. If an error did occur, the caller will need
37814 ** to rollback the transaction.
37816 ** ERROR:
37818 ** The ERROR state is entered when an IO or disk-full error (including
37819 ** SQLITE_IOERR_NOMEM) occurs at a point in the code that makes it
37820 ** difficult to be sure that the in-memory pager state (cache contents,
37821 ** db size etc.) are consistent with the contents of the file-system.
37823 ** Temporary pager files may enter the ERROR state, but in-memory pagers
37824 ** cannot.
37826 ** For example, if an IO error occurs while performing a rollback,
37827 ** the contents of the page-cache may be left in an inconsistent state.
37828 ** At this point it would be dangerous to change back to READER state
37829 ** (as usually happens after a rollback). Any subsequent readers might
37830 ** report database corruption (due to the inconsistent cache), and if
37831 ** they upgrade to writers, they may inadvertently corrupt the database
37832 ** file. To avoid this hazard, the pager switches into the ERROR state
37833 ** instead of READER following such an error.
37835 ** Once it has entered the ERROR state, any attempt to use the pager
37836 ** to read or write data returns an error. Eventually, once all
37837 ** outstanding transactions have been abandoned, the pager is able to
37838 ** transition back to OPEN state, discarding the contents of the
37839 ** page-cache and any other in-memory state at the same time. Everything
37840 ** is reloaded from disk (and, if necessary, hot-journal rollback peformed)
37841 ** when a read-transaction is next opened on the pager (transitioning
37842 ** the pager into READER state). At that point the system has recovered
37843 ** from the error.
37845 ** Specifically, the pager jumps into the ERROR state if:
37847 ** 1. An error occurs while attempting a rollback. This happens in
37848 ** function sqlite3PagerRollback().
37850 ** 2. An error occurs while attempting to finalize a journal file
37851 ** following a commit in function sqlite3PagerCommitPhaseTwo().
37853 ** 3. An error occurs while attempting to write to the journal or
37854 ** database file in function pagerStress() in order to free up
37855 ** memory.
37857 ** In other cases, the error is returned to the b-tree layer. The b-tree
37858 ** layer then attempts a rollback operation. If the error condition
37859 ** persists, the pager enters the ERROR state via condition (1) above.
37861 ** Condition (3) is necessary because it can be triggered by a read-only
37862 ** statement executed within a transaction. In this case, if the error
37863 ** code were simply returned to the user, the b-tree layer would not
37864 ** automatically attempt a rollback, as it assumes that an error in a
37865 ** read-only statement cannot leave the pager in an internally inconsistent
37866 ** state.
37868 ** * The Pager.errCode variable is set to something other than SQLITE_OK.
37869 ** * There are one or more outstanding references to pages (after the
37870 ** last reference is dropped the pager should move back to OPEN state).
37871 ** * The pager is not an in-memory pager.
37874 ** Notes:
37876 ** * A pager is never in WRITER_DBMOD or WRITER_FINISHED state if the
37877 ** connection is open in WAL mode. A WAL connection is always in one
37878 ** of the first four states.
37880 ** * Normally, a connection open in exclusive mode is never in PAGER_OPEN
37881 ** state. There are two exceptions: immediately after exclusive-mode has
37882 ** been turned on (and before any read or write transactions are
37883 ** executed), and when the pager is leaving the "error state".
37885 ** * See also: assert_pager_state().
37887 #define PAGER_OPEN 0
37888 #define PAGER_READER 1
37889 #define PAGER_WRITER_LOCKED 2
37890 #define PAGER_WRITER_CACHEMOD 3
37891 #define PAGER_WRITER_DBMOD 4
37892 #define PAGER_WRITER_FINISHED 5
37893 #define PAGER_ERROR 6
37896 ** The Pager.eLock variable is almost always set to one of the
37897 ** following locking-states, according to the lock currently held on
37898 ** the database file: NO_LOCK, SHARED_LOCK, RESERVED_LOCK or EXCLUSIVE_LOCK.
37899 ** This variable is kept up to date as locks are taken and released by
37900 ** the pagerLockDb() and pagerUnlockDb() wrappers.
37902 ** If the VFS xLock() or xUnlock() returns an error other than SQLITE_BUSY
37903 ** (i.e. one of the SQLITE_IOERR subtypes), it is not clear whether or not
37904 ** the operation was successful. In these circumstances pagerLockDb() and
37905 ** pagerUnlockDb() take a conservative approach - eLock is always updated
37906 ** when unlocking the file, and only updated when locking the file if the
37907 ** VFS call is successful. This way, the Pager.eLock variable may be set
37908 ** to a less exclusive (lower) value than the lock that is actually held
37909 ** at the system level, but it is never set to a more exclusive value.
37911 ** This is usually safe. If an xUnlock fails or appears to fail, there may
37912 ** be a few redundant xLock() calls or a lock may be held for longer than
37913 ** required, but nothing really goes wrong.
37915 ** The exception is when the database file is unlocked as the pager moves
37916 ** from ERROR to OPEN state. At this point there may be a hot-journal file
37917 ** in the file-system that needs to be rolled back (as part of a OPEN->SHARED
37918 ** transition, by the same pager or any other). If the call to xUnlock()
37919 ** fails at this point and the pager is left holding an EXCLUSIVE lock, this
37920 ** can confuse the call to xCheckReservedLock() call made later as part
37921 ** of hot-journal detection.
37923 ** xCheckReservedLock() is defined as returning true "if there is a RESERVED
37924 ** lock held by this process or any others". So xCheckReservedLock may
37925 ** return true because the caller itself is holding an EXCLUSIVE lock (but
37926 ** doesn't know it because of a previous error in xUnlock). If this happens
37927 ** a hot-journal may be mistaken for a journal being created by an active
37928 ** transaction in another process, causing SQLite to read from the database
37929 ** without rolling it back.
37931 ** To work around this, if a call to xUnlock() fails when unlocking the
37932 ** database in the ERROR state, Pager.eLock is set to UNKNOWN_LOCK. It
37933 ** is only changed back to a real locking state after a successful call
37934 ** to xLock(EXCLUSIVE). Also, the code to do the OPEN->SHARED state transition
37935 ** omits the check for a hot-journal if Pager.eLock is set to UNKNOWN_LOCK
37936 ** lock. Instead, it assumes a hot-journal exists and obtains an EXCLUSIVE
37937 ** lock on the database file before attempting to roll it back. See function
37938 ** PagerSharedLock() for more detail.
37940 ** Pager.eLock may only be set to UNKNOWN_LOCK when the pager is in
37941 ** PAGER_OPEN state.
37943 #define UNKNOWN_LOCK (EXCLUSIVE_LOCK+1)
37946 ** A macro used for invoking the codec if there is one
37948 #ifdef SQLITE_HAS_CODEC
37949 # define CODEC1(P,D,N,X,E) \
37950 if( P->xCodec && P->xCodec(P->pCodec,D,N,X)==0 ){ E; }
37951 # define CODEC2(P,D,N,X,E,O) \
37952 if( P->xCodec==0 ){ O=(char*)D; }else \
37953 if( (O=(char*)(P->xCodec(P->pCodec,D,N,X)))==0 ){ E; }
37954 #else
37955 # define CODEC1(P,D,N,X,E) /* NO-OP */
37956 # define CODEC2(P,D,N,X,E,O) O=(char*)D
37957 #endif
37960 ** The maximum allowed sector size. 64KiB. If the xSectorsize() method
37961 ** returns a value larger than this, then MAX_SECTOR_SIZE is used instead.
37962 ** This could conceivably cause corruption following a power failure on
37963 ** such a system. This is currently an undocumented limit.
37965 #define MAX_SECTOR_SIZE 0x10000
37968 ** An instance of the following structure is allocated for each active
37969 ** savepoint and statement transaction in the system. All such structures
37970 ** are stored in the Pager.aSavepoint[] array, which is allocated and
37971 ** resized using sqlite3Realloc().
37973 ** When a savepoint is created, the PagerSavepoint.iHdrOffset field is
37974 ** set to 0. If a journal-header is written into the main journal while
37975 ** the savepoint is active, then iHdrOffset is set to the byte offset
37976 ** immediately following the last journal record written into the main
37977 ** journal before the journal-header. This is required during savepoint
37978 ** rollback (see pagerPlaybackSavepoint()).
37980 typedef struct PagerSavepoint PagerSavepoint;
37981 struct PagerSavepoint {
37982 i64 iOffset; /* Starting offset in main journal */
37983 i64 iHdrOffset; /* See above */
37984 Bitvec *pInSavepoint; /* Set of pages in this savepoint */
37985 Pgno nOrig; /* Original number of pages in file */
37986 Pgno iSubRec; /* Index of first record in sub-journal */
37987 #ifndef SQLITE_OMIT_WAL
37988 u32 aWalData[WAL_SAVEPOINT_NDATA]; /* WAL savepoint context */
37989 #endif
37993 ** A open page cache is an instance of struct Pager. A description of
37994 ** some of the more important member variables follows:
37996 ** eState
37998 ** The current 'state' of the pager object. See the comment and state
37999 ** diagram above for a description of the pager state.
38001 ** eLock
38003 ** For a real on-disk database, the current lock held on the database file -
38004 ** NO_LOCK, SHARED_LOCK, RESERVED_LOCK or EXCLUSIVE_LOCK.
38006 ** For a temporary or in-memory database (neither of which require any
38007 ** locks), this variable is always set to EXCLUSIVE_LOCK. Since such
38008 ** databases always have Pager.exclusiveMode==1, this tricks the pager
38009 ** logic into thinking that it already has all the locks it will ever
38010 ** need (and no reason to release them).
38012 ** In some (obscure) circumstances, this variable may also be set to
38013 ** UNKNOWN_LOCK. See the comment above the #define of UNKNOWN_LOCK for
38014 ** details.
38016 ** changeCountDone
38018 ** This boolean variable is used to make sure that the change-counter
38019 ** (the 4-byte header field at byte offset 24 of the database file) is
38020 ** not updated more often than necessary.
38022 ** It is set to true when the change-counter field is updated, which
38023 ** can only happen if an exclusive lock is held on the database file.
38024 ** It is cleared (set to false) whenever an exclusive lock is
38025 ** relinquished on the database file. Each time a transaction is committed,
38026 ** The changeCountDone flag is inspected. If it is true, the work of
38027 ** updating the change-counter is omitted for the current transaction.
38029 ** This mechanism means that when running in exclusive mode, a connection
38030 ** need only update the change-counter once, for the first transaction
38031 ** committed.
38033 ** setMaster
38035 ** When PagerCommitPhaseOne() is called to commit a transaction, it may
38036 ** (or may not) specify a master-journal name to be written into the
38037 ** journal file before it is synced to disk.
38039 ** Whether or not a journal file contains a master-journal pointer affects
38040 ** the way in which the journal file is finalized after the transaction is
38041 ** committed or rolled back when running in "journal_mode=PERSIST" mode.
38042 ** If a journal file does not contain a master-journal pointer, it is
38043 ** finalized by overwriting the first journal header with zeroes. If
38044 ** it does contain a master-journal pointer the journal file is finalized
38045 ** by truncating it to zero bytes, just as if the connection were
38046 ** running in "journal_mode=truncate" mode.
38048 ** Journal files that contain master journal pointers cannot be finalized
38049 ** simply by overwriting the first journal-header with zeroes, as the
38050 ** master journal pointer could interfere with hot-journal rollback of any
38051 ** subsequently interrupted transaction that reuses the journal file.
38053 ** The flag is cleared as soon as the journal file is finalized (either
38054 ** by PagerCommitPhaseTwo or PagerRollback). If an IO error prevents the
38055 ** journal file from being successfully finalized, the setMaster flag
38056 ** is cleared anyway (and the pager will move to ERROR state).
38058 ** doNotSpill, doNotSyncSpill
38060 ** These two boolean variables control the behaviour of cache-spills
38061 ** (calls made by the pcache module to the pagerStress() routine to
38062 ** write cached data to the file-system in order to free up memory).
38064 ** When doNotSpill is non-zero, writing to the database from pagerStress()
38065 ** is disabled altogether. This is done in a very obscure case that
38066 ** comes up during savepoint rollback that requires the pcache module
38067 ** to allocate a new page to prevent the journal file from being written
38068 ** while it is being traversed by code in pager_playback().
38070 ** If doNotSyncSpill is non-zero, writing to the database from pagerStress()
38071 ** is permitted, but syncing the journal file is not. This flag is set
38072 ** by sqlite3PagerWrite() when the file-system sector-size is larger than
38073 ** the database page-size in order to prevent a journal sync from happening
38074 ** in between the journalling of two pages on the same sector.
38076 ** subjInMemory
38078 ** This is a boolean variable. If true, then any required sub-journal
38079 ** is opened as an in-memory journal file. If false, then in-memory
38080 ** sub-journals are only used for in-memory pager files.
38082 ** This variable is updated by the upper layer each time a new
38083 ** write-transaction is opened.
38085 ** dbSize, dbOrigSize, dbFileSize
38087 ** Variable dbSize is set to the number of pages in the database file.
38088 ** It is valid in PAGER_READER and higher states (all states except for
38089 ** OPEN and ERROR).
38091 ** dbSize is set based on the size of the database file, which may be
38092 ** larger than the size of the database (the value stored at offset
38093 ** 28 of the database header by the btree). If the size of the file
38094 ** is not an integer multiple of the page-size, the value stored in
38095 ** dbSize is rounded down (i.e. a 5KB file with 2K page-size has dbSize==2).
38096 ** Except, any file that is greater than 0 bytes in size is considered
38097 ** to have at least one page. (i.e. a 1KB file with 2K page-size leads
38098 ** to dbSize==1).
38100 ** During a write-transaction, if pages with page-numbers greater than
38101 ** dbSize are modified in the cache, dbSize is updated accordingly.
38102 ** Similarly, if the database is truncated using PagerTruncateImage(),
38103 ** dbSize is updated.
38105 ** Variables dbOrigSize and dbFileSize are valid in states
38106 ** PAGER_WRITER_LOCKED and higher. dbOrigSize is a copy of the dbSize
38107 ** variable at the start of the transaction. It is used during rollback,
38108 ** and to determine whether or not pages need to be journalled before
38109 ** being modified.
38111 ** Throughout a write-transaction, dbFileSize contains the size of
38112 ** the file on disk in pages. It is set to a copy of dbSize when the
38113 ** write-transaction is first opened, and updated when VFS calls are made
38114 ** to write or truncate the database file on disk.
38116 ** The only reason the dbFileSize variable is required is to suppress
38117 ** unnecessary calls to xTruncate() after committing a transaction. If,
38118 ** when a transaction is committed, the dbFileSize variable indicates
38119 ** that the database file is larger than the database image (Pager.dbSize),
38120 ** pager_truncate() is called. The pager_truncate() call uses xFilesize()
38121 ** to measure the database file on disk, and then truncates it if required.
38122 ** dbFileSize is not used when rolling back a transaction. In this case
38123 ** pager_truncate() is called unconditionally (which means there may be
38124 ** a call to xFilesize() that is not strictly required). In either case,
38125 ** pager_truncate() may cause the file to become smaller or larger.
38127 ** dbHintSize
38129 ** The dbHintSize variable is used to limit the number of calls made to
38130 ** the VFS xFileControl(FCNTL_SIZE_HINT) method.
38132 ** dbHintSize is set to a copy of the dbSize variable when a
38133 ** write-transaction is opened (at the same time as dbFileSize and
38134 ** dbOrigSize). If the xFileControl(FCNTL_SIZE_HINT) method is called,
38135 ** dbHintSize is increased to the number of pages that correspond to the
38136 ** size-hint passed to the method call. See pager_write_pagelist() for
38137 ** details.
38139 ** errCode
38141 ** The Pager.errCode variable is only ever used in PAGER_ERROR state. It
38142 ** is set to zero in all other states. In PAGER_ERROR state, Pager.errCode
38143 ** is always set to SQLITE_FULL, SQLITE_IOERR or one of the SQLITE_IOERR_XXX
38144 ** sub-codes.
38146 struct Pager {
38147 sqlite3_vfs *pVfs; /* OS functions to use for IO */
38148 u8 exclusiveMode; /* Boolean. True if locking_mode==EXCLUSIVE */
38149 u8 journalMode; /* One of the PAGER_JOURNALMODE_* values */
38150 u8 useJournal; /* Use a rollback journal on this file */
38151 u8 noReadlock; /* Do not bother to obtain readlocks */
38152 u8 noSync; /* Do not sync the journal if true */
38153 u8 fullSync; /* Do extra syncs of the journal for robustness */
38154 u8 ckptSyncFlags; /* SYNC_NORMAL or SYNC_FULL for checkpoint */
38155 u8 syncFlags; /* SYNC_NORMAL or SYNC_FULL otherwise */
38156 u8 tempFile; /* zFilename is a temporary file */
38157 u8 readOnly; /* True for a read-only database */
38158 u8 memDb; /* True to inhibit all file I/O */
38160 /**************************************************************************
38161 ** The following block contains those class members that change during
38162 ** routine opertion. Class members not in this block are either fixed
38163 ** when the pager is first created or else only change when there is a
38164 ** significant mode change (such as changing the page_size, locking_mode,
38165 ** or the journal_mode). From another view, these class members describe
38166 ** the "state" of the pager, while other class members describe the
38167 ** "configuration" of the pager.
38169 u8 eState; /* Pager state (OPEN, READER, WRITER_LOCKED..) */
38170 u8 eLock; /* Current lock held on database file */
38171 u8 changeCountDone; /* Set after incrementing the change-counter */
38172 u8 setMaster; /* True if a m-j name has been written to jrnl */
38173 u8 doNotSpill; /* Do not spill the cache when non-zero */
38174 u8 doNotSyncSpill; /* Do not do a spill that requires jrnl sync */
38175 u8 subjInMemory; /* True to use in-memory sub-journals */
38176 Pgno dbSize; /* Number of pages in the database */
38177 Pgno dbOrigSize; /* dbSize before the current transaction */
38178 Pgno dbFileSize; /* Number of pages in the database file */
38179 Pgno dbHintSize; /* Value passed to FCNTL_SIZE_HINT call */
38180 int errCode; /* One of several kinds of errors */
38181 int nRec; /* Pages journalled since last j-header written */
38182 u32 cksumInit; /* Quasi-random value added to every checksum */
38183 u32 nSubRec; /* Number of records written to sub-journal */
38184 Bitvec *pInJournal; /* One bit for each page in the database file */
38185 sqlite3_file *fd; /* File descriptor for database */
38186 sqlite3_file *jfd; /* File descriptor for main journal */
38187 sqlite3_file *sjfd; /* File descriptor for sub-journal */
38188 i64 journalOff; /* Current write offset in the journal file */
38189 i64 journalHdr; /* Byte offset to previous journal header */
38190 sqlite3_backup *pBackup; /* Pointer to list of ongoing backup processes */
38191 PagerSavepoint *aSavepoint; /* Array of active savepoints */
38192 int nSavepoint; /* Number of elements in aSavepoint[] */
38193 char dbFileVers[16]; /* Changes whenever database file changes */
38195 ** End of the routinely-changing class members
38196 ***************************************************************************/
38198 u16 nExtra; /* Add this many bytes to each in-memory page */
38199 i16 nReserve; /* Number of unused bytes at end of each page */
38200 u32 vfsFlags; /* Flags for sqlite3_vfs.xOpen() */
38201 u32 sectorSize; /* Assumed sector size during rollback */
38202 int pageSize; /* Number of bytes in a page */
38203 Pgno mxPgno; /* Maximum allowed size of the database */
38204 i64 journalSizeLimit; /* Size limit for persistent journal files */
38205 char *zFilename; /* Name of the database file */
38206 char *zJournal; /* Name of the journal file */
38207 int (*xBusyHandler)(void*); /* Function to call when busy */
38208 void *pBusyHandlerArg; /* Context argument for xBusyHandler */
38209 #ifdef SQLITE_TEST
38210 int nHit, nMiss; /* Cache hits and missing */
38211 int nRead, nWrite; /* Database pages read/written */
38212 #endif
38213 void (*xReiniter)(DbPage*); /* Call this routine when reloading pages */
38214 #ifdef SQLITE_HAS_CODEC
38215 void *(*xCodec)(void*,void*,Pgno,int); /* Routine for en/decoding data */
38216 void (*xCodecSizeChng)(void*,int,int); /* Notify of page size changes */
38217 void (*xCodecFree)(void*); /* Destructor for the codec */
38218 void *pCodec; /* First argument to xCodec... methods */
38219 #endif
38220 char *pTmpSpace; /* Pager.pageSize bytes of space for tmp use */
38221 PCache *pPCache; /* Pointer to page cache object */
38222 #ifndef SQLITE_OMIT_WAL
38223 Wal *pWal; /* Write-ahead log used by "journal_mode=wal" */
38224 char *zWal; /* File name for write-ahead log */
38225 #endif
38229 ** The following global variables hold counters used for
38230 ** testing purposes only. These variables do not exist in
38231 ** a non-testing build. These variables are not thread-safe.
38233 #ifdef SQLITE_TEST
38234 SQLITE_API int sqlite3_pager_readdb_count = 0; /* Number of full pages read from DB */
38235 SQLITE_API int sqlite3_pager_writedb_count = 0; /* Number of full pages written to DB */
38236 SQLITE_API int sqlite3_pager_writej_count = 0; /* Number of pages written to journal */
38237 # define PAGER_INCR(v) v++
38238 #else
38239 # define PAGER_INCR(v)
38240 #endif
38245 ** Journal files begin with the following magic string. The data
38246 ** was obtained from /dev/random. It is used only as a sanity check.
38248 ** Since version 2.8.0, the journal format contains additional sanity
38249 ** checking information. If the power fails while the journal is being
38250 ** written, semi-random garbage data might appear in the journal
38251 ** file after power is restored. If an attempt is then made
38252 ** to roll the journal back, the database could be corrupted. The additional
38253 ** sanity checking data is an attempt to discover the garbage in the
38254 ** journal and ignore it.
38256 ** The sanity checking information for the new journal format consists
38257 ** of a 32-bit checksum on each page of data. The checksum covers both
38258 ** the page number and the pPager->pageSize bytes of data for the page.
38259 ** This cksum is initialized to a 32-bit random value that appears in the
38260 ** journal file right after the header. The random initializer is important,
38261 ** because garbage data that appears at the end of a journal is likely
38262 ** data that was once in other files that have now been deleted. If the
38263 ** garbage data came from an obsolete journal file, the checksums might
38264 ** be correct. But by initializing the checksum to random value which
38265 ** is different for every journal, we minimize that risk.
38267 static const unsigned char aJournalMagic[] = {
38268 0xd9, 0xd5, 0x05, 0xf9, 0x20, 0xa1, 0x63, 0xd7,
38272 ** The size of the of each page record in the journal is given by
38273 ** the following macro.
38275 #define JOURNAL_PG_SZ(pPager) ((pPager->pageSize) + 8)
38278 ** The journal header size for this pager. This is usually the same
38279 ** size as a single disk sector. See also setSectorSize().
38281 #define JOURNAL_HDR_SZ(pPager) (pPager->sectorSize)
38284 ** The macro MEMDB is true if we are dealing with an in-memory database.
38285 ** We do this as a macro so that if the SQLITE_OMIT_MEMORYDB macro is set,
38286 ** the value of MEMDB will be a constant and the compiler will optimize
38287 ** out code that would never execute.
38289 #ifdef SQLITE_OMIT_MEMORYDB
38290 # define MEMDB 0
38291 #else
38292 # define MEMDB pPager->memDb
38293 #endif
38296 ** The maximum legal page number is (2^31 - 1).
38298 #define PAGER_MAX_PGNO 2147483647
38301 ** The argument to this macro is a file descriptor (type sqlite3_file*).
38302 ** Return 0 if it is not open, or non-zero (but not 1) if it is.
38304 ** This is so that expressions can be written as:
38306 ** if( isOpen(pPager->jfd) ){ ...
38308 ** instead of
38310 ** if( pPager->jfd->pMethods ){ ...
38312 #define isOpen(pFd) ((pFd)->pMethods)
38315 ** Return true if this pager uses a write-ahead log instead of the usual
38316 ** rollback journal. Otherwise false.
38318 #ifndef SQLITE_OMIT_WAL
38319 static int pagerUseWal(Pager *pPager){
38320 return (pPager->pWal!=0);
38322 #else
38323 # define pagerUseWal(x) 0
38324 # define pagerRollbackWal(x) 0
38325 # define pagerWalFrames(v,w,x,y,z) 0
38326 # define pagerOpenWalIfPresent(z) SQLITE_OK
38327 # define pagerBeginReadTransaction(z) SQLITE_OK
38328 #endif
38330 #ifndef NDEBUG
38332 ** Usage:
38334 ** assert( assert_pager_state(pPager) );
38336 ** This function runs many asserts to try to find inconsistencies in
38337 ** the internal state of the Pager object.
38339 static int assert_pager_state(Pager *p){
38340 Pager *pPager = p;
38342 /* State must be valid. */
38343 assert( p->eState==PAGER_OPEN
38344 || p->eState==PAGER_READER
38345 || p->eState==PAGER_WRITER_LOCKED
38346 || p->eState==PAGER_WRITER_CACHEMOD
38347 || p->eState==PAGER_WRITER_DBMOD
38348 || p->eState==PAGER_WRITER_FINISHED
38349 || p->eState==PAGER_ERROR
38352 /* Regardless of the current state, a temp-file connection always behaves
38353 ** as if it has an exclusive lock on the database file. It never updates
38354 ** the change-counter field, so the changeCountDone flag is always set.
38356 assert( p->tempFile==0 || p->eLock==EXCLUSIVE_LOCK );
38357 assert( p->tempFile==0 || pPager->changeCountDone );
38359 /* If the useJournal flag is clear, the journal-mode must be "OFF".
38360 ** And if the journal-mode is "OFF", the journal file must not be open.
38362 assert( p->journalMode==PAGER_JOURNALMODE_OFF || p->useJournal );
38363 assert( p->journalMode!=PAGER_JOURNALMODE_OFF || !isOpen(p->jfd) );
38365 /* Check that MEMDB implies noSync. And an in-memory journal. Since
38366 ** this means an in-memory pager performs no IO at all, it cannot encounter
38367 ** either SQLITE_IOERR or SQLITE_FULL during rollback or while finalizing
38368 ** a journal file. (although the in-memory journal implementation may
38369 ** return SQLITE_IOERR_NOMEM while the journal file is being written). It
38370 ** is therefore not possible for an in-memory pager to enter the ERROR
38371 ** state.
38373 if( MEMDB ){
38374 assert( p->noSync );
38375 assert( p->journalMode==PAGER_JOURNALMODE_OFF
38376 || p->journalMode==PAGER_JOURNALMODE_MEMORY
38378 assert( p->eState!=PAGER_ERROR && p->eState!=PAGER_OPEN );
38379 assert( pagerUseWal(p)==0 );
38382 /* If changeCountDone is set, a RESERVED lock or greater must be held
38383 ** on the file.
38385 assert( pPager->changeCountDone==0 || pPager->eLock>=RESERVED_LOCK );
38386 assert( p->eLock!=PENDING_LOCK );
38388 switch( p->eState ){
38389 case PAGER_OPEN:
38390 assert( !MEMDB );
38391 assert( pPager->errCode==SQLITE_OK );
38392 assert( sqlite3PcacheRefCount(pPager->pPCache)==0 || pPager->tempFile );
38393 break;
38395 case PAGER_READER:
38396 assert( pPager->errCode==SQLITE_OK );
38397 assert( p->eLock!=UNKNOWN_LOCK );
38398 assert( p->eLock>=SHARED_LOCK || p->noReadlock );
38399 break;
38401 case PAGER_WRITER_LOCKED:
38402 assert( p->eLock!=UNKNOWN_LOCK );
38403 assert( pPager->errCode==SQLITE_OK );
38404 if( !pagerUseWal(pPager) ){
38405 assert( p->eLock>=RESERVED_LOCK );
38407 assert( pPager->dbSize==pPager->dbOrigSize );
38408 assert( pPager->dbOrigSize==pPager->dbFileSize );
38409 assert( pPager->dbOrigSize==pPager->dbHintSize );
38410 assert( pPager->setMaster==0 );
38411 break;
38413 case PAGER_WRITER_CACHEMOD:
38414 assert( p->eLock!=UNKNOWN_LOCK );
38415 assert( pPager->errCode==SQLITE_OK );
38416 if( !pagerUseWal(pPager) ){
38417 /* It is possible that if journal_mode=wal here that neither the
38418 ** journal file nor the WAL file are open. This happens during
38419 ** a rollback transaction that switches from journal_mode=off
38420 ** to journal_mode=wal.
38422 assert( p->eLock>=RESERVED_LOCK );
38423 assert( isOpen(p->jfd)
38424 || p->journalMode==PAGER_JOURNALMODE_OFF
38425 || p->journalMode==PAGER_JOURNALMODE_WAL
38428 assert( pPager->dbOrigSize==pPager->dbFileSize );
38429 assert( pPager->dbOrigSize==pPager->dbHintSize );
38430 break;
38432 case PAGER_WRITER_DBMOD:
38433 assert( p->eLock==EXCLUSIVE_LOCK );
38434 assert( pPager->errCode==SQLITE_OK );
38435 assert( !pagerUseWal(pPager) );
38436 assert( p->eLock>=EXCLUSIVE_LOCK );
38437 assert( isOpen(p->jfd)
38438 || p->journalMode==PAGER_JOURNALMODE_OFF
38439 || p->journalMode==PAGER_JOURNALMODE_WAL
38441 assert( pPager->dbOrigSize<=pPager->dbHintSize );
38442 break;
38444 case PAGER_WRITER_FINISHED:
38445 assert( p->eLock==EXCLUSIVE_LOCK );
38446 assert( pPager->errCode==SQLITE_OK );
38447 assert( !pagerUseWal(pPager) );
38448 assert( isOpen(p->jfd)
38449 || p->journalMode==PAGER_JOURNALMODE_OFF
38450 || p->journalMode==PAGER_JOURNALMODE_WAL
38452 break;
38454 case PAGER_ERROR:
38455 /* There must be at least one outstanding reference to the pager if
38456 ** in ERROR state. Otherwise the pager should have already dropped
38457 ** back to OPEN state.
38459 assert( pPager->errCode!=SQLITE_OK );
38460 assert( sqlite3PcacheRefCount(pPager->pPCache)>0 );
38461 break;
38464 return 1;
38466 #endif /* ifndef NDEBUG */
38468 #ifdef SQLITE_DEBUG
38470 ** Return a pointer to a human readable string in a static buffer
38471 ** containing the state of the Pager object passed as an argument. This
38472 ** is intended to be used within debuggers. For example, as an alternative
38473 ** to "print *pPager" in gdb:
38475 ** (gdb) printf "%s", print_pager_state(pPager)
38477 static char *print_pager_state(Pager *p){
38478 static char zRet[1024];
38480 sqlite3_snprintf(1024, zRet,
38481 "Filename: %s\n"
38482 "State: %s errCode=%d\n"
38483 "Lock: %s\n"
38484 "Locking mode: locking_mode=%s\n"
38485 "Journal mode: journal_mode=%s\n"
38486 "Backing store: tempFile=%d memDb=%d useJournal=%d\n"
38487 "Journal: journalOff=%lld journalHdr=%lld\n"
38488 "Size: dbsize=%d dbOrigSize=%d dbFileSize=%d\n"
38489 , p->zFilename
38490 , p->eState==PAGER_OPEN ? "OPEN" :
38491 p->eState==PAGER_READER ? "READER" :
38492 p->eState==PAGER_WRITER_LOCKED ? "WRITER_LOCKED" :
38493 p->eState==PAGER_WRITER_CACHEMOD ? "WRITER_CACHEMOD" :
38494 p->eState==PAGER_WRITER_DBMOD ? "WRITER_DBMOD" :
38495 p->eState==PAGER_WRITER_FINISHED ? "WRITER_FINISHED" :
38496 p->eState==PAGER_ERROR ? "ERROR" : "?error?"
38497 , (int)p->errCode
38498 , p->eLock==NO_LOCK ? "NO_LOCK" :
38499 p->eLock==RESERVED_LOCK ? "RESERVED" :
38500 p->eLock==EXCLUSIVE_LOCK ? "EXCLUSIVE" :
38501 p->eLock==SHARED_LOCK ? "SHARED" :
38502 p->eLock==UNKNOWN_LOCK ? "UNKNOWN" : "?error?"
38503 , p->exclusiveMode ? "exclusive" : "normal"
38504 , p->journalMode==PAGER_JOURNALMODE_MEMORY ? "memory" :
38505 p->journalMode==PAGER_JOURNALMODE_OFF ? "off" :
38506 p->journalMode==PAGER_JOURNALMODE_DELETE ? "delete" :
38507 p->journalMode==PAGER_JOURNALMODE_PERSIST ? "persist" :
38508 p->journalMode==PAGER_JOURNALMODE_TRUNCATE ? "truncate" :
38509 p->journalMode==PAGER_JOURNALMODE_WAL ? "wal" : "?error?"
38510 , (int)p->tempFile, (int)p->memDb, (int)p->useJournal
38511 , p->journalOff, p->journalHdr
38512 , (int)p->dbSize, (int)p->dbOrigSize, (int)p->dbFileSize
38515 return zRet;
38517 #endif
38520 ** Return true if it is necessary to write page *pPg into the sub-journal.
38521 ** A page needs to be written into the sub-journal if there exists one
38522 ** or more open savepoints for which:
38524 ** * The page-number is less than or equal to PagerSavepoint.nOrig, and
38525 ** * The bit corresponding to the page-number is not set in
38526 ** PagerSavepoint.pInSavepoint.
38528 static int subjRequiresPage(PgHdr *pPg){
38529 Pgno pgno = pPg->pgno;
38530 Pager *pPager = pPg->pPager;
38531 int i;
38532 for(i=0; i<pPager->nSavepoint; i++){
38533 PagerSavepoint *p = &pPager->aSavepoint[i];
38534 if( p->nOrig>=pgno && 0==sqlite3BitvecTest(p->pInSavepoint, pgno) ){
38535 return 1;
38538 return 0;
38542 ** Return true if the page is already in the journal file.
38544 static int pageInJournal(PgHdr *pPg){
38545 return sqlite3BitvecTest(pPg->pPager->pInJournal, pPg->pgno);
38549 ** Read a 32-bit integer from the given file descriptor. Store the integer
38550 ** that is read in *pRes. Return SQLITE_OK if everything worked, or an
38551 ** error code is something goes wrong.
38553 ** All values are stored on disk as big-endian.
38555 static int read32bits(sqlite3_file *fd, i64 offset, u32 *pRes){
38556 unsigned char ac[4];
38557 int rc = sqlite3OsRead(fd, ac, sizeof(ac), offset);
38558 if( rc==SQLITE_OK ){
38559 *pRes = sqlite3Get4byte(ac);
38561 return rc;
38565 ** Write a 32-bit integer into a string buffer in big-endian byte order.
38567 #define put32bits(A,B) sqlite3Put4byte((u8*)A,B)
38571 ** Write a 32-bit integer into the given file descriptor. Return SQLITE_OK
38572 ** on success or an error code is something goes wrong.
38574 static int write32bits(sqlite3_file *fd, i64 offset, u32 val){
38575 char ac[4];
38576 put32bits(ac, val);
38577 return sqlite3OsWrite(fd, ac, 4, offset);
38581 ** Unlock the database file to level eLock, which must be either NO_LOCK
38582 ** or SHARED_LOCK. Regardless of whether or not the call to xUnlock()
38583 ** succeeds, set the Pager.eLock variable to match the (attempted) new lock.
38585 ** Except, if Pager.eLock is set to UNKNOWN_LOCK when this function is
38586 ** called, do not modify it. See the comment above the #define of
38587 ** UNKNOWN_LOCK for an explanation of this.
38589 static int pagerUnlockDb(Pager *pPager, int eLock){
38590 int rc = SQLITE_OK;
38592 assert( !pPager->exclusiveMode || pPager->eLock==eLock );
38593 assert( eLock==NO_LOCK || eLock==SHARED_LOCK );
38594 assert( eLock!=NO_LOCK || pagerUseWal(pPager)==0 );
38595 if( isOpen(pPager->fd) ){
38596 assert( pPager->eLock>=eLock );
38597 rc = sqlite3OsUnlock(pPager->fd, eLock);
38598 if( pPager->eLock!=UNKNOWN_LOCK ){
38599 pPager->eLock = (u8)eLock;
38601 IOTRACE(("UNLOCK %p %d\n", pPager, eLock))
38603 return rc;
38607 ** Lock the database file to level eLock, which must be either SHARED_LOCK,
38608 ** RESERVED_LOCK or EXCLUSIVE_LOCK. If the caller is successful, set the
38609 ** Pager.eLock variable to the new locking state.
38611 ** Except, if Pager.eLock is set to UNKNOWN_LOCK when this function is
38612 ** called, do not modify it unless the new locking state is EXCLUSIVE_LOCK.
38613 ** See the comment above the #define of UNKNOWN_LOCK for an explanation
38614 ** of this.
38616 static int pagerLockDb(Pager *pPager, int eLock){
38617 int rc = SQLITE_OK;
38619 assert( eLock==SHARED_LOCK || eLock==RESERVED_LOCK || eLock==EXCLUSIVE_LOCK );
38620 if( pPager->eLock<eLock || pPager->eLock==UNKNOWN_LOCK ){
38621 rc = sqlite3OsLock(pPager->fd, eLock);
38622 if( rc==SQLITE_OK && (pPager->eLock!=UNKNOWN_LOCK||eLock==EXCLUSIVE_LOCK) ){
38623 pPager->eLock = (u8)eLock;
38624 IOTRACE(("LOCK %p %d\n", pPager, eLock))
38627 return rc;
38631 ** This function determines whether or not the atomic-write optimization
38632 ** can be used with this pager. The optimization can be used if:
38634 ** (a) the value returned by OsDeviceCharacteristics() indicates that
38635 ** a database page may be written atomically, and
38636 ** (b) the value returned by OsSectorSize() is less than or equal
38637 ** to the page size.
38639 ** The optimization is also always enabled for temporary files. It is
38640 ** an error to call this function if pPager is opened on an in-memory
38641 ** database.
38643 ** If the optimization cannot be used, 0 is returned. If it can be used,
38644 ** then the value returned is the size of the journal file when it
38645 ** contains rollback data for exactly one page.
38647 #ifdef SQLITE_ENABLE_ATOMIC_WRITE
38648 static int jrnlBufferSize(Pager *pPager){
38649 assert( !MEMDB );
38650 if( !pPager->tempFile ){
38651 int dc; /* Device characteristics */
38652 int nSector; /* Sector size */
38653 int szPage; /* Page size */
38655 assert( isOpen(pPager->fd) );
38656 dc = sqlite3OsDeviceCharacteristics(pPager->fd);
38657 nSector = pPager->sectorSize;
38658 szPage = pPager->pageSize;
38660 assert(SQLITE_IOCAP_ATOMIC512==(512>>8));
38661 assert(SQLITE_IOCAP_ATOMIC64K==(65536>>8));
38662 if( 0==(dc&(SQLITE_IOCAP_ATOMIC|(szPage>>8)) || nSector>szPage) ){
38663 return 0;
38667 return JOURNAL_HDR_SZ(pPager) + JOURNAL_PG_SZ(pPager);
38669 #endif
38672 ** If SQLITE_CHECK_PAGES is defined then we do some sanity checking
38673 ** on the cache using a hash function. This is used for testing
38674 ** and debugging only.
38676 #ifdef SQLITE_CHECK_PAGES
38678 ** Return a 32-bit hash of the page data for pPage.
38680 static u32 pager_datahash(int nByte, unsigned char *pData){
38681 u32 hash = 0;
38682 int i;
38683 for(i=0; i<nByte; i++){
38684 hash = (hash*1039) + pData[i];
38686 return hash;
38688 static u32 pager_pagehash(PgHdr *pPage){
38689 return pager_datahash(pPage->pPager->pageSize, (unsigned char *)pPage->pData);
38691 static void pager_set_pagehash(PgHdr *pPage){
38692 pPage->pageHash = pager_pagehash(pPage);
38696 ** The CHECK_PAGE macro takes a PgHdr* as an argument. If SQLITE_CHECK_PAGES
38697 ** is defined, and NDEBUG is not defined, an assert() statement checks
38698 ** that the page is either dirty or still matches the calculated page-hash.
38700 #define CHECK_PAGE(x) checkPage(x)
38701 static void checkPage(PgHdr *pPg){
38702 Pager *pPager = pPg->pPager;
38703 assert( pPager->eState!=PAGER_ERROR );
38704 assert( (pPg->flags&PGHDR_DIRTY) || pPg->pageHash==pager_pagehash(pPg) );
38707 #else
38708 #define pager_datahash(X,Y) 0
38709 #define pager_pagehash(X) 0
38710 #define pager_set_pagehash(X)
38711 #define CHECK_PAGE(x)
38712 #endif /* SQLITE_CHECK_PAGES */
38715 ** When this is called the journal file for pager pPager must be open.
38716 ** This function attempts to read a master journal file name from the
38717 ** end of the file and, if successful, copies it into memory supplied
38718 ** by the caller. See comments above writeMasterJournal() for the format
38719 ** used to store a master journal file name at the end of a journal file.
38721 ** zMaster must point to a buffer of at least nMaster bytes allocated by
38722 ** the caller. This should be sqlite3_vfs.mxPathname+1 (to ensure there is
38723 ** enough space to write the master journal name). If the master journal
38724 ** name in the journal is longer than nMaster bytes (including a
38725 ** nul-terminator), then this is handled as if no master journal name
38726 ** were present in the journal.
38728 ** If a master journal file name is present at the end of the journal
38729 ** file, then it is copied into the buffer pointed to by zMaster. A
38730 ** nul-terminator byte is appended to the buffer following the master
38731 ** journal file name.
38733 ** If it is determined that no master journal file name is present
38734 ** zMaster[0] is set to 0 and SQLITE_OK returned.
38736 ** If an error occurs while reading from the journal file, an SQLite
38737 ** error code is returned.
38739 static int readMasterJournal(sqlite3_file *pJrnl, char *zMaster, u32 nMaster){
38740 int rc; /* Return code */
38741 u32 len; /* Length in bytes of master journal name */
38742 i64 szJ; /* Total size in bytes of journal file pJrnl */
38743 u32 cksum; /* MJ checksum value read from journal */
38744 u32 u; /* Unsigned loop counter */
38745 unsigned char aMagic[8]; /* A buffer to hold the magic header */
38746 zMaster[0] = '\0';
38748 if( SQLITE_OK!=(rc = sqlite3OsFileSize(pJrnl, &szJ))
38749 || szJ<16
38750 || SQLITE_OK!=(rc = read32bits(pJrnl, szJ-16, &len))
38751 || len>=nMaster
38752 || SQLITE_OK!=(rc = read32bits(pJrnl, szJ-12, &cksum))
38753 || SQLITE_OK!=(rc = sqlite3OsRead(pJrnl, aMagic, 8, szJ-8))
38754 || memcmp(aMagic, aJournalMagic, 8)
38755 || SQLITE_OK!=(rc = sqlite3OsRead(pJrnl, zMaster, len, szJ-16-len))
38757 return rc;
38760 /* See if the checksum matches the master journal name */
38761 for(u=0; u<len; u++){
38762 cksum -= zMaster[u];
38764 if( cksum ){
38765 /* If the checksum doesn't add up, then one or more of the disk sectors
38766 ** containing the master journal filename is corrupted. This means
38767 ** definitely roll back, so just return SQLITE_OK and report a (nul)
38768 ** master-journal filename.
38770 len = 0;
38772 zMaster[len] = '\0';
38774 return SQLITE_OK;
38778 ** Return the offset of the sector boundary at or immediately
38779 ** following the value in pPager->journalOff, assuming a sector
38780 ** size of pPager->sectorSize bytes.
38782 ** i.e for a sector size of 512:
38784 ** Pager.journalOff Return value
38785 ** ---------------------------------------
38786 ** 0 0
38787 ** 512 512
38788 ** 100 512
38789 ** 2000 2048
38792 static i64 journalHdrOffset(Pager *pPager){
38793 i64 offset = 0;
38794 i64 c = pPager->journalOff;
38795 if( c ){
38796 offset = ((c-1)/JOURNAL_HDR_SZ(pPager) + 1) * JOURNAL_HDR_SZ(pPager);
38798 assert( offset%JOURNAL_HDR_SZ(pPager)==0 );
38799 assert( offset>=c );
38800 assert( (offset-c)<JOURNAL_HDR_SZ(pPager) );
38801 return offset;
38805 ** The journal file must be open when this function is called.
38807 ** This function is a no-op if the journal file has not been written to
38808 ** within the current transaction (i.e. if Pager.journalOff==0).
38810 ** If doTruncate is non-zero or the Pager.journalSizeLimit variable is
38811 ** set to 0, then truncate the journal file to zero bytes in size. Otherwise,
38812 ** zero the 28-byte header at the start of the journal file. In either case,
38813 ** if the pager is not in no-sync mode, sync the journal file immediately
38814 ** after writing or truncating it.
38816 ** If Pager.journalSizeLimit is set to a positive, non-zero value, and
38817 ** following the truncation or zeroing described above the size of the
38818 ** journal file in bytes is larger than this value, then truncate the
38819 ** journal file to Pager.journalSizeLimit bytes. The journal file does
38820 ** not need to be synced following this operation.
38822 ** If an IO error occurs, abandon processing and return the IO error code.
38823 ** Otherwise, return SQLITE_OK.
38825 static int zeroJournalHdr(Pager *pPager, int doTruncate){
38826 int rc = SQLITE_OK; /* Return code */
38827 assert( isOpen(pPager->jfd) );
38828 if( pPager->journalOff ){
38829 const i64 iLimit = pPager->journalSizeLimit; /* Local cache of jsl */
38831 IOTRACE(("JZEROHDR %p\n", pPager))
38832 if( doTruncate || iLimit==0 ){
38833 rc = sqlite3OsTruncate(pPager->jfd, 0);
38834 }else{
38835 static const char zeroHdr[28] = {0};
38836 rc = sqlite3OsWrite(pPager->jfd, zeroHdr, sizeof(zeroHdr), 0);
38838 if( rc==SQLITE_OK && !pPager->noSync ){
38839 rc = sqlite3OsSync(pPager->jfd, SQLITE_SYNC_DATAONLY|pPager->syncFlags);
38842 /* At this point the transaction is committed but the write lock
38843 ** is still held on the file. If there is a size limit configured for
38844 ** the persistent journal and the journal file currently consumes more
38845 ** space than that limit allows for, truncate it now. There is no need
38846 ** to sync the file following this operation.
38848 if( rc==SQLITE_OK && iLimit>0 ){
38849 i64 sz;
38850 rc = sqlite3OsFileSize(pPager->jfd, &sz);
38851 if( rc==SQLITE_OK && sz>iLimit ){
38852 rc = sqlite3OsTruncate(pPager->jfd, iLimit);
38856 return rc;
38860 ** The journal file must be open when this routine is called. A journal
38861 ** header (JOURNAL_HDR_SZ bytes) is written into the journal file at the
38862 ** current location.
38864 ** The format for the journal header is as follows:
38865 ** - 8 bytes: Magic identifying journal format.
38866 ** - 4 bytes: Number of records in journal, or -1 no-sync mode is on.
38867 ** - 4 bytes: Random number used for page hash.
38868 ** - 4 bytes: Initial database page count.
38869 ** - 4 bytes: Sector size used by the process that wrote this journal.
38870 ** - 4 bytes: Database page size.
38872 ** Followed by (JOURNAL_HDR_SZ - 28) bytes of unused space.
38874 static int writeJournalHdr(Pager *pPager){
38875 int rc = SQLITE_OK; /* Return code */
38876 char *zHeader = pPager->pTmpSpace; /* Temporary space used to build header */
38877 u32 nHeader = (u32)pPager->pageSize;/* Size of buffer pointed to by zHeader */
38878 u32 nWrite; /* Bytes of header sector written */
38879 int ii; /* Loop counter */
38881 assert( isOpen(pPager->jfd) ); /* Journal file must be open. */
38883 if( nHeader>JOURNAL_HDR_SZ(pPager) ){
38884 nHeader = JOURNAL_HDR_SZ(pPager);
38887 /* If there are active savepoints and any of them were created
38888 ** since the most recent journal header was written, update the
38889 ** PagerSavepoint.iHdrOffset fields now.
38891 for(ii=0; ii<pPager->nSavepoint; ii++){
38892 if( pPager->aSavepoint[ii].iHdrOffset==0 ){
38893 pPager->aSavepoint[ii].iHdrOffset = pPager->journalOff;
38897 pPager->journalHdr = pPager->journalOff = journalHdrOffset(pPager);
38900 ** Write the nRec Field - the number of page records that follow this
38901 ** journal header. Normally, zero is written to this value at this time.
38902 ** After the records are added to the journal (and the journal synced,
38903 ** if in full-sync mode), the zero is overwritten with the true number
38904 ** of records (see syncJournal()).
38906 ** A faster alternative is to write 0xFFFFFFFF to the nRec field. When
38907 ** reading the journal this value tells SQLite to assume that the
38908 ** rest of the journal file contains valid page records. This assumption
38909 ** is dangerous, as if a failure occurred whilst writing to the journal
38910 ** file it may contain some garbage data. There are two scenarios
38911 ** where this risk can be ignored:
38913 ** * When the pager is in no-sync mode. Corruption can follow a
38914 ** power failure in this case anyway.
38916 ** * When the SQLITE_IOCAP_SAFE_APPEND flag is set. This guarantees
38917 ** that garbage data is never appended to the journal file.
38919 assert( isOpen(pPager->fd) || pPager->noSync );
38920 if( pPager->noSync || (pPager->journalMode==PAGER_JOURNALMODE_MEMORY)
38921 || (sqlite3OsDeviceCharacteristics(pPager->fd)&SQLITE_IOCAP_SAFE_APPEND)
38923 memcpy(zHeader, aJournalMagic, sizeof(aJournalMagic));
38924 put32bits(&zHeader[sizeof(aJournalMagic)], 0xffffffff);
38925 }else{
38926 memset(zHeader, 0, sizeof(aJournalMagic)+4);
38929 /* The random check-hash initialiser */
38930 sqlite3_randomness(sizeof(pPager->cksumInit), &pPager->cksumInit);
38931 put32bits(&zHeader[sizeof(aJournalMagic)+4], pPager->cksumInit);
38932 /* The initial database size */
38933 put32bits(&zHeader[sizeof(aJournalMagic)+8], pPager->dbOrigSize);
38934 /* The assumed sector size for this process */
38935 put32bits(&zHeader[sizeof(aJournalMagic)+12], pPager->sectorSize);
38937 /* The page size */
38938 put32bits(&zHeader[sizeof(aJournalMagic)+16], pPager->pageSize);
38940 /* Initializing the tail of the buffer is not necessary. Everything
38941 ** works find if the following memset() is omitted. But initializing
38942 ** the memory prevents valgrind from complaining, so we are willing to
38943 ** take the performance hit.
38945 memset(&zHeader[sizeof(aJournalMagic)+20], 0,
38946 nHeader-(sizeof(aJournalMagic)+20));
38948 /* In theory, it is only necessary to write the 28 bytes that the
38949 ** journal header consumes to the journal file here. Then increment the
38950 ** Pager.journalOff variable by JOURNAL_HDR_SZ so that the next
38951 ** record is written to the following sector (leaving a gap in the file
38952 ** that will be implicitly filled in by the OS).
38954 ** However it has been discovered that on some systems this pattern can
38955 ** be significantly slower than contiguously writing data to the file,
38956 ** even if that means explicitly writing data to the block of
38957 ** (JOURNAL_HDR_SZ - 28) bytes that will not be used. So that is what
38958 ** is done.
38960 ** The loop is required here in case the sector-size is larger than the
38961 ** database page size. Since the zHeader buffer is only Pager.pageSize
38962 ** bytes in size, more than one call to sqlite3OsWrite() may be required
38963 ** to populate the entire journal header sector.
38965 for(nWrite=0; rc==SQLITE_OK&&nWrite<JOURNAL_HDR_SZ(pPager); nWrite+=nHeader){
38966 IOTRACE(("JHDR %p %lld %d\n", pPager, pPager->journalHdr, nHeader))
38967 rc = sqlite3OsWrite(pPager->jfd, zHeader, nHeader, pPager->journalOff);
38968 assert( pPager->journalHdr <= pPager->journalOff );
38969 pPager->journalOff += nHeader;
38972 return rc;
38976 ** The journal file must be open when this is called. A journal header file
38977 ** (JOURNAL_HDR_SZ bytes) is read from the current location in the journal
38978 ** file. The current location in the journal file is given by
38979 ** pPager->journalOff. See comments above function writeJournalHdr() for
38980 ** a description of the journal header format.
38982 ** If the header is read successfully, *pNRec is set to the number of
38983 ** page records following this header and *pDbSize is set to the size of the
38984 ** database before the transaction began, in pages. Also, pPager->cksumInit
38985 ** is set to the value read from the journal header. SQLITE_OK is returned
38986 ** in this case.
38988 ** If the journal header file appears to be corrupted, SQLITE_DONE is
38989 ** returned and *pNRec and *PDbSize are undefined. If JOURNAL_HDR_SZ bytes
38990 ** cannot be read from the journal file an error code is returned.
38992 static int readJournalHdr(
38993 Pager *pPager, /* Pager object */
38994 int isHot,
38995 i64 journalSize, /* Size of the open journal file in bytes */
38996 u32 *pNRec, /* OUT: Value read from the nRec field */
38997 u32 *pDbSize /* OUT: Value of original database size field */
38999 int rc; /* Return code */
39000 unsigned char aMagic[8]; /* A buffer to hold the magic header */
39001 i64 iHdrOff; /* Offset of journal header being read */
39003 assert( isOpen(pPager->jfd) ); /* Journal file must be open. */
39005 /* Advance Pager.journalOff to the start of the next sector. If the
39006 ** journal file is too small for there to be a header stored at this
39007 ** point, return SQLITE_DONE.
39009 pPager->journalOff = journalHdrOffset(pPager);
39010 if( pPager->journalOff+JOURNAL_HDR_SZ(pPager) > journalSize ){
39011 return SQLITE_DONE;
39013 iHdrOff = pPager->journalOff;
39015 /* Read in the first 8 bytes of the journal header. If they do not match
39016 ** the magic string found at the start of each journal header, return
39017 ** SQLITE_DONE. If an IO error occurs, return an error code. Otherwise,
39018 ** proceed.
39020 if( isHot || iHdrOff!=pPager->journalHdr ){
39021 rc = sqlite3OsRead(pPager->jfd, aMagic, sizeof(aMagic), iHdrOff);
39022 if( rc ){
39023 return rc;
39025 if( memcmp(aMagic, aJournalMagic, sizeof(aMagic))!=0 ){
39026 return SQLITE_DONE;
39030 /* Read the first three 32-bit fields of the journal header: The nRec
39031 ** field, the checksum-initializer and the database size at the start
39032 ** of the transaction. Return an error code if anything goes wrong.
39034 if( SQLITE_OK!=(rc = read32bits(pPager->jfd, iHdrOff+8, pNRec))
39035 || SQLITE_OK!=(rc = read32bits(pPager->jfd, iHdrOff+12, &pPager->cksumInit))
39036 || SQLITE_OK!=(rc = read32bits(pPager->jfd, iHdrOff+16, pDbSize))
39038 return rc;
39041 if( pPager->journalOff==0 ){
39042 u32 iPageSize; /* Page-size field of journal header */
39043 u32 iSectorSize; /* Sector-size field of journal header */
39045 /* Read the page-size and sector-size journal header fields. */
39046 if( SQLITE_OK!=(rc = read32bits(pPager->jfd, iHdrOff+20, &iSectorSize))
39047 || SQLITE_OK!=(rc = read32bits(pPager->jfd, iHdrOff+24, &iPageSize))
39049 return rc;
39052 /* Versions of SQLite prior to 3.5.8 set the page-size field of the
39053 ** journal header to zero. In this case, assume that the Pager.pageSize
39054 ** variable is already set to the correct page size.
39056 if( iPageSize==0 ){
39057 iPageSize = pPager->pageSize;
39060 /* Check that the values read from the page-size and sector-size fields
39061 ** are within range. To be 'in range', both values need to be a power
39062 ** of two greater than or equal to 512 or 32, and not greater than their
39063 ** respective compile time maximum limits.
39065 if( iPageSize<512 || iSectorSize<32
39066 || iPageSize>SQLITE_MAX_PAGE_SIZE || iSectorSize>MAX_SECTOR_SIZE
39067 || ((iPageSize-1)&iPageSize)!=0 || ((iSectorSize-1)&iSectorSize)!=0
39069 /* If the either the page-size or sector-size in the journal-header is
39070 ** invalid, then the process that wrote the journal-header must have
39071 ** crashed before the header was synced. In this case stop reading
39072 ** the journal file here.
39074 return SQLITE_DONE;
39077 /* Update the page-size to match the value read from the journal.
39078 ** Use a testcase() macro to make sure that malloc failure within
39079 ** PagerSetPagesize() is tested.
39081 rc = sqlite3PagerSetPagesize(pPager, &iPageSize, -1);
39082 testcase( rc!=SQLITE_OK );
39084 /* Update the assumed sector-size to match the value used by
39085 ** the process that created this journal. If this journal was
39086 ** created by a process other than this one, then this routine
39087 ** is being called from within pager_playback(). The local value
39088 ** of Pager.sectorSize is restored at the end of that routine.
39090 pPager->sectorSize = iSectorSize;
39093 pPager->journalOff += JOURNAL_HDR_SZ(pPager);
39094 return rc;
39099 ** Write the supplied master journal name into the journal file for pager
39100 ** pPager at the current location. The master journal name must be the last
39101 ** thing written to a journal file. If the pager is in full-sync mode, the
39102 ** journal file descriptor is advanced to the next sector boundary before
39103 ** anything is written. The format is:
39105 ** + 4 bytes: PAGER_MJ_PGNO.
39106 ** + N bytes: Master journal filename in utf-8.
39107 ** + 4 bytes: N (length of master journal name in bytes, no nul-terminator).
39108 ** + 4 bytes: Master journal name checksum.
39109 ** + 8 bytes: aJournalMagic[].
39111 ** The master journal page checksum is the sum of the bytes in the master
39112 ** journal name, where each byte is interpreted as a signed 8-bit integer.
39114 ** If zMaster is a NULL pointer (occurs for a single database transaction),
39115 ** this call is a no-op.
39117 static int writeMasterJournal(Pager *pPager, const char *zMaster){
39118 int rc; /* Return code */
39119 int nMaster; /* Length of string zMaster */
39120 i64 iHdrOff; /* Offset of header in journal file */
39121 i64 jrnlSize; /* Size of journal file on disk */
39122 u32 cksum = 0; /* Checksum of string zMaster */
39124 assert( pPager->setMaster==0 );
39125 assert( !pagerUseWal(pPager) );
39127 if( !zMaster
39128 || pPager->journalMode==PAGER_JOURNALMODE_MEMORY
39129 || pPager->journalMode==PAGER_JOURNALMODE_OFF
39131 return SQLITE_OK;
39133 pPager->setMaster = 1;
39134 assert( isOpen(pPager->jfd) );
39135 assert( pPager->journalHdr <= pPager->journalOff );
39137 /* Calculate the length in bytes and the checksum of zMaster */
39138 for(nMaster=0; zMaster[nMaster]; nMaster++){
39139 cksum += zMaster[nMaster];
39142 /* If in full-sync mode, advance to the next disk sector before writing
39143 ** the master journal name. This is in case the previous page written to
39144 ** the journal has already been synced.
39146 if( pPager->fullSync ){
39147 pPager->journalOff = journalHdrOffset(pPager);
39149 iHdrOff = pPager->journalOff;
39151 /* Write the master journal data to the end of the journal file. If
39152 ** an error occurs, return the error code to the caller.
39154 if( (0 != (rc = write32bits(pPager->jfd, iHdrOff, PAGER_MJ_PGNO(pPager))))
39155 || (0 != (rc = sqlite3OsWrite(pPager->jfd, zMaster, nMaster, iHdrOff+4)))
39156 || (0 != (rc = write32bits(pPager->jfd, iHdrOff+4+nMaster, nMaster)))
39157 || (0 != (rc = write32bits(pPager->jfd, iHdrOff+4+nMaster+4, cksum)))
39158 || (0 != (rc = sqlite3OsWrite(pPager->jfd, aJournalMagic, 8, iHdrOff+4+nMaster+8)))
39160 return rc;
39162 pPager->journalOff += (nMaster+20);
39164 /* If the pager is in peristent-journal mode, then the physical
39165 ** journal-file may extend past the end of the master-journal name
39166 ** and 8 bytes of magic data just written to the file. This is
39167 ** dangerous because the code to rollback a hot-journal file
39168 ** will not be able to find the master-journal name to determine
39169 ** whether or not the journal is hot.
39171 ** Easiest thing to do in this scenario is to truncate the journal
39172 ** file to the required size.
39174 if( SQLITE_OK==(rc = sqlite3OsFileSize(pPager->jfd, &jrnlSize))
39175 && jrnlSize>pPager->journalOff
39177 rc = sqlite3OsTruncate(pPager->jfd, pPager->journalOff);
39179 return rc;
39183 ** Find a page in the hash table given its page number. Return
39184 ** a pointer to the page or NULL if the requested page is not
39185 ** already in memory.
39187 static PgHdr *pager_lookup(Pager *pPager, Pgno pgno){
39188 PgHdr *p; /* Return value */
39190 /* It is not possible for a call to PcacheFetch() with createFlag==0 to
39191 ** fail, since no attempt to allocate dynamic memory will be made.
39193 (void)sqlite3PcacheFetch(pPager->pPCache, pgno, 0, &p);
39194 return p;
39198 ** Discard the entire contents of the in-memory page-cache.
39200 static void pager_reset(Pager *pPager){
39201 sqlite3BackupRestart(pPager->pBackup);
39202 sqlite3PcacheClear(pPager->pPCache);
39206 ** Free all structures in the Pager.aSavepoint[] array and set both
39207 ** Pager.aSavepoint and Pager.nSavepoint to zero. Close the sub-journal
39208 ** if it is open and the pager is not in exclusive mode.
39210 static void releaseAllSavepoints(Pager *pPager){
39211 int ii; /* Iterator for looping through Pager.aSavepoint */
39212 for(ii=0; ii<pPager->nSavepoint; ii++){
39213 sqlite3BitvecDestroy(pPager->aSavepoint[ii].pInSavepoint);
39215 if( !pPager->exclusiveMode || sqlite3IsMemJournal(pPager->sjfd) ){
39216 sqlite3OsClose(pPager->sjfd);
39218 sqlite3_free(pPager->aSavepoint);
39219 pPager->aSavepoint = 0;
39220 pPager->nSavepoint = 0;
39221 pPager->nSubRec = 0;
39225 ** Set the bit number pgno in the PagerSavepoint.pInSavepoint
39226 ** bitvecs of all open savepoints. Return SQLITE_OK if successful
39227 ** or SQLITE_NOMEM if a malloc failure occurs.
39229 static int addToSavepointBitvecs(Pager *pPager, Pgno pgno){
39230 int ii; /* Loop counter */
39231 int rc = SQLITE_OK; /* Result code */
39233 for(ii=0; ii<pPager->nSavepoint; ii++){
39234 PagerSavepoint *p = &pPager->aSavepoint[ii];
39235 if( pgno<=p->nOrig ){
39236 rc |= sqlite3BitvecSet(p->pInSavepoint, pgno);
39237 testcase( rc==SQLITE_NOMEM );
39238 assert( rc==SQLITE_OK || rc==SQLITE_NOMEM );
39241 return rc;
39245 ** This function is a no-op if the pager is in exclusive mode and not
39246 ** in the ERROR state. Otherwise, it switches the pager to PAGER_OPEN
39247 ** state.
39249 ** If the pager is not in exclusive-access mode, the database file is
39250 ** completely unlocked. If the file is unlocked and the file-system does
39251 ** not exhibit the UNDELETABLE_WHEN_OPEN property, the journal file is
39252 ** closed (if it is open).
39254 ** If the pager is in ERROR state when this function is called, the
39255 ** contents of the pager cache are discarded before switching back to
39256 ** the OPEN state. Regardless of whether the pager is in exclusive-mode
39257 ** or not, any journal file left in the file-system will be treated
39258 ** as a hot-journal and rolled back the next time a read-transaction
39259 ** is opened (by this or by any other connection).
39261 static void pager_unlock(Pager *pPager){
39263 assert( pPager->eState==PAGER_READER
39264 || pPager->eState==PAGER_OPEN
39265 || pPager->eState==PAGER_ERROR
39268 sqlite3BitvecDestroy(pPager->pInJournal);
39269 pPager->pInJournal = 0;
39270 releaseAllSavepoints(pPager);
39272 if( pagerUseWal(pPager) ){
39273 assert( !isOpen(pPager->jfd) );
39274 sqlite3WalEndReadTransaction(pPager->pWal);
39275 pPager->eState = PAGER_OPEN;
39276 }else if( !pPager->exclusiveMode ){
39277 int rc; /* Error code returned by pagerUnlockDb() */
39278 int iDc = isOpen(pPager->fd)?sqlite3OsDeviceCharacteristics(pPager->fd):0;
39280 /* If the operating system support deletion of open files, then
39281 ** close the journal file when dropping the database lock. Otherwise
39282 ** another connection with journal_mode=delete might delete the file
39283 ** out from under us.
39285 assert( (PAGER_JOURNALMODE_MEMORY & 5)!=1 );
39286 assert( (PAGER_JOURNALMODE_OFF & 5)!=1 );
39287 assert( (PAGER_JOURNALMODE_WAL & 5)!=1 );
39288 assert( (PAGER_JOURNALMODE_DELETE & 5)!=1 );
39289 assert( (PAGER_JOURNALMODE_TRUNCATE & 5)==1 );
39290 assert( (PAGER_JOURNALMODE_PERSIST & 5)==1 );
39291 if( 0==(iDc & SQLITE_IOCAP_UNDELETABLE_WHEN_OPEN)
39292 || 1!=(pPager->journalMode & 5)
39294 sqlite3OsClose(pPager->jfd);
39297 /* If the pager is in the ERROR state and the call to unlock the database
39298 ** file fails, set the current lock to UNKNOWN_LOCK. See the comment
39299 ** above the #define for UNKNOWN_LOCK for an explanation of why this
39300 ** is necessary.
39302 rc = pagerUnlockDb(pPager, NO_LOCK);
39303 if( rc!=SQLITE_OK && pPager->eState==PAGER_ERROR ){
39304 pPager->eLock = UNKNOWN_LOCK;
39307 /* The pager state may be changed from PAGER_ERROR to PAGER_OPEN here
39308 ** without clearing the error code. This is intentional - the error
39309 ** code is cleared and the cache reset in the block below.
39311 assert( pPager->errCode || pPager->eState!=PAGER_ERROR );
39312 pPager->changeCountDone = 0;
39313 pPager->eState = PAGER_OPEN;
39316 /* If Pager.errCode is set, the contents of the pager cache cannot be
39317 ** trusted. Now that there are no outstanding references to the pager,
39318 ** it can safely move back to PAGER_OPEN state. This happens in both
39319 ** normal and exclusive-locking mode.
39321 if( pPager->errCode ){
39322 assert( !MEMDB );
39323 pager_reset(pPager);
39324 pPager->changeCountDone = pPager->tempFile;
39325 pPager->eState = PAGER_OPEN;
39326 pPager->errCode = SQLITE_OK;
39329 pPager->journalOff = 0;
39330 pPager->journalHdr = 0;
39331 pPager->setMaster = 0;
39335 ** This function is called whenever an IOERR or FULL error that requires
39336 ** the pager to transition into the ERROR state may ahve occurred.
39337 ** The first argument is a pointer to the pager structure, the second
39338 ** the error-code about to be returned by a pager API function. The
39339 ** value returned is a copy of the second argument to this function.
39341 ** If the second argument is SQLITE_FULL, SQLITE_IOERR or one of the
39342 ** IOERR sub-codes, the pager enters the ERROR state and the error code
39343 ** is stored in Pager.errCode. While the pager remains in the ERROR state,
39344 ** all major API calls on the Pager will immediately return Pager.errCode.
39346 ** The ERROR state indicates that the contents of the pager-cache
39347 ** cannot be trusted. This state can be cleared by completely discarding
39348 ** the contents of the pager-cache. If a transaction was active when
39349 ** the persistent error occurred, then the rollback journal may need
39350 ** to be replayed to restore the contents of the database file (as if
39351 ** it were a hot-journal).
39353 static int pager_error(Pager *pPager, int rc){
39354 int rc2 = rc & 0xff;
39355 assert( rc==SQLITE_OK || !MEMDB );
39356 assert(
39357 pPager->errCode==SQLITE_FULL ||
39358 pPager->errCode==SQLITE_OK ||
39359 (pPager->errCode & 0xff)==SQLITE_IOERR
39361 if( rc2==SQLITE_FULL || rc2==SQLITE_IOERR ){
39362 pPager->errCode = rc;
39363 pPager->eState = PAGER_ERROR;
39365 return rc;
39369 ** This routine ends a transaction. A transaction is usually ended by
39370 ** either a COMMIT or a ROLLBACK operation. This routine may be called
39371 ** after rollback of a hot-journal, or if an error occurs while opening
39372 ** the journal file or writing the very first journal-header of a
39373 ** database transaction.
39375 ** This routine is never called in PAGER_ERROR state. If it is called
39376 ** in PAGER_NONE or PAGER_SHARED state and the lock held is less
39377 ** exclusive than a RESERVED lock, it is a no-op.
39379 ** Otherwise, any active savepoints are released.
39381 ** If the journal file is open, then it is "finalized". Once a journal
39382 ** file has been finalized it is not possible to use it to roll back a
39383 ** transaction. Nor will it be considered to be a hot-journal by this
39384 ** or any other database connection. Exactly how a journal is finalized
39385 ** depends on whether or not the pager is running in exclusive mode and
39386 ** the current journal-mode (Pager.journalMode value), as follows:
39388 ** journalMode==MEMORY
39389 ** Journal file descriptor is simply closed. This destroys an
39390 ** in-memory journal.
39392 ** journalMode==TRUNCATE
39393 ** Journal file is truncated to zero bytes in size.
39395 ** journalMode==PERSIST
39396 ** The first 28 bytes of the journal file are zeroed. This invalidates
39397 ** the first journal header in the file, and hence the entire journal
39398 ** file. An invalid journal file cannot be rolled back.
39400 ** journalMode==DELETE
39401 ** The journal file is closed and deleted using sqlite3OsDelete().
39403 ** If the pager is running in exclusive mode, this method of finalizing
39404 ** the journal file is never used. Instead, if the journalMode is
39405 ** DELETE and the pager is in exclusive mode, the method described under
39406 ** journalMode==PERSIST is used instead.
39408 ** After the journal is finalized, the pager moves to PAGER_READER state.
39409 ** If running in non-exclusive rollback mode, the lock on the file is
39410 ** downgraded to a SHARED_LOCK.
39412 ** SQLITE_OK is returned if no error occurs. If an error occurs during
39413 ** any of the IO operations to finalize the journal file or unlock the
39414 ** database then the IO error code is returned to the user. If the
39415 ** operation to finalize the journal file fails, then the code still
39416 ** tries to unlock the database file if not in exclusive mode. If the
39417 ** unlock operation fails as well, then the first error code related
39418 ** to the first error encountered (the journal finalization one) is
39419 ** returned.
39421 static int pager_end_transaction(Pager *pPager, int hasMaster){
39422 int rc = SQLITE_OK; /* Error code from journal finalization operation */
39423 int rc2 = SQLITE_OK; /* Error code from db file unlock operation */
39425 /* Do nothing if the pager does not have an open write transaction
39426 ** or at least a RESERVED lock. This function may be called when there
39427 ** is no write-transaction active but a RESERVED or greater lock is
39428 ** held under two circumstances:
39430 ** 1. After a successful hot-journal rollback, it is called with
39431 ** eState==PAGER_NONE and eLock==EXCLUSIVE_LOCK.
39433 ** 2. If a connection with locking_mode=exclusive holding an EXCLUSIVE
39434 ** lock switches back to locking_mode=normal and then executes a
39435 ** read-transaction, this function is called with eState==PAGER_READER
39436 ** and eLock==EXCLUSIVE_LOCK when the read-transaction is closed.
39438 assert( assert_pager_state(pPager) );
39439 assert( pPager->eState!=PAGER_ERROR );
39440 if( pPager->eState<PAGER_WRITER_LOCKED && pPager->eLock<RESERVED_LOCK ){
39441 return SQLITE_OK;
39444 releaseAllSavepoints(pPager);
39445 assert( isOpen(pPager->jfd) || pPager->pInJournal==0 );
39446 if( isOpen(pPager->jfd) ){
39447 assert( !pagerUseWal(pPager) );
39449 /* Finalize the journal file. */
39450 if( sqlite3IsMemJournal(pPager->jfd) ){
39451 assert( pPager->journalMode==PAGER_JOURNALMODE_MEMORY );
39452 sqlite3OsClose(pPager->jfd);
39453 }else if( pPager->journalMode==PAGER_JOURNALMODE_TRUNCATE ){
39454 if( pPager->journalOff==0 ){
39455 rc = SQLITE_OK;
39456 }else{
39457 rc = sqlite3OsTruncate(pPager->jfd, 0);
39459 pPager->journalOff = 0;
39460 }else if( pPager->journalMode==PAGER_JOURNALMODE_PERSIST
39461 || (pPager->exclusiveMode && pPager->journalMode!=PAGER_JOURNALMODE_WAL)
39463 rc = zeroJournalHdr(pPager, hasMaster);
39464 pPager->journalOff = 0;
39465 }else{
39466 /* This branch may be executed with Pager.journalMode==MEMORY if
39467 ** a hot-journal was just rolled back. In this case the journal
39468 ** file should be closed and deleted. If this connection writes to
39469 ** the database file, it will do so using an in-memory journal.
39471 assert( pPager->journalMode==PAGER_JOURNALMODE_DELETE
39472 || pPager->journalMode==PAGER_JOURNALMODE_MEMORY
39473 || pPager->journalMode==PAGER_JOURNALMODE_WAL
39475 sqlite3OsClose(pPager->jfd);
39476 if( !pPager->tempFile ){
39477 rc = sqlite3OsDelete(pPager->pVfs, pPager->zJournal, 0);
39482 #ifdef SQLITE_CHECK_PAGES
39483 sqlite3PcacheIterateDirty(pPager->pPCache, pager_set_pagehash);
39484 if( pPager->dbSize==0 && sqlite3PcacheRefCount(pPager->pPCache)>0 ){
39485 PgHdr *p = pager_lookup(pPager, 1);
39486 if( p ){
39487 p->pageHash = 0;
39488 sqlite3PagerUnref(p);
39491 #endif
39493 sqlite3BitvecDestroy(pPager->pInJournal);
39494 pPager->pInJournal = 0;
39495 pPager->nRec = 0;
39496 sqlite3PcacheCleanAll(pPager->pPCache);
39497 sqlite3PcacheTruncate(pPager->pPCache, pPager->dbSize);
39499 if( pagerUseWal(pPager) ){
39500 /* Drop the WAL write-lock, if any. Also, if the connection was in
39501 ** locking_mode=exclusive mode but is no longer, drop the EXCLUSIVE
39502 ** lock held on the database file.
39504 rc2 = sqlite3WalEndWriteTransaction(pPager->pWal);
39505 assert( rc2==SQLITE_OK );
39507 if( !pPager->exclusiveMode
39508 && (!pagerUseWal(pPager) || sqlite3WalExclusiveMode(pPager->pWal, 0))
39510 rc2 = pagerUnlockDb(pPager, SHARED_LOCK);
39511 pPager->changeCountDone = 0;
39513 pPager->eState = PAGER_READER;
39514 pPager->setMaster = 0;
39516 return (rc==SQLITE_OK?rc2:rc);
39520 ** Execute a rollback if a transaction is active and unlock the
39521 ** database file.
39523 ** If the pager has already entered the ERROR state, do not attempt
39524 ** the rollback at this time. Instead, pager_unlock() is called. The
39525 ** call to pager_unlock() will discard all in-memory pages, unlock
39526 ** the database file and move the pager back to OPEN state. If this
39527 ** means that there is a hot-journal left in the file-system, the next
39528 ** connection to obtain a shared lock on the pager (which may be this one)
39529 ** will roll it back.
39531 ** If the pager has not already entered the ERROR state, but an IO or
39532 ** malloc error occurs during a rollback, then this will itself cause
39533 ** the pager to enter the ERROR state. Which will be cleared by the
39534 ** call to pager_unlock(), as described above.
39536 static void pagerUnlockAndRollback(Pager *pPager){
39537 if( pPager->eState!=PAGER_ERROR && pPager->eState!=PAGER_OPEN ){
39538 assert( assert_pager_state(pPager) );
39539 if( pPager->eState>=PAGER_WRITER_LOCKED ){
39540 sqlite3BeginBenignMalloc();
39541 sqlite3PagerRollback(pPager);
39542 sqlite3EndBenignMalloc();
39543 }else if( !pPager->exclusiveMode ){
39544 assert( pPager->eState==PAGER_READER );
39545 pager_end_transaction(pPager, 0);
39548 pager_unlock(pPager);
39552 ** Parameter aData must point to a buffer of pPager->pageSize bytes
39553 ** of data. Compute and return a checksum based ont the contents of the
39554 ** page of data and the current value of pPager->cksumInit.
39556 ** This is not a real checksum. It is really just the sum of the
39557 ** random initial value (pPager->cksumInit) and every 200th byte
39558 ** of the page data, starting with byte offset (pPager->pageSize%200).
39559 ** Each byte is interpreted as an 8-bit unsigned integer.
39561 ** Changing the formula used to compute this checksum results in an
39562 ** incompatible journal file format.
39564 ** If journal corruption occurs due to a power failure, the most likely
39565 ** scenario is that one end or the other of the record will be changed.
39566 ** It is much less likely that the two ends of the journal record will be
39567 ** correct and the middle be corrupt. Thus, this "checksum" scheme,
39568 ** though fast and simple, catches the mostly likely kind of corruption.
39570 static u32 pager_cksum(Pager *pPager, const u8 *aData){
39571 u32 cksum = pPager->cksumInit; /* Checksum value to return */
39572 int i = pPager->pageSize-200; /* Loop counter */
39573 while( i>0 ){
39574 cksum += aData[i];
39575 i -= 200;
39577 return cksum;
39581 ** Report the current page size and number of reserved bytes back
39582 ** to the codec.
39584 #ifdef SQLITE_HAS_CODEC
39585 static void pagerReportSize(Pager *pPager){
39586 if( pPager->xCodecSizeChng ){
39587 pPager->xCodecSizeChng(pPager->pCodec, pPager->pageSize,
39588 (int)pPager->nReserve);
39591 #else
39592 # define pagerReportSize(X) /* No-op if we do not support a codec */
39593 #endif
39596 ** Read a single page from either the journal file (if isMainJrnl==1) or
39597 ** from the sub-journal (if isMainJrnl==0) and playback that page.
39598 ** The page begins at offset *pOffset into the file. The *pOffset
39599 ** value is increased to the start of the next page in the journal.
39601 ** The main rollback journal uses checksums - the statement journal does
39602 ** not.
39604 ** If the page number of the page record read from the (sub-)journal file
39605 ** is greater than the current value of Pager.dbSize, then playback is
39606 ** skipped and SQLITE_OK is returned.
39608 ** If pDone is not NULL, then it is a record of pages that have already
39609 ** been played back. If the page at *pOffset has already been played back
39610 ** (if the corresponding pDone bit is set) then skip the playback.
39611 ** Make sure the pDone bit corresponding to the *pOffset page is set
39612 ** prior to returning.
39614 ** If the page record is successfully read from the (sub-)journal file
39615 ** and played back, then SQLITE_OK is returned. If an IO error occurs
39616 ** while reading the record from the (sub-)journal file or while writing
39617 ** to the database file, then the IO error code is returned. If data
39618 ** is successfully read from the (sub-)journal file but appears to be
39619 ** corrupted, SQLITE_DONE is returned. Data is considered corrupted in
39620 ** two circumstances:
39622 ** * If the record page-number is illegal (0 or PAGER_MJ_PGNO), or
39623 ** * If the record is being rolled back from the main journal file
39624 ** and the checksum field does not match the record content.
39626 ** Neither of these two scenarios are possible during a savepoint rollback.
39628 ** If this is a savepoint rollback, then memory may have to be dynamically
39629 ** allocated by this function. If this is the case and an allocation fails,
39630 ** SQLITE_NOMEM is returned.
39632 static int pager_playback_one_page(
39633 Pager *pPager, /* The pager being played back */
39634 i64 *pOffset, /* Offset of record to playback */
39635 Bitvec *pDone, /* Bitvec of pages already played back */
39636 int isMainJrnl, /* 1 -> main journal. 0 -> sub-journal. */
39637 int isSavepnt /* True for a savepoint rollback */
39639 int rc;
39640 PgHdr *pPg; /* An existing page in the cache */
39641 Pgno pgno; /* The page number of a page in journal */
39642 u32 cksum; /* Checksum used for sanity checking */
39643 char *aData; /* Temporary storage for the page */
39644 sqlite3_file *jfd; /* The file descriptor for the journal file */
39645 int isSynced; /* True if journal page is synced */
39647 assert( (isMainJrnl&~1)==0 ); /* isMainJrnl is 0 or 1 */
39648 assert( (isSavepnt&~1)==0 ); /* isSavepnt is 0 or 1 */
39649 assert( isMainJrnl || pDone ); /* pDone always used on sub-journals */
39650 assert( isSavepnt || pDone==0 ); /* pDone never used on non-savepoint */
39652 aData = pPager->pTmpSpace;
39653 assert( aData ); /* Temp storage must have already been allocated */
39654 assert( pagerUseWal(pPager)==0 || (!isMainJrnl && isSavepnt) );
39656 /* Either the state is greater than PAGER_WRITER_CACHEMOD (a transaction
39657 ** or savepoint rollback done at the request of the caller) or this is
39658 ** a hot-journal rollback. If it is a hot-journal rollback, the pager
39659 ** is in state OPEN and holds an EXCLUSIVE lock. Hot-journal rollback
39660 ** only reads from the main journal, not the sub-journal.
39662 assert( pPager->eState>=PAGER_WRITER_CACHEMOD
39663 || (pPager->eState==PAGER_OPEN && pPager->eLock==EXCLUSIVE_LOCK)
39665 assert( pPager->eState>=PAGER_WRITER_CACHEMOD || isMainJrnl );
39667 /* Read the page number and page data from the journal or sub-journal
39668 ** file. Return an error code to the caller if an IO error occurs.
39670 jfd = isMainJrnl ? pPager->jfd : pPager->sjfd;
39671 rc = read32bits(jfd, *pOffset, &pgno);
39672 if( rc!=SQLITE_OK ) return rc;
39673 rc = sqlite3OsRead(jfd, (u8*)aData, pPager->pageSize, (*pOffset)+4);
39674 if( rc!=SQLITE_OK ) return rc;
39675 *pOffset += pPager->pageSize + 4 + isMainJrnl*4;
39677 /* Sanity checking on the page. This is more important that I originally
39678 ** thought. If a power failure occurs while the journal is being written,
39679 ** it could cause invalid data to be written into the journal. We need to
39680 ** detect this invalid data (with high probability) and ignore it.
39682 if( pgno==0 || pgno==PAGER_MJ_PGNO(pPager) ){
39683 assert( !isSavepnt );
39684 return SQLITE_DONE;
39686 if( pgno>(Pgno)pPager->dbSize || sqlite3BitvecTest(pDone, pgno) ){
39687 return SQLITE_OK;
39689 if( isMainJrnl ){
39690 rc = read32bits(jfd, (*pOffset)-4, &cksum);
39691 if( rc ) return rc;
39692 if( !isSavepnt && pager_cksum(pPager, (u8*)aData)!=cksum ){
39693 return SQLITE_DONE;
39697 /* If this page has already been played by before during the current
39698 ** rollback, then don't bother to play it back again.
39700 if( pDone && (rc = sqlite3BitvecSet(pDone, pgno))!=SQLITE_OK ){
39701 return rc;
39704 /* When playing back page 1, restore the nReserve setting
39706 if( pgno==1 && pPager->nReserve!=((u8*)aData)[20] ){
39707 pPager->nReserve = ((u8*)aData)[20];
39708 pagerReportSize(pPager);
39711 /* If the pager is in CACHEMOD state, then there must be a copy of this
39712 ** page in the pager cache. In this case just update the pager cache,
39713 ** not the database file. The page is left marked dirty in this case.
39715 ** An exception to the above rule: If the database is in no-sync mode
39716 ** and a page is moved during an incremental vacuum then the page may
39717 ** not be in the pager cache. Later: if a malloc() or IO error occurs
39718 ** during a Movepage() call, then the page may not be in the cache
39719 ** either. So the condition described in the above paragraph is not
39720 ** assert()able.
39722 ** If in WRITER_DBMOD, WRITER_FINISHED or OPEN state, then we update the
39723 ** pager cache if it exists and the main file. The page is then marked
39724 ** not dirty. Since this code is only executed in PAGER_OPEN state for
39725 ** a hot-journal rollback, it is guaranteed that the page-cache is empty
39726 ** if the pager is in OPEN state.
39728 ** Ticket #1171: The statement journal might contain page content that is
39729 ** different from the page content at the start of the transaction.
39730 ** This occurs when a page is changed prior to the start of a statement
39731 ** then changed again within the statement. When rolling back such a
39732 ** statement we must not write to the original database unless we know
39733 ** for certain that original page contents are synced into the main rollback
39734 ** journal. Otherwise, a power loss might leave modified data in the
39735 ** database file without an entry in the rollback journal that can
39736 ** restore the database to its original form. Two conditions must be
39737 ** met before writing to the database files. (1) the database must be
39738 ** locked. (2) we know that the original page content is fully synced
39739 ** in the main journal either because the page is not in cache or else
39740 ** the page is marked as needSync==0.
39742 ** 2008-04-14: When attempting to vacuum a corrupt database file, it
39743 ** is possible to fail a statement on a database that does not yet exist.
39744 ** Do not attempt to write if database file has never been opened.
39746 if( pagerUseWal(pPager) ){
39747 pPg = 0;
39748 }else{
39749 pPg = pager_lookup(pPager, pgno);
39751 assert( pPg || !MEMDB );
39752 assert( pPager->eState!=PAGER_OPEN || pPg==0 );
39753 PAGERTRACE(("PLAYBACK %d page %d hash(%08x) %s\n",
39754 PAGERID(pPager), pgno, pager_datahash(pPager->pageSize, (u8*)aData),
39755 (isMainJrnl?"main-journal":"sub-journal")
39757 if( isMainJrnl ){
39758 isSynced = pPager->noSync || (*pOffset <= pPager->journalHdr);
39759 }else{
39760 isSynced = (pPg==0 || 0==(pPg->flags & PGHDR_NEED_SYNC));
39762 if( isOpen(pPager->fd)
39763 && (pPager->eState>=PAGER_WRITER_DBMOD || pPager->eState==PAGER_OPEN)
39764 && isSynced
39766 i64 ofst = (pgno-1)*(i64)pPager->pageSize;
39767 testcase( !isSavepnt && pPg!=0 && (pPg->flags&PGHDR_NEED_SYNC)!=0 );
39768 assert( !pagerUseWal(pPager) );
39769 rc = sqlite3OsWrite(pPager->fd, (u8*)aData, pPager->pageSize, ofst);
39770 if( pgno>pPager->dbFileSize ){
39771 pPager->dbFileSize = pgno;
39773 if( pPager->pBackup ){
39774 CODEC1(pPager, aData, pgno, 3, rc=SQLITE_NOMEM);
39775 sqlite3BackupUpdate(pPager->pBackup, pgno, (u8*)aData);
39776 CODEC2(pPager, aData, pgno, 7, rc=SQLITE_NOMEM, aData);
39778 }else if( !isMainJrnl && pPg==0 ){
39779 /* If this is a rollback of a savepoint and data was not written to
39780 ** the database and the page is not in-memory, there is a potential
39781 ** problem. When the page is next fetched by the b-tree layer, it
39782 ** will be read from the database file, which may or may not be
39783 ** current.
39785 ** There are a couple of different ways this can happen. All are quite
39786 ** obscure. When running in synchronous mode, this can only happen
39787 ** if the page is on the free-list at the start of the transaction, then
39788 ** populated, then moved using sqlite3PagerMovepage().
39790 ** The solution is to add an in-memory page to the cache containing
39791 ** the data just read from the sub-journal. Mark the page as dirty
39792 ** and if the pager requires a journal-sync, then mark the page as
39793 ** requiring a journal-sync before it is written.
39795 assert( isSavepnt );
39796 assert( pPager->doNotSpill==0 );
39797 pPager->doNotSpill++;
39798 rc = sqlite3PagerAcquire(pPager, pgno, &pPg, 1);
39799 assert( pPager->doNotSpill==1 );
39800 pPager->doNotSpill--;
39801 if( rc!=SQLITE_OK ) return rc;
39802 pPg->flags &= ~PGHDR_NEED_READ;
39803 sqlite3PcacheMakeDirty(pPg);
39805 if( pPg ){
39806 /* No page should ever be explicitly rolled back that is in use, except
39807 ** for page 1 which is held in use in order to keep the lock on the
39808 ** database active. However such a page may be rolled back as a result
39809 ** of an internal error resulting in an automatic call to
39810 ** sqlite3PagerRollback().
39812 void *pData;
39813 pData = pPg->pData;
39814 memcpy(pData, (u8*)aData, pPager->pageSize);
39815 pPager->xReiniter(pPg);
39816 if( isMainJrnl && (!isSavepnt || *pOffset<=pPager->journalHdr) ){
39817 /* If the contents of this page were just restored from the main
39818 ** journal file, then its content must be as they were when the
39819 ** transaction was first opened. In this case we can mark the page
39820 ** as clean, since there will be no need to write it out to the
39821 ** database.
39823 ** There is one exception to this rule. If the page is being rolled
39824 ** back as part of a savepoint (or statement) rollback from an
39825 ** unsynced portion of the main journal file, then it is not safe
39826 ** to mark the page as clean. This is because marking the page as
39827 ** clean will clear the PGHDR_NEED_SYNC flag. Since the page is
39828 ** already in the journal file (recorded in Pager.pInJournal) and
39829 ** the PGHDR_NEED_SYNC flag is cleared, if the page is written to
39830 ** again within this transaction, it will be marked as dirty but
39831 ** the PGHDR_NEED_SYNC flag will not be set. It could then potentially
39832 ** be written out into the database file before its journal file
39833 ** segment is synced. If a crash occurs during or following this,
39834 ** database corruption may ensue.
39836 assert( !pagerUseWal(pPager) );
39837 sqlite3PcacheMakeClean(pPg);
39839 pager_set_pagehash(pPg);
39841 /* If this was page 1, then restore the value of Pager.dbFileVers.
39842 ** Do this before any decoding. */
39843 if( pgno==1 ){
39844 memcpy(&pPager->dbFileVers, &((u8*)pData)[24],sizeof(pPager->dbFileVers));
39847 /* Decode the page just read from disk */
39848 CODEC1(pPager, pData, pPg->pgno, 3, rc=SQLITE_NOMEM);
39849 sqlite3PcacheRelease(pPg);
39851 return rc;
39855 ** Parameter zMaster is the name of a master journal file. A single journal
39856 ** file that referred to the master journal file has just been rolled back.
39857 ** This routine checks if it is possible to delete the master journal file,
39858 ** and does so if it is.
39860 ** Argument zMaster may point to Pager.pTmpSpace. So that buffer is not
39861 ** available for use within this function.
39863 ** When a master journal file is created, it is populated with the names
39864 ** of all of its child journals, one after another, formatted as utf-8
39865 ** encoded text. The end of each child journal file is marked with a
39866 ** nul-terminator byte (0x00). i.e. the entire contents of a master journal
39867 ** file for a transaction involving two databases might be:
39869 ** "/home/bill/a.db-journal\x00/home/bill/b.db-journal\x00"
39871 ** A master journal file may only be deleted once all of its child
39872 ** journals have been rolled back.
39874 ** This function reads the contents of the master-journal file into
39875 ** memory and loops through each of the child journal names. For
39876 ** each child journal, it checks if:
39878 ** * if the child journal exists, and if so
39879 ** * if the child journal contains a reference to master journal
39880 ** file zMaster
39882 ** If a child journal can be found that matches both of the criteria
39883 ** above, this function returns without doing anything. Otherwise, if
39884 ** no such child journal can be found, file zMaster is deleted from
39885 ** the file-system using sqlite3OsDelete().
39887 ** If an IO error within this function, an error code is returned. This
39888 ** function allocates memory by calling sqlite3Malloc(). If an allocation
39889 ** fails, SQLITE_NOMEM is returned. Otherwise, if no IO or malloc errors
39890 ** occur, SQLITE_OK is returned.
39892 ** TODO: This function allocates a single block of memory to load
39893 ** the entire contents of the master journal file. This could be
39894 ** a couple of kilobytes or so - potentially larger than the page
39895 ** size.
39897 static int pager_delmaster(Pager *pPager, const char *zMaster){
39898 sqlite3_vfs *pVfs = pPager->pVfs;
39899 int rc; /* Return code */
39900 sqlite3_file *pMaster; /* Malloc'd master-journal file descriptor */
39901 sqlite3_file *pJournal; /* Malloc'd child-journal file descriptor */
39902 char *zMasterJournal = 0; /* Contents of master journal file */
39903 i64 nMasterJournal; /* Size of master journal file */
39904 char *zJournal; /* Pointer to one journal within MJ file */
39905 char *zMasterPtr; /* Space to hold MJ filename from a journal file */
39906 int nMasterPtr; /* Amount of space allocated to zMasterPtr[] */
39908 /* Allocate space for both the pJournal and pMaster file descriptors.
39909 ** If successful, open the master journal file for reading.
39911 pMaster = (sqlite3_file *)sqlite3MallocZero(pVfs->szOsFile * 2);
39912 pJournal = (sqlite3_file *)(((u8 *)pMaster) + pVfs->szOsFile);
39913 if( !pMaster ){
39914 rc = SQLITE_NOMEM;
39915 }else{
39916 const int flags = (SQLITE_OPEN_READONLY|SQLITE_OPEN_MASTER_JOURNAL);
39917 rc = sqlite3OsOpen(pVfs, zMaster, pMaster, flags, 0);
39919 if( rc!=SQLITE_OK ) goto delmaster_out;
39921 /* Load the entire master journal file into space obtained from
39922 ** sqlite3_malloc() and pointed to by zMasterJournal. Also obtain
39923 ** sufficient space (in zMasterPtr) to hold the names of master
39924 ** journal files extracted from regular rollback-journals.
39926 rc = sqlite3OsFileSize(pMaster, &nMasterJournal);
39927 if( rc!=SQLITE_OK ) goto delmaster_out;
39928 nMasterPtr = pVfs->mxPathname+1;
39929 zMasterJournal = sqlite3Malloc((int)nMasterJournal + nMasterPtr + 1);
39930 if( !zMasterJournal ){
39931 rc = SQLITE_NOMEM;
39932 goto delmaster_out;
39934 zMasterPtr = &zMasterJournal[nMasterJournal+1];
39935 rc = sqlite3OsRead(pMaster, zMasterJournal, (int)nMasterJournal, 0);
39936 if( rc!=SQLITE_OK ) goto delmaster_out;
39937 zMasterJournal[nMasterJournal] = 0;
39939 zJournal = zMasterJournal;
39940 while( (zJournal-zMasterJournal)<nMasterJournal ){
39941 int exists;
39942 rc = sqlite3OsAccess(pVfs, zJournal, SQLITE_ACCESS_EXISTS, &exists);
39943 if( rc!=SQLITE_OK ){
39944 goto delmaster_out;
39946 if( exists ){
39947 /* One of the journals pointed to by the master journal exists.
39948 ** Open it and check if it points at the master journal. If
39949 ** so, return without deleting the master journal file.
39951 int c;
39952 int flags = (SQLITE_OPEN_READONLY|SQLITE_OPEN_MAIN_JOURNAL);
39953 rc = sqlite3OsOpen(pVfs, zJournal, pJournal, flags, 0);
39954 if( rc!=SQLITE_OK ){
39955 goto delmaster_out;
39958 rc = readMasterJournal(pJournal, zMasterPtr, nMasterPtr);
39959 sqlite3OsClose(pJournal);
39960 if( rc!=SQLITE_OK ){
39961 goto delmaster_out;
39964 c = zMasterPtr[0]!=0 && strcmp(zMasterPtr, zMaster)==0;
39965 if( c ){
39966 /* We have a match. Do not delete the master journal file. */
39967 goto delmaster_out;
39970 zJournal += (sqlite3Strlen30(zJournal)+1);
39973 sqlite3OsClose(pMaster);
39974 rc = sqlite3OsDelete(pVfs, zMaster, 0);
39976 delmaster_out:
39977 sqlite3_free(zMasterJournal);
39978 if( pMaster ){
39979 sqlite3OsClose(pMaster);
39980 assert( !isOpen(pJournal) );
39981 sqlite3_free(pMaster);
39983 return rc;
39988 ** This function is used to change the actual size of the database
39989 ** file in the file-system. This only happens when committing a transaction,
39990 ** or rolling back a transaction (including rolling back a hot-journal).
39992 ** If the main database file is not open, or the pager is not in either
39993 ** DBMOD or OPEN state, this function is a no-op. Otherwise, the size
39994 ** of the file is changed to nPage pages (nPage*pPager->pageSize bytes).
39995 ** If the file on disk is currently larger than nPage pages, then use the VFS
39996 ** xTruncate() method to truncate it.
39998 ** Or, it might might be the case that the file on disk is smaller than
39999 ** nPage pages. Some operating system implementations can get confused if
40000 ** you try to truncate a file to some size that is larger than it
40001 ** currently is, so detect this case and write a single zero byte to
40002 ** the end of the new file instead.
40004 ** If successful, return SQLITE_OK. If an IO error occurs while modifying
40005 ** the database file, return the error code to the caller.
40007 static int pager_truncate(Pager *pPager, Pgno nPage){
40008 int rc = SQLITE_OK;
40009 assert( pPager->eState!=PAGER_ERROR );
40010 assert( pPager->eState!=PAGER_READER );
40012 if( isOpen(pPager->fd)
40013 && (pPager->eState>=PAGER_WRITER_DBMOD || pPager->eState==PAGER_OPEN)
40015 i64 currentSize, newSize;
40016 int szPage = pPager->pageSize;
40017 assert( pPager->eLock==EXCLUSIVE_LOCK );
40018 /* TODO: Is it safe to use Pager.dbFileSize here? */
40019 rc = sqlite3OsFileSize(pPager->fd, &currentSize);
40020 newSize = szPage*(i64)nPage;
40021 if( rc==SQLITE_OK && currentSize!=newSize ){
40022 if( currentSize>newSize ){
40023 rc = sqlite3OsTruncate(pPager->fd, newSize);
40024 }else{
40025 char *pTmp = pPager->pTmpSpace;
40026 memset(pTmp, 0, szPage);
40027 testcase( (newSize-szPage) < currentSize );
40028 testcase( (newSize-szPage) == currentSize );
40029 testcase( (newSize-szPage) > currentSize );
40030 rc = sqlite3OsWrite(pPager->fd, pTmp, szPage, newSize-szPage);
40032 if( rc==SQLITE_OK ){
40033 pPager->dbFileSize = nPage;
40037 return rc;
40041 ** Set the value of the Pager.sectorSize variable for the given
40042 ** pager based on the value returned by the xSectorSize method
40043 ** of the open database file. The sector size will be used used
40044 ** to determine the size and alignment of journal header and
40045 ** master journal pointers within created journal files.
40047 ** For temporary files the effective sector size is always 512 bytes.
40049 ** Otherwise, for non-temporary files, the effective sector size is
40050 ** the value returned by the xSectorSize() method rounded up to 32 if
40051 ** it is less than 32, or rounded down to MAX_SECTOR_SIZE if it
40052 ** is greater than MAX_SECTOR_SIZE.
40054 static void setSectorSize(Pager *pPager){
40055 assert( isOpen(pPager->fd) || pPager->tempFile );
40057 if( !pPager->tempFile ){
40058 /* Sector size doesn't matter for temporary files. Also, the file
40059 ** may not have been opened yet, in which case the OsSectorSize()
40060 ** call will segfault.
40062 pPager->sectorSize = sqlite3OsSectorSize(pPager->fd);
40064 if( pPager->sectorSize<32 ){
40065 pPager->sectorSize = 512;
40067 if( pPager->sectorSize>MAX_SECTOR_SIZE ){
40068 assert( MAX_SECTOR_SIZE>=512 );
40069 pPager->sectorSize = MAX_SECTOR_SIZE;
40074 ** Playback the journal and thus restore the database file to
40075 ** the state it was in before we started making changes.
40077 ** The journal file format is as follows:
40079 ** (1) 8 byte prefix. A copy of aJournalMagic[].
40080 ** (2) 4 byte big-endian integer which is the number of valid page records
40081 ** in the journal. If this value is 0xffffffff, then compute the
40082 ** number of page records from the journal size.
40083 ** (3) 4 byte big-endian integer which is the initial value for the
40084 ** sanity checksum.
40085 ** (4) 4 byte integer which is the number of pages to truncate the
40086 ** database to during a rollback.
40087 ** (5) 4 byte big-endian integer which is the sector size. The header
40088 ** is this many bytes in size.
40089 ** (6) 4 byte big-endian integer which is the page size.
40090 ** (7) zero padding out to the next sector size.
40091 ** (8) Zero or more pages instances, each as follows:
40092 ** + 4 byte page number.
40093 ** + pPager->pageSize bytes of data.
40094 ** + 4 byte checksum
40096 ** When we speak of the journal header, we mean the first 7 items above.
40097 ** Each entry in the journal is an instance of the 8th item.
40099 ** Call the value from the second bullet "nRec". nRec is the number of
40100 ** valid page entries in the journal. In most cases, you can compute the
40101 ** value of nRec from the size of the journal file. But if a power
40102 ** failure occurred while the journal was being written, it could be the
40103 ** case that the size of the journal file had already been increased but
40104 ** the extra entries had not yet made it safely to disk. In such a case,
40105 ** the value of nRec computed from the file size would be too large. For
40106 ** that reason, we always use the nRec value in the header.
40108 ** If the nRec value is 0xffffffff it means that nRec should be computed
40109 ** from the file size. This value is used when the user selects the
40110 ** no-sync option for the journal. A power failure could lead to corruption
40111 ** in this case. But for things like temporary table (which will be
40112 ** deleted when the power is restored) we don't care.
40114 ** If the file opened as the journal file is not a well-formed
40115 ** journal file then all pages up to the first corrupted page are rolled
40116 ** back (or no pages if the journal header is corrupted). The journal file
40117 ** is then deleted and SQLITE_OK returned, just as if no corruption had
40118 ** been encountered.
40120 ** If an I/O or malloc() error occurs, the journal-file is not deleted
40121 ** and an error code is returned.
40123 ** The isHot parameter indicates that we are trying to rollback a journal
40124 ** that might be a hot journal. Or, it could be that the journal is
40125 ** preserved because of JOURNALMODE_PERSIST or JOURNALMODE_TRUNCATE.
40126 ** If the journal really is hot, reset the pager cache prior rolling
40127 ** back any content. If the journal is merely persistent, no reset is
40128 ** needed.
40130 static int pager_playback(Pager *pPager, int isHot){
40131 sqlite3_vfs *pVfs = pPager->pVfs;
40132 i64 szJ; /* Size of the journal file in bytes */
40133 u32 nRec; /* Number of Records in the journal */
40134 u32 u; /* Unsigned loop counter */
40135 Pgno mxPg = 0; /* Size of the original file in pages */
40136 int rc; /* Result code of a subroutine */
40137 int res = 1; /* Value returned by sqlite3OsAccess() */
40138 char *zMaster = 0; /* Name of master journal file if any */
40139 int needPagerReset; /* True to reset page prior to first page rollback */
40141 /* Figure out how many records are in the journal. Abort early if
40142 ** the journal is empty.
40144 assert( isOpen(pPager->jfd) );
40145 rc = sqlite3OsFileSize(pPager->jfd, &szJ);
40146 if( rc!=SQLITE_OK ){
40147 goto end_playback;
40150 /* Read the master journal name from the journal, if it is present.
40151 ** If a master journal file name is specified, but the file is not
40152 ** present on disk, then the journal is not hot and does not need to be
40153 ** played back.
40155 ** TODO: Technically the following is an error because it assumes that
40156 ** buffer Pager.pTmpSpace is (mxPathname+1) bytes or larger. i.e. that
40157 ** (pPager->pageSize >= pPager->pVfs->mxPathname+1). Using os_unix.c,
40158 ** mxPathname is 512, which is the same as the minimum allowable value
40159 ** for pageSize.
40161 zMaster = pPager->pTmpSpace;
40162 rc = readMasterJournal(pPager->jfd, zMaster, pPager->pVfs->mxPathname+1);
40163 if( rc==SQLITE_OK && zMaster[0] ){
40164 rc = sqlite3OsAccess(pVfs, zMaster, SQLITE_ACCESS_EXISTS, &res);
40166 zMaster = 0;
40167 if( rc!=SQLITE_OK || !res ){
40168 goto end_playback;
40170 pPager->journalOff = 0;
40171 needPagerReset = isHot;
40173 /* This loop terminates either when a readJournalHdr() or
40174 ** pager_playback_one_page() call returns SQLITE_DONE or an IO error
40175 ** occurs.
40177 while( 1 ){
40178 /* Read the next journal header from the journal file. If there are
40179 ** not enough bytes left in the journal file for a complete header, or
40180 ** it is corrupted, then a process must have failed while writing it.
40181 ** This indicates nothing more needs to be rolled back.
40183 rc = readJournalHdr(pPager, isHot, szJ, &nRec, &mxPg);
40184 if( rc!=SQLITE_OK ){
40185 if( rc==SQLITE_DONE ){
40186 rc = SQLITE_OK;
40188 goto end_playback;
40191 /* If nRec is 0xffffffff, then this journal was created by a process
40192 ** working in no-sync mode. This means that the rest of the journal
40193 ** file consists of pages, there are no more journal headers. Compute
40194 ** the value of nRec based on this assumption.
40196 if( nRec==0xffffffff ){
40197 assert( pPager->journalOff==JOURNAL_HDR_SZ(pPager) );
40198 nRec = (int)((szJ - JOURNAL_HDR_SZ(pPager))/JOURNAL_PG_SZ(pPager));
40201 /* If nRec is 0 and this rollback is of a transaction created by this
40202 ** process and if this is the final header in the journal, then it means
40203 ** that this part of the journal was being filled but has not yet been
40204 ** synced to disk. Compute the number of pages based on the remaining
40205 ** size of the file.
40207 ** The third term of the test was added to fix ticket #2565.
40208 ** When rolling back a hot journal, nRec==0 always means that the next
40209 ** chunk of the journal contains zero pages to be rolled back. But
40210 ** when doing a ROLLBACK and the nRec==0 chunk is the last chunk in
40211 ** the journal, it means that the journal might contain additional
40212 ** pages that need to be rolled back and that the number of pages
40213 ** should be computed based on the journal file size.
40215 if( nRec==0 && !isHot &&
40216 pPager->journalHdr+JOURNAL_HDR_SZ(pPager)==pPager->journalOff ){
40217 nRec = (int)((szJ - pPager->journalOff) / JOURNAL_PG_SZ(pPager));
40220 /* If this is the first header read from the journal, truncate the
40221 ** database file back to its original size.
40223 if( pPager->journalOff==JOURNAL_HDR_SZ(pPager) ){
40224 rc = pager_truncate(pPager, mxPg);
40225 if( rc!=SQLITE_OK ){
40226 goto end_playback;
40228 pPager->dbSize = mxPg;
40231 /* Copy original pages out of the journal and back into the
40232 ** database file and/or page cache.
40234 for(u=0; u<nRec; u++){
40235 if( needPagerReset ){
40236 pager_reset(pPager);
40237 needPagerReset = 0;
40239 rc = pager_playback_one_page(pPager,&pPager->journalOff,0,1,0);
40240 if( rc!=SQLITE_OK ){
40241 if( rc==SQLITE_DONE ){
40242 rc = SQLITE_OK;
40243 pPager->journalOff = szJ;
40244 break;
40245 }else if( rc==SQLITE_IOERR_SHORT_READ ){
40246 /* If the journal has been truncated, simply stop reading and
40247 ** processing the journal. This might happen if the journal was
40248 ** not completely written and synced prior to a crash. In that
40249 ** case, the database should have never been written in the
40250 ** first place so it is OK to simply abandon the rollback. */
40251 rc = SQLITE_OK;
40252 goto end_playback;
40253 }else{
40254 /* If we are unable to rollback, quit and return the error
40255 ** code. This will cause the pager to enter the error state
40256 ** so that no further harm will be done. Perhaps the next
40257 ** process to come along will be able to rollback the database.
40259 goto end_playback;
40264 /*NOTREACHED*/
40265 assert( 0 );
40267 end_playback:
40268 /* Following a rollback, the database file should be back in its original
40269 ** state prior to the start of the transaction, so invoke the
40270 ** SQLITE_FCNTL_DB_UNCHANGED file-control method to disable the
40271 ** assertion that the transaction counter was modified.
40273 assert(
40274 pPager->fd->pMethods==0 ||
40275 sqlite3OsFileControl(pPager->fd,SQLITE_FCNTL_DB_UNCHANGED,0)>=SQLITE_OK
40278 /* If this playback is happening automatically as a result of an IO or
40279 ** malloc error that occurred after the change-counter was updated but
40280 ** before the transaction was committed, then the change-counter
40281 ** modification may just have been reverted. If this happens in exclusive
40282 ** mode, then subsequent transactions performed by the connection will not
40283 ** update the change-counter at all. This may lead to cache inconsistency
40284 ** problems for other processes at some point in the future. So, just
40285 ** in case this has happened, clear the changeCountDone flag now.
40287 pPager->changeCountDone = pPager->tempFile;
40289 if( rc==SQLITE_OK ){
40290 zMaster = pPager->pTmpSpace;
40291 rc = readMasterJournal(pPager->jfd, zMaster, pPager->pVfs->mxPathname+1);
40292 testcase( rc!=SQLITE_OK );
40294 if( rc==SQLITE_OK
40295 && (pPager->eState>=PAGER_WRITER_DBMOD || pPager->eState==PAGER_OPEN)
40297 rc = sqlite3PagerSync(pPager);
40299 if( rc==SQLITE_OK ){
40300 rc = pager_end_transaction(pPager, zMaster[0]!='\0');
40301 testcase( rc!=SQLITE_OK );
40303 if( rc==SQLITE_OK && zMaster[0] && res ){
40304 /* If there was a master journal and this routine will return success,
40305 ** see if it is possible to delete the master journal.
40307 rc = pager_delmaster(pPager, zMaster);
40308 testcase( rc!=SQLITE_OK );
40311 /* The Pager.sectorSize variable may have been updated while rolling
40312 ** back a journal created by a process with a different sector size
40313 ** value. Reset it to the correct value for this process.
40315 setSectorSize(pPager);
40316 return rc;
40321 ** Read the content for page pPg out of the database file and into
40322 ** pPg->pData. A shared lock or greater must be held on the database
40323 ** file before this function is called.
40325 ** If page 1 is read, then the value of Pager.dbFileVers[] is set to
40326 ** the value read from the database file.
40328 ** If an IO error occurs, then the IO error is returned to the caller.
40329 ** Otherwise, SQLITE_OK is returned.
40331 static int readDbPage(PgHdr *pPg){
40332 Pager *pPager = pPg->pPager; /* Pager object associated with page pPg */
40333 Pgno pgno = pPg->pgno; /* Page number to read */
40334 int rc = SQLITE_OK; /* Return code */
40335 int isInWal = 0; /* True if page is in log file */
40336 int pgsz = pPager->pageSize; /* Number of bytes to read */
40338 assert( pPager->eState>=PAGER_READER && !MEMDB );
40339 assert( isOpen(pPager->fd) );
40341 if( NEVER(!isOpen(pPager->fd)) ){
40342 assert( pPager->tempFile );
40343 memset(pPg->pData, 0, pPager->pageSize);
40344 return SQLITE_OK;
40347 if( pagerUseWal(pPager) ){
40348 /* Try to pull the page from the write-ahead log. */
40349 rc = sqlite3WalRead(pPager->pWal, pgno, &isInWal, pgsz, pPg->pData);
40351 if( rc==SQLITE_OK && !isInWal ){
40352 i64 iOffset = (pgno-1)*(i64)pPager->pageSize;
40353 rc = sqlite3OsRead(pPager->fd, pPg->pData, pgsz, iOffset);
40354 if( rc==SQLITE_IOERR_SHORT_READ ){
40355 rc = SQLITE_OK;
40359 if( pgno==1 ){
40360 if( rc ){
40361 /* If the read is unsuccessful, set the dbFileVers[] to something
40362 ** that will never be a valid file version. dbFileVers[] is a copy
40363 ** of bytes 24..39 of the database. Bytes 28..31 should always be
40364 ** zero or the size of the database in page. Bytes 32..35 and 35..39
40365 ** should be page numbers which are never 0xffffffff. So filling
40366 ** pPager->dbFileVers[] with all 0xff bytes should suffice.
40368 ** For an encrypted database, the situation is more complex: bytes
40369 ** 24..39 of the database are white noise. But the probability of
40370 ** white noising equaling 16 bytes of 0xff is vanishingly small so
40371 ** we should still be ok.
40373 memset(pPager->dbFileVers, 0xff, sizeof(pPager->dbFileVers));
40374 }else{
40375 u8 *dbFileVers = &((u8*)pPg->pData)[24];
40376 memcpy(&pPager->dbFileVers, dbFileVers, sizeof(pPager->dbFileVers));
40379 CODEC1(pPager, pPg->pData, pgno, 3, rc = SQLITE_NOMEM);
40381 PAGER_INCR(sqlite3_pager_readdb_count);
40382 PAGER_INCR(pPager->nRead);
40383 IOTRACE(("PGIN %p %d\n", pPager, pgno));
40384 PAGERTRACE(("FETCH %d page %d hash(%08x)\n",
40385 PAGERID(pPager), pgno, pager_pagehash(pPg)));
40387 return rc;
40391 ** Update the value of the change-counter at offsets 24 and 92 in
40392 ** the header and the sqlite version number at offset 96.
40394 ** This is an unconditional update. See also the pager_incr_changecounter()
40395 ** routine which only updates the change-counter if the update is actually
40396 ** needed, as determined by the pPager->changeCountDone state variable.
40398 static void pager_write_changecounter(PgHdr *pPg){
40399 u32 change_counter;
40401 /* Increment the value just read and write it back to byte 24. */
40402 change_counter = sqlite3Get4byte((u8*)pPg->pPager->dbFileVers)+1;
40403 put32bits(((char*)pPg->pData)+24, change_counter);
40405 /* Also store the SQLite version number in bytes 96..99 and in
40406 ** bytes 92..95 store the change counter for which the version number
40407 ** is valid. */
40408 put32bits(((char*)pPg->pData)+92, change_counter);
40409 put32bits(((char*)pPg->pData)+96, SQLITE_VERSION_NUMBER);
40412 #ifndef SQLITE_OMIT_WAL
40414 ** This function is invoked once for each page that has already been
40415 ** written into the log file when a WAL transaction is rolled back.
40416 ** Parameter iPg is the page number of said page. The pCtx argument
40417 ** is actually a pointer to the Pager structure.
40419 ** If page iPg is present in the cache, and has no outstanding references,
40420 ** it is discarded. Otherwise, if there are one or more outstanding
40421 ** references, the page content is reloaded from the database. If the
40422 ** attempt to reload content from the database is required and fails,
40423 ** return an SQLite error code. Otherwise, SQLITE_OK.
40425 static int pagerUndoCallback(void *pCtx, Pgno iPg){
40426 int rc = SQLITE_OK;
40427 Pager *pPager = (Pager *)pCtx;
40428 PgHdr *pPg;
40430 pPg = sqlite3PagerLookup(pPager, iPg);
40431 if( pPg ){
40432 if( sqlite3PcachePageRefcount(pPg)==1 ){
40433 sqlite3PcacheDrop(pPg);
40434 }else{
40435 rc = readDbPage(pPg);
40436 if( rc==SQLITE_OK ){
40437 pPager->xReiniter(pPg);
40439 sqlite3PagerUnref(pPg);
40443 /* Normally, if a transaction is rolled back, any backup processes are
40444 ** updated as data is copied out of the rollback journal and into the
40445 ** database. This is not generally possible with a WAL database, as
40446 ** rollback involves simply truncating the log file. Therefore, if one
40447 ** or more frames have already been written to the log (and therefore
40448 ** also copied into the backup databases) as part of this transaction,
40449 ** the backups must be restarted.
40451 sqlite3BackupRestart(pPager->pBackup);
40453 return rc;
40457 ** This function is called to rollback a transaction on a WAL database.
40459 static int pagerRollbackWal(Pager *pPager){
40460 int rc; /* Return Code */
40461 PgHdr *pList; /* List of dirty pages to revert */
40463 /* For all pages in the cache that are currently dirty or have already
40464 ** been written (but not committed) to the log file, do one of the
40465 ** following:
40467 ** + Discard the cached page (if refcount==0), or
40468 ** + Reload page content from the database (if refcount>0).
40470 pPager->dbSize = pPager->dbOrigSize;
40471 rc = sqlite3WalUndo(pPager->pWal, pagerUndoCallback, (void *)pPager);
40472 pList = sqlite3PcacheDirtyList(pPager->pPCache);
40473 while( pList && rc==SQLITE_OK ){
40474 PgHdr *pNext = pList->pDirty;
40475 rc = pagerUndoCallback((void *)pPager, pList->pgno);
40476 pList = pNext;
40479 return rc;
40483 ** This function is a wrapper around sqlite3WalFrames(). As well as logging
40484 ** the contents of the list of pages headed by pList (connected by pDirty),
40485 ** this function notifies any active backup processes that the pages have
40486 ** changed.
40488 ** The list of pages passed into this routine is always sorted by page number.
40489 ** Hence, if page 1 appears anywhere on the list, it will be the first page.
40491 static int pagerWalFrames(
40492 Pager *pPager, /* Pager object */
40493 PgHdr *pList, /* List of frames to log */
40494 Pgno nTruncate, /* Database size after this commit */
40495 int isCommit, /* True if this is a commit */
40496 int syncFlags /* Flags to pass to OsSync() (or 0) */
40498 int rc; /* Return code */
40499 #if defined(SQLITE_DEBUG) || defined(SQLITE_CHECK_PAGES)
40500 PgHdr *p; /* For looping over pages */
40501 #endif
40503 assert( pPager->pWal );
40504 #ifdef SQLITE_DEBUG
40505 /* Verify that the page list is in accending order */
40506 for(p=pList; p && p->pDirty; p=p->pDirty){
40507 assert( p->pgno < p->pDirty->pgno );
40509 #endif
40511 if( isCommit ){
40512 /* If a WAL transaction is being committed, there is no point in writing
40513 ** any pages with page numbers greater than nTruncate into the WAL file.
40514 ** They will never be read by any client. So remove them from the pDirty
40515 ** list here. */
40516 PgHdr *p;
40517 PgHdr **ppNext = &pList;
40518 for(p=pList; (*ppNext = p); p=p->pDirty){
40519 if( p->pgno<=nTruncate ) ppNext = &p->pDirty;
40521 assert( pList );
40524 if( pList->pgno==1 ) pager_write_changecounter(pList);
40525 rc = sqlite3WalFrames(pPager->pWal,
40526 pPager->pageSize, pList, nTruncate, isCommit, syncFlags
40528 if( rc==SQLITE_OK && pPager->pBackup ){
40529 PgHdr *p;
40530 for(p=pList; p; p=p->pDirty){
40531 sqlite3BackupUpdate(pPager->pBackup, p->pgno, (u8 *)p->pData);
40535 #ifdef SQLITE_CHECK_PAGES
40536 pList = sqlite3PcacheDirtyList(pPager->pPCache);
40537 for(p=pList; p; p=p->pDirty){
40538 pager_set_pagehash(p);
40540 #endif
40542 return rc;
40546 ** Begin a read transaction on the WAL.
40548 ** This routine used to be called "pagerOpenSnapshot()" because it essentially
40549 ** makes a snapshot of the database at the current point in time and preserves
40550 ** that snapshot for use by the reader in spite of concurrently changes by
40551 ** other writers or checkpointers.
40553 static int pagerBeginReadTransaction(Pager *pPager){
40554 int rc; /* Return code */
40555 int changed = 0; /* True if cache must be reset */
40557 assert( pagerUseWal(pPager) );
40558 assert( pPager->eState==PAGER_OPEN || pPager->eState==PAGER_READER );
40560 /* sqlite3WalEndReadTransaction() was not called for the previous
40561 ** transaction in locking_mode=EXCLUSIVE. So call it now. If we
40562 ** are in locking_mode=NORMAL and EndRead() was previously called,
40563 ** the duplicate call is harmless.
40565 sqlite3WalEndReadTransaction(pPager->pWal);
40567 rc = sqlite3WalBeginReadTransaction(pPager->pWal, &changed);
40568 if( rc!=SQLITE_OK || changed ){
40569 pager_reset(pPager);
40572 return rc;
40574 #endif
40577 ** This function is called as part of the transition from PAGER_OPEN
40578 ** to PAGER_READER state to determine the size of the database file
40579 ** in pages (assuming the page size currently stored in Pager.pageSize).
40581 ** If no error occurs, SQLITE_OK is returned and the size of the database
40582 ** in pages is stored in *pnPage. Otherwise, an error code (perhaps
40583 ** SQLITE_IOERR_FSTAT) is returned and *pnPage is left unmodified.
40585 static int pagerPagecount(Pager *pPager, Pgno *pnPage){
40586 Pgno nPage; /* Value to return via *pnPage */
40588 /* Query the WAL sub-system for the database size. The WalDbsize()
40589 ** function returns zero if the WAL is not open (i.e. Pager.pWal==0), or
40590 ** if the database size is not available. The database size is not
40591 ** available from the WAL sub-system if the log file is empty or
40592 ** contains no valid committed transactions.
40594 assert( pPager->eState==PAGER_OPEN );
40595 assert( pPager->eLock>=SHARED_LOCK || pPager->noReadlock );
40596 nPage = sqlite3WalDbsize(pPager->pWal);
40598 /* If the database size was not available from the WAL sub-system,
40599 ** determine it based on the size of the database file. If the size
40600 ** of the database file is not an integer multiple of the page-size,
40601 ** round down to the nearest page. Except, any file larger than 0
40602 ** bytes in size is considered to contain at least one page.
40604 if( nPage==0 ){
40605 i64 n = 0; /* Size of db file in bytes */
40606 assert( isOpen(pPager->fd) || pPager->tempFile );
40607 if( isOpen(pPager->fd) ){
40608 int rc = sqlite3OsFileSize(pPager->fd, &n);
40609 if( rc!=SQLITE_OK ){
40610 return rc;
40613 nPage = (Pgno)(n / pPager->pageSize);
40614 if( nPage==0 && n>0 ){
40615 nPage = 1;
40619 /* If the current number of pages in the file is greater than the
40620 ** configured maximum pager number, increase the allowed limit so
40621 ** that the file can be read.
40623 if( nPage>pPager->mxPgno ){
40624 pPager->mxPgno = (Pgno)nPage;
40627 *pnPage = nPage;
40628 return SQLITE_OK;
40631 #ifndef SQLITE_OMIT_WAL
40633 ** Check if the *-wal file that corresponds to the database opened by pPager
40634 ** exists if the database is not empy, or verify that the *-wal file does
40635 ** not exist (by deleting it) if the database file is empty.
40637 ** If the database is not empty and the *-wal file exists, open the pager
40638 ** in WAL mode. If the database is empty or if no *-wal file exists and
40639 ** if no error occurs, make sure Pager.journalMode is not set to
40640 ** PAGER_JOURNALMODE_WAL.
40642 ** Return SQLITE_OK or an error code.
40644 ** The caller must hold a SHARED lock on the database file to call this
40645 ** function. Because an EXCLUSIVE lock on the db file is required to delete
40646 ** a WAL on a none-empty database, this ensures there is no race condition
40647 ** between the xAccess() below and an xDelete() being executed by some
40648 ** other connection.
40650 static int pagerOpenWalIfPresent(Pager *pPager){
40651 int rc = SQLITE_OK;
40652 assert( pPager->eState==PAGER_OPEN );
40653 assert( pPager->eLock>=SHARED_LOCK || pPager->noReadlock );
40655 if( !pPager->tempFile ){
40656 int isWal; /* True if WAL file exists */
40657 Pgno nPage; /* Size of the database file */
40659 rc = pagerPagecount(pPager, &nPage);
40660 if( rc ) return rc;
40661 if( nPage==0 ){
40662 rc = sqlite3OsDelete(pPager->pVfs, pPager->zWal, 0);
40663 isWal = 0;
40664 }else{
40665 rc = sqlite3OsAccess(
40666 pPager->pVfs, pPager->zWal, SQLITE_ACCESS_EXISTS, &isWal
40669 if( rc==SQLITE_OK ){
40670 if( isWal ){
40671 testcase( sqlite3PcachePagecount(pPager->pPCache)==0 );
40672 rc = sqlite3PagerOpenWal(pPager, 0);
40673 }else if( pPager->journalMode==PAGER_JOURNALMODE_WAL ){
40674 pPager->journalMode = PAGER_JOURNALMODE_DELETE;
40678 return rc;
40680 #endif
40683 ** Playback savepoint pSavepoint. Or, if pSavepoint==NULL, then playback
40684 ** the entire master journal file. The case pSavepoint==NULL occurs when
40685 ** a ROLLBACK TO command is invoked on a SAVEPOINT that is a transaction
40686 ** savepoint.
40688 ** When pSavepoint is not NULL (meaning a non-transaction savepoint is
40689 ** being rolled back), then the rollback consists of up to three stages,
40690 ** performed in the order specified:
40692 ** * Pages are played back from the main journal starting at byte
40693 ** offset PagerSavepoint.iOffset and continuing to
40694 ** PagerSavepoint.iHdrOffset, or to the end of the main journal
40695 ** file if PagerSavepoint.iHdrOffset is zero.
40697 ** * If PagerSavepoint.iHdrOffset is not zero, then pages are played
40698 ** back starting from the journal header immediately following
40699 ** PagerSavepoint.iHdrOffset to the end of the main journal file.
40701 ** * Pages are then played back from the sub-journal file, starting
40702 ** with the PagerSavepoint.iSubRec and continuing to the end of
40703 ** the journal file.
40705 ** Throughout the rollback process, each time a page is rolled back, the
40706 ** corresponding bit is set in a bitvec structure (variable pDone in the
40707 ** implementation below). This is used to ensure that a page is only
40708 ** rolled back the first time it is encountered in either journal.
40710 ** If pSavepoint is NULL, then pages are only played back from the main
40711 ** journal file. There is no need for a bitvec in this case.
40713 ** In either case, before playback commences the Pager.dbSize variable
40714 ** is reset to the value that it held at the start of the savepoint
40715 ** (or transaction). No page with a page-number greater than this value
40716 ** is played back. If one is encountered it is simply skipped.
40718 static int pagerPlaybackSavepoint(Pager *pPager, PagerSavepoint *pSavepoint){
40719 i64 szJ; /* Effective size of the main journal */
40720 i64 iHdrOff; /* End of first segment of main-journal records */
40721 int rc = SQLITE_OK; /* Return code */
40722 Bitvec *pDone = 0; /* Bitvec to ensure pages played back only once */
40724 assert( pPager->eState!=PAGER_ERROR );
40725 assert( pPager->eState>=PAGER_WRITER_LOCKED );
40727 /* Allocate a bitvec to use to store the set of pages rolled back */
40728 if( pSavepoint ){
40729 pDone = sqlite3BitvecCreate(pSavepoint->nOrig);
40730 if( !pDone ){
40731 return SQLITE_NOMEM;
40735 /* Set the database size back to the value it was before the savepoint
40736 ** being reverted was opened.
40738 pPager->dbSize = pSavepoint ? pSavepoint->nOrig : pPager->dbOrigSize;
40739 pPager->changeCountDone = pPager->tempFile;
40741 if( !pSavepoint && pagerUseWal(pPager) ){
40742 return pagerRollbackWal(pPager);
40745 /* Use pPager->journalOff as the effective size of the main rollback
40746 ** journal. The actual file might be larger than this in
40747 ** PAGER_JOURNALMODE_TRUNCATE or PAGER_JOURNALMODE_PERSIST. But anything
40748 ** past pPager->journalOff is off-limits to us.
40750 szJ = pPager->journalOff;
40751 assert( pagerUseWal(pPager)==0 || szJ==0 );
40753 /* Begin by rolling back records from the main journal starting at
40754 ** PagerSavepoint.iOffset and continuing to the next journal header.
40755 ** There might be records in the main journal that have a page number
40756 ** greater than the current database size (pPager->dbSize) but those
40757 ** will be skipped automatically. Pages are added to pDone as they
40758 ** are played back.
40760 if( pSavepoint && !pagerUseWal(pPager) ){
40761 iHdrOff = pSavepoint->iHdrOffset ? pSavepoint->iHdrOffset : szJ;
40762 pPager->journalOff = pSavepoint->iOffset;
40763 while( rc==SQLITE_OK && pPager->journalOff<iHdrOff ){
40764 rc = pager_playback_one_page(pPager, &pPager->journalOff, pDone, 1, 1);
40766 assert( rc!=SQLITE_DONE );
40767 }else{
40768 pPager->journalOff = 0;
40771 /* Continue rolling back records out of the main journal starting at
40772 ** the first journal header seen and continuing until the effective end
40773 ** of the main journal file. Continue to skip out-of-range pages and
40774 ** continue adding pages rolled back to pDone.
40776 while( rc==SQLITE_OK && pPager->journalOff<szJ ){
40777 u32 ii; /* Loop counter */
40778 u32 nJRec = 0; /* Number of Journal Records */
40779 u32 dummy;
40780 rc = readJournalHdr(pPager, 0, szJ, &nJRec, &dummy);
40781 assert( rc!=SQLITE_DONE );
40784 ** The "pPager->journalHdr+JOURNAL_HDR_SZ(pPager)==pPager->journalOff"
40785 ** test is related to ticket #2565. See the discussion in the
40786 ** pager_playback() function for additional information.
40788 if( nJRec==0
40789 && pPager->journalHdr+JOURNAL_HDR_SZ(pPager)==pPager->journalOff
40791 nJRec = (u32)((szJ - pPager->journalOff)/JOURNAL_PG_SZ(pPager));
40793 for(ii=0; rc==SQLITE_OK && ii<nJRec && pPager->journalOff<szJ; ii++){
40794 rc = pager_playback_one_page(pPager, &pPager->journalOff, pDone, 1, 1);
40796 assert( rc!=SQLITE_DONE );
40798 assert( rc!=SQLITE_OK || pPager->journalOff>=szJ );
40800 /* Finally, rollback pages from the sub-journal. Page that were
40801 ** previously rolled back out of the main journal (and are hence in pDone)
40802 ** will be skipped. Out-of-range pages are also skipped.
40804 if( pSavepoint ){
40805 u32 ii; /* Loop counter */
40806 i64 offset = pSavepoint->iSubRec*(4+pPager->pageSize);
40808 if( pagerUseWal(pPager) ){
40809 rc = sqlite3WalSavepointUndo(pPager->pWal, pSavepoint->aWalData);
40811 for(ii=pSavepoint->iSubRec; rc==SQLITE_OK && ii<pPager->nSubRec; ii++){
40812 assert( offset==ii*(4+pPager->pageSize) );
40813 rc = pager_playback_one_page(pPager, &offset, pDone, 0, 1);
40815 assert( rc!=SQLITE_DONE );
40818 sqlite3BitvecDestroy(pDone);
40819 if( rc==SQLITE_OK ){
40820 pPager->journalOff = szJ;
40823 return rc;
40827 ** Change the maximum number of in-memory pages that are allowed.
40829 SQLITE_PRIVATE void sqlite3PagerSetCachesize(Pager *pPager, int mxPage){
40830 sqlite3PcacheSetCachesize(pPager->pPCache, mxPage);
40834 ** Adjust the robustness of the database to damage due to OS crashes
40835 ** or power failures by changing the number of syncs()s when writing
40836 ** the rollback journal. There are three levels:
40838 ** OFF sqlite3OsSync() is never called. This is the default
40839 ** for temporary and transient files.
40841 ** NORMAL The journal is synced once before writes begin on the
40842 ** database. This is normally adequate protection, but
40843 ** it is theoretically possible, though very unlikely,
40844 ** that an inopertune power failure could leave the journal
40845 ** in a state which would cause damage to the database
40846 ** when it is rolled back.
40848 ** FULL The journal is synced twice before writes begin on the
40849 ** database (with some additional information - the nRec field
40850 ** of the journal header - being written in between the two
40851 ** syncs). If we assume that writing a
40852 ** single disk sector is atomic, then this mode provides
40853 ** assurance that the journal will not be corrupted to the
40854 ** point of causing damage to the database during rollback.
40856 ** The above is for a rollback-journal mode. For WAL mode, OFF continues
40857 ** to mean that no syncs ever occur. NORMAL means that the WAL is synced
40858 ** prior to the start of checkpoint and that the database file is synced
40859 ** at the conclusion of the checkpoint if the entire content of the WAL
40860 ** was written back into the database. But no sync operations occur for
40861 ** an ordinary commit in NORMAL mode with WAL. FULL means that the WAL
40862 ** file is synced following each commit operation, in addition to the
40863 ** syncs associated with NORMAL.
40865 ** Do not confuse synchronous=FULL with SQLITE_SYNC_FULL. The
40866 ** SQLITE_SYNC_FULL macro means to use the MacOSX-style full-fsync
40867 ** using fcntl(F_FULLFSYNC). SQLITE_SYNC_NORMAL means to do an
40868 ** ordinary fsync() call. There is no difference between SQLITE_SYNC_FULL
40869 ** and SQLITE_SYNC_NORMAL on platforms other than MacOSX. But the
40870 ** synchronous=FULL versus synchronous=NORMAL setting determines when
40871 ** the xSync primitive is called and is relevant to all platforms.
40873 ** Numeric values associated with these states are OFF==1, NORMAL=2,
40874 ** and FULL=3.
40876 #ifndef SQLITE_OMIT_PAGER_PRAGMAS
40877 SQLITE_PRIVATE void sqlite3PagerSetSafetyLevel(
40878 Pager *pPager, /* The pager to set safety level for */
40879 int level, /* PRAGMA synchronous. 1=OFF, 2=NORMAL, 3=FULL */
40880 int bFullFsync, /* PRAGMA fullfsync */
40881 int bCkptFullFsync /* PRAGMA checkpoint_fullfsync */
40883 assert( level>=1 && level<=3 );
40884 pPager->noSync = (level==1 || pPager->tempFile) ?1:0;
40885 pPager->fullSync = (level==3 && !pPager->tempFile) ?1:0;
40886 if( pPager->noSync ){
40887 pPager->syncFlags = 0;
40888 pPager->ckptSyncFlags = 0;
40889 }else if( bFullFsync ){
40890 pPager->syncFlags = SQLITE_SYNC_FULL;
40891 pPager->ckptSyncFlags = SQLITE_SYNC_FULL;
40892 }else if( bCkptFullFsync ){
40893 pPager->syncFlags = SQLITE_SYNC_NORMAL;
40894 pPager->ckptSyncFlags = SQLITE_SYNC_FULL;
40895 }else{
40896 pPager->syncFlags = SQLITE_SYNC_NORMAL;
40897 pPager->ckptSyncFlags = SQLITE_SYNC_NORMAL;
40900 #endif
40903 ** The following global variable is incremented whenever the library
40904 ** attempts to open a temporary file. This information is used for
40905 ** testing and analysis only.
40907 #ifdef SQLITE_TEST
40908 SQLITE_API int sqlite3_opentemp_count = 0;
40909 #endif
40912 ** Open a temporary file.
40914 ** Write the file descriptor into *pFile. Return SQLITE_OK on success
40915 ** or some other error code if we fail. The OS will automatically
40916 ** delete the temporary file when it is closed.
40918 ** The flags passed to the VFS layer xOpen() call are those specified
40919 ** by parameter vfsFlags ORed with the following:
40921 ** SQLITE_OPEN_READWRITE
40922 ** SQLITE_OPEN_CREATE
40923 ** SQLITE_OPEN_EXCLUSIVE
40924 ** SQLITE_OPEN_DELETEONCLOSE
40926 static int pagerOpentemp(
40927 Pager *pPager, /* The pager object */
40928 sqlite3_file *pFile, /* Write the file descriptor here */
40929 int vfsFlags /* Flags passed through to the VFS */
40931 int rc; /* Return code */
40933 #ifdef SQLITE_TEST
40934 sqlite3_opentemp_count++; /* Used for testing and analysis only */
40935 #endif
40937 vfsFlags |= SQLITE_OPEN_READWRITE | SQLITE_OPEN_CREATE |
40938 SQLITE_OPEN_EXCLUSIVE | SQLITE_OPEN_DELETEONCLOSE;
40939 rc = sqlite3OsOpen(pPager->pVfs, 0, pFile, vfsFlags, 0);
40940 assert( rc!=SQLITE_OK || isOpen(pFile) );
40941 return rc;
40945 ** Set the busy handler function.
40947 ** The pager invokes the busy-handler if sqlite3OsLock() returns
40948 ** SQLITE_BUSY when trying to upgrade from no-lock to a SHARED lock,
40949 ** or when trying to upgrade from a RESERVED lock to an EXCLUSIVE
40950 ** lock. It does *not* invoke the busy handler when upgrading from
40951 ** SHARED to RESERVED, or when upgrading from SHARED to EXCLUSIVE
40952 ** (which occurs during hot-journal rollback). Summary:
40954 ** Transition | Invokes xBusyHandler
40955 ** --------------------------------------------------------
40956 ** NO_LOCK -> SHARED_LOCK | Yes
40957 ** SHARED_LOCK -> RESERVED_LOCK | No
40958 ** SHARED_LOCK -> EXCLUSIVE_LOCK | No
40959 ** RESERVED_LOCK -> EXCLUSIVE_LOCK | Yes
40961 ** If the busy-handler callback returns non-zero, the lock is
40962 ** retried. If it returns zero, then the SQLITE_BUSY error is
40963 ** returned to the caller of the pager API function.
40965 SQLITE_PRIVATE void sqlite3PagerSetBusyhandler(
40966 Pager *pPager, /* Pager object */
40967 int (*xBusyHandler)(void *), /* Pointer to busy-handler function */
40968 void *pBusyHandlerArg /* Argument to pass to xBusyHandler */
40970 pPager->xBusyHandler = xBusyHandler;
40971 pPager->pBusyHandlerArg = pBusyHandlerArg;
40975 ** Change the page size used by the Pager object. The new page size
40976 ** is passed in *pPageSize.
40978 ** If the pager is in the error state when this function is called, it
40979 ** is a no-op. The value returned is the error state error code (i.e.
40980 ** one of SQLITE_IOERR, an SQLITE_IOERR_xxx sub-code or SQLITE_FULL).
40982 ** Otherwise, if all of the following are true:
40984 ** * the new page size (value of *pPageSize) is valid (a power
40985 ** of two between 512 and SQLITE_MAX_PAGE_SIZE, inclusive), and
40987 ** * there are no outstanding page references, and
40989 ** * the database is either not an in-memory database or it is
40990 ** an in-memory database that currently consists of zero pages.
40992 ** then the pager object page size is set to *pPageSize.
40994 ** If the page size is changed, then this function uses sqlite3PagerMalloc()
40995 ** to obtain a new Pager.pTmpSpace buffer. If this allocation attempt
40996 ** fails, SQLITE_NOMEM is returned and the page size remains unchanged.
40997 ** In all other cases, SQLITE_OK is returned.
40999 ** If the page size is not changed, either because one of the enumerated
41000 ** conditions above is not true, the pager was in error state when this
41001 ** function was called, or because the memory allocation attempt failed,
41002 ** then *pPageSize is set to the old, retained page size before returning.
41004 SQLITE_PRIVATE int sqlite3PagerSetPagesize(Pager *pPager, u32 *pPageSize, int nReserve){
41005 int rc = SQLITE_OK;
41007 /* It is not possible to do a full assert_pager_state() here, as this
41008 ** function may be called from within PagerOpen(), before the state
41009 ** of the Pager object is internally consistent.
41011 ** At one point this function returned an error if the pager was in
41012 ** PAGER_ERROR state. But since PAGER_ERROR state guarantees that
41013 ** there is at least one outstanding page reference, this function
41014 ** is a no-op for that case anyhow.
41017 u32 pageSize = *pPageSize;
41018 assert( pageSize==0 || (pageSize>=512 && pageSize<=SQLITE_MAX_PAGE_SIZE) );
41019 if( (pPager->memDb==0 || pPager->dbSize==0)
41020 && sqlite3PcacheRefCount(pPager->pPCache)==0
41021 && pageSize && pageSize!=(u32)pPager->pageSize
41023 char *pNew = NULL; /* New temp space */
41024 i64 nByte = 0;
41026 if( pPager->eState>PAGER_OPEN && isOpen(pPager->fd) ){
41027 rc = sqlite3OsFileSize(pPager->fd, &nByte);
41029 if( rc==SQLITE_OK ){
41030 pNew = (char *)sqlite3PageMalloc(pageSize);
41031 if( !pNew ) rc = SQLITE_NOMEM;
41034 if( rc==SQLITE_OK ){
41035 pager_reset(pPager);
41036 pPager->dbSize = (Pgno)(nByte/pageSize);
41037 pPager->pageSize = pageSize;
41038 sqlite3PageFree(pPager->pTmpSpace);
41039 pPager->pTmpSpace = pNew;
41040 sqlite3PcacheSetPageSize(pPager->pPCache, pageSize);
41044 *pPageSize = pPager->pageSize;
41045 if( rc==SQLITE_OK ){
41046 if( nReserve<0 ) nReserve = pPager->nReserve;
41047 assert( nReserve>=0 && nReserve<1000 );
41048 pPager->nReserve = (i16)nReserve;
41049 pagerReportSize(pPager);
41051 return rc;
41055 ** Return a pointer to the "temporary page" buffer held internally
41056 ** by the pager. This is a buffer that is big enough to hold the
41057 ** entire content of a database page. This buffer is used internally
41058 ** during rollback and will be overwritten whenever a rollback
41059 ** occurs. But other modules are free to use it too, as long as
41060 ** no rollbacks are happening.
41062 SQLITE_PRIVATE void *sqlite3PagerTempSpace(Pager *pPager){
41063 return pPager->pTmpSpace;
41067 ** Attempt to set the maximum database page count if mxPage is positive.
41068 ** Make no changes if mxPage is zero or negative. And never reduce the
41069 ** maximum page count below the current size of the database.
41071 ** Regardless of mxPage, return the current maximum page count.
41073 SQLITE_PRIVATE int sqlite3PagerMaxPageCount(Pager *pPager, int mxPage){
41074 if( mxPage>0 ){
41075 pPager->mxPgno = mxPage;
41077 assert( pPager->eState!=PAGER_OPEN ); /* Called only by OP_MaxPgcnt */
41078 assert( pPager->mxPgno>=pPager->dbSize ); /* OP_MaxPgcnt enforces this */
41079 return pPager->mxPgno;
41083 ** The following set of routines are used to disable the simulated
41084 ** I/O error mechanism. These routines are used to avoid simulated
41085 ** errors in places where we do not care about errors.
41087 ** Unless -DSQLITE_TEST=1 is used, these routines are all no-ops
41088 ** and generate no code.
41090 #ifdef SQLITE_TEST
41091 SQLITE_API extern int sqlite3_io_error_pending;
41092 SQLITE_API extern int sqlite3_io_error_hit;
41093 static int saved_cnt;
41094 void disable_simulated_io_errors(void){
41095 saved_cnt = sqlite3_io_error_pending;
41096 sqlite3_io_error_pending = -1;
41098 void enable_simulated_io_errors(void){
41099 sqlite3_io_error_pending = saved_cnt;
41101 #else
41102 # define disable_simulated_io_errors()
41103 # define enable_simulated_io_errors()
41104 #endif
41107 ** Read the first N bytes from the beginning of the file into memory
41108 ** that pDest points to.
41110 ** If the pager was opened on a transient file (zFilename==""), or
41111 ** opened on a file less than N bytes in size, the output buffer is
41112 ** zeroed and SQLITE_OK returned. The rationale for this is that this
41113 ** function is used to read database headers, and a new transient or
41114 ** zero sized database has a header than consists entirely of zeroes.
41116 ** If any IO error apart from SQLITE_IOERR_SHORT_READ is encountered,
41117 ** the error code is returned to the caller and the contents of the
41118 ** output buffer undefined.
41120 SQLITE_PRIVATE int sqlite3PagerReadFileheader(Pager *pPager, int N, unsigned char *pDest){
41121 int rc = SQLITE_OK;
41122 memset(pDest, 0, N);
41123 assert( isOpen(pPager->fd) || pPager->tempFile );
41125 /* This routine is only called by btree immediately after creating
41126 ** the Pager object. There has not been an opportunity to transition
41127 ** to WAL mode yet.
41129 assert( !pagerUseWal(pPager) );
41131 if( isOpen(pPager->fd) ){
41132 IOTRACE(("DBHDR %p 0 %d\n", pPager, N))
41133 rc = sqlite3OsRead(pPager->fd, pDest, N, 0);
41134 if( rc==SQLITE_IOERR_SHORT_READ ){
41135 rc = SQLITE_OK;
41138 return rc;
41142 ** This function may only be called when a read-transaction is open on
41143 ** the pager. It returns the total number of pages in the database.
41145 ** However, if the file is between 1 and <page-size> bytes in size, then
41146 ** this is considered a 1 page file.
41148 SQLITE_PRIVATE void sqlite3PagerPagecount(Pager *pPager, int *pnPage){
41149 assert( pPager->eState>=PAGER_READER );
41150 assert( pPager->eState!=PAGER_WRITER_FINISHED );
41151 *pnPage = (int)pPager->dbSize;
41156 ** Try to obtain a lock of type locktype on the database file. If
41157 ** a similar or greater lock is already held, this function is a no-op
41158 ** (returning SQLITE_OK immediately).
41160 ** Otherwise, attempt to obtain the lock using sqlite3OsLock(). Invoke
41161 ** the busy callback if the lock is currently not available. Repeat
41162 ** until the busy callback returns false or until the attempt to
41163 ** obtain the lock succeeds.
41165 ** Return SQLITE_OK on success and an error code if we cannot obtain
41166 ** the lock. If the lock is obtained successfully, set the Pager.state
41167 ** variable to locktype before returning.
41169 static int pager_wait_on_lock(Pager *pPager, int locktype){
41170 int rc; /* Return code */
41172 /* Check that this is either a no-op (because the requested lock is
41173 ** already held, or one of the transistions that the busy-handler
41174 ** may be invoked during, according to the comment above
41175 ** sqlite3PagerSetBusyhandler().
41177 assert( (pPager->eLock>=locktype)
41178 || (pPager->eLock==NO_LOCK && locktype==SHARED_LOCK)
41179 || (pPager->eLock==RESERVED_LOCK && locktype==EXCLUSIVE_LOCK)
41182 do {
41183 rc = pagerLockDb(pPager, locktype);
41184 }while( rc==SQLITE_BUSY && pPager->xBusyHandler(pPager->pBusyHandlerArg) );
41185 return rc;
41189 ** Function assertTruncateConstraint(pPager) checks that one of the
41190 ** following is true for all dirty pages currently in the page-cache:
41192 ** a) The page number is less than or equal to the size of the
41193 ** current database image, in pages, OR
41195 ** b) if the page content were written at this time, it would not
41196 ** be necessary to write the current content out to the sub-journal
41197 ** (as determined by function subjRequiresPage()).
41199 ** If the condition asserted by this function were not true, and the
41200 ** dirty page were to be discarded from the cache via the pagerStress()
41201 ** routine, pagerStress() would not write the current page content to
41202 ** the database file. If a savepoint transaction were rolled back after
41203 ** this happened, the correct behaviour would be to restore the current
41204 ** content of the page. However, since this content is not present in either
41205 ** the database file or the portion of the rollback journal and
41206 ** sub-journal rolled back the content could not be restored and the
41207 ** database image would become corrupt. It is therefore fortunate that
41208 ** this circumstance cannot arise.
41210 #if defined(SQLITE_DEBUG)
41211 static void assertTruncateConstraintCb(PgHdr *pPg){
41212 assert( pPg->flags&PGHDR_DIRTY );
41213 assert( !subjRequiresPage(pPg) || pPg->pgno<=pPg->pPager->dbSize );
41215 static void assertTruncateConstraint(Pager *pPager){
41216 sqlite3PcacheIterateDirty(pPager->pPCache, assertTruncateConstraintCb);
41218 #else
41219 # define assertTruncateConstraint(pPager)
41220 #endif
41223 ** Truncate the in-memory database file image to nPage pages. This
41224 ** function does not actually modify the database file on disk. It
41225 ** just sets the internal state of the pager object so that the
41226 ** truncation will be done when the current transaction is committed.
41228 SQLITE_PRIVATE void sqlite3PagerTruncateImage(Pager *pPager, Pgno nPage){
41229 assert( pPager->dbSize>=nPage );
41230 assert( pPager->eState>=PAGER_WRITER_CACHEMOD );
41231 pPager->dbSize = nPage;
41232 assertTruncateConstraint(pPager);
41237 ** This function is called before attempting a hot-journal rollback. It
41238 ** syncs the journal file to disk, then sets pPager->journalHdr to the
41239 ** size of the journal file so that the pager_playback() routine knows
41240 ** that the entire journal file has been synced.
41242 ** Syncing a hot-journal to disk before attempting to roll it back ensures
41243 ** that if a power-failure occurs during the rollback, the process that
41244 ** attempts rollback following system recovery sees the same journal
41245 ** content as this process.
41247 ** If everything goes as planned, SQLITE_OK is returned. Otherwise,
41248 ** an SQLite error code.
41250 static int pagerSyncHotJournal(Pager *pPager){
41251 int rc = SQLITE_OK;
41252 if( !pPager->noSync ){
41253 rc = sqlite3OsSync(pPager->jfd, SQLITE_SYNC_NORMAL);
41255 if( rc==SQLITE_OK ){
41256 rc = sqlite3OsFileSize(pPager->jfd, &pPager->journalHdr);
41258 return rc;
41262 ** Shutdown the page cache. Free all memory and close all files.
41264 ** If a transaction was in progress when this routine is called, that
41265 ** transaction is rolled back. All outstanding pages are invalidated
41266 ** and their memory is freed. Any attempt to use a page associated
41267 ** with this page cache after this function returns will likely
41268 ** result in a coredump.
41270 ** This function always succeeds. If a transaction is active an attempt
41271 ** is made to roll it back. If an error occurs during the rollback
41272 ** a hot journal may be left in the filesystem but no error is returned
41273 ** to the caller.
41275 SQLITE_PRIVATE int sqlite3PagerClose(Pager *pPager){
41276 u8 *pTmp = (u8 *)pPager->pTmpSpace;
41278 assert( assert_pager_state(pPager) );
41279 disable_simulated_io_errors();
41280 sqlite3BeginBenignMalloc();
41281 /* pPager->errCode = 0; */
41282 pPager->exclusiveMode = 0;
41283 #ifndef SQLITE_OMIT_WAL
41284 sqlite3WalClose(pPager->pWal, pPager->ckptSyncFlags, pPager->pageSize, pTmp);
41285 pPager->pWal = 0;
41286 #endif
41287 pager_reset(pPager);
41288 if( MEMDB ){
41289 pager_unlock(pPager);
41290 }else{
41291 /* If it is open, sync the journal file before calling UnlockAndRollback.
41292 ** If this is not done, then an unsynced portion of the open journal
41293 ** file may be played back into the database. If a power failure occurs
41294 ** while this is happening, the database could become corrupt.
41296 ** If an error occurs while trying to sync the journal, shift the pager
41297 ** into the ERROR state. This causes UnlockAndRollback to unlock the
41298 ** database and close the journal file without attempting to roll it
41299 ** back or finalize it. The next database user will have to do hot-journal
41300 ** rollback before accessing the database file.
41302 if( isOpen(pPager->jfd) ){
41303 pager_error(pPager, pagerSyncHotJournal(pPager));
41305 pagerUnlockAndRollback(pPager);
41307 sqlite3EndBenignMalloc();
41308 enable_simulated_io_errors();
41309 PAGERTRACE(("CLOSE %d\n", PAGERID(pPager)));
41310 IOTRACE(("CLOSE %p\n", pPager))
41311 sqlite3OsClose(pPager->jfd);
41312 sqlite3OsClose(pPager->fd);
41313 sqlite3PageFree(pTmp);
41314 sqlite3PcacheClose(pPager->pPCache);
41316 #ifdef SQLITE_HAS_CODEC
41317 if( pPager->xCodecFree ) pPager->xCodecFree(pPager->pCodec);
41318 #endif
41320 assert( !pPager->aSavepoint && !pPager->pInJournal );
41321 assert( !isOpen(pPager->jfd) && !isOpen(pPager->sjfd) );
41323 sqlite3_free(pPager);
41324 return SQLITE_OK;
41327 #if !defined(NDEBUG) || defined(SQLITE_TEST)
41329 ** Return the page number for page pPg.
41331 SQLITE_PRIVATE Pgno sqlite3PagerPagenumber(DbPage *pPg){
41332 return pPg->pgno;
41334 #endif
41337 ** Increment the reference count for page pPg.
41339 SQLITE_PRIVATE void sqlite3PagerRef(DbPage *pPg){
41340 sqlite3PcacheRef(pPg);
41344 ** Sync the journal. In other words, make sure all the pages that have
41345 ** been written to the journal have actually reached the surface of the
41346 ** disk and can be restored in the event of a hot-journal rollback.
41348 ** If the Pager.noSync flag is set, then this function is a no-op.
41349 ** Otherwise, the actions required depend on the journal-mode and the
41350 ** device characteristics of the the file-system, as follows:
41352 ** * If the journal file is an in-memory journal file, no action need
41353 ** be taken.
41355 ** * Otherwise, if the device does not support the SAFE_APPEND property,
41356 ** then the nRec field of the most recently written journal header
41357 ** is updated to contain the number of journal records that have
41358 ** been written following it. If the pager is operating in full-sync
41359 ** mode, then the journal file is synced before this field is updated.
41361 ** * If the device does not support the SEQUENTIAL property, then
41362 ** journal file is synced.
41364 ** Or, in pseudo-code:
41366 ** if( NOT <in-memory journal> ){
41367 ** if( NOT SAFE_APPEND ){
41368 ** if( <full-sync mode> ) xSync(<journal file>);
41369 ** <update nRec field>
41370 ** }
41371 ** if( NOT SEQUENTIAL ) xSync(<journal file>);
41372 ** }
41374 ** If successful, this routine clears the PGHDR_NEED_SYNC flag of every
41375 ** page currently held in memory before returning SQLITE_OK. If an IO
41376 ** error is encountered, then the IO error code is returned to the caller.
41378 static int syncJournal(Pager *pPager, int newHdr){
41379 int rc; /* Return code */
41381 assert( pPager->eState==PAGER_WRITER_CACHEMOD
41382 || pPager->eState==PAGER_WRITER_DBMOD
41384 assert( assert_pager_state(pPager) );
41385 assert( !pagerUseWal(pPager) );
41387 rc = sqlite3PagerExclusiveLock(pPager);
41388 if( rc!=SQLITE_OK ) return rc;
41390 if( !pPager->noSync ){
41391 assert( !pPager->tempFile );
41392 if( isOpen(pPager->jfd) && pPager->journalMode!=PAGER_JOURNALMODE_MEMORY ){
41393 const int iDc = sqlite3OsDeviceCharacteristics(pPager->fd);
41394 assert( isOpen(pPager->jfd) );
41396 if( 0==(iDc&SQLITE_IOCAP_SAFE_APPEND) ){
41397 /* This block deals with an obscure problem. If the last connection
41398 ** that wrote to this database was operating in persistent-journal
41399 ** mode, then the journal file may at this point actually be larger
41400 ** than Pager.journalOff bytes. If the next thing in the journal
41401 ** file happens to be a journal-header (written as part of the
41402 ** previous connection's transaction), and a crash or power-failure
41403 ** occurs after nRec is updated but before this connection writes
41404 ** anything else to the journal file (or commits/rolls back its
41405 ** transaction), then SQLite may become confused when doing the
41406 ** hot-journal rollback following recovery. It may roll back all
41407 ** of this connections data, then proceed to rolling back the old,
41408 ** out-of-date data that follows it. Database corruption.
41410 ** To work around this, if the journal file does appear to contain
41411 ** a valid header following Pager.journalOff, then write a 0x00
41412 ** byte to the start of it to prevent it from being recognized.
41414 ** Variable iNextHdrOffset is set to the offset at which this
41415 ** problematic header will occur, if it exists. aMagic is used
41416 ** as a temporary buffer to inspect the first couple of bytes of
41417 ** the potential journal header.
41419 i64 iNextHdrOffset;
41420 u8 aMagic[8];
41421 u8 zHeader[sizeof(aJournalMagic)+4];
41423 memcpy(zHeader, aJournalMagic, sizeof(aJournalMagic));
41424 put32bits(&zHeader[sizeof(aJournalMagic)], pPager->nRec);
41426 iNextHdrOffset = journalHdrOffset(pPager);
41427 rc = sqlite3OsRead(pPager->jfd, aMagic, 8, iNextHdrOffset);
41428 if( rc==SQLITE_OK && 0==memcmp(aMagic, aJournalMagic, 8) ){
41429 static const u8 zerobyte = 0;
41430 rc = sqlite3OsWrite(pPager->jfd, &zerobyte, 1, iNextHdrOffset);
41432 if( rc!=SQLITE_OK && rc!=SQLITE_IOERR_SHORT_READ ){
41433 return rc;
41436 /* Write the nRec value into the journal file header. If in
41437 ** full-synchronous mode, sync the journal first. This ensures that
41438 ** all data has really hit the disk before nRec is updated to mark
41439 ** it as a candidate for rollback.
41441 ** This is not required if the persistent media supports the
41442 ** SAFE_APPEND property. Because in this case it is not possible
41443 ** for garbage data to be appended to the file, the nRec field
41444 ** is populated with 0xFFFFFFFF when the journal header is written
41445 ** and never needs to be updated.
41447 if( pPager->fullSync && 0==(iDc&SQLITE_IOCAP_SEQUENTIAL) ){
41448 PAGERTRACE(("SYNC journal of %d\n", PAGERID(pPager)));
41449 IOTRACE(("JSYNC %p\n", pPager))
41450 rc = sqlite3OsSync(pPager->jfd, pPager->syncFlags);
41451 if( rc!=SQLITE_OK ) return rc;
41453 IOTRACE(("JHDR %p %lld\n", pPager, pPager->journalHdr));
41454 rc = sqlite3OsWrite(
41455 pPager->jfd, zHeader, sizeof(zHeader), pPager->journalHdr
41457 if( rc!=SQLITE_OK ) return rc;
41459 if( 0==(iDc&SQLITE_IOCAP_SEQUENTIAL) ){
41460 PAGERTRACE(("SYNC journal of %d\n", PAGERID(pPager)));
41461 IOTRACE(("JSYNC %p\n", pPager))
41462 rc = sqlite3OsSync(pPager->jfd, pPager->syncFlags|
41463 (pPager->syncFlags==SQLITE_SYNC_FULL?SQLITE_SYNC_DATAONLY:0)
41465 if( rc!=SQLITE_OK ) return rc;
41468 pPager->journalHdr = pPager->journalOff;
41469 if( newHdr && 0==(iDc&SQLITE_IOCAP_SAFE_APPEND) ){
41470 pPager->nRec = 0;
41471 rc = writeJournalHdr(pPager);
41472 if( rc!=SQLITE_OK ) return rc;
41474 }else{
41475 pPager->journalHdr = pPager->journalOff;
41479 /* Unless the pager is in noSync mode, the journal file was just
41480 ** successfully synced. Either way, clear the PGHDR_NEED_SYNC flag on
41481 ** all pages.
41483 sqlite3PcacheClearSyncFlags(pPager->pPCache);
41484 pPager->eState = PAGER_WRITER_DBMOD;
41485 assert( assert_pager_state(pPager) );
41486 return SQLITE_OK;
41490 ** The argument is the first in a linked list of dirty pages connected
41491 ** by the PgHdr.pDirty pointer. This function writes each one of the
41492 ** in-memory pages in the list to the database file. The argument may
41493 ** be NULL, representing an empty list. In this case this function is
41494 ** a no-op.
41496 ** The pager must hold at least a RESERVED lock when this function
41497 ** is called. Before writing anything to the database file, this lock
41498 ** is upgraded to an EXCLUSIVE lock. If the lock cannot be obtained,
41499 ** SQLITE_BUSY is returned and no data is written to the database file.
41501 ** If the pager is a temp-file pager and the actual file-system file
41502 ** is not yet open, it is created and opened before any data is
41503 ** written out.
41505 ** Once the lock has been upgraded and, if necessary, the file opened,
41506 ** the pages are written out to the database file in list order. Writing
41507 ** a page is skipped if it meets either of the following criteria:
41509 ** * The page number is greater than Pager.dbSize, or
41510 ** * The PGHDR_DONT_WRITE flag is set on the page.
41512 ** If writing out a page causes the database file to grow, Pager.dbFileSize
41513 ** is updated accordingly. If page 1 is written out, then the value cached
41514 ** in Pager.dbFileVers[] is updated to match the new value stored in
41515 ** the database file.
41517 ** If everything is successful, SQLITE_OK is returned. If an IO error
41518 ** occurs, an IO error code is returned. Or, if the EXCLUSIVE lock cannot
41519 ** be obtained, SQLITE_BUSY is returned.
41521 static int pager_write_pagelist(Pager *pPager, PgHdr *pList){
41522 int rc = SQLITE_OK; /* Return code */
41524 /* This function is only called for rollback pagers in WRITER_DBMOD state. */
41525 assert( !pagerUseWal(pPager) );
41526 assert( pPager->eState==PAGER_WRITER_DBMOD );
41527 assert( pPager->eLock==EXCLUSIVE_LOCK );
41529 /* If the file is a temp-file has not yet been opened, open it now. It
41530 ** is not possible for rc to be other than SQLITE_OK if this branch
41531 ** is taken, as pager_wait_on_lock() is a no-op for temp-files.
41533 if( !isOpen(pPager->fd) ){
41534 assert( pPager->tempFile && rc==SQLITE_OK );
41535 rc = pagerOpentemp(pPager, pPager->fd, pPager->vfsFlags);
41538 /* Before the first write, give the VFS a hint of what the final
41539 ** file size will be.
41541 assert( rc!=SQLITE_OK || isOpen(pPager->fd) );
41542 if( rc==SQLITE_OK && pPager->dbSize>pPager->dbHintSize ){
41543 sqlite3_int64 szFile = pPager->pageSize * (sqlite3_int64)pPager->dbSize;
41544 sqlite3OsFileControl(pPager->fd, SQLITE_FCNTL_SIZE_HINT, &szFile);
41545 pPager->dbHintSize = pPager->dbSize;
41548 while( rc==SQLITE_OK && pList ){
41549 Pgno pgno = pList->pgno;
41551 /* If there are dirty pages in the page cache with page numbers greater
41552 ** than Pager.dbSize, this means sqlite3PagerTruncateImage() was called to
41553 ** make the file smaller (presumably by auto-vacuum code). Do not write
41554 ** any such pages to the file.
41556 ** Also, do not write out any page that has the PGHDR_DONT_WRITE flag
41557 ** set (set by sqlite3PagerDontWrite()).
41559 if( pgno<=pPager->dbSize && 0==(pList->flags&PGHDR_DONT_WRITE) ){
41560 i64 offset = (pgno-1)*(i64)pPager->pageSize; /* Offset to write */
41561 char *pData; /* Data to write */
41563 assert( (pList->flags&PGHDR_NEED_SYNC)==0 );
41564 if( pList->pgno==1 ) pager_write_changecounter(pList);
41566 /* Encode the database */
41567 CODEC2(pPager, pList->pData, pgno, 6, return SQLITE_NOMEM, pData);
41569 /* Write out the page data. */
41570 rc = sqlite3OsWrite(pPager->fd, pData, pPager->pageSize, offset);
41572 /* If page 1 was just written, update Pager.dbFileVers to match
41573 ** the value now stored in the database file. If writing this
41574 ** page caused the database file to grow, update dbFileSize.
41576 if( pgno==1 ){
41577 memcpy(&pPager->dbFileVers, &pData[24], sizeof(pPager->dbFileVers));
41579 if( pgno>pPager->dbFileSize ){
41580 pPager->dbFileSize = pgno;
41583 /* Update any backup objects copying the contents of this pager. */
41584 sqlite3BackupUpdate(pPager->pBackup, pgno, (u8*)pList->pData);
41586 PAGERTRACE(("STORE %d page %d hash(%08x)\n",
41587 PAGERID(pPager), pgno, pager_pagehash(pList)));
41588 IOTRACE(("PGOUT %p %d\n", pPager, pgno));
41589 PAGER_INCR(sqlite3_pager_writedb_count);
41590 PAGER_INCR(pPager->nWrite);
41591 }else{
41592 PAGERTRACE(("NOSTORE %d page %d\n", PAGERID(pPager), pgno));
41594 pager_set_pagehash(pList);
41595 pList = pList->pDirty;
41598 return rc;
41602 ** Ensure that the sub-journal file is open. If it is already open, this
41603 ** function is a no-op.
41605 ** SQLITE_OK is returned if everything goes according to plan. An
41606 ** SQLITE_IOERR_XXX error code is returned if a call to sqlite3OsOpen()
41607 ** fails.
41609 static int openSubJournal(Pager *pPager){
41610 int rc = SQLITE_OK;
41611 if( !isOpen(pPager->sjfd) ){
41612 if( pPager->journalMode==PAGER_JOURNALMODE_MEMORY || pPager->subjInMemory ){
41613 sqlite3MemJournalOpen(pPager->sjfd);
41614 }else{
41615 rc = pagerOpentemp(pPager, pPager->sjfd, SQLITE_OPEN_SUBJOURNAL);
41618 return rc;
41622 ** Append a record of the current state of page pPg to the sub-journal.
41623 ** It is the callers responsibility to use subjRequiresPage() to check
41624 ** that it is really required before calling this function.
41626 ** If successful, set the bit corresponding to pPg->pgno in the bitvecs
41627 ** for all open savepoints before returning.
41629 ** This function returns SQLITE_OK if everything is successful, an IO
41630 ** error code if the attempt to write to the sub-journal fails, or
41631 ** SQLITE_NOMEM if a malloc fails while setting a bit in a savepoint
41632 ** bitvec.
41634 static int subjournalPage(PgHdr *pPg){
41635 int rc = SQLITE_OK;
41636 Pager *pPager = pPg->pPager;
41637 if( pPager->journalMode!=PAGER_JOURNALMODE_OFF ){
41639 /* Open the sub-journal, if it has not already been opened */
41640 assert( pPager->useJournal );
41641 assert( isOpen(pPager->jfd) || pagerUseWal(pPager) );
41642 assert( isOpen(pPager->sjfd) || pPager->nSubRec==0 );
41643 assert( pagerUseWal(pPager)
41644 || pageInJournal(pPg)
41645 || pPg->pgno>pPager->dbOrigSize
41647 rc = openSubJournal(pPager);
41649 /* If the sub-journal was opened successfully (or was already open),
41650 ** write the journal record into the file. */
41651 if( rc==SQLITE_OK ){
41652 void *pData = pPg->pData;
41653 i64 offset = pPager->nSubRec*(4+pPager->pageSize);
41654 char *pData2;
41656 CODEC2(pPager, pData, pPg->pgno, 7, return SQLITE_NOMEM, pData2);
41657 PAGERTRACE(("STMT-JOURNAL %d page %d\n", PAGERID(pPager), pPg->pgno));
41658 rc = write32bits(pPager->sjfd, offset, pPg->pgno);
41659 if( rc==SQLITE_OK ){
41660 rc = sqlite3OsWrite(pPager->sjfd, pData2, pPager->pageSize, offset+4);
41664 if( rc==SQLITE_OK ){
41665 pPager->nSubRec++;
41666 assert( pPager->nSavepoint>0 );
41667 rc = addToSavepointBitvecs(pPager, pPg->pgno);
41669 return rc;
41673 ** This function is called by the pcache layer when it has reached some
41674 ** soft memory limit. The first argument is a pointer to a Pager object
41675 ** (cast as a void*). The pager is always 'purgeable' (not an in-memory
41676 ** database). The second argument is a reference to a page that is
41677 ** currently dirty but has no outstanding references. The page
41678 ** is always associated with the Pager object passed as the first
41679 ** argument.
41681 ** The job of this function is to make pPg clean by writing its contents
41682 ** out to the database file, if possible. This may involve syncing the
41683 ** journal file.
41685 ** If successful, sqlite3PcacheMakeClean() is called on the page and
41686 ** SQLITE_OK returned. If an IO error occurs while trying to make the
41687 ** page clean, the IO error code is returned. If the page cannot be
41688 ** made clean for some other reason, but no error occurs, then SQLITE_OK
41689 ** is returned by sqlite3PcacheMakeClean() is not called.
41691 static int pagerStress(void *p, PgHdr *pPg){
41692 Pager *pPager = (Pager *)p;
41693 int rc = SQLITE_OK;
41695 assert( pPg->pPager==pPager );
41696 assert( pPg->flags&PGHDR_DIRTY );
41698 /* The doNotSyncSpill flag is set during times when doing a sync of
41699 ** journal (and adding a new header) is not allowed. This occurs
41700 ** during calls to sqlite3PagerWrite() while trying to journal multiple
41701 ** pages belonging to the same sector.
41703 ** The doNotSpill flag inhibits all cache spilling regardless of whether
41704 ** or not a sync is required. This is set during a rollback.
41706 ** Spilling is also prohibited when in an error state since that could
41707 ** lead to database corruption. In the current implementaton it
41708 ** is impossible for sqlite3PCacheFetch() to be called with createFlag==1
41709 ** while in the error state, hence it is impossible for this routine to
41710 ** be called in the error state. Nevertheless, we include a NEVER()
41711 ** test for the error state as a safeguard against future changes.
41713 if( NEVER(pPager->errCode) ) return SQLITE_OK;
41714 if( pPager->doNotSpill ) return SQLITE_OK;
41715 if( pPager->doNotSyncSpill && (pPg->flags & PGHDR_NEED_SYNC)!=0 ){
41716 return SQLITE_OK;
41719 pPg->pDirty = 0;
41720 if( pagerUseWal(pPager) ){
41721 /* Write a single frame for this page to the log. */
41722 if( subjRequiresPage(pPg) ){
41723 rc = subjournalPage(pPg);
41725 if( rc==SQLITE_OK ){
41726 rc = pagerWalFrames(pPager, pPg, 0, 0, 0);
41728 }else{
41730 /* Sync the journal file if required. */
41731 if( pPg->flags&PGHDR_NEED_SYNC
41732 || pPager->eState==PAGER_WRITER_CACHEMOD
41734 rc = syncJournal(pPager, 1);
41737 /* If the page number of this page is larger than the current size of
41738 ** the database image, it may need to be written to the sub-journal.
41739 ** This is because the call to pager_write_pagelist() below will not
41740 ** actually write data to the file in this case.
41742 ** Consider the following sequence of events:
41744 ** BEGIN;
41745 ** <journal page X>
41746 ** <modify page X>
41747 ** SAVEPOINT sp;
41748 ** <shrink database file to Y pages>
41749 ** pagerStress(page X)
41750 ** ROLLBACK TO sp;
41752 ** If (X>Y), then when pagerStress is called page X will not be written
41753 ** out to the database file, but will be dropped from the cache. Then,
41754 ** following the "ROLLBACK TO sp" statement, reading page X will read
41755 ** data from the database file. This will be the copy of page X as it
41756 ** was when the transaction started, not as it was when "SAVEPOINT sp"
41757 ** was executed.
41759 ** The solution is to write the current data for page X into the
41760 ** sub-journal file now (if it is not already there), so that it will
41761 ** be restored to its current value when the "ROLLBACK TO sp" is
41762 ** executed.
41764 if( NEVER(
41765 rc==SQLITE_OK && pPg->pgno>pPager->dbSize && subjRequiresPage(pPg)
41766 ) ){
41767 rc = subjournalPage(pPg);
41770 /* Write the contents of the page out to the database file. */
41771 if( rc==SQLITE_OK ){
41772 assert( (pPg->flags&PGHDR_NEED_SYNC)==0 );
41773 rc = pager_write_pagelist(pPager, pPg);
41777 /* Mark the page as clean. */
41778 if( rc==SQLITE_OK ){
41779 PAGERTRACE(("STRESS %d page %d\n", PAGERID(pPager), pPg->pgno));
41780 sqlite3PcacheMakeClean(pPg);
41783 return pager_error(pPager, rc);
41788 ** Allocate and initialize a new Pager object and put a pointer to it
41789 ** in *ppPager. The pager should eventually be freed by passing it
41790 ** to sqlite3PagerClose().
41792 ** The zFilename argument is the path to the database file to open.
41793 ** If zFilename is NULL then a randomly-named temporary file is created
41794 ** and used as the file to be cached. Temporary files are be deleted
41795 ** automatically when they are closed. If zFilename is ":memory:" then
41796 ** all information is held in cache. It is never written to disk.
41797 ** This can be used to implement an in-memory database.
41799 ** The nExtra parameter specifies the number of bytes of space allocated
41800 ** along with each page reference. This space is available to the user
41801 ** via the sqlite3PagerGetExtra() API.
41803 ** The flags argument is used to specify properties that affect the
41804 ** operation of the pager. It should be passed some bitwise combination
41805 ** of the PAGER_OMIT_JOURNAL and PAGER_NO_READLOCK flags.
41807 ** The vfsFlags parameter is a bitmask to pass to the flags parameter
41808 ** of the xOpen() method of the supplied VFS when opening files.
41810 ** If the pager object is allocated and the specified file opened
41811 ** successfully, SQLITE_OK is returned and *ppPager set to point to
41812 ** the new pager object. If an error occurs, *ppPager is set to NULL
41813 ** and error code returned. This function may return SQLITE_NOMEM
41814 ** (sqlite3Malloc() is used to allocate memory), SQLITE_CANTOPEN or
41815 ** various SQLITE_IO_XXX errors.
41817 SQLITE_PRIVATE int sqlite3PagerOpen(
41818 sqlite3_vfs *pVfs, /* The virtual file system to use */
41819 Pager **ppPager, /* OUT: Return the Pager structure here */
41820 const char *zFilename, /* Name of the database file to open */
41821 int nExtra, /* Extra bytes append to each in-memory page */
41822 int flags, /* flags controlling this file */
41823 int vfsFlags, /* flags passed through to sqlite3_vfs.xOpen() */
41824 void (*xReinit)(DbPage*) /* Function to reinitialize pages */
41826 u8 *pPtr;
41827 Pager *pPager = 0; /* Pager object to allocate and return */
41828 int rc = SQLITE_OK; /* Return code */
41829 int tempFile = 0; /* True for temp files (incl. in-memory files) */
41830 int memDb = 0; /* True if this is an in-memory file */
41831 int readOnly = 0; /* True if this is a read-only file */
41832 int journalFileSize; /* Bytes to allocate for each journal fd */
41833 char *zPathname = 0; /* Full path to database file */
41834 int nPathname = 0; /* Number of bytes in zPathname */
41835 int useJournal = (flags & PAGER_OMIT_JOURNAL)==0; /* False to omit journal */
41836 int noReadlock = (flags & PAGER_NO_READLOCK)!=0; /* True to omit read-lock */
41837 int pcacheSize = sqlite3PcacheSize(); /* Bytes to allocate for PCache */
41838 u32 szPageDflt = SQLITE_DEFAULT_PAGE_SIZE; /* Default page size */
41839 const char *zUri = 0; /* URI args to copy */
41840 int nUri = 0; /* Number of bytes of URI args at *zUri */
41842 /* Figure out how much space is required for each journal file-handle
41843 ** (there are two of them, the main journal and the sub-journal). This
41844 ** is the maximum space required for an in-memory journal file handle
41845 ** and a regular journal file-handle. Note that a "regular journal-handle"
41846 ** may be a wrapper capable of caching the first portion of the journal
41847 ** file in memory to implement the atomic-write optimization (see
41848 ** source file journal.c).
41850 if( sqlite3JournalSize(pVfs)>sqlite3MemJournalSize() ){
41851 journalFileSize = ROUND8(sqlite3JournalSize(pVfs));
41852 }else{
41853 journalFileSize = ROUND8(sqlite3MemJournalSize());
41856 /* Set the output variable to NULL in case an error occurs. */
41857 *ppPager = 0;
41859 #ifndef SQLITE_OMIT_MEMORYDB
41860 if( flags & PAGER_MEMORY ){
41861 memDb = 1;
41862 zFilename = 0;
41864 #endif
41866 /* Compute and store the full pathname in an allocated buffer pointed
41867 ** to by zPathname, length nPathname. Or, if this is a temporary file,
41868 ** leave both nPathname and zPathname set to 0.
41870 if( zFilename && zFilename[0] ){
41871 const char *z;
41872 nPathname = pVfs->mxPathname+1;
41873 zPathname = sqlite3Malloc(nPathname*2);
41874 if( zPathname==0 ){
41875 return SQLITE_NOMEM;
41877 zPathname[0] = 0; /* Make sure initialized even if FullPathname() fails */
41878 rc = sqlite3OsFullPathname(pVfs, zFilename, nPathname, zPathname);
41879 nPathname = sqlite3Strlen30(zPathname);
41880 z = zUri = &zFilename[sqlite3Strlen30(zFilename)+1];
41881 while( *z ){
41882 z += sqlite3Strlen30(z)+1;
41883 z += sqlite3Strlen30(z)+1;
41885 nUri = &z[1] - zUri;
41886 if( rc==SQLITE_OK && nPathname+8>pVfs->mxPathname ){
41887 /* This branch is taken when the journal path required by
41888 ** the database being opened will be more than pVfs->mxPathname
41889 ** bytes in length. This means the database cannot be opened,
41890 ** as it will not be possible to open the journal file or even
41891 ** check for a hot-journal before reading.
41893 rc = SQLITE_CANTOPEN_BKPT;
41895 if( rc!=SQLITE_OK ){
41896 sqlite3_free(zPathname);
41897 return rc;
41901 /* Allocate memory for the Pager structure, PCache object, the
41902 ** three file descriptors, the database file name and the journal
41903 ** file name. The layout in memory is as follows:
41905 ** Pager object (sizeof(Pager) bytes)
41906 ** PCache object (sqlite3PcacheSize() bytes)
41907 ** Database file handle (pVfs->szOsFile bytes)
41908 ** Sub-journal file handle (journalFileSize bytes)
41909 ** Main journal file handle (journalFileSize bytes)
41910 ** Database file name (nPathname+1 bytes)
41911 ** Journal file name (nPathname+8+1 bytes)
41913 pPtr = (u8 *)sqlite3MallocZero(
41914 ROUND8(sizeof(*pPager)) + /* Pager structure */
41915 ROUND8(pcacheSize) + /* PCache object */
41916 ROUND8(pVfs->szOsFile) + /* The main db file */
41917 journalFileSize * 2 + /* The two journal files */
41918 nPathname + 1 + nUri + /* zFilename */
41919 nPathname + 8 + 1 /* zJournal */
41920 #ifndef SQLITE_OMIT_WAL
41921 + nPathname + 4 + 1 /* zWal */
41922 #endif
41924 assert( EIGHT_BYTE_ALIGNMENT(SQLITE_INT_TO_PTR(journalFileSize)) );
41925 if( !pPtr ){
41926 sqlite3_free(zPathname);
41927 return SQLITE_NOMEM;
41929 pPager = (Pager*)(pPtr);
41930 pPager->pPCache = (PCache*)(pPtr += ROUND8(sizeof(*pPager)));
41931 pPager->fd = (sqlite3_file*)(pPtr += ROUND8(pcacheSize));
41932 pPager->sjfd = (sqlite3_file*)(pPtr += ROUND8(pVfs->szOsFile));
41933 pPager->jfd = (sqlite3_file*)(pPtr += journalFileSize);
41934 pPager->zFilename = (char*)(pPtr += journalFileSize);
41935 assert( EIGHT_BYTE_ALIGNMENT(pPager->jfd) );
41937 /* Fill in the Pager.zFilename and Pager.zJournal buffers, if required. */
41938 if( zPathname ){
41939 assert( nPathname>0 );
41940 pPager->zJournal = (char*)(pPtr += nPathname + 1 + nUri);
41941 memcpy(pPager->zFilename, zPathname, nPathname);
41942 memcpy(&pPager->zFilename[nPathname+1], zUri, nUri);
41943 memcpy(pPager->zJournal, zPathname, nPathname);
41944 memcpy(&pPager->zJournal[nPathname], "-journal", 8);
41945 sqlite3FileSuffix3(pPager->zFilename, pPager->zJournal);
41946 #ifndef SQLITE_OMIT_WAL
41947 pPager->zWal = &pPager->zJournal[nPathname+8+1];
41948 memcpy(pPager->zWal, zPathname, nPathname);
41949 memcpy(&pPager->zWal[nPathname], "-wal", 4);
41950 sqlite3FileSuffix3(pPager->zFilename, pPager->zWal);
41951 #endif
41952 sqlite3_free(zPathname);
41954 pPager->pVfs = pVfs;
41955 pPager->vfsFlags = vfsFlags;
41957 /* Open the pager file.
41959 if( zFilename && zFilename[0] ){
41960 int fout = 0; /* VFS flags returned by xOpen() */
41961 rc = sqlite3OsOpen(pVfs, pPager->zFilename, pPager->fd, vfsFlags, &fout);
41962 assert( !memDb );
41963 readOnly = (fout&SQLITE_OPEN_READONLY);
41965 /* If the file was successfully opened for read/write access,
41966 ** choose a default page size in case we have to create the
41967 ** database file. The default page size is the maximum of:
41969 ** + SQLITE_DEFAULT_PAGE_SIZE,
41970 ** + The value returned by sqlite3OsSectorSize()
41971 ** + The largest page size that can be written atomically.
41973 if( rc==SQLITE_OK && !readOnly ){
41974 setSectorSize(pPager);
41975 assert(SQLITE_DEFAULT_PAGE_SIZE<=SQLITE_MAX_DEFAULT_PAGE_SIZE);
41976 if( szPageDflt<pPager->sectorSize ){
41977 if( pPager->sectorSize>SQLITE_MAX_DEFAULT_PAGE_SIZE ){
41978 szPageDflt = SQLITE_MAX_DEFAULT_PAGE_SIZE;
41979 }else{
41980 szPageDflt = (u32)pPager->sectorSize;
41983 #ifdef SQLITE_ENABLE_ATOMIC_WRITE
41985 int iDc = sqlite3OsDeviceCharacteristics(pPager->fd);
41986 int ii;
41987 assert(SQLITE_IOCAP_ATOMIC512==(512>>8));
41988 assert(SQLITE_IOCAP_ATOMIC64K==(65536>>8));
41989 assert(SQLITE_MAX_DEFAULT_PAGE_SIZE<=65536);
41990 for(ii=szPageDflt; ii<=SQLITE_MAX_DEFAULT_PAGE_SIZE; ii=ii*2){
41991 if( iDc&(SQLITE_IOCAP_ATOMIC|(ii>>8)) ){
41992 szPageDflt = ii;
41996 #endif
41998 }else{
41999 /* If a temporary file is requested, it is not opened immediately.
42000 ** In this case we accept the default page size and delay actually
42001 ** opening the file until the first call to OsWrite().
42003 ** This branch is also run for an in-memory database. An in-memory
42004 ** database is the same as a temp-file that is never written out to
42005 ** disk and uses an in-memory rollback journal.
42007 tempFile = 1;
42008 pPager->eState = PAGER_READER;
42009 pPager->eLock = EXCLUSIVE_LOCK;
42010 readOnly = (vfsFlags&SQLITE_OPEN_READONLY);
42013 /* The following call to PagerSetPagesize() serves to set the value of
42014 ** Pager.pageSize and to allocate the Pager.pTmpSpace buffer.
42016 if( rc==SQLITE_OK ){
42017 assert( pPager->memDb==0 );
42018 rc = sqlite3PagerSetPagesize(pPager, &szPageDflt, -1);
42019 testcase( rc!=SQLITE_OK );
42022 /* If an error occurred in either of the blocks above, free the
42023 ** Pager structure and close the file.
42025 if( rc!=SQLITE_OK ){
42026 assert( !pPager->pTmpSpace );
42027 sqlite3OsClose(pPager->fd);
42028 sqlite3_free(pPager);
42029 return rc;
42032 /* Initialize the PCache object. */
42033 assert( nExtra<1000 );
42034 nExtra = ROUND8(nExtra);
42035 sqlite3PcacheOpen(szPageDflt, nExtra, !memDb,
42036 !memDb?pagerStress:0, (void *)pPager, pPager->pPCache);
42038 PAGERTRACE(("OPEN %d %s\n", FILEHANDLEID(pPager->fd), pPager->zFilename));
42039 IOTRACE(("OPEN %p %s\n", pPager, pPager->zFilename))
42041 pPager->useJournal = (u8)useJournal;
42042 pPager->noReadlock = (noReadlock && readOnly) ?1:0;
42043 /* pPager->stmtOpen = 0; */
42044 /* pPager->stmtInUse = 0; */
42045 /* pPager->nRef = 0; */
42046 /* pPager->stmtSize = 0; */
42047 /* pPager->stmtJSize = 0; */
42048 /* pPager->nPage = 0; */
42049 pPager->mxPgno = SQLITE_MAX_PAGE_COUNT;
42050 /* pPager->state = PAGER_UNLOCK; */
42051 #if 0
42052 assert( pPager->state == (tempFile ? PAGER_EXCLUSIVE : PAGER_UNLOCK) );
42053 #endif
42054 /* pPager->errMask = 0; */
42055 pPager->tempFile = (u8)tempFile;
42056 assert( tempFile==PAGER_LOCKINGMODE_NORMAL
42057 || tempFile==PAGER_LOCKINGMODE_EXCLUSIVE );
42058 assert( PAGER_LOCKINGMODE_EXCLUSIVE==1 );
42059 pPager->exclusiveMode = (u8)tempFile;
42060 pPager->changeCountDone = pPager->tempFile;
42061 pPager->memDb = (u8)memDb;
42062 pPager->readOnly = (u8)readOnly;
42063 assert( useJournal || pPager->tempFile );
42064 pPager->noSync = pPager->tempFile;
42065 pPager->fullSync = pPager->noSync ?0:1;
42066 pPager->syncFlags = pPager->noSync ? 0 : SQLITE_SYNC_NORMAL;
42067 pPager->ckptSyncFlags = pPager->syncFlags;
42068 /* pPager->pFirst = 0; */
42069 /* pPager->pFirstSynced = 0; */
42070 /* pPager->pLast = 0; */
42071 pPager->nExtra = (u16)nExtra;
42072 pPager->journalSizeLimit = SQLITE_DEFAULT_JOURNAL_SIZE_LIMIT;
42073 assert( isOpen(pPager->fd) || tempFile );
42074 setSectorSize(pPager);
42075 if( !useJournal ){
42076 pPager->journalMode = PAGER_JOURNALMODE_OFF;
42077 }else if( memDb ){
42078 pPager->journalMode = PAGER_JOURNALMODE_MEMORY;
42080 /* pPager->xBusyHandler = 0; */
42081 /* pPager->pBusyHandlerArg = 0; */
42082 pPager->xReiniter = xReinit;
42083 /* memset(pPager->aHash, 0, sizeof(pPager->aHash)); */
42085 *ppPager = pPager;
42086 return SQLITE_OK;
42092 ** This function is called after transitioning from PAGER_UNLOCK to
42093 ** PAGER_SHARED state. It tests if there is a hot journal present in
42094 ** the file-system for the given pager. A hot journal is one that
42095 ** needs to be played back. According to this function, a hot-journal
42096 ** file exists if the following criteria are met:
42098 ** * The journal file exists in the file system, and
42099 ** * No process holds a RESERVED or greater lock on the database file, and
42100 ** * The database file itself is greater than 0 bytes in size, and
42101 ** * The first byte of the journal file exists and is not 0x00.
42103 ** If the current size of the database file is 0 but a journal file
42104 ** exists, that is probably an old journal left over from a prior
42105 ** database with the same name. In this case the journal file is
42106 ** just deleted using OsDelete, *pExists is set to 0 and SQLITE_OK
42107 ** is returned.
42109 ** This routine does not check if there is a master journal filename
42110 ** at the end of the file. If there is, and that master journal file
42111 ** does not exist, then the journal file is not really hot. In this
42112 ** case this routine will return a false-positive. The pager_playback()
42113 ** routine will discover that the journal file is not really hot and
42114 ** will not roll it back.
42116 ** If a hot-journal file is found to exist, *pExists is set to 1 and
42117 ** SQLITE_OK returned. If no hot-journal file is present, *pExists is
42118 ** set to 0 and SQLITE_OK returned. If an IO error occurs while trying
42119 ** to determine whether or not a hot-journal file exists, the IO error
42120 ** code is returned and the value of *pExists is undefined.
42122 static int hasHotJournal(Pager *pPager, int *pExists){
42123 sqlite3_vfs * const pVfs = pPager->pVfs;
42124 int rc = SQLITE_OK; /* Return code */
42125 int exists = 1; /* True if a journal file is present */
42126 int jrnlOpen = !!isOpen(pPager->jfd);
42128 assert( pPager->useJournal );
42129 assert( isOpen(pPager->fd) );
42130 assert( pPager->eState==PAGER_OPEN );
42132 assert( jrnlOpen==0 || ( sqlite3OsDeviceCharacteristics(pPager->jfd) &
42133 SQLITE_IOCAP_UNDELETABLE_WHEN_OPEN
42136 *pExists = 0;
42137 if( !jrnlOpen ){
42138 rc = sqlite3OsAccess(pVfs, pPager->zJournal, SQLITE_ACCESS_EXISTS, &exists);
42140 if( rc==SQLITE_OK && exists ){
42141 int locked = 0; /* True if some process holds a RESERVED lock */
42143 /* Race condition here: Another process might have been holding the
42144 ** the RESERVED lock and have a journal open at the sqlite3OsAccess()
42145 ** call above, but then delete the journal and drop the lock before
42146 ** we get to the following sqlite3OsCheckReservedLock() call. If that
42147 ** is the case, this routine might think there is a hot journal when
42148 ** in fact there is none. This results in a false-positive which will
42149 ** be dealt with by the playback routine. Ticket #3883.
42151 rc = sqlite3OsCheckReservedLock(pPager->fd, &locked);
42152 if( rc==SQLITE_OK && !locked ){
42153 Pgno nPage; /* Number of pages in database file */
42155 /* Check the size of the database file. If it consists of 0 pages,
42156 ** then delete the journal file. See the header comment above for
42157 ** the reasoning here. Delete the obsolete journal file under
42158 ** a RESERVED lock to avoid race conditions and to avoid violating
42159 ** [H33020].
42161 rc = pagerPagecount(pPager, &nPage);
42162 if( rc==SQLITE_OK ){
42163 if( nPage==0 ){
42164 sqlite3BeginBenignMalloc();
42165 if( pagerLockDb(pPager, RESERVED_LOCK)==SQLITE_OK ){
42166 sqlite3OsDelete(pVfs, pPager->zJournal, 0);
42167 if( !pPager->exclusiveMode ) pagerUnlockDb(pPager, SHARED_LOCK);
42169 sqlite3EndBenignMalloc();
42170 }else{
42171 /* The journal file exists and no other connection has a reserved
42172 ** or greater lock on the database file. Now check that there is
42173 ** at least one non-zero bytes at the start of the journal file.
42174 ** If there is, then we consider this journal to be hot. If not,
42175 ** it can be ignored.
42177 if( !jrnlOpen ){
42178 int f = SQLITE_OPEN_READONLY|SQLITE_OPEN_MAIN_JOURNAL;
42179 rc = sqlite3OsOpen(pVfs, pPager->zJournal, pPager->jfd, f, &f);
42181 if( rc==SQLITE_OK ){
42182 u8 first = 0;
42183 rc = sqlite3OsRead(pPager->jfd, (void *)&first, 1, 0);
42184 if( rc==SQLITE_IOERR_SHORT_READ ){
42185 rc = SQLITE_OK;
42187 if( !jrnlOpen ){
42188 sqlite3OsClose(pPager->jfd);
42190 *pExists = (first!=0);
42191 }else if( rc==SQLITE_CANTOPEN ){
42192 /* If we cannot open the rollback journal file in order to see if
42193 ** its has a zero header, that might be due to an I/O error, or
42194 ** it might be due to the race condition described above and in
42195 ** ticket #3883. Either way, assume that the journal is hot.
42196 ** This might be a false positive. But if it is, then the
42197 ** automatic journal playback and recovery mechanism will deal
42198 ** with it under an EXCLUSIVE lock where we do not need to
42199 ** worry so much with race conditions.
42201 *pExists = 1;
42202 rc = SQLITE_OK;
42209 return rc;
42213 ** This function is called to obtain a shared lock on the database file.
42214 ** It is illegal to call sqlite3PagerAcquire() until after this function
42215 ** has been successfully called. If a shared-lock is already held when
42216 ** this function is called, it is a no-op.
42218 ** The following operations are also performed by this function.
42220 ** 1) If the pager is currently in PAGER_OPEN state (no lock held
42221 ** on the database file), then an attempt is made to obtain a
42222 ** SHARED lock on the database file. Immediately after obtaining
42223 ** the SHARED lock, the file-system is checked for a hot-journal,
42224 ** which is played back if present. Following any hot-journal
42225 ** rollback, the contents of the cache are validated by checking
42226 ** the 'change-counter' field of the database file header and
42227 ** discarded if they are found to be invalid.
42229 ** 2) If the pager is running in exclusive-mode, and there are currently
42230 ** no outstanding references to any pages, and is in the error state,
42231 ** then an attempt is made to clear the error state by discarding
42232 ** the contents of the page cache and rolling back any open journal
42233 ** file.
42235 ** If everything is successful, SQLITE_OK is returned. If an IO error
42236 ** occurs while locking the database, checking for a hot-journal file or
42237 ** rolling back a journal file, the IO error code is returned.
42239 SQLITE_PRIVATE int sqlite3PagerSharedLock(Pager *pPager){
42240 int rc = SQLITE_OK; /* Return code */
42242 /* This routine is only called from b-tree and only when there are no
42243 ** outstanding pages. This implies that the pager state should either
42244 ** be OPEN or READER. READER is only possible if the pager is or was in
42245 ** exclusive access mode.
42247 assert( sqlite3PcacheRefCount(pPager->pPCache)==0 );
42248 assert( assert_pager_state(pPager) );
42249 assert( pPager->eState==PAGER_OPEN || pPager->eState==PAGER_READER );
42250 if( NEVER(MEMDB && pPager->errCode) ){ return pPager->errCode; }
42252 if( !pagerUseWal(pPager) && pPager->eState==PAGER_OPEN ){
42253 int bHotJournal = 1; /* True if there exists a hot journal-file */
42255 assert( !MEMDB );
42256 assert( pPager->noReadlock==0 || pPager->readOnly );
42258 if( pPager->noReadlock==0 ){
42259 rc = pager_wait_on_lock(pPager, SHARED_LOCK);
42260 if( rc!=SQLITE_OK ){
42261 assert( pPager->eLock==NO_LOCK || pPager->eLock==UNKNOWN_LOCK );
42262 goto failed;
42266 /* If a journal file exists, and there is no RESERVED lock on the
42267 ** database file, then it either needs to be played back or deleted.
42269 if( pPager->eLock<=SHARED_LOCK ){
42270 rc = hasHotJournal(pPager, &bHotJournal);
42272 if( rc!=SQLITE_OK ){
42273 goto failed;
42275 if( bHotJournal ){
42276 /* Get an EXCLUSIVE lock on the database file. At this point it is
42277 ** important that a RESERVED lock is not obtained on the way to the
42278 ** EXCLUSIVE lock. If it were, another process might open the
42279 ** database file, detect the RESERVED lock, and conclude that the
42280 ** database is safe to read while this process is still rolling the
42281 ** hot-journal back.
42283 ** Because the intermediate RESERVED lock is not requested, any
42284 ** other process attempting to access the database file will get to
42285 ** this point in the code and fail to obtain its own EXCLUSIVE lock
42286 ** on the database file.
42288 ** Unless the pager is in locking_mode=exclusive mode, the lock is
42289 ** downgraded to SHARED_LOCK before this function returns.
42291 rc = pagerLockDb(pPager, EXCLUSIVE_LOCK);
42292 if( rc!=SQLITE_OK ){
42293 goto failed;
42296 /* If it is not already open and the file exists on disk, open the
42297 ** journal for read/write access. Write access is required because
42298 ** in exclusive-access mode the file descriptor will be kept open
42299 ** and possibly used for a transaction later on. Also, write-access
42300 ** is usually required to finalize the journal in journal_mode=persist
42301 ** mode (and also for journal_mode=truncate on some systems).
42303 ** If the journal does not exist, it usually means that some
42304 ** other connection managed to get in and roll it back before
42305 ** this connection obtained the exclusive lock above. Or, it
42306 ** may mean that the pager was in the error-state when this
42307 ** function was called and the journal file does not exist.
42309 if( !isOpen(pPager->jfd) ){
42310 sqlite3_vfs * const pVfs = pPager->pVfs;
42311 int bExists; /* True if journal file exists */
42312 rc = sqlite3OsAccess(
42313 pVfs, pPager->zJournal, SQLITE_ACCESS_EXISTS, &bExists);
42314 if( rc==SQLITE_OK && bExists ){
42315 int fout = 0;
42316 int f = SQLITE_OPEN_READWRITE|SQLITE_OPEN_MAIN_JOURNAL;
42317 assert( !pPager->tempFile );
42318 rc = sqlite3OsOpen(pVfs, pPager->zJournal, pPager->jfd, f, &fout);
42319 assert( rc!=SQLITE_OK || isOpen(pPager->jfd) );
42320 if( rc==SQLITE_OK && fout&SQLITE_OPEN_READONLY ){
42321 rc = SQLITE_CANTOPEN_BKPT;
42322 sqlite3OsClose(pPager->jfd);
42327 /* Playback and delete the journal. Drop the database write
42328 ** lock and reacquire the read lock. Purge the cache before
42329 ** playing back the hot-journal so that we don't end up with
42330 ** an inconsistent cache. Sync the hot journal before playing
42331 ** it back since the process that crashed and left the hot journal
42332 ** probably did not sync it and we are required to always sync
42333 ** the journal before playing it back.
42335 if( isOpen(pPager->jfd) ){
42336 assert( rc==SQLITE_OK );
42337 rc = pagerSyncHotJournal(pPager);
42338 if( rc==SQLITE_OK ){
42339 rc = pager_playback(pPager, 1);
42340 pPager->eState = PAGER_OPEN;
42342 }else if( !pPager->exclusiveMode ){
42343 pagerUnlockDb(pPager, SHARED_LOCK);
42346 if( rc!=SQLITE_OK ){
42347 /* This branch is taken if an error occurs while trying to open
42348 ** or roll back a hot-journal while holding an EXCLUSIVE lock. The
42349 ** pager_unlock() routine will be called before returning to unlock
42350 ** the file. If the unlock attempt fails, then Pager.eLock must be
42351 ** set to UNKNOWN_LOCK (see the comment above the #define for
42352 ** UNKNOWN_LOCK above for an explanation).
42354 ** In order to get pager_unlock() to do this, set Pager.eState to
42355 ** PAGER_ERROR now. This is not actually counted as a transition
42356 ** to ERROR state in the state diagram at the top of this file,
42357 ** since we know that the same call to pager_unlock() will very
42358 ** shortly transition the pager object to the OPEN state. Calling
42359 ** assert_pager_state() would fail now, as it should not be possible
42360 ** to be in ERROR state when there are zero outstanding page
42361 ** references.
42363 pager_error(pPager, rc);
42364 goto failed;
42367 assert( pPager->eState==PAGER_OPEN );
42368 assert( (pPager->eLock==SHARED_LOCK)
42369 || (pPager->exclusiveMode && pPager->eLock>SHARED_LOCK)
42373 if( !pPager->tempFile
42374 && (pPager->pBackup || sqlite3PcachePagecount(pPager->pPCache)>0)
42376 /* The shared-lock has just been acquired on the database file
42377 ** and there are already pages in the cache (from a previous
42378 ** read or write transaction). Check to see if the database
42379 ** has been modified. If the database has changed, flush the
42380 ** cache.
42382 ** Database changes is detected by looking at 15 bytes beginning
42383 ** at offset 24 into the file. The first 4 of these 16 bytes are
42384 ** a 32-bit counter that is incremented with each change. The
42385 ** other bytes change randomly with each file change when
42386 ** a codec is in use.
42388 ** There is a vanishingly small chance that a change will not be
42389 ** detected. The chance of an undetected change is so small that
42390 ** it can be neglected.
42392 Pgno nPage = 0;
42393 char dbFileVers[sizeof(pPager->dbFileVers)];
42395 rc = pagerPagecount(pPager, &nPage);
42396 if( rc ) goto failed;
42398 if( nPage>0 ){
42399 IOTRACE(("CKVERS %p %d\n", pPager, sizeof(dbFileVers)));
42400 rc = sqlite3OsRead(pPager->fd, &dbFileVers, sizeof(dbFileVers), 24);
42401 if( rc!=SQLITE_OK ){
42402 goto failed;
42404 }else{
42405 memset(dbFileVers, 0, sizeof(dbFileVers));
42408 if( memcmp(pPager->dbFileVers, dbFileVers, sizeof(dbFileVers))!=0 ){
42409 pager_reset(pPager);
42413 /* If there is a WAL file in the file-system, open this database in WAL
42414 ** mode. Otherwise, the following function call is a no-op.
42416 rc = pagerOpenWalIfPresent(pPager);
42417 #ifndef SQLITE_OMIT_WAL
42418 assert( pPager->pWal==0 || rc==SQLITE_OK );
42419 #endif
42422 if( pagerUseWal(pPager) ){
42423 assert( rc==SQLITE_OK );
42424 rc = pagerBeginReadTransaction(pPager);
42427 if( pPager->eState==PAGER_OPEN && rc==SQLITE_OK ){
42428 rc = pagerPagecount(pPager, &pPager->dbSize);
42431 failed:
42432 if( rc!=SQLITE_OK ){
42433 assert( !MEMDB );
42434 pager_unlock(pPager);
42435 assert( pPager->eState==PAGER_OPEN );
42436 }else{
42437 pPager->eState = PAGER_READER;
42439 return rc;
42443 ** If the reference count has reached zero, rollback any active
42444 ** transaction and unlock the pager.
42446 ** Except, in locking_mode=EXCLUSIVE when there is nothing to in
42447 ** the rollback journal, the unlock is not performed and there is
42448 ** nothing to rollback, so this routine is a no-op.
42450 static void pagerUnlockIfUnused(Pager *pPager){
42451 if( (sqlite3PcacheRefCount(pPager->pPCache)==0) ){
42452 pagerUnlockAndRollback(pPager);
42457 ** Acquire a reference to page number pgno in pager pPager (a page
42458 ** reference has type DbPage*). If the requested reference is
42459 ** successfully obtained, it is copied to *ppPage and SQLITE_OK returned.
42461 ** If the requested page is already in the cache, it is returned.
42462 ** Otherwise, a new page object is allocated and populated with data
42463 ** read from the database file. In some cases, the pcache module may
42464 ** choose not to allocate a new page object and may reuse an existing
42465 ** object with no outstanding references.
42467 ** The extra data appended to a page is always initialized to zeros the
42468 ** first time a page is loaded into memory. If the page requested is
42469 ** already in the cache when this function is called, then the extra
42470 ** data is left as it was when the page object was last used.
42472 ** If the database image is smaller than the requested page or if a
42473 ** non-zero value is passed as the noContent parameter and the
42474 ** requested page is not already stored in the cache, then no
42475 ** actual disk read occurs. In this case the memory image of the
42476 ** page is initialized to all zeros.
42478 ** If noContent is true, it means that we do not care about the contents
42479 ** of the page. This occurs in two seperate scenarios:
42481 ** a) When reading a free-list leaf page from the database, and
42483 ** b) When a savepoint is being rolled back and we need to load
42484 ** a new page into the cache to be filled with the data read
42485 ** from the savepoint journal.
42487 ** If noContent is true, then the data returned is zeroed instead of
42488 ** being read from the database. Additionally, the bits corresponding
42489 ** to pgno in Pager.pInJournal (bitvec of pages already written to the
42490 ** journal file) and the PagerSavepoint.pInSavepoint bitvecs of any open
42491 ** savepoints are set. This means if the page is made writable at any
42492 ** point in the future, using a call to sqlite3PagerWrite(), its contents
42493 ** will not be journaled. This saves IO.
42495 ** The acquisition might fail for several reasons. In all cases,
42496 ** an appropriate error code is returned and *ppPage is set to NULL.
42498 ** See also sqlite3PagerLookup(). Both this routine and Lookup() attempt
42499 ** to find a page in the in-memory cache first. If the page is not already
42500 ** in memory, this routine goes to disk to read it in whereas Lookup()
42501 ** just returns 0. This routine acquires a read-lock the first time it
42502 ** has to go to disk, and could also playback an old journal if necessary.
42503 ** Since Lookup() never goes to disk, it never has to deal with locks
42504 ** or journal files.
42506 SQLITE_PRIVATE int sqlite3PagerAcquire(
42507 Pager *pPager, /* The pager open on the database file */
42508 Pgno pgno, /* Page number to fetch */
42509 DbPage **ppPage, /* Write a pointer to the page here */
42510 int noContent /* Do not bother reading content from disk if true */
42512 int rc;
42513 PgHdr *pPg;
42515 assert( pPager->eState>=PAGER_READER );
42516 assert( assert_pager_state(pPager) );
42518 if( pgno==0 ){
42519 return SQLITE_CORRUPT_BKPT;
42522 /* If the pager is in the error state, return an error immediately.
42523 ** Otherwise, request the page from the PCache layer. */
42524 if( pPager->errCode!=SQLITE_OK ){
42525 rc = pPager->errCode;
42526 }else{
42527 rc = sqlite3PcacheFetch(pPager->pPCache, pgno, 1, ppPage);
42530 if( rc!=SQLITE_OK ){
42531 /* Either the call to sqlite3PcacheFetch() returned an error or the
42532 ** pager was already in the error-state when this function was called.
42533 ** Set pPg to 0 and jump to the exception handler. */
42534 pPg = 0;
42535 goto pager_acquire_err;
42537 assert( (*ppPage)->pgno==pgno );
42538 assert( (*ppPage)->pPager==pPager || (*ppPage)->pPager==0 );
42540 if( (*ppPage)->pPager && !noContent ){
42541 /* In this case the pcache already contains an initialized copy of
42542 ** the page. Return without further ado. */
42543 assert( pgno<=PAGER_MAX_PGNO && pgno!=PAGER_MJ_PGNO(pPager) );
42544 PAGER_INCR(pPager->nHit);
42545 return SQLITE_OK;
42547 }else{
42548 /* The pager cache has created a new page. Its content needs to
42549 ** be initialized. */
42551 PAGER_INCR(pPager->nMiss);
42552 pPg = *ppPage;
42553 pPg->pPager = pPager;
42555 /* The maximum page number is 2^31. Return SQLITE_CORRUPT if a page
42556 ** number greater than this, or the unused locking-page, is requested. */
42557 if( pgno>PAGER_MAX_PGNO || pgno==PAGER_MJ_PGNO(pPager) ){
42558 rc = SQLITE_CORRUPT_BKPT;
42559 goto pager_acquire_err;
42562 if( MEMDB || pPager->dbSize<pgno || noContent || !isOpen(pPager->fd) ){
42563 if( pgno>pPager->mxPgno ){
42564 rc = SQLITE_FULL;
42565 goto pager_acquire_err;
42567 if( noContent ){
42568 /* Failure to set the bits in the InJournal bit-vectors is benign.
42569 ** It merely means that we might do some extra work to journal a
42570 ** page that does not need to be journaled. Nevertheless, be sure
42571 ** to test the case where a malloc error occurs while trying to set
42572 ** a bit in a bit vector.
42574 sqlite3BeginBenignMalloc();
42575 if( pgno<=pPager->dbOrigSize ){
42576 TESTONLY( rc = ) sqlite3BitvecSet(pPager->pInJournal, pgno);
42577 testcase( rc==SQLITE_NOMEM );
42579 TESTONLY( rc = ) addToSavepointBitvecs(pPager, pgno);
42580 testcase( rc==SQLITE_NOMEM );
42581 sqlite3EndBenignMalloc();
42583 memset(pPg->pData, 0, pPager->pageSize);
42584 IOTRACE(("ZERO %p %d\n", pPager, pgno));
42585 }else{
42586 assert( pPg->pPager==pPager );
42587 rc = readDbPage(pPg);
42588 if( rc!=SQLITE_OK ){
42589 goto pager_acquire_err;
42592 pager_set_pagehash(pPg);
42595 return SQLITE_OK;
42597 pager_acquire_err:
42598 assert( rc!=SQLITE_OK );
42599 if( pPg ){
42600 sqlite3PcacheDrop(pPg);
42602 pagerUnlockIfUnused(pPager);
42604 *ppPage = 0;
42605 return rc;
42609 ** Acquire a page if it is already in the in-memory cache. Do
42610 ** not read the page from disk. Return a pointer to the page,
42611 ** or 0 if the page is not in cache.
42613 ** See also sqlite3PagerGet(). The difference between this routine
42614 ** and sqlite3PagerGet() is that _get() will go to the disk and read
42615 ** in the page if the page is not already in cache. This routine
42616 ** returns NULL if the page is not in cache or if a disk I/O error
42617 ** has ever happened.
42619 SQLITE_PRIVATE DbPage *sqlite3PagerLookup(Pager *pPager, Pgno pgno){
42620 PgHdr *pPg = 0;
42621 assert( pPager!=0 );
42622 assert( pgno!=0 );
42623 assert( pPager->pPCache!=0 );
42624 assert( pPager->eState>=PAGER_READER && pPager->eState!=PAGER_ERROR );
42625 sqlite3PcacheFetch(pPager->pPCache, pgno, 0, &pPg);
42626 return pPg;
42630 ** Release a page reference.
42632 ** If the number of references to the page drop to zero, then the
42633 ** page is added to the LRU list. When all references to all pages
42634 ** are released, a rollback occurs and the lock on the database is
42635 ** removed.
42637 SQLITE_PRIVATE void sqlite3PagerUnref(DbPage *pPg){
42638 if( pPg ){
42639 Pager *pPager = pPg->pPager;
42640 sqlite3PcacheRelease(pPg);
42641 pagerUnlockIfUnused(pPager);
42646 ** This function is called at the start of every write transaction.
42647 ** There must already be a RESERVED or EXCLUSIVE lock on the database
42648 ** file when this routine is called.
42650 ** Open the journal file for pager pPager and write a journal header
42651 ** to the start of it. If there are active savepoints, open the sub-journal
42652 ** as well. This function is only used when the journal file is being
42653 ** opened to write a rollback log for a transaction. It is not used
42654 ** when opening a hot journal file to roll it back.
42656 ** If the journal file is already open (as it may be in exclusive mode),
42657 ** then this function just writes a journal header to the start of the
42658 ** already open file.
42660 ** Whether or not the journal file is opened by this function, the
42661 ** Pager.pInJournal bitvec structure is allocated.
42663 ** Return SQLITE_OK if everything is successful. Otherwise, return
42664 ** SQLITE_NOMEM if the attempt to allocate Pager.pInJournal fails, or
42665 ** an IO error code if opening or writing the journal file fails.
42667 static int pager_open_journal(Pager *pPager){
42668 int rc = SQLITE_OK; /* Return code */
42669 sqlite3_vfs * const pVfs = pPager->pVfs; /* Local cache of vfs pointer */
42671 assert( pPager->eState==PAGER_WRITER_LOCKED );
42672 assert( assert_pager_state(pPager) );
42673 assert( pPager->pInJournal==0 );
42675 /* If already in the error state, this function is a no-op. But on
42676 ** the other hand, this routine is never called if we are already in
42677 ** an error state. */
42678 if( NEVER(pPager->errCode) ) return pPager->errCode;
42680 if( !pagerUseWal(pPager) && pPager->journalMode!=PAGER_JOURNALMODE_OFF ){
42681 pPager->pInJournal = sqlite3BitvecCreate(pPager->dbSize);
42682 if( pPager->pInJournal==0 ){
42683 return SQLITE_NOMEM;
42686 /* Open the journal file if it is not already open. */
42687 if( !isOpen(pPager->jfd) ){
42688 if( pPager->journalMode==PAGER_JOURNALMODE_MEMORY ){
42689 sqlite3MemJournalOpen(pPager->jfd);
42690 }else{
42691 const int flags = /* VFS flags to open journal file */
42692 SQLITE_OPEN_READWRITE|SQLITE_OPEN_CREATE|
42693 (pPager->tempFile ?
42694 (SQLITE_OPEN_DELETEONCLOSE|SQLITE_OPEN_TEMP_JOURNAL):
42695 (SQLITE_OPEN_MAIN_JOURNAL)
42697 #ifdef SQLITE_ENABLE_ATOMIC_WRITE
42698 rc = sqlite3JournalOpen(
42699 pVfs, pPager->zJournal, pPager->jfd, flags, jrnlBufferSize(pPager)
42701 #else
42702 rc = sqlite3OsOpen(pVfs, pPager->zJournal, pPager->jfd, flags, 0);
42703 #endif
42705 assert( rc!=SQLITE_OK || isOpen(pPager->jfd) );
42709 /* Write the first journal header to the journal file and open
42710 ** the sub-journal if necessary.
42712 if( rc==SQLITE_OK ){
42713 /* TODO: Check if all of these are really required. */
42714 pPager->nRec = 0;
42715 pPager->journalOff = 0;
42716 pPager->setMaster = 0;
42717 pPager->journalHdr = 0;
42718 rc = writeJournalHdr(pPager);
42722 if( rc!=SQLITE_OK ){
42723 sqlite3BitvecDestroy(pPager->pInJournal);
42724 pPager->pInJournal = 0;
42725 }else{
42726 assert( pPager->eState==PAGER_WRITER_LOCKED );
42727 pPager->eState = PAGER_WRITER_CACHEMOD;
42730 return rc;
42734 ** Begin a write-transaction on the specified pager object. If a
42735 ** write-transaction has already been opened, this function is a no-op.
42737 ** If the exFlag argument is false, then acquire at least a RESERVED
42738 ** lock on the database file. If exFlag is true, then acquire at least
42739 ** an EXCLUSIVE lock. If such a lock is already held, no locking
42740 ** functions need be called.
42742 ** If the subjInMemory argument is non-zero, then any sub-journal opened
42743 ** within this transaction will be opened as an in-memory file. This
42744 ** has no effect if the sub-journal is already opened (as it may be when
42745 ** running in exclusive mode) or if the transaction does not require a
42746 ** sub-journal. If the subjInMemory argument is zero, then any required
42747 ** sub-journal is implemented in-memory if pPager is an in-memory database,
42748 ** or using a temporary file otherwise.
42750 SQLITE_PRIVATE int sqlite3PagerBegin(Pager *pPager, int exFlag, int subjInMemory){
42751 int rc = SQLITE_OK;
42753 if( pPager->errCode ) return pPager->errCode;
42754 assert( pPager->eState>=PAGER_READER && pPager->eState<PAGER_ERROR );
42755 pPager->subjInMemory = (u8)subjInMemory;
42757 if( ALWAYS(pPager->eState==PAGER_READER) ){
42758 assert( pPager->pInJournal==0 );
42760 if( pagerUseWal(pPager) ){
42761 /* If the pager is configured to use locking_mode=exclusive, and an
42762 ** exclusive lock on the database is not already held, obtain it now.
42764 if( pPager->exclusiveMode && sqlite3WalExclusiveMode(pPager->pWal, -1) ){
42765 rc = pagerLockDb(pPager, EXCLUSIVE_LOCK);
42766 if( rc!=SQLITE_OK ){
42767 return rc;
42769 sqlite3WalExclusiveMode(pPager->pWal, 1);
42772 /* Grab the write lock on the log file. If successful, upgrade to
42773 ** PAGER_RESERVED state. Otherwise, return an error code to the caller.
42774 ** The busy-handler is not invoked if another connection already
42775 ** holds the write-lock. If possible, the upper layer will call it.
42777 rc = sqlite3WalBeginWriteTransaction(pPager->pWal);
42778 }else{
42779 /* Obtain a RESERVED lock on the database file. If the exFlag parameter
42780 ** is true, then immediately upgrade this to an EXCLUSIVE lock. The
42781 ** busy-handler callback can be used when upgrading to the EXCLUSIVE
42782 ** lock, but not when obtaining the RESERVED lock.
42784 rc = pagerLockDb(pPager, RESERVED_LOCK);
42785 if( rc==SQLITE_OK && exFlag ){
42786 rc = pager_wait_on_lock(pPager, EXCLUSIVE_LOCK);
42790 if( rc==SQLITE_OK ){
42791 /* Change to WRITER_LOCKED state.
42793 ** WAL mode sets Pager.eState to PAGER_WRITER_LOCKED or CACHEMOD
42794 ** when it has an open transaction, but never to DBMOD or FINISHED.
42795 ** This is because in those states the code to roll back savepoint
42796 ** transactions may copy data from the sub-journal into the database
42797 ** file as well as into the page cache. Which would be incorrect in
42798 ** WAL mode.
42800 pPager->eState = PAGER_WRITER_LOCKED;
42801 pPager->dbHintSize = pPager->dbSize;
42802 pPager->dbFileSize = pPager->dbSize;
42803 pPager->dbOrigSize = pPager->dbSize;
42804 pPager->journalOff = 0;
42807 assert( rc==SQLITE_OK || pPager->eState==PAGER_READER );
42808 assert( rc!=SQLITE_OK || pPager->eState==PAGER_WRITER_LOCKED );
42809 assert( assert_pager_state(pPager) );
42812 PAGERTRACE(("TRANSACTION %d\n", PAGERID(pPager)));
42813 return rc;
42817 ** Mark a single data page as writeable. The page is written into the
42818 ** main journal or sub-journal as required. If the page is written into
42819 ** one of the journals, the corresponding bit is set in the
42820 ** Pager.pInJournal bitvec and the PagerSavepoint.pInSavepoint bitvecs
42821 ** of any open savepoints as appropriate.
42823 static int pager_write(PgHdr *pPg){
42824 void *pData = pPg->pData;
42825 Pager *pPager = pPg->pPager;
42826 int rc = SQLITE_OK;
42828 /* This routine is not called unless a write-transaction has already
42829 ** been started. The journal file may or may not be open at this point.
42830 ** It is never called in the ERROR state.
42832 assert( pPager->eState==PAGER_WRITER_LOCKED
42833 || pPager->eState==PAGER_WRITER_CACHEMOD
42834 || pPager->eState==PAGER_WRITER_DBMOD
42836 assert( assert_pager_state(pPager) );
42838 /* If an error has been previously detected, report the same error
42839 ** again. This should not happen, but the check provides robustness. */
42840 if( NEVER(pPager->errCode) ) return pPager->errCode;
42842 /* Higher-level routines never call this function if database is not
42843 ** writable. But check anyway, just for robustness. */
42844 if( NEVER(pPager->readOnly) ) return SQLITE_PERM;
42846 CHECK_PAGE(pPg);
42848 /* The journal file needs to be opened. Higher level routines have already
42849 ** obtained the necessary locks to begin the write-transaction, but the
42850 ** rollback journal might not yet be open. Open it now if this is the case.
42852 ** This is done before calling sqlite3PcacheMakeDirty() on the page.
42853 ** Otherwise, if it were done after calling sqlite3PcacheMakeDirty(), then
42854 ** an error might occur and the pager would end up in WRITER_LOCKED state
42855 ** with pages marked as dirty in the cache.
42857 if( pPager->eState==PAGER_WRITER_LOCKED ){
42858 rc = pager_open_journal(pPager);
42859 if( rc!=SQLITE_OK ) return rc;
42861 assert( pPager->eState>=PAGER_WRITER_CACHEMOD );
42862 assert( assert_pager_state(pPager) );
42864 /* Mark the page as dirty. If the page has already been written
42865 ** to the journal then we can return right away.
42867 sqlite3PcacheMakeDirty(pPg);
42868 if( pageInJournal(pPg) && !subjRequiresPage(pPg) ){
42869 assert( !pagerUseWal(pPager) );
42870 }else{
42872 /* The transaction journal now exists and we have a RESERVED or an
42873 ** EXCLUSIVE lock on the main database file. Write the current page to
42874 ** the transaction journal if it is not there already.
42876 if( !pageInJournal(pPg) && !pagerUseWal(pPager) ){
42877 assert( pagerUseWal(pPager)==0 );
42878 if( pPg->pgno<=pPager->dbOrigSize && isOpen(pPager->jfd) ){
42879 u32 cksum;
42880 char *pData2;
42881 i64 iOff = pPager->journalOff;
42883 /* We should never write to the journal file the page that
42884 ** contains the database locks. The following assert verifies
42885 ** that we do not. */
42886 assert( pPg->pgno!=PAGER_MJ_PGNO(pPager) );
42888 assert( pPager->journalHdr<=pPager->journalOff );
42889 CODEC2(pPager, pData, pPg->pgno, 7, return SQLITE_NOMEM, pData2);
42890 cksum = pager_cksum(pPager, (u8*)pData2);
42892 /* Even if an IO or diskfull error occurs while journalling the
42893 ** page in the block above, set the need-sync flag for the page.
42894 ** Otherwise, when the transaction is rolled back, the logic in
42895 ** playback_one_page() will think that the page needs to be restored
42896 ** in the database file. And if an IO error occurs while doing so,
42897 ** then corruption may follow.
42899 pPg->flags |= PGHDR_NEED_SYNC;
42901 rc = write32bits(pPager->jfd, iOff, pPg->pgno);
42902 if( rc!=SQLITE_OK ) return rc;
42903 rc = sqlite3OsWrite(pPager->jfd, pData2, pPager->pageSize, iOff+4);
42904 if( rc!=SQLITE_OK ) return rc;
42905 rc = write32bits(pPager->jfd, iOff+pPager->pageSize+4, cksum);
42906 if( rc!=SQLITE_OK ) return rc;
42908 IOTRACE(("JOUT %p %d %lld %d\n", pPager, pPg->pgno,
42909 pPager->journalOff, pPager->pageSize));
42910 PAGER_INCR(sqlite3_pager_writej_count);
42911 PAGERTRACE(("JOURNAL %d page %d needSync=%d hash(%08x)\n",
42912 PAGERID(pPager), pPg->pgno,
42913 ((pPg->flags&PGHDR_NEED_SYNC)?1:0), pager_pagehash(pPg)));
42915 pPager->journalOff += 8 + pPager->pageSize;
42916 pPager->nRec++;
42917 assert( pPager->pInJournal!=0 );
42918 rc = sqlite3BitvecSet(pPager->pInJournal, pPg->pgno);
42919 testcase( rc==SQLITE_NOMEM );
42920 assert( rc==SQLITE_OK || rc==SQLITE_NOMEM );
42921 rc |= addToSavepointBitvecs(pPager, pPg->pgno);
42922 if( rc!=SQLITE_OK ){
42923 assert( rc==SQLITE_NOMEM );
42924 return rc;
42926 }else{
42927 if( pPager->eState!=PAGER_WRITER_DBMOD ){
42928 pPg->flags |= PGHDR_NEED_SYNC;
42930 PAGERTRACE(("APPEND %d page %d needSync=%d\n",
42931 PAGERID(pPager), pPg->pgno,
42932 ((pPg->flags&PGHDR_NEED_SYNC)?1:0)));
42936 /* If the statement journal is open and the page is not in it,
42937 ** then write the current page to the statement journal. Note that
42938 ** the statement journal format differs from the standard journal format
42939 ** in that it omits the checksums and the header.
42941 if( subjRequiresPage(pPg) ){
42942 rc = subjournalPage(pPg);
42946 /* Update the database size and return.
42948 if( pPager->dbSize<pPg->pgno ){
42949 pPager->dbSize = pPg->pgno;
42951 return rc;
42955 ** Mark a data page as writeable. This routine must be called before
42956 ** making changes to a page. The caller must check the return value
42957 ** of this function and be careful not to change any page data unless
42958 ** this routine returns SQLITE_OK.
42960 ** The difference between this function and pager_write() is that this
42961 ** function also deals with the special case where 2 or more pages
42962 ** fit on a single disk sector. In this case all co-resident pages
42963 ** must have been written to the journal file before returning.
42965 ** If an error occurs, SQLITE_NOMEM or an IO error code is returned
42966 ** as appropriate. Otherwise, SQLITE_OK.
42968 SQLITE_PRIVATE int sqlite3PagerWrite(DbPage *pDbPage){
42969 int rc = SQLITE_OK;
42971 PgHdr *pPg = pDbPage;
42972 Pager *pPager = pPg->pPager;
42973 Pgno nPagePerSector = (pPager->sectorSize/pPager->pageSize);
42975 assert( pPager->eState>=PAGER_WRITER_LOCKED );
42976 assert( pPager->eState!=PAGER_ERROR );
42977 assert( assert_pager_state(pPager) );
42979 if( nPagePerSector>1 ){
42980 Pgno nPageCount; /* Total number of pages in database file */
42981 Pgno pg1; /* First page of the sector pPg is located on. */
42982 int nPage = 0; /* Number of pages starting at pg1 to journal */
42983 int ii; /* Loop counter */
42984 int needSync = 0; /* True if any page has PGHDR_NEED_SYNC */
42986 /* Set the doNotSyncSpill flag to 1. This is because we cannot allow
42987 ** a journal header to be written between the pages journaled by
42988 ** this function.
42990 assert( !MEMDB );
42991 assert( pPager->doNotSyncSpill==0 );
42992 pPager->doNotSyncSpill++;
42994 /* This trick assumes that both the page-size and sector-size are
42995 ** an integer power of 2. It sets variable pg1 to the identifier
42996 ** of the first page of the sector pPg is located on.
42998 pg1 = ((pPg->pgno-1) & ~(nPagePerSector-1)) + 1;
43000 nPageCount = pPager->dbSize;
43001 if( pPg->pgno>nPageCount ){
43002 nPage = (pPg->pgno - pg1)+1;
43003 }else if( (pg1+nPagePerSector-1)>nPageCount ){
43004 nPage = nPageCount+1-pg1;
43005 }else{
43006 nPage = nPagePerSector;
43008 assert(nPage>0);
43009 assert(pg1<=pPg->pgno);
43010 assert((pg1+nPage)>pPg->pgno);
43012 for(ii=0; ii<nPage && rc==SQLITE_OK; ii++){
43013 Pgno pg = pg1+ii;
43014 PgHdr *pPage;
43015 if( pg==pPg->pgno || !sqlite3BitvecTest(pPager->pInJournal, pg) ){
43016 if( pg!=PAGER_MJ_PGNO(pPager) ){
43017 rc = sqlite3PagerGet(pPager, pg, &pPage);
43018 if( rc==SQLITE_OK ){
43019 rc = pager_write(pPage);
43020 if( pPage->flags&PGHDR_NEED_SYNC ){
43021 needSync = 1;
43023 sqlite3PagerUnref(pPage);
43026 }else if( (pPage = pager_lookup(pPager, pg))!=0 ){
43027 if( pPage->flags&PGHDR_NEED_SYNC ){
43028 needSync = 1;
43030 sqlite3PagerUnref(pPage);
43034 /* If the PGHDR_NEED_SYNC flag is set for any of the nPage pages
43035 ** starting at pg1, then it needs to be set for all of them. Because
43036 ** writing to any of these nPage pages may damage the others, the
43037 ** journal file must contain sync()ed copies of all of them
43038 ** before any of them can be written out to the database file.
43040 if( rc==SQLITE_OK && needSync ){
43041 assert( !MEMDB );
43042 for(ii=0; ii<nPage; ii++){
43043 PgHdr *pPage = pager_lookup(pPager, pg1+ii);
43044 if( pPage ){
43045 pPage->flags |= PGHDR_NEED_SYNC;
43046 sqlite3PagerUnref(pPage);
43051 assert( pPager->doNotSyncSpill==1 );
43052 pPager->doNotSyncSpill--;
43053 }else{
43054 rc = pager_write(pDbPage);
43056 return rc;
43060 ** Return TRUE if the page given in the argument was previously passed
43061 ** to sqlite3PagerWrite(). In other words, return TRUE if it is ok
43062 ** to change the content of the page.
43064 #ifndef NDEBUG
43065 SQLITE_PRIVATE int sqlite3PagerIswriteable(DbPage *pPg){
43066 return pPg->flags&PGHDR_DIRTY;
43068 #endif
43071 ** A call to this routine tells the pager that it is not necessary to
43072 ** write the information on page pPg back to the disk, even though
43073 ** that page might be marked as dirty. This happens, for example, when
43074 ** the page has been added as a leaf of the freelist and so its
43075 ** content no longer matters.
43077 ** The overlying software layer calls this routine when all of the data
43078 ** on the given page is unused. The pager marks the page as clean so
43079 ** that it does not get written to disk.
43081 ** Tests show that this optimization can quadruple the speed of large
43082 ** DELETE operations.
43084 SQLITE_PRIVATE void sqlite3PagerDontWrite(PgHdr *pPg){
43085 Pager *pPager = pPg->pPager;
43086 if( (pPg->flags&PGHDR_DIRTY) && pPager->nSavepoint==0 ){
43087 PAGERTRACE(("DONT_WRITE page %d of %d\n", pPg->pgno, PAGERID(pPager)));
43088 IOTRACE(("CLEAN %p %d\n", pPager, pPg->pgno))
43089 pPg->flags |= PGHDR_DONT_WRITE;
43090 pager_set_pagehash(pPg);
43095 ** This routine is called to increment the value of the database file
43096 ** change-counter, stored as a 4-byte big-endian integer starting at
43097 ** byte offset 24 of the pager file. The secondary change counter at
43098 ** 92 is also updated, as is the SQLite version number at offset 96.
43100 ** But this only happens if the pPager->changeCountDone flag is false.
43101 ** To avoid excess churning of page 1, the update only happens once.
43102 ** See also the pager_write_changecounter() routine that does an
43103 ** unconditional update of the change counters.
43105 ** If the isDirectMode flag is zero, then this is done by calling
43106 ** sqlite3PagerWrite() on page 1, then modifying the contents of the
43107 ** page data. In this case the file will be updated when the current
43108 ** transaction is committed.
43110 ** The isDirectMode flag may only be non-zero if the library was compiled
43111 ** with the SQLITE_ENABLE_ATOMIC_WRITE macro defined. In this case,
43112 ** if isDirect is non-zero, then the database file is updated directly
43113 ** by writing an updated version of page 1 using a call to the
43114 ** sqlite3OsWrite() function.
43116 static int pager_incr_changecounter(Pager *pPager, int isDirectMode){
43117 int rc = SQLITE_OK;
43119 assert( pPager->eState==PAGER_WRITER_CACHEMOD
43120 || pPager->eState==PAGER_WRITER_DBMOD
43122 assert( assert_pager_state(pPager) );
43124 /* Declare and initialize constant integer 'isDirect'. If the
43125 ** atomic-write optimization is enabled in this build, then isDirect
43126 ** is initialized to the value passed as the isDirectMode parameter
43127 ** to this function. Otherwise, it is always set to zero.
43129 ** The idea is that if the atomic-write optimization is not
43130 ** enabled at compile time, the compiler can omit the tests of
43131 ** 'isDirect' below, as well as the block enclosed in the
43132 ** "if( isDirect )" condition.
43134 #ifndef SQLITE_ENABLE_ATOMIC_WRITE
43135 # define DIRECT_MODE 0
43136 assert( isDirectMode==0 );
43137 UNUSED_PARAMETER(isDirectMode);
43138 #else
43139 # define DIRECT_MODE isDirectMode
43140 #endif
43142 if( !pPager->changeCountDone && pPager->dbSize>0 ){
43143 PgHdr *pPgHdr; /* Reference to page 1 */
43145 assert( !pPager->tempFile && isOpen(pPager->fd) );
43147 /* Open page 1 of the file for writing. */
43148 rc = sqlite3PagerGet(pPager, 1, &pPgHdr);
43149 assert( pPgHdr==0 || rc==SQLITE_OK );
43151 /* If page one was fetched successfully, and this function is not
43152 ** operating in direct-mode, make page 1 writable. When not in
43153 ** direct mode, page 1 is always held in cache and hence the PagerGet()
43154 ** above is always successful - hence the ALWAYS on rc==SQLITE_OK.
43156 if( !DIRECT_MODE && ALWAYS(rc==SQLITE_OK) ){
43157 rc = sqlite3PagerWrite(pPgHdr);
43160 if( rc==SQLITE_OK ){
43161 /* Actually do the update of the change counter */
43162 pager_write_changecounter(pPgHdr);
43164 /* If running in direct mode, write the contents of page 1 to the file. */
43165 if( DIRECT_MODE ){
43166 const void *zBuf;
43167 assert( pPager->dbFileSize>0 );
43168 CODEC2(pPager, pPgHdr->pData, 1, 6, rc=SQLITE_NOMEM, zBuf);
43169 if( rc==SQLITE_OK ){
43170 rc = sqlite3OsWrite(pPager->fd, zBuf, pPager->pageSize, 0);
43172 if( rc==SQLITE_OK ){
43173 pPager->changeCountDone = 1;
43175 }else{
43176 pPager->changeCountDone = 1;
43180 /* Release the page reference. */
43181 sqlite3PagerUnref(pPgHdr);
43183 return rc;
43187 ** Sync the database file to disk. This is a no-op for in-memory databases
43188 ** or pages with the Pager.noSync flag set.
43190 ** If successful, or if called on a pager for which it is a no-op, this
43191 ** function returns SQLITE_OK. Otherwise, an IO error code is returned.
43193 SQLITE_PRIVATE int sqlite3PagerSync(Pager *pPager){
43194 int rc = SQLITE_OK;
43195 if( !pPager->noSync ){
43196 assert( !MEMDB );
43197 rc = sqlite3OsSync(pPager->fd, pPager->syncFlags);
43198 }else if( isOpen(pPager->fd) ){
43199 assert( !MEMDB );
43200 sqlite3OsFileControl(pPager->fd, SQLITE_FCNTL_SYNC_OMITTED, (void *)&rc);
43202 return rc;
43206 ** This function may only be called while a write-transaction is active in
43207 ** rollback. If the connection is in WAL mode, this call is a no-op.
43208 ** Otherwise, if the connection does not already have an EXCLUSIVE lock on
43209 ** the database file, an attempt is made to obtain one.
43211 ** If the EXCLUSIVE lock is already held or the attempt to obtain it is
43212 ** successful, or the connection is in WAL mode, SQLITE_OK is returned.
43213 ** Otherwise, either SQLITE_BUSY or an SQLITE_IOERR_XXX error code is
43214 ** returned.
43216 SQLITE_PRIVATE int sqlite3PagerExclusiveLock(Pager *pPager){
43217 int rc = SQLITE_OK;
43218 assert( pPager->eState==PAGER_WRITER_CACHEMOD
43219 || pPager->eState==PAGER_WRITER_DBMOD
43220 || pPager->eState==PAGER_WRITER_LOCKED
43222 assert( assert_pager_state(pPager) );
43223 if( 0==pagerUseWal(pPager) ){
43224 rc = pager_wait_on_lock(pPager, EXCLUSIVE_LOCK);
43226 return rc;
43230 ** Sync the database file for the pager pPager. zMaster points to the name
43231 ** of a master journal file that should be written into the individual
43232 ** journal file. zMaster may be NULL, which is interpreted as no master
43233 ** journal (a single database transaction).
43235 ** This routine ensures that:
43237 ** * The database file change-counter is updated,
43238 ** * the journal is synced (unless the atomic-write optimization is used),
43239 ** * all dirty pages are written to the database file,
43240 ** * the database file is truncated (if required), and
43241 ** * the database file synced.
43243 ** The only thing that remains to commit the transaction is to finalize
43244 ** (delete, truncate or zero the first part of) the journal file (or
43245 ** delete the master journal file if specified).
43247 ** Note that if zMaster==NULL, this does not overwrite a previous value
43248 ** passed to an sqlite3PagerCommitPhaseOne() call.
43250 ** If the final parameter - noSync - is true, then the database file itself
43251 ** is not synced. The caller must call sqlite3PagerSync() directly to
43252 ** sync the database file before calling CommitPhaseTwo() to delete the
43253 ** journal file in this case.
43255 SQLITE_PRIVATE int sqlite3PagerCommitPhaseOne(
43256 Pager *pPager, /* Pager object */
43257 const char *zMaster, /* If not NULL, the master journal name */
43258 int noSync /* True to omit the xSync on the db file */
43260 int rc = SQLITE_OK; /* Return code */
43262 assert( pPager->eState==PAGER_WRITER_LOCKED
43263 || pPager->eState==PAGER_WRITER_CACHEMOD
43264 || pPager->eState==PAGER_WRITER_DBMOD
43265 || pPager->eState==PAGER_ERROR
43267 assert( assert_pager_state(pPager) );
43269 /* If a prior error occurred, report that error again. */
43270 if( NEVER(pPager->errCode) ) return pPager->errCode;
43272 PAGERTRACE(("DATABASE SYNC: File=%s zMaster=%s nSize=%d\n",
43273 pPager->zFilename, zMaster, pPager->dbSize));
43275 /* If no database changes have been made, return early. */
43276 if( pPager->eState<PAGER_WRITER_CACHEMOD ) return SQLITE_OK;
43278 if( MEMDB ){
43279 /* If this is an in-memory db, or no pages have been written to, or this
43280 ** function has already been called, it is mostly a no-op. However, any
43281 ** backup in progress needs to be restarted.
43283 sqlite3BackupRestart(pPager->pBackup);
43284 }else{
43285 if( pagerUseWal(pPager) ){
43286 PgHdr *pList = sqlite3PcacheDirtyList(pPager->pPCache);
43287 PgHdr *pPageOne = 0;
43288 if( pList==0 ){
43289 /* Must have at least one page for the WAL commit flag.
43290 ** Ticket [2d1a5c67dfc2363e44f29d9bbd57f] 2011-05-18 */
43291 rc = sqlite3PagerGet(pPager, 1, &pPageOne);
43292 pList = pPageOne;
43293 pList->pDirty = 0;
43295 assert( rc==SQLITE_OK );
43296 if( ALWAYS(pList) ){
43297 rc = pagerWalFrames(pPager, pList, pPager->dbSize, 1,
43298 (pPager->fullSync ? pPager->syncFlags : 0)
43301 sqlite3PagerUnref(pPageOne);
43302 if( rc==SQLITE_OK ){
43303 sqlite3PcacheCleanAll(pPager->pPCache);
43305 }else{
43306 /* The following block updates the change-counter. Exactly how it
43307 ** does this depends on whether or not the atomic-update optimization
43308 ** was enabled at compile time, and if this transaction meets the
43309 ** runtime criteria to use the operation:
43311 ** * The file-system supports the atomic-write property for
43312 ** blocks of size page-size, and
43313 ** * This commit is not part of a multi-file transaction, and
43314 ** * Exactly one page has been modified and store in the journal file.
43316 ** If the optimization was not enabled at compile time, then the
43317 ** pager_incr_changecounter() function is called to update the change
43318 ** counter in 'indirect-mode'. If the optimization is compiled in but
43319 ** is not applicable to this transaction, call sqlite3JournalCreate()
43320 ** to make sure the journal file has actually been created, then call
43321 ** pager_incr_changecounter() to update the change-counter in indirect
43322 ** mode.
43324 ** Otherwise, if the optimization is both enabled and applicable,
43325 ** then call pager_incr_changecounter() to update the change-counter
43326 ** in 'direct' mode. In this case the journal file will never be
43327 ** created for this transaction.
43329 #ifdef SQLITE_ENABLE_ATOMIC_WRITE
43330 PgHdr *pPg;
43331 assert( isOpen(pPager->jfd)
43332 || pPager->journalMode==PAGER_JOURNALMODE_OFF
43333 || pPager->journalMode==PAGER_JOURNALMODE_WAL
43335 if( !zMaster && isOpen(pPager->jfd)
43336 && pPager->journalOff==jrnlBufferSize(pPager)
43337 && pPager->dbSize>=pPager->dbOrigSize
43338 && (0==(pPg = sqlite3PcacheDirtyList(pPager->pPCache)) || 0==pPg->pDirty)
43340 /* Update the db file change counter via the direct-write method. The
43341 ** following call will modify the in-memory representation of page 1
43342 ** to include the updated change counter and then write page 1
43343 ** directly to the database file. Because of the atomic-write
43344 ** property of the host file-system, this is safe.
43346 rc = pager_incr_changecounter(pPager, 1);
43347 }else{
43348 rc = sqlite3JournalCreate(pPager->jfd);
43349 if( rc==SQLITE_OK ){
43350 rc = pager_incr_changecounter(pPager, 0);
43353 #else
43354 rc = pager_incr_changecounter(pPager, 0);
43355 #endif
43356 if( rc!=SQLITE_OK ) goto commit_phase_one_exit;
43358 /* If this transaction has made the database smaller, then all pages
43359 ** being discarded by the truncation must be written to the journal
43360 ** file. This can only happen in auto-vacuum mode.
43362 ** Before reading the pages with page numbers larger than the
43363 ** current value of Pager.dbSize, set dbSize back to the value
43364 ** that it took at the start of the transaction. Otherwise, the
43365 ** calls to sqlite3PagerGet() return zeroed pages instead of
43366 ** reading data from the database file.
43368 #ifndef SQLITE_OMIT_AUTOVACUUM
43369 if( pPager->dbSize<pPager->dbOrigSize
43370 && pPager->journalMode!=PAGER_JOURNALMODE_OFF
43372 Pgno i; /* Iterator variable */
43373 const Pgno iSkip = PAGER_MJ_PGNO(pPager); /* Pending lock page */
43374 const Pgno dbSize = pPager->dbSize; /* Database image size */
43375 pPager->dbSize = pPager->dbOrigSize;
43376 for( i=dbSize+1; i<=pPager->dbOrigSize; i++ ){
43377 if( !sqlite3BitvecTest(pPager->pInJournal, i) && i!=iSkip ){
43378 PgHdr *pPage; /* Page to journal */
43379 rc = sqlite3PagerGet(pPager, i, &pPage);
43380 if( rc!=SQLITE_OK ) goto commit_phase_one_exit;
43381 rc = sqlite3PagerWrite(pPage);
43382 sqlite3PagerUnref(pPage);
43383 if( rc!=SQLITE_OK ) goto commit_phase_one_exit;
43386 pPager->dbSize = dbSize;
43388 #endif
43390 /* Write the master journal name into the journal file. If a master
43391 ** journal file name has already been written to the journal file,
43392 ** or if zMaster is NULL (no master journal), then this call is a no-op.
43394 rc = writeMasterJournal(pPager, zMaster);
43395 if( rc!=SQLITE_OK ) goto commit_phase_one_exit;
43397 /* Sync the journal file and write all dirty pages to the database.
43398 ** If the atomic-update optimization is being used, this sync will not
43399 ** create the journal file or perform any real IO.
43401 ** Because the change-counter page was just modified, unless the
43402 ** atomic-update optimization is used it is almost certain that the
43403 ** journal requires a sync here. However, in locking_mode=exclusive
43404 ** on a system under memory pressure it is just possible that this is
43405 ** not the case. In this case it is likely enough that the redundant
43406 ** xSync() call will be changed to a no-op by the OS anyhow.
43408 rc = syncJournal(pPager, 0);
43409 if( rc!=SQLITE_OK ) goto commit_phase_one_exit;
43411 rc = pager_write_pagelist(pPager,sqlite3PcacheDirtyList(pPager->pPCache));
43412 if( rc!=SQLITE_OK ){
43413 assert( rc!=SQLITE_IOERR_BLOCKED );
43414 goto commit_phase_one_exit;
43416 sqlite3PcacheCleanAll(pPager->pPCache);
43418 /* If the file on disk is not the same size as the database image,
43419 ** then use pager_truncate to grow or shrink the file here.
43421 if( pPager->dbSize!=pPager->dbFileSize ){
43422 Pgno nNew = pPager->dbSize - (pPager->dbSize==PAGER_MJ_PGNO(pPager));
43423 assert( pPager->eState==PAGER_WRITER_DBMOD );
43424 rc = pager_truncate(pPager, nNew);
43425 if( rc!=SQLITE_OK ) goto commit_phase_one_exit;
43428 /* Finally, sync the database file. */
43429 if( !noSync ){
43430 rc = sqlite3PagerSync(pPager);
43432 IOTRACE(("DBSYNC %p\n", pPager))
43436 commit_phase_one_exit:
43437 if( rc==SQLITE_OK && !pagerUseWal(pPager) ){
43438 pPager->eState = PAGER_WRITER_FINISHED;
43440 return rc;
43445 ** When this function is called, the database file has been completely
43446 ** updated to reflect the changes made by the current transaction and
43447 ** synced to disk. The journal file still exists in the file-system
43448 ** though, and if a failure occurs at this point it will eventually
43449 ** be used as a hot-journal and the current transaction rolled back.
43451 ** This function finalizes the journal file, either by deleting,
43452 ** truncating or partially zeroing it, so that it cannot be used
43453 ** for hot-journal rollback. Once this is done the transaction is
43454 ** irrevocably committed.
43456 ** If an error occurs, an IO error code is returned and the pager
43457 ** moves into the error state. Otherwise, SQLITE_OK is returned.
43459 SQLITE_PRIVATE int sqlite3PagerCommitPhaseTwo(Pager *pPager){
43460 int rc = SQLITE_OK; /* Return code */
43462 /* This routine should not be called if a prior error has occurred.
43463 ** But if (due to a coding error elsewhere in the system) it does get
43464 ** called, just return the same error code without doing anything. */
43465 if( NEVER(pPager->errCode) ) return pPager->errCode;
43467 assert( pPager->eState==PAGER_WRITER_LOCKED
43468 || pPager->eState==PAGER_WRITER_FINISHED
43469 || (pagerUseWal(pPager) && pPager->eState==PAGER_WRITER_CACHEMOD)
43471 assert( assert_pager_state(pPager) );
43473 /* An optimization. If the database was not actually modified during
43474 ** this transaction, the pager is running in exclusive-mode and is
43475 ** using persistent journals, then this function is a no-op.
43477 ** The start of the journal file currently contains a single journal
43478 ** header with the nRec field set to 0. If such a journal is used as
43479 ** a hot-journal during hot-journal rollback, 0 changes will be made
43480 ** to the database file. So there is no need to zero the journal
43481 ** header. Since the pager is in exclusive mode, there is no need
43482 ** to drop any locks either.
43484 if( pPager->eState==PAGER_WRITER_LOCKED
43485 && pPager->exclusiveMode
43486 && pPager->journalMode==PAGER_JOURNALMODE_PERSIST
43488 assert( pPager->journalOff==JOURNAL_HDR_SZ(pPager) || !pPager->journalOff );
43489 pPager->eState = PAGER_READER;
43490 return SQLITE_OK;
43493 PAGERTRACE(("COMMIT %d\n", PAGERID(pPager)));
43494 rc = pager_end_transaction(pPager, pPager->setMaster);
43495 return pager_error(pPager, rc);
43499 ** If a write transaction is open, then all changes made within the
43500 ** transaction are reverted and the current write-transaction is closed.
43501 ** The pager falls back to PAGER_READER state if successful, or PAGER_ERROR
43502 ** state if an error occurs.
43504 ** If the pager is already in PAGER_ERROR state when this function is called,
43505 ** it returns Pager.errCode immediately. No work is performed in this case.
43507 ** Otherwise, in rollback mode, this function performs two functions:
43509 ** 1) It rolls back the journal file, restoring all database file and
43510 ** in-memory cache pages to the state they were in when the transaction
43511 ** was opened, and
43513 ** 2) It finalizes the journal file, so that it is not used for hot
43514 ** rollback at any point in the future.
43516 ** Finalization of the journal file (task 2) is only performed if the
43517 ** rollback is successful.
43519 ** In WAL mode, all cache-entries containing data modified within the
43520 ** current transaction are either expelled from the cache or reverted to
43521 ** their pre-transaction state by re-reading data from the database or
43522 ** WAL files. The WAL transaction is then closed.
43524 SQLITE_PRIVATE int sqlite3PagerRollback(Pager *pPager){
43525 int rc = SQLITE_OK; /* Return code */
43526 PAGERTRACE(("ROLLBACK %d\n", PAGERID(pPager)));
43528 /* PagerRollback() is a no-op if called in READER or OPEN state. If
43529 ** the pager is already in the ERROR state, the rollback is not
43530 ** attempted here. Instead, the error code is returned to the caller.
43532 assert( assert_pager_state(pPager) );
43533 if( pPager->eState==PAGER_ERROR ) return pPager->errCode;
43534 if( pPager->eState<=PAGER_READER ) return SQLITE_OK;
43536 if( pagerUseWal(pPager) ){
43537 int rc2;
43538 rc = sqlite3PagerSavepoint(pPager, SAVEPOINT_ROLLBACK, -1);
43539 rc2 = pager_end_transaction(pPager, pPager->setMaster);
43540 if( rc==SQLITE_OK ) rc = rc2;
43541 }else if( !isOpen(pPager->jfd) || pPager->eState==PAGER_WRITER_LOCKED ){
43542 int eState = pPager->eState;
43543 rc = pager_end_transaction(pPager, 0);
43544 if( !MEMDB && eState>PAGER_WRITER_LOCKED ){
43545 /* This can happen using journal_mode=off. Move the pager to the error
43546 ** state to indicate that the contents of the cache may not be trusted.
43547 ** Any active readers will get SQLITE_ABORT.
43549 pPager->errCode = SQLITE_ABORT;
43550 pPager->eState = PAGER_ERROR;
43551 return rc;
43553 }else{
43554 rc = pager_playback(pPager, 0);
43557 assert( pPager->eState==PAGER_READER || rc!=SQLITE_OK );
43558 assert( rc==SQLITE_OK || rc==SQLITE_FULL || (rc&0xFF)==SQLITE_IOERR );
43560 /* If an error occurs during a ROLLBACK, we can no longer trust the pager
43561 ** cache. So call pager_error() on the way out to make any error persistent.
43563 return pager_error(pPager, rc);
43567 ** Return TRUE if the database file is opened read-only. Return FALSE
43568 ** if the database is (in theory) writable.
43570 SQLITE_PRIVATE u8 sqlite3PagerIsreadonly(Pager *pPager){
43571 return pPager->readOnly;
43575 ** Return the number of references to the pager.
43577 SQLITE_PRIVATE int sqlite3PagerRefcount(Pager *pPager){
43578 return sqlite3PcacheRefCount(pPager->pPCache);
43582 ** Return the approximate number of bytes of memory currently
43583 ** used by the pager and its associated cache.
43585 SQLITE_PRIVATE int sqlite3PagerMemUsed(Pager *pPager){
43586 int perPageSize = pPager->pageSize + pPager->nExtra + sizeof(PgHdr)
43587 + 5*sizeof(void*);
43588 return perPageSize*sqlite3PcachePagecount(pPager->pPCache)
43589 + sqlite3MallocSize(pPager)
43590 + pPager->pageSize;
43594 ** Return the number of references to the specified page.
43596 SQLITE_PRIVATE int sqlite3PagerPageRefcount(DbPage *pPage){
43597 return sqlite3PcachePageRefcount(pPage);
43600 #ifdef SQLITE_TEST
43602 ** This routine is used for testing and analysis only.
43604 SQLITE_PRIVATE int *sqlite3PagerStats(Pager *pPager){
43605 static int a[11];
43606 a[0] = sqlite3PcacheRefCount(pPager->pPCache);
43607 a[1] = sqlite3PcachePagecount(pPager->pPCache);
43608 a[2] = sqlite3PcacheGetCachesize(pPager->pPCache);
43609 a[3] = pPager->eState==PAGER_OPEN ? -1 : (int) pPager->dbSize;
43610 a[4] = pPager->eState;
43611 a[5] = pPager->errCode;
43612 a[6] = pPager->nHit;
43613 a[7] = pPager->nMiss;
43614 a[8] = 0; /* Used to be pPager->nOvfl */
43615 a[9] = pPager->nRead;
43616 a[10] = pPager->nWrite;
43617 return a;
43619 #endif
43622 ** Return true if this is an in-memory pager.
43624 SQLITE_PRIVATE int sqlite3PagerIsMemdb(Pager *pPager){
43625 return MEMDB;
43629 ** Check that there are at least nSavepoint savepoints open. If there are
43630 ** currently less than nSavepoints open, then open one or more savepoints
43631 ** to make up the difference. If the number of savepoints is already
43632 ** equal to nSavepoint, then this function is a no-op.
43634 ** If a memory allocation fails, SQLITE_NOMEM is returned. If an error
43635 ** occurs while opening the sub-journal file, then an IO error code is
43636 ** returned. Otherwise, SQLITE_OK.
43638 SQLITE_PRIVATE int sqlite3PagerOpenSavepoint(Pager *pPager, int nSavepoint){
43639 int rc = SQLITE_OK; /* Return code */
43640 int nCurrent = pPager->nSavepoint; /* Current number of savepoints */
43642 assert( pPager->eState>=PAGER_WRITER_LOCKED );
43643 assert( assert_pager_state(pPager) );
43645 if( nSavepoint>nCurrent && pPager->useJournal ){
43646 int ii; /* Iterator variable */
43647 PagerSavepoint *aNew; /* New Pager.aSavepoint array */
43649 /* Grow the Pager.aSavepoint array using realloc(). Return SQLITE_NOMEM
43650 ** if the allocation fails. Otherwise, zero the new portion in case a
43651 ** malloc failure occurs while populating it in the for(...) loop below.
43653 aNew = (PagerSavepoint *)sqlite3Realloc(
43654 pPager->aSavepoint, sizeof(PagerSavepoint)*nSavepoint
43656 if( !aNew ){
43657 return SQLITE_NOMEM;
43659 memset(&aNew[nCurrent], 0, (nSavepoint-nCurrent) * sizeof(PagerSavepoint));
43660 pPager->aSavepoint = aNew;
43662 /* Populate the PagerSavepoint structures just allocated. */
43663 for(ii=nCurrent; ii<nSavepoint; ii++){
43664 aNew[ii].nOrig = pPager->dbSize;
43665 if( isOpen(pPager->jfd) && pPager->journalOff>0 ){
43666 aNew[ii].iOffset = pPager->journalOff;
43667 }else{
43668 aNew[ii].iOffset = JOURNAL_HDR_SZ(pPager);
43670 aNew[ii].iSubRec = pPager->nSubRec;
43671 aNew[ii].pInSavepoint = sqlite3BitvecCreate(pPager->dbSize);
43672 if( !aNew[ii].pInSavepoint ){
43673 return SQLITE_NOMEM;
43675 if( pagerUseWal(pPager) ){
43676 sqlite3WalSavepoint(pPager->pWal, aNew[ii].aWalData);
43678 pPager->nSavepoint = ii+1;
43680 assert( pPager->nSavepoint==nSavepoint );
43681 assertTruncateConstraint(pPager);
43684 return rc;
43688 ** This function is called to rollback or release (commit) a savepoint.
43689 ** The savepoint to release or rollback need not be the most recently
43690 ** created savepoint.
43692 ** Parameter op is always either SAVEPOINT_ROLLBACK or SAVEPOINT_RELEASE.
43693 ** If it is SAVEPOINT_RELEASE, then release and destroy the savepoint with
43694 ** index iSavepoint. If it is SAVEPOINT_ROLLBACK, then rollback all changes
43695 ** that have occurred since the specified savepoint was created.
43697 ** The savepoint to rollback or release is identified by parameter
43698 ** iSavepoint. A value of 0 means to operate on the outermost savepoint
43699 ** (the first created). A value of (Pager.nSavepoint-1) means operate
43700 ** on the most recently created savepoint. If iSavepoint is greater than
43701 ** (Pager.nSavepoint-1), then this function is a no-op.
43703 ** If a negative value is passed to this function, then the current
43704 ** transaction is rolled back. This is different to calling
43705 ** sqlite3PagerRollback() because this function does not terminate
43706 ** the transaction or unlock the database, it just restores the
43707 ** contents of the database to its original state.
43709 ** In any case, all savepoints with an index greater than iSavepoint
43710 ** are destroyed. If this is a release operation (op==SAVEPOINT_RELEASE),
43711 ** then savepoint iSavepoint is also destroyed.
43713 ** This function may return SQLITE_NOMEM if a memory allocation fails,
43714 ** or an IO error code if an IO error occurs while rolling back a
43715 ** savepoint. If no errors occur, SQLITE_OK is returned.
43717 SQLITE_PRIVATE int sqlite3PagerSavepoint(Pager *pPager, int op, int iSavepoint){
43718 int rc = pPager->errCode; /* Return code */
43720 assert( op==SAVEPOINT_RELEASE || op==SAVEPOINT_ROLLBACK );
43721 assert( iSavepoint>=0 || op==SAVEPOINT_ROLLBACK );
43723 if( rc==SQLITE_OK && iSavepoint<pPager->nSavepoint ){
43724 int ii; /* Iterator variable */
43725 int nNew; /* Number of remaining savepoints after this op. */
43727 /* Figure out how many savepoints will still be active after this
43728 ** operation. Store this value in nNew. Then free resources associated
43729 ** with any savepoints that are destroyed by this operation.
43731 nNew = iSavepoint + (( op==SAVEPOINT_RELEASE ) ? 0 : 1);
43732 for(ii=nNew; ii<pPager->nSavepoint; ii++){
43733 sqlite3BitvecDestroy(pPager->aSavepoint[ii].pInSavepoint);
43735 pPager->nSavepoint = nNew;
43737 /* If this is a release of the outermost savepoint, truncate
43738 ** the sub-journal to zero bytes in size. */
43739 if( op==SAVEPOINT_RELEASE ){
43740 if( nNew==0 && isOpen(pPager->sjfd) ){
43741 /* Only truncate if it is an in-memory sub-journal. */
43742 if( sqlite3IsMemJournal(pPager->sjfd) ){
43743 rc = sqlite3OsTruncate(pPager->sjfd, 0);
43744 assert( rc==SQLITE_OK );
43746 pPager->nSubRec = 0;
43749 /* Else this is a rollback operation, playback the specified savepoint.
43750 ** If this is a temp-file, it is possible that the journal file has
43751 ** not yet been opened. In this case there have been no changes to
43752 ** the database file, so the playback operation can be skipped.
43754 else if( pagerUseWal(pPager) || isOpen(pPager->jfd) ){
43755 PagerSavepoint *pSavepoint = (nNew==0)?0:&pPager->aSavepoint[nNew-1];
43756 rc = pagerPlaybackSavepoint(pPager, pSavepoint);
43757 assert(rc!=SQLITE_DONE);
43761 return rc;
43765 ** Return the full pathname of the database file.
43767 SQLITE_PRIVATE const char *sqlite3PagerFilename(Pager *pPager){
43768 return pPager->zFilename;
43772 ** Return the VFS structure for the pager.
43774 SQLITE_PRIVATE const sqlite3_vfs *sqlite3PagerVfs(Pager *pPager){
43775 return pPager->pVfs;
43779 ** Return the file handle for the database file associated
43780 ** with the pager. This might return NULL if the file has
43781 ** not yet been opened.
43783 SQLITE_PRIVATE sqlite3_file *sqlite3PagerFile(Pager *pPager){
43784 return pPager->fd;
43788 ** Return the full pathname of the journal file.
43790 SQLITE_PRIVATE const char *sqlite3PagerJournalname(Pager *pPager){
43791 return pPager->zJournal;
43795 ** Return true if fsync() calls are disabled for this pager. Return FALSE
43796 ** if fsync()s are executed normally.
43798 SQLITE_PRIVATE int sqlite3PagerNosync(Pager *pPager){
43799 return pPager->noSync;
43802 #ifdef SQLITE_HAS_CODEC
43804 ** Set or retrieve the codec for this pager
43806 SQLITE_PRIVATE void sqlite3PagerSetCodec(
43807 Pager *pPager,
43808 void *(*xCodec)(void*,void*,Pgno,int),
43809 void (*xCodecSizeChng)(void*,int,int),
43810 void (*xCodecFree)(void*),
43811 void *pCodec
43813 if( pPager->xCodecFree ) pPager->xCodecFree(pPager->pCodec);
43814 pPager->xCodec = pPager->memDb ? 0 : xCodec;
43815 pPager->xCodecSizeChng = xCodecSizeChng;
43816 pPager->xCodecFree = xCodecFree;
43817 pPager->pCodec = pCodec;
43818 pagerReportSize(pPager);
43820 SQLITE_PRIVATE void *sqlite3PagerGetCodec(Pager *pPager){
43821 return pPager->pCodec;
43823 #endif
43825 #ifndef SQLITE_OMIT_AUTOVACUUM
43827 ** Move the page pPg to location pgno in the file.
43829 ** There must be no references to the page previously located at
43830 ** pgno (which we call pPgOld) though that page is allowed to be
43831 ** in cache. If the page previously located at pgno is not already
43832 ** in the rollback journal, it is not put there by by this routine.
43834 ** References to the page pPg remain valid. Updating any
43835 ** meta-data associated with pPg (i.e. data stored in the nExtra bytes
43836 ** allocated along with the page) is the responsibility of the caller.
43838 ** A transaction must be active when this routine is called. It used to be
43839 ** required that a statement transaction was not active, but this restriction
43840 ** has been removed (CREATE INDEX needs to move a page when a statement
43841 ** transaction is active).
43843 ** If the fourth argument, isCommit, is non-zero, then this page is being
43844 ** moved as part of a database reorganization just before the transaction
43845 ** is being committed. In this case, it is guaranteed that the database page
43846 ** pPg refers to will not be written to again within this transaction.
43848 ** This function may return SQLITE_NOMEM or an IO error code if an error
43849 ** occurs. Otherwise, it returns SQLITE_OK.
43851 SQLITE_PRIVATE int sqlite3PagerMovepage(Pager *pPager, DbPage *pPg, Pgno pgno, int isCommit){
43852 PgHdr *pPgOld; /* The page being overwritten. */
43853 Pgno needSyncPgno = 0; /* Old value of pPg->pgno, if sync is required */
43854 int rc; /* Return code */
43855 Pgno origPgno; /* The original page number */
43857 assert( pPg->nRef>0 );
43858 assert( pPager->eState==PAGER_WRITER_CACHEMOD
43859 || pPager->eState==PAGER_WRITER_DBMOD
43861 assert( assert_pager_state(pPager) );
43863 /* In order to be able to rollback, an in-memory database must journal
43864 ** the page we are moving from.
43866 if( MEMDB ){
43867 rc = sqlite3PagerWrite(pPg);
43868 if( rc ) return rc;
43871 /* If the page being moved is dirty and has not been saved by the latest
43872 ** savepoint, then save the current contents of the page into the
43873 ** sub-journal now. This is required to handle the following scenario:
43875 ** BEGIN;
43876 ** <journal page X, then modify it in memory>
43877 ** SAVEPOINT one;
43878 ** <Move page X to location Y>
43879 ** ROLLBACK TO one;
43881 ** If page X were not written to the sub-journal here, it would not
43882 ** be possible to restore its contents when the "ROLLBACK TO one"
43883 ** statement were is processed.
43885 ** subjournalPage() may need to allocate space to store pPg->pgno into
43886 ** one or more savepoint bitvecs. This is the reason this function
43887 ** may return SQLITE_NOMEM.
43889 if( pPg->flags&PGHDR_DIRTY
43890 && subjRequiresPage(pPg)
43891 && SQLITE_OK!=(rc = subjournalPage(pPg))
43893 return rc;
43896 PAGERTRACE(("MOVE %d page %d (needSync=%d) moves to %d\n",
43897 PAGERID(pPager), pPg->pgno, (pPg->flags&PGHDR_NEED_SYNC)?1:0, pgno));
43898 IOTRACE(("MOVE %p %d %d\n", pPager, pPg->pgno, pgno))
43900 /* If the journal needs to be sync()ed before page pPg->pgno can
43901 ** be written to, store pPg->pgno in local variable needSyncPgno.
43903 ** If the isCommit flag is set, there is no need to remember that
43904 ** the journal needs to be sync()ed before database page pPg->pgno
43905 ** can be written to. The caller has already promised not to write to it.
43907 if( (pPg->flags&PGHDR_NEED_SYNC) && !isCommit ){
43908 needSyncPgno = pPg->pgno;
43909 assert( pageInJournal(pPg) || pPg->pgno>pPager->dbOrigSize );
43910 assert( pPg->flags&PGHDR_DIRTY );
43913 /* If the cache contains a page with page-number pgno, remove it
43914 ** from its hash chain. Also, if the PGHDR_NEED_SYNC flag was set for
43915 ** page pgno before the 'move' operation, it needs to be retained
43916 ** for the page moved there.
43918 pPg->flags &= ~PGHDR_NEED_SYNC;
43919 pPgOld = pager_lookup(pPager, pgno);
43920 assert( !pPgOld || pPgOld->nRef==1 );
43921 if( pPgOld ){
43922 pPg->flags |= (pPgOld->flags&PGHDR_NEED_SYNC);
43923 if( MEMDB ){
43924 /* Do not discard pages from an in-memory database since we might
43925 ** need to rollback later. Just move the page out of the way. */
43926 sqlite3PcacheMove(pPgOld, pPager->dbSize+1);
43927 }else{
43928 sqlite3PcacheDrop(pPgOld);
43932 origPgno = pPg->pgno;
43933 sqlite3PcacheMove(pPg, pgno);
43934 sqlite3PcacheMakeDirty(pPg);
43936 /* For an in-memory database, make sure the original page continues
43937 ** to exist, in case the transaction needs to roll back. Use pPgOld
43938 ** as the original page since it has already been allocated.
43940 if( MEMDB ){
43941 assert( pPgOld );
43942 sqlite3PcacheMove(pPgOld, origPgno);
43943 sqlite3PagerUnref(pPgOld);
43946 if( needSyncPgno ){
43947 /* If needSyncPgno is non-zero, then the journal file needs to be
43948 ** sync()ed before any data is written to database file page needSyncPgno.
43949 ** Currently, no such page exists in the page-cache and the
43950 ** "is journaled" bitvec flag has been set. This needs to be remedied by
43951 ** loading the page into the pager-cache and setting the PGHDR_NEED_SYNC
43952 ** flag.
43954 ** If the attempt to load the page into the page-cache fails, (due
43955 ** to a malloc() or IO failure), clear the bit in the pInJournal[]
43956 ** array. Otherwise, if the page is loaded and written again in
43957 ** this transaction, it may be written to the database file before
43958 ** it is synced into the journal file. This way, it may end up in
43959 ** the journal file twice, but that is not a problem.
43961 PgHdr *pPgHdr;
43962 rc = sqlite3PagerGet(pPager, needSyncPgno, &pPgHdr);
43963 if( rc!=SQLITE_OK ){
43964 if( needSyncPgno<=pPager->dbOrigSize ){
43965 assert( pPager->pTmpSpace!=0 );
43966 sqlite3BitvecClear(pPager->pInJournal, needSyncPgno, pPager->pTmpSpace);
43968 return rc;
43970 pPgHdr->flags |= PGHDR_NEED_SYNC;
43971 sqlite3PcacheMakeDirty(pPgHdr);
43972 sqlite3PagerUnref(pPgHdr);
43975 return SQLITE_OK;
43977 #endif
43980 ** Return a pointer to the data for the specified page.
43982 SQLITE_PRIVATE void *sqlite3PagerGetData(DbPage *pPg){
43983 assert( pPg->nRef>0 || pPg->pPager->memDb );
43984 return pPg->pData;
43988 ** Return a pointer to the Pager.nExtra bytes of "extra" space
43989 ** allocated along with the specified page.
43991 SQLITE_PRIVATE void *sqlite3PagerGetExtra(DbPage *pPg){
43992 return pPg->pExtra;
43996 ** Get/set the locking-mode for this pager. Parameter eMode must be one
43997 ** of PAGER_LOCKINGMODE_QUERY, PAGER_LOCKINGMODE_NORMAL or
43998 ** PAGER_LOCKINGMODE_EXCLUSIVE. If the parameter is not _QUERY, then
43999 ** the locking-mode is set to the value specified.
44001 ** The returned value is either PAGER_LOCKINGMODE_NORMAL or
44002 ** PAGER_LOCKINGMODE_EXCLUSIVE, indicating the current (possibly updated)
44003 ** locking-mode.
44005 SQLITE_PRIVATE int sqlite3PagerLockingMode(Pager *pPager, int eMode){
44006 assert( eMode==PAGER_LOCKINGMODE_QUERY
44007 || eMode==PAGER_LOCKINGMODE_NORMAL
44008 || eMode==PAGER_LOCKINGMODE_EXCLUSIVE );
44009 assert( PAGER_LOCKINGMODE_QUERY<0 );
44010 assert( PAGER_LOCKINGMODE_NORMAL>=0 && PAGER_LOCKINGMODE_EXCLUSIVE>=0 );
44011 assert( pPager->exclusiveMode || 0==sqlite3WalHeapMemory(pPager->pWal) );
44012 if( eMode>=0 && !pPager->tempFile && !sqlite3WalHeapMemory(pPager->pWal) ){
44013 pPager->exclusiveMode = (u8)eMode;
44015 return (int)pPager->exclusiveMode;
44019 ** Set the journal-mode for this pager. Parameter eMode must be one of:
44021 ** PAGER_JOURNALMODE_DELETE
44022 ** PAGER_JOURNALMODE_TRUNCATE
44023 ** PAGER_JOURNALMODE_PERSIST
44024 ** PAGER_JOURNALMODE_OFF
44025 ** PAGER_JOURNALMODE_MEMORY
44026 ** PAGER_JOURNALMODE_WAL
44028 ** The journalmode is set to the value specified if the change is allowed.
44029 ** The change may be disallowed for the following reasons:
44031 ** * An in-memory database can only have its journal_mode set to _OFF
44032 ** or _MEMORY.
44034 ** * Temporary databases cannot have _WAL journalmode.
44036 ** The returned indicate the current (possibly updated) journal-mode.
44038 SQLITE_PRIVATE int sqlite3PagerSetJournalMode(Pager *pPager, int eMode){
44039 u8 eOld = pPager->journalMode; /* Prior journalmode */
44041 #ifdef SQLITE_DEBUG
44042 /* The print_pager_state() routine is intended to be used by the debugger
44043 ** only. We invoke it once here to suppress a compiler warning. */
44044 print_pager_state(pPager);
44045 #endif
44048 /* The eMode parameter is always valid */
44049 assert( eMode==PAGER_JOURNALMODE_DELETE
44050 || eMode==PAGER_JOURNALMODE_TRUNCATE
44051 || eMode==PAGER_JOURNALMODE_PERSIST
44052 || eMode==PAGER_JOURNALMODE_OFF
44053 || eMode==PAGER_JOURNALMODE_WAL
44054 || eMode==PAGER_JOURNALMODE_MEMORY );
44056 /* This routine is only called from the OP_JournalMode opcode, and
44057 ** the logic there will never allow a temporary file to be changed
44058 ** to WAL mode.
44060 assert( pPager->tempFile==0 || eMode!=PAGER_JOURNALMODE_WAL );
44062 /* Do allow the journalmode of an in-memory database to be set to
44063 ** anything other than MEMORY or OFF
44065 if( MEMDB ){
44066 assert( eOld==PAGER_JOURNALMODE_MEMORY || eOld==PAGER_JOURNALMODE_OFF );
44067 if( eMode!=PAGER_JOURNALMODE_MEMORY && eMode!=PAGER_JOURNALMODE_OFF ){
44068 eMode = eOld;
44072 if( eMode!=eOld ){
44074 /* Change the journal mode. */
44075 assert( pPager->eState!=PAGER_ERROR );
44076 pPager->journalMode = (u8)eMode;
44078 /* When transistioning from TRUNCATE or PERSIST to any other journal
44079 ** mode except WAL, unless the pager is in locking_mode=exclusive mode,
44080 ** delete the journal file.
44082 assert( (PAGER_JOURNALMODE_TRUNCATE & 5)==1 );
44083 assert( (PAGER_JOURNALMODE_PERSIST & 5)==1 );
44084 assert( (PAGER_JOURNALMODE_DELETE & 5)==0 );
44085 assert( (PAGER_JOURNALMODE_MEMORY & 5)==4 );
44086 assert( (PAGER_JOURNALMODE_OFF & 5)==0 );
44087 assert( (PAGER_JOURNALMODE_WAL & 5)==5 );
44089 assert( isOpen(pPager->fd) || pPager->exclusiveMode );
44090 if( !pPager->exclusiveMode && (eOld & 5)==1 && (eMode & 1)==0 ){
44092 /* In this case we would like to delete the journal file. If it is
44093 ** not possible, then that is not a problem. Deleting the journal file
44094 ** here is an optimization only.
44096 ** Before deleting the journal file, obtain a RESERVED lock on the
44097 ** database file. This ensures that the journal file is not deleted
44098 ** while it is in use by some other client.
44100 sqlite3OsClose(pPager->jfd);
44101 if( pPager->eLock>=RESERVED_LOCK ){
44102 sqlite3OsDelete(pPager->pVfs, pPager->zJournal, 0);
44103 }else{
44104 int rc = SQLITE_OK;
44105 int state = pPager->eState;
44106 assert( state==PAGER_OPEN || state==PAGER_READER );
44107 if( state==PAGER_OPEN ){
44108 rc = sqlite3PagerSharedLock(pPager);
44110 if( pPager->eState==PAGER_READER ){
44111 assert( rc==SQLITE_OK );
44112 rc = pagerLockDb(pPager, RESERVED_LOCK);
44114 if( rc==SQLITE_OK ){
44115 sqlite3OsDelete(pPager->pVfs, pPager->zJournal, 0);
44117 if( rc==SQLITE_OK && state==PAGER_READER ){
44118 pagerUnlockDb(pPager, SHARED_LOCK);
44119 }else if( state==PAGER_OPEN ){
44120 pager_unlock(pPager);
44122 assert( state==pPager->eState );
44127 /* Return the new journal mode */
44128 return (int)pPager->journalMode;
44132 ** Return the current journal mode.
44134 SQLITE_PRIVATE int sqlite3PagerGetJournalMode(Pager *pPager){
44135 return (int)pPager->journalMode;
44139 ** Return TRUE if the pager is in a state where it is OK to change the
44140 ** journalmode. Journalmode changes can only happen when the database
44141 ** is unmodified.
44143 SQLITE_PRIVATE int sqlite3PagerOkToChangeJournalMode(Pager *pPager){
44144 assert( assert_pager_state(pPager) );
44145 if( pPager->eState>=PAGER_WRITER_CACHEMOD ) return 0;
44146 if( NEVER(isOpen(pPager->jfd) && pPager->journalOff>0) ) return 0;
44147 return 1;
44151 ** Get/set the size-limit used for persistent journal files.
44153 ** Setting the size limit to -1 means no limit is enforced.
44154 ** An attempt to set a limit smaller than -1 is a no-op.
44156 SQLITE_PRIVATE i64 sqlite3PagerJournalSizeLimit(Pager *pPager, i64 iLimit){
44157 if( iLimit>=-1 ){
44158 pPager->journalSizeLimit = iLimit;
44159 sqlite3WalLimit(pPager->pWal, iLimit);
44161 return pPager->journalSizeLimit;
44165 ** Return a pointer to the pPager->pBackup variable. The backup module
44166 ** in backup.c maintains the content of this variable. This module
44167 ** uses it opaquely as an argument to sqlite3BackupRestart() and
44168 ** sqlite3BackupUpdate() only.
44170 SQLITE_PRIVATE sqlite3_backup **sqlite3PagerBackupPtr(Pager *pPager){
44171 return &pPager->pBackup;
44174 #ifndef SQLITE_OMIT_WAL
44176 ** This function is called when the user invokes "PRAGMA wal_checkpoint",
44177 ** "PRAGMA wal_blocking_checkpoint" or calls the sqlite3_wal_checkpoint()
44178 ** or wal_blocking_checkpoint() API functions.
44180 ** Parameter eMode is one of SQLITE_CHECKPOINT_PASSIVE, FULL or RESTART.
44182 SQLITE_PRIVATE int sqlite3PagerCheckpoint(Pager *pPager, int eMode, int *pnLog, int *pnCkpt){
44183 int rc = SQLITE_OK;
44184 if( pPager->pWal ){
44185 rc = sqlite3WalCheckpoint(pPager->pWal, eMode,
44186 pPager->xBusyHandler, pPager->pBusyHandlerArg,
44187 pPager->ckptSyncFlags, pPager->pageSize, (u8 *)pPager->pTmpSpace,
44188 pnLog, pnCkpt
44191 return rc;
44194 SQLITE_PRIVATE int sqlite3PagerWalCallback(Pager *pPager){
44195 return sqlite3WalCallback(pPager->pWal);
44199 ** Return true if the underlying VFS for the given pager supports the
44200 ** primitives necessary for write-ahead logging.
44202 SQLITE_PRIVATE int sqlite3PagerWalSupported(Pager *pPager){
44203 const sqlite3_io_methods *pMethods = pPager->fd->pMethods;
44204 return pPager->exclusiveMode || (pMethods->iVersion>=2 && pMethods->xShmMap);
44208 ** Attempt to take an exclusive lock on the database file. If a PENDING lock
44209 ** is obtained instead, immediately release it.
44211 static int pagerExclusiveLock(Pager *pPager){
44212 int rc; /* Return code */
44214 assert( pPager->eLock==SHARED_LOCK || pPager->eLock==EXCLUSIVE_LOCK );
44215 rc = pagerLockDb(pPager, EXCLUSIVE_LOCK);
44216 if( rc!=SQLITE_OK ){
44217 /* If the attempt to grab the exclusive lock failed, release the
44218 ** pending lock that may have been obtained instead. */
44219 pagerUnlockDb(pPager, SHARED_LOCK);
44222 return rc;
44226 ** Call sqlite3WalOpen() to open the WAL handle. If the pager is in
44227 ** exclusive-locking mode when this function is called, take an EXCLUSIVE
44228 ** lock on the database file and use heap-memory to store the wal-index
44229 ** in. Otherwise, use the normal shared-memory.
44231 static int pagerOpenWal(Pager *pPager){
44232 int rc = SQLITE_OK;
44234 assert( pPager->pWal==0 && pPager->tempFile==0 );
44235 assert( pPager->eLock==SHARED_LOCK || pPager->eLock==EXCLUSIVE_LOCK || pPager->noReadlock);
44237 /* If the pager is already in exclusive-mode, the WAL module will use
44238 ** heap-memory for the wal-index instead of the VFS shared-memory
44239 ** implementation. Take the exclusive lock now, before opening the WAL
44240 ** file, to make sure this is safe.
44242 if( pPager->exclusiveMode ){
44243 rc = pagerExclusiveLock(pPager);
44246 /* Open the connection to the log file. If this operation fails,
44247 ** (e.g. due to malloc() failure), return an error code.
44249 if( rc==SQLITE_OK ){
44250 rc = sqlite3WalOpen(pPager->pVfs,
44251 pPager->fd, pPager->zWal, pPager->exclusiveMode,
44252 pPager->journalSizeLimit, &pPager->pWal
44256 return rc;
44261 ** The caller must be holding a SHARED lock on the database file to call
44262 ** this function.
44264 ** If the pager passed as the first argument is open on a real database
44265 ** file (not a temp file or an in-memory database), and the WAL file
44266 ** is not already open, make an attempt to open it now. If successful,
44267 ** return SQLITE_OK. If an error occurs or the VFS used by the pager does
44268 ** not support the xShmXXX() methods, return an error code. *pbOpen is
44269 ** not modified in either case.
44271 ** If the pager is open on a temp-file (or in-memory database), or if
44272 ** the WAL file is already open, set *pbOpen to 1 and return SQLITE_OK
44273 ** without doing anything.
44275 SQLITE_PRIVATE int sqlite3PagerOpenWal(
44276 Pager *pPager, /* Pager object */
44277 int *pbOpen /* OUT: Set to true if call is a no-op */
44279 int rc = SQLITE_OK; /* Return code */
44281 assert( assert_pager_state(pPager) );
44282 assert( pPager->eState==PAGER_OPEN || pbOpen );
44283 assert( pPager->eState==PAGER_READER || !pbOpen );
44284 assert( pbOpen==0 || *pbOpen==0 );
44285 assert( pbOpen!=0 || (!pPager->tempFile && !pPager->pWal) );
44287 if( !pPager->tempFile && !pPager->pWal ){
44288 if( !sqlite3PagerWalSupported(pPager) ) return SQLITE_CANTOPEN;
44290 /* Close any rollback journal previously open */
44291 sqlite3OsClose(pPager->jfd);
44293 rc = pagerOpenWal(pPager);
44294 if( rc==SQLITE_OK ){
44295 pPager->journalMode = PAGER_JOURNALMODE_WAL;
44296 pPager->eState = PAGER_OPEN;
44298 }else{
44299 *pbOpen = 1;
44302 return rc;
44306 ** This function is called to close the connection to the log file prior
44307 ** to switching from WAL to rollback mode.
44309 ** Before closing the log file, this function attempts to take an
44310 ** EXCLUSIVE lock on the database file. If this cannot be obtained, an
44311 ** error (SQLITE_BUSY) is returned and the log connection is not closed.
44312 ** If successful, the EXCLUSIVE lock is not released before returning.
44314 SQLITE_PRIVATE int sqlite3PagerCloseWal(Pager *pPager){
44315 int rc = SQLITE_OK;
44317 assert( pPager->journalMode==PAGER_JOURNALMODE_WAL );
44319 /* If the log file is not already open, but does exist in the file-system,
44320 ** it may need to be checkpointed before the connection can switch to
44321 ** rollback mode. Open it now so this can happen.
44323 if( !pPager->pWal ){
44324 int logexists = 0;
44325 rc = pagerLockDb(pPager, SHARED_LOCK);
44326 if( rc==SQLITE_OK ){
44327 rc = sqlite3OsAccess(
44328 pPager->pVfs, pPager->zWal, SQLITE_ACCESS_EXISTS, &logexists
44331 if( rc==SQLITE_OK && logexists ){
44332 rc = pagerOpenWal(pPager);
44336 /* Checkpoint and close the log. Because an EXCLUSIVE lock is held on
44337 ** the database file, the log and log-summary files will be deleted.
44339 if( rc==SQLITE_OK && pPager->pWal ){
44340 rc = pagerExclusiveLock(pPager);
44341 if( rc==SQLITE_OK ){
44342 rc = sqlite3WalClose(pPager->pWal, pPager->ckptSyncFlags,
44343 pPager->pageSize, (u8*)pPager->pTmpSpace);
44344 pPager->pWal = 0;
44347 return rc;
44350 #ifdef SQLITE_HAS_CODEC
44352 ** This function is called by the wal module when writing page content
44353 ** into the log file.
44355 ** This function returns a pointer to a buffer containing the encrypted
44356 ** page content. If a malloc fails, this function may return NULL.
44358 SQLITE_PRIVATE void *sqlite3PagerCodec(PgHdr *pPg){
44359 void *aData = 0;
44360 CODEC2(pPg->pPager, pPg->pData, pPg->pgno, 6, return 0, aData);
44361 return aData;
44363 #endif /* SQLITE_HAS_CODEC */
44365 #endif /* !SQLITE_OMIT_WAL */
44367 #endif /* SQLITE_OMIT_DISKIO */
44369 /************** End of pager.c ***********************************************/
44370 /************** Begin file wal.c *********************************************/
44372 ** 2010 February 1
44374 ** The author disclaims copyright to this source code. In place of
44375 ** a legal notice, here is a blessing:
44377 ** May you do good and not evil.
44378 ** May you find forgiveness for yourself and forgive others.
44379 ** May you share freely, never taking more than you give.
44381 *************************************************************************
44383 ** This file contains the implementation of a write-ahead log (WAL) used in
44384 ** "journal_mode=WAL" mode.
44386 ** WRITE-AHEAD LOG (WAL) FILE FORMAT
44388 ** A WAL file consists of a header followed by zero or more "frames".
44389 ** Each frame records the revised content of a single page from the
44390 ** database file. All changes to the database are recorded by writing
44391 ** frames into the WAL. Transactions commit when a frame is written that
44392 ** contains a commit marker. A single WAL can and usually does record
44393 ** multiple transactions. Periodically, the content of the WAL is
44394 ** transferred back into the database file in an operation called a
44395 ** "checkpoint".
44397 ** A single WAL file can be used multiple times. In other words, the
44398 ** WAL can fill up with frames and then be checkpointed and then new
44399 ** frames can overwrite the old ones. A WAL always grows from beginning
44400 ** toward the end. Checksums and counters attached to each frame are
44401 ** used to determine which frames within the WAL are valid and which
44402 ** are leftovers from prior checkpoints.
44404 ** The WAL header is 32 bytes in size and consists of the following eight
44405 ** big-endian 32-bit unsigned integer values:
44407 ** 0: Magic number. 0x377f0682 or 0x377f0683
44408 ** 4: File format version. Currently 3007000
44409 ** 8: Database page size. Example: 1024
44410 ** 12: Checkpoint sequence number
44411 ** 16: Salt-1, random integer incremented with each checkpoint
44412 ** 20: Salt-2, a different random integer changing with each ckpt
44413 ** 24: Checksum-1 (first part of checksum for first 24 bytes of header).
44414 ** 28: Checksum-2 (second part of checksum for first 24 bytes of header).
44416 ** Immediately following the wal-header are zero or more frames. Each
44417 ** frame consists of a 24-byte frame-header followed by a <page-size> bytes
44418 ** of page data. The frame-header is six big-endian 32-bit unsigned
44419 ** integer values, as follows:
44421 ** 0: Page number.
44422 ** 4: For commit records, the size of the database image in pages
44423 ** after the commit. For all other records, zero.
44424 ** 8: Salt-1 (copied from the header)
44425 ** 12: Salt-2 (copied from the header)
44426 ** 16: Checksum-1.
44427 ** 20: Checksum-2.
44429 ** A frame is considered valid if and only if the following conditions are
44430 ** true:
44432 ** (1) The salt-1 and salt-2 values in the frame-header match
44433 ** salt values in the wal-header
44435 ** (2) The checksum values in the final 8 bytes of the frame-header
44436 ** exactly match the checksum computed consecutively on the
44437 ** WAL header and the first 8 bytes and the content of all frames
44438 ** up to and including the current frame.
44440 ** The checksum is computed using 32-bit big-endian integers if the
44441 ** magic number in the first 4 bytes of the WAL is 0x377f0683 and it
44442 ** is computed using little-endian if the magic number is 0x377f0682.
44443 ** The checksum values are always stored in the frame header in a
44444 ** big-endian format regardless of which byte order is used to compute
44445 ** the checksum. The checksum is computed by interpreting the input as
44446 ** an even number of unsigned 32-bit integers: x[0] through x[N]. The
44447 ** algorithm used for the checksum is as follows:
44449 ** for i from 0 to n-1 step 2:
44450 ** s0 += x[i] + s1;
44451 ** s1 += x[i+1] + s0;
44452 ** endfor
44454 ** Note that s0 and s1 are both weighted checksums using fibonacci weights
44455 ** in reverse order (the largest fibonacci weight occurs on the first element
44456 ** of the sequence being summed.) The s1 value spans all 32-bit
44457 ** terms of the sequence whereas s0 omits the final term.
44459 ** On a checkpoint, the WAL is first VFS.xSync-ed, then valid content of the
44460 ** WAL is transferred into the database, then the database is VFS.xSync-ed.
44461 ** The VFS.xSync operations serve as write barriers - all writes launched
44462 ** before the xSync must complete before any write that launches after the
44463 ** xSync begins.
44465 ** After each checkpoint, the salt-1 value is incremented and the salt-2
44466 ** value is randomized. This prevents old and new frames in the WAL from
44467 ** being considered valid at the same time and being checkpointing together
44468 ** following a crash.
44470 ** READER ALGORITHM
44472 ** To read a page from the database (call it page number P), a reader
44473 ** first checks the WAL to see if it contains page P. If so, then the
44474 ** last valid instance of page P that is a followed by a commit frame
44475 ** or is a commit frame itself becomes the value read. If the WAL
44476 ** contains no copies of page P that are valid and which are a commit
44477 ** frame or are followed by a commit frame, then page P is read from
44478 ** the database file.
44480 ** To start a read transaction, the reader records the index of the last
44481 ** valid frame in the WAL. The reader uses this recorded "mxFrame" value
44482 ** for all subsequent read operations. New transactions can be appended
44483 ** to the WAL, but as long as the reader uses its original mxFrame value
44484 ** and ignores the newly appended content, it will see a consistent snapshot
44485 ** of the database from a single point in time. This technique allows
44486 ** multiple concurrent readers to view different versions of the database
44487 ** content simultaneously.
44489 ** The reader algorithm in the previous paragraphs works correctly, but
44490 ** because frames for page P can appear anywhere within the WAL, the
44491 ** reader has to scan the entire WAL looking for page P frames. If the
44492 ** WAL is large (multiple megabytes is typical) that scan can be slow,
44493 ** and read performance suffers. To overcome this problem, a separate
44494 ** data structure called the wal-index is maintained to expedite the
44495 ** search for frames of a particular page.
44497 ** WAL-INDEX FORMAT
44499 ** Conceptually, the wal-index is shared memory, though VFS implementations
44500 ** might choose to implement the wal-index using a mmapped file. Because
44501 ** the wal-index is shared memory, SQLite does not support journal_mode=WAL
44502 ** on a network filesystem. All users of the database must be able to
44503 ** share memory.
44505 ** The wal-index is transient. After a crash, the wal-index can (and should
44506 ** be) reconstructed from the original WAL file. In fact, the VFS is required
44507 ** to either truncate or zero the header of the wal-index when the last
44508 ** connection to it closes. Because the wal-index is transient, it can
44509 ** use an architecture-specific format; it does not have to be cross-platform.
44510 ** Hence, unlike the database and WAL file formats which store all values
44511 ** as big endian, the wal-index can store multi-byte values in the native
44512 ** byte order of the host computer.
44514 ** The purpose of the wal-index is to answer this question quickly: Given
44515 ** a page number P, return the index of the last frame for page P in the WAL,
44516 ** or return NULL if there are no frames for page P in the WAL.
44518 ** The wal-index consists of a header region, followed by an one or
44519 ** more index blocks.
44521 ** The wal-index header contains the total number of frames within the WAL
44522 ** in the the mxFrame field.
44524 ** Each index block except for the first contains information on
44525 ** HASHTABLE_NPAGE frames. The first index block contains information on
44526 ** HASHTABLE_NPAGE_ONE frames. The values of HASHTABLE_NPAGE_ONE and
44527 ** HASHTABLE_NPAGE are selected so that together the wal-index header and
44528 ** first index block are the same size as all other index blocks in the
44529 ** wal-index.
44531 ** Each index block contains two sections, a page-mapping that contains the
44532 ** database page number associated with each wal frame, and a hash-table
44533 ** that allows readers to query an index block for a specific page number.
44534 ** The page-mapping is an array of HASHTABLE_NPAGE (or HASHTABLE_NPAGE_ONE
44535 ** for the first index block) 32-bit page numbers. The first entry in the
44536 ** first index-block contains the database page number corresponding to the
44537 ** first frame in the WAL file. The first entry in the second index block
44538 ** in the WAL file corresponds to the (HASHTABLE_NPAGE_ONE+1)th frame in
44539 ** the log, and so on.
44541 ** The last index block in a wal-index usually contains less than the full
44542 ** complement of HASHTABLE_NPAGE (or HASHTABLE_NPAGE_ONE) page-numbers,
44543 ** depending on the contents of the WAL file. This does not change the
44544 ** allocated size of the page-mapping array - the page-mapping array merely
44545 ** contains unused entries.
44547 ** Even without using the hash table, the last frame for page P
44548 ** can be found by scanning the page-mapping sections of each index block
44549 ** starting with the last index block and moving toward the first, and
44550 ** within each index block, starting at the end and moving toward the
44551 ** beginning. The first entry that equals P corresponds to the frame
44552 ** holding the content for that page.
44554 ** The hash table consists of HASHTABLE_NSLOT 16-bit unsigned integers.
44555 ** HASHTABLE_NSLOT = 2*HASHTABLE_NPAGE, and there is one entry in the
44556 ** hash table for each page number in the mapping section, so the hash
44557 ** table is never more than half full. The expected number of collisions
44558 ** prior to finding a match is 1. Each entry of the hash table is an
44559 ** 1-based index of an entry in the mapping section of the same
44560 ** index block. Let K be the 1-based index of the largest entry in
44561 ** the mapping section. (For index blocks other than the last, K will
44562 ** always be exactly HASHTABLE_NPAGE (4096) and for the last index block
44563 ** K will be (mxFrame%HASHTABLE_NPAGE).) Unused slots of the hash table
44564 ** contain a value of 0.
44566 ** To look for page P in the hash table, first compute a hash iKey on
44567 ** P as follows:
44569 ** iKey = (P * 383) % HASHTABLE_NSLOT
44571 ** Then start scanning entries of the hash table, starting with iKey
44572 ** (wrapping around to the beginning when the end of the hash table is
44573 ** reached) until an unused hash slot is found. Let the first unused slot
44574 ** be at index iUnused. (iUnused might be less than iKey if there was
44575 ** wrap-around.) Because the hash table is never more than half full,
44576 ** the search is guaranteed to eventually hit an unused entry. Let
44577 ** iMax be the value between iKey and iUnused, closest to iUnused,
44578 ** where aHash[iMax]==P. If there is no iMax entry (if there exists
44579 ** no hash slot such that aHash[i]==p) then page P is not in the
44580 ** current index block. Otherwise the iMax-th mapping entry of the
44581 ** current index block corresponds to the last entry that references
44582 ** page P.
44584 ** A hash search begins with the last index block and moves toward the
44585 ** first index block, looking for entries corresponding to page P. On
44586 ** average, only two or three slots in each index block need to be
44587 ** examined in order to either find the last entry for page P, or to
44588 ** establish that no such entry exists in the block. Each index block
44589 ** holds over 4000 entries. So two or three index blocks are sufficient
44590 ** to cover a typical 10 megabyte WAL file, assuming 1K pages. 8 or 10
44591 ** comparisons (on average) suffice to either locate a frame in the
44592 ** WAL or to establish that the frame does not exist in the WAL. This
44593 ** is much faster than scanning the entire 10MB WAL.
44595 ** Note that entries are added in order of increasing K. Hence, one
44596 ** reader might be using some value K0 and a second reader that started
44597 ** at a later time (after additional transactions were added to the WAL
44598 ** and to the wal-index) might be using a different value K1, where K1>K0.
44599 ** Both readers can use the same hash table and mapping section to get
44600 ** the correct result. There may be entries in the hash table with
44601 ** K>K0 but to the first reader, those entries will appear to be unused
44602 ** slots in the hash table and so the first reader will get an answer as
44603 ** if no values greater than K0 had ever been inserted into the hash table
44604 ** in the first place - which is what reader one wants. Meanwhile, the
44605 ** second reader using K1 will see additional values that were inserted
44606 ** later, which is exactly what reader two wants.
44608 ** When a rollback occurs, the value of K is decreased. Hash table entries
44609 ** that correspond to frames greater than the new K value are removed
44610 ** from the hash table at this point.
44612 #ifndef SQLITE_OMIT_WAL
44616 ** Trace output macros
44618 #if defined(SQLITE_TEST) && defined(SQLITE_DEBUG)
44619 SQLITE_PRIVATE int sqlite3WalTrace = 0;
44620 # define WALTRACE(X) if(sqlite3WalTrace) sqlite3DebugPrintf X
44621 #else
44622 # define WALTRACE(X)
44623 #endif
44626 ** The maximum (and only) versions of the wal and wal-index formats
44627 ** that may be interpreted by this version of SQLite.
44629 ** If a client begins recovering a WAL file and finds that (a) the checksum
44630 ** values in the wal-header are correct and (b) the version field is not
44631 ** WAL_MAX_VERSION, recovery fails and SQLite returns SQLITE_CANTOPEN.
44633 ** Similarly, if a client successfully reads a wal-index header (i.e. the
44634 ** checksum test is successful) and finds that the version field is not
44635 ** WALINDEX_MAX_VERSION, then no read-transaction is opened and SQLite
44636 ** returns SQLITE_CANTOPEN.
44638 #define WAL_MAX_VERSION 3007000
44639 #define WALINDEX_MAX_VERSION 3007000
44642 ** Indices of various locking bytes. WAL_NREADER is the number
44643 ** of available reader locks and should be at least 3.
44645 #define WAL_WRITE_LOCK 0
44646 #define WAL_ALL_BUT_WRITE 1
44647 #define WAL_CKPT_LOCK 1
44648 #define WAL_RECOVER_LOCK 2
44649 #define WAL_READ_LOCK(I) (3+(I))
44650 #define WAL_NREADER (SQLITE_SHM_NLOCK-3)
44653 /* Object declarations */
44654 typedef struct WalIndexHdr WalIndexHdr;
44655 typedef struct WalIterator WalIterator;
44656 typedef struct WalCkptInfo WalCkptInfo;
44660 ** The following object holds a copy of the wal-index header content.
44662 ** The actual header in the wal-index consists of two copies of this
44663 ** object.
44665 ** The szPage value can be any power of 2 between 512 and 32768, inclusive.
44666 ** Or it can be 1 to represent a 65536-byte page. The latter case was
44667 ** added in 3.7.1 when support for 64K pages was added.
44669 struct WalIndexHdr {
44670 u32 iVersion; /* Wal-index version */
44671 u32 unused; /* Unused (padding) field */
44672 u32 iChange; /* Counter incremented each transaction */
44673 u8 isInit; /* 1 when initialized */
44674 u8 bigEndCksum; /* True if checksums in WAL are big-endian */
44675 u16 szPage; /* Database page size in bytes. 1==64K */
44676 u32 mxFrame; /* Index of last valid frame in the WAL */
44677 u32 nPage; /* Size of database in pages */
44678 u32 aFrameCksum[2]; /* Checksum of last frame in log */
44679 u32 aSalt[2]; /* Two salt values copied from WAL header */
44680 u32 aCksum[2]; /* Checksum over all prior fields */
44684 ** A copy of the following object occurs in the wal-index immediately
44685 ** following the second copy of the WalIndexHdr. This object stores
44686 ** information used by checkpoint.
44688 ** nBackfill is the number of frames in the WAL that have been written
44689 ** back into the database. (We call the act of moving content from WAL to
44690 ** database "backfilling".) The nBackfill number is never greater than
44691 ** WalIndexHdr.mxFrame. nBackfill can only be increased by threads
44692 ** holding the WAL_CKPT_LOCK lock (which includes a recovery thread).
44693 ** However, a WAL_WRITE_LOCK thread can move the value of nBackfill from
44694 ** mxFrame back to zero when the WAL is reset.
44696 ** There is one entry in aReadMark[] for each reader lock. If a reader
44697 ** holds read-lock K, then the value in aReadMark[K] is no greater than
44698 ** the mxFrame for that reader. The value READMARK_NOT_USED (0xffffffff)
44699 ** for any aReadMark[] means that entry is unused. aReadMark[0] is
44700 ** a special case; its value is never used and it exists as a place-holder
44701 ** to avoid having to offset aReadMark[] indexs by one. Readers holding
44702 ** WAL_READ_LOCK(0) always ignore the entire WAL and read all content
44703 ** directly from the database.
44705 ** The value of aReadMark[K] may only be changed by a thread that
44706 ** is holding an exclusive lock on WAL_READ_LOCK(K). Thus, the value of
44707 ** aReadMark[K] cannot changed while there is a reader is using that mark
44708 ** since the reader will be holding a shared lock on WAL_READ_LOCK(K).
44710 ** The checkpointer may only transfer frames from WAL to database where
44711 ** the frame numbers are less than or equal to every aReadMark[] that is
44712 ** in use (that is, every aReadMark[j] for which there is a corresponding
44713 ** WAL_READ_LOCK(j)). New readers (usually) pick the aReadMark[] with the
44714 ** largest value and will increase an unused aReadMark[] to mxFrame if there
44715 ** is not already an aReadMark[] equal to mxFrame. The exception to the
44716 ** previous sentence is when nBackfill equals mxFrame (meaning that everything
44717 ** in the WAL has been backfilled into the database) then new readers
44718 ** will choose aReadMark[0] which has value 0 and hence such reader will
44719 ** get all their all content directly from the database file and ignore
44720 ** the WAL.
44722 ** Writers normally append new frames to the end of the WAL. However,
44723 ** if nBackfill equals mxFrame (meaning that all WAL content has been
44724 ** written back into the database) and if no readers are using the WAL
44725 ** (in other words, if there are no WAL_READ_LOCK(i) where i>0) then
44726 ** the writer will first "reset" the WAL back to the beginning and start
44727 ** writing new content beginning at frame 1.
44729 ** We assume that 32-bit loads are atomic and so no locks are needed in
44730 ** order to read from any aReadMark[] entries.
44732 struct WalCkptInfo {
44733 u32 nBackfill; /* Number of WAL frames backfilled into DB */
44734 u32 aReadMark[WAL_NREADER]; /* Reader marks */
44736 #define READMARK_NOT_USED 0xffffffff
44739 /* A block of WALINDEX_LOCK_RESERVED bytes beginning at
44740 ** WALINDEX_LOCK_OFFSET is reserved for locks. Since some systems
44741 ** only support mandatory file-locks, we do not read or write data
44742 ** from the region of the file on which locks are applied.
44744 #define WALINDEX_LOCK_OFFSET (sizeof(WalIndexHdr)*2 + sizeof(WalCkptInfo))
44745 #define WALINDEX_LOCK_RESERVED 16
44746 #define WALINDEX_HDR_SIZE (WALINDEX_LOCK_OFFSET+WALINDEX_LOCK_RESERVED)
44748 /* Size of header before each frame in wal */
44749 #define WAL_FRAME_HDRSIZE 24
44751 /* Size of write ahead log header, including checksum. */
44752 /* #define WAL_HDRSIZE 24 */
44753 #define WAL_HDRSIZE 32
44755 /* WAL magic value. Either this value, or the same value with the least
44756 ** significant bit also set (WAL_MAGIC | 0x00000001) is stored in 32-bit
44757 ** big-endian format in the first 4 bytes of a WAL file.
44759 ** If the LSB is set, then the checksums for each frame within the WAL
44760 ** file are calculated by treating all data as an array of 32-bit
44761 ** big-endian words. Otherwise, they are calculated by interpreting
44762 ** all data as 32-bit little-endian words.
44764 #define WAL_MAGIC 0x377f0682
44767 ** Return the offset of frame iFrame in the write-ahead log file,
44768 ** assuming a database page size of szPage bytes. The offset returned
44769 ** is to the start of the write-ahead log frame-header.
44771 #define walFrameOffset(iFrame, szPage) ( \
44772 WAL_HDRSIZE + ((iFrame)-1)*(i64)((szPage)+WAL_FRAME_HDRSIZE) \
44776 ** An open write-ahead log file is represented by an instance of the
44777 ** following object.
44779 struct Wal {
44780 sqlite3_vfs *pVfs; /* The VFS used to create pDbFd */
44781 sqlite3_file *pDbFd; /* File handle for the database file */
44782 sqlite3_file *pWalFd; /* File handle for WAL file */
44783 u32 iCallback; /* Value to pass to log callback (or 0) */
44784 i64 mxWalSize; /* Truncate WAL to this size upon reset */
44785 int nWiData; /* Size of array apWiData */
44786 volatile u32 **apWiData; /* Pointer to wal-index content in memory */
44787 u32 szPage; /* Database page size */
44788 i16 readLock; /* Which read lock is being held. -1 for none */
44789 u8 exclusiveMode; /* Non-zero if connection is in exclusive mode */
44790 u8 writeLock; /* True if in a write transaction */
44791 u8 ckptLock; /* True if holding a checkpoint lock */
44792 u8 readOnly; /* WAL_RDWR, WAL_RDONLY, or WAL_SHM_RDONLY */
44793 WalIndexHdr hdr; /* Wal-index header for current transaction */
44794 const char *zWalName; /* Name of WAL file */
44795 u32 nCkpt; /* Checkpoint sequence counter in the wal-header */
44796 #ifdef SQLITE_DEBUG
44797 u8 lockError; /* True if a locking error has occurred */
44798 #endif
44802 ** Candidate values for Wal.exclusiveMode.
44804 #define WAL_NORMAL_MODE 0
44805 #define WAL_EXCLUSIVE_MODE 1
44806 #define WAL_HEAPMEMORY_MODE 2
44809 ** Possible values for WAL.readOnly
44811 #define WAL_RDWR 0 /* Normal read/write connection */
44812 #define WAL_RDONLY 1 /* The WAL file is readonly */
44813 #define WAL_SHM_RDONLY 2 /* The SHM file is readonly */
44816 ** Each page of the wal-index mapping contains a hash-table made up of
44817 ** an array of HASHTABLE_NSLOT elements of the following type.
44819 typedef u16 ht_slot;
44822 ** This structure is used to implement an iterator that loops through
44823 ** all frames in the WAL in database page order. Where two or more frames
44824 ** correspond to the same database page, the iterator visits only the
44825 ** frame most recently written to the WAL (in other words, the frame with
44826 ** the largest index).
44828 ** The internals of this structure are only accessed by:
44830 ** walIteratorInit() - Create a new iterator,
44831 ** walIteratorNext() - Step an iterator,
44832 ** walIteratorFree() - Free an iterator.
44834 ** This functionality is used by the checkpoint code (see walCheckpoint()).
44836 struct WalIterator {
44837 int iPrior; /* Last result returned from the iterator */
44838 int nSegment; /* Number of entries in aSegment[] */
44839 struct WalSegment {
44840 int iNext; /* Next slot in aIndex[] not yet returned */
44841 ht_slot *aIndex; /* i0, i1, i2... such that aPgno[iN] ascend */
44842 u32 *aPgno; /* Array of page numbers. */
44843 int nEntry; /* Nr. of entries in aPgno[] and aIndex[] */
44844 int iZero; /* Frame number associated with aPgno[0] */
44845 } aSegment[1]; /* One for every 32KB page in the wal-index */
44849 ** Define the parameters of the hash tables in the wal-index file. There
44850 ** is a hash-table following every HASHTABLE_NPAGE page numbers in the
44851 ** wal-index.
44853 ** Changing any of these constants will alter the wal-index format and
44854 ** create incompatibilities.
44856 #define HASHTABLE_NPAGE 4096 /* Must be power of 2 */
44857 #define HASHTABLE_HASH_1 383 /* Should be prime */
44858 #define HASHTABLE_NSLOT (HASHTABLE_NPAGE*2) /* Must be a power of 2 */
44861 ** The block of page numbers associated with the first hash-table in a
44862 ** wal-index is smaller than usual. This is so that there is a complete
44863 ** hash-table on each aligned 32KB page of the wal-index.
44865 #define HASHTABLE_NPAGE_ONE (HASHTABLE_NPAGE - (WALINDEX_HDR_SIZE/sizeof(u32)))
44867 /* The wal-index is divided into pages of WALINDEX_PGSZ bytes each. */
44868 #define WALINDEX_PGSZ ( \
44869 sizeof(ht_slot)*HASHTABLE_NSLOT + HASHTABLE_NPAGE*sizeof(u32) \
44873 ** Obtain a pointer to the iPage'th page of the wal-index. The wal-index
44874 ** is broken into pages of WALINDEX_PGSZ bytes. Wal-index pages are
44875 ** numbered from zero.
44877 ** If this call is successful, *ppPage is set to point to the wal-index
44878 ** page and SQLITE_OK is returned. If an error (an OOM or VFS error) occurs,
44879 ** then an SQLite error code is returned and *ppPage is set to 0.
44881 static int walIndexPage(Wal *pWal, int iPage, volatile u32 **ppPage){
44882 int rc = SQLITE_OK;
44884 /* Enlarge the pWal->apWiData[] array if required */
44885 if( pWal->nWiData<=iPage ){
44886 int nByte = sizeof(u32*)*(iPage+1);
44887 volatile u32 **apNew;
44888 apNew = (volatile u32 **)sqlite3_realloc((void *)pWal->apWiData, nByte);
44889 if( !apNew ){
44890 *ppPage = 0;
44891 return SQLITE_NOMEM;
44893 memset((void*)&apNew[pWal->nWiData], 0,
44894 sizeof(u32*)*(iPage+1-pWal->nWiData));
44895 pWal->apWiData = apNew;
44896 pWal->nWiData = iPage+1;
44899 /* Request a pointer to the required page from the VFS */
44900 if( pWal->apWiData[iPage]==0 ){
44901 if( pWal->exclusiveMode==WAL_HEAPMEMORY_MODE ){
44902 pWal->apWiData[iPage] = (u32 volatile *)sqlite3MallocZero(WALINDEX_PGSZ);
44903 if( !pWal->apWiData[iPage] ) rc = SQLITE_NOMEM;
44904 }else{
44905 rc = sqlite3OsShmMap(pWal->pDbFd, iPage, WALINDEX_PGSZ,
44906 pWal->writeLock, (void volatile **)&pWal->apWiData[iPage]
44908 if( rc==SQLITE_READONLY ){
44909 pWal->readOnly |= WAL_SHM_RDONLY;
44910 rc = SQLITE_OK;
44915 *ppPage = pWal->apWiData[iPage];
44916 assert( iPage==0 || *ppPage || rc!=SQLITE_OK );
44917 return rc;
44921 ** Return a pointer to the WalCkptInfo structure in the wal-index.
44923 static volatile WalCkptInfo *walCkptInfo(Wal *pWal){
44924 assert( pWal->nWiData>0 && pWal->apWiData[0] );
44925 return (volatile WalCkptInfo*)&(pWal->apWiData[0][sizeof(WalIndexHdr)/2]);
44929 ** Return a pointer to the WalIndexHdr structure in the wal-index.
44931 static volatile WalIndexHdr *walIndexHdr(Wal *pWal){
44932 assert( pWal->nWiData>0 && pWal->apWiData[0] );
44933 return (volatile WalIndexHdr*)pWal->apWiData[0];
44937 ** The argument to this macro must be of type u32. On a little-endian
44938 ** architecture, it returns the u32 value that results from interpreting
44939 ** the 4 bytes as a big-endian value. On a big-endian architecture, it
44940 ** returns the value that would be produced by intepreting the 4 bytes
44941 ** of the input value as a little-endian integer.
44943 #define BYTESWAP32(x) ( \
44944 (((x)&0x000000FF)<<24) + (((x)&0x0000FF00)<<8) \
44945 + (((x)&0x00FF0000)>>8) + (((x)&0xFF000000)>>24) \
44949 ** Generate or extend an 8 byte checksum based on the data in
44950 ** array aByte[] and the initial values of aIn[0] and aIn[1] (or
44951 ** initial values of 0 and 0 if aIn==NULL).
44953 ** The checksum is written back into aOut[] before returning.
44955 ** nByte must be a positive multiple of 8.
44957 static void walChecksumBytes(
44958 int nativeCksum, /* True for native byte-order, false for non-native */
44959 u8 *a, /* Content to be checksummed */
44960 int nByte, /* Bytes of content in a[]. Must be a multiple of 8. */
44961 const u32 *aIn, /* Initial checksum value input */
44962 u32 *aOut /* OUT: Final checksum value output */
44964 u32 s1, s2;
44965 u32 *aData = (u32 *)a;
44966 u32 *aEnd = (u32 *)&a[nByte];
44968 if( aIn ){
44969 s1 = aIn[0];
44970 s2 = aIn[1];
44971 }else{
44972 s1 = s2 = 0;
44975 assert( nByte>=8 );
44976 assert( (nByte&0x00000007)==0 );
44978 if( nativeCksum ){
44979 do {
44980 s1 += *aData++ + s2;
44981 s2 += *aData++ + s1;
44982 }while( aData<aEnd );
44983 }else{
44984 do {
44985 s1 += BYTESWAP32(aData[0]) + s2;
44986 s2 += BYTESWAP32(aData[1]) + s1;
44987 aData += 2;
44988 }while( aData<aEnd );
44991 aOut[0] = s1;
44992 aOut[1] = s2;
44995 static void walShmBarrier(Wal *pWal){
44996 if( pWal->exclusiveMode!=WAL_HEAPMEMORY_MODE ){
44997 sqlite3OsShmBarrier(pWal->pDbFd);
45002 ** Write the header information in pWal->hdr into the wal-index.
45004 ** The checksum on pWal->hdr is updated before it is written.
45006 static void walIndexWriteHdr(Wal *pWal){
45007 volatile WalIndexHdr *aHdr = walIndexHdr(pWal);
45008 const int nCksum = offsetof(WalIndexHdr, aCksum);
45010 assert( pWal->writeLock );
45011 pWal->hdr.isInit = 1;
45012 pWal->hdr.iVersion = WALINDEX_MAX_VERSION;
45013 walChecksumBytes(1, (u8*)&pWal->hdr, nCksum, 0, pWal->hdr.aCksum);
45014 memcpy((void *)&aHdr[1], (void *)&pWal->hdr, sizeof(WalIndexHdr));
45015 walShmBarrier(pWal);
45016 memcpy((void *)&aHdr[0], (void *)&pWal->hdr, sizeof(WalIndexHdr));
45020 ** This function encodes a single frame header and writes it to a buffer
45021 ** supplied by the caller. A frame-header is made up of a series of
45022 ** 4-byte big-endian integers, as follows:
45024 ** 0: Page number.
45025 ** 4: For commit records, the size of the database image in pages
45026 ** after the commit. For all other records, zero.
45027 ** 8: Salt-1 (copied from the wal-header)
45028 ** 12: Salt-2 (copied from the wal-header)
45029 ** 16: Checksum-1.
45030 ** 20: Checksum-2.
45032 static void walEncodeFrame(
45033 Wal *pWal, /* The write-ahead log */
45034 u32 iPage, /* Database page number for frame */
45035 u32 nTruncate, /* New db size (or 0 for non-commit frames) */
45036 u8 *aData, /* Pointer to page data */
45037 u8 *aFrame /* OUT: Write encoded frame here */
45039 int nativeCksum; /* True for native byte-order checksums */
45040 u32 *aCksum = pWal->hdr.aFrameCksum;
45041 assert( WAL_FRAME_HDRSIZE==24 );
45042 sqlite3Put4byte(&aFrame[0], iPage);
45043 sqlite3Put4byte(&aFrame[4], nTruncate);
45044 memcpy(&aFrame[8], pWal->hdr.aSalt, 8);
45046 nativeCksum = (pWal->hdr.bigEndCksum==SQLITE_BIGENDIAN);
45047 walChecksumBytes(nativeCksum, aFrame, 8, aCksum, aCksum);
45048 walChecksumBytes(nativeCksum, aData, pWal->szPage, aCksum, aCksum);
45050 sqlite3Put4byte(&aFrame[16], aCksum[0]);
45051 sqlite3Put4byte(&aFrame[20], aCksum[1]);
45055 ** Check to see if the frame with header in aFrame[] and content
45056 ** in aData[] is valid. If it is a valid frame, fill *piPage and
45057 ** *pnTruncate and return true. Return if the frame is not valid.
45059 static int walDecodeFrame(
45060 Wal *pWal, /* The write-ahead log */
45061 u32 *piPage, /* OUT: Database page number for frame */
45062 u32 *pnTruncate, /* OUT: New db size (or 0 if not commit) */
45063 u8 *aData, /* Pointer to page data (for checksum) */
45064 u8 *aFrame /* Frame data */
45066 int nativeCksum; /* True for native byte-order checksums */
45067 u32 *aCksum = pWal->hdr.aFrameCksum;
45068 u32 pgno; /* Page number of the frame */
45069 assert( WAL_FRAME_HDRSIZE==24 );
45071 /* A frame is only valid if the salt values in the frame-header
45072 ** match the salt values in the wal-header.
45074 if( memcmp(&pWal->hdr.aSalt, &aFrame[8], 8)!=0 ){
45075 return 0;
45078 /* A frame is only valid if the page number is creater than zero.
45080 pgno = sqlite3Get4byte(&aFrame[0]);
45081 if( pgno==0 ){
45082 return 0;
45085 /* A frame is only valid if a checksum of the WAL header,
45086 ** all prior frams, the first 16 bytes of this frame-header,
45087 ** and the frame-data matches the checksum in the last 8
45088 ** bytes of this frame-header.
45090 nativeCksum = (pWal->hdr.bigEndCksum==SQLITE_BIGENDIAN);
45091 walChecksumBytes(nativeCksum, aFrame, 8, aCksum, aCksum);
45092 walChecksumBytes(nativeCksum, aData, pWal->szPage, aCksum, aCksum);
45093 if( aCksum[0]!=sqlite3Get4byte(&aFrame[16])
45094 || aCksum[1]!=sqlite3Get4byte(&aFrame[20])
45096 /* Checksum failed. */
45097 return 0;
45100 /* If we reach this point, the frame is valid. Return the page number
45101 ** and the new database size.
45103 *piPage = pgno;
45104 *pnTruncate = sqlite3Get4byte(&aFrame[4]);
45105 return 1;
45109 #if defined(SQLITE_TEST) && defined(SQLITE_DEBUG)
45111 ** Names of locks. This routine is used to provide debugging output and is not
45112 ** a part of an ordinary build.
45114 static const char *walLockName(int lockIdx){
45115 if( lockIdx==WAL_WRITE_LOCK ){
45116 return "WRITE-LOCK";
45117 }else if( lockIdx==WAL_CKPT_LOCK ){
45118 return "CKPT-LOCK";
45119 }else if( lockIdx==WAL_RECOVER_LOCK ){
45120 return "RECOVER-LOCK";
45121 }else{
45122 static char zName[15];
45123 sqlite3_snprintf(sizeof(zName), zName, "READ-LOCK[%d]",
45124 lockIdx-WAL_READ_LOCK(0));
45125 return zName;
45128 #endif /*defined(SQLITE_TEST) || defined(SQLITE_DEBUG) */
45132 ** Set or release locks on the WAL. Locks are either shared or exclusive.
45133 ** A lock cannot be moved directly between shared and exclusive - it must go
45134 ** through the unlocked state first.
45136 ** In locking_mode=EXCLUSIVE, all of these routines become no-ops.
45138 static int walLockShared(Wal *pWal, int lockIdx){
45139 int rc;
45140 if( pWal->exclusiveMode ) return SQLITE_OK;
45141 rc = sqlite3OsShmLock(pWal->pDbFd, lockIdx, 1,
45142 SQLITE_SHM_LOCK | SQLITE_SHM_SHARED);
45143 WALTRACE(("WAL%p: acquire SHARED-%s %s\n", pWal,
45144 walLockName(lockIdx), rc ? "failed" : "ok"));
45145 VVA_ONLY( pWal->lockError = (u8)(rc!=SQLITE_OK && rc!=SQLITE_BUSY); )
45146 return rc;
45148 static void walUnlockShared(Wal *pWal, int lockIdx){
45149 if( pWal->exclusiveMode ) return;
45150 (void)sqlite3OsShmLock(pWal->pDbFd, lockIdx, 1,
45151 SQLITE_SHM_UNLOCK | SQLITE_SHM_SHARED);
45152 WALTRACE(("WAL%p: release SHARED-%s\n", pWal, walLockName(lockIdx)));
45154 static int walLockExclusive(Wal *pWal, int lockIdx, int n){
45155 int rc;
45156 if( pWal->exclusiveMode ) return SQLITE_OK;
45157 rc = sqlite3OsShmLock(pWal->pDbFd, lockIdx, n,
45158 SQLITE_SHM_LOCK | SQLITE_SHM_EXCLUSIVE);
45159 WALTRACE(("WAL%p: acquire EXCLUSIVE-%s cnt=%d %s\n", pWal,
45160 walLockName(lockIdx), n, rc ? "failed" : "ok"));
45161 VVA_ONLY( pWal->lockError = (u8)(rc!=SQLITE_OK && rc!=SQLITE_BUSY); )
45162 return rc;
45164 static void walUnlockExclusive(Wal *pWal, int lockIdx, int n){
45165 if( pWal->exclusiveMode ) return;
45166 (void)sqlite3OsShmLock(pWal->pDbFd, lockIdx, n,
45167 SQLITE_SHM_UNLOCK | SQLITE_SHM_EXCLUSIVE);
45168 WALTRACE(("WAL%p: release EXCLUSIVE-%s cnt=%d\n", pWal,
45169 walLockName(lockIdx), n));
45173 ** Compute a hash on a page number. The resulting hash value must land
45174 ** between 0 and (HASHTABLE_NSLOT-1). The walHashNext() function advances
45175 ** the hash to the next value in the event of a collision.
45177 static int walHash(u32 iPage){
45178 assert( iPage>0 );
45179 assert( (HASHTABLE_NSLOT & (HASHTABLE_NSLOT-1))==0 );
45180 return (iPage*HASHTABLE_HASH_1) & (HASHTABLE_NSLOT-1);
45182 static int walNextHash(int iPriorHash){
45183 return (iPriorHash+1)&(HASHTABLE_NSLOT-1);
45187 ** Return pointers to the hash table and page number array stored on
45188 ** page iHash of the wal-index. The wal-index is broken into 32KB pages
45189 ** numbered starting from 0.
45191 ** Set output variable *paHash to point to the start of the hash table
45192 ** in the wal-index file. Set *piZero to one less than the frame
45193 ** number of the first frame indexed by this hash table. If a
45194 ** slot in the hash table is set to N, it refers to frame number
45195 ** (*piZero+N) in the log.
45197 ** Finally, set *paPgno so that *paPgno[1] is the page number of the
45198 ** first frame indexed by the hash table, frame (*piZero+1).
45200 static int walHashGet(
45201 Wal *pWal, /* WAL handle */
45202 int iHash, /* Find the iHash'th table */
45203 volatile ht_slot **paHash, /* OUT: Pointer to hash index */
45204 volatile u32 **paPgno, /* OUT: Pointer to page number array */
45205 u32 *piZero /* OUT: Frame associated with *paPgno[0] */
45207 int rc; /* Return code */
45208 volatile u32 *aPgno;
45210 rc = walIndexPage(pWal, iHash, &aPgno);
45211 assert( rc==SQLITE_OK || iHash>0 );
45213 if( rc==SQLITE_OK ){
45214 u32 iZero;
45215 volatile ht_slot *aHash;
45217 aHash = (volatile ht_slot *)&aPgno[HASHTABLE_NPAGE];
45218 if( iHash==0 ){
45219 aPgno = &aPgno[WALINDEX_HDR_SIZE/sizeof(u32)];
45220 iZero = 0;
45221 }else{
45222 iZero = HASHTABLE_NPAGE_ONE + (iHash-1)*HASHTABLE_NPAGE;
45225 *paPgno = &aPgno[-1];
45226 *paHash = aHash;
45227 *piZero = iZero;
45229 return rc;
45233 ** Return the number of the wal-index page that contains the hash-table
45234 ** and page-number array that contain entries corresponding to WAL frame
45235 ** iFrame. The wal-index is broken up into 32KB pages. Wal-index pages
45236 ** are numbered starting from 0.
45238 static int walFramePage(u32 iFrame){
45239 int iHash = (iFrame+HASHTABLE_NPAGE-HASHTABLE_NPAGE_ONE-1) / HASHTABLE_NPAGE;
45240 assert( (iHash==0 || iFrame>HASHTABLE_NPAGE_ONE)
45241 && (iHash>=1 || iFrame<=HASHTABLE_NPAGE_ONE)
45242 && (iHash<=1 || iFrame>(HASHTABLE_NPAGE_ONE+HASHTABLE_NPAGE))
45243 && (iHash>=2 || iFrame<=HASHTABLE_NPAGE_ONE+HASHTABLE_NPAGE)
45244 && (iHash<=2 || iFrame>(HASHTABLE_NPAGE_ONE+2*HASHTABLE_NPAGE))
45246 return iHash;
45250 ** Return the page number associated with frame iFrame in this WAL.
45252 static u32 walFramePgno(Wal *pWal, u32 iFrame){
45253 int iHash = walFramePage(iFrame);
45254 if( iHash==0 ){
45255 return pWal->apWiData[0][WALINDEX_HDR_SIZE/sizeof(u32) + iFrame - 1];
45257 return pWal->apWiData[iHash][(iFrame-1-HASHTABLE_NPAGE_ONE)%HASHTABLE_NPAGE];
45261 ** Remove entries from the hash table that point to WAL slots greater
45262 ** than pWal->hdr.mxFrame.
45264 ** This function is called whenever pWal->hdr.mxFrame is decreased due
45265 ** to a rollback or savepoint.
45267 ** At most only the hash table containing pWal->hdr.mxFrame needs to be
45268 ** updated. Any later hash tables will be automatically cleared when
45269 ** pWal->hdr.mxFrame advances to the point where those hash tables are
45270 ** actually needed.
45272 static void walCleanupHash(Wal *pWal){
45273 volatile ht_slot *aHash = 0; /* Pointer to hash table to clear */
45274 volatile u32 *aPgno = 0; /* Page number array for hash table */
45275 u32 iZero = 0; /* frame == (aHash[x]+iZero) */
45276 int iLimit = 0; /* Zero values greater than this */
45277 int nByte; /* Number of bytes to zero in aPgno[] */
45278 int i; /* Used to iterate through aHash[] */
45280 assert( pWal->writeLock );
45281 testcase( pWal->hdr.mxFrame==HASHTABLE_NPAGE_ONE-1 );
45282 testcase( pWal->hdr.mxFrame==HASHTABLE_NPAGE_ONE );
45283 testcase( pWal->hdr.mxFrame==HASHTABLE_NPAGE_ONE+1 );
45285 if( pWal->hdr.mxFrame==0 ) return;
45287 /* Obtain pointers to the hash-table and page-number array containing
45288 ** the entry that corresponds to frame pWal->hdr.mxFrame. It is guaranteed
45289 ** that the page said hash-table and array reside on is already mapped.
45291 assert( pWal->nWiData>walFramePage(pWal->hdr.mxFrame) );
45292 assert( pWal->apWiData[walFramePage(pWal->hdr.mxFrame)] );
45293 walHashGet(pWal, walFramePage(pWal->hdr.mxFrame), &aHash, &aPgno, &iZero);
45295 /* Zero all hash-table entries that correspond to frame numbers greater
45296 ** than pWal->hdr.mxFrame.
45298 iLimit = pWal->hdr.mxFrame - iZero;
45299 assert( iLimit>0 );
45300 for(i=0; i<HASHTABLE_NSLOT; i++){
45301 if( aHash[i]>iLimit ){
45302 aHash[i] = 0;
45306 /* Zero the entries in the aPgno array that correspond to frames with
45307 ** frame numbers greater than pWal->hdr.mxFrame.
45309 nByte = (int)((char *)aHash - (char *)&aPgno[iLimit+1]);
45310 memset((void *)&aPgno[iLimit+1], 0, nByte);
45312 #ifdef SQLITE_ENABLE_EXPENSIVE_ASSERT
45313 /* Verify that the every entry in the mapping region is still reachable
45314 ** via the hash table even after the cleanup.
45316 if( iLimit ){
45317 int i; /* Loop counter */
45318 int iKey; /* Hash key */
45319 for(i=1; i<=iLimit; i++){
45320 for(iKey=walHash(aPgno[i]); aHash[iKey]; iKey=walNextHash(iKey)){
45321 if( aHash[iKey]==i ) break;
45323 assert( aHash[iKey]==i );
45326 #endif /* SQLITE_ENABLE_EXPENSIVE_ASSERT */
45331 ** Set an entry in the wal-index that will map database page number
45332 ** pPage into WAL frame iFrame.
45334 static int walIndexAppend(Wal *pWal, u32 iFrame, u32 iPage){
45335 int rc; /* Return code */
45336 u32 iZero = 0; /* One less than frame number of aPgno[1] */
45337 volatile u32 *aPgno = 0; /* Page number array */
45338 volatile ht_slot *aHash = 0; /* Hash table */
45340 rc = walHashGet(pWal, walFramePage(iFrame), &aHash, &aPgno, &iZero);
45342 /* Assuming the wal-index file was successfully mapped, populate the
45343 ** page number array and hash table entry.
45345 if( rc==SQLITE_OK ){
45346 int iKey; /* Hash table key */
45347 int idx; /* Value to write to hash-table slot */
45348 int nCollide; /* Number of hash collisions */
45350 idx = iFrame - iZero;
45351 assert( idx <= HASHTABLE_NSLOT/2 + 1 );
45353 /* If this is the first entry to be added to this hash-table, zero the
45354 ** entire hash table and aPgno[] array before proceding.
45356 if( idx==1 ){
45357 int nByte = (int)((u8 *)&aHash[HASHTABLE_NSLOT] - (u8 *)&aPgno[1]);
45358 memset((void*)&aPgno[1], 0, nByte);
45361 /* If the entry in aPgno[] is already set, then the previous writer
45362 ** must have exited unexpectedly in the middle of a transaction (after
45363 ** writing one or more dirty pages to the WAL to free up memory).
45364 ** Remove the remnants of that writers uncommitted transaction from
45365 ** the hash-table before writing any new entries.
45367 if( aPgno[idx] ){
45368 walCleanupHash(pWal);
45369 assert( !aPgno[idx] );
45372 /* Write the aPgno[] array entry and the hash-table slot. */
45373 nCollide = idx;
45374 for(iKey=walHash(iPage); aHash[iKey]; iKey=walNextHash(iKey)){
45375 if( (nCollide--)==0 ) return SQLITE_CORRUPT_BKPT;
45377 aPgno[idx] = iPage;
45378 aHash[iKey] = (ht_slot)idx;
45380 #ifdef SQLITE_ENABLE_EXPENSIVE_ASSERT
45381 /* Verify that the number of entries in the hash table exactly equals
45382 ** the number of entries in the mapping region.
45385 int i; /* Loop counter */
45386 int nEntry = 0; /* Number of entries in the hash table */
45387 for(i=0; i<HASHTABLE_NSLOT; i++){ if( aHash[i] ) nEntry++; }
45388 assert( nEntry==idx );
45391 /* Verify that the every entry in the mapping region is reachable
45392 ** via the hash table. This turns out to be a really, really expensive
45393 ** thing to check, so only do this occasionally - not on every
45394 ** iteration.
45396 if( (idx&0x3ff)==0 ){
45397 int i; /* Loop counter */
45398 for(i=1; i<=idx; i++){
45399 for(iKey=walHash(aPgno[i]); aHash[iKey]; iKey=walNextHash(iKey)){
45400 if( aHash[iKey]==i ) break;
45402 assert( aHash[iKey]==i );
45405 #endif /* SQLITE_ENABLE_EXPENSIVE_ASSERT */
45409 return rc;
45414 ** Recover the wal-index by reading the write-ahead log file.
45416 ** This routine first tries to establish an exclusive lock on the
45417 ** wal-index to prevent other threads/processes from doing anything
45418 ** with the WAL or wal-index while recovery is running. The
45419 ** WAL_RECOVER_LOCK is also held so that other threads will know
45420 ** that this thread is running recovery. If unable to establish
45421 ** the necessary locks, this routine returns SQLITE_BUSY.
45423 static int walIndexRecover(Wal *pWal){
45424 int rc; /* Return Code */
45425 i64 nSize; /* Size of log file */
45426 u32 aFrameCksum[2] = {0, 0};
45427 int iLock; /* Lock offset to lock for checkpoint */
45428 int nLock; /* Number of locks to hold */
45430 /* Obtain an exclusive lock on all byte in the locking range not already
45431 ** locked by the caller. The caller is guaranteed to have locked the
45432 ** WAL_WRITE_LOCK byte, and may have also locked the WAL_CKPT_LOCK byte.
45433 ** If successful, the same bytes that are locked here are unlocked before
45434 ** this function returns.
45436 assert( pWal->ckptLock==1 || pWal->ckptLock==0 );
45437 assert( WAL_ALL_BUT_WRITE==WAL_WRITE_LOCK+1 );
45438 assert( WAL_CKPT_LOCK==WAL_ALL_BUT_WRITE );
45439 assert( pWal->writeLock );
45440 iLock = WAL_ALL_BUT_WRITE + pWal->ckptLock;
45441 nLock = SQLITE_SHM_NLOCK - iLock;
45442 rc = walLockExclusive(pWal, iLock, nLock);
45443 if( rc ){
45444 return rc;
45446 WALTRACE(("WAL%p: recovery begin...\n", pWal));
45448 memset(&pWal->hdr, 0, sizeof(WalIndexHdr));
45450 rc = sqlite3OsFileSize(pWal->pWalFd, &nSize);
45451 if( rc!=SQLITE_OK ){
45452 goto recovery_error;
45455 if( nSize>WAL_HDRSIZE ){
45456 u8 aBuf[WAL_HDRSIZE]; /* Buffer to load WAL header into */
45457 u8 *aFrame = 0; /* Malloc'd buffer to load entire frame */
45458 int szFrame; /* Number of bytes in buffer aFrame[] */
45459 u8 *aData; /* Pointer to data part of aFrame buffer */
45460 int iFrame; /* Index of last frame read */
45461 i64 iOffset; /* Next offset to read from log file */
45462 int szPage; /* Page size according to the log */
45463 u32 magic; /* Magic value read from WAL header */
45464 u32 version; /* Magic value read from WAL header */
45466 /* Read in the WAL header. */
45467 rc = sqlite3OsRead(pWal->pWalFd, aBuf, WAL_HDRSIZE, 0);
45468 if( rc!=SQLITE_OK ){
45469 goto recovery_error;
45472 /* If the database page size is not a power of two, or is greater than
45473 ** SQLITE_MAX_PAGE_SIZE, conclude that the WAL file contains no valid
45474 ** data. Similarly, if the 'magic' value is invalid, ignore the whole
45475 ** WAL file.
45477 magic = sqlite3Get4byte(&aBuf[0]);
45478 szPage = sqlite3Get4byte(&aBuf[8]);
45479 if( (magic&0xFFFFFFFE)!=WAL_MAGIC
45480 || szPage&(szPage-1)
45481 || szPage>SQLITE_MAX_PAGE_SIZE
45482 || szPage<512
45484 goto finished;
45486 pWal->hdr.bigEndCksum = (u8)(magic&0x00000001);
45487 pWal->szPage = szPage;
45488 pWal->nCkpt = sqlite3Get4byte(&aBuf[12]);
45489 memcpy(&pWal->hdr.aSalt, &aBuf[16], 8);
45491 /* Verify that the WAL header checksum is correct */
45492 walChecksumBytes(pWal->hdr.bigEndCksum==SQLITE_BIGENDIAN,
45493 aBuf, WAL_HDRSIZE-2*4, 0, pWal->hdr.aFrameCksum
45495 if( pWal->hdr.aFrameCksum[0]!=sqlite3Get4byte(&aBuf[24])
45496 || pWal->hdr.aFrameCksum[1]!=sqlite3Get4byte(&aBuf[28])
45498 goto finished;
45501 /* Verify that the version number on the WAL format is one that
45502 ** are able to understand */
45503 version = sqlite3Get4byte(&aBuf[4]);
45504 if( version!=WAL_MAX_VERSION ){
45505 rc = SQLITE_CANTOPEN_BKPT;
45506 goto finished;
45509 /* Malloc a buffer to read frames into. */
45510 szFrame = szPage + WAL_FRAME_HDRSIZE;
45511 aFrame = (u8 *)sqlite3_malloc(szFrame);
45512 if( !aFrame ){
45513 rc = SQLITE_NOMEM;
45514 goto recovery_error;
45516 aData = &aFrame[WAL_FRAME_HDRSIZE];
45518 /* Read all frames from the log file. */
45519 iFrame = 0;
45520 for(iOffset=WAL_HDRSIZE; (iOffset+szFrame)<=nSize; iOffset+=szFrame){
45521 u32 pgno; /* Database page number for frame */
45522 u32 nTruncate; /* dbsize field from frame header */
45523 int isValid; /* True if this frame is valid */
45525 /* Read and decode the next log frame. */
45526 rc = sqlite3OsRead(pWal->pWalFd, aFrame, szFrame, iOffset);
45527 if( rc!=SQLITE_OK ) break;
45528 isValid = walDecodeFrame(pWal, &pgno, &nTruncate, aData, aFrame);
45529 if( !isValid ) break;
45530 rc = walIndexAppend(pWal, ++iFrame, pgno);
45531 if( rc!=SQLITE_OK ) break;
45533 /* If nTruncate is non-zero, this is a commit record. */
45534 if( nTruncate ){
45535 pWal->hdr.mxFrame = iFrame;
45536 pWal->hdr.nPage = nTruncate;
45537 pWal->hdr.szPage = (u16)((szPage&0xff00) | (szPage>>16));
45538 testcase( szPage<=32768 );
45539 testcase( szPage>=65536 );
45540 aFrameCksum[0] = pWal->hdr.aFrameCksum[0];
45541 aFrameCksum[1] = pWal->hdr.aFrameCksum[1];
45545 sqlite3_free(aFrame);
45548 finished:
45549 if( rc==SQLITE_OK ){
45550 volatile WalCkptInfo *pInfo;
45551 int i;
45552 pWal->hdr.aFrameCksum[0] = aFrameCksum[0];
45553 pWal->hdr.aFrameCksum[1] = aFrameCksum[1];
45554 walIndexWriteHdr(pWal);
45556 /* Reset the checkpoint-header. This is safe because this thread is
45557 ** currently holding locks that exclude all other readers, writers and
45558 ** checkpointers.
45560 pInfo = walCkptInfo(pWal);
45561 pInfo->nBackfill = 0;
45562 pInfo->aReadMark[0] = 0;
45563 for(i=1; i<WAL_NREADER; i++) pInfo->aReadMark[i] = READMARK_NOT_USED;
45565 /* If more than one frame was recovered from the log file, report an
45566 ** event via sqlite3_log(). This is to help with identifying performance
45567 ** problems caused by applications routinely shutting down without
45568 ** checkpointing the log file.
45570 if( pWal->hdr.nPage ){
45571 sqlite3_log(SQLITE_OK, "Recovered %d frames from WAL file %s",
45572 pWal->hdr.nPage, pWal->zWalName
45577 recovery_error:
45578 WALTRACE(("WAL%p: recovery %s\n", pWal, rc ? "failed" : "ok"));
45579 walUnlockExclusive(pWal, iLock, nLock);
45580 return rc;
45584 ** Close an open wal-index.
45586 static void walIndexClose(Wal *pWal, int isDelete){
45587 if( pWal->exclusiveMode==WAL_HEAPMEMORY_MODE ){
45588 int i;
45589 for(i=0; i<pWal->nWiData; i++){
45590 sqlite3_free((void *)pWal->apWiData[i]);
45591 pWal->apWiData[i] = 0;
45593 }else{
45594 sqlite3OsShmUnmap(pWal->pDbFd, isDelete);
45599 ** Open a connection to the WAL file zWalName. The database file must
45600 ** already be opened on connection pDbFd. The buffer that zWalName points
45601 ** to must remain valid for the lifetime of the returned Wal* handle.
45603 ** A SHARED lock should be held on the database file when this function
45604 ** is called. The purpose of this SHARED lock is to prevent any other
45605 ** client from unlinking the WAL or wal-index file. If another process
45606 ** were to do this just after this client opened one of these files, the
45607 ** system would be badly broken.
45609 ** If the log file is successfully opened, SQLITE_OK is returned and
45610 ** *ppWal is set to point to a new WAL handle. If an error occurs,
45611 ** an SQLite error code is returned and *ppWal is left unmodified.
45613 SQLITE_PRIVATE int sqlite3WalOpen(
45614 sqlite3_vfs *pVfs, /* vfs module to open wal and wal-index */
45615 sqlite3_file *pDbFd, /* The open database file */
45616 const char *zWalName, /* Name of the WAL file */
45617 int bNoShm, /* True to run in heap-memory mode */
45618 i64 mxWalSize, /* Truncate WAL to this size on reset */
45619 Wal **ppWal /* OUT: Allocated Wal handle */
45621 int rc; /* Return Code */
45622 Wal *pRet; /* Object to allocate and return */
45623 int flags; /* Flags passed to OsOpen() */
45625 assert( zWalName && zWalName[0] );
45626 assert( pDbFd );
45628 /* In the amalgamation, the os_unix.c and os_win.c source files come before
45629 ** this source file. Verify that the #defines of the locking byte offsets
45630 ** in os_unix.c and os_win.c agree with the WALINDEX_LOCK_OFFSET value.
45632 #ifdef WIN_SHM_BASE
45633 assert( WIN_SHM_BASE==WALINDEX_LOCK_OFFSET );
45634 #endif
45635 #ifdef UNIX_SHM_BASE
45636 assert( UNIX_SHM_BASE==WALINDEX_LOCK_OFFSET );
45637 #endif
45640 /* Allocate an instance of struct Wal to return. */
45641 *ppWal = 0;
45642 pRet = (Wal*)sqlite3MallocZero(sizeof(Wal) + pVfs->szOsFile);
45643 if( !pRet ){
45644 return SQLITE_NOMEM;
45647 pRet->pVfs = pVfs;
45648 pRet->pWalFd = (sqlite3_file *)&pRet[1];
45649 pRet->pDbFd = pDbFd;
45650 pRet->readLock = -1;
45651 pRet->mxWalSize = mxWalSize;
45652 pRet->zWalName = zWalName;
45653 pRet->exclusiveMode = (bNoShm ? WAL_HEAPMEMORY_MODE: WAL_NORMAL_MODE);
45655 /* Open file handle on the write-ahead log file. */
45656 flags = (SQLITE_OPEN_READWRITE|SQLITE_OPEN_CREATE|SQLITE_OPEN_WAL);
45657 rc = sqlite3OsOpen(pVfs, zWalName, pRet->pWalFd, flags, &flags);
45658 if( rc==SQLITE_OK && flags&SQLITE_OPEN_READONLY ){
45659 pRet->readOnly = WAL_RDONLY;
45662 if( rc!=SQLITE_OK ){
45663 walIndexClose(pRet, 0);
45664 sqlite3OsClose(pRet->pWalFd);
45665 sqlite3_free(pRet);
45666 }else{
45667 *ppWal = pRet;
45668 WALTRACE(("WAL%d: opened\n", pRet));
45670 return rc;
45674 ** Change the size to which the WAL file is trucated on each reset.
45676 SQLITE_PRIVATE void sqlite3WalLimit(Wal *pWal, i64 iLimit){
45677 if( pWal ) pWal->mxWalSize = iLimit;
45681 ** Find the smallest page number out of all pages held in the WAL that
45682 ** has not been returned by any prior invocation of this method on the
45683 ** same WalIterator object. Write into *piFrame the frame index where
45684 ** that page was last written into the WAL. Write into *piPage the page
45685 ** number.
45687 ** Return 0 on success. If there are no pages in the WAL with a page
45688 ** number larger than *piPage, then return 1.
45690 static int walIteratorNext(
45691 WalIterator *p, /* Iterator */
45692 u32 *piPage, /* OUT: The page number of the next page */
45693 u32 *piFrame /* OUT: Wal frame index of next page */
45695 u32 iMin; /* Result pgno must be greater than iMin */
45696 u32 iRet = 0xFFFFFFFF; /* 0xffffffff is never a valid page number */
45697 int i; /* For looping through segments */
45699 iMin = p->iPrior;
45700 assert( iMin<0xffffffff );
45701 for(i=p->nSegment-1; i>=0; i--){
45702 struct WalSegment *pSegment = &p->aSegment[i];
45703 while( pSegment->iNext<pSegment->nEntry ){
45704 u32 iPg = pSegment->aPgno[pSegment->aIndex[pSegment->iNext]];
45705 if( iPg>iMin ){
45706 if( iPg<iRet ){
45707 iRet = iPg;
45708 *piFrame = pSegment->iZero + pSegment->aIndex[pSegment->iNext];
45710 break;
45712 pSegment->iNext++;
45716 *piPage = p->iPrior = iRet;
45717 return (iRet==0xFFFFFFFF);
45721 ** This function merges two sorted lists into a single sorted list.
45723 ** aLeft[] and aRight[] are arrays of indices. The sort key is
45724 ** aContent[aLeft[]] and aContent[aRight[]]. Upon entry, the following
45725 ** is guaranteed for all J<K:
45727 ** aContent[aLeft[J]] < aContent[aLeft[K]]
45728 ** aContent[aRight[J]] < aContent[aRight[K]]
45730 ** This routine overwrites aRight[] with a new (probably longer) sequence
45731 ** of indices such that the aRight[] contains every index that appears in
45732 ** either aLeft[] or the old aRight[] and such that the second condition
45733 ** above is still met.
45735 ** The aContent[aLeft[X]] values will be unique for all X. And the
45736 ** aContent[aRight[X]] values will be unique too. But there might be
45737 ** one or more combinations of X and Y such that
45739 ** aLeft[X]!=aRight[Y] && aContent[aLeft[X]] == aContent[aRight[Y]]
45741 ** When that happens, omit the aLeft[X] and use the aRight[Y] index.
45743 static void walMerge(
45744 const u32 *aContent, /* Pages in wal - keys for the sort */
45745 ht_slot *aLeft, /* IN: Left hand input list */
45746 int nLeft, /* IN: Elements in array *paLeft */
45747 ht_slot **paRight, /* IN/OUT: Right hand input list */
45748 int *pnRight, /* IN/OUT: Elements in *paRight */
45749 ht_slot *aTmp /* Temporary buffer */
45751 int iLeft = 0; /* Current index in aLeft */
45752 int iRight = 0; /* Current index in aRight */
45753 int iOut = 0; /* Current index in output buffer */
45754 int nRight = *pnRight;
45755 ht_slot *aRight = *paRight;
45757 assert( nLeft>0 && nRight>0 );
45758 while( iRight<nRight || iLeft<nLeft ){
45759 ht_slot logpage;
45760 Pgno dbpage;
45762 if( (iLeft<nLeft)
45763 && (iRight>=nRight || aContent[aLeft[iLeft]]<aContent[aRight[iRight]])
45765 logpage = aLeft[iLeft++];
45766 }else{
45767 logpage = aRight[iRight++];
45769 dbpage = aContent[logpage];
45771 aTmp[iOut++] = logpage;
45772 if( iLeft<nLeft && aContent[aLeft[iLeft]]==dbpage ) iLeft++;
45774 assert( iLeft>=nLeft || aContent[aLeft[iLeft]]>dbpage );
45775 assert( iRight>=nRight || aContent[aRight[iRight]]>dbpage );
45778 *paRight = aLeft;
45779 *pnRight = iOut;
45780 memcpy(aLeft, aTmp, sizeof(aTmp[0])*iOut);
45784 ** Sort the elements in list aList using aContent[] as the sort key.
45785 ** Remove elements with duplicate keys, preferring to keep the
45786 ** larger aList[] values.
45788 ** The aList[] entries are indices into aContent[]. The values in
45789 ** aList[] are to be sorted so that for all J<K:
45791 ** aContent[aList[J]] < aContent[aList[K]]
45793 ** For any X and Y such that
45795 ** aContent[aList[X]] == aContent[aList[Y]]
45797 ** Keep the larger of the two values aList[X] and aList[Y] and discard
45798 ** the smaller.
45800 static void walMergesort(
45801 const u32 *aContent, /* Pages in wal */
45802 ht_slot *aBuffer, /* Buffer of at least *pnList items to use */
45803 ht_slot *aList, /* IN/OUT: List to sort */
45804 int *pnList /* IN/OUT: Number of elements in aList[] */
45806 struct Sublist {
45807 int nList; /* Number of elements in aList */
45808 ht_slot *aList; /* Pointer to sub-list content */
45811 const int nList = *pnList; /* Size of input list */
45812 int nMerge = 0; /* Number of elements in list aMerge */
45813 ht_slot *aMerge = 0; /* List to be merged */
45814 int iList; /* Index into input list */
45815 int iSub = 0; /* Index into aSub array */
45816 struct Sublist aSub[13]; /* Array of sub-lists */
45818 memset(aSub, 0, sizeof(aSub));
45819 assert( nList<=HASHTABLE_NPAGE && nList>0 );
45820 assert( HASHTABLE_NPAGE==(1<<(ArraySize(aSub)-1)) );
45822 for(iList=0; iList<nList; iList++){
45823 nMerge = 1;
45824 aMerge = &aList[iList];
45825 for(iSub=0; iList & (1<<iSub); iSub++){
45826 struct Sublist *p = &aSub[iSub];
45827 assert( p->aList && p->nList<=(1<<iSub) );
45828 assert( p->aList==&aList[iList&~((2<<iSub)-1)] );
45829 walMerge(aContent, p->aList, p->nList, &aMerge, &nMerge, aBuffer);
45831 aSub[iSub].aList = aMerge;
45832 aSub[iSub].nList = nMerge;
45835 for(iSub++; iSub<ArraySize(aSub); iSub++){
45836 if( nList & (1<<iSub) ){
45837 struct Sublist *p = &aSub[iSub];
45838 assert( p->nList<=(1<<iSub) );
45839 assert( p->aList==&aList[nList&~((2<<iSub)-1)] );
45840 walMerge(aContent, p->aList, p->nList, &aMerge, &nMerge, aBuffer);
45843 assert( aMerge==aList );
45844 *pnList = nMerge;
45846 #ifdef SQLITE_DEBUG
45848 int i;
45849 for(i=1; i<*pnList; i++){
45850 assert( aContent[aList[i]] > aContent[aList[i-1]] );
45853 #endif
45857 ** Free an iterator allocated by walIteratorInit().
45859 static void walIteratorFree(WalIterator *p){
45860 sqlite3ScratchFree(p);
45864 ** Construct a WalInterator object that can be used to loop over all
45865 ** pages in the WAL in ascending order. The caller must hold the checkpoint
45866 ** lock.
45868 ** On success, make *pp point to the newly allocated WalInterator object
45869 ** return SQLITE_OK. Otherwise, return an error code. If this routine
45870 ** returns an error, the value of *pp is undefined.
45872 ** The calling routine should invoke walIteratorFree() to destroy the
45873 ** WalIterator object when it has finished with it.
45875 static int walIteratorInit(Wal *pWal, WalIterator **pp){
45876 WalIterator *p; /* Return value */
45877 int nSegment; /* Number of segments to merge */
45878 u32 iLast; /* Last frame in log */
45879 int nByte; /* Number of bytes to allocate */
45880 int i; /* Iterator variable */
45881 ht_slot *aTmp; /* Temp space used by merge-sort */
45882 int rc = SQLITE_OK; /* Return Code */
45884 /* This routine only runs while holding the checkpoint lock. And
45885 ** it only runs if there is actually content in the log (mxFrame>0).
45887 assert( pWal->ckptLock && pWal->hdr.mxFrame>0 );
45888 iLast = pWal->hdr.mxFrame;
45890 /* Allocate space for the WalIterator object. */
45891 nSegment = walFramePage(iLast) + 1;
45892 nByte = sizeof(WalIterator)
45893 + (nSegment-1)*sizeof(struct WalSegment)
45894 + iLast*sizeof(ht_slot);
45895 p = (WalIterator *)sqlite3ScratchMalloc(nByte);
45896 if( !p ){
45897 return SQLITE_NOMEM;
45899 memset(p, 0, nByte);
45900 p->nSegment = nSegment;
45902 /* Allocate temporary space used by the merge-sort routine. This block
45903 ** of memory will be freed before this function returns.
45905 aTmp = (ht_slot *)sqlite3ScratchMalloc(
45906 sizeof(ht_slot) * (iLast>HASHTABLE_NPAGE?HASHTABLE_NPAGE:iLast)
45908 if( !aTmp ){
45909 rc = SQLITE_NOMEM;
45912 for(i=0; rc==SQLITE_OK && i<nSegment; i++){
45913 volatile ht_slot *aHash;
45914 u32 iZero;
45915 volatile u32 *aPgno;
45917 rc = walHashGet(pWal, i, &aHash, &aPgno, &iZero);
45918 if( rc==SQLITE_OK ){
45919 int j; /* Counter variable */
45920 int nEntry; /* Number of entries in this segment */
45921 ht_slot *aIndex; /* Sorted index for this segment */
45923 aPgno++;
45924 if( (i+1)==nSegment ){
45925 nEntry = (int)(iLast - iZero);
45926 }else{
45927 nEntry = (int)((u32*)aHash - (u32*)aPgno);
45929 aIndex = &((ht_slot *)&p->aSegment[p->nSegment])[iZero];
45930 iZero++;
45932 for(j=0; j<nEntry; j++){
45933 aIndex[j] = (ht_slot)j;
45935 walMergesort((u32 *)aPgno, aTmp, aIndex, &nEntry);
45936 p->aSegment[i].iZero = iZero;
45937 p->aSegment[i].nEntry = nEntry;
45938 p->aSegment[i].aIndex = aIndex;
45939 p->aSegment[i].aPgno = (u32 *)aPgno;
45942 sqlite3ScratchFree(aTmp);
45944 if( rc!=SQLITE_OK ){
45945 walIteratorFree(p);
45947 *pp = p;
45948 return rc;
45952 ** Attempt to obtain the exclusive WAL lock defined by parameters lockIdx and
45953 ** n. If the attempt fails and parameter xBusy is not NULL, then it is a
45954 ** busy-handler function. Invoke it and retry the lock until either the
45955 ** lock is successfully obtained or the busy-handler returns 0.
45957 static int walBusyLock(
45958 Wal *pWal, /* WAL connection */
45959 int (*xBusy)(void*), /* Function to call when busy */
45960 void *pBusyArg, /* Context argument for xBusyHandler */
45961 int lockIdx, /* Offset of first byte to lock */
45962 int n /* Number of bytes to lock */
45964 int rc;
45965 do {
45966 rc = walLockExclusive(pWal, lockIdx, n);
45967 }while( xBusy && rc==SQLITE_BUSY && xBusy(pBusyArg) );
45968 return rc;
45972 ** The cache of the wal-index header must be valid to call this function.
45973 ** Return the page-size in bytes used by the database.
45975 static int walPagesize(Wal *pWal){
45976 return (pWal->hdr.szPage&0xfe00) + ((pWal->hdr.szPage&0x0001)<<16);
45980 ** Copy as much content as we can from the WAL back into the database file
45981 ** in response to an sqlite3_wal_checkpoint() request or the equivalent.
45983 ** The amount of information copies from WAL to database might be limited
45984 ** by active readers. This routine will never overwrite a database page
45985 ** that a concurrent reader might be using.
45987 ** All I/O barrier operations (a.k.a fsyncs) occur in this routine when
45988 ** SQLite is in WAL-mode in synchronous=NORMAL. That means that if
45989 ** checkpoints are always run by a background thread or background
45990 ** process, foreground threads will never block on a lengthy fsync call.
45992 ** Fsync is called on the WAL before writing content out of the WAL and
45993 ** into the database. This ensures that if the new content is persistent
45994 ** in the WAL and can be recovered following a power-loss or hard reset.
45996 ** Fsync is also called on the database file if (and only if) the entire
45997 ** WAL content is copied into the database file. This second fsync makes
45998 ** it safe to delete the WAL since the new content will persist in the
45999 ** database file.
46001 ** This routine uses and updates the nBackfill field of the wal-index header.
46002 ** This is the only routine tha will increase the value of nBackfill.
46003 ** (A WAL reset or recovery will revert nBackfill to zero, but not increase
46004 ** its value.)
46006 ** The caller must be holding sufficient locks to ensure that no other
46007 ** checkpoint is running (in any other thread or process) at the same
46008 ** time.
46010 static int walCheckpoint(
46011 Wal *pWal, /* Wal connection */
46012 int eMode, /* One of PASSIVE, FULL or RESTART */
46013 int (*xBusyCall)(void*), /* Function to call when busy */
46014 void *pBusyArg, /* Context argument for xBusyHandler */
46015 int sync_flags, /* Flags for OsSync() (or 0) */
46016 u8 *zBuf /* Temporary buffer to use */
46018 int rc; /* Return code */
46019 int szPage; /* Database page-size */
46020 WalIterator *pIter = 0; /* Wal iterator context */
46021 u32 iDbpage = 0; /* Next database page to write */
46022 u32 iFrame = 0; /* Wal frame containing data for iDbpage */
46023 u32 mxSafeFrame; /* Max frame that can be backfilled */
46024 u32 mxPage; /* Max database page to write */
46025 int i; /* Loop counter */
46026 volatile WalCkptInfo *pInfo; /* The checkpoint status information */
46027 int (*xBusy)(void*) = 0; /* Function to call when waiting for locks */
46029 szPage = walPagesize(pWal);
46030 testcase( szPage<=32768 );
46031 testcase( szPage>=65536 );
46032 pInfo = walCkptInfo(pWal);
46033 if( pInfo->nBackfill>=pWal->hdr.mxFrame ) return SQLITE_OK;
46035 /* Allocate the iterator */
46036 rc = walIteratorInit(pWal, &pIter);
46037 if( rc!=SQLITE_OK ){
46038 return rc;
46040 assert( pIter );
46042 if( eMode!=SQLITE_CHECKPOINT_PASSIVE ) xBusy = xBusyCall;
46044 /* Compute in mxSafeFrame the index of the last frame of the WAL that is
46045 ** safe to write into the database. Frames beyond mxSafeFrame might
46046 ** overwrite database pages that are in use by active readers and thus
46047 ** cannot be backfilled from the WAL.
46049 mxSafeFrame = pWal->hdr.mxFrame;
46050 mxPage = pWal->hdr.nPage;
46051 for(i=1; i<WAL_NREADER; i++){
46052 u32 y = pInfo->aReadMark[i];
46053 if( mxSafeFrame>y ){
46054 assert( y<=pWal->hdr.mxFrame );
46055 rc = walBusyLock(pWal, xBusy, pBusyArg, WAL_READ_LOCK(i), 1);
46056 if( rc==SQLITE_OK ){
46057 pInfo->aReadMark[i] = READMARK_NOT_USED;
46058 walUnlockExclusive(pWal, WAL_READ_LOCK(i), 1);
46059 }else if( rc==SQLITE_BUSY ){
46060 mxSafeFrame = y;
46061 xBusy = 0;
46062 }else{
46063 goto walcheckpoint_out;
46068 if( pInfo->nBackfill<mxSafeFrame
46069 && (rc = walBusyLock(pWal, xBusy, pBusyArg, WAL_READ_LOCK(0), 1))==SQLITE_OK
46071 i64 nSize; /* Current size of database file */
46072 u32 nBackfill = pInfo->nBackfill;
46074 /* Sync the WAL to disk */
46075 if( sync_flags ){
46076 rc = sqlite3OsSync(pWal->pWalFd, sync_flags);
46079 /* If the database file may grow as a result of this checkpoint, hint
46080 ** about the eventual size of the db file to the VFS layer.
46082 if( rc==SQLITE_OK ){
46083 i64 nReq = ((i64)mxPage * szPage);
46084 rc = sqlite3OsFileSize(pWal->pDbFd, &nSize);
46085 if( rc==SQLITE_OK && nSize<nReq ){
46086 sqlite3OsFileControl(pWal->pDbFd, SQLITE_FCNTL_SIZE_HINT, &nReq);
46090 /* Iterate through the contents of the WAL, copying data to the db file. */
46091 while( rc==SQLITE_OK && 0==walIteratorNext(pIter, &iDbpage, &iFrame) ){
46092 i64 iOffset;
46093 assert( walFramePgno(pWal, iFrame)==iDbpage );
46094 if( iFrame<=nBackfill || iFrame>mxSafeFrame || iDbpage>mxPage ) continue;
46095 iOffset = walFrameOffset(iFrame, szPage) + WAL_FRAME_HDRSIZE;
46096 /* testcase( IS_BIG_INT(iOffset) ); // requires a 4GiB WAL file */
46097 rc = sqlite3OsRead(pWal->pWalFd, zBuf, szPage, iOffset);
46098 if( rc!=SQLITE_OK ) break;
46099 iOffset = (iDbpage-1)*(i64)szPage;
46100 testcase( IS_BIG_INT(iOffset) );
46101 rc = sqlite3OsWrite(pWal->pDbFd, zBuf, szPage, iOffset);
46102 if( rc!=SQLITE_OK ) break;
46105 /* If work was actually accomplished... */
46106 if( rc==SQLITE_OK ){
46107 if( mxSafeFrame==walIndexHdr(pWal)->mxFrame ){
46108 i64 szDb = pWal->hdr.nPage*(i64)szPage;
46109 testcase( IS_BIG_INT(szDb) );
46110 rc = sqlite3OsTruncate(pWal->pDbFd, szDb);
46111 if( rc==SQLITE_OK && sync_flags ){
46112 rc = sqlite3OsSync(pWal->pDbFd, sync_flags);
46115 if( rc==SQLITE_OK ){
46116 pInfo->nBackfill = mxSafeFrame;
46120 /* Release the reader lock held while backfilling */
46121 walUnlockExclusive(pWal, WAL_READ_LOCK(0), 1);
46124 if( rc==SQLITE_BUSY ){
46125 /* Reset the return code so as not to report a checkpoint failure
46126 ** just because there are active readers. */
46127 rc = SQLITE_OK;
46130 /* If this is an SQLITE_CHECKPOINT_RESTART operation, and the entire wal
46131 ** file has been copied into the database file, then block until all
46132 ** readers have finished using the wal file. This ensures that the next
46133 ** process to write to the database restarts the wal file.
46135 if( rc==SQLITE_OK && eMode!=SQLITE_CHECKPOINT_PASSIVE ){
46136 assert( pWal->writeLock );
46137 if( pInfo->nBackfill<pWal->hdr.mxFrame ){
46138 rc = SQLITE_BUSY;
46139 }else if( eMode==SQLITE_CHECKPOINT_RESTART ){
46140 assert( mxSafeFrame==pWal->hdr.mxFrame );
46141 rc = walBusyLock(pWal, xBusy, pBusyArg, WAL_READ_LOCK(1), WAL_NREADER-1);
46142 if( rc==SQLITE_OK ){
46143 walUnlockExclusive(pWal, WAL_READ_LOCK(1), WAL_NREADER-1);
46148 walcheckpoint_out:
46149 walIteratorFree(pIter);
46150 return rc;
46154 ** Close a connection to a log file.
46156 SQLITE_PRIVATE int sqlite3WalClose(
46157 Wal *pWal, /* Wal to close */
46158 int sync_flags, /* Flags to pass to OsSync() (or 0) */
46159 int nBuf,
46160 u8 *zBuf /* Buffer of at least nBuf bytes */
46162 int rc = SQLITE_OK;
46163 if( pWal ){
46164 int isDelete = 0; /* True to unlink wal and wal-index files */
46166 /* If an EXCLUSIVE lock can be obtained on the database file (using the
46167 ** ordinary, rollback-mode locking methods, this guarantees that the
46168 ** connection associated with this log file is the only connection to
46169 ** the database. In this case checkpoint the database and unlink both
46170 ** the wal and wal-index files.
46172 ** The EXCLUSIVE lock is not released before returning.
46174 rc = sqlite3OsLock(pWal->pDbFd, SQLITE_LOCK_EXCLUSIVE);
46175 if( rc==SQLITE_OK ){
46176 int bPersistWal = -1;
46177 if( pWal->exclusiveMode==WAL_NORMAL_MODE ){
46178 pWal->exclusiveMode = WAL_EXCLUSIVE_MODE;
46180 rc = sqlite3WalCheckpoint(
46181 pWal, SQLITE_CHECKPOINT_PASSIVE, 0, 0, sync_flags, nBuf, zBuf, 0, 0
46183 sqlite3OsFileControl(pWal->pDbFd, SQLITE_FCNTL_PERSIST_WAL, &bPersistWal);
46184 if( rc==SQLITE_OK && bPersistWal!=1 ){
46185 isDelete = 1;
46189 walIndexClose(pWal, isDelete);
46190 sqlite3OsClose(pWal->pWalFd);
46191 if( isDelete ){
46192 sqlite3OsDelete(pWal->pVfs, pWal->zWalName, 0);
46194 WALTRACE(("WAL%p: closed\n", pWal));
46195 sqlite3_free((void *)pWal->apWiData);
46196 sqlite3_free(pWal);
46198 return rc;
46202 ** Try to read the wal-index header. Return 0 on success and 1 if
46203 ** there is a problem.
46205 ** The wal-index is in shared memory. Another thread or process might
46206 ** be writing the header at the same time this procedure is trying to
46207 ** read it, which might result in inconsistency. A dirty read is detected
46208 ** by verifying that both copies of the header are the same and also by
46209 ** a checksum on the header.
46211 ** If and only if the read is consistent and the header is different from
46212 ** pWal->hdr, then pWal->hdr is updated to the content of the new header
46213 ** and *pChanged is set to 1.
46215 ** If the checksum cannot be verified return non-zero. If the header
46216 ** is read successfully and the checksum verified, return zero.
46218 static int walIndexTryHdr(Wal *pWal, int *pChanged){
46219 u32 aCksum[2]; /* Checksum on the header content */
46220 WalIndexHdr h1, h2; /* Two copies of the header content */
46221 WalIndexHdr volatile *aHdr; /* Header in shared memory */
46223 /* The first page of the wal-index must be mapped at this point. */
46224 assert( pWal->nWiData>0 && pWal->apWiData[0] );
46226 /* Read the header. This might happen concurrently with a write to the
46227 ** same area of shared memory on a different CPU in a SMP,
46228 ** meaning it is possible that an inconsistent snapshot is read
46229 ** from the file. If this happens, return non-zero.
46231 ** There are two copies of the header at the beginning of the wal-index.
46232 ** When reading, read [0] first then [1]. Writes are in the reverse order.
46233 ** Memory barriers are used to prevent the compiler or the hardware from
46234 ** reordering the reads and writes.
46236 aHdr = walIndexHdr(pWal);
46237 memcpy(&h1, (void *)&aHdr[0], sizeof(h1));
46238 walShmBarrier(pWal);
46239 memcpy(&h2, (void *)&aHdr[1], sizeof(h2));
46241 if( memcmp(&h1, &h2, sizeof(h1))!=0 ){
46242 return 1; /* Dirty read */
46244 if( h1.isInit==0 ){
46245 return 1; /* Malformed header - probably all zeros */
46247 walChecksumBytes(1, (u8*)&h1, sizeof(h1)-sizeof(h1.aCksum), 0, aCksum);
46248 if( aCksum[0]!=h1.aCksum[0] || aCksum[1]!=h1.aCksum[1] ){
46249 return 1; /* Checksum does not match */
46252 if( memcmp(&pWal->hdr, &h1, sizeof(WalIndexHdr)) ){
46253 *pChanged = 1;
46254 memcpy(&pWal->hdr, &h1, sizeof(WalIndexHdr));
46255 pWal->szPage = (pWal->hdr.szPage&0xfe00) + ((pWal->hdr.szPage&0x0001)<<16);
46256 testcase( pWal->szPage<=32768 );
46257 testcase( pWal->szPage>=65536 );
46260 /* The header was successfully read. Return zero. */
46261 return 0;
46265 ** Read the wal-index header from the wal-index and into pWal->hdr.
46266 ** If the wal-header appears to be corrupt, try to reconstruct the
46267 ** wal-index from the WAL before returning.
46269 ** Set *pChanged to 1 if the wal-index header value in pWal->hdr is
46270 ** changed by this opertion. If pWal->hdr is unchanged, set *pChanged
46271 ** to 0.
46273 ** If the wal-index header is successfully read, return SQLITE_OK.
46274 ** Otherwise an SQLite error code.
46276 static int walIndexReadHdr(Wal *pWal, int *pChanged){
46277 int rc; /* Return code */
46278 int badHdr; /* True if a header read failed */
46279 volatile u32 *page0; /* Chunk of wal-index containing header */
46281 /* Ensure that page 0 of the wal-index (the page that contains the
46282 ** wal-index header) is mapped. Return early if an error occurs here.
46284 assert( pChanged );
46285 rc = walIndexPage(pWal, 0, &page0);
46286 if( rc!=SQLITE_OK ){
46287 return rc;
46289 assert( page0 || pWal->writeLock==0 );
46291 /* If the first page of the wal-index has been mapped, try to read the
46292 ** wal-index header immediately, without holding any lock. This usually
46293 ** works, but may fail if the wal-index header is corrupt or currently
46294 ** being modified by another thread or process.
46296 badHdr = (page0 ? walIndexTryHdr(pWal, pChanged) : 1);
46298 /* If the first attempt failed, it might have been due to a race
46299 ** with a writer. So get a WRITE lock and try again.
46301 assert( badHdr==0 || pWal->writeLock==0 );
46302 if( badHdr ){
46303 if( pWal->readOnly & WAL_SHM_RDONLY ){
46304 if( SQLITE_OK==(rc = walLockShared(pWal, WAL_WRITE_LOCK)) ){
46305 walUnlockShared(pWal, WAL_WRITE_LOCK);
46306 rc = SQLITE_READONLY_RECOVERY;
46308 }else if( SQLITE_OK==(rc = walLockExclusive(pWal, WAL_WRITE_LOCK, 1)) ){
46309 pWal->writeLock = 1;
46310 if( SQLITE_OK==(rc = walIndexPage(pWal, 0, &page0)) ){
46311 badHdr = walIndexTryHdr(pWal, pChanged);
46312 if( badHdr ){
46313 /* If the wal-index header is still malformed even while holding
46314 ** a WRITE lock, it can only mean that the header is corrupted and
46315 ** needs to be reconstructed. So run recovery to do exactly that.
46317 rc = walIndexRecover(pWal);
46318 *pChanged = 1;
46321 pWal->writeLock = 0;
46322 walUnlockExclusive(pWal, WAL_WRITE_LOCK, 1);
46326 /* If the header is read successfully, check the version number to make
46327 ** sure the wal-index was not constructed with some future format that
46328 ** this version of SQLite cannot understand.
46330 if( badHdr==0 && pWal->hdr.iVersion!=WALINDEX_MAX_VERSION ){
46331 rc = SQLITE_CANTOPEN_BKPT;
46334 return rc;
46338 ** This is the value that walTryBeginRead returns when it needs to
46339 ** be retried.
46341 #define WAL_RETRY (-1)
46344 ** Attempt to start a read transaction. This might fail due to a race or
46345 ** other transient condition. When that happens, it returns WAL_RETRY to
46346 ** indicate to the caller that it is safe to retry immediately.
46348 ** On success return SQLITE_OK. On a permanent failure (such an
46349 ** I/O error or an SQLITE_BUSY because another process is running
46350 ** recovery) return a positive error code.
46352 ** The useWal parameter is true to force the use of the WAL and disable
46353 ** the case where the WAL is bypassed because it has been completely
46354 ** checkpointed. If useWal==0 then this routine calls walIndexReadHdr()
46355 ** to make a copy of the wal-index header into pWal->hdr. If the
46356 ** wal-index header has changed, *pChanged is set to 1 (as an indication
46357 ** to the caller that the local paget cache is obsolete and needs to be
46358 ** flushed.) When useWal==1, the wal-index header is assumed to already
46359 ** be loaded and the pChanged parameter is unused.
46361 ** The caller must set the cnt parameter to the number of prior calls to
46362 ** this routine during the current read attempt that returned WAL_RETRY.
46363 ** This routine will start taking more aggressive measures to clear the
46364 ** race conditions after multiple WAL_RETRY returns, and after an excessive
46365 ** number of errors will ultimately return SQLITE_PROTOCOL. The
46366 ** SQLITE_PROTOCOL return indicates that some other process has gone rogue
46367 ** and is not honoring the locking protocol. There is a vanishingly small
46368 ** chance that SQLITE_PROTOCOL could be returned because of a run of really
46369 ** bad luck when there is lots of contention for the wal-index, but that
46370 ** possibility is so small that it can be safely neglected, we believe.
46372 ** On success, this routine obtains a read lock on
46373 ** WAL_READ_LOCK(pWal->readLock). The pWal->readLock integer is
46374 ** in the range 0 <= pWal->readLock < WAL_NREADER. If pWal->readLock==(-1)
46375 ** that means the Wal does not hold any read lock. The reader must not
46376 ** access any database page that is modified by a WAL frame up to and
46377 ** including frame number aReadMark[pWal->readLock]. The reader will
46378 ** use WAL frames up to and including pWal->hdr.mxFrame if pWal->readLock>0
46379 ** Or if pWal->readLock==0, then the reader will ignore the WAL
46380 ** completely and get all content directly from the database file.
46381 ** If the useWal parameter is 1 then the WAL will never be ignored and
46382 ** this routine will always set pWal->readLock>0 on success.
46383 ** When the read transaction is completed, the caller must release the
46384 ** lock on WAL_READ_LOCK(pWal->readLock) and set pWal->readLock to -1.
46386 ** This routine uses the nBackfill and aReadMark[] fields of the header
46387 ** to select a particular WAL_READ_LOCK() that strives to let the
46388 ** checkpoint process do as much work as possible. This routine might
46389 ** update values of the aReadMark[] array in the header, but if it does
46390 ** so it takes care to hold an exclusive lock on the corresponding
46391 ** WAL_READ_LOCK() while changing values.
46393 static int walTryBeginRead(Wal *pWal, int *pChanged, int useWal, int cnt){
46394 volatile WalCkptInfo *pInfo; /* Checkpoint information in wal-index */
46395 u32 mxReadMark; /* Largest aReadMark[] value */
46396 int mxI; /* Index of largest aReadMark[] value */
46397 int i; /* Loop counter */
46398 int rc = SQLITE_OK; /* Return code */
46400 assert( pWal->readLock<0 ); /* Not currently locked */
46402 /* Take steps to avoid spinning forever if there is a protocol error.
46404 ** Circumstances that cause a RETRY should only last for the briefest
46405 ** instances of time. No I/O or other system calls are done while the
46406 ** locks are held, so the locks should not be held for very long. But
46407 ** if we are unlucky, another process that is holding a lock might get
46408 ** paged out or take a page-fault that is time-consuming to resolve,
46409 ** during the few nanoseconds that it is holding the lock. In that case,
46410 ** it might take longer than normal for the lock to free.
46412 ** After 5 RETRYs, we begin calling sqlite3OsSleep(). The first few
46413 ** calls to sqlite3OsSleep() have a delay of 1 microsecond. Really this
46414 ** is more of a scheduler yield than an actual delay. But on the 10th
46415 ** an subsequent retries, the delays start becoming longer and longer,
46416 ** so that on the 100th (and last) RETRY we delay for 21 milliseconds.
46417 ** The total delay time before giving up is less than 1 second.
46419 if( cnt>5 ){
46420 int nDelay = 1; /* Pause time in microseconds */
46421 if( cnt>100 ){
46422 VVA_ONLY( pWal->lockError = 1; )
46423 return SQLITE_PROTOCOL;
46425 if( cnt>=10 ) nDelay = (cnt-9)*238; /* Max delay 21ms. Total delay 996ms */
46426 sqlite3OsSleep(pWal->pVfs, nDelay);
46429 if( !useWal ){
46430 rc = walIndexReadHdr(pWal, pChanged);
46431 if( rc==SQLITE_BUSY ){
46432 /* If there is not a recovery running in another thread or process
46433 ** then convert BUSY errors to WAL_RETRY. If recovery is known to
46434 ** be running, convert BUSY to BUSY_RECOVERY. There is a race here
46435 ** which might cause WAL_RETRY to be returned even if BUSY_RECOVERY
46436 ** would be technically correct. But the race is benign since with
46437 ** WAL_RETRY this routine will be called again and will probably be
46438 ** right on the second iteration.
46440 if( pWal->apWiData[0]==0 ){
46441 /* This branch is taken when the xShmMap() method returns SQLITE_BUSY.
46442 ** We assume this is a transient condition, so return WAL_RETRY. The
46443 ** xShmMap() implementation used by the default unix and win32 VFS
46444 ** modules may return SQLITE_BUSY due to a race condition in the
46445 ** code that determines whether or not the shared-memory region
46446 ** must be zeroed before the requested page is returned.
46448 rc = WAL_RETRY;
46449 }else if( SQLITE_OK==(rc = walLockShared(pWal, WAL_RECOVER_LOCK)) ){
46450 walUnlockShared(pWal, WAL_RECOVER_LOCK);
46451 rc = WAL_RETRY;
46452 }else if( rc==SQLITE_BUSY ){
46453 rc = SQLITE_BUSY_RECOVERY;
46456 if( rc!=SQLITE_OK ){
46457 return rc;
46461 pInfo = walCkptInfo(pWal);
46462 if( !useWal && pInfo->nBackfill==pWal->hdr.mxFrame ){
46463 /* The WAL has been completely backfilled (or it is empty).
46464 ** and can be safely ignored.
46466 rc = walLockShared(pWal, WAL_READ_LOCK(0));
46467 walShmBarrier(pWal);
46468 if( rc==SQLITE_OK ){
46469 if( memcmp((void *)walIndexHdr(pWal), &pWal->hdr, sizeof(WalIndexHdr)) ){
46470 /* It is not safe to allow the reader to continue here if frames
46471 ** may have been appended to the log before READ_LOCK(0) was obtained.
46472 ** When holding READ_LOCK(0), the reader ignores the entire log file,
46473 ** which implies that the database file contains a trustworthy
46474 ** snapshoT. Since holding READ_LOCK(0) prevents a checkpoint from
46475 ** happening, this is usually correct.
46477 ** However, if frames have been appended to the log (or if the log
46478 ** is wrapped and written for that matter) before the READ_LOCK(0)
46479 ** is obtained, that is not necessarily true. A checkpointer may
46480 ** have started to backfill the appended frames but crashed before
46481 ** it finished. Leaving a corrupt image in the database file.
46483 walUnlockShared(pWal, WAL_READ_LOCK(0));
46484 return WAL_RETRY;
46486 pWal->readLock = 0;
46487 return SQLITE_OK;
46488 }else if( rc!=SQLITE_BUSY ){
46489 return rc;
46493 /* If we get this far, it means that the reader will want to use
46494 ** the WAL to get at content from recent commits. The job now is
46495 ** to select one of the aReadMark[] entries that is closest to
46496 ** but not exceeding pWal->hdr.mxFrame and lock that entry.
46498 mxReadMark = 0;
46499 mxI = 0;
46500 for(i=1; i<WAL_NREADER; i++){
46501 u32 thisMark = pInfo->aReadMark[i];
46502 if( mxReadMark<=thisMark && thisMark<=pWal->hdr.mxFrame ){
46503 assert( thisMark!=READMARK_NOT_USED );
46504 mxReadMark = thisMark;
46505 mxI = i;
46508 /* There was once an "if" here. The extra "{" is to preserve indentation. */
46510 if( (pWal->readOnly & WAL_SHM_RDONLY)==0
46511 && (mxReadMark<pWal->hdr.mxFrame || mxI==0)
46513 for(i=1; i<WAL_NREADER; i++){
46514 rc = walLockExclusive(pWal, WAL_READ_LOCK(i), 1);
46515 if( rc==SQLITE_OK ){
46516 mxReadMark = pInfo->aReadMark[i] = pWal->hdr.mxFrame;
46517 mxI = i;
46518 walUnlockExclusive(pWal, WAL_READ_LOCK(i), 1);
46519 break;
46520 }else if( rc!=SQLITE_BUSY ){
46521 return rc;
46525 if( mxI==0 ){
46526 assert( rc==SQLITE_BUSY || (pWal->readOnly & WAL_SHM_RDONLY)!=0 );
46527 return rc==SQLITE_BUSY ? WAL_RETRY : SQLITE_READONLY_CANTLOCK;
46530 rc = walLockShared(pWal, WAL_READ_LOCK(mxI));
46531 if( rc ){
46532 return rc==SQLITE_BUSY ? WAL_RETRY : rc;
46534 /* Now that the read-lock has been obtained, check that neither the
46535 ** value in the aReadMark[] array or the contents of the wal-index
46536 ** header have changed.
46538 ** It is necessary to check that the wal-index header did not change
46539 ** between the time it was read and when the shared-lock was obtained
46540 ** on WAL_READ_LOCK(mxI) was obtained to account for the possibility
46541 ** that the log file may have been wrapped by a writer, or that frames
46542 ** that occur later in the log than pWal->hdr.mxFrame may have been
46543 ** copied into the database by a checkpointer. If either of these things
46544 ** happened, then reading the database with the current value of
46545 ** pWal->hdr.mxFrame risks reading a corrupted snapshot. So, retry
46546 ** instead.
46548 ** This does not guarantee that the copy of the wal-index header is up to
46549 ** date before proceeding. That would not be possible without somehow
46550 ** blocking writers. It only guarantees that a dangerous checkpoint or
46551 ** log-wrap (either of which would require an exclusive lock on
46552 ** WAL_READ_LOCK(mxI)) has not occurred since the snapshot was valid.
46554 walShmBarrier(pWal);
46555 if( pInfo->aReadMark[mxI]!=mxReadMark
46556 || memcmp((void *)walIndexHdr(pWal), &pWal->hdr, sizeof(WalIndexHdr))
46558 walUnlockShared(pWal, WAL_READ_LOCK(mxI));
46559 return WAL_RETRY;
46560 }else{
46561 assert( mxReadMark<=pWal->hdr.mxFrame );
46562 pWal->readLock = (i16)mxI;
46565 return rc;
46569 ** Begin a read transaction on the database.
46571 ** This routine used to be called sqlite3OpenSnapshot() and with good reason:
46572 ** it takes a snapshot of the state of the WAL and wal-index for the current
46573 ** instant in time. The current thread will continue to use this snapshot.
46574 ** Other threads might append new content to the WAL and wal-index but
46575 ** that extra content is ignored by the current thread.
46577 ** If the database contents have changes since the previous read
46578 ** transaction, then *pChanged is set to 1 before returning. The
46579 ** Pager layer will use this to know that is cache is stale and
46580 ** needs to be flushed.
46582 SQLITE_PRIVATE int sqlite3WalBeginReadTransaction(Wal *pWal, int *pChanged){
46583 int rc; /* Return code */
46584 int cnt = 0; /* Number of TryBeginRead attempts */
46587 rc = walTryBeginRead(pWal, pChanged, 0, ++cnt);
46588 }while( rc==WAL_RETRY );
46589 testcase( (rc&0xff)==SQLITE_BUSY );
46590 testcase( (rc&0xff)==SQLITE_IOERR );
46591 testcase( rc==SQLITE_PROTOCOL );
46592 testcase( rc==SQLITE_OK );
46593 return rc;
46597 ** Finish with a read transaction. All this does is release the
46598 ** read-lock.
46600 SQLITE_PRIVATE void sqlite3WalEndReadTransaction(Wal *pWal){
46601 sqlite3WalEndWriteTransaction(pWal);
46602 if( pWal->readLock>=0 ){
46603 walUnlockShared(pWal, WAL_READ_LOCK(pWal->readLock));
46604 pWal->readLock = -1;
46609 ** Read a page from the WAL, if it is present in the WAL and if the
46610 ** current read transaction is configured to use the WAL.
46612 ** The *pInWal is set to 1 if the requested page is in the WAL and
46613 ** has been loaded. Or *pInWal is set to 0 if the page was not in
46614 ** the WAL and needs to be read out of the database.
46616 SQLITE_PRIVATE int sqlite3WalRead(
46617 Wal *pWal, /* WAL handle */
46618 Pgno pgno, /* Database page number to read data for */
46619 int *pInWal, /* OUT: True if data is read from WAL */
46620 int nOut, /* Size of buffer pOut in bytes */
46621 u8 *pOut /* Buffer to write page data to */
46623 u32 iRead = 0; /* If !=0, WAL frame to return data from */
46624 u32 iLast = pWal->hdr.mxFrame; /* Last page in WAL for this reader */
46625 int iHash; /* Used to loop through N hash tables */
46627 /* This routine is only be called from within a read transaction. */
46628 assert( pWal->readLock>=0 || pWal->lockError );
46630 /* If the "last page" field of the wal-index header snapshot is 0, then
46631 ** no data will be read from the wal under any circumstances. Return early
46632 ** in this case as an optimization. Likewise, if pWal->readLock==0,
46633 ** then the WAL is ignored by the reader so return early, as if the
46634 ** WAL were empty.
46636 if( iLast==0 || pWal->readLock==0 ){
46637 *pInWal = 0;
46638 return SQLITE_OK;
46641 /* Search the hash table or tables for an entry matching page number
46642 ** pgno. Each iteration of the following for() loop searches one
46643 ** hash table (each hash table indexes up to HASHTABLE_NPAGE frames).
46645 ** This code might run concurrently to the code in walIndexAppend()
46646 ** that adds entries to the wal-index (and possibly to this hash
46647 ** table). This means the value just read from the hash
46648 ** slot (aHash[iKey]) may have been added before or after the
46649 ** current read transaction was opened. Values added after the
46650 ** read transaction was opened may have been written incorrectly -
46651 ** i.e. these slots may contain garbage data. However, we assume
46652 ** that any slots written before the current read transaction was
46653 ** opened remain unmodified.
46655 ** For the reasons above, the if(...) condition featured in the inner
46656 ** loop of the following block is more stringent that would be required
46657 ** if we had exclusive access to the hash-table:
46659 ** (aPgno[iFrame]==pgno):
46660 ** This condition filters out normal hash-table collisions.
46662 ** (iFrame<=iLast):
46663 ** This condition filters out entries that were added to the hash
46664 ** table after the current read-transaction had started.
46666 for(iHash=walFramePage(iLast); iHash>=0 && iRead==0; iHash--){
46667 volatile ht_slot *aHash; /* Pointer to hash table */
46668 volatile u32 *aPgno; /* Pointer to array of page numbers */
46669 u32 iZero; /* Frame number corresponding to aPgno[0] */
46670 int iKey; /* Hash slot index */
46671 int nCollide; /* Number of hash collisions remaining */
46672 int rc; /* Error code */
46674 rc = walHashGet(pWal, iHash, &aHash, &aPgno, &iZero);
46675 if( rc!=SQLITE_OK ){
46676 return rc;
46678 nCollide = HASHTABLE_NSLOT;
46679 for(iKey=walHash(pgno); aHash[iKey]; iKey=walNextHash(iKey)){
46680 u32 iFrame = aHash[iKey] + iZero;
46681 if( iFrame<=iLast && aPgno[aHash[iKey]]==pgno ){
46682 assert( iFrame>iRead );
46683 iRead = iFrame;
46685 if( (nCollide--)==0 ){
46686 return SQLITE_CORRUPT_BKPT;
46691 #ifdef SQLITE_ENABLE_EXPENSIVE_ASSERT
46692 /* If expensive assert() statements are available, do a linear search
46693 ** of the wal-index file content. Make sure the results agree with the
46694 ** result obtained using the hash indexes above. */
46696 u32 iRead2 = 0;
46697 u32 iTest;
46698 for(iTest=iLast; iTest>0; iTest--){
46699 if( walFramePgno(pWal, iTest)==pgno ){
46700 iRead2 = iTest;
46701 break;
46704 assert( iRead==iRead2 );
46706 #endif
46708 /* If iRead is non-zero, then it is the log frame number that contains the
46709 ** required page. Read and return data from the log file.
46711 if( iRead ){
46712 int sz;
46713 i64 iOffset;
46714 sz = pWal->hdr.szPage;
46715 sz = (pWal->hdr.szPage&0xfe00) + ((pWal->hdr.szPage&0x0001)<<16);
46716 testcase( sz<=32768 );
46717 testcase( sz>=65536 );
46718 iOffset = walFrameOffset(iRead, sz) + WAL_FRAME_HDRSIZE;
46719 *pInWal = 1;
46720 /* testcase( IS_BIG_INT(iOffset) ); // requires a 4GiB WAL */
46721 return sqlite3OsRead(pWal->pWalFd, pOut, nOut, iOffset);
46724 *pInWal = 0;
46725 return SQLITE_OK;
46730 ** Return the size of the database in pages (or zero, if unknown).
46732 SQLITE_PRIVATE Pgno sqlite3WalDbsize(Wal *pWal){
46733 if( pWal && ALWAYS(pWal->readLock>=0) ){
46734 return pWal->hdr.nPage;
46736 return 0;
46741 ** This function starts a write transaction on the WAL.
46743 ** A read transaction must have already been started by a prior call
46744 ** to sqlite3WalBeginReadTransaction().
46746 ** If another thread or process has written into the database since
46747 ** the read transaction was started, then it is not possible for this
46748 ** thread to write as doing so would cause a fork. So this routine
46749 ** returns SQLITE_BUSY in that case and no write transaction is started.
46751 ** There can only be a single writer active at a time.
46753 SQLITE_PRIVATE int sqlite3WalBeginWriteTransaction(Wal *pWal){
46754 int rc;
46756 /* Cannot start a write transaction without first holding a read
46757 ** transaction. */
46758 assert( pWal->readLock>=0 );
46760 if( pWal->readOnly ){
46761 return SQLITE_READONLY;
46764 /* Only one writer allowed at a time. Get the write lock. Return
46765 ** SQLITE_BUSY if unable.
46767 rc = walLockExclusive(pWal, WAL_WRITE_LOCK, 1);
46768 if( rc ){
46769 return rc;
46771 pWal->writeLock = 1;
46773 /* If another connection has written to the database file since the
46774 ** time the read transaction on this connection was started, then
46775 ** the write is disallowed.
46777 if( memcmp(&pWal->hdr, (void *)walIndexHdr(pWal), sizeof(WalIndexHdr))!=0 ){
46778 walUnlockExclusive(pWal, WAL_WRITE_LOCK, 1);
46779 pWal->writeLock = 0;
46780 rc = SQLITE_BUSY;
46783 return rc;
46787 ** End a write transaction. The commit has already been done. This
46788 ** routine merely releases the lock.
46790 SQLITE_PRIVATE int sqlite3WalEndWriteTransaction(Wal *pWal){
46791 if( pWal->writeLock ){
46792 walUnlockExclusive(pWal, WAL_WRITE_LOCK, 1);
46793 pWal->writeLock = 0;
46795 return SQLITE_OK;
46799 ** If any data has been written (but not committed) to the log file, this
46800 ** function moves the write-pointer back to the start of the transaction.
46802 ** Additionally, the callback function is invoked for each frame written
46803 ** to the WAL since the start of the transaction. If the callback returns
46804 ** other than SQLITE_OK, it is not invoked again and the error code is
46805 ** returned to the caller.
46807 ** Otherwise, if the callback function does not return an error, this
46808 ** function returns SQLITE_OK.
46810 SQLITE_PRIVATE int sqlite3WalUndo(Wal *pWal, int (*xUndo)(void *, Pgno), void *pUndoCtx){
46811 int rc = SQLITE_OK;
46812 if( ALWAYS(pWal->writeLock) ){
46813 Pgno iMax = pWal->hdr.mxFrame;
46814 Pgno iFrame;
46816 /* Restore the clients cache of the wal-index header to the state it
46817 ** was in before the client began writing to the database.
46819 memcpy(&pWal->hdr, (void *)walIndexHdr(pWal), sizeof(WalIndexHdr));
46821 for(iFrame=pWal->hdr.mxFrame+1;
46822 ALWAYS(rc==SQLITE_OK) && iFrame<=iMax;
46823 iFrame++
46825 /* This call cannot fail. Unless the page for which the page number
46826 ** is passed as the second argument is (a) in the cache and
46827 ** (b) has an outstanding reference, then xUndo is either a no-op
46828 ** (if (a) is false) or simply expels the page from the cache (if (b)
46829 ** is false).
46831 ** If the upper layer is doing a rollback, it is guaranteed that there
46832 ** are no outstanding references to any page other than page 1. And
46833 ** page 1 is never written to the log until the transaction is
46834 ** committed. As a result, the call to xUndo may not fail.
46836 assert( walFramePgno(pWal, iFrame)!=1 );
46837 rc = xUndo(pUndoCtx, walFramePgno(pWal, iFrame));
46839 walCleanupHash(pWal);
46841 assert( rc==SQLITE_OK );
46842 return rc;
46846 ** Argument aWalData must point to an array of WAL_SAVEPOINT_NDATA u32
46847 ** values. This function populates the array with values required to
46848 ** "rollback" the write position of the WAL handle back to the current
46849 ** point in the event of a savepoint rollback (via WalSavepointUndo()).
46851 SQLITE_PRIVATE void sqlite3WalSavepoint(Wal *pWal, u32 *aWalData){
46852 assert( pWal->writeLock );
46853 aWalData[0] = pWal->hdr.mxFrame;
46854 aWalData[1] = pWal->hdr.aFrameCksum[0];
46855 aWalData[2] = pWal->hdr.aFrameCksum[1];
46856 aWalData[3] = pWal->nCkpt;
46860 ** Move the write position of the WAL back to the point identified by
46861 ** the values in the aWalData[] array. aWalData must point to an array
46862 ** of WAL_SAVEPOINT_NDATA u32 values that has been previously populated
46863 ** by a call to WalSavepoint().
46865 SQLITE_PRIVATE int sqlite3WalSavepointUndo(Wal *pWal, u32 *aWalData){
46866 int rc = SQLITE_OK;
46868 assert( pWal->writeLock );
46869 assert( aWalData[3]!=pWal->nCkpt || aWalData[0]<=pWal->hdr.mxFrame );
46871 if( aWalData[3]!=pWal->nCkpt ){
46872 /* This savepoint was opened immediately after the write-transaction
46873 ** was started. Right after that, the writer decided to wrap around
46874 ** to the start of the log. Update the savepoint values to match.
46876 aWalData[0] = 0;
46877 aWalData[3] = pWal->nCkpt;
46880 if( aWalData[0]<pWal->hdr.mxFrame ){
46881 pWal->hdr.mxFrame = aWalData[0];
46882 pWal->hdr.aFrameCksum[0] = aWalData[1];
46883 pWal->hdr.aFrameCksum[1] = aWalData[2];
46884 walCleanupHash(pWal);
46887 return rc;
46891 ** This function is called just before writing a set of frames to the log
46892 ** file (see sqlite3WalFrames()). It checks to see if, instead of appending
46893 ** to the current log file, it is possible to overwrite the start of the
46894 ** existing log file with the new frames (i.e. "reset" the log). If so,
46895 ** it sets pWal->hdr.mxFrame to 0. Otherwise, pWal->hdr.mxFrame is left
46896 ** unchanged.
46898 ** SQLITE_OK is returned if no error is encountered (regardless of whether
46899 ** or not pWal->hdr.mxFrame is modified). An SQLite error code is returned
46900 ** if an error occurs.
46902 static int walRestartLog(Wal *pWal){
46903 int rc = SQLITE_OK;
46904 int cnt;
46906 if( pWal->readLock==0 ){
46907 volatile WalCkptInfo *pInfo = walCkptInfo(pWal);
46908 assert( pInfo->nBackfill==pWal->hdr.mxFrame );
46909 if( pInfo->nBackfill>0 ){
46910 u32 salt1;
46911 sqlite3_randomness(4, &salt1);
46912 rc = walLockExclusive(pWal, WAL_READ_LOCK(1), WAL_NREADER-1);
46913 if( rc==SQLITE_OK ){
46914 /* If all readers are using WAL_READ_LOCK(0) (in other words if no
46915 ** readers are currently using the WAL), then the transactions
46916 ** frames will overwrite the start of the existing log. Update the
46917 ** wal-index header to reflect this.
46919 ** In theory it would be Ok to update the cache of the header only
46920 ** at this point. But updating the actual wal-index header is also
46921 ** safe and means there is no special case for sqlite3WalUndo()
46922 ** to handle if this transaction is rolled back.
46924 int i; /* Loop counter */
46925 u32 *aSalt = pWal->hdr.aSalt; /* Big-endian salt values */
46927 /* Limit the size of WAL file if the journal_size_limit PRAGMA is
46928 ** set to a non-negative value. Log errors encountered
46929 ** during the truncation attempt. */
46930 if( pWal->mxWalSize>=0 ){
46931 i64 sz;
46932 int rx;
46933 sqlite3BeginBenignMalloc();
46934 rx = sqlite3OsFileSize(pWal->pWalFd, &sz);
46935 if( rx==SQLITE_OK && (sz > pWal->mxWalSize) ){
46936 rx = sqlite3OsTruncate(pWal->pWalFd, pWal->mxWalSize);
46938 sqlite3EndBenignMalloc();
46939 if( rx ){
46940 sqlite3_log(rx, "cannot limit WAL size: %s", pWal->zWalName);
46944 pWal->nCkpt++;
46945 pWal->hdr.mxFrame = 0;
46946 sqlite3Put4byte((u8*)&aSalt[0], 1 + sqlite3Get4byte((u8*)&aSalt[0]));
46947 aSalt[1] = salt1;
46948 walIndexWriteHdr(pWal);
46949 pInfo->nBackfill = 0;
46950 for(i=1; i<WAL_NREADER; i++) pInfo->aReadMark[i] = READMARK_NOT_USED;
46951 assert( pInfo->aReadMark[0]==0 );
46952 walUnlockExclusive(pWal, WAL_READ_LOCK(1), WAL_NREADER-1);
46953 }else if( rc!=SQLITE_BUSY ){
46954 return rc;
46957 walUnlockShared(pWal, WAL_READ_LOCK(0));
46958 pWal->readLock = -1;
46959 cnt = 0;
46961 int notUsed;
46962 rc = walTryBeginRead(pWal, &notUsed, 1, ++cnt);
46963 }while( rc==WAL_RETRY );
46964 assert( (rc&0xff)!=SQLITE_BUSY ); /* BUSY not possible when useWal==1 */
46965 testcase( (rc&0xff)==SQLITE_IOERR );
46966 testcase( rc==SQLITE_PROTOCOL );
46967 testcase( rc==SQLITE_OK );
46969 return rc;
46973 ** Write a set of frames to the log. The caller must hold the write-lock
46974 ** on the log file (obtained using sqlite3WalBeginWriteTransaction()).
46976 SQLITE_PRIVATE int sqlite3WalFrames(
46977 Wal *pWal, /* Wal handle to write to */
46978 int szPage, /* Database page-size in bytes */
46979 PgHdr *pList, /* List of dirty pages to write */
46980 Pgno nTruncate, /* Database size after this commit */
46981 int isCommit, /* True if this is a commit */
46982 int sync_flags /* Flags to pass to OsSync() (or 0) */
46984 int rc; /* Used to catch return codes */
46985 u32 iFrame; /* Next frame address */
46986 u8 aFrame[WAL_FRAME_HDRSIZE]; /* Buffer to assemble frame-header in */
46987 PgHdr *p; /* Iterator to run through pList with. */
46988 PgHdr *pLast = 0; /* Last frame in list */
46989 int nLast = 0; /* Number of extra copies of last page */
46991 assert( pList );
46992 assert( pWal->writeLock );
46994 #if defined(SQLITE_TEST) && defined(SQLITE_DEBUG)
46995 { int cnt; for(cnt=0, p=pList; p; p=p->pDirty, cnt++){}
46996 WALTRACE(("WAL%p: frame write begin. %d frames. mxFrame=%d. %s\n",
46997 pWal, cnt, pWal->hdr.mxFrame, isCommit ? "Commit" : "Spill"));
46999 #endif
47001 /* See if it is possible to write these frames into the start of the
47002 ** log file, instead of appending to it at pWal->hdr.mxFrame.
47004 if( SQLITE_OK!=(rc = walRestartLog(pWal)) ){
47005 return rc;
47008 /* If this is the first frame written into the log, write the WAL
47009 ** header to the start of the WAL file. See comments at the top of
47010 ** this source file for a description of the WAL header format.
47012 iFrame = pWal->hdr.mxFrame;
47013 if( iFrame==0 ){
47014 u8 aWalHdr[WAL_HDRSIZE]; /* Buffer to assemble wal-header in */
47015 u32 aCksum[2]; /* Checksum for wal-header */
47017 sqlite3Put4byte(&aWalHdr[0], (WAL_MAGIC | SQLITE_BIGENDIAN));
47018 sqlite3Put4byte(&aWalHdr[4], WAL_MAX_VERSION);
47019 sqlite3Put4byte(&aWalHdr[8], szPage);
47020 sqlite3Put4byte(&aWalHdr[12], pWal->nCkpt);
47021 sqlite3_randomness(8, pWal->hdr.aSalt);
47022 memcpy(&aWalHdr[16], pWal->hdr.aSalt, 8);
47023 walChecksumBytes(1, aWalHdr, WAL_HDRSIZE-2*4, 0, aCksum);
47024 sqlite3Put4byte(&aWalHdr[24], aCksum[0]);
47025 sqlite3Put4byte(&aWalHdr[28], aCksum[1]);
47027 pWal->szPage = szPage;
47028 pWal->hdr.bigEndCksum = SQLITE_BIGENDIAN;
47029 pWal->hdr.aFrameCksum[0] = aCksum[0];
47030 pWal->hdr.aFrameCksum[1] = aCksum[1];
47032 rc = sqlite3OsWrite(pWal->pWalFd, aWalHdr, sizeof(aWalHdr), 0);
47033 WALTRACE(("WAL%p: wal-header write %s\n", pWal, rc ? "failed" : "ok"));
47034 if( rc!=SQLITE_OK ){
47035 return rc;
47038 assert( (int)pWal->szPage==szPage );
47040 /* Write the log file. */
47041 for(p=pList; p; p=p->pDirty){
47042 u32 nDbsize; /* Db-size field for frame header */
47043 i64 iOffset; /* Write offset in log file */
47044 void *pData;
47046 iOffset = walFrameOffset(++iFrame, szPage);
47047 /* testcase( IS_BIG_INT(iOffset) ); // requires a 4GiB WAL */
47049 /* Populate and write the frame header */
47050 nDbsize = (isCommit && p->pDirty==0) ? nTruncate : 0;
47051 #if defined(SQLITE_HAS_CODEC)
47052 if( (pData = sqlite3PagerCodec(p))==0 ) return SQLITE_NOMEM;
47053 #else
47054 pData = p->pData;
47055 #endif
47056 walEncodeFrame(pWal, p->pgno, nDbsize, pData, aFrame);
47057 rc = sqlite3OsWrite(pWal->pWalFd, aFrame, sizeof(aFrame), iOffset);
47058 if( rc!=SQLITE_OK ){
47059 return rc;
47062 /* Write the page data */
47063 rc = sqlite3OsWrite(pWal->pWalFd, pData, szPage, iOffset+sizeof(aFrame));
47064 if( rc!=SQLITE_OK ){
47065 return rc;
47067 pLast = p;
47070 /* Sync the log file if the 'isSync' flag was specified. */
47071 if( sync_flags ){
47072 i64 iSegment = sqlite3OsSectorSize(pWal->pWalFd);
47073 i64 iOffset = walFrameOffset(iFrame+1, szPage);
47075 assert( isCommit );
47076 assert( iSegment>0 );
47078 iSegment = (((iOffset+iSegment-1)/iSegment) * iSegment);
47079 while( iOffset<iSegment ){
47080 void *pData;
47081 #if defined(SQLITE_HAS_CODEC)
47082 if( (pData = sqlite3PagerCodec(pLast))==0 ) return SQLITE_NOMEM;
47083 #else
47084 pData = pLast->pData;
47085 #endif
47086 walEncodeFrame(pWal, pLast->pgno, nTruncate, pData, aFrame);
47087 /* testcase( IS_BIG_INT(iOffset) ); // requires a 4GiB WAL */
47088 rc = sqlite3OsWrite(pWal->pWalFd, aFrame, sizeof(aFrame), iOffset);
47089 if( rc!=SQLITE_OK ){
47090 return rc;
47092 iOffset += WAL_FRAME_HDRSIZE;
47093 rc = sqlite3OsWrite(pWal->pWalFd, pData, szPage, iOffset);
47094 if( rc!=SQLITE_OK ){
47095 return rc;
47097 nLast++;
47098 iOffset += szPage;
47101 rc = sqlite3OsSync(pWal->pWalFd, sync_flags);
47104 /* Append data to the wal-index. It is not necessary to lock the
47105 ** wal-index to do this as the SQLITE_SHM_WRITE lock held on the wal-index
47106 ** guarantees that there are no other writers, and no data that may
47107 ** be in use by existing readers is being overwritten.
47109 iFrame = pWal->hdr.mxFrame;
47110 for(p=pList; p && rc==SQLITE_OK; p=p->pDirty){
47111 iFrame++;
47112 rc = walIndexAppend(pWal, iFrame, p->pgno);
47114 while( nLast>0 && rc==SQLITE_OK ){
47115 iFrame++;
47116 nLast--;
47117 rc = walIndexAppend(pWal, iFrame, pLast->pgno);
47120 if( rc==SQLITE_OK ){
47121 /* Update the private copy of the header. */
47122 pWal->hdr.szPage = (u16)((szPage&0xff00) | (szPage>>16));
47123 testcase( szPage<=32768 );
47124 testcase( szPage>=65536 );
47125 pWal->hdr.mxFrame = iFrame;
47126 if( isCommit ){
47127 pWal->hdr.iChange++;
47128 pWal->hdr.nPage = nTruncate;
47130 /* If this is a commit, update the wal-index header too. */
47131 if( isCommit ){
47132 walIndexWriteHdr(pWal);
47133 pWal->iCallback = iFrame;
47137 WALTRACE(("WAL%p: frame write %s\n", pWal, rc ? "failed" : "ok"));
47138 return rc;
47142 ** This routine is called to implement sqlite3_wal_checkpoint() and
47143 ** related interfaces.
47145 ** Obtain a CHECKPOINT lock and then backfill as much information as
47146 ** we can from WAL into the database.
47148 ** If parameter xBusy is not NULL, it is a pointer to a busy-handler
47149 ** callback. In this case this function runs a blocking checkpoint.
47151 SQLITE_PRIVATE int sqlite3WalCheckpoint(
47152 Wal *pWal, /* Wal connection */
47153 int eMode, /* PASSIVE, FULL or RESTART */
47154 int (*xBusy)(void*), /* Function to call when busy */
47155 void *pBusyArg, /* Context argument for xBusyHandler */
47156 int sync_flags, /* Flags to sync db file with (or 0) */
47157 int nBuf, /* Size of temporary buffer */
47158 u8 *zBuf, /* Temporary buffer to use */
47159 int *pnLog, /* OUT: Number of frames in WAL */
47160 int *pnCkpt /* OUT: Number of backfilled frames in WAL */
47162 int rc; /* Return code */
47163 int isChanged = 0; /* True if a new wal-index header is loaded */
47164 int eMode2 = eMode; /* Mode to pass to walCheckpoint() */
47166 assert( pWal->ckptLock==0 );
47167 assert( pWal->writeLock==0 );
47169 if( pWal->readOnly ) return SQLITE_READONLY;
47170 WALTRACE(("WAL%p: checkpoint begins\n", pWal));
47171 rc = walLockExclusive(pWal, WAL_CKPT_LOCK, 1);
47172 if( rc ){
47173 /* Usually this is SQLITE_BUSY meaning that another thread or process
47174 ** is already running a checkpoint, or maybe a recovery. But it might
47175 ** also be SQLITE_IOERR. */
47176 return rc;
47178 pWal->ckptLock = 1;
47180 /* If this is a blocking-checkpoint, then obtain the write-lock as well
47181 ** to prevent any writers from running while the checkpoint is underway.
47182 ** This has to be done before the call to walIndexReadHdr() below.
47184 ** If the writer lock cannot be obtained, then a passive checkpoint is
47185 ** run instead. Since the checkpointer is not holding the writer lock,
47186 ** there is no point in blocking waiting for any readers. Assuming no
47187 ** other error occurs, this function will return SQLITE_BUSY to the caller.
47189 if( eMode!=SQLITE_CHECKPOINT_PASSIVE ){
47190 rc = walBusyLock(pWal, xBusy, pBusyArg, WAL_WRITE_LOCK, 1);
47191 if( rc==SQLITE_OK ){
47192 pWal->writeLock = 1;
47193 }else if( rc==SQLITE_BUSY ){
47194 eMode2 = SQLITE_CHECKPOINT_PASSIVE;
47195 rc = SQLITE_OK;
47199 /* Read the wal-index header. */
47200 if( rc==SQLITE_OK ){
47201 rc = walIndexReadHdr(pWal, &isChanged);
47204 /* Copy data from the log to the database file. */
47205 if( rc==SQLITE_OK ){
47206 if( pWal->hdr.mxFrame && walPagesize(pWal)!=nBuf ){
47207 rc = SQLITE_CORRUPT_BKPT;
47208 }else{
47209 rc = walCheckpoint(pWal, eMode2, xBusy, pBusyArg, sync_flags, zBuf);
47212 /* If no error occurred, set the output variables. */
47213 if( rc==SQLITE_OK || rc==SQLITE_BUSY ){
47214 if( pnLog ) *pnLog = (int)pWal->hdr.mxFrame;
47215 if( pnCkpt ) *pnCkpt = (int)(walCkptInfo(pWal)->nBackfill);
47219 if( isChanged ){
47220 /* If a new wal-index header was loaded before the checkpoint was
47221 ** performed, then the pager-cache associated with pWal is now
47222 ** out of date. So zero the cached wal-index header to ensure that
47223 ** next time the pager opens a snapshot on this database it knows that
47224 ** the cache needs to be reset.
47226 memset(&pWal->hdr, 0, sizeof(WalIndexHdr));
47229 /* Release the locks. */
47230 sqlite3WalEndWriteTransaction(pWal);
47231 walUnlockExclusive(pWal, WAL_CKPT_LOCK, 1);
47232 pWal->ckptLock = 0;
47233 WALTRACE(("WAL%p: checkpoint %s\n", pWal, rc ? "failed" : "ok"));
47234 return (rc==SQLITE_OK && eMode!=eMode2 ? SQLITE_BUSY : rc);
47237 /* Return the value to pass to a sqlite3_wal_hook callback, the
47238 ** number of frames in the WAL at the point of the last commit since
47239 ** sqlite3WalCallback() was called. If no commits have occurred since
47240 ** the last call, then return 0.
47242 SQLITE_PRIVATE int sqlite3WalCallback(Wal *pWal){
47243 u32 ret = 0;
47244 if( pWal ){
47245 ret = pWal->iCallback;
47246 pWal->iCallback = 0;
47248 return (int)ret;
47252 ** This function is called to change the WAL subsystem into or out
47253 ** of locking_mode=EXCLUSIVE.
47255 ** If op is zero, then attempt to change from locking_mode=EXCLUSIVE
47256 ** into locking_mode=NORMAL. This means that we must acquire a lock
47257 ** on the pWal->readLock byte. If the WAL is already in locking_mode=NORMAL
47258 ** or if the acquisition of the lock fails, then return 0. If the
47259 ** transition out of exclusive-mode is successful, return 1. This
47260 ** operation must occur while the pager is still holding the exclusive
47261 ** lock on the main database file.
47263 ** If op is one, then change from locking_mode=NORMAL into
47264 ** locking_mode=EXCLUSIVE. This means that the pWal->readLock must
47265 ** be released. Return 1 if the transition is made and 0 if the
47266 ** WAL is already in exclusive-locking mode - meaning that this
47267 ** routine is a no-op. The pager must already hold the exclusive lock
47268 ** on the main database file before invoking this operation.
47270 ** If op is negative, then do a dry-run of the op==1 case but do
47271 ** not actually change anything. The pager uses this to see if it
47272 ** should acquire the database exclusive lock prior to invoking
47273 ** the op==1 case.
47275 SQLITE_PRIVATE int sqlite3WalExclusiveMode(Wal *pWal, int op){
47276 int rc;
47277 assert( pWal->writeLock==0 );
47278 assert( pWal->exclusiveMode!=WAL_HEAPMEMORY_MODE || op==-1 );
47280 /* pWal->readLock is usually set, but might be -1 if there was a
47281 ** prior error while attempting to acquire are read-lock. This cannot
47282 ** happen if the connection is actually in exclusive mode (as no xShmLock
47283 ** locks are taken in this case). Nor should the pager attempt to
47284 ** upgrade to exclusive-mode following such an error.
47286 assert( pWal->readLock>=0 || pWal->lockError );
47287 assert( pWal->readLock>=0 || (op<=0 && pWal->exclusiveMode==0) );
47289 if( op==0 ){
47290 if( pWal->exclusiveMode ){
47291 pWal->exclusiveMode = 0;
47292 if( walLockShared(pWal, WAL_READ_LOCK(pWal->readLock))!=SQLITE_OK ){
47293 pWal->exclusiveMode = 1;
47295 rc = pWal->exclusiveMode==0;
47296 }else{
47297 /* Already in locking_mode=NORMAL */
47298 rc = 0;
47300 }else if( op>0 ){
47301 assert( pWal->exclusiveMode==0 );
47302 assert( pWal->readLock>=0 );
47303 walUnlockShared(pWal, WAL_READ_LOCK(pWal->readLock));
47304 pWal->exclusiveMode = 1;
47305 rc = 1;
47306 }else{
47307 rc = pWal->exclusiveMode==0;
47309 return rc;
47313 ** Return true if the argument is non-NULL and the WAL module is using
47314 ** heap-memory for the wal-index. Otherwise, if the argument is NULL or the
47315 ** WAL module is using shared-memory, return false.
47317 SQLITE_PRIVATE int sqlite3WalHeapMemory(Wal *pWal){
47318 return (pWal && pWal->exclusiveMode==WAL_HEAPMEMORY_MODE );
47321 #endif /* #ifndef SQLITE_OMIT_WAL */
47323 /************** End of wal.c *************************************************/
47324 /************** Begin file btmutex.c *****************************************/
47326 ** 2007 August 27
47328 ** The author disclaims copyright to this source code. In place of
47329 ** a legal notice, here is a blessing:
47331 ** May you do good and not evil.
47332 ** May you find forgiveness for yourself and forgive others.
47333 ** May you share freely, never taking more than you give.
47335 *************************************************************************
47337 ** This file contains code used to implement mutexes on Btree objects.
47338 ** This code really belongs in btree.c. But btree.c is getting too
47339 ** big and we want to break it down some. This packaged seemed like
47340 ** a good breakout.
47342 /************** Include btreeInt.h in the middle of btmutex.c ****************/
47343 /************** Begin file btreeInt.h ****************************************/
47345 ** 2004 April 6
47347 ** The author disclaims copyright to this source code. In place of
47348 ** a legal notice, here is a blessing:
47350 ** May you do good and not evil.
47351 ** May you find forgiveness for yourself and forgive others.
47352 ** May you share freely, never taking more than you give.
47354 *************************************************************************
47355 ** This file implements a external (disk-based) database using BTrees.
47356 ** For a detailed discussion of BTrees, refer to
47358 ** Donald E. Knuth, THE ART OF COMPUTER PROGRAMMING, Volume 3:
47359 ** "Sorting And Searching", pages 473-480. Addison-Wesley
47360 ** Publishing Company, Reading, Massachusetts.
47362 ** The basic idea is that each page of the file contains N database
47363 ** entries and N+1 pointers to subpages.
47365 ** ----------------------------------------------------------------
47366 ** | Ptr(0) | Key(0) | Ptr(1) | Key(1) | ... | Key(N-1) | Ptr(N) |
47367 ** ----------------------------------------------------------------
47369 ** All of the keys on the page that Ptr(0) points to have values less
47370 ** than Key(0). All of the keys on page Ptr(1) and its subpages have
47371 ** values greater than Key(0) and less than Key(1). All of the keys
47372 ** on Ptr(N) and its subpages have values greater than Key(N-1). And
47373 ** so forth.
47375 ** Finding a particular key requires reading O(log(M)) pages from the
47376 ** disk where M is the number of entries in the tree.
47378 ** In this implementation, a single file can hold one or more separate
47379 ** BTrees. Each BTree is identified by the index of its root page. The
47380 ** key and data for any entry are combined to form the "payload". A
47381 ** fixed amount of payload can be carried directly on the database
47382 ** page. If the payload is larger than the preset amount then surplus
47383 ** bytes are stored on overflow pages. The payload for an entry
47384 ** and the preceding pointer are combined to form a "Cell". Each
47385 ** page has a small header which contains the Ptr(N) pointer and other
47386 ** information such as the size of key and data.
47388 ** FORMAT DETAILS
47390 ** The file is divided into pages. The first page is called page 1,
47391 ** the second is page 2, and so forth. A page number of zero indicates
47392 ** "no such page". The page size can be any power of 2 between 512 and 65536.
47393 ** Each page can be either a btree page, a freelist page, an overflow
47394 ** page, or a pointer-map page.
47396 ** The first page is always a btree page. The first 100 bytes of the first
47397 ** page contain a special header (the "file header") that describes the file.
47398 ** The format of the file header is as follows:
47400 ** OFFSET SIZE DESCRIPTION
47401 ** 0 16 Header string: "SQLite format 3\000"
47402 ** 16 2 Page size in bytes.
47403 ** 18 1 File format write version
47404 ** 19 1 File format read version
47405 ** 20 1 Bytes of unused space at the end of each page
47406 ** 21 1 Max embedded payload fraction
47407 ** 22 1 Min embedded payload fraction
47408 ** 23 1 Min leaf payload fraction
47409 ** 24 4 File change counter
47410 ** 28 4 Reserved for future use
47411 ** 32 4 First freelist page
47412 ** 36 4 Number of freelist pages in the file
47413 ** 40 60 15 4-byte meta values passed to higher layers
47415 ** 40 4 Schema cookie
47416 ** 44 4 File format of schema layer
47417 ** 48 4 Size of page cache
47418 ** 52 4 Largest root-page (auto/incr_vacuum)
47419 ** 56 4 1=UTF-8 2=UTF16le 3=UTF16be
47420 ** 60 4 User version
47421 ** 64 4 Incremental vacuum mode
47422 ** 68 4 unused
47423 ** 72 4 unused
47424 ** 76 4 unused
47426 ** All of the integer values are big-endian (most significant byte first).
47428 ** The file change counter is incremented when the database is changed
47429 ** This counter allows other processes to know when the file has changed
47430 ** and thus when they need to flush their cache.
47432 ** The max embedded payload fraction is the amount of the total usable
47433 ** space in a page that can be consumed by a single cell for standard
47434 ** B-tree (non-LEAFDATA) tables. A value of 255 means 100%. The default
47435 ** is to limit the maximum cell size so that at least 4 cells will fit
47436 ** on one page. Thus the default max embedded payload fraction is 64.
47438 ** If the payload for a cell is larger than the max payload, then extra
47439 ** payload is spilled to overflow pages. Once an overflow page is allocated,
47440 ** as many bytes as possible are moved into the overflow pages without letting
47441 ** the cell size drop below the min embedded payload fraction.
47443 ** The min leaf payload fraction is like the min embedded payload fraction
47444 ** except that it applies to leaf nodes in a LEAFDATA tree. The maximum
47445 ** payload fraction for a LEAFDATA tree is always 100% (or 255) and it
47446 ** not specified in the header.
47448 ** Each btree pages is divided into three sections: The header, the
47449 ** cell pointer array, and the cell content area. Page 1 also has a 100-byte
47450 ** file header that occurs before the page header.
47452 ** |----------------|
47453 ** | file header | 100 bytes. Page 1 only.
47454 ** |----------------|
47455 ** | page header | 8 bytes for leaves. 12 bytes for interior nodes
47456 ** |----------------|
47457 ** | cell pointer | | 2 bytes per cell. Sorted order.
47458 ** | array | | Grows downward
47459 ** | | v
47460 ** |----------------|
47461 ** | unallocated |
47462 ** | space |
47463 ** |----------------| ^ Grows upwards
47464 ** | cell content | | Arbitrary order interspersed with freeblocks.
47465 ** | area | | and free space fragments.
47466 ** |----------------|
47468 ** The page headers looks like this:
47470 ** OFFSET SIZE DESCRIPTION
47471 ** 0 1 Flags. 1: intkey, 2: zerodata, 4: leafdata, 8: leaf
47472 ** 1 2 byte offset to the first freeblock
47473 ** 3 2 number of cells on this page
47474 ** 5 2 first byte of the cell content area
47475 ** 7 1 number of fragmented free bytes
47476 ** 8 4 Right child (the Ptr(N) value). Omitted on leaves.
47478 ** The flags define the format of this btree page. The leaf flag means that
47479 ** this page has no children. The zerodata flag means that this page carries
47480 ** only keys and no data. The intkey flag means that the key is a integer
47481 ** which is stored in the key size entry of the cell header rather than in
47482 ** the payload area.
47484 ** The cell pointer array begins on the first byte after the page header.
47485 ** The cell pointer array contains zero or more 2-byte numbers which are
47486 ** offsets from the beginning of the page to the cell content in the cell
47487 ** content area. The cell pointers occur in sorted order. The system strives
47488 ** to keep free space after the last cell pointer so that new cells can
47489 ** be easily added without having to defragment the page.
47491 ** Cell content is stored at the very end of the page and grows toward the
47492 ** beginning of the page.
47494 ** Unused space within the cell content area is collected into a linked list of
47495 ** freeblocks. Each freeblock is at least 4 bytes in size. The byte offset
47496 ** to the first freeblock is given in the header. Freeblocks occur in
47497 ** increasing order. Because a freeblock must be at least 4 bytes in size,
47498 ** any group of 3 or fewer unused bytes in the cell content area cannot
47499 ** exist on the freeblock chain. A group of 3 or fewer free bytes is called
47500 ** a fragment. The total number of bytes in all fragments is recorded.
47501 ** in the page header at offset 7.
47503 ** SIZE DESCRIPTION
47504 ** 2 Byte offset of the next freeblock
47505 ** 2 Bytes in this freeblock
47507 ** Cells are of variable length. Cells are stored in the cell content area at
47508 ** the end of the page. Pointers to the cells are in the cell pointer array
47509 ** that immediately follows the page header. Cells is not necessarily
47510 ** contiguous or in order, but cell pointers are contiguous and in order.
47512 ** Cell content makes use of variable length integers. A variable
47513 ** length integer is 1 to 9 bytes where the lower 7 bits of each
47514 ** byte are used. The integer consists of all bytes that have bit 8 set and
47515 ** the first byte with bit 8 clear. The most significant byte of the integer
47516 ** appears first. A variable-length integer may not be more than 9 bytes long.
47517 ** As a special case, all 8 bytes of the 9th byte are used as data. This
47518 ** allows a 64-bit integer to be encoded in 9 bytes.
47520 ** 0x00 becomes 0x00000000
47521 ** 0x7f becomes 0x0000007f
47522 ** 0x81 0x00 becomes 0x00000080
47523 ** 0x82 0x00 becomes 0x00000100
47524 ** 0x80 0x7f becomes 0x0000007f
47525 ** 0x8a 0x91 0xd1 0xac 0x78 becomes 0x12345678
47526 ** 0x81 0x81 0x81 0x81 0x01 becomes 0x10204081
47528 ** Variable length integers are used for rowids and to hold the number of
47529 ** bytes of key and data in a btree cell.
47531 ** The content of a cell looks like this:
47533 ** SIZE DESCRIPTION
47534 ** 4 Page number of the left child. Omitted if leaf flag is set.
47535 ** var Number of bytes of data. Omitted if the zerodata flag is set.
47536 ** var Number of bytes of key. Or the key itself if intkey flag is set.
47537 ** * Payload
47538 ** 4 First page of the overflow chain. Omitted if no overflow
47540 ** Overflow pages form a linked list. Each page except the last is completely
47541 ** filled with data (pagesize - 4 bytes). The last page can have as little
47542 ** as 1 byte of data.
47544 ** SIZE DESCRIPTION
47545 ** 4 Page number of next overflow page
47546 ** * Data
47548 ** Freelist pages come in two subtypes: trunk pages and leaf pages. The
47549 ** file header points to the first in a linked list of trunk page. Each trunk
47550 ** page points to multiple leaf pages. The content of a leaf page is
47551 ** unspecified. A trunk page looks like this:
47553 ** SIZE DESCRIPTION
47554 ** 4 Page number of next trunk page
47555 ** 4 Number of leaf pointers on this page
47556 ** * zero or more pages numbers of leaves
47560 /* The following value is the maximum cell size assuming a maximum page
47561 ** size give above.
47563 #define MX_CELL_SIZE(pBt) ((int)(pBt->pageSize-8))
47565 /* The maximum number of cells on a single page of the database. This
47566 ** assumes a minimum cell size of 6 bytes (4 bytes for the cell itself
47567 ** plus 2 bytes for the index to the cell in the page header). Such
47568 ** small cells will be rare, but they are possible.
47570 #define MX_CELL(pBt) ((pBt->pageSize-8)/6)
47572 /* Forward declarations */
47573 typedef struct MemPage MemPage;
47574 typedef struct BtLock BtLock;
47577 ** This is a magic string that appears at the beginning of every
47578 ** SQLite database in order to identify the file as a real database.
47580 ** You can change this value at compile-time by specifying a
47581 ** -DSQLITE_FILE_HEADER="..." on the compiler command-line. The
47582 ** header must be exactly 16 bytes including the zero-terminator so
47583 ** the string itself should be 15 characters long. If you change
47584 ** the header, then your custom library will not be able to read
47585 ** databases generated by the standard tools and the standard tools
47586 ** will not be able to read databases created by your custom library.
47588 #ifndef SQLITE_FILE_HEADER /* 123456789 123456 */
47589 # define SQLITE_FILE_HEADER "SQLite format 3"
47590 #endif
47593 ** Page type flags. An ORed combination of these flags appear as the
47594 ** first byte of on-disk image of every BTree page.
47596 #define PTF_INTKEY 0x01
47597 #define PTF_ZERODATA 0x02
47598 #define PTF_LEAFDATA 0x04
47599 #define PTF_LEAF 0x08
47602 ** As each page of the file is loaded into memory, an instance of the following
47603 ** structure is appended and initialized to zero. This structure stores
47604 ** information about the page that is decoded from the raw file page.
47606 ** The pParent field points back to the parent page. This allows us to
47607 ** walk up the BTree from any leaf to the root. Care must be taken to
47608 ** unref() the parent page pointer when this page is no longer referenced.
47609 ** The pageDestructor() routine handles that chore.
47611 ** Access to all fields of this structure is controlled by the mutex
47612 ** stored in MemPage.pBt->mutex.
47614 struct MemPage {
47615 u8 isInit; /* True if previously initialized. MUST BE FIRST! */
47616 u8 nOverflow; /* Number of overflow cell bodies in aCell[] */
47617 u8 intKey; /* True if intkey flag is set */
47618 u8 leaf; /* True if leaf flag is set */
47619 u8 hasData; /* True if this page stores data */
47620 u8 hdrOffset; /* 100 for page 1. 0 otherwise */
47621 u8 childPtrSize; /* 0 if leaf==1. 4 if leaf==0 */
47622 u16 maxLocal; /* Copy of BtShared.maxLocal or BtShared.maxLeaf */
47623 u16 minLocal; /* Copy of BtShared.minLocal or BtShared.minLeaf */
47624 u16 cellOffset; /* Index in aData of first cell pointer */
47625 u16 nFree; /* Number of free bytes on the page */
47626 u16 nCell; /* Number of cells on this page, local and ovfl */
47627 u16 maskPage; /* Mask for page offset */
47628 struct _OvflCell { /* Cells that will not fit on aData[] */
47629 u8 *pCell; /* Pointers to the body of the overflow cell */
47630 u16 idx; /* Insert this cell before idx-th non-overflow cell */
47631 } aOvfl[5];
47632 BtShared *pBt; /* Pointer to BtShared that this page is part of */
47633 u8 *aData; /* Pointer to disk image of the page data */
47634 DbPage *pDbPage; /* Pager page handle */
47635 Pgno pgno; /* Page number for this page */
47639 ** The in-memory image of a disk page has the auxiliary information appended
47640 ** to the end. EXTRA_SIZE is the number of bytes of space needed to hold
47641 ** that extra information.
47643 #define EXTRA_SIZE sizeof(MemPage)
47646 ** A linked list of the following structures is stored at BtShared.pLock.
47647 ** Locks are added (or upgraded from READ_LOCK to WRITE_LOCK) when a cursor
47648 ** is opened on the table with root page BtShared.iTable. Locks are removed
47649 ** from this list when a transaction is committed or rolled back, or when
47650 ** a btree handle is closed.
47652 struct BtLock {
47653 Btree *pBtree; /* Btree handle holding this lock */
47654 Pgno iTable; /* Root page of table */
47655 u8 eLock; /* READ_LOCK or WRITE_LOCK */
47656 BtLock *pNext; /* Next in BtShared.pLock list */
47659 /* Candidate values for BtLock.eLock */
47660 #define READ_LOCK 1
47661 #define WRITE_LOCK 2
47663 /* A Btree handle
47665 ** A database connection contains a pointer to an instance of
47666 ** this object for every database file that it has open. This structure
47667 ** is opaque to the database connection. The database connection cannot
47668 ** see the internals of this structure and only deals with pointers to
47669 ** this structure.
47671 ** For some database files, the same underlying database cache might be
47672 ** shared between multiple connections. In that case, each connection
47673 ** has it own instance of this object. But each instance of this object
47674 ** points to the same BtShared object. The database cache and the
47675 ** schema associated with the database file are all contained within
47676 ** the BtShared object.
47678 ** All fields in this structure are accessed under sqlite3.mutex.
47679 ** The pBt pointer itself may not be changed while there exists cursors
47680 ** in the referenced BtShared that point back to this Btree since those
47681 ** cursors have to go through this Btree to find their BtShared and
47682 ** they often do so without holding sqlite3.mutex.
47684 struct Btree {
47685 sqlite3 *db; /* The database connection holding this btree */
47686 BtShared *pBt; /* Sharable content of this btree */
47687 u8 inTrans; /* TRANS_NONE, TRANS_READ or TRANS_WRITE */
47688 u8 sharable; /* True if we can share pBt with another db */
47689 u8 locked; /* True if db currently has pBt locked */
47690 int wantToLock; /* Number of nested calls to sqlite3BtreeEnter() */
47691 int nBackup; /* Number of backup operations reading this btree */
47692 Btree *pNext; /* List of other sharable Btrees from the same db */
47693 Btree *pPrev; /* Back pointer of the same list */
47694 #ifndef SQLITE_OMIT_SHARED_CACHE
47695 BtLock lock; /* Object used to lock page 1 */
47696 #endif
47700 ** Btree.inTrans may take one of the following values.
47702 ** If the shared-data extension is enabled, there may be multiple users
47703 ** of the Btree structure. At most one of these may open a write transaction,
47704 ** but any number may have active read transactions.
47706 #define TRANS_NONE 0
47707 #define TRANS_READ 1
47708 #define TRANS_WRITE 2
47711 ** An instance of this object represents a single database file.
47713 ** A single database file can be in use as the same time by two
47714 ** or more database connections. When two or more connections are
47715 ** sharing the same database file, each connection has it own
47716 ** private Btree object for the file and each of those Btrees points
47717 ** to this one BtShared object. BtShared.nRef is the number of
47718 ** connections currently sharing this database file.
47720 ** Fields in this structure are accessed under the BtShared.mutex
47721 ** mutex, except for nRef and pNext which are accessed under the
47722 ** global SQLITE_MUTEX_STATIC_MASTER mutex. The pPager field
47723 ** may not be modified once it is initially set as long as nRef>0.
47724 ** The pSchema field may be set once under BtShared.mutex and
47725 ** thereafter is unchanged as long as nRef>0.
47727 ** isPending:
47729 ** If a BtShared client fails to obtain a write-lock on a database
47730 ** table (because there exists one or more read-locks on the table),
47731 ** the shared-cache enters 'pending-lock' state and isPending is
47732 ** set to true.
47734 ** The shared-cache leaves the 'pending lock' state when either of
47735 ** the following occur:
47737 ** 1) The current writer (BtShared.pWriter) concludes its transaction, OR
47738 ** 2) The number of locks held by other connections drops to zero.
47740 ** while in the 'pending-lock' state, no connection may start a new
47741 ** transaction.
47743 ** This feature is included to help prevent writer-starvation.
47745 struct BtShared {
47746 Pager *pPager; /* The page cache */
47747 sqlite3 *db; /* Database connection currently using this Btree */
47748 BtCursor *pCursor; /* A list of all open cursors */
47749 MemPage *pPage1; /* First page of the database */
47750 u8 readOnly; /* True if the underlying file is readonly */
47751 u8 pageSizeFixed; /* True if the page size can no longer be changed */
47752 u8 secureDelete; /* True if secure_delete is enabled */
47753 u8 initiallyEmpty; /* Database is empty at start of transaction */
47754 u8 openFlags; /* Flags to sqlite3BtreeOpen() */
47755 #ifndef SQLITE_OMIT_AUTOVACUUM
47756 u8 autoVacuum; /* True if auto-vacuum is enabled */
47757 u8 incrVacuum; /* True if incr-vacuum is enabled */
47758 #endif
47759 u8 inTransaction; /* Transaction state */
47760 u8 doNotUseWAL; /* If true, do not open write-ahead-log file */
47761 u16 maxLocal; /* Maximum local payload in non-LEAFDATA tables */
47762 u16 minLocal; /* Minimum local payload in non-LEAFDATA tables */
47763 u16 maxLeaf; /* Maximum local payload in a LEAFDATA table */
47764 u16 minLeaf; /* Minimum local payload in a LEAFDATA table */
47765 u32 pageSize; /* Total number of bytes on a page */
47766 u32 usableSize; /* Number of usable bytes on each page */
47767 int nTransaction; /* Number of open transactions (read + write) */
47768 u32 nPage; /* Number of pages in the database */
47769 void *pSchema; /* Pointer to space allocated by sqlite3BtreeSchema() */
47770 void (*xFreeSchema)(void*); /* Destructor for BtShared.pSchema */
47771 sqlite3_mutex *mutex; /* Non-recursive mutex required to access this object */
47772 Bitvec *pHasContent; /* Set of pages moved to free-list this transaction */
47773 #ifndef SQLITE_OMIT_SHARED_CACHE
47774 int nRef; /* Number of references to this structure */
47775 BtShared *pNext; /* Next on a list of sharable BtShared structs */
47776 BtLock *pLock; /* List of locks held on this shared-btree struct */
47777 Btree *pWriter; /* Btree with currently open write transaction */
47778 u8 isExclusive; /* True if pWriter has an EXCLUSIVE lock on the db */
47779 u8 isPending; /* If waiting for read-locks to clear */
47780 #endif
47781 u8 *pTmpSpace; /* BtShared.pageSize bytes of space for tmp use */
47785 ** An instance of the following structure is used to hold information
47786 ** about a cell. The parseCellPtr() function fills in this structure
47787 ** based on information extract from the raw disk page.
47789 typedef struct CellInfo CellInfo;
47790 struct CellInfo {
47791 i64 nKey; /* The key for INTKEY tables, or number of bytes in key */
47792 u8 *pCell; /* Pointer to the start of cell content */
47793 u32 nData; /* Number of bytes of data */
47794 u32 nPayload; /* Total amount of payload */
47795 u16 nHeader; /* Size of the cell content header in bytes */
47796 u16 nLocal; /* Amount of payload held locally */
47797 u16 iOverflow; /* Offset to overflow page number. Zero if no overflow */
47798 u16 nSize; /* Size of the cell content on the main b-tree page */
47802 ** Maximum depth of an SQLite B-Tree structure. Any B-Tree deeper than
47803 ** this will be declared corrupt. This value is calculated based on a
47804 ** maximum database size of 2^31 pages a minimum fanout of 2 for a
47805 ** root-node and 3 for all other internal nodes.
47807 ** If a tree that appears to be taller than this is encountered, it is
47808 ** assumed that the database is corrupt.
47810 #define BTCURSOR_MAX_DEPTH 20
47813 ** A cursor is a pointer to a particular entry within a particular
47814 ** b-tree within a database file.
47816 ** The entry is identified by its MemPage and the index in
47817 ** MemPage.aCell[] of the entry.
47819 ** A single database file can shared by two more database connections,
47820 ** but cursors cannot be shared. Each cursor is associated with a
47821 ** particular database connection identified BtCursor.pBtree.db.
47823 ** Fields in this structure are accessed under the BtShared.mutex
47824 ** found at self->pBt->mutex.
47826 struct BtCursor {
47827 Btree *pBtree; /* The Btree to which this cursor belongs */
47828 BtShared *pBt; /* The BtShared this cursor points to */
47829 BtCursor *pNext, *pPrev; /* Forms a linked list of all cursors */
47830 struct KeyInfo *pKeyInfo; /* Argument passed to comparison function */
47831 Pgno pgnoRoot; /* The root page of this tree */
47832 sqlite3_int64 cachedRowid; /* Next rowid cache. 0 means not valid */
47833 CellInfo info; /* A parse of the cell we are pointing at */
47834 i64 nKey; /* Size of pKey, or last integer key */
47835 void *pKey; /* Saved key that was cursor's last known position */
47836 int skipNext; /* Prev() is noop if negative. Next() is noop if positive */
47837 u8 wrFlag; /* True if writable */
47838 u8 atLast; /* Cursor pointing to the last entry */
47839 u8 validNKey; /* True if info.nKey is valid */
47840 u8 eState; /* One of the CURSOR_XXX constants (see below) */
47841 #ifndef SQLITE_OMIT_INCRBLOB
47842 Pgno *aOverflow; /* Cache of overflow page locations */
47843 u8 isIncrblobHandle; /* True if this cursor is an incr. io handle */
47844 #endif
47845 i16 iPage; /* Index of current page in apPage */
47846 u16 aiIdx[BTCURSOR_MAX_DEPTH]; /* Current index in apPage[i] */
47847 MemPage *apPage[BTCURSOR_MAX_DEPTH]; /* Pages from root to current page */
47851 ** Potential values for BtCursor.eState.
47853 ** CURSOR_VALID:
47854 ** Cursor points to a valid entry. getPayload() etc. may be called.
47856 ** CURSOR_INVALID:
47857 ** Cursor does not point to a valid entry. This can happen (for example)
47858 ** because the table is empty or because BtreeCursorFirst() has not been
47859 ** called.
47861 ** CURSOR_REQUIRESEEK:
47862 ** The table that this cursor was opened on still exists, but has been
47863 ** modified since the cursor was last used. The cursor position is saved
47864 ** in variables BtCursor.pKey and BtCursor.nKey. When a cursor is in
47865 ** this state, restoreCursorPosition() can be called to attempt to
47866 ** seek the cursor to the saved position.
47868 ** CURSOR_FAULT:
47869 ** A unrecoverable error (an I/O error or a malloc failure) has occurred
47870 ** on a different connection that shares the BtShared cache with this
47871 ** cursor. The error has left the cache in an inconsistent state.
47872 ** Do nothing else with this cursor. Any attempt to use the cursor
47873 ** should return the error code stored in BtCursor.skip
47875 #define CURSOR_INVALID 0
47876 #define CURSOR_VALID 1
47877 #define CURSOR_REQUIRESEEK 2
47878 #define CURSOR_FAULT 3
47881 ** The database page the PENDING_BYTE occupies. This page is never used.
47883 # define PENDING_BYTE_PAGE(pBt) PAGER_MJ_PGNO(pBt)
47886 ** These macros define the location of the pointer-map entry for a
47887 ** database page. The first argument to each is the number of usable
47888 ** bytes on each page of the database (often 1024). The second is the
47889 ** page number to look up in the pointer map.
47891 ** PTRMAP_PAGENO returns the database page number of the pointer-map
47892 ** page that stores the required pointer. PTRMAP_PTROFFSET returns
47893 ** the offset of the requested map entry.
47895 ** If the pgno argument passed to PTRMAP_PAGENO is a pointer-map page,
47896 ** then pgno is returned. So (pgno==PTRMAP_PAGENO(pgsz, pgno)) can be
47897 ** used to test if pgno is a pointer-map page. PTRMAP_ISPAGE implements
47898 ** this test.
47900 #define PTRMAP_PAGENO(pBt, pgno) ptrmapPageno(pBt, pgno)
47901 #define PTRMAP_PTROFFSET(pgptrmap, pgno) (5*(pgno-pgptrmap-1))
47902 #define PTRMAP_ISPAGE(pBt, pgno) (PTRMAP_PAGENO((pBt),(pgno))==(pgno))
47905 ** The pointer map is a lookup table that identifies the parent page for
47906 ** each child page in the database file. The parent page is the page that
47907 ** contains a pointer to the child. Every page in the database contains
47908 ** 0 or 1 parent pages. (In this context 'database page' refers
47909 ** to any page that is not part of the pointer map itself.) Each pointer map
47910 ** entry consists of a single byte 'type' and a 4 byte parent page number.
47911 ** The PTRMAP_XXX identifiers below are the valid types.
47913 ** The purpose of the pointer map is to facility moving pages from one
47914 ** position in the file to another as part of autovacuum. When a page
47915 ** is moved, the pointer in its parent must be updated to point to the
47916 ** new location. The pointer map is used to locate the parent page quickly.
47918 ** PTRMAP_ROOTPAGE: The database page is a root-page. The page-number is not
47919 ** used in this case.
47921 ** PTRMAP_FREEPAGE: The database page is an unused (free) page. The page-number
47922 ** is not used in this case.
47924 ** PTRMAP_OVERFLOW1: The database page is the first page in a list of
47925 ** overflow pages. The page number identifies the page that
47926 ** contains the cell with a pointer to this overflow page.
47928 ** PTRMAP_OVERFLOW2: The database page is the second or later page in a list of
47929 ** overflow pages. The page-number identifies the previous
47930 ** page in the overflow page list.
47932 ** PTRMAP_BTREE: The database page is a non-root btree page. The page number
47933 ** identifies the parent page in the btree.
47935 #define PTRMAP_ROOTPAGE 1
47936 #define PTRMAP_FREEPAGE 2
47937 #define PTRMAP_OVERFLOW1 3
47938 #define PTRMAP_OVERFLOW2 4
47939 #define PTRMAP_BTREE 5
47941 /* A bunch of assert() statements to check the transaction state variables
47942 ** of handle p (type Btree*) are internally consistent.
47944 #define btreeIntegrity(p) \
47945 assert( p->pBt->inTransaction!=TRANS_NONE || p->pBt->nTransaction==0 ); \
47946 assert( p->pBt->inTransaction>=p->inTrans );
47950 ** The ISAUTOVACUUM macro is used within balance_nonroot() to determine
47951 ** if the database supports auto-vacuum or not. Because it is used
47952 ** within an expression that is an argument to another macro
47953 ** (sqliteMallocRaw), it is not possible to use conditional compilation.
47954 ** So, this macro is defined instead.
47956 #ifndef SQLITE_OMIT_AUTOVACUUM
47957 #define ISAUTOVACUUM (pBt->autoVacuum)
47958 #else
47959 #define ISAUTOVACUUM 0
47960 #endif
47964 ** This structure is passed around through all the sanity checking routines
47965 ** in order to keep track of some global state information.
47967 typedef struct IntegrityCk IntegrityCk;
47968 struct IntegrityCk {
47969 BtShared *pBt; /* The tree being checked out */
47970 Pager *pPager; /* The associated pager. Also accessible by pBt->pPager */
47971 Pgno nPage; /* Number of pages in the database */
47972 int *anRef; /* Number of times each page is referenced */
47973 int mxErr; /* Stop accumulating errors when this reaches zero */
47974 int nErr; /* Number of messages written to zErrMsg so far */
47975 int mallocFailed; /* A memory allocation error has occurred */
47976 StrAccum errMsg; /* Accumulate the error message text here */
47980 ** Read or write a two- and four-byte big-endian integer values.
47982 #define get2byte(x) ((x)[0]<<8 | (x)[1])
47983 #define put2byte(p,v) ((p)[0] = (u8)((v)>>8), (p)[1] = (u8)(v))
47984 #define get4byte sqlite3Get4byte
47985 #define put4byte sqlite3Put4byte
47987 /************** End of btreeInt.h ********************************************/
47988 /************** Continuing where we left off in btmutex.c ********************/
47989 #ifndef SQLITE_OMIT_SHARED_CACHE
47990 #if SQLITE_THREADSAFE
47993 ** Obtain the BtShared mutex associated with B-Tree handle p. Also,
47994 ** set BtShared.db to the database handle associated with p and the
47995 ** p->locked boolean to true.
47997 static void lockBtreeMutex(Btree *p){
47998 assert( p->locked==0 );
47999 assert( sqlite3_mutex_notheld(p->pBt->mutex) );
48000 assert( sqlite3_mutex_held(p->db->mutex) );
48002 sqlite3_mutex_enter(p->pBt->mutex);
48003 p->pBt->db = p->db;
48004 p->locked = 1;
48008 ** Release the BtShared mutex associated with B-Tree handle p and
48009 ** clear the p->locked boolean.
48011 static void unlockBtreeMutex(Btree *p){
48012 BtShared *pBt = p->pBt;
48013 assert( p->locked==1 );
48014 assert( sqlite3_mutex_held(pBt->mutex) );
48015 assert( sqlite3_mutex_held(p->db->mutex) );
48016 assert( p->db==pBt->db );
48018 sqlite3_mutex_leave(pBt->mutex);
48019 p->locked = 0;
48023 ** Enter a mutex on the given BTree object.
48025 ** If the object is not sharable, then no mutex is ever required
48026 ** and this routine is a no-op. The underlying mutex is non-recursive.
48027 ** But we keep a reference count in Btree.wantToLock so the behavior
48028 ** of this interface is recursive.
48030 ** To avoid deadlocks, multiple Btrees are locked in the same order
48031 ** by all database connections. The p->pNext is a list of other
48032 ** Btrees belonging to the same database connection as the p Btree
48033 ** which need to be locked after p. If we cannot get a lock on
48034 ** p, then first unlock all of the others on p->pNext, then wait
48035 ** for the lock to become available on p, then relock all of the
48036 ** subsequent Btrees that desire a lock.
48038 SQLITE_PRIVATE void sqlite3BtreeEnter(Btree *p){
48039 Btree *pLater;
48041 /* Some basic sanity checking on the Btree. The list of Btrees
48042 ** connected by pNext and pPrev should be in sorted order by
48043 ** Btree.pBt value. All elements of the list should belong to
48044 ** the same connection. Only shared Btrees are on the list. */
48045 assert( p->pNext==0 || p->pNext->pBt>p->pBt );
48046 assert( p->pPrev==0 || p->pPrev->pBt<p->pBt );
48047 assert( p->pNext==0 || p->pNext->db==p->db );
48048 assert( p->pPrev==0 || p->pPrev->db==p->db );
48049 assert( p->sharable || (p->pNext==0 && p->pPrev==0) );
48051 /* Check for locking consistency */
48052 assert( !p->locked || p->wantToLock>0 );
48053 assert( p->sharable || p->wantToLock==0 );
48055 /* We should already hold a lock on the database connection */
48056 assert( sqlite3_mutex_held(p->db->mutex) );
48058 /* Unless the database is sharable and unlocked, then BtShared.db
48059 ** should already be set correctly. */
48060 assert( (p->locked==0 && p->sharable) || p->pBt->db==p->db );
48062 if( !p->sharable ) return;
48063 p->wantToLock++;
48064 if( p->locked ) return;
48066 /* In most cases, we should be able to acquire the lock we
48067 ** want without having to go throught the ascending lock
48068 ** procedure that follows. Just be sure not to block.
48070 if( sqlite3_mutex_try(p->pBt->mutex)==SQLITE_OK ){
48071 p->pBt->db = p->db;
48072 p->locked = 1;
48073 return;
48076 /* To avoid deadlock, first release all locks with a larger
48077 ** BtShared address. Then acquire our lock. Then reacquire
48078 ** the other BtShared locks that we used to hold in ascending
48079 ** order.
48081 for(pLater=p->pNext; pLater; pLater=pLater->pNext){
48082 assert( pLater->sharable );
48083 assert( pLater->pNext==0 || pLater->pNext->pBt>pLater->pBt );
48084 assert( !pLater->locked || pLater->wantToLock>0 );
48085 if( pLater->locked ){
48086 unlockBtreeMutex(pLater);
48089 lockBtreeMutex(p);
48090 for(pLater=p->pNext; pLater; pLater=pLater->pNext){
48091 if( pLater->wantToLock ){
48092 lockBtreeMutex(pLater);
48098 ** Exit the recursive mutex on a Btree.
48100 SQLITE_PRIVATE void sqlite3BtreeLeave(Btree *p){
48101 if( p->sharable ){
48102 assert( p->wantToLock>0 );
48103 p->wantToLock--;
48104 if( p->wantToLock==0 ){
48105 unlockBtreeMutex(p);
48110 #ifndef NDEBUG
48112 ** Return true if the BtShared mutex is held on the btree, or if the
48113 ** B-Tree is not marked as sharable.
48115 ** This routine is used only from within assert() statements.
48117 SQLITE_PRIVATE int sqlite3BtreeHoldsMutex(Btree *p){
48118 assert( p->sharable==0 || p->locked==0 || p->wantToLock>0 );
48119 assert( p->sharable==0 || p->locked==0 || p->db==p->pBt->db );
48120 assert( p->sharable==0 || p->locked==0 || sqlite3_mutex_held(p->pBt->mutex) );
48121 assert( p->sharable==0 || p->locked==0 || sqlite3_mutex_held(p->db->mutex) );
48123 return (p->sharable==0 || p->locked);
48125 #endif
48128 #ifndef SQLITE_OMIT_INCRBLOB
48130 ** Enter and leave a mutex on a Btree given a cursor owned by that
48131 ** Btree. These entry points are used by incremental I/O and can be
48132 ** omitted if that module is not used.
48134 SQLITE_PRIVATE void sqlite3BtreeEnterCursor(BtCursor *pCur){
48135 sqlite3BtreeEnter(pCur->pBtree);
48137 SQLITE_PRIVATE void sqlite3BtreeLeaveCursor(BtCursor *pCur){
48138 sqlite3BtreeLeave(pCur->pBtree);
48140 #endif /* SQLITE_OMIT_INCRBLOB */
48144 ** Enter the mutex on every Btree associated with a database
48145 ** connection. This is needed (for example) prior to parsing
48146 ** a statement since we will be comparing table and column names
48147 ** against all schemas and we do not want those schemas being
48148 ** reset out from under us.
48150 ** There is a corresponding leave-all procedures.
48152 ** Enter the mutexes in accending order by BtShared pointer address
48153 ** to avoid the possibility of deadlock when two threads with
48154 ** two or more btrees in common both try to lock all their btrees
48155 ** at the same instant.
48157 SQLITE_PRIVATE void sqlite3BtreeEnterAll(sqlite3 *db){
48158 int i;
48159 Btree *p;
48160 assert( sqlite3_mutex_held(db->mutex) );
48161 for(i=0; i<db->nDb; i++){
48162 p = db->aDb[i].pBt;
48163 if( p ) sqlite3BtreeEnter(p);
48166 SQLITE_PRIVATE void sqlite3BtreeLeaveAll(sqlite3 *db){
48167 int i;
48168 Btree *p;
48169 assert( sqlite3_mutex_held(db->mutex) );
48170 for(i=0; i<db->nDb; i++){
48171 p = db->aDb[i].pBt;
48172 if( p ) sqlite3BtreeLeave(p);
48177 ** Return true if a particular Btree requires a lock. Return FALSE if
48178 ** no lock is ever required since it is not sharable.
48180 SQLITE_PRIVATE int sqlite3BtreeSharable(Btree *p){
48181 return p->sharable;
48184 #ifndef NDEBUG
48186 ** Return true if the current thread holds the database connection
48187 ** mutex and all required BtShared mutexes.
48189 ** This routine is used inside assert() statements only.
48191 SQLITE_PRIVATE int sqlite3BtreeHoldsAllMutexes(sqlite3 *db){
48192 int i;
48193 if( !sqlite3_mutex_held(db->mutex) ){
48194 return 0;
48196 for(i=0; i<db->nDb; i++){
48197 Btree *p;
48198 p = db->aDb[i].pBt;
48199 if( p && p->sharable &&
48200 (p->wantToLock==0 || !sqlite3_mutex_held(p->pBt->mutex)) ){
48201 return 0;
48204 return 1;
48206 #endif /* NDEBUG */
48208 #ifndef NDEBUG
48210 ** Return true if the correct mutexes are held for accessing the
48211 ** db->aDb[iDb].pSchema structure. The mutexes required for schema
48212 ** access are:
48214 ** (1) The mutex on db
48215 ** (2) if iDb!=1, then the mutex on db->aDb[iDb].pBt.
48217 ** If pSchema is not NULL, then iDb is computed from pSchema and
48218 ** db using sqlite3SchemaToIndex().
48220 SQLITE_PRIVATE int sqlite3SchemaMutexHeld(sqlite3 *db, int iDb, Schema *pSchema){
48221 Btree *p;
48222 assert( db!=0 );
48223 if( pSchema ) iDb = sqlite3SchemaToIndex(db, pSchema);
48224 assert( iDb>=0 && iDb<db->nDb );
48225 if( !sqlite3_mutex_held(db->mutex) ) return 0;
48226 if( iDb==1 ) return 1;
48227 p = db->aDb[iDb].pBt;
48228 assert( p!=0 );
48229 return p->sharable==0 || p->locked==1;
48231 #endif /* NDEBUG */
48233 #else /* SQLITE_THREADSAFE>0 above. SQLITE_THREADSAFE==0 below */
48235 ** The following are special cases for mutex enter routines for use
48236 ** in single threaded applications that use shared cache. Except for
48237 ** these two routines, all mutex operations are no-ops in that case and
48238 ** are null #defines in btree.h.
48240 ** If shared cache is disabled, then all btree mutex routines, including
48241 ** the ones below, are no-ops and are null #defines in btree.h.
48244 SQLITE_PRIVATE void sqlite3BtreeEnter(Btree *p){
48245 p->pBt->db = p->db;
48247 SQLITE_PRIVATE void sqlite3BtreeEnterAll(sqlite3 *db){
48248 int i;
48249 for(i=0; i<db->nDb; i++){
48250 Btree *p = db->aDb[i].pBt;
48251 if( p ){
48252 p->pBt->db = p->db;
48256 #endif /* if SQLITE_THREADSAFE */
48257 #endif /* ifndef SQLITE_OMIT_SHARED_CACHE */
48259 /************** End of btmutex.c *********************************************/
48260 /************** Begin file btree.c *******************************************/
48262 ** 2004 April 6
48264 ** The author disclaims copyright to this source code. In place of
48265 ** a legal notice, here is a blessing:
48267 ** May you do good and not evil.
48268 ** May you find forgiveness for yourself and forgive others.
48269 ** May you share freely, never taking more than you give.
48271 *************************************************************************
48272 ** This file implements a external (disk-based) database using BTrees.
48273 ** See the header comment on "btreeInt.h" for additional information.
48274 ** Including a description of file format and an overview of operation.
48278 ** The header string that appears at the beginning of every
48279 ** SQLite database.
48281 static const char zMagicHeader[] = SQLITE_FILE_HEADER;
48284 ** Set this global variable to 1 to enable tracing using the TRACE
48285 ** macro.
48287 #if 0
48288 int sqlite3BtreeTrace=1; /* True to enable tracing */
48289 # define TRACE(X) if(sqlite3BtreeTrace){printf X;fflush(stdout);}
48290 #else
48291 # define TRACE(X)
48292 #endif
48295 ** Extract a 2-byte big-endian integer from an array of unsigned bytes.
48296 ** But if the value is zero, make it 65536.
48298 ** This routine is used to extract the "offset to cell content area" value
48299 ** from the header of a btree page. If the page size is 65536 and the page
48300 ** is empty, the offset should be 65536, but the 2-byte value stores zero.
48301 ** This routine makes the necessary adjustment to 65536.
48303 #define get2byteNotZero(X) (((((int)get2byte(X))-1)&0xffff)+1)
48305 #ifndef SQLITE_OMIT_SHARED_CACHE
48307 ** A list of BtShared objects that are eligible for participation
48308 ** in shared cache. This variable has file scope during normal builds,
48309 ** but the test harness needs to access it so we make it global for
48310 ** test builds.
48312 ** Access to this variable is protected by SQLITE_MUTEX_STATIC_MASTER.
48314 #ifdef SQLITE_TEST
48315 SQLITE_PRIVATE BtShared *SQLITE_WSD sqlite3SharedCacheList = 0;
48316 #else
48317 static BtShared *SQLITE_WSD sqlite3SharedCacheList = 0;
48318 #endif
48319 #endif /* SQLITE_OMIT_SHARED_CACHE */
48321 #ifndef SQLITE_OMIT_SHARED_CACHE
48323 ** Enable or disable the shared pager and schema features.
48325 ** This routine has no effect on existing database connections.
48326 ** The shared cache setting effects only future calls to
48327 ** sqlite3_open(), sqlite3_open16(), or sqlite3_open_v2().
48329 SQLITE_API int sqlite3_enable_shared_cache(int enable){
48330 sqlite3GlobalConfig.sharedCacheEnabled = enable;
48331 return SQLITE_OK;
48333 #endif
48337 #ifdef SQLITE_OMIT_SHARED_CACHE
48339 ** The functions querySharedCacheTableLock(), setSharedCacheTableLock(),
48340 ** and clearAllSharedCacheTableLocks()
48341 ** manipulate entries in the BtShared.pLock linked list used to store
48342 ** shared-cache table level locks. If the library is compiled with the
48343 ** shared-cache feature disabled, then there is only ever one user
48344 ** of each BtShared structure and so this locking is not necessary.
48345 ** So define the lock related functions as no-ops.
48347 #define querySharedCacheTableLock(a,b,c) SQLITE_OK
48348 #define setSharedCacheTableLock(a,b,c) SQLITE_OK
48349 #define clearAllSharedCacheTableLocks(a)
48350 #define downgradeAllSharedCacheTableLocks(a)
48351 #define hasSharedCacheTableLock(a,b,c,d) 1
48352 #define hasReadConflicts(a, b) 0
48353 #endif
48355 #ifndef SQLITE_OMIT_SHARED_CACHE
48357 #ifdef SQLITE_DEBUG
48359 **** This function is only used as part of an assert() statement. ***
48361 ** Check to see if pBtree holds the required locks to read or write to the
48362 ** table with root page iRoot. Return 1 if it does and 0 if not.
48364 ** For example, when writing to a table with root-page iRoot via
48365 ** Btree connection pBtree:
48367 ** assert( hasSharedCacheTableLock(pBtree, iRoot, 0, WRITE_LOCK) );
48369 ** When writing to an index that resides in a sharable database, the
48370 ** caller should have first obtained a lock specifying the root page of
48371 ** the corresponding table. This makes things a bit more complicated,
48372 ** as this module treats each table as a separate structure. To determine
48373 ** the table corresponding to the index being written, this
48374 ** function has to search through the database schema.
48376 ** Instead of a lock on the table/index rooted at page iRoot, the caller may
48377 ** hold a write-lock on the schema table (root page 1). This is also
48378 ** acceptable.
48380 static int hasSharedCacheTableLock(
48381 Btree *pBtree, /* Handle that must hold lock */
48382 Pgno iRoot, /* Root page of b-tree */
48383 int isIndex, /* True if iRoot is the root of an index b-tree */
48384 int eLockType /* Required lock type (READ_LOCK or WRITE_LOCK) */
48386 Schema *pSchema = (Schema *)pBtree->pBt->pSchema;
48387 Pgno iTab = 0;
48388 BtLock *pLock;
48390 /* If this database is not shareable, or if the client is reading
48391 ** and has the read-uncommitted flag set, then no lock is required.
48392 ** Return true immediately.
48394 if( (pBtree->sharable==0)
48395 || (eLockType==READ_LOCK && (pBtree->db->flags & SQLITE_ReadUncommitted))
48397 return 1;
48400 /* If the client is reading or writing an index and the schema is
48401 ** not loaded, then it is too difficult to actually check to see if
48402 ** the correct locks are held. So do not bother - just return true.
48403 ** This case does not come up very often anyhow.
48405 if( isIndex && (!pSchema || (pSchema->flags&DB_SchemaLoaded)==0) ){
48406 return 1;
48409 /* Figure out the root-page that the lock should be held on. For table
48410 ** b-trees, this is just the root page of the b-tree being read or
48411 ** written. For index b-trees, it is the root page of the associated
48412 ** table. */
48413 if( isIndex ){
48414 HashElem *p;
48415 for(p=sqliteHashFirst(&pSchema->idxHash); p; p=sqliteHashNext(p)){
48416 Index *pIdx = (Index *)sqliteHashData(p);
48417 if( pIdx->tnum==(int)iRoot ){
48418 iTab = pIdx->pTable->tnum;
48421 }else{
48422 iTab = iRoot;
48425 /* Search for the required lock. Either a write-lock on root-page iTab, a
48426 ** write-lock on the schema table, or (if the client is reading) a
48427 ** read-lock on iTab will suffice. Return 1 if any of these are found. */
48428 for(pLock=pBtree->pBt->pLock; pLock; pLock=pLock->pNext){
48429 if( pLock->pBtree==pBtree
48430 && (pLock->iTable==iTab || (pLock->eLock==WRITE_LOCK && pLock->iTable==1))
48431 && pLock->eLock>=eLockType
48433 return 1;
48437 /* Failed to find the required lock. */
48438 return 0;
48440 #endif /* SQLITE_DEBUG */
48442 #ifdef SQLITE_DEBUG
48444 **** This function may be used as part of assert() statements only. ****
48446 ** Return true if it would be illegal for pBtree to write into the
48447 ** table or index rooted at iRoot because other shared connections are
48448 ** simultaneously reading that same table or index.
48450 ** It is illegal for pBtree to write if some other Btree object that
48451 ** shares the same BtShared object is currently reading or writing
48452 ** the iRoot table. Except, if the other Btree object has the
48453 ** read-uncommitted flag set, then it is OK for the other object to
48454 ** have a read cursor.
48456 ** For example, before writing to any part of the table or index
48457 ** rooted at page iRoot, one should call:
48459 ** assert( !hasReadConflicts(pBtree, iRoot) );
48461 static int hasReadConflicts(Btree *pBtree, Pgno iRoot){
48462 BtCursor *p;
48463 for(p=pBtree->pBt->pCursor; p; p=p->pNext){
48464 if( p->pgnoRoot==iRoot
48465 && p->pBtree!=pBtree
48466 && 0==(p->pBtree->db->flags & SQLITE_ReadUncommitted)
48468 return 1;
48471 return 0;
48473 #endif /* #ifdef SQLITE_DEBUG */
48476 ** Query to see if Btree handle p may obtain a lock of type eLock
48477 ** (READ_LOCK or WRITE_LOCK) on the table with root-page iTab. Return
48478 ** SQLITE_OK if the lock may be obtained (by calling
48479 ** setSharedCacheTableLock()), or SQLITE_LOCKED if not.
48481 static int querySharedCacheTableLock(Btree *p, Pgno iTab, u8 eLock){
48482 BtShared *pBt = p->pBt;
48483 BtLock *pIter;
48485 assert( sqlite3BtreeHoldsMutex(p) );
48486 assert( eLock==READ_LOCK || eLock==WRITE_LOCK );
48487 assert( p->db!=0 );
48488 assert( !(p->db->flags&SQLITE_ReadUncommitted)||eLock==WRITE_LOCK||iTab==1 );
48490 /* If requesting a write-lock, then the Btree must have an open write
48491 ** transaction on this file. And, obviously, for this to be so there
48492 ** must be an open write transaction on the file itself.
48494 assert( eLock==READ_LOCK || (p==pBt->pWriter && p->inTrans==TRANS_WRITE) );
48495 assert( eLock==READ_LOCK || pBt->inTransaction==TRANS_WRITE );
48497 /* This routine is a no-op if the shared-cache is not enabled */
48498 if( !p->sharable ){
48499 return SQLITE_OK;
48502 /* If some other connection is holding an exclusive lock, the
48503 ** requested lock may not be obtained.
48505 if( pBt->pWriter!=p && pBt->isExclusive ){
48506 sqlite3ConnectionBlocked(p->db, pBt->pWriter->db);
48507 return SQLITE_LOCKED_SHAREDCACHE;
48510 for(pIter=pBt->pLock; pIter; pIter=pIter->pNext){
48511 /* The condition (pIter->eLock!=eLock) in the following if(...)
48512 ** statement is a simplification of:
48514 ** (eLock==WRITE_LOCK || pIter->eLock==WRITE_LOCK)
48516 ** since we know that if eLock==WRITE_LOCK, then no other connection
48517 ** may hold a WRITE_LOCK on any table in this file (since there can
48518 ** only be a single writer).
48520 assert( pIter->eLock==READ_LOCK || pIter->eLock==WRITE_LOCK );
48521 assert( eLock==READ_LOCK || pIter->pBtree==p || pIter->eLock==READ_LOCK);
48522 if( pIter->pBtree!=p && pIter->iTable==iTab && pIter->eLock!=eLock ){
48523 sqlite3ConnectionBlocked(p->db, pIter->pBtree->db);
48524 if( eLock==WRITE_LOCK ){
48525 assert( p==pBt->pWriter );
48526 pBt->isPending = 1;
48528 return SQLITE_LOCKED_SHAREDCACHE;
48531 return SQLITE_OK;
48533 #endif /* !SQLITE_OMIT_SHARED_CACHE */
48535 #ifndef SQLITE_OMIT_SHARED_CACHE
48537 ** Add a lock on the table with root-page iTable to the shared-btree used
48538 ** by Btree handle p. Parameter eLock must be either READ_LOCK or
48539 ** WRITE_LOCK.
48541 ** This function assumes the following:
48543 ** (a) The specified Btree object p is connected to a sharable
48544 ** database (one with the BtShared.sharable flag set), and
48546 ** (b) No other Btree objects hold a lock that conflicts
48547 ** with the requested lock (i.e. querySharedCacheTableLock() has
48548 ** already been called and returned SQLITE_OK).
48550 ** SQLITE_OK is returned if the lock is added successfully. SQLITE_NOMEM
48551 ** is returned if a malloc attempt fails.
48553 static int setSharedCacheTableLock(Btree *p, Pgno iTable, u8 eLock){
48554 BtShared *pBt = p->pBt;
48555 BtLock *pLock = 0;
48556 BtLock *pIter;
48558 assert( sqlite3BtreeHoldsMutex(p) );
48559 assert( eLock==READ_LOCK || eLock==WRITE_LOCK );
48560 assert( p->db!=0 );
48562 /* A connection with the read-uncommitted flag set will never try to
48563 ** obtain a read-lock using this function. The only read-lock obtained
48564 ** by a connection in read-uncommitted mode is on the sqlite_master
48565 ** table, and that lock is obtained in BtreeBeginTrans(). */
48566 assert( 0==(p->db->flags&SQLITE_ReadUncommitted) || eLock==WRITE_LOCK );
48568 /* This function should only be called on a sharable b-tree after it
48569 ** has been determined that no other b-tree holds a conflicting lock. */
48570 assert( p->sharable );
48571 assert( SQLITE_OK==querySharedCacheTableLock(p, iTable, eLock) );
48573 /* First search the list for an existing lock on this table. */
48574 for(pIter=pBt->pLock; pIter; pIter=pIter->pNext){
48575 if( pIter->iTable==iTable && pIter->pBtree==p ){
48576 pLock = pIter;
48577 break;
48581 /* If the above search did not find a BtLock struct associating Btree p
48582 ** with table iTable, allocate one and link it into the list.
48584 if( !pLock ){
48585 pLock = (BtLock *)sqlite3MallocZero(sizeof(BtLock));
48586 if( !pLock ){
48587 return SQLITE_NOMEM;
48589 pLock->iTable = iTable;
48590 pLock->pBtree = p;
48591 pLock->pNext = pBt->pLock;
48592 pBt->pLock = pLock;
48595 /* Set the BtLock.eLock variable to the maximum of the current lock
48596 ** and the requested lock. This means if a write-lock was already held
48597 ** and a read-lock requested, we don't incorrectly downgrade the lock.
48599 assert( WRITE_LOCK>READ_LOCK );
48600 if( eLock>pLock->eLock ){
48601 pLock->eLock = eLock;
48604 return SQLITE_OK;
48606 #endif /* !SQLITE_OMIT_SHARED_CACHE */
48608 #ifndef SQLITE_OMIT_SHARED_CACHE
48610 ** Release all the table locks (locks obtained via calls to
48611 ** the setSharedCacheTableLock() procedure) held by Btree object p.
48613 ** This function assumes that Btree p has an open read or write
48614 ** transaction. If it does not, then the BtShared.isPending variable
48615 ** may be incorrectly cleared.
48617 static void clearAllSharedCacheTableLocks(Btree *p){
48618 BtShared *pBt = p->pBt;
48619 BtLock **ppIter = &pBt->pLock;
48621 assert( sqlite3BtreeHoldsMutex(p) );
48622 assert( p->sharable || 0==*ppIter );
48623 assert( p->inTrans>0 );
48625 while( *ppIter ){
48626 BtLock *pLock = *ppIter;
48627 assert( pBt->isExclusive==0 || pBt->pWriter==pLock->pBtree );
48628 assert( pLock->pBtree->inTrans>=pLock->eLock );
48629 if( pLock->pBtree==p ){
48630 *ppIter = pLock->pNext;
48631 assert( pLock->iTable!=1 || pLock==&p->lock );
48632 if( pLock->iTable!=1 ){
48633 sqlite3_free(pLock);
48635 }else{
48636 ppIter = &pLock->pNext;
48640 assert( pBt->isPending==0 || pBt->pWriter );
48641 if( pBt->pWriter==p ){
48642 pBt->pWriter = 0;
48643 pBt->isExclusive = 0;
48644 pBt->isPending = 0;
48645 }else if( pBt->nTransaction==2 ){
48646 /* This function is called when Btree p is concluding its
48647 ** transaction. If there currently exists a writer, and p is not
48648 ** that writer, then the number of locks held by connections other
48649 ** than the writer must be about to drop to zero. In this case
48650 ** set the isPending flag to 0.
48652 ** If there is not currently a writer, then BtShared.isPending must
48653 ** be zero already. So this next line is harmless in that case.
48655 pBt->isPending = 0;
48660 ** This function changes all write-locks held by Btree p into read-locks.
48662 static void downgradeAllSharedCacheTableLocks(Btree *p){
48663 BtShared *pBt = p->pBt;
48664 if( pBt->pWriter==p ){
48665 BtLock *pLock;
48666 pBt->pWriter = 0;
48667 pBt->isExclusive = 0;
48668 pBt->isPending = 0;
48669 for(pLock=pBt->pLock; pLock; pLock=pLock->pNext){
48670 assert( pLock->eLock==READ_LOCK || pLock->pBtree==p );
48671 pLock->eLock = READ_LOCK;
48676 #endif /* SQLITE_OMIT_SHARED_CACHE */
48678 static void releasePage(MemPage *pPage); /* Forward reference */
48681 ***** This routine is used inside of assert() only ****
48683 ** Verify that the cursor holds the mutex on its BtShared
48685 #ifdef SQLITE_DEBUG
48686 static int cursorHoldsMutex(BtCursor *p){
48687 return sqlite3_mutex_held(p->pBt->mutex);
48689 #endif
48692 #ifndef SQLITE_OMIT_INCRBLOB
48694 ** Invalidate the overflow page-list cache for cursor pCur, if any.
48696 static void invalidateOverflowCache(BtCursor *pCur){
48697 assert( cursorHoldsMutex(pCur) );
48698 sqlite3_free(pCur->aOverflow);
48699 pCur->aOverflow = 0;
48703 ** Invalidate the overflow page-list cache for all cursors opened
48704 ** on the shared btree structure pBt.
48706 static void invalidateAllOverflowCache(BtShared *pBt){
48707 BtCursor *p;
48708 assert( sqlite3_mutex_held(pBt->mutex) );
48709 for(p=pBt->pCursor; p; p=p->pNext){
48710 invalidateOverflowCache(p);
48715 ** This function is called before modifying the contents of a table
48716 ** to invalidate any incrblob cursors that are open on the
48717 ** row or one of the rows being modified.
48719 ** If argument isClearTable is true, then the entire contents of the
48720 ** table is about to be deleted. In this case invalidate all incrblob
48721 ** cursors open on any row within the table with root-page pgnoRoot.
48723 ** Otherwise, if argument isClearTable is false, then the row with
48724 ** rowid iRow is being replaced or deleted. In this case invalidate
48725 ** only those incrblob cursors open on that specific row.
48727 static void invalidateIncrblobCursors(
48728 Btree *pBtree, /* The database file to check */
48729 i64 iRow, /* The rowid that might be changing */
48730 int isClearTable /* True if all rows are being deleted */
48732 BtCursor *p;
48733 BtShared *pBt = pBtree->pBt;
48734 assert( sqlite3BtreeHoldsMutex(pBtree) );
48735 for(p=pBt->pCursor; p; p=p->pNext){
48736 if( p->isIncrblobHandle && (isClearTable || p->info.nKey==iRow) ){
48737 p->eState = CURSOR_INVALID;
48742 #else
48743 /* Stub functions when INCRBLOB is omitted */
48744 #define invalidateOverflowCache(x)
48745 #define invalidateAllOverflowCache(x)
48746 #define invalidateIncrblobCursors(x,y,z)
48747 #endif /* SQLITE_OMIT_INCRBLOB */
48750 ** Set bit pgno of the BtShared.pHasContent bitvec. This is called
48751 ** when a page that previously contained data becomes a free-list leaf
48752 ** page.
48754 ** The BtShared.pHasContent bitvec exists to work around an obscure
48755 ** bug caused by the interaction of two useful IO optimizations surrounding
48756 ** free-list leaf pages:
48758 ** 1) When all data is deleted from a page and the page becomes
48759 ** a free-list leaf page, the page is not written to the database
48760 ** (as free-list leaf pages contain no meaningful data). Sometimes
48761 ** such a page is not even journalled (as it will not be modified,
48762 ** why bother journalling it?).
48764 ** 2) When a free-list leaf page is reused, its content is not read
48765 ** from the database or written to the journal file (why should it
48766 ** be, if it is not at all meaningful?).
48768 ** By themselves, these optimizations work fine and provide a handy
48769 ** performance boost to bulk delete or insert operations. However, if
48770 ** a page is moved to the free-list and then reused within the same
48771 ** transaction, a problem comes up. If the page is not journalled when
48772 ** it is moved to the free-list and it is also not journalled when it
48773 ** is extracted from the free-list and reused, then the original data
48774 ** may be lost. In the event of a rollback, it may not be possible
48775 ** to restore the database to its original configuration.
48777 ** The solution is the BtShared.pHasContent bitvec. Whenever a page is
48778 ** moved to become a free-list leaf page, the corresponding bit is
48779 ** set in the bitvec. Whenever a leaf page is extracted from the free-list,
48780 ** optimization 2 above is omitted if the corresponding bit is already
48781 ** set in BtShared.pHasContent. The contents of the bitvec are cleared
48782 ** at the end of every transaction.
48784 static int btreeSetHasContent(BtShared *pBt, Pgno pgno){
48785 int rc = SQLITE_OK;
48786 if( !pBt->pHasContent ){
48787 assert( pgno<=pBt->nPage );
48788 pBt->pHasContent = sqlite3BitvecCreate(pBt->nPage);
48789 if( !pBt->pHasContent ){
48790 rc = SQLITE_NOMEM;
48793 if( rc==SQLITE_OK && pgno<=sqlite3BitvecSize(pBt->pHasContent) ){
48794 rc = sqlite3BitvecSet(pBt->pHasContent, pgno);
48796 return rc;
48800 ** Query the BtShared.pHasContent vector.
48802 ** This function is called when a free-list leaf page is removed from the
48803 ** free-list for reuse. It returns false if it is safe to retrieve the
48804 ** page from the pager layer with the 'no-content' flag set. True otherwise.
48806 static int btreeGetHasContent(BtShared *pBt, Pgno pgno){
48807 Bitvec *p = pBt->pHasContent;
48808 return (p && (pgno>sqlite3BitvecSize(p) || sqlite3BitvecTest(p, pgno)));
48812 ** Clear (destroy) the BtShared.pHasContent bitvec. This should be
48813 ** invoked at the conclusion of each write-transaction.
48815 static void btreeClearHasContent(BtShared *pBt){
48816 sqlite3BitvecDestroy(pBt->pHasContent);
48817 pBt->pHasContent = 0;
48821 ** Save the current cursor position in the variables BtCursor.nKey
48822 ** and BtCursor.pKey. The cursor's state is set to CURSOR_REQUIRESEEK.
48824 ** The caller must ensure that the cursor is valid (has eState==CURSOR_VALID)
48825 ** prior to calling this routine.
48827 static int saveCursorPosition(BtCursor *pCur){
48828 int rc;
48830 assert( CURSOR_VALID==pCur->eState );
48831 assert( 0==pCur->pKey );
48832 assert( cursorHoldsMutex(pCur) );
48834 rc = sqlite3BtreeKeySize(pCur, &pCur->nKey);
48835 assert( rc==SQLITE_OK ); /* KeySize() cannot fail */
48837 /* If this is an intKey table, then the above call to BtreeKeySize()
48838 ** stores the integer key in pCur->nKey. In this case this value is
48839 ** all that is required. Otherwise, if pCur is not open on an intKey
48840 ** table, then malloc space for and store the pCur->nKey bytes of key
48841 ** data.
48843 if( 0==pCur->apPage[0]->intKey ){
48844 void *pKey = sqlite3Malloc( (int)pCur->nKey );
48845 if( pKey ){
48846 rc = sqlite3BtreeKey(pCur, 0, (int)pCur->nKey, pKey);
48847 if( rc==SQLITE_OK ){
48848 pCur->pKey = pKey;
48849 }else{
48850 sqlite3_free(pKey);
48852 }else{
48853 rc = SQLITE_NOMEM;
48856 assert( !pCur->apPage[0]->intKey || !pCur->pKey );
48858 if( rc==SQLITE_OK ){
48859 int i;
48860 for(i=0; i<=pCur->iPage; i++){
48861 releasePage(pCur->apPage[i]);
48862 pCur->apPage[i] = 0;
48864 pCur->iPage = -1;
48865 pCur->eState = CURSOR_REQUIRESEEK;
48868 invalidateOverflowCache(pCur);
48869 return rc;
48873 ** Save the positions of all cursors (except pExcept) that are open on
48874 ** the table with root-page iRoot. Usually, this is called just before cursor
48875 ** pExcept is used to modify the table (BtreeDelete() or BtreeInsert()).
48877 static int saveAllCursors(BtShared *pBt, Pgno iRoot, BtCursor *pExcept){
48878 BtCursor *p;
48879 assert( sqlite3_mutex_held(pBt->mutex) );
48880 assert( pExcept==0 || pExcept->pBt==pBt );
48881 for(p=pBt->pCursor; p; p=p->pNext){
48882 if( p!=pExcept && (0==iRoot || p->pgnoRoot==iRoot) &&
48883 p->eState==CURSOR_VALID ){
48884 int rc = saveCursorPosition(p);
48885 if( SQLITE_OK!=rc ){
48886 return rc;
48890 return SQLITE_OK;
48894 ** Clear the current cursor position.
48896 SQLITE_PRIVATE void sqlite3BtreeClearCursor(BtCursor *pCur){
48897 assert( cursorHoldsMutex(pCur) );
48898 sqlite3_free(pCur->pKey);
48899 pCur->pKey = 0;
48900 pCur->eState = CURSOR_INVALID;
48904 ** In this version of BtreeMoveto, pKey is a packed index record
48905 ** such as is generated by the OP_MakeRecord opcode. Unpack the
48906 ** record and then call BtreeMovetoUnpacked() to do the work.
48908 static int btreeMoveto(
48909 BtCursor *pCur, /* Cursor open on the btree to be searched */
48910 const void *pKey, /* Packed key if the btree is an index */
48911 i64 nKey, /* Integer key for tables. Size of pKey for indices */
48912 int bias, /* Bias search to the high end */
48913 int *pRes /* Write search results here */
48915 int rc; /* Status code */
48916 UnpackedRecord *pIdxKey; /* Unpacked index key */
48917 char aSpace[150]; /* Temp space for pIdxKey - to avoid a malloc */
48918 char *pFree = 0;
48920 if( pKey ){
48921 assert( nKey==(i64)(int)nKey );
48922 pIdxKey = sqlite3VdbeAllocUnpackedRecord(
48923 pCur->pKeyInfo, aSpace, sizeof(aSpace), &pFree
48925 if( pIdxKey==0 ) return SQLITE_NOMEM;
48926 sqlite3VdbeRecordUnpack(pCur->pKeyInfo, (int)nKey, pKey, pIdxKey);
48927 }else{
48928 pIdxKey = 0;
48930 rc = sqlite3BtreeMovetoUnpacked(pCur, pIdxKey, nKey, bias, pRes);
48931 if( pFree ){
48932 sqlite3DbFree(pCur->pKeyInfo->db, pFree);
48934 return rc;
48938 ** Restore the cursor to the position it was in (or as close to as possible)
48939 ** when saveCursorPosition() was called. Note that this call deletes the
48940 ** saved position info stored by saveCursorPosition(), so there can be
48941 ** at most one effective restoreCursorPosition() call after each
48942 ** saveCursorPosition().
48944 static int btreeRestoreCursorPosition(BtCursor *pCur){
48945 int rc;
48946 assert( cursorHoldsMutex(pCur) );
48947 assert( pCur->eState>=CURSOR_REQUIRESEEK );
48948 if( pCur->eState==CURSOR_FAULT ){
48949 return pCur->skipNext;
48951 pCur->eState = CURSOR_INVALID;
48952 rc = btreeMoveto(pCur, pCur->pKey, pCur->nKey, 0, &pCur->skipNext);
48953 if( rc==SQLITE_OK ){
48954 sqlite3_free(pCur->pKey);
48955 pCur->pKey = 0;
48956 assert( pCur->eState==CURSOR_VALID || pCur->eState==CURSOR_INVALID );
48958 return rc;
48961 #define restoreCursorPosition(p) \
48962 (p->eState>=CURSOR_REQUIRESEEK ? \
48963 btreeRestoreCursorPosition(p) : \
48964 SQLITE_OK)
48967 ** Determine whether or not a cursor has moved from the position it
48968 ** was last placed at. Cursors can move when the row they are pointing
48969 ** at is deleted out from under them.
48971 ** This routine returns an error code if something goes wrong. The
48972 ** integer *pHasMoved is set to one if the cursor has moved and 0 if not.
48974 SQLITE_PRIVATE int sqlite3BtreeCursorHasMoved(BtCursor *pCur, int *pHasMoved){
48975 int rc;
48977 rc = restoreCursorPosition(pCur);
48978 if( rc ){
48979 *pHasMoved = 1;
48980 return rc;
48982 if( pCur->eState!=CURSOR_VALID || pCur->skipNext!=0 ){
48983 *pHasMoved = 1;
48984 }else{
48985 *pHasMoved = 0;
48987 return SQLITE_OK;
48990 #ifndef SQLITE_OMIT_AUTOVACUUM
48992 ** Given a page number of a regular database page, return the page
48993 ** number for the pointer-map page that contains the entry for the
48994 ** input page number.
48996 ** Return 0 (not a valid page) for pgno==1 since there is
48997 ** no pointer map associated with page 1. The integrity_check logic
48998 ** requires that ptrmapPageno(*,1)!=1.
49000 static Pgno ptrmapPageno(BtShared *pBt, Pgno pgno){
49001 int nPagesPerMapPage;
49002 Pgno iPtrMap, ret;
49003 assert( sqlite3_mutex_held(pBt->mutex) );
49004 if( pgno<2 ) return 0;
49005 nPagesPerMapPage = (pBt->usableSize/5)+1;
49006 iPtrMap = (pgno-2)/nPagesPerMapPage;
49007 ret = (iPtrMap*nPagesPerMapPage) + 2;
49008 if( ret==PENDING_BYTE_PAGE(pBt) ){
49009 ret++;
49011 return ret;
49015 ** Write an entry into the pointer map.
49017 ** This routine updates the pointer map entry for page number 'key'
49018 ** so that it maps to type 'eType' and parent page number 'pgno'.
49020 ** If *pRC is initially non-zero (non-SQLITE_OK) then this routine is
49021 ** a no-op. If an error occurs, the appropriate error code is written
49022 ** into *pRC.
49024 static void ptrmapPut(BtShared *pBt, Pgno key, u8 eType, Pgno parent, int *pRC){
49025 DbPage *pDbPage; /* The pointer map page */
49026 u8 *pPtrmap; /* The pointer map data */
49027 Pgno iPtrmap; /* The pointer map page number */
49028 int offset; /* Offset in pointer map page */
49029 int rc; /* Return code from subfunctions */
49031 if( *pRC ) return;
49033 assert( sqlite3_mutex_held(pBt->mutex) );
49034 /* The master-journal page number must never be used as a pointer map page */
49035 assert( 0==PTRMAP_ISPAGE(pBt, PENDING_BYTE_PAGE(pBt)) );
49037 assert( pBt->autoVacuum );
49038 if( key==0 ){
49039 *pRC = SQLITE_CORRUPT_BKPT;
49040 return;
49042 iPtrmap = PTRMAP_PAGENO(pBt, key);
49043 rc = sqlite3PagerGet(pBt->pPager, iPtrmap, &pDbPage);
49044 if( rc!=SQLITE_OK ){
49045 *pRC = rc;
49046 return;
49048 offset = PTRMAP_PTROFFSET(iPtrmap, key);
49049 if( offset<0 ){
49050 *pRC = SQLITE_CORRUPT_BKPT;
49051 goto ptrmap_exit;
49053 assert( offset <= (int)pBt->usableSize-5 );
49054 pPtrmap = (u8 *)sqlite3PagerGetData(pDbPage);
49056 if( eType!=pPtrmap[offset] || get4byte(&pPtrmap[offset+1])!=parent ){
49057 TRACE(("PTRMAP_UPDATE: %d->(%d,%d)\n", key, eType, parent));
49058 *pRC= rc = sqlite3PagerWrite(pDbPage);
49059 if( rc==SQLITE_OK ){
49060 pPtrmap[offset] = eType;
49061 put4byte(&pPtrmap[offset+1], parent);
49065 ptrmap_exit:
49066 sqlite3PagerUnref(pDbPage);
49070 ** Read an entry from the pointer map.
49072 ** This routine retrieves the pointer map entry for page 'key', writing
49073 ** the type and parent page number to *pEType and *pPgno respectively.
49074 ** An error code is returned if something goes wrong, otherwise SQLITE_OK.
49076 static int ptrmapGet(BtShared *pBt, Pgno key, u8 *pEType, Pgno *pPgno){
49077 DbPage *pDbPage; /* The pointer map page */
49078 int iPtrmap; /* Pointer map page index */
49079 u8 *pPtrmap; /* Pointer map page data */
49080 int offset; /* Offset of entry in pointer map */
49081 int rc;
49083 assert( sqlite3_mutex_held(pBt->mutex) );
49085 iPtrmap = PTRMAP_PAGENO(pBt, key);
49086 rc = sqlite3PagerGet(pBt->pPager, iPtrmap, &pDbPage);
49087 if( rc!=0 ){
49088 return rc;
49090 pPtrmap = (u8 *)sqlite3PagerGetData(pDbPage);
49092 offset = PTRMAP_PTROFFSET(iPtrmap, key);
49093 if( offset<0 ){
49094 sqlite3PagerUnref(pDbPage);
49095 return SQLITE_CORRUPT_BKPT;
49097 assert( offset <= (int)pBt->usableSize-5 );
49098 assert( pEType!=0 );
49099 *pEType = pPtrmap[offset];
49100 if( pPgno ) *pPgno = get4byte(&pPtrmap[offset+1]);
49102 sqlite3PagerUnref(pDbPage);
49103 if( *pEType<1 || *pEType>5 ) return SQLITE_CORRUPT_BKPT;
49104 return SQLITE_OK;
49107 #else /* if defined SQLITE_OMIT_AUTOVACUUM */
49108 #define ptrmapPut(w,x,y,z,rc)
49109 #define ptrmapGet(w,x,y,z) SQLITE_OK
49110 #define ptrmapPutOvflPtr(x, y, rc)
49111 #endif
49114 ** Given a btree page and a cell index (0 means the first cell on
49115 ** the page, 1 means the second cell, and so forth) return a pointer
49116 ** to the cell content.
49118 ** This routine works only for pages that do not contain overflow cells.
49120 #define findCell(P,I) \
49121 ((P)->aData + ((P)->maskPage & get2byte(&(P)->aData[(P)->cellOffset+2*(I)])))
49122 #define findCellv2(D,M,O,I) (D+(M&get2byte(D+(O+2*(I)))))
49126 ** This a more complex version of findCell() that works for
49127 ** pages that do contain overflow cells.
49129 static u8 *findOverflowCell(MemPage *pPage, int iCell){
49130 int i;
49131 assert( sqlite3_mutex_held(pPage->pBt->mutex) );
49132 for(i=pPage->nOverflow-1; i>=0; i--){
49133 int k;
49134 struct _OvflCell *pOvfl;
49135 pOvfl = &pPage->aOvfl[i];
49136 k = pOvfl->idx;
49137 if( k<=iCell ){
49138 if( k==iCell ){
49139 return pOvfl->pCell;
49141 iCell--;
49144 return findCell(pPage, iCell);
49148 ** Parse a cell content block and fill in the CellInfo structure. There
49149 ** are two versions of this function. btreeParseCell() takes a
49150 ** cell index as the second argument and btreeParseCellPtr()
49151 ** takes a pointer to the body of the cell as its second argument.
49153 ** Within this file, the parseCell() macro can be called instead of
49154 ** btreeParseCellPtr(). Using some compilers, this will be faster.
49156 static void btreeParseCellPtr(
49157 MemPage *pPage, /* Page containing the cell */
49158 u8 *pCell, /* Pointer to the cell text. */
49159 CellInfo *pInfo /* Fill in this structure */
49161 u16 n; /* Number bytes in cell content header */
49162 u32 nPayload; /* Number of bytes of cell payload */
49164 assert( sqlite3_mutex_held(pPage->pBt->mutex) );
49166 pInfo->pCell = pCell;
49167 assert( pPage->leaf==0 || pPage->leaf==1 );
49168 n = pPage->childPtrSize;
49169 assert( n==4-4*pPage->leaf );
49170 if( pPage->intKey ){
49171 if( pPage->hasData ){
49172 n += getVarint32(&pCell[n], nPayload);
49173 }else{
49174 nPayload = 0;
49176 n += getVarint(&pCell[n], (u64*)&pInfo->nKey);
49177 pInfo->nData = nPayload;
49178 }else{
49179 pInfo->nData = 0;
49180 n += getVarint32(&pCell[n], nPayload);
49181 pInfo->nKey = nPayload;
49183 pInfo->nPayload = nPayload;
49184 pInfo->nHeader = n;
49185 testcase( nPayload==pPage->maxLocal );
49186 testcase( nPayload==pPage->maxLocal+1 );
49187 if( likely(nPayload<=pPage->maxLocal) ){
49188 /* This is the (easy) common case where the entire payload fits
49189 ** on the local page. No overflow is required.
49191 if( (pInfo->nSize = (u16)(n+nPayload))<4 ) pInfo->nSize = 4;
49192 pInfo->nLocal = (u16)nPayload;
49193 pInfo->iOverflow = 0;
49194 }else{
49195 /* If the payload will not fit completely on the local page, we have
49196 ** to decide how much to store locally and how much to spill onto
49197 ** overflow pages. The strategy is to minimize the amount of unused
49198 ** space on overflow pages while keeping the amount of local storage
49199 ** in between minLocal and maxLocal.
49201 ** Warning: changing the way overflow payload is distributed in any
49202 ** way will result in an incompatible file format.
49204 int minLocal; /* Minimum amount of payload held locally */
49205 int maxLocal; /* Maximum amount of payload held locally */
49206 int surplus; /* Overflow payload available for local storage */
49208 minLocal = pPage->minLocal;
49209 maxLocal = pPage->maxLocal;
49210 surplus = minLocal + (nPayload - minLocal)%(pPage->pBt->usableSize - 4);
49211 testcase( surplus==maxLocal );
49212 testcase( surplus==maxLocal+1 );
49213 if( surplus <= maxLocal ){
49214 pInfo->nLocal = (u16)surplus;
49215 }else{
49216 pInfo->nLocal = (u16)minLocal;
49218 pInfo->iOverflow = (u16)(pInfo->nLocal + n);
49219 pInfo->nSize = pInfo->iOverflow + 4;
49222 #define parseCell(pPage, iCell, pInfo) \
49223 btreeParseCellPtr((pPage), findCell((pPage), (iCell)), (pInfo))
49224 static void btreeParseCell(
49225 MemPage *pPage, /* Page containing the cell */
49226 int iCell, /* The cell index. First cell is 0 */
49227 CellInfo *pInfo /* Fill in this structure */
49229 parseCell(pPage, iCell, pInfo);
49233 ** Compute the total number of bytes that a Cell needs in the cell
49234 ** data area of the btree-page. The return number includes the cell
49235 ** data header and the local payload, but not any overflow page or
49236 ** the space used by the cell pointer.
49238 static u16 cellSizePtr(MemPage *pPage, u8 *pCell){
49239 u8 *pIter = &pCell[pPage->childPtrSize];
49240 u32 nSize;
49242 #ifdef SQLITE_DEBUG
49243 /* The value returned by this function should always be the same as
49244 ** the (CellInfo.nSize) value found by doing a full parse of the
49245 ** cell. If SQLITE_DEBUG is defined, an assert() at the bottom of
49246 ** this function verifies that this invariant is not violated. */
49247 CellInfo debuginfo;
49248 btreeParseCellPtr(pPage, pCell, &debuginfo);
49249 #endif
49251 if( pPage->intKey ){
49252 u8 *pEnd;
49253 if( pPage->hasData ){
49254 pIter += getVarint32(pIter, nSize);
49255 }else{
49256 nSize = 0;
49259 /* pIter now points at the 64-bit integer key value, a variable length
49260 ** integer. The following block moves pIter to point at the first byte
49261 ** past the end of the key value. */
49262 pEnd = &pIter[9];
49263 while( (*pIter++)&0x80 && pIter<pEnd );
49264 }else{
49265 pIter += getVarint32(pIter, nSize);
49268 testcase( nSize==pPage->maxLocal );
49269 testcase( nSize==pPage->maxLocal+1 );
49270 if( nSize>pPage->maxLocal ){
49271 int minLocal = pPage->minLocal;
49272 nSize = minLocal + (nSize - minLocal) % (pPage->pBt->usableSize - 4);
49273 testcase( nSize==pPage->maxLocal );
49274 testcase( nSize==pPage->maxLocal+1 );
49275 if( nSize>pPage->maxLocal ){
49276 nSize = minLocal;
49278 nSize += 4;
49280 nSize += (u32)(pIter - pCell);
49282 /* The minimum size of any cell is 4 bytes. */
49283 if( nSize<4 ){
49284 nSize = 4;
49287 assert( nSize==debuginfo.nSize );
49288 return (u16)nSize;
49291 #ifdef SQLITE_DEBUG
49292 /* This variation on cellSizePtr() is used inside of assert() statements
49293 ** only. */
49294 static u16 cellSize(MemPage *pPage, int iCell){
49295 return cellSizePtr(pPage, findCell(pPage, iCell));
49297 #endif
49299 #ifndef SQLITE_OMIT_AUTOVACUUM
49301 ** If the cell pCell, part of page pPage contains a pointer
49302 ** to an overflow page, insert an entry into the pointer-map
49303 ** for the overflow page.
49305 static void ptrmapPutOvflPtr(MemPage *pPage, u8 *pCell, int *pRC){
49306 CellInfo info;
49307 if( *pRC ) return;
49308 assert( pCell!=0 );
49309 btreeParseCellPtr(pPage, pCell, &info);
49310 assert( (info.nData+(pPage->intKey?0:info.nKey))==info.nPayload );
49311 if( info.iOverflow ){
49312 Pgno ovfl = get4byte(&pCell[info.iOverflow]);
49313 ptrmapPut(pPage->pBt, ovfl, PTRMAP_OVERFLOW1, pPage->pgno, pRC);
49316 #endif
49320 ** Defragment the page given. All Cells are moved to the
49321 ** end of the page and all free space is collected into one
49322 ** big FreeBlk that occurs in between the header and cell
49323 ** pointer array and the cell content area.
49325 static int defragmentPage(MemPage *pPage){
49326 int i; /* Loop counter */
49327 int pc; /* Address of a i-th cell */
49328 int hdr; /* Offset to the page header */
49329 int size; /* Size of a cell */
49330 int usableSize; /* Number of usable bytes on a page */
49331 int cellOffset; /* Offset to the cell pointer array */
49332 int cbrk; /* Offset to the cell content area */
49333 int nCell; /* Number of cells on the page */
49334 unsigned char *data; /* The page data */
49335 unsigned char *temp; /* Temp area for cell content */
49336 int iCellFirst; /* First allowable cell index */
49337 int iCellLast; /* Last possible cell index */
49340 assert( sqlite3PagerIswriteable(pPage->pDbPage) );
49341 assert( pPage->pBt!=0 );
49342 assert( pPage->pBt->usableSize <= SQLITE_MAX_PAGE_SIZE );
49343 assert( pPage->nOverflow==0 );
49344 assert( sqlite3_mutex_held(pPage->pBt->mutex) );
49345 temp = sqlite3PagerTempSpace(pPage->pBt->pPager);
49346 data = pPage->aData;
49347 hdr = pPage->hdrOffset;
49348 cellOffset = pPage->cellOffset;
49349 nCell = pPage->nCell;
49350 assert( nCell==get2byte(&data[hdr+3]) );
49351 usableSize = pPage->pBt->usableSize;
49352 cbrk = get2byte(&data[hdr+5]);
49353 memcpy(&temp[cbrk], &data[cbrk], usableSize - cbrk);
49354 cbrk = usableSize;
49355 iCellFirst = cellOffset + 2*nCell;
49356 iCellLast = usableSize - 4;
49357 for(i=0; i<nCell; i++){
49358 u8 *pAddr; /* The i-th cell pointer */
49359 pAddr = &data[cellOffset + i*2];
49360 pc = get2byte(pAddr);
49361 testcase( pc==iCellFirst );
49362 testcase( pc==iCellLast );
49363 #if !defined(SQLITE_ENABLE_OVERSIZE_CELL_CHECK)
49364 /* These conditions have already been verified in btreeInitPage()
49365 ** if SQLITE_ENABLE_OVERSIZE_CELL_CHECK is defined
49367 if( pc<iCellFirst || pc>iCellLast ){
49368 return SQLITE_CORRUPT_BKPT;
49370 #endif
49371 assert( pc>=iCellFirst && pc<=iCellLast );
49372 size = cellSizePtr(pPage, &temp[pc]);
49373 cbrk -= size;
49374 #if defined(SQLITE_ENABLE_OVERSIZE_CELL_CHECK)
49375 if( cbrk<iCellFirst ){
49376 return SQLITE_CORRUPT_BKPT;
49378 #else
49379 if( cbrk<iCellFirst || pc+size>usableSize ){
49380 return SQLITE_CORRUPT_BKPT;
49382 #endif
49383 assert( cbrk+size<=usableSize && cbrk>=iCellFirst );
49384 testcase( cbrk+size==usableSize );
49385 testcase( pc+size==usableSize );
49386 memcpy(&data[cbrk], &temp[pc], size);
49387 put2byte(pAddr, cbrk);
49389 assert( cbrk>=iCellFirst );
49390 put2byte(&data[hdr+5], cbrk);
49391 data[hdr+1] = 0;
49392 data[hdr+2] = 0;
49393 data[hdr+7] = 0;
49394 memset(&data[iCellFirst], 0, cbrk-iCellFirst);
49395 assert( sqlite3PagerIswriteable(pPage->pDbPage) );
49396 if( cbrk-iCellFirst!=pPage->nFree ){
49397 return SQLITE_CORRUPT_BKPT;
49399 return SQLITE_OK;
49403 ** Allocate nByte bytes of space from within the B-Tree page passed
49404 ** as the first argument. Write into *pIdx the index into pPage->aData[]
49405 ** of the first byte of allocated space. Return either SQLITE_OK or
49406 ** an error code (usually SQLITE_CORRUPT).
49408 ** The caller guarantees that there is sufficient space to make the
49409 ** allocation. This routine might need to defragment in order to bring
49410 ** all the space together, however. This routine will avoid using
49411 ** the first two bytes past the cell pointer area since presumably this
49412 ** allocation is being made in order to insert a new cell, so we will
49413 ** also end up needing a new cell pointer.
49415 static int allocateSpace(MemPage *pPage, int nByte, int *pIdx){
49416 const int hdr = pPage->hdrOffset; /* Local cache of pPage->hdrOffset */
49417 u8 * const data = pPage->aData; /* Local cache of pPage->aData */
49418 int nFrag; /* Number of fragmented bytes on pPage */
49419 int top; /* First byte of cell content area */
49420 int gap; /* First byte of gap between cell pointers and cell content */
49421 int rc; /* Integer return code */
49422 int usableSize; /* Usable size of the page */
49424 assert( sqlite3PagerIswriteable(pPage->pDbPage) );
49425 assert( pPage->pBt );
49426 assert( sqlite3_mutex_held(pPage->pBt->mutex) );
49427 assert( nByte>=0 ); /* Minimum cell size is 4 */
49428 assert( pPage->nFree>=nByte );
49429 assert( pPage->nOverflow==0 );
49430 usableSize = pPage->pBt->usableSize;
49431 assert( nByte < usableSize-8 );
49433 nFrag = data[hdr+7];
49434 assert( pPage->cellOffset == hdr + 12 - 4*pPage->leaf );
49435 gap = pPage->cellOffset + 2*pPage->nCell;
49436 top = get2byteNotZero(&data[hdr+5]);
49437 if( gap>top ) return SQLITE_CORRUPT_BKPT;
49438 testcase( gap+2==top );
49439 testcase( gap+1==top );
49440 testcase( gap==top );
49442 if( nFrag>=60 ){
49443 /* Always defragment highly fragmented pages */
49444 rc = defragmentPage(pPage);
49445 if( rc ) return rc;
49446 top = get2byteNotZero(&data[hdr+5]);
49447 }else if( gap+2<=top ){
49448 /* Search the freelist looking for a free slot big enough to satisfy
49449 ** the request. The allocation is made from the first free slot in
49450 ** the list that is large enough to accomadate it.
49452 int pc, addr;
49453 for(addr=hdr+1; (pc = get2byte(&data[addr]))>0; addr=pc){
49454 int size; /* Size of the free slot */
49455 if( pc>usableSize-4 || pc<addr+4 ){
49456 return SQLITE_CORRUPT_BKPT;
49458 size = get2byte(&data[pc+2]);
49459 if( size>=nByte ){
49460 int x = size - nByte;
49461 testcase( x==4 );
49462 testcase( x==3 );
49463 if( x<4 ){
49464 /* Remove the slot from the free-list. Update the number of
49465 ** fragmented bytes within the page. */
49466 memcpy(&data[addr], &data[pc], 2);
49467 data[hdr+7] = (u8)(nFrag + x);
49468 }else if( size+pc > usableSize ){
49469 return SQLITE_CORRUPT_BKPT;
49470 }else{
49471 /* The slot remains on the free-list. Reduce its size to account
49472 ** for the portion used by the new allocation. */
49473 put2byte(&data[pc+2], x);
49475 *pIdx = pc + x;
49476 return SQLITE_OK;
49481 /* Check to make sure there is enough space in the gap to satisfy
49482 ** the allocation. If not, defragment.
49484 testcase( gap+2+nByte==top );
49485 if( gap+2+nByte>top ){
49486 rc = defragmentPage(pPage);
49487 if( rc ) return rc;
49488 top = get2byteNotZero(&data[hdr+5]);
49489 assert( gap+nByte<=top );
49493 /* Allocate memory from the gap in between the cell pointer array
49494 ** and the cell content area. The btreeInitPage() call has already
49495 ** validated the freelist. Given that the freelist is valid, there
49496 ** is no way that the allocation can extend off the end of the page.
49497 ** The assert() below verifies the previous sentence.
49499 top -= nByte;
49500 put2byte(&data[hdr+5], top);
49501 assert( top+nByte <= (int)pPage->pBt->usableSize );
49502 *pIdx = top;
49503 return SQLITE_OK;
49507 ** Return a section of the pPage->aData to the freelist.
49508 ** The first byte of the new free block is pPage->aDisk[start]
49509 ** and the size of the block is "size" bytes.
49511 ** Most of the effort here is involved in coalesing adjacent
49512 ** free blocks into a single big free block.
49514 static int freeSpace(MemPage *pPage, int start, int size){
49515 int addr, pbegin, hdr;
49516 int iLast; /* Largest possible freeblock offset */
49517 unsigned char *data = pPage->aData;
49519 assert( pPage->pBt!=0 );
49520 assert( sqlite3PagerIswriteable(pPage->pDbPage) );
49521 assert( start>=pPage->hdrOffset+6+pPage->childPtrSize );
49522 assert( (start + size) <= (int)pPage->pBt->usableSize );
49523 assert( sqlite3_mutex_held(pPage->pBt->mutex) );
49524 assert( size>=0 ); /* Minimum cell size is 4 */
49526 if( pPage->pBt->secureDelete ){
49527 /* Overwrite deleted information with zeros when the secure_delete
49528 ** option is enabled */
49529 memset(&data[start], 0, size);
49532 /* Add the space back into the linked list of freeblocks. Note that
49533 ** even though the freeblock list was checked by btreeInitPage(),
49534 ** btreeInitPage() did not detect overlapping cells or
49535 ** freeblocks that overlapped cells. Nor does it detect when the
49536 ** cell content area exceeds the value in the page header. If these
49537 ** situations arise, then subsequent insert operations might corrupt
49538 ** the freelist. So we do need to check for corruption while scanning
49539 ** the freelist.
49541 hdr = pPage->hdrOffset;
49542 addr = hdr + 1;
49543 iLast = pPage->pBt->usableSize - 4;
49544 assert( start<=iLast );
49545 while( (pbegin = get2byte(&data[addr]))<start && pbegin>0 ){
49546 if( pbegin<addr+4 ){
49547 return SQLITE_CORRUPT_BKPT;
49549 addr = pbegin;
49551 if( pbegin>iLast ){
49552 return SQLITE_CORRUPT_BKPT;
49554 assert( pbegin>addr || pbegin==0 );
49555 put2byte(&data[addr], start);
49556 put2byte(&data[start], pbegin);
49557 put2byte(&data[start+2], size);
49558 pPage->nFree = pPage->nFree + (u16)size;
49560 /* Coalesce adjacent free blocks */
49561 addr = hdr + 1;
49562 while( (pbegin = get2byte(&data[addr]))>0 ){
49563 int pnext, psize, x;
49564 assert( pbegin>addr );
49565 assert( pbegin <= (int)pPage->pBt->usableSize-4 );
49566 pnext = get2byte(&data[pbegin]);
49567 psize = get2byte(&data[pbegin+2]);
49568 if( pbegin + psize + 3 >= pnext && pnext>0 ){
49569 int frag = pnext - (pbegin+psize);
49570 if( (frag<0) || (frag>(int)data[hdr+7]) ){
49571 return SQLITE_CORRUPT_BKPT;
49573 data[hdr+7] -= (u8)frag;
49574 x = get2byte(&data[pnext]);
49575 put2byte(&data[pbegin], x);
49576 x = pnext + get2byte(&data[pnext+2]) - pbegin;
49577 put2byte(&data[pbegin+2], x);
49578 }else{
49579 addr = pbegin;
49583 /* If the cell content area begins with a freeblock, remove it. */
49584 if( data[hdr+1]==data[hdr+5] && data[hdr+2]==data[hdr+6] ){
49585 int top;
49586 pbegin = get2byte(&data[hdr+1]);
49587 memcpy(&data[hdr+1], &data[pbegin], 2);
49588 top = get2byte(&data[hdr+5]) + get2byte(&data[pbegin+2]);
49589 put2byte(&data[hdr+5], top);
49591 assert( sqlite3PagerIswriteable(pPage->pDbPage) );
49592 return SQLITE_OK;
49596 ** Decode the flags byte (the first byte of the header) for a page
49597 ** and initialize fields of the MemPage structure accordingly.
49599 ** Only the following combinations are supported. Anything different
49600 ** indicates a corrupt database files:
49602 ** PTF_ZERODATA
49603 ** PTF_ZERODATA | PTF_LEAF
49604 ** PTF_LEAFDATA | PTF_INTKEY
49605 ** PTF_LEAFDATA | PTF_INTKEY | PTF_LEAF
49607 static int decodeFlags(MemPage *pPage, int flagByte){
49608 BtShared *pBt; /* A copy of pPage->pBt */
49610 assert( pPage->hdrOffset==(pPage->pgno==1 ? 100 : 0) );
49611 assert( sqlite3_mutex_held(pPage->pBt->mutex) );
49612 pPage->leaf = (u8)(flagByte>>3); assert( PTF_LEAF == 1<<3 );
49613 flagByte &= ~PTF_LEAF;
49614 pPage->childPtrSize = 4-4*pPage->leaf;
49615 pBt = pPage->pBt;
49616 if( flagByte==(PTF_LEAFDATA | PTF_INTKEY) ){
49617 pPage->intKey = 1;
49618 pPage->hasData = pPage->leaf;
49619 pPage->maxLocal = pBt->maxLeaf;
49620 pPage->minLocal = pBt->minLeaf;
49621 }else if( flagByte==PTF_ZERODATA ){
49622 pPage->intKey = 0;
49623 pPage->hasData = 0;
49624 pPage->maxLocal = pBt->maxLocal;
49625 pPage->minLocal = pBt->minLocal;
49626 }else{
49627 return SQLITE_CORRUPT_BKPT;
49629 return SQLITE_OK;
49633 ** Initialize the auxiliary information for a disk block.
49635 ** Return SQLITE_OK on success. If we see that the page does
49636 ** not contain a well-formed database page, then return
49637 ** SQLITE_CORRUPT. Note that a return of SQLITE_OK does not
49638 ** guarantee that the page is well-formed. It only shows that
49639 ** we failed to detect any corruption.
49641 static int btreeInitPage(MemPage *pPage){
49643 assert( pPage->pBt!=0 );
49644 assert( sqlite3_mutex_held(pPage->pBt->mutex) );
49645 assert( pPage->pgno==sqlite3PagerPagenumber(pPage->pDbPage) );
49646 assert( pPage == sqlite3PagerGetExtra(pPage->pDbPage) );
49647 assert( pPage->aData == sqlite3PagerGetData(pPage->pDbPage) );
49649 if( !pPage->isInit ){
49650 u16 pc; /* Address of a freeblock within pPage->aData[] */
49651 u8 hdr; /* Offset to beginning of page header */
49652 u8 *data; /* Equal to pPage->aData */
49653 BtShared *pBt; /* The main btree structure */
49654 int usableSize; /* Amount of usable space on each page */
49655 u16 cellOffset; /* Offset from start of page to first cell pointer */
49656 int nFree; /* Number of unused bytes on the page */
49657 int top; /* First byte of the cell content area */
49658 int iCellFirst; /* First allowable cell or freeblock offset */
49659 int iCellLast; /* Last possible cell or freeblock offset */
49661 pBt = pPage->pBt;
49663 hdr = pPage->hdrOffset;
49664 data = pPage->aData;
49665 if( decodeFlags(pPage, data[hdr]) ) return SQLITE_CORRUPT_BKPT;
49666 assert( pBt->pageSize>=512 && pBt->pageSize<=65536 );
49667 pPage->maskPage = (u16)(pBt->pageSize - 1);
49668 pPage->nOverflow = 0;
49669 usableSize = pBt->usableSize;
49670 pPage->cellOffset = cellOffset = hdr + 12 - 4*pPage->leaf;
49671 top = get2byteNotZero(&data[hdr+5]);
49672 pPage->nCell = get2byte(&data[hdr+3]);
49673 if( pPage->nCell>MX_CELL(pBt) ){
49674 /* To many cells for a single page. The page must be corrupt */
49675 return SQLITE_CORRUPT_BKPT;
49677 testcase( pPage->nCell==MX_CELL(pBt) );
49679 /* A malformed database page might cause us to read past the end
49680 ** of page when parsing a cell.
49682 ** The following block of code checks early to see if a cell extends
49683 ** past the end of a page boundary and causes SQLITE_CORRUPT to be
49684 ** returned if it does.
49686 iCellFirst = cellOffset + 2*pPage->nCell;
49687 iCellLast = usableSize - 4;
49688 #if defined(SQLITE_ENABLE_OVERSIZE_CELL_CHECK)
49690 int i; /* Index into the cell pointer array */
49691 int sz; /* Size of a cell */
49693 if( !pPage->leaf ) iCellLast--;
49694 for(i=0; i<pPage->nCell; i++){
49695 pc = get2byte(&data[cellOffset+i*2]);
49696 testcase( pc==iCellFirst );
49697 testcase( pc==iCellLast );
49698 if( pc<iCellFirst || pc>iCellLast ){
49699 return SQLITE_CORRUPT_BKPT;
49701 sz = cellSizePtr(pPage, &data[pc]);
49702 testcase( pc+sz==usableSize );
49703 if( pc+sz>usableSize ){
49704 return SQLITE_CORRUPT_BKPT;
49707 if( !pPage->leaf ) iCellLast++;
49709 #endif
49711 /* Compute the total free space on the page */
49712 pc = get2byte(&data[hdr+1]);
49713 nFree = data[hdr+7] + top;
49714 while( pc>0 ){
49715 u16 next, size;
49716 if( pc<iCellFirst || pc>iCellLast ){
49717 /* Start of free block is off the page */
49718 return SQLITE_CORRUPT_BKPT;
49720 next = get2byte(&data[pc]);
49721 size = get2byte(&data[pc+2]);
49722 if( (next>0 && next<=pc+size+3) || pc+size>usableSize ){
49723 /* Free blocks must be in ascending order. And the last byte of
49724 ** the free-block must lie on the database page. */
49725 return SQLITE_CORRUPT_BKPT;
49727 nFree = nFree + size;
49728 pc = next;
49731 /* At this point, nFree contains the sum of the offset to the start
49732 ** of the cell-content area plus the number of free bytes within
49733 ** the cell-content area. If this is greater than the usable-size
49734 ** of the page, then the page must be corrupted. This check also
49735 ** serves to verify that the offset to the start of the cell-content
49736 ** area, according to the page header, lies within the page.
49738 if( nFree>usableSize ){
49739 return SQLITE_CORRUPT_BKPT;
49741 pPage->nFree = (u16)(nFree - iCellFirst);
49742 pPage->isInit = 1;
49744 return SQLITE_OK;
49748 ** Set up a raw page so that it looks like a database page holding
49749 ** no entries.
49751 static void zeroPage(MemPage *pPage, int flags){
49752 unsigned char *data = pPage->aData;
49753 BtShared *pBt = pPage->pBt;
49754 u8 hdr = pPage->hdrOffset;
49755 u16 first;
49757 assert( sqlite3PagerPagenumber(pPage->pDbPage)==pPage->pgno );
49758 assert( sqlite3PagerGetExtra(pPage->pDbPage) == (void*)pPage );
49759 assert( sqlite3PagerGetData(pPage->pDbPage) == data );
49760 assert( sqlite3PagerIswriteable(pPage->pDbPage) );
49761 assert( sqlite3_mutex_held(pBt->mutex) );
49762 if( pBt->secureDelete ){
49763 memset(&data[hdr], 0, pBt->usableSize - hdr);
49765 data[hdr] = (char)flags;
49766 first = hdr + 8 + 4*((flags&PTF_LEAF)==0 ?1:0);
49767 memset(&data[hdr+1], 0, 4);
49768 data[hdr+7] = 0;
49769 put2byte(&data[hdr+5], pBt->usableSize);
49770 pPage->nFree = (u16)(pBt->usableSize - first);
49771 decodeFlags(pPage, flags);
49772 pPage->hdrOffset = hdr;
49773 pPage->cellOffset = first;
49774 pPage->nOverflow = 0;
49775 assert( pBt->pageSize>=512 && pBt->pageSize<=65536 );
49776 pPage->maskPage = (u16)(pBt->pageSize - 1);
49777 pPage->nCell = 0;
49778 pPage->isInit = 1;
49783 ** Convert a DbPage obtained from the pager into a MemPage used by
49784 ** the btree layer.
49786 static MemPage *btreePageFromDbPage(DbPage *pDbPage, Pgno pgno, BtShared *pBt){
49787 MemPage *pPage = (MemPage*)sqlite3PagerGetExtra(pDbPage);
49788 pPage->aData = sqlite3PagerGetData(pDbPage);
49789 pPage->pDbPage = pDbPage;
49790 pPage->pBt = pBt;
49791 pPage->pgno = pgno;
49792 pPage->hdrOffset = pPage->pgno==1 ? 100 : 0;
49793 return pPage;
49797 ** Get a page from the pager. Initialize the MemPage.pBt and
49798 ** MemPage.aData elements if needed.
49800 ** If the noContent flag is set, it means that we do not care about
49801 ** the content of the page at this time. So do not go to the disk
49802 ** to fetch the content. Just fill in the content with zeros for now.
49803 ** If in the future we call sqlite3PagerWrite() on this page, that
49804 ** means we have started to be concerned about content and the disk
49805 ** read should occur at that point.
49807 static int btreeGetPage(
49808 BtShared *pBt, /* The btree */
49809 Pgno pgno, /* Number of the page to fetch */
49810 MemPage **ppPage, /* Return the page in this parameter */
49811 int noContent /* Do not load page content if true */
49813 int rc;
49814 DbPage *pDbPage;
49816 assert( sqlite3_mutex_held(pBt->mutex) );
49817 rc = sqlite3PagerAcquire(pBt->pPager, pgno, (DbPage**)&pDbPage, noContent);
49818 if( rc ) return rc;
49819 *ppPage = btreePageFromDbPage(pDbPage, pgno, pBt);
49820 return SQLITE_OK;
49824 ** Retrieve a page from the pager cache. If the requested page is not
49825 ** already in the pager cache return NULL. Initialize the MemPage.pBt and
49826 ** MemPage.aData elements if needed.
49828 static MemPage *btreePageLookup(BtShared *pBt, Pgno pgno){
49829 DbPage *pDbPage;
49830 assert( sqlite3_mutex_held(pBt->mutex) );
49831 pDbPage = sqlite3PagerLookup(pBt->pPager, pgno);
49832 if( pDbPage ){
49833 return btreePageFromDbPage(pDbPage, pgno, pBt);
49835 return 0;
49839 ** Return the size of the database file in pages. If there is any kind of
49840 ** error, return ((unsigned int)-1).
49842 static Pgno btreePagecount(BtShared *pBt){
49843 return pBt->nPage;
49845 SQLITE_PRIVATE u32 sqlite3BtreeLastPage(Btree *p){
49846 assert( sqlite3BtreeHoldsMutex(p) );
49847 assert( ((p->pBt->nPage)&0x8000000)==0 );
49848 return (int)btreePagecount(p->pBt);
49852 ** Get a page from the pager and initialize it. This routine is just a
49853 ** convenience wrapper around separate calls to btreeGetPage() and
49854 ** btreeInitPage().
49856 ** If an error occurs, then the value *ppPage is set to is undefined. It
49857 ** may remain unchanged, or it may be set to an invalid value.
49859 static int getAndInitPage(
49860 BtShared *pBt, /* The database file */
49861 Pgno pgno, /* Number of the page to get */
49862 MemPage **ppPage /* Write the page pointer here */
49864 int rc;
49865 assert( sqlite3_mutex_held(pBt->mutex) );
49867 if( pgno>btreePagecount(pBt) ){
49868 rc = SQLITE_CORRUPT_BKPT;
49869 }else{
49870 rc = btreeGetPage(pBt, pgno, ppPage, 0);
49871 if( rc==SQLITE_OK ){
49872 rc = btreeInitPage(*ppPage);
49873 if( rc!=SQLITE_OK ){
49874 releasePage(*ppPage);
49879 testcase( pgno==0 );
49880 assert( pgno!=0 || rc==SQLITE_CORRUPT );
49881 return rc;
49885 ** Release a MemPage. This should be called once for each prior
49886 ** call to btreeGetPage.
49888 static void releasePage(MemPage *pPage){
49889 if( pPage ){
49890 assert( pPage->aData );
49891 assert( pPage->pBt );
49892 assert( sqlite3PagerGetExtra(pPage->pDbPage) == (void*)pPage );
49893 assert( sqlite3PagerGetData(pPage->pDbPage)==pPage->aData );
49894 assert( sqlite3_mutex_held(pPage->pBt->mutex) );
49895 sqlite3PagerUnref(pPage->pDbPage);
49900 ** During a rollback, when the pager reloads information into the cache
49901 ** so that the cache is restored to its original state at the start of
49902 ** the transaction, for each page restored this routine is called.
49904 ** This routine needs to reset the extra data section at the end of the
49905 ** page to agree with the restored data.
49907 static void pageReinit(DbPage *pData){
49908 MemPage *pPage;
49909 pPage = (MemPage *)sqlite3PagerGetExtra(pData);
49910 assert( sqlite3PagerPageRefcount(pData)>0 );
49911 if( pPage->isInit ){
49912 assert( sqlite3_mutex_held(pPage->pBt->mutex) );
49913 pPage->isInit = 0;
49914 if( sqlite3PagerPageRefcount(pData)>1 ){
49915 /* pPage might not be a btree page; it might be an overflow page
49916 ** or ptrmap page or a free page. In those cases, the following
49917 ** call to btreeInitPage() will likely return SQLITE_CORRUPT.
49918 ** But no harm is done by this. And it is very important that
49919 ** btreeInitPage() be called on every btree page so we make
49920 ** the call for every page that comes in for re-initing. */
49921 btreeInitPage(pPage);
49927 ** Invoke the busy handler for a btree.
49929 static int btreeInvokeBusyHandler(void *pArg){
49930 BtShared *pBt = (BtShared*)pArg;
49931 assert( pBt->db );
49932 assert( sqlite3_mutex_held(pBt->db->mutex) );
49933 return sqlite3InvokeBusyHandler(&pBt->db->busyHandler);
49937 ** Open a database file.
49939 ** zFilename is the name of the database file. If zFilename is NULL
49940 ** then an ephemeral database is created. The ephemeral database might
49941 ** be exclusively in memory, or it might use a disk-based memory cache.
49942 ** Either way, the ephemeral database will be automatically deleted
49943 ** when sqlite3BtreeClose() is called.
49945 ** If zFilename is ":memory:" then an in-memory database is created
49946 ** that is automatically destroyed when it is closed.
49948 ** The "flags" parameter is a bitmask that might contain bits
49949 ** BTREE_OMIT_JOURNAL and/or BTREE_NO_READLOCK. The BTREE_NO_READLOCK
49950 ** bit is also set if the SQLITE_NoReadlock flags is set in db->flags.
49951 ** These flags are passed through into sqlite3PagerOpen() and must
49952 ** be the same values as PAGER_OMIT_JOURNAL and PAGER_NO_READLOCK.
49954 ** If the database is already opened in the same database connection
49955 ** and we are in shared cache mode, then the open will fail with an
49956 ** SQLITE_CONSTRAINT error. We cannot allow two or more BtShared
49957 ** objects in the same database connection since doing so will lead
49958 ** to problems with locking.
49960 SQLITE_PRIVATE int sqlite3BtreeOpen(
49961 sqlite3_vfs *pVfs, /* VFS to use for this b-tree */
49962 const char *zFilename, /* Name of the file containing the BTree database */
49963 sqlite3 *db, /* Associated database handle */
49964 Btree **ppBtree, /* Pointer to new Btree object written here */
49965 int flags, /* Options */
49966 int vfsFlags /* Flags passed through to sqlite3_vfs.xOpen() */
49968 BtShared *pBt = 0; /* Shared part of btree structure */
49969 Btree *p; /* Handle to return */
49970 sqlite3_mutex *mutexOpen = 0; /* Prevents a race condition. Ticket #3537 */
49971 int rc = SQLITE_OK; /* Result code from this function */
49972 u8 nReserve; /* Byte of unused space on each page */
49973 unsigned char zDbHeader[100]; /* Database header content */
49975 /* True if opening an ephemeral, temporary database */
49976 const int isTempDb = zFilename==0 || zFilename[0]==0;
49978 /* Set the variable isMemdb to true for an in-memory database, or
49979 ** false for a file-based database.
49981 #ifdef SQLITE_OMIT_MEMORYDB
49982 const int isMemdb = 0;
49983 #else
49984 const int isMemdb = (zFilename && strcmp(zFilename, ":memory:")==0)
49985 || (isTempDb && sqlite3TempInMemory(db));
49986 #endif
49988 assert( db!=0 );
49989 assert( pVfs!=0 );
49990 assert( sqlite3_mutex_held(db->mutex) );
49991 assert( (flags&0xff)==flags ); /* flags fit in 8 bits */
49993 /* Only a BTREE_SINGLE database can be BTREE_UNORDERED */
49994 assert( (flags & BTREE_UNORDERED)==0 || (flags & BTREE_SINGLE)!=0 );
49996 /* A BTREE_SINGLE database is always a temporary and/or ephemeral */
49997 assert( (flags & BTREE_SINGLE)==0 || isTempDb );
49999 if( db->flags & SQLITE_NoReadlock ){
50000 flags |= BTREE_NO_READLOCK;
50002 if( isMemdb ){
50003 flags |= BTREE_MEMORY;
50005 if( (vfsFlags & SQLITE_OPEN_MAIN_DB)!=0 && (isMemdb || isTempDb) ){
50006 vfsFlags = (vfsFlags & ~SQLITE_OPEN_MAIN_DB) | SQLITE_OPEN_TEMP_DB;
50008 p = sqlite3MallocZero(sizeof(Btree));
50009 if( !p ){
50010 return SQLITE_NOMEM;
50012 p->inTrans = TRANS_NONE;
50013 p->db = db;
50014 #ifndef SQLITE_OMIT_SHARED_CACHE
50015 p->lock.pBtree = p;
50016 p->lock.iTable = 1;
50017 #endif
50019 #if !defined(SQLITE_OMIT_SHARED_CACHE) && !defined(SQLITE_OMIT_DISKIO)
50021 ** If this Btree is a candidate for shared cache, try to find an
50022 ** existing BtShared object that we can share with
50024 if( isMemdb==0 && isTempDb==0 ){
50025 if( vfsFlags & SQLITE_OPEN_SHAREDCACHE ){
50026 int nFullPathname = pVfs->mxPathname+1;
50027 char *zFullPathname = sqlite3Malloc(nFullPathname);
50028 sqlite3_mutex *mutexShared;
50029 p->sharable = 1;
50030 if( !zFullPathname ){
50031 sqlite3_free(p);
50032 return SQLITE_NOMEM;
50034 sqlite3OsFullPathname(pVfs, zFilename, nFullPathname, zFullPathname);
50035 mutexOpen = sqlite3MutexAlloc(SQLITE_MUTEX_STATIC_OPEN);
50036 sqlite3_mutex_enter(mutexOpen);
50037 mutexShared = sqlite3MutexAlloc(SQLITE_MUTEX_STATIC_MASTER);
50038 sqlite3_mutex_enter(mutexShared);
50039 for(pBt=GLOBAL(BtShared*,sqlite3SharedCacheList); pBt; pBt=pBt->pNext){
50040 assert( pBt->nRef>0 );
50041 if( 0==strcmp(zFullPathname, sqlite3PagerFilename(pBt->pPager))
50042 && sqlite3PagerVfs(pBt->pPager)==pVfs ){
50043 int iDb;
50044 for(iDb=db->nDb-1; iDb>=0; iDb--){
50045 Btree *pExisting = db->aDb[iDb].pBt;
50046 if( pExisting && pExisting->pBt==pBt ){
50047 sqlite3_mutex_leave(mutexShared);
50048 sqlite3_mutex_leave(mutexOpen);
50049 sqlite3_free(zFullPathname);
50050 sqlite3_free(p);
50051 return SQLITE_CONSTRAINT;
50054 p->pBt = pBt;
50055 pBt->nRef++;
50056 break;
50059 sqlite3_mutex_leave(mutexShared);
50060 sqlite3_free(zFullPathname);
50062 #ifdef SQLITE_DEBUG
50063 else{
50064 /* In debug mode, we mark all persistent databases as sharable
50065 ** even when they are not. This exercises the locking code and
50066 ** gives more opportunity for asserts(sqlite3_mutex_held())
50067 ** statements to find locking problems.
50069 p->sharable = 1;
50071 #endif
50073 #endif
50074 if( pBt==0 ){
50076 ** The following asserts make sure that structures used by the btree are
50077 ** the right size. This is to guard against size changes that result
50078 ** when compiling on a different architecture.
50080 assert( sizeof(i64)==8 || sizeof(i64)==4 );
50081 assert( sizeof(u64)==8 || sizeof(u64)==4 );
50082 assert( sizeof(u32)==4 );
50083 assert( sizeof(u16)==2 );
50084 assert( sizeof(Pgno)==4 );
50086 pBt = sqlite3MallocZero( sizeof(*pBt) );
50087 if( pBt==0 ){
50088 rc = SQLITE_NOMEM;
50089 goto btree_open_out;
50091 rc = sqlite3PagerOpen(pVfs, &pBt->pPager, zFilename,
50092 EXTRA_SIZE, flags, vfsFlags, pageReinit);
50093 if( rc==SQLITE_OK ){
50094 rc = sqlite3PagerReadFileheader(pBt->pPager,sizeof(zDbHeader),zDbHeader);
50096 if( rc!=SQLITE_OK ){
50097 goto btree_open_out;
50099 pBt->openFlags = (u8)flags;
50100 pBt->db = db;
50101 sqlite3PagerSetBusyhandler(pBt->pPager, btreeInvokeBusyHandler, pBt);
50102 p->pBt = pBt;
50104 pBt->pCursor = 0;
50105 pBt->pPage1 = 0;
50106 pBt->readOnly = sqlite3PagerIsreadonly(pBt->pPager);
50107 #ifdef SQLITE_SECURE_DELETE
50108 pBt->secureDelete = 1;
50109 #endif
50110 pBt->pageSize = (zDbHeader[16]<<8) | (zDbHeader[17]<<16);
50111 if( pBt->pageSize<512 || pBt->pageSize>SQLITE_MAX_PAGE_SIZE
50112 || ((pBt->pageSize-1)&pBt->pageSize)!=0 ){
50113 pBt->pageSize = 0;
50114 #ifndef SQLITE_OMIT_AUTOVACUUM
50115 /* If the magic name ":memory:" will create an in-memory database, then
50116 ** leave the autoVacuum mode at 0 (do not auto-vacuum), even if
50117 ** SQLITE_DEFAULT_AUTOVACUUM is true. On the other hand, if
50118 ** SQLITE_OMIT_MEMORYDB has been defined, then ":memory:" is just a
50119 ** regular file-name. In this case the auto-vacuum applies as per normal.
50121 if( zFilename && !isMemdb ){
50122 pBt->autoVacuum = (SQLITE_DEFAULT_AUTOVACUUM ? 1 : 0);
50123 pBt->incrVacuum = (SQLITE_DEFAULT_AUTOVACUUM==2 ? 1 : 0);
50125 #endif
50126 nReserve = 0;
50127 }else{
50128 nReserve = zDbHeader[20];
50129 pBt->pageSizeFixed = 1;
50130 #ifndef SQLITE_OMIT_AUTOVACUUM
50131 pBt->autoVacuum = (get4byte(&zDbHeader[36 + 4*4])?1:0);
50132 pBt->incrVacuum = (get4byte(&zDbHeader[36 + 7*4])?1:0);
50133 #endif
50135 rc = sqlite3PagerSetPagesize(pBt->pPager, &pBt->pageSize, nReserve);
50136 if( rc ) goto btree_open_out;
50137 pBt->usableSize = pBt->pageSize - nReserve;
50138 assert( (pBt->pageSize & 7)==0 ); /* 8-byte alignment of pageSize */
50140 #if !defined(SQLITE_OMIT_SHARED_CACHE) && !defined(SQLITE_OMIT_DISKIO)
50141 /* Add the new BtShared object to the linked list sharable BtShareds.
50143 if( p->sharable ){
50144 sqlite3_mutex *mutexShared;
50145 pBt->nRef = 1;
50146 mutexShared = sqlite3MutexAlloc(SQLITE_MUTEX_STATIC_MASTER);
50147 if( SQLITE_THREADSAFE && sqlite3GlobalConfig.bCoreMutex ){
50148 pBt->mutex = sqlite3MutexAlloc(SQLITE_MUTEX_FAST);
50149 if( pBt->mutex==0 ){
50150 rc = SQLITE_NOMEM;
50151 db->mallocFailed = 0;
50152 goto btree_open_out;
50155 sqlite3_mutex_enter(mutexShared);
50156 pBt->pNext = GLOBAL(BtShared*,sqlite3SharedCacheList);
50157 GLOBAL(BtShared*,sqlite3SharedCacheList) = pBt;
50158 sqlite3_mutex_leave(mutexShared);
50160 #endif
50163 #if !defined(SQLITE_OMIT_SHARED_CACHE) && !defined(SQLITE_OMIT_DISKIO)
50164 /* If the new Btree uses a sharable pBtShared, then link the new
50165 ** Btree into the list of all sharable Btrees for the same connection.
50166 ** The list is kept in ascending order by pBt address.
50168 if( p->sharable ){
50169 int i;
50170 Btree *pSib;
50171 for(i=0; i<db->nDb; i++){
50172 if( (pSib = db->aDb[i].pBt)!=0 && pSib->sharable ){
50173 while( pSib->pPrev ){ pSib = pSib->pPrev; }
50174 if( p->pBt<pSib->pBt ){
50175 p->pNext = pSib;
50176 p->pPrev = 0;
50177 pSib->pPrev = p;
50178 }else{
50179 while( pSib->pNext && pSib->pNext->pBt<p->pBt ){
50180 pSib = pSib->pNext;
50182 p->pNext = pSib->pNext;
50183 p->pPrev = pSib;
50184 if( p->pNext ){
50185 p->pNext->pPrev = p;
50187 pSib->pNext = p;
50189 break;
50193 #endif
50194 *ppBtree = p;
50196 btree_open_out:
50197 if( rc!=SQLITE_OK ){
50198 if( pBt && pBt->pPager ){
50199 sqlite3PagerClose(pBt->pPager);
50201 sqlite3_free(pBt);
50202 sqlite3_free(p);
50203 *ppBtree = 0;
50204 }else{
50205 /* If the B-Tree was successfully opened, set the pager-cache size to the
50206 ** default value. Except, when opening on an existing shared pager-cache,
50207 ** do not change the pager-cache size.
50209 if( sqlite3BtreeSchema(p, 0, 0)==0 ){
50210 sqlite3PagerSetCachesize(p->pBt->pPager, SQLITE_DEFAULT_CACHE_SIZE);
50213 if( mutexOpen ){
50214 assert( sqlite3_mutex_held(mutexOpen) );
50215 sqlite3_mutex_leave(mutexOpen);
50217 return rc;
50221 ** Decrement the BtShared.nRef counter. When it reaches zero,
50222 ** remove the BtShared structure from the sharing list. Return
50223 ** true if the BtShared.nRef counter reaches zero and return
50224 ** false if it is still positive.
50226 static int removeFromSharingList(BtShared *pBt){
50227 #ifndef SQLITE_OMIT_SHARED_CACHE
50228 sqlite3_mutex *pMaster;
50229 BtShared *pList;
50230 int removed = 0;
50232 assert( sqlite3_mutex_notheld(pBt->mutex) );
50233 pMaster = sqlite3MutexAlloc(SQLITE_MUTEX_STATIC_MASTER);
50234 sqlite3_mutex_enter(pMaster);
50235 pBt->nRef--;
50236 if( pBt->nRef<=0 ){
50237 if( GLOBAL(BtShared*,sqlite3SharedCacheList)==pBt ){
50238 GLOBAL(BtShared*,sqlite3SharedCacheList) = pBt->pNext;
50239 }else{
50240 pList = GLOBAL(BtShared*,sqlite3SharedCacheList);
50241 while( ALWAYS(pList) && pList->pNext!=pBt ){
50242 pList=pList->pNext;
50244 if( ALWAYS(pList) ){
50245 pList->pNext = pBt->pNext;
50248 if( SQLITE_THREADSAFE ){
50249 sqlite3_mutex_free(pBt->mutex);
50251 removed = 1;
50253 sqlite3_mutex_leave(pMaster);
50254 return removed;
50255 #else
50256 return 1;
50257 #endif
50261 ** Make sure pBt->pTmpSpace points to an allocation of
50262 ** MX_CELL_SIZE(pBt) bytes.
50264 static void allocateTempSpace(BtShared *pBt){
50265 if( !pBt->pTmpSpace ){
50266 pBt->pTmpSpace = sqlite3PageMalloc( pBt->pageSize );
50271 ** Free the pBt->pTmpSpace allocation
50273 static void freeTempSpace(BtShared *pBt){
50274 sqlite3PageFree( pBt->pTmpSpace);
50275 pBt->pTmpSpace = 0;
50279 ** Close an open database and invalidate all cursors.
50281 SQLITE_PRIVATE int sqlite3BtreeClose(Btree *p){
50282 BtShared *pBt = p->pBt;
50283 BtCursor *pCur;
50285 /* Close all cursors opened via this handle. */
50286 assert( sqlite3_mutex_held(p->db->mutex) );
50287 sqlite3BtreeEnter(p);
50288 pCur = pBt->pCursor;
50289 while( pCur ){
50290 BtCursor *pTmp = pCur;
50291 pCur = pCur->pNext;
50292 if( pTmp->pBtree==p ){
50293 sqlite3BtreeCloseCursor(pTmp);
50297 /* Rollback any active transaction and free the handle structure.
50298 ** The call to sqlite3BtreeRollback() drops any table-locks held by
50299 ** this handle.
50301 sqlite3BtreeRollback(p);
50302 sqlite3BtreeLeave(p);
50304 /* If there are still other outstanding references to the shared-btree
50305 ** structure, return now. The remainder of this procedure cleans
50306 ** up the shared-btree.
50308 assert( p->wantToLock==0 && p->locked==0 );
50309 if( !p->sharable || removeFromSharingList(pBt) ){
50310 /* The pBt is no longer on the sharing list, so we can access
50311 ** it without having to hold the mutex.
50313 ** Clean out and delete the BtShared object.
50315 assert( !pBt->pCursor );
50316 sqlite3PagerClose(pBt->pPager);
50317 if( pBt->xFreeSchema && pBt->pSchema ){
50318 pBt->xFreeSchema(pBt->pSchema);
50320 sqlite3DbFree(0, pBt->pSchema);
50321 freeTempSpace(pBt);
50322 sqlite3_free(pBt);
50325 #ifndef SQLITE_OMIT_SHARED_CACHE
50326 assert( p->wantToLock==0 );
50327 assert( p->locked==0 );
50328 if( p->pPrev ) p->pPrev->pNext = p->pNext;
50329 if( p->pNext ) p->pNext->pPrev = p->pPrev;
50330 #endif
50332 sqlite3_free(p);
50333 return SQLITE_OK;
50337 ** Change the limit on the number of pages allowed in the cache.
50339 ** The maximum number of cache pages is set to the absolute
50340 ** value of mxPage. If mxPage is negative, the pager will
50341 ** operate asynchronously - it will not stop to do fsync()s
50342 ** to insure data is written to the disk surface before
50343 ** continuing. Transactions still work if synchronous is off,
50344 ** and the database cannot be corrupted if this program
50345 ** crashes. But if the operating system crashes or there is
50346 ** an abrupt power failure when synchronous is off, the database
50347 ** could be left in an inconsistent and unrecoverable state.
50348 ** Synchronous is on by default so database corruption is not
50349 ** normally a worry.
50351 SQLITE_PRIVATE int sqlite3BtreeSetCacheSize(Btree *p, int mxPage){
50352 BtShared *pBt = p->pBt;
50353 assert( sqlite3_mutex_held(p->db->mutex) );
50354 sqlite3BtreeEnter(p);
50355 sqlite3PagerSetCachesize(pBt->pPager, mxPage);
50356 sqlite3BtreeLeave(p);
50357 return SQLITE_OK;
50361 ** Change the way data is synced to disk in order to increase or decrease
50362 ** how well the database resists damage due to OS crashes and power
50363 ** failures. Level 1 is the same as asynchronous (no syncs() occur and
50364 ** there is a high probability of damage) Level 2 is the default. There
50365 ** is a very low but non-zero probability of damage. Level 3 reduces the
50366 ** probability of damage to near zero but with a write performance reduction.
50368 #ifndef SQLITE_OMIT_PAGER_PRAGMAS
50369 SQLITE_PRIVATE int sqlite3BtreeSetSafetyLevel(
50370 Btree *p, /* The btree to set the safety level on */
50371 int level, /* PRAGMA synchronous. 1=OFF, 2=NORMAL, 3=FULL */
50372 int fullSync, /* PRAGMA fullfsync. */
50373 int ckptFullSync /* PRAGMA checkpoint_fullfync */
50375 BtShared *pBt = p->pBt;
50376 assert( sqlite3_mutex_held(p->db->mutex) );
50377 assert( level>=1 && level<=3 );
50378 sqlite3BtreeEnter(p);
50379 sqlite3PagerSetSafetyLevel(pBt->pPager, level, fullSync, ckptFullSync);
50380 sqlite3BtreeLeave(p);
50381 return SQLITE_OK;
50383 #endif
50386 ** Return TRUE if the given btree is set to safety level 1. In other
50387 ** words, return TRUE if no sync() occurs on the disk files.
50389 SQLITE_PRIVATE int sqlite3BtreeSyncDisabled(Btree *p){
50390 BtShared *pBt = p->pBt;
50391 int rc;
50392 assert( sqlite3_mutex_held(p->db->mutex) );
50393 sqlite3BtreeEnter(p);
50394 assert( pBt && pBt->pPager );
50395 rc = sqlite3PagerNosync(pBt->pPager);
50396 sqlite3BtreeLeave(p);
50397 return rc;
50401 ** Change the default pages size and the number of reserved bytes per page.
50402 ** Or, if the page size has already been fixed, return SQLITE_READONLY
50403 ** without changing anything.
50405 ** The page size must be a power of 2 between 512 and 65536. If the page
50406 ** size supplied does not meet this constraint then the page size is not
50407 ** changed.
50409 ** Page sizes are constrained to be a power of two so that the region
50410 ** of the database file used for locking (beginning at PENDING_BYTE,
50411 ** the first byte past the 1GB boundary, 0x40000000) needs to occur
50412 ** at the beginning of a page.
50414 ** If parameter nReserve is less than zero, then the number of reserved
50415 ** bytes per page is left unchanged.
50417 ** If the iFix!=0 then the pageSizeFixed flag is set so that the page size
50418 ** and autovacuum mode can no longer be changed.
50420 SQLITE_PRIVATE int sqlite3BtreeSetPageSize(Btree *p, int pageSize, int nReserve, int iFix){
50421 int rc = SQLITE_OK;
50422 BtShared *pBt = p->pBt;
50423 assert( nReserve>=-1 && nReserve<=255 );
50424 sqlite3BtreeEnter(p);
50425 if( pBt->pageSizeFixed ){
50426 sqlite3BtreeLeave(p);
50427 return SQLITE_READONLY;
50429 if( nReserve<0 ){
50430 nReserve = pBt->pageSize - pBt->usableSize;
50432 assert( nReserve>=0 && nReserve<=255 );
50433 if( pageSize>=512 && pageSize<=SQLITE_MAX_PAGE_SIZE &&
50434 ((pageSize-1)&pageSize)==0 ){
50435 assert( (pageSize & 7)==0 );
50436 assert( !pBt->pPage1 && !pBt->pCursor );
50437 pBt->pageSize = (u32)pageSize;
50438 freeTempSpace(pBt);
50440 rc = sqlite3PagerSetPagesize(pBt->pPager, &pBt->pageSize, nReserve);
50441 pBt->usableSize = pBt->pageSize - (u16)nReserve;
50442 if( iFix ) pBt->pageSizeFixed = 1;
50443 sqlite3BtreeLeave(p);
50444 return rc;
50448 ** Return the currently defined page size
50450 SQLITE_PRIVATE int sqlite3BtreeGetPageSize(Btree *p){
50451 return p->pBt->pageSize;
50454 #if !defined(SQLITE_OMIT_PAGER_PRAGMAS) || !defined(SQLITE_OMIT_VACUUM)
50456 ** Return the number of bytes of space at the end of every page that
50457 ** are intentually left unused. This is the "reserved" space that is
50458 ** sometimes used by extensions.
50460 SQLITE_PRIVATE int sqlite3BtreeGetReserve(Btree *p){
50461 int n;
50462 sqlite3BtreeEnter(p);
50463 n = p->pBt->pageSize - p->pBt->usableSize;
50464 sqlite3BtreeLeave(p);
50465 return n;
50469 ** Set the maximum page count for a database if mxPage is positive.
50470 ** No changes are made if mxPage is 0 or negative.
50471 ** Regardless of the value of mxPage, return the maximum page count.
50473 SQLITE_PRIVATE int sqlite3BtreeMaxPageCount(Btree *p, int mxPage){
50474 int n;
50475 sqlite3BtreeEnter(p);
50476 n = sqlite3PagerMaxPageCount(p->pBt->pPager, mxPage);
50477 sqlite3BtreeLeave(p);
50478 return n;
50482 ** Set the secureDelete flag if newFlag is 0 or 1. If newFlag is -1,
50483 ** then make no changes. Always return the value of the secureDelete
50484 ** setting after the change.
50486 SQLITE_PRIVATE int sqlite3BtreeSecureDelete(Btree *p, int newFlag){
50487 int b;
50488 if( p==0 ) return 0;
50489 sqlite3BtreeEnter(p);
50490 if( newFlag>=0 ){
50491 p->pBt->secureDelete = (newFlag!=0) ? 1 : 0;
50493 b = p->pBt->secureDelete;
50494 sqlite3BtreeLeave(p);
50495 return b;
50497 #endif /* !defined(SQLITE_OMIT_PAGER_PRAGMAS) || !defined(SQLITE_OMIT_VACUUM) */
50500 ** Change the 'auto-vacuum' property of the database. If the 'autoVacuum'
50501 ** parameter is non-zero, then auto-vacuum mode is enabled. If zero, it
50502 ** is disabled. The default value for the auto-vacuum property is
50503 ** determined by the SQLITE_DEFAULT_AUTOVACUUM macro.
50505 SQLITE_PRIVATE int sqlite3BtreeSetAutoVacuum(Btree *p, int autoVacuum){
50506 #ifdef SQLITE_OMIT_AUTOVACUUM
50507 return SQLITE_READONLY;
50508 #else
50509 BtShared *pBt = p->pBt;
50510 int rc = SQLITE_OK;
50511 u8 av = (u8)autoVacuum;
50513 sqlite3BtreeEnter(p);
50514 if( pBt->pageSizeFixed && (av ?1:0)!=pBt->autoVacuum ){
50515 rc = SQLITE_READONLY;
50516 }else{
50517 pBt->autoVacuum = av ?1:0;
50518 pBt->incrVacuum = av==2 ?1:0;
50520 sqlite3BtreeLeave(p);
50521 return rc;
50522 #endif
50526 ** Return the value of the 'auto-vacuum' property. If auto-vacuum is
50527 ** enabled 1 is returned. Otherwise 0.
50529 SQLITE_PRIVATE int sqlite3BtreeGetAutoVacuum(Btree *p){
50530 #ifdef SQLITE_OMIT_AUTOVACUUM
50531 return BTREE_AUTOVACUUM_NONE;
50532 #else
50533 int rc;
50534 sqlite3BtreeEnter(p);
50535 rc = (
50536 (!p->pBt->autoVacuum)?BTREE_AUTOVACUUM_NONE:
50537 (!p->pBt->incrVacuum)?BTREE_AUTOVACUUM_FULL:
50538 BTREE_AUTOVACUUM_INCR
50540 sqlite3BtreeLeave(p);
50541 return rc;
50542 #endif
50547 ** Get a reference to pPage1 of the database file. This will
50548 ** also acquire a readlock on that file.
50550 ** SQLITE_OK is returned on success. If the file is not a
50551 ** well-formed database file, then SQLITE_CORRUPT is returned.
50552 ** SQLITE_BUSY is returned if the database is locked. SQLITE_NOMEM
50553 ** is returned if we run out of memory.
50555 static int lockBtree(BtShared *pBt){
50556 int rc; /* Result code from subfunctions */
50557 MemPage *pPage1; /* Page 1 of the database file */
50558 int nPage; /* Number of pages in the database */
50559 int nPageFile = 0; /* Number of pages in the database file */
50560 int nPageHeader; /* Number of pages in the database according to hdr */
50562 assert( sqlite3_mutex_held(pBt->mutex) );
50563 assert( pBt->pPage1==0 );
50564 rc = sqlite3PagerSharedLock(pBt->pPager);
50565 if( rc!=SQLITE_OK ) return rc;
50566 rc = btreeGetPage(pBt, 1, &pPage1, 0);
50567 if( rc!=SQLITE_OK ) return rc;
50569 /* Do some checking to help insure the file we opened really is
50570 ** a valid database file.
50572 nPage = nPageHeader = get4byte(28+(u8*)pPage1->aData);
50573 sqlite3PagerPagecount(pBt->pPager, &nPageFile);
50574 if( nPage==0 || memcmp(24+(u8*)pPage1->aData, 92+(u8*)pPage1->aData,4)!=0 ){
50575 nPage = nPageFile;
50577 if( nPage>0 ){
50578 u32 pageSize;
50579 u32 usableSize;
50580 u8 *page1 = pPage1->aData;
50581 rc = SQLITE_NOTADB;
50582 if( memcmp(page1, zMagicHeader, 16)!=0 ){
50583 goto page1_init_failed;
50586 #ifdef SQLITE_OMIT_WAL
50587 if( page1[18]>1 ){
50588 pBt->readOnly = 1;
50590 if( page1[19]>1 ){
50591 goto page1_init_failed;
50593 #else
50594 if( page1[18]>2 ){
50595 pBt->readOnly = 1;
50597 if( page1[19]>2 ){
50598 goto page1_init_failed;
50601 /* If the write version is set to 2, this database should be accessed
50602 ** in WAL mode. If the log is not already open, open it now. Then
50603 ** return SQLITE_OK and return without populating BtShared.pPage1.
50604 ** The caller detects this and calls this function again. This is
50605 ** required as the version of page 1 currently in the page1 buffer
50606 ** may not be the latest version - there may be a newer one in the log
50607 ** file.
50609 if( page1[19]==2 && pBt->doNotUseWAL==0 ){
50610 int isOpen = 0;
50611 rc = sqlite3PagerOpenWal(pBt->pPager, &isOpen);
50612 if( rc!=SQLITE_OK ){
50613 goto page1_init_failed;
50614 }else if( isOpen==0 ){
50615 releasePage(pPage1);
50616 return SQLITE_OK;
50618 rc = SQLITE_NOTADB;
50620 #endif
50622 /* The maximum embedded fraction must be exactly 25%. And the minimum
50623 ** embedded fraction must be 12.5% for both leaf-data and non-leaf-data.
50624 ** The original design allowed these amounts to vary, but as of
50625 ** version 3.6.0, we require them to be fixed.
50627 if( memcmp(&page1[21], "\100\040\040",3)!=0 ){
50628 goto page1_init_failed;
50630 pageSize = (page1[16]<<8) | (page1[17]<<16);
50631 if( ((pageSize-1)&pageSize)!=0
50632 || pageSize>SQLITE_MAX_PAGE_SIZE
50633 || pageSize<=256
50635 goto page1_init_failed;
50637 assert( (pageSize & 7)==0 );
50638 usableSize = pageSize - page1[20];
50639 if( (u32)pageSize!=pBt->pageSize ){
50640 /* After reading the first page of the database assuming a page size
50641 ** of BtShared.pageSize, we have discovered that the page-size is
50642 ** actually pageSize. Unlock the database, leave pBt->pPage1 at
50643 ** zero and return SQLITE_OK. The caller will call this function
50644 ** again with the correct page-size.
50646 releasePage(pPage1);
50647 pBt->usableSize = usableSize;
50648 pBt->pageSize = pageSize;
50649 freeTempSpace(pBt);
50650 rc = sqlite3PagerSetPagesize(pBt->pPager, &pBt->pageSize,
50651 pageSize-usableSize);
50652 return rc;
50654 if( (pBt->db->flags & SQLITE_RecoveryMode)==0 && nPage>nPageFile ){
50655 rc = SQLITE_CORRUPT_BKPT;
50656 goto page1_init_failed;
50658 if( usableSize<480 ){
50659 goto page1_init_failed;
50661 pBt->pageSize = pageSize;
50662 pBt->usableSize = usableSize;
50663 #ifndef SQLITE_OMIT_AUTOVACUUM
50664 pBt->autoVacuum = (get4byte(&page1[36 + 4*4])?1:0);
50665 pBt->incrVacuum = (get4byte(&page1[36 + 7*4])?1:0);
50666 #endif
50669 /* maxLocal is the maximum amount of payload to store locally for
50670 ** a cell. Make sure it is small enough so that at least minFanout
50671 ** cells can will fit on one page. We assume a 10-byte page header.
50672 ** Besides the payload, the cell must store:
50673 ** 2-byte pointer to the cell
50674 ** 4-byte child pointer
50675 ** 9-byte nKey value
50676 ** 4-byte nData value
50677 ** 4-byte overflow page pointer
50678 ** So a cell consists of a 2-byte pointer, a header which is as much as
50679 ** 17 bytes long, 0 to N bytes of payload, and an optional 4 byte overflow
50680 ** page pointer.
50682 pBt->maxLocal = (u16)((pBt->usableSize-12)*64/255 - 23);
50683 pBt->minLocal = (u16)((pBt->usableSize-12)*32/255 - 23);
50684 pBt->maxLeaf = (u16)(pBt->usableSize - 35);
50685 pBt->minLeaf = (u16)((pBt->usableSize-12)*32/255 - 23);
50686 assert( pBt->maxLeaf + 23 <= MX_CELL_SIZE(pBt) );
50687 pBt->pPage1 = pPage1;
50688 pBt->nPage = nPage;
50689 return SQLITE_OK;
50691 page1_init_failed:
50692 releasePage(pPage1);
50693 pBt->pPage1 = 0;
50694 return rc;
50698 ** If there are no outstanding cursors and we are not in the middle
50699 ** of a transaction but there is a read lock on the database, then
50700 ** this routine unrefs the first page of the database file which
50701 ** has the effect of releasing the read lock.
50703 ** If there is a transaction in progress, this routine is a no-op.
50705 static void unlockBtreeIfUnused(BtShared *pBt){
50706 assert( sqlite3_mutex_held(pBt->mutex) );
50707 assert( pBt->pCursor==0 || pBt->inTransaction>TRANS_NONE );
50708 if( pBt->inTransaction==TRANS_NONE && pBt->pPage1!=0 ){
50709 assert( pBt->pPage1->aData );
50710 assert( sqlite3PagerRefcount(pBt->pPager)==1 );
50711 assert( pBt->pPage1->aData );
50712 releasePage(pBt->pPage1);
50713 pBt->pPage1 = 0;
50718 ** If pBt points to an empty file then convert that empty file
50719 ** into a new empty database by initializing the first page of
50720 ** the database.
50722 static int newDatabase(BtShared *pBt){
50723 MemPage *pP1;
50724 unsigned char *data;
50725 int rc;
50727 assert( sqlite3_mutex_held(pBt->mutex) );
50728 if( pBt->nPage>0 ){
50729 return SQLITE_OK;
50731 pP1 = pBt->pPage1;
50732 assert( pP1!=0 );
50733 data = pP1->aData;
50734 rc = sqlite3PagerWrite(pP1->pDbPage);
50735 if( rc ) return rc;
50736 memcpy(data, zMagicHeader, sizeof(zMagicHeader));
50737 assert( sizeof(zMagicHeader)==16 );
50738 data[16] = (u8)((pBt->pageSize>>8)&0xff);
50739 data[17] = (u8)((pBt->pageSize>>16)&0xff);
50740 data[18] = 1;
50741 data[19] = 1;
50742 assert( pBt->usableSize<=pBt->pageSize && pBt->usableSize+255>=pBt->pageSize);
50743 data[20] = (u8)(pBt->pageSize - pBt->usableSize);
50744 data[21] = 64;
50745 data[22] = 32;
50746 data[23] = 32;
50747 memset(&data[24], 0, 100-24);
50748 zeroPage(pP1, PTF_INTKEY|PTF_LEAF|PTF_LEAFDATA );
50749 pBt->pageSizeFixed = 1;
50750 #ifndef SQLITE_OMIT_AUTOVACUUM
50751 assert( pBt->autoVacuum==1 || pBt->autoVacuum==0 );
50752 assert( pBt->incrVacuum==1 || pBt->incrVacuum==0 );
50753 put4byte(&data[36 + 4*4], pBt->autoVacuum);
50754 put4byte(&data[36 + 7*4], pBt->incrVacuum);
50755 #endif
50756 pBt->nPage = 1;
50757 data[31] = 1;
50758 return SQLITE_OK;
50762 ** Attempt to start a new transaction. A write-transaction
50763 ** is started if the second argument is nonzero, otherwise a read-
50764 ** transaction. If the second argument is 2 or more and exclusive
50765 ** transaction is started, meaning that no other process is allowed
50766 ** to access the database. A preexisting transaction may not be
50767 ** upgraded to exclusive by calling this routine a second time - the
50768 ** exclusivity flag only works for a new transaction.
50770 ** A write-transaction must be started before attempting any
50771 ** changes to the database. None of the following routines
50772 ** will work unless a transaction is started first:
50774 ** sqlite3BtreeCreateTable()
50775 ** sqlite3BtreeCreateIndex()
50776 ** sqlite3BtreeClearTable()
50777 ** sqlite3BtreeDropTable()
50778 ** sqlite3BtreeInsert()
50779 ** sqlite3BtreeDelete()
50780 ** sqlite3BtreeUpdateMeta()
50782 ** If an initial attempt to acquire the lock fails because of lock contention
50783 ** and the database was previously unlocked, then invoke the busy handler
50784 ** if there is one. But if there was previously a read-lock, do not
50785 ** invoke the busy handler - just return SQLITE_BUSY. SQLITE_BUSY is
50786 ** returned when there is already a read-lock in order to avoid a deadlock.
50788 ** Suppose there are two processes A and B. A has a read lock and B has
50789 ** a reserved lock. B tries to promote to exclusive but is blocked because
50790 ** of A's read lock. A tries to promote to reserved but is blocked by B.
50791 ** One or the other of the two processes must give way or there can be
50792 ** no progress. By returning SQLITE_BUSY and not invoking the busy callback
50793 ** when A already has a read lock, we encourage A to give up and let B
50794 ** proceed.
50796 SQLITE_PRIVATE int sqlite3BtreeBeginTrans(Btree *p, int wrflag){
50797 sqlite3 *pBlock = 0;
50798 BtShared *pBt = p->pBt;
50799 int rc = SQLITE_OK;
50801 sqlite3BtreeEnter(p);
50802 btreeIntegrity(p);
50804 /* If the btree is already in a write-transaction, or it
50805 ** is already in a read-transaction and a read-transaction
50806 ** is requested, this is a no-op.
50808 if( p->inTrans==TRANS_WRITE || (p->inTrans==TRANS_READ && !wrflag) ){
50809 goto trans_begun;
50812 /* Write transactions are not possible on a read-only database */
50813 if( pBt->readOnly && wrflag ){
50814 rc = SQLITE_READONLY;
50815 goto trans_begun;
50818 #ifndef SQLITE_OMIT_SHARED_CACHE
50819 /* If another database handle has already opened a write transaction
50820 ** on this shared-btree structure and a second write transaction is
50821 ** requested, return SQLITE_LOCKED.
50823 if( (wrflag && pBt->inTransaction==TRANS_WRITE) || pBt->isPending ){
50824 pBlock = pBt->pWriter->db;
50825 }else if( wrflag>1 ){
50826 BtLock *pIter;
50827 for(pIter=pBt->pLock; pIter; pIter=pIter->pNext){
50828 if( pIter->pBtree!=p ){
50829 pBlock = pIter->pBtree->db;
50830 break;
50834 if( pBlock ){
50835 sqlite3ConnectionBlocked(p->db, pBlock);
50836 rc = SQLITE_LOCKED_SHAREDCACHE;
50837 goto trans_begun;
50839 #endif
50841 /* Any read-only or read-write transaction implies a read-lock on
50842 ** page 1. So if some other shared-cache client already has a write-lock
50843 ** on page 1, the transaction cannot be opened. */
50844 rc = querySharedCacheTableLock(p, MASTER_ROOT, READ_LOCK);
50845 if( SQLITE_OK!=rc ) goto trans_begun;
50847 pBt->initiallyEmpty = (u8)(pBt->nPage==0);
50848 do {
50849 /* Call lockBtree() until either pBt->pPage1 is populated or
50850 ** lockBtree() returns something other than SQLITE_OK. lockBtree()
50851 ** may return SQLITE_OK but leave pBt->pPage1 set to 0 if after
50852 ** reading page 1 it discovers that the page-size of the database
50853 ** file is not pBt->pageSize. In this case lockBtree() will update
50854 ** pBt->pageSize to the page-size of the file on disk.
50856 while( pBt->pPage1==0 && SQLITE_OK==(rc = lockBtree(pBt)) );
50858 if( rc==SQLITE_OK && wrflag ){
50859 if( pBt->readOnly ){
50860 rc = SQLITE_READONLY;
50861 }else{
50862 rc = sqlite3PagerBegin(pBt->pPager,wrflag>1,sqlite3TempInMemory(p->db));
50863 if( rc==SQLITE_OK ){
50864 rc = newDatabase(pBt);
50869 if( rc!=SQLITE_OK ){
50870 unlockBtreeIfUnused(pBt);
50872 }while( (rc&0xFF)==SQLITE_BUSY && pBt->inTransaction==TRANS_NONE &&
50873 btreeInvokeBusyHandler(pBt) );
50875 if( rc==SQLITE_OK ){
50876 if( p->inTrans==TRANS_NONE ){
50877 pBt->nTransaction++;
50878 #ifndef SQLITE_OMIT_SHARED_CACHE
50879 if( p->sharable ){
50880 assert( p->lock.pBtree==p && p->lock.iTable==1 );
50881 p->lock.eLock = READ_LOCK;
50882 p->lock.pNext = pBt->pLock;
50883 pBt->pLock = &p->lock;
50885 #endif
50887 p->inTrans = (wrflag?TRANS_WRITE:TRANS_READ);
50888 if( p->inTrans>pBt->inTransaction ){
50889 pBt->inTransaction = p->inTrans;
50891 if( wrflag ){
50892 MemPage *pPage1 = pBt->pPage1;
50893 #ifndef SQLITE_OMIT_SHARED_CACHE
50894 assert( !pBt->pWriter );
50895 pBt->pWriter = p;
50896 pBt->isExclusive = (u8)(wrflag>1);
50897 #endif
50899 /* If the db-size header field is incorrect (as it may be if an old
50900 ** client has been writing the database file), update it now. Doing
50901 ** this sooner rather than later means the database size can safely
50902 ** re-read the database size from page 1 if a savepoint or transaction
50903 ** rollback occurs within the transaction.
50905 if( pBt->nPage!=get4byte(&pPage1->aData[28]) ){
50906 rc = sqlite3PagerWrite(pPage1->pDbPage);
50907 if( rc==SQLITE_OK ){
50908 put4byte(&pPage1->aData[28], pBt->nPage);
50915 trans_begun:
50916 if( rc==SQLITE_OK && wrflag ){
50917 /* This call makes sure that the pager has the correct number of
50918 ** open savepoints. If the second parameter is greater than 0 and
50919 ** the sub-journal is not already open, then it will be opened here.
50921 rc = sqlite3PagerOpenSavepoint(pBt->pPager, p->db->nSavepoint);
50924 btreeIntegrity(p);
50925 sqlite3BtreeLeave(p);
50926 return rc;
50929 #ifndef SQLITE_OMIT_AUTOVACUUM
50932 ** Set the pointer-map entries for all children of page pPage. Also, if
50933 ** pPage contains cells that point to overflow pages, set the pointer
50934 ** map entries for the overflow pages as well.
50936 static int setChildPtrmaps(MemPage *pPage){
50937 int i; /* Counter variable */
50938 int nCell; /* Number of cells in page pPage */
50939 int rc; /* Return code */
50940 BtShared *pBt = pPage->pBt;
50941 u8 isInitOrig = pPage->isInit;
50942 Pgno pgno = pPage->pgno;
50944 assert( sqlite3_mutex_held(pPage->pBt->mutex) );
50945 rc = btreeInitPage(pPage);
50946 if( rc!=SQLITE_OK ){
50947 goto set_child_ptrmaps_out;
50949 nCell = pPage->nCell;
50951 for(i=0; i<nCell; i++){
50952 u8 *pCell = findCell(pPage, i);
50954 ptrmapPutOvflPtr(pPage, pCell, &rc);
50956 if( !pPage->leaf ){
50957 Pgno childPgno = get4byte(pCell);
50958 ptrmapPut(pBt, childPgno, PTRMAP_BTREE, pgno, &rc);
50962 if( !pPage->leaf ){
50963 Pgno childPgno = get4byte(&pPage->aData[pPage->hdrOffset+8]);
50964 ptrmapPut(pBt, childPgno, PTRMAP_BTREE, pgno, &rc);
50967 set_child_ptrmaps_out:
50968 pPage->isInit = isInitOrig;
50969 return rc;
50973 ** Somewhere on pPage is a pointer to page iFrom. Modify this pointer so
50974 ** that it points to iTo. Parameter eType describes the type of pointer to
50975 ** be modified, as follows:
50977 ** PTRMAP_BTREE: pPage is a btree-page. The pointer points at a child
50978 ** page of pPage.
50980 ** PTRMAP_OVERFLOW1: pPage is a btree-page. The pointer points at an overflow
50981 ** page pointed to by one of the cells on pPage.
50983 ** PTRMAP_OVERFLOW2: pPage is an overflow-page. The pointer points at the next
50984 ** overflow page in the list.
50986 static int modifyPagePointer(MemPage *pPage, Pgno iFrom, Pgno iTo, u8 eType){
50987 assert( sqlite3_mutex_held(pPage->pBt->mutex) );
50988 assert( sqlite3PagerIswriteable(pPage->pDbPage) );
50989 if( eType==PTRMAP_OVERFLOW2 ){
50990 /* The pointer is always the first 4 bytes of the page in this case. */
50991 if( get4byte(pPage->aData)!=iFrom ){
50992 return SQLITE_CORRUPT_BKPT;
50994 put4byte(pPage->aData, iTo);
50995 }else{
50996 u8 isInitOrig = pPage->isInit;
50997 int i;
50998 int nCell;
51000 btreeInitPage(pPage);
51001 nCell = pPage->nCell;
51003 for(i=0; i<nCell; i++){
51004 u8 *pCell = findCell(pPage, i);
51005 if( eType==PTRMAP_OVERFLOW1 ){
51006 CellInfo info;
51007 btreeParseCellPtr(pPage, pCell, &info);
51008 if( info.iOverflow
51009 && pCell+info.iOverflow+3<=pPage->aData+pPage->maskPage
51010 && iFrom==get4byte(&pCell[info.iOverflow])
51012 put4byte(&pCell[info.iOverflow], iTo);
51013 break;
51015 }else{
51016 if( get4byte(pCell)==iFrom ){
51017 put4byte(pCell, iTo);
51018 break;
51023 if( i==nCell ){
51024 if( eType!=PTRMAP_BTREE ||
51025 get4byte(&pPage->aData[pPage->hdrOffset+8])!=iFrom ){
51026 return SQLITE_CORRUPT_BKPT;
51028 put4byte(&pPage->aData[pPage->hdrOffset+8], iTo);
51031 pPage->isInit = isInitOrig;
51033 return SQLITE_OK;
51038 ** Move the open database page pDbPage to location iFreePage in the
51039 ** database. The pDbPage reference remains valid.
51041 ** The isCommit flag indicates that there is no need to remember that
51042 ** the journal needs to be sync()ed before database page pDbPage->pgno
51043 ** can be written to. The caller has already promised not to write to that
51044 ** page.
51046 static int relocatePage(
51047 BtShared *pBt, /* Btree */
51048 MemPage *pDbPage, /* Open page to move */
51049 u8 eType, /* Pointer map 'type' entry for pDbPage */
51050 Pgno iPtrPage, /* Pointer map 'page-no' entry for pDbPage */
51051 Pgno iFreePage, /* The location to move pDbPage to */
51052 int isCommit /* isCommit flag passed to sqlite3PagerMovepage */
51054 MemPage *pPtrPage; /* The page that contains a pointer to pDbPage */
51055 Pgno iDbPage = pDbPage->pgno;
51056 Pager *pPager = pBt->pPager;
51057 int rc;
51059 assert( eType==PTRMAP_OVERFLOW2 || eType==PTRMAP_OVERFLOW1 ||
51060 eType==PTRMAP_BTREE || eType==PTRMAP_ROOTPAGE );
51061 assert( sqlite3_mutex_held(pBt->mutex) );
51062 assert( pDbPage->pBt==pBt );
51064 /* Move page iDbPage from its current location to page number iFreePage */
51065 TRACE(("AUTOVACUUM: Moving %d to free page %d (ptr page %d type %d)\n",
51066 iDbPage, iFreePage, iPtrPage, eType));
51067 rc = sqlite3PagerMovepage(pPager, pDbPage->pDbPage, iFreePage, isCommit);
51068 if( rc!=SQLITE_OK ){
51069 return rc;
51071 pDbPage->pgno = iFreePage;
51073 /* If pDbPage was a btree-page, then it may have child pages and/or cells
51074 ** that point to overflow pages. The pointer map entries for all these
51075 ** pages need to be changed.
51077 ** If pDbPage is an overflow page, then the first 4 bytes may store a
51078 ** pointer to a subsequent overflow page. If this is the case, then
51079 ** the pointer map needs to be updated for the subsequent overflow page.
51081 if( eType==PTRMAP_BTREE || eType==PTRMAP_ROOTPAGE ){
51082 rc = setChildPtrmaps(pDbPage);
51083 if( rc!=SQLITE_OK ){
51084 return rc;
51086 }else{
51087 Pgno nextOvfl = get4byte(pDbPage->aData);
51088 if( nextOvfl!=0 ){
51089 ptrmapPut(pBt, nextOvfl, PTRMAP_OVERFLOW2, iFreePage, &rc);
51090 if( rc!=SQLITE_OK ){
51091 return rc;
51096 /* Fix the database pointer on page iPtrPage that pointed at iDbPage so
51097 ** that it points at iFreePage. Also fix the pointer map entry for
51098 ** iPtrPage.
51100 if( eType!=PTRMAP_ROOTPAGE ){
51101 rc = btreeGetPage(pBt, iPtrPage, &pPtrPage, 0);
51102 if( rc!=SQLITE_OK ){
51103 return rc;
51105 rc = sqlite3PagerWrite(pPtrPage->pDbPage);
51106 if( rc!=SQLITE_OK ){
51107 releasePage(pPtrPage);
51108 return rc;
51110 rc = modifyPagePointer(pPtrPage, iDbPage, iFreePage, eType);
51111 releasePage(pPtrPage);
51112 if( rc==SQLITE_OK ){
51113 ptrmapPut(pBt, iFreePage, eType, iPtrPage, &rc);
51116 return rc;
51119 /* Forward declaration required by incrVacuumStep(). */
51120 static int allocateBtreePage(BtShared *, MemPage **, Pgno *, Pgno, u8);
51123 ** Perform a single step of an incremental-vacuum. If successful,
51124 ** return SQLITE_OK. If there is no work to do (and therefore no
51125 ** point in calling this function again), return SQLITE_DONE.
51127 ** More specificly, this function attempts to re-organize the
51128 ** database so that the last page of the file currently in use
51129 ** is no longer in use.
51131 ** If the nFin parameter is non-zero, this function assumes
51132 ** that the caller will keep calling incrVacuumStep() until
51133 ** it returns SQLITE_DONE or an error, and that nFin is the
51134 ** number of pages the database file will contain after this
51135 ** process is complete. If nFin is zero, it is assumed that
51136 ** incrVacuumStep() will be called a finite amount of times
51137 ** which may or may not empty the freelist. A full autovacuum
51138 ** has nFin>0. A "PRAGMA incremental_vacuum" has nFin==0.
51140 static int incrVacuumStep(BtShared *pBt, Pgno nFin, Pgno iLastPg){
51141 Pgno nFreeList; /* Number of pages still on the free-list */
51142 int rc;
51144 assert( sqlite3_mutex_held(pBt->mutex) );
51145 assert( iLastPg>nFin );
51147 if( !PTRMAP_ISPAGE(pBt, iLastPg) && iLastPg!=PENDING_BYTE_PAGE(pBt) ){
51148 u8 eType;
51149 Pgno iPtrPage;
51151 nFreeList = get4byte(&pBt->pPage1->aData[36]);
51152 if( nFreeList==0 ){
51153 return SQLITE_DONE;
51156 rc = ptrmapGet(pBt, iLastPg, &eType, &iPtrPage);
51157 if( rc!=SQLITE_OK ){
51158 return rc;
51160 if( eType==PTRMAP_ROOTPAGE ){
51161 return SQLITE_CORRUPT_BKPT;
51164 if( eType==PTRMAP_FREEPAGE ){
51165 if( nFin==0 ){
51166 /* Remove the page from the files free-list. This is not required
51167 ** if nFin is non-zero. In that case, the free-list will be
51168 ** truncated to zero after this function returns, so it doesn't
51169 ** matter if it still contains some garbage entries.
51171 Pgno iFreePg;
51172 MemPage *pFreePg;
51173 rc = allocateBtreePage(pBt, &pFreePg, &iFreePg, iLastPg, 1);
51174 if( rc!=SQLITE_OK ){
51175 return rc;
51177 assert( iFreePg==iLastPg );
51178 releasePage(pFreePg);
51180 } else {
51181 Pgno iFreePg; /* Index of free page to move pLastPg to */
51182 MemPage *pLastPg;
51184 rc = btreeGetPage(pBt, iLastPg, &pLastPg, 0);
51185 if( rc!=SQLITE_OK ){
51186 return rc;
51189 /* If nFin is zero, this loop runs exactly once and page pLastPg
51190 ** is swapped with the first free page pulled off the free list.
51192 ** On the other hand, if nFin is greater than zero, then keep
51193 ** looping until a free-page located within the first nFin pages
51194 ** of the file is found.
51196 do {
51197 MemPage *pFreePg;
51198 rc = allocateBtreePage(pBt, &pFreePg, &iFreePg, 0, 0);
51199 if( rc!=SQLITE_OK ){
51200 releasePage(pLastPg);
51201 return rc;
51203 releasePage(pFreePg);
51204 }while( nFin!=0 && iFreePg>nFin );
51205 assert( iFreePg<iLastPg );
51207 rc = sqlite3PagerWrite(pLastPg->pDbPage);
51208 if( rc==SQLITE_OK ){
51209 rc = relocatePage(pBt, pLastPg, eType, iPtrPage, iFreePg, nFin!=0);
51211 releasePage(pLastPg);
51212 if( rc!=SQLITE_OK ){
51213 return rc;
51218 if( nFin==0 ){
51219 iLastPg--;
51220 while( iLastPg==PENDING_BYTE_PAGE(pBt)||PTRMAP_ISPAGE(pBt, iLastPg) ){
51221 if( PTRMAP_ISPAGE(pBt, iLastPg) ){
51222 MemPage *pPg;
51223 rc = btreeGetPage(pBt, iLastPg, &pPg, 0);
51224 if( rc!=SQLITE_OK ){
51225 return rc;
51227 rc = sqlite3PagerWrite(pPg->pDbPage);
51228 releasePage(pPg);
51229 if( rc!=SQLITE_OK ){
51230 return rc;
51233 iLastPg--;
51235 sqlite3PagerTruncateImage(pBt->pPager, iLastPg);
51236 pBt->nPage = iLastPg;
51238 return SQLITE_OK;
51242 ** A write-transaction must be opened before calling this function.
51243 ** It performs a single unit of work towards an incremental vacuum.
51245 ** If the incremental vacuum is finished after this function has run,
51246 ** SQLITE_DONE is returned. If it is not finished, but no error occurred,
51247 ** SQLITE_OK is returned. Otherwise an SQLite error code.
51249 SQLITE_PRIVATE int sqlite3BtreeIncrVacuum(Btree *p){
51250 int rc;
51251 BtShared *pBt = p->pBt;
51253 sqlite3BtreeEnter(p);
51254 assert( pBt->inTransaction==TRANS_WRITE && p->inTrans==TRANS_WRITE );
51255 if( !pBt->autoVacuum ){
51256 rc = SQLITE_DONE;
51257 }else{
51258 invalidateAllOverflowCache(pBt);
51259 rc = incrVacuumStep(pBt, 0, btreePagecount(pBt));
51260 if( rc==SQLITE_OK ){
51261 rc = sqlite3PagerWrite(pBt->pPage1->pDbPage);
51262 put4byte(&pBt->pPage1->aData[28], pBt->nPage);
51265 sqlite3BtreeLeave(p);
51266 return rc;
51270 ** This routine is called prior to sqlite3PagerCommit when a transaction
51271 ** is commited for an auto-vacuum database.
51273 ** If SQLITE_OK is returned, then *pnTrunc is set to the number of pages
51274 ** the database file should be truncated to during the commit process.
51275 ** i.e. the database has been reorganized so that only the first *pnTrunc
51276 ** pages are in use.
51278 static int autoVacuumCommit(BtShared *pBt){
51279 int rc = SQLITE_OK;
51280 Pager *pPager = pBt->pPager;
51281 VVA_ONLY( int nRef = sqlite3PagerRefcount(pPager) );
51283 assert( sqlite3_mutex_held(pBt->mutex) );
51284 invalidateAllOverflowCache(pBt);
51285 assert(pBt->autoVacuum);
51286 if( !pBt->incrVacuum ){
51287 Pgno nFin; /* Number of pages in database after autovacuuming */
51288 Pgno nFree; /* Number of pages on the freelist initially */
51289 Pgno nPtrmap; /* Number of PtrMap pages to be freed */
51290 Pgno iFree; /* The next page to be freed */
51291 int nEntry; /* Number of entries on one ptrmap page */
51292 Pgno nOrig; /* Database size before freeing */
51294 nOrig = btreePagecount(pBt);
51295 if( PTRMAP_ISPAGE(pBt, nOrig) || nOrig==PENDING_BYTE_PAGE(pBt) ){
51296 /* It is not possible to create a database for which the final page
51297 ** is either a pointer-map page or the pending-byte page. If one
51298 ** is encountered, this indicates corruption.
51300 return SQLITE_CORRUPT_BKPT;
51303 nFree = get4byte(&pBt->pPage1->aData[36]);
51304 nEntry = pBt->usableSize/5;
51305 nPtrmap = (nFree-nOrig+PTRMAP_PAGENO(pBt, nOrig)+nEntry)/nEntry;
51306 nFin = nOrig - nFree - nPtrmap;
51307 if( nOrig>PENDING_BYTE_PAGE(pBt) && nFin<PENDING_BYTE_PAGE(pBt) ){
51308 nFin--;
51310 while( PTRMAP_ISPAGE(pBt, nFin) || nFin==PENDING_BYTE_PAGE(pBt) ){
51311 nFin--;
51313 if( nFin>nOrig ) return SQLITE_CORRUPT_BKPT;
51315 for(iFree=nOrig; iFree>nFin && rc==SQLITE_OK; iFree--){
51316 rc = incrVacuumStep(pBt, nFin, iFree);
51318 if( (rc==SQLITE_DONE || rc==SQLITE_OK) && nFree>0 ){
51319 rc = sqlite3PagerWrite(pBt->pPage1->pDbPage);
51320 put4byte(&pBt->pPage1->aData[32], 0);
51321 put4byte(&pBt->pPage1->aData[36], 0);
51322 put4byte(&pBt->pPage1->aData[28], nFin);
51323 sqlite3PagerTruncateImage(pBt->pPager, nFin);
51324 pBt->nPage = nFin;
51326 if( rc!=SQLITE_OK ){
51327 sqlite3PagerRollback(pPager);
51331 assert( nRef==sqlite3PagerRefcount(pPager) );
51332 return rc;
51335 #else /* ifndef SQLITE_OMIT_AUTOVACUUM */
51336 # define setChildPtrmaps(x) SQLITE_OK
51337 #endif
51340 ** This routine does the first phase of a two-phase commit. This routine
51341 ** causes a rollback journal to be created (if it does not already exist)
51342 ** and populated with enough information so that if a power loss occurs
51343 ** the database can be restored to its original state by playing back
51344 ** the journal. Then the contents of the journal are flushed out to
51345 ** the disk. After the journal is safely on oxide, the changes to the
51346 ** database are written into the database file and flushed to oxide.
51347 ** At the end of this call, the rollback journal still exists on the
51348 ** disk and we are still holding all locks, so the transaction has not
51349 ** committed. See sqlite3BtreeCommitPhaseTwo() for the second phase of the
51350 ** commit process.
51352 ** This call is a no-op if no write-transaction is currently active on pBt.
51354 ** Otherwise, sync the database file for the btree pBt. zMaster points to
51355 ** the name of a master journal file that should be written into the
51356 ** individual journal file, or is NULL, indicating no master journal file
51357 ** (single database transaction).
51359 ** When this is called, the master journal should already have been
51360 ** created, populated with this journal pointer and synced to disk.
51362 ** Once this is routine has returned, the only thing required to commit
51363 ** the write-transaction for this database file is to delete the journal.
51365 SQLITE_PRIVATE int sqlite3BtreeCommitPhaseOne(Btree *p, const char *zMaster){
51366 int rc = SQLITE_OK;
51367 if( p->inTrans==TRANS_WRITE ){
51368 BtShared *pBt = p->pBt;
51369 sqlite3BtreeEnter(p);
51370 #ifndef SQLITE_OMIT_AUTOVACUUM
51371 if( pBt->autoVacuum ){
51372 rc = autoVacuumCommit(pBt);
51373 if( rc!=SQLITE_OK ){
51374 sqlite3BtreeLeave(p);
51375 return rc;
51378 #endif
51379 rc = sqlite3PagerCommitPhaseOne(pBt->pPager, zMaster, 0);
51380 sqlite3BtreeLeave(p);
51382 return rc;
51386 ** This function is called from both BtreeCommitPhaseTwo() and BtreeRollback()
51387 ** at the conclusion of a transaction.
51389 static void btreeEndTransaction(Btree *p){
51390 BtShared *pBt = p->pBt;
51391 assert( sqlite3BtreeHoldsMutex(p) );
51393 btreeClearHasContent(pBt);
51394 if( p->inTrans>TRANS_NONE && p->db->activeVdbeCnt>1 ){
51395 /* If there are other active statements that belong to this database
51396 ** handle, downgrade to a read-only transaction. The other statements
51397 ** may still be reading from the database. */
51398 downgradeAllSharedCacheTableLocks(p);
51399 p->inTrans = TRANS_READ;
51400 }else{
51401 /* If the handle had any kind of transaction open, decrement the
51402 ** transaction count of the shared btree. If the transaction count
51403 ** reaches 0, set the shared state to TRANS_NONE. The unlockBtreeIfUnused()
51404 ** call below will unlock the pager. */
51405 if( p->inTrans!=TRANS_NONE ){
51406 clearAllSharedCacheTableLocks(p);
51407 pBt->nTransaction--;
51408 if( 0==pBt->nTransaction ){
51409 pBt->inTransaction = TRANS_NONE;
51413 /* Set the current transaction state to TRANS_NONE and unlock the
51414 ** pager if this call closed the only read or write transaction. */
51415 p->inTrans = TRANS_NONE;
51416 unlockBtreeIfUnused(pBt);
51419 btreeIntegrity(p);
51423 ** Commit the transaction currently in progress.
51425 ** This routine implements the second phase of a 2-phase commit. The
51426 ** sqlite3BtreeCommitPhaseOne() routine does the first phase and should
51427 ** be invoked prior to calling this routine. The sqlite3BtreeCommitPhaseOne()
51428 ** routine did all the work of writing information out to disk and flushing the
51429 ** contents so that they are written onto the disk platter. All this
51430 ** routine has to do is delete or truncate or zero the header in the
51431 ** the rollback journal (which causes the transaction to commit) and
51432 ** drop locks.
51434 ** Normally, if an error occurs while the pager layer is attempting to
51435 ** finalize the underlying journal file, this function returns an error and
51436 ** the upper layer will attempt a rollback. However, if the second argument
51437 ** is non-zero then this b-tree transaction is part of a multi-file
51438 ** transaction. In this case, the transaction has already been committed
51439 ** (by deleting a master journal file) and the caller will ignore this
51440 ** functions return code. So, even if an error occurs in the pager layer,
51441 ** reset the b-tree objects internal state to indicate that the write
51442 ** transaction has been closed. This is quite safe, as the pager will have
51443 ** transitioned to the error state.
51445 ** This will release the write lock on the database file. If there
51446 ** are no active cursors, it also releases the read lock.
51448 SQLITE_PRIVATE int sqlite3BtreeCommitPhaseTwo(Btree *p, int bCleanup){
51450 if( p->inTrans==TRANS_NONE ) return SQLITE_OK;
51451 sqlite3BtreeEnter(p);
51452 btreeIntegrity(p);
51454 /* If the handle has a write-transaction open, commit the shared-btrees
51455 ** transaction and set the shared state to TRANS_READ.
51457 if( p->inTrans==TRANS_WRITE ){
51458 int rc;
51459 BtShared *pBt = p->pBt;
51460 assert( pBt->inTransaction==TRANS_WRITE );
51461 assert( pBt->nTransaction>0 );
51462 rc = sqlite3PagerCommitPhaseTwo(pBt->pPager);
51463 if( rc!=SQLITE_OK && bCleanup==0 ){
51464 sqlite3BtreeLeave(p);
51465 return rc;
51467 pBt->inTransaction = TRANS_READ;
51470 btreeEndTransaction(p);
51471 sqlite3BtreeLeave(p);
51472 return SQLITE_OK;
51476 ** Do both phases of a commit.
51478 SQLITE_PRIVATE int sqlite3BtreeCommit(Btree *p){
51479 int rc;
51480 sqlite3BtreeEnter(p);
51481 rc = sqlite3BtreeCommitPhaseOne(p, 0);
51482 if( rc==SQLITE_OK ){
51483 rc = sqlite3BtreeCommitPhaseTwo(p, 0);
51485 sqlite3BtreeLeave(p);
51486 return rc;
51489 #ifndef NDEBUG
51491 ** Return the number of write-cursors open on this handle. This is for use
51492 ** in assert() expressions, so it is only compiled if NDEBUG is not
51493 ** defined.
51495 ** For the purposes of this routine, a write-cursor is any cursor that
51496 ** is capable of writing to the databse. That means the cursor was
51497 ** originally opened for writing and the cursor has not be disabled
51498 ** by having its state changed to CURSOR_FAULT.
51500 static int countWriteCursors(BtShared *pBt){
51501 BtCursor *pCur;
51502 int r = 0;
51503 for(pCur=pBt->pCursor; pCur; pCur=pCur->pNext){
51504 if( pCur->wrFlag && pCur->eState!=CURSOR_FAULT ) r++;
51506 return r;
51508 #endif
51511 ** This routine sets the state to CURSOR_FAULT and the error
51512 ** code to errCode for every cursor on BtShared that pBtree
51513 ** references.
51515 ** Every cursor is tripped, including cursors that belong
51516 ** to other database connections that happen to be sharing
51517 ** the cache with pBtree.
51519 ** This routine gets called when a rollback occurs.
51520 ** All cursors using the same cache must be tripped
51521 ** to prevent them from trying to use the btree after
51522 ** the rollback. The rollback may have deleted tables
51523 ** or moved root pages, so it is not sufficient to
51524 ** save the state of the cursor. The cursor must be
51525 ** invalidated.
51527 SQLITE_PRIVATE void sqlite3BtreeTripAllCursors(Btree *pBtree, int errCode){
51528 BtCursor *p;
51529 sqlite3BtreeEnter(pBtree);
51530 for(p=pBtree->pBt->pCursor; p; p=p->pNext){
51531 int i;
51532 sqlite3BtreeClearCursor(p);
51533 p->eState = CURSOR_FAULT;
51534 p->skipNext = errCode;
51535 for(i=0; i<=p->iPage; i++){
51536 releasePage(p->apPage[i]);
51537 p->apPage[i] = 0;
51540 sqlite3BtreeLeave(pBtree);
51544 ** Rollback the transaction in progress. All cursors will be
51545 ** invalided by this operation. Any attempt to use a cursor
51546 ** that was open at the beginning of this operation will result
51547 ** in an error.
51549 ** This will release the write lock on the database file. If there
51550 ** are no active cursors, it also releases the read lock.
51552 SQLITE_PRIVATE int sqlite3BtreeRollback(Btree *p){
51553 int rc;
51554 BtShared *pBt = p->pBt;
51555 MemPage *pPage1;
51557 sqlite3BtreeEnter(p);
51558 rc = saveAllCursors(pBt, 0, 0);
51559 #ifndef SQLITE_OMIT_SHARED_CACHE
51560 if( rc!=SQLITE_OK ){
51561 /* This is a horrible situation. An IO or malloc() error occurred whilst
51562 ** trying to save cursor positions. If this is an automatic rollback (as
51563 ** the result of a constraint, malloc() failure or IO error) then
51564 ** the cache may be internally inconsistent (not contain valid trees) so
51565 ** we cannot simply return the error to the caller. Instead, abort
51566 ** all queries that may be using any of the cursors that failed to save.
51568 sqlite3BtreeTripAllCursors(p, rc);
51570 #endif
51571 btreeIntegrity(p);
51573 if( p->inTrans==TRANS_WRITE ){
51574 int rc2;
51576 assert( TRANS_WRITE==pBt->inTransaction );
51577 rc2 = sqlite3PagerRollback(pBt->pPager);
51578 if( rc2!=SQLITE_OK ){
51579 rc = rc2;
51582 /* The rollback may have destroyed the pPage1->aData value. So
51583 ** call btreeGetPage() on page 1 again to make
51584 ** sure pPage1->aData is set correctly. */
51585 if( btreeGetPage(pBt, 1, &pPage1, 0)==SQLITE_OK ){
51586 int nPage = get4byte(28+(u8*)pPage1->aData);
51587 testcase( nPage==0 );
51588 if( nPage==0 ) sqlite3PagerPagecount(pBt->pPager, &nPage);
51589 testcase( pBt->nPage!=nPage );
51590 pBt->nPage = nPage;
51591 releasePage(pPage1);
51593 assert( countWriteCursors(pBt)==0 );
51594 pBt->inTransaction = TRANS_READ;
51597 btreeEndTransaction(p);
51598 sqlite3BtreeLeave(p);
51599 return rc;
51603 ** Start a statement subtransaction. The subtransaction can can be rolled
51604 ** back independently of the main transaction. You must start a transaction
51605 ** before starting a subtransaction. The subtransaction is ended automatically
51606 ** if the main transaction commits or rolls back.
51608 ** Statement subtransactions are used around individual SQL statements
51609 ** that are contained within a BEGIN...COMMIT block. If a constraint
51610 ** error occurs within the statement, the effect of that one statement
51611 ** can be rolled back without having to rollback the entire transaction.
51613 ** A statement sub-transaction is implemented as an anonymous savepoint. The
51614 ** value passed as the second parameter is the total number of savepoints,
51615 ** including the new anonymous savepoint, open on the B-Tree. i.e. if there
51616 ** are no active savepoints and no other statement-transactions open,
51617 ** iStatement is 1. This anonymous savepoint can be released or rolled back
51618 ** using the sqlite3BtreeSavepoint() function.
51620 SQLITE_PRIVATE int sqlite3BtreeBeginStmt(Btree *p, int iStatement){
51621 int rc;
51622 BtShared *pBt = p->pBt;
51623 sqlite3BtreeEnter(p);
51624 assert( p->inTrans==TRANS_WRITE );
51625 assert( pBt->readOnly==0 );
51626 assert( iStatement>0 );
51627 assert( iStatement>p->db->nSavepoint );
51628 assert( pBt->inTransaction==TRANS_WRITE );
51629 /* At the pager level, a statement transaction is a savepoint with
51630 ** an index greater than all savepoints created explicitly using
51631 ** SQL statements. It is illegal to open, release or rollback any
51632 ** such savepoints while the statement transaction savepoint is active.
51634 rc = sqlite3PagerOpenSavepoint(pBt->pPager, iStatement);
51635 sqlite3BtreeLeave(p);
51636 return rc;
51640 ** The second argument to this function, op, is always SAVEPOINT_ROLLBACK
51641 ** or SAVEPOINT_RELEASE. This function either releases or rolls back the
51642 ** savepoint identified by parameter iSavepoint, depending on the value
51643 ** of op.
51645 ** Normally, iSavepoint is greater than or equal to zero. However, if op is
51646 ** SAVEPOINT_ROLLBACK, then iSavepoint may also be -1. In this case the
51647 ** contents of the entire transaction are rolled back. This is different
51648 ** from a normal transaction rollback, as no locks are released and the
51649 ** transaction remains open.
51651 SQLITE_PRIVATE int sqlite3BtreeSavepoint(Btree *p, int op, int iSavepoint){
51652 int rc = SQLITE_OK;
51653 if( p && p->inTrans==TRANS_WRITE ){
51654 BtShared *pBt = p->pBt;
51655 assert( op==SAVEPOINT_RELEASE || op==SAVEPOINT_ROLLBACK );
51656 assert( iSavepoint>=0 || (iSavepoint==-1 && op==SAVEPOINT_ROLLBACK) );
51657 sqlite3BtreeEnter(p);
51658 rc = sqlite3PagerSavepoint(pBt->pPager, op, iSavepoint);
51659 if( rc==SQLITE_OK ){
51660 if( iSavepoint<0 && pBt->initiallyEmpty ) pBt->nPage = 0;
51661 rc = newDatabase(pBt);
51662 pBt->nPage = get4byte(28 + pBt->pPage1->aData);
51664 /* The database size was written into the offset 28 of the header
51665 ** when the transaction started, so we know that the value at offset
51666 ** 28 is nonzero. */
51667 assert( pBt->nPage>0 );
51669 sqlite3BtreeLeave(p);
51671 return rc;
51675 ** Create a new cursor for the BTree whose root is on the page
51676 ** iTable. If a read-only cursor is requested, it is assumed that
51677 ** the caller already has at least a read-only transaction open
51678 ** on the database already. If a write-cursor is requested, then
51679 ** the caller is assumed to have an open write transaction.
51681 ** If wrFlag==0, then the cursor can only be used for reading.
51682 ** If wrFlag==1, then the cursor can be used for reading or for
51683 ** writing if other conditions for writing are also met. These
51684 ** are the conditions that must be met in order for writing to
51685 ** be allowed:
51687 ** 1: The cursor must have been opened with wrFlag==1
51689 ** 2: Other database connections that share the same pager cache
51690 ** but which are not in the READ_UNCOMMITTED state may not have
51691 ** cursors open with wrFlag==0 on the same table. Otherwise
51692 ** the changes made by this write cursor would be visible to
51693 ** the read cursors in the other database connection.
51695 ** 3: The database must be writable (not on read-only media)
51697 ** 4: There must be an active transaction.
51699 ** No checking is done to make sure that page iTable really is the
51700 ** root page of a b-tree. If it is not, then the cursor acquired
51701 ** will not work correctly.
51703 ** It is assumed that the sqlite3BtreeCursorZero() has been called
51704 ** on pCur to initialize the memory space prior to invoking this routine.
51706 static int btreeCursor(
51707 Btree *p, /* The btree */
51708 int iTable, /* Root page of table to open */
51709 int wrFlag, /* 1 to write. 0 read-only */
51710 struct KeyInfo *pKeyInfo, /* First arg to comparison function */
51711 BtCursor *pCur /* Space for new cursor */
51713 BtShared *pBt = p->pBt; /* Shared b-tree handle */
51715 assert( sqlite3BtreeHoldsMutex(p) );
51716 assert( wrFlag==0 || wrFlag==1 );
51718 /* The following assert statements verify that if this is a sharable
51719 ** b-tree database, the connection is holding the required table locks,
51720 ** and that no other connection has any open cursor that conflicts with
51721 ** this lock. */
51722 assert( hasSharedCacheTableLock(p, iTable, pKeyInfo!=0, wrFlag+1) );
51723 assert( wrFlag==0 || !hasReadConflicts(p, iTable) );
51725 /* Assert that the caller has opened the required transaction. */
51726 assert( p->inTrans>TRANS_NONE );
51727 assert( wrFlag==0 || p->inTrans==TRANS_WRITE );
51728 assert( pBt->pPage1 && pBt->pPage1->aData );
51730 if( NEVER(wrFlag && pBt->readOnly) ){
51731 return SQLITE_READONLY;
51733 if( iTable==1 && btreePagecount(pBt)==0 ){
51734 assert( wrFlag==0 );
51735 iTable = 0;
51738 /* Now that no other errors can occur, finish filling in the BtCursor
51739 ** variables and link the cursor into the BtShared list. */
51740 pCur->pgnoRoot = (Pgno)iTable;
51741 pCur->iPage = -1;
51742 pCur->pKeyInfo = pKeyInfo;
51743 pCur->pBtree = p;
51744 pCur->pBt = pBt;
51745 pCur->wrFlag = (u8)wrFlag;
51746 pCur->pNext = pBt->pCursor;
51747 if( pCur->pNext ){
51748 pCur->pNext->pPrev = pCur;
51750 pBt->pCursor = pCur;
51751 pCur->eState = CURSOR_INVALID;
51752 pCur->cachedRowid = 0;
51753 return SQLITE_OK;
51755 SQLITE_PRIVATE int sqlite3BtreeCursor(
51756 Btree *p, /* The btree */
51757 int iTable, /* Root page of table to open */
51758 int wrFlag, /* 1 to write. 0 read-only */
51759 struct KeyInfo *pKeyInfo, /* First arg to xCompare() */
51760 BtCursor *pCur /* Write new cursor here */
51762 int rc;
51763 sqlite3BtreeEnter(p);
51764 rc = btreeCursor(p, iTable, wrFlag, pKeyInfo, pCur);
51765 sqlite3BtreeLeave(p);
51766 return rc;
51770 ** Return the size of a BtCursor object in bytes.
51772 ** This interfaces is needed so that users of cursors can preallocate
51773 ** sufficient storage to hold a cursor. The BtCursor object is opaque
51774 ** to users so they cannot do the sizeof() themselves - they must call
51775 ** this routine.
51777 SQLITE_PRIVATE int sqlite3BtreeCursorSize(void){
51778 return ROUND8(sizeof(BtCursor));
51782 ** Initialize memory that will be converted into a BtCursor object.
51784 ** The simple approach here would be to memset() the entire object
51785 ** to zero. But it turns out that the apPage[] and aiIdx[] arrays
51786 ** do not need to be zeroed and they are large, so we can save a lot
51787 ** of run-time by skipping the initialization of those elements.
51789 SQLITE_PRIVATE void sqlite3BtreeCursorZero(BtCursor *p){
51790 memset(p, 0, offsetof(BtCursor, iPage));
51794 ** Set the cached rowid value of every cursor in the same database file
51795 ** as pCur and having the same root page number as pCur. The value is
51796 ** set to iRowid.
51798 ** Only positive rowid values are considered valid for this cache.
51799 ** The cache is initialized to zero, indicating an invalid cache.
51800 ** A btree will work fine with zero or negative rowids. We just cannot
51801 ** cache zero or negative rowids, which means tables that use zero or
51802 ** negative rowids might run a little slower. But in practice, zero
51803 ** or negative rowids are very uncommon so this should not be a problem.
51805 SQLITE_PRIVATE void sqlite3BtreeSetCachedRowid(BtCursor *pCur, sqlite3_int64 iRowid){
51806 BtCursor *p;
51807 for(p=pCur->pBt->pCursor; p; p=p->pNext){
51808 if( p->pgnoRoot==pCur->pgnoRoot ) p->cachedRowid = iRowid;
51810 assert( pCur->cachedRowid==iRowid );
51814 ** Return the cached rowid for the given cursor. A negative or zero
51815 ** return value indicates that the rowid cache is invalid and should be
51816 ** ignored. If the rowid cache has never before been set, then a
51817 ** zero is returned.
51819 SQLITE_PRIVATE sqlite3_int64 sqlite3BtreeGetCachedRowid(BtCursor *pCur){
51820 return pCur->cachedRowid;
51824 ** Close a cursor. The read lock on the database file is released
51825 ** when the last cursor is closed.
51827 SQLITE_PRIVATE int sqlite3BtreeCloseCursor(BtCursor *pCur){
51828 Btree *pBtree = pCur->pBtree;
51829 if( pBtree ){
51830 int i;
51831 BtShared *pBt = pCur->pBt;
51832 sqlite3BtreeEnter(pBtree);
51833 sqlite3BtreeClearCursor(pCur);
51834 if( pCur->pPrev ){
51835 pCur->pPrev->pNext = pCur->pNext;
51836 }else{
51837 pBt->pCursor = pCur->pNext;
51839 if( pCur->pNext ){
51840 pCur->pNext->pPrev = pCur->pPrev;
51842 for(i=0; i<=pCur->iPage; i++){
51843 releasePage(pCur->apPage[i]);
51845 unlockBtreeIfUnused(pBt);
51846 invalidateOverflowCache(pCur);
51847 /* sqlite3_free(pCur); */
51848 sqlite3BtreeLeave(pBtree);
51850 return SQLITE_OK;
51854 ** Make sure the BtCursor* given in the argument has a valid
51855 ** BtCursor.info structure. If it is not already valid, call
51856 ** btreeParseCell() to fill it in.
51858 ** BtCursor.info is a cache of the information in the current cell.
51859 ** Using this cache reduces the number of calls to btreeParseCell().
51861 ** 2007-06-25: There is a bug in some versions of MSVC that cause the
51862 ** compiler to crash when getCellInfo() is implemented as a macro.
51863 ** But there is a measureable speed advantage to using the macro on gcc
51864 ** (when less compiler optimizations like -Os or -O0 are used and the
51865 ** compiler is not doing agressive inlining.) So we use a real function
51866 ** for MSVC and a macro for everything else. Ticket #2457.
51868 #ifndef NDEBUG
51869 static void assertCellInfo(BtCursor *pCur){
51870 CellInfo info;
51871 int iPage = pCur->iPage;
51872 memset(&info, 0, sizeof(info));
51873 btreeParseCell(pCur->apPage[iPage], pCur->aiIdx[iPage], &info);
51874 assert( memcmp(&info, &pCur->info, sizeof(info))==0 );
51876 #else
51877 #define assertCellInfo(x)
51878 #endif
51879 #ifdef _MSC_VER
51880 /* Use a real function in MSVC to work around bugs in that compiler. */
51881 static void getCellInfo(BtCursor *pCur){
51882 if( pCur->info.nSize==0 ){
51883 int iPage = pCur->iPage;
51884 btreeParseCell(pCur->apPage[iPage],pCur->aiIdx[iPage],&pCur->info);
51885 pCur->validNKey = 1;
51886 }else{
51887 assertCellInfo(pCur);
51890 #else /* if not _MSC_VER */
51891 /* Use a macro in all other compilers so that the function is inlined */
51892 #define getCellInfo(pCur) \
51893 if( pCur->info.nSize==0 ){ \
51894 int iPage = pCur->iPage; \
51895 btreeParseCell(pCur->apPage[iPage],pCur->aiIdx[iPage],&pCur->info); \
51896 pCur->validNKey = 1; \
51897 }else{ \
51898 assertCellInfo(pCur); \
51900 #endif /* _MSC_VER */
51902 #ifndef NDEBUG /* The next routine used only within assert() statements */
51904 ** Return true if the given BtCursor is valid. A valid cursor is one
51905 ** that is currently pointing to a row in a (non-empty) table.
51906 ** This is a verification routine is used only within assert() statements.
51908 SQLITE_PRIVATE int sqlite3BtreeCursorIsValid(BtCursor *pCur){
51909 return pCur && pCur->eState==CURSOR_VALID;
51911 #endif /* NDEBUG */
51914 ** Set *pSize to the size of the buffer needed to hold the value of
51915 ** the key for the current entry. If the cursor is not pointing
51916 ** to a valid entry, *pSize is set to 0.
51918 ** For a table with the INTKEY flag set, this routine returns the key
51919 ** itself, not the number of bytes in the key.
51921 ** The caller must position the cursor prior to invoking this routine.
51923 ** This routine cannot fail. It always returns SQLITE_OK.
51925 SQLITE_PRIVATE int sqlite3BtreeKeySize(BtCursor *pCur, i64 *pSize){
51926 assert( cursorHoldsMutex(pCur) );
51927 assert( pCur->eState==CURSOR_INVALID || pCur->eState==CURSOR_VALID );
51928 if( pCur->eState!=CURSOR_VALID ){
51929 *pSize = 0;
51930 }else{
51931 getCellInfo(pCur);
51932 *pSize = pCur->info.nKey;
51934 return SQLITE_OK;
51938 ** Set *pSize to the number of bytes of data in the entry the
51939 ** cursor currently points to.
51941 ** The caller must guarantee that the cursor is pointing to a non-NULL
51942 ** valid entry. In other words, the calling procedure must guarantee
51943 ** that the cursor has Cursor.eState==CURSOR_VALID.
51945 ** Failure is not possible. This function always returns SQLITE_OK.
51946 ** It might just as well be a procedure (returning void) but we continue
51947 ** to return an integer result code for historical reasons.
51949 SQLITE_PRIVATE int sqlite3BtreeDataSize(BtCursor *pCur, u32 *pSize){
51950 assert( cursorHoldsMutex(pCur) );
51951 assert( pCur->eState==CURSOR_VALID );
51952 getCellInfo(pCur);
51953 *pSize = pCur->info.nData;
51954 return SQLITE_OK;
51958 ** Given the page number of an overflow page in the database (parameter
51959 ** ovfl), this function finds the page number of the next page in the
51960 ** linked list of overflow pages. If possible, it uses the auto-vacuum
51961 ** pointer-map data instead of reading the content of page ovfl to do so.
51963 ** If an error occurs an SQLite error code is returned. Otherwise:
51965 ** The page number of the next overflow page in the linked list is
51966 ** written to *pPgnoNext. If page ovfl is the last page in its linked
51967 ** list, *pPgnoNext is set to zero.
51969 ** If ppPage is not NULL, and a reference to the MemPage object corresponding
51970 ** to page number pOvfl was obtained, then *ppPage is set to point to that
51971 ** reference. It is the responsibility of the caller to call releasePage()
51972 ** on *ppPage to free the reference. In no reference was obtained (because
51973 ** the pointer-map was used to obtain the value for *pPgnoNext), then
51974 ** *ppPage is set to zero.
51976 static int getOverflowPage(
51977 BtShared *pBt, /* The database file */
51978 Pgno ovfl, /* Current overflow page number */
51979 MemPage **ppPage, /* OUT: MemPage handle (may be NULL) */
51980 Pgno *pPgnoNext /* OUT: Next overflow page number */
51982 Pgno next = 0;
51983 MemPage *pPage = 0;
51984 int rc = SQLITE_OK;
51986 assert( sqlite3_mutex_held(pBt->mutex) );
51987 assert(pPgnoNext);
51989 #ifndef SQLITE_OMIT_AUTOVACUUM
51990 /* Try to find the next page in the overflow list using the
51991 ** autovacuum pointer-map pages. Guess that the next page in
51992 ** the overflow list is page number (ovfl+1). If that guess turns
51993 ** out to be wrong, fall back to loading the data of page
51994 ** number ovfl to determine the next page number.
51996 if( pBt->autoVacuum ){
51997 Pgno pgno;
51998 Pgno iGuess = ovfl+1;
51999 u8 eType;
52001 while( PTRMAP_ISPAGE(pBt, iGuess) || iGuess==PENDING_BYTE_PAGE(pBt) ){
52002 iGuess++;
52005 if( iGuess<=btreePagecount(pBt) ){
52006 rc = ptrmapGet(pBt, iGuess, &eType, &pgno);
52007 if( rc==SQLITE_OK && eType==PTRMAP_OVERFLOW2 && pgno==ovfl ){
52008 next = iGuess;
52009 rc = SQLITE_DONE;
52013 #endif
52015 assert( next==0 || rc==SQLITE_DONE );
52016 if( rc==SQLITE_OK ){
52017 rc = btreeGetPage(pBt, ovfl, &pPage, 0);
52018 assert( rc==SQLITE_OK || pPage==0 );
52019 if( rc==SQLITE_OK ){
52020 next = get4byte(pPage->aData);
52024 *pPgnoNext = next;
52025 if( ppPage ){
52026 *ppPage = pPage;
52027 }else{
52028 releasePage(pPage);
52030 return (rc==SQLITE_DONE ? SQLITE_OK : rc);
52034 ** Copy data from a buffer to a page, or from a page to a buffer.
52036 ** pPayload is a pointer to data stored on database page pDbPage.
52037 ** If argument eOp is false, then nByte bytes of data are copied
52038 ** from pPayload to the buffer pointed at by pBuf. If eOp is true,
52039 ** then sqlite3PagerWrite() is called on pDbPage and nByte bytes
52040 ** of data are copied from the buffer pBuf to pPayload.
52042 ** SQLITE_OK is returned on success, otherwise an error code.
52044 static int copyPayload(
52045 void *pPayload, /* Pointer to page data */
52046 void *pBuf, /* Pointer to buffer */
52047 int nByte, /* Number of bytes to copy */
52048 int eOp, /* 0 -> copy from page, 1 -> copy to page */
52049 DbPage *pDbPage /* Page containing pPayload */
52051 if( eOp ){
52052 /* Copy data from buffer to page (a write operation) */
52053 int rc = sqlite3PagerWrite(pDbPage);
52054 if( rc!=SQLITE_OK ){
52055 return rc;
52057 memcpy(pPayload, pBuf, nByte);
52058 }else{
52059 /* Copy data from page to buffer (a read operation) */
52060 memcpy(pBuf, pPayload, nByte);
52062 return SQLITE_OK;
52066 ** This function is used to read or overwrite payload information
52067 ** for the entry that the pCur cursor is pointing to. If the eOp
52068 ** parameter is 0, this is a read operation (data copied into
52069 ** buffer pBuf). If it is non-zero, a write (data copied from
52070 ** buffer pBuf).
52072 ** A total of "amt" bytes are read or written beginning at "offset".
52073 ** Data is read to or from the buffer pBuf.
52075 ** The content being read or written might appear on the main page
52076 ** or be scattered out on multiple overflow pages.
52078 ** If the BtCursor.isIncrblobHandle flag is set, and the current
52079 ** cursor entry uses one or more overflow pages, this function
52080 ** allocates space for and lazily popluates the overflow page-list
52081 ** cache array (BtCursor.aOverflow). Subsequent calls use this
52082 ** cache to make seeking to the supplied offset more efficient.
52084 ** Once an overflow page-list cache has been allocated, it may be
52085 ** invalidated if some other cursor writes to the same table, or if
52086 ** the cursor is moved to a different row. Additionally, in auto-vacuum
52087 ** mode, the following events may invalidate an overflow page-list cache.
52089 ** * An incremental vacuum,
52090 ** * A commit in auto_vacuum="full" mode,
52091 ** * Creating a table (may require moving an overflow page).
52093 static int accessPayload(
52094 BtCursor *pCur, /* Cursor pointing to entry to read from */
52095 u32 offset, /* Begin reading this far into payload */
52096 u32 amt, /* Read this many bytes */
52097 unsigned char *pBuf, /* Write the bytes into this buffer */
52098 int eOp /* zero to read. non-zero to write. */
52100 unsigned char *aPayload;
52101 int rc = SQLITE_OK;
52102 u32 nKey;
52103 int iIdx = 0;
52104 MemPage *pPage = pCur->apPage[pCur->iPage]; /* Btree page of current entry */
52105 BtShared *pBt = pCur->pBt; /* Btree this cursor belongs to */
52107 assert( pPage );
52108 assert( pCur->eState==CURSOR_VALID );
52109 assert( pCur->aiIdx[pCur->iPage]<pPage->nCell );
52110 assert( cursorHoldsMutex(pCur) );
52112 getCellInfo(pCur);
52113 aPayload = pCur->info.pCell + pCur->info.nHeader;
52114 nKey = (pPage->intKey ? 0 : (int)pCur->info.nKey);
52116 if( NEVER(offset+amt > nKey+pCur->info.nData)
52117 || &aPayload[pCur->info.nLocal] > &pPage->aData[pBt->usableSize]
52119 /* Trying to read or write past the end of the data is an error */
52120 return SQLITE_CORRUPT_BKPT;
52123 /* Check if data must be read/written to/from the btree page itself. */
52124 if( offset<pCur->info.nLocal ){
52125 int a = amt;
52126 if( a+offset>pCur->info.nLocal ){
52127 a = pCur->info.nLocal - offset;
52129 rc = copyPayload(&aPayload[offset], pBuf, a, eOp, pPage->pDbPage);
52130 offset = 0;
52131 pBuf += a;
52132 amt -= a;
52133 }else{
52134 offset -= pCur->info.nLocal;
52137 if( rc==SQLITE_OK && amt>0 ){
52138 const u32 ovflSize = pBt->usableSize - 4; /* Bytes content per ovfl page */
52139 Pgno nextPage;
52141 nextPage = get4byte(&aPayload[pCur->info.nLocal]);
52143 #ifndef SQLITE_OMIT_INCRBLOB
52144 /* If the isIncrblobHandle flag is set and the BtCursor.aOverflow[]
52145 ** has not been allocated, allocate it now. The array is sized at
52146 ** one entry for each overflow page in the overflow chain. The
52147 ** page number of the first overflow page is stored in aOverflow[0],
52148 ** etc. A value of 0 in the aOverflow[] array means "not yet known"
52149 ** (the cache is lazily populated).
52151 if( pCur->isIncrblobHandle && !pCur->aOverflow ){
52152 int nOvfl = (pCur->info.nPayload-pCur->info.nLocal+ovflSize-1)/ovflSize;
52153 pCur->aOverflow = (Pgno *)sqlite3MallocZero(sizeof(Pgno)*nOvfl);
52154 /* nOvfl is always positive. If it were zero, fetchPayload would have
52155 ** been used instead of this routine. */
52156 if( ALWAYS(nOvfl) && !pCur->aOverflow ){
52157 rc = SQLITE_NOMEM;
52161 /* If the overflow page-list cache has been allocated and the
52162 ** entry for the first required overflow page is valid, skip
52163 ** directly to it.
52165 if( pCur->aOverflow && pCur->aOverflow[offset/ovflSize] ){
52166 iIdx = (offset/ovflSize);
52167 nextPage = pCur->aOverflow[iIdx];
52168 offset = (offset%ovflSize);
52170 #endif
52172 for( ; rc==SQLITE_OK && amt>0 && nextPage; iIdx++){
52174 #ifndef SQLITE_OMIT_INCRBLOB
52175 /* If required, populate the overflow page-list cache. */
52176 if( pCur->aOverflow ){
52177 assert(!pCur->aOverflow[iIdx] || pCur->aOverflow[iIdx]==nextPage);
52178 pCur->aOverflow[iIdx] = nextPage;
52180 #endif
52182 if( offset>=ovflSize ){
52183 /* The only reason to read this page is to obtain the page
52184 ** number for the next page in the overflow chain. The page
52185 ** data is not required. So first try to lookup the overflow
52186 ** page-list cache, if any, then fall back to the getOverflowPage()
52187 ** function.
52189 #ifndef SQLITE_OMIT_INCRBLOB
52190 if( pCur->aOverflow && pCur->aOverflow[iIdx+1] ){
52191 nextPage = pCur->aOverflow[iIdx+1];
52192 } else
52193 #endif
52194 rc = getOverflowPage(pBt, nextPage, 0, &nextPage);
52195 offset -= ovflSize;
52196 }else{
52197 /* Need to read this page properly. It contains some of the
52198 ** range of data that is being read (eOp==0) or written (eOp!=0).
52200 DbPage *pDbPage;
52201 int a = amt;
52202 rc = sqlite3PagerGet(pBt->pPager, nextPage, &pDbPage);
52203 if( rc==SQLITE_OK ){
52204 aPayload = sqlite3PagerGetData(pDbPage);
52205 nextPage = get4byte(aPayload);
52206 if( a + offset > ovflSize ){
52207 a = ovflSize - offset;
52209 rc = copyPayload(&aPayload[offset+4], pBuf, a, eOp, pDbPage);
52210 sqlite3PagerUnref(pDbPage);
52211 offset = 0;
52212 amt -= a;
52213 pBuf += a;
52219 if( rc==SQLITE_OK && amt>0 ){
52220 return SQLITE_CORRUPT_BKPT;
52222 return rc;
52226 ** Read part of the key associated with cursor pCur. Exactly
52227 ** "amt" bytes will be transfered into pBuf[]. The transfer
52228 ** begins at "offset".
52230 ** The caller must ensure that pCur is pointing to a valid row
52231 ** in the table.
52233 ** Return SQLITE_OK on success or an error code if anything goes
52234 ** wrong. An error is returned if "offset+amt" is larger than
52235 ** the available payload.
52237 SQLITE_PRIVATE int sqlite3BtreeKey(BtCursor *pCur, u32 offset, u32 amt, void *pBuf){
52238 assert( cursorHoldsMutex(pCur) );
52239 assert( pCur->eState==CURSOR_VALID );
52240 assert( pCur->iPage>=0 && pCur->apPage[pCur->iPage] );
52241 assert( pCur->aiIdx[pCur->iPage]<pCur->apPage[pCur->iPage]->nCell );
52242 return accessPayload(pCur, offset, amt, (unsigned char*)pBuf, 0);
52246 ** Read part of the data associated with cursor pCur. Exactly
52247 ** "amt" bytes will be transfered into pBuf[]. The transfer
52248 ** begins at "offset".
52250 ** Return SQLITE_OK on success or an error code if anything goes
52251 ** wrong. An error is returned if "offset+amt" is larger than
52252 ** the available payload.
52254 SQLITE_PRIVATE int sqlite3BtreeData(BtCursor *pCur, u32 offset, u32 amt, void *pBuf){
52255 int rc;
52257 #ifndef SQLITE_OMIT_INCRBLOB
52258 if ( pCur->eState==CURSOR_INVALID ){
52259 return SQLITE_ABORT;
52261 #endif
52263 assert( cursorHoldsMutex(pCur) );
52264 rc = restoreCursorPosition(pCur);
52265 if( rc==SQLITE_OK ){
52266 assert( pCur->eState==CURSOR_VALID );
52267 assert( pCur->iPage>=0 && pCur->apPage[pCur->iPage] );
52268 assert( pCur->aiIdx[pCur->iPage]<pCur->apPage[pCur->iPage]->nCell );
52269 rc = accessPayload(pCur, offset, amt, pBuf, 0);
52271 return rc;
52275 ** Return a pointer to payload information from the entry that the
52276 ** pCur cursor is pointing to. The pointer is to the beginning of
52277 ** the key if skipKey==0 and it points to the beginning of data if
52278 ** skipKey==1. The number of bytes of available key/data is written
52279 ** into *pAmt. If *pAmt==0, then the value returned will not be
52280 ** a valid pointer.
52282 ** This routine is an optimization. It is common for the entire key
52283 ** and data to fit on the local page and for there to be no overflow
52284 ** pages. When that is so, this routine can be used to access the
52285 ** key and data without making a copy. If the key and/or data spills
52286 ** onto overflow pages, then accessPayload() must be used to reassemble
52287 ** the key/data and copy it into a preallocated buffer.
52289 ** The pointer returned by this routine looks directly into the cached
52290 ** page of the database. The data might change or move the next time
52291 ** any btree routine is called.
52293 static const unsigned char *fetchPayload(
52294 BtCursor *pCur, /* Cursor pointing to entry to read from */
52295 int *pAmt, /* Write the number of available bytes here */
52296 int skipKey /* read beginning at data if this is true */
52298 unsigned char *aPayload;
52299 MemPage *pPage;
52300 u32 nKey;
52301 u32 nLocal;
52303 assert( pCur!=0 && pCur->iPage>=0 && pCur->apPage[pCur->iPage]);
52304 assert( pCur->eState==CURSOR_VALID );
52305 assert( cursorHoldsMutex(pCur) );
52306 pPage = pCur->apPage[pCur->iPage];
52307 assert( pCur->aiIdx[pCur->iPage]<pPage->nCell );
52308 if( NEVER(pCur->info.nSize==0) ){
52309 btreeParseCell(pCur->apPage[pCur->iPage], pCur->aiIdx[pCur->iPage],
52310 &pCur->info);
52312 aPayload = pCur->info.pCell;
52313 aPayload += pCur->info.nHeader;
52314 if( pPage->intKey ){
52315 nKey = 0;
52316 }else{
52317 nKey = (int)pCur->info.nKey;
52319 if( skipKey ){
52320 aPayload += nKey;
52321 nLocal = pCur->info.nLocal - nKey;
52322 }else{
52323 nLocal = pCur->info.nLocal;
52324 assert( nLocal<=nKey );
52326 *pAmt = nLocal;
52327 return aPayload;
52332 ** For the entry that cursor pCur is point to, return as
52333 ** many bytes of the key or data as are available on the local
52334 ** b-tree page. Write the number of available bytes into *pAmt.
52336 ** The pointer returned is ephemeral. The key/data may move
52337 ** or be destroyed on the next call to any Btree routine,
52338 ** including calls from other threads against the same cache.
52339 ** Hence, a mutex on the BtShared should be held prior to calling
52340 ** this routine.
52342 ** These routines is used to get quick access to key and data
52343 ** in the common case where no overflow pages are used.
52345 SQLITE_PRIVATE const void *sqlite3BtreeKeyFetch(BtCursor *pCur, int *pAmt){
52346 const void *p = 0;
52347 assert( sqlite3_mutex_held(pCur->pBtree->db->mutex) );
52348 assert( cursorHoldsMutex(pCur) );
52349 if( ALWAYS(pCur->eState==CURSOR_VALID) ){
52350 p = (const void*)fetchPayload(pCur, pAmt, 0);
52352 return p;
52354 SQLITE_PRIVATE const void *sqlite3BtreeDataFetch(BtCursor *pCur, int *pAmt){
52355 const void *p = 0;
52356 assert( sqlite3_mutex_held(pCur->pBtree->db->mutex) );
52357 assert( cursorHoldsMutex(pCur) );
52358 if( ALWAYS(pCur->eState==CURSOR_VALID) ){
52359 p = (const void*)fetchPayload(pCur, pAmt, 1);
52361 return p;
52366 ** Move the cursor down to a new child page. The newPgno argument is the
52367 ** page number of the child page to move to.
52369 ** This function returns SQLITE_CORRUPT if the page-header flags field of
52370 ** the new child page does not match the flags field of the parent (i.e.
52371 ** if an intkey page appears to be the parent of a non-intkey page, or
52372 ** vice-versa).
52374 static int moveToChild(BtCursor *pCur, u32 newPgno){
52375 int rc;
52376 int i = pCur->iPage;
52377 MemPage *pNewPage;
52378 BtShared *pBt = pCur->pBt;
52380 assert( cursorHoldsMutex(pCur) );
52381 assert( pCur->eState==CURSOR_VALID );
52382 assert( pCur->iPage<BTCURSOR_MAX_DEPTH );
52383 if( pCur->iPage>=(BTCURSOR_MAX_DEPTH-1) ){
52384 return SQLITE_CORRUPT_BKPT;
52386 rc = getAndInitPage(pBt, newPgno, &pNewPage);
52387 if( rc ) return rc;
52388 pCur->apPage[i+1] = pNewPage;
52389 pCur->aiIdx[i+1] = 0;
52390 pCur->iPage++;
52392 pCur->info.nSize = 0;
52393 pCur->validNKey = 0;
52394 if( pNewPage->nCell<1 || pNewPage->intKey!=pCur->apPage[i]->intKey ){
52395 return SQLITE_CORRUPT_BKPT;
52397 return SQLITE_OK;
52400 #ifndef NDEBUG
52402 ** Page pParent is an internal (non-leaf) tree page. This function
52403 ** asserts that page number iChild is the left-child if the iIdx'th
52404 ** cell in page pParent. Or, if iIdx is equal to the total number of
52405 ** cells in pParent, that page number iChild is the right-child of
52406 ** the page.
52408 static void assertParentIndex(MemPage *pParent, int iIdx, Pgno iChild){
52409 assert( iIdx<=pParent->nCell );
52410 if( iIdx==pParent->nCell ){
52411 assert( get4byte(&pParent->aData[pParent->hdrOffset+8])==iChild );
52412 }else{
52413 assert( get4byte(findCell(pParent, iIdx))==iChild );
52416 #else
52417 # define assertParentIndex(x,y,z)
52418 #endif
52421 ** Move the cursor up to the parent page.
52423 ** pCur->idx is set to the cell index that contains the pointer
52424 ** to the page we are coming from. If we are coming from the
52425 ** right-most child page then pCur->idx is set to one more than
52426 ** the largest cell index.
52428 static void moveToParent(BtCursor *pCur){
52429 assert( cursorHoldsMutex(pCur) );
52430 assert( pCur->eState==CURSOR_VALID );
52431 assert( pCur->iPage>0 );
52432 assert( pCur->apPage[pCur->iPage] );
52433 assertParentIndex(
52434 pCur->apPage[pCur->iPage-1],
52435 pCur->aiIdx[pCur->iPage-1],
52436 pCur->apPage[pCur->iPage]->pgno
52438 releasePage(pCur->apPage[pCur->iPage]);
52439 pCur->iPage--;
52440 pCur->info.nSize = 0;
52441 pCur->validNKey = 0;
52445 ** Move the cursor to point to the root page of its b-tree structure.
52447 ** If the table has a virtual root page, then the cursor is moved to point
52448 ** to the virtual root page instead of the actual root page. A table has a
52449 ** virtual root page when the actual root page contains no cells and a
52450 ** single child page. This can only happen with the table rooted at page 1.
52452 ** If the b-tree structure is empty, the cursor state is set to
52453 ** CURSOR_INVALID. Otherwise, the cursor is set to point to the first
52454 ** cell located on the root (or virtual root) page and the cursor state
52455 ** is set to CURSOR_VALID.
52457 ** If this function returns successfully, it may be assumed that the
52458 ** page-header flags indicate that the [virtual] root-page is the expected
52459 ** kind of b-tree page (i.e. if when opening the cursor the caller did not
52460 ** specify a KeyInfo structure the flags byte is set to 0x05 or 0x0D,
52461 ** indicating a table b-tree, or if the caller did specify a KeyInfo
52462 ** structure the flags byte is set to 0x02 or 0x0A, indicating an index
52463 ** b-tree).
52465 static int moveToRoot(BtCursor *pCur){
52466 MemPage *pRoot;
52467 int rc = SQLITE_OK;
52468 Btree *p = pCur->pBtree;
52469 BtShared *pBt = p->pBt;
52471 assert( cursorHoldsMutex(pCur) );
52472 assert( CURSOR_INVALID < CURSOR_REQUIRESEEK );
52473 assert( CURSOR_VALID < CURSOR_REQUIRESEEK );
52474 assert( CURSOR_FAULT > CURSOR_REQUIRESEEK );
52475 if( pCur->eState>=CURSOR_REQUIRESEEK ){
52476 if( pCur->eState==CURSOR_FAULT ){
52477 assert( pCur->skipNext!=SQLITE_OK );
52478 return pCur->skipNext;
52480 sqlite3BtreeClearCursor(pCur);
52483 if( pCur->iPage>=0 ){
52484 int i;
52485 for(i=1; i<=pCur->iPage; i++){
52486 releasePage(pCur->apPage[i]);
52488 pCur->iPage = 0;
52489 }else if( pCur->pgnoRoot==0 ){
52490 pCur->eState = CURSOR_INVALID;
52491 return SQLITE_OK;
52492 }else{
52493 rc = getAndInitPage(pBt, pCur->pgnoRoot, &pCur->apPage[0]);
52494 if( rc!=SQLITE_OK ){
52495 pCur->eState = CURSOR_INVALID;
52496 return rc;
52498 pCur->iPage = 0;
52500 /* If pCur->pKeyInfo is not NULL, then the caller that opened this cursor
52501 ** expected to open it on an index b-tree. Otherwise, if pKeyInfo is
52502 ** NULL, the caller expects a table b-tree. If this is not the case,
52503 ** return an SQLITE_CORRUPT error. */
52504 assert( pCur->apPage[0]->intKey==1 || pCur->apPage[0]->intKey==0 );
52505 if( (pCur->pKeyInfo==0)!=pCur->apPage[0]->intKey ){
52506 return SQLITE_CORRUPT_BKPT;
52510 /* Assert that the root page is of the correct type. This must be the
52511 ** case as the call to this function that loaded the root-page (either
52512 ** this call or a previous invocation) would have detected corruption
52513 ** if the assumption were not true, and it is not possible for the flags
52514 ** byte to have been modified while this cursor is holding a reference
52515 ** to the page. */
52516 pRoot = pCur->apPage[0];
52517 assert( pRoot->pgno==pCur->pgnoRoot );
52518 assert( pRoot->isInit && (pCur->pKeyInfo==0)==pRoot->intKey );
52520 pCur->aiIdx[0] = 0;
52521 pCur->info.nSize = 0;
52522 pCur->atLast = 0;
52523 pCur->validNKey = 0;
52525 if( pRoot->nCell==0 && !pRoot->leaf ){
52526 Pgno subpage;
52527 if( pRoot->pgno!=1 ) return SQLITE_CORRUPT_BKPT;
52528 subpage = get4byte(&pRoot->aData[pRoot->hdrOffset+8]);
52529 pCur->eState = CURSOR_VALID;
52530 rc = moveToChild(pCur, subpage);
52531 }else{
52532 pCur->eState = ((pRoot->nCell>0)?CURSOR_VALID:CURSOR_INVALID);
52534 return rc;
52538 ** Move the cursor down to the left-most leaf entry beneath the
52539 ** entry to which it is currently pointing.
52541 ** The left-most leaf is the one with the smallest key - the first
52542 ** in ascending order.
52544 static int moveToLeftmost(BtCursor *pCur){
52545 Pgno pgno;
52546 int rc = SQLITE_OK;
52547 MemPage *pPage;
52549 assert( cursorHoldsMutex(pCur) );
52550 assert( pCur->eState==CURSOR_VALID );
52551 while( rc==SQLITE_OK && !(pPage = pCur->apPage[pCur->iPage])->leaf ){
52552 assert( pCur->aiIdx[pCur->iPage]<pPage->nCell );
52553 pgno = get4byte(findCell(pPage, pCur->aiIdx[pCur->iPage]));
52554 rc = moveToChild(pCur, pgno);
52556 return rc;
52560 ** Move the cursor down to the right-most leaf entry beneath the
52561 ** page to which it is currently pointing. Notice the difference
52562 ** between moveToLeftmost() and moveToRightmost(). moveToLeftmost()
52563 ** finds the left-most entry beneath the *entry* whereas moveToRightmost()
52564 ** finds the right-most entry beneath the *page*.
52566 ** The right-most entry is the one with the largest key - the last
52567 ** key in ascending order.
52569 static int moveToRightmost(BtCursor *pCur){
52570 Pgno pgno;
52571 int rc = SQLITE_OK;
52572 MemPage *pPage = 0;
52574 assert( cursorHoldsMutex(pCur) );
52575 assert( pCur->eState==CURSOR_VALID );
52576 while( rc==SQLITE_OK && !(pPage = pCur->apPage[pCur->iPage])->leaf ){
52577 pgno = get4byte(&pPage->aData[pPage->hdrOffset+8]);
52578 pCur->aiIdx[pCur->iPage] = pPage->nCell;
52579 rc = moveToChild(pCur, pgno);
52581 if( rc==SQLITE_OK ){
52582 pCur->aiIdx[pCur->iPage] = pPage->nCell-1;
52583 pCur->info.nSize = 0;
52584 pCur->validNKey = 0;
52586 return rc;
52589 /* Move the cursor to the first entry in the table. Return SQLITE_OK
52590 ** on success. Set *pRes to 0 if the cursor actually points to something
52591 ** or set *pRes to 1 if the table is empty.
52593 SQLITE_PRIVATE int sqlite3BtreeFirst(BtCursor *pCur, int *pRes){
52594 int rc;
52596 assert( cursorHoldsMutex(pCur) );
52597 assert( sqlite3_mutex_held(pCur->pBtree->db->mutex) );
52598 rc = moveToRoot(pCur);
52599 if( rc==SQLITE_OK ){
52600 if( pCur->eState==CURSOR_INVALID ){
52601 assert( pCur->pgnoRoot==0 || pCur->apPage[pCur->iPage]->nCell==0 );
52602 *pRes = 1;
52603 }else{
52604 assert( pCur->apPage[pCur->iPage]->nCell>0 );
52605 *pRes = 0;
52606 rc = moveToLeftmost(pCur);
52609 return rc;
52612 /* Move the cursor to the last entry in the table. Return SQLITE_OK
52613 ** on success. Set *pRes to 0 if the cursor actually points to something
52614 ** or set *pRes to 1 if the table is empty.
52616 SQLITE_PRIVATE int sqlite3BtreeLast(BtCursor *pCur, int *pRes){
52617 int rc;
52619 assert( cursorHoldsMutex(pCur) );
52620 assert( sqlite3_mutex_held(pCur->pBtree->db->mutex) );
52622 /* If the cursor already points to the last entry, this is a no-op. */
52623 if( CURSOR_VALID==pCur->eState && pCur->atLast ){
52624 #ifdef SQLITE_DEBUG
52625 /* This block serves to assert() that the cursor really does point
52626 ** to the last entry in the b-tree. */
52627 int ii;
52628 for(ii=0; ii<pCur->iPage; ii++){
52629 assert( pCur->aiIdx[ii]==pCur->apPage[ii]->nCell );
52631 assert( pCur->aiIdx[pCur->iPage]==pCur->apPage[pCur->iPage]->nCell-1 );
52632 assert( pCur->apPage[pCur->iPage]->leaf );
52633 #endif
52634 return SQLITE_OK;
52637 rc = moveToRoot(pCur);
52638 if( rc==SQLITE_OK ){
52639 if( CURSOR_INVALID==pCur->eState ){
52640 assert( pCur->pgnoRoot==0 || pCur->apPage[pCur->iPage]->nCell==0 );
52641 *pRes = 1;
52642 }else{
52643 assert( pCur->eState==CURSOR_VALID );
52644 *pRes = 0;
52645 rc = moveToRightmost(pCur);
52646 pCur->atLast = rc==SQLITE_OK ?1:0;
52649 return rc;
52652 /* Move the cursor so that it points to an entry near the key
52653 ** specified by pIdxKey or intKey. Return a success code.
52655 ** For INTKEY tables, the intKey parameter is used. pIdxKey
52656 ** must be NULL. For index tables, pIdxKey is used and intKey
52657 ** is ignored.
52659 ** If an exact match is not found, then the cursor is always
52660 ** left pointing at a leaf page which would hold the entry if it
52661 ** were present. The cursor might point to an entry that comes
52662 ** before or after the key.
52664 ** An integer is written into *pRes which is the result of
52665 ** comparing the key with the entry to which the cursor is
52666 ** pointing. The meaning of the integer written into
52667 ** *pRes is as follows:
52669 ** *pRes<0 The cursor is left pointing at an entry that
52670 ** is smaller than intKey/pIdxKey or if the table is empty
52671 ** and the cursor is therefore left point to nothing.
52673 ** *pRes==0 The cursor is left pointing at an entry that
52674 ** exactly matches intKey/pIdxKey.
52676 ** *pRes>0 The cursor is left pointing at an entry that
52677 ** is larger than intKey/pIdxKey.
52680 SQLITE_PRIVATE int sqlite3BtreeMovetoUnpacked(
52681 BtCursor *pCur, /* The cursor to be moved */
52682 UnpackedRecord *pIdxKey, /* Unpacked index key */
52683 i64 intKey, /* The table key */
52684 int biasRight, /* If true, bias the search to the high end */
52685 int *pRes /* Write search results here */
52687 int rc;
52689 assert( cursorHoldsMutex(pCur) );
52690 assert( sqlite3_mutex_held(pCur->pBtree->db->mutex) );
52691 assert( pRes );
52692 assert( (pIdxKey==0)==(pCur->pKeyInfo==0) );
52694 /* If the cursor is already positioned at the point we are trying
52695 ** to move to, then just return without doing any work */
52696 if( pCur->eState==CURSOR_VALID && pCur->validNKey
52697 && pCur->apPage[0]->intKey
52699 if( pCur->info.nKey==intKey ){
52700 *pRes = 0;
52701 return SQLITE_OK;
52703 if( pCur->atLast && pCur->info.nKey<intKey ){
52704 *pRes = -1;
52705 return SQLITE_OK;
52709 rc = moveToRoot(pCur);
52710 if( rc ){
52711 return rc;
52713 assert( pCur->pgnoRoot==0 || pCur->apPage[pCur->iPage] );
52714 assert( pCur->pgnoRoot==0 || pCur->apPage[pCur->iPage]->isInit );
52715 assert( pCur->eState==CURSOR_INVALID || pCur->apPage[pCur->iPage]->nCell>0 );
52716 if( pCur->eState==CURSOR_INVALID ){
52717 *pRes = -1;
52718 assert( pCur->pgnoRoot==0 || pCur->apPage[pCur->iPage]->nCell==0 );
52719 return SQLITE_OK;
52721 assert( pCur->apPage[0]->intKey || pIdxKey );
52722 for(;;){
52723 int lwr, upr, idx;
52724 Pgno chldPg;
52725 MemPage *pPage = pCur->apPage[pCur->iPage];
52726 int c;
52728 /* pPage->nCell must be greater than zero. If this is the root-page
52729 ** the cursor would have been INVALID above and this for(;;) loop
52730 ** not run. If this is not the root-page, then the moveToChild() routine
52731 ** would have already detected db corruption. Similarly, pPage must
52732 ** be the right kind (index or table) of b-tree page. Otherwise
52733 ** a moveToChild() or moveToRoot() call would have detected corruption. */
52734 assert( pPage->nCell>0 );
52735 assert( pPage->intKey==(pIdxKey==0) );
52736 lwr = 0;
52737 upr = pPage->nCell-1;
52738 if( biasRight ){
52739 pCur->aiIdx[pCur->iPage] = (u16)(idx = upr);
52740 }else{
52741 pCur->aiIdx[pCur->iPage] = (u16)(idx = (upr+lwr)/2);
52743 for(;;){
52744 u8 *pCell; /* Pointer to current cell in pPage */
52746 assert( idx==pCur->aiIdx[pCur->iPage] );
52747 pCur->info.nSize = 0;
52748 pCell = findCell(pPage, idx) + pPage->childPtrSize;
52749 if( pPage->intKey ){
52750 i64 nCellKey;
52751 if( pPage->hasData ){
52752 u32 dummy;
52753 pCell += getVarint32(pCell, dummy);
52755 getVarint(pCell, (u64*)&nCellKey);
52756 if( nCellKey==intKey ){
52757 c = 0;
52758 }else if( nCellKey<intKey ){
52759 c = -1;
52760 }else{
52761 assert( nCellKey>intKey );
52762 c = +1;
52764 pCur->validNKey = 1;
52765 pCur->info.nKey = nCellKey;
52766 }else{
52767 /* The maximum supported page-size is 65536 bytes. This means that
52768 ** the maximum number of record bytes stored on an index B-Tree
52769 ** page is less than 16384 bytes and may be stored as a 2-byte
52770 ** varint. This information is used to attempt to avoid parsing
52771 ** the entire cell by checking for the cases where the record is
52772 ** stored entirely within the b-tree page by inspecting the first
52773 ** 2 bytes of the cell.
52775 int nCell = pCell[0];
52776 if( !(nCell & 0x80) && nCell<=pPage->maxLocal ){
52777 /* This branch runs if the record-size field of the cell is a
52778 ** single byte varint and the record fits entirely on the main
52779 ** b-tree page. */
52780 c = sqlite3VdbeRecordCompare(nCell, (void*)&pCell[1], pIdxKey);
52781 }else if( !(pCell[1] & 0x80)
52782 && (nCell = ((nCell&0x7f)<<7) + pCell[1])<=pPage->maxLocal
52784 /* The record-size field is a 2 byte varint and the record
52785 ** fits entirely on the main b-tree page. */
52786 c = sqlite3VdbeRecordCompare(nCell, (void*)&pCell[2], pIdxKey);
52787 }else{
52788 /* The record flows over onto one or more overflow pages. In
52789 ** this case the whole cell needs to be parsed, a buffer allocated
52790 ** and accessPayload() used to retrieve the record into the
52791 ** buffer before VdbeRecordCompare() can be called. */
52792 void *pCellKey;
52793 u8 * const pCellBody = pCell - pPage->childPtrSize;
52794 btreeParseCellPtr(pPage, pCellBody, &pCur->info);
52795 nCell = (int)pCur->info.nKey;
52796 pCellKey = sqlite3Malloc( nCell );
52797 if( pCellKey==0 ){
52798 rc = SQLITE_NOMEM;
52799 goto moveto_finish;
52801 rc = accessPayload(pCur, 0, nCell, (unsigned char*)pCellKey, 0);
52802 if( rc ){
52803 sqlite3_free(pCellKey);
52804 goto moveto_finish;
52806 c = sqlite3VdbeRecordCompare(nCell, pCellKey, pIdxKey);
52807 sqlite3_free(pCellKey);
52810 if( c==0 ){
52811 if( pPage->intKey && !pPage->leaf ){
52812 lwr = idx;
52813 upr = lwr - 1;
52814 break;
52815 }else{
52816 *pRes = 0;
52817 rc = SQLITE_OK;
52818 goto moveto_finish;
52821 if( c<0 ){
52822 lwr = idx+1;
52823 }else{
52824 upr = idx-1;
52826 if( lwr>upr ){
52827 break;
52829 pCur->aiIdx[pCur->iPage] = (u16)(idx = (lwr+upr)/2);
52831 assert( lwr==upr+1 );
52832 assert( pPage->isInit );
52833 if( pPage->leaf ){
52834 chldPg = 0;
52835 }else if( lwr>=pPage->nCell ){
52836 chldPg = get4byte(&pPage->aData[pPage->hdrOffset+8]);
52837 }else{
52838 chldPg = get4byte(findCell(pPage, lwr));
52840 if( chldPg==0 ){
52841 assert( pCur->aiIdx[pCur->iPage]<pCur->apPage[pCur->iPage]->nCell );
52842 *pRes = c;
52843 rc = SQLITE_OK;
52844 goto moveto_finish;
52846 pCur->aiIdx[pCur->iPage] = (u16)lwr;
52847 pCur->info.nSize = 0;
52848 pCur->validNKey = 0;
52849 rc = moveToChild(pCur, chldPg);
52850 if( rc ) goto moveto_finish;
52852 moveto_finish:
52853 return rc;
52858 ** Return TRUE if the cursor is not pointing at an entry of the table.
52860 ** TRUE will be returned after a call to sqlite3BtreeNext() moves
52861 ** past the last entry in the table or sqlite3BtreePrev() moves past
52862 ** the first entry. TRUE is also returned if the table is empty.
52864 SQLITE_PRIVATE int sqlite3BtreeEof(BtCursor *pCur){
52865 /* TODO: What if the cursor is in CURSOR_REQUIRESEEK but all table entries
52866 ** have been deleted? This API will need to change to return an error code
52867 ** as well as the boolean result value.
52869 return (CURSOR_VALID!=pCur->eState);
52873 ** Advance the cursor to the next entry in the database. If
52874 ** successful then set *pRes=0. If the cursor
52875 ** was already pointing to the last entry in the database before
52876 ** this routine was called, then set *pRes=1.
52878 SQLITE_PRIVATE int sqlite3BtreeNext(BtCursor *pCur, int *pRes){
52879 int rc;
52880 int idx;
52881 MemPage *pPage;
52883 assert( cursorHoldsMutex(pCur) );
52884 rc = restoreCursorPosition(pCur);
52885 if( rc!=SQLITE_OK ){
52886 return rc;
52888 assert( pRes!=0 );
52889 if( CURSOR_INVALID==pCur->eState ){
52890 *pRes = 1;
52891 return SQLITE_OK;
52893 if( pCur->skipNext>0 ){
52894 pCur->skipNext = 0;
52895 *pRes = 0;
52896 return SQLITE_OK;
52898 pCur->skipNext = 0;
52900 pPage = pCur->apPage[pCur->iPage];
52901 idx = ++pCur->aiIdx[pCur->iPage];
52902 assert( pPage->isInit );
52903 assert( idx<=pPage->nCell );
52905 pCur->info.nSize = 0;
52906 pCur->validNKey = 0;
52907 if( idx>=pPage->nCell ){
52908 if( !pPage->leaf ){
52909 rc = moveToChild(pCur, get4byte(&pPage->aData[pPage->hdrOffset+8]));
52910 if( rc ) return rc;
52911 rc = moveToLeftmost(pCur);
52912 *pRes = 0;
52913 return rc;
52916 if( pCur->iPage==0 ){
52917 *pRes = 1;
52918 pCur->eState = CURSOR_INVALID;
52919 return SQLITE_OK;
52921 moveToParent(pCur);
52922 pPage = pCur->apPage[pCur->iPage];
52923 }while( pCur->aiIdx[pCur->iPage]>=pPage->nCell );
52924 *pRes = 0;
52925 if( pPage->intKey ){
52926 rc = sqlite3BtreeNext(pCur, pRes);
52927 }else{
52928 rc = SQLITE_OK;
52930 return rc;
52932 *pRes = 0;
52933 if( pPage->leaf ){
52934 return SQLITE_OK;
52936 rc = moveToLeftmost(pCur);
52937 return rc;
52942 ** Step the cursor to the back to the previous entry in the database. If
52943 ** successful then set *pRes=0. If the cursor
52944 ** was already pointing to the first entry in the database before
52945 ** this routine was called, then set *pRes=1.
52947 SQLITE_PRIVATE int sqlite3BtreePrevious(BtCursor *pCur, int *pRes){
52948 int rc;
52949 MemPage *pPage;
52951 assert( cursorHoldsMutex(pCur) );
52952 rc = restoreCursorPosition(pCur);
52953 if( rc!=SQLITE_OK ){
52954 return rc;
52956 pCur->atLast = 0;
52957 if( CURSOR_INVALID==pCur->eState ){
52958 *pRes = 1;
52959 return SQLITE_OK;
52961 if( pCur->skipNext<0 ){
52962 pCur->skipNext = 0;
52963 *pRes = 0;
52964 return SQLITE_OK;
52966 pCur->skipNext = 0;
52968 pPage = pCur->apPage[pCur->iPage];
52969 assert( pPage->isInit );
52970 if( !pPage->leaf ){
52971 int idx = pCur->aiIdx[pCur->iPage];
52972 rc = moveToChild(pCur, get4byte(findCell(pPage, idx)));
52973 if( rc ){
52974 return rc;
52976 rc = moveToRightmost(pCur);
52977 }else{
52978 while( pCur->aiIdx[pCur->iPage]==0 ){
52979 if( pCur->iPage==0 ){
52980 pCur->eState = CURSOR_INVALID;
52981 *pRes = 1;
52982 return SQLITE_OK;
52984 moveToParent(pCur);
52986 pCur->info.nSize = 0;
52987 pCur->validNKey = 0;
52989 pCur->aiIdx[pCur->iPage]--;
52990 pPage = pCur->apPage[pCur->iPage];
52991 if( pPage->intKey && !pPage->leaf ){
52992 rc = sqlite3BtreePrevious(pCur, pRes);
52993 }else{
52994 rc = SQLITE_OK;
52997 *pRes = 0;
52998 return rc;
53002 ** Allocate a new page from the database file.
53004 ** The new page is marked as dirty. (In other words, sqlite3PagerWrite()
53005 ** has already been called on the new page.) The new page has also
53006 ** been referenced and the calling routine is responsible for calling
53007 ** sqlite3PagerUnref() on the new page when it is done.
53009 ** SQLITE_OK is returned on success. Any other return value indicates
53010 ** an error. *ppPage and *pPgno are undefined in the event of an error.
53011 ** Do not invoke sqlite3PagerUnref() on *ppPage if an error is returned.
53013 ** If the "nearby" parameter is not 0, then a (feeble) effort is made to
53014 ** locate a page close to the page number "nearby". This can be used in an
53015 ** attempt to keep related pages close to each other in the database file,
53016 ** which in turn can make database access faster.
53018 ** If the "exact" parameter is not 0, and the page-number nearby exists
53019 ** anywhere on the free-list, then it is guarenteed to be returned. This
53020 ** is only used by auto-vacuum databases when allocating a new table.
53022 static int allocateBtreePage(
53023 BtShared *pBt,
53024 MemPage **ppPage,
53025 Pgno *pPgno,
53026 Pgno nearby,
53027 u8 exact
53029 MemPage *pPage1;
53030 int rc;
53031 u32 n; /* Number of pages on the freelist */
53032 u32 k; /* Number of leaves on the trunk of the freelist */
53033 MemPage *pTrunk = 0;
53034 MemPage *pPrevTrunk = 0;
53035 Pgno mxPage; /* Total size of the database file */
53037 assert( sqlite3_mutex_held(pBt->mutex) );
53038 pPage1 = pBt->pPage1;
53039 mxPage = btreePagecount(pBt);
53040 n = get4byte(&pPage1->aData[36]);
53041 testcase( n==mxPage-1 );
53042 if( n>=mxPage ){
53043 return SQLITE_CORRUPT_BKPT;
53045 if( n>0 ){
53046 /* There are pages on the freelist. Reuse one of those pages. */
53047 Pgno iTrunk;
53048 u8 searchList = 0; /* If the free-list must be searched for 'nearby' */
53050 /* If the 'exact' parameter was true and a query of the pointer-map
53051 ** shows that the page 'nearby' is somewhere on the free-list, then
53052 ** the entire-list will be searched for that page.
53054 #ifndef SQLITE_OMIT_AUTOVACUUM
53055 if( exact && nearby<=mxPage ){
53056 u8 eType;
53057 assert( nearby>0 );
53058 assert( pBt->autoVacuum );
53059 rc = ptrmapGet(pBt, nearby, &eType, 0);
53060 if( rc ) return rc;
53061 if( eType==PTRMAP_FREEPAGE ){
53062 searchList = 1;
53064 *pPgno = nearby;
53066 #endif
53068 /* Decrement the free-list count by 1. Set iTrunk to the index of the
53069 ** first free-list trunk page. iPrevTrunk is initially 1.
53071 rc = sqlite3PagerWrite(pPage1->pDbPage);
53072 if( rc ) return rc;
53073 put4byte(&pPage1->aData[36], n-1);
53075 /* The code within this loop is run only once if the 'searchList' variable
53076 ** is not true. Otherwise, it runs once for each trunk-page on the
53077 ** free-list until the page 'nearby' is located.
53079 do {
53080 pPrevTrunk = pTrunk;
53081 if( pPrevTrunk ){
53082 iTrunk = get4byte(&pPrevTrunk->aData[0]);
53083 }else{
53084 iTrunk = get4byte(&pPage1->aData[32]);
53086 testcase( iTrunk==mxPage );
53087 if( iTrunk>mxPage ){
53088 rc = SQLITE_CORRUPT_BKPT;
53089 }else{
53090 rc = btreeGetPage(pBt, iTrunk, &pTrunk, 0);
53092 if( rc ){
53093 pTrunk = 0;
53094 goto end_allocate_page;
53097 k = get4byte(&pTrunk->aData[4]); /* # of leaves on this trunk page */
53098 if( k==0 && !searchList ){
53099 /* The trunk has no leaves and the list is not being searched.
53100 ** So extract the trunk page itself and use it as the newly
53101 ** allocated page */
53102 assert( pPrevTrunk==0 );
53103 rc = sqlite3PagerWrite(pTrunk->pDbPage);
53104 if( rc ){
53105 goto end_allocate_page;
53107 *pPgno = iTrunk;
53108 memcpy(&pPage1->aData[32], &pTrunk->aData[0], 4);
53109 *ppPage = pTrunk;
53110 pTrunk = 0;
53111 TRACE(("ALLOCATE: %d trunk - %d free pages left\n", *pPgno, n-1));
53112 }else if( k>(u32)(pBt->usableSize/4 - 2) ){
53113 /* Value of k is out of range. Database corruption */
53114 rc = SQLITE_CORRUPT_BKPT;
53115 goto end_allocate_page;
53116 #ifndef SQLITE_OMIT_AUTOVACUUM
53117 }else if( searchList && nearby==iTrunk ){
53118 /* The list is being searched and this trunk page is the page
53119 ** to allocate, regardless of whether it has leaves.
53121 assert( *pPgno==iTrunk );
53122 *ppPage = pTrunk;
53123 searchList = 0;
53124 rc = sqlite3PagerWrite(pTrunk->pDbPage);
53125 if( rc ){
53126 goto end_allocate_page;
53128 if( k==0 ){
53129 if( !pPrevTrunk ){
53130 memcpy(&pPage1->aData[32], &pTrunk->aData[0], 4);
53131 }else{
53132 rc = sqlite3PagerWrite(pPrevTrunk->pDbPage);
53133 if( rc!=SQLITE_OK ){
53134 goto end_allocate_page;
53136 memcpy(&pPrevTrunk->aData[0], &pTrunk->aData[0], 4);
53138 }else{
53139 /* The trunk page is required by the caller but it contains
53140 ** pointers to free-list leaves. The first leaf becomes a trunk
53141 ** page in this case.
53143 MemPage *pNewTrunk;
53144 Pgno iNewTrunk = get4byte(&pTrunk->aData[8]);
53145 if( iNewTrunk>mxPage ){
53146 rc = SQLITE_CORRUPT_BKPT;
53147 goto end_allocate_page;
53149 testcase( iNewTrunk==mxPage );
53150 rc = btreeGetPage(pBt, iNewTrunk, &pNewTrunk, 0);
53151 if( rc!=SQLITE_OK ){
53152 goto end_allocate_page;
53154 rc = sqlite3PagerWrite(pNewTrunk->pDbPage);
53155 if( rc!=SQLITE_OK ){
53156 releasePage(pNewTrunk);
53157 goto end_allocate_page;
53159 memcpy(&pNewTrunk->aData[0], &pTrunk->aData[0], 4);
53160 put4byte(&pNewTrunk->aData[4], k-1);
53161 memcpy(&pNewTrunk->aData[8], &pTrunk->aData[12], (k-1)*4);
53162 releasePage(pNewTrunk);
53163 if( !pPrevTrunk ){
53164 assert( sqlite3PagerIswriteable(pPage1->pDbPage) );
53165 put4byte(&pPage1->aData[32], iNewTrunk);
53166 }else{
53167 rc = sqlite3PagerWrite(pPrevTrunk->pDbPage);
53168 if( rc ){
53169 goto end_allocate_page;
53171 put4byte(&pPrevTrunk->aData[0], iNewTrunk);
53174 pTrunk = 0;
53175 TRACE(("ALLOCATE: %d trunk - %d free pages left\n", *pPgno, n-1));
53176 #endif
53177 }else if( k>0 ){
53178 /* Extract a leaf from the trunk */
53179 u32 closest;
53180 Pgno iPage;
53181 unsigned char *aData = pTrunk->aData;
53182 if( nearby>0 ){
53183 u32 i;
53184 int dist;
53185 closest = 0;
53186 dist = sqlite3AbsInt32(get4byte(&aData[8]) - nearby);
53187 for(i=1; i<k; i++){
53188 int d2 = sqlite3AbsInt32(get4byte(&aData[8+i*4]) - nearby);
53189 if( d2<dist ){
53190 closest = i;
53191 dist = d2;
53194 }else{
53195 closest = 0;
53198 iPage = get4byte(&aData[8+closest*4]);
53199 testcase( iPage==mxPage );
53200 if( iPage>mxPage ){
53201 rc = SQLITE_CORRUPT_BKPT;
53202 goto end_allocate_page;
53204 testcase( iPage==mxPage );
53205 if( !searchList || iPage==nearby ){
53206 int noContent;
53207 *pPgno = iPage;
53208 TRACE(("ALLOCATE: %d was leaf %d of %d on trunk %d"
53209 ": %d more free pages\n",
53210 *pPgno, closest+1, k, pTrunk->pgno, n-1));
53211 rc = sqlite3PagerWrite(pTrunk->pDbPage);
53212 if( rc ) goto end_allocate_page;
53213 if( closest<k-1 ){
53214 memcpy(&aData[8+closest*4], &aData[4+k*4], 4);
53216 put4byte(&aData[4], k-1);
53217 noContent = !btreeGetHasContent(pBt, *pPgno);
53218 rc = btreeGetPage(pBt, *pPgno, ppPage, noContent);
53219 if( rc==SQLITE_OK ){
53220 rc = sqlite3PagerWrite((*ppPage)->pDbPage);
53221 if( rc!=SQLITE_OK ){
53222 releasePage(*ppPage);
53225 searchList = 0;
53228 releasePage(pPrevTrunk);
53229 pPrevTrunk = 0;
53230 }while( searchList );
53231 }else{
53232 /* There are no pages on the freelist, so create a new page at the
53233 ** end of the file */
53234 rc = sqlite3PagerWrite(pBt->pPage1->pDbPage);
53235 if( rc ) return rc;
53236 pBt->nPage++;
53237 if( pBt->nPage==PENDING_BYTE_PAGE(pBt) ) pBt->nPage++;
53239 #ifndef SQLITE_OMIT_AUTOVACUUM
53240 if( pBt->autoVacuum && PTRMAP_ISPAGE(pBt, pBt->nPage) ){
53241 /* If *pPgno refers to a pointer-map page, allocate two new pages
53242 ** at the end of the file instead of one. The first allocated page
53243 ** becomes a new pointer-map page, the second is used by the caller.
53245 MemPage *pPg = 0;
53246 TRACE(("ALLOCATE: %d from end of file (pointer-map page)\n", pBt->nPage));
53247 assert( pBt->nPage!=PENDING_BYTE_PAGE(pBt) );
53248 rc = btreeGetPage(pBt, pBt->nPage, &pPg, 1);
53249 if( rc==SQLITE_OK ){
53250 rc = sqlite3PagerWrite(pPg->pDbPage);
53251 releasePage(pPg);
53253 if( rc ) return rc;
53254 pBt->nPage++;
53255 if( pBt->nPage==PENDING_BYTE_PAGE(pBt) ){ pBt->nPage++; }
53257 #endif
53258 put4byte(28 + (u8*)pBt->pPage1->aData, pBt->nPage);
53259 *pPgno = pBt->nPage;
53261 assert( *pPgno!=PENDING_BYTE_PAGE(pBt) );
53262 rc = btreeGetPage(pBt, *pPgno, ppPage, 1);
53263 if( rc ) return rc;
53264 rc = sqlite3PagerWrite((*ppPage)->pDbPage);
53265 if( rc!=SQLITE_OK ){
53266 releasePage(*ppPage);
53268 TRACE(("ALLOCATE: %d from end of file\n", *pPgno));
53271 assert( *pPgno!=PENDING_BYTE_PAGE(pBt) );
53273 end_allocate_page:
53274 releasePage(pTrunk);
53275 releasePage(pPrevTrunk);
53276 if( rc==SQLITE_OK ){
53277 if( sqlite3PagerPageRefcount((*ppPage)->pDbPage)>1 ){
53278 releasePage(*ppPage);
53279 return SQLITE_CORRUPT_BKPT;
53281 (*ppPage)->isInit = 0;
53282 }else{
53283 *ppPage = 0;
53285 assert( rc!=SQLITE_OK || sqlite3PagerIswriteable((*ppPage)->pDbPage) );
53286 return rc;
53290 ** This function is used to add page iPage to the database file free-list.
53291 ** It is assumed that the page is not already a part of the free-list.
53293 ** The value passed as the second argument to this function is optional.
53294 ** If the caller happens to have a pointer to the MemPage object
53295 ** corresponding to page iPage handy, it may pass it as the second value.
53296 ** Otherwise, it may pass NULL.
53298 ** If a pointer to a MemPage object is passed as the second argument,
53299 ** its reference count is not altered by this function.
53301 static int freePage2(BtShared *pBt, MemPage *pMemPage, Pgno iPage){
53302 MemPage *pTrunk = 0; /* Free-list trunk page */
53303 Pgno iTrunk = 0; /* Page number of free-list trunk page */
53304 MemPage *pPage1 = pBt->pPage1; /* Local reference to page 1 */
53305 MemPage *pPage; /* Page being freed. May be NULL. */
53306 int rc; /* Return Code */
53307 int nFree; /* Initial number of pages on free-list */
53309 assert( sqlite3_mutex_held(pBt->mutex) );
53310 assert( iPage>1 );
53311 assert( !pMemPage || pMemPage->pgno==iPage );
53313 if( pMemPage ){
53314 pPage = pMemPage;
53315 sqlite3PagerRef(pPage->pDbPage);
53316 }else{
53317 pPage = btreePageLookup(pBt, iPage);
53320 /* Increment the free page count on pPage1 */
53321 rc = sqlite3PagerWrite(pPage1->pDbPage);
53322 if( rc ) goto freepage_out;
53323 nFree = get4byte(&pPage1->aData[36]);
53324 put4byte(&pPage1->aData[36], nFree+1);
53326 if( pBt->secureDelete ){
53327 /* If the secure_delete option is enabled, then
53328 ** always fully overwrite deleted information with zeros.
53330 if( (!pPage && ((rc = btreeGetPage(pBt, iPage, &pPage, 0))!=0) )
53331 || ((rc = sqlite3PagerWrite(pPage->pDbPage))!=0)
53333 goto freepage_out;
53335 memset(pPage->aData, 0, pPage->pBt->pageSize);
53338 /* If the database supports auto-vacuum, write an entry in the pointer-map
53339 ** to indicate that the page is free.
53341 if( ISAUTOVACUUM ){
53342 ptrmapPut(pBt, iPage, PTRMAP_FREEPAGE, 0, &rc);
53343 if( rc ) goto freepage_out;
53346 /* Now manipulate the actual database free-list structure. There are two
53347 ** possibilities. If the free-list is currently empty, or if the first
53348 ** trunk page in the free-list is full, then this page will become a
53349 ** new free-list trunk page. Otherwise, it will become a leaf of the
53350 ** first trunk page in the current free-list. This block tests if it
53351 ** is possible to add the page as a new free-list leaf.
53353 if( nFree!=0 ){
53354 u32 nLeaf; /* Initial number of leaf cells on trunk page */
53356 iTrunk = get4byte(&pPage1->aData[32]);
53357 rc = btreeGetPage(pBt, iTrunk, &pTrunk, 0);
53358 if( rc!=SQLITE_OK ){
53359 goto freepage_out;
53362 nLeaf = get4byte(&pTrunk->aData[4]);
53363 assert( pBt->usableSize>32 );
53364 if( nLeaf > (u32)pBt->usableSize/4 - 2 ){
53365 rc = SQLITE_CORRUPT_BKPT;
53366 goto freepage_out;
53368 if( nLeaf < (u32)pBt->usableSize/4 - 8 ){
53369 /* In this case there is room on the trunk page to insert the page
53370 ** being freed as a new leaf.
53372 ** Note that the trunk page is not really full until it contains
53373 ** usableSize/4 - 2 entries, not usableSize/4 - 8 entries as we have
53374 ** coded. But due to a coding error in versions of SQLite prior to
53375 ** 3.6.0, databases with freelist trunk pages holding more than
53376 ** usableSize/4 - 8 entries will be reported as corrupt. In order
53377 ** to maintain backwards compatibility with older versions of SQLite,
53378 ** we will continue to restrict the number of entries to usableSize/4 - 8
53379 ** for now. At some point in the future (once everyone has upgraded
53380 ** to 3.6.0 or later) we should consider fixing the conditional above
53381 ** to read "usableSize/4-2" instead of "usableSize/4-8".
53383 rc = sqlite3PagerWrite(pTrunk->pDbPage);
53384 if( rc==SQLITE_OK ){
53385 put4byte(&pTrunk->aData[4], nLeaf+1);
53386 put4byte(&pTrunk->aData[8+nLeaf*4], iPage);
53387 if( pPage && !pBt->secureDelete ){
53388 sqlite3PagerDontWrite(pPage->pDbPage);
53390 rc = btreeSetHasContent(pBt, iPage);
53392 TRACE(("FREE-PAGE: %d leaf on trunk page %d\n",pPage->pgno,pTrunk->pgno));
53393 goto freepage_out;
53397 /* If control flows to this point, then it was not possible to add the
53398 ** the page being freed as a leaf page of the first trunk in the free-list.
53399 ** Possibly because the free-list is empty, or possibly because the
53400 ** first trunk in the free-list is full. Either way, the page being freed
53401 ** will become the new first trunk page in the free-list.
53403 if( pPage==0 && SQLITE_OK!=(rc = btreeGetPage(pBt, iPage, &pPage, 0)) ){
53404 goto freepage_out;
53406 rc = sqlite3PagerWrite(pPage->pDbPage);
53407 if( rc!=SQLITE_OK ){
53408 goto freepage_out;
53410 put4byte(pPage->aData, iTrunk);
53411 put4byte(&pPage->aData[4], 0);
53412 put4byte(&pPage1->aData[32], iPage);
53413 TRACE(("FREE-PAGE: %d new trunk page replacing %d\n", pPage->pgno, iTrunk));
53415 freepage_out:
53416 if( pPage ){
53417 pPage->isInit = 0;
53419 releasePage(pPage);
53420 releasePage(pTrunk);
53421 return rc;
53423 static void freePage(MemPage *pPage, int *pRC){
53424 if( (*pRC)==SQLITE_OK ){
53425 *pRC = freePage2(pPage->pBt, pPage, pPage->pgno);
53430 ** Free any overflow pages associated with the given Cell.
53432 static int clearCell(MemPage *pPage, unsigned char *pCell){
53433 BtShared *pBt = pPage->pBt;
53434 CellInfo info;
53435 Pgno ovflPgno;
53436 int rc;
53437 int nOvfl;
53438 u32 ovflPageSize;
53440 assert( sqlite3_mutex_held(pPage->pBt->mutex) );
53441 btreeParseCellPtr(pPage, pCell, &info);
53442 if( info.iOverflow==0 ){
53443 return SQLITE_OK; /* No overflow pages. Return without doing anything */
53445 if( pCell+info.iOverflow+3 > pPage->aData+pPage->maskPage ){
53446 return SQLITE_CORRUPT; /* Cell extends past end of page */
53448 ovflPgno = get4byte(&pCell[info.iOverflow]);
53449 assert( pBt->usableSize > 4 );
53450 ovflPageSize = pBt->usableSize - 4;
53451 nOvfl = (info.nPayload - info.nLocal + ovflPageSize - 1)/ovflPageSize;
53452 assert( ovflPgno==0 || nOvfl>0 );
53453 while( nOvfl-- ){
53454 Pgno iNext = 0;
53455 MemPage *pOvfl = 0;
53456 if( ovflPgno<2 || ovflPgno>btreePagecount(pBt) ){
53457 /* 0 is not a legal page number and page 1 cannot be an
53458 ** overflow page. Therefore if ovflPgno<2 or past the end of the
53459 ** file the database must be corrupt. */
53460 return SQLITE_CORRUPT_BKPT;
53462 if( nOvfl ){
53463 rc = getOverflowPage(pBt, ovflPgno, &pOvfl, &iNext);
53464 if( rc ) return rc;
53467 if( ( pOvfl || ((pOvfl = btreePageLookup(pBt, ovflPgno))!=0) )
53468 && sqlite3PagerPageRefcount(pOvfl->pDbPage)!=1
53470 /* There is no reason any cursor should have an outstanding reference
53471 ** to an overflow page belonging to a cell that is being deleted/updated.
53472 ** So if there exists more than one reference to this page, then it
53473 ** must not really be an overflow page and the database must be corrupt.
53474 ** It is helpful to detect this before calling freePage2(), as
53475 ** freePage2() may zero the page contents if secure-delete mode is
53476 ** enabled. If this 'overflow' page happens to be a page that the
53477 ** caller is iterating through or using in some other way, this
53478 ** can be problematic.
53480 rc = SQLITE_CORRUPT_BKPT;
53481 }else{
53482 rc = freePage2(pBt, pOvfl, ovflPgno);
53485 if( pOvfl ){
53486 sqlite3PagerUnref(pOvfl->pDbPage);
53488 if( rc ) return rc;
53489 ovflPgno = iNext;
53491 return SQLITE_OK;
53495 ** Create the byte sequence used to represent a cell on page pPage
53496 ** and write that byte sequence into pCell[]. Overflow pages are
53497 ** allocated and filled in as necessary. The calling procedure
53498 ** is responsible for making sure sufficient space has been allocated
53499 ** for pCell[].
53501 ** Note that pCell does not necessary need to point to the pPage->aData
53502 ** area. pCell might point to some temporary storage. The cell will
53503 ** be constructed in this temporary area then copied into pPage->aData
53504 ** later.
53506 static int fillInCell(
53507 MemPage *pPage, /* The page that contains the cell */
53508 unsigned char *pCell, /* Complete text of the cell */
53509 const void *pKey, i64 nKey, /* The key */
53510 const void *pData,int nData, /* The data */
53511 int nZero, /* Extra zero bytes to append to pData */
53512 int *pnSize /* Write cell size here */
53514 int nPayload;
53515 const u8 *pSrc;
53516 int nSrc, n, rc;
53517 int spaceLeft;
53518 MemPage *pOvfl = 0;
53519 MemPage *pToRelease = 0;
53520 unsigned char *pPrior;
53521 unsigned char *pPayload;
53522 BtShared *pBt = pPage->pBt;
53523 Pgno pgnoOvfl = 0;
53524 int nHeader;
53525 CellInfo info;
53527 assert( sqlite3_mutex_held(pPage->pBt->mutex) );
53529 /* pPage is not necessarily writeable since pCell might be auxiliary
53530 ** buffer space that is separate from the pPage buffer area */
53531 assert( pCell<pPage->aData || pCell>=&pPage->aData[pBt->pageSize]
53532 || sqlite3PagerIswriteable(pPage->pDbPage) );
53534 /* Fill in the header. */
53535 nHeader = 0;
53536 if( !pPage->leaf ){
53537 nHeader += 4;
53539 if( pPage->hasData ){
53540 nHeader += putVarint(&pCell[nHeader], nData+nZero);
53541 }else{
53542 nData = nZero = 0;
53544 nHeader += putVarint(&pCell[nHeader], *(u64*)&nKey);
53545 btreeParseCellPtr(pPage, pCell, &info);
53546 assert( info.nHeader==nHeader );
53547 assert( info.nKey==nKey );
53548 assert( info.nData==(u32)(nData+nZero) );
53550 /* Fill in the payload */
53551 nPayload = nData + nZero;
53552 if( pPage->intKey ){
53553 pSrc = pData;
53554 nSrc = nData;
53555 nData = 0;
53556 }else{
53557 if( NEVER(nKey>0x7fffffff || pKey==0) ){
53558 return SQLITE_CORRUPT_BKPT;
53560 nPayload += (int)nKey;
53561 pSrc = pKey;
53562 nSrc = (int)nKey;
53564 *pnSize = info.nSize;
53565 spaceLeft = info.nLocal;
53566 pPayload = &pCell[nHeader];
53567 pPrior = &pCell[info.iOverflow];
53569 while( nPayload>0 ){
53570 if( spaceLeft==0 ){
53571 #ifndef SQLITE_OMIT_AUTOVACUUM
53572 Pgno pgnoPtrmap = pgnoOvfl; /* Overflow page pointer-map entry page */
53573 if( pBt->autoVacuum ){
53575 pgnoOvfl++;
53576 } while(
53577 PTRMAP_ISPAGE(pBt, pgnoOvfl) || pgnoOvfl==PENDING_BYTE_PAGE(pBt)
53580 #endif
53581 rc = allocateBtreePage(pBt, &pOvfl, &pgnoOvfl, pgnoOvfl, 0);
53582 #ifndef SQLITE_OMIT_AUTOVACUUM
53583 /* If the database supports auto-vacuum, and the second or subsequent
53584 ** overflow page is being allocated, add an entry to the pointer-map
53585 ** for that page now.
53587 ** If this is the first overflow page, then write a partial entry
53588 ** to the pointer-map. If we write nothing to this pointer-map slot,
53589 ** then the optimistic overflow chain processing in clearCell()
53590 ** may misinterpret the uninitialised values and delete the
53591 ** wrong pages from the database.
53593 if( pBt->autoVacuum && rc==SQLITE_OK ){
53594 u8 eType = (pgnoPtrmap?PTRMAP_OVERFLOW2:PTRMAP_OVERFLOW1);
53595 ptrmapPut(pBt, pgnoOvfl, eType, pgnoPtrmap, &rc);
53596 if( rc ){
53597 releasePage(pOvfl);
53600 #endif
53601 if( rc ){
53602 releasePage(pToRelease);
53603 return rc;
53606 /* If pToRelease is not zero than pPrior points into the data area
53607 ** of pToRelease. Make sure pToRelease is still writeable. */
53608 assert( pToRelease==0 || sqlite3PagerIswriteable(pToRelease->pDbPage) );
53610 /* If pPrior is part of the data area of pPage, then make sure pPage
53611 ** is still writeable */
53612 assert( pPrior<pPage->aData || pPrior>=&pPage->aData[pBt->pageSize]
53613 || sqlite3PagerIswriteable(pPage->pDbPage) );
53615 put4byte(pPrior, pgnoOvfl);
53616 releasePage(pToRelease);
53617 pToRelease = pOvfl;
53618 pPrior = pOvfl->aData;
53619 put4byte(pPrior, 0);
53620 pPayload = &pOvfl->aData[4];
53621 spaceLeft = pBt->usableSize - 4;
53623 n = nPayload;
53624 if( n>spaceLeft ) n = spaceLeft;
53626 /* If pToRelease is not zero than pPayload points into the data area
53627 ** of pToRelease. Make sure pToRelease is still writeable. */
53628 assert( pToRelease==0 || sqlite3PagerIswriteable(pToRelease->pDbPage) );
53630 /* If pPayload is part of the data area of pPage, then make sure pPage
53631 ** is still writeable */
53632 assert( pPayload<pPage->aData || pPayload>=&pPage->aData[pBt->pageSize]
53633 || sqlite3PagerIswriteable(pPage->pDbPage) );
53635 if( nSrc>0 ){
53636 if( n>nSrc ) n = nSrc;
53637 assert( pSrc );
53638 memcpy(pPayload, pSrc, n);
53639 }else{
53640 memset(pPayload, 0, n);
53642 nPayload -= n;
53643 pPayload += n;
53644 pSrc += n;
53645 nSrc -= n;
53646 spaceLeft -= n;
53647 if( nSrc==0 ){
53648 nSrc = nData;
53649 pSrc = pData;
53652 releasePage(pToRelease);
53653 return SQLITE_OK;
53657 ** Remove the i-th cell from pPage. This routine effects pPage only.
53658 ** The cell content is not freed or deallocated. It is assumed that
53659 ** the cell content has been copied someplace else. This routine just
53660 ** removes the reference to the cell from pPage.
53662 ** "sz" must be the number of bytes in the cell.
53664 static void dropCell(MemPage *pPage, int idx, int sz, int *pRC){
53665 u32 pc; /* Offset to cell content of cell being deleted */
53666 u8 *data; /* pPage->aData */
53667 u8 *ptr; /* Used to move bytes around within data[] */
53668 u8 *endPtr; /* End of loop */
53669 int rc; /* The return code */
53670 int hdr; /* Beginning of the header. 0 most pages. 100 page 1 */
53672 if( *pRC ) return;
53674 assert( idx>=0 && idx<pPage->nCell );
53675 assert( sz==cellSize(pPage, idx) );
53676 assert( sqlite3PagerIswriteable(pPage->pDbPage) );
53677 assert( sqlite3_mutex_held(pPage->pBt->mutex) );
53678 data = pPage->aData;
53679 ptr = &data[pPage->cellOffset + 2*idx];
53680 pc = get2byte(ptr);
53681 hdr = pPage->hdrOffset;
53682 testcase( pc==get2byte(&data[hdr+5]) );
53683 testcase( pc+sz==pPage->pBt->usableSize );
53684 if( pc < (u32)get2byte(&data[hdr+5]) || pc+sz > pPage->pBt->usableSize ){
53685 *pRC = SQLITE_CORRUPT_BKPT;
53686 return;
53688 rc = freeSpace(pPage, pc, sz);
53689 if( rc ){
53690 *pRC = rc;
53691 return;
53693 endPtr = &data[pPage->cellOffset + 2*pPage->nCell - 2];
53694 assert( (SQLITE_PTR_TO_INT(ptr)&1)==0 ); /* ptr is always 2-byte aligned */
53695 while( ptr<endPtr ){
53696 *(u16*)ptr = *(u16*)&ptr[2];
53697 ptr += 2;
53699 pPage->nCell--;
53700 put2byte(&data[hdr+3], pPage->nCell);
53701 pPage->nFree += 2;
53705 ** Insert a new cell on pPage at cell index "i". pCell points to the
53706 ** content of the cell.
53708 ** If the cell content will fit on the page, then put it there. If it
53709 ** will not fit, then make a copy of the cell content into pTemp if
53710 ** pTemp is not null. Regardless of pTemp, allocate a new entry
53711 ** in pPage->aOvfl[] and make it point to the cell content (either
53712 ** in pTemp or the original pCell) and also record its index.
53713 ** Allocating a new entry in pPage->aCell[] implies that
53714 ** pPage->nOverflow is incremented.
53716 ** If nSkip is non-zero, then do not copy the first nSkip bytes of the
53717 ** cell. The caller will overwrite them after this function returns. If
53718 ** nSkip is non-zero, then pCell may not point to an invalid memory location
53719 ** (but pCell+nSkip is always valid).
53721 static void insertCell(
53722 MemPage *pPage, /* Page into which we are copying */
53723 int i, /* New cell becomes the i-th cell of the page */
53724 u8 *pCell, /* Content of the new cell */
53725 int sz, /* Bytes of content in pCell */
53726 u8 *pTemp, /* Temp storage space for pCell, if needed */
53727 Pgno iChild, /* If non-zero, replace first 4 bytes with this value */
53728 int *pRC /* Read and write return code from here */
53730 int idx = 0; /* Where to write new cell content in data[] */
53731 int j; /* Loop counter */
53732 int end; /* First byte past the last cell pointer in data[] */
53733 int ins; /* Index in data[] where new cell pointer is inserted */
53734 int cellOffset; /* Address of first cell pointer in data[] */
53735 u8 *data; /* The content of the whole page */
53736 u8 *ptr; /* Used for moving information around in data[] */
53737 u8 *endPtr; /* End of the loop */
53739 int nSkip = (iChild ? 4 : 0);
53741 if( *pRC ) return;
53743 assert( i>=0 && i<=pPage->nCell+pPage->nOverflow );
53744 assert( pPage->nCell<=MX_CELL(pPage->pBt) && MX_CELL(pPage->pBt)<=10921 );
53745 assert( pPage->nOverflow<=ArraySize(pPage->aOvfl) );
53746 assert( sqlite3_mutex_held(pPage->pBt->mutex) );
53747 /* The cell should normally be sized correctly. However, when moving a
53748 ** malformed cell from a leaf page to an interior page, if the cell size
53749 ** wanted to be less than 4 but got rounded up to 4 on the leaf, then size
53750 ** might be less than 8 (leaf-size + pointer) on the interior node. Hence
53751 ** the term after the || in the following assert(). */
53752 assert( sz==cellSizePtr(pPage, pCell) || (sz==8 && iChild>0) );
53753 if( pPage->nOverflow || sz+2>pPage->nFree ){
53754 if( pTemp ){
53755 memcpy(pTemp+nSkip, pCell+nSkip, sz-nSkip);
53756 pCell = pTemp;
53758 if( iChild ){
53759 put4byte(pCell, iChild);
53761 j = pPage->nOverflow++;
53762 assert( j<(int)(sizeof(pPage->aOvfl)/sizeof(pPage->aOvfl[0])) );
53763 pPage->aOvfl[j].pCell = pCell;
53764 pPage->aOvfl[j].idx = (u16)i;
53765 }else{
53766 int rc = sqlite3PagerWrite(pPage->pDbPage);
53767 if( rc!=SQLITE_OK ){
53768 *pRC = rc;
53769 return;
53771 assert( sqlite3PagerIswriteable(pPage->pDbPage) );
53772 data = pPage->aData;
53773 cellOffset = pPage->cellOffset;
53774 end = cellOffset + 2*pPage->nCell;
53775 ins = cellOffset + 2*i;
53776 rc = allocateSpace(pPage, sz, &idx);
53777 if( rc ){ *pRC = rc; return; }
53778 /* The allocateSpace() routine guarantees the following two properties
53779 ** if it returns success */
53780 assert( idx >= end+2 );
53781 assert( idx+sz <= (int)pPage->pBt->usableSize );
53782 pPage->nCell++;
53783 pPage->nFree -= (u16)(2 + sz);
53784 memcpy(&data[idx+nSkip], pCell+nSkip, sz-nSkip);
53785 if( iChild ){
53786 put4byte(&data[idx], iChild);
53788 ptr = &data[end];
53789 endPtr = &data[ins];
53790 assert( (SQLITE_PTR_TO_INT(ptr)&1)==0 ); /* ptr is always 2-byte aligned */
53791 while( ptr>endPtr ){
53792 *(u16*)ptr = *(u16*)&ptr[-2];
53793 ptr -= 2;
53795 put2byte(&data[ins], idx);
53796 put2byte(&data[pPage->hdrOffset+3], pPage->nCell);
53797 #ifndef SQLITE_OMIT_AUTOVACUUM
53798 if( pPage->pBt->autoVacuum ){
53799 /* The cell may contain a pointer to an overflow page. If so, write
53800 ** the entry for the overflow page into the pointer map.
53802 ptrmapPutOvflPtr(pPage, pCell, pRC);
53804 #endif
53809 ** Add a list of cells to a page. The page should be initially empty.
53810 ** The cells are guaranteed to fit on the page.
53812 static void assemblePage(
53813 MemPage *pPage, /* The page to be assemblied */
53814 int nCell, /* The number of cells to add to this page */
53815 u8 **apCell, /* Pointers to cell bodies */
53816 u16 *aSize /* Sizes of the cells */
53818 int i; /* Loop counter */
53819 u8 *pCellptr; /* Address of next cell pointer */
53820 int cellbody; /* Address of next cell body */
53821 u8 * const data = pPage->aData; /* Pointer to data for pPage */
53822 const int hdr = pPage->hdrOffset; /* Offset of header on pPage */
53823 const int nUsable = pPage->pBt->usableSize; /* Usable size of page */
53825 assert( pPage->nOverflow==0 );
53826 assert( sqlite3_mutex_held(pPage->pBt->mutex) );
53827 assert( nCell>=0 && nCell<=(int)MX_CELL(pPage->pBt)
53828 && (int)MX_CELL(pPage->pBt)<=10921);
53829 assert( sqlite3PagerIswriteable(pPage->pDbPage) );
53831 /* Check that the page has just been zeroed by zeroPage() */
53832 assert( pPage->nCell==0 );
53833 assert( get2byteNotZero(&data[hdr+5])==nUsable );
53835 pCellptr = &data[pPage->cellOffset + nCell*2];
53836 cellbody = nUsable;
53837 for(i=nCell-1; i>=0; i--){
53838 u16 sz = aSize[i];
53839 pCellptr -= 2;
53840 cellbody -= sz;
53841 put2byte(pCellptr, cellbody);
53842 memcpy(&data[cellbody], apCell[i], sz);
53844 put2byte(&data[hdr+3], nCell);
53845 put2byte(&data[hdr+5], cellbody);
53846 pPage->nFree -= (nCell*2 + nUsable - cellbody);
53847 pPage->nCell = (u16)nCell;
53851 ** The following parameters determine how many adjacent pages get involved
53852 ** in a balancing operation. NN is the number of neighbors on either side
53853 ** of the page that participate in the balancing operation. NB is the
53854 ** total number of pages that participate, including the target page and
53855 ** NN neighbors on either side.
53857 ** The minimum value of NN is 1 (of course). Increasing NN above 1
53858 ** (to 2 or 3) gives a modest improvement in SELECT and DELETE performance
53859 ** in exchange for a larger degradation in INSERT and UPDATE performance.
53860 ** The value of NN appears to give the best results overall.
53862 #define NN 1 /* Number of neighbors on either side of pPage */
53863 #define NB (NN*2+1) /* Total pages involved in the balance */
53866 #ifndef SQLITE_OMIT_QUICKBALANCE
53868 ** This version of balance() handles the common special case where
53869 ** a new entry is being inserted on the extreme right-end of the
53870 ** tree, in other words, when the new entry will become the largest
53871 ** entry in the tree.
53873 ** Instead of trying to balance the 3 right-most leaf pages, just add
53874 ** a new page to the right-hand side and put the one new entry in
53875 ** that page. This leaves the right side of the tree somewhat
53876 ** unbalanced. But odds are that we will be inserting new entries
53877 ** at the end soon afterwards so the nearly empty page will quickly
53878 ** fill up. On average.
53880 ** pPage is the leaf page which is the right-most page in the tree.
53881 ** pParent is its parent. pPage must have a single overflow entry
53882 ** which is also the right-most entry on the page.
53884 ** The pSpace buffer is used to store a temporary copy of the divider
53885 ** cell that will be inserted into pParent. Such a cell consists of a 4
53886 ** byte page number followed by a variable length integer. In other
53887 ** words, at most 13 bytes. Hence the pSpace buffer must be at
53888 ** least 13 bytes in size.
53890 static int balance_quick(MemPage *pParent, MemPage *pPage, u8 *pSpace){
53891 BtShared *const pBt = pPage->pBt; /* B-Tree Database */
53892 MemPage *pNew; /* Newly allocated page */
53893 int rc; /* Return Code */
53894 Pgno pgnoNew; /* Page number of pNew */
53896 assert( sqlite3_mutex_held(pPage->pBt->mutex) );
53897 assert( sqlite3PagerIswriteable(pParent->pDbPage) );
53898 assert( pPage->nOverflow==1 );
53900 /* This error condition is now caught prior to reaching this function */
53901 if( pPage->nCell<=0 ) return SQLITE_CORRUPT_BKPT;
53903 /* Allocate a new page. This page will become the right-sibling of
53904 ** pPage. Make the parent page writable, so that the new divider cell
53905 ** may be inserted. If both these operations are successful, proceed.
53907 rc = allocateBtreePage(pBt, &pNew, &pgnoNew, 0, 0);
53909 if( rc==SQLITE_OK ){
53911 u8 *pOut = &pSpace[4];
53912 u8 *pCell = pPage->aOvfl[0].pCell;
53913 u16 szCell = cellSizePtr(pPage, pCell);
53914 u8 *pStop;
53916 assert( sqlite3PagerIswriteable(pNew->pDbPage) );
53917 assert( pPage->aData[0]==(PTF_INTKEY|PTF_LEAFDATA|PTF_LEAF) );
53918 zeroPage(pNew, PTF_INTKEY|PTF_LEAFDATA|PTF_LEAF);
53919 assemblePage(pNew, 1, &pCell, &szCell);
53921 /* If this is an auto-vacuum database, update the pointer map
53922 ** with entries for the new page, and any pointer from the
53923 ** cell on the page to an overflow page. If either of these
53924 ** operations fails, the return code is set, but the contents
53925 ** of the parent page are still manipulated by thh code below.
53926 ** That is Ok, at this point the parent page is guaranteed to
53927 ** be marked as dirty. Returning an error code will cause a
53928 ** rollback, undoing any changes made to the parent page.
53930 if( ISAUTOVACUUM ){
53931 ptrmapPut(pBt, pgnoNew, PTRMAP_BTREE, pParent->pgno, &rc);
53932 if( szCell>pNew->minLocal ){
53933 ptrmapPutOvflPtr(pNew, pCell, &rc);
53937 /* Create a divider cell to insert into pParent. The divider cell
53938 ** consists of a 4-byte page number (the page number of pPage) and
53939 ** a variable length key value (which must be the same value as the
53940 ** largest key on pPage).
53942 ** To find the largest key value on pPage, first find the right-most
53943 ** cell on pPage. The first two fields of this cell are the
53944 ** record-length (a variable length integer at most 32-bits in size)
53945 ** and the key value (a variable length integer, may have any value).
53946 ** The first of the while(...) loops below skips over the record-length
53947 ** field. The second while(...) loop copies the key value from the
53948 ** cell on pPage into the pSpace buffer.
53950 pCell = findCell(pPage, pPage->nCell-1);
53951 pStop = &pCell[9];
53952 while( (*(pCell++)&0x80) && pCell<pStop );
53953 pStop = &pCell[9];
53954 while( ((*(pOut++) = *(pCell++))&0x80) && pCell<pStop );
53956 /* Insert the new divider cell into pParent. */
53957 insertCell(pParent, pParent->nCell, pSpace, (int)(pOut-pSpace),
53958 0, pPage->pgno, &rc);
53960 /* Set the right-child pointer of pParent to point to the new page. */
53961 put4byte(&pParent->aData[pParent->hdrOffset+8], pgnoNew);
53963 /* Release the reference to the new page. */
53964 releasePage(pNew);
53967 return rc;
53969 #endif /* SQLITE_OMIT_QUICKBALANCE */
53971 #if 0
53973 ** This function does not contribute anything to the operation of SQLite.
53974 ** it is sometimes activated temporarily while debugging code responsible
53975 ** for setting pointer-map entries.
53977 static int ptrmapCheckPages(MemPage **apPage, int nPage){
53978 int i, j;
53979 for(i=0; i<nPage; i++){
53980 Pgno n;
53981 u8 e;
53982 MemPage *pPage = apPage[i];
53983 BtShared *pBt = pPage->pBt;
53984 assert( pPage->isInit );
53986 for(j=0; j<pPage->nCell; j++){
53987 CellInfo info;
53988 u8 *z;
53990 z = findCell(pPage, j);
53991 btreeParseCellPtr(pPage, z, &info);
53992 if( info.iOverflow ){
53993 Pgno ovfl = get4byte(&z[info.iOverflow]);
53994 ptrmapGet(pBt, ovfl, &e, &n);
53995 assert( n==pPage->pgno && e==PTRMAP_OVERFLOW1 );
53997 if( !pPage->leaf ){
53998 Pgno child = get4byte(z);
53999 ptrmapGet(pBt, child, &e, &n);
54000 assert( n==pPage->pgno && e==PTRMAP_BTREE );
54003 if( !pPage->leaf ){
54004 Pgno child = get4byte(&pPage->aData[pPage->hdrOffset+8]);
54005 ptrmapGet(pBt, child, &e, &n);
54006 assert( n==pPage->pgno && e==PTRMAP_BTREE );
54009 return 1;
54011 #endif
54014 ** This function is used to copy the contents of the b-tree node stored
54015 ** on page pFrom to page pTo. If page pFrom was not a leaf page, then
54016 ** the pointer-map entries for each child page are updated so that the
54017 ** parent page stored in the pointer map is page pTo. If pFrom contained
54018 ** any cells with overflow page pointers, then the corresponding pointer
54019 ** map entries are also updated so that the parent page is page pTo.
54021 ** If pFrom is currently carrying any overflow cells (entries in the
54022 ** MemPage.aOvfl[] array), they are not copied to pTo.
54024 ** Before returning, page pTo is reinitialized using btreeInitPage().
54026 ** The performance of this function is not critical. It is only used by
54027 ** the balance_shallower() and balance_deeper() procedures, neither of
54028 ** which are called often under normal circumstances.
54030 static void copyNodeContent(MemPage *pFrom, MemPage *pTo, int *pRC){
54031 if( (*pRC)==SQLITE_OK ){
54032 BtShared * const pBt = pFrom->pBt;
54033 u8 * const aFrom = pFrom->aData;
54034 u8 * const aTo = pTo->aData;
54035 int const iFromHdr = pFrom->hdrOffset;
54036 int const iToHdr = ((pTo->pgno==1) ? 100 : 0);
54037 int rc;
54038 int iData;
54041 assert( pFrom->isInit );
54042 assert( pFrom->nFree>=iToHdr );
54043 assert( get2byte(&aFrom[iFromHdr+5]) <= (int)pBt->usableSize );
54045 /* Copy the b-tree node content from page pFrom to page pTo. */
54046 iData = get2byte(&aFrom[iFromHdr+5]);
54047 memcpy(&aTo[iData], &aFrom[iData], pBt->usableSize-iData);
54048 memcpy(&aTo[iToHdr], &aFrom[iFromHdr], pFrom->cellOffset + 2*pFrom->nCell);
54050 /* Reinitialize page pTo so that the contents of the MemPage structure
54051 ** match the new data. The initialization of pTo can actually fail under
54052 ** fairly obscure circumstances, even though it is a copy of initialized
54053 ** page pFrom.
54055 pTo->isInit = 0;
54056 rc = btreeInitPage(pTo);
54057 if( rc!=SQLITE_OK ){
54058 *pRC = rc;
54059 return;
54062 /* If this is an auto-vacuum database, update the pointer-map entries
54063 ** for any b-tree or overflow pages that pTo now contains the pointers to.
54065 if( ISAUTOVACUUM ){
54066 *pRC = setChildPtrmaps(pTo);
54072 ** This routine redistributes cells on the iParentIdx'th child of pParent
54073 ** (hereafter "the page") and up to 2 siblings so that all pages have about the
54074 ** same amount of free space. Usually a single sibling on either side of the
54075 ** page are used in the balancing, though both siblings might come from one
54076 ** side if the page is the first or last child of its parent. If the page
54077 ** has fewer than 2 siblings (something which can only happen if the page
54078 ** is a root page or a child of a root page) then all available siblings
54079 ** participate in the balancing.
54081 ** The number of siblings of the page might be increased or decreased by
54082 ** one or two in an effort to keep pages nearly full but not over full.
54084 ** Note that when this routine is called, some of the cells on the page
54085 ** might not actually be stored in MemPage.aData[]. This can happen
54086 ** if the page is overfull. This routine ensures that all cells allocated
54087 ** to the page and its siblings fit into MemPage.aData[] before returning.
54089 ** In the course of balancing the page and its siblings, cells may be
54090 ** inserted into or removed from the parent page (pParent). Doing so
54091 ** may cause the parent page to become overfull or underfull. If this
54092 ** happens, it is the responsibility of the caller to invoke the correct
54093 ** balancing routine to fix this problem (see the balance() routine).
54095 ** If this routine fails for any reason, it might leave the database
54096 ** in a corrupted state. So if this routine fails, the database should
54097 ** be rolled back.
54099 ** The third argument to this function, aOvflSpace, is a pointer to a
54100 ** buffer big enough to hold one page. If while inserting cells into the parent
54101 ** page (pParent) the parent page becomes overfull, this buffer is
54102 ** used to store the parent's overflow cells. Because this function inserts
54103 ** a maximum of four divider cells into the parent page, and the maximum
54104 ** size of a cell stored within an internal node is always less than 1/4
54105 ** of the page-size, the aOvflSpace[] buffer is guaranteed to be large
54106 ** enough for all overflow cells.
54108 ** If aOvflSpace is set to a null pointer, this function returns
54109 ** SQLITE_NOMEM.
54111 static int balance_nonroot(
54112 MemPage *pParent, /* Parent page of siblings being balanced */
54113 int iParentIdx, /* Index of "the page" in pParent */
54114 u8 *aOvflSpace, /* page-size bytes of space for parent ovfl */
54115 int isRoot /* True if pParent is a root-page */
54117 BtShared *pBt; /* The whole database */
54118 int nCell = 0; /* Number of cells in apCell[] */
54119 int nMaxCells = 0; /* Allocated size of apCell, szCell, aFrom. */
54120 int nNew = 0; /* Number of pages in apNew[] */
54121 int nOld; /* Number of pages in apOld[] */
54122 int i, j, k; /* Loop counters */
54123 int nxDiv; /* Next divider slot in pParent->aCell[] */
54124 int rc = SQLITE_OK; /* The return code */
54125 u16 leafCorrection; /* 4 if pPage is a leaf. 0 if not */
54126 int leafData; /* True if pPage is a leaf of a LEAFDATA tree */
54127 int usableSpace; /* Bytes in pPage beyond the header */
54128 int pageFlags; /* Value of pPage->aData[0] */
54129 int subtotal; /* Subtotal of bytes in cells on one page */
54130 int iSpace1 = 0; /* First unused byte of aSpace1[] */
54131 int iOvflSpace = 0; /* First unused byte of aOvflSpace[] */
54132 int szScratch; /* Size of scratch memory requested */
54133 MemPage *apOld[NB]; /* pPage and up to two siblings */
54134 MemPage *apCopy[NB]; /* Private copies of apOld[] pages */
54135 MemPage *apNew[NB+2]; /* pPage and up to NB siblings after balancing */
54136 u8 *pRight; /* Location in parent of right-sibling pointer */
54137 u8 *apDiv[NB-1]; /* Divider cells in pParent */
54138 int cntNew[NB+2]; /* Index in aCell[] of cell after i-th page */
54139 int szNew[NB+2]; /* Combined size of cells place on i-th page */
54140 u8 **apCell = 0; /* All cells begin balanced */
54141 u16 *szCell; /* Local size of all cells in apCell[] */
54142 u8 *aSpace1; /* Space for copies of dividers cells */
54143 Pgno pgno; /* Temp var to store a page number in */
54145 pBt = pParent->pBt;
54146 assert( sqlite3_mutex_held(pBt->mutex) );
54147 assert( sqlite3PagerIswriteable(pParent->pDbPage) );
54149 #if 0
54150 TRACE(("BALANCE: begin page %d child of %d\n", pPage->pgno, pParent->pgno));
54151 #endif
54153 /* At this point pParent may have at most one overflow cell. And if
54154 ** this overflow cell is present, it must be the cell with
54155 ** index iParentIdx. This scenario comes about when this function
54156 ** is called (indirectly) from sqlite3BtreeDelete().
54158 assert( pParent->nOverflow==0 || pParent->nOverflow==1 );
54159 assert( pParent->nOverflow==0 || pParent->aOvfl[0].idx==iParentIdx );
54161 if( !aOvflSpace ){
54162 return SQLITE_NOMEM;
54165 /* Find the sibling pages to balance. Also locate the cells in pParent
54166 ** that divide the siblings. An attempt is made to find NN siblings on
54167 ** either side of pPage. More siblings are taken from one side, however,
54168 ** if there are fewer than NN siblings on the other side. If pParent
54169 ** has NB or fewer children then all children of pParent are taken.
54171 ** This loop also drops the divider cells from the parent page. This
54172 ** way, the remainder of the function does not have to deal with any
54173 ** overflow cells in the parent page, since if any existed they will
54174 ** have already been removed.
54176 i = pParent->nOverflow + pParent->nCell;
54177 if( i<2 ){
54178 nxDiv = 0;
54179 nOld = i+1;
54180 }else{
54181 nOld = 3;
54182 if( iParentIdx==0 ){
54183 nxDiv = 0;
54184 }else if( iParentIdx==i ){
54185 nxDiv = i-2;
54186 }else{
54187 nxDiv = iParentIdx-1;
54189 i = 2;
54191 if( (i+nxDiv-pParent->nOverflow)==pParent->nCell ){
54192 pRight = &pParent->aData[pParent->hdrOffset+8];
54193 }else{
54194 pRight = findCell(pParent, i+nxDiv-pParent->nOverflow);
54196 pgno = get4byte(pRight);
54197 while( 1 ){
54198 rc = getAndInitPage(pBt, pgno, &apOld[i]);
54199 if( rc ){
54200 memset(apOld, 0, (i+1)*sizeof(MemPage*));
54201 goto balance_cleanup;
54203 nMaxCells += 1+apOld[i]->nCell+apOld[i]->nOverflow;
54204 if( (i--)==0 ) break;
54206 if( i+nxDiv==pParent->aOvfl[0].idx && pParent->nOverflow ){
54207 apDiv[i] = pParent->aOvfl[0].pCell;
54208 pgno = get4byte(apDiv[i]);
54209 szNew[i] = cellSizePtr(pParent, apDiv[i]);
54210 pParent->nOverflow = 0;
54211 }else{
54212 apDiv[i] = findCell(pParent, i+nxDiv-pParent->nOverflow);
54213 pgno = get4byte(apDiv[i]);
54214 szNew[i] = cellSizePtr(pParent, apDiv[i]);
54216 /* Drop the cell from the parent page. apDiv[i] still points to
54217 ** the cell within the parent, even though it has been dropped.
54218 ** This is safe because dropping a cell only overwrites the first
54219 ** four bytes of it, and this function does not need the first
54220 ** four bytes of the divider cell. So the pointer is safe to use
54221 ** later on.
54223 ** Unless SQLite is compiled in secure-delete mode. In this case,
54224 ** the dropCell() routine will overwrite the entire cell with zeroes.
54225 ** In this case, temporarily copy the cell into the aOvflSpace[]
54226 ** buffer. It will be copied out again as soon as the aSpace[] buffer
54227 ** is allocated. */
54228 if( pBt->secureDelete ){
54229 int iOff = SQLITE_PTR_TO_INT(apDiv[i]) - SQLITE_PTR_TO_INT(pParent->aData);
54230 if( (iOff+szNew[i])>(int)pBt->usableSize ){
54231 rc = SQLITE_CORRUPT_BKPT;
54232 memset(apOld, 0, (i+1)*sizeof(MemPage*));
54233 goto balance_cleanup;
54234 }else{
54235 memcpy(&aOvflSpace[iOff], apDiv[i], szNew[i]);
54236 apDiv[i] = &aOvflSpace[apDiv[i]-pParent->aData];
54239 dropCell(pParent, i+nxDiv-pParent->nOverflow, szNew[i], &rc);
54243 /* Make nMaxCells a multiple of 4 in order to preserve 8-byte
54244 ** alignment */
54245 nMaxCells = (nMaxCells + 3)&~3;
54248 ** Allocate space for memory structures
54250 k = pBt->pageSize + ROUND8(sizeof(MemPage));
54251 szScratch =
54252 nMaxCells*sizeof(u8*) /* apCell */
54253 + nMaxCells*sizeof(u16) /* szCell */
54254 + pBt->pageSize /* aSpace1 */
54255 + k*nOld; /* Page copies (apCopy) */
54256 apCell = sqlite3ScratchMalloc( szScratch );
54257 if( apCell==0 ){
54258 rc = SQLITE_NOMEM;
54259 goto balance_cleanup;
54261 szCell = (u16*)&apCell[nMaxCells];
54262 aSpace1 = (u8*)&szCell[nMaxCells];
54263 assert( EIGHT_BYTE_ALIGNMENT(aSpace1) );
54266 ** Load pointers to all cells on sibling pages and the divider cells
54267 ** into the local apCell[] array. Make copies of the divider cells
54268 ** into space obtained from aSpace1[] and remove the the divider Cells
54269 ** from pParent.
54271 ** If the siblings are on leaf pages, then the child pointers of the
54272 ** divider cells are stripped from the cells before they are copied
54273 ** into aSpace1[]. In this way, all cells in apCell[] are without
54274 ** child pointers. If siblings are not leaves, then all cell in
54275 ** apCell[] include child pointers. Either way, all cells in apCell[]
54276 ** are alike.
54278 ** leafCorrection: 4 if pPage is a leaf. 0 if pPage is not a leaf.
54279 ** leafData: 1 if pPage holds key+data and pParent holds only keys.
54281 leafCorrection = apOld[0]->leaf*4;
54282 leafData = apOld[0]->hasData;
54283 for(i=0; i<nOld; i++){
54284 int limit;
54286 /* Before doing anything else, take a copy of the i'th original sibling
54287 ** The rest of this function will use data from the copies rather
54288 ** that the original pages since the original pages will be in the
54289 ** process of being overwritten. */
54290 MemPage *pOld = apCopy[i] = (MemPage*)&aSpace1[pBt->pageSize + k*i];
54291 memcpy(pOld, apOld[i], sizeof(MemPage));
54292 pOld->aData = (void*)&pOld[1];
54293 memcpy(pOld->aData, apOld[i]->aData, pBt->pageSize);
54295 limit = pOld->nCell+pOld->nOverflow;
54296 if( pOld->nOverflow>0 ){
54297 for(j=0; j<limit; j++){
54298 assert( nCell<nMaxCells );
54299 apCell[nCell] = findOverflowCell(pOld, j);
54300 szCell[nCell] = cellSizePtr(pOld, apCell[nCell]);
54301 nCell++;
54303 }else{
54304 u8 *aData = pOld->aData;
54305 u16 maskPage = pOld->maskPage;
54306 u16 cellOffset = pOld->cellOffset;
54307 for(j=0; j<limit; j++){
54308 assert( nCell<nMaxCells );
54309 apCell[nCell] = findCellv2(aData, maskPage, cellOffset, j);
54310 szCell[nCell] = cellSizePtr(pOld, apCell[nCell]);
54311 nCell++;
54314 if( i<nOld-1 && !leafData){
54315 u16 sz = (u16)szNew[i];
54316 u8 *pTemp;
54317 assert( nCell<nMaxCells );
54318 szCell[nCell] = sz;
54319 pTemp = &aSpace1[iSpace1];
54320 iSpace1 += sz;
54321 assert( sz<=pBt->maxLocal+23 );
54322 assert( iSpace1 <= (int)pBt->pageSize );
54323 memcpy(pTemp, apDiv[i], sz);
54324 apCell[nCell] = pTemp+leafCorrection;
54325 assert( leafCorrection==0 || leafCorrection==4 );
54326 szCell[nCell] = szCell[nCell] - leafCorrection;
54327 if( !pOld->leaf ){
54328 assert( leafCorrection==0 );
54329 assert( pOld->hdrOffset==0 );
54330 /* The right pointer of the child page pOld becomes the left
54331 ** pointer of the divider cell */
54332 memcpy(apCell[nCell], &pOld->aData[8], 4);
54333 }else{
54334 assert( leafCorrection==4 );
54335 if( szCell[nCell]<4 ){
54336 /* Do not allow any cells smaller than 4 bytes. */
54337 szCell[nCell] = 4;
54340 nCell++;
54345 ** Figure out the number of pages needed to hold all nCell cells.
54346 ** Store this number in "k". Also compute szNew[] which is the total
54347 ** size of all cells on the i-th page and cntNew[] which is the index
54348 ** in apCell[] of the cell that divides page i from page i+1.
54349 ** cntNew[k] should equal nCell.
54351 ** Values computed by this block:
54353 ** k: The total number of sibling pages
54354 ** szNew[i]: Spaced used on the i-th sibling page.
54355 ** cntNew[i]: Index in apCell[] and szCell[] for the first cell to
54356 ** the right of the i-th sibling page.
54357 ** usableSpace: Number of bytes of space available on each sibling.
54360 usableSpace = pBt->usableSize - 12 + leafCorrection;
54361 for(subtotal=k=i=0; i<nCell; i++){
54362 assert( i<nMaxCells );
54363 subtotal += szCell[i] + 2;
54364 if( subtotal > usableSpace ){
54365 szNew[k] = subtotal - szCell[i];
54366 cntNew[k] = i;
54367 if( leafData ){ i--; }
54368 subtotal = 0;
54369 k++;
54370 if( k>NB+1 ){ rc = SQLITE_CORRUPT_BKPT; goto balance_cleanup; }
54373 szNew[k] = subtotal;
54374 cntNew[k] = nCell;
54375 k++;
54378 ** The packing computed by the previous block is biased toward the siblings
54379 ** on the left side. The left siblings are always nearly full, while the
54380 ** right-most sibling might be nearly empty. This block of code attempts
54381 ** to adjust the packing of siblings to get a better balance.
54383 ** This adjustment is more than an optimization. The packing above might
54384 ** be so out of balance as to be illegal. For example, the right-most
54385 ** sibling might be completely empty. This adjustment is not optional.
54387 for(i=k-1; i>0; i--){
54388 int szRight = szNew[i]; /* Size of sibling on the right */
54389 int szLeft = szNew[i-1]; /* Size of sibling on the left */
54390 int r; /* Index of right-most cell in left sibling */
54391 int d; /* Index of first cell to the left of right sibling */
54393 r = cntNew[i-1] - 1;
54394 d = r + 1 - leafData;
54395 assert( d<nMaxCells );
54396 assert( r<nMaxCells );
54397 while( szRight==0 || szRight+szCell[d]+2<=szLeft-(szCell[r]+2) ){
54398 szRight += szCell[d] + 2;
54399 szLeft -= szCell[r] + 2;
54400 cntNew[i-1]--;
54401 r = cntNew[i-1] - 1;
54402 d = r + 1 - leafData;
54404 szNew[i] = szRight;
54405 szNew[i-1] = szLeft;
54408 /* Either we found one or more cells (cntnew[0])>0) or pPage is
54409 ** a virtual root page. A virtual root page is when the real root
54410 ** page is page 1 and we are the only child of that page.
54412 assert( cntNew[0]>0 || (pParent->pgno==1 && pParent->nCell==0) );
54414 TRACE(("BALANCE: old: %d %d %d ",
54415 apOld[0]->pgno,
54416 nOld>=2 ? apOld[1]->pgno : 0,
54417 nOld>=3 ? apOld[2]->pgno : 0
54421 ** Allocate k new pages. Reuse old pages where possible.
54423 if( apOld[0]->pgno<=1 ){
54424 rc = SQLITE_CORRUPT_BKPT;
54425 goto balance_cleanup;
54427 pageFlags = apOld[0]->aData[0];
54428 for(i=0; i<k; i++){
54429 MemPage *pNew;
54430 if( i<nOld ){
54431 pNew = apNew[i] = apOld[i];
54432 apOld[i] = 0;
54433 rc = sqlite3PagerWrite(pNew->pDbPage);
54434 nNew++;
54435 if( rc ) goto balance_cleanup;
54436 }else{
54437 assert( i>0 );
54438 rc = allocateBtreePage(pBt, &pNew, &pgno, pgno, 0);
54439 if( rc ) goto balance_cleanup;
54440 apNew[i] = pNew;
54441 nNew++;
54443 /* Set the pointer-map entry for the new sibling page. */
54444 if( ISAUTOVACUUM ){
54445 ptrmapPut(pBt, pNew->pgno, PTRMAP_BTREE, pParent->pgno, &rc);
54446 if( rc!=SQLITE_OK ){
54447 goto balance_cleanup;
54453 /* Free any old pages that were not reused as new pages.
54455 while( i<nOld ){
54456 freePage(apOld[i], &rc);
54457 if( rc ) goto balance_cleanup;
54458 releasePage(apOld[i]);
54459 apOld[i] = 0;
54460 i++;
54464 ** Put the new pages in accending order. This helps to
54465 ** keep entries in the disk file in order so that a scan
54466 ** of the table is a linear scan through the file. That
54467 ** in turn helps the operating system to deliver pages
54468 ** from the disk more rapidly.
54470 ** An O(n^2) insertion sort algorithm is used, but since
54471 ** n is never more than NB (a small constant), that should
54472 ** not be a problem.
54474 ** When NB==3, this one optimization makes the database
54475 ** about 25% faster for large insertions and deletions.
54477 for(i=0; i<k-1; i++){
54478 int minV = apNew[i]->pgno;
54479 int minI = i;
54480 for(j=i+1; j<k; j++){
54481 if( apNew[j]->pgno<(unsigned)minV ){
54482 minI = j;
54483 minV = apNew[j]->pgno;
54486 if( minI>i ){
54487 MemPage *pT;
54488 pT = apNew[i];
54489 apNew[i] = apNew[minI];
54490 apNew[minI] = pT;
54493 TRACE(("new: %d(%d) %d(%d) %d(%d) %d(%d) %d(%d)\n",
54494 apNew[0]->pgno, szNew[0],
54495 nNew>=2 ? apNew[1]->pgno : 0, nNew>=2 ? szNew[1] : 0,
54496 nNew>=3 ? apNew[2]->pgno : 0, nNew>=3 ? szNew[2] : 0,
54497 nNew>=4 ? apNew[3]->pgno : 0, nNew>=4 ? szNew[3] : 0,
54498 nNew>=5 ? apNew[4]->pgno : 0, nNew>=5 ? szNew[4] : 0));
54500 assert( sqlite3PagerIswriteable(pParent->pDbPage) );
54501 put4byte(pRight, apNew[nNew-1]->pgno);
54504 ** Evenly distribute the data in apCell[] across the new pages.
54505 ** Insert divider cells into pParent as necessary.
54507 j = 0;
54508 for(i=0; i<nNew; i++){
54509 /* Assemble the new sibling page. */
54510 MemPage *pNew = apNew[i];
54511 assert( j<nMaxCells );
54512 zeroPage(pNew, pageFlags);
54513 assemblePage(pNew, cntNew[i]-j, &apCell[j], &szCell[j]);
54514 assert( pNew->nCell>0 || (nNew==1 && cntNew[0]==0) );
54515 assert( pNew->nOverflow==0 );
54517 j = cntNew[i];
54519 /* If the sibling page assembled above was not the right-most sibling,
54520 ** insert a divider cell into the parent page.
54522 assert( i<nNew-1 || j==nCell );
54523 if( j<nCell ){
54524 u8 *pCell;
54525 u8 *pTemp;
54526 int sz;
54528 assert( j<nMaxCells );
54529 pCell = apCell[j];
54530 sz = szCell[j] + leafCorrection;
54531 pTemp = &aOvflSpace[iOvflSpace];
54532 if( !pNew->leaf ){
54533 memcpy(&pNew->aData[8], pCell, 4);
54534 }else if( leafData ){
54535 /* If the tree is a leaf-data tree, and the siblings are leaves,
54536 ** then there is no divider cell in apCell[]. Instead, the divider
54537 ** cell consists of the integer key for the right-most cell of
54538 ** the sibling-page assembled above only.
54540 CellInfo info;
54541 j--;
54542 btreeParseCellPtr(pNew, apCell[j], &info);
54543 pCell = pTemp;
54544 sz = 4 + putVarint(&pCell[4], info.nKey);
54545 pTemp = 0;
54546 }else{
54547 pCell -= 4;
54548 /* Obscure case for non-leaf-data trees: If the cell at pCell was
54549 ** previously stored on a leaf node, and its reported size was 4
54550 ** bytes, then it may actually be smaller than this
54551 ** (see btreeParseCellPtr(), 4 bytes is the minimum size of
54552 ** any cell). But it is important to pass the correct size to
54553 ** insertCell(), so reparse the cell now.
54555 ** Note that this can never happen in an SQLite data file, as all
54556 ** cells are at least 4 bytes. It only happens in b-trees used
54557 ** to evaluate "IN (SELECT ...)" and similar clauses.
54559 if( szCell[j]==4 ){
54560 assert(leafCorrection==4);
54561 sz = cellSizePtr(pParent, pCell);
54564 iOvflSpace += sz;
54565 assert( sz<=pBt->maxLocal+23 );
54566 assert( iOvflSpace <= (int)pBt->pageSize );
54567 insertCell(pParent, nxDiv, pCell, sz, pTemp, pNew->pgno, &rc);
54568 if( rc!=SQLITE_OK ) goto balance_cleanup;
54569 assert( sqlite3PagerIswriteable(pParent->pDbPage) );
54571 j++;
54572 nxDiv++;
54575 assert( j==nCell );
54576 assert( nOld>0 );
54577 assert( nNew>0 );
54578 if( (pageFlags & PTF_LEAF)==0 ){
54579 u8 *zChild = &apCopy[nOld-1]->aData[8];
54580 memcpy(&apNew[nNew-1]->aData[8], zChild, 4);
54583 if( isRoot && pParent->nCell==0 && pParent->hdrOffset<=apNew[0]->nFree ){
54584 /* The root page of the b-tree now contains no cells. The only sibling
54585 ** page is the right-child of the parent. Copy the contents of the
54586 ** child page into the parent, decreasing the overall height of the
54587 ** b-tree structure by one. This is described as the "balance-shallower"
54588 ** sub-algorithm in some documentation.
54590 ** If this is an auto-vacuum database, the call to copyNodeContent()
54591 ** sets all pointer-map entries corresponding to database image pages
54592 ** for which the pointer is stored within the content being copied.
54594 ** The second assert below verifies that the child page is defragmented
54595 ** (it must be, as it was just reconstructed using assemblePage()). This
54596 ** is important if the parent page happens to be page 1 of the database
54597 ** image. */
54598 assert( nNew==1 );
54599 assert( apNew[0]->nFree ==
54600 (get2byte(&apNew[0]->aData[5])-apNew[0]->cellOffset-apNew[0]->nCell*2)
54602 copyNodeContent(apNew[0], pParent, &rc);
54603 freePage(apNew[0], &rc);
54604 }else if( ISAUTOVACUUM ){
54605 /* Fix the pointer-map entries for all the cells that were shifted around.
54606 ** There are several different types of pointer-map entries that need to
54607 ** be dealt with by this routine. Some of these have been set already, but
54608 ** many have not. The following is a summary:
54610 ** 1) The entries associated with new sibling pages that were not
54611 ** siblings when this function was called. These have already
54612 ** been set. We don't need to worry about old siblings that were
54613 ** moved to the free-list - the freePage() code has taken care
54614 ** of those.
54616 ** 2) The pointer-map entries associated with the first overflow
54617 ** page in any overflow chains used by new divider cells. These
54618 ** have also already been taken care of by the insertCell() code.
54620 ** 3) If the sibling pages are not leaves, then the child pages of
54621 ** cells stored on the sibling pages may need to be updated.
54623 ** 4) If the sibling pages are not internal intkey nodes, then any
54624 ** overflow pages used by these cells may need to be updated
54625 ** (internal intkey nodes never contain pointers to overflow pages).
54627 ** 5) If the sibling pages are not leaves, then the pointer-map
54628 ** entries for the right-child pages of each sibling may need
54629 ** to be updated.
54631 ** Cases 1 and 2 are dealt with above by other code. The next
54632 ** block deals with cases 3 and 4 and the one after that, case 5. Since
54633 ** setting a pointer map entry is a relatively expensive operation, this
54634 ** code only sets pointer map entries for child or overflow pages that have
54635 ** actually moved between pages. */
54636 MemPage *pNew = apNew[0];
54637 MemPage *pOld = apCopy[0];
54638 int nOverflow = pOld->nOverflow;
54639 int iNextOld = pOld->nCell + nOverflow;
54640 int iOverflow = (nOverflow ? pOld->aOvfl[0].idx : -1);
54641 j = 0; /* Current 'old' sibling page */
54642 k = 0; /* Current 'new' sibling page */
54643 for(i=0; i<nCell; i++){
54644 int isDivider = 0;
54645 while( i==iNextOld ){
54646 /* Cell i is the cell immediately following the last cell on old
54647 ** sibling page j. If the siblings are not leaf pages of an
54648 ** intkey b-tree, then cell i was a divider cell. */
54649 pOld = apCopy[++j];
54650 iNextOld = i + !leafData + pOld->nCell + pOld->nOverflow;
54651 if( pOld->nOverflow ){
54652 nOverflow = pOld->nOverflow;
54653 iOverflow = i + !leafData + pOld->aOvfl[0].idx;
54655 isDivider = !leafData;
54658 assert(nOverflow>0 || iOverflow<i );
54659 assert(nOverflow<2 || pOld->aOvfl[0].idx==pOld->aOvfl[1].idx-1);
54660 assert(nOverflow<3 || pOld->aOvfl[1].idx==pOld->aOvfl[2].idx-1);
54661 if( i==iOverflow ){
54662 isDivider = 1;
54663 if( (--nOverflow)>0 ){
54664 iOverflow++;
54668 if( i==cntNew[k] ){
54669 /* Cell i is the cell immediately following the last cell on new
54670 ** sibling page k. If the siblings are not leaf pages of an
54671 ** intkey b-tree, then cell i is a divider cell. */
54672 pNew = apNew[++k];
54673 if( !leafData ) continue;
54675 assert( j<nOld );
54676 assert( k<nNew );
54678 /* If the cell was originally divider cell (and is not now) or
54679 ** an overflow cell, or if the cell was located on a different sibling
54680 ** page before the balancing, then the pointer map entries associated
54681 ** with any child or overflow pages need to be updated. */
54682 if( isDivider || pOld->pgno!=pNew->pgno ){
54683 if( !leafCorrection ){
54684 ptrmapPut(pBt, get4byte(apCell[i]), PTRMAP_BTREE, pNew->pgno, &rc);
54686 if( szCell[i]>pNew->minLocal ){
54687 ptrmapPutOvflPtr(pNew, apCell[i], &rc);
54692 if( !leafCorrection ){
54693 for(i=0; i<nNew; i++){
54694 u32 key = get4byte(&apNew[i]->aData[8]);
54695 ptrmapPut(pBt, key, PTRMAP_BTREE, apNew[i]->pgno, &rc);
54699 #if 0
54700 /* The ptrmapCheckPages() contains assert() statements that verify that
54701 ** all pointer map pages are set correctly. This is helpful while
54702 ** debugging. This is usually disabled because a corrupt database may
54703 ** cause an assert() statement to fail. */
54704 ptrmapCheckPages(apNew, nNew);
54705 ptrmapCheckPages(&pParent, 1);
54706 #endif
54709 assert( pParent->isInit );
54710 TRACE(("BALANCE: finished: old=%d new=%d cells=%d\n",
54711 nOld, nNew, nCell));
54714 ** Cleanup before returning.
54716 balance_cleanup:
54717 sqlite3ScratchFree(apCell);
54718 for(i=0; i<nOld; i++){
54719 releasePage(apOld[i]);
54721 for(i=0; i<nNew; i++){
54722 releasePage(apNew[i]);
54725 return rc;
54730 ** This function is called when the root page of a b-tree structure is
54731 ** overfull (has one or more overflow pages).
54733 ** A new child page is allocated and the contents of the current root
54734 ** page, including overflow cells, are copied into the child. The root
54735 ** page is then overwritten to make it an empty page with the right-child
54736 ** pointer pointing to the new page.
54738 ** Before returning, all pointer-map entries corresponding to pages
54739 ** that the new child-page now contains pointers to are updated. The
54740 ** entry corresponding to the new right-child pointer of the root
54741 ** page is also updated.
54743 ** If successful, *ppChild is set to contain a reference to the child
54744 ** page and SQLITE_OK is returned. In this case the caller is required
54745 ** to call releasePage() on *ppChild exactly once. If an error occurs,
54746 ** an error code is returned and *ppChild is set to 0.
54748 static int balance_deeper(MemPage *pRoot, MemPage **ppChild){
54749 int rc; /* Return value from subprocedures */
54750 MemPage *pChild = 0; /* Pointer to a new child page */
54751 Pgno pgnoChild = 0; /* Page number of the new child page */
54752 BtShared *pBt = pRoot->pBt; /* The BTree */
54754 assert( pRoot->nOverflow>0 );
54755 assert( sqlite3_mutex_held(pBt->mutex) );
54757 /* Make pRoot, the root page of the b-tree, writable. Allocate a new
54758 ** page that will become the new right-child of pPage. Copy the contents
54759 ** of the node stored on pRoot into the new child page.
54761 rc = sqlite3PagerWrite(pRoot->pDbPage);
54762 if( rc==SQLITE_OK ){
54763 rc = allocateBtreePage(pBt,&pChild,&pgnoChild,pRoot->pgno,0);
54764 copyNodeContent(pRoot, pChild, &rc);
54765 if( ISAUTOVACUUM ){
54766 ptrmapPut(pBt, pgnoChild, PTRMAP_BTREE, pRoot->pgno, &rc);
54769 if( rc ){
54770 *ppChild = 0;
54771 releasePage(pChild);
54772 return rc;
54774 assert( sqlite3PagerIswriteable(pChild->pDbPage) );
54775 assert( sqlite3PagerIswriteable(pRoot->pDbPage) );
54776 assert( pChild->nCell==pRoot->nCell );
54778 TRACE(("BALANCE: copy root %d into %d\n", pRoot->pgno, pChild->pgno));
54780 /* Copy the overflow cells from pRoot to pChild */
54781 memcpy(pChild->aOvfl, pRoot->aOvfl, pRoot->nOverflow*sizeof(pRoot->aOvfl[0]));
54782 pChild->nOverflow = pRoot->nOverflow;
54784 /* Zero the contents of pRoot. Then install pChild as the right-child. */
54785 zeroPage(pRoot, pChild->aData[0] & ~PTF_LEAF);
54786 put4byte(&pRoot->aData[pRoot->hdrOffset+8], pgnoChild);
54788 *ppChild = pChild;
54789 return SQLITE_OK;
54793 ** The page that pCur currently points to has just been modified in
54794 ** some way. This function figures out if this modification means the
54795 ** tree needs to be balanced, and if so calls the appropriate balancing
54796 ** routine. Balancing routines are:
54798 ** balance_quick()
54799 ** balance_deeper()
54800 ** balance_nonroot()
54802 static int balance(BtCursor *pCur){
54803 int rc = SQLITE_OK;
54804 const int nMin = pCur->pBt->usableSize * 2 / 3;
54805 u8 aBalanceQuickSpace[13];
54806 u8 *pFree = 0;
54808 TESTONLY( int balance_quick_called = 0 );
54809 TESTONLY( int balance_deeper_called = 0 );
54811 do {
54812 int iPage = pCur->iPage;
54813 MemPage *pPage = pCur->apPage[iPage];
54815 if( iPage==0 ){
54816 if( pPage->nOverflow ){
54817 /* The root page of the b-tree is overfull. In this case call the
54818 ** balance_deeper() function to create a new child for the root-page
54819 ** and copy the current contents of the root-page to it. The
54820 ** next iteration of the do-loop will balance the child page.
54822 assert( (balance_deeper_called++)==0 );
54823 rc = balance_deeper(pPage, &pCur->apPage[1]);
54824 if( rc==SQLITE_OK ){
54825 pCur->iPage = 1;
54826 pCur->aiIdx[0] = 0;
54827 pCur->aiIdx[1] = 0;
54828 assert( pCur->apPage[1]->nOverflow );
54830 }else{
54831 break;
54833 }else if( pPage->nOverflow==0 && pPage->nFree<=nMin ){
54834 break;
54835 }else{
54836 MemPage * const pParent = pCur->apPage[iPage-1];
54837 int const iIdx = pCur->aiIdx[iPage-1];
54839 rc = sqlite3PagerWrite(pParent->pDbPage);
54840 if( rc==SQLITE_OK ){
54841 #ifndef SQLITE_OMIT_QUICKBALANCE
54842 if( pPage->hasData
54843 && pPage->nOverflow==1
54844 && pPage->aOvfl[0].idx==pPage->nCell
54845 && pParent->pgno!=1
54846 && pParent->nCell==iIdx
54848 /* Call balance_quick() to create a new sibling of pPage on which
54849 ** to store the overflow cell. balance_quick() inserts a new cell
54850 ** into pParent, which may cause pParent overflow. If this
54851 ** happens, the next interation of the do-loop will balance pParent
54852 ** use either balance_nonroot() or balance_deeper(). Until this
54853 ** happens, the overflow cell is stored in the aBalanceQuickSpace[]
54854 ** buffer.
54856 ** The purpose of the following assert() is to check that only a
54857 ** single call to balance_quick() is made for each call to this
54858 ** function. If this were not verified, a subtle bug involving reuse
54859 ** of the aBalanceQuickSpace[] might sneak in.
54861 assert( (balance_quick_called++)==0 );
54862 rc = balance_quick(pParent, pPage, aBalanceQuickSpace);
54863 }else
54864 #endif
54866 /* In this case, call balance_nonroot() to redistribute cells
54867 ** between pPage and up to 2 of its sibling pages. This involves
54868 ** modifying the contents of pParent, which may cause pParent to
54869 ** become overfull or underfull. The next iteration of the do-loop
54870 ** will balance the parent page to correct this.
54872 ** If the parent page becomes overfull, the overflow cell or cells
54873 ** are stored in the pSpace buffer allocated immediately below.
54874 ** A subsequent iteration of the do-loop will deal with this by
54875 ** calling balance_nonroot() (balance_deeper() may be called first,
54876 ** but it doesn't deal with overflow cells - just moves them to a
54877 ** different page). Once this subsequent call to balance_nonroot()
54878 ** has completed, it is safe to release the pSpace buffer used by
54879 ** the previous call, as the overflow cell data will have been
54880 ** copied either into the body of a database page or into the new
54881 ** pSpace buffer passed to the latter call to balance_nonroot().
54883 u8 *pSpace = sqlite3PageMalloc(pCur->pBt->pageSize);
54884 rc = balance_nonroot(pParent, iIdx, pSpace, iPage==1);
54885 if( pFree ){
54886 /* If pFree is not NULL, it points to the pSpace buffer used
54887 ** by a previous call to balance_nonroot(). Its contents are
54888 ** now stored either on real database pages or within the
54889 ** new pSpace buffer, so it may be safely freed here. */
54890 sqlite3PageFree(pFree);
54893 /* The pSpace buffer will be freed after the next call to
54894 ** balance_nonroot(), or just before this function returns, whichever
54895 ** comes first. */
54896 pFree = pSpace;
54900 pPage->nOverflow = 0;
54902 /* The next iteration of the do-loop balances the parent page. */
54903 releasePage(pPage);
54904 pCur->iPage--;
54906 }while( rc==SQLITE_OK );
54908 if( pFree ){
54909 sqlite3PageFree(pFree);
54911 return rc;
54916 ** Insert a new record into the BTree. The key is given by (pKey,nKey)
54917 ** and the data is given by (pData,nData). The cursor is used only to
54918 ** define what table the record should be inserted into. The cursor
54919 ** is left pointing at a random location.
54921 ** For an INTKEY table, only the nKey value of the key is used. pKey is
54922 ** ignored. For a ZERODATA table, the pData and nData are both ignored.
54924 ** If the seekResult parameter is non-zero, then a successful call to
54925 ** MovetoUnpacked() to seek cursor pCur to (pKey, nKey) has already
54926 ** been performed. seekResult is the search result returned (a negative
54927 ** number if pCur points at an entry that is smaller than (pKey, nKey), or
54928 ** a positive value if pCur points at an etry that is larger than
54929 ** (pKey, nKey)).
54931 ** If the seekResult parameter is non-zero, then the caller guarantees that
54932 ** cursor pCur is pointing at the existing copy of a row that is to be
54933 ** overwritten. If the seekResult parameter is 0, then cursor pCur may
54934 ** point to any entry or to no entry at all and so this function has to seek
54935 ** the cursor before the new key can be inserted.
54937 SQLITE_PRIVATE int sqlite3BtreeInsert(
54938 BtCursor *pCur, /* Insert data into the table of this cursor */
54939 const void *pKey, i64 nKey, /* The key of the new record */
54940 const void *pData, int nData, /* The data of the new record */
54941 int nZero, /* Number of extra 0 bytes to append to data */
54942 int appendBias, /* True if this is likely an append */
54943 int seekResult /* Result of prior MovetoUnpacked() call */
54945 int rc;
54946 int loc = seekResult; /* -1: before desired location +1: after */
54947 int szNew = 0;
54948 int idx;
54949 MemPage *pPage;
54950 Btree *p = pCur->pBtree;
54951 BtShared *pBt = p->pBt;
54952 unsigned char *oldCell;
54953 unsigned char *newCell = 0;
54955 if( pCur->eState==CURSOR_FAULT ){
54956 assert( pCur->skipNext!=SQLITE_OK );
54957 return pCur->skipNext;
54960 assert( cursorHoldsMutex(pCur) );
54961 assert( pCur->wrFlag && pBt->inTransaction==TRANS_WRITE && !pBt->readOnly );
54962 assert( hasSharedCacheTableLock(p, pCur->pgnoRoot, pCur->pKeyInfo!=0, 2) );
54964 /* Assert that the caller has been consistent. If this cursor was opened
54965 ** expecting an index b-tree, then the caller should be inserting blob
54966 ** keys with no associated data. If the cursor was opened expecting an
54967 ** intkey table, the caller should be inserting integer keys with a
54968 ** blob of associated data. */
54969 assert( (pKey==0)==(pCur->pKeyInfo==0) );
54971 /* If this is an insert into a table b-tree, invalidate any incrblob
54972 ** cursors open on the row being replaced (assuming this is a replace
54973 ** operation - if it is not, the following is a no-op). */
54974 if( pCur->pKeyInfo==0 ){
54975 invalidateIncrblobCursors(p, nKey, 0);
54978 /* Save the positions of any other cursors open on this table.
54980 ** In some cases, the call to btreeMoveto() below is a no-op. For
54981 ** example, when inserting data into a table with auto-generated integer
54982 ** keys, the VDBE layer invokes sqlite3BtreeLast() to figure out the
54983 ** integer key to use. It then calls this function to actually insert the
54984 ** data into the intkey B-Tree. In this case btreeMoveto() recognizes
54985 ** that the cursor is already where it needs to be and returns without
54986 ** doing any work. To avoid thwarting these optimizations, it is important
54987 ** not to clear the cursor here.
54989 rc = saveAllCursors(pBt, pCur->pgnoRoot, pCur);
54990 if( rc ) return rc;
54991 if( !loc ){
54992 rc = btreeMoveto(pCur, pKey, nKey, appendBias, &loc);
54993 if( rc ) return rc;
54995 assert( pCur->eState==CURSOR_VALID || (pCur->eState==CURSOR_INVALID && loc) );
54997 pPage = pCur->apPage[pCur->iPage];
54998 assert( pPage->intKey || nKey>=0 );
54999 assert( pPage->leaf || !pPage->intKey );
55001 TRACE(("INSERT: table=%d nkey=%lld ndata=%d page=%d %s\n",
55002 pCur->pgnoRoot, nKey, nData, pPage->pgno,
55003 loc==0 ? "overwrite" : "new entry"));
55004 assert( pPage->isInit );
55005 allocateTempSpace(pBt);
55006 newCell = pBt->pTmpSpace;
55007 if( newCell==0 ) return SQLITE_NOMEM;
55008 rc = fillInCell(pPage, newCell, pKey, nKey, pData, nData, nZero, &szNew);
55009 if( rc ) goto end_insert;
55010 assert( szNew==cellSizePtr(pPage, newCell) );
55011 assert( szNew <= MX_CELL_SIZE(pBt) );
55012 idx = pCur->aiIdx[pCur->iPage];
55013 if( loc==0 ){
55014 u16 szOld;
55015 assert( idx<pPage->nCell );
55016 rc = sqlite3PagerWrite(pPage->pDbPage);
55017 if( rc ){
55018 goto end_insert;
55020 oldCell = findCell(pPage, idx);
55021 if( !pPage->leaf ){
55022 memcpy(newCell, oldCell, 4);
55024 szOld = cellSizePtr(pPage, oldCell);
55025 rc = clearCell(pPage, oldCell);
55026 dropCell(pPage, idx, szOld, &rc);
55027 if( rc ) goto end_insert;
55028 }else if( loc<0 && pPage->nCell>0 ){
55029 assert( pPage->leaf );
55030 idx = ++pCur->aiIdx[pCur->iPage];
55031 }else{
55032 assert( pPage->leaf );
55034 insertCell(pPage, idx, newCell, szNew, 0, 0, &rc);
55035 assert( rc!=SQLITE_OK || pPage->nCell>0 || pPage->nOverflow>0 );
55037 /* If no error has occured and pPage has an overflow cell, call balance()
55038 ** to redistribute the cells within the tree. Since balance() may move
55039 ** the cursor, zero the BtCursor.info.nSize and BtCursor.validNKey
55040 ** variables.
55042 ** Previous versions of SQLite called moveToRoot() to move the cursor
55043 ** back to the root page as balance() used to invalidate the contents
55044 ** of BtCursor.apPage[] and BtCursor.aiIdx[]. Instead of doing that,
55045 ** set the cursor state to "invalid". This makes common insert operations
55046 ** slightly faster.
55048 ** There is a subtle but important optimization here too. When inserting
55049 ** multiple records into an intkey b-tree using a single cursor (as can
55050 ** happen while processing an "INSERT INTO ... SELECT" statement), it
55051 ** is advantageous to leave the cursor pointing to the last entry in
55052 ** the b-tree if possible. If the cursor is left pointing to the last
55053 ** entry in the table, and the next row inserted has an integer key
55054 ** larger than the largest existing key, it is possible to insert the
55055 ** row without seeking the cursor. This can be a big performance boost.
55057 pCur->info.nSize = 0;
55058 pCur->validNKey = 0;
55059 if( rc==SQLITE_OK && pPage->nOverflow ){
55060 rc = balance(pCur);
55062 /* Must make sure nOverflow is reset to zero even if the balance()
55063 ** fails. Internal data structure corruption will result otherwise.
55064 ** Also, set the cursor state to invalid. This stops saveCursorPosition()
55065 ** from trying to save the current position of the cursor. */
55066 pCur->apPage[pCur->iPage]->nOverflow = 0;
55067 pCur->eState = CURSOR_INVALID;
55069 assert( pCur->apPage[pCur->iPage]->nOverflow==0 );
55071 end_insert:
55072 return rc;
55076 ** Delete the entry that the cursor is pointing to. The cursor
55077 ** is left pointing at a arbitrary location.
55079 SQLITE_PRIVATE int sqlite3BtreeDelete(BtCursor *pCur){
55080 Btree *p = pCur->pBtree;
55081 BtShared *pBt = p->pBt;
55082 int rc; /* Return code */
55083 MemPage *pPage; /* Page to delete cell from */
55084 unsigned char *pCell; /* Pointer to cell to delete */
55085 int iCellIdx; /* Index of cell to delete */
55086 int iCellDepth; /* Depth of node containing pCell */
55088 assert( cursorHoldsMutex(pCur) );
55089 assert( pBt->inTransaction==TRANS_WRITE );
55090 assert( !pBt->readOnly );
55091 assert( pCur->wrFlag );
55092 assert( hasSharedCacheTableLock(p, pCur->pgnoRoot, pCur->pKeyInfo!=0, 2) );
55093 assert( !hasReadConflicts(p, pCur->pgnoRoot) );
55095 if( NEVER(pCur->aiIdx[pCur->iPage]>=pCur->apPage[pCur->iPage]->nCell)
55096 || NEVER(pCur->eState!=CURSOR_VALID)
55098 return SQLITE_ERROR; /* Something has gone awry. */
55101 /* If this is a delete operation to remove a row from a table b-tree,
55102 ** invalidate any incrblob cursors open on the row being deleted. */
55103 if( pCur->pKeyInfo==0 ){
55104 invalidateIncrblobCursors(p, pCur->info.nKey, 0);
55107 iCellDepth = pCur->iPage;
55108 iCellIdx = pCur->aiIdx[iCellDepth];
55109 pPage = pCur->apPage[iCellDepth];
55110 pCell = findCell(pPage, iCellIdx);
55112 /* If the page containing the entry to delete is not a leaf page, move
55113 ** the cursor to the largest entry in the tree that is smaller than
55114 ** the entry being deleted. This cell will replace the cell being deleted
55115 ** from the internal node. The 'previous' entry is used for this instead
55116 ** of the 'next' entry, as the previous entry is always a part of the
55117 ** sub-tree headed by the child page of the cell being deleted. This makes
55118 ** balancing the tree following the delete operation easier. */
55119 if( !pPage->leaf ){
55120 int notUsed;
55121 rc = sqlite3BtreePrevious(pCur, &notUsed);
55122 if( rc ) return rc;
55125 /* Save the positions of any other cursors open on this table before
55126 ** making any modifications. Make the page containing the entry to be
55127 ** deleted writable. Then free any overflow pages associated with the
55128 ** entry and finally remove the cell itself from within the page.
55130 rc = saveAllCursors(pBt, pCur->pgnoRoot, pCur);
55131 if( rc ) return rc;
55132 rc = sqlite3PagerWrite(pPage->pDbPage);
55133 if( rc ) return rc;
55134 rc = clearCell(pPage, pCell);
55135 dropCell(pPage, iCellIdx, cellSizePtr(pPage, pCell), &rc);
55136 if( rc ) return rc;
55138 /* If the cell deleted was not located on a leaf page, then the cursor
55139 ** is currently pointing to the largest entry in the sub-tree headed
55140 ** by the child-page of the cell that was just deleted from an internal
55141 ** node. The cell from the leaf node needs to be moved to the internal
55142 ** node to replace the deleted cell. */
55143 if( !pPage->leaf ){
55144 MemPage *pLeaf = pCur->apPage[pCur->iPage];
55145 int nCell;
55146 Pgno n = pCur->apPage[iCellDepth+1]->pgno;
55147 unsigned char *pTmp;
55149 pCell = findCell(pLeaf, pLeaf->nCell-1);
55150 nCell = cellSizePtr(pLeaf, pCell);
55151 assert( MX_CELL_SIZE(pBt) >= nCell );
55153 allocateTempSpace(pBt);
55154 pTmp = pBt->pTmpSpace;
55156 rc = sqlite3PagerWrite(pLeaf->pDbPage);
55157 insertCell(pPage, iCellIdx, pCell-4, nCell+4, pTmp, n, &rc);
55158 dropCell(pLeaf, pLeaf->nCell-1, nCell, &rc);
55159 if( rc ) return rc;
55162 /* Balance the tree. If the entry deleted was located on a leaf page,
55163 ** then the cursor still points to that page. In this case the first
55164 ** call to balance() repairs the tree, and the if(...) condition is
55165 ** never true.
55167 ** Otherwise, if the entry deleted was on an internal node page, then
55168 ** pCur is pointing to the leaf page from which a cell was removed to
55169 ** replace the cell deleted from the internal node. This is slightly
55170 ** tricky as the leaf node may be underfull, and the internal node may
55171 ** be either under or overfull. In this case run the balancing algorithm
55172 ** on the leaf node first. If the balance proceeds far enough up the
55173 ** tree that we can be sure that any problem in the internal node has
55174 ** been corrected, so be it. Otherwise, after balancing the leaf node,
55175 ** walk the cursor up the tree to the internal node and balance it as
55176 ** well. */
55177 rc = balance(pCur);
55178 if( rc==SQLITE_OK && pCur->iPage>iCellDepth ){
55179 while( pCur->iPage>iCellDepth ){
55180 releasePage(pCur->apPage[pCur->iPage--]);
55182 rc = balance(pCur);
55185 if( rc==SQLITE_OK ){
55186 moveToRoot(pCur);
55188 return rc;
55192 ** Create a new BTree table. Write into *piTable the page
55193 ** number for the root page of the new table.
55195 ** The type of type is determined by the flags parameter. Only the
55196 ** following values of flags are currently in use. Other values for
55197 ** flags might not work:
55199 ** BTREE_INTKEY|BTREE_LEAFDATA Used for SQL tables with rowid keys
55200 ** BTREE_ZERODATA Used for SQL indices
55202 static int btreeCreateTable(Btree *p, int *piTable, int createTabFlags){
55203 BtShared *pBt = p->pBt;
55204 MemPage *pRoot;
55205 Pgno pgnoRoot;
55206 int rc;
55207 int ptfFlags; /* Page-type flage for the root page of new table */
55209 assert( sqlite3BtreeHoldsMutex(p) );
55210 assert( pBt->inTransaction==TRANS_WRITE );
55211 assert( !pBt->readOnly );
55213 #ifdef SQLITE_OMIT_AUTOVACUUM
55214 rc = allocateBtreePage(pBt, &pRoot, &pgnoRoot, 1, 0);
55215 if( rc ){
55216 return rc;
55218 #else
55219 if( pBt->autoVacuum ){
55220 Pgno pgnoMove; /* Move a page here to make room for the root-page */
55221 MemPage *pPageMove; /* The page to move to. */
55223 /* Creating a new table may probably require moving an existing database
55224 ** to make room for the new tables root page. In case this page turns
55225 ** out to be an overflow page, delete all overflow page-map caches
55226 ** held by open cursors.
55228 invalidateAllOverflowCache(pBt);
55230 /* Read the value of meta[3] from the database to determine where the
55231 ** root page of the new table should go. meta[3] is the largest root-page
55232 ** created so far, so the new root-page is (meta[3]+1).
55234 sqlite3BtreeGetMeta(p, BTREE_LARGEST_ROOT_PAGE, &pgnoRoot);
55235 pgnoRoot++;
55237 /* The new root-page may not be allocated on a pointer-map page, or the
55238 ** PENDING_BYTE page.
55240 while( pgnoRoot==PTRMAP_PAGENO(pBt, pgnoRoot) ||
55241 pgnoRoot==PENDING_BYTE_PAGE(pBt) ){
55242 pgnoRoot++;
55244 assert( pgnoRoot>=3 );
55246 /* Allocate a page. The page that currently resides at pgnoRoot will
55247 ** be moved to the allocated page (unless the allocated page happens
55248 ** to reside at pgnoRoot).
55250 rc = allocateBtreePage(pBt, &pPageMove, &pgnoMove, pgnoRoot, 1);
55251 if( rc!=SQLITE_OK ){
55252 return rc;
55255 if( pgnoMove!=pgnoRoot ){
55256 /* pgnoRoot is the page that will be used for the root-page of
55257 ** the new table (assuming an error did not occur). But we were
55258 ** allocated pgnoMove. If required (i.e. if it was not allocated
55259 ** by extending the file), the current page at position pgnoMove
55260 ** is already journaled.
55262 u8 eType = 0;
55263 Pgno iPtrPage = 0;
55265 releasePage(pPageMove);
55267 /* Move the page currently at pgnoRoot to pgnoMove. */
55268 rc = btreeGetPage(pBt, pgnoRoot, &pRoot, 0);
55269 if( rc!=SQLITE_OK ){
55270 return rc;
55272 rc = ptrmapGet(pBt, pgnoRoot, &eType, &iPtrPage);
55273 if( eType==PTRMAP_ROOTPAGE || eType==PTRMAP_FREEPAGE ){
55274 rc = SQLITE_CORRUPT_BKPT;
55276 if( rc!=SQLITE_OK ){
55277 releasePage(pRoot);
55278 return rc;
55280 assert( eType!=PTRMAP_ROOTPAGE );
55281 assert( eType!=PTRMAP_FREEPAGE );
55282 rc = relocatePage(pBt, pRoot, eType, iPtrPage, pgnoMove, 0);
55283 releasePage(pRoot);
55285 /* Obtain the page at pgnoRoot */
55286 if( rc!=SQLITE_OK ){
55287 return rc;
55289 rc = btreeGetPage(pBt, pgnoRoot, &pRoot, 0);
55290 if( rc!=SQLITE_OK ){
55291 return rc;
55293 rc = sqlite3PagerWrite(pRoot->pDbPage);
55294 if( rc!=SQLITE_OK ){
55295 releasePage(pRoot);
55296 return rc;
55298 }else{
55299 pRoot = pPageMove;
55302 /* Update the pointer-map and meta-data with the new root-page number. */
55303 ptrmapPut(pBt, pgnoRoot, PTRMAP_ROOTPAGE, 0, &rc);
55304 if( rc ){
55305 releasePage(pRoot);
55306 return rc;
55309 /* When the new root page was allocated, page 1 was made writable in
55310 ** order either to increase the database filesize, or to decrement the
55311 ** freelist count. Hence, the sqlite3BtreeUpdateMeta() call cannot fail.
55313 assert( sqlite3PagerIswriteable(pBt->pPage1->pDbPage) );
55314 rc = sqlite3BtreeUpdateMeta(p, 4, pgnoRoot);
55315 if( NEVER(rc) ){
55316 releasePage(pRoot);
55317 return rc;
55320 }else{
55321 rc = allocateBtreePage(pBt, &pRoot, &pgnoRoot, 1, 0);
55322 if( rc ) return rc;
55324 #endif
55325 assert( sqlite3PagerIswriteable(pRoot->pDbPage) );
55326 if( createTabFlags & BTREE_INTKEY ){
55327 ptfFlags = PTF_INTKEY | PTF_LEAFDATA | PTF_LEAF;
55328 }else{
55329 ptfFlags = PTF_ZERODATA | PTF_LEAF;
55331 zeroPage(pRoot, ptfFlags);
55332 sqlite3PagerUnref(pRoot->pDbPage);
55333 assert( (pBt->openFlags & BTREE_SINGLE)==0 || pgnoRoot==2 );
55334 *piTable = (int)pgnoRoot;
55335 return SQLITE_OK;
55337 SQLITE_PRIVATE int sqlite3BtreeCreateTable(Btree *p, int *piTable, int flags){
55338 int rc;
55339 sqlite3BtreeEnter(p);
55340 rc = btreeCreateTable(p, piTable, flags);
55341 sqlite3BtreeLeave(p);
55342 return rc;
55346 ** Erase the given database page and all its children. Return
55347 ** the page to the freelist.
55349 static int clearDatabasePage(
55350 BtShared *pBt, /* The BTree that contains the table */
55351 Pgno pgno, /* Page number to clear */
55352 int freePageFlag, /* Deallocate page if true */
55353 int *pnChange /* Add number of Cells freed to this counter */
55355 MemPage *pPage;
55356 int rc;
55357 unsigned char *pCell;
55358 int i;
55360 assert( sqlite3_mutex_held(pBt->mutex) );
55361 if( pgno>btreePagecount(pBt) ){
55362 return SQLITE_CORRUPT_BKPT;
55365 rc = getAndInitPage(pBt, pgno, &pPage);
55366 if( rc ) return rc;
55367 for(i=0; i<pPage->nCell; i++){
55368 pCell = findCell(pPage, i);
55369 if( !pPage->leaf ){
55370 rc = clearDatabasePage(pBt, get4byte(pCell), 1, pnChange);
55371 if( rc ) goto cleardatabasepage_out;
55373 rc = clearCell(pPage, pCell);
55374 if( rc ) goto cleardatabasepage_out;
55376 if( !pPage->leaf ){
55377 rc = clearDatabasePage(pBt, get4byte(&pPage->aData[8]), 1, pnChange);
55378 if( rc ) goto cleardatabasepage_out;
55379 }else if( pnChange ){
55380 assert( pPage->intKey );
55381 *pnChange += pPage->nCell;
55383 if( freePageFlag ){
55384 freePage(pPage, &rc);
55385 }else if( (rc = sqlite3PagerWrite(pPage->pDbPage))==0 ){
55386 zeroPage(pPage, pPage->aData[0] | PTF_LEAF);
55389 cleardatabasepage_out:
55390 releasePage(pPage);
55391 return rc;
55395 ** Delete all information from a single table in the database. iTable is
55396 ** the page number of the root of the table. After this routine returns,
55397 ** the root page is empty, but still exists.
55399 ** This routine will fail with SQLITE_LOCKED if there are any open
55400 ** read cursors on the table. Open write cursors are moved to the
55401 ** root of the table.
55403 ** If pnChange is not NULL, then table iTable must be an intkey table. The
55404 ** integer value pointed to by pnChange is incremented by the number of
55405 ** entries in the table.
55407 SQLITE_PRIVATE int sqlite3BtreeClearTable(Btree *p, int iTable, int *pnChange){
55408 int rc;
55409 BtShared *pBt = p->pBt;
55410 sqlite3BtreeEnter(p);
55411 assert( p->inTrans==TRANS_WRITE );
55413 /* Invalidate all incrblob cursors open on table iTable (assuming iTable
55414 ** is the root of a table b-tree - if it is not, the following call is
55415 ** a no-op). */
55416 invalidateIncrblobCursors(p, 0, 1);
55418 rc = saveAllCursors(pBt, (Pgno)iTable, 0);
55419 if( SQLITE_OK==rc ){
55420 rc = clearDatabasePage(pBt, (Pgno)iTable, 0, pnChange);
55422 sqlite3BtreeLeave(p);
55423 return rc;
55427 ** Erase all information in a table and add the root of the table to
55428 ** the freelist. Except, the root of the principle table (the one on
55429 ** page 1) is never added to the freelist.
55431 ** This routine will fail with SQLITE_LOCKED if there are any open
55432 ** cursors on the table.
55434 ** If AUTOVACUUM is enabled and the page at iTable is not the last
55435 ** root page in the database file, then the last root page
55436 ** in the database file is moved into the slot formerly occupied by
55437 ** iTable and that last slot formerly occupied by the last root page
55438 ** is added to the freelist instead of iTable. In this say, all
55439 ** root pages are kept at the beginning of the database file, which
55440 ** is necessary for AUTOVACUUM to work right. *piMoved is set to the
55441 ** page number that used to be the last root page in the file before
55442 ** the move. If no page gets moved, *piMoved is set to 0.
55443 ** The last root page is recorded in meta[3] and the value of
55444 ** meta[3] is updated by this procedure.
55446 static int btreeDropTable(Btree *p, Pgno iTable, int *piMoved){
55447 int rc;
55448 MemPage *pPage = 0;
55449 BtShared *pBt = p->pBt;
55451 assert( sqlite3BtreeHoldsMutex(p) );
55452 assert( p->inTrans==TRANS_WRITE );
55454 /* It is illegal to drop a table if any cursors are open on the
55455 ** database. This is because in auto-vacuum mode the backend may
55456 ** need to move another root-page to fill a gap left by the deleted
55457 ** root page. If an open cursor was using this page a problem would
55458 ** occur.
55460 ** This error is caught long before control reaches this point.
55462 if( NEVER(pBt->pCursor) ){
55463 sqlite3ConnectionBlocked(p->db, pBt->pCursor->pBtree->db);
55464 return SQLITE_LOCKED_SHAREDCACHE;
55467 rc = btreeGetPage(pBt, (Pgno)iTable, &pPage, 0);
55468 if( rc ) return rc;
55469 rc = sqlite3BtreeClearTable(p, iTable, 0);
55470 if( rc ){
55471 releasePage(pPage);
55472 return rc;
55475 *piMoved = 0;
55477 if( iTable>1 ){
55478 #ifdef SQLITE_OMIT_AUTOVACUUM
55479 freePage(pPage, &rc);
55480 releasePage(pPage);
55481 #else
55482 if( pBt->autoVacuum ){
55483 Pgno maxRootPgno;
55484 sqlite3BtreeGetMeta(p, BTREE_LARGEST_ROOT_PAGE, &maxRootPgno);
55486 if( iTable==maxRootPgno ){
55487 /* If the table being dropped is the table with the largest root-page
55488 ** number in the database, put the root page on the free list.
55490 freePage(pPage, &rc);
55491 releasePage(pPage);
55492 if( rc!=SQLITE_OK ){
55493 return rc;
55495 }else{
55496 /* The table being dropped does not have the largest root-page
55497 ** number in the database. So move the page that does into the
55498 ** gap left by the deleted root-page.
55500 MemPage *pMove;
55501 releasePage(pPage);
55502 rc = btreeGetPage(pBt, maxRootPgno, &pMove, 0);
55503 if( rc!=SQLITE_OK ){
55504 return rc;
55506 rc = relocatePage(pBt, pMove, PTRMAP_ROOTPAGE, 0, iTable, 0);
55507 releasePage(pMove);
55508 if( rc!=SQLITE_OK ){
55509 return rc;
55511 pMove = 0;
55512 rc = btreeGetPage(pBt, maxRootPgno, &pMove, 0);
55513 freePage(pMove, &rc);
55514 releasePage(pMove);
55515 if( rc!=SQLITE_OK ){
55516 return rc;
55518 *piMoved = maxRootPgno;
55521 /* Set the new 'max-root-page' value in the database header. This
55522 ** is the old value less one, less one more if that happens to
55523 ** be a root-page number, less one again if that is the
55524 ** PENDING_BYTE_PAGE.
55526 maxRootPgno--;
55527 while( maxRootPgno==PENDING_BYTE_PAGE(pBt)
55528 || PTRMAP_ISPAGE(pBt, maxRootPgno) ){
55529 maxRootPgno--;
55531 assert( maxRootPgno!=PENDING_BYTE_PAGE(pBt) );
55533 rc = sqlite3BtreeUpdateMeta(p, 4, maxRootPgno);
55534 }else{
55535 freePage(pPage, &rc);
55536 releasePage(pPage);
55538 #endif
55539 }else{
55540 /* If sqlite3BtreeDropTable was called on page 1.
55541 ** This really never should happen except in a corrupt
55542 ** database.
55544 zeroPage(pPage, PTF_INTKEY|PTF_LEAF );
55545 releasePage(pPage);
55547 return rc;
55549 SQLITE_PRIVATE int sqlite3BtreeDropTable(Btree *p, int iTable, int *piMoved){
55550 int rc;
55551 sqlite3BtreeEnter(p);
55552 rc = btreeDropTable(p, iTable, piMoved);
55553 sqlite3BtreeLeave(p);
55554 return rc;
55559 ** This function may only be called if the b-tree connection already
55560 ** has a read or write transaction open on the database.
55562 ** Read the meta-information out of a database file. Meta[0]
55563 ** is the number of free pages currently in the database. Meta[1]
55564 ** through meta[15] are available for use by higher layers. Meta[0]
55565 ** is read-only, the others are read/write.
55567 ** The schema layer numbers meta values differently. At the schema
55568 ** layer (and the SetCookie and ReadCookie opcodes) the number of
55569 ** free pages is not visible. So Cookie[0] is the same as Meta[1].
55571 SQLITE_PRIVATE void sqlite3BtreeGetMeta(Btree *p, int idx, u32 *pMeta){
55572 BtShared *pBt = p->pBt;
55574 sqlite3BtreeEnter(p);
55575 assert( p->inTrans>TRANS_NONE );
55576 assert( SQLITE_OK==querySharedCacheTableLock(p, MASTER_ROOT, READ_LOCK) );
55577 assert( pBt->pPage1 );
55578 assert( idx>=0 && idx<=15 );
55580 *pMeta = get4byte(&pBt->pPage1->aData[36 + idx*4]);
55582 /* If auto-vacuum is disabled in this build and this is an auto-vacuum
55583 ** database, mark the database as read-only. */
55584 #ifdef SQLITE_OMIT_AUTOVACUUM
55585 if( idx==BTREE_LARGEST_ROOT_PAGE && *pMeta>0 ) pBt->readOnly = 1;
55586 #endif
55588 sqlite3BtreeLeave(p);
55592 ** Write meta-information back into the database. Meta[0] is
55593 ** read-only and may not be written.
55595 SQLITE_PRIVATE int sqlite3BtreeUpdateMeta(Btree *p, int idx, u32 iMeta){
55596 BtShared *pBt = p->pBt;
55597 unsigned char *pP1;
55598 int rc;
55599 assert( idx>=1 && idx<=15 );
55600 sqlite3BtreeEnter(p);
55601 assert( p->inTrans==TRANS_WRITE );
55602 assert( pBt->pPage1!=0 );
55603 pP1 = pBt->pPage1->aData;
55604 rc = sqlite3PagerWrite(pBt->pPage1->pDbPage);
55605 if( rc==SQLITE_OK ){
55606 put4byte(&pP1[36 + idx*4], iMeta);
55607 #ifndef SQLITE_OMIT_AUTOVACUUM
55608 if( idx==BTREE_INCR_VACUUM ){
55609 assert( pBt->autoVacuum || iMeta==0 );
55610 assert( iMeta==0 || iMeta==1 );
55611 pBt->incrVacuum = (u8)iMeta;
55613 #endif
55615 sqlite3BtreeLeave(p);
55616 return rc;
55619 #ifndef SQLITE_OMIT_BTREECOUNT
55621 ** The first argument, pCur, is a cursor opened on some b-tree. Count the
55622 ** number of entries in the b-tree and write the result to *pnEntry.
55624 ** SQLITE_OK is returned if the operation is successfully executed.
55625 ** Otherwise, if an error is encountered (i.e. an IO error or database
55626 ** corruption) an SQLite error code is returned.
55628 SQLITE_PRIVATE int sqlite3BtreeCount(BtCursor *pCur, i64 *pnEntry){
55629 i64 nEntry = 0; /* Value to return in *pnEntry */
55630 int rc; /* Return code */
55632 if( pCur->pgnoRoot==0 ){
55633 *pnEntry = 0;
55634 return SQLITE_OK;
55636 rc = moveToRoot(pCur);
55638 /* Unless an error occurs, the following loop runs one iteration for each
55639 ** page in the B-Tree structure (not including overflow pages).
55641 while( rc==SQLITE_OK ){
55642 int iIdx; /* Index of child node in parent */
55643 MemPage *pPage; /* Current page of the b-tree */
55645 /* If this is a leaf page or the tree is not an int-key tree, then
55646 ** this page contains countable entries. Increment the entry counter
55647 ** accordingly.
55649 pPage = pCur->apPage[pCur->iPage];
55650 if( pPage->leaf || !pPage->intKey ){
55651 nEntry += pPage->nCell;
55654 /* pPage is a leaf node. This loop navigates the cursor so that it
55655 ** points to the first interior cell that it points to the parent of
55656 ** the next page in the tree that has not yet been visited. The
55657 ** pCur->aiIdx[pCur->iPage] value is set to the index of the parent cell
55658 ** of the page, or to the number of cells in the page if the next page
55659 ** to visit is the right-child of its parent.
55661 ** If all pages in the tree have been visited, return SQLITE_OK to the
55662 ** caller.
55664 if( pPage->leaf ){
55665 do {
55666 if( pCur->iPage==0 ){
55667 /* All pages of the b-tree have been visited. Return successfully. */
55668 *pnEntry = nEntry;
55669 return SQLITE_OK;
55671 moveToParent(pCur);
55672 }while ( pCur->aiIdx[pCur->iPage]>=pCur->apPage[pCur->iPage]->nCell );
55674 pCur->aiIdx[pCur->iPage]++;
55675 pPage = pCur->apPage[pCur->iPage];
55678 /* Descend to the child node of the cell that the cursor currently
55679 ** points at. This is the right-child if (iIdx==pPage->nCell).
55681 iIdx = pCur->aiIdx[pCur->iPage];
55682 if( iIdx==pPage->nCell ){
55683 rc = moveToChild(pCur, get4byte(&pPage->aData[pPage->hdrOffset+8]));
55684 }else{
55685 rc = moveToChild(pCur, get4byte(findCell(pPage, iIdx)));
55689 /* An error has occurred. Return an error code. */
55690 return rc;
55692 #endif
55695 ** Return the pager associated with a BTree. This routine is used for
55696 ** testing and debugging only.
55698 SQLITE_PRIVATE Pager *sqlite3BtreePager(Btree *p){
55699 return p->pBt->pPager;
55702 #ifndef SQLITE_OMIT_INTEGRITY_CHECK
55704 ** Append a message to the error message string.
55706 static void checkAppendMsg(
55707 IntegrityCk *pCheck,
55708 char *zMsg1,
55709 const char *zFormat,
55712 va_list ap;
55713 if( !pCheck->mxErr ) return;
55714 pCheck->mxErr--;
55715 pCheck->nErr++;
55716 va_start(ap, zFormat);
55717 if( pCheck->errMsg.nChar ){
55718 sqlite3StrAccumAppend(&pCheck->errMsg, "\n", 1);
55720 if( zMsg1 ){
55721 sqlite3StrAccumAppend(&pCheck->errMsg, zMsg1, -1);
55723 sqlite3VXPrintf(&pCheck->errMsg, 1, zFormat, ap);
55724 va_end(ap);
55725 if( pCheck->errMsg.mallocFailed ){
55726 pCheck->mallocFailed = 1;
55729 #endif /* SQLITE_OMIT_INTEGRITY_CHECK */
55731 #ifndef SQLITE_OMIT_INTEGRITY_CHECK
55733 ** Add 1 to the reference count for page iPage. If this is the second
55734 ** reference to the page, add an error message to pCheck->zErrMsg.
55735 ** Return 1 if there are 2 ore more references to the page and 0 if
55736 ** if this is the first reference to the page.
55738 ** Also check that the page number is in bounds.
55740 static int checkRef(IntegrityCk *pCheck, Pgno iPage, char *zContext){
55741 if( iPage==0 ) return 1;
55742 if( iPage>pCheck->nPage ){
55743 checkAppendMsg(pCheck, zContext, "invalid page number %d", iPage);
55744 return 1;
55746 if( pCheck->anRef[iPage]==1 ){
55747 checkAppendMsg(pCheck, zContext, "2nd reference to page %d", iPage);
55748 return 1;
55750 return (pCheck->anRef[iPage]++)>1;
55753 #ifndef SQLITE_OMIT_AUTOVACUUM
55755 ** Check that the entry in the pointer-map for page iChild maps to
55756 ** page iParent, pointer type ptrType. If not, append an error message
55757 ** to pCheck.
55759 static void checkPtrmap(
55760 IntegrityCk *pCheck, /* Integrity check context */
55761 Pgno iChild, /* Child page number */
55762 u8 eType, /* Expected pointer map type */
55763 Pgno iParent, /* Expected pointer map parent page number */
55764 char *zContext /* Context description (used for error msg) */
55766 int rc;
55767 u8 ePtrmapType;
55768 Pgno iPtrmapParent;
55770 rc = ptrmapGet(pCheck->pBt, iChild, &ePtrmapType, &iPtrmapParent);
55771 if( rc!=SQLITE_OK ){
55772 if( rc==SQLITE_NOMEM || rc==SQLITE_IOERR_NOMEM ) pCheck->mallocFailed = 1;
55773 checkAppendMsg(pCheck, zContext, "Failed to read ptrmap key=%d", iChild);
55774 return;
55777 if( ePtrmapType!=eType || iPtrmapParent!=iParent ){
55778 checkAppendMsg(pCheck, zContext,
55779 "Bad ptr map entry key=%d expected=(%d,%d) got=(%d,%d)",
55780 iChild, eType, iParent, ePtrmapType, iPtrmapParent);
55783 #endif
55786 ** Check the integrity of the freelist or of an overflow page list.
55787 ** Verify that the number of pages on the list is N.
55789 static void checkList(
55790 IntegrityCk *pCheck, /* Integrity checking context */
55791 int isFreeList, /* True for a freelist. False for overflow page list */
55792 int iPage, /* Page number for first page in the list */
55793 int N, /* Expected number of pages in the list */
55794 char *zContext /* Context for error messages */
55796 int i;
55797 int expected = N;
55798 int iFirst = iPage;
55799 while( N-- > 0 && pCheck->mxErr ){
55800 DbPage *pOvflPage;
55801 unsigned char *pOvflData;
55802 if( iPage<1 ){
55803 checkAppendMsg(pCheck, zContext,
55804 "%d of %d pages missing from overflow list starting at %d",
55805 N+1, expected, iFirst);
55806 break;
55808 if( checkRef(pCheck, iPage, zContext) ) break;
55809 if( sqlite3PagerGet(pCheck->pPager, (Pgno)iPage, &pOvflPage) ){
55810 checkAppendMsg(pCheck, zContext, "failed to get page %d", iPage);
55811 break;
55813 pOvflData = (unsigned char *)sqlite3PagerGetData(pOvflPage);
55814 if( isFreeList ){
55815 int n = get4byte(&pOvflData[4]);
55816 #ifndef SQLITE_OMIT_AUTOVACUUM
55817 if( pCheck->pBt->autoVacuum ){
55818 checkPtrmap(pCheck, iPage, PTRMAP_FREEPAGE, 0, zContext);
55820 #endif
55821 if( n>(int)pCheck->pBt->usableSize/4-2 ){
55822 checkAppendMsg(pCheck, zContext,
55823 "freelist leaf count too big on page %d", iPage);
55824 N--;
55825 }else{
55826 for(i=0; i<n; i++){
55827 Pgno iFreePage = get4byte(&pOvflData[8+i*4]);
55828 #ifndef SQLITE_OMIT_AUTOVACUUM
55829 if( pCheck->pBt->autoVacuum ){
55830 checkPtrmap(pCheck, iFreePage, PTRMAP_FREEPAGE, 0, zContext);
55832 #endif
55833 checkRef(pCheck, iFreePage, zContext);
55835 N -= n;
55838 #ifndef SQLITE_OMIT_AUTOVACUUM
55839 else{
55840 /* If this database supports auto-vacuum and iPage is not the last
55841 ** page in this overflow list, check that the pointer-map entry for
55842 ** the following page matches iPage.
55844 if( pCheck->pBt->autoVacuum && N>0 ){
55845 i = get4byte(pOvflData);
55846 checkPtrmap(pCheck, i, PTRMAP_OVERFLOW2, iPage, zContext);
55849 #endif
55850 iPage = get4byte(pOvflData);
55851 sqlite3PagerUnref(pOvflPage);
55854 #endif /* SQLITE_OMIT_INTEGRITY_CHECK */
55856 #ifndef SQLITE_OMIT_INTEGRITY_CHECK
55858 ** Do various sanity checks on a single page of a tree. Return
55859 ** the tree depth. Root pages return 0. Parents of root pages
55860 ** return 1, and so forth.
55862 ** These checks are done:
55864 ** 1. Make sure that cells and freeblocks do not overlap
55865 ** but combine to completely cover the page.
55866 ** NO 2. Make sure cell keys are in order.
55867 ** NO 3. Make sure no key is less than or equal to zLowerBound.
55868 ** NO 4. Make sure no key is greater than or equal to zUpperBound.
55869 ** 5. Check the integrity of overflow pages.
55870 ** 6. Recursively call checkTreePage on all children.
55871 ** 7. Verify that the depth of all children is the same.
55872 ** 8. Make sure this page is at least 33% full or else it is
55873 ** the root of the tree.
55875 static int checkTreePage(
55876 IntegrityCk *pCheck, /* Context for the sanity check */
55877 int iPage, /* Page number of the page to check */
55878 char *zParentContext, /* Parent context */
55879 i64 *pnParentMinKey,
55880 i64 *pnParentMaxKey
55882 MemPage *pPage;
55883 int i, rc, depth, d2, pgno, cnt;
55884 int hdr, cellStart;
55885 int nCell;
55886 u8 *data;
55887 BtShared *pBt;
55888 int usableSize;
55889 char zContext[100];
55890 char *hit = 0;
55891 i64 nMinKey = 0;
55892 i64 nMaxKey = 0;
55894 sqlite3_snprintf(sizeof(zContext), zContext, "Page %d: ", iPage);
55896 /* Check that the page exists
55898 pBt = pCheck->pBt;
55899 usableSize = pBt->usableSize;
55900 if( iPage==0 ) return 0;
55901 if( checkRef(pCheck, iPage, zParentContext) ) return 0;
55902 if( (rc = btreeGetPage(pBt, (Pgno)iPage, &pPage, 0))!=0 ){
55903 checkAppendMsg(pCheck, zContext,
55904 "unable to get the page. error code=%d", rc);
55905 return 0;
55908 /* Clear MemPage.isInit to make sure the corruption detection code in
55909 ** btreeInitPage() is executed. */
55910 pPage->isInit = 0;
55911 if( (rc = btreeInitPage(pPage))!=0 ){
55912 assert( rc==SQLITE_CORRUPT ); /* The only possible error from InitPage */
55913 checkAppendMsg(pCheck, zContext,
55914 "btreeInitPage() returns error code %d", rc);
55915 releasePage(pPage);
55916 return 0;
55919 /* Check out all the cells.
55921 depth = 0;
55922 for(i=0; i<pPage->nCell && pCheck->mxErr; i++){
55923 u8 *pCell;
55924 u32 sz;
55925 CellInfo info;
55927 /* Check payload overflow pages
55929 sqlite3_snprintf(sizeof(zContext), zContext,
55930 "On tree page %d cell %d: ", iPage, i);
55931 pCell = findCell(pPage,i);
55932 btreeParseCellPtr(pPage, pCell, &info);
55933 sz = info.nData;
55934 if( !pPage->intKey ) sz += (int)info.nKey;
55935 /* For intKey pages, check that the keys are in order.
55937 else if( i==0 ) nMinKey = nMaxKey = info.nKey;
55938 else{
55939 if( info.nKey <= nMaxKey ){
55940 checkAppendMsg(pCheck, zContext,
55941 "Rowid %lld out of order (previous was %lld)", info.nKey, nMaxKey);
55943 nMaxKey = info.nKey;
55945 assert( sz==info.nPayload );
55946 if( (sz>info.nLocal)
55947 && (&pCell[info.iOverflow]<=&pPage->aData[pBt->usableSize])
55949 int nPage = (sz - info.nLocal + usableSize - 5)/(usableSize - 4);
55950 Pgno pgnoOvfl = get4byte(&pCell[info.iOverflow]);
55951 #ifndef SQLITE_OMIT_AUTOVACUUM
55952 if( pBt->autoVacuum ){
55953 checkPtrmap(pCheck, pgnoOvfl, PTRMAP_OVERFLOW1, iPage, zContext);
55955 #endif
55956 checkList(pCheck, 0, pgnoOvfl, nPage, zContext);
55959 /* Check sanity of left child page.
55961 if( !pPage->leaf ){
55962 pgno = get4byte(pCell);
55963 #ifndef SQLITE_OMIT_AUTOVACUUM
55964 if( pBt->autoVacuum ){
55965 checkPtrmap(pCheck, pgno, PTRMAP_BTREE, iPage, zContext);
55967 #endif
55968 d2 = checkTreePage(pCheck, pgno, zContext, &nMinKey, i==0 ? NULL : &nMaxKey);
55969 if( i>0 && d2!=depth ){
55970 checkAppendMsg(pCheck, zContext, "Child page depth differs");
55972 depth = d2;
55976 if( !pPage->leaf ){
55977 pgno = get4byte(&pPage->aData[pPage->hdrOffset+8]);
55978 sqlite3_snprintf(sizeof(zContext), zContext,
55979 "On page %d at right child: ", iPage);
55980 #ifndef SQLITE_OMIT_AUTOVACUUM
55981 if( pBt->autoVacuum ){
55982 checkPtrmap(pCheck, pgno, PTRMAP_BTREE, iPage, zContext);
55984 #endif
55985 checkTreePage(pCheck, pgno, zContext, NULL, !pPage->nCell ? NULL : &nMaxKey);
55988 /* For intKey leaf pages, check that the min/max keys are in order
55989 ** with any left/parent/right pages.
55991 if( pPage->leaf && pPage->intKey ){
55992 /* if we are a left child page */
55993 if( pnParentMinKey ){
55994 /* if we are the left most child page */
55995 if( !pnParentMaxKey ){
55996 if( nMaxKey > *pnParentMinKey ){
55997 checkAppendMsg(pCheck, zContext,
55998 "Rowid %lld out of order (max larger than parent min of %lld)",
55999 nMaxKey, *pnParentMinKey);
56001 }else{
56002 if( nMinKey <= *pnParentMinKey ){
56003 checkAppendMsg(pCheck, zContext,
56004 "Rowid %lld out of order (min less than parent min of %lld)",
56005 nMinKey, *pnParentMinKey);
56007 if( nMaxKey > *pnParentMaxKey ){
56008 checkAppendMsg(pCheck, zContext,
56009 "Rowid %lld out of order (max larger than parent max of %lld)",
56010 nMaxKey, *pnParentMaxKey);
56012 *pnParentMinKey = nMaxKey;
56014 /* else if we're a right child page */
56015 } else if( pnParentMaxKey ){
56016 if( nMinKey <= *pnParentMaxKey ){
56017 checkAppendMsg(pCheck, zContext,
56018 "Rowid %lld out of order (min less than parent max of %lld)",
56019 nMinKey, *pnParentMaxKey);
56024 /* Check for complete coverage of the page
56026 data = pPage->aData;
56027 hdr = pPage->hdrOffset;
56028 hit = sqlite3PageMalloc( pBt->pageSize );
56029 if( hit==0 ){
56030 pCheck->mallocFailed = 1;
56031 }else{
56032 int contentOffset = get2byteNotZero(&data[hdr+5]);
56033 assert( contentOffset<=usableSize ); /* Enforced by btreeInitPage() */
56034 memset(hit+contentOffset, 0, usableSize-contentOffset);
56035 memset(hit, 1, contentOffset);
56036 nCell = get2byte(&data[hdr+3]);
56037 cellStart = hdr + 12 - 4*pPage->leaf;
56038 for(i=0; i<nCell; i++){
56039 int pc = get2byte(&data[cellStart+i*2]);
56040 u32 size = 65536;
56041 int j;
56042 if( pc<=usableSize-4 ){
56043 size = cellSizePtr(pPage, &data[pc]);
56045 if( (int)(pc+size-1)>=usableSize ){
56046 checkAppendMsg(pCheck, 0,
56047 "Corruption detected in cell %d on page %d",i,iPage);
56048 }else{
56049 for(j=pc+size-1; j>=pc; j--) hit[j]++;
56052 i = get2byte(&data[hdr+1]);
56053 while( i>0 ){
56054 int size, j;
56055 assert( i<=usableSize-4 ); /* Enforced by btreeInitPage() */
56056 size = get2byte(&data[i+2]);
56057 assert( i+size<=usableSize ); /* Enforced by btreeInitPage() */
56058 for(j=i+size-1; j>=i; j--) hit[j]++;
56059 j = get2byte(&data[i]);
56060 assert( j==0 || j>i+size ); /* Enforced by btreeInitPage() */
56061 assert( j<=usableSize-4 ); /* Enforced by btreeInitPage() */
56062 i = j;
56064 for(i=cnt=0; i<usableSize; i++){
56065 if( hit[i]==0 ){
56066 cnt++;
56067 }else if( hit[i]>1 ){
56068 checkAppendMsg(pCheck, 0,
56069 "Multiple uses for byte %d of page %d", i, iPage);
56070 break;
56073 if( cnt!=data[hdr+7] ){
56074 checkAppendMsg(pCheck, 0,
56075 "Fragmentation of %d bytes reported as %d on page %d",
56076 cnt, data[hdr+7], iPage);
56079 sqlite3PageFree(hit);
56080 releasePage(pPage);
56081 return depth+1;
56083 #endif /* SQLITE_OMIT_INTEGRITY_CHECK */
56085 #ifndef SQLITE_OMIT_INTEGRITY_CHECK
56087 ** This routine does a complete check of the given BTree file. aRoot[] is
56088 ** an array of pages numbers were each page number is the root page of
56089 ** a table. nRoot is the number of entries in aRoot.
56091 ** A read-only or read-write transaction must be opened before calling
56092 ** this function.
56094 ** Write the number of error seen in *pnErr. Except for some memory
56095 ** allocation errors, an error message held in memory obtained from
56096 ** malloc is returned if *pnErr is non-zero. If *pnErr==0 then NULL is
56097 ** returned. If a memory allocation error occurs, NULL is returned.
56099 SQLITE_PRIVATE char *sqlite3BtreeIntegrityCheck(
56100 Btree *p, /* The btree to be checked */
56101 int *aRoot, /* An array of root pages numbers for individual trees */
56102 int nRoot, /* Number of entries in aRoot[] */
56103 int mxErr, /* Stop reporting errors after this many */
56104 int *pnErr /* Write number of errors seen to this variable */
56106 Pgno i;
56107 int nRef;
56108 IntegrityCk sCheck;
56109 BtShared *pBt = p->pBt;
56110 char zErr[100];
56112 sqlite3BtreeEnter(p);
56113 assert( p->inTrans>TRANS_NONE && pBt->inTransaction>TRANS_NONE );
56114 nRef = sqlite3PagerRefcount(pBt->pPager);
56115 sCheck.pBt = pBt;
56116 sCheck.pPager = pBt->pPager;
56117 sCheck.nPage = btreePagecount(sCheck.pBt);
56118 sCheck.mxErr = mxErr;
56119 sCheck.nErr = 0;
56120 sCheck.mallocFailed = 0;
56121 *pnErr = 0;
56122 if( sCheck.nPage==0 ){
56123 sqlite3BtreeLeave(p);
56124 return 0;
56126 sCheck.anRef = sqlite3Malloc( (sCheck.nPage+1)*sizeof(sCheck.anRef[0]) );
56127 if( !sCheck.anRef ){
56128 *pnErr = 1;
56129 sqlite3BtreeLeave(p);
56130 return 0;
56132 for(i=0; i<=sCheck.nPage; i++){ sCheck.anRef[i] = 0; }
56133 i = PENDING_BYTE_PAGE(pBt);
56134 if( i<=sCheck.nPage ){
56135 sCheck.anRef[i] = 1;
56137 sqlite3StrAccumInit(&sCheck.errMsg, zErr, sizeof(zErr), 20000);
56138 sCheck.errMsg.useMalloc = 2;
56140 /* Check the integrity of the freelist
56142 checkList(&sCheck, 1, get4byte(&pBt->pPage1->aData[32]),
56143 get4byte(&pBt->pPage1->aData[36]), "Main freelist: ");
56145 /* Check all the tables.
56147 for(i=0; (int)i<nRoot && sCheck.mxErr; i++){
56148 if( aRoot[i]==0 ) continue;
56149 #ifndef SQLITE_OMIT_AUTOVACUUM
56150 if( pBt->autoVacuum && aRoot[i]>1 ){
56151 checkPtrmap(&sCheck, aRoot[i], PTRMAP_ROOTPAGE, 0, 0);
56153 #endif
56154 checkTreePage(&sCheck, aRoot[i], "List of tree roots: ", NULL, NULL);
56157 /* Make sure every page in the file is referenced
56159 for(i=1; i<=sCheck.nPage && sCheck.mxErr; i++){
56160 #ifdef SQLITE_OMIT_AUTOVACUUM
56161 if( sCheck.anRef[i]==0 ){
56162 checkAppendMsg(&sCheck, 0, "Page %d is never used", i);
56164 #else
56165 /* If the database supports auto-vacuum, make sure no tables contain
56166 ** references to pointer-map pages.
56168 if( sCheck.anRef[i]==0 &&
56169 (PTRMAP_PAGENO(pBt, i)!=i || !pBt->autoVacuum) ){
56170 checkAppendMsg(&sCheck, 0, "Page %d is never used", i);
56172 if( sCheck.anRef[i]!=0 &&
56173 (PTRMAP_PAGENO(pBt, i)==i && pBt->autoVacuum) ){
56174 checkAppendMsg(&sCheck, 0, "Pointer map page %d is referenced", i);
56176 #endif
56179 /* Make sure this analysis did not leave any unref() pages.
56180 ** This is an internal consistency check; an integrity check
56181 ** of the integrity check.
56183 if( NEVER(nRef != sqlite3PagerRefcount(pBt->pPager)) ){
56184 checkAppendMsg(&sCheck, 0,
56185 "Outstanding page count goes from %d to %d during this analysis",
56186 nRef, sqlite3PagerRefcount(pBt->pPager)
56190 /* Clean up and report errors.
56192 sqlite3BtreeLeave(p);
56193 sqlite3_free(sCheck.anRef);
56194 if( sCheck.mallocFailed ){
56195 sqlite3StrAccumReset(&sCheck.errMsg);
56196 *pnErr = sCheck.nErr+1;
56197 return 0;
56199 *pnErr = sCheck.nErr;
56200 if( sCheck.nErr==0 ) sqlite3StrAccumReset(&sCheck.errMsg);
56201 return sqlite3StrAccumFinish(&sCheck.errMsg);
56203 #endif /* SQLITE_OMIT_INTEGRITY_CHECK */
56206 ** Return the full pathname of the underlying database file.
56208 ** The pager filename is invariant as long as the pager is
56209 ** open so it is safe to access without the BtShared mutex.
56211 SQLITE_PRIVATE const char *sqlite3BtreeGetFilename(Btree *p){
56212 assert( p->pBt->pPager!=0 );
56213 return sqlite3PagerFilename(p->pBt->pPager);
56217 ** Return the pathname of the journal file for this database. The return
56218 ** value of this routine is the same regardless of whether the journal file
56219 ** has been created or not.
56221 ** The pager journal filename is invariant as long as the pager is
56222 ** open so it is safe to access without the BtShared mutex.
56224 SQLITE_PRIVATE const char *sqlite3BtreeGetJournalname(Btree *p){
56225 assert( p->pBt->pPager!=0 );
56226 return sqlite3PagerJournalname(p->pBt->pPager);
56230 ** Return non-zero if a transaction is active.
56232 SQLITE_PRIVATE int sqlite3BtreeIsInTrans(Btree *p){
56233 assert( p==0 || sqlite3_mutex_held(p->db->mutex) );
56234 return (p && (p->inTrans==TRANS_WRITE));
56237 #ifndef SQLITE_OMIT_WAL
56239 ** Run a checkpoint on the Btree passed as the first argument.
56241 ** Return SQLITE_LOCKED if this or any other connection has an open
56242 ** transaction on the shared-cache the argument Btree is connected to.
56244 ** Parameter eMode is one of SQLITE_CHECKPOINT_PASSIVE, FULL or RESTART.
56246 SQLITE_PRIVATE int sqlite3BtreeCheckpoint(Btree *p, int eMode, int *pnLog, int *pnCkpt){
56247 int rc = SQLITE_OK;
56248 if( p ){
56249 BtShared *pBt = p->pBt;
56250 sqlite3BtreeEnter(p);
56251 if( pBt->inTransaction!=TRANS_NONE ){
56252 rc = SQLITE_LOCKED;
56253 }else{
56254 rc = sqlite3PagerCheckpoint(pBt->pPager, eMode, pnLog, pnCkpt);
56256 sqlite3BtreeLeave(p);
56258 return rc;
56260 #endif
56263 ** Return non-zero if a read (or write) transaction is active.
56265 SQLITE_PRIVATE int sqlite3BtreeIsInReadTrans(Btree *p){
56266 assert( p );
56267 assert( sqlite3_mutex_held(p->db->mutex) );
56268 return p->inTrans!=TRANS_NONE;
56271 SQLITE_PRIVATE int sqlite3BtreeIsInBackup(Btree *p){
56272 assert( p );
56273 assert( sqlite3_mutex_held(p->db->mutex) );
56274 return p->nBackup!=0;
56278 ** This function returns a pointer to a blob of memory associated with
56279 ** a single shared-btree. The memory is used by client code for its own
56280 ** purposes (for example, to store a high-level schema associated with
56281 ** the shared-btree). The btree layer manages reference counting issues.
56283 ** The first time this is called on a shared-btree, nBytes bytes of memory
56284 ** are allocated, zeroed, and returned to the caller. For each subsequent
56285 ** call the nBytes parameter is ignored and a pointer to the same blob
56286 ** of memory returned.
56288 ** If the nBytes parameter is 0 and the blob of memory has not yet been
56289 ** allocated, a null pointer is returned. If the blob has already been
56290 ** allocated, it is returned as normal.
56292 ** Just before the shared-btree is closed, the function passed as the
56293 ** xFree argument when the memory allocation was made is invoked on the
56294 ** blob of allocated memory. The xFree function should not call sqlite3_free()
56295 ** on the memory, the btree layer does that.
56297 SQLITE_PRIVATE void *sqlite3BtreeSchema(Btree *p, int nBytes, void(*xFree)(void *)){
56298 BtShared *pBt = p->pBt;
56299 sqlite3BtreeEnter(p);
56300 if( !pBt->pSchema && nBytes ){
56301 pBt->pSchema = sqlite3DbMallocZero(0, nBytes);
56302 pBt->xFreeSchema = xFree;
56304 sqlite3BtreeLeave(p);
56305 return pBt->pSchema;
56309 ** Return SQLITE_LOCKED_SHAREDCACHE if another user of the same shared
56310 ** btree as the argument handle holds an exclusive lock on the
56311 ** sqlite_master table. Otherwise SQLITE_OK.
56313 SQLITE_PRIVATE int sqlite3BtreeSchemaLocked(Btree *p){
56314 int rc;
56315 assert( sqlite3_mutex_held(p->db->mutex) );
56316 sqlite3BtreeEnter(p);
56317 rc = querySharedCacheTableLock(p, MASTER_ROOT, READ_LOCK);
56318 assert( rc==SQLITE_OK || rc==SQLITE_LOCKED_SHAREDCACHE );
56319 sqlite3BtreeLeave(p);
56320 return rc;
56324 #ifndef SQLITE_OMIT_SHARED_CACHE
56326 ** Obtain a lock on the table whose root page is iTab. The
56327 ** lock is a write lock if isWritelock is true or a read lock
56328 ** if it is false.
56330 SQLITE_PRIVATE int sqlite3BtreeLockTable(Btree *p, int iTab, u8 isWriteLock){
56331 int rc = SQLITE_OK;
56332 assert( p->inTrans!=TRANS_NONE );
56333 if( p->sharable ){
56334 u8 lockType = READ_LOCK + isWriteLock;
56335 assert( READ_LOCK+1==WRITE_LOCK );
56336 assert( isWriteLock==0 || isWriteLock==1 );
56338 sqlite3BtreeEnter(p);
56339 rc = querySharedCacheTableLock(p, iTab, lockType);
56340 if( rc==SQLITE_OK ){
56341 rc = setSharedCacheTableLock(p, iTab, lockType);
56343 sqlite3BtreeLeave(p);
56345 return rc;
56347 #endif
56349 #ifndef SQLITE_OMIT_INCRBLOB
56351 ** Argument pCsr must be a cursor opened for writing on an
56352 ** INTKEY table currently pointing at a valid table entry.
56353 ** This function modifies the data stored as part of that entry.
56355 ** Only the data content may only be modified, it is not possible to
56356 ** change the length of the data stored. If this function is called with
56357 ** parameters that attempt to write past the end of the existing data,
56358 ** no modifications are made and SQLITE_CORRUPT is returned.
56360 SQLITE_PRIVATE int sqlite3BtreePutData(BtCursor *pCsr, u32 offset, u32 amt, void *z){
56361 int rc;
56362 assert( cursorHoldsMutex(pCsr) );
56363 assert( sqlite3_mutex_held(pCsr->pBtree->db->mutex) );
56364 assert( pCsr->isIncrblobHandle );
56366 rc = restoreCursorPosition(pCsr);
56367 if( rc!=SQLITE_OK ){
56368 return rc;
56370 assert( pCsr->eState!=CURSOR_REQUIRESEEK );
56371 if( pCsr->eState!=CURSOR_VALID ){
56372 return SQLITE_ABORT;
56375 /* Check some assumptions:
56376 ** (a) the cursor is open for writing,
56377 ** (b) there is a read/write transaction open,
56378 ** (c) the connection holds a write-lock on the table (if required),
56379 ** (d) there are no conflicting read-locks, and
56380 ** (e) the cursor points at a valid row of an intKey table.
56382 if( !pCsr->wrFlag ){
56383 return SQLITE_READONLY;
56385 assert( !pCsr->pBt->readOnly && pCsr->pBt->inTransaction==TRANS_WRITE );
56386 assert( hasSharedCacheTableLock(pCsr->pBtree, pCsr->pgnoRoot, 0, 2) );
56387 assert( !hasReadConflicts(pCsr->pBtree, pCsr->pgnoRoot) );
56388 assert( pCsr->apPage[pCsr->iPage]->intKey );
56390 return accessPayload(pCsr, offset, amt, (unsigned char *)z, 1);
56394 ** Set a flag on this cursor to cache the locations of pages from the
56395 ** overflow list for the current row. This is used by cursors opened
56396 ** for incremental blob IO only.
56398 ** This function sets a flag only. The actual page location cache
56399 ** (stored in BtCursor.aOverflow[]) is allocated and used by function
56400 ** accessPayload() (the worker function for sqlite3BtreeData() and
56401 ** sqlite3BtreePutData()).
56403 SQLITE_PRIVATE void sqlite3BtreeCacheOverflow(BtCursor *pCur){
56404 assert( cursorHoldsMutex(pCur) );
56405 assert( sqlite3_mutex_held(pCur->pBtree->db->mutex) );
56406 invalidateOverflowCache(pCur);
56407 pCur->isIncrblobHandle = 1;
56409 #endif
56412 ** Set both the "read version" (single byte at byte offset 18) and
56413 ** "write version" (single byte at byte offset 19) fields in the database
56414 ** header to iVersion.
56416 SQLITE_PRIVATE int sqlite3BtreeSetVersion(Btree *pBtree, int iVersion){
56417 BtShared *pBt = pBtree->pBt;
56418 int rc; /* Return code */
56420 assert( iVersion==1 || iVersion==2 );
56422 /* If setting the version fields to 1, do not automatically open the
56423 ** WAL connection, even if the version fields are currently set to 2.
56425 pBt->doNotUseWAL = (u8)(iVersion==1);
56427 rc = sqlite3BtreeBeginTrans(pBtree, 0);
56428 if( rc==SQLITE_OK ){
56429 u8 *aData = pBt->pPage1->aData;
56430 if( aData[18]!=(u8)iVersion || aData[19]!=(u8)iVersion ){
56431 rc = sqlite3BtreeBeginTrans(pBtree, 2);
56432 if( rc==SQLITE_OK ){
56433 rc = sqlite3PagerWrite(pBt->pPage1->pDbPage);
56434 if( rc==SQLITE_OK ){
56435 aData[18] = (u8)iVersion;
56436 aData[19] = (u8)iVersion;
56442 pBt->doNotUseWAL = 0;
56443 return rc;
56446 /************** End of btree.c ***********************************************/
56447 /************** Begin file backup.c ******************************************/
56449 ** 2009 January 28
56451 ** The author disclaims copyright to this source code. In place of
56452 ** a legal notice, here is a blessing:
56454 ** May you do good and not evil.
56455 ** May you find forgiveness for yourself and forgive others.
56456 ** May you share freely, never taking more than you give.
56458 *************************************************************************
56459 ** This file contains the implementation of the sqlite3_backup_XXX()
56460 ** API functions and the related features.
56463 /* Macro to find the minimum of two numeric values.
56465 #ifndef MIN
56466 # define MIN(x,y) ((x)<(y)?(x):(y))
56467 #endif
56470 ** Structure allocated for each backup operation.
56472 struct sqlite3_backup {
56473 sqlite3* pDestDb; /* Destination database handle */
56474 Btree *pDest; /* Destination b-tree file */
56475 u32 iDestSchema; /* Original schema cookie in destination */
56476 int bDestLocked; /* True once a write-transaction is open on pDest */
56478 Pgno iNext; /* Page number of the next source page to copy */
56479 sqlite3* pSrcDb; /* Source database handle */
56480 Btree *pSrc; /* Source b-tree file */
56482 int rc; /* Backup process error code */
56484 /* These two variables are set by every call to backup_step(). They are
56485 ** read by calls to backup_remaining() and backup_pagecount().
56487 Pgno nRemaining; /* Number of pages left to copy */
56488 Pgno nPagecount; /* Total number of pages to copy */
56490 int isAttached; /* True once backup has been registered with pager */
56491 sqlite3_backup *pNext; /* Next backup associated with source pager */
56495 ** THREAD SAFETY NOTES:
56497 ** Once it has been created using backup_init(), a single sqlite3_backup
56498 ** structure may be accessed via two groups of thread-safe entry points:
56500 ** * Via the sqlite3_backup_XXX() API function backup_step() and
56501 ** backup_finish(). Both these functions obtain the source database
56502 ** handle mutex and the mutex associated with the source BtShared
56503 ** structure, in that order.
56505 ** * Via the BackupUpdate() and BackupRestart() functions, which are
56506 ** invoked by the pager layer to report various state changes in
56507 ** the page cache associated with the source database. The mutex
56508 ** associated with the source database BtShared structure will always
56509 ** be held when either of these functions are invoked.
56511 ** The other sqlite3_backup_XXX() API functions, backup_remaining() and
56512 ** backup_pagecount() are not thread-safe functions. If they are called
56513 ** while some other thread is calling backup_step() or backup_finish(),
56514 ** the values returned may be invalid. There is no way for a call to
56515 ** BackupUpdate() or BackupRestart() to interfere with backup_remaining()
56516 ** or backup_pagecount().
56518 ** Depending on the SQLite configuration, the database handles and/or
56519 ** the Btree objects may have their own mutexes that require locking.
56520 ** Non-sharable Btrees (in-memory databases for example), do not have
56521 ** associated mutexes.
56525 ** Return a pointer corresponding to database zDb (i.e. "main", "temp")
56526 ** in connection handle pDb. If such a database cannot be found, return
56527 ** a NULL pointer and write an error message to pErrorDb.
56529 ** If the "temp" database is requested, it may need to be opened by this
56530 ** function. If an error occurs while doing so, return 0 and write an
56531 ** error message to pErrorDb.
56533 static Btree *findBtree(sqlite3 *pErrorDb, sqlite3 *pDb, const char *zDb){
56534 int i = sqlite3FindDbName(pDb, zDb);
56536 if( i==1 ){
56537 Parse *pParse;
56538 int rc = 0;
56539 pParse = sqlite3StackAllocZero(pErrorDb, sizeof(*pParse));
56540 if( pParse==0 ){
56541 sqlite3Error(pErrorDb, SQLITE_NOMEM, "out of memory");
56542 rc = SQLITE_NOMEM;
56543 }else{
56544 pParse->db = pDb;
56545 if( sqlite3OpenTempDatabase(pParse) ){
56546 sqlite3Error(pErrorDb, pParse->rc, "%s", pParse->zErrMsg);
56547 rc = SQLITE_ERROR;
56549 sqlite3DbFree(pErrorDb, pParse->zErrMsg);
56550 sqlite3StackFree(pErrorDb, pParse);
56552 if( rc ){
56553 return 0;
56557 if( i<0 ){
56558 sqlite3Error(pErrorDb, SQLITE_ERROR, "unknown database %s", zDb);
56559 return 0;
56562 return pDb->aDb[i].pBt;
56566 ** Attempt to set the page size of the destination to match the page size
56567 ** of the source.
56569 static int setDestPgsz(sqlite3_backup *p){
56570 int rc;
56571 rc = sqlite3BtreeSetPageSize(p->pDest,sqlite3BtreeGetPageSize(p->pSrc),-1,0);
56572 return rc;
56576 ** Create an sqlite3_backup process to copy the contents of zSrcDb from
56577 ** connection handle pSrcDb to zDestDb in pDestDb. If successful, return
56578 ** a pointer to the new sqlite3_backup object.
56580 ** If an error occurs, NULL is returned and an error code and error message
56581 ** stored in database handle pDestDb.
56583 SQLITE_API sqlite3_backup *sqlite3_backup_init(
56584 sqlite3* pDestDb, /* Database to write to */
56585 const char *zDestDb, /* Name of database within pDestDb */
56586 sqlite3* pSrcDb, /* Database connection to read from */
56587 const char *zSrcDb /* Name of database within pSrcDb */
56589 sqlite3_backup *p; /* Value to return */
56591 /* Lock the source database handle. The destination database
56592 ** handle is not locked in this routine, but it is locked in
56593 ** sqlite3_backup_step(). The user is required to ensure that no
56594 ** other thread accesses the destination handle for the duration
56595 ** of the backup operation. Any attempt to use the destination
56596 ** database connection while a backup is in progress may cause
56597 ** a malfunction or a deadlock.
56599 sqlite3_mutex_enter(pSrcDb->mutex);
56600 sqlite3_mutex_enter(pDestDb->mutex);
56602 if( pSrcDb==pDestDb ){
56603 sqlite3Error(
56604 pDestDb, SQLITE_ERROR, "source and destination must be distinct"
56606 p = 0;
56607 }else {
56608 /* Allocate space for a new sqlite3_backup object...
56609 ** EVIDENCE-OF: R-64852-21591 The sqlite3_backup object is created by a
56610 ** call to sqlite3_backup_init() and is destroyed by a call to
56611 ** sqlite3_backup_finish(). */
56612 p = (sqlite3_backup *)sqlite3_malloc(sizeof(sqlite3_backup));
56613 if( !p ){
56614 sqlite3Error(pDestDb, SQLITE_NOMEM, 0);
56618 /* If the allocation succeeded, populate the new object. */
56619 if( p ){
56620 memset(p, 0, sizeof(sqlite3_backup));
56621 p->pSrc = findBtree(pDestDb, pSrcDb, zSrcDb);
56622 p->pDest = findBtree(pDestDb, pDestDb, zDestDb);
56623 p->pDestDb = pDestDb;
56624 p->pSrcDb = pSrcDb;
56625 p->iNext = 1;
56626 p->isAttached = 0;
56628 if( 0==p->pSrc || 0==p->pDest || setDestPgsz(p)==SQLITE_NOMEM ){
56629 /* One (or both) of the named databases did not exist or an OOM
56630 ** error was hit. The error has already been written into the
56631 ** pDestDb handle. All that is left to do here is free the
56632 ** sqlite3_backup structure.
56634 sqlite3_free(p);
56635 p = 0;
56638 if( p ){
56639 p->pSrc->nBackup++;
56642 sqlite3_mutex_leave(pDestDb->mutex);
56643 sqlite3_mutex_leave(pSrcDb->mutex);
56644 return p;
56648 ** Argument rc is an SQLite error code. Return true if this error is
56649 ** considered fatal if encountered during a backup operation. All errors
56650 ** are considered fatal except for SQLITE_BUSY and SQLITE_LOCKED.
56652 static int isFatalError(int rc){
56653 return (rc!=SQLITE_OK && rc!=SQLITE_BUSY && ALWAYS(rc!=SQLITE_LOCKED));
56657 ** Parameter zSrcData points to a buffer containing the data for
56658 ** page iSrcPg from the source database. Copy this data into the
56659 ** destination database.
56661 static int backupOnePage(sqlite3_backup *p, Pgno iSrcPg, const u8 *zSrcData){
56662 Pager * const pDestPager = sqlite3BtreePager(p->pDest);
56663 const int nSrcPgsz = sqlite3BtreeGetPageSize(p->pSrc);
56664 int nDestPgsz = sqlite3BtreeGetPageSize(p->pDest);
56665 const int nCopy = MIN(nSrcPgsz, nDestPgsz);
56666 const i64 iEnd = (i64)iSrcPg*(i64)nSrcPgsz;
56667 #ifdef SQLITE_HAS_CODEC
56668 int nSrcReserve = sqlite3BtreeGetReserve(p->pSrc);
56669 int nDestReserve = sqlite3BtreeGetReserve(p->pDest);
56670 #endif
56672 int rc = SQLITE_OK;
56673 i64 iOff;
56675 assert( p->bDestLocked );
56676 assert( !isFatalError(p->rc) );
56677 assert( iSrcPg!=PENDING_BYTE_PAGE(p->pSrc->pBt) );
56678 assert( zSrcData );
56680 /* Catch the case where the destination is an in-memory database and the
56681 ** page sizes of the source and destination differ.
56683 if( nSrcPgsz!=nDestPgsz && sqlite3PagerIsMemdb(pDestPager) ){
56684 rc = SQLITE_READONLY;
56687 #ifdef SQLITE_HAS_CODEC
56688 /* Backup is not possible if the page size of the destination is changing
56689 ** and a codec is in use.
56691 if( nSrcPgsz!=nDestPgsz && sqlite3PagerGetCodec(pDestPager)!=0 ){
56692 rc = SQLITE_READONLY;
56695 /* Backup is not possible if the number of bytes of reserve space differ
56696 ** between source and destination. If there is a difference, try to
56697 ** fix the destination to agree with the source. If that is not possible,
56698 ** then the backup cannot proceed.
56700 if( nSrcReserve!=nDestReserve ){
56701 u32 newPgsz = nSrcPgsz;
56702 rc = sqlite3PagerSetPagesize(pDestPager, &newPgsz, nSrcReserve);
56703 if( rc==SQLITE_OK && newPgsz!=nSrcPgsz ) rc = SQLITE_READONLY;
56705 #endif
56707 /* This loop runs once for each destination page spanned by the source
56708 ** page. For each iteration, variable iOff is set to the byte offset
56709 ** of the destination page.
56711 for(iOff=iEnd-(i64)nSrcPgsz; rc==SQLITE_OK && iOff<iEnd; iOff+=nDestPgsz){
56712 DbPage *pDestPg = 0;
56713 Pgno iDest = (Pgno)(iOff/nDestPgsz)+1;
56714 if( iDest==PENDING_BYTE_PAGE(p->pDest->pBt) ) continue;
56715 if( SQLITE_OK==(rc = sqlite3PagerGet(pDestPager, iDest, &pDestPg))
56716 && SQLITE_OK==(rc = sqlite3PagerWrite(pDestPg))
56718 const u8 *zIn = &zSrcData[iOff%nSrcPgsz];
56719 u8 *zDestData = sqlite3PagerGetData(pDestPg);
56720 u8 *zOut = &zDestData[iOff%nDestPgsz];
56722 /* Copy the data from the source page into the destination page.
56723 ** Then clear the Btree layer MemPage.isInit flag. Both this module
56724 ** and the pager code use this trick (clearing the first byte
56725 ** of the page 'extra' space to invalidate the Btree layers
56726 ** cached parse of the page). MemPage.isInit is marked
56727 ** "MUST BE FIRST" for this purpose.
56729 memcpy(zOut, zIn, nCopy);
56730 ((u8 *)sqlite3PagerGetExtra(pDestPg))[0] = 0;
56732 sqlite3PagerUnref(pDestPg);
56735 return rc;
56739 ** If pFile is currently larger than iSize bytes, then truncate it to
56740 ** exactly iSize bytes. If pFile is not larger than iSize bytes, then
56741 ** this function is a no-op.
56743 ** Return SQLITE_OK if everything is successful, or an SQLite error
56744 ** code if an error occurs.
56746 static int backupTruncateFile(sqlite3_file *pFile, i64 iSize){
56747 i64 iCurrent;
56748 int rc = sqlite3OsFileSize(pFile, &iCurrent);
56749 if( rc==SQLITE_OK && iCurrent>iSize ){
56750 rc = sqlite3OsTruncate(pFile, iSize);
56752 return rc;
56756 ** Register this backup object with the associated source pager for
56757 ** callbacks when pages are changed or the cache invalidated.
56759 static void attachBackupObject(sqlite3_backup *p){
56760 sqlite3_backup **pp;
56761 assert( sqlite3BtreeHoldsMutex(p->pSrc) );
56762 pp = sqlite3PagerBackupPtr(sqlite3BtreePager(p->pSrc));
56763 p->pNext = *pp;
56764 *pp = p;
56765 p->isAttached = 1;
56769 ** Copy nPage pages from the source b-tree to the destination.
56771 SQLITE_API int sqlite3_backup_step(sqlite3_backup *p, int nPage){
56772 int rc;
56773 int destMode; /* Destination journal mode */
56774 int pgszSrc = 0; /* Source page size */
56775 int pgszDest = 0; /* Destination page size */
56777 sqlite3_mutex_enter(p->pSrcDb->mutex);
56778 sqlite3BtreeEnter(p->pSrc);
56779 if( p->pDestDb ){
56780 sqlite3_mutex_enter(p->pDestDb->mutex);
56783 rc = p->rc;
56784 if( !isFatalError(rc) ){
56785 Pager * const pSrcPager = sqlite3BtreePager(p->pSrc); /* Source pager */
56786 Pager * const pDestPager = sqlite3BtreePager(p->pDest); /* Dest pager */
56787 int ii; /* Iterator variable */
56788 int nSrcPage = -1; /* Size of source db in pages */
56789 int bCloseTrans = 0; /* True if src db requires unlocking */
56791 /* If the source pager is currently in a write-transaction, return
56792 ** SQLITE_BUSY immediately.
56794 if( p->pDestDb && p->pSrc->pBt->inTransaction==TRANS_WRITE ){
56795 rc = SQLITE_BUSY;
56796 }else{
56797 rc = SQLITE_OK;
56800 /* Lock the destination database, if it is not locked already. */
56801 if( SQLITE_OK==rc && p->bDestLocked==0
56802 && SQLITE_OK==(rc = sqlite3BtreeBeginTrans(p->pDest, 2))
56804 p->bDestLocked = 1;
56805 sqlite3BtreeGetMeta(p->pDest, BTREE_SCHEMA_VERSION, &p->iDestSchema);
56808 /* If there is no open read-transaction on the source database, open
56809 ** one now. If a transaction is opened here, then it will be closed
56810 ** before this function exits.
56812 if( rc==SQLITE_OK && 0==sqlite3BtreeIsInReadTrans(p->pSrc) ){
56813 rc = sqlite3BtreeBeginTrans(p->pSrc, 0);
56814 bCloseTrans = 1;
56817 /* Do not allow backup if the destination database is in WAL mode
56818 ** and the page sizes are different between source and destination */
56819 pgszSrc = sqlite3BtreeGetPageSize(p->pSrc);
56820 pgszDest = sqlite3BtreeGetPageSize(p->pDest);
56821 destMode = sqlite3PagerGetJournalMode(sqlite3BtreePager(p->pDest));
56822 if( SQLITE_OK==rc && destMode==PAGER_JOURNALMODE_WAL && pgszSrc!=pgszDest ){
56823 rc = SQLITE_READONLY;
56826 /* Now that there is a read-lock on the source database, query the
56827 ** source pager for the number of pages in the database.
56829 nSrcPage = (int)sqlite3BtreeLastPage(p->pSrc);
56830 assert( nSrcPage>=0 );
56831 for(ii=0; (nPage<0 || ii<nPage) && p->iNext<=(Pgno)nSrcPage && !rc; ii++){
56832 const Pgno iSrcPg = p->iNext; /* Source page number */
56833 if( iSrcPg!=PENDING_BYTE_PAGE(p->pSrc->pBt) ){
56834 DbPage *pSrcPg; /* Source page object */
56835 rc = sqlite3PagerGet(pSrcPager, iSrcPg, &pSrcPg);
56836 if( rc==SQLITE_OK ){
56837 rc = backupOnePage(p, iSrcPg, sqlite3PagerGetData(pSrcPg));
56838 sqlite3PagerUnref(pSrcPg);
56841 p->iNext++;
56843 if( rc==SQLITE_OK ){
56844 p->nPagecount = nSrcPage;
56845 p->nRemaining = nSrcPage+1-p->iNext;
56846 if( p->iNext>(Pgno)nSrcPage ){
56847 rc = SQLITE_DONE;
56848 }else if( !p->isAttached ){
56849 attachBackupObject(p);
56853 /* Update the schema version field in the destination database. This
56854 ** is to make sure that the schema-version really does change in
56855 ** the case where the source and destination databases have the
56856 ** same schema version.
56858 if( rc==SQLITE_DONE ){
56859 rc = sqlite3BtreeUpdateMeta(p->pDest,1,p->iDestSchema+1);
56860 if( rc==SQLITE_OK ){
56861 if( p->pDestDb ){
56862 sqlite3ResetInternalSchema(p->pDestDb, -1);
56864 if( destMode==PAGER_JOURNALMODE_WAL ){
56865 rc = sqlite3BtreeSetVersion(p->pDest, 2);
56868 if( rc==SQLITE_OK ){
56869 int nDestTruncate;
56870 /* Set nDestTruncate to the final number of pages in the destination
56871 ** database. The complication here is that the destination page
56872 ** size may be different to the source page size.
56874 ** If the source page size is smaller than the destination page size,
56875 ** round up. In this case the call to sqlite3OsTruncate() below will
56876 ** fix the size of the file. However it is important to call
56877 ** sqlite3PagerTruncateImage() here so that any pages in the
56878 ** destination file that lie beyond the nDestTruncate page mark are
56879 ** journalled by PagerCommitPhaseOne() before they are destroyed
56880 ** by the file truncation.
56882 assert( pgszSrc==sqlite3BtreeGetPageSize(p->pSrc) );
56883 assert( pgszDest==sqlite3BtreeGetPageSize(p->pDest) );
56884 if( pgszSrc<pgszDest ){
56885 int ratio = pgszDest/pgszSrc;
56886 nDestTruncate = (nSrcPage+ratio-1)/ratio;
56887 if( nDestTruncate==(int)PENDING_BYTE_PAGE(p->pDest->pBt) ){
56888 nDestTruncate--;
56890 }else{
56891 nDestTruncate = nSrcPage * (pgszSrc/pgszDest);
56893 sqlite3PagerTruncateImage(pDestPager, nDestTruncate);
56895 if( pgszSrc<pgszDest ){
56896 /* If the source page-size is smaller than the destination page-size,
56897 ** two extra things may need to happen:
56899 ** * The destination may need to be truncated, and
56901 ** * Data stored on the pages immediately following the
56902 ** pending-byte page in the source database may need to be
56903 ** copied into the destination database.
56905 const i64 iSize = (i64)pgszSrc * (i64)nSrcPage;
56906 sqlite3_file * const pFile = sqlite3PagerFile(pDestPager);
56907 i64 iOff;
56908 i64 iEnd;
56910 assert( pFile );
56911 assert( (i64)nDestTruncate*(i64)pgszDest >= iSize || (
56912 nDestTruncate==(int)(PENDING_BYTE_PAGE(p->pDest->pBt)-1)
56913 && iSize>=PENDING_BYTE && iSize<=PENDING_BYTE+pgszDest
56916 /* This call ensures that all data required to recreate the original
56917 ** database has been stored in the journal for pDestPager and the
56918 ** journal synced to disk. So at this point we may safely modify
56919 ** the database file in any way, knowing that if a power failure
56920 ** occurs, the original database will be reconstructed from the
56921 ** journal file. */
56922 rc = sqlite3PagerCommitPhaseOne(pDestPager, 0, 1);
56924 /* Write the extra pages and truncate the database file as required */
56925 iEnd = MIN(PENDING_BYTE + pgszDest, iSize);
56926 for(
56927 iOff=PENDING_BYTE+pgszSrc;
56928 rc==SQLITE_OK && iOff<iEnd;
56929 iOff+=pgszSrc
56931 PgHdr *pSrcPg = 0;
56932 const Pgno iSrcPg = (Pgno)((iOff/pgszSrc)+1);
56933 rc = sqlite3PagerGet(pSrcPager, iSrcPg, &pSrcPg);
56934 if( rc==SQLITE_OK ){
56935 u8 *zData = sqlite3PagerGetData(pSrcPg);
56936 rc = sqlite3OsWrite(pFile, zData, pgszSrc, iOff);
56938 sqlite3PagerUnref(pSrcPg);
56940 if( rc==SQLITE_OK ){
56941 rc = backupTruncateFile(pFile, iSize);
56944 /* Sync the database file to disk. */
56945 if( rc==SQLITE_OK ){
56946 rc = sqlite3PagerSync(pDestPager);
56948 }else{
56949 rc = sqlite3PagerCommitPhaseOne(pDestPager, 0, 0);
56952 /* Finish committing the transaction to the destination database. */
56953 if( SQLITE_OK==rc
56954 && SQLITE_OK==(rc = sqlite3BtreeCommitPhaseTwo(p->pDest, 0))
56956 rc = SQLITE_DONE;
56961 /* If bCloseTrans is true, then this function opened a read transaction
56962 ** on the source database. Close the read transaction here. There is
56963 ** no need to check the return values of the btree methods here, as
56964 ** "committing" a read-only transaction cannot fail.
56966 if( bCloseTrans ){
56967 TESTONLY( int rc2 );
56968 TESTONLY( rc2 = ) sqlite3BtreeCommitPhaseOne(p->pSrc, 0);
56969 TESTONLY( rc2 |= ) sqlite3BtreeCommitPhaseTwo(p->pSrc, 0);
56970 assert( rc2==SQLITE_OK );
56973 if( rc==SQLITE_IOERR_NOMEM ){
56974 rc = SQLITE_NOMEM;
56976 p->rc = rc;
56978 if( p->pDestDb ){
56979 sqlite3_mutex_leave(p->pDestDb->mutex);
56981 sqlite3BtreeLeave(p->pSrc);
56982 sqlite3_mutex_leave(p->pSrcDb->mutex);
56983 return rc;
56987 ** Release all resources associated with an sqlite3_backup* handle.
56989 SQLITE_API int sqlite3_backup_finish(sqlite3_backup *p){
56990 sqlite3_backup **pp; /* Ptr to head of pagers backup list */
56991 sqlite3_mutex *mutex; /* Mutex to protect source database */
56992 int rc; /* Value to return */
56994 /* Enter the mutexes */
56995 if( p==0 ) return SQLITE_OK;
56996 sqlite3_mutex_enter(p->pSrcDb->mutex);
56997 sqlite3BtreeEnter(p->pSrc);
56998 mutex = p->pSrcDb->mutex;
56999 if( p->pDestDb ){
57000 sqlite3_mutex_enter(p->pDestDb->mutex);
57003 /* Detach this backup from the source pager. */
57004 if( p->pDestDb ){
57005 p->pSrc->nBackup--;
57007 if( p->isAttached ){
57008 pp = sqlite3PagerBackupPtr(sqlite3BtreePager(p->pSrc));
57009 while( *pp!=p ){
57010 pp = &(*pp)->pNext;
57012 *pp = p->pNext;
57015 /* If a transaction is still open on the Btree, roll it back. */
57016 sqlite3BtreeRollback(p->pDest);
57018 /* Set the error code of the destination database handle. */
57019 rc = (p->rc==SQLITE_DONE) ? SQLITE_OK : p->rc;
57020 sqlite3Error(p->pDestDb, rc, 0);
57022 /* Exit the mutexes and free the backup context structure. */
57023 if( p->pDestDb ){
57024 sqlite3_mutex_leave(p->pDestDb->mutex);
57026 sqlite3BtreeLeave(p->pSrc);
57027 if( p->pDestDb ){
57028 /* EVIDENCE-OF: R-64852-21591 The sqlite3_backup object is created by a
57029 ** call to sqlite3_backup_init() and is destroyed by a call to
57030 ** sqlite3_backup_finish(). */
57031 sqlite3_free(p);
57033 sqlite3_mutex_leave(mutex);
57034 return rc;
57038 ** Return the number of pages still to be backed up as of the most recent
57039 ** call to sqlite3_backup_step().
57041 SQLITE_API int sqlite3_backup_remaining(sqlite3_backup *p){
57042 return p->nRemaining;
57046 ** Return the total number of pages in the source database as of the most
57047 ** recent call to sqlite3_backup_step().
57049 SQLITE_API int sqlite3_backup_pagecount(sqlite3_backup *p){
57050 return p->nPagecount;
57054 ** This function is called after the contents of page iPage of the
57055 ** source database have been modified. If page iPage has already been
57056 ** copied into the destination database, then the data written to the
57057 ** destination is now invalidated. The destination copy of iPage needs
57058 ** to be updated with the new data before the backup operation is
57059 ** complete.
57061 ** It is assumed that the mutex associated with the BtShared object
57062 ** corresponding to the source database is held when this function is
57063 ** called.
57065 SQLITE_PRIVATE void sqlite3BackupUpdate(sqlite3_backup *pBackup, Pgno iPage, const u8 *aData){
57066 sqlite3_backup *p; /* Iterator variable */
57067 for(p=pBackup; p; p=p->pNext){
57068 assert( sqlite3_mutex_held(p->pSrc->pBt->mutex) );
57069 if( !isFatalError(p->rc) && iPage<p->iNext ){
57070 /* The backup process p has already copied page iPage. But now it
57071 ** has been modified by a transaction on the source pager. Copy
57072 ** the new data into the backup.
57074 int rc;
57075 assert( p->pDestDb );
57076 sqlite3_mutex_enter(p->pDestDb->mutex);
57077 rc = backupOnePage(p, iPage, aData);
57078 sqlite3_mutex_leave(p->pDestDb->mutex);
57079 assert( rc!=SQLITE_BUSY && rc!=SQLITE_LOCKED );
57080 if( rc!=SQLITE_OK ){
57081 p->rc = rc;
57088 ** Restart the backup process. This is called when the pager layer
57089 ** detects that the database has been modified by an external database
57090 ** connection. In this case there is no way of knowing which of the
57091 ** pages that have been copied into the destination database are still
57092 ** valid and which are not, so the entire process needs to be restarted.
57094 ** It is assumed that the mutex associated with the BtShared object
57095 ** corresponding to the source database is held when this function is
57096 ** called.
57098 SQLITE_PRIVATE void sqlite3BackupRestart(sqlite3_backup *pBackup){
57099 sqlite3_backup *p; /* Iterator variable */
57100 for(p=pBackup; p; p=p->pNext){
57101 assert( sqlite3_mutex_held(p->pSrc->pBt->mutex) );
57102 p->iNext = 1;
57106 #ifndef SQLITE_OMIT_VACUUM
57108 ** Copy the complete content of pBtFrom into pBtTo. A transaction
57109 ** must be active for both files.
57111 ** The size of file pTo may be reduced by this operation. If anything
57112 ** goes wrong, the transaction on pTo is rolled back. If successful, the
57113 ** transaction is committed before returning.
57115 SQLITE_PRIVATE int sqlite3BtreeCopyFile(Btree *pTo, Btree *pFrom){
57116 int rc;
57117 sqlite3_backup b;
57118 sqlite3BtreeEnter(pTo);
57119 sqlite3BtreeEnter(pFrom);
57121 /* Set up an sqlite3_backup object. sqlite3_backup.pDestDb must be set
57122 ** to 0. This is used by the implementations of sqlite3_backup_step()
57123 ** and sqlite3_backup_finish() to detect that they are being called
57124 ** from this function, not directly by the user.
57126 memset(&b, 0, sizeof(b));
57127 b.pSrcDb = pFrom->db;
57128 b.pSrc = pFrom;
57129 b.pDest = pTo;
57130 b.iNext = 1;
57132 /* 0x7FFFFFFF is the hard limit for the number of pages in a database
57133 ** file. By passing this as the number of pages to copy to
57134 ** sqlite3_backup_step(), we can guarantee that the copy finishes
57135 ** within a single call (unless an error occurs). The assert() statement
57136 ** checks this assumption - (p->rc) should be set to either SQLITE_DONE
57137 ** or an error code.
57139 sqlite3_backup_step(&b, 0x7FFFFFFF);
57140 assert( b.rc!=SQLITE_OK );
57141 rc = sqlite3_backup_finish(&b);
57142 if( rc==SQLITE_OK ){
57143 pTo->pBt->pageSizeFixed = 0;
57146 sqlite3BtreeLeave(pFrom);
57147 sqlite3BtreeLeave(pTo);
57148 return rc;
57150 #endif /* SQLITE_OMIT_VACUUM */
57152 /************** End of backup.c **********************************************/
57153 /************** Begin file vdbemem.c *****************************************/
57155 ** 2004 May 26
57157 ** The author disclaims copyright to this source code. In place of
57158 ** a legal notice, here is a blessing:
57160 ** May you do good and not evil.
57161 ** May you find forgiveness for yourself and forgive others.
57162 ** May you share freely, never taking more than you give.
57164 *************************************************************************
57166 ** This file contains code use to manipulate "Mem" structure. A "Mem"
57167 ** stores a single value in the VDBE. Mem is an opaque structure visible
57168 ** only within the VDBE. Interface routines refer to a Mem using the
57169 ** name sqlite_value
57173 ** Call sqlite3VdbeMemExpandBlob() on the supplied value (type Mem*)
57174 ** P if required.
57176 #define expandBlob(P) (((P)->flags&MEM_Zero)?sqlite3VdbeMemExpandBlob(P):0)
57179 ** If pMem is an object with a valid string representation, this routine
57180 ** ensures the internal encoding for the string representation is
57181 ** 'desiredEnc', one of SQLITE_UTF8, SQLITE_UTF16LE or SQLITE_UTF16BE.
57183 ** If pMem is not a string object, or the encoding of the string
57184 ** representation is already stored using the requested encoding, then this
57185 ** routine is a no-op.
57187 ** SQLITE_OK is returned if the conversion is successful (or not required).
57188 ** SQLITE_NOMEM may be returned if a malloc() fails during conversion
57189 ** between formats.
57191 SQLITE_PRIVATE int sqlite3VdbeChangeEncoding(Mem *pMem, int desiredEnc){
57192 int rc;
57193 assert( (pMem->flags&MEM_RowSet)==0 );
57194 assert( desiredEnc==SQLITE_UTF8 || desiredEnc==SQLITE_UTF16LE
57195 || desiredEnc==SQLITE_UTF16BE );
57196 if( !(pMem->flags&MEM_Str) || pMem->enc==desiredEnc ){
57197 return SQLITE_OK;
57199 assert( pMem->db==0 || sqlite3_mutex_held(pMem->db->mutex) );
57200 #ifdef SQLITE_OMIT_UTF16
57201 return SQLITE_ERROR;
57202 #else
57204 /* MemTranslate() may return SQLITE_OK or SQLITE_NOMEM. If NOMEM is returned,
57205 ** then the encoding of the value may not have changed.
57207 rc = sqlite3VdbeMemTranslate(pMem, (u8)desiredEnc);
57208 assert(rc==SQLITE_OK || rc==SQLITE_NOMEM);
57209 assert(rc==SQLITE_OK || pMem->enc!=desiredEnc);
57210 assert(rc==SQLITE_NOMEM || pMem->enc==desiredEnc);
57211 return rc;
57212 #endif
57216 ** Make sure pMem->z points to a writable allocation of at least
57217 ** n bytes.
57219 ** If the memory cell currently contains string or blob data
57220 ** and the third argument passed to this function is true, the
57221 ** current content of the cell is preserved. Otherwise, it may
57222 ** be discarded.
57224 ** This function sets the MEM_Dyn flag and clears any xDel callback.
57225 ** It also clears MEM_Ephem and MEM_Static. If the preserve flag is
57226 ** not set, Mem.n is zeroed.
57228 SQLITE_PRIVATE int sqlite3VdbeMemGrow(Mem *pMem, int n, int preserve){
57229 assert( 1 >=
57230 ((pMem->zMalloc && pMem->zMalloc==pMem->z) ? 1 : 0) +
57231 (((pMem->flags&MEM_Dyn)&&pMem->xDel) ? 1 : 0) +
57232 ((pMem->flags&MEM_Ephem) ? 1 : 0) +
57233 ((pMem->flags&MEM_Static) ? 1 : 0)
57235 assert( (pMem->flags&MEM_RowSet)==0 );
57237 if( n<32 ) n = 32;
57238 if( sqlite3DbMallocSize(pMem->db, pMem->zMalloc)<n ){
57239 if( preserve && pMem->z==pMem->zMalloc ){
57240 pMem->z = pMem->zMalloc = sqlite3DbReallocOrFree(pMem->db, pMem->z, n);
57241 preserve = 0;
57242 }else{
57243 sqlite3DbFree(pMem->db, pMem->zMalloc);
57244 pMem->zMalloc = sqlite3DbMallocRaw(pMem->db, n);
57248 if( pMem->z && preserve && pMem->zMalloc && pMem->z!=pMem->zMalloc ){
57249 memcpy(pMem->zMalloc, pMem->z, pMem->n);
57251 if( pMem->flags&MEM_Dyn && pMem->xDel ){
57252 pMem->xDel((void *)(pMem->z));
57255 pMem->z = pMem->zMalloc;
57256 if( pMem->z==0 ){
57257 pMem->flags = MEM_Null;
57258 }else{
57259 pMem->flags &= ~(MEM_Ephem|MEM_Static);
57261 pMem->xDel = 0;
57262 return (pMem->z ? SQLITE_OK : SQLITE_NOMEM);
57266 ** Make the given Mem object MEM_Dyn. In other words, make it so
57267 ** that any TEXT or BLOB content is stored in memory obtained from
57268 ** malloc(). In this way, we know that the memory is safe to be
57269 ** overwritten or altered.
57271 ** Return SQLITE_OK on success or SQLITE_NOMEM if malloc fails.
57273 SQLITE_PRIVATE int sqlite3VdbeMemMakeWriteable(Mem *pMem){
57274 int f;
57275 assert( pMem->db==0 || sqlite3_mutex_held(pMem->db->mutex) );
57276 assert( (pMem->flags&MEM_RowSet)==0 );
57277 expandBlob(pMem);
57278 f = pMem->flags;
57279 if( (f&(MEM_Str|MEM_Blob)) && pMem->z!=pMem->zMalloc ){
57280 if( sqlite3VdbeMemGrow(pMem, pMem->n + 2, 1) ){
57281 return SQLITE_NOMEM;
57283 pMem->z[pMem->n] = 0;
57284 pMem->z[pMem->n+1] = 0;
57285 pMem->flags |= MEM_Term;
57286 #ifdef SQLITE_DEBUG
57287 pMem->pScopyFrom = 0;
57288 #endif
57291 return SQLITE_OK;
57295 ** If the given Mem* has a zero-filled tail, turn it into an ordinary
57296 ** blob stored in dynamically allocated space.
57298 #ifndef SQLITE_OMIT_INCRBLOB
57299 SQLITE_PRIVATE int sqlite3VdbeMemExpandBlob(Mem *pMem){
57300 if( pMem->flags & MEM_Zero ){
57301 int nByte;
57302 assert( pMem->flags&MEM_Blob );
57303 assert( (pMem->flags&MEM_RowSet)==0 );
57304 assert( pMem->db==0 || sqlite3_mutex_held(pMem->db->mutex) );
57306 /* Set nByte to the number of bytes required to store the expanded blob. */
57307 nByte = pMem->n + pMem->u.nZero;
57308 if( nByte<=0 ){
57309 nByte = 1;
57311 if( sqlite3VdbeMemGrow(pMem, nByte, 1) ){
57312 return SQLITE_NOMEM;
57315 memset(&pMem->z[pMem->n], 0, pMem->u.nZero);
57316 pMem->n += pMem->u.nZero;
57317 pMem->flags &= ~(MEM_Zero|MEM_Term);
57319 return SQLITE_OK;
57321 #endif
57325 ** Make sure the given Mem is \u0000 terminated.
57327 SQLITE_PRIVATE int sqlite3VdbeMemNulTerminate(Mem *pMem){
57328 assert( pMem->db==0 || sqlite3_mutex_held(pMem->db->mutex) );
57329 if( (pMem->flags & MEM_Term)!=0 || (pMem->flags & MEM_Str)==0 ){
57330 return SQLITE_OK; /* Nothing to do */
57332 if( sqlite3VdbeMemGrow(pMem, pMem->n+2, 1) ){
57333 return SQLITE_NOMEM;
57335 pMem->z[pMem->n] = 0;
57336 pMem->z[pMem->n+1] = 0;
57337 pMem->flags |= MEM_Term;
57338 return SQLITE_OK;
57342 ** Add MEM_Str to the set of representations for the given Mem. Numbers
57343 ** are converted using sqlite3_snprintf(). Converting a BLOB to a string
57344 ** is a no-op.
57346 ** Existing representations MEM_Int and MEM_Real are *not* invalidated.
57348 ** A MEM_Null value will never be passed to this function. This function is
57349 ** used for converting values to text for returning to the user (i.e. via
57350 ** sqlite3_value_text()), or for ensuring that values to be used as btree
57351 ** keys are strings. In the former case a NULL pointer is returned the
57352 ** user and the later is an internal programming error.
57354 SQLITE_PRIVATE int sqlite3VdbeMemStringify(Mem *pMem, int enc){
57355 int rc = SQLITE_OK;
57356 int fg = pMem->flags;
57357 const int nByte = 32;
57359 assert( pMem->db==0 || sqlite3_mutex_held(pMem->db->mutex) );
57360 assert( !(fg&MEM_Zero) );
57361 assert( !(fg&(MEM_Str|MEM_Blob)) );
57362 assert( fg&(MEM_Int|MEM_Real) );
57363 assert( (pMem->flags&MEM_RowSet)==0 );
57364 assert( EIGHT_BYTE_ALIGNMENT(pMem) );
57367 if( sqlite3VdbeMemGrow(pMem, nByte, 0) ){
57368 return SQLITE_NOMEM;
57371 /* For a Real or Integer, use sqlite3_mprintf() to produce the UTF-8
57372 ** string representation of the value. Then, if the required encoding
57373 ** is UTF-16le or UTF-16be do a translation.
57375 ** FIX ME: It would be better if sqlite3_snprintf() could do UTF-16.
57377 if( fg & MEM_Int ){
57378 sqlite3_snprintf(nByte, pMem->z, "%lld", pMem->u.i);
57379 }else{
57380 assert( fg & MEM_Real );
57381 sqlite3_snprintf(nByte, pMem->z, "%!.15g", pMem->r);
57383 pMem->n = sqlite3Strlen30(pMem->z);
57384 pMem->enc = SQLITE_UTF8;
57385 pMem->flags |= MEM_Str|MEM_Term;
57386 sqlite3VdbeChangeEncoding(pMem, enc);
57387 return rc;
57391 ** Memory cell pMem contains the context of an aggregate function.
57392 ** This routine calls the finalize method for that function. The
57393 ** result of the aggregate is stored back into pMem.
57395 ** Return SQLITE_ERROR if the finalizer reports an error. SQLITE_OK
57396 ** otherwise.
57398 SQLITE_PRIVATE int sqlite3VdbeMemFinalize(Mem *pMem, FuncDef *pFunc){
57399 int rc = SQLITE_OK;
57400 if( ALWAYS(pFunc && pFunc->xFinalize) ){
57401 sqlite3_context ctx;
57402 assert( (pMem->flags & MEM_Null)!=0 || pFunc==pMem->u.pDef );
57403 assert( pMem->db==0 || sqlite3_mutex_held(pMem->db->mutex) );
57404 memset(&ctx, 0, sizeof(ctx));
57405 ctx.s.flags = MEM_Null;
57406 ctx.s.db = pMem->db;
57407 ctx.pMem = pMem;
57408 ctx.pFunc = pFunc;
57409 pFunc->xFinalize(&ctx); /* IMP: R-24505-23230 */
57410 assert( 0==(pMem->flags&MEM_Dyn) && !pMem->xDel );
57411 sqlite3DbFree(pMem->db, pMem->zMalloc);
57412 memcpy(pMem, &ctx.s, sizeof(ctx.s));
57413 rc = ctx.isError;
57415 return rc;
57419 ** If the memory cell contains a string value that must be freed by
57420 ** invoking an external callback, free it now. Calling this function
57421 ** does not free any Mem.zMalloc buffer.
57423 SQLITE_PRIVATE void sqlite3VdbeMemReleaseExternal(Mem *p){
57424 assert( p->db==0 || sqlite3_mutex_held(p->db->mutex) );
57425 if( p->flags&MEM_Agg ){
57426 sqlite3VdbeMemFinalize(p, p->u.pDef);
57427 assert( (p->flags & MEM_Agg)==0 );
57428 sqlite3VdbeMemRelease(p);
57429 }else if( p->flags&MEM_Dyn && p->xDel ){
57430 assert( (p->flags&MEM_RowSet)==0 );
57431 p->xDel((void *)p->z);
57432 p->xDel = 0;
57433 }else if( p->flags&MEM_RowSet ){
57434 sqlite3RowSetClear(p->u.pRowSet);
57435 }else if( p->flags&MEM_Frame ){
57436 sqlite3VdbeMemSetNull(p);
57441 ** Release any memory held by the Mem. This may leave the Mem in an
57442 ** inconsistent state, for example with (Mem.z==0) and
57443 ** (Mem.type==SQLITE_TEXT).
57445 SQLITE_PRIVATE void sqlite3VdbeMemRelease(Mem *p){
57446 MemReleaseExt(p);
57447 sqlite3DbFree(p->db, p->zMalloc);
57448 p->z = 0;
57449 p->zMalloc = 0;
57450 p->xDel = 0;
57454 ** Convert a 64-bit IEEE double into a 64-bit signed integer.
57455 ** If the double is too large, return 0x8000000000000000.
57457 ** Most systems appear to do this simply by assigning
57458 ** variables and without the extra range tests. But
57459 ** there are reports that windows throws an expection
57460 ** if the floating point value is out of range. (See ticket #2880.)
57461 ** Because we do not completely understand the problem, we will
57462 ** take the conservative approach and always do range tests
57463 ** before attempting the conversion.
57465 static i64 doubleToInt64(double r){
57466 #ifdef SQLITE_OMIT_FLOATING_POINT
57467 /* When floating-point is omitted, double and int64 are the same thing */
57468 return r;
57469 #else
57471 ** Many compilers we encounter do not define constants for the
57472 ** minimum and maximum 64-bit integers, or they define them
57473 ** inconsistently. And many do not understand the "LL" notation.
57474 ** So we define our own static constants here using nothing
57475 ** larger than a 32-bit integer constant.
57477 static const i64 maxInt = LARGEST_INT64;
57478 static const i64 minInt = SMALLEST_INT64;
57480 if( r<(double)minInt ){
57481 return minInt;
57482 }else if( r>(double)maxInt ){
57483 /* minInt is correct here - not maxInt. It turns out that assigning
57484 ** a very large positive number to an integer results in a very large
57485 ** negative integer. This makes no sense, but it is what x86 hardware
57486 ** does so for compatibility we will do the same in software. */
57487 return minInt;
57488 }else{
57489 return (i64)r;
57491 #endif
57495 ** Return some kind of integer value which is the best we can do
57496 ** at representing the value that *pMem describes as an integer.
57497 ** If pMem is an integer, then the value is exact. If pMem is
57498 ** a floating-point then the value returned is the integer part.
57499 ** If pMem is a string or blob, then we make an attempt to convert
57500 ** it into a integer and return that. If pMem represents an
57501 ** an SQL-NULL value, return 0.
57503 ** If pMem represents a string value, its encoding might be changed.
57505 SQLITE_PRIVATE i64 sqlite3VdbeIntValue(Mem *pMem){
57506 int flags;
57507 assert( pMem->db==0 || sqlite3_mutex_held(pMem->db->mutex) );
57508 assert( EIGHT_BYTE_ALIGNMENT(pMem) );
57509 flags = pMem->flags;
57510 if( flags & MEM_Int ){
57511 return pMem->u.i;
57512 }else if( flags & MEM_Real ){
57513 return doubleToInt64(pMem->r);
57514 }else if( flags & (MEM_Str|MEM_Blob) ){
57515 i64 value = 0;
57516 assert( pMem->z || pMem->n==0 );
57517 testcase( pMem->z==0 );
57518 sqlite3Atoi64(pMem->z, &value, pMem->n, pMem->enc);
57519 return value;
57520 }else{
57521 return 0;
57526 ** Return the best representation of pMem that we can get into a
57527 ** double. If pMem is already a double or an integer, return its
57528 ** value. If it is a string or blob, try to convert it to a double.
57529 ** If it is a NULL, return 0.0.
57531 SQLITE_PRIVATE double sqlite3VdbeRealValue(Mem *pMem){
57532 assert( pMem->db==0 || sqlite3_mutex_held(pMem->db->mutex) );
57533 assert( EIGHT_BYTE_ALIGNMENT(pMem) );
57534 if( pMem->flags & MEM_Real ){
57535 return pMem->r;
57536 }else if( pMem->flags & MEM_Int ){
57537 return (double)pMem->u.i;
57538 }else if( pMem->flags & (MEM_Str|MEM_Blob) ){
57539 /* (double)0 In case of SQLITE_OMIT_FLOATING_POINT... */
57540 double val = (double)0;
57541 sqlite3AtoF(pMem->z, &val, pMem->n, pMem->enc);
57542 return val;
57543 }else{
57544 /* (double)0 In case of SQLITE_OMIT_FLOATING_POINT... */
57545 return (double)0;
57550 ** The MEM structure is already a MEM_Real. Try to also make it a
57551 ** MEM_Int if we can.
57553 SQLITE_PRIVATE void sqlite3VdbeIntegerAffinity(Mem *pMem){
57554 assert( pMem->flags & MEM_Real );
57555 assert( (pMem->flags & MEM_RowSet)==0 );
57556 assert( pMem->db==0 || sqlite3_mutex_held(pMem->db->mutex) );
57557 assert( EIGHT_BYTE_ALIGNMENT(pMem) );
57559 pMem->u.i = doubleToInt64(pMem->r);
57561 /* Only mark the value as an integer if
57563 ** (1) the round-trip conversion real->int->real is a no-op, and
57564 ** (2) The integer is neither the largest nor the smallest
57565 ** possible integer (ticket #3922)
57567 ** The second and third terms in the following conditional enforces
57568 ** the second condition under the assumption that addition overflow causes
57569 ** values to wrap around. On x86 hardware, the third term is always
57570 ** true and could be omitted. But we leave it in because other
57571 ** architectures might behave differently.
57573 if( pMem->r==(double)pMem->u.i && pMem->u.i>SMALLEST_INT64
57574 && ALWAYS(pMem->u.i<LARGEST_INT64) ){
57575 pMem->flags |= MEM_Int;
57580 ** Convert pMem to type integer. Invalidate any prior representations.
57582 SQLITE_PRIVATE int sqlite3VdbeMemIntegerify(Mem *pMem){
57583 assert( pMem->db==0 || sqlite3_mutex_held(pMem->db->mutex) );
57584 assert( (pMem->flags & MEM_RowSet)==0 );
57585 assert( EIGHT_BYTE_ALIGNMENT(pMem) );
57587 pMem->u.i = sqlite3VdbeIntValue(pMem);
57588 MemSetTypeFlag(pMem, MEM_Int);
57589 return SQLITE_OK;
57593 ** Convert pMem so that it is of type MEM_Real.
57594 ** Invalidate any prior representations.
57596 SQLITE_PRIVATE int sqlite3VdbeMemRealify(Mem *pMem){
57597 assert( pMem->db==0 || sqlite3_mutex_held(pMem->db->mutex) );
57598 assert( EIGHT_BYTE_ALIGNMENT(pMem) );
57600 pMem->r = sqlite3VdbeRealValue(pMem);
57601 MemSetTypeFlag(pMem, MEM_Real);
57602 return SQLITE_OK;
57606 ** Convert pMem so that it has types MEM_Real or MEM_Int or both.
57607 ** Invalidate any prior representations.
57609 ** Every effort is made to force the conversion, even if the input
57610 ** is a string that does not look completely like a number. Convert
57611 ** as much of the string as we can and ignore the rest.
57613 SQLITE_PRIVATE int sqlite3VdbeMemNumerify(Mem *pMem){
57614 if( (pMem->flags & (MEM_Int|MEM_Real|MEM_Null))==0 ){
57615 assert( (pMem->flags & (MEM_Blob|MEM_Str))!=0 );
57616 assert( pMem->db==0 || sqlite3_mutex_held(pMem->db->mutex) );
57617 if( 0==sqlite3Atoi64(pMem->z, &pMem->u.i, pMem->n, pMem->enc) ){
57618 MemSetTypeFlag(pMem, MEM_Int);
57619 }else{
57620 pMem->r = sqlite3VdbeRealValue(pMem);
57621 MemSetTypeFlag(pMem, MEM_Real);
57622 sqlite3VdbeIntegerAffinity(pMem);
57625 assert( (pMem->flags & (MEM_Int|MEM_Real|MEM_Null))!=0 );
57626 pMem->flags &= ~(MEM_Str|MEM_Blob);
57627 return SQLITE_OK;
57631 ** Delete any previous value and set the value stored in *pMem to NULL.
57633 SQLITE_PRIVATE void sqlite3VdbeMemSetNull(Mem *pMem){
57634 if( pMem->flags & MEM_Frame ){
57635 VdbeFrame *pFrame = pMem->u.pFrame;
57636 pFrame->pParent = pFrame->v->pDelFrame;
57637 pFrame->v->pDelFrame = pFrame;
57639 if( pMem->flags & MEM_RowSet ){
57640 sqlite3RowSetClear(pMem->u.pRowSet);
57642 MemSetTypeFlag(pMem, MEM_Null);
57643 pMem->type = SQLITE_NULL;
57647 ** Delete any previous value and set the value to be a BLOB of length
57648 ** n containing all zeros.
57650 SQLITE_PRIVATE void sqlite3VdbeMemSetZeroBlob(Mem *pMem, int n){
57651 sqlite3VdbeMemRelease(pMem);
57652 pMem->flags = MEM_Blob|MEM_Zero;
57653 pMem->type = SQLITE_BLOB;
57654 pMem->n = 0;
57655 if( n<0 ) n = 0;
57656 pMem->u.nZero = n;
57657 pMem->enc = SQLITE_UTF8;
57659 #ifdef SQLITE_OMIT_INCRBLOB
57660 sqlite3VdbeMemGrow(pMem, n, 0);
57661 if( pMem->z ){
57662 pMem->n = n;
57663 memset(pMem->z, 0, n);
57665 #endif
57669 ** Delete any previous value and set the value stored in *pMem to val,
57670 ** manifest type INTEGER.
57672 SQLITE_PRIVATE void sqlite3VdbeMemSetInt64(Mem *pMem, i64 val){
57673 sqlite3VdbeMemRelease(pMem);
57674 pMem->u.i = val;
57675 pMem->flags = MEM_Int;
57676 pMem->type = SQLITE_INTEGER;
57679 #ifndef SQLITE_OMIT_FLOATING_POINT
57681 ** Delete any previous value and set the value stored in *pMem to val,
57682 ** manifest type REAL.
57684 SQLITE_PRIVATE void sqlite3VdbeMemSetDouble(Mem *pMem, double val){
57685 if( sqlite3IsNaN(val) ){
57686 sqlite3VdbeMemSetNull(pMem);
57687 }else{
57688 sqlite3VdbeMemRelease(pMem);
57689 pMem->r = val;
57690 pMem->flags = MEM_Real;
57691 pMem->type = SQLITE_FLOAT;
57694 #endif
57697 ** Delete any previous value and set the value of pMem to be an
57698 ** empty boolean index.
57700 SQLITE_PRIVATE void sqlite3VdbeMemSetRowSet(Mem *pMem){
57701 sqlite3 *db = pMem->db;
57702 assert( db!=0 );
57703 assert( (pMem->flags & MEM_RowSet)==0 );
57704 sqlite3VdbeMemRelease(pMem);
57705 pMem->zMalloc = sqlite3DbMallocRaw(db, 64);
57706 if( db->mallocFailed ){
57707 pMem->flags = MEM_Null;
57708 }else{
57709 assert( pMem->zMalloc );
57710 pMem->u.pRowSet = sqlite3RowSetInit(db, pMem->zMalloc,
57711 sqlite3DbMallocSize(db, pMem->zMalloc));
57712 assert( pMem->u.pRowSet!=0 );
57713 pMem->flags = MEM_RowSet;
57718 ** Return true if the Mem object contains a TEXT or BLOB that is
57719 ** too large - whose size exceeds SQLITE_MAX_LENGTH.
57721 SQLITE_PRIVATE int sqlite3VdbeMemTooBig(Mem *p){
57722 assert( p->db!=0 );
57723 if( p->flags & (MEM_Str|MEM_Blob) ){
57724 int n = p->n;
57725 if( p->flags & MEM_Zero ){
57726 n += p->u.nZero;
57728 return n>p->db->aLimit[SQLITE_LIMIT_LENGTH];
57730 return 0;
57733 #ifdef SQLITE_DEBUG
57735 ** This routine prepares a memory cell for modication by breaking
57736 ** its link to a shallow copy and by marking any current shallow
57737 ** copies of this cell as invalid.
57739 ** This is used for testing and debugging only - to make sure shallow
57740 ** copies are not misused.
57742 SQLITE_PRIVATE void sqlite3VdbeMemPrepareToChange(Vdbe *pVdbe, Mem *pMem){
57743 int i;
57744 Mem *pX;
57745 for(i=1, pX=&pVdbe->aMem[1]; i<=pVdbe->nMem; i++, pX++){
57746 if( pX->pScopyFrom==pMem ){
57747 pX->flags |= MEM_Invalid;
57748 pX->pScopyFrom = 0;
57751 pMem->pScopyFrom = 0;
57753 #endif /* SQLITE_DEBUG */
57756 ** Size of struct Mem not including the Mem.zMalloc member.
57758 #define MEMCELLSIZE (size_t)(&(((Mem *)0)->zMalloc))
57761 ** Make an shallow copy of pFrom into pTo. Prior contents of
57762 ** pTo are freed. The pFrom->z field is not duplicated. If
57763 ** pFrom->z is used, then pTo->z points to the same thing as pFrom->z
57764 ** and flags gets srcType (either MEM_Ephem or MEM_Static).
57766 SQLITE_PRIVATE void sqlite3VdbeMemShallowCopy(Mem *pTo, const Mem *pFrom, int srcType){
57767 assert( (pFrom->flags & MEM_RowSet)==0 );
57768 MemReleaseExt(pTo);
57769 memcpy(pTo, pFrom, MEMCELLSIZE);
57770 pTo->xDel = 0;
57771 if( (pFrom->flags&MEM_Static)==0 ){
57772 pTo->flags &= ~(MEM_Dyn|MEM_Static|MEM_Ephem);
57773 assert( srcType==MEM_Ephem || srcType==MEM_Static );
57774 pTo->flags |= srcType;
57779 ** Make a full copy of pFrom into pTo. Prior contents of pTo are
57780 ** freed before the copy is made.
57782 SQLITE_PRIVATE int sqlite3VdbeMemCopy(Mem *pTo, const Mem *pFrom){
57783 int rc = SQLITE_OK;
57785 assert( (pFrom->flags & MEM_RowSet)==0 );
57786 MemReleaseExt(pTo);
57787 memcpy(pTo, pFrom, MEMCELLSIZE);
57788 pTo->flags &= ~MEM_Dyn;
57790 if( pTo->flags&(MEM_Str|MEM_Blob) ){
57791 if( 0==(pFrom->flags&MEM_Static) ){
57792 pTo->flags |= MEM_Ephem;
57793 rc = sqlite3VdbeMemMakeWriteable(pTo);
57797 return rc;
57801 ** Transfer the contents of pFrom to pTo. Any existing value in pTo is
57802 ** freed. If pFrom contains ephemeral data, a copy is made.
57804 ** pFrom contains an SQL NULL when this routine returns.
57806 SQLITE_PRIVATE void sqlite3VdbeMemMove(Mem *pTo, Mem *pFrom){
57807 assert( pFrom->db==0 || sqlite3_mutex_held(pFrom->db->mutex) );
57808 assert( pTo->db==0 || sqlite3_mutex_held(pTo->db->mutex) );
57809 assert( pFrom->db==0 || pTo->db==0 || pFrom->db==pTo->db );
57811 sqlite3VdbeMemRelease(pTo);
57812 memcpy(pTo, pFrom, sizeof(Mem));
57813 pFrom->flags = MEM_Null;
57814 pFrom->xDel = 0;
57815 pFrom->zMalloc = 0;
57819 ** Change the value of a Mem to be a string or a BLOB.
57821 ** The memory management strategy depends on the value of the xDel
57822 ** parameter. If the value passed is SQLITE_TRANSIENT, then the
57823 ** string is copied into a (possibly existing) buffer managed by the
57824 ** Mem structure. Otherwise, any existing buffer is freed and the
57825 ** pointer copied.
57827 ** If the string is too large (if it exceeds the SQLITE_LIMIT_LENGTH
57828 ** size limit) then no memory allocation occurs. If the string can be
57829 ** stored without allocating memory, then it is. If a memory allocation
57830 ** is required to store the string, then value of pMem is unchanged. In
57831 ** either case, SQLITE_TOOBIG is returned.
57833 SQLITE_PRIVATE int sqlite3VdbeMemSetStr(
57834 Mem *pMem, /* Memory cell to set to string value */
57835 const char *z, /* String pointer */
57836 int n, /* Bytes in string, or negative */
57837 u8 enc, /* Encoding of z. 0 for BLOBs */
57838 void (*xDel)(void*) /* Destructor function */
57840 int nByte = n; /* New value for pMem->n */
57841 int iLimit; /* Maximum allowed string or blob size */
57842 u16 flags = 0; /* New value for pMem->flags */
57844 assert( pMem->db==0 || sqlite3_mutex_held(pMem->db->mutex) );
57845 assert( (pMem->flags & MEM_RowSet)==0 );
57847 /* If z is a NULL pointer, set pMem to contain an SQL NULL. */
57848 if( !z ){
57849 sqlite3VdbeMemSetNull(pMem);
57850 return SQLITE_OK;
57853 if( pMem->db ){
57854 iLimit = pMem->db->aLimit[SQLITE_LIMIT_LENGTH];
57855 }else{
57856 iLimit = SQLITE_MAX_LENGTH;
57858 flags = (enc==0?MEM_Blob:MEM_Str);
57859 if( nByte<0 ){
57860 assert( enc!=0 );
57861 if( enc==SQLITE_UTF8 ){
57862 for(nByte=0; nByte<=iLimit && z[nByte]; nByte++){}
57863 }else{
57864 for(nByte=0; nByte<=iLimit && (z[nByte] | z[nByte+1]); nByte+=2){}
57866 flags |= MEM_Term;
57869 /* The following block sets the new values of Mem.z and Mem.xDel. It
57870 ** also sets a flag in local variable "flags" to indicate the memory
57871 ** management (one of MEM_Dyn or MEM_Static).
57873 if( xDel==SQLITE_TRANSIENT ){
57874 int nAlloc = nByte;
57875 if( flags&MEM_Term ){
57876 nAlloc += (enc==SQLITE_UTF8?1:2);
57878 if( nByte>iLimit ){
57879 return SQLITE_TOOBIG;
57881 if( sqlite3VdbeMemGrow(pMem, nAlloc, 0) ){
57882 return SQLITE_NOMEM;
57884 memcpy(pMem->z, z, nAlloc);
57885 }else if( xDel==SQLITE_DYNAMIC ){
57886 sqlite3VdbeMemRelease(pMem);
57887 pMem->zMalloc = pMem->z = (char *)z;
57888 pMem->xDel = 0;
57889 }else{
57890 sqlite3VdbeMemRelease(pMem);
57891 pMem->z = (char *)z;
57892 pMem->xDel = xDel;
57893 flags |= ((xDel==SQLITE_STATIC)?MEM_Static:MEM_Dyn);
57896 pMem->n = nByte;
57897 pMem->flags = flags;
57898 pMem->enc = (enc==0 ? SQLITE_UTF8 : enc);
57899 pMem->type = (enc==0 ? SQLITE_BLOB : SQLITE_TEXT);
57901 #ifndef SQLITE_OMIT_UTF16
57902 if( pMem->enc!=SQLITE_UTF8 && sqlite3VdbeMemHandleBom(pMem) ){
57903 return SQLITE_NOMEM;
57905 #endif
57907 if( nByte>iLimit ){
57908 return SQLITE_TOOBIG;
57911 return SQLITE_OK;
57915 ** Compare the values contained by the two memory cells, returning
57916 ** negative, zero or positive if pMem1 is less than, equal to, or greater
57917 ** than pMem2. Sorting order is NULL's first, followed by numbers (integers
57918 ** and reals) sorted numerically, followed by text ordered by the collating
57919 ** sequence pColl and finally blob's ordered by memcmp().
57921 ** Two NULL values are considered equal by this function.
57923 SQLITE_PRIVATE int sqlite3MemCompare(const Mem *pMem1, const Mem *pMem2, const CollSeq *pColl){
57924 int rc;
57925 int f1, f2;
57926 int combined_flags;
57928 f1 = pMem1->flags;
57929 f2 = pMem2->flags;
57930 combined_flags = f1|f2;
57931 assert( (combined_flags & MEM_RowSet)==0 );
57933 /* If one value is NULL, it is less than the other. If both values
57934 ** are NULL, return 0.
57936 if( combined_flags&MEM_Null ){
57937 return (f2&MEM_Null) - (f1&MEM_Null);
57940 /* If one value is a number and the other is not, the number is less.
57941 ** If both are numbers, compare as reals if one is a real, or as integers
57942 ** if both values are integers.
57944 if( combined_flags&(MEM_Int|MEM_Real) ){
57945 if( !(f1&(MEM_Int|MEM_Real)) ){
57946 return 1;
57948 if( !(f2&(MEM_Int|MEM_Real)) ){
57949 return -1;
57951 if( (f1 & f2 & MEM_Int)==0 ){
57952 double r1, r2;
57953 if( (f1&MEM_Real)==0 ){
57954 r1 = (double)pMem1->u.i;
57955 }else{
57956 r1 = pMem1->r;
57958 if( (f2&MEM_Real)==0 ){
57959 r2 = (double)pMem2->u.i;
57960 }else{
57961 r2 = pMem2->r;
57963 if( r1<r2 ) return -1;
57964 if( r1>r2 ) return 1;
57965 return 0;
57966 }else{
57967 assert( f1&MEM_Int );
57968 assert( f2&MEM_Int );
57969 if( pMem1->u.i < pMem2->u.i ) return -1;
57970 if( pMem1->u.i > pMem2->u.i ) return 1;
57971 return 0;
57975 /* If one value is a string and the other is a blob, the string is less.
57976 ** If both are strings, compare using the collating functions.
57978 if( combined_flags&MEM_Str ){
57979 if( (f1 & MEM_Str)==0 ){
57980 return 1;
57982 if( (f2 & MEM_Str)==0 ){
57983 return -1;
57986 assert( pMem1->enc==pMem2->enc );
57987 assert( pMem1->enc==SQLITE_UTF8 ||
57988 pMem1->enc==SQLITE_UTF16LE || pMem1->enc==SQLITE_UTF16BE );
57990 /* The collation sequence must be defined at this point, even if
57991 ** the user deletes the collation sequence after the vdbe program is
57992 ** compiled (this was not always the case).
57994 assert( !pColl || pColl->xCmp );
57996 if( pColl ){
57997 if( pMem1->enc==pColl->enc ){
57998 /* The strings are already in the correct encoding. Call the
57999 ** comparison function directly */
58000 return pColl->xCmp(pColl->pUser,pMem1->n,pMem1->z,pMem2->n,pMem2->z);
58001 }else{
58002 const void *v1, *v2;
58003 int n1, n2;
58004 Mem c1;
58005 Mem c2;
58006 memset(&c1, 0, sizeof(c1));
58007 memset(&c2, 0, sizeof(c2));
58008 sqlite3VdbeMemShallowCopy(&c1, pMem1, MEM_Ephem);
58009 sqlite3VdbeMemShallowCopy(&c2, pMem2, MEM_Ephem);
58010 v1 = sqlite3ValueText((sqlite3_value*)&c1, pColl->enc);
58011 n1 = v1==0 ? 0 : c1.n;
58012 v2 = sqlite3ValueText((sqlite3_value*)&c2, pColl->enc);
58013 n2 = v2==0 ? 0 : c2.n;
58014 rc = pColl->xCmp(pColl->pUser, n1, v1, n2, v2);
58015 sqlite3VdbeMemRelease(&c1);
58016 sqlite3VdbeMemRelease(&c2);
58017 return rc;
58020 /* If a NULL pointer was passed as the collate function, fall through
58021 ** to the blob case and use memcmp(). */
58024 /* Both values must be blobs. Compare using memcmp(). */
58025 rc = memcmp(pMem1->z, pMem2->z, (pMem1->n>pMem2->n)?pMem2->n:pMem1->n);
58026 if( rc==0 ){
58027 rc = pMem1->n - pMem2->n;
58029 return rc;
58033 ** Move data out of a btree key or data field and into a Mem structure.
58034 ** The data or key is taken from the entry that pCur is currently pointing
58035 ** to. offset and amt determine what portion of the data or key to retrieve.
58036 ** key is true to get the key or false to get data. The result is written
58037 ** into the pMem element.
58039 ** The pMem structure is assumed to be uninitialized. Any prior content
58040 ** is overwritten without being freed.
58042 ** If this routine fails for any reason (malloc returns NULL or unable
58043 ** to read from the disk) then the pMem is left in an inconsistent state.
58045 SQLITE_PRIVATE int sqlite3VdbeMemFromBtree(
58046 BtCursor *pCur, /* Cursor pointing at record to retrieve. */
58047 int offset, /* Offset from the start of data to return bytes from. */
58048 int amt, /* Number of bytes to return. */
58049 int key, /* If true, retrieve from the btree key, not data. */
58050 Mem *pMem /* OUT: Return data in this Mem structure. */
58052 char *zData; /* Data from the btree layer */
58053 int available = 0; /* Number of bytes available on the local btree page */
58054 int rc = SQLITE_OK; /* Return code */
58056 assert( sqlite3BtreeCursorIsValid(pCur) );
58058 /* Note: the calls to BtreeKeyFetch() and DataFetch() below assert()
58059 ** that both the BtShared and database handle mutexes are held. */
58060 assert( (pMem->flags & MEM_RowSet)==0 );
58061 if( key ){
58062 zData = (char *)sqlite3BtreeKeyFetch(pCur, &available);
58063 }else{
58064 zData = (char *)sqlite3BtreeDataFetch(pCur, &available);
58066 assert( zData!=0 );
58068 if( offset+amt<=available && (pMem->flags&MEM_Dyn)==0 ){
58069 sqlite3VdbeMemRelease(pMem);
58070 pMem->z = &zData[offset];
58071 pMem->flags = MEM_Blob|MEM_Ephem;
58072 }else if( SQLITE_OK==(rc = sqlite3VdbeMemGrow(pMem, amt+2, 0)) ){
58073 pMem->flags = MEM_Blob|MEM_Dyn|MEM_Term;
58074 pMem->enc = 0;
58075 pMem->type = SQLITE_BLOB;
58076 if( key ){
58077 rc = sqlite3BtreeKey(pCur, offset, amt, pMem->z);
58078 }else{
58079 rc = sqlite3BtreeData(pCur, offset, amt, pMem->z);
58081 pMem->z[amt] = 0;
58082 pMem->z[amt+1] = 0;
58083 if( rc!=SQLITE_OK ){
58084 sqlite3VdbeMemRelease(pMem);
58087 pMem->n = amt;
58089 return rc;
58092 /* This function is only available internally, it is not part of the
58093 ** external API. It works in a similar way to sqlite3_value_text(),
58094 ** except the data returned is in the encoding specified by the second
58095 ** parameter, which must be one of SQLITE_UTF16BE, SQLITE_UTF16LE or
58096 ** SQLITE_UTF8.
58098 ** (2006-02-16:) The enc value can be or-ed with SQLITE_UTF16_ALIGNED.
58099 ** If that is the case, then the result must be aligned on an even byte
58100 ** boundary.
58102 SQLITE_PRIVATE const void *sqlite3ValueText(sqlite3_value* pVal, u8 enc){
58103 if( !pVal ) return 0;
58105 assert( pVal->db==0 || sqlite3_mutex_held(pVal->db->mutex) );
58106 assert( (enc&3)==(enc&~SQLITE_UTF16_ALIGNED) );
58107 assert( (pVal->flags & MEM_RowSet)==0 );
58109 if( pVal->flags&MEM_Null ){
58110 return 0;
58112 assert( (MEM_Blob>>3) == MEM_Str );
58113 pVal->flags |= (pVal->flags & MEM_Blob)>>3;
58114 expandBlob(pVal);
58115 if( pVal->flags&MEM_Str ){
58116 sqlite3VdbeChangeEncoding(pVal, enc & ~SQLITE_UTF16_ALIGNED);
58117 if( (enc & SQLITE_UTF16_ALIGNED)!=0 && 1==(1&SQLITE_PTR_TO_INT(pVal->z)) ){
58118 assert( (pVal->flags & (MEM_Ephem|MEM_Static))!=0 );
58119 if( sqlite3VdbeMemMakeWriteable(pVal)!=SQLITE_OK ){
58120 return 0;
58123 sqlite3VdbeMemNulTerminate(pVal); /* IMP: R-59893-45467 */
58124 }else{
58125 assert( (pVal->flags&MEM_Blob)==0 );
58126 sqlite3VdbeMemStringify(pVal, enc);
58127 assert( 0==(1&SQLITE_PTR_TO_INT(pVal->z)) );
58129 assert(pVal->enc==(enc & ~SQLITE_UTF16_ALIGNED) || pVal->db==0
58130 || pVal->db->mallocFailed );
58131 if( pVal->enc==(enc & ~SQLITE_UTF16_ALIGNED) ){
58132 return pVal->z;
58133 }else{
58134 return 0;
58139 ** Create a new sqlite3_value object.
58141 SQLITE_PRIVATE sqlite3_value *sqlite3ValueNew(sqlite3 *db){
58142 Mem *p = sqlite3DbMallocZero(db, sizeof(*p));
58143 if( p ){
58144 p->flags = MEM_Null;
58145 p->type = SQLITE_NULL;
58146 p->db = db;
58148 return p;
58152 ** Create a new sqlite3_value object, containing the value of pExpr.
58154 ** This only works for very simple expressions that consist of one constant
58155 ** token (i.e. "5", "5.1", "'a string'"). If the expression can
58156 ** be converted directly into a value, then the value is allocated and
58157 ** a pointer written to *ppVal. The caller is responsible for deallocating
58158 ** the value by passing it to sqlite3ValueFree() later on. If the expression
58159 ** cannot be converted to a value, then *ppVal is set to NULL.
58161 SQLITE_PRIVATE int sqlite3ValueFromExpr(
58162 sqlite3 *db, /* The database connection */
58163 Expr *pExpr, /* The expression to evaluate */
58164 u8 enc, /* Encoding to use */
58165 u8 affinity, /* Affinity to use */
58166 sqlite3_value **ppVal /* Write the new value here */
58168 int op;
58169 char *zVal = 0;
58170 sqlite3_value *pVal = 0;
58171 int negInt = 1;
58172 const char *zNeg = "";
58174 if( !pExpr ){
58175 *ppVal = 0;
58176 return SQLITE_OK;
58178 op = pExpr->op;
58180 /* op can only be TK_REGISTER if we have compiled with SQLITE_ENABLE_STAT2.
58181 ** The ifdef here is to enable us to achieve 100% branch test coverage even
58182 ** when SQLITE_ENABLE_STAT2 is omitted.
58184 #ifdef SQLITE_ENABLE_STAT2
58185 if( op==TK_REGISTER ) op = pExpr->op2;
58186 #else
58187 if( NEVER(op==TK_REGISTER) ) op = pExpr->op2;
58188 #endif
58190 /* Handle negative integers in a single step. This is needed in the
58191 ** case when the value is -9223372036854775808.
58193 if( op==TK_UMINUS
58194 && (pExpr->pLeft->op==TK_INTEGER || pExpr->pLeft->op==TK_FLOAT) ){
58195 pExpr = pExpr->pLeft;
58196 op = pExpr->op;
58197 negInt = -1;
58198 zNeg = "-";
58201 if( op==TK_STRING || op==TK_FLOAT || op==TK_INTEGER ){
58202 pVal = sqlite3ValueNew(db);
58203 if( pVal==0 ) goto no_mem;
58204 if( ExprHasProperty(pExpr, EP_IntValue) ){
58205 sqlite3VdbeMemSetInt64(pVal, (i64)pExpr->u.iValue*negInt);
58206 }else{
58207 zVal = sqlite3MPrintf(db, "%s%s", zNeg, pExpr->u.zToken);
58208 if( zVal==0 ) goto no_mem;
58209 sqlite3ValueSetStr(pVal, -1, zVal, SQLITE_UTF8, SQLITE_DYNAMIC);
58210 if( op==TK_FLOAT ) pVal->type = SQLITE_FLOAT;
58212 if( (op==TK_INTEGER || op==TK_FLOAT ) && affinity==SQLITE_AFF_NONE ){
58213 sqlite3ValueApplyAffinity(pVal, SQLITE_AFF_NUMERIC, SQLITE_UTF8);
58214 }else{
58215 sqlite3ValueApplyAffinity(pVal, affinity, SQLITE_UTF8);
58217 if( pVal->flags & (MEM_Int|MEM_Real) ) pVal->flags &= ~MEM_Str;
58218 if( enc!=SQLITE_UTF8 ){
58219 sqlite3VdbeChangeEncoding(pVal, enc);
58221 }else if( op==TK_UMINUS ) {
58222 /* This branch happens for multiple negative signs. Ex: -(-5) */
58223 if( SQLITE_OK==sqlite3ValueFromExpr(db,pExpr->pLeft,enc,affinity,&pVal) ){
58224 sqlite3VdbeMemNumerify(pVal);
58225 if( pVal->u.i==SMALLEST_INT64 ){
58226 pVal->flags &= MEM_Int;
58227 pVal->flags |= MEM_Real;
58228 pVal->r = (double)LARGEST_INT64;
58229 }else{
58230 pVal->u.i = -pVal->u.i;
58232 pVal->r = -pVal->r;
58233 sqlite3ValueApplyAffinity(pVal, affinity, enc);
58235 }else if( op==TK_NULL ){
58236 pVal = sqlite3ValueNew(db);
58237 if( pVal==0 ) goto no_mem;
58239 #ifndef SQLITE_OMIT_BLOB_LITERAL
58240 else if( op==TK_BLOB ){
58241 int nVal;
58242 assert( pExpr->u.zToken[0]=='x' || pExpr->u.zToken[0]=='X' );
58243 assert( pExpr->u.zToken[1]=='\'' );
58244 pVal = sqlite3ValueNew(db);
58245 if( !pVal ) goto no_mem;
58246 zVal = &pExpr->u.zToken[2];
58247 nVal = sqlite3Strlen30(zVal)-1;
58248 assert( zVal[nVal]=='\'' );
58249 sqlite3VdbeMemSetStr(pVal, sqlite3HexToBlob(db, zVal, nVal), nVal/2,
58250 0, SQLITE_DYNAMIC);
58252 #endif
58254 if( pVal ){
58255 sqlite3VdbeMemStoreType(pVal);
58257 *ppVal = pVal;
58258 return SQLITE_OK;
58260 no_mem:
58261 db->mallocFailed = 1;
58262 sqlite3DbFree(db, zVal);
58263 sqlite3ValueFree(pVal);
58264 *ppVal = 0;
58265 return SQLITE_NOMEM;
58269 ** Change the string value of an sqlite3_value object
58271 SQLITE_PRIVATE void sqlite3ValueSetStr(
58272 sqlite3_value *v, /* Value to be set */
58273 int n, /* Length of string z */
58274 const void *z, /* Text of the new string */
58275 u8 enc, /* Encoding to use */
58276 void (*xDel)(void*) /* Destructor for the string */
58278 if( v ) sqlite3VdbeMemSetStr((Mem *)v, z, n, enc, xDel);
58282 ** Free an sqlite3_value object
58284 SQLITE_PRIVATE void sqlite3ValueFree(sqlite3_value *v){
58285 if( !v ) return;
58286 sqlite3VdbeMemRelease((Mem *)v);
58287 sqlite3DbFree(((Mem*)v)->db, v);
58291 ** Return the number of bytes in the sqlite3_value object assuming
58292 ** that it uses the encoding "enc"
58294 SQLITE_PRIVATE int sqlite3ValueBytes(sqlite3_value *pVal, u8 enc){
58295 Mem *p = (Mem*)pVal;
58296 if( (p->flags & MEM_Blob)!=0 || sqlite3ValueText(pVal, enc) ){
58297 if( p->flags & MEM_Zero ){
58298 return p->n + p->u.nZero;
58299 }else{
58300 return p->n;
58303 return 0;
58306 /************** End of vdbemem.c *********************************************/
58307 /************** Begin file vdbeaux.c *****************************************/
58309 ** 2003 September 6
58311 ** The author disclaims copyright to this source code. In place of
58312 ** a legal notice, here is a blessing:
58314 ** May you do good and not evil.
58315 ** May you find forgiveness for yourself and forgive others.
58316 ** May you share freely, never taking more than you give.
58318 *************************************************************************
58319 ** This file contains code used for creating, destroying, and populating
58320 ** a VDBE (or an "sqlite3_stmt" as it is known to the outside world.) Prior
58321 ** to version 2.8.7, all this code was combined into the vdbe.c source file.
58322 ** But that file was getting too big so this subroutines were split out.
58328 ** When debugging the code generator in a symbolic debugger, one can
58329 ** set the sqlite3VdbeAddopTrace to 1 and all opcodes will be printed
58330 ** as they are added to the instruction stream.
58332 #ifdef SQLITE_DEBUG
58333 SQLITE_PRIVATE int sqlite3VdbeAddopTrace = 0;
58334 #endif
58338 ** Create a new virtual database engine.
58340 SQLITE_PRIVATE Vdbe *sqlite3VdbeCreate(sqlite3 *db){
58341 Vdbe *p;
58342 p = sqlite3DbMallocZero(db, sizeof(Vdbe) );
58343 if( p==0 ) return 0;
58344 p->db = db;
58345 if( db->pVdbe ){
58346 db->pVdbe->pPrev = p;
58348 p->pNext = db->pVdbe;
58349 p->pPrev = 0;
58350 db->pVdbe = p;
58351 p->magic = VDBE_MAGIC_INIT;
58352 return p;
58356 ** Remember the SQL string for a prepared statement.
58358 SQLITE_PRIVATE void sqlite3VdbeSetSql(Vdbe *p, const char *z, int n, int isPrepareV2){
58359 assert( isPrepareV2==1 || isPrepareV2==0 );
58360 if( p==0 ) return;
58361 #ifdef SQLITE_OMIT_TRACE
58362 if( !isPrepareV2 ) return;
58363 #endif
58364 assert( p->zSql==0 );
58365 p->zSql = sqlite3DbStrNDup(p->db, z, n);
58366 p->isPrepareV2 = (u8)isPrepareV2;
58370 ** Return the SQL associated with a prepared statement
58372 SQLITE_API const char *sqlite3_sql(sqlite3_stmt *pStmt){
58373 Vdbe *p = (Vdbe *)pStmt;
58374 return (p && p->isPrepareV2) ? p->zSql : 0;
58378 ** Swap all content between two VDBE structures.
58380 SQLITE_PRIVATE void sqlite3VdbeSwap(Vdbe *pA, Vdbe *pB){
58381 Vdbe tmp, *pTmp;
58382 char *zTmp;
58383 tmp = *pA;
58384 *pA = *pB;
58385 *pB = tmp;
58386 pTmp = pA->pNext;
58387 pA->pNext = pB->pNext;
58388 pB->pNext = pTmp;
58389 pTmp = pA->pPrev;
58390 pA->pPrev = pB->pPrev;
58391 pB->pPrev = pTmp;
58392 zTmp = pA->zSql;
58393 pA->zSql = pB->zSql;
58394 pB->zSql = zTmp;
58395 pB->isPrepareV2 = pA->isPrepareV2;
58398 #ifdef SQLITE_DEBUG
58400 ** Turn tracing on or off
58402 SQLITE_PRIVATE void sqlite3VdbeTrace(Vdbe *p, FILE *trace){
58403 p->trace = trace;
58405 #endif
58408 ** Resize the Vdbe.aOp array so that it is at least one op larger than
58409 ** it was.
58411 ** If an out-of-memory error occurs while resizing the array, return
58412 ** SQLITE_NOMEM. In this case Vdbe.aOp and Vdbe.nOpAlloc remain
58413 ** unchanged (this is so that any opcodes already allocated can be
58414 ** correctly deallocated along with the rest of the Vdbe).
58416 static int growOpArray(Vdbe *p){
58417 VdbeOp *pNew;
58418 int nNew = (p->nOpAlloc ? p->nOpAlloc*2 : (int)(1024/sizeof(Op)));
58419 pNew = sqlite3DbRealloc(p->db, p->aOp, nNew*sizeof(Op));
58420 if( pNew ){
58421 p->nOpAlloc = sqlite3DbMallocSize(p->db, pNew)/sizeof(Op);
58422 p->aOp = pNew;
58424 return (pNew ? SQLITE_OK : SQLITE_NOMEM);
58428 ** Add a new instruction to the list of instructions current in the
58429 ** VDBE. Return the address of the new instruction.
58431 ** Parameters:
58433 ** p Pointer to the VDBE
58435 ** op The opcode for this instruction
58437 ** p1, p2, p3 Operands
58439 ** Use the sqlite3VdbeResolveLabel() function to fix an address and
58440 ** the sqlite3VdbeChangeP4() function to change the value of the P4
58441 ** operand.
58443 SQLITE_PRIVATE int sqlite3VdbeAddOp3(Vdbe *p, int op, int p1, int p2, int p3){
58444 int i;
58445 VdbeOp *pOp;
58447 i = p->nOp;
58448 assert( p->magic==VDBE_MAGIC_INIT );
58449 assert( op>0 && op<0xff );
58450 if( p->nOpAlloc<=i ){
58451 if( growOpArray(p) ){
58452 return 1;
58455 p->nOp++;
58456 pOp = &p->aOp[i];
58457 pOp->opcode = (u8)op;
58458 pOp->p5 = 0;
58459 pOp->p1 = p1;
58460 pOp->p2 = p2;
58461 pOp->p3 = p3;
58462 pOp->p4.p = 0;
58463 pOp->p4type = P4_NOTUSED;
58464 #ifdef SQLITE_DEBUG
58465 pOp->zComment = 0;
58466 if( sqlite3VdbeAddopTrace ) sqlite3VdbePrintOp(0, i, &p->aOp[i]);
58467 #endif
58468 #ifdef VDBE_PROFILE
58469 pOp->cycles = 0;
58470 pOp->cnt = 0;
58471 #endif
58472 return i;
58474 SQLITE_PRIVATE int sqlite3VdbeAddOp0(Vdbe *p, int op){
58475 return sqlite3VdbeAddOp3(p, op, 0, 0, 0);
58477 SQLITE_PRIVATE int sqlite3VdbeAddOp1(Vdbe *p, int op, int p1){
58478 return sqlite3VdbeAddOp3(p, op, p1, 0, 0);
58480 SQLITE_PRIVATE int sqlite3VdbeAddOp2(Vdbe *p, int op, int p1, int p2){
58481 return sqlite3VdbeAddOp3(p, op, p1, p2, 0);
58486 ** Add an opcode that includes the p4 value as a pointer.
58488 SQLITE_PRIVATE int sqlite3VdbeAddOp4(
58489 Vdbe *p, /* Add the opcode to this VM */
58490 int op, /* The new opcode */
58491 int p1, /* The P1 operand */
58492 int p2, /* The P2 operand */
58493 int p3, /* The P3 operand */
58494 const char *zP4, /* The P4 operand */
58495 int p4type /* P4 operand type */
58497 int addr = sqlite3VdbeAddOp3(p, op, p1, p2, p3);
58498 sqlite3VdbeChangeP4(p, addr, zP4, p4type);
58499 return addr;
58503 ** Add an OP_ParseSchema opcode. This routine is broken out from
58504 ** sqlite3VdbeAddOp4() since it needs to also local all btrees.
58506 ** The zWhere string must have been obtained from sqlite3_malloc().
58507 ** This routine will take ownership of the allocated memory.
58509 SQLITE_PRIVATE void sqlite3VdbeAddParseSchemaOp(Vdbe *p, int iDb, char *zWhere){
58510 int j;
58511 int addr = sqlite3VdbeAddOp3(p, OP_ParseSchema, iDb, 0, 0);
58512 sqlite3VdbeChangeP4(p, addr, zWhere, P4_DYNAMIC);
58513 for(j=0; j<p->db->nDb; j++) sqlite3VdbeUsesBtree(p, j);
58517 ** Add an opcode that includes the p4 value as an integer.
58519 SQLITE_PRIVATE int sqlite3VdbeAddOp4Int(
58520 Vdbe *p, /* Add the opcode to this VM */
58521 int op, /* The new opcode */
58522 int p1, /* The P1 operand */
58523 int p2, /* The P2 operand */
58524 int p3, /* The P3 operand */
58525 int p4 /* The P4 operand as an integer */
58527 int addr = sqlite3VdbeAddOp3(p, op, p1, p2, p3);
58528 sqlite3VdbeChangeP4(p, addr, SQLITE_INT_TO_PTR(p4), P4_INT32);
58529 return addr;
58533 ** Create a new symbolic label for an instruction that has yet to be
58534 ** coded. The symbolic label is really just a negative number. The
58535 ** label can be used as the P2 value of an operation. Later, when
58536 ** the label is resolved to a specific address, the VDBE will scan
58537 ** through its operation list and change all values of P2 which match
58538 ** the label into the resolved address.
58540 ** The VDBE knows that a P2 value is a label because labels are
58541 ** always negative and P2 values are suppose to be non-negative.
58542 ** Hence, a negative P2 value is a label that has yet to be resolved.
58544 ** Zero is returned if a malloc() fails.
58546 SQLITE_PRIVATE int sqlite3VdbeMakeLabel(Vdbe *p){
58547 int i;
58548 i = p->nLabel++;
58549 assert( p->magic==VDBE_MAGIC_INIT );
58550 if( i>=p->nLabelAlloc ){
58551 int n = p->nLabelAlloc*2 + 5;
58552 p->aLabel = sqlite3DbReallocOrFree(p->db, p->aLabel,
58553 n*sizeof(p->aLabel[0]));
58554 p->nLabelAlloc = sqlite3DbMallocSize(p->db, p->aLabel)/sizeof(p->aLabel[0]);
58556 if( p->aLabel ){
58557 p->aLabel[i] = -1;
58559 return -1-i;
58563 ** Resolve label "x" to be the address of the next instruction to
58564 ** be inserted. The parameter "x" must have been obtained from
58565 ** a prior call to sqlite3VdbeMakeLabel().
58567 SQLITE_PRIVATE void sqlite3VdbeResolveLabel(Vdbe *p, int x){
58568 int j = -1-x;
58569 assert( p->magic==VDBE_MAGIC_INIT );
58570 assert( j>=0 && j<p->nLabel );
58571 if( p->aLabel ){
58572 p->aLabel[j] = p->nOp;
58577 ** Mark the VDBE as one that can only be run one time.
58579 SQLITE_PRIVATE void sqlite3VdbeRunOnlyOnce(Vdbe *p){
58580 p->runOnlyOnce = 1;
58583 #ifdef SQLITE_DEBUG /* sqlite3AssertMayAbort() logic */
58586 ** The following type and function are used to iterate through all opcodes
58587 ** in a Vdbe main program and each of the sub-programs (triggers) it may
58588 ** invoke directly or indirectly. It should be used as follows:
58590 ** Op *pOp;
58591 ** VdbeOpIter sIter;
58593 ** memset(&sIter, 0, sizeof(sIter));
58594 ** sIter.v = v; // v is of type Vdbe*
58595 ** while( (pOp = opIterNext(&sIter)) ){
58596 ** // Do something with pOp
58597 ** }
58598 ** sqlite3DbFree(v->db, sIter.apSub);
58601 typedef struct VdbeOpIter VdbeOpIter;
58602 struct VdbeOpIter {
58603 Vdbe *v; /* Vdbe to iterate through the opcodes of */
58604 SubProgram **apSub; /* Array of subprograms */
58605 int nSub; /* Number of entries in apSub */
58606 int iAddr; /* Address of next instruction to return */
58607 int iSub; /* 0 = main program, 1 = first sub-program etc. */
58609 static Op *opIterNext(VdbeOpIter *p){
58610 Vdbe *v = p->v;
58611 Op *pRet = 0;
58612 Op *aOp;
58613 int nOp;
58615 if( p->iSub<=p->nSub ){
58617 if( p->iSub==0 ){
58618 aOp = v->aOp;
58619 nOp = v->nOp;
58620 }else{
58621 aOp = p->apSub[p->iSub-1]->aOp;
58622 nOp = p->apSub[p->iSub-1]->nOp;
58624 assert( p->iAddr<nOp );
58626 pRet = &aOp[p->iAddr];
58627 p->iAddr++;
58628 if( p->iAddr==nOp ){
58629 p->iSub++;
58630 p->iAddr = 0;
58633 if( pRet->p4type==P4_SUBPROGRAM ){
58634 int nByte = (p->nSub+1)*sizeof(SubProgram*);
58635 int j;
58636 for(j=0; j<p->nSub; j++){
58637 if( p->apSub[j]==pRet->p4.pProgram ) break;
58639 if( j==p->nSub ){
58640 p->apSub = sqlite3DbReallocOrFree(v->db, p->apSub, nByte);
58641 if( !p->apSub ){
58642 pRet = 0;
58643 }else{
58644 p->apSub[p->nSub++] = pRet->p4.pProgram;
58650 return pRet;
58654 ** Check if the program stored in the VM associated with pParse may
58655 ** throw an ABORT exception (causing the statement, but not entire transaction
58656 ** to be rolled back). This condition is true if the main program or any
58657 ** sub-programs contains any of the following:
58659 ** * OP_Halt with P1=SQLITE_CONSTRAINT and P2=OE_Abort.
58660 ** * OP_HaltIfNull with P1=SQLITE_CONSTRAINT and P2=OE_Abort.
58661 ** * OP_Destroy
58662 ** * OP_VUpdate
58663 ** * OP_VRename
58664 ** * OP_FkCounter with P2==0 (immediate foreign key constraint)
58666 ** Then check that the value of Parse.mayAbort is true if an
58667 ** ABORT may be thrown, or false otherwise. Return true if it does
58668 ** match, or false otherwise. This function is intended to be used as
58669 ** part of an assert statement in the compiler. Similar to:
58671 ** assert( sqlite3VdbeAssertMayAbort(pParse->pVdbe, pParse->mayAbort) );
58673 SQLITE_PRIVATE int sqlite3VdbeAssertMayAbort(Vdbe *v, int mayAbort){
58674 int hasAbort = 0;
58675 Op *pOp;
58676 VdbeOpIter sIter;
58677 memset(&sIter, 0, sizeof(sIter));
58678 sIter.v = v;
58680 while( (pOp = opIterNext(&sIter))!=0 ){
58681 int opcode = pOp->opcode;
58682 if( opcode==OP_Destroy || opcode==OP_VUpdate || opcode==OP_VRename
58683 #ifndef SQLITE_OMIT_FOREIGN_KEY
58684 || (opcode==OP_FkCounter && pOp->p1==0 && pOp->p2==1)
58685 #endif
58686 || ((opcode==OP_Halt || opcode==OP_HaltIfNull)
58687 && (pOp->p1==SQLITE_CONSTRAINT && pOp->p2==OE_Abort))
58689 hasAbort = 1;
58690 break;
58693 sqlite3DbFree(v->db, sIter.apSub);
58695 /* Return true if hasAbort==mayAbort. Or if a malloc failure occured.
58696 ** If malloc failed, then the while() loop above may not have iterated
58697 ** through all opcodes and hasAbort may be set incorrectly. Return
58698 ** true for this case to prevent the assert() in the callers frame
58699 ** from failing. */
58700 return ( v->db->mallocFailed || hasAbort==mayAbort );
58702 #endif /* SQLITE_DEBUG - the sqlite3AssertMayAbort() function */
58705 ** Loop through the program looking for P2 values that are negative
58706 ** on jump instructions. Each such value is a label. Resolve the
58707 ** label by setting the P2 value to its correct non-zero value.
58709 ** This routine is called once after all opcodes have been inserted.
58711 ** Variable *pMaxFuncArgs is set to the maximum value of any P2 argument
58712 ** to an OP_Function, OP_AggStep or OP_VFilter opcode. This is used by
58713 ** sqlite3VdbeMakeReady() to size the Vdbe.apArg[] array.
58715 ** The Op.opflags field is set on all opcodes.
58717 static void resolveP2Values(Vdbe *p, int *pMaxFuncArgs){
58718 int i;
58719 int nMaxArgs = *pMaxFuncArgs;
58720 Op *pOp;
58721 int *aLabel = p->aLabel;
58722 p->readOnly = 1;
58723 for(pOp=p->aOp, i=p->nOp-1; i>=0; i--, pOp++){
58724 u8 opcode = pOp->opcode;
58726 pOp->opflags = sqlite3OpcodeProperty[opcode];
58727 if( opcode==OP_Function || opcode==OP_AggStep ){
58728 if( pOp->p5>nMaxArgs ) nMaxArgs = pOp->p5;
58729 }else if( (opcode==OP_Transaction && pOp->p2!=0) || opcode==OP_Vacuum ){
58730 p->readOnly = 0;
58731 #ifndef SQLITE_OMIT_VIRTUALTABLE
58732 }else if( opcode==OP_VUpdate ){
58733 if( pOp->p2>nMaxArgs ) nMaxArgs = pOp->p2;
58734 }else if( opcode==OP_VFilter ){
58735 int n;
58736 assert( p->nOp - i >= 3 );
58737 assert( pOp[-1].opcode==OP_Integer );
58738 n = pOp[-1].p1;
58739 if( n>nMaxArgs ) nMaxArgs = n;
58740 #endif
58741 }else if( opcode==OP_Next || opcode==OP_SorterNext ){
58742 pOp->p4.xAdvance = sqlite3BtreeNext;
58743 pOp->p4type = P4_ADVANCE;
58744 }else if( opcode==OP_Prev ){
58745 pOp->p4.xAdvance = sqlite3BtreePrevious;
58746 pOp->p4type = P4_ADVANCE;
58749 if( (pOp->opflags & OPFLG_JUMP)!=0 && pOp->p2<0 ){
58750 assert( -1-pOp->p2<p->nLabel );
58751 pOp->p2 = aLabel[-1-pOp->p2];
58754 sqlite3DbFree(p->db, p->aLabel);
58755 p->aLabel = 0;
58757 *pMaxFuncArgs = nMaxArgs;
58761 ** Return the address of the next instruction to be inserted.
58763 SQLITE_PRIVATE int sqlite3VdbeCurrentAddr(Vdbe *p){
58764 assert( p->magic==VDBE_MAGIC_INIT );
58765 return p->nOp;
58769 ** This function returns a pointer to the array of opcodes associated with
58770 ** the Vdbe passed as the first argument. It is the callers responsibility
58771 ** to arrange for the returned array to be eventually freed using the
58772 ** vdbeFreeOpArray() function.
58774 ** Before returning, *pnOp is set to the number of entries in the returned
58775 ** array. Also, *pnMaxArg is set to the larger of its current value and
58776 ** the number of entries in the Vdbe.apArg[] array required to execute the
58777 ** returned program.
58779 SQLITE_PRIVATE VdbeOp *sqlite3VdbeTakeOpArray(Vdbe *p, int *pnOp, int *pnMaxArg){
58780 VdbeOp *aOp = p->aOp;
58781 assert( aOp && !p->db->mallocFailed );
58783 /* Check that sqlite3VdbeUsesBtree() was not called on this VM */
58784 assert( p->btreeMask==0 );
58786 resolveP2Values(p, pnMaxArg);
58787 *pnOp = p->nOp;
58788 p->aOp = 0;
58789 return aOp;
58793 ** Add a whole list of operations to the operation stack. Return the
58794 ** address of the first operation added.
58796 SQLITE_PRIVATE int sqlite3VdbeAddOpList(Vdbe *p, int nOp, VdbeOpList const *aOp){
58797 int addr;
58798 assert( p->magic==VDBE_MAGIC_INIT );
58799 if( p->nOp + nOp > p->nOpAlloc && growOpArray(p) ){
58800 return 0;
58802 addr = p->nOp;
58803 if( ALWAYS(nOp>0) ){
58804 int i;
58805 VdbeOpList const *pIn = aOp;
58806 for(i=0; i<nOp; i++, pIn++){
58807 int p2 = pIn->p2;
58808 VdbeOp *pOut = &p->aOp[i+addr];
58809 pOut->opcode = pIn->opcode;
58810 pOut->p1 = pIn->p1;
58811 if( p2<0 && (sqlite3OpcodeProperty[pOut->opcode] & OPFLG_JUMP)!=0 ){
58812 pOut->p2 = addr + ADDR(p2);
58813 }else{
58814 pOut->p2 = p2;
58816 pOut->p3 = pIn->p3;
58817 pOut->p4type = P4_NOTUSED;
58818 pOut->p4.p = 0;
58819 pOut->p5 = 0;
58820 #ifdef SQLITE_DEBUG
58821 pOut->zComment = 0;
58822 if( sqlite3VdbeAddopTrace ){
58823 sqlite3VdbePrintOp(0, i+addr, &p->aOp[i+addr]);
58825 #endif
58827 p->nOp += nOp;
58829 return addr;
58833 ** Change the value of the P1 operand for a specific instruction.
58834 ** This routine is useful when a large program is loaded from a
58835 ** static array using sqlite3VdbeAddOpList but we want to make a
58836 ** few minor changes to the program.
58838 SQLITE_PRIVATE void sqlite3VdbeChangeP1(Vdbe *p, u32 addr, int val){
58839 assert( p!=0 );
58840 if( ((u32)p->nOp)>addr ){
58841 p->aOp[addr].p1 = val;
58846 ** Change the value of the P2 operand for a specific instruction.
58847 ** This routine is useful for setting a jump destination.
58849 SQLITE_PRIVATE void sqlite3VdbeChangeP2(Vdbe *p, u32 addr, int val){
58850 assert( p!=0 );
58851 if( ((u32)p->nOp)>addr ){
58852 p->aOp[addr].p2 = val;
58857 ** Change the value of the P3 operand for a specific instruction.
58859 SQLITE_PRIVATE void sqlite3VdbeChangeP3(Vdbe *p, u32 addr, int val){
58860 assert( p!=0 );
58861 if( ((u32)p->nOp)>addr ){
58862 p->aOp[addr].p3 = val;
58867 ** Change the value of the P5 operand for the most recently
58868 ** added operation.
58870 SQLITE_PRIVATE void sqlite3VdbeChangeP5(Vdbe *p, u8 val){
58871 assert( p!=0 );
58872 if( p->aOp ){
58873 assert( p->nOp>0 );
58874 p->aOp[p->nOp-1].p5 = val;
58879 ** Change the P2 operand of instruction addr so that it points to
58880 ** the address of the next instruction to be coded.
58882 SQLITE_PRIVATE void sqlite3VdbeJumpHere(Vdbe *p, int addr){
58883 assert( addr>=0 );
58884 sqlite3VdbeChangeP2(p, addr, p->nOp);
58889 ** If the input FuncDef structure is ephemeral, then free it. If
58890 ** the FuncDef is not ephermal, then do nothing.
58892 static void freeEphemeralFunction(sqlite3 *db, FuncDef *pDef){
58893 if( ALWAYS(pDef) && (pDef->flags & SQLITE_FUNC_EPHEM)!=0 ){
58894 sqlite3DbFree(db, pDef);
58898 static void vdbeFreeOpArray(sqlite3 *, Op *, int);
58901 ** Delete a P4 value if necessary.
58903 static void freeP4(sqlite3 *db, int p4type, void *p4){
58904 if( p4 ){
58905 assert( db );
58906 switch( p4type ){
58907 case P4_REAL:
58908 case P4_INT64:
58909 case P4_DYNAMIC:
58910 case P4_KEYINFO:
58911 case P4_INTARRAY:
58912 case P4_KEYINFO_HANDOFF: {
58913 sqlite3DbFree(db, p4);
58914 break;
58916 case P4_MPRINTF: {
58917 if( db->pnBytesFreed==0 ) sqlite3_free(p4);
58918 break;
58920 case P4_VDBEFUNC: {
58921 VdbeFunc *pVdbeFunc = (VdbeFunc *)p4;
58922 freeEphemeralFunction(db, pVdbeFunc->pFunc);
58923 if( db->pnBytesFreed==0 ) sqlite3VdbeDeleteAuxData(pVdbeFunc, 0);
58924 sqlite3DbFree(db, pVdbeFunc);
58925 break;
58927 case P4_FUNCDEF: {
58928 freeEphemeralFunction(db, (FuncDef*)p4);
58929 break;
58931 case P4_MEM: {
58932 if( db->pnBytesFreed==0 ){
58933 sqlite3ValueFree((sqlite3_value*)p4);
58934 }else{
58935 Mem *p = (Mem*)p4;
58936 sqlite3DbFree(db, p->zMalloc);
58937 sqlite3DbFree(db, p);
58939 break;
58941 case P4_VTAB : {
58942 if( db->pnBytesFreed==0 ) sqlite3VtabUnlock((VTable *)p4);
58943 break;
58950 ** Free the space allocated for aOp and any p4 values allocated for the
58951 ** opcodes contained within. If aOp is not NULL it is assumed to contain
58952 ** nOp entries.
58954 static void vdbeFreeOpArray(sqlite3 *db, Op *aOp, int nOp){
58955 if( aOp ){
58956 Op *pOp;
58957 for(pOp=aOp; pOp<&aOp[nOp]; pOp++){
58958 freeP4(db, pOp->p4type, pOp->p4.p);
58959 #ifdef SQLITE_DEBUG
58960 sqlite3DbFree(db, pOp->zComment);
58961 #endif
58964 sqlite3DbFree(db, aOp);
58968 ** Link the SubProgram object passed as the second argument into the linked
58969 ** list at Vdbe.pSubProgram. This list is used to delete all sub-program
58970 ** objects when the VM is no longer required.
58972 SQLITE_PRIVATE void sqlite3VdbeLinkSubProgram(Vdbe *pVdbe, SubProgram *p){
58973 p->pNext = pVdbe->pProgram;
58974 pVdbe->pProgram = p;
58978 ** Change the opcode at addr into OP_Noop
58980 SQLITE_PRIVATE void sqlite3VdbeChangeToNoop(Vdbe *p, int addr){
58981 if( p->aOp ){
58982 VdbeOp *pOp = &p->aOp[addr];
58983 sqlite3 *db = p->db;
58984 freeP4(db, pOp->p4type, pOp->p4.p);
58985 memset(pOp, 0, sizeof(pOp[0]));
58986 pOp->opcode = OP_Noop;
58991 ** Change the value of the P4 operand for a specific instruction.
58992 ** This routine is useful when a large program is loaded from a
58993 ** static array using sqlite3VdbeAddOpList but we want to make a
58994 ** few minor changes to the program.
58996 ** If n>=0 then the P4 operand is dynamic, meaning that a copy of
58997 ** the string is made into memory obtained from sqlite3_malloc().
58998 ** A value of n==0 means copy bytes of zP4 up to and including the
58999 ** first null byte. If n>0 then copy n+1 bytes of zP4.
59001 ** If n==P4_KEYINFO it means that zP4 is a pointer to a KeyInfo structure.
59002 ** A copy is made of the KeyInfo structure into memory obtained from
59003 ** sqlite3_malloc, to be freed when the Vdbe is finalized.
59004 ** n==P4_KEYINFO_HANDOFF indicates that zP4 points to a KeyInfo structure
59005 ** stored in memory that the caller has obtained from sqlite3_malloc. The
59006 ** caller should not free the allocation, it will be freed when the Vdbe is
59007 ** finalized.
59009 ** Other values of n (P4_STATIC, P4_COLLSEQ etc.) indicate that zP4 points
59010 ** to a string or structure that is guaranteed to exist for the lifetime of
59011 ** the Vdbe. In these cases we can just copy the pointer.
59013 ** If addr<0 then change P4 on the most recently inserted instruction.
59015 SQLITE_PRIVATE void sqlite3VdbeChangeP4(Vdbe *p, int addr, const char *zP4, int n){
59016 Op *pOp;
59017 sqlite3 *db;
59018 assert( p!=0 );
59019 db = p->db;
59020 assert( p->magic==VDBE_MAGIC_INIT );
59021 if( p->aOp==0 || db->mallocFailed ){
59022 if ( n!=P4_KEYINFO && n!=P4_VTAB ) {
59023 freeP4(db, n, (void*)*(char**)&zP4);
59025 return;
59027 assert( p->nOp>0 );
59028 assert( addr<p->nOp );
59029 if( addr<0 ){
59030 addr = p->nOp - 1;
59032 pOp = &p->aOp[addr];
59033 freeP4(db, pOp->p4type, pOp->p4.p);
59034 pOp->p4.p = 0;
59035 if( n==P4_INT32 ){
59036 /* Note: this cast is safe, because the origin data point was an int
59037 ** that was cast to a (const char *). */
59038 pOp->p4.i = SQLITE_PTR_TO_INT(zP4);
59039 pOp->p4type = P4_INT32;
59040 }else if( zP4==0 ){
59041 pOp->p4.p = 0;
59042 pOp->p4type = P4_NOTUSED;
59043 }else if( n==P4_KEYINFO ){
59044 KeyInfo *pKeyInfo;
59045 int nField, nByte;
59047 nField = ((KeyInfo*)zP4)->nField;
59048 nByte = sizeof(*pKeyInfo) + (nField-1)*sizeof(pKeyInfo->aColl[0]) + nField;
59049 pKeyInfo = sqlite3DbMallocRaw(0, nByte);
59050 pOp->p4.pKeyInfo = pKeyInfo;
59051 if( pKeyInfo ){
59052 u8 *aSortOrder;
59053 memcpy((char*)pKeyInfo, zP4, nByte - nField);
59054 aSortOrder = pKeyInfo->aSortOrder;
59055 if( aSortOrder ){
59056 pKeyInfo->aSortOrder = (unsigned char*)&pKeyInfo->aColl[nField];
59057 memcpy(pKeyInfo->aSortOrder, aSortOrder, nField);
59059 pOp->p4type = P4_KEYINFO;
59060 }else{
59061 p->db->mallocFailed = 1;
59062 pOp->p4type = P4_NOTUSED;
59064 }else if( n==P4_KEYINFO_HANDOFF ){
59065 pOp->p4.p = (void*)zP4;
59066 pOp->p4type = P4_KEYINFO;
59067 }else if( n==P4_VTAB ){
59068 pOp->p4.p = (void*)zP4;
59069 pOp->p4type = P4_VTAB;
59070 sqlite3VtabLock((VTable *)zP4);
59071 assert( ((VTable *)zP4)->db==p->db );
59072 }else if( n<0 ){
59073 pOp->p4.p = (void*)zP4;
59074 pOp->p4type = (signed char)n;
59075 }else{
59076 if( n==0 ) n = sqlite3Strlen30(zP4);
59077 pOp->p4.z = sqlite3DbStrNDup(p->db, zP4, n);
59078 pOp->p4type = P4_DYNAMIC;
59082 #ifndef NDEBUG
59084 ** Change the comment on the the most recently coded instruction. Or
59085 ** insert a No-op and add the comment to that new instruction. This
59086 ** makes the code easier to read during debugging. None of this happens
59087 ** in a production build.
59089 SQLITE_PRIVATE void sqlite3VdbeComment(Vdbe *p, const char *zFormat, ...){
59090 va_list ap;
59091 if( !p ) return;
59092 assert( p->nOp>0 || p->aOp==0 );
59093 assert( p->aOp==0 || p->aOp[p->nOp-1].zComment==0 || p->db->mallocFailed );
59094 if( p->nOp ){
59095 char **pz = &p->aOp[p->nOp-1].zComment;
59096 va_start(ap, zFormat);
59097 sqlite3DbFree(p->db, *pz);
59098 *pz = sqlite3VMPrintf(p->db, zFormat, ap);
59099 va_end(ap);
59102 SQLITE_PRIVATE void sqlite3VdbeNoopComment(Vdbe *p, const char *zFormat, ...){
59103 va_list ap;
59104 if( !p ) return;
59105 sqlite3VdbeAddOp0(p, OP_Noop);
59106 assert( p->nOp>0 || p->aOp==0 );
59107 assert( p->aOp==0 || p->aOp[p->nOp-1].zComment==0 || p->db->mallocFailed );
59108 if( p->nOp ){
59109 char **pz = &p->aOp[p->nOp-1].zComment;
59110 va_start(ap, zFormat);
59111 sqlite3DbFree(p->db, *pz);
59112 *pz = sqlite3VMPrintf(p->db, zFormat, ap);
59113 va_end(ap);
59116 #endif /* NDEBUG */
59119 ** Return the opcode for a given address. If the address is -1, then
59120 ** return the most recently inserted opcode.
59122 ** If a memory allocation error has occurred prior to the calling of this
59123 ** routine, then a pointer to a dummy VdbeOp will be returned. That opcode
59124 ** is readable but not writable, though it is cast to a writable value.
59125 ** The return of a dummy opcode allows the call to continue functioning
59126 ** after a OOM fault without having to check to see if the return from
59127 ** this routine is a valid pointer. But because the dummy.opcode is 0,
59128 ** dummy will never be written to. This is verified by code inspection and
59129 ** by running with Valgrind.
59131 ** About the #ifdef SQLITE_OMIT_TRACE: Normally, this routine is never called
59132 ** unless p->nOp>0. This is because in the absense of SQLITE_OMIT_TRACE,
59133 ** an OP_Trace instruction is always inserted by sqlite3VdbeGet() as soon as
59134 ** a new VDBE is created. So we are free to set addr to p->nOp-1 without
59135 ** having to double-check to make sure that the result is non-negative. But
59136 ** if SQLITE_OMIT_TRACE is defined, the OP_Trace is omitted and we do need to
59137 ** check the value of p->nOp-1 before continuing.
59139 SQLITE_PRIVATE VdbeOp *sqlite3VdbeGetOp(Vdbe *p, int addr){
59140 /* C89 specifies that the constant "dummy" will be initialized to all
59141 ** zeros, which is correct. MSVC generates a warning, nevertheless. */
59142 static VdbeOp dummy; /* Ignore the MSVC warning about no initializer */
59143 assert( p->magic==VDBE_MAGIC_INIT );
59144 if( addr<0 ){
59145 #ifdef SQLITE_OMIT_TRACE
59146 if( p->nOp==0 ) return (VdbeOp*)&dummy;
59147 #endif
59148 addr = p->nOp - 1;
59150 assert( (addr>=0 && addr<p->nOp) || p->db->mallocFailed );
59151 if( p->db->mallocFailed ){
59152 return (VdbeOp*)&dummy;
59153 }else{
59154 return &p->aOp[addr];
59158 #if !defined(SQLITE_OMIT_EXPLAIN) || !defined(NDEBUG) \
59159 || defined(VDBE_PROFILE) || defined(SQLITE_DEBUG)
59161 ** Compute a string that describes the P4 parameter for an opcode.
59162 ** Use zTemp for any required temporary buffer space.
59164 static char *displayP4(Op *pOp, char *zTemp, int nTemp){
59165 char *zP4 = zTemp;
59166 assert( nTemp>=20 );
59167 switch( pOp->p4type ){
59168 case P4_KEYINFO_STATIC:
59169 case P4_KEYINFO: {
59170 int i, j;
59171 KeyInfo *pKeyInfo = pOp->p4.pKeyInfo;
59172 sqlite3_snprintf(nTemp, zTemp, "keyinfo(%d", pKeyInfo->nField);
59173 i = sqlite3Strlen30(zTemp);
59174 for(j=0; j<pKeyInfo->nField; j++){
59175 CollSeq *pColl = pKeyInfo->aColl[j];
59176 if( pColl ){
59177 int n = sqlite3Strlen30(pColl->zName);
59178 if( i+n>nTemp-6 ){
59179 memcpy(&zTemp[i],",...",4);
59180 break;
59182 zTemp[i++] = ',';
59183 if( pKeyInfo->aSortOrder && pKeyInfo->aSortOrder[j] ){
59184 zTemp[i++] = '-';
59186 memcpy(&zTemp[i], pColl->zName,n+1);
59187 i += n;
59188 }else if( i+4<nTemp-6 ){
59189 memcpy(&zTemp[i],",nil",4);
59190 i += 4;
59193 zTemp[i++] = ')';
59194 zTemp[i] = 0;
59195 assert( i<nTemp );
59196 break;
59198 case P4_COLLSEQ: {
59199 CollSeq *pColl = pOp->p4.pColl;
59200 sqlite3_snprintf(nTemp, zTemp, "collseq(%.20s)", pColl->zName);
59201 break;
59203 case P4_FUNCDEF: {
59204 FuncDef *pDef = pOp->p4.pFunc;
59205 sqlite3_snprintf(nTemp, zTemp, "%s(%d)", pDef->zName, pDef->nArg);
59206 break;
59208 case P4_INT64: {
59209 sqlite3_snprintf(nTemp, zTemp, "%lld", *pOp->p4.pI64);
59210 break;
59212 case P4_INT32: {
59213 sqlite3_snprintf(nTemp, zTemp, "%d", pOp->p4.i);
59214 break;
59216 case P4_REAL: {
59217 sqlite3_snprintf(nTemp, zTemp, "%.16g", *pOp->p4.pReal);
59218 break;
59220 case P4_MEM: {
59221 Mem *pMem = pOp->p4.pMem;
59222 assert( (pMem->flags & MEM_Null)==0 );
59223 if( pMem->flags & MEM_Str ){
59224 zP4 = pMem->z;
59225 }else if( pMem->flags & MEM_Int ){
59226 sqlite3_snprintf(nTemp, zTemp, "%lld", pMem->u.i);
59227 }else if( pMem->flags & MEM_Real ){
59228 sqlite3_snprintf(nTemp, zTemp, "%.16g", pMem->r);
59229 }else{
59230 assert( pMem->flags & MEM_Blob );
59231 zP4 = "(blob)";
59233 break;
59235 #ifndef SQLITE_OMIT_VIRTUALTABLE
59236 case P4_VTAB: {
59237 sqlite3_vtab *pVtab = pOp->p4.pVtab->pVtab;
59238 sqlite3_snprintf(nTemp, zTemp, "vtab:%p:%p", pVtab, pVtab->pModule);
59239 break;
59241 #endif
59242 case P4_INTARRAY: {
59243 sqlite3_snprintf(nTemp, zTemp, "intarray");
59244 break;
59246 case P4_SUBPROGRAM: {
59247 sqlite3_snprintf(nTemp, zTemp, "program");
59248 break;
59250 case P4_ADVANCE: {
59251 zTemp[0] = 0;
59252 break;
59254 default: {
59255 zP4 = pOp->p4.z;
59256 if( zP4==0 ){
59257 zP4 = zTemp;
59258 zTemp[0] = 0;
59262 assert( zP4!=0 );
59263 return zP4;
59265 #endif
59268 ** Declare to the Vdbe that the BTree object at db->aDb[i] is used.
59270 ** The prepared statements need to know in advance the complete set of
59271 ** attached databases that they will be using. A mask of these databases
59272 ** is maintained in p->btreeMask and is used for locking and other purposes.
59274 SQLITE_PRIVATE void sqlite3VdbeUsesBtree(Vdbe *p, int i){
59275 assert( i>=0 && i<p->db->nDb && i<(int)sizeof(yDbMask)*8 );
59276 assert( i<(int)sizeof(p->btreeMask)*8 );
59277 p->btreeMask |= ((yDbMask)1)<<i;
59278 if( i!=1 && sqlite3BtreeSharable(p->db->aDb[i].pBt) ){
59279 p->lockMask |= ((yDbMask)1)<<i;
59283 #if !defined(SQLITE_OMIT_SHARED_CACHE) && SQLITE_THREADSAFE>0
59285 ** If SQLite is compiled to support shared-cache mode and to be threadsafe,
59286 ** this routine obtains the mutex associated with each BtShared structure
59287 ** that may be accessed by the VM passed as an argument. In doing so it also
59288 ** sets the BtShared.db member of each of the BtShared structures, ensuring
59289 ** that the correct busy-handler callback is invoked if required.
59291 ** If SQLite is not threadsafe but does support shared-cache mode, then
59292 ** sqlite3BtreeEnter() is invoked to set the BtShared.db variables
59293 ** of all of BtShared structures accessible via the database handle
59294 ** associated with the VM.
59296 ** If SQLite is not threadsafe and does not support shared-cache mode, this
59297 ** function is a no-op.
59299 ** The p->btreeMask field is a bitmask of all btrees that the prepared
59300 ** statement p will ever use. Let N be the number of bits in p->btreeMask
59301 ** corresponding to btrees that use shared cache. Then the runtime of
59302 ** this routine is N*N. But as N is rarely more than 1, this should not
59303 ** be a problem.
59305 SQLITE_PRIVATE void sqlite3VdbeEnter(Vdbe *p){
59306 int i;
59307 yDbMask mask;
59308 sqlite3 *db;
59309 Db *aDb;
59310 int nDb;
59311 if( p->lockMask==0 ) return; /* The common case */
59312 db = p->db;
59313 aDb = db->aDb;
59314 nDb = db->nDb;
59315 for(i=0, mask=1; i<nDb; i++, mask += mask){
59316 if( i!=1 && (mask & p->lockMask)!=0 && ALWAYS(aDb[i].pBt!=0) ){
59317 sqlite3BtreeEnter(aDb[i].pBt);
59321 #endif
59323 #if !defined(SQLITE_OMIT_SHARED_CACHE) && SQLITE_THREADSAFE>0
59325 ** Unlock all of the btrees previously locked by a call to sqlite3VdbeEnter().
59327 SQLITE_PRIVATE void sqlite3VdbeLeave(Vdbe *p){
59328 int i;
59329 yDbMask mask;
59330 sqlite3 *db;
59331 Db *aDb;
59332 int nDb;
59333 if( p->lockMask==0 ) return; /* The common case */
59334 db = p->db;
59335 aDb = db->aDb;
59336 nDb = db->nDb;
59337 for(i=0, mask=1; i<nDb; i++, mask += mask){
59338 if( i!=1 && (mask & p->lockMask)!=0 && ALWAYS(aDb[i].pBt!=0) ){
59339 sqlite3BtreeLeave(aDb[i].pBt);
59343 #endif
59345 #if defined(VDBE_PROFILE) || defined(SQLITE_DEBUG)
59347 ** Print a single opcode. This routine is used for debugging only.
59349 SQLITE_PRIVATE void sqlite3VdbePrintOp(FILE *pOut, int pc, Op *pOp){
59350 char *zP4;
59351 char zPtr[50];
59352 static const char *zFormat1 = "%4d %-13s %4d %4d %4d %-4s %.2X %s\n";
59353 if( pOut==0 ) pOut = stdout;
59354 zP4 = displayP4(pOp, zPtr, sizeof(zPtr));
59355 fprintf(pOut, zFormat1, pc,
59356 sqlite3OpcodeName(pOp->opcode), pOp->p1, pOp->p2, pOp->p3, zP4, pOp->p5,
59357 #ifdef SQLITE_DEBUG
59358 pOp->zComment ? pOp->zComment : ""
59359 #else
59361 #endif
59363 fflush(pOut);
59365 #endif
59368 ** Release an array of N Mem elements
59370 static void releaseMemArray(Mem *p, int N){
59371 if( p && N ){
59372 Mem *pEnd;
59373 sqlite3 *db = p->db;
59374 u8 malloc_failed = db->mallocFailed;
59375 if( db->pnBytesFreed ){
59376 for(pEnd=&p[N]; p<pEnd; p++){
59377 sqlite3DbFree(db, p->zMalloc);
59379 return;
59381 for(pEnd=&p[N]; p<pEnd; p++){
59382 assert( (&p[1])==pEnd || p[0].db==p[1].db );
59384 /* This block is really an inlined version of sqlite3VdbeMemRelease()
59385 ** that takes advantage of the fact that the memory cell value is
59386 ** being set to NULL after releasing any dynamic resources.
59388 ** The justification for duplicating code is that according to
59389 ** callgrind, this causes a certain test case to hit the CPU 4.7
59390 ** percent less (x86 linux, gcc version 4.1.2, -O6) than if
59391 ** sqlite3MemRelease() were called from here. With -O2, this jumps
59392 ** to 6.6 percent. The test case is inserting 1000 rows into a table
59393 ** with no indexes using a single prepared INSERT statement, bind()
59394 ** and reset(). Inserts are grouped into a transaction.
59396 if( p->flags&(MEM_Agg|MEM_Dyn|MEM_Frame|MEM_RowSet) ){
59397 sqlite3VdbeMemRelease(p);
59398 }else if( p->zMalloc ){
59399 sqlite3DbFree(db, p->zMalloc);
59400 p->zMalloc = 0;
59403 p->flags = MEM_Null;
59405 db->mallocFailed = malloc_failed;
59410 ** Delete a VdbeFrame object and its contents. VdbeFrame objects are
59411 ** allocated by the OP_Program opcode in sqlite3VdbeExec().
59413 SQLITE_PRIVATE void sqlite3VdbeFrameDelete(VdbeFrame *p){
59414 int i;
59415 Mem *aMem = VdbeFrameMem(p);
59416 VdbeCursor **apCsr = (VdbeCursor **)&aMem[p->nChildMem];
59417 for(i=0; i<p->nChildCsr; i++){
59418 sqlite3VdbeFreeCursor(p->v, apCsr[i]);
59420 releaseMemArray(aMem, p->nChildMem);
59421 sqlite3DbFree(p->v->db, p);
59424 #ifndef SQLITE_OMIT_EXPLAIN
59426 ** Give a listing of the program in the virtual machine.
59428 ** The interface is the same as sqlite3VdbeExec(). But instead of
59429 ** running the code, it invokes the callback once for each instruction.
59430 ** This feature is used to implement "EXPLAIN".
59432 ** When p->explain==1, each instruction is listed. When
59433 ** p->explain==2, only OP_Explain instructions are listed and these
59434 ** are shown in a different format. p->explain==2 is used to implement
59435 ** EXPLAIN QUERY PLAN.
59437 ** When p->explain==1, first the main program is listed, then each of
59438 ** the trigger subprograms are listed one by one.
59440 SQLITE_PRIVATE int sqlite3VdbeList(
59441 Vdbe *p /* The VDBE */
59443 int nRow; /* Stop when row count reaches this */
59444 int nSub = 0; /* Number of sub-vdbes seen so far */
59445 SubProgram **apSub = 0; /* Array of sub-vdbes */
59446 Mem *pSub = 0; /* Memory cell hold array of subprogs */
59447 sqlite3 *db = p->db; /* The database connection */
59448 int i; /* Loop counter */
59449 int rc = SQLITE_OK; /* Return code */
59450 Mem *pMem = p->pResultSet = &p->aMem[1]; /* First Mem of result set */
59452 assert( p->explain );
59453 assert( p->magic==VDBE_MAGIC_RUN );
59454 assert( p->rc==SQLITE_OK || p->rc==SQLITE_BUSY || p->rc==SQLITE_NOMEM );
59456 /* Even though this opcode does not use dynamic strings for
59457 ** the result, result columns may become dynamic if the user calls
59458 ** sqlite3_column_text16(), causing a translation to UTF-16 encoding.
59460 releaseMemArray(pMem, 8);
59462 if( p->rc==SQLITE_NOMEM ){
59463 /* This happens if a malloc() inside a call to sqlite3_column_text() or
59464 ** sqlite3_column_text16() failed. */
59465 db->mallocFailed = 1;
59466 return SQLITE_ERROR;
59469 /* When the number of output rows reaches nRow, that means the
59470 ** listing has finished and sqlite3_step() should return SQLITE_DONE.
59471 ** nRow is the sum of the number of rows in the main program, plus
59472 ** the sum of the number of rows in all trigger subprograms encountered
59473 ** so far. The nRow value will increase as new trigger subprograms are
59474 ** encountered, but p->pc will eventually catch up to nRow.
59476 nRow = p->nOp;
59477 if( p->explain==1 ){
59478 /* The first 8 memory cells are used for the result set. So we will
59479 ** commandeer the 9th cell to use as storage for an array of pointers
59480 ** to trigger subprograms. The VDBE is guaranteed to have at least 9
59481 ** cells. */
59482 assert( p->nMem>9 );
59483 pSub = &p->aMem[9];
59484 if( pSub->flags&MEM_Blob ){
59485 /* On the first call to sqlite3_step(), pSub will hold a NULL. It is
59486 ** initialized to a BLOB by the P4_SUBPROGRAM processing logic below */
59487 nSub = pSub->n/sizeof(Vdbe*);
59488 apSub = (SubProgram **)pSub->z;
59490 for(i=0; i<nSub; i++){
59491 nRow += apSub[i]->nOp;
59496 i = p->pc++;
59497 }while( i<nRow && p->explain==2 && p->aOp[i].opcode!=OP_Explain );
59498 if( i>=nRow ){
59499 p->rc = SQLITE_OK;
59500 rc = SQLITE_DONE;
59501 }else if( db->u1.isInterrupted ){
59502 p->rc = SQLITE_INTERRUPT;
59503 rc = SQLITE_ERROR;
59504 sqlite3SetString(&p->zErrMsg, db, "%s", sqlite3ErrStr(p->rc));
59505 }else{
59506 char *z;
59507 Op *pOp;
59508 if( i<p->nOp ){
59509 /* The output line number is small enough that we are still in the
59510 ** main program. */
59511 pOp = &p->aOp[i];
59512 }else{
59513 /* We are currently listing subprograms. Figure out which one and
59514 ** pick up the appropriate opcode. */
59515 int j;
59516 i -= p->nOp;
59517 for(j=0; i>=apSub[j]->nOp; j++){
59518 i -= apSub[j]->nOp;
59520 pOp = &apSub[j]->aOp[i];
59522 if( p->explain==1 ){
59523 pMem->flags = MEM_Int;
59524 pMem->type = SQLITE_INTEGER;
59525 pMem->u.i = i; /* Program counter */
59526 pMem++;
59528 pMem->flags = MEM_Static|MEM_Str|MEM_Term;
59529 pMem->z = (char*)sqlite3OpcodeName(pOp->opcode); /* Opcode */
59530 assert( pMem->z!=0 );
59531 pMem->n = sqlite3Strlen30(pMem->z);
59532 pMem->type = SQLITE_TEXT;
59533 pMem->enc = SQLITE_UTF8;
59534 pMem++;
59536 /* When an OP_Program opcode is encounter (the only opcode that has
59537 ** a P4_SUBPROGRAM argument), expand the size of the array of subprograms
59538 ** kept in p->aMem[9].z to hold the new program - assuming this subprogram
59539 ** has not already been seen.
59541 if( pOp->p4type==P4_SUBPROGRAM ){
59542 int nByte = (nSub+1)*sizeof(SubProgram*);
59543 int j;
59544 for(j=0; j<nSub; j++){
59545 if( apSub[j]==pOp->p4.pProgram ) break;
59547 if( j==nSub && SQLITE_OK==sqlite3VdbeMemGrow(pSub, nByte, 1) ){
59548 apSub = (SubProgram **)pSub->z;
59549 apSub[nSub++] = pOp->p4.pProgram;
59550 pSub->flags |= MEM_Blob;
59551 pSub->n = nSub*sizeof(SubProgram*);
59556 pMem->flags = MEM_Int;
59557 pMem->u.i = pOp->p1; /* P1 */
59558 pMem->type = SQLITE_INTEGER;
59559 pMem++;
59561 pMem->flags = MEM_Int;
59562 pMem->u.i = pOp->p2; /* P2 */
59563 pMem->type = SQLITE_INTEGER;
59564 pMem++;
59566 pMem->flags = MEM_Int;
59567 pMem->u.i = pOp->p3; /* P3 */
59568 pMem->type = SQLITE_INTEGER;
59569 pMem++;
59571 if( sqlite3VdbeMemGrow(pMem, 32, 0) ){ /* P4 */
59572 assert( p->db->mallocFailed );
59573 return SQLITE_ERROR;
59575 pMem->flags = MEM_Dyn|MEM_Str|MEM_Term;
59576 z = displayP4(pOp, pMem->z, 32);
59577 if( z!=pMem->z ){
59578 sqlite3VdbeMemSetStr(pMem, z, -1, SQLITE_UTF8, 0);
59579 }else{
59580 assert( pMem->z!=0 );
59581 pMem->n = sqlite3Strlen30(pMem->z);
59582 pMem->enc = SQLITE_UTF8;
59584 pMem->type = SQLITE_TEXT;
59585 pMem++;
59587 if( p->explain==1 ){
59588 if( sqlite3VdbeMemGrow(pMem, 4, 0) ){
59589 assert( p->db->mallocFailed );
59590 return SQLITE_ERROR;
59592 pMem->flags = MEM_Dyn|MEM_Str|MEM_Term;
59593 pMem->n = 2;
59594 sqlite3_snprintf(3, pMem->z, "%.2x", pOp->p5); /* P5 */
59595 pMem->type = SQLITE_TEXT;
59596 pMem->enc = SQLITE_UTF8;
59597 pMem++;
59599 #ifdef SQLITE_DEBUG
59600 if( pOp->zComment ){
59601 pMem->flags = MEM_Str|MEM_Term;
59602 pMem->z = pOp->zComment;
59603 pMem->n = sqlite3Strlen30(pMem->z);
59604 pMem->enc = SQLITE_UTF8;
59605 pMem->type = SQLITE_TEXT;
59606 }else
59607 #endif
59609 pMem->flags = MEM_Null; /* Comment */
59610 pMem->type = SQLITE_NULL;
59614 p->nResColumn = 8 - 4*(p->explain-1);
59615 p->rc = SQLITE_OK;
59616 rc = SQLITE_ROW;
59618 return rc;
59620 #endif /* SQLITE_OMIT_EXPLAIN */
59622 #ifdef SQLITE_DEBUG
59624 ** Print the SQL that was used to generate a VDBE program.
59626 SQLITE_PRIVATE void sqlite3VdbePrintSql(Vdbe *p){
59627 int nOp = p->nOp;
59628 VdbeOp *pOp;
59629 if( nOp<1 ) return;
59630 pOp = &p->aOp[0];
59631 if( pOp->opcode==OP_Trace && pOp->p4.z!=0 ){
59632 const char *z = pOp->p4.z;
59633 while( sqlite3Isspace(*z) ) z++;
59634 printf("SQL: [%s]\n", z);
59637 #endif
59639 #if !defined(SQLITE_OMIT_TRACE) && defined(SQLITE_ENABLE_IOTRACE)
59641 ** Print an IOTRACE message showing SQL content.
59643 SQLITE_PRIVATE void sqlite3VdbeIOTraceSql(Vdbe *p){
59644 int nOp = p->nOp;
59645 VdbeOp *pOp;
59646 if( sqlite3IoTrace==0 ) return;
59647 if( nOp<1 ) return;
59648 pOp = &p->aOp[0];
59649 if( pOp->opcode==OP_Trace && pOp->p4.z!=0 ){
59650 int i, j;
59651 char z[1000];
59652 sqlite3_snprintf(sizeof(z), z, "%s", pOp->p4.z);
59653 for(i=0; sqlite3Isspace(z[i]); i++){}
59654 for(j=0; z[i]; i++){
59655 if( sqlite3Isspace(z[i]) ){
59656 if( z[i-1]!=' ' ){
59657 z[j++] = ' ';
59659 }else{
59660 z[j++] = z[i];
59663 z[j] = 0;
59664 sqlite3IoTrace("SQL %s\n", z);
59667 #endif /* !SQLITE_OMIT_TRACE && SQLITE_ENABLE_IOTRACE */
59670 ** Allocate space from a fixed size buffer and return a pointer to
59671 ** that space. If insufficient space is available, return NULL.
59673 ** The pBuf parameter is the initial value of a pointer which will
59674 ** receive the new memory. pBuf is normally NULL. If pBuf is not
59675 ** NULL, it means that memory space has already been allocated and that
59676 ** this routine should not allocate any new memory. When pBuf is not
59677 ** NULL simply return pBuf. Only allocate new memory space when pBuf
59678 ** is NULL.
59680 ** nByte is the number of bytes of space needed.
59682 ** *ppFrom points to available space and pEnd points to the end of the
59683 ** available space. When space is allocated, *ppFrom is advanced past
59684 ** the end of the allocated space.
59686 ** *pnByte is a counter of the number of bytes of space that have failed
59687 ** to allocate. If there is insufficient space in *ppFrom to satisfy the
59688 ** request, then increment *pnByte by the amount of the request.
59690 static void *allocSpace(
59691 void *pBuf, /* Where return pointer will be stored */
59692 int nByte, /* Number of bytes to allocate */
59693 u8 **ppFrom, /* IN/OUT: Allocate from *ppFrom */
59694 u8 *pEnd, /* Pointer to 1 byte past the end of *ppFrom buffer */
59695 int *pnByte /* If allocation cannot be made, increment *pnByte */
59697 assert( EIGHT_BYTE_ALIGNMENT(*ppFrom) );
59698 if( pBuf ) return pBuf;
59699 nByte = ROUND8(nByte);
59700 if( &(*ppFrom)[nByte] <= pEnd ){
59701 pBuf = (void*)*ppFrom;
59702 *ppFrom += nByte;
59703 }else{
59704 *pnByte += nByte;
59706 return pBuf;
59710 ** Rewind the VDBE back to the beginning in preparation for
59711 ** running it.
59713 SQLITE_PRIVATE void sqlite3VdbeRewind(Vdbe *p){
59714 #if defined(SQLITE_DEBUG) || defined(VDBE_PROFILE)
59715 int i;
59716 #endif
59717 assert( p!=0 );
59718 assert( p->magic==VDBE_MAGIC_INIT );
59720 /* There should be at least one opcode.
59722 assert( p->nOp>0 );
59724 /* Set the magic to VDBE_MAGIC_RUN sooner rather than later. */
59725 p->magic = VDBE_MAGIC_RUN;
59727 #ifdef SQLITE_DEBUG
59728 for(i=1; i<p->nMem; i++){
59729 assert( p->aMem[i].db==p->db );
59731 #endif
59732 p->pc = -1;
59733 p->rc = SQLITE_OK;
59734 p->errorAction = OE_Abort;
59735 p->magic = VDBE_MAGIC_RUN;
59736 p->nChange = 0;
59737 p->cacheCtr = 1;
59738 p->minWriteFileFormat = 255;
59739 p->iStatement = 0;
59740 p->nFkConstraint = 0;
59741 #ifdef VDBE_PROFILE
59742 for(i=0; i<p->nOp; i++){
59743 p->aOp[i].cnt = 0;
59744 p->aOp[i].cycles = 0;
59746 #endif
59750 ** Prepare a virtual machine for execution for the first time after
59751 ** creating the virtual machine. This involves things such
59752 ** as allocating stack space and initializing the program counter.
59753 ** After the VDBE has be prepped, it can be executed by one or more
59754 ** calls to sqlite3VdbeExec().
59756 ** This function may be called exact once on a each virtual machine.
59757 ** After this routine is called the VM has been "packaged" and is ready
59758 ** to run. After this routine is called, futher calls to
59759 ** sqlite3VdbeAddOp() functions are prohibited. This routine disconnects
59760 ** the Vdbe from the Parse object that helped generate it so that the
59761 ** the Vdbe becomes an independent entity and the Parse object can be
59762 ** destroyed.
59764 ** Use the sqlite3VdbeRewind() procedure to restore a virtual machine back
59765 ** to its initial state after it has been run.
59767 SQLITE_PRIVATE void sqlite3VdbeMakeReady(
59768 Vdbe *p, /* The VDBE */
59769 Parse *pParse /* Parsing context */
59771 sqlite3 *db; /* The database connection */
59772 int nVar; /* Number of parameters */
59773 int nMem; /* Number of VM memory registers */
59774 int nCursor; /* Number of cursors required */
59775 int nArg; /* Number of arguments in subprograms */
59776 int n; /* Loop counter */
59777 u8 *zCsr; /* Memory available for allocation */
59778 u8 *zEnd; /* First byte past allocated memory */
59779 int nByte; /* How much extra memory is needed */
59781 assert( p!=0 );
59782 assert( p->nOp>0 );
59783 assert( pParse!=0 );
59784 assert( p->magic==VDBE_MAGIC_INIT );
59785 db = p->db;
59786 assert( db->mallocFailed==0 );
59787 nVar = pParse->nVar;
59788 nMem = pParse->nMem;
59789 nCursor = pParse->nTab;
59790 nArg = pParse->nMaxArg;
59792 /* For each cursor required, also allocate a memory cell. Memory
59793 ** cells (nMem+1-nCursor)..nMem, inclusive, will never be used by
59794 ** the vdbe program. Instead they are used to allocate space for
59795 ** VdbeCursor/BtCursor structures. The blob of memory associated with
59796 ** cursor 0 is stored in memory cell nMem. Memory cell (nMem-1)
59797 ** stores the blob of memory associated with cursor 1, etc.
59799 ** See also: allocateCursor().
59801 nMem += nCursor;
59803 /* Allocate space for memory registers, SQL variables, VDBE cursors and
59804 ** an array to marshal SQL function arguments in.
59806 zCsr = (u8*)&p->aOp[p->nOp]; /* Memory avaliable for allocation */
59807 zEnd = (u8*)&p->aOp[p->nOpAlloc]; /* First byte past end of zCsr[] */
59809 resolveP2Values(p, &nArg);
59810 p->usesStmtJournal = (u8)(pParse->isMultiWrite && pParse->mayAbort);
59811 if( pParse->explain && nMem<10 ){
59812 nMem = 10;
59814 memset(zCsr, 0, zEnd-zCsr);
59815 zCsr += (zCsr - (u8*)0)&7;
59816 assert( EIGHT_BYTE_ALIGNMENT(zCsr) );
59817 p->expired = 0;
59819 /* Memory for registers, parameters, cursor, etc, is allocated in two
59820 ** passes. On the first pass, we try to reuse unused space at the
59821 ** end of the opcode array. If we are unable to satisfy all memory
59822 ** requirements by reusing the opcode array tail, then the second
59823 ** pass will fill in the rest using a fresh allocation.
59825 ** This two-pass approach that reuses as much memory as possible from
59826 ** the leftover space at the end of the opcode array can significantly
59827 ** reduce the amount of memory held by a prepared statement.
59829 do {
59830 nByte = 0;
59831 p->aMem = allocSpace(p->aMem, nMem*sizeof(Mem), &zCsr, zEnd, &nByte);
59832 p->aVar = allocSpace(p->aVar, nVar*sizeof(Mem), &zCsr, zEnd, &nByte);
59833 p->apArg = allocSpace(p->apArg, nArg*sizeof(Mem*), &zCsr, zEnd, &nByte);
59834 p->azVar = allocSpace(p->azVar, nVar*sizeof(char*), &zCsr, zEnd, &nByte);
59835 p->apCsr = allocSpace(p->apCsr, nCursor*sizeof(VdbeCursor*),
59836 &zCsr, zEnd, &nByte);
59837 if( nByte ){
59838 p->pFree = sqlite3DbMallocZero(db, nByte);
59840 zCsr = p->pFree;
59841 zEnd = &zCsr[nByte];
59842 }while( nByte && !db->mallocFailed );
59844 p->nCursor = (u16)nCursor;
59845 if( p->aVar ){
59846 p->nVar = (ynVar)nVar;
59847 for(n=0; n<nVar; n++){
59848 p->aVar[n].flags = MEM_Null;
59849 p->aVar[n].db = db;
59852 if( p->azVar ){
59853 p->nzVar = pParse->nzVar;
59854 memcpy(p->azVar, pParse->azVar, p->nzVar*sizeof(p->azVar[0]));
59855 memset(pParse->azVar, 0, pParse->nzVar*sizeof(pParse->azVar[0]));
59857 if( p->aMem ){
59858 p->aMem--; /* aMem[] goes from 1..nMem */
59859 p->nMem = nMem; /* not from 0..nMem-1 */
59860 for(n=1; n<=nMem; n++){
59861 p->aMem[n].flags = MEM_Null;
59862 p->aMem[n].db = db;
59865 p->explain = pParse->explain;
59866 sqlite3VdbeRewind(p);
59870 ** Close a VDBE cursor and release all the resources that cursor
59871 ** happens to hold.
59873 SQLITE_PRIVATE void sqlite3VdbeFreeCursor(Vdbe *p, VdbeCursor *pCx){
59874 if( pCx==0 ){
59875 return;
59877 sqlite3VdbeSorterClose(p->db, pCx);
59878 if( pCx->pBt ){
59879 sqlite3BtreeClose(pCx->pBt);
59880 /* The pCx->pCursor will be close automatically, if it exists, by
59881 ** the call above. */
59882 }else if( pCx->pCursor ){
59883 sqlite3BtreeCloseCursor(pCx->pCursor);
59885 #ifndef SQLITE_OMIT_VIRTUALTABLE
59886 if( pCx->pVtabCursor ){
59887 sqlite3_vtab_cursor *pVtabCursor = pCx->pVtabCursor;
59888 const sqlite3_module *pModule = pCx->pModule;
59889 p->inVtabMethod = 1;
59890 pModule->xClose(pVtabCursor);
59891 p->inVtabMethod = 0;
59893 #endif
59897 ** Copy the values stored in the VdbeFrame structure to its Vdbe. This
59898 ** is used, for example, when a trigger sub-program is halted to restore
59899 ** control to the main program.
59901 SQLITE_PRIVATE int sqlite3VdbeFrameRestore(VdbeFrame *pFrame){
59902 Vdbe *v = pFrame->v;
59903 v->aOp = pFrame->aOp;
59904 v->nOp = pFrame->nOp;
59905 v->aMem = pFrame->aMem;
59906 v->nMem = pFrame->nMem;
59907 v->apCsr = pFrame->apCsr;
59908 v->nCursor = pFrame->nCursor;
59909 v->db->lastRowid = pFrame->lastRowid;
59910 v->nChange = pFrame->nChange;
59911 return pFrame->pc;
59915 ** Close all cursors.
59917 ** Also release any dynamic memory held by the VM in the Vdbe.aMem memory
59918 ** cell array. This is necessary as the memory cell array may contain
59919 ** pointers to VdbeFrame objects, which may in turn contain pointers to
59920 ** open cursors.
59922 static void closeAllCursors(Vdbe *p){
59923 if( p->pFrame ){
59924 VdbeFrame *pFrame;
59925 for(pFrame=p->pFrame; pFrame->pParent; pFrame=pFrame->pParent);
59926 sqlite3VdbeFrameRestore(pFrame);
59928 p->pFrame = 0;
59929 p->nFrame = 0;
59931 if( p->apCsr ){
59932 int i;
59933 for(i=0; i<p->nCursor; i++){
59934 VdbeCursor *pC = p->apCsr[i];
59935 if( pC ){
59936 sqlite3VdbeFreeCursor(p, pC);
59937 p->apCsr[i] = 0;
59941 if( p->aMem ){
59942 releaseMemArray(&p->aMem[1], p->nMem);
59944 while( p->pDelFrame ){
59945 VdbeFrame *pDel = p->pDelFrame;
59946 p->pDelFrame = pDel->pParent;
59947 sqlite3VdbeFrameDelete(pDel);
59952 ** Clean up the VM after execution.
59954 ** This routine will automatically close any cursors, lists, and/or
59955 ** sorters that were left open. It also deletes the values of
59956 ** variables in the aVar[] array.
59958 static void Cleanup(Vdbe *p){
59959 sqlite3 *db = p->db;
59961 #ifdef SQLITE_DEBUG
59962 /* Execute assert() statements to ensure that the Vdbe.apCsr[] and
59963 ** Vdbe.aMem[] arrays have already been cleaned up. */
59964 int i;
59965 for(i=0; i<p->nCursor; i++) assert( p->apCsr==0 || p->apCsr[i]==0 );
59966 for(i=1; i<=p->nMem; i++) assert( p->aMem==0 || p->aMem[i].flags==MEM_Null );
59967 #endif
59969 sqlite3DbFree(db, p->zErrMsg);
59970 p->zErrMsg = 0;
59971 p->pResultSet = 0;
59975 ** Set the number of result columns that will be returned by this SQL
59976 ** statement. This is now set at compile time, rather than during
59977 ** execution of the vdbe program so that sqlite3_column_count() can
59978 ** be called on an SQL statement before sqlite3_step().
59980 SQLITE_PRIVATE void sqlite3VdbeSetNumCols(Vdbe *p, int nResColumn){
59981 Mem *pColName;
59982 int n;
59983 sqlite3 *db = p->db;
59985 releaseMemArray(p->aColName, p->nResColumn*COLNAME_N);
59986 sqlite3DbFree(db, p->aColName);
59987 n = nResColumn*COLNAME_N;
59988 p->nResColumn = (u16)nResColumn;
59989 p->aColName = pColName = (Mem*)sqlite3DbMallocZero(db, sizeof(Mem)*n );
59990 if( p->aColName==0 ) return;
59991 while( n-- > 0 ){
59992 pColName->flags = MEM_Null;
59993 pColName->db = p->db;
59994 pColName++;
59999 ** Set the name of the idx'th column to be returned by the SQL statement.
60000 ** zName must be a pointer to a nul terminated string.
60002 ** This call must be made after a call to sqlite3VdbeSetNumCols().
60004 ** The final parameter, xDel, must be one of SQLITE_DYNAMIC, SQLITE_STATIC
60005 ** or SQLITE_TRANSIENT. If it is SQLITE_DYNAMIC, then the buffer pointed
60006 ** to by zName will be freed by sqlite3DbFree() when the vdbe is destroyed.
60008 SQLITE_PRIVATE int sqlite3VdbeSetColName(
60009 Vdbe *p, /* Vdbe being configured */
60010 int idx, /* Index of column zName applies to */
60011 int var, /* One of the COLNAME_* constants */
60012 const char *zName, /* Pointer to buffer containing name */
60013 void (*xDel)(void*) /* Memory management strategy for zName */
60015 int rc;
60016 Mem *pColName;
60017 assert( idx<p->nResColumn );
60018 assert( var<COLNAME_N );
60019 if( p->db->mallocFailed ){
60020 assert( !zName || xDel!=SQLITE_DYNAMIC );
60021 return SQLITE_NOMEM;
60023 assert( p->aColName!=0 );
60024 pColName = &(p->aColName[idx+var*p->nResColumn]);
60025 rc = sqlite3VdbeMemSetStr(pColName, zName, -1, SQLITE_UTF8, xDel);
60026 assert( rc!=0 || !zName || (pColName->flags&MEM_Term)!=0 );
60027 return rc;
60031 ** A read or write transaction may or may not be active on database handle
60032 ** db. If a transaction is active, commit it. If there is a
60033 ** write-transaction spanning more than one database file, this routine
60034 ** takes care of the master journal trickery.
60036 static int vdbeCommit(sqlite3 *db, Vdbe *p){
60037 int i;
60038 int nTrans = 0; /* Number of databases with an active write-transaction */
60039 int rc = SQLITE_OK;
60040 int needXcommit = 0;
60042 #ifdef SQLITE_OMIT_VIRTUALTABLE
60043 /* With this option, sqlite3VtabSync() is defined to be simply
60044 ** SQLITE_OK so p is not used.
60046 UNUSED_PARAMETER(p);
60047 #endif
60049 /* Before doing anything else, call the xSync() callback for any
60050 ** virtual module tables written in this transaction. This has to
60051 ** be done before determining whether a master journal file is
60052 ** required, as an xSync() callback may add an attached database
60053 ** to the transaction.
60055 rc = sqlite3VtabSync(db, &p->zErrMsg);
60057 /* This loop determines (a) if the commit hook should be invoked and
60058 ** (b) how many database files have open write transactions, not
60059 ** including the temp database. (b) is important because if more than
60060 ** one database file has an open write transaction, a master journal
60061 ** file is required for an atomic commit.
60063 for(i=0; rc==SQLITE_OK && i<db->nDb; i++){
60064 Btree *pBt = db->aDb[i].pBt;
60065 if( sqlite3BtreeIsInTrans(pBt) ){
60066 needXcommit = 1;
60067 if( i!=1 ) nTrans++;
60068 rc = sqlite3PagerExclusiveLock(sqlite3BtreePager(pBt));
60071 if( rc!=SQLITE_OK ){
60072 return rc;
60075 /* If there are any write-transactions at all, invoke the commit hook */
60076 if( needXcommit && db->xCommitCallback ){
60077 rc = db->xCommitCallback(db->pCommitArg);
60078 if( rc ){
60079 return SQLITE_CONSTRAINT;
60083 /* The simple case - no more than one database file (not counting the
60084 ** TEMP database) has a transaction active. There is no need for the
60085 ** master-journal.
60087 ** If the return value of sqlite3BtreeGetFilename() is a zero length
60088 ** string, it means the main database is :memory: or a temp file. In
60089 ** that case we do not support atomic multi-file commits, so use the
60090 ** simple case then too.
60092 if( 0==sqlite3Strlen30(sqlite3BtreeGetFilename(db->aDb[0].pBt))
60093 || nTrans<=1
60095 for(i=0; rc==SQLITE_OK && i<db->nDb; i++){
60096 Btree *pBt = db->aDb[i].pBt;
60097 if( pBt ){
60098 rc = sqlite3BtreeCommitPhaseOne(pBt, 0);
60102 /* Do the commit only if all databases successfully complete phase 1.
60103 ** If one of the BtreeCommitPhaseOne() calls fails, this indicates an
60104 ** IO error while deleting or truncating a journal file. It is unlikely,
60105 ** but could happen. In this case abandon processing and return the error.
60107 for(i=0; rc==SQLITE_OK && i<db->nDb; i++){
60108 Btree *pBt = db->aDb[i].pBt;
60109 if( pBt ){
60110 rc = sqlite3BtreeCommitPhaseTwo(pBt, 0);
60113 if( rc==SQLITE_OK ){
60114 sqlite3VtabCommit(db);
60118 /* The complex case - There is a multi-file write-transaction active.
60119 ** This requires a master journal file to ensure the transaction is
60120 ** committed atomicly.
60122 #ifndef SQLITE_OMIT_DISKIO
60123 else{
60124 sqlite3_vfs *pVfs = db->pVfs;
60125 int needSync = 0;
60126 char *zMaster = 0; /* File-name for the master journal */
60127 char const *zMainFile = sqlite3BtreeGetFilename(db->aDb[0].pBt);
60128 sqlite3_file *pMaster = 0;
60129 i64 offset = 0;
60130 int res;
60132 /* Select a master journal file name */
60133 do {
60134 u32 iRandom;
60135 sqlite3DbFree(db, zMaster);
60136 sqlite3_randomness(sizeof(iRandom), &iRandom);
60137 zMaster = sqlite3MPrintf(db, "%s-mj%08X", zMainFile, iRandom&0x7fffffff);
60138 if( !zMaster ){
60139 return SQLITE_NOMEM;
60141 sqlite3FileSuffix3(zMainFile, zMaster);
60142 rc = sqlite3OsAccess(pVfs, zMaster, SQLITE_ACCESS_EXISTS, &res);
60143 }while( rc==SQLITE_OK && res );
60144 if( rc==SQLITE_OK ){
60145 /* Open the master journal. */
60146 rc = sqlite3OsOpenMalloc(pVfs, zMaster, &pMaster,
60147 SQLITE_OPEN_READWRITE|SQLITE_OPEN_CREATE|
60148 SQLITE_OPEN_EXCLUSIVE|SQLITE_OPEN_MASTER_JOURNAL, 0
60151 if( rc!=SQLITE_OK ){
60152 sqlite3DbFree(db, zMaster);
60153 return rc;
60156 /* Write the name of each database file in the transaction into the new
60157 ** master journal file. If an error occurs at this point close
60158 ** and delete the master journal file. All the individual journal files
60159 ** still have 'null' as the master journal pointer, so they will roll
60160 ** back independently if a failure occurs.
60162 for(i=0; i<db->nDb; i++){
60163 Btree *pBt = db->aDb[i].pBt;
60164 if( sqlite3BtreeIsInTrans(pBt) ){
60165 char const *zFile = sqlite3BtreeGetJournalname(pBt);
60166 if( zFile==0 ){
60167 continue; /* Ignore TEMP and :memory: databases */
60169 assert( zFile[0]!=0 );
60170 if( !needSync && !sqlite3BtreeSyncDisabled(pBt) ){
60171 needSync = 1;
60173 rc = sqlite3OsWrite(pMaster, zFile, sqlite3Strlen30(zFile)+1, offset);
60174 offset += sqlite3Strlen30(zFile)+1;
60175 if( rc!=SQLITE_OK ){
60176 sqlite3OsCloseFree(pMaster);
60177 sqlite3OsDelete(pVfs, zMaster, 0);
60178 sqlite3DbFree(db, zMaster);
60179 return rc;
60184 /* Sync the master journal file. If the IOCAP_SEQUENTIAL device
60185 ** flag is set this is not required.
60187 if( needSync
60188 && 0==(sqlite3OsDeviceCharacteristics(pMaster)&SQLITE_IOCAP_SEQUENTIAL)
60189 && SQLITE_OK!=(rc = sqlite3OsSync(pMaster, SQLITE_SYNC_NORMAL))
60191 sqlite3OsCloseFree(pMaster);
60192 sqlite3OsDelete(pVfs, zMaster, 0);
60193 sqlite3DbFree(db, zMaster);
60194 return rc;
60197 /* Sync all the db files involved in the transaction. The same call
60198 ** sets the master journal pointer in each individual journal. If
60199 ** an error occurs here, do not delete the master journal file.
60201 ** If the error occurs during the first call to
60202 ** sqlite3BtreeCommitPhaseOne(), then there is a chance that the
60203 ** master journal file will be orphaned. But we cannot delete it,
60204 ** in case the master journal file name was written into the journal
60205 ** file before the failure occurred.
60207 for(i=0; rc==SQLITE_OK && i<db->nDb; i++){
60208 Btree *pBt = db->aDb[i].pBt;
60209 if( pBt ){
60210 rc = sqlite3BtreeCommitPhaseOne(pBt, zMaster);
60213 sqlite3OsCloseFree(pMaster);
60214 assert( rc!=SQLITE_BUSY );
60215 if( rc!=SQLITE_OK ){
60216 sqlite3DbFree(db, zMaster);
60217 return rc;
60220 /* Delete the master journal file. This commits the transaction. After
60221 ** doing this the directory is synced again before any individual
60222 ** transaction files are deleted.
60224 rc = sqlite3OsDelete(pVfs, zMaster, 1);
60225 sqlite3DbFree(db, zMaster);
60226 zMaster = 0;
60227 if( rc ){
60228 return rc;
60231 /* All files and directories have already been synced, so the following
60232 ** calls to sqlite3BtreeCommitPhaseTwo() are only closing files and
60233 ** deleting or truncating journals. If something goes wrong while
60234 ** this is happening we don't really care. The integrity of the
60235 ** transaction is already guaranteed, but some stray 'cold' journals
60236 ** may be lying around. Returning an error code won't help matters.
60238 disable_simulated_io_errors();
60239 sqlite3BeginBenignMalloc();
60240 for(i=0; i<db->nDb; i++){
60241 Btree *pBt = db->aDb[i].pBt;
60242 if( pBt ){
60243 sqlite3BtreeCommitPhaseTwo(pBt, 1);
60246 sqlite3EndBenignMalloc();
60247 enable_simulated_io_errors();
60249 sqlite3VtabCommit(db);
60251 #endif
60253 return rc;
60257 ** This routine checks that the sqlite3.activeVdbeCnt count variable
60258 ** matches the number of vdbe's in the list sqlite3.pVdbe that are
60259 ** currently active. An assertion fails if the two counts do not match.
60260 ** This is an internal self-check only - it is not an essential processing
60261 ** step.
60263 ** This is a no-op if NDEBUG is defined.
60265 #ifndef NDEBUG
60266 static void checkActiveVdbeCnt(sqlite3 *db){
60267 Vdbe *p;
60268 int cnt = 0;
60269 int nWrite = 0;
60270 p = db->pVdbe;
60271 while( p ){
60272 if( p->magic==VDBE_MAGIC_RUN && p->pc>=0 ){
60273 cnt++;
60274 if( p->readOnly==0 ) nWrite++;
60276 p = p->pNext;
60278 assert( cnt==db->activeVdbeCnt );
60279 assert( nWrite==db->writeVdbeCnt );
60281 #else
60282 #define checkActiveVdbeCnt(x)
60283 #endif
60286 ** For every Btree that in database connection db which
60287 ** has been modified, "trip" or invalidate each cursor in
60288 ** that Btree might have been modified so that the cursor
60289 ** can never be used again. This happens when a rollback
60290 *** occurs. We have to trip all the other cursors, even
60291 ** cursor from other VMs in different database connections,
60292 ** so that none of them try to use the data at which they
60293 ** were pointing and which now may have been changed due
60294 ** to the rollback.
60296 ** Remember that a rollback can delete tables complete and
60297 ** reorder rootpages. So it is not sufficient just to save
60298 ** the state of the cursor. We have to invalidate the cursor
60299 ** so that it is never used again.
60301 static void invalidateCursorsOnModifiedBtrees(sqlite3 *db){
60302 int i;
60303 for(i=0; i<db->nDb; i++){
60304 Btree *p = db->aDb[i].pBt;
60305 if( p && sqlite3BtreeIsInTrans(p) ){
60306 sqlite3BtreeTripAllCursors(p, SQLITE_ABORT);
60312 ** If the Vdbe passed as the first argument opened a statement-transaction,
60313 ** close it now. Argument eOp must be either SAVEPOINT_ROLLBACK or
60314 ** SAVEPOINT_RELEASE. If it is SAVEPOINT_ROLLBACK, then the statement
60315 ** transaction is rolled back. If eOp is SAVEPOINT_RELEASE, then the
60316 ** statement transaction is commtted.
60318 ** If an IO error occurs, an SQLITE_IOERR_XXX error code is returned.
60319 ** Otherwise SQLITE_OK.
60321 SQLITE_PRIVATE int sqlite3VdbeCloseStatement(Vdbe *p, int eOp){
60322 sqlite3 *const db = p->db;
60323 int rc = SQLITE_OK;
60325 /* If p->iStatement is greater than zero, then this Vdbe opened a
60326 ** statement transaction that should be closed here. The only exception
60327 ** is that an IO error may have occured, causing an emergency rollback.
60328 ** In this case (db->nStatement==0), and there is nothing to do.
60330 if( db->nStatement && p->iStatement ){
60331 int i;
60332 const int iSavepoint = p->iStatement-1;
60334 assert( eOp==SAVEPOINT_ROLLBACK || eOp==SAVEPOINT_RELEASE);
60335 assert( db->nStatement>0 );
60336 assert( p->iStatement==(db->nStatement+db->nSavepoint) );
60338 for(i=0; i<db->nDb; i++){
60339 int rc2 = SQLITE_OK;
60340 Btree *pBt = db->aDb[i].pBt;
60341 if( pBt ){
60342 if( eOp==SAVEPOINT_ROLLBACK ){
60343 rc2 = sqlite3BtreeSavepoint(pBt, SAVEPOINT_ROLLBACK, iSavepoint);
60345 if( rc2==SQLITE_OK ){
60346 rc2 = sqlite3BtreeSavepoint(pBt, SAVEPOINT_RELEASE, iSavepoint);
60348 if( rc==SQLITE_OK ){
60349 rc = rc2;
60353 db->nStatement--;
60354 p->iStatement = 0;
60356 if( rc==SQLITE_OK ){
60357 if( eOp==SAVEPOINT_ROLLBACK ){
60358 rc = sqlite3VtabSavepoint(db, SAVEPOINT_ROLLBACK, iSavepoint);
60360 if( rc==SQLITE_OK ){
60361 rc = sqlite3VtabSavepoint(db, SAVEPOINT_RELEASE, iSavepoint);
60365 /* If the statement transaction is being rolled back, also restore the
60366 ** database handles deferred constraint counter to the value it had when
60367 ** the statement transaction was opened. */
60368 if( eOp==SAVEPOINT_ROLLBACK ){
60369 db->nDeferredCons = p->nStmtDefCons;
60372 return rc;
60376 ** This function is called when a transaction opened by the database
60377 ** handle associated with the VM passed as an argument is about to be
60378 ** committed. If there are outstanding deferred foreign key constraint
60379 ** violations, return SQLITE_ERROR. Otherwise, SQLITE_OK.
60381 ** If there are outstanding FK violations and this function returns
60382 ** SQLITE_ERROR, set the result of the VM to SQLITE_CONSTRAINT and write
60383 ** an error message to it. Then return SQLITE_ERROR.
60385 #ifndef SQLITE_OMIT_FOREIGN_KEY
60386 SQLITE_PRIVATE int sqlite3VdbeCheckFk(Vdbe *p, int deferred){
60387 sqlite3 *db = p->db;
60388 if( (deferred && db->nDeferredCons>0) || (!deferred && p->nFkConstraint>0) ){
60389 p->rc = SQLITE_CONSTRAINT;
60390 p->errorAction = OE_Abort;
60391 sqlite3SetString(&p->zErrMsg, db, "foreign key constraint failed");
60392 return SQLITE_ERROR;
60394 return SQLITE_OK;
60396 #endif
60399 ** This routine is called the when a VDBE tries to halt. If the VDBE
60400 ** has made changes and is in autocommit mode, then commit those
60401 ** changes. If a rollback is needed, then do the rollback.
60403 ** This routine is the only way to move the state of a VM from
60404 ** SQLITE_MAGIC_RUN to SQLITE_MAGIC_HALT. It is harmless to
60405 ** call this on a VM that is in the SQLITE_MAGIC_HALT state.
60407 ** Return an error code. If the commit could not complete because of
60408 ** lock contention, return SQLITE_BUSY. If SQLITE_BUSY is returned, it
60409 ** means the close did not happen and needs to be repeated.
60411 SQLITE_PRIVATE int sqlite3VdbeHalt(Vdbe *p){
60412 int rc; /* Used to store transient return codes */
60413 sqlite3 *db = p->db;
60415 /* This function contains the logic that determines if a statement or
60416 ** transaction will be committed or rolled back as a result of the
60417 ** execution of this virtual machine.
60419 ** If any of the following errors occur:
60421 ** SQLITE_NOMEM
60422 ** SQLITE_IOERR
60423 ** SQLITE_FULL
60424 ** SQLITE_INTERRUPT
60426 ** Then the internal cache might have been left in an inconsistent
60427 ** state. We need to rollback the statement transaction, if there is
60428 ** one, or the complete transaction if there is no statement transaction.
60431 if( p->db->mallocFailed ){
60432 p->rc = SQLITE_NOMEM;
60434 closeAllCursors(p);
60435 if( p->magic!=VDBE_MAGIC_RUN ){
60436 return SQLITE_OK;
60438 checkActiveVdbeCnt(db);
60440 /* No commit or rollback needed if the program never started */
60441 if( p->pc>=0 ){
60442 int mrc; /* Primary error code from p->rc */
60443 int eStatementOp = 0;
60444 int isSpecialError; /* Set to true if a 'special' error */
60446 /* Lock all btrees used by the statement */
60447 sqlite3VdbeEnter(p);
60449 /* Check for one of the special errors */
60450 mrc = p->rc & 0xff;
60451 assert( p->rc!=SQLITE_IOERR_BLOCKED ); /* This error no longer exists */
60452 isSpecialError = mrc==SQLITE_NOMEM || mrc==SQLITE_IOERR
60453 || mrc==SQLITE_INTERRUPT || mrc==SQLITE_FULL;
60454 if( isSpecialError ){
60455 /* If the query was read-only and the error code is SQLITE_INTERRUPT,
60456 ** no rollback is necessary. Otherwise, at least a savepoint
60457 ** transaction must be rolled back to restore the database to a
60458 ** consistent state.
60460 ** Even if the statement is read-only, it is important to perform
60461 ** a statement or transaction rollback operation. If the error
60462 ** occured while writing to the journal, sub-journal or database
60463 ** file as part of an effort to free up cache space (see function
60464 ** pagerStress() in pager.c), the rollback is required to restore
60465 ** the pager to a consistent state.
60467 if( !p->readOnly || mrc!=SQLITE_INTERRUPT ){
60468 if( (mrc==SQLITE_NOMEM || mrc==SQLITE_FULL) && p->usesStmtJournal ){
60469 eStatementOp = SAVEPOINT_ROLLBACK;
60470 }else{
60471 /* We are forced to roll back the active transaction. Before doing
60472 ** so, abort any other statements this handle currently has active.
60474 invalidateCursorsOnModifiedBtrees(db);
60475 sqlite3RollbackAll(db);
60476 sqlite3CloseSavepoints(db);
60477 db->autoCommit = 1;
60482 /* Check for immediate foreign key violations. */
60483 if( p->rc==SQLITE_OK ){
60484 sqlite3VdbeCheckFk(p, 0);
60487 /* If the auto-commit flag is set and this is the only active writer
60488 ** VM, then we do either a commit or rollback of the current transaction.
60490 ** Note: This block also runs if one of the special errors handled
60491 ** above has occurred.
60493 if( !sqlite3VtabInSync(db)
60494 && db->autoCommit
60495 && db->writeVdbeCnt==(p->readOnly==0)
60497 if( p->rc==SQLITE_OK || (p->errorAction==OE_Fail && !isSpecialError) ){
60498 rc = sqlite3VdbeCheckFk(p, 1);
60499 if( rc!=SQLITE_OK ){
60500 if( NEVER(p->readOnly) ){
60501 sqlite3VdbeLeave(p);
60502 return SQLITE_ERROR;
60504 rc = SQLITE_CONSTRAINT;
60505 }else{
60506 /* The auto-commit flag is true, the vdbe program was successful
60507 ** or hit an 'OR FAIL' constraint and there are no deferred foreign
60508 ** key constraints to hold up the transaction. This means a commit
60509 ** is required. */
60510 rc = vdbeCommit(db, p);
60512 if( rc==SQLITE_BUSY && p->readOnly ){
60513 sqlite3VdbeLeave(p);
60514 return SQLITE_BUSY;
60515 }else if( rc!=SQLITE_OK ){
60516 p->rc = rc;
60517 sqlite3RollbackAll(db);
60518 }else{
60519 db->nDeferredCons = 0;
60520 sqlite3CommitInternalChanges(db);
60522 }else{
60523 sqlite3RollbackAll(db);
60525 db->nStatement = 0;
60526 }else if( eStatementOp==0 ){
60527 if( p->rc==SQLITE_OK || p->errorAction==OE_Fail ){
60528 eStatementOp = SAVEPOINT_RELEASE;
60529 }else if( p->errorAction==OE_Abort ){
60530 eStatementOp = SAVEPOINT_ROLLBACK;
60531 }else{
60532 invalidateCursorsOnModifiedBtrees(db);
60533 sqlite3RollbackAll(db);
60534 sqlite3CloseSavepoints(db);
60535 db->autoCommit = 1;
60539 /* If eStatementOp is non-zero, then a statement transaction needs to
60540 ** be committed or rolled back. Call sqlite3VdbeCloseStatement() to
60541 ** do so. If this operation returns an error, and the current statement
60542 ** error code is SQLITE_OK or SQLITE_CONSTRAINT, then promote the
60543 ** current statement error code.
60545 if( eStatementOp ){
60546 rc = sqlite3VdbeCloseStatement(p, eStatementOp);
60547 if( rc ){
60548 if( p->rc==SQLITE_OK || p->rc==SQLITE_CONSTRAINT ){
60549 p->rc = rc;
60550 sqlite3DbFree(db, p->zErrMsg);
60551 p->zErrMsg = 0;
60553 invalidateCursorsOnModifiedBtrees(db);
60554 sqlite3RollbackAll(db);
60555 sqlite3CloseSavepoints(db);
60556 db->autoCommit = 1;
60560 /* If this was an INSERT, UPDATE or DELETE and no statement transaction
60561 ** has been rolled back, update the database connection change-counter.
60563 if( p->changeCntOn ){
60564 if( eStatementOp!=SAVEPOINT_ROLLBACK ){
60565 sqlite3VdbeSetChanges(db, p->nChange);
60566 }else{
60567 sqlite3VdbeSetChanges(db, 0);
60569 p->nChange = 0;
60572 /* Rollback or commit any schema changes that occurred. */
60573 if( p->rc!=SQLITE_OK && db->flags&SQLITE_InternChanges ){
60574 sqlite3ResetInternalSchema(db, -1);
60575 db->flags = (db->flags | SQLITE_InternChanges);
60578 /* Release the locks */
60579 sqlite3VdbeLeave(p);
60582 /* We have successfully halted and closed the VM. Record this fact. */
60583 if( p->pc>=0 ){
60584 db->activeVdbeCnt--;
60585 if( !p->readOnly ){
60586 db->writeVdbeCnt--;
60588 assert( db->activeVdbeCnt>=db->writeVdbeCnt );
60590 p->magic = VDBE_MAGIC_HALT;
60591 checkActiveVdbeCnt(db);
60592 if( p->db->mallocFailed ){
60593 p->rc = SQLITE_NOMEM;
60596 /* If the auto-commit flag is set to true, then any locks that were held
60597 ** by connection db have now been released. Call sqlite3ConnectionUnlocked()
60598 ** to invoke any required unlock-notify callbacks.
60600 if( db->autoCommit ){
60601 sqlite3ConnectionUnlocked(db);
60604 assert( db->activeVdbeCnt>0 || db->autoCommit==0 || db->nStatement==0 );
60605 return (p->rc==SQLITE_BUSY ? SQLITE_BUSY : SQLITE_OK);
60610 ** Each VDBE holds the result of the most recent sqlite3_step() call
60611 ** in p->rc. This routine sets that result back to SQLITE_OK.
60613 SQLITE_PRIVATE void sqlite3VdbeResetStepResult(Vdbe *p){
60614 p->rc = SQLITE_OK;
60618 ** Clean up a VDBE after execution but do not delete the VDBE just yet.
60619 ** Write any error messages into *pzErrMsg. Return the result code.
60621 ** After this routine is run, the VDBE should be ready to be executed
60622 ** again.
60624 ** To look at it another way, this routine resets the state of the
60625 ** virtual machine from VDBE_MAGIC_RUN or VDBE_MAGIC_HALT back to
60626 ** VDBE_MAGIC_INIT.
60628 SQLITE_PRIVATE int sqlite3VdbeReset(Vdbe *p){
60629 sqlite3 *db;
60630 db = p->db;
60632 /* If the VM did not run to completion or if it encountered an
60633 ** error, then it might not have been halted properly. So halt
60634 ** it now.
60636 sqlite3VdbeHalt(p);
60638 /* If the VDBE has be run even partially, then transfer the error code
60639 ** and error message from the VDBE into the main database structure. But
60640 ** if the VDBE has just been set to run but has not actually executed any
60641 ** instructions yet, leave the main database error information unchanged.
60643 if( p->pc>=0 ){
60644 if( p->zErrMsg ){
60645 sqlite3BeginBenignMalloc();
60646 sqlite3ValueSetStr(db->pErr,-1,p->zErrMsg,SQLITE_UTF8,SQLITE_TRANSIENT);
60647 sqlite3EndBenignMalloc();
60648 db->errCode = p->rc;
60649 sqlite3DbFree(db, p->zErrMsg);
60650 p->zErrMsg = 0;
60651 }else if( p->rc ){
60652 sqlite3Error(db, p->rc, 0);
60653 }else{
60654 sqlite3Error(db, SQLITE_OK, 0);
60656 if( p->runOnlyOnce ) p->expired = 1;
60657 }else if( p->rc && p->expired ){
60658 /* The expired flag was set on the VDBE before the first call
60659 ** to sqlite3_step(). For consistency (since sqlite3_step() was
60660 ** called), set the database error in this case as well.
60662 sqlite3Error(db, p->rc, 0);
60663 sqlite3ValueSetStr(db->pErr, -1, p->zErrMsg, SQLITE_UTF8, SQLITE_TRANSIENT);
60664 sqlite3DbFree(db, p->zErrMsg);
60665 p->zErrMsg = 0;
60668 /* Reclaim all memory used by the VDBE
60670 Cleanup(p);
60672 /* Save profiling information from this VDBE run.
60674 #ifdef VDBE_PROFILE
60676 FILE *out = fopen("vdbe_profile.out", "a");
60677 if( out ){
60678 int i;
60679 fprintf(out, "---- ");
60680 for(i=0; i<p->nOp; i++){
60681 fprintf(out, "%02x", p->aOp[i].opcode);
60683 fprintf(out, "\n");
60684 for(i=0; i<p->nOp; i++){
60685 fprintf(out, "%6d %10lld %8lld ",
60686 p->aOp[i].cnt,
60687 p->aOp[i].cycles,
60688 p->aOp[i].cnt>0 ? p->aOp[i].cycles/p->aOp[i].cnt : 0
60690 sqlite3VdbePrintOp(out, i, &p->aOp[i]);
60692 fclose(out);
60695 #endif
60696 p->magic = VDBE_MAGIC_INIT;
60697 return p->rc & db->errMask;
60701 ** Clean up and delete a VDBE after execution. Return an integer which is
60702 ** the result code. Write any error message text into *pzErrMsg.
60704 SQLITE_PRIVATE int sqlite3VdbeFinalize(Vdbe *p){
60705 int rc = SQLITE_OK;
60706 if( p->magic==VDBE_MAGIC_RUN || p->magic==VDBE_MAGIC_HALT ){
60707 rc = sqlite3VdbeReset(p);
60708 assert( (rc & p->db->errMask)==rc );
60710 sqlite3VdbeDelete(p);
60711 return rc;
60715 ** Call the destructor for each auxdata entry in pVdbeFunc for which
60716 ** the corresponding bit in mask is clear. Auxdata entries beyond 31
60717 ** are always destroyed. To destroy all auxdata entries, call this
60718 ** routine with mask==0.
60720 SQLITE_PRIVATE void sqlite3VdbeDeleteAuxData(VdbeFunc *pVdbeFunc, int mask){
60721 int i;
60722 for(i=0; i<pVdbeFunc->nAux; i++){
60723 struct AuxData *pAux = &pVdbeFunc->apAux[i];
60724 if( (i>31 || !(mask&(((u32)1)<<i))) && pAux->pAux ){
60725 if( pAux->xDelete ){
60726 pAux->xDelete(pAux->pAux);
60728 pAux->pAux = 0;
60734 ** Free all memory associated with the Vdbe passed as the second argument.
60735 ** The difference between this function and sqlite3VdbeDelete() is that
60736 ** VdbeDelete() also unlinks the Vdbe from the list of VMs associated with
60737 ** the database connection.
60739 SQLITE_PRIVATE void sqlite3VdbeDeleteObject(sqlite3 *db, Vdbe *p){
60740 SubProgram *pSub, *pNext;
60741 int i;
60742 assert( p->db==0 || p->db==db );
60743 releaseMemArray(p->aVar, p->nVar);
60744 releaseMemArray(p->aColName, p->nResColumn*COLNAME_N);
60745 for(pSub=p->pProgram; pSub; pSub=pNext){
60746 pNext = pSub->pNext;
60747 vdbeFreeOpArray(db, pSub->aOp, pSub->nOp);
60748 sqlite3DbFree(db, pSub);
60750 for(i=p->nzVar-1; i>=0; i--) sqlite3DbFree(db, p->azVar[i]);
60751 vdbeFreeOpArray(db, p->aOp, p->nOp);
60752 sqlite3DbFree(db, p->aLabel);
60753 sqlite3DbFree(db, p->aColName);
60754 sqlite3DbFree(db, p->zSql);
60755 sqlite3DbFree(db, p->pFree);
60756 sqlite3DbFree(db, p);
60760 ** Delete an entire VDBE.
60762 SQLITE_PRIVATE void sqlite3VdbeDelete(Vdbe *p){
60763 sqlite3 *db;
60765 if( NEVER(p==0) ) return;
60766 db = p->db;
60767 if( p->pPrev ){
60768 p->pPrev->pNext = p->pNext;
60769 }else{
60770 assert( db->pVdbe==p );
60771 db->pVdbe = p->pNext;
60773 if( p->pNext ){
60774 p->pNext->pPrev = p->pPrev;
60776 p->magic = VDBE_MAGIC_DEAD;
60777 p->db = 0;
60778 sqlite3VdbeDeleteObject(db, p);
60782 ** Make sure the cursor p is ready to read or write the row to which it
60783 ** was last positioned. Return an error code if an OOM fault or I/O error
60784 ** prevents us from positioning the cursor to its correct position.
60786 ** If a MoveTo operation is pending on the given cursor, then do that
60787 ** MoveTo now. If no move is pending, check to see if the row has been
60788 ** deleted out from under the cursor and if it has, mark the row as
60789 ** a NULL row.
60791 ** If the cursor is already pointing to the correct row and that row has
60792 ** not been deleted out from under the cursor, then this routine is a no-op.
60794 SQLITE_PRIVATE int sqlite3VdbeCursorMoveto(VdbeCursor *p){
60795 if( p->deferredMoveto ){
60796 int res, rc;
60797 #ifdef SQLITE_TEST
60798 extern int sqlite3_search_count;
60799 #endif
60800 assert( p->isTable );
60801 rc = sqlite3BtreeMovetoUnpacked(p->pCursor, 0, p->movetoTarget, 0, &res);
60802 if( rc ) return rc;
60803 p->lastRowid = p->movetoTarget;
60804 if( res!=0 ) return SQLITE_CORRUPT_BKPT;
60805 p->rowidIsValid = 1;
60806 #ifdef SQLITE_TEST
60807 sqlite3_search_count++;
60808 #endif
60809 p->deferredMoveto = 0;
60810 p->cacheStatus = CACHE_STALE;
60811 }else if( ALWAYS(p->pCursor) ){
60812 int hasMoved;
60813 int rc = sqlite3BtreeCursorHasMoved(p->pCursor, &hasMoved);
60814 if( rc ) return rc;
60815 if( hasMoved ){
60816 p->cacheStatus = CACHE_STALE;
60817 p->nullRow = 1;
60820 return SQLITE_OK;
60824 ** The following functions:
60826 ** sqlite3VdbeSerialType()
60827 ** sqlite3VdbeSerialTypeLen()
60828 ** sqlite3VdbeSerialLen()
60829 ** sqlite3VdbeSerialPut()
60830 ** sqlite3VdbeSerialGet()
60832 ** encapsulate the code that serializes values for storage in SQLite
60833 ** data and index records. Each serialized value consists of a
60834 ** 'serial-type' and a blob of data. The serial type is an 8-byte unsigned
60835 ** integer, stored as a varint.
60837 ** In an SQLite index record, the serial type is stored directly before
60838 ** the blob of data that it corresponds to. In a table record, all serial
60839 ** types are stored at the start of the record, and the blobs of data at
60840 ** the end. Hence these functions allow the caller to handle the
60841 ** serial-type and data blob seperately.
60843 ** The following table describes the various storage classes for data:
60845 ** serial type bytes of data type
60846 ** -------------- --------------- ---------------
60847 ** 0 0 NULL
60848 ** 1 1 signed integer
60849 ** 2 2 signed integer
60850 ** 3 3 signed integer
60851 ** 4 4 signed integer
60852 ** 5 6 signed integer
60853 ** 6 8 signed integer
60854 ** 7 8 IEEE float
60855 ** 8 0 Integer constant 0
60856 ** 9 0 Integer constant 1
60857 ** 10,11 reserved for expansion
60858 ** N>=12 and even (N-12)/2 BLOB
60859 ** N>=13 and odd (N-13)/2 text
60861 ** The 8 and 9 types were added in 3.3.0, file format 4. Prior versions
60862 ** of SQLite will not understand those serial types.
60866 ** Return the serial-type for the value stored in pMem.
60868 SQLITE_PRIVATE u32 sqlite3VdbeSerialType(Mem *pMem, int file_format){
60869 int flags = pMem->flags;
60870 int n;
60872 if( flags&MEM_Null ){
60873 return 0;
60875 if( flags&MEM_Int ){
60876 /* Figure out whether to use 1, 2, 4, 6 or 8 bytes. */
60877 # define MAX_6BYTE ((((i64)0x00008000)<<32)-1)
60878 i64 i = pMem->u.i;
60879 u64 u;
60880 if( file_format>=4 && (i&1)==i ){
60881 return 8+(u32)i;
60883 if( i<0 ){
60884 if( i<(-MAX_6BYTE) ) return 6;
60885 /* Previous test prevents: u = -(-9223372036854775808) */
60886 u = -i;
60887 }else{
60888 u = i;
60890 if( u<=127 ) return 1;
60891 if( u<=32767 ) return 2;
60892 if( u<=8388607 ) return 3;
60893 if( u<=2147483647 ) return 4;
60894 if( u<=MAX_6BYTE ) return 5;
60895 return 6;
60897 if( flags&MEM_Real ){
60898 return 7;
60900 assert( pMem->db->mallocFailed || flags&(MEM_Str|MEM_Blob) );
60901 n = pMem->n;
60902 if( flags & MEM_Zero ){
60903 n += pMem->u.nZero;
60905 assert( n>=0 );
60906 return ((n*2) + 12 + ((flags&MEM_Str)!=0));
60910 ** Return the length of the data corresponding to the supplied serial-type.
60912 SQLITE_PRIVATE u32 sqlite3VdbeSerialTypeLen(u32 serial_type){
60913 if( serial_type>=12 ){
60914 return (serial_type-12)/2;
60915 }else{
60916 static const u8 aSize[] = { 0, 1, 2, 3, 4, 6, 8, 8, 0, 0, 0, 0 };
60917 return aSize[serial_type];
60922 ** If we are on an architecture with mixed-endian floating
60923 ** points (ex: ARM7) then swap the lower 4 bytes with the
60924 ** upper 4 bytes. Return the result.
60926 ** For most architectures, this is a no-op.
60928 ** (later): It is reported to me that the mixed-endian problem
60929 ** on ARM7 is an issue with GCC, not with the ARM7 chip. It seems
60930 ** that early versions of GCC stored the two words of a 64-bit
60931 ** float in the wrong order. And that error has been propagated
60932 ** ever since. The blame is not necessarily with GCC, though.
60933 ** GCC might have just copying the problem from a prior compiler.
60934 ** I am also told that newer versions of GCC that follow a different
60935 ** ABI get the byte order right.
60937 ** Developers using SQLite on an ARM7 should compile and run their
60938 ** application using -DSQLITE_DEBUG=1 at least once. With DEBUG
60939 ** enabled, some asserts below will ensure that the byte order of
60940 ** floating point values is correct.
60942 ** (2007-08-30) Frank van Vugt has studied this problem closely
60943 ** and has send his findings to the SQLite developers. Frank
60944 ** writes that some Linux kernels offer floating point hardware
60945 ** emulation that uses only 32-bit mantissas instead of a full
60946 ** 48-bits as required by the IEEE standard. (This is the
60947 ** CONFIG_FPE_FASTFPE option.) On such systems, floating point
60948 ** byte swapping becomes very complicated. To avoid problems,
60949 ** the necessary byte swapping is carried out using a 64-bit integer
60950 ** rather than a 64-bit float. Frank assures us that the code here
60951 ** works for him. We, the developers, have no way to independently
60952 ** verify this, but Frank seems to know what he is talking about
60953 ** so we trust him.
60955 #ifdef SQLITE_MIXED_ENDIAN_64BIT_FLOAT
60956 static u64 floatSwap(u64 in){
60957 union {
60958 u64 r;
60959 u32 i[2];
60960 } u;
60961 u32 t;
60963 u.r = in;
60964 t = u.i[0];
60965 u.i[0] = u.i[1];
60966 u.i[1] = t;
60967 return u.r;
60969 # define swapMixedEndianFloat(X) X = floatSwap(X)
60970 #else
60971 # define swapMixedEndianFloat(X)
60972 #endif
60975 ** Write the serialized data blob for the value stored in pMem into
60976 ** buf. It is assumed that the caller has allocated sufficient space.
60977 ** Return the number of bytes written.
60979 ** nBuf is the amount of space left in buf[]. nBuf must always be
60980 ** large enough to hold the entire field. Except, if the field is
60981 ** a blob with a zero-filled tail, then buf[] might be just the right
60982 ** size to hold everything except for the zero-filled tail. If buf[]
60983 ** is only big enough to hold the non-zero prefix, then only write that
60984 ** prefix into buf[]. But if buf[] is large enough to hold both the
60985 ** prefix and the tail then write the prefix and set the tail to all
60986 ** zeros.
60988 ** Return the number of bytes actually written into buf[]. The number
60989 ** of bytes in the zero-filled tail is included in the return value only
60990 ** if those bytes were zeroed in buf[].
60992 SQLITE_PRIVATE u32 sqlite3VdbeSerialPut(u8 *buf, int nBuf, Mem *pMem, int file_format){
60993 u32 serial_type = sqlite3VdbeSerialType(pMem, file_format);
60994 u32 len;
60996 /* Integer and Real */
60997 if( serial_type<=7 && serial_type>0 ){
60998 u64 v;
60999 u32 i;
61000 if( serial_type==7 ){
61001 assert( sizeof(v)==sizeof(pMem->r) );
61002 memcpy(&v, &pMem->r, sizeof(v));
61003 swapMixedEndianFloat(v);
61004 }else{
61005 v = pMem->u.i;
61007 len = i = sqlite3VdbeSerialTypeLen(serial_type);
61008 assert( len<=(u32)nBuf );
61009 while( i-- ){
61010 buf[i] = (u8)(v&0xFF);
61011 v >>= 8;
61013 return len;
61016 /* String or blob */
61017 if( serial_type>=12 ){
61018 assert( pMem->n + ((pMem->flags & MEM_Zero)?pMem->u.nZero:0)
61019 == (int)sqlite3VdbeSerialTypeLen(serial_type) );
61020 assert( pMem->n<=nBuf );
61021 len = pMem->n;
61022 memcpy(buf, pMem->z, len);
61023 if( pMem->flags & MEM_Zero ){
61024 len += pMem->u.nZero;
61025 assert( nBuf>=0 );
61026 if( len > (u32)nBuf ){
61027 len = (u32)nBuf;
61029 memset(&buf[pMem->n], 0, len-pMem->n);
61031 return len;
61034 /* NULL or constants 0 or 1 */
61035 return 0;
61039 ** Deserialize the data blob pointed to by buf as serial type serial_type
61040 ** and store the result in pMem. Return the number of bytes read.
61042 SQLITE_PRIVATE u32 sqlite3VdbeSerialGet(
61043 const unsigned char *buf, /* Buffer to deserialize from */
61044 u32 serial_type, /* Serial type to deserialize */
61045 Mem *pMem /* Memory cell to write value into */
61047 switch( serial_type ){
61048 case 10: /* Reserved for future use */
61049 case 11: /* Reserved for future use */
61050 case 0: { /* NULL */
61051 pMem->flags = MEM_Null;
61052 break;
61054 case 1: { /* 1-byte signed integer */
61055 pMem->u.i = (signed char)buf[0];
61056 pMem->flags = MEM_Int;
61057 return 1;
61059 case 2: { /* 2-byte signed integer */
61060 pMem->u.i = (((signed char)buf[0])<<8) | buf[1];
61061 pMem->flags = MEM_Int;
61062 return 2;
61064 case 3: { /* 3-byte signed integer */
61065 pMem->u.i = (((signed char)buf[0])<<16) | (buf[1]<<8) | buf[2];
61066 pMem->flags = MEM_Int;
61067 return 3;
61069 case 4: { /* 4-byte signed integer */
61070 pMem->u.i = (buf[0]<<24) | (buf[1]<<16) | (buf[2]<<8) | buf[3];
61071 pMem->flags = MEM_Int;
61072 return 4;
61074 case 5: { /* 6-byte signed integer */
61075 u64 x = (((signed char)buf[0])<<8) | buf[1];
61076 u32 y = (buf[2]<<24) | (buf[3]<<16) | (buf[4]<<8) | buf[5];
61077 x = (x<<32) | y;
61078 pMem->u.i = *(i64*)&x;
61079 pMem->flags = MEM_Int;
61080 return 6;
61082 case 6: /* 8-byte signed integer */
61083 case 7: { /* IEEE floating point */
61084 u64 x;
61085 u32 y;
61086 #if !defined(NDEBUG) && !defined(SQLITE_OMIT_FLOATING_POINT)
61087 /* Verify that integers and floating point values use the same
61088 ** byte order. Or, that if SQLITE_MIXED_ENDIAN_64BIT_FLOAT is
61089 ** defined that 64-bit floating point values really are mixed
61090 ** endian.
61092 static const u64 t1 = ((u64)0x3ff00000)<<32;
61093 static const double r1 = 1.0;
61094 u64 t2 = t1;
61095 swapMixedEndianFloat(t2);
61096 assert( sizeof(r1)==sizeof(t2) && memcmp(&r1, &t2, sizeof(r1))==0 );
61097 #endif
61099 x = (buf[0]<<24) | (buf[1]<<16) | (buf[2]<<8) | buf[3];
61100 y = (buf[4]<<24) | (buf[5]<<16) | (buf[6]<<8) | buf[7];
61101 x = (x<<32) | y;
61102 if( serial_type==6 ){
61103 pMem->u.i = *(i64*)&x;
61104 pMem->flags = MEM_Int;
61105 }else{
61106 assert( sizeof(x)==8 && sizeof(pMem->r)==8 );
61107 swapMixedEndianFloat(x);
61108 memcpy(&pMem->r, &x, sizeof(x));
61109 pMem->flags = sqlite3IsNaN(pMem->r) ? MEM_Null : MEM_Real;
61111 return 8;
61113 case 8: /* Integer 0 */
61114 case 9: { /* Integer 1 */
61115 pMem->u.i = serial_type-8;
61116 pMem->flags = MEM_Int;
61117 return 0;
61119 default: {
61120 u32 len = (serial_type-12)/2;
61121 pMem->z = (char *)buf;
61122 pMem->n = len;
61123 pMem->xDel = 0;
61124 if( serial_type&0x01 ){
61125 pMem->flags = MEM_Str | MEM_Ephem;
61126 }else{
61127 pMem->flags = MEM_Blob | MEM_Ephem;
61129 return len;
61132 return 0;
61136 ** This routine is used to allocate sufficient space for an UnpackedRecord
61137 ** structure large enough to be used with sqlite3VdbeRecordUnpack() if
61138 ** the first argument is a pointer to KeyInfo structure pKeyInfo.
61140 ** The space is either allocated using sqlite3DbMallocRaw() or from within
61141 ** the unaligned buffer passed via the second and third arguments (presumably
61142 ** stack space). If the former, then *ppFree is set to a pointer that should
61143 ** be eventually freed by the caller using sqlite3DbFree(). Or, if the
61144 ** allocation comes from the pSpace/szSpace buffer, *ppFree is set to NULL
61145 ** before returning.
61147 ** If an OOM error occurs, NULL is returned.
61149 SQLITE_PRIVATE UnpackedRecord *sqlite3VdbeAllocUnpackedRecord(
61150 KeyInfo *pKeyInfo, /* Description of the record */
61151 char *pSpace, /* Unaligned space available */
61152 int szSpace, /* Size of pSpace[] in bytes */
61153 char **ppFree /* OUT: Caller should free this pointer */
61155 UnpackedRecord *p; /* Unpacked record to return */
61156 int nOff; /* Increment pSpace by nOff to align it */
61157 int nByte; /* Number of bytes required for *p */
61159 /* We want to shift the pointer pSpace up such that it is 8-byte aligned.
61160 ** Thus, we need to calculate a value, nOff, between 0 and 7, to shift
61161 ** it by. If pSpace is already 8-byte aligned, nOff should be zero.
61163 nOff = (8 - (SQLITE_PTR_TO_INT(pSpace) & 7)) & 7;
61164 nByte = ROUND8(sizeof(UnpackedRecord)) + sizeof(Mem)*(pKeyInfo->nField+1);
61165 if( nByte>szSpace+nOff ){
61166 p = (UnpackedRecord *)sqlite3DbMallocRaw(pKeyInfo->db, nByte);
61167 *ppFree = (char *)p;
61168 if( !p ) return 0;
61169 }else{
61170 p = (UnpackedRecord*)&pSpace[nOff];
61171 *ppFree = 0;
61174 p->aMem = (Mem*)&((char*)p)[ROUND8(sizeof(UnpackedRecord))];
61175 p->pKeyInfo = pKeyInfo;
61176 p->nField = pKeyInfo->nField + 1;
61177 return p;
61181 ** Given the nKey-byte encoding of a record in pKey[], populate the
61182 ** UnpackedRecord structure indicated by the fourth argument with the
61183 ** contents of the decoded record.
61185 SQLITE_PRIVATE void sqlite3VdbeRecordUnpack(
61186 KeyInfo *pKeyInfo, /* Information about the record format */
61187 int nKey, /* Size of the binary record */
61188 const void *pKey, /* The binary record */
61189 UnpackedRecord *p /* Populate this structure before returning. */
61191 const unsigned char *aKey = (const unsigned char *)pKey;
61192 int d;
61193 u32 idx; /* Offset in aKey[] to read from */
61194 u16 u; /* Unsigned loop counter */
61195 u32 szHdr;
61196 Mem *pMem = p->aMem;
61198 p->flags = 0;
61199 assert( EIGHT_BYTE_ALIGNMENT(pMem) );
61200 idx = getVarint32(aKey, szHdr);
61201 d = szHdr;
61202 u = 0;
61203 while( idx<szHdr && u<p->nField && d<=nKey ){
61204 u32 serial_type;
61206 idx += getVarint32(&aKey[idx], serial_type);
61207 pMem->enc = pKeyInfo->enc;
61208 pMem->db = pKeyInfo->db;
61209 /* pMem->flags = 0; // sqlite3VdbeSerialGet() will set this for us */
61210 pMem->zMalloc = 0;
61211 d += sqlite3VdbeSerialGet(&aKey[d], serial_type, pMem);
61212 pMem++;
61213 u++;
61215 assert( u<=pKeyInfo->nField + 1 );
61216 p->nField = u;
61220 ** This function compares the two table rows or index records
61221 ** specified by {nKey1, pKey1} and pPKey2. It returns a negative, zero
61222 ** or positive integer if key1 is less than, equal to or
61223 ** greater than key2. The {nKey1, pKey1} key must be a blob
61224 ** created by th OP_MakeRecord opcode of the VDBE. The pPKey2
61225 ** key must be a parsed key such as obtained from
61226 ** sqlite3VdbeParseRecord.
61228 ** Key1 and Key2 do not have to contain the same number of fields.
61229 ** The key with fewer fields is usually compares less than the
61230 ** longer key. However if the UNPACKED_INCRKEY flags in pPKey2 is set
61231 ** and the common prefixes are equal, then key1 is less than key2.
61232 ** Or if the UNPACKED_MATCH_PREFIX flag is set and the prefixes are
61233 ** equal, then the keys are considered to be equal and
61234 ** the parts beyond the common prefix are ignored.
61236 ** If the UNPACKED_IGNORE_ROWID flag is set, then the last byte of
61237 ** the header of pKey1 is ignored. It is assumed that pKey1 is
61238 ** an index key, and thus ends with a rowid value. The last byte
61239 ** of the header will therefore be the serial type of the rowid:
61240 ** one of 1, 2, 3, 4, 5, 6, 8, or 9 - the integer serial types.
61241 ** The serial type of the final rowid will always be a single byte.
61242 ** By ignoring this last byte of the header, we force the comparison
61243 ** to ignore the rowid at the end of key1.
61245 SQLITE_PRIVATE int sqlite3VdbeRecordCompare(
61246 int nKey1, const void *pKey1, /* Left key */
61247 UnpackedRecord *pPKey2 /* Right key */
61249 int d1; /* Offset into aKey[] of next data element */
61250 u32 idx1; /* Offset into aKey[] of next header element */
61251 u32 szHdr1; /* Number of bytes in header */
61252 int i = 0;
61253 int nField;
61254 int rc = 0;
61255 const unsigned char *aKey1 = (const unsigned char *)pKey1;
61256 KeyInfo *pKeyInfo;
61257 Mem mem1;
61259 pKeyInfo = pPKey2->pKeyInfo;
61260 mem1.enc = pKeyInfo->enc;
61261 mem1.db = pKeyInfo->db;
61262 /* mem1.flags = 0; // Will be initialized by sqlite3VdbeSerialGet() */
61263 VVA_ONLY( mem1.zMalloc = 0; ) /* Only needed by assert() statements */
61265 /* Compilers may complain that mem1.u.i is potentially uninitialized.
61266 ** We could initialize it, as shown here, to silence those complaints.
61267 ** But in fact, mem1.u.i will never actually be used uninitialized, and doing
61268 ** the unnecessary initialization has a measurable negative performance
61269 ** impact, since this routine is a very high runner. And so, we choose
61270 ** to ignore the compiler warnings and leave this variable uninitialized.
61272 /* mem1.u.i = 0; // not needed, here to silence compiler warning */
61274 idx1 = getVarint32(aKey1, szHdr1);
61275 d1 = szHdr1;
61276 if( pPKey2->flags & UNPACKED_IGNORE_ROWID ){
61277 szHdr1--;
61279 nField = pKeyInfo->nField;
61280 while( idx1<szHdr1 && i<pPKey2->nField ){
61281 u32 serial_type1;
61283 /* Read the serial types for the next element in each key. */
61284 idx1 += getVarint32( aKey1+idx1, serial_type1 );
61285 if( d1>=nKey1 && sqlite3VdbeSerialTypeLen(serial_type1)>0 ) break;
61287 /* Extract the values to be compared.
61289 d1 += sqlite3VdbeSerialGet(&aKey1[d1], serial_type1, &mem1);
61291 /* Do the comparison
61293 rc = sqlite3MemCompare(&mem1, &pPKey2->aMem[i],
61294 i<nField ? pKeyInfo->aColl[i] : 0);
61295 if( rc!=0 ){
61296 assert( mem1.zMalloc==0 ); /* See comment below */
61298 /* Invert the result if we are using DESC sort order. */
61299 if( pKeyInfo->aSortOrder && i<nField && pKeyInfo->aSortOrder[i] ){
61300 rc = -rc;
61303 /* If the PREFIX_SEARCH flag is set and all fields except the final
61304 ** rowid field were equal, then clear the PREFIX_SEARCH flag and set
61305 ** pPKey2->rowid to the value of the rowid field in (pKey1, nKey1).
61306 ** This is used by the OP_IsUnique opcode.
61308 if( (pPKey2->flags & UNPACKED_PREFIX_SEARCH) && i==(pPKey2->nField-1) ){
61309 assert( idx1==szHdr1 && rc );
61310 assert( mem1.flags & MEM_Int );
61311 pPKey2->flags &= ~UNPACKED_PREFIX_SEARCH;
61312 pPKey2->rowid = mem1.u.i;
61315 return rc;
61317 i++;
61320 /* No memory allocation is ever used on mem1. Prove this using
61321 ** the following assert(). If the assert() fails, it indicates a
61322 ** memory leak and a need to call sqlite3VdbeMemRelease(&mem1).
61324 assert( mem1.zMalloc==0 );
61326 /* rc==0 here means that one of the keys ran out of fields and
61327 ** all the fields up to that point were equal. If the UNPACKED_INCRKEY
61328 ** flag is set, then break the tie by treating key2 as larger.
61329 ** If the UPACKED_PREFIX_MATCH flag is set, then keys with common prefixes
61330 ** are considered to be equal. Otherwise, the longer key is the
61331 ** larger. As it happens, the pPKey2 will always be the longer
61332 ** if there is a difference.
61334 assert( rc==0 );
61335 if( pPKey2->flags & UNPACKED_INCRKEY ){
61336 rc = -1;
61337 }else if( pPKey2->flags & UNPACKED_PREFIX_MATCH ){
61338 /* Leave rc==0 */
61339 }else if( idx1<szHdr1 ){
61340 rc = 1;
61342 return rc;
61347 ** pCur points at an index entry created using the OP_MakeRecord opcode.
61348 ** Read the rowid (the last field in the record) and store it in *rowid.
61349 ** Return SQLITE_OK if everything works, or an error code otherwise.
61351 ** pCur might be pointing to text obtained from a corrupt database file.
61352 ** So the content cannot be trusted. Do appropriate checks on the content.
61354 SQLITE_PRIVATE int sqlite3VdbeIdxRowid(sqlite3 *db, BtCursor *pCur, i64 *rowid){
61355 i64 nCellKey = 0;
61356 int rc;
61357 u32 szHdr; /* Size of the header */
61358 u32 typeRowid; /* Serial type of the rowid */
61359 u32 lenRowid; /* Size of the rowid */
61360 Mem m, v;
61362 UNUSED_PARAMETER(db);
61364 /* Get the size of the index entry. Only indices entries of less
61365 ** than 2GiB are support - anything large must be database corruption.
61366 ** Any corruption is detected in sqlite3BtreeParseCellPtr(), though, so
61367 ** this code can safely assume that nCellKey is 32-bits
61369 assert( sqlite3BtreeCursorIsValid(pCur) );
61370 rc = sqlite3BtreeKeySize(pCur, &nCellKey);
61371 assert( rc==SQLITE_OK ); /* pCur is always valid so KeySize cannot fail */
61372 assert( (nCellKey & SQLITE_MAX_U32)==(u64)nCellKey );
61374 /* Read in the complete content of the index entry */
61375 memset(&m, 0, sizeof(m));
61376 rc = sqlite3VdbeMemFromBtree(pCur, 0, (int)nCellKey, 1, &m);
61377 if( rc ){
61378 return rc;
61381 /* The index entry must begin with a header size */
61382 (void)getVarint32((u8*)m.z, szHdr);
61383 testcase( szHdr==3 );
61384 testcase( szHdr==m.n );
61385 if( unlikely(szHdr<3 || (int)szHdr>m.n) ){
61386 goto idx_rowid_corruption;
61389 /* The last field of the index should be an integer - the ROWID.
61390 ** Verify that the last entry really is an integer. */
61391 (void)getVarint32((u8*)&m.z[szHdr-1], typeRowid);
61392 testcase( typeRowid==1 );
61393 testcase( typeRowid==2 );
61394 testcase( typeRowid==3 );
61395 testcase( typeRowid==4 );
61396 testcase( typeRowid==5 );
61397 testcase( typeRowid==6 );
61398 testcase( typeRowid==8 );
61399 testcase( typeRowid==9 );
61400 if( unlikely(typeRowid<1 || typeRowid>9 || typeRowid==7) ){
61401 goto idx_rowid_corruption;
61403 lenRowid = sqlite3VdbeSerialTypeLen(typeRowid);
61404 testcase( (u32)m.n==szHdr+lenRowid );
61405 if( unlikely((u32)m.n<szHdr+lenRowid) ){
61406 goto idx_rowid_corruption;
61409 /* Fetch the integer off the end of the index record */
61410 sqlite3VdbeSerialGet((u8*)&m.z[m.n-lenRowid], typeRowid, &v);
61411 *rowid = v.u.i;
61412 sqlite3VdbeMemRelease(&m);
61413 return SQLITE_OK;
61415 /* Jump here if database corruption is detected after m has been
61416 ** allocated. Free the m object and return SQLITE_CORRUPT. */
61417 idx_rowid_corruption:
61418 testcase( m.zMalloc!=0 );
61419 sqlite3VdbeMemRelease(&m);
61420 return SQLITE_CORRUPT_BKPT;
61424 ** Compare the key of the index entry that cursor pC is pointing to against
61425 ** the key string in pUnpacked. Write into *pRes a number
61426 ** that is negative, zero, or positive if pC is less than, equal to,
61427 ** or greater than pUnpacked. Return SQLITE_OK on success.
61429 ** pUnpacked is either created without a rowid or is truncated so that it
61430 ** omits the rowid at the end. The rowid at the end of the index entry
61431 ** is ignored as well. Hence, this routine only compares the prefixes
61432 ** of the keys prior to the final rowid, not the entire key.
61434 SQLITE_PRIVATE int sqlite3VdbeIdxKeyCompare(
61435 VdbeCursor *pC, /* The cursor to compare against */
61436 UnpackedRecord *pUnpacked, /* Unpacked version of key to compare against */
61437 int *res /* Write the comparison result here */
61439 i64 nCellKey = 0;
61440 int rc;
61441 BtCursor *pCur = pC->pCursor;
61442 Mem m;
61444 assert( sqlite3BtreeCursorIsValid(pCur) );
61445 rc = sqlite3BtreeKeySize(pCur, &nCellKey);
61446 assert( rc==SQLITE_OK ); /* pCur is always valid so KeySize cannot fail */
61447 /* nCellKey will always be between 0 and 0xffffffff because of the say
61448 ** that btreeParseCellPtr() and sqlite3GetVarint32() are implemented */
61449 if( nCellKey<=0 || nCellKey>0x7fffffff ){
61450 *res = 0;
61451 return SQLITE_CORRUPT_BKPT;
61453 memset(&m, 0, sizeof(m));
61454 rc = sqlite3VdbeMemFromBtree(pC->pCursor, 0, (int)nCellKey, 1, &m);
61455 if( rc ){
61456 return rc;
61458 assert( pUnpacked->flags & UNPACKED_IGNORE_ROWID );
61459 *res = sqlite3VdbeRecordCompare(m.n, m.z, pUnpacked);
61460 sqlite3VdbeMemRelease(&m);
61461 return SQLITE_OK;
61465 ** This routine sets the value to be returned by subsequent calls to
61466 ** sqlite3_changes() on the database handle 'db'.
61468 SQLITE_PRIVATE void sqlite3VdbeSetChanges(sqlite3 *db, int nChange){
61469 assert( sqlite3_mutex_held(db->mutex) );
61470 db->nChange = nChange;
61471 db->nTotalChange += nChange;
61475 ** Set a flag in the vdbe to update the change counter when it is finalised
61476 ** or reset.
61478 SQLITE_PRIVATE void sqlite3VdbeCountChanges(Vdbe *v){
61479 v->changeCntOn = 1;
61483 ** Mark every prepared statement associated with a database connection
61484 ** as expired.
61486 ** An expired statement means that recompilation of the statement is
61487 ** recommend. Statements expire when things happen that make their
61488 ** programs obsolete. Removing user-defined functions or collating
61489 ** sequences, or changing an authorization function are the types of
61490 ** things that make prepared statements obsolete.
61492 SQLITE_PRIVATE void sqlite3ExpirePreparedStatements(sqlite3 *db){
61493 Vdbe *p;
61494 for(p = db->pVdbe; p; p=p->pNext){
61495 p->expired = 1;
61500 ** Return the database associated with the Vdbe.
61502 SQLITE_PRIVATE sqlite3 *sqlite3VdbeDb(Vdbe *v){
61503 return v->db;
61507 ** Return a pointer to an sqlite3_value structure containing the value bound
61508 ** parameter iVar of VM v. Except, if the value is an SQL NULL, return
61509 ** 0 instead. Unless it is NULL, apply affinity aff (one of the SQLITE_AFF_*
61510 ** constants) to the value before returning it.
61512 ** The returned value must be freed by the caller using sqlite3ValueFree().
61514 SQLITE_PRIVATE sqlite3_value *sqlite3VdbeGetValue(Vdbe *v, int iVar, u8 aff){
61515 assert( iVar>0 );
61516 if( v ){
61517 Mem *pMem = &v->aVar[iVar-1];
61518 if( 0==(pMem->flags & MEM_Null) ){
61519 sqlite3_value *pRet = sqlite3ValueNew(v->db);
61520 if( pRet ){
61521 sqlite3VdbeMemCopy((Mem *)pRet, pMem);
61522 sqlite3ValueApplyAffinity(pRet, aff, SQLITE_UTF8);
61523 sqlite3VdbeMemStoreType((Mem *)pRet);
61525 return pRet;
61528 return 0;
61532 ** Configure SQL variable iVar so that binding a new value to it signals
61533 ** to sqlite3_reoptimize() that re-preparing the statement may result
61534 ** in a better query plan.
61536 SQLITE_PRIVATE void sqlite3VdbeSetVarmask(Vdbe *v, int iVar){
61537 assert( iVar>0 );
61538 if( iVar>32 ){
61539 v->expmask = 0xffffffff;
61540 }else{
61541 v->expmask |= ((u32)1 << (iVar-1));
61545 /************** End of vdbeaux.c *********************************************/
61546 /************** Begin file vdbeapi.c *****************************************/
61548 ** 2004 May 26
61550 ** The author disclaims copyright to this source code. In place of
61551 ** a legal notice, here is a blessing:
61553 ** May you do good and not evil.
61554 ** May you find forgiveness for yourself and forgive others.
61555 ** May you share freely, never taking more than you give.
61557 *************************************************************************
61559 ** This file contains code use to implement APIs that are part of the
61560 ** VDBE.
61563 #ifndef SQLITE_OMIT_DEPRECATED
61565 ** Return TRUE (non-zero) of the statement supplied as an argument needs
61566 ** to be recompiled. A statement needs to be recompiled whenever the
61567 ** execution environment changes in a way that would alter the program
61568 ** that sqlite3_prepare() generates. For example, if new functions or
61569 ** collating sequences are registered or if an authorizer function is
61570 ** added or changed.
61572 SQLITE_API int sqlite3_expired(sqlite3_stmt *pStmt){
61573 Vdbe *p = (Vdbe*)pStmt;
61574 return p==0 || p->expired;
61576 #endif
61579 ** Check on a Vdbe to make sure it has not been finalized. Log
61580 ** an error and return true if it has been finalized (or is otherwise
61581 ** invalid). Return false if it is ok.
61583 static int vdbeSafety(Vdbe *p){
61584 if( p->db==0 ){
61585 sqlite3_log(SQLITE_MISUSE, "API called with finalized prepared statement");
61586 return 1;
61587 }else{
61588 return 0;
61591 static int vdbeSafetyNotNull(Vdbe *p){
61592 if( p==0 ){
61593 sqlite3_log(SQLITE_MISUSE, "API called with NULL prepared statement");
61594 return 1;
61595 }else{
61596 return vdbeSafety(p);
61601 ** The following routine destroys a virtual machine that is created by
61602 ** the sqlite3_compile() routine. The integer returned is an SQLITE_
61603 ** success/failure code that describes the result of executing the virtual
61604 ** machine.
61606 ** This routine sets the error code and string returned by
61607 ** sqlite3_errcode(), sqlite3_errmsg() and sqlite3_errmsg16().
61609 SQLITE_API int sqlite3_finalize(sqlite3_stmt *pStmt){
61610 int rc;
61611 if( pStmt==0 ){
61612 /* IMPLEMENTATION-OF: R-57228-12904 Invoking sqlite3_finalize() on a NULL
61613 ** pointer is a harmless no-op. */
61614 rc = SQLITE_OK;
61615 }else{
61616 Vdbe *v = (Vdbe*)pStmt;
61617 sqlite3 *db = v->db;
61618 #if SQLITE_THREADSAFE
61619 sqlite3_mutex *mutex;
61620 #endif
61621 if( vdbeSafety(v) ) return SQLITE_MISUSE_BKPT;
61622 #if SQLITE_THREADSAFE
61623 mutex = v->db->mutex;
61624 #endif
61625 sqlite3_mutex_enter(mutex);
61626 rc = sqlite3VdbeFinalize(v);
61627 rc = sqlite3ApiExit(db, rc);
61628 sqlite3_mutex_leave(mutex);
61630 return rc;
61634 ** Terminate the current execution of an SQL statement and reset it
61635 ** back to its starting state so that it can be reused. A success code from
61636 ** the prior execution is returned.
61638 ** This routine sets the error code and string returned by
61639 ** sqlite3_errcode(), sqlite3_errmsg() and sqlite3_errmsg16().
61641 SQLITE_API int sqlite3_reset(sqlite3_stmt *pStmt){
61642 int rc;
61643 if( pStmt==0 ){
61644 rc = SQLITE_OK;
61645 }else{
61646 Vdbe *v = (Vdbe*)pStmt;
61647 sqlite3_mutex_enter(v->db->mutex);
61648 rc = sqlite3VdbeReset(v);
61649 sqlite3VdbeRewind(v);
61650 assert( (rc & (v->db->errMask))==rc );
61651 rc = sqlite3ApiExit(v->db, rc);
61652 sqlite3_mutex_leave(v->db->mutex);
61654 return rc;
61658 ** Set all the parameters in the compiled SQL statement to NULL.
61660 SQLITE_API int sqlite3_clear_bindings(sqlite3_stmt *pStmt){
61661 int i;
61662 int rc = SQLITE_OK;
61663 Vdbe *p = (Vdbe*)pStmt;
61664 #if SQLITE_THREADSAFE
61665 sqlite3_mutex *mutex = ((Vdbe*)pStmt)->db->mutex;
61666 #endif
61667 sqlite3_mutex_enter(mutex);
61668 for(i=0; i<p->nVar; i++){
61669 sqlite3VdbeMemRelease(&p->aVar[i]);
61670 p->aVar[i].flags = MEM_Null;
61672 if( p->isPrepareV2 && p->expmask ){
61673 p->expired = 1;
61675 sqlite3_mutex_leave(mutex);
61676 return rc;
61680 /**************************** sqlite3_value_ *******************************
61681 ** The following routines extract information from a Mem or sqlite3_value
61682 ** structure.
61684 SQLITE_API const void *sqlite3_value_blob(sqlite3_value *pVal){
61685 Mem *p = (Mem*)pVal;
61686 if( p->flags & (MEM_Blob|MEM_Str) ){
61687 sqlite3VdbeMemExpandBlob(p);
61688 p->flags &= ~MEM_Str;
61689 p->flags |= MEM_Blob;
61690 return p->n ? p->z : 0;
61691 }else{
61692 return sqlite3_value_text(pVal);
61695 SQLITE_API int sqlite3_value_bytes(sqlite3_value *pVal){
61696 return sqlite3ValueBytes(pVal, SQLITE_UTF8);
61698 SQLITE_API int sqlite3_value_bytes16(sqlite3_value *pVal){
61699 return sqlite3ValueBytes(pVal, SQLITE_UTF16NATIVE);
61701 SQLITE_API double sqlite3_value_double(sqlite3_value *pVal){
61702 return sqlite3VdbeRealValue((Mem*)pVal);
61704 SQLITE_API int sqlite3_value_int(sqlite3_value *pVal){
61705 return (int)sqlite3VdbeIntValue((Mem*)pVal);
61707 SQLITE_API sqlite_int64 sqlite3_value_int64(sqlite3_value *pVal){
61708 return sqlite3VdbeIntValue((Mem*)pVal);
61710 SQLITE_API const unsigned char *sqlite3_value_text(sqlite3_value *pVal){
61711 return (const unsigned char *)sqlite3ValueText(pVal, SQLITE_UTF8);
61713 #ifndef SQLITE_OMIT_UTF16
61714 SQLITE_API const void *sqlite3_value_text16(sqlite3_value* pVal){
61715 return sqlite3ValueText(pVal, SQLITE_UTF16NATIVE);
61717 SQLITE_API const void *sqlite3_value_text16be(sqlite3_value *pVal){
61718 return sqlite3ValueText(pVal, SQLITE_UTF16BE);
61720 SQLITE_API const void *sqlite3_value_text16le(sqlite3_value *pVal){
61721 return sqlite3ValueText(pVal, SQLITE_UTF16LE);
61723 #endif /* SQLITE_OMIT_UTF16 */
61724 SQLITE_API int sqlite3_value_type(sqlite3_value* pVal){
61725 return pVal->type;
61728 /**************************** sqlite3_result_ *******************************
61729 ** The following routines are used by user-defined functions to specify
61730 ** the function result.
61732 ** The setStrOrError() funtion calls sqlite3VdbeMemSetStr() to store the
61733 ** result as a string or blob but if the string or blob is too large, it
61734 ** then sets the error code to SQLITE_TOOBIG
61736 static void setResultStrOrError(
61737 sqlite3_context *pCtx, /* Function context */
61738 const char *z, /* String pointer */
61739 int n, /* Bytes in string, or negative */
61740 u8 enc, /* Encoding of z. 0 for BLOBs */
61741 void (*xDel)(void*) /* Destructor function */
61743 if( sqlite3VdbeMemSetStr(&pCtx->s, z, n, enc, xDel)==SQLITE_TOOBIG ){
61744 sqlite3_result_error_toobig(pCtx);
61747 SQLITE_API void sqlite3_result_blob(
61748 sqlite3_context *pCtx,
61749 const void *z,
61750 int n,
61751 void (*xDel)(void *)
61753 assert( n>=0 );
61754 assert( sqlite3_mutex_held(pCtx->s.db->mutex) );
61755 setResultStrOrError(pCtx, z, n, 0, xDel);
61757 SQLITE_API void sqlite3_result_double(sqlite3_context *pCtx, double rVal){
61758 assert( sqlite3_mutex_held(pCtx->s.db->mutex) );
61759 sqlite3VdbeMemSetDouble(&pCtx->s, rVal);
61761 SQLITE_API void sqlite3_result_error(sqlite3_context *pCtx, const char *z, int n){
61762 assert( sqlite3_mutex_held(pCtx->s.db->mutex) );
61763 pCtx->isError = SQLITE_ERROR;
61764 sqlite3VdbeMemSetStr(&pCtx->s, z, n, SQLITE_UTF8, SQLITE_TRANSIENT);
61766 #ifndef SQLITE_OMIT_UTF16
61767 SQLITE_API void sqlite3_result_error16(sqlite3_context *pCtx, const void *z, int n){
61768 assert( sqlite3_mutex_held(pCtx->s.db->mutex) );
61769 pCtx->isError = SQLITE_ERROR;
61770 sqlite3VdbeMemSetStr(&pCtx->s, z, n, SQLITE_UTF16NATIVE, SQLITE_TRANSIENT);
61772 #endif
61773 SQLITE_API void sqlite3_result_int(sqlite3_context *pCtx, int iVal){
61774 assert( sqlite3_mutex_held(pCtx->s.db->mutex) );
61775 sqlite3VdbeMemSetInt64(&pCtx->s, (i64)iVal);
61777 SQLITE_API void sqlite3_result_int64(sqlite3_context *pCtx, i64 iVal){
61778 assert( sqlite3_mutex_held(pCtx->s.db->mutex) );
61779 sqlite3VdbeMemSetInt64(&pCtx->s, iVal);
61781 SQLITE_API void sqlite3_result_null(sqlite3_context *pCtx){
61782 assert( sqlite3_mutex_held(pCtx->s.db->mutex) );
61783 sqlite3VdbeMemSetNull(&pCtx->s);
61785 SQLITE_API void sqlite3_result_text(
61786 sqlite3_context *pCtx,
61787 const char *z,
61788 int n,
61789 void (*xDel)(void *)
61791 assert( sqlite3_mutex_held(pCtx->s.db->mutex) );
61792 setResultStrOrError(pCtx, z, n, SQLITE_UTF8, xDel);
61794 #ifndef SQLITE_OMIT_UTF16
61795 SQLITE_API void sqlite3_result_text16(
61796 sqlite3_context *pCtx,
61797 const void *z,
61798 int n,
61799 void (*xDel)(void *)
61801 assert( sqlite3_mutex_held(pCtx->s.db->mutex) );
61802 setResultStrOrError(pCtx, z, n, SQLITE_UTF16NATIVE, xDel);
61804 SQLITE_API void sqlite3_result_text16be(
61805 sqlite3_context *pCtx,
61806 const void *z,
61807 int n,
61808 void (*xDel)(void *)
61810 assert( sqlite3_mutex_held(pCtx->s.db->mutex) );
61811 setResultStrOrError(pCtx, z, n, SQLITE_UTF16BE, xDel);
61813 SQLITE_API void sqlite3_result_text16le(
61814 sqlite3_context *pCtx,
61815 const void *z,
61816 int n,
61817 void (*xDel)(void *)
61819 assert( sqlite3_mutex_held(pCtx->s.db->mutex) );
61820 setResultStrOrError(pCtx, z, n, SQLITE_UTF16LE, xDel);
61822 #endif /* SQLITE_OMIT_UTF16 */
61823 SQLITE_API void sqlite3_result_value(sqlite3_context *pCtx, sqlite3_value *pValue){
61824 assert( sqlite3_mutex_held(pCtx->s.db->mutex) );
61825 sqlite3VdbeMemCopy(&pCtx->s, pValue);
61827 SQLITE_API void sqlite3_result_zeroblob(sqlite3_context *pCtx, int n){
61828 assert( sqlite3_mutex_held(pCtx->s.db->mutex) );
61829 sqlite3VdbeMemSetZeroBlob(&pCtx->s, n);
61831 SQLITE_API void sqlite3_result_error_code(sqlite3_context *pCtx, int errCode){
61832 pCtx->isError = errCode;
61833 if( pCtx->s.flags & MEM_Null ){
61834 sqlite3VdbeMemSetStr(&pCtx->s, sqlite3ErrStr(errCode), -1,
61835 SQLITE_UTF8, SQLITE_STATIC);
61839 /* Force an SQLITE_TOOBIG error. */
61840 SQLITE_API void sqlite3_result_error_toobig(sqlite3_context *pCtx){
61841 assert( sqlite3_mutex_held(pCtx->s.db->mutex) );
61842 pCtx->isError = SQLITE_TOOBIG;
61843 sqlite3VdbeMemSetStr(&pCtx->s, "string or blob too big", -1,
61844 SQLITE_UTF8, SQLITE_STATIC);
61847 /* An SQLITE_NOMEM error. */
61848 SQLITE_API void sqlite3_result_error_nomem(sqlite3_context *pCtx){
61849 assert( sqlite3_mutex_held(pCtx->s.db->mutex) );
61850 sqlite3VdbeMemSetNull(&pCtx->s);
61851 pCtx->isError = SQLITE_NOMEM;
61852 pCtx->s.db->mallocFailed = 1;
61856 ** This function is called after a transaction has been committed. It
61857 ** invokes callbacks registered with sqlite3_wal_hook() as required.
61859 static int doWalCallbacks(sqlite3 *db){
61860 int rc = SQLITE_OK;
61861 #ifndef SQLITE_OMIT_WAL
61862 int i;
61863 for(i=0; i<db->nDb; i++){
61864 Btree *pBt = db->aDb[i].pBt;
61865 if( pBt ){
61866 int nEntry = sqlite3PagerWalCallback(sqlite3BtreePager(pBt));
61867 if( db->xWalCallback && nEntry>0 && rc==SQLITE_OK ){
61868 rc = db->xWalCallback(db->pWalArg, db, db->aDb[i].zName, nEntry);
61872 #endif
61873 return rc;
61877 ** Execute the statement pStmt, either until a row of data is ready, the
61878 ** statement is completely executed or an error occurs.
61880 ** This routine implements the bulk of the logic behind the sqlite_step()
61881 ** API. The only thing omitted is the automatic recompile if a
61882 ** schema change has occurred. That detail is handled by the
61883 ** outer sqlite3_step() wrapper procedure.
61885 static int sqlite3Step(Vdbe *p){
61886 sqlite3 *db;
61887 int rc;
61889 assert(p);
61890 if( p->magic!=VDBE_MAGIC_RUN ){
61891 /* We used to require that sqlite3_reset() be called before retrying
61892 ** sqlite3_step() after any error or after SQLITE_DONE. But beginning
61893 ** with version 3.7.0, we changed this so that sqlite3_reset() would
61894 ** be called automatically instead of throwing the SQLITE_MISUSE error.
61895 ** This "automatic-reset" change is not technically an incompatibility,
61896 ** since any application that receives an SQLITE_MISUSE is broken by
61897 ** definition.
61899 ** Nevertheless, some published applications that were originally written
61900 ** for version 3.6.23 or earlier do in fact depend on SQLITE_MISUSE
61901 ** returns, and the so were broken by the automatic-reset change. As a
61902 ** a work-around, the SQLITE_OMIT_AUTORESET compile-time restores the
61903 ** legacy behavior of returning SQLITE_MISUSE for cases where the
61904 ** previous sqlite3_step() returned something other than a SQLITE_LOCKED
61905 ** or SQLITE_BUSY error.
61907 #ifdef SQLITE_OMIT_AUTORESET
61908 if( p->rc==SQLITE_BUSY || p->rc==SQLITE_LOCKED ){
61909 sqlite3_reset((sqlite3_stmt*)p);
61910 }else{
61911 return SQLITE_MISUSE_BKPT;
61913 #else
61914 sqlite3_reset((sqlite3_stmt*)p);
61915 #endif
61918 /* Check that malloc() has not failed. If it has, return early. */
61919 db = p->db;
61920 if( db->mallocFailed ){
61921 p->rc = SQLITE_NOMEM;
61922 return SQLITE_NOMEM;
61925 if( p->pc<=0 && p->expired ){
61926 p->rc = SQLITE_SCHEMA;
61927 rc = SQLITE_ERROR;
61928 goto end_of_step;
61930 if( p->pc<0 ){
61931 /* If there are no other statements currently running, then
61932 ** reset the interrupt flag. This prevents a call to sqlite3_interrupt
61933 ** from interrupting a statement that has not yet started.
61935 if( db->activeVdbeCnt==0 ){
61936 db->u1.isInterrupted = 0;
61939 assert( db->writeVdbeCnt>0 || db->autoCommit==0 || db->nDeferredCons==0 );
61941 #ifndef SQLITE_OMIT_TRACE
61942 if( db->xProfile && !db->init.busy ){
61943 sqlite3OsCurrentTimeInt64(db->pVfs, &p->startTime);
61945 #endif
61947 db->activeVdbeCnt++;
61948 if( p->readOnly==0 ) db->writeVdbeCnt++;
61949 p->pc = 0;
61951 #ifndef SQLITE_OMIT_EXPLAIN
61952 if( p->explain ){
61953 rc = sqlite3VdbeList(p);
61954 }else
61955 #endif /* SQLITE_OMIT_EXPLAIN */
61957 db->vdbeExecCnt++;
61958 rc = sqlite3VdbeExec(p);
61959 db->vdbeExecCnt--;
61962 #ifndef SQLITE_OMIT_TRACE
61963 /* Invoke the profile callback if there is one
61965 if( rc!=SQLITE_ROW && db->xProfile && !db->init.busy && p->zSql ){
61966 sqlite3_int64 iNow;
61967 sqlite3OsCurrentTimeInt64(db->pVfs, &iNow);
61968 db->xProfile(db->pProfileArg, p->zSql, (iNow - p->startTime)*1000000);
61970 #endif
61972 if( rc==SQLITE_DONE ){
61973 assert( p->rc==SQLITE_OK );
61974 p->rc = doWalCallbacks(db);
61975 if( p->rc!=SQLITE_OK ){
61976 rc = SQLITE_ERROR;
61980 db->errCode = rc;
61981 if( SQLITE_NOMEM==sqlite3ApiExit(p->db, p->rc) ){
61982 p->rc = SQLITE_NOMEM;
61984 end_of_step:
61985 /* At this point local variable rc holds the value that should be
61986 ** returned if this statement was compiled using the legacy
61987 ** sqlite3_prepare() interface. According to the docs, this can only
61988 ** be one of the values in the first assert() below. Variable p->rc
61989 ** contains the value that would be returned if sqlite3_finalize()
61990 ** were called on statement p.
61992 assert( rc==SQLITE_ROW || rc==SQLITE_DONE || rc==SQLITE_ERROR
61993 || rc==SQLITE_BUSY || rc==SQLITE_MISUSE
61995 assert( p->rc!=SQLITE_ROW && p->rc!=SQLITE_DONE );
61996 if( p->isPrepareV2 && rc!=SQLITE_ROW && rc!=SQLITE_DONE ){
61997 /* If this statement was prepared using sqlite3_prepare_v2(), and an
61998 ** error has occured, then return the error code in p->rc to the
61999 ** caller. Set the error code in the database handle to the same value.
62001 rc = db->errCode = p->rc;
62003 return (rc&db->errMask);
62007 ** The maximum number of times that a statement will try to reparse
62008 ** itself before giving up and returning SQLITE_SCHEMA.
62010 #ifndef SQLITE_MAX_SCHEMA_RETRY
62011 # define SQLITE_MAX_SCHEMA_RETRY 5
62012 #endif
62015 ** This is the top-level implementation of sqlite3_step(). Call
62016 ** sqlite3Step() to do most of the work. If a schema error occurs,
62017 ** call sqlite3Reprepare() and try again.
62019 SQLITE_API int sqlite3_step(sqlite3_stmt *pStmt){
62020 int rc = SQLITE_OK; /* Result from sqlite3Step() */
62021 int rc2 = SQLITE_OK; /* Result from sqlite3Reprepare() */
62022 Vdbe *v = (Vdbe*)pStmt; /* the prepared statement */
62023 int cnt = 0; /* Counter to prevent infinite loop of reprepares */
62024 sqlite3 *db; /* The database connection */
62026 if( vdbeSafetyNotNull(v) ){
62027 return SQLITE_MISUSE_BKPT;
62029 db = v->db;
62030 sqlite3_mutex_enter(db->mutex);
62031 while( (rc = sqlite3Step(v))==SQLITE_SCHEMA
62032 && cnt++ < SQLITE_MAX_SCHEMA_RETRY
62033 && (rc2 = rc = sqlite3Reprepare(v))==SQLITE_OK ){
62034 sqlite3_reset(pStmt);
62035 assert( v->expired==0 );
62037 if( rc2!=SQLITE_OK && ALWAYS(v->isPrepareV2) && ALWAYS(db->pErr) ){
62038 /* This case occurs after failing to recompile an sql statement.
62039 ** The error message from the SQL compiler has already been loaded
62040 ** into the database handle. This block copies the error message
62041 ** from the database handle into the statement and sets the statement
62042 ** program counter to 0 to ensure that when the statement is
62043 ** finalized or reset the parser error message is available via
62044 ** sqlite3_errmsg() and sqlite3_errcode().
62046 const char *zErr = (const char *)sqlite3_value_text(db->pErr);
62047 sqlite3DbFree(db, v->zErrMsg);
62048 if( !db->mallocFailed ){
62049 v->zErrMsg = sqlite3DbStrDup(db, zErr);
62050 v->rc = rc2;
62051 } else {
62052 v->zErrMsg = 0;
62053 v->rc = rc = SQLITE_NOMEM;
62056 rc = sqlite3ApiExit(db, rc);
62057 sqlite3_mutex_leave(db->mutex);
62058 return rc;
62062 ** Extract the user data from a sqlite3_context structure and return a
62063 ** pointer to it.
62065 SQLITE_API void *sqlite3_user_data(sqlite3_context *p){
62066 assert( p && p->pFunc );
62067 return p->pFunc->pUserData;
62071 ** Extract the user data from a sqlite3_context structure and return a
62072 ** pointer to it.
62074 ** IMPLEMENTATION-OF: R-46798-50301 The sqlite3_context_db_handle() interface
62075 ** returns a copy of the pointer to the database connection (the 1st
62076 ** parameter) of the sqlite3_create_function() and
62077 ** sqlite3_create_function16() routines that originally registered the
62078 ** application defined function.
62080 SQLITE_API sqlite3 *sqlite3_context_db_handle(sqlite3_context *p){
62081 assert( p && p->pFunc );
62082 return p->s.db;
62086 ** The following is the implementation of an SQL function that always
62087 ** fails with an error message stating that the function is used in the
62088 ** wrong context. The sqlite3_overload_function() API might construct
62089 ** SQL function that use this routine so that the functions will exist
62090 ** for name resolution but are actually overloaded by the xFindFunction
62091 ** method of virtual tables.
62093 SQLITE_PRIVATE void sqlite3InvalidFunction(
62094 sqlite3_context *context, /* The function calling context */
62095 int NotUsed, /* Number of arguments to the function */
62096 sqlite3_value **NotUsed2 /* Value of each argument */
62098 const char *zName = context->pFunc->zName;
62099 char *zErr;
62100 UNUSED_PARAMETER2(NotUsed, NotUsed2);
62101 zErr = sqlite3_mprintf(
62102 "unable to use function %s in the requested context", zName);
62103 sqlite3_result_error(context, zErr, -1);
62104 sqlite3_free(zErr);
62108 ** Allocate or return the aggregate context for a user function. A new
62109 ** context is allocated on the first call. Subsequent calls return the
62110 ** same context that was returned on prior calls.
62112 SQLITE_API void *sqlite3_aggregate_context(sqlite3_context *p, int nByte){
62113 Mem *pMem;
62114 assert( p && p->pFunc && p->pFunc->xStep );
62115 assert( sqlite3_mutex_held(p->s.db->mutex) );
62116 pMem = p->pMem;
62117 testcase( nByte<0 );
62118 if( (pMem->flags & MEM_Agg)==0 ){
62119 if( nByte<=0 ){
62120 sqlite3VdbeMemReleaseExternal(pMem);
62121 pMem->flags = MEM_Null;
62122 pMem->z = 0;
62123 }else{
62124 sqlite3VdbeMemGrow(pMem, nByte, 0);
62125 pMem->flags = MEM_Agg;
62126 pMem->u.pDef = p->pFunc;
62127 if( pMem->z ){
62128 memset(pMem->z, 0, nByte);
62132 return (void*)pMem->z;
62136 ** Return the auxilary data pointer, if any, for the iArg'th argument to
62137 ** the user-function defined by pCtx.
62139 SQLITE_API void *sqlite3_get_auxdata(sqlite3_context *pCtx, int iArg){
62140 VdbeFunc *pVdbeFunc;
62142 assert( sqlite3_mutex_held(pCtx->s.db->mutex) );
62143 pVdbeFunc = pCtx->pVdbeFunc;
62144 if( !pVdbeFunc || iArg>=pVdbeFunc->nAux || iArg<0 ){
62145 return 0;
62147 return pVdbeFunc->apAux[iArg].pAux;
62151 ** Set the auxilary data pointer and delete function, for the iArg'th
62152 ** argument to the user-function defined by pCtx. Any previous value is
62153 ** deleted by calling the delete function specified when it was set.
62155 SQLITE_API void sqlite3_set_auxdata(
62156 sqlite3_context *pCtx,
62157 int iArg,
62158 void *pAux,
62159 void (*xDelete)(void*)
62161 struct AuxData *pAuxData;
62162 VdbeFunc *pVdbeFunc;
62163 if( iArg<0 ) goto failed;
62165 assert( sqlite3_mutex_held(pCtx->s.db->mutex) );
62166 pVdbeFunc = pCtx->pVdbeFunc;
62167 if( !pVdbeFunc || pVdbeFunc->nAux<=iArg ){
62168 int nAux = (pVdbeFunc ? pVdbeFunc->nAux : 0);
62169 int nMalloc = sizeof(VdbeFunc) + sizeof(struct AuxData)*iArg;
62170 pVdbeFunc = sqlite3DbRealloc(pCtx->s.db, pVdbeFunc, nMalloc);
62171 if( !pVdbeFunc ){
62172 goto failed;
62174 pCtx->pVdbeFunc = pVdbeFunc;
62175 memset(&pVdbeFunc->apAux[nAux], 0, sizeof(struct AuxData)*(iArg+1-nAux));
62176 pVdbeFunc->nAux = iArg+1;
62177 pVdbeFunc->pFunc = pCtx->pFunc;
62180 pAuxData = &pVdbeFunc->apAux[iArg];
62181 if( pAuxData->pAux && pAuxData->xDelete ){
62182 pAuxData->xDelete(pAuxData->pAux);
62184 pAuxData->pAux = pAux;
62185 pAuxData->xDelete = xDelete;
62186 return;
62188 failed:
62189 if( xDelete ){
62190 xDelete(pAux);
62194 #ifndef SQLITE_OMIT_DEPRECATED
62196 ** Return the number of times the Step function of a aggregate has been
62197 ** called.
62199 ** This function is deprecated. Do not use it for new code. It is
62200 ** provide only to avoid breaking legacy code. New aggregate function
62201 ** implementations should keep their own counts within their aggregate
62202 ** context.
62204 SQLITE_API int sqlite3_aggregate_count(sqlite3_context *p){
62205 assert( p && p->pMem && p->pFunc && p->pFunc->xStep );
62206 return p->pMem->n;
62208 #endif
62211 ** Return the number of columns in the result set for the statement pStmt.
62213 SQLITE_API int sqlite3_column_count(sqlite3_stmt *pStmt){
62214 Vdbe *pVm = (Vdbe *)pStmt;
62215 return pVm ? pVm->nResColumn : 0;
62219 ** Return the number of values available from the current row of the
62220 ** currently executing statement pStmt.
62222 SQLITE_API int sqlite3_data_count(sqlite3_stmt *pStmt){
62223 Vdbe *pVm = (Vdbe *)pStmt;
62224 if( pVm==0 || pVm->pResultSet==0 ) return 0;
62225 return pVm->nResColumn;
62230 ** Check to see if column iCol of the given statement is valid. If
62231 ** it is, return a pointer to the Mem for the value of that column.
62232 ** If iCol is not valid, return a pointer to a Mem which has a value
62233 ** of NULL.
62235 static Mem *columnMem(sqlite3_stmt *pStmt, int i){
62236 Vdbe *pVm;
62237 Mem *pOut;
62239 pVm = (Vdbe *)pStmt;
62240 if( pVm && pVm->pResultSet!=0 && i<pVm->nResColumn && i>=0 ){
62241 sqlite3_mutex_enter(pVm->db->mutex);
62242 pOut = &pVm->pResultSet[i];
62243 }else{
62244 /* If the value passed as the second argument is out of range, return
62245 ** a pointer to the following static Mem object which contains the
62246 ** value SQL NULL. Even though the Mem structure contains an element
62247 ** of type i64, on certain architecture (x86) with certain compiler
62248 ** switches (-Os), gcc may align this Mem object on a 4-byte boundary
62249 ** instead of an 8-byte one. This all works fine, except that when
62250 ** running with SQLITE_DEBUG defined the SQLite code sometimes assert()s
62251 ** that a Mem structure is located on an 8-byte boundary. To prevent
62252 ** this assert() from failing, when building with SQLITE_DEBUG defined
62253 ** using gcc, force nullMem to be 8-byte aligned using the magical
62254 ** __attribute__((aligned(8))) macro. */
62255 static const Mem nullMem
62256 #if defined(SQLITE_DEBUG) && defined(__GNUC__)
62257 __attribute__((aligned(8)))
62258 #endif
62259 = {0, "", (double)0, {0}, 0, MEM_Null, SQLITE_NULL, 0,
62260 #ifdef SQLITE_DEBUG
62261 0, 0, /* pScopyFrom, pFiller */
62262 #endif
62263 0, 0 };
62265 if( pVm && ALWAYS(pVm->db) ){
62266 sqlite3_mutex_enter(pVm->db->mutex);
62267 sqlite3Error(pVm->db, SQLITE_RANGE, 0);
62269 pOut = (Mem*)&nullMem;
62271 return pOut;
62275 ** This function is called after invoking an sqlite3_value_XXX function on a
62276 ** column value (i.e. a value returned by evaluating an SQL expression in the
62277 ** select list of a SELECT statement) that may cause a malloc() failure. If
62278 ** malloc() has failed, the threads mallocFailed flag is cleared and the result
62279 ** code of statement pStmt set to SQLITE_NOMEM.
62281 ** Specifically, this is called from within:
62283 ** sqlite3_column_int()
62284 ** sqlite3_column_int64()
62285 ** sqlite3_column_text()
62286 ** sqlite3_column_text16()
62287 ** sqlite3_column_real()
62288 ** sqlite3_column_bytes()
62289 ** sqlite3_column_bytes16()
62290 ** sqiite3_column_blob()
62292 static void columnMallocFailure(sqlite3_stmt *pStmt)
62294 /* If malloc() failed during an encoding conversion within an
62295 ** sqlite3_column_XXX API, then set the return code of the statement to
62296 ** SQLITE_NOMEM. The next call to _step() (if any) will return SQLITE_ERROR
62297 ** and _finalize() will return NOMEM.
62299 Vdbe *p = (Vdbe *)pStmt;
62300 if( p ){
62301 p->rc = sqlite3ApiExit(p->db, p->rc);
62302 sqlite3_mutex_leave(p->db->mutex);
62306 /**************************** sqlite3_column_ *******************************
62307 ** The following routines are used to access elements of the current row
62308 ** in the result set.
62310 SQLITE_API const void *sqlite3_column_blob(sqlite3_stmt *pStmt, int i){
62311 const void *val;
62312 val = sqlite3_value_blob( columnMem(pStmt,i) );
62313 /* Even though there is no encoding conversion, value_blob() might
62314 ** need to call malloc() to expand the result of a zeroblob()
62315 ** expression.
62317 columnMallocFailure(pStmt);
62318 return val;
62320 SQLITE_API int sqlite3_column_bytes(sqlite3_stmt *pStmt, int i){
62321 int val = sqlite3_value_bytes( columnMem(pStmt,i) );
62322 columnMallocFailure(pStmt);
62323 return val;
62325 SQLITE_API int sqlite3_column_bytes16(sqlite3_stmt *pStmt, int i){
62326 int val = sqlite3_value_bytes16( columnMem(pStmt,i) );
62327 columnMallocFailure(pStmt);
62328 return val;
62330 SQLITE_API double sqlite3_column_double(sqlite3_stmt *pStmt, int i){
62331 double val = sqlite3_value_double( columnMem(pStmt,i) );
62332 columnMallocFailure(pStmt);
62333 return val;
62335 SQLITE_API int sqlite3_column_int(sqlite3_stmt *pStmt, int i){
62336 int val = sqlite3_value_int( columnMem(pStmt,i) );
62337 columnMallocFailure(pStmt);
62338 return val;
62340 SQLITE_API sqlite_int64 sqlite3_column_int64(sqlite3_stmt *pStmt, int i){
62341 sqlite_int64 val = sqlite3_value_int64( columnMem(pStmt,i) );
62342 columnMallocFailure(pStmt);
62343 return val;
62345 SQLITE_API const unsigned char *sqlite3_column_text(sqlite3_stmt *pStmt, int i){
62346 const unsigned char *val = sqlite3_value_text( columnMem(pStmt,i) );
62347 columnMallocFailure(pStmt);
62348 return val;
62350 SQLITE_API sqlite3_value *sqlite3_column_value(sqlite3_stmt *pStmt, int i){
62351 Mem *pOut = columnMem(pStmt, i);
62352 if( pOut->flags&MEM_Static ){
62353 pOut->flags &= ~MEM_Static;
62354 pOut->flags |= MEM_Ephem;
62356 columnMallocFailure(pStmt);
62357 return (sqlite3_value *)pOut;
62359 #ifndef SQLITE_OMIT_UTF16
62360 SQLITE_API const void *sqlite3_column_text16(sqlite3_stmt *pStmt, int i){
62361 const void *val = sqlite3_value_text16( columnMem(pStmt,i) );
62362 columnMallocFailure(pStmt);
62363 return val;
62365 #endif /* SQLITE_OMIT_UTF16 */
62366 SQLITE_API int sqlite3_column_type(sqlite3_stmt *pStmt, int i){
62367 int iType = sqlite3_value_type( columnMem(pStmt,i) );
62368 columnMallocFailure(pStmt);
62369 return iType;
62372 /* The following function is experimental and subject to change or
62373 ** removal */
62374 /*int sqlite3_column_numeric_type(sqlite3_stmt *pStmt, int i){
62375 ** return sqlite3_value_numeric_type( columnMem(pStmt,i) );
62380 ** Convert the N-th element of pStmt->pColName[] into a string using
62381 ** xFunc() then return that string. If N is out of range, return 0.
62383 ** There are up to 5 names for each column. useType determines which
62384 ** name is returned. Here are the names:
62386 ** 0 The column name as it should be displayed for output
62387 ** 1 The datatype name for the column
62388 ** 2 The name of the database that the column derives from
62389 ** 3 The name of the table that the column derives from
62390 ** 4 The name of the table column that the result column derives from
62392 ** If the result is not a simple column reference (if it is an expression
62393 ** or a constant) then useTypes 2, 3, and 4 return NULL.
62395 static const void *columnName(
62396 sqlite3_stmt *pStmt,
62397 int N,
62398 const void *(*xFunc)(Mem*),
62399 int useType
62401 const void *ret = 0;
62402 Vdbe *p = (Vdbe *)pStmt;
62403 int n;
62404 sqlite3 *db = p->db;
62406 assert( db!=0 );
62407 n = sqlite3_column_count(pStmt);
62408 if( N<n && N>=0 ){
62409 N += useType*n;
62410 sqlite3_mutex_enter(db->mutex);
62411 assert( db->mallocFailed==0 );
62412 ret = xFunc(&p->aColName[N]);
62413 /* A malloc may have failed inside of the xFunc() call. If this
62414 ** is the case, clear the mallocFailed flag and return NULL.
62416 if( db->mallocFailed ){
62417 db->mallocFailed = 0;
62418 ret = 0;
62420 sqlite3_mutex_leave(db->mutex);
62422 return ret;
62426 ** Return the name of the Nth column of the result set returned by SQL
62427 ** statement pStmt.
62429 SQLITE_API const char *sqlite3_column_name(sqlite3_stmt *pStmt, int N){
62430 return columnName(
62431 pStmt, N, (const void*(*)(Mem*))sqlite3_value_text, COLNAME_NAME);
62433 #ifndef SQLITE_OMIT_UTF16
62434 SQLITE_API const void *sqlite3_column_name16(sqlite3_stmt *pStmt, int N){
62435 return columnName(
62436 pStmt, N, (const void*(*)(Mem*))sqlite3_value_text16, COLNAME_NAME);
62438 #endif
62441 ** Constraint: If you have ENABLE_COLUMN_METADATA then you must
62442 ** not define OMIT_DECLTYPE.
62444 #if defined(SQLITE_OMIT_DECLTYPE) && defined(SQLITE_ENABLE_COLUMN_METADATA)
62445 # error "Must not define both SQLITE_OMIT_DECLTYPE \
62446 and SQLITE_ENABLE_COLUMN_METADATA"
62447 #endif
62449 #ifndef SQLITE_OMIT_DECLTYPE
62451 ** Return the column declaration type (if applicable) of the 'i'th column
62452 ** of the result set of SQL statement pStmt.
62454 SQLITE_API const char *sqlite3_column_decltype(sqlite3_stmt *pStmt, int N){
62455 return columnName(
62456 pStmt, N, (const void*(*)(Mem*))sqlite3_value_text, COLNAME_DECLTYPE);
62458 #ifndef SQLITE_OMIT_UTF16
62459 SQLITE_API const void *sqlite3_column_decltype16(sqlite3_stmt *pStmt, int N){
62460 return columnName(
62461 pStmt, N, (const void*(*)(Mem*))sqlite3_value_text16, COLNAME_DECLTYPE);
62463 #endif /* SQLITE_OMIT_UTF16 */
62464 #endif /* SQLITE_OMIT_DECLTYPE */
62466 #ifdef SQLITE_ENABLE_COLUMN_METADATA
62468 ** Return the name of the database from which a result column derives.
62469 ** NULL is returned if the result column is an expression or constant or
62470 ** anything else which is not an unabiguous reference to a database column.
62472 SQLITE_API const char *sqlite3_column_database_name(sqlite3_stmt *pStmt, int N){
62473 return columnName(
62474 pStmt, N, (const void*(*)(Mem*))sqlite3_value_text, COLNAME_DATABASE);
62476 #ifndef SQLITE_OMIT_UTF16
62477 SQLITE_API const void *sqlite3_column_database_name16(sqlite3_stmt *pStmt, int N){
62478 return columnName(
62479 pStmt, N, (const void*(*)(Mem*))sqlite3_value_text16, COLNAME_DATABASE);
62481 #endif /* SQLITE_OMIT_UTF16 */
62484 ** Return the name of the table from which a result column derives.
62485 ** NULL is returned if the result column is an expression or constant or
62486 ** anything else which is not an unabiguous reference to a database column.
62488 SQLITE_API const char *sqlite3_column_table_name(sqlite3_stmt *pStmt, int N){
62489 return columnName(
62490 pStmt, N, (const void*(*)(Mem*))sqlite3_value_text, COLNAME_TABLE);
62492 #ifndef SQLITE_OMIT_UTF16
62493 SQLITE_API const void *sqlite3_column_table_name16(sqlite3_stmt *pStmt, int N){
62494 return columnName(
62495 pStmt, N, (const void*(*)(Mem*))sqlite3_value_text16, COLNAME_TABLE);
62497 #endif /* SQLITE_OMIT_UTF16 */
62500 ** Return the name of the table column from which a result column derives.
62501 ** NULL is returned if the result column is an expression or constant or
62502 ** anything else which is not an unabiguous reference to a database column.
62504 SQLITE_API const char *sqlite3_column_origin_name(sqlite3_stmt *pStmt, int N){
62505 return columnName(
62506 pStmt, N, (const void*(*)(Mem*))sqlite3_value_text, COLNAME_COLUMN);
62508 #ifndef SQLITE_OMIT_UTF16
62509 SQLITE_API const void *sqlite3_column_origin_name16(sqlite3_stmt *pStmt, int N){
62510 return columnName(
62511 pStmt, N, (const void*(*)(Mem*))sqlite3_value_text16, COLNAME_COLUMN);
62513 #endif /* SQLITE_OMIT_UTF16 */
62514 #endif /* SQLITE_ENABLE_COLUMN_METADATA */
62517 /******************************* sqlite3_bind_ ***************************
62519 ** Routines used to attach values to wildcards in a compiled SQL statement.
62522 ** Unbind the value bound to variable i in virtual machine p. This is the
62523 ** the same as binding a NULL value to the column. If the "i" parameter is
62524 ** out of range, then SQLITE_RANGE is returned. Othewise SQLITE_OK.
62526 ** A successful evaluation of this routine acquires the mutex on p.
62527 ** the mutex is released if any kind of error occurs.
62529 ** The error code stored in database p->db is overwritten with the return
62530 ** value in any case.
62532 static int vdbeUnbind(Vdbe *p, int i){
62533 Mem *pVar;
62534 if( vdbeSafetyNotNull(p) ){
62535 return SQLITE_MISUSE_BKPT;
62537 sqlite3_mutex_enter(p->db->mutex);
62538 if( p->magic!=VDBE_MAGIC_RUN || p->pc>=0 ){
62539 sqlite3Error(p->db, SQLITE_MISUSE, 0);
62540 sqlite3_mutex_leave(p->db->mutex);
62541 sqlite3_log(SQLITE_MISUSE,
62542 "bind on a busy prepared statement: [%s]", p->zSql);
62543 return SQLITE_MISUSE_BKPT;
62545 if( i<1 || i>p->nVar ){
62546 sqlite3Error(p->db, SQLITE_RANGE, 0);
62547 sqlite3_mutex_leave(p->db->mutex);
62548 return SQLITE_RANGE;
62550 i--;
62551 pVar = &p->aVar[i];
62552 sqlite3VdbeMemRelease(pVar);
62553 pVar->flags = MEM_Null;
62554 sqlite3Error(p->db, SQLITE_OK, 0);
62556 /* If the bit corresponding to this variable in Vdbe.expmask is set, then
62557 ** binding a new value to this variable invalidates the current query plan.
62559 ** IMPLEMENTATION-OF: R-48440-37595 If the specific value bound to host
62560 ** parameter in the WHERE clause might influence the choice of query plan
62561 ** for a statement, then the statement will be automatically recompiled,
62562 ** as if there had been a schema change, on the first sqlite3_step() call
62563 ** following any change to the bindings of that parameter.
62565 if( p->isPrepareV2 &&
62566 ((i<32 && p->expmask & ((u32)1 << i)) || p->expmask==0xffffffff)
62568 p->expired = 1;
62570 return SQLITE_OK;
62574 ** Bind a text or BLOB value.
62576 static int bindText(
62577 sqlite3_stmt *pStmt, /* The statement to bind against */
62578 int i, /* Index of the parameter to bind */
62579 const void *zData, /* Pointer to the data to be bound */
62580 int nData, /* Number of bytes of data to be bound */
62581 void (*xDel)(void*), /* Destructor for the data */
62582 u8 encoding /* Encoding for the data */
62584 Vdbe *p = (Vdbe *)pStmt;
62585 Mem *pVar;
62586 int rc;
62588 rc = vdbeUnbind(p, i);
62589 if( rc==SQLITE_OK ){
62590 if( zData!=0 ){
62591 pVar = &p->aVar[i-1];
62592 rc = sqlite3VdbeMemSetStr(pVar, zData, nData, encoding, xDel);
62593 if( rc==SQLITE_OK && encoding!=0 ){
62594 rc = sqlite3VdbeChangeEncoding(pVar, ENC(p->db));
62596 sqlite3Error(p->db, rc, 0);
62597 rc = sqlite3ApiExit(p->db, rc);
62599 sqlite3_mutex_leave(p->db->mutex);
62600 }else if( xDel!=SQLITE_STATIC && xDel!=SQLITE_TRANSIENT ){
62601 xDel((void*)zData);
62603 return rc;
62608 ** Bind a blob value to an SQL statement variable.
62610 SQLITE_API int sqlite3_bind_blob(
62611 sqlite3_stmt *pStmt,
62612 int i,
62613 const void *zData,
62614 int nData,
62615 void (*xDel)(void*)
62617 return bindText(pStmt, i, zData, nData, xDel, 0);
62619 SQLITE_API int sqlite3_bind_double(sqlite3_stmt *pStmt, int i, double rValue){
62620 int rc;
62621 Vdbe *p = (Vdbe *)pStmt;
62622 rc = vdbeUnbind(p, i);
62623 if( rc==SQLITE_OK ){
62624 sqlite3VdbeMemSetDouble(&p->aVar[i-1], rValue);
62625 sqlite3_mutex_leave(p->db->mutex);
62627 return rc;
62629 SQLITE_API int sqlite3_bind_int(sqlite3_stmt *p, int i, int iValue){
62630 return sqlite3_bind_int64(p, i, (i64)iValue);
62632 SQLITE_API int sqlite3_bind_int64(sqlite3_stmt *pStmt, int i, sqlite_int64 iValue){
62633 int rc;
62634 Vdbe *p = (Vdbe *)pStmt;
62635 rc = vdbeUnbind(p, i);
62636 if( rc==SQLITE_OK ){
62637 sqlite3VdbeMemSetInt64(&p->aVar[i-1], iValue);
62638 sqlite3_mutex_leave(p->db->mutex);
62640 return rc;
62642 SQLITE_API int sqlite3_bind_null(sqlite3_stmt *pStmt, int i){
62643 int rc;
62644 Vdbe *p = (Vdbe*)pStmt;
62645 rc = vdbeUnbind(p, i);
62646 if( rc==SQLITE_OK ){
62647 sqlite3_mutex_leave(p->db->mutex);
62649 return rc;
62651 SQLITE_API int sqlite3_bind_text(
62652 sqlite3_stmt *pStmt,
62653 int i,
62654 const char *zData,
62655 int nData,
62656 void (*xDel)(void*)
62658 return bindText(pStmt, i, zData, nData, xDel, SQLITE_UTF8);
62660 #ifndef SQLITE_OMIT_UTF16
62661 SQLITE_API int sqlite3_bind_text16(
62662 sqlite3_stmt *pStmt,
62663 int i,
62664 const void *zData,
62665 int nData,
62666 void (*xDel)(void*)
62668 return bindText(pStmt, i, zData, nData, xDel, SQLITE_UTF16NATIVE);
62670 #endif /* SQLITE_OMIT_UTF16 */
62671 SQLITE_API int sqlite3_bind_value(sqlite3_stmt *pStmt, int i, const sqlite3_value *pValue){
62672 int rc;
62673 switch( pValue->type ){
62674 case SQLITE_INTEGER: {
62675 rc = sqlite3_bind_int64(pStmt, i, pValue->u.i);
62676 break;
62678 case SQLITE_FLOAT: {
62679 rc = sqlite3_bind_double(pStmt, i, pValue->r);
62680 break;
62682 case SQLITE_BLOB: {
62683 if( pValue->flags & MEM_Zero ){
62684 rc = sqlite3_bind_zeroblob(pStmt, i, pValue->u.nZero);
62685 }else{
62686 rc = sqlite3_bind_blob(pStmt, i, pValue->z, pValue->n,SQLITE_TRANSIENT);
62688 break;
62690 case SQLITE_TEXT: {
62691 rc = bindText(pStmt,i, pValue->z, pValue->n, SQLITE_TRANSIENT,
62692 pValue->enc);
62693 break;
62695 default: {
62696 rc = sqlite3_bind_null(pStmt, i);
62697 break;
62700 return rc;
62702 SQLITE_API int sqlite3_bind_zeroblob(sqlite3_stmt *pStmt, int i, int n){
62703 int rc;
62704 Vdbe *p = (Vdbe *)pStmt;
62705 rc = vdbeUnbind(p, i);
62706 if( rc==SQLITE_OK ){
62707 sqlite3VdbeMemSetZeroBlob(&p->aVar[i-1], n);
62708 sqlite3_mutex_leave(p->db->mutex);
62710 return rc;
62714 ** Return the number of wildcards that can be potentially bound to.
62715 ** This routine is added to support DBD::SQLite.
62717 SQLITE_API int sqlite3_bind_parameter_count(sqlite3_stmt *pStmt){
62718 Vdbe *p = (Vdbe*)pStmt;
62719 return p ? p->nVar : 0;
62723 ** Return the name of a wildcard parameter. Return NULL if the index
62724 ** is out of range or if the wildcard is unnamed.
62726 ** The result is always UTF-8.
62728 SQLITE_API const char *sqlite3_bind_parameter_name(sqlite3_stmt *pStmt, int i){
62729 Vdbe *p = (Vdbe*)pStmt;
62730 if( p==0 || i<1 || i>p->nzVar ){
62731 return 0;
62733 return p->azVar[i-1];
62737 ** Given a wildcard parameter name, return the index of the variable
62738 ** with that name. If there is no variable with the given name,
62739 ** return 0.
62741 SQLITE_PRIVATE int sqlite3VdbeParameterIndex(Vdbe *p, const char *zName, int nName){
62742 int i;
62743 if( p==0 ){
62744 return 0;
62746 if( zName ){
62747 for(i=0; i<p->nzVar; i++){
62748 const char *z = p->azVar[i];
62749 if( z && memcmp(z,zName,nName)==0 && z[nName]==0 ){
62750 return i+1;
62754 return 0;
62756 SQLITE_API int sqlite3_bind_parameter_index(sqlite3_stmt *pStmt, const char *zName){
62757 return sqlite3VdbeParameterIndex((Vdbe*)pStmt, zName, sqlite3Strlen30(zName));
62761 ** Transfer all bindings from the first statement over to the second.
62763 SQLITE_PRIVATE int sqlite3TransferBindings(sqlite3_stmt *pFromStmt, sqlite3_stmt *pToStmt){
62764 Vdbe *pFrom = (Vdbe*)pFromStmt;
62765 Vdbe *pTo = (Vdbe*)pToStmt;
62766 int i;
62767 assert( pTo->db==pFrom->db );
62768 assert( pTo->nVar==pFrom->nVar );
62769 sqlite3_mutex_enter(pTo->db->mutex);
62770 for(i=0; i<pFrom->nVar; i++){
62771 sqlite3VdbeMemMove(&pTo->aVar[i], &pFrom->aVar[i]);
62773 sqlite3_mutex_leave(pTo->db->mutex);
62774 return SQLITE_OK;
62777 #ifndef SQLITE_OMIT_DEPRECATED
62779 ** Deprecated external interface. Internal/core SQLite code
62780 ** should call sqlite3TransferBindings.
62782 ** Is is misuse to call this routine with statements from different
62783 ** database connections. But as this is a deprecated interface, we
62784 ** will not bother to check for that condition.
62786 ** If the two statements contain a different number of bindings, then
62787 ** an SQLITE_ERROR is returned. Nothing else can go wrong, so otherwise
62788 ** SQLITE_OK is returned.
62790 SQLITE_API int sqlite3_transfer_bindings(sqlite3_stmt *pFromStmt, sqlite3_stmt *pToStmt){
62791 Vdbe *pFrom = (Vdbe*)pFromStmt;
62792 Vdbe *pTo = (Vdbe*)pToStmt;
62793 if( pFrom->nVar!=pTo->nVar ){
62794 return SQLITE_ERROR;
62796 if( pTo->isPrepareV2 && pTo->expmask ){
62797 pTo->expired = 1;
62799 if( pFrom->isPrepareV2 && pFrom->expmask ){
62800 pFrom->expired = 1;
62802 return sqlite3TransferBindings(pFromStmt, pToStmt);
62804 #endif
62807 ** Return the sqlite3* database handle to which the prepared statement given
62808 ** in the argument belongs. This is the same database handle that was
62809 ** the first argument to the sqlite3_prepare() that was used to create
62810 ** the statement in the first place.
62812 SQLITE_API sqlite3 *sqlite3_db_handle(sqlite3_stmt *pStmt){
62813 return pStmt ? ((Vdbe*)pStmt)->db : 0;
62817 ** Return true if the prepared statement is guaranteed to not modify the
62818 ** database.
62820 SQLITE_API int sqlite3_stmt_readonly(sqlite3_stmt *pStmt){
62821 return pStmt ? ((Vdbe*)pStmt)->readOnly : 1;
62825 ** Return a pointer to the next prepared statement after pStmt associated
62826 ** with database connection pDb. If pStmt is NULL, return the first
62827 ** prepared statement for the database connection. Return NULL if there
62828 ** are no more.
62830 SQLITE_API sqlite3_stmt *sqlite3_next_stmt(sqlite3 *pDb, sqlite3_stmt *pStmt){
62831 sqlite3_stmt *pNext;
62832 sqlite3_mutex_enter(pDb->mutex);
62833 if( pStmt==0 ){
62834 pNext = (sqlite3_stmt*)pDb->pVdbe;
62835 }else{
62836 pNext = (sqlite3_stmt*)((Vdbe*)pStmt)->pNext;
62838 sqlite3_mutex_leave(pDb->mutex);
62839 return pNext;
62843 ** Return the value of a status counter for a prepared statement
62845 SQLITE_API int sqlite3_stmt_status(sqlite3_stmt *pStmt, int op, int resetFlag){
62846 Vdbe *pVdbe = (Vdbe*)pStmt;
62847 int v = pVdbe->aCounter[op-1];
62848 if( resetFlag ) pVdbe->aCounter[op-1] = 0;
62849 return v;
62852 /************** End of vdbeapi.c *********************************************/
62853 /************** Begin file vdbetrace.c ***************************************/
62855 ** 2009 November 25
62857 ** The author disclaims copyright to this source code. In place of
62858 ** a legal notice, here is a blessing:
62860 ** May you do good and not evil.
62861 ** May you find forgiveness for yourself and forgive others.
62862 ** May you share freely, never taking more than you give.
62864 *************************************************************************
62866 ** This file contains code used to insert the values of host parameters
62867 ** (aka "wildcards") into the SQL text output by sqlite3_trace().
62870 #ifndef SQLITE_OMIT_TRACE
62873 ** zSql is a zero-terminated string of UTF-8 SQL text. Return the number of
62874 ** bytes in this text up to but excluding the first character in
62875 ** a host parameter. If the text contains no host parameters, return
62876 ** the total number of bytes in the text.
62878 static int findNextHostParameter(const char *zSql, int *pnToken){
62879 int tokenType;
62880 int nTotal = 0;
62881 int n;
62883 *pnToken = 0;
62884 while( zSql[0] ){
62885 n = sqlite3GetToken((u8*)zSql, &tokenType);
62886 assert( n>0 && tokenType!=TK_ILLEGAL );
62887 if( tokenType==TK_VARIABLE ){
62888 *pnToken = n;
62889 break;
62891 nTotal += n;
62892 zSql += n;
62894 return nTotal;
62898 ** This function returns a pointer to a nul-terminated string in memory
62899 ** obtained from sqlite3DbMalloc(). If sqlite3.vdbeExecCnt is 1, then the
62900 ** string contains a copy of zRawSql but with host parameters expanded to
62901 ** their current bindings. Or, if sqlite3.vdbeExecCnt is greater than 1,
62902 ** then the returned string holds a copy of zRawSql with "-- " prepended
62903 ** to each line of text.
62905 ** The calling function is responsible for making sure the memory returned
62906 ** is eventually freed.
62908 ** ALGORITHM: Scan the input string looking for host parameters in any of
62909 ** these forms: ?, ?N, $A, @A, :A. Take care to avoid text within
62910 ** string literals, quoted identifier names, and comments. For text forms,
62911 ** the host parameter index is found by scanning the perpared
62912 ** statement for the corresponding OP_Variable opcode. Once the host
62913 ** parameter index is known, locate the value in p->aVar[]. Then render
62914 ** the value as a literal in place of the host parameter name.
62916 SQLITE_PRIVATE char *sqlite3VdbeExpandSql(
62917 Vdbe *p, /* The prepared statement being evaluated */
62918 const char *zRawSql /* Raw text of the SQL statement */
62920 sqlite3 *db; /* The database connection */
62921 int idx = 0; /* Index of a host parameter */
62922 int nextIndex = 1; /* Index of next ? host parameter */
62923 int n; /* Length of a token prefix */
62924 int nToken; /* Length of the parameter token */
62925 int i; /* Loop counter */
62926 Mem *pVar; /* Value of a host parameter */
62927 StrAccum out; /* Accumulate the output here */
62928 char zBase[100]; /* Initial working space */
62930 db = p->db;
62931 sqlite3StrAccumInit(&out, zBase, sizeof(zBase),
62932 db->aLimit[SQLITE_LIMIT_LENGTH]);
62933 out.db = db;
62934 if( db->vdbeExecCnt>1 ){
62935 while( *zRawSql ){
62936 const char *zStart = zRawSql;
62937 while( *(zRawSql++)!='\n' && *zRawSql );
62938 sqlite3StrAccumAppend(&out, "-- ", 3);
62939 sqlite3StrAccumAppend(&out, zStart, (int)(zRawSql-zStart));
62941 }else{
62942 while( zRawSql[0] ){
62943 n = findNextHostParameter(zRawSql, &nToken);
62944 assert( n>0 );
62945 sqlite3StrAccumAppend(&out, zRawSql, n);
62946 zRawSql += n;
62947 assert( zRawSql[0] || nToken==0 );
62948 if( nToken==0 ) break;
62949 if( zRawSql[0]=='?' ){
62950 if( nToken>1 ){
62951 assert( sqlite3Isdigit(zRawSql[1]) );
62952 sqlite3GetInt32(&zRawSql[1], &idx);
62953 }else{
62954 idx = nextIndex;
62956 }else{
62957 assert( zRawSql[0]==':' || zRawSql[0]=='$' || zRawSql[0]=='@' );
62958 testcase( zRawSql[0]==':' );
62959 testcase( zRawSql[0]=='$' );
62960 testcase( zRawSql[0]=='@' );
62961 idx = sqlite3VdbeParameterIndex(p, zRawSql, nToken);
62962 assert( idx>0 );
62964 zRawSql += nToken;
62965 nextIndex = idx + 1;
62966 assert( idx>0 && idx<=p->nVar );
62967 pVar = &p->aVar[idx-1];
62968 if( pVar->flags & MEM_Null ){
62969 sqlite3StrAccumAppend(&out, "NULL", 4);
62970 }else if( pVar->flags & MEM_Int ){
62971 sqlite3XPrintf(&out, "%lld", pVar->u.i);
62972 }else if( pVar->flags & MEM_Real ){
62973 sqlite3XPrintf(&out, "%!.15g", pVar->r);
62974 }else if( pVar->flags & MEM_Str ){
62975 #ifndef SQLITE_OMIT_UTF16
62976 u8 enc = ENC(db);
62977 if( enc!=SQLITE_UTF8 ){
62978 Mem utf8;
62979 memset(&utf8, 0, sizeof(utf8));
62980 utf8.db = db;
62981 sqlite3VdbeMemSetStr(&utf8, pVar->z, pVar->n, enc, SQLITE_STATIC);
62982 sqlite3VdbeChangeEncoding(&utf8, SQLITE_UTF8);
62983 sqlite3XPrintf(&out, "'%.*q'", utf8.n, utf8.z);
62984 sqlite3VdbeMemRelease(&utf8);
62985 }else
62986 #endif
62988 sqlite3XPrintf(&out, "'%.*q'", pVar->n, pVar->z);
62990 }else if( pVar->flags & MEM_Zero ){
62991 sqlite3XPrintf(&out, "zeroblob(%d)", pVar->u.nZero);
62992 }else{
62993 assert( pVar->flags & MEM_Blob );
62994 sqlite3StrAccumAppend(&out, "x'", 2);
62995 for(i=0; i<pVar->n; i++){
62996 sqlite3XPrintf(&out, "%02x", pVar->z[i]&0xff);
62998 sqlite3StrAccumAppend(&out, "'", 1);
63002 return sqlite3StrAccumFinish(&out);
63005 #endif /* #ifndef SQLITE_OMIT_TRACE */
63007 /************** End of vdbetrace.c *******************************************/
63008 /************** Begin file vdbe.c ********************************************/
63010 ** 2001 September 15
63012 ** The author disclaims copyright to this source code. In place of
63013 ** a legal notice, here is a blessing:
63015 ** May you do good and not evil.
63016 ** May you find forgiveness for yourself and forgive others.
63017 ** May you share freely, never taking more than you give.
63019 *************************************************************************
63020 ** The code in this file implements execution method of the
63021 ** Virtual Database Engine (VDBE). A separate file ("vdbeaux.c")
63022 ** handles housekeeping details such as creating and deleting
63023 ** VDBE instances. This file is solely interested in executing
63024 ** the VDBE program.
63026 ** In the external interface, an "sqlite3_stmt*" is an opaque pointer
63027 ** to a VDBE.
63029 ** The SQL parser generates a program which is then executed by
63030 ** the VDBE to do the work of the SQL statement. VDBE programs are
63031 ** similar in form to assembly language. The program consists of
63032 ** a linear sequence of operations. Each operation has an opcode
63033 ** and 5 operands. Operands P1, P2, and P3 are integers. Operand P4
63034 ** is a null-terminated string. Operand P5 is an unsigned character.
63035 ** Few opcodes use all 5 operands.
63037 ** Computation results are stored on a set of registers numbered beginning
63038 ** with 1 and going up to Vdbe.nMem. Each register can store
63039 ** either an integer, a null-terminated string, a floating point
63040 ** number, or the SQL "NULL" value. An implicit conversion from one
63041 ** type to the other occurs as necessary.
63043 ** Most of the code in this file is taken up by the sqlite3VdbeExec()
63044 ** function which does the work of interpreting a VDBE program.
63045 ** But other routines are also provided to help in building up
63046 ** a program instruction by instruction.
63048 ** Various scripts scan this source file in order to generate HTML
63049 ** documentation, headers files, or other derived files. The formatting
63050 ** of the code in this file is, therefore, important. See other comments
63051 ** in this file for details. If in doubt, do not deviate from existing
63052 ** commenting and indentation practices when changing or adding code.
63056 ** Invoke this macro on memory cells just prior to changing the
63057 ** value of the cell. This macro verifies that shallow copies are
63058 ** not misused.
63060 #ifdef SQLITE_DEBUG
63061 # define memAboutToChange(P,M) sqlite3VdbeMemPrepareToChange(P,M)
63062 #else
63063 # define memAboutToChange(P,M)
63064 #endif
63067 ** The following global variable is incremented every time a cursor
63068 ** moves, either by the OP_SeekXX, OP_Next, or OP_Prev opcodes. The test
63069 ** procedures use this information to make sure that indices are
63070 ** working correctly. This variable has no function other than to
63071 ** help verify the correct operation of the library.
63073 #ifdef SQLITE_TEST
63074 SQLITE_API int sqlite3_search_count = 0;
63075 #endif
63078 ** When this global variable is positive, it gets decremented once before
63079 ** each instruction in the VDBE. When reaches zero, the u1.isInterrupted
63080 ** field of the sqlite3 structure is set in order to simulate and interrupt.
63082 ** This facility is used for testing purposes only. It does not function
63083 ** in an ordinary build.
63085 #ifdef SQLITE_TEST
63086 SQLITE_API int sqlite3_interrupt_count = 0;
63087 #endif
63090 ** The next global variable is incremented each type the OP_Sort opcode
63091 ** is executed. The test procedures use this information to make sure that
63092 ** sorting is occurring or not occurring at appropriate times. This variable
63093 ** has no function other than to help verify the correct operation of the
63094 ** library.
63096 #ifdef SQLITE_TEST
63097 SQLITE_API int sqlite3_sort_count = 0;
63098 #endif
63101 ** The next global variable records the size of the largest MEM_Blob
63102 ** or MEM_Str that has been used by a VDBE opcode. The test procedures
63103 ** use this information to make sure that the zero-blob functionality
63104 ** is working correctly. This variable has no function other than to
63105 ** help verify the correct operation of the library.
63107 #ifdef SQLITE_TEST
63108 SQLITE_API int sqlite3_max_blobsize = 0;
63109 static void updateMaxBlobsize(Mem *p){
63110 if( (p->flags & (MEM_Str|MEM_Blob))!=0 && p->n>sqlite3_max_blobsize ){
63111 sqlite3_max_blobsize = p->n;
63114 #endif
63117 ** The next global variable is incremented each type the OP_Found opcode
63118 ** is executed. This is used to test whether or not the foreign key
63119 ** operation implemented using OP_FkIsZero is working. This variable
63120 ** has no function other than to help verify the correct operation of the
63121 ** library.
63123 #ifdef SQLITE_TEST
63124 SQLITE_API int sqlite3_found_count = 0;
63125 #endif
63128 ** Test a register to see if it exceeds the current maximum blob size.
63129 ** If it does, record the new maximum blob size.
63131 #if defined(SQLITE_TEST) && !defined(SQLITE_OMIT_BUILTIN_TEST)
63132 # define UPDATE_MAX_BLOBSIZE(P) updateMaxBlobsize(P)
63133 #else
63134 # define UPDATE_MAX_BLOBSIZE(P)
63135 #endif
63138 ** Convert the given register into a string if it isn't one
63139 ** already. Return non-zero if a malloc() fails.
63141 #define Stringify(P, enc) \
63142 if(((P)->flags&(MEM_Str|MEM_Blob))==0 && sqlite3VdbeMemStringify(P,enc)) \
63143 { goto no_mem; }
63146 ** An ephemeral string value (signified by the MEM_Ephem flag) contains
63147 ** a pointer to a dynamically allocated string where some other entity
63148 ** is responsible for deallocating that string. Because the register
63149 ** does not control the string, it might be deleted without the register
63150 ** knowing it.
63152 ** This routine converts an ephemeral string into a dynamically allocated
63153 ** string that the register itself controls. In other words, it
63154 ** converts an MEM_Ephem string into an MEM_Dyn string.
63156 #define Deephemeralize(P) \
63157 if( ((P)->flags&MEM_Ephem)!=0 \
63158 && sqlite3VdbeMemMakeWriteable(P) ){ goto no_mem;}
63161 ** Call sqlite3VdbeMemExpandBlob() on the supplied value (type Mem*)
63162 ** P if required.
63164 #define ExpandBlob(P) (((P)->flags&MEM_Zero)?sqlite3VdbeMemExpandBlob(P):0)
63166 /* Return true if the cursor was opened using the OP_OpenSorter opcode. */
63167 #ifdef SQLITE_OMIT_MERGE_SORT
63168 # define isSorter(x) 0
63169 #else
63170 # define isSorter(x) ((x)->pSorter!=0)
63171 #endif
63174 ** Argument pMem points at a register that will be passed to a
63175 ** user-defined function or returned to the user as the result of a query.
63176 ** This routine sets the pMem->type variable used by the sqlite3_value_*()
63177 ** routines.
63179 SQLITE_PRIVATE void sqlite3VdbeMemStoreType(Mem *pMem){
63180 int flags = pMem->flags;
63181 if( flags & MEM_Null ){
63182 pMem->type = SQLITE_NULL;
63184 else if( flags & MEM_Int ){
63185 pMem->type = SQLITE_INTEGER;
63187 else if( flags & MEM_Real ){
63188 pMem->type = SQLITE_FLOAT;
63190 else if( flags & MEM_Str ){
63191 pMem->type = SQLITE_TEXT;
63192 }else{
63193 pMem->type = SQLITE_BLOB;
63198 ** Allocate VdbeCursor number iCur. Return a pointer to it. Return NULL
63199 ** if we run out of memory.
63201 static VdbeCursor *allocateCursor(
63202 Vdbe *p, /* The virtual machine */
63203 int iCur, /* Index of the new VdbeCursor */
63204 int nField, /* Number of fields in the table or index */
63205 int iDb, /* When database the cursor belongs to, or -1 */
63206 int isBtreeCursor /* True for B-Tree. False for pseudo-table or vtab */
63208 /* Find the memory cell that will be used to store the blob of memory
63209 ** required for this VdbeCursor structure. It is convenient to use a
63210 ** vdbe memory cell to manage the memory allocation required for a
63211 ** VdbeCursor structure for the following reasons:
63213 ** * Sometimes cursor numbers are used for a couple of different
63214 ** purposes in a vdbe program. The different uses might require
63215 ** different sized allocations. Memory cells provide growable
63216 ** allocations.
63218 ** * When using ENABLE_MEMORY_MANAGEMENT, memory cell buffers can
63219 ** be freed lazily via the sqlite3_release_memory() API. This
63220 ** minimizes the number of malloc calls made by the system.
63222 ** Memory cells for cursors are allocated at the top of the address
63223 ** space. Memory cell (p->nMem) corresponds to cursor 0. Space for
63224 ** cursor 1 is managed by memory cell (p->nMem-1), etc.
63226 Mem *pMem = &p->aMem[p->nMem-iCur];
63228 int nByte;
63229 VdbeCursor *pCx = 0;
63230 nByte =
63231 ROUND8(sizeof(VdbeCursor)) +
63232 (isBtreeCursor?sqlite3BtreeCursorSize():0) +
63233 2*nField*sizeof(u32);
63235 assert( iCur<p->nCursor );
63236 if( p->apCsr[iCur] ){
63237 sqlite3VdbeFreeCursor(p, p->apCsr[iCur]);
63238 p->apCsr[iCur] = 0;
63240 if( SQLITE_OK==sqlite3VdbeMemGrow(pMem, nByte, 0) ){
63241 p->apCsr[iCur] = pCx = (VdbeCursor*)pMem->z;
63242 memset(pCx, 0, sizeof(VdbeCursor));
63243 pCx->iDb = iDb;
63244 pCx->nField = nField;
63245 if( nField ){
63246 pCx->aType = (u32 *)&pMem->z[ROUND8(sizeof(VdbeCursor))];
63248 if( isBtreeCursor ){
63249 pCx->pCursor = (BtCursor*)
63250 &pMem->z[ROUND8(sizeof(VdbeCursor))+2*nField*sizeof(u32)];
63251 sqlite3BtreeCursorZero(pCx->pCursor);
63254 return pCx;
63258 ** Try to convert a value into a numeric representation if we can
63259 ** do so without loss of information. In other words, if the string
63260 ** looks like a number, convert it into a number. If it does not
63261 ** look like a number, leave it alone.
63263 static void applyNumericAffinity(Mem *pRec){
63264 if( (pRec->flags & (MEM_Real|MEM_Int))==0 ){
63265 double rValue;
63266 i64 iValue;
63267 u8 enc = pRec->enc;
63268 if( (pRec->flags&MEM_Str)==0 ) return;
63269 if( sqlite3AtoF(pRec->z, &rValue, pRec->n, enc)==0 ) return;
63270 if( 0==sqlite3Atoi64(pRec->z, &iValue, pRec->n, enc) ){
63271 pRec->u.i = iValue;
63272 pRec->flags |= MEM_Int;
63273 }else{
63274 pRec->r = rValue;
63275 pRec->flags |= MEM_Real;
63281 ** Processing is determine by the affinity parameter:
63283 ** SQLITE_AFF_INTEGER:
63284 ** SQLITE_AFF_REAL:
63285 ** SQLITE_AFF_NUMERIC:
63286 ** Try to convert pRec to an integer representation or a
63287 ** floating-point representation if an integer representation
63288 ** is not possible. Note that the integer representation is
63289 ** always preferred, even if the affinity is REAL, because
63290 ** an integer representation is more space efficient on disk.
63292 ** SQLITE_AFF_TEXT:
63293 ** Convert pRec to a text representation.
63295 ** SQLITE_AFF_NONE:
63296 ** No-op. pRec is unchanged.
63298 static void applyAffinity(
63299 Mem *pRec, /* The value to apply affinity to */
63300 char affinity, /* The affinity to be applied */
63301 u8 enc /* Use this text encoding */
63303 if( affinity==SQLITE_AFF_TEXT ){
63304 /* Only attempt the conversion to TEXT if there is an integer or real
63305 ** representation (blob and NULL do not get converted) but no string
63306 ** representation.
63308 if( 0==(pRec->flags&MEM_Str) && (pRec->flags&(MEM_Real|MEM_Int)) ){
63309 sqlite3VdbeMemStringify(pRec, enc);
63311 pRec->flags &= ~(MEM_Real|MEM_Int);
63312 }else if( affinity!=SQLITE_AFF_NONE ){
63313 assert( affinity==SQLITE_AFF_INTEGER || affinity==SQLITE_AFF_REAL
63314 || affinity==SQLITE_AFF_NUMERIC );
63315 applyNumericAffinity(pRec);
63316 if( pRec->flags & MEM_Real ){
63317 sqlite3VdbeIntegerAffinity(pRec);
63323 ** Try to convert the type of a function argument or a result column
63324 ** into a numeric representation. Use either INTEGER or REAL whichever
63325 ** is appropriate. But only do the conversion if it is possible without
63326 ** loss of information and return the revised type of the argument.
63328 SQLITE_API int sqlite3_value_numeric_type(sqlite3_value *pVal){
63329 Mem *pMem = (Mem*)pVal;
63330 if( pMem->type==SQLITE_TEXT ){
63331 applyNumericAffinity(pMem);
63332 sqlite3VdbeMemStoreType(pMem);
63334 return pMem->type;
63338 ** Exported version of applyAffinity(). This one works on sqlite3_value*,
63339 ** not the internal Mem* type.
63341 SQLITE_PRIVATE void sqlite3ValueApplyAffinity(
63342 sqlite3_value *pVal,
63343 u8 affinity,
63344 u8 enc
63346 applyAffinity((Mem *)pVal, affinity, enc);
63349 #ifdef SQLITE_DEBUG
63351 ** Write a nice string representation of the contents of cell pMem
63352 ** into buffer zBuf, length nBuf.
63354 SQLITE_PRIVATE void sqlite3VdbeMemPrettyPrint(Mem *pMem, char *zBuf){
63355 char *zCsr = zBuf;
63356 int f = pMem->flags;
63358 static const char *const encnames[] = {"(X)", "(8)", "(16LE)", "(16BE)"};
63360 if( f&MEM_Blob ){
63361 int i;
63362 char c;
63363 if( f & MEM_Dyn ){
63364 c = 'z';
63365 assert( (f & (MEM_Static|MEM_Ephem))==0 );
63366 }else if( f & MEM_Static ){
63367 c = 't';
63368 assert( (f & (MEM_Dyn|MEM_Ephem))==0 );
63369 }else if( f & MEM_Ephem ){
63370 c = 'e';
63371 assert( (f & (MEM_Static|MEM_Dyn))==0 );
63372 }else{
63373 c = 's';
63376 sqlite3_snprintf(100, zCsr, "%c", c);
63377 zCsr += sqlite3Strlen30(zCsr);
63378 sqlite3_snprintf(100, zCsr, "%d[", pMem->n);
63379 zCsr += sqlite3Strlen30(zCsr);
63380 for(i=0; i<16 && i<pMem->n; i++){
63381 sqlite3_snprintf(100, zCsr, "%02X", ((int)pMem->z[i] & 0xFF));
63382 zCsr += sqlite3Strlen30(zCsr);
63384 for(i=0; i<16 && i<pMem->n; i++){
63385 char z = pMem->z[i];
63386 if( z<32 || z>126 ) *zCsr++ = '.';
63387 else *zCsr++ = z;
63390 sqlite3_snprintf(100, zCsr, "]%s", encnames[pMem->enc]);
63391 zCsr += sqlite3Strlen30(zCsr);
63392 if( f & MEM_Zero ){
63393 sqlite3_snprintf(100, zCsr,"+%dz",pMem->u.nZero);
63394 zCsr += sqlite3Strlen30(zCsr);
63396 *zCsr = '\0';
63397 }else if( f & MEM_Str ){
63398 int j, k;
63399 zBuf[0] = ' ';
63400 if( f & MEM_Dyn ){
63401 zBuf[1] = 'z';
63402 assert( (f & (MEM_Static|MEM_Ephem))==0 );
63403 }else if( f & MEM_Static ){
63404 zBuf[1] = 't';
63405 assert( (f & (MEM_Dyn|MEM_Ephem))==0 );
63406 }else if( f & MEM_Ephem ){
63407 zBuf[1] = 'e';
63408 assert( (f & (MEM_Static|MEM_Dyn))==0 );
63409 }else{
63410 zBuf[1] = 's';
63412 k = 2;
63413 sqlite3_snprintf(100, &zBuf[k], "%d", pMem->n);
63414 k += sqlite3Strlen30(&zBuf[k]);
63415 zBuf[k++] = '[';
63416 for(j=0; j<15 && j<pMem->n; j++){
63417 u8 c = pMem->z[j];
63418 if( c>=0x20 && c<0x7f ){
63419 zBuf[k++] = c;
63420 }else{
63421 zBuf[k++] = '.';
63424 zBuf[k++] = ']';
63425 sqlite3_snprintf(100,&zBuf[k], encnames[pMem->enc]);
63426 k += sqlite3Strlen30(&zBuf[k]);
63427 zBuf[k++] = 0;
63430 #endif
63432 #ifdef SQLITE_DEBUG
63434 ** Print the value of a register for tracing purposes:
63436 static void memTracePrint(FILE *out, Mem *p){
63437 if( p->flags & MEM_Null ){
63438 fprintf(out, " NULL");
63439 }else if( (p->flags & (MEM_Int|MEM_Str))==(MEM_Int|MEM_Str) ){
63440 fprintf(out, " si:%lld", p->u.i);
63441 }else if( p->flags & MEM_Int ){
63442 fprintf(out, " i:%lld", p->u.i);
63443 #ifndef SQLITE_OMIT_FLOATING_POINT
63444 }else if( p->flags & MEM_Real ){
63445 fprintf(out, " r:%g", p->r);
63446 #endif
63447 }else if( p->flags & MEM_RowSet ){
63448 fprintf(out, " (rowset)");
63449 }else{
63450 char zBuf[200];
63451 sqlite3VdbeMemPrettyPrint(p, zBuf);
63452 fprintf(out, " ");
63453 fprintf(out, "%s", zBuf);
63456 static void registerTrace(FILE *out, int iReg, Mem *p){
63457 fprintf(out, "REG[%d] = ", iReg);
63458 memTracePrint(out, p);
63459 fprintf(out, "\n");
63461 #endif
63463 #ifdef SQLITE_DEBUG
63464 # define REGISTER_TRACE(R,M) if(p->trace)registerTrace(p->trace,R,M)
63465 #else
63466 # define REGISTER_TRACE(R,M)
63467 #endif
63470 #ifdef VDBE_PROFILE
63473 ** hwtime.h contains inline assembler code for implementing
63474 ** high-performance timing routines.
63476 /************** Include hwtime.h in the middle of vdbe.c *********************/
63477 /************** Begin file hwtime.h ******************************************/
63479 ** 2008 May 27
63481 ** The author disclaims copyright to this source code. In place of
63482 ** a legal notice, here is a blessing:
63484 ** May you do good and not evil.
63485 ** May you find forgiveness for yourself and forgive others.
63486 ** May you share freely, never taking more than you give.
63488 ******************************************************************************
63490 ** This file contains inline asm code for retrieving "high-performance"
63491 ** counters for x86 class CPUs.
63493 #ifndef _HWTIME_H_
63494 #define _HWTIME_H_
63497 ** The following routine only works on pentium-class (or newer) processors.
63498 ** It uses the RDTSC opcode to read the cycle count value out of the
63499 ** processor and returns that value. This can be used for high-res
63500 ** profiling.
63502 #if (defined(__GNUC__) || defined(_MSC_VER)) && \
63503 (defined(i386) || defined(__i386__) || defined(_M_IX86))
63505 #if defined(__GNUC__)
63507 __inline__ sqlite_uint64 sqlite3Hwtime(void){
63508 unsigned int lo, hi;
63509 __asm__ __volatile__ ("rdtsc" : "=a" (lo), "=d" (hi));
63510 return (sqlite_uint64)hi << 32 | lo;
63513 #elif defined(_MSC_VER)
63515 __declspec(naked) __inline sqlite_uint64 __cdecl sqlite3Hwtime(void){
63516 __asm {
63517 rdtsc
63518 ret ; return value at EDX:EAX
63522 #endif
63524 #elif (defined(__GNUC__) && defined(__x86_64__))
63526 __inline__ sqlite_uint64 sqlite3Hwtime(void){
63527 unsigned long val;
63528 __asm__ __volatile__ ("rdtsc" : "=A" (val));
63529 return val;
63532 #elif (defined(__GNUC__) && defined(__ppc__))
63534 __inline__ sqlite_uint64 sqlite3Hwtime(void){
63535 unsigned long long retval;
63536 unsigned long junk;
63537 __asm__ __volatile__ ("\n\
63538 1: mftbu %1\n\
63539 mftb %L0\n\
63540 mftbu %0\n\
63541 cmpw %0,%1\n\
63542 bne 1b"
63543 : "=r" (retval), "=r" (junk));
63544 return retval;
63547 #else
63549 #error Need implementation of sqlite3Hwtime() for your platform.
63552 ** To compile without implementing sqlite3Hwtime() for your platform,
63553 ** you can remove the above #error and use the following
63554 ** stub function. You will lose timing support for many
63555 ** of the debugging and testing utilities, but it should at
63556 ** least compile and run.
63558 SQLITE_PRIVATE sqlite_uint64 sqlite3Hwtime(void){ return ((sqlite_uint64)0); }
63560 #endif
63562 #endif /* !defined(_HWTIME_H_) */
63564 /************** End of hwtime.h **********************************************/
63565 /************** Continuing where we left off in vdbe.c ***********************/
63567 #endif
63570 ** The CHECK_FOR_INTERRUPT macro defined here looks to see if the
63571 ** sqlite3_interrupt() routine has been called. If it has been, then
63572 ** processing of the VDBE program is interrupted.
63574 ** This macro added to every instruction that does a jump in order to
63575 ** implement a loop. This test used to be on every single instruction,
63576 ** but that meant we more testing that we needed. By only testing the
63577 ** flag on jump instructions, we get a (small) speed improvement.
63579 #define CHECK_FOR_INTERRUPT \
63580 if( db->u1.isInterrupted ) goto abort_due_to_interrupt;
63583 #ifndef NDEBUG
63585 ** This function is only called from within an assert() expression. It
63586 ** checks that the sqlite3.nTransaction variable is correctly set to
63587 ** the number of non-transaction savepoints currently in the
63588 ** linked list starting at sqlite3.pSavepoint.
63590 ** Usage:
63592 ** assert( checkSavepointCount(db) );
63594 static int checkSavepointCount(sqlite3 *db){
63595 int n = 0;
63596 Savepoint *p;
63597 for(p=db->pSavepoint; p; p=p->pNext) n++;
63598 assert( n==(db->nSavepoint + db->isTransactionSavepoint) );
63599 return 1;
63601 #endif
63604 ** Transfer error message text from an sqlite3_vtab.zErrMsg (text stored
63605 ** in memory obtained from sqlite3_malloc) into a Vdbe.zErrMsg (text stored
63606 ** in memory obtained from sqlite3DbMalloc).
63608 static void importVtabErrMsg(Vdbe *p, sqlite3_vtab *pVtab){
63609 sqlite3 *db = p->db;
63610 sqlite3DbFree(db, p->zErrMsg);
63611 p->zErrMsg = sqlite3DbStrDup(db, pVtab->zErrMsg);
63612 sqlite3_free(pVtab->zErrMsg);
63613 pVtab->zErrMsg = 0;
63618 ** Execute as much of a VDBE program as we can then return.
63620 ** sqlite3VdbeMakeReady() must be called before this routine in order to
63621 ** close the program with a final OP_Halt and to set up the callbacks
63622 ** and the error message pointer.
63624 ** Whenever a row or result data is available, this routine will either
63625 ** invoke the result callback (if there is one) or return with
63626 ** SQLITE_ROW.
63628 ** If an attempt is made to open a locked database, then this routine
63629 ** will either invoke the busy callback (if there is one) or it will
63630 ** return SQLITE_BUSY.
63632 ** If an error occurs, an error message is written to memory obtained
63633 ** from sqlite3_malloc() and p->zErrMsg is made to point to that memory.
63634 ** The error code is stored in p->rc and this routine returns SQLITE_ERROR.
63636 ** If the callback ever returns non-zero, then the program exits
63637 ** immediately. There will be no error message but the p->rc field is
63638 ** set to SQLITE_ABORT and this routine will return SQLITE_ERROR.
63640 ** A memory allocation error causes p->rc to be set to SQLITE_NOMEM and this
63641 ** routine to return SQLITE_ERROR.
63643 ** Other fatal errors return SQLITE_ERROR.
63645 ** After this routine has finished, sqlite3VdbeFinalize() should be
63646 ** used to clean up the mess that was left behind.
63648 SQLITE_PRIVATE int sqlite3VdbeExec(
63649 Vdbe *p /* The VDBE */
63651 int pc=0; /* The program counter */
63652 Op *aOp = p->aOp; /* Copy of p->aOp */
63653 Op *pOp; /* Current operation */
63654 int rc = SQLITE_OK; /* Value to return */
63655 sqlite3 *db = p->db; /* The database */
63656 u8 resetSchemaOnFault = 0; /* Reset schema after an error if positive */
63657 u8 encoding = ENC(db); /* The database encoding */
63658 #ifndef SQLITE_OMIT_PROGRESS_CALLBACK
63659 int checkProgress; /* True if progress callbacks are enabled */
63660 int nProgressOps = 0; /* Opcodes executed since progress callback. */
63661 #endif
63662 Mem *aMem = p->aMem; /* Copy of p->aMem */
63663 Mem *pIn1 = 0; /* 1st input operand */
63664 Mem *pIn2 = 0; /* 2nd input operand */
63665 Mem *pIn3 = 0; /* 3rd input operand */
63666 Mem *pOut = 0; /* Output operand */
63667 int iCompare = 0; /* Result of last OP_Compare operation */
63668 int *aPermute = 0; /* Permutation of columns for OP_Compare */
63669 i64 lastRowid = db->lastRowid; /* Saved value of the last insert ROWID */
63670 #ifdef VDBE_PROFILE
63671 u64 start; /* CPU clock count at start of opcode */
63672 int origPc; /* Program counter at start of opcode */
63673 #endif
63674 /********************************************************************
63675 ** Automatically generated code
63677 ** The following union is automatically generated by the
63678 ** vdbe-compress.tcl script. The purpose of this union is to
63679 ** reduce the amount of stack space required by this function.
63680 ** See comments in the vdbe-compress.tcl script for details.
63682 union vdbeExecUnion {
63683 struct OP_Yield_stack_vars {
63684 int pcDest;
63685 } aa;
63686 struct OP_Variable_stack_vars {
63687 Mem *pVar; /* Value being transferred */
63688 } ab;
63689 struct OP_Move_stack_vars {
63690 char *zMalloc; /* Holding variable for allocated memory */
63691 int n; /* Number of registers left to copy */
63692 int p1; /* Register to copy from */
63693 int p2; /* Register to copy to */
63694 } ac;
63695 struct OP_ResultRow_stack_vars {
63696 Mem *pMem;
63697 int i;
63698 } ad;
63699 struct OP_Concat_stack_vars {
63700 i64 nByte;
63701 } ae;
63702 struct OP_Remainder_stack_vars {
63703 int flags; /* Combined MEM_* flags from both inputs */
63704 i64 iA; /* Integer value of left operand */
63705 i64 iB; /* Integer value of right operand */
63706 double rA; /* Real value of left operand */
63707 double rB; /* Real value of right operand */
63708 } af;
63709 struct OP_Function_stack_vars {
63710 int i;
63711 Mem *pArg;
63712 sqlite3_context ctx;
63713 sqlite3_value **apVal;
63714 int n;
63715 } ag;
63716 struct OP_ShiftRight_stack_vars {
63717 i64 iA;
63718 u64 uA;
63719 i64 iB;
63720 u8 op;
63721 } ah;
63722 struct OP_Ge_stack_vars {
63723 int res; /* Result of the comparison of pIn1 against pIn3 */
63724 char affinity; /* Affinity to use for comparison */
63725 u16 flags1; /* Copy of initial value of pIn1->flags */
63726 u16 flags3; /* Copy of initial value of pIn3->flags */
63727 } ai;
63728 struct OP_Compare_stack_vars {
63729 int n;
63730 int i;
63731 int p1;
63732 int p2;
63733 const KeyInfo *pKeyInfo;
63734 int idx;
63735 CollSeq *pColl; /* Collating sequence to use on this term */
63736 int bRev; /* True for DESCENDING sort order */
63737 } aj;
63738 struct OP_Or_stack_vars {
63739 int v1; /* Left operand: 0==FALSE, 1==TRUE, 2==UNKNOWN or NULL */
63740 int v2; /* Right operand: 0==FALSE, 1==TRUE, 2==UNKNOWN or NULL */
63741 } ak;
63742 struct OP_IfNot_stack_vars {
63743 int c;
63744 } al;
63745 struct OP_Column_stack_vars {
63746 u32 payloadSize; /* Number of bytes in the record */
63747 i64 payloadSize64; /* Number of bytes in the record */
63748 int p1; /* P1 value of the opcode */
63749 int p2; /* column number to retrieve */
63750 VdbeCursor *pC; /* The VDBE cursor */
63751 char *zRec; /* Pointer to complete record-data */
63752 BtCursor *pCrsr; /* The BTree cursor */
63753 u32 *aType; /* aType[i] holds the numeric type of the i-th column */
63754 u32 *aOffset; /* aOffset[i] is offset to start of data for i-th column */
63755 int nField; /* number of fields in the record */
63756 int len; /* The length of the serialized data for the column */
63757 int i; /* Loop counter */
63758 char *zData; /* Part of the record being decoded */
63759 Mem *pDest; /* Where to write the extracted value */
63760 Mem sMem; /* For storing the record being decoded */
63761 u8 *zIdx; /* Index into header */
63762 u8 *zEndHdr; /* Pointer to first byte after the header */
63763 u32 offset; /* Offset into the data */
63764 u32 szField; /* Number of bytes in the content of a field */
63765 int szHdr; /* Size of the header size field at start of record */
63766 int avail; /* Number of bytes of available data */
63767 u32 t; /* A type code from the record header */
63768 Mem *pReg; /* PseudoTable input register */
63769 } am;
63770 struct OP_Affinity_stack_vars {
63771 const char *zAffinity; /* The affinity to be applied */
63772 char cAff; /* A single character of affinity */
63773 } an;
63774 struct OP_MakeRecord_stack_vars {
63775 u8 *zNewRecord; /* A buffer to hold the data for the new record */
63776 Mem *pRec; /* The new record */
63777 u64 nData; /* Number of bytes of data space */
63778 int nHdr; /* Number of bytes of header space */
63779 i64 nByte; /* Data space required for this record */
63780 int nZero; /* Number of zero bytes at the end of the record */
63781 int nVarint; /* Number of bytes in a varint */
63782 u32 serial_type; /* Type field */
63783 Mem *pData0; /* First field to be combined into the record */
63784 Mem *pLast; /* Last field of the record */
63785 int nField; /* Number of fields in the record */
63786 char *zAffinity; /* The affinity string for the record */
63787 int file_format; /* File format to use for encoding */
63788 int i; /* Space used in zNewRecord[] */
63789 int len; /* Length of a field */
63790 } ao;
63791 struct OP_Count_stack_vars {
63792 i64 nEntry;
63793 BtCursor *pCrsr;
63794 } ap;
63795 struct OP_Savepoint_stack_vars {
63796 int p1; /* Value of P1 operand */
63797 char *zName; /* Name of savepoint */
63798 int nName;
63799 Savepoint *pNew;
63800 Savepoint *pSavepoint;
63801 Savepoint *pTmp;
63802 int iSavepoint;
63803 int ii;
63804 } aq;
63805 struct OP_AutoCommit_stack_vars {
63806 int desiredAutoCommit;
63807 int iRollback;
63808 int turnOnAC;
63809 } ar;
63810 struct OP_Transaction_stack_vars {
63811 Btree *pBt;
63812 } as;
63813 struct OP_ReadCookie_stack_vars {
63814 int iMeta;
63815 int iDb;
63816 int iCookie;
63817 } at;
63818 struct OP_SetCookie_stack_vars {
63819 Db *pDb;
63820 } au;
63821 struct OP_VerifyCookie_stack_vars {
63822 int iMeta;
63823 int iGen;
63824 Btree *pBt;
63825 } av;
63826 struct OP_OpenWrite_stack_vars {
63827 int nField;
63828 KeyInfo *pKeyInfo;
63829 int p2;
63830 int iDb;
63831 int wrFlag;
63832 Btree *pX;
63833 VdbeCursor *pCur;
63834 Db *pDb;
63835 } aw;
63836 struct OP_OpenEphemeral_stack_vars {
63837 VdbeCursor *pCx;
63838 } ax;
63839 struct OP_SorterOpen_stack_vars {
63840 VdbeCursor *pCx;
63841 } ay;
63842 struct OP_OpenPseudo_stack_vars {
63843 VdbeCursor *pCx;
63844 } az;
63845 struct OP_SeekGt_stack_vars {
63846 int res;
63847 int oc;
63848 VdbeCursor *pC;
63849 UnpackedRecord r;
63850 int nField;
63851 i64 iKey; /* The rowid we are to seek to */
63852 } ba;
63853 struct OP_Seek_stack_vars {
63854 VdbeCursor *pC;
63855 } bb;
63856 struct OP_Found_stack_vars {
63857 int alreadyExists;
63858 VdbeCursor *pC;
63859 int res;
63860 char *pFree;
63861 UnpackedRecord *pIdxKey;
63862 UnpackedRecord r;
63863 char aTempRec[ROUND8(sizeof(UnpackedRecord)) + sizeof(Mem)*3 + 7];
63864 } bc;
63865 struct OP_IsUnique_stack_vars {
63866 u16 ii;
63867 VdbeCursor *pCx;
63868 BtCursor *pCrsr;
63869 u16 nField;
63870 Mem *aMx;
63871 UnpackedRecord r; /* B-Tree index search key */
63872 i64 R; /* Rowid stored in register P3 */
63873 } bd;
63874 struct OP_NotExists_stack_vars {
63875 VdbeCursor *pC;
63876 BtCursor *pCrsr;
63877 int res;
63878 u64 iKey;
63879 } be;
63880 struct OP_NewRowid_stack_vars {
63881 i64 v; /* The new rowid */
63882 VdbeCursor *pC; /* Cursor of table to get the new rowid */
63883 int res; /* Result of an sqlite3BtreeLast() */
63884 int cnt; /* Counter to limit the number of searches */
63885 Mem *pMem; /* Register holding largest rowid for AUTOINCREMENT */
63886 VdbeFrame *pFrame; /* Root frame of VDBE */
63887 } bf;
63888 struct OP_InsertInt_stack_vars {
63889 Mem *pData; /* MEM cell holding data for the record to be inserted */
63890 Mem *pKey; /* MEM cell holding key for the record */
63891 i64 iKey; /* The integer ROWID or key for the record to be inserted */
63892 VdbeCursor *pC; /* Cursor to table into which insert is written */
63893 int nZero; /* Number of zero-bytes to append */
63894 int seekResult; /* Result of prior seek or 0 if no USESEEKRESULT flag */
63895 const char *zDb; /* database name - used by the update hook */
63896 const char *zTbl; /* Table name - used by the opdate hook */
63897 int op; /* Opcode for update hook: SQLITE_UPDATE or SQLITE_INSERT */
63898 } bg;
63899 struct OP_Delete_stack_vars {
63900 i64 iKey;
63901 VdbeCursor *pC;
63902 } bh;
63903 struct OP_SorterCompare_stack_vars {
63904 VdbeCursor *pC;
63905 int res;
63906 } bi;
63907 struct OP_SorterData_stack_vars {
63908 VdbeCursor *pC;
63909 } bj;
63910 struct OP_RowData_stack_vars {
63911 VdbeCursor *pC;
63912 BtCursor *pCrsr;
63913 u32 n;
63914 i64 n64;
63915 } bk;
63916 struct OP_Rowid_stack_vars {
63917 VdbeCursor *pC;
63918 i64 v;
63919 sqlite3_vtab *pVtab;
63920 const sqlite3_module *pModule;
63921 } bl;
63922 struct OP_NullRow_stack_vars {
63923 VdbeCursor *pC;
63924 } bm;
63925 struct OP_Last_stack_vars {
63926 VdbeCursor *pC;
63927 BtCursor *pCrsr;
63928 int res;
63929 } bn;
63930 struct OP_Rewind_stack_vars {
63931 VdbeCursor *pC;
63932 BtCursor *pCrsr;
63933 int res;
63934 } bo;
63935 struct OP_Next_stack_vars {
63936 VdbeCursor *pC;
63937 int res;
63938 } bp;
63939 struct OP_IdxInsert_stack_vars {
63940 VdbeCursor *pC;
63941 BtCursor *pCrsr;
63942 int nKey;
63943 const char *zKey;
63944 } bq;
63945 struct OP_IdxDelete_stack_vars {
63946 VdbeCursor *pC;
63947 BtCursor *pCrsr;
63948 int res;
63949 UnpackedRecord r;
63950 } br;
63951 struct OP_IdxRowid_stack_vars {
63952 BtCursor *pCrsr;
63953 VdbeCursor *pC;
63954 i64 rowid;
63955 } bs;
63956 struct OP_IdxGE_stack_vars {
63957 VdbeCursor *pC;
63958 int res;
63959 UnpackedRecord r;
63960 } bt;
63961 struct OP_Destroy_stack_vars {
63962 int iMoved;
63963 int iCnt;
63964 Vdbe *pVdbe;
63965 int iDb;
63966 } bu;
63967 struct OP_Clear_stack_vars {
63968 int nChange;
63969 } bv;
63970 struct OP_CreateTable_stack_vars {
63971 int pgno;
63972 int flags;
63973 Db *pDb;
63974 } bw;
63975 struct OP_ParseSchema_stack_vars {
63976 int iDb;
63977 const char *zMaster;
63978 char *zSql;
63979 InitData initData;
63980 } bx;
63981 struct OP_IntegrityCk_stack_vars {
63982 int nRoot; /* Number of tables to check. (Number of root pages.) */
63983 int *aRoot; /* Array of rootpage numbers for tables to be checked */
63984 int j; /* Loop counter */
63985 int nErr; /* Number of errors reported */
63986 char *z; /* Text of the error report */
63987 Mem *pnErr; /* Register keeping track of errors remaining */
63988 } by;
63989 struct OP_RowSetRead_stack_vars {
63990 i64 val;
63991 } bz;
63992 struct OP_RowSetTest_stack_vars {
63993 int iSet;
63994 int exists;
63995 } ca;
63996 struct OP_Program_stack_vars {
63997 int nMem; /* Number of memory registers for sub-program */
63998 int nByte; /* Bytes of runtime space required for sub-program */
63999 Mem *pRt; /* Register to allocate runtime space */
64000 Mem *pMem; /* Used to iterate through memory cells */
64001 Mem *pEnd; /* Last memory cell in new array */
64002 VdbeFrame *pFrame; /* New vdbe frame to execute in */
64003 SubProgram *pProgram; /* Sub-program to execute */
64004 void *t; /* Token identifying trigger */
64005 } cb;
64006 struct OP_Param_stack_vars {
64007 VdbeFrame *pFrame;
64008 Mem *pIn;
64009 } cc;
64010 struct OP_MemMax_stack_vars {
64011 Mem *pIn1;
64012 VdbeFrame *pFrame;
64013 } cd;
64014 struct OP_AggStep_stack_vars {
64015 int n;
64016 int i;
64017 Mem *pMem;
64018 Mem *pRec;
64019 sqlite3_context ctx;
64020 sqlite3_value **apVal;
64021 } ce;
64022 struct OP_AggFinal_stack_vars {
64023 Mem *pMem;
64024 } cf;
64025 struct OP_Checkpoint_stack_vars {
64026 int i; /* Loop counter */
64027 int aRes[3]; /* Results */
64028 Mem *pMem; /* Write results here */
64029 } cg;
64030 struct OP_JournalMode_stack_vars {
64031 Btree *pBt; /* Btree to change journal mode of */
64032 Pager *pPager; /* Pager associated with pBt */
64033 int eNew; /* New journal mode */
64034 int eOld; /* The old journal mode */
64035 const char *zFilename; /* Name of database file for pPager */
64036 } ch;
64037 struct OP_IncrVacuum_stack_vars {
64038 Btree *pBt;
64039 } ci;
64040 struct OP_VBegin_stack_vars {
64041 VTable *pVTab;
64042 } cj;
64043 struct OP_VOpen_stack_vars {
64044 VdbeCursor *pCur;
64045 sqlite3_vtab_cursor *pVtabCursor;
64046 sqlite3_vtab *pVtab;
64047 sqlite3_module *pModule;
64048 } ck;
64049 struct OP_VFilter_stack_vars {
64050 int nArg;
64051 int iQuery;
64052 const sqlite3_module *pModule;
64053 Mem *pQuery;
64054 Mem *pArgc;
64055 sqlite3_vtab_cursor *pVtabCursor;
64056 sqlite3_vtab *pVtab;
64057 VdbeCursor *pCur;
64058 int res;
64059 int i;
64060 Mem **apArg;
64061 } cl;
64062 struct OP_VColumn_stack_vars {
64063 sqlite3_vtab *pVtab;
64064 const sqlite3_module *pModule;
64065 Mem *pDest;
64066 sqlite3_context sContext;
64067 } cm;
64068 struct OP_VNext_stack_vars {
64069 sqlite3_vtab *pVtab;
64070 const sqlite3_module *pModule;
64071 int res;
64072 VdbeCursor *pCur;
64073 } cn;
64074 struct OP_VRename_stack_vars {
64075 sqlite3_vtab *pVtab;
64076 Mem *pName;
64077 } co;
64078 struct OP_VUpdate_stack_vars {
64079 sqlite3_vtab *pVtab;
64080 sqlite3_module *pModule;
64081 int nArg;
64082 int i;
64083 sqlite_int64 rowid;
64084 Mem **apArg;
64085 Mem *pX;
64086 } cp;
64087 struct OP_Trace_stack_vars {
64088 char *zTrace;
64089 char *z;
64090 } cq;
64091 } u;
64092 /* End automatically generated code
64093 ********************************************************************/
64095 assert( p->magic==VDBE_MAGIC_RUN ); /* sqlite3_step() verifies this */
64096 sqlite3VdbeEnter(p);
64097 if( p->rc==SQLITE_NOMEM ){
64098 /* This happens if a malloc() inside a call to sqlite3_column_text() or
64099 ** sqlite3_column_text16() failed. */
64100 goto no_mem;
64102 assert( p->rc==SQLITE_OK || p->rc==SQLITE_BUSY );
64103 p->rc = SQLITE_OK;
64104 assert( p->explain==0 );
64105 p->pResultSet = 0;
64106 db->busyHandler.nBusy = 0;
64107 CHECK_FOR_INTERRUPT;
64108 sqlite3VdbeIOTraceSql(p);
64109 #ifndef SQLITE_OMIT_PROGRESS_CALLBACK
64110 checkProgress = db->xProgress!=0;
64111 #endif
64112 #ifdef SQLITE_DEBUG
64113 sqlite3BeginBenignMalloc();
64114 if( p->pc==0 && (p->db->flags & SQLITE_VdbeListing)!=0 ){
64115 int i;
64116 printf("VDBE Program Listing:\n");
64117 sqlite3VdbePrintSql(p);
64118 for(i=0; i<p->nOp; i++){
64119 sqlite3VdbePrintOp(stdout, i, &aOp[i]);
64122 sqlite3EndBenignMalloc();
64123 #endif
64124 for(pc=p->pc; rc==SQLITE_OK; pc++){
64125 assert( pc>=0 && pc<p->nOp );
64126 if( db->mallocFailed ) goto no_mem;
64127 #ifdef VDBE_PROFILE
64128 origPc = pc;
64129 start = sqlite3Hwtime();
64130 #endif
64131 pOp = &aOp[pc];
64133 /* Only allow tracing if SQLITE_DEBUG is defined.
64135 #ifdef SQLITE_DEBUG
64136 if( p->trace ){
64137 if( pc==0 ){
64138 printf("VDBE Execution Trace:\n");
64139 sqlite3VdbePrintSql(p);
64141 sqlite3VdbePrintOp(p->trace, pc, pOp);
64143 #endif
64146 /* Check to see if we need to simulate an interrupt. This only happens
64147 ** if we have a special test build.
64149 #ifdef SQLITE_TEST
64150 if( sqlite3_interrupt_count>0 ){
64151 sqlite3_interrupt_count--;
64152 if( sqlite3_interrupt_count==0 ){
64153 sqlite3_interrupt(db);
64156 #endif
64158 #ifndef SQLITE_OMIT_PROGRESS_CALLBACK
64159 /* Call the progress callback if it is configured and the required number
64160 ** of VDBE ops have been executed (either since this invocation of
64161 ** sqlite3VdbeExec() or since last time the progress callback was called).
64162 ** If the progress callback returns non-zero, exit the virtual machine with
64163 ** a return code SQLITE_ABORT.
64165 if( checkProgress ){
64166 if( db->nProgressOps==nProgressOps ){
64167 int prc;
64168 prc = db->xProgress(db->pProgressArg);
64169 if( prc!=0 ){
64170 rc = SQLITE_INTERRUPT;
64171 goto vdbe_error_halt;
64173 nProgressOps = 0;
64175 nProgressOps++;
64177 #endif
64179 /* On any opcode with the "out2-prerelase" tag, free any
64180 ** external allocations out of mem[p2] and set mem[p2] to be
64181 ** an undefined integer. Opcodes will either fill in the integer
64182 ** value or convert mem[p2] to a different type.
64184 assert( pOp->opflags==sqlite3OpcodeProperty[pOp->opcode] );
64185 if( pOp->opflags & OPFLG_OUT2_PRERELEASE ){
64186 assert( pOp->p2>0 );
64187 assert( pOp->p2<=p->nMem );
64188 pOut = &aMem[pOp->p2];
64189 memAboutToChange(p, pOut);
64190 MemReleaseExt(pOut);
64191 pOut->flags = MEM_Int;
64194 /* Sanity checking on other operands */
64195 #ifdef SQLITE_DEBUG
64196 if( (pOp->opflags & OPFLG_IN1)!=0 ){
64197 assert( pOp->p1>0 );
64198 assert( pOp->p1<=p->nMem );
64199 assert( memIsValid(&aMem[pOp->p1]) );
64200 REGISTER_TRACE(pOp->p1, &aMem[pOp->p1]);
64202 if( (pOp->opflags & OPFLG_IN2)!=0 ){
64203 assert( pOp->p2>0 );
64204 assert( pOp->p2<=p->nMem );
64205 assert( memIsValid(&aMem[pOp->p2]) );
64206 REGISTER_TRACE(pOp->p2, &aMem[pOp->p2]);
64208 if( (pOp->opflags & OPFLG_IN3)!=0 ){
64209 assert( pOp->p3>0 );
64210 assert( pOp->p3<=p->nMem );
64211 assert( memIsValid(&aMem[pOp->p3]) );
64212 REGISTER_TRACE(pOp->p3, &aMem[pOp->p3]);
64214 if( (pOp->opflags & OPFLG_OUT2)!=0 ){
64215 assert( pOp->p2>0 );
64216 assert( pOp->p2<=p->nMem );
64217 memAboutToChange(p, &aMem[pOp->p2]);
64219 if( (pOp->opflags & OPFLG_OUT3)!=0 ){
64220 assert( pOp->p3>0 );
64221 assert( pOp->p3<=p->nMem );
64222 memAboutToChange(p, &aMem[pOp->p3]);
64224 #endif
64226 switch( pOp->opcode ){
64228 /*****************************************************************************
64229 ** What follows is a massive switch statement where each case implements a
64230 ** separate instruction in the virtual machine. If we follow the usual
64231 ** indentation conventions, each case should be indented by 6 spaces. But
64232 ** that is a lot of wasted space on the left margin. So the code within
64233 ** the switch statement will break with convention and be flush-left. Another
64234 ** big comment (similar to this one) will mark the point in the code where
64235 ** we transition back to normal indentation.
64237 ** The formatting of each case is important. The makefile for SQLite
64238 ** generates two C files "opcodes.h" and "opcodes.c" by scanning this
64239 ** file looking for lines that begin with "case OP_". The opcodes.h files
64240 ** will be filled with #defines that give unique integer values to each
64241 ** opcode and the opcodes.c file is filled with an array of strings where
64242 ** each string is the symbolic name for the corresponding opcode. If the
64243 ** case statement is followed by a comment of the form "/# same as ... #/"
64244 ** that comment is used to determine the particular value of the opcode.
64246 ** Other keywords in the comment that follows each case are used to
64247 ** construct the OPFLG_INITIALIZER value that initializes opcodeProperty[].
64248 ** Keywords include: in1, in2, in3, out2_prerelease, out2, out3. See
64249 ** the mkopcodeh.awk script for additional information.
64251 ** Documentation about VDBE opcodes is generated by scanning this file
64252 ** for lines of that contain "Opcode:". That line and all subsequent
64253 ** comment lines are used in the generation of the opcode.html documentation
64254 ** file.
64256 ** SUMMARY:
64258 ** Formatting is important to scripts that scan this file.
64259 ** Do not deviate from the formatting style currently in use.
64261 *****************************************************************************/
64263 /* Opcode: Goto * P2 * * *
64265 ** An unconditional jump to address P2.
64266 ** The next instruction executed will be
64267 ** the one at index P2 from the beginning of
64268 ** the program.
64270 case OP_Goto: { /* jump */
64271 CHECK_FOR_INTERRUPT;
64272 pc = pOp->p2 - 1;
64273 break;
64276 /* Opcode: Gosub P1 P2 * * *
64278 ** Write the current address onto register P1
64279 ** and then jump to address P2.
64281 case OP_Gosub: { /* jump, in1 */
64282 pIn1 = &aMem[pOp->p1];
64283 assert( (pIn1->flags & MEM_Dyn)==0 );
64284 memAboutToChange(p, pIn1);
64285 pIn1->flags = MEM_Int;
64286 pIn1->u.i = pc;
64287 REGISTER_TRACE(pOp->p1, pIn1);
64288 pc = pOp->p2 - 1;
64289 break;
64292 /* Opcode: Return P1 * * * *
64294 ** Jump to the next instruction after the address in register P1.
64296 case OP_Return: { /* in1 */
64297 pIn1 = &aMem[pOp->p1];
64298 assert( pIn1->flags & MEM_Int );
64299 pc = (int)pIn1->u.i;
64300 break;
64303 /* Opcode: Yield P1 * * * *
64305 ** Swap the program counter with the value in register P1.
64307 case OP_Yield: { /* in1 */
64308 #if 0 /* local variables moved into u.aa */
64309 int pcDest;
64310 #endif /* local variables moved into u.aa */
64311 pIn1 = &aMem[pOp->p1];
64312 assert( (pIn1->flags & MEM_Dyn)==0 );
64313 pIn1->flags = MEM_Int;
64314 u.aa.pcDest = (int)pIn1->u.i;
64315 pIn1->u.i = pc;
64316 REGISTER_TRACE(pOp->p1, pIn1);
64317 pc = u.aa.pcDest;
64318 break;
64321 /* Opcode: HaltIfNull P1 P2 P3 P4 *
64323 ** Check the value in register P3. If it is NULL then Halt using
64324 ** parameter P1, P2, and P4 as if this were a Halt instruction. If the
64325 ** value in register P3 is not NULL, then this routine is a no-op.
64327 case OP_HaltIfNull: { /* in3 */
64328 pIn3 = &aMem[pOp->p3];
64329 if( (pIn3->flags & MEM_Null)==0 ) break;
64330 /* Fall through into OP_Halt */
64333 /* Opcode: Halt P1 P2 * P4 *
64335 ** Exit immediately. All open cursors, etc are closed
64336 ** automatically.
64338 ** P1 is the result code returned by sqlite3_exec(), sqlite3_reset(),
64339 ** or sqlite3_finalize(). For a normal halt, this should be SQLITE_OK (0).
64340 ** For errors, it can be some other value. If P1!=0 then P2 will determine
64341 ** whether or not to rollback the current transaction. Do not rollback
64342 ** if P2==OE_Fail. Do the rollback if P2==OE_Rollback. If P2==OE_Abort,
64343 ** then back out all changes that have occurred during this execution of the
64344 ** VDBE, but do not rollback the transaction.
64346 ** If P4 is not null then it is an error message string.
64348 ** There is an implied "Halt 0 0 0" instruction inserted at the very end of
64349 ** every program. So a jump past the last instruction of the program
64350 ** is the same as executing Halt.
64352 case OP_Halt: {
64353 if( pOp->p1==SQLITE_OK && p->pFrame ){
64354 /* Halt the sub-program. Return control to the parent frame. */
64355 VdbeFrame *pFrame = p->pFrame;
64356 p->pFrame = pFrame->pParent;
64357 p->nFrame--;
64358 sqlite3VdbeSetChanges(db, p->nChange);
64359 pc = sqlite3VdbeFrameRestore(pFrame);
64360 lastRowid = db->lastRowid;
64361 if( pOp->p2==OE_Ignore ){
64362 /* Instruction pc is the OP_Program that invoked the sub-program
64363 ** currently being halted. If the p2 instruction of this OP_Halt
64364 ** instruction is set to OE_Ignore, then the sub-program is throwing
64365 ** an IGNORE exception. In this case jump to the address specified
64366 ** as the p2 of the calling OP_Program. */
64367 pc = p->aOp[pc].p2-1;
64369 aOp = p->aOp;
64370 aMem = p->aMem;
64371 break;
64374 p->rc = pOp->p1;
64375 p->errorAction = (u8)pOp->p2;
64376 p->pc = pc;
64377 if( pOp->p4.z ){
64378 assert( p->rc!=SQLITE_OK );
64379 sqlite3SetString(&p->zErrMsg, db, "%s", pOp->p4.z);
64380 testcase( sqlite3GlobalConfig.xLog!=0 );
64381 sqlite3_log(pOp->p1, "abort at %d in [%s]: %s", pc, p->zSql, pOp->p4.z);
64382 }else if( p->rc ){
64383 testcase( sqlite3GlobalConfig.xLog!=0 );
64384 sqlite3_log(pOp->p1, "constraint failed at %d in [%s]", pc, p->zSql);
64386 rc = sqlite3VdbeHalt(p);
64387 assert( rc==SQLITE_BUSY || rc==SQLITE_OK || rc==SQLITE_ERROR );
64388 if( rc==SQLITE_BUSY ){
64389 p->rc = rc = SQLITE_BUSY;
64390 }else{
64391 assert( rc==SQLITE_OK || p->rc==SQLITE_CONSTRAINT );
64392 assert( rc==SQLITE_OK || db->nDeferredCons>0 );
64393 rc = p->rc ? SQLITE_ERROR : SQLITE_DONE;
64395 goto vdbe_return;
64398 /* Opcode: Integer P1 P2 * * *
64400 ** The 32-bit integer value P1 is written into register P2.
64402 case OP_Integer: { /* out2-prerelease */
64403 pOut->u.i = pOp->p1;
64404 break;
64407 /* Opcode: Int64 * P2 * P4 *
64409 ** P4 is a pointer to a 64-bit integer value.
64410 ** Write that value into register P2.
64412 case OP_Int64: { /* out2-prerelease */
64413 assert( pOp->p4.pI64!=0 );
64414 pOut->u.i = *pOp->p4.pI64;
64415 break;
64418 #ifndef SQLITE_OMIT_FLOATING_POINT
64419 /* Opcode: Real * P2 * P4 *
64421 ** P4 is a pointer to a 64-bit floating point value.
64422 ** Write that value into register P2.
64424 case OP_Real: { /* same as TK_FLOAT, out2-prerelease */
64425 pOut->flags = MEM_Real;
64426 assert( !sqlite3IsNaN(*pOp->p4.pReal) );
64427 pOut->r = *pOp->p4.pReal;
64428 break;
64430 #endif
64432 /* Opcode: String8 * P2 * P4 *
64434 ** P4 points to a nul terminated UTF-8 string. This opcode is transformed
64435 ** into an OP_String before it is executed for the first time.
64437 case OP_String8: { /* same as TK_STRING, out2-prerelease */
64438 assert( pOp->p4.z!=0 );
64439 pOp->opcode = OP_String;
64440 pOp->p1 = sqlite3Strlen30(pOp->p4.z);
64442 #ifndef SQLITE_OMIT_UTF16
64443 if( encoding!=SQLITE_UTF8 ){
64444 rc = sqlite3VdbeMemSetStr(pOut, pOp->p4.z, -1, SQLITE_UTF8, SQLITE_STATIC);
64445 if( rc==SQLITE_TOOBIG ) goto too_big;
64446 if( SQLITE_OK!=sqlite3VdbeChangeEncoding(pOut, encoding) ) goto no_mem;
64447 assert( pOut->zMalloc==pOut->z );
64448 assert( pOut->flags & MEM_Dyn );
64449 pOut->zMalloc = 0;
64450 pOut->flags |= MEM_Static;
64451 pOut->flags &= ~MEM_Dyn;
64452 if( pOp->p4type==P4_DYNAMIC ){
64453 sqlite3DbFree(db, pOp->p4.z);
64455 pOp->p4type = P4_DYNAMIC;
64456 pOp->p4.z = pOut->z;
64457 pOp->p1 = pOut->n;
64459 #endif
64460 if( pOp->p1>db->aLimit[SQLITE_LIMIT_LENGTH] ){
64461 goto too_big;
64463 /* Fall through to the next case, OP_String */
64466 /* Opcode: String P1 P2 * P4 *
64468 ** The string value P4 of length P1 (bytes) is stored in register P2.
64470 case OP_String: { /* out2-prerelease */
64471 assert( pOp->p4.z!=0 );
64472 pOut->flags = MEM_Str|MEM_Static|MEM_Term;
64473 pOut->z = pOp->p4.z;
64474 pOut->n = pOp->p1;
64475 pOut->enc = encoding;
64476 UPDATE_MAX_BLOBSIZE(pOut);
64477 break;
64480 /* Opcode: Null * P2 * * *
64482 ** Write a NULL into register P2.
64484 case OP_Null: { /* out2-prerelease */
64485 pOut->flags = MEM_Null;
64486 break;
64490 /* Opcode: Blob P1 P2 * P4
64492 ** P4 points to a blob of data P1 bytes long. Store this
64493 ** blob in register P2.
64495 case OP_Blob: { /* out2-prerelease */
64496 assert( pOp->p1 <= SQLITE_MAX_LENGTH );
64497 sqlite3VdbeMemSetStr(pOut, pOp->p4.z, pOp->p1, 0, 0);
64498 pOut->enc = encoding;
64499 UPDATE_MAX_BLOBSIZE(pOut);
64500 break;
64503 /* Opcode: Variable P1 P2 * P4 *
64505 ** Transfer the values of bound parameter P1 into register P2
64507 ** If the parameter is named, then its name appears in P4 and P3==1.
64508 ** The P4 value is used by sqlite3_bind_parameter_name().
64510 case OP_Variable: { /* out2-prerelease */
64511 #if 0 /* local variables moved into u.ab */
64512 Mem *pVar; /* Value being transferred */
64513 #endif /* local variables moved into u.ab */
64515 assert( pOp->p1>0 && pOp->p1<=p->nVar );
64516 assert( pOp->p4.z==0 || pOp->p4.z==p->azVar[pOp->p1-1] );
64517 u.ab.pVar = &p->aVar[pOp->p1 - 1];
64518 if( sqlite3VdbeMemTooBig(u.ab.pVar) ){
64519 goto too_big;
64521 sqlite3VdbeMemShallowCopy(pOut, u.ab.pVar, MEM_Static);
64522 UPDATE_MAX_BLOBSIZE(pOut);
64523 break;
64526 /* Opcode: Move P1 P2 P3 * *
64528 ** Move the values in register P1..P1+P3-1 over into
64529 ** registers P2..P2+P3-1. Registers P1..P1+P1-1 are
64530 ** left holding a NULL. It is an error for register ranges
64531 ** P1..P1+P3-1 and P2..P2+P3-1 to overlap.
64533 case OP_Move: {
64534 #if 0 /* local variables moved into u.ac */
64535 char *zMalloc; /* Holding variable for allocated memory */
64536 int n; /* Number of registers left to copy */
64537 int p1; /* Register to copy from */
64538 int p2; /* Register to copy to */
64539 #endif /* local variables moved into u.ac */
64541 u.ac.n = pOp->p3;
64542 u.ac.p1 = pOp->p1;
64543 u.ac.p2 = pOp->p2;
64544 assert( u.ac.n>0 && u.ac.p1>0 && u.ac.p2>0 );
64545 assert( u.ac.p1+u.ac.n<=u.ac.p2 || u.ac.p2+u.ac.n<=u.ac.p1 );
64547 pIn1 = &aMem[u.ac.p1];
64548 pOut = &aMem[u.ac.p2];
64549 while( u.ac.n-- ){
64550 assert( pOut<=&aMem[p->nMem] );
64551 assert( pIn1<=&aMem[p->nMem] );
64552 assert( memIsValid(pIn1) );
64553 memAboutToChange(p, pOut);
64554 u.ac.zMalloc = pOut->zMalloc;
64555 pOut->zMalloc = 0;
64556 sqlite3VdbeMemMove(pOut, pIn1);
64557 #ifdef SQLITE_DEBUG
64558 if( pOut->pScopyFrom>=&aMem[u.ac.p1] && pOut->pScopyFrom<&aMem[u.ac.p1+pOp->p3] ){
64559 pOut->pScopyFrom += u.ac.p1 - pOp->p2;
64561 #endif
64562 pIn1->zMalloc = u.ac.zMalloc;
64563 REGISTER_TRACE(u.ac.p2++, pOut);
64564 pIn1++;
64565 pOut++;
64567 break;
64570 /* Opcode: Copy P1 P2 * * *
64572 ** Make a copy of register P1 into register P2.
64574 ** This instruction makes a deep copy of the value. A duplicate
64575 ** is made of any string or blob constant. See also OP_SCopy.
64577 case OP_Copy: { /* in1, out2 */
64578 pIn1 = &aMem[pOp->p1];
64579 pOut = &aMem[pOp->p2];
64580 assert( pOut!=pIn1 );
64581 sqlite3VdbeMemShallowCopy(pOut, pIn1, MEM_Ephem);
64582 Deephemeralize(pOut);
64583 REGISTER_TRACE(pOp->p2, pOut);
64584 break;
64587 /* Opcode: SCopy P1 P2 * * *
64589 ** Make a shallow copy of register P1 into register P2.
64591 ** This instruction makes a shallow copy of the value. If the value
64592 ** is a string or blob, then the copy is only a pointer to the
64593 ** original and hence if the original changes so will the copy.
64594 ** Worse, if the original is deallocated, the copy becomes invalid.
64595 ** Thus the program must guarantee that the original will not change
64596 ** during the lifetime of the copy. Use OP_Copy to make a complete
64597 ** copy.
64599 case OP_SCopy: { /* in1, out2 */
64600 pIn1 = &aMem[pOp->p1];
64601 pOut = &aMem[pOp->p2];
64602 assert( pOut!=pIn1 );
64603 sqlite3VdbeMemShallowCopy(pOut, pIn1, MEM_Ephem);
64604 #ifdef SQLITE_DEBUG
64605 if( pOut->pScopyFrom==0 ) pOut->pScopyFrom = pIn1;
64606 #endif
64607 REGISTER_TRACE(pOp->p2, pOut);
64608 break;
64611 /* Opcode: ResultRow P1 P2 * * *
64613 ** The registers P1 through P1+P2-1 contain a single row of
64614 ** results. This opcode causes the sqlite3_step() call to terminate
64615 ** with an SQLITE_ROW return code and it sets up the sqlite3_stmt
64616 ** structure to provide access to the top P1 values as the result
64617 ** row.
64619 case OP_ResultRow: {
64620 #if 0 /* local variables moved into u.ad */
64621 Mem *pMem;
64622 int i;
64623 #endif /* local variables moved into u.ad */
64624 assert( p->nResColumn==pOp->p2 );
64625 assert( pOp->p1>0 );
64626 assert( pOp->p1+pOp->p2<=p->nMem+1 );
64628 /* If this statement has violated immediate foreign key constraints, do
64629 ** not return the number of rows modified. And do not RELEASE the statement
64630 ** transaction. It needs to be rolled back. */
64631 if( SQLITE_OK!=(rc = sqlite3VdbeCheckFk(p, 0)) ){
64632 assert( db->flags&SQLITE_CountRows );
64633 assert( p->usesStmtJournal );
64634 break;
64637 /* If the SQLITE_CountRows flag is set in sqlite3.flags mask, then
64638 ** DML statements invoke this opcode to return the number of rows
64639 ** modified to the user. This is the only way that a VM that
64640 ** opens a statement transaction may invoke this opcode.
64642 ** In case this is such a statement, close any statement transaction
64643 ** opened by this VM before returning control to the user. This is to
64644 ** ensure that statement-transactions are always nested, not overlapping.
64645 ** If the open statement-transaction is not closed here, then the user
64646 ** may step another VM that opens its own statement transaction. This
64647 ** may lead to overlapping statement transactions.
64649 ** The statement transaction is never a top-level transaction. Hence
64650 ** the RELEASE call below can never fail.
64652 assert( p->iStatement==0 || db->flags&SQLITE_CountRows );
64653 rc = sqlite3VdbeCloseStatement(p, SAVEPOINT_RELEASE);
64654 if( NEVER(rc!=SQLITE_OK) ){
64655 break;
64658 /* Invalidate all ephemeral cursor row caches */
64659 p->cacheCtr = (p->cacheCtr + 2)|1;
64661 /* Make sure the results of the current row are \000 terminated
64662 ** and have an assigned type. The results are de-ephemeralized as
64663 ** as side effect.
64665 u.ad.pMem = p->pResultSet = &aMem[pOp->p1];
64666 for(u.ad.i=0; u.ad.i<pOp->p2; u.ad.i++){
64667 assert( memIsValid(&u.ad.pMem[u.ad.i]) );
64668 Deephemeralize(&u.ad.pMem[u.ad.i]);
64669 assert( (u.ad.pMem[u.ad.i].flags & MEM_Ephem)==0
64670 || (u.ad.pMem[u.ad.i].flags & (MEM_Str|MEM_Blob))==0 );
64671 sqlite3VdbeMemNulTerminate(&u.ad.pMem[u.ad.i]);
64672 sqlite3VdbeMemStoreType(&u.ad.pMem[u.ad.i]);
64673 REGISTER_TRACE(pOp->p1+u.ad.i, &u.ad.pMem[u.ad.i]);
64675 if( db->mallocFailed ) goto no_mem;
64677 /* Return SQLITE_ROW
64679 p->pc = pc + 1;
64680 rc = SQLITE_ROW;
64681 goto vdbe_return;
64684 /* Opcode: Concat P1 P2 P3 * *
64686 ** Add the text in register P1 onto the end of the text in
64687 ** register P2 and store the result in register P3.
64688 ** If either the P1 or P2 text are NULL then store NULL in P3.
64690 ** P3 = P2 || P1
64692 ** It is illegal for P1 and P3 to be the same register. Sometimes,
64693 ** if P3 is the same register as P2, the implementation is able
64694 ** to avoid a memcpy().
64696 case OP_Concat: { /* same as TK_CONCAT, in1, in2, out3 */
64697 #if 0 /* local variables moved into u.ae */
64698 i64 nByte;
64699 #endif /* local variables moved into u.ae */
64701 pIn1 = &aMem[pOp->p1];
64702 pIn2 = &aMem[pOp->p2];
64703 pOut = &aMem[pOp->p3];
64704 assert( pIn1!=pOut );
64705 if( (pIn1->flags | pIn2->flags) & MEM_Null ){
64706 sqlite3VdbeMemSetNull(pOut);
64707 break;
64709 if( ExpandBlob(pIn1) || ExpandBlob(pIn2) ) goto no_mem;
64710 Stringify(pIn1, encoding);
64711 Stringify(pIn2, encoding);
64712 u.ae.nByte = pIn1->n + pIn2->n;
64713 if( u.ae.nByte>db->aLimit[SQLITE_LIMIT_LENGTH] ){
64714 goto too_big;
64716 MemSetTypeFlag(pOut, MEM_Str);
64717 if( sqlite3VdbeMemGrow(pOut, (int)u.ae.nByte+2, pOut==pIn2) ){
64718 goto no_mem;
64720 if( pOut!=pIn2 ){
64721 memcpy(pOut->z, pIn2->z, pIn2->n);
64723 memcpy(&pOut->z[pIn2->n], pIn1->z, pIn1->n);
64724 pOut->z[u.ae.nByte] = 0;
64725 pOut->z[u.ae.nByte+1] = 0;
64726 pOut->flags |= MEM_Term;
64727 pOut->n = (int)u.ae.nByte;
64728 pOut->enc = encoding;
64729 UPDATE_MAX_BLOBSIZE(pOut);
64730 break;
64733 /* Opcode: Add P1 P2 P3 * *
64735 ** Add the value in register P1 to the value in register P2
64736 ** and store the result in register P3.
64737 ** If either input is NULL, the result is NULL.
64739 /* Opcode: Multiply P1 P2 P3 * *
64742 ** Multiply the value in register P1 by the value in register P2
64743 ** and store the result in register P3.
64744 ** If either input is NULL, the result is NULL.
64746 /* Opcode: Subtract P1 P2 P3 * *
64748 ** Subtract the value in register P1 from the value in register P2
64749 ** and store the result in register P3.
64750 ** If either input is NULL, the result is NULL.
64752 /* Opcode: Divide P1 P2 P3 * *
64754 ** Divide the value in register P1 by the value in register P2
64755 ** and store the result in register P3 (P3=P2/P1). If the value in
64756 ** register P1 is zero, then the result is NULL. If either input is
64757 ** NULL, the result is NULL.
64759 /* Opcode: Remainder P1 P2 P3 * *
64761 ** Compute the remainder after integer division of the value in
64762 ** register P1 by the value in register P2 and store the result in P3.
64763 ** If the value in register P2 is zero the result is NULL.
64764 ** If either operand is NULL, the result is NULL.
64766 case OP_Add: /* same as TK_PLUS, in1, in2, out3 */
64767 case OP_Subtract: /* same as TK_MINUS, in1, in2, out3 */
64768 case OP_Multiply: /* same as TK_STAR, in1, in2, out3 */
64769 case OP_Divide: /* same as TK_SLASH, in1, in2, out3 */
64770 case OP_Remainder: { /* same as TK_REM, in1, in2, out3 */
64771 #if 0 /* local variables moved into u.af */
64772 int flags; /* Combined MEM_* flags from both inputs */
64773 i64 iA; /* Integer value of left operand */
64774 i64 iB; /* Integer value of right operand */
64775 double rA; /* Real value of left operand */
64776 double rB; /* Real value of right operand */
64777 #endif /* local variables moved into u.af */
64779 pIn1 = &aMem[pOp->p1];
64780 applyNumericAffinity(pIn1);
64781 pIn2 = &aMem[pOp->p2];
64782 applyNumericAffinity(pIn2);
64783 pOut = &aMem[pOp->p3];
64784 u.af.flags = pIn1->flags | pIn2->flags;
64785 if( (u.af.flags & MEM_Null)!=0 ) goto arithmetic_result_is_null;
64786 if( (pIn1->flags & pIn2->flags & MEM_Int)==MEM_Int ){
64787 u.af.iA = pIn1->u.i;
64788 u.af.iB = pIn2->u.i;
64789 switch( pOp->opcode ){
64790 case OP_Add: if( sqlite3AddInt64(&u.af.iB,u.af.iA) ) goto fp_math; break;
64791 case OP_Subtract: if( sqlite3SubInt64(&u.af.iB,u.af.iA) ) goto fp_math; break;
64792 case OP_Multiply: if( sqlite3MulInt64(&u.af.iB,u.af.iA) ) goto fp_math; break;
64793 case OP_Divide: {
64794 if( u.af.iA==0 ) goto arithmetic_result_is_null;
64795 if( u.af.iA==-1 && u.af.iB==SMALLEST_INT64 ) goto fp_math;
64796 u.af.iB /= u.af.iA;
64797 break;
64799 default: {
64800 if( u.af.iA==0 ) goto arithmetic_result_is_null;
64801 if( u.af.iA==-1 ) u.af.iA = 1;
64802 u.af.iB %= u.af.iA;
64803 break;
64806 pOut->u.i = u.af.iB;
64807 MemSetTypeFlag(pOut, MEM_Int);
64808 }else{
64809 fp_math:
64810 u.af.rA = sqlite3VdbeRealValue(pIn1);
64811 u.af.rB = sqlite3VdbeRealValue(pIn2);
64812 switch( pOp->opcode ){
64813 case OP_Add: u.af.rB += u.af.rA; break;
64814 case OP_Subtract: u.af.rB -= u.af.rA; break;
64815 case OP_Multiply: u.af.rB *= u.af.rA; break;
64816 case OP_Divide: {
64817 /* (double)0 In case of SQLITE_OMIT_FLOATING_POINT... */
64818 if( u.af.rA==(double)0 ) goto arithmetic_result_is_null;
64819 u.af.rB /= u.af.rA;
64820 break;
64822 default: {
64823 u.af.iA = (i64)u.af.rA;
64824 u.af.iB = (i64)u.af.rB;
64825 if( u.af.iA==0 ) goto arithmetic_result_is_null;
64826 if( u.af.iA==-1 ) u.af.iA = 1;
64827 u.af.rB = (double)(u.af.iB % u.af.iA);
64828 break;
64831 #ifdef SQLITE_OMIT_FLOATING_POINT
64832 pOut->u.i = u.af.rB;
64833 MemSetTypeFlag(pOut, MEM_Int);
64834 #else
64835 if( sqlite3IsNaN(u.af.rB) ){
64836 goto arithmetic_result_is_null;
64838 pOut->r = u.af.rB;
64839 MemSetTypeFlag(pOut, MEM_Real);
64840 if( (u.af.flags & MEM_Real)==0 ){
64841 sqlite3VdbeIntegerAffinity(pOut);
64843 #endif
64845 break;
64847 arithmetic_result_is_null:
64848 sqlite3VdbeMemSetNull(pOut);
64849 break;
64852 /* Opcode: CollSeq * * P4
64854 ** P4 is a pointer to a CollSeq struct. If the next call to a user function
64855 ** or aggregate calls sqlite3GetFuncCollSeq(), this collation sequence will
64856 ** be returned. This is used by the built-in min(), max() and nullif()
64857 ** functions.
64859 ** The interface used by the implementation of the aforementioned functions
64860 ** to retrieve the collation sequence set by this opcode is not available
64861 ** publicly, only to user functions defined in func.c.
64863 case OP_CollSeq: {
64864 assert( pOp->p4type==P4_COLLSEQ );
64865 break;
64868 /* Opcode: Function P1 P2 P3 P4 P5
64870 ** Invoke a user function (P4 is a pointer to a Function structure that
64871 ** defines the function) with P5 arguments taken from register P2 and
64872 ** successors. The result of the function is stored in register P3.
64873 ** Register P3 must not be one of the function inputs.
64875 ** P1 is a 32-bit bitmask indicating whether or not each argument to the
64876 ** function was determined to be constant at compile time. If the first
64877 ** argument was constant then bit 0 of P1 is set. This is used to determine
64878 ** whether meta data associated with a user function argument using the
64879 ** sqlite3_set_auxdata() API may be safely retained until the next
64880 ** invocation of this opcode.
64882 ** See also: AggStep and AggFinal
64884 case OP_Function: {
64885 #if 0 /* local variables moved into u.ag */
64886 int i;
64887 Mem *pArg;
64888 sqlite3_context ctx;
64889 sqlite3_value **apVal;
64890 int n;
64891 #endif /* local variables moved into u.ag */
64893 u.ag.n = pOp->p5;
64894 u.ag.apVal = p->apArg;
64895 assert( u.ag.apVal || u.ag.n==0 );
64896 assert( pOp->p3>0 && pOp->p3<=p->nMem );
64897 pOut = &aMem[pOp->p3];
64898 memAboutToChange(p, pOut);
64900 assert( u.ag.n==0 || (pOp->p2>0 && pOp->p2+u.ag.n<=p->nMem+1) );
64901 assert( pOp->p3<pOp->p2 || pOp->p3>=pOp->p2+u.ag.n );
64902 u.ag.pArg = &aMem[pOp->p2];
64903 for(u.ag.i=0; u.ag.i<u.ag.n; u.ag.i++, u.ag.pArg++){
64904 assert( memIsValid(u.ag.pArg) );
64905 u.ag.apVal[u.ag.i] = u.ag.pArg;
64906 Deephemeralize(u.ag.pArg);
64907 sqlite3VdbeMemStoreType(u.ag.pArg);
64908 REGISTER_TRACE(pOp->p2+u.ag.i, u.ag.pArg);
64911 assert( pOp->p4type==P4_FUNCDEF || pOp->p4type==P4_VDBEFUNC );
64912 if( pOp->p4type==P4_FUNCDEF ){
64913 u.ag.ctx.pFunc = pOp->p4.pFunc;
64914 u.ag.ctx.pVdbeFunc = 0;
64915 }else{
64916 u.ag.ctx.pVdbeFunc = (VdbeFunc*)pOp->p4.pVdbeFunc;
64917 u.ag.ctx.pFunc = u.ag.ctx.pVdbeFunc->pFunc;
64920 u.ag.ctx.s.flags = MEM_Null;
64921 u.ag.ctx.s.db = db;
64922 u.ag.ctx.s.xDel = 0;
64923 u.ag.ctx.s.zMalloc = 0;
64925 /* The output cell may already have a buffer allocated. Move
64926 ** the pointer to u.ag.ctx.s so in case the user-function can use
64927 ** the already allocated buffer instead of allocating a new one.
64929 sqlite3VdbeMemMove(&u.ag.ctx.s, pOut);
64930 MemSetTypeFlag(&u.ag.ctx.s, MEM_Null);
64932 u.ag.ctx.isError = 0;
64933 if( u.ag.ctx.pFunc->flags & SQLITE_FUNC_NEEDCOLL ){
64934 assert( pOp>aOp );
64935 assert( pOp[-1].p4type==P4_COLLSEQ );
64936 assert( pOp[-1].opcode==OP_CollSeq );
64937 u.ag.ctx.pColl = pOp[-1].p4.pColl;
64939 db->lastRowid = lastRowid;
64940 (*u.ag.ctx.pFunc->xFunc)(&u.ag.ctx, u.ag.n, u.ag.apVal); /* IMP: R-24505-23230 */
64941 lastRowid = db->lastRowid;
64943 /* If any auxiliary data functions have been called by this user function,
64944 ** immediately call the destructor for any non-static values.
64946 if( u.ag.ctx.pVdbeFunc ){
64947 sqlite3VdbeDeleteAuxData(u.ag.ctx.pVdbeFunc, pOp->p1);
64948 pOp->p4.pVdbeFunc = u.ag.ctx.pVdbeFunc;
64949 pOp->p4type = P4_VDBEFUNC;
64952 if( db->mallocFailed ){
64953 /* Even though a malloc() has failed, the implementation of the
64954 ** user function may have called an sqlite3_result_XXX() function
64955 ** to return a value. The following call releases any resources
64956 ** associated with such a value.
64958 sqlite3VdbeMemRelease(&u.ag.ctx.s);
64959 goto no_mem;
64962 /* If the function returned an error, throw an exception */
64963 if( u.ag.ctx.isError ){
64964 sqlite3SetString(&p->zErrMsg, db, "%s", sqlite3_value_text(&u.ag.ctx.s));
64965 rc = u.ag.ctx.isError;
64968 /* Copy the result of the function into register P3 */
64969 sqlite3VdbeChangeEncoding(&u.ag.ctx.s, encoding);
64970 sqlite3VdbeMemMove(pOut, &u.ag.ctx.s);
64971 if( sqlite3VdbeMemTooBig(pOut) ){
64972 goto too_big;
64975 #if 0
64976 /* The app-defined function has done something that as caused this
64977 ** statement to expire. (Perhaps the function called sqlite3_exec()
64978 ** with a CREATE TABLE statement.)
64980 if( p->expired ) rc = SQLITE_ABORT;
64981 #endif
64983 REGISTER_TRACE(pOp->p3, pOut);
64984 UPDATE_MAX_BLOBSIZE(pOut);
64985 break;
64988 /* Opcode: BitAnd P1 P2 P3 * *
64990 ** Take the bit-wise AND of the values in register P1 and P2 and
64991 ** store the result in register P3.
64992 ** If either input is NULL, the result is NULL.
64994 /* Opcode: BitOr P1 P2 P3 * *
64996 ** Take the bit-wise OR of the values in register P1 and P2 and
64997 ** store the result in register P3.
64998 ** If either input is NULL, the result is NULL.
65000 /* Opcode: ShiftLeft P1 P2 P3 * *
65002 ** Shift the integer value in register P2 to the left by the
65003 ** number of bits specified by the integer in register P1.
65004 ** Store the result in register P3.
65005 ** If either input is NULL, the result is NULL.
65007 /* Opcode: ShiftRight P1 P2 P3 * *
65009 ** Shift the integer value in register P2 to the right by the
65010 ** number of bits specified by the integer in register P1.
65011 ** Store the result in register P3.
65012 ** If either input is NULL, the result is NULL.
65014 case OP_BitAnd: /* same as TK_BITAND, in1, in2, out3 */
65015 case OP_BitOr: /* same as TK_BITOR, in1, in2, out3 */
65016 case OP_ShiftLeft: /* same as TK_LSHIFT, in1, in2, out3 */
65017 case OP_ShiftRight: { /* same as TK_RSHIFT, in1, in2, out3 */
65018 #if 0 /* local variables moved into u.ah */
65019 i64 iA;
65020 u64 uA;
65021 i64 iB;
65022 u8 op;
65023 #endif /* local variables moved into u.ah */
65025 pIn1 = &aMem[pOp->p1];
65026 pIn2 = &aMem[pOp->p2];
65027 pOut = &aMem[pOp->p3];
65028 if( (pIn1->flags | pIn2->flags) & MEM_Null ){
65029 sqlite3VdbeMemSetNull(pOut);
65030 break;
65032 u.ah.iA = sqlite3VdbeIntValue(pIn2);
65033 u.ah.iB = sqlite3VdbeIntValue(pIn1);
65034 u.ah.op = pOp->opcode;
65035 if( u.ah.op==OP_BitAnd ){
65036 u.ah.iA &= u.ah.iB;
65037 }else if( u.ah.op==OP_BitOr ){
65038 u.ah.iA |= u.ah.iB;
65039 }else if( u.ah.iB!=0 ){
65040 assert( u.ah.op==OP_ShiftRight || u.ah.op==OP_ShiftLeft );
65042 /* If shifting by a negative amount, shift in the other direction */
65043 if( u.ah.iB<0 ){
65044 assert( OP_ShiftRight==OP_ShiftLeft+1 );
65045 u.ah.op = 2*OP_ShiftLeft + 1 - u.ah.op;
65046 u.ah.iB = u.ah.iB>(-64) ? -u.ah.iB : 64;
65049 if( u.ah.iB>=64 ){
65050 u.ah.iA = (u.ah.iA>=0 || u.ah.op==OP_ShiftLeft) ? 0 : -1;
65051 }else{
65052 memcpy(&u.ah.uA, &u.ah.iA, sizeof(u.ah.uA));
65053 if( u.ah.op==OP_ShiftLeft ){
65054 u.ah.uA <<= u.ah.iB;
65055 }else{
65056 u.ah.uA >>= u.ah.iB;
65057 /* Sign-extend on a right shift of a negative number */
65058 if( u.ah.iA<0 ) u.ah.uA |= ((((u64)0xffffffff)<<32)|0xffffffff) << (64-u.ah.iB);
65060 memcpy(&u.ah.iA, &u.ah.uA, sizeof(u.ah.iA));
65063 pOut->u.i = u.ah.iA;
65064 MemSetTypeFlag(pOut, MEM_Int);
65065 break;
65068 /* Opcode: AddImm P1 P2 * * *
65070 ** Add the constant P2 to the value in register P1.
65071 ** The result is always an integer.
65073 ** To force any register to be an integer, just add 0.
65075 case OP_AddImm: { /* in1 */
65076 pIn1 = &aMem[pOp->p1];
65077 memAboutToChange(p, pIn1);
65078 sqlite3VdbeMemIntegerify(pIn1);
65079 pIn1->u.i += pOp->p2;
65080 break;
65083 /* Opcode: MustBeInt P1 P2 * * *
65085 ** Force the value in register P1 to be an integer. If the value
65086 ** in P1 is not an integer and cannot be converted into an integer
65087 ** without data loss, then jump immediately to P2, or if P2==0
65088 ** raise an SQLITE_MISMATCH exception.
65090 case OP_MustBeInt: { /* jump, in1 */
65091 pIn1 = &aMem[pOp->p1];
65092 applyAffinity(pIn1, SQLITE_AFF_NUMERIC, encoding);
65093 if( (pIn1->flags & MEM_Int)==0 ){
65094 if( pOp->p2==0 ){
65095 rc = SQLITE_MISMATCH;
65096 goto abort_due_to_error;
65097 }else{
65098 pc = pOp->p2 - 1;
65100 }else{
65101 MemSetTypeFlag(pIn1, MEM_Int);
65103 break;
65106 #ifndef SQLITE_OMIT_FLOATING_POINT
65107 /* Opcode: RealAffinity P1 * * * *
65109 ** If register P1 holds an integer convert it to a real value.
65111 ** This opcode is used when extracting information from a column that
65112 ** has REAL affinity. Such column values may still be stored as
65113 ** integers, for space efficiency, but after extraction we want them
65114 ** to have only a real value.
65116 case OP_RealAffinity: { /* in1 */
65117 pIn1 = &aMem[pOp->p1];
65118 if( pIn1->flags & MEM_Int ){
65119 sqlite3VdbeMemRealify(pIn1);
65121 break;
65123 #endif
65125 #ifndef SQLITE_OMIT_CAST
65126 /* Opcode: ToText P1 * * * *
65128 ** Force the value in register P1 to be text.
65129 ** If the value is numeric, convert it to a string using the
65130 ** equivalent of printf(). Blob values are unchanged and
65131 ** are afterwards simply interpreted as text.
65133 ** A NULL value is not changed by this routine. It remains NULL.
65135 case OP_ToText: { /* same as TK_TO_TEXT, in1 */
65136 pIn1 = &aMem[pOp->p1];
65137 memAboutToChange(p, pIn1);
65138 if( pIn1->flags & MEM_Null ) break;
65139 assert( MEM_Str==(MEM_Blob>>3) );
65140 pIn1->flags |= (pIn1->flags&MEM_Blob)>>3;
65141 applyAffinity(pIn1, SQLITE_AFF_TEXT, encoding);
65142 rc = ExpandBlob(pIn1);
65143 assert( pIn1->flags & MEM_Str || db->mallocFailed );
65144 pIn1->flags &= ~(MEM_Int|MEM_Real|MEM_Blob|MEM_Zero);
65145 UPDATE_MAX_BLOBSIZE(pIn1);
65146 break;
65149 /* Opcode: ToBlob P1 * * * *
65151 ** Force the value in register P1 to be a BLOB.
65152 ** If the value is numeric, convert it to a string first.
65153 ** Strings are simply reinterpreted as blobs with no change
65154 ** to the underlying data.
65156 ** A NULL value is not changed by this routine. It remains NULL.
65158 case OP_ToBlob: { /* same as TK_TO_BLOB, in1 */
65159 pIn1 = &aMem[pOp->p1];
65160 if( pIn1->flags & MEM_Null ) break;
65161 if( (pIn1->flags & MEM_Blob)==0 ){
65162 applyAffinity(pIn1, SQLITE_AFF_TEXT, encoding);
65163 assert( pIn1->flags & MEM_Str || db->mallocFailed );
65164 MemSetTypeFlag(pIn1, MEM_Blob);
65165 }else{
65166 pIn1->flags &= ~(MEM_TypeMask&~MEM_Blob);
65168 UPDATE_MAX_BLOBSIZE(pIn1);
65169 break;
65172 /* Opcode: ToNumeric P1 * * * *
65174 ** Force the value in register P1 to be numeric (either an
65175 ** integer or a floating-point number.)
65176 ** If the value is text or blob, try to convert it to an using the
65177 ** equivalent of atoi() or atof() and store 0 if no such conversion
65178 ** is possible.
65180 ** A NULL value is not changed by this routine. It remains NULL.
65182 case OP_ToNumeric: { /* same as TK_TO_NUMERIC, in1 */
65183 pIn1 = &aMem[pOp->p1];
65184 sqlite3VdbeMemNumerify(pIn1);
65185 break;
65187 #endif /* SQLITE_OMIT_CAST */
65189 /* Opcode: ToInt P1 * * * *
65191 ** Force the value in register P1 to be an integer. If
65192 ** The value is currently a real number, drop its fractional part.
65193 ** If the value is text or blob, try to convert it to an integer using the
65194 ** equivalent of atoi() and store 0 if no such conversion is possible.
65196 ** A NULL value is not changed by this routine. It remains NULL.
65198 case OP_ToInt: { /* same as TK_TO_INT, in1 */
65199 pIn1 = &aMem[pOp->p1];
65200 if( (pIn1->flags & MEM_Null)==0 ){
65201 sqlite3VdbeMemIntegerify(pIn1);
65203 break;
65206 #if !defined(SQLITE_OMIT_CAST) && !defined(SQLITE_OMIT_FLOATING_POINT)
65207 /* Opcode: ToReal P1 * * * *
65209 ** Force the value in register P1 to be a floating point number.
65210 ** If The value is currently an integer, convert it.
65211 ** If the value is text or blob, try to convert it to an integer using the
65212 ** equivalent of atoi() and store 0.0 if no such conversion is possible.
65214 ** A NULL value is not changed by this routine. It remains NULL.
65216 case OP_ToReal: { /* same as TK_TO_REAL, in1 */
65217 pIn1 = &aMem[pOp->p1];
65218 memAboutToChange(p, pIn1);
65219 if( (pIn1->flags & MEM_Null)==0 ){
65220 sqlite3VdbeMemRealify(pIn1);
65222 break;
65224 #endif /* !defined(SQLITE_OMIT_CAST) && !defined(SQLITE_OMIT_FLOATING_POINT) */
65226 /* Opcode: Lt P1 P2 P3 P4 P5
65228 ** Compare the values in register P1 and P3. If reg(P3)<reg(P1) then
65229 ** jump to address P2.
65231 ** If the SQLITE_JUMPIFNULL bit of P5 is set and either reg(P1) or
65232 ** reg(P3) is NULL then take the jump. If the SQLITE_JUMPIFNULL
65233 ** bit is clear then fall through if either operand is NULL.
65235 ** The SQLITE_AFF_MASK portion of P5 must be an affinity character -
65236 ** SQLITE_AFF_TEXT, SQLITE_AFF_INTEGER, and so forth. An attempt is made
65237 ** to coerce both inputs according to this affinity before the
65238 ** comparison is made. If the SQLITE_AFF_MASK is 0x00, then numeric
65239 ** affinity is used. Note that the affinity conversions are stored
65240 ** back into the input registers P1 and P3. So this opcode can cause
65241 ** persistent changes to registers P1 and P3.
65243 ** Once any conversions have taken place, and neither value is NULL,
65244 ** the values are compared. If both values are blobs then memcmp() is
65245 ** used to determine the results of the comparison. If both values
65246 ** are text, then the appropriate collating function specified in
65247 ** P4 is used to do the comparison. If P4 is not specified then
65248 ** memcmp() is used to compare text string. If both values are
65249 ** numeric, then a numeric comparison is used. If the two values
65250 ** are of different types, then numbers are considered less than
65251 ** strings and strings are considered less than blobs.
65253 ** If the SQLITE_STOREP2 bit of P5 is set, then do not jump. Instead,
65254 ** store a boolean result (either 0, or 1, or NULL) in register P2.
65256 /* Opcode: Ne P1 P2 P3 P4 P5
65258 ** This works just like the Lt opcode except that the jump is taken if
65259 ** the operands in registers P1 and P3 are not equal. See the Lt opcode for
65260 ** additional information.
65262 ** If SQLITE_NULLEQ is set in P5 then the result of comparison is always either
65263 ** true or false and is never NULL. If both operands are NULL then the result
65264 ** of comparison is false. If either operand is NULL then the result is true.
65265 ** If neither operand is NULL the result is the same as it would be if
65266 ** the SQLITE_NULLEQ flag were omitted from P5.
65268 /* Opcode: Eq P1 P2 P3 P4 P5
65270 ** This works just like the Lt opcode except that the jump is taken if
65271 ** the operands in registers P1 and P3 are equal.
65272 ** See the Lt opcode for additional information.
65274 ** If SQLITE_NULLEQ is set in P5 then the result of comparison is always either
65275 ** true or false and is never NULL. If both operands are NULL then the result
65276 ** of comparison is true. If either operand is NULL then the result is false.
65277 ** If neither operand is NULL the result is the same as it would be if
65278 ** the SQLITE_NULLEQ flag were omitted from P5.
65280 /* Opcode: Le P1 P2 P3 P4 P5
65282 ** This works just like the Lt opcode except that the jump is taken if
65283 ** the content of register P3 is less than or equal to the content of
65284 ** register P1. See the Lt opcode for additional information.
65286 /* Opcode: Gt P1 P2 P3 P4 P5
65288 ** This works just like the Lt opcode except that the jump is taken if
65289 ** the content of register P3 is greater than the content of
65290 ** register P1. See the Lt opcode for additional information.
65292 /* Opcode: Ge P1 P2 P3 P4 P5
65294 ** This works just like the Lt opcode except that the jump is taken if
65295 ** the content of register P3 is greater than or equal to the content of
65296 ** register P1. See the Lt opcode for additional information.
65298 case OP_Eq: /* same as TK_EQ, jump, in1, in3 */
65299 case OP_Ne: /* same as TK_NE, jump, in1, in3 */
65300 case OP_Lt: /* same as TK_LT, jump, in1, in3 */
65301 case OP_Le: /* same as TK_LE, jump, in1, in3 */
65302 case OP_Gt: /* same as TK_GT, jump, in1, in3 */
65303 case OP_Ge: { /* same as TK_GE, jump, in1, in3 */
65304 #if 0 /* local variables moved into u.ai */
65305 int res; /* Result of the comparison of pIn1 against pIn3 */
65306 char affinity; /* Affinity to use for comparison */
65307 u16 flags1; /* Copy of initial value of pIn1->flags */
65308 u16 flags3; /* Copy of initial value of pIn3->flags */
65309 #endif /* local variables moved into u.ai */
65311 pIn1 = &aMem[pOp->p1];
65312 pIn3 = &aMem[pOp->p3];
65313 u.ai.flags1 = pIn1->flags;
65314 u.ai.flags3 = pIn3->flags;
65315 if( (u.ai.flags1 | u.ai.flags3)&MEM_Null ){
65316 /* One or both operands are NULL */
65317 if( pOp->p5 & SQLITE_NULLEQ ){
65318 /* If SQLITE_NULLEQ is set (which will only happen if the operator is
65319 ** OP_Eq or OP_Ne) then take the jump or not depending on whether
65320 ** or not both operands are null.
65322 assert( pOp->opcode==OP_Eq || pOp->opcode==OP_Ne );
65323 u.ai.res = (u.ai.flags1 & u.ai.flags3 & MEM_Null)==0;
65324 }else{
65325 /* SQLITE_NULLEQ is clear and at least one operand is NULL,
65326 ** then the result is always NULL.
65327 ** The jump is taken if the SQLITE_JUMPIFNULL bit is set.
65329 if( pOp->p5 & SQLITE_STOREP2 ){
65330 pOut = &aMem[pOp->p2];
65331 MemSetTypeFlag(pOut, MEM_Null);
65332 REGISTER_TRACE(pOp->p2, pOut);
65333 }else if( pOp->p5 & SQLITE_JUMPIFNULL ){
65334 pc = pOp->p2-1;
65336 break;
65338 }else{
65339 /* Neither operand is NULL. Do a comparison. */
65340 u.ai.affinity = pOp->p5 & SQLITE_AFF_MASK;
65341 if( u.ai.affinity ){
65342 applyAffinity(pIn1, u.ai.affinity, encoding);
65343 applyAffinity(pIn3, u.ai.affinity, encoding);
65344 if( db->mallocFailed ) goto no_mem;
65347 assert( pOp->p4type==P4_COLLSEQ || pOp->p4.pColl==0 );
65348 ExpandBlob(pIn1);
65349 ExpandBlob(pIn3);
65350 u.ai.res = sqlite3MemCompare(pIn3, pIn1, pOp->p4.pColl);
65352 switch( pOp->opcode ){
65353 case OP_Eq: u.ai.res = u.ai.res==0; break;
65354 case OP_Ne: u.ai.res = u.ai.res!=0; break;
65355 case OP_Lt: u.ai.res = u.ai.res<0; break;
65356 case OP_Le: u.ai.res = u.ai.res<=0; break;
65357 case OP_Gt: u.ai.res = u.ai.res>0; break;
65358 default: u.ai.res = u.ai.res>=0; break;
65361 if( pOp->p5 & SQLITE_STOREP2 ){
65362 pOut = &aMem[pOp->p2];
65363 memAboutToChange(p, pOut);
65364 MemSetTypeFlag(pOut, MEM_Int);
65365 pOut->u.i = u.ai.res;
65366 REGISTER_TRACE(pOp->p2, pOut);
65367 }else if( u.ai.res ){
65368 pc = pOp->p2-1;
65371 /* Undo any changes made by applyAffinity() to the input registers. */
65372 pIn1->flags = (pIn1->flags&~MEM_TypeMask) | (u.ai.flags1&MEM_TypeMask);
65373 pIn3->flags = (pIn3->flags&~MEM_TypeMask) | (u.ai.flags3&MEM_TypeMask);
65374 break;
65377 /* Opcode: Permutation * * * P4 *
65379 ** Set the permutation used by the OP_Compare operator to be the array
65380 ** of integers in P4.
65382 ** The permutation is only valid until the next OP_Permutation, OP_Compare,
65383 ** OP_Halt, or OP_ResultRow. Typically the OP_Permutation should occur
65384 ** immediately prior to the OP_Compare.
65386 case OP_Permutation: {
65387 assert( pOp->p4type==P4_INTARRAY );
65388 assert( pOp->p4.ai );
65389 aPermute = pOp->p4.ai;
65390 break;
65393 /* Opcode: Compare P1 P2 P3 P4 *
65395 ** Compare two vectors of registers in reg(P1)..reg(P1+P3-1) (call this
65396 ** vector "A") and in reg(P2)..reg(P2+P3-1) ("B"). Save the result of
65397 ** the comparison for use by the next OP_Jump instruct.
65399 ** P4 is a KeyInfo structure that defines collating sequences and sort
65400 ** orders for the comparison. The permutation applies to registers
65401 ** only. The KeyInfo elements are used sequentially.
65403 ** The comparison is a sort comparison, so NULLs compare equal,
65404 ** NULLs are less than numbers, numbers are less than strings,
65405 ** and strings are less than blobs.
65407 case OP_Compare: {
65408 #if 0 /* local variables moved into u.aj */
65409 int n;
65410 int i;
65411 int p1;
65412 int p2;
65413 const KeyInfo *pKeyInfo;
65414 int idx;
65415 CollSeq *pColl; /* Collating sequence to use on this term */
65416 int bRev; /* True for DESCENDING sort order */
65417 #endif /* local variables moved into u.aj */
65419 u.aj.n = pOp->p3;
65420 u.aj.pKeyInfo = pOp->p4.pKeyInfo;
65421 assert( u.aj.n>0 );
65422 assert( u.aj.pKeyInfo!=0 );
65423 u.aj.p1 = pOp->p1;
65424 u.aj.p2 = pOp->p2;
65425 #if SQLITE_DEBUG
65426 if( aPermute ){
65427 int k, mx = 0;
65428 for(k=0; k<u.aj.n; k++) if( aPermute[k]>mx ) mx = aPermute[k];
65429 assert( u.aj.p1>0 && u.aj.p1+mx<=p->nMem+1 );
65430 assert( u.aj.p2>0 && u.aj.p2+mx<=p->nMem+1 );
65431 }else{
65432 assert( u.aj.p1>0 && u.aj.p1+u.aj.n<=p->nMem+1 );
65433 assert( u.aj.p2>0 && u.aj.p2+u.aj.n<=p->nMem+1 );
65435 #endif /* SQLITE_DEBUG */
65436 for(u.aj.i=0; u.aj.i<u.aj.n; u.aj.i++){
65437 u.aj.idx = aPermute ? aPermute[u.aj.i] : u.aj.i;
65438 assert( memIsValid(&aMem[u.aj.p1+u.aj.idx]) );
65439 assert( memIsValid(&aMem[u.aj.p2+u.aj.idx]) );
65440 REGISTER_TRACE(u.aj.p1+u.aj.idx, &aMem[u.aj.p1+u.aj.idx]);
65441 REGISTER_TRACE(u.aj.p2+u.aj.idx, &aMem[u.aj.p2+u.aj.idx]);
65442 assert( u.aj.i<u.aj.pKeyInfo->nField );
65443 u.aj.pColl = u.aj.pKeyInfo->aColl[u.aj.i];
65444 u.aj.bRev = u.aj.pKeyInfo->aSortOrder[u.aj.i];
65445 iCompare = sqlite3MemCompare(&aMem[u.aj.p1+u.aj.idx], &aMem[u.aj.p2+u.aj.idx], u.aj.pColl);
65446 if( iCompare ){
65447 if( u.aj.bRev ) iCompare = -iCompare;
65448 break;
65451 aPermute = 0;
65452 break;
65455 /* Opcode: Jump P1 P2 P3 * *
65457 ** Jump to the instruction at address P1, P2, or P3 depending on whether
65458 ** in the most recent OP_Compare instruction the P1 vector was less than
65459 ** equal to, or greater than the P2 vector, respectively.
65461 case OP_Jump: { /* jump */
65462 if( iCompare<0 ){
65463 pc = pOp->p1 - 1;
65464 }else if( iCompare==0 ){
65465 pc = pOp->p2 - 1;
65466 }else{
65467 pc = pOp->p3 - 1;
65469 break;
65472 /* Opcode: And P1 P2 P3 * *
65474 ** Take the logical AND of the values in registers P1 and P2 and
65475 ** write the result into register P3.
65477 ** If either P1 or P2 is 0 (false) then the result is 0 even if
65478 ** the other input is NULL. A NULL and true or two NULLs give
65479 ** a NULL output.
65481 /* Opcode: Or P1 P2 P3 * *
65483 ** Take the logical OR of the values in register P1 and P2 and
65484 ** store the answer in register P3.
65486 ** If either P1 or P2 is nonzero (true) then the result is 1 (true)
65487 ** even if the other input is NULL. A NULL and false or two NULLs
65488 ** give a NULL output.
65490 case OP_And: /* same as TK_AND, in1, in2, out3 */
65491 case OP_Or: { /* same as TK_OR, in1, in2, out3 */
65492 #if 0 /* local variables moved into u.ak */
65493 int v1; /* Left operand: 0==FALSE, 1==TRUE, 2==UNKNOWN or NULL */
65494 int v2; /* Right operand: 0==FALSE, 1==TRUE, 2==UNKNOWN or NULL */
65495 #endif /* local variables moved into u.ak */
65497 pIn1 = &aMem[pOp->p1];
65498 if( pIn1->flags & MEM_Null ){
65499 u.ak.v1 = 2;
65500 }else{
65501 u.ak.v1 = sqlite3VdbeIntValue(pIn1)!=0;
65503 pIn2 = &aMem[pOp->p2];
65504 if( pIn2->flags & MEM_Null ){
65505 u.ak.v2 = 2;
65506 }else{
65507 u.ak.v2 = sqlite3VdbeIntValue(pIn2)!=0;
65509 if( pOp->opcode==OP_And ){
65510 static const unsigned char and_logic[] = { 0, 0, 0, 0, 1, 2, 0, 2, 2 };
65511 u.ak.v1 = and_logic[u.ak.v1*3+u.ak.v2];
65512 }else{
65513 static const unsigned char or_logic[] = { 0, 1, 2, 1, 1, 1, 2, 1, 2 };
65514 u.ak.v1 = or_logic[u.ak.v1*3+u.ak.v2];
65516 pOut = &aMem[pOp->p3];
65517 if( u.ak.v1==2 ){
65518 MemSetTypeFlag(pOut, MEM_Null);
65519 }else{
65520 pOut->u.i = u.ak.v1;
65521 MemSetTypeFlag(pOut, MEM_Int);
65523 break;
65526 /* Opcode: Not P1 P2 * * *
65528 ** Interpret the value in register P1 as a boolean value. Store the
65529 ** boolean complement in register P2. If the value in register P1 is
65530 ** NULL, then a NULL is stored in P2.
65532 case OP_Not: { /* same as TK_NOT, in1, out2 */
65533 pIn1 = &aMem[pOp->p1];
65534 pOut = &aMem[pOp->p2];
65535 if( pIn1->flags & MEM_Null ){
65536 sqlite3VdbeMemSetNull(pOut);
65537 }else{
65538 sqlite3VdbeMemSetInt64(pOut, !sqlite3VdbeIntValue(pIn1));
65540 break;
65543 /* Opcode: BitNot P1 P2 * * *
65545 ** Interpret the content of register P1 as an integer. Store the
65546 ** ones-complement of the P1 value into register P2. If P1 holds
65547 ** a NULL then store a NULL in P2.
65549 case OP_BitNot: { /* same as TK_BITNOT, in1, out2 */
65550 pIn1 = &aMem[pOp->p1];
65551 pOut = &aMem[pOp->p2];
65552 if( pIn1->flags & MEM_Null ){
65553 sqlite3VdbeMemSetNull(pOut);
65554 }else{
65555 sqlite3VdbeMemSetInt64(pOut, ~sqlite3VdbeIntValue(pIn1));
65557 break;
65560 /* Opcode: Once P1 P2 * * *
65562 ** Jump to P2 if the value in register P1 is a not null or zero. If
65563 ** the value is NULL or zero, fall through and change the P1 register
65564 ** to an integer 1.
65566 ** When P1 is not used otherwise in a program, this opcode falls through
65567 ** once and jumps on all subsequent invocations. It is the equivalent
65568 ** of "OP_If P1 P2", followed by "OP_Integer 1 P1".
65570 /* Opcode: If P1 P2 P3 * *
65572 ** Jump to P2 if the value in register P1 is true. The value
65573 ** is considered true if it is numeric and non-zero. If the value
65574 ** in P1 is NULL then take the jump if P3 is true.
65576 /* Opcode: IfNot P1 P2 P3 * *
65578 ** Jump to P2 if the value in register P1 is False. The value
65579 ** is considered true if it has a numeric value of zero. If the value
65580 ** in P1 is NULL then take the jump if P3 is true.
65582 case OP_Once: /* jump, in1 */
65583 case OP_If: /* jump, in1 */
65584 case OP_IfNot: { /* jump, in1 */
65585 #if 0 /* local variables moved into u.al */
65586 int c;
65587 #endif /* local variables moved into u.al */
65588 pIn1 = &aMem[pOp->p1];
65589 if( pIn1->flags & MEM_Null ){
65590 u.al.c = pOp->p3;
65591 }else{
65592 #ifdef SQLITE_OMIT_FLOATING_POINT
65593 u.al.c = sqlite3VdbeIntValue(pIn1)!=0;
65594 #else
65595 u.al.c = sqlite3VdbeRealValue(pIn1)!=0.0;
65596 #endif
65597 if( pOp->opcode==OP_IfNot ) u.al.c = !u.al.c;
65599 if( u.al.c ){
65600 pc = pOp->p2-1;
65601 }else if( pOp->opcode==OP_Once ){
65602 assert( (pIn1->flags & (MEM_Agg|MEM_Dyn|MEM_RowSet|MEM_Frame))==0 );
65603 memAboutToChange(p, pIn1);
65604 pIn1->flags = MEM_Int;
65605 pIn1->u.i = 1;
65606 REGISTER_TRACE(pOp->p1, pIn1);
65608 break;
65611 /* Opcode: IsNull P1 P2 * * *
65613 ** Jump to P2 if the value in register P1 is NULL.
65615 case OP_IsNull: { /* same as TK_ISNULL, jump, in1 */
65616 pIn1 = &aMem[pOp->p1];
65617 if( (pIn1->flags & MEM_Null)!=0 ){
65618 pc = pOp->p2 - 1;
65620 break;
65623 /* Opcode: NotNull P1 P2 * * *
65625 ** Jump to P2 if the value in register P1 is not NULL.
65627 case OP_NotNull: { /* same as TK_NOTNULL, jump, in1 */
65628 pIn1 = &aMem[pOp->p1];
65629 if( (pIn1->flags & MEM_Null)==0 ){
65630 pc = pOp->p2 - 1;
65632 break;
65635 /* Opcode: Column P1 P2 P3 P4 P5
65637 ** Interpret the data that cursor P1 points to as a structure built using
65638 ** the MakeRecord instruction. (See the MakeRecord opcode for additional
65639 ** information about the format of the data.) Extract the P2-th column
65640 ** from this record. If there are less that (P2+1)
65641 ** values in the record, extract a NULL.
65643 ** The value extracted is stored in register P3.
65645 ** If the column contains fewer than P2 fields, then extract a NULL. Or,
65646 ** if the P4 argument is a P4_MEM use the value of the P4 argument as
65647 ** the result.
65649 ** If the OPFLAG_CLEARCACHE bit is set on P5 and P1 is a pseudo-table cursor,
65650 ** then the cache of the cursor is reset prior to extracting the column.
65651 ** The first OP_Column against a pseudo-table after the value of the content
65652 ** register has changed should have this bit set.
65654 case OP_Column: {
65655 #if 0 /* local variables moved into u.am */
65656 u32 payloadSize; /* Number of bytes in the record */
65657 i64 payloadSize64; /* Number of bytes in the record */
65658 int p1; /* P1 value of the opcode */
65659 int p2; /* column number to retrieve */
65660 VdbeCursor *pC; /* The VDBE cursor */
65661 char *zRec; /* Pointer to complete record-data */
65662 BtCursor *pCrsr; /* The BTree cursor */
65663 u32 *aType; /* aType[i] holds the numeric type of the i-th column */
65664 u32 *aOffset; /* aOffset[i] is offset to start of data for i-th column */
65665 int nField; /* number of fields in the record */
65666 int len; /* The length of the serialized data for the column */
65667 int i; /* Loop counter */
65668 char *zData; /* Part of the record being decoded */
65669 Mem *pDest; /* Where to write the extracted value */
65670 Mem sMem; /* For storing the record being decoded */
65671 u8 *zIdx; /* Index into header */
65672 u8 *zEndHdr; /* Pointer to first byte after the header */
65673 u32 offset; /* Offset into the data */
65674 u32 szField; /* Number of bytes in the content of a field */
65675 int szHdr; /* Size of the header size field at start of record */
65676 int avail; /* Number of bytes of available data */
65677 u32 t; /* A type code from the record header */
65678 Mem *pReg; /* PseudoTable input register */
65679 #endif /* local variables moved into u.am */
65682 u.am.p1 = pOp->p1;
65683 u.am.p2 = pOp->p2;
65684 u.am.pC = 0;
65685 memset(&u.am.sMem, 0, sizeof(u.am.sMem));
65686 assert( u.am.p1<p->nCursor );
65687 assert( pOp->p3>0 && pOp->p3<=p->nMem );
65688 u.am.pDest = &aMem[pOp->p3];
65689 memAboutToChange(p, u.am.pDest);
65690 u.am.zRec = 0;
65692 /* This block sets the variable u.am.payloadSize to be the total number of
65693 ** bytes in the record.
65695 ** u.am.zRec is set to be the complete text of the record if it is available.
65696 ** The complete record text is always available for pseudo-tables
65697 ** If the record is stored in a cursor, the complete record text
65698 ** might be available in the u.am.pC->aRow cache. Or it might not be.
65699 ** If the data is unavailable, u.am.zRec is set to NULL.
65701 ** We also compute the number of columns in the record. For cursors,
65702 ** the number of columns is stored in the VdbeCursor.nField element.
65704 u.am.pC = p->apCsr[u.am.p1];
65705 assert( u.am.pC!=0 );
65706 #ifndef SQLITE_OMIT_VIRTUALTABLE
65707 assert( u.am.pC->pVtabCursor==0 );
65708 #endif
65709 u.am.pCrsr = u.am.pC->pCursor;
65710 if( u.am.pCrsr!=0 ){
65711 /* The record is stored in a B-Tree */
65712 rc = sqlite3VdbeCursorMoveto(u.am.pC);
65713 if( rc ) goto abort_due_to_error;
65714 if( u.am.pC->nullRow ){
65715 u.am.payloadSize = 0;
65716 }else if( u.am.pC->cacheStatus==p->cacheCtr ){
65717 u.am.payloadSize = u.am.pC->payloadSize;
65718 u.am.zRec = (char*)u.am.pC->aRow;
65719 }else if( u.am.pC->isIndex ){
65720 assert( sqlite3BtreeCursorIsValid(u.am.pCrsr) );
65721 rc = sqlite3BtreeKeySize(u.am.pCrsr, &u.am.payloadSize64);
65722 assert( rc==SQLITE_OK ); /* True because of CursorMoveto() call above */
65723 /* sqlite3BtreeParseCellPtr() uses getVarint32() to extract the
65724 ** payload size, so it is impossible for u.am.payloadSize64 to be
65725 ** larger than 32 bits. */
65726 assert( (u.am.payloadSize64 & SQLITE_MAX_U32)==(u64)u.am.payloadSize64 );
65727 u.am.payloadSize = (u32)u.am.payloadSize64;
65728 }else{
65729 assert( sqlite3BtreeCursorIsValid(u.am.pCrsr) );
65730 rc = sqlite3BtreeDataSize(u.am.pCrsr, &u.am.payloadSize);
65731 assert( rc==SQLITE_OK ); /* DataSize() cannot fail */
65733 }else if( ALWAYS(u.am.pC->pseudoTableReg>0) ){
65734 u.am.pReg = &aMem[u.am.pC->pseudoTableReg];
65735 assert( u.am.pReg->flags & MEM_Blob );
65736 assert( memIsValid(u.am.pReg) );
65737 u.am.payloadSize = u.am.pReg->n;
65738 u.am.zRec = u.am.pReg->z;
65739 u.am.pC->cacheStatus = (pOp->p5&OPFLAG_CLEARCACHE) ? CACHE_STALE : p->cacheCtr;
65740 assert( u.am.payloadSize==0 || u.am.zRec!=0 );
65741 }else{
65742 /* Consider the row to be NULL */
65743 u.am.payloadSize = 0;
65746 /* If u.am.payloadSize is 0, then just store a NULL. This can happen because of
65747 ** nullRow or because of a corrupt database. */
65748 if( u.am.payloadSize==0 ){
65749 MemSetTypeFlag(u.am.pDest, MEM_Null);
65750 goto op_column_out;
65752 assert( db->aLimit[SQLITE_LIMIT_LENGTH]>=0 );
65753 if( u.am.payloadSize > (u32)db->aLimit[SQLITE_LIMIT_LENGTH] ){
65754 goto too_big;
65757 u.am.nField = u.am.pC->nField;
65758 assert( u.am.p2<u.am.nField );
65760 /* Read and parse the table header. Store the results of the parse
65761 ** into the record header cache fields of the cursor.
65763 u.am.aType = u.am.pC->aType;
65764 if( u.am.pC->cacheStatus==p->cacheCtr ){
65765 u.am.aOffset = u.am.pC->aOffset;
65766 }else{
65767 assert(u.am.aType);
65768 u.am.avail = 0;
65769 u.am.pC->aOffset = u.am.aOffset = &u.am.aType[u.am.nField];
65770 u.am.pC->payloadSize = u.am.payloadSize;
65771 u.am.pC->cacheStatus = p->cacheCtr;
65773 /* Figure out how many bytes are in the header */
65774 if( u.am.zRec ){
65775 u.am.zData = u.am.zRec;
65776 }else{
65777 if( u.am.pC->isIndex ){
65778 u.am.zData = (char*)sqlite3BtreeKeyFetch(u.am.pCrsr, &u.am.avail);
65779 }else{
65780 u.am.zData = (char*)sqlite3BtreeDataFetch(u.am.pCrsr, &u.am.avail);
65782 /* If KeyFetch()/DataFetch() managed to get the entire payload,
65783 ** save the payload in the u.am.pC->aRow cache. That will save us from
65784 ** having to make additional calls to fetch the content portion of
65785 ** the record.
65787 assert( u.am.avail>=0 );
65788 if( u.am.payloadSize <= (u32)u.am.avail ){
65789 u.am.zRec = u.am.zData;
65790 u.am.pC->aRow = (u8*)u.am.zData;
65791 }else{
65792 u.am.pC->aRow = 0;
65795 /* The following assert is true in all cases accept when
65796 ** the database file has been corrupted externally.
65797 ** assert( u.am.zRec!=0 || u.am.avail>=u.am.payloadSize || u.am.avail>=9 ); */
65798 u.am.szHdr = getVarint32((u8*)u.am.zData, u.am.offset);
65800 /* Make sure a corrupt database has not given us an oversize header.
65801 ** Do this now to avoid an oversize memory allocation.
65803 ** Type entries can be between 1 and 5 bytes each. But 4 and 5 byte
65804 ** types use so much data space that there can only be 4096 and 32 of
65805 ** them, respectively. So the maximum header length results from a
65806 ** 3-byte type for each of the maximum of 32768 columns plus three
65807 ** extra bytes for the header length itself. 32768*3 + 3 = 98307.
65809 if( u.am.offset > 98307 ){
65810 rc = SQLITE_CORRUPT_BKPT;
65811 goto op_column_out;
65814 /* Compute in u.am.len the number of bytes of data we need to read in order
65815 ** to get u.am.nField type values. u.am.offset is an upper bound on this. But
65816 ** u.am.nField might be significantly less than the true number of columns
65817 ** in the table, and in that case, 5*u.am.nField+3 might be smaller than u.am.offset.
65818 ** We want to minimize u.am.len in order to limit the size of the memory
65819 ** allocation, especially if a corrupt database file has caused u.am.offset
65820 ** to be oversized. Offset is limited to 98307 above. But 98307 might
65821 ** still exceed Robson memory allocation limits on some configurations.
65822 ** On systems that cannot tolerate large memory allocations, u.am.nField*5+3
65823 ** will likely be much smaller since u.am.nField will likely be less than
65824 ** 20 or so. This insures that Robson memory allocation limits are
65825 ** not exceeded even for corrupt database files.
65827 u.am.len = u.am.nField*5 + 3;
65828 if( u.am.len > (int)u.am.offset ) u.am.len = (int)u.am.offset;
65830 /* The KeyFetch() or DataFetch() above are fast and will get the entire
65831 ** record header in most cases. But they will fail to get the complete
65832 ** record header if the record header does not fit on a single page
65833 ** in the B-Tree. When that happens, use sqlite3VdbeMemFromBtree() to
65834 ** acquire the complete header text.
65836 if( !u.am.zRec && u.am.avail<u.am.len ){
65837 u.am.sMem.flags = 0;
65838 u.am.sMem.db = 0;
65839 rc = sqlite3VdbeMemFromBtree(u.am.pCrsr, 0, u.am.len, u.am.pC->isIndex, &u.am.sMem);
65840 if( rc!=SQLITE_OK ){
65841 goto op_column_out;
65843 u.am.zData = u.am.sMem.z;
65845 u.am.zEndHdr = (u8 *)&u.am.zData[u.am.len];
65846 u.am.zIdx = (u8 *)&u.am.zData[u.am.szHdr];
65848 /* Scan the header and use it to fill in the u.am.aType[] and u.am.aOffset[]
65849 ** arrays. u.am.aType[u.am.i] will contain the type integer for the u.am.i-th
65850 ** column and u.am.aOffset[u.am.i] will contain the u.am.offset from the beginning
65851 ** of the record to the start of the data for the u.am.i-th column
65853 for(u.am.i=0; u.am.i<u.am.nField; u.am.i++){
65854 if( u.am.zIdx<u.am.zEndHdr ){
65855 u.am.aOffset[u.am.i] = u.am.offset;
65856 if( u.am.zIdx[0]<0x80 ){
65857 u.am.t = u.am.zIdx[0];
65858 u.am.zIdx++;
65859 }else{
65860 u.am.zIdx += sqlite3GetVarint32(u.am.zIdx, &u.am.t);
65862 u.am.aType[u.am.i] = u.am.t;
65863 u.am.szField = sqlite3VdbeSerialTypeLen(u.am.t);
65864 u.am.offset += u.am.szField;
65865 if( u.am.offset<u.am.szField ){ /* True if u.am.offset overflows */
65866 u.am.zIdx = &u.am.zEndHdr[1]; /* Forces SQLITE_CORRUPT return below */
65867 break;
65869 }else{
65870 /* If u.am.i is less that u.am.nField, then there are less fields in this
65871 ** record than SetNumColumns indicated there are columns in the
65872 ** table. Set the u.am.offset for any extra columns not present in
65873 ** the record to 0. This tells code below to store a NULL
65874 ** instead of deserializing a value from the record.
65876 u.am.aOffset[u.am.i] = 0;
65879 sqlite3VdbeMemRelease(&u.am.sMem);
65880 u.am.sMem.flags = MEM_Null;
65882 /* If we have read more header data than was contained in the header,
65883 ** or if the end of the last field appears to be past the end of the
65884 ** record, or if the end of the last field appears to be before the end
65885 ** of the record (when all fields present), then we must be dealing
65886 ** with a corrupt database.
65888 if( (u.am.zIdx > u.am.zEndHdr) || (u.am.offset > u.am.payloadSize)
65889 || (u.am.zIdx==u.am.zEndHdr && u.am.offset!=u.am.payloadSize) ){
65890 rc = SQLITE_CORRUPT_BKPT;
65891 goto op_column_out;
65895 /* Get the column information. If u.am.aOffset[u.am.p2] is non-zero, then
65896 ** deserialize the value from the record. If u.am.aOffset[u.am.p2] is zero,
65897 ** then there are not enough fields in the record to satisfy the
65898 ** request. In this case, set the value NULL or to P4 if P4 is
65899 ** a pointer to a Mem object.
65901 if( u.am.aOffset[u.am.p2] ){
65902 assert( rc==SQLITE_OK );
65903 if( u.am.zRec ){
65904 MemReleaseExt(u.am.pDest);
65905 sqlite3VdbeSerialGet((u8 *)&u.am.zRec[u.am.aOffset[u.am.p2]], u.am.aType[u.am.p2], u.am.pDest);
65906 }else{
65907 u.am.len = sqlite3VdbeSerialTypeLen(u.am.aType[u.am.p2]);
65908 sqlite3VdbeMemMove(&u.am.sMem, u.am.pDest);
65909 rc = sqlite3VdbeMemFromBtree(u.am.pCrsr, u.am.aOffset[u.am.p2], u.am.len, u.am.pC->isIndex, &u.am.sMem);
65910 if( rc!=SQLITE_OK ){
65911 goto op_column_out;
65913 u.am.zData = u.am.sMem.z;
65914 sqlite3VdbeSerialGet((u8*)u.am.zData, u.am.aType[u.am.p2], u.am.pDest);
65916 u.am.pDest->enc = encoding;
65917 }else{
65918 if( pOp->p4type==P4_MEM ){
65919 sqlite3VdbeMemShallowCopy(u.am.pDest, pOp->p4.pMem, MEM_Static);
65920 }else{
65921 MemSetTypeFlag(u.am.pDest, MEM_Null);
65925 /* If we dynamically allocated space to hold the data (in the
65926 ** sqlite3VdbeMemFromBtree() call above) then transfer control of that
65927 ** dynamically allocated space over to the u.am.pDest structure.
65928 ** This prevents a memory copy.
65930 if( u.am.sMem.zMalloc ){
65931 assert( u.am.sMem.z==u.am.sMem.zMalloc );
65932 assert( !(u.am.pDest->flags & MEM_Dyn) );
65933 assert( !(u.am.pDest->flags & (MEM_Blob|MEM_Str)) || u.am.pDest->z==u.am.sMem.z );
65934 u.am.pDest->flags &= ~(MEM_Ephem|MEM_Static);
65935 u.am.pDest->flags |= MEM_Term;
65936 u.am.pDest->z = u.am.sMem.z;
65937 u.am.pDest->zMalloc = u.am.sMem.zMalloc;
65940 rc = sqlite3VdbeMemMakeWriteable(u.am.pDest);
65942 op_column_out:
65943 UPDATE_MAX_BLOBSIZE(u.am.pDest);
65944 REGISTER_TRACE(pOp->p3, u.am.pDest);
65945 break;
65948 /* Opcode: Affinity P1 P2 * P4 *
65950 ** Apply affinities to a range of P2 registers starting with P1.
65952 ** P4 is a string that is P2 characters long. The nth character of the
65953 ** string indicates the column affinity that should be used for the nth
65954 ** memory cell in the range.
65956 case OP_Affinity: {
65957 #if 0 /* local variables moved into u.an */
65958 const char *zAffinity; /* The affinity to be applied */
65959 char cAff; /* A single character of affinity */
65960 #endif /* local variables moved into u.an */
65962 u.an.zAffinity = pOp->p4.z;
65963 assert( u.an.zAffinity!=0 );
65964 assert( u.an.zAffinity[pOp->p2]==0 );
65965 pIn1 = &aMem[pOp->p1];
65966 while( (u.an.cAff = *(u.an.zAffinity++))!=0 ){
65967 assert( pIn1 <= &p->aMem[p->nMem] );
65968 assert( memIsValid(pIn1) );
65969 ExpandBlob(pIn1);
65970 applyAffinity(pIn1, u.an.cAff, encoding);
65971 pIn1++;
65973 break;
65976 /* Opcode: MakeRecord P1 P2 P3 P4 *
65978 ** Convert P2 registers beginning with P1 into the [record format]
65979 ** use as a data record in a database table or as a key
65980 ** in an index. The OP_Column opcode can decode the record later.
65982 ** P4 may be a string that is P2 characters long. The nth character of the
65983 ** string indicates the column affinity that should be used for the nth
65984 ** field of the index key.
65986 ** The mapping from character to affinity is given by the SQLITE_AFF_
65987 ** macros defined in sqliteInt.h.
65989 ** If P4 is NULL then all index fields have the affinity NONE.
65991 case OP_MakeRecord: {
65992 #if 0 /* local variables moved into u.ao */
65993 u8 *zNewRecord; /* A buffer to hold the data for the new record */
65994 Mem *pRec; /* The new record */
65995 u64 nData; /* Number of bytes of data space */
65996 int nHdr; /* Number of bytes of header space */
65997 i64 nByte; /* Data space required for this record */
65998 int nZero; /* Number of zero bytes at the end of the record */
65999 int nVarint; /* Number of bytes in a varint */
66000 u32 serial_type; /* Type field */
66001 Mem *pData0; /* First field to be combined into the record */
66002 Mem *pLast; /* Last field of the record */
66003 int nField; /* Number of fields in the record */
66004 char *zAffinity; /* The affinity string for the record */
66005 int file_format; /* File format to use for encoding */
66006 int i; /* Space used in zNewRecord[] */
66007 int len; /* Length of a field */
66008 #endif /* local variables moved into u.ao */
66010 /* Assuming the record contains N fields, the record format looks
66011 ** like this:
66013 ** ------------------------------------------------------------------------
66014 ** | hdr-size | type 0 | type 1 | ... | type N-1 | data0 | ... | data N-1 |
66015 ** ------------------------------------------------------------------------
66017 ** Data(0) is taken from register P1. Data(1) comes from register P1+1
66018 ** and so froth.
66020 ** Each type field is a varint representing the serial type of the
66021 ** corresponding data element (see sqlite3VdbeSerialType()). The
66022 ** hdr-size field is also a varint which is the offset from the beginning
66023 ** of the record to data0.
66025 u.ao.nData = 0; /* Number of bytes of data space */
66026 u.ao.nHdr = 0; /* Number of bytes of header space */
66027 u.ao.nZero = 0; /* Number of zero bytes at the end of the record */
66028 u.ao.nField = pOp->p1;
66029 u.ao.zAffinity = pOp->p4.z;
66030 assert( u.ao.nField>0 && pOp->p2>0 && pOp->p2+u.ao.nField<=p->nMem+1 );
66031 u.ao.pData0 = &aMem[u.ao.nField];
66032 u.ao.nField = pOp->p2;
66033 u.ao.pLast = &u.ao.pData0[u.ao.nField-1];
66034 u.ao.file_format = p->minWriteFileFormat;
66036 /* Identify the output register */
66037 assert( pOp->p3<pOp->p1 || pOp->p3>=pOp->p1+pOp->p2 );
66038 pOut = &aMem[pOp->p3];
66039 memAboutToChange(p, pOut);
66041 /* Loop through the elements that will make up the record to figure
66042 ** out how much space is required for the new record.
66044 for(u.ao.pRec=u.ao.pData0; u.ao.pRec<=u.ao.pLast; u.ao.pRec++){
66045 assert( memIsValid(u.ao.pRec) );
66046 if( u.ao.zAffinity ){
66047 applyAffinity(u.ao.pRec, u.ao.zAffinity[u.ao.pRec-u.ao.pData0], encoding);
66049 if( u.ao.pRec->flags&MEM_Zero && u.ao.pRec->n>0 ){
66050 sqlite3VdbeMemExpandBlob(u.ao.pRec);
66052 u.ao.serial_type = sqlite3VdbeSerialType(u.ao.pRec, u.ao.file_format);
66053 u.ao.len = sqlite3VdbeSerialTypeLen(u.ao.serial_type);
66054 u.ao.nData += u.ao.len;
66055 u.ao.nHdr += sqlite3VarintLen(u.ao.serial_type);
66056 if( u.ao.pRec->flags & MEM_Zero ){
66057 /* Only pure zero-filled BLOBs can be input to this Opcode.
66058 ** We do not allow blobs with a prefix and a zero-filled tail. */
66059 u.ao.nZero += u.ao.pRec->u.nZero;
66060 }else if( u.ao.len ){
66061 u.ao.nZero = 0;
66065 /* Add the initial header varint and total the size */
66066 u.ao.nHdr += u.ao.nVarint = sqlite3VarintLen(u.ao.nHdr);
66067 if( u.ao.nVarint<sqlite3VarintLen(u.ao.nHdr) ){
66068 u.ao.nHdr++;
66070 u.ao.nByte = u.ao.nHdr+u.ao.nData-u.ao.nZero;
66071 if( u.ao.nByte>db->aLimit[SQLITE_LIMIT_LENGTH] ){
66072 goto too_big;
66075 /* Make sure the output register has a buffer large enough to store
66076 ** the new record. The output register (pOp->p3) is not allowed to
66077 ** be one of the input registers (because the following call to
66078 ** sqlite3VdbeMemGrow() could clobber the value before it is used).
66080 if( sqlite3VdbeMemGrow(pOut, (int)u.ao.nByte, 0) ){
66081 goto no_mem;
66083 u.ao.zNewRecord = (u8 *)pOut->z;
66085 /* Write the record */
66086 u.ao.i = putVarint32(u.ao.zNewRecord, u.ao.nHdr);
66087 for(u.ao.pRec=u.ao.pData0; u.ao.pRec<=u.ao.pLast; u.ao.pRec++){
66088 u.ao.serial_type = sqlite3VdbeSerialType(u.ao.pRec, u.ao.file_format);
66089 u.ao.i += putVarint32(&u.ao.zNewRecord[u.ao.i], u.ao.serial_type); /* serial type */
66091 for(u.ao.pRec=u.ao.pData0; u.ao.pRec<=u.ao.pLast; u.ao.pRec++){ /* serial data */
66092 u.ao.i += sqlite3VdbeSerialPut(&u.ao.zNewRecord[u.ao.i], (int)(u.ao.nByte-u.ao.i), u.ao.pRec,u.ao.file_format);
66094 assert( u.ao.i==u.ao.nByte );
66096 assert( pOp->p3>0 && pOp->p3<=p->nMem );
66097 pOut->n = (int)u.ao.nByte;
66098 pOut->flags = MEM_Blob | MEM_Dyn;
66099 pOut->xDel = 0;
66100 if( u.ao.nZero ){
66101 pOut->u.nZero = u.ao.nZero;
66102 pOut->flags |= MEM_Zero;
66104 pOut->enc = SQLITE_UTF8; /* In case the blob is ever converted to text */
66105 REGISTER_TRACE(pOp->p3, pOut);
66106 UPDATE_MAX_BLOBSIZE(pOut);
66107 break;
66110 /* Opcode: Count P1 P2 * * *
66112 ** Store the number of entries (an integer value) in the table or index
66113 ** opened by cursor P1 in register P2
66115 #ifndef SQLITE_OMIT_BTREECOUNT
66116 case OP_Count: { /* out2-prerelease */
66117 #if 0 /* local variables moved into u.ap */
66118 i64 nEntry;
66119 BtCursor *pCrsr;
66120 #endif /* local variables moved into u.ap */
66122 u.ap.pCrsr = p->apCsr[pOp->p1]->pCursor;
66123 if( ALWAYS(u.ap.pCrsr) ){
66124 rc = sqlite3BtreeCount(u.ap.pCrsr, &u.ap.nEntry);
66125 }else{
66126 u.ap.nEntry = 0;
66128 pOut->u.i = u.ap.nEntry;
66129 break;
66131 #endif
66133 /* Opcode: Savepoint P1 * * P4 *
66135 ** Open, release or rollback the savepoint named by parameter P4, depending
66136 ** on the value of P1. To open a new savepoint, P1==0. To release (commit) an
66137 ** existing savepoint, P1==1, or to rollback an existing savepoint P1==2.
66139 case OP_Savepoint: {
66140 #if 0 /* local variables moved into u.aq */
66141 int p1; /* Value of P1 operand */
66142 char *zName; /* Name of savepoint */
66143 int nName;
66144 Savepoint *pNew;
66145 Savepoint *pSavepoint;
66146 Savepoint *pTmp;
66147 int iSavepoint;
66148 int ii;
66149 #endif /* local variables moved into u.aq */
66151 u.aq.p1 = pOp->p1;
66152 u.aq.zName = pOp->p4.z;
66154 /* Assert that the u.aq.p1 parameter is valid. Also that if there is no open
66155 ** transaction, then there cannot be any savepoints.
66157 assert( db->pSavepoint==0 || db->autoCommit==0 );
66158 assert( u.aq.p1==SAVEPOINT_BEGIN||u.aq.p1==SAVEPOINT_RELEASE||u.aq.p1==SAVEPOINT_ROLLBACK );
66159 assert( db->pSavepoint || db->isTransactionSavepoint==0 );
66160 assert( checkSavepointCount(db) );
66162 if( u.aq.p1==SAVEPOINT_BEGIN ){
66163 if( db->writeVdbeCnt>0 ){
66164 /* A new savepoint cannot be created if there are active write
66165 ** statements (i.e. open read/write incremental blob handles).
66167 sqlite3SetString(&p->zErrMsg, db, "cannot open savepoint - "
66168 "SQL statements in progress");
66169 rc = SQLITE_BUSY;
66170 }else{
66171 u.aq.nName = sqlite3Strlen30(u.aq.zName);
66173 #ifndef SQLITE_OMIT_VIRTUALTABLE
66174 /* This call is Ok even if this savepoint is actually a transaction
66175 ** savepoint (and therefore should not prompt xSavepoint()) callbacks.
66176 ** If this is a transaction savepoint being opened, it is guaranteed
66177 ** that the db->aVTrans[] array is empty. */
66178 assert( db->autoCommit==0 || db->nVTrans==0 );
66179 rc = sqlite3VtabSavepoint(db, SAVEPOINT_BEGIN,
66180 db->nStatement+db->nSavepoint);
66181 if( rc!=SQLITE_OK ) goto abort_due_to_error;
66182 #endif
66184 /* Create a new savepoint structure. */
66185 u.aq.pNew = sqlite3DbMallocRaw(db, sizeof(Savepoint)+u.aq.nName+1);
66186 if( u.aq.pNew ){
66187 u.aq.pNew->zName = (char *)&u.aq.pNew[1];
66188 memcpy(u.aq.pNew->zName, u.aq.zName, u.aq.nName+1);
66190 /* If there is no open transaction, then mark this as a special
66191 ** "transaction savepoint". */
66192 if( db->autoCommit ){
66193 db->autoCommit = 0;
66194 db->isTransactionSavepoint = 1;
66195 }else{
66196 db->nSavepoint++;
66199 /* Link the new savepoint into the database handle's list. */
66200 u.aq.pNew->pNext = db->pSavepoint;
66201 db->pSavepoint = u.aq.pNew;
66202 u.aq.pNew->nDeferredCons = db->nDeferredCons;
66205 }else{
66206 u.aq.iSavepoint = 0;
66208 /* Find the named savepoint. If there is no such savepoint, then an
66209 ** an error is returned to the user. */
66210 for(
66211 u.aq.pSavepoint = db->pSavepoint;
66212 u.aq.pSavepoint && sqlite3StrICmp(u.aq.pSavepoint->zName, u.aq.zName);
66213 u.aq.pSavepoint = u.aq.pSavepoint->pNext
66215 u.aq.iSavepoint++;
66217 if( !u.aq.pSavepoint ){
66218 sqlite3SetString(&p->zErrMsg, db, "no such savepoint: %s", u.aq.zName);
66219 rc = SQLITE_ERROR;
66220 }else if(
66221 db->writeVdbeCnt>0 || (u.aq.p1==SAVEPOINT_ROLLBACK && db->activeVdbeCnt>1)
66223 /* It is not possible to release (commit) a savepoint if there are
66224 ** active write statements. It is not possible to rollback a savepoint
66225 ** if there are any active statements at all.
66227 sqlite3SetString(&p->zErrMsg, db,
66228 "cannot %s savepoint - SQL statements in progress",
66229 (u.aq.p1==SAVEPOINT_ROLLBACK ? "rollback": "release")
66231 rc = SQLITE_BUSY;
66232 }else{
66234 /* Determine whether or not this is a transaction savepoint. If so,
66235 ** and this is a RELEASE command, then the current transaction
66236 ** is committed.
66238 int isTransaction = u.aq.pSavepoint->pNext==0 && db->isTransactionSavepoint;
66239 if( isTransaction && u.aq.p1==SAVEPOINT_RELEASE ){
66240 if( (rc = sqlite3VdbeCheckFk(p, 1))!=SQLITE_OK ){
66241 goto vdbe_return;
66243 db->autoCommit = 1;
66244 if( sqlite3VdbeHalt(p)==SQLITE_BUSY ){
66245 p->pc = pc;
66246 db->autoCommit = 0;
66247 p->rc = rc = SQLITE_BUSY;
66248 goto vdbe_return;
66250 db->isTransactionSavepoint = 0;
66251 rc = p->rc;
66252 }else{
66253 u.aq.iSavepoint = db->nSavepoint - u.aq.iSavepoint - 1;
66254 for(u.aq.ii=0; u.aq.ii<db->nDb; u.aq.ii++){
66255 rc = sqlite3BtreeSavepoint(db->aDb[u.aq.ii].pBt, u.aq.p1, u.aq.iSavepoint);
66256 if( rc!=SQLITE_OK ){
66257 goto abort_due_to_error;
66260 if( u.aq.p1==SAVEPOINT_ROLLBACK && (db->flags&SQLITE_InternChanges)!=0 ){
66261 sqlite3ExpirePreparedStatements(db);
66262 sqlite3ResetInternalSchema(db, -1);
66263 db->flags = (db->flags | SQLITE_InternChanges);
66267 /* Regardless of whether this is a RELEASE or ROLLBACK, destroy all
66268 ** savepoints nested inside of the savepoint being operated on. */
66269 while( db->pSavepoint!=u.aq.pSavepoint ){
66270 u.aq.pTmp = db->pSavepoint;
66271 db->pSavepoint = u.aq.pTmp->pNext;
66272 sqlite3DbFree(db, u.aq.pTmp);
66273 db->nSavepoint--;
66276 /* If it is a RELEASE, then destroy the savepoint being operated on
66277 ** too. If it is a ROLLBACK TO, then set the number of deferred
66278 ** constraint violations present in the database to the value stored
66279 ** when the savepoint was created. */
66280 if( u.aq.p1==SAVEPOINT_RELEASE ){
66281 assert( u.aq.pSavepoint==db->pSavepoint );
66282 db->pSavepoint = u.aq.pSavepoint->pNext;
66283 sqlite3DbFree(db, u.aq.pSavepoint);
66284 if( !isTransaction ){
66285 db->nSavepoint--;
66287 }else{
66288 db->nDeferredCons = u.aq.pSavepoint->nDeferredCons;
66291 if( !isTransaction ){
66292 rc = sqlite3VtabSavepoint(db, u.aq.p1, u.aq.iSavepoint);
66293 if( rc!=SQLITE_OK ) goto abort_due_to_error;
66298 break;
66301 /* Opcode: AutoCommit P1 P2 * * *
66303 ** Set the database auto-commit flag to P1 (1 or 0). If P2 is true, roll
66304 ** back any currently active btree transactions. If there are any active
66305 ** VMs (apart from this one), then a ROLLBACK fails. A COMMIT fails if
66306 ** there are active writing VMs or active VMs that use shared cache.
66308 ** This instruction causes the VM to halt.
66310 case OP_AutoCommit: {
66311 #if 0 /* local variables moved into u.ar */
66312 int desiredAutoCommit;
66313 int iRollback;
66314 int turnOnAC;
66315 #endif /* local variables moved into u.ar */
66317 u.ar.desiredAutoCommit = pOp->p1;
66318 u.ar.iRollback = pOp->p2;
66319 u.ar.turnOnAC = u.ar.desiredAutoCommit && !db->autoCommit;
66320 assert( u.ar.desiredAutoCommit==1 || u.ar.desiredAutoCommit==0 );
66321 assert( u.ar.desiredAutoCommit==1 || u.ar.iRollback==0 );
66322 assert( db->activeVdbeCnt>0 ); /* At least this one VM is active */
66324 if( u.ar.turnOnAC && u.ar.iRollback && db->activeVdbeCnt>1 ){
66325 /* If this instruction implements a ROLLBACK and other VMs are
66326 ** still running, and a transaction is active, return an error indicating
66327 ** that the other VMs must complete first.
66329 sqlite3SetString(&p->zErrMsg, db, "cannot rollback transaction - "
66330 "SQL statements in progress");
66331 rc = SQLITE_BUSY;
66332 }else if( u.ar.turnOnAC && !u.ar.iRollback && db->writeVdbeCnt>0 ){
66333 /* If this instruction implements a COMMIT and other VMs are writing
66334 ** return an error indicating that the other VMs must complete first.
66336 sqlite3SetString(&p->zErrMsg, db, "cannot commit transaction - "
66337 "SQL statements in progress");
66338 rc = SQLITE_BUSY;
66339 }else if( u.ar.desiredAutoCommit!=db->autoCommit ){
66340 if( u.ar.iRollback ){
66341 assert( u.ar.desiredAutoCommit==1 );
66342 sqlite3RollbackAll(db);
66343 db->autoCommit = 1;
66344 }else if( (rc = sqlite3VdbeCheckFk(p, 1))!=SQLITE_OK ){
66345 goto vdbe_return;
66346 }else{
66347 db->autoCommit = (u8)u.ar.desiredAutoCommit;
66348 if( sqlite3VdbeHalt(p)==SQLITE_BUSY ){
66349 p->pc = pc;
66350 db->autoCommit = (u8)(1-u.ar.desiredAutoCommit);
66351 p->rc = rc = SQLITE_BUSY;
66352 goto vdbe_return;
66355 assert( db->nStatement==0 );
66356 sqlite3CloseSavepoints(db);
66357 if( p->rc==SQLITE_OK ){
66358 rc = SQLITE_DONE;
66359 }else{
66360 rc = SQLITE_ERROR;
66362 goto vdbe_return;
66363 }else{
66364 sqlite3SetString(&p->zErrMsg, db,
66365 (!u.ar.desiredAutoCommit)?"cannot start a transaction within a transaction":(
66366 (u.ar.iRollback)?"cannot rollback - no transaction is active":
66367 "cannot commit - no transaction is active"));
66369 rc = SQLITE_ERROR;
66371 break;
66374 /* Opcode: Transaction P1 P2 * * *
66376 ** Begin a transaction. The transaction ends when a Commit or Rollback
66377 ** opcode is encountered. Depending on the ON CONFLICT setting, the
66378 ** transaction might also be rolled back if an error is encountered.
66380 ** P1 is the index of the database file on which the transaction is
66381 ** started. Index 0 is the main database file and index 1 is the
66382 ** file used for temporary tables. Indices of 2 or more are used for
66383 ** attached databases.
66385 ** If P2 is non-zero, then a write-transaction is started. A RESERVED lock is
66386 ** obtained on the database file when a write-transaction is started. No
66387 ** other process can start another write transaction while this transaction is
66388 ** underway. Starting a write transaction also creates a rollback journal. A
66389 ** write transaction must be started before any changes can be made to the
66390 ** database. If P2 is 2 or greater then an EXCLUSIVE lock is also obtained
66391 ** on the file.
66393 ** If a write-transaction is started and the Vdbe.usesStmtJournal flag is
66394 ** true (this flag is set if the Vdbe may modify more than one row and may
66395 ** throw an ABORT exception), a statement transaction may also be opened.
66396 ** More specifically, a statement transaction is opened iff the database
66397 ** connection is currently not in autocommit mode, or if there are other
66398 ** active statements. A statement transaction allows the affects of this
66399 ** VDBE to be rolled back after an error without having to roll back the
66400 ** entire transaction. If no error is encountered, the statement transaction
66401 ** will automatically commit when the VDBE halts.
66403 ** If P2 is zero, then a read-lock is obtained on the database file.
66405 case OP_Transaction: {
66406 #if 0 /* local variables moved into u.as */
66407 Btree *pBt;
66408 #endif /* local variables moved into u.as */
66410 assert( pOp->p1>=0 && pOp->p1<db->nDb );
66411 assert( (p->btreeMask & (((yDbMask)1)<<pOp->p1))!=0 );
66412 u.as.pBt = db->aDb[pOp->p1].pBt;
66414 if( u.as.pBt ){
66415 rc = sqlite3BtreeBeginTrans(u.as.pBt, pOp->p2);
66416 if( rc==SQLITE_BUSY ){
66417 p->pc = pc;
66418 p->rc = rc = SQLITE_BUSY;
66419 goto vdbe_return;
66421 if( rc!=SQLITE_OK ){
66422 goto abort_due_to_error;
66425 if( pOp->p2 && p->usesStmtJournal
66426 && (db->autoCommit==0 || db->activeVdbeCnt>1)
66428 assert( sqlite3BtreeIsInTrans(u.as.pBt) );
66429 if( p->iStatement==0 ){
66430 assert( db->nStatement>=0 && db->nSavepoint>=0 );
66431 db->nStatement++;
66432 p->iStatement = db->nSavepoint + db->nStatement;
66435 rc = sqlite3VtabSavepoint(db, SAVEPOINT_BEGIN, p->iStatement-1);
66436 if( rc==SQLITE_OK ){
66437 rc = sqlite3BtreeBeginStmt(u.as.pBt, p->iStatement);
66440 /* Store the current value of the database handles deferred constraint
66441 ** counter. If the statement transaction needs to be rolled back,
66442 ** the value of this counter needs to be restored too. */
66443 p->nStmtDefCons = db->nDeferredCons;
66446 break;
66449 /* Opcode: ReadCookie P1 P2 P3 * *
66451 ** Read cookie number P3 from database P1 and write it into register P2.
66452 ** P3==1 is the schema version. P3==2 is the database format.
66453 ** P3==3 is the recommended pager cache size, and so forth. P1==0 is
66454 ** the main database file and P1==1 is the database file used to store
66455 ** temporary tables.
66457 ** There must be a read-lock on the database (either a transaction
66458 ** must be started or there must be an open cursor) before
66459 ** executing this instruction.
66461 case OP_ReadCookie: { /* out2-prerelease */
66462 #if 0 /* local variables moved into u.at */
66463 int iMeta;
66464 int iDb;
66465 int iCookie;
66466 #endif /* local variables moved into u.at */
66468 u.at.iDb = pOp->p1;
66469 u.at.iCookie = pOp->p3;
66470 assert( pOp->p3<SQLITE_N_BTREE_META );
66471 assert( u.at.iDb>=0 && u.at.iDb<db->nDb );
66472 assert( db->aDb[u.at.iDb].pBt!=0 );
66473 assert( (p->btreeMask & (((yDbMask)1)<<u.at.iDb))!=0 );
66475 sqlite3BtreeGetMeta(db->aDb[u.at.iDb].pBt, u.at.iCookie, (u32 *)&u.at.iMeta);
66476 pOut->u.i = u.at.iMeta;
66477 break;
66480 /* Opcode: SetCookie P1 P2 P3 * *
66482 ** Write the content of register P3 (interpreted as an integer)
66483 ** into cookie number P2 of database P1. P2==1 is the schema version.
66484 ** P2==2 is the database format. P2==3 is the recommended pager cache
66485 ** size, and so forth. P1==0 is the main database file and P1==1 is the
66486 ** database file used to store temporary tables.
66488 ** A transaction must be started before executing this opcode.
66490 case OP_SetCookie: { /* in3 */
66491 #if 0 /* local variables moved into u.au */
66492 Db *pDb;
66493 #endif /* local variables moved into u.au */
66494 assert( pOp->p2<SQLITE_N_BTREE_META );
66495 assert( pOp->p1>=0 && pOp->p1<db->nDb );
66496 assert( (p->btreeMask & (((yDbMask)1)<<pOp->p1))!=0 );
66497 u.au.pDb = &db->aDb[pOp->p1];
66498 assert( u.au.pDb->pBt!=0 );
66499 assert( sqlite3SchemaMutexHeld(db, pOp->p1, 0) );
66500 pIn3 = &aMem[pOp->p3];
66501 sqlite3VdbeMemIntegerify(pIn3);
66502 /* See note about index shifting on OP_ReadCookie */
66503 rc = sqlite3BtreeUpdateMeta(u.au.pDb->pBt, pOp->p2, (int)pIn3->u.i);
66504 if( pOp->p2==BTREE_SCHEMA_VERSION ){
66505 /* When the schema cookie changes, record the new cookie internally */
66506 u.au.pDb->pSchema->schema_cookie = (int)pIn3->u.i;
66507 db->flags |= SQLITE_InternChanges;
66508 }else if( pOp->p2==BTREE_FILE_FORMAT ){
66509 /* Record changes in the file format */
66510 u.au.pDb->pSchema->file_format = (u8)pIn3->u.i;
66512 if( pOp->p1==1 ){
66513 /* Invalidate all prepared statements whenever the TEMP database
66514 ** schema is changed. Ticket #1644 */
66515 sqlite3ExpirePreparedStatements(db);
66516 p->expired = 0;
66518 break;
66521 /* Opcode: VerifyCookie P1 P2 P3 * *
66523 ** Check the value of global database parameter number 0 (the
66524 ** schema version) and make sure it is equal to P2 and that the
66525 ** generation counter on the local schema parse equals P3.
66527 ** P1 is the database number which is 0 for the main database file
66528 ** and 1 for the file holding temporary tables and some higher number
66529 ** for auxiliary databases.
66531 ** The cookie changes its value whenever the database schema changes.
66532 ** This operation is used to detect when that the cookie has changed
66533 ** and that the current process needs to reread the schema.
66535 ** Either a transaction needs to have been started or an OP_Open needs
66536 ** to be executed (to establish a read lock) before this opcode is
66537 ** invoked.
66539 case OP_VerifyCookie: {
66540 #if 0 /* local variables moved into u.av */
66541 int iMeta;
66542 int iGen;
66543 Btree *pBt;
66544 #endif /* local variables moved into u.av */
66546 assert( pOp->p1>=0 && pOp->p1<db->nDb );
66547 assert( (p->btreeMask & (((yDbMask)1)<<pOp->p1))!=0 );
66548 assert( sqlite3SchemaMutexHeld(db, pOp->p1, 0) );
66549 u.av.pBt = db->aDb[pOp->p1].pBt;
66550 if( u.av.pBt ){
66551 sqlite3BtreeGetMeta(u.av.pBt, BTREE_SCHEMA_VERSION, (u32 *)&u.av.iMeta);
66552 u.av.iGen = db->aDb[pOp->p1].pSchema->iGeneration;
66553 }else{
66554 u.av.iGen = u.av.iMeta = 0;
66556 if( u.av.iMeta!=pOp->p2 || u.av.iGen!=pOp->p3 ){
66557 sqlite3DbFree(db, p->zErrMsg);
66558 p->zErrMsg = sqlite3DbStrDup(db, "database schema has changed");
66559 /* If the schema-cookie from the database file matches the cookie
66560 ** stored with the in-memory representation of the schema, do
66561 ** not reload the schema from the database file.
66563 ** If virtual-tables are in use, this is not just an optimization.
66564 ** Often, v-tables store their data in other SQLite tables, which
66565 ** are queried from within xNext() and other v-table methods using
66566 ** prepared queries. If such a query is out-of-date, we do not want to
66567 ** discard the database schema, as the user code implementing the
66568 ** v-table would have to be ready for the sqlite3_vtab structure itself
66569 ** to be invalidated whenever sqlite3_step() is called from within
66570 ** a v-table method.
66572 if( db->aDb[pOp->p1].pSchema->schema_cookie!=u.av.iMeta ){
66573 sqlite3ResetInternalSchema(db, pOp->p1);
66576 p->expired = 1;
66577 rc = SQLITE_SCHEMA;
66579 break;
66582 /* Opcode: OpenRead P1 P2 P3 P4 P5
66584 ** Open a read-only cursor for the database table whose root page is
66585 ** P2 in a database file. The database file is determined by P3.
66586 ** P3==0 means the main database, P3==1 means the database used for
66587 ** temporary tables, and P3>1 means used the corresponding attached
66588 ** database. Give the new cursor an identifier of P1. The P1
66589 ** values need not be contiguous but all P1 values should be small integers.
66590 ** It is an error for P1 to be negative.
66592 ** If P5!=0 then use the content of register P2 as the root page, not
66593 ** the value of P2 itself.
66595 ** There will be a read lock on the database whenever there is an
66596 ** open cursor. If the database was unlocked prior to this instruction
66597 ** then a read lock is acquired as part of this instruction. A read
66598 ** lock allows other processes to read the database but prohibits
66599 ** any other process from modifying the database. The read lock is
66600 ** released when all cursors are closed. If this instruction attempts
66601 ** to get a read lock but fails, the script terminates with an
66602 ** SQLITE_BUSY error code.
66604 ** The P4 value may be either an integer (P4_INT32) or a pointer to
66605 ** a KeyInfo structure (P4_KEYINFO). If it is a pointer to a KeyInfo
66606 ** structure, then said structure defines the content and collating
66607 ** sequence of the index being opened. Otherwise, if P4 is an integer
66608 ** value, it is set to the number of columns in the table.
66610 ** See also OpenWrite.
66612 /* Opcode: OpenWrite P1 P2 P3 P4 P5
66614 ** Open a read/write cursor named P1 on the table or index whose root
66615 ** page is P2. Or if P5!=0 use the content of register P2 to find the
66616 ** root page.
66618 ** The P4 value may be either an integer (P4_INT32) or a pointer to
66619 ** a KeyInfo structure (P4_KEYINFO). If it is a pointer to a KeyInfo
66620 ** structure, then said structure defines the content and collating
66621 ** sequence of the index being opened. Otherwise, if P4 is an integer
66622 ** value, it is set to the number of columns in the table, or to the
66623 ** largest index of any column of the table that is actually used.
66625 ** This instruction works just like OpenRead except that it opens the cursor
66626 ** in read/write mode. For a given table, there can be one or more read-only
66627 ** cursors or a single read/write cursor but not both.
66629 ** See also OpenRead.
66631 case OP_OpenRead:
66632 case OP_OpenWrite: {
66633 #if 0 /* local variables moved into u.aw */
66634 int nField;
66635 KeyInfo *pKeyInfo;
66636 int p2;
66637 int iDb;
66638 int wrFlag;
66639 Btree *pX;
66640 VdbeCursor *pCur;
66641 Db *pDb;
66642 #endif /* local variables moved into u.aw */
66644 if( p->expired ){
66645 rc = SQLITE_ABORT;
66646 break;
66649 u.aw.nField = 0;
66650 u.aw.pKeyInfo = 0;
66651 u.aw.p2 = pOp->p2;
66652 u.aw.iDb = pOp->p3;
66653 assert( u.aw.iDb>=0 && u.aw.iDb<db->nDb );
66654 assert( (p->btreeMask & (((yDbMask)1)<<u.aw.iDb))!=0 );
66655 u.aw.pDb = &db->aDb[u.aw.iDb];
66656 u.aw.pX = u.aw.pDb->pBt;
66657 assert( u.aw.pX!=0 );
66658 if( pOp->opcode==OP_OpenWrite ){
66659 u.aw.wrFlag = 1;
66660 assert( sqlite3SchemaMutexHeld(db, u.aw.iDb, 0) );
66661 if( u.aw.pDb->pSchema->file_format < p->minWriteFileFormat ){
66662 p->minWriteFileFormat = u.aw.pDb->pSchema->file_format;
66664 }else{
66665 u.aw.wrFlag = 0;
66667 if( pOp->p5 ){
66668 assert( u.aw.p2>0 );
66669 assert( u.aw.p2<=p->nMem );
66670 pIn2 = &aMem[u.aw.p2];
66671 assert( memIsValid(pIn2) );
66672 assert( (pIn2->flags & MEM_Int)!=0 );
66673 sqlite3VdbeMemIntegerify(pIn2);
66674 u.aw.p2 = (int)pIn2->u.i;
66675 /* The u.aw.p2 value always comes from a prior OP_CreateTable opcode and
66676 ** that opcode will always set the u.aw.p2 value to 2 or more or else fail.
66677 ** If there were a failure, the prepared statement would have halted
66678 ** before reaching this instruction. */
66679 if( NEVER(u.aw.p2<2) ) {
66680 rc = SQLITE_CORRUPT_BKPT;
66681 goto abort_due_to_error;
66684 if( pOp->p4type==P4_KEYINFO ){
66685 u.aw.pKeyInfo = pOp->p4.pKeyInfo;
66686 u.aw.pKeyInfo->enc = ENC(p->db);
66687 u.aw.nField = u.aw.pKeyInfo->nField+1;
66688 }else if( pOp->p4type==P4_INT32 ){
66689 u.aw.nField = pOp->p4.i;
66691 assert( pOp->p1>=0 );
66692 u.aw.pCur = allocateCursor(p, pOp->p1, u.aw.nField, u.aw.iDb, 1);
66693 if( u.aw.pCur==0 ) goto no_mem;
66694 u.aw.pCur->nullRow = 1;
66695 u.aw.pCur->isOrdered = 1;
66696 rc = sqlite3BtreeCursor(u.aw.pX, u.aw.p2, u.aw.wrFlag, u.aw.pKeyInfo, u.aw.pCur->pCursor);
66697 u.aw.pCur->pKeyInfo = u.aw.pKeyInfo;
66699 /* Since it performs no memory allocation or IO, the only value that
66700 ** sqlite3BtreeCursor() may return is SQLITE_OK. */
66701 assert( rc==SQLITE_OK );
66703 /* Set the VdbeCursor.isTable and isIndex variables. Previous versions of
66704 ** SQLite used to check if the root-page flags were sane at this point
66705 ** and report database corruption if they were not, but this check has
66706 ** since moved into the btree layer. */
66707 u.aw.pCur->isTable = pOp->p4type!=P4_KEYINFO;
66708 u.aw.pCur->isIndex = !u.aw.pCur->isTable;
66709 break;
66712 /* Opcode: OpenEphemeral P1 P2 * P4 P5
66714 ** Open a new cursor P1 to a transient table.
66715 ** The cursor is always opened read/write even if
66716 ** the main database is read-only. The ephemeral
66717 ** table is deleted automatically when the cursor is closed.
66719 ** P2 is the number of columns in the ephemeral table.
66720 ** The cursor points to a BTree table if P4==0 and to a BTree index
66721 ** if P4 is not 0. If P4 is not NULL, it points to a KeyInfo structure
66722 ** that defines the format of keys in the index.
66724 ** This opcode was once called OpenTemp. But that created
66725 ** confusion because the term "temp table", might refer either
66726 ** to a TEMP table at the SQL level, or to a table opened by
66727 ** this opcode. Then this opcode was call OpenVirtual. But
66728 ** that created confusion with the whole virtual-table idea.
66730 ** The P5 parameter can be a mask of the BTREE_* flags defined
66731 ** in btree.h. These flags control aspects of the operation of
66732 ** the btree. The BTREE_OMIT_JOURNAL and BTREE_SINGLE flags are
66733 ** added automatically.
66735 /* Opcode: OpenAutoindex P1 P2 * P4 *
66737 ** This opcode works the same as OP_OpenEphemeral. It has a
66738 ** different name to distinguish its use. Tables created using
66739 ** by this opcode will be used for automatically created transient
66740 ** indices in joins.
66742 case OP_OpenAutoindex:
66743 case OP_OpenEphemeral: {
66744 #if 0 /* local variables moved into u.ax */
66745 VdbeCursor *pCx;
66746 #endif /* local variables moved into u.ax */
66747 static const int vfsFlags =
66748 SQLITE_OPEN_READWRITE |
66749 SQLITE_OPEN_CREATE |
66750 SQLITE_OPEN_EXCLUSIVE |
66751 SQLITE_OPEN_DELETEONCLOSE |
66752 SQLITE_OPEN_TRANSIENT_DB;
66754 assert( pOp->p1>=0 );
66755 u.ax.pCx = allocateCursor(p, pOp->p1, pOp->p2, -1, 1);
66756 if( u.ax.pCx==0 ) goto no_mem;
66757 u.ax.pCx->nullRow = 1;
66758 rc = sqlite3BtreeOpen(db->pVfs, 0, db, &u.ax.pCx->pBt,
66759 BTREE_OMIT_JOURNAL | BTREE_SINGLE | pOp->p5, vfsFlags);
66760 if( rc==SQLITE_OK ){
66761 rc = sqlite3BtreeBeginTrans(u.ax.pCx->pBt, 1);
66763 if( rc==SQLITE_OK ){
66764 /* If a transient index is required, create it by calling
66765 ** sqlite3BtreeCreateTable() with the BTREE_BLOBKEY flag before
66766 ** opening it. If a transient table is required, just use the
66767 ** automatically created table with root-page 1 (an BLOB_INTKEY table).
66769 if( pOp->p4.pKeyInfo ){
66770 int pgno;
66771 assert( pOp->p4type==P4_KEYINFO );
66772 rc = sqlite3BtreeCreateTable(u.ax.pCx->pBt, &pgno, BTREE_BLOBKEY | pOp->p5);
66773 if( rc==SQLITE_OK ){
66774 assert( pgno==MASTER_ROOT+1 );
66775 rc = sqlite3BtreeCursor(u.ax.pCx->pBt, pgno, 1,
66776 (KeyInfo*)pOp->p4.z, u.ax.pCx->pCursor);
66777 u.ax.pCx->pKeyInfo = pOp->p4.pKeyInfo;
66778 u.ax.pCx->pKeyInfo->enc = ENC(p->db);
66780 u.ax.pCx->isTable = 0;
66781 }else{
66782 rc = sqlite3BtreeCursor(u.ax.pCx->pBt, MASTER_ROOT, 1, 0, u.ax.pCx->pCursor);
66783 u.ax.pCx->isTable = 1;
66786 u.ax.pCx->isOrdered = (pOp->p5!=BTREE_UNORDERED);
66787 u.ax.pCx->isIndex = !u.ax.pCx->isTable;
66788 break;
66791 /* Opcode: OpenSorter P1 P2 * P4 *
66793 ** This opcode works like OP_OpenEphemeral except that it opens
66794 ** a transient index that is specifically designed to sort large
66795 ** tables using an external merge-sort algorithm.
66797 case OP_SorterOpen: {
66798 #if 0 /* local variables moved into u.ay */
66799 VdbeCursor *pCx;
66800 #endif /* local variables moved into u.ay */
66801 #ifndef SQLITE_OMIT_MERGE_SORT
66802 u.ay.pCx = allocateCursor(p, pOp->p1, pOp->p2, -1, 1);
66803 if( u.ay.pCx==0 ) goto no_mem;
66804 u.ay.pCx->pKeyInfo = pOp->p4.pKeyInfo;
66805 u.ay.pCx->pKeyInfo->enc = ENC(p->db);
66806 u.ay.pCx->isSorter = 1;
66807 rc = sqlite3VdbeSorterInit(db, u.ay.pCx);
66808 #else
66809 pOp->opcode = OP_OpenEphemeral;
66810 pc--;
66811 #endif
66812 break;
66815 /* Opcode: OpenPseudo P1 P2 P3 * *
66817 ** Open a new cursor that points to a fake table that contains a single
66818 ** row of data. The content of that one row in the content of memory
66819 ** register P2. In other words, cursor P1 becomes an alias for the
66820 ** MEM_Blob content contained in register P2.
66822 ** A pseudo-table created by this opcode is used to hold a single
66823 ** row output from the sorter so that the row can be decomposed into
66824 ** individual columns using the OP_Column opcode. The OP_Column opcode
66825 ** is the only cursor opcode that works with a pseudo-table.
66827 ** P3 is the number of fields in the records that will be stored by
66828 ** the pseudo-table.
66830 case OP_OpenPseudo: {
66831 #if 0 /* local variables moved into u.az */
66832 VdbeCursor *pCx;
66833 #endif /* local variables moved into u.az */
66835 assert( pOp->p1>=0 );
66836 u.az.pCx = allocateCursor(p, pOp->p1, pOp->p3, -1, 0);
66837 if( u.az.pCx==0 ) goto no_mem;
66838 u.az.pCx->nullRow = 1;
66839 u.az.pCx->pseudoTableReg = pOp->p2;
66840 u.az.pCx->isTable = 1;
66841 u.az.pCx->isIndex = 0;
66842 break;
66845 /* Opcode: Close P1 * * * *
66847 ** Close a cursor previously opened as P1. If P1 is not
66848 ** currently open, this instruction is a no-op.
66850 case OP_Close: {
66851 assert( pOp->p1>=0 && pOp->p1<p->nCursor );
66852 sqlite3VdbeFreeCursor(p, p->apCsr[pOp->p1]);
66853 p->apCsr[pOp->p1] = 0;
66854 break;
66857 /* Opcode: SeekGe P1 P2 P3 P4 *
66859 ** If cursor P1 refers to an SQL table (B-Tree that uses integer keys),
66860 ** use the value in register P3 as the key. If cursor P1 refers
66861 ** to an SQL index, then P3 is the first in an array of P4 registers
66862 ** that are used as an unpacked index key.
66864 ** Reposition cursor P1 so that it points to the smallest entry that
66865 ** is greater than or equal to the key value. If there are no records
66866 ** greater than or equal to the key and P2 is not zero, then jump to P2.
66868 ** See also: Found, NotFound, Distinct, SeekLt, SeekGt, SeekLe
66870 /* Opcode: SeekGt P1 P2 P3 P4 *
66872 ** If cursor P1 refers to an SQL table (B-Tree that uses integer keys),
66873 ** use the value in register P3 as a key. If cursor P1 refers
66874 ** to an SQL index, then P3 is the first in an array of P4 registers
66875 ** that are used as an unpacked index key.
66877 ** Reposition cursor P1 so that it points to the smallest entry that
66878 ** is greater than the key value. If there are no records greater than
66879 ** the key and P2 is not zero, then jump to P2.
66881 ** See also: Found, NotFound, Distinct, SeekLt, SeekGe, SeekLe
66883 /* Opcode: SeekLt P1 P2 P3 P4 *
66885 ** If cursor P1 refers to an SQL table (B-Tree that uses integer keys),
66886 ** use the value in register P3 as a key. If cursor P1 refers
66887 ** to an SQL index, then P3 is the first in an array of P4 registers
66888 ** that are used as an unpacked index key.
66890 ** Reposition cursor P1 so that it points to the largest entry that
66891 ** is less than the key value. If there are no records less than
66892 ** the key and P2 is not zero, then jump to P2.
66894 ** See also: Found, NotFound, Distinct, SeekGt, SeekGe, SeekLe
66896 /* Opcode: SeekLe P1 P2 P3 P4 *
66898 ** If cursor P1 refers to an SQL table (B-Tree that uses integer keys),
66899 ** use the value in register P3 as a key. If cursor P1 refers
66900 ** to an SQL index, then P3 is the first in an array of P4 registers
66901 ** that are used as an unpacked index key.
66903 ** Reposition cursor P1 so that it points to the largest entry that
66904 ** is less than or equal to the key value. If there are no records
66905 ** less than or equal to the key and P2 is not zero, then jump to P2.
66907 ** See also: Found, NotFound, Distinct, SeekGt, SeekGe, SeekLt
66909 case OP_SeekLt: /* jump, in3 */
66910 case OP_SeekLe: /* jump, in3 */
66911 case OP_SeekGe: /* jump, in3 */
66912 case OP_SeekGt: { /* jump, in3 */
66913 #if 0 /* local variables moved into u.ba */
66914 int res;
66915 int oc;
66916 VdbeCursor *pC;
66917 UnpackedRecord r;
66918 int nField;
66919 i64 iKey; /* The rowid we are to seek to */
66920 #endif /* local variables moved into u.ba */
66922 assert( pOp->p1>=0 && pOp->p1<p->nCursor );
66923 assert( pOp->p2!=0 );
66924 u.ba.pC = p->apCsr[pOp->p1];
66925 assert( u.ba.pC!=0 );
66926 assert( u.ba.pC->pseudoTableReg==0 );
66927 assert( OP_SeekLe == OP_SeekLt+1 );
66928 assert( OP_SeekGe == OP_SeekLt+2 );
66929 assert( OP_SeekGt == OP_SeekLt+3 );
66930 assert( u.ba.pC->isOrdered );
66931 if( ALWAYS(u.ba.pC->pCursor!=0) ){
66932 u.ba.oc = pOp->opcode;
66933 u.ba.pC->nullRow = 0;
66934 if( u.ba.pC->isTable ){
66935 /* The input value in P3 might be of any type: integer, real, string,
66936 ** blob, or NULL. But it needs to be an integer before we can do
66937 ** the seek, so covert it. */
66938 pIn3 = &aMem[pOp->p3];
66939 applyNumericAffinity(pIn3);
66940 u.ba.iKey = sqlite3VdbeIntValue(pIn3);
66941 u.ba.pC->rowidIsValid = 0;
66943 /* If the P3 value could not be converted into an integer without
66944 ** loss of information, then special processing is required... */
66945 if( (pIn3->flags & MEM_Int)==0 ){
66946 if( (pIn3->flags & MEM_Real)==0 ){
66947 /* If the P3 value cannot be converted into any kind of a number,
66948 ** then the seek is not possible, so jump to P2 */
66949 pc = pOp->p2 - 1;
66950 break;
66952 /* If we reach this point, then the P3 value must be a floating
66953 ** point number. */
66954 assert( (pIn3->flags & MEM_Real)!=0 );
66956 if( u.ba.iKey==SMALLEST_INT64 && (pIn3->r<(double)u.ba.iKey || pIn3->r>0) ){
66957 /* The P3 value is too large in magnitude to be expressed as an
66958 ** integer. */
66959 u.ba.res = 1;
66960 if( pIn3->r<0 ){
66961 if( u.ba.oc>=OP_SeekGe ){ assert( u.ba.oc==OP_SeekGe || u.ba.oc==OP_SeekGt );
66962 rc = sqlite3BtreeFirst(u.ba.pC->pCursor, &u.ba.res);
66963 if( rc!=SQLITE_OK ) goto abort_due_to_error;
66965 }else{
66966 if( u.ba.oc<=OP_SeekLe ){ assert( u.ba.oc==OP_SeekLt || u.ba.oc==OP_SeekLe );
66967 rc = sqlite3BtreeLast(u.ba.pC->pCursor, &u.ba.res);
66968 if( rc!=SQLITE_OK ) goto abort_due_to_error;
66971 if( u.ba.res ){
66972 pc = pOp->p2 - 1;
66974 break;
66975 }else if( u.ba.oc==OP_SeekLt || u.ba.oc==OP_SeekGe ){
66976 /* Use the ceiling() function to convert real->int */
66977 if( pIn3->r > (double)u.ba.iKey ) u.ba.iKey++;
66978 }else{
66979 /* Use the floor() function to convert real->int */
66980 assert( u.ba.oc==OP_SeekLe || u.ba.oc==OP_SeekGt );
66981 if( pIn3->r < (double)u.ba.iKey ) u.ba.iKey--;
66984 rc = sqlite3BtreeMovetoUnpacked(u.ba.pC->pCursor, 0, (u64)u.ba.iKey, 0, &u.ba.res);
66985 if( rc!=SQLITE_OK ){
66986 goto abort_due_to_error;
66988 if( u.ba.res==0 ){
66989 u.ba.pC->rowidIsValid = 1;
66990 u.ba.pC->lastRowid = u.ba.iKey;
66992 }else{
66993 u.ba.nField = pOp->p4.i;
66994 assert( pOp->p4type==P4_INT32 );
66995 assert( u.ba.nField>0 );
66996 u.ba.r.pKeyInfo = u.ba.pC->pKeyInfo;
66997 u.ba.r.nField = (u16)u.ba.nField;
66999 /* The next line of code computes as follows, only faster:
67000 ** if( u.ba.oc==OP_SeekGt || u.ba.oc==OP_SeekLe ){
67001 ** u.ba.r.flags = UNPACKED_INCRKEY;
67002 ** }else{
67003 ** u.ba.r.flags = 0;
67004 ** }
67006 u.ba.r.flags = (u16)(UNPACKED_INCRKEY * (1 & (u.ba.oc - OP_SeekLt)));
67007 assert( u.ba.oc!=OP_SeekGt || u.ba.r.flags==UNPACKED_INCRKEY );
67008 assert( u.ba.oc!=OP_SeekLe || u.ba.r.flags==UNPACKED_INCRKEY );
67009 assert( u.ba.oc!=OP_SeekGe || u.ba.r.flags==0 );
67010 assert( u.ba.oc!=OP_SeekLt || u.ba.r.flags==0 );
67012 u.ba.r.aMem = &aMem[pOp->p3];
67013 #ifdef SQLITE_DEBUG
67014 { int i; for(i=0; i<u.ba.r.nField; i++) assert( memIsValid(&u.ba.r.aMem[i]) ); }
67015 #endif
67016 ExpandBlob(u.ba.r.aMem);
67017 rc = sqlite3BtreeMovetoUnpacked(u.ba.pC->pCursor, &u.ba.r, 0, 0, &u.ba.res);
67018 if( rc!=SQLITE_OK ){
67019 goto abort_due_to_error;
67021 u.ba.pC->rowidIsValid = 0;
67023 u.ba.pC->deferredMoveto = 0;
67024 u.ba.pC->cacheStatus = CACHE_STALE;
67025 #ifdef SQLITE_TEST
67026 sqlite3_search_count++;
67027 #endif
67028 if( u.ba.oc>=OP_SeekGe ){ assert( u.ba.oc==OP_SeekGe || u.ba.oc==OP_SeekGt );
67029 if( u.ba.res<0 || (u.ba.res==0 && u.ba.oc==OP_SeekGt) ){
67030 rc = sqlite3BtreeNext(u.ba.pC->pCursor, &u.ba.res);
67031 if( rc!=SQLITE_OK ) goto abort_due_to_error;
67032 u.ba.pC->rowidIsValid = 0;
67033 }else{
67034 u.ba.res = 0;
67036 }else{
67037 assert( u.ba.oc==OP_SeekLt || u.ba.oc==OP_SeekLe );
67038 if( u.ba.res>0 || (u.ba.res==0 && u.ba.oc==OP_SeekLt) ){
67039 rc = sqlite3BtreePrevious(u.ba.pC->pCursor, &u.ba.res);
67040 if( rc!=SQLITE_OK ) goto abort_due_to_error;
67041 u.ba.pC->rowidIsValid = 0;
67042 }else{
67043 /* u.ba.res might be negative because the table is empty. Check to
67044 ** see if this is the case.
67046 u.ba.res = sqlite3BtreeEof(u.ba.pC->pCursor);
67049 assert( pOp->p2>0 );
67050 if( u.ba.res ){
67051 pc = pOp->p2 - 1;
67053 }else{
67054 /* This happens when attempting to open the sqlite3_master table
67055 ** for read access returns SQLITE_EMPTY. In this case always
67056 ** take the jump (since there are no records in the table).
67058 pc = pOp->p2 - 1;
67060 break;
67063 /* Opcode: Seek P1 P2 * * *
67065 ** P1 is an open table cursor and P2 is a rowid integer. Arrange
67066 ** for P1 to move so that it points to the rowid given by P2.
67068 ** This is actually a deferred seek. Nothing actually happens until
67069 ** the cursor is used to read a record. That way, if no reads
67070 ** occur, no unnecessary I/O happens.
67072 case OP_Seek: { /* in2 */
67073 #if 0 /* local variables moved into u.bb */
67074 VdbeCursor *pC;
67075 #endif /* local variables moved into u.bb */
67077 assert( pOp->p1>=0 && pOp->p1<p->nCursor );
67078 u.bb.pC = p->apCsr[pOp->p1];
67079 assert( u.bb.pC!=0 );
67080 if( ALWAYS(u.bb.pC->pCursor!=0) ){
67081 assert( u.bb.pC->isTable );
67082 u.bb.pC->nullRow = 0;
67083 pIn2 = &aMem[pOp->p2];
67084 u.bb.pC->movetoTarget = sqlite3VdbeIntValue(pIn2);
67085 u.bb.pC->rowidIsValid = 0;
67086 u.bb.pC->deferredMoveto = 1;
67088 break;
67092 /* Opcode: Found P1 P2 P3 P4 *
67094 ** If P4==0 then register P3 holds a blob constructed by MakeRecord. If
67095 ** P4>0 then register P3 is the first of P4 registers that form an unpacked
67096 ** record.
67098 ** Cursor P1 is on an index btree. If the record identified by P3 and P4
67099 ** is a prefix of any entry in P1 then a jump is made to P2 and
67100 ** P1 is left pointing at the matching entry.
67102 /* Opcode: NotFound P1 P2 P3 P4 *
67104 ** If P4==0 then register P3 holds a blob constructed by MakeRecord. If
67105 ** P4>0 then register P3 is the first of P4 registers that form an unpacked
67106 ** record.
67108 ** Cursor P1 is on an index btree. If the record identified by P3 and P4
67109 ** is not the prefix of any entry in P1 then a jump is made to P2. If P1
67110 ** does contain an entry whose prefix matches the P3/P4 record then control
67111 ** falls through to the next instruction and P1 is left pointing at the
67112 ** matching entry.
67114 ** See also: Found, NotExists, IsUnique
67116 case OP_NotFound: /* jump, in3 */
67117 case OP_Found: { /* jump, in3 */
67118 #if 0 /* local variables moved into u.bc */
67119 int alreadyExists;
67120 VdbeCursor *pC;
67121 int res;
67122 char *pFree;
67123 UnpackedRecord *pIdxKey;
67124 UnpackedRecord r;
67125 char aTempRec[ROUND8(sizeof(UnpackedRecord)) + sizeof(Mem)*3 + 7];
67126 #endif /* local variables moved into u.bc */
67128 #ifdef SQLITE_TEST
67129 sqlite3_found_count++;
67130 #endif
67132 u.bc.alreadyExists = 0;
67133 assert( pOp->p1>=0 && pOp->p1<p->nCursor );
67134 assert( pOp->p4type==P4_INT32 );
67135 u.bc.pC = p->apCsr[pOp->p1];
67136 assert( u.bc.pC!=0 );
67137 pIn3 = &aMem[pOp->p3];
67138 if( ALWAYS(u.bc.pC->pCursor!=0) ){
67140 assert( u.bc.pC->isTable==0 );
67141 if( pOp->p4.i>0 ){
67142 u.bc.r.pKeyInfo = u.bc.pC->pKeyInfo;
67143 u.bc.r.nField = (u16)pOp->p4.i;
67144 u.bc.r.aMem = pIn3;
67145 #ifdef SQLITE_DEBUG
67146 { int i; for(i=0; i<u.bc.r.nField; i++) assert( memIsValid(&u.bc.r.aMem[i]) ); }
67147 #endif
67148 u.bc.r.flags = UNPACKED_PREFIX_MATCH;
67149 u.bc.pIdxKey = &u.bc.r;
67150 }else{
67151 u.bc.pIdxKey = sqlite3VdbeAllocUnpackedRecord(
67152 u.bc.pC->pKeyInfo, u.bc.aTempRec, sizeof(u.bc.aTempRec), &u.bc.pFree
67154 if( u.bc.pIdxKey==0 ) goto no_mem;
67155 assert( pIn3->flags & MEM_Blob );
67156 assert( (pIn3->flags & MEM_Zero)==0 ); /* zeroblobs already expanded */
67157 sqlite3VdbeRecordUnpack(u.bc.pC->pKeyInfo, pIn3->n, pIn3->z, u.bc.pIdxKey);
67158 u.bc.pIdxKey->flags |= UNPACKED_PREFIX_MATCH;
67160 rc = sqlite3BtreeMovetoUnpacked(u.bc.pC->pCursor, u.bc.pIdxKey, 0, 0, &u.bc.res);
67161 if( pOp->p4.i==0 ){
67162 sqlite3DbFree(db, u.bc.pFree);
67164 if( rc!=SQLITE_OK ){
67165 break;
67167 u.bc.alreadyExists = (u.bc.res==0);
67168 u.bc.pC->deferredMoveto = 0;
67169 u.bc.pC->cacheStatus = CACHE_STALE;
67171 if( pOp->opcode==OP_Found ){
67172 if( u.bc.alreadyExists ) pc = pOp->p2 - 1;
67173 }else{
67174 if( !u.bc.alreadyExists ) pc = pOp->p2 - 1;
67176 break;
67179 /* Opcode: IsUnique P1 P2 P3 P4 *
67181 ** Cursor P1 is open on an index b-tree - that is to say, a btree which
67182 ** no data and where the key are records generated by OP_MakeRecord with
67183 ** the list field being the integer ROWID of the entry that the index
67184 ** entry refers to.
67186 ** The P3 register contains an integer record number. Call this record
67187 ** number R. Register P4 is the first in a set of N contiguous registers
67188 ** that make up an unpacked index key that can be used with cursor P1.
67189 ** The value of N can be inferred from the cursor. N includes the rowid
67190 ** value appended to the end of the index record. This rowid value may
67191 ** or may not be the same as R.
67193 ** If any of the N registers beginning with register P4 contains a NULL
67194 ** value, jump immediately to P2.
67196 ** Otherwise, this instruction checks if cursor P1 contains an entry
67197 ** where the first (N-1) fields match but the rowid value at the end
67198 ** of the index entry is not R. If there is no such entry, control jumps
67199 ** to instruction P2. Otherwise, the rowid of the conflicting index
67200 ** entry is copied to register P3 and control falls through to the next
67201 ** instruction.
67203 ** See also: NotFound, NotExists, Found
67205 case OP_IsUnique: { /* jump, in3 */
67206 #if 0 /* local variables moved into u.bd */
67207 u16 ii;
67208 VdbeCursor *pCx;
67209 BtCursor *pCrsr;
67210 u16 nField;
67211 Mem *aMx;
67212 UnpackedRecord r; /* B-Tree index search key */
67213 i64 R; /* Rowid stored in register P3 */
67214 #endif /* local variables moved into u.bd */
67216 pIn3 = &aMem[pOp->p3];
67217 u.bd.aMx = &aMem[pOp->p4.i];
67218 /* Assert that the values of parameters P1 and P4 are in range. */
67219 assert( pOp->p4type==P4_INT32 );
67220 assert( pOp->p4.i>0 && pOp->p4.i<=p->nMem );
67221 assert( pOp->p1>=0 && pOp->p1<p->nCursor );
67223 /* Find the index cursor. */
67224 u.bd.pCx = p->apCsr[pOp->p1];
67225 assert( u.bd.pCx->deferredMoveto==0 );
67226 u.bd.pCx->seekResult = 0;
67227 u.bd.pCx->cacheStatus = CACHE_STALE;
67228 u.bd.pCrsr = u.bd.pCx->pCursor;
67230 /* If any of the values are NULL, take the jump. */
67231 u.bd.nField = u.bd.pCx->pKeyInfo->nField;
67232 for(u.bd.ii=0; u.bd.ii<u.bd.nField; u.bd.ii++){
67233 if( u.bd.aMx[u.bd.ii].flags & MEM_Null ){
67234 pc = pOp->p2 - 1;
67235 u.bd.pCrsr = 0;
67236 break;
67239 assert( (u.bd.aMx[u.bd.nField].flags & MEM_Null)==0 );
67241 if( u.bd.pCrsr!=0 ){
67242 /* Populate the index search key. */
67243 u.bd.r.pKeyInfo = u.bd.pCx->pKeyInfo;
67244 u.bd.r.nField = u.bd.nField + 1;
67245 u.bd.r.flags = UNPACKED_PREFIX_SEARCH;
67246 u.bd.r.aMem = u.bd.aMx;
67247 #ifdef SQLITE_DEBUG
67248 { int i; for(i=0; i<u.bd.r.nField; i++) assert( memIsValid(&u.bd.r.aMem[i]) ); }
67249 #endif
67251 /* Extract the value of u.bd.R from register P3. */
67252 sqlite3VdbeMemIntegerify(pIn3);
67253 u.bd.R = pIn3->u.i;
67255 /* Search the B-Tree index. If no conflicting record is found, jump
67256 ** to P2. Otherwise, copy the rowid of the conflicting record to
67257 ** register P3 and fall through to the next instruction. */
67258 rc = sqlite3BtreeMovetoUnpacked(u.bd.pCrsr, &u.bd.r, 0, 0, &u.bd.pCx->seekResult);
67259 if( (u.bd.r.flags & UNPACKED_PREFIX_SEARCH) || u.bd.r.rowid==u.bd.R ){
67260 pc = pOp->p2 - 1;
67261 }else{
67262 pIn3->u.i = u.bd.r.rowid;
67265 break;
67268 /* Opcode: NotExists P1 P2 P3 * *
67270 ** Use the content of register P3 as an integer key. If a record
67271 ** with that key does not exist in table of P1, then jump to P2.
67272 ** If the record does exist, then fall through. The cursor is left
67273 ** pointing to the record if it exists.
67275 ** The difference between this operation and NotFound is that this
67276 ** operation assumes the key is an integer and that P1 is a table whereas
67277 ** NotFound assumes key is a blob constructed from MakeRecord and
67278 ** P1 is an index.
67280 ** See also: Found, NotFound, IsUnique
67282 case OP_NotExists: { /* jump, in3 */
67283 #if 0 /* local variables moved into u.be */
67284 VdbeCursor *pC;
67285 BtCursor *pCrsr;
67286 int res;
67287 u64 iKey;
67288 #endif /* local variables moved into u.be */
67290 pIn3 = &aMem[pOp->p3];
67291 assert( pIn3->flags & MEM_Int );
67292 assert( pOp->p1>=0 && pOp->p1<p->nCursor );
67293 u.be.pC = p->apCsr[pOp->p1];
67294 assert( u.be.pC!=0 );
67295 assert( u.be.pC->isTable );
67296 assert( u.be.pC->pseudoTableReg==0 );
67297 u.be.pCrsr = u.be.pC->pCursor;
67298 if( ALWAYS(u.be.pCrsr!=0) ){
67299 u.be.res = 0;
67300 u.be.iKey = pIn3->u.i;
67301 rc = sqlite3BtreeMovetoUnpacked(u.be.pCrsr, 0, u.be.iKey, 0, &u.be.res);
67302 u.be.pC->lastRowid = pIn3->u.i;
67303 u.be.pC->rowidIsValid = u.be.res==0 ?1:0;
67304 u.be.pC->nullRow = 0;
67305 u.be.pC->cacheStatus = CACHE_STALE;
67306 u.be.pC->deferredMoveto = 0;
67307 if( u.be.res!=0 ){
67308 pc = pOp->p2 - 1;
67309 assert( u.be.pC->rowidIsValid==0 );
67311 u.be.pC->seekResult = u.be.res;
67312 }else{
67313 /* This happens when an attempt to open a read cursor on the
67314 ** sqlite_master table returns SQLITE_EMPTY.
67316 pc = pOp->p2 - 1;
67317 assert( u.be.pC->rowidIsValid==0 );
67318 u.be.pC->seekResult = 0;
67320 break;
67323 /* Opcode: Sequence P1 P2 * * *
67325 ** Find the next available sequence number for cursor P1.
67326 ** Write the sequence number into register P2.
67327 ** The sequence number on the cursor is incremented after this
67328 ** instruction.
67330 case OP_Sequence: { /* out2-prerelease */
67331 assert( pOp->p1>=0 && pOp->p1<p->nCursor );
67332 assert( p->apCsr[pOp->p1]!=0 );
67333 pOut->u.i = p->apCsr[pOp->p1]->seqCount++;
67334 break;
67338 /* Opcode: NewRowid P1 P2 P3 * *
67340 ** Get a new integer record number (a.k.a "rowid") used as the key to a table.
67341 ** The record number is not previously used as a key in the database
67342 ** table that cursor P1 points to. The new record number is written
67343 ** written to register P2.
67345 ** If P3>0 then P3 is a register in the root frame of this VDBE that holds
67346 ** the largest previously generated record number. No new record numbers are
67347 ** allowed to be less than this value. When this value reaches its maximum,
67348 ** an SQLITE_FULL error is generated. The P3 register is updated with the '
67349 ** generated record number. This P3 mechanism is used to help implement the
67350 ** AUTOINCREMENT feature.
67352 case OP_NewRowid: { /* out2-prerelease */
67353 #if 0 /* local variables moved into u.bf */
67354 i64 v; /* The new rowid */
67355 VdbeCursor *pC; /* Cursor of table to get the new rowid */
67356 int res; /* Result of an sqlite3BtreeLast() */
67357 int cnt; /* Counter to limit the number of searches */
67358 Mem *pMem; /* Register holding largest rowid for AUTOINCREMENT */
67359 VdbeFrame *pFrame; /* Root frame of VDBE */
67360 #endif /* local variables moved into u.bf */
67362 u.bf.v = 0;
67363 u.bf.res = 0;
67364 assert( pOp->p1>=0 && pOp->p1<p->nCursor );
67365 u.bf.pC = p->apCsr[pOp->p1];
67366 assert( u.bf.pC!=0 );
67367 if( NEVER(u.bf.pC->pCursor==0) ){
67368 /* The zero initialization above is all that is needed */
67369 }else{
67370 /* The next rowid or record number (different terms for the same
67371 ** thing) is obtained in a two-step algorithm.
67373 ** First we attempt to find the largest existing rowid and add one
67374 ** to that. But if the largest existing rowid is already the maximum
67375 ** positive integer, we have to fall through to the second
67376 ** probabilistic algorithm
67378 ** The second algorithm is to select a rowid at random and see if
67379 ** it already exists in the table. If it does not exist, we have
67380 ** succeeded. If the random rowid does exist, we select a new one
67381 ** and try again, up to 100 times.
67383 assert( u.bf.pC->isTable );
67385 #ifdef SQLITE_32BIT_ROWID
67386 # define MAX_ROWID 0x7fffffff
67387 #else
67388 /* Some compilers complain about constants of the form 0x7fffffffffffffff.
67389 ** Others complain about 0x7ffffffffffffffffLL. The following macro seems
67390 ** to provide the constant while making all compilers happy.
67392 # define MAX_ROWID (i64)( (((u64)0x7fffffff)<<32) | (u64)0xffffffff )
67393 #endif
67395 if( !u.bf.pC->useRandomRowid ){
67396 u.bf.v = sqlite3BtreeGetCachedRowid(u.bf.pC->pCursor);
67397 if( u.bf.v==0 ){
67398 rc = sqlite3BtreeLast(u.bf.pC->pCursor, &u.bf.res);
67399 if( rc!=SQLITE_OK ){
67400 goto abort_due_to_error;
67402 if( u.bf.res ){
67403 u.bf.v = 1; /* IMP: R-61914-48074 */
67404 }else{
67405 assert( sqlite3BtreeCursorIsValid(u.bf.pC->pCursor) );
67406 rc = sqlite3BtreeKeySize(u.bf.pC->pCursor, &u.bf.v);
67407 assert( rc==SQLITE_OK ); /* Cannot fail following BtreeLast() */
67408 if( u.bf.v==MAX_ROWID ){
67409 u.bf.pC->useRandomRowid = 1;
67410 }else{
67411 u.bf.v++; /* IMP: R-29538-34987 */
67416 #ifndef SQLITE_OMIT_AUTOINCREMENT
67417 if( pOp->p3 ){
67418 /* Assert that P3 is a valid memory cell. */
67419 assert( pOp->p3>0 );
67420 if( p->pFrame ){
67421 for(u.bf.pFrame=p->pFrame; u.bf.pFrame->pParent; u.bf.pFrame=u.bf.pFrame->pParent);
67422 /* Assert that P3 is a valid memory cell. */
67423 assert( pOp->p3<=u.bf.pFrame->nMem );
67424 u.bf.pMem = &u.bf.pFrame->aMem[pOp->p3];
67425 }else{
67426 /* Assert that P3 is a valid memory cell. */
67427 assert( pOp->p3<=p->nMem );
67428 u.bf.pMem = &aMem[pOp->p3];
67429 memAboutToChange(p, u.bf.pMem);
67431 assert( memIsValid(u.bf.pMem) );
67433 REGISTER_TRACE(pOp->p3, u.bf.pMem);
67434 sqlite3VdbeMemIntegerify(u.bf.pMem);
67435 assert( (u.bf.pMem->flags & MEM_Int)!=0 ); /* mem(P3) holds an integer */
67436 if( u.bf.pMem->u.i==MAX_ROWID || u.bf.pC->useRandomRowid ){
67437 rc = SQLITE_FULL; /* IMP: R-12275-61338 */
67438 goto abort_due_to_error;
67440 if( u.bf.v<u.bf.pMem->u.i+1 ){
67441 u.bf.v = u.bf.pMem->u.i + 1;
67443 u.bf.pMem->u.i = u.bf.v;
67445 #endif
67447 sqlite3BtreeSetCachedRowid(u.bf.pC->pCursor, u.bf.v<MAX_ROWID ? u.bf.v+1 : 0);
67449 if( u.bf.pC->useRandomRowid ){
67450 /* IMPLEMENTATION-OF: R-07677-41881 If the largest ROWID is equal to the
67451 ** largest possible integer (9223372036854775807) then the database
67452 ** engine starts picking positive candidate ROWIDs at random until
67453 ** it finds one that is not previously used. */
67454 assert( pOp->p3==0 ); /* We cannot be in random rowid mode if this is
67455 ** an AUTOINCREMENT table. */
67456 /* on the first attempt, simply do one more than previous */
67457 u.bf.v = lastRowid;
67458 u.bf.v &= (MAX_ROWID>>1); /* ensure doesn't go negative */
67459 u.bf.v++; /* ensure non-zero */
67460 u.bf.cnt = 0;
67461 while( ((rc = sqlite3BtreeMovetoUnpacked(u.bf.pC->pCursor, 0, (u64)u.bf.v,
67462 0, &u.bf.res))==SQLITE_OK)
67463 && (u.bf.res==0)
67464 && (++u.bf.cnt<100)){
67465 /* collision - try another random rowid */
67466 sqlite3_randomness(sizeof(u.bf.v), &u.bf.v);
67467 if( u.bf.cnt<5 ){
67468 /* try "small" random rowids for the initial attempts */
67469 u.bf.v &= 0xffffff;
67470 }else{
67471 u.bf.v &= (MAX_ROWID>>1); /* ensure doesn't go negative */
67473 u.bf.v++; /* ensure non-zero */
67475 if( rc==SQLITE_OK && u.bf.res==0 ){
67476 rc = SQLITE_FULL; /* IMP: R-38219-53002 */
67477 goto abort_due_to_error;
67479 assert( u.bf.v>0 ); /* EV: R-40812-03570 */
67481 u.bf.pC->rowidIsValid = 0;
67482 u.bf.pC->deferredMoveto = 0;
67483 u.bf.pC->cacheStatus = CACHE_STALE;
67485 pOut->u.i = u.bf.v;
67486 break;
67489 /* Opcode: Insert P1 P2 P3 P4 P5
67491 ** Write an entry into the table of cursor P1. A new entry is
67492 ** created if it doesn't already exist or the data for an existing
67493 ** entry is overwritten. The data is the value MEM_Blob stored in register
67494 ** number P2. The key is stored in register P3. The key must
67495 ** be a MEM_Int.
67497 ** If the OPFLAG_NCHANGE flag of P5 is set, then the row change count is
67498 ** incremented (otherwise not). If the OPFLAG_LASTROWID flag of P5 is set,
67499 ** then rowid is stored for subsequent return by the
67500 ** sqlite3_last_insert_rowid() function (otherwise it is unmodified).
67502 ** If the OPFLAG_USESEEKRESULT flag of P5 is set and if the result of
67503 ** the last seek operation (OP_NotExists) was a success, then this
67504 ** operation will not attempt to find the appropriate row before doing
67505 ** the insert but will instead overwrite the row that the cursor is
67506 ** currently pointing to. Presumably, the prior OP_NotExists opcode
67507 ** has already positioned the cursor correctly. This is an optimization
67508 ** that boosts performance by avoiding redundant seeks.
67510 ** If the OPFLAG_ISUPDATE flag is set, then this opcode is part of an
67511 ** UPDATE operation. Otherwise (if the flag is clear) then this opcode
67512 ** is part of an INSERT operation. The difference is only important to
67513 ** the update hook.
67515 ** Parameter P4 may point to a string containing the table-name, or
67516 ** may be NULL. If it is not NULL, then the update-hook
67517 ** (sqlite3.xUpdateCallback) is invoked following a successful insert.
67519 ** (WARNING/TODO: If P1 is a pseudo-cursor and P2 is dynamically
67520 ** allocated, then ownership of P2 is transferred to the pseudo-cursor
67521 ** and register P2 becomes ephemeral. If the cursor is changed, the
67522 ** value of register P2 will then change. Make sure this does not
67523 ** cause any problems.)
67525 ** This instruction only works on tables. The equivalent instruction
67526 ** for indices is OP_IdxInsert.
67528 /* Opcode: InsertInt P1 P2 P3 P4 P5
67530 ** This works exactly like OP_Insert except that the key is the
67531 ** integer value P3, not the value of the integer stored in register P3.
67533 case OP_Insert:
67534 case OP_InsertInt: {
67535 #if 0 /* local variables moved into u.bg */
67536 Mem *pData; /* MEM cell holding data for the record to be inserted */
67537 Mem *pKey; /* MEM cell holding key for the record */
67538 i64 iKey; /* The integer ROWID or key for the record to be inserted */
67539 VdbeCursor *pC; /* Cursor to table into which insert is written */
67540 int nZero; /* Number of zero-bytes to append */
67541 int seekResult; /* Result of prior seek or 0 if no USESEEKRESULT flag */
67542 const char *zDb; /* database name - used by the update hook */
67543 const char *zTbl; /* Table name - used by the opdate hook */
67544 int op; /* Opcode for update hook: SQLITE_UPDATE or SQLITE_INSERT */
67545 #endif /* local variables moved into u.bg */
67547 u.bg.pData = &aMem[pOp->p2];
67548 assert( pOp->p1>=0 && pOp->p1<p->nCursor );
67549 assert( memIsValid(u.bg.pData) );
67550 u.bg.pC = p->apCsr[pOp->p1];
67551 assert( u.bg.pC!=0 );
67552 assert( u.bg.pC->pCursor!=0 );
67553 assert( u.bg.pC->pseudoTableReg==0 );
67554 assert( u.bg.pC->isTable );
67555 REGISTER_TRACE(pOp->p2, u.bg.pData);
67557 if( pOp->opcode==OP_Insert ){
67558 u.bg.pKey = &aMem[pOp->p3];
67559 assert( u.bg.pKey->flags & MEM_Int );
67560 assert( memIsValid(u.bg.pKey) );
67561 REGISTER_TRACE(pOp->p3, u.bg.pKey);
67562 u.bg.iKey = u.bg.pKey->u.i;
67563 }else{
67564 assert( pOp->opcode==OP_InsertInt );
67565 u.bg.iKey = pOp->p3;
67568 if( pOp->p5 & OPFLAG_NCHANGE ) p->nChange++;
67569 if( pOp->p5 & OPFLAG_LASTROWID ) db->lastRowid = lastRowid = u.bg.iKey;
67570 if( u.bg.pData->flags & MEM_Null ){
67571 u.bg.pData->z = 0;
67572 u.bg.pData->n = 0;
67573 }else{
67574 assert( u.bg.pData->flags & (MEM_Blob|MEM_Str) );
67576 u.bg.seekResult = ((pOp->p5 & OPFLAG_USESEEKRESULT) ? u.bg.pC->seekResult : 0);
67577 if( u.bg.pData->flags & MEM_Zero ){
67578 u.bg.nZero = u.bg.pData->u.nZero;
67579 }else{
67580 u.bg.nZero = 0;
67582 sqlite3BtreeSetCachedRowid(u.bg.pC->pCursor, 0);
67583 rc = sqlite3BtreeInsert(u.bg.pC->pCursor, 0, u.bg.iKey,
67584 u.bg.pData->z, u.bg.pData->n, u.bg.nZero,
67585 pOp->p5 & OPFLAG_APPEND, u.bg.seekResult
67587 u.bg.pC->rowidIsValid = 0;
67588 u.bg.pC->deferredMoveto = 0;
67589 u.bg.pC->cacheStatus = CACHE_STALE;
67591 /* Invoke the update-hook if required. */
67592 if( rc==SQLITE_OK && db->xUpdateCallback && pOp->p4.z ){
67593 u.bg.zDb = db->aDb[u.bg.pC->iDb].zName;
67594 u.bg.zTbl = pOp->p4.z;
67595 u.bg.op = ((pOp->p5 & OPFLAG_ISUPDATE) ? SQLITE_UPDATE : SQLITE_INSERT);
67596 assert( u.bg.pC->isTable );
67597 db->xUpdateCallback(db->pUpdateArg, u.bg.op, u.bg.zDb, u.bg.zTbl, u.bg.iKey);
67598 assert( u.bg.pC->iDb>=0 );
67600 break;
67603 /* Opcode: Delete P1 P2 * P4 *
67605 ** Delete the record at which the P1 cursor is currently pointing.
67607 ** The cursor will be left pointing at either the next or the previous
67608 ** record in the table. If it is left pointing at the next record, then
67609 ** the next Next instruction will be a no-op. Hence it is OK to delete
67610 ** a record from within an Next loop.
67612 ** If the OPFLAG_NCHANGE flag of P2 is set, then the row change count is
67613 ** incremented (otherwise not).
67615 ** P1 must not be pseudo-table. It has to be a real table with
67616 ** multiple rows.
67618 ** If P4 is not NULL, then it is the name of the table that P1 is
67619 ** pointing to. The update hook will be invoked, if it exists.
67620 ** If P4 is not NULL then the P1 cursor must have been positioned
67621 ** using OP_NotFound prior to invoking this opcode.
67623 case OP_Delete: {
67624 #if 0 /* local variables moved into u.bh */
67625 i64 iKey;
67626 VdbeCursor *pC;
67627 #endif /* local variables moved into u.bh */
67629 u.bh.iKey = 0;
67630 assert( pOp->p1>=0 && pOp->p1<p->nCursor );
67631 u.bh.pC = p->apCsr[pOp->p1];
67632 assert( u.bh.pC!=0 );
67633 assert( u.bh.pC->pCursor!=0 ); /* Only valid for real tables, no pseudotables */
67635 /* If the update-hook will be invoked, set u.bh.iKey to the rowid of the
67636 ** row being deleted.
67638 if( db->xUpdateCallback && pOp->p4.z ){
67639 assert( u.bh.pC->isTable );
67640 assert( u.bh.pC->rowidIsValid ); /* lastRowid set by previous OP_NotFound */
67641 u.bh.iKey = u.bh.pC->lastRowid;
67644 /* The OP_Delete opcode always follows an OP_NotExists or OP_Last or
67645 ** OP_Column on the same table without any intervening operations that
67646 ** might move or invalidate the cursor. Hence cursor u.bh.pC is always pointing
67647 ** to the row to be deleted and the sqlite3VdbeCursorMoveto() operation
67648 ** below is always a no-op and cannot fail. We will run it anyhow, though,
67649 ** to guard against future changes to the code generator.
67651 assert( u.bh.pC->deferredMoveto==0 );
67652 rc = sqlite3VdbeCursorMoveto(u.bh.pC);
67653 if( NEVER(rc!=SQLITE_OK) ) goto abort_due_to_error;
67655 sqlite3BtreeSetCachedRowid(u.bh.pC->pCursor, 0);
67656 rc = sqlite3BtreeDelete(u.bh.pC->pCursor);
67657 u.bh.pC->cacheStatus = CACHE_STALE;
67659 /* Invoke the update-hook if required. */
67660 if( rc==SQLITE_OK && db->xUpdateCallback && pOp->p4.z ){
67661 const char *zDb = db->aDb[u.bh.pC->iDb].zName;
67662 const char *zTbl = pOp->p4.z;
67663 db->xUpdateCallback(db->pUpdateArg, SQLITE_DELETE, zDb, zTbl, u.bh.iKey);
67664 assert( u.bh.pC->iDb>=0 );
67666 if( pOp->p2 & OPFLAG_NCHANGE ) p->nChange++;
67667 break;
67669 /* Opcode: ResetCount * * * * *
67671 ** The value of the change counter is copied to the database handle
67672 ** change counter (returned by subsequent calls to sqlite3_changes()).
67673 ** Then the VMs internal change counter resets to 0.
67674 ** This is used by trigger programs.
67676 case OP_ResetCount: {
67677 sqlite3VdbeSetChanges(db, p->nChange);
67678 p->nChange = 0;
67679 break;
67682 /* Opcode: SorterCompare P1 P2 P3
67684 ** P1 is a sorter cursor. This instruction compares the record blob in
67685 ** register P3 with the entry that the sorter cursor currently points to.
67686 ** If, excluding the rowid fields at the end, the two records are a match,
67687 ** fall through to the next instruction. Otherwise, jump to instruction P2.
67689 case OP_SorterCompare: {
67690 #if 0 /* local variables moved into u.bi */
67691 VdbeCursor *pC;
67692 int res;
67693 #endif /* local variables moved into u.bi */
67695 u.bi.pC = p->apCsr[pOp->p1];
67696 assert( isSorter(u.bi.pC) );
67697 pIn3 = &aMem[pOp->p3];
67698 rc = sqlite3VdbeSorterCompare(u.bi.pC, pIn3, &u.bi.res);
67699 if( u.bi.res ){
67700 pc = pOp->p2-1;
67702 break;
67705 /* Opcode: SorterData P1 P2 * * *
67707 ** Write into register P2 the current sorter data for sorter cursor P1.
67709 case OP_SorterData: {
67710 #if 0 /* local variables moved into u.bj */
67711 VdbeCursor *pC;
67712 #endif /* local variables moved into u.bj */
67713 #ifndef SQLITE_OMIT_MERGE_SORT
67714 pOut = &aMem[pOp->p2];
67715 u.bj.pC = p->apCsr[pOp->p1];
67716 assert( u.bj.pC->isSorter );
67717 rc = sqlite3VdbeSorterRowkey(u.bj.pC, pOut);
67718 #else
67719 pOp->opcode = OP_RowKey;
67720 pc--;
67721 #endif
67722 break;
67725 /* Opcode: RowData P1 P2 * * *
67727 ** Write into register P2 the complete row data for cursor P1.
67728 ** There is no interpretation of the data.
67729 ** It is just copied onto the P2 register exactly as
67730 ** it is found in the database file.
67732 ** If the P1 cursor must be pointing to a valid row (not a NULL row)
67733 ** of a real table, not a pseudo-table.
67735 /* Opcode: RowKey P1 P2 * * *
67737 ** Write into register P2 the complete row key for cursor P1.
67738 ** There is no interpretation of the data.
67739 ** The key is copied onto the P3 register exactly as
67740 ** it is found in the database file.
67742 ** If the P1 cursor must be pointing to a valid row (not a NULL row)
67743 ** of a real table, not a pseudo-table.
67745 case OP_RowKey:
67746 case OP_RowData: {
67747 #if 0 /* local variables moved into u.bk */
67748 VdbeCursor *pC;
67749 BtCursor *pCrsr;
67750 u32 n;
67751 i64 n64;
67752 #endif /* local variables moved into u.bk */
67754 pOut = &aMem[pOp->p2];
67755 memAboutToChange(p, pOut);
67757 /* Note that RowKey and RowData are really exactly the same instruction */
67758 assert( pOp->p1>=0 && pOp->p1<p->nCursor );
67759 u.bk.pC = p->apCsr[pOp->p1];
67760 assert( u.bk.pC->isSorter==0 );
67761 assert( u.bk.pC->isTable || pOp->opcode!=OP_RowData );
67762 assert( u.bk.pC->isIndex || pOp->opcode==OP_RowData );
67763 assert( u.bk.pC!=0 );
67764 assert( u.bk.pC->nullRow==0 );
67765 assert( u.bk.pC->pseudoTableReg==0 );
67766 assert( !u.bk.pC->isSorter );
67767 assert( u.bk.pC->pCursor!=0 );
67768 u.bk.pCrsr = u.bk.pC->pCursor;
67769 assert( sqlite3BtreeCursorIsValid(u.bk.pCrsr) );
67771 /* The OP_RowKey and OP_RowData opcodes always follow OP_NotExists or
67772 ** OP_Rewind/Op_Next with no intervening instructions that might invalidate
67773 ** the cursor. Hence the following sqlite3VdbeCursorMoveto() call is always
67774 ** a no-op and can never fail. But we leave it in place as a safety.
67776 assert( u.bk.pC->deferredMoveto==0 );
67777 rc = sqlite3VdbeCursorMoveto(u.bk.pC);
67778 if( NEVER(rc!=SQLITE_OK) ) goto abort_due_to_error;
67780 if( u.bk.pC->isIndex ){
67781 assert( !u.bk.pC->isTable );
67782 rc = sqlite3BtreeKeySize(u.bk.pCrsr, &u.bk.n64);
67783 assert( rc==SQLITE_OK ); /* True because of CursorMoveto() call above */
67784 if( u.bk.n64>db->aLimit[SQLITE_LIMIT_LENGTH] ){
67785 goto too_big;
67787 u.bk.n = (u32)u.bk.n64;
67788 }else{
67789 rc = sqlite3BtreeDataSize(u.bk.pCrsr, &u.bk.n);
67790 assert( rc==SQLITE_OK ); /* DataSize() cannot fail */
67791 if( u.bk.n>(u32)db->aLimit[SQLITE_LIMIT_LENGTH] ){
67792 goto too_big;
67795 if( sqlite3VdbeMemGrow(pOut, u.bk.n, 0) ){
67796 goto no_mem;
67798 pOut->n = u.bk.n;
67799 MemSetTypeFlag(pOut, MEM_Blob);
67800 if( u.bk.pC->isIndex ){
67801 rc = sqlite3BtreeKey(u.bk.pCrsr, 0, u.bk.n, pOut->z);
67802 }else{
67803 rc = sqlite3BtreeData(u.bk.pCrsr, 0, u.bk.n, pOut->z);
67805 pOut->enc = SQLITE_UTF8; /* In case the blob is ever cast to text */
67806 UPDATE_MAX_BLOBSIZE(pOut);
67807 break;
67810 /* Opcode: Rowid P1 P2 * * *
67812 ** Store in register P2 an integer which is the key of the table entry that
67813 ** P1 is currently point to.
67815 ** P1 can be either an ordinary table or a virtual table. There used to
67816 ** be a separate OP_VRowid opcode for use with virtual tables, but this
67817 ** one opcode now works for both table types.
67819 case OP_Rowid: { /* out2-prerelease */
67820 #if 0 /* local variables moved into u.bl */
67821 VdbeCursor *pC;
67822 i64 v;
67823 sqlite3_vtab *pVtab;
67824 const sqlite3_module *pModule;
67825 #endif /* local variables moved into u.bl */
67827 assert( pOp->p1>=0 && pOp->p1<p->nCursor );
67828 u.bl.pC = p->apCsr[pOp->p1];
67829 assert( u.bl.pC!=0 );
67830 assert( u.bl.pC->pseudoTableReg==0 );
67831 if( u.bl.pC->nullRow ){
67832 pOut->flags = MEM_Null;
67833 break;
67834 }else if( u.bl.pC->deferredMoveto ){
67835 u.bl.v = u.bl.pC->movetoTarget;
67836 #ifndef SQLITE_OMIT_VIRTUALTABLE
67837 }else if( u.bl.pC->pVtabCursor ){
67838 u.bl.pVtab = u.bl.pC->pVtabCursor->pVtab;
67839 u.bl.pModule = u.bl.pVtab->pModule;
67840 assert( u.bl.pModule->xRowid );
67841 rc = u.bl.pModule->xRowid(u.bl.pC->pVtabCursor, &u.bl.v);
67842 importVtabErrMsg(p, u.bl.pVtab);
67843 #endif /* SQLITE_OMIT_VIRTUALTABLE */
67844 }else{
67845 assert( u.bl.pC->pCursor!=0 );
67846 rc = sqlite3VdbeCursorMoveto(u.bl.pC);
67847 if( rc ) goto abort_due_to_error;
67848 if( u.bl.pC->rowidIsValid ){
67849 u.bl.v = u.bl.pC->lastRowid;
67850 }else{
67851 rc = sqlite3BtreeKeySize(u.bl.pC->pCursor, &u.bl.v);
67852 assert( rc==SQLITE_OK ); /* Always so because of CursorMoveto() above */
67855 pOut->u.i = u.bl.v;
67856 break;
67859 /* Opcode: NullRow P1 * * * *
67861 ** Move the cursor P1 to a null row. Any OP_Column operations
67862 ** that occur while the cursor is on the null row will always
67863 ** write a NULL.
67865 case OP_NullRow: {
67866 #if 0 /* local variables moved into u.bm */
67867 VdbeCursor *pC;
67868 #endif /* local variables moved into u.bm */
67870 assert( pOp->p1>=0 && pOp->p1<p->nCursor );
67871 u.bm.pC = p->apCsr[pOp->p1];
67872 assert( u.bm.pC!=0 );
67873 u.bm.pC->nullRow = 1;
67874 u.bm.pC->rowidIsValid = 0;
67875 assert( u.bm.pC->pCursor || u.bm.pC->pVtabCursor );
67876 if( u.bm.pC->pCursor ){
67877 sqlite3BtreeClearCursor(u.bm.pC->pCursor);
67879 break;
67882 /* Opcode: Last P1 P2 * * *
67884 ** The next use of the Rowid or Column or Next instruction for P1
67885 ** will refer to the last entry in the database table or index.
67886 ** If the table or index is empty and P2>0, then jump immediately to P2.
67887 ** If P2 is 0 or if the table or index is not empty, fall through
67888 ** to the following instruction.
67890 case OP_Last: { /* jump */
67891 #if 0 /* local variables moved into u.bn */
67892 VdbeCursor *pC;
67893 BtCursor *pCrsr;
67894 int res;
67895 #endif /* local variables moved into u.bn */
67897 assert( pOp->p1>=0 && pOp->p1<p->nCursor );
67898 u.bn.pC = p->apCsr[pOp->p1];
67899 assert( u.bn.pC!=0 );
67900 u.bn.pCrsr = u.bn.pC->pCursor;
67901 if( NEVER(u.bn.pCrsr==0) ){
67902 u.bn.res = 1;
67903 }else{
67904 rc = sqlite3BtreeLast(u.bn.pCrsr, &u.bn.res);
67906 u.bn.pC->nullRow = (u8)u.bn.res;
67907 u.bn.pC->deferredMoveto = 0;
67908 u.bn.pC->rowidIsValid = 0;
67909 u.bn.pC->cacheStatus = CACHE_STALE;
67910 if( pOp->p2>0 && u.bn.res ){
67911 pc = pOp->p2 - 1;
67913 break;
67917 /* Opcode: Sort P1 P2 * * *
67919 ** This opcode does exactly the same thing as OP_Rewind except that
67920 ** it increments an undocumented global variable used for testing.
67922 ** Sorting is accomplished by writing records into a sorting index,
67923 ** then rewinding that index and playing it back from beginning to
67924 ** end. We use the OP_Sort opcode instead of OP_Rewind to do the
67925 ** rewinding so that the global variable will be incremented and
67926 ** regression tests can determine whether or not the optimizer is
67927 ** correctly optimizing out sorts.
67929 case OP_SorterSort: /* jump */
67930 #ifdef SQLITE_OMIT_MERGE_SORT
67931 pOp->opcode = OP_Sort;
67932 #endif
67933 case OP_Sort: { /* jump */
67934 #ifdef SQLITE_TEST
67935 sqlite3_sort_count++;
67936 sqlite3_search_count--;
67937 #endif
67938 p->aCounter[SQLITE_STMTSTATUS_SORT-1]++;
67939 /* Fall through into OP_Rewind */
67941 /* Opcode: Rewind P1 P2 * * *
67943 ** The next use of the Rowid or Column or Next instruction for P1
67944 ** will refer to the first entry in the database table or index.
67945 ** If the table or index is empty and P2>0, then jump immediately to P2.
67946 ** If P2 is 0 or if the table or index is not empty, fall through
67947 ** to the following instruction.
67949 case OP_Rewind: { /* jump */
67950 #if 0 /* local variables moved into u.bo */
67951 VdbeCursor *pC;
67952 BtCursor *pCrsr;
67953 int res;
67954 #endif /* local variables moved into u.bo */
67956 assert( pOp->p1>=0 && pOp->p1<p->nCursor );
67957 u.bo.pC = p->apCsr[pOp->p1];
67958 assert( u.bo.pC!=0 );
67959 assert( u.bo.pC->isSorter==(pOp->opcode==OP_SorterSort) );
67960 u.bo.res = 1;
67961 if( isSorter(u.bo.pC) ){
67962 rc = sqlite3VdbeSorterRewind(db, u.bo.pC, &u.bo.res);
67963 }else{
67964 u.bo.pCrsr = u.bo.pC->pCursor;
67965 assert( u.bo.pCrsr );
67966 rc = sqlite3BtreeFirst(u.bo.pCrsr, &u.bo.res);
67967 u.bo.pC->atFirst = u.bo.res==0 ?1:0;
67968 u.bo.pC->deferredMoveto = 0;
67969 u.bo.pC->cacheStatus = CACHE_STALE;
67970 u.bo.pC->rowidIsValid = 0;
67972 u.bo.pC->nullRow = (u8)u.bo.res;
67973 assert( pOp->p2>0 && pOp->p2<p->nOp );
67974 if( u.bo.res ){
67975 pc = pOp->p2 - 1;
67977 break;
67980 /* Opcode: Next P1 P2 * P4 P5
67982 ** Advance cursor P1 so that it points to the next key/data pair in its
67983 ** table or index. If there are no more key/value pairs then fall through
67984 ** to the following instruction. But if the cursor advance was successful,
67985 ** jump immediately to P2.
67987 ** The P1 cursor must be for a real table, not a pseudo-table.
67989 ** P4 is always of type P4_ADVANCE. The function pointer points to
67990 ** sqlite3BtreeNext().
67992 ** If P5 is positive and the jump is taken, then event counter
67993 ** number P5-1 in the prepared statement is incremented.
67995 ** See also: Prev
67997 /* Opcode: Prev P1 P2 * * P5
67999 ** Back up cursor P1 so that it points to the previous key/data pair in its
68000 ** table or index. If there is no previous key/value pairs then fall through
68001 ** to the following instruction. But if the cursor backup was successful,
68002 ** jump immediately to P2.
68004 ** The P1 cursor must be for a real table, not a pseudo-table.
68006 ** P4 is always of type P4_ADVANCE. The function pointer points to
68007 ** sqlite3BtreePrevious().
68009 ** If P5 is positive and the jump is taken, then event counter
68010 ** number P5-1 in the prepared statement is incremented.
68012 case OP_SorterNext: /* jump */
68013 #ifdef SQLITE_OMIT_MERGE_SORT
68014 pOp->opcode = OP_Next;
68015 #endif
68016 case OP_Prev: /* jump */
68017 case OP_Next: { /* jump */
68018 #if 0 /* local variables moved into u.bp */
68019 VdbeCursor *pC;
68020 int res;
68021 #endif /* local variables moved into u.bp */
68023 CHECK_FOR_INTERRUPT;
68024 assert( pOp->p1>=0 && pOp->p1<p->nCursor );
68025 assert( pOp->p5<=ArraySize(p->aCounter) );
68026 u.bp.pC = p->apCsr[pOp->p1];
68027 if( u.bp.pC==0 ){
68028 break; /* See ticket #2273 */
68030 assert( u.bp.pC->isSorter==(pOp->opcode==OP_SorterNext) );
68031 if( isSorter(u.bp.pC) ){
68032 assert( pOp->opcode==OP_SorterNext );
68033 rc = sqlite3VdbeSorterNext(db, u.bp.pC, &u.bp.res);
68034 }else{
68035 u.bp.res = 1;
68036 assert( u.bp.pC->deferredMoveto==0 );
68037 assert( u.bp.pC->pCursor );
68038 assert( pOp->opcode!=OP_Next || pOp->p4.xAdvance==sqlite3BtreeNext );
68039 assert( pOp->opcode!=OP_Prev || pOp->p4.xAdvance==sqlite3BtreePrevious );
68040 rc = pOp->p4.xAdvance(u.bp.pC->pCursor, &u.bp.res);
68042 u.bp.pC->nullRow = (u8)u.bp.res;
68043 u.bp.pC->cacheStatus = CACHE_STALE;
68044 if( u.bp.res==0 ){
68045 pc = pOp->p2 - 1;
68046 if( pOp->p5 ) p->aCounter[pOp->p5-1]++;
68047 #ifdef SQLITE_TEST
68048 sqlite3_search_count++;
68049 #endif
68051 u.bp.pC->rowidIsValid = 0;
68052 break;
68055 /* Opcode: IdxInsert P1 P2 P3 * P5
68057 ** Register P2 holds an SQL index key made using the
68058 ** MakeRecord instructions. This opcode writes that key
68059 ** into the index P1. Data for the entry is nil.
68061 ** P3 is a flag that provides a hint to the b-tree layer that this
68062 ** insert is likely to be an append.
68064 ** This instruction only works for indices. The equivalent instruction
68065 ** for tables is OP_Insert.
68067 case OP_SorterInsert: /* in2 */
68068 #ifdef SQLITE_OMIT_MERGE_SORT
68069 pOp->opcode = OP_IdxInsert;
68070 #endif
68071 case OP_IdxInsert: { /* in2 */
68072 #if 0 /* local variables moved into u.bq */
68073 VdbeCursor *pC;
68074 BtCursor *pCrsr;
68075 int nKey;
68076 const char *zKey;
68077 #endif /* local variables moved into u.bq */
68079 assert( pOp->p1>=0 && pOp->p1<p->nCursor );
68080 u.bq.pC = p->apCsr[pOp->p1];
68081 assert( u.bq.pC!=0 );
68082 assert( u.bq.pC->isSorter==(pOp->opcode==OP_SorterInsert) );
68083 pIn2 = &aMem[pOp->p2];
68084 assert( pIn2->flags & MEM_Blob );
68085 u.bq.pCrsr = u.bq.pC->pCursor;
68086 if( ALWAYS(u.bq.pCrsr!=0) ){
68087 assert( u.bq.pC->isTable==0 );
68088 rc = ExpandBlob(pIn2);
68089 if( rc==SQLITE_OK ){
68090 if( isSorter(u.bq.pC) ){
68091 rc = sqlite3VdbeSorterWrite(db, u.bq.pC, pIn2);
68092 }else{
68093 u.bq.nKey = pIn2->n;
68094 u.bq.zKey = pIn2->z;
68095 rc = sqlite3BtreeInsert(u.bq.pCrsr, u.bq.zKey, u.bq.nKey, "", 0, 0, pOp->p3,
68096 ((pOp->p5 & OPFLAG_USESEEKRESULT) ? u.bq.pC->seekResult : 0)
68098 assert( u.bq.pC->deferredMoveto==0 );
68099 u.bq.pC->cacheStatus = CACHE_STALE;
68103 break;
68106 /* Opcode: IdxDelete P1 P2 P3 * *
68108 ** The content of P3 registers starting at register P2 form
68109 ** an unpacked index key. This opcode removes that entry from the
68110 ** index opened by cursor P1.
68112 case OP_IdxDelete: {
68113 #if 0 /* local variables moved into u.br */
68114 VdbeCursor *pC;
68115 BtCursor *pCrsr;
68116 int res;
68117 UnpackedRecord r;
68118 #endif /* local variables moved into u.br */
68120 assert( pOp->p3>0 );
68121 assert( pOp->p2>0 && pOp->p2+pOp->p3<=p->nMem+1 );
68122 assert( pOp->p1>=0 && pOp->p1<p->nCursor );
68123 u.br.pC = p->apCsr[pOp->p1];
68124 assert( u.br.pC!=0 );
68125 u.br.pCrsr = u.br.pC->pCursor;
68126 if( ALWAYS(u.br.pCrsr!=0) ){
68127 u.br.r.pKeyInfo = u.br.pC->pKeyInfo;
68128 u.br.r.nField = (u16)pOp->p3;
68129 u.br.r.flags = 0;
68130 u.br.r.aMem = &aMem[pOp->p2];
68131 #ifdef SQLITE_DEBUG
68132 { int i; for(i=0; i<u.br.r.nField; i++) assert( memIsValid(&u.br.r.aMem[i]) ); }
68133 #endif
68134 rc = sqlite3BtreeMovetoUnpacked(u.br.pCrsr, &u.br.r, 0, 0, &u.br.res);
68135 if( rc==SQLITE_OK && u.br.res==0 ){
68136 rc = sqlite3BtreeDelete(u.br.pCrsr);
68138 assert( u.br.pC->deferredMoveto==0 );
68139 u.br.pC->cacheStatus = CACHE_STALE;
68141 break;
68144 /* Opcode: IdxRowid P1 P2 * * *
68146 ** Write into register P2 an integer which is the last entry in the record at
68147 ** the end of the index key pointed to by cursor P1. This integer should be
68148 ** the rowid of the table entry to which this index entry points.
68150 ** See also: Rowid, MakeRecord.
68152 case OP_IdxRowid: { /* out2-prerelease */
68153 #if 0 /* local variables moved into u.bs */
68154 BtCursor *pCrsr;
68155 VdbeCursor *pC;
68156 i64 rowid;
68157 #endif /* local variables moved into u.bs */
68159 assert( pOp->p1>=0 && pOp->p1<p->nCursor );
68160 u.bs.pC = p->apCsr[pOp->p1];
68161 assert( u.bs.pC!=0 );
68162 u.bs.pCrsr = u.bs.pC->pCursor;
68163 pOut->flags = MEM_Null;
68164 if( ALWAYS(u.bs.pCrsr!=0) ){
68165 rc = sqlite3VdbeCursorMoveto(u.bs.pC);
68166 if( NEVER(rc) ) goto abort_due_to_error;
68167 assert( u.bs.pC->deferredMoveto==0 );
68168 assert( u.bs.pC->isTable==0 );
68169 if( !u.bs.pC->nullRow ){
68170 rc = sqlite3VdbeIdxRowid(db, u.bs.pCrsr, &u.bs.rowid);
68171 if( rc!=SQLITE_OK ){
68172 goto abort_due_to_error;
68174 pOut->u.i = u.bs.rowid;
68175 pOut->flags = MEM_Int;
68178 break;
68181 /* Opcode: IdxGE P1 P2 P3 P4 P5
68183 ** The P4 register values beginning with P3 form an unpacked index
68184 ** key that omits the ROWID. Compare this key value against the index
68185 ** that P1 is currently pointing to, ignoring the ROWID on the P1 index.
68187 ** If the P1 index entry is greater than or equal to the key value
68188 ** then jump to P2. Otherwise fall through to the next instruction.
68190 ** If P5 is non-zero then the key value is increased by an epsilon
68191 ** prior to the comparison. This make the opcode work like IdxGT except
68192 ** that if the key from register P3 is a prefix of the key in the cursor,
68193 ** the result is false whereas it would be true with IdxGT.
68195 /* Opcode: IdxLT P1 P2 P3 P4 P5
68197 ** The P4 register values beginning with P3 form an unpacked index
68198 ** key that omits the ROWID. Compare this key value against the index
68199 ** that P1 is currently pointing to, ignoring the ROWID on the P1 index.
68201 ** If the P1 index entry is less than the key value then jump to P2.
68202 ** Otherwise fall through to the next instruction.
68204 ** If P5 is non-zero then the key value is increased by an epsilon prior
68205 ** to the comparison. This makes the opcode work like IdxLE.
68207 case OP_IdxLT: /* jump */
68208 case OP_IdxGE: { /* jump */
68209 #if 0 /* local variables moved into u.bt */
68210 VdbeCursor *pC;
68211 int res;
68212 UnpackedRecord r;
68213 #endif /* local variables moved into u.bt */
68215 assert( pOp->p1>=0 && pOp->p1<p->nCursor );
68216 u.bt.pC = p->apCsr[pOp->p1];
68217 assert( u.bt.pC!=0 );
68218 assert( u.bt.pC->isOrdered );
68219 if( ALWAYS(u.bt.pC->pCursor!=0) ){
68220 assert( u.bt.pC->deferredMoveto==0 );
68221 assert( pOp->p5==0 || pOp->p5==1 );
68222 assert( pOp->p4type==P4_INT32 );
68223 u.bt.r.pKeyInfo = u.bt.pC->pKeyInfo;
68224 u.bt.r.nField = (u16)pOp->p4.i;
68225 if( pOp->p5 ){
68226 u.bt.r.flags = UNPACKED_INCRKEY | UNPACKED_IGNORE_ROWID;
68227 }else{
68228 u.bt.r.flags = UNPACKED_IGNORE_ROWID;
68230 u.bt.r.aMem = &aMem[pOp->p3];
68231 #ifdef SQLITE_DEBUG
68232 { int i; for(i=0; i<u.bt.r.nField; i++) assert( memIsValid(&u.bt.r.aMem[i]) ); }
68233 #endif
68234 rc = sqlite3VdbeIdxKeyCompare(u.bt.pC, &u.bt.r, &u.bt.res);
68235 if( pOp->opcode==OP_IdxLT ){
68236 u.bt.res = -u.bt.res;
68237 }else{
68238 assert( pOp->opcode==OP_IdxGE );
68239 u.bt.res++;
68241 if( u.bt.res>0 ){
68242 pc = pOp->p2 - 1 ;
68245 break;
68248 /* Opcode: Destroy P1 P2 P3 * *
68250 ** Delete an entire database table or index whose root page in the database
68251 ** file is given by P1.
68253 ** The table being destroyed is in the main database file if P3==0. If
68254 ** P3==1 then the table to be clear is in the auxiliary database file
68255 ** that is used to store tables create using CREATE TEMPORARY TABLE.
68257 ** If AUTOVACUUM is enabled then it is possible that another root page
68258 ** might be moved into the newly deleted root page in order to keep all
68259 ** root pages contiguous at the beginning of the database. The former
68260 ** value of the root page that moved - its value before the move occurred -
68261 ** is stored in register P2. If no page
68262 ** movement was required (because the table being dropped was already
68263 ** the last one in the database) then a zero is stored in register P2.
68264 ** If AUTOVACUUM is disabled then a zero is stored in register P2.
68266 ** See also: Clear
68268 case OP_Destroy: { /* out2-prerelease */
68269 #if 0 /* local variables moved into u.bu */
68270 int iMoved;
68271 int iCnt;
68272 Vdbe *pVdbe;
68273 int iDb;
68274 #endif /* local variables moved into u.bu */
68275 #ifndef SQLITE_OMIT_VIRTUALTABLE
68276 u.bu.iCnt = 0;
68277 for(u.bu.pVdbe=db->pVdbe; u.bu.pVdbe; u.bu.pVdbe = u.bu.pVdbe->pNext){
68278 if( u.bu.pVdbe->magic==VDBE_MAGIC_RUN && u.bu.pVdbe->inVtabMethod<2 && u.bu.pVdbe->pc>=0 ){
68279 u.bu.iCnt++;
68282 #else
68283 u.bu.iCnt = db->activeVdbeCnt;
68284 #endif
68285 pOut->flags = MEM_Null;
68286 if( u.bu.iCnt>1 ){
68287 rc = SQLITE_LOCKED;
68288 p->errorAction = OE_Abort;
68289 }else{
68290 u.bu.iDb = pOp->p3;
68291 assert( u.bu.iCnt==1 );
68292 assert( (p->btreeMask & (((yDbMask)1)<<u.bu.iDb))!=0 );
68293 rc = sqlite3BtreeDropTable(db->aDb[u.bu.iDb].pBt, pOp->p1, &u.bu.iMoved);
68294 pOut->flags = MEM_Int;
68295 pOut->u.i = u.bu.iMoved;
68296 #ifndef SQLITE_OMIT_AUTOVACUUM
68297 if( rc==SQLITE_OK && u.bu.iMoved!=0 ){
68298 sqlite3RootPageMoved(db, u.bu.iDb, u.bu.iMoved, pOp->p1);
68299 /* All OP_Destroy operations occur on the same btree */
68300 assert( resetSchemaOnFault==0 || resetSchemaOnFault==u.bu.iDb+1 );
68301 resetSchemaOnFault = u.bu.iDb+1;
68303 #endif
68305 break;
68308 /* Opcode: Clear P1 P2 P3
68310 ** Delete all contents of the database table or index whose root page
68311 ** in the database file is given by P1. But, unlike Destroy, do not
68312 ** remove the table or index from the database file.
68314 ** The table being clear is in the main database file if P2==0. If
68315 ** P2==1 then the table to be clear is in the auxiliary database file
68316 ** that is used to store tables create using CREATE TEMPORARY TABLE.
68318 ** If the P3 value is non-zero, then the table referred to must be an
68319 ** intkey table (an SQL table, not an index). In this case the row change
68320 ** count is incremented by the number of rows in the table being cleared.
68321 ** If P3 is greater than zero, then the value stored in register P3 is
68322 ** also incremented by the number of rows in the table being cleared.
68324 ** See also: Destroy
68326 case OP_Clear: {
68327 #if 0 /* local variables moved into u.bv */
68328 int nChange;
68329 #endif /* local variables moved into u.bv */
68331 u.bv.nChange = 0;
68332 assert( (p->btreeMask & (((yDbMask)1)<<pOp->p2))!=0 );
68333 rc = sqlite3BtreeClearTable(
68334 db->aDb[pOp->p2].pBt, pOp->p1, (pOp->p3 ? &u.bv.nChange : 0)
68336 if( pOp->p3 ){
68337 p->nChange += u.bv.nChange;
68338 if( pOp->p3>0 ){
68339 assert( memIsValid(&aMem[pOp->p3]) );
68340 memAboutToChange(p, &aMem[pOp->p3]);
68341 aMem[pOp->p3].u.i += u.bv.nChange;
68344 break;
68347 /* Opcode: CreateTable P1 P2 * * *
68349 ** Allocate a new table in the main database file if P1==0 or in the
68350 ** auxiliary database file if P1==1 or in an attached database if
68351 ** P1>1. Write the root page number of the new table into
68352 ** register P2
68354 ** The difference between a table and an index is this: A table must
68355 ** have a 4-byte integer key and can have arbitrary data. An index
68356 ** has an arbitrary key but no data.
68358 ** See also: CreateIndex
68360 /* Opcode: CreateIndex P1 P2 * * *
68362 ** Allocate a new index in the main database file if P1==0 or in the
68363 ** auxiliary database file if P1==1 or in an attached database if
68364 ** P1>1. Write the root page number of the new table into
68365 ** register P2.
68367 ** See documentation on OP_CreateTable for additional information.
68369 case OP_CreateIndex: /* out2-prerelease */
68370 case OP_CreateTable: { /* out2-prerelease */
68371 #if 0 /* local variables moved into u.bw */
68372 int pgno;
68373 int flags;
68374 Db *pDb;
68375 #endif /* local variables moved into u.bw */
68377 u.bw.pgno = 0;
68378 assert( pOp->p1>=0 && pOp->p1<db->nDb );
68379 assert( (p->btreeMask & (((yDbMask)1)<<pOp->p1))!=0 );
68380 u.bw.pDb = &db->aDb[pOp->p1];
68381 assert( u.bw.pDb->pBt!=0 );
68382 if( pOp->opcode==OP_CreateTable ){
68383 /* u.bw.flags = BTREE_INTKEY; */
68384 u.bw.flags = BTREE_INTKEY;
68385 }else{
68386 u.bw.flags = BTREE_BLOBKEY;
68388 rc = sqlite3BtreeCreateTable(u.bw.pDb->pBt, &u.bw.pgno, u.bw.flags);
68389 pOut->u.i = u.bw.pgno;
68390 break;
68393 /* Opcode: ParseSchema P1 * * P4 *
68395 ** Read and parse all entries from the SQLITE_MASTER table of database P1
68396 ** that match the WHERE clause P4.
68398 ** This opcode invokes the parser to create a new virtual machine,
68399 ** then runs the new virtual machine. It is thus a re-entrant opcode.
68401 case OP_ParseSchema: {
68402 #if 0 /* local variables moved into u.bx */
68403 int iDb;
68404 const char *zMaster;
68405 char *zSql;
68406 InitData initData;
68407 #endif /* local variables moved into u.bx */
68409 /* Any prepared statement that invokes this opcode will hold mutexes
68410 ** on every btree. This is a prerequisite for invoking
68411 ** sqlite3InitCallback().
68413 #ifdef SQLITE_DEBUG
68414 for(u.bx.iDb=0; u.bx.iDb<db->nDb; u.bx.iDb++){
68415 assert( u.bx.iDb==1 || sqlite3BtreeHoldsMutex(db->aDb[u.bx.iDb].pBt) );
68417 #endif
68419 u.bx.iDb = pOp->p1;
68420 assert( u.bx.iDb>=0 && u.bx.iDb<db->nDb );
68421 assert( DbHasProperty(db, u.bx.iDb, DB_SchemaLoaded) );
68422 /* Used to be a conditional */ {
68423 u.bx.zMaster = SCHEMA_TABLE(u.bx.iDb);
68424 u.bx.initData.db = db;
68425 u.bx.initData.iDb = pOp->p1;
68426 u.bx.initData.pzErrMsg = &p->zErrMsg;
68427 u.bx.zSql = sqlite3MPrintf(db,
68428 "SELECT name, rootpage, sql FROM '%q'.%s WHERE %s ORDER BY rowid",
68429 db->aDb[u.bx.iDb].zName, u.bx.zMaster, pOp->p4.z);
68430 if( u.bx.zSql==0 ){
68431 rc = SQLITE_NOMEM;
68432 }else{
68433 assert( db->init.busy==0 );
68434 db->init.busy = 1;
68435 u.bx.initData.rc = SQLITE_OK;
68436 assert( !db->mallocFailed );
68437 rc = sqlite3_exec(db, u.bx.zSql, sqlite3InitCallback, &u.bx.initData, 0);
68438 if( rc==SQLITE_OK ) rc = u.bx.initData.rc;
68439 sqlite3DbFree(db, u.bx.zSql);
68440 db->init.busy = 0;
68443 if( rc==SQLITE_NOMEM ){
68444 goto no_mem;
68446 break;
68449 #if !defined(SQLITE_OMIT_ANALYZE)
68450 /* Opcode: LoadAnalysis P1 * * * *
68452 ** Read the sqlite_stat1 table for database P1 and load the content
68453 ** of that table into the internal index hash table. This will cause
68454 ** the analysis to be used when preparing all subsequent queries.
68456 case OP_LoadAnalysis: {
68457 assert( pOp->p1>=0 && pOp->p1<db->nDb );
68458 rc = sqlite3AnalysisLoad(db, pOp->p1);
68459 break;
68461 #endif /* !defined(SQLITE_OMIT_ANALYZE) */
68463 /* Opcode: DropTable P1 * * P4 *
68465 ** Remove the internal (in-memory) data structures that describe
68466 ** the table named P4 in database P1. This is called after a table
68467 ** is dropped in order to keep the internal representation of the
68468 ** schema consistent with what is on disk.
68470 case OP_DropTable: {
68471 sqlite3UnlinkAndDeleteTable(db, pOp->p1, pOp->p4.z);
68472 break;
68475 /* Opcode: DropIndex P1 * * P4 *
68477 ** Remove the internal (in-memory) data structures that describe
68478 ** the index named P4 in database P1. This is called after an index
68479 ** is dropped in order to keep the internal representation of the
68480 ** schema consistent with what is on disk.
68482 case OP_DropIndex: {
68483 sqlite3UnlinkAndDeleteIndex(db, pOp->p1, pOp->p4.z);
68484 break;
68487 /* Opcode: DropTrigger P1 * * P4 *
68489 ** Remove the internal (in-memory) data structures that describe
68490 ** the trigger named P4 in database P1. This is called after a trigger
68491 ** is dropped in order to keep the internal representation of the
68492 ** schema consistent with what is on disk.
68494 case OP_DropTrigger: {
68495 sqlite3UnlinkAndDeleteTrigger(db, pOp->p1, pOp->p4.z);
68496 break;
68500 #ifndef SQLITE_OMIT_INTEGRITY_CHECK
68501 /* Opcode: IntegrityCk P1 P2 P3 * P5
68503 ** Do an analysis of the currently open database. Store in
68504 ** register P1 the text of an error message describing any problems.
68505 ** If no problems are found, store a NULL in register P1.
68507 ** The register P3 contains the maximum number of allowed errors.
68508 ** At most reg(P3) errors will be reported.
68509 ** In other words, the analysis stops as soon as reg(P1) errors are
68510 ** seen. Reg(P1) is updated with the number of errors remaining.
68512 ** The root page numbers of all tables in the database are integer
68513 ** stored in reg(P1), reg(P1+1), reg(P1+2), .... There are P2 tables
68514 ** total.
68516 ** If P5 is not zero, the check is done on the auxiliary database
68517 ** file, not the main database file.
68519 ** This opcode is used to implement the integrity_check pragma.
68521 case OP_IntegrityCk: {
68522 #if 0 /* local variables moved into u.by */
68523 int nRoot; /* Number of tables to check. (Number of root pages.) */
68524 int *aRoot; /* Array of rootpage numbers for tables to be checked */
68525 int j; /* Loop counter */
68526 int nErr; /* Number of errors reported */
68527 char *z; /* Text of the error report */
68528 Mem *pnErr; /* Register keeping track of errors remaining */
68529 #endif /* local variables moved into u.by */
68531 u.by.nRoot = pOp->p2;
68532 assert( u.by.nRoot>0 );
68533 u.by.aRoot = sqlite3DbMallocRaw(db, sizeof(int)*(u.by.nRoot+1) );
68534 if( u.by.aRoot==0 ) goto no_mem;
68535 assert( pOp->p3>0 && pOp->p3<=p->nMem );
68536 u.by.pnErr = &aMem[pOp->p3];
68537 assert( (u.by.pnErr->flags & MEM_Int)!=0 );
68538 assert( (u.by.pnErr->flags & (MEM_Str|MEM_Blob))==0 );
68539 pIn1 = &aMem[pOp->p1];
68540 for(u.by.j=0; u.by.j<u.by.nRoot; u.by.j++){
68541 u.by.aRoot[u.by.j] = (int)sqlite3VdbeIntValue(&pIn1[u.by.j]);
68543 u.by.aRoot[u.by.j] = 0;
68544 assert( pOp->p5<db->nDb );
68545 assert( (p->btreeMask & (((yDbMask)1)<<pOp->p5))!=0 );
68546 u.by.z = sqlite3BtreeIntegrityCheck(db->aDb[pOp->p5].pBt, u.by.aRoot, u.by.nRoot,
68547 (int)u.by.pnErr->u.i, &u.by.nErr);
68548 sqlite3DbFree(db, u.by.aRoot);
68549 u.by.pnErr->u.i -= u.by.nErr;
68550 sqlite3VdbeMemSetNull(pIn1);
68551 if( u.by.nErr==0 ){
68552 assert( u.by.z==0 );
68553 }else if( u.by.z==0 ){
68554 goto no_mem;
68555 }else{
68556 sqlite3VdbeMemSetStr(pIn1, u.by.z, -1, SQLITE_UTF8, sqlite3_free);
68558 UPDATE_MAX_BLOBSIZE(pIn1);
68559 sqlite3VdbeChangeEncoding(pIn1, encoding);
68560 break;
68562 #endif /* SQLITE_OMIT_INTEGRITY_CHECK */
68564 /* Opcode: RowSetAdd P1 P2 * * *
68566 ** Insert the integer value held by register P2 into a boolean index
68567 ** held in register P1.
68569 ** An assertion fails if P2 is not an integer.
68571 case OP_RowSetAdd: { /* in1, in2 */
68572 pIn1 = &aMem[pOp->p1];
68573 pIn2 = &aMem[pOp->p2];
68574 assert( (pIn2->flags & MEM_Int)!=0 );
68575 if( (pIn1->flags & MEM_RowSet)==0 ){
68576 sqlite3VdbeMemSetRowSet(pIn1);
68577 if( (pIn1->flags & MEM_RowSet)==0 ) goto no_mem;
68579 sqlite3RowSetInsert(pIn1->u.pRowSet, pIn2->u.i);
68580 break;
68583 /* Opcode: RowSetRead P1 P2 P3 * *
68585 ** Extract the smallest value from boolean index P1 and put that value into
68586 ** register P3. Or, if boolean index P1 is initially empty, leave P3
68587 ** unchanged and jump to instruction P2.
68589 case OP_RowSetRead: { /* jump, in1, out3 */
68590 #if 0 /* local variables moved into u.bz */
68591 i64 val;
68592 #endif /* local variables moved into u.bz */
68593 CHECK_FOR_INTERRUPT;
68594 pIn1 = &aMem[pOp->p1];
68595 if( (pIn1->flags & MEM_RowSet)==0
68596 || sqlite3RowSetNext(pIn1->u.pRowSet, &u.bz.val)==0
68598 /* The boolean index is empty */
68599 sqlite3VdbeMemSetNull(pIn1);
68600 pc = pOp->p2 - 1;
68601 }else{
68602 /* A value was pulled from the index */
68603 sqlite3VdbeMemSetInt64(&aMem[pOp->p3], u.bz.val);
68605 break;
68608 /* Opcode: RowSetTest P1 P2 P3 P4
68610 ** Register P3 is assumed to hold a 64-bit integer value. If register P1
68611 ** contains a RowSet object and that RowSet object contains
68612 ** the value held in P3, jump to register P2. Otherwise, insert the
68613 ** integer in P3 into the RowSet and continue on to the
68614 ** next opcode.
68616 ** The RowSet object is optimized for the case where successive sets
68617 ** of integers, where each set contains no duplicates. Each set
68618 ** of values is identified by a unique P4 value. The first set
68619 ** must have P4==0, the final set P4=-1. P4 must be either -1 or
68620 ** non-negative. For non-negative values of P4 only the lower 4
68621 ** bits are significant.
68623 ** This allows optimizations: (a) when P4==0 there is no need to test
68624 ** the rowset object for P3, as it is guaranteed not to contain it,
68625 ** (b) when P4==-1 there is no need to insert the value, as it will
68626 ** never be tested for, and (c) when a value that is part of set X is
68627 ** inserted, there is no need to search to see if the same value was
68628 ** previously inserted as part of set X (only if it was previously
68629 ** inserted as part of some other set).
68631 case OP_RowSetTest: { /* jump, in1, in3 */
68632 #if 0 /* local variables moved into u.ca */
68633 int iSet;
68634 int exists;
68635 #endif /* local variables moved into u.ca */
68637 pIn1 = &aMem[pOp->p1];
68638 pIn3 = &aMem[pOp->p3];
68639 u.ca.iSet = pOp->p4.i;
68640 assert( pIn3->flags&MEM_Int );
68642 /* If there is anything other than a rowset object in memory cell P1,
68643 ** delete it now and initialize P1 with an empty rowset
68645 if( (pIn1->flags & MEM_RowSet)==0 ){
68646 sqlite3VdbeMemSetRowSet(pIn1);
68647 if( (pIn1->flags & MEM_RowSet)==0 ) goto no_mem;
68650 assert( pOp->p4type==P4_INT32 );
68651 assert( u.ca.iSet==-1 || u.ca.iSet>=0 );
68652 if( u.ca.iSet ){
68653 u.ca.exists = sqlite3RowSetTest(pIn1->u.pRowSet,
68654 (u8)(u.ca.iSet>=0 ? u.ca.iSet & 0xf : 0xff),
68655 pIn3->u.i);
68656 if( u.ca.exists ){
68657 pc = pOp->p2 - 1;
68658 break;
68661 if( u.ca.iSet>=0 ){
68662 sqlite3RowSetInsert(pIn1->u.pRowSet, pIn3->u.i);
68664 break;
68668 #ifndef SQLITE_OMIT_TRIGGER
68670 /* Opcode: Program P1 P2 P3 P4 *
68672 ** Execute the trigger program passed as P4 (type P4_SUBPROGRAM).
68674 ** P1 contains the address of the memory cell that contains the first memory
68675 ** cell in an array of values used as arguments to the sub-program. P2
68676 ** contains the address to jump to if the sub-program throws an IGNORE
68677 ** exception using the RAISE() function. Register P3 contains the address
68678 ** of a memory cell in this (the parent) VM that is used to allocate the
68679 ** memory required by the sub-vdbe at runtime.
68681 ** P4 is a pointer to the VM containing the trigger program.
68683 case OP_Program: { /* jump */
68684 #if 0 /* local variables moved into u.cb */
68685 int nMem; /* Number of memory registers for sub-program */
68686 int nByte; /* Bytes of runtime space required for sub-program */
68687 Mem *pRt; /* Register to allocate runtime space */
68688 Mem *pMem; /* Used to iterate through memory cells */
68689 Mem *pEnd; /* Last memory cell in new array */
68690 VdbeFrame *pFrame; /* New vdbe frame to execute in */
68691 SubProgram *pProgram; /* Sub-program to execute */
68692 void *t; /* Token identifying trigger */
68693 #endif /* local variables moved into u.cb */
68695 u.cb.pProgram = pOp->p4.pProgram;
68696 u.cb.pRt = &aMem[pOp->p3];
68697 assert( memIsValid(u.cb.pRt) );
68698 assert( u.cb.pProgram->nOp>0 );
68700 /* If the p5 flag is clear, then recursive invocation of triggers is
68701 ** disabled for backwards compatibility (p5 is set if this sub-program
68702 ** is really a trigger, not a foreign key action, and the flag set
68703 ** and cleared by the "PRAGMA recursive_triggers" command is clear).
68705 ** It is recursive invocation of triggers, at the SQL level, that is
68706 ** disabled. In some cases a single trigger may generate more than one
68707 ** SubProgram (if the trigger may be executed with more than one different
68708 ** ON CONFLICT algorithm). SubProgram structures associated with a
68709 ** single trigger all have the same value for the SubProgram.token
68710 ** variable. */
68711 if( pOp->p5 ){
68712 u.cb.t = u.cb.pProgram->token;
68713 for(u.cb.pFrame=p->pFrame; u.cb.pFrame && u.cb.pFrame->token!=u.cb.t; u.cb.pFrame=u.cb.pFrame->pParent);
68714 if( u.cb.pFrame ) break;
68717 if( p->nFrame>=db->aLimit[SQLITE_LIMIT_TRIGGER_DEPTH] ){
68718 rc = SQLITE_ERROR;
68719 sqlite3SetString(&p->zErrMsg, db, "too many levels of trigger recursion");
68720 break;
68723 /* Register u.cb.pRt is used to store the memory required to save the state
68724 ** of the current program, and the memory required at runtime to execute
68725 ** the trigger program. If this trigger has been fired before, then u.cb.pRt
68726 ** is already allocated. Otherwise, it must be initialized. */
68727 if( (u.cb.pRt->flags&MEM_Frame)==0 ){
68728 /* SubProgram.nMem is set to the number of memory cells used by the
68729 ** program stored in SubProgram.aOp. As well as these, one memory
68730 ** cell is required for each cursor used by the program. Set local
68731 ** variable u.cb.nMem (and later, VdbeFrame.nChildMem) to this value.
68733 u.cb.nMem = u.cb.pProgram->nMem + u.cb.pProgram->nCsr;
68734 u.cb.nByte = ROUND8(sizeof(VdbeFrame))
68735 + u.cb.nMem * sizeof(Mem)
68736 + u.cb.pProgram->nCsr * sizeof(VdbeCursor *);
68737 u.cb.pFrame = sqlite3DbMallocZero(db, u.cb.nByte);
68738 if( !u.cb.pFrame ){
68739 goto no_mem;
68741 sqlite3VdbeMemRelease(u.cb.pRt);
68742 u.cb.pRt->flags = MEM_Frame;
68743 u.cb.pRt->u.pFrame = u.cb.pFrame;
68745 u.cb.pFrame->v = p;
68746 u.cb.pFrame->nChildMem = u.cb.nMem;
68747 u.cb.pFrame->nChildCsr = u.cb.pProgram->nCsr;
68748 u.cb.pFrame->pc = pc;
68749 u.cb.pFrame->aMem = p->aMem;
68750 u.cb.pFrame->nMem = p->nMem;
68751 u.cb.pFrame->apCsr = p->apCsr;
68752 u.cb.pFrame->nCursor = p->nCursor;
68753 u.cb.pFrame->aOp = p->aOp;
68754 u.cb.pFrame->nOp = p->nOp;
68755 u.cb.pFrame->token = u.cb.pProgram->token;
68757 u.cb.pEnd = &VdbeFrameMem(u.cb.pFrame)[u.cb.pFrame->nChildMem];
68758 for(u.cb.pMem=VdbeFrameMem(u.cb.pFrame); u.cb.pMem!=u.cb.pEnd; u.cb.pMem++){
68759 u.cb.pMem->flags = MEM_Null;
68760 u.cb.pMem->db = db;
68762 }else{
68763 u.cb.pFrame = u.cb.pRt->u.pFrame;
68764 assert( u.cb.pProgram->nMem+u.cb.pProgram->nCsr==u.cb.pFrame->nChildMem );
68765 assert( u.cb.pProgram->nCsr==u.cb.pFrame->nChildCsr );
68766 assert( pc==u.cb.pFrame->pc );
68769 p->nFrame++;
68770 u.cb.pFrame->pParent = p->pFrame;
68771 u.cb.pFrame->lastRowid = lastRowid;
68772 u.cb.pFrame->nChange = p->nChange;
68773 p->nChange = 0;
68774 p->pFrame = u.cb.pFrame;
68775 p->aMem = aMem = &VdbeFrameMem(u.cb.pFrame)[-1];
68776 p->nMem = u.cb.pFrame->nChildMem;
68777 p->nCursor = (u16)u.cb.pFrame->nChildCsr;
68778 p->apCsr = (VdbeCursor **)&aMem[p->nMem+1];
68779 p->aOp = aOp = u.cb.pProgram->aOp;
68780 p->nOp = u.cb.pProgram->nOp;
68781 pc = -1;
68783 break;
68786 /* Opcode: Param P1 P2 * * *
68788 ** This opcode is only ever present in sub-programs called via the
68789 ** OP_Program instruction. Copy a value currently stored in a memory
68790 ** cell of the calling (parent) frame to cell P2 in the current frames
68791 ** address space. This is used by trigger programs to access the new.*
68792 ** and old.* values.
68794 ** The address of the cell in the parent frame is determined by adding
68795 ** the value of the P1 argument to the value of the P1 argument to the
68796 ** calling OP_Program instruction.
68798 case OP_Param: { /* out2-prerelease */
68799 #if 0 /* local variables moved into u.cc */
68800 VdbeFrame *pFrame;
68801 Mem *pIn;
68802 #endif /* local variables moved into u.cc */
68803 u.cc.pFrame = p->pFrame;
68804 u.cc.pIn = &u.cc.pFrame->aMem[pOp->p1 + u.cc.pFrame->aOp[u.cc.pFrame->pc].p1];
68805 sqlite3VdbeMemShallowCopy(pOut, u.cc.pIn, MEM_Ephem);
68806 break;
68809 #endif /* #ifndef SQLITE_OMIT_TRIGGER */
68811 #ifndef SQLITE_OMIT_FOREIGN_KEY
68812 /* Opcode: FkCounter P1 P2 * * *
68814 ** Increment a "constraint counter" by P2 (P2 may be negative or positive).
68815 ** If P1 is non-zero, the database constraint counter is incremented
68816 ** (deferred foreign key constraints). Otherwise, if P1 is zero, the
68817 ** statement counter is incremented (immediate foreign key constraints).
68819 case OP_FkCounter: {
68820 if( pOp->p1 ){
68821 db->nDeferredCons += pOp->p2;
68822 }else{
68823 p->nFkConstraint += pOp->p2;
68825 break;
68828 /* Opcode: FkIfZero P1 P2 * * *
68830 ** This opcode tests if a foreign key constraint-counter is currently zero.
68831 ** If so, jump to instruction P2. Otherwise, fall through to the next
68832 ** instruction.
68834 ** If P1 is non-zero, then the jump is taken if the database constraint-counter
68835 ** is zero (the one that counts deferred constraint violations). If P1 is
68836 ** zero, the jump is taken if the statement constraint-counter is zero
68837 ** (immediate foreign key constraint violations).
68839 case OP_FkIfZero: { /* jump */
68840 if( pOp->p1 ){
68841 if( db->nDeferredCons==0 ) pc = pOp->p2-1;
68842 }else{
68843 if( p->nFkConstraint==0 ) pc = pOp->p2-1;
68845 break;
68847 #endif /* #ifndef SQLITE_OMIT_FOREIGN_KEY */
68849 #ifndef SQLITE_OMIT_AUTOINCREMENT
68850 /* Opcode: MemMax P1 P2 * * *
68852 ** P1 is a register in the root frame of this VM (the root frame is
68853 ** different from the current frame if this instruction is being executed
68854 ** within a sub-program). Set the value of register P1 to the maximum of
68855 ** its current value and the value in register P2.
68857 ** This instruction throws an error if the memory cell is not initially
68858 ** an integer.
68860 case OP_MemMax: { /* in2 */
68861 #if 0 /* local variables moved into u.cd */
68862 Mem *pIn1;
68863 VdbeFrame *pFrame;
68864 #endif /* local variables moved into u.cd */
68865 if( p->pFrame ){
68866 for(u.cd.pFrame=p->pFrame; u.cd.pFrame->pParent; u.cd.pFrame=u.cd.pFrame->pParent);
68867 u.cd.pIn1 = &u.cd.pFrame->aMem[pOp->p1];
68868 }else{
68869 u.cd.pIn1 = &aMem[pOp->p1];
68871 assert( memIsValid(u.cd.pIn1) );
68872 sqlite3VdbeMemIntegerify(u.cd.pIn1);
68873 pIn2 = &aMem[pOp->p2];
68874 sqlite3VdbeMemIntegerify(pIn2);
68875 if( u.cd.pIn1->u.i<pIn2->u.i){
68876 u.cd.pIn1->u.i = pIn2->u.i;
68878 break;
68880 #endif /* SQLITE_OMIT_AUTOINCREMENT */
68882 /* Opcode: IfPos P1 P2 * * *
68884 ** If the value of register P1 is 1 or greater, jump to P2.
68886 ** It is illegal to use this instruction on a register that does
68887 ** not contain an integer. An assertion fault will result if you try.
68889 case OP_IfPos: { /* jump, in1 */
68890 pIn1 = &aMem[pOp->p1];
68891 assert( pIn1->flags&MEM_Int );
68892 if( pIn1->u.i>0 ){
68893 pc = pOp->p2 - 1;
68895 break;
68898 /* Opcode: IfNeg P1 P2 * * *
68900 ** If the value of register P1 is less than zero, jump to P2.
68902 ** It is illegal to use this instruction on a register that does
68903 ** not contain an integer. An assertion fault will result if you try.
68905 case OP_IfNeg: { /* jump, in1 */
68906 pIn1 = &aMem[pOp->p1];
68907 assert( pIn1->flags&MEM_Int );
68908 if( pIn1->u.i<0 ){
68909 pc = pOp->p2 - 1;
68911 break;
68914 /* Opcode: IfZero P1 P2 P3 * *
68916 ** The register P1 must contain an integer. Add literal P3 to the
68917 ** value in register P1. If the result is exactly 0, jump to P2.
68919 ** It is illegal to use this instruction on a register that does
68920 ** not contain an integer. An assertion fault will result if you try.
68922 case OP_IfZero: { /* jump, in1 */
68923 pIn1 = &aMem[pOp->p1];
68924 assert( pIn1->flags&MEM_Int );
68925 pIn1->u.i += pOp->p3;
68926 if( pIn1->u.i==0 ){
68927 pc = pOp->p2 - 1;
68929 break;
68932 /* Opcode: AggStep * P2 P3 P4 P5
68934 ** Execute the step function for an aggregate. The
68935 ** function has P5 arguments. P4 is a pointer to the FuncDef
68936 ** structure that specifies the function. Use register
68937 ** P3 as the accumulator.
68939 ** The P5 arguments are taken from register P2 and its
68940 ** successors.
68942 case OP_AggStep: {
68943 #if 0 /* local variables moved into u.ce */
68944 int n;
68945 int i;
68946 Mem *pMem;
68947 Mem *pRec;
68948 sqlite3_context ctx;
68949 sqlite3_value **apVal;
68950 #endif /* local variables moved into u.ce */
68952 u.ce.n = pOp->p5;
68953 assert( u.ce.n>=0 );
68954 u.ce.pRec = &aMem[pOp->p2];
68955 u.ce.apVal = p->apArg;
68956 assert( u.ce.apVal || u.ce.n==0 );
68957 for(u.ce.i=0; u.ce.i<u.ce.n; u.ce.i++, u.ce.pRec++){
68958 assert( memIsValid(u.ce.pRec) );
68959 u.ce.apVal[u.ce.i] = u.ce.pRec;
68960 memAboutToChange(p, u.ce.pRec);
68961 sqlite3VdbeMemStoreType(u.ce.pRec);
68963 u.ce.ctx.pFunc = pOp->p4.pFunc;
68964 assert( pOp->p3>0 && pOp->p3<=p->nMem );
68965 u.ce.ctx.pMem = u.ce.pMem = &aMem[pOp->p3];
68966 u.ce.pMem->n++;
68967 u.ce.ctx.s.flags = MEM_Null;
68968 u.ce.ctx.s.z = 0;
68969 u.ce.ctx.s.zMalloc = 0;
68970 u.ce.ctx.s.xDel = 0;
68971 u.ce.ctx.s.db = db;
68972 u.ce.ctx.isError = 0;
68973 u.ce.ctx.pColl = 0;
68974 if( u.ce.ctx.pFunc->flags & SQLITE_FUNC_NEEDCOLL ){
68975 assert( pOp>p->aOp );
68976 assert( pOp[-1].p4type==P4_COLLSEQ );
68977 assert( pOp[-1].opcode==OP_CollSeq );
68978 u.ce.ctx.pColl = pOp[-1].p4.pColl;
68980 (u.ce.ctx.pFunc->xStep)(&u.ce.ctx, u.ce.n, u.ce.apVal); /* IMP: R-24505-23230 */
68981 if( u.ce.ctx.isError ){
68982 sqlite3SetString(&p->zErrMsg, db, "%s", sqlite3_value_text(&u.ce.ctx.s));
68983 rc = u.ce.ctx.isError;
68986 sqlite3VdbeMemRelease(&u.ce.ctx.s);
68988 break;
68991 /* Opcode: AggFinal P1 P2 * P4 *
68993 ** Execute the finalizer function for an aggregate. P1 is
68994 ** the memory location that is the accumulator for the aggregate.
68996 ** P2 is the number of arguments that the step function takes and
68997 ** P4 is a pointer to the FuncDef for this function. The P2
68998 ** argument is not used by this opcode. It is only there to disambiguate
68999 ** functions that can take varying numbers of arguments. The
69000 ** P4 argument is only needed for the degenerate case where
69001 ** the step function was not previously called.
69003 case OP_AggFinal: {
69004 #if 0 /* local variables moved into u.cf */
69005 Mem *pMem;
69006 #endif /* local variables moved into u.cf */
69007 assert( pOp->p1>0 && pOp->p1<=p->nMem );
69008 u.cf.pMem = &aMem[pOp->p1];
69009 assert( (u.cf.pMem->flags & ~(MEM_Null|MEM_Agg))==0 );
69010 rc = sqlite3VdbeMemFinalize(u.cf.pMem, pOp->p4.pFunc);
69011 if( rc ){
69012 sqlite3SetString(&p->zErrMsg, db, "%s", sqlite3_value_text(u.cf.pMem));
69014 sqlite3VdbeChangeEncoding(u.cf.pMem, encoding);
69015 UPDATE_MAX_BLOBSIZE(u.cf.pMem);
69016 if( sqlite3VdbeMemTooBig(u.cf.pMem) ){
69017 goto too_big;
69019 break;
69022 #ifndef SQLITE_OMIT_WAL
69023 /* Opcode: Checkpoint P1 P2 P3 * *
69025 ** Checkpoint database P1. This is a no-op if P1 is not currently in
69026 ** WAL mode. Parameter P2 is one of SQLITE_CHECKPOINT_PASSIVE, FULL
69027 ** or RESTART. Write 1 or 0 into mem[P3] if the checkpoint returns
69028 ** SQLITE_BUSY or not, respectively. Write the number of pages in the
69029 ** WAL after the checkpoint into mem[P3+1] and the number of pages
69030 ** in the WAL that have been checkpointed after the checkpoint
69031 ** completes into mem[P3+2]. However on an error, mem[P3+1] and
69032 ** mem[P3+2] are initialized to -1.
69034 case OP_Checkpoint: {
69035 #if 0 /* local variables moved into u.cg */
69036 int i; /* Loop counter */
69037 int aRes[3]; /* Results */
69038 Mem *pMem; /* Write results here */
69039 #endif /* local variables moved into u.cg */
69041 u.cg.aRes[0] = 0;
69042 u.cg.aRes[1] = u.cg.aRes[2] = -1;
69043 assert( pOp->p2==SQLITE_CHECKPOINT_PASSIVE
69044 || pOp->p2==SQLITE_CHECKPOINT_FULL
69045 || pOp->p2==SQLITE_CHECKPOINT_RESTART
69047 rc = sqlite3Checkpoint(db, pOp->p1, pOp->p2, &u.cg.aRes[1], &u.cg.aRes[2]);
69048 if( rc==SQLITE_BUSY ){
69049 rc = SQLITE_OK;
69050 u.cg.aRes[0] = 1;
69052 for(u.cg.i=0, u.cg.pMem = &aMem[pOp->p3]; u.cg.i<3; u.cg.i++, u.cg.pMem++){
69053 sqlite3VdbeMemSetInt64(u.cg.pMem, (i64)u.cg.aRes[u.cg.i]);
69055 break;
69057 #endif
69059 #ifndef SQLITE_OMIT_PRAGMA
69060 /* Opcode: JournalMode P1 P2 P3 * P5
69062 ** Change the journal mode of database P1 to P3. P3 must be one of the
69063 ** PAGER_JOURNALMODE_XXX values. If changing between the various rollback
69064 ** modes (delete, truncate, persist, off and memory), this is a simple
69065 ** operation. No IO is required.
69067 ** If changing into or out of WAL mode the procedure is more complicated.
69069 ** Write a string containing the final journal-mode to register P2.
69071 case OP_JournalMode: { /* out2-prerelease */
69072 #if 0 /* local variables moved into u.ch */
69073 Btree *pBt; /* Btree to change journal mode of */
69074 Pager *pPager; /* Pager associated with pBt */
69075 int eNew; /* New journal mode */
69076 int eOld; /* The old journal mode */
69077 const char *zFilename; /* Name of database file for pPager */
69078 #endif /* local variables moved into u.ch */
69080 u.ch.eNew = pOp->p3;
69081 assert( u.ch.eNew==PAGER_JOURNALMODE_DELETE
69082 || u.ch.eNew==PAGER_JOURNALMODE_TRUNCATE
69083 || u.ch.eNew==PAGER_JOURNALMODE_PERSIST
69084 || u.ch.eNew==PAGER_JOURNALMODE_OFF
69085 || u.ch.eNew==PAGER_JOURNALMODE_MEMORY
69086 || u.ch.eNew==PAGER_JOURNALMODE_WAL
69087 || u.ch.eNew==PAGER_JOURNALMODE_QUERY
69089 assert( pOp->p1>=0 && pOp->p1<db->nDb );
69091 u.ch.pBt = db->aDb[pOp->p1].pBt;
69092 u.ch.pPager = sqlite3BtreePager(u.ch.pBt);
69093 u.ch.eOld = sqlite3PagerGetJournalMode(u.ch.pPager);
69094 if( u.ch.eNew==PAGER_JOURNALMODE_QUERY ) u.ch.eNew = u.ch.eOld;
69095 if( !sqlite3PagerOkToChangeJournalMode(u.ch.pPager) ) u.ch.eNew = u.ch.eOld;
69097 #ifndef SQLITE_OMIT_WAL
69098 u.ch.zFilename = sqlite3PagerFilename(u.ch.pPager);
69100 /* Do not allow a transition to journal_mode=WAL for a database
69101 ** in temporary storage or if the VFS does not support shared memory
69103 if( u.ch.eNew==PAGER_JOURNALMODE_WAL
69104 && (u.ch.zFilename[0]==0 /* Temp file */
69105 || !sqlite3PagerWalSupported(u.ch.pPager)) /* No shared-memory support */
69107 u.ch.eNew = u.ch.eOld;
69110 if( (u.ch.eNew!=u.ch.eOld)
69111 && (u.ch.eOld==PAGER_JOURNALMODE_WAL || u.ch.eNew==PAGER_JOURNALMODE_WAL)
69113 if( !db->autoCommit || db->activeVdbeCnt>1 ){
69114 rc = SQLITE_ERROR;
69115 sqlite3SetString(&p->zErrMsg, db,
69116 "cannot change %s wal mode from within a transaction",
69117 (u.ch.eNew==PAGER_JOURNALMODE_WAL ? "into" : "out of")
69119 break;
69120 }else{
69122 if( u.ch.eOld==PAGER_JOURNALMODE_WAL ){
69123 /* If leaving WAL mode, close the log file. If successful, the call
69124 ** to PagerCloseWal() checkpoints and deletes the write-ahead-log
69125 ** file. An EXCLUSIVE lock may still be held on the database file
69126 ** after a successful return.
69128 rc = sqlite3PagerCloseWal(u.ch.pPager);
69129 if( rc==SQLITE_OK ){
69130 sqlite3PagerSetJournalMode(u.ch.pPager, u.ch.eNew);
69132 }else if( u.ch.eOld==PAGER_JOURNALMODE_MEMORY ){
69133 /* Cannot transition directly from MEMORY to WAL. Use mode OFF
69134 ** as an intermediate */
69135 sqlite3PagerSetJournalMode(u.ch.pPager, PAGER_JOURNALMODE_OFF);
69138 /* Open a transaction on the database file. Regardless of the journal
69139 ** mode, this transaction always uses a rollback journal.
69141 assert( sqlite3BtreeIsInTrans(u.ch.pBt)==0 );
69142 if( rc==SQLITE_OK ){
69143 rc = sqlite3BtreeSetVersion(u.ch.pBt, (u.ch.eNew==PAGER_JOURNALMODE_WAL ? 2 : 1));
69147 #endif /* ifndef SQLITE_OMIT_WAL */
69149 if( rc ){
69150 u.ch.eNew = u.ch.eOld;
69152 u.ch.eNew = sqlite3PagerSetJournalMode(u.ch.pPager, u.ch.eNew);
69154 pOut = &aMem[pOp->p2];
69155 pOut->flags = MEM_Str|MEM_Static|MEM_Term;
69156 pOut->z = (char *)sqlite3JournalModename(u.ch.eNew);
69157 pOut->n = sqlite3Strlen30(pOut->z);
69158 pOut->enc = SQLITE_UTF8;
69159 sqlite3VdbeChangeEncoding(pOut, encoding);
69160 break;
69162 #endif /* SQLITE_OMIT_PRAGMA */
69164 #if !defined(SQLITE_OMIT_VACUUM) && !defined(SQLITE_OMIT_ATTACH)
69165 /* Opcode: Vacuum * * * * *
69167 ** Vacuum the entire database. This opcode will cause other virtual
69168 ** machines to be created and run. It may not be called from within
69169 ** a transaction.
69171 case OP_Vacuum: {
69172 rc = sqlite3RunVacuum(&p->zErrMsg, db);
69173 break;
69175 #endif
69177 #if !defined(SQLITE_OMIT_AUTOVACUUM)
69178 /* Opcode: IncrVacuum P1 P2 * * *
69180 ** Perform a single step of the incremental vacuum procedure on
69181 ** the P1 database. If the vacuum has finished, jump to instruction
69182 ** P2. Otherwise, fall through to the next instruction.
69184 case OP_IncrVacuum: { /* jump */
69185 #if 0 /* local variables moved into u.ci */
69186 Btree *pBt;
69187 #endif /* local variables moved into u.ci */
69189 assert( pOp->p1>=0 && pOp->p1<db->nDb );
69190 assert( (p->btreeMask & (((yDbMask)1)<<pOp->p1))!=0 );
69191 u.ci.pBt = db->aDb[pOp->p1].pBt;
69192 rc = sqlite3BtreeIncrVacuum(u.ci.pBt);
69193 if( rc==SQLITE_DONE ){
69194 pc = pOp->p2 - 1;
69195 rc = SQLITE_OK;
69197 break;
69199 #endif
69201 /* Opcode: Expire P1 * * * *
69203 ** Cause precompiled statements to become expired. An expired statement
69204 ** fails with an error code of SQLITE_SCHEMA if it is ever executed
69205 ** (via sqlite3_step()).
69207 ** If P1 is 0, then all SQL statements become expired. If P1 is non-zero,
69208 ** then only the currently executing statement is affected.
69210 case OP_Expire: {
69211 if( !pOp->p1 ){
69212 sqlite3ExpirePreparedStatements(db);
69213 }else{
69214 p->expired = 1;
69216 break;
69219 #ifndef SQLITE_OMIT_SHARED_CACHE
69220 /* Opcode: TableLock P1 P2 P3 P4 *
69222 ** Obtain a lock on a particular table. This instruction is only used when
69223 ** the shared-cache feature is enabled.
69225 ** P1 is the index of the database in sqlite3.aDb[] of the database
69226 ** on which the lock is acquired. A readlock is obtained if P3==0 or
69227 ** a write lock if P3==1.
69229 ** P2 contains the root-page of the table to lock.
69231 ** P4 contains a pointer to the name of the table being locked. This is only
69232 ** used to generate an error message if the lock cannot be obtained.
69234 case OP_TableLock: {
69235 u8 isWriteLock = (u8)pOp->p3;
69236 if( isWriteLock || 0==(db->flags&SQLITE_ReadUncommitted) ){
69237 int p1 = pOp->p1;
69238 assert( p1>=0 && p1<db->nDb );
69239 assert( (p->btreeMask & (((yDbMask)1)<<p1))!=0 );
69240 assert( isWriteLock==0 || isWriteLock==1 );
69241 rc = sqlite3BtreeLockTable(db->aDb[p1].pBt, pOp->p2, isWriteLock);
69242 if( (rc&0xFF)==SQLITE_LOCKED ){
69243 const char *z = pOp->p4.z;
69244 sqlite3SetString(&p->zErrMsg, db, "database table is locked: %s", z);
69247 break;
69249 #endif /* SQLITE_OMIT_SHARED_CACHE */
69251 #ifndef SQLITE_OMIT_VIRTUALTABLE
69252 /* Opcode: VBegin * * * P4 *
69254 ** P4 may be a pointer to an sqlite3_vtab structure. If so, call the
69255 ** xBegin method for that table.
69257 ** Also, whether or not P4 is set, check that this is not being called from
69258 ** within a callback to a virtual table xSync() method. If it is, the error
69259 ** code will be set to SQLITE_LOCKED.
69261 case OP_VBegin: {
69262 #if 0 /* local variables moved into u.cj */
69263 VTable *pVTab;
69264 #endif /* local variables moved into u.cj */
69265 u.cj.pVTab = pOp->p4.pVtab;
69266 rc = sqlite3VtabBegin(db, u.cj.pVTab);
69267 if( u.cj.pVTab ) importVtabErrMsg(p, u.cj.pVTab->pVtab);
69268 break;
69270 #endif /* SQLITE_OMIT_VIRTUALTABLE */
69272 #ifndef SQLITE_OMIT_VIRTUALTABLE
69273 /* Opcode: VCreate P1 * * P4 *
69275 ** P4 is the name of a virtual table in database P1. Call the xCreate method
69276 ** for that table.
69278 case OP_VCreate: {
69279 rc = sqlite3VtabCallCreate(db, pOp->p1, pOp->p4.z, &p->zErrMsg);
69280 break;
69282 #endif /* SQLITE_OMIT_VIRTUALTABLE */
69284 #ifndef SQLITE_OMIT_VIRTUALTABLE
69285 /* Opcode: VDestroy P1 * * P4 *
69287 ** P4 is the name of a virtual table in database P1. Call the xDestroy method
69288 ** of that table.
69290 case OP_VDestroy: {
69291 p->inVtabMethod = 2;
69292 rc = sqlite3VtabCallDestroy(db, pOp->p1, pOp->p4.z);
69293 p->inVtabMethod = 0;
69294 break;
69296 #endif /* SQLITE_OMIT_VIRTUALTABLE */
69298 #ifndef SQLITE_OMIT_VIRTUALTABLE
69299 /* Opcode: VOpen P1 * * P4 *
69301 ** P4 is a pointer to a virtual table object, an sqlite3_vtab structure.
69302 ** P1 is a cursor number. This opcode opens a cursor to the virtual
69303 ** table and stores that cursor in P1.
69305 case OP_VOpen: {
69306 #if 0 /* local variables moved into u.ck */
69307 VdbeCursor *pCur;
69308 sqlite3_vtab_cursor *pVtabCursor;
69309 sqlite3_vtab *pVtab;
69310 sqlite3_module *pModule;
69311 #endif /* local variables moved into u.ck */
69313 u.ck.pCur = 0;
69314 u.ck.pVtabCursor = 0;
69315 u.ck.pVtab = pOp->p4.pVtab->pVtab;
69316 u.ck.pModule = (sqlite3_module *)u.ck.pVtab->pModule;
69317 assert(u.ck.pVtab && u.ck.pModule);
69318 rc = u.ck.pModule->xOpen(u.ck.pVtab, &u.ck.pVtabCursor);
69319 importVtabErrMsg(p, u.ck.pVtab);
69320 if( SQLITE_OK==rc ){
69321 /* Initialize sqlite3_vtab_cursor base class */
69322 u.ck.pVtabCursor->pVtab = u.ck.pVtab;
69324 /* Initialise vdbe cursor object */
69325 u.ck.pCur = allocateCursor(p, pOp->p1, 0, -1, 0);
69326 if( u.ck.pCur ){
69327 u.ck.pCur->pVtabCursor = u.ck.pVtabCursor;
69328 u.ck.pCur->pModule = u.ck.pVtabCursor->pVtab->pModule;
69329 }else{
69330 db->mallocFailed = 1;
69331 u.ck.pModule->xClose(u.ck.pVtabCursor);
69334 break;
69336 #endif /* SQLITE_OMIT_VIRTUALTABLE */
69338 #ifndef SQLITE_OMIT_VIRTUALTABLE
69339 /* Opcode: VFilter P1 P2 P3 P4 *
69341 ** P1 is a cursor opened using VOpen. P2 is an address to jump to if
69342 ** the filtered result set is empty.
69344 ** P4 is either NULL or a string that was generated by the xBestIndex
69345 ** method of the module. The interpretation of the P4 string is left
69346 ** to the module implementation.
69348 ** This opcode invokes the xFilter method on the virtual table specified
69349 ** by P1. The integer query plan parameter to xFilter is stored in register
69350 ** P3. Register P3+1 stores the argc parameter to be passed to the
69351 ** xFilter method. Registers P3+2..P3+1+argc are the argc
69352 ** additional parameters which are passed to
69353 ** xFilter as argv. Register P3+2 becomes argv[0] when passed to xFilter.
69355 ** A jump is made to P2 if the result set after filtering would be empty.
69357 case OP_VFilter: { /* jump */
69358 #if 0 /* local variables moved into u.cl */
69359 int nArg;
69360 int iQuery;
69361 const sqlite3_module *pModule;
69362 Mem *pQuery;
69363 Mem *pArgc;
69364 sqlite3_vtab_cursor *pVtabCursor;
69365 sqlite3_vtab *pVtab;
69366 VdbeCursor *pCur;
69367 int res;
69368 int i;
69369 Mem **apArg;
69370 #endif /* local variables moved into u.cl */
69372 u.cl.pQuery = &aMem[pOp->p3];
69373 u.cl.pArgc = &u.cl.pQuery[1];
69374 u.cl.pCur = p->apCsr[pOp->p1];
69375 assert( memIsValid(u.cl.pQuery) );
69376 REGISTER_TRACE(pOp->p3, u.cl.pQuery);
69377 assert( u.cl.pCur->pVtabCursor );
69378 u.cl.pVtabCursor = u.cl.pCur->pVtabCursor;
69379 u.cl.pVtab = u.cl.pVtabCursor->pVtab;
69380 u.cl.pModule = u.cl.pVtab->pModule;
69382 /* Grab the index number and argc parameters */
69383 assert( (u.cl.pQuery->flags&MEM_Int)!=0 && u.cl.pArgc->flags==MEM_Int );
69384 u.cl.nArg = (int)u.cl.pArgc->u.i;
69385 u.cl.iQuery = (int)u.cl.pQuery->u.i;
69387 /* Invoke the xFilter method */
69389 u.cl.res = 0;
69390 u.cl.apArg = p->apArg;
69391 for(u.cl.i = 0; u.cl.i<u.cl.nArg; u.cl.i++){
69392 u.cl.apArg[u.cl.i] = &u.cl.pArgc[u.cl.i+1];
69393 sqlite3VdbeMemStoreType(u.cl.apArg[u.cl.i]);
69396 p->inVtabMethod = 1;
69397 rc = u.cl.pModule->xFilter(u.cl.pVtabCursor, u.cl.iQuery, pOp->p4.z, u.cl.nArg, u.cl.apArg);
69398 p->inVtabMethod = 0;
69399 importVtabErrMsg(p, u.cl.pVtab);
69400 if( rc==SQLITE_OK ){
69401 u.cl.res = u.cl.pModule->xEof(u.cl.pVtabCursor);
69404 if( u.cl.res ){
69405 pc = pOp->p2 - 1;
69408 u.cl.pCur->nullRow = 0;
69410 break;
69412 #endif /* SQLITE_OMIT_VIRTUALTABLE */
69414 #ifndef SQLITE_OMIT_VIRTUALTABLE
69415 /* Opcode: VColumn P1 P2 P3 * *
69417 ** Store the value of the P2-th column of
69418 ** the row of the virtual-table that the
69419 ** P1 cursor is pointing to into register P3.
69421 case OP_VColumn: {
69422 #if 0 /* local variables moved into u.cm */
69423 sqlite3_vtab *pVtab;
69424 const sqlite3_module *pModule;
69425 Mem *pDest;
69426 sqlite3_context sContext;
69427 #endif /* local variables moved into u.cm */
69429 VdbeCursor *pCur = p->apCsr[pOp->p1];
69430 assert( pCur->pVtabCursor );
69431 assert( pOp->p3>0 && pOp->p3<=p->nMem );
69432 u.cm.pDest = &aMem[pOp->p3];
69433 memAboutToChange(p, u.cm.pDest);
69434 if( pCur->nullRow ){
69435 sqlite3VdbeMemSetNull(u.cm.pDest);
69436 break;
69438 u.cm.pVtab = pCur->pVtabCursor->pVtab;
69439 u.cm.pModule = u.cm.pVtab->pModule;
69440 assert( u.cm.pModule->xColumn );
69441 memset(&u.cm.sContext, 0, sizeof(u.cm.sContext));
69443 /* The output cell may already have a buffer allocated. Move
69444 ** the current contents to u.cm.sContext.s so in case the user-function
69445 ** can use the already allocated buffer instead of allocating a
69446 ** new one.
69448 sqlite3VdbeMemMove(&u.cm.sContext.s, u.cm.pDest);
69449 MemSetTypeFlag(&u.cm.sContext.s, MEM_Null);
69451 rc = u.cm.pModule->xColumn(pCur->pVtabCursor, &u.cm.sContext, pOp->p2);
69452 importVtabErrMsg(p, u.cm.pVtab);
69453 if( u.cm.sContext.isError ){
69454 rc = u.cm.sContext.isError;
69457 /* Copy the result of the function to the P3 register. We
69458 ** do this regardless of whether or not an error occurred to ensure any
69459 ** dynamic allocation in u.cm.sContext.s (a Mem struct) is released.
69461 sqlite3VdbeChangeEncoding(&u.cm.sContext.s, encoding);
69462 sqlite3VdbeMemMove(u.cm.pDest, &u.cm.sContext.s);
69463 REGISTER_TRACE(pOp->p3, u.cm.pDest);
69464 UPDATE_MAX_BLOBSIZE(u.cm.pDest);
69466 if( sqlite3VdbeMemTooBig(u.cm.pDest) ){
69467 goto too_big;
69469 break;
69471 #endif /* SQLITE_OMIT_VIRTUALTABLE */
69473 #ifndef SQLITE_OMIT_VIRTUALTABLE
69474 /* Opcode: VNext P1 P2 * * *
69476 ** Advance virtual table P1 to the next row in its result set and
69477 ** jump to instruction P2. Or, if the virtual table has reached
69478 ** the end of its result set, then fall through to the next instruction.
69480 case OP_VNext: { /* jump */
69481 #if 0 /* local variables moved into u.cn */
69482 sqlite3_vtab *pVtab;
69483 const sqlite3_module *pModule;
69484 int res;
69485 VdbeCursor *pCur;
69486 #endif /* local variables moved into u.cn */
69488 u.cn.res = 0;
69489 u.cn.pCur = p->apCsr[pOp->p1];
69490 assert( u.cn.pCur->pVtabCursor );
69491 if( u.cn.pCur->nullRow ){
69492 break;
69494 u.cn.pVtab = u.cn.pCur->pVtabCursor->pVtab;
69495 u.cn.pModule = u.cn.pVtab->pModule;
69496 assert( u.cn.pModule->xNext );
69498 /* Invoke the xNext() method of the module. There is no way for the
69499 ** underlying implementation to return an error if one occurs during
69500 ** xNext(). Instead, if an error occurs, true is returned (indicating that
69501 ** data is available) and the error code returned when xColumn or
69502 ** some other method is next invoked on the save virtual table cursor.
69504 p->inVtabMethod = 1;
69505 rc = u.cn.pModule->xNext(u.cn.pCur->pVtabCursor);
69506 p->inVtabMethod = 0;
69507 importVtabErrMsg(p, u.cn.pVtab);
69508 if( rc==SQLITE_OK ){
69509 u.cn.res = u.cn.pModule->xEof(u.cn.pCur->pVtabCursor);
69512 if( !u.cn.res ){
69513 /* If there is data, jump to P2 */
69514 pc = pOp->p2 - 1;
69516 break;
69518 #endif /* SQLITE_OMIT_VIRTUALTABLE */
69520 #ifndef SQLITE_OMIT_VIRTUALTABLE
69521 /* Opcode: VRename P1 * * P4 *
69523 ** P4 is a pointer to a virtual table object, an sqlite3_vtab structure.
69524 ** This opcode invokes the corresponding xRename method. The value
69525 ** in register P1 is passed as the zName argument to the xRename method.
69527 case OP_VRename: {
69528 #if 0 /* local variables moved into u.co */
69529 sqlite3_vtab *pVtab;
69530 Mem *pName;
69531 #endif /* local variables moved into u.co */
69533 u.co.pVtab = pOp->p4.pVtab->pVtab;
69534 u.co.pName = &aMem[pOp->p1];
69535 assert( u.co.pVtab->pModule->xRename );
69536 assert( memIsValid(u.co.pName) );
69537 REGISTER_TRACE(pOp->p1, u.co.pName);
69538 assert( u.co.pName->flags & MEM_Str );
69539 rc = u.co.pVtab->pModule->xRename(u.co.pVtab, u.co.pName->z);
69540 importVtabErrMsg(p, u.co.pVtab);
69541 p->expired = 0;
69543 break;
69545 #endif
69547 #ifndef SQLITE_OMIT_VIRTUALTABLE
69548 /* Opcode: VUpdate P1 P2 P3 P4 *
69550 ** P4 is a pointer to a virtual table object, an sqlite3_vtab structure.
69551 ** This opcode invokes the corresponding xUpdate method. P2 values
69552 ** are contiguous memory cells starting at P3 to pass to the xUpdate
69553 ** invocation. The value in register (P3+P2-1) corresponds to the
69554 ** p2th element of the argv array passed to xUpdate.
69556 ** The xUpdate method will do a DELETE or an INSERT or both.
69557 ** The argv[0] element (which corresponds to memory cell P3)
69558 ** is the rowid of a row to delete. If argv[0] is NULL then no
69559 ** deletion occurs. The argv[1] element is the rowid of the new
69560 ** row. This can be NULL to have the virtual table select the new
69561 ** rowid for itself. The subsequent elements in the array are
69562 ** the values of columns in the new row.
69564 ** If P2==1 then no insert is performed. argv[0] is the rowid of
69565 ** a row to delete.
69567 ** P1 is a boolean flag. If it is set to true and the xUpdate call
69568 ** is successful, then the value returned by sqlite3_last_insert_rowid()
69569 ** is set to the value of the rowid for the row just inserted.
69571 case OP_VUpdate: {
69572 #if 0 /* local variables moved into u.cp */
69573 sqlite3_vtab *pVtab;
69574 sqlite3_module *pModule;
69575 int nArg;
69576 int i;
69577 sqlite_int64 rowid;
69578 Mem **apArg;
69579 Mem *pX;
69580 #endif /* local variables moved into u.cp */
69582 assert( pOp->p2==1 || pOp->p5==OE_Fail || pOp->p5==OE_Rollback
69583 || pOp->p5==OE_Abort || pOp->p5==OE_Ignore || pOp->p5==OE_Replace
69585 u.cp.pVtab = pOp->p4.pVtab->pVtab;
69586 u.cp.pModule = (sqlite3_module *)u.cp.pVtab->pModule;
69587 u.cp.nArg = pOp->p2;
69588 assert( pOp->p4type==P4_VTAB );
69589 if( ALWAYS(u.cp.pModule->xUpdate) ){
69590 u8 vtabOnConflict = db->vtabOnConflict;
69591 u.cp.apArg = p->apArg;
69592 u.cp.pX = &aMem[pOp->p3];
69593 for(u.cp.i=0; u.cp.i<u.cp.nArg; u.cp.i++){
69594 assert( memIsValid(u.cp.pX) );
69595 memAboutToChange(p, u.cp.pX);
69596 sqlite3VdbeMemStoreType(u.cp.pX);
69597 u.cp.apArg[u.cp.i] = u.cp.pX;
69598 u.cp.pX++;
69600 db->vtabOnConflict = pOp->p5;
69601 rc = u.cp.pModule->xUpdate(u.cp.pVtab, u.cp.nArg, u.cp.apArg, &u.cp.rowid);
69602 db->vtabOnConflict = vtabOnConflict;
69603 importVtabErrMsg(p, u.cp.pVtab);
69604 if( rc==SQLITE_OK && pOp->p1 ){
69605 assert( u.cp.nArg>1 && u.cp.apArg[0] && (u.cp.apArg[0]->flags&MEM_Null) );
69606 db->lastRowid = lastRowid = u.cp.rowid;
69608 if( rc==SQLITE_CONSTRAINT && pOp->p4.pVtab->bConstraint ){
69609 if( pOp->p5==OE_Ignore ){
69610 rc = SQLITE_OK;
69611 }else{
69612 p->errorAction = ((pOp->p5==OE_Replace) ? OE_Abort : pOp->p5);
69614 }else{
69615 p->nChange++;
69618 break;
69620 #endif /* SQLITE_OMIT_VIRTUALTABLE */
69622 #ifndef SQLITE_OMIT_PAGER_PRAGMAS
69623 /* Opcode: Pagecount P1 P2 * * *
69625 ** Write the current number of pages in database P1 to memory cell P2.
69627 case OP_Pagecount: { /* out2-prerelease */
69628 pOut->u.i = sqlite3BtreeLastPage(db->aDb[pOp->p1].pBt);
69629 break;
69631 #endif
69634 #ifndef SQLITE_OMIT_PAGER_PRAGMAS
69635 /* Opcode: MaxPgcnt P1 P2 P3 * *
69637 ** Try to set the maximum page count for database P1 to the value in P3.
69638 ** Do not let the maximum page count fall below the current page count and
69639 ** do not change the maximum page count value if P3==0.
69641 ** Store the maximum page count after the change in register P2.
69643 case OP_MaxPgcnt: { /* out2-prerelease */
69644 unsigned int newMax;
69645 Btree *pBt;
69647 pBt = db->aDb[pOp->p1].pBt;
69648 newMax = 0;
69649 if( pOp->p3 ){
69650 newMax = sqlite3BtreeLastPage(pBt);
69651 if( newMax < (unsigned)pOp->p3 ) newMax = (unsigned)pOp->p3;
69653 pOut->u.i = sqlite3BtreeMaxPageCount(pBt, newMax);
69654 break;
69656 #endif
69659 #ifndef SQLITE_OMIT_TRACE
69660 /* Opcode: Trace * * * P4 *
69662 ** If tracing is enabled (by the sqlite3_trace()) interface, then
69663 ** the UTF-8 string contained in P4 is emitted on the trace callback.
69665 case OP_Trace: {
69666 #if 0 /* local variables moved into u.cq */
69667 char *zTrace;
69668 char *z;
69669 #endif /* local variables moved into u.cq */
69671 if( db->xTrace && (u.cq.zTrace = (pOp->p4.z ? pOp->p4.z : p->zSql))!=0 ){
69672 u.cq.z = sqlite3VdbeExpandSql(p, u.cq.zTrace);
69673 db->xTrace(db->pTraceArg, u.cq.z);
69674 sqlite3DbFree(db, u.cq.z);
69676 #ifdef SQLITE_DEBUG
69677 if( (db->flags & SQLITE_SqlTrace)!=0
69678 && (u.cq.zTrace = (pOp->p4.z ? pOp->p4.z : p->zSql))!=0
69680 sqlite3DebugPrintf("SQL-trace: %s\n", u.cq.zTrace);
69682 #endif /* SQLITE_DEBUG */
69683 break;
69685 #endif
69688 /* Opcode: Noop * * * * *
69690 ** Do nothing. This instruction is often useful as a jump
69691 ** destination.
69694 ** The magic Explain opcode are only inserted when explain==2 (which
69695 ** is to say when the EXPLAIN QUERY PLAN syntax is used.)
69696 ** This opcode records information from the optimizer. It is the
69697 ** the same as a no-op. This opcodesnever appears in a real VM program.
69699 default: { /* This is really OP_Noop and OP_Explain */
69700 assert( pOp->opcode==OP_Noop || pOp->opcode==OP_Explain );
69701 break;
69704 /*****************************************************************************
69705 ** The cases of the switch statement above this line should all be indented
69706 ** by 6 spaces. But the left-most 6 spaces have been removed to improve the
69707 ** readability. From this point on down, the normal indentation rules are
69708 ** restored.
69709 *****************************************************************************/
69712 #ifdef VDBE_PROFILE
69714 u64 elapsed = sqlite3Hwtime() - start;
69715 pOp->cycles += elapsed;
69716 pOp->cnt++;
69717 #if 0
69718 fprintf(stdout, "%10llu ", elapsed);
69719 sqlite3VdbePrintOp(stdout, origPc, &aOp[origPc]);
69720 #endif
69722 #endif
69724 /* The following code adds nothing to the actual functionality
69725 ** of the program. It is only here for testing and debugging.
69726 ** On the other hand, it does burn CPU cycles every time through
69727 ** the evaluator loop. So we can leave it out when NDEBUG is defined.
69729 #ifndef NDEBUG
69730 assert( pc>=-1 && pc<p->nOp );
69732 #ifdef SQLITE_DEBUG
69733 if( p->trace ){
69734 if( rc!=0 ) fprintf(p->trace,"rc=%d\n",rc);
69735 if( pOp->opflags & (OPFLG_OUT2_PRERELEASE|OPFLG_OUT2) ){
69736 registerTrace(p->trace, pOp->p2, &aMem[pOp->p2]);
69738 if( pOp->opflags & OPFLG_OUT3 ){
69739 registerTrace(p->trace, pOp->p3, &aMem[pOp->p3]);
69742 #endif /* SQLITE_DEBUG */
69743 #endif /* NDEBUG */
69744 } /* The end of the for(;;) loop the loops through opcodes */
69746 /* If we reach this point, it means that execution is finished with
69747 ** an error of some kind.
69749 vdbe_error_halt:
69750 assert( rc );
69751 p->rc = rc;
69752 testcase( sqlite3GlobalConfig.xLog!=0 );
69753 sqlite3_log(rc, "statement aborts at %d: [%s] %s",
69754 pc, p->zSql, p->zErrMsg);
69755 sqlite3VdbeHalt(p);
69756 if( rc==SQLITE_IOERR_NOMEM ) db->mallocFailed = 1;
69757 rc = SQLITE_ERROR;
69758 if( resetSchemaOnFault>0 ){
69759 sqlite3ResetInternalSchema(db, resetSchemaOnFault-1);
69762 /* This is the only way out of this procedure. We have to
69763 ** release the mutexes on btrees that were acquired at the
69764 ** top. */
69765 vdbe_return:
69766 db->lastRowid = lastRowid;
69767 sqlite3VdbeLeave(p);
69768 return rc;
69770 /* Jump to here if a string or blob larger than SQLITE_MAX_LENGTH
69771 ** is encountered.
69773 too_big:
69774 sqlite3SetString(&p->zErrMsg, db, "string or blob too big");
69775 rc = SQLITE_TOOBIG;
69776 goto vdbe_error_halt;
69778 /* Jump to here if a malloc() fails.
69780 no_mem:
69781 db->mallocFailed = 1;
69782 sqlite3SetString(&p->zErrMsg, db, "out of memory");
69783 rc = SQLITE_NOMEM;
69784 goto vdbe_error_halt;
69786 /* Jump to here for any other kind of fatal error. The "rc" variable
69787 ** should hold the error number.
69789 abort_due_to_error:
69790 assert( p->zErrMsg==0 );
69791 if( db->mallocFailed ) rc = SQLITE_NOMEM;
69792 if( rc!=SQLITE_IOERR_NOMEM ){
69793 sqlite3SetString(&p->zErrMsg, db, "%s", sqlite3ErrStr(rc));
69795 goto vdbe_error_halt;
69797 /* Jump to here if the sqlite3_interrupt() API sets the interrupt
69798 ** flag.
69800 abort_due_to_interrupt:
69801 assert( db->u1.isInterrupted );
69802 rc = SQLITE_INTERRUPT;
69803 p->rc = rc;
69804 sqlite3SetString(&p->zErrMsg, db, "%s", sqlite3ErrStr(rc));
69805 goto vdbe_error_halt;
69808 /************** End of vdbe.c ************************************************/
69809 /************** Begin file vdbeblob.c ****************************************/
69811 ** 2007 May 1
69813 ** The author disclaims copyright to this source code. In place of
69814 ** a legal notice, here is a blessing:
69816 ** May you do good and not evil.
69817 ** May you find forgiveness for yourself and forgive others.
69818 ** May you share freely, never taking more than you give.
69820 *************************************************************************
69822 ** This file contains code used to implement incremental BLOB I/O.
69826 #ifndef SQLITE_OMIT_INCRBLOB
69829 ** Valid sqlite3_blob* handles point to Incrblob structures.
69831 typedef struct Incrblob Incrblob;
69832 struct Incrblob {
69833 int flags; /* Copy of "flags" passed to sqlite3_blob_open() */
69834 int nByte; /* Size of open blob, in bytes */
69835 int iOffset; /* Byte offset of blob in cursor data */
69836 int iCol; /* Table column this handle is open on */
69837 BtCursor *pCsr; /* Cursor pointing at blob row */
69838 sqlite3_stmt *pStmt; /* Statement holding cursor open */
69839 sqlite3 *db; /* The associated database */
69844 ** This function is used by both blob_open() and blob_reopen(). It seeks
69845 ** the b-tree cursor associated with blob handle p to point to row iRow.
69846 ** If successful, SQLITE_OK is returned and subsequent calls to
69847 ** sqlite3_blob_read() or sqlite3_blob_write() access the specified row.
69849 ** If an error occurs, or if the specified row does not exist or does not
69850 ** contain a value of type TEXT or BLOB in the column nominated when the
69851 ** blob handle was opened, then an error code is returned and *pzErr may
69852 ** be set to point to a buffer containing an error message. It is the
69853 ** responsibility of the caller to free the error message buffer using
69854 ** sqlite3DbFree().
69856 ** If an error does occur, then the b-tree cursor is closed. All subsequent
69857 ** calls to sqlite3_blob_read(), blob_write() or blob_reopen() will
69858 ** immediately return SQLITE_ABORT.
69860 static int blobSeekToRow(Incrblob *p, sqlite3_int64 iRow, char **pzErr){
69861 int rc; /* Error code */
69862 char *zErr = 0; /* Error message */
69863 Vdbe *v = (Vdbe *)p->pStmt;
69865 /* Set the value of the SQL statements only variable to integer iRow.
69866 ** This is done directly instead of using sqlite3_bind_int64() to avoid
69867 ** triggering asserts related to mutexes.
69869 assert( v->aVar[0].flags&MEM_Int );
69870 v->aVar[0].u.i = iRow;
69872 rc = sqlite3_step(p->pStmt);
69873 if( rc==SQLITE_ROW ){
69874 u32 type = v->apCsr[0]->aType[p->iCol];
69875 if( type<12 ){
69876 zErr = sqlite3MPrintf(p->db, "cannot open value of type %s",
69877 type==0?"null": type==7?"real": "integer"
69879 rc = SQLITE_ERROR;
69880 sqlite3_finalize(p->pStmt);
69881 p->pStmt = 0;
69882 }else{
69883 p->iOffset = v->apCsr[0]->aOffset[p->iCol];
69884 p->nByte = sqlite3VdbeSerialTypeLen(type);
69885 p->pCsr = v->apCsr[0]->pCursor;
69886 sqlite3BtreeEnterCursor(p->pCsr);
69887 sqlite3BtreeCacheOverflow(p->pCsr);
69888 sqlite3BtreeLeaveCursor(p->pCsr);
69892 if( rc==SQLITE_ROW ){
69893 rc = SQLITE_OK;
69894 }else if( p->pStmt ){
69895 rc = sqlite3_finalize(p->pStmt);
69896 p->pStmt = 0;
69897 if( rc==SQLITE_OK ){
69898 zErr = sqlite3MPrintf(p->db, "no such rowid: %lld", iRow);
69899 rc = SQLITE_ERROR;
69900 }else{
69901 zErr = sqlite3MPrintf(p->db, "%s", sqlite3_errmsg(p->db));
69905 assert( rc!=SQLITE_OK || zErr==0 );
69906 assert( rc!=SQLITE_ROW && rc!=SQLITE_DONE );
69908 *pzErr = zErr;
69909 return rc;
69913 ** Open a blob handle.
69915 SQLITE_API int sqlite3_blob_open(
69916 sqlite3* db, /* The database connection */
69917 const char *zDb, /* The attached database containing the blob */
69918 const char *zTable, /* The table containing the blob */
69919 const char *zColumn, /* The column containing the blob */
69920 sqlite_int64 iRow, /* The row containing the glob */
69921 int flags, /* True -> read/write access, false -> read-only */
69922 sqlite3_blob **ppBlob /* Handle for accessing the blob returned here */
69924 int nAttempt = 0;
69925 int iCol; /* Index of zColumn in row-record */
69927 /* This VDBE program seeks a btree cursor to the identified
69928 ** db/table/row entry. The reason for using a vdbe program instead
69929 ** of writing code to use the b-tree layer directly is that the
69930 ** vdbe program will take advantage of the various transaction,
69931 ** locking and error handling infrastructure built into the vdbe.
69933 ** After seeking the cursor, the vdbe executes an OP_ResultRow.
69934 ** Code external to the Vdbe then "borrows" the b-tree cursor and
69935 ** uses it to implement the blob_read(), blob_write() and
69936 ** blob_bytes() functions.
69938 ** The sqlite3_blob_close() function finalizes the vdbe program,
69939 ** which closes the b-tree cursor and (possibly) commits the
69940 ** transaction.
69942 static const VdbeOpList openBlob[] = {
69943 {OP_Transaction, 0, 0, 0}, /* 0: Start a transaction */
69944 {OP_VerifyCookie, 0, 0, 0}, /* 1: Check the schema cookie */
69945 {OP_TableLock, 0, 0, 0}, /* 2: Acquire a read or write lock */
69947 /* One of the following two instructions is replaced by an OP_Noop. */
69948 {OP_OpenRead, 0, 0, 0}, /* 3: Open cursor 0 for reading */
69949 {OP_OpenWrite, 0, 0, 0}, /* 4: Open cursor 0 for read/write */
69951 {OP_Variable, 1, 1, 1}, /* 5: Push the rowid to the stack */
69952 {OP_NotExists, 0, 10, 1}, /* 6: Seek the cursor */
69953 {OP_Column, 0, 0, 1}, /* 7 */
69954 {OP_ResultRow, 1, 0, 0}, /* 8 */
69955 {OP_Goto, 0, 5, 0}, /* 9 */
69956 {OP_Close, 0, 0, 0}, /* 10 */
69957 {OP_Halt, 0, 0, 0}, /* 11 */
69960 int rc = SQLITE_OK;
69961 char *zErr = 0;
69962 Table *pTab;
69963 Parse *pParse = 0;
69964 Incrblob *pBlob = 0;
69966 flags = !!flags; /* flags = (flags ? 1 : 0); */
69967 *ppBlob = 0;
69969 sqlite3_mutex_enter(db->mutex);
69971 pBlob = (Incrblob *)sqlite3DbMallocZero(db, sizeof(Incrblob));
69972 if( !pBlob ) goto blob_open_out;
69973 pParse = sqlite3StackAllocRaw(db, sizeof(*pParse));
69974 if( !pParse ) goto blob_open_out;
69976 do {
69977 memset(pParse, 0, sizeof(Parse));
69978 pParse->db = db;
69979 sqlite3DbFree(db, zErr);
69980 zErr = 0;
69982 sqlite3BtreeEnterAll(db);
69983 pTab = sqlite3LocateTable(pParse, 0, zTable, zDb);
69984 if( pTab && IsVirtual(pTab) ){
69985 pTab = 0;
69986 sqlite3ErrorMsg(pParse, "cannot open virtual table: %s", zTable);
69988 #ifndef SQLITE_OMIT_VIEW
69989 if( pTab && pTab->pSelect ){
69990 pTab = 0;
69991 sqlite3ErrorMsg(pParse, "cannot open view: %s", zTable);
69993 #endif
69994 if( !pTab ){
69995 if( pParse->zErrMsg ){
69996 sqlite3DbFree(db, zErr);
69997 zErr = pParse->zErrMsg;
69998 pParse->zErrMsg = 0;
70000 rc = SQLITE_ERROR;
70001 sqlite3BtreeLeaveAll(db);
70002 goto blob_open_out;
70005 /* Now search pTab for the exact column. */
70006 for(iCol=0; iCol<pTab->nCol; iCol++) {
70007 if( sqlite3StrICmp(pTab->aCol[iCol].zName, zColumn)==0 ){
70008 break;
70011 if( iCol==pTab->nCol ){
70012 sqlite3DbFree(db, zErr);
70013 zErr = sqlite3MPrintf(db, "no such column: \"%s\"", zColumn);
70014 rc = SQLITE_ERROR;
70015 sqlite3BtreeLeaveAll(db);
70016 goto blob_open_out;
70019 /* If the value is being opened for writing, check that the
70020 ** column is not indexed, and that it is not part of a foreign key.
70021 ** It is against the rules to open a column to which either of these
70022 ** descriptions applies for writing. */
70023 if( flags ){
70024 const char *zFault = 0;
70025 Index *pIdx;
70026 #ifndef SQLITE_OMIT_FOREIGN_KEY
70027 if( db->flags&SQLITE_ForeignKeys ){
70028 /* Check that the column is not part of an FK child key definition. It
70029 ** is not necessary to check if it is part of a parent key, as parent
70030 ** key columns must be indexed. The check below will pick up this
70031 ** case. */
70032 FKey *pFKey;
70033 for(pFKey=pTab->pFKey; pFKey; pFKey=pFKey->pNextFrom){
70034 int j;
70035 for(j=0; j<pFKey->nCol; j++){
70036 if( pFKey->aCol[j].iFrom==iCol ){
70037 zFault = "foreign key";
70042 #endif
70043 for(pIdx=pTab->pIndex; pIdx; pIdx=pIdx->pNext){
70044 int j;
70045 for(j=0; j<pIdx->nColumn; j++){
70046 if( pIdx->aiColumn[j]==iCol ){
70047 zFault = "indexed";
70051 if( zFault ){
70052 sqlite3DbFree(db, zErr);
70053 zErr = sqlite3MPrintf(db, "cannot open %s column for writing", zFault);
70054 rc = SQLITE_ERROR;
70055 sqlite3BtreeLeaveAll(db);
70056 goto blob_open_out;
70060 pBlob->pStmt = (sqlite3_stmt *)sqlite3VdbeCreate(db);
70061 assert( pBlob->pStmt || db->mallocFailed );
70062 if( pBlob->pStmt ){
70063 Vdbe *v = (Vdbe *)pBlob->pStmt;
70064 int iDb = sqlite3SchemaToIndex(db, pTab->pSchema);
70066 sqlite3VdbeAddOpList(v, sizeof(openBlob)/sizeof(VdbeOpList), openBlob);
70069 /* Configure the OP_Transaction */
70070 sqlite3VdbeChangeP1(v, 0, iDb);
70071 sqlite3VdbeChangeP2(v, 0, flags);
70073 /* Configure the OP_VerifyCookie */
70074 sqlite3VdbeChangeP1(v, 1, iDb);
70075 sqlite3VdbeChangeP2(v, 1, pTab->pSchema->schema_cookie);
70076 sqlite3VdbeChangeP3(v, 1, pTab->pSchema->iGeneration);
70078 /* Make sure a mutex is held on the table to be accessed */
70079 sqlite3VdbeUsesBtree(v, iDb);
70081 /* Configure the OP_TableLock instruction */
70082 #ifdef SQLITE_OMIT_SHARED_CACHE
70083 sqlite3VdbeChangeToNoop(v, 2);
70084 #else
70085 sqlite3VdbeChangeP1(v, 2, iDb);
70086 sqlite3VdbeChangeP2(v, 2, pTab->tnum);
70087 sqlite3VdbeChangeP3(v, 2, flags);
70088 sqlite3VdbeChangeP4(v, 2, pTab->zName, P4_TRANSIENT);
70089 #endif
70091 /* Remove either the OP_OpenWrite or OpenRead. Set the P2
70092 ** parameter of the other to pTab->tnum. */
70093 sqlite3VdbeChangeToNoop(v, 4 - flags);
70094 sqlite3VdbeChangeP2(v, 3 + flags, pTab->tnum);
70095 sqlite3VdbeChangeP3(v, 3 + flags, iDb);
70097 /* Configure the number of columns. Configure the cursor to
70098 ** think that the table has one more column than it really
70099 ** does. An OP_Column to retrieve this imaginary column will
70100 ** always return an SQL NULL. This is useful because it means
70101 ** we can invoke OP_Column to fill in the vdbe cursors type
70102 ** and offset cache without causing any IO.
70104 sqlite3VdbeChangeP4(v, 3+flags, SQLITE_INT_TO_PTR(pTab->nCol+1),P4_INT32);
70105 sqlite3VdbeChangeP2(v, 7, pTab->nCol);
70106 if( !db->mallocFailed ){
70107 pParse->nVar = 1;
70108 pParse->nMem = 1;
70109 pParse->nTab = 1;
70110 sqlite3VdbeMakeReady(v, pParse);
70114 pBlob->flags = flags;
70115 pBlob->iCol = iCol;
70116 pBlob->db = db;
70117 sqlite3BtreeLeaveAll(db);
70118 if( db->mallocFailed ){
70119 goto blob_open_out;
70121 sqlite3_bind_int64(pBlob->pStmt, 1, iRow);
70122 rc = blobSeekToRow(pBlob, iRow, &zErr);
70123 } while( (++nAttempt)<5 && rc==SQLITE_SCHEMA );
70125 blob_open_out:
70126 if( rc==SQLITE_OK && db->mallocFailed==0 ){
70127 *ppBlob = (sqlite3_blob *)pBlob;
70128 }else{
70129 if( pBlob && pBlob->pStmt ) sqlite3VdbeFinalize((Vdbe *)pBlob->pStmt);
70130 sqlite3DbFree(db, pBlob);
70132 sqlite3Error(db, rc, (zErr ? "%s" : 0), zErr);
70133 sqlite3DbFree(db, zErr);
70134 sqlite3StackFree(db, pParse);
70135 rc = sqlite3ApiExit(db, rc);
70136 sqlite3_mutex_leave(db->mutex);
70137 return rc;
70141 ** Close a blob handle that was previously created using
70142 ** sqlite3_blob_open().
70144 SQLITE_API int sqlite3_blob_close(sqlite3_blob *pBlob){
70145 Incrblob *p = (Incrblob *)pBlob;
70146 int rc;
70147 sqlite3 *db;
70149 if( p ){
70150 db = p->db;
70151 sqlite3_mutex_enter(db->mutex);
70152 rc = sqlite3_finalize(p->pStmt);
70153 sqlite3DbFree(db, p);
70154 sqlite3_mutex_leave(db->mutex);
70155 }else{
70156 rc = SQLITE_OK;
70158 return rc;
70162 ** Perform a read or write operation on a blob
70164 static int blobReadWrite(
70165 sqlite3_blob *pBlob,
70166 void *z,
70167 int n,
70168 int iOffset,
70169 int (*xCall)(BtCursor*, u32, u32, void*)
70171 int rc;
70172 Incrblob *p = (Incrblob *)pBlob;
70173 Vdbe *v;
70174 sqlite3 *db;
70176 if( p==0 ) return SQLITE_MISUSE_BKPT;
70177 db = p->db;
70178 sqlite3_mutex_enter(db->mutex);
70179 v = (Vdbe*)p->pStmt;
70181 if( n<0 || iOffset<0 || (iOffset+n)>p->nByte ){
70182 /* Request is out of range. Return a transient error. */
70183 rc = SQLITE_ERROR;
70184 sqlite3Error(db, SQLITE_ERROR, 0);
70185 }else if( v==0 ){
70186 /* If there is no statement handle, then the blob-handle has
70187 ** already been invalidated. Return SQLITE_ABORT in this case.
70189 rc = SQLITE_ABORT;
70190 }else{
70191 /* Call either BtreeData() or BtreePutData(). If SQLITE_ABORT is
70192 ** returned, clean-up the statement handle.
70194 assert( db == v->db );
70195 sqlite3BtreeEnterCursor(p->pCsr);
70196 rc = xCall(p->pCsr, iOffset+p->iOffset, n, z);
70197 sqlite3BtreeLeaveCursor(p->pCsr);
70198 if( rc==SQLITE_ABORT ){
70199 sqlite3VdbeFinalize(v);
70200 p->pStmt = 0;
70201 }else{
70202 db->errCode = rc;
70203 v->rc = rc;
70206 rc = sqlite3ApiExit(db, rc);
70207 sqlite3_mutex_leave(db->mutex);
70208 return rc;
70212 ** Read data from a blob handle.
70214 SQLITE_API int sqlite3_blob_read(sqlite3_blob *pBlob, void *z, int n, int iOffset){
70215 return blobReadWrite(pBlob, z, n, iOffset, sqlite3BtreeData);
70219 ** Write data to a blob handle.
70221 SQLITE_API int sqlite3_blob_write(sqlite3_blob *pBlob, const void *z, int n, int iOffset){
70222 return blobReadWrite(pBlob, (void *)z, n, iOffset, sqlite3BtreePutData);
70226 ** Query a blob handle for the size of the data.
70228 ** The Incrblob.nByte field is fixed for the lifetime of the Incrblob
70229 ** so no mutex is required for access.
70231 SQLITE_API int sqlite3_blob_bytes(sqlite3_blob *pBlob){
70232 Incrblob *p = (Incrblob *)pBlob;
70233 return (p && p->pStmt) ? p->nByte : 0;
70237 ** Move an existing blob handle to point to a different row of the same
70238 ** database table.
70240 ** If an error occurs, or if the specified row does not exist or does not
70241 ** contain a blob or text value, then an error code is returned and the
70242 ** database handle error code and message set. If this happens, then all
70243 ** subsequent calls to sqlite3_blob_xxx() functions (except blob_close())
70244 ** immediately return SQLITE_ABORT.
70246 SQLITE_API int sqlite3_blob_reopen(sqlite3_blob *pBlob, sqlite3_int64 iRow){
70247 int rc;
70248 Incrblob *p = (Incrblob *)pBlob;
70249 sqlite3 *db;
70251 if( p==0 ) return SQLITE_MISUSE_BKPT;
70252 db = p->db;
70253 sqlite3_mutex_enter(db->mutex);
70255 if( p->pStmt==0 ){
70256 /* If there is no statement handle, then the blob-handle has
70257 ** already been invalidated. Return SQLITE_ABORT in this case.
70259 rc = SQLITE_ABORT;
70260 }else{
70261 char *zErr;
70262 rc = blobSeekToRow(p, iRow, &zErr);
70263 if( rc!=SQLITE_OK ){
70264 sqlite3Error(db, rc, (zErr ? "%s" : 0), zErr);
70265 sqlite3DbFree(db, zErr);
70267 assert( rc!=SQLITE_SCHEMA );
70270 rc = sqlite3ApiExit(db, rc);
70271 assert( rc==SQLITE_OK || p->pStmt==0 );
70272 sqlite3_mutex_leave(db->mutex);
70273 return rc;
70276 #endif /* #ifndef SQLITE_OMIT_INCRBLOB */
70278 /************** End of vdbeblob.c ********************************************/
70279 /************** Begin file vdbesort.c ****************************************/
70281 ** 2011 July 9
70283 ** The author disclaims copyright to this source code. In place of
70284 ** a legal notice, here is a blessing:
70286 ** May you do good and not evil.
70287 ** May you find forgiveness for yourself and forgive others.
70288 ** May you share freely, never taking more than you give.
70290 *************************************************************************
70291 ** This file contains code for the VdbeSorter object, used in concert with
70292 ** a VdbeCursor to sort large numbers of keys (as may be required, for
70293 ** example, by CREATE INDEX statements on tables too large to fit in main
70294 ** memory).
70298 #ifndef SQLITE_OMIT_MERGE_SORT
70300 typedef struct VdbeSorterIter VdbeSorterIter;
70301 typedef struct SorterRecord SorterRecord;
70304 ** NOTES ON DATA STRUCTURE USED FOR N-WAY MERGES:
70306 ** As keys are added to the sorter, they are written to disk in a series
70307 ** of sorted packed-memory-arrays (PMAs). The size of each PMA is roughly
70308 ** the same as the cache-size allowed for temporary databases. In order
70309 ** to allow the caller to extract keys from the sorter in sorted order,
70310 ** all PMAs currently stored on disk must be merged together. This comment
70311 ** describes the data structure used to do so. The structure supports
70312 ** merging any number of arrays in a single pass with no redundant comparison
70313 ** operations.
70315 ** The aIter[] array contains an iterator for each of the PMAs being merged.
70316 ** An aIter[] iterator either points to a valid key or else is at EOF. For
70317 ** the purposes of the paragraphs below, we assume that the array is actually
70318 ** N elements in size, where N is the smallest power of 2 greater to or equal
70319 ** to the number of iterators being merged. The extra aIter[] elements are
70320 ** treated as if they are empty (always at EOF).
70322 ** The aTree[] array is also N elements in size. The value of N is stored in
70323 ** the VdbeSorter.nTree variable.
70325 ** The final (N/2) elements of aTree[] contain the results of comparing
70326 ** pairs of iterator keys together. Element i contains the result of
70327 ** comparing aIter[2*i-N] and aIter[2*i-N+1]. Whichever key is smaller, the
70328 ** aTree element is set to the index of it.
70330 ** For the purposes of this comparison, EOF is considered greater than any
70331 ** other key value. If the keys are equal (only possible with two EOF
70332 ** values), it doesn't matter which index is stored.
70334 ** The (N/4) elements of aTree[] that preceed the final (N/2) described
70335 ** above contains the index of the smallest of each block of 4 iterators.
70336 ** And so on. So that aTree[1] contains the index of the iterator that
70337 ** currently points to the smallest key value. aTree[0] is unused.
70339 ** Example:
70341 ** aIter[0] -> Banana
70342 ** aIter[1] -> Feijoa
70343 ** aIter[2] -> Elderberry
70344 ** aIter[3] -> Currant
70345 ** aIter[4] -> Grapefruit
70346 ** aIter[5] -> Apple
70347 ** aIter[6] -> Durian
70348 ** aIter[7] -> EOF
70350 ** aTree[] = { X, 5 0, 5 0, 3, 5, 6 }
70352 ** The current element is "Apple" (the value of the key indicated by
70353 ** iterator 5). When the Next() operation is invoked, iterator 5 will
70354 ** be advanced to the next key in its segment. Say the next key is
70355 ** "Eggplant":
70357 ** aIter[5] -> Eggplant
70359 ** The contents of aTree[] are updated first by comparing the new iterator
70360 ** 5 key to the current key of iterator 4 (still "Grapefruit"). The iterator
70361 ** 5 value is still smaller, so aTree[6] is set to 5. And so on up the tree.
70362 ** The value of iterator 6 - "Durian" - is now smaller than that of iterator
70363 ** 5, so aTree[3] is set to 6. Key 0 is smaller than key 6 (Banana<Durian),
70364 ** so the value written into element 1 of the array is 0. As follows:
70366 ** aTree[] = { X, 0 0, 6 0, 3, 5, 6 }
70368 ** In other words, each time we advance to the next sorter element, log2(N)
70369 ** key comparison operations are required, where N is the number of segments
70370 ** being merged (rounded up to the next power of 2).
70372 struct VdbeSorter {
70373 int nInMemory; /* Current size of pRecord list as PMA */
70374 int nTree; /* Used size of aTree/aIter (power of 2) */
70375 VdbeSorterIter *aIter; /* Array of iterators to merge */
70376 int *aTree; /* Current state of incremental merge */
70377 i64 iWriteOff; /* Current write offset within file pTemp1 */
70378 i64 iReadOff; /* Current read offset within file pTemp1 */
70379 sqlite3_file *pTemp1; /* PMA file 1 */
70380 int nPMA; /* Number of PMAs stored in pTemp1 */
70381 SorterRecord *pRecord; /* Head of in-memory record list */
70382 int mnPmaSize; /* Minimum PMA size, in bytes */
70383 int mxPmaSize; /* Maximum PMA size, in bytes. 0==no limit */
70384 UnpackedRecord *pUnpacked; /* Used to unpack keys */
70388 ** The following type is an iterator for a PMA. It caches the current key in
70389 ** variables nKey/aKey. If the iterator is at EOF, pFile==0.
70391 struct VdbeSorterIter {
70392 i64 iReadOff; /* Current read offset */
70393 i64 iEof; /* 1 byte past EOF for this iterator */
70394 sqlite3_file *pFile; /* File iterator is reading from */
70395 int nAlloc; /* Bytes of space at aAlloc */
70396 u8 *aAlloc; /* Allocated space */
70397 int nKey; /* Number of bytes in key */
70398 u8 *aKey; /* Pointer to current key */
70402 ** A structure to store a single record. All in-memory records are connected
70403 ** together into a linked list headed at VdbeSorter.pRecord using the
70404 ** SorterRecord.pNext pointer.
70406 struct SorterRecord {
70407 void *pVal;
70408 int nVal;
70409 SorterRecord *pNext;
70412 /* Minimum allowable value for the VdbeSorter.nWorking variable */
70413 #define SORTER_MIN_WORKING 10
70415 /* Maximum number of segments to merge in a single pass. */
70416 #define SORTER_MAX_MERGE_COUNT 16
70419 ** Free all memory belonging to the VdbeSorterIter object passed as the second
70420 ** argument. All structure fields are set to zero before returning.
70422 static void vdbeSorterIterZero(sqlite3 *db, VdbeSorterIter *pIter){
70423 sqlite3DbFree(db, pIter->aAlloc);
70424 memset(pIter, 0, sizeof(VdbeSorterIter));
70428 ** Advance iterator pIter to the next key in its PMA. Return SQLITE_OK if
70429 ** no error occurs, or an SQLite error code if one does.
70431 static int vdbeSorterIterNext(
70432 sqlite3 *db, /* Database handle (for sqlite3DbMalloc() ) */
70433 VdbeSorterIter *pIter /* Iterator to advance */
70435 int rc; /* Return Code */
70436 int nRead; /* Number of bytes read */
70437 int nRec = 0; /* Size of record in bytes */
70438 int iOff = 0; /* Size of serialized size varint in bytes */
70440 assert( pIter->iEof>=pIter->iReadOff );
70441 if( pIter->iEof-pIter->iReadOff>5 ){
70442 nRead = 5;
70443 }else{
70444 nRead = (int)(pIter->iEof - pIter->iReadOff);
70446 if( nRead<=0 ){
70447 /* This is an EOF condition */
70448 vdbeSorterIterZero(db, pIter);
70449 return SQLITE_OK;
70452 rc = sqlite3OsRead(pIter->pFile, pIter->aAlloc, nRead, pIter->iReadOff);
70453 if( rc==SQLITE_OK ){
70454 iOff = getVarint32(pIter->aAlloc, nRec);
70455 if( (iOff+nRec)>nRead ){
70456 int nRead2; /* Number of extra bytes to read */
70457 if( (iOff+nRec)>pIter->nAlloc ){
70458 int nNew = pIter->nAlloc*2;
70459 while( (iOff+nRec)>nNew ) nNew = nNew*2;
70460 pIter->aAlloc = sqlite3DbReallocOrFree(db, pIter->aAlloc, nNew);
70461 if( !pIter->aAlloc ) return SQLITE_NOMEM;
70462 pIter->nAlloc = nNew;
70465 nRead2 = iOff + nRec - nRead;
70466 rc = sqlite3OsRead(
70467 pIter->pFile, &pIter->aAlloc[nRead], nRead2, pIter->iReadOff+nRead
70472 assert( rc!=SQLITE_OK || nRec>0 );
70473 pIter->iReadOff += iOff+nRec;
70474 pIter->nKey = nRec;
70475 pIter->aKey = &pIter->aAlloc[iOff];
70476 return rc;
70480 ** Write a single varint, value iVal, to file-descriptor pFile. Return
70481 ** SQLITE_OK if successful, or an SQLite error code if some error occurs.
70483 ** The value of *piOffset when this function is called is used as the byte
70484 ** offset in file pFile to write to. Before returning, *piOffset is
70485 ** incremented by the number of bytes written.
70487 static int vdbeSorterWriteVarint(
70488 sqlite3_file *pFile, /* File to write to */
70489 i64 iVal, /* Value to write as a varint */
70490 i64 *piOffset /* IN/OUT: Write offset in file pFile */
70492 u8 aVarint[9]; /* Buffer large enough for a varint */
70493 int nVarint; /* Number of used bytes in varint */
70494 int rc; /* Result of write() call */
70496 nVarint = sqlite3PutVarint(aVarint, iVal);
70497 rc = sqlite3OsWrite(pFile, aVarint, nVarint, *piOffset);
70498 *piOffset += nVarint;
70500 return rc;
70504 ** Read a single varint from file-descriptor pFile. Return SQLITE_OK if
70505 ** successful, or an SQLite error code if some error occurs.
70507 ** The value of *piOffset when this function is called is used as the
70508 ** byte offset in file pFile from whence to read the varint. If successful
70509 ** (i.e. if no IO error occurs), then *piOffset is set to the offset of
70510 ** the first byte past the end of the varint before returning. *piVal is
70511 ** set to the integer value read. If an error occurs, the final values of
70512 ** both *piOffset and *piVal are undefined.
70514 static int vdbeSorterReadVarint(
70515 sqlite3_file *pFile, /* File to read from */
70516 i64 *piOffset, /* IN/OUT: Read offset in pFile */
70517 i64 *piVal /* OUT: Value read from file */
70519 u8 aVarint[9]; /* Buffer large enough for a varint */
70520 i64 iOff = *piOffset; /* Offset in file to read from */
70521 int rc; /* Return code */
70523 rc = sqlite3OsRead(pFile, aVarint, 9, iOff);
70524 if( rc==SQLITE_OK ){
70525 *piOffset += getVarint(aVarint, (u64 *)piVal);
70528 return rc;
70532 ** Initialize iterator pIter to scan through the PMA stored in file pFile
70533 ** starting at offset iStart and ending at offset iEof-1. This function
70534 ** leaves the iterator pointing to the first key in the PMA (or EOF if the
70535 ** PMA is empty).
70537 static int vdbeSorterIterInit(
70538 sqlite3 *db, /* Database handle */
70539 VdbeSorter *pSorter, /* Sorter object */
70540 i64 iStart, /* Start offset in pFile */
70541 VdbeSorterIter *pIter, /* Iterator to populate */
70542 i64 *pnByte /* IN/OUT: Increment this value by PMA size */
70544 int rc;
70546 assert( pSorter->iWriteOff>iStart );
70547 assert( pIter->aAlloc==0 );
70548 pIter->pFile = pSorter->pTemp1;
70549 pIter->iReadOff = iStart;
70550 pIter->nAlloc = 128;
70551 pIter->aAlloc = (u8 *)sqlite3DbMallocRaw(db, pIter->nAlloc);
70552 if( !pIter->aAlloc ){
70553 rc = SQLITE_NOMEM;
70554 }else{
70555 i64 nByte; /* Total size of PMA in bytes */
70556 rc = vdbeSorterReadVarint(pSorter->pTemp1, &pIter->iReadOff, &nByte);
70557 *pnByte += nByte;
70558 pIter->iEof = pIter->iReadOff + nByte;
70560 if( rc==SQLITE_OK ){
70561 rc = vdbeSorterIterNext(db, pIter);
70563 return rc;
70568 ** Compare key1 (buffer pKey1, size nKey1 bytes) with key2 (buffer pKey2,
70569 ** size nKey2 bytes). Argument pKeyInfo supplies the collation functions
70570 ** used by the comparison. If an error occurs, return an SQLite error code.
70571 ** Otherwise, return SQLITE_OK and set *pRes to a negative, zero or positive
70572 ** value, depending on whether key1 is smaller, equal to or larger than key2.
70574 ** If the bOmitRowid argument is non-zero, assume both keys end in a rowid
70575 ** field. For the purposes of the comparison, ignore it. Also, if bOmitRowid
70576 ** is true and key1 contains even a single NULL value, it is considered to
70577 ** be less than key2. Even if key2 also contains NULL values.
70579 ** If pKey2 is passed a NULL pointer, then it is assumed that the pCsr->aSpace
70580 ** has been allocated and contains an unpacked record that is used as key2.
70582 static void vdbeSorterCompare(
70583 VdbeCursor *pCsr, /* Cursor object (for pKeyInfo) */
70584 int bOmitRowid, /* Ignore rowid field at end of keys */
70585 void *pKey1, int nKey1, /* Left side of comparison */
70586 void *pKey2, int nKey2, /* Right side of comparison */
70587 int *pRes /* OUT: Result of comparison */
70589 KeyInfo *pKeyInfo = pCsr->pKeyInfo;
70590 VdbeSorter *pSorter = pCsr->pSorter;
70591 UnpackedRecord *r2 = pSorter->pUnpacked;
70592 int i;
70594 if( pKey2 ){
70595 sqlite3VdbeRecordUnpack(pKeyInfo, nKey2, pKey2, r2);
70598 if( bOmitRowid ){
70599 r2->nField = pKeyInfo->nField;
70600 assert( r2->nField>0 );
70601 for(i=0; i<r2->nField; i++){
70602 if( r2->aMem[i].flags & MEM_Null ){
70603 *pRes = -1;
70604 return;
70607 r2->flags |= UNPACKED_PREFIX_MATCH;
70610 *pRes = sqlite3VdbeRecordCompare(nKey1, pKey1, r2);
70614 ** This function is called to compare two iterator keys when merging
70615 ** multiple b-tree segments. Parameter iOut is the index of the aTree[]
70616 ** value to recalculate.
70618 static int vdbeSorterDoCompare(VdbeCursor *pCsr, int iOut){
70619 VdbeSorter *pSorter = pCsr->pSorter;
70620 int i1;
70621 int i2;
70622 int iRes;
70623 VdbeSorterIter *p1;
70624 VdbeSorterIter *p2;
70626 assert( iOut<pSorter->nTree && iOut>0 );
70628 if( iOut>=(pSorter->nTree/2) ){
70629 i1 = (iOut - pSorter->nTree/2) * 2;
70630 i2 = i1 + 1;
70631 }else{
70632 i1 = pSorter->aTree[iOut*2];
70633 i2 = pSorter->aTree[iOut*2+1];
70636 p1 = &pSorter->aIter[i1];
70637 p2 = &pSorter->aIter[i2];
70639 if( p1->pFile==0 ){
70640 iRes = i2;
70641 }else if( p2->pFile==0 ){
70642 iRes = i1;
70643 }else{
70644 int res;
70645 assert( pCsr->pSorter->pUnpacked!=0 ); /* allocated in vdbeSorterMerge() */
70646 vdbeSorterCompare(
70647 pCsr, 0, p1->aKey, p1->nKey, p2->aKey, p2->nKey, &res
70649 if( res<=0 ){
70650 iRes = i1;
70651 }else{
70652 iRes = i2;
70656 pSorter->aTree[iOut] = iRes;
70657 return SQLITE_OK;
70661 ** Initialize the temporary index cursor just opened as a sorter cursor.
70663 SQLITE_PRIVATE int sqlite3VdbeSorterInit(sqlite3 *db, VdbeCursor *pCsr){
70664 int pgsz; /* Page size of main database */
70665 int mxCache; /* Cache size */
70666 VdbeSorter *pSorter; /* The new sorter */
70667 char *d; /* Dummy */
70669 assert( pCsr->pKeyInfo && pCsr->pBt==0 );
70670 pCsr->pSorter = pSorter = sqlite3DbMallocZero(db, sizeof(VdbeSorter));
70671 if( pSorter==0 ){
70672 return SQLITE_NOMEM;
70675 pSorter->pUnpacked = sqlite3VdbeAllocUnpackedRecord(pCsr->pKeyInfo, 0, 0, &d);
70676 if( pSorter->pUnpacked==0 ) return SQLITE_NOMEM;
70677 assert( pSorter->pUnpacked==(UnpackedRecord *)d );
70679 if( !sqlite3TempInMemory(db) ){
70680 pgsz = sqlite3BtreeGetPageSize(db->aDb[0].pBt);
70681 pSorter->mnPmaSize = SORTER_MIN_WORKING * pgsz;
70682 mxCache = db->aDb[0].pSchema->cache_size;
70683 if( mxCache<SORTER_MIN_WORKING ) mxCache = SORTER_MIN_WORKING;
70684 pSorter->mxPmaSize = mxCache * pgsz;
70687 return SQLITE_OK;
70691 ** Free the list of sorted records starting at pRecord.
70693 static void vdbeSorterRecordFree(sqlite3 *db, SorterRecord *pRecord){
70694 SorterRecord *p;
70695 SorterRecord *pNext;
70696 for(p=pRecord; p; p=pNext){
70697 pNext = p->pNext;
70698 sqlite3DbFree(db, p);
70703 ** Free any cursor components allocated by sqlite3VdbeSorterXXX routines.
70705 SQLITE_PRIVATE void sqlite3VdbeSorterClose(sqlite3 *db, VdbeCursor *pCsr){
70706 VdbeSorter *pSorter = pCsr->pSorter;
70707 if( pSorter ){
70708 if( pSorter->aIter ){
70709 int i;
70710 for(i=0; i<pSorter->nTree; i++){
70711 vdbeSorterIterZero(db, &pSorter->aIter[i]);
70713 sqlite3DbFree(db, pSorter->aIter);
70715 if( pSorter->pTemp1 ){
70716 sqlite3OsCloseFree(pSorter->pTemp1);
70718 vdbeSorterRecordFree(db, pSorter->pRecord);
70719 sqlite3DbFree(db, pSorter->pUnpacked);
70720 sqlite3DbFree(db, pSorter);
70721 pCsr->pSorter = 0;
70726 ** Allocate space for a file-handle and open a temporary file. If successful,
70727 ** set *ppFile to point to the malloc'd file-handle and return SQLITE_OK.
70728 ** Otherwise, set *ppFile to 0 and return an SQLite error code.
70730 static int vdbeSorterOpenTempFile(sqlite3 *db, sqlite3_file **ppFile){
70731 int dummy;
70732 return sqlite3OsOpenMalloc(db->pVfs, 0, ppFile,
70733 SQLITE_OPEN_TEMP_JOURNAL |
70734 SQLITE_OPEN_READWRITE | SQLITE_OPEN_CREATE |
70735 SQLITE_OPEN_EXCLUSIVE | SQLITE_OPEN_DELETEONCLOSE, &dummy
70740 ** Merge the two sorted lists p1 and p2 into a single list.
70741 ** Set *ppOut to the head of the new list.
70743 static void vdbeSorterMerge(
70744 VdbeCursor *pCsr, /* For pKeyInfo */
70745 SorterRecord *p1, /* First list to merge */
70746 SorterRecord *p2, /* Second list to merge */
70747 SorterRecord **ppOut /* OUT: Head of merged list */
70749 SorterRecord *pFinal = 0;
70750 SorterRecord **pp = &pFinal;
70751 void *pVal2 = p2 ? p2->pVal : 0;
70753 while( p1 && p2 ){
70754 int res;
70755 vdbeSorterCompare(pCsr, 0, p1->pVal, p1->nVal, pVal2, p2->nVal, &res);
70756 if( res<=0 ){
70757 *pp = p1;
70758 pp = &p1->pNext;
70759 p1 = p1->pNext;
70760 pVal2 = 0;
70761 }else{
70762 *pp = p2;
70763 pp = &p2->pNext;
70764 p2 = p2->pNext;
70765 if( p2==0 ) break;
70766 pVal2 = p2->pVal;
70769 *pp = p1 ? p1 : p2;
70770 *ppOut = pFinal;
70774 ** Sort the linked list of records headed at pCsr->pRecord. Return SQLITE_OK
70775 ** if successful, or an SQLite error code (i.e. SQLITE_NOMEM) if an error
70776 ** occurs.
70778 static int vdbeSorterSort(VdbeCursor *pCsr){
70779 int i;
70780 SorterRecord **aSlot;
70781 SorterRecord *p;
70782 VdbeSorter *pSorter = pCsr->pSorter;
70784 aSlot = (SorterRecord **)sqlite3MallocZero(64 * sizeof(SorterRecord *));
70785 if( !aSlot ){
70786 return SQLITE_NOMEM;
70789 p = pSorter->pRecord;
70790 while( p ){
70791 SorterRecord *pNext = p->pNext;
70792 p->pNext = 0;
70793 for(i=0; aSlot[i]; i++){
70794 vdbeSorterMerge(pCsr, p, aSlot[i], &p);
70795 aSlot[i] = 0;
70797 aSlot[i] = p;
70798 p = pNext;
70801 p = 0;
70802 for(i=0; i<64; i++){
70803 vdbeSorterMerge(pCsr, p, aSlot[i], &p);
70805 pSorter->pRecord = p;
70807 sqlite3_free(aSlot);
70808 return SQLITE_OK;
70813 ** Write the current contents of the in-memory linked-list to a PMA. Return
70814 ** SQLITE_OK if successful, or an SQLite error code otherwise.
70816 ** The format of a PMA is:
70818 ** * A varint. This varint contains the total number of bytes of content
70819 ** in the PMA (not including the varint itself).
70821 ** * One or more records packed end-to-end in order of ascending keys.
70822 ** Each record consists of a varint followed by a blob of data (the
70823 ** key). The varint is the number of bytes in the blob of data.
70825 static int vdbeSorterListToPMA(sqlite3 *db, VdbeCursor *pCsr){
70826 int rc = SQLITE_OK; /* Return code */
70827 VdbeSorter *pSorter = pCsr->pSorter;
70829 if( pSorter->nInMemory==0 ){
70830 assert( pSorter->pRecord==0 );
70831 return rc;
70834 rc = vdbeSorterSort(pCsr);
70836 /* If the first temporary PMA file has not been opened, open it now. */
70837 if( rc==SQLITE_OK && pSorter->pTemp1==0 ){
70838 rc = vdbeSorterOpenTempFile(db, &pSorter->pTemp1);
70839 assert( rc!=SQLITE_OK || pSorter->pTemp1 );
70840 assert( pSorter->iWriteOff==0 );
70841 assert( pSorter->nPMA==0 );
70844 if( rc==SQLITE_OK ){
70845 i64 iOff = pSorter->iWriteOff;
70846 SorterRecord *p;
70847 SorterRecord *pNext = 0;
70848 static const char eightZeros[8] = { 0, 0, 0, 0, 0, 0, 0, 0 };
70850 pSorter->nPMA++;
70851 rc = vdbeSorterWriteVarint(pSorter->pTemp1, pSorter->nInMemory, &iOff);
70852 for(p=pSorter->pRecord; rc==SQLITE_OK && p; p=pNext){
70853 pNext = p->pNext;
70854 rc = vdbeSorterWriteVarint(pSorter->pTemp1, p->nVal, &iOff);
70856 if( rc==SQLITE_OK ){
70857 rc = sqlite3OsWrite(pSorter->pTemp1, p->pVal, p->nVal, iOff);
70858 iOff += p->nVal;
70861 sqlite3DbFree(db, p);
70864 /* This assert verifies that unless an error has occurred, the size of
70865 ** the PMA on disk is the same as the expected size stored in
70866 ** pSorter->nInMemory. */
70867 assert( rc!=SQLITE_OK || pSorter->nInMemory==(
70868 iOff-pSorter->iWriteOff-sqlite3VarintLen(pSorter->nInMemory)
70871 pSorter->iWriteOff = iOff;
70872 if( rc==SQLITE_OK ){
70873 /* Terminate each file with 8 extra bytes so that from any offset
70874 ** in the file we can always read 9 bytes without a SHORT_READ error */
70875 rc = sqlite3OsWrite(pSorter->pTemp1, eightZeros, 8, iOff);
70877 pSorter->pRecord = p;
70880 return rc;
70884 ** Add a record to the sorter.
70886 SQLITE_PRIVATE int sqlite3VdbeSorterWrite(
70887 sqlite3 *db, /* Database handle */
70888 VdbeCursor *pCsr, /* Sorter cursor */
70889 Mem *pVal /* Memory cell containing record */
70891 VdbeSorter *pSorter = pCsr->pSorter;
70892 int rc = SQLITE_OK; /* Return Code */
70893 SorterRecord *pNew; /* New list element */
70895 assert( pSorter );
70896 pSorter->nInMemory += sqlite3VarintLen(pVal->n) + pVal->n;
70898 pNew = (SorterRecord *)sqlite3DbMallocRaw(db, pVal->n + sizeof(SorterRecord));
70899 if( pNew==0 ){
70900 rc = SQLITE_NOMEM;
70901 }else{
70902 pNew->pVal = (void *)&pNew[1];
70903 memcpy(pNew->pVal, pVal->z, pVal->n);
70904 pNew->nVal = pVal->n;
70905 pNew->pNext = pSorter->pRecord;
70906 pSorter->pRecord = pNew;
70909 /* See if the contents of the sorter should now be written out. They
70910 ** are written out when either of the following are true:
70912 ** * The total memory allocated for the in-memory list is greater
70913 ** than (page-size * cache-size), or
70915 ** * The total memory allocated for the in-memory list is greater
70916 ** than (page-size * 10) and sqlite3HeapNearlyFull() returns true.
70918 if( rc==SQLITE_OK && pSorter->mxPmaSize>0 && (
70919 (pSorter->nInMemory>pSorter->mxPmaSize)
70920 || (pSorter->nInMemory>pSorter->mnPmaSize && sqlite3HeapNearlyFull())
70922 rc = vdbeSorterListToPMA(db, pCsr);
70923 pSorter->nInMemory = 0;
70926 return rc;
70930 ** Helper function for sqlite3VdbeSorterRewind().
70932 static int vdbeSorterInitMerge(
70933 sqlite3 *db, /* Database handle */
70934 VdbeCursor *pCsr, /* Cursor handle for this sorter */
70935 i64 *pnByte /* Sum of bytes in all opened PMAs */
70937 VdbeSorter *pSorter = pCsr->pSorter;
70938 int rc = SQLITE_OK; /* Return code */
70939 int i; /* Used to iterator through aIter[] */
70940 i64 nByte = 0; /* Total bytes in all opened PMAs */
70942 /* Initialize the iterators. */
70943 for(i=0; i<SORTER_MAX_MERGE_COUNT; i++){
70944 VdbeSorterIter *pIter = &pSorter->aIter[i];
70945 rc = vdbeSorterIterInit(db, pSorter, pSorter->iReadOff, pIter, &nByte);
70946 pSorter->iReadOff = pIter->iEof;
70947 assert( rc!=SQLITE_OK || pSorter->iReadOff<=pSorter->iWriteOff );
70948 if( rc!=SQLITE_OK || pSorter->iReadOff>=pSorter->iWriteOff ) break;
70951 /* Initialize the aTree[] array. */
70952 for(i=pSorter->nTree-1; rc==SQLITE_OK && i>0; i--){
70953 rc = vdbeSorterDoCompare(pCsr, i);
70956 *pnByte = nByte;
70957 return rc;
70961 ** Once the sorter has been populated, this function is called to prepare
70962 ** for iterating through its contents in sorted order.
70964 SQLITE_PRIVATE int sqlite3VdbeSorterRewind(sqlite3 *db, VdbeCursor *pCsr, int *pbEof){
70965 VdbeSorter *pSorter = pCsr->pSorter;
70966 int rc; /* Return code */
70967 sqlite3_file *pTemp2 = 0; /* Second temp file to use */
70968 i64 iWrite2 = 0; /* Write offset for pTemp2 */
70969 int nIter; /* Number of iterators used */
70970 int nByte; /* Bytes of space required for aIter/aTree */
70971 int N = 2; /* Power of 2 >= nIter */
70973 assert( pSorter );
70975 /* If no data has been written to disk, then do not do so now. Instead,
70976 ** sort the VdbeSorter.pRecord list. The vdbe layer will read data directly
70977 ** from the in-memory list. */
70978 if( pSorter->nPMA==0 ){
70979 *pbEof = !pSorter->pRecord;
70980 assert( pSorter->aTree==0 );
70981 return vdbeSorterSort(pCsr);
70984 /* Write the current b-tree to a PMA. Close the b-tree cursor. */
70985 rc = vdbeSorterListToPMA(db, pCsr);
70986 if( rc!=SQLITE_OK ) return rc;
70988 /* Allocate space for aIter[] and aTree[]. */
70989 nIter = pSorter->nPMA;
70990 if( nIter>SORTER_MAX_MERGE_COUNT ) nIter = SORTER_MAX_MERGE_COUNT;
70991 assert( nIter>0 );
70992 while( N<nIter ) N += N;
70993 nByte = N * (sizeof(int) + sizeof(VdbeSorterIter));
70994 pSorter->aIter = (VdbeSorterIter *)sqlite3DbMallocZero(db, nByte);
70995 if( !pSorter->aIter ) return SQLITE_NOMEM;
70996 pSorter->aTree = (int *)&pSorter->aIter[N];
70997 pSorter->nTree = N;
70999 do {
71000 int iNew; /* Index of new, merged, PMA */
71002 for(iNew=0;
71003 rc==SQLITE_OK && iNew*SORTER_MAX_MERGE_COUNT<pSorter->nPMA;
71004 iNew++
71006 i64 nWrite; /* Number of bytes in new PMA */
71008 /* If there are SORTER_MAX_MERGE_COUNT or less PMAs in file pTemp1,
71009 ** initialize an iterator for each of them and break out of the loop.
71010 ** These iterators will be incrementally merged as the VDBE layer calls
71011 ** sqlite3VdbeSorterNext().
71013 ** Otherwise, if pTemp1 contains more than SORTER_MAX_MERGE_COUNT PMAs,
71014 ** initialize interators for SORTER_MAX_MERGE_COUNT of them. These PMAs
71015 ** are merged into a single PMA that is written to file pTemp2.
71017 rc = vdbeSorterInitMerge(db, pCsr, &nWrite);
71018 assert( rc!=SQLITE_OK || pSorter->aIter[ pSorter->aTree[1] ].pFile );
71019 if( rc!=SQLITE_OK || pSorter->nPMA<=SORTER_MAX_MERGE_COUNT ){
71020 break;
71023 /* Open the second temp file, if it is not already open. */
71024 if( pTemp2==0 ){
71025 assert( iWrite2==0 );
71026 rc = vdbeSorterOpenTempFile(db, &pTemp2);
71029 if( rc==SQLITE_OK ){
71030 rc = vdbeSorterWriteVarint(pTemp2, nWrite, &iWrite2);
71033 if( rc==SQLITE_OK ){
71034 int bEof = 0;
71035 while( rc==SQLITE_OK && bEof==0 ){
71036 int nToWrite;
71037 VdbeSorterIter *pIter = &pSorter->aIter[ pSorter->aTree[1] ];
71038 assert( pIter->pFile );
71039 nToWrite = pIter->nKey + sqlite3VarintLen(pIter->nKey);
71040 rc = sqlite3OsWrite(pTemp2, pIter->aAlloc, nToWrite, iWrite2);
71041 iWrite2 += nToWrite;
71042 if( rc==SQLITE_OK ){
71043 rc = sqlite3VdbeSorterNext(db, pCsr, &bEof);
71049 if( pSorter->nPMA<=SORTER_MAX_MERGE_COUNT ){
71050 break;
71051 }else{
71052 sqlite3_file *pTmp = pSorter->pTemp1;
71053 pSorter->nPMA = iNew;
71054 pSorter->pTemp1 = pTemp2;
71055 pTemp2 = pTmp;
71056 pSorter->iWriteOff = iWrite2;
71057 pSorter->iReadOff = 0;
71058 iWrite2 = 0;
71060 }while( rc==SQLITE_OK );
71062 if( pTemp2 ){
71063 sqlite3OsCloseFree(pTemp2);
71065 *pbEof = (pSorter->aIter[pSorter->aTree[1]].pFile==0);
71066 return rc;
71070 ** Advance to the next element in the sorter.
71072 SQLITE_PRIVATE int sqlite3VdbeSorterNext(sqlite3 *db, VdbeCursor *pCsr, int *pbEof){
71073 VdbeSorter *pSorter = pCsr->pSorter;
71074 int rc; /* Return code */
71076 if( pSorter->aTree ){
71077 int iPrev = pSorter->aTree[1];/* Index of iterator to advance */
71078 int i; /* Index of aTree[] to recalculate */
71080 rc = vdbeSorterIterNext(db, &pSorter->aIter[iPrev]);
71081 for(i=(pSorter->nTree+iPrev)/2; rc==SQLITE_OK && i>0; i=i/2){
71082 rc = vdbeSorterDoCompare(pCsr, i);
71085 *pbEof = (pSorter->aIter[pSorter->aTree[1]].pFile==0);
71086 }else{
71087 SorterRecord *pFree = pSorter->pRecord;
71088 pSorter->pRecord = pFree->pNext;
71089 pFree->pNext = 0;
71090 vdbeSorterRecordFree(db, pFree);
71091 *pbEof = !pSorter->pRecord;
71092 rc = SQLITE_OK;
71094 return rc;
71098 ** Return a pointer to a buffer owned by the sorter that contains the
71099 ** current key.
71101 static void *vdbeSorterRowkey(
71102 VdbeSorter *pSorter, /* Sorter object */
71103 int *pnKey /* OUT: Size of current key in bytes */
71105 void *pKey;
71106 if( pSorter->aTree ){
71107 VdbeSorterIter *pIter;
71108 pIter = &pSorter->aIter[ pSorter->aTree[1] ];
71109 *pnKey = pIter->nKey;
71110 pKey = pIter->aKey;
71111 }else{
71112 *pnKey = pSorter->pRecord->nVal;
71113 pKey = pSorter->pRecord->pVal;
71115 return pKey;
71119 ** Copy the current sorter key into the memory cell pOut.
71121 SQLITE_PRIVATE int sqlite3VdbeSorterRowkey(VdbeCursor *pCsr, Mem *pOut){
71122 VdbeSorter *pSorter = pCsr->pSorter;
71123 void *pKey; int nKey; /* Sorter key to copy into pOut */
71125 pKey = vdbeSorterRowkey(pSorter, &nKey);
71126 if( sqlite3VdbeMemGrow(pOut, nKey, 0) ){
71127 return SQLITE_NOMEM;
71129 pOut->n = nKey;
71130 MemSetTypeFlag(pOut, MEM_Blob);
71131 memcpy(pOut->z, pKey, nKey);
71133 return SQLITE_OK;
71137 ** Compare the key in memory cell pVal with the key that the sorter cursor
71138 ** passed as the first argument currently points to. For the purposes of
71139 ** the comparison, ignore the rowid field at the end of each record.
71141 ** If an error occurs, return an SQLite error code (i.e. SQLITE_NOMEM).
71142 ** Otherwise, set *pRes to a negative, zero or positive value if the
71143 ** key in pVal is smaller than, equal to or larger than the current sorter
71144 ** key.
71146 SQLITE_PRIVATE int sqlite3VdbeSorterCompare(
71147 VdbeCursor *pCsr, /* Sorter cursor */
71148 Mem *pVal, /* Value to compare to current sorter key */
71149 int *pRes /* OUT: Result of comparison */
71151 VdbeSorter *pSorter = pCsr->pSorter;
71152 void *pKey; int nKey; /* Sorter key to compare pVal with */
71154 pKey = vdbeSorterRowkey(pSorter, &nKey);
71155 vdbeSorterCompare(pCsr, 1, pVal->z, pVal->n, pKey, nKey, pRes);
71156 return SQLITE_OK;
71159 #endif /* #ifndef SQLITE_OMIT_MERGE_SORT */
71161 /************** End of vdbesort.c ********************************************/
71162 /************** Begin file journal.c *****************************************/
71164 ** 2007 August 22
71166 ** The author disclaims copyright to this source code. In place of
71167 ** a legal notice, here is a blessing:
71169 ** May you do good and not evil.
71170 ** May you find forgiveness for yourself and forgive others.
71171 ** May you share freely, never taking more than you give.
71173 *************************************************************************
71175 ** This file implements a special kind of sqlite3_file object used
71176 ** by SQLite to create journal files if the atomic-write optimization
71177 ** is enabled.
71179 ** The distinctive characteristic of this sqlite3_file is that the
71180 ** actual on disk file is created lazily. When the file is created,
71181 ** the caller specifies a buffer size for an in-memory buffer to
71182 ** be used to service read() and write() requests. The actual file
71183 ** on disk is not created or populated until either:
71185 ** 1) The in-memory representation grows too large for the allocated
71186 ** buffer, or
71187 ** 2) The sqlite3JournalCreate() function is called.
71189 #ifdef SQLITE_ENABLE_ATOMIC_WRITE
71193 ** A JournalFile object is a subclass of sqlite3_file used by
71194 ** as an open file handle for journal files.
71196 struct JournalFile {
71197 sqlite3_io_methods *pMethod; /* I/O methods on journal files */
71198 int nBuf; /* Size of zBuf[] in bytes */
71199 char *zBuf; /* Space to buffer journal writes */
71200 int iSize; /* Amount of zBuf[] currently used */
71201 int flags; /* xOpen flags */
71202 sqlite3_vfs *pVfs; /* The "real" underlying VFS */
71203 sqlite3_file *pReal; /* The "real" underlying file descriptor */
71204 const char *zJournal; /* Name of the journal file */
71206 typedef struct JournalFile JournalFile;
71209 ** If it does not already exists, create and populate the on-disk file
71210 ** for JournalFile p.
71212 static int createFile(JournalFile *p){
71213 int rc = SQLITE_OK;
71214 if( !p->pReal ){
71215 sqlite3_file *pReal = (sqlite3_file *)&p[1];
71216 rc = sqlite3OsOpen(p->pVfs, p->zJournal, pReal, p->flags, 0);
71217 if( rc==SQLITE_OK ){
71218 p->pReal = pReal;
71219 if( p->iSize>0 ){
71220 assert(p->iSize<=p->nBuf);
71221 rc = sqlite3OsWrite(p->pReal, p->zBuf, p->iSize, 0);
71225 return rc;
71229 ** Close the file.
71231 static int jrnlClose(sqlite3_file *pJfd){
71232 JournalFile *p = (JournalFile *)pJfd;
71233 if( p->pReal ){
71234 sqlite3OsClose(p->pReal);
71236 sqlite3_free(p->zBuf);
71237 return SQLITE_OK;
71241 ** Read data from the file.
71243 static int jrnlRead(
71244 sqlite3_file *pJfd, /* The journal file from which to read */
71245 void *zBuf, /* Put the results here */
71246 int iAmt, /* Number of bytes to read */
71247 sqlite_int64 iOfst /* Begin reading at this offset */
71249 int rc = SQLITE_OK;
71250 JournalFile *p = (JournalFile *)pJfd;
71251 if( p->pReal ){
71252 rc = sqlite3OsRead(p->pReal, zBuf, iAmt, iOfst);
71253 }else if( (iAmt+iOfst)>p->iSize ){
71254 rc = SQLITE_IOERR_SHORT_READ;
71255 }else{
71256 memcpy(zBuf, &p->zBuf[iOfst], iAmt);
71258 return rc;
71262 ** Write data to the file.
71264 static int jrnlWrite(
71265 sqlite3_file *pJfd, /* The journal file into which to write */
71266 const void *zBuf, /* Take data to be written from here */
71267 int iAmt, /* Number of bytes to write */
71268 sqlite_int64 iOfst /* Begin writing at this offset into the file */
71270 int rc = SQLITE_OK;
71271 JournalFile *p = (JournalFile *)pJfd;
71272 if( !p->pReal && (iOfst+iAmt)>p->nBuf ){
71273 rc = createFile(p);
71275 if( rc==SQLITE_OK ){
71276 if( p->pReal ){
71277 rc = sqlite3OsWrite(p->pReal, zBuf, iAmt, iOfst);
71278 }else{
71279 memcpy(&p->zBuf[iOfst], zBuf, iAmt);
71280 if( p->iSize<(iOfst+iAmt) ){
71281 p->iSize = (iOfst+iAmt);
71285 return rc;
71289 ** Truncate the file.
71291 static int jrnlTruncate(sqlite3_file *pJfd, sqlite_int64 size){
71292 int rc = SQLITE_OK;
71293 JournalFile *p = (JournalFile *)pJfd;
71294 if( p->pReal ){
71295 rc = sqlite3OsTruncate(p->pReal, size);
71296 }else if( size<p->iSize ){
71297 p->iSize = size;
71299 return rc;
71303 ** Sync the file.
71305 static int jrnlSync(sqlite3_file *pJfd, int flags){
71306 int rc;
71307 JournalFile *p = (JournalFile *)pJfd;
71308 if( p->pReal ){
71309 rc = sqlite3OsSync(p->pReal, flags);
71310 }else{
71311 rc = SQLITE_OK;
71313 return rc;
71317 ** Query the size of the file in bytes.
71319 static int jrnlFileSize(sqlite3_file *pJfd, sqlite_int64 *pSize){
71320 int rc = SQLITE_OK;
71321 JournalFile *p = (JournalFile *)pJfd;
71322 if( p->pReal ){
71323 rc = sqlite3OsFileSize(p->pReal, pSize);
71324 }else{
71325 *pSize = (sqlite_int64) p->iSize;
71327 return rc;
71331 ** Table of methods for JournalFile sqlite3_file object.
71333 static struct sqlite3_io_methods JournalFileMethods = {
71334 1, /* iVersion */
71335 jrnlClose, /* xClose */
71336 jrnlRead, /* xRead */
71337 jrnlWrite, /* xWrite */
71338 jrnlTruncate, /* xTruncate */
71339 jrnlSync, /* xSync */
71340 jrnlFileSize, /* xFileSize */
71341 0, /* xLock */
71342 0, /* xUnlock */
71343 0, /* xCheckReservedLock */
71344 0, /* xFileControl */
71345 0, /* xSectorSize */
71346 0, /* xDeviceCharacteristics */
71347 0, /* xShmMap */
71348 0, /* xShmLock */
71349 0, /* xShmBarrier */
71350 0 /* xShmUnmap */
71354 ** Open a journal file.
71356 SQLITE_PRIVATE int sqlite3JournalOpen(
71357 sqlite3_vfs *pVfs, /* The VFS to use for actual file I/O */
71358 const char *zName, /* Name of the journal file */
71359 sqlite3_file *pJfd, /* Preallocated, blank file handle */
71360 int flags, /* Opening flags */
71361 int nBuf /* Bytes buffered before opening the file */
71363 JournalFile *p = (JournalFile *)pJfd;
71364 memset(p, 0, sqlite3JournalSize(pVfs));
71365 if( nBuf>0 ){
71366 p->zBuf = sqlite3MallocZero(nBuf);
71367 if( !p->zBuf ){
71368 return SQLITE_NOMEM;
71370 }else{
71371 return sqlite3OsOpen(pVfs, zName, pJfd, flags, 0);
71373 p->pMethod = &JournalFileMethods;
71374 p->nBuf = nBuf;
71375 p->flags = flags;
71376 p->zJournal = zName;
71377 p->pVfs = pVfs;
71378 return SQLITE_OK;
71382 ** If the argument p points to a JournalFile structure, and the underlying
71383 ** file has not yet been created, create it now.
71385 SQLITE_PRIVATE int sqlite3JournalCreate(sqlite3_file *p){
71386 if( p->pMethods!=&JournalFileMethods ){
71387 return SQLITE_OK;
71389 return createFile((JournalFile *)p);
71393 ** Return the number of bytes required to store a JournalFile that uses vfs
71394 ** pVfs to create the underlying on-disk files.
71396 SQLITE_PRIVATE int sqlite3JournalSize(sqlite3_vfs *pVfs){
71397 return (pVfs->szOsFile+sizeof(JournalFile));
71399 #endif
71401 /************** End of journal.c *********************************************/
71402 /************** Begin file memjournal.c **************************************/
71404 ** 2008 October 7
71406 ** The author disclaims copyright to this source code. In place of
71407 ** a legal notice, here is a blessing:
71409 ** May you do good and not evil.
71410 ** May you find forgiveness for yourself and forgive others.
71411 ** May you share freely, never taking more than you give.
71413 *************************************************************************
71415 ** This file contains code use to implement an in-memory rollback journal.
71416 ** The in-memory rollback journal is used to journal transactions for
71417 ** ":memory:" databases and when the journal_mode=MEMORY pragma is used.
71420 /* Forward references to internal structures */
71421 typedef struct MemJournal MemJournal;
71422 typedef struct FilePoint FilePoint;
71423 typedef struct FileChunk FileChunk;
71425 /* Space to hold the rollback journal is allocated in increments of
71426 ** this many bytes.
71428 ** The size chosen is a little less than a power of two. That way,
71429 ** the FileChunk object will have a size that almost exactly fills
71430 ** a power-of-two allocation. This mimimizes wasted space in power-of-two
71431 ** memory allocators.
71433 #define JOURNAL_CHUNKSIZE ((int)(1024-sizeof(FileChunk*)))
71435 /* Macro to find the minimum of two numeric values.
71437 #ifndef MIN
71438 # define MIN(x,y) ((x)<(y)?(x):(y))
71439 #endif
71442 ** The rollback journal is composed of a linked list of these structures.
71444 struct FileChunk {
71445 FileChunk *pNext; /* Next chunk in the journal */
71446 u8 zChunk[JOURNAL_CHUNKSIZE]; /* Content of this chunk */
71450 ** An instance of this object serves as a cursor into the rollback journal.
71451 ** The cursor can be either for reading or writing.
71453 struct FilePoint {
71454 sqlite3_int64 iOffset; /* Offset from the beginning of the file */
71455 FileChunk *pChunk; /* Specific chunk into which cursor points */
71459 ** This subclass is a subclass of sqlite3_file. Each open memory-journal
71460 ** is an instance of this class.
71462 struct MemJournal {
71463 sqlite3_io_methods *pMethod; /* Parent class. MUST BE FIRST */
71464 FileChunk *pFirst; /* Head of in-memory chunk-list */
71465 FilePoint endpoint; /* Pointer to the end of the file */
71466 FilePoint readpoint; /* Pointer to the end of the last xRead() */
71470 ** Read data from the in-memory journal file. This is the implementation
71471 ** of the sqlite3_vfs.xRead method.
71473 static int memjrnlRead(
71474 sqlite3_file *pJfd, /* The journal file from which to read */
71475 void *zBuf, /* Put the results here */
71476 int iAmt, /* Number of bytes to read */
71477 sqlite_int64 iOfst /* Begin reading at this offset */
71479 MemJournal *p = (MemJournal *)pJfd;
71480 u8 *zOut = zBuf;
71481 int nRead = iAmt;
71482 int iChunkOffset;
71483 FileChunk *pChunk;
71485 /* SQLite never tries to read past the end of a rollback journal file */
71486 assert( iOfst+iAmt<=p->endpoint.iOffset );
71488 if( p->readpoint.iOffset!=iOfst || iOfst==0 ){
71489 sqlite3_int64 iOff = 0;
71490 for(pChunk=p->pFirst;
71491 ALWAYS(pChunk) && (iOff+JOURNAL_CHUNKSIZE)<=iOfst;
71492 pChunk=pChunk->pNext
71494 iOff += JOURNAL_CHUNKSIZE;
71496 }else{
71497 pChunk = p->readpoint.pChunk;
71500 iChunkOffset = (int)(iOfst%JOURNAL_CHUNKSIZE);
71501 do {
71502 int iSpace = JOURNAL_CHUNKSIZE - iChunkOffset;
71503 int nCopy = MIN(nRead, (JOURNAL_CHUNKSIZE - iChunkOffset));
71504 memcpy(zOut, &pChunk->zChunk[iChunkOffset], nCopy);
71505 zOut += nCopy;
71506 nRead -= iSpace;
71507 iChunkOffset = 0;
71508 } while( nRead>=0 && (pChunk=pChunk->pNext)!=0 && nRead>0 );
71509 p->readpoint.iOffset = iOfst+iAmt;
71510 p->readpoint.pChunk = pChunk;
71512 return SQLITE_OK;
71516 ** Write data to the file.
71518 static int memjrnlWrite(
71519 sqlite3_file *pJfd, /* The journal file into which to write */
71520 const void *zBuf, /* Take data to be written from here */
71521 int iAmt, /* Number of bytes to write */
71522 sqlite_int64 iOfst /* Begin writing at this offset into the file */
71524 MemJournal *p = (MemJournal *)pJfd;
71525 int nWrite = iAmt;
71526 u8 *zWrite = (u8 *)zBuf;
71528 /* An in-memory journal file should only ever be appended to. Random
71529 ** access writes are not required by sqlite.
71531 assert( iOfst==p->endpoint.iOffset );
71532 UNUSED_PARAMETER(iOfst);
71534 while( nWrite>0 ){
71535 FileChunk *pChunk = p->endpoint.pChunk;
71536 int iChunkOffset = (int)(p->endpoint.iOffset%JOURNAL_CHUNKSIZE);
71537 int iSpace = MIN(nWrite, JOURNAL_CHUNKSIZE - iChunkOffset);
71539 if( iChunkOffset==0 ){
71540 /* New chunk is required to extend the file. */
71541 FileChunk *pNew = sqlite3_malloc(sizeof(FileChunk));
71542 if( !pNew ){
71543 return SQLITE_IOERR_NOMEM;
71545 pNew->pNext = 0;
71546 if( pChunk ){
71547 assert( p->pFirst );
71548 pChunk->pNext = pNew;
71549 }else{
71550 assert( !p->pFirst );
71551 p->pFirst = pNew;
71553 p->endpoint.pChunk = pNew;
71556 memcpy(&p->endpoint.pChunk->zChunk[iChunkOffset], zWrite, iSpace);
71557 zWrite += iSpace;
71558 nWrite -= iSpace;
71559 p->endpoint.iOffset += iSpace;
71562 return SQLITE_OK;
71566 ** Truncate the file.
71568 static int memjrnlTruncate(sqlite3_file *pJfd, sqlite_int64 size){
71569 MemJournal *p = (MemJournal *)pJfd;
71570 FileChunk *pChunk;
71571 assert(size==0);
71572 UNUSED_PARAMETER(size);
71573 pChunk = p->pFirst;
71574 while( pChunk ){
71575 FileChunk *pTmp = pChunk;
71576 pChunk = pChunk->pNext;
71577 sqlite3_free(pTmp);
71579 sqlite3MemJournalOpen(pJfd);
71580 return SQLITE_OK;
71584 ** Close the file.
71586 static int memjrnlClose(sqlite3_file *pJfd){
71587 memjrnlTruncate(pJfd, 0);
71588 return SQLITE_OK;
71593 ** Sync the file.
71595 ** Syncing an in-memory journal is a no-op. And, in fact, this routine
71596 ** is never called in a working implementation. This implementation
71597 ** exists purely as a contingency, in case some malfunction in some other
71598 ** part of SQLite causes Sync to be called by mistake.
71600 static int memjrnlSync(sqlite3_file *NotUsed, int NotUsed2){
71601 UNUSED_PARAMETER2(NotUsed, NotUsed2);
71602 return SQLITE_OK;
71606 ** Query the size of the file in bytes.
71608 static int memjrnlFileSize(sqlite3_file *pJfd, sqlite_int64 *pSize){
71609 MemJournal *p = (MemJournal *)pJfd;
71610 *pSize = (sqlite_int64) p->endpoint.iOffset;
71611 return SQLITE_OK;
71615 ** Table of methods for MemJournal sqlite3_file object.
71617 static const struct sqlite3_io_methods MemJournalMethods = {
71618 1, /* iVersion */
71619 memjrnlClose, /* xClose */
71620 memjrnlRead, /* xRead */
71621 memjrnlWrite, /* xWrite */
71622 memjrnlTruncate, /* xTruncate */
71623 memjrnlSync, /* xSync */
71624 memjrnlFileSize, /* xFileSize */
71625 0, /* xLock */
71626 0, /* xUnlock */
71627 0, /* xCheckReservedLock */
71628 0, /* xFileControl */
71629 0, /* xSectorSize */
71630 0, /* xDeviceCharacteristics */
71631 0, /* xShmMap */
71632 0, /* xShmLock */
71633 0, /* xShmBarrier */
71634 0 /* xShmUnlock */
71638 ** Open a journal file.
71640 SQLITE_PRIVATE void sqlite3MemJournalOpen(sqlite3_file *pJfd){
71641 MemJournal *p = (MemJournal *)pJfd;
71642 assert( EIGHT_BYTE_ALIGNMENT(p) );
71643 memset(p, 0, sqlite3MemJournalSize());
71644 p->pMethod = (sqlite3_io_methods*)&MemJournalMethods;
71648 ** Return true if the file-handle passed as an argument is
71649 ** an in-memory journal
71651 SQLITE_PRIVATE int sqlite3IsMemJournal(sqlite3_file *pJfd){
71652 return pJfd->pMethods==&MemJournalMethods;
71656 ** Return the number of bytes required to store a MemJournal file descriptor.
71658 SQLITE_PRIVATE int sqlite3MemJournalSize(void){
71659 return sizeof(MemJournal);
71662 /************** End of memjournal.c ******************************************/
71663 /************** Begin file walker.c ******************************************/
71665 ** 2008 August 16
71667 ** The author disclaims copyright to this source code. In place of
71668 ** a legal notice, here is a blessing:
71670 ** May you do good and not evil.
71671 ** May you find forgiveness for yourself and forgive others.
71672 ** May you share freely, never taking more than you give.
71674 *************************************************************************
71675 ** This file contains routines used for walking the parser tree for
71676 ** an SQL statement.
71678 /* #include <stdlib.h> */
71679 /* #include <string.h> */
71683 ** Walk an expression tree. Invoke the callback once for each node
71684 ** of the expression, while decending. (In other words, the callback
71685 ** is invoked before visiting children.)
71687 ** The return value from the callback should be one of the WRC_*
71688 ** constants to specify how to proceed with the walk.
71690 ** WRC_Continue Continue descending down the tree.
71692 ** WRC_Prune Do not descend into child nodes. But allow
71693 ** the walk to continue with sibling nodes.
71695 ** WRC_Abort Do no more callbacks. Unwind the stack and
71696 ** return the top-level walk call.
71698 ** The return value from this routine is WRC_Abort to abandon the tree walk
71699 ** and WRC_Continue to continue.
71701 SQLITE_PRIVATE int sqlite3WalkExpr(Walker *pWalker, Expr *pExpr){
71702 int rc;
71703 if( pExpr==0 ) return WRC_Continue;
71704 testcase( ExprHasProperty(pExpr, EP_TokenOnly) );
71705 testcase( ExprHasProperty(pExpr, EP_Reduced) );
71706 rc = pWalker->xExprCallback(pWalker, pExpr);
71707 if( rc==WRC_Continue
71708 && !ExprHasAnyProperty(pExpr,EP_TokenOnly) ){
71709 if( sqlite3WalkExpr(pWalker, pExpr->pLeft) ) return WRC_Abort;
71710 if( sqlite3WalkExpr(pWalker, pExpr->pRight) ) return WRC_Abort;
71711 if( ExprHasProperty(pExpr, EP_xIsSelect) ){
71712 if( sqlite3WalkSelect(pWalker, pExpr->x.pSelect) ) return WRC_Abort;
71713 }else{
71714 if( sqlite3WalkExprList(pWalker, pExpr->x.pList) ) return WRC_Abort;
71717 return rc & WRC_Abort;
71721 ** Call sqlite3WalkExpr() for every expression in list p or until
71722 ** an abort request is seen.
71724 SQLITE_PRIVATE int sqlite3WalkExprList(Walker *pWalker, ExprList *p){
71725 int i;
71726 struct ExprList_item *pItem;
71727 if( p ){
71728 for(i=p->nExpr, pItem=p->a; i>0; i--, pItem++){
71729 if( sqlite3WalkExpr(pWalker, pItem->pExpr) ) return WRC_Abort;
71732 return WRC_Continue;
71736 ** Walk all expressions associated with SELECT statement p. Do
71737 ** not invoke the SELECT callback on p, but do (of course) invoke
71738 ** any expr callbacks and SELECT callbacks that come from subqueries.
71739 ** Return WRC_Abort or WRC_Continue.
71741 SQLITE_PRIVATE int sqlite3WalkSelectExpr(Walker *pWalker, Select *p){
71742 if( sqlite3WalkExprList(pWalker, p->pEList) ) return WRC_Abort;
71743 if( sqlite3WalkExpr(pWalker, p->pWhere) ) return WRC_Abort;
71744 if( sqlite3WalkExprList(pWalker, p->pGroupBy) ) return WRC_Abort;
71745 if( sqlite3WalkExpr(pWalker, p->pHaving) ) return WRC_Abort;
71746 if( sqlite3WalkExprList(pWalker, p->pOrderBy) ) return WRC_Abort;
71747 if( sqlite3WalkExpr(pWalker, p->pLimit) ) return WRC_Abort;
71748 if( sqlite3WalkExpr(pWalker, p->pOffset) ) return WRC_Abort;
71749 return WRC_Continue;
71753 ** Walk the parse trees associated with all subqueries in the
71754 ** FROM clause of SELECT statement p. Do not invoke the select
71755 ** callback on p, but do invoke it on each FROM clause subquery
71756 ** and on any subqueries further down in the tree. Return
71757 ** WRC_Abort or WRC_Continue;
71759 SQLITE_PRIVATE int sqlite3WalkSelectFrom(Walker *pWalker, Select *p){
71760 SrcList *pSrc;
71761 int i;
71762 struct SrcList_item *pItem;
71764 pSrc = p->pSrc;
71765 if( ALWAYS(pSrc) ){
71766 for(i=pSrc->nSrc, pItem=pSrc->a; i>0; i--, pItem++){
71767 if( sqlite3WalkSelect(pWalker, pItem->pSelect) ){
71768 return WRC_Abort;
71772 return WRC_Continue;
71776 ** Call sqlite3WalkExpr() for every expression in Select statement p.
71777 ** Invoke sqlite3WalkSelect() for subqueries in the FROM clause and
71778 ** on the compound select chain, p->pPrior.
71780 ** Return WRC_Continue under normal conditions. Return WRC_Abort if
71781 ** there is an abort request.
71783 ** If the Walker does not have an xSelectCallback() then this routine
71784 ** is a no-op returning WRC_Continue.
71786 SQLITE_PRIVATE int sqlite3WalkSelect(Walker *pWalker, Select *p){
71787 int rc;
71788 if( p==0 || pWalker->xSelectCallback==0 ) return WRC_Continue;
71789 rc = WRC_Continue;
71790 while( p ){
71791 rc = pWalker->xSelectCallback(pWalker, p);
71792 if( rc ) break;
71793 if( sqlite3WalkSelectExpr(pWalker, p) ) return WRC_Abort;
71794 if( sqlite3WalkSelectFrom(pWalker, p) ) return WRC_Abort;
71795 p = p->pPrior;
71797 return rc & WRC_Abort;
71800 /************** End of walker.c **********************************************/
71801 /************** Begin file resolve.c *****************************************/
71803 ** 2008 August 18
71805 ** The author disclaims copyright to this source code. In place of
71806 ** a legal notice, here is a blessing:
71808 ** May you do good and not evil.
71809 ** May you find forgiveness for yourself and forgive others.
71810 ** May you share freely, never taking more than you give.
71812 *************************************************************************
71814 ** This file contains routines used for walking the parser tree and
71815 ** resolve all identifiers by associating them with a particular
71816 ** table and column.
71818 /* #include <stdlib.h> */
71819 /* #include <string.h> */
71822 ** Turn the pExpr expression into an alias for the iCol-th column of the
71823 ** result set in pEList.
71825 ** If the result set column is a simple column reference, then this routine
71826 ** makes an exact copy. But for any other kind of expression, this
71827 ** routine make a copy of the result set column as the argument to the
71828 ** TK_AS operator. The TK_AS operator causes the expression to be
71829 ** evaluated just once and then reused for each alias.
71831 ** The reason for suppressing the TK_AS term when the expression is a simple
71832 ** column reference is so that the column reference will be recognized as
71833 ** usable by indices within the WHERE clause processing logic.
71835 ** Hack: The TK_AS operator is inhibited if zType[0]=='G'. This means
71836 ** that in a GROUP BY clause, the expression is evaluated twice. Hence:
71838 ** SELECT random()%5 AS x, count(*) FROM tab GROUP BY x
71840 ** Is equivalent to:
71842 ** SELECT random()%5 AS x, count(*) FROM tab GROUP BY random()%5
71844 ** The result of random()%5 in the GROUP BY clause is probably different
71845 ** from the result in the result-set. We might fix this someday. Or
71846 ** then again, we might not...
71848 static void resolveAlias(
71849 Parse *pParse, /* Parsing context */
71850 ExprList *pEList, /* A result set */
71851 int iCol, /* A column in the result set. 0..pEList->nExpr-1 */
71852 Expr *pExpr, /* Transform this into an alias to the result set */
71853 const char *zType /* "GROUP" or "ORDER" or "" */
71855 Expr *pOrig; /* The iCol-th column of the result set */
71856 Expr *pDup; /* Copy of pOrig */
71857 sqlite3 *db; /* The database connection */
71859 assert( iCol>=0 && iCol<pEList->nExpr );
71860 pOrig = pEList->a[iCol].pExpr;
71861 assert( pOrig!=0 );
71862 assert( pOrig->flags & EP_Resolved );
71863 db = pParse->db;
71864 if( pOrig->op!=TK_COLUMN && zType[0]!='G' ){
71865 pDup = sqlite3ExprDup(db, pOrig, 0);
71866 pDup = sqlite3PExpr(pParse, TK_AS, pDup, 0, 0);
71867 if( pDup==0 ) return;
71868 if( pEList->a[iCol].iAlias==0 ){
71869 pEList->a[iCol].iAlias = (u16)(++pParse->nAlias);
71871 pDup->iTable = pEList->a[iCol].iAlias;
71872 }else if( ExprHasProperty(pOrig, EP_IntValue) || pOrig->u.zToken==0 ){
71873 pDup = sqlite3ExprDup(db, pOrig, 0);
71874 if( pDup==0 ) return;
71875 }else{
71876 char *zToken = pOrig->u.zToken;
71877 assert( zToken!=0 );
71878 pOrig->u.zToken = 0;
71879 pDup = sqlite3ExprDup(db, pOrig, 0);
71880 pOrig->u.zToken = zToken;
71881 if( pDup==0 ) return;
71882 assert( (pDup->flags & (EP_Reduced|EP_TokenOnly))==0 );
71883 pDup->flags2 |= EP2_MallocedToken;
71884 pDup->u.zToken = sqlite3DbStrDup(db, zToken);
71886 if( pExpr->flags & EP_ExpCollate ){
71887 pDup->pColl = pExpr->pColl;
71888 pDup->flags |= EP_ExpCollate;
71891 /* Before calling sqlite3ExprDelete(), set the EP_Static flag. This
71892 ** prevents ExprDelete() from deleting the Expr structure itself,
71893 ** allowing it to be repopulated by the memcpy() on the following line.
71895 ExprSetProperty(pExpr, EP_Static);
71896 sqlite3ExprDelete(db, pExpr);
71897 memcpy(pExpr, pDup, sizeof(*pExpr));
71898 sqlite3DbFree(db, pDup);
71902 ** Given the name of a column of the form X.Y.Z or Y.Z or just Z, look up
71903 ** that name in the set of source tables in pSrcList and make the pExpr
71904 ** expression node refer back to that source column. The following changes
71905 ** are made to pExpr:
71907 ** pExpr->iDb Set the index in db->aDb[] of the database X
71908 ** (even if X is implied).
71909 ** pExpr->iTable Set to the cursor number for the table obtained
71910 ** from pSrcList.
71911 ** pExpr->pTab Points to the Table structure of X.Y (even if
71912 ** X and/or Y are implied.)
71913 ** pExpr->iColumn Set to the column number within the table.
71914 ** pExpr->op Set to TK_COLUMN.
71915 ** pExpr->pLeft Any expression this points to is deleted
71916 ** pExpr->pRight Any expression this points to is deleted.
71918 ** The zDb variable is the name of the database (the "X"). This value may be
71919 ** NULL meaning that name is of the form Y.Z or Z. Any available database
71920 ** can be used. The zTable variable is the name of the table (the "Y"). This
71921 ** value can be NULL if zDb is also NULL. If zTable is NULL it
71922 ** means that the form of the name is Z and that columns from any table
71923 ** can be used.
71925 ** If the name cannot be resolved unambiguously, leave an error message
71926 ** in pParse and return WRC_Abort. Return WRC_Prune on success.
71928 static int lookupName(
71929 Parse *pParse, /* The parsing context */
71930 const char *zDb, /* Name of the database containing table, or NULL */
71931 const char *zTab, /* Name of table containing column, or NULL */
71932 const char *zCol, /* Name of the column. */
71933 NameContext *pNC, /* The name context used to resolve the name */
71934 Expr *pExpr /* Make this EXPR node point to the selected column */
71936 int i, j; /* Loop counters */
71937 int cnt = 0; /* Number of matching column names */
71938 int cntTab = 0; /* Number of matching table names */
71939 sqlite3 *db = pParse->db; /* The database connection */
71940 struct SrcList_item *pItem; /* Use for looping over pSrcList items */
71941 struct SrcList_item *pMatch = 0; /* The matching pSrcList item */
71942 NameContext *pTopNC = pNC; /* First namecontext in the list */
71943 Schema *pSchema = 0; /* Schema of the expression */
71944 int isTrigger = 0;
71946 assert( pNC ); /* the name context cannot be NULL. */
71947 assert( zCol ); /* The Z in X.Y.Z cannot be NULL */
71948 assert( ~ExprHasAnyProperty(pExpr, EP_TokenOnly|EP_Reduced) );
71950 /* Initialize the node to no-match */
71951 pExpr->iTable = -1;
71952 pExpr->pTab = 0;
71953 ExprSetIrreducible(pExpr);
71955 /* Start at the inner-most context and move outward until a match is found */
71956 while( pNC && cnt==0 ){
71957 ExprList *pEList;
71958 SrcList *pSrcList = pNC->pSrcList;
71960 if( pSrcList ){
71961 for(i=0, pItem=pSrcList->a; i<pSrcList->nSrc; i++, pItem++){
71962 Table *pTab;
71963 int iDb;
71964 Column *pCol;
71966 pTab = pItem->pTab;
71967 assert( pTab!=0 && pTab->zName!=0 );
71968 iDb = sqlite3SchemaToIndex(db, pTab->pSchema);
71969 assert( pTab->nCol>0 );
71970 if( zTab ){
71971 if( pItem->zAlias ){
71972 char *zTabName = pItem->zAlias;
71973 if( sqlite3StrICmp(zTabName, zTab)!=0 ) continue;
71974 }else{
71975 char *zTabName = pTab->zName;
71976 if( NEVER(zTabName==0) || sqlite3StrICmp(zTabName, zTab)!=0 ){
71977 continue;
71979 if( zDb!=0 && sqlite3StrICmp(db->aDb[iDb].zName, zDb)!=0 ){
71980 continue;
71984 if( 0==(cntTab++) ){
71985 pExpr->iTable = pItem->iCursor;
71986 pExpr->pTab = pTab;
71987 pSchema = pTab->pSchema;
71988 pMatch = pItem;
71990 for(j=0, pCol=pTab->aCol; j<pTab->nCol; j++, pCol++){
71991 if( sqlite3StrICmp(pCol->zName, zCol)==0 ){
71992 IdList *pUsing;
71993 cnt++;
71994 pExpr->iTable = pItem->iCursor;
71995 pExpr->pTab = pTab;
71996 pMatch = pItem;
71997 pSchema = pTab->pSchema;
71998 /* Substitute the rowid (column -1) for the INTEGER PRIMARY KEY */
71999 pExpr->iColumn = j==pTab->iPKey ? -1 : (i16)j;
72000 if( i<pSrcList->nSrc-1 ){
72001 if( pItem[1].jointype & JT_NATURAL ){
72002 /* If this match occurred in the left table of a natural join,
72003 ** then skip the right table to avoid a duplicate match */
72004 pItem++;
72005 i++;
72006 }else if( (pUsing = pItem[1].pUsing)!=0 ){
72007 /* If this match occurs on a column that is in the USING clause
72008 ** of a join, skip the search of the right table of the join
72009 ** to avoid a duplicate match there. */
72010 int k;
72011 for(k=0; k<pUsing->nId; k++){
72012 if( sqlite3StrICmp(pUsing->a[k].zName, zCol)==0 ){
72013 pItem++;
72014 i++;
72015 break;
72020 break;
72026 #ifndef SQLITE_OMIT_TRIGGER
72027 /* If we have not already resolved the name, then maybe
72028 ** it is a new.* or old.* trigger argument reference
72030 if( zDb==0 && zTab!=0 && cnt==0 && pParse->pTriggerTab!=0 ){
72031 int op = pParse->eTriggerOp;
72032 Table *pTab = 0;
72033 assert( op==TK_DELETE || op==TK_UPDATE || op==TK_INSERT );
72034 if( op!=TK_DELETE && sqlite3StrICmp("new",zTab) == 0 ){
72035 pExpr->iTable = 1;
72036 pTab = pParse->pTriggerTab;
72037 }else if( op!=TK_INSERT && sqlite3StrICmp("old",zTab)==0 ){
72038 pExpr->iTable = 0;
72039 pTab = pParse->pTriggerTab;
72042 if( pTab ){
72043 int iCol;
72044 pSchema = pTab->pSchema;
72045 cntTab++;
72046 for(iCol=0; iCol<pTab->nCol; iCol++){
72047 Column *pCol = &pTab->aCol[iCol];
72048 if( sqlite3StrICmp(pCol->zName, zCol)==0 ){
72049 if( iCol==pTab->iPKey ){
72050 iCol = -1;
72052 break;
72055 if( iCol>=pTab->nCol && sqlite3IsRowid(zCol) ){
72056 iCol = -1; /* IMP: R-44911-55124 */
72058 if( iCol<pTab->nCol ){
72059 cnt++;
72060 if( iCol<0 ){
72061 pExpr->affinity = SQLITE_AFF_INTEGER;
72062 }else if( pExpr->iTable==0 ){
72063 testcase( iCol==31 );
72064 testcase( iCol==32 );
72065 pParse->oldmask |= (iCol>=32 ? 0xffffffff : (((u32)1)<<iCol));
72066 }else{
72067 testcase( iCol==31 );
72068 testcase( iCol==32 );
72069 pParse->newmask |= (iCol>=32 ? 0xffffffff : (((u32)1)<<iCol));
72071 pExpr->iColumn = (i16)iCol;
72072 pExpr->pTab = pTab;
72073 isTrigger = 1;
72077 #endif /* !defined(SQLITE_OMIT_TRIGGER) */
72080 ** Perhaps the name is a reference to the ROWID
72082 if( cnt==0 && cntTab==1 && sqlite3IsRowid(zCol) ){
72083 cnt = 1;
72084 pExpr->iColumn = -1; /* IMP: R-44911-55124 */
72085 pExpr->affinity = SQLITE_AFF_INTEGER;
72089 ** If the input is of the form Z (not Y.Z or X.Y.Z) then the name Z
72090 ** might refer to an result-set alias. This happens, for example, when
72091 ** we are resolving names in the WHERE clause of the following command:
72093 ** SELECT a+b AS x FROM table WHERE x<10;
72095 ** In cases like this, replace pExpr with a copy of the expression that
72096 ** forms the result set entry ("a+b" in the example) and return immediately.
72097 ** Note that the expression in the result set should have already been
72098 ** resolved by the time the WHERE clause is resolved.
72100 if( cnt==0 && (pEList = pNC->pEList)!=0 && zTab==0 ){
72101 for(j=0; j<pEList->nExpr; j++){
72102 char *zAs = pEList->a[j].zName;
72103 if( zAs!=0 && sqlite3StrICmp(zAs, zCol)==0 ){
72104 Expr *pOrig;
72105 assert( pExpr->pLeft==0 && pExpr->pRight==0 );
72106 assert( pExpr->x.pList==0 );
72107 assert( pExpr->x.pSelect==0 );
72108 pOrig = pEList->a[j].pExpr;
72109 if( !pNC->allowAgg && ExprHasProperty(pOrig, EP_Agg) ){
72110 sqlite3ErrorMsg(pParse, "misuse of aliased aggregate %s", zAs);
72111 return WRC_Abort;
72113 resolveAlias(pParse, pEList, j, pExpr, "");
72114 cnt = 1;
72115 pMatch = 0;
72116 assert( zTab==0 && zDb==0 );
72117 goto lookupname_end;
72122 /* Advance to the next name context. The loop will exit when either
72123 ** we have a match (cnt>0) or when we run out of name contexts.
72125 if( cnt==0 ){
72126 pNC = pNC->pNext;
72131 ** If X and Y are NULL (in other words if only the column name Z is
72132 ** supplied) and the value of Z is enclosed in double-quotes, then
72133 ** Z is a string literal if it doesn't match any column names. In that
72134 ** case, we need to return right away and not make any changes to
72135 ** pExpr.
72137 ** Because no reference was made to outer contexts, the pNC->nRef
72138 ** fields are not changed in any context.
72140 if( cnt==0 && zTab==0 && ExprHasProperty(pExpr,EP_DblQuoted) ){
72141 pExpr->op = TK_STRING;
72142 pExpr->pTab = 0;
72143 return WRC_Prune;
72147 ** cnt==0 means there was not match. cnt>1 means there were two or
72148 ** more matches. Either way, we have an error.
72150 if( cnt!=1 ){
72151 const char *zErr;
72152 zErr = cnt==0 ? "no such column" : "ambiguous column name";
72153 if( zDb ){
72154 sqlite3ErrorMsg(pParse, "%s: %s.%s.%s", zErr, zDb, zTab, zCol);
72155 }else if( zTab ){
72156 sqlite3ErrorMsg(pParse, "%s: %s.%s", zErr, zTab, zCol);
72157 }else{
72158 sqlite3ErrorMsg(pParse, "%s: %s", zErr, zCol);
72160 pParse->checkSchema = 1;
72161 pTopNC->nErr++;
72164 /* If a column from a table in pSrcList is referenced, then record
72165 ** this fact in the pSrcList.a[].colUsed bitmask. Column 0 causes
72166 ** bit 0 to be set. Column 1 sets bit 1. And so forth. If the
72167 ** column number is greater than the number of bits in the bitmask
72168 ** then set the high-order bit of the bitmask.
72170 if( pExpr->iColumn>=0 && pMatch!=0 ){
72171 int n = pExpr->iColumn;
72172 testcase( n==BMS-1 );
72173 if( n>=BMS ){
72174 n = BMS-1;
72176 assert( pMatch->iCursor==pExpr->iTable );
72177 pMatch->colUsed |= ((Bitmask)1)<<n;
72180 /* Clean up and return
72182 sqlite3ExprDelete(db, pExpr->pLeft);
72183 pExpr->pLeft = 0;
72184 sqlite3ExprDelete(db, pExpr->pRight);
72185 pExpr->pRight = 0;
72186 pExpr->op = (isTrigger ? TK_TRIGGER : TK_COLUMN);
72187 lookupname_end:
72188 if( cnt==1 ){
72189 assert( pNC!=0 );
72190 sqlite3AuthRead(pParse, pExpr, pSchema, pNC->pSrcList);
72191 /* Increment the nRef value on all name contexts from TopNC up to
72192 ** the point where the name matched. */
72193 for(;;){
72194 assert( pTopNC!=0 );
72195 pTopNC->nRef++;
72196 if( pTopNC==pNC ) break;
72197 pTopNC = pTopNC->pNext;
72199 return WRC_Prune;
72200 } else {
72201 return WRC_Abort;
72206 ** Allocate and return a pointer to an expression to load the column iCol
72207 ** from datasource iSrc in SrcList pSrc.
72209 SQLITE_PRIVATE Expr *sqlite3CreateColumnExpr(sqlite3 *db, SrcList *pSrc, int iSrc, int iCol){
72210 Expr *p = sqlite3ExprAlloc(db, TK_COLUMN, 0, 0);
72211 if( p ){
72212 struct SrcList_item *pItem = &pSrc->a[iSrc];
72213 p->pTab = pItem->pTab;
72214 p->iTable = pItem->iCursor;
72215 if( p->pTab->iPKey==iCol ){
72216 p->iColumn = -1;
72217 }else{
72218 p->iColumn = (ynVar)iCol;
72219 testcase( iCol==BMS );
72220 testcase( iCol==BMS-1 );
72221 pItem->colUsed |= ((Bitmask)1)<<(iCol>=BMS ? BMS-1 : iCol);
72223 ExprSetProperty(p, EP_Resolved);
72225 return p;
72229 ** This routine is callback for sqlite3WalkExpr().
72231 ** Resolve symbolic names into TK_COLUMN operators for the current
72232 ** node in the expression tree. Return 0 to continue the search down
72233 ** the tree or 2 to abort the tree walk.
72235 ** This routine also does error checking and name resolution for
72236 ** function names. The operator for aggregate functions is changed
72237 ** to TK_AGG_FUNCTION.
72239 static int resolveExprStep(Walker *pWalker, Expr *pExpr){
72240 NameContext *pNC;
72241 Parse *pParse;
72243 pNC = pWalker->u.pNC;
72244 assert( pNC!=0 );
72245 pParse = pNC->pParse;
72246 assert( pParse==pWalker->pParse );
72248 if( ExprHasAnyProperty(pExpr, EP_Resolved) ) return WRC_Prune;
72249 ExprSetProperty(pExpr, EP_Resolved);
72250 #ifndef NDEBUG
72251 if( pNC->pSrcList && pNC->pSrcList->nAlloc>0 ){
72252 SrcList *pSrcList = pNC->pSrcList;
72253 int i;
72254 for(i=0; i<pNC->pSrcList->nSrc; i++){
72255 assert( pSrcList->a[i].iCursor>=0 && pSrcList->a[i].iCursor<pParse->nTab);
72258 #endif
72259 switch( pExpr->op ){
72261 #if defined(SQLITE_ENABLE_UPDATE_DELETE_LIMIT) && !defined(SQLITE_OMIT_SUBQUERY)
72262 /* The special operator TK_ROW means use the rowid for the first
72263 ** column in the FROM clause. This is used by the LIMIT and ORDER BY
72264 ** clause processing on UPDATE and DELETE statements.
72266 case TK_ROW: {
72267 SrcList *pSrcList = pNC->pSrcList;
72268 struct SrcList_item *pItem;
72269 assert( pSrcList && pSrcList->nSrc==1 );
72270 pItem = pSrcList->a;
72271 pExpr->op = TK_COLUMN;
72272 pExpr->pTab = pItem->pTab;
72273 pExpr->iTable = pItem->iCursor;
72274 pExpr->iColumn = -1;
72275 pExpr->affinity = SQLITE_AFF_INTEGER;
72276 break;
72278 #endif /* defined(SQLITE_ENABLE_UPDATE_DELETE_LIMIT) && !defined(SQLITE_OMIT_SUBQUERY) */
72280 /* A lone identifier is the name of a column.
72282 case TK_ID: {
72283 return lookupName(pParse, 0, 0, pExpr->u.zToken, pNC, pExpr);
72286 /* A table name and column name: ID.ID
72287 ** Or a database, table and column: ID.ID.ID
72289 case TK_DOT: {
72290 const char *zColumn;
72291 const char *zTable;
72292 const char *zDb;
72293 Expr *pRight;
72295 /* if( pSrcList==0 ) break; */
72296 pRight = pExpr->pRight;
72297 if( pRight->op==TK_ID ){
72298 zDb = 0;
72299 zTable = pExpr->pLeft->u.zToken;
72300 zColumn = pRight->u.zToken;
72301 }else{
72302 assert( pRight->op==TK_DOT );
72303 zDb = pExpr->pLeft->u.zToken;
72304 zTable = pRight->pLeft->u.zToken;
72305 zColumn = pRight->pRight->u.zToken;
72307 return lookupName(pParse, zDb, zTable, zColumn, pNC, pExpr);
72310 /* Resolve function names
72312 case TK_CONST_FUNC:
72313 case TK_FUNCTION: {
72314 ExprList *pList = pExpr->x.pList; /* The argument list */
72315 int n = pList ? pList->nExpr : 0; /* Number of arguments */
72316 int no_such_func = 0; /* True if no such function exists */
72317 int wrong_num_args = 0; /* True if wrong number of arguments */
72318 int is_agg = 0; /* True if is an aggregate function */
72319 int auth; /* Authorization to use the function */
72320 int nId; /* Number of characters in function name */
72321 const char *zId; /* The function name. */
72322 FuncDef *pDef; /* Information about the function */
72323 u8 enc = ENC(pParse->db); /* The database encoding */
72325 testcase( pExpr->op==TK_CONST_FUNC );
72326 assert( !ExprHasProperty(pExpr, EP_xIsSelect) );
72327 zId = pExpr->u.zToken;
72328 nId = sqlite3Strlen30(zId);
72329 pDef = sqlite3FindFunction(pParse->db, zId, nId, n, enc, 0);
72330 if( pDef==0 ){
72331 pDef = sqlite3FindFunction(pParse->db, zId, nId, -1, enc, 0);
72332 if( pDef==0 ){
72333 no_such_func = 1;
72334 }else{
72335 wrong_num_args = 1;
72337 }else{
72338 is_agg = pDef->xFunc==0;
72340 #ifndef SQLITE_OMIT_AUTHORIZATION
72341 if( pDef ){
72342 auth = sqlite3AuthCheck(pParse, SQLITE_FUNCTION, 0, pDef->zName, 0);
72343 if( auth!=SQLITE_OK ){
72344 if( auth==SQLITE_DENY ){
72345 sqlite3ErrorMsg(pParse, "not authorized to use function: %s",
72346 pDef->zName);
72347 pNC->nErr++;
72349 pExpr->op = TK_NULL;
72350 return WRC_Prune;
72353 #endif
72354 if( is_agg && !pNC->allowAgg ){
72355 sqlite3ErrorMsg(pParse, "misuse of aggregate function %.*s()", nId,zId);
72356 pNC->nErr++;
72357 is_agg = 0;
72358 }else if( no_such_func ){
72359 sqlite3ErrorMsg(pParse, "no such function: %.*s", nId, zId);
72360 pNC->nErr++;
72361 }else if( wrong_num_args ){
72362 sqlite3ErrorMsg(pParse,"wrong number of arguments to function %.*s()",
72363 nId, zId);
72364 pNC->nErr++;
72366 if( is_agg ){
72367 pExpr->op = TK_AGG_FUNCTION;
72368 pNC->hasAgg = 1;
72370 if( is_agg ) pNC->allowAgg = 0;
72371 sqlite3WalkExprList(pWalker, pList);
72372 if( is_agg ) pNC->allowAgg = 1;
72373 /* FIX ME: Compute pExpr->affinity based on the expected return
72374 ** type of the function
72376 return WRC_Prune;
72378 #ifndef SQLITE_OMIT_SUBQUERY
72379 case TK_SELECT:
72380 case TK_EXISTS: testcase( pExpr->op==TK_EXISTS );
72381 #endif
72382 case TK_IN: {
72383 testcase( pExpr->op==TK_IN );
72384 if( ExprHasProperty(pExpr, EP_xIsSelect) ){
72385 int nRef = pNC->nRef;
72386 #ifndef SQLITE_OMIT_CHECK
72387 if( pNC->isCheck ){
72388 sqlite3ErrorMsg(pParse,"subqueries prohibited in CHECK constraints");
72390 #endif
72391 sqlite3WalkSelect(pWalker, pExpr->x.pSelect);
72392 assert( pNC->nRef>=nRef );
72393 if( nRef!=pNC->nRef ){
72394 ExprSetProperty(pExpr, EP_VarSelect);
72397 break;
72399 #ifndef SQLITE_OMIT_CHECK
72400 case TK_VARIABLE: {
72401 if( pNC->isCheck ){
72402 sqlite3ErrorMsg(pParse,"parameters prohibited in CHECK constraints");
72404 break;
72406 #endif
72408 return (pParse->nErr || pParse->db->mallocFailed) ? WRC_Abort : WRC_Continue;
72412 ** pEList is a list of expressions which are really the result set of the
72413 ** a SELECT statement. pE is a term in an ORDER BY or GROUP BY clause.
72414 ** This routine checks to see if pE is a simple identifier which corresponds
72415 ** to the AS-name of one of the terms of the expression list. If it is,
72416 ** this routine return an integer between 1 and N where N is the number of
72417 ** elements in pEList, corresponding to the matching entry. If there is
72418 ** no match, or if pE is not a simple identifier, then this routine
72419 ** return 0.
72421 ** pEList has been resolved. pE has not.
72423 static int resolveAsName(
72424 Parse *pParse, /* Parsing context for error messages */
72425 ExprList *pEList, /* List of expressions to scan */
72426 Expr *pE /* Expression we are trying to match */
72428 int i; /* Loop counter */
72430 UNUSED_PARAMETER(pParse);
72432 if( pE->op==TK_ID ){
72433 char *zCol = pE->u.zToken;
72434 for(i=0; i<pEList->nExpr; i++){
72435 char *zAs = pEList->a[i].zName;
72436 if( zAs!=0 && sqlite3StrICmp(zAs, zCol)==0 ){
72437 return i+1;
72441 return 0;
72445 ** pE is a pointer to an expression which is a single term in the
72446 ** ORDER BY of a compound SELECT. The expression has not been
72447 ** name resolved.
72449 ** At the point this routine is called, we already know that the
72450 ** ORDER BY term is not an integer index into the result set. That
72451 ** case is handled by the calling routine.
72453 ** Attempt to match pE against result set columns in the left-most
72454 ** SELECT statement. Return the index i of the matching column,
72455 ** as an indication to the caller that it should sort by the i-th column.
72456 ** The left-most column is 1. In other words, the value returned is the
72457 ** same integer value that would be used in the SQL statement to indicate
72458 ** the column.
72460 ** If there is no match, return 0. Return -1 if an error occurs.
72462 static int resolveOrderByTermToExprList(
72463 Parse *pParse, /* Parsing context for error messages */
72464 Select *pSelect, /* The SELECT statement with the ORDER BY clause */
72465 Expr *pE /* The specific ORDER BY term */
72467 int i; /* Loop counter */
72468 ExprList *pEList; /* The columns of the result set */
72469 NameContext nc; /* Name context for resolving pE */
72470 sqlite3 *db; /* Database connection */
72471 int rc; /* Return code from subprocedures */
72472 u8 savedSuppErr; /* Saved value of db->suppressErr */
72474 assert( sqlite3ExprIsInteger(pE, &i)==0 );
72475 pEList = pSelect->pEList;
72477 /* Resolve all names in the ORDER BY term expression
72479 memset(&nc, 0, sizeof(nc));
72480 nc.pParse = pParse;
72481 nc.pSrcList = pSelect->pSrc;
72482 nc.pEList = pEList;
72483 nc.allowAgg = 1;
72484 nc.nErr = 0;
72485 db = pParse->db;
72486 savedSuppErr = db->suppressErr;
72487 db->suppressErr = 1;
72488 rc = sqlite3ResolveExprNames(&nc, pE);
72489 db->suppressErr = savedSuppErr;
72490 if( rc ) return 0;
72492 /* Try to match the ORDER BY expression against an expression
72493 ** in the result set. Return an 1-based index of the matching
72494 ** result-set entry.
72496 for(i=0; i<pEList->nExpr; i++){
72497 if( sqlite3ExprCompare(pEList->a[i].pExpr, pE)<2 ){
72498 return i+1;
72502 /* If no match, return 0. */
72503 return 0;
72507 ** Generate an ORDER BY or GROUP BY term out-of-range error.
72509 static void resolveOutOfRangeError(
72510 Parse *pParse, /* The error context into which to write the error */
72511 const char *zType, /* "ORDER" or "GROUP" */
72512 int i, /* The index (1-based) of the term out of range */
72513 int mx /* Largest permissible value of i */
72515 sqlite3ErrorMsg(pParse,
72516 "%r %s BY term out of range - should be "
72517 "between 1 and %d", i, zType, mx);
72521 ** Analyze the ORDER BY clause in a compound SELECT statement. Modify
72522 ** each term of the ORDER BY clause is a constant integer between 1
72523 ** and N where N is the number of columns in the compound SELECT.
72525 ** ORDER BY terms that are already an integer between 1 and N are
72526 ** unmodified. ORDER BY terms that are integers outside the range of
72527 ** 1 through N generate an error. ORDER BY terms that are expressions
72528 ** are matched against result set expressions of compound SELECT
72529 ** beginning with the left-most SELECT and working toward the right.
72530 ** At the first match, the ORDER BY expression is transformed into
72531 ** the integer column number.
72533 ** Return the number of errors seen.
72535 static int resolveCompoundOrderBy(
72536 Parse *pParse, /* Parsing context. Leave error messages here */
72537 Select *pSelect /* The SELECT statement containing the ORDER BY */
72539 int i;
72540 ExprList *pOrderBy;
72541 ExprList *pEList;
72542 sqlite3 *db;
72543 int moreToDo = 1;
72545 pOrderBy = pSelect->pOrderBy;
72546 if( pOrderBy==0 ) return 0;
72547 db = pParse->db;
72548 #if SQLITE_MAX_COLUMN
72549 if( pOrderBy->nExpr>db->aLimit[SQLITE_LIMIT_COLUMN] ){
72550 sqlite3ErrorMsg(pParse, "too many terms in ORDER BY clause");
72551 return 1;
72553 #endif
72554 for(i=0; i<pOrderBy->nExpr; i++){
72555 pOrderBy->a[i].done = 0;
72557 pSelect->pNext = 0;
72558 while( pSelect->pPrior ){
72559 pSelect->pPrior->pNext = pSelect;
72560 pSelect = pSelect->pPrior;
72562 while( pSelect && moreToDo ){
72563 struct ExprList_item *pItem;
72564 moreToDo = 0;
72565 pEList = pSelect->pEList;
72566 assert( pEList!=0 );
72567 for(i=0, pItem=pOrderBy->a; i<pOrderBy->nExpr; i++, pItem++){
72568 int iCol = -1;
72569 Expr *pE, *pDup;
72570 if( pItem->done ) continue;
72571 pE = pItem->pExpr;
72572 if( sqlite3ExprIsInteger(pE, &iCol) ){
72573 if( iCol<=0 || iCol>pEList->nExpr ){
72574 resolveOutOfRangeError(pParse, "ORDER", i+1, pEList->nExpr);
72575 return 1;
72577 }else{
72578 iCol = resolveAsName(pParse, pEList, pE);
72579 if( iCol==0 ){
72580 pDup = sqlite3ExprDup(db, pE, 0);
72581 if( !db->mallocFailed ){
72582 assert(pDup);
72583 iCol = resolveOrderByTermToExprList(pParse, pSelect, pDup);
72585 sqlite3ExprDelete(db, pDup);
72588 if( iCol>0 ){
72589 CollSeq *pColl = pE->pColl;
72590 int flags = pE->flags & EP_ExpCollate;
72591 sqlite3ExprDelete(db, pE);
72592 pItem->pExpr = pE = sqlite3Expr(db, TK_INTEGER, 0);
72593 if( pE==0 ) return 1;
72594 pE->pColl = pColl;
72595 pE->flags |= EP_IntValue | flags;
72596 pE->u.iValue = iCol;
72597 pItem->iCol = (u16)iCol;
72598 pItem->done = 1;
72599 }else{
72600 moreToDo = 1;
72603 pSelect = pSelect->pNext;
72605 for(i=0; i<pOrderBy->nExpr; i++){
72606 if( pOrderBy->a[i].done==0 ){
72607 sqlite3ErrorMsg(pParse, "%r ORDER BY term does not match any "
72608 "column in the result set", i+1);
72609 return 1;
72612 return 0;
72616 ** Check every term in the ORDER BY or GROUP BY clause pOrderBy of
72617 ** the SELECT statement pSelect. If any term is reference to a
72618 ** result set expression (as determined by the ExprList.a.iCol field)
72619 ** then convert that term into a copy of the corresponding result set
72620 ** column.
72622 ** If any errors are detected, add an error message to pParse and
72623 ** return non-zero. Return zero if no errors are seen.
72625 SQLITE_PRIVATE int sqlite3ResolveOrderGroupBy(
72626 Parse *pParse, /* Parsing context. Leave error messages here */
72627 Select *pSelect, /* The SELECT statement containing the clause */
72628 ExprList *pOrderBy, /* The ORDER BY or GROUP BY clause to be processed */
72629 const char *zType /* "ORDER" or "GROUP" */
72631 int i;
72632 sqlite3 *db = pParse->db;
72633 ExprList *pEList;
72634 struct ExprList_item *pItem;
72636 if( pOrderBy==0 || pParse->db->mallocFailed ) return 0;
72637 #if SQLITE_MAX_COLUMN
72638 if( pOrderBy->nExpr>db->aLimit[SQLITE_LIMIT_COLUMN] ){
72639 sqlite3ErrorMsg(pParse, "too many terms in %s BY clause", zType);
72640 return 1;
72642 #endif
72643 pEList = pSelect->pEList;
72644 assert( pEList!=0 ); /* sqlite3SelectNew() guarantees this */
72645 for(i=0, pItem=pOrderBy->a; i<pOrderBy->nExpr; i++, pItem++){
72646 if( pItem->iCol ){
72647 if( pItem->iCol>pEList->nExpr ){
72648 resolveOutOfRangeError(pParse, zType, i+1, pEList->nExpr);
72649 return 1;
72651 resolveAlias(pParse, pEList, pItem->iCol-1, pItem->pExpr, zType);
72654 return 0;
72658 ** pOrderBy is an ORDER BY or GROUP BY clause in SELECT statement pSelect.
72659 ** The Name context of the SELECT statement is pNC. zType is either
72660 ** "ORDER" or "GROUP" depending on which type of clause pOrderBy is.
72662 ** This routine resolves each term of the clause into an expression.
72663 ** If the order-by term is an integer I between 1 and N (where N is the
72664 ** number of columns in the result set of the SELECT) then the expression
72665 ** in the resolution is a copy of the I-th result-set expression. If
72666 ** the order-by term is an identify that corresponds to the AS-name of
72667 ** a result-set expression, then the term resolves to a copy of the
72668 ** result-set expression. Otherwise, the expression is resolved in
72669 ** the usual way - using sqlite3ResolveExprNames().
72671 ** This routine returns the number of errors. If errors occur, then
72672 ** an appropriate error message might be left in pParse. (OOM errors
72673 ** excepted.)
72675 static int resolveOrderGroupBy(
72676 NameContext *pNC, /* The name context of the SELECT statement */
72677 Select *pSelect, /* The SELECT statement holding pOrderBy */
72678 ExprList *pOrderBy, /* An ORDER BY or GROUP BY clause to resolve */
72679 const char *zType /* Either "ORDER" or "GROUP", as appropriate */
72681 int i; /* Loop counter */
72682 int iCol; /* Column number */
72683 struct ExprList_item *pItem; /* A term of the ORDER BY clause */
72684 Parse *pParse; /* Parsing context */
72685 int nResult; /* Number of terms in the result set */
72687 if( pOrderBy==0 ) return 0;
72688 nResult = pSelect->pEList->nExpr;
72689 pParse = pNC->pParse;
72690 for(i=0, pItem=pOrderBy->a; i<pOrderBy->nExpr; i++, pItem++){
72691 Expr *pE = pItem->pExpr;
72692 iCol = resolveAsName(pParse, pSelect->pEList, pE);
72693 if( iCol>0 ){
72694 /* If an AS-name match is found, mark this ORDER BY column as being
72695 ** a copy of the iCol-th result-set column. The subsequent call to
72696 ** sqlite3ResolveOrderGroupBy() will convert the expression to a
72697 ** copy of the iCol-th result-set expression. */
72698 pItem->iCol = (u16)iCol;
72699 continue;
72701 if( sqlite3ExprIsInteger(pE, &iCol) ){
72702 /* The ORDER BY term is an integer constant. Again, set the column
72703 ** number so that sqlite3ResolveOrderGroupBy() will convert the
72704 ** order-by term to a copy of the result-set expression */
72705 if( iCol<1 ){
72706 resolveOutOfRangeError(pParse, zType, i+1, nResult);
72707 return 1;
72709 pItem->iCol = (u16)iCol;
72710 continue;
72713 /* Otherwise, treat the ORDER BY term as an ordinary expression */
72714 pItem->iCol = 0;
72715 if( sqlite3ResolveExprNames(pNC, pE) ){
72716 return 1;
72719 return sqlite3ResolveOrderGroupBy(pParse, pSelect, pOrderBy, zType);
72723 ** Resolve names in the SELECT statement p and all of its descendents.
72725 static int resolveSelectStep(Walker *pWalker, Select *p){
72726 NameContext *pOuterNC; /* Context that contains this SELECT */
72727 NameContext sNC; /* Name context of this SELECT */
72728 int isCompound; /* True if p is a compound select */
72729 int nCompound; /* Number of compound terms processed so far */
72730 Parse *pParse; /* Parsing context */
72731 ExprList *pEList; /* Result set expression list */
72732 int i; /* Loop counter */
72733 ExprList *pGroupBy; /* The GROUP BY clause */
72734 Select *pLeftmost; /* Left-most of SELECT of a compound */
72735 sqlite3 *db; /* Database connection */
72738 assert( p!=0 );
72739 if( p->selFlags & SF_Resolved ){
72740 return WRC_Prune;
72742 pOuterNC = pWalker->u.pNC;
72743 pParse = pWalker->pParse;
72744 db = pParse->db;
72746 /* Normally sqlite3SelectExpand() will be called first and will have
72747 ** already expanded this SELECT. However, if this is a subquery within
72748 ** an expression, sqlite3ResolveExprNames() will be called without a
72749 ** prior call to sqlite3SelectExpand(). When that happens, let
72750 ** sqlite3SelectPrep() do all of the processing for this SELECT.
72751 ** sqlite3SelectPrep() will invoke both sqlite3SelectExpand() and
72752 ** this routine in the correct order.
72754 if( (p->selFlags & SF_Expanded)==0 ){
72755 sqlite3SelectPrep(pParse, p, pOuterNC);
72756 return (pParse->nErr || db->mallocFailed) ? WRC_Abort : WRC_Prune;
72759 isCompound = p->pPrior!=0;
72760 nCompound = 0;
72761 pLeftmost = p;
72762 while( p ){
72763 assert( (p->selFlags & SF_Expanded)!=0 );
72764 assert( (p->selFlags & SF_Resolved)==0 );
72765 p->selFlags |= SF_Resolved;
72767 /* Resolve the expressions in the LIMIT and OFFSET clauses. These
72768 ** are not allowed to refer to any names, so pass an empty NameContext.
72770 memset(&sNC, 0, sizeof(sNC));
72771 sNC.pParse = pParse;
72772 if( sqlite3ResolveExprNames(&sNC, p->pLimit) ||
72773 sqlite3ResolveExprNames(&sNC, p->pOffset) ){
72774 return WRC_Abort;
72777 /* Set up the local name-context to pass to sqlite3ResolveExprNames() to
72778 ** resolve the result-set expression list.
72780 sNC.allowAgg = 1;
72781 sNC.pSrcList = p->pSrc;
72782 sNC.pNext = pOuterNC;
72784 /* Resolve names in the result set. */
72785 pEList = p->pEList;
72786 assert( pEList!=0 );
72787 for(i=0; i<pEList->nExpr; i++){
72788 Expr *pX = pEList->a[i].pExpr;
72789 if( sqlite3ResolveExprNames(&sNC, pX) ){
72790 return WRC_Abort;
72794 /* Recursively resolve names in all subqueries
72796 for(i=0; i<p->pSrc->nSrc; i++){
72797 struct SrcList_item *pItem = &p->pSrc->a[i];
72798 if( pItem->pSelect ){
72799 NameContext *pNC; /* Used to iterate name contexts */
72800 int nRef = 0; /* Refcount for pOuterNC and outer contexts */
72801 const char *zSavedContext = pParse->zAuthContext;
72803 /* Count the total number of references to pOuterNC and all of its
72804 ** parent contexts. After resolving references to expressions in
72805 ** pItem->pSelect, check if this value has changed. If so, then
72806 ** SELECT statement pItem->pSelect must be correlated. Set the
72807 ** pItem->isCorrelated flag if this is the case. */
72808 for(pNC=pOuterNC; pNC; pNC=pNC->pNext) nRef += pNC->nRef;
72810 if( pItem->zName ) pParse->zAuthContext = pItem->zName;
72811 sqlite3ResolveSelectNames(pParse, pItem->pSelect, pOuterNC);
72812 pParse->zAuthContext = zSavedContext;
72813 if( pParse->nErr || db->mallocFailed ) return WRC_Abort;
72815 for(pNC=pOuterNC; pNC; pNC=pNC->pNext) nRef -= pNC->nRef;
72816 assert( pItem->isCorrelated==0 && nRef<=0 );
72817 pItem->isCorrelated = (nRef!=0);
72821 /* If there are no aggregate functions in the result-set, and no GROUP BY
72822 ** expression, do not allow aggregates in any of the other expressions.
72824 assert( (p->selFlags & SF_Aggregate)==0 );
72825 pGroupBy = p->pGroupBy;
72826 if( pGroupBy || sNC.hasAgg ){
72827 p->selFlags |= SF_Aggregate;
72828 }else{
72829 sNC.allowAgg = 0;
72832 /* If a HAVING clause is present, then there must be a GROUP BY clause.
72834 if( p->pHaving && !pGroupBy ){
72835 sqlite3ErrorMsg(pParse, "a GROUP BY clause is required before HAVING");
72836 return WRC_Abort;
72839 /* Add the expression list to the name-context before parsing the
72840 ** other expressions in the SELECT statement. This is so that
72841 ** expressions in the WHERE clause (etc.) can refer to expressions by
72842 ** aliases in the result set.
72844 ** Minor point: If this is the case, then the expression will be
72845 ** re-evaluated for each reference to it.
72847 sNC.pEList = p->pEList;
72848 if( sqlite3ResolveExprNames(&sNC, p->pWhere) ||
72849 sqlite3ResolveExprNames(&sNC, p->pHaving)
72851 return WRC_Abort;
72854 /* The ORDER BY and GROUP BY clauses may not refer to terms in
72855 ** outer queries
72857 sNC.pNext = 0;
72858 sNC.allowAgg = 1;
72860 /* Process the ORDER BY clause for singleton SELECT statements.
72861 ** The ORDER BY clause for compounds SELECT statements is handled
72862 ** below, after all of the result-sets for all of the elements of
72863 ** the compound have been resolved.
72865 if( !isCompound && resolveOrderGroupBy(&sNC, p, p->pOrderBy, "ORDER") ){
72866 return WRC_Abort;
72868 if( db->mallocFailed ){
72869 return WRC_Abort;
72872 /* Resolve the GROUP BY clause. At the same time, make sure
72873 ** the GROUP BY clause does not contain aggregate functions.
72875 if( pGroupBy ){
72876 struct ExprList_item *pItem;
72878 if( resolveOrderGroupBy(&sNC, p, pGroupBy, "GROUP") || db->mallocFailed ){
72879 return WRC_Abort;
72881 for(i=0, pItem=pGroupBy->a; i<pGroupBy->nExpr; i++, pItem++){
72882 if( ExprHasProperty(pItem->pExpr, EP_Agg) ){
72883 sqlite3ErrorMsg(pParse, "aggregate functions are not allowed in "
72884 "the GROUP BY clause");
72885 return WRC_Abort;
72890 /* Advance to the next term of the compound
72892 p = p->pPrior;
72893 nCompound++;
72896 /* Resolve the ORDER BY on a compound SELECT after all terms of
72897 ** the compound have been resolved.
72899 if( isCompound && resolveCompoundOrderBy(pParse, pLeftmost) ){
72900 return WRC_Abort;
72903 return WRC_Prune;
72907 ** This routine walks an expression tree and resolves references to
72908 ** table columns and result-set columns. At the same time, do error
72909 ** checking on function usage and set a flag if any aggregate functions
72910 ** are seen.
72912 ** To resolve table columns references we look for nodes (or subtrees) of the
72913 ** form X.Y.Z or Y.Z or just Z where
72915 ** X: The name of a database. Ex: "main" or "temp" or
72916 ** the symbolic name assigned to an ATTACH-ed database.
72918 ** Y: The name of a table in a FROM clause. Or in a trigger
72919 ** one of the special names "old" or "new".
72921 ** Z: The name of a column in table Y.
72923 ** The node at the root of the subtree is modified as follows:
72925 ** Expr.op Changed to TK_COLUMN
72926 ** Expr.pTab Points to the Table object for X.Y
72927 ** Expr.iColumn The column index in X.Y. -1 for the rowid.
72928 ** Expr.iTable The VDBE cursor number for X.Y
72931 ** To resolve result-set references, look for expression nodes of the
72932 ** form Z (with no X and Y prefix) where the Z matches the right-hand
72933 ** size of an AS clause in the result-set of a SELECT. The Z expression
72934 ** is replaced by a copy of the left-hand side of the result-set expression.
72935 ** Table-name and function resolution occurs on the substituted expression
72936 ** tree. For example, in:
72938 ** SELECT a+b AS x, c+d AS y FROM t1 ORDER BY x;
72940 ** The "x" term of the order by is replaced by "a+b" to render:
72942 ** SELECT a+b AS x, c+d AS y FROM t1 ORDER BY a+b;
72944 ** Function calls are checked to make sure that the function is
72945 ** defined and that the correct number of arguments are specified.
72946 ** If the function is an aggregate function, then the pNC->hasAgg is
72947 ** set and the opcode is changed from TK_FUNCTION to TK_AGG_FUNCTION.
72948 ** If an expression contains aggregate functions then the EP_Agg
72949 ** property on the expression is set.
72951 ** An error message is left in pParse if anything is amiss. The number
72952 ** if errors is returned.
72954 SQLITE_PRIVATE int sqlite3ResolveExprNames(
72955 NameContext *pNC, /* Namespace to resolve expressions in. */
72956 Expr *pExpr /* The expression to be analyzed. */
72958 int savedHasAgg;
72959 Walker w;
72961 if( pExpr==0 ) return 0;
72962 #if SQLITE_MAX_EXPR_DEPTH>0
72964 Parse *pParse = pNC->pParse;
72965 if( sqlite3ExprCheckHeight(pParse, pExpr->nHeight+pNC->pParse->nHeight) ){
72966 return 1;
72968 pParse->nHeight += pExpr->nHeight;
72970 #endif
72971 savedHasAgg = pNC->hasAgg;
72972 pNC->hasAgg = 0;
72973 w.xExprCallback = resolveExprStep;
72974 w.xSelectCallback = resolveSelectStep;
72975 w.pParse = pNC->pParse;
72976 w.u.pNC = pNC;
72977 sqlite3WalkExpr(&w, pExpr);
72978 #if SQLITE_MAX_EXPR_DEPTH>0
72979 pNC->pParse->nHeight -= pExpr->nHeight;
72980 #endif
72981 if( pNC->nErr>0 || w.pParse->nErr>0 ){
72982 ExprSetProperty(pExpr, EP_Error);
72984 if( pNC->hasAgg ){
72985 ExprSetProperty(pExpr, EP_Agg);
72986 }else if( savedHasAgg ){
72987 pNC->hasAgg = 1;
72989 return ExprHasProperty(pExpr, EP_Error);
72994 ** Resolve all names in all expressions of a SELECT and in all
72995 ** decendents of the SELECT, including compounds off of p->pPrior,
72996 ** subqueries in expressions, and subqueries used as FROM clause
72997 ** terms.
72999 ** See sqlite3ResolveExprNames() for a description of the kinds of
73000 ** transformations that occur.
73002 ** All SELECT statements should have been expanded using
73003 ** sqlite3SelectExpand() prior to invoking this routine.
73005 SQLITE_PRIVATE void sqlite3ResolveSelectNames(
73006 Parse *pParse, /* The parser context */
73007 Select *p, /* The SELECT statement being coded. */
73008 NameContext *pOuterNC /* Name context for parent SELECT statement */
73010 Walker w;
73012 assert( p!=0 );
73013 w.xExprCallback = resolveExprStep;
73014 w.xSelectCallback = resolveSelectStep;
73015 w.pParse = pParse;
73016 w.u.pNC = pOuterNC;
73017 sqlite3WalkSelect(&w, p);
73020 /************** End of resolve.c *********************************************/
73021 /************** Begin file expr.c ********************************************/
73023 ** 2001 September 15
73025 ** The author disclaims copyright to this source code. In place of
73026 ** a legal notice, here is a blessing:
73028 ** May you do good and not evil.
73029 ** May you find forgiveness for yourself and forgive others.
73030 ** May you share freely, never taking more than you give.
73032 *************************************************************************
73033 ** This file contains routines used for analyzing expressions and
73034 ** for generating VDBE code that evaluates expressions in SQLite.
73038 ** Return the 'affinity' of the expression pExpr if any.
73040 ** If pExpr is a column, a reference to a column via an 'AS' alias,
73041 ** or a sub-select with a column as the return value, then the
73042 ** affinity of that column is returned. Otherwise, 0x00 is returned,
73043 ** indicating no affinity for the expression.
73045 ** i.e. the WHERE clause expresssions in the following statements all
73046 ** have an affinity:
73048 ** CREATE TABLE t1(a);
73049 ** SELECT * FROM t1 WHERE a;
73050 ** SELECT a AS b FROM t1 WHERE b;
73051 ** SELECT * FROM t1 WHERE (select a from t1);
73053 SQLITE_PRIVATE char sqlite3ExprAffinity(Expr *pExpr){
73054 int op = pExpr->op;
73055 if( op==TK_SELECT ){
73056 assert( pExpr->flags&EP_xIsSelect );
73057 return sqlite3ExprAffinity(pExpr->x.pSelect->pEList->a[0].pExpr);
73059 #ifndef SQLITE_OMIT_CAST
73060 if( op==TK_CAST ){
73061 assert( !ExprHasProperty(pExpr, EP_IntValue) );
73062 return sqlite3AffinityType(pExpr->u.zToken);
73064 #endif
73065 if( (op==TK_AGG_COLUMN || op==TK_COLUMN || op==TK_REGISTER)
73066 && pExpr->pTab!=0
73068 /* op==TK_REGISTER && pExpr->pTab!=0 happens when pExpr was originally
73069 ** a TK_COLUMN but was previously evaluated and cached in a register */
73070 int j = pExpr->iColumn;
73071 if( j<0 ) return SQLITE_AFF_INTEGER;
73072 assert( pExpr->pTab && j<pExpr->pTab->nCol );
73073 return pExpr->pTab->aCol[j].affinity;
73075 return pExpr->affinity;
73079 ** Set the explicit collating sequence for an expression to the
73080 ** collating sequence supplied in the second argument.
73082 SQLITE_PRIVATE Expr *sqlite3ExprSetColl(Expr *pExpr, CollSeq *pColl){
73083 if( pExpr && pColl ){
73084 pExpr->pColl = pColl;
73085 pExpr->flags |= EP_ExpCollate;
73087 return pExpr;
73091 ** Set the collating sequence for expression pExpr to be the collating
73092 ** sequence named by pToken. Return a pointer to the revised expression.
73093 ** The collating sequence is marked as "explicit" using the EP_ExpCollate
73094 ** flag. An explicit collating sequence will override implicit
73095 ** collating sequences.
73097 SQLITE_PRIVATE Expr *sqlite3ExprSetCollByToken(Parse *pParse, Expr *pExpr, Token *pCollName){
73098 char *zColl = 0; /* Dequoted name of collation sequence */
73099 CollSeq *pColl;
73100 sqlite3 *db = pParse->db;
73101 zColl = sqlite3NameFromToken(db, pCollName);
73102 pColl = sqlite3LocateCollSeq(pParse, zColl);
73103 sqlite3ExprSetColl(pExpr, pColl);
73104 sqlite3DbFree(db, zColl);
73105 return pExpr;
73109 ** Return the default collation sequence for the expression pExpr. If
73110 ** there is no default collation type, return 0.
73112 SQLITE_PRIVATE CollSeq *sqlite3ExprCollSeq(Parse *pParse, Expr *pExpr){
73113 CollSeq *pColl = 0;
73114 Expr *p = pExpr;
73115 while( p ){
73116 int op;
73117 pColl = p->pColl;
73118 if( pColl ) break;
73119 op = p->op;
73120 if( p->pTab!=0 && (
73121 op==TK_AGG_COLUMN || op==TK_COLUMN || op==TK_REGISTER || op==TK_TRIGGER
73123 /* op==TK_REGISTER && p->pTab!=0 happens when pExpr was originally
73124 ** a TK_COLUMN but was previously evaluated and cached in a register */
73125 const char *zColl;
73126 int j = p->iColumn;
73127 if( j>=0 ){
73128 sqlite3 *db = pParse->db;
73129 zColl = p->pTab->aCol[j].zColl;
73130 pColl = sqlite3FindCollSeq(db, ENC(db), zColl, 0);
73131 pExpr->pColl = pColl;
73133 break;
73135 if( op!=TK_CAST && op!=TK_UPLUS ){
73136 break;
73138 p = p->pLeft;
73140 if( sqlite3CheckCollSeq(pParse, pColl) ){
73141 pColl = 0;
73143 return pColl;
73147 ** pExpr is an operand of a comparison operator. aff2 is the
73148 ** type affinity of the other operand. This routine returns the
73149 ** type affinity that should be used for the comparison operator.
73151 SQLITE_PRIVATE char sqlite3CompareAffinity(Expr *pExpr, char aff2){
73152 char aff1 = sqlite3ExprAffinity(pExpr);
73153 if( aff1 && aff2 ){
73154 /* Both sides of the comparison are columns. If one has numeric
73155 ** affinity, use that. Otherwise use no affinity.
73157 if( sqlite3IsNumericAffinity(aff1) || sqlite3IsNumericAffinity(aff2) ){
73158 return SQLITE_AFF_NUMERIC;
73159 }else{
73160 return SQLITE_AFF_NONE;
73162 }else if( !aff1 && !aff2 ){
73163 /* Neither side of the comparison is a column. Compare the
73164 ** results directly.
73166 return SQLITE_AFF_NONE;
73167 }else{
73168 /* One side is a column, the other is not. Use the columns affinity. */
73169 assert( aff1==0 || aff2==0 );
73170 return (aff1 + aff2);
73175 ** pExpr is a comparison operator. Return the type affinity that should
73176 ** be applied to both operands prior to doing the comparison.
73178 static char comparisonAffinity(Expr *pExpr){
73179 char aff;
73180 assert( pExpr->op==TK_EQ || pExpr->op==TK_IN || pExpr->op==TK_LT ||
73181 pExpr->op==TK_GT || pExpr->op==TK_GE || pExpr->op==TK_LE ||
73182 pExpr->op==TK_NE || pExpr->op==TK_IS || pExpr->op==TK_ISNOT );
73183 assert( pExpr->pLeft );
73184 aff = sqlite3ExprAffinity(pExpr->pLeft);
73185 if( pExpr->pRight ){
73186 aff = sqlite3CompareAffinity(pExpr->pRight, aff);
73187 }else if( ExprHasProperty(pExpr, EP_xIsSelect) ){
73188 aff = sqlite3CompareAffinity(pExpr->x.pSelect->pEList->a[0].pExpr, aff);
73189 }else if( !aff ){
73190 aff = SQLITE_AFF_NONE;
73192 return aff;
73196 ** pExpr is a comparison expression, eg. '=', '<', IN(...) etc.
73197 ** idx_affinity is the affinity of an indexed column. Return true
73198 ** if the index with affinity idx_affinity may be used to implement
73199 ** the comparison in pExpr.
73201 SQLITE_PRIVATE int sqlite3IndexAffinityOk(Expr *pExpr, char idx_affinity){
73202 char aff = comparisonAffinity(pExpr);
73203 switch( aff ){
73204 case SQLITE_AFF_NONE:
73205 return 1;
73206 case SQLITE_AFF_TEXT:
73207 return idx_affinity==SQLITE_AFF_TEXT;
73208 default:
73209 return sqlite3IsNumericAffinity(idx_affinity);
73214 ** Return the P5 value that should be used for a binary comparison
73215 ** opcode (OP_Eq, OP_Ge etc.) used to compare pExpr1 and pExpr2.
73217 static u8 binaryCompareP5(Expr *pExpr1, Expr *pExpr2, int jumpIfNull){
73218 u8 aff = (char)sqlite3ExprAffinity(pExpr2);
73219 aff = (u8)sqlite3CompareAffinity(pExpr1, aff) | (u8)jumpIfNull;
73220 return aff;
73224 ** Return a pointer to the collation sequence that should be used by
73225 ** a binary comparison operator comparing pLeft and pRight.
73227 ** If the left hand expression has a collating sequence type, then it is
73228 ** used. Otherwise the collation sequence for the right hand expression
73229 ** is used, or the default (BINARY) if neither expression has a collating
73230 ** type.
73232 ** Argument pRight (but not pLeft) may be a null pointer. In this case,
73233 ** it is not considered.
73235 SQLITE_PRIVATE CollSeq *sqlite3BinaryCompareCollSeq(
73236 Parse *pParse,
73237 Expr *pLeft,
73238 Expr *pRight
73240 CollSeq *pColl;
73241 assert( pLeft );
73242 if( pLeft->flags & EP_ExpCollate ){
73243 assert( pLeft->pColl );
73244 pColl = pLeft->pColl;
73245 }else if( pRight && pRight->flags & EP_ExpCollate ){
73246 assert( pRight->pColl );
73247 pColl = pRight->pColl;
73248 }else{
73249 pColl = sqlite3ExprCollSeq(pParse, pLeft);
73250 if( !pColl ){
73251 pColl = sqlite3ExprCollSeq(pParse, pRight);
73254 return pColl;
73258 ** Generate code for a comparison operator.
73260 static int codeCompare(
73261 Parse *pParse, /* The parsing (and code generating) context */
73262 Expr *pLeft, /* The left operand */
73263 Expr *pRight, /* The right operand */
73264 int opcode, /* The comparison opcode */
73265 int in1, int in2, /* Register holding operands */
73266 int dest, /* Jump here if true. */
73267 int jumpIfNull /* If true, jump if either operand is NULL */
73269 int p5;
73270 int addr;
73271 CollSeq *p4;
73273 p4 = sqlite3BinaryCompareCollSeq(pParse, pLeft, pRight);
73274 p5 = binaryCompareP5(pLeft, pRight, jumpIfNull);
73275 addr = sqlite3VdbeAddOp4(pParse->pVdbe, opcode, in2, dest, in1,
73276 (void*)p4, P4_COLLSEQ);
73277 sqlite3VdbeChangeP5(pParse->pVdbe, (u8)p5);
73278 return addr;
73281 #if SQLITE_MAX_EXPR_DEPTH>0
73283 ** Check that argument nHeight is less than or equal to the maximum
73284 ** expression depth allowed. If it is not, leave an error message in
73285 ** pParse.
73287 SQLITE_PRIVATE int sqlite3ExprCheckHeight(Parse *pParse, int nHeight){
73288 int rc = SQLITE_OK;
73289 int mxHeight = pParse->db->aLimit[SQLITE_LIMIT_EXPR_DEPTH];
73290 if( nHeight>mxHeight ){
73291 sqlite3ErrorMsg(pParse,
73292 "Expression tree is too large (maximum depth %d)", mxHeight
73294 rc = SQLITE_ERROR;
73296 return rc;
73299 /* The following three functions, heightOfExpr(), heightOfExprList()
73300 ** and heightOfSelect(), are used to determine the maximum height
73301 ** of any expression tree referenced by the structure passed as the
73302 ** first argument.
73304 ** If this maximum height is greater than the current value pointed
73305 ** to by pnHeight, the second parameter, then set *pnHeight to that
73306 ** value.
73308 static void heightOfExpr(Expr *p, int *pnHeight){
73309 if( p ){
73310 if( p->nHeight>*pnHeight ){
73311 *pnHeight = p->nHeight;
73315 static void heightOfExprList(ExprList *p, int *pnHeight){
73316 if( p ){
73317 int i;
73318 for(i=0; i<p->nExpr; i++){
73319 heightOfExpr(p->a[i].pExpr, pnHeight);
73323 static void heightOfSelect(Select *p, int *pnHeight){
73324 if( p ){
73325 heightOfExpr(p->pWhere, pnHeight);
73326 heightOfExpr(p->pHaving, pnHeight);
73327 heightOfExpr(p->pLimit, pnHeight);
73328 heightOfExpr(p->pOffset, pnHeight);
73329 heightOfExprList(p->pEList, pnHeight);
73330 heightOfExprList(p->pGroupBy, pnHeight);
73331 heightOfExprList(p->pOrderBy, pnHeight);
73332 heightOfSelect(p->pPrior, pnHeight);
73337 ** Set the Expr.nHeight variable in the structure passed as an
73338 ** argument. An expression with no children, Expr.pList or
73339 ** Expr.pSelect member has a height of 1. Any other expression
73340 ** has a height equal to the maximum height of any other
73341 ** referenced Expr plus one.
73343 static void exprSetHeight(Expr *p){
73344 int nHeight = 0;
73345 heightOfExpr(p->pLeft, &nHeight);
73346 heightOfExpr(p->pRight, &nHeight);
73347 if( ExprHasProperty(p, EP_xIsSelect) ){
73348 heightOfSelect(p->x.pSelect, &nHeight);
73349 }else{
73350 heightOfExprList(p->x.pList, &nHeight);
73352 p->nHeight = nHeight + 1;
73356 ** Set the Expr.nHeight variable using the exprSetHeight() function. If
73357 ** the height is greater than the maximum allowed expression depth,
73358 ** leave an error in pParse.
73360 SQLITE_PRIVATE void sqlite3ExprSetHeight(Parse *pParse, Expr *p){
73361 exprSetHeight(p);
73362 sqlite3ExprCheckHeight(pParse, p->nHeight);
73366 ** Return the maximum height of any expression tree referenced
73367 ** by the select statement passed as an argument.
73369 SQLITE_PRIVATE int sqlite3SelectExprHeight(Select *p){
73370 int nHeight = 0;
73371 heightOfSelect(p, &nHeight);
73372 return nHeight;
73374 #else
73375 #define exprSetHeight(y)
73376 #endif /* SQLITE_MAX_EXPR_DEPTH>0 */
73379 ** This routine is the core allocator for Expr nodes.
73381 ** Construct a new expression node and return a pointer to it. Memory
73382 ** for this node and for the pToken argument is a single allocation
73383 ** obtained from sqlite3DbMalloc(). The calling function
73384 ** is responsible for making sure the node eventually gets freed.
73386 ** If dequote is true, then the token (if it exists) is dequoted.
73387 ** If dequote is false, no dequoting is performance. The deQuote
73388 ** parameter is ignored if pToken is NULL or if the token does not
73389 ** appear to be quoted. If the quotes were of the form "..." (double-quotes)
73390 ** then the EP_DblQuoted flag is set on the expression node.
73392 ** Special case: If op==TK_INTEGER and pToken points to a string that
73393 ** can be translated into a 32-bit integer, then the token is not
73394 ** stored in u.zToken. Instead, the integer values is written
73395 ** into u.iValue and the EP_IntValue flag is set. No extra storage
73396 ** is allocated to hold the integer text and the dequote flag is ignored.
73398 SQLITE_PRIVATE Expr *sqlite3ExprAlloc(
73399 sqlite3 *db, /* Handle for sqlite3DbMallocZero() (may be null) */
73400 int op, /* Expression opcode */
73401 const Token *pToken, /* Token argument. Might be NULL */
73402 int dequote /* True to dequote */
73404 Expr *pNew;
73405 int nExtra = 0;
73406 int iValue = 0;
73408 if( pToken ){
73409 if( op!=TK_INTEGER || pToken->z==0
73410 || sqlite3GetInt32(pToken->z, &iValue)==0 ){
73411 nExtra = pToken->n+1;
73412 assert( iValue>=0 );
73415 pNew = sqlite3DbMallocZero(db, sizeof(Expr)+nExtra);
73416 if( pNew ){
73417 pNew->op = (u8)op;
73418 pNew->iAgg = -1;
73419 if( pToken ){
73420 if( nExtra==0 ){
73421 pNew->flags |= EP_IntValue;
73422 pNew->u.iValue = iValue;
73423 }else{
73424 int c;
73425 pNew->u.zToken = (char*)&pNew[1];
73426 memcpy(pNew->u.zToken, pToken->z, pToken->n);
73427 pNew->u.zToken[pToken->n] = 0;
73428 if( dequote && nExtra>=3
73429 && ((c = pToken->z[0])=='\'' || c=='"' || c=='[' || c=='`') ){
73430 sqlite3Dequote(pNew->u.zToken);
73431 if( c=='"' ) pNew->flags |= EP_DblQuoted;
73435 #if SQLITE_MAX_EXPR_DEPTH>0
73436 pNew->nHeight = 1;
73437 #endif
73439 return pNew;
73443 ** Allocate a new expression node from a zero-terminated token that has
73444 ** already been dequoted.
73446 SQLITE_PRIVATE Expr *sqlite3Expr(
73447 sqlite3 *db, /* Handle for sqlite3DbMallocZero() (may be null) */
73448 int op, /* Expression opcode */
73449 const char *zToken /* Token argument. Might be NULL */
73451 Token x;
73452 x.z = zToken;
73453 x.n = zToken ? sqlite3Strlen30(zToken) : 0;
73454 return sqlite3ExprAlloc(db, op, &x, 0);
73458 ** Attach subtrees pLeft and pRight to the Expr node pRoot.
73460 ** If pRoot==NULL that means that a memory allocation error has occurred.
73461 ** In that case, delete the subtrees pLeft and pRight.
73463 SQLITE_PRIVATE void sqlite3ExprAttachSubtrees(
73464 sqlite3 *db,
73465 Expr *pRoot,
73466 Expr *pLeft,
73467 Expr *pRight
73469 if( pRoot==0 ){
73470 assert( db->mallocFailed );
73471 sqlite3ExprDelete(db, pLeft);
73472 sqlite3ExprDelete(db, pRight);
73473 }else{
73474 if( pRight ){
73475 pRoot->pRight = pRight;
73476 if( pRight->flags & EP_ExpCollate ){
73477 pRoot->flags |= EP_ExpCollate;
73478 pRoot->pColl = pRight->pColl;
73481 if( pLeft ){
73482 pRoot->pLeft = pLeft;
73483 if( pLeft->flags & EP_ExpCollate ){
73484 pRoot->flags |= EP_ExpCollate;
73485 pRoot->pColl = pLeft->pColl;
73488 exprSetHeight(pRoot);
73493 ** Allocate a Expr node which joins as many as two subtrees.
73495 ** One or both of the subtrees can be NULL. Return a pointer to the new
73496 ** Expr node. Or, if an OOM error occurs, set pParse->db->mallocFailed,
73497 ** free the subtrees and return NULL.
73499 SQLITE_PRIVATE Expr *sqlite3PExpr(
73500 Parse *pParse, /* Parsing context */
73501 int op, /* Expression opcode */
73502 Expr *pLeft, /* Left operand */
73503 Expr *pRight, /* Right operand */
73504 const Token *pToken /* Argument token */
73506 Expr *p = sqlite3ExprAlloc(pParse->db, op, pToken, 1);
73507 sqlite3ExprAttachSubtrees(pParse->db, p, pLeft, pRight);
73508 if( p ) {
73509 sqlite3ExprCheckHeight(pParse, p->nHeight);
73511 return p;
73515 ** Join two expressions using an AND operator. If either expression is
73516 ** NULL, then just return the other expression.
73518 SQLITE_PRIVATE Expr *sqlite3ExprAnd(sqlite3 *db, Expr *pLeft, Expr *pRight){
73519 if( pLeft==0 ){
73520 return pRight;
73521 }else if( pRight==0 ){
73522 return pLeft;
73523 }else{
73524 Expr *pNew = sqlite3ExprAlloc(db, TK_AND, 0, 0);
73525 sqlite3ExprAttachSubtrees(db, pNew, pLeft, pRight);
73526 return pNew;
73531 ** Construct a new expression node for a function with multiple
73532 ** arguments.
73534 SQLITE_PRIVATE Expr *sqlite3ExprFunction(Parse *pParse, ExprList *pList, Token *pToken){
73535 Expr *pNew;
73536 sqlite3 *db = pParse->db;
73537 assert( pToken );
73538 pNew = sqlite3ExprAlloc(db, TK_FUNCTION, pToken, 1);
73539 if( pNew==0 ){
73540 sqlite3ExprListDelete(db, pList); /* Avoid memory leak when malloc fails */
73541 return 0;
73543 pNew->x.pList = pList;
73544 assert( !ExprHasProperty(pNew, EP_xIsSelect) );
73545 sqlite3ExprSetHeight(pParse, pNew);
73546 return pNew;
73550 ** Assign a variable number to an expression that encodes a wildcard
73551 ** in the original SQL statement.
73553 ** Wildcards consisting of a single "?" are assigned the next sequential
73554 ** variable number.
73556 ** Wildcards of the form "?nnn" are assigned the number "nnn". We make
73557 ** sure "nnn" is not too be to avoid a denial of service attack when
73558 ** the SQL statement comes from an external source.
73560 ** Wildcards of the form ":aaa", "@aaa", or "$aaa" are assigned the same number
73561 ** as the previous instance of the same wildcard. Or if this is the first
73562 ** instance of the wildcard, the next sequenial variable number is
73563 ** assigned.
73565 SQLITE_PRIVATE void sqlite3ExprAssignVarNumber(Parse *pParse, Expr *pExpr){
73566 sqlite3 *db = pParse->db;
73567 const char *z;
73569 if( pExpr==0 ) return;
73570 assert( !ExprHasAnyProperty(pExpr, EP_IntValue|EP_Reduced|EP_TokenOnly) );
73571 z = pExpr->u.zToken;
73572 assert( z!=0 );
73573 assert( z[0]!=0 );
73574 if( z[1]==0 ){
73575 /* Wildcard of the form "?". Assign the next variable number */
73576 assert( z[0]=='?' );
73577 pExpr->iColumn = (ynVar)(++pParse->nVar);
73578 }else{
73579 ynVar x = 0;
73580 u32 n = sqlite3Strlen30(z);
73581 if( z[0]=='?' ){
73582 /* Wildcard of the form "?nnn". Convert "nnn" to an integer and
73583 ** use it as the variable number */
73584 i64 i;
73585 int bOk = 0==sqlite3Atoi64(&z[1], &i, n-1, SQLITE_UTF8);
73586 pExpr->iColumn = x = (ynVar)i;
73587 testcase( i==0 );
73588 testcase( i==1 );
73589 testcase( i==db->aLimit[SQLITE_LIMIT_VARIABLE_NUMBER]-1 );
73590 testcase( i==db->aLimit[SQLITE_LIMIT_VARIABLE_NUMBER] );
73591 if( bOk==0 || i<1 || i>db->aLimit[SQLITE_LIMIT_VARIABLE_NUMBER] ){
73592 sqlite3ErrorMsg(pParse, "variable number must be between ?1 and ?%d",
73593 db->aLimit[SQLITE_LIMIT_VARIABLE_NUMBER]);
73594 x = 0;
73596 if( i>pParse->nVar ){
73597 pParse->nVar = (int)i;
73599 }else{
73600 /* Wildcards like ":aaa", "$aaa" or "@aaa". Reuse the same variable
73601 ** number as the prior appearance of the same name, or if the name
73602 ** has never appeared before, reuse the same variable number
73604 ynVar i;
73605 for(i=0; i<pParse->nzVar; i++){
73606 if( pParse->azVar[i] && memcmp(pParse->azVar[i],z,n+1)==0 ){
73607 pExpr->iColumn = x = (ynVar)i+1;
73608 break;
73611 if( x==0 ) x = pExpr->iColumn = (ynVar)(++pParse->nVar);
73613 if( x>0 ){
73614 if( x>pParse->nzVar ){
73615 char **a;
73616 a = sqlite3DbRealloc(db, pParse->azVar, x*sizeof(a[0]));
73617 if( a==0 ) return; /* Error reported through db->mallocFailed */
73618 pParse->azVar = a;
73619 memset(&a[pParse->nzVar], 0, (x-pParse->nzVar)*sizeof(a[0]));
73620 pParse->nzVar = x;
73622 if( z[0]!='?' || pParse->azVar[x-1]==0 ){
73623 sqlite3DbFree(db, pParse->azVar[x-1]);
73624 pParse->azVar[x-1] = sqlite3DbStrNDup(db, z, n);
73628 if( !pParse->nErr && pParse->nVar>db->aLimit[SQLITE_LIMIT_VARIABLE_NUMBER] ){
73629 sqlite3ErrorMsg(pParse, "too many SQL variables");
73634 ** Recursively delete an expression tree.
73636 SQLITE_PRIVATE void sqlite3ExprDelete(sqlite3 *db, Expr *p){
73637 if( p==0 ) return;
73638 /* Sanity check: Assert that the IntValue is non-negative if it exists */
73639 assert( !ExprHasProperty(p, EP_IntValue) || p->u.iValue>=0 );
73640 if( !ExprHasAnyProperty(p, EP_TokenOnly) ){
73641 sqlite3ExprDelete(db, p->pLeft);
73642 sqlite3ExprDelete(db, p->pRight);
73643 if( !ExprHasProperty(p, EP_Reduced) && (p->flags2 & EP2_MallocedToken)!=0 ){
73644 sqlite3DbFree(db, p->u.zToken);
73646 if( ExprHasProperty(p, EP_xIsSelect) ){
73647 sqlite3SelectDelete(db, p->x.pSelect);
73648 }else{
73649 sqlite3ExprListDelete(db, p->x.pList);
73652 if( !ExprHasProperty(p, EP_Static) ){
73653 sqlite3DbFree(db, p);
73658 ** Return the number of bytes allocated for the expression structure
73659 ** passed as the first argument. This is always one of EXPR_FULLSIZE,
73660 ** EXPR_REDUCEDSIZE or EXPR_TOKENONLYSIZE.
73662 static int exprStructSize(Expr *p){
73663 if( ExprHasProperty(p, EP_TokenOnly) ) return EXPR_TOKENONLYSIZE;
73664 if( ExprHasProperty(p, EP_Reduced) ) return EXPR_REDUCEDSIZE;
73665 return EXPR_FULLSIZE;
73669 ** The dupedExpr*Size() routines each return the number of bytes required
73670 ** to store a copy of an expression or expression tree. They differ in
73671 ** how much of the tree is measured.
73673 ** dupedExprStructSize() Size of only the Expr structure
73674 ** dupedExprNodeSize() Size of Expr + space for token
73675 ** dupedExprSize() Expr + token + subtree components
73677 ***************************************************************************
73679 ** The dupedExprStructSize() function returns two values OR-ed together:
73680 ** (1) the space required for a copy of the Expr structure only and
73681 ** (2) the EP_xxx flags that indicate what the structure size should be.
73682 ** The return values is always one of:
73684 ** EXPR_FULLSIZE
73685 ** EXPR_REDUCEDSIZE | EP_Reduced
73686 ** EXPR_TOKENONLYSIZE | EP_TokenOnly
73688 ** The size of the structure can be found by masking the return value
73689 ** of this routine with 0xfff. The flags can be found by masking the
73690 ** return value with EP_Reduced|EP_TokenOnly.
73692 ** Note that with flags==EXPRDUP_REDUCE, this routines works on full-size
73693 ** (unreduced) Expr objects as they or originally constructed by the parser.
73694 ** During expression analysis, extra information is computed and moved into
73695 ** later parts of teh Expr object and that extra information might get chopped
73696 ** off if the expression is reduced. Note also that it does not work to
73697 ** make a EXPRDUP_REDUCE copy of a reduced expression. It is only legal
73698 ** to reduce a pristine expression tree from the parser. The implementation
73699 ** of dupedExprStructSize() contain multiple assert() statements that attempt
73700 ** to enforce this constraint.
73702 static int dupedExprStructSize(Expr *p, int flags){
73703 int nSize;
73704 assert( flags==EXPRDUP_REDUCE || flags==0 ); /* Only one flag value allowed */
73705 if( 0==(flags&EXPRDUP_REDUCE) ){
73706 nSize = EXPR_FULLSIZE;
73707 }else{
73708 assert( !ExprHasAnyProperty(p, EP_TokenOnly|EP_Reduced) );
73709 assert( !ExprHasProperty(p, EP_FromJoin) );
73710 assert( (p->flags2 & EP2_MallocedToken)==0 );
73711 assert( (p->flags2 & EP2_Irreducible)==0 );
73712 if( p->pLeft || p->pRight || p->pColl || p->x.pList ){
73713 nSize = EXPR_REDUCEDSIZE | EP_Reduced;
73714 }else{
73715 nSize = EXPR_TOKENONLYSIZE | EP_TokenOnly;
73718 return nSize;
73722 ** This function returns the space in bytes required to store the copy
73723 ** of the Expr structure and a copy of the Expr.u.zToken string (if that
73724 ** string is defined.)
73726 static int dupedExprNodeSize(Expr *p, int flags){
73727 int nByte = dupedExprStructSize(p, flags) & 0xfff;
73728 if( !ExprHasProperty(p, EP_IntValue) && p->u.zToken ){
73729 nByte += sqlite3Strlen30(p->u.zToken)+1;
73731 return ROUND8(nByte);
73735 ** Return the number of bytes required to create a duplicate of the
73736 ** expression passed as the first argument. The second argument is a
73737 ** mask containing EXPRDUP_XXX flags.
73739 ** The value returned includes space to create a copy of the Expr struct
73740 ** itself and the buffer referred to by Expr.u.zToken, if any.
73742 ** If the EXPRDUP_REDUCE flag is set, then the return value includes
73743 ** space to duplicate all Expr nodes in the tree formed by Expr.pLeft
73744 ** and Expr.pRight variables (but not for any structures pointed to or
73745 ** descended from the Expr.x.pList or Expr.x.pSelect variables).
73747 static int dupedExprSize(Expr *p, int flags){
73748 int nByte = 0;
73749 if( p ){
73750 nByte = dupedExprNodeSize(p, flags);
73751 if( flags&EXPRDUP_REDUCE ){
73752 nByte += dupedExprSize(p->pLeft, flags) + dupedExprSize(p->pRight, flags);
73755 return nByte;
73759 ** This function is similar to sqlite3ExprDup(), except that if pzBuffer
73760 ** is not NULL then *pzBuffer is assumed to point to a buffer large enough
73761 ** to store the copy of expression p, the copies of p->u.zToken
73762 ** (if applicable), and the copies of the p->pLeft and p->pRight expressions,
73763 ** if any. Before returning, *pzBuffer is set to the first byte passed the
73764 ** portion of the buffer copied into by this function.
73766 static Expr *exprDup(sqlite3 *db, Expr *p, int flags, u8 **pzBuffer){
73767 Expr *pNew = 0; /* Value to return */
73768 if( p ){
73769 const int isReduced = (flags&EXPRDUP_REDUCE);
73770 u8 *zAlloc;
73771 u32 staticFlag = 0;
73773 assert( pzBuffer==0 || isReduced );
73775 /* Figure out where to write the new Expr structure. */
73776 if( pzBuffer ){
73777 zAlloc = *pzBuffer;
73778 staticFlag = EP_Static;
73779 }else{
73780 zAlloc = sqlite3DbMallocRaw(db, dupedExprSize(p, flags));
73782 pNew = (Expr *)zAlloc;
73784 if( pNew ){
73785 /* Set nNewSize to the size allocated for the structure pointed to
73786 ** by pNew. This is either EXPR_FULLSIZE, EXPR_REDUCEDSIZE or
73787 ** EXPR_TOKENONLYSIZE. nToken is set to the number of bytes consumed
73788 ** by the copy of the p->u.zToken string (if any).
73790 const unsigned nStructSize = dupedExprStructSize(p, flags);
73791 const int nNewSize = nStructSize & 0xfff;
73792 int nToken;
73793 if( !ExprHasProperty(p, EP_IntValue) && p->u.zToken ){
73794 nToken = sqlite3Strlen30(p->u.zToken) + 1;
73795 }else{
73796 nToken = 0;
73798 if( isReduced ){
73799 assert( ExprHasProperty(p, EP_Reduced)==0 );
73800 memcpy(zAlloc, p, nNewSize);
73801 }else{
73802 int nSize = exprStructSize(p);
73803 memcpy(zAlloc, p, nSize);
73804 memset(&zAlloc[nSize], 0, EXPR_FULLSIZE-nSize);
73807 /* Set the EP_Reduced, EP_TokenOnly, and EP_Static flags appropriately. */
73808 pNew->flags &= ~(EP_Reduced|EP_TokenOnly|EP_Static);
73809 pNew->flags |= nStructSize & (EP_Reduced|EP_TokenOnly);
73810 pNew->flags |= staticFlag;
73812 /* Copy the p->u.zToken string, if any. */
73813 if( nToken ){
73814 char *zToken = pNew->u.zToken = (char*)&zAlloc[nNewSize];
73815 memcpy(zToken, p->u.zToken, nToken);
73818 if( 0==((p->flags|pNew->flags) & EP_TokenOnly) ){
73819 /* Fill in the pNew->x.pSelect or pNew->x.pList member. */
73820 if( ExprHasProperty(p, EP_xIsSelect) ){
73821 pNew->x.pSelect = sqlite3SelectDup(db, p->x.pSelect, isReduced);
73822 }else{
73823 pNew->x.pList = sqlite3ExprListDup(db, p->x.pList, isReduced);
73827 /* Fill in pNew->pLeft and pNew->pRight. */
73828 if( ExprHasAnyProperty(pNew, EP_Reduced|EP_TokenOnly) ){
73829 zAlloc += dupedExprNodeSize(p, flags);
73830 if( ExprHasProperty(pNew, EP_Reduced) ){
73831 pNew->pLeft = exprDup(db, p->pLeft, EXPRDUP_REDUCE, &zAlloc);
73832 pNew->pRight = exprDup(db, p->pRight, EXPRDUP_REDUCE, &zAlloc);
73834 if( pzBuffer ){
73835 *pzBuffer = zAlloc;
73837 }else{
73838 pNew->flags2 = 0;
73839 if( !ExprHasAnyProperty(p, EP_TokenOnly) ){
73840 pNew->pLeft = sqlite3ExprDup(db, p->pLeft, 0);
73841 pNew->pRight = sqlite3ExprDup(db, p->pRight, 0);
73847 return pNew;
73851 ** The following group of routines make deep copies of expressions,
73852 ** expression lists, ID lists, and select statements. The copies can
73853 ** be deleted (by being passed to their respective ...Delete() routines)
73854 ** without effecting the originals.
73856 ** The expression list, ID, and source lists return by sqlite3ExprListDup(),
73857 ** sqlite3IdListDup(), and sqlite3SrcListDup() can not be further expanded
73858 ** by subsequent calls to sqlite*ListAppend() routines.
73860 ** Any tables that the SrcList might point to are not duplicated.
73862 ** The flags parameter contains a combination of the EXPRDUP_XXX flags.
73863 ** If the EXPRDUP_REDUCE flag is set, then the structure returned is a
73864 ** truncated version of the usual Expr structure that will be stored as
73865 ** part of the in-memory representation of the database schema.
73867 SQLITE_PRIVATE Expr *sqlite3ExprDup(sqlite3 *db, Expr *p, int flags){
73868 return exprDup(db, p, flags, 0);
73870 SQLITE_PRIVATE ExprList *sqlite3ExprListDup(sqlite3 *db, ExprList *p, int flags){
73871 ExprList *pNew;
73872 struct ExprList_item *pItem, *pOldItem;
73873 int i;
73874 if( p==0 ) return 0;
73875 pNew = sqlite3DbMallocRaw(db, sizeof(*pNew) );
73876 if( pNew==0 ) return 0;
73877 pNew->iECursor = 0;
73878 pNew->nExpr = pNew->nAlloc = p->nExpr;
73879 pNew->a = pItem = sqlite3DbMallocRaw(db, p->nExpr*sizeof(p->a[0]) );
73880 if( pItem==0 ){
73881 sqlite3DbFree(db, pNew);
73882 return 0;
73884 pOldItem = p->a;
73885 for(i=0; i<p->nExpr; i++, pItem++, pOldItem++){
73886 Expr *pOldExpr = pOldItem->pExpr;
73887 pItem->pExpr = sqlite3ExprDup(db, pOldExpr, flags);
73888 pItem->zName = sqlite3DbStrDup(db, pOldItem->zName);
73889 pItem->zSpan = sqlite3DbStrDup(db, pOldItem->zSpan);
73890 pItem->sortOrder = pOldItem->sortOrder;
73891 pItem->done = 0;
73892 pItem->iCol = pOldItem->iCol;
73893 pItem->iAlias = pOldItem->iAlias;
73895 return pNew;
73899 ** If cursors, triggers, views and subqueries are all omitted from
73900 ** the build, then none of the following routines, except for
73901 ** sqlite3SelectDup(), can be called. sqlite3SelectDup() is sometimes
73902 ** called with a NULL argument.
73904 #if !defined(SQLITE_OMIT_VIEW) || !defined(SQLITE_OMIT_TRIGGER) \
73905 || !defined(SQLITE_OMIT_SUBQUERY)
73906 SQLITE_PRIVATE SrcList *sqlite3SrcListDup(sqlite3 *db, SrcList *p, int flags){
73907 SrcList *pNew;
73908 int i;
73909 int nByte;
73910 if( p==0 ) return 0;
73911 nByte = sizeof(*p) + (p->nSrc>0 ? sizeof(p->a[0]) * (p->nSrc-1) : 0);
73912 pNew = sqlite3DbMallocRaw(db, nByte );
73913 if( pNew==0 ) return 0;
73914 pNew->nSrc = pNew->nAlloc = p->nSrc;
73915 for(i=0; i<p->nSrc; i++){
73916 struct SrcList_item *pNewItem = &pNew->a[i];
73917 struct SrcList_item *pOldItem = &p->a[i];
73918 Table *pTab;
73919 pNewItem->zDatabase = sqlite3DbStrDup(db, pOldItem->zDatabase);
73920 pNewItem->zName = sqlite3DbStrDup(db, pOldItem->zName);
73921 pNewItem->zAlias = sqlite3DbStrDup(db, pOldItem->zAlias);
73922 pNewItem->jointype = pOldItem->jointype;
73923 pNewItem->iCursor = pOldItem->iCursor;
73924 pNewItem->addrFillSub = pOldItem->addrFillSub;
73925 pNewItem->regReturn = pOldItem->regReturn;
73926 pNewItem->isCorrelated = pOldItem->isCorrelated;
73927 pNewItem->zIndex = sqlite3DbStrDup(db, pOldItem->zIndex);
73928 pNewItem->notIndexed = pOldItem->notIndexed;
73929 pNewItem->pIndex = pOldItem->pIndex;
73930 pTab = pNewItem->pTab = pOldItem->pTab;
73931 if( pTab ){
73932 pTab->nRef++;
73934 pNewItem->pSelect = sqlite3SelectDup(db, pOldItem->pSelect, flags);
73935 pNewItem->pOn = sqlite3ExprDup(db, pOldItem->pOn, flags);
73936 pNewItem->pUsing = sqlite3IdListDup(db, pOldItem->pUsing);
73937 pNewItem->colUsed = pOldItem->colUsed;
73939 return pNew;
73941 SQLITE_PRIVATE IdList *sqlite3IdListDup(sqlite3 *db, IdList *p){
73942 IdList *pNew;
73943 int i;
73944 if( p==0 ) return 0;
73945 pNew = sqlite3DbMallocRaw(db, sizeof(*pNew) );
73946 if( pNew==0 ) return 0;
73947 pNew->nId = pNew->nAlloc = p->nId;
73948 pNew->a = sqlite3DbMallocRaw(db, p->nId*sizeof(p->a[0]) );
73949 if( pNew->a==0 ){
73950 sqlite3DbFree(db, pNew);
73951 return 0;
73953 for(i=0; i<p->nId; i++){
73954 struct IdList_item *pNewItem = &pNew->a[i];
73955 struct IdList_item *pOldItem = &p->a[i];
73956 pNewItem->zName = sqlite3DbStrDup(db, pOldItem->zName);
73957 pNewItem->idx = pOldItem->idx;
73959 return pNew;
73961 SQLITE_PRIVATE Select *sqlite3SelectDup(sqlite3 *db, Select *p, int flags){
73962 Select *pNew;
73963 if( p==0 ) return 0;
73964 pNew = sqlite3DbMallocRaw(db, sizeof(*p) );
73965 if( pNew==0 ) return 0;
73966 pNew->pEList = sqlite3ExprListDup(db, p->pEList, flags);
73967 pNew->pSrc = sqlite3SrcListDup(db, p->pSrc, flags);
73968 pNew->pWhere = sqlite3ExprDup(db, p->pWhere, flags);
73969 pNew->pGroupBy = sqlite3ExprListDup(db, p->pGroupBy, flags);
73970 pNew->pHaving = sqlite3ExprDup(db, p->pHaving, flags);
73971 pNew->pOrderBy = sqlite3ExprListDup(db, p->pOrderBy, flags);
73972 pNew->op = p->op;
73973 pNew->pPrior = sqlite3SelectDup(db, p->pPrior, flags);
73974 pNew->pLimit = sqlite3ExprDup(db, p->pLimit, flags);
73975 pNew->pOffset = sqlite3ExprDup(db, p->pOffset, flags);
73976 pNew->iLimit = 0;
73977 pNew->iOffset = 0;
73978 pNew->selFlags = p->selFlags & ~SF_UsesEphemeral;
73979 pNew->pRightmost = 0;
73980 pNew->addrOpenEphm[0] = -1;
73981 pNew->addrOpenEphm[1] = -1;
73982 pNew->addrOpenEphm[2] = -1;
73983 return pNew;
73985 #else
73986 SQLITE_PRIVATE Select *sqlite3SelectDup(sqlite3 *db, Select *p, int flags){
73987 assert( p==0 );
73988 return 0;
73990 #endif
73994 ** Add a new element to the end of an expression list. If pList is
73995 ** initially NULL, then create a new expression list.
73997 ** If a memory allocation error occurs, the entire list is freed and
73998 ** NULL is returned. If non-NULL is returned, then it is guaranteed
73999 ** that the new entry was successfully appended.
74001 SQLITE_PRIVATE ExprList *sqlite3ExprListAppend(
74002 Parse *pParse, /* Parsing context */
74003 ExprList *pList, /* List to which to append. Might be NULL */
74004 Expr *pExpr /* Expression to be appended. Might be NULL */
74006 sqlite3 *db = pParse->db;
74007 if( pList==0 ){
74008 pList = sqlite3DbMallocZero(db, sizeof(ExprList) );
74009 if( pList==0 ){
74010 goto no_mem;
74012 assert( pList->nAlloc==0 );
74014 if( pList->nAlloc<=pList->nExpr ){
74015 struct ExprList_item *a;
74016 int n = pList->nAlloc*2 + 4;
74017 a = sqlite3DbRealloc(db, pList->a, n*sizeof(pList->a[0]));
74018 if( a==0 ){
74019 goto no_mem;
74021 pList->a = a;
74022 pList->nAlloc = sqlite3DbMallocSize(db, a)/sizeof(a[0]);
74024 assert( pList->a!=0 );
74025 if( 1 ){
74026 struct ExprList_item *pItem = &pList->a[pList->nExpr++];
74027 memset(pItem, 0, sizeof(*pItem));
74028 pItem->pExpr = pExpr;
74030 return pList;
74032 no_mem:
74033 /* Avoid leaking memory if malloc has failed. */
74034 sqlite3ExprDelete(db, pExpr);
74035 sqlite3ExprListDelete(db, pList);
74036 return 0;
74040 ** Set the ExprList.a[].zName element of the most recently added item
74041 ** on the expression list.
74043 ** pList might be NULL following an OOM error. But pName should never be
74044 ** NULL. If a memory allocation fails, the pParse->db->mallocFailed flag
74045 ** is set.
74047 SQLITE_PRIVATE void sqlite3ExprListSetName(
74048 Parse *pParse, /* Parsing context */
74049 ExprList *pList, /* List to which to add the span. */
74050 Token *pName, /* Name to be added */
74051 int dequote /* True to cause the name to be dequoted */
74053 assert( pList!=0 || pParse->db->mallocFailed!=0 );
74054 if( pList ){
74055 struct ExprList_item *pItem;
74056 assert( pList->nExpr>0 );
74057 pItem = &pList->a[pList->nExpr-1];
74058 assert( pItem->zName==0 );
74059 pItem->zName = sqlite3DbStrNDup(pParse->db, pName->z, pName->n);
74060 if( dequote && pItem->zName ) sqlite3Dequote(pItem->zName);
74065 ** Set the ExprList.a[].zSpan element of the most recently added item
74066 ** on the expression list.
74068 ** pList might be NULL following an OOM error. But pSpan should never be
74069 ** NULL. If a memory allocation fails, the pParse->db->mallocFailed flag
74070 ** is set.
74072 SQLITE_PRIVATE void sqlite3ExprListSetSpan(
74073 Parse *pParse, /* Parsing context */
74074 ExprList *pList, /* List to which to add the span. */
74075 ExprSpan *pSpan /* The span to be added */
74077 sqlite3 *db = pParse->db;
74078 assert( pList!=0 || db->mallocFailed!=0 );
74079 if( pList ){
74080 struct ExprList_item *pItem = &pList->a[pList->nExpr-1];
74081 assert( pList->nExpr>0 );
74082 assert( db->mallocFailed || pItem->pExpr==pSpan->pExpr );
74083 sqlite3DbFree(db, pItem->zSpan);
74084 pItem->zSpan = sqlite3DbStrNDup(db, (char*)pSpan->zStart,
74085 (int)(pSpan->zEnd - pSpan->zStart));
74090 ** If the expression list pEList contains more than iLimit elements,
74091 ** leave an error message in pParse.
74093 SQLITE_PRIVATE void sqlite3ExprListCheckLength(
74094 Parse *pParse,
74095 ExprList *pEList,
74096 const char *zObject
74098 int mx = pParse->db->aLimit[SQLITE_LIMIT_COLUMN];
74099 testcase( pEList && pEList->nExpr==mx );
74100 testcase( pEList && pEList->nExpr==mx+1 );
74101 if( pEList && pEList->nExpr>mx ){
74102 sqlite3ErrorMsg(pParse, "too many columns in %s", zObject);
74107 ** Delete an entire expression list.
74109 SQLITE_PRIVATE void sqlite3ExprListDelete(sqlite3 *db, ExprList *pList){
74110 int i;
74111 struct ExprList_item *pItem;
74112 if( pList==0 ) return;
74113 assert( pList->a!=0 || (pList->nExpr==0 && pList->nAlloc==0) );
74114 assert( pList->nExpr<=pList->nAlloc );
74115 for(pItem=pList->a, i=0; i<pList->nExpr; i++, pItem++){
74116 sqlite3ExprDelete(db, pItem->pExpr);
74117 sqlite3DbFree(db, pItem->zName);
74118 sqlite3DbFree(db, pItem->zSpan);
74120 sqlite3DbFree(db, pList->a);
74121 sqlite3DbFree(db, pList);
74125 ** These routines are Walker callbacks. Walker.u.pi is a pointer
74126 ** to an integer. These routines are checking an expression to see
74127 ** if it is a constant. Set *Walker.u.pi to 0 if the expression is
74128 ** not constant.
74130 ** These callback routines are used to implement the following:
74132 ** sqlite3ExprIsConstant()
74133 ** sqlite3ExprIsConstantNotJoin()
74134 ** sqlite3ExprIsConstantOrFunction()
74137 static int exprNodeIsConstant(Walker *pWalker, Expr *pExpr){
74139 /* If pWalker->u.i is 3 then any term of the expression that comes from
74140 ** the ON or USING clauses of a join disqualifies the expression
74141 ** from being considered constant. */
74142 if( pWalker->u.i==3 && ExprHasAnyProperty(pExpr, EP_FromJoin) ){
74143 pWalker->u.i = 0;
74144 return WRC_Abort;
74147 switch( pExpr->op ){
74148 /* Consider functions to be constant if all their arguments are constant
74149 ** and pWalker->u.i==2 */
74150 case TK_FUNCTION:
74151 if( pWalker->u.i==2 ) return 0;
74152 /* Fall through */
74153 case TK_ID:
74154 case TK_COLUMN:
74155 case TK_AGG_FUNCTION:
74156 case TK_AGG_COLUMN:
74157 testcase( pExpr->op==TK_ID );
74158 testcase( pExpr->op==TK_COLUMN );
74159 testcase( pExpr->op==TK_AGG_FUNCTION );
74160 testcase( pExpr->op==TK_AGG_COLUMN );
74161 pWalker->u.i = 0;
74162 return WRC_Abort;
74163 default:
74164 testcase( pExpr->op==TK_SELECT ); /* selectNodeIsConstant will disallow */
74165 testcase( pExpr->op==TK_EXISTS ); /* selectNodeIsConstant will disallow */
74166 return WRC_Continue;
74169 static int selectNodeIsConstant(Walker *pWalker, Select *NotUsed){
74170 UNUSED_PARAMETER(NotUsed);
74171 pWalker->u.i = 0;
74172 return WRC_Abort;
74174 static int exprIsConst(Expr *p, int initFlag){
74175 Walker w;
74176 w.u.i = initFlag;
74177 w.xExprCallback = exprNodeIsConstant;
74178 w.xSelectCallback = selectNodeIsConstant;
74179 sqlite3WalkExpr(&w, p);
74180 return w.u.i;
74184 ** Walk an expression tree. Return 1 if the expression is constant
74185 ** and 0 if it involves variables or function calls.
74187 ** For the purposes of this function, a double-quoted string (ex: "abc")
74188 ** is considered a variable but a single-quoted string (ex: 'abc') is
74189 ** a constant.
74191 SQLITE_PRIVATE int sqlite3ExprIsConstant(Expr *p){
74192 return exprIsConst(p, 1);
74196 ** Walk an expression tree. Return 1 if the expression is constant
74197 ** that does no originate from the ON or USING clauses of a join.
74198 ** Return 0 if it involves variables or function calls or terms from
74199 ** an ON or USING clause.
74201 SQLITE_PRIVATE int sqlite3ExprIsConstantNotJoin(Expr *p){
74202 return exprIsConst(p, 3);
74206 ** Walk an expression tree. Return 1 if the expression is constant
74207 ** or a function call with constant arguments. Return and 0 if there
74208 ** are any variables.
74210 ** For the purposes of this function, a double-quoted string (ex: "abc")
74211 ** is considered a variable but a single-quoted string (ex: 'abc') is
74212 ** a constant.
74214 SQLITE_PRIVATE int sqlite3ExprIsConstantOrFunction(Expr *p){
74215 return exprIsConst(p, 2);
74219 ** If the expression p codes a constant integer that is small enough
74220 ** to fit in a 32-bit integer, return 1 and put the value of the integer
74221 ** in *pValue. If the expression is not an integer or if it is too big
74222 ** to fit in a signed 32-bit integer, return 0 and leave *pValue unchanged.
74224 SQLITE_PRIVATE int sqlite3ExprIsInteger(Expr *p, int *pValue){
74225 int rc = 0;
74227 /* If an expression is an integer literal that fits in a signed 32-bit
74228 ** integer, then the EP_IntValue flag will have already been set */
74229 assert( p->op!=TK_INTEGER || (p->flags & EP_IntValue)!=0
74230 || sqlite3GetInt32(p->u.zToken, &rc)==0 );
74232 if( p->flags & EP_IntValue ){
74233 *pValue = p->u.iValue;
74234 return 1;
74236 switch( p->op ){
74237 case TK_UPLUS: {
74238 rc = sqlite3ExprIsInteger(p->pLeft, pValue);
74239 break;
74241 case TK_UMINUS: {
74242 int v;
74243 if( sqlite3ExprIsInteger(p->pLeft, &v) ){
74244 *pValue = -v;
74245 rc = 1;
74247 break;
74249 default: break;
74251 return rc;
74255 ** Return FALSE if there is no chance that the expression can be NULL.
74257 ** If the expression might be NULL or if the expression is too complex
74258 ** to tell return TRUE.
74260 ** This routine is used as an optimization, to skip OP_IsNull opcodes
74261 ** when we know that a value cannot be NULL. Hence, a false positive
74262 ** (returning TRUE when in fact the expression can never be NULL) might
74263 ** be a small performance hit but is otherwise harmless. On the other
74264 ** hand, a false negative (returning FALSE when the result could be NULL)
74265 ** will likely result in an incorrect answer. So when in doubt, return
74266 ** TRUE.
74268 SQLITE_PRIVATE int sqlite3ExprCanBeNull(const Expr *p){
74269 u8 op;
74270 while( p->op==TK_UPLUS || p->op==TK_UMINUS ){ p = p->pLeft; }
74271 op = p->op;
74272 if( op==TK_REGISTER ) op = p->op2;
74273 switch( op ){
74274 case TK_INTEGER:
74275 case TK_STRING:
74276 case TK_FLOAT:
74277 case TK_BLOB:
74278 return 0;
74279 default:
74280 return 1;
74285 ** Generate an OP_IsNull instruction that tests register iReg and jumps
74286 ** to location iDest if the value in iReg is NULL. The value in iReg
74287 ** was computed by pExpr. If we can look at pExpr at compile-time and
74288 ** determine that it can never generate a NULL, then the OP_IsNull operation
74289 ** can be omitted.
74291 SQLITE_PRIVATE void sqlite3ExprCodeIsNullJump(
74292 Vdbe *v, /* The VDBE under construction */
74293 const Expr *pExpr, /* Only generate OP_IsNull if this expr can be NULL */
74294 int iReg, /* Test the value in this register for NULL */
74295 int iDest /* Jump here if the value is null */
74297 if( sqlite3ExprCanBeNull(pExpr) ){
74298 sqlite3VdbeAddOp2(v, OP_IsNull, iReg, iDest);
74303 ** Return TRUE if the given expression is a constant which would be
74304 ** unchanged by OP_Affinity with the affinity given in the second
74305 ** argument.
74307 ** This routine is used to determine if the OP_Affinity operation
74308 ** can be omitted. When in doubt return FALSE. A false negative
74309 ** is harmless. A false positive, however, can result in the wrong
74310 ** answer.
74312 SQLITE_PRIVATE int sqlite3ExprNeedsNoAffinityChange(const Expr *p, char aff){
74313 u8 op;
74314 if( aff==SQLITE_AFF_NONE ) return 1;
74315 while( p->op==TK_UPLUS || p->op==TK_UMINUS ){ p = p->pLeft; }
74316 op = p->op;
74317 if( op==TK_REGISTER ) op = p->op2;
74318 switch( op ){
74319 case TK_INTEGER: {
74320 return aff==SQLITE_AFF_INTEGER || aff==SQLITE_AFF_NUMERIC;
74322 case TK_FLOAT: {
74323 return aff==SQLITE_AFF_REAL || aff==SQLITE_AFF_NUMERIC;
74325 case TK_STRING: {
74326 return aff==SQLITE_AFF_TEXT;
74328 case TK_BLOB: {
74329 return 1;
74331 case TK_COLUMN: {
74332 assert( p->iTable>=0 ); /* p cannot be part of a CHECK constraint */
74333 return p->iColumn<0
74334 && (aff==SQLITE_AFF_INTEGER || aff==SQLITE_AFF_NUMERIC);
74336 default: {
74337 return 0;
74343 ** Return TRUE if the given string is a row-id column name.
74345 SQLITE_PRIVATE int sqlite3IsRowid(const char *z){
74346 if( sqlite3StrICmp(z, "_ROWID_")==0 ) return 1;
74347 if( sqlite3StrICmp(z, "ROWID")==0 ) return 1;
74348 if( sqlite3StrICmp(z, "OID")==0 ) return 1;
74349 return 0;
74353 ** Return true if we are able to the IN operator optimization on a
74354 ** query of the form
74356 ** x IN (SELECT ...)
74358 ** Where the SELECT... clause is as specified by the parameter to this
74359 ** routine.
74361 ** The Select object passed in has already been preprocessed and no
74362 ** errors have been found.
74364 #ifndef SQLITE_OMIT_SUBQUERY
74365 static int isCandidateForInOpt(Select *p){
74366 SrcList *pSrc;
74367 ExprList *pEList;
74368 Table *pTab;
74369 if( p==0 ) return 0; /* right-hand side of IN is SELECT */
74370 if( p->pPrior ) return 0; /* Not a compound SELECT */
74371 if( p->selFlags & (SF_Distinct|SF_Aggregate) ){
74372 testcase( (p->selFlags & (SF_Distinct|SF_Aggregate))==SF_Distinct );
74373 testcase( (p->selFlags & (SF_Distinct|SF_Aggregate))==SF_Aggregate );
74374 return 0; /* No DISTINCT keyword and no aggregate functions */
74376 assert( p->pGroupBy==0 ); /* Has no GROUP BY clause */
74377 if( p->pLimit ) return 0; /* Has no LIMIT clause */
74378 assert( p->pOffset==0 ); /* No LIMIT means no OFFSET */
74379 if( p->pWhere ) return 0; /* Has no WHERE clause */
74380 pSrc = p->pSrc;
74381 assert( pSrc!=0 );
74382 if( pSrc->nSrc!=1 ) return 0; /* Single term in FROM clause */
74383 if( pSrc->a[0].pSelect ) return 0; /* FROM is not a subquery or view */
74384 pTab = pSrc->a[0].pTab;
74385 if( NEVER(pTab==0) ) return 0;
74386 assert( pTab->pSelect==0 ); /* FROM clause is not a view */
74387 if( IsVirtual(pTab) ) return 0; /* FROM clause not a virtual table */
74388 pEList = p->pEList;
74389 if( pEList->nExpr!=1 ) return 0; /* One column in the result set */
74390 if( pEList->a[0].pExpr->op!=TK_COLUMN ) return 0; /* Result is a column */
74391 return 1;
74393 #endif /* SQLITE_OMIT_SUBQUERY */
74396 ** This function is used by the implementation of the IN (...) operator.
74397 ** It's job is to find or create a b-tree structure that may be used
74398 ** either to test for membership of the (...) set or to iterate through
74399 ** its members, skipping duplicates.
74401 ** The index of the cursor opened on the b-tree (database table, database index
74402 ** or ephermal table) is stored in pX->iTable before this function returns.
74403 ** The returned value of this function indicates the b-tree type, as follows:
74405 ** IN_INDEX_ROWID - The cursor was opened on a database table.
74406 ** IN_INDEX_INDEX - The cursor was opened on a database index.
74407 ** IN_INDEX_EPH - The cursor was opened on a specially created and
74408 ** populated epheremal table.
74410 ** An existing b-tree may only be used if the SELECT is of the simple
74411 ** form:
74413 ** SELECT <column> FROM <table>
74415 ** If the prNotFound parameter is 0, then the b-tree will be used to iterate
74416 ** through the set members, skipping any duplicates. In this case an
74417 ** epheremal table must be used unless the selected <column> is guaranteed
74418 ** to be unique - either because it is an INTEGER PRIMARY KEY or it
74419 ** has a UNIQUE constraint or UNIQUE index.
74421 ** If the prNotFound parameter is not 0, then the b-tree will be used
74422 ** for fast set membership tests. In this case an epheremal table must
74423 ** be used unless <column> is an INTEGER PRIMARY KEY or an index can
74424 ** be found with <column> as its left-most column.
74426 ** When the b-tree is being used for membership tests, the calling function
74427 ** needs to know whether or not the structure contains an SQL NULL
74428 ** value in order to correctly evaluate expressions like "X IN (Y, Z)".
74429 ** If there is any chance that the (...) might contain a NULL value at
74430 ** runtime, then a register is allocated and the register number written
74431 ** to *prNotFound. If there is no chance that the (...) contains a
74432 ** NULL value, then *prNotFound is left unchanged.
74434 ** If a register is allocated and its location stored in *prNotFound, then
74435 ** its initial value is NULL. If the (...) does not remain constant
74436 ** for the duration of the query (i.e. the SELECT within the (...)
74437 ** is a correlated subquery) then the value of the allocated register is
74438 ** reset to NULL each time the subquery is rerun. This allows the
74439 ** caller to use vdbe code equivalent to the following:
74441 ** if( register==NULL ){
74442 ** has_null = <test if data structure contains null>
74443 ** register = 1
74444 ** }
74446 ** in order to avoid running the <test if data structure contains null>
74447 ** test more often than is necessary.
74449 #ifndef SQLITE_OMIT_SUBQUERY
74450 SQLITE_PRIVATE int sqlite3FindInIndex(Parse *pParse, Expr *pX, int *prNotFound){
74451 Select *p; /* SELECT to the right of IN operator */
74452 int eType = 0; /* Type of RHS table. IN_INDEX_* */
74453 int iTab = pParse->nTab++; /* Cursor of the RHS table */
74454 int mustBeUnique = (prNotFound==0); /* True if RHS must be unique */
74456 assert( pX->op==TK_IN );
74458 /* Check to see if an existing table or index can be used to
74459 ** satisfy the query. This is preferable to generating a new
74460 ** ephemeral table.
74462 p = (ExprHasProperty(pX, EP_xIsSelect) ? pX->x.pSelect : 0);
74463 if( ALWAYS(pParse->nErr==0) && isCandidateForInOpt(p) ){
74464 sqlite3 *db = pParse->db; /* Database connection */
74465 Expr *pExpr = p->pEList->a[0].pExpr; /* Expression <column> */
74466 int iCol = pExpr->iColumn; /* Index of column <column> */
74467 Vdbe *v = sqlite3GetVdbe(pParse); /* Virtual machine being coded */
74468 Table *pTab = p->pSrc->a[0].pTab; /* Table <table>. */
74469 int iDb; /* Database idx for pTab */
74471 /* Code an OP_VerifyCookie and OP_TableLock for <table>. */
74472 iDb = sqlite3SchemaToIndex(db, pTab->pSchema);
74473 sqlite3CodeVerifySchema(pParse, iDb);
74474 sqlite3TableLock(pParse, iDb, pTab->tnum, 0, pTab->zName);
74476 /* This function is only called from two places. In both cases the vdbe
74477 ** has already been allocated. So assume sqlite3GetVdbe() is always
74478 ** successful here.
74480 assert(v);
74481 if( iCol<0 ){
74482 int iMem = ++pParse->nMem;
74483 int iAddr;
74485 iAddr = sqlite3VdbeAddOp1(v, OP_Once, iMem);
74487 sqlite3OpenTable(pParse, iTab, iDb, pTab, OP_OpenRead);
74488 eType = IN_INDEX_ROWID;
74490 sqlite3VdbeJumpHere(v, iAddr);
74491 }else{
74492 Index *pIdx; /* Iterator variable */
74494 /* The collation sequence used by the comparison. If an index is to
74495 ** be used in place of a temp-table, it must be ordered according
74496 ** to this collation sequence. */
74497 CollSeq *pReq = sqlite3BinaryCompareCollSeq(pParse, pX->pLeft, pExpr);
74499 /* Check that the affinity that will be used to perform the
74500 ** comparison is the same as the affinity of the column. If
74501 ** it is not, it is not possible to use any index.
74503 char aff = comparisonAffinity(pX);
74504 int affinity_ok = (pTab->aCol[iCol].affinity==aff||aff==SQLITE_AFF_NONE);
74506 for(pIdx=pTab->pIndex; pIdx && eType==0 && affinity_ok; pIdx=pIdx->pNext){
74507 if( (pIdx->aiColumn[0]==iCol)
74508 && sqlite3FindCollSeq(db, ENC(db), pIdx->azColl[0], 0)==pReq
74509 && (!mustBeUnique || (pIdx->nColumn==1 && pIdx->onError!=OE_None))
74511 int iMem = ++pParse->nMem;
74512 int iAddr;
74513 char *pKey;
74515 pKey = (char *)sqlite3IndexKeyinfo(pParse, pIdx);
74516 iAddr = sqlite3VdbeAddOp1(v, OP_Once, iMem);
74518 sqlite3VdbeAddOp4(v, OP_OpenRead, iTab, pIdx->tnum, iDb,
74519 pKey,P4_KEYINFO_HANDOFF);
74520 VdbeComment((v, "%s", pIdx->zName));
74521 eType = IN_INDEX_INDEX;
74523 sqlite3VdbeJumpHere(v, iAddr);
74524 if( prNotFound && !pTab->aCol[iCol].notNull ){
74525 *prNotFound = ++pParse->nMem;
74532 if( eType==0 ){
74533 /* Could not found an existing table or index to use as the RHS b-tree.
74534 ** We will have to generate an ephemeral table to do the job.
74536 double savedNQueryLoop = pParse->nQueryLoop;
74537 int rMayHaveNull = 0;
74538 eType = IN_INDEX_EPH;
74539 if( prNotFound ){
74540 *prNotFound = rMayHaveNull = ++pParse->nMem;
74541 }else{
74542 testcase( pParse->nQueryLoop>(double)1 );
74543 pParse->nQueryLoop = (double)1;
74544 if( pX->pLeft->iColumn<0 && !ExprHasAnyProperty(pX, EP_xIsSelect) ){
74545 eType = IN_INDEX_ROWID;
74548 sqlite3CodeSubselect(pParse, pX, rMayHaveNull, eType==IN_INDEX_ROWID);
74549 pParse->nQueryLoop = savedNQueryLoop;
74550 }else{
74551 pX->iTable = iTab;
74553 return eType;
74555 #endif
74558 ** Generate code for scalar subqueries used as a subquery expression, EXISTS,
74559 ** or IN operators. Examples:
74561 ** (SELECT a FROM b) -- subquery
74562 ** EXISTS (SELECT a FROM b) -- EXISTS subquery
74563 ** x IN (4,5,11) -- IN operator with list on right-hand side
74564 ** x IN (SELECT a FROM b) -- IN operator with subquery on the right
74566 ** The pExpr parameter describes the expression that contains the IN
74567 ** operator or subquery.
74569 ** If parameter isRowid is non-zero, then expression pExpr is guaranteed
74570 ** to be of the form "<rowid> IN (?, ?, ?)", where <rowid> is a reference
74571 ** to some integer key column of a table B-Tree. In this case, use an
74572 ** intkey B-Tree to store the set of IN(...) values instead of the usual
74573 ** (slower) variable length keys B-Tree.
74575 ** If rMayHaveNull is non-zero, that means that the operation is an IN
74576 ** (not a SELECT or EXISTS) and that the RHS might contains NULLs.
74577 ** Furthermore, the IN is in a WHERE clause and that we really want
74578 ** to iterate over the RHS of the IN operator in order to quickly locate
74579 ** all corresponding LHS elements. All this routine does is initialize
74580 ** the register given by rMayHaveNull to NULL. Calling routines will take
74581 ** care of changing this register value to non-NULL if the RHS is NULL-free.
74583 ** If rMayHaveNull is zero, that means that the subquery is being used
74584 ** for membership testing only. There is no need to initialize any
74585 ** registers to indicate the presense or absence of NULLs on the RHS.
74587 ** For a SELECT or EXISTS operator, return the register that holds the
74588 ** result. For IN operators or if an error occurs, the return value is 0.
74590 #ifndef SQLITE_OMIT_SUBQUERY
74591 SQLITE_PRIVATE int sqlite3CodeSubselect(
74592 Parse *pParse, /* Parsing context */
74593 Expr *pExpr, /* The IN, SELECT, or EXISTS operator */
74594 int rMayHaveNull, /* Register that records whether NULLs exist in RHS */
74595 int isRowid /* If true, LHS of IN operator is a rowid */
74597 int testAddr = -1; /* One-time test address */
74598 int rReg = 0; /* Register storing resulting */
74599 Vdbe *v = sqlite3GetVdbe(pParse);
74600 if( NEVER(v==0) ) return 0;
74601 sqlite3ExprCachePush(pParse);
74603 /* This code must be run in its entirety every time it is encountered
74604 ** if any of the following is true:
74606 ** * The right-hand side is a correlated subquery
74607 ** * The right-hand side is an expression list containing variables
74608 ** * We are inside a trigger
74610 ** If all of the above are false, then we can run this code just once
74611 ** save the results, and reuse the same result on subsequent invocations.
74613 if( !ExprHasAnyProperty(pExpr, EP_VarSelect) && !pParse->pTriggerTab ){
74614 int mem = ++pParse->nMem;
74615 testAddr = sqlite3VdbeAddOp1(v, OP_Once, mem);
74618 #ifndef SQLITE_OMIT_EXPLAIN
74619 if( pParse->explain==2 ){
74620 char *zMsg = sqlite3MPrintf(
74621 pParse->db, "EXECUTE %s%s SUBQUERY %d", testAddr>=0?"":"CORRELATED ",
74622 pExpr->op==TK_IN?"LIST":"SCALAR", pParse->iNextSelectId
74624 sqlite3VdbeAddOp4(v, OP_Explain, pParse->iSelectId, 0, 0, zMsg, P4_DYNAMIC);
74626 #endif
74628 switch( pExpr->op ){
74629 case TK_IN: {
74630 char affinity; /* Affinity of the LHS of the IN */
74631 KeyInfo keyInfo; /* Keyinfo for the generated table */
74632 int addr; /* Address of OP_OpenEphemeral instruction */
74633 Expr *pLeft = pExpr->pLeft; /* the LHS of the IN operator */
74635 if( rMayHaveNull ){
74636 sqlite3VdbeAddOp2(v, OP_Null, 0, rMayHaveNull);
74639 affinity = sqlite3ExprAffinity(pLeft);
74641 /* Whether this is an 'x IN(SELECT...)' or an 'x IN(<exprlist>)'
74642 ** expression it is handled the same way. An ephemeral table is
74643 ** filled with single-field index keys representing the results
74644 ** from the SELECT or the <exprlist>.
74646 ** If the 'x' expression is a column value, or the SELECT...
74647 ** statement returns a column value, then the affinity of that
74648 ** column is used to build the index keys. If both 'x' and the
74649 ** SELECT... statement are columns, then numeric affinity is used
74650 ** if either column has NUMERIC or INTEGER affinity. If neither
74651 ** 'x' nor the SELECT... statement are columns, then numeric affinity
74652 ** is used.
74654 pExpr->iTable = pParse->nTab++;
74655 addr = sqlite3VdbeAddOp2(v, OP_OpenEphemeral, pExpr->iTable, !isRowid);
74656 if( rMayHaveNull==0 ) sqlite3VdbeChangeP5(v, BTREE_UNORDERED);
74657 memset(&keyInfo, 0, sizeof(keyInfo));
74658 keyInfo.nField = 1;
74660 if( ExprHasProperty(pExpr, EP_xIsSelect) ){
74661 /* Case 1: expr IN (SELECT ...)
74663 ** Generate code to write the results of the select into the temporary
74664 ** table allocated and opened above.
74666 SelectDest dest;
74667 ExprList *pEList;
74669 assert( !isRowid );
74670 sqlite3SelectDestInit(&dest, SRT_Set, pExpr->iTable);
74671 dest.affinity = (u8)affinity;
74672 assert( (pExpr->iTable&0x0000FFFF)==pExpr->iTable );
74673 pExpr->x.pSelect->iLimit = 0;
74674 if( sqlite3Select(pParse, pExpr->x.pSelect, &dest) ){
74675 return 0;
74677 pEList = pExpr->x.pSelect->pEList;
74678 if( ALWAYS(pEList!=0 && pEList->nExpr>0) ){
74679 keyInfo.aColl[0] = sqlite3BinaryCompareCollSeq(pParse, pExpr->pLeft,
74680 pEList->a[0].pExpr);
74682 }else if( ALWAYS(pExpr->x.pList!=0) ){
74683 /* Case 2: expr IN (exprlist)
74685 ** For each expression, build an index key from the evaluation and
74686 ** store it in the temporary table. If <expr> is a column, then use
74687 ** that columns affinity when building index keys. If <expr> is not
74688 ** a column, use numeric affinity.
74690 int i;
74691 ExprList *pList = pExpr->x.pList;
74692 struct ExprList_item *pItem;
74693 int r1, r2, r3;
74695 if( !affinity ){
74696 affinity = SQLITE_AFF_NONE;
74698 keyInfo.aColl[0] = sqlite3ExprCollSeq(pParse, pExpr->pLeft);
74700 /* Loop through each expression in <exprlist>. */
74701 r1 = sqlite3GetTempReg(pParse);
74702 r2 = sqlite3GetTempReg(pParse);
74703 sqlite3VdbeAddOp2(v, OP_Null, 0, r2);
74704 for(i=pList->nExpr, pItem=pList->a; i>0; i--, pItem++){
74705 Expr *pE2 = pItem->pExpr;
74706 int iValToIns;
74708 /* If the expression is not constant then we will need to
74709 ** disable the test that was generated above that makes sure
74710 ** this code only executes once. Because for a non-constant
74711 ** expression we need to rerun this code each time.
74713 if( testAddr>=0 && !sqlite3ExprIsConstant(pE2) ){
74714 sqlite3VdbeChangeToNoop(v, testAddr);
74715 testAddr = -1;
74718 /* Evaluate the expression and insert it into the temp table */
74719 if( isRowid && sqlite3ExprIsInteger(pE2, &iValToIns) ){
74720 sqlite3VdbeAddOp3(v, OP_InsertInt, pExpr->iTable, r2, iValToIns);
74721 }else{
74722 r3 = sqlite3ExprCodeTarget(pParse, pE2, r1);
74723 if( isRowid ){
74724 sqlite3VdbeAddOp2(v, OP_MustBeInt, r3,
74725 sqlite3VdbeCurrentAddr(v)+2);
74726 sqlite3VdbeAddOp3(v, OP_Insert, pExpr->iTable, r2, r3);
74727 }else{
74728 sqlite3VdbeAddOp4(v, OP_MakeRecord, r3, 1, r2, &affinity, 1);
74729 sqlite3ExprCacheAffinityChange(pParse, r3, 1);
74730 sqlite3VdbeAddOp2(v, OP_IdxInsert, pExpr->iTable, r2);
74734 sqlite3ReleaseTempReg(pParse, r1);
74735 sqlite3ReleaseTempReg(pParse, r2);
74737 if( !isRowid ){
74738 sqlite3VdbeChangeP4(v, addr, (void *)&keyInfo, P4_KEYINFO);
74740 break;
74743 case TK_EXISTS:
74744 case TK_SELECT:
74745 default: {
74746 /* If this has to be a scalar SELECT. Generate code to put the
74747 ** value of this select in a memory cell and record the number
74748 ** of the memory cell in iColumn. If this is an EXISTS, write
74749 ** an integer 0 (not exists) or 1 (exists) into a memory cell
74750 ** and record that memory cell in iColumn.
74752 Select *pSel; /* SELECT statement to encode */
74753 SelectDest dest; /* How to deal with SELECt result */
74755 testcase( pExpr->op==TK_EXISTS );
74756 testcase( pExpr->op==TK_SELECT );
74757 assert( pExpr->op==TK_EXISTS || pExpr->op==TK_SELECT );
74759 assert( ExprHasProperty(pExpr, EP_xIsSelect) );
74760 pSel = pExpr->x.pSelect;
74761 sqlite3SelectDestInit(&dest, 0, ++pParse->nMem);
74762 if( pExpr->op==TK_SELECT ){
74763 dest.eDest = SRT_Mem;
74764 sqlite3VdbeAddOp2(v, OP_Null, 0, dest.iParm);
74765 VdbeComment((v, "Init subquery result"));
74766 }else{
74767 dest.eDest = SRT_Exists;
74768 sqlite3VdbeAddOp2(v, OP_Integer, 0, dest.iParm);
74769 VdbeComment((v, "Init EXISTS result"));
74771 sqlite3ExprDelete(pParse->db, pSel->pLimit);
74772 pSel->pLimit = sqlite3PExpr(pParse, TK_INTEGER, 0, 0,
74773 &sqlite3IntTokens[1]);
74774 pSel->iLimit = 0;
74775 if( sqlite3Select(pParse, pSel, &dest) ){
74776 return 0;
74778 rReg = dest.iParm;
74779 ExprSetIrreducible(pExpr);
74780 break;
74784 if( testAddr>=0 ){
74785 sqlite3VdbeJumpHere(v, testAddr);
74787 sqlite3ExprCachePop(pParse, 1);
74789 return rReg;
74791 #endif /* SQLITE_OMIT_SUBQUERY */
74793 #ifndef SQLITE_OMIT_SUBQUERY
74795 ** Generate code for an IN expression.
74797 ** x IN (SELECT ...)
74798 ** x IN (value, value, ...)
74800 ** The left-hand side (LHS) is a scalar expression. The right-hand side (RHS)
74801 ** is an array of zero or more values. The expression is true if the LHS is
74802 ** contained within the RHS. The value of the expression is unknown (NULL)
74803 ** if the LHS is NULL or if the LHS is not contained within the RHS and the
74804 ** RHS contains one or more NULL values.
74806 ** This routine generates code will jump to destIfFalse if the LHS is not
74807 ** contained within the RHS. If due to NULLs we cannot determine if the LHS
74808 ** is contained in the RHS then jump to destIfNull. If the LHS is contained
74809 ** within the RHS then fall through.
74811 static void sqlite3ExprCodeIN(
74812 Parse *pParse, /* Parsing and code generating context */
74813 Expr *pExpr, /* The IN expression */
74814 int destIfFalse, /* Jump here if LHS is not contained in the RHS */
74815 int destIfNull /* Jump here if the results are unknown due to NULLs */
74817 int rRhsHasNull = 0; /* Register that is true if RHS contains NULL values */
74818 char affinity; /* Comparison affinity to use */
74819 int eType; /* Type of the RHS */
74820 int r1; /* Temporary use register */
74821 Vdbe *v; /* Statement under construction */
74823 /* Compute the RHS. After this step, the table with cursor
74824 ** pExpr->iTable will contains the values that make up the RHS.
74826 v = pParse->pVdbe;
74827 assert( v!=0 ); /* OOM detected prior to this routine */
74828 VdbeNoopComment((v, "begin IN expr"));
74829 eType = sqlite3FindInIndex(pParse, pExpr, &rRhsHasNull);
74831 /* Figure out the affinity to use to create a key from the results
74832 ** of the expression. affinityStr stores a static string suitable for
74833 ** P4 of OP_MakeRecord.
74835 affinity = comparisonAffinity(pExpr);
74837 /* Code the LHS, the <expr> from "<expr> IN (...)".
74839 sqlite3ExprCachePush(pParse);
74840 r1 = sqlite3GetTempReg(pParse);
74841 sqlite3ExprCode(pParse, pExpr->pLeft, r1);
74843 /* If the LHS is NULL, then the result is either false or NULL depending
74844 ** on whether the RHS is empty or not, respectively.
74846 if( destIfNull==destIfFalse ){
74847 /* Shortcut for the common case where the false and NULL outcomes are
74848 ** the same. */
74849 sqlite3VdbeAddOp2(v, OP_IsNull, r1, destIfNull);
74850 }else{
74851 int addr1 = sqlite3VdbeAddOp1(v, OP_NotNull, r1);
74852 sqlite3VdbeAddOp2(v, OP_Rewind, pExpr->iTable, destIfFalse);
74853 sqlite3VdbeAddOp2(v, OP_Goto, 0, destIfNull);
74854 sqlite3VdbeJumpHere(v, addr1);
74857 if( eType==IN_INDEX_ROWID ){
74858 /* In this case, the RHS is the ROWID of table b-tree
74860 sqlite3VdbeAddOp2(v, OP_MustBeInt, r1, destIfFalse);
74861 sqlite3VdbeAddOp3(v, OP_NotExists, pExpr->iTable, destIfFalse, r1);
74862 }else{
74863 /* In this case, the RHS is an index b-tree.
74865 sqlite3VdbeAddOp4(v, OP_Affinity, r1, 1, 0, &affinity, 1);
74867 /* If the set membership test fails, then the result of the
74868 ** "x IN (...)" expression must be either 0 or NULL. If the set
74869 ** contains no NULL values, then the result is 0. If the set
74870 ** contains one or more NULL values, then the result of the
74871 ** expression is also NULL.
74873 if( rRhsHasNull==0 || destIfFalse==destIfNull ){
74874 /* This branch runs if it is known at compile time that the RHS
74875 ** cannot contain NULL values. This happens as the result
74876 ** of a "NOT NULL" constraint in the database schema.
74878 ** Also run this branch if NULL is equivalent to FALSE
74879 ** for this particular IN operator.
74881 sqlite3VdbeAddOp4Int(v, OP_NotFound, pExpr->iTable, destIfFalse, r1, 1);
74883 }else{
74884 /* In this branch, the RHS of the IN might contain a NULL and
74885 ** the presence of a NULL on the RHS makes a difference in the
74886 ** outcome.
74888 int j1, j2, j3;
74890 /* First check to see if the LHS is contained in the RHS. If so,
74891 ** then the presence of NULLs in the RHS does not matter, so jump
74892 ** over all of the code that follows.
74894 j1 = sqlite3VdbeAddOp4Int(v, OP_Found, pExpr->iTable, 0, r1, 1);
74896 /* Here we begin generating code that runs if the LHS is not
74897 ** contained within the RHS. Generate additional code that
74898 ** tests the RHS for NULLs. If the RHS contains a NULL then
74899 ** jump to destIfNull. If there are no NULLs in the RHS then
74900 ** jump to destIfFalse.
74902 j2 = sqlite3VdbeAddOp1(v, OP_NotNull, rRhsHasNull);
74903 j3 = sqlite3VdbeAddOp4Int(v, OP_Found, pExpr->iTable, 0, rRhsHasNull, 1);
74904 sqlite3VdbeAddOp2(v, OP_Integer, -1, rRhsHasNull);
74905 sqlite3VdbeJumpHere(v, j3);
74906 sqlite3VdbeAddOp2(v, OP_AddImm, rRhsHasNull, 1);
74907 sqlite3VdbeJumpHere(v, j2);
74909 /* Jump to the appropriate target depending on whether or not
74910 ** the RHS contains a NULL
74912 sqlite3VdbeAddOp2(v, OP_If, rRhsHasNull, destIfNull);
74913 sqlite3VdbeAddOp2(v, OP_Goto, 0, destIfFalse);
74915 /* The OP_Found at the top of this branch jumps here when true,
74916 ** causing the overall IN expression evaluation to fall through.
74918 sqlite3VdbeJumpHere(v, j1);
74921 sqlite3ReleaseTempReg(pParse, r1);
74922 sqlite3ExprCachePop(pParse, 1);
74923 VdbeComment((v, "end IN expr"));
74925 #endif /* SQLITE_OMIT_SUBQUERY */
74928 ** Duplicate an 8-byte value
74930 static char *dup8bytes(Vdbe *v, const char *in){
74931 char *out = sqlite3DbMallocRaw(sqlite3VdbeDb(v), 8);
74932 if( out ){
74933 memcpy(out, in, 8);
74935 return out;
74938 #ifndef SQLITE_OMIT_FLOATING_POINT
74940 ** Generate an instruction that will put the floating point
74941 ** value described by z[0..n-1] into register iMem.
74943 ** The z[] string will probably not be zero-terminated. But the
74944 ** z[n] character is guaranteed to be something that does not look
74945 ** like the continuation of the number.
74947 static void codeReal(Vdbe *v, const char *z, int negateFlag, int iMem){
74948 if( ALWAYS(z!=0) ){
74949 double value;
74950 char *zV;
74951 sqlite3AtoF(z, &value, sqlite3Strlen30(z), SQLITE_UTF8);
74952 assert( !sqlite3IsNaN(value) ); /* The new AtoF never returns NaN */
74953 if( negateFlag ) value = -value;
74954 zV = dup8bytes(v, (char*)&value);
74955 sqlite3VdbeAddOp4(v, OP_Real, 0, iMem, 0, zV, P4_REAL);
74958 #endif
74962 ** Generate an instruction that will put the integer describe by
74963 ** text z[0..n-1] into register iMem.
74965 ** Expr.u.zToken is always UTF8 and zero-terminated.
74967 static void codeInteger(Parse *pParse, Expr *pExpr, int negFlag, int iMem){
74968 Vdbe *v = pParse->pVdbe;
74969 if( pExpr->flags & EP_IntValue ){
74970 int i = pExpr->u.iValue;
74971 assert( i>=0 );
74972 if( negFlag ) i = -i;
74973 sqlite3VdbeAddOp2(v, OP_Integer, i, iMem);
74974 }else{
74975 int c;
74976 i64 value;
74977 const char *z = pExpr->u.zToken;
74978 assert( z!=0 );
74979 c = sqlite3Atoi64(z, &value, sqlite3Strlen30(z), SQLITE_UTF8);
74980 if( c==0 || (c==2 && negFlag) ){
74981 char *zV;
74982 if( negFlag ){ value = c==2 ? SMALLEST_INT64 : -value; }
74983 zV = dup8bytes(v, (char*)&value);
74984 sqlite3VdbeAddOp4(v, OP_Int64, 0, iMem, 0, zV, P4_INT64);
74985 }else{
74986 #ifdef SQLITE_OMIT_FLOATING_POINT
74987 sqlite3ErrorMsg(pParse, "oversized integer: %s%s", negFlag ? "-" : "", z);
74988 #else
74989 codeReal(v, z, negFlag, iMem);
74990 #endif
74996 ** Clear a cache entry.
74998 static void cacheEntryClear(Parse *pParse, struct yColCache *p){
74999 if( p->tempReg ){
75000 if( pParse->nTempReg<ArraySize(pParse->aTempReg) ){
75001 pParse->aTempReg[pParse->nTempReg++] = p->iReg;
75003 p->tempReg = 0;
75009 ** Record in the column cache that a particular column from a
75010 ** particular table is stored in a particular register.
75012 SQLITE_PRIVATE void sqlite3ExprCacheStore(Parse *pParse, int iTab, int iCol, int iReg){
75013 int i;
75014 int minLru;
75015 int idxLru;
75016 struct yColCache *p;
75018 assert( iReg>0 ); /* Register numbers are always positive */
75019 assert( iCol>=-1 && iCol<32768 ); /* Finite column numbers */
75021 /* The SQLITE_ColumnCache flag disables the column cache. This is used
75022 ** for testing only - to verify that SQLite always gets the same answer
75023 ** with and without the column cache.
75025 if( pParse->db->flags & SQLITE_ColumnCache ) return;
75027 /* First replace any existing entry.
75029 ** Actually, the way the column cache is currently used, we are guaranteed
75030 ** that the object will never already be in cache. Verify this guarantee.
75032 #ifndef NDEBUG
75033 for(i=0, p=pParse->aColCache; i<SQLITE_N_COLCACHE; i++, p++){
75034 #if 0 /* This code wold remove the entry from the cache if it existed */
75035 if( p->iReg && p->iTable==iTab && p->iColumn==iCol ){
75036 cacheEntryClear(pParse, p);
75037 p->iLevel = pParse->iCacheLevel;
75038 p->iReg = iReg;
75039 p->lru = pParse->iCacheCnt++;
75040 return;
75042 #endif
75043 assert( p->iReg==0 || p->iTable!=iTab || p->iColumn!=iCol );
75045 #endif
75047 /* Find an empty slot and replace it */
75048 for(i=0, p=pParse->aColCache; i<SQLITE_N_COLCACHE; i++, p++){
75049 if( p->iReg==0 ){
75050 p->iLevel = pParse->iCacheLevel;
75051 p->iTable = iTab;
75052 p->iColumn = iCol;
75053 p->iReg = iReg;
75054 p->tempReg = 0;
75055 p->lru = pParse->iCacheCnt++;
75056 return;
75060 /* Replace the last recently used */
75061 minLru = 0x7fffffff;
75062 idxLru = -1;
75063 for(i=0, p=pParse->aColCache; i<SQLITE_N_COLCACHE; i++, p++){
75064 if( p->lru<minLru ){
75065 idxLru = i;
75066 minLru = p->lru;
75069 if( ALWAYS(idxLru>=0) ){
75070 p = &pParse->aColCache[idxLru];
75071 p->iLevel = pParse->iCacheLevel;
75072 p->iTable = iTab;
75073 p->iColumn = iCol;
75074 p->iReg = iReg;
75075 p->tempReg = 0;
75076 p->lru = pParse->iCacheCnt++;
75077 return;
75082 ** Indicate that registers between iReg..iReg+nReg-1 are being overwritten.
75083 ** Purge the range of registers from the column cache.
75085 SQLITE_PRIVATE void sqlite3ExprCacheRemove(Parse *pParse, int iReg, int nReg){
75086 int i;
75087 int iLast = iReg + nReg - 1;
75088 struct yColCache *p;
75089 for(i=0, p=pParse->aColCache; i<SQLITE_N_COLCACHE; i++, p++){
75090 int r = p->iReg;
75091 if( r>=iReg && r<=iLast ){
75092 cacheEntryClear(pParse, p);
75093 p->iReg = 0;
75099 ** Remember the current column cache context. Any new entries added
75100 ** added to the column cache after this call are removed when the
75101 ** corresponding pop occurs.
75103 SQLITE_PRIVATE void sqlite3ExprCachePush(Parse *pParse){
75104 pParse->iCacheLevel++;
75108 ** Remove from the column cache any entries that were added since the
75109 ** the previous N Push operations. In other words, restore the cache
75110 ** to the state it was in N Pushes ago.
75112 SQLITE_PRIVATE void sqlite3ExprCachePop(Parse *pParse, int N){
75113 int i;
75114 struct yColCache *p;
75115 assert( N>0 );
75116 assert( pParse->iCacheLevel>=N );
75117 pParse->iCacheLevel -= N;
75118 for(i=0, p=pParse->aColCache; i<SQLITE_N_COLCACHE; i++, p++){
75119 if( p->iReg && p->iLevel>pParse->iCacheLevel ){
75120 cacheEntryClear(pParse, p);
75121 p->iReg = 0;
75127 ** When a cached column is reused, make sure that its register is
75128 ** no longer available as a temp register. ticket #3879: that same
75129 ** register might be in the cache in multiple places, so be sure to
75130 ** get them all.
75132 static void sqlite3ExprCachePinRegister(Parse *pParse, int iReg){
75133 int i;
75134 struct yColCache *p;
75135 for(i=0, p=pParse->aColCache; i<SQLITE_N_COLCACHE; i++, p++){
75136 if( p->iReg==iReg ){
75137 p->tempReg = 0;
75143 ** Generate code to extract the value of the iCol-th column of a table.
75145 SQLITE_PRIVATE void sqlite3ExprCodeGetColumnOfTable(
75146 Vdbe *v, /* The VDBE under construction */
75147 Table *pTab, /* The table containing the value */
75148 int iTabCur, /* The cursor for this table */
75149 int iCol, /* Index of the column to extract */
75150 int regOut /* Extract the valud into this register */
75152 if( iCol<0 || iCol==pTab->iPKey ){
75153 sqlite3VdbeAddOp2(v, OP_Rowid, iTabCur, regOut);
75154 }else{
75155 int op = IsVirtual(pTab) ? OP_VColumn : OP_Column;
75156 sqlite3VdbeAddOp3(v, op, iTabCur, iCol, regOut);
75158 if( iCol>=0 ){
75159 sqlite3ColumnDefault(v, pTab, iCol, regOut);
75164 ** Generate code that will extract the iColumn-th column from
75165 ** table pTab and store the column value in a register. An effort
75166 ** is made to store the column value in register iReg, but this is
75167 ** not guaranteed. The location of the column value is returned.
75169 ** There must be an open cursor to pTab in iTable when this routine
75170 ** is called. If iColumn<0 then code is generated that extracts the rowid.
75172 SQLITE_PRIVATE int sqlite3ExprCodeGetColumn(
75173 Parse *pParse, /* Parsing and code generating context */
75174 Table *pTab, /* Description of the table we are reading from */
75175 int iColumn, /* Index of the table column */
75176 int iTable, /* The cursor pointing to the table */
75177 int iReg /* Store results here */
75179 Vdbe *v = pParse->pVdbe;
75180 int i;
75181 struct yColCache *p;
75183 for(i=0, p=pParse->aColCache; i<SQLITE_N_COLCACHE; i++, p++){
75184 if( p->iReg>0 && p->iTable==iTable && p->iColumn==iColumn ){
75185 p->lru = pParse->iCacheCnt++;
75186 sqlite3ExprCachePinRegister(pParse, p->iReg);
75187 return p->iReg;
75190 assert( v!=0 );
75191 sqlite3ExprCodeGetColumnOfTable(v, pTab, iTable, iColumn, iReg);
75192 sqlite3ExprCacheStore(pParse, iTable, iColumn, iReg);
75193 return iReg;
75197 ** Clear all column cache entries.
75199 SQLITE_PRIVATE void sqlite3ExprCacheClear(Parse *pParse){
75200 int i;
75201 struct yColCache *p;
75203 for(i=0, p=pParse->aColCache; i<SQLITE_N_COLCACHE; i++, p++){
75204 if( p->iReg ){
75205 cacheEntryClear(pParse, p);
75206 p->iReg = 0;
75212 ** Record the fact that an affinity change has occurred on iCount
75213 ** registers starting with iStart.
75215 SQLITE_PRIVATE void sqlite3ExprCacheAffinityChange(Parse *pParse, int iStart, int iCount){
75216 sqlite3ExprCacheRemove(pParse, iStart, iCount);
75220 ** Generate code to move content from registers iFrom...iFrom+nReg-1
75221 ** over to iTo..iTo+nReg-1. Keep the column cache up-to-date.
75223 SQLITE_PRIVATE void sqlite3ExprCodeMove(Parse *pParse, int iFrom, int iTo, int nReg){
75224 int i;
75225 struct yColCache *p;
75226 if( NEVER(iFrom==iTo) ) return;
75227 sqlite3VdbeAddOp3(pParse->pVdbe, OP_Move, iFrom, iTo, nReg);
75228 for(i=0, p=pParse->aColCache; i<SQLITE_N_COLCACHE; i++, p++){
75229 int x = p->iReg;
75230 if( x>=iFrom && x<iFrom+nReg ){
75231 p->iReg += iTo-iFrom;
75237 ** Generate code to copy content from registers iFrom...iFrom+nReg-1
75238 ** over to iTo..iTo+nReg-1.
75240 SQLITE_PRIVATE void sqlite3ExprCodeCopy(Parse *pParse, int iFrom, int iTo, int nReg){
75241 int i;
75242 if( NEVER(iFrom==iTo) ) return;
75243 for(i=0; i<nReg; i++){
75244 sqlite3VdbeAddOp2(pParse->pVdbe, OP_Copy, iFrom+i, iTo+i);
75248 #if defined(SQLITE_DEBUG) || defined(SQLITE_COVERAGE_TEST)
75250 ** Return true if any register in the range iFrom..iTo (inclusive)
75251 ** is used as part of the column cache.
75253 ** This routine is used within assert() and testcase() macros only
75254 ** and does not appear in a normal build.
75256 static int usedAsColumnCache(Parse *pParse, int iFrom, int iTo){
75257 int i;
75258 struct yColCache *p;
75259 for(i=0, p=pParse->aColCache; i<SQLITE_N_COLCACHE; i++, p++){
75260 int r = p->iReg;
75261 if( r>=iFrom && r<=iTo ) return 1; /*NO_TEST*/
75263 return 0;
75265 #endif /* SQLITE_DEBUG || SQLITE_COVERAGE_TEST */
75268 ** Generate code into the current Vdbe to evaluate the given
75269 ** expression. Attempt to store the results in register "target".
75270 ** Return the register where results are stored.
75272 ** With this routine, there is no guarantee that results will
75273 ** be stored in target. The result might be stored in some other
75274 ** register if it is convenient to do so. The calling function
75275 ** must check the return code and move the results to the desired
75276 ** register.
75278 SQLITE_PRIVATE int sqlite3ExprCodeTarget(Parse *pParse, Expr *pExpr, int target){
75279 Vdbe *v = pParse->pVdbe; /* The VM under construction */
75280 int op; /* The opcode being coded */
75281 int inReg = target; /* Results stored in register inReg */
75282 int regFree1 = 0; /* If non-zero free this temporary register */
75283 int regFree2 = 0; /* If non-zero free this temporary register */
75284 int r1, r2, r3, r4; /* Various register numbers */
75285 sqlite3 *db = pParse->db; /* The database connection */
75287 assert( target>0 && target<=pParse->nMem );
75288 if( v==0 ){
75289 assert( pParse->db->mallocFailed );
75290 return 0;
75293 if( pExpr==0 ){
75294 op = TK_NULL;
75295 }else{
75296 op = pExpr->op;
75298 switch( op ){
75299 case TK_AGG_COLUMN: {
75300 AggInfo *pAggInfo = pExpr->pAggInfo;
75301 struct AggInfo_col *pCol = &pAggInfo->aCol[pExpr->iAgg];
75302 if( !pAggInfo->directMode ){
75303 assert( pCol->iMem>0 );
75304 inReg = pCol->iMem;
75305 break;
75306 }else if( pAggInfo->useSortingIdx ){
75307 sqlite3VdbeAddOp3(v, OP_Column, pAggInfo->sortingIdxPTab,
75308 pCol->iSorterColumn, target);
75309 break;
75311 /* Otherwise, fall thru into the TK_COLUMN case */
75313 case TK_COLUMN: {
75314 if( pExpr->iTable<0 ){
75315 /* This only happens when coding check constraints */
75316 assert( pParse->ckBase>0 );
75317 inReg = pExpr->iColumn + pParse->ckBase;
75318 }else{
75319 inReg = sqlite3ExprCodeGetColumn(pParse, pExpr->pTab,
75320 pExpr->iColumn, pExpr->iTable, target);
75322 break;
75324 case TK_INTEGER: {
75325 codeInteger(pParse, pExpr, 0, target);
75326 break;
75328 #ifndef SQLITE_OMIT_FLOATING_POINT
75329 case TK_FLOAT: {
75330 assert( !ExprHasProperty(pExpr, EP_IntValue) );
75331 codeReal(v, pExpr->u.zToken, 0, target);
75332 break;
75334 #endif
75335 case TK_STRING: {
75336 assert( !ExprHasProperty(pExpr, EP_IntValue) );
75337 sqlite3VdbeAddOp4(v, OP_String8, 0, target, 0, pExpr->u.zToken, 0);
75338 break;
75340 case TK_NULL: {
75341 sqlite3VdbeAddOp2(v, OP_Null, 0, target);
75342 break;
75344 #ifndef SQLITE_OMIT_BLOB_LITERAL
75345 case TK_BLOB: {
75346 int n;
75347 const char *z;
75348 char *zBlob;
75349 assert( !ExprHasProperty(pExpr, EP_IntValue) );
75350 assert( pExpr->u.zToken[0]=='x' || pExpr->u.zToken[0]=='X' );
75351 assert( pExpr->u.zToken[1]=='\'' );
75352 z = &pExpr->u.zToken[2];
75353 n = sqlite3Strlen30(z) - 1;
75354 assert( z[n]=='\'' );
75355 zBlob = sqlite3HexToBlob(sqlite3VdbeDb(v), z, n);
75356 sqlite3VdbeAddOp4(v, OP_Blob, n/2, target, 0, zBlob, P4_DYNAMIC);
75357 break;
75359 #endif
75360 case TK_VARIABLE: {
75361 assert( !ExprHasProperty(pExpr, EP_IntValue) );
75362 assert( pExpr->u.zToken!=0 );
75363 assert( pExpr->u.zToken[0]!=0 );
75364 sqlite3VdbeAddOp2(v, OP_Variable, pExpr->iColumn, target);
75365 if( pExpr->u.zToken[1]!=0 ){
75366 assert( pExpr->u.zToken[0]=='?'
75367 || strcmp(pExpr->u.zToken, pParse->azVar[pExpr->iColumn-1])==0 );
75368 sqlite3VdbeChangeP4(v, -1, pParse->azVar[pExpr->iColumn-1], P4_STATIC);
75370 break;
75372 case TK_REGISTER: {
75373 inReg = pExpr->iTable;
75374 break;
75376 case TK_AS: {
75377 inReg = sqlite3ExprCodeTarget(pParse, pExpr->pLeft, target);
75378 break;
75380 #ifndef SQLITE_OMIT_CAST
75381 case TK_CAST: {
75382 /* Expressions of the form: CAST(pLeft AS token) */
75383 int aff, to_op;
75384 inReg = sqlite3ExprCodeTarget(pParse, pExpr->pLeft, target);
75385 assert( !ExprHasProperty(pExpr, EP_IntValue) );
75386 aff = sqlite3AffinityType(pExpr->u.zToken);
75387 to_op = aff - SQLITE_AFF_TEXT + OP_ToText;
75388 assert( to_op==OP_ToText || aff!=SQLITE_AFF_TEXT );
75389 assert( to_op==OP_ToBlob || aff!=SQLITE_AFF_NONE );
75390 assert( to_op==OP_ToNumeric || aff!=SQLITE_AFF_NUMERIC );
75391 assert( to_op==OP_ToInt || aff!=SQLITE_AFF_INTEGER );
75392 assert( to_op==OP_ToReal || aff!=SQLITE_AFF_REAL );
75393 testcase( to_op==OP_ToText );
75394 testcase( to_op==OP_ToBlob );
75395 testcase( to_op==OP_ToNumeric );
75396 testcase( to_op==OP_ToInt );
75397 testcase( to_op==OP_ToReal );
75398 if( inReg!=target ){
75399 sqlite3VdbeAddOp2(v, OP_SCopy, inReg, target);
75400 inReg = target;
75402 sqlite3VdbeAddOp1(v, to_op, inReg);
75403 testcase( usedAsColumnCache(pParse, inReg, inReg) );
75404 sqlite3ExprCacheAffinityChange(pParse, inReg, 1);
75405 break;
75407 #endif /* SQLITE_OMIT_CAST */
75408 case TK_LT:
75409 case TK_LE:
75410 case TK_GT:
75411 case TK_GE:
75412 case TK_NE:
75413 case TK_EQ: {
75414 assert( TK_LT==OP_Lt );
75415 assert( TK_LE==OP_Le );
75416 assert( TK_GT==OP_Gt );
75417 assert( TK_GE==OP_Ge );
75418 assert( TK_EQ==OP_Eq );
75419 assert( TK_NE==OP_Ne );
75420 testcase( op==TK_LT );
75421 testcase( op==TK_LE );
75422 testcase( op==TK_GT );
75423 testcase( op==TK_GE );
75424 testcase( op==TK_EQ );
75425 testcase( op==TK_NE );
75426 r1 = sqlite3ExprCodeTemp(pParse, pExpr->pLeft, &regFree1);
75427 r2 = sqlite3ExprCodeTemp(pParse, pExpr->pRight, &regFree2);
75428 codeCompare(pParse, pExpr->pLeft, pExpr->pRight, op,
75429 r1, r2, inReg, SQLITE_STOREP2);
75430 testcase( regFree1==0 );
75431 testcase( regFree2==0 );
75432 break;
75434 case TK_IS:
75435 case TK_ISNOT: {
75436 testcase( op==TK_IS );
75437 testcase( op==TK_ISNOT );
75438 r1 = sqlite3ExprCodeTemp(pParse, pExpr->pLeft, &regFree1);
75439 r2 = sqlite3ExprCodeTemp(pParse, pExpr->pRight, &regFree2);
75440 op = (op==TK_IS) ? TK_EQ : TK_NE;
75441 codeCompare(pParse, pExpr->pLeft, pExpr->pRight, op,
75442 r1, r2, inReg, SQLITE_STOREP2 | SQLITE_NULLEQ);
75443 testcase( regFree1==0 );
75444 testcase( regFree2==0 );
75445 break;
75447 case TK_AND:
75448 case TK_OR:
75449 case TK_PLUS:
75450 case TK_STAR:
75451 case TK_MINUS:
75452 case TK_REM:
75453 case TK_BITAND:
75454 case TK_BITOR:
75455 case TK_SLASH:
75456 case TK_LSHIFT:
75457 case TK_RSHIFT:
75458 case TK_CONCAT: {
75459 assert( TK_AND==OP_And );
75460 assert( TK_OR==OP_Or );
75461 assert( TK_PLUS==OP_Add );
75462 assert( TK_MINUS==OP_Subtract );
75463 assert( TK_REM==OP_Remainder );
75464 assert( TK_BITAND==OP_BitAnd );
75465 assert( TK_BITOR==OP_BitOr );
75466 assert( TK_SLASH==OP_Divide );
75467 assert( TK_LSHIFT==OP_ShiftLeft );
75468 assert( TK_RSHIFT==OP_ShiftRight );
75469 assert( TK_CONCAT==OP_Concat );
75470 testcase( op==TK_AND );
75471 testcase( op==TK_OR );
75472 testcase( op==TK_PLUS );
75473 testcase( op==TK_MINUS );
75474 testcase( op==TK_REM );
75475 testcase( op==TK_BITAND );
75476 testcase( op==TK_BITOR );
75477 testcase( op==TK_SLASH );
75478 testcase( op==TK_LSHIFT );
75479 testcase( op==TK_RSHIFT );
75480 testcase( op==TK_CONCAT );
75481 r1 = sqlite3ExprCodeTemp(pParse, pExpr->pLeft, &regFree1);
75482 r2 = sqlite3ExprCodeTemp(pParse, pExpr->pRight, &regFree2);
75483 sqlite3VdbeAddOp3(v, op, r2, r1, target);
75484 testcase( regFree1==0 );
75485 testcase( regFree2==0 );
75486 break;
75488 case TK_UMINUS: {
75489 Expr *pLeft = pExpr->pLeft;
75490 assert( pLeft );
75491 if( pLeft->op==TK_INTEGER ){
75492 codeInteger(pParse, pLeft, 1, target);
75493 #ifndef SQLITE_OMIT_FLOATING_POINT
75494 }else if( pLeft->op==TK_FLOAT ){
75495 assert( !ExprHasProperty(pExpr, EP_IntValue) );
75496 codeReal(v, pLeft->u.zToken, 1, target);
75497 #endif
75498 }else{
75499 regFree1 = r1 = sqlite3GetTempReg(pParse);
75500 sqlite3VdbeAddOp2(v, OP_Integer, 0, r1);
75501 r2 = sqlite3ExprCodeTemp(pParse, pExpr->pLeft, &regFree2);
75502 sqlite3VdbeAddOp3(v, OP_Subtract, r2, r1, target);
75503 testcase( regFree2==0 );
75505 inReg = target;
75506 break;
75508 case TK_BITNOT:
75509 case TK_NOT: {
75510 assert( TK_BITNOT==OP_BitNot );
75511 assert( TK_NOT==OP_Not );
75512 testcase( op==TK_BITNOT );
75513 testcase( op==TK_NOT );
75514 r1 = sqlite3ExprCodeTemp(pParse, pExpr->pLeft, &regFree1);
75515 testcase( regFree1==0 );
75516 inReg = target;
75517 sqlite3VdbeAddOp2(v, op, r1, inReg);
75518 break;
75520 case TK_ISNULL:
75521 case TK_NOTNULL: {
75522 int addr;
75523 assert( TK_ISNULL==OP_IsNull );
75524 assert( TK_NOTNULL==OP_NotNull );
75525 testcase( op==TK_ISNULL );
75526 testcase( op==TK_NOTNULL );
75527 sqlite3VdbeAddOp2(v, OP_Integer, 1, target);
75528 r1 = sqlite3ExprCodeTemp(pParse, pExpr->pLeft, &regFree1);
75529 testcase( regFree1==0 );
75530 addr = sqlite3VdbeAddOp1(v, op, r1);
75531 sqlite3VdbeAddOp2(v, OP_AddImm, target, -1);
75532 sqlite3VdbeJumpHere(v, addr);
75533 break;
75535 case TK_AGG_FUNCTION: {
75536 AggInfo *pInfo = pExpr->pAggInfo;
75537 if( pInfo==0 ){
75538 assert( !ExprHasProperty(pExpr, EP_IntValue) );
75539 sqlite3ErrorMsg(pParse, "misuse of aggregate: %s()", pExpr->u.zToken);
75540 }else{
75541 inReg = pInfo->aFunc[pExpr->iAgg].iMem;
75543 break;
75545 case TK_CONST_FUNC:
75546 case TK_FUNCTION: {
75547 ExprList *pFarg; /* List of function arguments */
75548 int nFarg; /* Number of function arguments */
75549 FuncDef *pDef; /* The function definition object */
75550 int nId; /* Length of the function name in bytes */
75551 const char *zId; /* The function name */
75552 int constMask = 0; /* Mask of function arguments that are constant */
75553 int i; /* Loop counter */
75554 u8 enc = ENC(db); /* The text encoding used by this database */
75555 CollSeq *pColl = 0; /* A collating sequence */
75557 assert( !ExprHasProperty(pExpr, EP_xIsSelect) );
75558 testcase( op==TK_CONST_FUNC );
75559 testcase( op==TK_FUNCTION );
75560 if( ExprHasAnyProperty(pExpr, EP_TokenOnly) ){
75561 pFarg = 0;
75562 }else{
75563 pFarg = pExpr->x.pList;
75565 nFarg = pFarg ? pFarg->nExpr : 0;
75566 assert( !ExprHasProperty(pExpr, EP_IntValue) );
75567 zId = pExpr->u.zToken;
75568 nId = sqlite3Strlen30(zId);
75569 pDef = sqlite3FindFunction(db, zId, nId, nFarg, enc, 0);
75570 if( pDef==0 ){
75571 sqlite3ErrorMsg(pParse, "unknown function: %.*s()", nId, zId);
75572 break;
75575 /* Attempt a direct implementation of the built-in COALESCE() and
75576 ** IFNULL() functions. This avoids unnecessary evalation of
75577 ** arguments past the first non-NULL argument.
75579 if( pDef->flags & SQLITE_FUNC_COALESCE ){
75580 int endCoalesce = sqlite3VdbeMakeLabel(v);
75581 assert( nFarg>=2 );
75582 sqlite3ExprCode(pParse, pFarg->a[0].pExpr, target);
75583 for(i=1; i<nFarg; i++){
75584 sqlite3VdbeAddOp2(v, OP_NotNull, target, endCoalesce);
75585 sqlite3ExprCacheRemove(pParse, target, 1);
75586 sqlite3ExprCachePush(pParse);
75587 sqlite3ExprCode(pParse, pFarg->a[i].pExpr, target);
75588 sqlite3ExprCachePop(pParse, 1);
75590 sqlite3VdbeResolveLabel(v, endCoalesce);
75591 break;
75595 if( pFarg ){
75596 r1 = sqlite3GetTempRange(pParse, nFarg);
75597 sqlite3ExprCachePush(pParse); /* Ticket 2ea2425d34be */
75598 sqlite3ExprCodeExprList(pParse, pFarg, r1, 1);
75599 sqlite3ExprCachePop(pParse, 1); /* Ticket 2ea2425d34be */
75600 }else{
75601 r1 = 0;
75603 #ifndef SQLITE_OMIT_VIRTUALTABLE
75604 /* Possibly overload the function if the first argument is
75605 ** a virtual table column.
75607 ** For infix functions (LIKE, GLOB, REGEXP, and MATCH) use the
75608 ** second argument, not the first, as the argument to test to
75609 ** see if it is a column in a virtual table. This is done because
75610 ** the left operand of infix functions (the operand we want to
75611 ** control overloading) ends up as the second argument to the
75612 ** function. The expression "A glob B" is equivalent to
75613 ** "glob(B,A). We want to use the A in "A glob B" to test
75614 ** for function overloading. But we use the B term in "glob(B,A)".
75616 if( nFarg>=2 && (pExpr->flags & EP_InfixFunc) ){
75617 pDef = sqlite3VtabOverloadFunction(db, pDef, nFarg, pFarg->a[1].pExpr);
75618 }else if( nFarg>0 ){
75619 pDef = sqlite3VtabOverloadFunction(db, pDef, nFarg, pFarg->a[0].pExpr);
75621 #endif
75622 for(i=0; i<nFarg; i++){
75623 if( i<32 && sqlite3ExprIsConstant(pFarg->a[i].pExpr) ){
75624 constMask |= (1<<i);
75626 if( (pDef->flags & SQLITE_FUNC_NEEDCOLL)!=0 && !pColl ){
75627 pColl = sqlite3ExprCollSeq(pParse, pFarg->a[i].pExpr);
75630 if( pDef->flags & SQLITE_FUNC_NEEDCOLL ){
75631 if( !pColl ) pColl = db->pDfltColl;
75632 sqlite3VdbeAddOp4(v, OP_CollSeq, 0, 0, 0, (char *)pColl, P4_COLLSEQ);
75634 sqlite3VdbeAddOp4(v, OP_Function, constMask, r1, target,
75635 (char*)pDef, P4_FUNCDEF);
75636 sqlite3VdbeChangeP5(v, (u8)nFarg);
75637 if( nFarg ){
75638 sqlite3ReleaseTempRange(pParse, r1, nFarg);
75640 break;
75642 #ifndef SQLITE_OMIT_SUBQUERY
75643 case TK_EXISTS:
75644 case TK_SELECT: {
75645 testcase( op==TK_EXISTS );
75646 testcase( op==TK_SELECT );
75647 inReg = sqlite3CodeSubselect(pParse, pExpr, 0, 0);
75648 break;
75650 case TK_IN: {
75651 int destIfFalse = sqlite3VdbeMakeLabel(v);
75652 int destIfNull = sqlite3VdbeMakeLabel(v);
75653 sqlite3VdbeAddOp2(v, OP_Null, 0, target);
75654 sqlite3ExprCodeIN(pParse, pExpr, destIfFalse, destIfNull);
75655 sqlite3VdbeAddOp2(v, OP_Integer, 1, target);
75656 sqlite3VdbeResolveLabel(v, destIfFalse);
75657 sqlite3VdbeAddOp2(v, OP_AddImm, target, 0);
75658 sqlite3VdbeResolveLabel(v, destIfNull);
75659 break;
75661 #endif /* SQLITE_OMIT_SUBQUERY */
75665 ** x BETWEEN y AND z
75667 ** This is equivalent to
75669 ** x>=y AND x<=z
75671 ** X is stored in pExpr->pLeft.
75672 ** Y is stored in pExpr->pList->a[0].pExpr.
75673 ** Z is stored in pExpr->pList->a[1].pExpr.
75675 case TK_BETWEEN: {
75676 Expr *pLeft = pExpr->pLeft;
75677 struct ExprList_item *pLItem = pExpr->x.pList->a;
75678 Expr *pRight = pLItem->pExpr;
75680 r1 = sqlite3ExprCodeTemp(pParse, pLeft, &regFree1);
75681 r2 = sqlite3ExprCodeTemp(pParse, pRight, &regFree2);
75682 testcase( regFree1==0 );
75683 testcase( regFree2==0 );
75684 r3 = sqlite3GetTempReg(pParse);
75685 r4 = sqlite3GetTempReg(pParse);
75686 codeCompare(pParse, pLeft, pRight, OP_Ge,
75687 r1, r2, r3, SQLITE_STOREP2);
75688 pLItem++;
75689 pRight = pLItem->pExpr;
75690 sqlite3ReleaseTempReg(pParse, regFree2);
75691 r2 = sqlite3ExprCodeTemp(pParse, pRight, &regFree2);
75692 testcase( regFree2==0 );
75693 codeCompare(pParse, pLeft, pRight, OP_Le, r1, r2, r4, SQLITE_STOREP2);
75694 sqlite3VdbeAddOp3(v, OP_And, r3, r4, target);
75695 sqlite3ReleaseTempReg(pParse, r3);
75696 sqlite3ReleaseTempReg(pParse, r4);
75697 break;
75699 case TK_UPLUS: {
75700 inReg = sqlite3ExprCodeTarget(pParse, pExpr->pLeft, target);
75701 break;
75704 case TK_TRIGGER: {
75705 /* If the opcode is TK_TRIGGER, then the expression is a reference
75706 ** to a column in the new.* or old.* pseudo-tables available to
75707 ** trigger programs. In this case Expr.iTable is set to 1 for the
75708 ** new.* pseudo-table, or 0 for the old.* pseudo-table. Expr.iColumn
75709 ** is set to the column of the pseudo-table to read, or to -1 to
75710 ** read the rowid field.
75712 ** The expression is implemented using an OP_Param opcode. The p1
75713 ** parameter is set to 0 for an old.rowid reference, or to (i+1)
75714 ** to reference another column of the old.* pseudo-table, where
75715 ** i is the index of the column. For a new.rowid reference, p1 is
75716 ** set to (n+1), where n is the number of columns in each pseudo-table.
75717 ** For a reference to any other column in the new.* pseudo-table, p1
75718 ** is set to (n+2+i), where n and i are as defined previously. For
75719 ** example, if the table on which triggers are being fired is
75720 ** declared as:
75722 ** CREATE TABLE t1(a, b);
75724 ** Then p1 is interpreted as follows:
75726 ** p1==0 -> old.rowid p1==3 -> new.rowid
75727 ** p1==1 -> old.a p1==4 -> new.a
75728 ** p1==2 -> old.b p1==5 -> new.b
75730 Table *pTab = pExpr->pTab;
75731 int p1 = pExpr->iTable * (pTab->nCol+1) + 1 + pExpr->iColumn;
75733 assert( pExpr->iTable==0 || pExpr->iTable==1 );
75734 assert( pExpr->iColumn>=-1 && pExpr->iColumn<pTab->nCol );
75735 assert( pTab->iPKey<0 || pExpr->iColumn!=pTab->iPKey );
75736 assert( p1>=0 && p1<(pTab->nCol*2+2) );
75738 sqlite3VdbeAddOp2(v, OP_Param, p1, target);
75739 VdbeComment((v, "%s.%s -> $%d",
75740 (pExpr->iTable ? "new" : "old"),
75741 (pExpr->iColumn<0 ? "rowid" : pExpr->pTab->aCol[pExpr->iColumn].zName),
75742 target
75745 #ifndef SQLITE_OMIT_FLOATING_POINT
75746 /* If the column has REAL affinity, it may currently be stored as an
75747 ** integer. Use OP_RealAffinity to make sure it is really real. */
75748 if( pExpr->iColumn>=0
75749 && pTab->aCol[pExpr->iColumn].affinity==SQLITE_AFF_REAL
75751 sqlite3VdbeAddOp1(v, OP_RealAffinity, target);
75753 #endif
75754 break;
75759 ** Form A:
75760 ** CASE x WHEN e1 THEN r1 WHEN e2 THEN r2 ... WHEN eN THEN rN ELSE y END
75762 ** Form B:
75763 ** CASE WHEN e1 THEN r1 WHEN e2 THEN r2 ... WHEN eN THEN rN ELSE y END
75765 ** Form A is can be transformed into the equivalent form B as follows:
75766 ** CASE WHEN x=e1 THEN r1 WHEN x=e2 THEN r2 ...
75767 ** WHEN x=eN THEN rN ELSE y END
75769 ** X (if it exists) is in pExpr->pLeft.
75770 ** Y is in pExpr->pRight. The Y is also optional. If there is no
75771 ** ELSE clause and no other term matches, then the result of the
75772 ** exprssion is NULL.
75773 ** Ei is in pExpr->pList->a[i*2] and Ri is pExpr->pList->a[i*2+1].
75775 ** The result of the expression is the Ri for the first matching Ei,
75776 ** or if there is no matching Ei, the ELSE term Y, or if there is
75777 ** no ELSE term, NULL.
75779 default: assert( op==TK_CASE ); {
75780 int endLabel; /* GOTO label for end of CASE stmt */
75781 int nextCase; /* GOTO label for next WHEN clause */
75782 int nExpr; /* 2x number of WHEN terms */
75783 int i; /* Loop counter */
75784 ExprList *pEList; /* List of WHEN terms */
75785 struct ExprList_item *aListelem; /* Array of WHEN terms */
75786 Expr opCompare; /* The X==Ei expression */
75787 Expr cacheX; /* Cached expression X */
75788 Expr *pX; /* The X expression */
75789 Expr *pTest = 0; /* X==Ei (form A) or just Ei (form B) */
75790 VVA_ONLY( int iCacheLevel = pParse->iCacheLevel; )
75792 assert( !ExprHasProperty(pExpr, EP_xIsSelect) && pExpr->x.pList );
75793 assert((pExpr->x.pList->nExpr % 2) == 0);
75794 assert(pExpr->x.pList->nExpr > 0);
75795 pEList = pExpr->x.pList;
75796 aListelem = pEList->a;
75797 nExpr = pEList->nExpr;
75798 endLabel = sqlite3VdbeMakeLabel(v);
75799 if( (pX = pExpr->pLeft)!=0 ){
75800 cacheX = *pX;
75801 testcase( pX->op==TK_COLUMN );
75802 testcase( pX->op==TK_REGISTER );
75803 cacheX.iTable = sqlite3ExprCodeTemp(pParse, pX, &regFree1);
75804 testcase( regFree1==0 );
75805 cacheX.op = TK_REGISTER;
75806 opCompare.op = TK_EQ;
75807 opCompare.pLeft = &cacheX;
75808 pTest = &opCompare;
75809 /* Ticket b351d95f9cd5ef17e9d9dbae18f5ca8611190001:
75810 ** The value in regFree1 might get SCopy-ed into the file result.
75811 ** So make sure that the regFree1 register is not reused for other
75812 ** purposes and possibly overwritten. */
75813 regFree1 = 0;
75815 for(i=0; i<nExpr; i=i+2){
75816 sqlite3ExprCachePush(pParse);
75817 if( pX ){
75818 assert( pTest!=0 );
75819 opCompare.pRight = aListelem[i].pExpr;
75820 }else{
75821 pTest = aListelem[i].pExpr;
75823 nextCase = sqlite3VdbeMakeLabel(v);
75824 testcase( pTest->op==TK_COLUMN );
75825 sqlite3ExprIfFalse(pParse, pTest, nextCase, SQLITE_JUMPIFNULL);
75826 testcase( aListelem[i+1].pExpr->op==TK_COLUMN );
75827 testcase( aListelem[i+1].pExpr->op==TK_REGISTER );
75828 sqlite3ExprCode(pParse, aListelem[i+1].pExpr, target);
75829 sqlite3VdbeAddOp2(v, OP_Goto, 0, endLabel);
75830 sqlite3ExprCachePop(pParse, 1);
75831 sqlite3VdbeResolveLabel(v, nextCase);
75833 if( pExpr->pRight ){
75834 sqlite3ExprCachePush(pParse);
75835 sqlite3ExprCode(pParse, pExpr->pRight, target);
75836 sqlite3ExprCachePop(pParse, 1);
75837 }else{
75838 sqlite3VdbeAddOp2(v, OP_Null, 0, target);
75840 assert( db->mallocFailed || pParse->nErr>0
75841 || pParse->iCacheLevel==iCacheLevel );
75842 sqlite3VdbeResolveLabel(v, endLabel);
75843 break;
75845 #ifndef SQLITE_OMIT_TRIGGER
75846 case TK_RAISE: {
75847 assert( pExpr->affinity==OE_Rollback
75848 || pExpr->affinity==OE_Abort
75849 || pExpr->affinity==OE_Fail
75850 || pExpr->affinity==OE_Ignore
75852 if( !pParse->pTriggerTab ){
75853 sqlite3ErrorMsg(pParse,
75854 "RAISE() may only be used within a trigger-program");
75855 return 0;
75857 if( pExpr->affinity==OE_Abort ){
75858 sqlite3MayAbort(pParse);
75860 assert( !ExprHasProperty(pExpr, EP_IntValue) );
75861 if( pExpr->affinity==OE_Ignore ){
75862 sqlite3VdbeAddOp4(
75863 v, OP_Halt, SQLITE_OK, OE_Ignore, 0, pExpr->u.zToken,0);
75864 }else{
75865 sqlite3HaltConstraint(pParse, pExpr->affinity, pExpr->u.zToken, 0);
75868 break;
75870 #endif
75872 sqlite3ReleaseTempReg(pParse, regFree1);
75873 sqlite3ReleaseTempReg(pParse, regFree2);
75874 return inReg;
75878 ** Generate code to evaluate an expression and store the results
75879 ** into a register. Return the register number where the results
75880 ** are stored.
75882 ** If the register is a temporary register that can be deallocated,
75883 ** then write its number into *pReg. If the result register is not
75884 ** a temporary, then set *pReg to zero.
75886 SQLITE_PRIVATE int sqlite3ExprCodeTemp(Parse *pParse, Expr *pExpr, int *pReg){
75887 int r1 = sqlite3GetTempReg(pParse);
75888 int r2 = sqlite3ExprCodeTarget(pParse, pExpr, r1);
75889 if( r2==r1 ){
75890 *pReg = r1;
75891 }else{
75892 sqlite3ReleaseTempReg(pParse, r1);
75893 *pReg = 0;
75895 return r2;
75899 ** Generate code that will evaluate expression pExpr and store the
75900 ** results in register target. The results are guaranteed to appear
75901 ** in register target.
75903 SQLITE_PRIVATE int sqlite3ExprCode(Parse *pParse, Expr *pExpr, int target){
75904 int inReg;
75906 assert( target>0 && target<=pParse->nMem );
75907 if( pExpr && pExpr->op==TK_REGISTER ){
75908 sqlite3VdbeAddOp2(pParse->pVdbe, OP_Copy, pExpr->iTable, target);
75909 }else{
75910 inReg = sqlite3ExprCodeTarget(pParse, pExpr, target);
75911 assert( pParse->pVdbe || pParse->db->mallocFailed );
75912 if( inReg!=target && pParse->pVdbe ){
75913 sqlite3VdbeAddOp2(pParse->pVdbe, OP_SCopy, inReg, target);
75916 return target;
75920 ** Generate code that evalutes the given expression and puts the result
75921 ** in register target.
75923 ** Also make a copy of the expression results into another "cache" register
75924 ** and modify the expression so that the next time it is evaluated,
75925 ** the result is a copy of the cache register.
75927 ** This routine is used for expressions that are used multiple
75928 ** times. They are evaluated once and the results of the expression
75929 ** are reused.
75931 SQLITE_PRIVATE int sqlite3ExprCodeAndCache(Parse *pParse, Expr *pExpr, int target){
75932 Vdbe *v = pParse->pVdbe;
75933 int inReg;
75934 inReg = sqlite3ExprCode(pParse, pExpr, target);
75935 assert( target>0 );
75936 /* This routine is called for terms to INSERT or UPDATE. And the only
75937 ** other place where expressions can be converted into TK_REGISTER is
75938 ** in WHERE clause processing. So as currently implemented, there is
75939 ** no way for a TK_REGISTER to exist here. But it seems prudent to
75940 ** keep the ALWAYS() in case the conditions above change with future
75941 ** modifications or enhancements. */
75942 if( ALWAYS(pExpr->op!=TK_REGISTER) ){
75943 int iMem;
75944 iMem = ++pParse->nMem;
75945 sqlite3VdbeAddOp2(v, OP_Copy, inReg, iMem);
75946 pExpr->iTable = iMem;
75947 pExpr->op2 = pExpr->op;
75948 pExpr->op = TK_REGISTER;
75950 return inReg;
75954 ** Return TRUE if pExpr is an constant expression that is appropriate
75955 ** for factoring out of a loop. Appropriate expressions are:
75957 ** * Any expression that evaluates to two or more opcodes.
75959 ** * Any OP_Integer, OP_Real, OP_String, OP_Blob, OP_Null,
75960 ** or OP_Variable that does not need to be placed in a
75961 ** specific register.
75963 ** There is no point in factoring out single-instruction constant
75964 ** expressions that need to be placed in a particular register.
75965 ** We could factor them out, but then we would end up adding an
75966 ** OP_SCopy instruction to move the value into the correct register
75967 ** later. We might as well just use the original instruction and
75968 ** avoid the OP_SCopy.
75970 static int isAppropriateForFactoring(Expr *p){
75971 if( !sqlite3ExprIsConstantNotJoin(p) ){
75972 return 0; /* Only constant expressions are appropriate for factoring */
75974 if( (p->flags & EP_FixedDest)==0 ){
75975 return 1; /* Any constant without a fixed destination is appropriate */
75977 while( p->op==TK_UPLUS ) p = p->pLeft;
75978 switch( p->op ){
75979 #ifndef SQLITE_OMIT_BLOB_LITERAL
75980 case TK_BLOB:
75981 #endif
75982 case TK_VARIABLE:
75983 case TK_INTEGER:
75984 case TK_FLOAT:
75985 case TK_NULL:
75986 case TK_STRING: {
75987 testcase( p->op==TK_BLOB );
75988 testcase( p->op==TK_VARIABLE );
75989 testcase( p->op==TK_INTEGER );
75990 testcase( p->op==TK_FLOAT );
75991 testcase( p->op==TK_NULL );
75992 testcase( p->op==TK_STRING );
75993 /* Single-instruction constants with a fixed destination are
75994 ** better done in-line. If we factor them, they will just end
75995 ** up generating an OP_SCopy to move the value to the destination
75996 ** register. */
75997 return 0;
75999 case TK_UMINUS: {
76000 if( p->pLeft->op==TK_FLOAT || p->pLeft->op==TK_INTEGER ){
76001 return 0;
76003 break;
76005 default: {
76006 break;
76009 return 1;
76013 ** If pExpr is a constant expression that is appropriate for
76014 ** factoring out of a loop, then evaluate the expression
76015 ** into a register and convert the expression into a TK_REGISTER
76016 ** expression.
76018 static int evalConstExpr(Walker *pWalker, Expr *pExpr){
76019 Parse *pParse = pWalker->pParse;
76020 switch( pExpr->op ){
76021 case TK_IN:
76022 case TK_REGISTER: {
76023 return WRC_Prune;
76025 case TK_FUNCTION:
76026 case TK_AGG_FUNCTION:
76027 case TK_CONST_FUNC: {
76028 /* The arguments to a function have a fixed destination.
76029 ** Mark them this way to avoid generated unneeded OP_SCopy
76030 ** instructions.
76032 ExprList *pList = pExpr->x.pList;
76033 assert( !ExprHasProperty(pExpr, EP_xIsSelect) );
76034 if( pList ){
76035 int i = pList->nExpr;
76036 struct ExprList_item *pItem = pList->a;
76037 for(; i>0; i--, pItem++){
76038 if( ALWAYS(pItem->pExpr) ) pItem->pExpr->flags |= EP_FixedDest;
76041 break;
76044 if( isAppropriateForFactoring(pExpr) ){
76045 int r1 = ++pParse->nMem;
76046 int r2;
76047 r2 = sqlite3ExprCodeTarget(pParse, pExpr, r1);
76048 if( NEVER(r1!=r2) ) sqlite3ReleaseTempReg(pParse, r1);
76049 pExpr->op2 = pExpr->op;
76050 pExpr->op = TK_REGISTER;
76051 pExpr->iTable = r2;
76052 return WRC_Prune;
76054 return WRC_Continue;
76058 ** Preevaluate constant subexpressions within pExpr and store the
76059 ** results in registers. Modify pExpr so that the constant subexpresions
76060 ** are TK_REGISTER opcodes that refer to the precomputed values.
76062 ** This routine is a no-op if the jump to the cookie-check code has
76063 ** already occur. Since the cookie-check jump is generated prior to
76064 ** any other serious processing, this check ensures that there is no
76065 ** way to accidently bypass the constant initializations.
76067 ** This routine is also a no-op if the SQLITE_FactorOutConst optimization
76068 ** is disabled via the sqlite3_test_control(SQLITE_TESTCTRL_OPTIMIZATIONS)
76069 ** interface. This allows test logic to verify that the same answer is
76070 ** obtained for queries regardless of whether or not constants are
76071 ** precomputed into registers or if they are inserted in-line.
76073 SQLITE_PRIVATE void sqlite3ExprCodeConstants(Parse *pParse, Expr *pExpr){
76074 Walker w;
76075 if( pParse->cookieGoto ) return;
76076 if( (pParse->db->flags & SQLITE_FactorOutConst)!=0 ) return;
76077 w.xExprCallback = evalConstExpr;
76078 w.xSelectCallback = 0;
76079 w.pParse = pParse;
76080 sqlite3WalkExpr(&w, pExpr);
76085 ** Generate code that pushes the value of every element of the given
76086 ** expression list into a sequence of registers beginning at target.
76088 ** Return the number of elements evaluated.
76090 SQLITE_PRIVATE int sqlite3ExprCodeExprList(
76091 Parse *pParse, /* Parsing context */
76092 ExprList *pList, /* The expression list to be coded */
76093 int target, /* Where to write results */
76094 int doHardCopy /* Make a hard copy of every element */
76096 struct ExprList_item *pItem;
76097 int i, n;
76098 assert( pList!=0 );
76099 assert( target>0 );
76100 assert( pParse->pVdbe!=0 ); /* Never gets this far otherwise */
76101 n = pList->nExpr;
76102 for(pItem=pList->a, i=0; i<n; i++, pItem++){
76103 Expr *pExpr = pItem->pExpr;
76104 int inReg = sqlite3ExprCodeTarget(pParse, pExpr, target+i);
76105 if( inReg!=target+i ){
76106 sqlite3VdbeAddOp2(pParse->pVdbe, doHardCopy ? OP_Copy : OP_SCopy,
76107 inReg, target+i);
76110 return n;
76114 ** Generate code for a BETWEEN operator.
76116 ** x BETWEEN y AND z
76118 ** The above is equivalent to
76120 ** x>=y AND x<=z
76122 ** Code it as such, taking care to do the common subexpression
76123 ** elementation of x.
76125 static void exprCodeBetween(
76126 Parse *pParse, /* Parsing and code generating context */
76127 Expr *pExpr, /* The BETWEEN expression */
76128 int dest, /* Jump here if the jump is taken */
76129 int jumpIfTrue, /* Take the jump if the BETWEEN is true */
76130 int jumpIfNull /* Take the jump if the BETWEEN is NULL */
76132 Expr exprAnd; /* The AND operator in x>=y AND x<=z */
76133 Expr compLeft; /* The x>=y term */
76134 Expr compRight; /* The x<=z term */
76135 Expr exprX; /* The x subexpression */
76136 int regFree1 = 0; /* Temporary use register */
76138 assert( !ExprHasProperty(pExpr, EP_xIsSelect) );
76139 exprX = *pExpr->pLeft;
76140 exprAnd.op = TK_AND;
76141 exprAnd.pLeft = &compLeft;
76142 exprAnd.pRight = &compRight;
76143 compLeft.op = TK_GE;
76144 compLeft.pLeft = &exprX;
76145 compLeft.pRight = pExpr->x.pList->a[0].pExpr;
76146 compRight.op = TK_LE;
76147 compRight.pLeft = &exprX;
76148 compRight.pRight = pExpr->x.pList->a[1].pExpr;
76149 exprX.iTable = sqlite3ExprCodeTemp(pParse, &exprX, &regFree1);
76150 exprX.op = TK_REGISTER;
76151 if( jumpIfTrue ){
76152 sqlite3ExprIfTrue(pParse, &exprAnd, dest, jumpIfNull);
76153 }else{
76154 sqlite3ExprIfFalse(pParse, &exprAnd, dest, jumpIfNull);
76156 sqlite3ReleaseTempReg(pParse, regFree1);
76158 /* Ensure adequate test coverage */
76159 testcase( jumpIfTrue==0 && jumpIfNull==0 && regFree1==0 );
76160 testcase( jumpIfTrue==0 && jumpIfNull==0 && regFree1!=0 );
76161 testcase( jumpIfTrue==0 && jumpIfNull!=0 && regFree1==0 );
76162 testcase( jumpIfTrue==0 && jumpIfNull!=0 && regFree1!=0 );
76163 testcase( jumpIfTrue!=0 && jumpIfNull==0 && regFree1==0 );
76164 testcase( jumpIfTrue!=0 && jumpIfNull==0 && regFree1!=0 );
76165 testcase( jumpIfTrue!=0 && jumpIfNull!=0 && regFree1==0 );
76166 testcase( jumpIfTrue!=0 && jumpIfNull!=0 && regFree1!=0 );
76170 ** Generate code for a boolean expression such that a jump is made
76171 ** to the label "dest" if the expression is true but execution
76172 ** continues straight thru if the expression is false.
76174 ** If the expression evaluates to NULL (neither true nor false), then
76175 ** take the jump if the jumpIfNull flag is SQLITE_JUMPIFNULL.
76177 ** This code depends on the fact that certain token values (ex: TK_EQ)
76178 ** are the same as opcode values (ex: OP_Eq) that implement the corresponding
76179 ** operation. Special comments in vdbe.c and the mkopcodeh.awk script in
76180 ** the make process cause these values to align. Assert()s in the code
76181 ** below verify that the numbers are aligned correctly.
76183 SQLITE_PRIVATE void sqlite3ExprIfTrue(Parse *pParse, Expr *pExpr, int dest, int jumpIfNull){
76184 Vdbe *v = pParse->pVdbe;
76185 int op = 0;
76186 int regFree1 = 0;
76187 int regFree2 = 0;
76188 int r1, r2;
76190 assert( jumpIfNull==SQLITE_JUMPIFNULL || jumpIfNull==0 );
76191 if( NEVER(v==0) ) return; /* Existance of VDBE checked by caller */
76192 if( NEVER(pExpr==0) ) return; /* No way this can happen */
76193 op = pExpr->op;
76194 switch( op ){
76195 case TK_AND: {
76196 int d2 = sqlite3VdbeMakeLabel(v);
76197 testcase( jumpIfNull==0 );
76198 sqlite3ExprCachePush(pParse);
76199 sqlite3ExprIfFalse(pParse, pExpr->pLeft, d2,jumpIfNull^SQLITE_JUMPIFNULL);
76200 sqlite3ExprIfTrue(pParse, pExpr->pRight, dest, jumpIfNull);
76201 sqlite3VdbeResolveLabel(v, d2);
76202 sqlite3ExprCachePop(pParse, 1);
76203 break;
76205 case TK_OR: {
76206 testcase( jumpIfNull==0 );
76207 sqlite3ExprIfTrue(pParse, pExpr->pLeft, dest, jumpIfNull);
76208 sqlite3ExprIfTrue(pParse, pExpr->pRight, dest, jumpIfNull);
76209 break;
76211 case TK_NOT: {
76212 testcase( jumpIfNull==0 );
76213 sqlite3ExprIfFalse(pParse, pExpr->pLeft, dest, jumpIfNull);
76214 break;
76216 case TK_LT:
76217 case TK_LE:
76218 case TK_GT:
76219 case TK_GE:
76220 case TK_NE:
76221 case TK_EQ: {
76222 assert( TK_LT==OP_Lt );
76223 assert( TK_LE==OP_Le );
76224 assert( TK_GT==OP_Gt );
76225 assert( TK_GE==OP_Ge );
76226 assert( TK_EQ==OP_Eq );
76227 assert( TK_NE==OP_Ne );
76228 testcase( op==TK_LT );
76229 testcase( op==TK_LE );
76230 testcase( op==TK_GT );
76231 testcase( op==TK_GE );
76232 testcase( op==TK_EQ );
76233 testcase( op==TK_NE );
76234 testcase( jumpIfNull==0 );
76235 r1 = sqlite3ExprCodeTemp(pParse, pExpr->pLeft, &regFree1);
76236 r2 = sqlite3ExprCodeTemp(pParse, pExpr->pRight, &regFree2);
76237 codeCompare(pParse, pExpr->pLeft, pExpr->pRight, op,
76238 r1, r2, dest, jumpIfNull);
76239 testcase( regFree1==0 );
76240 testcase( regFree2==0 );
76241 break;
76243 case TK_IS:
76244 case TK_ISNOT: {
76245 testcase( op==TK_IS );
76246 testcase( op==TK_ISNOT );
76247 r1 = sqlite3ExprCodeTemp(pParse, pExpr->pLeft, &regFree1);
76248 r2 = sqlite3ExprCodeTemp(pParse, pExpr->pRight, &regFree2);
76249 op = (op==TK_IS) ? TK_EQ : TK_NE;
76250 codeCompare(pParse, pExpr->pLeft, pExpr->pRight, op,
76251 r1, r2, dest, SQLITE_NULLEQ);
76252 testcase( regFree1==0 );
76253 testcase( regFree2==0 );
76254 break;
76256 case TK_ISNULL:
76257 case TK_NOTNULL: {
76258 assert( TK_ISNULL==OP_IsNull );
76259 assert( TK_NOTNULL==OP_NotNull );
76260 testcase( op==TK_ISNULL );
76261 testcase( op==TK_NOTNULL );
76262 r1 = sqlite3ExprCodeTemp(pParse, pExpr->pLeft, &regFree1);
76263 sqlite3VdbeAddOp2(v, op, r1, dest);
76264 testcase( regFree1==0 );
76265 break;
76267 case TK_BETWEEN: {
76268 testcase( jumpIfNull==0 );
76269 exprCodeBetween(pParse, pExpr, dest, 1, jumpIfNull);
76270 break;
76272 #ifndef SQLITE_OMIT_SUBQUERY
76273 case TK_IN: {
76274 int destIfFalse = sqlite3VdbeMakeLabel(v);
76275 int destIfNull = jumpIfNull ? dest : destIfFalse;
76276 sqlite3ExprCodeIN(pParse, pExpr, destIfFalse, destIfNull);
76277 sqlite3VdbeAddOp2(v, OP_Goto, 0, dest);
76278 sqlite3VdbeResolveLabel(v, destIfFalse);
76279 break;
76281 #endif
76282 default: {
76283 r1 = sqlite3ExprCodeTemp(pParse, pExpr, &regFree1);
76284 sqlite3VdbeAddOp3(v, OP_If, r1, dest, jumpIfNull!=0);
76285 testcase( regFree1==0 );
76286 testcase( jumpIfNull==0 );
76287 break;
76290 sqlite3ReleaseTempReg(pParse, regFree1);
76291 sqlite3ReleaseTempReg(pParse, regFree2);
76295 ** Generate code for a boolean expression such that a jump is made
76296 ** to the label "dest" if the expression is false but execution
76297 ** continues straight thru if the expression is true.
76299 ** If the expression evaluates to NULL (neither true nor false) then
76300 ** jump if jumpIfNull is SQLITE_JUMPIFNULL or fall through if jumpIfNull
76301 ** is 0.
76303 SQLITE_PRIVATE void sqlite3ExprIfFalse(Parse *pParse, Expr *pExpr, int dest, int jumpIfNull){
76304 Vdbe *v = pParse->pVdbe;
76305 int op = 0;
76306 int regFree1 = 0;
76307 int regFree2 = 0;
76308 int r1, r2;
76310 assert( jumpIfNull==SQLITE_JUMPIFNULL || jumpIfNull==0 );
76311 if( NEVER(v==0) ) return; /* Existance of VDBE checked by caller */
76312 if( pExpr==0 ) return;
76314 /* The value of pExpr->op and op are related as follows:
76316 ** pExpr->op op
76317 ** --------- ----------
76318 ** TK_ISNULL OP_NotNull
76319 ** TK_NOTNULL OP_IsNull
76320 ** TK_NE OP_Eq
76321 ** TK_EQ OP_Ne
76322 ** TK_GT OP_Le
76323 ** TK_LE OP_Gt
76324 ** TK_GE OP_Lt
76325 ** TK_LT OP_Ge
76327 ** For other values of pExpr->op, op is undefined and unused.
76328 ** The value of TK_ and OP_ constants are arranged such that we
76329 ** can compute the mapping above using the following expression.
76330 ** Assert()s verify that the computation is correct.
76332 op = ((pExpr->op+(TK_ISNULL&1))^1)-(TK_ISNULL&1);
76334 /* Verify correct alignment of TK_ and OP_ constants
76336 assert( pExpr->op!=TK_ISNULL || op==OP_NotNull );
76337 assert( pExpr->op!=TK_NOTNULL || op==OP_IsNull );
76338 assert( pExpr->op!=TK_NE || op==OP_Eq );
76339 assert( pExpr->op!=TK_EQ || op==OP_Ne );
76340 assert( pExpr->op!=TK_LT || op==OP_Ge );
76341 assert( pExpr->op!=TK_LE || op==OP_Gt );
76342 assert( pExpr->op!=TK_GT || op==OP_Le );
76343 assert( pExpr->op!=TK_GE || op==OP_Lt );
76345 switch( pExpr->op ){
76346 case TK_AND: {
76347 testcase( jumpIfNull==0 );
76348 sqlite3ExprIfFalse(pParse, pExpr->pLeft, dest, jumpIfNull);
76349 sqlite3ExprIfFalse(pParse, pExpr->pRight, dest, jumpIfNull);
76350 break;
76352 case TK_OR: {
76353 int d2 = sqlite3VdbeMakeLabel(v);
76354 testcase( jumpIfNull==0 );
76355 sqlite3ExprCachePush(pParse);
76356 sqlite3ExprIfTrue(pParse, pExpr->pLeft, d2, jumpIfNull^SQLITE_JUMPIFNULL);
76357 sqlite3ExprIfFalse(pParse, pExpr->pRight, dest, jumpIfNull);
76358 sqlite3VdbeResolveLabel(v, d2);
76359 sqlite3ExprCachePop(pParse, 1);
76360 break;
76362 case TK_NOT: {
76363 testcase( jumpIfNull==0 );
76364 sqlite3ExprIfTrue(pParse, pExpr->pLeft, dest, jumpIfNull);
76365 break;
76367 case TK_LT:
76368 case TK_LE:
76369 case TK_GT:
76370 case TK_GE:
76371 case TK_NE:
76372 case TK_EQ: {
76373 testcase( op==TK_LT );
76374 testcase( op==TK_LE );
76375 testcase( op==TK_GT );
76376 testcase( op==TK_GE );
76377 testcase( op==TK_EQ );
76378 testcase( op==TK_NE );
76379 testcase( jumpIfNull==0 );
76380 r1 = sqlite3ExprCodeTemp(pParse, pExpr->pLeft, &regFree1);
76381 r2 = sqlite3ExprCodeTemp(pParse, pExpr->pRight, &regFree2);
76382 codeCompare(pParse, pExpr->pLeft, pExpr->pRight, op,
76383 r1, r2, dest, jumpIfNull);
76384 testcase( regFree1==0 );
76385 testcase( regFree2==0 );
76386 break;
76388 case TK_IS:
76389 case TK_ISNOT: {
76390 testcase( pExpr->op==TK_IS );
76391 testcase( pExpr->op==TK_ISNOT );
76392 r1 = sqlite3ExprCodeTemp(pParse, pExpr->pLeft, &regFree1);
76393 r2 = sqlite3ExprCodeTemp(pParse, pExpr->pRight, &regFree2);
76394 op = (pExpr->op==TK_IS) ? TK_NE : TK_EQ;
76395 codeCompare(pParse, pExpr->pLeft, pExpr->pRight, op,
76396 r1, r2, dest, SQLITE_NULLEQ);
76397 testcase( regFree1==0 );
76398 testcase( regFree2==0 );
76399 break;
76401 case TK_ISNULL:
76402 case TK_NOTNULL: {
76403 testcase( op==TK_ISNULL );
76404 testcase( op==TK_NOTNULL );
76405 r1 = sqlite3ExprCodeTemp(pParse, pExpr->pLeft, &regFree1);
76406 sqlite3VdbeAddOp2(v, op, r1, dest);
76407 testcase( regFree1==0 );
76408 break;
76410 case TK_BETWEEN: {
76411 testcase( jumpIfNull==0 );
76412 exprCodeBetween(pParse, pExpr, dest, 0, jumpIfNull);
76413 break;
76415 #ifndef SQLITE_OMIT_SUBQUERY
76416 case TK_IN: {
76417 if( jumpIfNull ){
76418 sqlite3ExprCodeIN(pParse, pExpr, dest, dest);
76419 }else{
76420 int destIfNull = sqlite3VdbeMakeLabel(v);
76421 sqlite3ExprCodeIN(pParse, pExpr, dest, destIfNull);
76422 sqlite3VdbeResolveLabel(v, destIfNull);
76424 break;
76426 #endif
76427 default: {
76428 r1 = sqlite3ExprCodeTemp(pParse, pExpr, &regFree1);
76429 sqlite3VdbeAddOp3(v, OP_IfNot, r1, dest, jumpIfNull!=0);
76430 testcase( regFree1==0 );
76431 testcase( jumpIfNull==0 );
76432 break;
76435 sqlite3ReleaseTempReg(pParse, regFree1);
76436 sqlite3ReleaseTempReg(pParse, regFree2);
76440 ** Do a deep comparison of two expression trees. Return 0 if the two
76441 ** expressions are completely identical. Return 1 if they differ only
76442 ** by a COLLATE operator at the top level. Return 2 if there are differences
76443 ** other than the top-level COLLATE operator.
76445 ** Sometimes this routine will return 2 even if the two expressions
76446 ** really are equivalent. If we cannot prove that the expressions are
76447 ** identical, we return 2 just to be safe. So if this routine
76448 ** returns 2, then you do not really know for certain if the two
76449 ** expressions are the same. But if you get a 0 or 1 return, then you
76450 ** can be sure the expressions are the same. In the places where
76451 ** this routine is used, it does not hurt to get an extra 2 - that
76452 ** just might result in some slightly slower code. But returning
76453 ** an incorrect 0 or 1 could lead to a malfunction.
76455 SQLITE_PRIVATE int sqlite3ExprCompare(Expr *pA, Expr *pB){
76456 if( pA==0||pB==0 ){
76457 return pB==pA ? 0 : 2;
76459 assert( !ExprHasAnyProperty(pA, EP_TokenOnly|EP_Reduced) );
76460 assert( !ExprHasAnyProperty(pB, EP_TokenOnly|EP_Reduced) );
76461 if( ExprHasProperty(pA, EP_xIsSelect) || ExprHasProperty(pB, EP_xIsSelect) ){
76462 return 2;
76464 if( (pA->flags & EP_Distinct)!=(pB->flags & EP_Distinct) ) return 2;
76465 if( pA->op!=pB->op ) return 2;
76466 if( sqlite3ExprCompare(pA->pLeft, pB->pLeft) ) return 2;
76467 if( sqlite3ExprCompare(pA->pRight, pB->pRight) ) return 2;
76468 if( sqlite3ExprListCompare(pA->x.pList, pB->x.pList) ) return 2;
76469 if( pA->iTable!=pB->iTable || pA->iColumn!=pB->iColumn ) return 2;
76470 if( ExprHasProperty(pA, EP_IntValue) ){
76471 if( !ExprHasProperty(pB, EP_IntValue) || pA->u.iValue!=pB->u.iValue ){
76472 return 2;
76474 }else if( pA->op!=TK_COLUMN && pA->u.zToken ){
76475 if( ExprHasProperty(pB, EP_IntValue) || NEVER(pB->u.zToken==0) ) return 2;
76476 if( sqlite3StrICmp(pA->u.zToken,pB->u.zToken)!=0 ){
76477 return 2;
76480 if( (pA->flags & EP_ExpCollate)!=(pB->flags & EP_ExpCollate) ) return 1;
76481 if( (pA->flags & EP_ExpCollate)!=0 && pA->pColl!=pB->pColl ) return 2;
76482 return 0;
76486 ** Compare two ExprList objects. Return 0 if they are identical and
76487 ** non-zero if they differ in any way.
76489 ** This routine might return non-zero for equivalent ExprLists. The
76490 ** only consequence will be disabled optimizations. But this routine
76491 ** must never return 0 if the two ExprList objects are different, or
76492 ** a malfunction will result.
76494 ** Two NULL pointers are considered to be the same. But a NULL pointer
76495 ** always differs from a non-NULL pointer.
76497 SQLITE_PRIVATE int sqlite3ExprListCompare(ExprList *pA, ExprList *pB){
76498 int i;
76499 if( pA==0 && pB==0 ) return 0;
76500 if( pA==0 || pB==0 ) return 1;
76501 if( pA->nExpr!=pB->nExpr ) return 1;
76502 for(i=0; i<pA->nExpr; i++){
76503 Expr *pExprA = pA->a[i].pExpr;
76504 Expr *pExprB = pB->a[i].pExpr;
76505 if( pA->a[i].sortOrder!=pB->a[i].sortOrder ) return 1;
76506 if( sqlite3ExprCompare(pExprA, pExprB) ) return 1;
76508 return 0;
76512 ** Add a new element to the pAggInfo->aCol[] array. Return the index of
76513 ** the new element. Return a negative number if malloc fails.
76515 static int addAggInfoColumn(sqlite3 *db, AggInfo *pInfo){
76516 int i;
76517 pInfo->aCol = sqlite3ArrayAllocate(
76519 pInfo->aCol,
76520 sizeof(pInfo->aCol[0]),
76522 &pInfo->nColumn,
76523 &pInfo->nColumnAlloc,
76526 return i;
76530 ** Add a new element to the pAggInfo->aFunc[] array. Return the index of
76531 ** the new element. Return a negative number if malloc fails.
76533 static int addAggInfoFunc(sqlite3 *db, AggInfo *pInfo){
76534 int i;
76535 pInfo->aFunc = sqlite3ArrayAllocate(
76536 db,
76537 pInfo->aFunc,
76538 sizeof(pInfo->aFunc[0]),
76540 &pInfo->nFunc,
76541 &pInfo->nFuncAlloc,
76544 return i;
76548 ** This is the xExprCallback for a tree walker. It is used to
76549 ** implement sqlite3ExprAnalyzeAggregates(). See sqlite3ExprAnalyzeAggregates
76550 ** for additional information.
76552 static int analyzeAggregate(Walker *pWalker, Expr *pExpr){
76553 int i;
76554 NameContext *pNC = pWalker->u.pNC;
76555 Parse *pParse = pNC->pParse;
76556 SrcList *pSrcList = pNC->pSrcList;
76557 AggInfo *pAggInfo = pNC->pAggInfo;
76559 switch( pExpr->op ){
76560 case TK_AGG_COLUMN:
76561 case TK_COLUMN: {
76562 testcase( pExpr->op==TK_AGG_COLUMN );
76563 testcase( pExpr->op==TK_COLUMN );
76564 /* Check to see if the column is in one of the tables in the FROM
76565 ** clause of the aggregate query */
76566 if( ALWAYS(pSrcList!=0) ){
76567 struct SrcList_item *pItem = pSrcList->a;
76568 for(i=0; i<pSrcList->nSrc; i++, pItem++){
76569 struct AggInfo_col *pCol;
76570 assert( !ExprHasAnyProperty(pExpr, EP_TokenOnly|EP_Reduced) );
76571 if( pExpr->iTable==pItem->iCursor ){
76572 /* If we reach this point, it means that pExpr refers to a table
76573 ** that is in the FROM clause of the aggregate query.
76575 ** Make an entry for the column in pAggInfo->aCol[] if there
76576 ** is not an entry there already.
76578 int k;
76579 pCol = pAggInfo->aCol;
76580 for(k=0; k<pAggInfo->nColumn; k++, pCol++){
76581 if( pCol->iTable==pExpr->iTable &&
76582 pCol->iColumn==pExpr->iColumn ){
76583 break;
76586 if( (k>=pAggInfo->nColumn)
76587 && (k = addAggInfoColumn(pParse->db, pAggInfo))>=0
76589 pCol = &pAggInfo->aCol[k];
76590 pCol->pTab = pExpr->pTab;
76591 pCol->iTable = pExpr->iTable;
76592 pCol->iColumn = pExpr->iColumn;
76593 pCol->iMem = ++pParse->nMem;
76594 pCol->iSorterColumn = -1;
76595 pCol->pExpr = pExpr;
76596 if( pAggInfo->pGroupBy ){
76597 int j, n;
76598 ExprList *pGB = pAggInfo->pGroupBy;
76599 struct ExprList_item *pTerm = pGB->a;
76600 n = pGB->nExpr;
76601 for(j=0; j<n; j++, pTerm++){
76602 Expr *pE = pTerm->pExpr;
76603 if( pE->op==TK_COLUMN && pE->iTable==pExpr->iTable &&
76604 pE->iColumn==pExpr->iColumn ){
76605 pCol->iSorterColumn = j;
76606 break;
76610 if( pCol->iSorterColumn<0 ){
76611 pCol->iSorterColumn = pAggInfo->nSortingColumn++;
76614 /* There is now an entry for pExpr in pAggInfo->aCol[] (either
76615 ** because it was there before or because we just created it).
76616 ** Convert the pExpr to be a TK_AGG_COLUMN referring to that
76617 ** pAggInfo->aCol[] entry.
76619 ExprSetIrreducible(pExpr);
76620 pExpr->pAggInfo = pAggInfo;
76621 pExpr->op = TK_AGG_COLUMN;
76622 pExpr->iAgg = (i16)k;
76623 break;
76624 } /* endif pExpr->iTable==pItem->iCursor */
76625 } /* end loop over pSrcList */
76627 return WRC_Prune;
76629 case TK_AGG_FUNCTION: {
76630 /* The pNC->nDepth==0 test causes aggregate functions in subqueries
76631 ** to be ignored */
76632 if( pNC->nDepth==0 ){
76633 /* Check to see if pExpr is a duplicate of another aggregate
76634 ** function that is already in the pAggInfo structure
76636 struct AggInfo_func *pItem = pAggInfo->aFunc;
76637 for(i=0; i<pAggInfo->nFunc; i++, pItem++){
76638 if( sqlite3ExprCompare(pItem->pExpr, pExpr)==0 ){
76639 break;
76642 if( i>=pAggInfo->nFunc ){
76643 /* pExpr is original. Make a new entry in pAggInfo->aFunc[]
76645 u8 enc = ENC(pParse->db);
76646 i = addAggInfoFunc(pParse->db, pAggInfo);
76647 if( i>=0 ){
76648 assert( !ExprHasProperty(pExpr, EP_xIsSelect) );
76649 pItem = &pAggInfo->aFunc[i];
76650 pItem->pExpr = pExpr;
76651 pItem->iMem = ++pParse->nMem;
76652 assert( !ExprHasProperty(pExpr, EP_IntValue) );
76653 pItem->pFunc = sqlite3FindFunction(pParse->db,
76654 pExpr->u.zToken, sqlite3Strlen30(pExpr->u.zToken),
76655 pExpr->x.pList ? pExpr->x.pList->nExpr : 0, enc, 0);
76656 if( pExpr->flags & EP_Distinct ){
76657 pItem->iDistinct = pParse->nTab++;
76658 }else{
76659 pItem->iDistinct = -1;
76663 /* Make pExpr point to the appropriate pAggInfo->aFunc[] entry
76665 assert( !ExprHasAnyProperty(pExpr, EP_TokenOnly|EP_Reduced) );
76666 ExprSetIrreducible(pExpr);
76667 pExpr->iAgg = (i16)i;
76668 pExpr->pAggInfo = pAggInfo;
76669 return WRC_Prune;
76673 return WRC_Continue;
76675 static int analyzeAggregatesInSelect(Walker *pWalker, Select *pSelect){
76676 NameContext *pNC = pWalker->u.pNC;
76677 if( pNC->nDepth==0 ){
76678 pNC->nDepth++;
76679 sqlite3WalkSelect(pWalker, pSelect);
76680 pNC->nDepth--;
76681 return WRC_Prune;
76682 }else{
76683 return WRC_Continue;
76688 ** Analyze the given expression looking for aggregate functions and
76689 ** for variables that need to be added to the pParse->aAgg[] array.
76690 ** Make additional entries to the pParse->aAgg[] array as necessary.
76692 ** This routine should only be called after the expression has been
76693 ** analyzed by sqlite3ResolveExprNames().
76695 SQLITE_PRIVATE void sqlite3ExprAnalyzeAggregates(NameContext *pNC, Expr *pExpr){
76696 Walker w;
76697 w.xExprCallback = analyzeAggregate;
76698 w.xSelectCallback = analyzeAggregatesInSelect;
76699 w.u.pNC = pNC;
76700 assert( pNC->pSrcList!=0 );
76701 sqlite3WalkExpr(&w, pExpr);
76705 ** Call sqlite3ExprAnalyzeAggregates() for every expression in an
76706 ** expression list. Return the number of errors.
76708 ** If an error is found, the analysis is cut short.
76710 SQLITE_PRIVATE void sqlite3ExprAnalyzeAggList(NameContext *pNC, ExprList *pList){
76711 struct ExprList_item *pItem;
76712 int i;
76713 if( pList ){
76714 for(pItem=pList->a, i=0; i<pList->nExpr; i++, pItem++){
76715 sqlite3ExprAnalyzeAggregates(pNC, pItem->pExpr);
76721 ** Allocate a single new register for use to hold some intermediate result.
76723 SQLITE_PRIVATE int sqlite3GetTempReg(Parse *pParse){
76724 if( pParse->nTempReg==0 ){
76725 return ++pParse->nMem;
76727 return pParse->aTempReg[--pParse->nTempReg];
76731 ** Deallocate a register, making available for reuse for some other
76732 ** purpose.
76734 ** If a register is currently being used by the column cache, then
76735 ** the dallocation is deferred until the column cache line that uses
76736 ** the register becomes stale.
76738 SQLITE_PRIVATE void sqlite3ReleaseTempReg(Parse *pParse, int iReg){
76739 if( iReg && pParse->nTempReg<ArraySize(pParse->aTempReg) ){
76740 int i;
76741 struct yColCache *p;
76742 for(i=0, p=pParse->aColCache; i<SQLITE_N_COLCACHE; i++, p++){
76743 if( p->iReg==iReg ){
76744 p->tempReg = 1;
76745 return;
76748 pParse->aTempReg[pParse->nTempReg++] = iReg;
76753 ** Allocate or deallocate a block of nReg consecutive registers
76755 SQLITE_PRIVATE int sqlite3GetTempRange(Parse *pParse, int nReg){
76756 int i, n;
76757 i = pParse->iRangeReg;
76758 n = pParse->nRangeReg;
76759 if( nReg<=n ){
76760 assert( !usedAsColumnCache(pParse, i, i+n-1) );
76761 pParse->iRangeReg += nReg;
76762 pParse->nRangeReg -= nReg;
76763 }else{
76764 i = pParse->nMem+1;
76765 pParse->nMem += nReg;
76767 return i;
76769 SQLITE_PRIVATE void sqlite3ReleaseTempRange(Parse *pParse, int iReg, int nReg){
76770 sqlite3ExprCacheRemove(pParse, iReg, nReg);
76771 if( nReg>pParse->nRangeReg ){
76772 pParse->nRangeReg = nReg;
76773 pParse->iRangeReg = iReg;
76777 /************** End of expr.c ************************************************/
76778 /************** Begin file alter.c *******************************************/
76780 ** 2005 February 15
76782 ** The author disclaims copyright to this source code. In place of
76783 ** a legal notice, here is a blessing:
76785 ** May you do good and not evil.
76786 ** May you find forgiveness for yourself and forgive others.
76787 ** May you share freely, never taking more than you give.
76789 *************************************************************************
76790 ** This file contains C code routines that used to generate VDBE code
76791 ** that implements the ALTER TABLE command.
76795 ** The code in this file only exists if we are not omitting the
76796 ** ALTER TABLE logic from the build.
76798 #ifndef SQLITE_OMIT_ALTERTABLE
76802 ** This function is used by SQL generated to implement the
76803 ** ALTER TABLE command. The first argument is the text of a CREATE TABLE or
76804 ** CREATE INDEX command. The second is a table name. The table name in
76805 ** the CREATE TABLE or CREATE INDEX statement is replaced with the third
76806 ** argument and the result returned. Examples:
76808 ** sqlite_rename_table('CREATE TABLE abc(a, b, c)', 'def')
76809 ** -> 'CREATE TABLE def(a, b, c)'
76811 ** sqlite_rename_table('CREATE INDEX i ON abc(a)', 'def')
76812 ** -> 'CREATE INDEX i ON def(a, b, c)'
76814 static void renameTableFunc(
76815 sqlite3_context *context,
76816 int NotUsed,
76817 sqlite3_value **argv
76819 unsigned char const *zSql = sqlite3_value_text(argv[0]);
76820 unsigned char const *zTableName = sqlite3_value_text(argv[1]);
76822 int token;
76823 Token tname;
76824 unsigned char const *zCsr = zSql;
76825 int len = 0;
76826 char *zRet;
76828 sqlite3 *db = sqlite3_context_db_handle(context);
76830 UNUSED_PARAMETER(NotUsed);
76832 /* The principle used to locate the table name in the CREATE TABLE
76833 ** statement is that the table name is the first non-space token that
76834 ** is immediately followed by a TK_LP or TK_USING token.
76836 if( zSql ){
76837 do {
76838 if( !*zCsr ){
76839 /* Ran out of input before finding an opening bracket. Return NULL. */
76840 return;
76843 /* Store the token that zCsr points to in tname. */
76844 tname.z = (char*)zCsr;
76845 tname.n = len;
76847 /* Advance zCsr to the next token. Store that token type in 'token',
76848 ** and its length in 'len' (to be used next iteration of this loop).
76850 do {
76851 zCsr += len;
76852 len = sqlite3GetToken(zCsr, &token);
76853 } while( token==TK_SPACE );
76854 assert( len>0 );
76855 } while( token!=TK_LP && token!=TK_USING );
76857 zRet = sqlite3MPrintf(db, "%.*s\"%w\"%s", ((u8*)tname.z) - zSql, zSql,
76858 zTableName, tname.z+tname.n);
76859 sqlite3_result_text(context, zRet, -1, SQLITE_DYNAMIC);
76864 ** This C function implements an SQL user function that is used by SQL code
76865 ** generated by the ALTER TABLE ... RENAME command to modify the definition
76866 ** of any foreign key constraints that use the table being renamed as the
76867 ** parent table. It is passed three arguments:
76869 ** 1) The complete text of the CREATE TABLE statement being modified,
76870 ** 2) The old name of the table being renamed, and
76871 ** 3) The new name of the table being renamed.
76873 ** It returns the new CREATE TABLE statement. For example:
76875 ** sqlite_rename_parent('CREATE TABLE t1(a REFERENCES t2)', 't2', 't3')
76876 ** -> 'CREATE TABLE t1(a REFERENCES t3)'
76878 #ifndef SQLITE_OMIT_FOREIGN_KEY
76879 static void renameParentFunc(
76880 sqlite3_context *context,
76881 int NotUsed,
76882 sqlite3_value **argv
76884 sqlite3 *db = sqlite3_context_db_handle(context);
76885 char *zOutput = 0;
76886 char *zResult;
76887 unsigned char const *zInput = sqlite3_value_text(argv[0]);
76888 unsigned char const *zOld = sqlite3_value_text(argv[1]);
76889 unsigned char const *zNew = sqlite3_value_text(argv[2]);
76891 unsigned const char *z; /* Pointer to token */
76892 int n; /* Length of token z */
76893 int token; /* Type of token */
76895 UNUSED_PARAMETER(NotUsed);
76896 for(z=zInput; *z; z=z+n){
76897 n = sqlite3GetToken(z, &token);
76898 if( token==TK_REFERENCES ){
76899 char *zParent;
76900 do {
76901 z += n;
76902 n = sqlite3GetToken(z, &token);
76903 }while( token==TK_SPACE );
76905 zParent = sqlite3DbStrNDup(db, (const char *)z, n);
76906 if( zParent==0 ) break;
76907 sqlite3Dequote(zParent);
76908 if( 0==sqlite3StrICmp((const char *)zOld, zParent) ){
76909 char *zOut = sqlite3MPrintf(db, "%s%.*s\"%w\"",
76910 (zOutput?zOutput:""), z-zInput, zInput, (const char *)zNew
76912 sqlite3DbFree(db, zOutput);
76913 zOutput = zOut;
76914 zInput = &z[n];
76916 sqlite3DbFree(db, zParent);
76920 zResult = sqlite3MPrintf(db, "%s%s", (zOutput?zOutput:""), zInput),
76921 sqlite3_result_text(context, zResult, -1, SQLITE_DYNAMIC);
76922 sqlite3DbFree(db, zOutput);
76924 #endif
76926 #ifndef SQLITE_OMIT_TRIGGER
76927 /* This function is used by SQL generated to implement the
76928 ** ALTER TABLE command. The first argument is the text of a CREATE TRIGGER
76929 ** statement. The second is a table name. The table name in the CREATE
76930 ** TRIGGER statement is replaced with the third argument and the result
76931 ** returned. This is analagous to renameTableFunc() above, except for CREATE
76932 ** TRIGGER, not CREATE INDEX and CREATE TABLE.
76934 static void renameTriggerFunc(
76935 sqlite3_context *context,
76936 int NotUsed,
76937 sqlite3_value **argv
76939 unsigned char const *zSql = sqlite3_value_text(argv[0]);
76940 unsigned char const *zTableName = sqlite3_value_text(argv[1]);
76942 int token;
76943 Token tname;
76944 int dist = 3;
76945 unsigned char const *zCsr = zSql;
76946 int len = 0;
76947 char *zRet;
76948 sqlite3 *db = sqlite3_context_db_handle(context);
76950 UNUSED_PARAMETER(NotUsed);
76952 /* The principle used to locate the table name in the CREATE TRIGGER
76953 ** statement is that the table name is the first token that is immediatedly
76954 ** preceded by either TK_ON or TK_DOT and immediatedly followed by one
76955 ** of TK_WHEN, TK_BEGIN or TK_FOR.
76957 if( zSql ){
76958 do {
76960 if( !*zCsr ){
76961 /* Ran out of input before finding the table name. Return NULL. */
76962 return;
76965 /* Store the token that zCsr points to in tname. */
76966 tname.z = (char*)zCsr;
76967 tname.n = len;
76969 /* Advance zCsr to the next token. Store that token type in 'token',
76970 ** and its length in 'len' (to be used next iteration of this loop).
76972 do {
76973 zCsr += len;
76974 len = sqlite3GetToken(zCsr, &token);
76975 }while( token==TK_SPACE );
76976 assert( len>0 );
76978 /* Variable 'dist' stores the number of tokens read since the most
76979 ** recent TK_DOT or TK_ON. This means that when a WHEN, FOR or BEGIN
76980 ** token is read and 'dist' equals 2, the condition stated above
76981 ** to be met.
76983 ** Note that ON cannot be a database, table or column name, so
76984 ** there is no need to worry about syntax like
76985 ** "CREATE TRIGGER ... ON ON.ON BEGIN ..." etc.
76987 dist++;
76988 if( token==TK_DOT || token==TK_ON ){
76989 dist = 0;
76991 } while( dist!=2 || (token!=TK_WHEN && token!=TK_FOR && token!=TK_BEGIN) );
76993 /* Variable tname now contains the token that is the old table-name
76994 ** in the CREATE TRIGGER statement.
76996 zRet = sqlite3MPrintf(db, "%.*s\"%w\"%s", ((u8*)tname.z) - zSql, zSql,
76997 zTableName, tname.z+tname.n);
76998 sqlite3_result_text(context, zRet, -1, SQLITE_DYNAMIC);
77001 #endif /* !SQLITE_OMIT_TRIGGER */
77004 ** Register built-in functions used to help implement ALTER TABLE
77006 SQLITE_PRIVATE void sqlite3AlterFunctions(void){
77007 static SQLITE_WSD FuncDef aAlterTableFuncs[] = {
77008 FUNCTION(sqlite_rename_table, 2, 0, 0, renameTableFunc),
77009 #ifndef SQLITE_OMIT_TRIGGER
77010 FUNCTION(sqlite_rename_trigger, 2, 0, 0, renameTriggerFunc),
77011 #endif
77012 #ifndef SQLITE_OMIT_FOREIGN_KEY
77013 FUNCTION(sqlite_rename_parent, 3, 0, 0, renameParentFunc),
77014 #endif
77016 int i;
77017 FuncDefHash *pHash = &GLOBAL(FuncDefHash, sqlite3GlobalFunctions);
77018 FuncDef *aFunc = (FuncDef*)&GLOBAL(FuncDef, aAlterTableFuncs);
77020 for(i=0; i<ArraySize(aAlterTableFuncs); i++){
77021 sqlite3FuncDefInsert(pHash, &aFunc[i]);
77026 ** This function is used to create the text of expressions of the form:
77028 ** name=<constant1> OR name=<constant2> OR ...
77030 ** If argument zWhere is NULL, then a pointer string containing the text
77031 ** "name=<constant>" is returned, where <constant> is the quoted version
77032 ** of the string passed as argument zConstant. The returned buffer is
77033 ** allocated using sqlite3DbMalloc(). It is the responsibility of the
77034 ** caller to ensure that it is eventually freed.
77036 ** If argument zWhere is not NULL, then the string returned is
77037 ** "<where> OR name=<constant>", where <where> is the contents of zWhere.
77038 ** In this case zWhere is passed to sqlite3DbFree() before returning.
77041 static char *whereOrName(sqlite3 *db, char *zWhere, char *zConstant){
77042 char *zNew;
77043 if( !zWhere ){
77044 zNew = sqlite3MPrintf(db, "name=%Q", zConstant);
77045 }else{
77046 zNew = sqlite3MPrintf(db, "%s OR name=%Q", zWhere, zConstant);
77047 sqlite3DbFree(db, zWhere);
77049 return zNew;
77052 #if !defined(SQLITE_OMIT_FOREIGN_KEY) && !defined(SQLITE_OMIT_TRIGGER)
77054 ** Generate the text of a WHERE expression which can be used to select all
77055 ** tables that have foreign key constraints that refer to table pTab (i.e.
77056 ** constraints for which pTab is the parent table) from the sqlite_master
77057 ** table.
77059 static char *whereForeignKeys(Parse *pParse, Table *pTab){
77060 FKey *p;
77061 char *zWhere = 0;
77062 for(p=sqlite3FkReferences(pTab); p; p=p->pNextTo){
77063 zWhere = whereOrName(pParse->db, zWhere, p->pFrom->zName);
77065 return zWhere;
77067 #endif
77070 ** Generate the text of a WHERE expression which can be used to select all
77071 ** temporary triggers on table pTab from the sqlite_temp_master table. If
77072 ** table pTab has no temporary triggers, or is itself stored in the
77073 ** temporary database, NULL is returned.
77075 static char *whereTempTriggers(Parse *pParse, Table *pTab){
77076 Trigger *pTrig;
77077 char *zWhere = 0;
77078 const Schema *pTempSchema = pParse->db->aDb[1].pSchema; /* Temp db schema */
77080 /* If the table is not located in the temp-db (in which case NULL is
77081 ** returned, loop through the tables list of triggers. For each trigger
77082 ** that is not part of the temp-db schema, add a clause to the WHERE
77083 ** expression being built up in zWhere.
77085 if( pTab->pSchema!=pTempSchema ){
77086 sqlite3 *db = pParse->db;
77087 for(pTrig=sqlite3TriggerList(pParse, pTab); pTrig; pTrig=pTrig->pNext){
77088 if( pTrig->pSchema==pTempSchema ){
77089 zWhere = whereOrName(db, zWhere, pTrig->zName);
77093 if( zWhere ){
77094 char *zNew = sqlite3MPrintf(pParse->db, "type='trigger' AND (%s)", zWhere);
77095 sqlite3DbFree(pParse->db, zWhere);
77096 zWhere = zNew;
77098 return zWhere;
77102 ** Generate code to drop and reload the internal representation of table
77103 ** pTab from the database, including triggers and temporary triggers.
77104 ** Argument zName is the name of the table in the database schema at
77105 ** the time the generated code is executed. This can be different from
77106 ** pTab->zName if this function is being called to code part of an
77107 ** "ALTER TABLE RENAME TO" statement.
77109 static void reloadTableSchema(Parse *pParse, Table *pTab, const char *zName){
77110 Vdbe *v;
77111 char *zWhere;
77112 int iDb; /* Index of database containing pTab */
77113 #ifndef SQLITE_OMIT_TRIGGER
77114 Trigger *pTrig;
77115 #endif
77117 v = sqlite3GetVdbe(pParse);
77118 if( NEVER(v==0) ) return;
77119 assert( sqlite3BtreeHoldsAllMutexes(pParse->db) );
77120 iDb = sqlite3SchemaToIndex(pParse->db, pTab->pSchema);
77121 assert( iDb>=0 );
77123 #ifndef SQLITE_OMIT_TRIGGER
77124 /* Drop any table triggers from the internal schema. */
77125 for(pTrig=sqlite3TriggerList(pParse, pTab); pTrig; pTrig=pTrig->pNext){
77126 int iTrigDb = sqlite3SchemaToIndex(pParse->db, pTrig->pSchema);
77127 assert( iTrigDb==iDb || iTrigDb==1 );
77128 sqlite3VdbeAddOp4(v, OP_DropTrigger, iTrigDb, 0, 0, pTrig->zName, 0);
77130 #endif
77132 /* Drop the table and index from the internal schema. */
77133 sqlite3VdbeAddOp4(v, OP_DropTable, iDb, 0, 0, pTab->zName, 0);
77135 /* Reload the table, index and permanent trigger schemas. */
77136 zWhere = sqlite3MPrintf(pParse->db, "tbl_name=%Q", zName);
77137 if( !zWhere ) return;
77138 sqlite3VdbeAddParseSchemaOp(v, iDb, zWhere);
77140 #ifndef SQLITE_OMIT_TRIGGER
77141 /* Now, if the table is not stored in the temp database, reload any temp
77142 ** triggers. Don't use IN(...) in case SQLITE_OMIT_SUBQUERY is defined.
77144 if( (zWhere=whereTempTriggers(pParse, pTab))!=0 ){
77145 sqlite3VdbeAddParseSchemaOp(v, 1, zWhere);
77147 #endif
77151 ** Parameter zName is the name of a table that is about to be altered
77152 ** (either with ALTER TABLE ... RENAME TO or ALTER TABLE ... ADD COLUMN).
77153 ** If the table is a system table, this function leaves an error message
77154 ** in pParse->zErr (system tables may not be altered) and returns non-zero.
77156 ** Or, if zName is not a system table, zero is returned.
77158 static int isSystemTable(Parse *pParse, const char *zName){
77159 if( sqlite3Strlen30(zName)>6 && 0==sqlite3StrNICmp(zName, "sqlite_", 7) ){
77160 sqlite3ErrorMsg(pParse, "table %s may not be altered", zName);
77161 return 1;
77163 return 0;
77167 ** Generate code to implement the "ALTER TABLE xxx RENAME TO yyy"
77168 ** command.
77170 SQLITE_PRIVATE void sqlite3AlterRenameTable(
77171 Parse *pParse, /* Parser context. */
77172 SrcList *pSrc, /* The table to rename. */
77173 Token *pName /* The new table name. */
77175 int iDb; /* Database that contains the table */
77176 char *zDb; /* Name of database iDb */
77177 Table *pTab; /* Table being renamed */
77178 char *zName = 0; /* NULL-terminated version of pName */
77179 sqlite3 *db = pParse->db; /* Database connection */
77180 int nTabName; /* Number of UTF-8 characters in zTabName */
77181 const char *zTabName; /* Original name of the table */
77182 Vdbe *v;
77183 #ifndef SQLITE_OMIT_TRIGGER
77184 char *zWhere = 0; /* Where clause to locate temp triggers */
77185 #endif
77186 VTable *pVTab = 0; /* Non-zero if this is a v-tab with an xRename() */
77187 int savedDbFlags; /* Saved value of db->flags */
77189 savedDbFlags = db->flags;
77190 if( NEVER(db->mallocFailed) ) goto exit_rename_table;
77191 assert( pSrc->nSrc==1 );
77192 assert( sqlite3BtreeHoldsAllMutexes(pParse->db) );
77194 pTab = sqlite3LocateTable(pParse, 0, pSrc->a[0].zName, pSrc->a[0].zDatabase);
77195 if( !pTab ) goto exit_rename_table;
77196 iDb = sqlite3SchemaToIndex(pParse->db, pTab->pSchema);
77197 zDb = db->aDb[iDb].zName;
77198 db->flags |= SQLITE_PreferBuiltin;
77200 /* Get a NULL terminated version of the new table name. */
77201 zName = sqlite3NameFromToken(db, pName);
77202 if( !zName ) goto exit_rename_table;
77204 /* Check that a table or index named 'zName' does not already exist
77205 ** in database iDb. If so, this is an error.
77207 if( sqlite3FindTable(db, zName, zDb) || sqlite3FindIndex(db, zName, zDb) ){
77208 sqlite3ErrorMsg(pParse,
77209 "there is already another table or index with this name: %s", zName);
77210 goto exit_rename_table;
77213 /* Make sure it is not a system table being altered, or a reserved name
77214 ** that the table is being renamed to.
77216 if( SQLITE_OK!=isSystemTable(pParse, pTab->zName) ){
77217 goto exit_rename_table;
77219 if( SQLITE_OK!=sqlite3CheckObjectName(pParse, zName) ){ goto
77220 exit_rename_table;
77223 #ifndef SQLITE_OMIT_VIEW
77224 if( pTab->pSelect ){
77225 sqlite3ErrorMsg(pParse, "view %s may not be altered", pTab->zName);
77226 goto exit_rename_table;
77228 #endif
77230 #ifndef SQLITE_OMIT_AUTHORIZATION
77231 /* Invoke the authorization callback. */
77232 if( sqlite3AuthCheck(pParse, SQLITE_ALTER_TABLE, zDb, pTab->zName, 0) ){
77233 goto exit_rename_table;
77235 #endif
77237 #ifndef SQLITE_OMIT_VIRTUALTABLE
77238 if( sqlite3ViewGetColumnNames(pParse, pTab) ){
77239 goto exit_rename_table;
77241 if( IsVirtual(pTab) ){
77242 pVTab = sqlite3GetVTable(db, pTab);
77243 if( pVTab->pVtab->pModule->xRename==0 ){
77244 pVTab = 0;
77247 #endif
77249 /* Begin a transaction and code the VerifyCookie for database iDb.
77250 ** Then modify the schema cookie (since the ALTER TABLE modifies the
77251 ** schema). Open a statement transaction if the table is a virtual
77252 ** table.
77254 v = sqlite3GetVdbe(pParse);
77255 if( v==0 ){
77256 goto exit_rename_table;
77258 sqlite3BeginWriteOperation(pParse, pVTab!=0, iDb);
77259 sqlite3ChangeCookie(pParse, iDb);
77261 /* If this is a virtual table, invoke the xRename() function if
77262 ** one is defined. The xRename() callback will modify the names
77263 ** of any resources used by the v-table implementation (including other
77264 ** SQLite tables) that are identified by the name of the virtual table.
77266 #ifndef SQLITE_OMIT_VIRTUALTABLE
77267 if( pVTab ){
77268 int i = ++pParse->nMem;
77269 sqlite3VdbeAddOp4(v, OP_String8, 0, i, 0, zName, 0);
77270 sqlite3VdbeAddOp4(v, OP_VRename, i, 0, 0,(const char*)pVTab, P4_VTAB);
77271 sqlite3MayAbort(pParse);
77273 #endif
77275 /* figure out how many UTF-8 characters are in zName */
77276 zTabName = pTab->zName;
77277 nTabName = sqlite3Utf8CharLen(zTabName, -1);
77279 #if !defined(SQLITE_OMIT_FOREIGN_KEY) && !defined(SQLITE_OMIT_TRIGGER)
77280 if( db->flags&SQLITE_ForeignKeys ){
77281 /* If foreign-key support is enabled, rewrite the CREATE TABLE
77282 ** statements corresponding to all child tables of foreign key constraints
77283 ** for which the renamed table is the parent table. */
77284 if( (zWhere=whereForeignKeys(pParse, pTab))!=0 ){
77285 sqlite3NestedParse(pParse,
77286 "UPDATE \"%w\".%s SET "
77287 "sql = sqlite_rename_parent(sql, %Q, %Q) "
77288 "WHERE %s;", zDb, SCHEMA_TABLE(iDb), zTabName, zName, zWhere);
77289 sqlite3DbFree(db, zWhere);
77292 #endif
77294 /* Modify the sqlite_master table to use the new table name. */
77295 sqlite3NestedParse(pParse,
77296 "UPDATE %Q.%s SET "
77297 #ifdef SQLITE_OMIT_TRIGGER
77298 "sql = sqlite_rename_table(sql, %Q), "
77299 #else
77300 "sql = CASE "
77301 "WHEN type = 'trigger' THEN sqlite_rename_trigger(sql, %Q)"
77302 "ELSE sqlite_rename_table(sql, %Q) END, "
77303 #endif
77304 "tbl_name = %Q, "
77305 "name = CASE "
77306 "WHEN type='table' THEN %Q "
77307 "WHEN name LIKE 'sqlite_autoindex%%' AND type='index' THEN "
77308 "'sqlite_autoindex_' || %Q || substr(name,%d+18) "
77309 "ELSE name END "
77310 "WHERE tbl_name=%Q AND "
77311 "(type='table' OR type='index' OR type='trigger');",
77312 zDb, SCHEMA_TABLE(iDb), zName, zName, zName,
77313 #ifndef SQLITE_OMIT_TRIGGER
77314 zName,
77315 #endif
77316 zName, nTabName, zTabName
77319 #ifndef SQLITE_OMIT_AUTOINCREMENT
77320 /* If the sqlite_sequence table exists in this database, then update
77321 ** it with the new table name.
77323 if( sqlite3FindTable(db, "sqlite_sequence", zDb) ){
77324 sqlite3NestedParse(pParse,
77325 "UPDATE \"%w\".sqlite_sequence set name = %Q WHERE name = %Q",
77326 zDb, zName, pTab->zName);
77328 #endif
77330 #ifndef SQLITE_OMIT_TRIGGER
77331 /* If there are TEMP triggers on this table, modify the sqlite_temp_master
77332 ** table. Don't do this if the table being ALTERed is itself located in
77333 ** the temp database.
77335 if( (zWhere=whereTempTriggers(pParse, pTab))!=0 ){
77336 sqlite3NestedParse(pParse,
77337 "UPDATE sqlite_temp_master SET "
77338 "sql = sqlite_rename_trigger(sql, %Q), "
77339 "tbl_name = %Q "
77340 "WHERE %s;", zName, zName, zWhere);
77341 sqlite3DbFree(db, zWhere);
77343 #endif
77345 #if !defined(SQLITE_OMIT_FOREIGN_KEY) && !defined(SQLITE_OMIT_TRIGGER)
77346 if( db->flags&SQLITE_ForeignKeys ){
77347 FKey *p;
77348 for(p=sqlite3FkReferences(pTab); p; p=p->pNextTo){
77349 Table *pFrom = p->pFrom;
77350 if( pFrom!=pTab ){
77351 reloadTableSchema(pParse, p->pFrom, pFrom->zName);
77355 #endif
77357 /* Drop and reload the internal table schema. */
77358 reloadTableSchema(pParse, pTab, zName);
77360 exit_rename_table:
77361 sqlite3SrcListDelete(db, pSrc);
77362 sqlite3DbFree(db, zName);
77363 db->flags = savedDbFlags;
77368 ** Generate code to make sure the file format number is at least minFormat.
77369 ** The generated code will increase the file format number if necessary.
77371 SQLITE_PRIVATE void sqlite3MinimumFileFormat(Parse *pParse, int iDb, int minFormat){
77372 Vdbe *v;
77373 v = sqlite3GetVdbe(pParse);
77374 /* The VDBE should have been allocated before this routine is called.
77375 ** If that allocation failed, we would have quit before reaching this
77376 ** point */
77377 if( ALWAYS(v) ){
77378 int r1 = sqlite3GetTempReg(pParse);
77379 int r2 = sqlite3GetTempReg(pParse);
77380 int j1;
77381 sqlite3VdbeAddOp3(v, OP_ReadCookie, iDb, r1, BTREE_FILE_FORMAT);
77382 sqlite3VdbeUsesBtree(v, iDb);
77383 sqlite3VdbeAddOp2(v, OP_Integer, minFormat, r2);
77384 j1 = sqlite3VdbeAddOp3(v, OP_Ge, r2, 0, r1);
77385 sqlite3VdbeAddOp3(v, OP_SetCookie, iDb, BTREE_FILE_FORMAT, r2);
77386 sqlite3VdbeJumpHere(v, j1);
77387 sqlite3ReleaseTempReg(pParse, r1);
77388 sqlite3ReleaseTempReg(pParse, r2);
77393 ** This function is called after an "ALTER TABLE ... ADD" statement
77394 ** has been parsed. Argument pColDef contains the text of the new
77395 ** column definition.
77397 ** The Table structure pParse->pNewTable was extended to include
77398 ** the new column during parsing.
77400 SQLITE_PRIVATE void sqlite3AlterFinishAddColumn(Parse *pParse, Token *pColDef){
77401 Table *pNew; /* Copy of pParse->pNewTable */
77402 Table *pTab; /* Table being altered */
77403 int iDb; /* Database number */
77404 const char *zDb; /* Database name */
77405 const char *zTab; /* Table name */
77406 char *zCol; /* Null-terminated column definition */
77407 Column *pCol; /* The new column */
77408 Expr *pDflt; /* Default value for the new column */
77409 sqlite3 *db; /* The database connection; */
77411 db = pParse->db;
77412 if( pParse->nErr || db->mallocFailed ) return;
77413 pNew = pParse->pNewTable;
77414 assert( pNew );
77416 assert( sqlite3BtreeHoldsAllMutexes(db) );
77417 iDb = sqlite3SchemaToIndex(db, pNew->pSchema);
77418 zDb = db->aDb[iDb].zName;
77419 zTab = &pNew->zName[16]; /* Skip the "sqlite_altertab_" prefix on the name */
77420 pCol = &pNew->aCol[pNew->nCol-1];
77421 pDflt = pCol->pDflt;
77422 pTab = sqlite3FindTable(db, zTab, zDb);
77423 assert( pTab );
77425 #ifndef SQLITE_OMIT_AUTHORIZATION
77426 /* Invoke the authorization callback. */
77427 if( sqlite3AuthCheck(pParse, SQLITE_ALTER_TABLE, zDb, pTab->zName, 0) ){
77428 return;
77430 #endif
77432 /* If the default value for the new column was specified with a
77433 ** literal NULL, then set pDflt to 0. This simplifies checking
77434 ** for an SQL NULL default below.
77436 if( pDflt && pDflt->op==TK_NULL ){
77437 pDflt = 0;
77440 /* Check that the new column is not specified as PRIMARY KEY or UNIQUE.
77441 ** If there is a NOT NULL constraint, then the default value for the
77442 ** column must not be NULL.
77444 if( pCol->isPrimKey ){
77445 sqlite3ErrorMsg(pParse, "Cannot add a PRIMARY KEY column");
77446 return;
77448 if( pNew->pIndex ){
77449 sqlite3ErrorMsg(pParse, "Cannot add a UNIQUE column");
77450 return;
77452 if( (db->flags&SQLITE_ForeignKeys) && pNew->pFKey && pDflt ){
77453 sqlite3ErrorMsg(pParse,
77454 "Cannot add a REFERENCES column with non-NULL default value");
77455 return;
77457 if( pCol->notNull && !pDflt ){
77458 sqlite3ErrorMsg(pParse,
77459 "Cannot add a NOT NULL column with default value NULL");
77460 return;
77463 /* Ensure the default expression is something that sqlite3ValueFromExpr()
77464 ** can handle (i.e. not CURRENT_TIME etc.)
77466 if( pDflt ){
77467 sqlite3_value *pVal;
77468 if( sqlite3ValueFromExpr(db, pDflt, SQLITE_UTF8, SQLITE_AFF_NONE, &pVal) ){
77469 db->mallocFailed = 1;
77470 return;
77472 if( !pVal ){
77473 sqlite3ErrorMsg(pParse, "Cannot add a column with non-constant default");
77474 return;
77476 sqlite3ValueFree(pVal);
77479 /* Modify the CREATE TABLE statement. */
77480 zCol = sqlite3DbStrNDup(db, (char*)pColDef->z, pColDef->n);
77481 if( zCol ){
77482 char *zEnd = &zCol[pColDef->n-1];
77483 int savedDbFlags = db->flags;
77484 while( zEnd>zCol && (*zEnd==';' || sqlite3Isspace(*zEnd)) ){
77485 *zEnd-- = '\0';
77487 db->flags |= SQLITE_PreferBuiltin;
77488 sqlite3NestedParse(pParse,
77489 "UPDATE \"%w\".%s SET "
77490 "sql = substr(sql,1,%d) || ', ' || %Q || substr(sql,%d) "
77491 "WHERE type = 'table' AND name = %Q",
77492 zDb, SCHEMA_TABLE(iDb), pNew->addColOffset, zCol, pNew->addColOffset+1,
77493 zTab
77495 sqlite3DbFree(db, zCol);
77496 db->flags = savedDbFlags;
77499 /* If the default value of the new column is NULL, then set the file
77500 ** format to 2. If the default value of the new column is not NULL,
77501 ** the file format becomes 3.
77503 sqlite3MinimumFileFormat(pParse, iDb, pDflt ? 3 : 2);
77505 /* Reload the schema of the modified table. */
77506 reloadTableSchema(pParse, pTab, pTab->zName);
77510 ** This function is called by the parser after the table-name in
77511 ** an "ALTER TABLE <table-name> ADD" statement is parsed. Argument
77512 ** pSrc is the full-name of the table being altered.
77514 ** This routine makes a (partial) copy of the Table structure
77515 ** for the table being altered and sets Parse.pNewTable to point
77516 ** to it. Routines called by the parser as the column definition
77517 ** is parsed (i.e. sqlite3AddColumn()) add the new Column data to
77518 ** the copy. The copy of the Table structure is deleted by tokenize.c
77519 ** after parsing is finished.
77521 ** Routine sqlite3AlterFinishAddColumn() will be called to complete
77522 ** coding the "ALTER TABLE ... ADD" statement.
77524 SQLITE_PRIVATE void sqlite3AlterBeginAddColumn(Parse *pParse, SrcList *pSrc){
77525 Table *pNew;
77526 Table *pTab;
77527 Vdbe *v;
77528 int iDb;
77529 int i;
77530 int nAlloc;
77531 sqlite3 *db = pParse->db;
77533 /* Look up the table being altered. */
77534 assert( pParse->pNewTable==0 );
77535 assert( sqlite3BtreeHoldsAllMutexes(db) );
77536 if( db->mallocFailed ) goto exit_begin_add_column;
77537 pTab = sqlite3LocateTable(pParse, 0, pSrc->a[0].zName, pSrc->a[0].zDatabase);
77538 if( !pTab ) goto exit_begin_add_column;
77540 #ifndef SQLITE_OMIT_VIRTUALTABLE
77541 if( IsVirtual(pTab) ){
77542 sqlite3ErrorMsg(pParse, "virtual tables may not be altered");
77543 goto exit_begin_add_column;
77545 #endif
77547 /* Make sure this is not an attempt to ALTER a view. */
77548 if( pTab->pSelect ){
77549 sqlite3ErrorMsg(pParse, "Cannot add a column to a view");
77550 goto exit_begin_add_column;
77552 if( SQLITE_OK!=isSystemTable(pParse, pTab->zName) ){
77553 goto exit_begin_add_column;
77556 assert( pTab->addColOffset>0 );
77557 iDb = sqlite3SchemaToIndex(db, pTab->pSchema);
77559 /* Put a copy of the Table struct in Parse.pNewTable for the
77560 ** sqlite3AddColumn() function and friends to modify. But modify
77561 ** the name by adding an "sqlite_altertab_" prefix. By adding this
77562 ** prefix, we insure that the name will not collide with an existing
77563 ** table because user table are not allowed to have the "sqlite_"
77564 ** prefix on their name.
77566 pNew = (Table*)sqlite3DbMallocZero(db, sizeof(Table));
77567 if( !pNew ) goto exit_begin_add_column;
77568 pParse->pNewTable = pNew;
77569 pNew->nRef = 1;
77570 pNew->nCol = pTab->nCol;
77571 assert( pNew->nCol>0 );
77572 nAlloc = (((pNew->nCol-1)/8)*8)+8;
77573 assert( nAlloc>=pNew->nCol && nAlloc%8==0 && nAlloc-pNew->nCol<8 );
77574 pNew->aCol = (Column*)sqlite3DbMallocZero(db, sizeof(Column)*nAlloc);
77575 pNew->zName = sqlite3MPrintf(db, "sqlite_altertab_%s", pTab->zName);
77576 if( !pNew->aCol || !pNew->zName ){
77577 db->mallocFailed = 1;
77578 goto exit_begin_add_column;
77580 memcpy(pNew->aCol, pTab->aCol, sizeof(Column)*pNew->nCol);
77581 for(i=0; i<pNew->nCol; i++){
77582 Column *pCol = &pNew->aCol[i];
77583 pCol->zName = sqlite3DbStrDup(db, pCol->zName);
77584 pCol->zColl = 0;
77585 pCol->zType = 0;
77586 pCol->pDflt = 0;
77587 pCol->zDflt = 0;
77589 pNew->pSchema = db->aDb[iDb].pSchema;
77590 pNew->addColOffset = pTab->addColOffset;
77591 pNew->nRef = 1;
77593 /* Begin a transaction and increment the schema cookie. */
77594 sqlite3BeginWriteOperation(pParse, 0, iDb);
77595 v = sqlite3GetVdbe(pParse);
77596 if( !v ) goto exit_begin_add_column;
77597 sqlite3ChangeCookie(pParse, iDb);
77599 exit_begin_add_column:
77600 sqlite3SrcListDelete(db, pSrc);
77601 return;
77603 #endif /* SQLITE_ALTER_TABLE */
77605 /************** End of alter.c ***********************************************/
77606 /************** Begin file analyze.c *****************************************/
77608 ** 2005 July 8
77610 ** The author disclaims copyright to this source code. In place of
77611 ** a legal notice, here is a blessing:
77613 ** May you do good and not evil.
77614 ** May you find forgiveness for yourself and forgive others.
77615 ** May you share freely, never taking more than you give.
77617 *************************************************************************
77618 ** This file contains code associated with the ANALYZE command.
77620 #ifndef SQLITE_OMIT_ANALYZE
77623 ** This routine generates code that opens the sqlite_stat1 table for
77624 ** writing with cursor iStatCur. If the library was built with the
77625 ** SQLITE_ENABLE_STAT2 macro defined, then the sqlite_stat2 table is
77626 ** opened for writing using cursor (iStatCur+1)
77628 ** If the sqlite_stat1 tables does not previously exist, it is created.
77629 ** Similarly, if the sqlite_stat2 table does not exist and the library
77630 ** is compiled with SQLITE_ENABLE_STAT2 defined, it is created.
77632 ** Argument zWhere may be a pointer to a buffer containing a table name,
77633 ** or it may be a NULL pointer. If it is not NULL, then all entries in
77634 ** the sqlite_stat1 and (if applicable) sqlite_stat2 tables associated
77635 ** with the named table are deleted. If zWhere==0, then code is generated
77636 ** to delete all stat table entries.
77638 static void openStatTable(
77639 Parse *pParse, /* Parsing context */
77640 int iDb, /* The database we are looking in */
77641 int iStatCur, /* Open the sqlite_stat1 table on this cursor */
77642 const char *zWhere, /* Delete entries for this table or index */
77643 const char *zWhereType /* Either "tbl" or "idx" */
77645 static const struct {
77646 const char *zName;
77647 const char *zCols;
77648 } aTable[] = {
77649 { "sqlite_stat1", "tbl,idx,stat" },
77650 #ifdef SQLITE_ENABLE_STAT2
77651 { "sqlite_stat2", "tbl,idx,sampleno,sample" },
77652 #endif
77655 int aRoot[] = {0, 0};
77656 u8 aCreateTbl[] = {0, 0};
77658 int i;
77659 sqlite3 *db = pParse->db;
77660 Db *pDb;
77661 Vdbe *v = sqlite3GetVdbe(pParse);
77662 if( v==0 ) return;
77663 assert( sqlite3BtreeHoldsAllMutexes(db) );
77664 assert( sqlite3VdbeDb(v)==db );
77665 pDb = &db->aDb[iDb];
77667 for(i=0; i<ArraySize(aTable); i++){
77668 const char *zTab = aTable[i].zName;
77669 Table *pStat;
77670 if( (pStat = sqlite3FindTable(db, zTab, pDb->zName))==0 ){
77671 /* The sqlite_stat[12] table does not exist. Create it. Note that a
77672 ** side-effect of the CREATE TABLE statement is to leave the rootpage
77673 ** of the new table in register pParse->regRoot. This is important
77674 ** because the OpenWrite opcode below will be needing it. */
77675 sqlite3NestedParse(pParse,
77676 "CREATE TABLE %Q.%s(%s)", pDb->zName, zTab, aTable[i].zCols
77678 aRoot[i] = pParse->regRoot;
77679 aCreateTbl[i] = 1;
77680 }else{
77681 /* The table already exists. If zWhere is not NULL, delete all entries
77682 ** associated with the table zWhere. If zWhere is NULL, delete the
77683 ** entire contents of the table. */
77684 aRoot[i] = pStat->tnum;
77685 sqlite3TableLock(pParse, iDb, aRoot[i], 1, zTab);
77686 if( zWhere ){
77687 sqlite3NestedParse(pParse,
77688 "DELETE FROM %Q.%s WHERE %s=%Q", pDb->zName, zTab, zWhereType, zWhere
77690 }else{
77691 /* The sqlite_stat[12] table already exists. Delete all rows. */
77692 sqlite3VdbeAddOp2(v, OP_Clear, aRoot[i], iDb);
77697 /* Open the sqlite_stat[12] tables for writing. */
77698 for(i=0; i<ArraySize(aTable); i++){
77699 sqlite3VdbeAddOp3(v, OP_OpenWrite, iStatCur+i, aRoot[i], iDb);
77700 sqlite3VdbeChangeP4(v, -1, (char *)3, P4_INT32);
77701 sqlite3VdbeChangeP5(v, aCreateTbl[i]);
77706 ** Generate code to do an analysis of all indices associated with
77707 ** a single table.
77709 static void analyzeOneTable(
77710 Parse *pParse, /* Parser context */
77711 Table *pTab, /* Table whose indices are to be analyzed */
77712 Index *pOnlyIdx, /* If not NULL, only analyze this one index */
77713 int iStatCur, /* Index of VdbeCursor that writes the sqlite_stat1 table */
77714 int iMem /* Available memory locations begin here */
77716 sqlite3 *db = pParse->db; /* Database handle */
77717 Index *pIdx; /* An index to being analyzed */
77718 int iIdxCur; /* Cursor open on index being analyzed */
77719 Vdbe *v; /* The virtual machine being built up */
77720 int i; /* Loop counter */
77721 int topOfLoop; /* The top of the loop */
77722 int endOfLoop; /* The end of the loop */
77723 int jZeroRows = -1; /* Jump from here if number of rows is zero */
77724 int iDb; /* Index of database containing pTab */
77725 int regTabname = iMem++; /* Register containing table name */
77726 int regIdxname = iMem++; /* Register containing index name */
77727 int regSampleno = iMem++; /* Register containing next sample number */
77728 int regCol = iMem++; /* Content of a column analyzed table */
77729 int regRec = iMem++; /* Register holding completed record */
77730 int regTemp = iMem++; /* Temporary use register */
77731 int regRowid = iMem++; /* Rowid for the inserted record */
77733 #ifdef SQLITE_ENABLE_STAT2
77734 int addr = 0; /* Instruction address */
77735 int regTemp2 = iMem++; /* Temporary use register */
77736 int regSamplerecno = iMem++; /* Index of next sample to record */
77737 int regRecno = iMem++; /* Current sample index */
77738 int regLast = iMem++; /* Index of last sample to record */
77739 int regFirst = iMem++; /* Index of first sample to record */
77740 #endif
77742 v = sqlite3GetVdbe(pParse);
77743 if( v==0 || NEVER(pTab==0) ){
77744 return;
77746 if( pTab->tnum==0 ){
77747 /* Do not gather statistics on views or virtual tables */
77748 return;
77750 if( memcmp(pTab->zName, "sqlite_", 7)==0 ){
77751 /* Do not gather statistics on system tables */
77752 return;
77754 assert( sqlite3BtreeHoldsAllMutexes(db) );
77755 iDb = sqlite3SchemaToIndex(db, pTab->pSchema);
77756 assert( iDb>=0 );
77757 assert( sqlite3SchemaMutexHeld(db, iDb, 0) );
77758 #ifndef SQLITE_OMIT_AUTHORIZATION
77759 if( sqlite3AuthCheck(pParse, SQLITE_ANALYZE, pTab->zName, 0,
77760 db->aDb[iDb].zName ) ){
77761 return;
77763 #endif
77765 /* Establish a read-lock on the table at the shared-cache level. */
77766 sqlite3TableLock(pParse, iDb, pTab->tnum, 0, pTab->zName);
77768 iIdxCur = pParse->nTab++;
77769 sqlite3VdbeAddOp4(v, OP_String8, 0, regTabname, 0, pTab->zName, 0);
77770 for(pIdx=pTab->pIndex; pIdx; pIdx=pIdx->pNext){
77771 int nCol;
77772 KeyInfo *pKey;
77774 if( pOnlyIdx && pOnlyIdx!=pIdx ) continue;
77775 nCol = pIdx->nColumn;
77776 pKey = sqlite3IndexKeyinfo(pParse, pIdx);
77777 if( iMem+1+(nCol*2)>pParse->nMem ){
77778 pParse->nMem = iMem+1+(nCol*2);
77781 /* Open a cursor to the index to be analyzed. */
77782 assert( iDb==sqlite3SchemaToIndex(db, pIdx->pSchema) );
77783 sqlite3VdbeAddOp4(v, OP_OpenRead, iIdxCur, pIdx->tnum, iDb,
77784 (char *)pKey, P4_KEYINFO_HANDOFF);
77785 VdbeComment((v, "%s", pIdx->zName));
77787 /* Populate the register containing the index name. */
77788 sqlite3VdbeAddOp4(v, OP_String8, 0, regIdxname, 0, pIdx->zName, 0);
77790 #ifdef SQLITE_ENABLE_STAT2
77792 /* If this iteration of the loop is generating code to analyze the
77793 ** first index in the pTab->pIndex list, then register regLast has
77794 ** not been populated. In this case populate it now. */
77795 if( pTab->pIndex==pIdx ){
77796 sqlite3VdbeAddOp2(v, OP_Integer, SQLITE_INDEX_SAMPLES, regSamplerecno);
77797 sqlite3VdbeAddOp2(v, OP_Integer, SQLITE_INDEX_SAMPLES*2-1, regTemp);
77798 sqlite3VdbeAddOp2(v, OP_Integer, SQLITE_INDEX_SAMPLES*2, regTemp2);
77800 sqlite3VdbeAddOp2(v, OP_Count, iIdxCur, regLast);
77801 sqlite3VdbeAddOp2(v, OP_Null, 0, regFirst);
77802 addr = sqlite3VdbeAddOp3(v, OP_Lt, regSamplerecno, 0, regLast);
77803 sqlite3VdbeAddOp3(v, OP_Divide, regTemp2, regLast, regFirst);
77804 sqlite3VdbeAddOp3(v, OP_Multiply, regLast, regTemp, regLast);
77805 sqlite3VdbeAddOp2(v, OP_AddImm, regLast, SQLITE_INDEX_SAMPLES*2-2);
77806 sqlite3VdbeAddOp3(v, OP_Divide, regTemp2, regLast, regLast);
77807 sqlite3VdbeJumpHere(v, addr);
77810 /* Zero the regSampleno and regRecno registers. */
77811 sqlite3VdbeAddOp2(v, OP_Integer, 0, regSampleno);
77812 sqlite3VdbeAddOp2(v, OP_Integer, 0, regRecno);
77813 sqlite3VdbeAddOp2(v, OP_Copy, regFirst, regSamplerecno);
77814 #endif
77816 /* The block of memory cells initialized here is used as follows.
77818 ** iMem:
77819 ** The total number of rows in the table.
77821 ** iMem+1 .. iMem+nCol:
77822 ** Number of distinct entries in index considering the
77823 ** left-most N columns only, where N is between 1 and nCol,
77824 ** inclusive.
77826 ** iMem+nCol+1 .. Mem+2*nCol:
77827 ** Previous value of indexed columns, from left to right.
77829 ** Cells iMem through iMem+nCol are initialized to 0. The others are
77830 ** initialized to contain an SQL NULL.
77832 for(i=0; i<=nCol; i++){
77833 sqlite3VdbeAddOp2(v, OP_Integer, 0, iMem+i);
77835 for(i=0; i<nCol; i++){
77836 sqlite3VdbeAddOp2(v, OP_Null, 0, iMem+nCol+i+1);
77839 /* Start the analysis loop. This loop runs through all the entries in
77840 ** the index b-tree. */
77841 endOfLoop = sqlite3VdbeMakeLabel(v);
77842 sqlite3VdbeAddOp2(v, OP_Rewind, iIdxCur, endOfLoop);
77843 topOfLoop = sqlite3VdbeCurrentAddr(v);
77844 sqlite3VdbeAddOp2(v, OP_AddImm, iMem, 1);
77846 for(i=0; i<nCol; i++){
77847 CollSeq *pColl;
77848 sqlite3VdbeAddOp3(v, OP_Column, iIdxCur, i, regCol);
77849 if( i==0 ){
77850 #ifdef SQLITE_ENABLE_STAT2
77851 /* Check if the record that cursor iIdxCur points to contains a
77852 ** value that should be stored in the sqlite_stat2 table. If so,
77853 ** store it. */
77854 int ne = sqlite3VdbeAddOp3(v, OP_Ne, regRecno, 0, regSamplerecno);
77855 assert( regTabname+1==regIdxname
77856 && regTabname+2==regSampleno
77857 && regTabname+3==regCol
77859 sqlite3VdbeChangeP5(v, SQLITE_JUMPIFNULL);
77860 sqlite3VdbeAddOp4(v, OP_MakeRecord, regTabname, 4, regRec, "aaab", 0);
77861 sqlite3VdbeAddOp2(v, OP_NewRowid, iStatCur+1, regRowid);
77862 sqlite3VdbeAddOp3(v, OP_Insert, iStatCur+1, regRec, regRowid);
77864 /* Calculate new values for regSamplerecno and regSampleno.
77866 ** sampleno = sampleno + 1
77867 ** samplerecno = samplerecno+(remaining records)/(remaining samples)
77869 sqlite3VdbeAddOp2(v, OP_AddImm, regSampleno, 1);
77870 sqlite3VdbeAddOp3(v, OP_Subtract, regRecno, regLast, regTemp);
77871 sqlite3VdbeAddOp2(v, OP_AddImm, regTemp, -1);
77872 sqlite3VdbeAddOp2(v, OP_Integer, SQLITE_INDEX_SAMPLES, regTemp2);
77873 sqlite3VdbeAddOp3(v, OP_Subtract, regSampleno, regTemp2, regTemp2);
77874 sqlite3VdbeAddOp3(v, OP_Divide, regTemp2, regTemp, regTemp);
77875 sqlite3VdbeAddOp3(v, OP_Add, regSamplerecno, regTemp, regSamplerecno);
77877 sqlite3VdbeJumpHere(v, ne);
77878 sqlite3VdbeAddOp2(v, OP_AddImm, regRecno, 1);
77879 #endif
77881 /* Always record the very first row */
77882 sqlite3VdbeAddOp1(v, OP_IfNot, iMem+1);
77884 assert( pIdx->azColl!=0 );
77885 assert( pIdx->azColl[i]!=0 );
77886 pColl = sqlite3LocateCollSeq(pParse, pIdx->azColl[i]);
77887 sqlite3VdbeAddOp4(v, OP_Ne, regCol, 0, iMem+nCol+i+1,
77888 (char*)pColl, P4_COLLSEQ);
77889 sqlite3VdbeChangeP5(v, SQLITE_NULLEQ);
77891 if( db->mallocFailed ){
77892 /* If a malloc failure has occurred, then the result of the expression
77893 ** passed as the second argument to the call to sqlite3VdbeJumpHere()
77894 ** below may be negative. Which causes an assert() to fail (or an
77895 ** out-of-bounds write if SQLITE_DEBUG is not defined). */
77896 return;
77898 sqlite3VdbeAddOp2(v, OP_Goto, 0, endOfLoop);
77899 for(i=0; i<nCol; i++){
77900 int addr2 = sqlite3VdbeCurrentAddr(v) - (nCol*2);
77901 if( i==0 ){
77902 sqlite3VdbeJumpHere(v, addr2-1); /* Set jump dest for the OP_IfNot */
77904 sqlite3VdbeJumpHere(v, addr2); /* Set jump dest for the OP_Ne */
77905 sqlite3VdbeAddOp2(v, OP_AddImm, iMem+i+1, 1);
77906 sqlite3VdbeAddOp3(v, OP_Column, iIdxCur, i, iMem+nCol+i+1);
77909 /* End of the analysis loop. */
77910 sqlite3VdbeResolveLabel(v, endOfLoop);
77911 sqlite3VdbeAddOp2(v, OP_Next, iIdxCur, topOfLoop);
77912 sqlite3VdbeAddOp1(v, OP_Close, iIdxCur);
77914 /* Store the results in sqlite_stat1.
77916 ** The result is a single row of the sqlite_stat1 table. The first
77917 ** two columns are the names of the table and index. The third column
77918 ** is a string composed of a list of integer statistics about the
77919 ** index. The first integer in the list is the total number of entries
77920 ** in the index. There is one additional integer in the list for each
77921 ** column of the table. This additional integer is a guess of how many
77922 ** rows of the table the index will select. If D is the count of distinct
77923 ** values and K is the total number of rows, then the integer is computed
77924 ** as:
77926 ** I = (K+D-1)/D
77928 ** If K==0 then no entry is made into the sqlite_stat1 table.
77929 ** If K>0 then it is always the case the D>0 so division by zero
77930 ** is never possible.
77932 sqlite3VdbeAddOp2(v, OP_SCopy, iMem, regSampleno);
77933 if( jZeroRows<0 ){
77934 jZeroRows = sqlite3VdbeAddOp1(v, OP_IfNot, iMem);
77936 for(i=0; i<nCol; i++){
77937 sqlite3VdbeAddOp4(v, OP_String8, 0, regTemp, 0, " ", 0);
77938 sqlite3VdbeAddOp3(v, OP_Concat, regTemp, regSampleno, regSampleno);
77939 sqlite3VdbeAddOp3(v, OP_Add, iMem, iMem+i+1, regTemp);
77940 sqlite3VdbeAddOp2(v, OP_AddImm, regTemp, -1);
77941 sqlite3VdbeAddOp3(v, OP_Divide, iMem+i+1, regTemp, regTemp);
77942 sqlite3VdbeAddOp1(v, OP_ToInt, regTemp);
77943 sqlite3VdbeAddOp3(v, OP_Concat, regTemp, regSampleno, regSampleno);
77945 sqlite3VdbeAddOp4(v, OP_MakeRecord, regTabname, 3, regRec, "aaa", 0);
77946 sqlite3VdbeAddOp2(v, OP_NewRowid, iStatCur, regRowid);
77947 sqlite3VdbeAddOp3(v, OP_Insert, iStatCur, regRec, regRowid);
77948 sqlite3VdbeChangeP5(v, OPFLAG_APPEND);
77951 /* If the table has no indices, create a single sqlite_stat1 entry
77952 ** containing NULL as the index name and the row count as the content.
77954 if( pTab->pIndex==0 ){
77955 sqlite3VdbeAddOp3(v, OP_OpenRead, iIdxCur, pTab->tnum, iDb);
77956 VdbeComment((v, "%s", pTab->zName));
77957 sqlite3VdbeAddOp2(v, OP_Count, iIdxCur, regSampleno);
77958 sqlite3VdbeAddOp1(v, OP_Close, iIdxCur);
77959 jZeroRows = sqlite3VdbeAddOp1(v, OP_IfNot, regSampleno);
77960 }else{
77961 sqlite3VdbeJumpHere(v, jZeroRows);
77962 jZeroRows = sqlite3VdbeAddOp0(v, OP_Goto);
77964 sqlite3VdbeAddOp2(v, OP_Null, 0, regIdxname);
77965 sqlite3VdbeAddOp4(v, OP_MakeRecord, regTabname, 3, regRec, "aaa", 0);
77966 sqlite3VdbeAddOp2(v, OP_NewRowid, iStatCur, regRowid);
77967 sqlite3VdbeAddOp3(v, OP_Insert, iStatCur, regRec, regRowid);
77968 sqlite3VdbeChangeP5(v, OPFLAG_APPEND);
77969 if( pParse->nMem<regRec ) pParse->nMem = regRec;
77970 sqlite3VdbeJumpHere(v, jZeroRows);
77974 ** Generate code that will cause the most recent index analysis to
77975 ** be loaded into internal hash tables where is can be used.
77977 static void loadAnalysis(Parse *pParse, int iDb){
77978 Vdbe *v = sqlite3GetVdbe(pParse);
77979 if( v ){
77980 sqlite3VdbeAddOp1(v, OP_LoadAnalysis, iDb);
77985 ** Generate code that will do an analysis of an entire database
77987 static void analyzeDatabase(Parse *pParse, int iDb){
77988 sqlite3 *db = pParse->db;
77989 Schema *pSchema = db->aDb[iDb].pSchema; /* Schema of database iDb */
77990 HashElem *k;
77991 int iStatCur;
77992 int iMem;
77994 sqlite3BeginWriteOperation(pParse, 0, iDb);
77995 iStatCur = pParse->nTab;
77996 pParse->nTab += 2;
77997 openStatTable(pParse, iDb, iStatCur, 0, 0);
77998 iMem = pParse->nMem+1;
77999 assert( sqlite3SchemaMutexHeld(db, iDb, 0) );
78000 for(k=sqliteHashFirst(&pSchema->tblHash); k; k=sqliteHashNext(k)){
78001 Table *pTab = (Table*)sqliteHashData(k);
78002 analyzeOneTable(pParse, pTab, 0, iStatCur, iMem);
78004 loadAnalysis(pParse, iDb);
78008 ** Generate code that will do an analysis of a single table in
78009 ** a database. If pOnlyIdx is not NULL then it is a single index
78010 ** in pTab that should be analyzed.
78012 static void analyzeTable(Parse *pParse, Table *pTab, Index *pOnlyIdx){
78013 int iDb;
78014 int iStatCur;
78016 assert( pTab!=0 );
78017 assert( sqlite3BtreeHoldsAllMutexes(pParse->db) );
78018 iDb = sqlite3SchemaToIndex(pParse->db, pTab->pSchema);
78019 sqlite3BeginWriteOperation(pParse, 0, iDb);
78020 iStatCur = pParse->nTab;
78021 pParse->nTab += 2;
78022 if( pOnlyIdx ){
78023 openStatTable(pParse, iDb, iStatCur, pOnlyIdx->zName, "idx");
78024 }else{
78025 openStatTable(pParse, iDb, iStatCur, pTab->zName, "tbl");
78027 analyzeOneTable(pParse, pTab, pOnlyIdx, iStatCur, pParse->nMem+1);
78028 loadAnalysis(pParse, iDb);
78032 ** Generate code for the ANALYZE command. The parser calls this routine
78033 ** when it recognizes an ANALYZE command.
78035 ** ANALYZE -- 1
78036 ** ANALYZE <database> -- 2
78037 ** ANALYZE ?<database>.?<tablename> -- 3
78039 ** Form 1 causes all indices in all attached databases to be analyzed.
78040 ** Form 2 analyzes all indices the single database named.
78041 ** Form 3 analyzes all indices associated with the named table.
78043 SQLITE_PRIVATE void sqlite3Analyze(Parse *pParse, Token *pName1, Token *pName2){
78044 sqlite3 *db = pParse->db;
78045 int iDb;
78046 int i;
78047 char *z, *zDb;
78048 Table *pTab;
78049 Index *pIdx;
78050 Token *pTableName;
78052 /* Read the database schema. If an error occurs, leave an error message
78053 ** and code in pParse and return NULL. */
78054 assert( sqlite3BtreeHoldsAllMutexes(pParse->db) );
78055 if( SQLITE_OK!=sqlite3ReadSchema(pParse) ){
78056 return;
78059 assert( pName2!=0 || pName1==0 );
78060 if( pName1==0 ){
78061 /* Form 1: Analyze everything */
78062 for(i=0; i<db->nDb; i++){
78063 if( i==1 ) continue; /* Do not analyze the TEMP database */
78064 analyzeDatabase(pParse, i);
78066 }else if( pName2->n==0 ){
78067 /* Form 2: Analyze the database or table named */
78068 iDb = sqlite3FindDb(db, pName1);
78069 if( iDb>=0 ){
78070 analyzeDatabase(pParse, iDb);
78071 }else{
78072 z = sqlite3NameFromToken(db, pName1);
78073 if( z ){
78074 if( (pIdx = sqlite3FindIndex(db, z, 0))!=0 ){
78075 analyzeTable(pParse, pIdx->pTable, pIdx);
78076 }else if( (pTab = sqlite3LocateTable(pParse, 0, z, 0))!=0 ){
78077 analyzeTable(pParse, pTab, 0);
78079 sqlite3DbFree(db, z);
78082 }else{
78083 /* Form 3: Analyze the fully qualified table name */
78084 iDb = sqlite3TwoPartName(pParse, pName1, pName2, &pTableName);
78085 if( iDb>=0 ){
78086 zDb = db->aDb[iDb].zName;
78087 z = sqlite3NameFromToken(db, pTableName);
78088 if( z ){
78089 if( (pIdx = sqlite3FindIndex(db, z, zDb))!=0 ){
78090 analyzeTable(pParse, pIdx->pTable, pIdx);
78091 }else if( (pTab = sqlite3LocateTable(pParse, 0, z, zDb))!=0 ){
78092 analyzeTable(pParse, pTab, 0);
78094 sqlite3DbFree(db, z);
78101 ** Used to pass information from the analyzer reader through to the
78102 ** callback routine.
78104 typedef struct analysisInfo analysisInfo;
78105 struct analysisInfo {
78106 sqlite3 *db;
78107 const char *zDatabase;
78111 ** This callback is invoked once for each index when reading the
78112 ** sqlite_stat1 table.
78114 ** argv[0] = name of the table
78115 ** argv[1] = name of the index (might be NULL)
78116 ** argv[2] = results of analysis - on integer for each column
78118 ** Entries for which argv[1]==NULL simply record the number of rows in
78119 ** the table.
78121 static int analysisLoader(void *pData, int argc, char **argv, char **NotUsed){
78122 analysisInfo *pInfo = (analysisInfo*)pData;
78123 Index *pIndex;
78124 Table *pTable;
78125 int i, c, n;
78126 unsigned int v;
78127 const char *z;
78129 assert( argc==3 );
78130 UNUSED_PARAMETER2(NotUsed, argc);
78132 if( argv==0 || argv[0]==0 || argv[2]==0 ){
78133 return 0;
78135 pTable = sqlite3FindTable(pInfo->db, argv[0], pInfo->zDatabase);
78136 if( pTable==0 ){
78137 return 0;
78139 if( argv[1] ){
78140 pIndex = sqlite3FindIndex(pInfo->db, argv[1], pInfo->zDatabase);
78141 }else{
78142 pIndex = 0;
78144 n = pIndex ? pIndex->nColumn : 0;
78145 z = argv[2];
78146 for(i=0; *z && i<=n; i++){
78147 v = 0;
78148 while( (c=z[0])>='0' && c<='9' ){
78149 v = v*10 + c - '0';
78150 z++;
78152 if( i==0 ) pTable->nRowEst = v;
78153 if( pIndex==0 ) break;
78154 pIndex->aiRowEst[i] = v;
78155 if( *z==' ' ) z++;
78156 if( memcmp(z, "unordered", 10)==0 ){
78157 pIndex->bUnordered = 1;
78158 break;
78161 return 0;
78165 ** If the Index.aSample variable is not NULL, delete the aSample[] array
78166 ** and its contents.
78168 SQLITE_PRIVATE void sqlite3DeleteIndexSamples(sqlite3 *db, Index *pIdx){
78169 #ifdef SQLITE_ENABLE_STAT2
78170 if( pIdx->aSample ){
78171 int j;
78172 for(j=0; j<SQLITE_INDEX_SAMPLES; j++){
78173 IndexSample *p = &pIdx->aSample[j];
78174 if( p->eType==SQLITE_TEXT || p->eType==SQLITE_BLOB ){
78175 sqlite3DbFree(db, p->u.z);
78178 sqlite3DbFree(db, pIdx->aSample);
78180 #else
78181 UNUSED_PARAMETER(db);
78182 UNUSED_PARAMETER(pIdx);
78183 #endif
78187 ** Load the content of the sqlite_stat1 and sqlite_stat2 tables. The
78188 ** contents of sqlite_stat1 are used to populate the Index.aiRowEst[]
78189 ** arrays. The contents of sqlite_stat2 are used to populate the
78190 ** Index.aSample[] arrays.
78192 ** If the sqlite_stat1 table is not present in the database, SQLITE_ERROR
78193 ** is returned. In this case, even if SQLITE_ENABLE_STAT2 was defined
78194 ** during compilation and the sqlite_stat2 table is present, no data is
78195 ** read from it.
78197 ** If SQLITE_ENABLE_STAT2 was defined during compilation and the
78198 ** sqlite_stat2 table is not present in the database, SQLITE_ERROR is
78199 ** returned. However, in this case, data is read from the sqlite_stat1
78200 ** table (if it is present) before returning.
78202 ** If an OOM error occurs, this function always sets db->mallocFailed.
78203 ** This means if the caller does not care about other errors, the return
78204 ** code may be ignored.
78206 SQLITE_PRIVATE int sqlite3AnalysisLoad(sqlite3 *db, int iDb){
78207 analysisInfo sInfo;
78208 HashElem *i;
78209 char *zSql;
78210 int rc;
78212 assert( iDb>=0 && iDb<db->nDb );
78213 assert( db->aDb[iDb].pBt!=0 );
78215 /* Clear any prior statistics */
78216 assert( sqlite3SchemaMutexHeld(db, iDb, 0) );
78217 for(i=sqliteHashFirst(&db->aDb[iDb].pSchema->idxHash);i;i=sqliteHashNext(i)){
78218 Index *pIdx = sqliteHashData(i);
78219 sqlite3DefaultRowEst(pIdx);
78220 sqlite3DeleteIndexSamples(db, pIdx);
78221 pIdx->aSample = 0;
78224 /* Check to make sure the sqlite_stat1 table exists */
78225 sInfo.db = db;
78226 sInfo.zDatabase = db->aDb[iDb].zName;
78227 if( sqlite3FindTable(db, "sqlite_stat1", sInfo.zDatabase)==0 ){
78228 return SQLITE_ERROR;
78231 /* Load new statistics out of the sqlite_stat1 table */
78232 zSql = sqlite3MPrintf(db,
78233 "SELECT tbl, idx, stat FROM %Q.sqlite_stat1", sInfo.zDatabase);
78234 if( zSql==0 ){
78235 rc = SQLITE_NOMEM;
78236 }else{
78237 rc = sqlite3_exec(db, zSql, analysisLoader, &sInfo, 0);
78238 sqlite3DbFree(db, zSql);
78242 /* Load the statistics from the sqlite_stat2 table. */
78243 #ifdef SQLITE_ENABLE_STAT2
78244 if( rc==SQLITE_OK && !sqlite3FindTable(db, "sqlite_stat2", sInfo.zDatabase) ){
78245 rc = SQLITE_ERROR;
78247 if( rc==SQLITE_OK ){
78248 sqlite3_stmt *pStmt = 0;
78250 zSql = sqlite3MPrintf(db,
78251 "SELECT idx,sampleno,sample FROM %Q.sqlite_stat2", sInfo.zDatabase);
78252 if( !zSql ){
78253 rc = SQLITE_NOMEM;
78254 }else{
78255 rc = sqlite3_prepare(db, zSql, -1, &pStmt, 0);
78256 sqlite3DbFree(db, zSql);
78259 if( rc==SQLITE_OK ){
78260 while( sqlite3_step(pStmt)==SQLITE_ROW ){
78261 char *zIndex; /* Index name */
78262 Index *pIdx; /* Pointer to the index object */
78264 zIndex = (char *)sqlite3_column_text(pStmt, 0);
78265 pIdx = zIndex ? sqlite3FindIndex(db, zIndex, sInfo.zDatabase) : 0;
78266 if( pIdx ){
78267 int iSample = sqlite3_column_int(pStmt, 1);
78268 if( iSample<SQLITE_INDEX_SAMPLES && iSample>=0 ){
78269 int eType = sqlite3_column_type(pStmt, 2);
78271 if( pIdx->aSample==0 ){
78272 static const int sz = sizeof(IndexSample)*SQLITE_INDEX_SAMPLES;
78273 pIdx->aSample = (IndexSample *)sqlite3DbMallocRaw(0, sz);
78274 if( pIdx->aSample==0 ){
78275 db->mallocFailed = 1;
78276 break;
78278 memset(pIdx->aSample, 0, sz);
78281 assert( pIdx->aSample );
78283 IndexSample *pSample = &pIdx->aSample[iSample];
78284 pSample->eType = (u8)eType;
78285 if( eType==SQLITE_INTEGER || eType==SQLITE_FLOAT ){
78286 pSample->u.r = sqlite3_column_double(pStmt, 2);
78287 }else if( eType==SQLITE_TEXT || eType==SQLITE_BLOB ){
78288 const char *z = (const char *)(
78289 (eType==SQLITE_BLOB) ?
78290 sqlite3_column_blob(pStmt, 2):
78291 sqlite3_column_text(pStmt, 2)
78293 int n = sqlite3_column_bytes(pStmt, 2);
78294 if( n>24 ){
78295 n = 24;
78297 pSample->nByte = (u8)n;
78298 if( n < 1){
78299 pSample->u.z = 0;
78300 }else{
78301 pSample->u.z = sqlite3DbStrNDup(0, z, n);
78302 if( pSample->u.z==0 ){
78303 db->mallocFailed = 1;
78304 break;
78312 rc = sqlite3_finalize(pStmt);
78315 #endif
78317 if( rc==SQLITE_NOMEM ){
78318 db->mallocFailed = 1;
78320 return rc;
78324 #endif /* SQLITE_OMIT_ANALYZE */
78326 /************** End of analyze.c *********************************************/
78327 /************** Begin file attach.c ******************************************/
78329 ** 2003 April 6
78331 ** The author disclaims copyright to this source code. In place of
78332 ** a legal notice, here is a blessing:
78334 ** May you do good and not evil.
78335 ** May you find forgiveness for yourself and forgive others.
78336 ** May you share freely, never taking more than you give.
78338 *************************************************************************
78339 ** This file contains code used to implement the ATTACH and DETACH commands.
78342 #ifndef SQLITE_OMIT_ATTACH
78344 ** Resolve an expression that was part of an ATTACH or DETACH statement. This
78345 ** is slightly different from resolving a normal SQL expression, because simple
78346 ** identifiers are treated as strings, not possible column names or aliases.
78348 ** i.e. if the parser sees:
78350 ** ATTACH DATABASE abc AS def
78352 ** it treats the two expressions as literal strings 'abc' and 'def' instead of
78353 ** looking for columns of the same name.
78355 ** This only applies to the root node of pExpr, so the statement:
78357 ** ATTACH DATABASE abc||def AS 'db2'
78359 ** will fail because neither abc or def can be resolved.
78361 static int resolveAttachExpr(NameContext *pName, Expr *pExpr)
78363 int rc = SQLITE_OK;
78364 if( pExpr ){
78365 if( pExpr->op!=TK_ID ){
78366 rc = sqlite3ResolveExprNames(pName, pExpr);
78367 if( rc==SQLITE_OK && !sqlite3ExprIsConstant(pExpr) ){
78368 sqlite3ErrorMsg(pName->pParse, "invalid name: \"%s\"", pExpr->u.zToken);
78369 return SQLITE_ERROR;
78371 }else{
78372 pExpr->op = TK_STRING;
78375 return rc;
78379 ** An SQL user-function registered to do the work of an ATTACH statement. The
78380 ** three arguments to the function come directly from an attach statement:
78382 ** ATTACH DATABASE x AS y KEY z
78384 ** SELECT sqlite_attach(x, y, z)
78386 ** If the optional "KEY z" syntax is omitted, an SQL NULL is passed as the
78387 ** third argument.
78389 static void attachFunc(
78390 sqlite3_context *context,
78391 int NotUsed,
78392 sqlite3_value **argv
78394 int i;
78395 int rc = 0;
78396 sqlite3 *db = sqlite3_context_db_handle(context);
78397 const char *zName;
78398 const char *zFile;
78399 char *zPath = 0;
78400 char *zErr = 0;
78401 unsigned int flags;
78402 Db *aNew;
78403 char *zErrDyn = 0;
78404 sqlite3_vfs *pVfs;
78406 UNUSED_PARAMETER(NotUsed);
78408 zFile = (const char *)sqlite3_value_text(argv[0]);
78409 zName = (const char *)sqlite3_value_text(argv[1]);
78410 if( zFile==0 ) zFile = "";
78411 if( zName==0 ) zName = "";
78413 /* Check for the following errors:
78415 ** * Too many attached databases,
78416 ** * Transaction currently open
78417 ** * Specified database name already being used.
78419 if( db->nDb>=db->aLimit[SQLITE_LIMIT_ATTACHED]+2 ){
78420 zErrDyn = sqlite3MPrintf(db, "too many attached databases - max %d",
78421 db->aLimit[SQLITE_LIMIT_ATTACHED]
78423 goto attach_error;
78425 if( !db->autoCommit ){
78426 zErrDyn = sqlite3MPrintf(db, "cannot ATTACH database within transaction");
78427 goto attach_error;
78429 for(i=0; i<db->nDb; i++){
78430 char *z = db->aDb[i].zName;
78431 assert( z && zName );
78432 if( sqlite3StrICmp(z, zName)==0 ){
78433 zErrDyn = sqlite3MPrintf(db, "database %s is already in use", zName);
78434 goto attach_error;
78438 /* Allocate the new entry in the db->aDb[] array and initialise the schema
78439 ** hash tables.
78441 if( db->aDb==db->aDbStatic ){
78442 aNew = sqlite3DbMallocRaw(db, sizeof(db->aDb[0])*3 );
78443 if( aNew==0 ) return;
78444 memcpy(aNew, db->aDb, sizeof(db->aDb[0])*2);
78445 }else{
78446 aNew = sqlite3DbRealloc(db, db->aDb, sizeof(db->aDb[0])*(db->nDb+1) );
78447 if( aNew==0 ) return;
78449 db->aDb = aNew;
78450 aNew = &db->aDb[db->nDb];
78451 memset(aNew, 0, sizeof(*aNew));
78453 /* Open the database file. If the btree is successfully opened, use
78454 ** it to obtain the database schema. At this point the schema may
78455 ** or may not be initialised.
78457 flags = db->openFlags;
78458 rc = sqlite3ParseUri(db->pVfs->zName, zFile, &flags, &pVfs, &zPath, &zErr);
78459 if( rc!=SQLITE_OK ){
78460 if( rc==SQLITE_NOMEM ) db->mallocFailed = 1;
78461 sqlite3_result_error(context, zErr, -1);
78462 sqlite3_free(zErr);
78463 return;
78465 assert( pVfs );
78466 flags |= SQLITE_OPEN_MAIN_DB;
78467 rc = sqlite3BtreeOpen(pVfs, zPath, db, &aNew->pBt, 0, flags);
78468 sqlite3_free( zPath );
78469 db->nDb++;
78470 if( rc==SQLITE_CONSTRAINT ){
78471 rc = SQLITE_ERROR;
78472 zErrDyn = sqlite3MPrintf(db, "database is already attached");
78473 }else if( rc==SQLITE_OK ){
78474 Pager *pPager;
78475 aNew->pSchema = sqlite3SchemaGet(db, aNew->pBt);
78476 if( !aNew->pSchema ){
78477 rc = SQLITE_NOMEM;
78478 }else if( aNew->pSchema->file_format && aNew->pSchema->enc!=ENC(db) ){
78479 zErrDyn = sqlite3MPrintf(db,
78480 "attached databases must use the same text encoding as main database");
78481 rc = SQLITE_ERROR;
78483 pPager = sqlite3BtreePager(aNew->pBt);
78484 sqlite3PagerLockingMode(pPager, db->dfltLockMode);
78485 sqlite3BtreeSecureDelete(aNew->pBt,
78486 sqlite3BtreeSecureDelete(db->aDb[0].pBt,-1) );
78488 aNew->safety_level = 3;
78489 aNew->zName = sqlite3DbStrDup(db, zName);
78490 if( rc==SQLITE_OK && aNew->zName==0 ){
78491 rc = SQLITE_NOMEM;
78495 #ifdef SQLITE_HAS_CODEC
78496 if( rc==SQLITE_OK ){
78497 extern int sqlite3CodecAttach(sqlite3*, int, const void*, int);
78498 extern void sqlite3CodecGetKey(sqlite3*, int, void**, int*);
78499 int nKey;
78500 char *zKey;
78501 int t = sqlite3_value_type(argv[2]);
78502 switch( t ){
78503 case SQLITE_INTEGER:
78504 case SQLITE_FLOAT:
78505 zErrDyn = sqlite3DbStrDup(db, "Invalid key value");
78506 rc = SQLITE_ERROR;
78507 break;
78509 case SQLITE_TEXT:
78510 case SQLITE_BLOB:
78511 nKey = sqlite3_value_bytes(argv[2]);
78512 zKey = (char *)sqlite3_value_blob(argv[2]);
78513 rc = sqlite3CodecAttach(db, db->nDb-1, zKey, nKey);
78514 break;
78516 case SQLITE_NULL:
78517 /* No key specified. Use the key from the main database */
78518 sqlite3CodecGetKey(db, 0, (void**)&zKey, &nKey);
78519 if( nKey>0 || sqlite3BtreeGetReserve(db->aDb[0].pBt)>0 ){
78520 rc = sqlite3CodecAttach(db, db->nDb-1, zKey, nKey);
78522 break;
78525 #endif
78527 /* If the file was opened successfully, read the schema for the new database.
78528 ** If this fails, or if opening the file failed, then close the file and
78529 ** remove the entry from the db->aDb[] array. i.e. put everything back the way
78530 ** we found it.
78532 if( rc==SQLITE_OK ){
78533 sqlite3BtreeEnterAll(db);
78534 rc = sqlite3Init(db, &zErrDyn);
78535 sqlite3BtreeLeaveAll(db);
78537 if( rc ){
78538 int iDb = db->nDb - 1;
78539 assert( iDb>=2 );
78540 if( db->aDb[iDb].pBt ){
78541 sqlite3BtreeClose(db->aDb[iDb].pBt);
78542 db->aDb[iDb].pBt = 0;
78543 db->aDb[iDb].pSchema = 0;
78545 sqlite3ResetInternalSchema(db, -1);
78546 db->nDb = iDb;
78547 if( rc==SQLITE_NOMEM || rc==SQLITE_IOERR_NOMEM ){
78548 db->mallocFailed = 1;
78549 sqlite3DbFree(db, zErrDyn);
78550 zErrDyn = sqlite3MPrintf(db, "out of memory");
78551 }else if( zErrDyn==0 ){
78552 zErrDyn = sqlite3MPrintf(db, "unable to open database: %s", zFile);
78554 goto attach_error;
78557 return;
78559 attach_error:
78560 /* Return an error if we get here */
78561 if( zErrDyn ){
78562 sqlite3_result_error(context, zErrDyn, -1);
78563 sqlite3DbFree(db, zErrDyn);
78565 if( rc ) sqlite3_result_error_code(context, rc);
78569 ** An SQL user-function registered to do the work of an DETACH statement. The
78570 ** three arguments to the function come directly from a detach statement:
78572 ** DETACH DATABASE x
78574 ** SELECT sqlite_detach(x)
78576 static void detachFunc(
78577 sqlite3_context *context,
78578 int NotUsed,
78579 sqlite3_value **argv
78581 const char *zName = (const char *)sqlite3_value_text(argv[0]);
78582 sqlite3 *db = sqlite3_context_db_handle(context);
78583 int i;
78584 Db *pDb = 0;
78585 char zErr[128];
78587 UNUSED_PARAMETER(NotUsed);
78589 if( zName==0 ) zName = "";
78590 for(i=0; i<db->nDb; i++){
78591 pDb = &db->aDb[i];
78592 if( pDb->pBt==0 ) continue;
78593 if( sqlite3StrICmp(pDb->zName, zName)==0 ) break;
78596 if( i>=db->nDb ){
78597 sqlite3_snprintf(sizeof(zErr),zErr, "no such database: %s", zName);
78598 goto detach_error;
78600 if( i<2 ){
78601 sqlite3_snprintf(sizeof(zErr),zErr, "cannot detach database %s", zName);
78602 goto detach_error;
78604 if( !db->autoCommit ){
78605 sqlite3_snprintf(sizeof(zErr), zErr,
78606 "cannot DETACH database within transaction");
78607 goto detach_error;
78609 if( sqlite3BtreeIsInReadTrans(pDb->pBt) || sqlite3BtreeIsInBackup(pDb->pBt) ){
78610 sqlite3_snprintf(sizeof(zErr),zErr, "database %s is locked", zName);
78611 goto detach_error;
78614 sqlite3BtreeClose(pDb->pBt);
78615 pDb->pBt = 0;
78616 pDb->pSchema = 0;
78617 sqlite3ResetInternalSchema(db, -1);
78618 return;
78620 detach_error:
78621 sqlite3_result_error(context, zErr, -1);
78625 ** This procedure generates VDBE code for a single invocation of either the
78626 ** sqlite_detach() or sqlite_attach() SQL user functions.
78628 static void codeAttach(
78629 Parse *pParse, /* The parser context */
78630 int type, /* Either SQLITE_ATTACH or SQLITE_DETACH */
78631 FuncDef const *pFunc,/* FuncDef wrapper for detachFunc() or attachFunc() */
78632 Expr *pAuthArg, /* Expression to pass to authorization callback */
78633 Expr *pFilename, /* Name of database file */
78634 Expr *pDbname, /* Name of the database to use internally */
78635 Expr *pKey /* Database key for encryption extension */
78637 int rc;
78638 NameContext sName;
78639 Vdbe *v;
78640 sqlite3* db = pParse->db;
78641 int regArgs;
78643 memset(&sName, 0, sizeof(NameContext));
78644 sName.pParse = pParse;
78646 if(
78647 SQLITE_OK!=(rc = resolveAttachExpr(&sName, pFilename)) ||
78648 SQLITE_OK!=(rc = resolveAttachExpr(&sName, pDbname)) ||
78649 SQLITE_OK!=(rc = resolveAttachExpr(&sName, pKey))
78651 pParse->nErr++;
78652 goto attach_end;
78655 #ifndef SQLITE_OMIT_AUTHORIZATION
78656 if( pAuthArg ){
78657 char *zAuthArg;
78658 if( pAuthArg->op==TK_STRING ){
78659 zAuthArg = pAuthArg->u.zToken;
78660 }else{
78661 zAuthArg = 0;
78663 rc = sqlite3AuthCheck(pParse, type, zAuthArg, 0, 0);
78664 if(rc!=SQLITE_OK ){
78665 goto attach_end;
78668 #endif /* SQLITE_OMIT_AUTHORIZATION */
78671 v = sqlite3GetVdbe(pParse);
78672 regArgs = sqlite3GetTempRange(pParse, 4);
78673 sqlite3ExprCode(pParse, pFilename, regArgs);
78674 sqlite3ExprCode(pParse, pDbname, regArgs+1);
78675 sqlite3ExprCode(pParse, pKey, regArgs+2);
78677 assert( v || db->mallocFailed );
78678 if( v ){
78679 sqlite3VdbeAddOp3(v, OP_Function, 0, regArgs+3-pFunc->nArg, regArgs+3);
78680 assert( pFunc->nArg==-1 || (pFunc->nArg&0xff)==pFunc->nArg );
78681 sqlite3VdbeChangeP5(v, (u8)(pFunc->nArg));
78682 sqlite3VdbeChangeP4(v, -1, (char *)pFunc, P4_FUNCDEF);
78684 /* Code an OP_Expire. For an ATTACH statement, set P1 to true (expire this
78685 ** statement only). For DETACH, set it to false (expire all existing
78686 ** statements).
78688 sqlite3VdbeAddOp1(v, OP_Expire, (type==SQLITE_ATTACH));
78691 attach_end:
78692 sqlite3ExprDelete(db, pFilename);
78693 sqlite3ExprDelete(db, pDbname);
78694 sqlite3ExprDelete(db, pKey);
78698 ** Called by the parser to compile a DETACH statement.
78700 ** DETACH pDbname
78702 SQLITE_PRIVATE void sqlite3Detach(Parse *pParse, Expr *pDbname){
78703 static const FuncDef detach_func = {
78704 1, /* nArg */
78705 SQLITE_UTF8, /* iPrefEnc */
78706 0, /* flags */
78707 0, /* pUserData */
78708 0, /* pNext */
78709 detachFunc, /* xFunc */
78710 0, /* xStep */
78711 0, /* xFinalize */
78712 "sqlite_detach", /* zName */
78713 0, /* pHash */
78714 0 /* pDestructor */
78716 codeAttach(pParse, SQLITE_DETACH, &detach_func, pDbname, 0, 0, pDbname);
78720 ** Called by the parser to compile an ATTACH statement.
78722 ** ATTACH p AS pDbname KEY pKey
78724 SQLITE_PRIVATE void sqlite3Attach(Parse *pParse, Expr *p, Expr *pDbname, Expr *pKey){
78725 static const FuncDef attach_func = {
78726 3, /* nArg */
78727 SQLITE_UTF8, /* iPrefEnc */
78728 0, /* flags */
78729 0, /* pUserData */
78730 0, /* pNext */
78731 attachFunc, /* xFunc */
78732 0, /* xStep */
78733 0, /* xFinalize */
78734 "sqlite_attach", /* zName */
78735 0, /* pHash */
78736 0 /* pDestructor */
78738 codeAttach(pParse, SQLITE_ATTACH, &attach_func, p, p, pDbname, pKey);
78740 #endif /* SQLITE_OMIT_ATTACH */
78743 ** Initialize a DbFixer structure. This routine must be called prior
78744 ** to passing the structure to one of the sqliteFixAAAA() routines below.
78746 ** The return value indicates whether or not fixation is required. TRUE
78747 ** means we do need to fix the database references, FALSE means we do not.
78749 SQLITE_PRIVATE int sqlite3FixInit(
78750 DbFixer *pFix, /* The fixer to be initialized */
78751 Parse *pParse, /* Error messages will be written here */
78752 int iDb, /* This is the database that must be used */
78753 const char *zType, /* "view", "trigger", or "index" */
78754 const Token *pName /* Name of the view, trigger, or index */
78756 sqlite3 *db;
78758 if( NEVER(iDb<0) || iDb==1 ) return 0;
78759 db = pParse->db;
78760 assert( db->nDb>iDb );
78761 pFix->pParse = pParse;
78762 pFix->zDb = db->aDb[iDb].zName;
78763 pFix->zType = zType;
78764 pFix->pName = pName;
78765 return 1;
78769 ** The following set of routines walk through the parse tree and assign
78770 ** a specific database to all table references where the database name
78771 ** was left unspecified in the original SQL statement. The pFix structure
78772 ** must have been initialized by a prior call to sqlite3FixInit().
78774 ** These routines are used to make sure that an index, trigger, or
78775 ** view in one database does not refer to objects in a different database.
78776 ** (Exception: indices, triggers, and views in the TEMP database are
78777 ** allowed to refer to anything.) If a reference is explicitly made
78778 ** to an object in a different database, an error message is added to
78779 ** pParse->zErrMsg and these routines return non-zero. If everything
78780 ** checks out, these routines return 0.
78782 SQLITE_PRIVATE int sqlite3FixSrcList(
78783 DbFixer *pFix, /* Context of the fixation */
78784 SrcList *pList /* The Source list to check and modify */
78786 int i;
78787 const char *zDb;
78788 struct SrcList_item *pItem;
78790 if( NEVER(pList==0) ) return 0;
78791 zDb = pFix->zDb;
78792 for(i=0, pItem=pList->a; i<pList->nSrc; i++, pItem++){
78793 if( pItem->zDatabase==0 ){
78794 pItem->zDatabase = sqlite3DbStrDup(pFix->pParse->db, zDb);
78795 }else if( sqlite3StrICmp(pItem->zDatabase,zDb)!=0 ){
78796 sqlite3ErrorMsg(pFix->pParse,
78797 "%s %T cannot reference objects in database %s",
78798 pFix->zType, pFix->pName, pItem->zDatabase);
78799 return 1;
78801 #if !defined(SQLITE_OMIT_VIEW) || !defined(SQLITE_OMIT_TRIGGER)
78802 if( sqlite3FixSelect(pFix, pItem->pSelect) ) return 1;
78803 if( sqlite3FixExpr(pFix, pItem->pOn) ) return 1;
78804 #endif
78806 return 0;
78808 #if !defined(SQLITE_OMIT_VIEW) || !defined(SQLITE_OMIT_TRIGGER)
78809 SQLITE_PRIVATE int sqlite3FixSelect(
78810 DbFixer *pFix, /* Context of the fixation */
78811 Select *pSelect /* The SELECT statement to be fixed to one database */
78813 while( pSelect ){
78814 if( sqlite3FixExprList(pFix, pSelect->pEList) ){
78815 return 1;
78817 if( sqlite3FixSrcList(pFix, pSelect->pSrc) ){
78818 return 1;
78820 if( sqlite3FixExpr(pFix, pSelect->pWhere) ){
78821 return 1;
78823 if( sqlite3FixExpr(pFix, pSelect->pHaving) ){
78824 return 1;
78826 pSelect = pSelect->pPrior;
78828 return 0;
78830 SQLITE_PRIVATE int sqlite3FixExpr(
78831 DbFixer *pFix, /* Context of the fixation */
78832 Expr *pExpr /* The expression to be fixed to one database */
78834 while( pExpr ){
78835 if( ExprHasAnyProperty(pExpr, EP_TokenOnly) ) break;
78836 if( ExprHasProperty(pExpr, EP_xIsSelect) ){
78837 if( sqlite3FixSelect(pFix, pExpr->x.pSelect) ) return 1;
78838 }else{
78839 if( sqlite3FixExprList(pFix, pExpr->x.pList) ) return 1;
78841 if( sqlite3FixExpr(pFix, pExpr->pRight) ){
78842 return 1;
78844 pExpr = pExpr->pLeft;
78846 return 0;
78848 SQLITE_PRIVATE int sqlite3FixExprList(
78849 DbFixer *pFix, /* Context of the fixation */
78850 ExprList *pList /* The expression to be fixed to one database */
78852 int i;
78853 struct ExprList_item *pItem;
78854 if( pList==0 ) return 0;
78855 for(i=0, pItem=pList->a; i<pList->nExpr; i++, pItem++){
78856 if( sqlite3FixExpr(pFix, pItem->pExpr) ){
78857 return 1;
78860 return 0;
78862 #endif
78864 #ifndef SQLITE_OMIT_TRIGGER
78865 SQLITE_PRIVATE int sqlite3FixTriggerStep(
78866 DbFixer *pFix, /* Context of the fixation */
78867 TriggerStep *pStep /* The trigger step be fixed to one database */
78869 while( pStep ){
78870 if( sqlite3FixSelect(pFix, pStep->pSelect) ){
78871 return 1;
78873 if( sqlite3FixExpr(pFix, pStep->pWhere) ){
78874 return 1;
78876 if( sqlite3FixExprList(pFix, pStep->pExprList) ){
78877 return 1;
78879 pStep = pStep->pNext;
78881 return 0;
78883 #endif
78885 /************** End of attach.c **********************************************/
78886 /************** Begin file auth.c ********************************************/
78888 ** 2003 January 11
78890 ** The author disclaims copyright to this source code. In place of
78891 ** a legal notice, here is a blessing:
78893 ** May you do good and not evil.
78894 ** May you find forgiveness for yourself and forgive others.
78895 ** May you share freely, never taking more than you give.
78897 *************************************************************************
78898 ** This file contains code used to implement the sqlite3_set_authorizer()
78899 ** API. This facility is an optional feature of the library. Embedded
78900 ** systems that do not need this facility may omit it by recompiling
78901 ** the library with -DSQLITE_OMIT_AUTHORIZATION=1
78905 ** All of the code in this file may be omitted by defining a single
78906 ** macro.
78908 #ifndef SQLITE_OMIT_AUTHORIZATION
78911 ** Set or clear the access authorization function.
78913 ** The access authorization function is be called during the compilation
78914 ** phase to verify that the user has read and/or write access permission on
78915 ** various fields of the database. The first argument to the auth function
78916 ** is a copy of the 3rd argument to this routine. The second argument
78917 ** to the auth function is one of these constants:
78919 ** SQLITE_CREATE_INDEX
78920 ** SQLITE_CREATE_TABLE
78921 ** SQLITE_CREATE_TEMP_INDEX
78922 ** SQLITE_CREATE_TEMP_TABLE
78923 ** SQLITE_CREATE_TEMP_TRIGGER
78924 ** SQLITE_CREATE_TEMP_VIEW
78925 ** SQLITE_CREATE_TRIGGER
78926 ** SQLITE_CREATE_VIEW
78927 ** SQLITE_DELETE
78928 ** SQLITE_DROP_INDEX
78929 ** SQLITE_DROP_TABLE
78930 ** SQLITE_DROP_TEMP_INDEX
78931 ** SQLITE_DROP_TEMP_TABLE
78932 ** SQLITE_DROP_TEMP_TRIGGER
78933 ** SQLITE_DROP_TEMP_VIEW
78934 ** SQLITE_DROP_TRIGGER
78935 ** SQLITE_DROP_VIEW
78936 ** SQLITE_INSERT
78937 ** SQLITE_PRAGMA
78938 ** SQLITE_READ
78939 ** SQLITE_SELECT
78940 ** SQLITE_TRANSACTION
78941 ** SQLITE_UPDATE
78943 ** The third and fourth arguments to the auth function are the name of
78944 ** the table and the column that are being accessed. The auth function
78945 ** should return either SQLITE_OK, SQLITE_DENY, or SQLITE_IGNORE. If
78946 ** SQLITE_OK is returned, it means that access is allowed. SQLITE_DENY
78947 ** means that the SQL statement will never-run - the sqlite3_exec() call
78948 ** will return with an error. SQLITE_IGNORE means that the SQL statement
78949 ** should run but attempts to read the specified column will return NULL
78950 ** and attempts to write the column will be ignored.
78952 ** Setting the auth function to NULL disables this hook. The default
78953 ** setting of the auth function is NULL.
78955 SQLITE_API int sqlite3_set_authorizer(
78956 sqlite3 *db,
78957 int (*xAuth)(void*,int,const char*,const char*,const char*,const char*),
78958 void *pArg
78960 sqlite3_mutex_enter(db->mutex);
78961 db->xAuth = xAuth;
78962 db->pAuthArg = pArg;
78963 sqlite3ExpirePreparedStatements(db);
78964 sqlite3_mutex_leave(db->mutex);
78965 return SQLITE_OK;
78969 ** Write an error message into pParse->zErrMsg that explains that the
78970 ** user-supplied authorization function returned an illegal value.
78972 static void sqliteAuthBadReturnCode(Parse *pParse){
78973 sqlite3ErrorMsg(pParse, "authorizer malfunction");
78974 pParse->rc = SQLITE_ERROR;
78978 ** Invoke the authorization callback for permission to read column zCol from
78979 ** table zTab in database zDb. This function assumes that an authorization
78980 ** callback has been registered (i.e. that sqlite3.xAuth is not NULL).
78982 ** If SQLITE_IGNORE is returned and pExpr is not NULL, then pExpr is changed
78983 ** to an SQL NULL expression. Otherwise, if pExpr is NULL, then SQLITE_IGNORE
78984 ** is treated as SQLITE_DENY. In this case an error is left in pParse.
78986 SQLITE_PRIVATE int sqlite3AuthReadCol(
78987 Parse *pParse, /* The parser context */
78988 const char *zTab, /* Table name */
78989 const char *zCol, /* Column name */
78990 int iDb /* Index of containing database. */
78992 sqlite3 *db = pParse->db; /* Database handle */
78993 char *zDb = db->aDb[iDb].zName; /* Name of attached database */
78994 int rc; /* Auth callback return code */
78996 rc = db->xAuth(db->pAuthArg, SQLITE_READ, zTab,zCol,zDb,pParse->zAuthContext);
78997 if( rc==SQLITE_DENY ){
78998 if( db->nDb>2 || iDb!=0 ){
78999 sqlite3ErrorMsg(pParse, "access to %s.%s.%s is prohibited",zDb,zTab,zCol);
79000 }else{
79001 sqlite3ErrorMsg(pParse, "access to %s.%s is prohibited", zTab, zCol);
79003 pParse->rc = SQLITE_AUTH;
79004 }else if( rc!=SQLITE_IGNORE && rc!=SQLITE_OK ){
79005 sqliteAuthBadReturnCode(pParse);
79007 return rc;
79011 ** The pExpr should be a TK_COLUMN expression. The table referred to
79012 ** is in pTabList or else it is the NEW or OLD table of a trigger.
79013 ** Check to see if it is OK to read this particular column.
79015 ** If the auth function returns SQLITE_IGNORE, change the TK_COLUMN
79016 ** instruction into a TK_NULL. If the auth function returns SQLITE_DENY,
79017 ** then generate an error.
79019 SQLITE_PRIVATE void sqlite3AuthRead(
79020 Parse *pParse, /* The parser context */
79021 Expr *pExpr, /* The expression to check authorization on */
79022 Schema *pSchema, /* The schema of the expression */
79023 SrcList *pTabList /* All table that pExpr might refer to */
79025 sqlite3 *db = pParse->db;
79026 Table *pTab = 0; /* The table being read */
79027 const char *zCol; /* Name of the column of the table */
79028 int iSrc; /* Index in pTabList->a[] of table being read */
79029 int iDb; /* The index of the database the expression refers to */
79030 int iCol; /* Index of column in table */
79032 if( db->xAuth==0 ) return;
79033 iDb = sqlite3SchemaToIndex(pParse->db, pSchema);
79034 if( iDb<0 ){
79035 /* An attempt to read a column out of a subquery or other
79036 ** temporary table. */
79037 return;
79040 assert( pExpr->op==TK_COLUMN || pExpr->op==TK_TRIGGER );
79041 if( pExpr->op==TK_TRIGGER ){
79042 pTab = pParse->pTriggerTab;
79043 }else{
79044 assert( pTabList );
79045 for(iSrc=0; ALWAYS(iSrc<pTabList->nSrc); iSrc++){
79046 if( pExpr->iTable==pTabList->a[iSrc].iCursor ){
79047 pTab = pTabList->a[iSrc].pTab;
79048 break;
79052 iCol = pExpr->iColumn;
79053 if( NEVER(pTab==0) ) return;
79055 if( iCol>=0 ){
79056 assert( iCol<pTab->nCol );
79057 zCol = pTab->aCol[iCol].zName;
79058 }else if( pTab->iPKey>=0 ){
79059 assert( pTab->iPKey<pTab->nCol );
79060 zCol = pTab->aCol[pTab->iPKey].zName;
79061 }else{
79062 zCol = "ROWID";
79064 assert( iDb>=0 && iDb<db->nDb );
79065 if( SQLITE_IGNORE==sqlite3AuthReadCol(pParse, pTab->zName, zCol, iDb) ){
79066 pExpr->op = TK_NULL;
79071 ** Do an authorization check using the code and arguments given. Return
79072 ** either SQLITE_OK (zero) or SQLITE_IGNORE or SQLITE_DENY. If SQLITE_DENY
79073 ** is returned, then the error count and error message in pParse are
79074 ** modified appropriately.
79076 SQLITE_PRIVATE int sqlite3AuthCheck(
79077 Parse *pParse,
79078 int code,
79079 const char *zArg1,
79080 const char *zArg2,
79081 const char *zArg3
79083 sqlite3 *db = pParse->db;
79084 int rc;
79086 /* Don't do any authorization checks if the database is initialising
79087 ** or if the parser is being invoked from within sqlite3_declare_vtab.
79089 if( db->init.busy || IN_DECLARE_VTAB ){
79090 return SQLITE_OK;
79093 if( db->xAuth==0 ){
79094 return SQLITE_OK;
79096 rc = db->xAuth(db->pAuthArg, code, zArg1, zArg2, zArg3, pParse->zAuthContext);
79097 if( rc==SQLITE_DENY ){
79098 sqlite3ErrorMsg(pParse, "not authorized");
79099 pParse->rc = SQLITE_AUTH;
79100 }else if( rc!=SQLITE_OK && rc!=SQLITE_IGNORE ){
79101 rc = SQLITE_DENY;
79102 sqliteAuthBadReturnCode(pParse);
79104 return rc;
79108 ** Push an authorization context. After this routine is called, the
79109 ** zArg3 argument to authorization callbacks will be zContext until
79110 ** popped. Or if pParse==0, this routine is a no-op.
79112 SQLITE_PRIVATE void sqlite3AuthContextPush(
79113 Parse *pParse,
79114 AuthContext *pContext,
79115 const char *zContext
79117 assert( pParse );
79118 pContext->pParse = pParse;
79119 pContext->zAuthContext = pParse->zAuthContext;
79120 pParse->zAuthContext = zContext;
79124 ** Pop an authorization context that was previously pushed
79125 ** by sqlite3AuthContextPush
79127 SQLITE_PRIVATE void sqlite3AuthContextPop(AuthContext *pContext){
79128 if( pContext->pParse ){
79129 pContext->pParse->zAuthContext = pContext->zAuthContext;
79130 pContext->pParse = 0;
79134 #endif /* SQLITE_OMIT_AUTHORIZATION */
79136 /************** End of auth.c ************************************************/
79137 /************** Begin file build.c *******************************************/
79139 ** 2001 September 15
79141 ** The author disclaims copyright to this source code. In place of
79142 ** a legal notice, here is a blessing:
79144 ** May you do good and not evil.
79145 ** May you find forgiveness for yourself and forgive others.
79146 ** May you share freely, never taking more than you give.
79148 *************************************************************************
79149 ** This file contains C code routines that are called by the SQLite parser
79150 ** when syntax rules are reduced. The routines in this file handle the
79151 ** following kinds of SQL syntax:
79153 ** CREATE TABLE
79154 ** DROP TABLE
79155 ** CREATE INDEX
79156 ** DROP INDEX
79157 ** creating ID lists
79158 ** BEGIN TRANSACTION
79159 ** COMMIT
79160 ** ROLLBACK
79164 ** This routine is called when a new SQL statement is beginning to
79165 ** be parsed. Initialize the pParse structure as needed.
79167 SQLITE_PRIVATE void sqlite3BeginParse(Parse *pParse, int explainFlag){
79168 pParse->explain = (u8)explainFlag;
79169 pParse->nVar = 0;
79172 #ifndef SQLITE_OMIT_SHARED_CACHE
79174 ** The TableLock structure is only used by the sqlite3TableLock() and
79175 ** codeTableLocks() functions.
79177 struct TableLock {
79178 int iDb; /* The database containing the table to be locked */
79179 int iTab; /* The root page of the table to be locked */
79180 u8 isWriteLock; /* True for write lock. False for a read lock */
79181 const char *zName; /* Name of the table */
79185 ** Record the fact that we want to lock a table at run-time.
79187 ** The table to be locked has root page iTab and is found in database iDb.
79188 ** A read or a write lock can be taken depending on isWritelock.
79190 ** This routine just records the fact that the lock is desired. The
79191 ** code to make the lock occur is generated by a later call to
79192 ** codeTableLocks() which occurs during sqlite3FinishCoding().
79194 SQLITE_PRIVATE void sqlite3TableLock(
79195 Parse *pParse, /* Parsing context */
79196 int iDb, /* Index of the database containing the table to lock */
79197 int iTab, /* Root page number of the table to be locked */
79198 u8 isWriteLock, /* True for a write lock */
79199 const char *zName /* Name of the table to be locked */
79201 Parse *pToplevel = sqlite3ParseToplevel(pParse);
79202 int i;
79203 int nBytes;
79204 TableLock *p;
79205 assert( iDb>=0 );
79207 for(i=0; i<pToplevel->nTableLock; i++){
79208 p = &pToplevel->aTableLock[i];
79209 if( p->iDb==iDb && p->iTab==iTab ){
79210 p->isWriteLock = (p->isWriteLock || isWriteLock);
79211 return;
79215 nBytes = sizeof(TableLock) * (pToplevel->nTableLock+1);
79216 pToplevel->aTableLock =
79217 sqlite3DbReallocOrFree(pToplevel->db, pToplevel->aTableLock, nBytes);
79218 if( pToplevel->aTableLock ){
79219 p = &pToplevel->aTableLock[pToplevel->nTableLock++];
79220 p->iDb = iDb;
79221 p->iTab = iTab;
79222 p->isWriteLock = isWriteLock;
79223 p->zName = zName;
79224 }else{
79225 pToplevel->nTableLock = 0;
79226 pToplevel->db->mallocFailed = 1;
79231 ** Code an OP_TableLock instruction for each table locked by the
79232 ** statement (configured by calls to sqlite3TableLock()).
79234 static void codeTableLocks(Parse *pParse){
79235 int i;
79236 Vdbe *pVdbe;
79238 pVdbe = sqlite3GetVdbe(pParse);
79239 assert( pVdbe!=0 ); /* sqlite3GetVdbe cannot fail: VDBE already allocated */
79241 for(i=0; i<pParse->nTableLock; i++){
79242 TableLock *p = &pParse->aTableLock[i];
79243 int p1 = p->iDb;
79244 sqlite3VdbeAddOp4(pVdbe, OP_TableLock, p1, p->iTab, p->isWriteLock,
79245 p->zName, P4_STATIC);
79248 #else
79249 #define codeTableLocks(x)
79250 #endif
79253 ** This routine is called after a single SQL statement has been
79254 ** parsed and a VDBE program to execute that statement has been
79255 ** prepared. This routine puts the finishing touches on the
79256 ** VDBE program and resets the pParse structure for the next
79257 ** parse.
79259 ** Note that if an error occurred, it might be the case that
79260 ** no VDBE code was generated.
79262 SQLITE_PRIVATE void sqlite3FinishCoding(Parse *pParse){
79263 sqlite3 *db;
79264 Vdbe *v;
79266 db = pParse->db;
79267 if( db->mallocFailed ) return;
79268 if( pParse->nested ) return;
79269 if( pParse->nErr ) return;
79271 /* Begin by generating some termination code at the end of the
79272 ** vdbe program
79274 v = sqlite3GetVdbe(pParse);
79275 assert( !pParse->isMultiWrite
79276 || sqlite3VdbeAssertMayAbort(v, pParse->mayAbort));
79277 if( v ){
79278 sqlite3VdbeAddOp0(v, OP_Halt);
79280 /* The cookie mask contains one bit for each database file open.
79281 ** (Bit 0 is for main, bit 1 is for temp, and so forth.) Bits are
79282 ** set for each database that is used. Generate code to start a
79283 ** transaction on each used database and to verify the schema cookie
79284 ** on each used database.
79286 if( pParse->cookieGoto>0 ){
79287 yDbMask mask;
79288 int iDb;
79289 sqlite3VdbeJumpHere(v, pParse->cookieGoto-1);
79290 for(iDb=0, mask=1; iDb<db->nDb; mask<<=1, iDb++){
79291 if( (mask & pParse->cookieMask)==0 ) continue;
79292 sqlite3VdbeUsesBtree(v, iDb);
79293 sqlite3VdbeAddOp2(v,OP_Transaction, iDb, (mask & pParse->writeMask)!=0);
79294 if( db->init.busy==0 ){
79295 assert( sqlite3SchemaMutexHeld(db, iDb, 0) );
79296 sqlite3VdbeAddOp3(v, OP_VerifyCookie,
79297 iDb, pParse->cookieValue[iDb],
79298 db->aDb[iDb].pSchema->iGeneration);
79301 #ifndef SQLITE_OMIT_VIRTUALTABLE
79303 int i;
79304 for(i=0; i<pParse->nVtabLock; i++){
79305 char *vtab = (char *)sqlite3GetVTable(db, pParse->apVtabLock[i]);
79306 sqlite3VdbeAddOp4(v, OP_VBegin, 0, 0, 0, vtab, P4_VTAB);
79308 pParse->nVtabLock = 0;
79310 #endif
79312 /* Once all the cookies have been verified and transactions opened,
79313 ** obtain the required table-locks. This is a no-op unless the
79314 ** shared-cache feature is enabled.
79316 codeTableLocks(pParse);
79318 /* Initialize any AUTOINCREMENT data structures required.
79320 sqlite3AutoincrementBegin(pParse);
79322 /* Finally, jump back to the beginning of the executable code. */
79323 sqlite3VdbeAddOp2(v, OP_Goto, 0, pParse->cookieGoto);
79328 /* Get the VDBE program ready for execution
79330 if( v && ALWAYS(pParse->nErr==0) && !db->mallocFailed ){
79331 #ifdef SQLITE_DEBUG
79332 FILE *trace = (db->flags & SQLITE_VdbeTrace)!=0 ? stdout : 0;
79333 sqlite3VdbeTrace(v, trace);
79334 #endif
79335 assert( pParse->iCacheLevel==0 ); /* Disables and re-enables match */
79336 /* A minimum of one cursor is required if autoincrement is used
79337 * See ticket [a696379c1f08866] */
79338 if( pParse->pAinc!=0 && pParse->nTab==0 ) pParse->nTab = 1;
79339 sqlite3VdbeMakeReady(v, pParse);
79340 pParse->rc = SQLITE_DONE;
79341 pParse->colNamesSet = 0;
79342 }else{
79343 pParse->rc = SQLITE_ERROR;
79345 pParse->nTab = 0;
79346 pParse->nMem = 0;
79347 pParse->nSet = 0;
79348 pParse->nVar = 0;
79349 pParse->cookieMask = 0;
79350 pParse->cookieGoto = 0;
79354 ** Run the parser and code generator recursively in order to generate
79355 ** code for the SQL statement given onto the end of the pParse context
79356 ** currently under construction. When the parser is run recursively
79357 ** this way, the final OP_Halt is not appended and other initialization
79358 ** and finalization steps are omitted because those are handling by the
79359 ** outermost parser.
79361 ** Not everything is nestable. This facility is designed to permit
79362 ** INSERT, UPDATE, and DELETE operations against SQLITE_MASTER. Use
79363 ** care if you decide to try to use this routine for some other purposes.
79365 SQLITE_PRIVATE void sqlite3NestedParse(Parse *pParse, const char *zFormat, ...){
79366 va_list ap;
79367 char *zSql;
79368 char *zErrMsg = 0;
79369 sqlite3 *db = pParse->db;
79370 # define SAVE_SZ (sizeof(Parse) - offsetof(Parse,nVar))
79371 char saveBuf[SAVE_SZ];
79373 if( pParse->nErr ) return;
79374 assert( pParse->nested<10 ); /* Nesting should only be of limited depth */
79375 va_start(ap, zFormat);
79376 zSql = sqlite3VMPrintf(db, zFormat, ap);
79377 va_end(ap);
79378 if( zSql==0 ){
79379 return; /* A malloc must have failed */
79381 pParse->nested++;
79382 memcpy(saveBuf, &pParse->nVar, SAVE_SZ);
79383 memset(&pParse->nVar, 0, SAVE_SZ);
79384 sqlite3RunParser(pParse, zSql, &zErrMsg);
79385 sqlite3DbFree(db, zErrMsg);
79386 sqlite3DbFree(db, zSql);
79387 memcpy(&pParse->nVar, saveBuf, SAVE_SZ);
79388 pParse->nested--;
79392 ** Locate the in-memory structure that describes a particular database
79393 ** table given the name of that table and (optionally) the name of the
79394 ** database containing the table. Return NULL if not found.
79396 ** If zDatabase is 0, all databases are searched for the table and the
79397 ** first matching table is returned. (No checking for duplicate table
79398 ** names is done.) The search order is TEMP first, then MAIN, then any
79399 ** auxiliary databases added using the ATTACH command.
79401 ** See also sqlite3LocateTable().
79403 SQLITE_PRIVATE Table *sqlite3FindTable(sqlite3 *db, const char *zName, const char *zDatabase){
79404 Table *p = 0;
79405 int i;
79406 int nName;
79407 assert( zName!=0 );
79408 nName = sqlite3Strlen30(zName);
79409 /* All mutexes are required for schema access. Make sure we hold them. */
79410 assert( zDatabase!=0 || sqlite3BtreeHoldsAllMutexes(db) );
79411 for(i=OMIT_TEMPDB; i<db->nDb; i++){
79412 int j = (i<2) ? i^1 : i; /* Search TEMP before MAIN */
79413 if( zDatabase!=0 && sqlite3StrICmp(zDatabase, db->aDb[j].zName) ) continue;
79414 assert( sqlite3SchemaMutexHeld(db, j, 0) );
79415 p = sqlite3HashFind(&db->aDb[j].pSchema->tblHash, zName, nName);
79416 if( p ) break;
79418 return p;
79422 ** Locate the in-memory structure that describes a particular database
79423 ** table given the name of that table and (optionally) the name of the
79424 ** database containing the table. Return NULL if not found. Also leave an
79425 ** error message in pParse->zErrMsg.
79427 ** The difference between this routine and sqlite3FindTable() is that this
79428 ** routine leaves an error message in pParse->zErrMsg where
79429 ** sqlite3FindTable() does not.
79431 SQLITE_PRIVATE Table *sqlite3LocateTable(
79432 Parse *pParse, /* context in which to report errors */
79433 int isView, /* True if looking for a VIEW rather than a TABLE */
79434 const char *zName, /* Name of the table we are looking for */
79435 const char *zDbase /* Name of the database. Might be NULL */
79437 Table *p;
79439 /* Read the database schema. If an error occurs, leave an error message
79440 ** and code in pParse and return NULL. */
79441 if( SQLITE_OK!=sqlite3ReadSchema(pParse) ){
79442 return 0;
79445 p = sqlite3FindTable(pParse->db, zName, zDbase);
79446 if( p==0 ){
79447 const char *zMsg = isView ? "no such view" : "no such table";
79448 if( zDbase ){
79449 sqlite3ErrorMsg(pParse, "%s: %s.%s", zMsg, zDbase, zName);
79450 }else{
79451 sqlite3ErrorMsg(pParse, "%s: %s", zMsg, zName);
79453 pParse->checkSchema = 1;
79455 return p;
79459 ** Locate the in-memory structure that describes
79460 ** a particular index given the name of that index
79461 ** and the name of the database that contains the index.
79462 ** Return NULL if not found.
79464 ** If zDatabase is 0, all databases are searched for the
79465 ** table and the first matching index is returned. (No checking
79466 ** for duplicate index names is done.) The search order is
79467 ** TEMP first, then MAIN, then any auxiliary databases added
79468 ** using the ATTACH command.
79470 SQLITE_PRIVATE Index *sqlite3FindIndex(sqlite3 *db, const char *zName, const char *zDb){
79471 Index *p = 0;
79472 int i;
79473 int nName = sqlite3Strlen30(zName);
79474 /* All mutexes are required for schema access. Make sure we hold them. */
79475 assert( zDb!=0 || sqlite3BtreeHoldsAllMutexes(db) );
79476 for(i=OMIT_TEMPDB; i<db->nDb; i++){
79477 int j = (i<2) ? i^1 : i; /* Search TEMP before MAIN */
79478 Schema *pSchema = db->aDb[j].pSchema;
79479 assert( pSchema );
79480 if( zDb && sqlite3StrICmp(zDb, db->aDb[j].zName) ) continue;
79481 assert( sqlite3SchemaMutexHeld(db, j, 0) );
79482 p = sqlite3HashFind(&pSchema->idxHash, zName, nName);
79483 if( p ) break;
79485 return p;
79489 ** Reclaim the memory used by an index
79491 static void freeIndex(sqlite3 *db, Index *p){
79492 #ifndef SQLITE_OMIT_ANALYZE
79493 sqlite3DeleteIndexSamples(db, p);
79494 #endif
79495 sqlite3DbFree(db, p->zColAff);
79496 sqlite3DbFree(db, p);
79500 ** For the index called zIdxName which is found in the database iDb,
79501 ** unlike that index from its Table then remove the index from
79502 ** the index hash table and free all memory structures associated
79503 ** with the index.
79505 SQLITE_PRIVATE void sqlite3UnlinkAndDeleteIndex(sqlite3 *db, int iDb, const char *zIdxName){
79506 Index *pIndex;
79507 int len;
79508 Hash *pHash;
79510 assert( sqlite3SchemaMutexHeld(db, iDb, 0) );
79511 pHash = &db->aDb[iDb].pSchema->idxHash;
79512 len = sqlite3Strlen30(zIdxName);
79513 pIndex = sqlite3HashInsert(pHash, zIdxName, len, 0);
79514 if( ALWAYS(pIndex) ){
79515 if( pIndex->pTable->pIndex==pIndex ){
79516 pIndex->pTable->pIndex = pIndex->pNext;
79517 }else{
79518 Index *p;
79519 /* Justification of ALWAYS(); The index must be on the list of
79520 ** indices. */
79521 p = pIndex->pTable->pIndex;
79522 while( ALWAYS(p) && p->pNext!=pIndex ){ p = p->pNext; }
79523 if( ALWAYS(p && p->pNext==pIndex) ){
79524 p->pNext = pIndex->pNext;
79527 freeIndex(db, pIndex);
79529 db->flags |= SQLITE_InternChanges;
79533 ** Erase all schema information from the in-memory hash tables of
79534 ** a single database. This routine is called to reclaim memory
79535 ** before the database closes. It is also called during a rollback
79536 ** if there were schema changes during the transaction or if a
79537 ** schema-cookie mismatch occurs.
79539 ** If iDb<0 then reset the internal schema tables for all database
79540 ** files. If iDb>=0 then reset the internal schema for only the
79541 ** single file indicated.
79543 SQLITE_PRIVATE void sqlite3ResetInternalSchema(sqlite3 *db, int iDb){
79544 int i, j;
79545 assert( iDb<db->nDb );
79547 if( iDb>=0 ){
79548 /* Case 1: Reset the single schema identified by iDb */
79549 Db *pDb = &db->aDb[iDb];
79550 assert( sqlite3SchemaMutexHeld(db, iDb, 0) );
79551 assert( pDb->pSchema!=0 );
79552 sqlite3SchemaClear(pDb->pSchema);
79554 /* If any database other than TEMP is reset, then also reset TEMP
79555 ** since TEMP might be holding triggers that reference tables in the
79556 ** other database.
79558 if( iDb!=1 ){
79559 pDb = &db->aDb[1];
79560 assert( pDb->pSchema!=0 );
79561 sqlite3SchemaClear(pDb->pSchema);
79563 return;
79565 /* Case 2 (from here to the end): Reset all schemas for all attached
79566 ** databases. */
79567 assert( iDb<0 );
79568 sqlite3BtreeEnterAll(db);
79569 for(i=0; i<db->nDb; i++){
79570 Db *pDb = &db->aDb[i];
79571 if( pDb->pSchema ){
79572 sqlite3SchemaClear(pDb->pSchema);
79575 db->flags &= ~SQLITE_InternChanges;
79576 sqlite3VtabUnlockList(db);
79577 sqlite3BtreeLeaveAll(db);
79579 /* If one or more of the auxiliary database files has been closed,
79580 ** then remove them from the auxiliary database list. We take the
79581 ** opportunity to do this here since we have just deleted all of the
79582 ** schema hash tables and therefore do not have to make any changes
79583 ** to any of those tables.
79585 for(i=j=2; i<db->nDb; i++){
79586 struct Db *pDb = &db->aDb[i];
79587 if( pDb->pBt==0 ){
79588 sqlite3DbFree(db, pDb->zName);
79589 pDb->zName = 0;
79590 continue;
79592 if( j<i ){
79593 db->aDb[j] = db->aDb[i];
79595 j++;
79597 memset(&db->aDb[j], 0, (db->nDb-j)*sizeof(db->aDb[j]));
79598 db->nDb = j;
79599 if( db->nDb<=2 && db->aDb!=db->aDbStatic ){
79600 memcpy(db->aDbStatic, db->aDb, 2*sizeof(db->aDb[0]));
79601 sqlite3DbFree(db, db->aDb);
79602 db->aDb = db->aDbStatic;
79607 ** This routine is called when a commit occurs.
79609 SQLITE_PRIVATE void sqlite3CommitInternalChanges(sqlite3 *db){
79610 db->flags &= ~SQLITE_InternChanges;
79614 ** Delete memory allocated for the column names of a table or view (the
79615 ** Table.aCol[] array).
79617 static void sqliteDeleteColumnNames(sqlite3 *db, Table *pTable){
79618 int i;
79619 Column *pCol;
79620 assert( pTable!=0 );
79621 if( (pCol = pTable->aCol)!=0 ){
79622 for(i=0; i<pTable->nCol; i++, pCol++){
79623 sqlite3DbFree(db, pCol->zName);
79624 sqlite3ExprDelete(db, pCol->pDflt);
79625 sqlite3DbFree(db, pCol->zDflt);
79626 sqlite3DbFree(db, pCol->zType);
79627 sqlite3DbFree(db, pCol->zColl);
79629 sqlite3DbFree(db, pTable->aCol);
79634 ** Remove the memory data structures associated with the given
79635 ** Table. No changes are made to disk by this routine.
79637 ** This routine just deletes the data structure. It does not unlink
79638 ** the table data structure from the hash table. But it does destroy
79639 ** memory structures of the indices and foreign keys associated with
79640 ** the table.
79642 SQLITE_PRIVATE void sqlite3DeleteTable(sqlite3 *db, Table *pTable){
79643 Index *pIndex, *pNext;
79645 assert( !pTable || pTable->nRef>0 );
79647 /* Do not delete the table until the reference count reaches zero. */
79648 if( !pTable ) return;
79649 if( ((!db || db->pnBytesFreed==0) && (--pTable->nRef)>0) ) return;
79651 /* Delete all indices associated with this table. */
79652 for(pIndex = pTable->pIndex; pIndex; pIndex=pNext){
79653 pNext = pIndex->pNext;
79654 assert( pIndex->pSchema==pTable->pSchema );
79655 if( !db || db->pnBytesFreed==0 ){
79656 char *zName = pIndex->zName;
79657 TESTONLY ( Index *pOld = ) sqlite3HashInsert(
79658 &pIndex->pSchema->idxHash, zName, sqlite3Strlen30(zName), 0
79660 assert( db==0 || sqlite3SchemaMutexHeld(db, 0, pIndex->pSchema) );
79661 assert( pOld==pIndex || pOld==0 );
79663 freeIndex(db, pIndex);
79666 /* Delete any foreign keys attached to this table. */
79667 sqlite3FkDelete(db, pTable);
79669 /* Delete the Table structure itself.
79671 sqliteDeleteColumnNames(db, pTable);
79672 sqlite3DbFree(db, pTable->zName);
79673 sqlite3DbFree(db, pTable->zColAff);
79674 sqlite3SelectDelete(db, pTable->pSelect);
79675 #ifndef SQLITE_OMIT_CHECK
79676 sqlite3ExprDelete(db, pTable->pCheck);
79677 #endif
79678 #ifndef SQLITE_OMIT_VIRTUALTABLE
79679 sqlite3VtabClear(db, pTable);
79680 #endif
79681 sqlite3DbFree(db, pTable);
79685 ** Unlink the given table from the hash tables and the delete the
79686 ** table structure with all its indices and foreign keys.
79688 SQLITE_PRIVATE void sqlite3UnlinkAndDeleteTable(sqlite3 *db, int iDb, const char *zTabName){
79689 Table *p;
79690 Db *pDb;
79692 assert( db!=0 );
79693 assert( iDb>=0 && iDb<db->nDb );
79694 assert( zTabName );
79695 assert( sqlite3SchemaMutexHeld(db, iDb, 0) );
79696 testcase( zTabName[0]==0 ); /* Zero-length table names are allowed */
79697 pDb = &db->aDb[iDb];
79698 p = sqlite3HashInsert(&pDb->pSchema->tblHash, zTabName,
79699 sqlite3Strlen30(zTabName),0);
79700 sqlite3DeleteTable(db, p);
79701 db->flags |= SQLITE_InternChanges;
79705 ** Given a token, return a string that consists of the text of that
79706 ** token. Space to hold the returned string
79707 ** is obtained from sqliteMalloc() and must be freed by the calling
79708 ** function.
79710 ** Any quotation marks (ex: "name", 'name', [name], or `name`) that
79711 ** surround the body of the token are removed.
79713 ** Tokens are often just pointers into the original SQL text and so
79714 ** are not \000 terminated and are not persistent. The returned string
79715 ** is \000 terminated and is persistent.
79717 SQLITE_PRIVATE char *sqlite3NameFromToken(sqlite3 *db, Token *pName){
79718 char *zName;
79719 if( pName ){
79720 zName = sqlite3DbStrNDup(db, (char*)pName->z, pName->n);
79721 sqlite3Dequote(zName);
79722 }else{
79723 zName = 0;
79725 return zName;
79729 ** Open the sqlite_master table stored in database number iDb for
79730 ** writing. The table is opened using cursor 0.
79732 SQLITE_PRIVATE void sqlite3OpenMasterTable(Parse *p, int iDb){
79733 Vdbe *v = sqlite3GetVdbe(p);
79734 sqlite3TableLock(p, iDb, MASTER_ROOT, 1, SCHEMA_TABLE(iDb));
79735 sqlite3VdbeAddOp3(v, OP_OpenWrite, 0, MASTER_ROOT, iDb);
79736 sqlite3VdbeChangeP4(v, -1, (char *)5, P4_INT32); /* 5 column table */
79737 if( p->nTab==0 ){
79738 p->nTab = 1;
79743 ** Parameter zName points to a nul-terminated buffer containing the name
79744 ** of a database ("main", "temp" or the name of an attached db). This
79745 ** function returns the index of the named database in db->aDb[], or
79746 ** -1 if the named db cannot be found.
79748 SQLITE_PRIVATE int sqlite3FindDbName(sqlite3 *db, const char *zName){
79749 int i = -1; /* Database number */
79750 if( zName ){
79751 Db *pDb;
79752 int n = sqlite3Strlen30(zName);
79753 for(i=(db->nDb-1), pDb=&db->aDb[i]; i>=0; i--, pDb--){
79754 if( (!OMIT_TEMPDB || i!=1 ) && n==sqlite3Strlen30(pDb->zName) &&
79755 0==sqlite3StrICmp(pDb->zName, zName) ){
79756 break;
79760 return i;
79764 ** The token *pName contains the name of a database (either "main" or
79765 ** "temp" or the name of an attached db). This routine returns the
79766 ** index of the named database in db->aDb[], or -1 if the named db
79767 ** does not exist.
79769 SQLITE_PRIVATE int sqlite3FindDb(sqlite3 *db, Token *pName){
79770 int i; /* Database number */
79771 char *zName; /* Name we are searching for */
79772 zName = sqlite3NameFromToken(db, pName);
79773 i = sqlite3FindDbName(db, zName);
79774 sqlite3DbFree(db, zName);
79775 return i;
79778 /* The table or view or trigger name is passed to this routine via tokens
79779 ** pName1 and pName2. If the table name was fully qualified, for example:
79781 ** CREATE TABLE xxx.yyy (...);
79783 ** Then pName1 is set to "xxx" and pName2 "yyy". On the other hand if
79784 ** the table name is not fully qualified, i.e.:
79786 ** CREATE TABLE yyy(...);
79788 ** Then pName1 is set to "yyy" and pName2 is "".
79790 ** This routine sets the *ppUnqual pointer to point at the token (pName1 or
79791 ** pName2) that stores the unqualified table name. The index of the
79792 ** database "xxx" is returned.
79794 SQLITE_PRIVATE int sqlite3TwoPartName(
79795 Parse *pParse, /* Parsing and code generating context */
79796 Token *pName1, /* The "xxx" in the name "xxx.yyy" or "xxx" */
79797 Token *pName2, /* The "yyy" in the name "xxx.yyy" */
79798 Token **pUnqual /* Write the unqualified object name here */
79800 int iDb; /* Database holding the object */
79801 sqlite3 *db = pParse->db;
79803 if( ALWAYS(pName2!=0) && pName2->n>0 ){
79804 if( db->init.busy ) {
79805 sqlite3ErrorMsg(pParse, "corrupt database");
79806 pParse->nErr++;
79807 return -1;
79809 *pUnqual = pName2;
79810 iDb = sqlite3FindDb(db, pName1);
79811 if( iDb<0 ){
79812 sqlite3ErrorMsg(pParse, "unknown database %T", pName1);
79813 pParse->nErr++;
79814 return -1;
79816 }else{
79817 assert( db->init.iDb==0 || db->init.busy );
79818 iDb = db->init.iDb;
79819 *pUnqual = pName1;
79821 return iDb;
79825 ** This routine is used to check if the UTF-8 string zName is a legal
79826 ** unqualified name for a new schema object (table, index, view or
79827 ** trigger). All names are legal except those that begin with the string
79828 ** "sqlite_" (in upper, lower or mixed case). This portion of the namespace
79829 ** is reserved for internal use.
79831 SQLITE_PRIVATE int sqlite3CheckObjectName(Parse *pParse, const char *zName){
79832 if( !pParse->db->init.busy && pParse->nested==0
79833 && (pParse->db->flags & SQLITE_WriteSchema)==0
79834 && 0==sqlite3StrNICmp(zName, "sqlite_", 7) ){
79835 sqlite3ErrorMsg(pParse, "object name reserved for internal use: %s", zName);
79836 return SQLITE_ERROR;
79838 return SQLITE_OK;
79842 ** Begin constructing a new table representation in memory. This is
79843 ** the first of several action routines that get called in response
79844 ** to a CREATE TABLE statement. In particular, this routine is called
79845 ** after seeing tokens "CREATE" and "TABLE" and the table name. The isTemp
79846 ** flag is true if the table should be stored in the auxiliary database
79847 ** file instead of in the main database file. This is normally the case
79848 ** when the "TEMP" or "TEMPORARY" keyword occurs in between
79849 ** CREATE and TABLE.
79851 ** The new table record is initialized and put in pParse->pNewTable.
79852 ** As more of the CREATE TABLE statement is parsed, additional action
79853 ** routines will be called to add more information to this record.
79854 ** At the end of the CREATE TABLE statement, the sqlite3EndTable() routine
79855 ** is called to complete the construction of the new table record.
79857 SQLITE_PRIVATE void sqlite3StartTable(
79858 Parse *pParse, /* Parser context */
79859 Token *pName1, /* First part of the name of the table or view */
79860 Token *pName2, /* Second part of the name of the table or view */
79861 int isTemp, /* True if this is a TEMP table */
79862 int isView, /* True if this is a VIEW */
79863 int isVirtual, /* True if this is a VIRTUAL table */
79864 int noErr /* Do nothing if table already exists */
79866 Table *pTable;
79867 char *zName = 0; /* The name of the new table */
79868 sqlite3 *db = pParse->db;
79869 Vdbe *v;
79870 int iDb; /* Database number to create the table in */
79871 Token *pName; /* Unqualified name of the table to create */
79873 /* The table or view name to create is passed to this routine via tokens
79874 ** pName1 and pName2. If the table name was fully qualified, for example:
79876 ** CREATE TABLE xxx.yyy (...);
79878 ** Then pName1 is set to "xxx" and pName2 "yyy". On the other hand if
79879 ** the table name is not fully qualified, i.e.:
79881 ** CREATE TABLE yyy(...);
79883 ** Then pName1 is set to "yyy" and pName2 is "".
79885 ** The call below sets the pName pointer to point at the token (pName1 or
79886 ** pName2) that stores the unqualified table name. The variable iDb is
79887 ** set to the index of the database that the table or view is to be
79888 ** created in.
79890 iDb = sqlite3TwoPartName(pParse, pName1, pName2, &pName);
79891 if( iDb<0 ) return;
79892 if( !OMIT_TEMPDB && isTemp && pName2->n>0 && iDb!=1 ){
79893 /* If creating a temp table, the name may not be qualified. Unless
79894 ** the database name is "temp" anyway. */
79895 sqlite3ErrorMsg(pParse, "temporary table name must be unqualified");
79896 return;
79898 if( !OMIT_TEMPDB && isTemp ) iDb = 1;
79900 pParse->sNameToken = *pName;
79901 zName = sqlite3NameFromToken(db, pName);
79902 if( zName==0 ) return;
79903 if( SQLITE_OK!=sqlite3CheckObjectName(pParse, zName) ){
79904 goto begin_table_error;
79906 if( db->init.iDb==1 ) isTemp = 1;
79907 #ifndef SQLITE_OMIT_AUTHORIZATION
79908 assert( (isTemp & 1)==isTemp );
79910 int code;
79911 char *zDb = db->aDb[iDb].zName;
79912 if( sqlite3AuthCheck(pParse, SQLITE_INSERT, SCHEMA_TABLE(isTemp), 0, zDb) ){
79913 goto begin_table_error;
79915 if( isView ){
79916 if( !OMIT_TEMPDB && isTemp ){
79917 code = SQLITE_CREATE_TEMP_VIEW;
79918 }else{
79919 code = SQLITE_CREATE_VIEW;
79921 }else{
79922 if( !OMIT_TEMPDB && isTemp ){
79923 code = SQLITE_CREATE_TEMP_TABLE;
79924 }else{
79925 code = SQLITE_CREATE_TABLE;
79928 if( !isVirtual && sqlite3AuthCheck(pParse, code, zName, 0, zDb) ){
79929 goto begin_table_error;
79932 #endif
79934 /* Make sure the new table name does not collide with an existing
79935 ** index or table name in the same database. Issue an error message if
79936 ** it does. The exception is if the statement being parsed was passed
79937 ** to an sqlite3_declare_vtab() call. In that case only the column names
79938 ** and types will be used, so there is no need to test for namespace
79939 ** collisions.
79941 if( !IN_DECLARE_VTAB ){
79942 char *zDb = db->aDb[iDb].zName;
79943 if( SQLITE_OK!=sqlite3ReadSchema(pParse) ){
79944 goto begin_table_error;
79946 pTable = sqlite3FindTable(db, zName, zDb);
79947 if( pTable ){
79948 if( !noErr ){
79949 sqlite3ErrorMsg(pParse, "table %T already exists", pName);
79950 }else{
79951 assert( !db->init.busy );
79952 sqlite3CodeVerifySchema(pParse, iDb);
79954 goto begin_table_error;
79956 if( sqlite3FindIndex(db, zName, zDb)!=0 ){
79957 sqlite3ErrorMsg(pParse, "there is already an index named %s", zName);
79958 goto begin_table_error;
79962 pTable = sqlite3DbMallocZero(db, sizeof(Table));
79963 if( pTable==0 ){
79964 db->mallocFailed = 1;
79965 pParse->rc = SQLITE_NOMEM;
79966 pParse->nErr++;
79967 goto begin_table_error;
79969 pTable->zName = zName;
79970 pTable->iPKey = -1;
79971 pTable->pSchema = db->aDb[iDb].pSchema;
79972 pTable->nRef = 1;
79973 pTable->nRowEst = 1000000;
79974 assert( pParse->pNewTable==0 );
79975 pParse->pNewTable = pTable;
79977 /* If this is the magic sqlite_sequence table used by autoincrement,
79978 ** then record a pointer to this table in the main database structure
79979 ** so that INSERT can find the table easily.
79981 #ifndef SQLITE_OMIT_AUTOINCREMENT
79982 if( !pParse->nested && strcmp(zName, "sqlite_sequence")==0 ){
79983 assert( sqlite3SchemaMutexHeld(db, iDb, 0) );
79984 pTable->pSchema->pSeqTab = pTable;
79986 #endif
79988 /* Begin generating the code that will insert the table record into
79989 ** the SQLITE_MASTER table. Note in particular that we must go ahead
79990 ** and allocate the record number for the table entry now. Before any
79991 ** PRIMARY KEY or UNIQUE keywords are parsed. Those keywords will cause
79992 ** indices to be created and the table record must come before the
79993 ** indices. Hence, the record number for the table must be allocated
79994 ** now.
79996 if( !db->init.busy && (v = sqlite3GetVdbe(pParse))!=0 ){
79997 int j1;
79998 int fileFormat;
79999 int reg1, reg2, reg3;
80000 sqlite3BeginWriteOperation(pParse, 0, iDb);
80002 #ifndef SQLITE_OMIT_VIRTUALTABLE
80003 if( isVirtual ){
80004 sqlite3VdbeAddOp0(v, OP_VBegin);
80006 #endif
80008 /* If the file format and encoding in the database have not been set,
80009 ** set them now.
80011 reg1 = pParse->regRowid = ++pParse->nMem;
80012 reg2 = pParse->regRoot = ++pParse->nMem;
80013 reg3 = ++pParse->nMem;
80014 sqlite3VdbeAddOp3(v, OP_ReadCookie, iDb, reg3, BTREE_FILE_FORMAT);
80015 sqlite3VdbeUsesBtree(v, iDb);
80016 j1 = sqlite3VdbeAddOp1(v, OP_If, reg3);
80017 fileFormat = (db->flags & SQLITE_LegacyFileFmt)!=0 ?
80018 1 : SQLITE_MAX_FILE_FORMAT;
80019 sqlite3VdbeAddOp2(v, OP_Integer, fileFormat, reg3);
80020 sqlite3VdbeAddOp3(v, OP_SetCookie, iDb, BTREE_FILE_FORMAT, reg3);
80021 sqlite3VdbeAddOp2(v, OP_Integer, ENC(db), reg3);
80022 sqlite3VdbeAddOp3(v, OP_SetCookie, iDb, BTREE_TEXT_ENCODING, reg3);
80023 sqlite3VdbeJumpHere(v, j1);
80025 /* This just creates a place-holder record in the sqlite_master table.
80026 ** The record created does not contain anything yet. It will be replaced
80027 ** by the real entry in code generated at sqlite3EndTable().
80029 ** The rowid for the new entry is left in register pParse->regRowid.
80030 ** The root page number of the new table is left in reg pParse->regRoot.
80031 ** The rowid and root page number values are needed by the code that
80032 ** sqlite3EndTable will generate.
80034 #if !defined(SQLITE_OMIT_VIEW) || !defined(SQLITE_OMIT_VIRTUALTABLE)
80035 if( isView || isVirtual ){
80036 sqlite3VdbeAddOp2(v, OP_Integer, 0, reg2);
80037 }else
80038 #endif
80040 sqlite3VdbeAddOp2(v, OP_CreateTable, iDb, reg2);
80042 sqlite3OpenMasterTable(pParse, iDb);
80043 sqlite3VdbeAddOp2(v, OP_NewRowid, 0, reg1);
80044 sqlite3VdbeAddOp2(v, OP_Null, 0, reg3);
80045 sqlite3VdbeAddOp3(v, OP_Insert, 0, reg3, reg1);
80046 sqlite3VdbeChangeP5(v, OPFLAG_APPEND);
80047 sqlite3VdbeAddOp0(v, OP_Close);
80050 /* Normal (non-error) return. */
80051 return;
80053 /* If an error occurs, we jump here */
80054 begin_table_error:
80055 sqlite3DbFree(db, zName);
80056 return;
80060 ** This macro is used to compare two strings in a case-insensitive manner.
80061 ** It is slightly faster than calling sqlite3StrICmp() directly, but
80062 ** produces larger code.
80064 ** WARNING: This macro is not compatible with the strcmp() family. It
80065 ** returns true if the two strings are equal, otherwise false.
80067 #define STRICMP(x, y) (\
80068 sqlite3UpperToLower[*(unsigned char *)(x)]== \
80069 sqlite3UpperToLower[*(unsigned char *)(y)] \
80070 && sqlite3StrICmp((x)+1,(y)+1)==0 )
80073 ** Add a new column to the table currently being constructed.
80075 ** The parser calls this routine once for each column declaration
80076 ** in a CREATE TABLE statement. sqlite3StartTable() gets called
80077 ** first to get things going. Then this routine is called for each
80078 ** column.
80080 SQLITE_PRIVATE void sqlite3AddColumn(Parse *pParse, Token *pName){
80081 Table *p;
80082 int i;
80083 char *z;
80084 Column *pCol;
80085 sqlite3 *db = pParse->db;
80086 if( (p = pParse->pNewTable)==0 ) return;
80087 #if SQLITE_MAX_COLUMN
80088 if( p->nCol+1>db->aLimit[SQLITE_LIMIT_COLUMN] ){
80089 sqlite3ErrorMsg(pParse, "too many columns on %s", p->zName);
80090 return;
80092 #endif
80093 z = sqlite3NameFromToken(db, pName);
80094 if( z==0 ) return;
80095 for(i=0; i<p->nCol; i++){
80096 if( STRICMP(z, p->aCol[i].zName) ){
80097 sqlite3ErrorMsg(pParse, "duplicate column name: %s", z);
80098 sqlite3DbFree(db, z);
80099 return;
80102 if( (p->nCol & 0x7)==0 ){
80103 Column *aNew;
80104 aNew = sqlite3DbRealloc(db,p->aCol,(p->nCol+8)*sizeof(p->aCol[0]));
80105 if( aNew==0 ){
80106 sqlite3DbFree(db, z);
80107 return;
80109 p->aCol = aNew;
80111 pCol = &p->aCol[p->nCol];
80112 memset(pCol, 0, sizeof(p->aCol[0]));
80113 pCol->zName = z;
80115 /* If there is no type specified, columns have the default affinity
80116 ** 'NONE'. If there is a type specified, then sqlite3AddColumnType() will
80117 ** be called next to set pCol->affinity correctly.
80119 pCol->affinity = SQLITE_AFF_NONE;
80120 p->nCol++;
80124 ** This routine is called by the parser while in the middle of
80125 ** parsing a CREATE TABLE statement. A "NOT NULL" constraint has
80126 ** been seen on a column. This routine sets the notNull flag on
80127 ** the column currently under construction.
80129 SQLITE_PRIVATE void sqlite3AddNotNull(Parse *pParse, int onError){
80130 Table *p;
80131 p = pParse->pNewTable;
80132 if( p==0 || NEVER(p->nCol<1) ) return;
80133 p->aCol[p->nCol-1].notNull = (u8)onError;
80137 ** Scan the column type name zType (length nType) and return the
80138 ** associated affinity type.
80140 ** This routine does a case-independent search of zType for the
80141 ** substrings in the following table. If one of the substrings is
80142 ** found, the corresponding affinity is returned. If zType contains
80143 ** more than one of the substrings, entries toward the top of
80144 ** the table take priority. For example, if zType is 'BLOBINT',
80145 ** SQLITE_AFF_INTEGER is returned.
80147 ** Substring | Affinity
80148 ** --------------------------------
80149 ** 'INT' | SQLITE_AFF_INTEGER
80150 ** 'CHAR' | SQLITE_AFF_TEXT
80151 ** 'CLOB' | SQLITE_AFF_TEXT
80152 ** 'TEXT' | SQLITE_AFF_TEXT
80153 ** 'BLOB' | SQLITE_AFF_NONE
80154 ** 'REAL' | SQLITE_AFF_REAL
80155 ** 'FLOA' | SQLITE_AFF_REAL
80156 ** 'DOUB' | SQLITE_AFF_REAL
80158 ** If none of the substrings in the above table are found,
80159 ** SQLITE_AFF_NUMERIC is returned.
80161 SQLITE_PRIVATE char sqlite3AffinityType(const char *zIn){
80162 u32 h = 0;
80163 char aff = SQLITE_AFF_NUMERIC;
80165 if( zIn ) while( zIn[0] ){
80166 h = (h<<8) + sqlite3UpperToLower[(*zIn)&0xff];
80167 zIn++;
80168 if( h==(('c'<<24)+('h'<<16)+('a'<<8)+'r') ){ /* CHAR */
80169 aff = SQLITE_AFF_TEXT;
80170 }else if( h==(('c'<<24)+('l'<<16)+('o'<<8)+'b') ){ /* CLOB */
80171 aff = SQLITE_AFF_TEXT;
80172 }else if( h==(('t'<<24)+('e'<<16)+('x'<<8)+'t') ){ /* TEXT */
80173 aff = SQLITE_AFF_TEXT;
80174 }else if( h==(('b'<<24)+('l'<<16)+('o'<<8)+'b') /* BLOB */
80175 && (aff==SQLITE_AFF_NUMERIC || aff==SQLITE_AFF_REAL) ){
80176 aff = SQLITE_AFF_NONE;
80177 #ifndef SQLITE_OMIT_FLOATING_POINT
80178 }else if( h==(('r'<<24)+('e'<<16)+('a'<<8)+'l') /* REAL */
80179 && aff==SQLITE_AFF_NUMERIC ){
80180 aff = SQLITE_AFF_REAL;
80181 }else if( h==(('f'<<24)+('l'<<16)+('o'<<8)+'a') /* FLOA */
80182 && aff==SQLITE_AFF_NUMERIC ){
80183 aff = SQLITE_AFF_REAL;
80184 }else if( h==(('d'<<24)+('o'<<16)+('u'<<8)+'b') /* DOUB */
80185 && aff==SQLITE_AFF_NUMERIC ){
80186 aff = SQLITE_AFF_REAL;
80187 #endif
80188 }else if( (h&0x00FFFFFF)==(('i'<<16)+('n'<<8)+'t') ){ /* INT */
80189 aff = SQLITE_AFF_INTEGER;
80190 break;
80194 return aff;
80198 ** This routine is called by the parser while in the middle of
80199 ** parsing a CREATE TABLE statement. The pFirst token is the first
80200 ** token in the sequence of tokens that describe the type of the
80201 ** column currently under construction. pLast is the last token
80202 ** in the sequence. Use this information to construct a string
80203 ** that contains the typename of the column and store that string
80204 ** in zType.
80206 SQLITE_PRIVATE void sqlite3AddColumnType(Parse *pParse, Token *pType){
80207 Table *p;
80208 Column *pCol;
80210 p = pParse->pNewTable;
80211 if( p==0 || NEVER(p->nCol<1) ) return;
80212 pCol = &p->aCol[p->nCol-1];
80213 assert( pCol->zType==0 );
80214 pCol->zType = sqlite3NameFromToken(pParse->db, pType);
80215 pCol->affinity = sqlite3AffinityType(pCol->zType);
80219 ** The expression is the default value for the most recently added column
80220 ** of the table currently under construction.
80222 ** Default value expressions must be constant. Raise an exception if this
80223 ** is not the case.
80225 ** This routine is called by the parser while in the middle of
80226 ** parsing a CREATE TABLE statement.
80228 SQLITE_PRIVATE void sqlite3AddDefaultValue(Parse *pParse, ExprSpan *pSpan){
80229 Table *p;
80230 Column *pCol;
80231 sqlite3 *db = pParse->db;
80232 p = pParse->pNewTable;
80233 if( p!=0 ){
80234 pCol = &(p->aCol[p->nCol-1]);
80235 if( !sqlite3ExprIsConstantOrFunction(pSpan->pExpr) ){
80236 sqlite3ErrorMsg(pParse, "default value of column [%s] is not constant",
80237 pCol->zName);
80238 }else{
80239 /* A copy of pExpr is used instead of the original, as pExpr contains
80240 ** tokens that point to volatile memory. The 'span' of the expression
80241 ** is required by pragma table_info.
80243 sqlite3ExprDelete(db, pCol->pDflt);
80244 pCol->pDflt = sqlite3ExprDup(db, pSpan->pExpr, EXPRDUP_REDUCE);
80245 sqlite3DbFree(db, pCol->zDflt);
80246 pCol->zDflt = sqlite3DbStrNDup(db, (char*)pSpan->zStart,
80247 (int)(pSpan->zEnd - pSpan->zStart));
80250 sqlite3ExprDelete(db, pSpan->pExpr);
80254 ** Designate the PRIMARY KEY for the table. pList is a list of names
80255 ** of columns that form the primary key. If pList is NULL, then the
80256 ** most recently added column of the table is the primary key.
80258 ** A table can have at most one primary key. If the table already has
80259 ** a primary key (and this is the second primary key) then create an
80260 ** error.
80262 ** If the PRIMARY KEY is on a single column whose datatype is INTEGER,
80263 ** then we will try to use that column as the rowid. Set the Table.iPKey
80264 ** field of the table under construction to be the index of the
80265 ** INTEGER PRIMARY KEY column. Table.iPKey is set to -1 if there is
80266 ** no INTEGER PRIMARY KEY.
80268 ** If the key is not an INTEGER PRIMARY KEY, then create a unique
80269 ** index for the key. No index is created for INTEGER PRIMARY KEYs.
80271 SQLITE_PRIVATE void sqlite3AddPrimaryKey(
80272 Parse *pParse, /* Parsing context */
80273 ExprList *pList, /* List of field names to be indexed */
80274 int onError, /* What to do with a uniqueness conflict */
80275 int autoInc, /* True if the AUTOINCREMENT keyword is present */
80276 int sortOrder /* SQLITE_SO_ASC or SQLITE_SO_DESC */
80278 Table *pTab = pParse->pNewTable;
80279 char *zType = 0;
80280 int iCol = -1, i;
80281 if( pTab==0 || IN_DECLARE_VTAB ) goto primary_key_exit;
80282 if( pTab->tabFlags & TF_HasPrimaryKey ){
80283 sqlite3ErrorMsg(pParse,
80284 "table \"%s\" has more than one primary key", pTab->zName);
80285 goto primary_key_exit;
80287 pTab->tabFlags |= TF_HasPrimaryKey;
80288 if( pList==0 ){
80289 iCol = pTab->nCol - 1;
80290 pTab->aCol[iCol].isPrimKey = 1;
80291 }else{
80292 for(i=0; i<pList->nExpr; i++){
80293 for(iCol=0; iCol<pTab->nCol; iCol++){
80294 if( sqlite3StrICmp(pList->a[i].zName, pTab->aCol[iCol].zName)==0 ){
80295 break;
80298 if( iCol<pTab->nCol ){
80299 pTab->aCol[iCol].isPrimKey = 1;
80302 if( pList->nExpr>1 ) iCol = -1;
80304 if( iCol>=0 && iCol<pTab->nCol ){
80305 zType = pTab->aCol[iCol].zType;
80307 if( zType && sqlite3StrICmp(zType, "INTEGER")==0
80308 && sortOrder==SQLITE_SO_ASC ){
80309 pTab->iPKey = iCol;
80310 pTab->keyConf = (u8)onError;
80311 assert( autoInc==0 || autoInc==1 );
80312 pTab->tabFlags |= autoInc*TF_Autoincrement;
80313 }else if( autoInc ){
80314 #ifndef SQLITE_OMIT_AUTOINCREMENT
80315 sqlite3ErrorMsg(pParse, "AUTOINCREMENT is only allowed on an "
80316 "INTEGER PRIMARY KEY");
80317 #endif
80318 }else{
80319 Index *p;
80320 p = sqlite3CreateIndex(pParse, 0, 0, 0, pList, onError, 0, 0, sortOrder, 0);
80321 if( p ){
80322 p->autoIndex = 2;
80324 pList = 0;
80327 primary_key_exit:
80328 sqlite3ExprListDelete(pParse->db, pList);
80329 return;
80333 ** Add a new CHECK constraint to the table currently under construction.
80335 SQLITE_PRIVATE void sqlite3AddCheckConstraint(
80336 Parse *pParse, /* Parsing context */
80337 Expr *pCheckExpr /* The check expression */
80339 sqlite3 *db = pParse->db;
80340 #ifndef SQLITE_OMIT_CHECK
80341 Table *pTab = pParse->pNewTable;
80342 if( pTab && !IN_DECLARE_VTAB ){
80343 pTab->pCheck = sqlite3ExprAnd(db, pTab->pCheck, pCheckExpr);
80344 }else
80345 #endif
80347 sqlite3ExprDelete(db, pCheckExpr);
80352 ** Set the collation function of the most recently parsed table column
80353 ** to the CollSeq given.
80355 SQLITE_PRIVATE void sqlite3AddCollateType(Parse *pParse, Token *pToken){
80356 Table *p;
80357 int i;
80358 char *zColl; /* Dequoted name of collation sequence */
80359 sqlite3 *db;
80361 if( (p = pParse->pNewTable)==0 ) return;
80362 i = p->nCol-1;
80363 db = pParse->db;
80364 zColl = sqlite3NameFromToken(db, pToken);
80365 if( !zColl ) return;
80367 if( sqlite3LocateCollSeq(pParse, zColl) ){
80368 Index *pIdx;
80369 p->aCol[i].zColl = zColl;
80371 /* If the column is declared as "<name> PRIMARY KEY COLLATE <type>",
80372 ** then an index may have been created on this column before the
80373 ** collation type was added. Correct this if it is the case.
80375 for(pIdx=p->pIndex; pIdx; pIdx=pIdx->pNext){
80376 assert( pIdx->nColumn==1 );
80377 if( pIdx->aiColumn[0]==i ){
80378 pIdx->azColl[0] = p->aCol[i].zColl;
80381 }else{
80382 sqlite3DbFree(db, zColl);
80387 ** This function returns the collation sequence for database native text
80388 ** encoding identified by the string zName, length nName.
80390 ** If the requested collation sequence is not available, or not available
80391 ** in the database native encoding, the collation factory is invoked to
80392 ** request it. If the collation factory does not supply such a sequence,
80393 ** and the sequence is available in another text encoding, then that is
80394 ** returned instead.
80396 ** If no versions of the requested collations sequence are available, or
80397 ** another error occurs, NULL is returned and an error message written into
80398 ** pParse.
80400 ** This routine is a wrapper around sqlite3FindCollSeq(). This routine
80401 ** invokes the collation factory if the named collation cannot be found
80402 ** and generates an error message.
80404 ** See also: sqlite3FindCollSeq(), sqlite3GetCollSeq()
80406 SQLITE_PRIVATE CollSeq *sqlite3LocateCollSeq(Parse *pParse, const char *zName){
80407 sqlite3 *db = pParse->db;
80408 u8 enc = ENC(db);
80409 u8 initbusy = db->init.busy;
80410 CollSeq *pColl;
80412 pColl = sqlite3FindCollSeq(db, enc, zName, initbusy);
80413 if( !initbusy && (!pColl || !pColl->xCmp) ){
80414 pColl = sqlite3GetCollSeq(db, enc, pColl, zName);
80415 if( !pColl ){
80416 sqlite3ErrorMsg(pParse, "no such collation sequence: %s", zName);
80420 return pColl;
80425 ** Generate code that will increment the schema cookie.
80427 ** The schema cookie is used to determine when the schema for the
80428 ** database changes. After each schema change, the cookie value
80429 ** changes. When a process first reads the schema it records the
80430 ** cookie. Thereafter, whenever it goes to access the database,
80431 ** it checks the cookie to make sure the schema has not changed
80432 ** since it was last read.
80434 ** This plan is not completely bullet-proof. It is possible for
80435 ** the schema to change multiple times and for the cookie to be
80436 ** set back to prior value. But schema changes are infrequent
80437 ** and the probability of hitting the same cookie value is only
80438 ** 1 chance in 2^32. So we're safe enough.
80440 SQLITE_PRIVATE void sqlite3ChangeCookie(Parse *pParse, int iDb){
80441 int r1 = sqlite3GetTempReg(pParse);
80442 sqlite3 *db = pParse->db;
80443 Vdbe *v = pParse->pVdbe;
80444 assert( sqlite3SchemaMutexHeld(db, iDb, 0) );
80445 sqlite3VdbeAddOp2(v, OP_Integer, db->aDb[iDb].pSchema->schema_cookie+1, r1);
80446 sqlite3VdbeAddOp3(v, OP_SetCookie, iDb, BTREE_SCHEMA_VERSION, r1);
80447 sqlite3ReleaseTempReg(pParse, r1);
80451 ** Measure the number of characters needed to output the given
80452 ** identifier. The number returned includes any quotes used
80453 ** but does not include the null terminator.
80455 ** The estimate is conservative. It might be larger that what is
80456 ** really needed.
80458 static int identLength(const char *z){
80459 int n;
80460 for(n=0; *z; n++, z++){
80461 if( *z=='"' ){ n++; }
80463 return n + 2;
80467 ** The first parameter is a pointer to an output buffer. The second
80468 ** parameter is a pointer to an integer that contains the offset at
80469 ** which to write into the output buffer. This function copies the
80470 ** nul-terminated string pointed to by the third parameter, zSignedIdent,
80471 ** to the specified offset in the buffer and updates *pIdx to refer
80472 ** to the first byte after the last byte written before returning.
80474 ** If the string zSignedIdent consists entirely of alpha-numeric
80475 ** characters, does not begin with a digit and is not an SQL keyword,
80476 ** then it is copied to the output buffer exactly as it is. Otherwise,
80477 ** it is quoted using double-quotes.
80479 static void identPut(char *z, int *pIdx, char *zSignedIdent){
80480 unsigned char *zIdent = (unsigned char*)zSignedIdent;
80481 int i, j, needQuote;
80482 i = *pIdx;
80484 for(j=0; zIdent[j]; j++){
80485 if( !sqlite3Isalnum(zIdent[j]) && zIdent[j]!='_' ) break;
80487 needQuote = sqlite3Isdigit(zIdent[0]) || sqlite3KeywordCode(zIdent, j)!=TK_ID;
80488 if( !needQuote ){
80489 needQuote = zIdent[j];
80492 if( needQuote ) z[i++] = '"';
80493 for(j=0; zIdent[j]; j++){
80494 z[i++] = zIdent[j];
80495 if( zIdent[j]=='"' ) z[i++] = '"';
80497 if( needQuote ) z[i++] = '"';
80498 z[i] = 0;
80499 *pIdx = i;
80503 ** Generate a CREATE TABLE statement appropriate for the given
80504 ** table. Memory to hold the text of the statement is obtained
80505 ** from sqliteMalloc() and must be freed by the calling function.
80507 static char *createTableStmt(sqlite3 *db, Table *p){
80508 int i, k, n;
80509 char *zStmt;
80510 char *zSep, *zSep2, *zEnd;
80511 Column *pCol;
80512 n = 0;
80513 for(pCol = p->aCol, i=0; i<p->nCol; i++, pCol++){
80514 n += identLength(pCol->zName) + 5;
80516 n += identLength(p->zName);
80517 if( n<50 ){
80518 zSep = "";
80519 zSep2 = ",";
80520 zEnd = ")";
80521 }else{
80522 zSep = "\n ";
80523 zSep2 = ",\n ";
80524 zEnd = "\n)";
80526 n += 35 + 6*p->nCol;
80527 zStmt = sqlite3DbMallocRaw(0, n);
80528 if( zStmt==0 ){
80529 db->mallocFailed = 1;
80530 return 0;
80532 sqlite3_snprintf(n, zStmt, "CREATE TABLE ");
80533 k = sqlite3Strlen30(zStmt);
80534 identPut(zStmt, &k, p->zName);
80535 zStmt[k++] = '(';
80536 for(pCol=p->aCol, i=0; i<p->nCol; i++, pCol++){
80537 static const char * const azType[] = {
80538 /* SQLITE_AFF_TEXT */ " TEXT",
80539 /* SQLITE_AFF_NONE */ "",
80540 /* SQLITE_AFF_NUMERIC */ " NUM",
80541 /* SQLITE_AFF_INTEGER */ " INT",
80542 /* SQLITE_AFF_REAL */ " REAL"
80544 int len;
80545 const char *zType;
80547 sqlite3_snprintf(n-k, &zStmt[k], zSep);
80548 k += sqlite3Strlen30(&zStmt[k]);
80549 zSep = zSep2;
80550 identPut(zStmt, &k, pCol->zName);
80551 assert( pCol->affinity-SQLITE_AFF_TEXT >= 0 );
80552 assert( pCol->affinity-SQLITE_AFF_TEXT < ArraySize(azType) );
80553 testcase( pCol->affinity==SQLITE_AFF_TEXT );
80554 testcase( pCol->affinity==SQLITE_AFF_NONE );
80555 testcase( pCol->affinity==SQLITE_AFF_NUMERIC );
80556 testcase( pCol->affinity==SQLITE_AFF_INTEGER );
80557 testcase( pCol->affinity==SQLITE_AFF_REAL );
80559 zType = azType[pCol->affinity - SQLITE_AFF_TEXT];
80560 len = sqlite3Strlen30(zType);
80561 assert( pCol->affinity==SQLITE_AFF_NONE
80562 || pCol->affinity==sqlite3AffinityType(zType) );
80563 memcpy(&zStmt[k], zType, len);
80564 k += len;
80565 assert( k<=n );
80567 sqlite3_snprintf(n-k, &zStmt[k], "%s", zEnd);
80568 return zStmt;
80572 ** This routine is called to report the final ")" that terminates
80573 ** a CREATE TABLE statement.
80575 ** The table structure that other action routines have been building
80576 ** is added to the internal hash tables, assuming no errors have
80577 ** occurred.
80579 ** An entry for the table is made in the master table on disk, unless
80580 ** this is a temporary table or db->init.busy==1. When db->init.busy==1
80581 ** it means we are reading the sqlite_master table because we just
80582 ** connected to the database or because the sqlite_master table has
80583 ** recently changed, so the entry for this table already exists in
80584 ** the sqlite_master table. We do not want to create it again.
80586 ** If the pSelect argument is not NULL, it means that this routine
80587 ** was called to create a table generated from a
80588 ** "CREATE TABLE ... AS SELECT ..." statement. The column names of
80589 ** the new table will match the result set of the SELECT.
80591 SQLITE_PRIVATE void sqlite3EndTable(
80592 Parse *pParse, /* Parse context */
80593 Token *pCons, /* The ',' token after the last column defn. */
80594 Token *pEnd, /* The final ')' token in the CREATE TABLE */
80595 Select *pSelect /* Select from a "CREATE ... AS SELECT" */
80597 Table *p;
80598 sqlite3 *db = pParse->db;
80599 int iDb;
80601 if( (pEnd==0 && pSelect==0) || db->mallocFailed ){
80602 return;
80604 p = pParse->pNewTable;
80605 if( p==0 ) return;
80607 assert( !db->init.busy || !pSelect );
80609 iDb = sqlite3SchemaToIndex(db, p->pSchema);
80611 #ifndef SQLITE_OMIT_CHECK
80612 /* Resolve names in all CHECK constraint expressions.
80614 if( p->pCheck ){
80615 SrcList sSrc; /* Fake SrcList for pParse->pNewTable */
80616 NameContext sNC; /* Name context for pParse->pNewTable */
80618 memset(&sNC, 0, sizeof(sNC));
80619 memset(&sSrc, 0, sizeof(sSrc));
80620 sSrc.nSrc = 1;
80621 sSrc.a[0].zName = p->zName;
80622 sSrc.a[0].pTab = p;
80623 sSrc.a[0].iCursor = -1;
80624 sNC.pParse = pParse;
80625 sNC.pSrcList = &sSrc;
80626 sNC.isCheck = 1;
80627 if( sqlite3ResolveExprNames(&sNC, p->pCheck) ){
80628 return;
80631 #endif /* !defined(SQLITE_OMIT_CHECK) */
80633 /* If the db->init.busy is 1 it means we are reading the SQL off the
80634 ** "sqlite_master" or "sqlite_temp_master" table on the disk.
80635 ** So do not write to the disk again. Extract the root page number
80636 ** for the table from the db->init.newTnum field. (The page number
80637 ** should have been put there by the sqliteOpenCb routine.)
80639 if( db->init.busy ){
80640 p->tnum = db->init.newTnum;
80643 /* If not initializing, then create a record for the new table
80644 ** in the SQLITE_MASTER table of the database.
80646 ** If this is a TEMPORARY table, write the entry into the auxiliary
80647 ** file instead of into the main database file.
80649 if( !db->init.busy ){
80650 int n;
80651 Vdbe *v;
80652 char *zType; /* "view" or "table" */
80653 char *zType2; /* "VIEW" or "TABLE" */
80654 char *zStmt; /* Text of the CREATE TABLE or CREATE VIEW statement */
80656 v = sqlite3GetVdbe(pParse);
80657 if( NEVER(v==0) ) return;
80659 sqlite3VdbeAddOp1(v, OP_Close, 0);
80662 ** Initialize zType for the new view or table.
80664 if( p->pSelect==0 ){
80665 /* A regular table */
80666 zType = "table";
80667 zType2 = "TABLE";
80668 #ifndef SQLITE_OMIT_VIEW
80669 }else{
80670 /* A view */
80671 zType = "view";
80672 zType2 = "VIEW";
80673 #endif
80676 /* If this is a CREATE TABLE xx AS SELECT ..., execute the SELECT
80677 ** statement to populate the new table. The root-page number for the
80678 ** new table is in register pParse->regRoot.
80680 ** Once the SELECT has been coded by sqlite3Select(), it is in a
80681 ** suitable state to query for the column names and types to be used
80682 ** by the new table.
80684 ** A shared-cache write-lock is not required to write to the new table,
80685 ** as a schema-lock must have already been obtained to create it. Since
80686 ** a schema-lock excludes all other database users, the write-lock would
80687 ** be redundant.
80689 if( pSelect ){
80690 SelectDest dest;
80691 Table *pSelTab;
80693 assert(pParse->nTab==1);
80694 sqlite3VdbeAddOp3(v, OP_OpenWrite, 1, pParse->regRoot, iDb);
80695 sqlite3VdbeChangeP5(v, 1);
80696 pParse->nTab = 2;
80697 sqlite3SelectDestInit(&dest, SRT_Table, 1);
80698 sqlite3Select(pParse, pSelect, &dest);
80699 sqlite3VdbeAddOp1(v, OP_Close, 1);
80700 if( pParse->nErr==0 ){
80701 pSelTab = sqlite3ResultSetOfSelect(pParse, pSelect);
80702 if( pSelTab==0 ) return;
80703 assert( p->aCol==0 );
80704 p->nCol = pSelTab->nCol;
80705 p->aCol = pSelTab->aCol;
80706 pSelTab->nCol = 0;
80707 pSelTab->aCol = 0;
80708 sqlite3DeleteTable(db, pSelTab);
80712 /* Compute the complete text of the CREATE statement */
80713 if( pSelect ){
80714 zStmt = createTableStmt(db, p);
80715 }else{
80716 n = (int)(pEnd->z - pParse->sNameToken.z) + 1;
80717 zStmt = sqlite3MPrintf(db,
80718 "CREATE %s %.*s", zType2, n, pParse->sNameToken.z
80722 /* A slot for the record has already been allocated in the
80723 ** SQLITE_MASTER table. We just need to update that slot with all
80724 ** the information we've collected.
80726 sqlite3NestedParse(pParse,
80727 "UPDATE %Q.%s "
80728 "SET type='%s', name=%Q, tbl_name=%Q, rootpage=#%d, sql=%Q "
80729 "WHERE rowid=#%d",
80730 db->aDb[iDb].zName, SCHEMA_TABLE(iDb),
80731 zType,
80732 p->zName,
80733 p->zName,
80734 pParse->regRoot,
80735 zStmt,
80736 pParse->regRowid
80738 sqlite3DbFree(db, zStmt);
80739 sqlite3ChangeCookie(pParse, iDb);
80741 #ifndef SQLITE_OMIT_AUTOINCREMENT
80742 /* Check to see if we need to create an sqlite_sequence table for
80743 ** keeping track of autoincrement keys.
80745 if( p->tabFlags & TF_Autoincrement ){
80746 Db *pDb = &db->aDb[iDb];
80747 assert( sqlite3SchemaMutexHeld(db, iDb, 0) );
80748 if( pDb->pSchema->pSeqTab==0 ){
80749 sqlite3NestedParse(pParse,
80750 "CREATE TABLE %Q.sqlite_sequence(name,seq)",
80751 pDb->zName
80755 #endif
80757 /* Reparse everything to update our internal data structures */
80758 sqlite3VdbeAddParseSchemaOp(v, iDb,
80759 sqlite3MPrintf(db, "tbl_name='%q'", p->zName));
80763 /* Add the table to the in-memory representation of the database.
80765 if( db->init.busy ){
80766 Table *pOld;
80767 Schema *pSchema = p->pSchema;
80768 assert( sqlite3SchemaMutexHeld(db, iDb, 0) );
80769 pOld = sqlite3HashInsert(&pSchema->tblHash, p->zName,
80770 sqlite3Strlen30(p->zName),p);
80771 if( pOld ){
80772 assert( p==pOld ); /* Malloc must have failed inside HashInsert() */
80773 db->mallocFailed = 1;
80774 return;
80776 pParse->pNewTable = 0;
80777 db->nTable++;
80778 db->flags |= SQLITE_InternChanges;
80780 #ifndef SQLITE_OMIT_ALTERTABLE
80781 if( !p->pSelect ){
80782 const char *zName = (const char *)pParse->sNameToken.z;
80783 int nName;
80784 assert( !pSelect && pCons && pEnd );
80785 if( pCons->z==0 ){
80786 pCons = pEnd;
80788 nName = (int)((const char *)pCons->z - zName);
80789 p->addColOffset = 13 + sqlite3Utf8CharLen(zName, nName);
80791 #endif
80795 #ifndef SQLITE_OMIT_VIEW
80797 ** The parser calls this routine in order to create a new VIEW
80799 SQLITE_PRIVATE void sqlite3CreateView(
80800 Parse *pParse, /* The parsing context */
80801 Token *pBegin, /* The CREATE token that begins the statement */
80802 Token *pName1, /* The token that holds the name of the view */
80803 Token *pName2, /* The token that holds the name of the view */
80804 Select *pSelect, /* A SELECT statement that will become the new view */
80805 int isTemp, /* TRUE for a TEMPORARY view */
80806 int noErr /* Suppress error messages if VIEW already exists */
80808 Table *p;
80809 int n;
80810 const char *z;
80811 Token sEnd;
80812 DbFixer sFix;
80813 Token *pName = 0;
80814 int iDb;
80815 sqlite3 *db = pParse->db;
80817 if( pParse->nVar>0 ){
80818 sqlite3ErrorMsg(pParse, "parameters are not allowed in views");
80819 sqlite3SelectDelete(db, pSelect);
80820 return;
80822 sqlite3StartTable(pParse, pName1, pName2, isTemp, 1, 0, noErr);
80823 p = pParse->pNewTable;
80824 if( p==0 || pParse->nErr ){
80825 sqlite3SelectDelete(db, pSelect);
80826 return;
80828 sqlite3TwoPartName(pParse, pName1, pName2, &pName);
80829 iDb = sqlite3SchemaToIndex(db, p->pSchema);
80830 if( sqlite3FixInit(&sFix, pParse, iDb, "view", pName)
80831 && sqlite3FixSelect(&sFix, pSelect)
80833 sqlite3SelectDelete(db, pSelect);
80834 return;
80837 /* Make a copy of the entire SELECT statement that defines the view.
80838 ** This will force all the Expr.token.z values to be dynamically
80839 ** allocated rather than point to the input string - which means that
80840 ** they will persist after the current sqlite3_exec() call returns.
80842 p->pSelect = sqlite3SelectDup(db, pSelect, EXPRDUP_REDUCE);
80843 sqlite3SelectDelete(db, pSelect);
80844 if( db->mallocFailed ){
80845 return;
80847 if( !db->init.busy ){
80848 sqlite3ViewGetColumnNames(pParse, p);
80851 /* Locate the end of the CREATE VIEW statement. Make sEnd point to
80852 ** the end.
80854 sEnd = pParse->sLastToken;
80855 if( ALWAYS(sEnd.z[0]!=0) && sEnd.z[0]!=';' ){
80856 sEnd.z += sEnd.n;
80858 sEnd.n = 0;
80859 n = (int)(sEnd.z - pBegin->z);
80860 z = pBegin->z;
80861 while( ALWAYS(n>0) && sqlite3Isspace(z[n-1]) ){ n--; }
80862 sEnd.z = &z[n-1];
80863 sEnd.n = 1;
80865 /* Use sqlite3EndTable() to add the view to the SQLITE_MASTER table */
80866 sqlite3EndTable(pParse, 0, &sEnd, 0);
80867 return;
80869 #endif /* SQLITE_OMIT_VIEW */
80871 #if !defined(SQLITE_OMIT_VIEW) || !defined(SQLITE_OMIT_VIRTUALTABLE)
80873 ** The Table structure pTable is really a VIEW. Fill in the names of
80874 ** the columns of the view in the pTable structure. Return the number
80875 ** of errors. If an error is seen leave an error message in pParse->zErrMsg.
80877 SQLITE_PRIVATE int sqlite3ViewGetColumnNames(Parse *pParse, Table *pTable){
80878 Table *pSelTab; /* A fake table from which we get the result set */
80879 Select *pSel; /* Copy of the SELECT that implements the view */
80880 int nErr = 0; /* Number of errors encountered */
80881 int n; /* Temporarily holds the number of cursors assigned */
80882 sqlite3 *db = pParse->db; /* Database connection for malloc errors */
80883 int (*xAuth)(void*,int,const char*,const char*,const char*,const char*);
80885 assert( pTable );
80887 #ifndef SQLITE_OMIT_VIRTUALTABLE
80888 if( sqlite3VtabCallConnect(pParse, pTable) ){
80889 return SQLITE_ERROR;
80891 if( IsVirtual(pTable) ) return 0;
80892 #endif
80894 #ifndef SQLITE_OMIT_VIEW
80895 /* A positive nCol means the columns names for this view are
80896 ** already known.
80898 if( pTable->nCol>0 ) return 0;
80900 /* A negative nCol is a special marker meaning that we are currently
80901 ** trying to compute the column names. If we enter this routine with
80902 ** a negative nCol, it means two or more views form a loop, like this:
80904 ** CREATE VIEW one AS SELECT * FROM two;
80905 ** CREATE VIEW two AS SELECT * FROM one;
80907 ** Actually, the error above is now caught prior to reaching this point.
80908 ** But the following test is still important as it does come up
80909 ** in the following:
80911 ** CREATE TABLE main.ex1(a);
80912 ** CREATE TEMP VIEW ex1 AS SELECT a FROM ex1;
80913 ** SELECT * FROM temp.ex1;
80915 if( pTable->nCol<0 ){
80916 sqlite3ErrorMsg(pParse, "view %s is circularly defined", pTable->zName);
80917 return 1;
80919 assert( pTable->nCol>=0 );
80921 /* If we get this far, it means we need to compute the table names.
80922 ** Note that the call to sqlite3ResultSetOfSelect() will expand any
80923 ** "*" elements in the results set of the view and will assign cursors
80924 ** to the elements of the FROM clause. But we do not want these changes
80925 ** to be permanent. So the computation is done on a copy of the SELECT
80926 ** statement that defines the view.
80928 assert( pTable->pSelect );
80929 pSel = sqlite3SelectDup(db, pTable->pSelect, 0);
80930 if( pSel ){
80931 u8 enableLookaside = db->lookaside.bEnabled;
80932 n = pParse->nTab;
80933 sqlite3SrcListAssignCursors(pParse, pSel->pSrc);
80934 pTable->nCol = -1;
80935 db->lookaside.bEnabled = 0;
80936 #ifndef SQLITE_OMIT_AUTHORIZATION
80937 xAuth = db->xAuth;
80938 db->xAuth = 0;
80939 pSelTab = sqlite3ResultSetOfSelect(pParse, pSel);
80940 db->xAuth = xAuth;
80941 #else
80942 pSelTab = sqlite3ResultSetOfSelect(pParse, pSel);
80943 #endif
80944 db->lookaside.bEnabled = enableLookaside;
80945 pParse->nTab = n;
80946 if( pSelTab ){
80947 assert( pTable->aCol==0 );
80948 pTable->nCol = pSelTab->nCol;
80949 pTable->aCol = pSelTab->aCol;
80950 pSelTab->nCol = 0;
80951 pSelTab->aCol = 0;
80952 sqlite3DeleteTable(db, pSelTab);
80953 assert( sqlite3SchemaMutexHeld(db, 0, pTable->pSchema) );
80954 pTable->pSchema->flags |= DB_UnresetViews;
80955 }else{
80956 pTable->nCol = 0;
80957 nErr++;
80959 sqlite3SelectDelete(db, pSel);
80960 } else {
80961 nErr++;
80963 #endif /* SQLITE_OMIT_VIEW */
80964 return nErr;
80966 #endif /* !defined(SQLITE_OMIT_VIEW) || !defined(SQLITE_OMIT_VIRTUALTABLE) */
80968 #ifndef SQLITE_OMIT_VIEW
80970 ** Clear the column names from every VIEW in database idx.
80972 static void sqliteViewResetAll(sqlite3 *db, int idx){
80973 HashElem *i;
80974 assert( sqlite3SchemaMutexHeld(db, idx, 0) );
80975 if( !DbHasProperty(db, idx, DB_UnresetViews) ) return;
80976 for(i=sqliteHashFirst(&db->aDb[idx].pSchema->tblHash); i;i=sqliteHashNext(i)){
80977 Table *pTab = sqliteHashData(i);
80978 if( pTab->pSelect ){
80979 sqliteDeleteColumnNames(db, pTab);
80980 pTab->aCol = 0;
80981 pTab->nCol = 0;
80984 DbClearProperty(db, idx, DB_UnresetViews);
80986 #else
80987 # define sqliteViewResetAll(A,B)
80988 #endif /* SQLITE_OMIT_VIEW */
80991 ** This function is called by the VDBE to adjust the internal schema
80992 ** used by SQLite when the btree layer moves a table root page. The
80993 ** root-page of a table or index in database iDb has changed from iFrom
80994 ** to iTo.
80996 ** Ticket #1728: The symbol table might still contain information
80997 ** on tables and/or indices that are the process of being deleted.
80998 ** If you are unlucky, one of those deleted indices or tables might
80999 ** have the same rootpage number as the real table or index that is
81000 ** being moved. So we cannot stop searching after the first match
81001 ** because the first match might be for one of the deleted indices
81002 ** or tables and not the table/index that is actually being moved.
81003 ** We must continue looping until all tables and indices with
81004 ** rootpage==iFrom have been converted to have a rootpage of iTo
81005 ** in order to be certain that we got the right one.
81007 #ifndef SQLITE_OMIT_AUTOVACUUM
81008 SQLITE_PRIVATE void sqlite3RootPageMoved(sqlite3 *db, int iDb, int iFrom, int iTo){
81009 HashElem *pElem;
81010 Hash *pHash;
81011 Db *pDb;
81013 assert( sqlite3SchemaMutexHeld(db, iDb, 0) );
81014 pDb = &db->aDb[iDb];
81015 pHash = &pDb->pSchema->tblHash;
81016 for(pElem=sqliteHashFirst(pHash); pElem; pElem=sqliteHashNext(pElem)){
81017 Table *pTab = sqliteHashData(pElem);
81018 if( pTab->tnum==iFrom ){
81019 pTab->tnum = iTo;
81022 pHash = &pDb->pSchema->idxHash;
81023 for(pElem=sqliteHashFirst(pHash); pElem; pElem=sqliteHashNext(pElem)){
81024 Index *pIdx = sqliteHashData(pElem);
81025 if( pIdx->tnum==iFrom ){
81026 pIdx->tnum = iTo;
81030 #endif
81033 ** Write code to erase the table with root-page iTable from database iDb.
81034 ** Also write code to modify the sqlite_master table and internal schema
81035 ** if a root-page of another table is moved by the btree-layer whilst
81036 ** erasing iTable (this can happen with an auto-vacuum database).
81038 static void destroyRootPage(Parse *pParse, int iTable, int iDb){
81039 Vdbe *v = sqlite3GetVdbe(pParse);
81040 int r1 = sqlite3GetTempReg(pParse);
81041 sqlite3VdbeAddOp3(v, OP_Destroy, iTable, r1, iDb);
81042 sqlite3MayAbort(pParse);
81043 #ifndef SQLITE_OMIT_AUTOVACUUM
81044 /* OP_Destroy stores an in integer r1. If this integer
81045 ** is non-zero, then it is the root page number of a table moved to
81046 ** location iTable. The following code modifies the sqlite_master table to
81047 ** reflect this.
81049 ** The "#NNN" in the SQL is a special constant that means whatever value
81050 ** is in register NNN. See grammar rules associated with the TK_REGISTER
81051 ** token for additional information.
81053 sqlite3NestedParse(pParse,
81054 "UPDATE %Q.%s SET rootpage=%d WHERE #%d AND rootpage=#%d",
81055 pParse->db->aDb[iDb].zName, SCHEMA_TABLE(iDb), iTable, r1, r1);
81056 #endif
81057 sqlite3ReleaseTempReg(pParse, r1);
81061 ** Write VDBE code to erase table pTab and all associated indices on disk.
81062 ** Code to update the sqlite_master tables and internal schema definitions
81063 ** in case a root-page belonging to another table is moved by the btree layer
81064 ** is also added (this can happen with an auto-vacuum database).
81066 static void destroyTable(Parse *pParse, Table *pTab){
81067 #ifdef SQLITE_OMIT_AUTOVACUUM
81068 Index *pIdx;
81069 int iDb = sqlite3SchemaToIndex(pParse->db, pTab->pSchema);
81070 destroyRootPage(pParse, pTab->tnum, iDb);
81071 for(pIdx=pTab->pIndex; pIdx; pIdx=pIdx->pNext){
81072 destroyRootPage(pParse, pIdx->tnum, iDb);
81074 #else
81075 /* If the database may be auto-vacuum capable (if SQLITE_OMIT_AUTOVACUUM
81076 ** is not defined), then it is important to call OP_Destroy on the
81077 ** table and index root-pages in order, starting with the numerically
81078 ** largest root-page number. This guarantees that none of the root-pages
81079 ** to be destroyed is relocated by an earlier OP_Destroy. i.e. if the
81080 ** following were coded:
81082 ** OP_Destroy 4 0
81083 ** ...
81084 ** OP_Destroy 5 0
81086 ** and root page 5 happened to be the largest root-page number in the
81087 ** database, then root page 5 would be moved to page 4 by the
81088 ** "OP_Destroy 4 0" opcode. The subsequent "OP_Destroy 5 0" would hit
81089 ** a free-list page.
81091 int iTab = pTab->tnum;
81092 int iDestroyed = 0;
81094 while( 1 ){
81095 Index *pIdx;
81096 int iLargest = 0;
81098 if( iDestroyed==0 || iTab<iDestroyed ){
81099 iLargest = iTab;
81101 for(pIdx=pTab->pIndex; pIdx; pIdx=pIdx->pNext){
81102 int iIdx = pIdx->tnum;
81103 assert( pIdx->pSchema==pTab->pSchema );
81104 if( (iDestroyed==0 || (iIdx<iDestroyed)) && iIdx>iLargest ){
81105 iLargest = iIdx;
81108 if( iLargest==0 ){
81109 return;
81110 }else{
81111 int iDb = sqlite3SchemaToIndex(pParse->db, pTab->pSchema);
81112 destroyRootPage(pParse, iLargest, iDb);
81113 iDestroyed = iLargest;
81116 #endif
81120 ** Remove entries from the sqlite_stat1 and sqlite_stat2 tables
81121 ** after a DROP INDEX or DROP TABLE command.
81123 static void sqlite3ClearStatTables(
81124 Parse *pParse, /* The parsing context */
81125 int iDb, /* The database number */
81126 const char *zType, /* "idx" or "tbl" */
81127 const char *zName /* Name of index or table */
81129 static const char *azStatTab[] = { "sqlite_stat1", "sqlite_stat2" };
81130 int i;
81131 const char *zDbName = pParse->db->aDb[iDb].zName;
81132 for(i=0; i<ArraySize(azStatTab); i++){
81133 if( sqlite3FindTable(pParse->db, azStatTab[i], zDbName) ){
81134 sqlite3NestedParse(pParse,
81135 "DELETE FROM %Q.%s WHERE %s=%Q",
81136 zDbName, azStatTab[i], zType, zName
81143 ** This routine is called to do the work of a DROP TABLE statement.
81144 ** pName is the name of the table to be dropped.
81146 SQLITE_PRIVATE void sqlite3DropTable(Parse *pParse, SrcList *pName, int isView, int noErr){
81147 Table *pTab;
81148 Vdbe *v;
81149 sqlite3 *db = pParse->db;
81150 int iDb;
81152 if( db->mallocFailed ){
81153 goto exit_drop_table;
81155 assert( pParse->nErr==0 );
81156 assert( pName->nSrc==1 );
81157 if( noErr ) db->suppressErr++;
81158 pTab = sqlite3LocateTable(pParse, isView,
81159 pName->a[0].zName, pName->a[0].zDatabase);
81160 if( noErr ) db->suppressErr--;
81162 if( pTab==0 ){
81163 if( noErr ) sqlite3CodeVerifyNamedSchema(pParse, pName->a[0].zDatabase);
81164 goto exit_drop_table;
81166 iDb = sqlite3SchemaToIndex(db, pTab->pSchema);
81167 assert( iDb>=0 && iDb<db->nDb );
81169 /* If pTab is a virtual table, call ViewGetColumnNames() to ensure
81170 ** it is initialized.
81172 if( IsVirtual(pTab) && sqlite3ViewGetColumnNames(pParse, pTab) ){
81173 goto exit_drop_table;
81175 #ifndef SQLITE_OMIT_AUTHORIZATION
81177 int code;
81178 const char *zTab = SCHEMA_TABLE(iDb);
81179 const char *zDb = db->aDb[iDb].zName;
81180 const char *zArg2 = 0;
81181 if( sqlite3AuthCheck(pParse, SQLITE_DELETE, zTab, 0, zDb)){
81182 goto exit_drop_table;
81184 if( isView ){
81185 if( !OMIT_TEMPDB && iDb==1 ){
81186 code = SQLITE_DROP_TEMP_VIEW;
81187 }else{
81188 code = SQLITE_DROP_VIEW;
81190 #ifndef SQLITE_OMIT_VIRTUALTABLE
81191 }else if( IsVirtual(pTab) ){
81192 code = SQLITE_DROP_VTABLE;
81193 zArg2 = sqlite3GetVTable(db, pTab)->pMod->zName;
81194 #endif
81195 }else{
81196 if( !OMIT_TEMPDB && iDb==1 ){
81197 code = SQLITE_DROP_TEMP_TABLE;
81198 }else{
81199 code = SQLITE_DROP_TABLE;
81202 if( sqlite3AuthCheck(pParse, code, pTab->zName, zArg2, zDb) ){
81203 goto exit_drop_table;
81205 if( sqlite3AuthCheck(pParse, SQLITE_DELETE, pTab->zName, 0, zDb) ){
81206 goto exit_drop_table;
81209 #endif
81210 if( sqlite3StrNICmp(pTab->zName, "sqlite_", 7)==0 ){
81211 sqlite3ErrorMsg(pParse, "table %s may not be dropped", pTab->zName);
81212 goto exit_drop_table;
81215 #ifndef SQLITE_OMIT_VIEW
81216 /* Ensure DROP TABLE is not used on a view, and DROP VIEW is not used
81217 ** on a table.
81219 if( isView && pTab->pSelect==0 ){
81220 sqlite3ErrorMsg(pParse, "use DROP TABLE to delete table %s", pTab->zName);
81221 goto exit_drop_table;
81223 if( !isView && pTab->pSelect ){
81224 sqlite3ErrorMsg(pParse, "use DROP VIEW to delete view %s", pTab->zName);
81225 goto exit_drop_table;
81227 #endif
81229 /* Generate code to remove the table from the master table
81230 ** on disk.
81232 v = sqlite3GetVdbe(pParse);
81233 if( v ){
81234 Trigger *pTrigger;
81235 Db *pDb = &db->aDb[iDb];
81236 sqlite3BeginWriteOperation(pParse, 1, iDb);
81238 #ifndef SQLITE_OMIT_VIRTUALTABLE
81239 if( IsVirtual(pTab) ){
81240 sqlite3VdbeAddOp0(v, OP_VBegin);
81242 #endif
81243 sqlite3FkDropTable(pParse, pName, pTab);
81245 /* Drop all triggers associated with the table being dropped. Code
81246 ** is generated to remove entries from sqlite_master and/or
81247 ** sqlite_temp_master if required.
81249 pTrigger = sqlite3TriggerList(pParse, pTab);
81250 while( pTrigger ){
81251 assert( pTrigger->pSchema==pTab->pSchema ||
81252 pTrigger->pSchema==db->aDb[1].pSchema );
81253 sqlite3DropTriggerPtr(pParse, pTrigger);
81254 pTrigger = pTrigger->pNext;
81257 #ifndef SQLITE_OMIT_AUTOINCREMENT
81258 /* Remove any entries of the sqlite_sequence table associated with
81259 ** the table being dropped. This is done before the table is dropped
81260 ** at the btree level, in case the sqlite_sequence table needs to
81261 ** move as a result of the drop (can happen in auto-vacuum mode).
81263 if( pTab->tabFlags & TF_Autoincrement ){
81264 sqlite3NestedParse(pParse,
81265 "DELETE FROM %s.sqlite_sequence WHERE name=%Q",
81266 pDb->zName, pTab->zName
81269 #endif
81271 /* Drop all SQLITE_MASTER table and index entries that refer to the
81272 ** table. The program name loops through the master table and deletes
81273 ** every row that refers to a table of the same name as the one being
81274 ** dropped. Triggers are handled seperately because a trigger can be
81275 ** created in the temp database that refers to a table in another
81276 ** database.
81278 sqlite3NestedParse(pParse,
81279 "DELETE FROM %Q.%s WHERE tbl_name=%Q and type!='trigger'",
81280 pDb->zName, SCHEMA_TABLE(iDb), pTab->zName);
81281 sqlite3ClearStatTables(pParse, iDb, "tbl", pTab->zName);
81282 if( !isView && !IsVirtual(pTab) ){
81283 destroyTable(pParse, pTab);
81286 /* Remove the table entry from SQLite's internal schema and modify
81287 ** the schema cookie.
81289 if( IsVirtual(pTab) ){
81290 sqlite3VdbeAddOp4(v, OP_VDestroy, iDb, 0, 0, pTab->zName, 0);
81292 sqlite3VdbeAddOp4(v, OP_DropTable, iDb, 0, 0, pTab->zName, 0);
81293 sqlite3ChangeCookie(pParse, iDb);
81295 sqliteViewResetAll(db, iDb);
81297 exit_drop_table:
81298 sqlite3SrcListDelete(db, pName);
81302 ** This routine is called to create a new foreign key on the table
81303 ** currently under construction. pFromCol determines which columns
81304 ** in the current table point to the foreign key. If pFromCol==0 then
81305 ** connect the key to the last column inserted. pTo is the name of
81306 ** the table referred to. pToCol is a list of tables in the other
81307 ** pTo table that the foreign key points to. flags contains all
81308 ** information about the conflict resolution algorithms specified
81309 ** in the ON DELETE, ON UPDATE and ON INSERT clauses.
81311 ** An FKey structure is created and added to the table currently
81312 ** under construction in the pParse->pNewTable field.
81314 ** The foreign key is set for IMMEDIATE processing. A subsequent call
81315 ** to sqlite3DeferForeignKey() might change this to DEFERRED.
81317 SQLITE_PRIVATE void sqlite3CreateForeignKey(
81318 Parse *pParse, /* Parsing context */
81319 ExprList *pFromCol, /* Columns in this table that point to other table */
81320 Token *pTo, /* Name of the other table */
81321 ExprList *pToCol, /* Columns in the other table */
81322 int flags /* Conflict resolution algorithms. */
81324 sqlite3 *db = pParse->db;
81325 #ifndef SQLITE_OMIT_FOREIGN_KEY
81326 FKey *pFKey = 0;
81327 FKey *pNextTo;
81328 Table *p = pParse->pNewTable;
81329 int nByte;
81330 int i;
81331 int nCol;
81332 char *z;
81334 assert( pTo!=0 );
81335 if( p==0 || IN_DECLARE_VTAB ) goto fk_end;
81336 if( pFromCol==0 ){
81337 int iCol = p->nCol-1;
81338 if( NEVER(iCol<0) ) goto fk_end;
81339 if( pToCol && pToCol->nExpr!=1 ){
81340 sqlite3ErrorMsg(pParse, "foreign key on %s"
81341 " should reference only one column of table %T",
81342 p->aCol[iCol].zName, pTo);
81343 goto fk_end;
81345 nCol = 1;
81346 }else if( pToCol && pToCol->nExpr!=pFromCol->nExpr ){
81347 sqlite3ErrorMsg(pParse,
81348 "number of columns in foreign key does not match the number of "
81349 "columns in the referenced table");
81350 goto fk_end;
81351 }else{
81352 nCol = pFromCol->nExpr;
81354 nByte = sizeof(*pFKey) + (nCol-1)*sizeof(pFKey->aCol[0]) + pTo->n + 1;
81355 if( pToCol ){
81356 for(i=0; i<pToCol->nExpr; i++){
81357 nByte += sqlite3Strlen30(pToCol->a[i].zName) + 1;
81360 pFKey = sqlite3DbMallocZero(db, nByte );
81361 if( pFKey==0 ){
81362 goto fk_end;
81364 pFKey->pFrom = p;
81365 pFKey->pNextFrom = p->pFKey;
81366 z = (char*)&pFKey->aCol[nCol];
81367 pFKey->zTo = z;
81368 memcpy(z, pTo->z, pTo->n);
81369 z[pTo->n] = 0;
81370 sqlite3Dequote(z);
81371 z += pTo->n+1;
81372 pFKey->nCol = nCol;
81373 if( pFromCol==0 ){
81374 pFKey->aCol[0].iFrom = p->nCol-1;
81375 }else{
81376 for(i=0; i<nCol; i++){
81377 int j;
81378 for(j=0; j<p->nCol; j++){
81379 if( sqlite3StrICmp(p->aCol[j].zName, pFromCol->a[i].zName)==0 ){
81380 pFKey->aCol[i].iFrom = j;
81381 break;
81384 if( j>=p->nCol ){
81385 sqlite3ErrorMsg(pParse,
81386 "unknown column \"%s\" in foreign key definition",
81387 pFromCol->a[i].zName);
81388 goto fk_end;
81392 if( pToCol ){
81393 for(i=0; i<nCol; i++){
81394 int n = sqlite3Strlen30(pToCol->a[i].zName);
81395 pFKey->aCol[i].zCol = z;
81396 memcpy(z, pToCol->a[i].zName, n);
81397 z[n] = 0;
81398 z += n+1;
81401 pFKey->isDeferred = 0;
81402 pFKey->aAction[0] = (u8)(flags & 0xff); /* ON DELETE action */
81403 pFKey->aAction[1] = (u8)((flags >> 8 ) & 0xff); /* ON UPDATE action */
81405 assert( sqlite3SchemaMutexHeld(db, 0, p->pSchema) );
81406 pNextTo = (FKey *)sqlite3HashInsert(&p->pSchema->fkeyHash,
81407 pFKey->zTo, sqlite3Strlen30(pFKey->zTo), (void *)pFKey
81409 if( pNextTo==pFKey ){
81410 db->mallocFailed = 1;
81411 goto fk_end;
81413 if( pNextTo ){
81414 assert( pNextTo->pPrevTo==0 );
81415 pFKey->pNextTo = pNextTo;
81416 pNextTo->pPrevTo = pFKey;
81419 /* Link the foreign key to the table as the last step.
81421 p->pFKey = pFKey;
81422 pFKey = 0;
81424 fk_end:
81425 sqlite3DbFree(db, pFKey);
81426 #endif /* !defined(SQLITE_OMIT_FOREIGN_KEY) */
81427 sqlite3ExprListDelete(db, pFromCol);
81428 sqlite3ExprListDelete(db, pToCol);
81432 ** This routine is called when an INITIALLY IMMEDIATE or INITIALLY DEFERRED
81433 ** clause is seen as part of a foreign key definition. The isDeferred
81434 ** parameter is 1 for INITIALLY DEFERRED and 0 for INITIALLY IMMEDIATE.
81435 ** The behavior of the most recently created foreign key is adjusted
81436 ** accordingly.
81438 SQLITE_PRIVATE void sqlite3DeferForeignKey(Parse *pParse, int isDeferred){
81439 #ifndef SQLITE_OMIT_FOREIGN_KEY
81440 Table *pTab;
81441 FKey *pFKey;
81442 if( (pTab = pParse->pNewTable)==0 || (pFKey = pTab->pFKey)==0 ) return;
81443 assert( isDeferred==0 || isDeferred==1 ); /* EV: R-30323-21917 */
81444 pFKey->isDeferred = (u8)isDeferred;
81445 #endif
81449 ** Generate code that will erase and refill index *pIdx. This is
81450 ** used to initialize a newly created index or to recompute the
81451 ** content of an index in response to a REINDEX command.
81453 ** if memRootPage is not negative, it means that the index is newly
81454 ** created. The register specified by memRootPage contains the
81455 ** root page number of the index. If memRootPage is negative, then
81456 ** the index already exists and must be cleared before being refilled and
81457 ** the root page number of the index is taken from pIndex->tnum.
81459 static void sqlite3RefillIndex(Parse *pParse, Index *pIndex, int memRootPage){
81460 Table *pTab = pIndex->pTable; /* The table that is indexed */
81461 int iTab = pParse->nTab++; /* Btree cursor used for pTab */
81462 int iIdx = pParse->nTab++; /* Btree cursor used for pIndex */
81463 int iSorter = iTab; /* Cursor opened by OpenSorter (if in use) */
81464 int addr1; /* Address of top of loop */
81465 int addr2; /* Address to jump to for next iteration */
81466 int tnum; /* Root page of index */
81467 Vdbe *v; /* Generate code into this virtual machine */
81468 KeyInfo *pKey; /* KeyInfo for index */
81469 int regIdxKey; /* Registers containing the index key */
81470 int regRecord; /* Register holding assemblied index record */
81471 sqlite3 *db = pParse->db; /* The database connection */
81472 int iDb = sqlite3SchemaToIndex(db, pIndex->pSchema);
81474 #ifndef SQLITE_OMIT_AUTHORIZATION
81475 if( sqlite3AuthCheck(pParse, SQLITE_REINDEX, pIndex->zName, 0,
81476 db->aDb[iDb].zName ) ){
81477 return;
81479 #endif
81481 /* Require a write-lock on the table to perform this operation */
81482 sqlite3TableLock(pParse, iDb, pTab->tnum, 1, pTab->zName);
81484 v = sqlite3GetVdbe(pParse);
81485 if( v==0 ) return;
81486 if( memRootPage>=0 ){
81487 tnum = memRootPage;
81488 }else{
81489 tnum = pIndex->tnum;
81490 sqlite3VdbeAddOp2(v, OP_Clear, tnum, iDb);
81492 pKey = sqlite3IndexKeyinfo(pParse, pIndex);
81493 sqlite3VdbeAddOp4(v, OP_OpenWrite, iIdx, tnum, iDb,
81494 (char *)pKey, P4_KEYINFO_HANDOFF);
81495 if( memRootPage>=0 ){
81496 sqlite3VdbeChangeP5(v, 1);
81499 #ifndef SQLITE_OMIT_MERGE_SORT
81500 /* Open the sorter cursor if we are to use one. */
81501 iSorter = pParse->nTab++;
81502 sqlite3VdbeAddOp4(v, OP_SorterOpen, iSorter, 0, 0, (char*)pKey, P4_KEYINFO);
81503 #endif
81505 /* Open the table. Loop through all rows of the table, inserting index
81506 ** records into the sorter. */
81507 sqlite3OpenTable(pParse, iTab, iDb, pTab, OP_OpenRead);
81508 addr1 = sqlite3VdbeAddOp2(v, OP_Rewind, iTab, 0);
81509 addr2 = addr1 + 1;
81510 regRecord = sqlite3GetTempReg(pParse);
81511 regIdxKey = sqlite3GenerateIndexKey(pParse, pIndex, iTab, regRecord, 1);
81513 #ifndef SQLITE_OMIT_MERGE_SORT
81514 sqlite3VdbeAddOp2(v, OP_SorterInsert, iSorter, regRecord);
81515 sqlite3VdbeAddOp2(v, OP_Next, iTab, addr1+1);
81516 sqlite3VdbeJumpHere(v, addr1);
81517 addr1 = sqlite3VdbeAddOp2(v, OP_SorterSort, iSorter, 0);
81518 if( pIndex->onError!=OE_None ){
81519 int j2 = sqlite3VdbeCurrentAddr(v) + 3;
81520 sqlite3VdbeAddOp2(v, OP_Goto, 0, j2);
81521 addr2 = sqlite3VdbeCurrentAddr(v);
81522 sqlite3VdbeAddOp3(v, OP_SorterCompare, iSorter, j2, regRecord);
81523 sqlite3HaltConstraint(
81524 pParse, OE_Abort, "indexed columns are not unique", P4_STATIC
81526 }else{
81527 addr2 = sqlite3VdbeCurrentAddr(v);
81529 sqlite3VdbeAddOp2(v, OP_SorterData, iSorter, regRecord);
81530 sqlite3VdbeAddOp3(v, OP_IdxInsert, iIdx, regRecord, 1);
81531 sqlite3VdbeChangeP5(v, OPFLAG_USESEEKRESULT);
81532 #else
81533 if( pIndex->onError!=OE_None ){
81534 const int regRowid = regIdxKey + pIndex->nColumn;
81535 const int j2 = sqlite3VdbeCurrentAddr(v) + 2;
81536 void * const pRegKey = SQLITE_INT_TO_PTR(regIdxKey);
81538 /* The registers accessed by the OP_IsUnique opcode were allocated
81539 ** using sqlite3GetTempRange() inside of the sqlite3GenerateIndexKey()
81540 ** call above. Just before that function was freed they were released
81541 ** (made available to the compiler for reuse) using
81542 ** sqlite3ReleaseTempRange(). So in some ways having the OP_IsUnique
81543 ** opcode use the values stored within seems dangerous. However, since
81544 ** we can be sure that no other temp registers have been allocated
81545 ** since sqlite3ReleaseTempRange() was called, it is safe to do so.
81547 sqlite3VdbeAddOp4(v, OP_IsUnique, iIdx, j2, regRowid, pRegKey, P4_INT32);
81548 sqlite3HaltConstraint(
81549 pParse, OE_Abort, "indexed columns are not unique", P4_STATIC);
81551 sqlite3VdbeAddOp3(v, OP_IdxInsert, iIdx, regRecord, 0);
81552 sqlite3VdbeChangeP5(v, OPFLAG_USESEEKRESULT);
81553 #endif
81554 sqlite3ReleaseTempReg(pParse, regRecord);
81555 sqlite3VdbeAddOp2(v, OP_SorterNext, iSorter, addr2);
81556 sqlite3VdbeJumpHere(v, addr1);
81558 sqlite3VdbeAddOp1(v, OP_Close, iTab);
81559 sqlite3VdbeAddOp1(v, OP_Close, iIdx);
81560 sqlite3VdbeAddOp1(v, OP_Close, iSorter);
81564 ** Create a new index for an SQL table. pName1.pName2 is the name of the index
81565 ** and pTblList is the name of the table that is to be indexed. Both will
81566 ** be NULL for a primary key or an index that is created to satisfy a
81567 ** UNIQUE constraint. If pTable and pIndex are NULL, use pParse->pNewTable
81568 ** as the table to be indexed. pParse->pNewTable is a table that is
81569 ** currently being constructed by a CREATE TABLE statement.
81571 ** pList is a list of columns to be indexed. pList will be NULL if this
81572 ** is a primary key or unique-constraint on the most recent column added
81573 ** to the table currently under construction.
81575 ** If the index is created successfully, return a pointer to the new Index
81576 ** structure. This is used by sqlite3AddPrimaryKey() to mark the index
81577 ** as the tables primary key (Index.autoIndex==2).
81579 SQLITE_PRIVATE Index *sqlite3CreateIndex(
81580 Parse *pParse, /* All information about this parse */
81581 Token *pName1, /* First part of index name. May be NULL */
81582 Token *pName2, /* Second part of index name. May be NULL */
81583 SrcList *pTblName, /* Table to index. Use pParse->pNewTable if 0 */
81584 ExprList *pList, /* A list of columns to be indexed */
81585 int onError, /* OE_Abort, OE_Ignore, OE_Replace, or OE_None */
81586 Token *pStart, /* The CREATE token that begins this statement */
81587 Token *pEnd, /* The ")" that closes the CREATE INDEX statement */
81588 int sortOrder, /* Sort order of primary key when pList==NULL */
81589 int ifNotExist /* Omit error if index already exists */
81591 Index *pRet = 0; /* Pointer to return */
81592 Table *pTab = 0; /* Table to be indexed */
81593 Index *pIndex = 0; /* The index to be created */
81594 char *zName = 0; /* Name of the index */
81595 int nName; /* Number of characters in zName */
81596 int i, j;
81597 Token nullId; /* Fake token for an empty ID list */
81598 DbFixer sFix; /* For assigning database names to pTable */
81599 int sortOrderMask; /* 1 to honor DESC in index. 0 to ignore. */
81600 sqlite3 *db = pParse->db;
81601 Db *pDb; /* The specific table containing the indexed database */
81602 int iDb; /* Index of the database that is being written */
81603 Token *pName = 0; /* Unqualified name of the index to create */
81604 struct ExprList_item *pListItem; /* For looping over pList */
81605 int nCol;
81606 int nExtra = 0;
81607 char *zExtra;
81609 assert( pStart==0 || pEnd!=0 ); /* pEnd must be non-NULL if pStart is */
81610 assert( pParse->nErr==0 ); /* Never called with prior errors */
81611 if( db->mallocFailed || IN_DECLARE_VTAB ){
81612 goto exit_create_index;
81614 if( SQLITE_OK!=sqlite3ReadSchema(pParse) ){
81615 goto exit_create_index;
81619 ** Find the table that is to be indexed. Return early if not found.
81621 if( pTblName!=0 ){
81623 /* Use the two-part index name to determine the database
81624 ** to search for the table. 'Fix' the table name to this db
81625 ** before looking up the table.
81627 assert( pName1 && pName2 );
81628 iDb = sqlite3TwoPartName(pParse, pName1, pName2, &pName);
81629 if( iDb<0 ) goto exit_create_index;
81631 #ifndef SQLITE_OMIT_TEMPDB
81632 /* If the index name was unqualified, check if the the table
81633 ** is a temp table. If so, set the database to 1. Do not do this
81634 ** if initialising a database schema.
81636 if( !db->init.busy ){
81637 pTab = sqlite3SrcListLookup(pParse, pTblName);
81638 if( pName2->n==0 && pTab && pTab->pSchema==db->aDb[1].pSchema ){
81639 iDb = 1;
81642 #endif
81644 if( sqlite3FixInit(&sFix, pParse, iDb, "index", pName) &&
81645 sqlite3FixSrcList(&sFix, pTblName)
81647 /* Because the parser constructs pTblName from a single identifier,
81648 ** sqlite3FixSrcList can never fail. */
81649 assert(0);
81651 pTab = sqlite3LocateTable(pParse, 0, pTblName->a[0].zName,
81652 pTblName->a[0].zDatabase);
81653 if( !pTab || db->mallocFailed ) goto exit_create_index;
81654 assert( db->aDb[iDb].pSchema==pTab->pSchema );
81655 }else{
81656 assert( pName==0 );
81657 pTab = pParse->pNewTable;
81658 if( !pTab ) goto exit_create_index;
81659 iDb = sqlite3SchemaToIndex(db, pTab->pSchema);
81661 pDb = &db->aDb[iDb];
81663 assert( pTab!=0 );
81664 assert( pParse->nErr==0 );
81665 if( sqlite3StrNICmp(pTab->zName, "sqlite_", 7)==0
81666 && memcmp(&pTab->zName[7],"altertab_",9)!=0 ){
81667 sqlite3ErrorMsg(pParse, "table %s may not be indexed", pTab->zName);
81668 goto exit_create_index;
81670 #ifndef SQLITE_OMIT_VIEW
81671 if( pTab->pSelect ){
81672 sqlite3ErrorMsg(pParse, "views may not be indexed");
81673 goto exit_create_index;
81675 #endif
81676 #ifndef SQLITE_OMIT_VIRTUALTABLE
81677 if( IsVirtual(pTab) ){
81678 sqlite3ErrorMsg(pParse, "virtual tables may not be indexed");
81679 goto exit_create_index;
81681 #endif
81684 ** Find the name of the index. Make sure there is not already another
81685 ** index or table with the same name.
81687 ** Exception: If we are reading the names of permanent indices from the
81688 ** sqlite_master table (because some other process changed the schema) and
81689 ** one of the index names collides with the name of a temporary table or
81690 ** index, then we will continue to process this index.
81692 ** If pName==0 it means that we are
81693 ** dealing with a primary key or UNIQUE constraint. We have to invent our
81694 ** own name.
81696 if( pName ){
81697 zName = sqlite3NameFromToken(db, pName);
81698 if( zName==0 ) goto exit_create_index;
81699 if( SQLITE_OK!=sqlite3CheckObjectName(pParse, zName) ){
81700 goto exit_create_index;
81702 if( !db->init.busy ){
81703 if( sqlite3FindTable(db, zName, 0)!=0 ){
81704 sqlite3ErrorMsg(pParse, "there is already a table named %s", zName);
81705 goto exit_create_index;
81708 if( sqlite3FindIndex(db, zName, pDb->zName)!=0 ){
81709 if( !ifNotExist ){
81710 sqlite3ErrorMsg(pParse, "index %s already exists", zName);
81711 }else{
81712 assert( !db->init.busy );
81713 sqlite3CodeVerifySchema(pParse, iDb);
81715 goto exit_create_index;
81717 }else{
81718 int n;
81719 Index *pLoop;
81720 for(pLoop=pTab->pIndex, n=1; pLoop; pLoop=pLoop->pNext, n++){}
81721 zName = sqlite3MPrintf(db, "sqlite_autoindex_%s_%d", pTab->zName, n);
81722 if( zName==0 ){
81723 goto exit_create_index;
81727 /* Check for authorization to create an index.
81729 #ifndef SQLITE_OMIT_AUTHORIZATION
81731 const char *zDb = pDb->zName;
81732 if( sqlite3AuthCheck(pParse, SQLITE_INSERT, SCHEMA_TABLE(iDb), 0, zDb) ){
81733 goto exit_create_index;
81735 i = SQLITE_CREATE_INDEX;
81736 if( !OMIT_TEMPDB && iDb==1 ) i = SQLITE_CREATE_TEMP_INDEX;
81737 if( sqlite3AuthCheck(pParse, i, zName, pTab->zName, zDb) ){
81738 goto exit_create_index;
81741 #endif
81743 /* If pList==0, it means this routine was called to make a primary
81744 ** key out of the last column added to the table under construction.
81745 ** So create a fake list to simulate this.
81747 if( pList==0 ){
81748 nullId.z = pTab->aCol[pTab->nCol-1].zName;
81749 nullId.n = sqlite3Strlen30((char*)nullId.z);
81750 pList = sqlite3ExprListAppend(pParse, 0, 0);
81751 if( pList==0 ) goto exit_create_index;
81752 sqlite3ExprListSetName(pParse, pList, &nullId, 0);
81753 pList->a[0].sortOrder = (u8)sortOrder;
81756 /* Figure out how many bytes of space are required to store explicitly
81757 ** specified collation sequence names.
81759 for(i=0; i<pList->nExpr; i++){
81760 Expr *pExpr = pList->a[i].pExpr;
81761 if( pExpr ){
81762 CollSeq *pColl = pExpr->pColl;
81763 /* Either pColl!=0 or there was an OOM failure. But if an OOM
81764 ** failure we have quit before reaching this point. */
81765 if( ALWAYS(pColl) ){
81766 nExtra += (1 + sqlite3Strlen30(pColl->zName));
81772 ** Allocate the index structure.
81774 nName = sqlite3Strlen30(zName);
81775 nCol = pList->nExpr;
81776 pIndex = sqlite3DbMallocZero(db,
81777 sizeof(Index) + /* Index structure */
81778 sizeof(int)*nCol + /* Index.aiColumn */
81779 sizeof(int)*(nCol+1) + /* Index.aiRowEst */
81780 sizeof(char *)*nCol + /* Index.azColl */
81781 sizeof(u8)*nCol + /* Index.aSortOrder */
81782 nName + 1 + /* Index.zName */
81783 nExtra /* Collation sequence names */
81785 if( db->mallocFailed ){
81786 goto exit_create_index;
81788 pIndex->azColl = (char**)(&pIndex[1]);
81789 pIndex->aiColumn = (int *)(&pIndex->azColl[nCol]);
81790 pIndex->aiRowEst = (unsigned *)(&pIndex->aiColumn[nCol]);
81791 pIndex->aSortOrder = (u8 *)(&pIndex->aiRowEst[nCol+1]);
81792 pIndex->zName = (char *)(&pIndex->aSortOrder[nCol]);
81793 zExtra = (char *)(&pIndex->zName[nName+1]);
81794 memcpy(pIndex->zName, zName, nName+1);
81795 pIndex->pTable = pTab;
81796 pIndex->nColumn = pList->nExpr;
81797 pIndex->onError = (u8)onError;
81798 pIndex->autoIndex = (u8)(pName==0);
81799 pIndex->pSchema = db->aDb[iDb].pSchema;
81800 assert( sqlite3SchemaMutexHeld(db, iDb, 0) );
81802 /* Check to see if we should honor DESC requests on index columns
81804 if( pDb->pSchema->file_format>=4 ){
81805 sortOrderMask = -1; /* Honor DESC */
81806 }else{
81807 sortOrderMask = 0; /* Ignore DESC */
81810 /* Scan the names of the columns of the table to be indexed and
81811 ** load the column indices into the Index structure. Report an error
81812 ** if any column is not found.
81814 ** TODO: Add a test to make sure that the same column is not named
81815 ** more than once within the same index. Only the first instance of
81816 ** the column will ever be used by the optimizer. Note that using the
81817 ** same column more than once cannot be an error because that would
81818 ** break backwards compatibility - it needs to be a warning.
81820 for(i=0, pListItem=pList->a; i<pList->nExpr; i++, pListItem++){
81821 const char *zColName = pListItem->zName;
81822 Column *pTabCol;
81823 int requestedSortOrder;
81824 char *zColl; /* Collation sequence name */
81826 for(j=0, pTabCol=pTab->aCol; j<pTab->nCol; j++, pTabCol++){
81827 if( sqlite3StrICmp(zColName, pTabCol->zName)==0 ) break;
81829 if( j>=pTab->nCol ){
81830 sqlite3ErrorMsg(pParse, "table %s has no column named %s",
81831 pTab->zName, zColName);
81832 pParse->checkSchema = 1;
81833 goto exit_create_index;
81835 pIndex->aiColumn[i] = j;
81836 /* Justification of the ALWAYS(pListItem->pExpr->pColl): Because of
81837 ** the way the "idxlist" non-terminal is constructed by the parser,
81838 ** if pListItem->pExpr is not null then either pListItem->pExpr->pColl
81839 ** must exist or else there must have been an OOM error. But if there
81840 ** was an OOM error, we would never reach this point. */
81841 if( pListItem->pExpr && ALWAYS(pListItem->pExpr->pColl) ){
81842 int nColl;
81843 zColl = pListItem->pExpr->pColl->zName;
81844 nColl = sqlite3Strlen30(zColl) + 1;
81845 assert( nExtra>=nColl );
81846 memcpy(zExtra, zColl, nColl);
81847 zColl = zExtra;
81848 zExtra += nColl;
81849 nExtra -= nColl;
81850 }else{
81851 zColl = pTab->aCol[j].zColl;
81852 if( !zColl ){
81853 zColl = db->pDfltColl->zName;
81856 if( !db->init.busy && !sqlite3LocateCollSeq(pParse, zColl) ){
81857 goto exit_create_index;
81859 pIndex->azColl[i] = zColl;
81860 requestedSortOrder = pListItem->sortOrder & sortOrderMask;
81861 pIndex->aSortOrder[i] = (u8)requestedSortOrder;
81863 sqlite3DefaultRowEst(pIndex);
81865 if( pTab==pParse->pNewTable ){
81866 /* This routine has been called to create an automatic index as a
81867 ** result of a PRIMARY KEY or UNIQUE clause on a column definition, or
81868 ** a PRIMARY KEY or UNIQUE clause following the column definitions.
81869 ** i.e. one of:
81871 ** CREATE TABLE t(x PRIMARY KEY, y);
81872 ** CREATE TABLE t(x, y, UNIQUE(x, y));
81874 ** Either way, check to see if the table already has such an index. If
81875 ** so, don't bother creating this one. This only applies to
81876 ** automatically created indices. Users can do as they wish with
81877 ** explicit indices.
81879 ** Two UNIQUE or PRIMARY KEY constraints are considered equivalent
81880 ** (and thus suppressing the second one) even if they have different
81881 ** sort orders.
81883 ** If there are different collating sequences or if the columns of
81884 ** the constraint occur in different orders, then the constraints are
81885 ** considered distinct and both result in separate indices.
81887 Index *pIdx;
81888 for(pIdx=pTab->pIndex; pIdx; pIdx=pIdx->pNext){
81889 int k;
81890 assert( pIdx->onError!=OE_None );
81891 assert( pIdx->autoIndex );
81892 assert( pIndex->onError!=OE_None );
81894 if( pIdx->nColumn!=pIndex->nColumn ) continue;
81895 for(k=0; k<pIdx->nColumn; k++){
81896 const char *z1;
81897 const char *z2;
81898 if( pIdx->aiColumn[k]!=pIndex->aiColumn[k] ) break;
81899 z1 = pIdx->azColl[k];
81900 z2 = pIndex->azColl[k];
81901 if( z1!=z2 && sqlite3StrICmp(z1, z2) ) break;
81903 if( k==pIdx->nColumn ){
81904 if( pIdx->onError!=pIndex->onError ){
81905 /* This constraint creates the same index as a previous
81906 ** constraint specified somewhere in the CREATE TABLE statement.
81907 ** However the ON CONFLICT clauses are different. If both this
81908 ** constraint and the previous equivalent constraint have explicit
81909 ** ON CONFLICT clauses this is an error. Otherwise, use the
81910 ** explicitly specified behaviour for the index.
81912 if( !(pIdx->onError==OE_Default || pIndex->onError==OE_Default) ){
81913 sqlite3ErrorMsg(pParse,
81914 "conflicting ON CONFLICT clauses specified", 0);
81916 if( pIdx->onError==OE_Default ){
81917 pIdx->onError = pIndex->onError;
81920 goto exit_create_index;
81925 /* Link the new Index structure to its table and to the other
81926 ** in-memory database structures.
81928 if( db->init.busy ){
81929 Index *p;
81930 assert( sqlite3SchemaMutexHeld(db, 0, pIndex->pSchema) );
81931 p = sqlite3HashInsert(&pIndex->pSchema->idxHash,
81932 pIndex->zName, sqlite3Strlen30(pIndex->zName),
81933 pIndex);
81934 if( p ){
81935 assert( p==pIndex ); /* Malloc must have failed */
81936 db->mallocFailed = 1;
81937 goto exit_create_index;
81939 db->flags |= SQLITE_InternChanges;
81940 if( pTblName!=0 ){
81941 pIndex->tnum = db->init.newTnum;
81945 /* If the db->init.busy is 0 then create the index on disk. This
81946 ** involves writing the index into the master table and filling in the
81947 ** index with the current table contents.
81949 ** The db->init.busy is 0 when the user first enters a CREATE INDEX
81950 ** command. db->init.busy is 1 when a database is opened and
81951 ** CREATE INDEX statements are read out of the master table. In
81952 ** the latter case the index already exists on disk, which is why
81953 ** we don't want to recreate it.
81955 ** If pTblName==0 it means this index is generated as a primary key
81956 ** or UNIQUE constraint of a CREATE TABLE statement. Since the table
81957 ** has just been created, it contains no data and the index initialization
81958 ** step can be skipped.
81960 else{ /* if( db->init.busy==0 ) */
81961 Vdbe *v;
81962 char *zStmt;
81963 int iMem = ++pParse->nMem;
81965 v = sqlite3GetVdbe(pParse);
81966 if( v==0 ) goto exit_create_index;
81969 /* Create the rootpage for the index
81971 sqlite3BeginWriteOperation(pParse, 1, iDb);
81972 sqlite3VdbeAddOp2(v, OP_CreateIndex, iDb, iMem);
81974 /* Gather the complete text of the CREATE INDEX statement into
81975 ** the zStmt variable
81977 if( pStart ){
81978 assert( pEnd!=0 );
81979 /* A named index with an explicit CREATE INDEX statement */
81980 zStmt = sqlite3MPrintf(db, "CREATE%s INDEX %.*s",
81981 onError==OE_None ? "" : " UNIQUE",
81982 (int)(pEnd->z - pName->z) + 1,
81983 pName->z);
81984 }else{
81985 /* An automatic index created by a PRIMARY KEY or UNIQUE constraint */
81986 /* zStmt = sqlite3MPrintf(""); */
81987 zStmt = 0;
81990 /* Add an entry in sqlite_master for this index
81992 sqlite3NestedParse(pParse,
81993 "INSERT INTO %Q.%s VALUES('index',%Q,%Q,#%d,%Q);",
81994 db->aDb[iDb].zName, SCHEMA_TABLE(iDb),
81995 pIndex->zName,
81996 pTab->zName,
81997 iMem,
81998 zStmt
82000 sqlite3DbFree(db, zStmt);
82002 /* Fill the index with data and reparse the schema. Code an OP_Expire
82003 ** to invalidate all pre-compiled statements.
82005 if( pTblName ){
82006 sqlite3RefillIndex(pParse, pIndex, iMem);
82007 sqlite3ChangeCookie(pParse, iDb);
82008 sqlite3VdbeAddParseSchemaOp(v, iDb,
82009 sqlite3MPrintf(db, "name='%q' AND type='index'", pIndex->zName));
82010 sqlite3VdbeAddOp1(v, OP_Expire, 0);
82014 /* When adding an index to the list of indices for a table, make
82015 ** sure all indices labeled OE_Replace come after all those labeled
82016 ** OE_Ignore. This is necessary for the correct constraint check
82017 ** processing (in sqlite3GenerateConstraintChecks()) as part of
82018 ** UPDATE and INSERT statements.
82020 if( db->init.busy || pTblName==0 ){
82021 if( onError!=OE_Replace || pTab->pIndex==0
82022 || pTab->pIndex->onError==OE_Replace){
82023 pIndex->pNext = pTab->pIndex;
82024 pTab->pIndex = pIndex;
82025 }else{
82026 Index *pOther = pTab->pIndex;
82027 while( pOther->pNext && pOther->pNext->onError!=OE_Replace ){
82028 pOther = pOther->pNext;
82030 pIndex->pNext = pOther->pNext;
82031 pOther->pNext = pIndex;
82033 pRet = pIndex;
82034 pIndex = 0;
82037 /* Clean up before exiting */
82038 exit_create_index:
82039 if( pIndex ){
82040 sqlite3DbFree(db, pIndex->zColAff);
82041 sqlite3DbFree(db, pIndex);
82043 sqlite3ExprListDelete(db, pList);
82044 sqlite3SrcListDelete(db, pTblName);
82045 sqlite3DbFree(db, zName);
82046 return pRet;
82050 ** Fill the Index.aiRowEst[] array with default information - information
82051 ** to be used when we have not run the ANALYZE command.
82053 ** aiRowEst[0] is suppose to contain the number of elements in the index.
82054 ** Since we do not know, guess 1 million. aiRowEst[1] is an estimate of the
82055 ** number of rows in the table that match any particular value of the
82056 ** first column of the index. aiRowEst[2] is an estimate of the number
82057 ** of rows that match any particular combiniation of the first 2 columns
82058 ** of the index. And so forth. It must always be the case that
82060 ** aiRowEst[N]<=aiRowEst[N-1]
82061 ** aiRowEst[N]>=1
82063 ** Apart from that, we have little to go on besides intuition as to
82064 ** how aiRowEst[] should be initialized. The numbers generated here
82065 ** are based on typical values found in actual indices.
82067 SQLITE_PRIVATE void sqlite3DefaultRowEst(Index *pIdx){
82068 unsigned *a = pIdx->aiRowEst;
82069 int i;
82070 unsigned n;
82071 assert( a!=0 );
82072 a[0] = pIdx->pTable->nRowEst;
82073 if( a[0]<10 ) a[0] = 10;
82074 n = 10;
82075 for(i=1; i<=pIdx->nColumn; i++){
82076 a[i] = n;
82077 if( n>5 ) n--;
82079 if( pIdx->onError!=OE_None ){
82080 a[pIdx->nColumn] = 1;
82085 ** This routine will drop an existing named index. This routine
82086 ** implements the DROP INDEX statement.
82088 SQLITE_PRIVATE void sqlite3DropIndex(Parse *pParse, SrcList *pName, int ifExists){
82089 Index *pIndex;
82090 Vdbe *v;
82091 sqlite3 *db = pParse->db;
82092 int iDb;
82094 assert( pParse->nErr==0 ); /* Never called with prior errors */
82095 if( db->mallocFailed ){
82096 goto exit_drop_index;
82098 assert( pName->nSrc==1 );
82099 if( SQLITE_OK!=sqlite3ReadSchema(pParse) ){
82100 goto exit_drop_index;
82102 pIndex = sqlite3FindIndex(db, pName->a[0].zName, pName->a[0].zDatabase);
82103 if( pIndex==0 ){
82104 if( !ifExists ){
82105 sqlite3ErrorMsg(pParse, "no such index: %S", pName, 0);
82106 }else{
82107 sqlite3CodeVerifyNamedSchema(pParse, pName->a[0].zDatabase);
82109 pParse->checkSchema = 1;
82110 goto exit_drop_index;
82112 if( pIndex->autoIndex ){
82113 sqlite3ErrorMsg(pParse, "index associated with UNIQUE "
82114 "or PRIMARY KEY constraint cannot be dropped", 0);
82115 goto exit_drop_index;
82117 iDb = sqlite3SchemaToIndex(db, pIndex->pSchema);
82118 #ifndef SQLITE_OMIT_AUTHORIZATION
82120 int code = SQLITE_DROP_INDEX;
82121 Table *pTab = pIndex->pTable;
82122 const char *zDb = db->aDb[iDb].zName;
82123 const char *zTab = SCHEMA_TABLE(iDb);
82124 if( sqlite3AuthCheck(pParse, SQLITE_DELETE, zTab, 0, zDb) ){
82125 goto exit_drop_index;
82127 if( !OMIT_TEMPDB && iDb ) code = SQLITE_DROP_TEMP_INDEX;
82128 if( sqlite3AuthCheck(pParse, code, pIndex->zName, pTab->zName, zDb) ){
82129 goto exit_drop_index;
82132 #endif
82134 /* Generate code to remove the index and from the master table */
82135 v = sqlite3GetVdbe(pParse);
82136 if( v ){
82137 sqlite3BeginWriteOperation(pParse, 1, iDb);
82138 sqlite3NestedParse(pParse,
82139 "DELETE FROM %Q.%s WHERE name=%Q AND type='index'",
82140 db->aDb[iDb].zName, SCHEMA_TABLE(iDb), pIndex->zName
82142 sqlite3ClearStatTables(pParse, iDb, "idx", pIndex->zName);
82143 sqlite3ChangeCookie(pParse, iDb);
82144 destroyRootPage(pParse, pIndex->tnum, iDb);
82145 sqlite3VdbeAddOp4(v, OP_DropIndex, iDb, 0, 0, pIndex->zName, 0);
82148 exit_drop_index:
82149 sqlite3SrcListDelete(db, pName);
82153 ** pArray is a pointer to an array of objects. Each object in the
82154 ** array is szEntry bytes in size. This routine allocates a new
82155 ** object on the end of the array.
82157 ** *pnEntry is the number of entries already in use. *pnAlloc is
82158 ** the previously allocated size of the array. initSize is the
82159 ** suggested initial array size allocation.
82161 ** The index of the new entry is returned in *pIdx.
82163 ** This routine returns a pointer to the array of objects. This
82164 ** might be the same as the pArray parameter or it might be a different
82165 ** pointer if the array was resized.
82167 SQLITE_PRIVATE void *sqlite3ArrayAllocate(
82168 sqlite3 *db, /* Connection to notify of malloc failures */
82169 void *pArray, /* Array of objects. Might be reallocated */
82170 int szEntry, /* Size of each object in the array */
82171 int initSize, /* Suggested initial allocation, in elements */
82172 int *pnEntry, /* Number of objects currently in use */
82173 int *pnAlloc, /* Current size of the allocation, in elements */
82174 int *pIdx /* Write the index of a new slot here */
82176 char *z;
82177 if( *pnEntry >= *pnAlloc ){
82178 void *pNew;
82179 int newSize;
82180 newSize = (*pnAlloc)*2 + initSize;
82181 pNew = sqlite3DbRealloc(db, pArray, newSize*szEntry);
82182 if( pNew==0 ){
82183 *pIdx = -1;
82184 return pArray;
82186 *pnAlloc = sqlite3DbMallocSize(db, pNew)/szEntry;
82187 pArray = pNew;
82189 z = (char*)pArray;
82190 memset(&z[*pnEntry * szEntry], 0, szEntry);
82191 *pIdx = *pnEntry;
82192 ++*pnEntry;
82193 return pArray;
82197 ** Append a new element to the given IdList. Create a new IdList if
82198 ** need be.
82200 ** A new IdList is returned, or NULL if malloc() fails.
82202 SQLITE_PRIVATE IdList *sqlite3IdListAppend(sqlite3 *db, IdList *pList, Token *pToken){
82203 int i;
82204 if( pList==0 ){
82205 pList = sqlite3DbMallocZero(db, sizeof(IdList) );
82206 if( pList==0 ) return 0;
82207 pList->nAlloc = 0;
82209 pList->a = sqlite3ArrayAllocate(
82211 pList->a,
82212 sizeof(pList->a[0]),
82214 &pList->nId,
82215 &pList->nAlloc,
82218 if( i<0 ){
82219 sqlite3IdListDelete(db, pList);
82220 return 0;
82222 pList->a[i].zName = sqlite3NameFromToken(db, pToken);
82223 return pList;
82227 ** Delete an IdList.
82229 SQLITE_PRIVATE void sqlite3IdListDelete(sqlite3 *db, IdList *pList){
82230 int i;
82231 if( pList==0 ) return;
82232 for(i=0; i<pList->nId; i++){
82233 sqlite3DbFree(db, pList->a[i].zName);
82235 sqlite3DbFree(db, pList->a);
82236 sqlite3DbFree(db, pList);
82240 ** Return the index in pList of the identifier named zId. Return -1
82241 ** if not found.
82243 SQLITE_PRIVATE int sqlite3IdListIndex(IdList *pList, const char *zName){
82244 int i;
82245 if( pList==0 ) return -1;
82246 for(i=0; i<pList->nId; i++){
82247 if( sqlite3StrICmp(pList->a[i].zName, zName)==0 ) return i;
82249 return -1;
82253 ** Expand the space allocated for the given SrcList object by
82254 ** creating nExtra new slots beginning at iStart. iStart is zero based.
82255 ** New slots are zeroed.
82257 ** For example, suppose a SrcList initially contains two entries: A,B.
82258 ** To append 3 new entries onto the end, do this:
82260 ** sqlite3SrcListEnlarge(db, pSrclist, 3, 2);
82262 ** After the call above it would contain: A, B, nil, nil, nil.
82263 ** If the iStart argument had been 1 instead of 2, then the result
82264 ** would have been: A, nil, nil, nil, B. To prepend the new slots,
82265 ** the iStart value would be 0. The result then would
82266 ** be: nil, nil, nil, A, B.
82268 ** If a memory allocation fails the SrcList is unchanged. The
82269 ** db->mallocFailed flag will be set to true.
82271 SQLITE_PRIVATE SrcList *sqlite3SrcListEnlarge(
82272 sqlite3 *db, /* Database connection to notify of OOM errors */
82273 SrcList *pSrc, /* The SrcList to be enlarged */
82274 int nExtra, /* Number of new slots to add to pSrc->a[] */
82275 int iStart /* Index in pSrc->a[] of first new slot */
82277 int i;
82279 /* Sanity checking on calling parameters */
82280 assert( iStart>=0 );
82281 assert( nExtra>=1 );
82282 assert( pSrc!=0 );
82283 assert( iStart<=pSrc->nSrc );
82285 /* Allocate additional space if needed */
82286 if( pSrc->nSrc+nExtra>pSrc->nAlloc ){
82287 SrcList *pNew;
82288 int nAlloc = pSrc->nSrc+nExtra;
82289 int nGot;
82290 pNew = sqlite3DbRealloc(db, pSrc,
82291 sizeof(*pSrc) + (nAlloc-1)*sizeof(pSrc->a[0]) );
82292 if( pNew==0 ){
82293 assert( db->mallocFailed );
82294 return pSrc;
82296 pSrc = pNew;
82297 nGot = (sqlite3DbMallocSize(db, pNew) - sizeof(*pSrc))/sizeof(pSrc->a[0])+1;
82298 pSrc->nAlloc = (u16)nGot;
82301 /* Move existing slots that come after the newly inserted slots
82302 ** out of the way */
82303 for(i=pSrc->nSrc-1; i>=iStart; i--){
82304 pSrc->a[i+nExtra] = pSrc->a[i];
82306 pSrc->nSrc += (i16)nExtra;
82308 /* Zero the newly allocated slots */
82309 memset(&pSrc->a[iStart], 0, sizeof(pSrc->a[0])*nExtra);
82310 for(i=iStart; i<iStart+nExtra; i++){
82311 pSrc->a[i].iCursor = -1;
82314 /* Return a pointer to the enlarged SrcList */
82315 return pSrc;
82320 ** Append a new table name to the given SrcList. Create a new SrcList if
82321 ** need be. A new entry is created in the SrcList even if pTable is NULL.
82323 ** A SrcList is returned, or NULL if there is an OOM error. The returned
82324 ** SrcList might be the same as the SrcList that was input or it might be
82325 ** a new one. If an OOM error does occurs, then the prior value of pList
82326 ** that is input to this routine is automatically freed.
82328 ** If pDatabase is not null, it means that the table has an optional
82329 ** database name prefix. Like this: "database.table". The pDatabase
82330 ** points to the table name and the pTable points to the database name.
82331 ** The SrcList.a[].zName field is filled with the table name which might
82332 ** come from pTable (if pDatabase is NULL) or from pDatabase.
82333 ** SrcList.a[].zDatabase is filled with the database name from pTable,
82334 ** or with NULL if no database is specified.
82336 ** In other words, if call like this:
82338 ** sqlite3SrcListAppend(D,A,B,0);
82340 ** Then B is a table name and the database name is unspecified. If called
82341 ** like this:
82343 ** sqlite3SrcListAppend(D,A,B,C);
82345 ** Then C is the table name and B is the database name. If C is defined
82346 ** then so is B. In other words, we never have a case where:
82348 ** sqlite3SrcListAppend(D,A,0,C);
82350 ** Both pTable and pDatabase are assumed to be quoted. They are dequoted
82351 ** before being added to the SrcList.
82353 SQLITE_PRIVATE SrcList *sqlite3SrcListAppend(
82354 sqlite3 *db, /* Connection to notify of malloc failures */
82355 SrcList *pList, /* Append to this SrcList. NULL creates a new SrcList */
82356 Token *pTable, /* Table to append */
82357 Token *pDatabase /* Database of the table */
82359 struct SrcList_item *pItem;
82360 assert( pDatabase==0 || pTable!=0 ); /* Cannot have C without B */
82361 if( pList==0 ){
82362 pList = sqlite3DbMallocZero(db, sizeof(SrcList) );
82363 if( pList==0 ) return 0;
82364 pList->nAlloc = 1;
82366 pList = sqlite3SrcListEnlarge(db, pList, 1, pList->nSrc);
82367 if( db->mallocFailed ){
82368 sqlite3SrcListDelete(db, pList);
82369 return 0;
82371 pItem = &pList->a[pList->nSrc-1];
82372 if( pDatabase && pDatabase->z==0 ){
82373 pDatabase = 0;
82375 if( pDatabase ){
82376 Token *pTemp = pDatabase;
82377 pDatabase = pTable;
82378 pTable = pTemp;
82380 pItem->zName = sqlite3NameFromToken(db, pTable);
82381 pItem->zDatabase = sqlite3NameFromToken(db, pDatabase);
82382 return pList;
82386 ** Assign VdbeCursor index numbers to all tables in a SrcList
82388 SQLITE_PRIVATE void sqlite3SrcListAssignCursors(Parse *pParse, SrcList *pList){
82389 int i;
82390 struct SrcList_item *pItem;
82391 assert(pList || pParse->db->mallocFailed );
82392 if( pList ){
82393 for(i=0, pItem=pList->a; i<pList->nSrc; i++, pItem++){
82394 if( pItem->iCursor>=0 ) break;
82395 pItem->iCursor = pParse->nTab++;
82396 if( pItem->pSelect ){
82397 sqlite3SrcListAssignCursors(pParse, pItem->pSelect->pSrc);
82404 ** Delete an entire SrcList including all its substructure.
82406 SQLITE_PRIVATE void sqlite3SrcListDelete(sqlite3 *db, SrcList *pList){
82407 int i;
82408 struct SrcList_item *pItem;
82409 if( pList==0 ) return;
82410 for(pItem=pList->a, i=0; i<pList->nSrc; i++, pItem++){
82411 sqlite3DbFree(db, pItem->zDatabase);
82412 sqlite3DbFree(db, pItem->zName);
82413 sqlite3DbFree(db, pItem->zAlias);
82414 sqlite3DbFree(db, pItem->zIndex);
82415 sqlite3DeleteTable(db, pItem->pTab);
82416 sqlite3SelectDelete(db, pItem->pSelect);
82417 sqlite3ExprDelete(db, pItem->pOn);
82418 sqlite3IdListDelete(db, pItem->pUsing);
82420 sqlite3DbFree(db, pList);
82424 ** This routine is called by the parser to add a new term to the
82425 ** end of a growing FROM clause. The "p" parameter is the part of
82426 ** the FROM clause that has already been constructed. "p" is NULL
82427 ** if this is the first term of the FROM clause. pTable and pDatabase
82428 ** are the name of the table and database named in the FROM clause term.
82429 ** pDatabase is NULL if the database name qualifier is missing - the
82430 ** usual case. If the term has a alias, then pAlias points to the
82431 ** alias token. If the term is a subquery, then pSubquery is the
82432 ** SELECT statement that the subquery encodes. The pTable and
82433 ** pDatabase parameters are NULL for subqueries. The pOn and pUsing
82434 ** parameters are the content of the ON and USING clauses.
82436 ** Return a new SrcList which encodes is the FROM with the new
82437 ** term added.
82439 SQLITE_PRIVATE SrcList *sqlite3SrcListAppendFromTerm(
82440 Parse *pParse, /* Parsing context */
82441 SrcList *p, /* The left part of the FROM clause already seen */
82442 Token *pTable, /* Name of the table to add to the FROM clause */
82443 Token *pDatabase, /* Name of the database containing pTable */
82444 Token *pAlias, /* The right-hand side of the AS subexpression */
82445 Select *pSubquery, /* A subquery used in place of a table name */
82446 Expr *pOn, /* The ON clause of a join */
82447 IdList *pUsing /* The USING clause of a join */
82449 struct SrcList_item *pItem;
82450 sqlite3 *db = pParse->db;
82451 if( !p && (pOn || pUsing) ){
82452 sqlite3ErrorMsg(pParse, "a JOIN clause is required before %s",
82453 (pOn ? "ON" : "USING")
82455 goto append_from_error;
82457 p = sqlite3SrcListAppend(db, p, pTable, pDatabase);
82458 if( p==0 || NEVER(p->nSrc==0) ){
82459 goto append_from_error;
82461 pItem = &p->a[p->nSrc-1];
82462 assert( pAlias!=0 );
82463 if( pAlias->n ){
82464 pItem->zAlias = sqlite3NameFromToken(db, pAlias);
82466 pItem->pSelect = pSubquery;
82467 pItem->pOn = pOn;
82468 pItem->pUsing = pUsing;
82469 return p;
82471 append_from_error:
82472 assert( p==0 );
82473 sqlite3ExprDelete(db, pOn);
82474 sqlite3IdListDelete(db, pUsing);
82475 sqlite3SelectDelete(db, pSubquery);
82476 return 0;
82480 ** Add an INDEXED BY or NOT INDEXED clause to the most recently added
82481 ** element of the source-list passed as the second argument.
82483 SQLITE_PRIVATE void sqlite3SrcListIndexedBy(Parse *pParse, SrcList *p, Token *pIndexedBy){
82484 assert( pIndexedBy!=0 );
82485 if( p && ALWAYS(p->nSrc>0) ){
82486 struct SrcList_item *pItem = &p->a[p->nSrc-1];
82487 assert( pItem->notIndexed==0 && pItem->zIndex==0 );
82488 if( pIndexedBy->n==1 && !pIndexedBy->z ){
82489 /* A "NOT INDEXED" clause was supplied. See parse.y
82490 ** construct "indexed_opt" for details. */
82491 pItem->notIndexed = 1;
82492 }else{
82493 pItem->zIndex = sqlite3NameFromToken(pParse->db, pIndexedBy);
82499 ** When building up a FROM clause in the parser, the join operator
82500 ** is initially attached to the left operand. But the code generator
82501 ** expects the join operator to be on the right operand. This routine
82502 ** Shifts all join operators from left to right for an entire FROM
82503 ** clause.
82505 ** Example: Suppose the join is like this:
82507 ** A natural cross join B
82509 ** The operator is "natural cross join". The A and B operands are stored
82510 ** in p->a[0] and p->a[1], respectively. The parser initially stores the
82511 ** operator with A. This routine shifts that operator over to B.
82513 SQLITE_PRIVATE void sqlite3SrcListShiftJoinType(SrcList *p){
82514 if( p ){
82515 int i;
82516 assert( p->a || p->nSrc==0 );
82517 for(i=p->nSrc-1; i>0; i--){
82518 p->a[i].jointype = p->a[i-1].jointype;
82520 p->a[0].jointype = 0;
82525 ** Begin a transaction
82527 SQLITE_PRIVATE void sqlite3BeginTransaction(Parse *pParse, int type){
82528 sqlite3 *db;
82529 Vdbe *v;
82530 int i;
82532 assert( pParse!=0 );
82533 db = pParse->db;
82534 assert( db!=0 );
82535 /* if( db->aDb[0].pBt==0 ) return; */
82536 if( sqlite3AuthCheck(pParse, SQLITE_TRANSACTION, "BEGIN", 0, 0) ){
82537 return;
82539 v = sqlite3GetVdbe(pParse);
82540 if( !v ) return;
82541 if( type!=TK_DEFERRED ){
82542 for(i=0; i<db->nDb; i++){
82543 sqlite3VdbeAddOp2(v, OP_Transaction, i, (type==TK_EXCLUSIVE)+1);
82544 sqlite3VdbeUsesBtree(v, i);
82547 sqlite3VdbeAddOp2(v, OP_AutoCommit, 0, 0);
82551 ** Commit a transaction
82553 SQLITE_PRIVATE void sqlite3CommitTransaction(Parse *pParse){
82554 sqlite3 *db;
82555 Vdbe *v;
82557 assert( pParse!=0 );
82558 db = pParse->db;
82559 assert( db!=0 );
82560 /* if( db->aDb[0].pBt==0 ) return; */
82561 if( sqlite3AuthCheck(pParse, SQLITE_TRANSACTION, "COMMIT", 0, 0) ){
82562 return;
82564 v = sqlite3GetVdbe(pParse);
82565 if( v ){
82566 sqlite3VdbeAddOp2(v, OP_AutoCommit, 1, 0);
82571 ** Rollback a transaction
82573 SQLITE_PRIVATE void sqlite3RollbackTransaction(Parse *pParse){
82574 sqlite3 *db;
82575 Vdbe *v;
82577 assert( pParse!=0 );
82578 db = pParse->db;
82579 assert( db!=0 );
82580 /* if( db->aDb[0].pBt==0 ) return; */
82581 if( sqlite3AuthCheck(pParse, SQLITE_TRANSACTION, "ROLLBACK", 0, 0) ){
82582 return;
82584 v = sqlite3GetVdbe(pParse);
82585 if( v ){
82586 sqlite3VdbeAddOp2(v, OP_AutoCommit, 1, 1);
82591 ** This function is called by the parser when it parses a command to create,
82592 ** release or rollback an SQL savepoint.
82594 SQLITE_PRIVATE void sqlite3Savepoint(Parse *pParse, int op, Token *pName){
82595 char *zName = sqlite3NameFromToken(pParse->db, pName);
82596 if( zName ){
82597 Vdbe *v = sqlite3GetVdbe(pParse);
82598 #ifndef SQLITE_OMIT_AUTHORIZATION
82599 static const char * const az[] = { "BEGIN", "RELEASE", "ROLLBACK" };
82600 assert( !SAVEPOINT_BEGIN && SAVEPOINT_RELEASE==1 && SAVEPOINT_ROLLBACK==2 );
82601 #endif
82602 if( !v || sqlite3AuthCheck(pParse, SQLITE_SAVEPOINT, az[op], zName, 0) ){
82603 sqlite3DbFree(pParse->db, zName);
82604 return;
82606 sqlite3VdbeAddOp4(v, OP_Savepoint, op, 0, 0, zName, P4_DYNAMIC);
82611 ** Make sure the TEMP database is open and available for use. Return
82612 ** the number of errors. Leave any error messages in the pParse structure.
82614 SQLITE_PRIVATE int sqlite3OpenTempDatabase(Parse *pParse){
82615 sqlite3 *db = pParse->db;
82616 if( db->aDb[1].pBt==0 && !pParse->explain ){
82617 int rc;
82618 Btree *pBt;
82619 static const int flags =
82620 SQLITE_OPEN_READWRITE |
82621 SQLITE_OPEN_CREATE |
82622 SQLITE_OPEN_EXCLUSIVE |
82623 SQLITE_OPEN_DELETEONCLOSE |
82624 SQLITE_OPEN_TEMP_DB;
82626 rc = sqlite3BtreeOpen(db->pVfs, 0, db, &pBt, 0, flags);
82627 if( rc!=SQLITE_OK ){
82628 sqlite3ErrorMsg(pParse, "unable to open a temporary database "
82629 "file for storing temporary tables");
82630 pParse->rc = rc;
82631 return 1;
82633 db->aDb[1].pBt = pBt;
82634 assert( db->aDb[1].pSchema );
82635 if( SQLITE_NOMEM==sqlite3BtreeSetPageSize(pBt, db->nextPagesize, -1, 0) ){
82636 db->mallocFailed = 1;
82637 return 1;
82640 return 0;
82644 ** Generate VDBE code that will verify the schema cookie and start
82645 ** a read-transaction for all named database files.
82647 ** It is important that all schema cookies be verified and all
82648 ** read transactions be started before anything else happens in
82649 ** the VDBE program. But this routine can be called after much other
82650 ** code has been generated. So here is what we do:
82652 ** The first time this routine is called, we code an OP_Goto that
82653 ** will jump to a subroutine at the end of the program. Then we
82654 ** record every database that needs its schema verified in the
82655 ** pParse->cookieMask field. Later, after all other code has been
82656 ** generated, the subroutine that does the cookie verifications and
82657 ** starts the transactions will be coded and the OP_Goto P2 value
82658 ** will be made to point to that subroutine. The generation of the
82659 ** cookie verification subroutine code happens in sqlite3FinishCoding().
82661 ** If iDb<0 then code the OP_Goto only - don't set flag to verify the
82662 ** schema on any databases. This can be used to position the OP_Goto
82663 ** early in the code, before we know if any database tables will be used.
82665 SQLITE_PRIVATE void sqlite3CodeVerifySchema(Parse *pParse, int iDb){
82666 Parse *pToplevel = sqlite3ParseToplevel(pParse);
82668 if( pToplevel->cookieGoto==0 ){
82669 Vdbe *v = sqlite3GetVdbe(pToplevel);
82670 if( v==0 ) return; /* This only happens if there was a prior error */
82671 pToplevel->cookieGoto = sqlite3VdbeAddOp2(v, OP_Goto, 0, 0)+1;
82673 if( iDb>=0 ){
82674 sqlite3 *db = pToplevel->db;
82675 yDbMask mask;
82677 assert( iDb<db->nDb );
82678 assert( db->aDb[iDb].pBt!=0 || iDb==1 );
82679 assert( iDb<SQLITE_MAX_ATTACHED+2 );
82680 assert( sqlite3SchemaMutexHeld(db, iDb, 0) );
82681 mask = ((yDbMask)1)<<iDb;
82682 if( (pToplevel->cookieMask & mask)==0 ){
82683 pToplevel->cookieMask |= mask;
82684 pToplevel->cookieValue[iDb] = db->aDb[iDb].pSchema->schema_cookie;
82685 if( !OMIT_TEMPDB && iDb==1 ){
82686 sqlite3OpenTempDatabase(pToplevel);
82693 ** If argument zDb is NULL, then call sqlite3CodeVerifySchema() for each
82694 ** attached database. Otherwise, invoke it for the database named zDb only.
82696 SQLITE_PRIVATE void sqlite3CodeVerifyNamedSchema(Parse *pParse, const char *zDb){
82697 sqlite3 *db = pParse->db;
82698 int i;
82699 for(i=0; i<db->nDb; i++){
82700 Db *pDb = &db->aDb[i];
82701 if( pDb->pBt && (!zDb || 0==sqlite3StrICmp(zDb, pDb->zName)) ){
82702 sqlite3CodeVerifySchema(pParse, i);
82708 ** Generate VDBE code that prepares for doing an operation that
82709 ** might change the database.
82711 ** This routine starts a new transaction if we are not already within
82712 ** a transaction. If we are already within a transaction, then a checkpoint
82713 ** is set if the setStatement parameter is true. A checkpoint should
82714 ** be set for operations that might fail (due to a constraint) part of
82715 ** the way through and which will need to undo some writes without having to
82716 ** rollback the whole transaction. For operations where all constraints
82717 ** can be checked before any changes are made to the database, it is never
82718 ** necessary to undo a write and the checkpoint should not be set.
82720 SQLITE_PRIVATE void sqlite3BeginWriteOperation(Parse *pParse, int setStatement, int iDb){
82721 Parse *pToplevel = sqlite3ParseToplevel(pParse);
82722 sqlite3CodeVerifySchema(pParse, iDb);
82723 pToplevel->writeMask |= ((yDbMask)1)<<iDb;
82724 pToplevel->isMultiWrite |= setStatement;
82728 ** Indicate that the statement currently under construction might write
82729 ** more than one entry (example: deleting one row then inserting another,
82730 ** inserting multiple rows in a table, or inserting a row and index entries.)
82731 ** If an abort occurs after some of these writes have completed, then it will
82732 ** be necessary to undo the completed writes.
82734 SQLITE_PRIVATE void sqlite3MultiWrite(Parse *pParse){
82735 Parse *pToplevel = sqlite3ParseToplevel(pParse);
82736 pToplevel->isMultiWrite = 1;
82740 ** The code generator calls this routine if is discovers that it is
82741 ** possible to abort a statement prior to completion. In order to
82742 ** perform this abort without corrupting the database, we need to make
82743 ** sure that the statement is protected by a statement transaction.
82745 ** Technically, we only need to set the mayAbort flag if the
82746 ** isMultiWrite flag was previously set. There is a time dependency
82747 ** such that the abort must occur after the multiwrite. This makes
82748 ** some statements involving the REPLACE conflict resolution algorithm
82749 ** go a little faster. But taking advantage of this time dependency
82750 ** makes it more difficult to prove that the code is correct (in
82751 ** particular, it prevents us from writing an effective
82752 ** implementation of sqlite3AssertMayAbort()) and so we have chosen
82753 ** to take the safe route and skip the optimization.
82755 SQLITE_PRIVATE void sqlite3MayAbort(Parse *pParse){
82756 Parse *pToplevel = sqlite3ParseToplevel(pParse);
82757 pToplevel->mayAbort = 1;
82761 ** Code an OP_Halt that causes the vdbe to return an SQLITE_CONSTRAINT
82762 ** error. The onError parameter determines which (if any) of the statement
82763 ** and/or current transaction is rolled back.
82765 SQLITE_PRIVATE void sqlite3HaltConstraint(Parse *pParse, int onError, char *p4, int p4type){
82766 Vdbe *v = sqlite3GetVdbe(pParse);
82767 if( onError==OE_Abort ){
82768 sqlite3MayAbort(pParse);
82770 sqlite3VdbeAddOp4(v, OP_Halt, SQLITE_CONSTRAINT, onError, 0, p4, p4type);
82774 ** Check to see if pIndex uses the collating sequence pColl. Return
82775 ** true if it does and false if it does not.
82777 #ifndef SQLITE_OMIT_REINDEX
82778 static int collationMatch(const char *zColl, Index *pIndex){
82779 int i;
82780 assert( zColl!=0 );
82781 for(i=0; i<pIndex->nColumn; i++){
82782 const char *z = pIndex->azColl[i];
82783 assert( z!=0 );
82784 if( 0==sqlite3StrICmp(z, zColl) ){
82785 return 1;
82788 return 0;
82790 #endif
82793 ** Recompute all indices of pTab that use the collating sequence pColl.
82794 ** If pColl==0 then recompute all indices of pTab.
82796 #ifndef SQLITE_OMIT_REINDEX
82797 static void reindexTable(Parse *pParse, Table *pTab, char const *zColl){
82798 Index *pIndex; /* An index associated with pTab */
82800 for(pIndex=pTab->pIndex; pIndex; pIndex=pIndex->pNext){
82801 if( zColl==0 || collationMatch(zColl, pIndex) ){
82802 int iDb = sqlite3SchemaToIndex(pParse->db, pTab->pSchema);
82803 sqlite3BeginWriteOperation(pParse, 0, iDb);
82804 sqlite3RefillIndex(pParse, pIndex, -1);
82808 #endif
82811 ** Recompute all indices of all tables in all databases where the
82812 ** indices use the collating sequence pColl. If pColl==0 then recompute
82813 ** all indices everywhere.
82815 #ifndef SQLITE_OMIT_REINDEX
82816 static void reindexDatabases(Parse *pParse, char const *zColl){
82817 Db *pDb; /* A single database */
82818 int iDb; /* The database index number */
82819 sqlite3 *db = pParse->db; /* The database connection */
82820 HashElem *k; /* For looping over tables in pDb */
82821 Table *pTab; /* A table in the database */
82823 assert( sqlite3BtreeHoldsAllMutexes(db) ); /* Needed for schema access */
82824 for(iDb=0, pDb=db->aDb; iDb<db->nDb; iDb++, pDb++){
82825 assert( pDb!=0 );
82826 for(k=sqliteHashFirst(&pDb->pSchema->tblHash); k; k=sqliteHashNext(k)){
82827 pTab = (Table*)sqliteHashData(k);
82828 reindexTable(pParse, pTab, zColl);
82832 #endif
82835 ** Generate code for the REINDEX command.
82837 ** REINDEX -- 1
82838 ** REINDEX <collation> -- 2
82839 ** REINDEX ?<database>.?<tablename> -- 3
82840 ** REINDEX ?<database>.?<indexname> -- 4
82842 ** Form 1 causes all indices in all attached databases to be rebuilt.
82843 ** Form 2 rebuilds all indices in all databases that use the named
82844 ** collating function. Forms 3 and 4 rebuild the named index or all
82845 ** indices associated with the named table.
82847 #ifndef SQLITE_OMIT_REINDEX
82848 SQLITE_PRIVATE void sqlite3Reindex(Parse *pParse, Token *pName1, Token *pName2){
82849 CollSeq *pColl; /* Collating sequence to be reindexed, or NULL */
82850 char *z; /* Name of a table or index */
82851 const char *zDb; /* Name of the database */
82852 Table *pTab; /* A table in the database */
82853 Index *pIndex; /* An index associated with pTab */
82854 int iDb; /* The database index number */
82855 sqlite3 *db = pParse->db; /* The database connection */
82856 Token *pObjName; /* Name of the table or index to be reindexed */
82858 /* Read the database schema. If an error occurs, leave an error message
82859 ** and code in pParse and return NULL. */
82860 if( SQLITE_OK!=sqlite3ReadSchema(pParse) ){
82861 return;
82864 if( pName1==0 ){
82865 reindexDatabases(pParse, 0);
82866 return;
82867 }else if( NEVER(pName2==0) || pName2->z==0 ){
82868 char *zColl;
82869 assert( pName1->z );
82870 zColl = sqlite3NameFromToken(pParse->db, pName1);
82871 if( !zColl ) return;
82872 pColl = sqlite3FindCollSeq(db, ENC(db), zColl, 0);
82873 if( pColl ){
82874 reindexDatabases(pParse, zColl);
82875 sqlite3DbFree(db, zColl);
82876 return;
82878 sqlite3DbFree(db, zColl);
82880 iDb = sqlite3TwoPartName(pParse, pName1, pName2, &pObjName);
82881 if( iDb<0 ) return;
82882 z = sqlite3NameFromToken(db, pObjName);
82883 if( z==0 ) return;
82884 zDb = db->aDb[iDb].zName;
82885 pTab = sqlite3FindTable(db, z, zDb);
82886 if( pTab ){
82887 reindexTable(pParse, pTab, 0);
82888 sqlite3DbFree(db, z);
82889 return;
82891 pIndex = sqlite3FindIndex(db, z, zDb);
82892 sqlite3DbFree(db, z);
82893 if( pIndex ){
82894 sqlite3BeginWriteOperation(pParse, 0, iDb);
82895 sqlite3RefillIndex(pParse, pIndex, -1);
82896 return;
82898 sqlite3ErrorMsg(pParse, "unable to identify the object to be reindexed");
82900 #endif
82903 ** Return a dynamicly allocated KeyInfo structure that can be used
82904 ** with OP_OpenRead or OP_OpenWrite to access database index pIdx.
82906 ** If successful, a pointer to the new structure is returned. In this case
82907 ** the caller is responsible for calling sqlite3DbFree(db, ) on the returned
82908 ** pointer. If an error occurs (out of memory or missing collation
82909 ** sequence), NULL is returned and the state of pParse updated to reflect
82910 ** the error.
82912 SQLITE_PRIVATE KeyInfo *sqlite3IndexKeyinfo(Parse *pParse, Index *pIdx){
82913 int i;
82914 int nCol = pIdx->nColumn;
82915 int nBytes = sizeof(KeyInfo) + (nCol-1)*sizeof(CollSeq*) + nCol;
82916 sqlite3 *db = pParse->db;
82917 KeyInfo *pKey = (KeyInfo *)sqlite3DbMallocZero(db, nBytes);
82919 if( pKey ){
82920 pKey->db = pParse->db;
82921 pKey->aSortOrder = (u8 *)&(pKey->aColl[nCol]);
82922 assert( &pKey->aSortOrder[nCol]==&(((u8 *)pKey)[nBytes]) );
82923 for(i=0; i<nCol; i++){
82924 char *zColl = pIdx->azColl[i];
82925 assert( zColl );
82926 pKey->aColl[i] = sqlite3LocateCollSeq(pParse, zColl);
82927 pKey->aSortOrder[i] = pIdx->aSortOrder[i];
82929 pKey->nField = (u16)nCol;
82932 if( pParse->nErr ){
82933 sqlite3DbFree(db, pKey);
82934 pKey = 0;
82936 return pKey;
82939 /************** End of build.c ***********************************************/
82940 /************** Begin file callback.c ****************************************/
82942 ** 2005 May 23
82944 ** The author disclaims copyright to this source code. In place of
82945 ** a legal notice, here is a blessing:
82947 ** May you do good and not evil.
82948 ** May you find forgiveness for yourself and forgive others.
82949 ** May you share freely, never taking more than you give.
82951 *************************************************************************
82953 ** This file contains functions used to access the internal hash tables
82954 ** of user defined functions and collation sequences.
82959 ** Invoke the 'collation needed' callback to request a collation sequence
82960 ** in the encoding enc of name zName, length nName.
82962 static void callCollNeeded(sqlite3 *db, int enc, const char *zName){
82963 assert( !db->xCollNeeded || !db->xCollNeeded16 );
82964 if( db->xCollNeeded ){
82965 char *zExternal = sqlite3DbStrDup(db, zName);
82966 if( !zExternal ) return;
82967 db->xCollNeeded(db->pCollNeededArg, db, enc, zExternal);
82968 sqlite3DbFree(db, zExternal);
82970 #ifndef SQLITE_OMIT_UTF16
82971 if( db->xCollNeeded16 ){
82972 char const *zExternal;
82973 sqlite3_value *pTmp = sqlite3ValueNew(db);
82974 sqlite3ValueSetStr(pTmp, -1, zName, SQLITE_UTF8, SQLITE_STATIC);
82975 zExternal = sqlite3ValueText(pTmp, SQLITE_UTF16NATIVE);
82976 if( zExternal ){
82977 db->xCollNeeded16(db->pCollNeededArg, db, (int)ENC(db), zExternal);
82979 sqlite3ValueFree(pTmp);
82981 #endif
82985 ** This routine is called if the collation factory fails to deliver a
82986 ** collation function in the best encoding but there may be other versions
82987 ** of this collation function (for other text encodings) available. Use one
82988 ** of these instead if they exist. Avoid a UTF-8 <-> UTF-16 conversion if
82989 ** possible.
82991 static int synthCollSeq(sqlite3 *db, CollSeq *pColl){
82992 CollSeq *pColl2;
82993 char *z = pColl->zName;
82994 int i;
82995 static const u8 aEnc[] = { SQLITE_UTF16BE, SQLITE_UTF16LE, SQLITE_UTF8 };
82996 for(i=0; i<3; i++){
82997 pColl2 = sqlite3FindCollSeq(db, aEnc[i], z, 0);
82998 if( pColl2->xCmp!=0 ){
82999 memcpy(pColl, pColl2, sizeof(CollSeq));
83000 pColl->xDel = 0; /* Do not copy the destructor */
83001 return SQLITE_OK;
83004 return SQLITE_ERROR;
83008 ** This function is responsible for invoking the collation factory callback
83009 ** or substituting a collation sequence of a different encoding when the
83010 ** requested collation sequence is not available in the desired encoding.
83012 ** If it is not NULL, then pColl must point to the database native encoding
83013 ** collation sequence with name zName, length nName.
83015 ** The return value is either the collation sequence to be used in database
83016 ** db for collation type name zName, length nName, or NULL, if no collation
83017 ** sequence can be found.
83019 ** See also: sqlite3LocateCollSeq(), sqlite3FindCollSeq()
83021 SQLITE_PRIVATE CollSeq *sqlite3GetCollSeq(
83022 sqlite3* db, /* The database connection */
83023 u8 enc, /* The desired encoding for the collating sequence */
83024 CollSeq *pColl, /* Collating sequence with native encoding, or NULL */
83025 const char *zName /* Collating sequence name */
83027 CollSeq *p;
83029 p = pColl;
83030 if( !p ){
83031 p = sqlite3FindCollSeq(db, enc, zName, 0);
83033 if( !p || !p->xCmp ){
83034 /* No collation sequence of this type for this encoding is registered.
83035 ** Call the collation factory to see if it can supply us with one.
83037 callCollNeeded(db, enc, zName);
83038 p = sqlite3FindCollSeq(db, enc, zName, 0);
83040 if( p && !p->xCmp && synthCollSeq(db, p) ){
83041 p = 0;
83043 assert( !p || p->xCmp );
83044 return p;
83048 ** This routine is called on a collation sequence before it is used to
83049 ** check that it is defined. An undefined collation sequence exists when
83050 ** a database is loaded that contains references to collation sequences
83051 ** that have not been defined by sqlite3_create_collation() etc.
83053 ** If required, this routine calls the 'collation needed' callback to
83054 ** request a definition of the collating sequence. If this doesn't work,
83055 ** an equivalent collating sequence that uses a text encoding different
83056 ** from the main database is substituted, if one is available.
83058 SQLITE_PRIVATE int sqlite3CheckCollSeq(Parse *pParse, CollSeq *pColl){
83059 if( pColl ){
83060 const char *zName = pColl->zName;
83061 sqlite3 *db = pParse->db;
83062 CollSeq *p = sqlite3GetCollSeq(db, ENC(db), pColl, zName);
83063 if( !p ){
83064 sqlite3ErrorMsg(pParse, "no such collation sequence: %s", zName);
83065 pParse->nErr++;
83066 return SQLITE_ERROR;
83068 assert( p==pColl );
83070 return SQLITE_OK;
83076 ** Locate and return an entry from the db.aCollSeq hash table. If the entry
83077 ** specified by zName and nName is not found and parameter 'create' is
83078 ** true, then create a new entry. Otherwise return NULL.
83080 ** Each pointer stored in the sqlite3.aCollSeq hash table contains an
83081 ** array of three CollSeq structures. The first is the collation sequence
83082 ** prefferred for UTF-8, the second UTF-16le, and the third UTF-16be.
83084 ** Stored immediately after the three collation sequences is a copy of
83085 ** the collation sequence name. A pointer to this string is stored in
83086 ** each collation sequence structure.
83088 static CollSeq *findCollSeqEntry(
83089 sqlite3 *db, /* Database connection */
83090 const char *zName, /* Name of the collating sequence */
83091 int create /* Create a new entry if true */
83093 CollSeq *pColl;
83094 int nName = sqlite3Strlen30(zName);
83095 pColl = sqlite3HashFind(&db->aCollSeq, zName, nName);
83097 if( 0==pColl && create ){
83098 pColl = sqlite3DbMallocZero(db, 3*sizeof(*pColl) + nName + 1 );
83099 if( pColl ){
83100 CollSeq *pDel = 0;
83101 pColl[0].zName = (char*)&pColl[3];
83102 pColl[0].enc = SQLITE_UTF8;
83103 pColl[1].zName = (char*)&pColl[3];
83104 pColl[1].enc = SQLITE_UTF16LE;
83105 pColl[2].zName = (char*)&pColl[3];
83106 pColl[2].enc = SQLITE_UTF16BE;
83107 memcpy(pColl[0].zName, zName, nName);
83108 pColl[0].zName[nName] = 0;
83109 pDel = sqlite3HashInsert(&db->aCollSeq, pColl[0].zName, nName, pColl);
83111 /* If a malloc() failure occurred in sqlite3HashInsert(), it will
83112 ** return the pColl pointer to be deleted (because it wasn't added
83113 ** to the hash table).
83115 assert( pDel==0 || pDel==pColl );
83116 if( pDel!=0 ){
83117 db->mallocFailed = 1;
83118 sqlite3DbFree(db, pDel);
83119 pColl = 0;
83123 return pColl;
83127 ** Parameter zName points to a UTF-8 encoded string nName bytes long.
83128 ** Return the CollSeq* pointer for the collation sequence named zName
83129 ** for the encoding 'enc' from the database 'db'.
83131 ** If the entry specified is not found and 'create' is true, then create a
83132 ** new entry. Otherwise return NULL.
83134 ** A separate function sqlite3LocateCollSeq() is a wrapper around
83135 ** this routine. sqlite3LocateCollSeq() invokes the collation factory
83136 ** if necessary and generates an error message if the collating sequence
83137 ** cannot be found.
83139 ** See also: sqlite3LocateCollSeq(), sqlite3GetCollSeq()
83141 SQLITE_PRIVATE CollSeq *sqlite3FindCollSeq(
83142 sqlite3 *db,
83143 u8 enc,
83144 const char *zName,
83145 int create
83147 CollSeq *pColl;
83148 if( zName ){
83149 pColl = findCollSeqEntry(db, zName, create);
83150 }else{
83151 pColl = db->pDfltColl;
83153 assert( SQLITE_UTF8==1 && SQLITE_UTF16LE==2 && SQLITE_UTF16BE==3 );
83154 assert( enc>=SQLITE_UTF8 && enc<=SQLITE_UTF16BE );
83155 if( pColl ) pColl += enc-1;
83156 return pColl;
83159 /* During the search for the best function definition, this procedure
83160 ** is called to test how well the function passed as the first argument
83161 ** matches the request for a function with nArg arguments in a system
83162 ** that uses encoding enc. The value returned indicates how well the
83163 ** request is matched. A higher value indicates a better match.
83165 ** The returned value is always between 0 and 6, as follows:
83167 ** 0: Not a match, or if nArg<0 and the function is has no implementation.
83168 ** 1: A variable arguments function that prefers UTF-8 when a UTF-16
83169 ** encoding is requested, or vice versa.
83170 ** 2: A variable arguments function that uses UTF-16BE when UTF-16LE is
83171 ** requested, or vice versa.
83172 ** 3: A variable arguments function using the same text encoding.
83173 ** 4: A function with the exact number of arguments requested that
83174 ** prefers UTF-8 when a UTF-16 encoding is requested, or vice versa.
83175 ** 5: A function with the exact number of arguments requested that
83176 ** prefers UTF-16LE when UTF-16BE is requested, or vice versa.
83177 ** 6: An exact match.
83180 static int matchQuality(FuncDef *p, int nArg, u8 enc){
83181 int match = 0;
83182 if( p->nArg==-1 || p->nArg==nArg
83183 || (nArg==-1 && (p->xFunc!=0 || p->xStep!=0))
83185 match = 1;
83186 if( p->nArg==nArg || nArg==-1 ){
83187 match = 4;
83189 if( enc==p->iPrefEnc ){
83190 match += 2;
83192 else if( (enc==SQLITE_UTF16LE && p->iPrefEnc==SQLITE_UTF16BE) ||
83193 (enc==SQLITE_UTF16BE && p->iPrefEnc==SQLITE_UTF16LE) ){
83194 match += 1;
83197 return match;
83201 ** Search a FuncDefHash for a function with the given name. Return
83202 ** a pointer to the matching FuncDef if found, or 0 if there is no match.
83204 static FuncDef *functionSearch(
83205 FuncDefHash *pHash, /* Hash table to search */
83206 int h, /* Hash of the name */
83207 const char *zFunc, /* Name of function */
83208 int nFunc /* Number of bytes in zFunc */
83210 FuncDef *p;
83211 for(p=pHash->a[h]; p; p=p->pHash){
83212 if( sqlite3StrNICmp(p->zName, zFunc, nFunc)==0 && p->zName[nFunc]==0 ){
83213 return p;
83216 return 0;
83220 ** Insert a new FuncDef into a FuncDefHash hash table.
83222 SQLITE_PRIVATE void sqlite3FuncDefInsert(
83223 FuncDefHash *pHash, /* The hash table into which to insert */
83224 FuncDef *pDef /* The function definition to insert */
83226 FuncDef *pOther;
83227 int nName = sqlite3Strlen30(pDef->zName);
83228 u8 c1 = (u8)pDef->zName[0];
83229 int h = (sqlite3UpperToLower[c1] + nName) % ArraySize(pHash->a);
83230 pOther = functionSearch(pHash, h, pDef->zName, nName);
83231 if( pOther ){
83232 assert( pOther!=pDef && pOther->pNext!=pDef );
83233 pDef->pNext = pOther->pNext;
83234 pOther->pNext = pDef;
83235 }else{
83236 pDef->pNext = 0;
83237 pDef->pHash = pHash->a[h];
83238 pHash->a[h] = pDef;
83245 ** Locate a user function given a name, a number of arguments and a flag
83246 ** indicating whether the function prefers UTF-16 over UTF-8. Return a
83247 ** pointer to the FuncDef structure that defines that function, or return
83248 ** NULL if the function does not exist.
83250 ** If the createFlag argument is true, then a new (blank) FuncDef
83251 ** structure is created and liked into the "db" structure if a
83252 ** no matching function previously existed. When createFlag is true
83253 ** and the nArg parameter is -1, then only a function that accepts
83254 ** any number of arguments will be returned.
83256 ** If createFlag is false and nArg is -1, then the first valid
83257 ** function found is returned. A function is valid if either xFunc
83258 ** or xStep is non-zero.
83260 ** If createFlag is false, then a function with the required name and
83261 ** number of arguments may be returned even if the eTextRep flag does not
83262 ** match that requested.
83264 SQLITE_PRIVATE FuncDef *sqlite3FindFunction(
83265 sqlite3 *db, /* An open database */
83266 const char *zName, /* Name of the function. Not null-terminated */
83267 int nName, /* Number of characters in the name */
83268 int nArg, /* Number of arguments. -1 means any number */
83269 u8 enc, /* Preferred text encoding */
83270 int createFlag /* Create new entry if true and does not otherwise exist */
83272 FuncDef *p; /* Iterator variable */
83273 FuncDef *pBest = 0; /* Best match found so far */
83274 int bestScore = 0; /* Score of best match */
83275 int h; /* Hash value */
83278 assert( enc==SQLITE_UTF8 || enc==SQLITE_UTF16LE || enc==SQLITE_UTF16BE );
83279 h = (sqlite3UpperToLower[(u8)zName[0]] + nName) % ArraySize(db->aFunc.a);
83281 /* First search for a match amongst the application-defined functions.
83283 p = functionSearch(&db->aFunc, h, zName, nName);
83284 while( p ){
83285 int score = matchQuality(p, nArg, enc);
83286 if( score>bestScore ){
83287 pBest = p;
83288 bestScore = score;
83290 p = p->pNext;
83293 /* If no match is found, search the built-in functions.
83295 ** If the SQLITE_PreferBuiltin flag is set, then search the built-in
83296 ** functions even if a prior app-defined function was found. And give
83297 ** priority to built-in functions.
83299 ** Except, if createFlag is true, that means that we are trying to
83300 ** install a new function. Whatever FuncDef structure is returned it will
83301 ** have fields overwritten with new information appropriate for the
83302 ** new function. But the FuncDefs for built-in functions are read-only.
83303 ** So we must not search for built-ins when creating a new function.
83305 if( !createFlag && (pBest==0 || (db->flags & SQLITE_PreferBuiltin)!=0) ){
83306 FuncDefHash *pHash = &GLOBAL(FuncDefHash, sqlite3GlobalFunctions);
83307 bestScore = 0;
83308 p = functionSearch(pHash, h, zName, nName);
83309 while( p ){
83310 int score = matchQuality(p, nArg, enc);
83311 if( score>bestScore ){
83312 pBest = p;
83313 bestScore = score;
83315 p = p->pNext;
83319 /* If the createFlag parameter is true and the search did not reveal an
83320 ** exact match for the name, number of arguments and encoding, then add a
83321 ** new entry to the hash table and return it.
83323 if( createFlag && (bestScore<6 || pBest->nArg!=nArg) &&
83324 (pBest = sqlite3DbMallocZero(db, sizeof(*pBest)+nName+1))!=0 ){
83325 pBest->zName = (char *)&pBest[1];
83326 pBest->nArg = (u16)nArg;
83327 pBest->iPrefEnc = enc;
83328 memcpy(pBest->zName, zName, nName);
83329 pBest->zName[nName] = 0;
83330 sqlite3FuncDefInsert(&db->aFunc, pBest);
83333 if( pBest && (pBest->xStep || pBest->xFunc || createFlag) ){
83334 return pBest;
83336 return 0;
83340 ** Free all resources held by the schema structure. The void* argument points
83341 ** at a Schema struct. This function does not call sqlite3DbFree(db, ) on the
83342 ** pointer itself, it just cleans up subsidiary resources (i.e. the contents
83343 ** of the schema hash tables).
83345 ** The Schema.cache_size variable is not cleared.
83347 SQLITE_PRIVATE void sqlite3SchemaClear(void *p){
83348 Hash temp1;
83349 Hash temp2;
83350 HashElem *pElem;
83351 Schema *pSchema = (Schema *)p;
83353 temp1 = pSchema->tblHash;
83354 temp2 = pSchema->trigHash;
83355 sqlite3HashInit(&pSchema->trigHash);
83356 sqlite3HashClear(&pSchema->idxHash);
83357 for(pElem=sqliteHashFirst(&temp2); pElem; pElem=sqliteHashNext(pElem)){
83358 sqlite3DeleteTrigger(0, (Trigger*)sqliteHashData(pElem));
83360 sqlite3HashClear(&temp2);
83361 sqlite3HashInit(&pSchema->tblHash);
83362 for(pElem=sqliteHashFirst(&temp1); pElem; pElem=sqliteHashNext(pElem)){
83363 Table *pTab = sqliteHashData(pElem);
83364 sqlite3DeleteTable(0, pTab);
83366 sqlite3HashClear(&temp1);
83367 sqlite3HashClear(&pSchema->fkeyHash);
83368 pSchema->pSeqTab = 0;
83369 if( pSchema->flags & DB_SchemaLoaded ){
83370 pSchema->iGeneration++;
83371 pSchema->flags &= ~DB_SchemaLoaded;
83376 ** Find and return the schema associated with a BTree. Create
83377 ** a new one if necessary.
83379 SQLITE_PRIVATE Schema *sqlite3SchemaGet(sqlite3 *db, Btree *pBt){
83380 Schema * p;
83381 if( pBt ){
83382 p = (Schema *)sqlite3BtreeSchema(pBt, sizeof(Schema), sqlite3SchemaClear);
83383 }else{
83384 p = (Schema *)sqlite3DbMallocZero(0, sizeof(Schema));
83386 if( !p ){
83387 db->mallocFailed = 1;
83388 }else if ( 0==p->file_format ){
83389 sqlite3HashInit(&p->tblHash);
83390 sqlite3HashInit(&p->idxHash);
83391 sqlite3HashInit(&p->trigHash);
83392 sqlite3HashInit(&p->fkeyHash);
83393 p->enc = SQLITE_UTF8;
83395 return p;
83398 /************** End of callback.c ********************************************/
83399 /************** Begin file delete.c ******************************************/
83401 ** 2001 September 15
83403 ** The author disclaims copyright to this source code. In place of
83404 ** a legal notice, here is a blessing:
83406 ** May you do good and not evil.
83407 ** May you find forgiveness for yourself and forgive others.
83408 ** May you share freely, never taking more than you give.
83410 *************************************************************************
83411 ** This file contains C code routines that are called by the parser
83412 ** in order to generate code for DELETE FROM statements.
83416 ** While a SrcList can in general represent multiple tables and subqueries
83417 ** (as in the FROM clause of a SELECT statement) in this case it contains
83418 ** the name of a single table, as one might find in an INSERT, DELETE,
83419 ** or UPDATE statement. Look up that table in the symbol table and
83420 ** return a pointer. Set an error message and return NULL if the table
83421 ** name is not found or if any other error occurs.
83423 ** The following fields are initialized appropriate in pSrc:
83425 ** pSrc->a[0].pTab Pointer to the Table object
83426 ** pSrc->a[0].pIndex Pointer to the INDEXED BY index, if there is one
83429 SQLITE_PRIVATE Table *sqlite3SrcListLookup(Parse *pParse, SrcList *pSrc){
83430 struct SrcList_item *pItem = pSrc->a;
83431 Table *pTab;
83432 assert( pItem && pSrc->nSrc==1 );
83433 pTab = sqlite3LocateTable(pParse, 0, pItem->zName, pItem->zDatabase);
83434 sqlite3DeleteTable(pParse->db, pItem->pTab);
83435 pItem->pTab = pTab;
83436 if( pTab ){
83437 pTab->nRef++;
83439 if( sqlite3IndexedByLookup(pParse, pItem) ){
83440 pTab = 0;
83442 return pTab;
83446 ** Check to make sure the given table is writable. If it is not
83447 ** writable, generate an error message and return 1. If it is
83448 ** writable return 0;
83450 SQLITE_PRIVATE int sqlite3IsReadOnly(Parse *pParse, Table *pTab, int viewOk){
83451 /* A table is not writable under the following circumstances:
83453 ** 1) It is a virtual table and no implementation of the xUpdate method
83454 ** has been provided, or
83455 ** 2) It is a system table (i.e. sqlite_master), this call is not
83456 ** part of a nested parse and writable_schema pragma has not
83457 ** been specified.
83459 ** In either case leave an error message in pParse and return non-zero.
83461 if( ( IsVirtual(pTab)
83462 && sqlite3GetVTable(pParse->db, pTab)->pMod->pModule->xUpdate==0 )
83463 || ( (pTab->tabFlags & TF_Readonly)!=0
83464 && (pParse->db->flags & SQLITE_WriteSchema)==0
83465 && pParse->nested==0 )
83467 sqlite3ErrorMsg(pParse, "table %s may not be modified", pTab->zName);
83468 return 1;
83471 #ifndef SQLITE_OMIT_VIEW
83472 if( !viewOk && pTab->pSelect ){
83473 sqlite3ErrorMsg(pParse,"cannot modify %s because it is a view",pTab->zName);
83474 return 1;
83476 #endif
83477 return 0;
83481 #if !defined(SQLITE_OMIT_VIEW) && !defined(SQLITE_OMIT_TRIGGER)
83483 ** Evaluate a view and store its result in an ephemeral table. The
83484 ** pWhere argument is an optional WHERE clause that restricts the
83485 ** set of rows in the view that are to be added to the ephemeral table.
83487 SQLITE_PRIVATE void sqlite3MaterializeView(
83488 Parse *pParse, /* Parsing context */
83489 Table *pView, /* View definition */
83490 Expr *pWhere, /* Optional WHERE clause to be added */
83491 int iCur /* Cursor number for ephemerial table */
83493 SelectDest dest;
83494 Select *pDup;
83495 sqlite3 *db = pParse->db;
83497 pDup = sqlite3SelectDup(db, pView->pSelect, 0);
83498 if( pWhere ){
83499 SrcList *pFrom;
83501 pWhere = sqlite3ExprDup(db, pWhere, 0);
83502 pFrom = sqlite3SrcListAppend(db, 0, 0, 0);
83503 if( pFrom ){
83504 assert( pFrom->nSrc==1 );
83505 pFrom->a[0].zAlias = sqlite3DbStrDup(db, pView->zName);
83506 pFrom->a[0].pSelect = pDup;
83507 assert( pFrom->a[0].pOn==0 );
83508 assert( pFrom->a[0].pUsing==0 );
83509 }else{
83510 sqlite3SelectDelete(db, pDup);
83512 pDup = sqlite3SelectNew(pParse, 0, pFrom, pWhere, 0, 0, 0, 0, 0, 0);
83514 sqlite3SelectDestInit(&dest, SRT_EphemTab, iCur);
83515 sqlite3Select(pParse, pDup, &dest);
83516 sqlite3SelectDelete(db, pDup);
83518 #endif /* !defined(SQLITE_OMIT_VIEW) && !defined(SQLITE_OMIT_TRIGGER) */
83520 #if defined(SQLITE_ENABLE_UPDATE_DELETE_LIMIT) && !defined(SQLITE_OMIT_SUBQUERY)
83522 ** Generate an expression tree to implement the WHERE, ORDER BY,
83523 ** and LIMIT/OFFSET portion of DELETE and UPDATE statements.
83525 ** DELETE FROM table_wxyz WHERE a<5 ORDER BY a LIMIT 1;
83526 ** \__________________________/
83527 ** pLimitWhere (pInClause)
83529 SQLITE_PRIVATE Expr *sqlite3LimitWhere(
83530 Parse *pParse, /* The parser context */
83531 SrcList *pSrc, /* the FROM clause -- which tables to scan */
83532 Expr *pWhere, /* The WHERE clause. May be null */
83533 ExprList *pOrderBy, /* The ORDER BY clause. May be null */
83534 Expr *pLimit, /* The LIMIT clause. May be null */
83535 Expr *pOffset, /* The OFFSET clause. May be null */
83536 char *zStmtType /* Either DELETE or UPDATE. For error messages. */
83538 Expr *pWhereRowid = NULL; /* WHERE rowid .. */
83539 Expr *pInClause = NULL; /* WHERE rowid IN ( select ) */
83540 Expr *pSelectRowid = NULL; /* SELECT rowid ... */
83541 ExprList *pEList = NULL; /* Expression list contaning only pSelectRowid */
83542 SrcList *pSelectSrc = NULL; /* SELECT rowid FROM x ... (dup of pSrc) */
83543 Select *pSelect = NULL; /* Complete SELECT tree */
83545 /* Check that there isn't an ORDER BY without a LIMIT clause.
83547 if( pOrderBy && (pLimit == 0) ) {
83548 sqlite3ErrorMsg(pParse, "ORDER BY without LIMIT on %s", zStmtType);
83549 pParse->parseError = 1;
83550 goto limit_where_cleanup_2;
83553 /* We only need to generate a select expression if there
83554 ** is a limit/offset term to enforce.
83556 if( pLimit == 0 ) {
83557 /* if pLimit is null, pOffset will always be null as well. */
83558 assert( pOffset == 0 );
83559 return pWhere;
83562 /* Generate a select expression tree to enforce the limit/offset
83563 ** term for the DELETE or UPDATE statement. For example:
83564 ** DELETE FROM table_a WHERE col1=1 ORDER BY col2 LIMIT 1 OFFSET 1
83565 ** becomes:
83566 ** DELETE FROM table_a WHERE rowid IN (
83567 ** SELECT rowid FROM table_a WHERE col1=1 ORDER BY col2 LIMIT 1 OFFSET 1
83568 ** );
83571 pSelectRowid = sqlite3PExpr(pParse, TK_ROW, 0, 0, 0);
83572 if( pSelectRowid == 0 ) goto limit_where_cleanup_2;
83573 pEList = sqlite3ExprListAppend(pParse, 0, pSelectRowid);
83574 if( pEList == 0 ) goto limit_where_cleanup_2;
83576 /* duplicate the FROM clause as it is needed by both the DELETE/UPDATE tree
83577 ** and the SELECT subtree. */
83578 pSelectSrc = sqlite3SrcListDup(pParse->db, pSrc, 0);
83579 if( pSelectSrc == 0 ) {
83580 sqlite3ExprListDelete(pParse->db, pEList);
83581 goto limit_where_cleanup_2;
83584 /* generate the SELECT expression tree. */
83585 pSelect = sqlite3SelectNew(pParse,pEList,pSelectSrc,pWhere,0,0,
83586 pOrderBy,0,pLimit,pOffset);
83587 if( pSelect == 0 ) return 0;
83589 /* now generate the new WHERE rowid IN clause for the DELETE/UDPATE */
83590 pWhereRowid = sqlite3PExpr(pParse, TK_ROW, 0, 0, 0);
83591 if( pWhereRowid == 0 ) goto limit_where_cleanup_1;
83592 pInClause = sqlite3PExpr(pParse, TK_IN, pWhereRowid, 0, 0);
83593 if( pInClause == 0 ) goto limit_where_cleanup_1;
83595 pInClause->x.pSelect = pSelect;
83596 pInClause->flags |= EP_xIsSelect;
83597 sqlite3ExprSetHeight(pParse, pInClause);
83598 return pInClause;
83600 /* something went wrong. clean up anything allocated. */
83601 limit_where_cleanup_1:
83602 sqlite3SelectDelete(pParse->db, pSelect);
83603 return 0;
83605 limit_where_cleanup_2:
83606 sqlite3ExprDelete(pParse->db, pWhere);
83607 sqlite3ExprListDelete(pParse->db, pOrderBy);
83608 sqlite3ExprDelete(pParse->db, pLimit);
83609 sqlite3ExprDelete(pParse->db, pOffset);
83610 return 0;
83612 #endif /* defined(SQLITE_ENABLE_UPDATE_DELETE_LIMIT) && !defined(SQLITE_OMIT_SUBQUERY) */
83615 ** Generate code for a DELETE FROM statement.
83617 ** DELETE FROM table_wxyz WHERE a<5 AND b NOT NULL;
83618 ** \________/ \________________/
83619 ** pTabList pWhere
83621 SQLITE_PRIVATE void sqlite3DeleteFrom(
83622 Parse *pParse, /* The parser context */
83623 SrcList *pTabList, /* The table from which we should delete things */
83624 Expr *pWhere /* The WHERE clause. May be null */
83626 Vdbe *v; /* The virtual database engine */
83627 Table *pTab; /* The table from which records will be deleted */
83628 const char *zDb; /* Name of database holding pTab */
83629 int end, addr = 0; /* A couple addresses of generated code */
83630 int i; /* Loop counter */
83631 WhereInfo *pWInfo; /* Information about the WHERE clause */
83632 Index *pIdx; /* For looping over indices of the table */
83633 int iCur; /* VDBE Cursor number for pTab */
83634 sqlite3 *db; /* Main database structure */
83635 AuthContext sContext; /* Authorization context */
83636 NameContext sNC; /* Name context to resolve expressions in */
83637 int iDb; /* Database number */
83638 int memCnt = -1; /* Memory cell used for change counting */
83639 int rcauth; /* Value returned by authorization callback */
83641 #ifndef SQLITE_OMIT_TRIGGER
83642 int isView; /* True if attempting to delete from a view */
83643 Trigger *pTrigger; /* List of table triggers, if required */
83644 #endif
83646 memset(&sContext, 0, sizeof(sContext));
83647 db = pParse->db;
83648 if( pParse->nErr || db->mallocFailed ){
83649 goto delete_from_cleanup;
83651 assert( pTabList->nSrc==1 );
83653 /* Locate the table which we want to delete. This table has to be
83654 ** put in an SrcList structure because some of the subroutines we
83655 ** will be calling are designed to work with multiple tables and expect
83656 ** an SrcList* parameter instead of just a Table* parameter.
83658 pTab = sqlite3SrcListLookup(pParse, pTabList);
83659 if( pTab==0 ) goto delete_from_cleanup;
83661 /* Figure out if we have any triggers and if the table being
83662 ** deleted from is a view
83664 #ifndef SQLITE_OMIT_TRIGGER
83665 pTrigger = sqlite3TriggersExist(pParse, pTab, TK_DELETE, 0, 0);
83666 isView = pTab->pSelect!=0;
83667 #else
83668 # define pTrigger 0
83669 # define isView 0
83670 #endif
83671 #ifdef SQLITE_OMIT_VIEW
83672 # undef isView
83673 # define isView 0
83674 #endif
83676 /* If pTab is really a view, make sure it has been initialized.
83678 if( sqlite3ViewGetColumnNames(pParse, pTab) ){
83679 goto delete_from_cleanup;
83682 if( sqlite3IsReadOnly(pParse, pTab, (pTrigger?1:0)) ){
83683 goto delete_from_cleanup;
83685 iDb = sqlite3SchemaToIndex(db, pTab->pSchema);
83686 assert( iDb<db->nDb );
83687 zDb = db->aDb[iDb].zName;
83688 rcauth = sqlite3AuthCheck(pParse, SQLITE_DELETE, pTab->zName, 0, zDb);
83689 assert( rcauth==SQLITE_OK || rcauth==SQLITE_DENY || rcauth==SQLITE_IGNORE );
83690 if( rcauth==SQLITE_DENY ){
83691 goto delete_from_cleanup;
83693 assert(!isView || pTrigger);
83695 /* Assign cursor number to the table and all its indices.
83697 assert( pTabList->nSrc==1 );
83698 iCur = pTabList->a[0].iCursor = pParse->nTab++;
83699 for(pIdx=pTab->pIndex; pIdx; pIdx=pIdx->pNext){
83700 pParse->nTab++;
83703 /* Start the view context
83705 if( isView ){
83706 sqlite3AuthContextPush(pParse, &sContext, pTab->zName);
83709 /* Begin generating code.
83711 v = sqlite3GetVdbe(pParse);
83712 if( v==0 ){
83713 goto delete_from_cleanup;
83715 if( pParse->nested==0 ) sqlite3VdbeCountChanges(v);
83716 sqlite3BeginWriteOperation(pParse, 1, iDb);
83718 /* If we are trying to delete from a view, realize that view into
83719 ** a ephemeral table.
83721 #if !defined(SQLITE_OMIT_VIEW) && !defined(SQLITE_OMIT_TRIGGER)
83722 if( isView ){
83723 sqlite3MaterializeView(pParse, pTab, pWhere, iCur);
83725 #endif
83727 /* Resolve the column names in the WHERE clause.
83729 memset(&sNC, 0, sizeof(sNC));
83730 sNC.pParse = pParse;
83731 sNC.pSrcList = pTabList;
83732 if( sqlite3ResolveExprNames(&sNC, pWhere) ){
83733 goto delete_from_cleanup;
83736 /* Initialize the counter of the number of rows deleted, if
83737 ** we are counting rows.
83739 if( db->flags & SQLITE_CountRows ){
83740 memCnt = ++pParse->nMem;
83741 sqlite3VdbeAddOp2(v, OP_Integer, 0, memCnt);
83744 #ifndef SQLITE_OMIT_TRUNCATE_OPTIMIZATION
83745 /* Special case: A DELETE without a WHERE clause deletes everything.
83746 ** It is easier just to erase the whole table. Prior to version 3.6.5,
83747 ** this optimization caused the row change count (the value returned by
83748 ** API function sqlite3_count_changes) to be set incorrectly. */
83749 if( rcauth==SQLITE_OK && pWhere==0 && !pTrigger && !IsVirtual(pTab)
83750 && 0==sqlite3FkRequired(pParse, pTab, 0, 0)
83752 assert( !isView );
83753 sqlite3VdbeAddOp4(v, OP_Clear, pTab->tnum, iDb, memCnt,
83754 pTab->zName, P4_STATIC);
83755 for(pIdx=pTab->pIndex; pIdx; pIdx=pIdx->pNext){
83756 assert( pIdx->pSchema==pTab->pSchema );
83757 sqlite3VdbeAddOp2(v, OP_Clear, pIdx->tnum, iDb);
83759 }else
83760 #endif /* SQLITE_OMIT_TRUNCATE_OPTIMIZATION */
83761 /* The usual case: There is a WHERE clause so we have to scan through
83762 ** the table and pick which records to delete.
83765 int iRowSet = ++pParse->nMem; /* Register for rowset of rows to delete */
83766 int iRowid = ++pParse->nMem; /* Used for storing rowid values. */
83767 int regRowid; /* Actual register containing rowids */
83769 /* Collect rowids of every row to be deleted.
83771 sqlite3VdbeAddOp2(v, OP_Null, 0, iRowSet);
83772 pWInfo = sqlite3WhereBegin(
83773 pParse, pTabList, pWhere, 0, 0, WHERE_DUPLICATES_OK
83775 if( pWInfo==0 ) goto delete_from_cleanup;
83776 regRowid = sqlite3ExprCodeGetColumn(pParse, pTab, -1, iCur, iRowid);
83777 sqlite3VdbeAddOp2(v, OP_RowSetAdd, iRowSet, regRowid);
83778 if( db->flags & SQLITE_CountRows ){
83779 sqlite3VdbeAddOp2(v, OP_AddImm, memCnt, 1);
83781 sqlite3WhereEnd(pWInfo);
83783 /* Delete every item whose key was written to the list during the
83784 ** database scan. We have to delete items after the scan is complete
83785 ** because deleting an item can change the scan order. */
83786 end = sqlite3VdbeMakeLabel(v);
83788 /* Unless this is a view, open cursors for the table we are
83789 ** deleting from and all its indices. If this is a view, then the
83790 ** only effect this statement has is to fire the INSTEAD OF
83791 ** triggers. */
83792 if( !isView ){
83793 sqlite3OpenTableAndIndices(pParse, pTab, iCur, OP_OpenWrite);
83796 addr = sqlite3VdbeAddOp3(v, OP_RowSetRead, iRowSet, end, iRowid);
83798 /* Delete the row */
83799 #ifndef SQLITE_OMIT_VIRTUALTABLE
83800 if( IsVirtual(pTab) ){
83801 const char *pVTab = (const char *)sqlite3GetVTable(db, pTab);
83802 sqlite3VtabMakeWritable(pParse, pTab);
83803 sqlite3VdbeAddOp4(v, OP_VUpdate, 0, 1, iRowid, pVTab, P4_VTAB);
83804 sqlite3VdbeChangeP5(v, OE_Abort);
83805 sqlite3MayAbort(pParse);
83806 }else
83807 #endif
83809 int count = (pParse->nested==0); /* True to count changes */
83810 sqlite3GenerateRowDelete(pParse, pTab, iCur, iRowid, count, pTrigger, OE_Default);
83813 /* End of the delete loop */
83814 sqlite3VdbeAddOp2(v, OP_Goto, 0, addr);
83815 sqlite3VdbeResolveLabel(v, end);
83817 /* Close the cursors open on the table and its indexes. */
83818 if( !isView && !IsVirtual(pTab) ){
83819 for(i=1, pIdx=pTab->pIndex; pIdx; i++, pIdx=pIdx->pNext){
83820 sqlite3VdbeAddOp2(v, OP_Close, iCur + i, pIdx->tnum);
83822 sqlite3VdbeAddOp1(v, OP_Close, iCur);
83826 /* Update the sqlite_sequence table by storing the content of the
83827 ** maximum rowid counter values recorded while inserting into
83828 ** autoincrement tables.
83830 if( pParse->nested==0 && pParse->pTriggerTab==0 ){
83831 sqlite3AutoincrementEnd(pParse);
83834 /* Return the number of rows that were deleted. If this routine is
83835 ** generating code because of a call to sqlite3NestedParse(), do not
83836 ** invoke the callback function.
83838 if( (db->flags&SQLITE_CountRows) && !pParse->nested && !pParse->pTriggerTab ){
83839 sqlite3VdbeAddOp2(v, OP_ResultRow, memCnt, 1);
83840 sqlite3VdbeSetNumCols(v, 1);
83841 sqlite3VdbeSetColName(v, 0, COLNAME_NAME, "rows deleted", SQLITE_STATIC);
83844 delete_from_cleanup:
83845 sqlite3AuthContextPop(&sContext);
83846 sqlite3SrcListDelete(db, pTabList);
83847 sqlite3ExprDelete(db, pWhere);
83848 return;
83850 /* Make sure "isView" and other macros defined above are undefined. Otherwise
83851 ** thely may interfere with compilation of other functions in this file
83852 ** (or in another file, if this file becomes part of the amalgamation). */
83853 #ifdef isView
83854 #undef isView
83855 #endif
83856 #ifdef pTrigger
83857 #undef pTrigger
83858 #endif
83861 ** This routine generates VDBE code that causes a single row of a
83862 ** single table to be deleted.
83864 ** The VDBE must be in a particular state when this routine is called.
83865 ** These are the requirements:
83867 ** 1. A read/write cursor pointing to pTab, the table containing the row
83868 ** to be deleted, must be opened as cursor number $iCur.
83870 ** 2. Read/write cursors for all indices of pTab must be open as
83871 ** cursor number base+i for the i-th index.
83873 ** 3. The record number of the row to be deleted must be stored in
83874 ** memory cell iRowid.
83876 ** This routine generates code to remove both the table record and all
83877 ** index entries that point to that record.
83879 SQLITE_PRIVATE void sqlite3GenerateRowDelete(
83880 Parse *pParse, /* Parsing context */
83881 Table *pTab, /* Table containing the row to be deleted */
83882 int iCur, /* Cursor number for the table */
83883 int iRowid, /* Memory cell that contains the rowid to delete */
83884 int count, /* If non-zero, increment the row change counter */
83885 Trigger *pTrigger, /* List of triggers to (potentially) fire */
83886 int onconf /* Default ON CONFLICT policy for triggers */
83888 Vdbe *v = pParse->pVdbe; /* Vdbe */
83889 int iOld = 0; /* First register in OLD.* array */
83890 int iLabel; /* Label resolved to end of generated code */
83892 /* Vdbe is guaranteed to have been allocated by this stage. */
83893 assert( v );
83895 /* Seek cursor iCur to the row to delete. If this row no longer exists
83896 ** (this can happen if a trigger program has already deleted it), do
83897 ** not attempt to delete it or fire any DELETE triggers. */
83898 iLabel = sqlite3VdbeMakeLabel(v);
83899 sqlite3VdbeAddOp3(v, OP_NotExists, iCur, iLabel, iRowid);
83901 /* If there are any triggers to fire, allocate a range of registers to
83902 ** use for the old.* references in the triggers. */
83903 if( sqlite3FkRequired(pParse, pTab, 0, 0) || pTrigger ){
83904 u32 mask; /* Mask of OLD.* columns in use */
83905 int iCol; /* Iterator used while populating OLD.* */
83907 /* TODO: Could use temporary registers here. Also could attempt to
83908 ** avoid copying the contents of the rowid register. */
83909 mask = sqlite3TriggerColmask(
83910 pParse, pTrigger, 0, 0, TRIGGER_BEFORE|TRIGGER_AFTER, pTab, onconf
83912 mask |= sqlite3FkOldmask(pParse, pTab);
83913 iOld = pParse->nMem+1;
83914 pParse->nMem += (1 + pTab->nCol);
83916 /* Populate the OLD.* pseudo-table register array. These values will be
83917 ** used by any BEFORE and AFTER triggers that exist. */
83918 sqlite3VdbeAddOp2(v, OP_Copy, iRowid, iOld);
83919 for(iCol=0; iCol<pTab->nCol; iCol++){
83920 if( mask==0xffffffff || mask&(1<<iCol) ){
83921 sqlite3ExprCodeGetColumnOfTable(v, pTab, iCur, iCol, iOld+iCol+1);
83925 /* Invoke BEFORE DELETE trigger programs. */
83926 sqlite3CodeRowTrigger(pParse, pTrigger,
83927 TK_DELETE, 0, TRIGGER_BEFORE, pTab, iOld, onconf, iLabel
83930 /* Seek the cursor to the row to be deleted again. It may be that
83931 ** the BEFORE triggers coded above have already removed the row
83932 ** being deleted. Do not attempt to delete the row a second time, and
83933 ** do not fire AFTER triggers. */
83934 sqlite3VdbeAddOp3(v, OP_NotExists, iCur, iLabel, iRowid);
83936 /* Do FK processing. This call checks that any FK constraints that
83937 ** refer to this table (i.e. constraints attached to other tables)
83938 ** are not violated by deleting this row. */
83939 sqlite3FkCheck(pParse, pTab, iOld, 0);
83942 /* Delete the index and table entries. Skip this step if pTab is really
83943 ** a view (in which case the only effect of the DELETE statement is to
83944 ** fire the INSTEAD OF triggers). */
83945 if( pTab->pSelect==0 ){
83946 sqlite3GenerateRowIndexDelete(pParse, pTab, iCur, 0);
83947 sqlite3VdbeAddOp2(v, OP_Delete, iCur, (count?OPFLAG_NCHANGE:0));
83948 if( count ){
83949 sqlite3VdbeChangeP4(v, -1, pTab->zName, P4_TRANSIENT);
83953 /* Do any ON CASCADE, SET NULL or SET DEFAULT operations required to
83954 ** handle rows (possibly in other tables) that refer via a foreign key
83955 ** to the row just deleted. */
83956 sqlite3FkActions(pParse, pTab, 0, iOld);
83958 /* Invoke AFTER DELETE trigger programs. */
83959 sqlite3CodeRowTrigger(pParse, pTrigger,
83960 TK_DELETE, 0, TRIGGER_AFTER, pTab, iOld, onconf, iLabel
83963 /* Jump here if the row had already been deleted before any BEFORE
83964 ** trigger programs were invoked. Or if a trigger program throws a
83965 ** RAISE(IGNORE) exception. */
83966 sqlite3VdbeResolveLabel(v, iLabel);
83970 ** This routine generates VDBE code that causes the deletion of all
83971 ** index entries associated with a single row of a single table.
83973 ** The VDBE must be in a particular state when this routine is called.
83974 ** These are the requirements:
83976 ** 1. A read/write cursor pointing to pTab, the table containing the row
83977 ** to be deleted, must be opened as cursor number "iCur".
83979 ** 2. Read/write cursors for all indices of pTab must be open as
83980 ** cursor number iCur+i for the i-th index.
83982 ** 3. The "iCur" cursor must be pointing to the row that is to be
83983 ** deleted.
83985 SQLITE_PRIVATE void sqlite3GenerateRowIndexDelete(
83986 Parse *pParse, /* Parsing and code generating context */
83987 Table *pTab, /* Table containing the row to be deleted */
83988 int iCur, /* Cursor number for the table */
83989 int *aRegIdx /* Only delete if aRegIdx!=0 && aRegIdx[i]>0 */
83991 int i;
83992 Index *pIdx;
83993 int r1;
83995 for(i=1, pIdx=pTab->pIndex; pIdx; i++, pIdx=pIdx->pNext){
83996 if( aRegIdx!=0 && aRegIdx[i-1]==0 ) continue;
83997 r1 = sqlite3GenerateIndexKey(pParse, pIdx, iCur, 0, 0);
83998 sqlite3VdbeAddOp3(pParse->pVdbe, OP_IdxDelete, iCur+i, r1,pIdx->nColumn+1);
84003 ** Generate code that will assemble an index key and put it in register
84004 ** regOut. The key with be for index pIdx which is an index on pTab.
84005 ** iCur is the index of a cursor open on the pTab table and pointing to
84006 ** the entry that needs indexing.
84008 ** Return a register number which is the first in a block of
84009 ** registers that holds the elements of the index key. The
84010 ** block of registers has already been deallocated by the time
84011 ** this routine returns.
84013 SQLITE_PRIVATE int sqlite3GenerateIndexKey(
84014 Parse *pParse, /* Parsing context */
84015 Index *pIdx, /* The index for which to generate a key */
84016 int iCur, /* Cursor number for the pIdx->pTable table */
84017 int regOut, /* Write the new index key to this register */
84018 int doMakeRec /* Run the OP_MakeRecord instruction if true */
84020 Vdbe *v = pParse->pVdbe;
84021 int j;
84022 Table *pTab = pIdx->pTable;
84023 int regBase;
84024 int nCol;
84026 nCol = pIdx->nColumn;
84027 regBase = sqlite3GetTempRange(pParse, nCol+1);
84028 sqlite3VdbeAddOp2(v, OP_Rowid, iCur, regBase+nCol);
84029 for(j=0; j<nCol; j++){
84030 int idx = pIdx->aiColumn[j];
84031 if( idx==pTab->iPKey ){
84032 sqlite3VdbeAddOp2(v, OP_SCopy, regBase+nCol, regBase+j);
84033 }else{
84034 sqlite3VdbeAddOp3(v, OP_Column, iCur, idx, regBase+j);
84035 sqlite3ColumnDefault(v, pTab, idx, -1);
84038 if( doMakeRec ){
84039 const char *zAff;
84040 if( pTab->pSelect || (pParse->db->flags & SQLITE_IdxRealAsInt)!=0 ){
84041 zAff = 0;
84042 }else{
84043 zAff = sqlite3IndexAffinityStr(v, pIdx);
84045 sqlite3VdbeAddOp3(v, OP_MakeRecord, regBase, nCol+1, regOut);
84046 sqlite3VdbeChangeP4(v, -1, zAff, P4_TRANSIENT);
84048 sqlite3ReleaseTempRange(pParse, regBase, nCol+1);
84049 return regBase;
84052 /************** End of delete.c **********************************************/
84053 /************** Begin file func.c ********************************************/
84055 ** 2002 February 23
84057 ** The author disclaims copyright to this source code. In place of
84058 ** a legal notice, here is a blessing:
84060 ** May you do good and not evil.
84061 ** May you find forgiveness for yourself and forgive others.
84062 ** May you share freely, never taking more than you give.
84064 *************************************************************************
84065 ** This file contains the C functions that implement various SQL
84066 ** functions of SQLite.
84068 ** There is only one exported symbol in this file - the function
84069 ** sqliteRegisterBuildinFunctions() found at the bottom of the file.
84070 ** All other code has file scope.
84072 /* #include <stdlib.h> */
84073 /* #include <assert.h> */
84076 ** Return the collating function associated with a function.
84078 static CollSeq *sqlite3GetFuncCollSeq(sqlite3_context *context){
84079 return context->pColl;
84083 ** Implementation of the non-aggregate min() and max() functions
84085 static void minmaxFunc(
84086 sqlite3_context *context,
84087 int argc,
84088 sqlite3_value **argv
84090 int i;
84091 int mask; /* 0 for min() or 0xffffffff for max() */
84092 int iBest;
84093 CollSeq *pColl;
84095 assert( argc>1 );
84096 mask = sqlite3_user_data(context)==0 ? 0 : -1;
84097 pColl = sqlite3GetFuncCollSeq(context);
84098 assert( pColl );
84099 assert( mask==-1 || mask==0 );
84100 iBest = 0;
84101 if( sqlite3_value_type(argv[0])==SQLITE_NULL ) return;
84102 for(i=1; i<argc; i++){
84103 if( sqlite3_value_type(argv[i])==SQLITE_NULL ) return;
84104 if( (sqlite3MemCompare(argv[iBest], argv[i], pColl)^mask)>=0 ){
84105 testcase( mask==0 );
84106 iBest = i;
84109 sqlite3_result_value(context, argv[iBest]);
84113 ** Return the type of the argument.
84115 static void typeofFunc(
84116 sqlite3_context *context,
84117 int NotUsed,
84118 sqlite3_value **argv
84120 const char *z = 0;
84121 UNUSED_PARAMETER(NotUsed);
84122 switch( sqlite3_value_type(argv[0]) ){
84123 case SQLITE_INTEGER: z = "integer"; break;
84124 case SQLITE_TEXT: z = "text"; break;
84125 case SQLITE_FLOAT: z = "real"; break;
84126 case SQLITE_BLOB: z = "blob"; break;
84127 default: z = "null"; break;
84129 sqlite3_result_text(context, z, -1, SQLITE_STATIC);
84134 ** Implementation of the length() function
84136 static void lengthFunc(
84137 sqlite3_context *context,
84138 int argc,
84139 sqlite3_value **argv
84141 int len;
84143 assert( argc==1 );
84144 UNUSED_PARAMETER(argc);
84145 switch( sqlite3_value_type(argv[0]) ){
84146 case SQLITE_BLOB:
84147 case SQLITE_INTEGER:
84148 case SQLITE_FLOAT: {
84149 sqlite3_result_int(context, sqlite3_value_bytes(argv[0]));
84150 break;
84152 case SQLITE_TEXT: {
84153 const unsigned char *z = sqlite3_value_text(argv[0]);
84154 if( z==0 ) return;
84155 len = 0;
84156 while( *z ){
84157 len++;
84158 SQLITE_SKIP_UTF8(z);
84160 sqlite3_result_int(context, len);
84161 break;
84163 default: {
84164 sqlite3_result_null(context);
84165 break;
84171 ** Implementation of the abs() function.
84173 ** IMP: R-23979-26855 The abs(X) function returns the absolute value of
84174 ** the numeric argument X.
84176 static void absFunc(sqlite3_context *context, int argc, sqlite3_value **argv){
84177 assert( argc==1 );
84178 UNUSED_PARAMETER(argc);
84179 switch( sqlite3_value_type(argv[0]) ){
84180 case SQLITE_INTEGER: {
84181 i64 iVal = sqlite3_value_int64(argv[0]);
84182 if( iVal<0 ){
84183 if( (iVal<<1)==0 ){
84184 /* IMP: R-35460-15084 If X is the integer -9223372036854775807 then
84185 ** abs(X) throws an integer overflow error since there is no
84186 ** equivalent positive 64-bit two complement value. */
84187 sqlite3_result_error(context, "integer overflow", -1);
84188 return;
84190 iVal = -iVal;
84192 sqlite3_result_int64(context, iVal);
84193 break;
84195 case SQLITE_NULL: {
84196 /* IMP: R-37434-19929 Abs(X) returns NULL if X is NULL. */
84197 sqlite3_result_null(context);
84198 break;
84200 default: {
84201 /* Because sqlite3_value_double() returns 0.0 if the argument is not
84202 ** something that can be converted into a number, we have:
84203 ** IMP: R-57326-31541 Abs(X) return 0.0 if X is a string or blob that
84204 ** cannot be converted to a numeric value.
84206 double rVal = sqlite3_value_double(argv[0]);
84207 if( rVal<0 ) rVal = -rVal;
84208 sqlite3_result_double(context, rVal);
84209 break;
84215 ** Implementation of the substr() function.
84217 ** substr(x,p1,p2) returns p2 characters of x[] beginning with p1.
84218 ** p1 is 1-indexed. So substr(x,1,1) returns the first character
84219 ** of x. If x is text, then we actually count UTF-8 characters.
84220 ** If x is a blob, then we count bytes.
84222 ** If p1 is negative, then we begin abs(p1) from the end of x[].
84224 ** If p2 is negative, return the p2 characters preceeding p1.
84226 static void substrFunc(
84227 sqlite3_context *context,
84228 int argc,
84229 sqlite3_value **argv
84231 const unsigned char *z;
84232 const unsigned char *z2;
84233 int len;
84234 int p0type;
84235 i64 p1, p2;
84236 int negP2 = 0;
84238 assert( argc==3 || argc==2 );
84239 if( sqlite3_value_type(argv[1])==SQLITE_NULL
84240 || (argc==3 && sqlite3_value_type(argv[2])==SQLITE_NULL)
84242 return;
84244 p0type = sqlite3_value_type(argv[0]);
84245 p1 = sqlite3_value_int(argv[1]);
84246 if( p0type==SQLITE_BLOB ){
84247 len = sqlite3_value_bytes(argv[0]);
84248 z = sqlite3_value_blob(argv[0]);
84249 if( z==0 ) return;
84250 assert( len==sqlite3_value_bytes(argv[0]) );
84251 }else{
84252 z = sqlite3_value_text(argv[0]);
84253 if( z==0 ) return;
84254 len = 0;
84255 if( p1<0 ){
84256 for(z2=z; *z2; len++){
84257 SQLITE_SKIP_UTF8(z2);
84261 if( argc==3 ){
84262 p2 = sqlite3_value_int(argv[2]);
84263 if( p2<0 ){
84264 p2 = -p2;
84265 negP2 = 1;
84267 }else{
84268 p2 = sqlite3_context_db_handle(context)->aLimit[SQLITE_LIMIT_LENGTH];
84270 if( p1<0 ){
84271 p1 += len;
84272 if( p1<0 ){
84273 p2 += p1;
84274 if( p2<0 ) p2 = 0;
84275 p1 = 0;
84277 }else if( p1>0 ){
84278 p1--;
84279 }else if( p2>0 ){
84280 p2--;
84282 if( negP2 ){
84283 p1 -= p2;
84284 if( p1<0 ){
84285 p2 += p1;
84286 p1 = 0;
84289 assert( p1>=0 && p2>=0 );
84290 if( p0type!=SQLITE_BLOB ){
84291 while( *z && p1 ){
84292 SQLITE_SKIP_UTF8(z);
84293 p1--;
84295 for(z2=z; *z2 && p2; p2--){
84296 SQLITE_SKIP_UTF8(z2);
84298 sqlite3_result_text(context, (char*)z, (int)(z2-z), SQLITE_TRANSIENT);
84299 }else{
84300 if( p1+p2>len ){
84301 p2 = len-p1;
84302 if( p2<0 ) p2 = 0;
84304 sqlite3_result_blob(context, (char*)&z[p1], (int)p2, SQLITE_TRANSIENT);
84309 ** Implementation of the round() function
84311 #ifndef SQLITE_OMIT_FLOATING_POINT
84312 static void roundFunc(sqlite3_context *context, int argc, sqlite3_value **argv){
84313 int n = 0;
84314 double r;
84315 char *zBuf;
84316 assert( argc==1 || argc==2 );
84317 if( argc==2 ){
84318 if( SQLITE_NULL==sqlite3_value_type(argv[1]) ) return;
84319 n = sqlite3_value_int(argv[1]);
84320 if( n>30 ) n = 30;
84321 if( n<0 ) n = 0;
84323 if( sqlite3_value_type(argv[0])==SQLITE_NULL ) return;
84324 r = sqlite3_value_double(argv[0]);
84325 /* If Y==0 and X will fit in a 64-bit int,
84326 ** handle the rounding directly,
84327 ** otherwise use printf.
84329 if( n==0 && r>=0 && r<LARGEST_INT64-1 ){
84330 r = (double)((sqlite_int64)(r+0.5));
84331 }else if( n==0 && r<0 && (-r)<LARGEST_INT64-1 ){
84332 r = -(double)((sqlite_int64)((-r)+0.5));
84333 }else{
84334 zBuf = sqlite3_mprintf("%.*f",n,r);
84335 if( zBuf==0 ){
84336 sqlite3_result_error_nomem(context);
84337 return;
84339 sqlite3AtoF(zBuf, &r, sqlite3Strlen30(zBuf), SQLITE_UTF8);
84340 sqlite3_free(zBuf);
84342 sqlite3_result_double(context, r);
84344 #endif
84347 ** Allocate nByte bytes of space using sqlite3_malloc(). If the
84348 ** allocation fails, call sqlite3_result_error_nomem() to notify
84349 ** the database handle that malloc() has failed and return NULL.
84350 ** If nByte is larger than the maximum string or blob length, then
84351 ** raise an SQLITE_TOOBIG exception and return NULL.
84353 static void *contextMalloc(sqlite3_context *context, i64 nByte){
84354 char *z;
84355 sqlite3 *db = sqlite3_context_db_handle(context);
84356 assert( nByte>0 );
84357 testcase( nByte==db->aLimit[SQLITE_LIMIT_LENGTH] );
84358 testcase( nByte==db->aLimit[SQLITE_LIMIT_LENGTH]+1 );
84359 if( nByte>db->aLimit[SQLITE_LIMIT_LENGTH] ){
84360 sqlite3_result_error_toobig(context);
84361 z = 0;
84362 }else{
84363 z = sqlite3Malloc((int)nByte);
84364 if( !z ){
84365 sqlite3_result_error_nomem(context);
84368 return z;
84372 ** Implementation of the upper() and lower() SQL functions.
84374 static void upperFunc(sqlite3_context *context, int argc, sqlite3_value **argv){
84375 char *z1;
84376 const char *z2;
84377 int i, n;
84378 UNUSED_PARAMETER(argc);
84379 z2 = (char*)sqlite3_value_text(argv[0]);
84380 n = sqlite3_value_bytes(argv[0]);
84381 /* Verify that the call to _bytes() does not invalidate the _text() pointer */
84382 assert( z2==(char*)sqlite3_value_text(argv[0]) );
84383 if( z2 ){
84384 z1 = contextMalloc(context, ((i64)n)+1);
84385 if( z1 ){
84386 memcpy(z1, z2, n+1);
84387 for(i=0; z1[i]; i++){
84388 z1[i] = (char)sqlite3Toupper(z1[i]);
84390 sqlite3_result_text(context, z1, -1, sqlite3_free);
84394 static void lowerFunc(sqlite3_context *context, int argc, sqlite3_value **argv){
84395 u8 *z1;
84396 const char *z2;
84397 int i, n;
84398 UNUSED_PARAMETER(argc);
84399 z2 = (char*)sqlite3_value_text(argv[0]);
84400 n = sqlite3_value_bytes(argv[0]);
84401 /* Verify that the call to _bytes() does not invalidate the _text() pointer */
84402 assert( z2==(char*)sqlite3_value_text(argv[0]) );
84403 if( z2 ){
84404 z1 = contextMalloc(context, ((i64)n)+1);
84405 if( z1 ){
84406 memcpy(z1, z2, n+1);
84407 for(i=0; z1[i]; i++){
84408 z1[i] = sqlite3Tolower(z1[i]);
84410 sqlite3_result_text(context, (char *)z1, -1, sqlite3_free);
84416 #if 0 /* This function is never used. */
84418 ** The COALESCE() and IFNULL() functions used to be implemented as shown
84419 ** here. But now they are implemented as VDBE code so that unused arguments
84420 ** do not have to be computed. This legacy implementation is retained as
84421 ** comment.
84424 ** Implementation of the IFNULL(), NVL(), and COALESCE() functions.
84425 ** All three do the same thing. They return the first non-NULL
84426 ** argument.
84428 static void ifnullFunc(
84429 sqlite3_context *context,
84430 int argc,
84431 sqlite3_value **argv
84433 int i;
84434 for(i=0; i<argc; i++){
84435 if( SQLITE_NULL!=sqlite3_value_type(argv[i]) ){
84436 sqlite3_result_value(context, argv[i]);
84437 break;
84441 #endif /* NOT USED */
84442 #define ifnullFunc versionFunc /* Substitute function - never called */
84445 ** Implementation of random(). Return a random integer.
84447 static void randomFunc(
84448 sqlite3_context *context,
84449 int NotUsed,
84450 sqlite3_value **NotUsed2
84452 sqlite_int64 r;
84453 UNUSED_PARAMETER2(NotUsed, NotUsed2);
84454 sqlite3_randomness(sizeof(r), &r);
84455 if( r<0 ){
84456 /* We need to prevent a random number of 0x8000000000000000
84457 ** (or -9223372036854775808) since when you do abs() of that
84458 ** number of you get the same value back again. To do this
84459 ** in a way that is testable, mask the sign bit off of negative
84460 ** values, resulting in a positive value. Then take the
84461 ** 2s complement of that positive value. The end result can
84462 ** therefore be no less than -9223372036854775807.
84464 r = -(r ^ (((sqlite3_int64)1)<<63));
84466 sqlite3_result_int64(context, r);
84470 ** Implementation of randomblob(N). Return a random blob
84471 ** that is N bytes long.
84473 static void randomBlob(
84474 sqlite3_context *context,
84475 int argc,
84476 sqlite3_value **argv
84478 int n;
84479 unsigned char *p;
84480 assert( argc==1 );
84481 UNUSED_PARAMETER(argc);
84482 n = sqlite3_value_int(argv[0]);
84483 if( n<1 ){
84484 n = 1;
84486 p = contextMalloc(context, n);
84487 if( p ){
84488 sqlite3_randomness(n, p);
84489 sqlite3_result_blob(context, (char*)p, n, sqlite3_free);
84494 ** Implementation of the last_insert_rowid() SQL function. The return
84495 ** value is the same as the sqlite3_last_insert_rowid() API function.
84497 static void last_insert_rowid(
84498 sqlite3_context *context,
84499 int NotUsed,
84500 sqlite3_value **NotUsed2
84502 sqlite3 *db = sqlite3_context_db_handle(context);
84503 UNUSED_PARAMETER2(NotUsed, NotUsed2);
84504 /* IMP: R-51513-12026 The last_insert_rowid() SQL function is a
84505 ** wrapper around the sqlite3_last_insert_rowid() C/C++ interface
84506 ** function. */
84507 sqlite3_result_int64(context, sqlite3_last_insert_rowid(db));
84511 ** Implementation of the changes() SQL function.
84513 ** IMP: R-62073-11209 The changes() SQL function is a wrapper
84514 ** around the sqlite3_changes() C/C++ function and hence follows the same
84515 ** rules for counting changes.
84517 static void changes(
84518 sqlite3_context *context,
84519 int NotUsed,
84520 sqlite3_value **NotUsed2
84522 sqlite3 *db = sqlite3_context_db_handle(context);
84523 UNUSED_PARAMETER2(NotUsed, NotUsed2);
84524 sqlite3_result_int(context, sqlite3_changes(db));
84528 ** Implementation of the total_changes() SQL function. The return value is
84529 ** the same as the sqlite3_total_changes() API function.
84531 static void total_changes(
84532 sqlite3_context *context,
84533 int NotUsed,
84534 sqlite3_value **NotUsed2
84536 sqlite3 *db = sqlite3_context_db_handle(context);
84537 UNUSED_PARAMETER2(NotUsed, NotUsed2);
84538 /* IMP: R-52756-41993 This function is a wrapper around the
84539 ** sqlite3_total_changes() C/C++ interface. */
84540 sqlite3_result_int(context, sqlite3_total_changes(db));
84544 ** A structure defining how to do GLOB-style comparisons.
84546 struct compareInfo {
84547 u8 matchAll;
84548 u8 matchOne;
84549 u8 matchSet;
84550 u8 noCase;
84554 ** For LIKE and GLOB matching on EBCDIC machines, assume that every
84555 ** character is exactly one byte in size. Also, all characters are
84556 ** able to participate in upper-case-to-lower-case mappings in EBCDIC
84557 ** whereas only characters less than 0x80 do in ASCII.
84559 #if defined(SQLITE_EBCDIC)
84560 # define sqlite3Utf8Read(A,C) (*(A++))
84561 # define GlogUpperToLower(A) A = sqlite3UpperToLower[A]
84562 #else
84563 # define GlogUpperToLower(A) if( !((A)&~0x7f) ){ A = sqlite3UpperToLower[A]; }
84564 #endif
84566 static const struct compareInfo globInfo = { '*', '?', '[', 0 };
84567 /* The correct SQL-92 behavior is for the LIKE operator to ignore
84568 ** case. Thus 'a' LIKE 'A' would be true. */
84569 static const struct compareInfo likeInfoNorm = { '%', '_', 0, 1 };
84570 /* If SQLITE_CASE_SENSITIVE_LIKE is defined, then the LIKE operator
84571 ** is case sensitive causing 'a' LIKE 'A' to be false */
84572 static const struct compareInfo likeInfoAlt = { '%', '_', 0, 0 };
84575 ** Compare two UTF-8 strings for equality where the first string can
84576 ** potentially be a "glob" expression. Return true (1) if they
84577 ** are the same and false (0) if they are different.
84579 ** Globbing rules:
84581 ** '*' Matches any sequence of zero or more characters.
84583 ** '?' Matches exactly one character.
84585 ** [...] Matches one character from the enclosed list of
84586 ** characters.
84588 ** [^...] Matches one character not in the enclosed list.
84590 ** With the [...] and [^...] matching, a ']' character can be included
84591 ** in the list by making it the first character after '[' or '^'. A
84592 ** range of characters can be specified using '-'. Example:
84593 ** "[a-z]" matches any single lower-case letter. To match a '-', make
84594 ** it the last character in the list.
84596 ** This routine is usually quick, but can be N**2 in the worst case.
84598 ** Hints: to match '*' or '?', put them in "[]". Like this:
84600 ** abc[*]xyz Matches "abc*xyz" only
84602 static int patternCompare(
84603 const u8 *zPattern, /* The glob pattern */
84604 const u8 *zString, /* The string to compare against the glob */
84605 const struct compareInfo *pInfo, /* Information about how to do the compare */
84606 u32 esc /* The escape character */
84608 u32 c, c2;
84609 int invert;
84610 int seen;
84611 u8 matchOne = pInfo->matchOne;
84612 u8 matchAll = pInfo->matchAll;
84613 u8 matchSet = pInfo->matchSet;
84614 u8 noCase = pInfo->noCase;
84615 int prevEscape = 0; /* True if the previous character was 'escape' */
84617 while( (c = sqlite3Utf8Read(zPattern,&zPattern))!=0 ){
84618 if( !prevEscape && c==matchAll ){
84619 while( (c=sqlite3Utf8Read(zPattern,&zPattern)) == matchAll
84620 || c == matchOne ){
84621 if( c==matchOne && sqlite3Utf8Read(zString, &zString)==0 ){
84622 return 0;
84625 if( c==0 ){
84626 return 1;
84627 }else if( c==esc ){
84628 c = sqlite3Utf8Read(zPattern, &zPattern);
84629 if( c==0 ){
84630 return 0;
84632 }else if( c==matchSet ){
84633 assert( esc==0 ); /* This is GLOB, not LIKE */
84634 assert( matchSet<0x80 ); /* '[' is a single-byte character */
84635 while( *zString && patternCompare(&zPattern[-1],zString,pInfo,esc)==0 ){
84636 SQLITE_SKIP_UTF8(zString);
84638 return *zString!=0;
84640 while( (c2 = sqlite3Utf8Read(zString,&zString))!=0 ){
84641 if( noCase ){
84642 GlogUpperToLower(c2);
84643 GlogUpperToLower(c);
84644 while( c2 != 0 && c2 != c ){
84645 c2 = sqlite3Utf8Read(zString, &zString);
84646 GlogUpperToLower(c2);
84648 }else{
84649 while( c2 != 0 && c2 != c ){
84650 c2 = sqlite3Utf8Read(zString, &zString);
84653 if( c2==0 ) return 0;
84654 if( patternCompare(zPattern,zString,pInfo,esc) ) return 1;
84656 return 0;
84657 }else if( !prevEscape && c==matchOne ){
84658 if( sqlite3Utf8Read(zString, &zString)==0 ){
84659 return 0;
84661 }else if( c==matchSet ){
84662 u32 prior_c = 0;
84663 assert( esc==0 ); /* This only occurs for GLOB, not LIKE */
84664 seen = 0;
84665 invert = 0;
84666 c = sqlite3Utf8Read(zString, &zString);
84667 if( c==0 ) return 0;
84668 c2 = sqlite3Utf8Read(zPattern, &zPattern);
84669 if( c2=='^' ){
84670 invert = 1;
84671 c2 = sqlite3Utf8Read(zPattern, &zPattern);
84673 if( c2==']' ){
84674 if( c==']' ) seen = 1;
84675 c2 = sqlite3Utf8Read(zPattern, &zPattern);
84677 while( c2 && c2!=']' ){
84678 if( c2=='-' && zPattern[0]!=']' && zPattern[0]!=0 && prior_c>0 ){
84679 c2 = sqlite3Utf8Read(zPattern, &zPattern);
84680 if( c>=prior_c && c<=c2 ) seen = 1;
84681 prior_c = 0;
84682 }else{
84683 if( c==c2 ){
84684 seen = 1;
84686 prior_c = c2;
84688 c2 = sqlite3Utf8Read(zPattern, &zPattern);
84690 if( c2==0 || (seen ^ invert)==0 ){
84691 return 0;
84693 }else if( esc==c && !prevEscape ){
84694 prevEscape = 1;
84695 }else{
84696 c2 = sqlite3Utf8Read(zString, &zString);
84697 if( noCase ){
84698 GlogUpperToLower(c);
84699 GlogUpperToLower(c2);
84701 if( c!=c2 ){
84702 return 0;
84704 prevEscape = 0;
84707 return *zString==0;
84711 ** Count the number of times that the LIKE operator (or GLOB which is
84712 ** just a variation of LIKE) gets called. This is used for testing
84713 ** only.
84715 #ifdef SQLITE_TEST
84716 SQLITE_API int sqlite3_like_count = 0;
84717 #endif
84721 ** Implementation of the like() SQL function. This function implements
84722 ** the build-in LIKE operator. The first argument to the function is the
84723 ** pattern and the second argument is the string. So, the SQL statements:
84725 ** A LIKE B
84727 ** is implemented as like(B,A).
84729 ** This same function (with a different compareInfo structure) computes
84730 ** the GLOB operator.
84732 static void likeFunc(
84733 sqlite3_context *context,
84734 int argc,
84735 sqlite3_value **argv
84737 const unsigned char *zA, *zB;
84738 u32 escape = 0;
84739 int nPat;
84740 sqlite3 *db = sqlite3_context_db_handle(context);
84742 zB = sqlite3_value_text(argv[0]);
84743 zA = sqlite3_value_text(argv[1]);
84745 /* Limit the length of the LIKE or GLOB pattern to avoid problems
84746 ** of deep recursion and N*N behavior in patternCompare().
84748 nPat = sqlite3_value_bytes(argv[0]);
84749 testcase( nPat==db->aLimit[SQLITE_LIMIT_LIKE_PATTERN_LENGTH] );
84750 testcase( nPat==db->aLimit[SQLITE_LIMIT_LIKE_PATTERN_LENGTH]+1 );
84751 if( nPat > db->aLimit[SQLITE_LIMIT_LIKE_PATTERN_LENGTH] ){
84752 sqlite3_result_error(context, "LIKE or GLOB pattern too complex", -1);
84753 return;
84755 assert( zB==sqlite3_value_text(argv[0]) ); /* Encoding did not change */
84757 if( argc==3 ){
84758 /* The escape character string must consist of a single UTF-8 character.
84759 ** Otherwise, return an error.
84761 const unsigned char *zEsc = sqlite3_value_text(argv[2]);
84762 if( zEsc==0 ) return;
84763 if( sqlite3Utf8CharLen((char*)zEsc, -1)!=1 ){
84764 sqlite3_result_error(context,
84765 "ESCAPE expression must be a single character", -1);
84766 return;
84768 escape = sqlite3Utf8Read(zEsc, &zEsc);
84770 if( zA && zB ){
84771 struct compareInfo *pInfo = sqlite3_user_data(context);
84772 #ifdef SQLITE_TEST
84773 sqlite3_like_count++;
84774 #endif
84776 sqlite3_result_int(context, patternCompare(zB, zA, pInfo, escape));
84781 ** Implementation of the NULLIF(x,y) function. The result is the first
84782 ** argument if the arguments are different. The result is NULL if the
84783 ** arguments are equal to each other.
84785 static void nullifFunc(
84786 sqlite3_context *context,
84787 int NotUsed,
84788 sqlite3_value **argv
84790 CollSeq *pColl = sqlite3GetFuncCollSeq(context);
84791 UNUSED_PARAMETER(NotUsed);
84792 if( sqlite3MemCompare(argv[0], argv[1], pColl)!=0 ){
84793 sqlite3_result_value(context, argv[0]);
84798 ** Implementation of the sqlite_version() function. The result is the version
84799 ** of the SQLite library that is running.
84801 static void versionFunc(
84802 sqlite3_context *context,
84803 int NotUsed,
84804 sqlite3_value **NotUsed2
84806 UNUSED_PARAMETER2(NotUsed, NotUsed2);
84807 /* IMP: R-48699-48617 This function is an SQL wrapper around the
84808 ** sqlite3_libversion() C-interface. */
84809 sqlite3_result_text(context, sqlite3_libversion(), -1, SQLITE_STATIC);
84813 ** Implementation of the sqlite_source_id() function. The result is a string
84814 ** that identifies the particular version of the source code used to build
84815 ** SQLite.
84817 static void sourceidFunc(
84818 sqlite3_context *context,
84819 int NotUsed,
84820 sqlite3_value **NotUsed2
84822 UNUSED_PARAMETER2(NotUsed, NotUsed2);
84823 /* IMP: R-24470-31136 This function is an SQL wrapper around the
84824 ** sqlite3_sourceid() C interface. */
84825 sqlite3_result_text(context, sqlite3_sourceid(), -1, SQLITE_STATIC);
84829 ** Implementation of the sqlite_log() function. This is a wrapper around
84830 ** sqlite3_log(). The return value is NULL. The function exists purely for
84831 ** its side-effects.
84833 static void errlogFunc(
84834 sqlite3_context *context,
84835 int argc,
84836 sqlite3_value **argv
84838 UNUSED_PARAMETER(argc);
84839 UNUSED_PARAMETER(context);
84840 sqlite3_log(sqlite3_value_int(argv[0]), "%s", sqlite3_value_text(argv[1]));
84844 ** Implementation of the sqlite_compileoption_used() function.
84845 ** The result is an integer that identifies if the compiler option
84846 ** was used to build SQLite.
84848 #ifndef SQLITE_OMIT_COMPILEOPTION_DIAGS
84849 static void compileoptionusedFunc(
84850 sqlite3_context *context,
84851 int argc,
84852 sqlite3_value **argv
84854 const char *zOptName;
84855 assert( argc==1 );
84856 UNUSED_PARAMETER(argc);
84857 /* IMP: R-39564-36305 The sqlite_compileoption_used() SQL
84858 ** function is a wrapper around the sqlite3_compileoption_used() C/C++
84859 ** function.
84861 if( (zOptName = (const char*)sqlite3_value_text(argv[0]))!=0 ){
84862 sqlite3_result_int(context, sqlite3_compileoption_used(zOptName));
84865 #endif /* SQLITE_OMIT_COMPILEOPTION_DIAGS */
84868 ** Implementation of the sqlite_compileoption_get() function.
84869 ** The result is a string that identifies the compiler options
84870 ** used to build SQLite.
84872 #ifndef SQLITE_OMIT_COMPILEOPTION_DIAGS
84873 static void compileoptiongetFunc(
84874 sqlite3_context *context,
84875 int argc,
84876 sqlite3_value **argv
84878 int n;
84879 assert( argc==1 );
84880 UNUSED_PARAMETER(argc);
84881 /* IMP: R-04922-24076 The sqlite_compileoption_get() SQL function
84882 ** is a wrapper around the sqlite3_compileoption_get() C/C++ function.
84884 n = sqlite3_value_int(argv[0]);
84885 sqlite3_result_text(context, sqlite3_compileoption_get(n), -1, SQLITE_STATIC);
84887 #endif /* SQLITE_OMIT_COMPILEOPTION_DIAGS */
84889 /* Array for converting from half-bytes (nybbles) into ASCII hex
84890 ** digits. */
84891 static const char hexdigits[] = {
84892 '0', '1', '2', '3', '4', '5', '6', '7',
84893 '8', '9', 'A', 'B', 'C', 'D', 'E', 'F'
84897 ** EXPERIMENTAL - This is not an official function. The interface may
84898 ** change. This function may disappear. Do not write code that depends
84899 ** on this function.
84901 ** Implementation of the QUOTE() function. This function takes a single
84902 ** argument. If the argument is numeric, the return value is the same as
84903 ** the argument. If the argument is NULL, the return value is the string
84904 ** "NULL". Otherwise, the argument is enclosed in single quotes with
84905 ** single-quote escapes.
84907 static void quoteFunc(sqlite3_context *context, int argc, sqlite3_value **argv){
84908 assert( argc==1 );
84909 UNUSED_PARAMETER(argc);
84910 switch( sqlite3_value_type(argv[0]) ){
84911 case SQLITE_INTEGER:
84912 case SQLITE_FLOAT: {
84913 sqlite3_result_value(context, argv[0]);
84914 break;
84916 case SQLITE_BLOB: {
84917 char *zText = 0;
84918 char const *zBlob = sqlite3_value_blob(argv[0]);
84919 int nBlob = sqlite3_value_bytes(argv[0]);
84920 assert( zBlob==sqlite3_value_blob(argv[0]) ); /* No encoding change */
84921 zText = (char *)contextMalloc(context, (2*(i64)nBlob)+4);
84922 if( zText ){
84923 int i;
84924 for(i=0; i<nBlob; i++){
84925 zText[(i*2)+2] = hexdigits[(zBlob[i]>>4)&0x0F];
84926 zText[(i*2)+3] = hexdigits[(zBlob[i])&0x0F];
84928 zText[(nBlob*2)+2] = '\'';
84929 zText[(nBlob*2)+3] = '\0';
84930 zText[0] = 'X';
84931 zText[1] = '\'';
84932 sqlite3_result_text(context, zText, -1, SQLITE_TRANSIENT);
84933 sqlite3_free(zText);
84935 break;
84937 case SQLITE_TEXT: {
84938 int i,j;
84939 u64 n;
84940 const unsigned char *zArg = sqlite3_value_text(argv[0]);
84941 char *z;
84943 if( zArg==0 ) return;
84944 for(i=0, n=0; zArg[i]; i++){ if( zArg[i]=='\'' ) n++; }
84945 z = contextMalloc(context, ((i64)i)+((i64)n)+3);
84946 if( z ){
84947 z[0] = '\'';
84948 for(i=0, j=1; zArg[i]; i++){
84949 z[j++] = zArg[i];
84950 if( zArg[i]=='\'' ){
84951 z[j++] = '\'';
84954 z[j++] = '\'';
84955 z[j] = 0;
84956 sqlite3_result_text(context, z, j, sqlite3_free);
84958 break;
84960 default: {
84961 assert( sqlite3_value_type(argv[0])==SQLITE_NULL );
84962 sqlite3_result_text(context, "NULL", 4, SQLITE_STATIC);
84963 break;
84969 ** The hex() function. Interpret the argument as a blob. Return
84970 ** a hexadecimal rendering as text.
84972 static void hexFunc(
84973 sqlite3_context *context,
84974 int argc,
84975 sqlite3_value **argv
84977 int i, n;
84978 const unsigned char *pBlob;
84979 char *zHex, *z;
84980 assert( argc==1 );
84981 UNUSED_PARAMETER(argc);
84982 pBlob = sqlite3_value_blob(argv[0]);
84983 n = sqlite3_value_bytes(argv[0]);
84984 assert( pBlob==sqlite3_value_blob(argv[0]) ); /* No encoding change */
84985 z = zHex = contextMalloc(context, ((i64)n)*2 + 1);
84986 if( zHex ){
84987 for(i=0; i<n; i++, pBlob++){
84988 unsigned char c = *pBlob;
84989 *(z++) = hexdigits[(c>>4)&0xf];
84990 *(z++) = hexdigits[c&0xf];
84992 *z = 0;
84993 sqlite3_result_text(context, zHex, n*2, sqlite3_free);
84998 ** The zeroblob(N) function returns a zero-filled blob of size N bytes.
85000 static void zeroblobFunc(
85001 sqlite3_context *context,
85002 int argc,
85003 sqlite3_value **argv
85005 i64 n;
85006 sqlite3 *db = sqlite3_context_db_handle(context);
85007 assert( argc==1 );
85008 UNUSED_PARAMETER(argc);
85009 n = sqlite3_value_int64(argv[0]);
85010 testcase( n==db->aLimit[SQLITE_LIMIT_LENGTH] );
85011 testcase( n==db->aLimit[SQLITE_LIMIT_LENGTH]+1 );
85012 if( n>db->aLimit[SQLITE_LIMIT_LENGTH] ){
85013 sqlite3_result_error_toobig(context);
85014 }else{
85015 sqlite3_result_zeroblob(context, (int)n); /* IMP: R-00293-64994 */
85020 ** The replace() function. Three arguments are all strings: call
85021 ** them A, B, and C. The result is also a string which is derived
85022 ** from A by replacing every occurance of B with C. The match
85023 ** must be exact. Collating sequences are not used.
85025 static void replaceFunc(
85026 sqlite3_context *context,
85027 int argc,
85028 sqlite3_value **argv
85030 const unsigned char *zStr; /* The input string A */
85031 const unsigned char *zPattern; /* The pattern string B */
85032 const unsigned char *zRep; /* The replacement string C */
85033 unsigned char *zOut; /* The output */
85034 int nStr; /* Size of zStr */
85035 int nPattern; /* Size of zPattern */
85036 int nRep; /* Size of zRep */
85037 i64 nOut; /* Maximum size of zOut */
85038 int loopLimit; /* Last zStr[] that might match zPattern[] */
85039 int i, j; /* Loop counters */
85041 assert( argc==3 );
85042 UNUSED_PARAMETER(argc);
85043 zStr = sqlite3_value_text(argv[0]);
85044 if( zStr==0 ) return;
85045 nStr = sqlite3_value_bytes(argv[0]);
85046 assert( zStr==sqlite3_value_text(argv[0]) ); /* No encoding change */
85047 zPattern = sqlite3_value_text(argv[1]);
85048 if( zPattern==0 ){
85049 assert( sqlite3_value_type(argv[1])==SQLITE_NULL
85050 || sqlite3_context_db_handle(context)->mallocFailed );
85051 return;
85053 if( zPattern[0]==0 ){
85054 assert( sqlite3_value_type(argv[1])!=SQLITE_NULL );
85055 sqlite3_result_value(context, argv[0]);
85056 return;
85058 nPattern = sqlite3_value_bytes(argv[1]);
85059 assert( zPattern==sqlite3_value_text(argv[1]) ); /* No encoding change */
85060 zRep = sqlite3_value_text(argv[2]);
85061 if( zRep==0 ) return;
85062 nRep = sqlite3_value_bytes(argv[2]);
85063 assert( zRep==sqlite3_value_text(argv[2]) );
85064 nOut = nStr + 1;
85065 assert( nOut<SQLITE_MAX_LENGTH );
85066 zOut = contextMalloc(context, (i64)nOut);
85067 if( zOut==0 ){
85068 return;
85070 loopLimit = nStr - nPattern;
85071 for(i=j=0; i<=loopLimit; i++){
85072 if( zStr[i]!=zPattern[0] || memcmp(&zStr[i], zPattern, nPattern) ){
85073 zOut[j++] = zStr[i];
85074 }else{
85075 u8 *zOld;
85076 sqlite3 *db = sqlite3_context_db_handle(context);
85077 nOut += nRep - nPattern;
85078 testcase( nOut-1==db->aLimit[SQLITE_LIMIT_LENGTH] );
85079 testcase( nOut-2==db->aLimit[SQLITE_LIMIT_LENGTH] );
85080 if( nOut-1>db->aLimit[SQLITE_LIMIT_LENGTH] ){
85081 sqlite3_result_error_toobig(context);
85082 sqlite3_free(zOut);
85083 return;
85085 zOld = zOut;
85086 zOut = sqlite3_realloc(zOut, (int)nOut);
85087 if( zOut==0 ){
85088 sqlite3_result_error_nomem(context);
85089 sqlite3_free(zOld);
85090 return;
85092 memcpy(&zOut[j], zRep, nRep);
85093 j += nRep;
85094 i += nPattern-1;
85097 assert( j+nStr-i+1==nOut );
85098 memcpy(&zOut[j], &zStr[i], nStr-i);
85099 j += nStr - i;
85100 assert( j<=nOut );
85101 zOut[j] = 0;
85102 sqlite3_result_text(context, (char*)zOut, j, sqlite3_free);
85106 ** Implementation of the TRIM(), LTRIM(), and RTRIM() functions.
85107 ** The userdata is 0x1 for left trim, 0x2 for right trim, 0x3 for both.
85109 static void trimFunc(
85110 sqlite3_context *context,
85111 int argc,
85112 sqlite3_value **argv
85114 const unsigned char *zIn; /* Input string */
85115 const unsigned char *zCharSet; /* Set of characters to trim */
85116 int nIn; /* Number of bytes in input */
85117 int flags; /* 1: trimleft 2: trimright 3: trim */
85118 int i; /* Loop counter */
85119 unsigned char *aLen = 0; /* Length of each character in zCharSet */
85120 unsigned char **azChar = 0; /* Individual characters in zCharSet */
85121 int nChar; /* Number of characters in zCharSet */
85123 if( sqlite3_value_type(argv[0])==SQLITE_NULL ){
85124 return;
85126 zIn = sqlite3_value_text(argv[0]);
85127 if( zIn==0 ) return;
85128 nIn = sqlite3_value_bytes(argv[0]);
85129 assert( zIn==sqlite3_value_text(argv[0]) );
85130 if( argc==1 ){
85131 static const unsigned char lenOne[] = { 1 };
85132 static unsigned char * const azOne[] = { (u8*)" " };
85133 nChar = 1;
85134 aLen = (u8*)lenOne;
85135 azChar = (unsigned char **)azOne;
85136 zCharSet = 0;
85137 }else if( (zCharSet = sqlite3_value_text(argv[1]))==0 ){
85138 return;
85139 }else{
85140 const unsigned char *z;
85141 for(z=zCharSet, nChar=0; *z; nChar++){
85142 SQLITE_SKIP_UTF8(z);
85144 if( nChar>0 ){
85145 azChar = contextMalloc(context, ((i64)nChar)*(sizeof(char*)+1));
85146 if( azChar==0 ){
85147 return;
85149 aLen = (unsigned char*)&azChar[nChar];
85150 for(z=zCharSet, nChar=0; *z; nChar++){
85151 azChar[nChar] = (unsigned char *)z;
85152 SQLITE_SKIP_UTF8(z);
85153 aLen[nChar] = (u8)(z - azChar[nChar]);
85157 if( nChar>0 ){
85158 flags = SQLITE_PTR_TO_INT(sqlite3_user_data(context));
85159 if( flags & 1 ){
85160 while( nIn>0 ){
85161 int len = 0;
85162 for(i=0; i<nChar; i++){
85163 len = aLen[i];
85164 if( len<=nIn && memcmp(zIn, azChar[i], len)==0 ) break;
85166 if( i>=nChar ) break;
85167 zIn += len;
85168 nIn -= len;
85171 if( flags & 2 ){
85172 while( nIn>0 ){
85173 int len = 0;
85174 for(i=0; i<nChar; i++){
85175 len = aLen[i];
85176 if( len<=nIn && memcmp(&zIn[nIn-len],azChar[i],len)==0 ) break;
85178 if( i>=nChar ) break;
85179 nIn -= len;
85182 if( zCharSet ){
85183 sqlite3_free(azChar);
85186 sqlite3_result_text(context, (char*)zIn, nIn, SQLITE_TRANSIENT);
85190 /* IMP: R-25361-16150 This function is omitted from SQLite by default. It
85191 ** is only available if the SQLITE_SOUNDEX compile-time option is used
85192 ** when SQLite is built.
85194 #ifdef SQLITE_SOUNDEX
85196 ** Compute the soundex encoding of a word.
85198 ** IMP: R-59782-00072 The soundex(X) function returns a string that is the
85199 ** soundex encoding of the string X.
85201 static void soundexFunc(
85202 sqlite3_context *context,
85203 int argc,
85204 sqlite3_value **argv
85206 char zResult[8];
85207 const u8 *zIn;
85208 int i, j;
85209 static const unsigned char iCode[] = {
85210 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0,
85211 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0,
85212 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0,
85213 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0,
85214 0, 0, 1, 2, 3, 0, 1, 2, 0, 0, 2, 2, 4, 5, 5, 0,
85215 1, 2, 6, 2, 3, 0, 1, 0, 2, 0, 2, 0, 0, 0, 0, 0,
85216 0, 0, 1, 2, 3, 0, 1, 2, 0, 0, 2, 2, 4, 5, 5, 0,
85217 1, 2, 6, 2, 3, 0, 1, 0, 2, 0, 2, 0, 0, 0, 0, 0,
85219 assert( argc==1 );
85220 zIn = (u8*)sqlite3_value_text(argv[0]);
85221 if( zIn==0 ) zIn = (u8*)"";
85222 for(i=0; zIn[i] && !sqlite3Isalpha(zIn[i]); i++){}
85223 if( zIn[i] ){
85224 u8 prevcode = iCode[zIn[i]&0x7f];
85225 zResult[0] = sqlite3Toupper(zIn[i]);
85226 for(j=1; j<4 && zIn[i]; i++){
85227 int code = iCode[zIn[i]&0x7f];
85228 if( code>0 ){
85229 if( code!=prevcode ){
85230 prevcode = code;
85231 zResult[j++] = code + '0';
85233 }else{
85234 prevcode = 0;
85237 while( j<4 ){
85238 zResult[j++] = '0';
85240 zResult[j] = 0;
85241 sqlite3_result_text(context, zResult, 4, SQLITE_TRANSIENT);
85242 }else{
85243 /* IMP: R-64894-50321 The string "?000" is returned if the argument
85244 ** is NULL or contains no ASCII alphabetic characters. */
85245 sqlite3_result_text(context, "?000", 4, SQLITE_STATIC);
85248 #endif /* SQLITE_SOUNDEX */
85250 #ifndef SQLITE_OMIT_LOAD_EXTENSION
85252 ** A function that loads a shared-library extension then returns NULL.
85254 static void loadExt(sqlite3_context *context, int argc, sqlite3_value **argv){
85255 const char *zFile = (const char *)sqlite3_value_text(argv[0]);
85256 const char *zProc;
85257 sqlite3 *db = sqlite3_context_db_handle(context);
85258 char *zErrMsg = 0;
85260 if( argc==2 ){
85261 zProc = (const char *)sqlite3_value_text(argv[1]);
85262 }else{
85263 zProc = 0;
85265 if( zFile && sqlite3_load_extension(db, zFile, zProc, &zErrMsg) ){
85266 sqlite3_result_error(context, zErrMsg, -1);
85267 sqlite3_free(zErrMsg);
85270 #endif
85274 ** An instance of the following structure holds the context of a
85275 ** sum() or avg() aggregate computation.
85277 typedef struct SumCtx SumCtx;
85278 struct SumCtx {
85279 double rSum; /* Floating point sum */
85280 i64 iSum; /* Integer sum */
85281 i64 cnt; /* Number of elements summed */
85282 u8 overflow; /* True if integer overflow seen */
85283 u8 approx; /* True if non-integer value was input to the sum */
85287 ** Routines used to compute the sum, average, and total.
85289 ** The SUM() function follows the (broken) SQL standard which means
85290 ** that it returns NULL if it sums over no inputs. TOTAL returns
85291 ** 0.0 in that case. In addition, TOTAL always returns a float where
85292 ** SUM might return an integer if it never encounters a floating point
85293 ** value. TOTAL never fails, but SUM might through an exception if
85294 ** it overflows an integer.
85296 static void sumStep(sqlite3_context *context, int argc, sqlite3_value **argv){
85297 SumCtx *p;
85298 int type;
85299 assert( argc==1 );
85300 UNUSED_PARAMETER(argc);
85301 p = sqlite3_aggregate_context(context, sizeof(*p));
85302 type = sqlite3_value_numeric_type(argv[0]);
85303 if( p && type!=SQLITE_NULL ){
85304 p->cnt++;
85305 if( type==SQLITE_INTEGER ){
85306 i64 v = sqlite3_value_int64(argv[0]);
85307 p->rSum += v;
85308 if( (p->approx|p->overflow)==0 && sqlite3AddInt64(&p->iSum, v) ){
85309 p->overflow = 1;
85311 }else{
85312 p->rSum += sqlite3_value_double(argv[0]);
85313 p->approx = 1;
85317 static void sumFinalize(sqlite3_context *context){
85318 SumCtx *p;
85319 p = sqlite3_aggregate_context(context, 0);
85320 if( p && p->cnt>0 ){
85321 if( p->overflow ){
85322 sqlite3_result_error(context,"integer overflow",-1);
85323 }else if( p->approx ){
85324 sqlite3_result_double(context, p->rSum);
85325 }else{
85326 sqlite3_result_int64(context, p->iSum);
85330 static void avgFinalize(sqlite3_context *context){
85331 SumCtx *p;
85332 p = sqlite3_aggregate_context(context, 0);
85333 if( p && p->cnt>0 ){
85334 sqlite3_result_double(context, p->rSum/(double)p->cnt);
85337 static void totalFinalize(sqlite3_context *context){
85338 SumCtx *p;
85339 p = sqlite3_aggregate_context(context, 0);
85340 /* (double)0 In case of SQLITE_OMIT_FLOATING_POINT... */
85341 sqlite3_result_double(context, p ? p->rSum : (double)0);
85345 ** The following structure keeps track of state information for the
85346 ** count() aggregate function.
85348 typedef struct CountCtx CountCtx;
85349 struct CountCtx {
85350 i64 n;
85354 ** Routines to implement the count() aggregate function.
85356 static void countStep(sqlite3_context *context, int argc, sqlite3_value **argv){
85357 CountCtx *p;
85358 p = sqlite3_aggregate_context(context, sizeof(*p));
85359 if( (argc==0 || SQLITE_NULL!=sqlite3_value_type(argv[0])) && p ){
85360 p->n++;
85363 #ifndef SQLITE_OMIT_DEPRECATED
85364 /* The sqlite3_aggregate_count() function is deprecated. But just to make
85365 ** sure it still operates correctly, verify that its count agrees with our
85366 ** internal count when using count(*) and when the total count can be
85367 ** expressed as a 32-bit integer. */
85368 assert( argc==1 || p==0 || p->n>0x7fffffff
85369 || p->n==sqlite3_aggregate_count(context) );
85370 #endif
85372 static void countFinalize(sqlite3_context *context){
85373 CountCtx *p;
85374 p = sqlite3_aggregate_context(context, 0);
85375 sqlite3_result_int64(context, p ? p->n : 0);
85379 ** Routines to implement min() and max() aggregate functions.
85381 static void minmaxStep(
85382 sqlite3_context *context,
85383 int NotUsed,
85384 sqlite3_value **argv
85386 Mem *pArg = (Mem *)argv[0];
85387 Mem *pBest;
85388 UNUSED_PARAMETER(NotUsed);
85390 if( sqlite3_value_type(argv[0])==SQLITE_NULL ) return;
85391 pBest = (Mem *)sqlite3_aggregate_context(context, sizeof(*pBest));
85392 if( !pBest ) return;
85394 if( pBest->flags ){
85395 int max;
85396 int cmp;
85397 CollSeq *pColl = sqlite3GetFuncCollSeq(context);
85398 /* This step function is used for both the min() and max() aggregates,
85399 ** the only difference between the two being that the sense of the
85400 ** comparison is inverted. For the max() aggregate, the
85401 ** sqlite3_user_data() function returns (void *)-1. For min() it
85402 ** returns (void *)db, where db is the sqlite3* database pointer.
85403 ** Therefore the next statement sets variable 'max' to 1 for the max()
85404 ** aggregate, or 0 for min().
85406 max = sqlite3_user_data(context)!=0;
85407 cmp = sqlite3MemCompare(pBest, pArg, pColl);
85408 if( (max && cmp<0) || (!max && cmp>0) ){
85409 sqlite3VdbeMemCopy(pBest, pArg);
85411 }else{
85412 sqlite3VdbeMemCopy(pBest, pArg);
85415 static void minMaxFinalize(sqlite3_context *context){
85416 sqlite3_value *pRes;
85417 pRes = (sqlite3_value *)sqlite3_aggregate_context(context, 0);
85418 if( pRes ){
85419 if( ALWAYS(pRes->flags) ){
85420 sqlite3_result_value(context, pRes);
85422 sqlite3VdbeMemRelease(pRes);
85427 ** group_concat(EXPR, ?SEPARATOR?)
85429 static void groupConcatStep(
85430 sqlite3_context *context,
85431 int argc,
85432 sqlite3_value **argv
85434 const char *zVal;
85435 StrAccum *pAccum;
85436 const char *zSep;
85437 int nVal, nSep;
85438 assert( argc==1 || argc==2 );
85439 if( sqlite3_value_type(argv[0])==SQLITE_NULL ) return;
85440 pAccum = (StrAccum*)sqlite3_aggregate_context(context, sizeof(*pAccum));
85442 if( pAccum ){
85443 sqlite3 *db = sqlite3_context_db_handle(context);
85444 int firstTerm = pAccum->useMalloc==0;
85445 pAccum->useMalloc = 2;
85446 pAccum->mxAlloc = db->aLimit[SQLITE_LIMIT_LENGTH];
85447 if( !firstTerm ){
85448 if( argc==2 ){
85449 zSep = (char*)sqlite3_value_text(argv[1]);
85450 nSep = sqlite3_value_bytes(argv[1]);
85451 }else{
85452 zSep = ",";
85453 nSep = 1;
85455 sqlite3StrAccumAppend(pAccum, zSep, nSep);
85457 zVal = (char*)sqlite3_value_text(argv[0]);
85458 nVal = sqlite3_value_bytes(argv[0]);
85459 sqlite3StrAccumAppend(pAccum, zVal, nVal);
85462 static void groupConcatFinalize(sqlite3_context *context){
85463 StrAccum *pAccum;
85464 pAccum = sqlite3_aggregate_context(context, 0);
85465 if( pAccum ){
85466 if( pAccum->tooBig ){
85467 sqlite3_result_error_toobig(context);
85468 }else if( pAccum->mallocFailed ){
85469 sqlite3_result_error_nomem(context);
85470 }else{
85471 sqlite3_result_text(context, sqlite3StrAccumFinish(pAccum), -1,
85472 sqlite3_free);
85478 ** This routine does per-connection function registration. Most
85479 ** of the built-in functions above are part of the global function set.
85480 ** This routine only deals with those that are not global.
85482 SQLITE_PRIVATE void sqlite3RegisterBuiltinFunctions(sqlite3 *db){
85483 int rc = sqlite3_overload_function(db, "MATCH", 2);
85484 assert( rc==SQLITE_NOMEM || rc==SQLITE_OK );
85485 if( rc==SQLITE_NOMEM ){
85486 db->mallocFailed = 1;
85491 ** Set the LIKEOPT flag on the 2-argument function with the given name.
85493 static void setLikeOptFlag(sqlite3 *db, const char *zName, u8 flagVal){
85494 FuncDef *pDef;
85495 pDef = sqlite3FindFunction(db, zName, sqlite3Strlen30(zName),
85496 2, SQLITE_UTF8, 0);
85497 if( ALWAYS(pDef) ){
85498 pDef->flags = flagVal;
85503 ** Register the built-in LIKE and GLOB functions. The caseSensitive
85504 ** parameter determines whether or not the LIKE operator is case
85505 ** sensitive. GLOB is always case sensitive.
85507 SQLITE_PRIVATE void sqlite3RegisterLikeFunctions(sqlite3 *db, int caseSensitive){
85508 struct compareInfo *pInfo;
85509 if( caseSensitive ){
85510 pInfo = (struct compareInfo*)&likeInfoAlt;
85511 }else{
85512 pInfo = (struct compareInfo*)&likeInfoNorm;
85514 sqlite3CreateFunc(db, "like", 2, SQLITE_UTF8, pInfo, likeFunc, 0, 0, 0);
85515 sqlite3CreateFunc(db, "like", 3, SQLITE_UTF8, pInfo, likeFunc, 0, 0, 0);
85516 sqlite3CreateFunc(db, "glob", 2, SQLITE_UTF8,
85517 (struct compareInfo*)&globInfo, likeFunc, 0, 0, 0);
85518 setLikeOptFlag(db, "glob", SQLITE_FUNC_LIKE | SQLITE_FUNC_CASE);
85519 setLikeOptFlag(db, "like",
85520 caseSensitive ? (SQLITE_FUNC_LIKE | SQLITE_FUNC_CASE) : SQLITE_FUNC_LIKE);
85524 ** pExpr points to an expression which implements a function. If
85525 ** it is appropriate to apply the LIKE optimization to that function
85526 ** then set aWc[0] through aWc[2] to the wildcard characters and
85527 ** return TRUE. If the function is not a LIKE-style function then
85528 ** return FALSE.
85530 SQLITE_PRIVATE int sqlite3IsLikeFunction(sqlite3 *db, Expr *pExpr, int *pIsNocase, char *aWc){
85531 FuncDef *pDef;
85532 if( pExpr->op!=TK_FUNCTION
85533 || !pExpr->x.pList
85534 || pExpr->x.pList->nExpr!=2
85536 return 0;
85538 assert( !ExprHasProperty(pExpr, EP_xIsSelect) );
85539 pDef = sqlite3FindFunction(db, pExpr->u.zToken,
85540 sqlite3Strlen30(pExpr->u.zToken),
85541 2, SQLITE_UTF8, 0);
85542 if( NEVER(pDef==0) || (pDef->flags & SQLITE_FUNC_LIKE)==0 ){
85543 return 0;
85546 /* The memcpy() statement assumes that the wildcard characters are
85547 ** the first three statements in the compareInfo structure. The
85548 ** asserts() that follow verify that assumption
85550 memcpy(aWc, pDef->pUserData, 3);
85551 assert( (char*)&likeInfoAlt == (char*)&likeInfoAlt.matchAll );
85552 assert( &((char*)&likeInfoAlt)[1] == (char*)&likeInfoAlt.matchOne );
85553 assert( &((char*)&likeInfoAlt)[2] == (char*)&likeInfoAlt.matchSet );
85554 *pIsNocase = (pDef->flags & SQLITE_FUNC_CASE)==0;
85555 return 1;
85559 ** All all of the FuncDef structures in the aBuiltinFunc[] array above
85560 ** to the global function hash table. This occurs at start-time (as
85561 ** a consequence of calling sqlite3_initialize()).
85563 ** After this routine runs
85565 SQLITE_PRIVATE void sqlite3RegisterGlobalFunctions(void){
85567 ** The following array holds FuncDef structures for all of the functions
85568 ** defined in this file.
85570 ** The array cannot be constant since changes are made to the
85571 ** FuncDef.pHash elements at start-time. The elements of this array
85572 ** are read-only after initialization is complete.
85574 static SQLITE_WSD FuncDef aBuiltinFunc[] = {
85575 FUNCTION(ltrim, 1, 1, 0, trimFunc ),
85576 FUNCTION(ltrim, 2, 1, 0, trimFunc ),
85577 FUNCTION(rtrim, 1, 2, 0, trimFunc ),
85578 FUNCTION(rtrim, 2, 2, 0, trimFunc ),
85579 FUNCTION(trim, 1, 3, 0, trimFunc ),
85580 FUNCTION(trim, 2, 3, 0, trimFunc ),
85581 FUNCTION(min, -1, 0, 1, minmaxFunc ),
85582 FUNCTION(min, 0, 0, 1, 0 ),
85583 AGGREGATE(min, 1, 0, 1, minmaxStep, minMaxFinalize ),
85584 FUNCTION(max, -1, 1, 1, minmaxFunc ),
85585 FUNCTION(max, 0, 1, 1, 0 ),
85586 AGGREGATE(max, 1, 1, 1, minmaxStep, minMaxFinalize ),
85587 FUNCTION(typeof, 1, 0, 0, typeofFunc ),
85588 FUNCTION(length, 1, 0, 0, lengthFunc ),
85589 FUNCTION(substr, 2, 0, 0, substrFunc ),
85590 FUNCTION(substr, 3, 0, 0, substrFunc ),
85591 FUNCTION(abs, 1, 0, 0, absFunc ),
85592 #ifndef SQLITE_OMIT_FLOATING_POINT
85593 FUNCTION(round, 1, 0, 0, roundFunc ),
85594 FUNCTION(round, 2, 0, 0, roundFunc ),
85595 #endif
85596 FUNCTION(upper, 1, 0, 0, upperFunc ),
85597 FUNCTION(lower, 1, 0, 0, lowerFunc ),
85598 FUNCTION(coalesce, 1, 0, 0, 0 ),
85599 FUNCTION(coalesce, 0, 0, 0, 0 ),
85600 /* FUNCTION(coalesce, -1, 0, 0, ifnullFunc ), */
85601 {-1,SQLITE_UTF8,SQLITE_FUNC_COALESCE,0,0,ifnullFunc,0,0,"coalesce",0,0},
85602 FUNCTION(hex, 1, 0, 0, hexFunc ),
85603 /* FUNCTION(ifnull, 2, 0, 0, ifnullFunc ), */
85604 {2,SQLITE_UTF8,SQLITE_FUNC_COALESCE,0,0,ifnullFunc,0,0,"ifnull",0,0},
85605 FUNCTION(random, 0, 0, 0, randomFunc ),
85606 FUNCTION(randomblob, 1, 0, 0, randomBlob ),
85607 FUNCTION(nullif, 2, 0, 1, nullifFunc ),
85608 FUNCTION(sqlite_version, 0, 0, 0, versionFunc ),
85609 FUNCTION(sqlite_source_id, 0, 0, 0, sourceidFunc ),
85610 FUNCTION(sqlite_log, 2, 0, 0, errlogFunc ),
85611 #ifndef SQLITE_OMIT_COMPILEOPTION_DIAGS
85612 FUNCTION(sqlite_compileoption_used,1, 0, 0, compileoptionusedFunc ),
85613 FUNCTION(sqlite_compileoption_get, 1, 0, 0, compileoptiongetFunc ),
85614 #endif /* SQLITE_OMIT_COMPILEOPTION_DIAGS */
85615 FUNCTION(quote, 1, 0, 0, quoteFunc ),
85616 FUNCTION(last_insert_rowid, 0, 0, 0, last_insert_rowid),
85617 FUNCTION(changes, 0, 0, 0, changes ),
85618 FUNCTION(total_changes, 0, 0, 0, total_changes ),
85619 FUNCTION(replace, 3, 0, 0, replaceFunc ),
85620 FUNCTION(zeroblob, 1, 0, 0, zeroblobFunc ),
85621 #ifdef SQLITE_SOUNDEX
85622 FUNCTION(soundex, 1, 0, 0, soundexFunc ),
85623 #endif
85624 #ifndef SQLITE_OMIT_LOAD_EXTENSION
85625 FUNCTION(load_extension, 1, 0, 0, loadExt ),
85626 FUNCTION(load_extension, 2, 0, 0, loadExt ),
85627 #endif
85628 AGGREGATE(sum, 1, 0, 0, sumStep, sumFinalize ),
85629 AGGREGATE(total, 1, 0, 0, sumStep, totalFinalize ),
85630 AGGREGATE(avg, 1, 0, 0, sumStep, avgFinalize ),
85631 /* AGGREGATE(count, 0, 0, 0, countStep, countFinalize ), */
85632 {0,SQLITE_UTF8,SQLITE_FUNC_COUNT,0,0,0,countStep,countFinalize,"count",0,0},
85633 AGGREGATE(count, 1, 0, 0, countStep, countFinalize ),
85634 AGGREGATE(group_concat, 1, 0, 0, groupConcatStep, groupConcatFinalize),
85635 AGGREGATE(group_concat, 2, 0, 0, groupConcatStep, groupConcatFinalize),
85637 LIKEFUNC(glob, 2, &globInfo, SQLITE_FUNC_LIKE|SQLITE_FUNC_CASE),
85638 #ifdef SQLITE_CASE_SENSITIVE_LIKE
85639 LIKEFUNC(like, 2, &likeInfoAlt, SQLITE_FUNC_LIKE|SQLITE_FUNC_CASE),
85640 LIKEFUNC(like, 3, &likeInfoAlt, SQLITE_FUNC_LIKE|SQLITE_FUNC_CASE),
85641 #else
85642 LIKEFUNC(like, 2, &likeInfoNorm, SQLITE_FUNC_LIKE),
85643 LIKEFUNC(like, 3, &likeInfoNorm, SQLITE_FUNC_LIKE),
85644 #endif
85647 int i;
85648 FuncDefHash *pHash = &GLOBAL(FuncDefHash, sqlite3GlobalFunctions);
85649 FuncDef *aFunc = (FuncDef*)&GLOBAL(FuncDef, aBuiltinFunc);
85651 for(i=0; i<ArraySize(aBuiltinFunc); i++){
85652 sqlite3FuncDefInsert(pHash, &aFunc[i]);
85654 sqlite3RegisterDateTimeFunctions();
85655 #ifndef SQLITE_OMIT_ALTERTABLE
85656 sqlite3AlterFunctions();
85657 #endif
85660 /************** End of func.c ************************************************/
85661 /************** Begin file fkey.c ********************************************/
85664 ** The author disclaims copyright to this source code. In place of
85665 ** a legal notice, here is a blessing:
85667 ** May you do good and not evil.
85668 ** May you find forgiveness for yourself and forgive others.
85669 ** May you share freely, never taking more than you give.
85671 *************************************************************************
85672 ** This file contains code used by the compiler to add foreign key
85673 ** support to compiled SQL statements.
85676 #ifndef SQLITE_OMIT_FOREIGN_KEY
85677 #ifndef SQLITE_OMIT_TRIGGER
85680 ** Deferred and Immediate FKs
85681 ** --------------------------
85683 ** Foreign keys in SQLite come in two flavours: deferred and immediate.
85684 ** If an immediate foreign key constraint is violated, SQLITE_CONSTRAINT
85685 ** is returned and the current statement transaction rolled back. If a
85686 ** deferred foreign key constraint is violated, no action is taken
85687 ** immediately. However if the application attempts to commit the
85688 ** transaction before fixing the constraint violation, the attempt fails.
85690 ** Deferred constraints are implemented using a simple counter associated
85691 ** with the database handle. The counter is set to zero each time a
85692 ** database transaction is opened. Each time a statement is executed
85693 ** that causes a foreign key violation, the counter is incremented. Each
85694 ** time a statement is executed that removes an existing violation from
85695 ** the database, the counter is decremented. When the transaction is
85696 ** committed, the commit fails if the current value of the counter is
85697 ** greater than zero. This scheme has two big drawbacks:
85699 ** * When a commit fails due to a deferred foreign key constraint,
85700 ** there is no way to tell which foreign constraint is not satisfied,
85701 ** or which row it is not satisfied for.
85703 ** * If the database contains foreign key violations when the
85704 ** transaction is opened, this may cause the mechanism to malfunction.
85706 ** Despite these problems, this approach is adopted as it seems simpler
85707 ** than the alternatives.
85709 ** INSERT operations:
85711 ** I.1) For each FK for which the table is the child table, search
85712 ** the parent table for a match. If none is found increment the
85713 ** constraint counter.
85715 ** I.2) For each FK for which the table is the parent table,
85716 ** search the child table for rows that correspond to the new
85717 ** row in the parent table. Decrement the counter for each row
85718 ** found (as the constraint is now satisfied).
85720 ** DELETE operations:
85722 ** D.1) For each FK for which the table is the child table,
85723 ** search the parent table for a row that corresponds to the
85724 ** deleted row in the child table. If such a row is not found,
85725 ** decrement the counter.
85727 ** D.2) For each FK for which the table is the parent table, search
85728 ** the child table for rows that correspond to the deleted row
85729 ** in the parent table. For each found increment the counter.
85731 ** UPDATE operations:
85733 ** An UPDATE command requires that all 4 steps above are taken, but only
85734 ** for FK constraints for which the affected columns are actually
85735 ** modified (values must be compared at runtime).
85737 ** Note that I.1 and D.1 are very similar operations, as are I.2 and D.2.
85738 ** This simplifies the implementation a bit.
85740 ** For the purposes of immediate FK constraints, the OR REPLACE conflict
85741 ** resolution is considered to delete rows before the new row is inserted.
85742 ** If a delete caused by OR REPLACE violates an FK constraint, an exception
85743 ** is thrown, even if the FK constraint would be satisfied after the new
85744 ** row is inserted.
85746 ** Immediate constraints are usually handled similarly. The only difference
85747 ** is that the counter used is stored as part of each individual statement
85748 ** object (struct Vdbe). If, after the statement has run, its immediate
85749 ** constraint counter is greater than zero, it returns SQLITE_CONSTRAINT
85750 ** and the statement transaction is rolled back. An exception is an INSERT
85751 ** statement that inserts a single row only (no triggers). In this case,
85752 ** instead of using a counter, an exception is thrown immediately if the
85753 ** INSERT violates a foreign key constraint. This is necessary as such
85754 ** an INSERT does not open a statement transaction.
85756 ** TODO: How should dropping a table be handled? How should renaming a
85757 ** table be handled?
85760 ** Query API Notes
85761 ** ---------------
85763 ** Before coding an UPDATE or DELETE row operation, the code-generator
85764 ** for those two operations needs to know whether or not the operation
85765 ** requires any FK processing and, if so, which columns of the original
85766 ** row are required by the FK processing VDBE code (i.e. if FKs were
85767 ** implemented using triggers, which of the old.* columns would be
85768 ** accessed). No information is required by the code-generator before
85769 ** coding an INSERT operation. The functions used by the UPDATE/DELETE
85770 ** generation code to query for this information are:
85772 ** sqlite3FkRequired() - Test to see if FK processing is required.
85773 ** sqlite3FkOldmask() - Query for the set of required old.* columns.
85776 ** Externally accessible module functions
85777 ** --------------------------------------
85779 ** sqlite3FkCheck() - Check for foreign key violations.
85780 ** sqlite3FkActions() - Code triggers for ON UPDATE/ON DELETE actions.
85781 ** sqlite3FkDelete() - Delete an FKey structure.
85785 ** VDBE Calling Convention
85786 ** -----------------------
85788 ** Example:
85790 ** For the following INSERT statement:
85792 ** CREATE TABLE t1(a, b INTEGER PRIMARY KEY, c);
85793 ** INSERT INTO t1 VALUES(1, 2, 3.1);
85795 ** Register (x): 2 (type integer)
85796 ** Register (x+1): 1 (type integer)
85797 ** Register (x+2): NULL (type NULL)
85798 ** Register (x+3): 3.1 (type real)
85802 ** A foreign key constraint requires that the key columns in the parent
85803 ** table are collectively subject to a UNIQUE or PRIMARY KEY constraint.
85804 ** Given that pParent is the parent table for foreign key constraint pFKey,
85805 ** search the schema a unique index on the parent key columns.
85807 ** If successful, zero is returned. If the parent key is an INTEGER PRIMARY
85808 ** KEY column, then output variable *ppIdx is set to NULL. Otherwise, *ppIdx
85809 ** is set to point to the unique index.
85811 ** If the parent key consists of a single column (the foreign key constraint
85812 ** is not a composite foreign key), output variable *paiCol is set to NULL.
85813 ** Otherwise, it is set to point to an allocated array of size N, where
85814 ** N is the number of columns in the parent key. The first element of the
85815 ** array is the index of the child table column that is mapped by the FK
85816 ** constraint to the parent table column stored in the left-most column
85817 ** of index *ppIdx. The second element of the array is the index of the
85818 ** child table column that corresponds to the second left-most column of
85819 ** *ppIdx, and so on.
85821 ** If the required index cannot be found, either because:
85823 ** 1) The named parent key columns do not exist, or
85825 ** 2) The named parent key columns do exist, but are not subject to a
85826 ** UNIQUE or PRIMARY KEY constraint, or
85828 ** 3) No parent key columns were provided explicitly as part of the
85829 ** foreign key definition, and the parent table does not have a
85830 ** PRIMARY KEY, or
85832 ** 4) No parent key columns were provided explicitly as part of the
85833 ** foreign key definition, and the PRIMARY KEY of the parent table
85834 ** consists of a a different number of columns to the child key in
85835 ** the child table.
85837 ** then non-zero is returned, and a "foreign key mismatch" error loaded
85838 ** into pParse. If an OOM error occurs, non-zero is returned and the
85839 ** pParse->db->mallocFailed flag is set.
85841 static int locateFkeyIndex(
85842 Parse *pParse, /* Parse context to store any error in */
85843 Table *pParent, /* Parent table of FK constraint pFKey */
85844 FKey *pFKey, /* Foreign key to find index for */
85845 Index **ppIdx, /* OUT: Unique index on parent table */
85846 int **paiCol /* OUT: Map of index columns in pFKey */
85848 Index *pIdx = 0; /* Value to return via *ppIdx */
85849 int *aiCol = 0; /* Value to return via *paiCol */
85850 int nCol = pFKey->nCol; /* Number of columns in parent key */
85851 char *zKey = pFKey->aCol[0].zCol; /* Name of left-most parent key column */
85853 /* The caller is responsible for zeroing output parameters. */
85854 assert( ppIdx && *ppIdx==0 );
85855 assert( !paiCol || *paiCol==0 );
85856 assert( pParse );
85858 /* If this is a non-composite (single column) foreign key, check if it
85859 ** maps to the INTEGER PRIMARY KEY of table pParent. If so, leave *ppIdx
85860 ** and *paiCol set to zero and return early.
85862 ** Otherwise, for a composite foreign key (more than one column), allocate
85863 ** space for the aiCol array (returned via output parameter *paiCol).
85864 ** Non-composite foreign keys do not require the aiCol array.
85866 if( nCol==1 ){
85867 /* The FK maps to the IPK if any of the following are true:
85869 ** 1) There is an INTEGER PRIMARY KEY column and the FK is implicitly
85870 ** mapped to the primary key of table pParent, or
85871 ** 2) The FK is explicitly mapped to a column declared as INTEGER
85872 ** PRIMARY KEY.
85874 if( pParent->iPKey>=0 ){
85875 if( !zKey ) return 0;
85876 if( !sqlite3StrICmp(pParent->aCol[pParent->iPKey].zName, zKey) ) return 0;
85878 }else if( paiCol ){
85879 assert( nCol>1 );
85880 aiCol = (int *)sqlite3DbMallocRaw(pParse->db, nCol*sizeof(int));
85881 if( !aiCol ) return 1;
85882 *paiCol = aiCol;
85885 for(pIdx=pParent->pIndex; pIdx; pIdx=pIdx->pNext){
85886 if( pIdx->nColumn==nCol && pIdx->onError!=OE_None ){
85887 /* pIdx is a UNIQUE index (or a PRIMARY KEY) and has the right number
85888 ** of columns. If each indexed column corresponds to a foreign key
85889 ** column of pFKey, then this index is a winner. */
85891 if( zKey==0 ){
85892 /* If zKey is NULL, then this foreign key is implicitly mapped to
85893 ** the PRIMARY KEY of table pParent. The PRIMARY KEY index may be
85894 ** identified by the test (Index.autoIndex==2). */
85895 if( pIdx->autoIndex==2 ){
85896 if( aiCol ){
85897 int i;
85898 for(i=0; i<nCol; i++) aiCol[i] = pFKey->aCol[i].iFrom;
85900 break;
85902 }else{
85903 /* If zKey is non-NULL, then this foreign key was declared to
85904 ** map to an explicit list of columns in table pParent. Check if this
85905 ** index matches those columns. Also, check that the index uses
85906 ** the default collation sequences for each column. */
85907 int i, j;
85908 for(i=0; i<nCol; i++){
85909 int iCol = pIdx->aiColumn[i]; /* Index of column in parent tbl */
85910 char *zDfltColl; /* Def. collation for column */
85911 char *zIdxCol; /* Name of indexed column */
85913 /* If the index uses a collation sequence that is different from
85914 ** the default collation sequence for the column, this index is
85915 ** unusable. Bail out early in this case. */
85916 zDfltColl = pParent->aCol[iCol].zColl;
85917 if( !zDfltColl ){
85918 zDfltColl = "BINARY";
85920 if( sqlite3StrICmp(pIdx->azColl[i], zDfltColl) ) break;
85922 zIdxCol = pParent->aCol[iCol].zName;
85923 for(j=0; j<nCol; j++){
85924 if( sqlite3StrICmp(pFKey->aCol[j].zCol, zIdxCol)==0 ){
85925 if( aiCol ) aiCol[i] = pFKey->aCol[j].iFrom;
85926 break;
85929 if( j==nCol ) break;
85931 if( i==nCol ) break; /* pIdx is usable */
85936 if( !pIdx ){
85937 if( !pParse->disableTriggers ){
85938 sqlite3ErrorMsg(pParse, "foreign key mismatch");
85940 sqlite3DbFree(pParse->db, aiCol);
85941 return 1;
85944 *ppIdx = pIdx;
85945 return 0;
85949 ** This function is called when a row is inserted into or deleted from the
85950 ** child table of foreign key constraint pFKey. If an SQL UPDATE is executed
85951 ** on the child table of pFKey, this function is invoked twice for each row
85952 ** affected - once to "delete" the old row, and then again to "insert" the
85953 ** new row.
85955 ** Each time it is called, this function generates VDBE code to locate the
85956 ** row in the parent table that corresponds to the row being inserted into
85957 ** or deleted from the child table. If the parent row can be found, no
85958 ** special action is taken. Otherwise, if the parent row can *not* be
85959 ** found in the parent table:
85961 ** Operation | FK type | Action taken
85962 ** --------------------------------------------------------------------------
85963 ** INSERT immediate Increment the "immediate constraint counter".
85965 ** DELETE immediate Decrement the "immediate constraint counter".
85967 ** INSERT deferred Increment the "deferred constraint counter".
85969 ** DELETE deferred Decrement the "deferred constraint counter".
85971 ** These operations are identified in the comment at the top of this file
85972 ** (fkey.c) as "I.1" and "D.1".
85974 static void fkLookupParent(
85975 Parse *pParse, /* Parse context */
85976 int iDb, /* Index of database housing pTab */
85977 Table *pTab, /* Parent table of FK pFKey */
85978 Index *pIdx, /* Unique index on parent key columns in pTab */
85979 FKey *pFKey, /* Foreign key constraint */
85980 int *aiCol, /* Map from parent key columns to child table columns */
85981 int regData, /* Address of array containing child table row */
85982 int nIncr, /* Increment constraint counter by this */
85983 int isIgnore /* If true, pretend pTab contains all NULL values */
85985 int i; /* Iterator variable */
85986 Vdbe *v = sqlite3GetVdbe(pParse); /* Vdbe to add code to */
85987 int iCur = pParse->nTab - 1; /* Cursor number to use */
85988 int iOk = sqlite3VdbeMakeLabel(v); /* jump here if parent key found */
85990 /* If nIncr is less than zero, then check at runtime if there are any
85991 ** outstanding constraints to resolve. If there are not, there is no need
85992 ** to check if deleting this row resolves any outstanding violations.
85994 ** Check if any of the key columns in the child table row are NULL. If
85995 ** any are, then the constraint is considered satisfied. No need to
85996 ** search for a matching row in the parent table. */
85997 if( nIncr<0 ){
85998 sqlite3VdbeAddOp2(v, OP_FkIfZero, pFKey->isDeferred, iOk);
86000 for(i=0; i<pFKey->nCol; i++){
86001 int iReg = aiCol[i] + regData + 1;
86002 sqlite3VdbeAddOp2(v, OP_IsNull, iReg, iOk);
86005 if( isIgnore==0 ){
86006 if( pIdx==0 ){
86007 /* If pIdx is NULL, then the parent key is the INTEGER PRIMARY KEY
86008 ** column of the parent table (table pTab). */
86009 int iMustBeInt; /* Address of MustBeInt instruction */
86010 int regTemp = sqlite3GetTempReg(pParse);
86012 /* Invoke MustBeInt to coerce the child key value to an integer (i.e.
86013 ** apply the affinity of the parent key). If this fails, then there
86014 ** is no matching parent key. Before using MustBeInt, make a copy of
86015 ** the value. Otherwise, the value inserted into the child key column
86016 ** will have INTEGER affinity applied to it, which may not be correct. */
86017 sqlite3VdbeAddOp2(v, OP_SCopy, aiCol[0]+1+regData, regTemp);
86018 iMustBeInt = sqlite3VdbeAddOp2(v, OP_MustBeInt, regTemp, 0);
86020 /* If the parent table is the same as the child table, and we are about
86021 ** to increment the constraint-counter (i.e. this is an INSERT operation),
86022 ** then check if the row being inserted matches itself. If so, do not
86023 ** increment the constraint-counter. */
86024 if( pTab==pFKey->pFrom && nIncr==1 ){
86025 sqlite3VdbeAddOp3(v, OP_Eq, regData, iOk, regTemp);
86028 sqlite3OpenTable(pParse, iCur, iDb, pTab, OP_OpenRead);
86029 sqlite3VdbeAddOp3(v, OP_NotExists, iCur, 0, regTemp);
86030 sqlite3VdbeAddOp2(v, OP_Goto, 0, iOk);
86031 sqlite3VdbeJumpHere(v, sqlite3VdbeCurrentAddr(v)-2);
86032 sqlite3VdbeJumpHere(v, iMustBeInt);
86033 sqlite3ReleaseTempReg(pParse, regTemp);
86034 }else{
86035 int nCol = pFKey->nCol;
86036 int regTemp = sqlite3GetTempRange(pParse, nCol);
86037 int regRec = sqlite3GetTempReg(pParse);
86038 KeyInfo *pKey = sqlite3IndexKeyinfo(pParse, pIdx);
86040 sqlite3VdbeAddOp3(v, OP_OpenRead, iCur, pIdx->tnum, iDb);
86041 sqlite3VdbeChangeP4(v, -1, (char*)pKey, P4_KEYINFO_HANDOFF);
86042 for(i=0; i<nCol; i++){
86043 sqlite3VdbeAddOp2(v, OP_Copy, aiCol[i]+1+regData, regTemp+i);
86046 /* If the parent table is the same as the child table, and we are about
86047 ** to increment the constraint-counter (i.e. this is an INSERT operation),
86048 ** then check if the row being inserted matches itself. If so, do not
86049 ** increment the constraint-counter.
86051 ** If any of the parent-key values are NULL, then the row cannot match
86052 ** itself. So set JUMPIFNULL to make sure we do the OP_Found if any
86053 ** of the parent-key values are NULL (at this point it is known that
86054 ** none of the child key values are).
86056 if( pTab==pFKey->pFrom && nIncr==1 ){
86057 int iJump = sqlite3VdbeCurrentAddr(v) + nCol + 1;
86058 for(i=0; i<nCol; i++){
86059 int iChild = aiCol[i]+1+regData;
86060 int iParent = pIdx->aiColumn[i]+1+regData;
86061 assert( aiCol[i]!=pTab->iPKey );
86062 if( pIdx->aiColumn[i]==pTab->iPKey ){
86063 /* The parent key is a composite key that includes the IPK column */
86064 iParent = regData;
86066 sqlite3VdbeAddOp3(v, OP_Ne, iChild, iJump, iParent);
86067 sqlite3VdbeChangeP5(v, SQLITE_JUMPIFNULL);
86069 sqlite3VdbeAddOp2(v, OP_Goto, 0, iOk);
86072 sqlite3VdbeAddOp3(v, OP_MakeRecord, regTemp, nCol, regRec);
86073 sqlite3VdbeChangeP4(v, -1, sqlite3IndexAffinityStr(v,pIdx), P4_TRANSIENT);
86074 sqlite3VdbeAddOp4Int(v, OP_Found, iCur, iOk, regRec, 0);
86076 sqlite3ReleaseTempReg(pParse, regRec);
86077 sqlite3ReleaseTempRange(pParse, regTemp, nCol);
86081 if( !pFKey->isDeferred && !pParse->pToplevel && !pParse->isMultiWrite ){
86082 /* Special case: If this is an INSERT statement that will insert exactly
86083 ** one row into the table, raise a constraint immediately instead of
86084 ** incrementing a counter. This is necessary as the VM code is being
86085 ** generated for will not open a statement transaction. */
86086 assert( nIncr==1 );
86087 sqlite3HaltConstraint(
86088 pParse, OE_Abort, "foreign key constraint failed", P4_STATIC
86090 }else{
86091 if( nIncr>0 && pFKey->isDeferred==0 ){
86092 sqlite3ParseToplevel(pParse)->mayAbort = 1;
86094 sqlite3VdbeAddOp2(v, OP_FkCounter, pFKey->isDeferred, nIncr);
86097 sqlite3VdbeResolveLabel(v, iOk);
86098 sqlite3VdbeAddOp1(v, OP_Close, iCur);
86102 ** This function is called to generate code executed when a row is deleted
86103 ** from the parent table of foreign key constraint pFKey and, if pFKey is
86104 ** deferred, when a row is inserted into the same table. When generating
86105 ** code for an SQL UPDATE operation, this function may be called twice -
86106 ** once to "delete" the old row and once to "insert" the new row.
86108 ** The code generated by this function scans through the rows in the child
86109 ** table that correspond to the parent table row being deleted or inserted.
86110 ** For each child row found, one of the following actions is taken:
86112 ** Operation | FK type | Action taken
86113 ** --------------------------------------------------------------------------
86114 ** DELETE immediate Increment the "immediate constraint counter".
86115 ** Or, if the ON (UPDATE|DELETE) action is RESTRICT,
86116 ** throw a "foreign key constraint failed" exception.
86118 ** INSERT immediate Decrement the "immediate constraint counter".
86120 ** DELETE deferred Increment the "deferred constraint counter".
86121 ** Or, if the ON (UPDATE|DELETE) action is RESTRICT,
86122 ** throw a "foreign key constraint failed" exception.
86124 ** INSERT deferred Decrement the "deferred constraint counter".
86126 ** These operations are identified in the comment at the top of this file
86127 ** (fkey.c) as "I.2" and "D.2".
86129 static void fkScanChildren(
86130 Parse *pParse, /* Parse context */
86131 SrcList *pSrc, /* SrcList containing the table to scan */
86132 Table *pTab,
86133 Index *pIdx, /* Foreign key index */
86134 FKey *pFKey, /* Foreign key relationship */
86135 int *aiCol, /* Map from pIdx cols to child table cols */
86136 int regData, /* Referenced table data starts here */
86137 int nIncr /* Amount to increment deferred counter by */
86139 sqlite3 *db = pParse->db; /* Database handle */
86140 int i; /* Iterator variable */
86141 Expr *pWhere = 0; /* WHERE clause to scan with */
86142 NameContext sNameContext; /* Context used to resolve WHERE clause */
86143 WhereInfo *pWInfo; /* Context used by sqlite3WhereXXX() */
86144 int iFkIfZero = 0; /* Address of OP_FkIfZero */
86145 Vdbe *v = sqlite3GetVdbe(pParse);
86147 assert( !pIdx || pIdx->pTable==pTab );
86149 if( nIncr<0 ){
86150 iFkIfZero = sqlite3VdbeAddOp2(v, OP_FkIfZero, pFKey->isDeferred, 0);
86153 /* Create an Expr object representing an SQL expression like:
86155 ** <parent-key1> = <child-key1> AND <parent-key2> = <child-key2> ...
86157 ** The collation sequence used for the comparison should be that of
86158 ** the parent key columns. The affinity of the parent key column should
86159 ** be applied to each child key value before the comparison takes place.
86161 for(i=0; i<pFKey->nCol; i++){
86162 Expr *pLeft; /* Value from parent table row */
86163 Expr *pRight; /* Column ref to child table */
86164 Expr *pEq; /* Expression (pLeft = pRight) */
86165 int iCol; /* Index of column in child table */
86166 const char *zCol; /* Name of column in child table */
86168 pLeft = sqlite3Expr(db, TK_REGISTER, 0);
86169 if( pLeft ){
86170 /* Set the collation sequence and affinity of the LHS of each TK_EQ
86171 ** expression to the parent key column defaults. */
86172 if( pIdx ){
86173 Column *pCol;
86174 iCol = pIdx->aiColumn[i];
86175 pCol = &pTab->aCol[iCol];
86176 if( pTab->iPKey==iCol ) iCol = -1;
86177 pLeft->iTable = regData+iCol+1;
86178 pLeft->affinity = pCol->affinity;
86179 pLeft->pColl = sqlite3LocateCollSeq(pParse, pCol->zColl);
86180 }else{
86181 pLeft->iTable = regData;
86182 pLeft->affinity = SQLITE_AFF_INTEGER;
86185 iCol = aiCol ? aiCol[i] : pFKey->aCol[0].iFrom;
86186 assert( iCol>=0 );
86187 zCol = pFKey->pFrom->aCol[iCol].zName;
86188 pRight = sqlite3Expr(db, TK_ID, zCol);
86189 pEq = sqlite3PExpr(pParse, TK_EQ, pLeft, pRight, 0);
86190 pWhere = sqlite3ExprAnd(db, pWhere, pEq);
86193 /* If the child table is the same as the parent table, and this scan
86194 ** is taking place as part of a DELETE operation (operation D.2), omit the
86195 ** row being deleted from the scan by adding ($rowid != rowid) to the WHERE
86196 ** clause, where $rowid is the rowid of the row being deleted. */
86197 if( pTab==pFKey->pFrom && nIncr>0 ){
86198 Expr *pEq; /* Expression (pLeft = pRight) */
86199 Expr *pLeft; /* Value from parent table row */
86200 Expr *pRight; /* Column ref to child table */
86201 pLeft = sqlite3Expr(db, TK_REGISTER, 0);
86202 pRight = sqlite3Expr(db, TK_COLUMN, 0);
86203 if( pLeft && pRight ){
86204 pLeft->iTable = regData;
86205 pLeft->affinity = SQLITE_AFF_INTEGER;
86206 pRight->iTable = pSrc->a[0].iCursor;
86207 pRight->iColumn = -1;
86209 pEq = sqlite3PExpr(pParse, TK_NE, pLeft, pRight, 0);
86210 pWhere = sqlite3ExprAnd(db, pWhere, pEq);
86213 /* Resolve the references in the WHERE clause. */
86214 memset(&sNameContext, 0, sizeof(NameContext));
86215 sNameContext.pSrcList = pSrc;
86216 sNameContext.pParse = pParse;
86217 sqlite3ResolveExprNames(&sNameContext, pWhere);
86219 /* Create VDBE to loop through the entries in pSrc that match the WHERE
86220 ** clause. If the constraint is not deferred, throw an exception for
86221 ** each row found. Otherwise, for deferred constraints, increment the
86222 ** deferred constraint counter by nIncr for each row selected. */
86223 pWInfo = sqlite3WhereBegin(pParse, pSrc, pWhere, 0, 0, 0);
86224 if( nIncr>0 && pFKey->isDeferred==0 ){
86225 sqlite3ParseToplevel(pParse)->mayAbort = 1;
86227 sqlite3VdbeAddOp2(v, OP_FkCounter, pFKey->isDeferred, nIncr);
86228 if( pWInfo ){
86229 sqlite3WhereEnd(pWInfo);
86232 /* Clean up the WHERE clause constructed above. */
86233 sqlite3ExprDelete(db, pWhere);
86234 if( iFkIfZero ){
86235 sqlite3VdbeJumpHere(v, iFkIfZero);
86240 ** This function returns a pointer to the head of a linked list of FK
86241 ** constraints for which table pTab is the parent table. For example,
86242 ** given the following schema:
86244 ** CREATE TABLE t1(a PRIMARY KEY);
86245 ** CREATE TABLE t2(b REFERENCES t1(a);
86247 ** Calling this function with table "t1" as an argument returns a pointer
86248 ** to the FKey structure representing the foreign key constraint on table
86249 ** "t2". Calling this function with "t2" as the argument would return a
86250 ** NULL pointer (as there are no FK constraints for which t2 is the parent
86251 ** table).
86253 SQLITE_PRIVATE FKey *sqlite3FkReferences(Table *pTab){
86254 int nName = sqlite3Strlen30(pTab->zName);
86255 return (FKey *)sqlite3HashFind(&pTab->pSchema->fkeyHash, pTab->zName, nName);
86259 ** The second argument is a Trigger structure allocated by the
86260 ** fkActionTrigger() routine. This function deletes the Trigger structure
86261 ** and all of its sub-components.
86263 ** The Trigger structure or any of its sub-components may be allocated from
86264 ** the lookaside buffer belonging to database handle dbMem.
86266 static void fkTriggerDelete(sqlite3 *dbMem, Trigger *p){
86267 if( p ){
86268 TriggerStep *pStep = p->step_list;
86269 sqlite3ExprDelete(dbMem, pStep->pWhere);
86270 sqlite3ExprListDelete(dbMem, pStep->pExprList);
86271 sqlite3SelectDelete(dbMem, pStep->pSelect);
86272 sqlite3ExprDelete(dbMem, p->pWhen);
86273 sqlite3DbFree(dbMem, p);
86278 ** This function is called to generate code that runs when table pTab is
86279 ** being dropped from the database. The SrcList passed as the second argument
86280 ** to this function contains a single entry guaranteed to resolve to
86281 ** table pTab.
86283 ** Normally, no code is required. However, if either
86285 ** (a) The table is the parent table of a FK constraint, or
86286 ** (b) The table is the child table of a deferred FK constraint and it is
86287 ** determined at runtime that there are outstanding deferred FK
86288 ** constraint violations in the database,
86290 ** then the equivalent of "DELETE FROM <tbl>" is executed before dropping
86291 ** the table from the database. Triggers are disabled while running this
86292 ** DELETE, but foreign key actions are not.
86294 SQLITE_PRIVATE void sqlite3FkDropTable(Parse *pParse, SrcList *pName, Table *pTab){
86295 sqlite3 *db = pParse->db;
86296 if( (db->flags&SQLITE_ForeignKeys) && !IsVirtual(pTab) && !pTab->pSelect ){
86297 int iSkip = 0;
86298 Vdbe *v = sqlite3GetVdbe(pParse);
86300 assert( v ); /* VDBE has already been allocated */
86301 if( sqlite3FkReferences(pTab)==0 ){
86302 /* Search for a deferred foreign key constraint for which this table
86303 ** is the child table. If one cannot be found, return without
86304 ** generating any VDBE code. If one can be found, then jump over
86305 ** the entire DELETE if there are no outstanding deferred constraints
86306 ** when this statement is run. */
86307 FKey *p;
86308 for(p=pTab->pFKey; p; p=p->pNextFrom){
86309 if( p->isDeferred ) break;
86311 if( !p ) return;
86312 iSkip = sqlite3VdbeMakeLabel(v);
86313 sqlite3VdbeAddOp2(v, OP_FkIfZero, 1, iSkip);
86316 pParse->disableTriggers = 1;
86317 sqlite3DeleteFrom(pParse, sqlite3SrcListDup(db, pName, 0), 0);
86318 pParse->disableTriggers = 0;
86320 /* If the DELETE has generated immediate foreign key constraint
86321 ** violations, halt the VDBE and return an error at this point, before
86322 ** any modifications to the schema are made. This is because statement
86323 ** transactions are not able to rollback schema changes. */
86324 sqlite3VdbeAddOp2(v, OP_FkIfZero, 0, sqlite3VdbeCurrentAddr(v)+2);
86325 sqlite3HaltConstraint(
86326 pParse, OE_Abort, "foreign key constraint failed", P4_STATIC
86329 if( iSkip ){
86330 sqlite3VdbeResolveLabel(v, iSkip);
86336 ** This function is called when inserting, deleting or updating a row of
86337 ** table pTab to generate VDBE code to perform foreign key constraint
86338 ** processing for the operation.
86340 ** For a DELETE operation, parameter regOld is passed the index of the
86341 ** first register in an array of (pTab->nCol+1) registers containing the
86342 ** rowid of the row being deleted, followed by each of the column values
86343 ** of the row being deleted, from left to right. Parameter regNew is passed
86344 ** zero in this case.
86346 ** For an INSERT operation, regOld is passed zero and regNew is passed the
86347 ** first register of an array of (pTab->nCol+1) registers containing the new
86348 ** row data.
86350 ** For an UPDATE operation, this function is called twice. Once before
86351 ** the original record is deleted from the table using the calling convention
86352 ** described for DELETE. Then again after the original record is deleted
86353 ** but before the new record is inserted using the INSERT convention.
86355 SQLITE_PRIVATE void sqlite3FkCheck(
86356 Parse *pParse, /* Parse context */
86357 Table *pTab, /* Row is being deleted from this table */
86358 int regOld, /* Previous row data is stored here */
86359 int regNew /* New row data is stored here */
86361 sqlite3 *db = pParse->db; /* Database handle */
86362 FKey *pFKey; /* Used to iterate through FKs */
86363 int iDb; /* Index of database containing pTab */
86364 const char *zDb; /* Name of database containing pTab */
86365 int isIgnoreErrors = pParse->disableTriggers;
86367 /* Exactly one of regOld and regNew should be non-zero. */
86368 assert( (regOld==0)!=(regNew==0) );
86370 /* If foreign-keys are disabled, this function is a no-op. */
86371 if( (db->flags&SQLITE_ForeignKeys)==0 ) return;
86373 iDb = sqlite3SchemaToIndex(db, pTab->pSchema);
86374 zDb = db->aDb[iDb].zName;
86376 /* Loop through all the foreign key constraints for which pTab is the
86377 ** child table (the table that the foreign key definition is part of). */
86378 for(pFKey=pTab->pFKey; pFKey; pFKey=pFKey->pNextFrom){
86379 Table *pTo; /* Parent table of foreign key pFKey */
86380 Index *pIdx = 0; /* Index on key columns in pTo */
86381 int *aiFree = 0;
86382 int *aiCol;
86383 int iCol;
86384 int i;
86385 int isIgnore = 0;
86387 /* Find the parent table of this foreign key. Also find a unique index
86388 ** on the parent key columns in the parent table. If either of these
86389 ** schema items cannot be located, set an error in pParse and return
86390 ** early. */
86391 if( pParse->disableTriggers ){
86392 pTo = sqlite3FindTable(db, pFKey->zTo, zDb);
86393 }else{
86394 pTo = sqlite3LocateTable(pParse, 0, pFKey->zTo, zDb);
86396 if( !pTo || locateFkeyIndex(pParse, pTo, pFKey, &pIdx, &aiFree) ){
86397 assert( isIgnoreErrors==0 || (regOld!=0 && regNew==0) );
86398 if( !isIgnoreErrors || db->mallocFailed ) return;
86399 if( pTo==0 ){
86400 /* If isIgnoreErrors is true, then a table is being dropped. In this
86401 ** case SQLite runs a "DELETE FROM xxx" on the table being dropped
86402 ** before actually dropping it in order to check FK constraints.
86403 ** If the parent table of an FK constraint on the current table is
86404 ** missing, behave as if it is empty. i.e. decrement the relevant
86405 ** FK counter for each row of the current table with non-NULL keys.
86407 Vdbe *v = sqlite3GetVdbe(pParse);
86408 int iJump = sqlite3VdbeCurrentAddr(v) + pFKey->nCol + 1;
86409 for(i=0; i<pFKey->nCol; i++){
86410 int iReg = pFKey->aCol[i].iFrom + regOld + 1;
86411 sqlite3VdbeAddOp2(v, OP_IsNull, iReg, iJump);
86413 sqlite3VdbeAddOp2(v, OP_FkCounter, pFKey->isDeferred, -1);
86415 continue;
86417 assert( pFKey->nCol==1 || (aiFree && pIdx) );
86419 if( aiFree ){
86420 aiCol = aiFree;
86421 }else{
86422 iCol = pFKey->aCol[0].iFrom;
86423 aiCol = &iCol;
86425 for(i=0; i<pFKey->nCol; i++){
86426 if( aiCol[i]==pTab->iPKey ){
86427 aiCol[i] = -1;
86429 #ifndef SQLITE_OMIT_AUTHORIZATION
86430 /* Request permission to read the parent key columns. If the
86431 ** authorization callback returns SQLITE_IGNORE, behave as if any
86432 ** values read from the parent table are NULL. */
86433 if( db->xAuth ){
86434 int rcauth;
86435 char *zCol = pTo->aCol[pIdx ? pIdx->aiColumn[i] : pTo->iPKey].zName;
86436 rcauth = sqlite3AuthReadCol(pParse, pTo->zName, zCol, iDb);
86437 isIgnore = (rcauth==SQLITE_IGNORE);
86439 #endif
86442 /* Take a shared-cache advisory read-lock on the parent table. Allocate
86443 ** a cursor to use to search the unique index on the parent key columns
86444 ** in the parent table. */
86445 sqlite3TableLock(pParse, iDb, pTo->tnum, 0, pTo->zName);
86446 pParse->nTab++;
86448 if( regOld!=0 ){
86449 /* A row is being removed from the child table. Search for the parent.
86450 ** If the parent does not exist, removing the child row resolves an
86451 ** outstanding foreign key constraint violation. */
86452 fkLookupParent(pParse, iDb, pTo, pIdx, pFKey, aiCol, regOld, -1,isIgnore);
86454 if( regNew!=0 ){
86455 /* A row is being added to the child table. If a parent row cannot
86456 ** be found, adding the child row has violated the FK constraint. */
86457 fkLookupParent(pParse, iDb, pTo, pIdx, pFKey, aiCol, regNew, +1,isIgnore);
86460 sqlite3DbFree(db, aiFree);
86463 /* Loop through all the foreign key constraints that refer to this table */
86464 for(pFKey = sqlite3FkReferences(pTab); pFKey; pFKey=pFKey->pNextTo){
86465 Index *pIdx = 0; /* Foreign key index for pFKey */
86466 SrcList *pSrc;
86467 int *aiCol = 0;
86469 if( !pFKey->isDeferred && !pParse->pToplevel && !pParse->isMultiWrite ){
86470 assert( regOld==0 && regNew!=0 );
86471 /* Inserting a single row into a parent table cannot cause an immediate
86472 ** foreign key violation. So do nothing in this case. */
86473 continue;
86476 if( locateFkeyIndex(pParse, pTab, pFKey, &pIdx, &aiCol) ){
86477 if( !isIgnoreErrors || db->mallocFailed ) return;
86478 continue;
86480 assert( aiCol || pFKey->nCol==1 );
86482 /* Create a SrcList structure containing a single table (the table
86483 ** the foreign key that refers to this table is attached to). This
86484 ** is required for the sqlite3WhereXXX() interface. */
86485 pSrc = sqlite3SrcListAppend(db, 0, 0, 0);
86486 if( pSrc ){
86487 struct SrcList_item *pItem = pSrc->a;
86488 pItem->pTab = pFKey->pFrom;
86489 pItem->zName = pFKey->pFrom->zName;
86490 pItem->pTab->nRef++;
86491 pItem->iCursor = pParse->nTab++;
86493 if( regNew!=0 ){
86494 fkScanChildren(pParse, pSrc, pTab, pIdx, pFKey, aiCol, regNew, -1);
86496 if( regOld!=0 ){
86497 /* If there is a RESTRICT action configured for the current operation
86498 ** on the parent table of this FK, then throw an exception
86499 ** immediately if the FK constraint is violated, even if this is a
86500 ** deferred trigger. That's what RESTRICT means. To defer checking
86501 ** the constraint, the FK should specify NO ACTION (represented
86502 ** using OE_None). NO ACTION is the default. */
86503 fkScanChildren(pParse, pSrc, pTab, pIdx, pFKey, aiCol, regOld, 1);
86505 pItem->zName = 0;
86506 sqlite3SrcListDelete(db, pSrc);
86508 sqlite3DbFree(db, aiCol);
86512 #define COLUMN_MASK(x) (((x)>31) ? 0xffffffff : ((u32)1<<(x)))
86515 ** This function is called before generating code to update or delete a
86516 ** row contained in table pTab.
86518 SQLITE_PRIVATE u32 sqlite3FkOldmask(
86519 Parse *pParse, /* Parse context */
86520 Table *pTab /* Table being modified */
86522 u32 mask = 0;
86523 if( pParse->db->flags&SQLITE_ForeignKeys ){
86524 FKey *p;
86525 int i;
86526 for(p=pTab->pFKey; p; p=p->pNextFrom){
86527 for(i=0; i<p->nCol; i++) mask |= COLUMN_MASK(p->aCol[i].iFrom);
86529 for(p=sqlite3FkReferences(pTab); p; p=p->pNextTo){
86530 Index *pIdx = 0;
86531 locateFkeyIndex(pParse, pTab, p, &pIdx, 0);
86532 if( pIdx ){
86533 for(i=0; i<pIdx->nColumn; i++) mask |= COLUMN_MASK(pIdx->aiColumn[i]);
86537 return mask;
86541 ** This function is called before generating code to update or delete a
86542 ** row contained in table pTab. If the operation is a DELETE, then
86543 ** parameter aChange is passed a NULL value. For an UPDATE, aChange points
86544 ** to an array of size N, where N is the number of columns in table pTab.
86545 ** If the i'th column is not modified by the UPDATE, then the corresponding
86546 ** entry in the aChange[] array is set to -1. If the column is modified,
86547 ** the value is 0 or greater. Parameter chngRowid is set to true if the
86548 ** UPDATE statement modifies the rowid fields of the table.
86550 ** If any foreign key processing will be required, this function returns
86551 ** true. If there is no foreign key related processing, this function
86552 ** returns false.
86554 SQLITE_PRIVATE int sqlite3FkRequired(
86555 Parse *pParse, /* Parse context */
86556 Table *pTab, /* Table being modified */
86557 int *aChange, /* Non-NULL for UPDATE operations */
86558 int chngRowid /* True for UPDATE that affects rowid */
86560 if( pParse->db->flags&SQLITE_ForeignKeys ){
86561 if( !aChange ){
86562 /* A DELETE operation. Foreign key processing is required if the
86563 ** table in question is either the child or parent table for any
86564 ** foreign key constraint. */
86565 return (sqlite3FkReferences(pTab) || pTab->pFKey);
86566 }else{
86567 /* This is an UPDATE. Foreign key processing is only required if the
86568 ** operation modifies one or more child or parent key columns. */
86569 int i;
86570 FKey *p;
86572 /* Check if any child key columns are being modified. */
86573 for(p=pTab->pFKey; p; p=p->pNextFrom){
86574 for(i=0; i<p->nCol; i++){
86575 int iChildKey = p->aCol[i].iFrom;
86576 if( aChange[iChildKey]>=0 ) return 1;
86577 if( iChildKey==pTab->iPKey && chngRowid ) return 1;
86581 /* Check if any parent key columns are being modified. */
86582 for(p=sqlite3FkReferences(pTab); p; p=p->pNextTo){
86583 for(i=0; i<p->nCol; i++){
86584 char *zKey = p->aCol[i].zCol;
86585 int iKey;
86586 for(iKey=0; iKey<pTab->nCol; iKey++){
86587 Column *pCol = &pTab->aCol[iKey];
86588 if( (zKey ? !sqlite3StrICmp(pCol->zName, zKey) : pCol->isPrimKey) ){
86589 if( aChange[iKey]>=0 ) return 1;
86590 if( iKey==pTab->iPKey && chngRowid ) return 1;
86597 return 0;
86601 ** This function is called when an UPDATE or DELETE operation is being
86602 ** compiled on table pTab, which is the parent table of foreign-key pFKey.
86603 ** If the current operation is an UPDATE, then the pChanges parameter is
86604 ** passed a pointer to the list of columns being modified. If it is a
86605 ** DELETE, pChanges is passed a NULL pointer.
86607 ** It returns a pointer to a Trigger structure containing a trigger
86608 ** equivalent to the ON UPDATE or ON DELETE action specified by pFKey.
86609 ** If the action is "NO ACTION" or "RESTRICT", then a NULL pointer is
86610 ** returned (these actions require no special handling by the triggers
86611 ** sub-system, code for them is created by fkScanChildren()).
86613 ** For example, if pFKey is the foreign key and pTab is table "p" in
86614 ** the following schema:
86616 ** CREATE TABLE p(pk PRIMARY KEY);
86617 ** CREATE TABLE c(ck REFERENCES p ON DELETE CASCADE);
86619 ** then the returned trigger structure is equivalent to:
86621 ** CREATE TRIGGER ... DELETE ON p BEGIN
86622 ** DELETE FROM c WHERE ck = old.pk;
86623 ** END;
86625 ** The returned pointer is cached as part of the foreign key object. It
86626 ** is eventually freed along with the rest of the foreign key object by
86627 ** sqlite3FkDelete().
86629 static Trigger *fkActionTrigger(
86630 Parse *pParse, /* Parse context */
86631 Table *pTab, /* Table being updated or deleted from */
86632 FKey *pFKey, /* Foreign key to get action for */
86633 ExprList *pChanges /* Change-list for UPDATE, NULL for DELETE */
86635 sqlite3 *db = pParse->db; /* Database handle */
86636 int action; /* One of OE_None, OE_Cascade etc. */
86637 Trigger *pTrigger; /* Trigger definition to return */
86638 int iAction = (pChanges!=0); /* 1 for UPDATE, 0 for DELETE */
86640 action = pFKey->aAction[iAction];
86641 pTrigger = pFKey->apTrigger[iAction];
86643 if( action!=OE_None && !pTrigger ){
86644 u8 enableLookaside; /* Copy of db->lookaside.bEnabled */
86645 char const *zFrom; /* Name of child table */
86646 int nFrom; /* Length in bytes of zFrom */
86647 Index *pIdx = 0; /* Parent key index for this FK */
86648 int *aiCol = 0; /* child table cols -> parent key cols */
86649 TriggerStep *pStep = 0; /* First (only) step of trigger program */
86650 Expr *pWhere = 0; /* WHERE clause of trigger step */
86651 ExprList *pList = 0; /* Changes list if ON UPDATE CASCADE */
86652 Select *pSelect = 0; /* If RESTRICT, "SELECT RAISE(...)" */
86653 int i; /* Iterator variable */
86654 Expr *pWhen = 0; /* WHEN clause for the trigger */
86656 if( locateFkeyIndex(pParse, pTab, pFKey, &pIdx, &aiCol) ) return 0;
86657 assert( aiCol || pFKey->nCol==1 );
86659 for(i=0; i<pFKey->nCol; i++){
86660 Token tOld = { "old", 3 }; /* Literal "old" token */
86661 Token tNew = { "new", 3 }; /* Literal "new" token */
86662 Token tFromCol; /* Name of column in child table */
86663 Token tToCol; /* Name of column in parent table */
86664 int iFromCol; /* Idx of column in child table */
86665 Expr *pEq; /* tFromCol = OLD.tToCol */
86667 iFromCol = aiCol ? aiCol[i] : pFKey->aCol[0].iFrom;
86668 assert( iFromCol>=0 );
86669 tToCol.z = pIdx ? pTab->aCol[pIdx->aiColumn[i]].zName : "oid";
86670 tFromCol.z = pFKey->pFrom->aCol[iFromCol].zName;
86672 tToCol.n = sqlite3Strlen30(tToCol.z);
86673 tFromCol.n = sqlite3Strlen30(tFromCol.z);
86675 /* Create the expression "OLD.zToCol = zFromCol". It is important
86676 ** that the "OLD.zToCol" term is on the LHS of the = operator, so
86677 ** that the affinity and collation sequence associated with the
86678 ** parent table are used for the comparison. */
86679 pEq = sqlite3PExpr(pParse, TK_EQ,
86680 sqlite3PExpr(pParse, TK_DOT,
86681 sqlite3PExpr(pParse, TK_ID, 0, 0, &tOld),
86682 sqlite3PExpr(pParse, TK_ID, 0, 0, &tToCol)
86683 , 0),
86684 sqlite3PExpr(pParse, TK_ID, 0, 0, &tFromCol)
86685 , 0);
86686 pWhere = sqlite3ExprAnd(db, pWhere, pEq);
86688 /* For ON UPDATE, construct the next term of the WHEN clause.
86689 ** The final WHEN clause will be like this:
86691 ** WHEN NOT(old.col1 IS new.col1 AND ... AND old.colN IS new.colN)
86693 if( pChanges ){
86694 pEq = sqlite3PExpr(pParse, TK_IS,
86695 sqlite3PExpr(pParse, TK_DOT,
86696 sqlite3PExpr(pParse, TK_ID, 0, 0, &tOld),
86697 sqlite3PExpr(pParse, TK_ID, 0, 0, &tToCol),
86699 sqlite3PExpr(pParse, TK_DOT,
86700 sqlite3PExpr(pParse, TK_ID, 0, 0, &tNew),
86701 sqlite3PExpr(pParse, TK_ID, 0, 0, &tToCol),
86704 pWhen = sqlite3ExprAnd(db, pWhen, pEq);
86707 if( action!=OE_Restrict && (action!=OE_Cascade || pChanges) ){
86708 Expr *pNew;
86709 if( action==OE_Cascade ){
86710 pNew = sqlite3PExpr(pParse, TK_DOT,
86711 sqlite3PExpr(pParse, TK_ID, 0, 0, &tNew),
86712 sqlite3PExpr(pParse, TK_ID, 0, 0, &tToCol)
86713 , 0);
86714 }else if( action==OE_SetDflt ){
86715 Expr *pDflt = pFKey->pFrom->aCol[iFromCol].pDflt;
86716 if( pDflt ){
86717 pNew = sqlite3ExprDup(db, pDflt, 0);
86718 }else{
86719 pNew = sqlite3PExpr(pParse, TK_NULL, 0, 0, 0);
86721 }else{
86722 pNew = sqlite3PExpr(pParse, TK_NULL, 0, 0, 0);
86724 pList = sqlite3ExprListAppend(pParse, pList, pNew);
86725 sqlite3ExprListSetName(pParse, pList, &tFromCol, 0);
86728 sqlite3DbFree(db, aiCol);
86730 zFrom = pFKey->pFrom->zName;
86731 nFrom = sqlite3Strlen30(zFrom);
86733 if( action==OE_Restrict ){
86734 Token tFrom;
86735 Expr *pRaise;
86737 tFrom.z = zFrom;
86738 tFrom.n = nFrom;
86739 pRaise = sqlite3Expr(db, TK_RAISE, "foreign key constraint failed");
86740 if( pRaise ){
86741 pRaise->affinity = OE_Abort;
86743 pSelect = sqlite3SelectNew(pParse,
86744 sqlite3ExprListAppend(pParse, 0, pRaise),
86745 sqlite3SrcListAppend(db, 0, &tFrom, 0),
86746 pWhere,
86747 0, 0, 0, 0, 0, 0
86749 pWhere = 0;
86752 /* Disable lookaside memory allocation */
86753 enableLookaside = db->lookaside.bEnabled;
86754 db->lookaside.bEnabled = 0;
86756 pTrigger = (Trigger *)sqlite3DbMallocZero(db,
86757 sizeof(Trigger) + /* struct Trigger */
86758 sizeof(TriggerStep) + /* Single step in trigger program */
86759 nFrom + 1 /* Space for pStep->target.z */
86761 if( pTrigger ){
86762 pStep = pTrigger->step_list = (TriggerStep *)&pTrigger[1];
86763 pStep->target.z = (char *)&pStep[1];
86764 pStep->target.n = nFrom;
86765 memcpy((char *)pStep->target.z, zFrom, nFrom);
86767 pStep->pWhere = sqlite3ExprDup(db, pWhere, EXPRDUP_REDUCE);
86768 pStep->pExprList = sqlite3ExprListDup(db, pList, EXPRDUP_REDUCE);
86769 pStep->pSelect = sqlite3SelectDup(db, pSelect, EXPRDUP_REDUCE);
86770 if( pWhen ){
86771 pWhen = sqlite3PExpr(pParse, TK_NOT, pWhen, 0, 0);
86772 pTrigger->pWhen = sqlite3ExprDup(db, pWhen, EXPRDUP_REDUCE);
86776 /* Re-enable the lookaside buffer, if it was disabled earlier. */
86777 db->lookaside.bEnabled = enableLookaside;
86779 sqlite3ExprDelete(db, pWhere);
86780 sqlite3ExprDelete(db, pWhen);
86781 sqlite3ExprListDelete(db, pList);
86782 sqlite3SelectDelete(db, pSelect);
86783 if( db->mallocFailed==1 ){
86784 fkTriggerDelete(db, pTrigger);
86785 return 0;
86788 switch( action ){
86789 case OE_Restrict:
86790 pStep->op = TK_SELECT;
86791 break;
86792 case OE_Cascade:
86793 if( !pChanges ){
86794 pStep->op = TK_DELETE;
86795 break;
86797 default:
86798 pStep->op = TK_UPDATE;
86800 pStep->pTrig = pTrigger;
86801 pTrigger->pSchema = pTab->pSchema;
86802 pTrigger->pTabSchema = pTab->pSchema;
86803 pFKey->apTrigger[iAction] = pTrigger;
86804 pTrigger->op = (pChanges ? TK_UPDATE : TK_DELETE);
86807 return pTrigger;
86811 ** This function is called when deleting or updating a row to implement
86812 ** any required CASCADE, SET NULL or SET DEFAULT actions.
86814 SQLITE_PRIVATE void sqlite3FkActions(
86815 Parse *pParse, /* Parse context */
86816 Table *pTab, /* Table being updated or deleted from */
86817 ExprList *pChanges, /* Change-list for UPDATE, NULL for DELETE */
86818 int regOld /* Address of array containing old row */
86820 /* If foreign-key support is enabled, iterate through all FKs that
86821 ** refer to table pTab. If there is an action associated with the FK
86822 ** for this operation (either update or delete), invoke the associated
86823 ** trigger sub-program. */
86824 if( pParse->db->flags&SQLITE_ForeignKeys ){
86825 FKey *pFKey; /* Iterator variable */
86826 for(pFKey = sqlite3FkReferences(pTab); pFKey; pFKey=pFKey->pNextTo){
86827 Trigger *pAction = fkActionTrigger(pParse, pTab, pFKey, pChanges);
86828 if( pAction ){
86829 sqlite3CodeRowTriggerDirect(pParse, pAction, pTab, regOld, OE_Abort, 0);
86835 #endif /* ifndef SQLITE_OMIT_TRIGGER */
86838 ** Free all memory associated with foreign key definitions attached to
86839 ** table pTab. Remove the deleted foreign keys from the Schema.fkeyHash
86840 ** hash table.
86842 SQLITE_PRIVATE void sqlite3FkDelete(sqlite3 *db, Table *pTab){
86843 FKey *pFKey; /* Iterator variable */
86844 FKey *pNext; /* Copy of pFKey->pNextFrom */
86846 assert( db==0 || sqlite3SchemaMutexHeld(db, 0, pTab->pSchema) );
86847 for(pFKey=pTab->pFKey; pFKey; pFKey=pNext){
86849 /* Remove the FK from the fkeyHash hash table. */
86850 if( !db || db->pnBytesFreed==0 ){
86851 if( pFKey->pPrevTo ){
86852 pFKey->pPrevTo->pNextTo = pFKey->pNextTo;
86853 }else{
86854 void *p = (void *)pFKey->pNextTo;
86855 const char *z = (p ? pFKey->pNextTo->zTo : pFKey->zTo);
86856 sqlite3HashInsert(&pTab->pSchema->fkeyHash, z, sqlite3Strlen30(z), p);
86858 if( pFKey->pNextTo ){
86859 pFKey->pNextTo->pPrevTo = pFKey->pPrevTo;
86863 /* EV: R-30323-21917 Each foreign key constraint in SQLite is
86864 ** classified as either immediate or deferred.
86866 assert( pFKey->isDeferred==0 || pFKey->isDeferred==1 );
86868 /* Delete any triggers created to implement actions for this FK. */
86869 #ifndef SQLITE_OMIT_TRIGGER
86870 fkTriggerDelete(db, pFKey->apTrigger[0]);
86871 fkTriggerDelete(db, pFKey->apTrigger[1]);
86872 #endif
86874 pNext = pFKey->pNextFrom;
86875 sqlite3DbFree(db, pFKey);
86878 #endif /* ifndef SQLITE_OMIT_FOREIGN_KEY */
86880 /************** End of fkey.c ************************************************/
86881 /************** Begin file insert.c ******************************************/
86883 ** 2001 September 15
86885 ** The author disclaims copyright to this source code. In place of
86886 ** a legal notice, here is a blessing:
86888 ** May you do good and not evil.
86889 ** May you find forgiveness for yourself and forgive others.
86890 ** May you share freely, never taking more than you give.
86892 *************************************************************************
86893 ** This file contains C code routines that are called by the parser
86894 ** to handle INSERT statements in SQLite.
86898 ** Generate code that will open a table for reading.
86900 SQLITE_PRIVATE void sqlite3OpenTable(
86901 Parse *p, /* Generate code into this VDBE */
86902 int iCur, /* The cursor number of the table */
86903 int iDb, /* The database index in sqlite3.aDb[] */
86904 Table *pTab, /* The table to be opened */
86905 int opcode /* OP_OpenRead or OP_OpenWrite */
86907 Vdbe *v;
86908 if( IsVirtual(pTab) ) return;
86909 v = sqlite3GetVdbe(p);
86910 assert( opcode==OP_OpenWrite || opcode==OP_OpenRead );
86911 sqlite3TableLock(p, iDb, pTab->tnum, (opcode==OP_OpenWrite)?1:0, pTab->zName);
86912 sqlite3VdbeAddOp3(v, opcode, iCur, pTab->tnum, iDb);
86913 sqlite3VdbeChangeP4(v, -1, SQLITE_INT_TO_PTR(pTab->nCol), P4_INT32);
86914 VdbeComment((v, "%s", pTab->zName));
86918 ** Return a pointer to the column affinity string associated with index
86919 ** pIdx. A column affinity string has one character for each column in
86920 ** the table, according to the affinity of the column:
86922 ** Character Column affinity
86923 ** ------------------------------
86924 ** 'a' TEXT
86925 ** 'b' NONE
86926 ** 'c' NUMERIC
86927 ** 'd' INTEGER
86928 ** 'e' REAL
86930 ** An extra 'b' is appended to the end of the string to cover the
86931 ** rowid that appears as the last column in every index.
86933 ** Memory for the buffer containing the column index affinity string
86934 ** is managed along with the rest of the Index structure. It will be
86935 ** released when sqlite3DeleteIndex() is called.
86937 SQLITE_PRIVATE const char *sqlite3IndexAffinityStr(Vdbe *v, Index *pIdx){
86938 if( !pIdx->zColAff ){
86939 /* The first time a column affinity string for a particular index is
86940 ** required, it is allocated and populated here. It is then stored as
86941 ** a member of the Index structure for subsequent use.
86943 ** The column affinity string will eventually be deleted by
86944 ** sqliteDeleteIndex() when the Index structure itself is cleaned
86945 ** up.
86947 int n;
86948 Table *pTab = pIdx->pTable;
86949 sqlite3 *db = sqlite3VdbeDb(v);
86950 pIdx->zColAff = (char *)sqlite3DbMallocRaw(0, pIdx->nColumn+2);
86951 if( !pIdx->zColAff ){
86952 db->mallocFailed = 1;
86953 return 0;
86955 for(n=0; n<pIdx->nColumn; n++){
86956 pIdx->zColAff[n] = pTab->aCol[pIdx->aiColumn[n]].affinity;
86958 pIdx->zColAff[n++] = SQLITE_AFF_NONE;
86959 pIdx->zColAff[n] = 0;
86962 return pIdx->zColAff;
86966 ** Set P4 of the most recently inserted opcode to a column affinity
86967 ** string for table pTab. A column affinity string has one character
86968 ** for each column indexed by the index, according to the affinity of the
86969 ** column:
86971 ** Character Column affinity
86972 ** ------------------------------
86973 ** 'a' TEXT
86974 ** 'b' NONE
86975 ** 'c' NUMERIC
86976 ** 'd' INTEGER
86977 ** 'e' REAL
86979 SQLITE_PRIVATE void sqlite3TableAffinityStr(Vdbe *v, Table *pTab){
86980 /* The first time a column affinity string for a particular table
86981 ** is required, it is allocated and populated here. It is then
86982 ** stored as a member of the Table structure for subsequent use.
86984 ** The column affinity string will eventually be deleted by
86985 ** sqlite3DeleteTable() when the Table structure itself is cleaned up.
86987 if( !pTab->zColAff ){
86988 char *zColAff;
86989 int i;
86990 sqlite3 *db = sqlite3VdbeDb(v);
86992 zColAff = (char *)sqlite3DbMallocRaw(0, pTab->nCol+1);
86993 if( !zColAff ){
86994 db->mallocFailed = 1;
86995 return;
86998 for(i=0; i<pTab->nCol; i++){
86999 zColAff[i] = pTab->aCol[i].affinity;
87001 zColAff[pTab->nCol] = '\0';
87003 pTab->zColAff = zColAff;
87006 sqlite3VdbeChangeP4(v, -1, pTab->zColAff, P4_TRANSIENT);
87010 ** Return non-zero if the table pTab in database iDb or any of its indices
87011 ** have been opened at any point in the VDBE program beginning at location
87012 ** iStartAddr throught the end of the program. This is used to see if
87013 ** a statement of the form "INSERT INTO <iDb, pTab> SELECT ..." can
87014 ** run without using temporary table for the results of the SELECT.
87016 static int readsTable(Parse *p, int iStartAddr, int iDb, Table *pTab){
87017 Vdbe *v = sqlite3GetVdbe(p);
87018 int i;
87019 int iEnd = sqlite3VdbeCurrentAddr(v);
87020 #ifndef SQLITE_OMIT_VIRTUALTABLE
87021 VTable *pVTab = IsVirtual(pTab) ? sqlite3GetVTable(p->db, pTab) : 0;
87022 #endif
87024 for(i=iStartAddr; i<iEnd; i++){
87025 VdbeOp *pOp = sqlite3VdbeGetOp(v, i);
87026 assert( pOp!=0 );
87027 if( pOp->opcode==OP_OpenRead && pOp->p3==iDb ){
87028 Index *pIndex;
87029 int tnum = pOp->p2;
87030 if( tnum==pTab->tnum ){
87031 return 1;
87033 for(pIndex=pTab->pIndex; pIndex; pIndex=pIndex->pNext){
87034 if( tnum==pIndex->tnum ){
87035 return 1;
87039 #ifndef SQLITE_OMIT_VIRTUALTABLE
87040 if( pOp->opcode==OP_VOpen && pOp->p4.pVtab==pVTab ){
87041 assert( pOp->p4.pVtab!=0 );
87042 assert( pOp->p4type==P4_VTAB );
87043 return 1;
87045 #endif
87047 return 0;
87050 #ifndef SQLITE_OMIT_AUTOINCREMENT
87052 ** Locate or create an AutoincInfo structure associated with table pTab
87053 ** which is in database iDb. Return the register number for the register
87054 ** that holds the maximum rowid.
87056 ** There is at most one AutoincInfo structure per table even if the
87057 ** same table is autoincremented multiple times due to inserts within
87058 ** triggers. A new AutoincInfo structure is created if this is the
87059 ** first use of table pTab. On 2nd and subsequent uses, the original
87060 ** AutoincInfo structure is used.
87062 ** Three memory locations are allocated:
87064 ** (1) Register to hold the name of the pTab table.
87065 ** (2) Register to hold the maximum ROWID of pTab.
87066 ** (3) Register to hold the rowid in sqlite_sequence of pTab
87068 ** The 2nd register is the one that is returned. That is all the
87069 ** insert routine needs to know about.
87071 static int autoIncBegin(
87072 Parse *pParse, /* Parsing context */
87073 int iDb, /* Index of the database holding pTab */
87074 Table *pTab /* The table we are writing to */
87076 int memId = 0; /* Register holding maximum rowid */
87077 if( pTab->tabFlags & TF_Autoincrement ){
87078 Parse *pToplevel = sqlite3ParseToplevel(pParse);
87079 AutoincInfo *pInfo;
87081 pInfo = pToplevel->pAinc;
87082 while( pInfo && pInfo->pTab!=pTab ){ pInfo = pInfo->pNext; }
87083 if( pInfo==0 ){
87084 pInfo = sqlite3DbMallocRaw(pParse->db, sizeof(*pInfo));
87085 if( pInfo==0 ) return 0;
87086 pInfo->pNext = pToplevel->pAinc;
87087 pToplevel->pAinc = pInfo;
87088 pInfo->pTab = pTab;
87089 pInfo->iDb = iDb;
87090 pToplevel->nMem++; /* Register to hold name of table */
87091 pInfo->regCtr = ++pToplevel->nMem; /* Max rowid register */
87092 pToplevel->nMem++; /* Rowid in sqlite_sequence */
87094 memId = pInfo->regCtr;
87096 return memId;
87100 ** This routine generates code that will initialize all of the
87101 ** register used by the autoincrement tracker.
87103 SQLITE_PRIVATE void sqlite3AutoincrementBegin(Parse *pParse){
87104 AutoincInfo *p; /* Information about an AUTOINCREMENT */
87105 sqlite3 *db = pParse->db; /* The database connection */
87106 Db *pDb; /* Database only autoinc table */
87107 int memId; /* Register holding max rowid */
87108 int addr; /* A VDBE address */
87109 Vdbe *v = pParse->pVdbe; /* VDBE under construction */
87111 /* This routine is never called during trigger-generation. It is
87112 ** only called from the top-level */
87113 assert( pParse->pTriggerTab==0 );
87114 assert( pParse==sqlite3ParseToplevel(pParse) );
87116 assert( v ); /* We failed long ago if this is not so */
87117 for(p = pParse->pAinc; p; p = p->pNext){
87118 pDb = &db->aDb[p->iDb];
87119 memId = p->regCtr;
87120 assert( sqlite3SchemaMutexHeld(db, 0, pDb->pSchema) );
87121 sqlite3OpenTable(pParse, 0, p->iDb, pDb->pSchema->pSeqTab, OP_OpenRead);
87122 addr = sqlite3VdbeCurrentAddr(v);
87123 sqlite3VdbeAddOp4(v, OP_String8, 0, memId-1, 0, p->pTab->zName, 0);
87124 sqlite3VdbeAddOp2(v, OP_Rewind, 0, addr+9);
87125 sqlite3VdbeAddOp3(v, OP_Column, 0, 0, memId);
87126 sqlite3VdbeAddOp3(v, OP_Ne, memId-1, addr+7, memId);
87127 sqlite3VdbeChangeP5(v, SQLITE_JUMPIFNULL);
87128 sqlite3VdbeAddOp2(v, OP_Rowid, 0, memId+1);
87129 sqlite3VdbeAddOp3(v, OP_Column, 0, 1, memId);
87130 sqlite3VdbeAddOp2(v, OP_Goto, 0, addr+9);
87131 sqlite3VdbeAddOp2(v, OP_Next, 0, addr+2);
87132 sqlite3VdbeAddOp2(v, OP_Integer, 0, memId);
87133 sqlite3VdbeAddOp0(v, OP_Close);
87138 ** Update the maximum rowid for an autoincrement calculation.
87140 ** This routine should be called when the top of the stack holds a
87141 ** new rowid that is about to be inserted. If that new rowid is
87142 ** larger than the maximum rowid in the memId memory cell, then the
87143 ** memory cell is updated. The stack is unchanged.
87145 static void autoIncStep(Parse *pParse, int memId, int regRowid){
87146 if( memId>0 ){
87147 sqlite3VdbeAddOp2(pParse->pVdbe, OP_MemMax, memId, regRowid);
87152 ** This routine generates the code needed to write autoincrement
87153 ** maximum rowid values back into the sqlite_sequence register.
87154 ** Every statement that might do an INSERT into an autoincrement
87155 ** table (either directly or through triggers) needs to call this
87156 ** routine just before the "exit" code.
87158 SQLITE_PRIVATE void sqlite3AutoincrementEnd(Parse *pParse){
87159 AutoincInfo *p;
87160 Vdbe *v = pParse->pVdbe;
87161 sqlite3 *db = pParse->db;
87163 assert( v );
87164 for(p = pParse->pAinc; p; p = p->pNext){
87165 Db *pDb = &db->aDb[p->iDb];
87166 int j1, j2, j3, j4, j5;
87167 int iRec;
87168 int memId = p->regCtr;
87170 iRec = sqlite3GetTempReg(pParse);
87171 assert( sqlite3SchemaMutexHeld(db, 0, pDb->pSchema) );
87172 sqlite3OpenTable(pParse, 0, p->iDb, pDb->pSchema->pSeqTab, OP_OpenWrite);
87173 j1 = sqlite3VdbeAddOp1(v, OP_NotNull, memId+1);
87174 j2 = sqlite3VdbeAddOp0(v, OP_Rewind);
87175 j3 = sqlite3VdbeAddOp3(v, OP_Column, 0, 0, iRec);
87176 j4 = sqlite3VdbeAddOp3(v, OP_Eq, memId-1, 0, iRec);
87177 sqlite3VdbeAddOp2(v, OP_Next, 0, j3);
87178 sqlite3VdbeJumpHere(v, j2);
87179 sqlite3VdbeAddOp2(v, OP_NewRowid, 0, memId+1);
87180 j5 = sqlite3VdbeAddOp0(v, OP_Goto);
87181 sqlite3VdbeJumpHere(v, j4);
87182 sqlite3VdbeAddOp2(v, OP_Rowid, 0, memId+1);
87183 sqlite3VdbeJumpHere(v, j1);
87184 sqlite3VdbeJumpHere(v, j5);
87185 sqlite3VdbeAddOp3(v, OP_MakeRecord, memId-1, 2, iRec);
87186 sqlite3VdbeAddOp3(v, OP_Insert, 0, iRec, memId+1);
87187 sqlite3VdbeChangeP5(v, OPFLAG_APPEND);
87188 sqlite3VdbeAddOp0(v, OP_Close);
87189 sqlite3ReleaseTempReg(pParse, iRec);
87192 #else
87194 ** If SQLITE_OMIT_AUTOINCREMENT is defined, then the three routines
87195 ** above are all no-ops
87197 # define autoIncBegin(A,B,C) (0)
87198 # define autoIncStep(A,B,C)
87199 #endif /* SQLITE_OMIT_AUTOINCREMENT */
87202 /* Forward declaration */
87203 static int xferOptimization(
87204 Parse *pParse, /* Parser context */
87205 Table *pDest, /* The table we are inserting into */
87206 Select *pSelect, /* A SELECT statement to use as the data source */
87207 int onError, /* How to handle constraint errors */
87208 int iDbDest /* The database of pDest */
87212 ** This routine is call to handle SQL of the following forms:
87214 ** insert into TABLE (IDLIST) values(EXPRLIST)
87215 ** insert into TABLE (IDLIST) select
87217 ** The IDLIST following the table name is always optional. If omitted,
87218 ** then a list of all columns for the table is substituted. The IDLIST
87219 ** appears in the pColumn parameter. pColumn is NULL if IDLIST is omitted.
87221 ** The pList parameter holds EXPRLIST in the first form of the INSERT
87222 ** statement above, and pSelect is NULL. For the second form, pList is
87223 ** NULL and pSelect is a pointer to the select statement used to generate
87224 ** data for the insert.
87226 ** The code generated follows one of four templates. For a simple
87227 ** select with data coming from a VALUES clause, the code executes
87228 ** once straight down through. Pseudo-code follows (we call this
87229 ** the "1st template"):
87231 ** open write cursor to <table> and its indices
87232 ** puts VALUES clause expressions onto the stack
87233 ** write the resulting record into <table>
87234 ** cleanup
87236 ** The three remaining templates assume the statement is of the form
87238 ** INSERT INTO <table> SELECT ...
87240 ** If the SELECT clause is of the restricted form "SELECT * FROM <table2>" -
87241 ** in other words if the SELECT pulls all columns from a single table
87242 ** and there is no WHERE or LIMIT or GROUP BY or ORDER BY clauses, and
87243 ** if <table2> and <table1> are distinct tables but have identical
87244 ** schemas, including all the same indices, then a special optimization
87245 ** is invoked that copies raw records from <table2> over to <table1>.
87246 ** See the xferOptimization() function for the implementation of this
87247 ** template. This is the 2nd template.
87249 ** open a write cursor to <table>
87250 ** open read cursor on <table2>
87251 ** transfer all records in <table2> over to <table>
87252 ** close cursors
87253 ** foreach index on <table>
87254 ** open a write cursor on the <table> index
87255 ** open a read cursor on the corresponding <table2> index
87256 ** transfer all records from the read to the write cursors
87257 ** close cursors
87258 ** end foreach
87260 ** The 3rd template is for when the second template does not apply
87261 ** and the SELECT clause does not read from <table> at any time.
87262 ** The generated code follows this template:
87264 ** EOF <- 0
87265 ** X <- A
87266 ** goto B
87267 ** A: setup for the SELECT
87268 ** loop over the rows in the SELECT
87269 ** load values into registers R..R+n
87270 ** yield X
87271 ** end loop
87272 ** cleanup after the SELECT
87273 ** EOF <- 1
87274 ** yield X
87275 ** goto A
87276 ** B: open write cursor to <table> and its indices
87277 ** C: yield X
87278 ** if EOF goto D
87279 ** insert the select result into <table> from R..R+n
87280 ** goto C
87281 ** D: cleanup
87283 ** The 4th template is used if the insert statement takes its
87284 ** values from a SELECT but the data is being inserted into a table
87285 ** that is also read as part of the SELECT. In the third form,
87286 ** we have to use a intermediate table to store the results of
87287 ** the select. The template is like this:
87289 ** EOF <- 0
87290 ** X <- A
87291 ** goto B
87292 ** A: setup for the SELECT
87293 ** loop over the tables in the SELECT
87294 ** load value into register R..R+n
87295 ** yield X
87296 ** end loop
87297 ** cleanup after the SELECT
87298 ** EOF <- 1
87299 ** yield X
87300 ** halt-error
87301 ** B: open temp table
87302 ** L: yield X
87303 ** if EOF goto M
87304 ** insert row from R..R+n into temp table
87305 ** goto L
87306 ** M: open write cursor to <table> and its indices
87307 ** rewind temp table
87308 ** C: loop over rows of intermediate table
87309 ** transfer values form intermediate table into <table>
87310 ** end loop
87311 ** D: cleanup
87313 SQLITE_PRIVATE void sqlite3Insert(
87314 Parse *pParse, /* Parser context */
87315 SrcList *pTabList, /* Name of table into which we are inserting */
87316 ExprList *pList, /* List of values to be inserted */
87317 Select *pSelect, /* A SELECT statement to use as the data source */
87318 IdList *pColumn, /* Column names corresponding to IDLIST. */
87319 int onError /* How to handle constraint errors */
87321 sqlite3 *db; /* The main database structure */
87322 Table *pTab; /* The table to insert into. aka TABLE */
87323 char *zTab; /* Name of the table into which we are inserting */
87324 const char *zDb; /* Name of the database holding this table */
87325 int i, j, idx; /* Loop counters */
87326 Vdbe *v; /* Generate code into this virtual machine */
87327 Index *pIdx; /* For looping over indices of the table */
87328 int nColumn; /* Number of columns in the data */
87329 int nHidden = 0; /* Number of hidden columns if TABLE is virtual */
87330 int baseCur = 0; /* VDBE Cursor number for pTab */
87331 int keyColumn = -1; /* Column that is the INTEGER PRIMARY KEY */
87332 int endOfLoop; /* Label for the end of the insertion loop */
87333 int useTempTable = 0; /* Store SELECT results in intermediate table */
87334 int srcTab = 0; /* Data comes from this temporary cursor if >=0 */
87335 int addrInsTop = 0; /* Jump to label "D" */
87336 int addrCont = 0; /* Top of insert loop. Label "C" in templates 3 and 4 */
87337 int addrSelect = 0; /* Address of coroutine that implements the SELECT */
87338 SelectDest dest; /* Destination for SELECT on rhs of INSERT */
87339 int iDb; /* Index of database holding TABLE */
87340 Db *pDb; /* The database containing table being inserted into */
87341 int appendFlag = 0; /* True if the insert is likely to be an append */
87343 /* Register allocations */
87344 int regFromSelect = 0;/* Base register for data coming from SELECT */
87345 int regAutoinc = 0; /* Register holding the AUTOINCREMENT counter */
87346 int regRowCount = 0; /* Memory cell used for the row counter */
87347 int regIns; /* Block of regs holding rowid+data being inserted */
87348 int regRowid; /* registers holding insert rowid */
87349 int regData; /* register holding first column to insert */
87350 int regEof = 0; /* Register recording end of SELECT data */
87351 int *aRegIdx = 0; /* One register allocated to each index */
87353 #ifndef SQLITE_OMIT_TRIGGER
87354 int isView; /* True if attempting to insert into a view */
87355 Trigger *pTrigger; /* List of triggers on pTab, if required */
87356 int tmask; /* Mask of trigger times */
87357 #endif
87359 db = pParse->db;
87360 memset(&dest, 0, sizeof(dest));
87361 if( pParse->nErr || db->mallocFailed ){
87362 goto insert_cleanup;
87365 /* Locate the table into which we will be inserting new information.
87367 assert( pTabList->nSrc==1 );
87368 zTab = pTabList->a[0].zName;
87369 if( NEVER(zTab==0) ) goto insert_cleanup;
87370 pTab = sqlite3SrcListLookup(pParse, pTabList);
87371 if( pTab==0 ){
87372 goto insert_cleanup;
87374 iDb = sqlite3SchemaToIndex(db, pTab->pSchema);
87375 assert( iDb<db->nDb );
87376 pDb = &db->aDb[iDb];
87377 zDb = pDb->zName;
87378 if( sqlite3AuthCheck(pParse, SQLITE_INSERT, pTab->zName, 0, zDb) ){
87379 goto insert_cleanup;
87382 /* Figure out if we have any triggers and if the table being
87383 ** inserted into is a view
87385 #ifndef SQLITE_OMIT_TRIGGER
87386 pTrigger = sqlite3TriggersExist(pParse, pTab, TK_INSERT, 0, &tmask);
87387 isView = pTab->pSelect!=0;
87388 #else
87389 # define pTrigger 0
87390 # define tmask 0
87391 # define isView 0
87392 #endif
87393 #ifdef SQLITE_OMIT_VIEW
87394 # undef isView
87395 # define isView 0
87396 #endif
87397 assert( (pTrigger && tmask) || (pTrigger==0 && tmask==0) );
87399 /* If pTab is really a view, make sure it has been initialized.
87400 ** ViewGetColumnNames() is a no-op if pTab is not a view (or virtual
87401 ** module table).
87403 if( sqlite3ViewGetColumnNames(pParse, pTab) ){
87404 goto insert_cleanup;
87407 /* Ensure that:
87408 * (a) the table is not read-only,
87409 * (b) that if it is a view then ON INSERT triggers exist
87411 if( sqlite3IsReadOnly(pParse, pTab, tmask) ){
87412 goto insert_cleanup;
87415 /* Allocate a VDBE
87417 v = sqlite3GetVdbe(pParse);
87418 if( v==0 ) goto insert_cleanup;
87419 if( pParse->nested==0 ) sqlite3VdbeCountChanges(v);
87420 sqlite3BeginWriteOperation(pParse, pSelect || pTrigger, iDb);
87422 #ifndef SQLITE_OMIT_XFER_OPT
87423 /* If the statement is of the form
87425 ** INSERT INTO <table1> SELECT * FROM <table2>;
87427 ** Then special optimizations can be applied that make the transfer
87428 ** very fast and which reduce fragmentation of indices.
87430 ** This is the 2nd template.
87432 if( pColumn==0 && xferOptimization(pParse, pTab, pSelect, onError, iDb) ){
87433 assert( !pTrigger );
87434 assert( pList==0 );
87435 goto insert_end;
87437 #endif /* SQLITE_OMIT_XFER_OPT */
87439 /* If this is an AUTOINCREMENT table, look up the sequence number in the
87440 ** sqlite_sequence table and store it in memory cell regAutoinc.
87442 regAutoinc = autoIncBegin(pParse, iDb, pTab);
87444 /* Figure out how many columns of data are supplied. If the data
87445 ** is coming from a SELECT statement, then generate a co-routine that
87446 ** produces a single row of the SELECT on each invocation. The
87447 ** co-routine is the common header to the 3rd and 4th templates.
87449 if( pSelect ){
87450 /* Data is coming from a SELECT. Generate code to implement that SELECT
87451 ** as a co-routine. The code is common to both the 3rd and 4th
87452 ** templates:
87454 ** EOF <- 0
87455 ** X <- A
87456 ** goto B
87457 ** A: setup for the SELECT
87458 ** loop over the tables in the SELECT
87459 ** load value into register R..R+n
87460 ** yield X
87461 ** end loop
87462 ** cleanup after the SELECT
87463 ** EOF <- 1
87464 ** yield X
87465 ** halt-error
87467 ** On each invocation of the co-routine, it puts a single row of the
87468 ** SELECT result into registers dest.iMem...dest.iMem+dest.nMem-1.
87469 ** (These output registers are allocated by sqlite3Select().) When
87470 ** the SELECT completes, it sets the EOF flag stored in regEof.
87472 int rc, j1;
87474 regEof = ++pParse->nMem;
87475 sqlite3VdbeAddOp2(v, OP_Integer, 0, regEof); /* EOF <- 0 */
87476 VdbeComment((v, "SELECT eof flag"));
87477 sqlite3SelectDestInit(&dest, SRT_Coroutine, ++pParse->nMem);
87478 addrSelect = sqlite3VdbeCurrentAddr(v)+2;
87479 sqlite3VdbeAddOp2(v, OP_Integer, addrSelect-1, dest.iParm);
87480 j1 = sqlite3VdbeAddOp2(v, OP_Goto, 0, 0);
87481 VdbeComment((v, "Jump over SELECT coroutine"));
87483 /* Resolve the expressions in the SELECT statement and execute it. */
87484 rc = sqlite3Select(pParse, pSelect, &dest);
87485 assert( pParse->nErr==0 || rc );
87486 if( rc || NEVER(pParse->nErr) || db->mallocFailed ){
87487 goto insert_cleanup;
87489 sqlite3VdbeAddOp2(v, OP_Integer, 1, regEof); /* EOF <- 1 */
87490 sqlite3VdbeAddOp1(v, OP_Yield, dest.iParm); /* yield X */
87491 sqlite3VdbeAddOp2(v, OP_Halt, SQLITE_INTERNAL, OE_Abort);
87492 VdbeComment((v, "End of SELECT coroutine"));
87493 sqlite3VdbeJumpHere(v, j1); /* label B: */
87495 regFromSelect = dest.iMem;
87496 assert( pSelect->pEList );
87497 nColumn = pSelect->pEList->nExpr;
87498 assert( dest.nMem==nColumn );
87500 /* Set useTempTable to TRUE if the result of the SELECT statement
87501 ** should be written into a temporary table (template 4). Set to
87502 ** FALSE if each* row of the SELECT can be written directly into
87503 ** the destination table (template 3).
87505 ** A temp table must be used if the table being updated is also one
87506 ** of the tables being read by the SELECT statement. Also use a
87507 ** temp table in the case of row triggers.
87509 if( pTrigger || readsTable(pParse, addrSelect, iDb, pTab) ){
87510 useTempTable = 1;
87513 if( useTempTable ){
87514 /* Invoke the coroutine to extract information from the SELECT
87515 ** and add it to a transient table srcTab. The code generated
87516 ** here is from the 4th template:
87518 ** B: open temp table
87519 ** L: yield X
87520 ** if EOF goto M
87521 ** insert row from R..R+n into temp table
87522 ** goto L
87523 ** M: ...
87525 int regRec; /* Register to hold packed record */
87526 int regTempRowid; /* Register to hold temp table ROWID */
87527 int addrTop; /* Label "L" */
87528 int addrIf; /* Address of jump to M */
87530 srcTab = pParse->nTab++;
87531 regRec = sqlite3GetTempReg(pParse);
87532 regTempRowid = sqlite3GetTempReg(pParse);
87533 sqlite3VdbeAddOp2(v, OP_OpenEphemeral, srcTab, nColumn);
87534 addrTop = sqlite3VdbeAddOp1(v, OP_Yield, dest.iParm);
87535 addrIf = sqlite3VdbeAddOp1(v, OP_If, regEof);
87536 sqlite3VdbeAddOp3(v, OP_MakeRecord, regFromSelect, nColumn, regRec);
87537 sqlite3VdbeAddOp2(v, OP_NewRowid, srcTab, regTempRowid);
87538 sqlite3VdbeAddOp3(v, OP_Insert, srcTab, regRec, regTempRowid);
87539 sqlite3VdbeAddOp2(v, OP_Goto, 0, addrTop);
87540 sqlite3VdbeJumpHere(v, addrIf);
87541 sqlite3ReleaseTempReg(pParse, regRec);
87542 sqlite3ReleaseTempReg(pParse, regTempRowid);
87544 }else{
87545 /* This is the case if the data for the INSERT is coming from a VALUES
87546 ** clause
87548 NameContext sNC;
87549 memset(&sNC, 0, sizeof(sNC));
87550 sNC.pParse = pParse;
87551 srcTab = -1;
87552 assert( useTempTable==0 );
87553 nColumn = pList ? pList->nExpr : 0;
87554 for(i=0; i<nColumn; i++){
87555 if( sqlite3ResolveExprNames(&sNC, pList->a[i].pExpr) ){
87556 goto insert_cleanup;
87561 /* Make sure the number of columns in the source data matches the number
87562 ** of columns to be inserted into the table.
87564 if( IsVirtual(pTab) ){
87565 for(i=0; i<pTab->nCol; i++){
87566 nHidden += (IsHiddenColumn(&pTab->aCol[i]) ? 1 : 0);
87569 if( pColumn==0 && nColumn && nColumn!=(pTab->nCol-nHidden) ){
87570 sqlite3ErrorMsg(pParse,
87571 "table %S has %d columns but %d values were supplied",
87572 pTabList, 0, pTab->nCol-nHidden, nColumn);
87573 goto insert_cleanup;
87575 if( pColumn!=0 && nColumn!=pColumn->nId ){
87576 sqlite3ErrorMsg(pParse, "%d values for %d columns", nColumn, pColumn->nId);
87577 goto insert_cleanup;
87580 /* If the INSERT statement included an IDLIST term, then make sure
87581 ** all elements of the IDLIST really are columns of the table and
87582 ** remember the column indices.
87584 ** If the table has an INTEGER PRIMARY KEY column and that column
87585 ** is named in the IDLIST, then record in the keyColumn variable
87586 ** the index into IDLIST of the primary key column. keyColumn is
87587 ** the index of the primary key as it appears in IDLIST, not as
87588 ** is appears in the original table. (The index of the primary
87589 ** key in the original table is pTab->iPKey.)
87591 if( pColumn ){
87592 for(i=0; i<pColumn->nId; i++){
87593 pColumn->a[i].idx = -1;
87595 for(i=0; i<pColumn->nId; i++){
87596 for(j=0; j<pTab->nCol; j++){
87597 if( sqlite3StrICmp(pColumn->a[i].zName, pTab->aCol[j].zName)==0 ){
87598 pColumn->a[i].idx = j;
87599 if( j==pTab->iPKey ){
87600 keyColumn = i;
87602 break;
87605 if( j>=pTab->nCol ){
87606 if( sqlite3IsRowid(pColumn->a[i].zName) ){
87607 keyColumn = i;
87608 }else{
87609 sqlite3ErrorMsg(pParse, "table %S has no column named %s",
87610 pTabList, 0, pColumn->a[i].zName);
87611 pParse->checkSchema = 1;
87612 goto insert_cleanup;
87618 /* If there is no IDLIST term but the table has an integer primary
87619 ** key, the set the keyColumn variable to the primary key column index
87620 ** in the original table definition.
87622 if( pColumn==0 && nColumn>0 ){
87623 keyColumn = pTab->iPKey;
87626 /* Initialize the count of rows to be inserted
87628 if( db->flags & SQLITE_CountRows ){
87629 regRowCount = ++pParse->nMem;
87630 sqlite3VdbeAddOp2(v, OP_Integer, 0, regRowCount);
87633 /* If this is not a view, open the table and and all indices */
87634 if( !isView ){
87635 int nIdx;
87637 baseCur = pParse->nTab;
87638 nIdx = sqlite3OpenTableAndIndices(pParse, pTab, baseCur, OP_OpenWrite);
87639 aRegIdx = sqlite3DbMallocRaw(db, sizeof(int)*(nIdx+1));
87640 if( aRegIdx==0 ){
87641 goto insert_cleanup;
87643 for(i=0; i<nIdx; i++){
87644 aRegIdx[i] = ++pParse->nMem;
87648 /* This is the top of the main insertion loop */
87649 if( useTempTable ){
87650 /* This block codes the top of loop only. The complete loop is the
87651 ** following pseudocode (template 4):
87653 ** rewind temp table
87654 ** C: loop over rows of intermediate table
87655 ** transfer values form intermediate table into <table>
87656 ** end loop
87657 ** D: ...
87659 addrInsTop = sqlite3VdbeAddOp1(v, OP_Rewind, srcTab);
87660 addrCont = sqlite3VdbeCurrentAddr(v);
87661 }else if( pSelect ){
87662 /* This block codes the top of loop only. The complete loop is the
87663 ** following pseudocode (template 3):
87665 ** C: yield X
87666 ** if EOF goto D
87667 ** insert the select result into <table> from R..R+n
87668 ** goto C
87669 ** D: ...
87671 addrCont = sqlite3VdbeAddOp1(v, OP_Yield, dest.iParm);
87672 addrInsTop = sqlite3VdbeAddOp1(v, OP_If, regEof);
87675 /* Allocate registers for holding the rowid of the new row,
87676 ** the content of the new row, and the assemblied row record.
87678 regRowid = regIns = pParse->nMem+1;
87679 pParse->nMem += pTab->nCol + 1;
87680 if( IsVirtual(pTab) ){
87681 regRowid++;
87682 pParse->nMem++;
87684 regData = regRowid+1;
87686 /* Run the BEFORE and INSTEAD OF triggers, if there are any
87688 endOfLoop = sqlite3VdbeMakeLabel(v);
87689 if( tmask & TRIGGER_BEFORE ){
87690 int regCols = sqlite3GetTempRange(pParse, pTab->nCol+1);
87692 /* build the NEW.* reference row. Note that if there is an INTEGER
87693 ** PRIMARY KEY into which a NULL is being inserted, that NULL will be
87694 ** translated into a unique ID for the row. But on a BEFORE trigger,
87695 ** we do not know what the unique ID will be (because the insert has
87696 ** not happened yet) so we substitute a rowid of -1
87698 if( keyColumn<0 ){
87699 sqlite3VdbeAddOp2(v, OP_Integer, -1, regCols);
87700 }else{
87701 int j1;
87702 if( useTempTable ){
87703 sqlite3VdbeAddOp3(v, OP_Column, srcTab, keyColumn, regCols);
87704 }else{
87705 assert( pSelect==0 ); /* Otherwise useTempTable is true */
87706 sqlite3ExprCode(pParse, pList->a[keyColumn].pExpr, regCols);
87708 j1 = sqlite3VdbeAddOp1(v, OP_NotNull, regCols);
87709 sqlite3VdbeAddOp2(v, OP_Integer, -1, regCols);
87710 sqlite3VdbeJumpHere(v, j1);
87711 sqlite3VdbeAddOp1(v, OP_MustBeInt, regCols);
87714 /* Cannot have triggers on a virtual table. If it were possible,
87715 ** this block would have to account for hidden column.
87717 assert( !IsVirtual(pTab) );
87719 /* Create the new column data
87721 for(i=0; i<pTab->nCol; i++){
87722 if( pColumn==0 ){
87723 j = i;
87724 }else{
87725 for(j=0; j<pColumn->nId; j++){
87726 if( pColumn->a[j].idx==i ) break;
87729 if( (!useTempTable && !pList) || (pColumn && j>=pColumn->nId) ){
87730 sqlite3ExprCode(pParse, pTab->aCol[i].pDflt, regCols+i+1);
87731 }else if( useTempTable ){
87732 sqlite3VdbeAddOp3(v, OP_Column, srcTab, j, regCols+i+1);
87733 }else{
87734 assert( pSelect==0 ); /* Otherwise useTempTable is true */
87735 sqlite3ExprCodeAndCache(pParse, pList->a[j].pExpr, regCols+i+1);
87739 /* If this is an INSERT on a view with an INSTEAD OF INSERT trigger,
87740 ** do not attempt any conversions before assembling the record.
87741 ** If this is a real table, attempt conversions as required by the
87742 ** table column affinities.
87744 if( !isView ){
87745 sqlite3VdbeAddOp2(v, OP_Affinity, regCols+1, pTab->nCol);
87746 sqlite3TableAffinityStr(v, pTab);
87749 /* Fire BEFORE or INSTEAD OF triggers */
87750 sqlite3CodeRowTrigger(pParse, pTrigger, TK_INSERT, 0, TRIGGER_BEFORE,
87751 pTab, regCols-pTab->nCol-1, onError, endOfLoop);
87753 sqlite3ReleaseTempRange(pParse, regCols, pTab->nCol+1);
87756 /* Push the record number for the new entry onto the stack. The
87757 ** record number is a randomly generate integer created by NewRowid
87758 ** except when the table has an INTEGER PRIMARY KEY column, in which
87759 ** case the record number is the same as that column.
87761 if( !isView ){
87762 if( IsVirtual(pTab) ){
87763 /* The row that the VUpdate opcode will delete: none */
87764 sqlite3VdbeAddOp2(v, OP_Null, 0, regIns);
87766 if( keyColumn>=0 ){
87767 if( useTempTable ){
87768 sqlite3VdbeAddOp3(v, OP_Column, srcTab, keyColumn, regRowid);
87769 }else if( pSelect ){
87770 sqlite3VdbeAddOp2(v, OP_SCopy, regFromSelect+keyColumn, regRowid);
87771 }else{
87772 VdbeOp *pOp;
87773 sqlite3ExprCode(pParse, pList->a[keyColumn].pExpr, regRowid);
87774 pOp = sqlite3VdbeGetOp(v, -1);
87775 if( ALWAYS(pOp) && pOp->opcode==OP_Null && !IsVirtual(pTab) ){
87776 appendFlag = 1;
87777 pOp->opcode = OP_NewRowid;
87778 pOp->p1 = baseCur;
87779 pOp->p2 = regRowid;
87780 pOp->p3 = regAutoinc;
87783 /* If the PRIMARY KEY expression is NULL, then use OP_NewRowid
87784 ** to generate a unique primary key value.
87786 if( !appendFlag ){
87787 int j1;
87788 if( !IsVirtual(pTab) ){
87789 j1 = sqlite3VdbeAddOp1(v, OP_NotNull, regRowid);
87790 sqlite3VdbeAddOp3(v, OP_NewRowid, baseCur, regRowid, regAutoinc);
87791 sqlite3VdbeJumpHere(v, j1);
87792 }else{
87793 j1 = sqlite3VdbeCurrentAddr(v);
87794 sqlite3VdbeAddOp2(v, OP_IsNull, regRowid, j1+2);
87796 sqlite3VdbeAddOp1(v, OP_MustBeInt, regRowid);
87798 }else if( IsVirtual(pTab) ){
87799 sqlite3VdbeAddOp2(v, OP_Null, 0, regRowid);
87800 }else{
87801 sqlite3VdbeAddOp3(v, OP_NewRowid, baseCur, regRowid, regAutoinc);
87802 appendFlag = 1;
87804 autoIncStep(pParse, regAutoinc, regRowid);
87806 /* Push onto the stack, data for all columns of the new entry, beginning
87807 ** with the first column.
87809 nHidden = 0;
87810 for(i=0; i<pTab->nCol; i++){
87811 int iRegStore = regRowid+1+i;
87812 if( i==pTab->iPKey ){
87813 /* The value of the INTEGER PRIMARY KEY column is always a NULL.
87814 ** Whenever this column is read, the record number will be substituted
87815 ** in its place. So will fill this column with a NULL to avoid
87816 ** taking up data space with information that will never be used. */
87817 sqlite3VdbeAddOp2(v, OP_Null, 0, iRegStore);
87818 continue;
87820 if( pColumn==0 ){
87821 if( IsHiddenColumn(&pTab->aCol[i]) ){
87822 assert( IsVirtual(pTab) );
87823 j = -1;
87824 nHidden++;
87825 }else{
87826 j = i - nHidden;
87828 }else{
87829 for(j=0; j<pColumn->nId; j++){
87830 if( pColumn->a[j].idx==i ) break;
87833 if( j<0 || nColumn==0 || (pColumn && j>=pColumn->nId) ){
87834 sqlite3ExprCode(pParse, pTab->aCol[i].pDflt, iRegStore);
87835 }else if( useTempTable ){
87836 sqlite3VdbeAddOp3(v, OP_Column, srcTab, j, iRegStore);
87837 }else if( pSelect ){
87838 sqlite3VdbeAddOp2(v, OP_SCopy, regFromSelect+j, iRegStore);
87839 }else{
87840 sqlite3ExprCode(pParse, pList->a[j].pExpr, iRegStore);
87844 /* Generate code to check constraints and generate index keys and
87845 ** do the insertion.
87847 #ifndef SQLITE_OMIT_VIRTUALTABLE
87848 if( IsVirtual(pTab) ){
87849 const char *pVTab = (const char *)sqlite3GetVTable(db, pTab);
87850 sqlite3VtabMakeWritable(pParse, pTab);
87851 sqlite3VdbeAddOp4(v, OP_VUpdate, 1, pTab->nCol+2, regIns, pVTab, P4_VTAB);
87852 sqlite3VdbeChangeP5(v, onError==OE_Default ? OE_Abort : onError);
87853 sqlite3MayAbort(pParse);
87854 }else
87855 #endif
87857 int isReplace; /* Set to true if constraints may cause a replace */
87858 sqlite3GenerateConstraintChecks(pParse, pTab, baseCur, regIns, aRegIdx,
87859 keyColumn>=0, 0, onError, endOfLoop, &isReplace
87861 sqlite3FkCheck(pParse, pTab, 0, regIns);
87862 sqlite3CompleteInsertion(
87863 pParse, pTab, baseCur, regIns, aRegIdx, 0, appendFlag, isReplace==0
87868 /* Update the count of rows that are inserted
87870 if( (db->flags & SQLITE_CountRows)!=0 ){
87871 sqlite3VdbeAddOp2(v, OP_AddImm, regRowCount, 1);
87874 if( pTrigger ){
87875 /* Code AFTER triggers */
87876 sqlite3CodeRowTrigger(pParse, pTrigger, TK_INSERT, 0, TRIGGER_AFTER,
87877 pTab, regData-2-pTab->nCol, onError, endOfLoop);
87880 /* The bottom of the main insertion loop, if the data source
87881 ** is a SELECT statement.
87883 sqlite3VdbeResolveLabel(v, endOfLoop);
87884 if( useTempTable ){
87885 sqlite3VdbeAddOp2(v, OP_Next, srcTab, addrCont);
87886 sqlite3VdbeJumpHere(v, addrInsTop);
87887 sqlite3VdbeAddOp1(v, OP_Close, srcTab);
87888 }else if( pSelect ){
87889 sqlite3VdbeAddOp2(v, OP_Goto, 0, addrCont);
87890 sqlite3VdbeJumpHere(v, addrInsTop);
87893 if( !IsVirtual(pTab) && !isView ){
87894 /* Close all tables opened */
87895 sqlite3VdbeAddOp1(v, OP_Close, baseCur);
87896 for(idx=1, pIdx=pTab->pIndex; pIdx; pIdx=pIdx->pNext, idx++){
87897 sqlite3VdbeAddOp1(v, OP_Close, idx+baseCur);
87901 insert_end:
87902 /* Update the sqlite_sequence table by storing the content of the
87903 ** maximum rowid counter values recorded while inserting into
87904 ** autoincrement tables.
87906 if( pParse->nested==0 && pParse->pTriggerTab==0 ){
87907 sqlite3AutoincrementEnd(pParse);
87911 ** Return the number of rows inserted. If this routine is
87912 ** generating code because of a call to sqlite3NestedParse(), do not
87913 ** invoke the callback function.
87915 if( (db->flags&SQLITE_CountRows) && !pParse->nested && !pParse->pTriggerTab ){
87916 sqlite3VdbeAddOp2(v, OP_ResultRow, regRowCount, 1);
87917 sqlite3VdbeSetNumCols(v, 1);
87918 sqlite3VdbeSetColName(v, 0, COLNAME_NAME, "rows inserted", SQLITE_STATIC);
87921 insert_cleanup:
87922 sqlite3SrcListDelete(db, pTabList);
87923 sqlite3ExprListDelete(db, pList);
87924 sqlite3SelectDelete(db, pSelect);
87925 sqlite3IdListDelete(db, pColumn);
87926 sqlite3DbFree(db, aRegIdx);
87929 /* Make sure "isView" and other macros defined above are undefined. Otherwise
87930 ** thely may interfere with compilation of other functions in this file
87931 ** (or in another file, if this file becomes part of the amalgamation). */
87932 #ifdef isView
87933 #undef isView
87934 #endif
87935 #ifdef pTrigger
87936 #undef pTrigger
87937 #endif
87938 #ifdef tmask
87939 #undef tmask
87940 #endif
87944 ** Generate code to do constraint checks prior to an INSERT or an UPDATE.
87946 ** The input is a range of consecutive registers as follows:
87948 ** 1. The rowid of the row after the update.
87950 ** 2. The data in the first column of the entry after the update.
87952 ** i. Data from middle columns...
87954 ** N. The data in the last column of the entry after the update.
87956 ** The regRowid parameter is the index of the register containing (1).
87958 ** If isUpdate is true and rowidChng is non-zero, then rowidChng contains
87959 ** the address of a register containing the rowid before the update takes
87960 ** place. isUpdate is true for UPDATEs and false for INSERTs. If isUpdate
87961 ** is false, indicating an INSERT statement, then a non-zero rowidChng
87962 ** indicates that the rowid was explicitly specified as part of the
87963 ** INSERT statement. If rowidChng is false, it means that the rowid is
87964 ** computed automatically in an insert or that the rowid value is not
87965 ** modified by an update.
87967 ** The code generated by this routine store new index entries into
87968 ** registers identified by aRegIdx[]. No index entry is created for
87969 ** indices where aRegIdx[i]==0. The order of indices in aRegIdx[] is
87970 ** the same as the order of indices on the linked list of indices
87971 ** attached to the table.
87973 ** This routine also generates code to check constraints. NOT NULL,
87974 ** CHECK, and UNIQUE constraints are all checked. If a constraint fails,
87975 ** then the appropriate action is performed. There are five possible
87976 ** actions: ROLLBACK, ABORT, FAIL, REPLACE, and IGNORE.
87978 ** Constraint type Action What Happens
87979 ** --------------- ---------- ----------------------------------------
87980 ** any ROLLBACK The current transaction is rolled back and
87981 ** sqlite3_exec() returns immediately with a
87982 ** return code of SQLITE_CONSTRAINT.
87984 ** any ABORT Back out changes from the current command
87985 ** only (do not do a complete rollback) then
87986 ** cause sqlite3_exec() to return immediately
87987 ** with SQLITE_CONSTRAINT.
87989 ** any FAIL Sqlite_exec() returns immediately with a
87990 ** return code of SQLITE_CONSTRAINT. The
87991 ** transaction is not rolled back and any
87992 ** prior changes are retained.
87994 ** any IGNORE The record number and data is popped from
87995 ** the stack and there is an immediate jump
87996 ** to label ignoreDest.
87998 ** NOT NULL REPLACE The NULL value is replace by the default
87999 ** value for that column. If the default value
88000 ** is NULL, the action is the same as ABORT.
88002 ** UNIQUE REPLACE The other row that conflicts with the row
88003 ** being inserted is removed.
88005 ** CHECK REPLACE Illegal. The results in an exception.
88007 ** Which action to take is determined by the overrideError parameter.
88008 ** Or if overrideError==OE_Default, then the pParse->onError parameter
88009 ** is used. Or if pParse->onError==OE_Default then the onError value
88010 ** for the constraint is used.
88012 ** The calling routine must open a read/write cursor for pTab with
88013 ** cursor number "baseCur". All indices of pTab must also have open
88014 ** read/write cursors with cursor number baseCur+i for the i-th cursor.
88015 ** Except, if there is no possibility of a REPLACE action then
88016 ** cursors do not need to be open for indices where aRegIdx[i]==0.
88018 SQLITE_PRIVATE void sqlite3GenerateConstraintChecks(
88019 Parse *pParse, /* The parser context */
88020 Table *pTab, /* the table into which we are inserting */
88021 int baseCur, /* Index of a read/write cursor pointing at pTab */
88022 int regRowid, /* Index of the range of input registers */
88023 int *aRegIdx, /* Register used by each index. 0 for unused indices */
88024 int rowidChng, /* True if the rowid might collide with existing entry */
88025 int isUpdate, /* True for UPDATE, False for INSERT */
88026 int overrideError, /* Override onError to this if not OE_Default */
88027 int ignoreDest, /* Jump to this label on an OE_Ignore resolution */
88028 int *pbMayReplace /* OUT: Set to true if constraint may cause a replace */
88030 int i; /* loop counter */
88031 Vdbe *v; /* VDBE under constrution */
88032 int nCol; /* Number of columns */
88033 int onError; /* Conflict resolution strategy */
88034 int j1; /* Addresss of jump instruction */
88035 int j2 = 0, j3; /* Addresses of jump instructions */
88036 int regData; /* Register containing first data column */
88037 int iCur; /* Table cursor number */
88038 Index *pIdx; /* Pointer to one of the indices */
88039 int seenReplace = 0; /* True if REPLACE is used to resolve INT PK conflict */
88040 int regOldRowid = (rowidChng && isUpdate) ? rowidChng : regRowid;
88042 v = sqlite3GetVdbe(pParse);
88043 assert( v!=0 );
88044 assert( pTab->pSelect==0 ); /* This table is not a VIEW */
88045 nCol = pTab->nCol;
88046 regData = regRowid + 1;
88048 /* Test all NOT NULL constraints.
88050 for(i=0; i<nCol; i++){
88051 if( i==pTab->iPKey ){
88052 continue;
88054 onError = pTab->aCol[i].notNull;
88055 if( onError==OE_None ) continue;
88056 if( overrideError!=OE_Default ){
88057 onError = overrideError;
88058 }else if( onError==OE_Default ){
88059 onError = OE_Abort;
88061 if( onError==OE_Replace && pTab->aCol[i].pDflt==0 ){
88062 onError = OE_Abort;
88064 assert( onError==OE_Rollback || onError==OE_Abort || onError==OE_Fail
88065 || onError==OE_Ignore || onError==OE_Replace );
88066 switch( onError ){
88067 case OE_Abort:
88068 sqlite3MayAbort(pParse);
88069 case OE_Rollback:
88070 case OE_Fail: {
88071 char *zMsg;
88072 sqlite3VdbeAddOp3(v, OP_HaltIfNull,
88073 SQLITE_CONSTRAINT, onError, regData+i);
88074 zMsg = sqlite3MPrintf(pParse->db, "%s.%s may not be NULL",
88075 pTab->zName, pTab->aCol[i].zName);
88076 sqlite3VdbeChangeP4(v, -1, zMsg, P4_DYNAMIC);
88077 break;
88079 case OE_Ignore: {
88080 sqlite3VdbeAddOp2(v, OP_IsNull, regData+i, ignoreDest);
88081 break;
88083 default: {
88084 assert( onError==OE_Replace );
88085 j1 = sqlite3VdbeAddOp1(v, OP_NotNull, regData+i);
88086 sqlite3ExprCode(pParse, pTab->aCol[i].pDflt, regData+i);
88087 sqlite3VdbeJumpHere(v, j1);
88088 break;
88093 /* Test all CHECK constraints
88095 #ifndef SQLITE_OMIT_CHECK
88096 if( pTab->pCheck && (pParse->db->flags & SQLITE_IgnoreChecks)==0 ){
88097 int allOk = sqlite3VdbeMakeLabel(v);
88098 pParse->ckBase = regData;
88099 sqlite3ExprIfTrue(pParse, pTab->pCheck, allOk, SQLITE_JUMPIFNULL);
88100 onError = overrideError!=OE_Default ? overrideError : OE_Abort;
88101 if( onError==OE_Ignore ){
88102 sqlite3VdbeAddOp2(v, OP_Goto, 0, ignoreDest);
88103 }else{
88104 if( onError==OE_Replace ) onError = OE_Abort; /* IMP: R-15569-63625 */
88105 sqlite3HaltConstraint(pParse, onError, 0, 0);
88107 sqlite3VdbeResolveLabel(v, allOk);
88109 #endif /* !defined(SQLITE_OMIT_CHECK) */
88111 /* If we have an INTEGER PRIMARY KEY, make sure the primary key
88112 ** of the new record does not previously exist. Except, if this
88113 ** is an UPDATE and the primary key is not changing, that is OK.
88115 if( rowidChng ){
88116 onError = pTab->keyConf;
88117 if( overrideError!=OE_Default ){
88118 onError = overrideError;
88119 }else if( onError==OE_Default ){
88120 onError = OE_Abort;
88123 if( isUpdate ){
88124 j2 = sqlite3VdbeAddOp3(v, OP_Eq, regRowid, 0, rowidChng);
88126 j3 = sqlite3VdbeAddOp3(v, OP_NotExists, baseCur, 0, regRowid);
88127 switch( onError ){
88128 default: {
88129 onError = OE_Abort;
88130 /* Fall thru into the next case */
88132 case OE_Rollback:
88133 case OE_Abort:
88134 case OE_Fail: {
88135 sqlite3HaltConstraint(
88136 pParse, onError, "PRIMARY KEY must be unique", P4_STATIC);
88137 break;
88139 case OE_Replace: {
88140 /* If there are DELETE triggers on this table and the
88141 ** recursive-triggers flag is set, call GenerateRowDelete() to
88142 ** remove the conflicting row from the the table. This will fire
88143 ** the triggers and remove both the table and index b-tree entries.
88145 ** Otherwise, if there are no triggers or the recursive-triggers
88146 ** flag is not set, but the table has one or more indexes, call
88147 ** GenerateRowIndexDelete(). This removes the index b-tree entries
88148 ** only. The table b-tree entry will be replaced by the new entry
88149 ** when it is inserted.
88151 ** If either GenerateRowDelete() or GenerateRowIndexDelete() is called,
88152 ** also invoke MultiWrite() to indicate that this VDBE may require
88153 ** statement rollback (if the statement is aborted after the delete
88154 ** takes place). Earlier versions called sqlite3MultiWrite() regardless,
88155 ** but being more selective here allows statements like:
88157 ** REPLACE INTO t(rowid) VALUES($newrowid)
88159 ** to run without a statement journal if there are no indexes on the
88160 ** table.
88162 Trigger *pTrigger = 0;
88163 if( pParse->db->flags&SQLITE_RecTriggers ){
88164 pTrigger = sqlite3TriggersExist(pParse, pTab, TK_DELETE, 0, 0);
88166 if( pTrigger || sqlite3FkRequired(pParse, pTab, 0, 0) ){
88167 sqlite3MultiWrite(pParse);
88168 sqlite3GenerateRowDelete(
88169 pParse, pTab, baseCur, regRowid, 0, pTrigger, OE_Replace
88171 }else if( pTab->pIndex ){
88172 sqlite3MultiWrite(pParse);
88173 sqlite3GenerateRowIndexDelete(pParse, pTab, baseCur, 0);
88175 seenReplace = 1;
88176 break;
88178 case OE_Ignore: {
88179 assert( seenReplace==0 );
88180 sqlite3VdbeAddOp2(v, OP_Goto, 0, ignoreDest);
88181 break;
88184 sqlite3VdbeJumpHere(v, j3);
88185 if( isUpdate ){
88186 sqlite3VdbeJumpHere(v, j2);
88190 /* Test all UNIQUE constraints by creating entries for each UNIQUE
88191 ** index and making sure that duplicate entries do not already exist.
88192 ** Add the new records to the indices as we go.
88194 for(iCur=0, pIdx=pTab->pIndex; pIdx; pIdx=pIdx->pNext, iCur++){
88195 int regIdx;
88196 int regR;
88198 if( aRegIdx[iCur]==0 ) continue; /* Skip unused indices */
88200 /* Create a key for accessing the index entry */
88201 regIdx = sqlite3GetTempRange(pParse, pIdx->nColumn+1);
88202 for(i=0; i<pIdx->nColumn; i++){
88203 int idx = pIdx->aiColumn[i];
88204 if( idx==pTab->iPKey ){
88205 sqlite3VdbeAddOp2(v, OP_SCopy, regRowid, regIdx+i);
88206 }else{
88207 sqlite3VdbeAddOp2(v, OP_SCopy, regData+idx, regIdx+i);
88210 sqlite3VdbeAddOp2(v, OP_SCopy, regRowid, regIdx+i);
88211 sqlite3VdbeAddOp3(v, OP_MakeRecord, regIdx, pIdx->nColumn+1, aRegIdx[iCur]);
88212 sqlite3VdbeChangeP4(v, -1, sqlite3IndexAffinityStr(v, pIdx), P4_TRANSIENT);
88213 sqlite3ExprCacheAffinityChange(pParse, regIdx, pIdx->nColumn+1);
88215 /* Find out what action to take in case there is an indexing conflict */
88216 onError = pIdx->onError;
88217 if( onError==OE_None ){
88218 sqlite3ReleaseTempRange(pParse, regIdx, pIdx->nColumn+1);
88219 continue; /* pIdx is not a UNIQUE index */
88221 if( overrideError!=OE_Default ){
88222 onError = overrideError;
88223 }else if( onError==OE_Default ){
88224 onError = OE_Abort;
88226 if( seenReplace ){
88227 if( onError==OE_Ignore ) onError = OE_Replace;
88228 else if( onError==OE_Fail ) onError = OE_Abort;
88231 /* Check to see if the new index entry will be unique */
88232 regR = sqlite3GetTempReg(pParse);
88233 sqlite3VdbeAddOp2(v, OP_SCopy, regOldRowid, regR);
88234 j3 = sqlite3VdbeAddOp4(v, OP_IsUnique, baseCur+iCur+1, 0,
88235 regR, SQLITE_INT_TO_PTR(regIdx),
88236 P4_INT32);
88237 sqlite3ReleaseTempRange(pParse, regIdx, pIdx->nColumn+1);
88239 /* Generate code that executes if the new index entry is not unique */
88240 assert( onError==OE_Rollback || onError==OE_Abort || onError==OE_Fail
88241 || onError==OE_Ignore || onError==OE_Replace );
88242 switch( onError ){
88243 case OE_Rollback:
88244 case OE_Abort:
88245 case OE_Fail: {
88246 int j;
88247 StrAccum errMsg;
88248 const char *zSep;
88249 char *zErr;
88251 sqlite3StrAccumInit(&errMsg, 0, 0, 200);
88252 errMsg.db = pParse->db;
88253 zSep = pIdx->nColumn>1 ? "columns " : "column ";
88254 for(j=0; j<pIdx->nColumn; j++){
88255 char *zCol = pTab->aCol[pIdx->aiColumn[j]].zName;
88256 sqlite3StrAccumAppend(&errMsg, zSep, -1);
88257 zSep = ", ";
88258 sqlite3StrAccumAppend(&errMsg, zCol, -1);
88260 sqlite3StrAccumAppend(&errMsg,
88261 pIdx->nColumn>1 ? " are not unique" : " is not unique", -1);
88262 zErr = sqlite3StrAccumFinish(&errMsg);
88263 sqlite3HaltConstraint(pParse, onError, zErr, 0);
88264 sqlite3DbFree(errMsg.db, zErr);
88265 break;
88267 case OE_Ignore: {
88268 assert( seenReplace==0 );
88269 sqlite3VdbeAddOp2(v, OP_Goto, 0, ignoreDest);
88270 break;
88272 default: {
88273 Trigger *pTrigger = 0;
88274 assert( onError==OE_Replace );
88275 sqlite3MultiWrite(pParse);
88276 if( pParse->db->flags&SQLITE_RecTriggers ){
88277 pTrigger = sqlite3TriggersExist(pParse, pTab, TK_DELETE, 0, 0);
88279 sqlite3GenerateRowDelete(
88280 pParse, pTab, baseCur, regR, 0, pTrigger, OE_Replace
88282 seenReplace = 1;
88283 break;
88286 sqlite3VdbeJumpHere(v, j3);
88287 sqlite3ReleaseTempReg(pParse, regR);
88290 if( pbMayReplace ){
88291 *pbMayReplace = seenReplace;
88296 ** This routine generates code to finish the INSERT or UPDATE operation
88297 ** that was started by a prior call to sqlite3GenerateConstraintChecks.
88298 ** A consecutive range of registers starting at regRowid contains the
88299 ** rowid and the content to be inserted.
88301 ** The arguments to this routine should be the same as the first six
88302 ** arguments to sqlite3GenerateConstraintChecks.
88304 SQLITE_PRIVATE void sqlite3CompleteInsertion(
88305 Parse *pParse, /* The parser context */
88306 Table *pTab, /* the table into which we are inserting */
88307 int baseCur, /* Index of a read/write cursor pointing at pTab */
88308 int regRowid, /* Range of content */
88309 int *aRegIdx, /* Register used by each index. 0 for unused indices */
88310 int isUpdate, /* True for UPDATE, False for INSERT */
88311 int appendBias, /* True if this is likely to be an append */
88312 int useSeekResult /* True to set the USESEEKRESULT flag on OP_[Idx]Insert */
88314 int i;
88315 Vdbe *v;
88316 int nIdx;
88317 Index *pIdx;
88318 u8 pik_flags;
88319 int regData;
88320 int regRec;
88322 v = sqlite3GetVdbe(pParse);
88323 assert( v!=0 );
88324 assert( pTab->pSelect==0 ); /* This table is not a VIEW */
88325 for(nIdx=0, pIdx=pTab->pIndex; pIdx; pIdx=pIdx->pNext, nIdx++){}
88326 for(i=nIdx-1; i>=0; i--){
88327 if( aRegIdx[i]==0 ) continue;
88328 sqlite3VdbeAddOp2(v, OP_IdxInsert, baseCur+i+1, aRegIdx[i]);
88329 if( useSeekResult ){
88330 sqlite3VdbeChangeP5(v, OPFLAG_USESEEKRESULT);
88333 regData = regRowid + 1;
88334 regRec = sqlite3GetTempReg(pParse);
88335 sqlite3VdbeAddOp3(v, OP_MakeRecord, regData, pTab->nCol, regRec);
88336 sqlite3TableAffinityStr(v, pTab);
88337 sqlite3ExprCacheAffinityChange(pParse, regData, pTab->nCol);
88338 if( pParse->nested ){
88339 pik_flags = 0;
88340 }else{
88341 pik_flags = OPFLAG_NCHANGE;
88342 pik_flags |= (isUpdate?OPFLAG_ISUPDATE:OPFLAG_LASTROWID);
88344 if( appendBias ){
88345 pik_flags |= OPFLAG_APPEND;
88347 if( useSeekResult ){
88348 pik_flags |= OPFLAG_USESEEKRESULT;
88350 sqlite3VdbeAddOp3(v, OP_Insert, baseCur, regRec, regRowid);
88351 if( !pParse->nested ){
88352 sqlite3VdbeChangeP4(v, -1, pTab->zName, P4_TRANSIENT);
88354 sqlite3VdbeChangeP5(v, pik_flags);
88358 ** Generate code that will open cursors for a table and for all
88359 ** indices of that table. The "baseCur" parameter is the cursor number used
88360 ** for the table. Indices are opened on subsequent cursors.
88362 ** Return the number of indices on the table.
88364 SQLITE_PRIVATE int sqlite3OpenTableAndIndices(
88365 Parse *pParse, /* Parsing context */
88366 Table *pTab, /* Table to be opened */
88367 int baseCur, /* Cursor number assigned to the table */
88368 int op /* OP_OpenRead or OP_OpenWrite */
88370 int i;
88371 int iDb;
88372 Index *pIdx;
88373 Vdbe *v;
88375 if( IsVirtual(pTab) ) return 0;
88376 iDb = sqlite3SchemaToIndex(pParse->db, pTab->pSchema);
88377 v = sqlite3GetVdbe(pParse);
88378 assert( v!=0 );
88379 sqlite3OpenTable(pParse, baseCur, iDb, pTab, op);
88380 for(i=1, pIdx=pTab->pIndex; pIdx; pIdx=pIdx->pNext, i++){
88381 KeyInfo *pKey = sqlite3IndexKeyinfo(pParse, pIdx);
88382 assert( pIdx->pSchema==pTab->pSchema );
88383 sqlite3VdbeAddOp4(v, op, i+baseCur, pIdx->tnum, iDb,
88384 (char*)pKey, P4_KEYINFO_HANDOFF);
88385 VdbeComment((v, "%s", pIdx->zName));
88387 if( pParse->nTab<baseCur+i ){
88388 pParse->nTab = baseCur+i;
88390 return i-1;
88394 #ifdef SQLITE_TEST
88396 ** The following global variable is incremented whenever the
88397 ** transfer optimization is used. This is used for testing
88398 ** purposes only - to make sure the transfer optimization really
88399 ** is happening when it is suppose to.
88401 SQLITE_API int sqlite3_xferopt_count;
88402 #endif /* SQLITE_TEST */
88405 #ifndef SQLITE_OMIT_XFER_OPT
88407 ** Check to collation names to see if they are compatible.
88409 static int xferCompatibleCollation(const char *z1, const char *z2){
88410 if( z1==0 ){
88411 return z2==0;
88413 if( z2==0 ){
88414 return 0;
88416 return sqlite3StrICmp(z1, z2)==0;
88421 ** Check to see if index pSrc is compatible as a source of data
88422 ** for index pDest in an insert transfer optimization. The rules
88423 ** for a compatible index:
88425 ** * The index is over the same set of columns
88426 ** * The same DESC and ASC markings occurs on all columns
88427 ** * The same onError processing (OE_Abort, OE_Ignore, etc)
88428 ** * The same collating sequence on each column
88430 static int xferCompatibleIndex(Index *pDest, Index *pSrc){
88431 int i;
88432 assert( pDest && pSrc );
88433 assert( pDest->pTable!=pSrc->pTable );
88434 if( pDest->nColumn!=pSrc->nColumn ){
88435 return 0; /* Different number of columns */
88437 if( pDest->onError!=pSrc->onError ){
88438 return 0; /* Different conflict resolution strategies */
88440 for(i=0; i<pSrc->nColumn; i++){
88441 if( pSrc->aiColumn[i]!=pDest->aiColumn[i] ){
88442 return 0; /* Different columns indexed */
88444 if( pSrc->aSortOrder[i]!=pDest->aSortOrder[i] ){
88445 return 0; /* Different sort orders */
88447 if( !xferCompatibleCollation(pSrc->azColl[i],pDest->azColl[i]) ){
88448 return 0; /* Different collating sequences */
88452 /* If no test above fails then the indices must be compatible */
88453 return 1;
88457 ** Attempt the transfer optimization on INSERTs of the form
88459 ** INSERT INTO tab1 SELECT * FROM tab2;
88461 ** This optimization is only attempted if
88463 ** (1) tab1 and tab2 have identical schemas including all the
88464 ** same indices and constraints
88466 ** (2) tab1 and tab2 are different tables
88468 ** (3) There must be no triggers on tab1
88470 ** (4) The result set of the SELECT statement is "*"
88472 ** (5) The SELECT statement has no WHERE, HAVING, ORDER BY, GROUP BY,
88473 ** or LIMIT clause.
88475 ** (6) The SELECT statement is a simple (not a compound) select that
88476 ** contains only tab2 in its FROM clause
88478 ** This method for implementing the INSERT transfers raw records from
88479 ** tab2 over to tab1. The columns are not decoded. Raw records from
88480 ** the indices of tab2 are transfered to tab1 as well. In so doing,
88481 ** the resulting tab1 has much less fragmentation.
88483 ** This routine returns TRUE if the optimization is attempted. If any
88484 ** of the conditions above fail so that the optimization should not
88485 ** be attempted, then this routine returns FALSE.
88487 static int xferOptimization(
88488 Parse *pParse, /* Parser context */
88489 Table *pDest, /* The table we are inserting into */
88490 Select *pSelect, /* A SELECT statement to use as the data source */
88491 int onError, /* How to handle constraint errors */
88492 int iDbDest /* The database of pDest */
88494 ExprList *pEList; /* The result set of the SELECT */
88495 Table *pSrc; /* The table in the FROM clause of SELECT */
88496 Index *pSrcIdx, *pDestIdx; /* Source and destination indices */
88497 struct SrcList_item *pItem; /* An element of pSelect->pSrc */
88498 int i; /* Loop counter */
88499 int iDbSrc; /* The database of pSrc */
88500 int iSrc, iDest; /* Cursors from source and destination */
88501 int addr1, addr2; /* Loop addresses */
88502 int emptyDestTest; /* Address of test for empty pDest */
88503 int emptySrcTest; /* Address of test for empty pSrc */
88504 Vdbe *v; /* The VDBE we are building */
88505 KeyInfo *pKey; /* Key information for an index */
88506 int regAutoinc; /* Memory register used by AUTOINC */
88507 int destHasUniqueIdx = 0; /* True if pDest has a UNIQUE index */
88508 int regData, regRowid; /* Registers holding data and rowid */
88510 if( pSelect==0 ){
88511 return 0; /* Must be of the form INSERT INTO ... SELECT ... */
88513 if( sqlite3TriggerList(pParse, pDest) ){
88514 return 0; /* tab1 must not have triggers */
88516 #ifndef SQLITE_OMIT_VIRTUALTABLE
88517 if( pDest->tabFlags & TF_Virtual ){
88518 return 0; /* tab1 must not be a virtual table */
88520 #endif
88521 if( onError==OE_Default ){
88522 onError = OE_Abort;
88524 if( onError!=OE_Abort && onError!=OE_Rollback ){
88525 return 0; /* Cannot do OR REPLACE or OR IGNORE or OR FAIL */
88527 assert(pSelect->pSrc); /* allocated even if there is no FROM clause */
88528 if( pSelect->pSrc->nSrc!=1 ){
88529 return 0; /* FROM clause must have exactly one term */
88531 if( pSelect->pSrc->a[0].pSelect ){
88532 return 0; /* FROM clause cannot contain a subquery */
88534 if( pSelect->pWhere ){
88535 return 0; /* SELECT may not have a WHERE clause */
88537 if( pSelect->pOrderBy ){
88538 return 0; /* SELECT may not have an ORDER BY clause */
88540 /* Do not need to test for a HAVING clause. If HAVING is present but
88541 ** there is no ORDER BY, we will get an error. */
88542 if( pSelect->pGroupBy ){
88543 return 0; /* SELECT may not have a GROUP BY clause */
88545 if( pSelect->pLimit ){
88546 return 0; /* SELECT may not have a LIMIT clause */
88548 assert( pSelect->pOffset==0 ); /* Must be so if pLimit==0 */
88549 if( pSelect->pPrior ){
88550 return 0; /* SELECT may not be a compound query */
88552 if( pSelect->selFlags & SF_Distinct ){
88553 return 0; /* SELECT may not be DISTINCT */
88555 pEList = pSelect->pEList;
88556 assert( pEList!=0 );
88557 if( pEList->nExpr!=1 ){
88558 return 0; /* The result set must have exactly one column */
88560 assert( pEList->a[0].pExpr );
88561 if( pEList->a[0].pExpr->op!=TK_ALL ){
88562 return 0; /* The result set must be the special operator "*" */
88565 /* At this point we have established that the statement is of the
88566 ** correct syntactic form to participate in this optimization. Now
88567 ** we have to check the semantics.
88569 pItem = pSelect->pSrc->a;
88570 pSrc = sqlite3LocateTable(pParse, 0, pItem->zName, pItem->zDatabase);
88571 if( pSrc==0 ){
88572 return 0; /* FROM clause does not contain a real table */
88574 if( pSrc==pDest ){
88575 return 0; /* tab1 and tab2 may not be the same table */
88577 #ifndef SQLITE_OMIT_VIRTUALTABLE
88578 if( pSrc->tabFlags & TF_Virtual ){
88579 return 0; /* tab2 must not be a virtual table */
88581 #endif
88582 if( pSrc->pSelect ){
88583 return 0; /* tab2 may not be a view */
88585 if( pDest->nCol!=pSrc->nCol ){
88586 return 0; /* Number of columns must be the same in tab1 and tab2 */
88588 if( pDest->iPKey!=pSrc->iPKey ){
88589 return 0; /* Both tables must have the same INTEGER PRIMARY KEY */
88591 for(i=0; i<pDest->nCol; i++){
88592 if( pDest->aCol[i].affinity!=pSrc->aCol[i].affinity ){
88593 return 0; /* Affinity must be the same on all columns */
88595 if( !xferCompatibleCollation(pDest->aCol[i].zColl, pSrc->aCol[i].zColl) ){
88596 return 0; /* Collating sequence must be the same on all columns */
88598 if( pDest->aCol[i].notNull && !pSrc->aCol[i].notNull ){
88599 return 0; /* tab2 must be NOT NULL if tab1 is */
88602 for(pDestIdx=pDest->pIndex; pDestIdx; pDestIdx=pDestIdx->pNext){
88603 if( pDestIdx->onError!=OE_None ){
88604 destHasUniqueIdx = 1;
88606 for(pSrcIdx=pSrc->pIndex; pSrcIdx; pSrcIdx=pSrcIdx->pNext){
88607 if( xferCompatibleIndex(pDestIdx, pSrcIdx) ) break;
88609 if( pSrcIdx==0 ){
88610 return 0; /* pDestIdx has no corresponding index in pSrc */
88613 #ifndef SQLITE_OMIT_CHECK
88614 if( pDest->pCheck && sqlite3ExprCompare(pSrc->pCheck, pDest->pCheck) ){
88615 return 0; /* Tables have different CHECK constraints. Ticket #2252 */
88617 #endif
88618 #ifndef SQLITE_OMIT_FOREIGN_KEY
88619 /* Disallow the transfer optimization if the destination table constains
88620 ** any foreign key constraints. This is more restrictive than necessary.
88621 ** But the main beneficiary of the transfer optimization is the VACUUM
88622 ** command, and the VACUUM command disables foreign key constraints. So
88623 ** the extra complication to make this rule less restrictive is probably
88624 ** not worth the effort. Ticket [6284df89debdfa61db8073e062908af0c9b6118e]
88626 if( (pParse->db->flags & SQLITE_ForeignKeys)!=0 && pDest->pFKey!=0 ){
88627 return 0;
88629 #endif
88631 /* If we get this far, it means either:
88633 ** * We can always do the transfer if the table contains an
88634 ** an integer primary key
88636 ** * We can conditionally do the transfer if the destination
88637 ** table is empty.
88639 #ifdef SQLITE_TEST
88640 sqlite3_xferopt_count++;
88641 #endif
88642 iDbSrc = sqlite3SchemaToIndex(pParse->db, pSrc->pSchema);
88643 v = sqlite3GetVdbe(pParse);
88644 sqlite3CodeVerifySchema(pParse, iDbSrc);
88645 iSrc = pParse->nTab++;
88646 iDest = pParse->nTab++;
88647 regAutoinc = autoIncBegin(pParse, iDbDest, pDest);
88648 sqlite3OpenTable(pParse, iDest, iDbDest, pDest, OP_OpenWrite);
88649 if( (pDest->iPKey<0 && pDest->pIndex!=0) || destHasUniqueIdx ){
88650 /* If tables do not have an INTEGER PRIMARY KEY and there
88651 ** are indices to be copied and the destination is not empty,
88652 ** we have to disallow the transfer optimization because the
88653 ** the rowids might change which will mess up indexing.
88655 ** Or if the destination has a UNIQUE index and is not empty,
88656 ** we also disallow the transfer optimization because we cannot
88657 ** insure that all entries in the union of DEST and SRC will be
88658 ** unique.
88660 addr1 = sqlite3VdbeAddOp2(v, OP_Rewind, iDest, 0);
88661 emptyDestTest = sqlite3VdbeAddOp2(v, OP_Goto, 0, 0);
88662 sqlite3VdbeJumpHere(v, addr1);
88663 }else{
88664 emptyDestTest = 0;
88666 sqlite3OpenTable(pParse, iSrc, iDbSrc, pSrc, OP_OpenRead);
88667 emptySrcTest = sqlite3VdbeAddOp2(v, OP_Rewind, iSrc, 0);
88668 regData = sqlite3GetTempReg(pParse);
88669 regRowid = sqlite3GetTempReg(pParse);
88670 if( pDest->iPKey>=0 ){
88671 addr1 = sqlite3VdbeAddOp2(v, OP_Rowid, iSrc, regRowid);
88672 addr2 = sqlite3VdbeAddOp3(v, OP_NotExists, iDest, 0, regRowid);
88673 sqlite3HaltConstraint(
88674 pParse, onError, "PRIMARY KEY must be unique", P4_STATIC);
88675 sqlite3VdbeJumpHere(v, addr2);
88676 autoIncStep(pParse, regAutoinc, regRowid);
88677 }else if( pDest->pIndex==0 ){
88678 addr1 = sqlite3VdbeAddOp2(v, OP_NewRowid, iDest, regRowid);
88679 }else{
88680 addr1 = sqlite3VdbeAddOp2(v, OP_Rowid, iSrc, regRowid);
88681 assert( (pDest->tabFlags & TF_Autoincrement)==0 );
88683 sqlite3VdbeAddOp2(v, OP_RowData, iSrc, regData);
88684 sqlite3VdbeAddOp3(v, OP_Insert, iDest, regData, regRowid);
88685 sqlite3VdbeChangeP5(v, OPFLAG_NCHANGE|OPFLAG_LASTROWID|OPFLAG_APPEND);
88686 sqlite3VdbeChangeP4(v, -1, pDest->zName, 0);
88687 sqlite3VdbeAddOp2(v, OP_Next, iSrc, addr1);
88688 for(pDestIdx=pDest->pIndex; pDestIdx; pDestIdx=pDestIdx->pNext){
88689 for(pSrcIdx=pSrc->pIndex; ALWAYS(pSrcIdx); pSrcIdx=pSrcIdx->pNext){
88690 if( xferCompatibleIndex(pDestIdx, pSrcIdx) ) break;
88692 assert( pSrcIdx );
88693 sqlite3VdbeAddOp2(v, OP_Close, iSrc, 0);
88694 sqlite3VdbeAddOp2(v, OP_Close, iDest, 0);
88695 pKey = sqlite3IndexKeyinfo(pParse, pSrcIdx);
88696 sqlite3VdbeAddOp4(v, OP_OpenRead, iSrc, pSrcIdx->tnum, iDbSrc,
88697 (char*)pKey, P4_KEYINFO_HANDOFF);
88698 VdbeComment((v, "%s", pSrcIdx->zName));
88699 pKey = sqlite3IndexKeyinfo(pParse, pDestIdx);
88700 sqlite3VdbeAddOp4(v, OP_OpenWrite, iDest, pDestIdx->tnum, iDbDest,
88701 (char*)pKey, P4_KEYINFO_HANDOFF);
88702 VdbeComment((v, "%s", pDestIdx->zName));
88703 addr1 = sqlite3VdbeAddOp2(v, OP_Rewind, iSrc, 0);
88704 sqlite3VdbeAddOp2(v, OP_RowKey, iSrc, regData);
88705 sqlite3VdbeAddOp3(v, OP_IdxInsert, iDest, regData, 1);
88706 sqlite3VdbeAddOp2(v, OP_Next, iSrc, addr1+1);
88707 sqlite3VdbeJumpHere(v, addr1);
88709 sqlite3VdbeJumpHere(v, emptySrcTest);
88710 sqlite3ReleaseTempReg(pParse, regRowid);
88711 sqlite3ReleaseTempReg(pParse, regData);
88712 sqlite3VdbeAddOp2(v, OP_Close, iSrc, 0);
88713 sqlite3VdbeAddOp2(v, OP_Close, iDest, 0);
88714 if( emptyDestTest ){
88715 sqlite3VdbeAddOp2(v, OP_Halt, SQLITE_OK, 0);
88716 sqlite3VdbeJumpHere(v, emptyDestTest);
88717 sqlite3VdbeAddOp2(v, OP_Close, iDest, 0);
88718 return 0;
88719 }else{
88720 return 1;
88723 #endif /* SQLITE_OMIT_XFER_OPT */
88725 /************** End of insert.c **********************************************/
88726 /************** Begin file legacy.c ******************************************/
88728 ** 2001 September 15
88730 ** The author disclaims copyright to this source code. In place of
88731 ** a legal notice, here is a blessing:
88733 ** May you do good and not evil.
88734 ** May you find forgiveness for yourself and forgive others.
88735 ** May you share freely, never taking more than you give.
88737 *************************************************************************
88738 ** Main file for the SQLite library. The routines in this file
88739 ** implement the programmer interface to the library. Routines in
88740 ** other files are for internal use by SQLite and should not be
88741 ** accessed by users of the library.
88746 ** Execute SQL code. Return one of the SQLITE_ success/failure
88747 ** codes. Also write an error message into memory obtained from
88748 ** malloc() and make *pzErrMsg point to that message.
88750 ** If the SQL is a query, then for each row in the query result
88751 ** the xCallback() function is called. pArg becomes the first
88752 ** argument to xCallback(). If xCallback=NULL then no callback
88753 ** is invoked, even for queries.
88755 SQLITE_API int sqlite3_exec(
88756 sqlite3 *db, /* The database on which the SQL executes */
88757 const char *zSql, /* The SQL to be executed */
88758 sqlite3_callback xCallback, /* Invoke this callback routine */
88759 void *pArg, /* First argument to xCallback() */
88760 char **pzErrMsg /* Write error messages here */
88762 int rc = SQLITE_OK; /* Return code */
88763 const char *zLeftover; /* Tail of unprocessed SQL */
88764 sqlite3_stmt *pStmt = 0; /* The current SQL statement */
88765 char **azCols = 0; /* Names of result columns */
88766 int nRetry = 0; /* Number of retry attempts */
88767 int callbackIsInit; /* True if callback data is initialized */
88769 if( !sqlite3SafetyCheckOk(db) ) return SQLITE_MISUSE_BKPT;
88770 if( zSql==0 ) zSql = "";
88772 sqlite3_mutex_enter(db->mutex);
88773 sqlite3Error(db, SQLITE_OK, 0);
88774 while( (rc==SQLITE_OK || (rc==SQLITE_SCHEMA && (++nRetry)<2)) && zSql[0] ){
88775 int nCol;
88776 char **azVals = 0;
88778 pStmt = 0;
88779 rc = sqlite3_prepare(db, zSql, -1, &pStmt, &zLeftover);
88780 assert( rc==SQLITE_OK || pStmt==0 );
88781 if( rc!=SQLITE_OK ){
88782 continue;
88784 if( !pStmt ){
88785 /* this happens for a comment or white-space */
88786 zSql = zLeftover;
88787 continue;
88790 callbackIsInit = 0;
88791 nCol = sqlite3_column_count(pStmt);
88793 while( 1 ){
88794 int i;
88795 rc = sqlite3_step(pStmt);
88797 /* Invoke the callback function if required */
88798 if( xCallback && (SQLITE_ROW==rc ||
88799 (SQLITE_DONE==rc && !callbackIsInit
88800 && db->flags&SQLITE_NullCallback)) ){
88801 if( !callbackIsInit ){
88802 azCols = sqlite3DbMallocZero(db, 2*nCol*sizeof(const char*) + 1);
88803 if( azCols==0 ){
88804 goto exec_out;
88806 for(i=0; i<nCol; i++){
88807 azCols[i] = (char *)sqlite3_column_name(pStmt, i);
88808 /* sqlite3VdbeSetColName() installs column names as UTF8
88809 ** strings so there is no way for sqlite3_column_name() to fail. */
88810 assert( azCols[i]!=0 );
88812 callbackIsInit = 1;
88814 if( rc==SQLITE_ROW ){
88815 azVals = &azCols[nCol];
88816 for(i=0; i<nCol; i++){
88817 azVals[i] = (char *)sqlite3_column_text(pStmt, i);
88818 if( !azVals[i] && sqlite3_column_type(pStmt, i)!=SQLITE_NULL ){
88819 db->mallocFailed = 1;
88820 goto exec_out;
88824 if( xCallback(pArg, nCol, azVals, azCols) ){
88825 rc = SQLITE_ABORT;
88826 sqlite3VdbeFinalize((Vdbe *)pStmt);
88827 pStmt = 0;
88828 sqlite3Error(db, SQLITE_ABORT, 0);
88829 goto exec_out;
88833 if( rc!=SQLITE_ROW ){
88834 rc = sqlite3VdbeFinalize((Vdbe *)pStmt);
88835 pStmt = 0;
88836 if( rc!=SQLITE_SCHEMA ){
88837 nRetry = 0;
88838 zSql = zLeftover;
88839 while( sqlite3Isspace(zSql[0]) ) zSql++;
88841 break;
88845 sqlite3DbFree(db, azCols);
88846 azCols = 0;
88849 exec_out:
88850 if( pStmt ) sqlite3VdbeFinalize((Vdbe *)pStmt);
88851 sqlite3DbFree(db, azCols);
88853 rc = sqlite3ApiExit(db, rc);
88854 if( rc!=SQLITE_OK && ALWAYS(rc==sqlite3_errcode(db)) && pzErrMsg ){
88855 int nErrMsg = 1 + sqlite3Strlen30(sqlite3_errmsg(db));
88856 *pzErrMsg = sqlite3Malloc(nErrMsg);
88857 if( *pzErrMsg ){
88858 memcpy(*pzErrMsg, sqlite3_errmsg(db), nErrMsg);
88859 }else{
88860 rc = SQLITE_NOMEM;
88861 sqlite3Error(db, SQLITE_NOMEM, 0);
88863 }else if( pzErrMsg ){
88864 *pzErrMsg = 0;
88867 assert( (rc&db->errMask)==rc );
88868 sqlite3_mutex_leave(db->mutex);
88869 return rc;
88872 /************** End of legacy.c **********************************************/
88873 /************** Begin file loadext.c *****************************************/
88875 ** 2006 June 7
88877 ** The author disclaims copyright to this source code. In place of
88878 ** a legal notice, here is a blessing:
88880 ** May you do good and not evil.
88881 ** May you find forgiveness for yourself and forgive others.
88882 ** May you share freely, never taking more than you give.
88884 *************************************************************************
88885 ** This file contains code used to dynamically load extensions into
88886 ** the SQLite library.
88889 #ifndef SQLITE_CORE
88890 #define SQLITE_CORE 1 /* Disable the API redefinition in sqlite3ext.h */
88891 #endif
88892 /************** Include sqlite3ext.h in the middle of loadext.c **************/
88893 /************** Begin file sqlite3ext.h **************************************/
88895 ** 2006 June 7
88897 ** The author disclaims copyright to this source code. In place of
88898 ** a legal notice, here is a blessing:
88900 ** May you do good and not evil.
88901 ** May you find forgiveness for yourself and forgive others.
88902 ** May you share freely, never taking more than you give.
88904 *************************************************************************
88905 ** This header file defines the SQLite interface for use by
88906 ** shared libraries that want to be imported as extensions into
88907 ** an SQLite instance. Shared libraries that intend to be loaded
88908 ** as extensions by SQLite should #include this file instead of
88909 ** sqlite3.h.
88911 #ifndef _SQLITE3EXT_H_
88912 #define _SQLITE3EXT_H_
88914 typedef struct sqlite3_api_routines sqlite3_api_routines;
88917 ** The following structure holds pointers to all of the SQLite API
88918 ** routines.
88920 ** WARNING: In order to maintain backwards compatibility, add new
88921 ** interfaces to the end of this structure only. If you insert new
88922 ** interfaces in the middle of this structure, then older different
88923 ** versions of SQLite will not be able to load each others' shared
88924 ** libraries!
88926 struct sqlite3_api_routines {
88927 void * (*aggregate_context)(sqlite3_context*,int nBytes);
88928 int (*aggregate_count)(sqlite3_context*);
88929 int (*bind_blob)(sqlite3_stmt*,int,const void*,int n,void(*)(void*));
88930 int (*bind_double)(sqlite3_stmt*,int,double);
88931 int (*bind_int)(sqlite3_stmt*,int,int);
88932 int (*bind_int64)(sqlite3_stmt*,int,sqlite_int64);
88933 int (*bind_null)(sqlite3_stmt*,int);
88934 int (*bind_parameter_count)(sqlite3_stmt*);
88935 int (*bind_parameter_index)(sqlite3_stmt*,const char*zName);
88936 const char * (*bind_parameter_name)(sqlite3_stmt*,int);
88937 int (*bind_text)(sqlite3_stmt*,int,const char*,int n,void(*)(void*));
88938 int (*bind_text16)(sqlite3_stmt*,int,const void*,int,void(*)(void*));
88939 int (*bind_value)(sqlite3_stmt*,int,const sqlite3_value*);
88940 int (*busy_handler)(sqlite3*,int(*)(void*,int),void*);
88941 int (*busy_timeout)(sqlite3*,int ms);
88942 int (*changes)(sqlite3*);
88943 int (*close)(sqlite3*);
88944 int (*collation_needed)(sqlite3*,void*,void(*)(void*,sqlite3*,int eTextRep,const char*));
88945 int (*collation_needed16)(sqlite3*,void*,void(*)(void*,sqlite3*,int eTextRep,const void*));
88946 const void * (*column_blob)(sqlite3_stmt*,int iCol);
88947 int (*column_bytes)(sqlite3_stmt*,int iCol);
88948 int (*column_bytes16)(sqlite3_stmt*,int iCol);
88949 int (*column_count)(sqlite3_stmt*pStmt);
88950 const char * (*column_database_name)(sqlite3_stmt*,int);
88951 const void * (*column_database_name16)(sqlite3_stmt*,int);
88952 const char * (*column_decltype)(sqlite3_stmt*,int i);
88953 const void * (*column_decltype16)(sqlite3_stmt*,int);
88954 double (*column_double)(sqlite3_stmt*,int iCol);
88955 int (*column_int)(sqlite3_stmt*,int iCol);
88956 sqlite_int64 (*column_int64)(sqlite3_stmt*,int iCol);
88957 const char * (*column_name)(sqlite3_stmt*,int);
88958 const void * (*column_name16)(sqlite3_stmt*,int);
88959 const char * (*column_origin_name)(sqlite3_stmt*,int);
88960 const void * (*column_origin_name16)(sqlite3_stmt*,int);
88961 const char * (*column_table_name)(sqlite3_stmt*,int);
88962 const void * (*column_table_name16)(sqlite3_stmt*,int);
88963 const unsigned char * (*column_text)(sqlite3_stmt*,int iCol);
88964 const void * (*column_text16)(sqlite3_stmt*,int iCol);
88965 int (*column_type)(sqlite3_stmt*,int iCol);
88966 sqlite3_value* (*column_value)(sqlite3_stmt*,int iCol);
88967 void * (*commit_hook)(sqlite3*,int(*)(void*),void*);
88968 int (*complete)(const char*sql);
88969 int (*complete16)(const void*sql);
88970 int (*create_collation)(sqlite3*,const char*,int,void*,int(*)(void*,int,const void*,int,const void*));
88971 int (*create_collation16)(sqlite3*,const void*,int,void*,int(*)(void*,int,const void*,int,const void*));
88972 int (*create_function)(sqlite3*,const char*,int,int,void*,void (*xFunc)(sqlite3_context*,int,sqlite3_value**),void (*xStep)(sqlite3_context*,int,sqlite3_value**),void (*xFinal)(sqlite3_context*));
88973 int (*create_function16)(sqlite3*,const void*,int,int,void*,void (*xFunc)(sqlite3_context*,int,sqlite3_value**),void (*xStep)(sqlite3_context*,int,sqlite3_value**),void (*xFinal)(sqlite3_context*));
88974 int (*create_module)(sqlite3*,const char*,const sqlite3_module*,void*);
88975 int (*data_count)(sqlite3_stmt*pStmt);
88976 sqlite3 * (*db_handle)(sqlite3_stmt*);
88977 int (*declare_vtab)(sqlite3*,const char*);
88978 int (*enable_shared_cache)(int);
88979 int (*errcode)(sqlite3*db);
88980 const char * (*errmsg)(sqlite3*);
88981 const void * (*errmsg16)(sqlite3*);
88982 int (*exec)(sqlite3*,const char*,sqlite3_callback,void*,char**);
88983 int (*expired)(sqlite3_stmt*);
88984 int (*finalize)(sqlite3_stmt*pStmt);
88985 void (*free)(void*);
88986 void (*free_table)(char**result);
88987 int (*get_autocommit)(sqlite3*);
88988 void * (*get_auxdata)(sqlite3_context*,int);
88989 int (*get_table)(sqlite3*,const char*,char***,int*,int*,char**);
88990 int (*global_recover)(void);
88991 void (*interruptx)(sqlite3*);
88992 sqlite_int64 (*last_insert_rowid)(sqlite3*);
88993 const char * (*libversion)(void);
88994 int (*libversion_number)(void);
88995 void *(*malloc)(int);
88996 char * (*mprintf)(const char*,...);
88997 int (*open)(const char*,sqlite3**);
88998 int (*open16)(const void*,sqlite3**);
88999 int (*prepare)(sqlite3*,const char*,int,sqlite3_stmt**,const char**);
89000 int (*prepare16)(sqlite3*,const void*,int,sqlite3_stmt**,const void**);
89001 void * (*profile)(sqlite3*,void(*)(void*,const char*,sqlite_uint64),void*);
89002 void (*progress_handler)(sqlite3*,int,int(*)(void*),void*);
89003 void *(*realloc)(void*,int);
89004 int (*reset)(sqlite3_stmt*pStmt);
89005 void (*result_blob)(sqlite3_context*,const void*,int,void(*)(void*));
89006 void (*result_double)(sqlite3_context*,double);
89007 void (*result_error)(sqlite3_context*,const char*,int);
89008 void (*result_error16)(sqlite3_context*,const void*,int);
89009 void (*result_int)(sqlite3_context*,int);
89010 void (*result_int64)(sqlite3_context*,sqlite_int64);
89011 void (*result_null)(sqlite3_context*);
89012 void (*result_text)(sqlite3_context*,const char*,int,void(*)(void*));
89013 void (*result_text16)(sqlite3_context*,const void*,int,void(*)(void*));
89014 void (*result_text16be)(sqlite3_context*,const void*,int,void(*)(void*));
89015 void (*result_text16le)(sqlite3_context*,const void*,int,void(*)(void*));
89016 void (*result_value)(sqlite3_context*,sqlite3_value*);
89017 void * (*rollback_hook)(sqlite3*,void(*)(void*),void*);
89018 int (*set_authorizer)(sqlite3*,int(*)(void*,int,const char*,const char*,const char*,const char*),void*);
89019 void (*set_auxdata)(sqlite3_context*,int,void*,void (*)(void*));
89020 char * (*snprintf)(int,char*,const char*,...);
89021 int (*step)(sqlite3_stmt*);
89022 int (*table_column_metadata)(sqlite3*,const char*,const char*,const char*,char const**,char const**,int*,int*,int*);
89023 void (*thread_cleanup)(void);
89024 int (*total_changes)(sqlite3*);
89025 void * (*trace)(sqlite3*,void(*xTrace)(void*,const char*),void*);
89026 int (*transfer_bindings)(sqlite3_stmt*,sqlite3_stmt*);
89027 void * (*update_hook)(sqlite3*,void(*)(void*,int ,char const*,char const*,sqlite_int64),void*);
89028 void * (*user_data)(sqlite3_context*);
89029 const void * (*value_blob)(sqlite3_value*);
89030 int (*value_bytes)(sqlite3_value*);
89031 int (*value_bytes16)(sqlite3_value*);
89032 double (*value_double)(sqlite3_value*);
89033 int (*value_int)(sqlite3_value*);
89034 sqlite_int64 (*value_int64)(sqlite3_value*);
89035 int (*value_numeric_type)(sqlite3_value*);
89036 const unsigned char * (*value_text)(sqlite3_value*);
89037 const void * (*value_text16)(sqlite3_value*);
89038 const void * (*value_text16be)(sqlite3_value*);
89039 const void * (*value_text16le)(sqlite3_value*);
89040 int (*value_type)(sqlite3_value*);
89041 char *(*vmprintf)(const char*,va_list);
89042 /* Added ??? */
89043 int (*overload_function)(sqlite3*, const char *zFuncName, int nArg);
89044 /* Added by 3.3.13 */
89045 int (*prepare_v2)(sqlite3*,const char*,int,sqlite3_stmt**,const char**);
89046 int (*prepare16_v2)(sqlite3*,const void*,int,sqlite3_stmt**,const void**);
89047 int (*clear_bindings)(sqlite3_stmt*);
89048 /* Added by 3.4.1 */
89049 int (*create_module_v2)(sqlite3*,const char*,const sqlite3_module*,void*,void (*xDestroy)(void *));
89050 /* Added by 3.5.0 */
89051 int (*bind_zeroblob)(sqlite3_stmt*,int,int);
89052 int (*blob_bytes)(sqlite3_blob*);
89053 int (*blob_close)(sqlite3_blob*);
89054 int (*blob_open)(sqlite3*,const char*,const char*,const char*,sqlite3_int64,int,sqlite3_blob**);
89055 int (*blob_read)(sqlite3_blob*,void*,int,int);
89056 int (*blob_write)(sqlite3_blob*,const void*,int,int);
89057 int (*create_collation_v2)(sqlite3*,const char*,int,void*,int(*)(void*,int,const void*,int,const void*),void(*)(void*));
89058 int (*file_control)(sqlite3*,const char*,int,void*);
89059 sqlite3_int64 (*memory_highwater)(int);
89060 sqlite3_int64 (*memory_used)(void);
89061 sqlite3_mutex *(*mutex_alloc)(int);
89062 void (*mutex_enter)(sqlite3_mutex*);
89063 void (*mutex_free)(sqlite3_mutex*);
89064 void (*mutex_leave)(sqlite3_mutex*);
89065 int (*mutex_try)(sqlite3_mutex*);
89066 int (*open_v2)(const char*,sqlite3**,int,const char*);
89067 int (*release_memory)(int);
89068 void (*result_error_nomem)(sqlite3_context*);
89069 void (*result_error_toobig)(sqlite3_context*);
89070 int (*sleep)(int);
89071 void (*soft_heap_limit)(int);
89072 sqlite3_vfs *(*vfs_find)(const char*);
89073 int (*vfs_register)(sqlite3_vfs*,int);
89074 int (*vfs_unregister)(sqlite3_vfs*);
89075 int (*xthreadsafe)(void);
89076 void (*result_zeroblob)(sqlite3_context*,int);
89077 void (*result_error_code)(sqlite3_context*,int);
89078 int (*test_control)(int, ...);
89079 void (*randomness)(int,void*);
89080 sqlite3 *(*context_db_handle)(sqlite3_context*);
89081 int (*extended_result_codes)(sqlite3*,int);
89082 int (*limit)(sqlite3*,int,int);
89083 sqlite3_stmt *(*next_stmt)(sqlite3*,sqlite3_stmt*);
89084 const char *(*sql)(sqlite3_stmt*);
89085 int (*status)(int,int*,int*,int);
89086 int (*backup_finish)(sqlite3_backup*);
89087 sqlite3_backup *(*backup_init)(sqlite3*,const char*,sqlite3*,const char*);
89088 int (*backup_pagecount)(sqlite3_backup*);
89089 int (*backup_remaining)(sqlite3_backup*);
89090 int (*backup_step)(sqlite3_backup*,int);
89091 const char *(*compileoption_get)(int);
89092 int (*compileoption_used)(const char*);
89093 int (*create_function_v2)(sqlite3*,const char*,int,int,void*,void (*xFunc)(sqlite3_context*,int,sqlite3_value**),void (*xStep)(sqlite3_context*,int,sqlite3_value**),void (*xFinal)(sqlite3_context*),void(*xDestroy)(void*));
89094 int (*db_config)(sqlite3*,int,...);
89095 sqlite3_mutex *(*db_mutex)(sqlite3*);
89096 int (*db_status)(sqlite3*,int,int*,int*,int);
89097 int (*extended_errcode)(sqlite3*);
89098 void (*log)(int,const char*,...);
89099 sqlite3_int64 (*soft_heap_limit64)(sqlite3_int64);
89100 const char *(*sourceid)(void);
89101 int (*stmt_status)(sqlite3_stmt*,int,int);
89102 int (*strnicmp)(const char*,const char*,int);
89103 int (*unlock_notify)(sqlite3*,void(*)(void**,int),void*);
89104 int (*wal_autocheckpoint)(sqlite3*,int);
89105 int (*wal_checkpoint)(sqlite3*,const char*);
89106 void *(*wal_hook)(sqlite3*,int(*)(void*,sqlite3*,const char*,int),void*);
89107 int (*blob_reopen)(sqlite3_blob*,sqlite3_int64);
89108 int (*vtab_config)(sqlite3*,int op,...);
89109 int (*vtab_on_conflict)(sqlite3*);
89113 ** The following macros redefine the API routines so that they are
89114 ** redirected throught the global sqlite3_api structure.
89116 ** This header file is also used by the loadext.c source file
89117 ** (part of the main SQLite library - not an extension) so that
89118 ** it can get access to the sqlite3_api_routines structure
89119 ** definition. But the main library does not want to redefine
89120 ** the API. So the redefinition macros are only valid if the
89121 ** SQLITE_CORE macros is undefined.
89123 #ifndef SQLITE_CORE
89124 #define sqlite3_aggregate_context sqlite3_api->aggregate_context
89125 #ifndef SQLITE_OMIT_DEPRECATED
89126 #define sqlite3_aggregate_count sqlite3_api->aggregate_count
89127 #endif
89128 #define sqlite3_bind_blob sqlite3_api->bind_blob
89129 #define sqlite3_bind_double sqlite3_api->bind_double
89130 #define sqlite3_bind_int sqlite3_api->bind_int
89131 #define sqlite3_bind_int64 sqlite3_api->bind_int64
89132 #define sqlite3_bind_null sqlite3_api->bind_null
89133 #define sqlite3_bind_parameter_count sqlite3_api->bind_parameter_count
89134 #define sqlite3_bind_parameter_index sqlite3_api->bind_parameter_index
89135 #define sqlite3_bind_parameter_name sqlite3_api->bind_parameter_name
89136 #define sqlite3_bind_text sqlite3_api->bind_text
89137 #define sqlite3_bind_text16 sqlite3_api->bind_text16
89138 #define sqlite3_bind_value sqlite3_api->bind_value
89139 #define sqlite3_busy_handler sqlite3_api->busy_handler
89140 #define sqlite3_busy_timeout sqlite3_api->busy_timeout
89141 #define sqlite3_changes sqlite3_api->changes
89142 #define sqlite3_close sqlite3_api->close
89143 #define sqlite3_collation_needed sqlite3_api->collation_needed
89144 #define sqlite3_collation_needed16 sqlite3_api->collation_needed16
89145 #define sqlite3_column_blob sqlite3_api->column_blob
89146 #define sqlite3_column_bytes sqlite3_api->column_bytes
89147 #define sqlite3_column_bytes16 sqlite3_api->column_bytes16
89148 #define sqlite3_column_count sqlite3_api->column_count
89149 #define sqlite3_column_database_name sqlite3_api->column_database_name
89150 #define sqlite3_column_database_name16 sqlite3_api->column_database_name16
89151 #define sqlite3_column_decltype sqlite3_api->column_decltype
89152 #define sqlite3_column_decltype16 sqlite3_api->column_decltype16
89153 #define sqlite3_column_double sqlite3_api->column_double
89154 #define sqlite3_column_int sqlite3_api->column_int
89155 #define sqlite3_column_int64 sqlite3_api->column_int64
89156 #define sqlite3_column_name sqlite3_api->column_name
89157 #define sqlite3_column_name16 sqlite3_api->column_name16
89158 #define sqlite3_column_origin_name sqlite3_api->column_origin_name
89159 #define sqlite3_column_origin_name16 sqlite3_api->column_origin_name16
89160 #define sqlite3_column_table_name sqlite3_api->column_table_name
89161 #define sqlite3_column_table_name16 sqlite3_api->column_table_name16
89162 #define sqlite3_column_text sqlite3_api->column_text
89163 #define sqlite3_column_text16 sqlite3_api->column_text16
89164 #define sqlite3_column_type sqlite3_api->column_type
89165 #define sqlite3_column_value sqlite3_api->column_value
89166 #define sqlite3_commit_hook sqlite3_api->commit_hook
89167 #define sqlite3_complete sqlite3_api->complete
89168 #define sqlite3_complete16 sqlite3_api->complete16
89169 #define sqlite3_create_collation sqlite3_api->create_collation
89170 #define sqlite3_create_collation16 sqlite3_api->create_collation16
89171 #define sqlite3_create_function sqlite3_api->create_function
89172 #define sqlite3_create_function16 sqlite3_api->create_function16
89173 #define sqlite3_create_module sqlite3_api->create_module
89174 #define sqlite3_create_module_v2 sqlite3_api->create_module_v2
89175 #define sqlite3_data_count sqlite3_api->data_count
89176 #define sqlite3_db_handle sqlite3_api->db_handle
89177 #define sqlite3_declare_vtab sqlite3_api->declare_vtab
89178 #define sqlite3_enable_shared_cache sqlite3_api->enable_shared_cache
89179 #define sqlite3_errcode sqlite3_api->errcode
89180 #define sqlite3_errmsg sqlite3_api->errmsg
89181 #define sqlite3_errmsg16 sqlite3_api->errmsg16
89182 #define sqlite3_exec sqlite3_api->exec
89183 #ifndef SQLITE_OMIT_DEPRECATED
89184 #define sqlite3_expired sqlite3_api->expired
89185 #endif
89186 #define sqlite3_finalize sqlite3_api->finalize
89187 #define sqlite3_free sqlite3_api->free
89188 #define sqlite3_free_table sqlite3_api->free_table
89189 #define sqlite3_get_autocommit sqlite3_api->get_autocommit
89190 #define sqlite3_get_auxdata sqlite3_api->get_auxdata
89191 #define sqlite3_get_table sqlite3_api->get_table
89192 #ifndef SQLITE_OMIT_DEPRECATED
89193 #define sqlite3_global_recover sqlite3_api->global_recover
89194 #endif
89195 #define sqlite3_interrupt sqlite3_api->interruptx
89196 #define sqlite3_last_insert_rowid sqlite3_api->last_insert_rowid
89197 #define sqlite3_libversion sqlite3_api->libversion
89198 #define sqlite3_libversion_number sqlite3_api->libversion_number
89199 #define sqlite3_malloc sqlite3_api->malloc
89200 #define sqlite3_mprintf sqlite3_api->mprintf
89201 #define sqlite3_open sqlite3_api->open
89202 #define sqlite3_open16 sqlite3_api->open16
89203 #define sqlite3_prepare sqlite3_api->prepare
89204 #define sqlite3_prepare16 sqlite3_api->prepare16
89205 #define sqlite3_prepare_v2 sqlite3_api->prepare_v2
89206 #define sqlite3_prepare16_v2 sqlite3_api->prepare16_v2
89207 #define sqlite3_profile sqlite3_api->profile
89208 #define sqlite3_progress_handler sqlite3_api->progress_handler
89209 #define sqlite3_realloc sqlite3_api->realloc
89210 #define sqlite3_reset sqlite3_api->reset
89211 #define sqlite3_result_blob sqlite3_api->result_blob
89212 #define sqlite3_result_double sqlite3_api->result_double
89213 #define sqlite3_result_error sqlite3_api->result_error
89214 #define sqlite3_result_error16 sqlite3_api->result_error16
89215 #define sqlite3_result_int sqlite3_api->result_int
89216 #define sqlite3_result_int64 sqlite3_api->result_int64
89217 #define sqlite3_result_null sqlite3_api->result_null
89218 #define sqlite3_result_text sqlite3_api->result_text
89219 #define sqlite3_result_text16 sqlite3_api->result_text16
89220 #define sqlite3_result_text16be sqlite3_api->result_text16be
89221 #define sqlite3_result_text16le sqlite3_api->result_text16le
89222 #define sqlite3_result_value sqlite3_api->result_value
89223 #define sqlite3_rollback_hook sqlite3_api->rollback_hook
89224 #define sqlite3_set_authorizer sqlite3_api->set_authorizer
89225 #define sqlite3_set_auxdata sqlite3_api->set_auxdata
89226 #define sqlite3_snprintf sqlite3_api->snprintf
89227 #define sqlite3_step sqlite3_api->step
89228 #define sqlite3_table_column_metadata sqlite3_api->table_column_metadata
89229 #define sqlite3_thread_cleanup sqlite3_api->thread_cleanup
89230 #define sqlite3_total_changes sqlite3_api->total_changes
89231 #define sqlite3_trace sqlite3_api->trace
89232 #ifndef SQLITE_OMIT_DEPRECATED
89233 #define sqlite3_transfer_bindings sqlite3_api->transfer_bindings
89234 #endif
89235 #define sqlite3_update_hook sqlite3_api->update_hook
89236 #define sqlite3_user_data sqlite3_api->user_data
89237 #define sqlite3_value_blob sqlite3_api->value_blob
89238 #define sqlite3_value_bytes sqlite3_api->value_bytes
89239 #define sqlite3_value_bytes16 sqlite3_api->value_bytes16
89240 #define sqlite3_value_double sqlite3_api->value_double
89241 #define sqlite3_value_int sqlite3_api->value_int
89242 #define sqlite3_value_int64 sqlite3_api->value_int64
89243 #define sqlite3_value_numeric_type sqlite3_api->value_numeric_type
89244 #define sqlite3_value_text sqlite3_api->value_text
89245 #define sqlite3_value_text16 sqlite3_api->value_text16
89246 #define sqlite3_value_text16be sqlite3_api->value_text16be
89247 #define sqlite3_value_text16le sqlite3_api->value_text16le
89248 #define sqlite3_value_type sqlite3_api->value_type
89249 #define sqlite3_vmprintf sqlite3_api->vmprintf
89250 #define sqlite3_overload_function sqlite3_api->overload_function
89251 #define sqlite3_prepare_v2 sqlite3_api->prepare_v2
89252 #define sqlite3_prepare16_v2 sqlite3_api->prepare16_v2
89253 #define sqlite3_clear_bindings sqlite3_api->clear_bindings
89254 #define sqlite3_bind_zeroblob sqlite3_api->bind_zeroblob
89255 #define sqlite3_blob_bytes sqlite3_api->blob_bytes
89256 #define sqlite3_blob_close sqlite3_api->blob_close
89257 #define sqlite3_blob_open sqlite3_api->blob_open
89258 #define sqlite3_blob_read sqlite3_api->blob_read
89259 #define sqlite3_blob_write sqlite3_api->blob_write
89260 #define sqlite3_create_collation_v2 sqlite3_api->create_collation_v2
89261 #define sqlite3_file_control sqlite3_api->file_control
89262 #define sqlite3_memory_highwater sqlite3_api->memory_highwater
89263 #define sqlite3_memory_used sqlite3_api->memory_used
89264 #define sqlite3_mutex_alloc sqlite3_api->mutex_alloc
89265 #define sqlite3_mutex_enter sqlite3_api->mutex_enter
89266 #define sqlite3_mutex_free sqlite3_api->mutex_free
89267 #define sqlite3_mutex_leave sqlite3_api->mutex_leave
89268 #define sqlite3_mutex_try sqlite3_api->mutex_try
89269 #define sqlite3_open_v2 sqlite3_api->open_v2
89270 #define sqlite3_release_memory sqlite3_api->release_memory
89271 #define sqlite3_result_error_nomem sqlite3_api->result_error_nomem
89272 #define sqlite3_result_error_toobig sqlite3_api->result_error_toobig
89273 #define sqlite3_sleep sqlite3_api->sleep
89274 #define sqlite3_soft_heap_limit sqlite3_api->soft_heap_limit
89275 #define sqlite3_vfs_find sqlite3_api->vfs_find
89276 #define sqlite3_vfs_register sqlite3_api->vfs_register
89277 #define sqlite3_vfs_unregister sqlite3_api->vfs_unregister
89278 #define sqlite3_threadsafe sqlite3_api->xthreadsafe
89279 #define sqlite3_result_zeroblob sqlite3_api->result_zeroblob
89280 #define sqlite3_result_error_code sqlite3_api->result_error_code
89281 #define sqlite3_test_control sqlite3_api->test_control
89282 #define sqlite3_randomness sqlite3_api->randomness
89283 #define sqlite3_context_db_handle sqlite3_api->context_db_handle
89284 #define sqlite3_extended_result_codes sqlite3_api->extended_result_codes
89285 #define sqlite3_limit sqlite3_api->limit
89286 #define sqlite3_next_stmt sqlite3_api->next_stmt
89287 #define sqlite3_sql sqlite3_api->sql
89288 #define sqlite3_status sqlite3_api->status
89289 #define sqlite3_backup_finish sqlite3_api->backup_finish
89290 #define sqlite3_backup_init sqlite3_api->backup_init
89291 #define sqlite3_backup_pagecount sqlite3_api->backup_pagecount
89292 #define sqlite3_backup_remaining sqlite3_api->backup_remaining
89293 #define sqlite3_backup_step sqlite3_api->backup_step
89294 #define sqlite3_compileoption_get sqlite3_api->compileoption_get
89295 #define sqlite3_compileoption_used sqlite3_api->compileoption_used
89296 #define sqlite3_create_function_v2 sqlite3_api->create_function_v2
89297 #define sqlite3_db_config sqlite3_api->db_config
89298 #define sqlite3_db_mutex sqlite3_api->db_mutex
89299 #define sqlite3_db_status sqlite3_api->db_status
89300 #define sqlite3_extended_errcode sqlite3_api->extended_errcode
89301 #define sqlite3_log sqlite3_api->log
89302 #define sqlite3_soft_heap_limit64 sqlite3_api->soft_heap_limit64
89303 #define sqlite3_sourceid sqlite3_api->sourceid
89304 #define sqlite3_stmt_status sqlite3_api->stmt_status
89305 #define sqlite3_strnicmp sqlite3_api->strnicmp
89306 #define sqlite3_unlock_notify sqlite3_api->unlock_notify
89307 #define sqlite3_wal_autocheckpoint sqlite3_api->wal_autocheckpoint
89308 #define sqlite3_wal_checkpoint sqlite3_api->wal_checkpoint
89309 #define sqlite3_wal_hook sqlite3_api->wal_hook
89310 #define sqlite3_blob_reopen sqlite3_api->blob_reopen
89311 #define sqlite3_vtab_config sqlite3_api->vtab_config
89312 #define sqlite3_vtab_on_conflict sqlite3_api->vtab_on_conflict
89313 #endif /* SQLITE_CORE */
89315 #define SQLITE_EXTENSION_INIT1 const sqlite3_api_routines *sqlite3_api = 0;
89316 #define SQLITE_EXTENSION_INIT2(v) sqlite3_api = v;
89318 #endif /* _SQLITE3EXT_H_ */
89320 /************** End of sqlite3ext.h ******************************************/
89321 /************** Continuing where we left off in loadext.c ********************/
89322 /* #include <string.h> */
89324 #ifndef SQLITE_OMIT_LOAD_EXTENSION
89327 ** Some API routines are omitted when various features are
89328 ** excluded from a build of SQLite. Substitute a NULL pointer
89329 ** for any missing APIs.
89331 #ifndef SQLITE_ENABLE_COLUMN_METADATA
89332 # define sqlite3_column_database_name 0
89333 # define sqlite3_column_database_name16 0
89334 # define sqlite3_column_table_name 0
89335 # define sqlite3_column_table_name16 0
89336 # define sqlite3_column_origin_name 0
89337 # define sqlite3_column_origin_name16 0
89338 # define sqlite3_table_column_metadata 0
89339 #endif
89341 #ifdef SQLITE_OMIT_AUTHORIZATION
89342 # define sqlite3_set_authorizer 0
89343 #endif
89345 #ifdef SQLITE_OMIT_UTF16
89346 # define sqlite3_bind_text16 0
89347 # define sqlite3_collation_needed16 0
89348 # define sqlite3_column_decltype16 0
89349 # define sqlite3_column_name16 0
89350 # define sqlite3_column_text16 0
89351 # define sqlite3_complete16 0
89352 # define sqlite3_create_collation16 0
89353 # define sqlite3_create_function16 0
89354 # define sqlite3_errmsg16 0
89355 # define sqlite3_open16 0
89356 # define sqlite3_prepare16 0
89357 # define sqlite3_prepare16_v2 0
89358 # define sqlite3_result_error16 0
89359 # define sqlite3_result_text16 0
89360 # define sqlite3_result_text16be 0
89361 # define sqlite3_result_text16le 0
89362 # define sqlite3_value_text16 0
89363 # define sqlite3_value_text16be 0
89364 # define sqlite3_value_text16le 0
89365 # define sqlite3_column_database_name16 0
89366 # define sqlite3_column_table_name16 0
89367 # define sqlite3_column_origin_name16 0
89368 #endif
89370 #ifdef SQLITE_OMIT_COMPLETE
89371 # define sqlite3_complete 0
89372 # define sqlite3_complete16 0
89373 #endif
89375 #ifdef SQLITE_OMIT_DECLTYPE
89376 # define sqlite3_column_decltype16 0
89377 # define sqlite3_column_decltype 0
89378 #endif
89380 #ifdef SQLITE_OMIT_PROGRESS_CALLBACK
89381 # define sqlite3_progress_handler 0
89382 #endif
89384 #ifdef SQLITE_OMIT_VIRTUALTABLE
89385 # define sqlite3_create_module 0
89386 # define sqlite3_create_module_v2 0
89387 # define sqlite3_declare_vtab 0
89388 # define sqlite3_vtab_config 0
89389 # define sqlite3_vtab_on_conflict 0
89390 #endif
89392 #ifdef SQLITE_OMIT_SHARED_CACHE
89393 # define sqlite3_enable_shared_cache 0
89394 #endif
89396 #ifdef SQLITE_OMIT_TRACE
89397 # define sqlite3_profile 0
89398 # define sqlite3_trace 0
89399 #endif
89401 #ifdef SQLITE_OMIT_GET_TABLE
89402 # define sqlite3_free_table 0
89403 # define sqlite3_get_table 0
89404 #endif
89406 #ifdef SQLITE_OMIT_INCRBLOB
89407 #define sqlite3_bind_zeroblob 0
89408 #define sqlite3_blob_bytes 0
89409 #define sqlite3_blob_close 0
89410 #define sqlite3_blob_open 0
89411 #define sqlite3_blob_read 0
89412 #define sqlite3_blob_write 0
89413 #define sqlite3_blob_reopen 0
89414 #endif
89417 ** The following structure contains pointers to all SQLite API routines.
89418 ** A pointer to this structure is passed into extensions when they are
89419 ** loaded so that the extension can make calls back into the SQLite
89420 ** library.
89422 ** When adding new APIs, add them to the bottom of this structure
89423 ** in order to preserve backwards compatibility.
89425 ** Extensions that use newer APIs should first call the
89426 ** sqlite3_libversion_number() to make sure that the API they
89427 ** intend to use is supported by the library. Extensions should
89428 ** also check to make sure that the pointer to the function is
89429 ** not NULL before calling it.
89431 static const sqlite3_api_routines sqlite3Apis = {
89432 sqlite3_aggregate_context,
89433 #ifndef SQLITE_OMIT_DEPRECATED
89434 sqlite3_aggregate_count,
89435 #else
89437 #endif
89438 sqlite3_bind_blob,
89439 sqlite3_bind_double,
89440 sqlite3_bind_int,
89441 sqlite3_bind_int64,
89442 sqlite3_bind_null,
89443 sqlite3_bind_parameter_count,
89444 sqlite3_bind_parameter_index,
89445 sqlite3_bind_parameter_name,
89446 sqlite3_bind_text,
89447 sqlite3_bind_text16,
89448 sqlite3_bind_value,
89449 sqlite3_busy_handler,
89450 sqlite3_busy_timeout,
89451 sqlite3_changes,
89452 sqlite3_close,
89453 sqlite3_collation_needed,
89454 sqlite3_collation_needed16,
89455 sqlite3_column_blob,
89456 sqlite3_column_bytes,
89457 sqlite3_column_bytes16,
89458 sqlite3_column_count,
89459 sqlite3_column_database_name,
89460 sqlite3_column_database_name16,
89461 sqlite3_column_decltype,
89462 sqlite3_column_decltype16,
89463 sqlite3_column_double,
89464 sqlite3_column_int,
89465 sqlite3_column_int64,
89466 sqlite3_column_name,
89467 sqlite3_column_name16,
89468 sqlite3_column_origin_name,
89469 sqlite3_column_origin_name16,
89470 sqlite3_column_table_name,
89471 sqlite3_column_table_name16,
89472 sqlite3_column_text,
89473 sqlite3_column_text16,
89474 sqlite3_column_type,
89475 sqlite3_column_value,
89476 sqlite3_commit_hook,
89477 sqlite3_complete,
89478 sqlite3_complete16,
89479 sqlite3_create_collation,
89480 sqlite3_create_collation16,
89481 sqlite3_create_function,
89482 sqlite3_create_function16,
89483 sqlite3_create_module,
89484 sqlite3_data_count,
89485 sqlite3_db_handle,
89486 sqlite3_declare_vtab,
89487 sqlite3_enable_shared_cache,
89488 sqlite3_errcode,
89489 sqlite3_errmsg,
89490 sqlite3_errmsg16,
89491 sqlite3_exec,
89492 #ifndef SQLITE_OMIT_DEPRECATED
89493 sqlite3_expired,
89494 #else
89496 #endif
89497 sqlite3_finalize,
89498 sqlite3_free,
89499 sqlite3_free_table,
89500 sqlite3_get_autocommit,
89501 sqlite3_get_auxdata,
89502 sqlite3_get_table,
89503 0, /* Was sqlite3_global_recover(), but that function is deprecated */
89504 sqlite3_interrupt,
89505 sqlite3_last_insert_rowid,
89506 sqlite3_libversion,
89507 sqlite3_libversion_number,
89508 sqlite3_malloc,
89509 sqlite3_mprintf,
89510 sqlite3_open,
89511 sqlite3_open16,
89512 sqlite3_prepare,
89513 sqlite3_prepare16,
89514 sqlite3_profile,
89515 sqlite3_progress_handler,
89516 sqlite3_realloc,
89517 sqlite3_reset,
89518 sqlite3_result_blob,
89519 sqlite3_result_double,
89520 sqlite3_result_error,
89521 sqlite3_result_error16,
89522 sqlite3_result_int,
89523 sqlite3_result_int64,
89524 sqlite3_result_null,
89525 sqlite3_result_text,
89526 sqlite3_result_text16,
89527 sqlite3_result_text16be,
89528 sqlite3_result_text16le,
89529 sqlite3_result_value,
89530 sqlite3_rollback_hook,
89531 sqlite3_set_authorizer,
89532 sqlite3_set_auxdata,
89533 sqlite3_snprintf,
89534 sqlite3_step,
89535 sqlite3_table_column_metadata,
89536 #ifndef SQLITE_OMIT_DEPRECATED
89537 sqlite3_thread_cleanup,
89538 #else
89540 #endif
89541 sqlite3_total_changes,
89542 sqlite3_trace,
89543 #ifndef SQLITE_OMIT_DEPRECATED
89544 sqlite3_transfer_bindings,
89545 #else
89547 #endif
89548 sqlite3_update_hook,
89549 sqlite3_user_data,
89550 sqlite3_value_blob,
89551 sqlite3_value_bytes,
89552 sqlite3_value_bytes16,
89553 sqlite3_value_double,
89554 sqlite3_value_int,
89555 sqlite3_value_int64,
89556 sqlite3_value_numeric_type,
89557 sqlite3_value_text,
89558 sqlite3_value_text16,
89559 sqlite3_value_text16be,
89560 sqlite3_value_text16le,
89561 sqlite3_value_type,
89562 sqlite3_vmprintf,
89564 ** The original API set ends here. All extensions can call any
89565 ** of the APIs above provided that the pointer is not NULL. But
89566 ** before calling APIs that follow, extension should check the
89567 ** sqlite3_libversion_number() to make sure they are dealing with
89568 ** a library that is new enough to support that API.
89569 *************************************************************************
89571 sqlite3_overload_function,
89574 ** Added after 3.3.13
89576 sqlite3_prepare_v2,
89577 sqlite3_prepare16_v2,
89578 sqlite3_clear_bindings,
89581 ** Added for 3.4.1
89583 sqlite3_create_module_v2,
89586 ** Added for 3.5.0
89588 sqlite3_bind_zeroblob,
89589 sqlite3_blob_bytes,
89590 sqlite3_blob_close,
89591 sqlite3_blob_open,
89592 sqlite3_blob_read,
89593 sqlite3_blob_write,
89594 sqlite3_create_collation_v2,
89595 sqlite3_file_control,
89596 sqlite3_memory_highwater,
89597 sqlite3_memory_used,
89598 #ifdef SQLITE_MUTEX_OMIT
89604 #else
89605 sqlite3_mutex_alloc,
89606 sqlite3_mutex_enter,
89607 sqlite3_mutex_free,
89608 sqlite3_mutex_leave,
89609 sqlite3_mutex_try,
89610 #endif
89611 sqlite3_open_v2,
89612 sqlite3_release_memory,
89613 sqlite3_result_error_nomem,
89614 sqlite3_result_error_toobig,
89615 sqlite3_sleep,
89616 sqlite3_soft_heap_limit,
89617 sqlite3_vfs_find,
89618 sqlite3_vfs_register,
89619 sqlite3_vfs_unregister,
89622 ** Added for 3.5.8
89624 sqlite3_threadsafe,
89625 sqlite3_result_zeroblob,
89626 sqlite3_result_error_code,
89627 sqlite3_test_control,
89628 sqlite3_randomness,
89629 sqlite3_context_db_handle,
89632 ** Added for 3.6.0
89634 sqlite3_extended_result_codes,
89635 sqlite3_limit,
89636 sqlite3_next_stmt,
89637 sqlite3_sql,
89638 sqlite3_status,
89641 ** Added for 3.7.4
89643 sqlite3_backup_finish,
89644 sqlite3_backup_init,
89645 sqlite3_backup_pagecount,
89646 sqlite3_backup_remaining,
89647 sqlite3_backup_step,
89648 #ifndef SQLITE_OMIT_COMPILEOPTION_DIAGS
89649 sqlite3_compileoption_get,
89650 sqlite3_compileoption_used,
89651 #else
89654 #endif
89655 sqlite3_create_function_v2,
89656 sqlite3_db_config,
89657 sqlite3_db_mutex,
89658 sqlite3_db_status,
89659 sqlite3_extended_errcode,
89660 sqlite3_log,
89661 sqlite3_soft_heap_limit64,
89662 sqlite3_sourceid,
89663 sqlite3_stmt_status,
89664 sqlite3_strnicmp,
89665 #ifdef SQLITE_ENABLE_UNLOCK_NOTIFY
89666 sqlite3_unlock_notify,
89667 #else
89669 #endif
89670 #ifndef SQLITE_OMIT_WAL
89671 sqlite3_wal_autocheckpoint,
89672 sqlite3_wal_checkpoint,
89673 sqlite3_wal_hook,
89674 #else
89678 #endif
89679 sqlite3_blob_reopen,
89680 sqlite3_vtab_config,
89681 sqlite3_vtab_on_conflict,
89685 ** Attempt to load an SQLite extension library contained in the file
89686 ** zFile. The entry point is zProc. zProc may be 0 in which case a
89687 ** default entry point name (sqlite3_extension_init) is used. Use
89688 ** of the default name is recommended.
89690 ** Return SQLITE_OK on success and SQLITE_ERROR if something goes wrong.
89692 ** If an error occurs and pzErrMsg is not 0, then fill *pzErrMsg with
89693 ** error message text. The calling function should free this memory
89694 ** by calling sqlite3DbFree(db, ).
89696 static int sqlite3LoadExtension(
89697 sqlite3 *db, /* Load the extension into this database connection */
89698 const char *zFile, /* Name of the shared library containing extension */
89699 const char *zProc, /* Entry point. Use "sqlite3_extension_init" if 0 */
89700 char **pzErrMsg /* Put error message here if not 0 */
89702 sqlite3_vfs *pVfs = db->pVfs;
89703 void *handle;
89704 int (*xInit)(sqlite3*,char**,const sqlite3_api_routines*);
89705 char *zErrmsg = 0;
89706 void **aHandle;
89707 const int nMsg = 300;
89709 if( pzErrMsg ) *pzErrMsg = 0;
89711 /* Ticket #1863. To avoid a creating security problems for older
89712 ** applications that relink against newer versions of SQLite, the
89713 ** ability to run load_extension is turned off by default. One
89714 ** must call sqlite3_enable_load_extension() to turn on extension
89715 ** loading. Otherwise you get the following error.
89717 if( (db->flags & SQLITE_LoadExtension)==0 ){
89718 if( pzErrMsg ){
89719 *pzErrMsg = sqlite3_mprintf("not authorized");
89721 return SQLITE_ERROR;
89724 if( zProc==0 ){
89725 zProc = "sqlite3_extension_init";
89728 handle = sqlite3OsDlOpen(pVfs, zFile);
89729 if( handle==0 ){
89730 if( pzErrMsg ){
89731 *pzErrMsg = zErrmsg = sqlite3_malloc(nMsg);
89732 if( zErrmsg ){
89733 sqlite3_snprintf(nMsg, zErrmsg,
89734 "unable to open shared library [%s]", zFile);
89735 sqlite3OsDlError(pVfs, nMsg-1, zErrmsg);
89738 return SQLITE_ERROR;
89740 xInit = (int(*)(sqlite3*,char**,const sqlite3_api_routines*))
89741 sqlite3OsDlSym(pVfs, handle, zProc);
89742 if( xInit==0 ){
89743 if( pzErrMsg ){
89744 *pzErrMsg = zErrmsg = sqlite3_malloc(nMsg);
89745 if( zErrmsg ){
89746 sqlite3_snprintf(nMsg, zErrmsg,
89747 "no entry point [%s] in shared library [%s]", zProc,zFile);
89748 sqlite3OsDlError(pVfs, nMsg-1, zErrmsg);
89750 sqlite3OsDlClose(pVfs, handle);
89752 return SQLITE_ERROR;
89753 }else if( xInit(db, &zErrmsg, &sqlite3Apis) ){
89754 if( pzErrMsg ){
89755 *pzErrMsg = sqlite3_mprintf("error during initialization: %s", zErrmsg);
89757 sqlite3_free(zErrmsg);
89758 sqlite3OsDlClose(pVfs, handle);
89759 return SQLITE_ERROR;
89762 /* Append the new shared library handle to the db->aExtension array. */
89763 aHandle = sqlite3DbMallocZero(db, sizeof(handle)*(db->nExtension+1));
89764 if( aHandle==0 ){
89765 return SQLITE_NOMEM;
89767 if( db->nExtension>0 ){
89768 memcpy(aHandle, db->aExtension, sizeof(handle)*db->nExtension);
89770 sqlite3DbFree(db, db->aExtension);
89771 db->aExtension = aHandle;
89773 db->aExtension[db->nExtension++] = handle;
89774 return SQLITE_OK;
89776 SQLITE_API int sqlite3_load_extension(
89777 sqlite3 *db, /* Load the extension into this database connection */
89778 const char *zFile, /* Name of the shared library containing extension */
89779 const char *zProc, /* Entry point. Use "sqlite3_extension_init" if 0 */
89780 char **pzErrMsg /* Put error message here if not 0 */
89782 int rc;
89783 sqlite3_mutex_enter(db->mutex);
89784 rc = sqlite3LoadExtension(db, zFile, zProc, pzErrMsg);
89785 rc = sqlite3ApiExit(db, rc);
89786 sqlite3_mutex_leave(db->mutex);
89787 return rc;
89791 ** Call this routine when the database connection is closing in order
89792 ** to clean up loaded extensions
89794 SQLITE_PRIVATE void sqlite3CloseExtensions(sqlite3 *db){
89795 int i;
89796 assert( sqlite3_mutex_held(db->mutex) );
89797 for(i=0; i<db->nExtension; i++){
89798 sqlite3OsDlClose(db->pVfs, db->aExtension[i]);
89800 sqlite3DbFree(db, db->aExtension);
89804 ** Enable or disable extension loading. Extension loading is disabled by
89805 ** default so as not to open security holes in older applications.
89807 SQLITE_API int sqlite3_enable_load_extension(sqlite3 *db, int onoff){
89808 sqlite3_mutex_enter(db->mutex);
89809 if( onoff ){
89810 db->flags |= SQLITE_LoadExtension;
89811 }else{
89812 db->flags &= ~SQLITE_LoadExtension;
89814 sqlite3_mutex_leave(db->mutex);
89815 return SQLITE_OK;
89818 #endif /* SQLITE_OMIT_LOAD_EXTENSION */
89821 ** The auto-extension code added regardless of whether or not extension
89822 ** loading is supported. We need a dummy sqlite3Apis pointer for that
89823 ** code if regular extension loading is not available. This is that
89824 ** dummy pointer.
89826 #ifdef SQLITE_OMIT_LOAD_EXTENSION
89827 static const sqlite3_api_routines sqlite3Apis = { 0 };
89828 #endif
89832 ** The following object holds the list of automatically loaded
89833 ** extensions.
89835 ** This list is shared across threads. The SQLITE_MUTEX_STATIC_MASTER
89836 ** mutex must be held while accessing this list.
89838 typedef struct sqlite3AutoExtList sqlite3AutoExtList;
89839 static SQLITE_WSD struct sqlite3AutoExtList {
89840 int nExt; /* Number of entries in aExt[] */
89841 void (**aExt)(void); /* Pointers to the extension init functions */
89842 } sqlite3Autoext = { 0, 0 };
89844 /* The "wsdAutoext" macro will resolve to the autoextension
89845 ** state vector. If writable static data is unsupported on the target,
89846 ** we have to locate the state vector at run-time. In the more common
89847 ** case where writable static data is supported, wsdStat can refer directly
89848 ** to the "sqlite3Autoext" state vector declared above.
89850 #ifdef SQLITE_OMIT_WSD
89851 # define wsdAutoextInit \
89852 sqlite3AutoExtList *x = &GLOBAL(sqlite3AutoExtList,sqlite3Autoext)
89853 # define wsdAutoext x[0]
89854 #else
89855 # define wsdAutoextInit
89856 # define wsdAutoext sqlite3Autoext
89857 #endif
89861 ** Register a statically linked extension that is automatically
89862 ** loaded by every new database connection.
89864 SQLITE_API int sqlite3_auto_extension(void (*xInit)(void)){
89865 int rc = SQLITE_OK;
89866 #ifndef SQLITE_OMIT_AUTOINIT
89867 rc = sqlite3_initialize();
89868 if( rc ){
89869 return rc;
89870 }else
89871 #endif
89873 int i;
89874 #if SQLITE_THREADSAFE
89875 sqlite3_mutex *mutex = sqlite3MutexAlloc(SQLITE_MUTEX_STATIC_MASTER);
89876 #endif
89877 wsdAutoextInit;
89878 sqlite3_mutex_enter(mutex);
89879 for(i=0; i<wsdAutoext.nExt; i++){
89880 if( wsdAutoext.aExt[i]==xInit ) break;
89882 if( i==wsdAutoext.nExt ){
89883 int nByte = (wsdAutoext.nExt+1)*sizeof(wsdAutoext.aExt[0]);
89884 void (**aNew)(void);
89885 aNew = sqlite3_realloc(wsdAutoext.aExt, nByte);
89886 if( aNew==0 ){
89887 rc = SQLITE_NOMEM;
89888 }else{
89889 wsdAutoext.aExt = aNew;
89890 wsdAutoext.aExt[wsdAutoext.nExt] = xInit;
89891 wsdAutoext.nExt++;
89894 sqlite3_mutex_leave(mutex);
89895 assert( (rc&0xff)==rc );
89896 return rc;
89901 ** Reset the automatic extension loading mechanism.
89903 SQLITE_API void sqlite3_reset_auto_extension(void){
89904 #ifndef SQLITE_OMIT_AUTOINIT
89905 if( sqlite3_initialize()==SQLITE_OK )
89906 #endif
89908 #if SQLITE_THREADSAFE
89909 sqlite3_mutex *mutex = sqlite3MutexAlloc(SQLITE_MUTEX_STATIC_MASTER);
89910 #endif
89911 wsdAutoextInit;
89912 sqlite3_mutex_enter(mutex);
89913 sqlite3_free(wsdAutoext.aExt);
89914 wsdAutoext.aExt = 0;
89915 wsdAutoext.nExt = 0;
89916 sqlite3_mutex_leave(mutex);
89921 ** Load all automatic extensions.
89923 ** If anything goes wrong, set an error in the database connection.
89925 SQLITE_PRIVATE void sqlite3AutoLoadExtensions(sqlite3 *db){
89926 int i;
89927 int go = 1;
89928 int (*xInit)(sqlite3*,char**,const sqlite3_api_routines*);
89930 wsdAutoextInit;
89931 if( wsdAutoext.nExt==0 ){
89932 /* Common case: early out without every having to acquire a mutex */
89933 return;
89935 for(i=0; go; i++){
89936 char *zErrmsg;
89937 #if SQLITE_THREADSAFE
89938 sqlite3_mutex *mutex = sqlite3MutexAlloc(SQLITE_MUTEX_STATIC_MASTER);
89939 #endif
89940 sqlite3_mutex_enter(mutex);
89941 if( i>=wsdAutoext.nExt ){
89942 xInit = 0;
89943 go = 0;
89944 }else{
89945 xInit = (int(*)(sqlite3*,char**,const sqlite3_api_routines*))
89946 wsdAutoext.aExt[i];
89948 sqlite3_mutex_leave(mutex);
89949 zErrmsg = 0;
89950 if( xInit && xInit(db, &zErrmsg, &sqlite3Apis) ){
89951 sqlite3Error(db, SQLITE_ERROR,
89952 "automatic extension loading failed: %s", zErrmsg);
89953 go = 0;
89955 sqlite3_free(zErrmsg);
89959 /************** End of loadext.c *********************************************/
89960 /************** Begin file pragma.c ******************************************/
89962 ** 2003 April 6
89964 ** The author disclaims copyright to this source code. In place of
89965 ** a legal notice, here is a blessing:
89967 ** May you do good and not evil.
89968 ** May you find forgiveness for yourself and forgive others.
89969 ** May you share freely, never taking more than you give.
89971 *************************************************************************
89972 ** This file contains code used to implement the PRAGMA command.
89976 ** Interpret the given string as a safety level. Return 0 for OFF,
89977 ** 1 for ON or NORMAL and 2 for FULL. Return 1 for an empty or
89978 ** unrecognized string argument.
89980 ** Note that the values returned are one less that the values that
89981 ** should be passed into sqlite3BtreeSetSafetyLevel(). The is done
89982 ** to support legacy SQL code. The safety level used to be boolean
89983 ** and older scripts may have used numbers 0 for OFF and 1 for ON.
89985 static u8 getSafetyLevel(const char *z){
89986 /* 123456789 123456789 */
89987 static const char zText[] = "onoffalseyestruefull";
89988 static const u8 iOffset[] = {0, 1, 2, 4, 9, 12, 16};
89989 static const u8 iLength[] = {2, 2, 3, 5, 3, 4, 4};
89990 static const u8 iValue[] = {1, 0, 0, 0, 1, 1, 2};
89991 int i, n;
89992 if( sqlite3Isdigit(*z) ){
89993 return (u8)sqlite3Atoi(z);
89995 n = sqlite3Strlen30(z);
89996 for(i=0; i<ArraySize(iLength); i++){
89997 if( iLength[i]==n && sqlite3StrNICmp(&zText[iOffset[i]],z,n)==0 ){
89998 return iValue[i];
90001 return 1;
90005 ** Interpret the given string as a boolean value.
90007 SQLITE_PRIVATE u8 sqlite3GetBoolean(const char *z){
90008 return getSafetyLevel(z)&1;
90011 /* The sqlite3GetBoolean() function is used by other modules but the
90012 ** remainder of this file is specific to PRAGMA processing. So omit
90013 ** the rest of the file if PRAGMAs are omitted from the build.
90015 #if !defined(SQLITE_OMIT_PRAGMA)
90018 ** Interpret the given string as a locking mode value.
90020 static int getLockingMode(const char *z){
90021 if( z ){
90022 if( 0==sqlite3StrICmp(z, "exclusive") ) return PAGER_LOCKINGMODE_EXCLUSIVE;
90023 if( 0==sqlite3StrICmp(z, "normal") ) return PAGER_LOCKINGMODE_NORMAL;
90025 return PAGER_LOCKINGMODE_QUERY;
90028 #ifndef SQLITE_OMIT_AUTOVACUUM
90030 ** Interpret the given string as an auto-vacuum mode value.
90032 ** The following strings, "none", "full" and "incremental" are
90033 ** acceptable, as are their numeric equivalents: 0, 1 and 2 respectively.
90035 static int getAutoVacuum(const char *z){
90036 int i;
90037 if( 0==sqlite3StrICmp(z, "none") ) return BTREE_AUTOVACUUM_NONE;
90038 if( 0==sqlite3StrICmp(z, "full") ) return BTREE_AUTOVACUUM_FULL;
90039 if( 0==sqlite3StrICmp(z, "incremental") ) return BTREE_AUTOVACUUM_INCR;
90040 i = sqlite3Atoi(z);
90041 return (u8)((i>=0&&i<=2)?i:0);
90043 #endif /* ifndef SQLITE_OMIT_AUTOVACUUM */
90045 #ifndef SQLITE_OMIT_PAGER_PRAGMAS
90047 ** Interpret the given string as a temp db location. Return 1 for file
90048 ** backed temporary databases, 2 for the Red-Black tree in memory database
90049 ** and 0 to use the compile-time default.
90051 static int getTempStore(const char *z){
90052 if( z[0]>='0' && z[0]<='2' ){
90053 return z[0] - '0';
90054 }else if( sqlite3StrICmp(z, "file")==0 ){
90055 return 1;
90056 }else if( sqlite3StrICmp(z, "memory")==0 ){
90057 return 2;
90058 }else{
90059 return 0;
90062 #endif /* SQLITE_PAGER_PRAGMAS */
90064 #ifndef SQLITE_OMIT_PAGER_PRAGMAS
90066 ** Invalidate temp storage, either when the temp storage is changed
90067 ** from default, or when 'file' and the temp_store_directory has changed
90069 static int invalidateTempStorage(Parse *pParse){
90070 sqlite3 *db = pParse->db;
90071 if( db->aDb[1].pBt!=0 ){
90072 if( !db->autoCommit || sqlite3BtreeIsInReadTrans(db->aDb[1].pBt) ){
90073 sqlite3ErrorMsg(pParse, "temporary storage cannot be changed "
90074 "from within a transaction");
90075 return SQLITE_ERROR;
90077 sqlite3BtreeClose(db->aDb[1].pBt);
90078 db->aDb[1].pBt = 0;
90079 sqlite3ResetInternalSchema(db, -1);
90081 return SQLITE_OK;
90083 #endif /* SQLITE_PAGER_PRAGMAS */
90085 #ifndef SQLITE_OMIT_PAGER_PRAGMAS
90087 ** If the TEMP database is open, close it and mark the database schema
90088 ** as needing reloading. This must be done when using the SQLITE_TEMP_STORE
90089 ** or DEFAULT_TEMP_STORE pragmas.
90091 static int changeTempStorage(Parse *pParse, const char *zStorageType){
90092 int ts = getTempStore(zStorageType);
90093 sqlite3 *db = pParse->db;
90094 if( db->temp_store==ts ) return SQLITE_OK;
90095 if( invalidateTempStorage( pParse ) != SQLITE_OK ){
90096 return SQLITE_ERROR;
90098 db->temp_store = (u8)ts;
90099 return SQLITE_OK;
90101 #endif /* SQLITE_PAGER_PRAGMAS */
90104 ** Generate code to return a single integer value.
90106 static void returnSingleInt(Parse *pParse, const char *zLabel, i64 value){
90107 Vdbe *v = sqlite3GetVdbe(pParse);
90108 int mem = ++pParse->nMem;
90109 i64 *pI64 = sqlite3DbMallocRaw(pParse->db, sizeof(value));
90110 if( pI64 ){
90111 memcpy(pI64, &value, sizeof(value));
90113 sqlite3VdbeAddOp4(v, OP_Int64, 0, mem, 0, (char*)pI64, P4_INT64);
90114 sqlite3VdbeSetNumCols(v, 1);
90115 sqlite3VdbeSetColName(v, 0, COLNAME_NAME, zLabel, SQLITE_STATIC);
90116 sqlite3VdbeAddOp2(v, OP_ResultRow, mem, 1);
90119 #ifndef SQLITE_OMIT_FLAG_PRAGMAS
90121 ** Check to see if zRight and zLeft refer to a pragma that queries
90122 ** or changes one of the flags in db->flags. Return 1 if so and 0 if not.
90123 ** Also, implement the pragma.
90125 static int flagPragma(Parse *pParse, const char *zLeft, const char *zRight){
90126 static const struct sPragmaType {
90127 const char *zName; /* Name of the pragma */
90128 int mask; /* Mask for the db->flags value */
90129 } aPragma[] = {
90130 { "full_column_names", SQLITE_FullColNames },
90131 { "short_column_names", SQLITE_ShortColNames },
90132 { "count_changes", SQLITE_CountRows },
90133 { "empty_result_callbacks", SQLITE_NullCallback },
90134 { "legacy_file_format", SQLITE_LegacyFileFmt },
90135 { "fullfsync", SQLITE_FullFSync },
90136 { "checkpoint_fullfsync", SQLITE_CkptFullFSync },
90137 { "reverse_unordered_selects", SQLITE_ReverseOrder },
90138 #ifndef SQLITE_OMIT_AUTOMATIC_INDEX
90139 { "automatic_index", SQLITE_AutoIndex },
90140 #endif
90141 #ifdef SQLITE_DEBUG
90142 { "sql_trace", SQLITE_SqlTrace },
90143 { "vdbe_listing", SQLITE_VdbeListing },
90144 { "vdbe_trace", SQLITE_VdbeTrace },
90145 #endif
90146 #ifndef SQLITE_OMIT_CHECK
90147 { "ignore_check_constraints", SQLITE_IgnoreChecks },
90148 #endif
90149 /* The following is VERY experimental */
90150 { "writable_schema", SQLITE_WriteSchema|SQLITE_RecoveryMode },
90151 { "omit_readlock", SQLITE_NoReadlock },
90153 /* TODO: Maybe it shouldn't be possible to change the ReadUncommitted
90154 ** flag if there are any active statements. */
90155 { "read_uncommitted", SQLITE_ReadUncommitted },
90156 { "recursive_triggers", SQLITE_RecTriggers },
90158 /* This flag may only be set if both foreign-key and trigger support
90159 ** are present in the build. */
90160 #if !defined(SQLITE_OMIT_FOREIGN_KEY) && !defined(SQLITE_OMIT_TRIGGER)
90161 { "foreign_keys", SQLITE_ForeignKeys },
90162 #endif
90164 int i;
90165 const struct sPragmaType *p;
90166 for(i=0, p=aPragma; i<ArraySize(aPragma); i++, p++){
90167 if( sqlite3StrICmp(zLeft, p->zName)==0 ){
90168 sqlite3 *db = pParse->db;
90169 Vdbe *v;
90170 v = sqlite3GetVdbe(pParse);
90171 assert( v!=0 ); /* Already allocated by sqlite3Pragma() */
90172 if( ALWAYS(v) ){
90173 if( zRight==0 ){
90174 returnSingleInt(pParse, p->zName, (db->flags & p->mask)!=0 );
90175 }else{
90176 int mask = p->mask; /* Mask of bits to set or clear. */
90177 if( db->autoCommit==0 ){
90178 /* Foreign key support may not be enabled or disabled while not
90179 ** in auto-commit mode. */
90180 mask &= ~(SQLITE_ForeignKeys);
90183 if( sqlite3GetBoolean(zRight) ){
90184 db->flags |= mask;
90185 }else{
90186 db->flags &= ~mask;
90189 /* Many of the flag-pragmas modify the code generated by the SQL
90190 ** compiler (eg. count_changes). So add an opcode to expire all
90191 ** compiled SQL statements after modifying a pragma value.
90193 sqlite3VdbeAddOp2(v, OP_Expire, 0, 0);
90197 return 1;
90200 return 0;
90202 #endif /* SQLITE_OMIT_FLAG_PRAGMAS */
90205 ** Return a human-readable name for a constraint resolution action.
90207 #ifndef SQLITE_OMIT_FOREIGN_KEY
90208 static const char *actionName(u8 action){
90209 const char *zName;
90210 switch( action ){
90211 case OE_SetNull: zName = "SET NULL"; break;
90212 case OE_SetDflt: zName = "SET DEFAULT"; break;
90213 case OE_Cascade: zName = "CASCADE"; break;
90214 case OE_Restrict: zName = "RESTRICT"; break;
90215 default: zName = "NO ACTION";
90216 assert( action==OE_None ); break;
90218 return zName;
90220 #endif
90224 ** Parameter eMode must be one of the PAGER_JOURNALMODE_XXX constants
90225 ** defined in pager.h. This function returns the associated lowercase
90226 ** journal-mode name.
90228 SQLITE_PRIVATE const char *sqlite3JournalModename(int eMode){
90229 static char * const azModeName[] = {
90230 "delete", "persist", "off", "truncate", "memory"
90231 #ifndef SQLITE_OMIT_WAL
90232 , "wal"
90233 #endif
90235 assert( PAGER_JOURNALMODE_DELETE==0 );
90236 assert( PAGER_JOURNALMODE_PERSIST==1 );
90237 assert( PAGER_JOURNALMODE_OFF==2 );
90238 assert( PAGER_JOURNALMODE_TRUNCATE==3 );
90239 assert( PAGER_JOURNALMODE_MEMORY==4 );
90240 assert( PAGER_JOURNALMODE_WAL==5 );
90241 assert( eMode>=0 && eMode<=ArraySize(azModeName) );
90243 if( eMode==ArraySize(azModeName) ) return 0;
90244 return azModeName[eMode];
90248 ** Process a pragma statement.
90250 ** Pragmas are of this form:
90252 ** PRAGMA [database.]id [= value]
90254 ** The identifier might also be a string. The value is a string, and
90255 ** identifier, or a number. If minusFlag is true, then the value is
90256 ** a number that was preceded by a minus sign.
90258 ** If the left side is "database.id" then pId1 is the database name
90259 ** and pId2 is the id. If the left side is just "id" then pId1 is the
90260 ** id and pId2 is any empty string.
90262 SQLITE_PRIVATE void sqlite3Pragma(
90263 Parse *pParse,
90264 Token *pId1, /* First part of [database.]id field */
90265 Token *pId2, /* Second part of [database.]id field, or NULL */
90266 Token *pValue, /* Token for <value>, or NULL */
90267 int minusFlag /* True if a '-' sign preceded <value> */
90269 char *zLeft = 0; /* Nul-terminated UTF-8 string <id> */
90270 char *zRight = 0; /* Nul-terminated UTF-8 string <value>, or NULL */
90271 const char *zDb = 0; /* The database name */
90272 Token *pId; /* Pointer to <id> token */
90273 int iDb; /* Database index for <database> */
90274 sqlite3 *db = pParse->db;
90275 Db *pDb;
90276 Vdbe *v = pParse->pVdbe = sqlite3VdbeCreate(db);
90277 if( v==0 ) return;
90278 sqlite3VdbeRunOnlyOnce(v);
90279 pParse->nMem = 2;
90281 /* Interpret the [database.] part of the pragma statement. iDb is the
90282 ** index of the database this pragma is being applied to in db.aDb[]. */
90283 iDb = sqlite3TwoPartName(pParse, pId1, pId2, &pId);
90284 if( iDb<0 ) return;
90285 pDb = &db->aDb[iDb];
90287 /* If the temp database has been explicitly named as part of the
90288 ** pragma, make sure it is open.
90290 if( iDb==1 && sqlite3OpenTempDatabase(pParse) ){
90291 return;
90294 zLeft = sqlite3NameFromToken(db, pId);
90295 if( !zLeft ) return;
90296 if( minusFlag ){
90297 zRight = sqlite3MPrintf(db, "-%T", pValue);
90298 }else{
90299 zRight = sqlite3NameFromToken(db, pValue);
90302 assert( pId2 );
90303 zDb = pId2->n>0 ? pDb->zName : 0;
90304 if( sqlite3AuthCheck(pParse, SQLITE_PRAGMA, zLeft, zRight, zDb) ){
90305 goto pragma_out;
90308 #ifndef SQLITE_OMIT_PAGER_PRAGMAS
90310 ** PRAGMA [database.]default_cache_size
90311 ** PRAGMA [database.]default_cache_size=N
90313 ** The first form reports the current persistent setting for the
90314 ** page cache size. The value returned is the maximum number of
90315 ** pages in the page cache. The second form sets both the current
90316 ** page cache size value and the persistent page cache size value
90317 ** stored in the database file.
90319 ** Older versions of SQLite would set the default cache size to a
90320 ** negative number to indicate synchronous=OFF. These days, synchronous
90321 ** is always on by default regardless of the sign of the default cache
90322 ** size. But continue to take the absolute value of the default cache
90323 ** size of historical compatibility.
90325 if( sqlite3StrICmp(zLeft,"default_cache_size")==0 ){
90326 static const VdbeOpList getCacheSize[] = {
90327 { OP_Transaction, 0, 0, 0}, /* 0 */
90328 { OP_ReadCookie, 0, 1, BTREE_DEFAULT_CACHE_SIZE}, /* 1 */
90329 { OP_IfPos, 1, 7, 0},
90330 { OP_Integer, 0, 2, 0},
90331 { OP_Subtract, 1, 2, 1},
90332 { OP_IfPos, 1, 7, 0},
90333 { OP_Integer, 0, 1, 0}, /* 6 */
90334 { OP_ResultRow, 1, 1, 0},
90336 int addr;
90337 if( sqlite3ReadSchema(pParse) ) goto pragma_out;
90338 sqlite3VdbeUsesBtree(v, iDb);
90339 if( !zRight ){
90340 sqlite3VdbeSetNumCols(v, 1);
90341 sqlite3VdbeSetColName(v, 0, COLNAME_NAME, "cache_size", SQLITE_STATIC);
90342 pParse->nMem += 2;
90343 addr = sqlite3VdbeAddOpList(v, ArraySize(getCacheSize), getCacheSize);
90344 sqlite3VdbeChangeP1(v, addr, iDb);
90345 sqlite3VdbeChangeP1(v, addr+1, iDb);
90346 sqlite3VdbeChangeP1(v, addr+6, SQLITE_DEFAULT_CACHE_SIZE);
90347 }else{
90348 int size = sqlite3AbsInt32(sqlite3Atoi(zRight));
90349 sqlite3BeginWriteOperation(pParse, 0, iDb);
90350 sqlite3VdbeAddOp2(v, OP_Integer, size, 1);
90351 sqlite3VdbeAddOp3(v, OP_SetCookie, iDb, BTREE_DEFAULT_CACHE_SIZE, 1);
90352 assert( sqlite3SchemaMutexHeld(db, iDb, 0) );
90353 pDb->pSchema->cache_size = size;
90354 sqlite3BtreeSetCacheSize(pDb->pBt, pDb->pSchema->cache_size);
90356 }else
90359 ** PRAGMA [database.]page_size
90360 ** PRAGMA [database.]page_size=N
90362 ** The first form reports the current setting for the
90363 ** database page size in bytes. The second form sets the
90364 ** database page size value. The value can only be set if
90365 ** the database has not yet been created.
90367 if( sqlite3StrICmp(zLeft,"page_size")==0 ){
90368 Btree *pBt = pDb->pBt;
90369 assert( pBt!=0 );
90370 if( !zRight ){
90371 int size = ALWAYS(pBt) ? sqlite3BtreeGetPageSize(pBt) : 0;
90372 returnSingleInt(pParse, "page_size", size);
90373 }else{
90374 /* Malloc may fail when setting the page-size, as there is an internal
90375 ** buffer that the pager module resizes using sqlite3_realloc().
90377 db->nextPagesize = sqlite3Atoi(zRight);
90378 if( SQLITE_NOMEM==sqlite3BtreeSetPageSize(pBt, db->nextPagesize, -1, 0) ){
90379 db->mallocFailed = 1;
90382 }else
90385 ** PRAGMA [database.]secure_delete
90386 ** PRAGMA [database.]secure_delete=ON/OFF
90388 ** The first form reports the current setting for the
90389 ** secure_delete flag. The second form changes the secure_delete
90390 ** flag setting and reports thenew value.
90392 if( sqlite3StrICmp(zLeft,"secure_delete")==0 ){
90393 Btree *pBt = pDb->pBt;
90394 int b = -1;
90395 assert( pBt!=0 );
90396 if( zRight ){
90397 b = sqlite3GetBoolean(zRight);
90399 if( pId2->n==0 && b>=0 ){
90400 int ii;
90401 for(ii=0; ii<db->nDb; ii++){
90402 sqlite3BtreeSecureDelete(db->aDb[ii].pBt, b);
90405 b = sqlite3BtreeSecureDelete(pBt, b);
90406 returnSingleInt(pParse, "secure_delete", b);
90407 }else
90410 ** PRAGMA [database.]max_page_count
90411 ** PRAGMA [database.]max_page_count=N
90413 ** The first form reports the current setting for the
90414 ** maximum number of pages in the database file. The
90415 ** second form attempts to change this setting. Both
90416 ** forms return the current setting.
90418 ** PRAGMA [database.]page_count
90420 ** Return the number of pages in the specified database.
90422 if( sqlite3StrICmp(zLeft,"page_count")==0
90423 || sqlite3StrICmp(zLeft,"max_page_count")==0
90425 int iReg;
90426 if( sqlite3ReadSchema(pParse) ) goto pragma_out;
90427 sqlite3CodeVerifySchema(pParse, iDb);
90428 iReg = ++pParse->nMem;
90429 if( zLeft[0]=='p' ){
90430 sqlite3VdbeAddOp2(v, OP_Pagecount, iDb, iReg);
90431 }else{
90432 sqlite3VdbeAddOp3(v, OP_MaxPgcnt, iDb, iReg, sqlite3Atoi(zRight));
90434 sqlite3VdbeAddOp2(v, OP_ResultRow, iReg, 1);
90435 sqlite3VdbeSetNumCols(v, 1);
90436 sqlite3VdbeSetColName(v, 0, COLNAME_NAME, zLeft, SQLITE_TRANSIENT);
90437 }else
90440 ** PRAGMA [database.]locking_mode
90441 ** PRAGMA [database.]locking_mode = (normal|exclusive)
90443 if( sqlite3StrICmp(zLeft,"locking_mode")==0 ){
90444 const char *zRet = "normal";
90445 int eMode = getLockingMode(zRight);
90447 if( pId2->n==0 && eMode==PAGER_LOCKINGMODE_QUERY ){
90448 /* Simple "PRAGMA locking_mode;" statement. This is a query for
90449 ** the current default locking mode (which may be different to
90450 ** the locking-mode of the main database).
90452 eMode = db->dfltLockMode;
90453 }else{
90454 Pager *pPager;
90455 if( pId2->n==0 ){
90456 /* This indicates that no database name was specified as part
90457 ** of the PRAGMA command. In this case the locking-mode must be
90458 ** set on all attached databases, as well as the main db file.
90460 ** Also, the sqlite3.dfltLockMode variable is set so that
90461 ** any subsequently attached databases also use the specified
90462 ** locking mode.
90464 int ii;
90465 assert(pDb==&db->aDb[0]);
90466 for(ii=2; ii<db->nDb; ii++){
90467 pPager = sqlite3BtreePager(db->aDb[ii].pBt);
90468 sqlite3PagerLockingMode(pPager, eMode);
90470 db->dfltLockMode = (u8)eMode;
90472 pPager = sqlite3BtreePager(pDb->pBt);
90473 eMode = sqlite3PagerLockingMode(pPager, eMode);
90476 assert(eMode==PAGER_LOCKINGMODE_NORMAL||eMode==PAGER_LOCKINGMODE_EXCLUSIVE);
90477 if( eMode==PAGER_LOCKINGMODE_EXCLUSIVE ){
90478 zRet = "exclusive";
90480 sqlite3VdbeSetNumCols(v, 1);
90481 sqlite3VdbeSetColName(v, 0, COLNAME_NAME, "locking_mode", SQLITE_STATIC);
90482 sqlite3VdbeAddOp4(v, OP_String8, 0, 1, 0, zRet, 0);
90483 sqlite3VdbeAddOp2(v, OP_ResultRow, 1, 1);
90484 }else
90487 ** PRAGMA [database.]journal_mode
90488 ** PRAGMA [database.]journal_mode =
90489 ** (delete|persist|off|truncate|memory|wal|off)
90491 if( sqlite3StrICmp(zLeft,"journal_mode")==0 ){
90492 int eMode; /* One of the PAGER_JOURNALMODE_XXX symbols */
90493 int ii; /* Loop counter */
90495 /* Force the schema to be loaded on all databases. This cases all
90496 ** database files to be opened and the journal_modes set. */
90497 if( sqlite3ReadSchema(pParse) ){
90498 goto pragma_out;
90501 sqlite3VdbeSetNumCols(v, 1);
90502 sqlite3VdbeSetColName(v, 0, COLNAME_NAME, "journal_mode", SQLITE_STATIC);
90504 if( zRight==0 ){
90505 /* If there is no "=MODE" part of the pragma, do a query for the
90506 ** current mode */
90507 eMode = PAGER_JOURNALMODE_QUERY;
90508 }else{
90509 const char *zMode;
90510 int n = sqlite3Strlen30(zRight);
90511 for(eMode=0; (zMode = sqlite3JournalModename(eMode))!=0; eMode++){
90512 if( sqlite3StrNICmp(zRight, zMode, n)==0 ) break;
90514 if( !zMode ){
90515 /* If the "=MODE" part does not match any known journal mode,
90516 ** then do a query */
90517 eMode = PAGER_JOURNALMODE_QUERY;
90520 if( eMode==PAGER_JOURNALMODE_QUERY && pId2->n==0 ){
90521 /* Convert "PRAGMA journal_mode" into "PRAGMA main.journal_mode" */
90522 iDb = 0;
90523 pId2->n = 1;
90525 for(ii=db->nDb-1; ii>=0; ii--){
90526 if( db->aDb[ii].pBt && (ii==iDb || pId2->n==0) ){
90527 sqlite3VdbeUsesBtree(v, ii);
90528 sqlite3VdbeAddOp3(v, OP_JournalMode, ii, 1, eMode);
90531 sqlite3VdbeAddOp2(v, OP_ResultRow, 1, 1);
90532 }else
90535 ** PRAGMA [database.]journal_size_limit
90536 ** PRAGMA [database.]journal_size_limit=N
90538 ** Get or set the size limit on rollback journal files.
90540 if( sqlite3StrICmp(zLeft,"journal_size_limit")==0 ){
90541 Pager *pPager = sqlite3BtreePager(pDb->pBt);
90542 i64 iLimit = -2;
90543 if( zRight ){
90544 sqlite3Atoi64(zRight, &iLimit, 1000000, SQLITE_UTF8);
90545 if( iLimit<-1 ) iLimit = -1;
90547 iLimit = sqlite3PagerJournalSizeLimit(pPager, iLimit);
90548 returnSingleInt(pParse, "journal_size_limit", iLimit);
90549 }else
90551 #endif /* SQLITE_OMIT_PAGER_PRAGMAS */
90554 ** PRAGMA [database.]auto_vacuum
90555 ** PRAGMA [database.]auto_vacuum=N
90557 ** Get or set the value of the database 'auto-vacuum' parameter.
90558 ** The value is one of: 0 NONE 1 FULL 2 INCREMENTAL
90560 #ifndef SQLITE_OMIT_AUTOVACUUM
90561 if( sqlite3StrICmp(zLeft,"auto_vacuum")==0 ){
90562 Btree *pBt = pDb->pBt;
90563 assert( pBt!=0 );
90564 if( sqlite3ReadSchema(pParse) ){
90565 goto pragma_out;
90567 if( !zRight ){
90568 int auto_vacuum;
90569 if( ALWAYS(pBt) ){
90570 auto_vacuum = sqlite3BtreeGetAutoVacuum(pBt);
90571 }else{
90572 auto_vacuum = SQLITE_DEFAULT_AUTOVACUUM;
90574 returnSingleInt(pParse, "auto_vacuum", auto_vacuum);
90575 }else{
90576 int eAuto = getAutoVacuum(zRight);
90577 assert( eAuto>=0 && eAuto<=2 );
90578 db->nextAutovac = (u8)eAuto;
90579 if( ALWAYS(eAuto>=0) ){
90580 /* Call SetAutoVacuum() to set initialize the internal auto and
90581 ** incr-vacuum flags. This is required in case this connection
90582 ** creates the database file. It is important that it is created
90583 ** as an auto-vacuum capable db.
90585 int rc = sqlite3BtreeSetAutoVacuum(pBt, eAuto);
90586 if( rc==SQLITE_OK && (eAuto==1 || eAuto==2) ){
90587 /* When setting the auto_vacuum mode to either "full" or
90588 ** "incremental", write the value of meta[6] in the database
90589 ** file. Before writing to meta[6], check that meta[3] indicates
90590 ** that this really is an auto-vacuum capable database.
90592 static const VdbeOpList setMeta6[] = {
90593 { OP_Transaction, 0, 1, 0}, /* 0 */
90594 { OP_ReadCookie, 0, 1, BTREE_LARGEST_ROOT_PAGE},
90595 { OP_If, 1, 0, 0}, /* 2 */
90596 { OP_Halt, SQLITE_OK, OE_Abort, 0}, /* 3 */
90597 { OP_Integer, 0, 1, 0}, /* 4 */
90598 { OP_SetCookie, 0, BTREE_INCR_VACUUM, 1}, /* 5 */
90600 int iAddr;
90601 iAddr = sqlite3VdbeAddOpList(v, ArraySize(setMeta6), setMeta6);
90602 sqlite3VdbeChangeP1(v, iAddr, iDb);
90603 sqlite3VdbeChangeP1(v, iAddr+1, iDb);
90604 sqlite3VdbeChangeP2(v, iAddr+2, iAddr+4);
90605 sqlite3VdbeChangeP1(v, iAddr+4, eAuto-1);
90606 sqlite3VdbeChangeP1(v, iAddr+5, iDb);
90607 sqlite3VdbeUsesBtree(v, iDb);
90611 }else
90612 #endif
90615 ** PRAGMA [database.]incremental_vacuum(N)
90617 ** Do N steps of incremental vacuuming on a database.
90619 #ifndef SQLITE_OMIT_AUTOVACUUM
90620 if( sqlite3StrICmp(zLeft,"incremental_vacuum")==0 ){
90621 int iLimit, addr;
90622 if( sqlite3ReadSchema(pParse) ){
90623 goto pragma_out;
90625 if( zRight==0 || !sqlite3GetInt32(zRight, &iLimit) || iLimit<=0 ){
90626 iLimit = 0x7fffffff;
90628 sqlite3BeginWriteOperation(pParse, 0, iDb);
90629 sqlite3VdbeAddOp2(v, OP_Integer, iLimit, 1);
90630 addr = sqlite3VdbeAddOp1(v, OP_IncrVacuum, iDb);
90631 sqlite3VdbeAddOp1(v, OP_ResultRow, 1);
90632 sqlite3VdbeAddOp2(v, OP_AddImm, 1, -1);
90633 sqlite3VdbeAddOp2(v, OP_IfPos, 1, addr);
90634 sqlite3VdbeJumpHere(v, addr);
90635 }else
90636 #endif
90638 #ifndef SQLITE_OMIT_PAGER_PRAGMAS
90640 ** PRAGMA [database.]cache_size
90641 ** PRAGMA [database.]cache_size=N
90643 ** The first form reports the current local setting for the
90644 ** page cache size. The local setting can be different from
90645 ** the persistent cache size value that is stored in the database
90646 ** file itself. The value returned is the maximum number of
90647 ** pages in the page cache. The second form sets the local
90648 ** page cache size value. It does not change the persistent
90649 ** cache size stored on the disk so the cache size will revert
90650 ** to its default value when the database is closed and reopened.
90651 ** N should be a positive integer.
90653 if( sqlite3StrICmp(zLeft,"cache_size")==0 ){
90654 if( sqlite3ReadSchema(pParse) ) goto pragma_out;
90655 assert( sqlite3SchemaMutexHeld(db, iDb, 0) );
90656 if( !zRight ){
90657 returnSingleInt(pParse, "cache_size", pDb->pSchema->cache_size);
90658 }else{
90659 int size = sqlite3AbsInt32(sqlite3Atoi(zRight));
90660 pDb->pSchema->cache_size = size;
90661 sqlite3BtreeSetCacheSize(pDb->pBt, pDb->pSchema->cache_size);
90663 }else
90666 ** PRAGMA temp_store
90667 ** PRAGMA temp_store = "default"|"memory"|"file"
90669 ** Return or set the local value of the temp_store flag. Changing
90670 ** the local value does not make changes to the disk file and the default
90671 ** value will be restored the next time the database is opened.
90673 ** Note that it is possible for the library compile-time options to
90674 ** override this setting
90676 if( sqlite3StrICmp(zLeft, "temp_store")==0 ){
90677 if( !zRight ){
90678 returnSingleInt(pParse, "temp_store", db->temp_store);
90679 }else{
90680 changeTempStorage(pParse, zRight);
90682 }else
90685 ** PRAGMA temp_store_directory
90686 ** PRAGMA temp_store_directory = ""|"directory_name"
90688 ** Return or set the local value of the temp_store_directory flag. Changing
90689 ** the value sets a specific directory to be used for temporary files.
90690 ** Setting to a null string reverts to the default temporary directory search.
90691 ** If temporary directory is changed, then invalidateTempStorage.
90694 if( sqlite3StrICmp(zLeft, "temp_store_directory")==0 ){
90695 if( !zRight ){
90696 if( sqlite3_temp_directory ){
90697 sqlite3VdbeSetNumCols(v, 1);
90698 sqlite3VdbeSetColName(v, 0, COLNAME_NAME,
90699 "temp_store_directory", SQLITE_STATIC);
90700 sqlite3VdbeAddOp4(v, OP_String8, 0, 1, 0, sqlite3_temp_directory, 0);
90701 sqlite3VdbeAddOp2(v, OP_ResultRow, 1, 1);
90703 }else{
90704 #ifndef SQLITE_OMIT_WSD
90705 if( zRight[0] ){
90706 int rc;
90707 int res;
90708 rc = sqlite3OsAccess(db->pVfs, zRight, SQLITE_ACCESS_READWRITE, &res);
90709 if( rc!=SQLITE_OK || res==0 ){
90710 sqlite3ErrorMsg(pParse, "not a writable directory");
90711 goto pragma_out;
90714 if( SQLITE_TEMP_STORE==0
90715 || (SQLITE_TEMP_STORE==1 && db->temp_store<=1)
90716 || (SQLITE_TEMP_STORE==2 && db->temp_store==1)
90718 invalidateTempStorage(pParse);
90720 sqlite3_free(sqlite3_temp_directory);
90721 if( zRight[0] ){
90722 sqlite3_temp_directory = sqlite3_mprintf("%s", zRight);
90723 }else{
90724 sqlite3_temp_directory = 0;
90726 #endif /* SQLITE_OMIT_WSD */
90728 }else
90730 #if !defined(SQLITE_ENABLE_LOCKING_STYLE)
90731 # if defined(__APPLE__)
90732 # define SQLITE_ENABLE_LOCKING_STYLE 1
90733 # else
90734 # define SQLITE_ENABLE_LOCKING_STYLE 0
90735 # endif
90736 #endif
90737 #if SQLITE_ENABLE_LOCKING_STYLE
90739 ** PRAGMA [database.]lock_proxy_file
90740 ** PRAGMA [database.]lock_proxy_file = ":auto:"|"lock_file_path"
90742 ** Return or set the value of the lock_proxy_file flag. Changing
90743 ** the value sets a specific file to be used for database access locks.
90746 if( sqlite3StrICmp(zLeft, "lock_proxy_file")==0 ){
90747 if( !zRight ){
90748 Pager *pPager = sqlite3BtreePager(pDb->pBt);
90749 char *proxy_file_path = NULL;
90750 sqlite3_file *pFile = sqlite3PagerFile(pPager);
90751 sqlite3OsFileControl(pFile, SQLITE_GET_LOCKPROXYFILE,
90752 &proxy_file_path);
90754 if( proxy_file_path ){
90755 sqlite3VdbeSetNumCols(v, 1);
90756 sqlite3VdbeSetColName(v, 0, COLNAME_NAME,
90757 "lock_proxy_file", SQLITE_STATIC);
90758 sqlite3VdbeAddOp4(v, OP_String8, 0, 1, 0, proxy_file_path, 0);
90759 sqlite3VdbeAddOp2(v, OP_ResultRow, 1, 1);
90761 }else{
90762 Pager *pPager = sqlite3BtreePager(pDb->pBt);
90763 sqlite3_file *pFile = sqlite3PagerFile(pPager);
90764 int res;
90765 if( zRight[0] ){
90766 res=sqlite3OsFileControl(pFile, SQLITE_SET_LOCKPROXYFILE,
90767 zRight);
90768 } else {
90769 res=sqlite3OsFileControl(pFile, SQLITE_SET_LOCKPROXYFILE,
90770 NULL);
90772 if( res!=SQLITE_OK ){
90773 sqlite3ErrorMsg(pParse, "failed to set lock proxy file");
90774 goto pragma_out;
90777 }else
90778 #endif /* SQLITE_ENABLE_LOCKING_STYLE */
90781 ** PRAGMA [database.]synchronous
90782 ** PRAGMA [database.]synchronous=OFF|ON|NORMAL|FULL
90784 ** Return or set the local value of the synchronous flag. Changing
90785 ** the local value does not make changes to the disk file and the
90786 ** default value will be restored the next time the database is
90787 ** opened.
90789 if( sqlite3StrICmp(zLeft,"synchronous")==0 ){
90790 if( sqlite3ReadSchema(pParse) ) goto pragma_out;
90791 if( !zRight ){
90792 returnSingleInt(pParse, "synchronous", pDb->safety_level-1);
90793 }else{
90794 if( !db->autoCommit ){
90795 sqlite3ErrorMsg(pParse,
90796 "Safety level may not be changed inside a transaction");
90797 }else{
90798 pDb->safety_level = getSafetyLevel(zRight)+1;
90801 }else
90802 #endif /* SQLITE_OMIT_PAGER_PRAGMAS */
90804 #ifndef SQLITE_OMIT_FLAG_PRAGMAS
90805 if( flagPragma(pParse, zLeft, zRight) ){
90806 /* The flagPragma() subroutine also generates any necessary code
90807 ** there is nothing more to do here */
90808 }else
90809 #endif /* SQLITE_OMIT_FLAG_PRAGMAS */
90811 #ifndef SQLITE_OMIT_SCHEMA_PRAGMAS
90813 ** PRAGMA table_info(<table>)
90815 ** Return a single row for each column of the named table. The columns of
90816 ** the returned data set are:
90818 ** cid: Column id (numbered from left to right, starting at 0)
90819 ** name: Column name
90820 ** type: Column declaration type.
90821 ** notnull: True if 'NOT NULL' is part of column declaration
90822 ** dflt_value: The default value for the column, if any.
90824 if( sqlite3StrICmp(zLeft, "table_info")==0 && zRight ){
90825 Table *pTab;
90826 if( sqlite3ReadSchema(pParse) ) goto pragma_out;
90827 pTab = sqlite3FindTable(db, zRight, zDb);
90828 if( pTab ){
90829 int i;
90830 int nHidden = 0;
90831 Column *pCol;
90832 sqlite3VdbeSetNumCols(v, 6);
90833 pParse->nMem = 6;
90834 sqlite3VdbeSetColName(v, 0, COLNAME_NAME, "cid", SQLITE_STATIC);
90835 sqlite3VdbeSetColName(v, 1, COLNAME_NAME, "name", SQLITE_STATIC);
90836 sqlite3VdbeSetColName(v, 2, COLNAME_NAME, "type", SQLITE_STATIC);
90837 sqlite3VdbeSetColName(v, 3, COLNAME_NAME, "notnull", SQLITE_STATIC);
90838 sqlite3VdbeSetColName(v, 4, COLNAME_NAME, "dflt_value", SQLITE_STATIC);
90839 sqlite3VdbeSetColName(v, 5, COLNAME_NAME, "pk", SQLITE_STATIC);
90840 sqlite3ViewGetColumnNames(pParse, pTab);
90841 for(i=0, pCol=pTab->aCol; i<pTab->nCol; i++, pCol++){
90842 if( IsHiddenColumn(pCol) ){
90843 nHidden++;
90844 continue;
90846 sqlite3VdbeAddOp2(v, OP_Integer, i-nHidden, 1);
90847 sqlite3VdbeAddOp4(v, OP_String8, 0, 2, 0, pCol->zName, 0);
90848 sqlite3VdbeAddOp4(v, OP_String8, 0, 3, 0,
90849 pCol->zType ? pCol->zType : "", 0);
90850 sqlite3VdbeAddOp2(v, OP_Integer, (pCol->notNull ? 1 : 0), 4);
90851 if( pCol->zDflt ){
90852 sqlite3VdbeAddOp4(v, OP_String8, 0, 5, 0, (char*)pCol->zDflt, 0);
90853 }else{
90854 sqlite3VdbeAddOp2(v, OP_Null, 0, 5);
90856 sqlite3VdbeAddOp2(v, OP_Integer, pCol->isPrimKey, 6);
90857 sqlite3VdbeAddOp2(v, OP_ResultRow, 1, 6);
90860 }else
90862 if( sqlite3StrICmp(zLeft, "index_info")==0 && zRight ){
90863 Index *pIdx;
90864 Table *pTab;
90865 if( sqlite3ReadSchema(pParse) ) goto pragma_out;
90866 pIdx = sqlite3FindIndex(db, zRight, zDb);
90867 if( pIdx ){
90868 int i;
90869 pTab = pIdx->pTable;
90870 sqlite3VdbeSetNumCols(v, 3);
90871 pParse->nMem = 3;
90872 sqlite3VdbeSetColName(v, 0, COLNAME_NAME, "seqno", SQLITE_STATIC);
90873 sqlite3VdbeSetColName(v, 1, COLNAME_NAME, "cid", SQLITE_STATIC);
90874 sqlite3VdbeSetColName(v, 2, COLNAME_NAME, "name", SQLITE_STATIC);
90875 for(i=0; i<pIdx->nColumn; i++){
90876 int cnum = pIdx->aiColumn[i];
90877 sqlite3VdbeAddOp2(v, OP_Integer, i, 1);
90878 sqlite3VdbeAddOp2(v, OP_Integer, cnum, 2);
90879 assert( pTab->nCol>cnum );
90880 sqlite3VdbeAddOp4(v, OP_String8, 0, 3, 0, pTab->aCol[cnum].zName, 0);
90881 sqlite3VdbeAddOp2(v, OP_ResultRow, 1, 3);
90884 }else
90886 if( sqlite3StrICmp(zLeft, "index_list")==0 && zRight ){
90887 Index *pIdx;
90888 Table *pTab;
90889 if( sqlite3ReadSchema(pParse) ) goto pragma_out;
90890 pTab = sqlite3FindTable(db, zRight, zDb);
90891 if( pTab ){
90892 v = sqlite3GetVdbe(pParse);
90893 pIdx = pTab->pIndex;
90894 if( pIdx ){
90895 int i = 0;
90896 sqlite3VdbeSetNumCols(v, 3);
90897 pParse->nMem = 3;
90898 sqlite3VdbeSetColName(v, 0, COLNAME_NAME, "seq", SQLITE_STATIC);
90899 sqlite3VdbeSetColName(v, 1, COLNAME_NAME, "name", SQLITE_STATIC);
90900 sqlite3VdbeSetColName(v, 2, COLNAME_NAME, "unique", SQLITE_STATIC);
90901 while(pIdx){
90902 sqlite3VdbeAddOp2(v, OP_Integer, i, 1);
90903 sqlite3VdbeAddOp4(v, OP_String8, 0, 2, 0, pIdx->zName, 0);
90904 sqlite3VdbeAddOp2(v, OP_Integer, pIdx->onError!=OE_None, 3);
90905 sqlite3VdbeAddOp2(v, OP_ResultRow, 1, 3);
90906 ++i;
90907 pIdx = pIdx->pNext;
90911 }else
90913 if( sqlite3StrICmp(zLeft, "database_list")==0 ){
90914 int i;
90915 if( sqlite3ReadSchema(pParse) ) goto pragma_out;
90916 sqlite3VdbeSetNumCols(v, 3);
90917 pParse->nMem = 3;
90918 sqlite3VdbeSetColName(v, 0, COLNAME_NAME, "seq", SQLITE_STATIC);
90919 sqlite3VdbeSetColName(v, 1, COLNAME_NAME, "name", SQLITE_STATIC);
90920 sqlite3VdbeSetColName(v, 2, COLNAME_NAME, "file", SQLITE_STATIC);
90921 for(i=0; i<db->nDb; i++){
90922 if( db->aDb[i].pBt==0 ) continue;
90923 assert( db->aDb[i].zName!=0 );
90924 sqlite3VdbeAddOp2(v, OP_Integer, i, 1);
90925 sqlite3VdbeAddOp4(v, OP_String8, 0, 2, 0, db->aDb[i].zName, 0);
90926 sqlite3VdbeAddOp4(v, OP_String8, 0, 3, 0,
90927 sqlite3BtreeGetFilename(db->aDb[i].pBt), 0);
90928 sqlite3VdbeAddOp2(v, OP_ResultRow, 1, 3);
90930 }else
90932 if( sqlite3StrICmp(zLeft, "collation_list")==0 ){
90933 int i = 0;
90934 HashElem *p;
90935 sqlite3VdbeSetNumCols(v, 2);
90936 pParse->nMem = 2;
90937 sqlite3VdbeSetColName(v, 0, COLNAME_NAME, "seq", SQLITE_STATIC);
90938 sqlite3VdbeSetColName(v, 1, COLNAME_NAME, "name", SQLITE_STATIC);
90939 for(p=sqliteHashFirst(&db->aCollSeq); p; p=sqliteHashNext(p)){
90940 CollSeq *pColl = (CollSeq *)sqliteHashData(p);
90941 sqlite3VdbeAddOp2(v, OP_Integer, i++, 1);
90942 sqlite3VdbeAddOp4(v, OP_String8, 0, 2, 0, pColl->zName, 0);
90943 sqlite3VdbeAddOp2(v, OP_ResultRow, 1, 2);
90945 }else
90946 #endif /* SQLITE_OMIT_SCHEMA_PRAGMAS */
90948 #ifndef SQLITE_OMIT_FOREIGN_KEY
90949 if( sqlite3StrICmp(zLeft, "foreign_key_list")==0 && zRight ){
90950 FKey *pFK;
90951 Table *pTab;
90952 if( sqlite3ReadSchema(pParse) ) goto pragma_out;
90953 pTab = sqlite3FindTable(db, zRight, zDb);
90954 if( pTab ){
90955 v = sqlite3GetVdbe(pParse);
90956 pFK = pTab->pFKey;
90957 if( pFK ){
90958 int i = 0;
90959 sqlite3VdbeSetNumCols(v, 8);
90960 pParse->nMem = 8;
90961 sqlite3VdbeSetColName(v, 0, COLNAME_NAME, "id", SQLITE_STATIC);
90962 sqlite3VdbeSetColName(v, 1, COLNAME_NAME, "seq", SQLITE_STATIC);
90963 sqlite3VdbeSetColName(v, 2, COLNAME_NAME, "table", SQLITE_STATIC);
90964 sqlite3VdbeSetColName(v, 3, COLNAME_NAME, "from", SQLITE_STATIC);
90965 sqlite3VdbeSetColName(v, 4, COLNAME_NAME, "to", SQLITE_STATIC);
90966 sqlite3VdbeSetColName(v, 5, COLNAME_NAME, "on_update", SQLITE_STATIC);
90967 sqlite3VdbeSetColName(v, 6, COLNAME_NAME, "on_delete", SQLITE_STATIC);
90968 sqlite3VdbeSetColName(v, 7, COLNAME_NAME, "match", SQLITE_STATIC);
90969 while(pFK){
90970 int j;
90971 for(j=0; j<pFK->nCol; j++){
90972 char *zCol = pFK->aCol[j].zCol;
90973 char *zOnDelete = (char *)actionName(pFK->aAction[0]);
90974 char *zOnUpdate = (char *)actionName(pFK->aAction[1]);
90975 sqlite3VdbeAddOp2(v, OP_Integer, i, 1);
90976 sqlite3VdbeAddOp2(v, OP_Integer, j, 2);
90977 sqlite3VdbeAddOp4(v, OP_String8, 0, 3, 0, pFK->zTo, 0);
90978 sqlite3VdbeAddOp4(v, OP_String8, 0, 4, 0,
90979 pTab->aCol[pFK->aCol[j].iFrom].zName, 0);
90980 sqlite3VdbeAddOp4(v, zCol ? OP_String8 : OP_Null, 0, 5, 0, zCol, 0);
90981 sqlite3VdbeAddOp4(v, OP_String8, 0, 6, 0, zOnUpdate, 0);
90982 sqlite3VdbeAddOp4(v, OP_String8, 0, 7, 0, zOnDelete, 0);
90983 sqlite3VdbeAddOp4(v, OP_String8, 0, 8, 0, "NONE", 0);
90984 sqlite3VdbeAddOp2(v, OP_ResultRow, 1, 8);
90986 ++i;
90987 pFK = pFK->pNextFrom;
90991 }else
90992 #endif /* !defined(SQLITE_OMIT_FOREIGN_KEY) */
90994 #ifndef NDEBUG
90995 if( sqlite3StrICmp(zLeft, "parser_trace")==0 ){
90996 if( zRight ){
90997 if( sqlite3GetBoolean(zRight) ){
90998 sqlite3ParserTrace(stderr, "parser: ");
90999 }else{
91000 sqlite3ParserTrace(0, 0);
91003 }else
91004 #endif
91006 /* Reinstall the LIKE and GLOB functions. The variant of LIKE
91007 ** used will be case sensitive or not depending on the RHS.
91009 if( sqlite3StrICmp(zLeft, "case_sensitive_like")==0 ){
91010 if( zRight ){
91011 sqlite3RegisterLikeFunctions(db, sqlite3GetBoolean(zRight));
91013 }else
91015 #ifndef SQLITE_INTEGRITY_CHECK_ERROR_MAX
91016 # define SQLITE_INTEGRITY_CHECK_ERROR_MAX 100
91017 #endif
91019 #ifndef SQLITE_OMIT_INTEGRITY_CHECK
91020 /* Pragma "quick_check" is an experimental reduced version of
91021 ** integrity_check designed to detect most database corruption
91022 ** without most of the overhead of a full integrity-check.
91024 if( sqlite3StrICmp(zLeft, "integrity_check")==0
91025 || sqlite3StrICmp(zLeft, "quick_check")==0
91027 int i, j, addr, mxErr;
91029 /* Code that appears at the end of the integrity check. If no error
91030 ** messages have been generated, output OK. Otherwise output the
91031 ** error message
91033 static const VdbeOpList endCode[] = {
91034 { OP_AddImm, 1, 0, 0}, /* 0 */
91035 { OP_IfNeg, 1, 0, 0}, /* 1 */
91036 { OP_String8, 0, 3, 0}, /* 2 */
91037 { OP_ResultRow, 3, 1, 0},
91040 int isQuick = (zLeft[0]=='q');
91042 /* Initialize the VDBE program */
91043 if( sqlite3ReadSchema(pParse) ) goto pragma_out;
91044 pParse->nMem = 6;
91045 sqlite3VdbeSetNumCols(v, 1);
91046 sqlite3VdbeSetColName(v, 0, COLNAME_NAME, "integrity_check", SQLITE_STATIC);
91048 /* Set the maximum error count */
91049 mxErr = SQLITE_INTEGRITY_CHECK_ERROR_MAX;
91050 if( zRight ){
91051 sqlite3GetInt32(zRight, &mxErr);
91052 if( mxErr<=0 ){
91053 mxErr = SQLITE_INTEGRITY_CHECK_ERROR_MAX;
91056 sqlite3VdbeAddOp2(v, OP_Integer, mxErr, 1); /* reg[1] holds errors left */
91058 /* Do an integrity check on each database file */
91059 for(i=0; i<db->nDb; i++){
91060 HashElem *x;
91061 Hash *pTbls;
91062 int cnt = 0;
91064 if( OMIT_TEMPDB && i==1 ) continue;
91066 sqlite3CodeVerifySchema(pParse, i);
91067 addr = sqlite3VdbeAddOp1(v, OP_IfPos, 1); /* Halt if out of errors */
91068 sqlite3VdbeAddOp2(v, OP_Halt, 0, 0);
91069 sqlite3VdbeJumpHere(v, addr);
91071 /* Do an integrity check of the B-Tree
91073 ** Begin by filling registers 2, 3, ... with the root pages numbers
91074 ** for all tables and indices in the database.
91076 assert( sqlite3SchemaMutexHeld(db, iDb, 0) );
91077 pTbls = &db->aDb[i].pSchema->tblHash;
91078 for(x=sqliteHashFirst(pTbls); x; x=sqliteHashNext(x)){
91079 Table *pTab = sqliteHashData(x);
91080 Index *pIdx;
91081 sqlite3VdbeAddOp2(v, OP_Integer, pTab->tnum, 2+cnt);
91082 cnt++;
91083 for(pIdx=pTab->pIndex; pIdx; pIdx=pIdx->pNext){
91084 sqlite3VdbeAddOp2(v, OP_Integer, pIdx->tnum, 2+cnt);
91085 cnt++;
91089 /* Make sure sufficient number of registers have been allocated */
91090 if( pParse->nMem < cnt+4 ){
91091 pParse->nMem = cnt+4;
91094 /* Do the b-tree integrity checks */
91095 sqlite3VdbeAddOp3(v, OP_IntegrityCk, 2, cnt, 1);
91096 sqlite3VdbeChangeP5(v, (u8)i);
91097 addr = sqlite3VdbeAddOp1(v, OP_IsNull, 2);
91098 sqlite3VdbeAddOp4(v, OP_String8, 0, 3, 0,
91099 sqlite3MPrintf(db, "*** in database %s ***\n", db->aDb[i].zName),
91100 P4_DYNAMIC);
91101 sqlite3VdbeAddOp3(v, OP_Move, 2, 4, 1);
91102 sqlite3VdbeAddOp3(v, OP_Concat, 4, 3, 2);
91103 sqlite3VdbeAddOp2(v, OP_ResultRow, 2, 1);
91104 sqlite3VdbeJumpHere(v, addr);
91106 /* Make sure all the indices are constructed correctly.
91108 for(x=sqliteHashFirst(pTbls); x && !isQuick; x=sqliteHashNext(x)){
91109 Table *pTab = sqliteHashData(x);
91110 Index *pIdx;
91111 int loopTop;
91113 if( pTab->pIndex==0 ) continue;
91114 addr = sqlite3VdbeAddOp1(v, OP_IfPos, 1); /* Stop if out of errors */
91115 sqlite3VdbeAddOp2(v, OP_Halt, 0, 0);
91116 sqlite3VdbeJumpHere(v, addr);
91117 sqlite3OpenTableAndIndices(pParse, pTab, 1, OP_OpenRead);
91118 sqlite3VdbeAddOp2(v, OP_Integer, 0, 2); /* reg(2) will count entries */
91119 loopTop = sqlite3VdbeAddOp2(v, OP_Rewind, 1, 0);
91120 sqlite3VdbeAddOp2(v, OP_AddImm, 2, 1); /* increment entry count */
91121 for(j=0, pIdx=pTab->pIndex; pIdx; pIdx=pIdx->pNext, j++){
91122 int jmp2;
91123 int r1;
91124 static const VdbeOpList idxErr[] = {
91125 { OP_AddImm, 1, -1, 0},
91126 { OP_String8, 0, 3, 0}, /* 1 */
91127 { OP_Rowid, 1, 4, 0},
91128 { OP_String8, 0, 5, 0}, /* 3 */
91129 { OP_String8, 0, 6, 0}, /* 4 */
91130 { OP_Concat, 4, 3, 3},
91131 { OP_Concat, 5, 3, 3},
91132 { OP_Concat, 6, 3, 3},
91133 { OP_ResultRow, 3, 1, 0},
91134 { OP_IfPos, 1, 0, 0}, /* 9 */
91135 { OP_Halt, 0, 0, 0},
91137 r1 = sqlite3GenerateIndexKey(pParse, pIdx, 1, 3, 0);
91138 jmp2 = sqlite3VdbeAddOp4Int(v, OP_Found, j+2, 0, r1, pIdx->nColumn+1);
91139 addr = sqlite3VdbeAddOpList(v, ArraySize(idxErr), idxErr);
91140 sqlite3VdbeChangeP4(v, addr+1, "rowid ", P4_STATIC);
91141 sqlite3VdbeChangeP4(v, addr+3, " missing from index ", P4_STATIC);
91142 sqlite3VdbeChangeP4(v, addr+4, pIdx->zName, P4_TRANSIENT);
91143 sqlite3VdbeJumpHere(v, addr+9);
91144 sqlite3VdbeJumpHere(v, jmp2);
91146 sqlite3VdbeAddOp2(v, OP_Next, 1, loopTop+1);
91147 sqlite3VdbeJumpHere(v, loopTop);
91148 for(j=0, pIdx=pTab->pIndex; pIdx; pIdx=pIdx->pNext, j++){
91149 static const VdbeOpList cntIdx[] = {
91150 { OP_Integer, 0, 3, 0},
91151 { OP_Rewind, 0, 0, 0}, /* 1 */
91152 { OP_AddImm, 3, 1, 0},
91153 { OP_Next, 0, 0, 0}, /* 3 */
91154 { OP_Eq, 2, 0, 3}, /* 4 */
91155 { OP_AddImm, 1, -1, 0},
91156 { OP_String8, 0, 2, 0}, /* 6 */
91157 { OP_String8, 0, 3, 0}, /* 7 */
91158 { OP_Concat, 3, 2, 2},
91159 { OP_ResultRow, 2, 1, 0},
91161 addr = sqlite3VdbeAddOp1(v, OP_IfPos, 1);
91162 sqlite3VdbeAddOp2(v, OP_Halt, 0, 0);
91163 sqlite3VdbeJumpHere(v, addr);
91164 addr = sqlite3VdbeAddOpList(v, ArraySize(cntIdx), cntIdx);
91165 sqlite3VdbeChangeP1(v, addr+1, j+2);
91166 sqlite3VdbeChangeP2(v, addr+1, addr+4);
91167 sqlite3VdbeChangeP1(v, addr+3, j+2);
91168 sqlite3VdbeChangeP2(v, addr+3, addr+2);
91169 sqlite3VdbeJumpHere(v, addr+4);
91170 sqlite3VdbeChangeP4(v, addr+6,
91171 "wrong # of entries in index ", P4_STATIC);
91172 sqlite3VdbeChangeP4(v, addr+7, pIdx->zName, P4_TRANSIENT);
91176 addr = sqlite3VdbeAddOpList(v, ArraySize(endCode), endCode);
91177 sqlite3VdbeChangeP2(v, addr, -mxErr);
91178 sqlite3VdbeJumpHere(v, addr+1);
91179 sqlite3VdbeChangeP4(v, addr+2, "ok", P4_STATIC);
91180 }else
91181 #endif /* SQLITE_OMIT_INTEGRITY_CHECK */
91183 #ifndef SQLITE_OMIT_UTF16
91185 ** PRAGMA encoding
91186 ** PRAGMA encoding = "utf-8"|"utf-16"|"utf-16le"|"utf-16be"
91188 ** In its first form, this pragma returns the encoding of the main
91189 ** database. If the database is not initialized, it is initialized now.
91191 ** The second form of this pragma is a no-op if the main database file
91192 ** has not already been initialized. In this case it sets the default
91193 ** encoding that will be used for the main database file if a new file
91194 ** is created. If an existing main database file is opened, then the
91195 ** default text encoding for the existing database is used.
91197 ** In all cases new databases created using the ATTACH command are
91198 ** created to use the same default text encoding as the main database. If
91199 ** the main database has not been initialized and/or created when ATTACH
91200 ** is executed, this is done before the ATTACH operation.
91202 ** In the second form this pragma sets the text encoding to be used in
91203 ** new database files created using this database handle. It is only
91204 ** useful if invoked immediately after the main database i
91206 if( sqlite3StrICmp(zLeft, "encoding")==0 ){
91207 static const struct EncName {
91208 char *zName;
91209 u8 enc;
91210 } encnames[] = {
91211 { "UTF8", SQLITE_UTF8 },
91212 { "UTF-8", SQLITE_UTF8 }, /* Must be element [1] */
91213 { "UTF-16le", SQLITE_UTF16LE }, /* Must be element [2] */
91214 { "UTF-16be", SQLITE_UTF16BE }, /* Must be element [3] */
91215 { "UTF16le", SQLITE_UTF16LE },
91216 { "UTF16be", SQLITE_UTF16BE },
91217 { "UTF-16", 0 }, /* SQLITE_UTF16NATIVE */
91218 { "UTF16", 0 }, /* SQLITE_UTF16NATIVE */
91219 { 0, 0 }
91221 const struct EncName *pEnc;
91222 if( !zRight ){ /* "PRAGMA encoding" */
91223 if( sqlite3ReadSchema(pParse) ) goto pragma_out;
91224 sqlite3VdbeSetNumCols(v, 1);
91225 sqlite3VdbeSetColName(v, 0, COLNAME_NAME, "encoding", SQLITE_STATIC);
91226 sqlite3VdbeAddOp2(v, OP_String8, 0, 1);
91227 assert( encnames[SQLITE_UTF8].enc==SQLITE_UTF8 );
91228 assert( encnames[SQLITE_UTF16LE].enc==SQLITE_UTF16LE );
91229 assert( encnames[SQLITE_UTF16BE].enc==SQLITE_UTF16BE );
91230 sqlite3VdbeChangeP4(v, -1, encnames[ENC(pParse->db)].zName, P4_STATIC);
91231 sqlite3VdbeAddOp2(v, OP_ResultRow, 1, 1);
91232 }else{ /* "PRAGMA encoding = XXX" */
91233 /* Only change the value of sqlite.enc if the database handle is not
91234 ** initialized. If the main database exists, the new sqlite.enc value
91235 ** will be overwritten when the schema is next loaded. If it does not
91236 ** already exists, it will be created to use the new encoding value.
91238 if(
91239 !(DbHasProperty(db, 0, DB_SchemaLoaded)) ||
91240 DbHasProperty(db, 0, DB_Empty)
91242 for(pEnc=&encnames[0]; pEnc->zName; pEnc++){
91243 if( 0==sqlite3StrICmp(zRight, pEnc->zName) ){
91244 ENC(pParse->db) = pEnc->enc ? pEnc->enc : SQLITE_UTF16NATIVE;
91245 break;
91248 if( !pEnc->zName ){
91249 sqlite3ErrorMsg(pParse, "unsupported encoding: %s", zRight);
91253 }else
91254 #endif /* SQLITE_OMIT_UTF16 */
91256 #ifndef SQLITE_OMIT_SCHEMA_VERSION_PRAGMAS
91258 ** PRAGMA [database.]schema_version
91259 ** PRAGMA [database.]schema_version = <integer>
91261 ** PRAGMA [database.]user_version
91262 ** PRAGMA [database.]user_version = <integer>
91264 ** The pragma's schema_version and user_version are used to set or get
91265 ** the value of the schema-version and user-version, respectively. Both
91266 ** the schema-version and the user-version are 32-bit signed integers
91267 ** stored in the database header.
91269 ** The schema-cookie is usually only manipulated internally by SQLite. It
91270 ** is incremented by SQLite whenever the database schema is modified (by
91271 ** creating or dropping a table or index). The schema version is used by
91272 ** SQLite each time a query is executed to ensure that the internal cache
91273 ** of the schema used when compiling the SQL query matches the schema of
91274 ** the database against which the compiled query is actually executed.
91275 ** Subverting this mechanism by using "PRAGMA schema_version" to modify
91276 ** the schema-version is potentially dangerous and may lead to program
91277 ** crashes or database corruption. Use with caution!
91279 ** The user-version is not used internally by SQLite. It may be used by
91280 ** applications for any purpose.
91282 if( sqlite3StrICmp(zLeft, "schema_version")==0
91283 || sqlite3StrICmp(zLeft, "user_version")==0
91284 || sqlite3StrICmp(zLeft, "freelist_count")==0
91286 int iCookie; /* Cookie index. 1 for schema-cookie, 6 for user-cookie. */
91287 sqlite3VdbeUsesBtree(v, iDb);
91288 switch( zLeft[0] ){
91289 case 'f': case 'F':
91290 iCookie = BTREE_FREE_PAGE_COUNT;
91291 break;
91292 case 's': case 'S':
91293 iCookie = BTREE_SCHEMA_VERSION;
91294 break;
91295 default:
91296 iCookie = BTREE_USER_VERSION;
91297 break;
91300 if( zRight && iCookie!=BTREE_FREE_PAGE_COUNT ){
91301 /* Write the specified cookie value */
91302 static const VdbeOpList setCookie[] = {
91303 { OP_Transaction, 0, 1, 0}, /* 0 */
91304 { OP_Integer, 0, 1, 0}, /* 1 */
91305 { OP_SetCookie, 0, 0, 1}, /* 2 */
91307 int addr = sqlite3VdbeAddOpList(v, ArraySize(setCookie), setCookie);
91308 sqlite3VdbeChangeP1(v, addr, iDb);
91309 sqlite3VdbeChangeP1(v, addr+1, sqlite3Atoi(zRight));
91310 sqlite3VdbeChangeP1(v, addr+2, iDb);
91311 sqlite3VdbeChangeP2(v, addr+2, iCookie);
91312 }else{
91313 /* Read the specified cookie value */
91314 static const VdbeOpList readCookie[] = {
91315 { OP_Transaction, 0, 0, 0}, /* 0 */
91316 { OP_ReadCookie, 0, 1, 0}, /* 1 */
91317 { OP_ResultRow, 1, 1, 0}
91319 int addr = sqlite3VdbeAddOpList(v, ArraySize(readCookie), readCookie);
91320 sqlite3VdbeChangeP1(v, addr, iDb);
91321 sqlite3VdbeChangeP1(v, addr+1, iDb);
91322 sqlite3VdbeChangeP3(v, addr+1, iCookie);
91323 sqlite3VdbeSetNumCols(v, 1);
91324 sqlite3VdbeSetColName(v, 0, COLNAME_NAME, zLeft, SQLITE_TRANSIENT);
91326 }else
91327 #endif /* SQLITE_OMIT_SCHEMA_VERSION_PRAGMAS */
91329 #ifndef SQLITE_OMIT_COMPILEOPTION_DIAGS
91331 ** PRAGMA compile_options
91333 ** Return the names of all compile-time options used in this build,
91334 ** one option per row.
91336 if( sqlite3StrICmp(zLeft, "compile_options")==0 ){
91337 int i = 0;
91338 const char *zOpt;
91339 sqlite3VdbeSetNumCols(v, 1);
91340 pParse->nMem = 1;
91341 sqlite3VdbeSetColName(v, 0, COLNAME_NAME, "compile_option", SQLITE_STATIC);
91342 while( (zOpt = sqlite3_compileoption_get(i++))!=0 ){
91343 sqlite3VdbeAddOp4(v, OP_String8, 0, 1, 0, zOpt, 0);
91344 sqlite3VdbeAddOp2(v, OP_ResultRow, 1, 1);
91346 }else
91347 #endif /* SQLITE_OMIT_COMPILEOPTION_DIAGS */
91349 #ifndef SQLITE_OMIT_WAL
91351 ** PRAGMA [database.]wal_checkpoint = passive|full|restart
91353 ** Checkpoint the database.
91355 if( sqlite3StrICmp(zLeft, "wal_checkpoint")==0 ){
91356 int iBt = (pId2->z?iDb:SQLITE_MAX_ATTACHED);
91357 int eMode = SQLITE_CHECKPOINT_PASSIVE;
91358 if( zRight ){
91359 if( sqlite3StrICmp(zRight, "full")==0 ){
91360 eMode = SQLITE_CHECKPOINT_FULL;
91361 }else if( sqlite3StrICmp(zRight, "restart")==0 ){
91362 eMode = SQLITE_CHECKPOINT_RESTART;
91365 if( sqlite3ReadSchema(pParse) ) goto pragma_out;
91366 sqlite3VdbeSetNumCols(v, 3);
91367 pParse->nMem = 3;
91368 sqlite3VdbeSetColName(v, 0, COLNAME_NAME, "busy", SQLITE_STATIC);
91369 sqlite3VdbeSetColName(v, 1, COLNAME_NAME, "log", SQLITE_STATIC);
91370 sqlite3VdbeSetColName(v, 2, COLNAME_NAME, "checkpointed", SQLITE_STATIC);
91372 sqlite3VdbeAddOp3(v, OP_Checkpoint, iBt, eMode, 1);
91373 sqlite3VdbeAddOp2(v, OP_ResultRow, 1, 3);
91374 }else
91377 ** PRAGMA wal_autocheckpoint
91378 ** PRAGMA wal_autocheckpoint = N
91380 ** Configure a database connection to automatically checkpoint a database
91381 ** after accumulating N frames in the log. Or query for the current value
91382 ** of N.
91384 if( sqlite3StrICmp(zLeft, "wal_autocheckpoint")==0 ){
91385 if( zRight ){
91386 sqlite3_wal_autocheckpoint(db, sqlite3Atoi(zRight));
91388 returnSingleInt(pParse, "wal_autocheckpoint",
91389 db->xWalCallback==sqlite3WalDefaultHook ?
91390 SQLITE_PTR_TO_INT(db->pWalArg) : 0);
91391 }else
91392 #endif
91394 #if defined(SQLITE_DEBUG) || defined(SQLITE_TEST)
91396 ** Report the current state of file logs for all databases
91398 if( sqlite3StrICmp(zLeft, "lock_status")==0 ){
91399 static const char *const azLockName[] = {
91400 "unlocked", "shared", "reserved", "pending", "exclusive"
91402 int i;
91403 sqlite3VdbeSetNumCols(v, 2);
91404 pParse->nMem = 2;
91405 sqlite3VdbeSetColName(v, 0, COLNAME_NAME, "database", SQLITE_STATIC);
91406 sqlite3VdbeSetColName(v, 1, COLNAME_NAME, "status", SQLITE_STATIC);
91407 for(i=0; i<db->nDb; i++){
91408 Btree *pBt;
91409 Pager *pPager;
91410 const char *zState = "unknown";
91411 int j;
91412 if( db->aDb[i].zName==0 ) continue;
91413 sqlite3VdbeAddOp4(v, OP_String8, 0, 1, 0, db->aDb[i].zName, P4_STATIC);
91414 pBt = db->aDb[i].pBt;
91415 if( pBt==0 || (pPager = sqlite3BtreePager(pBt))==0 ){
91416 zState = "closed";
91417 }else if( sqlite3_file_control(db, i ? db->aDb[i].zName : 0,
91418 SQLITE_FCNTL_LOCKSTATE, &j)==SQLITE_OK ){
91419 zState = azLockName[j];
91421 sqlite3VdbeAddOp4(v, OP_String8, 0, 2, 0, zState, P4_STATIC);
91422 sqlite3VdbeAddOp2(v, OP_ResultRow, 1, 2);
91425 }else
91426 #endif
91428 #ifdef SQLITE_HAS_CODEC
91429 if( sqlite3StrICmp(zLeft, "key")==0 && zRight ){
91430 sqlite3_key(db, zRight, sqlite3Strlen30(zRight));
91431 }else
91432 if( sqlite3StrICmp(zLeft, "rekey")==0 && zRight ){
91433 sqlite3_rekey(db, zRight, sqlite3Strlen30(zRight));
91434 }else
91435 if( zRight && (sqlite3StrICmp(zLeft, "hexkey")==0 ||
91436 sqlite3StrICmp(zLeft, "hexrekey")==0) ){
91437 int i, h1, h2;
91438 char zKey[40];
91439 for(i=0; (h1 = zRight[i])!=0 && (h2 = zRight[i+1])!=0; i+=2){
91440 h1 += 9*(1&(h1>>6));
91441 h2 += 9*(1&(h2>>6));
91442 zKey[i/2] = (h2 & 0x0f) | ((h1 & 0xf)<<4);
91444 if( (zLeft[3] & 0xf)==0xb ){
91445 sqlite3_key(db, zKey, i/2);
91446 }else{
91447 sqlite3_rekey(db, zKey, i/2);
91449 }else
91450 #endif
91451 #if defined(SQLITE_HAS_CODEC) || defined(SQLITE_ENABLE_CEROD)
91452 if( sqlite3StrICmp(zLeft, "activate_extensions")==0 ){
91453 #ifdef SQLITE_HAS_CODEC
91454 if( sqlite3StrNICmp(zRight, "see-", 4)==0 ){
91455 sqlite3_activate_see(&zRight[4]);
91457 #endif
91458 #ifdef SQLITE_ENABLE_CEROD
91459 if( sqlite3StrNICmp(zRight, "cerod-", 6)==0 ){
91460 sqlite3_activate_cerod(&zRight[6]);
91462 #endif
91463 }else
91464 #endif
91467 {/* Empty ELSE clause */}
91470 ** Reset the safety level, in case the fullfsync flag or synchronous
91471 ** setting changed.
91473 #ifndef SQLITE_OMIT_PAGER_PRAGMAS
91474 if( db->autoCommit ){
91475 sqlite3BtreeSetSafetyLevel(pDb->pBt, pDb->safety_level,
91476 (db->flags&SQLITE_FullFSync)!=0,
91477 (db->flags&SQLITE_CkptFullFSync)!=0);
91479 #endif
91480 pragma_out:
91481 sqlite3DbFree(db, zLeft);
91482 sqlite3DbFree(db, zRight);
91485 #endif /* SQLITE_OMIT_PRAGMA */
91487 /************** End of pragma.c **********************************************/
91488 /************** Begin file prepare.c *****************************************/
91490 ** 2005 May 25
91492 ** The author disclaims copyright to this source code. In place of
91493 ** a legal notice, here is a blessing:
91495 ** May you do good and not evil.
91496 ** May you find forgiveness for yourself and forgive others.
91497 ** May you share freely, never taking more than you give.
91499 *************************************************************************
91500 ** This file contains the implementation of the sqlite3_prepare()
91501 ** interface, and routines that contribute to loading the database schema
91502 ** from disk.
91506 ** Fill the InitData structure with an error message that indicates
91507 ** that the database is corrupt.
91509 static void corruptSchema(
91510 InitData *pData, /* Initialization context */
91511 const char *zObj, /* Object being parsed at the point of error */
91512 const char *zExtra /* Error information */
91514 sqlite3 *db = pData->db;
91515 if( !db->mallocFailed && (db->flags & SQLITE_RecoveryMode)==0 ){
91516 if( zObj==0 ) zObj = "?";
91517 sqlite3SetString(pData->pzErrMsg, db,
91518 "malformed database schema (%s)", zObj);
91519 if( zExtra ){
91520 *pData->pzErrMsg = sqlite3MAppendf(db, *pData->pzErrMsg,
91521 "%s - %s", *pData->pzErrMsg, zExtra);
91524 pData->rc = db->mallocFailed ? SQLITE_NOMEM : SQLITE_CORRUPT_BKPT;
91528 ** This is the callback routine for the code that initializes the
91529 ** database. See sqlite3Init() below for additional information.
91530 ** This routine is also called from the OP_ParseSchema opcode of the VDBE.
91532 ** Each callback contains the following information:
91534 ** argv[0] = name of thing being created
91535 ** argv[1] = root page number for table or index. 0 for trigger or view.
91536 ** argv[2] = SQL text for the CREATE statement.
91539 SQLITE_PRIVATE int sqlite3InitCallback(void *pInit, int argc, char **argv, char **NotUsed){
91540 InitData *pData = (InitData*)pInit;
91541 sqlite3 *db = pData->db;
91542 int iDb = pData->iDb;
91544 assert( argc==3 );
91545 UNUSED_PARAMETER2(NotUsed, argc);
91546 assert( sqlite3_mutex_held(db->mutex) );
91547 DbClearProperty(db, iDb, DB_Empty);
91548 if( db->mallocFailed ){
91549 corruptSchema(pData, argv[0], 0);
91550 return 1;
91553 assert( iDb>=0 && iDb<db->nDb );
91554 if( argv==0 ) return 0; /* Might happen if EMPTY_RESULT_CALLBACKS are on */
91555 if( argv[1]==0 ){
91556 corruptSchema(pData, argv[0], 0);
91557 }else if( argv[2] && argv[2][0] ){
91558 /* Call the parser to process a CREATE TABLE, INDEX or VIEW.
91559 ** But because db->init.busy is set to 1, no VDBE code is generated
91560 ** or executed. All the parser does is build the internal data
91561 ** structures that describe the table, index, or view.
91563 int rc;
91564 sqlite3_stmt *pStmt;
91565 TESTONLY(int rcp); /* Return code from sqlite3_prepare() */
91567 assert( db->init.busy );
91568 db->init.iDb = iDb;
91569 db->init.newTnum = sqlite3Atoi(argv[1]);
91570 db->init.orphanTrigger = 0;
91571 TESTONLY(rcp = ) sqlite3_prepare(db, argv[2], -1, &pStmt, 0);
91572 rc = db->errCode;
91573 assert( (rc&0xFF)==(rcp&0xFF) );
91574 db->init.iDb = 0;
91575 if( SQLITE_OK!=rc ){
91576 if( db->init.orphanTrigger ){
91577 assert( iDb==1 );
91578 }else{
91579 pData->rc = rc;
91580 if( rc==SQLITE_NOMEM ){
91581 db->mallocFailed = 1;
91582 }else if( rc!=SQLITE_INTERRUPT && (rc&0xFF)!=SQLITE_LOCKED ){
91583 corruptSchema(pData, argv[0], sqlite3_errmsg(db));
91587 sqlite3_finalize(pStmt);
91588 }else if( argv[0]==0 ){
91589 corruptSchema(pData, 0, 0);
91590 }else{
91591 /* If the SQL column is blank it means this is an index that
91592 ** was created to be the PRIMARY KEY or to fulfill a UNIQUE
91593 ** constraint for a CREATE TABLE. The index should have already
91594 ** been created when we processed the CREATE TABLE. All we have
91595 ** to do here is record the root page number for that index.
91597 Index *pIndex;
91598 pIndex = sqlite3FindIndex(db, argv[0], db->aDb[iDb].zName);
91599 if( pIndex==0 ){
91600 /* This can occur if there exists an index on a TEMP table which
91601 ** has the same name as another index on a permanent index. Since
91602 ** the permanent table is hidden by the TEMP table, we can also
91603 ** safely ignore the index on the permanent table.
91605 /* Do Nothing */;
91606 }else if( sqlite3GetInt32(argv[1], &pIndex->tnum)==0 ){
91607 corruptSchema(pData, argv[0], "invalid rootpage");
91610 return 0;
91614 ** Attempt to read the database schema and initialize internal
91615 ** data structures for a single database file. The index of the
91616 ** database file is given by iDb. iDb==0 is used for the main
91617 ** database. iDb==1 should never be used. iDb>=2 is used for
91618 ** auxiliary databases. Return one of the SQLITE_ error codes to
91619 ** indicate success or failure.
91621 static int sqlite3InitOne(sqlite3 *db, int iDb, char **pzErrMsg){
91622 int rc;
91623 int i;
91624 int size;
91625 Table *pTab;
91626 Db *pDb;
91627 char const *azArg[4];
91628 int meta[5];
91629 InitData initData;
91630 char const *zMasterSchema;
91631 char const *zMasterName;
91632 int openedTransaction = 0;
91635 ** The master database table has a structure like this
91637 static const char master_schema[] =
91638 "CREATE TABLE sqlite_master(\n"
91639 " type text,\n"
91640 " name text,\n"
91641 " tbl_name text,\n"
91642 " rootpage integer,\n"
91643 " sql text\n"
91646 #ifndef SQLITE_OMIT_TEMPDB
91647 static const char temp_master_schema[] =
91648 "CREATE TEMP TABLE sqlite_temp_master(\n"
91649 " type text,\n"
91650 " name text,\n"
91651 " tbl_name text,\n"
91652 " rootpage integer,\n"
91653 " sql text\n"
91656 #else
91657 #define temp_master_schema 0
91658 #endif
91660 assert( iDb>=0 && iDb<db->nDb );
91661 assert( db->aDb[iDb].pSchema );
91662 assert( sqlite3_mutex_held(db->mutex) );
91663 assert( iDb==1 || sqlite3BtreeHoldsMutex(db->aDb[iDb].pBt) );
91665 /* zMasterSchema and zInitScript are set to point at the master schema
91666 ** and initialisation script appropriate for the database being
91667 ** initialised. zMasterName is the name of the master table.
91669 if( !OMIT_TEMPDB && iDb==1 ){
91670 zMasterSchema = temp_master_schema;
91671 }else{
91672 zMasterSchema = master_schema;
91674 zMasterName = SCHEMA_TABLE(iDb);
91676 /* Construct the schema tables. */
91677 azArg[0] = zMasterName;
91678 azArg[1] = "1";
91679 azArg[2] = zMasterSchema;
91680 azArg[3] = 0;
91681 initData.db = db;
91682 initData.iDb = iDb;
91683 initData.rc = SQLITE_OK;
91684 initData.pzErrMsg = pzErrMsg;
91685 sqlite3InitCallback(&initData, 3, (char **)azArg, 0);
91686 if( initData.rc ){
91687 rc = initData.rc;
91688 goto error_out;
91690 pTab = sqlite3FindTable(db, zMasterName, db->aDb[iDb].zName);
91691 if( ALWAYS(pTab) ){
91692 pTab->tabFlags |= TF_Readonly;
91695 /* Create a cursor to hold the database open
91697 pDb = &db->aDb[iDb];
91698 if( pDb->pBt==0 ){
91699 if( !OMIT_TEMPDB && ALWAYS(iDb==1) ){
91700 DbSetProperty(db, 1, DB_SchemaLoaded);
91702 return SQLITE_OK;
91705 /* If there is not already a read-only (or read-write) transaction opened
91706 ** on the b-tree database, open one now. If a transaction is opened, it
91707 ** will be closed before this function returns. */
91708 sqlite3BtreeEnter(pDb->pBt);
91709 if( !sqlite3BtreeIsInReadTrans(pDb->pBt) ){
91710 rc = sqlite3BtreeBeginTrans(pDb->pBt, 0);
91711 if( rc!=SQLITE_OK ){
91712 sqlite3SetString(pzErrMsg, db, "%s", sqlite3ErrStr(rc));
91713 goto initone_error_out;
91715 openedTransaction = 1;
91718 /* Get the database meta information.
91720 ** Meta values are as follows:
91721 ** meta[0] Schema cookie. Changes with each schema change.
91722 ** meta[1] File format of schema layer.
91723 ** meta[2] Size of the page cache.
91724 ** meta[3] Largest rootpage (auto/incr_vacuum mode)
91725 ** meta[4] Db text encoding. 1:UTF-8 2:UTF-16LE 3:UTF-16BE
91726 ** meta[5] User version
91727 ** meta[6] Incremental vacuum mode
91728 ** meta[7] unused
91729 ** meta[8] unused
91730 ** meta[9] unused
91732 ** Note: The #defined SQLITE_UTF* symbols in sqliteInt.h correspond to
91733 ** the possible values of meta[4].
91735 for(i=0; i<ArraySize(meta); i++){
91736 sqlite3BtreeGetMeta(pDb->pBt, i+1, (u32 *)&meta[i]);
91738 pDb->pSchema->schema_cookie = meta[BTREE_SCHEMA_VERSION-1];
91740 /* If opening a non-empty database, check the text encoding. For the
91741 ** main database, set sqlite3.enc to the encoding of the main database.
91742 ** For an attached db, it is an error if the encoding is not the same
91743 ** as sqlite3.enc.
91745 if( meta[BTREE_TEXT_ENCODING-1] ){ /* text encoding */
91746 if( iDb==0 ){
91747 u8 encoding;
91748 /* If opening the main database, set ENC(db). */
91749 encoding = (u8)meta[BTREE_TEXT_ENCODING-1] & 3;
91750 if( encoding==0 ) encoding = SQLITE_UTF8;
91751 ENC(db) = encoding;
91752 db->pDfltColl = sqlite3FindCollSeq(db, SQLITE_UTF8, "BINARY", 0);
91753 }else{
91754 /* If opening an attached database, the encoding much match ENC(db) */
91755 if( meta[BTREE_TEXT_ENCODING-1]!=ENC(db) ){
91756 sqlite3SetString(pzErrMsg, db, "attached databases must use the same"
91757 " text encoding as main database");
91758 rc = SQLITE_ERROR;
91759 goto initone_error_out;
91762 }else{
91763 DbSetProperty(db, iDb, DB_Empty);
91765 pDb->pSchema->enc = ENC(db);
91767 if( pDb->pSchema->cache_size==0 ){
91768 size = sqlite3AbsInt32(meta[BTREE_DEFAULT_CACHE_SIZE-1]);
91769 if( size==0 ){ size = SQLITE_DEFAULT_CACHE_SIZE; }
91770 pDb->pSchema->cache_size = size;
91771 sqlite3BtreeSetCacheSize(pDb->pBt, pDb->pSchema->cache_size);
91775 ** file_format==1 Version 3.0.0.
91776 ** file_format==2 Version 3.1.3. // ALTER TABLE ADD COLUMN
91777 ** file_format==3 Version 3.1.4. // ditto but with non-NULL defaults
91778 ** file_format==4 Version 3.3.0. // DESC indices. Boolean constants
91780 pDb->pSchema->file_format = (u8)meta[BTREE_FILE_FORMAT-1];
91781 if( pDb->pSchema->file_format==0 ){
91782 pDb->pSchema->file_format = 1;
91784 if( pDb->pSchema->file_format>SQLITE_MAX_FILE_FORMAT ){
91785 sqlite3SetString(pzErrMsg, db, "unsupported file format");
91786 rc = SQLITE_ERROR;
91787 goto initone_error_out;
91790 /* Ticket #2804: When we open a database in the newer file format,
91791 ** clear the legacy_file_format pragma flag so that a VACUUM will
91792 ** not downgrade the database and thus invalidate any descending
91793 ** indices that the user might have created.
91795 if( iDb==0 && meta[BTREE_FILE_FORMAT-1]>=4 ){
91796 db->flags &= ~SQLITE_LegacyFileFmt;
91799 /* Read the schema information out of the schema tables
91801 assert( db->init.busy );
91803 char *zSql;
91804 zSql = sqlite3MPrintf(db,
91805 "SELECT name, rootpage, sql FROM '%q'.%s ORDER BY rowid",
91806 db->aDb[iDb].zName, zMasterName);
91807 #ifndef SQLITE_OMIT_AUTHORIZATION
91809 int (*xAuth)(void*,int,const char*,const char*,const char*,const char*);
91810 xAuth = db->xAuth;
91811 db->xAuth = 0;
91812 #endif
91813 rc = sqlite3_exec(db, zSql, sqlite3InitCallback, &initData, 0);
91814 #ifndef SQLITE_OMIT_AUTHORIZATION
91815 db->xAuth = xAuth;
91817 #endif
91818 if( rc==SQLITE_OK ) rc = initData.rc;
91819 sqlite3DbFree(db, zSql);
91820 #ifndef SQLITE_OMIT_ANALYZE
91821 if( rc==SQLITE_OK ){
91822 sqlite3AnalysisLoad(db, iDb);
91824 #endif
91826 if( db->mallocFailed ){
91827 rc = SQLITE_NOMEM;
91828 sqlite3ResetInternalSchema(db, -1);
91830 if( rc==SQLITE_OK || (db->flags&SQLITE_RecoveryMode)){
91831 /* Black magic: If the SQLITE_RecoveryMode flag is set, then consider
91832 ** the schema loaded, even if errors occurred. In this situation the
91833 ** current sqlite3_prepare() operation will fail, but the following one
91834 ** will attempt to compile the supplied statement against whatever subset
91835 ** of the schema was loaded before the error occurred. The primary
91836 ** purpose of this is to allow access to the sqlite_master table
91837 ** even when its contents have been corrupted.
91839 DbSetProperty(db, iDb, DB_SchemaLoaded);
91840 rc = SQLITE_OK;
91843 /* Jump here for an error that occurs after successfully allocating
91844 ** curMain and calling sqlite3BtreeEnter(). For an error that occurs
91845 ** before that point, jump to error_out.
91847 initone_error_out:
91848 if( openedTransaction ){
91849 sqlite3BtreeCommit(pDb->pBt);
91851 sqlite3BtreeLeave(pDb->pBt);
91853 error_out:
91854 if( rc==SQLITE_NOMEM || rc==SQLITE_IOERR_NOMEM ){
91855 db->mallocFailed = 1;
91857 return rc;
91861 ** Initialize all database files - the main database file, the file
91862 ** used to store temporary tables, and any additional database files
91863 ** created using ATTACH statements. Return a success code. If an
91864 ** error occurs, write an error message into *pzErrMsg.
91866 ** After a database is initialized, the DB_SchemaLoaded bit is set
91867 ** bit is set in the flags field of the Db structure. If the database
91868 ** file was of zero-length, then the DB_Empty flag is also set.
91870 SQLITE_PRIVATE int sqlite3Init(sqlite3 *db, char **pzErrMsg){
91871 int i, rc;
91872 int commit_internal = !(db->flags&SQLITE_InternChanges);
91874 assert( sqlite3_mutex_held(db->mutex) );
91875 rc = SQLITE_OK;
91876 db->init.busy = 1;
91877 for(i=0; rc==SQLITE_OK && i<db->nDb; i++){
91878 if( DbHasProperty(db, i, DB_SchemaLoaded) || i==1 ) continue;
91879 rc = sqlite3InitOne(db, i, pzErrMsg);
91880 if( rc ){
91881 sqlite3ResetInternalSchema(db, i);
91885 /* Once all the other databases have been initialised, load the schema
91886 ** for the TEMP database. This is loaded last, as the TEMP database
91887 ** schema may contain references to objects in other databases.
91889 #ifndef SQLITE_OMIT_TEMPDB
91890 if( rc==SQLITE_OK && ALWAYS(db->nDb>1)
91891 && !DbHasProperty(db, 1, DB_SchemaLoaded) ){
91892 rc = sqlite3InitOne(db, 1, pzErrMsg);
91893 if( rc ){
91894 sqlite3ResetInternalSchema(db, 1);
91897 #endif
91899 db->init.busy = 0;
91900 if( rc==SQLITE_OK && commit_internal ){
91901 sqlite3CommitInternalChanges(db);
91904 return rc;
91908 ** This routine is a no-op if the database schema is already initialised.
91909 ** Otherwise, the schema is loaded. An error code is returned.
91911 SQLITE_PRIVATE int sqlite3ReadSchema(Parse *pParse){
91912 int rc = SQLITE_OK;
91913 sqlite3 *db = pParse->db;
91914 assert( sqlite3_mutex_held(db->mutex) );
91915 if( !db->init.busy ){
91916 rc = sqlite3Init(db, &pParse->zErrMsg);
91918 if( rc!=SQLITE_OK ){
91919 pParse->rc = rc;
91920 pParse->nErr++;
91922 return rc;
91927 ** Check schema cookies in all databases. If any cookie is out
91928 ** of date set pParse->rc to SQLITE_SCHEMA. If all schema cookies
91929 ** make no changes to pParse->rc.
91931 static void schemaIsValid(Parse *pParse){
91932 sqlite3 *db = pParse->db;
91933 int iDb;
91934 int rc;
91935 int cookie;
91937 assert( pParse->checkSchema );
91938 assert( sqlite3_mutex_held(db->mutex) );
91939 for(iDb=0; iDb<db->nDb; iDb++){
91940 int openedTransaction = 0; /* True if a transaction is opened */
91941 Btree *pBt = db->aDb[iDb].pBt; /* Btree database to read cookie from */
91942 if( pBt==0 ) continue;
91944 /* If there is not already a read-only (or read-write) transaction opened
91945 ** on the b-tree database, open one now. If a transaction is opened, it
91946 ** will be closed immediately after reading the meta-value. */
91947 if( !sqlite3BtreeIsInReadTrans(pBt) ){
91948 rc = sqlite3BtreeBeginTrans(pBt, 0);
91949 if( rc==SQLITE_NOMEM || rc==SQLITE_IOERR_NOMEM ){
91950 db->mallocFailed = 1;
91952 if( rc!=SQLITE_OK ) return;
91953 openedTransaction = 1;
91956 /* Read the schema cookie from the database. If it does not match the
91957 ** value stored as part of the in-memory schema representation,
91958 ** set Parse.rc to SQLITE_SCHEMA. */
91959 sqlite3BtreeGetMeta(pBt, BTREE_SCHEMA_VERSION, (u32 *)&cookie);
91960 assert( sqlite3SchemaMutexHeld(db, iDb, 0) );
91961 if( cookie!=db->aDb[iDb].pSchema->schema_cookie ){
91962 sqlite3ResetInternalSchema(db, iDb);
91963 pParse->rc = SQLITE_SCHEMA;
91966 /* Close the transaction, if one was opened. */
91967 if( openedTransaction ){
91968 sqlite3BtreeCommit(pBt);
91974 ** Convert a schema pointer into the iDb index that indicates
91975 ** which database file in db->aDb[] the schema refers to.
91977 ** If the same database is attached more than once, the first
91978 ** attached database is returned.
91980 SQLITE_PRIVATE int sqlite3SchemaToIndex(sqlite3 *db, Schema *pSchema){
91981 int i = -1000000;
91983 /* If pSchema is NULL, then return -1000000. This happens when code in
91984 ** expr.c is trying to resolve a reference to a transient table (i.e. one
91985 ** created by a sub-select). In this case the return value of this
91986 ** function should never be used.
91988 ** We return -1000000 instead of the more usual -1 simply because using
91989 ** -1000000 as the incorrect index into db->aDb[] is much
91990 ** more likely to cause a segfault than -1 (of course there are assert()
91991 ** statements too, but it never hurts to play the odds).
91993 assert( sqlite3_mutex_held(db->mutex) );
91994 if( pSchema ){
91995 for(i=0; ALWAYS(i<db->nDb); i++){
91996 if( db->aDb[i].pSchema==pSchema ){
91997 break;
92000 assert( i>=0 && i<db->nDb );
92002 return i;
92006 ** Compile the UTF-8 encoded SQL statement zSql into a statement handle.
92008 static int sqlite3Prepare(
92009 sqlite3 *db, /* Database handle. */
92010 const char *zSql, /* UTF-8 encoded SQL statement. */
92011 int nBytes, /* Length of zSql in bytes. */
92012 int saveSqlFlag, /* True to copy SQL text into the sqlite3_stmt */
92013 Vdbe *pReprepare, /* VM being reprepared */
92014 sqlite3_stmt **ppStmt, /* OUT: A pointer to the prepared statement */
92015 const char **pzTail /* OUT: End of parsed string */
92017 Parse *pParse; /* Parsing context */
92018 char *zErrMsg = 0; /* Error message */
92019 int rc = SQLITE_OK; /* Result code */
92020 int i; /* Loop counter */
92022 /* Allocate the parsing context */
92023 pParse = sqlite3StackAllocZero(db, sizeof(*pParse));
92024 if( pParse==0 ){
92025 rc = SQLITE_NOMEM;
92026 goto end_prepare;
92028 pParse->pReprepare = pReprepare;
92029 assert( ppStmt && *ppStmt==0 );
92030 assert( !db->mallocFailed );
92031 assert( sqlite3_mutex_held(db->mutex) );
92033 /* Check to verify that it is possible to get a read lock on all
92034 ** database schemas. The inability to get a read lock indicates that
92035 ** some other database connection is holding a write-lock, which in
92036 ** turn means that the other connection has made uncommitted changes
92037 ** to the schema.
92039 ** Were we to proceed and prepare the statement against the uncommitted
92040 ** schema changes and if those schema changes are subsequently rolled
92041 ** back and different changes are made in their place, then when this
92042 ** prepared statement goes to run the schema cookie would fail to detect
92043 ** the schema change. Disaster would follow.
92045 ** This thread is currently holding mutexes on all Btrees (because
92046 ** of the sqlite3BtreeEnterAll() in sqlite3LockAndPrepare()) so it
92047 ** is not possible for another thread to start a new schema change
92048 ** while this routine is running. Hence, we do not need to hold
92049 ** locks on the schema, we just need to make sure nobody else is
92050 ** holding them.
92052 ** Note that setting READ_UNCOMMITTED overrides most lock detection,
92053 ** but it does *not* override schema lock detection, so this all still
92054 ** works even if READ_UNCOMMITTED is set.
92056 for(i=0; i<db->nDb; i++) {
92057 Btree *pBt = db->aDb[i].pBt;
92058 if( pBt ){
92059 assert( sqlite3BtreeHoldsMutex(pBt) );
92060 rc = sqlite3BtreeSchemaLocked(pBt);
92061 if( rc ){
92062 const char *zDb = db->aDb[i].zName;
92063 sqlite3Error(db, rc, "database schema is locked: %s", zDb);
92064 testcase( db->flags & SQLITE_ReadUncommitted );
92065 goto end_prepare;
92070 sqlite3VtabUnlockList(db);
92072 pParse->db = db;
92073 pParse->nQueryLoop = (double)1;
92074 if( nBytes>=0 && (nBytes==0 || zSql[nBytes-1]!=0) ){
92075 char *zSqlCopy;
92076 int mxLen = db->aLimit[SQLITE_LIMIT_SQL_LENGTH];
92077 testcase( nBytes==mxLen );
92078 testcase( nBytes==mxLen+1 );
92079 if( nBytes>mxLen ){
92080 sqlite3Error(db, SQLITE_TOOBIG, "statement too long");
92081 rc = sqlite3ApiExit(db, SQLITE_TOOBIG);
92082 goto end_prepare;
92084 zSqlCopy = sqlite3DbStrNDup(db, zSql, nBytes);
92085 if( zSqlCopy ){
92086 sqlite3RunParser(pParse, zSqlCopy, &zErrMsg);
92087 sqlite3DbFree(db, zSqlCopy);
92088 pParse->zTail = &zSql[pParse->zTail-zSqlCopy];
92089 }else{
92090 pParse->zTail = &zSql[nBytes];
92092 }else{
92093 sqlite3RunParser(pParse, zSql, &zErrMsg);
92095 assert( 1==(int)pParse->nQueryLoop );
92097 if( db->mallocFailed ){
92098 pParse->rc = SQLITE_NOMEM;
92100 if( pParse->rc==SQLITE_DONE ) pParse->rc = SQLITE_OK;
92101 if( pParse->checkSchema ){
92102 schemaIsValid(pParse);
92104 if( db->mallocFailed ){
92105 pParse->rc = SQLITE_NOMEM;
92107 if( pzTail ){
92108 *pzTail = pParse->zTail;
92110 rc = pParse->rc;
92112 #ifndef SQLITE_OMIT_EXPLAIN
92113 if( rc==SQLITE_OK && pParse->pVdbe && pParse->explain ){
92114 static const char * const azColName[] = {
92115 "addr", "opcode", "p1", "p2", "p3", "p4", "p5", "comment",
92116 "selectid", "order", "from", "detail"
92118 int iFirst, mx;
92119 if( pParse->explain==2 ){
92120 sqlite3VdbeSetNumCols(pParse->pVdbe, 4);
92121 iFirst = 8;
92122 mx = 12;
92123 }else{
92124 sqlite3VdbeSetNumCols(pParse->pVdbe, 8);
92125 iFirst = 0;
92126 mx = 8;
92128 for(i=iFirst; i<mx; i++){
92129 sqlite3VdbeSetColName(pParse->pVdbe, i-iFirst, COLNAME_NAME,
92130 azColName[i], SQLITE_STATIC);
92133 #endif
92135 assert( db->init.busy==0 || saveSqlFlag==0 );
92136 if( db->init.busy==0 ){
92137 Vdbe *pVdbe = pParse->pVdbe;
92138 sqlite3VdbeSetSql(pVdbe, zSql, (int)(pParse->zTail-zSql), saveSqlFlag);
92140 if( pParse->pVdbe && (rc!=SQLITE_OK || db->mallocFailed) ){
92141 sqlite3VdbeFinalize(pParse->pVdbe);
92142 assert(!(*ppStmt));
92143 }else{
92144 *ppStmt = (sqlite3_stmt*)pParse->pVdbe;
92147 if( zErrMsg ){
92148 sqlite3Error(db, rc, "%s", zErrMsg);
92149 sqlite3DbFree(db, zErrMsg);
92150 }else{
92151 sqlite3Error(db, rc, 0);
92154 /* Delete any TriggerPrg structures allocated while parsing this statement. */
92155 while( pParse->pTriggerPrg ){
92156 TriggerPrg *pT = pParse->pTriggerPrg;
92157 pParse->pTriggerPrg = pT->pNext;
92158 sqlite3DbFree(db, pT);
92161 end_prepare:
92163 sqlite3StackFree(db, pParse);
92164 rc = sqlite3ApiExit(db, rc);
92165 assert( (rc&db->errMask)==rc );
92166 return rc;
92168 static int sqlite3LockAndPrepare(
92169 sqlite3 *db, /* Database handle. */
92170 const char *zSql, /* UTF-8 encoded SQL statement. */
92171 int nBytes, /* Length of zSql in bytes. */
92172 int saveSqlFlag, /* True to copy SQL text into the sqlite3_stmt */
92173 Vdbe *pOld, /* VM being reprepared */
92174 sqlite3_stmt **ppStmt, /* OUT: A pointer to the prepared statement */
92175 const char **pzTail /* OUT: End of parsed string */
92177 int rc;
92178 assert( ppStmt!=0 );
92179 *ppStmt = 0;
92180 if( !sqlite3SafetyCheckOk(db) ){
92181 return SQLITE_MISUSE_BKPT;
92183 sqlite3_mutex_enter(db->mutex);
92184 sqlite3BtreeEnterAll(db);
92185 rc = sqlite3Prepare(db, zSql, nBytes, saveSqlFlag, pOld, ppStmt, pzTail);
92186 if( rc==SQLITE_SCHEMA ){
92187 sqlite3_finalize(*ppStmt);
92188 rc = sqlite3Prepare(db, zSql, nBytes, saveSqlFlag, pOld, ppStmt, pzTail);
92190 sqlite3BtreeLeaveAll(db);
92191 sqlite3_mutex_leave(db->mutex);
92192 return rc;
92196 ** Rerun the compilation of a statement after a schema change.
92198 ** If the statement is successfully recompiled, return SQLITE_OK. Otherwise,
92199 ** if the statement cannot be recompiled because another connection has
92200 ** locked the sqlite3_master table, return SQLITE_LOCKED. If any other error
92201 ** occurs, return SQLITE_SCHEMA.
92203 SQLITE_PRIVATE int sqlite3Reprepare(Vdbe *p){
92204 int rc;
92205 sqlite3_stmt *pNew;
92206 const char *zSql;
92207 sqlite3 *db;
92209 assert( sqlite3_mutex_held(sqlite3VdbeDb(p)->mutex) );
92210 zSql = sqlite3_sql((sqlite3_stmt *)p);
92211 assert( zSql!=0 ); /* Reprepare only called for prepare_v2() statements */
92212 db = sqlite3VdbeDb(p);
92213 assert( sqlite3_mutex_held(db->mutex) );
92214 rc = sqlite3LockAndPrepare(db, zSql, -1, 0, p, &pNew, 0);
92215 if( rc ){
92216 if( rc==SQLITE_NOMEM ){
92217 db->mallocFailed = 1;
92219 assert( pNew==0 );
92220 return rc;
92221 }else{
92222 assert( pNew!=0 );
92224 sqlite3VdbeSwap((Vdbe*)pNew, p);
92225 sqlite3TransferBindings(pNew, (sqlite3_stmt*)p);
92226 sqlite3VdbeResetStepResult((Vdbe*)pNew);
92227 sqlite3VdbeFinalize((Vdbe*)pNew);
92228 return SQLITE_OK;
92233 ** Two versions of the official API. Legacy and new use. In the legacy
92234 ** version, the original SQL text is not saved in the prepared statement
92235 ** and so if a schema change occurs, SQLITE_SCHEMA is returned by
92236 ** sqlite3_step(). In the new version, the original SQL text is retained
92237 ** and the statement is automatically recompiled if an schema change
92238 ** occurs.
92240 SQLITE_API int sqlite3_prepare(
92241 sqlite3 *db, /* Database handle. */
92242 const char *zSql, /* UTF-8 encoded SQL statement. */
92243 int nBytes, /* Length of zSql in bytes. */
92244 sqlite3_stmt **ppStmt, /* OUT: A pointer to the prepared statement */
92245 const char **pzTail /* OUT: End of parsed string */
92247 int rc;
92248 rc = sqlite3LockAndPrepare(db,zSql,nBytes,0,0,ppStmt,pzTail);
92249 assert( rc==SQLITE_OK || ppStmt==0 || *ppStmt==0 ); /* VERIFY: F13021 */
92250 return rc;
92252 SQLITE_API int sqlite3_prepare_v2(
92253 sqlite3 *db, /* Database handle. */
92254 const char *zSql, /* UTF-8 encoded SQL statement. */
92255 int nBytes, /* Length of zSql in bytes. */
92256 sqlite3_stmt **ppStmt, /* OUT: A pointer to the prepared statement */
92257 const char **pzTail /* OUT: End of parsed string */
92259 int rc;
92260 rc = sqlite3LockAndPrepare(db,zSql,nBytes,1,0,ppStmt,pzTail);
92261 assert( rc==SQLITE_OK || ppStmt==0 || *ppStmt==0 ); /* VERIFY: F13021 */
92262 return rc;
92266 #ifndef SQLITE_OMIT_UTF16
92268 ** Compile the UTF-16 encoded SQL statement zSql into a statement handle.
92270 static int sqlite3Prepare16(
92271 sqlite3 *db, /* Database handle. */
92272 const void *zSql, /* UTF-16 encoded SQL statement. */
92273 int nBytes, /* Length of zSql in bytes. */
92274 int saveSqlFlag, /* True to save SQL text into the sqlite3_stmt */
92275 sqlite3_stmt **ppStmt, /* OUT: A pointer to the prepared statement */
92276 const void **pzTail /* OUT: End of parsed string */
92278 /* This function currently works by first transforming the UTF-16
92279 ** encoded string to UTF-8, then invoking sqlite3_prepare(). The
92280 ** tricky bit is figuring out the pointer to return in *pzTail.
92282 char *zSql8;
92283 const char *zTail8 = 0;
92284 int rc = SQLITE_OK;
92286 assert( ppStmt );
92287 *ppStmt = 0;
92288 if( !sqlite3SafetyCheckOk(db) ){
92289 return SQLITE_MISUSE_BKPT;
92291 sqlite3_mutex_enter(db->mutex);
92292 zSql8 = sqlite3Utf16to8(db, zSql, nBytes, SQLITE_UTF16NATIVE);
92293 if( zSql8 ){
92294 rc = sqlite3LockAndPrepare(db, zSql8, -1, saveSqlFlag, 0, ppStmt, &zTail8);
92297 if( zTail8 && pzTail ){
92298 /* If sqlite3_prepare returns a tail pointer, we calculate the
92299 ** equivalent pointer into the UTF-16 string by counting the unicode
92300 ** characters between zSql8 and zTail8, and then returning a pointer
92301 ** the same number of characters into the UTF-16 string.
92303 int chars_parsed = sqlite3Utf8CharLen(zSql8, (int)(zTail8-zSql8));
92304 *pzTail = (u8 *)zSql + sqlite3Utf16ByteLen(zSql, chars_parsed);
92306 sqlite3DbFree(db, zSql8);
92307 rc = sqlite3ApiExit(db, rc);
92308 sqlite3_mutex_leave(db->mutex);
92309 return rc;
92313 ** Two versions of the official API. Legacy and new use. In the legacy
92314 ** version, the original SQL text is not saved in the prepared statement
92315 ** and so if a schema change occurs, SQLITE_SCHEMA is returned by
92316 ** sqlite3_step(). In the new version, the original SQL text is retained
92317 ** and the statement is automatically recompiled if an schema change
92318 ** occurs.
92320 SQLITE_API int sqlite3_prepare16(
92321 sqlite3 *db, /* Database handle. */
92322 const void *zSql, /* UTF-16 encoded SQL statement. */
92323 int nBytes, /* Length of zSql in bytes. */
92324 sqlite3_stmt **ppStmt, /* OUT: A pointer to the prepared statement */
92325 const void **pzTail /* OUT: End of parsed string */
92327 int rc;
92328 rc = sqlite3Prepare16(db,zSql,nBytes,0,ppStmt,pzTail);
92329 assert( rc==SQLITE_OK || ppStmt==0 || *ppStmt==0 ); /* VERIFY: F13021 */
92330 return rc;
92332 SQLITE_API int sqlite3_prepare16_v2(
92333 sqlite3 *db, /* Database handle. */
92334 const void *zSql, /* UTF-16 encoded SQL statement. */
92335 int nBytes, /* Length of zSql in bytes. */
92336 sqlite3_stmt **ppStmt, /* OUT: A pointer to the prepared statement */
92337 const void **pzTail /* OUT: End of parsed string */
92339 int rc;
92340 rc = sqlite3Prepare16(db,zSql,nBytes,1,ppStmt,pzTail);
92341 assert( rc==SQLITE_OK || ppStmt==0 || *ppStmt==0 ); /* VERIFY: F13021 */
92342 return rc;
92345 #endif /* SQLITE_OMIT_UTF16 */
92347 /************** End of prepare.c *********************************************/
92348 /************** Begin file select.c ******************************************/
92350 ** 2001 September 15
92352 ** The author disclaims copyright to this source code. In place of
92353 ** a legal notice, here is a blessing:
92355 ** May you do good and not evil.
92356 ** May you find forgiveness for yourself and forgive others.
92357 ** May you share freely, never taking more than you give.
92359 *************************************************************************
92360 ** This file contains C code routines that are called by the parser
92361 ** to handle SELECT statements in SQLite.
92366 ** Delete all the content of a Select structure but do not deallocate
92367 ** the select structure itself.
92369 static void clearSelect(sqlite3 *db, Select *p){
92370 sqlite3ExprListDelete(db, p->pEList);
92371 sqlite3SrcListDelete(db, p->pSrc);
92372 sqlite3ExprDelete(db, p->pWhere);
92373 sqlite3ExprListDelete(db, p->pGroupBy);
92374 sqlite3ExprDelete(db, p->pHaving);
92375 sqlite3ExprListDelete(db, p->pOrderBy);
92376 sqlite3SelectDelete(db, p->pPrior);
92377 sqlite3ExprDelete(db, p->pLimit);
92378 sqlite3ExprDelete(db, p->pOffset);
92382 ** Initialize a SelectDest structure.
92384 SQLITE_PRIVATE void sqlite3SelectDestInit(SelectDest *pDest, int eDest, int iParm){
92385 pDest->eDest = (u8)eDest;
92386 pDest->iParm = iParm;
92387 pDest->affinity = 0;
92388 pDest->iMem = 0;
92389 pDest->nMem = 0;
92394 ** Allocate a new Select structure and return a pointer to that
92395 ** structure.
92397 SQLITE_PRIVATE Select *sqlite3SelectNew(
92398 Parse *pParse, /* Parsing context */
92399 ExprList *pEList, /* which columns to include in the result */
92400 SrcList *pSrc, /* the FROM clause -- which tables to scan */
92401 Expr *pWhere, /* the WHERE clause */
92402 ExprList *pGroupBy, /* the GROUP BY clause */
92403 Expr *pHaving, /* the HAVING clause */
92404 ExprList *pOrderBy, /* the ORDER BY clause */
92405 int isDistinct, /* true if the DISTINCT keyword is present */
92406 Expr *pLimit, /* LIMIT value. NULL means not used */
92407 Expr *pOffset /* OFFSET value. NULL means no offset */
92409 Select *pNew;
92410 Select standin;
92411 sqlite3 *db = pParse->db;
92412 pNew = sqlite3DbMallocZero(db, sizeof(*pNew) );
92413 assert( db->mallocFailed || !pOffset || pLimit ); /* OFFSET implies LIMIT */
92414 if( pNew==0 ){
92415 pNew = &standin;
92416 memset(pNew, 0, sizeof(*pNew));
92418 if( pEList==0 ){
92419 pEList = sqlite3ExprListAppend(pParse, 0, sqlite3Expr(db,TK_ALL,0));
92421 pNew->pEList = pEList;
92422 pNew->pSrc = pSrc;
92423 pNew->pWhere = pWhere;
92424 pNew->pGroupBy = pGroupBy;
92425 pNew->pHaving = pHaving;
92426 pNew->pOrderBy = pOrderBy;
92427 pNew->selFlags = isDistinct ? SF_Distinct : 0;
92428 pNew->op = TK_SELECT;
92429 pNew->pLimit = pLimit;
92430 pNew->pOffset = pOffset;
92431 assert( pOffset==0 || pLimit!=0 );
92432 pNew->addrOpenEphm[0] = -1;
92433 pNew->addrOpenEphm[1] = -1;
92434 pNew->addrOpenEphm[2] = -1;
92435 if( db->mallocFailed ) {
92436 clearSelect(db, pNew);
92437 if( pNew!=&standin ) sqlite3DbFree(db, pNew);
92438 pNew = 0;
92439 }else{
92440 assert( pNew->pSrc!=0 || pParse->nErr>0 );
92442 return pNew;
92446 ** Delete the given Select structure and all of its substructures.
92448 SQLITE_PRIVATE void sqlite3SelectDelete(sqlite3 *db, Select *p){
92449 if( p ){
92450 clearSelect(db, p);
92451 sqlite3DbFree(db, p);
92456 ** Given 1 to 3 identifiers preceeding the JOIN keyword, determine the
92457 ** type of join. Return an integer constant that expresses that type
92458 ** in terms of the following bit values:
92460 ** JT_INNER
92461 ** JT_CROSS
92462 ** JT_OUTER
92463 ** JT_NATURAL
92464 ** JT_LEFT
92465 ** JT_RIGHT
92467 ** A full outer join is the combination of JT_LEFT and JT_RIGHT.
92469 ** If an illegal or unsupported join type is seen, then still return
92470 ** a join type, but put an error in the pParse structure.
92472 SQLITE_PRIVATE int sqlite3JoinType(Parse *pParse, Token *pA, Token *pB, Token *pC){
92473 int jointype = 0;
92474 Token *apAll[3];
92475 Token *p;
92476 /* 0123456789 123456789 123456789 123 */
92477 static const char zKeyText[] = "naturaleftouterightfullinnercross";
92478 static const struct {
92479 u8 i; /* Beginning of keyword text in zKeyText[] */
92480 u8 nChar; /* Length of the keyword in characters */
92481 u8 code; /* Join type mask */
92482 } aKeyword[] = {
92483 /* natural */ { 0, 7, JT_NATURAL },
92484 /* left */ { 6, 4, JT_LEFT|JT_OUTER },
92485 /* outer */ { 10, 5, JT_OUTER },
92486 /* right */ { 14, 5, JT_RIGHT|JT_OUTER },
92487 /* full */ { 19, 4, JT_LEFT|JT_RIGHT|JT_OUTER },
92488 /* inner */ { 23, 5, JT_INNER },
92489 /* cross */ { 28, 5, JT_INNER|JT_CROSS },
92491 int i, j;
92492 apAll[0] = pA;
92493 apAll[1] = pB;
92494 apAll[2] = pC;
92495 for(i=0; i<3 && apAll[i]; i++){
92496 p = apAll[i];
92497 for(j=0; j<ArraySize(aKeyword); j++){
92498 if( p->n==aKeyword[j].nChar
92499 && sqlite3StrNICmp((char*)p->z, &zKeyText[aKeyword[j].i], p->n)==0 ){
92500 jointype |= aKeyword[j].code;
92501 break;
92504 testcase( j==0 || j==1 || j==2 || j==3 || j==4 || j==5 || j==6 );
92505 if( j>=ArraySize(aKeyword) ){
92506 jointype |= JT_ERROR;
92507 break;
92511 (jointype & (JT_INNER|JT_OUTER))==(JT_INNER|JT_OUTER) ||
92512 (jointype & JT_ERROR)!=0
92514 const char *zSp = " ";
92515 assert( pB!=0 );
92516 if( pC==0 ){ zSp++; }
92517 sqlite3ErrorMsg(pParse, "unknown or unsupported join type: "
92518 "%T %T%s%T", pA, pB, zSp, pC);
92519 jointype = JT_INNER;
92520 }else if( (jointype & JT_OUTER)!=0
92521 && (jointype & (JT_LEFT|JT_RIGHT))!=JT_LEFT ){
92522 sqlite3ErrorMsg(pParse,
92523 "RIGHT and FULL OUTER JOINs are not currently supported");
92524 jointype = JT_INNER;
92526 return jointype;
92530 ** Return the index of a column in a table. Return -1 if the column
92531 ** is not contained in the table.
92533 static int columnIndex(Table *pTab, const char *zCol){
92534 int i;
92535 for(i=0; i<pTab->nCol; i++){
92536 if( sqlite3StrICmp(pTab->aCol[i].zName, zCol)==0 ) return i;
92538 return -1;
92542 ** Search the first N tables in pSrc, from left to right, looking for a
92543 ** table that has a column named zCol.
92545 ** When found, set *piTab and *piCol to the table index and column index
92546 ** of the matching column and return TRUE.
92548 ** If not found, return FALSE.
92550 static int tableAndColumnIndex(
92551 SrcList *pSrc, /* Array of tables to search */
92552 int N, /* Number of tables in pSrc->a[] to search */
92553 const char *zCol, /* Name of the column we are looking for */
92554 int *piTab, /* Write index of pSrc->a[] here */
92555 int *piCol /* Write index of pSrc->a[*piTab].pTab->aCol[] here */
92557 int i; /* For looping over tables in pSrc */
92558 int iCol; /* Index of column matching zCol */
92560 assert( (piTab==0)==(piCol==0) ); /* Both or neither are NULL */
92561 for(i=0; i<N; i++){
92562 iCol = columnIndex(pSrc->a[i].pTab, zCol);
92563 if( iCol>=0 ){
92564 if( piTab ){
92565 *piTab = i;
92566 *piCol = iCol;
92568 return 1;
92571 return 0;
92575 ** This function is used to add terms implied by JOIN syntax to the
92576 ** WHERE clause expression of a SELECT statement. The new term, which
92577 ** is ANDed with the existing WHERE clause, is of the form:
92579 ** (tab1.col1 = tab2.col2)
92581 ** where tab1 is the iSrc'th table in SrcList pSrc and tab2 is the
92582 ** (iSrc+1)'th. Column col1 is column iColLeft of tab1, and col2 is
92583 ** column iColRight of tab2.
92585 static void addWhereTerm(
92586 Parse *pParse, /* Parsing context */
92587 SrcList *pSrc, /* List of tables in FROM clause */
92588 int iLeft, /* Index of first table to join in pSrc */
92589 int iColLeft, /* Index of column in first table */
92590 int iRight, /* Index of second table in pSrc */
92591 int iColRight, /* Index of column in second table */
92592 int isOuterJoin, /* True if this is an OUTER join */
92593 Expr **ppWhere /* IN/OUT: The WHERE clause to add to */
92595 sqlite3 *db = pParse->db;
92596 Expr *pE1;
92597 Expr *pE2;
92598 Expr *pEq;
92600 assert( iLeft<iRight );
92601 assert( pSrc->nSrc>iRight );
92602 assert( pSrc->a[iLeft].pTab );
92603 assert( pSrc->a[iRight].pTab );
92605 pE1 = sqlite3CreateColumnExpr(db, pSrc, iLeft, iColLeft);
92606 pE2 = sqlite3CreateColumnExpr(db, pSrc, iRight, iColRight);
92608 pEq = sqlite3PExpr(pParse, TK_EQ, pE1, pE2, 0);
92609 if( pEq && isOuterJoin ){
92610 ExprSetProperty(pEq, EP_FromJoin);
92611 assert( !ExprHasAnyProperty(pEq, EP_TokenOnly|EP_Reduced) );
92612 ExprSetIrreducible(pEq);
92613 pEq->iRightJoinTable = (i16)pE2->iTable;
92615 *ppWhere = sqlite3ExprAnd(db, *ppWhere, pEq);
92619 ** Set the EP_FromJoin property on all terms of the given expression.
92620 ** And set the Expr.iRightJoinTable to iTable for every term in the
92621 ** expression.
92623 ** The EP_FromJoin property is used on terms of an expression to tell
92624 ** the LEFT OUTER JOIN processing logic that this term is part of the
92625 ** join restriction specified in the ON or USING clause and not a part
92626 ** of the more general WHERE clause. These terms are moved over to the
92627 ** WHERE clause during join processing but we need to remember that they
92628 ** originated in the ON or USING clause.
92630 ** The Expr.iRightJoinTable tells the WHERE clause processing that the
92631 ** expression depends on table iRightJoinTable even if that table is not
92632 ** explicitly mentioned in the expression. That information is needed
92633 ** for cases like this:
92635 ** SELECT * FROM t1 LEFT JOIN t2 ON t1.a=t2.b AND t1.x=5
92637 ** The where clause needs to defer the handling of the t1.x=5
92638 ** term until after the t2 loop of the join. In that way, a
92639 ** NULL t2 row will be inserted whenever t1.x!=5. If we do not
92640 ** defer the handling of t1.x=5, it will be processed immediately
92641 ** after the t1 loop and rows with t1.x!=5 will never appear in
92642 ** the output, which is incorrect.
92644 static void setJoinExpr(Expr *p, int iTable){
92645 while( p ){
92646 ExprSetProperty(p, EP_FromJoin);
92647 assert( !ExprHasAnyProperty(p, EP_TokenOnly|EP_Reduced) );
92648 ExprSetIrreducible(p);
92649 p->iRightJoinTable = (i16)iTable;
92650 setJoinExpr(p->pLeft, iTable);
92651 p = p->pRight;
92656 ** This routine processes the join information for a SELECT statement.
92657 ** ON and USING clauses are converted into extra terms of the WHERE clause.
92658 ** NATURAL joins also create extra WHERE clause terms.
92660 ** The terms of a FROM clause are contained in the Select.pSrc structure.
92661 ** The left most table is the first entry in Select.pSrc. The right-most
92662 ** table is the last entry. The join operator is held in the entry to
92663 ** the left. Thus entry 0 contains the join operator for the join between
92664 ** entries 0 and 1. Any ON or USING clauses associated with the join are
92665 ** also attached to the left entry.
92667 ** This routine returns the number of errors encountered.
92669 static int sqliteProcessJoin(Parse *pParse, Select *p){
92670 SrcList *pSrc; /* All tables in the FROM clause */
92671 int i, j; /* Loop counters */
92672 struct SrcList_item *pLeft; /* Left table being joined */
92673 struct SrcList_item *pRight; /* Right table being joined */
92675 pSrc = p->pSrc;
92676 pLeft = &pSrc->a[0];
92677 pRight = &pLeft[1];
92678 for(i=0; i<pSrc->nSrc-1; i++, pRight++, pLeft++){
92679 Table *pLeftTab = pLeft->pTab;
92680 Table *pRightTab = pRight->pTab;
92681 int isOuter;
92683 if( NEVER(pLeftTab==0 || pRightTab==0) ) continue;
92684 isOuter = (pRight->jointype & JT_OUTER)!=0;
92686 /* When the NATURAL keyword is present, add WHERE clause terms for
92687 ** every column that the two tables have in common.
92689 if( pRight->jointype & JT_NATURAL ){
92690 if( pRight->pOn || pRight->pUsing ){
92691 sqlite3ErrorMsg(pParse, "a NATURAL join may not have "
92692 "an ON or USING clause", 0);
92693 return 1;
92695 for(j=0; j<pRightTab->nCol; j++){
92696 char *zName; /* Name of column in the right table */
92697 int iLeft; /* Matching left table */
92698 int iLeftCol; /* Matching column in the left table */
92700 zName = pRightTab->aCol[j].zName;
92701 if( tableAndColumnIndex(pSrc, i+1, zName, &iLeft, &iLeftCol) ){
92702 addWhereTerm(pParse, pSrc, iLeft, iLeftCol, i+1, j,
92703 isOuter, &p->pWhere);
92708 /* Disallow both ON and USING clauses in the same join
92710 if( pRight->pOn && pRight->pUsing ){
92711 sqlite3ErrorMsg(pParse, "cannot have both ON and USING "
92712 "clauses in the same join");
92713 return 1;
92716 /* Add the ON clause to the end of the WHERE clause, connected by
92717 ** an AND operator.
92719 if( pRight->pOn ){
92720 if( isOuter ) setJoinExpr(pRight->pOn, pRight->iCursor);
92721 p->pWhere = sqlite3ExprAnd(pParse->db, p->pWhere, pRight->pOn);
92722 pRight->pOn = 0;
92725 /* Create extra terms on the WHERE clause for each column named
92726 ** in the USING clause. Example: If the two tables to be joined are
92727 ** A and B and the USING clause names X, Y, and Z, then add this
92728 ** to the WHERE clause: A.X=B.X AND A.Y=B.Y AND A.Z=B.Z
92729 ** Report an error if any column mentioned in the USING clause is
92730 ** not contained in both tables to be joined.
92732 if( pRight->pUsing ){
92733 IdList *pList = pRight->pUsing;
92734 for(j=0; j<pList->nId; j++){
92735 char *zName; /* Name of the term in the USING clause */
92736 int iLeft; /* Table on the left with matching column name */
92737 int iLeftCol; /* Column number of matching column on the left */
92738 int iRightCol; /* Column number of matching column on the right */
92740 zName = pList->a[j].zName;
92741 iRightCol = columnIndex(pRightTab, zName);
92742 if( iRightCol<0
92743 || !tableAndColumnIndex(pSrc, i+1, zName, &iLeft, &iLeftCol)
92745 sqlite3ErrorMsg(pParse, "cannot join using column %s - column "
92746 "not present in both tables", zName);
92747 return 1;
92749 addWhereTerm(pParse, pSrc, iLeft, iLeftCol, i+1, iRightCol,
92750 isOuter, &p->pWhere);
92754 return 0;
92758 ** Insert code into "v" that will push the record on the top of the
92759 ** stack into the sorter.
92761 static void pushOntoSorter(
92762 Parse *pParse, /* Parser context */
92763 ExprList *pOrderBy, /* The ORDER BY clause */
92764 Select *pSelect, /* The whole SELECT statement */
92765 int regData /* Register holding data to be sorted */
92767 Vdbe *v = pParse->pVdbe;
92768 int nExpr = pOrderBy->nExpr;
92769 int regBase = sqlite3GetTempRange(pParse, nExpr+2);
92770 int regRecord = sqlite3GetTempReg(pParse);
92771 int op;
92772 sqlite3ExprCacheClear(pParse);
92773 sqlite3ExprCodeExprList(pParse, pOrderBy, regBase, 0);
92774 sqlite3VdbeAddOp2(v, OP_Sequence, pOrderBy->iECursor, regBase+nExpr);
92775 sqlite3ExprCodeMove(pParse, regData, regBase+nExpr+1, 1);
92776 sqlite3VdbeAddOp3(v, OP_MakeRecord, regBase, nExpr + 2, regRecord);
92777 if( pSelect->selFlags & SF_UseSorter ){
92778 op = OP_SorterInsert;
92779 }else{
92780 op = OP_IdxInsert;
92782 sqlite3VdbeAddOp2(v, op, pOrderBy->iECursor, regRecord);
92783 sqlite3ReleaseTempReg(pParse, regRecord);
92784 sqlite3ReleaseTempRange(pParse, regBase, nExpr+2);
92785 if( pSelect->iLimit ){
92786 int addr1, addr2;
92787 int iLimit;
92788 if( pSelect->iOffset ){
92789 iLimit = pSelect->iOffset+1;
92790 }else{
92791 iLimit = pSelect->iLimit;
92793 addr1 = sqlite3VdbeAddOp1(v, OP_IfZero, iLimit);
92794 sqlite3VdbeAddOp2(v, OP_AddImm, iLimit, -1);
92795 addr2 = sqlite3VdbeAddOp0(v, OP_Goto);
92796 sqlite3VdbeJumpHere(v, addr1);
92797 sqlite3VdbeAddOp1(v, OP_Last, pOrderBy->iECursor);
92798 sqlite3VdbeAddOp1(v, OP_Delete, pOrderBy->iECursor);
92799 sqlite3VdbeJumpHere(v, addr2);
92804 ** Add code to implement the OFFSET
92806 static void codeOffset(
92807 Vdbe *v, /* Generate code into this VM */
92808 Select *p, /* The SELECT statement being coded */
92809 int iContinue /* Jump here to skip the current record */
92811 if( p->iOffset && iContinue!=0 ){
92812 int addr;
92813 sqlite3VdbeAddOp2(v, OP_AddImm, p->iOffset, -1);
92814 addr = sqlite3VdbeAddOp1(v, OP_IfNeg, p->iOffset);
92815 sqlite3VdbeAddOp2(v, OP_Goto, 0, iContinue);
92816 VdbeComment((v, "skip OFFSET records"));
92817 sqlite3VdbeJumpHere(v, addr);
92822 ** Add code that will check to make sure the N registers starting at iMem
92823 ** form a distinct entry. iTab is a sorting index that holds previously
92824 ** seen combinations of the N values. A new entry is made in iTab
92825 ** if the current N values are new.
92827 ** A jump to addrRepeat is made and the N+1 values are popped from the
92828 ** stack if the top N elements are not distinct.
92830 static void codeDistinct(
92831 Parse *pParse, /* Parsing and code generating context */
92832 int iTab, /* A sorting index used to test for distinctness */
92833 int addrRepeat, /* Jump to here if not distinct */
92834 int N, /* Number of elements */
92835 int iMem /* First element */
92837 Vdbe *v;
92838 int r1;
92840 v = pParse->pVdbe;
92841 r1 = sqlite3GetTempReg(pParse);
92842 sqlite3VdbeAddOp4Int(v, OP_Found, iTab, addrRepeat, iMem, N);
92843 sqlite3VdbeAddOp3(v, OP_MakeRecord, iMem, N, r1);
92844 sqlite3VdbeAddOp2(v, OP_IdxInsert, iTab, r1);
92845 sqlite3ReleaseTempReg(pParse, r1);
92848 #ifndef SQLITE_OMIT_SUBQUERY
92850 ** Generate an error message when a SELECT is used within a subexpression
92851 ** (example: "a IN (SELECT * FROM table)") but it has more than 1 result
92852 ** column. We do this in a subroutine because the error used to occur
92853 ** in multiple places. (The error only occurs in one place now, but we
92854 ** retain the subroutine to minimize code disruption.)
92856 static int checkForMultiColumnSelectError(
92857 Parse *pParse, /* Parse context. */
92858 SelectDest *pDest, /* Destination of SELECT results */
92859 int nExpr /* Number of result columns returned by SELECT */
92861 int eDest = pDest->eDest;
92862 if( nExpr>1 && (eDest==SRT_Mem || eDest==SRT_Set) ){
92863 sqlite3ErrorMsg(pParse, "only a single result allowed for "
92864 "a SELECT that is part of an expression");
92865 return 1;
92866 }else{
92867 return 0;
92870 #endif
92873 ** This routine generates the code for the inside of the inner loop
92874 ** of a SELECT.
92876 ** If srcTab and nColumn are both zero, then the pEList expressions
92877 ** are evaluated in order to get the data for this row. If nColumn>0
92878 ** then data is pulled from srcTab and pEList is used only to get the
92879 ** datatypes for each column.
92881 static void selectInnerLoop(
92882 Parse *pParse, /* The parser context */
92883 Select *p, /* The complete select statement being coded */
92884 ExprList *pEList, /* List of values being extracted */
92885 int srcTab, /* Pull data from this table */
92886 int nColumn, /* Number of columns in the source table */
92887 ExprList *pOrderBy, /* If not NULL, sort results using this key */
92888 int distinct, /* If >=0, make sure results are distinct */
92889 SelectDest *pDest, /* How to dispose of the results */
92890 int iContinue, /* Jump here to continue with next row */
92891 int iBreak /* Jump here to break out of the inner loop */
92893 Vdbe *v = pParse->pVdbe;
92894 int i;
92895 int hasDistinct; /* True if the DISTINCT keyword is present */
92896 int regResult; /* Start of memory holding result set */
92897 int eDest = pDest->eDest; /* How to dispose of results */
92898 int iParm = pDest->iParm; /* First argument to disposal method */
92899 int nResultCol; /* Number of result columns */
92901 assert( v );
92902 if( NEVER(v==0) ) return;
92903 assert( pEList!=0 );
92904 hasDistinct = distinct>=0;
92905 if( pOrderBy==0 && !hasDistinct ){
92906 codeOffset(v, p, iContinue);
92909 /* Pull the requested columns.
92911 if( nColumn>0 ){
92912 nResultCol = nColumn;
92913 }else{
92914 nResultCol = pEList->nExpr;
92916 if( pDest->iMem==0 ){
92917 pDest->iMem = pParse->nMem+1;
92918 pDest->nMem = nResultCol;
92919 pParse->nMem += nResultCol;
92920 }else{
92921 assert( pDest->nMem==nResultCol );
92923 regResult = pDest->iMem;
92924 if( nColumn>0 ){
92925 for(i=0; i<nColumn; i++){
92926 sqlite3VdbeAddOp3(v, OP_Column, srcTab, i, regResult+i);
92928 }else if( eDest!=SRT_Exists ){
92929 /* If the destination is an EXISTS(...) expression, the actual
92930 ** values returned by the SELECT are not required.
92932 sqlite3ExprCacheClear(pParse);
92933 sqlite3ExprCodeExprList(pParse, pEList, regResult, eDest==SRT_Output);
92935 nColumn = nResultCol;
92937 /* If the DISTINCT keyword was present on the SELECT statement
92938 ** and this row has been seen before, then do not make this row
92939 ** part of the result.
92941 if( hasDistinct ){
92942 assert( pEList!=0 );
92943 assert( pEList->nExpr==nColumn );
92944 codeDistinct(pParse, distinct, iContinue, nColumn, regResult);
92945 if( pOrderBy==0 ){
92946 codeOffset(v, p, iContinue);
92950 switch( eDest ){
92951 /* In this mode, write each query result to the key of the temporary
92952 ** table iParm.
92954 #ifndef SQLITE_OMIT_COMPOUND_SELECT
92955 case SRT_Union: {
92956 int r1;
92957 r1 = sqlite3GetTempReg(pParse);
92958 sqlite3VdbeAddOp3(v, OP_MakeRecord, regResult, nColumn, r1);
92959 sqlite3VdbeAddOp2(v, OP_IdxInsert, iParm, r1);
92960 sqlite3ReleaseTempReg(pParse, r1);
92961 break;
92964 /* Construct a record from the query result, but instead of
92965 ** saving that record, use it as a key to delete elements from
92966 ** the temporary table iParm.
92968 case SRT_Except: {
92969 sqlite3VdbeAddOp3(v, OP_IdxDelete, iParm, regResult, nColumn);
92970 break;
92972 #endif
92974 /* Store the result as data using a unique key.
92976 case SRT_Table:
92977 case SRT_EphemTab: {
92978 int r1 = sqlite3GetTempReg(pParse);
92979 testcase( eDest==SRT_Table );
92980 testcase( eDest==SRT_EphemTab );
92981 sqlite3VdbeAddOp3(v, OP_MakeRecord, regResult, nColumn, r1);
92982 if( pOrderBy ){
92983 pushOntoSorter(pParse, pOrderBy, p, r1);
92984 }else{
92985 int r2 = sqlite3GetTempReg(pParse);
92986 sqlite3VdbeAddOp2(v, OP_NewRowid, iParm, r2);
92987 sqlite3VdbeAddOp3(v, OP_Insert, iParm, r1, r2);
92988 sqlite3VdbeChangeP5(v, OPFLAG_APPEND);
92989 sqlite3ReleaseTempReg(pParse, r2);
92991 sqlite3ReleaseTempReg(pParse, r1);
92992 break;
92995 #ifndef SQLITE_OMIT_SUBQUERY
92996 /* If we are creating a set for an "expr IN (SELECT ...)" construct,
92997 ** then there should be a single item on the stack. Write this
92998 ** item into the set table with bogus data.
93000 case SRT_Set: {
93001 assert( nColumn==1 );
93002 p->affinity = sqlite3CompareAffinity(pEList->a[0].pExpr, pDest->affinity);
93003 if( pOrderBy ){
93004 /* At first glance you would think we could optimize out the
93005 ** ORDER BY in this case since the order of entries in the set
93006 ** does not matter. But there might be a LIMIT clause, in which
93007 ** case the order does matter */
93008 pushOntoSorter(pParse, pOrderBy, p, regResult);
93009 }else{
93010 int r1 = sqlite3GetTempReg(pParse);
93011 sqlite3VdbeAddOp4(v, OP_MakeRecord, regResult, 1, r1, &p->affinity, 1);
93012 sqlite3ExprCacheAffinityChange(pParse, regResult, 1);
93013 sqlite3VdbeAddOp2(v, OP_IdxInsert, iParm, r1);
93014 sqlite3ReleaseTempReg(pParse, r1);
93016 break;
93019 /* If any row exist in the result set, record that fact and abort.
93021 case SRT_Exists: {
93022 sqlite3VdbeAddOp2(v, OP_Integer, 1, iParm);
93023 /* The LIMIT clause will terminate the loop for us */
93024 break;
93027 /* If this is a scalar select that is part of an expression, then
93028 ** store the results in the appropriate memory cell and break out
93029 ** of the scan loop.
93031 case SRT_Mem: {
93032 assert( nColumn==1 );
93033 if( pOrderBy ){
93034 pushOntoSorter(pParse, pOrderBy, p, regResult);
93035 }else{
93036 sqlite3ExprCodeMove(pParse, regResult, iParm, 1);
93037 /* The LIMIT clause will jump out of the loop for us */
93039 break;
93041 #endif /* #ifndef SQLITE_OMIT_SUBQUERY */
93043 /* Send the data to the callback function or to a subroutine. In the
93044 ** case of a subroutine, the subroutine itself is responsible for
93045 ** popping the data from the stack.
93047 case SRT_Coroutine:
93048 case SRT_Output: {
93049 testcase( eDest==SRT_Coroutine );
93050 testcase( eDest==SRT_Output );
93051 if( pOrderBy ){
93052 int r1 = sqlite3GetTempReg(pParse);
93053 sqlite3VdbeAddOp3(v, OP_MakeRecord, regResult, nColumn, r1);
93054 pushOntoSorter(pParse, pOrderBy, p, r1);
93055 sqlite3ReleaseTempReg(pParse, r1);
93056 }else if( eDest==SRT_Coroutine ){
93057 sqlite3VdbeAddOp1(v, OP_Yield, pDest->iParm);
93058 }else{
93059 sqlite3VdbeAddOp2(v, OP_ResultRow, regResult, nColumn);
93060 sqlite3ExprCacheAffinityChange(pParse, regResult, nColumn);
93062 break;
93065 #if !defined(SQLITE_OMIT_TRIGGER)
93066 /* Discard the results. This is used for SELECT statements inside
93067 ** the body of a TRIGGER. The purpose of such selects is to call
93068 ** user-defined functions that have side effects. We do not care
93069 ** about the actual results of the select.
93071 default: {
93072 assert( eDest==SRT_Discard );
93073 break;
93075 #endif
93078 /* Jump to the end of the loop if the LIMIT is reached. Except, if
93079 ** there is a sorter, in which case the sorter has already limited
93080 ** the output for us.
93082 if( pOrderBy==0 && p->iLimit ){
93083 sqlite3VdbeAddOp3(v, OP_IfZero, p->iLimit, iBreak, -1);
93088 ** Given an expression list, generate a KeyInfo structure that records
93089 ** the collating sequence for each expression in that expression list.
93091 ** If the ExprList is an ORDER BY or GROUP BY clause then the resulting
93092 ** KeyInfo structure is appropriate for initializing a virtual index to
93093 ** implement that clause. If the ExprList is the result set of a SELECT
93094 ** then the KeyInfo structure is appropriate for initializing a virtual
93095 ** index to implement a DISTINCT test.
93097 ** Space to hold the KeyInfo structure is obtain from malloc. The calling
93098 ** function is responsible for seeing that this structure is eventually
93099 ** freed. Add the KeyInfo structure to the P4 field of an opcode using
93100 ** P4_KEYINFO_HANDOFF is the usual way of dealing with this.
93102 static KeyInfo *keyInfoFromExprList(Parse *pParse, ExprList *pList){
93103 sqlite3 *db = pParse->db;
93104 int nExpr;
93105 KeyInfo *pInfo;
93106 struct ExprList_item *pItem;
93107 int i;
93109 nExpr = pList->nExpr;
93110 pInfo = sqlite3DbMallocZero(db, sizeof(*pInfo) + nExpr*(sizeof(CollSeq*)+1) );
93111 if( pInfo ){
93112 pInfo->aSortOrder = (u8*)&pInfo->aColl[nExpr];
93113 pInfo->nField = (u16)nExpr;
93114 pInfo->enc = ENC(db);
93115 pInfo->db = db;
93116 for(i=0, pItem=pList->a; i<nExpr; i++, pItem++){
93117 CollSeq *pColl;
93118 pColl = sqlite3ExprCollSeq(pParse, pItem->pExpr);
93119 if( !pColl ){
93120 pColl = db->pDfltColl;
93122 pInfo->aColl[i] = pColl;
93123 pInfo->aSortOrder[i] = pItem->sortOrder;
93126 return pInfo;
93129 #ifndef SQLITE_OMIT_COMPOUND_SELECT
93131 ** Name of the connection operator, used for error messages.
93133 static const char *selectOpName(int id){
93134 char *z;
93135 switch( id ){
93136 case TK_ALL: z = "UNION ALL"; break;
93137 case TK_INTERSECT: z = "INTERSECT"; break;
93138 case TK_EXCEPT: z = "EXCEPT"; break;
93139 default: z = "UNION"; break;
93141 return z;
93143 #endif /* SQLITE_OMIT_COMPOUND_SELECT */
93145 #ifndef SQLITE_OMIT_EXPLAIN
93147 ** Unless an "EXPLAIN QUERY PLAN" command is being processed, this function
93148 ** is a no-op. Otherwise, it adds a single row of output to the EQP result,
93149 ** where the caption is of the form:
93151 ** "USE TEMP B-TREE FOR xxx"
93153 ** where xxx is one of "DISTINCT", "ORDER BY" or "GROUP BY". Exactly which
93154 ** is determined by the zUsage argument.
93156 static void explainTempTable(Parse *pParse, const char *zUsage){
93157 if( pParse->explain==2 ){
93158 Vdbe *v = pParse->pVdbe;
93159 char *zMsg = sqlite3MPrintf(pParse->db, "USE TEMP B-TREE FOR %s", zUsage);
93160 sqlite3VdbeAddOp4(v, OP_Explain, pParse->iSelectId, 0, 0, zMsg, P4_DYNAMIC);
93165 ** Assign expression b to lvalue a. A second, no-op, version of this macro
93166 ** is provided when SQLITE_OMIT_EXPLAIN is defined. This allows the code
93167 ** in sqlite3Select() to assign values to structure member variables that
93168 ** only exist if SQLITE_OMIT_EXPLAIN is not defined without polluting the
93169 ** code with #ifndef directives.
93171 # define explainSetInteger(a, b) a = b
93173 #else
93174 /* No-op versions of the explainXXX() functions and macros. */
93175 # define explainTempTable(y,z)
93176 # define explainSetInteger(y,z)
93177 #endif
93179 #if !defined(SQLITE_OMIT_EXPLAIN) && !defined(SQLITE_OMIT_COMPOUND_SELECT)
93181 ** Unless an "EXPLAIN QUERY PLAN" command is being processed, this function
93182 ** is a no-op. Otherwise, it adds a single row of output to the EQP result,
93183 ** where the caption is of one of the two forms:
93185 ** "COMPOSITE SUBQUERIES iSub1 and iSub2 (op)"
93186 ** "COMPOSITE SUBQUERIES iSub1 and iSub2 USING TEMP B-TREE (op)"
93188 ** where iSub1 and iSub2 are the integers passed as the corresponding
93189 ** function parameters, and op is the text representation of the parameter
93190 ** of the same name. The parameter "op" must be one of TK_UNION, TK_EXCEPT,
93191 ** TK_INTERSECT or TK_ALL. The first form is used if argument bUseTmp is
93192 ** false, or the second form if it is true.
93194 static void explainComposite(
93195 Parse *pParse, /* Parse context */
93196 int op, /* One of TK_UNION, TK_EXCEPT etc. */
93197 int iSub1, /* Subquery id 1 */
93198 int iSub2, /* Subquery id 2 */
93199 int bUseTmp /* True if a temp table was used */
93201 assert( op==TK_UNION || op==TK_EXCEPT || op==TK_INTERSECT || op==TK_ALL );
93202 if( pParse->explain==2 ){
93203 Vdbe *v = pParse->pVdbe;
93204 char *zMsg = sqlite3MPrintf(
93205 pParse->db, "COMPOUND SUBQUERIES %d AND %d %s(%s)", iSub1, iSub2,
93206 bUseTmp?"USING TEMP B-TREE ":"", selectOpName(op)
93208 sqlite3VdbeAddOp4(v, OP_Explain, pParse->iSelectId, 0, 0, zMsg, P4_DYNAMIC);
93211 #else
93212 /* No-op versions of the explainXXX() functions and macros. */
93213 # define explainComposite(v,w,x,y,z)
93214 #endif
93217 ** If the inner loop was generated using a non-null pOrderBy argument,
93218 ** then the results were placed in a sorter. After the loop is terminated
93219 ** we need to run the sorter and output the results. The following
93220 ** routine generates the code needed to do that.
93222 static void generateSortTail(
93223 Parse *pParse, /* Parsing context */
93224 Select *p, /* The SELECT statement */
93225 Vdbe *v, /* Generate code into this VDBE */
93226 int nColumn, /* Number of columns of data */
93227 SelectDest *pDest /* Write the sorted results here */
93229 int addrBreak = sqlite3VdbeMakeLabel(v); /* Jump here to exit loop */
93230 int addrContinue = sqlite3VdbeMakeLabel(v); /* Jump here for next cycle */
93231 int addr;
93232 int iTab;
93233 int pseudoTab = 0;
93234 ExprList *pOrderBy = p->pOrderBy;
93236 int eDest = pDest->eDest;
93237 int iParm = pDest->iParm;
93239 int regRow;
93240 int regRowid;
93242 iTab = pOrderBy->iECursor;
93243 regRow = sqlite3GetTempReg(pParse);
93244 if( eDest==SRT_Output || eDest==SRT_Coroutine ){
93245 pseudoTab = pParse->nTab++;
93246 sqlite3VdbeAddOp3(v, OP_OpenPseudo, pseudoTab, regRow, nColumn);
93247 regRowid = 0;
93248 }else{
93249 regRowid = sqlite3GetTempReg(pParse);
93251 if( p->selFlags & SF_UseSorter ){
93252 int regSortOut = ++pParse->nMem;
93253 int ptab2 = pParse->nTab++;
93254 sqlite3VdbeAddOp3(v, OP_OpenPseudo, ptab2, regSortOut, pOrderBy->nExpr+2);
93255 addr = 1 + sqlite3VdbeAddOp2(v, OP_SorterSort, iTab, addrBreak);
93256 codeOffset(v, p, addrContinue);
93257 sqlite3VdbeAddOp2(v, OP_SorterData, iTab, regSortOut);
93258 sqlite3VdbeAddOp3(v, OP_Column, ptab2, pOrderBy->nExpr+1, regRow);
93259 sqlite3VdbeChangeP5(v, OPFLAG_CLEARCACHE);
93260 }else{
93261 addr = 1 + sqlite3VdbeAddOp2(v, OP_Sort, iTab, addrBreak);
93262 codeOffset(v, p, addrContinue);
93263 sqlite3VdbeAddOp3(v, OP_Column, iTab, pOrderBy->nExpr+1, regRow);
93265 switch( eDest ){
93266 case SRT_Table:
93267 case SRT_EphemTab: {
93268 testcase( eDest==SRT_Table );
93269 testcase( eDest==SRT_EphemTab );
93270 sqlite3VdbeAddOp2(v, OP_NewRowid, iParm, regRowid);
93271 sqlite3VdbeAddOp3(v, OP_Insert, iParm, regRow, regRowid);
93272 sqlite3VdbeChangeP5(v, OPFLAG_APPEND);
93273 break;
93275 #ifndef SQLITE_OMIT_SUBQUERY
93276 case SRT_Set: {
93277 assert( nColumn==1 );
93278 sqlite3VdbeAddOp4(v, OP_MakeRecord, regRow, 1, regRowid, &p->affinity, 1);
93279 sqlite3ExprCacheAffinityChange(pParse, regRow, 1);
93280 sqlite3VdbeAddOp2(v, OP_IdxInsert, iParm, regRowid);
93281 break;
93283 case SRT_Mem: {
93284 assert( nColumn==1 );
93285 sqlite3ExprCodeMove(pParse, regRow, iParm, 1);
93286 /* The LIMIT clause will terminate the loop for us */
93287 break;
93289 #endif
93290 default: {
93291 int i;
93292 assert( eDest==SRT_Output || eDest==SRT_Coroutine );
93293 testcase( eDest==SRT_Output );
93294 testcase( eDest==SRT_Coroutine );
93295 for(i=0; i<nColumn; i++){
93296 assert( regRow!=pDest->iMem+i );
93297 sqlite3VdbeAddOp3(v, OP_Column, pseudoTab, i, pDest->iMem+i);
93298 if( i==0 ){
93299 sqlite3VdbeChangeP5(v, OPFLAG_CLEARCACHE);
93302 if( eDest==SRT_Output ){
93303 sqlite3VdbeAddOp2(v, OP_ResultRow, pDest->iMem, nColumn);
93304 sqlite3ExprCacheAffinityChange(pParse, pDest->iMem, nColumn);
93305 }else{
93306 sqlite3VdbeAddOp1(v, OP_Yield, pDest->iParm);
93308 break;
93311 sqlite3ReleaseTempReg(pParse, regRow);
93312 sqlite3ReleaseTempReg(pParse, regRowid);
93314 /* The bottom of the loop
93316 sqlite3VdbeResolveLabel(v, addrContinue);
93317 if( p->selFlags & SF_UseSorter ){
93318 sqlite3VdbeAddOp2(v, OP_SorterNext, iTab, addr);
93319 }else{
93320 sqlite3VdbeAddOp2(v, OP_Next, iTab, addr);
93322 sqlite3VdbeResolveLabel(v, addrBreak);
93323 if( eDest==SRT_Output || eDest==SRT_Coroutine ){
93324 sqlite3VdbeAddOp2(v, OP_Close, pseudoTab, 0);
93329 ** Return a pointer to a string containing the 'declaration type' of the
93330 ** expression pExpr. The string may be treated as static by the caller.
93332 ** The declaration type is the exact datatype definition extracted from the
93333 ** original CREATE TABLE statement if the expression is a column. The
93334 ** declaration type for a ROWID field is INTEGER. Exactly when an expression
93335 ** is considered a column can be complex in the presence of subqueries. The
93336 ** result-set expression in all of the following SELECT statements is
93337 ** considered a column by this function.
93339 ** SELECT col FROM tbl;
93340 ** SELECT (SELECT col FROM tbl;
93341 ** SELECT (SELECT col FROM tbl);
93342 ** SELECT abc FROM (SELECT col AS abc FROM tbl);
93344 ** The declaration type for any expression other than a column is NULL.
93346 static const char *columnType(
93347 NameContext *pNC,
93348 Expr *pExpr,
93349 const char **pzOriginDb,
93350 const char **pzOriginTab,
93351 const char **pzOriginCol
93353 char const *zType = 0;
93354 char const *zOriginDb = 0;
93355 char const *zOriginTab = 0;
93356 char const *zOriginCol = 0;
93357 int j;
93358 if( NEVER(pExpr==0) || pNC->pSrcList==0 ) return 0;
93360 switch( pExpr->op ){
93361 case TK_AGG_COLUMN:
93362 case TK_COLUMN: {
93363 /* The expression is a column. Locate the table the column is being
93364 ** extracted from in NameContext.pSrcList. This table may be real
93365 ** database table or a subquery.
93367 Table *pTab = 0; /* Table structure column is extracted from */
93368 Select *pS = 0; /* Select the column is extracted from */
93369 int iCol = pExpr->iColumn; /* Index of column in pTab */
93370 testcase( pExpr->op==TK_AGG_COLUMN );
93371 testcase( pExpr->op==TK_COLUMN );
93372 while( pNC && !pTab ){
93373 SrcList *pTabList = pNC->pSrcList;
93374 for(j=0;j<pTabList->nSrc && pTabList->a[j].iCursor!=pExpr->iTable;j++);
93375 if( j<pTabList->nSrc ){
93376 pTab = pTabList->a[j].pTab;
93377 pS = pTabList->a[j].pSelect;
93378 }else{
93379 pNC = pNC->pNext;
93383 if( pTab==0 ){
93384 /* At one time, code such as "SELECT new.x" within a trigger would
93385 ** cause this condition to run. Since then, we have restructured how
93386 ** trigger code is generated and so this condition is no longer
93387 ** possible. However, it can still be true for statements like
93388 ** the following:
93390 ** CREATE TABLE t1(col INTEGER);
93391 ** SELECT (SELECT t1.col) FROM FROM t1;
93393 ** when columnType() is called on the expression "t1.col" in the
93394 ** sub-select. In this case, set the column type to NULL, even
93395 ** though it should really be "INTEGER".
93397 ** This is not a problem, as the column type of "t1.col" is never
93398 ** used. When columnType() is called on the expression
93399 ** "(SELECT t1.col)", the correct type is returned (see the TK_SELECT
93400 ** branch below. */
93401 break;
93404 assert( pTab && pExpr->pTab==pTab );
93405 if( pS ){
93406 /* The "table" is actually a sub-select or a view in the FROM clause
93407 ** of the SELECT statement. Return the declaration type and origin
93408 ** data for the result-set column of the sub-select.
93410 if( iCol>=0 && ALWAYS(iCol<pS->pEList->nExpr) ){
93411 /* If iCol is less than zero, then the expression requests the
93412 ** rowid of the sub-select or view. This expression is legal (see
93413 ** test case misc2.2.2) - it always evaluates to NULL.
93415 NameContext sNC;
93416 Expr *p = pS->pEList->a[iCol].pExpr;
93417 sNC.pSrcList = pS->pSrc;
93418 sNC.pNext = pNC;
93419 sNC.pParse = pNC->pParse;
93420 zType = columnType(&sNC, p, &zOriginDb, &zOriginTab, &zOriginCol);
93422 }else if( ALWAYS(pTab->pSchema) ){
93423 /* A real table */
93424 assert( !pS );
93425 if( iCol<0 ) iCol = pTab->iPKey;
93426 assert( iCol==-1 || (iCol>=0 && iCol<pTab->nCol) );
93427 if( iCol<0 ){
93428 zType = "INTEGER";
93429 zOriginCol = "rowid";
93430 }else{
93431 zType = pTab->aCol[iCol].zType;
93432 zOriginCol = pTab->aCol[iCol].zName;
93434 zOriginTab = pTab->zName;
93435 if( pNC->pParse ){
93436 int iDb = sqlite3SchemaToIndex(pNC->pParse->db, pTab->pSchema);
93437 zOriginDb = pNC->pParse->db->aDb[iDb].zName;
93440 break;
93442 #ifndef SQLITE_OMIT_SUBQUERY
93443 case TK_SELECT: {
93444 /* The expression is a sub-select. Return the declaration type and
93445 ** origin info for the single column in the result set of the SELECT
93446 ** statement.
93448 NameContext sNC;
93449 Select *pS = pExpr->x.pSelect;
93450 Expr *p = pS->pEList->a[0].pExpr;
93451 assert( ExprHasProperty(pExpr, EP_xIsSelect) );
93452 sNC.pSrcList = pS->pSrc;
93453 sNC.pNext = pNC;
93454 sNC.pParse = pNC->pParse;
93455 zType = columnType(&sNC, p, &zOriginDb, &zOriginTab, &zOriginCol);
93456 break;
93458 #endif
93461 if( pzOriginDb ){
93462 assert( pzOriginTab && pzOriginCol );
93463 *pzOriginDb = zOriginDb;
93464 *pzOriginTab = zOriginTab;
93465 *pzOriginCol = zOriginCol;
93467 return zType;
93471 ** Generate code that will tell the VDBE the declaration types of columns
93472 ** in the result set.
93474 static void generateColumnTypes(
93475 Parse *pParse, /* Parser context */
93476 SrcList *pTabList, /* List of tables */
93477 ExprList *pEList /* Expressions defining the result set */
93479 #ifndef SQLITE_OMIT_DECLTYPE
93480 Vdbe *v = pParse->pVdbe;
93481 int i;
93482 NameContext sNC;
93483 sNC.pSrcList = pTabList;
93484 sNC.pParse = pParse;
93485 for(i=0; i<pEList->nExpr; i++){
93486 Expr *p = pEList->a[i].pExpr;
93487 const char *zType;
93488 #ifdef SQLITE_ENABLE_COLUMN_METADATA
93489 const char *zOrigDb = 0;
93490 const char *zOrigTab = 0;
93491 const char *zOrigCol = 0;
93492 zType = columnType(&sNC, p, &zOrigDb, &zOrigTab, &zOrigCol);
93494 /* The vdbe must make its own copy of the column-type and other
93495 ** column specific strings, in case the schema is reset before this
93496 ** virtual machine is deleted.
93498 sqlite3VdbeSetColName(v, i, COLNAME_DATABASE, zOrigDb, SQLITE_TRANSIENT);
93499 sqlite3VdbeSetColName(v, i, COLNAME_TABLE, zOrigTab, SQLITE_TRANSIENT);
93500 sqlite3VdbeSetColName(v, i, COLNAME_COLUMN, zOrigCol, SQLITE_TRANSIENT);
93501 #else
93502 zType = columnType(&sNC, p, 0, 0, 0);
93503 #endif
93504 sqlite3VdbeSetColName(v, i, COLNAME_DECLTYPE, zType, SQLITE_TRANSIENT);
93506 #endif /* SQLITE_OMIT_DECLTYPE */
93510 ** Generate code that will tell the VDBE the names of columns
93511 ** in the result set. This information is used to provide the
93512 ** azCol[] values in the callback.
93514 static void generateColumnNames(
93515 Parse *pParse, /* Parser context */
93516 SrcList *pTabList, /* List of tables */
93517 ExprList *pEList /* Expressions defining the result set */
93519 Vdbe *v = pParse->pVdbe;
93520 int i, j;
93521 sqlite3 *db = pParse->db;
93522 int fullNames, shortNames;
93524 #ifndef SQLITE_OMIT_EXPLAIN
93525 /* If this is an EXPLAIN, skip this step */
93526 if( pParse->explain ){
93527 return;
93529 #endif
93531 if( pParse->colNamesSet || NEVER(v==0) || db->mallocFailed ) return;
93532 pParse->colNamesSet = 1;
93533 fullNames = (db->flags & SQLITE_FullColNames)!=0;
93534 shortNames = (db->flags & SQLITE_ShortColNames)!=0;
93535 sqlite3VdbeSetNumCols(v, pEList->nExpr);
93536 for(i=0; i<pEList->nExpr; i++){
93537 Expr *p;
93538 p = pEList->a[i].pExpr;
93539 if( NEVER(p==0) ) continue;
93540 if( pEList->a[i].zName ){
93541 char *zName = pEList->a[i].zName;
93542 sqlite3VdbeSetColName(v, i, COLNAME_NAME, zName, SQLITE_TRANSIENT);
93543 }else if( (p->op==TK_COLUMN || p->op==TK_AGG_COLUMN) && pTabList ){
93544 Table *pTab;
93545 char *zCol;
93546 int iCol = p->iColumn;
93547 for(j=0; ALWAYS(j<pTabList->nSrc); j++){
93548 if( pTabList->a[j].iCursor==p->iTable ) break;
93550 assert( j<pTabList->nSrc );
93551 pTab = pTabList->a[j].pTab;
93552 if( iCol<0 ) iCol = pTab->iPKey;
93553 assert( iCol==-1 || (iCol>=0 && iCol<pTab->nCol) );
93554 if( iCol<0 ){
93555 zCol = "rowid";
93556 }else{
93557 zCol = pTab->aCol[iCol].zName;
93559 if( !shortNames && !fullNames ){
93560 sqlite3VdbeSetColName(v, i, COLNAME_NAME,
93561 sqlite3DbStrDup(db, pEList->a[i].zSpan), SQLITE_DYNAMIC);
93562 }else if( fullNames ){
93563 char *zName = 0;
93564 zName = sqlite3MPrintf(db, "%s.%s", pTab->zName, zCol);
93565 sqlite3VdbeSetColName(v, i, COLNAME_NAME, zName, SQLITE_DYNAMIC);
93566 }else{
93567 sqlite3VdbeSetColName(v, i, COLNAME_NAME, zCol, SQLITE_TRANSIENT);
93569 }else{
93570 sqlite3VdbeSetColName(v, i, COLNAME_NAME,
93571 sqlite3DbStrDup(db, pEList->a[i].zSpan), SQLITE_DYNAMIC);
93574 generateColumnTypes(pParse, pTabList, pEList);
93578 ** Given a an expression list (which is really the list of expressions
93579 ** that form the result set of a SELECT statement) compute appropriate
93580 ** column names for a table that would hold the expression list.
93582 ** All column names will be unique.
93584 ** Only the column names are computed. Column.zType, Column.zColl,
93585 ** and other fields of Column are zeroed.
93587 ** Return SQLITE_OK on success. If a memory allocation error occurs,
93588 ** store NULL in *paCol and 0 in *pnCol and return SQLITE_NOMEM.
93590 static int selectColumnsFromExprList(
93591 Parse *pParse, /* Parsing context */
93592 ExprList *pEList, /* Expr list from which to derive column names */
93593 int *pnCol, /* Write the number of columns here */
93594 Column **paCol /* Write the new column list here */
93596 sqlite3 *db = pParse->db; /* Database connection */
93597 int i, j; /* Loop counters */
93598 int cnt; /* Index added to make the name unique */
93599 Column *aCol, *pCol; /* For looping over result columns */
93600 int nCol; /* Number of columns in the result set */
93601 Expr *p; /* Expression for a single result column */
93602 char *zName; /* Column name */
93603 int nName; /* Size of name in zName[] */
93605 *pnCol = nCol = pEList->nExpr;
93606 aCol = *paCol = sqlite3DbMallocZero(db, sizeof(aCol[0])*nCol);
93607 if( aCol==0 ) return SQLITE_NOMEM;
93608 for(i=0, pCol=aCol; i<nCol; i++, pCol++){
93609 /* Get an appropriate name for the column
93611 p = pEList->a[i].pExpr;
93612 assert( p->pRight==0 || ExprHasProperty(p->pRight, EP_IntValue)
93613 || p->pRight->u.zToken==0 || p->pRight->u.zToken[0]!=0 );
93614 if( (zName = pEList->a[i].zName)!=0 ){
93615 /* If the column contains an "AS <name>" phrase, use <name> as the name */
93616 zName = sqlite3DbStrDup(db, zName);
93617 }else{
93618 Expr *pColExpr = p; /* The expression that is the result column name */
93619 Table *pTab; /* Table associated with this expression */
93620 while( pColExpr->op==TK_DOT ) pColExpr = pColExpr->pRight;
93621 if( pColExpr->op==TK_COLUMN && ALWAYS(pColExpr->pTab!=0) ){
93622 /* For columns use the column name name */
93623 int iCol = pColExpr->iColumn;
93624 pTab = pColExpr->pTab;
93625 if( iCol<0 ) iCol = pTab->iPKey;
93626 zName = sqlite3MPrintf(db, "%s",
93627 iCol>=0 ? pTab->aCol[iCol].zName : "rowid");
93628 }else if( pColExpr->op==TK_ID ){
93629 assert( !ExprHasProperty(pColExpr, EP_IntValue) );
93630 zName = sqlite3MPrintf(db, "%s", pColExpr->u.zToken);
93631 }else{
93632 /* Use the original text of the column expression as its name */
93633 zName = sqlite3MPrintf(db, "%s", pEList->a[i].zSpan);
93636 if( db->mallocFailed ){
93637 sqlite3DbFree(db, zName);
93638 break;
93641 /* Make sure the column name is unique. If the name is not unique,
93642 ** append a integer to the name so that it becomes unique.
93644 nName = sqlite3Strlen30(zName);
93645 for(j=cnt=0; j<i; j++){
93646 if( sqlite3StrICmp(aCol[j].zName, zName)==0 ){
93647 char *zNewName;
93648 zName[nName] = 0;
93649 zNewName = sqlite3MPrintf(db, "%s:%d", zName, ++cnt);
93650 sqlite3DbFree(db, zName);
93651 zName = zNewName;
93652 j = -1;
93653 if( zName==0 ) break;
93656 pCol->zName = zName;
93658 if( db->mallocFailed ){
93659 for(j=0; j<i; j++){
93660 sqlite3DbFree(db, aCol[j].zName);
93662 sqlite3DbFree(db, aCol);
93663 *paCol = 0;
93664 *pnCol = 0;
93665 return SQLITE_NOMEM;
93667 return SQLITE_OK;
93671 ** Add type and collation information to a column list based on
93672 ** a SELECT statement.
93674 ** The column list presumably came from selectColumnNamesFromExprList().
93675 ** The column list has only names, not types or collations. This
93676 ** routine goes through and adds the types and collations.
93678 ** This routine requires that all identifiers in the SELECT
93679 ** statement be resolved.
93681 static void selectAddColumnTypeAndCollation(
93682 Parse *pParse, /* Parsing contexts */
93683 int nCol, /* Number of columns */
93684 Column *aCol, /* List of columns */
93685 Select *pSelect /* SELECT used to determine types and collations */
93687 sqlite3 *db = pParse->db;
93688 NameContext sNC;
93689 Column *pCol;
93690 CollSeq *pColl;
93691 int i;
93692 Expr *p;
93693 struct ExprList_item *a;
93695 assert( pSelect!=0 );
93696 assert( (pSelect->selFlags & SF_Resolved)!=0 );
93697 assert( nCol==pSelect->pEList->nExpr || db->mallocFailed );
93698 if( db->mallocFailed ) return;
93699 memset(&sNC, 0, sizeof(sNC));
93700 sNC.pSrcList = pSelect->pSrc;
93701 a = pSelect->pEList->a;
93702 for(i=0, pCol=aCol; i<nCol; i++, pCol++){
93703 p = a[i].pExpr;
93704 pCol->zType = sqlite3DbStrDup(db, columnType(&sNC, p, 0, 0, 0));
93705 pCol->affinity = sqlite3ExprAffinity(p);
93706 if( pCol->affinity==0 ) pCol->affinity = SQLITE_AFF_NONE;
93707 pColl = sqlite3ExprCollSeq(pParse, p);
93708 if( pColl ){
93709 pCol->zColl = sqlite3DbStrDup(db, pColl->zName);
93715 ** Given a SELECT statement, generate a Table structure that describes
93716 ** the result set of that SELECT.
93718 SQLITE_PRIVATE Table *sqlite3ResultSetOfSelect(Parse *pParse, Select *pSelect){
93719 Table *pTab;
93720 sqlite3 *db = pParse->db;
93721 int savedFlags;
93723 savedFlags = db->flags;
93724 db->flags &= ~SQLITE_FullColNames;
93725 db->flags |= SQLITE_ShortColNames;
93726 sqlite3SelectPrep(pParse, pSelect, 0);
93727 if( pParse->nErr ) return 0;
93728 while( pSelect->pPrior ) pSelect = pSelect->pPrior;
93729 db->flags = savedFlags;
93730 pTab = sqlite3DbMallocZero(db, sizeof(Table) );
93731 if( pTab==0 ){
93732 return 0;
93734 /* The sqlite3ResultSetOfSelect() is only used n contexts where lookaside
93735 ** is disabled */
93736 assert( db->lookaside.bEnabled==0 );
93737 pTab->nRef = 1;
93738 pTab->zName = 0;
93739 pTab->nRowEst = 1000000;
93740 selectColumnsFromExprList(pParse, pSelect->pEList, &pTab->nCol, &pTab->aCol);
93741 selectAddColumnTypeAndCollation(pParse, pTab->nCol, pTab->aCol, pSelect);
93742 pTab->iPKey = -1;
93743 if( db->mallocFailed ){
93744 sqlite3DeleteTable(db, pTab);
93745 return 0;
93747 return pTab;
93751 ** Get a VDBE for the given parser context. Create a new one if necessary.
93752 ** If an error occurs, return NULL and leave a message in pParse.
93754 SQLITE_PRIVATE Vdbe *sqlite3GetVdbe(Parse *pParse){
93755 Vdbe *v = pParse->pVdbe;
93756 if( v==0 ){
93757 v = pParse->pVdbe = sqlite3VdbeCreate(pParse->db);
93758 #ifndef SQLITE_OMIT_TRACE
93759 if( v ){
93760 sqlite3VdbeAddOp0(v, OP_Trace);
93762 #endif
93764 return v;
93769 ** Compute the iLimit and iOffset fields of the SELECT based on the
93770 ** pLimit and pOffset expressions. pLimit and pOffset hold the expressions
93771 ** that appear in the original SQL statement after the LIMIT and OFFSET
93772 ** keywords. Or NULL if those keywords are omitted. iLimit and iOffset
93773 ** are the integer memory register numbers for counters used to compute
93774 ** the limit and offset. If there is no limit and/or offset, then
93775 ** iLimit and iOffset are negative.
93777 ** This routine changes the values of iLimit and iOffset only if
93778 ** a limit or offset is defined by pLimit and pOffset. iLimit and
93779 ** iOffset should have been preset to appropriate default values
93780 ** (usually but not always -1) prior to calling this routine.
93781 ** Only if pLimit!=0 or pOffset!=0 do the limit registers get
93782 ** redefined. The UNION ALL operator uses this property to force
93783 ** the reuse of the same limit and offset registers across multiple
93784 ** SELECT statements.
93786 static void computeLimitRegisters(Parse *pParse, Select *p, int iBreak){
93787 Vdbe *v = 0;
93788 int iLimit = 0;
93789 int iOffset;
93790 int addr1, n;
93791 if( p->iLimit ) return;
93794 ** "LIMIT -1" always shows all rows. There is some
93795 ** contraversy about what the correct behavior should be.
93796 ** The current implementation interprets "LIMIT 0" to mean
93797 ** no rows.
93799 sqlite3ExprCacheClear(pParse);
93800 assert( p->pOffset==0 || p->pLimit!=0 );
93801 if( p->pLimit ){
93802 p->iLimit = iLimit = ++pParse->nMem;
93803 v = sqlite3GetVdbe(pParse);
93804 if( NEVER(v==0) ) return; /* VDBE should have already been allocated */
93805 if( sqlite3ExprIsInteger(p->pLimit, &n) ){
93806 sqlite3VdbeAddOp2(v, OP_Integer, n, iLimit);
93807 VdbeComment((v, "LIMIT counter"));
93808 if( n==0 ){
93809 sqlite3VdbeAddOp2(v, OP_Goto, 0, iBreak);
93810 }else{
93811 if( p->nSelectRow > (double)n ) p->nSelectRow = (double)n;
93813 }else{
93814 sqlite3ExprCode(pParse, p->pLimit, iLimit);
93815 sqlite3VdbeAddOp1(v, OP_MustBeInt, iLimit);
93816 VdbeComment((v, "LIMIT counter"));
93817 sqlite3VdbeAddOp2(v, OP_IfZero, iLimit, iBreak);
93819 if( p->pOffset ){
93820 p->iOffset = iOffset = ++pParse->nMem;
93821 pParse->nMem++; /* Allocate an extra register for limit+offset */
93822 sqlite3ExprCode(pParse, p->pOffset, iOffset);
93823 sqlite3VdbeAddOp1(v, OP_MustBeInt, iOffset);
93824 VdbeComment((v, "OFFSET counter"));
93825 addr1 = sqlite3VdbeAddOp1(v, OP_IfPos, iOffset);
93826 sqlite3VdbeAddOp2(v, OP_Integer, 0, iOffset);
93827 sqlite3VdbeJumpHere(v, addr1);
93828 sqlite3VdbeAddOp3(v, OP_Add, iLimit, iOffset, iOffset+1);
93829 VdbeComment((v, "LIMIT+OFFSET"));
93830 addr1 = sqlite3VdbeAddOp1(v, OP_IfPos, iLimit);
93831 sqlite3VdbeAddOp2(v, OP_Integer, -1, iOffset+1);
93832 sqlite3VdbeJumpHere(v, addr1);
93837 #ifndef SQLITE_OMIT_COMPOUND_SELECT
93839 ** Return the appropriate collating sequence for the iCol-th column of
93840 ** the result set for the compound-select statement "p". Return NULL if
93841 ** the column has no default collating sequence.
93843 ** The collating sequence for the compound select is taken from the
93844 ** left-most term of the select that has a collating sequence.
93846 static CollSeq *multiSelectCollSeq(Parse *pParse, Select *p, int iCol){
93847 CollSeq *pRet;
93848 if( p->pPrior ){
93849 pRet = multiSelectCollSeq(pParse, p->pPrior, iCol);
93850 }else{
93851 pRet = 0;
93853 assert( iCol>=0 );
93854 if( pRet==0 && iCol<p->pEList->nExpr ){
93855 pRet = sqlite3ExprCollSeq(pParse, p->pEList->a[iCol].pExpr);
93857 return pRet;
93859 #endif /* SQLITE_OMIT_COMPOUND_SELECT */
93861 /* Forward reference */
93862 static int multiSelectOrderBy(
93863 Parse *pParse, /* Parsing context */
93864 Select *p, /* The right-most of SELECTs to be coded */
93865 SelectDest *pDest /* What to do with query results */
93869 #ifndef SQLITE_OMIT_COMPOUND_SELECT
93871 ** This routine is called to process a compound query form from
93872 ** two or more separate queries using UNION, UNION ALL, EXCEPT, or
93873 ** INTERSECT
93875 ** "p" points to the right-most of the two queries. the query on the
93876 ** left is p->pPrior. The left query could also be a compound query
93877 ** in which case this routine will be called recursively.
93879 ** The results of the total query are to be written into a destination
93880 ** of type eDest with parameter iParm.
93882 ** Example 1: Consider a three-way compound SQL statement.
93884 ** SELECT a FROM t1 UNION SELECT b FROM t2 UNION SELECT c FROM t3
93886 ** This statement is parsed up as follows:
93888 ** SELECT c FROM t3
93889 ** |
93890 ** `-----> SELECT b FROM t2
93891 ** |
93892 ** `------> SELECT a FROM t1
93894 ** The arrows in the diagram above represent the Select.pPrior pointer.
93895 ** So if this routine is called with p equal to the t3 query, then
93896 ** pPrior will be the t2 query. p->op will be TK_UNION in this case.
93898 ** Notice that because of the way SQLite parses compound SELECTs, the
93899 ** individual selects always group from left to right.
93901 static int multiSelect(
93902 Parse *pParse, /* Parsing context */
93903 Select *p, /* The right-most of SELECTs to be coded */
93904 SelectDest *pDest /* What to do with query results */
93906 int rc = SQLITE_OK; /* Success code from a subroutine */
93907 Select *pPrior; /* Another SELECT immediately to our left */
93908 Vdbe *v; /* Generate code to this VDBE */
93909 SelectDest dest; /* Alternative data destination */
93910 Select *pDelete = 0; /* Chain of simple selects to delete */
93911 sqlite3 *db; /* Database connection */
93912 #ifndef SQLITE_OMIT_EXPLAIN
93913 int iSub1; /* EQP id of left-hand query */
93914 int iSub2; /* EQP id of right-hand query */
93915 #endif
93917 /* Make sure there is no ORDER BY or LIMIT clause on prior SELECTs. Only
93918 ** the last (right-most) SELECT in the series may have an ORDER BY or LIMIT.
93920 assert( p && p->pPrior ); /* Calling function guarantees this much */
93921 db = pParse->db;
93922 pPrior = p->pPrior;
93923 assert( pPrior->pRightmost!=pPrior );
93924 assert( pPrior->pRightmost==p->pRightmost );
93925 dest = *pDest;
93926 if( pPrior->pOrderBy ){
93927 sqlite3ErrorMsg(pParse,"ORDER BY clause should come after %s not before",
93928 selectOpName(p->op));
93929 rc = 1;
93930 goto multi_select_end;
93932 if( pPrior->pLimit ){
93933 sqlite3ErrorMsg(pParse,"LIMIT clause should come after %s not before",
93934 selectOpName(p->op));
93935 rc = 1;
93936 goto multi_select_end;
93939 v = sqlite3GetVdbe(pParse);
93940 assert( v!=0 ); /* The VDBE already created by calling function */
93942 /* Create the destination temporary table if necessary
93944 if( dest.eDest==SRT_EphemTab ){
93945 assert( p->pEList );
93946 sqlite3VdbeAddOp2(v, OP_OpenEphemeral, dest.iParm, p->pEList->nExpr);
93947 sqlite3VdbeChangeP5(v, BTREE_UNORDERED);
93948 dest.eDest = SRT_Table;
93951 /* Make sure all SELECTs in the statement have the same number of elements
93952 ** in their result sets.
93954 assert( p->pEList && pPrior->pEList );
93955 if( p->pEList->nExpr!=pPrior->pEList->nExpr ){
93956 sqlite3ErrorMsg(pParse, "SELECTs to the left and right of %s"
93957 " do not have the same number of result columns", selectOpName(p->op));
93958 rc = 1;
93959 goto multi_select_end;
93962 /* Compound SELECTs that have an ORDER BY clause are handled separately.
93964 if( p->pOrderBy ){
93965 return multiSelectOrderBy(pParse, p, pDest);
93968 /* Generate code for the left and right SELECT statements.
93970 switch( p->op ){
93971 case TK_ALL: {
93972 int addr = 0;
93973 int nLimit;
93974 assert( !pPrior->pLimit );
93975 pPrior->pLimit = p->pLimit;
93976 pPrior->pOffset = p->pOffset;
93977 explainSetInteger(iSub1, pParse->iNextSelectId);
93978 rc = sqlite3Select(pParse, pPrior, &dest);
93979 p->pLimit = 0;
93980 p->pOffset = 0;
93981 if( rc ){
93982 goto multi_select_end;
93984 p->pPrior = 0;
93985 p->iLimit = pPrior->iLimit;
93986 p->iOffset = pPrior->iOffset;
93987 if( p->iLimit ){
93988 addr = sqlite3VdbeAddOp1(v, OP_IfZero, p->iLimit);
93989 VdbeComment((v, "Jump ahead if LIMIT reached"));
93991 explainSetInteger(iSub2, pParse->iNextSelectId);
93992 rc = sqlite3Select(pParse, p, &dest);
93993 testcase( rc!=SQLITE_OK );
93994 pDelete = p->pPrior;
93995 p->pPrior = pPrior;
93996 p->nSelectRow += pPrior->nSelectRow;
93997 if( pPrior->pLimit
93998 && sqlite3ExprIsInteger(pPrior->pLimit, &nLimit)
93999 && p->nSelectRow > (double)nLimit
94001 p->nSelectRow = (double)nLimit;
94003 if( addr ){
94004 sqlite3VdbeJumpHere(v, addr);
94006 break;
94008 case TK_EXCEPT:
94009 case TK_UNION: {
94010 int unionTab; /* Cursor number of the temporary table holding result */
94011 u8 op = 0; /* One of the SRT_ operations to apply to self */
94012 int priorOp; /* The SRT_ operation to apply to prior selects */
94013 Expr *pLimit, *pOffset; /* Saved values of p->nLimit and p->nOffset */
94014 int addr;
94015 SelectDest uniondest;
94017 testcase( p->op==TK_EXCEPT );
94018 testcase( p->op==TK_UNION );
94019 priorOp = SRT_Union;
94020 if( dest.eDest==priorOp && ALWAYS(!p->pLimit &&!p->pOffset) ){
94021 /* We can reuse a temporary table generated by a SELECT to our
94022 ** right.
94024 assert( p->pRightmost!=p ); /* Can only happen for leftward elements
94025 ** of a 3-way or more compound */
94026 assert( p->pLimit==0 ); /* Not allowed on leftward elements */
94027 assert( p->pOffset==0 ); /* Not allowed on leftward elements */
94028 unionTab = dest.iParm;
94029 }else{
94030 /* We will need to create our own temporary table to hold the
94031 ** intermediate results.
94033 unionTab = pParse->nTab++;
94034 assert( p->pOrderBy==0 );
94035 addr = sqlite3VdbeAddOp2(v, OP_OpenEphemeral, unionTab, 0);
94036 assert( p->addrOpenEphm[0] == -1 );
94037 p->addrOpenEphm[0] = addr;
94038 p->pRightmost->selFlags |= SF_UsesEphemeral;
94039 assert( p->pEList );
94042 /* Code the SELECT statements to our left
94044 assert( !pPrior->pOrderBy );
94045 sqlite3SelectDestInit(&uniondest, priorOp, unionTab);
94046 explainSetInteger(iSub1, pParse->iNextSelectId);
94047 rc = sqlite3Select(pParse, pPrior, &uniondest);
94048 if( rc ){
94049 goto multi_select_end;
94052 /* Code the current SELECT statement
94054 if( p->op==TK_EXCEPT ){
94055 op = SRT_Except;
94056 }else{
94057 assert( p->op==TK_UNION );
94058 op = SRT_Union;
94060 p->pPrior = 0;
94061 pLimit = p->pLimit;
94062 p->pLimit = 0;
94063 pOffset = p->pOffset;
94064 p->pOffset = 0;
94065 uniondest.eDest = op;
94066 explainSetInteger(iSub2, pParse->iNextSelectId);
94067 rc = sqlite3Select(pParse, p, &uniondest);
94068 testcase( rc!=SQLITE_OK );
94069 /* Query flattening in sqlite3Select() might refill p->pOrderBy.
94070 ** Be sure to delete p->pOrderBy, therefore, to avoid a memory leak. */
94071 sqlite3ExprListDelete(db, p->pOrderBy);
94072 pDelete = p->pPrior;
94073 p->pPrior = pPrior;
94074 p->pOrderBy = 0;
94075 if( p->op==TK_UNION ) p->nSelectRow += pPrior->nSelectRow;
94076 sqlite3ExprDelete(db, p->pLimit);
94077 p->pLimit = pLimit;
94078 p->pOffset = pOffset;
94079 p->iLimit = 0;
94080 p->iOffset = 0;
94082 /* Convert the data in the temporary table into whatever form
94083 ** it is that we currently need.
94085 assert( unionTab==dest.iParm || dest.eDest!=priorOp );
94086 if( dest.eDest!=priorOp ){
94087 int iCont, iBreak, iStart;
94088 assert( p->pEList );
94089 if( dest.eDest==SRT_Output ){
94090 Select *pFirst = p;
94091 while( pFirst->pPrior ) pFirst = pFirst->pPrior;
94092 generateColumnNames(pParse, 0, pFirst->pEList);
94094 iBreak = sqlite3VdbeMakeLabel(v);
94095 iCont = sqlite3VdbeMakeLabel(v);
94096 computeLimitRegisters(pParse, p, iBreak);
94097 sqlite3VdbeAddOp2(v, OP_Rewind, unionTab, iBreak);
94098 iStart = sqlite3VdbeCurrentAddr(v);
94099 selectInnerLoop(pParse, p, p->pEList, unionTab, p->pEList->nExpr,
94100 0, -1, &dest, iCont, iBreak);
94101 sqlite3VdbeResolveLabel(v, iCont);
94102 sqlite3VdbeAddOp2(v, OP_Next, unionTab, iStart);
94103 sqlite3VdbeResolveLabel(v, iBreak);
94104 sqlite3VdbeAddOp2(v, OP_Close, unionTab, 0);
94106 break;
94108 default: assert( p->op==TK_INTERSECT ); {
94109 int tab1, tab2;
94110 int iCont, iBreak, iStart;
94111 Expr *pLimit, *pOffset;
94112 int addr;
94113 SelectDest intersectdest;
94114 int r1;
94116 /* INTERSECT is different from the others since it requires
94117 ** two temporary tables. Hence it has its own case. Begin
94118 ** by allocating the tables we will need.
94120 tab1 = pParse->nTab++;
94121 tab2 = pParse->nTab++;
94122 assert( p->pOrderBy==0 );
94124 addr = sqlite3VdbeAddOp2(v, OP_OpenEphemeral, tab1, 0);
94125 assert( p->addrOpenEphm[0] == -1 );
94126 p->addrOpenEphm[0] = addr;
94127 p->pRightmost->selFlags |= SF_UsesEphemeral;
94128 assert( p->pEList );
94130 /* Code the SELECTs to our left into temporary table "tab1".
94132 sqlite3SelectDestInit(&intersectdest, SRT_Union, tab1);
94133 explainSetInteger(iSub1, pParse->iNextSelectId);
94134 rc = sqlite3Select(pParse, pPrior, &intersectdest);
94135 if( rc ){
94136 goto multi_select_end;
94139 /* Code the current SELECT into temporary table "tab2"
94141 addr = sqlite3VdbeAddOp2(v, OP_OpenEphemeral, tab2, 0);
94142 assert( p->addrOpenEphm[1] == -1 );
94143 p->addrOpenEphm[1] = addr;
94144 p->pPrior = 0;
94145 pLimit = p->pLimit;
94146 p->pLimit = 0;
94147 pOffset = p->pOffset;
94148 p->pOffset = 0;
94149 intersectdest.iParm = tab2;
94150 explainSetInteger(iSub2, pParse->iNextSelectId);
94151 rc = sqlite3Select(pParse, p, &intersectdest);
94152 testcase( rc!=SQLITE_OK );
94153 pDelete = p->pPrior;
94154 p->pPrior = pPrior;
94155 if( p->nSelectRow>pPrior->nSelectRow ) p->nSelectRow = pPrior->nSelectRow;
94156 sqlite3ExprDelete(db, p->pLimit);
94157 p->pLimit = pLimit;
94158 p->pOffset = pOffset;
94160 /* Generate code to take the intersection of the two temporary
94161 ** tables.
94163 assert( p->pEList );
94164 if( dest.eDest==SRT_Output ){
94165 Select *pFirst = p;
94166 while( pFirst->pPrior ) pFirst = pFirst->pPrior;
94167 generateColumnNames(pParse, 0, pFirst->pEList);
94169 iBreak = sqlite3VdbeMakeLabel(v);
94170 iCont = sqlite3VdbeMakeLabel(v);
94171 computeLimitRegisters(pParse, p, iBreak);
94172 sqlite3VdbeAddOp2(v, OP_Rewind, tab1, iBreak);
94173 r1 = sqlite3GetTempReg(pParse);
94174 iStart = sqlite3VdbeAddOp2(v, OP_RowKey, tab1, r1);
94175 sqlite3VdbeAddOp4Int(v, OP_NotFound, tab2, iCont, r1, 0);
94176 sqlite3ReleaseTempReg(pParse, r1);
94177 selectInnerLoop(pParse, p, p->pEList, tab1, p->pEList->nExpr,
94178 0, -1, &dest, iCont, iBreak);
94179 sqlite3VdbeResolveLabel(v, iCont);
94180 sqlite3VdbeAddOp2(v, OP_Next, tab1, iStart);
94181 sqlite3VdbeResolveLabel(v, iBreak);
94182 sqlite3VdbeAddOp2(v, OP_Close, tab2, 0);
94183 sqlite3VdbeAddOp2(v, OP_Close, tab1, 0);
94184 break;
94188 explainComposite(pParse, p->op, iSub1, iSub2, p->op!=TK_ALL);
94190 /* Compute collating sequences used by
94191 ** temporary tables needed to implement the compound select.
94192 ** Attach the KeyInfo structure to all temporary tables.
94194 ** This section is run by the right-most SELECT statement only.
94195 ** SELECT statements to the left always skip this part. The right-most
94196 ** SELECT might also skip this part if it has no ORDER BY clause and
94197 ** no temp tables are required.
94199 if( p->selFlags & SF_UsesEphemeral ){
94200 int i; /* Loop counter */
94201 KeyInfo *pKeyInfo; /* Collating sequence for the result set */
94202 Select *pLoop; /* For looping through SELECT statements */
94203 CollSeq **apColl; /* For looping through pKeyInfo->aColl[] */
94204 int nCol; /* Number of columns in result set */
94206 assert( p->pRightmost==p );
94207 nCol = p->pEList->nExpr;
94208 pKeyInfo = sqlite3DbMallocZero(db,
94209 sizeof(*pKeyInfo)+nCol*(sizeof(CollSeq*) + 1));
94210 if( !pKeyInfo ){
94211 rc = SQLITE_NOMEM;
94212 goto multi_select_end;
94215 pKeyInfo->enc = ENC(db);
94216 pKeyInfo->nField = (u16)nCol;
94218 for(i=0, apColl=pKeyInfo->aColl; i<nCol; i++, apColl++){
94219 *apColl = multiSelectCollSeq(pParse, p, i);
94220 if( 0==*apColl ){
94221 *apColl = db->pDfltColl;
94225 for(pLoop=p; pLoop; pLoop=pLoop->pPrior){
94226 for(i=0; i<2; i++){
94227 int addr = pLoop->addrOpenEphm[i];
94228 if( addr<0 ){
94229 /* If [0] is unused then [1] is also unused. So we can
94230 ** always safely abort as soon as the first unused slot is found */
94231 assert( pLoop->addrOpenEphm[1]<0 );
94232 break;
94234 sqlite3VdbeChangeP2(v, addr, nCol);
94235 sqlite3VdbeChangeP4(v, addr, (char*)pKeyInfo, P4_KEYINFO);
94236 pLoop->addrOpenEphm[i] = -1;
94239 sqlite3DbFree(db, pKeyInfo);
94242 multi_select_end:
94243 pDest->iMem = dest.iMem;
94244 pDest->nMem = dest.nMem;
94245 sqlite3SelectDelete(db, pDelete);
94246 return rc;
94248 #endif /* SQLITE_OMIT_COMPOUND_SELECT */
94251 ** Code an output subroutine for a coroutine implementation of a
94252 ** SELECT statment.
94254 ** The data to be output is contained in pIn->iMem. There are
94255 ** pIn->nMem columns to be output. pDest is where the output should
94256 ** be sent.
94258 ** regReturn is the number of the register holding the subroutine
94259 ** return address.
94261 ** If regPrev>0 then it is the first register in a vector that
94262 ** records the previous output. mem[regPrev] is a flag that is false
94263 ** if there has been no previous output. If regPrev>0 then code is
94264 ** generated to suppress duplicates. pKeyInfo is used for comparing
94265 ** keys.
94267 ** If the LIMIT found in p->iLimit is reached, jump immediately to
94268 ** iBreak.
94270 static int generateOutputSubroutine(
94271 Parse *pParse, /* Parsing context */
94272 Select *p, /* The SELECT statement */
94273 SelectDest *pIn, /* Coroutine supplying data */
94274 SelectDest *pDest, /* Where to send the data */
94275 int regReturn, /* The return address register */
94276 int regPrev, /* Previous result register. No uniqueness if 0 */
94277 KeyInfo *pKeyInfo, /* For comparing with previous entry */
94278 int p4type, /* The p4 type for pKeyInfo */
94279 int iBreak /* Jump here if we hit the LIMIT */
94281 Vdbe *v = pParse->pVdbe;
94282 int iContinue;
94283 int addr;
94285 addr = sqlite3VdbeCurrentAddr(v);
94286 iContinue = sqlite3VdbeMakeLabel(v);
94288 /* Suppress duplicates for UNION, EXCEPT, and INTERSECT
94290 if( regPrev ){
94291 int j1, j2;
94292 j1 = sqlite3VdbeAddOp1(v, OP_IfNot, regPrev);
94293 j2 = sqlite3VdbeAddOp4(v, OP_Compare, pIn->iMem, regPrev+1, pIn->nMem,
94294 (char*)pKeyInfo, p4type);
94295 sqlite3VdbeAddOp3(v, OP_Jump, j2+2, iContinue, j2+2);
94296 sqlite3VdbeJumpHere(v, j1);
94297 sqlite3ExprCodeCopy(pParse, pIn->iMem, regPrev+1, pIn->nMem);
94298 sqlite3VdbeAddOp2(v, OP_Integer, 1, regPrev);
94300 if( pParse->db->mallocFailed ) return 0;
94302 /* Suppress the the first OFFSET entries if there is an OFFSET clause
94304 codeOffset(v, p, iContinue);
94306 switch( pDest->eDest ){
94307 /* Store the result as data using a unique key.
94309 case SRT_Table:
94310 case SRT_EphemTab: {
94311 int r1 = sqlite3GetTempReg(pParse);
94312 int r2 = sqlite3GetTempReg(pParse);
94313 testcase( pDest->eDest==SRT_Table );
94314 testcase( pDest->eDest==SRT_EphemTab );
94315 sqlite3VdbeAddOp3(v, OP_MakeRecord, pIn->iMem, pIn->nMem, r1);
94316 sqlite3VdbeAddOp2(v, OP_NewRowid, pDest->iParm, r2);
94317 sqlite3VdbeAddOp3(v, OP_Insert, pDest->iParm, r1, r2);
94318 sqlite3VdbeChangeP5(v, OPFLAG_APPEND);
94319 sqlite3ReleaseTempReg(pParse, r2);
94320 sqlite3ReleaseTempReg(pParse, r1);
94321 break;
94324 #ifndef SQLITE_OMIT_SUBQUERY
94325 /* If we are creating a set for an "expr IN (SELECT ...)" construct,
94326 ** then there should be a single item on the stack. Write this
94327 ** item into the set table with bogus data.
94329 case SRT_Set: {
94330 int r1;
94331 assert( pIn->nMem==1 );
94332 p->affinity =
94333 sqlite3CompareAffinity(p->pEList->a[0].pExpr, pDest->affinity);
94334 r1 = sqlite3GetTempReg(pParse);
94335 sqlite3VdbeAddOp4(v, OP_MakeRecord, pIn->iMem, 1, r1, &p->affinity, 1);
94336 sqlite3ExprCacheAffinityChange(pParse, pIn->iMem, 1);
94337 sqlite3VdbeAddOp2(v, OP_IdxInsert, pDest->iParm, r1);
94338 sqlite3ReleaseTempReg(pParse, r1);
94339 break;
94342 #if 0 /* Never occurs on an ORDER BY query */
94343 /* If any row exist in the result set, record that fact and abort.
94345 case SRT_Exists: {
94346 sqlite3VdbeAddOp2(v, OP_Integer, 1, pDest->iParm);
94347 /* The LIMIT clause will terminate the loop for us */
94348 break;
94350 #endif
94352 /* If this is a scalar select that is part of an expression, then
94353 ** store the results in the appropriate memory cell and break out
94354 ** of the scan loop.
94356 case SRT_Mem: {
94357 assert( pIn->nMem==1 );
94358 sqlite3ExprCodeMove(pParse, pIn->iMem, pDest->iParm, 1);
94359 /* The LIMIT clause will jump out of the loop for us */
94360 break;
94362 #endif /* #ifndef SQLITE_OMIT_SUBQUERY */
94364 /* The results are stored in a sequence of registers
94365 ** starting at pDest->iMem. Then the co-routine yields.
94367 case SRT_Coroutine: {
94368 if( pDest->iMem==0 ){
94369 pDest->iMem = sqlite3GetTempRange(pParse, pIn->nMem);
94370 pDest->nMem = pIn->nMem;
94372 sqlite3ExprCodeMove(pParse, pIn->iMem, pDest->iMem, pDest->nMem);
94373 sqlite3VdbeAddOp1(v, OP_Yield, pDest->iParm);
94374 break;
94377 /* If none of the above, then the result destination must be
94378 ** SRT_Output. This routine is never called with any other
94379 ** destination other than the ones handled above or SRT_Output.
94381 ** For SRT_Output, results are stored in a sequence of registers.
94382 ** Then the OP_ResultRow opcode is used to cause sqlite3_step() to
94383 ** return the next row of result.
94385 default: {
94386 assert( pDest->eDest==SRT_Output );
94387 sqlite3VdbeAddOp2(v, OP_ResultRow, pIn->iMem, pIn->nMem);
94388 sqlite3ExprCacheAffinityChange(pParse, pIn->iMem, pIn->nMem);
94389 break;
94393 /* Jump to the end of the loop if the LIMIT is reached.
94395 if( p->iLimit ){
94396 sqlite3VdbeAddOp3(v, OP_IfZero, p->iLimit, iBreak, -1);
94399 /* Generate the subroutine return
94401 sqlite3VdbeResolveLabel(v, iContinue);
94402 sqlite3VdbeAddOp1(v, OP_Return, regReturn);
94404 return addr;
94408 ** Alternative compound select code generator for cases when there
94409 ** is an ORDER BY clause.
94411 ** We assume a query of the following form:
94413 ** <selectA> <operator> <selectB> ORDER BY <orderbylist>
94415 ** <operator> is one of UNION ALL, UNION, EXCEPT, or INTERSECT. The idea
94416 ** is to code both <selectA> and <selectB> with the ORDER BY clause as
94417 ** co-routines. Then run the co-routines in parallel and merge the results
94418 ** into the output. In addition to the two coroutines (called selectA and
94419 ** selectB) there are 7 subroutines:
94421 ** outA: Move the output of the selectA coroutine into the output
94422 ** of the compound query.
94424 ** outB: Move the output of the selectB coroutine into the output
94425 ** of the compound query. (Only generated for UNION and
94426 ** UNION ALL. EXCEPT and INSERTSECT never output a row that
94427 ** appears only in B.)
94429 ** AltB: Called when there is data from both coroutines and A<B.
94431 ** AeqB: Called when there is data from both coroutines and A==B.
94433 ** AgtB: Called when there is data from both coroutines and A>B.
94435 ** EofA: Called when data is exhausted from selectA.
94437 ** EofB: Called when data is exhausted from selectB.
94439 ** The implementation of the latter five subroutines depend on which
94440 ** <operator> is used:
94443 ** UNION ALL UNION EXCEPT INTERSECT
94444 ** ------------- ----------------- -------------- -----------------
94445 ** AltB: outA, nextA outA, nextA outA, nextA nextA
94447 ** AeqB: outA, nextA nextA nextA outA, nextA
94449 ** AgtB: outB, nextB outB, nextB nextB nextB
94451 ** EofA: outB, nextB outB, nextB halt halt
94453 ** EofB: outA, nextA outA, nextA outA, nextA halt
94455 ** In the AltB, AeqB, and AgtB subroutines, an EOF on A following nextA
94456 ** causes an immediate jump to EofA and an EOF on B following nextB causes
94457 ** an immediate jump to EofB. Within EofA and EofB, and EOF on entry or
94458 ** following nextX causes a jump to the end of the select processing.
94460 ** Duplicate removal in the UNION, EXCEPT, and INTERSECT cases is handled
94461 ** within the output subroutine. The regPrev register set holds the previously
94462 ** output value. A comparison is made against this value and the output
94463 ** is skipped if the next results would be the same as the previous.
94465 ** The implementation plan is to implement the two coroutines and seven
94466 ** subroutines first, then put the control logic at the bottom. Like this:
94468 ** goto Init
94469 ** coA: coroutine for left query (A)
94470 ** coB: coroutine for right query (B)
94471 ** outA: output one row of A
94472 ** outB: output one row of B (UNION and UNION ALL only)
94473 ** EofA: ...
94474 ** EofB: ...
94475 ** AltB: ...
94476 ** AeqB: ...
94477 ** AgtB: ...
94478 ** Init: initialize coroutine registers
94479 ** yield coA
94480 ** if eof(A) goto EofA
94481 ** yield coB
94482 ** if eof(B) goto EofB
94483 ** Cmpr: Compare A, B
94484 ** Jump AltB, AeqB, AgtB
94485 ** End: ...
94487 ** We call AltB, AeqB, AgtB, EofA, and EofB "subroutines" but they are not
94488 ** actually called using Gosub and they do not Return. EofA and EofB loop
94489 ** until all data is exhausted then jump to the "end" labe. AltB, AeqB,
94490 ** and AgtB jump to either L2 or to one of EofA or EofB.
94492 #ifndef SQLITE_OMIT_COMPOUND_SELECT
94493 static int multiSelectOrderBy(
94494 Parse *pParse, /* Parsing context */
94495 Select *p, /* The right-most of SELECTs to be coded */
94496 SelectDest *pDest /* What to do with query results */
94498 int i, j; /* Loop counters */
94499 Select *pPrior; /* Another SELECT immediately to our left */
94500 Vdbe *v; /* Generate code to this VDBE */
94501 SelectDest destA; /* Destination for coroutine A */
94502 SelectDest destB; /* Destination for coroutine B */
94503 int regAddrA; /* Address register for select-A coroutine */
94504 int regEofA; /* Flag to indicate when select-A is complete */
94505 int regAddrB; /* Address register for select-B coroutine */
94506 int regEofB; /* Flag to indicate when select-B is complete */
94507 int addrSelectA; /* Address of the select-A coroutine */
94508 int addrSelectB; /* Address of the select-B coroutine */
94509 int regOutA; /* Address register for the output-A subroutine */
94510 int regOutB; /* Address register for the output-B subroutine */
94511 int addrOutA; /* Address of the output-A subroutine */
94512 int addrOutB = 0; /* Address of the output-B subroutine */
94513 int addrEofA; /* Address of the select-A-exhausted subroutine */
94514 int addrEofB; /* Address of the select-B-exhausted subroutine */
94515 int addrAltB; /* Address of the A<B subroutine */
94516 int addrAeqB; /* Address of the A==B subroutine */
94517 int addrAgtB; /* Address of the A>B subroutine */
94518 int regLimitA; /* Limit register for select-A */
94519 int regLimitB; /* Limit register for select-A */
94520 int regPrev; /* A range of registers to hold previous output */
94521 int savedLimit; /* Saved value of p->iLimit */
94522 int savedOffset; /* Saved value of p->iOffset */
94523 int labelCmpr; /* Label for the start of the merge algorithm */
94524 int labelEnd; /* Label for the end of the overall SELECT stmt */
94525 int j1; /* Jump instructions that get retargetted */
94526 int op; /* One of TK_ALL, TK_UNION, TK_EXCEPT, TK_INTERSECT */
94527 KeyInfo *pKeyDup = 0; /* Comparison information for duplicate removal */
94528 KeyInfo *pKeyMerge; /* Comparison information for merging rows */
94529 sqlite3 *db; /* Database connection */
94530 ExprList *pOrderBy; /* The ORDER BY clause */
94531 int nOrderBy; /* Number of terms in the ORDER BY clause */
94532 int *aPermute; /* Mapping from ORDER BY terms to result set columns */
94533 #ifndef SQLITE_OMIT_EXPLAIN
94534 int iSub1; /* EQP id of left-hand query */
94535 int iSub2; /* EQP id of right-hand query */
94536 #endif
94538 assert( p->pOrderBy!=0 );
94539 assert( pKeyDup==0 ); /* "Managed" code needs this. Ticket #3382. */
94540 db = pParse->db;
94541 v = pParse->pVdbe;
94542 assert( v!=0 ); /* Already thrown the error if VDBE alloc failed */
94543 labelEnd = sqlite3VdbeMakeLabel(v);
94544 labelCmpr = sqlite3VdbeMakeLabel(v);
94547 /* Patch up the ORDER BY clause
94549 op = p->op;
94550 pPrior = p->pPrior;
94551 assert( pPrior->pOrderBy==0 );
94552 pOrderBy = p->pOrderBy;
94553 assert( pOrderBy );
94554 nOrderBy = pOrderBy->nExpr;
94556 /* For operators other than UNION ALL we have to make sure that
94557 ** the ORDER BY clause covers every term of the result set. Add
94558 ** terms to the ORDER BY clause as necessary.
94560 if( op!=TK_ALL ){
94561 for(i=1; db->mallocFailed==0 && i<=p->pEList->nExpr; i++){
94562 struct ExprList_item *pItem;
94563 for(j=0, pItem=pOrderBy->a; j<nOrderBy; j++, pItem++){
94564 assert( pItem->iCol>0 );
94565 if( pItem->iCol==i ) break;
94567 if( j==nOrderBy ){
94568 Expr *pNew = sqlite3Expr(db, TK_INTEGER, 0);
94569 if( pNew==0 ) return SQLITE_NOMEM;
94570 pNew->flags |= EP_IntValue;
94571 pNew->u.iValue = i;
94572 pOrderBy = sqlite3ExprListAppend(pParse, pOrderBy, pNew);
94573 pOrderBy->a[nOrderBy++].iCol = (u16)i;
94578 /* Compute the comparison permutation and keyinfo that is used with
94579 ** the permutation used to determine if the next
94580 ** row of results comes from selectA or selectB. Also add explicit
94581 ** collations to the ORDER BY clause terms so that when the subqueries
94582 ** to the right and the left are evaluated, they use the correct
94583 ** collation.
94585 aPermute = sqlite3DbMallocRaw(db, sizeof(int)*nOrderBy);
94586 if( aPermute ){
94587 struct ExprList_item *pItem;
94588 for(i=0, pItem=pOrderBy->a; i<nOrderBy; i++, pItem++){
94589 assert( pItem->iCol>0 && pItem->iCol<=p->pEList->nExpr );
94590 aPermute[i] = pItem->iCol - 1;
94592 pKeyMerge =
94593 sqlite3DbMallocRaw(db, sizeof(*pKeyMerge)+nOrderBy*(sizeof(CollSeq*)+1));
94594 if( pKeyMerge ){
94595 pKeyMerge->aSortOrder = (u8*)&pKeyMerge->aColl[nOrderBy];
94596 pKeyMerge->nField = (u16)nOrderBy;
94597 pKeyMerge->enc = ENC(db);
94598 for(i=0; i<nOrderBy; i++){
94599 CollSeq *pColl;
94600 Expr *pTerm = pOrderBy->a[i].pExpr;
94601 if( pTerm->flags & EP_ExpCollate ){
94602 pColl = pTerm->pColl;
94603 }else{
94604 pColl = multiSelectCollSeq(pParse, p, aPermute[i]);
94605 pTerm->flags |= EP_ExpCollate;
94606 pTerm->pColl = pColl;
94608 pKeyMerge->aColl[i] = pColl;
94609 pKeyMerge->aSortOrder[i] = pOrderBy->a[i].sortOrder;
94612 }else{
94613 pKeyMerge = 0;
94616 /* Reattach the ORDER BY clause to the query.
94618 p->pOrderBy = pOrderBy;
94619 pPrior->pOrderBy = sqlite3ExprListDup(pParse->db, pOrderBy, 0);
94621 /* Allocate a range of temporary registers and the KeyInfo needed
94622 ** for the logic that removes duplicate result rows when the
94623 ** operator is UNION, EXCEPT, or INTERSECT (but not UNION ALL).
94625 if( op==TK_ALL ){
94626 regPrev = 0;
94627 }else{
94628 int nExpr = p->pEList->nExpr;
94629 assert( nOrderBy>=nExpr || db->mallocFailed );
94630 regPrev = sqlite3GetTempRange(pParse, nExpr+1);
94631 sqlite3VdbeAddOp2(v, OP_Integer, 0, regPrev);
94632 pKeyDup = sqlite3DbMallocZero(db,
94633 sizeof(*pKeyDup) + nExpr*(sizeof(CollSeq*)+1) );
94634 if( pKeyDup ){
94635 pKeyDup->aSortOrder = (u8*)&pKeyDup->aColl[nExpr];
94636 pKeyDup->nField = (u16)nExpr;
94637 pKeyDup->enc = ENC(db);
94638 for(i=0; i<nExpr; i++){
94639 pKeyDup->aColl[i] = multiSelectCollSeq(pParse, p, i);
94640 pKeyDup->aSortOrder[i] = 0;
94645 /* Separate the left and the right query from one another
94647 p->pPrior = 0;
94648 sqlite3ResolveOrderGroupBy(pParse, p, p->pOrderBy, "ORDER");
94649 if( pPrior->pPrior==0 ){
94650 sqlite3ResolveOrderGroupBy(pParse, pPrior, pPrior->pOrderBy, "ORDER");
94653 /* Compute the limit registers */
94654 computeLimitRegisters(pParse, p, labelEnd);
94655 if( p->iLimit && op==TK_ALL ){
94656 regLimitA = ++pParse->nMem;
94657 regLimitB = ++pParse->nMem;
94658 sqlite3VdbeAddOp2(v, OP_Copy, p->iOffset ? p->iOffset+1 : p->iLimit,
94659 regLimitA);
94660 sqlite3VdbeAddOp2(v, OP_Copy, regLimitA, regLimitB);
94661 }else{
94662 regLimitA = regLimitB = 0;
94664 sqlite3ExprDelete(db, p->pLimit);
94665 p->pLimit = 0;
94666 sqlite3ExprDelete(db, p->pOffset);
94667 p->pOffset = 0;
94669 regAddrA = ++pParse->nMem;
94670 regEofA = ++pParse->nMem;
94671 regAddrB = ++pParse->nMem;
94672 regEofB = ++pParse->nMem;
94673 regOutA = ++pParse->nMem;
94674 regOutB = ++pParse->nMem;
94675 sqlite3SelectDestInit(&destA, SRT_Coroutine, regAddrA);
94676 sqlite3SelectDestInit(&destB, SRT_Coroutine, regAddrB);
94678 /* Jump past the various subroutines and coroutines to the main
94679 ** merge loop
94681 j1 = sqlite3VdbeAddOp0(v, OP_Goto);
94682 addrSelectA = sqlite3VdbeCurrentAddr(v);
94685 /* Generate a coroutine to evaluate the SELECT statement to the
94686 ** left of the compound operator - the "A" select.
94688 VdbeNoopComment((v, "Begin coroutine for left SELECT"));
94689 pPrior->iLimit = regLimitA;
94690 explainSetInteger(iSub1, pParse->iNextSelectId);
94691 sqlite3Select(pParse, pPrior, &destA);
94692 sqlite3VdbeAddOp2(v, OP_Integer, 1, regEofA);
94693 sqlite3VdbeAddOp1(v, OP_Yield, regAddrA);
94694 VdbeNoopComment((v, "End coroutine for left SELECT"));
94696 /* Generate a coroutine to evaluate the SELECT statement on
94697 ** the right - the "B" select
94699 addrSelectB = sqlite3VdbeCurrentAddr(v);
94700 VdbeNoopComment((v, "Begin coroutine for right SELECT"));
94701 savedLimit = p->iLimit;
94702 savedOffset = p->iOffset;
94703 p->iLimit = regLimitB;
94704 p->iOffset = 0;
94705 explainSetInteger(iSub2, pParse->iNextSelectId);
94706 sqlite3Select(pParse, p, &destB);
94707 p->iLimit = savedLimit;
94708 p->iOffset = savedOffset;
94709 sqlite3VdbeAddOp2(v, OP_Integer, 1, regEofB);
94710 sqlite3VdbeAddOp1(v, OP_Yield, regAddrB);
94711 VdbeNoopComment((v, "End coroutine for right SELECT"));
94713 /* Generate a subroutine that outputs the current row of the A
94714 ** select as the next output row of the compound select.
94716 VdbeNoopComment((v, "Output routine for A"));
94717 addrOutA = generateOutputSubroutine(pParse,
94718 p, &destA, pDest, regOutA,
94719 regPrev, pKeyDup, P4_KEYINFO_HANDOFF, labelEnd);
94721 /* Generate a subroutine that outputs the current row of the B
94722 ** select as the next output row of the compound select.
94724 if( op==TK_ALL || op==TK_UNION ){
94725 VdbeNoopComment((v, "Output routine for B"));
94726 addrOutB = generateOutputSubroutine(pParse,
94727 p, &destB, pDest, regOutB,
94728 regPrev, pKeyDup, P4_KEYINFO_STATIC, labelEnd);
94731 /* Generate a subroutine to run when the results from select A
94732 ** are exhausted and only data in select B remains.
94734 VdbeNoopComment((v, "eof-A subroutine"));
94735 if( op==TK_EXCEPT || op==TK_INTERSECT ){
94736 addrEofA = sqlite3VdbeAddOp2(v, OP_Goto, 0, labelEnd);
94737 }else{
94738 addrEofA = sqlite3VdbeAddOp2(v, OP_If, regEofB, labelEnd);
94739 sqlite3VdbeAddOp2(v, OP_Gosub, regOutB, addrOutB);
94740 sqlite3VdbeAddOp1(v, OP_Yield, regAddrB);
94741 sqlite3VdbeAddOp2(v, OP_Goto, 0, addrEofA);
94742 p->nSelectRow += pPrior->nSelectRow;
94745 /* Generate a subroutine to run when the results from select B
94746 ** are exhausted and only data in select A remains.
94748 if( op==TK_INTERSECT ){
94749 addrEofB = addrEofA;
94750 if( p->nSelectRow > pPrior->nSelectRow ) p->nSelectRow = pPrior->nSelectRow;
94751 }else{
94752 VdbeNoopComment((v, "eof-B subroutine"));
94753 addrEofB = sqlite3VdbeAddOp2(v, OP_If, regEofA, labelEnd);
94754 sqlite3VdbeAddOp2(v, OP_Gosub, regOutA, addrOutA);
94755 sqlite3VdbeAddOp1(v, OP_Yield, regAddrA);
94756 sqlite3VdbeAddOp2(v, OP_Goto, 0, addrEofB);
94759 /* Generate code to handle the case of A<B
94761 VdbeNoopComment((v, "A-lt-B subroutine"));
94762 addrAltB = sqlite3VdbeAddOp2(v, OP_Gosub, regOutA, addrOutA);
94763 sqlite3VdbeAddOp1(v, OP_Yield, regAddrA);
94764 sqlite3VdbeAddOp2(v, OP_If, regEofA, addrEofA);
94765 sqlite3VdbeAddOp2(v, OP_Goto, 0, labelCmpr);
94767 /* Generate code to handle the case of A==B
94769 if( op==TK_ALL ){
94770 addrAeqB = addrAltB;
94771 }else if( op==TK_INTERSECT ){
94772 addrAeqB = addrAltB;
94773 addrAltB++;
94774 }else{
94775 VdbeNoopComment((v, "A-eq-B subroutine"));
94776 addrAeqB =
94777 sqlite3VdbeAddOp1(v, OP_Yield, regAddrA);
94778 sqlite3VdbeAddOp2(v, OP_If, regEofA, addrEofA);
94779 sqlite3VdbeAddOp2(v, OP_Goto, 0, labelCmpr);
94782 /* Generate code to handle the case of A>B
94784 VdbeNoopComment((v, "A-gt-B subroutine"));
94785 addrAgtB = sqlite3VdbeCurrentAddr(v);
94786 if( op==TK_ALL || op==TK_UNION ){
94787 sqlite3VdbeAddOp2(v, OP_Gosub, regOutB, addrOutB);
94789 sqlite3VdbeAddOp1(v, OP_Yield, regAddrB);
94790 sqlite3VdbeAddOp2(v, OP_If, regEofB, addrEofB);
94791 sqlite3VdbeAddOp2(v, OP_Goto, 0, labelCmpr);
94793 /* This code runs once to initialize everything.
94795 sqlite3VdbeJumpHere(v, j1);
94796 sqlite3VdbeAddOp2(v, OP_Integer, 0, regEofA);
94797 sqlite3VdbeAddOp2(v, OP_Integer, 0, regEofB);
94798 sqlite3VdbeAddOp2(v, OP_Gosub, regAddrA, addrSelectA);
94799 sqlite3VdbeAddOp2(v, OP_Gosub, regAddrB, addrSelectB);
94800 sqlite3VdbeAddOp2(v, OP_If, regEofA, addrEofA);
94801 sqlite3VdbeAddOp2(v, OP_If, regEofB, addrEofB);
94803 /* Implement the main merge loop
94805 sqlite3VdbeResolveLabel(v, labelCmpr);
94806 sqlite3VdbeAddOp4(v, OP_Permutation, 0, 0, 0, (char*)aPermute, P4_INTARRAY);
94807 sqlite3VdbeAddOp4(v, OP_Compare, destA.iMem, destB.iMem, nOrderBy,
94808 (char*)pKeyMerge, P4_KEYINFO_HANDOFF);
94809 sqlite3VdbeAddOp3(v, OP_Jump, addrAltB, addrAeqB, addrAgtB);
94811 /* Release temporary registers
94813 if( regPrev ){
94814 sqlite3ReleaseTempRange(pParse, regPrev, nOrderBy+1);
94817 /* Jump to the this point in order to terminate the query.
94819 sqlite3VdbeResolveLabel(v, labelEnd);
94821 /* Set the number of output columns
94823 if( pDest->eDest==SRT_Output ){
94824 Select *pFirst = pPrior;
94825 while( pFirst->pPrior ) pFirst = pFirst->pPrior;
94826 generateColumnNames(pParse, 0, pFirst->pEList);
94829 /* Reassembly the compound query so that it will be freed correctly
94830 ** by the calling function */
94831 if( p->pPrior ){
94832 sqlite3SelectDelete(db, p->pPrior);
94834 p->pPrior = pPrior;
94836 /*** TBD: Insert subroutine calls to close cursors on incomplete
94837 **** subqueries ****/
94838 explainComposite(pParse, p->op, iSub1, iSub2, 0);
94839 return SQLITE_OK;
94841 #endif
94843 #if !defined(SQLITE_OMIT_SUBQUERY) || !defined(SQLITE_OMIT_VIEW)
94844 /* Forward Declarations */
94845 static void substExprList(sqlite3*, ExprList*, int, ExprList*);
94846 static void substSelect(sqlite3*, Select *, int, ExprList *);
94849 ** Scan through the expression pExpr. Replace every reference to
94850 ** a column in table number iTable with a copy of the iColumn-th
94851 ** entry in pEList. (But leave references to the ROWID column
94852 ** unchanged.)
94854 ** This routine is part of the flattening procedure. A subquery
94855 ** whose result set is defined by pEList appears as entry in the
94856 ** FROM clause of a SELECT such that the VDBE cursor assigned to that
94857 ** FORM clause entry is iTable. This routine make the necessary
94858 ** changes to pExpr so that it refers directly to the source table
94859 ** of the subquery rather the result set of the subquery.
94861 static Expr *substExpr(
94862 sqlite3 *db, /* Report malloc errors to this connection */
94863 Expr *pExpr, /* Expr in which substitution occurs */
94864 int iTable, /* Table to be substituted */
94865 ExprList *pEList /* Substitute expressions */
94867 if( pExpr==0 ) return 0;
94868 if( pExpr->op==TK_COLUMN && pExpr->iTable==iTable ){
94869 if( pExpr->iColumn<0 ){
94870 pExpr->op = TK_NULL;
94871 }else{
94872 Expr *pNew;
94873 assert( pEList!=0 && pExpr->iColumn<pEList->nExpr );
94874 assert( pExpr->pLeft==0 && pExpr->pRight==0 );
94875 pNew = sqlite3ExprDup(db, pEList->a[pExpr->iColumn].pExpr, 0);
94876 if( pNew && pExpr->pColl ){
94877 pNew->pColl = pExpr->pColl;
94879 sqlite3ExprDelete(db, pExpr);
94880 pExpr = pNew;
94882 }else{
94883 pExpr->pLeft = substExpr(db, pExpr->pLeft, iTable, pEList);
94884 pExpr->pRight = substExpr(db, pExpr->pRight, iTable, pEList);
94885 if( ExprHasProperty(pExpr, EP_xIsSelect) ){
94886 substSelect(db, pExpr->x.pSelect, iTable, pEList);
94887 }else{
94888 substExprList(db, pExpr->x.pList, iTable, pEList);
94891 return pExpr;
94893 static void substExprList(
94894 sqlite3 *db, /* Report malloc errors here */
94895 ExprList *pList, /* List to scan and in which to make substitutes */
94896 int iTable, /* Table to be substituted */
94897 ExprList *pEList /* Substitute values */
94899 int i;
94900 if( pList==0 ) return;
94901 for(i=0; i<pList->nExpr; i++){
94902 pList->a[i].pExpr = substExpr(db, pList->a[i].pExpr, iTable, pEList);
94905 static void substSelect(
94906 sqlite3 *db, /* Report malloc errors here */
94907 Select *p, /* SELECT statement in which to make substitutions */
94908 int iTable, /* Table to be replaced */
94909 ExprList *pEList /* Substitute values */
94911 SrcList *pSrc;
94912 struct SrcList_item *pItem;
94913 int i;
94914 if( !p ) return;
94915 substExprList(db, p->pEList, iTable, pEList);
94916 substExprList(db, p->pGroupBy, iTable, pEList);
94917 substExprList(db, p->pOrderBy, iTable, pEList);
94918 p->pHaving = substExpr(db, p->pHaving, iTable, pEList);
94919 p->pWhere = substExpr(db, p->pWhere, iTable, pEList);
94920 substSelect(db, p->pPrior, iTable, pEList);
94921 pSrc = p->pSrc;
94922 assert( pSrc ); /* Even for (SELECT 1) we have: pSrc!=0 but pSrc->nSrc==0 */
94923 if( ALWAYS(pSrc) ){
94924 for(i=pSrc->nSrc, pItem=pSrc->a; i>0; i--, pItem++){
94925 substSelect(db, pItem->pSelect, iTable, pEList);
94929 #endif /* !defined(SQLITE_OMIT_SUBQUERY) || !defined(SQLITE_OMIT_VIEW) */
94931 #if !defined(SQLITE_OMIT_SUBQUERY) || !defined(SQLITE_OMIT_VIEW)
94933 ** This routine attempts to flatten subqueries in order to speed
94934 ** execution. It returns 1 if it makes changes and 0 if no flattening
94935 ** occurs.
94937 ** To understand the concept of flattening, consider the following
94938 ** query:
94940 ** SELECT a FROM (SELECT x+y AS a FROM t1 WHERE z<100) WHERE a>5
94942 ** The default way of implementing this query is to execute the
94943 ** subquery first and store the results in a temporary table, then
94944 ** run the outer query on that temporary table. This requires two
94945 ** passes over the data. Furthermore, because the temporary table
94946 ** has no indices, the WHERE clause on the outer query cannot be
94947 ** optimized.
94949 ** This routine attempts to rewrite queries such as the above into
94950 ** a single flat select, like this:
94952 ** SELECT x+y AS a FROM t1 WHERE z<100 AND a>5
94954 ** The code generated for this simpification gives the same result
94955 ** but only has to scan the data once. And because indices might
94956 ** exist on the table t1, a complete scan of the data might be
94957 ** avoided.
94959 ** Flattening is only attempted if all of the following are true:
94961 ** (1) The subquery and the outer query do not both use aggregates.
94963 ** (2) The subquery is not an aggregate or the outer query is not a join.
94965 ** (3) The subquery is not the right operand of a left outer join
94966 ** (Originally ticket #306. Strengthened by ticket #3300)
94968 ** (4) The subquery is not DISTINCT.
94970 ** (**) At one point restrictions (4) and (5) defined a subset of DISTINCT
94971 ** sub-queries that were excluded from this optimization. Restriction
94972 ** (4) has since been expanded to exclude all DISTINCT subqueries.
94974 ** (6) The subquery does not use aggregates or the outer query is not
94975 ** DISTINCT.
94977 ** (7) The subquery has a FROM clause.
94979 ** (8) The subquery does not use LIMIT or the outer query is not a join.
94981 ** (9) The subquery does not use LIMIT or the outer query does not use
94982 ** aggregates.
94984 ** (10) The subquery does not use aggregates or the outer query does not
94985 ** use LIMIT.
94987 ** (11) The subquery and the outer query do not both have ORDER BY clauses.
94989 ** (**) Not implemented. Subsumed into restriction (3). Was previously
94990 ** a separate restriction deriving from ticket #350.
94992 ** (13) The subquery and outer query do not both use LIMIT.
94994 ** (14) The subquery does not use OFFSET.
94996 ** (15) The outer query is not part of a compound select or the
94997 ** subquery does not have a LIMIT clause.
94998 ** (See ticket #2339 and ticket [02a8e81d44]).
95000 ** (16) The outer query is not an aggregate or the subquery does
95001 ** not contain ORDER BY. (Ticket #2942) This used to not matter
95002 ** until we introduced the group_concat() function.
95004 ** (17) The sub-query is not a compound select, or it is a UNION ALL
95005 ** compound clause made up entirely of non-aggregate queries, and
95006 ** the parent query:
95008 ** * is not itself part of a compound select,
95009 ** * is not an aggregate or DISTINCT query, and
95010 ** * has no other tables or sub-selects in the FROM clause.
95012 ** The parent and sub-query may contain WHERE clauses. Subject to
95013 ** rules (11), (13) and (14), they may also contain ORDER BY,
95014 ** LIMIT and OFFSET clauses.
95016 ** (18) If the sub-query is a compound select, then all terms of the
95017 ** ORDER by clause of the parent must be simple references to
95018 ** columns of the sub-query.
95020 ** (19) The subquery does not use LIMIT or the outer query does not
95021 ** have a WHERE clause.
95023 ** (20) If the sub-query is a compound select, then it must not use
95024 ** an ORDER BY clause. Ticket #3773. We could relax this constraint
95025 ** somewhat by saying that the terms of the ORDER BY clause must
95026 ** appear as unmodified result columns in the outer query. But
95027 ** have other optimizations in mind to deal with that case.
95029 ** (21) The subquery does not use LIMIT or the outer query is not
95030 ** DISTINCT. (See ticket [752e1646fc]).
95032 ** In this routine, the "p" parameter is a pointer to the outer query.
95033 ** The subquery is p->pSrc->a[iFrom]. isAgg is true if the outer query
95034 ** uses aggregates and subqueryIsAgg is true if the subquery uses aggregates.
95036 ** If flattening is not attempted, this routine is a no-op and returns 0.
95037 ** If flattening is attempted this routine returns 1.
95039 ** All of the expression analysis must occur on both the outer query and
95040 ** the subquery before this routine runs.
95042 static int flattenSubquery(
95043 Parse *pParse, /* Parsing context */
95044 Select *p, /* The parent or outer SELECT statement */
95045 int iFrom, /* Index in p->pSrc->a[] of the inner subquery */
95046 int isAgg, /* True if outer SELECT uses aggregate functions */
95047 int subqueryIsAgg /* True if the subquery uses aggregate functions */
95049 const char *zSavedAuthContext = pParse->zAuthContext;
95050 Select *pParent;
95051 Select *pSub; /* The inner query or "subquery" */
95052 Select *pSub1; /* Pointer to the rightmost select in sub-query */
95053 SrcList *pSrc; /* The FROM clause of the outer query */
95054 SrcList *pSubSrc; /* The FROM clause of the subquery */
95055 ExprList *pList; /* The result set of the outer query */
95056 int iParent; /* VDBE cursor number of the pSub result set temp table */
95057 int i; /* Loop counter */
95058 Expr *pWhere; /* The WHERE clause */
95059 struct SrcList_item *pSubitem; /* The subquery */
95060 sqlite3 *db = pParse->db;
95062 /* Check to see if flattening is permitted. Return 0 if not.
95064 assert( p!=0 );
95065 assert( p->pPrior==0 ); /* Unable to flatten compound queries */
95066 if( db->flags & SQLITE_QueryFlattener ) return 0;
95067 pSrc = p->pSrc;
95068 assert( pSrc && iFrom>=0 && iFrom<pSrc->nSrc );
95069 pSubitem = &pSrc->a[iFrom];
95070 iParent = pSubitem->iCursor;
95071 pSub = pSubitem->pSelect;
95072 assert( pSub!=0 );
95073 if( isAgg && subqueryIsAgg ) return 0; /* Restriction (1) */
95074 if( subqueryIsAgg && pSrc->nSrc>1 ) return 0; /* Restriction (2) */
95075 pSubSrc = pSub->pSrc;
95076 assert( pSubSrc );
95077 /* Prior to version 3.1.2, when LIMIT and OFFSET had to be simple constants,
95078 ** not arbitrary expresssions, we allowed some combining of LIMIT and OFFSET
95079 ** because they could be computed at compile-time. But when LIMIT and OFFSET
95080 ** became arbitrary expressions, we were forced to add restrictions (13)
95081 ** and (14). */
95082 if( pSub->pLimit && p->pLimit ) return 0; /* Restriction (13) */
95083 if( pSub->pOffset ) return 0; /* Restriction (14) */
95084 if( p->pRightmost && pSub->pLimit ){
95085 return 0; /* Restriction (15) */
95087 if( pSubSrc->nSrc==0 ) return 0; /* Restriction (7) */
95088 if( pSub->selFlags & SF_Distinct ) return 0; /* Restriction (5) */
95089 if( pSub->pLimit && (pSrc->nSrc>1 || isAgg) ){
95090 return 0; /* Restrictions (8)(9) */
95092 if( (p->selFlags & SF_Distinct)!=0 && subqueryIsAgg ){
95093 return 0; /* Restriction (6) */
95095 if( p->pOrderBy && pSub->pOrderBy ){
95096 return 0; /* Restriction (11) */
95098 if( isAgg && pSub->pOrderBy ) return 0; /* Restriction (16) */
95099 if( pSub->pLimit && p->pWhere ) return 0; /* Restriction (19) */
95100 if( pSub->pLimit && (p->selFlags & SF_Distinct)!=0 ){
95101 return 0; /* Restriction (21) */
95104 /* OBSOLETE COMMENT 1:
95105 ** Restriction 3: If the subquery is a join, make sure the subquery is
95106 ** not used as the right operand of an outer join. Examples of why this
95107 ** is not allowed:
95109 ** t1 LEFT OUTER JOIN (t2 JOIN t3)
95111 ** If we flatten the above, we would get
95113 ** (t1 LEFT OUTER JOIN t2) JOIN t3
95115 ** which is not at all the same thing.
95117 ** OBSOLETE COMMENT 2:
95118 ** Restriction 12: If the subquery is the right operand of a left outer
95119 ** join, make sure the subquery has no WHERE clause.
95120 ** An examples of why this is not allowed:
95122 ** t1 LEFT OUTER JOIN (SELECT * FROM t2 WHERE t2.x>0)
95124 ** If we flatten the above, we would get
95126 ** (t1 LEFT OUTER JOIN t2) WHERE t2.x>0
95128 ** But the t2.x>0 test will always fail on a NULL row of t2, which
95129 ** effectively converts the OUTER JOIN into an INNER JOIN.
95131 ** THIS OVERRIDES OBSOLETE COMMENTS 1 AND 2 ABOVE:
95132 ** Ticket #3300 shows that flattening the right term of a LEFT JOIN
95133 ** is fraught with danger. Best to avoid the whole thing. If the
95134 ** subquery is the right term of a LEFT JOIN, then do not flatten.
95136 if( (pSubitem->jointype & JT_OUTER)!=0 ){
95137 return 0;
95140 /* Restriction 17: If the sub-query is a compound SELECT, then it must
95141 ** use only the UNION ALL operator. And none of the simple select queries
95142 ** that make up the compound SELECT are allowed to be aggregate or distinct
95143 ** queries.
95145 if( pSub->pPrior ){
95146 if( pSub->pOrderBy ){
95147 return 0; /* Restriction 20 */
95149 if( isAgg || (p->selFlags & SF_Distinct)!=0 || pSrc->nSrc!=1 ){
95150 return 0;
95152 for(pSub1=pSub; pSub1; pSub1=pSub1->pPrior){
95153 testcase( (pSub1->selFlags & (SF_Distinct|SF_Aggregate))==SF_Distinct );
95154 testcase( (pSub1->selFlags & (SF_Distinct|SF_Aggregate))==SF_Aggregate );
95155 if( (pSub1->selFlags & (SF_Distinct|SF_Aggregate))!=0
95156 || (pSub1->pPrior && pSub1->op!=TK_ALL)
95157 || NEVER(pSub1->pSrc==0) || pSub1->pSrc->nSrc!=1
95159 return 0;
95163 /* Restriction 18. */
95164 if( p->pOrderBy ){
95165 int ii;
95166 for(ii=0; ii<p->pOrderBy->nExpr; ii++){
95167 if( p->pOrderBy->a[ii].iCol==0 ) return 0;
95172 /***** If we reach this point, flattening is permitted. *****/
95174 /* Authorize the subquery */
95175 pParse->zAuthContext = pSubitem->zName;
95176 sqlite3AuthCheck(pParse, SQLITE_SELECT, 0, 0, 0);
95177 pParse->zAuthContext = zSavedAuthContext;
95179 /* If the sub-query is a compound SELECT statement, then (by restrictions
95180 ** 17 and 18 above) it must be a UNION ALL and the parent query must
95181 ** be of the form:
95183 ** SELECT <expr-list> FROM (<sub-query>) <where-clause>
95185 ** followed by any ORDER BY, LIMIT and/or OFFSET clauses. This block
95186 ** creates N-1 copies of the parent query without any ORDER BY, LIMIT or
95187 ** OFFSET clauses and joins them to the left-hand-side of the original
95188 ** using UNION ALL operators. In this case N is the number of simple
95189 ** select statements in the compound sub-query.
95191 ** Example:
95193 ** SELECT a+1 FROM (
95194 ** SELECT x FROM tab
95195 ** UNION ALL
95196 ** SELECT y FROM tab
95197 ** UNION ALL
95198 ** SELECT abs(z*2) FROM tab2
95199 ** ) WHERE a!=5 ORDER BY 1
95201 ** Transformed into:
95203 ** SELECT x+1 FROM tab WHERE x+1!=5
95204 ** UNION ALL
95205 ** SELECT y+1 FROM tab WHERE y+1!=5
95206 ** UNION ALL
95207 ** SELECT abs(z*2)+1 FROM tab2 WHERE abs(z*2)+1!=5
95208 ** ORDER BY 1
95210 ** We call this the "compound-subquery flattening".
95212 for(pSub=pSub->pPrior; pSub; pSub=pSub->pPrior){
95213 Select *pNew;
95214 ExprList *pOrderBy = p->pOrderBy;
95215 Expr *pLimit = p->pLimit;
95216 Select *pPrior = p->pPrior;
95217 p->pOrderBy = 0;
95218 p->pSrc = 0;
95219 p->pPrior = 0;
95220 p->pLimit = 0;
95221 pNew = sqlite3SelectDup(db, p, 0);
95222 p->pLimit = pLimit;
95223 p->pOrderBy = pOrderBy;
95224 p->pSrc = pSrc;
95225 p->op = TK_ALL;
95226 p->pRightmost = 0;
95227 if( pNew==0 ){
95228 pNew = pPrior;
95229 }else{
95230 pNew->pPrior = pPrior;
95231 pNew->pRightmost = 0;
95233 p->pPrior = pNew;
95234 if( db->mallocFailed ) return 1;
95237 /* Begin flattening the iFrom-th entry of the FROM clause
95238 ** in the outer query.
95240 pSub = pSub1 = pSubitem->pSelect;
95242 /* Delete the transient table structure associated with the
95243 ** subquery
95245 sqlite3DbFree(db, pSubitem->zDatabase);
95246 sqlite3DbFree(db, pSubitem->zName);
95247 sqlite3DbFree(db, pSubitem->zAlias);
95248 pSubitem->zDatabase = 0;
95249 pSubitem->zName = 0;
95250 pSubitem->zAlias = 0;
95251 pSubitem->pSelect = 0;
95253 /* Defer deleting the Table object associated with the
95254 ** subquery until code generation is
95255 ** complete, since there may still exist Expr.pTab entries that
95256 ** refer to the subquery even after flattening. Ticket #3346.
95258 ** pSubitem->pTab is always non-NULL by test restrictions and tests above.
95260 if( ALWAYS(pSubitem->pTab!=0) ){
95261 Table *pTabToDel = pSubitem->pTab;
95262 if( pTabToDel->nRef==1 ){
95263 Parse *pToplevel = sqlite3ParseToplevel(pParse);
95264 pTabToDel->pNextZombie = pToplevel->pZombieTab;
95265 pToplevel->pZombieTab = pTabToDel;
95266 }else{
95267 pTabToDel->nRef--;
95269 pSubitem->pTab = 0;
95272 /* The following loop runs once for each term in a compound-subquery
95273 ** flattening (as described above). If we are doing a different kind
95274 ** of flattening - a flattening other than a compound-subquery flattening -
95275 ** then this loop only runs once.
95277 ** This loop moves all of the FROM elements of the subquery into the
95278 ** the FROM clause of the outer query. Before doing this, remember
95279 ** the cursor number for the original outer query FROM element in
95280 ** iParent. The iParent cursor will never be used. Subsequent code
95281 ** will scan expressions looking for iParent references and replace
95282 ** those references with expressions that resolve to the subquery FROM
95283 ** elements we are now copying in.
95285 for(pParent=p; pParent; pParent=pParent->pPrior, pSub=pSub->pPrior){
95286 int nSubSrc;
95287 u8 jointype = 0;
95288 pSubSrc = pSub->pSrc; /* FROM clause of subquery */
95289 nSubSrc = pSubSrc->nSrc; /* Number of terms in subquery FROM clause */
95290 pSrc = pParent->pSrc; /* FROM clause of the outer query */
95292 if( pSrc ){
95293 assert( pParent==p ); /* First time through the loop */
95294 jointype = pSubitem->jointype;
95295 }else{
95296 assert( pParent!=p ); /* 2nd and subsequent times through the loop */
95297 pSrc = pParent->pSrc = sqlite3SrcListAppend(db, 0, 0, 0);
95298 if( pSrc==0 ){
95299 assert( db->mallocFailed );
95300 break;
95304 /* The subquery uses a single slot of the FROM clause of the outer
95305 ** query. If the subquery has more than one element in its FROM clause,
95306 ** then expand the outer query to make space for it to hold all elements
95307 ** of the subquery.
95309 ** Example:
95311 ** SELECT * FROM tabA, (SELECT * FROM sub1, sub2), tabB;
95313 ** The outer query has 3 slots in its FROM clause. One slot of the
95314 ** outer query (the middle slot) is used by the subquery. The next
95315 ** block of code will expand the out query to 4 slots. The middle
95316 ** slot is expanded to two slots in order to make space for the
95317 ** two elements in the FROM clause of the subquery.
95319 if( nSubSrc>1 ){
95320 pParent->pSrc = pSrc = sqlite3SrcListEnlarge(db, pSrc, nSubSrc-1,iFrom+1);
95321 if( db->mallocFailed ){
95322 break;
95326 /* Transfer the FROM clause terms from the subquery into the
95327 ** outer query.
95329 for(i=0; i<nSubSrc; i++){
95330 sqlite3IdListDelete(db, pSrc->a[i+iFrom].pUsing);
95331 pSrc->a[i+iFrom] = pSubSrc->a[i];
95332 memset(&pSubSrc->a[i], 0, sizeof(pSubSrc->a[i]));
95334 pSrc->a[iFrom].jointype = jointype;
95336 /* Now begin substituting subquery result set expressions for
95337 ** references to the iParent in the outer query.
95339 ** Example:
95341 ** SELECT a+5, b*10 FROM (SELECT x*3 AS a, y+10 AS b FROM t1) WHERE a>b;
95342 ** \ \_____________ subquery __________/ /
95343 ** \_____________________ outer query ______________________________/
95345 ** We look at every expression in the outer query and every place we see
95346 ** "a" we substitute "x*3" and every place we see "b" we substitute "y+10".
95348 pList = pParent->pEList;
95349 for(i=0; i<pList->nExpr; i++){
95350 if( pList->a[i].zName==0 ){
95351 const char *zSpan = pList->a[i].zSpan;
95352 if( ALWAYS(zSpan) ){
95353 pList->a[i].zName = sqlite3DbStrDup(db, zSpan);
95357 substExprList(db, pParent->pEList, iParent, pSub->pEList);
95358 if( isAgg ){
95359 substExprList(db, pParent->pGroupBy, iParent, pSub->pEList);
95360 pParent->pHaving = substExpr(db, pParent->pHaving, iParent, pSub->pEList);
95362 if( pSub->pOrderBy ){
95363 assert( pParent->pOrderBy==0 );
95364 pParent->pOrderBy = pSub->pOrderBy;
95365 pSub->pOrderBy = 0;
95366 }else if( pParent->pOrderBy ){
95367 substExprList(db, pParent->pOrderBy, iParent, pSub->pEList);
95369 if( pSub->pWhere ){
95370 pWhere = sqlite3ExprDup(db, pSub->pWhere, 0);
95371 }else{
95372 pWhere = 0;
95374 if( subqueryIsAgg ){
95375 assert( pParent->pHaving==0 );
95376 pParent->pHaving = pParent->pWhere;
95377 pParent->pWhere = pWhere;
95378 pParent->pHaving = substExpr(db, pParent->pHaving, iParent, pSub->pEList);
95379 pParent->pHaving = sqlite3ExprAnd(db, pParent->pHaving,
95380 sqlite3ExprDup(db, pSub->pHaving, 0));
95381 assert( pParent->pGroupBy==0 );
95382 pParent->pGroupBy = sqlite3ExprListDup(db, pSub->pGroupBy, 0);
95383 }else{
95384 pParent->pWhere = substExpr(db, pParent->pWhere, iParent, pSub->pEList);
95385 pParent->pWhere = sqlite3ExprAnd(db, pParent->pWhere, pWhere);
95388 /* The flattened query is distinct if either the inner or the
95389 ** outer query is distinct.
95391 pParent->selFlags |= pSub->selFlags & SF_Distinct;
95394 ** SELECT ... FROM (SELECT ... LIMIT a OFFSET b) LIMIT x OFFSET y;
95396 ** One is tempted to try to add a and b to combine the limits. But this
95397 ** does not work if either limit is negative.
95399 if( pSub->pLimit ){
95400 pParent->pLimit = pSub->pLimit;
95401 pSub->pLimit = 0;
95405 /* Finially, delete what is left of the subquery and return
95406 ** success.
95408 sqlite3SelectDelete(db, pSub1);
95410 return 1;
95412 #endif /* !defined(SQLITE_OMIT_SUBQUERY) || !defined(SQLITE_OMIT_VIEW) */
95415 ** Analyze the SELECT statement passed as an argument to see if it
95416 ** is a min() or max() query. Return WHERE_ORDERBY_MIN or WHERE_ORDERBY_MAX if
95417 ** it is, or 0 otherwise. At present, a query is considered to be
95418 ** a min()/max() query if:
95420 ** 1. There is a single object in the FROM clause.
95422 ** 2. There is a single expression in the result set, and it is
95423 ** either min(x) or max(x), where x is a column reference.
95425 static u8 minMaxQuery(Select *p){
95426 Expr *pExpr;
95427 ExprList *pEList = p->pEList;
95429 if( pEList->nExpr!=1 ) return WHERE_ORDERBY_NORMAL;
95430 pExpr = pEList->a[0].pExpr;
95431 if( pExpr->op!=TK_AGG_FUNCTION ) return 0;
95432 if( NEVER(ExprHasProperty(pExpr, EP_xIsSelect)) ) return 0;
95433 pEList = pExpr->x.pList;
95434 if( pEList==0 || pEList->nExpr!=1 ) return 0;
95435 if( pEList->a[0].pExpr->op!=TK_AGG_COLUMN ) return WHERE_ORDERBY_NORMAL;
95436 assert( !ExprHasProperty(pExpr, EP_IntValue) );
95437 if( sqlite3StrICmp(pExpr->u.zToken,"min")==0 ){
95438 return WHERE_ORDERBY_MIN;
95439 }else if( sqlite3StrICmp(pExpr->u.zToken,"max")==0 ){
95440 return WHERE_ORDERBY_MAX;
95442 return WHERE_ORDERBY_NORMAL;
95446 ** The select statement passed as the first argument is an aggregate query.
95447 ** The second argment is the associated aggregate-info object. This
95448 ** function tests if the SELECT is of the form:
95450 ** SELECT count(*) FROM <tbl>
95452 ** where table is a database table, not a sub-select or view. If the query
95453 ** does match this pattern, then a pointer to the Table object representing
95454 ** <tbl> is returned. Otherwise, 0 is returned.
95456 static Table *isSimpleCount(Select *p, AggInfo *pAggInfo){
95457 Table *pTab;
95458 Expr *pExpr;
95460 assert( !p->pGroupBy );
95462 if( p->pWhere || p->pEList->nExpr!=1
95463 || p->pSrc->nSrc!=1 || p->pSrc->a[0].pSelect
95465 return 0;
95467 pTab = p->pSrc->a[0].pTab;
95468 pExpr = p->pEList->a[0].pExpr;
95469 assert( pTab && !pTab->pSelect && pExpr );
95471 if( IsVirtual(pTab) ) return 0;
95472 if( pExpr->op!=TK_AGG_FUNCTION ) return 0;
95473 if( (pAggInfo->aFunc[0].pFunc->flags&SQLITE_FUNC_COUNT)==0 ) return 0;
95474 if( pExpr->flags&EP_Distinct ) return 0;
95476 return pTab;
95480 ** If the source-list item passed as an argument was augmented with an
95481 ** INDEXED BY clause, then try to locate the specified index. If there
95482 ** was such a clause and the named index cannot be found, return
95483 ** SQLITE_ERROR and leave an error in pParse. Otherwise, populate
95484 ** pFrom->pIndex and return SQLITE_OK.
95486 SQLITE_PRIVATE int sqlite3IndexedByLookup(Parse *pParse, struct SrcList_item *pFrom){
95487 if( pFrom->pTab && pFrom->zIndex ){
95488 Table *pTab = pFrom->pTab;
95489 char *zIndex = pFrom->zIndex;
95490 Index *pIdx;
95491 for(pIdx=pTab->pIndex;
95492 pIdx && sqlite3StrICmp(pIdx->zName, zIndex);
95493 pIdx=pIdx->pNext
95495 if( !pIdx ){
95496 sqlite3ErrorMsg(pParse, "no such index: %s", zIndex, 0);
95497 pParse->checkSchema = 1;
95498 return SQLITE_ERROR;
95500 pFrom->pIndex = pIdx;
95502 return SQLITE_OK;
95506 ** This routine is a Walker callback for "expanding" a SELECT statement.
95507 ** "Expanding" means to do the following:
95509 ** (1) Make sure VDBE cursor numbers have been assigned to every
95510 ** element of the FROM clause.
95512 ** (2) Fill in the pTabList->a[].pTab fields in the SrcList that
95513 ** defines FROM clause. When views appear in the FROM clause,
95514 ** fill pTabList->a[].pSelect with a copy of the SELECT statement
95515 ** that implements the view. A copy is made of the view's SELECT
95516 ** statement so that we can freely modify or delete that statement
95517 ** without worrying about messing up the presistent representation
95518 ** of the view.
95520 ** (3) Add terms to the WHERE clause to accomodate the NATURAL keyword
95521 ** on joins and the ON and USING clause of joins.
95523 ** (4) Scan the list of columns in the result set (pEList) looking
95524 ** for instances of the "*" operator or the TABLE.* operator.
95525 ** If found, expand each "*" to be every column in every table
95526 ** and TABLE.* to be every column in TABLE.
95529 static int selectExpander(Walker *pWalker, Select *p){
95530 Parse *pParse = pWalker->pParse;
95531 int i, j, k;
95532 SrcList *pTabList;
95533 ExprList *pEList;
95534 struct SrcList_item *pFrom;
95535 sqlite3 *db = pParse->db;
95537 if( db->mallocFailed ){
95538 return WRC_Abort;
95540 if( NEVER(p->pSrc==0) || (p->selFlags & SF_Expanded)!=0 ){
95541 return WRC_Prune;
95543 p->selFlags |= SF_Expanded;
95544 pTabList = p->pSrc;
95545 pEList = p->pEList;
95547 /* Make sure cursor numbers have been assigned to all entries in
95548 ** the FROM clause of the SELECT statement.
95550 sqlite3SrcListAssignCursors(pParse, pTabList);
95552 /* Look up every table named in the FROM clause of the select. If
95553 ** an entry of the FROM clause is a subquery instead of a table or view,
95554 ** then create a transient table structure to describe the subquery.
95556 for(i=0, pFrom=pTabList->a; i<pTabList->nSrc; i++, pFrom++){
95557 Table *pTab;
95558 if( pFrom->pTab!=0 ){
95559 /* This statement has already been prepared. There is no need
95560 ** to go further. */
95561 assert( i==0 );
95562 return WRC_Prune;
95564 if( pFrom->zName==0 ){
95565 #ifndef SQLITE_OMIT_SUBQUERY
95566 Select *pSel = pFrom->pSelect;
95567 /* A sub-query in the FROM clause of a SELECT */
95568 assert( pSel!=0 );
95569 assert( pFrom->pTab==0 );
95570 sqlite3WalkSelect(pWalker, pSel);
95571 pFrom->pTab = pTab = sqlite3DbMallocZero(db, sizeof(Table));
95572 if( pTab==0 ) return WRC_Abort;
95573 pTab->nRef = 1;
95574 pTab->zName = sqlite3MPrintf(db, "sqlite_subquery_%p_", (void*)pTab);
95575 while( pSel->pPrior ){ pSel = pSel->pPrior; }
95576 selectColumnsFromExprList(pParse, pSel->pEList, &pTab->nCol, &pTab->aCol);
95577 pTab->iPKey = -1;
95578 pTab->nRowEst = 1000000;
95579 pTab->tabFlags |= TF_Ephemeral;
95580 #endif
95581 }else{
95582 /* An ordinary table or view name in the FROM clause */
95583 assert( pFrom->pTab==0 );
95584 pFrom->pTab = pTab =
95585 sqlite3LocateTable(pParse,0,pFrom->zName,pFrom->zDatabase);
95586 if( pTab==0 ) return WRC_Abort;
95587 pTab->nRef++;
95588 #if !defined(SQLITE_OMIT_VIEW) || !defined (SQLITE_OMIT_VIRTUALTABLE)
95589 if( pTab->pSelect || IsVirtual(pTab) ){
95590 /* We reach here if the named table is a really a view */
95591 if( sqlite3ViewGetColumnNames(pParse, pTab) ) return WRC_Abort;
95592 assert( pFrom->pSelect==0 );
95593 pFrom->pSelect = sqlite3SelectDup(db, pTab->pSelect, 0);
95594 sqlite3WalkSelect(pWalker, pFrom->pSelect);
95596 #endif
95599 /* Locate the index named by the INDEXED BY clause, if any. */
95600 if( sqlite3IndexedByLookup(pParse, pFrom) ){
95601 return WRC_Abort;
95605 /* Process NATURAL keywords, and ON and USING clauses of joins.
95607 if( db->mallocFailed || sqliteProcessJoin(pParse, p) ){
95608 return WRC_Abort;
95611 /* For every "*" that occurs in the column list, insert the names of
95612 ** all columns in all tables. And for every TABLE.* insert the names
95613 ** of all columns in TABLE. The parser inserted a special expression
95614 ** with the TK_ALL operator for each "*" that it found in the column list.
95615 ** The following code just has to locate the TK_ALL expressions and expand
95616 ** each one to the list of all columns in all tables.
95618 ** The first loop just checks to see if there are any "*" operators
95619 ** that need expanding.
95621 for(k=0; k<pEList->nExpr; k++){
95622 Expr *pE = pEList->a[k].pExpr;
95623 if( pE->op==TK_ALL ) break;
95624 assert( pE->op!=TK_DOT || pE->pRight!=0 );
95625 assert( pE->op!=TK_DOT || (pE->pLeft!=0 && pE->pLeft->op==TK_ID) );
95626 if( pE->op==TK_DOT && pE->pRight->op==TK_ALL ) break;
95628 if( k<pEList->nExpr ){
95630 ** If we get here it means the result set contains one or more "*"
95631 ** operators that need to be expanded. Loop through each expression
95632 ** in the result set and expand them one by one.
95634 struct ExprList_item *a = pEList->a;
95635 ExprList *pNew = 0;
95636 int flags = pParse->db->flags;
95637 int longNames = (flags & SQLITE_FullColNames)!=0
95638 && (flags & SQLITE_ShortColNames)==0;
95640 for(k=0; k<pEList->nExpr; k++){
95641 Expr *pE = a[k].pExpr;
95642 assert( pE->op!=TK_DOT || pE->pRight!=0 );
95643 if( pE->op!=TK_ALL && (pE->op!=TK_DOT || pE->pRight->op!=TK_ALL) ){
95644 /* This particular expression does not need to be expanded.
95646 pNew = sqlite3ExprListAppend(pParse, pNew, a[k].pExpr);
95647 if( pNew ){
95648 pNew->a[pNew->nExpr-1].zName = a[k].zName;
95649 pNew->a[pNew->nExpr-1].zSpan = a[k].zSpan;
95650 a[k].zName = 0;
95651 a[k].zSpan = 0;
95653 a[k].pExpr = 0;
95654 }else{
95655 /* This expression is a "*" or a "TABLE.*" and needs to be
95656 ** expanded. */
95657 int tableSeen = 0; /* Set to 1 when TABLE matches */
95658 char *zTName; /* text of name of TABLE */
95659 if( pE->op==TK_DOT ){
95660 assert( pE->pLeft!=0 );
95661 assert( !ExprHasProperty(pE->pLeft, EP_IntValue) );
95662 zTName = pE->pLeft->u.zToken;
95663 }else{
95664 zTName = 0;
95666 for(i=0, pFrom=pTabList->a; i<pTabList->nSrc; i++, pFrom++){
95667 Table *pTab = pFrom->pTab;
95668 char *zTabName = pFrom->zAlias;
95669 if( zTabName==0 ){
95670 zTabName = pTab->zName;
95672 if( db->mallocFailed ) break;
95673 if( zTName && sqlite3StrICmp(zTName, zTabName)!=0 ){
95674 continue;
95676 tableSeen = 1;
95677 for(j=0; j<pTab->nCol; j++){
95678 Expr *pExpr, *pRight;
95679 char *zName = pTab->aCol[j].zName;
95680 char *zColname; /* The computed column name */
95681 char *zToFree; /* Malloced string that needs to be freed */
95682 Token sColname; /* Computed column name as a token */
95684 /* If a column is marked as 'hidden' (currently only possible
95685 ** for virtual tables), do not include it in the expanded
95686 ** result-set list.
95688 if( IsHiddenColumn(&pTab->aCol[j]) ){
95689 assert(IsVirtual(pTab));
95690 continue;
95693 if( i>0 && zTName==0 ){
95694 if( (pFrom->jointype & JT_NATURAL)!=0
95695 && tableAndColumnIndex(pTabList, i, zName, 0, 0)
95697 /* In a NATURAL join, omit the join columns from the
95698 ** table to the right of the join */
95699 continue;
95701 if( sqlite3IdListIndex(pFrom->pUsing, zName)>=0 ){
95702 /* In a join with a USING clause, omit columns in the
95703 ** using clause from the table on the right. */
95704 continue;
95707 pRight = sqlite3Expr(db, TK_ID, zName);
95708 zColname = zName;
95709 zToFree = 0;
95710 if( longNames || pTabList->nSrc>1 ){
95711 Expr *pLeft;
95712 pLeft = sqlite3Expr(db, TK_ID, zTabName);
95713 pExpr = sqlite3PExpr(pParse, TK_DOT, pLeft, pRight, 0);
95714 if( longNames ){
95715 zColname = sqlite3MPrintf(db, "%s.%s", zTabName, zName);
95716 zToFree = zColname;
95718 }else{
95719 pExpr = pRight;
95721 pNew = sqlite3ExprListAppend(pParse, pNew, pExpr);
95722 sColname.z = zColname;
95723 sColname.n = sqlite3Strlen30(zColname);
95724 sqlite3ExprListSetName(pParse, pNew, &sColname, 0);
95725 sqlite3DbFree(db, zToFree);
95728 if( !tableSeen ){
95729 if( zTName ){
95730 sqlite3ErrorMsg(pParse, "no such table: %s", zTName);
95731 }else{
95732 sqlite3ErrorMsg(pParse, "no tables specified");
95737 sqlite3ExprListDelete(db, pEList);
95738 p->pEList = pNew;
95740 #if SQLITE_MAX_COLUMN
95741 if( p->pEList && p->pEList->nExpr>db->aLimit[SQLITE_LIMIT_COLUMN] ){
95742 sqlite3ErrorMsg(pParse, "too many columns in result set");
95744 #endif
95745 return WRC_Continue;
95749 ** No-op routine for the parse-tree walker.
95751 ** When this routine is the Walker.xExprCallback then expression trees
95752 ** are walked without any actions being taken at each node. Presumably,
95753 ** when this routine is used for Walker.xExprCallback then
95754 ** Walker.xSelectCallback is set to do something useful for every
95755 ** subquery in the parser tree.
95757 static int exprWalkNoop(Walker *NotUsed, Expr *NotUsed2){
95758 UNUSED_PARAMETER2(NotUsed, NotUsed2);
95759 return WRC_Continue;
95763 ** This routine "expands" a SELECT statement and all of its subqueries.
95764 ** For additional information on what it means to "expand" a SELECT
95765 ** statement, see the comment on the selectExpand worker callback above.
95767 ** Expanding a SELECT statement is the first step in processing a
95768 ** SELECT statement. The SELECT statement must be expanded before
95769 ** name resolution is performed.
95771 ** If anything goes wrong, an error message is written into pParse.
95772 ** The calling function can detect the problem by looking at pParse->nErr
95773 ** and/or pParse->db->mallocFailed.
95775 static void sqlite3SelectExpand(Parse *pParse, Select *pSelect){
95776 Walker w;
95777 w.xSelectCallback = selectExpander;
95778 w.xExprCallback = exprWalkNoop;
95779 w.pParse = pParse;
95780 sqlite3WalkSelect(&w, pSelect);
95784 #ifndef SQLITE_OMIT_SUBQUERY
95786 ** This is a Walker.xSelectCallback callback for the sqlite3SelectTypeInfo()
95787 ** interface.
95789 ** For each FROM-clause subquery, add Column.zType and Column.zColl
95790 ** information to the Table structure that represents the result set
95791 ** of that subquery.
95793 ** The Table structure that represents the result set was constructed
95794 ** by selectExpander() but the type and collation information was omitted
95795 ** at that point because identifiers had not yet been resolved. This
95796 ** routine is called after identifier resolution.
95798 static int selectAddSubqueryTypeInfo(Walker *pWalker, Select *p){
95799 Parse *pParse;
95800 int i;
95801 SrcList *pTabList;
95802 struct SrcList_item *pFrom;
95804 assert( p->selFlags & SF_Resolved );
95805 if( (p->selFlags & SF_HasTypeInfo)==0 ){
95806 p->selFlags |= SF_HasTypeInfo;
95807 pParse = pWalker->pParse;
95808 pTabList = p->pSrc;
95809 for(i=0, pFrom=pTabList->a; i<pTabList->nSrc; i++, pFrom++){
95810 Table *pTab = pFrom->pTab;
95811 if( ALWAYS(pTab!=0) && (pTab->tabFlags & TF_Ephemeral)!=0 ){
95812 /* A sub-query in the FROM clause of a SELECT */
95813 Select *pSel = pFrom->pSelect;
95814 assert( pSel );
95815 while( pSel->pPrior ) pSel = pSel->pPrior;
95816 selectAddColumnTypeAndCollation(pParse, pTab->nCol, pTab->aCol, pSel);
95820 return WRC_Continue;
95822 #endif
95826 ** This routine adds datatype and collating sequence information to
95827 ** the Table structures of all FROM-clause subqueries in a
95828 ** SELECT statement.
95830 ** Use this routine after name resolution.
95832 static void sqlite3SelectAddTypeInfo(Parse *pParse, Select *pSelect){
95833 #ifndef SQLITE_OMIT_SUBQUERY
95834 Walker w;
95835 w.xSelectCallback = selectAddSubqueryTypeInfo;
95836 w.xExprCallback = exprWalkNoop;
95837 w.pParse = pParse;
95838 sqlite3WalkSelect(&w, pSelect);
95839 #endif
95844 ** This routine sets of a SELECT statement for processing. The
95845 ** following is accomplished:
95847 ** * VDBE Cursor numbers are assigned to all FROM-clause terms.
95848 ** * Ephemeral Table objects are created for all FROM-clause subqueries.
95849 ** * ON and USING clauses are shifted into WHERE statements
95850 ** * Wildcards "*" and "TABLE.*" in result sets are expanded.
95851 ** * Identifiers in expression are matched to tables.
95853 ** This routine acts recursively on all subqueries within the SELECT.
95855 SQLITE_PRIVATE void sqlite3SelectPrep(
95856 Parse *pParse, /* The parser context */
95857 Select *p, /* The SELECT statement being coded. */
95858 NameContext *pOuterNC /* Name context for container */
95860 sqlite3 *db;
95861 if( NEVER(p==0) ) return;
95862 db = pParse->db;
95863 if( p->selFlags & SF_HasTypeInfo ) return;
95864 sqlite3SelectExpand(pParse, p);
95865 if( pParse->nErr || db->mallocFailed ) return;
95866 sqlite3ResolveSelectNames(pParse, p, pOuterNC);
95867 if( pParse->nErr || db->mallocFailed ) return;
95868 sqlite3SelectAddTypeInfo(pParse, p);
95872 ** Reset the aggregate accumulator.
95874 ** The aggregate accumulator is a set of memory cells that hold
95875 ** intermediate results while calculating an aggregate. This
95876 ** routine simply stores NULLs in all of those memory cells.
95878 static void resetAccumulator(Parse *pParse, AggInfo *pAggInfo){
95879 Vdbe *v = pParse->pVdbe;
95880 int i;
95881 struct AggInfo_func *pFunc;
95882 if( pAggInfo->nFunc+pAggInfo->nColumn==0 ){
95883 return;
95885 for(i=0; i<pAggInfo->nColumn; i++){
95886 sqlite3VdbeAddOp2(v, OP_Null, 0, pAggInfo->aCol[i].iMem);
95888 for(pFunc=pAggInfo->aFunc, i=0; i<pAggInfo->nFunc; i++, pFunc++){
95889 sqlite3VdbeAddOp2(v, OP_Null, 0, pFunc->iMem);
95890 if( pFunc->iDistinct>=0 ){
95891 Expr *pE = pFunc->pExpr;
95892 assert( !ExprHasProperty(pE, EP_xIsSelect) );
95893 if( pE->x.pList==0 || pE->x.pList->nExpr!=1 ){
95894 sqlite3ErrorMsg(pParse, "DISTINCT aggregates must have exactly one "
95895 "argument");
95896 pFunc->iDistinct = -1;
95897 }else{
95898 KeyInfo *pKeyInfo = keyInfoFromExprList(pParse, pE->x.pList);
95899 sqlite3VdbeAddOp4(v, OP_OpenEphemeral, pFunc->iDistinct, 0, 0,
95900 (char*)pKeyInfo, P4_KEYINFO_HANDOFF);
95907 ** Invoke the OP_AggFinalize opcode for every aggregate function
95908 ** in the AggInfo structure.
95910 static void finalizeAggFunctions(Parse *pParse, AggInfo *pAggInfo){
95911 Vdbe *v = pParse->pVdbe;
95912 int i;
95913 struct AggInfo_func *pF;
95914 for(i=0, pF=pAggInfo->aFunc; i<pAggInfo->nFunc; i++, pF++){
95915 ExprList *pList = pF->pExpr->x.pList;
95916 assert( !ExprHasProperty(pF->pExpr, EP_xIsSelect) );
95917 sqlite3VdbeAddOp4(v, OP_AggFinal, pF->iMem, pList ? pList->nExpr : 0, 0,
95918 (void*)pF->pFunc, P4_FUNCDEF);
95923 ** Update the accumulator memory cells for an aggregate based on
95924 ** the current cursor position.
95926 static void updateAccumulator(Parse *pParse, AggInfo *pAggInfo){
95927 Vdbe *v = pParse->pVdbe;
95928 int i;
95929 struct AggInfo_func *pF;
95930 struct AggInfo_col *pC;
95932 pAggInfo->directMode = 1;
95933 sqlite3ExprCacheClear(pParse);
95934 for(i=0, pF=pAggInfo->aFunc; i<pAggInfo->nFunc; i++, pF++){
95935 int nArg;
95936 int addrNext = 0;
95937 int regAgg;
95938 ExprList *pList = pF->pExpr->x.pList;
95939 assert( !ExprHasProperty(pF->pExpr, EP_xIsSelect) );
95940 if( pList ){
95941 nArg = pList->nExpr;
95942 regAgg = sqlite3GetTempRange(pParse, nArg);
95943 sqlite3ExprCodeExprList(pParse, pList, regAgg, 1);
95944 }else{
95945 nArg = 0;
95946 regAgg = 0;
95948 if( pF->iDistinct>=0 ){
95949 addrNext = sqlite3VdbeMakeLabel(v);
95950 assert( nArg==1 );
95951 codeDistinct(pParse, pF->iDistinct, addrNext, 1, regAgg);
95953 if( pF->pFunc->flags & SQLITE_FUNC_NEEDCOLL ){
95954 CollSeq *pColl = 0;
95955 struct ExprList_item *pItem;
95956 int j;
95957 assert( pList!=0 ); /* pList!=0 if pF->pFunc has NEEDCOLL */
95958 for(j=0, pItem=pList->a; !pColl && j<nArg; j++, pItem++){
95959 pColl = sqlite3ExprCollSeq(pParse, pItem->pExpr);
95961 if( !pColl ){
95962 pColl = pParse->db->pDfltColl;
95964 sqlite3VdbeAddOp4(v, OP_CollSeq, 0, 0, 0, (char *)pColl, P4_COLLSEQ);
95966 sqlite3VdbeAddOp4(v, OP_AggStep, 0, regAgg, pF->iMem,
95967 (void*)pF->pFunc, P4_FUNCDEF);
95968 sqlite3VdbeChangeP5(v, (u8)nArg);
95969 sqlite3ExprCacheAffinityChange(pParse, regAgg, nArg);
95970 sqlite3ReleaseTempRange(pParse, regAgg, nArg);
95971 if( addrNext ){
95972 sqlite3VdbeResolveLabel(v, addrNext);
95973 sqlite3ExprCacheClear(pParse);
95977 /* Before populating the accumulator registers, clear the column cache.
95978 ** Otherwise, if any of the required column values are already present
95979 ** in registers, sqlite3ExprCode() may use OP_SCopy to copy the value
95980 ** to pC->iMem. But by the time the value is used, the original register
95981 ** may have been used, invalidating the underlying buffer holding the
95982 ** text or blob value. See ticket [883034dcb5].
95984 ** Another solution would be to change the OP_SCopy used to copy cached
95985 ** values to an OP_Copy.
95987 sqlite3ExprCacheClear(pParse);
95988 for(i=0, pC=pAggInfo->aCol; i<pAggInfo->nAccumulator; i++, pC++){
95989 sqlite3ExprCode(pParse, pC->pExpr, pC->iMem);
95991 pAggInfo->directMode = 0;
95992 sqlite3ExprCacheClear(pParse);
95996 ** Add a single OP_Explain instruction to the VDBE to explain a simple
95997 ** count(*) query ("SELECT count(*) FROM pTab").
95999 #ifndef SQLITE_OMIT_EXPLAIN
96000 static void explainSimpleCount(
96001 Parse *pParse, /* Parse context */
96002 Table *pTab, /* Table being queried */
96003 Index *pIdx /* Index used to optimize scan, or NULL */
96005 if( pParse->explain==2 ){
96006 char *zEqp = sqlite3MPrintf(pParse->db, "SCAN TABLE %s %s%s(~%d rows)",
96007 pTab->zName,
96008 pIdx ? "USING COVERING INDEX " : "",
96009 pIdx ? pIdx->zName : "",
96010 pTab->nRowEst
96012 sqlite3VdbeAddOp4(
96013 pParse->pVdbe, OP_Explain, pParse->iSelectId, 0, 0, zEqp, P4_DYNAMIC
96017 #else
96018 # define explainSimpleCount(a,b,c)
96019 #endif
96022 ** Generate code for the SELECT statement given in the p argument.
96024 ** The results are distributed in various ways depending on the
96025 ** contents of the SelectDest structure pointed to by argument pDest
96026 ** as follows:
96028 ** pDest->eDest Result
96029 ** ------------ -------------------------------------------
96030 ** SRT_Output Generate a row of output (using the OP_ResultRow
96031 ** opcode) for each row in the result set.
96033 ** SRT_Mem Only valid if the result is a single column.
96034 ** Store the first column of the first result row
96035 ** in register pDest->iParm then abandon the rest
96036 ** of the query. This destination implies "LIMIT 1".
96038 ** SRT_Set The result must be a single column. Store each
96039 ** row of result as the key in table pDest->iParm.
96040 ** Apply the affinity pDest->affinity before storing
96041 ** results. Used to implement "IN (SELECT ...)".
96043 ** SRT_Union Store results as a key in a temporary table pDest->iParm.
96045 ** SRT_Except Remove results from the temporary table pDest->iParm.
96047 ** SRT_Table Store results in temporary table pDest->iParm.
96048 ** This is like SRT_EphemTab except that the table
96049 ** is assumed to already be open.
96051 ** SRT_EphemTab Create an temporary table pDest->iParm and store
96052 ** the result there. The cursor is left open after
96053 ** returning. This is like SRT_Table except that
96054 ** this destination uses OP_OpenEphemeral to create
96055 ** the table first.
96057 ** SRT_Coroutine Generate a co-routine that returns a new row of
96058 ** results each time it is invoked. The entry point
96059 ** of the co-routine is stored in register pDest->iParm.
96061 ** SRT_Exists Store a 1 in memory cell pDest->iParm if the result
96062 ** set is not empty.
96064 ** SRT_Discard Throw the results away. This is used by SELECT
96065 ** statements within triggers whose only purpose is
96066 ** the side-effects of functions.
96068 ** This routine returns the number of errors. If any errors are
96069 ** encountered, then an appropriate error message is left in
96070 ** pParse->zErrMsg.
96072 ** This routine does NOT free the Select structure passed in. The
96073 ** calling function needs to do that.
96075 SQLITE_PRIVATE int sqlite3Select(
96076 Parse *pParse, /* The parser context */
96077 Select *p, /* The SELECT statement being coded. */
96078 SelectDest *pDest /* What to do with the query results */
96080 int i, j; /* Loop counters */
96081 WhereInfo *pWInfo; /* Return from sqlite3WhereBegin() */
96082 Vdbe *v; /* The virtual machine under construction */
96083 int isAgg; /* True for select lists like "count(*)" */
96084 ExprList *pEList; /* List of columns to extract. */
96085 SrcList *pTabList; /* List of tables to select from */
96086 Expr *pWhere; /* The WHERE clause. May be NULL */
96087 ExprList *pOrderBy; /* The ORDER BY clause. May be NULL */
96088 ExprList *pGroupBy; /* The GROUP BY clause. May be NULL */
96089 Expr *pHaving; /* The HAVING clause. May be NULL */
96090 int isDistinct; /* True if the DISTINCT keyword is present */
96091 int distinct; /* Table to use for the distinct set */
96092 int rc = 1; /* Value to return from this function */
96093 int addrSortIndex; /* Address of an OP_OpenEphemeral instruction */
96094 int addrDistinctIndex; /* Address of an OP_OpenEphemeral instruction */
96095 AggInfo sAggInfo; /* Information used by aggregate queries */
96096 int iEnd; /* Address of the end of the query */
96097 sqlite3 *db; /* The database connection */
96099 #ifndef SQLITE_OMIT_EXPLAIN
96100 int iRestoreSelectId = pParse->iSelectId;
96101 pParse->iSelectId = pParse->iNextSelectId++;
96102 #endif
96104 db = pParse->db;
96105 if( p==0 || db->mallocFailed || pParse->nErr ){
96106 return 1;
96108 if( sqlite3AuthCheck(pParse, SQLITE_SELECT, 0, 0, 0) ) return 1;
96109 memset(&sAggInfo, 0, sizeof(sAggInfo));
96111 if( IgnorableOrderby(pDest) ){
96112 assert(pDest->eDest==SRT_Exists || pDest->eDest==SRT_Union ||
96113 pDest->eDest==SRT_Except || pDest->eDest==SRT_Discard);
96114 /* If ORDER BY makes no difference in the output then neither does
96115 ** DISTINCT so it can be removed too. */
96116 sqlite3ExprListDelete(db, p->pOrderBy);
96117 p->pOrderBy = 0;
96118 p->selFlags &= ~SF_Distinct;
96120 sqlite3SelectPrep(pParse, p, 0);
96121 pOrderBy = p->pOrderBy;
96122 pTabList = p->pSrc;
96123 pEList = p->pEList;
96124 if( pParse->nErr || db->mallocFailed ){
96125 goto select_end;
96127 isAgg = (p->selFlags & SF_Aggregate)!=0;
96128 assert( pEList!=0 );
96130 /* Begin generating code.
96132 v = sqlite3GetVdbe(pParse);
96133 if( v==0 ) goto select_end;
96135 /* If writing to memory or generating a set
96136 ** only a single column may be output.
96138 #ifndef SQLITE_OMIT_SUBQUERY
96139 if( checkForMultiColumnSelectError(pParse, pDest, pEList->nExpr) ){
96140 goto select_end;
96142 #endif
96144 /* Generate code for all sub-queries in the FROM clause
96146 #if !defined(SQLITE_OMIT_SUBQUERY) || !defined(SQLITE_OMIT_VIEW)
96147 for(i=0; !p->pPrior && i<pTabList->nSrc; i++){
96148 struct SrcList_item *pItem = &pTabList->a[i];
96149 SelectDest dest;
96150 Select *pSub = pItem->pSelect;
96151 int isAggSub;
96153 if( pSub==0 ) continue;
96154 if( pItem->addrFillSub ){
96155 sqlite3VdbeAddOp2(v, OP_Gosub, pItem->regReturn, pItem->addrFillSub);
96156 continue;
96159 /* Increment Parse.nHeight by the height of the largest expression
96160 ** tree refered to by this, the parent select. The child select
96161 ** may contain expression trees of at most
96162 ** (SQLITE_MAX_EXPR_DEPTH-Parse.nHeight) height. This is a bit
96163 ** more conservative than necessary, but much easier than enforcing
96164 ** an exact limit.
96166 pParse->nHeight += sqlite3SelectExprHeight(p);
96168 isAggSub = (pSub->selFlags & SF_Aggregate)!=0;
96169 if( flattenSubquery(pParse, p, i, isAgg, isAggSub) ){
96170 /* This subquery can be absorbed into its parent. */
96171 if( isAggSub ){
96172 isAgg = 1;
96173 p->selFlags |= SF_Aggregate;
96175 i = -1;
96176 }else{
96177 /* Generate a subroutine that will fill an ephemeral table with
96178 ** the content of this subquery. pItem->addrFillSub will point
96179 ** to the address of the generated subroutine. pItem->regReturn
96180 ** is a register allocated to hold the subroutine return address
96182 int topAddr;
96183 int onceAddr = 0;
96184 int retAddr;
96185 assert( pItem->addrFillSub==0 );
96186 pItem->regReturn = ++pParse->nMem;
96187 topAddr = sqlite3VdbeAddOp2(v, OP_Integer, 0, pItem->regReturn);
96188 pItem->addrFillSub = topAddr+1;
96189 VdbeNoopComment((v, "materialize %s", pItem->pTab->zName));
96190 if( pItem->isCorrelated==0 && pParse->pTriggerTab==0 ){
96191 /* If the subquery is no correlated and if we are not inside of
96192 ** a trigger, then we only need to compute the value of the subquery
96193 ** once. */
96194 int regOnce = ++pParse->nMem;
96195 onceAddr = sqlite3VdbeAddOp1(v, OP_Once, regOnce);
96197 sqlite3SelectDestInit(&dest, SRT_EphemTab, pItem->iCursor);
96198 explainSetInteger(pItem->iSelectId, (u8)pParse->iNextSelectId);
96199 sqlite3Select(pParse, pSub, &dest);
96200 pItem->pTab->nRowEst = (unsigned)pSub->nSelectRow;
96201 if( onceAddr ) sqlite3VdbeJumpHere(v, onceAddr);
96202 retAddr = sqlite3VdbeAddOp1(v, OP_Return, pItem->regReturn);
96203 VdbeComment((v, "end %s", pItem->pTab->zName));
96204 sqlite3VdbeChangeP1(v, topAddr, retAddr);
96207 if( /*pParse->nErr ||*/ db->mallocFailed ){
96208 goto select_end;
96210 pParse->nHeight -= sqlite3SelectExprHeight(p);
96211 pTabList = p->pSrc;
96212 if( !IgnorableOrderby(pDest) ){
96213 pOrderBy = p->pOrderBy;
96216 pEList = p->pEList;
96217 #endif
96218 pWhere = p->pWhere;
96219 pGroupBy = p->pGroupBy;
96220 pHaving = p->pHaving;
96221 isDistinct = (p->selFlags & SF_Distinct)!=0;
96223 #ifndef SQLITE_OMIT_COMPOUND_SELECT
96224 /* If there is are a sequence of queries, do the earlier ones first.
96226 if( p->pPrior ){
96227 if( p->pRightmost==0 ){
96228 Select *pLoop, *pRight = 0;
96229 int cnt = 0;
96230 int mxSelect;
96231 for(pLoop=p; pLoop; pLoop=pLoop->pPrior, cnt++){
96232 pLoop->pRightmost = p;
96233 pLoop->pNext = pRight;
96234 pRight = pLoop;
96236 mxSelect = db->aLimit[SQLITE_LIMIT_COMPOUND_SELECT];
96237 if( mxSelect && cnt>mxSelect ){
96238 sqlite3ErrorMsg(pParse, "too many terms in compound SELECT");
96239 goto select_end;
96242 rc = multiSelect(pParse, p, pDest);
96243 explainSetInteger(pParse->iSelectId, iRestoreSelectId);
96244 return rc;
96246 #endif
96248 /* If there is both a GROUP BY and an ORDER BY clause and they are
96249 ** identical, then disable the ORDER BY clause since the GROUP BY
96250 ** will cause elements to come out in the correct order. This is
96251 ** an optimization - the correct answer should result regardless.
96252 ** Use the SQLITE_GroupByOrder flag with SQLITE_TESTCTRL_OPTIMIZER
96253 ** to disable this optimization for testing purposes.
96255 if( sqlite3ExprListCompare(p->pGroupBy, pOrderBy)==0
96256 && (db->flags & SQLITE_GroupByOrder)==0 ){
96257 pOrderBy = 0;
96260 /* If the query is DISTINCT with an ORDER BY but is not an aggregate, and
96261 ** if the select-list is the same as the ORDER BY list, then this query
96262 ** can be rewritten as a GROUP BY. In other words, this:
96264 ** SELECT DISTINCT xyz FROM ... ORDER BY xyz
96266 ** is transformed to:
96268 ** SELECT xyz FROM ... GROUP BY xyz
96270 ** The second form is preferred as a single index (or temp-table) may be
96271 ** used for both the ORDER BY and DISTINCT processing. As originally
96272 ** written the query must use a temp-table for at least one of the ORDER
96273 ** BY and DISTINCT, and an index or separate temp-table for the other.
96275 if( (p->selFlags & (SF_Distinct|SF_Aggregate))==SF_Distinct
96276 && sqlite3ExprListCompare(pOrderBy, p->pEList)==0
96278 p->selFlags &= ~SF_Distinct;
96279 p->pGroupBy = sqlite3ExprListDup(db, p->pEList, 0);
96280 pGroupBy = p->pGroupBy;
96281 pOrderBy = 0;
96284 /* If there is an ORDER BY clause, then this sorting
96285 ** index might end up being unused if the data can be
96286 ** extracted in pre-sorted order. If that is the case, then the
96287 ** OP_OpenEphemeral instruction will be changed to an OP_Noop once
96288 ** we figure out that the sorting index is not needed. The addrSortIndex
96289 ** variable is used to facilitate that change.
96291 if( pOrderBy ){
96292 KeyInfo *pKeyInfo;
96293 pKeyInfo = keyInfoFromExprList(pParse, pOrderBy);
96294 pOrderBy->iECursor = pParse->nTab++;
96295 p->addrOpenEphm[2] = addrSortIndex =
96296 sqlite3VdbeAddOp4(v, OP_OpenEphemeral,
96297 pOrderBy->iECursor, pOrderBy->nExpr+2, 0,
96298 (char*)pKeyInfo, P4_KEYINFO_HANDOFF);
96299 }else{
96300 addrSortIndex = -1;
96303 /* If the output is destined for a temporary table, open that table.
96305 if( pDest->eDest==SRT_EphemTab ){
96306 sqlite3VdbeAddOp2(v, OP_OpenEphemeral, pDest->iParm, pEList->nExpr);
96309 /* Set the limiter.
96311 iEnd = sqlite3VdbeMakeLabel(v);
96312 p->nSelectRow = (double)LARGEST_INT64;
96313 computeLimitRegisters(pParse, p, iEnd);
96314 if( p->iLimit==0 && addrSortIndex>=0 ){
96315 sqlite3VdbeGetOp(v, addrSortIndex)->opcode = OP_SorterOpen;
96316 p->selFlags |= SF_UseSorter;
96319 /* Open a virtual index to use for the distinct set.
96321 if( p->selFlags & SF_Distinct ){
96322 KeyInfo *pKeyInfo;
96323 distinct = pParse->nTab++;
96324 pKeyInfo = keyInfoFromExprList(pParse, p->pEList);
96325 addrDistinctIndex = sqlite3VdbeAddOp4(v, OP_OpenEphemeral, distinct, 0, 0,
96326 (char*)pKeyInfo, P4_KEYINFO_HANDOFF);
96327 sqlite3VdbeChangeP5(v, BTREE_UNORDERED);
96328 }else{
96329 distinct = addrDistinctIndex = -1;
96332 /* Aggregate and non-aggregate queries are handled differently */
96333 if( !isAgg && pGroupBy==0 ){
96334 ExprList *pDist = (isDistinct ? p->pEList : 0);
96336 /* Begin the database scan. */
96337 pWInfo = sqlite3WhereBegin(pParse, pTabList, pWhere, &pOrderBy, pDist, 0);
96338 if( pWInfo==0 ) goto select_end;
96339 if( pWInfo->nRowOut < p->nSelectRow ) p->nSelectRow = pWInfo->nRowOut;
96341 /* If sorting index that was created by a prior OP_OpenEphemeral
96342 ** instruction ended up not being needed, then change the OP_OpenEphemeral
96343 ** into an OP_Noop.
96345 if( addrSortIndex>=0 && pOrderBy==0 ){
96346 sqlite3VdbeChangeToNoop(v, addrSortIndex);
96347 p->addrOpenEphm[2] = -1;
96350 if( pWInfo->eDistinct ){
96351 VdbeOp *pOp; /* No longer required OpenEphemeral instr. */
96353 assert( addrDistinctIndex>=0 );
96354 pOp = sqlite3VdbeGetOp(v, addrDistinctIndex);
96356 assert( isDistinct );
96357 assert( pWInfo->eDistinct==WHERE_DISTINCT_ORDERED
96358 || pWInfo->eDistinct==WHERE_DISTINCT_UNIQUE
96360 distinct = -1;
96361 if( pWInfo->eDistinct==WHERE_DISTINCT_ORDERED ){
96362 int iJump;
96363 int iExpr;
96364 int iFlag = ++pParse->nMem;
96365 int iBase = pParse->nMem+1;
96366 int iBase2 = iBase + pEList->nExpr;
96367 pParse->nMem += (pEList->nExpr*2);
96369 /* Change the OP_OpenEphemeral coded earlier to an OP_Integer. The
96370 ** OP_Integer initializes the "first row" flag. */
96371 pOp->opcode = OP_Integer;
96372 pOp->p1 = 1;
96373 pOp->p2 = iFlag;
96375 sqlite3ExprCodeExprList(pParse, pEList, iBase, 1);
96376 iJump = sqlite3VdbeCurrentAddr(v) + 1 + pEList->nExpr + 1 + 1;
96377 sqlite3VdbeAddOp2(v, OP_If, iFlag, iJump-1);
96378 for(iExpr=0; iExpr<pEList->nExpr; iExpr++){
96379 CollSeq *pColl = sqlite3ExprCollSeq(pParse, pEList->a[iExpr].pExpr);
96380 sqlite3VdbeAddOp3(v, OP_Ne, iBase+iExpr, iJump, iBase2+iExpr);
96381 sqlite3VdbeChangeP4(v, -1, (const char *)pColl, P4_COLLSEQ);
96382 sqlite3VdbeChangeP5(v, SQLITE_NULLEQ);
96384 sqlite3VdbeAddOp2(v, OP_Goto, 0, pWInfo->iContinue);
96386 sqlite3VdbeAddOp2(v, OP_Integer, 0, iFlag);
96387 assert( sqlite3VdbeCurrentAddr(v)==iJump );
96388 sqlite3VdbeAddOp3(v, OP_Move, iBase, iBase2, pEList->nExpr);
96389 }else{
96390 pOp->opcode = OP_Noop;
96394 /* Use the standard inner loop. */
96395 selectInnerLoop(pParse, p, pEList, 0, 0, pOrderBy, distinct, pDest,
96396 pWInfo->iContinue, pWInfo->iBreak);
96398 /* End the database scan loop.
96400 sqlite3WhereEnd(pWInfo);
96401 }else{
96402 /* This is the processing for aggregate queries */
96403 NameContext sNC; /* Name context for processing aggregate information */
96404 int iAMem; /* First Mem address for storing current GROUP BY */
96405 int iBMem; /* First Mem address for previous GROUP BY */
96406 int iUseFlag; /* Mem address holding flag indicating that at least
96407 ** one row of the input to the aggregator has been
96408 ** processed */
96409 int iAbortFlag; /* Mem address which causes query abort if positive */
96410 int groupBySort; /* Rows come from source in GROUP BY order */
96411 int addrEnd; /* End of processing for this SELECT */
96412 int sortPTab = 0; /* Pseudotable used to decode sorting results */
96413 int sortOut = 0; /* Output register from the sorter */
96415 /* Remove any and all aliases between the result set and the
96416 ** GROUP BY clause.
96418 if( pGroupBy ){
96419 int k; /* Loop counter */
96420 struct ExprList_item *pItem; /* For looping over expression in a list */
96422 for(k=p->pEList->nExpr, pItem=p->pEList->a; k>0; k--, pItem++){
96423 pItem->iAlias = 0;
96425 for(k=pGroupBy->nExpr, pItem=pGroupBy->a; k>0; k--, pItem++){
96426 pItem->iAlias = 0;
96428 if( p->nSelectRow>(double)100 ) p->nSelectRow = (double)100;
96429 }else{
96430 p->nSelectRow = (double)1;
96434 /* Create a label to jump to when we want to abort the query */
96435 addrEnd = sqlite3VdbeMakeLabel(v);
96437 /* Convert TK_COLUMN nodes into TK_AGG_COLUMN and make entries in
96438 ** sAggInfo for all TK_AGG_FUNCTION nodes in expressions of the
96439 ** SELECT statement.
96441 memset(&sNC, 0, sizeof(sNC));
96442 sNC.pParse = pParse;
96443 sNC.pSrcList = pTabList;
96444 sNC.pAggInfo = &sAggInfo;
96445 sAggInfo.nSortingColumn = pGroupBy ? pGroupBy->nExpr+1 : 0;
96446 sAggInfo.pGroupBy = pGroupBy;
96447 sqlite3ExprAnalyzeAggList(&sNC, pEList);
96448 sqlite3ExprAnalyzeAggList(&sNC, pOrderBy);
96449 if( pHaving ){
96450 sqlite3ExprAnalyzeAggregates(&sNC, pHaving);
96452 sAggInfo.nAccumulator = sAggInfo.nColumn;
96453 for(i=0; i<sAggInfo.nFunc; i++){
96454 assert( !ExprHasProperty(sAggInfo.aFunc[i].pExpr, EP_xIsSelect) );
96455 sqlite3ExprAnalyzeAggList(&sNC, sAggInfo.aFunc[i].pExpr->x.pList);
96457 if( db->mallocFailed ) goto select_end;
96459 /* Processing for aggregates with GROUP BY is very different and
96460 ** much more complex than aggregates without a GROUP BY.
96462 if( pGroupBy ){
96463 KeyInfo *pKeyInfo; /* Keying information for the group by clause */
96464 int j1; /* A-vs-B comparision jump */
96465 int addrOutputRow; /* Start of subroutine that outputs a result row */
96466 int regOutputRow; /* Return address register for output subroutine */
96467 int addrSetAbort; /* Set the abort flag and return */
96468 int addrTopOfLoop; /* Top of the input loop */
96469 int addrSortingIdx; /* The OP_OpenEphemeral for the sorting index */
96470 int addrReset; /* Subroutine for resetting the accumulator */
96471 int regReset; /* Return address register for reset subroutine */
96473 /* If there is a GROUP BY clause we might need a sorting index to
96474 ** implement it. Allocate that sorting index now. If it turns out
96475 ** that we do not need it after all, the OP_SorterOpen instruction
96476 ** will be converted into a Noop.
96478 sAggInfo.sortingIdx = pParse->nTab++;
96479 pKeyInfo = keyInfoFromExprList(pParse, pGroupBy);
96480 addrSortingIdx = sqlite3VdbeAddOp4(v, OP_SorterOpen,
96481 sAggInfo.sortingIdx, sAggInfo.nSortingColumn,
96482 0, (char*)pKeyInfo, P4_KEYINFO_HANDOFF);
96484 /* Initialize memory locations used by GROUP BY aggregate processing
96486 iUseFlag = ++pParse->nMem;
96487 iAbortFlag = ++pParse->nMem;
96488 regOutputRow = ++pParse->nMem;
96489 addrOutputRow = sqlite3VdbeMakeLabel(v);
96490 regReset = ++pParse->nMem;
96491 addrReset = sqlite3VdbeMakeLabel(v);
96492 iAMem = pParse->nMem + 1;
96493 pParse->nMem += pGroupBy->nExpr;
96494 iBMem = pParse->nMem + 1;
96495 pParse->nMem += pGroupBy->nExpr;
96496 sqlite3VdbeAddOp2(v, OP_Integer, 0, iAbortFlag);
96497 VdbeComment((v, "clear abort flag"));
96498 sqlite3VdbeAddOp2(v, OP_Integer, 0, iUseFlag);
96499 VdbeComment((v, "indicate accumulator empty"));
96501 /* Begin a loop that will extract all source rows in GROUP BY order.
96502 ** This might involve two separate loops with an OP_Sort in between, or
96503 ** it might be a single loop that uses an index to extract information
96504 ** in the right order to begin with.
96506 sqlite3VdbeAddOp2(v, OP_Gosub, regReset, addrReset);
96507 pWInfo = sqlite3WhereBegin(pParse, pTabList, pWhere, &pGroupBy, 0, 0);
96508 if( pWInfo==0 ) goto select_end;
96509 if( pGroupBy==0 ){
96510 /* The optimizer is able to deliver rows in group by order so
96511 ** we do not have to sort. The OP_OpenEphemeral table will be
96512 ** cancelled later because we still need to use the pKeyInfo
96514 pGroupBy = p->pGroupBy;
96515 groupBySort = 0;
96516 }else{
96517 /* Rows are coming out in undetermined order. We have to push
96518 ** each row into a sorting index, terminate the first loop,
96519 ** then loop over the sorting index in order to get the output
96520 ** in sorted order
96522 int regBase;
96523 int regRecord;
96524 int nCol;
96525 int nGroupBy;
96527 explainTempTable(pParse,
96528 isDistinct && !(p->selFlags&SF_Distinct)?"DISTINCT":"GROUP BY");
96530 groupBySort = 1;
96531 nGroupBy = pGroupBy->nExpr;
96532 nCol = nGroupBy + 1;
96533 j = nGroupBy+1;
96534 for(i=0; i<sAggInfo.nColumn; i++){
96535 if( sAggInfo.aCol[i].iSorterColumn>=j ){
96536 nCol++;
96537 j++;
96540 regBase = sqlite3GetTempRange(pParse, nCol);
96541 sqlite3ExprCacheClear(pParse);
96542 sqlite3ExprCodeExprList(pParse, pGroupBy, regBase, 0);
96543 sqlite3VdbeAddOp2(v, OP_Sequence, sAggInfo.sortingIdx,regBase+nGroupBy);
96544 j = nGroupBy+1;
96545 for(i=0; i<sAggInfo.nColumn; i++){
96546 struct AggInfo_col *pCol = &sAggInfo.aCol[i];
96547 if( pCol->iSorterColumn>=j ){
96548 int r1 = j + regBase;
96549 int r2;
96551 r2 = sqlite3ExprCodeGetColumn(pParse,
96552 pCol->pTab, pCol->iColumn, pCol->iTable, r1);
96553 if( r1!=r2 ){
96554 sqlite3VdbeAddOp2(v, OP_SCopy, r2, r1);
96556 j++;
96559 regRecord = sqlite3GetTempReg(pParse);
96560 sqlite3VdbeAddOp3(v, OP_MakeRecord, regBase, nCol, regRecord);
96561 sqlite3VdbeAddOp2(v, OP_SorterInsert, sAggInfo.sortingIdx, regRecord);
96562 sqlite3ReleaseTempReg(pParse, regRecord);
96563 sqlite3ReleaseTempRange(pParse, regBase, nCol);
96564 sqlite3WhereEnd(pWInfo);
96565 sAggInfo.sortingIdxPTab = sortPTab = pParse->nTab++;
96566 sortOut = sqlite3GetTempReg(pParse);
96567 sqlite3VdbeAddOp3(v, OP_OpenPseudo, sortPTab, sortOut, nCol);
96568 sqlite3VdbeAddOp2(v, OP_SorterSort, sAggInfo.sortingIdx, addrEnd);
96569 VdbeComment((v, "GROUP BY sort"));
96570 sAggInfo.useSortingIdx = 1;
96571 sqlite3ExprCacheClear(pParse);
96574 /* Evaluate the current GROUP BY terms and store in b0, b1, b2...
96575 ** (b0 is memory location iBMem+0, b1 is iBMem+1, and so forth)
96576 ** Then compare the current GROUP BY terms against the GROUP BY terms
96577 ** from the previous row currently stored in a0, a1, a2...
96579 addrTopOfLoop = sqlite3VdbeCurrentAddr(v);
96580 sqlite3ExprCacheClear(pParse);
96581 if( groupBySort ){
96582 sqlite3VdbeAddOp2(v, OP_SorterData, sAggInfo.sortingIdx, sortOut);
96584 for(j=0; j<pGroupBy->nExpr; j++){
96585 if( groupBySort ){
96586 sqlite3VdbeAddOp3(v, OP_Column, sortPTab, j, iBMem+j);
96587 if( j==0 ) sqlite3VdbeChangeP5(v, OPFLAG_CLEARCACHE);
96588 }else{
96589 sAggInfo.directMode = 1;
96590 sqlite3ExprCode(pParse, pGroupBy->a[j].pExpr, iBMem+j);
96593 sqlite3VdbeAddOp4(v, OP_Compare, iAMem, iBMem, pGroupBy->nExpr,
96594 (char*)pKeyInfo, P4_KEYINFO);
96595 j1 = sqlite3VdbeCurrentAddr(v);
96596 sqlite3VdbeAddOp3(v, OP_Jump, j1+1, 0, j1+1);
96598 /* Generate code that runs whenever the GROUP BY changes.
96599 ** Changes in the GROUP BY are detected by the previous code
96600 ** block. If there were no changes, this block is skipped.
96602 ** This code copies current group by terms in b0,b1,b2,...
96603 ** over to a0,a1,a2. It then calls the output subroutine
96604 ** and resets the aggregate accumulator registers in preparation
96605 ** for the next GROUP BY batch.
96607 sqlite3ExprCodeMove(pParse, iBMem, iAMem, pGroupBy->nExpr);
96608 sqlite3VdbeAddOp2(v, OP_Gosub, regOutputRow, addrOutputRow);
96609 VdbeComment((v, "output one row"));
96610 sqlite3VdbeAddOp2(v, OP_IfPos, iAbortFlag, addrEnd);
96611 VdbeComment((v, "check abort flag"));
96612 sqlite3VdbeAddOp2(v, OP_Gosub, regReset, addrReset);
96613 VdbeComment((v, "reset accumulator"));
96615 /* Update the aggregate accumulators based on the content of
96616 ** the current row
96618 sqlite3VdbeJumpHere(v, j1);
96619 updateAccumulator(pParse, &sAggInfo);
96620 sqlite3VdbeAddOp2(v, OP_Integer, 1, iUseFlag);
96621 VdbeComment((v, "indicate data in accumulator"));
96623 /* End of the loop
96625 if( groupBySort ){
96626 sqlite3VdbeAddOp2(v, OP_SorterNext, sAggInfo.sortingIdx, addrTopOfLoop);
96627 }else{
96628 sqlite3WhereEnd(pWInfo);
96629 sqlite3VdbeChangeToNoop(v, addrSortingIdx);
96632 /* Output the final row of result
96634 sqlite3VdbeAddOp2(v, OP_Gosub, regOutputRow, addrOutputRow);
96635 VdbeComment((v, "output final row"));
96637 /* Jump over the subroutines
96639 sqlite3VdbeAddOp2(v, OP_Goto, 0, addrEnd);
96641 /* Generate a subroutine that outputs a single row of the result
96642 ** set. This subroutine first looks at the iUseFlag. If iUseFlag
96643 ** is less than or equal to zero, the subroutine is a no-op. If
96644 ** the processing calls for the query to abort, this subroutine
96645 ** increments the iAbortFlag memory location before returning in
96646 ** order to signal the caller to abort.
96648 addrSetAbort = sqlite3VdbeCurrentAddr(v);
96649 sqlite3VdbeAddOp2(v, OP_Integer, 1, iAbortFlag);
96650 VdbeComment((v, "set abort flag"));
96651 sqlite3VdbeAddOp1(v, OP_Return, regOutputRow);
96652 sqlite3VdbeResolveLabel(v, addrOutputRow);
96653 addrOutputRow = sqlite3VdbeCurrentAddr(v);
96654 sqlite3VdbeAddOp2(v, OP_IfPos, iUseFlag, addrOutputRow+2);
96655 VdbeComment((v, "Groupby result generator entry point"));
96656 sqlite3VdbeAddOp1(v, OP_Return, regOutputRow);
96657 finalizeAggFunctions(pParse, &sAggInfo);
96658 sqlite3ExprIfFalse(pParse, pHaving, addrOutputRow+1, SQLITE_JUMPIFNULL);
96659 selectInnerLoop(pParse, p, p->pEList, 0, 0, pOrderBy,
96660 distinct, pDest,
96661 addrOutputRow+1, addrSetAbort);
96662 sqlite3VdbeAddOp1(v, OP_Return, regOutputRow);
96663 VdbeComment((v, "end groupby result generator"));
96665 /* Generate a subroutine that will reset the group-by accumulator
96667 sqlite3VdbeResolveLabel(v, addrReset);
96668 resetAccumulator(pParse, &sAggInfo);
96669 sqlite3VdbeAddOp1(v, OP_Return, regReset);
96671 } /* endif pGroupBy. Begin aggregate queries without GROUP BY: */
96672 else {
96673 ExprList *pDel = 0;
96674 #ifndef SQLITE_OMIT_BTREECOUNT
96675 Table *pTab;
96676 if( (pTab = isSimpleCount(p, &sAggInfo))!=0 ){
96677 /* If isSimpleCount() returns a pointer to a Table structure, then
96678 ** the SQL statement is of the form:
96680 ** SELECT count(*) FROM <tbl>
96682 ** where the Table structure returned represents table <tbl>.
96684 ** This statement is so common that it is optimized specially. The
96685 ** OP_Count instruction is executed either on the intkey table that
96686 ** contains the data for table <tbl> or on one of its indexes. It
96687 ** is better to execute the op on an index, as indexes are almost
96688 ** always spread across less pages than their corresponding tables.
96690 const int iDb = sqlite3SchemaToIndex(pParse->db, pTab->pSchema);
96691 const int iCsr = pParse->nTab++; /* Cursor to scan b-tree */
96692 Index *pIdx; /* Iterator variable */
96693 KeyInfo *pKeyInfo = 0; /* Keyinfo for scanned index */
96694 Index *pBest = 0; /* Best index found so far */
96695 int iRoot = pTab->tnum; /* Root page of scanned b-tree */
96697 sqlite3CodeVerifySchema(pParse, iDb);
96698 sqlite3TableLock(pParse, iDb, pTab->tnum, 0, pTab->zName);
96700 /* Search for the index that has the least amount of columns. If
96701 ** there is such an index, and it has less columns than the table
96702 ** does, then we can assume that it consumes less space on disk and
96703 ** will therefore be cheaper to scan to determine the query result.
96704 ** In this case set iRoot to the root page number of the index b-tree
96705 ** and pKeyInfo to the KeyInfo structure required to navigate the
96706 ** index.
96708 ** (2011-04-15) Do not do a full scan of an unordered index.
96710 ** In practice the KeyInfo structure will not be used. It is only
96711 ** passed to keep OP_OpenRead happy.
96713 for(pIdx=pTab->pIndex; pIdx; pIdx=pIdx->pNext){
96714 if( pIdx->bUnordered==0 && (!pBest || pIdx->nColumn<pBest->nColumn) ){
96715 pBest = pIdx;
96718 if( pBest && pBest->nColumn<pTab->nCol ){
96719 iRoot = pBest->tnum;
96720 pKeyInfo = sqlite3IndexKeyinfo(pParse, pBest);
96723 /* Open a read-only cursor, execute the OP_Count, close the cursor. */
96724 sqlite3VdbeAddOp3(v, OP_OpenRead, iCsr, iRoot, iDb);
96725 if( pKeyInfo ){
96726 sqlite3VdbeChangeP4(v, -1, (char *)pKeyInfo, P4_KEYINFO_HANDOFF);
96728 sqlite3VdbeAddOp2(v, OP_Count, iCsr, sAggInfo.aFunc[0].iMem);
96729 sqlite3VdbeAddOp1(v, OP_Close, iCsr);
96730 explainSimpleCount(pParse, pTab, pBest);
96731 }else
96732 #endif /* SQLITE_OMIT_BTREECOUNT */
96734 /* Check if the query is of one of the following forms:
96736 ** SELECT min(x) FROM ...
96737 ** SELECT max(x) FROM ...
96739 ** If it is, then ask the code in where.c to attempt to sort results
96740 ** as if there was an "ORDER ON x" or "ORDER ON x DESC" clause.
96741 ** If where.c is able to produce results sorted in this order, then
96742 ** add vdbe code to break out of the processing loop after the
96743 ** first iteration (since the first iteration of the loop is
96744 ** guaranteed to operate on the row with the minimum or maximum
96745 ** value of x, the only row required).
96747 ** A special flag must be passed to sqlite3WhereBegin() to slightly
96748 ** modify behaviour as follows:
96750 ** + If the query is a "SELECT min(x)", then the loop coded by
96751 ** where.c should not iterate over any values with a NULL value
96752 ** for x.
96754 ** + The optimizer code in where.c (the thing that decides which
96755 ** index or indices to use) should place a different priority on
96756 ** satisfying the 'ORDER BY' clause than it does in other cases.
96757 ** Refer to code and comments in where.c for details.
96759 ExprList *pMinMax = 0;
96760 u8 flag = minMaxQuery(p);
96761 if( flag ){
96762 assert( !ExprHasProperty(p->pEList->a[0].pExpr, EP_xIsSelect) );
96763 pMinMax = sqlite3ExprListDup(db, p->pEList->a[0].pExpr->x.pList,0);
96764 pDel = pMinMax;
96765 if( pMinMax && !db->mallocFailed ){
96766 pMinMax->a[0].sortOrder = flag!=WHERE_ORDERBY_MIN ?1:0;
96767 pMinMax->a[0].pExpr->op = TK_COLUMN;
96771 /* This case runs if the aggregate has no GROUP BY clause. The
96772 ** processing is much simpler since there is only a single row
96773 ** of output.
96775 resetAccumulator(pParse, &sAggInfo);
96776 pWInfo = sqlite3WhereBegin(pParse, pTabList, pWhere, &pMinMax, 0, flag);
96777 if( pWInfo==0 ){
96778 sqlite3ExprListDelete(db, pDel);
96779 goto select_end;
96781 updateAccumulator(pParse, &sAggInfo);
96782 if( !pMinMax && flag ){
96783 sqlite3VdbeAddOp2(v, OP_Goto, 0, pWInfo->iBreak);
96784 VdbeComment((v, "%s() by index",
96785 (flag==WHERE_ORDERBY_MIN?"min":"max")));
96787 sqlite3WhereEnd(pWInfo);
96788 finalizeAggFunctions(pParse, &sAggInfo);
96791 pOrderBy = 0;
96792 sqlite3ExprIfFalse(pParse, pHaving, addrEnd, SQLITE_JUMPIFNULL);
96793 selectInnerLoop(pParse, p, p->pEList, 0, 0, 0, -1,
96794 pDest, addrEnd, addrEnd);
96795 sqlite3ExprListDelete(db, pDel);
96797 sqlite3VdbeResolveLabel(v, addrEnd);
96799 } /* endif aggregate query */
96801 if( distinct>=0 ){
96802 explainTempTable(pParse, "DISTINCT");
96805 /* If there is an ORDER BY clause, then we need to sort the results
96806 ** and send them to the callback one by one.
96808 if( pOrderBy ){
96809 explainTempTable(pParse, "ORDER BY");
96810 generateSortTail(pParse, p, v, pEList->nExpr, pDest);
96813 /* Jump here to skip this query
96815 sqlite3VdbeResolveLabel(v, iEnd);
96817 /* The SELECT was successfully coded. Set the return code to 0
96818 ** to indicate no errors.
96820 rc = 0;
96822 /* Control jumps to here if an error is encountered above, or upon
96823 ** successful coding of the SELECT.
96825 select_end:
96826 explainSetInteger(pParse->iSelectId, iRestoreSelectId);
96828 /* Identify column names if results of the SELECT are to be output.
96830 if( rc==SQLITE_OK && pDest->eDest==SRT_Output ){
96831 generateColumnNames(pParse, pTabList, pEList);
96834 sqlite3DbFree(db, sAggInfo.aCol);
96835 sqlite3DbFree(db, sAggInfo.aFunc);
96836 return rc;
96839 #if defined(SQLITE_DEBUG)
96841 *******************************************************************************
96842 ** The following code is used for testing and debugging only. The code
96843 ** that follows does not appear in normal builds.
96845 ** These routines are used to print out the content of all or part of a
96846 ** parse structures such as Select or Expr. Such printouts are useful
96847 ** for helping to understand what is happening inside the code generator
96848 ** during the execution of complex SELECT statements.
96850 ** These routine are not called anywhere from within the normal
96851 ** code base. Then are intended to be called from within the debugger
96852 ** or from temporary "printf" statements inserted for debugging.
96854 SQLITE_PRIVATE void sqlite3PrintExpr(Expr *p){
96855 if( !ExprHasProperty(p, EP_IntValue) && p->u.zToken ){
96856 sqlite3DebugPrintf("(%s", p->u.zToken);
96857 }else{
96858 sqlite3DebugPrintf("(%d", p->op);
96860 if( p->pLeft ){
96861 sqlite3DebugPrintf(" ");
96862 sqlite3PrintExpr(p->pLeft);
96864 if( p->pRight ){
96865 sqlite3DebugPrintf(" ");
96866 sqlite3PrintExpr(p->pRight);
96868 sqlite3DebugPrintf(")");
96870 SQLITE_PRIVATE void sqlite3PrintExprList(ExprList *pList){
96871 int i;
96872 for(i=0; i<pList->nExpr; i++){
96873 sqlite3PrintExpr(pList->a[i].pExpr);
96874 if( i<pList->nExpr-1 ){
96875 sqlite3DebugPrintf(", ");
96879 SQLITE_PRIVATE void sqlite3PrintSelect(Select *p, int indent){
96880 sqlite3DebugPrintf("%*sSELECT(%p) ", indent, "", p);
96881 sqlite3PrintExprList(p->pEList);
96882 sqlite3DebugPrintf("\n");
96883 if( p->pSrc ){
96884 char *zPrefix;
96885 int i;
96886 zPrefix = "FROM";
96887 for(i=0; i<p->pSrc->nSrc; i++){
96888 struct SrcList_item *pItem = &p->pSrc->a[i];
96889 sqlite3DebugPrintf("%*s ", indent+6, zPrefix);
96890 zPrefix = "";
96891 if( pItem->pSelect ){
96892 sqlite3DebugPrintf("(\n");
96893 sqlite3PrintSelect(pItem->pSelect, indent+10);
96894 sqlite3DebugPrintf("%*s)", indent+8, "");
96895 }else if( pItem->zName ){
96896 sqlite3DebugPrintf("%s", pItem->zName);
96898 if( pItem->pTab ){
96899 sqlite3DebugPrintf("(table: %s)", pItem->pTab->zName);
96901 if( pItem->zAlias ){
96902 sqlite3DebugPrintf(" AS %s", pItem->zAlias);
96904 if( i<p->pSrc->nSrc-1 ){
96905 sqlite3DebugPrintf(",");
96907 sqlite3DebugPrintf("\n");
96910 if( p->pWhere ){
96911 sqlite3DebugPrintf("%*s WHERE ", indent, "");
96912 sqlite3PrintExpr(p->pWhere);
96913 sqlite3DebugPrintf("\n");
96915 if( p->pGroupBy ){
96916 sqlite3DebugPrintf("%*s GROUP BY ", indent, "");
96917 sqlite3PrintExprList(p->pGroupBy);
96918 sqlite3DebugPrintf("\n");
96920 if( p->pHaving ){
96921 sqlite3DebugPrintf("%*s HAVING ", indent, "");
96922 sqlite3PrintExpr(p->pHaving);
96923 sqlite3DebugPrintf("\n");
96925 if( p->pOrderBy ){
96926 sqlite3DebugPrintf("%*s ORDER BY ", indent, "");
96927 sqlite3PrintExprList(p->pOrderBy);
96928 sqlite3DebugPrintf("\n");
96931 /* End of the structure debug printing code
96932 *****************************************************************************/
96933 #endif /* defined(SQLITE_TEST) || defined(SQLITE_DEBUG) */
96935 /************** End of select.c **********************************************/
96936 /************** Begin file table.c *******************************************/
96938 ** 2001 September 15
96940 ** The author disclaims copyright to this source code. In place of
96941 ** a legal notice, here is a blessing:
96943 ** May you do good and not evil.
96944 ** May you find forgiveness for yourself and forgive others.
96945 ** May you share freely, never taking more than you give.
96947 *************************************************************************
96948 ** This file contains the sqlite3_get_table() and sqlite3_free_table()
96949 ** interface routines. These are just wrappers around the main
96950 ** interface routine of sqlite3_exec().
96952 ** These routines are in a separate files so that they will not be linked
96953 ** if they are not used.
96955 /* #include <stdlib.h> */
96956 /* #include <string.h> */
96958 #ifndef SQLITE_OMIT_GET_TABLE
96961 ** This structure is used to pass data from sqlite3_get_table() through
96962 ** to the callback function is uses to build the result.
96964 typedef struct TabResult {
96965 char **azResult; /* Accumulated output */
96966 char *zErrMsg; /* Error message text, if an error occurs */
96967 int nAlloc; /* Slots allocated for azResult[] */
96968 int nRow; /* Number of rows in the result */
96969 int nColumn; /* Number of columns in the result */
96970 int nData; /* Slots used in azResult[]. (nRow+1)*nColumn */
96971 int rc; /* Return code from sqlite3_exec() */
96972 } TabResult;
96975 ** This routine is called once for each row in the result table. Its job
96976 ** is to fill in the TabResult structure appropriately, allocating new
96977 ** memory as necessary.
96979 static int sqlite3_get_table_cb(void *pArg, int nCol, char **argv, char **colv){
96980 TabResult *p = (TabResult*)pArg; /* Result accumulator */
96981 int need; /* Slots needed in p->azResult[] */
96982 int i; /* Loop counter */
96983 char *z; /* A single column of result */
96985 /* Make sure there is enough space in p->azResult to hold everything
96986 ** we need to remember from this invocation of the callback.
96988 if( p->nRow==0 && argv!=0 ){
96989 need = nCol*2;
96990 }else{
96991 need = nCol;
96993 if( p->nData + need > p->nAlloc ){
96994 char **azNew;
96995 p->nAlloc = p->nAlloc*2 + need;
96996 azNew = sqlite3_realloc( p->azResult, sizeof(char*)*p->nAlloc );
96997 if( azNew==0 ) goto malloc_failed;
96998 p->azResult = azNew;
97001 /* If this is the first row, then generate an extra row containing
97002 ** the names of all columns.
97004 if( p->nRow==0 ){
97005 p->nColumn = nCol;
97006 for(i=0; i<nCol; i++){
97007 z = sqlite3_mprintf("%s", colv[i]);
97008 if( z==0 ) goto malloc_failed;
97009 p->azResult[p->nData++] = z;
97011 }else if( p->nColumn!=nCol ){
97012 sqlite3_free(p->zErrMsg);
97013 p->zErrMsg = sqlite3_mprintf(
97014 "sqlite3_get_table() called with two or more incompatible queries"
97016 p->rc = SQLITE_ERROR;
97017 return 1;
97020 /* Copy over the row data
97022 if( argv!=0 ){
97023 for(i=0; i<nCol; i++){
97024 if( argv[i]==0 ){
97025 z = 0;
97026 }else{
97027 int n = sqlite3Strlen30(argv[i])+1;
97028 z = sqlite3_malloc( n );
97029 if( z==0 ) goto malloc_failed;
97030 memcpy(z, argv[i], n);
97032 p->azResult[p->nData++] = z;
97034 p->nRow++;
97036 return 0;
97038 malloc_failed:
97039 p->rc = SQLITE_NOMEM;
97040 return 1;
97044 ** Query the database. But instead of invoking a callback for each row,
97045 ** malloc() for space to hold the result and return the entire results
97046 ** at the conclusion of the call.
97048 ** The result that is written to ***pazResult is held in memory obtained
97049 ** from malloc(). But the caller cannot free this memory directly.
97050 ** Instead, the entire table should be passed to sqlite3_free_table() when
97051 ** the calling procedure is finished using it.
97053 SQLITE_API int sqlite3_get_table(
97054 sqlite3 *db, /* The database on which the SQL executes */
97055 const char *zSql, /* The SQL to be executed */
97056 char ***pazResult, /* Write the result table here */
97057 int *pnRow, /* Write the number of rows in the result here */
97058 int *pnColumn, /* Write the number of columns of result here */
97059 char **pzErrMsg /* Write error messages here */
97061 int rc;
97062 TabResult res;
97064 *pazResult = 0;
97065 if( pnColumn ) *pnColumn = 0;
97066 if( pnRow ) *pnRow = 0;
97067 if( pzErrMsg ) *pzErrMsg = 0;
97068 res.zErrMsg = 0;
97069 res.nRow = 0;
97070 res.nColumn = 0;
97071 res.nData = 1;
97072 res.nAlloc = 20;
97073 res.rc = SQLITE_OK;
97074 res.azResult = sqlite3_malloc(sizeof(char*)*res.nAlloc );
97075 if( res.azResult==0 ){
97076 db->errCode = SQLITE_NOMEM;
97077 return SQLITE_NOMEM;
97079 res.azResult[0] = 0;
97080 rc = sqlite3_exec(db, zSql, sqlite3_get_table_cb, &res, pzErrMsg);
97081 assert( sizeof(res.azResult[0])>= sizeof(res.nData) );
97082 res.azResult[0] = SQLITE_INT_TO_PTR(res.nData);
97083 if( (rc&0xff)==SQLITE_ABORT ){
97084 sqlite3_free_table(&res.azResult[1]);
97085 if( res.zErrMsg ){
97086 if( pzErrMsg ){
97087 sqlite3_free(*pzErrMsg);
97088 *pzErrMsg = sqlite3_mprintf("%s",res.zErrMsg);
97090 sqlite3_free(res.zErrMsg);
97092 db->errCode = res.rc; /* Assume 32-bit assignment is atomic */
97093 return res.rc;
97095 sqlite3_free(res.zErrMsg);
97096 if( rc!=SQLITE_OK ){
97097 sqlite3_free_table(&res.azResult[1]);
97098 return rc;
97100 if( res.nAlloc>res.nData ){
97101 char **azNew;
97102 azNew = sqlite3_realloc( res.azResult, sizeof(char*)*res.nData );
97103 if( azNew==0 ){
97104 sqlite3_free_table(&res.azResult[1]);
97105 db->errCode = SQLITE_NOMEM;
97106 return SQLITE_NOMEM;
97108 res.azResult = azNew;
97110 *pazResult = &res.azResult[1];
97111 if( pnColumn ) *pnColumn = res.nColumn;
97112 if( pnRow ) *pnRow = res.nRow;
97113 return rc;
97117 ** This routine frees the space the sqlite3_get_table() malloced.
97119 SQLITE_API void sqlite3_free_table(
97120 char **azResult /* Result returned from from sqlite3_get_table() */
97122 if( azResult ){
97123 int i, n;
97124 azResult--;
97125 assert( azResult!=0 );
97126 n = SQLITE_PTR_TO_INT(azResult[0]);
97127 for(i=1; i<n; i++){ if( azResult[i] ) sqlite3_free(azResult[i]); }
97128 sqlite3_free(azResult);
97132 #endif /* SQLITE_OMIT_GET_TABLE */
97134 /************** End of table.c ***********************************************/
97135 /************** Begin file trigger.c *****************************************/
97138 ** The author disclaims copyright to this source code. In place of
97139 ** a legal notice, here is a blessing:
97141 ** May you do good and not evil.
97142 ** May you find forgiveness for yourself and forgive others.
97143 ** May you share freely, never taking more than you give.
97145 *************************************************************************
97146 ** This file contains the implementation for TRIGGERs
97149 #ifndef SQLITE_OMIT_TRIGGER
97151 ** Delete a linked list of TriggerStep structures.
97153 SQLITE_PRIVATE void sqlite3DeleteTriggerStep(sqlite3 *db, TriggerStep *pTriggerStep){
97154 while( pTriggerStep ){
97155 TriggerStep * pTmp = pTriggerStep;
97156 pTriggerStep = pTriggerStep->pNext;
97158 sqlite3ExprDelete(db, pTmp->pWhere);
97159 sqlite3ExprListDelete(db, pTmp->pExprList);
97160 sqlite3SelectDelete(db, pTmp->pSelect);
97161 sqlite3IdListDelete(db, pTmp->pIdList);
97163 sqlite3DbFree(db, pTmp);
97168 ** Given table pTab, return a list of all the triggers attached to
97169 ** the table. The list is connected by Trigger.pNext pointers.
97171 ** All of the triggers on pTab that are in the same database as pTab
97172 ** are already attached to pTab->pTrigger. But there might be additional
97173 ** triggers on pTab in the TEMP schema. This routine prepends all
97174 ** TEMP triggers on pTab to the beginning of the pTab->pTrigger list
97175 ** and returns the combined list.
97177 ** To state it another way: This routine returns a list of all triggers
97178 ** that fire off of pTab. The list will include any TEMP triggers on
97179 ** pTab as well as the triggers lised in pTab->pTrigger.
97181 SQLITE_PRIVATE Trigger *sqlite3TriggerList(Parse *pParse, Table *pTab){
97182 Schema * const pTmpSchema = pParse->db->aDb[1].pSchema;
97183 Trigger *pList = 0; /* List of triggers to return */
97185 if( pParse->disableTriggers ){
97186 return 0;
97189 if( pTmpSchema!=pTab->pSchema ){
97190 HashElem *p;
97191 assert( sqlite3SchemaMutexHeld(pParse->db, 0, pTmpSchema) );
97192 for(p=sqliteHashFirst(&pTmpSchema->trigHash); p; p=sqliteHashNext(p)){
97193 Trigger *pTrig = (Trigger *)sqliteHashData(p);
97194 if( pTrig->pTabSchema==pTab->pSchema
97195 && 0==sqlite3StrICmp(pTrig->table, pTab->zName)
97197 pTrig->pNext = (pList ? pList : pTab->pTrigger);
97198 pList = pTrig;
97203 return (pList ? pList : pTab->pTrigger);
97207 ** This is called by the parser when it sees a CREATE TRIGGER statement
97208 ** up to the point of the BEGIN before the trigger actions. A Trigger
97209 ** structure is generated based on the information available and stored
97210 ** in pParse->pNewTrigger. After the trigger actions have been parsed, the
97211 ** sqlite3FinishTrigger() function is called to complete the trigger
97212 ** construction process.
97214 SQLITE_PRIVATE void sqlite3BeginTrigger(
97215 Parse *pParse, /* The parse context of the CREATE TRIGGER statement */
97216 Token *pName1, /* The name of the trigger */
97217 Token *pName2, /* The name of the trigger */
97218 int tr_tm, /* One of TK_BEFORE, TK_AFTER, TK_INSTEAD */
97219 int op, /* One of TK_INSERT, TK_UPDATE, TK_DELETE */
97220 IdList *pColumns, /* column list if this is an UPDATE OF trigger */
97221 SrcList *pTableName,/* The name of the table/view the trigger applies to */
97222 Expr *pWhen, /* WHEN clause */
97223 int isTemp, /* True if the TEMPORARY keyword is present */
97224 int noErr /* Suppress errors if the trigger already exists */
97226 Trigger *pTrigger = 0; /* The new trigger */
97227 Table *pTab; /* Table that the trigger fires off of */
97228 char *zName = 0; /* Name of the trigger */
97229 sqlite3 *db = pParse->db; /* The database connection */
97230 int iDb; /* The database to store the trigger in */
97231 Token *pName; /* The unqualified db name */
97232 DbFixer sFix; /* State vector for the DB fixer */
97233 int iTabDb; /* Index of the database holding pTab */
97235 assert( pName1!=0 ); /* pName1->z might be NULL, but not pName1 itself */
97236 assert( pName2!=0 );
97237 assert( op==TK_INSERT || op==TK_UPDATE || op==TK_DELETE );
97238 assert( op>0 && op<0xff );
97239 if( isTemp ){
97240 /* If TEMP was specified, then the trigger name may not be qualified. */
97241 if( pName2->n>0 ){
97242 sqlite3ErrorMsg(pParse, "temporary trigger may not have qualified name");
97243 goto trigger_cleanup;
97245 iDb = 1;
97246 pName = pName1;
97247 }else{
97248 /* Figure out the db that the the trigger will be created in */
97249 iDb = sqlite3TwoPartName(pParse, pName1, pName2, &pName);
97250 if( iDb<0 ){
97251 goto trigger_cleanup;
97254 if( !pTableName || db->mallocFailed ){
97255 goto trigger_cleanup;
97258 /* A long-standing parser bug is that this syntax was allowed:
97260 ** CREATE TRIGGER attached.demo AFTER INSERT ON attached.tab ....
97261 ** ^^^^^^^^
97263 ** To maintain backwards compatibility, ignore the database
97264 ** name on pTableName if we are reparsing our of SQLITE_MASTER.
97266 if( db->init.busy && iDb!=1 ){
97267 sqlite3DbFree(db, pTableName->a[0].zDatabase);
97268 pTableName->a[0].zDatabase = 0;
97271 /* If the trigger name was unqualified, and the table is a temp table,
97272 ** then set iDb to 1 to create the trigger in the temporary database.
97273 ** If sqlite3SrcListLookup() returns 0, indicating the table does not
97274 ** exist, the error is caught by the block below.
97276 pTab = sqlite3SrcListLookup(pParse, pTableName);
97277 if( db->init.busy==0 && pName2->n==0 && pTab
97278 && pTab->pSchema==db->aDb[1].pSchema ){
97279 iDb = 1;
97282 /* Ensure the table name matches database name and that the table exists */
97283 if( db->mallocFailed ) goto trigger_cleanup;
97284 assert( pTableName->nSrc==1 );
97285 if( sqlite3FixInit(&sFix, pParse, iDb, "trigger", pName) &&
97286 sqlite3FixSrcList(&sFix, pTableName) ){
97287 goto trigger_cleanup;
97289 pTab = sqlite3SrcListLookup(pParse, pTableName);
97290 if( !pTab ){
97291 /* The table does not exist. */
97292 if( db->init.iDb==1 ){
97293 /* Ticket #3810.
97294 ** Normally, whenever a table is dropped, all associated triggers are
97295 ** dropped too. But if a TEMP trigger is created on a non-TEMP table
97296 ** and the table is dropped by a different database connection, the
97297 ** trigger is not visible to the database connection that does the
97298 ** drop so the trigger cannot be dropped. This results in an
97299 ** "orphaned trigger" - a trigger whose associated table is missing.
97301 db->init.orphanTrigger = 1;
97303 goto trigger_cleanup;
97305 if( IsVirtual(pTab) ){
97306 sqlite3ErrorMsg(pParse, "cannot create triggers on virtual tables");
97307 goto trigger_cleanup;
97310 /* Check that the trigger name is not reserved and that no trigger of the
97311 ** specified name exists */
97312 zName = sqlite3NameFromToken(db, pName);
97313 if( !zName || SQLITE_OK!=sqlite3CheckObjectName(pParse, zName) ){
97314 goto trigger_cleanup;
97316 assert( sqlite3SchemaMutexHeld(db, iDb, 0) );
97317 if( sqlite3HashFind(&(db->aDb[iDb].pSchema->trigHash),
97318 zName, sqlite3Strlen30(zName)) ){
97319 if( !noErr ){
97320 sqlite3ErrorMsg(pParse, "trigger %T already exists", pName);
97321 }else{
97322 assert( !db->init.busy );
97323 sqlite3CodeVerifySchema(pParse, iDb);
97325 goto trigger_cleanup;
97328 /* Do not create a trigger on a system table */
97329 if( sqlite3StrNICmp(pTab->zName, "sqlite_", 7)==0 ){
97330 sqlite3ErrorMsg(pParse, "cannot create trigger on system table");
97331 pParse->nErr++;
97332 goto trigger_cleanup;
97335 /* INSTEAD of triggers are only for views and views only support INSTEAD
97336 ** of triggers.
97338 if( pTab->pSelect && tr_tm!=TK_INSTEAD ){
97339 sqlite3ErrorMsg(pParse, "cannot create %s trigger on view: %S",
97340 (tr_tm == TK_BEFORE)?"BEFORE":"AFTER", pTableName, 0);
97341 goto trigger_cleanup;
97343 if( !pTab->pSelect && tr_tm==TK_INSTEAD ){
97344 sqlite3ErrorMsg(pParse, "cannot create INSTEAD OF"
97345 " trigger on table: %S", pTableName, 0);
97346 goto trigger_cleanup;
97348 iTabDb = sqlite3SchemaToIndex(db, pTab->pSchema);
97350 #ifndef SQLITE_OMIT_AUTHORIZATION
97352 int code = SQLITE_CREATE_TRIGGER;
97353 const char *zDb = db->aDb[iTabDb].zName;
97354 const char *zDbTrig = isTemp ? db->aDb[1].zName : zDb;
97355 if( iTabDb==1 || isTemp ) code = SQLITE_CREATE_TEMP_TRIGGER;
97356 if( sqlite3AuthCheck(pParse, code, zName, pTab->zName, zDbTrig) ){
97357 goto trigger_cleanup;
97359 if( sqlite3AuthCheck(pParse, SQLITE_INSERT, SCHEMA_TABLE(iTabDb),0,zDb)){
97360 goto trigger_cleanup;
97363 #endif
97365 /* INSTEAD OF triggers can only appear on views and BEFORE triggers
97366 ** cannot appear on views. So we might as well translate every
97367 ** INSTEAD OF trigger into a BEFORE trigger. It simplifies code
97368 ** elsewhere.
97370 if (tr_tm == TK_INSTEAD){
97371 tr_tm = TK_BEFORE;
97374 /* Build the Trigger object */
97375 pTrigger = (Trigger*)sqlite3DbMallocZero(db, sizeof(Trigger));
97376 if( pTrigger==0 ) goto trigger_cleanup;
97377 pTrigger->zName = zName;
97378 zName = 0;
97379 pTrigger->table = sqlite3DbStrDup(db, pTableName->a[0].zName);
97380 pTrigger->pSchema = db->aDb[iDb].pSchema;
97381 pTrigger->pTabSchema = pTab->pSchema;
97382 pTrigger->op = (u8)op;
97383 pTrigger->tr_tm = tr_tm==TK_BEFORE ? TRIGGER_BEFORE : TRIGGER_AFTER;
97384 pTrigger->pWhen = sqlite3ExprDup(db, pWhen, EXPRDUP_REDUCE);
97385 pTrigger->pColumns = sqlite3IdListDup(db, pColumns);
97386 assert( pParse->pNewTrigger==0 );
97387 pParse->pNewTrigger = pTrigger;
97389 trigger_cleanup:
97390 sqlite3DbFree(db, zName);
97391 sqlite3SrcListDelete(db, pTableName);
97392 sqlite3IdListDelete(db, pColumns);
97393 sqlite3ExprDelete(db, pWhen);
97394 if( !pParse->pNewTrigger ){
97395 sqlite3DeleteTrigger(db, pTrigger);
97396 }else{
97397 assert( pParse->pNewTrigger==pTrigger );
97402 ** This routine is called after all of the trigger actions have been parsed
97403 ** in order to complete the process of building the trigger.
97405 SQLITE_PRIVATE void sqlite3FinishTrigger(
97406 Parse *pParse, /* Parser context */
97407 TriggerStep *pStepList, /* The triggered program */
97408 Token *pAll /* Token that describes the complete CREATE TRIGGER */
97410 Trigger *pTrig = pParse->pNewTrigger; /* Trigger being finished */
97411 char *zName; /* Name of trigger */
97412 sqlite3 *db = pParse->db; /* The database */
97413 DbFixer sFix; /* Fixer object */
97414 int iDb; /* Database containing the trigger */
97415 Token nameToken; /* Trigger name for error reporting */
97417 pParse->pNewTrigger = 0;
97418 if( NEVER(pParse->nErr) || !pTrig ) goto triggerfinish_cleanup;
97419 zName = pTrig->zName;
97420 iDb = sqlite3SchemaToIndex(pParse->db, pTrig->pSchema);
97421 pTrig->step_list = pStepList;
97422 while( pStepList ){
97423 pStepList->pTrig = pTrig;
97424 pStepList = pStepList->pNext;
97426 nameToken.z = pTrig->zName;
97427 nameToken.n = sqlite3Strlen30(nameToken.z);
97428 if( sqlite3FixInit(&sFix, pParse, iDb, "trigger", &nameToken)
97429 && sqlite3FixTriggerStep(&sFix, pTrig->step_list) ){
97430 goto triggerfinish_cleanup;
97433 /* if we are not initializing,
97434 ** build the sqlite_master entry
97436 if( !db->init.busy ){
97437 Vdbe *v;
97438 char *z;
97440 /* Make an entry in the sqlite_master table */
97441 v = sqlite3GetVdbe(pParse);
97442 if( v==0 ) goto triggerfinish_cleanup;
97443 sqlite3BeginWriteOperation(pParse, 0, iDb);
97444 z = sqlite3DbStrNDup(db, (char*)pAll->z, pAll->n);
97445 sqlite3NestedParse(pParse,
97446 "INSERT INTO %Q.%s VALUES('trigger',%Q,%Q,0,'CREATE TRIGGER %q')",
97447 db->aDb[iDb].zName, SCHEMA_TABLE(iDb), zName,
97448 pTrig->table, z);
97449 sqlite3DbFree(db, z);
97450 sqlite3ChangeCookie(pParse, iDb);
97451 sqlite3VdbeAddParseSchemaOp(v, iDb,
97452 sqlite3MPrintf(db, "type='trigger' AND name='%q'", zName));
97455 if( db->init.busy ){
97456 Trigger *pLink = pTrig;
97457 Hash *pHash = &db->aDb[iDb].pSchema->trigHash;
97458 assert( sqlite3SchemaMutexHeld(db, iDb, 0) );
97459 pTrig = sqlite3HashInsert(pHash, zName, sqlite3Strlen30(zName), pTrig);
97460 if( pTrig ){
97461 db->mallocFailed = 1;
97462 }else if( pLink->pSchema==pLink->pTabSchema ){
97463 Table *pTab;
97464 int n = sqlite3Strlen30(pLink->table);
97465 pTab = sqlite3HashFind(&pLink->pTabSchema->tblHash, pLink->table, n);
97466 assert( pTab!=0 );
97467 pLink->pNext = pTab->pTrigger;
97468 pTab->pTrigger = pLink;
97472 triggerfinish_cleanup:
97473 sqlite3DeleteTrigger(db, pTrig);
97474 assert( !pParse->pNewTrigger );
97475 sqlite3DeleteTriggerStep(db, pStepList);
97479 ** Turn a SELECT statement (that the pSelect parameter points to) into
97480 ** a trigger step. Return a pointer to a TriggerStep structure.
97482 ** The parser calls this routine when it finds a SELECT statement in
97483 ** body of a TRIGGER.
97485 SQLITE_PRIVATE TriggerStep *sqlite3TriggerSelectStep(sqlite3 *db, Select *pSelect){
97486 TriggerStep *pTriggerStep = sqlite3DbMallocZero(db, sizeof(TriggerStep));
97487 if( pTriggerStep==0 ) {
97488 sqlite3SelectDelete(db, pSelect);
97489 return 0;
97491 pTriggerStep->op = TK_SELECT;
97492 pTriggerStep->pSelect = pSelect;
97493 pTriggerStep->orconf = OE_Default;
97494 return pTriggerStep;
97498 ** Allocate space to hold a new trigger step. The allocated space
97499 ** holds both the TriggerStep object and the TriggerStep.target.z string.
97501 ** If an OOM error occurs, NULL is returned and db->mallocFailed is set.
97503 static TriggerStep *triggerStepAllocate(
97504 sqlite3 *db, /* Database connection */
97505 u8 op, /* Trigger opcode */
97506 Token *pName /* The target name */
97508 TriggerStep *pTriggerStep;
97510 pTriggerStep = sqlite3DbMallocZero(db, sizeof(TriggerStep) + pName->n);
97511 if( pTriggerStep ){
97512 char *z = (char*)&pTriggerStep[1];
97513 memcpy(z, pName->z, pName->n);
97514 pTriggerStep->target.z = z;
97515 pTriggerStep->target.n = pName->n;
97516 pTriggerStep->op = op;
97518 return pTriggerStep;
97522 ** Build a trigger step out of an INSERT statement. Return a pointer
97523 ** to the new trigger step.
97525 ** The parser calls this routine when it sees an INSERT inside the
97526 ** body of a trigger.
97528 SQLITE_PRIVATE TriggerStep *sqlite3TriggerInsertStep(
97529 sqlite3 *db, /* The database connection */
97530 Token *pTableName, /* Name of the table into which we insert */
97531 IdList *pColumn, /* List of columns in pTableName to insert into */
97532 ExprList *pEList, /* The VALUE clause: a list of values to be inserted */
97533 Select *pSelect, /* A SELECT statement that supplies values */
97534 u8 orconf /* The conflict algorithm (OE_Abort, OE_Replace, etc.) */
97536 TriggerStep *pTriggerStep;
97538 assert(pEList == 0 || pSelect == 0);
97539 assert(pEList != 0 || pSelect != 0 || db->mallocFailed);
97541 pTriggerStep = triggerStepAllocate(db, TK_INSERT, pTableName);
97542 if( pTriggerStep ){
97543 pTriggerStep->pSelect = sqlite3SelectDup(db, pSelect, EXPRDUP_REDUCE);
97544 pTriggerStep->pIdList = pColumn;
97545 pTriggerStep->pExprList = sqlite3ExprListDup(db, pEList, EXPRDUP_REDUCE);
97546 pTriggerStep->orconf = orconf;
97547 }else{
97548 sqlite3IdListDelete(db, pColumn);
97550 sqlite3ExprListDelete(db, pEList);
97551 sqlite3SelectDelete(db, pSelect);
97553 return pTriggerStep;
97557 ** Construct a trigger step that implements an UPDATE statement and return
97558 ** a pointer to that trigger step. The parser calls this routine when it
97559 ** sees an UPDATE statement inside the body of a CREATE TRIGGER.
97561 SQLITE_PRIVATE TriggerStep *sqlite3TriggerUpdateStep(
97562 sqlite3 *db, /* The database connection */
97563 Token *pTableName, /* Name of the table to be updated */
97564 ExprList *pEList, /* The SET clause: list of column and new values */
97565 Expr *pWhere, /* The WHERE clause */
97566 u8 orconf /* The conflict algorithm. (OE_Abort, OE_Ignore, etc) */
97568 TriggerStep *pTriggerStep;
97570 pTriggerStep = triggerStepAllocate(db, TK_UPDATE, pTableName);
97571 if( pTriggerStep ){
97572 pTriggerStep->pExprList = sqlite3ExprListDup(db, pEList, EXPRDUP_REDUCE);
97573 pTriggerStep->pWhere = sqlite3ExprDup(db, pWhere, EXPRDUP_REDUCE);
97574 pTriggerStep->orconf = orconf;
97576 sqlite3ExprListDelete(db, pEList);
97577 sqlite3ExprDelete(db, pWhere);
97578 return pTriggerStep;
97582 ** Construct a trigger step that implements a DELETE statement and return
97583 ** a pointer to that trigger step. The parser calls this routine when it
97584 ** sees a DELETE statement inside the body of a CREATE TRIGGER.
97586 SQLITE_PRIVATE TriggerStep *sqlite3TriggerDeleteStep(
97587 sqlite3 *db, /* Database connection */
97588 Token *pTableName, /* The table from which rows are deleted */
97589 Expr *pWhere /* The WHERE clause */
97591 TriggerStep *pTriggerStep;
97593 pTriggerStep = triggerStepAllocate(db, TK_DELETE, pTableName);
97594 if( pTriggerStep ){
97595 pTriggerStep->pWhere = sqlite3ExprDup(db, pWhere, EXPRDUP_REDUCE);
97596 pTriggerStep->orconf = OE_Default;
97598 sqlite3ExprDelete(db, pWhere);
97599 return pTriggerStep;
97603 ** Recursively delete a Trigger structure
97605 SQLITE_PRIVATE void sqlite3DeleteTrigger(sqlite3 *db, Trigger *pTrigger){
97606 if( pTrigger==0 ) return;
97607 sqlite3DeleteTriggerStep(db, pTrigger->step_list);
97608 sqlite3DbFree(db, pTrigger->zName);
97609 sqlite3DbFree(db, pTrigger->table);
97610 sqlite3ExprDelete(db, pTrigger->pWhen);
97611 sqlite3IdListDelete(db, pTrigger->pColumns);
97612 sqlite3DbFree(db, pTrigger);
97616 ** This function is called to drop a trigger from the database schema.
97618 ** This may be called directly from the parser and therefore identifies
97619 ** the trigger by name. The sqlite3DropTriggerPtr() routine does the
97620 ** same job as this routine except it takes a pointer to the trigger
97621 ** instead of the trigger name.
97623 SQLITE_PRIVATE void sqlite3DropTrigger(Parse *pParse, SrcList *pName, int noErr){
97624 Trigger *pTrigger = 0;
97625 int i;
97626 const char *zDb;
97627 const char *zName;
97628 int nName;
97629 sqlite3 *db = pParse->db;
97631 if( db->mallocFailed ) goto drop_trigger_cleanup;
97632 if( SQLITE_OK!=sqlite3ReadSchema(pParse) ){
97633 goto drop_trigger_cleanup;
97636 assert( pName->nSrc==1 );
97637 zDb = pName->a[0].zDatabase;
97638 zName = pName->a[0].zName;
97639 nName = sqlite3Strlen30(zName);
97640 assert( zDb!=0 || sqlite3BtreeHoldsAllMutexes(db) );
97641 for(i=OMIT_TEMPDB; i<db->nDb; i++){
97642 int j = (i<2) ? i^1 : i; /* Search TEMP before MAIN */
97643 if( zDb && sqlite3StrICmp(db->aDb[j].zName, zDb) ) continue;
97644 assert( sqlite3SchemaMutexHeld(db, j, 0) );
97645 pTrigger = sqlite3HashFind(&(db->aDb[j].pSchema->trigHash), zName, nName);
97646 if( pTrigger ) break;
97648 if( !pTrigger ){
97649 if( !noErr ){
97650 sqlite3ErrorMsg(pParse, "no such trigger: %S", pName, 0);
97651 }else{
97652 sqlite3CodeVerifyNamedSchema(pParse, zDb);
97654 pParse->checkSchema = 1;
97655 goto drop_trigger_cleanup;
97657 sqlite3DropTriggerPtr(pParse, pTrigger);
97659 drop_trigger_cleanup:
97660 sqlite3SrcListDelete(db, pName);
97664 ** Return a pointer to the Table structure for the table that a trigger
97665 ** is set on.
97667 static Table *tableOfTrigger(Trigger *pTrigger){
97668 int n = sqlite3Strlen30(pTrigger->table);
97669 return sqlite3HashFind(&pTrigger->pTabSchema->tblHash, pTrigger->table, n);
97674 ** Drop a trigger given a pointer to that trigger.
97676 SQLITE_PRIVATE void sqlite3DropTriggerPtr(Parse *pParse, Trigger *pTrigger){
97677 Table *pTable;
97678 Vdbe *v;
97679 sqlite3 *db = pParse->db;
97680 int iDb;
97682 iDb = sqlite3SchemaToIndex(pParse->db, pTrigger->pSchema);
97683 assert( iDb>=0 && iDb<db->nDb );
97684 pTable = tableOfTrigger(pTrigger);
97685 assert( pTable );
97686 assert( pTable->pSchema==pTrigger->pSchema || iDb==1 );
97687 #ifndef SQLITE_OMIT_AUTHORIZATION
97689 int code = SQLITE_DROP_TRIGGER;
97690 const char *zDb = db->aDb[iDb].zName;
97691 const char *zTab = SCHEMA_TABLE(iDb);
97692 if( iDb==1 ) code = SQLITE_DROP_TEMP_TRIGGER;
97693 if( sqlite3AuthCheck(pParse, code, pTrigger->zName, pTable->zName, zDb) ||
97694 sqlite3AuthCheck(pParse, SQLITE_DELETE, zTab, 0, zDb) ){
97695 return;
97698 #endif
97700 /* Generate code to destroy the database record of the trigger.
97702 assert( pTable!=0 );
97703 if( (v = sqlite3GetVdbe(pParse))!=0 ){
97704 int base;
97705 static const VdbeOpList dropTrigger[] = {
97706 { OP_Rewind, 0, ADDR(9), 0},
97707 { OP_String8, 0, 1, 0}, /* 1 */
97708 { OP_Column, 0, 1, 2},
97709 { OP_Ne, 2, ADDR(8), 1},
97710 { OP_String8, 0, 1, 0}, /* 4: "trigger" */
97711 { OP_Column, 0, 0, 2},
97712 { OP_Ne, 2, ADDR(8), 1},
97713 { OP_Delete, 0, 0, 0},
97714 { OP_Next, 0, ADDR(1), 0}, /* 8 */
97717 sqlite3BeginWriteOperation(pParse, 0, iDb);
97718 sqlite3OpenMasterTable(pParse, iDb);
97719 base = sqlite3VdbeAddOpList(v, ArraySize(dropTrigger), dropTrigger);
97720 sqlite3VdbeChangeP4(v, base+1, pTrigger->zName, P4_TRANSIENT);
97721 sqlite3VdbeChangeP4(v, base+4, "trigger", P4_STATIC);
97722 sqlite3ChangeCookie(pParse, iDb);
97723 sqlite3VdbeAddOp2(v, OP_Close, 0, 0);
97724 sqlite3VdbeAddOp4(v, OP_DropTrigger, iDb, 0, 0, pTrigger->zName, 0);
97725 if( pParse->nMem<3 ){
97726 pParse->nMem = 3;
97732 ** Remove a trigger from the hash tables of the sqlite* pointer.
97734 SQLITE_PRIVATE void sqlite3UnlinkAndDeleteTrigger(sqlite3 *db, int iDb, const char *zName){
97735 Trigger *pTrigger;
97736 Hash *pHash;
97738 assert( sqlite3SchemaMutexHeld(db, iDb, 0) );
97739 pHash = &(db->aDb[iDb].pSchema->trigHash);
97740 pTrigger = sqlite3HashInsert(pHash, zName, sqlite3Strlen30(zName), 0);
97741 if( ALWAYS(pTrigger) ){
97742 if( pTrigger->pSchema==pTrigger->pTabSchema ){
97743 Table *pTab = tableOfTrigger(pTrigger);
97744 Trigger **pp;
97745 for(pp=&pTab->pTrigger; *pp!=pTrigger; pp=&((*pp)->pNext));
97746 *pp = (*pp)->pNext;
97748 sqlite3DeleteTrigger(db, pTrigger);
97749 db->flags |= SQLITE_InternChanges;
97754 ** pEList is the SET clause of an UPDATE statement. Each entry
97755 ** in pEList is of the format <id>=<expr>. If any of the entries
97756 ** in pEList have an <id> which matches an identifier in pIdList,
97757 ** then return TRUE. If pIdList==NULL, then it is considered a
97758 ** wildcard that matches anything. Likewise if pEList==NULL then
97759 ** it matches anything so always return true. Return false only
97760 ** if there is no match.
97762 static int checkColumnOverlap(IdList *pIdList, ExprList *pEList){
97763 int e;
97764 if( pIdList==0 || NEVER(pEList==0) ) return 1;
97765 for(e=0; e<pEList->nExpr; e++){
97766 if( sqlite3IdListIndex(pIdList, pEList->a[e].zName)>=0 ) return 1;
97768 return 0;
97772 ** Return a list of all triggers on table pTab if there exists at least
97773 ** one trigger that must be fired when an operation of type 'op' is
97774 ** performed on the table, and, if that operation is an UPDATE, if at
97775 ** least one of the columns in pChanges is being modified.
97777 SQLITE_PRIVATE Trigger *sqlite3TriggersExist(
97778 Parse *pParse, /* Parse context */
97779 Table *pTab, /* The table the contains the triggers */
97780 int op, /* one of TK_DELETE, TK_INSERT, TK_UPDATE */
97781 ExprList *pChanges, /* Columns that change in an UPDATE statement */
97782 int *pMask /* OUT: Mask of TRIGGER_BEFORE|TRIGGER_AFTER */
97784 int mask = 0;
97785 Trigger *pList = 0;
97786 Trigger *p;
97788 if( (pParse->db->flags & SQLITE_EnableTrigger)!=0 ){
97789 pList = sqlite3TriggerList(pParse, pTab);
97791 assert( pList==0 || IsVirtual(pTab)==0 );
97792 for(p=pList; p; p=p->pNext){
97793 if( p->op==op && checkColumnOverlap(p->pColumns, pChanges) ){
97794 mask |= p->tr_tm;
97797 if( pMask ){
97798 *pMask = mask;
97800 return (mask ? pList : 0);
97804 ** Convert the pStep->target token into a SrcList and return a pointer
97805 ** to that SrcList.
97807 ** This routine adds a specific database name, if needed, to the target when
97808 ** forming the SrcList. This prevents a trigger in one database from
97809 ** referring to a target in another database. An exception is when the
97810 ** trigger is in TEMP in which case it can refer to any other database it
97811 ** wants.
97813 static SrcList *targetSrcList(
97814 Parse *pParse, /* The parsing context */
97815 TriggerStep *pStep /* The trigger containing the target token */
97817 int iDb; /* Index of the database to use */
97818 SrcList *pSrc; /* SrcList to be returned */
97820 pSrc = sqlite3SrcListAppend(pParse->db, 0, &pStep->target, 0);
97821 if( pSrc ){
97822 assert( pSrc->nSrc>0 );
97823 assert( pSrc->a!=0 );
97824 iDb = sqlite3SchemaToIndex(pParse->db, pStep->pTrig->pSchema);
97825 if( iDb==0 || iDb>=2 ){
97826 sqlite3 *db = pParse->db;
97827 assert( iDb<pParse->db->nDb );
97828 pSrc->a[pSrc->nSrc-1].zDatabase = sqlite3DbStrDup(db, db->aDb[iDb].zName);
97831 return pSrc;
97835 ** Generate VDBE code for the statements inside the body of a single
97836 ** trigger.
97838 static int codeTriggerProgram(
97839 Parse *pParse, /* The parser context */
97840 TriggerStep *pStepList, /* List of statements inside the trigger body */
97841 int orconf /* Conflict algorithm. (OE_Abort, etc) */
97843 TriggerStep *pStep;
97844 Vdbe *v = pParse->pVdbe;
97845 sqlite3 *db = pParse->db;
97847 assert( pParse->pTriggerTab && pParse->pToplevel );
97848 assert( pStepList );
97849 assert( v!=0 );
97850 for(pStep=pStepList; pStep; pStep=pStep->pNext){
97851 /* Figure out the ON CONFLICT policy that will be used for this step
97852 ** of the trigger program. If the statement that caused this trigger
97853 ** to fire had an explicit ON CONFLICT, then use it. Otherwise, use
97854 ** the ON CONFLICT policy that was specified as part of the trigger
97855 ** step statement. Example:
97857 ** CREATE TRIGGER AFTER INSERT ON t1 BEGIN;
97858 ** INSERT OR REPLACE INTO t2 VALUES(new.a, new.b);
97859 ** END;
97861 ** INSERT INTO t1 ... ; -- insert into t2 uses REPLACE policy
97862 ** INSERT OR IGNORE INTO t1 ... ; -- insert into t2 uses IGNORE policy
97864 pParse->eOrconf = (orconf==OE_Default)?pStep->orconf:(u8)orconf;
97866 switch( pStep->op ){
97867 case TK_UPDATE: {
97868 sqlite3Update(pParse,
97869 targetSrcList(pParse, pStep),
97870 sqlite3ExprListDup(db, pStep->pExprList, 0),
97871 sqlite3ExprDup(db, pStep->pWhere, 0),
97872 pParse->eOrconf
97874 break;
97876 case TK_INSERT: {
97877 sqlite3Insert(pParse,
97878 targetSrcList(pParse, pStep),
97879 sqlite3ExprListDup(db, pStep->pExprList, 0),
97880 sqlite3SelectDup(db, pStep->pSelect, 0),
97881 sqlite3IdListDup(db, pStep->pIdList),
97882 pParse->eOrconf
97884 break;
97886 case TK_DELETE: {
97887 sqlite3DeleteFrom(pParse,
97888 targetSrcList(pParse, pStep),
97889 sqlite3ExprDup(db, pStep->pWhere, 0)
97891 break;
97893 default: assert( pStep->op==TK_SELECT ); {
97894 SelectDest sDest;
97895 Select *pSelect = sqlite3SelectDup(db, pStep->pSelect, 0);
97896 sqlite3SelectDestInit(&sDest, SRT_Discard, 0);
97897 sqlite3Select(pParse, pSelect, &sDest);
97898 sqlite3SelectDelete(db, pSelect);
97899 break;
97902 if( pStep->op!=TK_SELECT ){
97903 sqlite3VdbeAddOp0(v, OP_ResetCount);
97907 return 0;
97910 #ifdef SQLITE_DEBUG
97912 ** This function is used to add VdbeComment() annotations to a VDBE
97913 ** program. It is not used in production code, only for debugging.
97915 static const char *onErrorText(int onError){
97916 switch( onError ){
97917 case OE_Abort: return "abort";
97918 case OE_Rollback: return "rollback";
97919 case OE_Fail: return "fail";
97920 case OE_Replace: return "replace";
97921 case OE_Ignore: return "ignore";
97922 case OE_Default: return "default";
97924 return "n/a";
97926 #endif
97929 ** Parse context structure pFrom has just been used to create a sub-vdbe
97930 ** (trigger program). If an error has occurred, transfer error information
97931 ** from pFrom to pTo.
97933 static void transferParseError(Parse *pTo, Parse *pFrom){
97934 assert( pFrom->zErrMsg==0 || pFrom->nErr );
97935 assert( pTo->zErrMsg==0 || pTo->nErr );
97936 if( pTo->nErr==0 ){
97937 pTo->zErrMsg = pFrom->zErrMsg;
97938 pTo->nErr = pFrom->nErr;
97939 }else{
97940 sqlite3DbFree(pFrom->db, pFrom->zErrMsg);
97945 ** Create and populate a new TriggerPrg object with a sub-program
97946 ** implementing trigger pTrigger with ON CONFLICT policy orconf.
97948 static TriggerPrg *codeRowTrigger(
97949 Parse *pParse, /* Current parse context */
97950 Trigger *pTrigger, /* Trigger to code */
97951 Table *pTab, /* The table pTrigger is attached to */
97952 int orconf /* ON CONFLICT policy to code trigger program with */
97954 Parse *pTop = sqlite3ParseToplevel(pParse);
97955 sqlite3 *db = pParse->db; /* Database handle */
97956 TriggerPrg *pPrg; /* Value to return */
97957 Expr *pWhen = 0; /* Duplicate of trigger WHEN expression */
97958 Vdbe *v; /* Temporary VM */
97959 NameContext sNC; /* Name context for sub-vdbe */
97960 SubProgram *pProgram = 0; /* Sub-vdbe for trigger program */
97961 Parse *pSubParse; /* Parse context for sub-vdbe */
97962 int iEndTrigger = 0; /* Label to jump to if WHEN is false */
97964 assert( pTrigger->zName==0 || pTab==tableOfTrigger(pTrigger) );
97965 assert( pTop->pVdbe );
97967 /* Allocate the TriggerPrg and SubProgram objects. To ensure that they
97968 ** are freed if an error occurs, link them into the Parse.pTriggerPrg
97969 ** list of the top-level Parse object sooner rather than later. */
97970 pPrg = sqlite3DbMallocZero(db, sizeof(TriggerPrg));
97971 if( !pPrg ) return 0;
97972 pPrg->pNext = pTop->pTriggerPrg;
97973 pTop->pTriggerPrg = pPrg;
97974 pPrg->pProgram = pProgram = sqlite3DbMallocZero(db, sizeof(SubProgram));
97975 if( !pProgram ) return 0;
97976 sqlite3VdbeLinkSubProgram(pTop->pVdbe, pProgram);
97977 pPrg->pTrigger = pTrigger;
97978 pPrg->orconf = orconf;
97979 pPrg->aColmask[0] = 0xffffffff;
97980 pPrg->aColmask[1] = 0xffffffff;
97982 /* Allocate and populate a new Parse context to use for coding the
97983 ** trigger sub-program. */
97984 pSubParse = sqlite3StackAllocZero(db, sizeof(Parse));
97985 if( !pSubParse ) return 0;
97986 memset(&sNC, 0, sizeof(sNC));
97987 sNC.pParse = pSubParse;
97988 pSubParse->db = db;
97989 pSubParse->pTriggerTab = pTab;
97990 pSubParse->pToplevel = pTop;
97991 pSubParse->zAuthContext = pTrigger->zName;
97992 pSubParse->eTriggerOp = pTrigger->op;
97993 pSubParse->nQueryLoop = pParse->nQueryLoop;
97995 v = sqlite3GetVdbe(pSubParse);
97996 if( v ){
97997 VdbeComment((v, "Start: %s.%s (%s %s%s%s ON %s)",
97998 pTrigger->zName, onErrorText(orconf),
97999 (pTrigger->tr_tm==TRIGGER_BEFORE ? "BEFORE" : "AFTER"),
98000 (pTrigger->op==TK_UPDATE ? "UPDATE" : ""),
98001 (pTrigger->op==TK_INSERT ? "INSERT" : ""),
98002 (pTrigger->op==TK_DELETE ? "DELETE" : ""),
98003 pTab->zName
98005 #ifndef SQLITE_OMIT_TRACE
98006 sqlite3VdbeChangeP4(v, -1,
98007 sqlite3MPrintf(db, "-- TRIGGER %s", pTrigger->zName), P4_DYNAMIC
98009 #endif
98011 /* If one was specified, code the WHEN clause. If it evaluates to false
98012 ** (or NULL) the sub-vdbe is immediately halted by jumping to the
98013 ** OP_Halt inserted at the end of the program. */
98014 if( pTrigger->pWhen ){
98015 pWhen = sqlite3ExprDup(db, pTrigger->pWhen, 0);
98016 if( SQLITE_OK==sqlite3ResolveExprNames(&sNC, pWhen)
98017 && db->mallocFailed==0
98019 iEndTrigger = sqlite3VdbeMakeLabel(v);
98020 sqlite3ExprIfFalse(pSubParse, pWhen, iEndTrigger, SQLITE_JUMPIFNULL);
98022 sqlite3ExprDelete(db, pWhen);
98025 /* Code the trigger program into the sub-vdbe. */
98026 codeTriggerProgram(pSubParse, pTrigger->step_list, orconf);
98028 /* Insert an OP_Halt at the end of the sub-program. */
98029 if( iEndTrigger ){
98030 sqlite3VdbeResolveLabel(v, iEndTrigger);
98032 sqlite3VdbeAddOp0(v, OP_Halt);
98033 VdbeComment((v, "End: %s.%s", pTrigger->zName, onErrorText(orconf)));
98035 transferParseError(pParse, pSubParse);
98036 if( db->mallocFailed==0 ){
98037 pProgram->aOp = sqlite3VdbeTakeOpArray(v, &pProgram->nOp, &pTop->nMaxArg);
98039 pProgram->nMem = pSubParse->nMem;
98040 pProgram->nCsr = pSubParse->nTab;
98041 pProgram->token = (void *)pTrigger;
98042 pPrg->aColmask[0] = pSubParse->oldmask;
98043 pPrg->aColmask[1] = pSubParse->newmask;
98044 sqlite3VdbeDelete(v);
98047 assert( !pSubParse->pAinc && !pSubParse->pZombieTab );
98048 assert( !pSubParse->pTriggerPrg && !pSubParse->nMaxArg );
98049 sqlite3StackFree(db, pSubParse);
98051 return pPrg;
98055 ** Return a pointer to a TriggerPrg object containing the sub-program for
98056 ** trigger pTrigger with default ON CONFLICT algorithm orconf. If no such
98057 ** TriggerPrg object exists, a new object is allocated and populated before
98058 ** being returned.
98060 static TriggerPrg *getRowTrigger(
98061 Parse *pParse, /* Current parse context */
98062 Trigger *pTrigger, /* Trigger to code */
98063 Table *pTab, /* The table trigger pTrigger is attached to */
98064 int orconf /* ON CONFLICT algorithm. */
98066 Parse *pRoot = sqlite3ParseToplevel(pParse);
98067 TriggerPrg *pPrg;
98069 assert( pTrigger->zName==0 || pTab==tableOfTrigger(pTrigger) );
98071 /* It may be that this trigger has already been coded (or is in the
98072 ** process of being coded). If this is the case, then an entry with
98073 ** a matching TriggerPrg.pTrigger field will be present somewhere
98074 ** in the Parse.pTriggerPrg list. Search for such an entry. */
98075 for(pPrg=pRoot->pTriggerPrg;
98076 pPrg && (pPrg->pTrigger!=pTrigger || pPrg->orconf!=orconf);
98077 pPrg=pPrg->pNext
98080 /* If an existing TriggerPrg could not be located, create a new one. */
98081 if( !pPrg ){
98082 pPrg = codeRowTrigger(pParse, pTrigger, pTab, orconf);
98085 return pPrg;
98089 ** Generate code for the trigger program associated with trigger p on
98090 ** table pTab. The reg, orconf and ignoreJump parameters passed to this
98091 ** function are the same as those described in the header function for
98092 ** sqlite3CodeRowTrigger()
98094 SQLITE_PRIVATE void sqlite3CodeRowTriggerDirect(
98095 Parse *pParse, /* Parse context */
98096 Trigger *p, /* Trigger to code */
98097 Table *pTab, /* The table to code triggers from */
98098 int reg, /* Reg array containing OLD.* and NEW.* values */
98099 int orconf, /* ON CONFLICT policy */
98100 int ignoreJump /* Instruction to jump to for RAISE(IGNORE) */
98102 Vdbe *v = sqlite3GetVdbe(pParse); /* Main VM */
98103 TriggerPrg *pPrg;
98104 pPrg = getRowTrigger(pParse, p, pTab, orconf);
98105 assert( pPrg || pParse->nErr || pParse->db->mallocFailed );
98107 /* Code the OP_Program opcode in the parent VDBE. P4 of the OP_Program
98108 ** is a pointer to the sub-vdbe containing the trigger program. */
98109 if( pPrg ){
98110 int bRecursive = (p->zName && 0==(pParse->db->flags&SQLITE_RecTriggers));
98112 sqlite3VdbeAddOp3(v, OP_Program, reg, ignoreJump, ++pParse->nMem);
98113 sqlite3VdbeChangeP4(v, -1, (const char *)pPrg->pProgram, P4_SUBPROGRAM);
98114 VdbeComment(
98115 (v, "Call: %s.%s", (p->zName?p->zName:"fkey"), onErrorText(orconf)));
98117 /* Set the P5 operand of the OP_Program instruction to non-zero if
98118 ** recursive invocation of this trigger program is disallowed. Recursive
98119 ** invocation is disallowed if (a) the sub-program is really a trigger,
98120 ** not a foreign key action, and (b) the flag to enable recursive triggers
98121 ** is clear. */
98122 sqlite3VdbeChangeP5(v, (u8)bRecursive);
98127 ** This is called to code the required FOR EACH ROW triggers for an operation
98128 ** on table pTab. The operation to code triggers for (INSERT, UPDATE or DELETE)
98129 ** is given by the op paramater. The tr_tm parameter determines whether the
98130 ** BEFORE or AFTER triggers are coded. If the operation is an UPDATE, then
98131 ** parameter pChanges is passed the list of columns being modified.
98133 ** If there are no triggers that fire at the specified time for the specified
98134 ** operation on pTab, this function is a no-op.
98136 ** The reg argument is the address of the first in an array of registers
98137 ** that contain the values substituted for the new.* and old.* references
98138 ** in the trigger program. If N is the number of columns in table pTab
98139 ** (a copy of pTab->nCol), then registers are populated as follows:
98141 ** Register Contains
98142 ** ------------------------------------------------------
98143 ** reg+0 OLD.rowid
98144 ** reg+1 OLD.* value of left-most column of pTab
98145 ** ... ...
98146 ** reg+N OLD.* value of right-most column of pTab
98147 ** reg+N+1 NEW.rowid
98148 ** reg+N+2 OLD.* value of left-most column of pTab
98149 ** ... ...
98150 ** reg+N+N+1 NEW.* value of right-most column of pTab
98152 ** For ON DELETE triggers, the registers containing the NEW.* values will
98153 ** never be accessed by the trigger program, so they are not allocated or
98154 ** populated by the caller (there is no data to populate them with anyway).
98155 ** Similarly, for ON INSERT triggers the values stored in the OLD.* registers
98156 ** are never accessed, and so are not allocated by the caller. So, for an
98157 ** ON INSERT trigger, the value passed to this function as parameter reg
98158 ** is not a readable register, although registers (reg+N) through
98159 ** (reg+N+N+1) are.
98161 ** Parameter orconf is the default conflict resolution algorithm for the
98162 ** trigger program to use (REPLACE, IGNORE etc.). Parameter ignoreJump
98163 ** is the instruction that control should jump to if a trigger program
98164 ** raises an IGNORE exception.
98166 SQLITE_PRIVATE void sqlite3CodeRowTrigger(
98167 Parse *pParse, /* Parse context */
98168 Trigger *pTrigger, /* List of triggers on table pTab */
98169 int op, /* One of TK_UPDATE, TK_INSERT, TK_DELETE */
98170 ExprList *pChanges, /* Changes list for any UPDATE OF triggers */
98171 int tr_tm, /* One of TRIGGER_BEFORE, TRIGGER_AFTER */
98172 Table *pTab, /* The table to code triggers from */
98173 int reg, /* The first in an array of registers (see above) */
98174 int orconf, /* ON CONFLICT policy */
98175 int ignoreJump /* Instruction to jump to for RAISE(IGNORE) */
98177 Trigger *p; /* Used to iterate through pTrigger list */
98179 assert( op==TK_UPDATE || op==TK_INSERT || op==TK_DELETE );
98180 assert( tr_tm==TRIGGER_BEFORE || tr_tm==TRIGGER_AFTER );
98181 assert( (op==TK_UPDATE)==(pChanges!=0) );
98183 for(p=pTrigger; p; p=p->pNext){
98185 /* Sanity checking: The schema for the trigger and for the table are
98186 ** always defined. The trigger must be in the same schema as the table
98187 ** or else it must be a TEMP trigger. */
98188 assert( p->pSchema!=0 );
98189 assert( p->pTabSchema!=0 );
98190 assert( p->pSchema==p->pTabSchema
98191 || p->pSchema==pParse->db->aDb[1].pSchema );
98193 /* Determine whether we should code this trigger */
98194 if( p->op==op
98195 && p->tr_tm==tr_tm
98196 && checkColumnOverlap(p->pColumns, pChanges)
98198 sqlite3CodeRowTriggerDirect(pParse, p, pTab, reg, orconf, ignoreJump);
98204 ** Triggers may access values stored in the old.* or new.* pseudo-table.
98205 ** This function returns a 32-bit bitmask indicating which columns of the
98206 ** old.* or new.* tables actually are used by triggers. This information
98207 ** may be used by the caller, for example, to avoid having to load the entire
98208 ** old.* record into memory when executing an UPDATE or DELETE command.
98210 ** Bit 0 of the returned mask is set if the left-most column of the
98211 ** table may be accessed using an [old|new].<col> reference. Bit 1 is set if
98212 ** the second leftmost column value is required, and so on. If there
98213 ** are more than 32 columns in the table, and at least one of the columns
98214 ** with an index greater than 32 may be accessed, 0xffffffff is returned.
98216 ** It is not possible to determine if the old.rowid or new.rowid column is
98217 ** accessed by triggers. The caller must always assume that it is.
98219 ** Parameter isNew must be either 1 or 0. If it is 0, then the mask returned
98220 ** applies to the old.* table. If 1, the new.* table.
98222 ** Parameter tr_tm must be a mask with one or both of the TRIGGER_BEFORE
98223 ** and TRIGGER_AFTER bits set. Values accessed by BEFORE triggers are only
98224 ** included in the returned mask if the TRIGGER_BEFORE bit is set in the
98225 ** tr_tm parameter. Similarly, values accessed by AFTER triggers are only
98226 ** included in the returned mask if the TRIGGER_AFTER bit is set in tr_tm.
98228 SQLITE_PRIVATE u32 sqlite3TriggerColmask(
98229 Parse *pParse, /* Parse context */
98230 Trigger *pTrigger, /* List of triggers on table pTab */
98231 ExprList *pChanges, /* Changes list for any UPDATE OF triggers */
98232 int isNew, /* 1 for new.* ref mask, 0 for old.* ref mask */
98233 int tr_tm, /* Mask of TRIGGER_BEFORE|TRIGGER_AFTER */
98234 Table *pTab, /* The table to code triggers from */
98235 int orconf /* Default ON CONFLICT policy for trigger steps */
98237 const int op = pChanges ? TK_UPDATE : TK_DELETE;
98238 u32 mask = 0;
98239 Trigger *p;
98241 assert( isNew==1 || isNew==0 );
98242 for(p=pTrigger; p; p=p->pNext){
98243 if( p->op==op && (tr_tm&p->tr_tm)
98244 && checkColumnOverlap(p->pColumns,pChanges)
98246 TriggerPrg *pPrg;
98247 pPrg = getRowTrigger(pParse, p, pTab, orconf);
98248 if( pPrg ){
98249 mask |= pPrg->aColmask[isNew];
98254 return mask;
98257 #endif /* !defined(SQLITE_OMIT_TRIGGER) */
98259 /************** End of trigger.c *********************************************/
98260 /************** Begin file update.c ******************************************/
98262 ** 2001 September 15
98264 ** The author disclaims copyright to this source code. In place of
98265 ** a legal notice, here is a blessing:
98267 ** May you do good and not evil.
98268 ** May you find forgiveness for yourself and forgive others.
98269 ** May you share freely, never taking more than you give.
98271 *************************************************************************
98272 ** This file contains C code routines that are called by the parser
98273 ** to handle UPDATE statements.
98276 #ifndef SQLITE_OMIT_VIRTUALTABLE
98277 /* Forward declaration */
98278 static void updateVirtualTable(
98279 Parse *pParse, /* The parsing context */
98280 SrcList *pSrc, /* The virtual table to be modified */
98281 Table *pTab, /* The virtual table */
98282 ExprList *pChanges, /* The columns to change in the UPDATE statement */
98283 Expr *pRowidExpr, /* Expression used to recompute the rowid */
98284 int *aXRef, /* Mapping from columns of pTab to entries in pChanges */
98285 Expr *pWhere, /* WHERE clause of the UPDATE statement */
98286 int onError /* ON CONFLICT strategy */
98288 #endif /* SQLITE_OMIT_VIRTUALTABLE */
98291 ** The most recently coded instruction was an OP_Column to retrieve the
98292 ** i-th column of table pTab. This routine sets the P4 parameter of the
98293 ** OP_Column to the default value, if any.
98295 ** The default value of a column is specified by a DEFAULT clause in the
98296 ** column definition. This was either supplied by the user when the table
98297 ** was created, or added later to the table definition by an ALTER TABLE
98298 ** command. If the latter, then the row-records in the table btree on disk
98299 ** may not contain a value for the column and the default value, taken
98300 ** from the P4 parameter of the OP_Column instruction, is returned instead.
98301 ** If the former, then all row-records are guaranteed to include a value
98302 ** for the column and the P4 value is not required.
98304 ** Column definitions created by an ALTER TABLE command may only have
98305 ** literal default values specified: a number, null or a string. (If a more
98306 ** complicated default expression value was provided, it is evaluated
98307 ** when the ALTER TABLE is executed and one of the literal values written
98308 ** into the sqlite_master table.)
98310 ** Therefore, the P4 parameter is only required if the default value for
98311 ** the column is a literal number, string or null. The sqlite3ValueFromExpr()
98312 ** function is capable of transforming these types of expressions into
98313 ** sqlite3_value objects.
98315 ** If parameter iReg is not negative, code an OP_RealAffinity instruction
98316 ** on register iReg. This is used when an equivalent integer value is
98317 ** stored in place of an 8-byte floating point value in order to save
98318 ** space.
98320 SQLITE_PRIVATE void sqlite3ColumnDefault(Vdbe *v, Table *pTab, int i, int iReg){
98321 assert( pTab!=0 );
98322 if( !pTab->pSelect ){
98323 sqlite3_value *pValue;
98324 u8 enc = ENC(sqlite3VdbeDb(v));
98325 Column *pCol = &pTab->aCol[i];
98326 VdbeComment((v, "%s.%s", pTab->zName, pCol->zName));
98327 assert( i<pTab->nCol );
98328 sqlite3ValueFromExpr(sqlite3VdbeDb(v), pCol->pDflt, enc,
98329 pCol->affinity, &pValue);
98330 if( pValue ){
98331 sqlite3VdbeChangeP4(v, -1, (const char *)pValue, P4_MEM);
98333 #ifndef SQLITE_OMIT_FLOATING_POINT
98334 if( iReg>=0 && pTab->aCol[i].affinity==SQLITE_AFF_REAL ){
98335 sqlite3VdbeAddOp1(v, OP_RealAffinity, iReg);
98337 #endif
98342 ** Process an UPDATE statement.
98344 ** UPDATE OR IGNORE table_wxyz SET a=b, c=d WHERE e<5 AND f NOT NULL;
98345 ** \_______/ \________/ \______/ \________________/
98346 * onError pTabList pChanges pWhere
98348 SQLITE_PRIVATE void sqlite3Update(
98349 Parse *pParse, /* The parser context */
98350 SrcList *pTabList, /* The table in which we should change things */
98351 ExprList *pChanges, /* Things to be changed */
98352 Expr *pWhere, /* The WHERE clause. May be null */
98353 int onError /* How to handle constraint errors */
98355 int i, j; /* Loop counters */
98356 Table *pTab; /* The table to be updated */
98357 int addr = 0; /* VDBE instruction address of the start of the loop */
98358 WhereInfo *pWInfo; /* Information about the WHERE clause */
98359 Vdbe *v; /* The virtual database engine */
98360 Index *pIdx; /* For looping over indices */
98361 int nIdx; /* Number of indices that need updating */
98362 int iCur; /* VDBE Cursor number of pTab */
98363 sqlite3 *db; /* The database structure */
98364 int *aRegIdx = 0; /* One register assigned to each index to be updated */
98365 int *aXRef = 0; /* aXRef[i] is the index in pChanges->a[] of the
98366 ** an expression for the i-th column of the table.
98367 ** aXRef[i]==-1 if the i-th column is not changed. */
98368 int chngRowid; /* True if the record number is being changed */
98369 Expr *pRowidExpr = 0; /* Expression defining the new record number */
98370 int openAll = 0; /* True if all indices need to be opened */
98371 AuthContext sContext; /* The authorization context */
98372 NameContext sNC; /* The name-context to resolve expressions in */
98373 int iDb; /* Database containing the table being updated */
98374 int okOnePass; /* True for one-pass algorithm without the FIFO */
98375 int hasFK; /* True if foreign key processing is required */
98377 #ifndef SQLITE_OMIT_TRIGGER
98378 int isView; /* True when updating a view (INSTEAD OF trigger) */
98379 Trigger *pTrigger; /* List of triggers on pTab, if required */
98380 int tmask; /* Mask of TRIGGER_BEFORE|TRIGGER_AFTER */
98381 #endif
98382 int newmask; /* Mask of NEW.* columns accessed by BEFORE triggers */
98384 /* Register Allocations */
98385 int regRowCount = 0; /* A count of rows changed */
98386 int regOldRowid; /* The old rowid */
98387 int regNewRowid; /* The new rowid */
98388 int regNew;
98389 int regOld = 0;
98390 int regRowSet = 0; /* Rowset of rows to be updated */
98392 memset(&sContext, 0, sizeof(sContext));
98393 db = pParse->db;
98394 if( pParse->nErr || db->mallocFailed ){
98395 goto update_cleanup;
98397 assert( pTabList->nSrc==1 );
98399 /* Locate the table which we want to update.
98401 pTab = sqlite3SrcListLookup(pParse, pTabList);
98402 if( pTab==0 ) goto update_cleanup;
98403 iDb = sqlite3SchemaToIndex(pParse->db, pTab->pSchema);
98405 /* Figure out if we have any triggers and if the table being
98406 ** updated is a view.
98408 #ifndef SQLITE_OMIT_TRIGGER
98409 pTrigger = sqlite3TriggersExist(pParse, pTab, TK_UPDATE, pChanges, &tmask);
98410 isView = pTab->pSelect!=0;
98411 assert( pTrigger || tmask==0 );
98412 #else
98413 # define pTrigger 0
98414 # define isView 0
98415 # define tmask 0
98416 #endif
98417 #ifdef SQLITE_OMIT_VIEW
98418 # undef isView
98419 # define isView 0
98420 #endif
98422 if( sqlite3ViewGetColumnNames(pParse, pTab) ){
98423 goto update_cleanup;
98425 if( sqlite3IsReadOnly(pParse, pTab, tmask) ){
98426 goto update_cleanup;
98428 aXRef = sqlite3DbMallocRaw(db, sizeof(int) * pTab->nCol );
98429 if( aXRef==0 ) goto update_cleanup;
98430 for(i=0; i<pTab->nCol; i++) aXRef[i] = -1;
98432 /* Allocate a cursors for the main database table and for all indices.
98433 ** The index cursors might not be used, but if they are used they
98434 ** need to occur right after the database cursor. So go ahead and
98435 ** allocate enough space, just in case.
98437 pTabList->a[0].iCursor = iCur = pParse->nTab++;
98438 for(pIdx=pTab->pIndex; pIdx; pIdx=pIdx->pNext){
98439 pParse->nTab++;
98442 /* Initialize the name-context */
98443 memset(&sNC, 0, sizeof(sNC));
98444 sNC.pParse = pParse;
98445 sNC.pSrcList = pTabList;
98447 /* Resolve the column names in all the expressions of the
98448 ** of the UPDATE statement. Also find the column index
98449 ** for each column to be updated in the pChanges array. For each
98450 ** column to be updated, make sure we have authorization to change
98451 ** that column.
98453 chngRowid = 0;
98454 for(i=0; i<pChanges->nExpr; i++){
98455 if( sqlite3ResolveExprNames(&sNC, pChanges->a[i].pExpr) ){
98456 goto update_cleanup;
98458 for(j=0; j<pTab->nCol; j++){
98459 if( sqlite3StrICmp(pTab->aCol[j].zName, pChanges->a[i].zName)==0 ){
98460 if( j==pTab->iPKey ){
98461 chngRowid = 1;
98462 pRowidExpr = pChanges->a[i].pExpr;
98464 aXRef[j] = i;
98465 break;
98468 if( j>=pTab->nCol ){
98469 if( sqlite3IsRowid(pChanges->a[i].zName) ){
98470 chngRowid = 1;
98471 pRowidExpr = pChanges->a[i].pExpr;
98472 }else{
98473 sqlite3ErrorMsg(pParse, "no such column: %s", pChanges->a[i].zName);
98474 pParse->checkSchema = 1;
98475 goto update_cleanup;
98478 #ifndef SQLITE_OMIT_AUTHORIZATION
98480 int rc;
98481 rc = sqlite3AuthCheck(pParse, SQLITE_UPDATE, pTab->zName,
98482 pTab->aCol[j].zName, db->aDb[iDb].zName);
98483 if( rc==SQLITE_DENY ){
98484 goto update_cleanup;
98485 }else if( rc==SQLITE_IGNORE ){
98486 aXRef[j] = -1;
98489 #endif
98492 hasFK = sqlite3FkRequired(pParse, pTab, aXRef, chngRowid);
98494 /* Allocate memory for the array aRegIdx[]. There is one entry in the
98495 ** array for each index associated with table being updated. Fill in
98496 ** the value with a register number for indices that are to be used
98497 ** and with zero for unused indices.
98499 for(nIdx=0, pIdx=pTab->pIndex; pIdx; pIdx=pIdx->pNext, nIdx++){}
98500 if( nIdx>0 ){
98501 aRegIdx = sqlite3DbMallocRaw(db, sizeof(Index*) * nIdx );
98502 if( aRegIdx==0 ) goto update_cleanup;
98504 for(j=0, pIdx=pTab->pIndex; pIdx; pIdx=pIdx->pNext, j++){
98505 int reg;
98506 if( hasFK || chngRowid ){
98507 reg = ++pParse->nMem;
98508 }else{
98509 reg = 0;
98510 for(i=0; i<pIdx->nColumn; i++){
98511 if( aXRef[pIdx->aiColumn[i]]>=0 ){
98512 reg = ++pParse->nMem;
98513 break;
98517 aRegIdx[j] = reg;
98520 /* Begin generating code. */
98521 v = sqlite3GetVdbe(pParse);
98522 if( v==0 ) goto update_cleanup;
98523 if( pParse->nested==0 ) sqlite3VdbeCountChanges(v);
98524 sqlite3BeginWriteOperation(pParse, 1, iDb);
98526 #ifndef SQLITE_OMIT_VIRTUALTABLE
98527 /* Virtual tables must be handled separately */
98528 if( IsVirtual(pTab) ){
98529 updateVirtualTable(pParse, pTabList, pTab, pChanges, pRowidExpr, aXRef,
98530 pWhere, onError);
98531 pWhere = 0;
98532 pTabList = 0;
98533 goto update_cleanup;
98535 #endif
98537 /* Allocate required registers. */
98538 regOldRowid = regNewRowid = ++pParse->nMem;
98539 if( pTrigger || hasFK ){
98540 regOld = pParse->nMem + 1;
98541 pParse->nMem += pTab->nCol;
98543 if( chngRowid || pTrigger || hasFK ){
98544 regNewRowid = ++pParse->nMem;
98546 regNew = pParse->nMem + 1;
98547 pParse->nMem += pTab->nCol;
98549 /* Start the view context. */
98550 if( isView ){
98551 sqlite3AuthContextPush(pParse, &sContext, pTab->zName);
98554 /* If we are trying to update a view, realize that view into
98555 ** a ephemeral table.
98557 #if !defined(SQLITE_OMIT_VIEW) && !defined(SQLITE_OMIT_TRIGGER)
98558 if( isView ){
98559 sqlite3MaterializeView(pParse, pTab, pWhere, iCur);
98561 #endif
98563 /* Resolve the column names in all the expressions in the
98564 ** WHERE clause.
98566 if( sqlite3ResolveExprNames(&sNC, pWhere) ){
98567 goto update_cleanup;
98570 /* Begin the database scan
98572 sqlite3VdbeAddOp2(v, OP_Null, 0, regOldRowid);
98573 pWInfo = sqlite3WhereBegin(
98574 pParse, pTabList, pWhere, 0, 0, WHERE_ONEPASS_DESIRED
98576 if( pWInfo==0 ) goto update_cleanup;
98577 okOnePass = pWInfo->okOnePass;
98579 /* Remember the rowid of every item to be updated.
98581 sqlite3VdbeAddOp2(v, OP_Rowid, iCur, regOldRowid);
98582 if( !okOnePass ){
98583 regRowSet = ++pParse->nMem;
98584 sqlite3VdbeAddOp2(v, OP_RowSetAdd, regRowSet, regOldRowid);
98587 /* End the database scan loop.
98589 sqlite3WhereEnd(pWInfo);
98591 /* Initialize the count of updated rows
98593 if( (db->flags & SQLITE_CountRows) && !pParse->pTriggerTab ){
98594 regRowCount = ++pParse->nMem;
98595 sqlite3VdbeAddOp2(v, OP_Integer, 0, regRowCount);
98598 if( !isView ){
98600 ** Open every index that needs updating. Note that if any
98601 ** index could potentially invoke a REPLACE conflict resolution
98602 ** action, then we need to open all indices because we might need
98603 ** to be deleting some records.
98605 if( !okOnePass ) sqlite3OpenTable(pParse, iCur, iDb, pTab, OP_OpenWrite);
98606 if( onError==OE_Replace ){
98607 openAll = 1;
98608 }else{
98609 openAll = 0;
98610 for(pIdx=pTab->pIndex; pIdx; pIdx=pIdx->pNext){
98611 if( pIdx->onError==OE_Replace ){
98612 openAll = 1;
98613 break;
98617 for(i=0, pIdx=pTab->pIndex; pIdx; pIdx=pIdx->pNext, i++){
98618 if( openAll || aRegIdx[i]>0 ){
98619 KeyInfo *pKey = sqlite3IndexKeyinfo(pParse, pIdx);
98620 sqlite3VdbeAddOp4(v, OP_OpenWrite, iCur+i+1, pIdx->tnum, iDb,
98621 (char*)pKey, P4_KEYINFO_HANDOFF);
98622 assert( pParse->nTab>iCur+i+1 );
98627 /* Top of the update loop */
98628 if( okOnePass ){
98629 int a1 = sqlite3VdbeAddOp1(v, OP_NotNull, regOldRowid);
98630 addr = sqlite3VdbeAddOp0(v, OP_Goto);
98631 sqlite3VdbeJumpHere(v, a1);
98632 }else{
98633 addr = sqlite3VdbeAddOp3(v, OP_RowSetRead, regRowSet, 0, regOldRowid);
98636 /* Make cursor iCur point to the record that is being updated. If
98637 ** this record does not exist for some reason (deleted by a trigger,
98638 ** for example, then jump to the next iteration of the RowSet loop. */
98639 sqlite3VdbeAddOp3(v, OP_NotExists, iCur, addr, regOldRowid);
98641 /* If the record number will change, set register regNewRowid to
98642 ** contain the new value. If the record number is not being modified,
98643 ** then regNewRowid is the same register as regOldRowid, which is
98644 ** already populated. */
98645 assert( chngRowid || pTrigger || hasFK || regOldRowid==regNewRowid );
98646 if( chngRowid ){
98647 sqlite3ExprCode(pParse, pRowidExpr, regNewRowid);
98648 sqlite3VdbeAddOp1(v, OP_MustBeInt, regNewRowid);
98651 /* If there are triggers on this table, populate an array of registers
98652 ** with the required old.* column data. */
98653 if( hasFK || pTrigger ){
98654 u32 oldmask = (hasFK ? sqlite3FkOldmask(pParse, pTab) : 0);
98655 oldmask |= sqlite3TriggerColmask(pParse,
98656 pTrigger, pChanges, 0, TRIGGER_BEFORE|TRIGGER_AFTER, pTab, onError
98658 for(i=0; i<pTab->nCol; i++){
98659 if( aXRef[i]<0 || oldmask==0xffffffff || (i<32 && (oldmask & (1<<i))) ){
98660 sqlite3ExprCodeGetColumnOfTable(v, pTab, iCur, i, regOld+i);
98661 }else{
98662 sqlite3VdbeAddOp2(v, OP_Null, 0, regOld+i);
98665 if( chngRowid==0 ){
98666 sqlite3VdbeAddOp2(v, OP_Copy, regOldRowid, regNewRowid);
98670 /* Populate the array of registers beginning at regNew with the new
98671 ** row data. This array is used to check constaints, create the new
98672 ** table and index records, and as the values for any new.* references
98673 ** made by triggers.
98675 ** If there are one or more BEFORE triggers, then do not populate the
98676 ** registers associated with columns that are (a) not modified by
98677 ** this UPDATE statement and (b) not accessed by new.* references. The
98678 ** values for registers not modified by the UPDATE must be reloaded from
98679 ** the database after the BEFORE triggers are fired anyway (as the trigger
98680 ** may have modified them). So not loading those that are not going to
98681 ** be used eliminates some redundant opcodes.
98683 newmask = sqlite3TriggerColmask(
98684 pParse, pTrigger, pChanges, 1, TRIGGER_BEFORE, pTab, onError
98686 for(i=0; i<pTab->nCol; i++){
98687 if( i==pTab->iPKey ){
98688 sqlite3VdbeAddOp2(v, OP_Null, 0, regNew+i);
98689 }else{
98690 j = aXRef[i];
98691 if( j>=0 ){
98692 sqlite3ExprCode(pParse, pChanges->a[j].pExpr, regNew+i);
98693 }else if( 0==(tmask&TRIGGER_BEFORE) || i>31 || (newmask&(1<<i)) ){
98694 /* This branch loads the value of a column that will not be changed
98695 ** into a register. This is done if there are no BEFORE triggers, or
98696 ** if there are one or more BEFORE triggers that use this value via
98697 ** a new.* reference in a trigger program.
98699 testcase( i==31 );
98700 testcase( i==32 );
98701 sqlite3VdbeAddOp3(v, OP_Column, iCur, i, regNew+i);
98702 sqlite3ColumnDefault(v, pTab, i, regNew+i);
98707 /* Fire any BEFORE UPDATE triggers. This happens before constraints are
98708 ** verified. One could argue that this is wrong.
98710 if( tmask&TRIGGER_BEFORE ){
98711 sqlite3VdbeAddOp2(v, OP_Affinity, regNew, pTab->nCol);
98712 sqlite3TableAffinityStr(v, pTab);
98713 sqlite3CodeRowTrigger(pParse, pTrigger, TK_UPDATE, pChanges,
98714 TRIGGER_BEFORE, pTab, regOldRowid, onError, addr);
98716 /* The row-trigger may have deleted the row being updated. In this
98717 ** case, jump to the next row. No updates or AFTER triggers are
98718 ** required. This behaviour - what happens when the row being updated
98719 ** is deleted or renamed by a BEFORE trigger - is left undefined in the
98720 ** documentation.
98722 sqlite3VdbeAddOp3(v, OP_NotExists, iCur, addr, regOldRowid);
98724 /* If it did not delete it, the row-trigger may still have modified
98725 ** some of the columns of the row being updated. Load the values for
98726 ** all columns not modified by the update statement into their
98727 ** registers in case this has happened.
98729 for(i=0; i<pTab->nCol; i++){
98730 if( aXRef[i]<0 && i!=pTab->iPKey ){
98731 sqlite3VdbeAddOp3(v, OP_Column, iCur, i, regNew+i);
98732 sqlite3ColumnDefault(v, pTab, i, regNew+i);
98737 if( !isView ){
98738 int j1; /* Address of jump instruction */
98740 /* Do constraint checks. */
98741 sqlite3GenerateConstraintChecks(pParse, pTab, iCur, regNewRowid,
98742 aRegIdx, (chngRowid?regOldRowid:0), 1, onError, addr, 0);
98744 /* Do FK constraint checks. */
98745 if( hasFK ){
98746 sqlite3FkCheck(pParse, pTab, regOldRowid, 0);
98749 /* Delete the index entries associated with the current record. */
98750 j1 = sqlite3VdbeAddOp3(v, OP_NotExists, iCur, 0, regOldRowid);
98751 sqlite3GenerateRowIndexDelete(pParse, pTab, iCur, aRegIdx);
98753 /* If changing the record number, delete the old record. */
98754 if( hasFK || chngRowid ){
98755 sqlite3VdbeAddOp2(v, OP_Delete, iCur, 0);
98757 sqlite3VdbeJumpHere(v, j1);
98759 if( hasFK ){
98760 sqlite3FkCheck(pParse, pTab, 0, regNewRowid);
98763 /* Insert the new index entries and the new record. */
98764 sqlite3CompleteInsertion(pParse, pTab, iCur, regNewRowid, aRegIdx, 1, 0, 0);
98766 /* Do any ON CASCADE, SET NULL or SET DEFAULT operations required to
98767 ** handle rows (possibly in other tables) that refer via a foreign key
98768 ** to the row just updated. */
98769 if( hasFK ){
98770 sqlite3FkActions(pParse, pTab, pChanges, regOldRowid);
98774 /* Increment the row counter
98776 if( (db->flags & SQLITE_CountRows) && !pParse->pTriggerTab){
98777 sqlite3VdbeAddOp2(v, OP_AddImm, regRowCount, 1);
98780 sqlite3CodeRowTrigger(pParse, pTrigger, TK_UPDATE, pChanges,
98781 TRIGGER_AFTER, pTab, regOldRowid, onError, addr);
98783 /* Repeat the above with the next record to be updated, until
98784 ** all record selected by the WHERE clause have been updated.
98786 sqlite3VdbeAddOp2(v, OP_Goto, 0, addr);
98787 sqlite3VdbeJumpHere(v, addr);
98789 /* Close all tables */
98790 for(i=0, pIdx=pTab->pIndex; pIdx; pIdx=pIdx->pNext, i++){
98791 if( openAll || aRegIdx[i]>0 ){
98792 sqlite3VdbeAddOp2(v, OP_Close, iCur+i+1, 0);
98795 sqlite3VdbeAddOp2(v, OP_Close, iCur, 0);
98797 /* Update the sqlite_sequence table by storing the content of the
98798 ** maximum rowid counter values recorded while inserting into
98799 ** autoincrement tables.
98801 if( pParse->nested==0 && pParse->pTriggerTab==0 ){
98802 sqlite3AutoincrementEnd(pParse);
98806 ** Return the number of rows that were changed. If this routine is
98807 ** generating code because of a call to sqlite3NestedParse(), do not
98808 ** invoke the callback function.
98810 if( (db->flags&SQLITE_CountRows) && !pParse->pTriggerTab && !pParse->nested ){
98811 sqlite3VdbeAddOp2(v, OP_ResultRow, regRowCount, 1);
98812 sqlite3VdbeSetNumCols(v, 1);
98813 sqlite3VdbeSetColName(v, 0, COLNAME_NAME, "rows updated", SQLITE_STATIC);
98816 update_cleanup:
98817 sqlite3AuthContextPop(&sContext);
98818 sqlite3DbFree(db, aRegIdx);
98819 sqlite3DbFree(db, aXRef);
98820 sqlite3SrcListDelete(db, pTabList);
98821 sqlite3ExprListDelete(db, pChanges);
98822 sqlite3ExprDelete(db, pWhere);
98823 return;
98825 /* Make sure "isView" and other macros defined above are undefined. Otherwise
98826 ** thely may interfere with compilation of other functions in this file
98827 ** (or in another file, if this file becomes part of the amalgamation). */
98828 #ifdef isView
98829 #undef isView
98830 #endif
98831 #ifdef pTrigger
98832 #undef pTrigger
98833 #endif
98835 #ifndef SQLITE_OMIT_VIRTUALTABLE
98837 ** Generate code for an UPDATE of a virtual table.
98839 ** The strategy is that we create an ephemerial table that contains
98840 ** for each row to be changed:
98842 ** (A) The original rowid of that row.
98843 ** (B) The revised rowid for the row. (note1)
98844 ** (C) The content of every column in the row.
98846 ** Then we loop over this ephemeral table and for each row in
98847 ** the ephermeral table call VUpdate.
98849 ** When finished, drop the ephemeral table.
98851 ** (note1) Actually, if we know in advance that (A) is always the same
98852 ** as (B) we only store (A), then duplicate (A) when pulling
98853 ** it out of the ephemeral table before calling VUpdate.
98855 static void updateVirtualTable(
98856 Parse *pParse, /* The parsing context */
98857 SrcList *pSrc, /* The virtual table to be modified */
98858 Table *pTab, /* The virtual table */
98859 ExprList *pChanges, /* The columns to change in the UPDATE statement */
98860 Expr *pRowid, /* Expression used to recompute the rowid */
98861 int *aXRef, /* Mapping from columns of pTab to entries in pChanges */
98862 Expr *pWhere, /* WHERE clause of the UPDATE statement */
98863 int onError /* ON CONFLICT strategy */
98865 Vdbe *v = pParse->pVdbe; /* Virtual machine under construction */
98866 ExprList *pEList = 0; /* The result set of the SELECT statement */
98867 Select *pSelect = 0; /* The SELECT statement */
98868 Expr *pExpr; /* Temporary expression */
98869 int ephemTab; /* Table holding the result of the SELECT */
98870 int i; /* Loop counter */
98871 int addr; /* Address of top of loop */
98872 int iReg; /* First register in set passed to OP_VUpdate */
98873 sqlite3 *db = pParse->db; /* Database connection */
98874 const char *pVTab = (const char*)sqlite3GetVTable(db, pTab);
98875 SelectDest dest;
98877 /* Construct the SELECT statement that will find the new values for
98878 ** all updated rows.
98880 pEList = sqlite3ExprListAppend(pParse, 0, sqlite3Expr(db, TK_ID, "_rowid_"));
98881 if( pRowid ){
98882 pEList = sqlite3ExprListAppend(pParse, pEList,
98883 sqlite3ExprDup(db, pRowid, 0));
98885 assert( pTab->iPKey<0 );
98886 for(i=0; i<pTab->nCol; i++){
98887 if( aXRef[i]>=0 ){
98888 pExpr = sqlite3ExprDup(db, pChanges->a[aXRef[i]].pExpr, 0);
98889 }else{
98890 pExpr = sqlite3Expr(db, TK_ID, pTab->aCol[i].zName);
98892 pEList = sqlite3ExprListAppend(pParse, pEList, pExpr);
98894 pSelect = sqlite3SelectNew(pParse, pEList, pSrc, pWhere, 0, 0, 0, 0, 0, 0);
98896 /* Create the ephemeral table into which the update results will
98897 ** be stored.
98899 assert( v );
98900 ephemTab = pParse->nTab++;
98901 sqlite3VdbeAddOp2(v, OP_OpenEphemeral, ephemTab, pTab->nCol+1+(pRowid!=0));
98902 sqlite3VdbeChangeP5(v, BTREE_UNORDERED);
98904 /* fill the ephemeral table
98906 sqlite3SelectDestInit(&dest, SRT_Table, ephemTab);
98907 sqlite3Select(pParse, pSelect, &dest);
98909 /* Generate code to scan the ephemeral table and call VUpdate. */
98910 iReg = ++pParse->nMem;
98911 pParse->nMem += pTab->nCol+1;
98912 addr = sqlite3VdbeAddOp2(v, OP_Rewind, ephemTab, 0);
98913 sqlite3VdbeAddOp3(v, OP_Column, ephemTab, 0, iReg);
98914 sqlite3VdbeAddOp3(v, OP_Column, ephemTab, (pRowid?1:0), iReg+1);
98915 for(i=0; i<pTab->nCol; i++){
98916 sqlite3VdbeAddOp3(v, OP_Column, ephemTab, i+1+(pRowid!=0), iReg+2+i);
98918 sqlite3VtabMakeWritable(pParse, pTab);
98919 sqlite3VdbeAddOp4(v, OP_VUpdate, 0, pTab->nCol+2, iReg, pVTab, P4_VTAB);
98920 sqlite3VdbeChangeP5(v, onError==OE_Default ? OE_Abort : onError);
98921 sqlite3MayAbort(pParse);
98922 sqlite3VdbeAddOp2(v, OP_Next, ephemTab, addr+1);
98923 sqlite3VdbeJumpHere(v, addr);
98924 sqlite3VdbeAddOp2(v, OP_Close, ephemTab, 0);
98926 /* Cleanup */
98927 sqlite3SelectDelete(db, pSelect);
98929 #endif /* SQLITE_OMIT_VIRTUALTABLE */
98931 /************** End of update.c **********************************************/
98932 /************** Begin file vacuum.c ******************************************/
98934 ** 2003 April 6
98936 ** The author disclaims copyright to this source code. In place of
98937 ** a legal notice, here is a blessing:
98939 ** May you do good and not evil.
98940 ** May you find forgiveness for yourself and forgive others.
98941 ** May you share freely, never taking more than you give.
98943 *************************************************************************
98944 ** This file contains code used to implement the VACUUM command.
98946 ** Most of the code in this file may be omitted by defining the
98947 ** SQLITE_OMIT_VACUUM macro.
98950 #if !defined(SQLITE_OMIT_VACUUM) && !defined(SQLITE_OMIT_ATTACH)
98952 ** Finalize a prepared statement. If there was an error, store the
98953 ** text of the error message in *pzErrMsg. Return the result code.
98955 static int vacuumFinalize(sqlite3 *db, sqlite3_stmt *pStmt, char **pzErrMsg){
98956 int rc;
98957 rc = sqlite3VdbeFinalize((Vdbe*)pStmt);
98958 if( rc ){
98959 sqlite3SetString(pzErrMsg, db, sqlite3_errmsg(db));
98961 return rc;
98965 ** Execute zSql on database db. Return an error code.
98967 static int execSql(sqlite3 *db, char **pzErrMsg, const char *zSql){
98968 sqlite3_stmt *pStmt;
98969 VVA_ONLY( int rc; )
98970 if( !zSql ){
98971 return SQLITE_NOMEM;
98973 if( SQLITE_OK!=sqlite3_prepare(db, zSql, -1, &pStmt, 0) ){
98974 sqlite3SetString(pzErrMsg, db, sqlite3_errmsg(db));
98975 return sqlite3_errcode(db);
98977 VVA_ONLY( rc = ) sqlite3_step(pStmt);
98978 assert( rc!=SQLITE_ROW );
98979 return vacuumFinalize(db, pStmt, pzErrMsg);
98983 ** Execute zSql on database db. The statement returns exactly
98984 ** one column. Execute this as SQL on the same database.
98986 static int execExecSql(sqlite3 *db, char **pzErrMsg, const char *zSql){
98987 sqlite3_stmt *pStmt;
98988 int rc;
98990 rc = sqlite3_prepare(db, zSql, -1, &pStmt, 0);
98991 if( rc!=SQLITE_OK ) return rc;
98993 while( SQLITE_ROW==sqlite3_step(pStmt) ){
98994 rc = execSql(db, pzErrMsg, (char*)sqlite3_column_text(pStmt, 0));
98995 if( rc!=SQLITE_OK ){
98996 vacuumFinalize(db, pStmt, pzErrMsg);
98997 return rc;
99001 return vacuumFinalize(db, pStmt, pzErrMsg);
99005 ** The non-standard VACUUM command is used to clean up the database,
99006 ** collapse free space, etc. It is modelled after the VACUUM command
99007 ** in PostgreSQL.
99009 ** In version 1.0.x of SQLite, the VACUUM command would call
99010 ** gdbm_reorganize() on all the database tables. But beginning
99011 ** with 2.0.0, SQLite no longer uses GDBM so this command has
99012 ** become a no-op.
99014 SQLITE_PRIVATE void sqlite3Vacuum(Parse *pParse){
99015 Vdbe *v = sqlite3GetVdbe(pParse);
99016 if( v ){
99017 sqlite3VdbeAddOp2(v, OP_Vacuum, 0, 0);
99019 return;
99023 ** This routine implements the OP_Vacuum opcode of the VDBE.
99025 SQLITE_PRIVATE int sqlite3RunVacuum(char **pzErrMsg, sqlite3 *db){
99026 int rc = SQLITE_OK; /* Return code from service routines */
99027 Btree *pMain; /* The database being vacuumed */
99028 Btree *pTemp; /* The temporary database we vacuum into */
99029 char *zSql = 0; /* SQL statements */
99030 int saved_flags; /* Saved value of the db->flags */
99031 int saved_nChange; /* Saved value of db->nChange */
99032 int saved_nTotalChange; /* Saved value of db->nTotalChange */
99033 void (*saved_xTrace)(void*,const char*); /* Saved db->xTrace */
99034 Db *pDb = 0; /* Database to detach at end of vacuum */
99035 int isMemDb; /* True if vacuuming a :memory: database */
99036 int nRes; /* Bytes of reserved space at the end of each page */
99037 int nDb; /* Number of attached databases */
99039 if( !db->autoCommit ){
99040 sqlite3SetString(pzErrMsg, db, "cannot VACUUM from within a transaction");
99041 return SQLITE_ERROR;
99043 if( db->activeVdbeCnt>1 ){
99044 sqlite3SetString(pzErrMsg, db,"cannot VACUUM - SQL statements in progress");
99045 return SQLITE_ERROR;
99048 /* Save the current value of the database flags so that it can be
99049 ** restored before returning. Then set the writable-schema flag, and
99050 ** disable CHECK and foreign key constraints. */
99051 saved_flags = db->flags;
99052 saved_nChange = db->nChange;
99053 saved_nTotalChange = db->nTotalChange;
99054 saved_xTrace = db->xTrace;
99055 db->flags |= SQLITE_WriteSchema | SQLITE_IgnoreChecks | SQLITE_PreferBuiltin;
99056 db->flags &= ~(SQLITE_ForeignKeys | SQLITE_ReverseOrder);
99057 db->xTrace = 0;
99059 pMain = db->aDb[0].pBt;
99060 isMemDb = sqlite3PagerIsMemdb(sqlite3BtreePager(pMain));
99062 /* Attach the temporary database as 'vacuum_db'. The synchronous pragma
99063 ** can be set to 'off' for this file, as it is not recovered if a crash
99064 ** occurs anyway. The integrity of the database is maintained by a
99065 ** (possibly synchronous) transaction opened on the main database before
99066 ** sqlite3BtreeCopyFile() is called.
99068 ** An optimisation would be to use a non-journaled pager.
99069 ** (Later:) I tried setting "PRAGMA vacuum_db.journal_mode=OFF" but
99070 ** that actually made the VACUUM run slower. Very little journalling
99071 ** actually occurs when doing a vacuum since the vacuum_db is initially
99072 ** empty. Only the journal header is written. Apparently it takes more
99073 ** time to parse and run the PRAGMA to turn journalling off than it does
99074 ** to write the journal header file.
99076 nDb = db->nDb;
99077 if( sqlite3TempInMemory(db) ){
99078 zSql = "ATTACH ':memory:' AS vacuum_db;";
99079 }else{
99080 zSql = "ATTACH '' AS vacuum_db;";
99082 rc = execSql(db, pzErrMsg, zSql);
99083 if( db->nDb>nDb ){
99084 pDb = &db->aDb[db->nDb-1];
99085 assert( strcmp(pDb->zName,"vacuum_db")==0 );
99087 if( rc!=SQLITE_OK ) goto end_of_vacuum;
99088 pTemp = db->aDb[db->nDb-1].pBt;
99090 /* The call to execSql() to attach the temp database has left the file
99091 ** locked (as there was more than one active statement when the transaction
99092 ** to read the schema was concluded. Unlock it here so that this doesn't
99093 ** cause problems for the call to BtreeSetPageSize() below. */
99094 sqlite3BtreeCommit(pTemp);
99096 nRes = sqlite3BtreeGetReserve(pMain);
99098 /* A VACUUM cannot change the pagesize of an encrypted database. */
99099 #ifdef SQLITE_HAS_CODEC
99100 if( db->nextPagesize ){
99101 extern void sqlite3CodecGetKey(sqlite3*, int, void**, int*);
99102 int nKey;
99103 char *zKey;
99104 sqlite3CodecGetKey(db, 0, (void**)&zKey, &nKey);
99105 if( nKey ) db->nextPagesize = 0;
99107 #endif
99109 /* Do not attempt to change the page size for a WAL database */
99110 if( sqlite3PagerGetJournalMode(sqlite3BtreePager(pMain))
99111 ==PAGER_JOURNALMODE_WAL ){
99112 db->nextPagesize = 0;
99115 if( sqlite3BtreeSetPageSize(pTemp, sqlite3BtreeGetPageSize(pMain), nRes, 0)
99116 || (!isMemDb && sqlite3BtreeSetPageSize(pTemp, db->nextPagesize, nRes, 0))
99117 || NEVER(db->mallocFailed)
99119 rc = SQLITE_NOMEM;
99120 goto end_of_vacuum;
99122 rc = execSql(db, pzErrMsg, "PRAGMA vacuum_db.synchronous=OFF");
99123 if( rc!=SQLITE_OK ){
99124 goto end_of_vacuum;
99127 #ifndef SQLITE_OMIT_AUTOVACUUM
99128 sqlite3BtreeSetAutoVacuum(pTemp, db->nextAutovac>=0 ? db->nextAutovac :
99129 sqlite3BtreeGetAutoVacuum(pMain));
99130 #endif
99132 /* Begin a transaction */
99133 rc = execSql(db, pzErrMsg, "BEGIN EXCLUSIVE;");
99134 if( rc!=SQLITE_OK ) goto end_of_vacuum;
99136 /* Query the schema of the main database. Create a mirror schema
99137 ** in the temporary database.
99139 rc = execExecSql(db, pzErrMsg,
99140 "SELECT 'CREATE TABLE vacuum_db.' || substr(sql,14) "
99141 " FROM sqlite_master WHERE type='table' AND name!='sqlite_sequence'"
99142 " AND rootpage>0"
99144 if( rc!=SQLITE_OK ) goto end_of_vacuum;
99145 rc = execExecSql(db, pzErrMsg,
99146 "SELECT 'CREATE INDEX vacuum_db.' || substr(sql,14)"
99147 " FROM sqlite_master WHERE sql LIKE 'CREATE INDEX %' ");
99148 if( rc!=SQLITE_OK ) goto end_of_vacuum;
99149 rc = execExecSql(db, pzErrMsg,
99150 "SELECT 'CREATE UNIQUE INDEX vacuum_db.' || substr(sql,21) "
99151 " FROM sqlite_master WHERE sql LIKE 'CREATE UNIQUE INDEX %'");
99152 if( rc!=SQLITE_OK ) goto end_of_vacuum;
99154 /* Loop through the tables in the main database. For each, do
99155 ** an "INSERT INTO vacuum_db.xxx SELECT * FROM main.xxx;" to copy
99156 ** the contents to the temporary database.
99158 rc = execExecSql(db, pzErrMsg,
99159 "SELECT 'INSERT INTO vacuum_db.' || quote(name) "
99160 "|| ' SELECT * FROM main.' || quote(name) || ';'"
99161 "FROM main.sqlite_master "
99162 "WHERE type = 'table' AND name!='sqlite_sequence' "
99163 " AND rootpage>0"
99165 if( rc!=SQLITE_OK ) goto end_of_vacuum;
99167 /* Copy over the sequence table
99169 rc = execExecSql(db, pzErrMsg,
99170 "SELECT 'DELETE FROM vacuum_db.' || quote(name) || ';' "
99171 "FROM vacuum_db.sqlite_master WHERE name='sqlite_sequence' "
99173 if( rc!=SQLITE_OK ) goto end_of_vacuum;
99174 rc = execExecSql(db, pzErrMsg,
99175 "SELECT 'INSERT INTO vacuum_db.' || quote(name) "
99176 "|| ' SELECT * FROM main.' || quote(name) || ';' "
99177 "FROM vacuum_db.sqlite_master WHERE name=='sqlite_sequence';"
99179 if( rc!=SQLITE_OK ) goto end_of_vacuum;
99182 /* Copy the triggers, views, and virtual tables from the main database
99183 ** over to the temporary database. None of these objects has any
99184 ** associated storage, so all we have to do is copy their entries
99185 ** from the SQLITE_MASTER table.
99187 rc = execSql(db, pzErrMsg,
99188 "INSERT INTO vacuum_db.sqlite_master "
99189 " SELECT type, name, tbl_name, rootpage, sql"
99190 " FROM main.sqlite_master"
99191 " WHERE type='view' OR type='trigger'"
99192 " OR (type='table' AND rootpage=0)"
99194 if( rc ) goto end_of_vacuum;
99196 /* At this point, unless the main db was completely empty, there is now a
99197 ** transaction open on the vacuum database, but not on the main database.
99198 ** Open a btree level transaction on the main database. This allows a
99199 ** call to sqlite3BtreeCopyFile(). The main database btree level
99200 ** transaction is then committed, so the SQL level never knows it was
99201 ** opened for writing. This way, the SQL transaction used to create the
99202 ** temporary database never needs to be committed.
99205 u32 meta;
99206 int i;
99208 /* This array determines which meta meta values are preserved in the
99209 ** vacuum. Even entries are the meta value number and odd entries
99210 ** are an increment to apply to the meta value after the vacuum.
99211 ** The increment is used to increase the schema cookie so that other
99212 ** connections to the same database will know to reread the schema.
99214 static const unsigned char aCopy[] = {
99215 BTREE_SCHEMA_VERSION, 1, /* Add one to the old schema cookie */
99216 BTREE_DEFAULT_CACHE_SIZE, 0, /* Preserve the default page cache size */
99217 BTREE_TEXT_ENCODING, 0, /* Preserve the text encoding */
99218 BTREE_USER_VERSION, 0, /* Preserve the user version */
99221 assert( 1==sqlite3BtreeIsInTrans(pTemp) );
99222 assert( 1==sqlite3BtreeIsInTrans(pMain) );
99224 /* Copy Btree meta values */
99225 for(i=0; i<ArraySize(aCopy); i+=2){
99226 /* GetMeta() and UpdateMeta() cannot fail in this context because
99227 ** we already have page 1 loaded into cache and marked dirty. */
99228 sqlite3BtreeGetMeta(pMain, aCopy[i], &meta);
99229 rc = sqlite3BtreeUpdateMeta(pTemp, aCopy[i], meta+aCopy[i+1]);
99230 if( NEVER(rc!=SQLITE_OK) ) goto end_of_vacuum;
99233 rc = sqlite3BtreeCopyFile(pMain, pTemp);
99234 if( rc!=SQLITE_OK ) goto end_of_vacuum;
99235 rc = sqlite3BtreeCommit(pTemp);
99236 if( rc!=SQLITE_OK ) goto end_of_vacuum;
99237 #ifndef SQLITE_OMIT_AUTOVACUUM
99238 sqlite3BtreeSetAutoVacuum(pMain, sqlite3BtreeGetAutoVacuum(pTemp));
99239 #endif
99242 assert( rc==SQLITE_OK );
99243 rc = sqlite3BtreeSetPageSize(pMain, sqlite3BtreeGetPageSize(pTemp), nRes,1);
99245 end_of_vacuum:
99246 /* Restore the original value of db->flags */
99247 db->flags = saved_flags;
99248 db->nChange = saved_nChange;
99249 db->nTotalChange = saved_nTotalChange;
99250 db->xTrace = saved_xTrace;
99251 sqlite3BtreeSetPageSize(pMain, -1, -1, 1);
99253 /* Currently there is an SQL level transaction open on the vacuum
99254 ** database. No locks are held on any other files (since the main file
99255 ** was committed at the btree level). So it safe to end the transaction
99256 ** by manually setting the autoCommit flag to true and detaching the
99257 ** vacuum database. The vacuum_db journal file is deleted when the pager
99258 ** is closed by the DETACH.
99260 db->autoCommit = 1;
99262 if( pDb ){
99263 sqlite3BtreeClose(pDb->pBt);
99264 pDb->pBt = 0;
99265 pDb->pSchema = 0;
99268 /* This both clears the schemas and reduces the size of the db->aDb[]
99269 ** array. */
99270 sqlite3ResetInternalSchema(db, -1);
99272 return rc;
99275 #endif /* SQLITE_OMIT_VACUUM && SQLITE_OMIT_ATTACH */
99277 /************** End of vacuum.c **********************************************/
99278 /************** Begin file vtab.c ********************************************/
99280 ** 2006 June 10
99282 ** The author disclaims copyright to this source code. In place of
99283 ** a legal notice, here is a blessing:
99285 ** May you do good and not evil.
99286 ** May you find forgiveness for yourself and forgive others.
99287 ** May you share freely, never taking more than you give.
99289 *************************************************************************
99290 ** This file contains code used to help implement virtual tables.
99292 #ifndef SQLITE_OMIT_VIRTUALTABLE
99295 ** Before a virtual table xCreate() or xConnect() method is invoked, the
99296 ** sqlite3.pVtabCtx member variable is set to point to an instance of
99297 ** this struct allocated on the stack. It is used by the implementation of
99298 ** the sqlite3_declare_vtab() and sqlite3_vtab_config() APIs, both of which
99299 ** are invoked only from within xCreate and xConnect methods.
99301 struct VtabCtx {
99302 Table *pTab;
99303 VTable *pVTable;
99307 ** The actual function that does the work of creating a new module.
99308 ** This function implements the sqlite3_create_module() and
99309 ** sqlite3_create_module_v2() interfaces.
99311 static int createModule(
99312 sqlite3 *db, /* Database in which module is registered */
99313 const char *zName, /* Name assigned to this module */
99314 const sqlite3_module *pModule, /* The definition of the module */
99315 void *pAux, /* Context pointer for xCreate/xConnect */
99316 void (*xDestroy)(void *) /* Module destructor function */
99318 int rc, nName;
99319 Module *pMod;
99321 sqlite3_mutex_enter(db->mutex);
99322 nName = sqlite3Strlen30(zName);
99323 pMod = (Module *)sqlite3DbMallocRaw(db, sizeof(Module) + nName + 1);
99324 if( pMod ){
99325 Module *pDel;
99326 char *zCopy = (char *)(&pMod[1]);
99327 memcpy(zCopy, zName, nName+1);
99328 pMod->zName = zCopy;
99329 pMod->pModule = pModule;
99330 pMod->pAux = pAux;
99331 pMod->xDestroy = xDestroy;
99332 pDel = (Module *)sqlite3HashInsert(&db->aModule, zCopy, nName, (void*)pMod);
99333 if( pDel && pDel->xDestroy ){
99334 sqlite3ResetInternalSchema(db, -1);
99335 pDel->xDestroy(pDel->pAux);
99337 sqlite3DbFree(db, pDel);
99338 if( pDel==pMod ){
99339 db->mallocFailed = 1;
99341 }else if( xDestroy ){
99342 xDestroy(pAux);
99344 rc = sqlite3ApiExit(db, SQLITE_OK);
99345 sqlite3_mutex_leave(db->mutex);
99346 return rc;
99351 ** External API function used to create a new virtual-table module.
99353 SQLITE_API int sqlite3_create_module(
99354 sqlite3 *db, /* Database in which module is registered */
99355 const char *zName, /* Name assigned to this module */
99356 const sqlite3_module *pModule, /* The definition of the module */
99357 void *pAux /* Context pointer for xCreate/xConnect */
99359 return createModule(db, zName, pModule, pAux, 0);
99363 ** External API function used to create a new virtual-table module.
99365 SQLITE_API int sqlite3_create_module_v2(
99366 sqlite3 *db, /* Database in which module is registered */
99367 const char *zName, /* Name assigned to this module */
99368 const sqlite3_module *pModule, /* The definition of the module */
99369 void *pAux, /* Context pointer for xCreate/xConnect */
99370 void (*xDestroy)(void *) /* Module destructor function */
99372 return createModule(db, zName, pModule, pAux, xDestroy);
99376 ** Lock the virtual table so that it cannot be disconnected.
99377 ** Locks nest. Every lock should have a corresponding unlock.
99378 ** If an unlock is omitted, resources leaks will occur.
99380 ** If a disconnect is attempted while a virtual table is locked,
99381 ** the disconnect is deferred until all locks have been removed.
99383 SQLITE_PRIVATE void sqlite3VtabLock(VTable *pVTab){
99384 pVTab->nRef++;
99389 ** pTab is a pointer to a Table structure representing a virtual-table.
99390 ** Return a pointer to the VTable object used by connection db to access
99391 ** this virtual-table, if one has been created, or NULL otherwise.
99393 SQLITE_PRIVATE VTable *sqlite3GetVTable(sqlite3 *db, Table *pTab){
99394 VTable *pVtab;
99395 assert( IsVirtual(pTab) );
99396 for(pVtab=pTab->pVTable; pVtab && pVtab->db!=db; pVtab=pVtab->pNext);
99397 return pVtab;
99401 ** Decrement the ref-count on a virtual table object. When the ref-count
99402 ** reaches zero, call the xDisconnect() method to delete the object.
99404 SQLITE_PRIVATE void sqlite3VtabUnlock(VTable *pVTab){
99405 sqlite3 *db = pVTab->db;
99407 assert( db );
99408 assert( pVTab->nRef>0 );
99409 assert( sqlite3SafetyCheckOk(db) );
99411 pVTab->nRef--;
99412 if( pVTab->nRef==0 ){
99413 sqlite3_vtab *p = pVTab->pVtab;
99414 if( p ){
99415 p->pModule->xDisconnect(p);
99417 sqlite3DbFree(db, pVTab);
99422 ** Table p is a virtual table. This function moves all elements in the
99423 ** p->pVTable list to the sqlite3.pDisconnect lists of their associated
99424 ** database connections to be disconnected at the next opportunity.
99425 ** Except, if argument db is not NULL, then the entry associated with
99426 ** connection db is left in the p->pVTable list.
99428 static VTable *vtabDisconnectAll(sqlite3 *db, Table *p){
99429 VTable *pRet = 0;
99430 VTable *pVTable = p->pVTable;
99431 p->pVTable = 0;
99433 /* Assert that the mutex (if any) associated with the BtShared database
99434 ** that contains table p is held by the caller. See header comments
99435 ** above function sqlite3VtabUnlockList() for an explanation of why
99436 ** this makes it safe to access the sqlite3.pDisconnect list of any
99437 ** database connection that may have an entry in the p->pVTable list.
99439 assert( db==0 || sqlite3SchemaMutexHeld(db, 0, p->pSchema) );
99441 while( pVTable ){
99442 sqlite3 *db2 = pVTable->db;
99443 VTable *pNext = pVTable->pNext;
99444 assert( db2 );
99445 if( db2==db ){
99446 pRet = pVTable;
99447 p->pVTable = pRet;
99448 pRet->pNext = 0;
99449 }else{
99450 pVTable->pNext = db2->pDisconnect;
99451 db2->pDisconnect = pVTable;
99453 pVTable = pNext;
99456 assert( !db || pRet );
99457 return pRet;
99462 ** Disconnect all the virtual table objects in the sqlite3.pDisconnect list.
99464 ** This function may only be called when the mutexes associated with all
99465 ** shared b-tree databases opened using connection db are held by the
99466 ** caller. This is done to protect the sqlite3.pDisconnect list. The
99467 ** sqlite3.pDisconnect list is accessed only as follows:
99469 ** 1) By this function. In this case, all BtShared mutexes and the mutex
99470 ** associated with the database handle itself must be held.
99472 ** 2) By function vtabDisconnectAll(), when it adds a VTable entry to
99473 ** the sqlite3.pDisconnect list. In this case either the BtShared mutex
99474 ** associated with the database the virtual table is stored in is held
99475 ** or, if the virtual table is stored in a non-sharable database, then
99476 ** the database handle mutex is held.
99478 ** As a result, a sqlite3.pDisconnect cannot be accessed simultaneously
99479 ** by multiple threads. It is thread-safe.
99481 SQLITE_PRIVATE void sqlite3VtabUnlockList(sqlite3 *db){
99482 VTable *p = db->pDisconnect;
99483 db->pDisconnect = 0;
99485 assert( sqlite3BtreeHoldsAllMutexes(db) );
99486 assert( sqlite3_mutex_held(db->mutex) );
99488 if( p ){
99489 sqlite3ExpirePreparedStatements(db);
99490 do {
99491 VTable *pNext = p->pNext;
99492 sqlite3VtabUnlock(p);
99493 p = pNext;
99494 }while( p );
99499 ** Clear any and all virtual-table information from the Table record.
99500 ** This routine is called, for example, just before deleting the Table
99501 ** record.
99503 ** Since it is a virtual-table, the Table structure contains a pointer
99504 ** to the head of a linked list of VTable structures. Each VTable
99505 ** structure is associated with a single sqlite3* user of the schema.
99506 ** The reference count of the VTable structure associated with database
99507 ** connection db is decremented immediately (which may lead to the
99508 ** structure being xDisconnected and free). Any other VTable structures
99509 ** in the list are moved to the sqlite3.pDisconnect list of the associated
99510 ** database connection.
99512 SQLITE_PRIVATE void sqlite3VtabClear(sqlite3 *db, Table *p){
99513 if( !db || db->pnBytesFreed==0 ) vtabDisconnectAll(0, p);
99514 if( p->azModuleArg ){
99515 int i;
99516 for(i=0; i<p->nModuleArg; i++){
99517 sqlite3DbFree(db, p->azModuleArg[i]);
99519 sqlite3DbFree(db, p->azModuleArg);
99524 ** Add a new module argument to pTable->azModuleArg[].
99525 ** The string is not copied - the pointer is stored. The
99526 ** string will be freed automatically when the table is
99527 ** deleted.
99529 static void addModuleArgument(sqlite3 *db, Table *pTable, char *zArg){
99530 int i = pTable->nModuleArg++;
99531 int nBytes = sizeof(char *)*(1+pTable->nModuleArg);
99532 char **azModuleArg;
99533 azModuleArg = sqlite3DbRealloc(db, pTable->azModuleArg, nBytes);
99534 if( azModuleArg==0 ){
99535 int j;
99536 for(j=0; j<i; j++){
99537 sqlite3DbFree(db, pTable->azModuleArg[j]);
99539 sqlite3DbFree(db, zArg);
99540 sqlite3DbFree(db, pTable->azModuleArg);
99541 pTable->nModuleArg = 0;
99542 }else{
99543 azModuleArg[i] = zArg;
99544 azModuleArg[i+1] = 0;
99546 pTable->azModuleArg = azModuleArg;
99550 ** The parser calls this routine when it first sees a CREATE VIRTUAL TABLE
99551 ** statement. The module name has been parsed, but the optional list
99552 ** of parameters that follow the module name are still pending.
99554 SQLITE_PRIVATE void sqlite3VtabBeginParse(
99555 Parse *pParse, /* Parsing context */
99556 Token *pName1, /* Name of new table, or database name */
99557 Token *pName2, /* Name of new table or NULL */
99558 Token *pModuleName /* Name of the module for the virtual table */
99560 int iDb; /* The database the table is being created in */
99561 Table *pTable; /* The new virtual table */
99562 sqlite3 *db; /* Database connection */
99564 sqlite3StartTable(pParse, pName1, pName2, 0, 0, 1, 0);
99565 pTable = pParse->pNewTable;
99566 if( pTable==0 ) return;
99567 assert( 0==pTable->pIndex );
99569 db = pParse->db;
99570 iDb = sqlite3SchemaToIndex(db, pTable->pSchema);
99571 assert( iDb>=0 );
99573 pTable->tabFlags |= TF_Virtual;
99574 pTable->nModuleArg = 0;
99575 addModuleArgument(db, pTable, sqlite3NameFromToken(db, pModuleName));
99576 addModuleArgument(db, pTable, sqlite3DbStrDup(db, db->aDb[iDb].zName));
99577 addModuleArgument(db, pTable, sqlite3DbStrDup(db, pTable->zName));
99578 pParse->sNameToken.n = (int)(&pModuleName->z[pModuleName->n] - pName1->z);
99580 #ifndef SQLITE_OMIT_AUTHORIZATION
99581 /* Creating a virtual table invokes the authorization callback twice.
99582 ** The first invocation, to obtain permission to INSERT a row into the
99583 ** sqlite_master table, has already been made by sqlite3StartTable().
99584 ** The second call, to obtain permission to create the table, is made now.
99586 if( pTable->azModuleArg ){
99587 sqlite3AuthCheck(pParse, SQLITE_CREATE_VTABLE, pTable->zName,
99588 pTable->azModuleArg[0], pParse->db->aDb[iDb].zName);
99590 #endif
99594 ** This routine takes the module argument that has been accumulating
99595 ** in pParse->zArg[] and appends it to the list of arguments on the
99596 ** virtual table currently under construction in pParse->pTable.
99598 static void addArgumentToVtab(Parse *pParse){
99599 if( pParse->sArg.z && ALWAYS(pParse->pNewTable) ){
99600 const char *z = (const char*)pParse->sArg.z;
99601 int n = pParse->sArg.n;
99602 sqlite3 *db = pParse->db;
99603 addModuleArgument(db, pParse->pNewTable, sqlite3DbStrNDup(db, z, n));
99608 ** The parser calls this routine after the CREATE VIRTUAL TABLE statement
99609 ** has been completely parsed.
99611 SQLITE_PRIVATE void sqlite3VtabFinishParse(Parse *pParse, Token *pEnd){
99612 Table *pTab = pParse->pNewTable; /* The table being constructed */
99613 sqlite3 *db = pParse->db; /* The database connection */
99615 if( pTab==0 ) return;
99616 addArgumentToVtab(pParse);
99617 pParse->sArg.z = 0;
99618 if( pTab->nModuleArg<1 ) return;
99620 /* If the CREATE VIRTUAL TABLE statement is being entered for the
99621 ** first time (in other words if the virtual table is actually being
99622 ** created now instead of just being read out of sqlite_master) then
99623 ** do additional initialization work and store the statement text
99624 ** in the sqlite_master table.
99626 if( !db->init.busy ){
99627 char *zStmt;
99628 char *zWhere;
99629 int iDb;
99630 Vdbe *v;
99632 /* Compute the complete text of the CREATE VIRTUAL TABLE statement */
99633 if( pEnd ){
99634 pParse->sNameToken.n = (int)(pEnd->z - pParse->sNameToken.z) + pEnd->n;
99636 zStmt = sqlite3MPrintf(db, "CREATE VIRTUAL TABLE %T", &pParse->sNameToken);
99638 /* A slot for the record has already been allocated in the
99639 ** SQLITE_MASTER table. We just need to update that slot with all
99640 ** the information we've collected.
99642 ** The VM register number pParse->regRowid holds the rowid of an
99643 ** entry in the sqlite_master table tht was created for this vtab
99644 ** by sqlite3StartTable().
99646 iDb = sqlite3SchemaToIndex(db, pTab->pSchema);
99647 sqlite3NestedParse(pParse,
99648 "UPDATE %Q.%s "
99649 "SET type='table', name=%Q, tbl_name=%Q, rootpage=0, sql=%Q "
99650 "WHERE rowid=#%d",
99651 db->aDb[iDb].zName, SCHEMA_TABLE(iDb),
99652 pTab->zName,
99653 pTab->zName,
99654 zStmt,
99655 pParse->regRowid
99657 sqlite3DbFree(db, zStmt);
99658 v = sqlite3GetVdbe(pParse);
99659 sqlite3ChangeCookie(pParse, iDb);
99661 sqlite3VdbeAddOp2(v, OP_Expire, 0, 0);
99662 zWhere = sqlite3MPrintf(db, "name='%q' AND type='table'", pTab->zName);
99663 sqlite3VdbeAddParseSchemaOp(v, iDb, zWhere);
99664 sqlite3VdbeAddOp4(v, OP_VCreate, iDb, 0, 0,
99665 pTab->zName, sqlite3Strlen30(pTab->zName) + 1);
99668 /* If we are rereading the sqlite_master table create the in-memory
99669 ** record of the table. The xConnect() method is not called until
99670 ** the first time the virtual table is used in an SQL statement. This
99671 ** allows a schema that contains virtual tables to be loaded before
99672 ** the required virtual table implementations are registered. */
99673 else {
99674 Table *pOld;
99675 Schema *pSchema = pTab->pSchema;
99676 const char *zName = pTab->zName;
99677 int nName = sqlite3Strlen30(zName);
99678 assert( sqlite3SchemaMutexHeld(db, 0, pSchema) );
99679 pOld = sqlite3HashInsert(&pSchema->tblHash, zName, nName, pTab);
99680 if( pOld ){
99681 db->mallocFailed = 1;
99682 assert( pTab==pOld ); /* Malloc must have failed inside HashInsert() */
99683 return;
99685 pParse->pNewTable = 0;
99690 ** The parser calls this routine when it sees the first token
99691 ** of an argument to the module name in a CREATE VIRTUAL TABLE statement.
99693 SQLITE_PRIVATE void sqlite3VtabArgInit(Parse *pParse){
99694 addArgumentToVtab(pParse);
99695 pParse->sArg.z = 0;
99696 pParse->sArg.n = 0;
99700 ** The parser calls this routine for each token after the first token
99701 ** in an argument to the module name in a CREATE VIRTUAL TABLE statement.
99703 SQLITE_PRIVATE void sqlite3VtabArgExtend(Parse *pParse, Token *p){
99704 Token *pArg = &pParse->sArg;
99705 if( pArg->z==0 ){
99706 pArg->z = p->z;
99707 pArg->n = p->n;
99708 }else{
99709 assert(pArg->z < p->z);
99710 pArg->n = (int)(&p->z[p->n] - pArg->z);
99715 ** Invoke a virtual table constructor (either xCreate or xConnect). The
99716 ** pointer to the function to invoke is passed as the fourth parameter
99717 ** to this procedure.
99719 static int vtabCallConstructor(
99720 sqlite3 *db,
99721 Table *pTab,
99722 Module *pMod,
99723 int (*xConstruct)(sqlite3*,void*,int,const char*const*,sqlite3_vtab**,char**),
99724 char **pzErr
99726 VtabCtx sCtx;
99727 VTable *pVTable;
99728 int rc;
99729 const char *const*azArg = (const char *const*)pTab->azModuleArg;
99730 int nArg = pTab->nModuleArg;
99731 char *zErr = 0;
99732 char *zModuleName = sqlite3MPrintf(db, "%s", pTab->zName);
99734 if( !zModuleName ){
99735 return SQLITE_NOMEM;
99738 pVTable = sqlite3DbMallocZero(db, sizeof(VTable));
99739 if( !pVTable ){
99740 sqlite3DbFree(db, zModuleName);
99741 return SQLITE_NOMEM;
99743 pVTable->db = db;
99744 pVTable->pMod = pMod;
99746 /* Invoke the virtual table constructor */
99747 assert( &db->pVtabCtx );
99748 assert( xConstruct );
99749 sCtx.pTab = pTab;
99750 sCtx.pVTable = pVTable;
99751 db->pVtabCtx = &sCtx;
99752 rc = xConstruct(db, pMod->pAux, nArg, azArg, &pVTable->pVtab, &zErr);
99753 db->pVtabCtx = 0;
99754 if( rc==SQLITE_NOMEM ) db->mallocFailed = 1;
99756 if( SQLITE_OK!=rc ){
99757 if( zErr==0 ){
99758 *pzErr = sqlite3MPrintf(db, "vtable constructor failed: %s", zModuleName);
99759 }else {
99760 *pzErr = sqlite3MPrintf(db, "%s", zErr);
99761 sqlite3_free(zErr);
99763 sqlite3DbFree(db, pVTable);
99764 }else if( ALWAYS(pVTable->pVtab) ){
99765 /* Justification of ALWAYS(): A correct vtab constructor must allocate
99766 ** the sqlite3_vtab object if successful. */
99767 pVTable->pVtab->pModule = pMod->pModule;
99768 pVTable->nRef = 1;
99769 if( sCtx.pTab ){
99770 const char *zFormat = "vtable constructor did not declare schema: %s";
99771 *pzErr = sqlite3MPrintf(db, zFormat, pTab->zName);
99772 sqlite3VtabUnlock(pVTable);
99773 rc = SQLITE_ERROR;
99774 }else{
99775 int iCol;
99776 /* If everything went according to plan, link the new VTable structure
99777 ** into the linked list headed by pTab->pVTable. Then loop through the
99778 ** columns of the table to see if any of them contain the token "hidden".
99779 ** If so, set the Column.isHidden flag and remove the token from
99780 ** the type string. */
99781 pVTable->pNext = pTab->pVTable;
99782 pTab->pVTable = pVTable;
99784 for(iCol=0; iCol<pTab->nCol; iCol++){
99785 char *zType = pTab->aCol[iCol].zType;
99786 int nType;
99787 int i = 0;
99788 if( !zType ) continue;
99789 nType = sqlite3Strlen30(zType);
99790 if( sqlite3StrNICmp("hidden", zType, 6)||(zType[6] && zType[6]!=' ') ){
99791 for(i=0; i<nType; i++){
99792 if( (0==sqlite3StrNICmp(" hidden", &zType[i], 7))
99793 && (zType[i+7]=='\0' || zType[i+7]==' ')
99795 i++;
99796 break;
99800 if( i<nType ){
99801 int j;
99802 int nDel = 6 + (zType[i+6] ? 1 : 0);
99803 for(j=i; (j+nDel)<=nType; j++){
99804 zType[j] = zType[j+nDel];
99806 if( zType[i]=='\0' && i>0 ){
99807 assert(zType[i-1]==' ');
99808 zType[i-1] = '\0';
99810 pTab->aCol[iCol].isHidden = 1;
99816 sqlite3DbFree(db, zModuleName);
99817 return rc;
99821 ** This function is invoked by the parser to call the xConnect() method
99822 ** of the virtual table pTab. If an error occurs, an error code is returned
99823 ** and an error left in pParse.
99825 ** This call is a no-op if table pTab is not a virtual table.
99827 SQLITE_PRIVATE int sqlite3VtabCallConnect(Parse *pParse, Table *pTab){
99828 sqlite3 *db = pParse->db;
99829 const char *zMod;
99830 Module *pMod;
99831 int rc;
99833 assert( pTab );
99834 if( (pTab->tabFlags & TF_Virtual)==0 || sqlite3GetVTable(db, pTab) ){
99835 return SQLITE_OK;
99838 /* Locate the required virtual table module */
99839 zMod = pTab->azModuleArg[0];
99840 pMod = (Module*)sqlite3HashFind(&db->aModule, zMod, sqlite3Strlen30(zMod));
99842 if( !pMod ){
99843 const char *zModule = pTab->azModuleArg[0];
99844 sqlite3ErrorMsg(pParse, "no such module: %s", zModule);
99845 rc = SQLITE_ERROR;
99846 }else{
99847 char *zErr = 0;
99848 rc = vtabCallConstructor(db, pTab, pMod, pMod->pModule->xConnect, &zErr);
99849 if( rc!=SQLITE_OK ){
99850 sqlite3ErrorMsg(pParse, "%s", zErr);
99852 sqlite3DbFree(db, zErr);
99855 return rc;
99858 ** Grow the db->aVTrans[] array so that there is room for at least one
99859 ** more v-table. Return SQLITE_NOMEM if a malloc fails, or SQLITE_OK otherwise.
99861 static int growVTrans(sqlite3 *db){
99862 const int ARRAY_INCR = 5;
99864 /* Grow the sqlite3.aVTrans array if required */
99865 if( (db->nVTrans%ARRAY_INCR)==0 ){
99866 VTable **aVTrans;
99867 int nBytes = sizeof(sqlite3_vtab *) * (db->nVTrans + ARRAY_INCR);
99868 aVTrans = sqlite3DbRealloc(db, (void *)db->aVTrans, nBytes);
99869 if( !aVTrans ){
99870 return SQLITE_NOMEM;
99872 memset(&aVTrans[db->nVTrans], 0, sizeof(sqlite3_vtab *)*ARRAY_INCR);
99873 db->aVTrans = aVTrans;
99876 return SQLITE_OK;
99880 ** Add the virtual table pVTab to the array sqlite3.aVTrans[]. Space should
99881 ** have already been reserved using growVTrans().
99883 static void addToVTrans(sqlite3 *db, VTable *pVTab){
99884 /* Add pVtab to the end of sqlite3.aVTrans */
99885 db->aVTrans[db->nVTrans++] = pVTab;
99886 sqlite3VtabLock(pVTab);
99890 ** This function is invoked by the vdbe to call the xCreate method
99891 ** of the virtual table named zTab in database iDb.
99893 ** If an error occurs, *pzErr is set to point an an English language
99894 ** description of the error and an SQLITE_XXX error code is returned.
99895 ** In this case the caller must call sqlite3DbFree(db, ) on *pzErr.
99897 SQLITE_PRIVATE int sqlite3VtabCallCreate(sqlite3 *db, int iDb, const char *zTab, char **pzErr){
99898 int rc = SQLITE_OK;
99899 Table *pTab;
99900 Module *pMod;
99901 const char *zMod;
99903 pTab = sqlite3FindTable(db, zTab, db->aDb[iDb].zName);
99904 assert( pTab && (pTab->tabFlags & TF_Virtual)!=0 && !pTab->pVTable );
99906 /* Locate the required virtual table module */
99907 zMod = pTab->azModuleArg[0];
99908 pMod = (Module*)sqlite3HashFind(&db->aModule, zMod, sqlite3Strlen30(zMod));
99910 /* If the module has been registered and includes a Create method,
99911 ** invoke it now. If the module has not been registered, return an
99912 ** error. Otherwise, do nothing.
99914 if( !pMod ){
99915 *pzErr = sqlite3MPrintf(db, "no such module: %s", zMod);
99916 rc = SQLITE_ERROR;
99917 }else{
99918 rc = vtabCallConstructor(db, pTab, pMod, pMod->pModule->xCreate, pzErr);
99921 /* Justification of ALWAYS(): The xConstructor method is required to
99922 ** create a valid sqlite3_vtab if it returns SQLITE_OK. */
99923 if( rc==SQLITE_OK && ALWAYS(sqlite3GetVTable(db, pTab)) ){
99924 rc = growVTrans(db);
99925 if( rc==SQLITE_OK ){
99926 addToVTrans(db, sqlite3GetVTable(db, pTab));
99930 return rc;
99934 ** This function is used to set the schema of a virtual table. It is only
99935 ** valid to call this function from within the xCreate() or xConnect() of a
99936 ** virtual table module.
99938 SQLITE_API int sqlite3_declare_vtab(sqlite3 *db, const char *zCreateTable){
99939 Parse *pParse;
99941 int rc = SQLITE_OK;
99942 Table *pTab;
99943 char *zErr = 0;
99945 sqlite3_mutex_enter(db->mutex);
99946 if( !db->pVtabCtx || !(pTab = db->pVtabCtx->pTab) ){
99947 sqlite3Error(db, SQLITE_MISUSE, 0);
99948 sqlite3_mutex_leave(db->mutex);
99949 return SQLITE_MISUSE_BKPT;
99951 assert( (pTab->tabFlags & TF_Virtual)!=0 );
99953 pParse = sqlite3StackAllocZero(db, sizeof(*pParse));
99954 if( pParse==0 ){
99955 rc = SQLITE_NOMEM;
99956 }else{
99957 pParse->declareVtab = 1;
99958 pParse->db = db;
99959 pParse->nQueryLoop = 1;
99961 if( SQLITE_OK==sqlite3RunParser(pParse, zCreateTable, &zErr)
99962 && pParse->pNewTable
99963 && !db->mallocFailed
99964 && !pParse->pNewTable->pSelect
99965 && (pParse->pNewTable->tabFlags & TF_Virtual)==0
99967 if( !pTab->aCol ){
99968 pTab->aCol = pParse->pNewTable->aCol;
99969 pTab->nCol = pParse->pNewTable->nCol;
99970 pParse->pNewTable->nCol = 0;
99971 pParse->pNewTable->aCol = 0;
99973 db->pVtabCtx->pTab = 0;
99974 }else{
99975 sqlite3Error(db, SQLITE_ERROR, (zErr ? "%s" : 0), zErr);
99976 sqlite3DbFree(db, zErr);
99977 rc = SQLITE_ERROR;
99979 pParse->declareVtab = 0;
99981 if( pParse->pVdbe ){
99982 sqlite3VdbeFinalize(pParse->pVdbe);
99984 sqlite3DeleteTable(db, pParse->pNewTable);
99985 sqlite3StackFree(db, pParse);
99988 assert( (rc&0xff)==rc );
99989 rc = sqlite3ApiExit(db, rc);
99990 sqlite3_mutex_leave(db->mutex);
99991 return rc;
99995 ** This function is invoked by the vdbe to call the xDestroy method
99996 ** of the virtual table named zTab in database iDb. This occurs
99997 ** when a DROP TABLE is mentioned.
99999 ** This call is a no-op if zTab is not a virtual table.
100001 SQLITE_PRIVATE int sqlite3VtabCallDestroy(sqlite3 *db, int iDb, const char *zTab){
100002 int rc = SQLITE_OK;
100003 Table *pTab;
100005 pTab = sqlite3FindTable(db, zTab, db->aDb[iDb].zName);
100006 if( ALWAYS(pTab!=0 && pTab->pVTable!=0) ){
100007 VTable *p = vtabDisconnectAll(db, pTab);
100009 assert( rc==SQLITE_OK );
100010 rc = p->pMod->pModule->xDestroy(p->pVtab);
100012 /* Remove the sqlite3_vtab* from the aVTrans[] array, if applicable */
100013 if( rc==SQLITE_OK ){
100014 assert( pTab->pVTable==p && p->pNext==0 );
100015 p->pVtab = 0;
100016 pTab->pVTable = 0;
100017 sqlite3VtabUnlock(p);
100021 return rc;
100025 ** This function invokes either the xRollback or xCommit method
100026 ** of each of the virtual tables in the sqlite3.aVTrans array. The method
100027 ** called is identified by the second argument, "offset", which is
100028 ** the offset of the method to call in the sqlite3_module structure.
100030 ** The array is cleared after invoking the callbacks.
100032 static void callFinaliser(sqlite3 *db, int offset){
100033 int i;
100034 if( db->aVTrans ){
100035 for(i=0; i<db->nVTrans; i++){
100036 VTable *pVTab = db->aVTrans[i];
100037 sqlite3_vtab *p = pVTab->pVtab;
100038 if( p ){
100039 int (*x)(sqlite3_vtab *);
100040 x = *(int (**)(sqlite3_vtab *))((char *)p->pModule + offset);
100041 if( x ) x(p);
100043 pVTab->iSavepoint = 0;
100044 sqlite3VtabUnlock(pVTab);
100046 sqlite3DbFree(db, db->aVTrans);
100047 db->nVTrans = 0;
100048 db->aVTrans = 0;
100053 ** Invoke the xSync method of all virtual tables in the sqlite3.aVTrans
100054 ** array. Return the error code for the first error that occurs, or
100055 ** SQLITE_OK if all xSync operations are successful.
100057 ** Set *pzErrmsg to point to a buffer that should be released using
100058 ** sqlite3DbFree() containing an error message, if one is available.
100060 SQLITE_PRIVATE int sqlite3VtabSync(sqlite3 *db, char **pzErrmsg){
100061 int i;
100062 int rc = SQLITE_OK;
100063 VTable **aVTrans = db->aVTrans;
100065 db->aVTrans = 0;
100066 for(i=0; rc==SQLITE_OK && i<db->nVTrans; i++){
100067 int (*x)(sqlite3_vtab *);
100068 sqlite3_vtab *pVtab = aVTrans[i]->pVtab;
100069 if( pVtab && (x = pVtab->pModule->xSync)!=0 ){
100070 rc = x(pVtab);
100071 sqlite3DbFree(db, *pzErrmsg);
100072 *pzErrmsg = sqlite3DbStrDup(db, pVtab->zErrMsg);
100073 sqlite3_free(pVtab->zErrMsg);
100076 db->aVTrans = aVTrans;
100077 return rc;
100081 ** Invoke the xRollback method of all virtual tables in the
100082 ** sqlite3.aVTrans array. Then clear the array itself.
100084 SQLITE_PRIVATE int sqlite3VtabRollback(sqlite3 *db){
100085 callFinaliser(db, offsetof(sqlite3_module,xRollback));
100086 return SQLITE_OK;
100090 ** Invoke the xCommit method of all virtual tables in the
100091 ** sqlite3.aVTrans array. Then clear the array itself.
100093 SQLITE_PRIVATE int sqlite3VtabCommit(sqlite3 *db){
100094 callFinaliser(db, offsetof(sqlite3_module,xCommit));
100095 return SQLITE_OK;
100099 ** If the virtual table pVtab supports the transaction interface
100100 ** (xBegin/xRollback/xCommit and optionally xSync) and a transaction is
100101 ** not currently open, invoke the xBegin method now.
100103 ** If the xBegin call is successful, place the sqlite3_vtab pointer
100104 ** in the sqlite3.aVTrans array.
100106 SQLITE_PRIVATE int sqlite3VtabBegin(sqlite3 *db, VTable *pVTab){
100107 int rc = SQLITE_OK;
100108 const sqlite3_module *pModule;
100110 /* Special case: If db->aVTrans is NULL and db->nVTrans is greater
100111 ** than zero, then this function is being called from within a
100112 ** virtual module xSync() callback. It is illegal to write to
100113 ** virtual module tables in this case, so return SQLITE_LOCKED.
100115 if( sqlite3VtabInSync(db) ){
100116 return SQLITE_LOCKED;
100118 if( !pVTab ){
100119 return SQLITE_OK;
100121 pModule = pVTab->pVtab->pModule;
100123 if( pModule->xBegin ){
100124 int i;
100126 /* If pVtab is already in the aVTrans array, return early */
100127 for(i=0; i<db->nVTrans; i++){
100128 if( db->aVTrans[i]==pVTab ){
100129 return SQLITE_OK;
100133 /* Invoke the xBegin method. If successful, add the vtab to the
100134 ** sqlite3.aVTrans[] array. */
100135 rc = growVTrans(db);
100136 if( rc==SQLITE_OK ){
100137 rc = pModule->xBegin(pVTab->pVtab);
100138 if( rc==SQLITE_OK ){
100139 addToVTrans(db, pVTab);
100143 return rc;
100147 ** Invoke either the xSavepoint, xRollbackTo or xRelease method of all
100148 ** virtual tables that currently have an open transaction. Pass iSavepoint
100149 ** as the second argument to the virtual table method invoked.
100151 ** If op is SAVEPOINT_BEGIN, the xSavepoint method is invoked. If it is
100152 ** SAVEPOINT_ROLLBACK, the xRollbackTo method. Otherwise, if op is
100153 ** SAVEPOINT_RELEASE, then the xRelease method of each virtual table with
100154 ** an open transaction is invoked.
100156 ** If any virtual table method returns an error code other than SQLITE_OK,
100157 ** processing is abandoned and the error returned to the caller of this
100158 ** function immediately. If all calls to virtual table methods are successful,
100159 ** SQLITE_OK is returned.
100161 SQLITE_PRIVATE int sqlite3VtabSavepoint(sqlite3 *db, int op, int iSavepoint){
100162 int rc = SQLITE_OK;
100164 assert( op==SAVEPOINT_RELEASE||op==SAVEPOINT_ROLLBACK||op==SAVEPOINT_BEGIN );
100165 assert( iSavepoint>=0 );
100166 if( db->aVTrans ){
100167 int i;
100168 for(i=0; rc==SQLITE_OK && i<db->nVTrans; i++){
100169 VTable *pVTab = db->aVTrans[i];
100170 const sqlite3_module *pMod = pVTab->pMod->pModule;
100171 if( pMod->iVersion>=2 ){
100172 int (*xMethod)(sqlite3_vtab *, int);
100173 switch( op ){
100174 case SAVEPOINT_BEGIN:
100175 xMethod = pMod->xSavepoint;
100176 pVTab->iSavepoint = iSavepoint+1;
100177 break;
100178 case SAVEPOINT_ROLLBACK:
100179 xMethod = pMod->xRollbackTo;
100180 break;
100181 default:
100182 xMethod = pMod->xRelease;
100183 break;
100185 if( xMethod && pVTab->iSavepoint>iSavepoint ){
100186 rc = xMethod(db->aVTrans[i]->pVtab, iSavepoint);
100191 return rc;
100195 ** The first parameter (pDef) is a function implementation. The
100196 ** second parameter (pExpr) is the first argument to this function.
100197 ** If pExpr is a column in a virtual table, then let the virtual
100198 ** table implementation have an opportunity to overload the function.
100200 ** This routine is used to allow virtual table implementations to
100201 ** overload MATCH, LIKE, GLOB, and REGEXP operators.
100203 ** Return either the pDef argument (indicating no change) or a
100204 ** new FuncDef structure that is marked as ephemeral using the
100205 ** SQLITE_FUNC_EPHEM flag.
100207 SQLITE_PRIVATE FuncDef *sqlite3VtabOverloadFunction(
100208 sqlite3 *db, /* Database connection for reporting malloc problems */
100209 FuncDef *pDef, /* Function to possibly overload */
100210 int nArg, /* Number of arguments to the function */
100211 Expr *pExpr /* First argument to the function */
100213 Table *pTab;
100214 sqlite3_vtab *pVtab;
100215 sqlite3_module *pMod;
100216 void (*xFunc)(sqlite3_context*,int,sqlite3_value**) = 0;
100217 void *pArg = 0;
100218 FuncDef *pNew;
100219 int rc = 0;
100220 char *zLowerName;
100221 unsigned char *z;
100224 /* Check to see the left operand is a column in a virtual table */
100225 if( NEVER(pExpr==0) ) return pDef;
100226 if( pExpr->op!=TK_COLUMN ) return pDef;
100227 pTab = pExpr->pTab;
100228 if( NEVER(pTab==0) ) return pDef;
100229 if( (pTab->tabFlags & TF_Virtual)==0 ) return pDef;
100230 pVtab = sqlite3GetVTable(db, pTab)->pVtab;
100231 assert( pVtab!=0 );
100232 assert( pVtab->pModule!=0 );
100233 pMod = (sqlite3_module *)pVtab->pModule;
100234 if( pMod->xFindFunction==0 ) return pDef;
100236 /* Call the xFindFunction method on the virtual table implementation
100237 ** to see if the implementation wants to overload this function
100239 zLowerName = sqlite3DbStrDup(db, pDef->zName);
100240 if( zLowerName ){
100241 for(z=(unsigned char*)zLowerName; *z; z++){
100242 *z = sqlite3UpperToLower[*z];
100244 rc = pMod->xFindFunction(pVtab, nArg, zLowerName, &xFunc, &pArg);
100245 sqlite3DbFree(db, zLowerName);
100247 if( rc==0 ){
100248 return pDef;
100251 /* Create a new ephemeral function definition for the overloaded
100252 ** function */
100253 pNew = sqlite3DbMallocZero(db, sizeof(*pNew)
100254 + sqlite3Strlen30(pDef->zName) + 1);
100255 if( pNew==0 ){
100256 return pDef;
100258 *pNew = *pDef;
100259 pNew->zName = (char *)&pNew[1];
100260 memcpy(pNew->zName, pDef->zName, sqlite3Strlen30(pDef->zName)+1);
100261 pNew->xFunc = xFunc;
100262 pNew->pUserData = pArg;
100263 pNew->flags |= SQLITE_FUNC_EPHEM;
100264 return pNew;
100268 ** Make sure virtual table pTab is contained in the pParse->apVirtualLock[]
100269 ** array so that an OP_VBegin will get generated for it. Add pTab to the
100270 ** array if it is missing. If pTab is already in the array, this routine
100271 ** is a no-op.
100273 SQLITE_PRIVATE void sqlite3VtabMakeWritable(Parse *pParse, Table *pTab){
100274 Parse *pToplevel = sqlite3ParseToplevel(pParse);
100275 int i, n;
100276 Table **apVtabLock;
100278 assert( IsVirtual(pTab) );
100279 for(i=0; i<pToplevel->nVtabLock; i++){
100280 if( pTab==pToplevel->apVtabLock[i] ) return;
100282 n = (pToplevel->nVtabLock+1)*sizeof(pToplevel->apVtabLock[0]);
100283 apVtabLock = sqlite3_realloc(pToplevel->apVtabLock, n);
100284 if( apVtabLock ){
100285 pToplevel->apVtabLock = apVtabLock;
100286 pToplevel->apVtabLock[pToplevel->nVtabLock++] = pTab;
100287 }else{
100288 pToplevel->db->mallocFailed = 1;
100293 ** Return the ON CONFLICT resolution mode in effect for the virtual
100294 ** table update operation currently in progress.
100296 ** The results of this routine are undefined unless it is called from
100297 ** within an xUpdate method.
100299 SQLITE_API int sqlite3_vtab_on_conflict(sqlite3 *db){
100300 static const unsigned char aMap[] = {
100301 SQLITE_ROLLBACK, SQLITE_ABORT, SQLITE_FAIL, SQLITE_IGNORE, SQLITE_REPLACE
100303 assert( OE_Rollback==1 && OE_Abort==2 && OE_Fail==3 );
100304 assert( OE_Ignore==4 && OE_Replace==5 );
100305 assert( db->vtabOnConflict>=1 && db->vtabOnConflict<=5 );
100306 return (int)aMap[db->vtabOnConflict-1];
100310 ** Call from within the xCreate() or xConnect() methods to provide
100311 ** the SQLite core with additional information about the behavior
100312 ** of the virtual table being implemented.
100314 SQLITE_API int sqlite3_vtab_config(sqlite3 *db, int op, ...){
100315 va_list ap;
100316 int rc = SQLITE_OK;
100318 sqlite3_mutex_enter(db->mutex);
100320 va_start(ap, op);
100321 switch( op ){
100322 case SQLITE_VTAB_CONSTRAINT_SUPPORT: {
100323 VtabCtx *p = db->pVtabCtx;
100324 if( !p ){
100325 rc = SQLITE_MISUSE_BKPT;
100326 }else{
100327 assert( p->pTab==0 || (p->pTab->tabFlags & TF_Virtual)!=0 );
100328 p->pVTable->bConstraint = (u8)va_arg(ap, int);
100330 break;
100332 default:
100333 rc = SQLITE_MISUSE_BKPT;
100334 break;
100336 va_end(ap);
100338 if( rc!=SQLITE_OK ) sqlite3Error(db, rc, 0);
100339 sqlite3_mutex_leave(db->mutex);
100340 return rc;
100343 #endif /* SQLITE_OMIT_VIRTUALTABLE */
100345 /************** End of vtab.c ************************************************/
100346 /************** Begin file where.c *******************************************/
100348 ** 2001 September 15
100350 ** The author disclaims copyright to this source code. In place of
100351 ** a legal notice, here is a blessing:
100353 ** May you do good and not evil.
100354 ** May you find forgiveness for yourself and forgive others.
100355 ** May you share freely, never taking more than you give.
100357 *************************************************************************
100358 ** This module contains C code that generates VDBE code used to process
100359 ** the WHERE clause of SQL statements. This module is responsible for
100360 ** generating the code that loops through a table looking for applicable
100361 ** rows. Indices are selected and used to speed the search when doing
100362 ** so is applicable. Because this module is responsible for selecting
100363 ** indices, you might also think of this module as the "query optimizer".
100368 ** Trace output macros
100370 #if defined(SQLITE_TEST) || defined(SQLITE_DEBUG)
100371 SQLITE_PRIVATE int sqlite3WhereTrace = 0;
100372 #endif
100373 #if defined(SQLITE_TEST) && defined(SQLITE_DEBUG)
100374 # define WHERETRACE(X) if(sqlite3WhereTrace) sqlite3DebugPrintf X
100375 #else
100376 # define WHERETRACE(X)
100377 #endif
100379 /* Forward reference
100381 typedef struct WhereClause WhereClause;
100382 typedef struct WhereMaskSet WhereMaskSet;
100383 typedef struct WhereOrInfo WhereOrInfo;
100384 typedef struct WhereAndInfo WhereAndInfo;
100385 typedef struct WhereCost WhereCost;
100388 ** The query generator uses an array of instances of this structure to
100389 ** help it analyze the subexpressions of the WHERE clause. Each WHERE
100390 ** clause subexpression is separated from the others by AND operators,
100391 ** usually, or sometimes subexpressions separated by OR.
100393 ** All WhereTerms are collected into a single WhereClause structure.
100394 ** The following identity holds:
100396 ** WhereTerm.pWC->a[WhereTerm.idx] == WhereTerm
100398 ** When a term is of the form:
100400 ** X <op> <expr>
100402 ** where X is a column name and <op> is one of certain operators,
100403 ** then WhereTerm.leftCursor and WhereTerm.u.leftColumn record the
100404 ** cursor number and column number for X. WhereTerm.eOperator records
100405 ** the <op> using a bitmask encoding defined by WO_xxx below. The
100406 ** use of a bitmask encoding for the operator allows us to search
100407 ** quickly for terms that match any of several different operators.
100409 ** A WhereTerm might also be two or more subterms connected by OR:
100411 ** (t1.X <op> <expr>) OR (t1.Y <op> <expr>) OR ....
100413 ** In this second case, wtFlag as the TERM_ORINFO set and eOperator==WO_OR
100414 ** and the WhereTerm.u.pOrInfo field points to auxiliary information that
100415 ** is collected about the
100417 ** If a term in the WHERE clause does not match either of the two previous
100418 ** categories, then eOperator==0. The WhereTerm.pExpr field is still set
100419 ** to the original subexpression content and wtFlags is set up appropriately
100420 ** but no other fields in the WhereTerm object are meaningful.
100422 ** When eOperator!=0, prereqRight and prereqAll record sets of cursor numbers,
100423 ** but they do so indirectly. A single WhereMaskSet structure translates
100424 ** cursor number into bits and the translated bit is stored in the prereq
100425 ** fields. The translation is used in order to maximize the number of
100426 ** bits that will fit in a Bitmask. The VDBE cursor numbers might be
100427 ** spread out over the non-negative integers. For example, the cursor
100428 ** numbers might be 3, 8, 9, 10, 20, 23, 41, and 45. The WhereMaskSet
100429 ** translates these sparse cursor numbers into consecutive integers
100430 ** beginning with 0 in order to make the best possible use of the available
100431 ** bits in the Bitmask. So, in the example above, the cursor numbers
100432 ** would be mapped into integers 0 through 7.
100434 ** The number of terms in a join is limited by the number of bits
100435 ** in prereqRight and prereqAll. The default is 64 bits, hence SQLite
100436 ** is only able to process joins with 64 or fewer tables.
100438 typedef struct WhereTerm WhereTerm;
100439 struct WhereTerm {
100440 Expr *pExpr; /* Pointer to the subexpression that is this term */
100441 int iParent; /* Disable pWC->a[iParent] when this term disabled */
100442 int leftCursor; /* Cursor number of X in "X <op> <expr>" */
100443 union {
100444 int leftColumn; /* Column number of X in "X <op> <expr>" */
100445 WhereOrInfo *pOrInfo; /* Extra information if eOperator==WO_OR */
100446 WhereAndInfo *pAndInfo; /* Extra information if eOperator==WO_AND */
100448 u16 eOperator; /* A WO_xx value describing <op> */
100449 u8 wtFlags; /* TERM_xxx bit flags. See below */
100450 u8 nChild; /* Number of children that must disable us */
100451 WhereClause *pWC; /* The clause this term is part of */
100452 Bitmask prereqRight; /* Bitmask of tables used by pExpr->pRight */
100453 Bitmask prereqAll; /* Bitmask of tables referenced by pExpr */
100457 ** Allowed values of WhereTerm.wtFlags
100459 #define TERM_DYNAMIC 0x01 /* Need to call sqlite3ExprDelete(db, pExpr) */
100460 #define TERM_VIRTUAL 0x02 /* Added by the optimizer. Do not code */
100461 #define TERM_CODED 0x04 /* This term is already coded */
100462 #define TERM_COPIED 0x08 /* Has a child */
100463 #define TERM_ORINFO 0x10 /* Need to free the WhereTerm.u.pOrInfo object */
100464 #define TERM_ANDINFO 0x20 /* Need to free the WhereTerm.u.pAndInfo obj */
100465 #define TERM_OR_OK 0x40 /* Used during OR-clause processing */
100466 #ifdef SQLITE_ENABLE_STAT2
100467 # define TERM_VNULL 0x80 /* Manufactured x>NULL or x<=NULL term */
100468 #else
100469 # define TERM_VNULL 0x00 /* Disabled if not using stat2 */
100470 #endif
100473 ** An instance of the following structure holds all information about a
100474 ** WHERE clause. Mostly this is a container for one or more WhereTerms.
100476 struct WhereClause {
100477 Parse *pParse; /* The parser context */
100478 WhereMaskSet *pMaskSet; /* Mapping of table cursor numbers to bitmasks */
100479 Bitmask vmask; /* Bitmask identifying virtual table cursors */
100480 u8 op; /* Split operator. TK_AND or TK_OR */
100481 int nTerm; /* Number of terms */
100482 int nSlot; /* Number of entries in a[] */
100483 WhereTerm *a; /* Each a[] describes a term of the WHERE cluase */
100484 #if defined(SQLITE_SMALL_STACK)
100485 WhereTerm aStatic[1]; /* Initial static space for a[] */
100486 #else
100487 WhereTerm aStatic[8]; /* Initial static space for a[] */
100488 #endif
100492 ** A WhereTerm with eOperator==WO_OR has its u.pOrInfo pointer set to
100493 ** a dynamically allocated instance of the following structure.
100495 struct WhereOrInfo {
100496 WhereClause wc; /* Decomposition into subterms */
100497 Bitmask indexable; /* Bitmask of all indexable tables in the clause */
100501 ** A WhereTerm with eOperator==WO_AND has its u.pAndInfo pointer set to
100502 ** a dynamically allocated instance of the following structure.
100504 struct WhereAndInfo {
100505 WhereClause wc; /* The subexpression broken out */
100509 ** An instance of the following structure keeps track of a mapping
100510 ** between VDBE cursor numbers and bits of the bitmasks in WhereTerm.
100512 ** The VDBE cursor numbers are small integers contained in
100513 ** SrcList_item.iCursor and Expr.iTable fields. For any given WHERE
100514 ** clause, the cursor numbers might not begin with 0 and they might
100515 ** contain gaps in the numbering sequence. But we want to make maximum
100516 ** use of the bits in our bitmasks. This structure provides a mapping
100517 ** from the sparse cursor numbers into consecutive integers beginning
100518 ** with 0.
100520 ** If WhereMaskSet.ix[A]==B it means that The A-th bit of a Bitmask
100521 ** corresponds VDBE cursor number B. The A-th bit of a bitmask is 1<<A.
100523 ** For example, if the WHERE clause expression used these VDBE
100524 ** cursors: 4, 5, 8, 29, 57, 73. Then the WhereMaskSet structure
100525 ** would map those cursor numbers into bits 0 through 5.
100527 ** Note that the mapping is not necessarily ordered. In the example
100528 ** above, the mapping might go like this: 4->3, 5->1, 8->2, 29->0,
100529 ** 57->5, 73->4. Or one of 719 other combinations might be used. It
100530 ** does not really matter. What is important is that sparse cursor
100531 ** numbers all get mapped into bit numbers that begin with 0 and contain
100532 ** no gaps.
100534 struct WhereMaskSet {
100535 int n; /* Number of assigned cursor values */
100536 int ix[BMS]; /* Cursor assigned to each bit */
100540 ** A WhereCost object records a lookup strategy and the estimated
100541 ** cost of pursuing that strategy.
100543 struct WhereCost {
100544 WherePlan plan; /* The lookup strategy */
100545 double rCost; /* Overall cost of pursuing this search strategy */
100546 Bitmask used; /* Bitmask of cursors used by this plan */
100550 ** Bitmasks for the operators that indices are able to exploit. An
100551 ** OR-ed combination of these values can be used when searching for
100552 ** terms in the where clause.
100554 #define WO_IN 0x001
100555 #define WO_EQ 0x002
100556 #define WO_LT (WO_EQ<<(TK_LT-TK_EQ))
100557 #define WO_LE (WO_EQ<<(TK_LE-TK_EQ))
100558 #define WO_GT (WO_EQ<<(TK_GT-TK_EQ))
100559 #define WO_GE (WO_EQ<<(TK_GE-TK_EQ))
100560 #define WO_MATCH 0x040
100561 #define WO_ISNULL 0x080
100562 #define WO_OR 0x100 /* Two or more OR-connected terms */
100563 #define WO_AND 0x200 /* Two or more AND-connected terms */
100564 #define WO_NOOP 0x800 /* This term does not restrict search space */
100566 #define WO_ALL 0xfff /* Mask of all possible WO_* values */
100567 #define WO_SINGLE 0x0ff /* Mask of all non-compound WO_* values */
100570 ** Value for wsFlags returned by bestIndex() and stored in
100571 ** WhereLevel.wsFlags. These flags determine which search
100572 ** strategies are appropriate.
100574 ** The least significant 12 bits is reserved as a mask for WO_ values above.
100575 ** The WhereLevel.wsFlags field is usually set to WO_IN|WO_EQ|WO_ISNULL.
100576 ** But if the table is the right table of a left join, WhereLevel.wsFlags
100577 ** is set to WO_IN|WO_EQ. The WhereLevel.wsFlags field can then be used as
100578 ** the "op" parameter to findTerm when we are resolving equality constraints.
100579 ** ISNULL constraints will then not be used on the right table of a left
100580 ** join. Tickets #2177 and #2189.
100582 #define WHERE_ROWID_EQ 0x00001000 /* rowid=EXPR or rowid IN (...) */
100583 #define WHERE_ROWID_RANGE 0x00002000 /* rowid<EXPR and/or rowid>EXPR */
100584 #define WHERE_COLUMN_EQ 0x00010000 /* x=EXPR or x IN (...) or x IS NULL */
100585 #define WHERE_COLUMN_RANGE 0x00020000 /* x<EXPR and/or x>EXPR */
100586 #define WHERE_COLUMN_IN 0x00040000 /* x IN (...) */
100587 #define WHERE_COLUMN_NULL 0x00080000 /* x IS NULL */
100588 #define WHERE_INDEXED 0x000f0000 /* Anything that uses an index */
100589 #define WHERE_NOT_FULLSCAN 0x100f3000 /* Does not do a full table scan */
100590 #define WHERE_IN_ABLE 0x000f1000 /* Able to support an IN operator */
100591 #define WHERE_TOP_LIMIT 0x00100000 /* x<EXPR or x<=EXPR constraint */
100592 #define WHERE_BTM_LIMIT 0x00200000 /* x>EXPR or x>=EXPR constraint */
100593 #define WHERE_BOTH_LIMIT 0x00300000 /* Both x>EXPR and x<EXPR */
100594 #define WHERE_IDX_ONLY 0x00800000 /* Use index only - omit table */
100595 #define WHERE_ORDERBY 0x01000000 /* Output will appear in correct order */
100596 #define WHERE_REVERSE 0x02000000 /* Scan in reverse order */
100597 #define WHERE_UNIQUE 0x04000000 /* Selects no more than one row */
100598 #define WHERE_VIRTUALTABLE 0x08000000 /* Use virtual-table processing */
100599 #define WHERE_MULTI_OR 0x10000000 /* OR using multiple indices */
100600 #define WHERE_TEMP_INDEX 0x20000000 /* Uses an ephemeral index */
100601 #define WHERE_DISTINCT 0x40000000 /* Correct order for DISTINCT */
100604 ** Initialize a preallocated WhereClause structure.
100606 static void whereClauseInit(
100607 WhereClause *pWC, /* The WhereClause to be initialized */
100608 Parse *pParse, /* The parsing context */
100609 WhereMaskSet *pMaskSet /* Mapping from table cursor numbers to bitmasks */
100611 pWC->pParse = pParse;
100612 pWC->pMaskSet = pMaskSet;
100613 pWC->nTerm = 0;
100614 pWC->nSlot = ArraySize(pWC->aStatic);
100615 pWC->a = pWC->aStatic;
100616 pWC->vmask = 0;
100619 /* Forward reference */
100620 static void whereClauseClear(WhereClause*);
100623 ** Deallocate all memory associated with a WhereOrInfo object.
100625 static void whereOrInfoDelete(sqlite3 *db, WhereOrInfo *p){
100626 whereClauseClear(&p->wc);
100627 sqlite3DbFree(db, p);
100631 ** Deallocate all memory associated with a WhereAndInfo object.
100633 static void whereAndInfoDelete(sqlite3 *db, WhereAndInfo *p){
100634 whereClauseClear(&p->wc);
100635 sqlite3DbFree(db, p);
100639 ** Deallocate a WhereClause structure. The WhereClause structure
100640 ** itself is not freed. This routine is the inverse of whereClauseInit().
100642 static void whereClauseClear(WhereClause *pWC){
100643 int i;
100644 WhereTerm *a;
100645 sqlite3 *db = pWC->pParse->db;
100646 for(i=pWC->nTerm-1, a=pWC->a; i>=0; i--, a++){
100647 if( a->wtFlags & TERM_DYNAMIC ){
100648 sqlite3ExprDelete(db, a->pExpr);
100650 if( a->wtFlags & TERM_ORINFO ){
100651 whereOrInfoDelete(db, a->u.pOrInfo);
100652 }else if( a->wtFlags & TERM_ANDINFO ){
100653 whereAndInfoDelete(db, a->u.pAndInfo);
100656 if( pWC->a!=pWC->aStatic ){
100657 sqlite3DbFree(db, pWC->a);
100662 ** Add a single new WhereTerm entry to the WhereClause object pWC.
100663 ** The new WhereTerm object is constructed from Expr p and with wtFlags.
100664 ** The index in pWC->a[] of the new WhereTerm is returned on success.
100665 ** 0 is returned if the new WhereTerm could not be added due to a memory
100666 ** allocation error. The memory allocation failure will be recorded in
100667 ** the db->mallocFailed flag so that higher-level functions can detect it.
100669 ** This routine will increase the size of the pWC->a[] array as necessary.
100671 ** If the wtFlags argument includes TERM_DYNAMIC, then responsibility
100672 ** for freeing the expression p is assumed by the WhereClause object pWC.
100673 ** This is true even if this routine fails to allocate a new WhereTerm.
100675 ** WARNING: This routine might reallocate the space used to store
100676 ** WhereTerms. All pointers to WhereTerms should be invalidated after
100677 ** calling this routine. Such pointers may be reinitialized by referencing
100678 ** the pWC->a[] array.
100680 static int whereClauseInsert(WhereClause *pWC, Expr *p, u8 wtFlags){
100681 WhereTerm *pTerm;
100682 int idx;
100683 testcase( wtFlags & TERM_VIRTUAL ); /* EV: R-00211-15100 */
100684 if( pWC->nTerm>=pWC->nSlot ){
100685 WhereTerm *pOld = pWC->a;
100686 sqlite3 *db = pWC->pParse->db;
100687 pWC->a = sqlite3DbMallocRaw(db, sizeof(pWC->a[0])*pWC->nSlot*2 );
100688 if( pWC->a==0 ){
100689 if( wtFlags & TERM_DYNAMIC ){
100690 sqlite3ExprDelete(db, p);
100692 pWC->a = pOld;
100693 return 0;
100695 memcpy(pWC->a, pOld, sizeof(pWC->a[0])*pWC->nTerm);
100696 if( pOld!=pWC->aStatic ){
100697 sqlite3DbFree(db, pOld);
100699 pWC->nSlot = sqlite3DbMallocSize(db, pWC->a)/sizeof(pWC->a[0]);
100701 pTerm = &pWC->a[idx = pWC->nTerm++];
100702 pTerm->pExpr = p;
100703 pTerm->wtFlags = wtFlags;
100704 pTerm->pWC = pWC;
100705 pTerm->iParent = -1;
100706 return idx;
100710 ** This routine identifies subexpressions in the WHERE clause where
100711 ** each subexpression is separated by the AND operator or some other
100712 ** operator specified in the op parameter. The WhereClause structure
100713 ** is filled with pointers to subexpressions. For example:
100715 ** WHERE a=='hello' AND coalesce(b,11)<10 AND (c+12!=d OR c==22)
100716 ** \________/ \_______________/ \________________/
100717 ** slot[0] slot[1] slot[2]
100719 ** The original WHERE clause in pExpr is unaltered. All this routine
100720 ** does is make slot[] entries point to substructure within pExpr.
100722 ** In the previous sentence and in the diagram, "slot[]" refers to
100723 ** the WhereClause.a[] array. The slot[] array grows as needed to contain
100724 ** all terms of the WHERE clause.
100726 static void whereSplit(WhereClause *pWC, Expr *pExpr, int op){
100727 pWC->op = (u8)op;
100728 if( pExpr==0 ) return;
100729 if( pExpr->op!=op ){
100730 whereClauseInsert(pWC, pExpr, 0);
100731 }else{
100732 whereSplit(pWC, pExpr->pLeft, op);
100733 whereSplit(pWC, pExpr->pRight, op);
100738 ** Initialize an expression mask set (a WhereMaskSet object)
100740 #define initMaskSet(P) memset(P, 0, sizeof(*P))
100743 ** Return the bitmask for the given cursor number. Return 0 if
100744 ** iCursor is not in the set.
100746 static Bitmask getMask(WhereMaskSet *pMaskSet, int iCursor){
100747 int i;
100748 assert( pMaskSet->n<=(int)sizeof(Bitmask)*8 );
100749 for(i=0; i<pMaskSet->n; i++){
100750 if( pMaskSet->ix[i]==iCursor ){
100751 return ((Bitmask)1)<<i;
100754 return 0;
100758 ** Create a new mask for cursor iCursor.
100760 ** There is one cursor per table in the FROM clause. The number of
100761 ** tables in the FROM clause is limited by a test early in the
100762 ** sqlite3WhereBegin() routine. So we know that the pMaskSet->ix[]
100763 ** array will never overflow.
100765 static void createMask(WhereMaskSet *pMaskSet, int iCursor){
100766 assert( pMaskSet->n < ArraySize(pMaskSet->ix) );
100767 pMaskSet->ix[pMaskSet->n++] = iCursor;
100771 ** This routine walks (recursively) an expression tree and generates
100772 ** a bitmask indicating which tables are used in that expression
100773 ** tree.
100775 ** In order for this routine to work, the calling function must have
100776 ** previously invoked sqlite3ResolveExprNames() on the expression. See
100777 ** the header comment on that routine for additional information.
100778 ** The sqlite3ResolveExprNames() routines looks for column names and
100779 ** sets their opcodes to TK_COLUMN and their Expr.iTable fields to
100780 ** the VDBE cursor number of the table. This routine just has to
100781 ** translate the cursor numbers into bitmask values and OR all
100782 ** the bitmasks together.
100784 static Bitmask exprListTableUsage(WhereMaskSet*, ExprList*);
100785 static Bitmask exprSelectTableUsage(WhereMaskSet*, Select*);
100786 static Bitmask exprTableUsage(WhereMaskSet *pMaskSet, Expr *p){
100787 Bitmask mask = 0;
100788 if( p==0 ) return 0;
100789 if( p->op==TK_COLUMN ){
100790 mask = getMask(pMaskSet, p->iTable);
100791 return mask;
100793 mask = exprTableUsage(pMaskSet, p->pRight);
100794 mask |= exprTableUsage(pMaskSet, p->pLeft);
100795 if( ExprHasProperty(p, EP_xIsSelect) ){
100796 mask |= exprSelectTableUsage(pMaskSet, p->x.pSelect);
100797 }else{
100798 mask |= exprListTableUsage(pMaskSet, p->x.pList);
100800 return mask;
100802 static Bitmask exprListTableUsage(WhereMaskSet *pMaskSet, ExprList *pList){
100803 int i;
100804 Bitmask mask = 0;
100805 if( pList ){
100806 for(i=0; i<pList->nExpr; i++){
100807 mask |= exprTableUsage(pMaskSet, pList->a[i].pExpr);
100810 return mask;
100812 static Bitmask exprSelectTableUsage(WhereMaskSet *pMaskSet, Select *pS){
100813 Bitmask mask = 0;
100814 while( pS ){
100815 SrcList *pSrc = pS->pSrc;
100816 mask |= exprListTableUsage(pMaskSet, pS->pEList);
100817 mask |= exprListTableUsage(pMaskSet, pS->pGroupBy);
100818 mask |= exprListTableUsage(pMaskSet, pS->pOrderBy);
100819 mask |= exprTableUsage(pMaskSet, pS->pWhere);
100820 mask |= exprTableUsage(pMaskSet, pS->pHaving);
100821 if( ALWAYS(pSrc!=0) ){
100822 int i;
100823 for(i=0; i<pSrc->nSrc; i++){
100824 mask |= exprSelectTableUsage(pMaskSet, pSrc->a[i].pSelect);
100825 mask |= exprTableUsage(pMaskSet, pSrc->a[i].pOn);
100828 pS = pS->pPrior;
100830 return mask;
100834 ** Return TRUE if the given operator is one of the operators that is
100835 ** allowed for an indexable WHERE clause term. The allowed operators are
100836 ** "=", "<", ">", "<=", ">=", and "IN".
100838 ** IMPLEMENTATION-OF: R-59926-26393 To be usable by an index a term must be
100839 ** of one of the following forms: column = expression column > expression
100840 ** column >= expression column < expression column <= expression
100841 ** expression = column expression > column expression >= column
100842 ** expression < column expression <= column column IN
100843 ** (expression-list) column IN (subquery) column IS NULL
100845 static int allowedOp(int op){
100846 assert( TK_GT>TK_EQ && TK_GT<TK_GE );
100847 assert( TK_LT>TK_EQ && TK_LT<TK_GE );
100848 assert( TK_LE>TK_EQ && TK_LE<TK_GE );
100849 assert( TK_GE==TK_EQ+4 );
100850 return op==TK_IN || (op>=TK_EQ && op<=TK_GE) || op==TK_ISNULL;
100854 ** Swap two objects of type TYPE.
100856 #define SWAP(TYPE,A,B) {TYPE t=A; A=B; B=t;}
100859 ** Commute a comparison operator. Expressions of the form "X op Y"
100860 ** are converted into "Y op X".
100862 ** If a collation sequence is associated with either the left or right
100863 ** side of the comparison, it remains associated with the same side after
100864 ** the commutation. So "Y collate NOCASE op X" becomes
100865 ** "X collate NOCASE op Y". This is because any collation sequence on
100866 ** the left hand side of a comparison overrides any collation sequence
100867 ** attached to the right. For the same reason the EP_ExpCollate flag
100868 ** is not commuted.
100870 static void exprCommute(Parse *pParse, Expr *pExpr){
100871 u16 expRight = (pExpr->pRight->flags & EP_ExpCollate);
100872 u16 expLeft = (pExpr->pLeft->flags & EP_ExpCollate);
100873 assert( allowedOp(pExpr->op) && pExpr->op!=TK_IN );
100874 pExpr->pRight->pColl = sqlite3ExprCollSeq(pParse, pExpr->pRight);
100875 pExpr->pLeft->pColl = sqlite3ExprCollSeq(pParse, pExpr->pLeft);
100876 SWAP(CollSeq*,pExpr->pRight->pColl,pExpr->pLeft->pColl);
100877 pExpr->pRight->flags = (pExpr->pRight->flags & ~EP_ExpCollate) | expLeft;
100878 pExpr->pLeft->flags = (pExpr->pLeft->flags & ~EP_ExpCollate) | expRight;
100879 SWAP(Expr*,pExpr->pRight,pExpr->pLeft);
100880 if( pExpr->op>=TK_GT ){
100881 assert( TK_LT==TK_GT+2 );
100882 assert( TK_GE==TK_LE+2 );
100883 assert( TK_GT>TK_EQ );
100884 assert( TK_GT<TK_LE );
100885 assert( pExpr->op>=TK_GT && pExpr->op<=TK_GE );
100886 pExpr->op = ((pExpr->op-TK_GT)^2)+TK_GT;
100891 ** Translate from TK_xx operator to WO_xx bitmask.
100893 static u16 operatorMask(int op){
100894 u16 c;
100895 assert( allowedOp(op) );
100896 if( op==TK_IN ){
100897 c = WO_IN;
100898 }else if( op==TK_ISNULL ){
100899 c = WO_ISNULL;
100900 }else{
100901 assert( (WO_EQ<<(op-TK_EQ)) < 0x7fff );
100902 c = (u16)(WO_EQ<<(op-TK_EQ));
100904 assert( op!=TK_ISNULL || c==WO_ISNULL );
100905 assert( op!=TK_IN || c==WO_IN );
100906 assert( op!=TK_EQ || c==WO_EQ );
100907 assert( op!=TK_LT || c==WO_LT );
100908 assert( op!=TK_LE || c==WO_LE );
100909 assert( op!=TK_GT || c==WO_GT );
100910 assert( op!=TK_GE || c==WO_GE );
100911 return c;
100915 ** Search for a term in the WHERE clause that is of the form "X <op> <expr>"
100916 ** where X is a reference to the iColumn of table iCur and <op> is one of
100917 ** the WO_xx operator codes specified by the op parameter.
100918 ** Return a pointer to the term. Return 0 if not found.
100920 static WhereTerm *findTerm(
100921 WhereClause *pWC, /* The WHERE clause to be searched */
100922 int iCur, /* Cursor number of LHS */
100923 int iColumn, /* Column number of LHS */
100924 Bitmask notReady, /* RHS must not overlap with this mask */
100925 u32 op, /* Mask of WO_xx values describing operator */
100926 Index *pIdx /* Must be compatible with this index, if not NULL */
100928 WhereTerm *pTerm;
100929 int k;
100930 assert( iCur>=0 );
100931 op &= WO_ALL;
100932 for(pTerm=pWC->a, k=pWC->nTerm; k; k--, pTerm++){
100933 if( pTerm->leftCursor==iCur
100934 && (pTerm->prereqRight & notReady)==0
100935 && pTerm->u.leftColumn==iColumn
100936 && (pTerm->eOperator & op)!=0
100938 if( pIdx && pTerm->eOperator!=WO_ISNULL ){
100939 Expr *pX = pTerm->pExpr;
100940 CollSeq *pColl;
100941 char idxaff;
100942 int j;
100943 Parse *pParse = pWC->pParse;
100945 idxaff = pIdx->pTable->aCol[iColumn].affinity;
100946 if( !sqlite3IndexAffinityOk(pX, idxaff) ) continue;
100948 /* Figure out the collation sequence required from an index for
100949 ** it to be useful for optimising expression pX. Store this
100950 ** value in variable pColl.
100952 assert(pX->pLeft);
100953 pColl = sqlite3BinaryCompareCollSeq(pParse, pX->pLeft, pX->pRight);
100954 assert(pColl || pParse->nErr);
100956 for(j=0; pIdx->aiColumn[j]!=iColumn; j++){
100957 if( NEVER(j>=pIdx->nColumn) ) return 0;
100959 if( pColl && sqlite3StrICmp(pColl->zName, pIdx->azColl[j]) ) continue;
100961 return pTerm;
100964 return 0;
100967 /* Forward reference */
100968 static void exprAnalyze(SrcList*, WhereClause*, int);
100971 ** Call exprAnalyze on all terms in a WHERE clause.
100975 static void exprAnalyzeAll(
100976 SrcList *pTabList, /* the FROM clause */
100977 WhereClause *pWC /* the WHERE clause to be analyzed */
100979 int i;
100980 for(i=pWC->nTerm-1; i>=0; i--){
100981 exprAnalyze(pTabList, pWC, i);
100985 #ifndef SQLITE_OMIT_LIKE_OPTIMIZATION
100987 ** Check to see if the given expression is a LIKE or GLOB operator that
100988 ** can be optimized using inequality constraints. Return TRUE if it is
100989 ** so and false if not.
100991 ** In order for the operator to be optimizible, the RHS must be a string
100992 ** literal that does not begin with a wildcard.
100994 static int isLikeOrGlob(
100995 Parse *pParse, /* Parsing and code generating context */
100996 Expr *pExpr, /* Test this expression */
100997 Expr **ppPrefix, /* Pointer to TK_STRING expression with pattern prefix */
100998 int *pisComplete, /* True if the only wildcard is % in the last character */
100999 int *pnoCase /* True if uppercase is equivalent to lowercase */
101001 const char *z = 0; /* String on RHS of LIKE operator */
101002 Expr *pRight, *pLeft; /* Right and left size of LIKE operator */
101003 ExprList *pList; /* List of operands to the LIKE operator */
101004 int c; /* One character in z[] */
101005 int cnt; /* Number of non-wildcard prefix characters */
101006 char wc[3]; /* Wildcard characters */
101007 sqlite3 *db = pParse->db; /* Database connection */
101008 sqlite3_value *pVal = 0;
101009 int op; /* Opcode of pRight */
101011 if( !sqlite3IsLikeFunction(db, pExpr, pnoCase, wc) ){
101012 return 0;
101014 #ifdef SQLITE_EBCDIC
101015 if( *pnoCase ) return 0;
101016 #endif
101017 pList = pExpr->x.pList;
101018 pLeft = pList->a[1].pExpr;
101019 if( pLeft->op!=TK_COLUMN || sqlite3ExprAffinity(pLeft)!=SQLITE_AFF_TEXT ){
101020 /* IMP: R-02065-49465 The left-hand side of the LIKE or GLOB operator must
101021 ** be the name of an indexed column with TEXT affinity. */
101022 return 0;
101024 assert( pLeft->iColumn!=(-1) ); /* Because IPK never has AFF_TEXT */
101026 pRight = pList->a[0].pExpr;
101027 op = pRight->op;
101028 if( op==TK_REGISTER ){
101029 op = pRight->op2;
101031 if( op==TK_VARIABLE ){
101032 Vdbe *pReprepare = pParse->pReprepare;
101033 int iCol = pRight->iColumn;
101034 pVal = sqlite3VdbeGetValue(pReprepare, iCol, SQLITE_AFF_NONE);
101035 if( pVal && sqlite3_value_type(pVal)==SQLITE_TEXT ){
101036 z = (char *)sqlite3_value_text(pVal);
101038 sqlite3VdbeSetVarmask(pParse->pVdbe, iCol); /* IMP: R-23257-02778 */
101039 assert( pRight->op==TK_VARIABLE || pRight->op==TK_REGISTER );
101040 }else if( op==TK_STRING ){
101041 z = pRight->u.zToken;
101043 if( z ){
101044 cnt = 0;
101045 while( (c=z[cnt])!=0 && c!=wc[0] && c!=wc[1] && c!=wc[2] ){
101046 cnt++;
101048 if( cnt!=0 && 255!=(u8)z[cnt-1] ){
101049 Expr *pPrefix;
101050 *pisComplete = c==wc[0] && z[cnt+1]==0;
101051 pPrefix = sqlite3Expr(db, TK_STRING, z);
101052 if( pPrefix ) pPrefix->u.zToken[cnt] = 0;
101053 *ppPrefix = pPrefix;
101054 if( op==TK_VARIABLE ){
101055 Vdbe *v = pParse->pVdbe;
101056 sqlite3VdbeSetVarmask(v, pRight->iColumn); /* IMP: R-23257-02778 */
101057 if( *pisComplete && pRight->u.zToken[1] ){
101058 /* If the rhs of the LIKE expression is a variable, and the current
101059 ** value of the variable means there is no need to invoke the LIKE
101060 ** function, then no OP_Variable will be added to the program.
101061 ** This causes problems for the sqlite3_bind_parameter_name()
101062 ** API. To workaround them, add a dummy OP_Variable here.
101064 int r1 = sqlite3GetTempReg(pParse);
101065 sqlite3ExprCodeTarget(pParse, pRight, r1);
101066 sqlite3VdbeChangeP3(v, sqlite3VdbeCurrentAddr(v)-1, 0);
101067 sqlite3ReleaseTempReg(pParse, r1);
101070 }else{
101071 z = 0;
101075 sqlite3ValueFree(pVal);
101076 return (z!=0);
101078 #endif /* SQLITE_OMIT_LIKE_OPTIMIZATION */
101081 #ifndef SQLITE_OMIT_VIRTUALTABLE
101083 ** Check to see if the given expression is of the form
101085 ** column MATCH expr
101087 ** If it is then return TRUE. If not, return FALSE.
101089 static int isMatchOfColumn(
101090 Expr *pExpr /* Test this expression */
101092 ExprList *pList;
101094 if( pExpr->op!=TK_FUNCTION ){
101095 return 0;
101097 if( sqlite3StrICmp(pExpr->u.zToken,"match")!=0 ){
101098 return 0;
101100 pList = pExpr->x.pList;
101101 if( pList->nExpr!=2 ){
101102 return 0;
101104 if( pList->a[1].pExpr->op != TK_COLUMN ){
101105 return 0;
101107 return 1;
101109 #endif /* SQLITE_OMIT_VIRTUALTABLE */
101112 ** If the pBase expression originated in the ON or USING clause of
101113 ** a join, then transfer the appropriate markings over to derived.
101115 static void transferJoinMarkings(Expr *pDerived, Expr *pBase){
101116 pDerived->flags |= pBase->flags & EP_FromJoin;
101117 pDerived->iRightJoinTable = pBase->iRightJoinTable;
101120 #if !defined(SQLITE_OMIT_OR_OPTIMIZATION) && !defined(SQLITE_OMIT_SUBQUERY)
101122 ** Analyze a term that consists of two or more OR-connected
101123 ** subterms. So in:
101125 ** ... WHERE (a=5) AND (b=7 OR c=9 OR d=13) AND (d=13)
101126 ** ^^^^^^^^^^^^^^^^^^^^
101128 ** This routine analyzes terms such as the middle term in the above example.
101129 ** A WhereOrTerm object is computed and attached to the term under
101130 ** analysis, regardless of the outcome of the analysis. Hence:
101132 ** WhereTerm.wtFlags |= TERM_ORINFO
101133 ** WhereTerm.u.pOrInfo = a dynamically allocated WhereOrTerm object
101135 ** The term being analyzed must have two or more of OR-connected subterms.
101136 ** A single subterm might be a set of AND-connected sub-subterms.
101137 ** Examples of terms under analysis:
101139 ** (A) t1.x=t2.y OR t1.x=t2.z OR t1.y=15 OR t1.z=t3.a+5
101140 ** (B) x=expr1 OR expr2=x OR x=expr3
101141 ** (C) t1.x=t2.y OR (t1.x=t2.z AND t1.y=15)
101142 ** (D) x=expr1 OR (y>11 AND y<22 AND z LIKE '*hello*')
101143 ** (E) (p.a=1 AND q.b=2 AND r.c=3) OR (p.x=4 AND q.y=5 AND r.z=6)
101145 ** CASE 1:
101147 ** If all subterms are of the form T.C=expr for some single column of C
101148 ** a single table T (as shown in example B above) then create a new virtual
101149 ** term that is an equivalent IN expression. In other words, if the term
101150 ** being analyzed is:
101152 ** x = expr1 OR expr2 = x OR x = expr3
101154 ** then create a new virtual term like this:
101156 ** x IN (expr1,expr2,expr3)
101158 ** CASE 2:
101160 ** If all subterms are indexable by a single table T, then set
101162 ** WhereTerm.eOperator = WO_OR
101163 ** WhereTerm.u.pOrInfo->indexable |= the cursor number for table T
101165 ** A subterm is "indexable" if it is of the form
101166 ** "T.C <op> <expr>" where C is any column of table T and
101167 ** <op> is one of "=", "<", "<=", ">", ">=", "IS NULL", or "IN".
101168 ** A subterm is also indexable if it is an AND of two or more
101169 ** subsubterms at least one of which is indexable. Indexable AND
101170 ** subterms have their eOperator set to WO_AND and they have
101171 ** u.pAndInfo set to a dynamically allocated WhereAndTerm object.
101173 ** From another point of view, "indexable" means that the subterm could
101174 ** potentially be used with an index if an appropriate index exists.
101175 ** This analysis does not consider whether or not the index exists; that
101176 ** is something the bestIndex() routine will determine. This analysis
101177 ** only looks at whether subterms appropriate for indexing exist.
101179 ** All examples A through E above all satisfy case 2. But if a term
101180 ** also statisfies case 1 (such as B) we know that the optimizer will
101181 ** always prefer case 1, so in that case we pretend that case 2 is not
101182 ** satisfied.
101184 ** It might be the case that multiple tables are indexable. For example,
101185 ** (E) above is indexable on tables P, Q, and R.
101187 ** Terms that satisfy case 2 are candidates for lookup by using
101188 ** separate indices to find rowids for each subterm and composing
101189 ** the union of all rowids using a RowSet object. This is similar
101190 ** to "bitmap indices" in other database engines.
101192 ** OTHERWISE:
101194 ** If neither case 1 nor case 2 apply, then leave the eOperator set to
101195 ** zero. This term is not useful for search.
101197 static void exprAnalyzeOrTerm(
101198 SrcList *pSrc, /* the FROM clause */
101199 WhereClause *pWC, /* the complete WHERE clause */
101200 int idxTerm /* Index of the OR-term to be analyzed */
101202 Parse *pParse = pWC->pParse; /* Parser context */
101203 sqlite3 *db = pParse->db; /* Database connection */
101204 WhereTerm *pTerm = &pWC->a[idxTerm]; /* The term to be analyzed */
101205 Expr *pExpr = pTerm->pExpr; /* The expression of the term */
101206 WhereMaskSet *pMaskSet = pWC->pMaskSet; /* Table use masks */
101207 int i; /* Loop counters */
101208 WhereClause *pOrWc; /* Breakup of pTerm into subterms */
101209 WhereTerm *pOrTerm; /* A Sub-term within the pOrWc */
101210 WhereOrInfo *pOrInfo; /* Additional information associated with pTerm */
101211 Bitmask chngToIN; /* Tables that might satisfy case 1 */
101212 Bitmask indexable; /* Tables that are indexable, satisfying case 2 */
101215 ** Break the OR clause into its separate subterms. The subterms are
101216 ** stored in a WhereClause structure containing within the WhereOrInfo
101217 ** object that is attached to the original OR clause term.
101219 assert( (pTerm->wtFlags & (TERM_DYNAMIC|TERM_ORINFO|TERM_ANDINFO))==0 );
101220 assert( pExpr->op==TK_OR );
101221 pTerm->u.pOrInfo = pOrInfo = sqlite3DbMallocZero(db, sizeof(*pOrInfo));
101222 if( pOrInfo==0 ) return;
101223 pTerm->wtFlags |= TERM_ORINFO;
101224 pOrWc = &pOrInfo->wc;
101225 whereClauseInit(pOrWc, pWC->pParse, pMaskSet);
101226 whereSplit(pOrWc, pExpr, TK_OR);
101227 exprAnalyzeAll(pSrc, pOrWc);
101228 if( db->mallocFailed ) return;
101229 assert( pOrWc->nTerm>=2 );
101232 ** Compute the set of tables that might satisfy cases 1 or 2.
101234 indexable = ~(Bitmask)0;
101235 chngToIN = ~(pWC->vmask);
101236 for(i=pOrWc->nTerm-1, pOrTerm=pOrWc->a; i>=0 && indexable; i--, pOrTerm++){
101237 if( (pOrTerm->eOperator & WO_SINGLE)==0 ){
101238 WhereAndInfo *pAndInfo;
101239 assert( pOrTerm->eOperator==0 );
101240 assert( (pOrTerm->wtFlags & (TERM_ANDINFO|TERM_ORINFO))==0 );
101241 chngToIN = 0;
101242 pAndInfo = sqlite3DbMallocRaw(db, sizeof(*pAndInfo));
101243 if( pAndInfo ){
101244 WhereClause *pAndWC;
101245 WhereTerm *pAndTerm;
101246 int j;
101247 Bitmask b = 0;
101248 pOrTerm->u.pAndInfo = pAndInfo;
101249 pOrTerm->wtFlags |= TERM_ANDINFO;
101250 pOrTerm->eOperator = WO_AND;
101251 pAndWC = &pAndInfo->wc;
101252 whereClauseInit(pAndWC, pWC->pParse, pMaskSet);
101253 whereSplit(pAndWC, pOrTerm->pExpr, TK_AND);
101254 exprAnalyzeAll(pSrc, pAndWC);
101255 testcase( db->mallocFailed );
101256 if( !db->mallocFailed ){
101257 for(j=0, pAndTerm=pAndWC->a; j<pAndWC->nTerm; j++, pAndTerm++){
101258 assert( pAndTerm->pExpr );
101259 if( allowedOp(pAndTerm->pExpr->op) ){
101260 b |= getMask(pMaskSet, pAndTerm->leftCursor);
101264 indexable &= b;
101266 }else if( pOrTerm->wtFlags & TERM_COPIED ){
101267 /* Skip this term for now. We revisit it when we process the
101268 ** corresponding TERM_VIRTUAL term */
101269 }else{
101270 Bitmask b;
101271 b = getMask(pMaskSet, pOrTerm->leftCursor);
101272 if( pOrTerm->wtFlags & TERM_VIRTUAL ){
101273 WhereTerm *pOther = &pOrWc->a[pOrTerm->iParent];
101274 b |= getMask(pMaskSet, pOther->leftCursor);
101276 indexable &= b;
101277 if( pOrTerm->eOperator!=WO_EQ ){
101278 chngToIN = 0;
101279 }else{
101280 chngToIN &= b;
101286 ** Record the set of tables that satisfy case 2. The set might be
101287 ** empty.
101289 pOrInfo->indexable = indexable;
101290 pTerm->eOperator = indexable==0 ? 0 : WO_OR;
101293 ** chngToIN holds a set of tables that *might* satisfy case 1. But
101294 ** we have to do some additional checking to see if case 1 really
101295 ** is satisfied.
101297 ** chngToIN will hold either 0, 1, or 2 bits. The 0-bit case means
101298 ** that there is no possibility of transforming the OR clause into an
101299 ** IN operator because one or more terms in the OR clause contain
101300 ** something other than == on a column in the single table. The 1-bit
101301 ** case means that every term of the OR clause is of the form
101302 ** "table.column=expr" for some single table. The one bit that is set
101303 ** will correspond to the common table. We still need to check to make
101304 ** sure the same column is used on all terms. The 2-bit case is when
101305 ** the all terms are of the form "table1.column=table2.column". It
101306 ** might be possible to form an IN operator with either table1.column
101307 ** or table2.column as the LHS if either is common to every term of
101308 ** the OR clause.
101310 ** Note that terms of the form "table.column1=table.column2" (the
101311 ** same table on both sizes of the ==) cannot be optimized.
101313 if( chngToIN ){
101314 int okToChngToIN = 0; /* True if the conversion to IN is valid */
101315 int iColumn = -1; /* Column index on lhs of IN operator */
101316 int iCursor = -1; /* Table cursor common to all terms */
101317 int j = 0; /* Loop counter */
101319 /* Search for a table and column that appears on one side or the
101320 ** other of the == operator in every subterm. That table and column
101321 ** will be recorded in iCursor and iColumn. There might not be any
101322 ** such table and column. Set okToChngToIN if an appropriate table
101323 ** and column is found but leave okToChngToIN false if not found.
101325 for(j=0; j<2 && !okToChngToIN; j++){
101326 pOrTerm = pOrWc->a;
101327 for(i=pOrWc->nTerm-1; i>=0; i--, pOrTerm++){
101328 assert( pOrTerm->eOperator==WO_EQ );
101329 pOrTerm->wtFlags &= ~TERM_OR_OK;
101330 if( pOrTerm->leftCursor==iCursor ){
101331 /* This is the 2-bit case and we are on the second iteration and
101332 ** current term is from the first iteration. So skip this term. */
101333 assert( j==1 );
101334 continue;
101336 if( (chngToIN & getMask(pMaskSet, pOrTerm->leftCursor))==0 ){
101337 /* This term must be of the form t1.a==t2.b where t2 is in the
101338 ** chngToIN set but t1 is not. This term will be either preceeded
101339 ** or follwed by an inverted copy (t2.b==t1.a). Skip this term
101340 ** and use its inversion. */
101341 testcase( pOrTerm->wtFlags & TERM_COPIED );
101342 testcase( pOrTerm->wtFlags & TERM_VIRTUAL );
101343 assert( pOrTerm->wtFlags & (TERM_COPIED|TERM_VIRTUAL) );
101344 continue;
101346 iColumn = pOrTerm->u.leftColumn;
101347 iCursor = pOrTerm->leftCursor;
101348 break;
101350 if( i<0 ){
101351 /* No candidate table+column was found. This can only occur
101352 ** on the second iteration */
101353 assert( j==1 );
101354 assert( (chngToIN&(chngToIN-1))==0 );
101355 assert( chngToIN==getMask(pMaskSet, iCursor) );
101356 break;
101358 testcase( j==1 );
101360 /* We have found a candidate table and column. Check to see if that
101361 ** table and column is common to every term in the OR clause */
101362 okToChngToIN = 1;
101363 for(; i>=0 && okToChngToIN; i--, pOrTerm++){
101364 assert( pOrTerm->eOperator==WO_EQ );
101365 if( pOrTerm->leftCursor!=iCursor ){
101366 pOrTerm->wtFlags &= ~TERM_OR_OK;
101367 }else if( pOrTerm->u.leftColumn!=iColumn ){
101368 okToChngToIN = 0;
101369 }else{
101370 int affLeft, affRight;
101371 /* If the right-hand side is also a column, then the affinities
101372 ** of both right and left sides must be such that no type
101373 ** conversions are required on the right. (Ticket #2249)
101375 affRight = sqlite3ExprAffinity(pOrTerm->pExpr->pRight);
101376 affLeft = sqlite3ExprAffinity(pOrTerm->pExpr->pLeft);
101377 if( affRight!=0 && affRight!=affLeft ){
101378 okToChngToIN = 0;
101379 }else{
101380 pOrTerm->wtFlags |= TERM_OR_OK;
101386 /* At this point, okToChngToIN is true if original pTerm satisfies
101387 ** case 1. In that case, construct a new virtual term that is
101388 ** pTerm converted into an IN operator.
101390 ** EV: R-00211-15100
101392 if( okToChngToIN ){
101393 Expr *pDup; /* A transient duplicate expression */
101394 ExprList *pList = 0; /* The RHS of the IN operator */
101395 Expr *pLeft = 0; /* The LHS of the IN operator */
101396 Expr *pNew; /* The complete IN operator */
101398 for(i=pOrWc->nTerm-1, pOrTerm=pOrWc->a; i>=0; i--, pOrTerm++){
101399 if( (pOrTerm->wtFlags & TERM_OR_OK)==0 ) continue;
101400 assert( pOrTerm->eOperator==WO_EQ );
101401 assert( pOrTerm->leftCursor==iCursor );
101402 assert( pOrTerm->u.leftColumn==iColumn );
101403 pDup = sqlite3ExprDup(db, pOrTerm->pExpr->pRight, 0);
101404 pList = sqlite3ExprListAppend(pWC->pParse, pList, pDup);
101405 pLeft = pOrTerm->pExpr->pLeft;
101407 assert( pLeft!=0 );
101408 pDup = sqlite3ExprDup(db, pLeft, 0);
101409 pNew = sqlite3PExpr(pParse, TK_IN, pDup, 0, 0);
101410 if( pNew ){
101411 int idxNew;
101412 transferJoinMarkings(pNew, pExpr);
101413 assert( !ExprHasProperty(pNew, EP_xIsSelect) );
101414 pNew->x.pList = pList;
101415 idxNew = whereClauseInsert(pWC, pNew, TERM_VIRTUAL|TERM_DYNAMIC);
101416 testcase( idxNew==0 );
101417 exprAnalyze(pSrc, pWC, idxNew);
101418 pTerm = &pWC->a[idxTerm];
101419 pWC->a[idxNew].iParent = idxTerm;
101420 pTerm->nChild = 1;
101421 }else{
101422 sqlite3ExprListDelete(db, pList);
101424 pTerm->eOperator = WO_NOOP; /* case 1 trumps case 2 */
101428 #endif /* !SQLITE_OMIT_OR_OPTIMIZATION && !SQLITE_OMIT_SUBQUERY */
101432 ** The input to this routine is an WhereTerm structure with only the
101433 ** "pExpr" field filled in. The job of this routine is to analyze the
101434 ** subexpression and populate all the other fields of the WhereTerm
101435 ** structure.
101437 ** If the expression is of the form "<expr> <op> X" it gets commuted
101438 ** to the standard form of "X <op> <expr>".
101440 ** If the expression is of the form "X <op> Y" where both X and Y are
101441 ** columns, then the original expression is unchanged and a new virtual
101442 ** term of the form "Y <op> X" is added to the WHERE clause and
101443 ** analyzed separately. The original term is marked with TERM_COPIED
101444 ** and the new term is marked with TERM_DYNAMIC (because it's pExpr
101445 ** needs to be freed with the WhereClause) and TERM_VIRTUAL (because it
101446 ** is a commuted copy of a prior term.) The original term has nChild=1
101447 ** and the copy has idxParent set to the index of the original term.
101449 static void exprAnalyze(
101450 SrcList *pSrc, /* the FROM clause */
101451 WhereClause *pWC, /* the WHERE clause */
101452 int idxTerm /* Index of the term to be analyzed */
101454 WhereTerm *pTerm; /* The term to be analyzed */
101455 WhereMaskSet *pMaskSet; /* Set of table index masks */
101456 Expr *pExpr; /* The expression to be analyzed */
101457 Bitmask prereqLeft; /* Prerequesites of the pExpr->pLeft */
101458 Bitmask prereqAll; /* Prerequesites of pExpr */
101459 Bitmask extraRight = 0; /* Extra dependencies on LEFT JOIN */
101460 Expr *pStr1 = 0; /* RHS of LIKE/GLOB operator */
101461 int isComplete = 0; /* RHS of LIKE/GLOB ends with wildcard */
101462 int noCase = 0; /* LIKE/GLOB distinguishes case */
101463 int op; /* Top-level operator. pExpr->op */
101464 Parse *pParse = pWC->pParse; /* Parsing context */
101465 sqlite3 *db = pParse->db; /* Database connection */
101467 if( db->mallocFailed ){
101468 return;
101470 pTerm = &pWC->a[idxTerm];
101471 pMaskSet = pWC->pMaskSet;
101472 pExpr = pTerm->pExpr;
101473 prereqLeft = exprTableUsage(pMaskSet, pExpr->pLeft);
101474 op = pExpr->op;
101475 if( op==TK_IN ){
101476 assert( pExpr->pRight==0 );
101477 if( ExprHasProperty(pExpr, EP_xIsSelect) ){
101478 pTerm->prereqRight = exprSelectTableUsage(pMaskSet, pExpr->x.pSelect);
101479 }else{
101480 pTerm->prereqRight = exprListTableUsage(pMaskSet, pExpr->x.pList);
101482 }else if( op==TK_ISNULL ){
101483 pTerm->prereqRight = 0;
101484 }else{
101485 pTerm->prereqRight = exprTableUsage(pMaskSet, pExpr->pRight);
101487 prereqAll = exprTableUsage(pMaskSet, pExpr);
101488 if( ExprHasProperty(pExpr, EP_FromJoin) ){
101489 Bitmask x = getMask(pMaskSet, pExpr->iRightJoinTable);
101490 prereqAll |= x;
101491 extraRight = x-1; /* ON clause terms may not be used with an index
101492 ** on left table of a LEFT JOIN. Ticket #3015 */
101494 pTerm->prereqAll = prereqAll;
101495 pTerm->leftCursor = -1;
101496 pTerm->iParent = -1;
101497 pTerm->eOperator = 0;
101498 if( allowedOp(op) && (pTerm->prereqRight & prereqLeft)==0 ){
101499 Expr *pLeft = pExpr->pLeft;
101500 Expr *pRight = pExpr->pRight;
101501 if( pLeft->op==TK_COLUMN ){
101502 pTerm->leftCursor = pLeft->iTable;
101503 pTerm->u.leftColumn = pLeft->iColumn;
101504 pTerm->eOperator = operatorMask(op);
101506 if( pRight && pRight->op==TK_COLUMN ){
101507 WhereTerm *pNew;
101508 Expr *pDup;
101509 if( pTerm->leftCursor>=0 ){
101510 int idxNew;
101511 pDup = sqlite3ExprDup(db, pExpr, 0);
101512 if( db->mallocFailed ){
101513 sqlite3ExprDelete(db, pDup);
101514 return;
101516 idxNew = whereClauseInsert(pWC, pDup, TERM_VIRTUAL|TERM_DYNAMIC);
101517 if( idxNew==0 ) return;
101518 pNew = &pWC->a[idxNew];
101519 pNew->iParent = idxTerm;
101520 pTerm = &pWC->a[idxTerm];
101521 pTerm->nChild = 1;
101522 pTerm->wtFlags |= TERM_COPIED;
101523 }else{
101524 pDup = pExpr;
101525 pNew = pTerm;
101527 exprCommute(pParse, pDup);
101528 pLeft = pDup->pLeft;
101529 pNew->leftCursor = pLeft->iTable;
101530 pNew->u.leftColumn = pLeft->iColumn;
101531 testcase( (prereqLeft | extraRight) != prereqLeft );
101532 pNew->prereqRight = prereqLeft | extraRight;
101533 pNew->prereqAll = prereqAll;
101534 pNew->eOperator = operatorMask(pDup->op);
101538 #ifndef SQLITE_OMIT_BETWEEN_OPTIMIZATION
101539 /* If a term is the BETWEEN operator, create two new virtual terms
101540 ** that define the range that the BETWEEN implements. For example:
101542 ** a BETWEEN b AND c
101544 ** is converted into:
101546 ** (a BETWEEN b AND c) AND (a>=b) AND (a<=c)
101548 ** The two new terms are added onto the end of the WhereClause object.
101549 ** The new terms are "dynamic" and are children of the original BETWEEN
101550 ** term. That means that if the BETWEEN term is coded, the children are
101551 ** skipped. Or, if the children are satisfied by an index, the original
101552 ** BETWEEN term is skipped.
101554 else if( pExpr->op==TK_BETWEEN && pWC->op==TK_AND ){
101555 ExprList *pList = pExpr->x.pList;
101556 int i;
101557 static const u8 ops[] = {TK_GE, TK_LE};
101558 assert( pList!=0 );
101559 assert( pList->nExpr==2 );
101560 for(i=0; i<2; i++){
101561 Expr *pNewExpr;
101562 int idxNew;
101563 pNewExpr = sqlite3PExpr(pParse, ops[i],
101564 sqlite3ExprDup(db, pExpr->pLeft, 0),
101565 sqlite3ExprDup(db, pList->a[i].pExpr, 0), 0);
101566 idxNew = whereClauseInsert(pWC, pNewExpr, TERM_VIRTUAL|TERM_DYNAMIC);
101567 testcase( idxNew==0 );
101568 exprAnalyze(pSrc, pWC, idxNew);
101569 pTerm = &pWC->a[idxTerm];
101570 pWC->a[idxNew].iParent = idxTerm;
101572 pTerm->nChild = 2;
101574 #endif /* SQLITE_OMIT_BETWEEN_OPTIMIZATION */
101576 #if !defined(SQLITE_OMIT_OR_OPTIMIZATION) && !defined(SQLITE_OMIT_SUBQUERY)
101577 /* Analyze a term that is composed of two or more subterms connected by
101578 ** an OR operator.
101580 else if( pExpr->op==TK_OR ){
101581 assert( pWC->op==TK_AND );
101582 exprAnalyzeOrTerm(pSrc, pWC, idxTerm);
101583 pTerm = &pWC->a[idxTerm];
101585 #endif /* SQLITE_OMIT_OR_OPTIMIZATION */
101587 #ifndef SQLITE_OMIT_LIKE_OPTIMIZATION
101588 /* Add constraints to reduce the search space on a LIKE or GLOB
101589 ** operator.
101591 ** A like pattern of the form "x LIKE 'abc%'" is changed into constraints
101593 ** x>='abc' AND x<'abd' AND x LIKE 'abc%'
101595 ** The last character of the prefix "abc" is incremented to form the
101596 ** termination condition "abd".
101598 if( pWC->op==TK_AND
101599 && isLikeOrGlob(pParse, pExpr, &pStr1, &isComplete, &noCase)
101601 Expr *pLeft; /* LHS of LIKE/GLOB operator */
101602 Expr *pStr2; /* Copy of pStr1 - RHS of LIKE/GLOB operator */
101603 Expr *pNewExpr1;
101604 Expr *pNewExpr2;
101605 int idxNew1;
101606 int idxNew2;
101607 CollSeq *pColl; /* Collating sequence to use */
101609 pLeft = pExpr->x.pList->a[1].pExpr;
101610 pStr2 = sqlite3ExprDup(db, pStr1, 0);
101611 if( !db->mallocFailed ){
101612 u8 c, *pC; /* Last character before the first wildcard */
101613 pC = (u8*)&pStr2->u.zToken[sqlite3Strlen30(pStr2->u.zToken)-1];
101614 c = *pC;
101615 if( noCase ){
101616 /* The point is to increment the last character before the first
101617 ** wildcard. But if we increment '@', that will push it into the
101618 ** alphabetic range where case conversions will mess up the
101619 ** inequality. To avoid this, make sure to also run the full
101620 ** LIKE on all candidate expressions by clearing the isComplete flag
101622 if( c=='A'-1 ) isComplete = 0; /* EV: R-64339-08207 */
101625 c = sqlite3UpperToLower[c];
101627 *pC = c + 1;
101629 pColl = sqlite3FindCollSeq(db, SQLITE_UTF8, noCase ? "NOCASE" : "BINARY",0);
101630 pNewExpr1 = sqlite3PExpr(pParse, TK_GE,
101631 sqlite3ExprSetColl(sqlite3ExprDup(db,pLeft,0), pColl),
101632 pStr1, 0);
101633 idxNew1 = whereClauseInsert(pWC, pNewExpr1, TERM_VIRTUAL|TERM_DYNAMIC);
101634 testcase( idxNew1==0 );
101635 exprAnalyze(pSrc, pWC, idxNew1);
101636 pNewExpr2 = sqlite3PExpr(pParse, TK_LT,
101637 sqlite3ExprSetColl(sqlite3ExprDup(db,pLeft,0), pColl),
101638 pStr2, 0);
101639 idxNew2 = whereClauseInsert(pWC, pNewExpr2, TERM_VIRTUAL|TERM_DYNAMIC);
101640 testcase( idxNew2==0 );
101641 exprAnalyze(pSrc, pWC, idxNew2);
101642 pTerm = &pWC->a[idxTerm];
101643 if( isComplete ){
101644 pWC->a[idxNew1].iParent = idxTerm;
101645 pWC->a[idxNew2].iParent = idxTerm;
101646 pTerm->nChild = 2;
101649 #endif /* SQLITE_OMIT_LIKE_OPTIMIZATION */
101651 #ifndef SQLITE_OMIT_VIRTUALTABLE
101652 /* Add a WO_MATCH auxiliary term to the constraint set if the
101653 ** current expression is of the form: column MATCH expr.
101654 ** This information is used by the xBestIndex methods of
101655 ** virtual tables. The native query optimizer does not attempt
101656 ** to do anything with MATCH functions.
101658 if( isMatchOfColumn(pExpr) ){
101659 int idxNew;
101660 Expr *pRight, *pLeft;
101661 WhereTerm *pNewTerm;
101662 Bitmask prereqColumn, prereqExpr;
101664 pRight = pExpr->x.pList->a[0].pExpr;
101665 pLeft = pExpr->x.pList->a[1].pExpr;
101666 prereqExpr = exprTableUsage(pMaskSet, pRight);
101667 prereqColumn = exprTableUsage(pMaskSet, pLeft);
101668 if( (prereqExpr & prereqColumn)==0 ){
101669 Expr *pNewExpr;
101670 pNewExpr = sqlite3PExpr(pParse, TK_MATCH,
101671 0, sqlite3ExprDup(db, pRight, 0), 0);
101672 idxNew = whereClauseInsert(pWC, pNewExpr, TERM_VIRTUAL|TERM_DYNAMIC);
101673 testcase( idxNew==0 );
101674 pNewTerm = &pWC->a[idxNew];
101675 pNewTerm->prereqRight = prereqExpr;
101676 pNewTerm->leftCursor = pLeft->iTable;
101677 pNewTerm->u.leftColumn = pLeft->iColumn;
101678 pNewTerm->eOperator = WO_MATCH;
101679 pNewTerm->iParent = idxTerm;
101680 pTerm = &pWC->a[idxTerm];
101681 pTerm->nChild = 1;
101682 pTerm->wtFlags |= TERM_COPIED;
101683 pNewTerm->prereqAll = pTerm->prereqAll;
101686 #endif /* SQLITE_OMIT_VIRTUALTABLE */
101688 #ifdef SQLITE_ENABLE_STAT2
101689 /* When sqlite_stat2 histogram data is available an operator of the
101690 ** form "x IS NOT NULL" can sometimes be evaluated more efficiently
101691 ** as "x>NULL" if x is not an INTEGER PRIMARY KEY. So construct a
101692 ** virtual term of that form.
101694 ** Note that the virtual term must be tagged with TERM_VNULL. This
101695 ** TERM_VNULL tag will suppress the not-null check at the beginning
101696 ** of the loop. Without the TERM_VNULL flag, the not-null check at
101697 ** the start of the loop will prevent any results from being returned.
101699 if( pExpr->op==TK_NOTNULL
101700 && pExpr->pLeft->op==TK_COLUMN
101701 && pExpr->pLeft->iColumn>=0
101703 Expr *pNewExpr;
101704 Expr *pLeft = pExpr->pLeft;
101705 int idxNew;
101706 WhereTerm *pNewTerm;
101708 pNewExpr = sqlite3PExpr(pParse, TK_GT,
101709 sqlite3ExprDup(db, pLeft, 0),
101710 sqlite3PExpr(pParse, TK_NULL, 0, 0, 0), 0);
101712 idxNew = whereClauseInsert(pWC, pNewExpr,
101713 TERM_VIRTUAL|TERM_DYNAMIC|TERM_VNULL);
101714 if( idxNew ){
101715 pNewTerm = &pWC->a[idxNew];
101716 pNewTerm->prereqRight = 0;
101717 pNewTerm->leftCursor = pLeft->iTable;
101718 pNewTerm->u.leftColumn = pLeft->iColumn;
101719 pNewTerm->eOperator = WO_GT;
101720 pNewTerm->iParent = idxTerm;
101721 pTerm = &pWC->a[idxTerm];
101722 pTerm->nChild = 1;
101723 pTerm->wtFlags |= TERM_COPIED;
101724 pNewTerm->prereqAll = pTerm->prereqAll;
101727 #endif /* SQLITE_ENABLE_STAT2 */
101729 /* Prevent ON clause terms of a LEFT JOIN from being used to drive
101730 ** an index for tables to the left of the join.
101732 pTerm->prereqRight |= extraRight;
101736 ** Return TRUE if any of the expressions in pList->a[iFirst...] contain
101737 ** a reference to any table other than the iBase table.
101739 static int referencesOtherTables(
101740 ExprList *pList, /* Search expressions in ths list */
101741 WhereMaskSet *pMaskSet, /* Mapping from tables to bitmaps */
101742 int iFirst, /* Be searching with the iFirst-th expression */
101743 int iBase /* Ignore references to this table */
101745 Bitmask allowed = ~getMask(pMaskSet, iBase);
101746 while( iFirst<pList->nExpr ){
101747 if( (exprTableUsage(pMaskSet, pList->a[iFirst++].pExpr)&allowed)!=0 ){
101748 return 1;
101751 return 0;
101755 ** This function searches the expression list passed as the second argument
101756 ** for an expression of type TK_COLUMN that refers to the same column and
101757 ** uses the same collation sequence as the iCol'th column of index pIdx.
101758 ** Argument iBase is the cursor number used for the table that pIdx refers
101759 ** to.
101761 ** If such an expression is found, its index in pList->a[] is returned. If
101762 ** no expression is found, -1 is returned.
101764 static int findIndexCol(
101765 Parse *pParse, /* Parse context */
101766 ExprList *pList, /* Expression list to search */
101767 int iBase, /* Cursor for table associated with pIdx */
101768 Index *pIdx, /* Index to match column of */
101769 int iCol /* Column of index to match */
101771 int i;
101772 const char *zColl = pIdx->azColl[iCol];
101774 for(i=0; i<pList->nExpr; i++){
101775 Expr *p = pList->a[i].pExpr;
101776 if( p->op==TK_COLUMN
101777 && p->iColumn==pIdx->aiColumn[iCol]
101778 && p->iTable==iBase
101780 CollSeq *pColl = sqlite3ExprCollSeq(pParse, p);
101781 if( ALWAYS(pColl) && 0==sqlite3StrICmp(pColl->zName, zColl) ){
101782 return i;
101787 return -1;
101791 ** This routine determines if pIdx can be used to assist in processing a
101792 ** DISTINCT qualifier. In other words, it tests whether or not using this
101793 ** index for the outer loop guarantees that rows with equal values for
101794 ** all expressions in the pDistinct list are delivered grouped together.
101796 ** For example, the query
101798 ** SELECT DISTINCT a, b, c FROM tbl WHERE a = ?
101800 ** can benefit from any index on columns "b" and "c".
101802 static int isDistinctIndex(
101803 Parse *pParse, /* Parsing context */
101804 WhereClause *pWC, /* The WHERE clause */
101805 Index *pIdx, /* The index being considered */
101806 int base, /* Cursor number for the table pIdx is on */
101807 ExprList *pDistinct, /* The DISTINCT expressions */
101808 int nEqCol /* Number of index columns with == */
101810 Bitmask mask = 0; /* Mask of unaccounted for pDistinct exprs */
101811 int i; /* Iterator variable */
101813 if( pIdx->zName==0 || pDistinct==0 || pDistinct->nExpr>=BMS ) return 0;
101814 testcase( pDistinct->nExpr==BMS-1 );
101816 /* Loop through all the expressions in the distinct list. If any of them
101817 ** are not simple column references, return early. Otherwise, test if the
101818 ** WHERE clause contains a "col=X" clause. If it does, the expression
101819 ** can be ignored. If it does not, and the column does not belong to the
101820 ** same table as index pIdx, return early. Finally, if there is no
101821 ** matching "col=X" expression and the column is on the same table as pIdx,
101822 ** set the corresponding bit in variable mask.
101824 for(i=0; i<pDistinct->nExpr; i++){
101825 WhereTerm *pTerm;
101826 Expr *p = pDistinct->a[i].pExpr;
101827 if( p->op!=TK_COLUMN ) return 0;
101828 pTerm = findTerm(pWC, p->iTable, p->iColumn, ~(Bitmask)0, WO_EQ, 0);
101829 if( pTerm ){
101830 Expr *pX = pTerm->pExpr;
101831 CollSeq *p1 = sqlite3BinaryCompareCollSeq(pParse, pX->pLeft, pX->pRight);
101832 CollSeq *p2 = sqlite3ExprCollSeq(pParse, p);
101833 if( p1==p2 ) continue;
101835 if( p->iTable!=base ) return 0;
101836 mask |= (((Bitmask)1) << i);
101839 for(i=nEqCol; mask && i<pIdx->nColumn; i++){
101840 int iExpr = findIndexCol(pParse, pDistinct, base, pIdx, i);
101841 if( iExpr<0 ) break;
101842 mask &= ~(((Bitmask)1) << iExpr);
101845 return (mask==0);
101850 ** Return true if the DISTINCT expression-list passed as the third argument
101851 ** is redundant. A DISTINCT list is redundant if the database contains a
101852 ** UNIQUE index that guarantees that the result of the query will be distinct
101853 ** anyway.
101855 static int isDistinctRedundant(
101856 Parse *pParse,
101857 SrcList *pTabList,
101858 WhereClause *pWC,
101859 ExprList *pDistinct
101861 Table *pTab;
101862 Index *pIdx;
101863 int i;
101864 int iBase;
101866 /* If there is more than one table or sub-select in the FROM clause of
101867 ** this query, then it will not be possible to show that the DISTINCT
101868 ** clause is redundant. */
101869 if( pTabList->nSrc!=1 ) return 0;
101870 iBase = pTabList->a[0].iCursor;
101871 pTab = pTabList->a[0].pTab;
101873 /* If any of the expressions is an IPK column on table iBase, then return
101874 ** true. Note: The (p->iTable==iBase) part of this test may be false if the
101875 ** current SELECT is a correlated sub-query.
101877 for(i=0; i<pDistinct->nExpr; i++){
101878 Expr *p = pDistinct->a[i].pExpr;
101879 if( p->op==TK_COLUMN && p->iTable==iBase && p->iColumn<0 ) return 1;
101882 /* Loop through all indices on the table, checking each to see if it makes
101883 ** the DISTINCT qualifier redundant. It does so if:
101885 ** 1. The index is itself UNIQUE, and
101887 ** 2. All of the columns in the index are either part of the pDistinct
101888 ** list, or else the WHERE clause contains a term of the form "col=X",
101889 ** where X is a constant value. The collation sequences of the
101890 ** comparison and select-list expressions must match those of the index.
101892 for(pIdx=pTab->pIndex; pIdx; pIdx=pIdx->pNext){
101893 if( pIdx->onError==OE_None ) continue;
101894 for(i=0; i<pIdx->nColumn; i++){
101895 int iCol = pIdx->aiColumn[i];
101896 if( 0==findTerm(pWC, iBase, iCol, ~(Bitmask)0, WO_EQ, pIdx)
101897 && 0>findIndexCol(pParse, pDistinct, iBase, pIdx, i)
101899 break;
101902 if( i==pIdx->nColumn ){
101903 /* This index implies that the DISTINCT qualifier is redundant. */
101904 return 1;
101908 return 0;
101912 ** This routine decides if pIdx can be used to satisfy the ORDER BY
101913 ** clause. If it can, it returns 1. If pIdx cannot satisfy the
101914 ** ORDER BY clause, this routine returns 0.
101916 ** pOrderBy is an ORDER BY clause from a SELECT statement. pTab is the
101917 ** left-most table in the FROM clause of that same SELECT statement and
101918 ** the table has a cursor number of "base". pIdx is an index on pTab.
101920 ** nEqCol is the number of columns of pIdx that are used as equality
101921 ** constraints. Any of these columns may be missing from the ORDER BY
101922 ** clause and the match can still be a success.
101924 ** All terms of the ORDER BY that match against the index must be either
101925 ** ASC or DESC. (Terms of the ORDER BY clause past the end of a UNIQUE
101926 ** index do not need to satisfy this constraint.) The *pbRev value is
101927 ** set to 1 if the ORDER BY clause is all DESC and it is set to 0 if
101928 ** the ORDER BY clause is all ASC.
101930 static int isSortingIndex(
101931 Parse *pParse, /* Parsing context */
101932 WhereMaskSet *pMaskSet, /* Mapping from table cursor numbers to bitmaps */
101933 Index *pIdx, /* The index we are testing */
101934 int base, /* Cursor number for the table to be sorted */
101935 ExprList *pOrderBy, /* The ORDER BY clause */
101936 int nEqCol, /* Number of index columns with == constraints */
101937 int wsFlags, /* Index usages flags */
101938 int *pbRev /* Set to 1 if ORDER BY is DESC */
101940 int i, j; /* Loop counters */
101941 int sortOrder = 0; /* XOR of index and ORDER BY sort direction */
101942 int nTerm; /* Number of ORDER BY terms */
101943 struct ExprList_item *pTerm; /* A term of the ORDER BY clause */
101944 sqlite3 *db = pParse->db;
101946 if( !pOrderBy ) return 0;
101947 if( wsFlags & WHERE_COLUMN_IN ) return 0;
101948 if( pIdx->bUnordered ) return 0;
101950 nTerm = pOrderBy->nExpr;
101951 assert( nTerm>0 );
101953 /* Argument pIdx must either point to a 'real' named index structure,
101954 ** or an index structure allocated on the stack by bestBtreeIndex() to
101955 ** represent the rowid index that is part of every table. */
101956 assert( pIdx->zName || (pIdx->nColumn==1 && pIdx->aiColumn[0]==-1) );
101958 /* Match terms of the ORDER BY clause against columns of
101959 ** the index.
101961 ** Note that indices have pIdx->nColumn regular columns plus
101962 ** one additional column containing the rowid. The rowid column
101963 ** of the index is also allowed to match against the ORDER BY
101964 ** clause.
101966 for(i=j=0, pTerm=pOrderBy->a; j<nTerm && i<=pIdx->nColumn; i++){
101967 Expr *pExpr; /* The expression of the ORDER BY pTerm */
101968 CollSeq *pColl; /* The collating sequence of pExpr */
101969 int termSortOrder; /* Sort order for this term */
101970 int iColumn; /* The i-th column of the index. -1 for rowid */
101971 int iSortOrder; /* 1 for DESC, 0 for ASC on the i-th index term */
101972 const char *zColl; /* Name of the collating sequence for i-th index term */
101974 pExpr = pTerm->pExpr;
101975 if( pExpr->op!=TK_COLUMN || pExpr->iTable!=base ){
101976 /* Can not use an index sort on anything that is not a column in the
101977 ** left-most table of the FROM clause */
101978 break;
101980 pColl = sqlite3ExprCollSeq(pParse, pExpr);
101981 if( !pColl ){
101982 pColl = db->pDfltColl;
101984 if( pIdx->zName && i<pIdx->nColumn ){
101985 iColumn = pIdx->aiColumn[i];
101986 if( iColumn==pIdx->pTable->iPKey ){
101987 iColumn = -1;
101989 iSortOrder = pIdx->aSortOrder[i];
101990 zColl = pIdx->azColl[i];
101991 }else{
101992 iColumn = -1;
101993 iSortOrder = 0;
101994 zColl = pColl->zName;
101996 if( pExpr->iColumn!=iColumn || sqlite3StrICmp(pColl->zName, zColl) ){
101997 /* Term j of the ORDER BY clause does not match column i of the index */
101998 if( i<nEqCol ){
101999 /* If an index column that is constrained by == fails to match an
102000 ** ORDER BY term, that is OK. Just ignore that column of the index
102002 continue;
102003 }else if( i==pIdx->nColumn ){
102004 /* Index column i is the rowid. All other terms match. */
102005 break;
102006 }else{
102007 /* If an index column fails to match and is not constrained by ==
102008 ** then the index cannot satisfy the ORDER BY constraint.
102010 return 0;
102013 assert( pIdx->aSortOrder!=0 || iColumn==-1 );
102014 assert( pTerm->sortOrder==0 || pTerm->sortOrder==1 );
102015 assert( iSortOrder==0 || iSortOrder==1 );
102016 termSortOrder = iSortOrder ^ pTerm->sortOrder;
102017 if( i>nEqCol ){
102018 if( termSortOrder!=sortOrder ){
102019 /* Indices can only be used if all ORDER BY terms past the
102020 ** equality constraints are all either DESC or ASC. */
102021 return 0;
102023 }else{
102024 sortOrder = termSortOrder;
102027 pTerm++;
102028 if( iColumn<0 && !referencesOtherTables(pOrderBy, pMaskSet, j, base) ){
102029 /* If the indexed column is the primary key and everything matches
102030 ** so far and none of the ORDER BY terms to the right reference other
102031 ** tables in the join, then we are assured that the index can be used
102032 ** to sort because the primary key is unique and so none of the other
102033 ** columns will make any difference
102035 j = nTerm;
102039 *pbRev = sortOrder!=0;
102040 if( j>=nTerm ){
102041 /* All terms of the ORDER BY clause are covered by this index so
102042 ** this index can be used for sorting. */
102043 return 1;
102045 if( pIdx->onError!=OE_None && i==pIdx->nColumn
102046 && (wsFlags & WHERE_COLUMN_NULL)==0
102047 && !referencesOtherTables(pOrderBy, pMaskSet, j, base) ){
102048 /* All terms of this index match some prefix of the ORDER BY clause
102049 ** and the index is UNIQUE and no terms on the tail of the ORDER BY
102050 ** clause reference other tables in a join. If this is all true then
102051 ** the order by clause is superfluous. Not that if the matching
102052 ** condition is IS NULL then the result is not necessarily unique
102053 ** even on a UNIQUE index, so disallow those cases. */
102054 return 1;
102056 return 0;
102060 ** Prepare a crude estimate of the logarithm of the input value.
102061 ** The results need not be exact. This is only used for estimating
102062 ** the total cost of performing operations with O(logN) or O(NlogN)
102063 ** complexity. Because N is just a guess, it is no great tragedy if
102064 ** logN is a little off.
102066 static double estLog(double N){
102067 double logN = 1;
102068 double x = 10;
102069 while( N>x ){
102070 logN += 1;
102071 x *= 10;
102073 return logN;
102077 ** Two routines for printing the content of an sqlite3_index_info
102078 ** structure. Used for testing and debugging only. If neither
102079 ** SQLITE_TEST or SQLITE_DEBUG are defined, then these routines
102080 ** are no-ops.
102082 #if !defined(SQLITE_OMIT_VIRTUALTABLE) && defined(SQLITE_DEBUG)
102083 static void TRACE_IDX_INPUTS(sqlite3_index_info *p){
102084 int i;
102085 if( !sqlite3WhereTrace ) return;
102086 for(i=0; i<p->nConstraint; i++){
102087 sqlite3DebugPrintf(" constraint[%d]: col=%d termid=%d op=%d usabled=%d\n",
102089 p->aConstraint[i].iColumn,
102090 p->aConstraint[i].iTermOffset,
102091 p->aConstraint[i].op,
102092 p->aConstraint[i].usable);
102094 for(i=0; i<p->nOrderBy; i++){
102095 sqlite3DebugPrintf(" orderby[%d]: col=%d desc=%d\n",
102097 p->aOrderBy[i].iColumn,
102098 p->aOrderBy[i].desc);
102101 static void TRACE_IDX_OUTPUTS(sqlite3_index_info *p){
102102 int i;
102103 if( !sqlite3WhereTrace ) return;
102104 for(i=0; i<p->nConstraint; i++){
102105 sqlite3DebugPrintf(" usage[%d]: argvIdx=%d omit=%d\n",
102107 p->aConstraintUsage[i].argvIndex,
102108 p->aConstraintUsage[i].omit);
102110 sqlite3DebugPrintf(" idxNum=%d\n", p->idxNum);
102111 sqlite3DebugPrintf(" idxStr=%s\n", p->idxStr);
102112 sqlite3DebugPrintf(" orderByConsumed=%d\n", p->orderByConsumed);
102113 sqlite3DebugPrintf(" estimatedCost=%g\n", p->estimatedCost);
102115 #else
102116 #define TRACE_IDX_INPUTS(A)
102117 #define TRACE_IDX_OUTPUTS(A)
102118 #endif
102121 ** Required because bestIndex() is called by bestOrClauseIndex()
102123 static void bestIndex(
102124 Parse*, WhereClause*, struct SrcList_item*,
102125 Bitmask, Bitmask, ExprList*, WhereCost*);
102128 ** This routine attempts to find an scanning strategy that can be used
102129 ** to optimize an 'OR' expression that is part of a WHERE clause.
102131 ** The table associated with FROM clause term pSrc may be either a
102132 ** regular B-Tree table or a virtual table.
102134 static void bestOrClauseIndex(
102135 Parse *pParse, /* The parsing context */
102136 WhereClause *pWC, /* The WHERE clause */
102137 struct SrcList_item *pSrc, /* The FROM clause term to search */
102138 Bitmask notReady, /* Mask of cursors not available for indexing */
102139 Bitmask notValid, /* Cursors not available for any purpose */
102140 ExprList *pOrderBy, /* The ORDER BY clause */
102141 WhereCost *pCost /* Lowest cost query plan */
102143 #ifndef SQLITE_OMIT_OR_OPTIMIZATION
102144 const int iCur = pSrc->iCursor; /* The cursor of the table to be accessed */
102145 const Bitmask maskSrc = getMask(pWC->pMaskSet, iCur); /* Bitmask for pSrc */
102146 WhereTerm * const pWCEnd = &pWC->a[pWC->nTerm]; /* End of pWC->a[] */
102147 WhereTerm *pTerm; /* A single term of the WHERE clause */
102149 /* No OR-clause optimization allowed if the INDEXED BY or NOT INDEXED clauses
102150 ** are used */
102151 if( pSrc->notIndexed || pSrc->pIndex!=0 ){
102152 return;
102155 /* Search the WHERE clause terms for a usable WO_OR term. */
102156 for(pTerm=pWC->a; pTerm<pWCEnd; pTerm++){
102157 if( pTerm->eOperator==WO_OR
102158 && ((pTerm->prereqAll & ~maskSrc) & notReady)==0
102159 && (pTerm->u.pOrInfo->indexable & maskSrc)!=0
102161 WhereClause * const pOrWC = &pTerm->u.pOrInfo->wc;
102162 WhereTerm * const pOrWCEnd = &pOrWC->a[pOrWC->nTerm];
102163 WhereTerm *pOrTerm;
102164 int flags = WHERE_MULTI_OR;
102165 double rTotal = 0;
102166 double nRow = 0;
102167 Bitmask used = 0;
102169 for(pOrTerm=pOrWC->a; pOrTerm<pOrWCEnd; pOrTerm++){
102170 WhereCost sTermCost;
102171 WHERETRACE(("... Multi-index OR testing for term %d of %d....\n",
102172 (pOrTerm - pOrWC->a), (pTerm - pWC->a)
102174 if( pOrTerm->eOperator==WO_AND ){
102175 WhereClause *pAndWC = &pOrTerm->u.pAndInfo->wc;
102176 bestIndex(pParse, pAndWC, pSrc, notReady, notValid, 0, &sTermCost);
102177 }else if( pOrTerm->leftCursor==iCur ){
102178 WhereClause tempWC;
102179 tempWC.pParse = pWC->pParse;
102180 tempWC.pMaskSet = pWC->pMaskSet;
102181 tempWC.op = TK_AND;
102182 tempWC.a = pOrTerm;
102183 tempWC.nTerm = 1;
102184 bestIndex(pParse, &tempWC, pSrc, notReady, notValid, 0, &sTermCost);
102185 }else{
102186 continue;
102188 rTotal += sTermCost.rCost;
102189 nRow += sTermCost.plan.nRow;
102190 used |= sTermCost.used;
102191 if( rTotal>=pCost->rCost ) break;
102194 /* If there is an ORDER BY clause, increase the scan cost to account
102195 ** for the cost of the sort. */
102196 if( pOrderBy!=0 ){
102197 WHERETRACE(("... sorting increases OR cost %.9g to %.9g\n",
102198 rTotal, rTotal+nRow*estLog(nRow)));
102199 rTotal += nRow*estLog(nRow);
102202 /* If the cost of scanning using this OR term for optimization is
102203 ** less than the current cost stored in pCost, replace the contents
102204 ** of pCost. */
102205 WHERETRACE(("... multi-index OR cost=%.9g nrow=%.9g\n", rTotal, nRow));
102206 if( rTotal<pCost->rCost ){
102207 pCost->rCost = rTotal;
102208 pCost->used = used;
102209 pCost->plan.nRow = nRow;
102210 pCost->plan.wsFlags = flags;
102211 pCost->plan.u.pTerm = pTerm;
102215 #endif /* SQLITE_OMIT_OR_OPTIMIZATION */
102218 #ifndef SQLITE_OMIT_AUTOMATIC_INDEX
102220 ** Return TRUE if the WHERE clause term pTerm is of a form where it
102221 ** could be used with an index to access pSrc, assuming an appropriate
102222 ** index existed.
102224 static int termCanDriveIndex(
102225 WhereTerm *pTerm, /* WHERE clause term to check */
102226 struct SrcList_item *pSrc, /* Table we are trying to access */
102227 Bitmask notReady /* Tables in outer loops of the join */
102229 char aff;
102230 if( pTerm->leftCursor!=pSrc->iCursor ) return 0;
102231 if( pTerm->eOperator!=WO_EQ ) return 0;
102232 if( (pTerm->prereqRight & notReady)!=0 ) return 0;
102233 aff = pSrc->pTab->aCol[pTerm->u.leftColumn].affinity;
102234 if( !sqlite3IndexAffinityOk(pTerm->pExpr, aff) ) return 0;
102235 return 1;
102237 #endif
102239 #ifndef SQLITE_OMIT_AUTOMATIC_INDEX
102241 ** If the query plan for pSrc specified in pCost is a full table scan
102242 ** and indexing is allows (if there is no NOT INDEXED clause) and it
102243 ** possible to construct a transient index that would perform better
102244 ** than a full table scan even when the cost of constructing the index
102245 ** is taken into account, then alter the query plan to use the
102246 ** transient index.
102248 static void bestAutomaticIndex(
102249 Parse *pParse, /* The parsing context */
102250 WhereClause *pWC, /* The WHERE clause */
102251 struct SrcList_item *pSrc, /* The FROM clause term to search */
102252 Bitmask notReady, /* Mask of cursors that are not available */
102253 WhereCost *pCost /* Lowest cost query plan */
102255 double nTableRow; /* Rows in the input table */
102256 double logN; /* log(nTableRow) */
102257 double costTempIdx; /* per-query cost of the transient index */
102258 WhereTerm *pTerm; /* A single term of the WHERE clause */
102259 WhereTerm *pWCEnd; /* End of pWC->a[] */
102260 Table *pTable; /* Table tht might be indexed */
102262 if( pParse->nQueryLoop<=(double)1 ){
102263 /* There is no point in building an automatic index for a single scan */
102264 return;
102266 if( (pParse->db->flags & SQLITE_AutoIndex)==0 ){
102267 /* Automatic indices are disabled at run-time */
102268 return;
102270 if( (pCost->plan.wsFlags & WHERE_NOT_FULLSCAN)!=0 ){
102271 /* We already have some kind of index in use for this query. */
102272 return;
102274 if( pSrc->notIndexed ){
102275 /* The NOT INDEXED clause appears in the SQL. */
102276 return;
102278 if( pSrc->isCorrelated ){
102279 /* The source is a correlated sub-query. No point in indexing it. */
102280 return;
102283 assert( pParse->nQueryLoop >= (double)1 );
102284 pTable = pSrc->pTab;
102285 nTableRow = pTable->nRowEst;
102286 logN = estLog(nTableRow);
102287 costTempIdx = 2*logN*(nTableRow/pParse->nQueryLoop + 1);
102288 if( costTempIdx>=pCost->rCost ){
102289 /* The cost of creating the transient table would be greater than
102290 ** doing the full table scan */
102291 return;
102294 /* Search for any equality comparison term */
102295 pWCEnd = &pWC->a[pWC->nTerm];
102296 for(pTerm=pWC->a; pTerm<pWCEnd; pTerm++){
102297 if( termCanDriveIndex(pTerm, pSrc, notReady) ){
102298 WHERETRACE(("auto-index reduces cost from %.1f to %.1f\n",
102299 pCost->rCost, costTempIdx));
102300 pCost->rCost = costTempIdx;
102301 pCost->plan.nRow = logN + 1;
102302 pCost->plan.wsFlags = WHERE_TEMP_INDEX;
102303 pCost->used = pTerm->prereqRight;
102304 break;
102308 #else
102309 # define bestAutomaticIndex(A,B,C,D,E) /* no-op */
102310 #endif /* SQLITE_OMIT_AUTOMATIC_INDEX */
102313 #ifndef SQLITE_OMIT_AUTOMATIC_INDEX
102315 ** Generate code to construct the Index object for an automatic index
102316 ** and to set up the WhereLevel object pLevel so that the code generator
102317 ** makes use of the automatic index.
102319 static void constructAutomaticIndex(
102320 Parse *pParse, /* The parsing context */
102321 WhereClause *pWC, /* The WHERE clause */
102322 struct SrcList_item *pSrc, /* The FROM clause term to get the next index */
102323 Bitmask notReady, /* Mask of cursors that are not available */
102324 WhereLevel *pLevel /* Write new index here */
102326 int nColumn; /* Number of columns in the constructed index */
102327 WhereTerm *pTerm; /* A single term of the WHERE clause */
102328 WhereTerm *pWCEnd; /* End of pWC->a[] */
102329 int nByte; /* Byte of memory needed for pIdx */
102330 Index *pIdx; /* Object describing the transient index */
102331 Vdbe *v; /* Prepared statement under construction */
102332 int regIsInit; /* Register set by initialization */
102333 int addrInit; /* Address of the initialization bypass jump */
102334 Table *pTable; /* The table being indexed */
102335 KeyInfo *pKeyinfo; /* Key information for the index */
102336 int addrTop; /* Top of the index fill loop */
102337 int regRecord; /* Register holding an index record */
102338 int n; /* Column counter */
102339 int i; /* Loop counter */
102340 int mxBitCol; /* Maximum column in pSrc->colUsed */
102341 CollSeq *pColl; /* Collating sequence to on a column */
102342 Bitmask idxCols; /* Bitmap of columns used for indexing */
102343 Bitmask extraCols; /* Bitmap of additional columns */
102345 /* Generate code to skip over the creation and initialization of the
102346 ** transient index on 2nd and subsequent iterations of the loop. */
102347 v = pParse->pVdbe;
102348 assert( v!=0 );
102349 regIsInit = ++pParse->nMem;
102350 addrInit = sqlite3VdbeAddOp1(v, OP_Once, regIsInit);
102352 /* Count the number of columns that will be added to the index
102353 ** and used to match WHERE clause constraints */
102354 nColumn = 0;
102355 pTable = pSrc->pTab;
102356 pWCEnd = &pWC->a[pWC->nTerm];
102357 idxCols = 0;
102358 for(pTerm=pWC->a; pTerm<pWCEnd; pTerm++){
102359 if( termCanDriveIndex(pTerm, pSrc, notReady) ){
102360 int iCol = pTerm->u.leftColumn;
102361 Bitmask cMask = iCol>=BMS ? ((Bitmask)1)<<(BMS-1) : ((Bitmask)1)<<iCol;
102362 testcase( iCol==BMS );
102363 testcase( iCol==BMS-1 );
102364 if( (idxCols & cMask)==0 ){
102365 nColumn++;
102366 idxCols |= cMask;
102370 assert( nColumn>0 );
102371 pLevel->plan.nEq = nColumn;
102373 /* Count the number of additional columns needed to create a
102374 ** covering index. A "covering index" is an index that contains all
102375 ** columns that are needed by the query. With a covering index, the
102376 ** original table never needs to be accessed. Automatic indices must
102377 ** be a covering index because the index will not be updated if the
102378 ** original table changes and the index and table cannot both be used
102379 ** if they go out of sync.
102381 extraCols = pSrc->colUsed & (~idxCols | (((Bitmask)1)<<(BMS-1)));
102382 mxBitCol = (pTable->nCol >= BMS-1) ? BMS-1 : pTable->nCol;
102383 testcase( pTable->nCol==BMS-1 );
102384 testcase( pTable->nCol==BMS-2 );
102385 for(i=0; i<mxBitCol; i++){
102386 if( extraCols & (((Bitmask)1)<<i) ) nColumn++;
102388 if( pSrc->colUsed & (((Bitmask)1)<<(BMS-1)) ){
102389 nColumn += pTable->nCol - BMS + 1;
102391 pLevel->plan.wsFlags |= WHERE_COLUMN_EQ | WHERE_IDX_ONLY | WO_EQ;
102393 /* Construct the Index object to describe this index */
102394 nByte = sizeof(Index);
102395 nByte += nColumn*sizeof(int); /* Index.aiColumn */
102396 nByte += nColumn*sizeof(char*); /* Index.azColl */
102397 nByte += nColumn; /* Index.aSortOrder */
102398 pIdx = sqlite3DbMallocZero(pParse->db, nByte);
102399 if( pIdx==0 ) return;
102400 pLevel->plan.u.pIdx = pIdx;
102401 pIdx->azColl = (char**)&pIdx[1];
102402 pIdx->aiColumn = (int*)&pIdx->azColl[nColumn];
102403 pIdx->aSortOrder = (u8*)&pIdx->aiColumn[nColumn];
102404 pIdx->zName = "auto-index";
102405 pIdx->nColumn = nColumn;
102406 pIdx->pTable = pTable;
102407 n = 0;
102408 idxCols = 0;
102409 for(pTerm=pWC->a; pTerm<pWCEnd; pTerm++){
102410 if( termCanDriveIndex(pTerm, pSrc, notReady) ){
102411 int iCol = pTerm->u.leftColumn;
102412 Bitmask cMask = iCol>=BMS ? ((Bitmask)1)<<(BMS-1) : ((Bitmask)1)<<iCol;
102413 if( (idxCols & cMask)==0 ){
102414 Expr *pX = pTerm->pExpr;
102415 idxCols |= cMask;
102416 pIdx->aiColumn[n] = pTerm->u.leftColumn;
102417 pColl = sqlite3BinaryCompareCollSeq(pParse, pX->pLeft, pX->pRight);
102418 pIdx->azColl[n] = ALWAYS(pColl) ? pColl->zName : "BINARY";
102423 assert( (u32)n==pLevel->plan.nEq );
102425 /* Add additional columns needed to make the automatic index into
102426 ** a covering index */
102427 for(i=0; i<mxBitCol; i++){
102428 if( extraCols & (((Bitmask)1)<<i) ){
102429 pIdx->aiColumn[n] = i;
102430 pIdx->azColl[n] = "BINARY";
102434 if( pSrc->colUsed & (((Bitmask)1)<<(BMS-1)) ){
102435 for(i=BMS-1; i<pTable->nCol; i++){
102436 pIdx->aiColumn[n] = i;
102437 pIdx->azColl[n] = "BINARY";
102441 assert( n==nColumn );
102443 /* Create the automatic index */
102444 pKeyinfo = sqlite3IndexKeyinfo(pParse, pIdx);
102445 assert( pLevel->iIdxCur>=0 );
102446 sqlite3VdbeAddOp4(v, OP_OpenAutoindex, pLevel->iIdxCur, nColumn+1, 0,
102447 (char*)pKeyinfo, P4_KEYINFO_HANDOFF);
102448 VdbeComment((v, "for %s", pTable->zName));
102450 /* Fill the automatic index with content */
102451 addrTop = sqlite3VdbeAddOp1(v, OP_Rewind, pLevel->iTabCur);
102452 regRecord = sqlite3GetTempReg(pParse);
102453 sqlite3GenerateIndexKey(pParse, pIdx, pLevel->iTabCur, regRecord, 1);
102454 sqlite3VdbeAddOp2(v, OP_IdxInsert, pLevel->iIdxCur, regRecord);
102455 sqlite3VdbeChangeP5(v, OPFLAG_USESEEKRESULT);
102456 sqlite3VdbeAddOp2(v, OP_Next, pLevel->iTabCur, addrTop+1);
102457 sqlite3VdbeChangeP5(v, SQLITE_STMTSTATUS_AUTOINDEX);
102458 sqlite3VdbeJumpHere(v, addrTop);
102459 sqlite3ReleaseTempReg(pParse, regRecord);
102461 /* Jump here when skipping the initialization */
102462 sqlite3VdbeJumpHere(v, addrInit);
102464 #endif /* SQLITE_OMIT_AUTOMATIC_INDEX */
102466 #ifndef SQLITE_OMIT_VIRTUALTABLE
102468 ** Allocate and populate an sqlite3_index_info structure. It is the
102469 ** responsibility of the caller to eventually release the structure
102470 ** by passing the pointer returned by this function to sqlite3_free().
102472 static sqlite3_index_info *allocateIndexInfo(
102473 Parse *pParse,
102474 WhereClause *pWC,
102475 struct SrcList_item *pSrc,
102476 ExprList *pOrderBy
102478 int i, j;
102479 int nTerm;
102480 struct sqlite3_index_constraint *pIdxCons;
102481 struct sqlite3_index_orderby *pIdxOrderBy;
102482 struct sqlite3_index_constraint_usage *pUsage;
102483 WhereTerm *pTerm;
102484 int nOrderBy;
102485 sqlite3_index_info *pIdxInfo;
102487 WHERETRACE(("Recomputing index info for %s...\n", pSrc->pTab->zName));
102489 /* Count the number of possible WHERE clause constraints referring
102490 ** to this virtual table */
102491 for(i=nTerm=0, pTerm=pWC->a; i<pWC->nTerm; i++, pTerm++){
102492 if( pTerm->leftCursor != pSrc->iCursor ) continue;
102493 assert( (pTerm->eOperator&(pTerm->eOperator-1))==0 );
102494 testcase( pTerm->eOperator==WO_IN );
102495 testcase( pTerm->eOperator==WO_ISNULL );
102496 if( pTerm->eOperator & (WO_IN|WO_ISNULL) ) continue;
102497 if( pTerm->wtFlags & TERM_VNULL ) continue;
102498 nTerm++;
102501 /* If the ORDER BY clause contains only columns in the current
102502 ** virtual table then allocate space for the aOrderBy part of
102503 ** the sqlite3_index_info structure.
102505 nOrderBy = 0;
102506 if( pOrderBy ){
102507 for(i=0; i<pOrderBy->nExpr; i++){
102508 Expr *pExpr = pOrderBy->a[i].pExpr;
102509 if( pExpr->op!=TK_COLUMN || pExpr->iTable!=pSrc->iCursor ) break;
102511 if( i==pOrderBy->nExpr ){
102512 nOrderBy = pOrderBy->nExpr;
102516 /* Allocate the sqlite3_index_info structure
102518 pIdxInfo = sqlite3DbMallocZero(pParse->db, sizeof(*pIdxInfo)
102519 + (sizeof(*pIdxCons) + sizeof(*pUsage))*nTerm
102520 + sizeof(*pIdxOrderBy)*nOrderBy );
102521 if( pIdxInfo==0 ){
102522 sqlite3ErrorMsg(pParse, "out of memory");
102523 /* (double)0 In case of SQLITE_OMIT_FLOATING_POINT... */
102524 return 0;
102527 /* Initialize the structure. The sqlite3_index_info structure contains
102528 ** many fields that are declared "const" to prevent xBestIndex from
102529 ** changing them. We have to do some funky casting in order to
102530 ** initialize those fields.
102532 pIdxCons = (struct sqlite3_index_constraint*)&pIdxInfo[1];
102533 pIdxOrderBy = (struct sqlite3_index_orderby*)&pIdxCons[nTerm];
102534 pUsage = (struct sqlite3_index_constraint_usage*)&pIdxOrderBy[nOrderBy];
102535 *(int*)&pIdxInfo->nConstraint = nTerm;
102536 *(int*)&pIdxInfo->nOrderBy = nOrderBy;
102537 *(struct sqlite3_index_constraint**)&pIdxInfo->aConstraint = pIdxCons;
102538 *(struct sqlite3_index_orderby**)&pIdxInfo->aOrderBy = pIdxOrderBy;
102539 *(struct sqlite3_index_constraint_usage**)&pIdxInfo->aConstraintUsage =
102540 pUsage;
102542 for(i=j=0, pTerm=pWC->a; i<pWC->nTerm; i++, pTerm++){
102543 if( pTerm->leftCursor != pSrc->iCursor ) continue;
102544 assert( (pTerm->eOperator&(pTerm->eOperator-1))==0 );
102545 testcase( pTerm->eOperator==WO_IN );
102546 testcase( pTerm->eOperator==WO_ISNULL );
102547 if( pTerm->eOperator & (WO_IN|WO_ISNULL) ) continue;
102548 if( pTerm->wtFlags & TERM_VNULL ) continue;
102549 pIdxCons[j].iColumn = pTerm->u.leftColumn;
102550 pIdxCons[j].iTermOffset = i;
102551 pIdxCons[j].op = (u8)pTerm->eOperator;
102552 /* The direct assignment in the previous line is possible only because
102553 ** the WO_ and SQLITE_INDEX_CONSTRAINT_ codes are identical. The
102554 ** following asserts verify this fact. */
102555 assert( WO_EQ==SQLITE_INDEX_CONSTRAINT_EQ );
102556 assert( WO_LT==SQLITE_INDEX_CONSTRAINT_LT );
102557 assert( WO_LE==SQLITE_INDEX_CONSTRAINT_LE );
102558 assert( WO_GT==SQLITE_INDEX_CONSTRAINT_GT );
102559 assert( WO_GE==SQLITE_INDEX_CONSTRAINT_GE );
102560 assert( WO_MATCH==SQLITE_INDEX_CONSTRAINT_MATCH );
102561 assert( pTerm->eOperator & (WO_EQ|WO_LT|WO_LE|WO_GT|WO_GE|WO_MATCH) );
102564 for(i=0; i<nOrderBy; i++){
102565 Expr *pExpr = pOrderBy->a[i].pExpr;
102566 pIdxOrderBy[i].iColumn = pExpr->iColumn;
102567 pIdxOrderBy[i].desc = pOrderBy->a[i].sortOrder;
102570 return pIdxInfo;
102574 ** The table object reference passed as the second argument to this function
102575 ** must represent a virtual table. This function invokes the xBestIndex()
102576 ** method of the virtual table with the sqlite3_index_info pointer passed
102577 ** as the argument.
102579 ** If an error occurs, pParse is populated with an error message and a
102580 ** non-zero value is returned. Otherwise, 0 is returned and the output
102581 ** part of the sqlite3_index_info structure is left populated.
102583 ** Whether or not an error is returned, it is the responsibility of the
102584 ** caller to eventually free p->idxStr if p->needToFreeIdxStr indicates
102585 ** that this is required.
102587 static int vtabBestIndex(Parse *pParse, Table *pTab, sqlite3_index_info *p){
102588 sqlite3_vtab *pVtab = sqlite3GetVTable(pParse->db, pTab)->pVtab;
102589 int i;
102590 int rc;
102592 WHERETRACE(("xBestIndex for %s\n", pTab->zName));
102593 TRACE_IDX_INPUTS(p);
102594 rc = pVtab->pModule->xBestIndex(pVtab, p);
102595 TRACE_IDX_OUTPUTS(p);
102597 if( rc!=SQLITE_OK ){
102598 if( rc==SQLITE_NOMEM ){
102599 pParse->db->mallocFailed = 1;
102600 }else if( !pVtab->zErrMsg ){
102601 sqlite3ErrorMsg(pParse, "%s", sqlite3ErrStr(rc));
102602 }else{
102603 sqlite3ErrorMsg(pParse, "%s", pVtab->zErrMsg);
102606 sqlite3_free(pVtab->zErrMsg);
102607 pVtab->zErrMsg = 0;
102609 for(i=0; i<p->nConstraint; i++){
102610 if( !p->aConstraint[i].usable && p->aConstraintUsage[i].argvIndex>0 ){
102611 sqlite3ErrorMsg(pParse,
102612 "table %s: xBestIndex returned an invalid plan", pTab->zName);
102616 return pParse->nErr;
102621 ** Compute the best index for a virtual table.
102623 ** The best index is computed by the xBestIndex method of the virtual
102624 ** table module. This routine is really just a wrapper that sets up
102625 ** the sqlite3_index_info structure that is used to communicate with
102626 ** xBestIndex.
102628 ** In a join, this routine might be called multiple times for the
102629 ** same virtual table. The sqlite3_index_info structure is created
102630 ** and initialized on the first invocation and reused on all subsequent
102631 ** invocations. The sqlite3_index_info structure is also used when
102632 ** code is generated to access the virtual table. The whereInfoDelete()
102633 ** routine takes care of freeing the sqlite3_index_info structure after
102634 ** everybody has finished with it.
102636 static void bestVirtualIndex(
102637 Parse *pParse, /* The parsing context */
102638 WhereClause *pWC, /* The WHERE clause */
102639 struct SrcList_item *pSrc, /* The FROM clause term to search */
102640 Bitmask notReady, /* Mask of cursors not available for index */
102641 Bitmask notValid, /* Cursors not valid for any purpose */
102642 ExprList *pOrderBy, /* The order by clause */
102643 WhereCost *pCost, /* Lowest cost query plan */
102644 sqlite3_index_info **ppIdxInfo /* Index information passed to xBestIndex */
102646 Table *pTab = pSrc->pTab;
102647 sqlite3_index_info *pIdxInfo;
102648 struct sqlite3_index_constraint *pIdxCons;
102649 struct sqlite3_index_constraint_usage *pUsage;
102650 WhereTerm *pTerm;
102651 int i, j;
102652 int nOrderBy;
102653 double rCost;
102655 /* Make sure wsFlags is initialized to some sane value. Otherwise, if the
102656 ** malloc in allocateIndexInfo() fails and this function returns leaving
102657 ** wsFlags in an uninitialized state, the caller may behave unpredictably.
102659 memset(pCost, 0, sizeof(*pCost));
102660 pCost->plan.wsFlags = WHERE_VIRTUALTABLE;
102662 /* If the sqlite3_index_info structure has not been previously
102663 ** allocated and initialized, then allocate and initialize it now.
102665 pIdxInfo = *ppIdxInfo;
102666 if( pIdxInfo==0 ){
102667 *ppIdxInfo = pIdxInfo = allocateIndexInfo(pParse, pWC, pSrc, pOrderBy);
102669 if( pIdxInfo==0 ){
102670 return;
102673 /* At this point, the sqlite3_index_info structure that pIdxInfo points
102674 ** to will have been initialized, either during the current invocation or
102675 ** during some prior invocation. Now we just have to customize the
102676 ** details of pIdxInfo for the current invocation and pass it to
102677 ** xBestIndex.
102680 /* The module name must be defined. Also, by this point there must
102681 ** be a pointer to an sqlite3_vtab structure. Otherwise
102682 ** sqlite3ViewGetColumnNames() would have picked up the error.
102684 assert( pTab->azModuleArg && pTab->azModuleArg[0] );
102685 assert( sqlite3GetVTable(pParse->db, pTab) );
102687 /* Set the aConstraint[].usable fields and initialize all
102688 ** output variables to zero.
102690 ** aConstraint[].usable is true for constraints where the right-hand
102691 ** side contains only references to tables to the left of the current
102692 ** table. In other words, if the constraint is of the form:
102694 ** column = expr
102696 ** and we are evaluating a join, then the constraint on column is
102697 ** only valid if all tables referenced in expr occur to the left
102698 ** of the table containing column.
102700 ** The aConstraints[] array contains entries for all constraints
102701 ** on the current table. That way we only have to compute it once
102702 ** even though we might try to pick the best index multiple times.
102703 ** For each attempt at picking an index, the order of tables in the
102704 ** join might be different so we have to recompute the usable flag
102705 ** each time.
102707 pIdxCons = *(struct sqlite3_index_constraint**)&pIdxInfo->aConstraint;
102708 pUsage = pIdxInfo->aConstraintUsage;
102709 for(i=0; i<pIdxInfo->nConstraint; i++, pIdxCons++){
102710 j = pIdxCons->iTermOffset;
102711 pTerm = &pWC->a[j];
102712 pIdxCons->usable = (pTerm->prereqRight&notReady) ? 0 : 1;
102714 memset(pUsage, 0, sizeof(pUsage[0])*pIdxInfo->nConstraint);
102715 if( pIdxInfo->needToFreeIdxStr ){
102716 sqlite3_free(pIdxInfo->idxStr);
102718 pIdxInfo->idxStr = 0;
102719 pIdxInfo->idxNum = 0;
102720 pIdxInfo->needToFreeIdxStr = 0;
102721 pIdxInfo->orderByConsumed = 0;
102722 /* ((double)2) In case of SQLITE_OMIT_FLOATING_POINT... */
102723 pIdxInfo->estimatedCost = SQLITE_BIG_DBL / ((double)2);
102724 nOrderBy = pIdxInfo->nOrderBy;
102725 if( !pOrderBy ){
102726 pIdxInfo->nOrderBy = 0;
102729 if( vtabBestIndex(pParse, pTab, pIdxInfo) ){
102730 return;
102733 pIdxCons = *(struct sqlite3_index_constraint**)&pIdxInfo->aConstraint;
102734 for(i=0; i<pIdxInfo->nConstraint; i++){
102735 if( pUsage[i].argvIndex>0 ){
102736 pCost->used |= pWC->a[pIdxCons[i].iTermOffset].prereqRight;
102740 /* If there is an ORDER BY clause, and the selected virtual table index
102741 ** does not satisfy it, increase the cost of the scan accordingly. This
102742 ** matches the processing for non-virtual tables in bestBtreeIndex().
102744 rCost = pIdxInfo->estimatedCost;
102745 if( pOrderBy && pIdxInfo->orderByConsumed==0 ){
102746 rCost += estLog(rCost)*rCost;
102749 /* The cost is not allowed to be larger than SQLITE_BIG_DBL (the
102750 ** inital value of lowestCost in this loop. If it is, then the
102751 ** (cost<lowestCost) test below will never be true.
102753 ** Use "(double)2" instead of "2.0" in case OMIT_FLOATING_POINT
102754 ** is defined.
102756 if( (SQLITE_BIG_DBL/((double)2))<rCost ){
102757 pCost->rCost = (SQLITE_BIG_DBL/((double)2));
102758 }else{
102759 pCost->rCost = rCost;
102761 pCost->plan.u.pVtabIdx = pIdxInfo;
102762 if( pIdxInfo->orderByConsumed ){
102763 pCost->plan.wsFlags |= WHERE_ORDERBY;
102765 pCost->plan.nEq = 0;
102766 pIdxInfo->nOrderBy = nOrderBy;
102768 /* Try to find a more efficient access pattern by using multiple indexes
102769 ** to optimize an OR expression within the WHERE clause.
102771 bestOrClauseIndex(pParse, pWC, pSrc, notReady, notValid, pOrderBy, pCost);
102773 #endif /* SQLITE_OMIT_VIRTUALTABLE */
102776 ** Argument pIdx is a pointer to an index structure that has an array of
102777 ** SQLITE_INDEX_SAMPLES evenly spaced samples of the first indexed column
102778 ** stored in Index.aSample. These samples divide the domain of values stored
102779 ** the index into (SQLITE_INDEX_SAMPLES+1) regions.
102780 ** Region 0 contains all values less than the first sample value. Region
102781 ** 1 contains values between the first and second samples. Region 2 contains
102782 ** values between samples 2 and 3. And so on. Region SQLITE_INDEX_SAMPLES
102783 ** contains values larger than the last sample.
102785 ** If the index contains many duplicates of a single value, then it is
102786 ** possible that two or more adjacent samples can hold the same value.
102787 ** When that is the case, the smallest possible region code is returned
102788 ** when roundUp is false and the largest possible region code is returned
102789 ** when roundUp is true.
102791 ** If successful, this function determines which of the regions value
102792 ** pVal lies in, sets *piRegion to the region index (a value between 0
102793 ** and SQLITE_INDEX_SAMPLES+1, inclusive) and returns SQLITE_OK.
102794 ** Or, if an OOM occurs while converting text values between encodings,
102795 ** SQLITE_NOMEM is returned and *piRegion is undefined.
102797 #ifdef SQLITE_ENABLE_STAT2
102798 static int whereRangeRegion(
102799 Parse *pParse, /* Database connection */
102800 Index *pIdx, /* Index to consider domain of */
102801 sqlite3_value *pVal, /* Value to consider */
102802 int roundUp, /* Return largest valid region if true */
102803 int *piRegion /* OUT: Region of domain in which value lies */
102805 assert( roundUp==0 || roundUp==1 );
102806 if( ALWAYS(pVal) ){
102807 IndexSample *aSample = pIdx->aSample;
102808 int i = 0;
102809 int eType = sqlite3_value_type(pVal);
102811 if( eType==SQLITE_INTEGER || eType==SQLITE_FLOAT ){
102812 double r = sqlite3_value_double(pVal);
102813 for(i=0; i<SQLITE_INDEX_SAMPLES; i++){
102814 if( aSample[i].eType==SQLITE_NULL ) continue;
102815 if( aSample[i].eType>=SQLITE_TEXT ) break;
102816 if( roundUp ){
102817 if( aSample[i].u.r>r ) break;
102818 }else{
102819 if( aSample[i].u.r>=r ) break;
102822 }else if( eType==SQLITE_NULL ){
102823 i = 0;
102824 if( roundUp ){
102825 while( i<SQLITE_INDEX_SAMPLES && aSample[i].eType==SQLITE_NULL ) i++;
102827 }else{
102828 sqlite3 *db = pParse->db;
102829 CollSeq *pColl;
102830 const u8 *z;
102831 int n;
102833 /* pVal comes from sqlite3ValueFromExpr() so the type cannot be NULL */
102834 assert( eType==SQLITE_TEXT || eType==SQLITE_BLOB );
102836 if( eType==SQLITE_BLOB ){
102837 z = (const u8 *)sqlite3_value_blob(pVal);
102838 pColl = db->pDfltColl;
102839 assert( pColl->enc==SQLITE_UTF8 );
102840 }else{
102841 pColl = sqlite3GetCollSeq(db, SQLITE_UTF8, 0, *pIdx->azColl);
102842 if( pColl==0 ){
102843 sqlite3ErrorMsg(pParse, "no such collation sequence: %s",
102844 *pIdx->azColl);
102845 return SQLITE_ERROR;
102847 z = (const u8 *)sqlite3ValueText(pVal, pColl->enc);
102848 if( !z ){
102849 return SQLITE_NOMEM;
102851 assert( z && pColl && pColl->xCmp );
102853 n = sqlite3ValueBytes(pVal, pColl->enc);
102855 for(i=0; i<SQLITE_INDEX_SAMPLES; i++){
102856 int c;
102857 int eSampletype = aSample[i].eType;
102858 if( eSampletype==SQLITE_NULL || eSampletype<eType ) continue;
102859 if( (eSampletype!=eType) ) break;
102860 #ifndef SQLITE_OMIT_UTF16
102861 if( pColl->enc!=SQLITE_UTF8 ){
102862 int nSample;
102863 char *zSample = sqlite3Utf8to16(
102864 db, pColl->enc, aSample[i].u.z, aSample[i].nByte, &nSample
102866 if( !zSample ){
102867 assert( db->mallocFailed );
102868 return SQLITE_NOMEM;
102870 c = pColl->xCmp(pColl->pUser, nSample, zSample, n, z);
102871 sqlite3DbFree(db, zSample);
102872 }else
102873 #endif
102875 c = pColl->xCmp(pColl->pUser, aSample[i].nByte, aSample[i].u.z, n, z);
102877 if( c-roundUp>=0 ) break;
102881 assert( i>=0 && i<=SQLITE_INDEX_SAMPLES );
102882 *piRegion = i;
102884 return SQLITE_OK;
102886 #endif /* #ifdef SQLITE_ENABLE_STAT2 */
102889 ** If expression pExpr represents a literal value, set *pp to point to
102890 ** an sqlite3_value structure containing the same value, with affinity
102891 ** aff applied to it, before returning. It is the responsibility of the
102892 ** caller to eventually release this structure by passing it to
102893 ** sqlite3ValueFree().
102895 ** If the current parse is a recompile (sqlite3Reprepare()) and pExpr
102896 ** is an SQL variable that currently has a non-NULL value bound to it,
102897 ** create an sqlite3_value structure containing this value, again with
102898 ** affinity aff applied to it, instead.
102900 ** If neither of the above apply, set *pp to NULL.
102902 ** If an error occurs, return an error code. Otherwise, SQLITE_OK.
102904 #ifdef SQLITE_ENABLE_STAT2
102905 static int valueFromExpr(
102906 Parse *pParse,
102907 Expr *pExpr,
102908 u8 aff,
102909 sqlite3_value **pp
102911 if( pExpr->op==TK_VARIABLE
102912 || (pExpr->op==TK_REGISTER && pExpr->op2==TK_VARIABLE)
102914 int iVar = pExpr->iColumn;
102915 sqlite3VdbeSetVarmask(pParse->pVdbe, iVar); /* IMP: R-23257-02778 */
102916 *pp = sqlite3VdbeGetValue(pParse->pReprepare, iVar, aff);
102917 return SQLITE_OK;
102919 return sqlite3ValueFromExpr(pParse->db, pExpr, SQLITE_UTF8, aff, pp);
102921 #endif
102924 ** This function is used to estimate the number of rows that will be visited
102925 ** by scanning an index for a range of values. The range may have an upper
102926 ** bound, a lower bound, or both. The WHERE clause terms that set the upper
102927 ** and lower bounds are represented by pLower and pUpper respectively. For
102928 ** example, assuming that index p is on t1(a):
102930 ** ... FROM t1 WHERE a > ? AND a < ? ...
102931 ** |_____| |_____|
102932 ** | |
102933 ** pLower pUpper
102935 ** If either of the upper or lower bound is not present, then NULL is passed in
102936 ** place of the corresponding WhereTerm.
102938 ** The nEq parameter is passed the index of the index column subject to the
102939 ** range constraint. Or, equivalently, the number of equality constraints
102940 ** optimized by the proposed index scan. For example, assuming index p is
102941 ** on t1(a, b), and the SQL query is:
102943 ** ... FROM t1 WHERE a = ? AND b > ? AND b < ? ...
102945 ** then nEq should be passed the value 1 (as the range restricted column,
102946 ** b, is the second left-most column of the index). Or, if the query is:
102948 ** ... FROM t1 WHERE a > ? AND a < ? ...
102950 ** then nEq should be passed 0.
102952 ** The returned value is an integer between 1 and 100, inclusive. A return
102953 ** value of 1 indicates that the proposed range scan is expected to visit
102954 ** approximately 1/100th (1%) of the rows selected by the nEq equality
102955 ** constraints (if any). A return value of 100 indicates that it is expected
102956 ** that the range scan will visit every row (100%) selected by the equality
102957 ** constraints.
102959 ** In the absence of sqlite_stat2 ANALYZE data, each range inequality
102960 ** reduces the search space by 3/4ths. Hence a single constraint (x>?)
102961 ** results in a return of 25 and a range constraint (x>? AND x<?) results
102962 ** in a return of 6.
102964 static int whereRangeScanEst(
102965 Parse *pParse, /* Parsing & code generating context */
102966 Index *p, /* The index containing the range-compared column; "x" */
102967 int nEq, /* index into p->aCol[] of the range-compared column */
102968 WhereTerm *pLower, /* Lower bound on the range. ex: "x>123" Might be NULL */
102969 WhereTerm *pUpper, /* Upper bound on the range. ex: "x<455" Might be NULL */
102970 int *piEst /* OUT: Return value */
102972 int rc = SQLITE_OK;
102974 #ifdef SQLITE_ENABLE_STAT2
102976 if( nEq==0 && p->aSample ){
102977 sqlite3_value *pLowerVal = 0;
102978 sqlite3_value *pUpperVal = 0;
102979 int iEst;
102980 int iLower = 0;
102981 int iUpper = SQLITE_INDEX_SAMPLES;
102982 int roundUpUpper = 0;
102983 int roundUpLower = 0;
102984 u8 aff = p->pTable->aCol[p->aiColumn[0]].affinity;
102986 if( pLower ){
102987 Expr *pExpr = pLower->pExpr->pRight;
102988 rc = valueFromExpr(pParse, pExpr, aff, &pLowerVal);
102989 assert( pLower->eOperator==WO_GT || pLower->eOperator==WO_GE );
102990 roundUpLower = (pLower->eOperator==WO_GT) ?1:0;
102992 if( rc==SQLITE_OK && pUpper ){
102993 Expr *pExpr = pUpper->pExpr->pRight;
102994 rc = valueFromExpr(pParse, pExpr, aff, &pUpperVal);
102995 assert( pUpper->eOperator==WO_LT || pUpper->eOperator==WO_LE );
102996 roundUpUpper = (pUpper->eOperator==WO_LE) ?1:0;
102999 if( rc!=SQLITE_OK || (pLowerVal==0 && pUpperVal==0) ){
103000 sqlite3ValueFree(pLowerVal);
103001 sqlite3ValueFree(pUpperVal);
103002 goto range_est_fallback;
103003 }else if( pLowerVal==0 ){
103004 rc = whereRangeRegion(pParse, p, pUpperVal, roundUpUpper, &iUpper);
103005 if( pLower ) iLower = iUpper/2;
103006 }else if( pUpperVal==0 ){
103007 rc = whereRangeRegion(pParse, p, pLowerVal, roundUpLower, &iLower);
103008 if( pUpper ) iUpper = (iLower + SQLITE_INDEX_SAMPLES + 1)/2;
103009 }else{
103010 rc = whereRangeRegion(pParse, p, pUpperVal, roundUpUpper, &iUpper);
103011 if( rc==SQLITE_OK ){
103012 rc = whereRangeRegion(pParse, p, pLowerVal, roundUpLower, &iLower);
103015 WHERETRACE(("range scan regions: %d..%d\n", iLower, iUpper));
103017 iEst = iUpper - iLower;
103018 testcase( iEst==SQLITE_INDEX_SAMPLES );
103019 assert( iEst<=SQLITE_INDEX_SAMPLES );
103020 if( iEst<1 ){
103021 *piEst = 50/SQLITE_INDEX_SAMPLES;
103022 }else{
103023 *piEst = (iEst*100)/SQLITE_INDEX_SAMPLES;
103025 sqlite3ValueFree(pLowerVal);
103026 sqlite3ValueFree(pUpperVal);
103027 return rc;
103029 range_est_fallback:
103030 #else
103031 UNUSED_PARAMETER(pParse);
103032 UNUSED_PARAMETER(p);
103033 UNUSED_PARAMETER(nEq);
103034 #endif
103035 assert( pLower || pUpper );
103036 *piEst = 100;
103037 if( pLower && (pLower->wtFlags & TERM_VNULL)==0 ) *piEst /= 4;
103038 if( pUpper ) *piEst /= 4;
103039 return rc;
103042 #ifdef SQLITE_ENABLE_STAT2
103044 ** Estimate the number of rows that will be returned based on
103045 ** an equality constraint x=VALUE and where that VALUE occurs in
103046 ** the histogram data. This only works when x is the left-most
103047 ** column of an index and sqlite_stat2 histogram data is available
103048 ** for that index. When pExpr==NULL that means the constraint is
103049 ** "x IS NULL" instead of "x=VALUE".
103051 ** Write the estimated row count into *pnRow and return SQLITE_OK.
103052 ** If unable to make an estimate, leave *pnRow unchanged and return
103053 ** non-zero.
103055 ** This routine can fail if it is unable to load a collating sequence
103056 ** required for string comparison, or if unable to allocate memory
103057 ** for a UTF conversion required for comparison. The error is stored
103058 ** in the pParse structure.
103060 static int whereEqualScanEst(
103061 Parse *pParse, /* Parsing & code generating context */
103062 Index *p, /* The index whose left-most column is pTerm */
103063 Expr *pExpr, /* Expression for VALUE in the x=VALUE constraint */
103064 double *pnRow /* Write the revised row estimate here */
103066 sqlite3_value *pRhs = 0; /* VALUE on right-hand side of pTerm */
103067 int iLower, iUpper; /* Range of histogram regions containing pRhs */
103068 u8 aff; /* Column affinity */
103069 int rc; /* Subfunction return code */
103070 double nRowEst; /* New estimate of the number of rows */
103072 assert( p->aSample!=0 );
103073 aff = p->pTable->aCol[p->aiColumn[0]].affinity;
103074 if( pExpr ){
103075 rc = valueFromExpr(pParse, pExpr, aff, &pRhs);
103076 if( rc ) goto whereEqualScanEst_cancel;
103077 }else{
103078 pRhs = sqlite3ValueNew(pParse->db);
103080 if( pRhs==0 ) return SQLITE_NOTFOUND;
103081 rc = whereRangeRegion(pParse, p, pRhs, 0, &iLower);
103082 if( rc ) goto whereEqualScanEst_cancel;
103083 rc = whereRangeRegion(pParse, p, pRhs, 1, &iUpper);
103084 if( rc ) goto whereEqualScanEst_cancel;
103085 WHERETRACE(("equality scan regions: %d..%d\n", iLower, iUpper));
103086 if( iLower>=iUpper ){
103087 nRowEst = p->aiRowEst[0]/(SQLITE_INDEX_SAMPLES*2);
103088 if( nRowEst<*pnRow ) *pnRow = nRowEst;
103089 }else{
103090 nRowEst = (iUpper-iLower)*p->aiRowEst[0]/SQLITE_INDEX_SAMPLES;
103091 *pnRow = nRowEst;
103094 whereEqualScanEst_cancel:
103095 sqlite3ValueFree(pRhs);
103096 return rc;
103098 #endif /* defined(SQLITE_ENABLE_STAT2) */
103100 #ifdef SQLITE_ENABLE_STAT2
103102 ** Estimate the number of rows that will be returned based on
103103 ** an IN constraint where the right-hand side of the IN operator
103104 ** is a list of values. Example:
103106 ** WHERE x IN (1,2,3,4)
103108 ** Write the estimated row count into *pnRow and return SQLITE_OK.
103109 ** If unable to make an estimate, leave *pnRow unchanged and return
103110 ** non-zero.
103112 ** This routine can fail if it is unable to load a collating sequence
103113 ** required for string comparison, or if unable to allocate memory
103114 ** for a UTF conversion required for comparison. The error is stored
103115 ** in the pParse structure.
103117 static int whereInScanEst(
103118 Parse *pParse, /* Parsing & code generating context */
103119 Index *p, /* The index whose left-most column is pTerm */
103120 ExprList *pList, /* The value list on the RHS of "x IN (v1,v2,v3,...)" */
103121 double *pnRow /* Write the revised row estimate here */
103123 sqlite3_value *pVal = 0; /* One value from list */
103124 int iLower, iUpper; /* Range of histogram regions containing pRhs */
103125 u8 aff; /* Column affinity */
103126 int rc = SQLITE_OK; /* Subfunction return code */
103127 double nRowEst; /* New estimate of the number of rows */
103128 int nSpan = 0; /* Number of histogram regions spanned */
103129 int nSingle = 0; /* Histogram regions hit by a single value */
103130 int nNotFound = 0; /* Count of values that are not constants */
103131 int i; /* Loop counter */
103132 u8 aSpan[SQLITE_INDEX_SAMPLES+1]; /* Histogram regions that are spanned */
103133 u8 aSingle[SQLITE_INDEX_SAMPLES+1]; /* Histogram regions hit once */
103135 assert( p->aSample!=0 );
103136 aff = p->pTable->aCol[p->aiColumn[0]].affinity;
103137 memset(aSpan, 0, sizeof(aSpan));
103138 memset(aSingle, 0, sizeof(aSingle));
103139 for(i=0; i<pList->nExpr; i++){
103140 sqlite3ValueFree(pVal);
103141 rc = valueFromExpr(pParse, pList->a[i].pExpr, aff, &pVal);
103142 if( rc ) break;
103143 if( pVal==0 || sqlite3_value_type(pVal)==SQLITE_NULL ){
103144 nNotFound++;
103145 continue;
103147 rc = whereRangeRegion(pParse, p, pVal, 0, &iLower);
103148 if( rc ) break;
103149 rc = whereRangeRegion(pParse, p, pVal, 1, &iUpper);
103150 if( rc ) break;
103151 if( iLower>=iUpper ){
103152 aSingle[iLower] = 1;
103153 }else{
103154 assert( iLower>=0 && iUpper<=SQLITE_INDEX_SAMPLES );
103155 while( iLower<iUpper ) aSpan[iLower++] = 1;
103158 if( rc==SQLITE_OK ){
103159 for(i=nSpan=0; i<=SQLITE_INDEX_SAMPLES; i++){
103160 if( aSpan[i] ){
103161 nSpan++;
103162 }else if( aSingle[i] ){
103163 nSingle++;
103166 nRowEst = (nSpan*2+nSingle)*p->aiRowEst[0]/(2*SQLITE_INDEX_SAMPLES)
103167 + nNotFound*p->aiRowEst[1];
103168 if( nRowEst > p->aiRowEst[0] ) nRowEst = p->aiRowEst[0];
103169 *pnRow = nRowEst;
103170 WHERETRACE(("IN row estimate: nSpan=%d, nSingle=%d, nNotFound=%d, est=%g\n",
103171 nSpan, nSingle, nNotFound, nRowEst));
103173 sqlite3ValueFree(pVal);
103174 return rc;
103176 #endif /* defined(SQLITE_ENABLE_STAT2) */
103180 ** Find the best query plan for accessing a particular table. Write the
103181 ** best query plan and its cost into the WhereCost object supplied as the
103182 ** last parameter.
103184 ** The lowest cost plan wins. The cost is an estimate of the amount of
103185 ** CPU and disk I/O needed to process the requested result.
103186 ** Factors that influence cost include:
103188 ** * The estimated number of rows that will be retrieved. (The
103189 ** fewer the better.)
103191 ** * Whether or not sorting must occur.
103193 ** * Whether or not there must be separate lookups in the
103194 ** index and in the main table.
103196 ** If there was an INDEXED BY clause (pSrc->pIndex) attached to the table in
103197 ** the SQL statement, then this function only considers plans using the
103198 ** named index. If no such plan is found, then the returned cost is
103199 ** SQLITE_BIG_DBL. If a plan is found that uses the named index,
103200 ** then the cost is calculated in the usual way.
103202 ** If a NOT INDEXED clause (pSrc->notIndexed!=0) was attached to the table
103203 ** in the SELECT statement, then no indexes are considered. However, the
103204 ** selected plan may still take advantage of the built-in rowid primary key
103205 ** index.
103207 static void bestBtreeIndex(
103208 Parse *pParse, /* The parsing context */
103209 WhereClause *pWC, /* The WHERE clause */
103210 struct SrcList_item *pSrc, /* The FROM clause term to search */
103211 Bitmask notReady, /* Mask of cursors not available for indexing */
103212 Bitmask notValid, /* Cursors not available for any purpose */
103213 ExprList *pOrderBy, /* The ORDER BY clause */
103214 ExprList *pDistinct, /* The select-list if query is DISTINCT */
103215 WhereCost *pCost /* Lowest cost query plan */
103217 int iCur = pSrc->iCursor; /* The cursor of the table to be accessed */
103218 Index *pProbe; /* An index we are evaluating */
103219 Index *pIdx; /* Copy of pProbe, or zero for IPK index */
103220 int eqTermMask; /* Current mask of valid equality operators */
103221 int idxEqTermMask; /* Index mask of valid equality operators */
103222 Index sPk; /* A fake index object for the primary key */
103223 unsigned int aiRowEstPk[2]; /* The aiRowEst[] value for the sPk index */
103224 int aiColumnPk = -1; /* The aColumn[] value for the sPk index */
103225 int wsFlagMask; /* Allowed flags in pCost->plan.wsFlag */
103227 /* Initialize the cost to a worst-case value */
103228 memset(pCost, 0, sizeof(*pCost));
103229 pCost->rCost = SQLITE_BIG_DBL;
103231 /* If the pSrc table is the right table of a LEFT JOIN then we may not
103232 ** use an index to satisfy IS NULL constraints on that table. This is
103233 ** because columns might end up being NULL if the table does not match -
103234 ** a circumstance which the index cannot help us discover. Ticket #2177.
103236 if( pSrc->jointype & JT_LEFT ){
103237 idxEqTermMask = WO_EQ|WO_IN;
103238 }else{
103239 idxEqTermMask = WO_EQ|WO_IN|WO_ISNULL;
103242 if( pSrc->pIndex ){
103243 /* An INDEXED BY clause specifies a particular index to use */
103244 pIdx = pProbe = pSrc->pIndex;
103245 wsFlagMask = ~(WHERE_ROWID_EQ|WHERE_ROWID_RANGE);
103246 eqTermMask = idxEqTermMask;
103247 }else{
103248 /* There is no INDEXED BY clause. Create a fake Index object in local
103249 ** variable sPk to represent the rowid primary key index. Make this
103250 ** fake index the first in a chain of Index objects with all of the real
103251 ** indices to follow */
103252 Index *pFirst; /* First of real indices on the table */
103253 memset(&sPk, 0, sizeof(Index));
103254 sPk.nColumn = 1;
103255 sPk.aiColumn = &aiColumnPk;
103256 sPk.aiRowEst = aiRowEstPk;
103257 sPk.onError = OE_Replace;
103258 sPk.pTable = pSrc->pTab;
103259 aiRowEstPk[0] = pSrc->pTab->nRowEst;
103260 aiRowEstPk[1] = 1;
103261 pFirst = pSrc->pTab->pIndex;
103262 if( pSrc->notIndexed==0 ){
103263 /* The real indices of the table are only considered if the
103264 ** NOT INDEXED qualifier is omitted from the FROM clause */
103265 sPk.pNext = pFirst;
103267 pProbe = &sPk;
103268 wsFlagMask = ~(
103269 WHERE_COLUMN_IN|WHERE_COLUMN_EQ|WHERE_COLUMN_NULL|WHERE_COLUMN_RANGE
103271 eqTermMask = WO_EQ|WO_IN;
103272 pIdx = 0;
103275 /* Loop over all indices looking for the best one to use
103277 for(; pProbe; pIdx=pProbe=pProbe->pNext){
103278 const unsigned int * const aiRowEst = pProbe->aiRowEst;
103279 double cost; /* Cost of using pProbe */
103280 double nRow; /* Estimated number of rows in result set */
103281 double log10N; /* base-10 logarithm of nRow (inexact) */
103282 int rev; /* True to scan in reverse order */
103283 int wsFlags = 0;
103284 Bitmask used = 0;
103286 /* The following variables are populated based on the properties of
103287 ** index being evaluated. They are then used to determine the expected
103288 ** cost and number of rows returned.
103290 ** nEq:
103291 ** Number of equality terms that can be implemented using the index.
103292 ** In other words, the number of initial fields in the index that
103293 ** are used in == or IN or NOT NULL constraints of the WHERE clause.
103295 ** nInMul:
103296 ** The "in-multiplier". This is an estimate of how many seek operations
103297 ** SQLite must perform on the index in question. For example, if the
103298 ** WHERE clause is:
103300 ** WHERE a IN (1, 2, 3) AND b IN (4, 5, 6)
103302 ** SQLite must perform 9 lookups on an index on (a, b), so nInMul is
103303 ** set to 9. Given the same schema and either of the following WHERE
103304 ** clauses:
103306 ** WHERE a = 1
103307 ** WHERE a >= 2
103309 ** nInMul is set to 1.
103311 ** If there exists a WHERE term of the form "x IN (SELECT ...)", then
103312 ** the sub-select is assumed to return 25 rows for the purposes of
103313 ** determining nInMul.
103315 ** bInEst:
103316 ** Set to true if there was at least one "x IN (SELECT ...)" term used
103317 ** in determining the value of nInMul. Note that the RHS of the
103318 ** IN operator must be a SELECT, not a value list, for this variable
103319 ** to be true.
103321 ** estBound:
103322 ** An estimate on the amount of the table that must be searched. A
103323 ** value of 100 means the entire table is searched. Range constraints
103324 ** might reduce this to a value less than 100 to indicate that only
103325 ** a fraction of the table needs searching. In the absence of
103326 ** sqlite_stat2 ANALYZE data, a single inequality reduces the search
103327 ** space to 1/4rd its original size. So an x>? constraint reduces
103328 ** estBound to 25. Two constraints (x>? AND x<?) reduce estBound to 6.
103330 ** bSort:
103331 ** Boolean. True if there is an ORDER BY clause that will require an
103332 ** external sort (i.e. scanning the index being evaluated will not
103333 ** correctly order records).
103335 ** bLookup:
103336 ** Boolean. True if a table lookup is required for each index entry
103337 ** visited. In other words, true if this is not a covering index.
103338 ** This is always false for the rowid primary key index of a table.
103339 ** For other indexes, it is true unless all the columns of the table
103340 ** used by the SELECT statement are present in the index (such an
103341 ** index is sometimes described as a covering index).
103342 ** For example, given the index on (a, b), the second of the following
103343 ** two queries requires table b-tree lookups in order to find the value
103344 ** of column c, but the first does not because columns a and b are
103345 ** both available in the index.
103347 ** SELECT a, b FROM tbl WHERE a = 1;
103348 ** SELECT a, b, c FROM tbl WHERE a = 1;
103350 int nEq; /* Number of == or IN terms matching index */
103351 int bInEst = 0; /* True if "x IN (SELECT...)" seen */
103352 int nInMul = 1; /* Number of distinct equalities to lookup */
103353 int estBound = 100; /* Estimated reduction in search space */
103354 int nBound = 0; /* Number of range constraints seen */
103355 int bSort = !!pOrderBy; /* True if external sort required */
103356 int bDist = !!pDistinct; /* True if index cannot help with DISTINCT */
103357 int bLookup = 0; /* True if not a covering index */
103358 WhereTerm *pTerm; /* A single term of the WHERE clause */
103359 #ifdef SQLITE_ENABLE_STAT2
103360 WhereTerm *pFirstTerm = 0; /* First term matching the index */
103361 #endif
103363 /* Determine the values of nEq and nInMul */
103364 for(nEq=0; nEq<pProbe->nColumn; nEq++){
103365 int j = pProbe->aiColumn[nEq];
103366 pTerm = findTerm(pWC, iCur, j, notReady, eqTermMask, pIdx);
103367 if( pTerm==0 ) break;
103368 wsFlags |= (WHERE_COLUMN_EQ|WHERE_ROWID_EQ);
103369 if( pTerm->eOperator & WO_IN ){
103370 Expr *pExpr = pTerm->pExpr;
103371 wsFlags |= WHERE_COLUMN_IN;
103372 if( ExprHasProperty(pExpr, EP_xIsSelect) ){
103373 /* "x IN (SELECT ...)": Assume the SELECT returns 25 rows */
103374 nInMul *= 25;
103375 bInEst = 1;
103376 }else if( ALWAYS(pExpr->x.pList && pExpr->x.pList->nExpr) ){
103377 /* "x IN (value, value, ...)" */
103378 nInMul *= pExpr->x.pList->nExpr;
103380 }else if( pTerm->eOperator & WO_ISNULL ){
103381 wsFlags |= WHERE_COLUMN_NULL;
103383 #ifdef SQLITE_ENABLE_STAT2
103384 if( nEq==0 && pProbe->aSample ) pFirstTerm = pTerm;
103385 #endif
103386 used |= pTerm->prereqRight;
103389 /* Determine the value of estBound. */
103390 if( nEq<pProbe->nColumn && pProbe->bUnordered==0 ){
103391 int j = pProbe->aiColumn[nEq];
103392 if( findTerm(pWC, iCur, j, notReady, WO_LT|WO_LE|WO_GT|WO_GE, pIdx) ){
103393 WhereTerm *pTop = findTerm(pWC, iCur, j, notReady, WO_LT|WO_LE, pIdx);
103394 WhereTerm *pBtm = findTerm(pWC, iCur, j, notReady, WO_GT|WO_GE, pIdx);
103395 whereRangeScanEst(pParse, pProbe, nEq, pBtm, pTop, &estBound);
103396 if( pTop ){
103397 nBound = 1;
103398 wsFlags |= WHERE_TOP_LIMIT;
103399 used |= pTop->prereqRight;
103401 if( pBtm ){
103402 nBound++;
103403 wsFlags |= WHERE_BTM_LIMIT;
103404 used |= pBtm->prereqRight;
103406 wsFlags |= (WHERE_COLUMN_RANGE|WHERE_ROWID_RANGE);
103408 }else if( pProbe->onError!=OE_None ){
103409 testcase( wsFlags & WHERE_COLUMN_IN );
103410 testcase( wsFlags & WHERE_COLUMN_NULL );
103411 if( (wsFlags & (WHERE_COLUMN_IN|WHERE_COLUMN_NULL))==0 ){
103412 wsFlags |= WHERE_UNIQUE;
103416 /* If there is an ORDER BY clause and the index being considered will
103417 ** naturally scan rows in the required order, set the appropriate flags
103418 ** in wsFlags. Otherwise, if there is an ORDER BY clause but the index
103419 ** will scan rows in a different order, set the bSort variable. */
103420 if( isSortingIndex(
103421 pParse, pWC->pMaskSet, pProbe, iCur, pOrderBy, nEq, wsFlags, &rev)
103423 bSort = 0;
103424 wsFlags |= WHERE_ROWID_RANGE|WHERE_COLUMN_RANGE|WHERE_ORDERBY;
103425 wsFlags |= (rev ? WHERE_REVERSE : 0);
103428 /* If there is a DISTINCT qualifier and this index will scan rows in
103429 ** order of the DISTINCT expressions, clear bDist and set the appropriate
103430 ** flags in wsFlags. */
103431 if( isDistinctIndex(pParse, pWC, pProbe, iCur, pDistinct, nEq) ){
103432 bDist = 0;
103433 wsFlags |= WHERE_ROWID_RANGE|WHERE_COLUMN_RANGE|WHERE_DISTINCT;
103436 /* If currently calculating the cost of using an index (not the IPK
103437 ** index), determine if all required column data may be obtained without
103438 ** using the main table (i.e. if the index is a covering
103439 ** index for this query). If it is, set the WHERE_IDX_ONLY flag in
103440 ** wsFlags. Otherwise, set the bLookup variable to true. */
103441 if( pIdx && wsFlags ){
103442 Bitmask m = pSrc->colUsed;
103443 int j;
103444 for(j=0; j<pIdx->nColumn; j++){
103445 int x = pIdx->aiColumn[j];
103446 if( x<BMS-1 ){
103447 m &= ~(((Bitmask)1)<<x);
103450 if( m==0 ){
103451 wsFlags |= WHERE_IDX_ONLY;
103452 }else{
103453 bLookup = 1;
103458 ** Estimate the number of rows of output. For an "x IN (SELECT...)"
103459 ** constraint, do not let the estimate exceed half the rows in the table.
103461 nRow = (double)(aiRowEst[nEq] * nInMul);
103462 if( bInEst && nRow*2>aiRowEst[0] ){
103463 nRow = aiRowEst[0]/2;
103464 nInMul = (int)(nRow / aiRowEst[nEq]);
103467 #ifdef SQLITE_ENABLE_STAT2
103468 /* If the constraint is of the form x=VALUE or x IN (E1,E2,...)
103469 ** and we do not think that values of x are unique and if histogram
103470 ** data is available for column x, then it might be possible
103471 ** to get a better estimate on the number of rows based on
103472 ** VALUE and how common that value is according to the histogram.
103474 if( nRow>(double)1 && nEq==1 && pFirstTerm!=0 && aiRowEst[1]>1 ){
103475 if( pFirstTerm->eOperator & (WO_EQ|WO_ISNULL) ){
103476 testcase( pFirstTerm->eOperator==WO_EQ );
103477 testcase( pFirstTerm->eOperator==WO_ISNULL );
103478 whereEqualScanEst(pParse, pProbe, pFirstTerm->pExpr->pRight, &nRow);
103479 }else if( pFirstTerm->eOperator==WO_IN && bInEst==0 ){
103480 whereInScanEst(pParse, pProbe, pFirstTerm->pExpr->x.pList, &nRow);
103483 #endif /* SQLITE_ENABLE_STAT2 */
103485 /* Adjust the number of output rows and downward to reflect rows
103486 ** that are excluded by range constraints.
103488 nRow = (nRow * (double)estBound) / (double)100;
103489 if( nRow<1 ) nRow = 1;
103491 /* Experiments run on real SQLite databases show that the time needed
103492 ** to do a binary search to locate a row in a table or index is roughly
103493 ** log10(N) times the time to move from one row to the next row within
103494 ** a table or index. The actual times can vary, with the size of
103495 ** records being an important factor. Both moves and searches are
103496 ** slower with larger records, presumably because fewer records fit
103497 ** on one page and hence more pages have to be fetched.
103499 ** The ANALYZE command and the sqlite_stat1 and sqlite_stat2 tables do
103500 ** not give us data on the relative sizes of table and index records.
103501 ** So this computation assumes table records are about twice as big
103502 ** as index records
103504 if( (wsFlags & WHERE_NOT_FULLSCAN)==0 ){
103505 /* The cost of a full table scan is a number of move operations equal
103506 ** to the number of rows in the table.
103508 ** We add an additional 4x penalty to full table scans. This causes
103509 ** the cost function to err on the side of choosing an index over
103510 ** choosing a full scan. This 4x full-scan penalty is an arguable
103511 ** decision and one which we expect to revisit in the future. But
103512 ** it seems to be working well enough at the moment.
103514 cost = aiRowEst[0]*4;
103515 }else{
103516 log10N = estLog(aiRowEst[0]);
103517 cost = nRow;
103518 if( pIdx ){
103519 if( bLookup ){
103520 /* For an index lookup followed by a table lookup:
103521 ** nInMul index searches to find the start of each index range
103522 ** + nRow steps through the index
103523 ** + nRow table searches to lookup the table entry using the rowid
103525 cost += (nInMul + nRow)*log10N;
103526 }else{
103527 /* For a covering index:
103528 ** nInMul index searches to find the initial entry
103529 ** + nRow steps through the index
103531 cost += nInMul*log10N;
103533 }else{
103534 /* For a rowid primary key lookup:
103535 ** nInMult table searches to find the initial entry for each range
103536 ** + nRow steps through the table
103538 cost += nInMul*log10N;
103542 /* Add in the estimated cost of sorting the result. Actual experimental
103543 ** measurements of sorting performance in SQLite show that sorting time
103544 ** adds C*N*log10(N) to the cost, where N is the number of rows to be
103545 ** sorted and C is a factor between 1.95 and 4.3. We will split the
103546 ** difference and select C of 3.0.
103548 if( bSort ){
103549 cost += nRow*estLog(nRow)*3;
103551 if( bDist ){
103552 cost += nRow*estLog(nRow)*3;
103555 /**** Cost of using this index has now been computed ****/
103557 /* If there are additional constraints on this table that cannot
103558 ** be used with the current index, but which might lower the number
103559 ** of output rows, adjust the nRow value accordingly. This only
103560 ** matters if the current index is the least costly, so do not bother
103561 ** with this step if we already know this index will not be chosen.
103562 ** Also, never reduce the output row count below 2 using this step.
103564 ** It is critical that the notValid mask be used here instead of
103565 ** the notReady mask. When computing an "optimal" index, the notReady
103566 ** mask will only have one bit set - the bit for the current table.
103567 ** The notValid mask, on the other hand, always has all bits set for
103568 ** tables that are not in outer loops. If notReady is used here instead
103569 ** of notValid, then a optimal index that depends on inner joins loops
103570 ** might be selected even when there exists an optimal index that has
103571 ** no such dependency.
103573 if( nRow>2 && cost<=pCost->rCost ){
103574 int k; /* Loop counter */
103575 int nSkipEq = nEq; /* Number of == constraints to skip */
103576 int nSkipRange = nBound; /* Number of < constraints to skip */
103577 Bitmask thisTab; /* Bitmap for pSrc */
103579 thisTab = getMask(pWC->pMaskSet, iCur);
103580 for(pTerm=pWC->a, k=pWC->nTerm; nRow>2 && k; k--, pTerm++){
103581 if( pTerm->wtFlags & TERM_VIRTUAL ) continue;
103582 if( (pTerm->prereqAll & notValid)!=thisTab ) continue;
103583 if( pTerm->eOperator & (WO_EQ|WO_IN|WO_ISNULL) ){
103584 if( nSkipEq ){
103585 /* Ignore the first nEq equality matches since the index
103586 ** has already accounted for these */
103587 nSkipEq--;
103588 }else{
103589 /* Assume each additional equality match reduces the result
103590 ** set size by a factor of 10 */
103591 nRow /= 10;
103593 }else if( pTerm->eOperator & (WO_LT|WO_LE|WO_GT|WO_GE) ){
103594 if( nSkipRange ){
103595 /* Ignore the first nSkipRange range constraints since the index
103596 ** has already accounted for these */
103597 nSkipRange--;
103598 }else{
103599 /* Assume each additional range constraint reduces the result
103600 ** set size by a factor of 3. Indexed range constraints reduce
103601 ** the search space by a larger factor: 4. We make indexed range
103602 ** more selective intentionally because of the subjective
103603 ** observation that indexed range constraints really are more
103604 ** selective in practice, on average. */
103605 nRow /= 3;
103607 }else if( pTerm->eOperator!=WO_NOOP ){
103608 /* Any other expression lowers the output row count by half */
103609 nRow /= 2;
103612 if( nRow<2 ) nRow = 2;
103616 WHERETRACE((
103617 "%s(%s): nEq=%d nInMul=%d estBound=%d bSort=%d bLookup=%d wsFlags=0x%x\n"
103618 " notReady=0x%llx log10N=%.1f nRow=%.1f cost=%.1f used=0x%llx\n",
103619 pSrc->pTab->zName, (pIdx ? pIdx->zName : "ipk"),
103620 nEq, nInMul, estBound, bSort, bLookup, wsFlags,
103621 notReady, log10N, nRow, cost, used
103624 /* If this index is the best we have seen so far, then record this
103625 ** index and its cost in the pCost structure.
103627 if( (!pIdx || wsFlags)
103628 && (cost<pCost->rCost || (cost<=pCost->rCost && nRow<pCost->plan.nRow))
103630 pCost->rCost = cost;
103631 pCost->used = used;
103632 pCost->plan.nRow = nRow;
103633 pCost->plan.wsFlags = (wsFlags&wsFlagMask);
103634 pCost->plan.nEq = nEq;
103635 pCost->plan.u.pIdx = pIdx;
103638 /* If there was an INDEXED BY clause, then only that one index is
103639 ** considered. */
103640 if( pSrc->pIndex ) break;
103642 /* Reset masks for the next index in the loop */
103643 wsFlagMask = ~(WHERE_ROWID_EQ|WHERE_ROWID_RANGE);
103644 eqTermMask = idxEqTermMask;
103647 /* If there is no ORDER BY clause and the SQLITE_ReverseOrder flag
103648 ** is set, then reverse the order that the index will be scanned
103649 ** in. This is used for application testing, to help find cases
103650 ** where application behaviour depends on the (undefined) order that
103651 ** SQLite outputs rows in in the absence of an ORDER BY clause. */
103652 if( !pOrderBy && pParse->db->flags & SQLITE_ReverseOrder ){
103653 pCost->plan.wsFlags |= WHERE_REVERSE;
103656 assert( pOrderBy || (pCost->plan.wsFlags&WHERE_ORDERBY)==0 );
103657 assert( pCost->plan.u.pIdx==0 || (pCost->plan.wsFlags&WHERE_ROWID_EQ)==0 );
103658 assert( pSrc->pIndex==0
103659 || pCost->plan.u.pIdx==0
103660 || pCost->plan.u.pIdx==pSrc->pIndex
103663 WHERETRACE(("best index is: %s\n",
103664 ((pCost->plan.wsFlags & WHERE_NOT_FULLSCAN)==0 ? "none" :
103665 pCost->plan.u.pIdx ? pCost->plan.u.pIdx->zName : "ipk")
103668 bestOrClauseIndex(pParse, pWC, pSrc, notReady, notValid, pOrderBy, pCost);
103669 bestAutomaticIndex(pParse, pWC, pSrc, notReady, pCost);
103670 pCost->plan.wsFlags |= eqTermMask;
103674 ** Find the query plan for accessing table pSrc->pTab. Write the
103675 ** best query plan and its cost into the WhereCost object supplied
103676 ** as the last parameter. This function may calculate the cost of
103677 ** both real and virtual table scans.
103679 static void bestIndex(
103680 Parse *pParse, /* The parsing context */
103681 WhereClause *pWC, /* The WHERE clause */
103682 struct SrcList_item *pSrc, /* The FROM clause term to search */
103683 Bitmask notReady, /* Mask of cursors not available for indexing */
103684 Bitmask notValid, /* Cursors not available for any purpose */
103685 ExprList *pOrderBy, /* The ORDER BY clause */
103686 WhereCost *pCost /* Lowest cost query plan */
103688 #ifndef SQLITE_OMIT_VIRTUALTABLE
103689 if( IsVirtual(pSrc->pTab) ){
103690 sqlite3_index_info *p = 0;
103691 bestVirtualIndex(pParse, pWC, pSrc, notReady, notValid, pOrderBy, pCost,&p);
103692 if( p->needToFreeIdxStr ){
103693 sqlite3_free(p->idxStr);
103695 sqlite3DbFree(pParse->db, p);
103696 }else
103697 #endif
103699 bestBtreeIndex(pParse, pWC, pSrc, notReady, notValid, pOrderBy, 0, pCost);
103704 ** Disable a term in the WHERE clause. Except, do not disable the term
103705 ** if it controls a LEFT OUTER JOIN and it did not originate in the ON
103706 ** or USING clause of that join.
103708 ** Consider the term t2.z='ok' in the following queries:
103710 ** (1) SELECT * FROM t1 LEFT JOIN t2 ON t1.a=t2.x WHERE t2.z='ok'
103711 ** (2) SELECT * FROM t1 LEFT JOIN t2 ON t1.a=t2.x AND t2.z='ok'
103712 ** (3) SELECT * FROM t1, t2 WHERE t1.a=t2.x AND t2.z='ok'
103714 ** The t2.z='ok' is disabled in the in (2) because it originates
103715 ** in the ON clause. The term is disabled in (3) because it is not part
103716 ** of a LEFT OUTER JOIN. In (1), the term is not disabled.
103718 ** IMPLEMENTATION-OF: R-24597-58655 No tests are done for terms that are
103719 ** completely satisfied by indices.
103721 ** Disabling a term causes that term to not be tested in the inner loop
103722 ** of the join. Disabling is an optimization. When terms are satisfied
103723 ** by indices, we disable them to prevent redundant tests in the inner
103724 ** loop. We would get the correct results if nothing were ever disabled,
103725 ** but joins might run a little slower. The trick is to disable as much
103726 ** as we can without disabling too much. If we disabled in (1), we'd get
103727 ** the wrong answer. See ticket #813.
103729 static void disableTerm(WhereLevel *pLevel, WhereTerm *pTerm){
103730 if( pTerm
103731 && (pTerm->wtFlags & TERM_CODED)==0
103732 && (pLevel->iLeftJoin==0 || ExprHasProperty(pTerm->pExpr, EP_FromJoin))
103734 pTerm->wtFlags |= TERM_CODED;
103735 if( pTerm->iParent>=0 ){
103736 WhereTerm *pOther = &pTerm->pWC->a[pTerm->iParent];
103737 if( (--pOther->nChild)==0 ){
103738 disableTerm(pLevel, pOther);
103745 ** Code an OP_Affinity opcode to apply the column affinity string zAff
103746 ** to the n registers starting at base.
103748 ** As an optimization, SQLITE_AFF_NONE entries (which are no-ops) at the
103749 ** beginning and end of zAff are ignored. If all entries in zAff are
103750 ** SQLITE_AFF_NONE, then no code gets generated.
103752 ** This routine makes its own copy of zAff so that the caller is free
103753 ** to modify zAff after this routine returns.
103755 static void codeApplyAffinity(Parse *pParse, int base, int n, char *zAff){
103756 Vdbe *v = pParse->pVdbe;
103757 if( zAff==0 ){
103758 assert( pParse->db->mallocFailed );
103759 return;
103761 assert( v!=0 );
103763 /* Adjust base and n to skip over SQLITE_AFF_NONE entries at the beginning
103764 ** and end of the affinity string.
103766 while( n>0 && zAff[0]==SQLITE_AFF_NONE ){
103768 base++;
103769 zAff++;
103771 while( n>1 && zAff[n-1]==SQLITE_AFF_NONE ){
103775 /* Code the OP_Affinity opcode if there is anything left to do. */
103776 if( n>0 ){
103777 sqlite3VdbeAddOp2(v, OP_Affinity, base, n);
103778 sqlite3VdbeChangeP4(v, -1, zAff, n);
103779 sqlite3ExprCacheAffinityChange(pParse, base, n);
103785 ** Generate code for a single equality term of the WHERE clause. An equality
103786 ** term can be either X=expr or X IN (...). pTerm is the term to be
103787 ** coded.
103789 ** The current value for the constraint is left in register iReg.
103791 ** For a constraint of the form X=expr, the expression is evaluated and its
103792 ** result is left on the stack. For constraints of the form X IN (...)
103793 ** this routine sets up a loop that will iterate over all values of X.
103795 static int codeEqualityTerm(
103796 Parse *pParse, /* The parsing context */
103797 WhereTerm *pTerm, /* The term of the WHERE clause to be coded */
103798 WhereLevel *pLevel, /* When level of the FROM clause we are working on */
103799 int iTarget /* Attempt to leave results in this register */
103801 Expr *pX = pTerm->pExpr;
103802 Vdbe *v = pParse->pVdbe;
103803 int iReg; /* Register holding results */
103805 assert( iTarget>0 );
103806 if( pX->op==TK_EQ ){
103807 iReg = sqlite3ExprCodeTarget(pParse, pX->pRight, iTarget);
103808 }else if( pX->op==TK_ISNULL ){
103809 iReg = iTarget;
103810 sqlite3VdbeAddOp2(v, OP_Null, 0, iReg);
103811 #ifndef SQLITE_OMIT_SUBQUERY
103812 }else{
103813 int eType;
103814 int iTab;
103815 struct InLoop *pIn;
103817 assert( pX->op==TK_IN );
103818 iReg = iTarget;
103819 eType = sqlite3FindInIndex(pParse, pX, 0);
103820 iTab = pX->iTable;
103821 sqlite3VdbeAddOp2(v, OP_Rewind, iTab, 0);
103822 assert( pLevel->plan.wsFlags & WHERE_IN_ABLE );
103823 if( pLevel->u.in.nIn==0 ){
103824 pLevel->addrNxt = sqlite3VdbeMakeLabel(v);
103826 pLevel->u.in.nIn++;
103827 pLevel->u.in.aInLoop =
103828 sqlite3DbReallocOrFree(pParse->db, pLevel->u.in.aInLoop,
103829 sizeof(pLevel->u.in.aInLoop[0])*pLevel->u.in.nIn);
103830 pIn = pLevel->u.in.aInLoop;
103831 if( pIn ){
103832 pIn += pLevel->u.in.nIn - 1;
103833 pIn->iCur = iTab;
103834 if( eType==IN_INDEX_ROWID ){
103835 pIn->addrInTop = sqlite3VdbeAddOp2(v, OP_Rowid, iTab, iReg);
103836 }else{
103837 pIn->addrInTop = sqlite3VdbeAddOp3(v, OP_Column, iTab, 0, iReg);
103839 sqlite3VdbeAddOp1(v, OP_IsNull, iReg);
103840 }else{
103841 pLevel->u.in.nIn = 0;
103843 #endif
103845 disableTerm(pLevel, pTerm);
103846 return iReg;
103850 ** Generate code that will evaluate all == and IN constraints for an
103851 ** index.
103853 ** For example, consider table t1(a,b,c,d,e,f) with index i1(a,b,c).
103854 ** Suppose the WHERE clause is this: a==5 AND b IN (1,2,3) AND c>5 AND c<10
103855 ** The index has as many as three equality constraints, but in this
103856 ** example, the third "c" value is an inequality. So only two
103857 ** constraints are coded. This routine will generate code to evaluate
103858 ** a==5 and b IN (1,2,3). The current values for a and b will be stored
103859 ** in consecutive registers and the index of the first register is returned.
103861 ** In the example above nEq==2. But this subroutine works for any value
103862 ** of nEq including 0. If nEq==0, this routine is nearly a no-op.
103863 ** The only thing it does is allocate the pLevel->iMem memory cell and
103864 ** compute the affinity string.
103866 ** This routine always allocates at least one memory cell and returns
103867 ** the index of that memory cell. The code that
103868 ** calls this routine will use that memory cell to store the termination
103869 ** key value of the loop. If one or more IN operators appear, then
103870 ** this routine allocates an additional nEq memory cells for internal
103871 ** use.
103873 ** Before returning, *pzAff is set to point to a buffer containing a
103874 ** copy of the column affinity string of the index allocated using
103875 ** sqlite3DbMalloc(). Except, entries in the copy of the string associated
103876 ** with equality constraints that use NONE affinity are set to
103877 ** SQLITE_AFF_NONE. This is to deal with SQL such as the following:
103879 ** CREATE TABLE t1(a TEXT PRIMARY KEY, b);
103880 ** SELECT ... FROM t1 AS t2, t1 WHERE t1.a = t2.b;
103882 ** In the example above, the index on t1(a) has TEXT affinity. But since
103883 ** the right hand side of the equality constraint (t2.b) has NONE affinity,
103884 ** no conversion should be attempted before using a t2.b value as part of
103885 ** a key to search the index. Hence the first byte in the returned affinity
103886 ** string in this example would be set to SQLITE_AFF_NONE.
103888 static int codeAllEqualityTerms(
103889 Parse *pParse, /* Parsing context */
103890 WhereLevel *pLevel, /* Which nested loop of the FROM we are coding */
103891 WhereClause *pWC, /* The WHERE clause */
103892 Bitmask notReady, /* Which parts of FROM have not yet been coded */
103893 int nExtraReg, /* Number of extra registers to allocate */
103894 char **pzAff /* OUT: Set to point to affinity string */
103896 int nEq = pLevel->plan.nEq; /* The number of == or IN constraints to code */
103897 Vdbe *v = pParse->pVdbe; /* The vm under construction */
103898 Index *pIdx; /* The index being used for this loop */
103899 int iCur = pLevel->iTabCur; /* The cursor of the table */
103900 WhereTerm *pTerm; /* A single constraint term */
103901 int j; /* Loop counter */
103902 int regBase; /* Base register */
103903 int nReg; /* Number of registers to allocate */
103904 char *zAff; /* Affinity string to return */
103906 /* This module is only called on query plans that use an index. */
103907 assert( pLevel->plan.wsFlags & WHERE_INDEXED );
103908 pIdx = pLevel->plan.u.pIdx;
103910 /* Figure out how many memory cells we will need then allocate them.
103912 regBase = pParse->nMem + 1;
103913 nReg = pLevel->plan.nEq + nExtraReg;
103914 pParse->nMem += nReg;
103916 zAff = sqlite3DbStrDup(pParse->db, sqlite3IndexAffinityStr(v, pIdx));
103917 if( !zAff ){
103918 pParse->db->mallocFailed = 1;
103921 /* Evaluate the equality constraints
103923 assert( pIdx->nColumn>=nEq );
103924 for(j=0; j<nEq; j++){
103925 int r1;
103926 int k = pIdx->aiColumn[j];
103927 pTerm = findTerm(pWC, iCur, k, notReady, pLevel->plan.wsFlags, pIdx);
103928 if( NEVER(pTerm==0) ) break;
103929 /* The following true for indices with redundant columns.
103930 ** Ex: CREATE INDEX i1 ON t1(a,b,a); SELECT * FROM t1 WHERE a=0 AND b=0; */
103931 testcase( (pTerm->wtFlags & TERM_CODED)!=0 );
103932 testcase( pTerm->wtFlags & TERM_VIRTUAL ); /* EV: R-30575-11662 */
103933 r1 = codeEqualityTerm(pParse, pTerm, pLevel, regBase+j);
103934 if( r1!=regBase+j ){
103935 if( nReg==1 ){
103936 sqlite3ReleaseTempReg(pParse, regBase);
103937 regBase = r1;
103938 }else{
103939 sqlite3VdbeAddOp2(v, OP_SCopy, r1, regBase+j);
103942 testcase( pTerm->eOperator & WO_ISNULL );
103943 testcase( pTerm->eOperator & WO_IN );
103944 if( (pTerm->eOperator & (WO_ISNULL|WO_IN))==0 ){
103945 Expr *pRight = pTerm->pExpr->pRight;
103946 sqlite3ExprCodeIsNullJump(v, pRight, regBase+j, pLevel->addrBrk);
103947 if( zAff ){
103948 if( sqlite3CompareAffinity(pRight, zAff[j])==SQLITE_AFF_NONE ){
103949 zAff[j] = SQLITE_AFF_NONE;
103951 if( sqlite3ExprNeedsNoAffinityChange(pRight, zAff[j]) ){
103952 zAff[j] = SQLITE_AFF_NONE;
103957 *pzAff = zAff;
103958 return regBase;
103961 #ifndef SQLITE_OMIT_EXPLAIN
103963 ** This routine is a helper for explainIndexRange() below
103965 ** pStr holds the text of an expression that we are building up one term
103966 ** at a time. This routine adds a new term to the end of the expression.
103967 ** Terms are separated by AND so add the "AND" text for second and subsequent
103968 ** terms only.
103970 static void explainAppendTerm(
103971 StrAccum *pStr, /* The text expression being built */
103972 int iTerm, /* Index of this term. First is zero */
103973 const char *zColumn, /* Name of the column */
103974 const char *zOp /* Name of the operator */
103976 if( iTerm ) sqlite3StrAccumAppend(pStr, " AND ", 5);
103977 sqlite3StrAccumAppend(pStr, zColumn, -1);
103978 sqlite3StrAccumAppend(pStr, zOp, 1);
103979 sqlite3StrAccumAppend(pStr, "?", 1);
103983 ** Argument pLevel describes a strategy for scanning table pTab. This
103984 ** function returns a pointer to a string buffer containing a description
103985 ** of the subset of table rows scanned by the strategy in the form of an
103986 ** SQL expression. Or, if all rows are scanned, NULL is returned.
103988 ** For example, if the query:
103990 ** SELECT * FROM t1 WHERE a=1 AND b>2;
103992 ** is run and there is an index on (a, b), then this function returns a
103993 ** string similar to:
103995 ** "a=? AND b>?"
103997 ** The returned pointer points to memory obtained from sqlite3DbMalloc().
103998 ** It is the responsibility of the caller to free the buffer when it is
103999 ** no longer required.
104001 static char *explainIndexRange(sqlite3 *db, WhereLevel *pLevel, Table *pTab){
104002 WherePlan *pPlan = &pLevel->plan;
104003 Index *pIndex = pPlan->u.pIdx;
104004 int nEq = pPlan->nEq;
104005 int i, j;
104006 Column *aCol = pTab->aCol;
104007 int *aiColumn = pIndex->aiColumn;
104008 StrAccum txt;
104010 if( nEq==0 && (pPlan->wsFlags & (WHERE_BTM_LIMIT|WHERE_TOP_LIMIT))==0 ){
104011 return 0;
104013 sqlite3StrAccumInit(&txt, 0, 0, SQLITE_MAX_LENGTH);
104014 txt.db = db;
104015 sqlite3StrAccumAppend(&txt, " (", 2);
104016 for(i=0; i<nEq; i++){
104017 explainAppendTerm(&txt, i, aCol[aiColumn[i]].zName, "=");
104020 j = i;
104021 if( pPlan->wsFlags&WHERE_BTM_LIMIT ){
104022 explainAppendTerm(&txt, i++, aCol[aiColumn[j]].zName, ">");
104024 if( pPlan->wsFlags&WHERE_TOP_LIMIT ){
104025 explainAppendTerm(&txt, i, aCol[aiColumn[j]].zName, "<");
104027 sqlite3StrAccumAppend(&txt, ")", 1);
104028 return sqlite3StrAccumFinish(&txt);
104032 ** This function is a no-op unless currently processing an EXPLAIN QUERY PLAN
104033 ** command. If the query being compiled is an EXPLAIN QUERY PLAN, a single
104034 ** record is added to the output to describe the table scan strategy in
104035 ** pLevel.
104037 static void explainOneScan(
104038 Parse *pParse, /* Parse context */
104039 SrcList *pTabList, /* Table list this loop refers to */
104040 WhereLevel *pLevel, /* Scan to write OP_Explain opcode for */
104041 int iLevel, /* Value for "level" column of output */
104042 int iFrom, /* Value for "from" column of output */
104043 u16 wctrlFlags /* Flags passed to sqlite3WhereBegin() */
104045 if( pParse->explain==2 ){
104046 u32 flags = pLevel->plan.wsFlags;
104047 struct SrcList_item *pItem = &pTabList->a[pLevel->iFrom];
104048 Vdbe *v = pParse->pVdbe; /* VM being constructed */
104049 sqlite3 *db = pParse->db; /* Database handle */
104050 char *zMsg; /* Text to add to EQP output */
104051 sqlite3_int64 nRow; /* Expected number of rows visited by scan */
104052 int iId = pParse->iSelectId; /* Select id (left-most output column) */
104053 int isSearch; /* True for a SEARCH. False for SCAN. */
104055 if( (flags&WHERE_MULTI_OR) || (wctrlFlags&WHERE_ONETABLE_ONLY) ) return;
104057 isSearch = (pLevel->plan.nEq>0)
104058 || (flags&(WHERE_BTM_LIMIT|WHERE_TOP_LIMIT))!=0
104059 || (wctrlFlags&(WHERE_ORDERBY_MIN|WHERE_ORDERBY_MAX));
104061 zMsg = sqlite3MPrintf(db, "%s", isSearch?"SEARCH":"SCAN");
104062 if( pItem->pSelect ){
104063 zMsg = sqlite3MAppendf(db, zMsg, "%s SUBQUERY %d", zMsg,pItem->iSelectId);
104064 }else{
104065 zMsg = sqlite3MAppendf(db, zMsg, "%s TABLE %s", zMsg, pItem->zName);
104068 if( pItem->zAlias ){
104069 zMsg = sqlite3MAppendf(db, zMsg, "%s AS %s", zMsg, pItem->zAlias);
104071 if( (flags & WHERE_INDEXED)!=0 ){
104072 char *zWhere = explainIndexRange(db, pLevel, pItem->pTab);
104073 zMsg = sqlite3MAppendf(db, zMsg, "%s USING %s%sINDEX%s%s%s", zMsg,
104074 ((flags & WHERE_TEMP_INDEX)?"AUTOMATIC ":""),
104075 ((flags & WHERE_IDX_ONLY)?"COVERING ":""),
104076 ((flags & WHERE_TEMP_INDEX)?"":" "),
104077 ((flags & WHERE_TEMP_INDEX)?"": pLevel->plan.u.pIdx->zName),
104078 zWhere
104080 sqlite3DbFree(db, zWhere);
104081 }else if( flags & (WHERE_ROWID_EQ|WHERE_ROWID_RANGE) ){
104082 zMsg = sqlite3MAppendf(db, zMsg, "%s USING INTEGER PRIMARY KEY", zMsg);
104084 if( flags&WHERE_ROWID_EQ ){
104085 zMsg = sqlite3MAppendf(db, zMsg, "%s (rowid=?)", zMsg);
104086 }else if( (flags&WHERE_BOTH_LIMIT)==WHERE_BOTH_LIMIT ){
104087 zMsg = sqlite3MAppendf(db, zMsg, "%s (rowid>? AND rowid<?)", zMsg);
104088 }else if( flags&WHERE_BTM_LIMIT ){
104089 zMsg = sqlite3MAppendf(db, zMsg, "%s (rowid>?)", zMsg);
104090 }else if( flags&WHERE_TOP_LIMIT ){
104091 zMsg = sqlite3MAppendf(db, zMsg, "%s (rowid<?)", zMsg);
104094 #ifndef SQLITE_OMIT_VIRTUALTABLE
104095 else if( (flags & WHERE_VIRTUALTABLE)!=0 ){
104096 sqlite3_index_info *pVtabIdx = pLevel->plan.u.pVtabIdx;
104097 zMsg = sqlite3MAppendf(db, zMsg, "%s VIRTUAL TABLE INDEX %d:%s", zMsg,
104098 pVtabIdx->idxNum, pVtabIdx->idxStr);
104100 #endif
104101 if( wctrlFlags&(WHERE_ORDERBY_MIN|WHERE_ORDERBY_MAX) ){
104102 testcase( wctrlFlags & WHERE_ORDERBY_MIN );
104103 nRow = 1;
104104 }else{
104105 nRow = (sqlite3_int64)pLevel->plan.nRow;
104107 zMsg = sqlite3MAppendf(db, zMsg, "%s (~%lld rows)", zMsg, nRow);
104108 sqlite3VdbeAddOp4(v, OP_Explain, iId, iLevel, iFrom, zMsg, P4_DYNAMIC);
104111 #else
104112 # define explainOneScan(u,v,w,x,y,z)
104113 #endif /* SQLITE_OMIT_EXPLAIN */
104117 ** Generate code for the start of the iLevel-th loop in the WHERE clause
104118 ** implementation described by pWInfo.
104120 static Bitmask codeOneLoopStart(
104121 WhereInfo *pWInfo, /* Complete information about the WHERE clause */
104122 int iLevel, /* Which level of pWInfo->a[] should be coded */
104123 u16 wctrlFlags, /* One of the WHERE_* flags defined in sqliteInt.h */
104124 Bitmask notReady /* Which tables are currently available */
104126 int j, k; /* Loop counters */
104127 int iCur; /* The VDBE cursor for the table */
104128 int addrNxt; /* Where to jump to continue with the next IN case */
104129 int omitTable; /* True if we use the index only */
104130 int bRev; /* True if we need to scan in reverse order */
104131 WhereLevel *pLevel; /* The where level to be coded */
104132 WhereClause *pWC; /* Decomposition of the entire WHERE clause */
104133 WhereTerm *pTerm; /* A WHERE clause term */
104134 Parse *pParse; /* Parsing context */
104135 Vdbe *v; /* The prepared stmt under constructions */
104136 struct SrcList_item *pTabItem; /* FROM clause term being coded */
104137 int addrBrk; /* Jump here to break out of the loop */
104138 int addrCont; /* Jump here to continue with next cycle */
104139 int iRowidReg = 0; /* Rowid is stored in this register, if not zero */
104140 int iReleaseReg = 0; /* Temp register to free before returning */
104142 pParse = pWInfo->pParse;
104143 v = pParse->pVdbe;
104144 pWC = pWInfo->pWC;
104145 pLevel = &pWInfo->a[iLevel];
104146 pTabItem = &pWInfo->pTabList->a[pLevel->iFrom];
104147 iCur = pTabItem->iCursor;
104148 bRev = (pLevel->plan.wsFlags & WHERE_REVERSE)!=0;
104149 omitTable = (pLevel->plan.wsFlags & WHERE_IDX_ONLY)!=0
104150 && (wctrlFlags & WHERE_FORCE_TABLE)==0;
104152 /* Create labels for the "break" and "continue" instructions
104153 ** for the current loop. Jump to addrBrk to break out of a loop.
104154 ** Jump to cont to go immediately to the next iteration of the
104155 ** loop.
104157 ** When there is an IN operator, we also have a "addrNxt" label that
104158 ** means to continue with the next IN value combination. When
104159 ** there are no IN operators in the constraints, the "addrNxt" label
104160 ** is the same as "addrBrk".
104162 addrBrk = pLevel->addrBrk = pLevel->addrNxt = sqlite3VdbeMakeLabel(v);
104163 addrCont = pLevel->addrCont = sqlite3VdbeMakeLabel(v);
104165 /* If this is the right table of a LEFT OUTER JOIN, allocate and
104166 ** initialize a memory cell that records if this table matches any
104167 ** row of the left table of the join.
104169 if( pLevel->iFrom>0 && (pTabItem[0].jointype & JT_LEFT)!=0 ){
104170 pLevel->iLeftJoin = ++pParse->nMem;
104171 sqlite3VdbeAddOp2(v, OP_Integer, 0, pLevel->iLeftJoin);
104172 VdbeComment((v, "init LEFT JOIN no-match flag"));
104175 #ifndef SQLITE_OMIT_VIRTUALTABLE
104176 if( (pLevel->plan.wsFlags & WHERE_VIRTUALTABLE)!=0 ){
104177 /* Case 0: The table is a virtual-table. Use the VFilter and VNext
104178 ** to access the data.
104180 int iReg; /* P3 Value for OP_VFilter */
104181 sqlite3_index_info *pVtabIdx = pLevel->plan.u.pVtabIdx;
104182 int nConstraint = pVtabIdx->nConstraint;
104183 struct sqlite3_index_constraint_usage *aUsage =
104184 pVtabIdx->aConstraintUsage;
104185 const struct sqlite3_index_constraint *aConstraint =
104186 pVtabIdx->aConstraint;
104188 sqlite3ExprCachePush(pParse);
104189 iReg = sqlite3GetTempRange(pParse, nConstraint+2);
104190 for(j=1; j<=nConstraint; j++){
104191 for(k=0; k<nConstraint; k++){
104192 if( aUsage[k].argvIndex==j ){
104193 int iTerm = aConstraint[k].iTermOffset;
104194 sqlite3ExprCode(pParse, pWC->a[iTerm].pExpr->pRight, iReg+j+1);
104195 break;
104198 if( k==nConstraint ) break;
104200 sqlite3VdbeAddOp2(v, OP_Integer, pVtabIdx->idxNum, iReg);
104201 sqlite3VdbeAddOp2(v, OP_Integer, j-1, iReg+1);
104202 sqlite3VdbeAddOp4(v, OP_VFilter, iCur, addrBrk, iReg, pVtabIdx->idxStr,
104203 pVtabIdx->needToFreeIdxStr ? P4_MPRINTF : P4_STATIC);
104204 pVtabIdx->needToFreeIdxStr = 0;
104205 for(j=0; j<nConstraint; j++){
104206 if( aUsage[j].omit ){
104207 int iTerm = aConstraint[j].iTermOffset;
104208 disableTerm(pLevel, &pWC->a[iTerm]);
104211 pLevel->op = OP_VNext;
104212 pLevel->p1 = iCur;
104213 pLevel->p2 = sqlite3VdbeCurrentAddr(v);
104214 sqlite3ReleaseTempRange(pParse, iReg, nConstraint+2);
104215 sqlite3ExprCachePop(pParse, 1);
104216 }else
104217 #endif /* SQLITE_OMIT_VIRTUALTABLE */
104219 if( pLevel->plan.wsFlags & WHERE_ROWID_EQ ){
104220 /* Case 1: We can directly reference a single row using an
104221 ** equality comparison against the ROWID field. Or
104222 ** we reference multiple rows using a "rowid IN (...)"
104223 ** construct.
104225 iReleaseReg = sqlite3GetTempReg(pParse);
104226 pTerm = findTerm(pWC, iCur, -1, notReady, WO_EQ|WO_IN, 0);
104227 assert( pTerm!=0 );
104228 assert( pTerm->pExpr!=0 );
104229 assert( pTerm->leftCursor==iCur );
104230 assert( omitTable==0 );
104231 testcase( pTerm->wtFlags & TERM_VIRTUAL ); /* EV: R-30575-11662 */
104232 iRowidReg = codeEqualityTerm(pParse, pTerm, pLevel, iReleaseReg);
104233 addrNxt = pLevel->addrNxt;
104234 sqlite3VdbeAddOp2(v, OP_MustBeInt, iRowidReg, addrNxt);
104235 sqlite3VdbeAddOp3(v, OP_NotExists, iCur, addrNxt, iRowidReg);
104236 sqlite3ExprCacheStore(pParse, iCur, -1, iRowidReg);
104237 VdbeComment((v, "pk"));
104238 pLevel->op = OP_Noop;
104239 }else if( pLevel->plan.wsFlags & WHERE_ROWID_RANGE ){
104240 /* Case 2: We have an inequality comparison against the ROWID field.
104242 int testOp = OP_Noop;
104243 int start;
104244 int memEndValue = 0;
104245 WhereTerm *pStart, *pEnd;
104247 assert( omitTable==0 );
104248 pStart = findTerm(pWC, iCur, -1, notReady, WO_GT|WO_GE, 0);
104249 pEnd = findTerm(pWC, iCur, -1, notReady, WO_LT|WO_LE, 0);
104250 if( bRev ){
104251 pTerm = pStart;
104252 pStart = pEnd;
104253 pEnd = pTerm;
104255 if( pStart ){
104256 Expr *pX; /* The expression that defines the start bound */
104257 int r1, rTemp; /* Registers for holding the start boundary */
104259 /* The following constant maps TK_xx codes into corresponding
104260 ** seek opcodes. It depends on a particular ordering of TK_xx
104262 const u8 aMoveOp[] = {
104263 /* TK_GT */ OP_SeekGt,
104264 /* TK_LE */ OP_SeekLe,
104265 /* TK_LT */ OP_SeekLt,
104266 /* TK_GE */ OP_SeekGe
104268 assert( TK_LE==TK_GT+1 ); /* Make sure the ordering.. */
104269 assert( TK_LT==TK_GT+2 ); /* ... of the TK_xx values... */
104270 assert( TK_GE==TK_GT+3 ); /* ... is correcct. */
104272 testcase( pStart->wtFlags & TERM_VIRTUAL ); /* EV: R-30575-11662 */
104273 pX = pStart->pExpr;
104274 assert( pX!=0 );
104275 assert( pStart->leftCursor==iCur );
104276 r1 = sqlite3ExprCodeTemp(pParse, pX->pRight, &rTemp);
104277 sqlite3VdbeAddOp3(v, aMoveOp[pX->op-TK_GT], iCur, addrBrk, r1);
104278 VdbeComment((v, "pk"));
104279 sqlite3ExprCacheAffinityChange(pParse, r1, 1);
104280 sqlite3ReleaseTempReg(pParse, rTemp);
104281 disableTerm(pLevel, pStart);
104282 }else{
104283 sqlite3VdbeAddOp2(v, bRev ? OP_Last : OP_Rewind, iCur, addrBrk);
104285 if( pEnd ){
104286 Expr *pX;
104287 pX = pEnd->pExpr;
104288 assert( pX!=0 );
104289 assert( pEnd->leftCursor==iCur );
104290 testcase( pEnd->wtFlags & TERM_VIRTUAL ); /* EV: R-30575-11662 */
104291 memEndValue = ++pParse->nMem;
104292 sqlite3ExprCode(pParse, pX->pRight, memEndValue);
104293 if( pX->op==TK_LT || pX->op==TK_GT ){
104294 testOp = bRev ? OP_Le : OP_Ge;
104295 }else{
104296 testOp = bRev ? OP_Lt : OP_Gt;
104298 disableTerm(pLevel, pEnd);
104300 start = sqlite3VdbeCurrentAddr(v);
104301 pLevel->op = bRev ? OP_Prev : OP_Next;
104302 pLevel->p1 = iCur;
104303 pLevel->p2 = start;
104304 if( pStart==0 && pEnd==0 ){
104305 pLevel->p5 = SQLITE_STMTSTATUS_FULLSCAN_STEP;
104306 }else{
104307 assert( pLevel->p5==0 );
104309 if( testOp!=OP_Noop ){
104310 iRowidReg = iReleaseReg = sqlite3GetTempReg(pParse);
104311 sqlite3VdbeAddOp2(v, OP_Rowid, iCur, iRowidReg);
104312 sqlite3ExprCacheStore(pParse, iCur, -1, iRowidReg);
104313 sqlite3VdbeAddOp3(v, testOp, memEndValue, addrBrk, iRowidReg);
104314 sqlite3VdbeChangeP5(v, SQLITE_AFF_NUMERIC | SQLITE_JUMPIFNULL);
104316 }else if( pLevel->plan.wsFlags & (WHERE_COLUMN_RANGE|WHERE_COLUMN_EQ) ){
104317 /* Case 3: A scan using an index.
104319 ** The WHERE clause may contain zero or more equality
104320 ** terms ("==" or "IN" operators) that refer to the N
104321 ** left-most columns of the index. It may also contain
104322 ** inequality constraints (>, <, >= or <=) on the indexed
104323 ** column that immediately follows the N equalities. Only
104324 ** the right-most column can be an inequality - the rest must
104325 ** use the "==" and "IN" operators. For example, if the
104326 ** index is on (x,y,z), then the following clauses are all
104327 ** optimized:
104329 ** x=5
104330 ** x=5 AND y=10
104331 ** x=5 AND y<10
104332 ** x=5 AND y>5 AND y<10
104333 ** x=5 AND y=5 AND z<=10
104335 ** The z<10 term of the following cannot be used, only
104336 ** the x=5 term:
104338 ** x=5 AND z<10
104340 ** N may be zero if there are inequality constraints.
104341 ** If there are no inequality constraints, then N is at
104342 ** least one.
104344 ** This case is also used when there are no WHERE clause
104345 ** constraints but an index is selected anyway, in order
104346 ** to force the output order to conform to an ORDER BY.
104348 static const u8 aStartOp[] = {
104351 OP_Rewind, /* 2: (!start_constraints && startEq && !bRev) */
104352 OP_Last, /* 3: (!start_constraints && startEq && bRev) */
104353 OP_SeekGt, /* 4: (start_constraints && !startEq && !bRev) */
104354 OP_SeekLt, /* 5: (start_constraints && !startEq && bRev) */
104355 OP_SeekGe, /* 6: (start_constraints && startEq && !bRev) */
104356 OP_SeekLe /* 7: (start_constraints && startEq && bRev) */
104358 static const u8 aEndOp[] = {
104359 OP_Noop, /* 0: (!end_constraints) */
104360 OP_IdxGE, /* 1: (end_constraints && !bRev) */
104361 OP_IdxLT /* 2: (end_constraints && bRev) */
104363 int nEq = pLevel->plan.nEq; /* Number of == or IN terms */
104364 int isMinQuery = 0; /* If this is an optimized SELECT min(x).. */
104365 int regBase; /* Base register holding constraint values */
104366 int r1; /* Temp register */
104367 WhereTerm *pRangeStart = 0; /* Inequality constraint at range start */
104368 WhereTerm *pRangeEnd = 0; /* Inequality constraint at range end */
104369 int startEq; /* True if range start uses ==, >= or <= */
104370 int endEq; /* True if range end uses ==, >= or <= */
104371 int start_constraints; /* Start of range is constrained */
104372 int nConstraint; /* Number of constraint terms */
104373 Index *pIdx; /* The index we will be using */
104374 int iIdxCur; /* The VDBE cursor for the index */
104375 int nExtraReg = 0; /* Number of extra registers needed */
104376 int op; /* Instruction opcode */
104377 char *zStartAff; /* Affinity for start of range constraint */
104378 char *zEndAff; /* Affinity for end of range constraint */
104380 pIdx = pLevel->plan.u.pIdx;
104381 iIdxCur = pLevel->iIdxCur;
104382 k = pIdx->aiColumn[nEq]; /* Column for inequality constraints */
104384 /* If this loop satisfies a sort order (pOrderBy) request that
104385 ** was passed to this function to implement a "SELECT min(x) ..."
104386 ** query, then the caller will only allow the loop to run for
104387 ** a single iteration. This means that the first row returned
104388 ** should not have a NULL value stored in 'x'. If column 'x' is
104389 ** the first one after the nEq equality constraints in the index,
104390 ** this requires some special handling.
104392 if( (wctrlFlags&WHERE_ORDERBY_MIN)!=0
104393 && (pLevel->plan.wsFlags&WHERE_ORDERBY)
104394 && (pIdx->nColumn>nEq)
104396 /* assert( pOrderBy->nExpr==1 ); */
104397 /* assert( pOrderBy->a[0].pExpr->iColumn==pIdx->aiColumn[nEq] ); */
104398 isMinQuery = 1;
104399 nExtraReg = 1;
104402 /* Find any inequality constraint terms for the start and end
104403 ** of the range.
104405 if( pLevel->plan.wsFlags & WHERE_TOP_LIMIT ){
104406 pRangeEnd = findTerm(pWC, iCur, k, notReady, (WO_LT|WO_LE), pIdx);
104407 nExtraReg = 1;
104409 if( pLevel->plan.wsFlags & WHERE_BTM_LIMIT ){
104410 pRangeStart = findTerm(pWC, iCur, k, notReady, (WO_GT|WO_GE), pIdx);
104411 nExtraReg = 1;
104414 /* Generate code to evaluate all constraint terms using == or IN
104415 ** and store the values of those terms in an array of registers
104416 ** starting at regBase.
104418 regBase = codeAllEqualityTerms(
104419 pParse, pLevel, pWC, notReady, nExtraReg, &zStartAff
104421 zEndAff = sqlite3DbStrDup(pParse->db, zStartAff);
104422 addrNxt = pLevel->addrNxt;
104424 /* If we are doing a reverse order scan on an ascending index, or
104425 ** a forward order scan on a descending index, interchange the
104426 ** start and end terms (pRangeStart and pRangeEnd).
104428 if( nEq<pIdx->nColumn && bRev==(pIdx->aSortOrder[nEq]==SQLITE_SO_ASC) ){
104429 SWAP(WhereTerm *, pRangeEnd, pRangeStart);
104432 testcase( pRangeStart && pRangeStart->eOperator & WO_LE );
104433 testcase( pRangeStart && pRangeStart->eOperator & WO_GE );
104434 testcase( pRangeEnd && pRangeEnd->eOperator & WO_LE );
104435 testcase( pRangeEnd && pRangeEnd->eOperator & WO_GE );
104436 startEq = !pRangeStart || pRangeStart->eOperator & (WO_LE|WO_GE);
104437 endEq = !pRangeEnd || pRangeEnd->eOperator & (WO_LE|WO_GE);
104438 start_constraints = pRangeStart || nEq>0;
104440 /* Seek the index cursor to the start of the range. */
104441 nConstraint = nEq;
104442 if( pRangeStart ){
104443 Expr *pRight = pRangeStart->pExpr->pRight;
104444 sqlite3ExprCode(pParse, pRight, regBase+nEq);
104445 if( (pRangeStart->wtFlags & TERM_VNULL)==0 ){
104446 sqlite3ExprCodeIsNullJump(v, pRight, regBase+nEq, addrNxt);
104448 if( zStartAff ){
104449 if( sqlite3CompareAffinity(pRight, zStartAff[nEq])==SQLITE_AFF_NONE){
104450 /* Since the comparison is to be performed with no conversions
104451 ** applied to the operands, set the affinity to apply to pRight to
104452 ** SQLITE_AFF_NONE. */
104453 zStartAff[nEq] = SQLITE_AFF_NONE;
104455 if( sqlite3ExprNeedsNoAffinityChange(pRight, zStartAff[nEq]) ){
104456 zStartAff[nEq] = SQLITE_AFF_NONE;
104459 nConstraint++;
104460 testcase( pRangeStart->wtFlags & TERM_VIRTUAL ); /* EV: R-30575-11662 */
104461 }else if( isMinQuery ){
104462 sqlite3VdbeAddOp2(v, OP_Null, 0, regBase+nEq);
104463 nConstraint++;
104464 startEq = 0;
104465 start_constraints = 1;
104467 codeApplyAffinity(pParse, regBase, nConstraint, zStartAff);
104468 op = aStartOp[(start_constraints<<2) + (startEq<<1) + bRev];
104469 assert( op!=0 );
104470 testcase( op==OP_Rewind );
104471 testcase( op==OP_Last );
104472 testcase( op==OP_SeekGt );
104473 testcase( op==OP_SeekGe );
104474 testcase( op==OP_SeekLe );
104475 testcase( op==OP_SeekLt );
104476 sqlite3VdbeAddOp4Int(v, op, iIdxCur, addrNxt, regBase, nConstraint);
104478 /* Load the value for the inequality constraint at the end of the
104479 ** range (if any).
104481 nConstraint = nEq;
104482 if( pRangeEnd ){
104483 Expr *pRight = pRangeEnd->pExpr->pRight;
104484 sqlite3ExprCacheRemove(pParse, regBase+nEq, 1);
104485 sqlite3ExprCode(pParse, pRight, regBase+nEq);
104486 if( (pRangeEnd->wtFlags & TERM_VNULL)==0 ){
104487 sqlite3ExprCodeIsNullJump(v, pRight, regBase+nEq, addrNxt);
104489 if( zEndAff ){
104490 if( sqlite3CompareAffinity(pRight, zEndAff[nEq])==SQLITE_AFF_NONE){
104491 /* Since the comparison is to be performed with no conversions
104492 ** applied to the operands, set the affinity to apply to pRight to
104493 ** SQLITE_AFF_NONE. */
104494 zEndAff[nEq] = SQLITE_AFF_NONE;
104496 if( sqlite3ExprNeedsNoAffinityChange(pRight, zEndAff[nEq]) ){
104497 zEndAff[nEq] = SQLITE_AFF_NONE;
104500 codeApplyAffinity(pParse, regBase, nEq+1, zEndAff);
104501 nConstraint++;
104502 testcase( pRangeEnd->wtFlags & TERM_VIRTUAL ); /* EV: R-30575-11662 */
104504 sqlite3DbFree(pParse->db, zStartAff);
104505 sqlite3DbFree(pParse->db, zEndAff);
104507 /* Top of the loop body */
104508 pLevel->p2 = sqlite3VdbeCurrentAddr(v);
104510 /* Check if the index cursor is past the end of the range. */
104511 op = aEndOp[(pRangeEnd || nEq) * (1 + bRev)];
104512 testcase( op==OP_Noop );
104513 testcase( op==OP_IdxGE );
104514 testcase( op==OP_IdxLT );
104515 if( op!=OP_Noop ){
104516 sqlite3VdbeAddOp4Int(v, op, iIdxCur, addrNxt, regBase, nConstraint);
104517 sqlite3VdbeChangeP5(v, endEq!=bRev ?1:0);
104520 /* If there are inequality constraints, check that the value
104521 ** of the table column that the inequality contrains is not NULL.
104522 ** If it is, jump to the next iteration of the loop.
104524 r1 = sqlite3GetTempReg(pParse);
104525 testcase( pLevel->plan.wsFlags & WHERE_BTM_LIMIT );
104526 testcase( pLevel->plan.wsFlags & WHERE_TOP_LIMIT );
104527 if( (pLevel->plan.wsFlags & (WHERE_BTM_LIMIT|WHERE_TOP_LIMIT))!=0 ){
104528 sqlite3VdbeAddOp3(v, OP_Column, iIdxCur, nEq, r1);
104529 sqlite3VdbeAddOp2(v, OP_IsNull, r1, addrCont);
104531 sqlite3ReleaseTempReg(pParse, r1);
104533 /* Seek the table cursor, if required */
104534 disableTerm(pLevel, pRangeStart);
104535 disableTerm(pLevel, pRangeEnd);
104536 if( !omitTable ){
104537 iRowidReg = iReleaseReg = sqlite3GetTempReg(pParse);
104538 sqlite3VdbeAddOp2(v, OP_IdxRowid, iIdxCur, iRowidReg);
104539 sqlite3ExprCacheStore(pParse, iCur, -1, iRowidReg);
104540 sqlite3VdbeAddOp2(v, OP_Seek, iCur, iRowidReg); /* Deferred seek */
104543 /* Record the instruction used to terminate the loop. Disable
104544 ** WHERE clause terms made redundant by the index range scan.
104546 if( pLevel->plan.wsFlags & WHERE_UNIQUE ){
104547 pLevel->op = OP_Noop;
104548 }else if( bRev ){
104549 pLevel->op = OP_Prev;
104550 }else{
104551 pLevel->op = OP_Next;
104553 pLevel->p1 = iIdxCur;
104554 }else
104556 #ifndef SQLITE_OMIT_OR_OPTIMIZATION
104557 if( pLevel->plan.wsFlags & WHERE_MULTI_OR ){
104558 /* Case 4: Two or more separately indexed terms connected by OR
104560 ** Example:
104562 ** CREATE TABLE t1(a,b,c,d);
104563 ** CREATE INDEX i1 ON t1(a);
104564 ** CREATE INDEX i2 ON t1(b);
104565 ** CREATE INDEX i3 ON t1(c);
104567 ** SELECT * FROM t1 WHERE a=5 OR b=7 OR (c=11 AND d=13)
104569 ** In the example, there are three indexed terms connected by OR.
104570 ** The top of the loop looks like this:
104572 ** Null 1 # Zero the rowset in reg 1
104574 ** Then, for each indexed term, the following. The arguments to
104575 ** RowSetTest are such that the rowid of the current row is inserted
104576 ** into the RowSet. If it is already present, control skips the
104577 ** Gosub opcode and jumps straight to the code generated by WhereEnd().
104579 ** sqlite3WhereBegin(<term>)
104580 ** RowSetTest # Insert rowid into rowset
104581 ** Gosub 2 A
104582 ** sqlite3WhereEnd()
104584 ** Following the above, code to terminate the loop. Label A, the target
104585 ** of the Gosub above, jumps to the instruction right after the Goto.
104587 ** Null 1 # Zero the rowset in reg 1
104588 ** Goto B # The loop is finished.
104590 ** A: <loop body> # Return data, whatever.
104592 ** Return 2 # Jump back to the Gosub
104594 ** B: <after the loop>
104597 WhereClause *pOrWc; /* The OR-clause broken out into subterms */
104598 SrcList *pOrTab; /* Shortened table list or OR-clause generation */
104600 int regReturn = ++pParse->nMem; /* Register used with OP_Gosub */
104601 int regRowset = 0; /* Register for RowSet object */
104602 int regRowid = 0; /* Register holding rowid */
104603 int iLoopBody = sqlite3VdbeMakeLabel(v); /* Start of loop body */
104604 int iRetInit; /* Address of regReturn init */
104605 int untestedTerms = 0; /* Some terms not completely tested */
104606 int ii;
104608 pTerm = pLevel->plan.u.pTerm;
104609 assert( pTerm!=0 );
104610 assert( pTerm->eOperator==WO_OR );
104611 assert( (pTerm->wtFlags & TERM_ORINFO)!=0 );
104612 pOrWc = &pTerm->u.pOrInfo->wc;
104613 pLevel->op = OP_Return;
104614 pLevel->p1 = regReturn;
104616 /* Set up a new SrcList ni pOrTab containing the table being scanned
104617 ** by this loop in the a[0] slot and all notReady tables in a[1..] slots.
104618 ** This becomes the SrcList in the recursive call to sqlite3WhereBegin().
104620 if( pWInfo->nLevel>1 ){
104621 int nNotReady; /* The number of notReady tables */
104622 struct SrcList_item *origSrc; /* Original list of tables */
104623 nNotReady = pWInfo->nLevel - iLevel - 1;
104624 pOrTab = sqlite3StackAllocRaw(pParse->db,
104625 sizeof(*pOrTab)+ nNotReady*sizeof(pOrTab->a[0]));
104626 if( pOrTab==0 ) return notReady;
104627 pOrTab->nAlloc = (i16)(nNotReady + 1);
104628 pOrTab->nSrc = pOrTab->nAlloc;
104629 memcpy(pOrTab->a, pTabItem, sizeof(*pTabItem));
104630 origSrc = pWInfo->pTabList->a;
104631 for(k=1; k<=nNotReady; k++){
104632 memcpy(&pOrTab->a[k], &origSrc[pLevel[k].iFrom], sizeof(pOrTab->a[k]));
104634 }else{
104635 pOrTab = pWInfo->pTabList;
104638 /* Initialize the rowset register to contain NULL. An SQL NULL is
104639 ** equivalent to an empty rowset.
104641 ** Also initialize regReturn to contain the address of the instruction
104642 ** immediately following the OP_Return at the bottom of the loop. This
104643 ** is required in a few obscure LEFT JOIN cases where control jumps
104644 ** over the top of the loop into the body of it. In this case the
104645 ** correct response for the end-of-loop code (the OP_Return) is to
104646 ** fall through to the next instruction, just as an OP_Next does if
104647 ** called on an uninitialized cursor.
104649 if( (wctrlFlags & WHERE_DUPLICATES_OK)==0 ){
104650 regRowset = ++pParse->nMem;
104651 regRowid = ++pParse->nMem;
104652 sqlite3VdbeAddOp2(v, OP_Null, 0, regRowset);
104654 iRetInit = sqlite3VdbeAddOp2(v, OP_Integer, 0, regReturn);
104656 for(ii=0; ii<pOrWc->nTerm; ii++){
104657 WhereTerm *pOrTerm = &pOrWc->a[ii];
104658 if( pOrTerm->leftCursor==iCur || pOrTerm->eOperator==WO_AND ){
104659 WhereInfo *pSubWInfo; /* Info for single OR-term scan */
104660 /* Loop through table entries that match term pOrTerm. */
104661 pSubWInfo = sqlite3WhereBegin(pParse, pOrTab, pOrTerm->pExpr, 0, 0,
104662 WHERE_OMIT_OPEN | WHERE_OMIT_CLOSE |
104663 WHERE_FORCE_TABLE | WHERE_ONETABLE_ONLY);
104664 if( pSubWInfo ){
104665 explainOneScan(
104666 pParse, pOrTab, &pSubWInfo->a[0], iLevel, pLevel->iFrom, 0
104668 if( (wctrlFlags & WHERE_DUPLICATES_OK)==0 ){
104669 int iSet = ((ii==pOrWc->nTerm-1)?-1:ii);
104670 int r;
104671 r = sqlite3ExprCodeGetColumn(pParse, pTabItem->pTab, -1, iCur,
104672 regRowid);
104673 sqlite3VdbeAddOp4Int(v, OP_RowSetTest, regRowset,
104674 sqlite3VdbeCurrentAddr(v)+2, r, iSet);
104676 sqlite3VdbeAddOp2(v, OP_Gosub, regReturn, iLoopBody);
104678 /* The pSubWInfo->untestedTerms flag means that this OR term
104679 ** contained one or more AND term from a notReady table. The
104680 ** terms from the notReady table could not be tested and will
104681 ** need to be tested later.
104683 if( pSubWInfo->untestedTerms ) untestedTerms = 1;
104685 /* Finish the loop through table entries that match term pOrTerm. */
104686 sqlite3WhereEnd(pSubWInfo);
104690 sqlite3VdbeChangeP1(v, iRetInit, sqlite3VdbeCurrentAddr(v));
104691 sqlite3VdbeAddOp2(v, OP_Goto, 0, pLevel->addrBrk);
104692 sqlite3VdbeResolveLabel(v, iLoopBody);
104694 if( pWInfo->nLevel>1 ) sqlite3StackFree(pParse->db, pOrTab);
104695 if( !untestedTerms ) disableTerm(pLevel, pTerm);
104696 }else
104697 #endif /* SQLITE_OMIT_OR_OPTIMIZATION */
104700 /* Case 5: There is no usable index. We must do a complete
104701 ** scan of the entire table.
104703 static const u8 aStep[] = { OP_Next, OP_Prev };
104704 static const u8 aStart[] = { OP_Rewind, OP_Last };
104705 assert( bRev==0 || bRev==1 );
104706 assert( omitTable==0 );
104707 pLevel->op = aStep[bRev];
104708 pLevel->p1 = iCur;
104709 pLevel->p2 = 1 + sqlite3VdbeAddOp2(v, aStart[bRev], iCur, addrBrk);
104710 pLevel->p5 = SQLITE_STMTSTATUS_FULLSCAN_STEP;
104712 notReady &= ~getMask(pWC->pMaskSet, iCur);
104714 /* Insert code to test every subexpression that can be completely
104715 ** computed using the current set of tables.
104717 ** IMPLEMENTATION-OF: R-49525-50935 Terms that cannot be satisfied through
104718 ** the use of indices become tests that are evaluated against each row of
104719 ** the relevant input tables.
104721 for(pTerm=pWC->a, j=pWC->nTerm; j>0; j--, pTerm++){
104722 Expr *pE;
104723 testcase( pTerm->wtFlags & TERM_VIRTUAL ); /* IMP: R-30575-11662 */
104724 testcase( pTerm->wtFlags & TERM_CODED );
104725 if( pTerm->wtFlags & (TERM_VIRTUAL|TERM_CODED) ) continue;
104726 if( (pTerm->prereqAll & notReady)!=0 ){
104727 testcase( pWInfo->untestedTerms==0
104728 && (pWInfo->wctrlFlags & WHERE_ONETABLE_ONLY)!=0 );
104729 pWInfo->untestedTerms = 1;
104730 continue;
104732 pE = pTerm->pExpr;
104733 assert( pE!=0 );
104734 if( pLevel->iLeftJoin && !ExprHasProperty(pE, EP_FromJoin) ){
104735 continue;
104737 sqlite3ExprIfFalse(pParse, pE, addrCont, SQLITE_JUMPIFNULL);
104738 pTerm->wtFlags |= TERM_CODED;
104741 /* For a LEFT OUTER JOIN, generate code that will record the fact that
104742 ** at least one row of the right table has matched the left table.
104744 if( pLevel->iLeftJoin ){
104745 pLevel->addrFirst = sqlite3VdbeCurrentAddr(v);
104746 sqlite3VdbeAddOp2(v, OP_Integer, 1, pLevel->iLeftJoin);
104747 VdbeComment((v, "record LEFT JOIN hit"));
104748 sqlite3ExprCacheClear(pParse);
104749 for(pTerm=pWC->a, j=0; j<pWC->nTerm; j++, pTerm++){
104750 testcase( pTerm->wtFlags & TERM_VIRTUAL ); /* IMP: R-30575-11662 */
104751 testcase( pTerm->wtFlags & TERM_CODED );
104752 if( pTerm->wtFlags & (TERM_VIRTUAL|TERM_CODED) ) continue;
104753 if( (pTerm->prereqAll & notReady)!=0 ){
104754 assert( pWInfo->untestedTerms );
104755 continue;
104757 assert( pTerm->pExpr );
104758 sqlite3ExprIfFalse(pParse, pTerm->pExpr, addrCont, SQLITE_JUMPIFNULL);
104759 pTerm->wtFlags |= TERM_CODED;
104762 sqlite3ReleaseTempReg(pParse, iReleaseReg);
104764 return notReady;
104767 #if defined(SQLITE_TEST)
104769 ** The following variable holds a text description of query plan generated
104770 ** by the most recent call to sqlite3WhereBegin(). Each call to WhereBegin
104771 ** overwrites the previous. This information is used for testing and
104772 ** analysis only.
104774 SQLITE_API char sqlite3_query_plan[BMS*2*40]; /* Text of the join */
104775 static int nQPlan = 0; /* Next free slow in _query_plan[] */
104777 #endif /* SQLITE_TEST */
104781 ** Free a WhereInfo structure
104783 static void whereInfoFree(sqlite3 *db, WhereInfo *pWInfo){
104784 if( ALWAYS(pWInfo) ){
104785 int i;
104786 for(i=0; i<pWInfo->nLevel; i++){
104787 sqlite3_index_info *pInfo = pWInfo->a[i].pIdxInfo;
104788 if( pInfo ){
104789 /* assert( pInfo->needToFreeIdxStr==0 || db->mallocFailed ); */
104790 if( pInfo->needToFreeIdxStr ){
104791 sqlite3_free(pInfo->idxStr);
104793 sqlite3DbFree(db, pInfo);
104795 if( pWInfo->a[i].plan.wsFlags & WHERE_TEMP_INDEX ){
104796 Index *pIdx = pWInfo->a[i].plan.u.pIdx;
104797 if( pIdx ){
104798 sqlite3DbFree(db, pIdx->zColAff);
104799 sqlite3DbFree(db, pIdx);
104803 whereClauseClear(pWInfo->pWC);
104804 sqlite3DbFree(db, pWInfo);
104810 ** Generate the beginning of the loop used for WHERE clause processing.
104811 ** The return value is a pointer to an opaque structure that contains
104812 ** information needed to terminate the loop. Later, the calling routine
104813 ** should invoke sqlite3WhereEnd() with the return value of this function
104814 ** in order to complete the WHERE clause processing.
104816 ** If an error occurs, this routine returns NULL.
104818 ** The basic idea is to do a nested loop, one loop for each table in
104819 ** the FROM clause of a select. (INSERT and UPDATE statements are the
104820 ** same as a SELECT with only a single table in the FROM clause.) For
104821 ** example, if the SQL is this:
104823 ** SELECT * FROM t1, t2, t3 WHERE ...;
104825 ** Then the code generated is conceptually like the following:
104827 ** foreach row1 in t1 do \ Code generated
104828 ** foreach row2 in t2 do |-- by sqlite3WhereBegin()
104829 ** foreach row3 in t3 do /
104830 ** ...
104831 ** end \ Code generated
104832 ** end |-- by sqlite3WhereEnd()
104833 ** end /
104835 ** Note that the loops might not be nested in the order in which they
104836 ** appear in the FROM clause if a different order is better able to make
104837 ** use of indices. Note also that when the IN operator appears in
104838 ** the WHERE clause, it might result in additional nested loops for
104839 ** scanning through all values on the right-hand side of the IN.
104841 ** There are Btree cursors associated with each table. t1 uses cursor
104842 ** number pTabList->a[0].iCursor. t2 uses the cursor pTabList->a[1].iCursor.
104843 ** And so forth. This routine generates code to open those VDBE cursors
104844 ** and sqlite3WhereEnd() generates the code to close them.
104846 ** The code that sqlite3WhereBegin() generates leaves the cursors named
104847 ** in pTabList pointing at their appropriate entries. The [...] code
104848 ** can use OP_Column and OP_Rowid opcodes on these cursors to extract
104849 ** data from the various tables of the loop.
104851 ** If the WHERE clause is empty, the foreach loops must each scan their
104852 ** entire tables. Thus a three-way join is an O(N^3) operation. But if
104853 ** the tables have indices and there are terms in the WHERE clause that
104854 ** refer to those indices, a complete table scan can be avoided and the
104855 ** code will run much faster. Most of the work of this routine is checking
104856 ** to see if there are indices that can be used to speed up the loop.
104858 ** Terms of the WHERE clause are also used to limit which rows actually
104859 ** make it to the "..." in the middle of the loop. After each "foreach",
104860 ** terms of the WHERE clause that use only terms in that loop and outer
104861 ** loops are evaluated and if false a jump is made around all subsequent
104862 ** inner loops (or around the "..." if the test occurs within the inner-
104863 ** most loop)
104865 ** OUTER JOINS
104867 ** An outer join of tables t1 and t2 is conceptally coded as follows:
104869 ** foreach row1 in t1 do
104870 ** flag = 0
104871 ** foreach row2 in t2 do
104872 ** start:
104873 ** ...
104874 ** flag = 1
104875 ** end
104876 ** if flag==0 then
104877 ** move the row2 cursor to a null row
104878 ** goto start
104879 ** fi
104880 ** end
104882 ** ORDER BY CLAUSE PROCESSING
104884 ** *ppOrderBy is a pointer to the ORDER BY clause of a SELECT statement,
104885 ** if there is one. If there is no ORDER BY clause or if this routine
104886 ** is called from an UPDATE or DELETE statement, then ppOrderBy is NULL.
104888 ** If an index can be used so that the natural output order of the table
104889 ** scan is correct for the ORDER BY clause, then that index is used and
104890 ** *ppOrderBy is set to NULL. This is an optimization that prevents an
104891 ** unnecessary sort of the result set if an index appropriate for the
104892 ** ORDER BY clause already exists.
104894 ** If the where clause loops cannot be arranged to provide the correct
104895 ** output order, then the *ppOrderBy is unchanged.
104897 SQLITE_PRIVATE WhereInfo *sqlite3WhereBegin(
104898 Parse *pParse, /* The parser context */
104899 SrcList *pTabList, /* A list of all tables to be scanned */
104900 Expr *pWhere, /* The WHERE clause */
104901 ExprList **ppOrderBy, /* An ORDER BY clause, or NULL */
104902 ExprList *pDistinct, /* The select-list for DISTINCT queries - or NULL */
104903 u16 wctrlFlags /* One of the WHERE_* flags defined in sqliteInt.h */
104905 int i; /* Loop counter */
104906 int nByteWInfo; /* Num. bytes allocated for WhereInfo struct */
104907 int nTabList; /* Number of elements in pTabList */
104908 WhereInfo *pWInfo; /* Will become the return value of this function */
104909 Vdbe *v = pParse->pVdbe; /* The virtual database engine */
104910 Bitmask notReady; /* Cursors that are not yet positioned */
104911 WhereMaskSet *pMaskSet; /* The expression mask set */
104912 WhereClause *pWC; /* Decomposition of the WHERE clause */
104913 struct SrcList_item *pTabItem; /* A single entry from pTabList */
104914 WhereLevel *pLevel; /* A single level in the pWInfo list */
104915 int iFrom; /* First unused FROM clause element */
104916 int andFlags; /* AND-ed combination of all pWC->a[].wtFlags */
104917 sqlite3 *db; /* Database connection */
104919 /* The number of tables in the FROM clause is limited by the number of
104920 ** bits in a Bitmask
104922 testcase( pTabList->nSrc==BMS );
104923 if( pTabList->nSrc>BMS ){
104924 sqlite3ErrorMsg(pParse, "at most %d tables in a join", BMS);
104925 return 0;
104928 /* This function normally generates a nested loop for all tables in
104929 ** pTabList. But if the WHERE_ONETABLE_ONLY flag is set, then we should
104930 ** only generate code for the first table in pTabList and assume that
104931 ** any cursors associated with subsequent tables are uninitialized.
104933 nTabList = (wctrlFlags & WHERE_ONETABLE_ONLY) ? 1 : pTabList->nSrc;
104935 /* Allocate and initialize the WhereInfo structure that will become the
104936 ** return value. A single allocation is used to store the WhereInfo
104937 ** struct, the contents of WhereInfo.a[], the WhereClause structure
104938 ** and the WhereMaskSet structure. Since WhereClause contains an 8-byte
104939 ** field (type Bitmask) it must be aligned on an 8-byte boundary on
104940 ** some architectures. Hence the ROUND8() below.
104942 db = pParse->db;
104943 nByteWInfo = ROUND8(sizeof(WhereInfo)+(nTabList-1)*sizeof(WhereLevel));
104944 pWInfo = sqlite3DbMallocZero(db,
104945 nByteWInfo +
104946 sizeof(WhereClause) +
104947 sizeof(WhereMaskSet)
104949 if( db->mallocFailed ){
104950 sqlite3DbFree(db, pWInfo);
104951 pWInfo = 0;
104952 goto whereBeginError;
104954 pWInfo->nLevel = nTabList;
104955 pWInfo->pParse = pParse;
104956 pWInfo->pTabList = pTabList;
104957 pWInfo->iBreak = sqlite3VdbeMakeLabel(v);
104958 pWInfo->pWC = pWC = (WhereClause *)&((u8 *)pWInfo)[nByteWInfo];
104959 pWInfo->wctrlFlags = wctrlFlags;
104960 pWInfo->savedNQueryLoop = pParse->nQueryLoop;
104961 pMaskSet = (WhereMaskSet*)&pWC[1];
104963 /* Disable the DISTINCT optimization if SQLITE_DistinctOpt is set via
104964 ** sqlite3_test_ctrl(SQLITE_TESTCTRL_OPTIMIZATIONS,...) */
104965 if( db->flags & SQLITE_DistinctOpt ) pDistinct = 0;
104967 /* Split the WHERE clause into separate subexpressions where each
104968 ** subexpression is separated by an AND operator.
104970 initMaskSet(pMaskSet);
104971 whereClauseInit(pWC, pParse, pMaskSet);
104972 sqlite3ExprCodeConstants(pParse, pWhere);
104973 whereSplit(pWC, pWhere, TK_AND); /* IMP: R-15842-53296 */
104975 /* Special case: a WHERE clause that is constant. Evaluate the
104976 ** expression and either jump over all of the code or fall thru.
104978 if( pWhere && (nTabList==0 || sqlite3ExprIsConstantNotJoin(pWhere)) ){
104979 sqlite3ExprIfFalse(pParse, pWhere, pWInfo->iBreak, SQLITE_JUMPIFNULL);
104980 pWhere = 0;
104983 /* Assign a bit from the bitmask to every term in the FROM clause.
104985 ** When assigning bitmask values to FROM clause cursors, it must be
104986 ** the case that if X is the bitmask for the N-th FROM clause term then
104987 ** the bitmask for all FROM clause terms to the left of the N-th term
104988 ** is (X-1). An expression from the ON clause of a LEFT JOIN can use
104989 ** its Expr.iRightJoinTable value to find the bitmask of the right table
104990 ** of the join. Subtracting one from the right table bitmask gives a
104991 ** bitmask for all tables to the left of the join. Knowing the bitmask
104992 ** for all tables to the left of a left join is important. Ticket #3015.
104994 ** Configure the WhereClause.vmask variable so that bits that correspond
104995 ** to virtual table cursors are set. This is used to selectively disable
104996 ** the OR-to-IN transformation in exprAnalyzeOrTerm(). It is not helpful
104997 ** with virtual tables.
104999 ** Note that bitmasks are created for all pTabList->nSrc tables in
105000 ** pTabList, not just the first nTabList tables. nTabList is normally
105001 ** equal to pTabList->nSrc but might be shortened to 1 if the
105002 ** WHERE_ONETABLE_ONLY flag is set.
105004 assert( pWC->vmask==0 && pMaskSet->n==0 );
105005 for(i=0; i<pTabList->nSrc; i++){
105006 createMask(pMaskSet, pTabList->a[i].iCursor);
105007 #ifndef SQLITE_OMIT_VIRTUALTABLE
105008 if( ALWAYS(pTabList->a[i].pTab) && IsVirtual(pTabList->a[i].pTab) ){
105009 pWC->vmask |= ((Bitmask)1 << i);
105011 #endif
105013 #ifndef NDEBUG
105015 Bitmask toTheLeft = 0;
105016 for(i=0; i<pTabList->nSrc; i++){
105017 Bitmask m = getMask(pMaskSet, pTabList->a[i].iCursor);
105018 assert( (m-1)==toTheLeft );
105019 toTheLeft |= m;
105022 #endif
105024 /* Analyze all of the subexpressions. Note that exprAnalyze() might
105025 ** add new virtual terms onto the end of the WHERE clause. We do not
105026 ** want to analyze these virtual terms, so start analyzing at the end
105027 ** and work forward so that the added virtual terms are never processed.
105029 exprAnalyzeAll(pTabList, pWC);
105030 if( db->mallocFailed ){
105031 goto whereBeginError;
105034 /* Check if the DISTINCT qualifier, if there is one, is redundant.
105035 ** If it is, then set pDistinct to NULL and WhereInfo.eDistinct to
105036 ** WHERE_DISTINCT_UNIQUE to tell the caller to ignore the DISTINCT.
105038 if( pDistinct && isDistinctRedundant(pParse, pTabList, pWC, pDistinct) ){
105039 pDistinct = 0;
105040 pWInfo->eDistinct = WHERE_DISTINCT_UNIQUE;
105043 /* Chose the best index to use for each table in the FROM clause.
105045 ** This loop fills in the following fields:
105047 ** pWInfo->a[].pIdx The index to use for this level of the loop.
105048 ** pWInfo->a[].wsFlags WHERE_xxx flags associated with pIdx
105049 ** pWInfo->a[].nEq The number of == and IN constraints
105050 ** pWInfo->a[].iFrom Which term of the FROM clause is being coded
105051 ** pWInfo->a[].iTabCur The VDBE cursor for the database table
105052 ** pWInfo->a[].iIdxCur The VDBE cursor for the index
105053 ** pWInfo->a[].pTerm When wsFlags==WO_OR, the OR-clause term
105055 ** This loop also figures out the nesting order of tables in the FROM
105056 ** clause.
105058 notReady = ~(Bitmask)0;
105059 andFlags = ~0;
105060 WHERETRACE(("*** Optimizer Start ***\n"));
105061 for(i=iFrom=0, pLevel=pWInfo->a; i<nTabList; i++, pLevel++){
105062 WhereCost bestPlan; /* Most efficient plan seen so far */
105063 Index *pIdx; /* Index for FROM table at pTabItem */
105064 int j; /* For looping over FROM tables */
105065 int bestJ = -1; /* The value of j */
105066 Bitmask m; /* Bitmask value for j or bestJ */
105067 int isOptimal; /* Iterator for optimal/non-optimal search */
105068 int nUnconstrained; /* Number tables without INDEXED BY */
105069 Bitmask notIndexed; /* Mask of tables that cannot use an index */
105071 memset(&bestPlan, 0, sizeof(bestPlan));
105072 bestPlan.rCost = SQLITE_BIG_DBL;
105073 WHERETRACE(("*** Begin search for loop %d ***\n", i));
105075 /* Loop through the remaining entries in the FROM clause to find the
105076 ** next nested loop. The loop tests all FROM clause entries
105077 ** either once or twice.
105079 ** The first test is always performed if there are two or more entries
105080 ** remaining and never performed if there is only one FROM clause entry
105081 ** to choose from. The first test looks for an "optimal" scan. In
105082 ** this context an optimal scan is one that uses the same strategy
105083 ** for the given FROM clause entry as would be selected if the entry
105084 ** were used as the innermost nested loop. In other words, a table
105085 ** is chosen such that the cost of running that table cannot be reduced
105086 ** by waiting for other tables to run first. This "optimal" test works
105087 ** by first assuming that the FROM clause is on the inner loop and finding
105088 ** its query plan, then checking to see if that query plan uses any
105089 ** other FROM clause terms that are notReady. If no notReady terms are
105090 ** used then the "optimal" query plan works.
105092 ** Note that the WhereCost.nRow parameter for an optimal scan might
105093 ** not be as small as it would be if the table really were the innermost
105094 ** join. The nRow value can be reduced by WHERE clause constraints
105095 ** that do not use indices. But this nRow reduction only happens if the
105096 ** table really is the innermost join.
105098 ** The second loop iteration is only performed if no optimal scan
105099 ** strategies were found by the first iteration. This second iteration
105100 ** is used to search for the lowest cost scan overall.
105102 ** Previous versions of SQLite performed only the second iteration -
105103 ** the next outermost loop was always that with the lowest overall
105104 ** cost. However, this meant that SQLite could select the wrong plan
105105 ** for scripts such as the following:
105107 ** CREATE TABLE t1(a, b);
105108 ** CREATE TABLE t2(c, d);
105109 ** SELECT * FROM t2, t1 WHERE t2.rowid = t1.a;
105111 ** The best strategy is to iterate through table t1 first. However it
105112 ** is not possible to determine this with a simple greedy algorithm.
105113 ** Since the cost of a linear scan through table t2 is the same
105114 ** as the cost of a linear scan through table t1, a simple greedy
105115 ** algorithm may choose to use t2 for the outer loop, which is a much
105116 ** costlier approach.
105118 nUnconstrained = 0;
105119 notIndexed = 0;
105120 for(isOptimal=(iFrom<nTabList-1); isOptimal>=0 && bestJ<0; isOptimal--){
105121 Bitmask mask; /* Mask of tables not yet ready */
105122 for(j=iFrom, pTabItem=&pTabList->a[j]; j<nTabList; j++, pTabItem++){
105123 int doNotReorder; /* True if this table should not be reordered */
105124 WhereCost sCost; /* Cost information from best[Virtual]Index() */
105125 ExprList *pOrderBy; /* ORDER BY clause for index to optimize */
105126 ExprList *pDist; /* DISTINCT clause for index to optimize */
105128 doNotReorder = (pTabItem->jointype & (JT_LEFT|JT_CROSS))!=0;
105129 if( j!=iFrom && doNotReorder ) break;
105130 m = getMask(pMaskSet, pTabItem->iCursor);
105131 if( (m & notReady)==0 ){
105132 if( j==iFrom ) iFrom++;
105133 continue;
105135 mask = (isOptimal ? m : notReady);
105136 pOrderBy = ((i==0 && ppOrderBy )?*ppOrderBy:0);
105137 pDist = (i==0 ? pDistinct : 0);
105138 if( pTabItem->pIndex==0 ) nUnconstrained++;
105140 WHERETRACE(("=== trying table %d with isOptimal=%d ===\n",
105141 j, isOptimal));
105142 assert( pTabItem->pTab );
105143 #ifndef SQLITE_OMIT_VIRTUALTABLE
105144 if( IsVirtual(pTabItem->pTab) ){
105145 sqlite3_index_info **pp = &pWInfo->a[j].pIdxInfo;
105146 bestVirtualIndex(pParse, pWC, pTabItem, mask, notReady, pOrderBy,
105147 &sCost, pp);
105148 }else
105149 #endif
105151 bestBtreeIndex(pParse, pWC, pTabItem, mask, notReady, pOrderBy,
105152 pDist, &sCost);
105154 assert( isOptimal || (sCost.used&notReady)==0 );
105156 /* If an INDEXED BY clause is present, then the plan must use that
105157 ** index if it uses any index at all */
105158 assert( pTabItem->pIndex==0
105159 || (sCost.plan.wsFlags & WHERE_NOT_FULLSCAN)==0
105160 || sCost.plan.u.pIdx==pTabItem->pIndex );
105162 if( isOptimal && (sCost.plan.wsFlags & WHERE_NOT_FULLSCAN)==0 ){
105163 notIndexed |= m;
105166 /* Conditions under which this table becomes the best so far:
105168 ** (1) The table must not depend on other tables that have not
105169 ** yet run.
105171 ** (2) A full-table-scan plan cannot supercede indexed plan unless
105172 ** the full-table-scan is an "optimal" plan as defined above.
105174 ** (3) All tables have an INDEXED BY clause or this table lacks an
105175 ** INDEXED BY clause or this table uses the specific
105176 ** index specified by its INDEXED BY clause. This rule ensures
105177 ** that a best-so-far is always selected even if an impossible
105178 ** combination of INDEXED BY clauses are given. The error
105179 ** will be detected and relayed back to the application later.
105180 ** The NEVER() comes about because rule (2) above prevents
105181 ** An indexable full-table-scan from reaching rule (3).
105183 ** (4) The plan cost must be lower than prior plans or else the
105184 ** cost must be the same and the number of rows must be lower.
105186 if( (sCost.used&notReady)==0 /* (1) */
105187 && (bestJ<0 || (notIndexed&m)!=0 /* (2) */
105188 || (bestPlan.plan.wsFlags & WHERE_NOT_FULLSCAN)==0
105189 || (sCost.plan.wsFlags & WHERE_NOT_FULLSCAN)!=0)
105190 && (nUnconstrained==0 || pTabItem->pIndex==0 /* (3) */
105191 || NEVER((sCost.plan.wsFlags & WHERE_NOT_FULLSCAN)!=0))
105192 && (bestJ<0 || sCost.rCost<bestPlan.rCost /* (4) */
105193 || (sCost.rCost<=bestPlan.rCost
105194 && sCost.plan.nRow<bestPlan.plan.nRow))
105196 WHERETRACE(("=== table %d is best so far"
105197 " with cost=%g and nRow=%g\n",
105198 j, sCost.rCost, sCost.plan.nRow));
105199 bestPlan = sCost;
105200 bestJ = j;
105202 if( doNotReorder ) break;
105205 assert( bestJ>=0 );
105206 assert( notReady & getMask(pMaskSet, pTabList->a[bestJ].iCursor) );
105207 WHERETRACE(("*** Optimizer selects table %d for loop %d"
105208 " with cost=%g and nRow=%g\n",
105209 bestJ, pLevel-pWInfo->a, bestPlan.rCost, bestPlan.plan.nRow));
105210 if( (bestPlan.plan.wsFlags & WHERE_ORDERBY)!=0 ){
105211 *ppOrderBy = 0;
105213 if( (bestPlan.plan.wsFlags & WHERE_DISTINCT)!=0 ){
105214 assert( pWInfo->eDistinct==0 );
105215 pWInfo->eDistinct = WHERE_DISTINCT_ORDERED;
105217 andFlags &= bestPlan.plan.wsFlags;
105218 pLevel->plan = bestPlan.plan;
105219 testcase( bestPlan.plan.wsFlags & WHERE_INDEXED );
105220 testcase( bestPlan.plan.wsFlags & WHERE_TEMP_INDEX );
105221 if( bestPlan.plan.wsFlags & (WHERE_INDEXED|WHERE_TEMP_INDEX) ){
105222 pLevel->iIdxCur = pParse->nTab++;
105223 }else{
105224 pLevel->iIdxCur = -1;
105226 notReady &= ~getMask(pMaskSet, pTabList->a[bestJ].iCursor);
105227 pLevel->iFrom = (u8)bestJ;
105228 if( bestPlan.plan.nRow>=(double)1 ){
105229 pParse->nQueryLoop *= bestPlan.plan.nRow;
105232 /* Check that if the table scanned by this loop iteration had an
105233 ** INDEXED BY clause attached to it, that the named index is being
105234 ** used for the scan. If not, then query compilation has failed.
105235 ** Return an error.
105237 pIdx = pTabList->a[bestJ].pIndex;
105238 if( pIdx ){
105239 if( (bestPlan.plan.wsFlags & WHERE_INDEXED)==0 ){
105240 sqlite3ErrorMsg(pParse, "cannot use index: %s", pIdx->zName);
105241 goto whereBeginError;
105242 }else{
105243 /* If an INDEXED BY clause is used, the bestIndex() function is
105244 ** guaranteed to find the index specified in the INDEXED BY clause
105245 ** if it find an index at all. */
105246 assert( bestPlan.plan.u.pIdx==pIdx );
105250 WHERETRACE(("*** Optimizer Finished ***\n"));
105251 if( pParse->nErr || db->mallocFailed ){
105252 goto whereBeginError;
105255 /* If the total query only selects a single row, then the ORDER BY
105256 ** clause is irrelevant.
105258 if( (andFlags & WHERE_UNIQUE)!=0 && ppOrderBy ){
105259 *ppOrderBy = 0;
105262 /* If the caller is an UPDATE or DELETE statement that is requesting
105263 ** to use a one-pass algorithm, determine if this is appropriate.
105264 ** The one-pass algorithm only works if the WHERE clause constraints
105265 ** the statement to update a single row.
105267 assert( (wctrlFlags & WHERE_ONEPASS_DESIRED)==0 || pWInfo->nLevel==1 );
105268 if( (wctrlFlags & WHERE_ONEPASS_DESIRED)!=0 && (andFlags & WHERE_UNIQUE)!=0 ){
105269 pWInfo->okOnePass = 1;
105270 pWInfo->a[0].plan.wsFlags &= ~WHERE_IDX_ONLY;
105273 /* Open all tables in the pTabList and any indices selected for
105274 ** searching those tables.
105276 sqlite3CodeVerifySchema(pParse, -1); /* Insert the cookie verifier Goto */
105277 notReady = ~(Bitmask)0;
105278 pWInfo->nRowOut = (double)1;
105279 for(i=0, pLevel=pWInfo->a; i<nTabList; i++, pLevel++){
105280 Table *pTab; /* Table to open */
105281 int iDb; /* Index of database containing table/index */
105283 pTabItem = &pTabList->a[pLevel->iFrom];
105284 pTab = pTabItem->pTab;
105285 pLevel->iTabCur = pTabItem->iCursor;
105286 pWInfo->nRowOut *= pLevel->plan.nRow;
105287 iDb = sqlite3SchemaToIndex(db, pTab->pSchema);
105288 if( (pTab->tabFlags & TF_Ephemeral)!=0 || pTab->pSelect ){
105289 /* Do nothing */
105290 }else
105291 #ifndef SQLITE_OMIT_VIRTUALTABLE
105292 if( (pLevel->plan.wsFlags & WHERE_VIRTUALTABLE)!=0 ){
105293 const char *pVTab = (const char *)sqlite3GetVTable(db, pTab);
105294 int iCur = pTabItem->iCursor;
105295 sqlite3VdbeAddOp4(v, OP_VOpen, iCur, 0, 0, pVTab, P4_VTAB);
105296 }else
105297 #endif
105298 if( (pLevel->plan.wsFlags & WHERE_IDX_ONLY)==0
105299 && (wctrlFlags & WHERE_OMIT_OPEN)==0 ){
105300 int op = pWInfo->okOnePass ? OP_OpenWrite : OP_OpenRead;
105301 sqlite3OpenTable(pParse, pTabItem->iCursor, iDb, pTab, op);
105302 testcase( pTab->nCol==BMS-1 );
105303 testcase( pTab->nCol==BMS );
105304 if( !pWInfo->okOnePass && pTab->nCol<BMS ){
105305 Bitmask b = pTabItem->colUsed;
105306 int n = 0;
105307 for(; b; b=b>>1, n++){}
105308 sqlite3VdbeChangeP4(v, sqlite3VdbeCurrentAddr(v)-1,
105309 SQLITE_INT_TO_PTR(n), P4_INT32);
105310 assert( n<=pTab->nCol );
105312 }else{
105313 sqlite3TableLock(pParse, iDb, pTab->tnum, 0, pTab->zName);
105315 #ifndef SQLITE_OMIT_AUTOMATIC_INDEX
105316 if( (pLevel->plan.wsFlags & WHERE_TEMP_INDEX)!=0 ){
105317 constructAutomaticIndex(pParse, pWC, pTabItem, notReady, pLevel);
105318 }else
105319 #endif
105320 if( (pLevel->plan.wsFlags & WHERE_INDEXED)!=0 ){
105321 Index *pIx = pLevel->plan.u.pIdx;
105322 KeyInfo *pKey = sqlite3IndexKeyinfo(pParse, pIx);
105323 int iIdxCur = pLevel->iIdxCur;
105324 assert( pIx->pSchema==pTab->pSchema );
105325 assert( iIdxCur>=0 );
105326 sqlite3VdbeAddOp4(v, OP_OpenRead, iIdxCur, pIx->tnum, iDb,
105327 (char*)pKey, P4_KEYINFO_HANDOFF);
105328 VdbeComment((v, "%s", pIx->zName));
105330 sqlite3CodeVerifySchema(pParse, iDb);
105331 notReady &= ~getMask(pWC->pMaskSet, pTabItem->iCursor);
105333 pWInfo->iTop = sqlite3VdbeCurrentAddr(v);
105334 if( db->mallocFailed ) goto whereBeginError;
105336 /* Generate the code to do the search. Each iteration of the for
105337 ** loop below generates code for a single nested loop of the VM
105338 ** program.
105340 notReady = ~(Bitmask)0;
105341 for(i=0; i<nTabList; i++){
105342 pLevel = &pWInfo->a[i];
105343 explainOneScan(pParse, pTabList, pLevel, i, pLevel->iFrom, wctrlFlags);
105344 notReady = codeOneLoopStart(pWInfo, i, wctrlFlags, notReady);
105345 pWInfo->iContinue = pLevel->addrCont;
105348 #ifdef SQLITE_TEST /* For testing and debugging use only */
105349 /* Record in the query plan information about the current table
105350 ** and the index used to access it (if any). If the table itself
105351 ** is not used, its name is just '{}'. If no index is used
105352 ** the index is listed as "{}". If the primary key is used the
105353 ** index name is '*'.
105355 for(i=0; i<nTabList; i++){
105356 char *z;
105357 int n;
105358 pLevel = &pWInfo->a[i];
105359 pTabItem = &pTabList->a[pLevel->iFrom];
105360 z = pTabItem->zAlias;
105361 if( z==0 ) z = pTabItem->pTab->zName;
105362 n = sqlite3Strlen30(z);
105363 if( n+nQPlan < sizeof(sqlite3_query_plan)-10 ){
105364 if( pLevel->plan.wsFlags & WHERE_IDX_ONLY ){
105365 memcpy(&sqlite3_query_plan[nQPlan], "{}", 2);
105366 nQPlan += 2;
105367 }else{
105368 memcpy(&sqlite3_query_plan[nQPlan], z, n);
105369 nQPlan += n;
105371 sqlite3_query_plan[nQPlan++] = ' ';
105373 testcase( pLevel->plan.wsFlags & WHERE_ROWID_EQ );
105374 testcase( pLevel->plan.wsFlags & WHERE_ROWID_RANGE );
105375 if( pLevel->plan.wsFlags & (WHERE_ROWID_EQ|WHERE_ROWID_RANGE) ){
105376 memcpy(&sqlite3_query_plan[nQPlan], "* ", 2);
105377 nQPlan += 2;
105378 }else if( (pLevel->plan.wsFlags & WHERE_INDEXED)!=0 ){
105379 n = sqlite3Strlen30(pLevel->plan.u.pIdx->zName);
105380 if( n+nQPlan < sizeof(sqlite3_query_plan)-2 ){
105381 memcpy(&sqlite3_query_plan[nQPlan], pLevel->plan.u.pIdx->zName, n);
105382 nQPlan += n;
105383 sqlite3_query_plan[nQPlan++] = ' ';
105385 }else{
105386 memcpy(&sqlite3_query_plan[nQPlan], "{} ", 3);
105387 nQPlan += 3;
105390 while( nQPlan>0 && sqlite3_query_plan[nQPlan-1]==' ' ){
105391 sqlite3_query_plan[--nQPlan] = 0;
105393 sqlite3_query_plan[nQPlan] = 0;
105394 nQPlan = 0;
105395 #endif /* SQLITE_TEST // Testing and debugging use only */
105397 /* Record the continuation address in the WhereInfo structure. Then
105398 ** clean up and return.
105400 return pWInfo;
105402 /* Jump here if malloc fails */
105403 whereBeginError:
105404 if( pWInfo ){
105405 pParse->nQueryLoop = pWInfo->savedNQueryLoop;
105406 whereInfoFree(db, pWInfo);
105408 return 0;
105412 ** Generate the end of the WHERE loop. See comments on
105413 ** sqlite3WhereBegin() for additional information.
105415 SQLITE_PRIVATE void sqlite3WhereEnd(WhereInfo *pWInfo){
105416 Parse *pParse = pWInfo->pParse;
105417 Vdbe *v = pParse->pVdbe;
105418 int i;
105419 WhereLevel *pLevel;
105420 SrcList *pTabList = pWInfo->pTabList;
105421 sqlite3 *db = pParse->db;
105423 /* Generate loop termination code.
105425 sqlite3ExprCacheClear(pParse);
105426 for(i=pWInfo->nLevel-1; i>=0; i--){
105427 pLevel = &pWInfo->a[i];
105428 sqlite3VdbeResolveLabel(v, pLevel->addrCont);
105429 if( pLevel->op!=OP_Noop ){
105430 sqlite3VdbeAddOp2(v, pLevel->op, pLevel->p1, pLevel->p2);
105431 sqlite3VdbeChangeP5(v, pLevel->p5);
105433 if( pLevel->plan.wsFlags & WHERE_IN_ABLE && pLevel->u.in.nIn>0 ){
105434 struct InLoop *pIn;
105435 int j;
105436 sqlite3VdbeResolveLabel(v, pLevel->addrNxt);
105437 for(j=pLevel->u.in.nIn, pIn=&pLevel->u.in.aInLoop[j-1]; j>0; j--, pIn--){
105438 sqlite3VdbeJumpHere(v, pIn->addrInTop+1);
105439 sqlite3VdbeAddOp2(v, OP_Next, pIn->iCur, pIn->addrInTop);
105440 sqlite3VdbeJumpHere(v, pIn->addrInTop-1);
105442 sqlite3DbFree(db, pLevel->u.in.aInLoop);
105444 sqlite3VdbeResolveLabel(v, pLevel->addrBrk);
105445 if( pLevel->iLeftJoin ){
105446 int addr;
105447 addr = sqlite3VdbeAddOp1(v, OP_IfPos, pLevel->iLeftJoin);
105448 assert( (pLevel->plan.wsFlags & WHERE_IDX_ONLY)==0
105449 || (pLevel->plan.wsFlags & WHERE_INDEXED)!=0 );
105450 if( (pLevel->plan.wsFlags & WHERE_IDX_ONLY)==0 ){
105451 sqlite3VdbeAddOp1(v, OP_NullRow, pTabList->a[i].iCursor);
105453 if( pLevel->iIdxCur>=0 ){
105454 sqlite3VdbeAddOp1(v, OP_NullRow, pLevel->iIdxCur);
105456 if( pLevel->op==OP_Return ){
105457 sqlite3VdbeAddOp2(v, OP_Gosub, pLevel->p1, pLevel->addrFirst);
105458 }else{
105459 sqlite3VdbeAddOp2(v, OP_Goto, 0, pLevel->addrFirst);
105461 sqlite3VdbeJumpHere(v, addr);
105465 /* The "break" point is here, just past the end of the outer loop.
105466 ** Set it.
105468 sqlite3VdbeResolveLabel(v, pWInfo->iBreak);
105470 /* Close all of the cursors that were opened by sqlite3WhereBegin.
105472 assert( pWInfo->nLevel==1 || pWInfo->nLevel==pTabList->nSrc );
105473 for(i=0, pLevel=pWInfo->a; i<pWInfo->nLevel; i++, pLevel++){
105474 struct SrcList_item *pTabItem = &pTabList->a[pLevel->iFrom];
105475 Table *pTab = pTabItem->pTab;
105476 assert( pTab!=0 );
105477 if( (pTab->tabFlags & TF_Ephemeral)==0
105478 && pTab->pSelect==0
105479 && (pWInfo->wctrlFlags & WHERE_OMIT_CLOSE)==0
105481 int ws = pLevel->plan.wsFlags;
105482 if( !pWInfo->okOnePass && (ws & WHERE_IDX_ONLY)==0 ){
105483 sqlite3VdbeAddOp1(v, OP_Close, pTabItem->iCursor);
105485 if( (ws & WHERE_INDEXED)!=0 && (ws & WHERE_TEMP_INDEX)==0 ){
105486 sqlite3VdbeAddOp1(v, OP_Close, pLevel->iIdxCur);
105490 /* If this scan uses an index, make code substitutions to read data
105491 ** from the index in preference to the table. Sometimes, this means
105492 ** the table need never be read from. This is a performance boost,
105493 ** as the vdbe level waits until the table is read before actually
105494 ** seeking the table cursor to the record corresponding to the current
105495 ** position in the index.
105497 ** Calls to the code generator in between sqlite3WhereBegin and
105498 ** sqlite3WhereEnd will have created code that references the table
105499 ** directly. This loop scans all that code looking for opcodes
105500 ** that reference the table and converts them into opcodes that
105501 ** reference the index.
105503 if( (pLevel->plan.wsFlags & WHERE_INDEXED)!=0 && !db->mallocFailed){
105504 int k, j, last;
105505 VdbeOp *pOp;
105506 Index *pIdx = pLevel->plan.u.pIdx;
105508 assert( pIdx!=0 );
105509 pOp = sqlite3VdbeGetOp(v, pWInfo->iTop);
105510 last = sqlite3VdbeCurrentAddr(v);
105511 for(k=pWInfo->iTop; k<last; k++, pOp++){
105512 if( pOp->p1!=pLevel->iTabCur ) continue;
105513 if( pOp->opcode==OP_Column ){
105514 for(j=0; j<pIdx->nColumn; j++){
105515 if( pOp->p2==pIdx->aiColumn[j] ){
105516 pOp->p2 = j;
105517 pOp->p1 = pLevel->iIdxCur;
105518 break;
105521 assert( (pLevel->plan.wsFlags & WHERE_IDX_ONLY)==0
105522 || j<pIdx->nColumn );
105523 }else if( pOp->opcode==OP_Rowid ){
105524 pOp->p1 = pLevel->iIdxCur;
105525 pOp->opcode = OP_IdxRowid;
105531 /* Final cleanup
105533 pParse->nQueryLoop = pWInfo->savedNQueryLoop;
105534 whereInfoFree(db, pWInfo);
105535 return;
105538 /************** End of where.c ***********************************************/
105539 /************** Begin file parse.c *******************************************/
105540 /* Driver template for the LEMON parser generator.
105541 ** The author disclaims copyright to this source code.
105543 ** This version of "lempar.c" is modified, slightly, for use by SQLite.
105544 ** The only modifications are the addition of a couple of NEVER()
105545 ** macros to disable tests that are needed in the case of a general
105546 ** LALR(1) grammar but which are always false in the
105547 ** specific grammar used by SQLite.
105549 /* First off, code is included that follows the "include" declaration
105550 ** in the input grammar file. */
105551 /* #include <stdio.h> */
105555 ** Disable all error recovery processing in the parser push-down
105556 ** automaton.
105558 #define YYNOERRORRECOVERY 1
105561 ** Make yytestcase() the same as testcase()
105563 #define yytestcase(X) testcase(X)
105566 ** An instance of this structure holds information about the
105567 ** LIMIT clause of a SELECT statement.
105569 struct LimitVal {
105570 Expr *pLimit; /* The LIMIT expression. NULL if there is no limit */
105571 Expr *pOffset; /* The OFFSET expression. NULL if there is none */
105575 ** An instance of this structure is used to store the LIKE,
105576 ** GLOB, NOT LIKE, and NOT GLOB operators.
105578 struct LikeOp {
105579 Token eOperator; /* "like" or "glob" or "regexp" */
105580 int not; /* True if the NOT keyword is present */
105584 ** An instance of the following structure describes the event of a
105585 ** TRIGGER. "a" is the event type, one of TK_UPDATE, TK_INSERT,
105586 ** TK_DELETE, or TK_INSTEAD. If the event is of the form
105588 ** UPDATE ON (a,b,c)
105590 ** Then the "b" IdList records the list "a,b,c".
105592 struct TrigEvent { int a; IdList * b; };
105595 ** An instance of this structure holds the ATTACH key and the key type.
105597 struct AttachKey { int type; Token key; };
105600 /* This is a utility routine used to set the ExprSpan.zStart and
105601 ** ExprSpan.zEnd values of pOut so that the span covers the complete
105602 ** range of text beginning with pStart and going to the end of pEnd.
105604 static void spanSet(ExprSpan *pOut, Token *pStart, Token *pEnd){
105605 pOut->zStart = pStart->z;
105606 pOut->zEnd = &pEnd->z[pEnd->n];
105609 /* Construct a new Expr object from a single identifier. Use the
105610 ** new Expr to populate pOut. Set the span of pOut to be the identifier
105611 ** that created the expression.
105613 static void spanExpr(ExprSpan *pOut, Parse *pParse, int op, Token *pValue){
105614 pOut->pExpr = sqlite3PExpr(pParse, op, 0, 0, pValue);
105615 pOut->zStart = pValue->z;
105616 pOut->zEnd = &pValue->z[pValue->n];
105619 /* This routine constructs a binary expression node out of two ExprSpan
105620 ** objects and uses the result to populate a new ExprSpan object.
105622 static void spanBinaryExpr(
105623 ExprSpan *pOut, /* Write the result here */
105624 Parse *pParse, /* The parsing context. Errors accumulate here */
105625 int op, /* The binary operation */
105626 ExprSpan *pLeft, /* The left operand */
105627 ExprSpan *pRight /* The right operand */
105629 pOut->pExpr = sqlite3PExpr(pParse, op, pLeft->pExpr, pRight->pExpr, 0);
105630 pOut->zStart = pLeft->zStart;
105631 pOut->zEnd = pRight->zEnd;
105634 /* Construct an expression node for a unary postfix operator
105636 static void spanUnaryPostfix(
105637 ExprSpan *pOut, /* Write the new expression node here */
105638 Parse *pParse, /* Parsing context to record errors */
105639 int op, /* The operator */
105640 ExprSpan *pOperand, /* The operand */
105641 Token *pPostOp /* The operand token for setting the span */
105643 pOut->pExpr = sqlite3PExpr(pParse, op, pOperand->pExpr, 0, 0);
105644 pOut->zStart = pOperand->zStart;
105645 pOut->zEnd = &pPostOp->z[pPostOp->n];
105648 /* A routine to convert a binary TK_IS or TK_ISNOT expression into a
105649 ** unary TK_ISNULL or TK_NOTNULL expression. */
105650 static void binaryToUnaryIfNull(Parse *pParse, Expr *pY, Expr *pA, int op){
105651 sqlite3 *db = pParse->db;
105652 if( db->mallocFailed==0 && pY->op==TK_NULL ){
105653 pA->op = (u8)op;
105654 sqlite3ExprDelete(db, pA->pRight);
105655 pA->pRight = 0;
105659 /* Construct an expression node for a unary prefix operator
105661 static void spanUnaryPrefix(
105662 ExprSpan *pOut, /* Write the new expression node here */
105663 Parse *pParse, /* Parsing context to record errors */
105664 int op, /* The operator */
105665 ExprSpan *pOperand, /* The operand */
105666 Token *pPreOp /* The operand token for setting the span */
105668 pOut->pExpr = sqlite3PExpr(pParse, op, pOperand->pExpr, 0, 0);
105669 pOut->zStart = pPreOp->z;
105670 pOut->zEnd = pOperand->zEnd;
105672 /* Next is all token values, in a form suitable for use by makeheaders.
105673 ** This section will be null unless lemon is run with the -m switch.
105676 ** These constants (all generated automatically by the parser generator)
105677 ** specify the various kinds of tokens (terminals) that the parser
105678 ** understands.
105680 ** Each symbol here is a terminal symbol in the grammar.
105682 /* Make sure the INTERFACE macro is defined.
105684 #ifndef INTERFACE
105685 # define INTERFACE 1
105686 #endif
105687 /* The next thing included is series of defines which control
105688 ** various aspects of the generated parser.
105689 ** YYCODETYPE is the data type used for storing terminal
105690 ** and nonterminal numbers. "unsigned char" is
105691 ** used if there are fewer than 250 terminals
105692 ** and nonterminals. "int" is used otherwise.
105693 ** YYNOCODE is a number of type YYCODETYPE which corresponds
105694 ** to no legal terminal or nonterminal number. This
105695 ** number is used to fill in empty slots of the hash
105696 ** table.
105697 ** YYFALLBACK If defined, this indicates that one or more tokens
105698 ** have fall-back values which should be used if the
105699 ** original value of the token will not parse.
105700 ** YYACTIONTYPE is the data type used for storing terminal
105701 ** and nonterminal numbers. "unsigned char" is
105702 ** used if there are fewer than 250 rules and
105703 ** states combined. "int" is used otherwise.
105704 ** sqlite3ParserTOKENTYPE is the data type used for minor tokens given
105705 ** directly to the parser from the tokenizer.
105706 ** YYMINORTYPE is the data type used for all minor tokens.
105707 ** This is typically a union of many types, one of
105708 ** which is sqlite3ParserTOKENTYPE. The entry in the union
105709 ** for base tokens is called "yy0".
105710 ** YYSTACKDEPTH is the maximum depth of the parser's stack. If
105711 ** zero the stack is dynamically sized using realloc()
105712 ** sqlite3ParserARG_SDECL A static variable declaration for the %extra_argument
105713 ** sqlite3ParserARG_PDECL A parameter declaration for the %extra_argument
105714 ** sqlite3ParserARG_STORE Code to store %extra_argument into yypParser
105715 ** sqlite3ParserARG_FETCH Code to extract %extra_argument from yypParser
105716 ** YYNSTATE the combined number of states.
105717 ** YYNRULE the number of rules in the grammar
105718 ** YYERRORSYMBOL is the code number of the error symbol. If not
105719 ** defined, then do no error processing.
105721 #define YYCODETYPE unsigned char
105722 #define YYNOCODE 253
105723 #define YYACTIONTYPE unsigned short int
105724 #define YYWILDCARD 67
105725 #define sqlite3ParserTOKENTYPE Token
105726 typedef union {
105727 int yyinit;
105728 sqlite3ParserTOKENTYPE yy0;
105729 int yy4;
105730 struct TrigEvent yy90;
105731 ExprSpan yy118;
105732 TriggerStep* yy203;
105733 u8 yy210;
105734 struct {int value; int mask;} yy215;
105735 SrcList* yy259;
105736 struct LimitVal yy292;
105737 Expr* yy314;
105738 ExprList* yy322;
105739 struct LikeOp yy342;
105740 IdList* yy384;
105741 Select* yy387;
105742 } YYMINORTYPE;
105743 #ifndef YYSTACKDEPTH
105744 #define YYSTACKDEPTH 100
105745 #endif
105746 #define sqlite3ParserARG_SDECL Parse *pParse;
105747 #define sqlite3ParserARG_PDECL ,Parse *pParse
105748 #define sqlite3ParserARG_FETCH Parse *pParse = yypParser->pParse
105749 #define sqlite3ParserARG_STORE yypParser->pParse = pParse
105750 #define YYNSTATE 630
105751 #define YYNRULE 329
105752 #define YYFALLBACK 1
105753 #define YY_NO_ACTION (YYNSTATE+YYNRULE+2)
105754 #define YY_ACCEPT_ACTION (YYNSTATE+YYNRULE+1)
105755 #define YY_ERROR_ACTION (YYNSTATE+YYNRULE)
105757 /* The yyzerominor constant is used to initialize instances of
105758 ** YYMINORTYPE objects to zero. */
105759 static const YYMINORTYPE yyzerominor = { 0 };
105761 /* Define the yytestcase() macro to be a no-op if is not already defined
105762 ** otherwise.
105764 ** Applications can choose to define yytestcase() in the %include section
105765 ** to a macro that can assist in verifying code coverage. For production
105766 ** code the yytestcase() macro should be turned off. But it is useful
105767 ** for testing.
105769 #ifndef yytestcase
105770 # define yytestcase(X)
105771 #endif
105774 /* Next are the tables used to determine what action to take based on the
105775 ** current state and lookahead token. These tables are used to implement
105776 ** functions that take a state number and lookahead value and return an
105777 ** action integer.
105779 ** Suppose the action integer is N. Then the action is determined as
105780 ** follows
105782 ** 0 <= N < YYNSTATE Shift N. That is, push the lookahead
105783 ** token onto the stack and goto state N.
105785 ** YYNSTATE <= N < YYNSTATE+YYNRULE Reduce by rule N-YYNSTATE.
105787 ** N == YYNSTATE+YYNRULE A syntax error has occurred.
105789 ** N == YYNSTATE+YYNRULE+1 The parser accepts its input.
105791 ** N == YYNSTATE+YYNRULE+2 No such action. Denotes unused
105792 ** slots in the yy_action[] table.
105794 ** The action table is constructed as a single large table named yy_action[].
105795 ** Given state S and lookahead X, the action is computed as
105797 ** yy_action[ yy_shift_ofst[S] + X ]
105799 ** If the index value yy_shift_ofst[S]+X is out of range or if the value
105800 ** yy_lookahead[yy_shift_ofst[S]+X] is not equal to X or if yy_shift_ofst[S]
105801 ** is equal to YY_SHIFT_USE_DFLT, it means that the action is not in the table
105802 ** and that yy_default[S] should be used instead.
105804 ** The formula above is for computing the action when the lookahead is
105805 ** a terminal symbol. If the lookahead is a non-terminal (as occurs after
105806 ** a reduce action) then the yy_reduce_ofst[] array is used in place of
105807 ** the yy_shift_ofst[] array and YY_REDUCE_USE_DFLT is used in place of
105808 ** YY_SHIFT_USE_DFLT.
105810 ** The following are the tables generated in this section:
105812 ** yy_action[] A single table containing all actions.
105813 ** yy_lookahead[] A table containing the lookahead for each entry in
105814 ** yy_action. Used to detect hash collisions.
105815 ** yy_shift_ofst[] For each state, the offset into yy_action for
105816 ** shifting terminals.
105817 ** yy_reduce_ofst[] For each state, the offset into yy_action for
105818 ** shifting non-terminals after a reduce.
105819 ** yy_default[] Default action for each state.
105821 #define YY_ACTTAB_COUNT (1557)
105822 static const YYACTIONTYPE yy_action[] = {
105823 /* 0 */ 313, 960, 186, 419, 2, 172, 627, 597, 55, 55,
105824 /* 10 */ 55, 55, 48, 53, 53, 53, 53, 52, 52, 51,
105825 /* 20 */ 51, 51, 50, 238, 302, 283, 623, 622, 516, 515,
105826 /* 30 */ 590, 584, 55, 55, 55, 55, 282, 53, 53, 53,
105827 /* 40 */ 53, 52, 52, 51, 51, 51, 50, 238, 6, 56,
105828 /* 50 */ 57, 47, 582, 581, 583, 583, 54, 54, 55, 55,
105829 /* 60 */ 55, 55, 608, 53, 53, 53, 53, 52, 52, 51,
105830 /* 70 */ 51, 51, 50, 238, 313, 597, 409, 330, 579, 579,
105831 /* 80 */ 32, 53, 53, 53, 53, 52, 52, 51, 51, 51,
105832 /* 90 */ 50, 238, 330, 217, 620, 619, 166, 411, 624, 382,
105833 /* 100 */ 379, 378, 7, 491, 590, 584, 200, 199, 198, 58,
105834 /* 110 */ 377, 300, 414, 621, 481, 66, 623, 622, 621, 580,
105835 /* 120 */ 254, 601, 94, 56, 57, 47, 582, 581, 583, 583,
105836 /* 130 */ 54, 54, 55, 55, 55, 55, 671, 53, 53, 53,
105837 /* 140 */ 53, 52, 52, 51, 51, 51, 50, 238, 313, 532,
105838 /* 150 */ 226, 506, 507, 133, 177, 139, 284, 385, 279, 384,
105839 /* 160 */ 169, 197, 342, 398, 251, 226, 253, 275, 388, 167,
105840 /* 170 */ 139, 284, 385, 279, 384, 169, 570, 236, 590, 584,
105841 /* 180 */ 672, 240, 275, 157, 620, 619, 554, 437, 51, 51,
105842 /* 190 */ 51, 50, 238, 343, 439, 553, 438, 56, 57, 47,
105843 /* 200 */ 582, 581, 583, 583, 54, 54, 55, 55, 55, 55,
105844 /* 210 */ 465, 53, 53, 53, 53, 52, 52, 51, 51, 51,
105845 /* 220 */ 50, 238, 313, 390, 52, 52, 51, 51, 51, 50,
105846 /* 230 */ 238, 391, 166, 491, 566, 382, 379, 378, 409, 440,
105847 /* 240 */ 579, 579, 252, 440, 607, 66, 377, 513, 621, 49,
105848 /* 250 */ 46, 147, 590, 584, 621, 16, 466, 189, 621, 441,
105849 /* 260 */ 442, 673, 526, 441, 340, 577, 595, 64, 194, 482,
105850 /* 270 */ 434, 56, 57, 47, 582, 581, 583, 583, 54, 54,
105851 /* 280 */ 55, 55, 55, 55, 30, 53, 53, 53, 53, 52,
105852 /* 290 */ 52, 51, 51, 51, 50, 238, 313, 593, 593, 593,
105853 /* 300 */ 387, 578, 606, 493, 259, 351, 258, 411, 1, 623,
105854 /* 310 */ 622, 496, 623, 622, 65, 240, 623, 622, 597, 443,
105855 /* 320 */ 237, 239, 414, 341, 237, 602, 590, 584, 18, 603,
105856 /* 330 */ 166, 601, 87, 382, 379, 378, 67, 623, 622, 38,
105857 /* 340 */ 623, 622, 176, 270, 377, 56, 57, 47, 582, 581,
105858 /* 350 */ 583, 583, 54, 54, 55, 55, 55, 55, 175, 53,
105859 /* 360 */ 53, 53, 53, 52, 52, 51, 51, 51, 50, 238,
105860 /* 370 */ 313, 396, 233, 411, 531, 565, 317, 620, 619, 44,
105861 /* 380 */ 620, 619, 240, 206, 620, 619, 597, 266, 414, 268,
105862 /* 390 */ 409, 597, 579, 579, 352, 184, 505, 601, 73, 533,
105863 /* 400 */ 590, 584, 466, 548, 190, 620, 619, 576, 620, 619,
105864 /* 410 */ 547, 383, 551, 35, 332, 575, 574, 600, 504, 56,
105865 /* 420 */ 57, 47, 582, 581, 583, 583, 54, 54, 55, 55,
105866 /* 430 */ 55, 55, 567, 53, 53, 53, 53, 52, 52, 51,
105867 /* 440 */ 51, 51, 50, 238, 313, 411, 561, 561, 528, 364,
105868 /* 450 */ 259, 351, 258, 183, 361, 549, 524, 374, 411, 597,
105869 /* 460 */ 414, 240, 560, 560, 409, 604, 579, 579, 328, 601,
105870 /* 470 */ 93, 623, 622, 414, 590, 584, 237, 564, 559, 559,
105871 /* 480 */ 520, 402, 601, 87, 409, 210, 579, 579, 168, 421,
105872 /* 490 */ 950, 519, 950, 56, 57, 47, 582, 581, 583, 583,
105873 /* 500 */ 54, 54, 55, 55, 55, 55, 192, 53, 53, 53,
105874 /* 510 */ 53, 52, 52, 51, 51, 51, 50, 238, 313, 600,
105875 /* 520 */ 293, 563, 511, 234, 357, 146, 475, 475, 367, 411,
105876 /* 530 */ 562, 411, 358, 542, 425, 171, 411, 215, 144, 620,
105877 /* 540 */ 619, 544, 318, 353, 414, 203, 414, 275, 590, 584,
105878 /* 550 */ 549, 414, 174, 601, 94, 601, 79, 558, 471, 61,
105879 /* 560 */ 601, 79, 421, 949, 350, 949, 34, 56, 57, 47,
105880 /* 570 */ 582, 581, 583, 583, 54, 54, 55, 55, 55, 55,
105881 /* 580 */ 535, 53, 53, 53, 53, 52, 52, 51, 51, 51,
105882 /* 590 */ 50, 238, 313, 307, 424, 394, 272, 49, 46, 147,
105883 /* 600 */ 349, 322, 4, 411, 491, 312, 321, 425, 568, 492,
105884 /* 610 */ 216, 264, 407, 575, 574, 429, 66, 549, 414, 621,
105885 /* 620 */ 540, 602, 590, 584, 13, 603, 621, 601, 72, 12,
105886 /* 630 */ 618, 617, 616, 202, 210, 621, 546, 469, 422, 319,
105887 /* 640 */ 148, 56, 57, 47, 582, 581, 583, 583, 54, 54,
105888 /* 650 */ 55, 55, 55, 55, 338, 53, 53, 53, 53, 52,
105889 /* 660 */ 52, 51, 51, 51, 50, 238, 313, 600, 600, 411,
105890 /* 670 */ 39, 21, 37, 170, 237, 875, 411, 572, 572, 201,
105891 /* 680 */ 144, 473, 538, 331, 414, 474, 143, 146, 630, 628,
105892 /* 690 */ 334, 414, 353, 601, 68, 168, 590, 584, 132, 365,
105893 /* 700 */ 601, 96, 307, 423, 530, 336, 49, 46, 147, 568,
105894 /* 710 */ 406, 216, 549, 360, 529, 56, 57, 47, 582, 581,
105895 /* 720 */ 583, 583, 54, 54, 55, 55, 55, 55, 411, 53,
105896 /* 730 */ 53, 53, 53, 52, 52, 51, 51, 51, 50, 238,
105897 /* 740 */ 313, 411, 605, 414, 484, 510, 172, 422, 597, 318,
105898 /* 750 */ 496, 485, 601, 99, 411, 142, 414, 411, 231, 411,
105899 /* 760 */ 540, 411, 359, 629, 2, 601, 97, 426, 308, 414,
105900 /* 770 */ 590, 584, 414, 20, 414, 621, 414, 621, 601, 106,
105901 /* 780 */ 503, 601, 105, 601, 108, 601, 109, 204, 28, 56,
105902 /* 790 */ 57, 47, 582, 581, 583, 583, 54, 54, 55, 55,
105903 /* 800 */ 55, 55, 411, 53, 53, 53, 53, 52, 52, 51,
105904 /* 810 */ 51, 51, 50, 238, 313, 411, 597, 414, 411, 276,
105905 /* 820 */ 214, 600, 411, 366, 213, 381, 601, 134, 274, 500,
105906 /* 830 */ 414, 167, 130, 414, 621, 411, 354, 414, 376, 601,
105907 /* 840 */ 135, 129, 601, 100, 590, 584, 601, 104, 522, 521,
105908 /* 850 */ 414, 621, 224, 273, 600, 167, 327, 282, 600, 601,
105909 /* 860 */ 103, 468, 521, 56, 57, 47, 582, 581, 583, 583,
105910 /* 870 */ 54, 54, 55, 55, 55, 55, 411, 53, 53, 53,
105911 /* 880 */ 53, 52, 52, 51, 51, 51, 50, 238, 313, 411,
105912 /* 890 */ 27, 414, 411, 375, 276, 167, 359, 544, 50, 238,
105913 /* 900 */ 601, 95, 128, 223, 414, 411, 165, 414, 411, 621,
105914 /* 910 */ 411, 621, 612, 601, 102, 372, 601, 76, 590, 584,
105915 /* 920 */ 414, 570, 236, 414, 470, 414, 167, 621, 188, 601,
105916 /* 930 */ 98, 225, 601, 138, 601, 137, 232, 56, 45, 47,
105917 /* 940 */ 582, 581, 583, 583, 54, 54, 55, 55, 55, 55,
105918 /* 950 */ 411, 53, 53, 53, 53, 52, 52, 51, 51, 51,
105919 /* 960 */ 50, 238, 313, 276, 276, 414, 411, 276, 544, 459,
105920 /* 970 */ 359, 171, 209, 479, 601, 136, 628, 334, 621, 621,
105921 /* 980 */ 125, 414, 621, 368, 411, 621, 257, 540, 589, 588,
105922 /* 990 */ 601, 75, 590, 584, 458, 446, 23, 23, 124, 414,
105923 /* 1000 */ 326, 325, 621, 427, 324, 309, 600, 288, 601, 92,
105924 /* 1010 */ 586, 585, 57, 47, 582, 581, 583, 583, 54, 54,
105925 /* 1020 */ 55, 55, 55, 55, 411, 53, 53, 53, 53, 52,
105926 /* 1030 */ 52, 51, 51, 51, 50, 238, 313, 587, 411, 414,
105927 /* 1040 */ 411, 207, 611, 476, 171, 472, 160, 123, 601, 91,
105928 /* 1050 */ 323, 261, 15, 414, 464, 414, 411, 621, 411, 354,
105929 /* 1060 */ 222, 411, 601, 74, 601, 90, 590, 584, 159, 264,
105930 /* 1070 */ 158, 414, 461, 414, 621, 600, 414, 121, 120, 25,
105931 /* 1080 */ 601, 89, 601, 101, 621, 601, 88, 47, 582, 581,
105932 /* 1090 */ 583, 583, 54, 54, 55, 55, 55, 55, 544, 53,
105933 /* 1100 */ 53, 53, 53, 52, 52, 51, 51, 51, 50, 238,
105934 /* 1110 */ 43, 405, 263, 3, 610, 264, 140, 415, 622, 24,
105935 /* 1120 */ 410, 11, 456, 594, 118, 155, 219, 452, 408, 621,
105936 /* 1130 */ 621, 621, 156, 43, 405, 621, 3, 286, 621, 113,
105937 /* 1140 */ 415, 622, 111, 445, 411, 400, 557, 403, 545, 10,
105938 /* 1150 */ 411, 408, 264, 110, 205, 436, 541, 566, 453, 414,
105939 /* 1160 */ 621, 621, 63, 621, 435, 414, 411, 621, 601, 94,
105940 /* 1170 */ 403, 621, 411, 337, 601, 86, 150, 40, 41, 534,
105941 /* 1180 */ 566, 414, 242, 264, 42, 413, 412, 414, 600, 595,
105942 /* 1190 */ 601, 85, 191, 333, 107, 451, 601, 84, 621, 539,
105943 /* 1200 */ 40, 41, 420, 230, 411, 149, 316, 42, 413, 412,
105944 /* 1210 */ 398, 127, 595, 315, 621, 399, 278, 625, 181, 414,
105945 /* 1220 */ 593, 593, 593, 592, 591, 14, 450, 411, 601, 71,
105946 /* 1230 */ 240, 621, 43, 405, 264, 3, 615, 180, 264, 415,
105947 /* 1240 */ 622, 614, 414, 593, 593, 593, 592, 591, 14, 621,
105948 /* 1250 */ 408, 601, 70, 621, 417, 33, 405, 613, 3, 411,
105949 /* 1260 */ 264, 411, 415, 622, 418, 626, 178, 509, 8, 403,
105950 /* 1270 */ 241, 416, 126, 408, 414, 621, 414, 449, 208, 566,
105951 /* 1280 */ 240, 221, 621, 601, 83, 601, 82, 599, 297, 277,
105952 /* 1290 */ 296, 30, 403, 31, 395, 264, 295, 397, 489, 40,
105953 /* 1300 */ 41, 411, 566, 220, 621, 294, 42, 413, 412, 271,
105954 /* 1310 */ 621, 595, 600, 621, 59, 60, 414, 269, 267, 623,
105955 /* 1320 */ 622, 36, 40, 41, 621, 601, 81, 598, 235, 42,
105956 /* 1330 */ 413, 412, 621, 621, 595, 265, 344, 411, 248, 556,
105957 /* 1340 */ 173, 185, 593, 593, 593, 592, 591, 14, 218, 29,
105958 /* 1350 */ 621, 543, 414, 305, 304, 303, 179, 301, 411, 566,
105959 /* 1360 */ 454, 601, 80, 289, 335, 593, 593, 593, 592, 591,
105960 /* 1370 */ 14, 411, 287, 414, 151, 392, 246, 260, 411, 196,
105961 /* 1380 */ 195, 523, 601, 69, 411, 245, 414, 526, 537, 285,
105962 /* 1390 */ 389, 595, 621, 414, 536, 601, 17, 362, 153, 414,
105963 /* 1400 */ 466, 463, 601, 78, 154, 414, 462, 152, 601, 77,
105964 /* 1410 */ 355, 255, 621, 455, 601, 9, 621, 386, 444, 517,
105965 /* 1420 */ 247, 621, 593, 593, 593, 621, 621, 244, 621, 243,
105966 /* 1430 */ 430, 518, 292, 621, 329, 621, 145, 393, 280, 513,
105967 /* 1440 */ 291, 131, 621, 514, 621, 621, 311, 621, 259, 346,
105968 /* 1450 */ 249, 621, 621, 229, 314, 621, 228, 512, 227, 240,
105969 /* 1460 */ 494, 488, 310, 164, 487, 486, 373, 480, 163, 262,
105970 /* 1470 */ 369, 371, 162, 26, 212, 478, 477, 161, 141, 363,
105971 /* 1480 */ 467, 122, 339, 187, 119, 348, 347, 117, 116, 115,
105972 /* 1490 */ 114, 112, 182, 457, 320, 22, 433, 432, 448, 19,
105973 /* 1500 */ 609, 431, 428, 62, 193, 596, 573, 298, 555, 552,
105974 /* 1510 */ 571, 404, 290, 380, 498, 510, 495, 306, 281, 499,
105975 /* 1520 */ 250, 5, 497, 460, 345, 447, 569, 550, 238, 299,
105976 /* 1530 */ 527, 525, 508, 961, 502, 501, 961, 401, 961, 211,
105977 /* 1540 */ 490, 356, 256, 961, 483, 961, 961, 961, 961, 961,
105978 /* 1550 */ 961, 961, 961, 961, 961, 961, 370,
105980 static const YYCODETYPE yy_lookahead[] = {
105981 /* 0 */ 19, 142, 143, 144, 145, 24, 1, 26, 77, 78,
105982 /* 10 */ 79, 80, 81, 82, 83, 84, 85, 86, 87, 88,
105983 /* 20 */ 89, 90, 91, 92, 15, 98, 26, 27, 7, 8,
105984 /* 30 */ 49, 50, 77, 78, 79, 80, 109, 82, 83, 84,
105985 /* 40 */ 85, 86, 87, 88, 89, 90, 91, 92, 22, 68,
105986 /* 50 */ 69, 70, 71, 72, 73, 74, 75, 76, 77, 78,
105987 /* 60 */ 79, 80, 23, 82, 83, 84, 85, 86, 87, 88,
105988 /* 70 */ 89, 90, 91, 92, 19, 94, 112, 19, 114, 115,
105989 /* 80 */ 25, 82, 83, 84, 85, 86, 87, 88, 89, 90,
105990 /* 90 */ 91, 92, 19, 22, 94, 95, 96, 150, 150, 99,
105991 /* 100 */ 100, 101, 76, 150, 49, 50, 105, 106, 107, 54,
105992 /* 110 */ 110, 158, 165, 165, 161, 162, 26, 27, 165, 113,
105993 /* 120 */ 16, 174, 175, 68, 69, 70, 71, 72, 73, 74,
105994 /* 130 */ 75, 76, 77, 78, 79, 80, 118, 82, 83, 84,
105995 /* 140 */ 85, 86, 87, 88, 89, 90, 91, 92, 19, 23,
105996 /* 150 */ 92, 97, 98, 24, 96, 97, 98, 99, 100, 101,
105997 /* 160 */ 102, 25, 97, 216, 60, 92, 62, 109, 221, 25,
105998 /* 170 */ 97, 98, 99, 100, 101, 102, 86, 87, 49, 50,
105999 /* 180 */ 118, 116, 109, 25, 94, 95, 32, 97, 88, 89,
106000 /* 190 */ 90, 91, 92, 128, 104, 41, 106, 68, 69, 70,
106001 /* 200 */ 71, 72, 73, 74, 75, 76, 77, 78, 79, 80,
106002 /* 210 */ 11, 82, 83, 84, 85, 86, 87, 88, 89, 90,
106003 /* 220 */ 91, 92, 19, 19, 86, 87, 88, 89, 90, 91,
106004 /* 230 */ 92, 27, 96, 150, 66, 99, 100, 101, 112, 150,
106005 /* 240 */ 114, 115, 138, 150, 161, 162, 110, 103, 165, 222,
106006 /* 250 */ 223, 224, 49, 50, 165, 22, 57, 24, 165, 170,
106007 /* 260 */ 171, 118, 94, 170, 171, 23, 98, 25, 185, 186,
106008 /* 270 */ 243, 68, 69, 70, 71, 72, 73, 74, 75, 76,
106009 /* 280 */ 77, 78, 79, 80, 126, 82, 83, 84, 85, 86,
106010 /* 290 */ 87, 88, 89, 90, 91, 92, 19, 129, 130, 131,
106011 /* 300 */ 88, 23, 172, 173, 105, 106, 107, 150, 22, 26,
106012 /* 310 */ 27, 181, 26, 27, 22, 116, 26, 27, 26, 230,
106013 /* 320 */ 231, 197, 165, 230, 231, 113, 49, 50, 204, 117,
106014 /* 330 */ 96, 174, 175, 99, 100, 101, 22, 26, 27, 136,
106015 /* 340 */ 26, 27, 118, 16, 110, 68, 69, 70, 71, 72,
106016 /* 350 */ 73, 74, 75, 76, 77, 78, 79, 80, 118, 82,
106017 /* 360 */ 83, 84, 85, 86, 87, 88, 89, 90, 91, 92,
106018 /* 370 */ 19, 214, 215, 150, 23, 23, 155, 94, 95, 22,
106019 /* 380 */ 94, 95, 116, 160, 94, 95, 94, 60, 165, 62,
106020 /* 390 */ 112, 26, 114, 115, 128, 23, 36, 174, 175, 88,
106021 /* 400 */ 49, 50, 57, 120, 22, 94, 95, 23, 94, 95,
106022 /* 410 */ 120, 51, 25, 136, 169, 170, 171, 194, 58, 68,
106023 /* 420 */ 69, 70, 71, 72, 73, 74, 75, 76, 77, 78,
106024 /* 430 */ 79, 80, 23, 82, 83, 84, 85, 86, 87, 88,
106025 /* 440 */ 89, 90, 91, 92, 19, 150, 12, 12, 23, 228,
106026 /* 450 */ 105, 106, 107, 23, 233, 25, 165, 19, 150, 94,
106027 /* 460 */ 165, 116, 28, 28, 112, 174, 114, 115, 108, 174,
106028 /* 470 */ 175, 26, 27, 165, 49, 50, 231, 11, 44, 44,
106029 /* 480 */ 46, 46, 174, 175, 112, 160, 114, 115, 50, 22,
106030 /* 490 */ 23, 57, 25, 68, 69, 70, 71, 72, 73, 74,
106031 /* 500 */ 75, 76, 77, 78, 79, 80, 119, 82, 83, 84,
106032 /* 510 */ 85, 86, 87, 88, 89, 90, 91, 92, 19, 194,
106033 /* 520 */ 225, 23, 23, 215, 19, 95, 105, 106, 107, 150,
106034 /* 530 */ 23, 150, 27, 23, 67, 25, 150, 206, 207, 94,
106035 /* 540 */ 95, 166, 104, 218, 165, 22, 165, 109, 49, 50,
106036 /* 550 */ 120, 165, 25, 174, 175, 174, 175, 23, 21, 234,
106037 /* 560 */ 174, 175, 22, 23, 239, 25, 25, 68, 69, 70,
106038 /* 570 */ 71, 72, 73, 74, 75, 76, 77, 78, 79, 80,
106039 /* 580 */ 205, 82, 83, 84, 85, 86, 87, 88, 89, 90,
106040 /* 590 */ 91, 92, 19, 22, 23, 216, 23, 222, 223, 224,
106041 /* 600 */ 63, 220, 35, 150, 150, 163, 220, 67, 166, 167,
106042 /* 610 */ 168, 150, 169, 170, 171, 161, 162, 25, 165, 165,
106043 /* 620 */ 150, 113, 49, 50, 25, 117, 165, 174, 175, 35,
106044 /* 630 */ 7, 8, 9, 160, 160, 165, 120, 100, 67, 247,
106045 /* 640 */ 248, 68, 69, 70, 71, 72, 73, 74, 75, 76,
106046 /* 650 */ 77, 78, 79, 80, 193, 82, 83, 84, 85, 86,
106047 /* 660 */ 87, 88, 89, 90, 91, 92, 19, 194, 194, 150,
106048 /* 670 */ 135, 24, 137, 35, 231, 138, 150, 129, 130, 206,
106049 /* 680 */ 207, 30, 27, 213, 165, 34, 118, 95, 0, 1,
106050 /* 690 */ 2, 165, 218, 174, 175, 50, 49, 50, 22, 48,
106051 /* 700 */ 174, 175, 22, 23, 23, 244, 222, 223, 224, 166,
106052 /* 710 */ 167, 168, 120, 239, 23, 68, 69, 70, 71, 72,
106053 /* 720 */ 73, 74, 75, 76, 77, 78, 79, 80, 150, 82,
106054 /* 730 */ 83, 84, 85, 86, 87, 88, 89, 90, 91, 92,
106055 /* 740 */ 19, 150, 173, 165, 181, 182, 24, 67, 26, 104,
106056 /* 750 */ 181, 188, 174, 175, 150, 39, 165, 150, 52, 150,
106057 /* 760 */ 150, 150, 150, 144, 145, 174, 175, 249, 250, 165,
106058 /* 770 */ 49, 50, 165, 52, 165, 165, 165, 165, 174, 175,
106059 /* 780 */ 29, 174, 175, 174, 175, 174, 175, 160, 22, 68,
106060 /* 790 */ 69, 70, 71, 72, 73, 74, 75, 76, 77, 78,
106061 /* 800 */ 79, 80, 150, 82, 83, 84, 85, 86, 87, 88,
106062 /* 810 */ 89, 90, 91, 92, 19, 150, 94, 165, 150, 150,
106063 /* 820 */ 160, 194, 150, 213, 160, 52, 174, 175, 23, 23,
106064 /* 830 */ 165, 25, 22, 165, 165, 150, 150, 165, 52, 174,
106065 /* 840 */ 175, 22, 174, 175, 49, 50, 174, 175, 190, 191,
106066 /* 850 */ 165, 165, 240, 23, 194, 25, 187, 109, 194, 174,
106067 /* 860 */ 175, 190, 191, 68, 69, 70, 71, 72, 73, 74,
106068 /* 870 */ 75, 76, 77, 78, 79, 80, 150, 82, 83, 84,
106069 /* 880 */ 85, 86, 87, 88, 89, 90, 91, 92, 19, 150,
106070 /* 890 */ 22, 165, 150, 23, 150, 25, 150, 166, 91, 92,
106071 /* 900 */ 174, 175, 22, 217, 165, 150, 102, 165, 150, 165,
106072 /* 910 */ 150, 165, 150, 174, 175, 19, 174, 175, 49, 50,
106073 /* 920 */ 165, 86, 87, 165, 23, 165, 25, 165, 24, 174,
106074 /* 930 */ 175, 187, 174, 175, 174, 175, 205, 68, 69, 70,
106075 /* 940 */ 71, 72, 73, 74, 75, 76, 77, 78, 79, 80,
106076 /* 950 */ 150, 82, 83, 84, 85, 86, 87, 88, 89, 90,
106077 /* 960 */ 91, 92, 19, 150, 150, 165, 150, 150, 166, 23,
106078 /* 970 */ 150, 25, 160, 20, 174, 175, 1, 2, 165, 165,
106079 /* 980 */ 104, 165, 165, 43, 150, 165, 240, 150, 49, 50,
106080 /* 990 */ 174, 175, 49, 50, 23, 23, 25, 25, 53, 165,
106081 /* 1000 */ 187, 187, 165, 23, 187, 25, 194, 205, 174, 175,
106082 /* 1010 */ 71, 72, 69, 70, 71, 72, 73, 74, 75, 76,
106083 /* 1020 */ 77, 78, 79, 80, 150, 82, 83, 84, 85, 86,
106084 /* 1030 */ 87, 88, 89, 90, 91, 92, 19, 98, 150, 165,
106085 /* 1040 */ 150, 160, 150, 59, 25, 53, 104, 22, 174, 175,
106086 /* 1050 */ 213, 138, 5, 165, 1, 165, 150, 165, 150, 150,
106087 /* 1060 */ 240, 150, 174, 175, 174, 175, 49, 50, 118, 150,
106088 /* 1070 */ 35, 165, 27, 165, 165, 194, 165, 108, 127, 76,
106089 /* 1080 */ 174, 175, 174, 175, 165, 174, 175, 70, 71, 72,
106090 /* 1090 */ 73, 74, 75, 76, 77, 78, 79, 80, 166, 82,
106091 /* 1100 */ 83, 84, 85, 86, 87, 88, 89, 90, 91, 92,
106092 /* 1110 */ 19, 20, 193, 22, 150, 150, 150, 26, 27, 76,
106093 /* 1120 */ 150, 22, 1, 150, 119, 121, 217, 20, 37, 165,
106094 /* 1130 */ 165, 165, 16, 19, 20, 165, 22, 205, 165, 119,
106095 /* 1140 */ 26, 27, 108, 128, 150, 150, 150, 56, 150, 22,
106096 /* 1150 */ 150, 37, 150, 127, 160, 23, 150, 66, 193, 165,
106097 /* 1160 */ 165, 165, 16, 165, 23, 165, 150, 165, 174, 175,
106098 /* 1170 */ 56, 165, 150, 65, 174, 175, 15, 86, 87, 88,
106099 /* 1180 */ 66, 165, 140, 150, 93, 94, 95, 165, 194, 98,
106100 /* 1190 */ 174, 175, 22, 3, 164, 193, 174, 175, 165, 150,
106101 /* 1200 */ 86, 87, 4, 180, 150, 248, 251, 93, 94, 95,
106102 /* 1210 */ 216, 180, 98, 251, 165, 221, 150, 149, 6, 165,
106103 /* 1220 */ 129, 130, 131, 132, 133, 134, 193, 150, 174, 175,
106104 /* 1230 */ 116, 165, 19, 20, 150, 22, 149, 151, 150, 26,
106105 /* 1240 */ 27, 149, 165, 129, 130, 131, 132, 133, 134, 165,
106106 /* 1250 */ 37, 174, 175, 165, 149, 19, 20, 13, 22, 150,
106107 /* 1260 */ 150, 150, 26, 27, 146, 147, 151, 150, 25, 56,
106108 /* 1270 */ 152, 159, 154, 37, 165, 165, 165, 193, 160, 66,
106109 /* 1280 */ 116, 193, 165, 174, 175, 174, 175, 194, 199, 150,
106110 /* 1290 */ 200, 126, 56, 124, 123, 150, 201, 122, 150, 86,
106111 /* 1300 */ 87, 150, 66, 193, 165, 202, 93, 94, 95, 150,
106112 /* 1310 */ 165, 98, 194, 165, 125, 22, 165, 150, 150, 26,
106113 /* 1320 */ 27, 135, 86, 87, 165, 174, 175, 203, 226, 93,
106114 /* 1330 */ 94, 95, 165, 165, 98, 150, 218, 150, 193, 157,
106115 /* 1340 */ 118, 157, 129, 130, 131, 132, 133, 134, 5, 104,
106116 /* 1350 */ 165, 211, 165, 10, 11, 12, 13, 14, 150, 66,
106117 /* 1360 */ 17, 174, 175, 210, 246, 129, 130, 131, 132, 133,
106118 /* 1370 */ 134, 150, 210, 165, 31, 121, 33, 150, 150, 86,
106119 /* 1380 */ 87, 176, 174, 175, 150, 42, 165, 94, 211, 210,
106120 /* 1390 */ 150, 98, 165, 165, 211, 174, 175, 150, 55, 165,
106121 /* 1400 */ 57, 150, 174, 175, 61, 165, 150, 64, 174, 175,
106122 /* 1410 */ 150, 150, 165, 150, 174, 175, 165, 104, 150, 184,
106123 /* 1420 */ 150, 165, 129, 130, 131, 165, 165, 150, 165, 150,
106124 /* 1430 */ 150, 176, 150, 165, 47, 165, 150, 150, 176, 103,
106125 /* 1440 */ 150, 22, 165, 178, 165, 165, 179, 165, 105, 106,
106126 /* 1450 */ 107, 165, 165, 229, 111, 165, 92, 176, 229, 116,
106127 /* 1460 */ 184, 176, 179, 156, 176, 176, 18, 157, 156, 237,
106128 /* 1470 */ 45, 157, 156, 135, 157, 157, 238, 156, 68, 157,
106129 /* 1480 */ 189, 189, 139, 219, 22, 157, 18, 192, 192, 192,
106130 /* 1490 */ 192, 189, 219, 199, 157, 242, 40, 157, 199, 242,
106131 /* 1500 */ 153, 157, 38, 245, 196, 166, 232, 198, 177, 177,
106132 /* 1510 */ 232, 227, 209, 178, 166, 182, 166, 148, 177, 177,
106133 /* 1520 */ 209, 196, 177, 199, 209, 199, 166, 208, 92, 195,
106134 /* 1530 */ 174, 174, 183, 252, 183, 183, 252, 191, 252, 235,
106135 /* 1540 */ 186, 241, 241, 252, 186, 252, 252, 252, 252, 252,
106136 /* 1550 */ 252, 252, 252, 252, 252, 252, 236,
106138 #define YY_SHIFT_USE_DFLT (-74)
106139 #define YY_SHIFT_COUNT (418)
106140 #define YY_SHIFT_MIN (-73)
106141 #define YY_SHIFT_MAX (1468)
106142 static const short yy_shift_ofst[] = {
106143 /* 0 */ 975, 1114, 1343, 1114, 1213, 1213, 90, 90, 0, -19,
106144 /* 10 */ 1213, 1213, 1213, 1213, 1213, 345, 445, 721, 1091, 1213,
106145 /* 20 */ 1213, 1213, 1213, 1213, 1213, 1213, 1213, 1213, 1213, 1213,
106146 /* 30 */ 1213, 1213, 1213, 1213, 1213, 1213, 1213, 1213, 1213, 1213,
106147 /* 40 */ 1213, 1213, 1213, 1213, 1213, 1213, 1213, 1236, 1213, 1213,
106148 /* 50 */ 1213, 1213, 1213, 1213, 1213, 1213, 1213, 1213, 1213, 1213,
106149 /* 60 */ 1213, 199, 445, 445, 835, 835, 365, 1164, 55, 647,
106150 /* 70 */ 573, 499, 425, 351, 277, 203, 129, 795, 795, 795,
106151 /* 80 */ 795, 795, 795, 795, 795, 795, 795, 795, 795, 795,
106152 /* 90 */ 795, 795, 795, 795, 795, 869, 795, 943, 1017, 1017,
106153 /* 100 */ -69, -45, -45, -45, -45, -45, -1, 58, 138, 100,
106154 /* 110 */ 445, 445, 445, 445, 445, 445, 445, 445, 445, 445,
106155 /* 120 */ 445, 445, 445, 445, 445, 445, 537, 438, 445, 445,
106156 /* 130 */ 445, 445, 445, 365, 807, 1436, -74, -74, -74, 1293,
106157 /* 140 */ 73, 434, 434, 311, 314, 290, 283, 286, 540, 467,
106158 /* 150 */ 445, 445, 445, 445, 445, 445, 445, 445, 445, 445,
106159 /* 160 */ 445, 445, 445, 445, 445, 445, 445, 445, 445, 445,
106160 /* 170 */ 445, 445, 445, 445, 445, 445, 445, 445, 445, 445,
106161 /* 180 */ 445, 445, 65, 722, 722, 722, 688, 266, 1164, 1164,
106162 /* 190 */ 1164, -74, -74, -74, 136, 168, 168, 234, 360, 360,
106163 /* 200 */ 360, 430, 372, 435, 352, 278, 126, -36, -36, -36,
106164 /* 210 */ -36, 421, 651, -36, -36, 592, 292, 212, 623, 158,
106165 /* 220 */ 204, 204, 505, 158, 505, 144, 365, 154, 365, 154,
106166 /* 230 */ 645, 154, 204, 154, 154, 535, 548, 548, 365, 387,
106167 /* 240 */ 508, 233, 1464, 1222, 1222, 1456, 1456, 1222, 1462, 1410,
106168 /* 250 */ 1165, 1468, 1468, 1468, 1468, 1222, 1165, 1462, 1410, 1410,
106169 /* 260 */ 1222, 1448, 1338, 1425, 1222, 1222, 1448, 1222, 1448, 1222,
106170 /* 270 */ 1448, 1419, 1313, 1313, 1313, 1387, 1364, 1364, 1419, 1313,
106171 /* 280 */ 1336, 1313, 1387, 1313, 1313, 1254, 1245, 1254, 1245, 1254,
106172 /* 290 */ 1245, 1222, 1222, 1186, 1189, 1175, 1169, 1171, 1165, 1164,
106173 /* 300 */ 1243, 1244, 1244, 1212, 1212, 1212, 1212, -74, -74, -74,
106174 /* 310 */ -74, -74, -74, 939, 104, 680, 571, 327, 1, 980,
106175 /* 320 */ 26, 972, 971, 946, 901, 870, 830, 806, 54, 21,
106176 /* 330 */ -73, 510, 242, 1198, 1190, 1170, 1042, 1161, 1108, 1146,
106177 /* 340 */ 1141, 1132, 1015, 1127, 1026, 1034, 1020, 1107, 1004, 1116,
106178 /* 350 */ 1121, 1005, 1099, 951, 1043, 1003, 969, 1045, 1035, 950,
106179 /* 360 */ 1053, 1047, 1025, 942, 913, 992, 1019, 945, 984, 940,
106180 /* 370 */ 876, 904, 953, 896, 748, 804, 880, 786, 868, 819,
106181 /* 380 */ 805, 810, 773, 751, 766, 706, 716, 691, 681, 568,
106182 /* 390 */ 655, 638, 676, 516, 541, 594, 599, 567, 541, 534,
106183 /* 400 */ 507, 527, 498, 523, 466, 382, 409, 384, 357, 6,
106184 /* 410 */ 240, 224, 143, 62, 18, 71, 39, 9, 5,
106186 #define YY_REDUCE_USE_DFLT (-142)
106187 #define YY_REDUCE_COUNT (312)
106188 #define YY_REDUCE_MIN (-141)
106189 #define YY_REDUCE_MAX (1369)
106190 static const short yy_reduce_ofst[] = {
106191 /* 0 */ -141, 994, 1118, 223, 157, -53, 93, 89, 83, 375,
106192 /* 10 */ 386, 381, 379, 308, 295, 325, -47, 27, 1240, 1234,
106193 /* 20 */ 1228, 1221, 1208, 1187, 1151, 1111, 1109, 1077, 1054, 1022,
106194 /* 30 */ 1016, 1000, 911, 908, 906, 890, 888, 874, 834, 816,
106195 /* 40 */ 800, 760, 758, 755, 742, 739, 726, 685, 672, 668,
106196 /* 50 */ 665, 652, 611, 609, 607, 604, 591, 578, 526, 519,
106197 /* 60 */ 453, 474, 454, 461, 443, 245, 442, 473, 484, 484,
106198 /* 70 */ 484, 484, 484, 484, 484, 484, 484, 484, 484, 484,
106199 /* 80 */ 484, 484, 484, 484, 484, 484, 484, 484, 484, 484,
106200 /* 90 */ 484, 484, 484, 484, 484, 484, 484, 484, 484, 484,
106201 /* 100 */ 484, 484, 484, 484, 484, 484, 484, 130, 484, 484,
106202 /* 110 */ 1145, 909, 1110, 1088, 1084, 1033, 1002, 965, 820, 837,
106203 /* 120 */ 746, 686, 612, 817, 610, 919, 221, 563, 814, 813,
106204 /* 130 */ 744, 669, 470, 543, 484, 484, 484, 484, 484, 291,
106205 /* 140 */ 569, 671, 658, 970, 1290, 1287, 1286, 1282, 518, 518,
106206 /* 150 */ 1280, 1279, 1277, 1270, 1268, 1263, 1261, 1260, 1256, 1251,
106207 /* 160 */ 1247, 1227, 1185, 1168, 1167, 1159, 1148, 1139, 1117, 1066,
106208 /* 170 */ 1049, 1006, 998, 996, 995, 973, 970, 966, 964, 892,
106209 /* 180 */ 762, -52, 881, 932, 802, 731, 619, 812, 664, 660,
106210 /* 190 */ 627, 392, 331, 124, 1358, 1357, 1356, 1354, 1352, 1351,
106211 /* 200 */ 1349, 1319, 1334, 1346, 1334, 1334, 1334, 1334, 1334, 1334,
106212 /* 210 */ 1334, 1320, 1304, 1334, 1334, 1319, 1360, 1325, 1369, 1326,
106213 /* 220 */ 1315, 1311, 1301, 1324, 1300, 1335, 1350, 1345, 1348, 1342,
106214 /* 230 */ 1333, 1341, 1303, 1332, 1331, 1284, 1278, 1274, 1339, 1309,
106215 /* 240 */ 1308, 1347, 1258, 1344, 1340, 1257, 1253, 1337, 1273, 1302,
106216 /* 250 */ 1299, 1298, 1297, 1296, 1295, 1328, 1294, 1264, 1292, 1291,
106217 /* 260 */ 1322, 1321, 1238, 1232, 1318, 1317, 1316, 1314, 1312, 1310,
106218 /* 270 */ 1307, 1283, 1289, 1288, 1285, 1276, 1229, 1224, 1267, 1281,
106219 /* 280 */ 1265, 1262, 1235, 1255, 1205, 1183, 1179, 1177, 1162, 1140,
106220 /* 290 */ 1153, 1184, 1182, 1102, 1124, 1103, 1095, 1090, 1089, 1093,
106221 /* 300 */ 1112, 1115, 1086, 1105, 1092, 1087, 1068, 962, 955, 957,
106222 /* 310 */ 1031, 1023, 1030,
106224 static const YYACTIONTYPE yy_default[] = {
106225 /* 0 */ 635, 870, 959, 959, 959, 870, 899, 899, 959, 759,
106226 /* 10 */ 959, 959, 959, 959, 868, 959, 959, 933, 959, 959,
106227 /* 20 */ 959, 959, 959, 959, 959, 959, 959, 959, 959, 959,
106228 /* 30 */ 959, 959, 959, 959, 959, 959, 959, 959, 959, 959,
106229 /* 40 */ 959, 959, 959, 959, 959, 959, 959, 959, 959, 959,
106230 /* 50 */ 959, 959, 959, 959, 959, 959, 959, 959, 959, 959,
106231 /* 60 */ 959, 959, 959, 959, 899, 899, 674, 763, 794, 959,
106232 /* 70 */ 959, 959, 959, 959, 959, 959, 959, 932, 934, 809,
106233 /* 80 */ 808, 802, 801, 912, 774, 799, 792, 785, 796, 871,
106234 /* 90 */ 864, 865, 863, 867, 872, 959, 795, 831, 848, 830,
106235 /* 100 */ 842, 847, 854, 846, 843, 833, 832, 666, 834, 835,
106236 /* 110 */ 959, 959, 959, 959, 959, 959, 959, 959, 959, 959,
106237 /* 120 */ 959, 959, 959, 959, 959, 959, 661, 728, 959, 959,
106238 /* 130 */ 959, 959, 959, 959, 836, 837, 851, 850, 849, 959,
106239 /* 140 */ 959, 959, 959, 959, 959, 959, 959, 959, 959, 959,
106240 /* 150 */ 959, 939, 937, 959, 883, 959, 959, 959, 959, 959,
106241 /* 160 */ 959, 959, 959, 959, 959, 959, 959, 959, 959, 959,
106242 /* 170 */ 959, 959, 959, 959, 959, 959, 959, 959, 959, 959,
106243 /* 180 */ 959, 641, 959, 759, 759, 759, 635, 959, 959, 959,
106244 /* 190 */ 959, 951, 763, 753, 719, 959, 959, 959, 959, 959,
106245 /* 200 */ 959, 959, 959, 959, 959, 959, 959, 804, 742, 922,
106246 /* 210 */ 924, 959, 905, 740, 663, 761, 676, 751, 643, 798,
106247 /* 220 */ 776, 776, 917, 798, 917, 700, 959, 788, 959, 788,
106248 /* 230 */ 697, 788, 776, 788, 788, 866, 959, 959, 959, 760,
106249 /* 240 */ 751, 959, 944, 767, 767, 936, 936, 767, 810, 732,
106250 /* 250 */ 798, 739, 739, 739, 739, 767, 798, 810, 732, 732,
106251 /* 260 */ 767, 658, 911, 909, 767, 767, 658, 767, 658, 767,
106252 /* 270 */ 658, 876, 730, 730, 730, 715, 880, 880, 876, 730,
106253 /* 280 */ 700, 730, 715, 730, 730, 780, 775, 780, 775, 780,
106254 /* 290 */ 775, 767, 767, 959, 793, 781, 791, 789, 798, 959,
106255 /* 300 */ 718, 651, 651, 640, 640, 640, 640, 956, 956, 951,
106256 /* 310 */ 702, 702, 684, 959, 959, 959, 959, 959, 959, 959,
106257 /* 320 */ 885, 959, 959, 959, 959, 959, 959, 959, 959, 959,
106258 /* 330 */ 959, 959, 959, 959, 636, 946, 959, 959, 943, 959,
106259 /* 340 */ 959, 959, 959, 959, 959, 959, 959, 959, 959, 959,
106260 /* 350 */ 959, 959, 959, 959, 959, 959, 959, 959, 959, 915,
106261 /* 360 */ 959, 959, 959, 959, 959, 959, 908, 907, 959, 959,
106262 /* 370 */ 959, 959, 959, 959, 959, 959, 959, 959, 959, 959,
106263 /* 380 */ 959, 959, 959, 959, 959, 959, 959, 959, 959, 959,
106264 /* 390 */ 959, 959, 959, 959, 790, 959, 782, 959, 869, 959,
106265 /* 400 */ 959, 959, 959, 959, 959, 959, 959, 959, 959, 745,
106266 /* 410 */ 819, 959, 818, 822, 817, 668, 959, 649, 959, 632,
106267 /* 420 */ 637, 955, 958, 957, 954, 953, 952, 947, 945, 942,
106268 /* 430 */ 941, 940, 938, 935, 931, 889, 887, 894, 893, 892,
106269 /* 440 */ 891, 890, 888, 886, 884, 805, 803, 800, 797, 930,
106270 /* 450 */ 882, 741, 738, 737, 657, 948, 914, 923, 921, 811,
106271 /* 460 */ 920, 919, 918, 916, 913, 900, 807, 806, 733, 874,
106272 /* 470 */ 873, 660, 904, 903, 902, 906, 910, 901, 769, 659,
106273 /* 480 */ 656, 665, 722, 721, 729, 727, 726, 725, 724, 723,
106274 /* 490 */ 720, 667, 675, 686, 714, 699, 698, 879, 881, 878,
106275 /* 500 */ 877, 707, 706, 712, 711, 710, 709, 708, 705, 704,
106276 /* 510 */ 703, 696, 695, 701, 694, 717, 716, 713, 693, 736,
106277 /* 520 */ 735, 734, 731, 692, 691, 690, 822, 689, 688, 828,
106278 /* 530 */ 827, 815, 858, 756, 755, 754, 766, 765, 778, 777,
106279 /* 540 */ 813, 812, 779, 764, 758, 757, 773, 772, 771, 770,
106280 /* 550 */ 762, 752, 784, 787, 786, 783, 860, 768, 857, 929,
106281 /* 560 */ 928, 927, 926, 925, 862, 861, 829, 826, 679, 680,
106282 /* 570 */ 898, 896, 897, 895, 682, 681, 678, 677, 859, 747,
106283 /* 580 */ 746, 855, 852, 844, 840, 856, 853, 845, 841, 839,
106284 /* 590 */ 838, 824, 823, 821, 820, 816, 825, 670, 748, 744,
106285 /* 600 */ 743, 814, 750, 749, 687, 685, 683, 664, 662, 655,
106286 /* 610 */ 653, 652, 654, 650, 648, 647, 646, 645, 644, 673,
106287 /* 620 */ 672, 671, 669, 668, 642, 639, 638, 634, 633, 631,
106290 /* The next table maps tokens into fallback tokens. If a construct
106291 ** like the following:
106293 ** %fallback ID X Y Z.
106295 ** appears in the grammar, then ID becomes a fallback token for X, Y,
106296 ** and Z. Whenever one of the tokens X, Y, or Z is input to the parser
106297 ** but it does not parse, the type of the token is changed to ID and
106298 ** the parse is retried before an error is thrown.
106300 #ifdef YYFALLBACK
106301 static const YYCODETYPE yyFallback[] = {
106302 0, /* $ => nothing */
106303 0, /* SEMI => nothing */
106304 26, /* EXPLAIN => ID */
106305 26, /* QUERY => ID */
106306 26, /* PLAN => ID */
106307 26, /* BEGIN => ID */
106308 0, /* TRANSACTION => nothing */
106309 26, /* DEFERRED => ID */
106310 26, /* IMMEDIATE => ID */
106311 26, /* EXCLUSIVE => ID */
106312 0, /* COMMIT => nothing */
106313 26, /* END => ID */
106314 26, /* ROLLBACK => ID */
106315 26, /* SAVEPOINT => ID */
106316 26, /* RELEASE => ID */
106317 0, /* TO => nothing */
106318 0, /* TABLE => nothing */
106319 0, /* CREATE => nothing */
106320 26, /* IF => ID */
106321 0, /* NOT => nothing */
106322 0, /* EXISTS => nothing */
106323 26, /* TEMP => ID */
106324 0, /* LP => nothing */
106325 0, /* RP => nothing */
106326 0, /* AS => nothing */
106327 0, /* COMMA => nothing */
106328 0, /* ID => nothing */
106329 0, /* INDEXED => nothing */
106330 26, /* ABORT => ID */
106331 26, /* ACTION => ID */
106332 26, /* AFTER => ID */
106333 26, /* ANALYZE => ID */
106334 26, /* ASC => ID */
106335 26, /* ATTACH => ID */
106336 26, /* BEFORE => ID */
106337 26, /* BY => ID */
106338 26, /* CASCADE => ID */
106339 26, /* CAST => ID */
106340 26, /* COLUMNKW => ID */
106341 26, /* CONFLICT => ID */
106342 26, /* DATABASE => ID */
106343 26, /* DESC => ID */
106344 26, /* DETACH => ID */
106345 26, /* EACH => ID */
106346 26, /* FAIL => ID */
106347 26, /* FOR => ID */
106348 26, /* IGNORE => ID */
106349 26, /* INITIALLY => ID */
106350 26, /* INSTEAD => ID */
106351 26, /* LIKE_KW => ID */
106352 26, /* MATCH => ID */
106353 26, /* NO => ID */
106354 26, /* KEY => ID */
106355 26, /* OF => ID */
106356 26, /* OFFSET => ID */
106357 26, /* PRAGMA => ID */
106358 26, /* RAISE => ID */
106359 26, /* REPLACE => ID */
106360 26, /* RESTRICT => ID */
106361 26, /* ROW => ID */
106362 26, /* TRIGGER => ID */
106363 26, /* VACUUM => ID */
106364 26, /* VIEW => ID */
106365 26, /* VIRTUAL => ID */
106366 26, /* REINDEX => ID */
106367 26, /* RENAME => ID */
106368 26, /* CTIME_KW => ID */
106370 #endif /* YYFALLBACK */
106372 /* The following structure represents a single element of the
106373 ** parser's stack. Information stored includes:
106375 ** + The state number for the parser at this level of the stack.
106377 ** + The value of the token stored at this level of the stack.
106378 ** (In other words, the "major" token.)
106380 ** + The semantic value stored at this level of the stack. This is
106381 ** the information used by the action routines in the grammar.
106382 ** It is sometimes called the "minor" token.
106384 struct yyStackEntry {
106385 YYACTIONTYPE stateno; /* The state-number */
106386 YYCODETYPE major; /* The major token value. This is the code
106387 ** number for the token at this stack level */
106388 YYMINORTYPE minor; /* The user-supplied minor token value. This
106389 ** is the value of the token */
106391 typedef struct yyStackEntry yyStackEntry;
106393 /* The state of the parser is completely contained in an instance of
106394 ** the following structure */
106395 struct yyParser {
106396 int yyidx; /* Index of top element in stack */
106397 #ifdef YYTRACKMAXSTACKDEPTH
106398 int yyidxMax; /* Maximum value of yyidx */
106399 #endif
106400 int yyerrcnt; /* Shifts left before out of the error */
106401 sqlite3ParserARG_SDECL /* A place to hold %extra_argument */
106402 #if YYSTACKDEPTH<=0
106403 int yystksz; /* Current side of the stack */
106404 yyStackEntry *yystack; /* The parser's stack */
106405 #else
106406 yyStackEntry yystack[YYSTACKDEPTH]; /* The parser's stack */
106407 #endif
106409 typedef struct yyParser yyParser;
106411 #ifndef NDEBUG
106412 /* #include <stdio.h> */
106413 static FILE *yyTraceFILE = 0;
106414 static char *yyTracePrompt = 0;
106415 #endif /* NDEBUG */
106417 #ifndef NDEBUG
106419 ** Turn parser tracing on by giving a stream to which to write the trace
106420 ** and a prompt to preface each trace message. Tracing is turned off
106421 ** by making either argument NULL
106423 ** Inputs:
106424 ** <ul>
106425 ** <li> A FILE* to which trace output should be written.
106426 ** If NULL, then tracing is turned off.
106427 ** <li> A prefix string written at the beginning of every
106428 ** line of trace output. If NULL, then tracing is
106429 ** turned off.
106430 ** </ul>
106432 ** Outputs:
106433 ** None.
106435 SQLITE_PRIVATE void sqlite3ParserTrace(FILE *TraceFILE, char *zTracePrompt){
106436 yyTraceFILE = TraceFILE;
106437 yyTracePrompt = zTracePrompt;
106438 if( yyTraceFILE==0 ) yyTracePrompt = 0;
106439 else if( yyTracePrompt==0 ) yyTraceFILE = 0;
106441 #endif /* NDEBUG */
106443 #ifndef NDEBUG
106444 /* For tracing shifts, the names of all terminals and nonterminals
106445 ** are required. The following table supplies these names */
106446 static const char *const yyTokenName[] = {
106447 "$", "SEMI", "EXPLAIN", "QUERY",
106448 "PLAN", "BEGIN", "TRANSACTION", "DEFERRED",
106449 "IMMEDIATE", "EXCLUSIVE", "COMMIT", "END",
106450 "ROLLBACK", "SAVEPOINT", "RELEASE", "TO",
106451 "TABLE", "CREATE", "IF", "NOT",
106452 "EXISTS", "TEMP", "LP", "RP",
106453 "AS", "COMMA", "ID", "INDEXED",
106454 "ABORT", "ACTION", "AFTER", "ANALYZE",
106455 "ASC", "ATTACH", "BEFORE", "BY",
106456 "CASCADE", "CAST", "COLUMNKW", "CONFLICT",
106457 "DATABASE", "DESC", "DETACH", "EACH",
106458 "FAIL", "FOR", "IGNORE", "INITIALLY",
106459 "INSTEAD", "LIKE_KW", "MATCH", "NO",
106460 "KEY", "OF", "OFFSET", "PRAGMA",
106461 "RAISE", "REPLACE", "RESTRICT", "ROW",
106462 "TRIGGER", "VACUUM", "VIEW", "VIRTUAL",
106463 "REINDEX", "RENAME", "CTIME_KW", "ANY",
106464 "OR", "AND", "IS", "BETWEEN",
106465 "IN", "ISNULL", "NOTNULL", "NE",
106466 "EQ", "GT", "LE", "LT",
106467 "GE", "ESCAPE", "BITAND", "BITOR",
106468 "LSHIFT", "RSHIFT", "PLUS", "MINUS",
106469 "STAR", "SLASH", "REM", "CONCAT",
106470 "COLLATE", "BITNOT", "STRING", "JOIN_KW",
106471 "CONSTRAINT", "DEFAULT", "NULL", "PRIMARY",
106472 "UNIQUE", "CHECK", "REFERENCES", "AUTOINCR",
106473 "ON", "INSERT", "DELETE", "UPDATE",
106474 "SET", "DEFERRABLE", "FOREIGN", "DROP",
106475 "UNION", "ALL", "EXCEPT", "INTERSECT",
106476 "SELECT", "DISTINCT", "DOT", "FROM",
106477 "JOIN", "USING", "ORDER", "GROUP",
106478 "HAVING", "LIMIT", "WHERE", "INTO",
106479 "VALUES", "INTEGER", "FLOAT", "BLOB",
106480 "REGISTER", "VARIABLE", "CASE", "WHEN",
106481 "THEN", "ELSE", "INDEX", "ALTER",
106482 "ADD", "error", "input", "cmdlist",
106483 "ecmd", "explain", "cmdx", "cmd",
106484 "transtype", "trans_opt", "nm", "savepoint_opt",
106485 "create_table", "create_table_args", "createkw", "temp",
106486 "ifnotexists", "dbnm", "columnlist", "conslist_opt",
106487 "select", "column", "columnid", "type",
106488 "carglist", "id", "ids", "typetoken",
106489 "typename", "signed", "plus_num", "minus_num",
106490 "carg", "ccons", "term", "expr",
106491 "onconf", "sortorder", "autoinc", "idxlist_opt",
106492 "refargs", "defer_subclause", "refarg", "refact",
106493 "init_deferred_pred_opt", "conslist", "tcons", "idxlist",
106494 "defer_subclause_opt", "orconf", "resolvetype", "raisetype",
106495 "ifexists", "fullname", "oneselect", "multiselect_op",
106496 "distinct", "selcollist", "from", "where_opt",
106497 "groupby_opt", "having_opt", "orderby_opt", "limit_opt",
106498 "sclp", "as", "seltablist", "stl_prefix",
106499 "joinop", "indexed_opt", "on_opt", "using_opt",
106500 "joinop2", "inscollist", "sortlist", "sortitem",
106501 "nexprlist", "setlist", "insert_cmd", "inscollist_opt",
106502 "itemlist", "exprlist", "likeop", "between_op",
106503 "in_op", "case_operand", "case_exprlist", "case_else",
106504 "uniqueflag", "collate", "nmnum", "plus_opt",
106505 "number", "trigger_decl", "trigger_cmd_list", "trigger_time",
106506 "trigger_event", "foreach_clause", "when_clause", "trigger_cmd",
106507 "trnm", "tridxby", "database_kw_opt", "key_opt",
106508 "add_column_fullname", "kwcolumn_opt", "create_vtab", "vtabarglist",
106509 "vtabarg", "vtabargtoken", "lp", "anylist",
106511 #endif /* NDEBUG */
106513 #ifndef NDEBUG
106514 /* For tracing reduce actions, the names of all rules are required.
106516 static const char *const yyRuleName[] = {
106517 /* 0 */ "input ::= cmdlist",
106518 /* 1 */ "cmdlist ::= cmdlist ecmd",
106519 /* 2 */ "cmdlist ::= ecmd",
106520 /* 3 */ "ecmd ::= SEMI",
106521 /* 4 */ "ecmd ::= explain cmdx SEMI",
106522 /* 5 */ "explain ::=",
106523 /* 6 */ "explain ::= EXPLAIN",
106524 /* 7 */ "explain ::= EXPLAIN QUERY PLAN",
106525 /* 8 */ "cmdx ::= cmd",
106526 /* 9 */ "cmd ::= BEGIN transtype trans_opt",
106527 /* 10 */ "trans_opt ::=",
106528 /* 11 */ "trans_opt ::= TRANSACTION",
106529 /* 12 */ "trans_opt ::= TRANSACTION nm",
106530 /* 13 */ "transtype ::=",
106531 /* 14 */ "transtype ::= DEFERRED",
106532 /* 15 */ "transtype ::= IMMEDIATE",
106533 /* 16 */ "transtype ::= EXCLUSIVE",
106534 /* 17 */ "cmd ::= COMMIT trans_opt",
106535 /* 18 */ "cmd ::= END trans_opt",
106536 /* 19 */ "cmd ::= ROLLBACK trans_opt",
106537 /* 20 */ "savepoint_opt ::= SAVEPOINT",
106538 /* 21 */ "savepoint_opt ::=",
106539 /* 22 */ "cmd ::= SAVEPOINT nm",
106540 /* 23 */ "cmd ::= RELEASE savepoint_opt nm",
106541 /* 24 */ "cmd ::= ROLLBACK trans_opt TO savepoint_opt nm",
106542 /* 25 */ "cmd ::= create_table create_table_args",
106543 /* 26 */ "create_table ::= createkw temp TABLE ifnotexists nm dbnm",
106544 /* 27 */ "createkw ::= CREATE",
106545 /* 28 */ "ifnotexists ::=",
106546 /* 29 */ "ifnotexists ::= IF NOT EXISTS",
106547 /* 30 */ "temp ::= TEMP",
106548 /* 31 */ "temp ::=",
106549 /* 32 */ "create_table_args ::= LP columnlist conslist_opt RP",
106550 /* 33 */ "create_table_args ::= AS select",
106551 /* 34 */ "columnlist ::= columnlist COMMA column",
106552 /* 35 */ "columnlist ::= column",
106553 /* 36 */ "column ::= columnid type carglist",
106554 /* 37 */ "columnid ::= nm",
106555 /* 38 */ "id ::= ID",
106556 /* 39 */ "id ::= INDEXED",
106557 /* 40 */ "ids ::= ID|STRING",
106558 /* 41 */ "nm ::= id",
106559 /* 42 */ "nm ::= STRING",
106560 /* 43 */ "nm ::= JOIN_KW",
106561 /* 44 */ "type ::=",
106562 /* 45 */ "type ::= typetoken",
106563 /* 46 */ "typetoken ::= typename",
106564 /* 47 */ "typetoken ::= typename LP signed RP",
106565 /* 48 */ "typetoken ::= typename LP signed COMMA signed RP",
106566 /* 49 */ "typename ::= ids",
106567 /* 50 */ "typename ::= typename ids",
106568 /* 51 */ "signed ::= plus_num",
106569 /* 52 */ "signed ::= minus_num",
106570 /* 53 */ "carglist ::= carglist carg",
106571 /* 54 */ "carglist ::=",
106572 /* 55 */ "carg ::= CONSTRAINT nm ccons",
106573 /* 56 */ "carg ::= ccons",
106574 /* 57 */ "ccons ::= DEFAULT term",
106575 /* 58 */ "ccons ::= DEFAULT LP expr RP",
106576 /* 59 */ "ccons ::= DEFAULT PLUS term",
106577 /* 60 */ "ccons ::= DEFAULT MINUS term",
106578 /* 61 */ "ccons ::= DEFAULT id",
106579 /* 62 */ "ccons ::= NULL onconf",
106580 /* 63 */ "ccons ::= NOT NULL onconf",
106581 /* 64 */ "ccons ::= PRIMARY KEY sortorder onconf autoinc",
106582 /* 65 */ "ccons ::= UNIQUE onconf",
106583 /* 66 */ "ccons ::= CHECK LP expr RP",
106584 /* 67 */ "ccons ::= REFERENCES nm idxlist_opt refargs",
106585 /* 68 */ "ccons ::= defer_subclause",
106586 /* 69 */ "ccons ::= COLLATE ids",
106587 /* 70 */ "autoinc ::=",
106588 /* 71 */ "autoinc ::= AUTOINCR",
106589 /* 72 */ "refargs ::=",
106590 /* 73 */ "refargs ::= refargs refarg",
106591 /* 74 */ "refarg ::= MATCH nm",
106592 /* 75 */ "refarg ::= ON INSERT refact",
106593 /* 76 */ "refarg ::= ON DELETE refact",
106594 /* 77 */ "refarg ::= ON UPDATE refact",
106595 /* 78 */ "refact ::= SET NULL",
106596 /* 79 */ "refact ::= SET DEFAULT",
106597 /* 80 */ "refact ::= CASCADE",
106598 /* 81 */ "refact ::= RESTRICT",
106599 /* 82 */ "refact ::= NO ACTION",
106600 /* 83 */ "defer_subclause ::= NOT DEFERRABLE init_deferred_pred_opt",
106601 /* 84 */ "defer_subclause ::= DEFERRABLE init_deferred_pred_opt",
106602 /* 85 */ "init_deferred_pred_opt ::=",
106603 /* 86 */ "init_deferred_pred_opt ::= INITIALLY DEFERRED",
106604 /* 87 */ "init_deferred_pred_opt ::= INITIALLY IMMEDIATE",
106605 /* 88 */ "conslist_opt ::=",
106606 /* 89 */ "conslist_opt ::= COMMA conslist",
106607 /* 90 */ "conslist ::= conslist COMMA tcons",
106608 /* 91 */ "conslist ::= conslist tcons",
106609 /* 92 */ "conslist ::= tcons",
106610 /* 93 */ "tcons ::= CONSTRAINT nm",
106611 /* 94 */ "tcons ::= PRIMARY KEY LP idxlist autoinc RP onconf",
106612 /* 95 */ "tcons ::= UNIQUE LP idxlist RP onconf",
106613 /* 96 */ "tcons ::= CHECK LP expr RP onconf",
106614 /* 97 */ "tcons ::= FOREIGN KEY LP idxlist RP REFERENCES nm idxlist_opt refargs defer_subclause_opt",
106615 /* 98 */ "defer_subclause_opt ::=",
106616 /* 99 */ "defer_subclause_opt ::= defer_subclause",
106617 /* 100 */ "onconf ::=",
106618 /* 101 */ "onconf ::= ON CONFLICT resolvetype",
106619 /* 102 */ "orconf ::=",
106620 /* 103 */ "orconf ::= OR resolvetype",
106621 /* 104 */ "resolvetype ::= raisetype",
106622 /* 105 */ "resolvetype ::= IGNORE",
106623 /* 106 */ "resolvetype ::= REPLACE",
106624 /* 107 */ "cmd ::= DROP TABLE ifexists fullname",
106625 /* 108 */ "ifexists ::= IF EXISTS",
106626 /* 109 */ "ifexists ::=",
106627 /* 110 */ "cmd ::= createkw temp VIEW ifnotexists nm dbnm AS select",
106628 /* 111 */ "cmd ::= DROP VIEW ifexists fullname",
106629 /* 112 */ "cmd ::= select",
106630 /* 113 */ "select ::= oneselect",
106631 /* 114 */ "select ::= select multiselect_op oneselect",
106632 /* 115 */ "multiselect_op ::= UNION",
106633 /* 116 */ "multiselect_op ::= UNION ALL",
106634 /* 117 */ "multiselect_op ::= EXCEPT|INTERSECT",
106635 /* 118 */ "oneselect ::= SELECT distinct selcollist from where_opt groupby_opt having_opt orderby_opt limit_opt",
106636 /* 119 */ "distinct ::= DISTINCT",
106637 /* 120 */ "distinct ::= ALL",
106638 /* 121 */ "distinct ::=",
106639 /* 122 */ "sclp ::= selcollist COMMA",
106640 /* 123 */ "sclp ::=",
106641 /* 124 */ "selcollist ::= sclp expr as",
106642 /* 125 */ "selcollist ::= sclp STAR",
106643 /* 126 */ "selcollist ::= sclp nm DOT STAR",
106644 /* 127 */ "as ::= AS nm",
106645 /* 128 */ "as ::= ids",
106646 /* 129 */ "as ::=",
106647 /* 130 */ "from ::=",
106648 /* 131 */ "from ::= FROM seltablist",
106649 /* 132 */ "stl_prefix ::= seltablist joinop",
106650 /* 133 */ "stl_prefix ::=",
106651 /* 134 */ "seltablist ::= stl_prefix nm dbnm as indexed_opt on_opt using_opt",
106652 /* 135 */ "seltablist ::= stl_prefix LP select RP as on_opt using_opt",
106653 /* 136 */ "seltablist ::= stl_prefix LP seltablist RP as on_opt using_opt",
106654 /* 137 */ "dbnm ::=",
106655 /* 138 */ "dbnm ::= DOT nm",
106656 /* 139 */ "fullname ::= nm dbnm",
106657 /* 140 */ "joinop ::= COMMA|JOIN",
106658 /* 141 */ "joinop ::= JOIN_KW JOIN",
106659 /* 142 */ "joinop ::= JOIN_KW nm JOIN",
106660 /* 143 */ "joinop ::= JOIN_KW nm nm JOIN",
106661 /* 144 */ "on_opt ::= ON expr",
106662 /* 145 */ "on_opt ::=",
106663 /* 146 */ "indexed_opt ::=",
106664 /* 147 */ "indexed_opt ::= INDEXED BY nm",
106665 /* 148 */ "indexed_opt ::= NOT INDEXED",
106666 /* 149 */ "using_opt ::= USING LP inscollist RP",
106667 /* 150 */ "using_opt ::=",
106668 /* 151 */ "orderby_opt ::=",
106669 /* 152 */ "orderby_opt ::= ORDER BY sortlist",
106670 /* 153 */ "sortlist ::= sortlist COMMA sortitem sortorder",
106671 /* 154 */ "sortlist ::= sortitem sortorder",
106672 /* 155 */ "sortitem ::= expr",
106673 /* 156 */ "sortorder ::= ASC",
106674 /* 157 */ "sortorder ::= DESC",
106675 /* 158 */ "sortorder ::=",
106676 /* 159 */ "groupby_opt ::=",
106677 /* 160 */ "groupby_opt ::= GROUP BY nexprlist",
106678 /* 161 */ "having_opt ::=",
106679 /* 162 */ "having_opt ::= HAVING expr",
106680 /* 163 */ "limit_opt ::=",
106681 /* 164 */ "limit_opt ::= LIMIT expr",
106682 /* 165 */ "limit_opt ::= LIMIT expr OFFSET expr",
106683 /* 166 */ "limit_opt ::= LIMIT expr COMMA expr",
106684 /* 167 */ "cmd ::= DELETE FROM fullname indexed_opt where_opt",
106685 /* 168 */ "where_opt ::=",
106686 /* 169 */ "where_opt ::= WHERE expr",
106687 /* 170 */ "cmd ::= UPDATE orconf fullname indexed_opt SET setlist where_opt",
106688 /* 171 */ "setlist ::= setlist COMMA nm EQ expr",
106689 /* 172 */ "setlist ::= nm EQ expr",
106690 /* 173 */ "cmd ::= insert_cmd INTO fullname inscollist_opt VALUES LP itemlist RP",
106691 /* 174 */ "cmd ::= insert_cmd INTO fullname inscollist_opt select",
106692 /* 175 */ "cmd ::= insert_cmd INTO fullname inscollist_opt DEFAULT VALUES",
106693 /* 176 */ "insert_cmd ::= INSERT orconf",
106694 /* 177 */ "insert_cmd ::= REPLACE",
106695 /* 178 */ "itemlist ::= itemlist COMMA expr",
106696 /* 179 */ "itemlist ::= expr",
106697 /* 180 */ "inscollist_opt ::=",
106698 /* 181 */ "inscollist_opt ::= LP inscollist RP",
106699 /* 182 */ "inscollist ::= inscollist COMMA nm",
106700 /* 183 */ "inscollist ::= nm",
106701 /* 184 */ "expr ::= term",
106702 /* 185 */ "expr ::= LP expr RP",
106703 /* 186 */ "term ::= NULL",
106704 /* 187 */ "expr ::= id",
106705 /* 188 */ "expr ::= JOIN_KW",
106706 /* 189 */ "expr ::= nm DOT nm",
106707 /* 190 */ "expr ::= nm DOT nm DOT nm",
106708 /* 191 */ "term ::= INTEGER|FLOAT|BLOB",
106709 /* 192 */ "term ::= STRING",
106710 /* 193 */ "expr ::= REGISTER",
106711 /* 194 */ "expr ::= VARIABLE",
106712 /* 195 */ "expr ::= expr COLLATE ids",
106713 /* 196 */ "expr ::= CAST LP expr AS typetoken RP",
106714 /* 197 */ "expr ::= ID LP distinct exprlist RP",
106715 /* 198 */ "expr ::= ID LP STAR RP",
106716 /* 199 */ "term ::= CTIME_KW",
106717 /* 200 */ "expr ::= expr AND expr",
106718 /* 201 */ "expr ::= expr OR expr",
106719 /* 202 */ "expr ::= expr LT|GT|GE|LE expr",
106720 /* 203 */ "expr ::= expr EQ|NE expr",
106721 /* 204 */ "expr ::= expr BITAND|BITOR|LSHIFT|RSHIFT expr",
106722 /* 205 */ "expr ::= expr PLUS|MINUS expr",
106723 /* 206 */ "expr ::= expr STAR|SLASH|REM expr",
106724 /* 207 */ "expr ::= expr CONCAT expr",
106725 /* 208 */ "likeop ::= LIKE_KW",
106726 /* 209 */ "likeop ::= NOT LIKE_KW",
106727 /* 210 */ "likeop ::= MATCH",
106728 /* 211 */ "likeop ::= NOT MATCH",
106729 /* 212 */ "expr ::= expr likeop expr",
106730 /* 213 */ "expr ::= expr likeop expr ESCAPE expr",
106731 /* 214 */ "expr ::= expr ISNULL|NOTNULL",
106732 /* 215 */ "expr ::= expr NOT NULL",
106733 /* 216 */ "expr ::= expr IS expr",
106734 /* 217 */ "expr ::= expr IS NOT expr",
106735 /* 218 */ "expr ::= NOT expr",
106736 /* 219 */ "expr ::= BITNOT expr",
106737 /* 220 */ "expr ::= MINUS expr",
106738 /* 221 */ "expr ::= PLUS expr",
106739 /* 222 */ "between_op ::= BETWEEN",
106740 /* 223 */ "between_op ::= NOT BETWEEN",
106741 /* 224 */ "expr ::= expr between_op expr AND expr",
106742 /* 225 */ "in_op ::= IN",
106743 /* 226 */ "in_op ::= NOT IN",
106744 /* 227 */ "expr ::= expr in_op LP exprlist RP",
106745 /* 228 */ "expr ::= LP select RP",
106746 /* 229 */ "expr ::= expr in_op LP select RP",
106747 /* 230 */ "expr ::= expr in_op nm dbnm",
106748 /* 231 */ "expr ::= EXISTS LP select RP",
106749 /* 232 */ "expr ::= CASE case_operand case_exprlist case_else END",
106750 /* 233 */ "case_exprlist ::= case_exprlist WHEN expr THEN expr",
106751 /* 234 */ "case_exprlist ::= WHEN expr THEN expr",
106752 /* 235 */ "case_else ::= ELSE expr",
106753 /* 236 */ "case_else ::=",
106754 /* 237 */ "case_operand ::= expr",
106755 /* 238 */ "case_operand ::=",
106756 /* 239 */ "exprlist ::= nexprlist",
106757 /* 240 */ "exprlist ::=",
106758 /* 241 */ "nexprlist ::= nexprlist COMMA expr",
106759 /* 242 */ "nexprlist ::= expr",
106760 /* 243 */ "cmd ::= createkw uniqueflag INDEX ifnotexists nm dbnm ON nm LP idxlist RP",
106761 /* 244 */ "uniqueflag ::= UNIQUE",
106762 /* 245 */ "uniqueflag ::=",
106763 /* 246 */ "idxlist_opt ::=",
106764 /* 247 */ "idxlist_opt ::= LP idxlist RP",
106765 /* 248 */ "idxlist ::= idxlist COMMA nm collate sortorder",
106766 /* 249 */ "idxlist ::= nm collate sortorder",
106767 /* 250 */ "collate ::=",
106768 /* 251 */ "collate ::= COLLATE ids",
106769 /* 252 */ "cmd ::= DROP INDEX ifexists fullname",
106770 /* 253 */ "cmd ::= VACUUM",
106771 /* 254 */ "cmd ::= VACUUM nm",
106772 /* 255 */ "cmd ::= PRAGMA nm dbnm",
106773 /* 256 */ "cmd ::= PRAGMA nm dbnm EQ nmnum",
106774 /* 257 */ "cmd ::= PRAGMA nm dbnm LP nmnum RP",
106775 /* 258 */ "cmd ::= PRAGMA nm dbnm EQ minus_num",
106776 /* 259 */ "cmd ::= PRAGMA nm dbnm LP minus_num RP",
106777 /* 260 */ "nmnum ::= plus_num",
106778 /* 261 */ "nmnum ::= nm",
106779 /* 262 */ "nmnum ::= ON",
106780 /* 263 */ "nmnum ::= DELETE",
106781 /* 264 */ "nmnum ::= DEFAULT",
106782 /* 265 */ "plus_num ::= plus_opt number",
106783 /* 266 */ "minus_num ::= MINUS number",
106784 /* 267 */ "number ::= INTEGER|FLOAT",
106785 /* 268 */ "plus_opt ::= PLUS",
106786 /* 269 */ "plus_opt ::=",
106787 /* 270 */ "cmd ::= createkw trigger_decl BEGIN trigger_cmd_list END",
106788 /* 271 */ "trigger_decl ::= temp TRIGGER ifnotexists nm dbnm trigger_time trigger_event ON fullname foreach_clause when_clause",
106789 /* 272 */ "trigger_time ::= BEFORE",
106790 /* 273 */ "trigger_time ::= AFTER",
106791 /* 274 */ "trigger_time ::= INSTEAD OF",
106792 /* 275 */ "trigger_time ::=",
106793 /* 276 */ "trigger_event ::= DELETE|INSERT",
106794 /* 277 */ "trigger_event ::= UPDATE",
106795 /* 278 */ "trigger_event ::= UPDATE OF inscollist",
106796 /* 279 */ "foreach_clause ::=",
106797 /* 280 */ "foreach_clause ::= FOR EACH ROW",
106798 /* 281 */ "when_clause ::=",
106799 /* 282 */ "when_clause ::= WHEN expr",
106800 /* 283 */ "trigger_cmd_list ::= trigger_cmd_list trigger_cmd SEMI",
106801 /* 284 */ "trigger_cmd_list ::= trigger_cmd SEMI",
106802 /* 285 */ "trnm ::= nm",
106803 /* 286 */ "trnm ::= nm DOT nm",
106804 /* 287 */ "tridxby ::=",
106805 /* 288 */ "tridxby ::= INDEXED BY nm",
106806 /* 289 */ "tridxby ::= NOT INDEXED",
106807 /* 290 */ "trigger_cmd ::= UPDATE orconf trnm tridxby SET setlist where_opt",
106808 /* 291 */ "trigger_cmd ::= insert_cmd INTO trnm inscollist_opt VALUES LP itemlist RP",
106809 /* 292 */ "trigger_cmd ::= insert_cmd INTO trnm inscollist_opt select",
106810 /* 293 */ "trigger_cmd ::= DELETE FROM trnm tridxby where_opt",
106811 /* 294 */ "trigger_cmd ::= select",
106812 /* 295 */ "expr ::= RAISE LP IGNORE RP",
106813 /* 296 */ "expr ::= RAISE LP raisetype COMMA nm RP",
106814 /* 297 */ "raisetype ::= ROLLBACK",
106815 /* 298 */ "raisetype ::= ABORT",
106816 /* 299 */ "raisetype ::= FAIL",
106817 /* 300 */ "cmd ::= DROP TRIGGER ifexists fullname",
106818 /* 301 */ "cmd ::= ATTACH database_kw_opt expr AS expr key_opt",
106819 /* 302 */ "cmd ::= DETACH database_kw_opt expr",
106820 /* 303 */ "key_opt ::=",
106821 /* 304 */ "key_opt ::= KEY expr",
106822 /* 305 */ "database_kw_opt ::= DATABASE",
106823 /* 306 */ "database_kw_opt ::=",
106824 /* 307 */ "cmd ::= REINDEX",
106825 /* 308 */ "cmd ::= REINDEX nm dbnm",
106826 /* 309 */ "cmd ::= ANALYZE",
106827 /* 310 */ "cmd ::= ANALYZE nm dbnm",
106828 /* 311 */ "cmd ::= ALTER TABLE fullname RENAME TO nm",
106829 /* 312 */ "cmd ::= ALTER TABLE add_column_fullname ADD kwcolumn_opt column",
106830 /* 313 */ "add_column_fullname ::= fullname",
106831 /* 314 */ "kwcolumn_opt ::=",
106832 /* 315 */ "kwcolumn_opt ::= COLUMNKW",
106833 /* 316 */ "cmd ::= create_vtab",
106834 /* 317 */ "cmd ::= create_vtab LP vtabarglist RP",
106835 /* 318 */ "create_vtab ::= createkw VIRTUAL TABLE nm dbnm USING nm",
106836 /* 319 */ "vtabarglist ::= vtabarg",
106837 /* 320 */ "vtabarglist ::= vtabarglist COMMA vtabarg",
106838 /* 321 */ "vtabarg ::=",
106839 /* 322 */ "vtabarg ::= vtabarg vtabargtoken",
106840 /* 323 */ "vtabargtoken ::= ANY",
106841 /* 324 */ "vtabargtoken ::= lp anylist RP",
106842 /* 325 */ "lp ::= LP",
106843 /* 326 */ "anylist ::=",
106844 /* 327 */ "anylist ::= anylist LP anylist RP",
106845 /* 328 */ "anylist ::= anylist ANY",
106847 #endif /* NDEBUG */
106850 #if YYSTACKDEPTH<=0
106852 ** Try to increase the size of the parser stack.
106854 static void yyGrowStack(yyParser *p){
106855 int newSize;
106856 yyStackEntry *pNew;
106858 newSize = p->yystksz*2 + 100;
106859 pNew = realloc(p->yystack, newSize*sizeof(pNew[0]));
106860 if( pNew ){
106861 p->yystack = pNew;
106862 p->yystksz = newSize;
106863 #ifndef NDEBUG
106864 if( yyTraceFILE ){
106865 fprintf(yyTraceFILE,"%sStack grows to %d entries!\n",
106866 yyTracePrompt, p->yystksz);
106868 #endif
106871 #endif
106874 ** This function allocates a new parser.
106875 ** The only argument is a pointer to a function which works like
106876 ** malloc.
106878 ** Inputs:
106879 ** A pointer to the function used to allocate memory.
106881 ** Outputs:
106882 ** A pointer to a parser. This pointer is used in subsequent calls
106883 ** to sqlite3Parser and sqlite3ParserFree.
106885 SQLITE_PRIVATE void *sqlite3ParserAlloc(void *(*mallocProc)(size_t)){
106886 yyParser *pParser;
106887 pParser = (yyParser*)(*mallocProc)( (size_t)sizeof(yyParser) );
106888 if( pParser ){
106889 pParser->yyidx = -1;
106890 #ifdef YYTRACKMAXSTACKDEPTH
106891 pParser->yyidxMax = 0;
106892 #endif
106893 #if YYSTACKDEPTH<=0
106894 pParser->yystack = NULL;
106895 pParser->yystksz = 0;
106896 yyGrowStack(pParser);
106897 #endif
106899 return pParser;
106902 /* The following function deletes the value associated with a
106903 ** symbol. The symbol can be either a terminal or nonterminal.
106904 ** "yymajor" is the symbol code, and "yypminor" is a pointer to
106905 ** the value.
106907 static void yy_destructor(
106908 yyParser *yypParser, /* The parser */
106909 YYCODETYPE yymajor, /* Type code for object to destroy */
106910 YYMINORTYPE *yypminor /* The object to be destroyed */
106912 sqlite3ParserARG_FETCH;
106913 switch( yymajor ){
106914 /* Here is inserted the actions which take place when a
106915 ** terminal or non-terminal is destroyed. This can happen
106916 ** when the symbol is popped from the stack during a
106917 ** reduce or during error processing or when a parser is
106918 ** being destroyed before it is finished parsing.
106920 ** Note: during a reduce, the only symbols destroyed are those
106921 ** which appear on the RHS of the rule, but which are not used
106922 ** inside the C code.
106924 case 160: /* select */
106925 case 194: /* oneselect */
106927 sqlite3SelectDelete(pParse->db, (yypminor->yy387));
106929 break;
106930 case 174: /* term */
106931 case 175: /* expr */
106933 sqlite3ExprDelete(pParse->db, (yypminor->yy118).pExpr);
106935 break;
106936 case 179: /* idxlist_opt */
106937 case 187: /* idxlist */
106938 case 197: /* selcollist */
106939 case 200: /* groupby_opt */
106940 case 202: /* orderby_opt */
106941 case 204: /* sclp */
106942 case 214: /* sortlist */
106943 case 216: /* nexprlist */
106944 case 217: /* setlist */
106945 case 220: /* itemlist */
106946 case 221: /* exprlist */
106947 case 226: /* case_exprlist */
106949 sqlite3ExprListDelete(pParse->db, (yypminor->yy322));
106951 break;
106952 case 193: /* fullname */
106953 case 198: /* from */
106954 case 206: /* seltablist */
106955 case 207: /* stl_prefix */
106957 sqlite3SrcListDelete(pParse->db, (yypminor->yy259));
106959 break;
106960 case 199: /* where_opt */
106961 case 201: /* having_opt */
106962 case 210: /* on_opt */
106963 case 215: /* sortitem */
106964 case 225: /* case_operand */
106965 case 227: /* case_else */
106966 case 238: /* when_clause */
106967 case 243: /* key_opt */
106969 sqlite3ExprDelete(pParse->db, (yypminor->yy314));
106971 break;
106972 case 211: /* using_opt */
106973 case 213: /* inscollist */
106974 case 219: /* inscollist_opt */
106976 sqlite3IdListDelete(pParse->db, (yypminor->yy384));
106978 break;
106979 case 234: /* trigger_cmd_list */
106980 case 239: /* trigger_cmd */
106982 sqlite3DeleteTriggerStep(pParse->db, (yypminor->yy203));
106984 break;
106985 case 236: /* trigger_event */
106987 sqlite3IdListDelete(pParse->db, (yypminor->yy90).b);
106989 break;
106990 default: break; /* If no destructor action specified: do nothing */
106995 ** Pop the parser's stack once.
106997 ** If there is a destructor routine associated with the token which
106998 ** is popped from the stack, then call it.
107000 ** Return the major token number for the symbol popped.
107002 static int yy_pop_parser_stack(yyParser *pParser){
107003 YYCODETYPE yymajor;
107004 yyStackEntry *yytos = &pParser->yystack[pParser->yyidx];
107006 /* There is no mechanism by which the parser stack can be popped below
107007 ** empty in SQLite. */
107008 if( NEVER(pParser->yyidx<0) ) return 0;
107009 #ifndef NDEBUG
107010 if( yyTraceFILE && pParser->yyidx>=0 ){
107011 fprintf(yyTraceFILE,"%sPopping %s\n",
107012 yyTracePrompt,
107013 yyTokenName[yytos->major]);
107015 #endif
107016 yymajor = yytos->major;
107017 yy_destructor(pParser, yymajor, &yytos->minor);
107018 pParser->yyidx--;
107019 return yymajor;
107023 ** Deallocate and destroy a parser. Destructors are all called for
107024 ** all stack elements before shutting the parser down.
107026 ** Inputs:
107027 ** <ul>
107028 ** <li> A pointer to the parser. This should be a pointer
107029 ** obtained from sqlite3ParserAlloc.
107030 ** <li> A pointer to a function used to reclaim memory obtained
107031 ** from malloc.
107032 ** </ul>
107034 SQLITE_PRIVATE void sqlite3ParserFree(
107035 void *p, /* The parser to be deleted */
107036 void (*freeProc)(void*) /* Function used to reclaim memory */
107038 yyParser *pParser = (yyParser*)p;
107039 /* In SQLite, we never try to destroy a parser that was not successfully
107040 ** created in the first place. */
107041 if( NEVER(pParser==0) ) return;
107042 while( pParser->yyidx>=0 ) yy_pop_parser_stack(pParser);
107043 #if YYSTACKDEPTH<=0
107044 free(pParser->yystack);
107045 #endif
107046 (*freeProc)((void*)pParser);
107050 ** Return the peak depth of the stack for a parser.
107052 #ifdef YYTRACKMAXSTACKDEPTH
107053 SQLITE_PRIVATE int sqlite3ParserStackPeak(void *p){
107054 yyParser *pParser = (yyParser*)p;
107055 return pParser->yyidxMax;
107057 #endif
107060 ** Find the appropriate action for a parser given the terminal
107061 ** look-ahead token iLookAhead.
107063 ** If the look-ahead token is YYNOCODE, then check to see if the action is
107064 ** independent of the look-ahead. If it is, return the action, otherwise
107065 ** return YY_NO_ACTION.
107067 static int yy_find_shift_action(
107068 yyParser *pParser, /* The parser */
107069 YYCODETYPE iLookAhead /* The look-ahead token */
107071 int i;
107072 int stateno = pParser->yystack[pParser->yyidx].stateno;
107074 if( stateno>YY_SHIFT_COUNT
107075 || (i = yy_shift_ofst[stateno])==YY_SHIFT_USE_DFLT ){
107076 return yy_default[stateno];
107078 assert( iLookAhead!=YYNOCODE );
107079 i += iLookAhead;
107080 if( i<0 || i>=YY_ACTTAB_COUNT || yy_lookahead[i]!=iLookAhead ){
107081 if( iLookAhead>0 ){
107082 #ifdef YYFALLBACK
107083 YYCODETYPE iFallback; /* Fallback token */
107084 if( iLookAhead<sizeof(yyFallback)/sizeof(yyFallback[0])
107085 && (iFallback = yyFallback[iLookAhead])!=0 ){
107086 #ifndef NDEBUG
107087 if( yyTraceFILE ){
107088 fprintf(yyTraceFILE, "%sFALLBACK %s => %s\n",
107089 yyTracePrompt, yyTokenName[iLookAhead], yyTokenName[iFallback]);
107091 #endif
107092 return yy_find_shift_action(pParser, iFallback);
107094 #endif
107095 #ifdef YYWILDCARD
107097 int j = i - iLookAhead + YYWILDCARD;
107099 #if YY_SHIFT_MIN+YYWILDCARD<0
107100 j>=0 &&
107101 #endif
107102 #if YY_SHIFT_MAX+YYWILDCARD>=YY_ACTTAB_COUNT
107103 j<YY_ACTTAB_COUNT &&
107104 #endif
107105 yy_lookahead[j]==YYWILDCARD
107107 #ifndef NDEBUG
107108 if( yyTraceFILE ){
107109 fprintf(yyTraceFILE, "%sWILDCARD %s => %s\n",
107110 yyTracePrompt, yyTokenName[iLookAhead], yyTokenName[YYWILDCARD]);
107112 #endif /* NDEBUG */
107113 return yy_action[j];
107116 #endif /* YYWILDCARD */
107118 return yy_default[stateno];
107119 }else{
107120 return yy_action[i];
107125 ** Find the appropriate action for a parser given the non-terminal
107126 ** look-ahead token iLookAhead.
107128 ** If the look-ahead token is YYNOCODE, then check to see if the action is
107129 ** independent of the look-ahead. If it is, return the action, otherwise
107130 ** return YY_NO_ACTION.
107132 static int yy_find_reduce_action(
107133 int stateno, /* Current state number */
107134 YYCODETYPE iLookAhead /* The look-ahead token */
107136 int i;
107137 #ifdef YYERRORSYMBOL
107138 if( stateno>YY_REDUCE_COUNT ){
107139 return yy_default[stateno];
107141 #else
107142 assert( stateno<=YY_REDUCE_COUNT );
107143 #endif
107144 i = yy_reduce_ofst[stateno];
107145 assert( i!=YY_REDUCE_USE_DFLT );
107146 assert( iLookAhead!=YYNOCODE );
107147 i += iLookAhead;
107148 #ifdef YYERRORSYMBOL
107149 if( i<0 || i>=YY_ACTTAB_COUNT || yy_lookahead[i]!=iLookAhead ){
107150 return yy_default[stateno];
107152 #else
107153 assert( i>=0 && i<YY_ACTTAB_COUNT );
107154 assert( yy_lookahead[i]==iLookAhead );
107155 #endif
107156 return yy_action[i];
107160 ** The following routine is called if the stack overflows.
107162 static void yyStackOverflow(yyParser *yypParser, YYMINORTYPE *yypMinor){
107163 sqlite3ParserARG_FETCH;
107164 yypParser->yyidx--;
107165 #ifndef NDEBUG
107166 if( yyTraceFILE ){
107167 fprintf(yyTraceFILE,"%sStack Overflow!\n",yyTracePrompt);
107169 #endif
107170 while( yypParser->yyidx>=0 ) yy_pop_parser_stack(yypParser);
107171 /* Here code is inserted which will execute if the parser
107172 ** stack every overflows */
107174 UNUSED_PARAMETER(yypMinor); /* Silence some compiler warnings */
107175 sqlite3ErrorMsg(pParse, "parser stack overflow");
107176 pParse->parseError = 1;
107177 sqlite3ParserARG_STORE; /* Suppress warning about unused %extra_argument var */
107181 ** Perform a shift action.
107183 static void yy_shift(
107184 yyParser *yypParser, /* The parser to be shifted */
107185 int yyNewState, /* The new state to shift in */
107186 int yyMajor, /* The major token to shift in */
107187 YYMINORTYPE *yypMinor /* Pointer to the minor token to shift in */
107189 yyStackEntry *yytos;
107190 yypParser->yyidx++;
107191 #ifdef YYTRACKMAXSTACKDEPTH
107192 if( yypParser->yyidx>yypParser->yyidxMax ){
107193 yypParser->yyidxMax = yypParser->yyidx;
107195 #endif
107196 #if YYSTACKDEPTH>0
107197 if( yypParser->yyidx>=YYSTACKDEPTH ){
107198 yyStackOverflow(yypParser, yypMinor);
107199 return;
107201 #else
107202 if( yypParser->yyidx>=yypParser->yystksz ){
107203 yyGrowStack(yypParser);
107204 if( yypParser->yyidx>=yypParser->yystksz ){
107205 yyStackOverflow(yypParser, yypMinor);
107206 return;
107209 #endif
107210 yytos = &yypParser->yystack[yypParser->yyidx];
107211 yytos->stateno = (YYACTIONTYPE)yyNewState;
107212 yytos->major = (YYCODETYPE)yyMajor;
107213 yytos->minor = *yypMinor;
107214 #ifndef NDEBUG
107215 if( yyTraceFILE && yypParser->yyidx>0 ){
107216 int i;
107217 fprintf(yyTraceFILE,"%sShift %d\n",yyTracePrompt,yyNewState);
107218 fprintf(yyTraceFILE,"%sStack:",yyTracePrompt);
107219 for(i=1; i<=yypParser->yyidx; i++)
107220 fprintf(yyTraceFILE," %s",yyTokenName[yypParser->yystack[i].major]);
107221 fprintf(yyTraceFILE,"\n");
107223 #endif
107226 /* The following table contains information about every rule that
107227 ** is used during the reduce.
107229 static const struct {
107230 YYCODETYPE lhs; /* Symbol on the left-hand side of the rule */
107231 unsigned char nrhs; /* Number of right-hand side symbols in the rule */
107232 } yyRuleInfo[] = {
107233 { 142, 1 },
107234 { 143, 2 },
107235 { 143, 1 },
107236 { 144, 1 },
107237 { 144, 3 },
107238 { 145, 0 },
107239 { 145, 1 },
107240 { 145, 3 },
107241 { 146, 1 },
107242 { 147, 3 },
107243 { 149, 0 },
107244 { 149, 1 },
107245 { 149, 2 },
107246 { 148, 0 },
107247 { 148, 1 },
107248 { 148, 1 },
107249 { 148, 1 },
107250 { 147, 2 },
107251 { 147, 2 },
107252 { 147, 2 },
107253 { 151, 1 },
107254 { 151, 0 },
107255 { 147, 2 },
107256 { 147, 3 },
107257 { 147, 5 },
107258 { 147, 2 },
107259 { 152, 6 },
107260 { 154, 1 },
107261 { 156, 0 },
107262 { 156, 3 },
107263 { 155, 1 },
107264 { 155, 0 },
107265 { 153, 4 },
107266 { 153, 2 },
107267 { 158, 3 },
107268 { 158, 1 },
107269 { 161, 3 },
107270 { 162, 1 },
107271 { 165, 1 },
107272 { 165, 1 },
107273 { 166, 1 },
107274 { 150, 1 },
107275 { 150, 1 },
107276 { 150, 1 },
107277 { 163, 0 },
107278 { 163, 1 },
107279 { 167, 1 },
107280 { 167, 4 },
107281 { 167, 6 },
107282 { 168, 1 },
107283 { 168, 2 },
107284 { 169, 1 },
107285 { 169, 1 },
107286 { 164, 2 },
107287 { 164, 0 },
107288 { 172, 3 },
107289 { 172, 1 },
107290 { 173, 2 },
107291 { 173, 4 },
107292 { 173, 3 },
107293 { 173, 3 },
107294 { 173, 2 },
107295 { 173, 2 },
107296 { 173, 3 },
107297 { 173, 5 },
107298 { 173, 2 },
107299 { 173, 4 },
107300 { 173, 4 },
107301 { 173, 1 },
107302 { 173, 2 },
107303 { 178, 0 },
107304 { 178, 1 },
107305 { 180, 0 },
107306 { 180, 2 },
107307 { 182, 2 },
107308 { 182, 3 },
107309 { 182, 3 },
107310 { 182, 3 },
107311 { 183, 2 },
107312 { 183, 2 },
107313 { 183, 1 },
107314 { 183, 1 },
107315 { 183, 2 },
107316 { 181, 3 },
107317 { 181, 2 },
107318 { 184, 0 },
107319 { 184, 2 },
107320 { 184, 2 },
107321 { 159, 0 },
107322 { 159, 2 },
107323 { 185, 3 },
107324 { 185, 2 },
107325 { 185, 1 },
107326 { 186, 2 },
107327 { 186, 7 },
107328 { 186, 5 },
107329 { 186, 5 },
107330 { 186, 10 },
107331 { 188, 0 },
107332 { 188, 1 },
107333 { 176, 0 },
107334 { 176, 3 },
107335 { 189, 0 },
107336 { 189, 2 },
107337 { 190, 1 },
107338 { 190, 1 },
107339 { 190, 1 },
107340 { 147, 4 },
107341 { 192, 2 },
107342 { 192, 0 },
107343 { 147, 8 },
107344 { 147, 4 },
107345 { 147, 1 },
107346 { 160, 1 },
107347 { 160, 3 },
107348 { 195, 1 },
107349 { 195, 2 },
107350 { 195, 1 },
107351 { 194, 9 },
107352 { 196, 1 },
107353 { 196, 1 },
107354 { 196, 0 },
107355 { 204, 2 },
107356 { 204, 0 },
107357 { 197, 3 },
107358 { 197, 2 },
107359 { 197, 4 },
107360 { 205, 2 },
107361 { 205, 1 },
107362 { 205, 0 },
107363 { 198, 0 },
107364 { 198, 2 },
107365 { 207, 2 },
107366 { 207, 0 },
107367 { 206, 7 },
107368 { 206, 7 },
107369 { 206, 7 },
107370 { 157, 0 },
107371 { 157, 2 },
107372 { 193, 2 },
107373 { 208, 1 },
107374 { 208, 2 },
107375 { 208, 3 },
107376 { 208, 4 },
107377 { 210, 2 },
107378 { 210, 0 },
107379 { 209, 0 },
107380 { 209, 3 },
107381 { 209, 2 },
107382 { 211, 4 },
107383 { 211, 0 },
107384 { 202, 0 },
107385 { 202, 3 },
107386 { 214, 4 },
107387 { 214, 2 },
107388 { 215, 1 },
107389 { 177, 1 },
107390 { 177, 1 },
107391 { 177, 0 },
107392 { 200, 0 },
107393 { 200, 3 },
107394 { 201, 0 },
107395 { 201, 2 },
107396 { 203, 0 },
107397 { 203, 2 },
107398 { 203, 4 },
107399 { 203, 4 },
107400 { 147, 5 },
107401 { 199, 0 },
107402 { 199, 2 },
107403 { 147, 7 },
107404 { 217, 5 },
107405 { 217, 3 },
107406 { 147, 8 },
107407 { 147, 5 },
107408 { 147, 6 },
107409 { 218, 2 },
107410 { 218, 1 },
107411 { 220, 3 },
107412 { 220, 1 },
107413 { 219, 0 },
107414 { 219, 3 },
107415 { 213, 3 },
107416 { 213, 1 },
107417 { 175, 1 },
107418 { 175, 3 },
107419 { 174, 1 },
107420 { 175, 1 },
107421 { 175, 1 },
107422 { 175, 3 },
107423 { 175, 5 },
107424 { 174, 1 },
107425 { 174, 1 },
107426 { 175, 1 },
107427 { 175, 1 },
107428 { 175, 3 },
107429 { 175, 6 },
107430 { 175, 5 },
107431 { 175, 4 },
107432 { 174, 1 },
107433 { 175, 3 },
107434 { 175, 3 },
107435 { 175, 3 },
107436 { 175, 3 },
107437 { 175, 3 },
107438 { 175, 3 },
107439 { 175, 3 },
107440 { 175, 3 },
107441 { 222, 1 },
107442 { 222, 2 },
107443 { 222, 1 },
107444 { 222, 2 },
107445 { 175, 3 },
107446 { 175, 5 },
107447 { 175, 2 },
107448 { 175, 3 },
107449 { 175, 3 },
107450 { 175, 4 },
107451 { 175, 2 },
107452 { 175, 2 },
107453 { 175, 2 },
107454 { 175, 2 },
107455 { 223, 1 },
107456 { 223, 2 },
107457 { 175, 5 },
107458 { 224, 1 },
107459 { 224, 2 },
107460 { 175, 5 },
107461 { 175, 3 },
107462 { 175, 5 },
107463 { 175, 4 },
107464 { 175, 4 },
107465 { 175, 5 },
107466 { 226, 5 },
107467 { 226, 4 },
107468 { 227, 2 },
107469 { 227, 0 },
107470 { 225, 1 },
107471 { 225, 0 },
107472 { 221, 1 },
107473 { 221, 0 },
107474 { 216, 3 },
107475 { 216, 1 },
107476 { 147, 11 },
107477 { 228, 1 },
107478 { 228, 0 },
107479 { 179, 0 },
107480 { 179, 3 },
107481 { 187, 5 },
107482 { 187, 3 },
107483 { 229, 0 },
107484 { 229, 2 },
107485 { 147, 4 },
107486 { 147, 1 },
107487 { 147, 2 },
107488 { 147, 3 },
107489 { 147, 5 },
107490 { 147, 6 },
107491 { 147, 5 },
107492 { 147, 6 },
107493 { 230, 1 },
107494 { 230, 1 },
107495 { 230, 1 },
107496 { 230, 1 },
107497 { 230, 1 },
107498 { 170, 2 },
107499 { 171, 2 },
107500 { 232, 1 },
107501 { 231, 1 },
107502 { 231, 0 },
107503 { 147, 5 },
107504 { 233, 11 },
107505 { 235, 1 },
107506 { 235, 1 },
107507 { 235, 2 },
107508 { 235, 0 },
107509 { 236, 1 },
107510 { 236, 1 },
107511 { 236, 3 },
107512 { 237, 0 },
107513 { 237, 3 },
107514 { 238, 0 },
107515 { 238, 2 },
107516 { 234, 3 },
107517 { 234, 2 },
107518 { 240, 1 },
107519 { 240, 3 },
107520 { 241, 0 },
107521 { 241, 3 },
107522 { 241, 2 },
107523 { 239, 7 },
107524 { 239, 8 },
107525 { 239, 5 },
107526 { 239, 5 },
107527 { 239, 1 },
107528 { 175, 4 },
107529 { 175, 6 },
107530 { 191, 1 },
107531 { 191, 1 },
107532 { 191, 1 },
107533 { 147, 4 },
107534 { 147, 6 },
107535 { 147, 3 },
107536 { 243, 0 },
107537 { 243, 2 },
107538 { 242, 1 },
107539 { 242, 0 },
107540 { 147, 1 },
107541 { 147, 3 },
107542 { 147, 1 },
107543 { 147, 3 },
107544 { 147, 6 },
107545 { 147, 6 },
107546 { 244, 1 },
107547 { 245, 0 },
107548 { 245, 1 },
107549 { 147, 1 },
107550 { 147, 4 },
107551 { 246, 7 },
107552 { 247, 1 },
107553 { 247, 3 },
107554 { 248, 0 },
107555 { 248, 2 },
107556 { 249, 1 },
107557 { 249, 3 },
107558 { 250, 1 },
107559 { 251, 0 },
107560 { 251, 4 },
107561 { 251, 2 },
107564 static void yy_accept(yyParser*); /* Forward Declaration */
107567 ** Perform a reduce action and the shift that must immediately
107568 ** follow the reduce.
107570 static void yy_reduce(
107571 yyParser *yypParser, /* The parser */
107572 int yyruleno /* Number of the rule by which to reduce */
107574 int yygoto; /* The next state */
107575 int yyact; /* The next action */
107576 YYMINORTYPE yygotominor; /* The LHS of the rule reduced */
107577 yyStackEntry *yymsp; /* The top of the parser's stack */
107578 int yysize; /* Amount to pop the stack */
107579 sqlite3ParserARG_FETCH;
107580 yymsp = &yypParser->yystack[yypParser->yyidx];
107581 #ifndef NDEBUG
107582 if( yyTraceFILE && yyruleno>=0
107583 && yyruleno<(int)(sizeof(yyRuleName)/sizeof(yyRuleName[0])) ){
107584 fprintf(yyTraceFILE, "%sReduce [%s].\n", yyTracePrompt,
107585 yyRuleName[yyruleno]);
107587 #endif /* NDEBUG */
107589 /* Silence complaints from purify about yygotominor being uninitialized
107590 ** in some cases when it is copied into the stack after the following
107591 ** switch. yygotominor is uninitialized when a rule reduces that does
107592 ** not set the value of its left-hand side nonterminal. Leaving the
107593 ** value of the nonterminal uninitialized is utterly harmless as long
107594 ** as the value is never used. So really the only thing this code
107595 ** accomplishes is to quieten purify.
107597 ** 2007-01-16: The wireshark project (www.wireshark.org) reports that
107598 ** without this code, their parser segfaults. I'm not sure what there
107599 ** parser is doing to make this happen. This is the second bug report
107600 ** from wireshark this week. Clearly they are stressing Lemon in ways
107601 ** that it has not been previously stressed... (SQLite ticket #2172)
107603 /*memset(&yygotominor, 0, sizeof(yygotominor));*/
107604 yygotominor = yyzerominor;
107607 switch( yyruleno ){
107608 /* Beginning here are the reduction cases. A typical example
107609 ** follows:
107610 ** case 0:
107611 ** #line <lineno> <grammarfile>
107612 ** { ... } // User supplied code
107613 ** #line <lineno> <thisfile>
107614 ** break;
107616 case 5: /* explain ::= */
107617 { sqlite3BeginParse(pParse, 0); }
107618 break;
107619 case 6: /* explain ::= EXPLAIN */
107620 { sqlite3BeginParse(pParse, 1); }
107621 break;
107622 case 7: /* explain ::= EXPLAIN QUERY PLAN */
107623 { sqlite3BeginParse(pParse, 2); }
107624 break;
107625 case 8: /* cmdx ::= cmd */
107626 { sqlite3FinishCoding(pParse); }
107627 break;
107628 case 9: /* cmd ::= BEGIN transtype trans_opt */
107629 {sqlite3BeginTransaction(pParse, yymsp[-1].minor.yy4);}
107630 break;
107631 case 13: /* transtype ::= */
107632 {yygotominor.yy4 = TK_DEFERRED;}
107633 break;
107634 case 14: /* transtype ::= DEFERRED */
107635 case 15: /* transtype ::= IMMEDIATE */ yytestcase(yyruleno==15);
107636 case 16: /* transtype ::= EXCLUSIVE */ yytestcase(yyruleno==16);
107637 case 115: /* multiselect_op ::= UNION */ yytestcase(yyruleno==115);
107638 case 117: /* multiselect_op ::= EXCEPT|INTERSECT */ yytestcase(yyruleno==117);
107639 {yygotominor.yy4 = yymsp[0].major;}
107640 break;
107641 case 17: /* cmd ::= COMMIT trans_opt */
107642 case 18: /* cmd ::= END trans_opt */ yytestcase(yyruleno==18);
107643 {sqlite3CommitTransaction(pParse);}
107644 break;
107645 case 19: /* cmd ::= ROLLBACK trans_opt */
107646 {sqlite3RollbackTransaction(pParse);}
107647 break;
107648 case 22: /* cmd ::= SAVEPOINT nm */
107650 sqlite3Savepoint(pParse, SAVEPOINT_BEGIN, &yymsp[0].minor.yy0);
107652 break;
107653 case 23: /* cmd ::= RELEASE savepoint_opt nm */
107655 sqlite3Savepoint(pParse, SAVEPOINT_RELEASE, &yymsp[0].minor.yy0);
107657 break;
107658 case 24: /* cmd ::= ROLLBACK trans_opt TO savepoint_opt nm */
107660 sqlite3Savepoint(pParse, SAVEPOINT_ROLLBACK, &yymsp[0].minor.yy0);
107662 break;
107663 case 26: /* create_table ::= createkw temp TABLE ifnotexists nm dbnm */
107665 sqlite3StartTable(pParse,&yymsp[-1].minor.yy0,&yymsp[0].minor.yy0,yymsp[-4].minor.yy4,0,0,yymsp[-2].minor.yy4);
107667 break;
107668 case 27: /* createkw ::= CREATE */
107670 pParse->db->lookaside.bEnabled = 0;
107671 yygotominor.yy0 = yymsp[0].minor.yy0;
107673 break;
107674 case 28: /* ifnotexists ::= */
107675 case 31: /* temp ::= */ yytestcase(yyruleno==31);
107676 case 70: /* autoinc ::= */ yytestcase(yyruleno==70);
107677 case 83: /* defer_subclause ::= NOT DEFERRABLE init_deferred_pred_opt */ yytestcase(yyruleno==83);
107678 case 85: /* init_deferred_pred_opt ::= */ yytestcase(yyruleno==85);
107679 case 87: /* init_deferred_pred_opt ::= INITIALLY IMMEDIATE */ yytestcase(yyruleno==87);
107680 case 98: /* defer_subclause_opt ::= */ yytestcase(yyruleno==98);
107681 case 109: /* ifexists ::= */ yytestcase(yyruleno==109);
107682 case 120: /* distinct ::= ALL */ yytestcase(yyruleno==120);
107683 case 121: /* distinct ::= */ yytestcase(yyruleno==121);
107684 case 222: /* between_op ::= BETWEEN */ yytestcase(yyruleno==222);
107685 case 225: /* in_op ::= IN */ yytestcase(yyruleno==225);
107686 {yygotominor.yy4 = 0;}
107687 break;
107688 case 29: /* ifnotexists ::= IF NOT EXISTS */
107689 case 30: /* temp ::= TEMP */ yytestcase(yyruleno==30);
107690 case 71: /* autoinc ::= AUTOINCR */ yytestcase(yyruleno==71);
107691 case 86: /* init_deferred_pred_opt ::= INITIALLY DEFERRED */ yytestcase(yyruleno==86);
107692 case 108: /* ifexists ::= IF EXISTS */ yytestcase(yyruleno==108);
107693 case 119: /* distinct ::= DISTINCT */ yytestcase(yyruleno==119);
107694 case 223: /* between_op ::= NOT BETWEEN */ yytestcase(yyruleno==223);
107695 case 226: /* in_op ::= NOT IN */ yytestcase(yyruleno==226);
107696 {yygotominor.yy4 = 1;}
107697 break;
107698 case 32: /* create_table_args ::= LP columnlist conslist_opt RP */
107700 sqlite3EndTable(pParse,&yymsp[-1].minor.yy0,&yymsp[0].minor.yy0,0);
107702 break;
107703 case 33: /* create_table_args ::= AS select */
107705 sqlite3EndTable(pParse,0,0,yymsp[0].minor.yy387);
107706 sqlite3SelectDelete(pParse->db, yymsp[0].minor.yy387);
107708 break;
107709 case 36: /* column ::= columnid type carglist */
107711 yygotominor.yy0.z = yymsp[-2].minor.yy0.z;
107712 yygotominor.yy0.n = (int)(pParse->sLastToken.z-yymsp[-2].minor.yy0.z) + pParse->sLastToken.n;
107714 break;
107715 case 37: /* columnid ::= nm */
107717 sqlite3AddColumn(pParse,&yymsp[0].minor.yy0);
107718 yygotominor.yy0 = yymsp[0].minor.yy0;
107720 break;
107721 case 38: /* id ::= ID */
107722 case 39: /* id ::= INDEXED */ yytestcase(yyruleno==39);
107723 case 40: /* ids ::= ID|STRING */ yytestcase(yyruleno==40);
107724 case 41: /* nm ::= id */ yytestcase(yyruleno==41);
107725 case 42: /* nm ::= STRING */ yytestcase(yyruleno==42);
107726 case 43: /* nm ::= JOIN_KW */ yytestcase(yyruleno==43);
107727 case 46: /* typetoken ::= typename */ yytestcase(yyruleno==46);
107728 case 49: /* typename ::= ids */ yytestcase(yyruleno==49);
107729 case 127: /* as ::= AS nm */ yytestcase(yyruleno==127);
107730 case 128: /* as ::= ids */ yytestcase(yyruleno==128);
107731 case 138: /* dbnm ::= DOT nm */ yytestcase(yyruleno==138);
107732 case 147: /* indexed_opt ::= INDEXED BY nm */ yytestcase(yyruleno==147);
107733 case 251: /* collate ::= COLLATE ids */ yytestcase(yyruleno==251);
107734 case 260: /* nmnum ::= plus_num */ yytestcase(yyruleno==260);
107735 case 261: /* nmnum ::= nm */ yytestcase(yyruleno==261);
107736 case 262: /* nmnum ::= ON */ yytestcase(yyruleno==262);
107737 case 263: /* nmnum ::= DELETE */ yytestcase(yyruleno==263);
107738 case 264: /* nmnum ::= DEFAULT */ yytestcase(yyruleno==264);
107739 case 265: /* plus_num ::= plus_opt number */ yytestcase(yyruleno==265);
107740 case 266: /* minus_num ::= MINUS number */ yytestcase(yyruleno==266);
107741 case 267: /* number ::= INTEGER|FLOAT */ yytestcase(yyruleno==267);
107742 case 285: /* trnm ::= nm */ yytestcase(yyruleno==285);
107743 {yygotominor.yy0 = yymsp[0].minor.yy0;}
107744 break;
107745 case 45: /* type ::= typetoken */
107746 {sqlite3AddColumnType(pParse,&yymsp[0].minor.yy0);}
107747 break;
107748 case 47: /* typetoken ::= typename LP signed RP */
107750 yygotominor.yy0.z = yymsp[-3].minor.yy0.z;
107751 yygotominor.yy0.n = (int)(&yymsp[0].minor.yy0.z[yymsp[0].minor.yy0.n] - yymsp[-3].minor.yy0.z);
107753 break;
107754 case 48: /* typetoken ::= typename LP signed COMMA signed RP */
107756 yygotominor.yy0.z = yymsp[-5].minor.yy0.z;
107757 yygotominor.yy0.n = (int)(&yymsp[0].minor.yy0.z[yymsp[0].minor.yy0.n] - yymsp[-5].minor.yy0.z);
107759 break;
107760 case 50: /* typename ::= typename ids */
107761 {yygotominor.yy0.z=yymsp[-1].minor.yy0.z; yygotominor.yy0.n=yymsp[0].minor.yy0.n+(int)(yymsp[0].minor.yy0.z-yymsp[-1].minor.yy0.z);}
107762 break;
107763 case 57: /* ccons ::= DEFAULT term */
107764 case 59: /* ccons ::= DEFAULT PLUS term */ yytestcase(yyruleno==59);
107765 {sqlite3AddDefaultValue(pParse,&yymsp[0].minor.yy118);}
107766 break;
107767 case 58: /* ccons ::= DEFAULT LP expr RP */
107768 {sqlite3AddDefaultValue(pParse,&yymsp[-1].minor.yy118);}
107769 break;
107770 case 60: /* ccons ::= DEFAULT MINUS term */
107772 ExprSpan v;
107773 v.pExpr = sqlite3PExpr(pParse, TK_UMINUS, yymsp[0].minor.yy118.pExpr, 0, 0);
107774 v.zStart = yymsp[-1].minor.yy0.z;
107775 v.zEnd = yymsp[0].minor.yy118.zEnd;
107776 sqlite3AddDefaultValue(pParse,&v);
107778 break;
107779 case 61: /* ccons ::= DEFAULT id */
107781 ExprSpan v;
107782 spanExpr(&v, pParse, TK_STRING, &yymsp[0].minor.yy0);
107783 sqlite3AddDefaultValue(pParse,&v);
107785 break;
107786 case 63: /* ccons ::= NOT NULL onconf */
107787 {sqlite3AddNotNull(pParse, yymsp[0].minor.yy4);}
107788 break;
107789 case 64: /* ccons ::= PRIMARY KEY sortorder onconf autoinc */
107790 {sqlite3AddPrimaryKey(pParse,0,yymsp[-1].minor.yy4,yymsp[0].minor.yy4,yymsp[-2].minor.yy4);}
107791 break;
107792 case 65: /* ccons ::= UNIQUE onconf */
107793 {sqlite3CreateIndex(pParse,0,0,0,0,yymsp[0].minor.yy4,0,0,0,0);}
107794 break;
107795 case 66: /* ccons ::= CHECK LP expr RP */
107796 {sqlite3AddCheckConstraint(pParse,yymsp[-1].minor.yy118.pExpr);}
107797 break;
107798 case 67: /* ccons ::= REFERENCES nm idxlist_opt refargs */
107799 {sqlite3CreateForeignKey(pParse,0,&yymsp[-2].minor.yy0,yymsp[-1].minor.yy322,yymsp[0].minor.yy4);}
107800 break;
107801 case 68: /* ccons ::= defer_subclause */
107802 {sqlite3DeferForeignKey(pParse,yymsp[0].minor.yy4);}
107803 break;
107804 case 69: /* ccons ::= COLLATE ids */
107805 {sqlite3AddCollateType(pParse, &yymsp[0].minor.yy0);}
107806 break;
107807 case 72: /* refargs ::= */
107808 { yygotominor.yy4 = OE_None*0x0101; /* EV: R-19803-45884 */}
107809 break;
107810 case 73: /* refargs ::= refargs refarg */
107811 { yygotominor.yy4 = (yymsp[-1].minor.yy4 & ~yymsp[0].minor.yy215.mask) | yymsp[0].minor.yy215.value; }
107812 break;
107813 case 74: /* refarg ::= MATCH nm */
107814 case 75: /* refarg ::= ON INSERT refact */ yytestcase(yyruleno==75);
107815 { yygotominor.yy215.value = 0; yygotominor.yy215.mask = 0x000000; }
107816 break;
107817 case 76: /* refarg ::= ON DELETE refact */
107818 { yygotominor.yy215.value = yymsp[0].minor.yy4; yygotominor.yy215.mask = 0x0000ff; }
107819 break;
107820 case 77: /* refarg ::= ON UPDATE refact */
107821 { yygotominor.yy215.value = yymsp[0].minor.yy4<<8; yygotominor.yy215.mask = 0x00ff00; }
107822 break;
107823 case 78: /* refact ::= SET NULL */
107824 { yygotominor.yy4 = OE_SetNull; /* EV: R-33326-45252 */}
107825 break;
107826 case 79: /* refact ::= SET DEFAULT */
107827 { yygotominor.yy4 = OE_SetDflt; /* EV: R-33326-45252 */}
107828 break;
107829 case 80: /* refact ::= CASCADE */
107830 { yygotominor.yy4 = OE_Cascade; /* EV: R-33326-45252 */}
107831 break;
107832 case 81: /* refact ::= RESTRICT */
107833 { yygotominor.yy4 = OE_Restrict; /* EV: R-33326-45252 */}
107834 break;
107835 case 82: /* refact ::= NO ACTION */
107836 { yygotominor.yy4 = OE_None; /* EV: R-33326-45252 */}
107837 break;
107838 case 84: /* defer_subclause ::= DEFERRABLE init_deferred_pred_opt */
107839 case 99: /* defer_subclause_opt ::= defer_subclause */ yytestcase(yyruleno==99);
107840 case 101: /* onconf ::= ON CONFLICT resolvetype */ yytestcase(yyruleno==101);
107841 case 104: /* resolvetype ::= raisetype */ yytestcase(yyruleno==104);
107842 {yygotominor.yy4 = yymsp[0].minor.yy4;}
107843 break;
107844 case 88: /* conslist_opt ::= */
107845 {yygotominor.yy0.n = 0; yygotominor.yy0.z = 0;}
107846 break;
107847 case 89: /* conslist_opt ::= COMMA conslist */
107848 {yygotominor.yy0 = yymsp[-1].minor.yy0;}
107849 break;
107850 case 94: /* tcons ::= PRIMARY KEY LP idxlist autoinc RP onconf */
107851 {sqlite3AddPrimaryKey(pParse,yymsp[-3].minor.yy322,yymsp[0].minor.yy4,yymsp[-2].minor.yy4,0);}
107852 break;
107853 case 95: /* tcons ::= UNIQUE LP idxlist RP onconf */
107854 {sqlite3CreateIndex(pParse,0,0,0,yymsp[-2].minor.yy322,yymsp[0].minor.yy4,0,0,0,0);}
107855 break;
107856 case 96: /* tcons ::= CHECK LP expr RP onconf */
107857 {sqlite3AddCheckConstraint(pParse,yymsp[-2].minor.yy118.pExpr);}
107858 break;
107859 case 97: /* tcons ::= FOREIGN KEY LP idxlist RP REFERENCES nm idxlist_opt refargs defer_subclause_opt */
107861 sqlite3CreateForeignKey(pParse, yymsp[-6].minor.yy322, &yymsp[-3].minor.yy0, yymsp[-2].minor.yy322, yymsp[-1].minor.yy4);
107862 sqlite3DeferForeignKey(pParse, yymsp[0].minor.yy4);
107864 break;
107865 case 100: /* onconf ::= */
107866 {yygotominor.yy4 = OE_Default;}
107867 break;
107868 case 102: /* orconf ::= */
107869 {yygotominor.yy210 = OE_Default;}
107870 break;
107871 case 103: /* orconf ::= OR resolvetype */
107872 {yygotominor.yy210 = (u8)yymsp[0].minor.yy4;}
107873 break;
107874 case 105: /* resolvetype ::= IGNORE */
107875 {yygotominor.yy4 = OE_Ignore;}
107876 break;
107877 case 106: /* resolvetype ::= REPLACE */
107878 {yygotominor.yy4 = OE_Replace;}
107879 break;
107880 case 107: /* cmd ::= DROP TABLE ifexists fullname */
107882 sqlite3DropTable(pParse, yymsp[0].minor.yy259, 0, yymsp[-1].minor.yy4);
107884 break;
107885 case 110: /* cmd ::= createkw temp VIEW ifnotexists nm dbnm AS select */
107887 sqlite3CreateView(pParse, &yymsp[-7].minor.yy0, &yymsp[-3].minor.yy0, &yymsp[-2].minor.yy0, yymsp[0].minor.yy387, yymsp[-6].minor.yy4, yymsp[-4].minor.yy4);
107889 break;
107890 case 111: /* cmd ::= DROP VIEW ifexists fullname */
107892 sqlite3DropTable(pParse, yymsp[0].minor.yy259, 1, yymsp[-1].minor.yy4);
107894 break;
107895 case 112: /* cmd ::= select */
107897 SelectDest dest = {SRT_Output, 0, 0, 0, 0};
107898 sqlite3Select(pParse, yymsp[0].minor.yy387, &dest);
107899 sqlite3SelectDelete(pParse->db, yymsp[0].minor.yy387);
107901 break;
107902 case 113: /* select ::= oneselect */
107903 {yygotominor.yy387 = yymsp[0].minor.yy387;}
107904 break;
107905 case 114: /* select ::= select multiselect_op oneselect */
107907 if( yymsp[0].minor.yy387 ){
107908 yymsp[0].minor.yy387->op = (u8)yymsp[-1].minor.yy4;
107909 yymsp[0].minor.yy387->pPrior = yymsp[-2].minor.yy387;
107910 }else{
107911 sqlite3SelectDelete(pParse->db, yymsp[-2].minor.yy387);
107913 yygotominor.yy387 = yymsp[0].minor.yy387;
107915 break;
107916 case 116: /* multiselect_op ::= UNION ALL */
107917 {yygotominor.yy4 = TK_ALL;}
107918 break;
107919 case 118: /* oneselect ::= SELECT distinct selcollist from where_opt groupby_opt having_opt orderby_opt limit_opt */
107921 yygotominor.yy387 = sqlite3SelectNew(pParse,yymsp[-6].minor.yy322,yymsp[-5].minor.yy259,yymsp[-4].minor.yy314,yymsp[-3].minor.yy322,yymsp[-2].minor.yy314,yymsp[-1].minor.yy322,yymsp[-7].minor.yy4,yymsp[0].minor.yy292.pLimit,yymsp[0].minor.yy292.pOffset);
107923 break;
107924 case 122: /* sclp ::= selcollist COMMA */
107925 case 247: /* idxlist_opt ::= LP idxlist RP */ yytestcase(yyruleno==247);
107926 {yygotominor.yy322 = yymsp[-1].minor.yy322;}
107927 break;
107928 case 123: /* sclp ::= */
107929 case 151: /* orderby_opt ::= */ yytestcase(yyruleno==151);
107930 case 159: /* groupby_opt ::= */ yytestcase(yyruleno==159);
107931 case 240: /* exprlist ::= */ yytestcase(yyruleno==240);
107932 case 246: /* idxlist_opt ::= */ yytestcase(yyruleno==246);
107933 {yygotominor.yy322 = 0;}
107934 break;
107935 case 124: /* selcollist ::= sclp expr as */
107937 yygotominor.yy322 = sqlite3ExprListAppend(pParse, yymsp[-2].minor.yy322, yymsp[-1].minor.yy118.pExpr);
107938 if( yymsp[0].minor.yy0.n>0 ) sqlite3ExprListSetName(pParse, yygotominor.yy322, &yymsp[0].minor.yy0, 1);
107939 sqlite3ExprListSetSpan(pParse,yygotominor.yy322,&yymsp[-1].minor.yy118);
107941 break;
107942 case 125: /* selcollist ::= sclp STAR */
107944 Expr *p = sqlite3Expr(pParse->db, TK_ALL, 0);
107945 yygotominor.yy322 = sqlite3ExprListAppend(pParse, yymsp[-1].minor.yy322, p);
107947 break;
107948 case 126: /* selcollist ::= sclp nm DOT STAR */
107950 Expr *pRight = sqlite3PExpr(pParse, TK_ALL, 0, 0, &yymsp[0].minor.yy0);
107951 Expr *pLeft = sqlite3PExpr(pParse, TK_ID, 0, 0, &yymsp[-2].minor.yy0);
107952 Expr *pDot = sqlite3PExpr(pParse, TK_DOT, pLeft, pRight, 0);
107953 yygotominor.yy322 = sqlite3ExprListAppend(pParse,yymsp[-3].minor.yy322, pDot);
107955 break;
107956 case 129: /* as ::= */
107957 {yygotominor.yy0.n = 0;}
107958 break;
107959 case 130: /* from ::= */
107960 {yygotominor.yy259 = sqlite3DbMallocZero(pParse->db, sizeof(*yygotominor.yy259));}
107961 break;
107962 case 131: /* from ::= FROM seltablist */
107964 yygotominor.yy259 = yymsp[0].minor.yy259;
107965 sqlite3SrcListShiftJoinType(yygotominor.yy259);
107967 break;
107968 case 132: /* stl_prefix ::= seltablist joinop */
107970 yygotominor.yy259 = yymsp[-1].minor.yy259;
107971 if( ALWAYS(yygotominor.yy259 && yygotominor.yy259->nSrc>0) ) yygotominor.yy259->a[yygotominor.yy259->nSrc-1].jointype = (u8)yymsp[0].minor.yy4;
107973 break;
107974 case 133: /* stl_prefix ::= */
107975 {yygotominor.yy259 = 0;}
107976 break;
107977 case 134: /* seltablist ::= stl_prefix nm dbnm as indexed_opt on_opt using_opt */
107979 yygotominor.yy259 = sqlite3SrcListAppendFromTerm(pParse,yymsp[-6].minor.yy259,&yymsp[-5].minor.yy0,&yymsp[-4].minor.yy0,&yymsp[-3].minor.yy0,0,yymsp[-1].minor.yy314,yymsp[0].minor.yy384);
107980 sqlite3SrcListIndexedBy(pParse, yygotominor.yy259, &yymsp[-2].minor.yy0);
107982 break;
107983 case 135: /* seltablist ::= stl_prefix LP select RP as on_opt using_opt */
107985 yygotominor.yy259 = sqlite3SrcListAppendFromTerm(pParse,yymsp[-6].minor.yy259,0,0,&yymsp[-2].minor.yy0,yymsp[-4].minor.yy387,yymsp[-1].minor.yy314,yymsp[0].minor.yy384);
107987 break;
107988 case 136: /* seltablist ::= stl_prefix LP seltablist RP as on_opt using_opt */
107990 if( yymsp[-6].minor.yy259==0 && yymsp[-2].minor.yy0.n==0 && yymsp[-1].minor.yy314==0 && yymsp[0].minor.yy384==0 ){
107991 yygotominor.yy259 = yymsp[-4].minor.yy259;
107992 }else{
107993 Select *pSubquery;
107994 sqlite3SrcListShiftJoinType(yymsp[-4].minor.yy259);
107995 pSubquery = sqlite3SelectNew(pParse,0,yymsp[-4].minor.yy259,0,0,0,0,0,0,0);
107996 yygotominor.yy259 = sqlite3SrcListAppendFromTerm(pParse,yymsp[-6].minor.yy259,0,0,&yymsp[-2].minor.yy0,pSubquery,yymsp[-1].minor.yy314,yymsp[0].minor.yy384);
107999 break;
108000 case 137: /* dbnm ::= */
108001 case 146: /* indexed_opt ::= */ yytestcase(yyruleno==146);
108002 {yygotominor.yy0.z=0; yygotominor.yy0.n=0;}
108003 break;
108004 case 139: /* fullname ::= nm dbnm */
108005 {yygotominor.yy259 = sqlite3SrcListAppend(pParse->db,0,&yymsp[-1].minor.yy0,&yymsp[0].minor.yy0);}
108006 break;
108007 case 140: /* joinop ::= COMMA|JOIN */
108008 { yygotominor.yy4 = JT_INNER; }
108009 break;
108010 case 141: /* joinop ::= JOIN_KW JOIN */
108011 { yygotominor.yy4 = sqlite3JoinType(pParse,&yymsp[-1].minor.yy0,0,0); }
108012 break;
108013 case 142: /* joinop ::= JOIN_KW nm JOIN */
108014 { yygotominor.yy4 = sqlite3JoinType(pParse,&yymsp[-2].minor.yy0,&yymsp[-1].minor.yy0,0); }
108015 break;
108016 case 143: /* joinop ::= JOIN_KW nm nm JOIN */
108017 { yygotominor.yy4 = sqlite3JoinType(pParse,&yymsp[-3].minor.yy0,&yymsp[-2].minor.yy0,&yymsp[-1].minor.yy0); }
108018 break;
108019 case 144: /* on_opt ::= ON expr */
108020 case 155: /* sortitem ::= expr */ yytestcase(yyruleno==155);
108021 case 162: /* having_opt ::= HAVING expr */ yytestcase(yyruleno==162);
108022 case 169: /* where_opt ::= WHERE expr */ yytestcase(yyruleno==169);
108023 case 235: /* case_else ::= ELSE expr */ yytestcase(yyruleno==235);
108024 case 237: /* case_operand ::= expr */ yytestcase(yyruleno==237);
108025 {yygotominor.yy314 = yymsp[0].minor.yy118.pExpr;}
108026 break;
108027 case 145: /* on_opt ::= */
108028 case 161: /* having_opt ::= */ yytestcase(yyruleno==161);
108029 case 168: /* where_opt ::= */ yytestcase(yyruleno==168);
108030 case 236: /* case_else ::= */ yytestcase(yyruleno==236);
108031 case 238: /* case_operand ::= */ yytestcase(yyruleno==238);
108032 {yygotominor.yy314 = 0;}
108033 break;
108034 case 148: /* indexed_opt ::= NOT INDEXED */
108035 {yygotominor.yy0.z=0; yygotominor.yy0.n=1;}
108036 break;
108037 case 149: /* using_opt ::= USING LP inscollist RP */
108038 case 181: /* inscollist_opt ::= LP inscollist RP */ yytestcase(yyruleno==181);
108039 {yygotominor.yy384 = yymsp[-1].minor.yy384;}
108040 break;
108041 case 150: /* using_opt ::= */
108042 case 180: /* inscollist_opt ::= */ yytestcase(yyruleno==180);
108043 {yygotominor.yy384 = 0;}
108044 break;
108045 case 152: /* orderby_opt ::= ORDER BY sortlist */
108046 case 160: /* groupby_opt ::= GROUP BY nexprlist */ yytestcase(yyruleno==160);
108047 case 239: /* exprlist ::= nexprlist */ yytestcase(yyruleno==239);
108048 {yygotominor.yy322 = yymsp[0].minor.yy322;}
108049 break;
108050 case 153: /* sortlist ::= sortlist COMMA sortitem sortorder */
108052 yygotominor.yy322 = sqlite3ExprListAppend(pParse,yymsp[-3].minor.yy322,yymsp[-1].minor.yy314);
108053 if( yygotominor.yy322 ) yygotominor.yy322->a[yygotominor.yy322->nExpr-1].sortOrder = (u8)yymsp[0].minor.yy4;
108055 break;
108056 case 154: /* sortlist ::= sortitem sortorder */
108058 yygotominor.yy322 = sqlite3ExprListAppend(pParse,0,yymsp[-1].minor.yy314);
108059 if( yygotominor.yy322 && ALWAYS(yygotominor.yy322->a) ) yygotominor.yy322->a[0].sortOrder = (u8)yymsp[0].minor.yy4;
108061 break;
108062 case 156: /* sortorder ::= ASC */
108063 case 158: /* sortorder ::= */ yytestcase(yyruleno==158);
108064 {yygotominor.yy4 = SQLITE_SO_ASC;}
108065 break;
108066 case 157: /* sortorder ::= DESC */
108067 {yygotominor.yy4 = SQLITE_SO_DESC;}
108068 break;
108069 case 163: /* limit_opt ::= */
108070 {yygotominor.yy292.pLimit = 0; yygotominor.yy292.pOffset = 0;}
108071 break;
108072 case 164: /* limit_opt ::= LIMIT expr */
108073 {yygotominor.yy292.pLimit = yymsp[0].minor.yy118.pExpr; yygotominor.yy292.pOffset = 0;}
108074 break;
108075 case 165: /* limit_opt ::= LIMIT expr OFFSET expr */
108076 {yygotominor.yy292.pLimit = yymsp[-2].minor.yy118.pExpr; yygotominor.yy292.pOffset = yymsp[0].minor.yy118.pExpr;}
108077 break;
108078 case 166: /* limit_opt ::= LIMIT expr COMMA expr */
108079 {yygotominor.yy292.pOffset = yymsp[-2].minor.yy118.pExpr; yygotominor.yy292.pLimit = yymsp[0].minor.yy118.pExpr;}
108080 break;
108081 case 167: /* cmd ::= DELETE FROM fullname indexed_opt where_opt */
108083 sqlite3SrcListIndexedBy(pParse, yymsp[-2].minor.yy259, &yymsp[-1].minor.yy0);
108084 sqlite3DeleteFrom(pParse,yymsp[-2].minor.yy259,yymsp[0].minor.yy314);
108086 break;
108087 case 170: /* cmd ::= UPDATE orconf fullname indexed_opt SET setlist where_opt */
108089 sqlite3SrcListIndexedBy(pParse, yymsp[-4].minor.yy259, &yymsp[-3].minor.yy0);
108090 sqlite3ExprListCheckLength(pParse,yymsp[-1].minor.yy322,"set list");
108091 sqlite3Update(pParse,yymsp[-4].minor.yy259,yymsp[-1].minor.yy322,yymsp[0].minor.yy314,yymsp[-5].minor.yy210);
108093 break;
108094 case 171: /* setlist ::= setlist COMMA nm EQ expr */
108096 yygotominor.yy322 = sqlite3ExprListAppend(pParse, yymsp[-4].minor.yy322, yymsp[0].minor.yy118.pExpr);
108097 sqlite3ExprListSetName(pParse, yygotominor.yy322, &yymsp[-2].minor.yy0, 1);
108099 break;
108100 case 172: /* setlist ::= nm EQ expr */
108102 yygotominor.yy322 = sqlite3ExprListAppend(pParse, 0, yymsp[0].minor.yy118.pExpr);
108103 sqlite3ExprListSetName(pParse, yygotominor.yy322, &yymsp[-2].minor.yy0, 1);
108105 break;
108106 case 173: /* cmd ::= insert_cmd INTO fullname inscollist_opt VALUES LP itemlist RP */
108107 {sqlite3Insert(pParse, yymsp[-5].minor.yy259, yymsp[-1].minor.yy322, 0, yymsp[-4].minor.yy384, yymsp[-7].minor.yy210);}
108108 break;
108109 case 174: /* cmd ::= insert_cmd INTO fullname inscollist_opt select */
108110 {sqlite3Insert(pParse, yymsp[-2].minor.yy259, 0, yymsp[0].minor.yy387, yymsp[-1].minor.yy384, yymsp[-4].minor.yy210);}
108111 break;
108112 case 175: /* cmd ::= insert_cmd INTO fullname inscollist_opt DEFAULT VALUES */
108113 {sqlite3Insert(pParse, yymsp[-3].minor.yy259, 0, 0, yymsp[-2].minor.yy384, yymsp[-5].minor.yy210);}
108114 break;
108115 case 176: /* insert_cmd ::= INSERT orconf */
108116 {yygotominor.yy210 = yymsp[0].minor.yy210;}
108117 break;
108118 case 177: /* insert_cmd ::= REPLACE */
108119 {yygotominor.yy210 = OE_Replace;}
108120 break;
108121 case 178: /* itemlist ::= itemlist COMMA expr */
108122 case 241: /* nexprlist ::= nexprlist COMMA expr */ yytestcase(yyruleno==241);
108123 {yygotominor.yy322 = sqlite3ExprListAppend(pParse,yymsp[-2].minor.yy322,yymsp[0].minor.yy118.pExpr);}
108124 break;
108125 case 179: /* itemlist ::= expr */
108126 case 242: /* nexprlist ::= expr */ yytestcase(yyruleno==242);
108127 {yygotominor.yy322 = sqlite3ExprListAppend(pParse,0,yymsp[0].minor.yy118.pExpr);}
108128 break;
108129 case 182: /* inscollist ::= inscollist COMMA nm */
108130 {yygotominor.yy384 = sqlite3IdListAppend(pParse->db,yymsp[-2].minor.yy384,&yymsp[0].minor.yy0);}
108131 break;
108132 case 183: /* inscollist ::= nm */
108133 {yygotominor.yy384 = sqlite3IdListAppend(pParse->db,0,&yymsp[0].minor.yy0);}
108134 break;
108135 case 184: /* expr ::= term */
108136 {yygotominor.yy118 = yymsp[0].minor.yy118;}
108137 break;
108138 case 185: /* expr ::= LP expr RP */
108139 {yygotominor.yy118.pExpr = yymsp[-1].minor.yy118.pExpr; spanSet(&yygotominor.yy118,&yymsp[-2].minor.yy0,&yymsp[0].minor.yy0);}
108140 break;
108141 case 186: /* term ::= NULL */
108142 case 191: /* term ::= INTEGER|FLOAT|BLOB */ yytestcase(yyruleno==191);
108143 case 192: /* term ::= STRING */ yytestcase(yyruleno==192);
108144 {spanExpr(&yygotominor.yy118, pParse, yymsp[0].major, &yymsp[0].minor.yy0);}
108145 break;
108146 case 187: /* expr ::= id */
108147 case 188: /* expr ::= JOIN_KW */ yytestcase(yyruleno==188);
108148 {spanExpr(&yygotominor.yy118, pParse, TK_ID, &yymsp[0].minor.yy0);}
108149 break;
108150 case 189: /* expr ::= nm DOT nm */
108152 Expr *temp1 = sqlite3PExpr(pParse, TK_ID, 0, 0, &yymsp[-2].minor.yy0);
108153 Expr *temp2 = sqlite3PExpr(pParse, TK_ID, 0, 0, &yymsp[0].minor.yy0);
108154 yygotominor.yy118.pExpr = sqlite3PExpr(pParse, TK_DOT, temp1, temp2, 0);
108155 spanSet(&yygotominor.yy118,&yymsp[-2].minor.yy0,&yymsp[0].minor.yy0);
108157 break;
108158 case 190: /* expr ::= nm DOT nm DOT nm */
108160 Expr *temp1 = sqlite3PExpr(pParse, TK_ID, 0, 0, &yymsp[-4].minor.yy0);
108161 Expr *temp2 = sqlite3PExpr(pParse, TK_ID, 0, 0, &yymsp[-2].minor.yy0);
108162 Expr *temp3 = sqlite3PExpr(pParse, TK_ID, 0, 0, &yymsp[0].minor.yy0);
108163 Expr *temp4 = sqlite3PExpr(pParse, TK_DOT, temp2, temp3, 0);
108164 yygotominor.yy118.pExpr = sqlite3PExpr(pParse, TK_DOT, temp1, temp4, 0);
108165 spanSet(&yygotominor.yy118,&yymsp[-4].minor.yy0,&yymsp[0].minor.yy0);
108167 break;
108168 case 193: /* expr ::= REGISTER */
108170 /* When doing a nested parse, one can include terms in an expression
108171 ** that look like this: #1 #2 ... These terms refer to registers
108172 ** in the virtual machine. #N is the N-th register. */
108173 if( pParse->nested==0 ){
108174 sqlite3ErrorMsg(pParse, "near \"%T\": syntax error", &yymsp[0].minor.yy0);
108175 yygotominor.yy118.pExpr = 0;
108176 }else{
108177 yygotominor.yy118.pExpr = sqlite3PExpr(pParse, TK_REGISTER, 0, 0, &yymsp[0].minor.yy0);
108178 if( yygotominor.yy118.pExpr ) sqlite3GetInt32(&yymsp[0].minor.yy0.z[1], &yygotominor.yy118.pExpr->iTable);
108180 spanSet(&yygotominor.yy118, &yymsp[0].minor.yy0, &yymsp[0].minor.yy0);
108182 break;
108183 case 194: /* expr ::= VARIABLE */
108185 spanExpr(&yygotominor.yy118, pParse, TK_VARIABLE, &yymsp[0].minor.yy0);
108186 sqlite3ExprAssignVarNumber(pParse, yygotominor.yy118.pExpr);
108187 spanSet(&yygotominor.yy118, &yymsp[0].minor.yy0, &yymsp[0].minor.yy0);
108189 break;
108190 case 195: /* expr ::= expr COLLATE ids */
108192 yygotominor.yy118.pExpr = sqlite3ExprSetCollByToken(pParse, yymsp[-2].minor.yy118.pExpr, &yymsp[0].minor.yy0);
108193 yygotominor.yy118.zStart = yymsp[-2].minor.yy118.zStart;
108194 yygotominor.yy118.zEnd = &yymsp[0].minor.yy0.z[yymsp[0].minor.yy0.n];
108196 break;
108197 case 196: /* expr ::= CAST LP expr AS typetoken RP */
108199 yygotominor.yy118.pExpr = sqlite3PExpr(pParse, TK_CAST, yymsp[-3].minor.yy118.pExpr, 0, &yymsp[-1].minor.yy0);
108200 spanSet(&yygotominor.yy118,&yymsp[-5].minor.yy0,&yymsp[0].minor.yy0);
108202 break;
108203 case 197: /* expr ::= ID LP distinct exprlist RP */
108205 if( yymsp[-1].minor.yy322 && yymsp[-1].minor.yy322->nExpr>pParse->db->aLimit[SQLITE_LIMIT_FUNCTION_ARG] ){
108206 sqlite3ErrorMsg(pParse, "too many arguments on function %T", &yymsp[-4].minor.yy0);
108208 yygotominor.yy118.pExpr = sqlite3ExprFunction(pParse, yymsp[-1].minor.yy322, &yymsp[-4].minor.yy0);
108209 spanSet(&yygotominor.yy118,&yymsp[-4].minor.yy0,&yymsp[0].minor.yy0);
108210 if( yymsp[-2].minor.yy4 && yygotominor.yy118.pExpr ){
108211 yygotominor.yy118.pExpr->flags |= EP_Distinct;
108214 break;
108215 case 198: /* expr ::= ID LP STAR RP */
108217 yygotominor.yy118.pExpr = sqlite3ExprFunction(pParse, 0, &yymsp[-3].minor.yy0);
108218 spanSet(&yygotominor.yy118,&yymsp[-3].minor.yy0,&yymsp[0].minor.yy0);
108220 break;
108221 case 199: /* term ::= CTIME_KW */
108223 /* The CURRENT_TIME, CURRENT_DATE, and CURRENT_TIMESTAMP values are
108224 ** treated as functions that return constants */
108225 yygotominor.yy118.pExpr = sqlite3ExprFunction(pParse, 0,&yymsp[0].minor.yy0);
108226 if( yygotominor.yy118.pExpr ){
108227 yygotominor.yy118.pExpr->op = TK_CONST_FUNC;
108229 spanSet(&yygotominor.yy118, &yymsp[0].minor.yy0, &yymsp[0].minor.yy0);
108231 break;
108232 case 200: /* expr ::= expr AND expr */
108233 case 201: /* expr ::= expr OR expr */ yytestcase(yyruleno==201);
108234 case 202: /* expr ::= expr LT|GT|GE|LE expr */ yytestcase(yyruleno==202);
108235 case 203: /* expr ::= expr EQ|NE expr */ yytestcase(yyruleno==203);
108236 case 204: /* expr ::= expr BITAND|BITOR|LSHIFT|RSHIFT expr */ yytestcase(yyruleno==204);
108237 case 205: /* expr ::= expr PLUS|MINUS expr */ yytestcase(yyruleno==205);
108238 case 206: /* expr ::= expr STAR|SLASH|REM expr */ yytestcase(yyruleno==206);
108239 case 207: /* expr ::= expr CONCAT expr */ yytestcase(yyruleno==207);
108240 {spanBinaryExpr(&yygotominor.yy118,pParse,yymsp[-1].major,&yymsp[-2].minor.yy118,&yymsp[0].minor.yy118);}
108241 break;
108242 case 208: /* likeop ::= LIKE_KW */
108243 case 210: /* likeop ::= MATCH */ yytestcase(yyruleno==210);
108244 {yygotominor.yy342.eOperator = yymsp[0].minor.yy0; yygotominor.yy342.not = 0;}
108245 break;
108246 case 209: /* likeop ::= NOT LIKE_KW */
108247 case 211: /* likeop ::= NOT MATCH */ yytestcase(yyruleno==211);
108248 {yygotominor.yy342.eOperator = yymsp[0].minor.yy0; yygotominor.yy342.not = 1;}
108249 break;
108250 case 212: /* expr ::= expr likeop expr */
108252 ExprList *pList;
108253 pList = sqlite3ExprListAppend(pParse,0, yymsp[0].minor.yy118.pExpr);
108254 pList = sqlite3ExprListAppend(pParse,pList, yymsp[-2].minor.yy118.pExpr);
108255 yygotominor.yy118.pExpr = sqlite3ExprFunction(pParse, pList, &yymsp[-1].minor.yy342.eOperator);
108256 if( yymsp[-1].minor.yy342.not ) yygotominor.yy118.pExpr = sqlite3PExpr(pParse, TK_NOT, yygotominor.yy118.pExpr, 0, 0);
108257 yygotominor.yy118.zStart = yymsp[-2].minor.yy118.zStart;
108258 yygotominor.yy118.zEnd = yymsp[0].minor.yy118.zEnd;
108259 if( yygotominor.yy118.pExpr ) yygotominor.yy118.pExpr->flags |= EP_InfixFunc;
108261 break;
108262 case 213: /* expr ::= expr likeop expr ESCAPE expr */
108264 ExprList *pList;
108265 pList = sqlite3ExprListAppend(pParse,0, yymsp[-2].minor.yy118.pExpr);
108266 pList = sqlite3ExprListAppend(pParse,pList, yymsp[-4].minor.yy118.pExpr);
108267 pList = sqlite3ExprListAppend(pParse,pList, yymsp[0].minor.yy118.pExpr);
108268 yygotominor.yy118.pExpr = sqlite3ExprFunction(pParse, pList, &yymsp[-3].minor.yy342.eOperator);
108269 if( yymsp[-3].minor.yy342.not ) yygotominor.yy118.pExpr = sqlite3PExpr(pParse, TK_NOT, yygotominor.yy118.pExpr, 0, 0);
108270 yygotominor.yy118.zStart = yymsp[-4].minor.yy118.zStart;
108271 yygotominor.yy118.zEnd = yymsp[0].minor.yy118.zEnd;
108272 if( yygotominor.yy118.pExpr ) yygotominor.yy118.pExpr->flags |= EP_InfixFunc;
108274 break;
108275 case 214: /* expr ::= expr ISNULL|NOTNULL */
108276 {spanUnaryPostfix(&yygotominor.yy118,pParse,yymsp[0].major,&yymsp[-1].minor.yy118,&yymsp[0].minor.yy0);}
108277 break;
108278 case 215: /* expr ::= expr NOT NULL */
108279 {spanUnaryPostfix(&yygotominor.yy118,pParse,TK_NOTNULL,&yymsp[-2].minor.yy118,&yymsp[0].minor.yy0);}
108280 break;
108281 case 216: /* expr ::= expr IS expr */
108283 spanBinaryExpr(&yygotominor.yy118,pParse,TK_IS,&yymsp[-2].minor.yy118,&yymsp[0].minor.yy118);
108284 binaryToUnaryIfNull(pParse, yymsp[0].minor.yy118.pExpr, yygotominor.yy118.pExpr, TK_ISNULL);
108286 break;
108287 case 217: /* expr ::= expr IS NOT expr */
108289 spanBinaryExpr(&yygotominor.yy118,pParse,TK_ISNOT,&yymsp[-3].minor.yy118,&yymsp[0].minor.yy118);
108290 binaryToUnaryIfNull(pParse, yymsp[0].minor.yy118.pExpr, yygotominor.yy118.pExpr, TK_NOTNULL);
108292 break;
108293 case 218: /* expr ::= NOT expr */
108294 case 219: /* expr ::= BITNOT expr */ yytestcase(yyruleno==219);
108295 {spanUnaryPrefix(&yygotominor.yy118,pParse,yymsp[-1].major,&yymsp[0].minor.yy118,&yymsp[-1].minor.yy0);}
108296 break;
108297 case 220: /* expr ::= MINUS expr */
108298 {spanUnaryPrefix(&yygotominor.yy118,pParse,TK_UMINUS,&yymsp[0].minor.yy118,&yymsp[-1].minor.yy0);}
108299 break;
108300 case 221: /* expr ::= PLUS expr */
108301 {spanUnaryPrefix(&yygotominor.yy118,pParse,TK_UPLUS,&yymsp[0].minor.yy118,&yymsp[-1].minor.yy0);}
108302 break;
108303 case 224: /* expr ::= expr between_op expr AND expr */
108305 ExprList *pList = sqlite3ExprListAppend(pParse,0, yymsp[-2].minor.yy118.pExpr);
108306 pList = sqlite3ExprListAppend(pParse,pList, yymsp[0].minor.yy118.pExpr);
108307 yygotominor.yy118.pExpr = sqlite3PExpr(pParse, TK_BETWEEN, yymsp[-4].minor.yy118.pExpr, 0, 0);
108308 if( yygotominor.yy118.pExpr ){
108309 yygotominor.yy118.pExpr->x.pList = pList;
108310 }else{
108311 sqlite3ExprListDelete(pParse->db, pList);
108313 if( yymsp[-3].minor.yy4 ) yygotominor.yy118.pExpr = sqlite3PExpr(pParse, TK_NOT, yygotominor.yy118.pExpr, 0, 0);
108314 yygotominor.yy118.zStart = yymsp[-4].minor.yy118.zStart;
108315 yygotominor.yy118.zEnd = yymsp[0].minor.yy118.zEnd;
108317 break;
108318 case 227: /* expr ::= expr in_op LP exprlist RP */
108320 if( yymsp[-1].minor.yy322==0 ){
108321 /* Expressions of the form
108323 ** expr1 IN ()
108324 ** expr1 NOT IN ()
108326 ** simplify to constants 0 (false) and 1 (true), respectively,
108327 ** regardless of the value of expr1.
108329 yygotominor.yy118.pExpr = sqlite3PExpr(pParse, TK_INTEGER, 0, 0, &sqlite3IntTokens[yymsp[-3].minor.yy4]);
108330 sqlite3ExprDelete(pParse->db, yymsp[-4].minor.yy118.pExpr);
108331 }else{
108332 yygotominor.yy118.pExpr = sqlite3PExpr(pParse, TK_IN, yymsp[-4].minor.yy118.pExpr, 0, 0);
108333 if( yygotominor.yy118.pExpr ){
108334 yygotominor.yy118.pExpr->x.pList = yymsp[-1].minor.yy322;
108335 sqlite3ExprSetHeight(pParse, yygotominor.yy118.pExpr);
108336 }else{
108337 sqlite3ExprListDelete(pParse->db, yymsp[-1].minor.yy322);
108339 if( yymsp[-3].minor.yy4 ) yygotominor.yy118.pExpr = sqlite3PExpr(pParse, TK_NOT, yygotominor.yy118.pExpr, 0, 0);
108341 yygotominor.yy118.zStart = yymsp[-4].minor.yy118.zStart;
108342 yygotominor.yy118.zEnd = &yymsp[0].minor.yy0.z[yymsp[0].minor.yy0.n];
108344 break;
108345 case 228: /* expr ::= LP select RP */
108347 yygotominor.yy118.pExpr = sqlite3PExpr(pParse, TK_SELECT, 0, 0, 0);
108348 if( yygotominor.yy118.pExpr ){
108349 yygotominor.yy118.pExpr->x.pSelect = yymsp[-1].minor.yy387;
108350 ExprSetProperty(yygotominor.yy118.pExpr, EP_xIsSelect);
108351 sqlite3ExprSetHeight(pParse, yygotominor.yy118.pExpr);
108352 }else{
108353 sqlite3SelectDelete(pParse->db, yymsp[-1].minor.yy387);
108355 yygotominor.yy118.zStart = yymsp[-2].minor.yy0.z;
108356 yygotominor.yy118.zEnd = &yymsp[0].minor.yy0.z[yymsp[0].minor.yy0.n];
108358 break;
108359 case 229: /* expr ::= expr in_op LP select RP */
108361 yygotominor.yy118.pExpr = sqlite3PExpr(pParse, TK_IN, yymsp[-4].minor.yy118.pExpr, 0, 0);
108362 if( yygotominor.yy118.pExpr ){
108363 yygotominor.yy118.pExpr->x.pSelect = yymsp[-1].minor.yy387;
108364 ExprSetProperty(yygotominor.yy118.pExpr, EP_xIsSelect);
108365 sqlite3ExprSetHeight(pParse, yygotominor.yy118.pExpr);
108366 }else{
108367 sqlite3SelectDelete(pParse->db, yymsp[-1].minor.yy387);
108369 if( yymsp[-3].minor.yy4 ) yygotominor.yy118.pExpr = sqlite3PExpr(pParse, TK_NOT, yygotominor.yy118.pExpr, 0, 0);
108370 yygotominor.yy118.zStart = yymsp[-4].minor.yy118.zStart;
108371 yygotominor.yy118.zEnd = &yymsp[0].minor.yy0.z[yymsp[0].minor.yy0.n];
108373 break;
108374 case 230: /* expr ::= expr in_op nm dbnm */
108376 SrcList *pSrc = sqlite3SrcListAppend(pParse->db, 0,&yymsp[-1].minor.yy0,&yymsp[0].minor.yy0);
108377 yygotominor.yy118.pExpr = sqlite3PExpr(pParse, TK_IN, yymsp[-3].minor.yy118.pExpr, 0, 0);
108378 if( yygotominor.yy118.pExpr ){
108379 yygotominor.yy118.pExpr->x.pSelect = sqlite3SelectNew(pParse, 0,pSrc,0,0,0,0,0,0,0);
108380 ExprSetProperty(yygotominor.yy118.pExpr, EP_xIsSelect);
108381 sqlite3ExprSetHeight(pParse, yygotominor.yy118.pExpr);
108382 }else{
108383 sqlite3SrcListDelete(pParse->db, pSrc);
108385 if( yymsp[-2].minor.yy4 ) yygotominor.yy118.pExpr = sqlite3PExpr(pParse, TK_NOT, yygotominor.yy118.pExpr, 0, 0);
108386 yygotominor.yy118.zStart = yymsp[-3].minor.yy118.zStart;
108387 yygotominor.yy118.zEnd = yymsp[0].minor.yy0.z ? &yymsp[0].minor.yy0.z[yymsp[0].minor.yy0.n] : &yymsp[-1].minor.yy0.z[yymsp[-1].minor.yy0.n];
108389 break;
108390 case 231: /* expr ::= EXISTS LP select RP */
108392 Expr *p = yygotominor.yy118.pExpr = sqlite3PExpr(pParse, TK_EXISTS, 0, 0, 0);
108393 if( p ){
108394 p->x.pSelect = yymsp[-1].minor.yy387;
108395 ExprSetProperty(p, EP_xIsSelect);
108396 sqlite3ExprSetHeight(pParse, p);
108397 }else{
108398 sqlite3SelectDelete(pParse->db, yymsp[-1].minor.yy387);
108400 yygotominor.yy118.zStart = yymsp[-3].minor.yy0.z;
108401 yygotominor.yy118.zEnd = &yymsp[0].minor.yy0.z[yymsp[0].minor.yy0.n];
108403 break;
108404 case 232: /* expr ::= CASE case_operand case_exprlist case_else END */
108406 yygotominor.yy118.pExpr = sqlite3PExpr(pParse, TK_CASE, yymsp[-3].minor.yy314, yymsp[-1].minor.yy314, 0);
108407 if( yygotominor.yy118.pExpr ){
108408 yygotominor.yy118.pExpr->x.pList = yymsp[-2].minor.yy322;
108409 sqlite3ExprSetHeight(pParse, yygotominor.yy118.pExpr);
108410 }else{
108411 sqlite3ExprListDelete(pParse->db, yymsp[-2].minor.yy322);
108413 yygotominor.yy118.zStart = yymsp[-4].minor.yy0.z;
108414 yygotominor.yy118.zEnd = &yymsp[0].minor.yy0.z[yymsp[0].minor.yy0.n];
108416 break;
108417 case 233: /* case_exprlist ::= case_exprlist WHEN expr THEN expr */
108419 yygotominor.yy322 = sqlite3ExprListAppend(pParse,yymsp[-4].minor.yy322, yymsp[-2].minor.yy118.pExpr);
108420 yygotominor.yy322 = sqlite3ExprListAppend(pParse,yygotominor.yy322, yymsp[0].minor.yy118.pExpr);
108422 break;
108423 case 234: /* case_exprlist ::= WHEN expr THEN expr */
108425 yygotominor.yy322 = sqlite3ExprListAppend(pParse,0, yymsp[-2].minor.yy118.pExpr);
108426 yygotominor.yy322 = sqlite3ExprListAppend(pParse,yygotominor.yy322, yymsp[0].minor.yy118.pExpr);
108428 break;
108429 case 243: /* cmd ::= createkw uniqueflag INDEX ifnotexists nm dbnm ON nm LP idxlist RP */
108431 sqlite3CreateIndex(pParse, &yymsp[-6].minor.yy0, &yymsp[-5].minor.yy0,
108432 sqlite3SrcListAppend(pParse->db,0,&yymsp[-3].minor.yy0,0), yymsp[-1].minor.yy322, yymsp[-9].minor.yy4,
108433 &yymsp[-10].minor.yy0, &yymsp[0].minor.yy0, SQLITE_SO_ASC, yymsp[-7].minor.yy4);
108435 break;
108436 case 244: /* uniqueflag ::= UNIQUE */
108437 case 298: /* raisetype ::= ABORT */ yytestcase(yyruleno==298);
108438 {yygotominor.yy4 = OE_Abort;}
108439 break;
108440 case 245: /* uniqueflag ::= */
108441 {yygotominor.yy4 = OE_None;}
108442 break;
108443 case 248: /* idxlist ::= idxlist COMMA nm collate sortorder */
108445 Expr *p = 0;
108446 if( yymsp[-1].minor.yy0.n>0 ){
108447 p = sqlite3Expr(pParse->db, TK_COLUMN, 0);
108448 sqlite3ExprSetCollByToken(pParse, p, &yymsp[-1].minor.yy0);
108450 yygotominor.yy322 = sqlite3ExprListAppend(pParse,yymsp[-4].minor.yy322, p);
108451 sqlite3ExprListSetName(pParse,yygotominor.yy322,&yymsp[-2].minor.yy0,1);
108452 sqlite3ExprListCheckLength(pParse, yygotominor.yy322, "index");
108453 if( yygotominor.yy322 ) yygotominor.yy322->a[yygotominor.yy322->nExpr-1].sortOrder = (u8)yymsp[0].minor.yy4;
108455 break;
108456 case 249: /* idxlist ::= nm collate sortorder */
108458 Expr *p = 0;
108459 if( yymsp[-1].minor.yy0.n>0 ){
108460 p = sqlite3PExpr(pParse, TK_COLUMN, 0, 0, 0);
108461 sqlite3ExprSetCollByToken(pParse, p, &yymsp[-1].minor.yy0);
108463 yygotominor.yy322 = sqlite3ExprListAppend(pParse,0, p);
108464 sqlite3ExprListSetName(pParse, yygotominor.yy322, &yymsp[-2].minor.yy0, 1);
108465 sqlite3ExprListCheckLength(pParse, yygotominor.yy322, "index");
108466 if( yygotominor.yy322 ) yygotominor.yy322->a[yygotominor.yy322->nExpr-1].sortOrder = (u8)yymsp[0].minor.yy4;
108468 break;
108469 case 250: /* collate ::= */
108470 {yygotominor.yy0.z = 0; yygotominor.yy0.n = 0;}
108471 break;
108472 case 252: /* cmd ::= DROP INDEX ifexists fullname */
108473 {sqlite3DropIndex(pParse, yymsp[0].minor.yy259, yymsp[-1].minor.yy4);}
108474 break;
108475 case 253: /* cmd ::= VACUUM */
108476 case 254: /* cmd ::= VACUUM nm */ yytestcase(yyruleno==254);
108477 {sqlite3Vacuum(pParse);}
108478 break;
108479 case 255: /* cmd ::= PRAGMA nm dbnm */
108480 {sqlite3Pragma(pParse,&yymsp[-1].minor.yy0,&yymsp[0].minor.yy0,0,0);}
108481 break;
108482 case 256: /* cmd ::= PRAGMA nm dbnm EQ nmnum */
108483 {sqlite3Pragma(pParse,&yymsp[-3].minor.yy0,&yymsp[-2].minor.yy0,&yymsp[0].minor.yy0,0);}
108484 break;
108485 case 257: /* cmd ::= PRAGMA nm dbnm LP nmnum RP */
108486 {sqlite3Pragma(pParse,&yymsp[-4].minor.yy0,&yymsp[-3].minor.yy0,&yymsp[-1].minor.yy0,0);}
108487 break;
108488 case 258: /* cmd ::= PRAGMA nm dbnm EQ minus_num */
108489 {sqlite3Pragma(pParse,&yymsp[-3].minor.yy0,&yymsp[-2].minor.yy0,&yymsp[0].minor.yy0,1);}
108490 break;
108491 case 259: /* cmd ::= PRAGMA nm dbnm LP minus_num RP */
108492 {sqlite3Pragma(pParse,&yymsp[-4].minor.yy0,&yymsp[-3].minor.yy0,&yymsp[-1].minor.yy0,1);}
108493 break;
108494 case 270: /* cmd ::= createkw trigger_decl BEGIN trigger_cmd_list END */
108496 Token all;
108497 all.z = yymsp[-3].minor.yy0.z;
108498 all.n = (int)(yymsp[0].minor.yy0.z - yymsp[-3].minor.yy0.z) + yymsp[0].minor.yy0.n;
108499 sqlite3FinishTrigger(pParse, yymsp[-1].minor.yy203, &all);
108501 break;
108502 case 271: /* trigger_decl ::= temp TRIGGER ifnotexists nm dbnm trigger_time trigger_event ON fullname foreach_clause when_clause */
108504 sqlite3BeginTrigger(pParse, &yymsp[-7].minor.yy0, &yymsp[-6].minor.yy0, yymsp[-5].minor.yy4, yymsp[-4].minor.yy90.a, yymsp[-4].minor.yy90.b, yymsp[-2].minor.yy259, yymsp[0].minor.yy314, yymsp[-10].minor.yy4, yymsp[-8].minor.yy4);
108505 yygotominor.yy0 = (yymsp[-6].minor.yy0.n==0?yymsp[-7].minor.yy0:yymsp[-6].minor.yy0);
108507 break;
108508 case 272: /* trigger_time ::= BEFORE */
108509 case 275: /* trigger_time ::= */ yytestcase(yyruleno==275);
108510 { yygotominor.yy4 = TK_BEFORE; }
108511 break;
108512 case 273: /* trigger_time ::= AFTER */
108513 { yygotominor.yy4 = TK_AFTER; }
108514 break;
108515 case 274: /* trigger_time ::= INSTEAD OF */
108516 { yygotominor.yy4 = TK_INSTEAD;}
108517 break;
108518 case 276: /* trigger_event ::= DELETE|INSERT */
108519 case 277: /* trigger_event ::= UPDATE */ yytestcase(yyruleno==277);
108520 {yygotominor.yy90.a = yymsp[0].major; yygotominor.yy90.b = 0;}
108521 break;
108522 case 278: /* trigger_event ::= UPDATE OF inscollist */
108523 {yygotominor.yy90.a = TK_UPDATE; yygotominor.yy90.b = yymsp[0].minor.yy384;}
108524 break;
108525 case 281: /* when_clause ::= */
108526 case 303: /* key_opt ::= */ yytestcase(yyruleno==303);
108527 { yygotominor.yy314 = 0; }
108528 break;
108529 case 282: /* when_clause ::= WHEN expr */
108530 case 304: /* key_opt ::= KEY expr */ yytestcase(yyruleno==304);
108531 { yygotominor.yy314 = yymsp[0].minor.yy118.pExpr; }
108532 break;
108533 case 283: /* trigger_cmd_list ::= trigger_cmd_list trigger_cmd SEMI */
108535 assert( yymsp[-2].minor.yy203!=0 );
108536 yymsp[-2].minor.yy203->pLast->pNext = yymsp[-1].minor.yy203;
108537 yymsp[-2].minor.yy203->pLast = yymsp[-1].minor.yy203;
108538 yygotominor.yy203 = yymsp[-2].minor.yy203;
108540 break;
108541 case 284: /* trigger_cmd_list ::= trigger_cmd SEMI */
108543 assert( yymsp[-1].minor.yy203!=0 );
108544 yymsp[-1].minor.yy203->pLast = yymsp[-1].minor.yy203;
108545 yygotominor.yy203 = yymsp[-1].minor.yy203;
108547 break;
108548 case 286: /* trnm ::= nm DOT nm */
108550 yygotominor.yy0 = yymsp[0].minor.yy0;
108551 sqlite3ErrorMsg(pParse,
108552 "qualified table names are not allowed on INSERT, UPDATE, and DELETE "
108553 "statements within triggers");
108555 break;
108556 case 288: /* tridxby ::= INDEXED BY nm */
108558 sqlite3ErrorMsg(pParse,
108559 "the INDEXED BY clause is not allowed on UPDATE or DELETE statements "
108560 "within triggers");
108562 break;
108563 case 289: /* tridxby ::= NOT INDEXED */
108565 sqlite3ErrorMsg(pParse,
108566 "the NOT INDEXED clause is not allowed on UPDATE or DELETE statements "
108567 "within triggers");
108569 break;
108570 case 290: /* trigger_cmd ::= UPDATE orconf trnm tridxby SET setlist where_opt */
108571 { yygotominor.yy203 = sqlite3TriggerUpdateStep(pParse->db, &yymsp[-4].minor.yy0, yymsp[-1].minor.yy322, yymsp[0].minor.yy314, yymsp[-5].minor.yy210); }
108572 break;
108573 case 291: /* trigger_cmd ::= insert_cmd INTO trnm inscollist_opt VALUES LP itemlist RP */
108574 {yygotominor.yy203 = sqlite3TriggerInsertStep(pParse->db, &yymsp[-5].minor.yy0, yymsp[-4].minor.yy384, yymsp[-1].minor.yy322, 0, yymsp[-7].minor.yy210);}
108575 break;
108576 case 292: /* trigger_cmd ::= insert_cmd INTO trnm inscollist_opt select */
108577 {yygotominor.yy203 = sqlite3TriggerInsertStep(pParse->db, &yymsp[-2].minor.yy0, yymsp[-1].minor.yy384, 0, yymsp[0].minor.yy387, yymsp[-4].minor.yy210);}
108578 break;
108579 case 293: /* trigger_cmd ::= DELETE FROM trnm tridxby where_opt */
108580 {yygotominor.yy203 = sqlite3TriggerDeleteStep(pParse->db, &yymsp[-2].minor.yy0, yymsp[0].minor.yy314);}
108581 break;
108582 case 294: /* trigger_cmd ::= select */
108583 {yygotominor.yy203 = sqlite3TriggerSelectStep(pParse->db, yymsp[0].minor.yy387); }
108584 break;
108585 case 295: /* expr ::= RAISE LP IGNORE RP */
108587 yygotominor.yy118.pExpr = sqlite3PExpr(pParse, TK_RAISE, 0, 0, 0);
108588 if( yygotominor.yy118.pExpr ){
108589 yygotominor.yy118.pExpr->affinity = OE_Ignore;
108591 yygotominor.yy118.zStart = yymsp[-3].minor.yy0.z;
108592 yygotominor.yy118.zEnd = &yymsp[0].minor.yy0.z[yymsp[0].minor.yy0.n];
108594 break;
108595 case 296: /* expr ::= RAISE LP raisetype COMMA nm RP */
108597 yygotominor.yy118.pExpr = sqlite3PExpr(pParse, TK_RAISE, 0, 0, &yymsp[-1].minor.yy0);
108598 if( yygotominor.yy118.pExpr ) {
108599 yygotominor.yy118.pExpr->affinity = (char)yymsp[-3].minor.yy4;
108601 yygotominor.yy118.zStart = yymsp[-5].minor.yy0.z;
108602 yygotominor.yy118.zEnd = &yymsp[0].minor.yy0.z[yymsp[0].minor.yy0.n];
108604 break;
108605 case 297: /* raisetype ::= ROLLBACK */
108606 {yygotominor.yy4 = OE_Rollback;}
108607 break;
108608 case 299: /* raisetype ::= FAIL */
108609 {yygotominor.yy4 = OE_Fail;}
108610 break;
108611 case 300: /* cmd ::= DROP TRIGGER ifexists fullname */
108613 sqlite3DropTrigger(pParse,yymsp[0].minor.yy259,yymsp[-1].minor.yy4);
108615 break;
108616 case 301: /* cmd ::= ATTACH database_kw_opt expr AS expr key_opt */
108618 sqlite3Attach(pParse, yymsp[-3].minor.yy118.pExpr, yymsp[-1].minor.yy118.pExpr, yymsp[0].minor.yy314);
108620 break;
108621 case 302: /* cmd ::= DETACH database_kw_opt expr */
108623 sqlite3Detach(pParse, yymsp[0].minor.yy118.pExpr);
108625 break;
108626 case 307: /* cmd ::= REINDEX */
108627 {sqlite3Reindex(pParse, 0, 0);}
108628 break;
108629 case 308: /* cmd ::= REINDEX nm dbnm */
108630 {sqlite3Reindex(pParse, &yymsp[-1].minor.yy0, &yymsp[0].minor.yy0);}
108631 break;
108632 case 309: /* cmd ::= ANALYZE */
108633 {sqlite3Analyze(pParse, 0, 0);}
108634 break;
108635 case 310: /* cmd ::= ANALYZE nm dbnm */
108636 {sqlite3Analyze(pParse, &yymsp[-1].minor.yy0, &yymsp[0].minor.yy0);}
108637 break;
108638 case 311: /* cmd ::= ALTER TABLE fullname RENAME TO nm */
108640 sqlite3AlterRenameTable(pParse,yymsp[-3].minor.yy259,&yymsp[0].minor.yy0);
108642 break;
108643 case 312: /* cmd ::= ALTER TABLE add_column_fullname ADD kwcolumn_opt column */
108645 sqlite3AlterFinishAddColumn(pParse, &yymsp[0].minor.yy0);
108647 break;
108648 case 313: /* add_column_fullname ::= fullname */
108650 pParse->db->lookaside.bEnabled = 0;
108651 sqlite3AlterBeginAddColumn(pParse, yymsp[0].minor.yy259);
108653 break;
108654 case 316: /* cmd ::= create_vtab */
108655 {sqlite3VtabFinishParse(pParse,0);}
108656 break;
108657 case 317: /* cmd ::= create_vtab LP vtabarglist RP */
108658 {sqlite3VtabFinishParse(pParse,&yymsp[0].minor.yy0);}
108659 break;
108660 case 318: /* create_vtab ::= createkw VIRTUAL TABLE nm dbnm USING nm */
108662 sqlite3VtabBeginParse(pParse, &yymsp[-3].minor.yy0, &yymsp[-2].minor.yy0, &yymsp[0].minor.yy0);
108664 break;
108665 case 321: /* vtabarg ::= */
108666 {sqlite3VtabArgInit(pParse);}
108667 break;
108668 case 323: /* vtabargtoken ::= ANY */
108669 case 324: /* vtabargtoken ::= lp anylist RP */ yytestcase(yyruleno==324);
108670 case 325: /* lp ::= LP */ yytestcase(yyruleno==325);
108671 {sqlite3VtabArgExtend(pParse,&yymsp[0].minor.yy0);}
108672 break;
108673 default:
108674 /* (0) input ::= cmdlist */ yytestcase(yyruleno==0);
108675 /* (1) cmdlist ::= cmdlist ecmd */ yytestcase(yyruleno==1);
108676 /* (2) cmdlist ::= ecmd */ yytestcase(yyruleno==2);
108677 /* (3) ecmd ::= SEMI */ yytestcase(yyruleno==3);
108678 /* (4) ecmd ::= explain cmdx SEMI */ yytestcase(yyruleno==4);
108679 /* (10) trans_opt ::= */ yytestcase(yyruleno==10);
108680 /* (11) trans_opt ::= TRANSACTION */ yytestcase(yyruleno==11);
108681 /* (12) trans_opt ::= TRANSACTION nm */ yytestcase(yyruleno==12);
108682 /* (20) savepoint_opt ::= SAVEPOINT */ yytestcase(yyruleno==20);
108683 /* (21) savepoint_opt ::= */ yytestcase(yyruleno==21);
108684 /* (25) cmd ::= create_table create_table_args */ yytestcase(yyruleno==25);
108685 /* (34) columnlist ::= columnlist COMMA column */ yytestcase(yyruleno==34);
108686 /* (35) columnlist ::= column */ yytestcase(yyruleno==35);
108687 /* (44) type ::= */ yytestcase(yyruleno==44);
108688 /* (51) signed ::= plus_num */ yytestcase(yyruleno==51);
108689 /* (52) signed ::= minus_num */ yytestcase(yyruleno==52);
108690 /* (53) carglist ::= carglist carg */ yytestcase(yyruleno==53);
108691 /* (54) carglist ::= */ yytestcase(yyruleno==54);
108692 /* (55) carg ::= CONSTRAINT nm ccons */ yytestcase(yyruleno==55);
108693 /* (56) carg ::= ccons */ yytestcase(yyruleno==56);
108694 /* (62) ccons ::= NULL onconf */ yytestcase(yyruleno==62);
108695 /* (90) conslist ::= conslist COMMA tcons */ yytestcase(yyruleno==90);
108696 /* (91) conslist ::= conslist tcons */ yytestcase(yyruleno==91);
108697 /* (92) conslist ::= tcons */ yytestcase(yyruleno==92);
108698 /* (93) tcons ::= CONSTRAINT nm */ yytestcase(yyruleno==93);
108699 /* (268) plus_opt ::= PLUS */ yytestcase(yyruleno==268);
108700 /* (269) plus_opt ::= */ yytestcase(yyruleno==269);
108701 /* (279) foreach_clause ::= */ yytestcase(yyruleno==279);
108702 /* (280) foreach_clause ::= FOR EACH ROW */ yytestcase(yyruleno==280);
108703 /* (287) tridxby ::= */ yytestcase(yyruleno==287);
108704 /* (305) database_kw_opt ::= DATABASE */ yytestcase(yyruleno==305);
108705 /* (306) database_kw_opt ::= */ yytestcase(yyruleno==306);
108706 /* (314) kwcolumn_opt ::= */ yytestcase(yyruleno==314);
108707 /* (315) kwcolumn_opt ::= COLUMNKW */ yytestcase(yyruleno==315);
108708 /* (319) vtabarglist ::= vtabarg */ yytestcase(yyruleno==319);
108709 /* (320) vtabarglist ::= vtabarglist COMMA vtabarg */ yytestcase(yyruleno==320);
108710 /* (322) vtabarg ::= vtabarg vtabargtoken */ yytestcase(yyruleno==322);
108711 /* (326) anylist ::= */ yytestcase(yyruleno==326);
108712 /* (327) anylist ::= anylist LP anylist RP */ yytestcase(yyruleno==327);
108713 /* (328) anylist ::= anylist ANY */ yytestcase(yyruleno==328);
108714 break;
108716 yygoto = yyRuleInfo[yyruleno].lhs;
108717 yysize = yyRuleInfo[yyruleno].nrhs;
108718 yypParser->yyidx -= yysize;
108719 yyact = yy_find_reduce_action(yymsp[-yysize].stateno,(YYCODETYPE)yygoto);
108720 if( yyact < YYNSTATE ){
108721 #ifdef NDEBUG
108722 /* If we are not debugging and the reduce action popped at least
108723 ** one element off the stack, then we can push the new element back
108724 ** onto the stack here, and skip the stack overflow test in yy_shift().
108725 ** That gives a significant speed improvement. */
108726 if( yysize ){
108727 yypParser->yyidx++;
108728 yymsp -= yysize-1;
108729 yymsp->stateno = (YYACTIONTYPE)yyact;
108730 yymsp->major = (YYCODETYPE)yygoto;
108731 yymsp->minor = yygotominor;
108732 }else
108733 #endif
108735 yy_shift(yypParser,yyact,yygoto,&yygotominor);
108737 }else{
108738 assert( yyact == YYNSTATE + YYNRULE + 1 );
108739 yy_accept(yypParser);
108744 ** The following code executes when the parse fails
108746 #ifndef YYNOERRORRECOVERY
108747 static void yy_parse_failed(
108748 yyParser *yypParser /* The parser */
108750 sqlite3ParserARG_FETCH;
108751 #ifndef NDEBUG
108752 if( yyTraceFILE ){
108753 fprintf(yyTraceFILE,"%sFail!\n",yyTracePrompt);
108755 #endif
108756 while( yypParser->yyidx>=0 ) yy_pop_parser_stack(yypParser);
108757 /* Here code is inserted which will be executed whenever the
108758 ** parser fails */
108759 sqlite3ParserARG_STORE; /* Suppress warning about unused %extra_argument variable */
108761 #endif /* YYNOERRORRECOVERY */
108764 ** The following code executes when a syntax error first occurs.
108766 static void yy_syntax_error(
108767 yyParser *yypParser, /* The parser */
108768 int yymajor, /* The major type of the error token */
108769 YYMINORTYPE yyminor /* The minor type of the error token */
108771 sqlite3ParserARG_FETCH;
108772 #define TOKEN (yyminor.yy0)
108774 UNUSED_PARAMETER(yymajor); /* Silence some compiler warnings */
108775 assert( TOKEN.z[0] ); /* The tokenizer always gives us a token */
108776 sqlite3ErrorMsg(pParse, "near \"%T\": syntax error", &TOKEN);
108777 pParse->parseError = 1;
108778 sqlite3ParserARG_STORE; /* Suppress warning about unused %extra_argument variable */
108782 ** The following is executed when the parser accepts
108784 static void yy_accept(
108785 yyParser *yypParser /* The parser */
108787 sqlite3ParserARG_FETCH;
108788 #ifndef NDEBUG
108789 if( yyTraceFILE ){
108790 fprintf(yyTraceFILE,"%sAccept!\n",yyTracePrompt);
108792 #endif
108793 while( yypParser->yyidx>=0 ) yy_pop_parser_stack(yypParser);
108794 /* Here code is inserted which will be executed whenever the
108795 ** parser accepts */
108796 sqlite3ParserARG_STORE; /* Suppress warning about unused %extra_argument variable */
108799 /* The main parser program.
108800 ** The first argument is a pointer to a structure obtained from
108801 ** "sqlite3ParserAlloc" which describes the current state of the parser.
108802 ** The second argument is the major token number. The third is
108803 ** the minor token. The fourth optional argument is whatever the
108804 ** user wants (and specified in the grammar) and is available for
108805 ** use by the action routines.
108807 ** Inputs:
108808 ** <ul>
108809 ** <li> A pointer to the parser (an opaque structure.)
108810 ** <li> The major token number.
108811 ** <li> The minor token number.
108812 ** <li> An option argument of a grammar-specified type.
108813 ** </ul>
108815 ** Outputs:
108816 ** None.
108818 SQLITE_PRIVATE void sqlite3Parser(
108819 void *yyp, /* The parser */
108820 int yymajor, /* The major token code number */
108821 sqlite3ParserTOKENTYPE yyminor /* The value for the token */
108822 sqlite3ParserARG_PDECL /* Optional %extra_argument parameter */
108824 YYMINORTYPE yyminorunion;
108825 int yyact; /* The parser action. */
108826 int yyendofinput; /* True if we are at the end of input */
108827 #ifdef YYERRORSYMBOL
108828 int yyerrorhit = 0; /* True if yymajor has invoked an error */
108829 #endif
108830 yyParser *yypParser; /* The parser */
108832 /* (re)initialize the parser, if necessary */
108833 yypParser = (yyParser*)yyp;
108834 if( yypParser->yyidx<0 ){
108835 #if YYSTACKDEPTH<=0
108836 if( yypParser->yystksz <=0 ){
108837 /*memset(&yyminorunion, 0, sizeof(yyminorunion));*/
108838 yyminorunion = yyzerominor;
108839 yyStackOverflow(yypParser, &yyminorunion);
108840 return;
108842 #endif
108843 yypParser->yyidx = 0;
108844 yypParser->yyerrcnt = -1;
108845 yypParser->yystack[0].stateno = 0;
108846 yypParser->yystack[0].major = 0;
108848 yyminorunion.yy0 = yyminor;
108849 yyendofinput = (yymajor==0);
108850 sqlite3ParserARG_STORE;
108852 #ifndef NDEBUG
108853 if( yyTraceFILE ){
108854 fprintf(yyTraceFILE,"%sInput %s\n",yyTracePrompt,yyTokenName[yymajor]);
108856 #endif
108859 yyact = yy_find_shift_action(yypParser,(YYCODETYPE)yymajor);
108860 if( yyact<YYNSTATE ){
108861 assert( !yyendofinput ); /* Impossible to shift the $ token */
108862 yy_shift(yypParser,yyact,yymajor,&yyminorunion);
108863 yypParser->yyerrcnt--;
108864 yymajor = YYNOCODE;
108865 }else if( yyact < YYNSTATE + YYNRULE ){
108866 yy_reduce(yypParser,yyact-YYNSTATE);
108867 }else{
108868 assert( yyact == YY_ERROR_ACTION );
108869 #ifdef YYERRORSYMBOL
108870 int yymx;
108871 #endif
108872 #ifndef NDEBUG
108873 if( yyTraceFILE ){
108874 fprintf(yyTraceFILE,"%sSyntax Error!\n",yyTracePrompt);
108876 #endif
108877 #ifdef YYERRORSYMBOL
108878 /* A syntax error has occurred.
108879 ** The response to an error depends upon whether or not the
108880 ** grammar defines an error token "ERROR".
108882 ** This is what we do if the grammar does define ERROR:
108884 ** * Call the %syntax_error function.
108886 ** * Begin popping the stack until we enter a state where
108887 ** it is legal to shift the error symbol, then shift
108888 ** the error symbol.
108890 ** * Set the error count to three.
108892 ** * Begin accepting and shifting new tokens. No new error
108893 ** processing will occur until three tokens have been
108894 ** shifted successfully.
108897 if( yypParser->yyerrcnt<0 ){
108898 yy_syntax_error(yypParser,yymajor,yyminorunion);
108900 yymx = yypParser->yystack[yypParser->yyidx].major;
108901 if( yymx==YYERRORSYMBOL || yyerrorhit ){
108902 #ifndef NDEBUG
108903 if( yyTraceFILE ){
108904 fprintf(yyTraceFILE,"%sDiscard input token %s\n",
108905 yyTracePrompt,yyTokenName[yymajor]);
108907 #endif
108908 yy_destructor(yypParser, (YYCODETYPE)yymajor,&yyminorunion);
108909 yymajor = YYNOCODE;
108910 }else{
108911 while(
108912 yypParser->yyidx >= 0 &&
108913 yymx != YYERRORSYMBOL &&
108914 (yyact = yy_find_reduce_action(
108915 yypParser->yystack[yypParser->yyidx].stateno,
108916 YYERRORSYMBOL)) >= YYNSTATE
108918 yy_pop_parser_stack(yypParser);
108920 if( yypParser->yyidx < 0 || yymajor==0 ){
108921 yy_destructor(yypParser,(YYCODETYPE)yymajor,&yyminorunion);
108922 yy_parse_failed(yypParser);
108923 yymajor = YYNOCODE;
108924 }else if( yymx!=YYERRORSYMBOL ){
108925 YYMINORTYPE u2;
108926 u2.YYERRSYMDT = 0;
108927 yy_shift(yypParser,yyact,YYERRORSYMBOL,&u2);
108930 yypParser->yyerrcnt = 3;
108931 yyerrorhit = 1;
108932 #elif defined(YYNOERRORRECOVERY)
108933 /* If the YYNOERRORRECOVERY macro is defined, then do not attempt to
108934 ** do any kind of error recovery. Instead, simply invoke the syntax
108935 ** error routine and continue going as if nothing had happened.
108937 ** Applications can set this macro (for example inside %include) if
108938 ** they intend to abandon the parse upon the first syntax error seen.
108940 yy_syntax_error(yypParser,yymajor,yyminorunion);
108941 yy_destructor(yypParser,(YYCODETYPE)yymajor,&yyminorunion);
108942 yymajor = YYNOCODE;
108944 #else /* YYERRORSYMBOL is not defined */
108945 /* This is what we do if the grammar does not define ERROR:
108947 ** * Report an error message, and throw away the input token.
108949 ** * If the input token is $, then fail the parse.
108951 ** As before, subsequent error messages are suppressed until
108952 ** three input tokens have been successfully shifted.
108954 if( yypParser->yyerrcnt<=0 ){
108955 yy_syntax_error(yypParser,yymajor,yyminorunion);
108957 yypParser->yyerrcnt = 3;
108958 yy_destructor(yypParser,(YYCODETYPE)yymajor,&yyminorunion);
108959 if( yyendofinput ){
108960 yy_parse_failed(yypParser);
108962 yymajor = YYNOCODE;
108963 #endif
108965 }while( yymajor!=YYNOCODE && yypParser->yyidx>=0 );
108966 return;
108969 /************** End of parse.c ***********************************************/
108970 /************** Begin file tokenize.c ****************************************/
108972 ** 2001 September 15
108974 ** The author disclaims copyright to this source code. In place of
108975 ** a legal notice, here is a blessing:
108977 ** May you do good and not evil.
108978 ** May you find forgiveness for yourself and forgive others.
108979 ** May you share freely, never taking more than you give.
108981 *************************************************************************
108982 ** An tokenizer for SQL
108984 ** This file contains C code that splits an SQL input string up into
108985 ** individual tokens and sends those tokens one-by-one over to the
108986 ** parser for analysis.
108988 /* #include <stdlib.h> */
108991 ** The charMap() macro maps alphabetic characters into their
108992 ** lower-case ASCII equivalent. On ASCII machines, this is just
108993 ** an upper-to-lower case map. On EBCDIC machines we also need
108994 ** to adjust the encoding. Only alphabetic characters and underscores
108995 ** need to be translated.
108997 #ifdef SQLITE_ASCII
108998 # define charMap(X) sqlite3UpperToLower[(unsigned char)X]
108999 #endif
109000 #ifdef SQLITE_EBCDIC
109001 # define charMap(X) ebcdicToAscii[(unsigned char)X]
109002 const unsigned char ebcdicToAscii[] = {
109003 /* 0 1 2 3 4 5 6 7 8 9 A B C D E F */
109004 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, /* 0x */
109005 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, /* 1x */
109006 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, /* 2x */
109007 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, /* 3x */
109008 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, /* 4x */
109009 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, /* 5x */
109010 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 95, 0, 0, /* 6x */
109011 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, /* 7x */
109012 0, 97, 98, 99,100,101,102,103,104,105, 0, 0, 0, 0, 0, 0, /* 8x */
109013 0,106,107,108,109,110,111,112,113,114, 0, 0, 0, 0, 0, 0, /* 9x */
109014 0, 0,115,116,117,118,119,120,121,122, 0, 0, 0, 0, 0, 0, /* Ax */
109015 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, /* Bx */
109016 0, 97, 98, 99,100,101,102,103,104,105, 0, 0, 0, 0, 0, 0, /* Cx */
109017 0,106,107,108,109,110,111,112,113,114, 0, 0, 0, 0, 0, 0, /* Dx */
109018 0, 0,115,116,117,118,119,120,121,122, 0, 0, 0, 0, 0, 0, /* Ex */
109019 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, /* Fx */
109021 #endif
109024 ** The sqlite3KeywordCode function looks up an identifier to determine if
109025 ** it is a keyword. If it is a keyword, the token code of that keyword is
109026 ** returned. If the input is not a keyword, TK_ID is returned.
109028 ** The implementation of this routine was generated by a program,
109029 ** mkkeywordhash.h, located in the tool subdirectory of the distribution.
109030 ** The output of the mkkeywordhash.c program is written into a file
109031 ** named keywordhash.h and then included into this source file by
109032 ** the #include below.
109034 /************** Include keywordhash.h in the middle of tokenize.c ************/
109035 /************** Begin file keywordhash.h *************************************/
109036 /***** This file contains automatically generated code ******
109038 ** The code in this file has been automatically generated by
109040 ** sqlite/tool/mkkeywordhash.c
109042 ** The code in this file implements a function that determines whether
109043 ** or not a given identifier is really an SQL keyword. The same thing
109044 ** might be implemented more directly using a hand-written hash table.
109045 ** But by using this automatically generated code, the size of the code
109046 ** is substantially reduced. This is important for embedded applications
109047 ** on platforms with limited memory.
109049 /* Hash score: 175 */
109050 static int keywordCode(const char *z, int n){
109051 /* zText[] encodes 811 bytes of keywords in 541 bytes */
109052 /* REINDEXEDESCAPEACHECKEYBEFOREIGNOREGEXPLAINSTEADDATABASELECT */
109053 /* ABLEFTHENDEFERRABLELSEXCEPTRANSACTIONATURALTERAISEXCLUSIVE */
109054 /* XISTSAVEPOINTERSECTRIGGEREFERENCESCONSTRAINTOFFSETEMPORARY */
109055 /* UNIQUERYATTACHAVINGROUPDATEBEGINNERELEASEBETWEENOTNULLIKE */
109056 /* CASCADELETECASECOLLATECREATECURRENT_DATEDETACHIMMEDIATEJOIN */
109057 /* SERTMATCHPLANALYZEPRAGMABORTVALUESVIRTUALIMITWHENWHERENAME */
109058 /* AFTEREPLACEANDEFAULTAUTOINCREMENTCASTCOLUMNCOMMITCONFLICTCROSS */
109059 /* CURRENT_TIMESTAMPRIMARYDEFERREDISTINCTDROPFAILFROMFULLGLOBYIF */
109060 /* ISNULLORDERESTRICTOUTERIGHTROLLBACKROWUNIONUSINGVACUUMVIEW */
109061 /* INITIALLY */
109062 static const char zText[540] = {
109063 'R','E','I','N','D','E','X','E','D','E','S','C','A','P','E','A','C','H',
109064 'E','C','K','E','Y','B','E','F','O','R','E','I','G','N','O','R','E','G',
109065 'E','X','P','L','A','I','N','S','T','E','A','D','D','A','T','A','B','A',
109066 'S','E','L','E','C','T','A','B','L','E','F','T','H','E','N','D','E','F',
109067 'E','R','R','A','B','L','E','L','S','E','X','C','E','P','T','R','A','N',
109068 'S','A','C','T','I','O','N','A','T','U','R','A','L','T','E','R','A','I',
109069 'S','E','X','C','L','U','S','I','V','E','X','I','S','T','S','A','V','E',
109070 'P','O','I','N','T','E','R','S','E','C','T','R','I','G','G','E','R','E',
109071 'F','E','R','E','N','C','E','S','C','O','N','S','T','R','A','I','N','T',
109072 'O','F','F','S','E','T','E','M','P','O','R','A','R','Y','U','N','I','Q',
109073 'U','E','R','Y','A','T','T','A','C','H','A','V','I','N','G','R','O','U',
109074 'P','D','A','T','E','B','E','G','I','N','N','E','R','E','L','E','A','S',
109075 'E','B','E','T','W','E','E','N','O','T','N','U','L','L','I','K','E','C',
109076 'A','S','C','A','D','E','L','E','T','E','C','A','S','E','C','O','L','L',
109077 'A','T','E','C','R','E','A','T','E','C','U','R','R','E','N','T','_','D',
109078 'A','T','E','D','E','T','A','C','H','I','M','M','E','D','I','A','T','E',
109079 'J','O','I','N','S','E','R','T','M','A','T','C','H','P','L','A','N','A',
109080 'L','Y','Z','E','P','R','A','G','M','A','B','O','R','T','V','A','L','U',
109081 'E','S','V','I','R','T','U','A','L','I','M','I','T','W','H','E','N','W',
109082 'H','E','R','E','N','A','M','E','A','F','T','E','R','E','P','L','A','C',
109083 'E','A','N','D','E','F','A','U','L','T','A','U','T','O','I','N','C','R',
109084 'E','M','E','N','T','C','A','S','T','C','O','L','U','M','N','C','O','M',
109085 'M','I','T','C','O','N','F','L','I','C','T','C','R','O','S','S','C','U',
109086 'R','R','E','N','T','_','T','I','M','E','S','T','A','M','P','R','I','M',
109087 'A','R','Y','D','E','F','E','R','R','E','D','I','S','T','I','N','C','T',
109088 'D','R','O','P','F','A','I','L','F','R','O','M','F','U','L','L','G','L',
109089 'O','B','Y','I','F','I','S','N','U','L','L','O','R','D','E','R','E','S',
109090 'T','R','I','C','T','O','U','T','E','R','I','G','H','T','R','O','L','L',
109091 'B','A','C','K','R','O','W','U','N','I','O','N','U','S','I','N','G','V',
109092 'A','C','U','U','M','V','I','E','W','I','N','I','T','I','A','L','L','Y',
109094 static const unsigned char aHash[127] = {
109095 72, 101, 114, 70, 0, 45, 0, 0, 78, 0, 73, 0, 0,
109096 42, 12, 74, 15, 0, 113, 81, 50, 108, 0, 19, 0, 0,
109097 118, 0, 116, 111, 0, 22, 89, 0, 9, 0, 0, 66, 67,
109098 0, 65, 6, 0, 48, 86, 98, 0, 115, 97, 0, 0, 44,
109099 0, 99, 24, 0, 17, 0, 119, 49, 23, 0, 5, 106, 25,
109100 92, 0, 0, 121, 102, 56, 120, 53, 28, 51, 0, 87, 0,
109101 96, 26, 0, 95, 0, 0, 0, 91, 88, 93, 84, 105, 14,
109102 39, 104, 0, 77, 0, 18, 85, 107, 32, 0, 117, 76, 109,
109103 58, 46, 80, 0, 0, 90, 40, 0, 112, 0, 36, 0, 0,
109104 29, 0, 82, 59, 60, 0, 20, 57, 0, 52,
109106 static const unsigned char aNext[121] = {
109107 0, 0, 0, 0, 4, 0, 0, 0, 0, 0, 0, 0, 0,
109108 0, 2, 0, 0, 0, 0, 0, 0, 13, 0, 0, 0, 0,
109109 0, 7, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0,
109110 0, 0, 0, 0, 33, 0, 21, 0, 0, 0, 43, 3, 47,
109111 0, 0, 0, 0, 30, 0, 54, 0, 38, 0, 0, 0, 1,
109112 62, 0, 0, 63, 0, 41, 0, 0, 0, 0, 0, 0, 0,
109113 61, 0, 0, 0, 0, 31, 55, 16, 34, 10, 0, 0, 0,
109114 0, 0, 0, 0, 11, 68, 75, 0, 8, 0, 100, 94, 0,
109115 103, 0, 83, 0, 71, 0, 0, 110, 27, 37, 69, 79, 0,
109116 35, 64, 0, 0,
109118 static const unsigned char aLen[121] = {
109119 7, 7, 5, 4, 6, 4, 5, 3, 6, 7, 3, 6, 6,
109120 7, 7, 3, 8, 2, 6, 5, 4, 4, 3, 10, 4, 6,
109121 11, 6, 2, 7, 5, 5, 9, 6, 9, 9, 7, 10, 10,
109122 4, 6, 2, 3, 9, 4, 2, 6, 5, 6, 6, 5, 6,
109123 5, 5, 7, 7, 7, 3, 2, 4, 4, 7, 3, 6, 4,
109124 7, 6, 12, 6, 9, 4, 6, 5, 4, 7, 6, 5, 6,
109125 7, 5, 4, 5, 6, 5, 7, 3, 7, 13, 2, 2, 4,
109126 6, 6, 8, 5, 17, 12, 7, 8, 8, 2, 4, 4, 4,
109127 4, 4, 2, 2, 6, 5, 8, 5, 5, 8, 3, 5, 5,
109128 6, 4, 9, 3,
109130 static const unsigned short int aOffset[121] = {
109131 0, 2, 2, 8, 9, 14, 16, 20, 23, 25, 25, 29, 33,
109132 36, 41, 46, 48, 53, 54, 59, 62, 65, 67, 69, 78, 81,
109133 86, 91, 95, 96, 101, 105, 109, 117, 122, 128, 136, 142, 152,
109134 159, 162, 162, 165, 167, 167, 171, 176, 179, 184, 189, 194, 197,
109135 203, 206, 210, 217, 223, 223, 223, 226, 229, 233, 234, 238, 244,
109136 248, 255, 261, 273, 279, 288, 290, 296, 301, 303, 310, 315, 320,
109137 326, 332, 337, 341, 344, 350, 354, 361, 363, 370, 372, 374, 383,
109138 387, 393, 399, 407, 412, 412, 428, 435, 442, 443, 450, 454, 458,
109139 462, 466, 469, 471, 473, 479, 483, 491, 495, 500, 508, 511, 516,
109140 521, 527, 531, 536,
109142 static const unsigned char aCode[121] = {
109143 TK_REINDEX, TK_INDEXED, TK_INDEX, TK_DESC, TK_ESCAPE,
109144 TK_EACH, TK_CHECK, TK_KEY, TK_BEFORE, TK_FOREIGN,
109145 TK_FOR, TK_IGNORE, TK_LIKE_KW, TK_EXPLAIN, TK_INSTEAD,
109146 TK_ADD, TK_DATABASE, TK_AS, TK_SELECT, TK_TABLE,
109147 TK_JOIN_KW, TK_THEN, TK_END, TK_DEFERRABLE, TK_ELSE,
109148 TK_EXCEPT, TK_TRANSACTION,TK_ACTION, TK_ON, TK_JOIN_KW,
109149 TK_ALTER, TK_RAISE, TK_EXCLUSIVE, TK_EXISTS, TK_SAVEPOINT,
109150 TK_INTERSECT, TK_TRIGGER, TK_REFERENCES, TK_CONSTRAINT, TK_INTO,
109151 TK_OFFSET, TK_OF, TK_SET, TK_TEMP, TK_TEMP,
109152 TK_OR, TK_UNIQUE, TK_QUERY, TK_ATTACH, TK_HAVING,
109153 TK_GROUP, TK_UPDATE, TK_BEGIN, TK_JOIN_KW, TK_RELEASE,
109154 TK_BETWEEN, TK_NOTNULL, TK_NOT, TK_NO, TK_NULL,
109155 TK_LIKE_KW, TK_CASCADE, TK_ASC, TK_DELETE, TK_CASE,
109156 TK_COLLATE, TK_CREATE, TK_CTIME_KW, TK_DETACH, TK_IMMEDIATE,
109157 TK_JOIN, TK_INSERT, TK_MATCH, TK_PLAN, TK_ANALYZE,
109158 TK_PRAGMA, TK_ABORT, TK_VALUES, TK_VIRTUAL, TK_LIMIT,
109159 TK_WHEN, TK_WHERE, TK_RENAME, TK_AFTER, TK_REPLACE,
109160 TK_AND, TK_DEFAULT, TK_AUTOINCR, TK_TO, TK_IN,
109161 TK_CAST, TK_COLUMNKW, TK_COMMIT, TK_CONFLICT, TK_JOIN_KW,
109162 TK_CTIME_KW, TK_CTIME_KW, TK_PRIMARY, TK_DEFERRED, TK_DISTINCT,
109163 TK_IS, TK_DROP, TK_FAIL, TK_FROM, TK_JOIN_KW,
109164 TK_LIKE_KW, TK_BY, TK_IF, TK_ISNULL, TK_ORDER,
109165 TK_RESTRICT, TK_JOIN_KW, TK_JOIN_KW, TK_ROLLBACK, TK_ROW,
109166 TK_UNION, TK_USING, TK_VACUUM, TK_VIEW, TK_INITIALLY,
109167 TK_ALL,
109169 int h, i;
109170 if( n<2 ) return TK_ID;
109171 h = ((charMap(z[0])*4) ^
109172 (charMap(z[n-1])*3) ^
109173 n) % 127;
109174 for(i=((int)aHash[h])-1; i>=0; i=((int)aNext[i])-1){
109175 if( aLen[i]==n && sqlite3StrNICmp(&zText[aOffset[i]],z,n)==0 ){
109176 testcase( i==0 ); /* REINDEX */
109177 testcase( i==1 ); /* INDEXED */
109178 testcase( i==2 ); /* INDEX */
109179 testcase( i==3 ); /* DESC */
109180 testcase( i==4 ); /* ESCAPE */
109181 testcase( i==5 ); /* EACH */
109182 testcase( i==6 ); /* CHECK */
109183 testcase( i==7 ); /* KEY */
109184 testcase( i==8 ); /* BEFORE */
109185 testcase( i==9 ); /* FOREIGN */
109186 testcase( i==10 ); /* FOR */
109187 testcase( i==11 ); /* IGNORE */
109188 testcase( i==12 ); /* REGEXP */
109189 testcase( i==13 ); /* EXPLAIN */
109190 testcase( i==14 ); /* INSTEAD */
109191 testcase( i==15 ); /* ADD */
109192 testcase( i==16 ); /* DATABASE */
109193 testcase( i==17 ); /* AS */
109194 testcase( i==18 ); /* SELECT */
109195 testcase( i==19 ); /* TABLE */
109196 testcase( i==20 ); /* LEFT */
109197 testcase( i==21 ); /* THEN */
109198 testcase( i==22 ); /* END */
109199 testcase( i==23 ); /* DEFERRABLE */
109200 testcase( i==24 ); /* ELSE */
109201 testcase( i==25 ); /* EXCEPT */
109202 testcase( i==26 ); /* TRANSACTION */
109203 testcase( i==27 ); /* ACTION */
109204 testcase( i==28 ); /* ON */
109205 testcase( i==29 ); /* NATURAL */
109206 testcase( i==30 ); /* ALTER */
109207 testcase( i==31 ); /* RAISE */
109208 testcase( i==32 ); /* EXCLUSIVE */
109209 testcase( i==33 ); /* EXISTS */
109210 testcase( i==34 ); /* SAVEPOINT */
109211 testcase( i==35 ); /* INTERSECT */
109212 testcase( i==36 ); /* TRIGGER */
109213 testcase( i==37 ); /* REFERENCES */
109214 testcase( i==38 ); /* CONSTRAINT */
109215 testcase( i==39 ); /* INTO */
109216 testcase( i==40 ); /* OFFSET */
109217 testcase( i==41 ); /* OF */
109218 testcase( i==42 ); /* SET */
109219 testcase( i==43 ); /* TEMPORARY */
109220 testcase( i==44 ); /* TEMP */
109221 testcase( i==45 ); /* OR */
109222 testcase( i==46 ); /* UNIQUE */
109223 testcase( i==47 ); /* QUERY */
109224 testcase( i==48 ); /* ATTACH */
109225 testcase( i==49 ); /* HAVING */
109226 testcase( i==50 ); /* GROUP */
109227 testcase( i==51 ); /* UPDATE */
109228 testcase( i==52 ); /* BEGIN */
109229 testcase( i==53 ); /* INNER */
109230 testcase( i==54 ); /* RELEASE */
109231 testcase( i==55 ); /* BETWEEN */
109232 testcase( i==56 ); /* NOTNULL */
109233 testcase( i==57 ); /* NOT */
109234 testcase( i==58 ); /* NO */
109235 testcase( i==59 ); /* NULL */
109236 testcase( i==60 ); /* LIKE */
109237 testcase( i==61 ); /* CASCADE */
109238 testcase( i==62 ); /* ASC */
109239 testcase( i==63 ); /* DELETE */
109240 testcase( i==64 ); /* CASE */
109241 testcase( i==65 ); /* COLLATE */
109242 testcase( i==66 ); /* CREATE */
109243 testcase( i==67 ); /* CURRENT_DATE */
109244 testcase( i==68 ); /* DETACH */
109245 testcase( i==69 ); /* IMMEDIATE */
109246 testcase( i==70 ); /* JOIN */
109247 testcase( i==71 ); /* INSERT */
109248 testcase( i==72 ); /* MATCH */
109249 testcase( i==73 ); /* PLAN */
109250 testcase( i==74 ); /* ANALYZE */
109251 testcase( i==75 ); /* PRAGMA */
109252 testcase( i==76 ); /* ABORT */
109253 testcase( i==77 ); /* VALUES */
109254 testcase( i==78 ); /* VIRTUAL */
109255 testcase( i==79 ); /* LIMIT */
109256 testcase( i==80 ); /* WHEN */
109257 testcase( i==81 ); /* WHERE */
109258 testcase( i==82 ); /* RENAME */
109259 testcase( i==83 ); /* AFTER */
109260 testcase( i==84 ); /* REPLACE */
109261 testcase( i==85 ); /* AND */
109262 testcase( i==86 ); /* DEFAULT */
109263 testcase( i==87 ); /* AUTOINCREMENT */
109264 testcase( i==88 ); /* TO */
109265 testcase( i==89 ); /* IN */
109266 testcase( i==90 ); /* CAST */
109267 testcase( i==91 ); /* COLUMN */
109268 testcase( i==92 ); /* COMMIT */
109269 testcase( i==93 ); /* CONFLICT */
109270 testcase( i==94 ); /* CROSS */
109271 testcase( i==95 ); /* CURRENT_TIMESTAMP */
109272 testcase( i==96 ); /* CURRENT_TIME */
109273 testcase( i==97 ); /* PRIMARY */
109274 testcase( i==98 ); /* DEFERRED */
109275 testcase( i==99 ); /* DISTINCT */
109276 testcase( i==100 ); /* IS */
109277 testcase( i==101 ); /* DROP */
109278 testcase( i==102 ); /* FAIL */
109279 testcase( i==103 ); /* FROM */
109280 testcase( i==104 ); /* FULL */
109281 testcase( i==105 ); /* GLOB */
109282 testcase( i==106 ); /* BY */
109283 testcase( i==107 ); /* IF */
109284 testcase( i==108 ); /* ISNULL */
109285 testcase( i==109 ); /* ORDER */
109286 testcase( i==110 ); /* RESTRICT */
109287 testcase( i==111 ); /* OUTER */
109288 testcase( i==112 ); /* RIGHT */
109289 testcase( i==113 ); /* ROLLBACK */
109290 testcase( i==114 ); /* ROW */
109291 testcase( i==115 ); /* UNION */
109292 testcase( i==116 ); /* USING */
109293 testcase( i==117 ); /* VACUUM */
109294 testcase( i==118 ); /* VIEW */
109295 testcase( i==119 ); /* INITIALLY */
109296 testcase( i==120 ); /* ALL */
109297 return aCode[i];
109300 return TK_ID;
109302 SQLITE_PRIVATE int sqlite3KeywordCode(const unsigned char *z, int n){
109303 return keywordCode((char*)z, n);
109305 #define SQLITE_N_KEYWORD 121
109307 /************** End of keywordhash.h *****************************************/
109308 /************** Continuing where we left off in tokenize.c *******************/
109312 ** If X is a character that can be used in an identifier then
109313 ** IdChar(X) will be true. Otherwise it is false.
109315 ** For ASCII, any character with the high-order bit set is
109316 ** allowed in an identifier. For 7-bit characters,
109317 ** sqlite3IsIdChar[X] must be 1.
109319 ** For EBCDIC, the rules are more complex but have the same
109320 ** end result.
109322 ** Ticket #1066. the SQL standard does not allow '$' in the
109323 ** middle of identfiers. But many SQL implementations do.
109324 ** SQLite will allow '$' in identifiers for compatibility.
109325 ** But the feature is undocumented.
109327 #ifdef SQLITE_ASCII
109328 #define IdChar(C) ((sqlite3CtypeMap[(unsigned char)C]&0x46)!=0)
109329 #endif
109330 #ifdef SQLITE_EBCDIC
109331 SQLITE_PRIVATE const char sqlite3IsEbcdicIdChar[] = {
109332 /* x0 x1 x2 x3 x4 x5 x6 x7 x8 x9 xA xB xC xD xE xF */
109333 0, 0, 1, 1, 1, 1, 1, 1, 1, 1, 0, 0, 0, 0, 0, 0, /* 4x */
109334 0, 1, 1, 1, 1, 1, 1, 1, 1, 1, 0, 1, 0, 0, 0, 0, /* 5x */
109335 0, 0, 1, 1, 1, 1, 1, 1, 1, 1, 0, 0, 0, 1, 0, 0, /* 6x */
109336 0, 1, 1, 1, 1, 1, 1, 1, 1, 0, 0, 0, 0, 0, 0, 0, /* 7x */
109337 0, 1, 1, 1, 1, 1, 1, 1, 1, 1, 0, 0, 1, 1, 1, 0, /* 8x */
109338 0, 1, 1, 1, 1, 1, 1, 1, 1, 1, 0, 0, 1, 0, 1, 0, /* 9x */
109339 1, 0, 1, 1, 1, 1, 1, 1, 1, 1, 1, 0, 1, 1, 1, 0, /* Ax */
109340 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, /* Bx */
109341 0, 1, 1, 1, 1, 1, 1, 1, 1, 1, 0, 1, 1, 1, 1, 1, /* Cx */
109342 0, 1, 1, 1, 1, 1, 1, 1, 1, 1, 0, 1, 1, 1, 1, 1, /* Dx */
109343 0, 0, 1, 1, 1, 1, 1, 1, 1, 1, 0, 1, 1, 1, 1, 1, /* Ex */
109344 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 0, 1, 1, 1, 1, 0, /* Fx */
109346 #define IdChar(C) (((c=C)>=0x42 && sqlite3IsEbcdicIdChar[c-0x40]))
109347 #endif
109351 ** Return the length of the token that begins at z[0].
109352 ** Store the token type in *tokenType before returning.
109354 SQLITE_PRIVATE int sqlite3GetToken(const unsigned char *z, int *tokenType){
109355 int i, c;
109356 switch( *z ){
109357 case ' ': case '\t': case '\n': case '\f': case '\r': {
109358 testcase( z[0]==' ' );
109359 testcase( z[0]=='\t' );
109360 testcase( z[0]=='\n' );
109361 testcase( z[0]=='\f' );
109362 testcase( z[0]=='\r' );
109363 for(i=1; sqlite3Isspace(z[i]); i++){}
109364 *tokenType = TK_SPACE;
109365 return i;
109367 case '-': {
109368 if( z[1]=='-' ){
109369 /* IMP: R-15891-05542 -- syntax diagram for comments */
109370 for(i=2; (c=z[i])!=0 && c!='\n'; i++){}
109371 *tokenType = TK_SPACE; /* IMP: R-22934-25134 */
109372 return i;
109374 *tokenType = TK_MINUS;
109375 return 1;
109377 case '(': {
109378 *tokenType = TK_LP;
109379 return 1;
109381 case ')': {
109382 *tokenType = TK_RP;
109383 return 1;
109385 case ';': {
109386 *tokenType = TK_SEMI;
109387 return 1;
109389 case '+': {
109390 *tokenType = TK_PLUS;
109391 return 1;
109393 case '*': {
109394 *tokenType = TK_STAR;
109395 return 1;
109397 case '/': {
109398 if( z[1]!='*' || z[2]==0 ){
109399 *tokenType = TK_SLASH;
109400 return 1;
109402 /* IMP: R-15891-05542 -- syntax diagram for comments */
109403 for(i=3, c=z[2]; (c!='*' || z[i]!='/') && (c=z[i])!=0; i++){}
109404 if( c ) i++;
109405 *tokenType = TK_SPACE; /* IMP: R-22934-25134 */
109406 return i;
109408 case '%': {
109409 *tokenType = TK_REM;
109410 return 1;
109412 case '=': {
109413 *tokenType = TK_EQ;
109414 return 1 + (z[1]=='=');
109416 case '<': {
109417 if( (c=z[1])=='=' ){
109418 *tokenType = TK_LE;
109419 return 2;
109420 }else if( c=='>' ){
109421 *tokenType = TK_NE;
109422 return 2;
109423 }else if( c=='<' ){
109424 *tokenType = TK_LSHIFT;
109425 return 2;
109426 }else{
109427 *tokenType = TK_LT;
109428 return 1;
109431 case '>': {
109432 if( (c=z[1])=='=' ){
109433 *tokenType = TK_GE;
109434 return 2;
109435 }else if( c=='>' ){
109436 *tokenType = TK_RSHIFT;
109437 return 2;
109438 }else{
109439 *tokenType = TK_GT;
109440 return 1;
109443 case '!': {
109444 if( z[1]!='=' ){
109445 *tokenType = TK_ILLEGAL;
109446 return 2;
109447 }else{
109448 *tokenType = TK_NE;
109449 return 2;
109452 case '|': {
109453 if( z[1]!='|' ){
109454 *tokenType = TK_BITOR;
109455 return 1;
109456 }else{
109457 *tokenType = TK_CONCAT;
109458 return 2;
109461 case ',': {
109462 *tokenType = TK_COMMA;
109463 return 1;
109465 case '&': {
109466 *tokenType = TK_BITAND;
109467 return 1;
109469 case '~': {
109470 *tokenType = TK_BITNOT;
109471 return 1;
109473 case '`':
109474 case '\'':
109475 case '"': {
109476 int delim = z[0];
109477 testcase( delim=='`' );
109478 testcase( delim=='\'' );
109479 testcase( delim=='"' );
109480 for(i=1; (c=z[i])!=0; i++){
109481 if( c==delim ){
109482 if( z[i+1]==delim ){
109484 }else{
109485 break;
109489 if( c=='\'' ){
109490 *tokenType = TK_STRING;
109491 return i+1;
109492 }else if( c!=0 ){
109493 *tokenType = TK_ID;
109494 return i+1;
109495 }else{
109496 *tokenType = TK_ILLEGAL;
109497 return i;
109500 case '.': {
109501 #ifndef SQLITE_OMIT_FLOATING_POINT
109502 if( !sqlite3Isdigit(z[1]) )
109503 #endif
109505 *tokenType = TK_DOT;
109506 return 1;
109508 /* If the next character is a digit, this is a floating point
109509 ** number that begins with ".". Fall thru into the next case */
109511 case '0': case '1': case '2': case '3': case '4':
109512 case '5': case '6': case '7': case '8': case '9': {
109513 testcase( z[0]=='0' ); testcase( z[0]=='1' ); testcase( z[0]=='2' );
109514 testcase( z[0]=='3' ); testcase( z[0]=='4' ); testcase( z[0]=='5' );
109515 testcase( z[0]=='6' ); testcase( z[0]=='7' ); testcase( z[0]=='8' );
109516 testcase( z[0]=='9' );
109517 *tokenType = TK_INTEGER;
109518 for(i=0; sqlite3Isdigit(z[i]); i++){}
109519 #ifndef SQLITE_OMIT_FLOATING_POINT
109520 if( z[i]=='.' ){
109522 while( sqlite3Isdigit(z[i]) ){ i++; }
109523 *tokenType = TK_FLOAT;
109525 if( (z[i]=='e' || z[i]=='E') &&
109526 ( sqlite3Isdigit(z[i+1])
109527 || ((z[i+1]=='+' || z[i+1]=='-') && sqlite3Isdigit(z[i+2]))
109530 i += 2;
109531 while( sqlite3Isdigit(z[i]) ){ i++; }
109532 *tokenType = TK_FLOAT;
109534 #endif
109535 while( IdChar(z[i]) ){
109536 *tokenType = TK_ILLEGAL;
109539 return i;
109541 case '[': {
109542 for(i=1, c=z[0]; c!=']' && (c=z[i])!=0; i++){}
109543 *tokenType = c==']' ? TK_ID : TK_ILLEGAL;
109544 return i;
109546 case '?': {
109547 *tokenType = TK_VARIABLE;
109548 for(i=1; sqlite3Isdigit(z[i]); i++){}
109549 return i;
109551 case '#': {
109552 for(i=1; sqlite3Isdigit(z[i]); i++){}
109553 if( i>1 ){
109554 /* Parameters of the form #NNN (where NNN is a number) are used
109555 ** internally by sqlite3NestedParse. */
109556 *tokenType = TK_REGISTER;
109557 return i;
109559 /* Fall through into the next case if the '#' is not followed by
109560 ** a digit. Try to match #AAAA where AAAA is a parameter name. */
109562 #ifndef SQLITE_OMIT_TCL_VARIABLE
109563 case '$':
109564 #endif
109565 case '@': /* For compatibility with MS SQL Server */
109566 case ':': {
109567 int n = 0;
109568 testcase( z[0]=='$' ); testcase( z[0]=='@' ); testcase( z[0]==':' );
109569 *tokenType = TK_VARIABLE;
109570 for(i=1; (c=z[i])!=0; i++){
109571 if( IdChar(c) ){
109573 #ifndef SQLITE_OMIT_TCL_VARIABLE
109574 }else if( c=='(' && n>0 ){
109577 }while( (c=z[i])!=0 && !sqlite3Isspace(c) && c!=')' );
109578 if( c==')' ){
109580 }else{
109581 *tokenType = TK_ILLEGAL;
109583 break;
109584 }else if( c==':' && z[i+1]==':' ){
109586 #endif
109587 }else{
109588 break;
109591 if( n==0 ) *tokenType = TK_ILLEGAL;
109592 return i;
109594 #ifndef SQLITE_OMIT_BLOB_LITERAL
109595 case 'x': case 'X': {
109596 testcase( z[0]=='x' ); testcase( z[0]=='X' );
109597 if( z[1]=='\'' ){
109598 *tokenType = TK_BLOB;
109599 for(i=2; sqlite3Isxdigit(z[i]); i++){}
109600 if( z[i]!='\'' || i%2 ){
109601 *tokenType = TK_ILLEGAL;
109602 while( z[i] && z[i]!='\'' ){ i++; }
109604 if( z[i] ) i++;
109605 return i;
109607 /* Otherwise fall through to the next case */
109609 #endif
109610 default: {
109611 if( !IdChar(*z) ){
109612 break;
109614 for(i=1; IdChar(z[i]); i++){}
109615 *tokenType = keywordCode((char*)z, i);
109616 return i;
109619 *tokenType = TK_ILLEGAL;
109620 return 1;
109624 ** Run the parser on the given SQL string. The parser structure is
109625 ** passed in. An SQLITE_ status code is returned. If an error occurs
109626 ** then an and attempt is made to write an error message into
109627 ** memory obtained from sqlite3_malloc() and to make *pzErrMsg point to that
109628 ** error message.
109630 SQLITE_PRIVATE int sqlite3RunParser(Parse *pParse, const char *zSql, char **pzErrMsg){
109631 int nErr = 0; /* Number of errors encountered */
109632 int i; /* Loop counter */
109633 void *pEngine; /* The LEMON-generated LALR(1) parser */
109634 int tokenType; /* type of the next token */
109635 int lastTokenParsed = -1; /* type of the previous token */
109636 u8 enableLookaside; /* Saved value of db->lookaside.bEnabled */
109637 sqlite3 *db = pParse->db; /* The database connection */
109638 int mxSqlLen; /* Max length of an SQL string */
109641 mxSqlLen = db->aLimit[SQLITE_LIMIT_SQL_LENGTH];
109642 if( db->activeVdbeCnt==0 ){
109643 db->u1.isInterrupted = 0;
109645 pParse->rc = SQLITE_OK;
109646 pParse->zTail = zSql;
109647 i = 0;
109648 assert( pzErrMsg!=0 );
109649 pEngine = sqlite3ParserAlloc((void*(*)(size_t))sqlite3Malloc);
109650 if( pEngine==0 ){
109651 db->mallocFailed = 1;
109652 return SQLITE_NOMEM;
109654 assert( pParse->pNewTable==0 );
109655 assert( pParse->pNewTrigger==0 );
109656 assert( pParse->nVar==0 );
109657 assert( pParse->nzVar==0 );
109658 assert( pParse->azVar==0 );
109659 enableLookaside = db->lookaside.bEnabled;
109660 if( db->lookaside.pStart ) db->lookaside.bEnabled = 1;
109661 while( !db->mallocFailed && zSql[i]!=0 ){
109662 assert( i>=0 );
109663 pParse->sLastToken.z = &zSql[i];
109664 pParse->sLastToken.n = sqlite3GetToken((unsigned char*)&zSql[i],&tokenType);
109665 i += pParse->sLastToken.n;
109666 if( i>mxSqlLen ){
109667 pParse->rc = SQLITE_TOOBIG;
109668 break;
109670 switch( tokenType ){
109671 case TK_SPACE: {
109672 if( db->u1.isInterrupted ){
109673 sqlite3ErrorMsg(pParse, "interrupt");
109674 pParse->rc = SQLITE_INTERRUPT;
109675 goto abort_parse;
109677 break;
109679 case TK_ILLEGAL: {
109680 sqlite3DbFree(db, *pzErrMsg);
109681 *pzErrMsg = sqlite3MPrintf(db, "unrecognized token: \"%T\"",
109682 &pParse->sLastToken);
109683 nErr++;
109684 goto abort_parse;
109686 case TK_SEMI: {
109687 pParse->zTail = &zSql[i];
109688 /* Fall thru into the default case */
109690 default: {
109691 sqlite3Parser(pEngine, tokenType, pParse->sLastToken, pParse);
109692 lastTokenParsed = tokenType;
109693 if( pParse->rc!=SQLITE_OK ){
109694 goto abort_parse;
109696 break;
109700 abort_parse:
109701 if( zSql[i]==0 && nErr==0 && pParse->rc==SQLITE_OK ){
109702 if( lastTokenParsed!=TK_SEMI ){
109703 sqlite3Parser(pEngine, TK_SEMI, pParse->sLastToken, pParse);
109704 pParse->zTail = &zSql[i];
109706 sqlite3Parser(pEngine, 0, pParse->sLastToken, pParse);
109708 #ifdef YYTRACKMAXSTACKDEPTH
109709 sqlite3StatusSet(SQLITE_STATUS_PARSER_STACK,
109710 sqlite3ParserStackPeak(pEngine)
109712 #endif /* YYDEBUG */
109713 sqlite3ParserFree(pEngine, sqlite3_free);
109714 db->lookaside.bEnabled = enableLookaside;
109715 if( db->mallocFailed ){
109716 pParse->rc = SQLITE_NOMEM;
109718 if( pParse->rc!=SQLITE_OK && pParse->rc!=SQLITE_DONE && pParse->zErrMsg==0 ){
109719 sqlite3SetString(&pParse->zErrMsg, db, "%s", sqlite3ErrStr(pParse->rc));
109721 assert( pzErrMsg!=0 );
109722 if( pParse->zErrMsg ){
109723 *pzErrMsg = pParse->zErrMsg;
109724 sqlite3_log(pParse->rc, "%s", *pzErrMsg);
109725 pParse->zErrMsg = 0;
109726 nErr++;
109728 if( pParse->pVdbe && pParse->nErr>0 && pParse->nested==0 ){
109729 sqlite3VdbeDelete(pParse->pVdbe);
109730 pParse->pVdbe = 0;
109732 #ifndef SQLITE_OMIT_SHARED_CACHE
109733 if( pParse->nested==0 ){
109734 sqlite3DbFree(db, pParse->aTableLock);
109735 pParse->aTableLock = 0;
109736 pParse->nTableLock = 0;
109738 #endif
109739 #ifndef SQLITE_OMIT_VIRTUALTABLE
109740 sqlite3_free(pParse->apVtabLock);
109741 #endif
109743 if( !IN_DECLARE_VTAB ){
109744 /* If the pParse->declareVtab flag is set, do not delete any table
109745 ** structure built up in pParse->pNewTable. The calling code (see vtab.c)
109746 ** will take responsibility for freeing the Table structure.
109748 sqlite3DeleteTable(db, pParse->pNewTable);
109751 sqlite3DeleteTrigger(db, pParse->pNewTrigger);
109752 for(i=pParse->nzVar-1; i>=0; i--) sqlite3DbFree(db, pParse->azVar[i]);
109753 sqlite3DbFree(db, pParse->azVar);
109754 sqlite3DbFree(db, pParse->aAlias);
109755 while( pParse->pAinc ){
109756 AutoincInfo *p = pParse->pAinc;
109757 pParse->pAinc = p->pNext;
109758 sqlite3DbFree(db, p);
109760 while( pParse->pZombieTab ){
109761 Table *p = pParse->pZombieTab;
109762 pParse->pZombieTab = p->pNextZombie;
109763 sqlite3DeleteTable(db, p);
109765 if( nErr>0 && pParse->rc==SQLITE_OK ){
109766 pParse->rc = SQLITE_ERROR;
109768 return nErr;
109771 /************** End of tokenize.c ********************************************/
109772 /************** Begin file complete.c ****************************************/
109774 ** 2001 September 15
109776 ** The author disclaims copyright to this source code. In place of
109777 ** a legal notice, here is a blessing:
109779 ** May you do good and not evil.
109780 ** May you find forgiveness for yourself and forgive others.
109781 ** May you share freely, never taking more than you give.
109783 *************************************************************************
109784 ** An tokenizer for SQL
109786 ** This file contains C code that implements the sqlite3_complete() API.
109787 ** This code used to be part of the tokenizer.c source file. But by
109788 ** separating it out, the code will be automatically omitted from
109789 ** static links that do not use it.
109791 #ifndef SQLITE_OMIT_COMPLETE
109794 ** This is defined in tokenize.c. We just have to import the definition.
109796 #ifndef SQLITE_AMALGAMATION
109797 #ifdef SQLITE_ASCII
109798 #define IdChar(C) ((sqlite3CtypeMap[(unsigned char)C]&0x46)!=0)
109799 #endif
109800 #ifdef SQLITE_EBCDIC
109801 SQLITE_PRIVATE const char sqlite3IsEbcdicIdChar[];
109802 #define IdChar(C) (((c=C)>=0x42 && sqlite3IsEbcdicIdChar[c-0x40]))
109803 #endif
109804 #endif /* SQLITE_AMALGAMATION */
109808 ** Token types used by the sqlite3_complete() routine. See the header
109809 ** comments on that procedure for additional information.
109811 #define tkSEMI 0
109812 #define tkWS 1
109813 #define tkOTHER 2
109814 #ifndef SQLITE_OMIT_TRIGGER
109815 #define tkEXPLAIN 3
109816 #define tkCREATE 4
109817 #define tkTEMP 5
109818 #define tkTRIGGER 6
109819 #define tkEND 7
109820 #endif
109823 ** Return TRUE if the given SQL string ends in a semicolon.
109825 ** Special handling is require for CREATE TRIGGER statements.
109826 ** Whenever the CREATE TRIGGER keywords are seen, the statement
109827 ** must end with ";END;".
109829 ** This implementation uses a state machine with 8 states:
109831 ** (0) INVALID We have not yet seen a non-whitespace character.
109833 ** (1) START At the beginning or end of an SQL statement. This routine
109834 ** returns 1 if it ends in the START state and 0 if it ends
109835 ** in any other state.
109837 ** (2) NORMAL We are in the middle of statement which ends with a single
109838 ** semicolon.
109840 ** (3) EXPLAIN The keyword EXPLAIN has been seen at the beginning of
109841 ** a statement.
109843 ** (4) CREATE The keyword CREATE has been seen at the beginning of a
109844 ** statement, possibly preceeded by EXPLAIN and/or followed by
109845 ** TEMP or TEMPORARY
109847 ** (5) TRIGGER We are in the middle of a trigger definition that must be
109848 ** ended by a semicolon, the keyword END, and another semicolon.
109850 ** (6) SEMI We've seen the first semicolon in the ";END;" that occurs at
109851 ** the end of a trigger definition.
109853 ** (7) END We've seen the ";END" of the ";END;" that occurs at the end
109854 ** of a trigger difinition.
109856 ** Transitions between states above are determined by tokens extracted
109857 ** from the input. The following tokens are significant:
109859 ** (0) tkSEMI A semicolon.
109860 ** (1) tkWS Whitespace.
109861 ** (2) tkOTHER Any other SQL token.
109862 ** (3) tkEXPLAIN The "explain" keyword.
109863 ** (4) tkCREATE The "create" keyword.
109864 ** (5) tkTEMP The "temp" or "temporary" keyword.
109865 ** (6) tkTRIGGER The "trigger" keyword.
109866 ** (7) tkEND The "end" keyword.
109868 ** Whitespace never causes a state transition and is always ignored.
109869 ** This means that a SQL string of all whitespace is invalid.
109871 ** If we compile with SQLITE_OMIT_TRIGGER, all of the computation needed
109872 ** to recognize the end of a trigger can be omitted. All we have to do
109873 ** is look for a semicolon that is not part of an string or comment.
109875 SQLITE_API int sqlite3_complete(const char *zSql){
109876 u8 state = 0; /* Current state, using numbers defined in header comment */
109877 u8 token; /* Value of the next token */
109879 #ifndef SQLITE_OMIT_TRIGGER
109880 /* A complex statement machine used to detect the end of a CREATE TRIGGER
109881 ** statement. This is the normal case.
109883 static const u8 trans[8][8] = {
109884 /* Token: */
109885 /* State: ** SEMI WS OTHER EXPLAIN CREATE TEMP TRIGGER END */
109886 /* 0 INVALID: */ { 1, 0, 2, 3, 4, 2, 2, 2, },
109887 /* 1 START: */ { 1, 1, 2, 3, 4, 2, 2, 2, },
109888 /* 2 NORMAL: */ { 1, 2, 2, 2, 2, 2, 2, 2, },
109889 /* 3 EXPLAIN: */ { 1, 3, 3, 2, 4, 2, 2, 2, },
109890 /* 4 CREATE: */ { 1, 4, 2, 2, 2, 4, 5, 2, },
109891 /* 5 TRIGGER: */ { 6, 5, 5, 5, 5, 5, 5, 5, },
109892 /* 6 SEMI: */ { 6, 6, 5, 5, 5, 5, 5, 7, },
109893 /* 7 END: */ { 1, 7, 5, 5, 5, 5, 5, 5, },
109895 #else
109896 /* If triggers are not supported by this compile then the statement machine
109897 ** used to detect the end of a statement is much simplier
109899 static const u8 trans[3][3] = {
109900 /* Token: */
109901 /* State: ** SEMI WS OTHER */
109902 /* 0 INVALID: */ { 1, 0, 2, },
109903 /* 1 START: */ { 1, 1, 2, },
109904 /* 2 NORMAL: */ { 1, 2, 2, },
109906 #endif /* SQLITE_OMIT_TRIGGER */
109908 while( *zSql ){
109909 switch( *zSql ){
109910 case ';': { /* A semicolon */
109911 token = tkSEMI;
109912 break;
109914 case ' ':
109915 case '\r':
109916 case '\t':
109917 case '\n':
109918 case '\f': { /* White space is ignored */
109919 token = tkWS;
109920 break;
109922 case '/': { /* C-style comments */
109923 if( zSql[1]!='*' ){
109924 token = tkOTHER;
109925 break;
109927 zSql += 2;
109928 while( zSql[0] && (zSql[0]!='*' || zSql[1]!='/') ){ zSql++; }
109929 if( zSql[0]==0 ) return 0;
109930 zSql++;
109931 token = tkWS;
109932 break;
109934 case '-': { /* SQL-style comments from "--" to end of line */
109935 if( zSql[1]!='-' ){
109936 token = tkOTHER;
109937 break;
109939 while( *zSql && *zSql!='\n' ){ zSql++; }
109940 if( *zSql==0 ) return state==1;
109941 token = tkWS;
109942 break;
109944 case '[': { /* Microsoft-style identifiers in [...] */
109945 zSql++;
109946 while( *zSql && *zSql!=']' ){ zSql++; }
109947 if( *zSql==0 ) return 0;
109948 token = tkOTHER;
109949 break;
109951 case '`': /* Grave-accent quoted symbols used by MySQL */
109952 case '"': /* single- and double-quoted strings */
109953 case '\'': {
109954 int c = *zSql;
109955 zSql++;
109956 while( *zSql && *zSql!=c ){ zSql++; }
109957 if( *zSql==0 ) return 0;
109958 token = tkOTHER;
109959 break;
109961 default: {
109962 #ifdef SQLITE_EBCDIC
109963 unsigned char c;
109964 #endif
109965 if( IdChar((u8)*zSql) ){
109966 /* Keywords and unquoted identifiers */
109967 int nId;
109968 for(nId=1; IdChar(zSql[nId]); nId++){}
109969 #ifdef SQLITE_OMIT_TRIGGER
109970 token = tkOTHER;
109971 #else
109972 switch( *zSql ){
109973 case 'c': case 'C': {
109974 if( nId==6 && sqlite3StrNICmp(zSql, "create", 6)==0 ){
109975 token = tkCREATE;
109976 }else{
109977 token = tkOTHER;
109979 break;
109981 case 't': case 'T': {
109982 if( nId==7 && sqlite3StrNICmp(zSql, "trigger", 7)==0 ){
109983 token = tkTRIGGER;
109984 }else if( nId==4 && sqlite3StrNICmp(zSql, "temp", 4)==0 ){
109985 token = tkTEMP;
109986 }else if( nId==9 && sqlite3StrNICmp(zSql, "temporary", 9)==0 ){
109987 token = tkTEMP;
109988 }else{
109989 token = tkOTHER;
109991 break;
109993 case 'e': case 'E': {
109994 if( nId==3 && sqlite3StrNICmp(zSql, "end", 3)==0 ){
109995 token = tkEND;
109996 }else
109997 #ifndef SQLITE_OMIT_EXPLAIN
109998 if( nId==7 && sqlite3StrNICmp(zSql, "explain", 7)==0 ){
109999 token = tkEXPLAIN;
110000 }else
110001 #endif
110003 token = tkOTHER;
110005 break;
110007 default: {
110008 token = tkOTHER;
110009 break;
110012 #endif /* SQLITE_OMIT_TRIGGER */
110013 zSql += nId-1;
110014 }else{
110015 /* Operators and special symbols */
110016 token = tkOTHER;
110018 break;
110021 state = trans[state][token];
110022 zSql++;
110024 return state==1;
110027 #ifndef SQLITE_OMIT_UTF16
110029 ** This routine is the same as the sqlite3_complete() routine described
110030 ** above, except that the parameter is required to be UTF-16 encoded, not
110031 ** UTF-8.
110033 SQLITE_API int sqlite3_complete16(const void *zSql){
110034 sqlite3_value *pVal;
110035 char const *zSql8;
110036 int rc = SQLITE_NOMEM;
110038 #ifndef SQLITE_OMIT_AUTOINIT
110039 rc = sqlite3_initialize();
110040 if( rc ) return rc;
110041 #endif
110042 pVal = sqlite3ValueNew(0);
110043 sqlite3ValueSetStr(pVal, -1, zSql, SQLITE_UTF16NATIVE, SQLITE_STATIC);
110044 zSql8 = sqlite3ValueText(pVal, SQLITE_UTF8);
110045 if( zSql8 ){
110046 rc = sqlite3_complete(zSql8);
110047 }else{
110048 rc = SQLITE_NOMEM;
110050 sqlite3ValueFree(pVal);
110051 return sqlite3ApiExit(0, rc);
110053 #endif /* SQLITE_OMIT_UTF16 */
110054 #endif /* SQLITE_OMIT_COMPLETE */
110056 /************** End of complete.c ********************************************/
110057 /************** Begin file main.c ********************************************/
110059 ** 2001 September 15
110061 ** The author disclaims copyright to this source code. In place of
110062 ** a legal notice, here is a blessing:
110064 ** May you do good and not evil.
110065 ** May you find forgiveness for yourself and forgive others.
110066 ** May you share freely, never taking more than you give.
110068 *************************************************************************
110069 ** Main file for the SQLite library. The routines in this file
110070 ** implement the programmer interface to the library. Routines in
110071 ** other files are for internal use by SQLite and should not be
110072 ** accessed by users of the library.
110075 #ifdef SQLITE_ENABLE_FTS3
110076 /************** Include fts3.h in the middle of main.c ***********************/
110077 /************** Begin file fts3.h ********************************************/
110079 ** 2006 Oct 10
110081 ** The author disclaims copyright to this source code. In place of
110082 ** a legal notice, here is a blessing:
110084 ** May you do good and not evil.
110085 ** May you find forgiveness for yourself and forgive others.
110086 ** May you share freely, never taking more than you give.
110088 ******************************************************************************
110090 ** This header file is used by programs that want to link against the
110091 ** FTS3 library. All it does is declare the sqlite3Fts3Init() interface.
110094 #if 0
110095 extern "C" {
110096 #endif /* __cplusplus */
110098 SQLITE_PRIVATE int sqlite3Fts3Init(sqlite3 *db);
110100 #if 0
110101 } /* extern "C" */
110102 #endif /* __cplusplus */
110104 /************** End of fts3.h ************************************************/
110105 /************** Continuing where we left off in main.c ***********************/
110106 #endif
110107 #ifdef SQLITE_ENABLE_RTREE
110108 /************** Include rtree.h in the middle of main.c **********************/
110109 /************** Begin file rtree.h *******************************************/
110111 ** 2008 May 26
110113 ** The author disclaims copyright to this source code. In place of
110114 ** a legal notice, here is a blessing:
110116 ** May you do good and not evil.
110117 ** May you find forgiveness for yourself and forgive others.
110118 ** May you share freely, never taking more than you give.
110120 ******************************************************************************
110122 ** This header file is used by programs that want to link against the
110123 ** RTREE library. All it does is declare the sqlite3RtreeInit() interface.
110126 #if 0
110127 extern "C" {
110128 #endif /* __cplusplus */
110130 SQLITE_PRIVATE int sqlite3RtreeInit(sqlite3 *db);
110132 #if 0
110133 } /* extern "C" */
110134 #endif /* __cplusplus */
110136 /************** End of rtree.h ***********************************************/
110137 /************** Continuing where we left off in main.c ***********************/
110138 #endif
110139 #ifdef SQLITE_ENABLE_ICU
110140 /************** Include sqliteicu.h in the middle of main.c ******************/
110141 /************** Begin file sqliteicu.h ***************************************/
110143 ** 2008 May 26
110145 ** The author disclaims copyright to this source code. In place of
110146 ** a legal notice, here is a blessing:
110148 ** May you do good and not evil.
110149 ** May you find forgiveness for yourself and forgive others.
110150 ** May you share freely, never taking more than you give.
110152 ******************************************************************************
110154 ** This header file is used by programs that want to link against the
110155 ** ICU extension. All it does is declare the sqlite3IcuInit() interface.
110158 #if 0
110159 extern "C" {
110160 #endif /* __cplusplus */
110162 SQLITE_PRIVATE int sqlite3IcuInit(sqlite3 *db);
110164 #if 0
110165 } /* extern "C" */
110166 #endif /* __cplusplus */
110169 /************** End of sqliteicu.h *******************************************/
110170 /************** Continuing where we left off in main.c ***********************/
110171 #endif
110173 #ifndef SQLITE_AMALGAMATION
110174 /* IMPLEMENTATION-OF: R-46656-45156 The sqlite3_version[] string constant
110175 ** contains the text of SQLITE_VERSION macro.
110177 SQLITE_API const char sqlite3_version[] = SQLITE_VERSION;
110178 #endif
110180 /* IMPLEMENTATION-OF: R-53536-42575 The sqlite3_libversion() function returns
110181 ** a pointer to the to the sqlite3_version[] string constant.
110183 SQLITE_API const char *sqlite3_libversion(void){ return sqlite3_version; }
110185 /* IMPLEMENTATION-OF: R-63124-39300 The sqlite3_sourceid() function returns a
110186 ** pointer to a string constant whose value is the same as the
110187 ** SQLITE_SOURCE_ID C preprocessor macro.
110189 SQLITE_API const char *sqlite3_sourceid(void){ return SQLITE_SOURCE_ID; }
110191 /* IMPLEMENTATION-OF: R-35210-63508 The sqlite3_libversion_number() function
110192 ** returns an integer equal to SQLITE_VERSION_NUMBER.
110194 SQLITE_API int sqlite3_libversion_number(void){ return SQLITE_VERSION_NUMBER; }
110196 /* IMPLEMENTATION-OF: R-54823-41343 The sqlite3_threadsafe() function returns
110197 ** zero if and only if SQLite was compiled mutexing code omitted due to
110198 ** the SQLITE_THREADSAFE compile-time option being set to 0.
110200 SQLITE_API int sqlite3_threadsafe(void){ return SQLITE_THREADSAFE; }
110202 #if !defined(SQLITE_OMIT_TRACE) && defined(SQLITE_ENABLE_IOTRACE)
110204 ** If the following function pointer is not NULL and if
110205 ** SQLITE_ENABLE_IOTRACE is enabled, then messages describing
110206 ** I/O active are written using this function. These messages
110207 ** are intended for debugging activity only.
110209 SQLITE_PRIVATE void (*sqlite3IoTrace)(const char*, ...) = 0;
110210 #endif
110213 ** If the following global variable points to a string which is the
110214 ** name of a directory, then that directory will be used to store
110215 ** temporary files.
110217 ** See also the "PRAGMA temp_store_directory" SQL command.
110219 SQLITE_API char *sqlite3_temp_directory = 0;
110222 ** Initialize SQLite.
110224 ** This routine must be called to initialize the memory allocation,
110225 ** VFS, and mutex subsystems prior to doing any serious work with
110226 ** SQLite. But as long as you do not compile with SQLITE_OMIT_AUTOINIT
110227 ** this routine will be called automatically by key routines such as
110228 ** sqlite3_open().
110230 ** This routine is a no-op except on its very first call for the process,
110231 ** or for the first call after a call to sqlite3_shutdown.
110233 ** The first thread to call this routine runs the initialization to
110234 ** completion. If subsequent threads call this routine before the first
110235 ** thread has finished the initialization process, then the subsequent
110236 ** threads must block until the first thread finishes with the initialization.
110238 ** The first thread might call this routine recursively. Recursive
110239 ** calls to this routine should not block, of course. Otherwise the
110240 ** initialization process would never complete.
110242 ** Let X be the first thread to enter this routine. Let Y be some other
110243 ** thread. Then while the initial invocation of this routine by X is
110244 ** incomplete, it is required that:
110246 ** * Calls to this routine from Y must block until the outer-most
110247 ** call by X completes.
110249 ** * Recursive calls to this routine from thread X return immediately
110250 ** without blocking.
110252 SQLITE_API int sqlite3_initialize(void){
110253 sqlite3_mutex *pMaster; /* The main static mutex */
110254 int rc; /* Result code */
110256 #ifdef SQLITE_OMIT_WSD
110257 rc = sqlite3_wsd_init(4096, 24);
110258 if( rc!=SQLITE_OK ){
110259 return rc;
110261 #endif
110263 /* If SQLite is already completely initialized, then this call
110264 ** to sqlite3_initialize() should be a no-op. But the initialization
110265 ** must be complete. So isInit must not be set until the very end
110266 ** of this routine.
110268 if( sqlite3GlobalConfig.isInit ) return SQLITE_OK;
110270 /* Make sure the mutex subsystem is initialized. If unable to
110271 ** initialize the mutex subsystem, return early with the error.
110272 ** If the system is so sick that we are unable to allocate a mutex,
110273 ** there is not much SQLite is going to be able to do.
110275 ** The mutex subsystem must take care of serializing its own
110276 ** initialization.
110278 rc = sqlite3MutexInit();
110279 if( rc ) return rc;
110281 /* Initialize the malloc() system and the recursive pInitMutex mutex.
110282 ** This operation is protected by the STATIC_MASTER mutex. Note that
110283 ** MutexAlloc() is called for a static mutex prior to initializing the
110284 ** malloc subsystem - this implies that the allocation of a static
110285 ** mutex must not require support from the malloc subsystem.
110287 pMaster = sqlite3MutexAlloc(SQLITE_MUTEX_STATIC_MASTER);
110288 sqlite3_mutex_enter(pMaster);
110289 sqlite3GlobalConfig.isMutexInit = 1;
110290 if( !sqlite3GlobalConfig.isMallocInit ){
110291 rc = sqlite3MallocInit();
110293 if( rc==SQLITE_OK ){
110294 sqlite3GlobalConfig.isMallocInit = 1;
110295 if( !sqlite3GlobalConfig.pInitMutex ){
110296 sqlite3GlobalConfig.pInitMutex =
110297 sqlite3MutexAlloc(SQLITE_MUTEX_RECURSIVE);
110298 if( sqlite3GlobalConfig.bCoreMutex && !sqlite3GlobalConfig.pInitMutex ){
110299 rc = SQLITE_NOMEM;
110303 if( rc==SQLITE_OK ){
110304 sqlite3GlobalConfig.nRefInitMutex++;
110306 sqlite3_mutex_leave(pMaster);
110308 /* If rc is not SQLITE_OK at this point, then either the malloc
110309 ** subsystem could not be initialized or the system failed to allocate
110310 ** the pInitMutex mutex. Return an error in either case. */
110311 if( rc!=SQLITE_OK ){
110312 return rc;
110315 /* Do the rest of the initialization under the recursive mutex so
110316 ** that we will be able to handle recursive calls into
110317 ** sqlite3_initialize(). The recursive calls normally come through
110318 ** sqlite3_os_init() when it invokes sqlite3_vfs_register(), but other
110319 ** recursive calls might also be possible.
110321 ** IMPLEMENTATION-OF: R-00140-37445 SQLite automatically serializes calls
110322 ** to the xInit method, so the xInit method need not be threadsafe.
110324 ** The following mutex is what serializes access to the appdef pcache xInit
110325 ** methods. The sqlite3_pcache_methods.xInit() all is embedded in the
110326 ** call to sqlite3PcacheInitialize().
110328 sqlite3_mutex_enter(sqlite3GlobalConfig.pInitMutex);
110329 if( sqlite3GlobalConfig.isInit==0 && sqlite3GlobalConfig.inProgress==0 ){
110330 FuncDefHash *pHash = &GLOBAL(FuncDefHash, sqlite3GlobalFunctions);
110331 sqlite3GlobalConfig.inProgress = 1;
110332 memset(pHash, 0, sizeof(sqlite3GlobalFunctions));
110333 sqlite3RegisterGlobalFunctions();
110334 if( sqlite3GlobalConfig.isPCacheInit==0 ){
110335 rc = sqlite3PcacheInitialize();
110337 if( rc==SQLITE_OK ){
110338 sqlite3GlobalConfig.isPCacheInit = 1;
110339 rc = sqlite3OsInit();
110341 if( rc==SQLITE_OK ){
110342 sqlite3PCacheBufferSetup( sqlite3GlobalConfig.pPage,
110343 sqlite3GlobalConfig.szPage, sqlite3GlobalConfig.nPage);
110344 sqlite3GlobalConfig.isInit = 1;
110346 sqlite3GlobalConfig.inProgress = 0;
110348 sqlite3_mutex_leave(sqlite3GlobalConfig.pInitMutex);
110350 /* Go back under the static mutex and clean up the recursive
110351 ** mutex to prevent a resource leak.
110353 sqlite3_mutex_enter(pMaster);
110354 sqlite3GlobalConfig.nRefInitMutex--;
110355 if( sqlite3GlobalConfig.nRefInitMutex<=0 ){
110356 assert( sqlite3GlobalConfig.nRefInitMutex==0 );
110357 sqlite3_mutex_free(sqlite3GlobalConfig.pInitMutex);
110358 sqlite3GlobalConfig.pInitMutex = 0;
110360 sqlite3_mutex_leave(pMaster);
110362 /* The following is just a sanity check to make sure SQLite has
110363 ** been compiled correctly. It is important to run this code, but
110364 ** we don't want to run it too often and soak up CPU cycles for no
110365 ** reason. So we run it once during initialization.
110367 #ifndef NDEBUG
110368 #ifndef SQLITE_OMIT_FLOATING_POINT
110369 /* This section of code's only "output" is via assert() statements. */
110370 if ( rc==SQLITE_OK ){
110371 u64 x = (((u64)1)<<63)-1;
110372 double y;
110373 assert(sizeof(x)==8);
110374 assert(sizeof(x)==sizeof(y));
110375 memcpy(&y, &x, 8);
110376 assert( sqlite3IsNaN(y) );
110378 #endif
110379 #endif
110381 /* Do extra initialization steps requested by the SQLITE_EXTRA_INIT
110382 ** compile-time option.
110384 #ifdef SQLITE_EXTRA_INIT
110385 if( rc==SQLITE_OK && sqlite3GlobalConfig.isInit ){
110386 int SQLITE_EXTRA_INIT(void);
110387 rc = SQLITE_EXTRA_INIT();
110389 #endif
110391 return rc;
110395 ** Undo the effects of sqlite3_initialize(). Must not be called while
110396 ** there are outstanding database connections or memory allocations or
110397 ** while any part of SQLite is otherwise in use in any thread. This
110398 ** routine is not threadsafe. But it is safe to invoke this routine
110399 ** on when SQLite is already shut down. If SQLite is already shut down
110400 ** when this routine is invoked, then this routine is a harmless no-op.
110402 SQLITE_API int sqlite3_shutdown(void){
110403 if( sqlite3GlobalConfig.isInit ){
110404 sqlite3_os_end();
110405 sqlite3_reset_auto_extension();
110406 sqlite3GlobalConfig.isInit = 0;
110408 if( sqlite3GlobalConfig.isPCacheInit ){
110409 sqlite3PcacheShutdown();
110410 sqlite3GlobalConfig.isPCacheInit = 0;
110412 if( sqlite3GlobalConfig.isMallocInit ){
110413 sqlite3MallocEnd();
110414 sqlite3GlobalConfig.isMallocInit = 0;
110416 if( sqlite3GlobalConfig.isMutexInit ){
110417 sqlite3MutexEnd();
110418 sqlite3GlobalConfig.isMutexInit = 0;
110421 return SQLITE_OK;
110425 ** This API allows applications to modify the global configuration of
110426 ** the SQLite library at run-time.
110428 ** This routine should only be called when there are no outstanding
110429 ** database connections or memory allocations. This routine is not
110430 ** threadsafe. Failure to heed these warnings can lead to unpredictable
110431 ** behavior.
110433 SQLITE_API int sqlite3_config(int op, ...){
110434 va_list ap;
110435 int rc = SQLITE_OK;
110437 /* sqlite3_config() shall return SQLITE_MISUSE if it is invoked while
110438 ** the SQLite library is in use. */
110439 if( sqlite3GlobalConfig.isInit ) return SQLITE_MISUSE_BKPT;
110441 va_start(ap, op);
110442 switch( op ){
110444 /* Mutex configuration options are only available in a threadsafe
110445 ** compile.
110447 #if defined(SQLITE_THREADSAFE) && SQLITE_THREADSAFE>0
110448 case SQLITE_CONFIG_SINGLETHREAD: {
110449 /* Disable all mutexing */
110450 sqlite3GlobalConfig.bCoreMutex = 0;
110451 sqlite3GlobalConfig.bFullMutex = 0;
110452 break;
110454 case SQLITE_CONFIG_MULTITHREAD: {
110455 /* Disable mutexing of database connections */
110456 /* Enable mutexing of core data structures */
110457 sqlite3GlobalConfig.bCoreMutex = 1;
110458 sqlite3GlobalConfig.bFullMutex = 0;
110459 break;
110461 case SQLITE_CONFIG_SERIALIZED: {
110462 /* Enable all mutexing */
110463 sqlite3GlobalConfig.bCoreMutex = 1;
110464 sqlite3GlobalConfig.bFullMutex = 1;
110465 break;
110467 case SQLITE_CONFIG_MUTEX: {
110468 /* Specify an alternative mutex implementation */
110469 sqlite3GlobalConfig.mutex = *va_arg(ap, sqlite3_mutex_methods*);
110470 break;
110472 case SQLITE_CONFIG_GETMUTEX: {
110473 /* Retrieve the current mutex implementation */
110474 *va_arg(ap, sqlite3_mutex_methods*) = sqlite3GlobalConfig.mutex;
110475 break;
110477 #endif
110480 case SQLITE_CONFIG_MALLOC: {
110481 /* Specify an alternative malloc implementation */
110482 sqlite3GlobalConfig.m = *va_arg(ap, sqlite3_mem_methods*);
110483 break;
110485 case SQLITE_CONFIG_GETMALLOC: {
110486 /* Retrieve the current malloc() implementation */
110487 if( sqlite3GlobalConfig.m.xMalloc==0 ) sqlite3MemSetDefault();
110488 *va_arg(ap, sqlite3_mem_methods*) = sqlite3GlobalConfig.m;
110489 break;
110491 case SQLITE_CONFIG_MEMSTATUS: {
110492 /* Enable or disable the malloc status collection */
110493 sqlite3GlobalConfig.bMemstat = va_arg(ap, int);
110494 break;
110496 case SQLITE_CONFIG_SCRATCH: {
110497 /* Designate a buffer for scratch memory space */
110498 sqlite3GlobalConfig.pScratch = va_arg(ap, void*);
110499 sqlite3GlobalConfig.szScratch = va_arg(ap, int);
110500 sqlite3GlobalConfig.nScratch = va_arg(ap, int);
110501 break;
110503 case SQLITE_CONFIG_PAGECACHE: {
110504 /* Designate a buffer for page cache memory space */
110505 sqlite3GlobalConfig.pPage = va_arg(ap, void*);
110506 sqlite3GlobalConfig.szPage = va_arg(ap, int);
110507 sqlite3GlobalConfig.nPage = va_arg(ap, int);
110508 break;
110511 case SQLITE_CONFIG_PCACHE: {
110512 /* Specify an alternative page cache implementation */
110513 sqlite3GlobalConfig.pcache = *va_arg(ap, sqlite3_pcache_methods*);
110514 break;
110517 case SQLITE_CONFIG_GETPCACHE: {
110518 if( sqlite3GlobalConfig.pcache.xInit==0 ){
110519 sqlite3PCacheSetDefault();
110521 *va_arg(ap, sqlite3_pcache_methods*) = sqlite3GlobalConfig.pcache;
110522 break;
110525 #if defined(SQLITE_ENABLE_MEMSYS3) || defined(SQLITE_ENABLE_MEMSYS5)
110526 case SQLITE_CONFIG_HEAP: {
110527 /* Designate a buffer for heap memory space */
110528 sqlite3GlobalConfig.pHeap = va_arg(ap, void*);
110529 sqlite3GlobalConfig.nHeap = va_arg(ap, int);
110530 sqlite3GlobalConfig.mnReq = va_arg(ap, int);
110532 if( sqlite3GlobalConfig.mnReq<1 ){
110533 sqlite3GlobalConfig.mnReq = 1;
110534 }else if( sqlite3GlobalConfig.mnReq>(1<<12) ){
110535 /* cap min request size at 2^12 */
110536 sqlite3GlobalConfig.mnReq = (1<<12);
110539 if( sqlite3GlobalConfig.pHeap==0 ){
110540 /* If the heap pointer is NULL, then restore the malloc implementation
110541 ** back to NULL pointers too. This will cause the malloc to go
110542 ** back to its default implementation when sqlite3_initialize() is
110543 ** run.
110545 memset(&sqlite3GlobalConfig.m, 0, sizeof(sqlite3GlobalConfig.m));
110546 }else{
110547 /* The heap pointer is not NULL, then install one of the
110548 ** mem5.c/mem3.c methods. If neither ENABLE_MEMSYS3 nor
110549 ** ENABLE_MEMSYS5 is defined, return an error.
110551 #ifdef SQLITE_ENABLE_MEMSYS3
110552 sqlite3GlobalConfig.m = *sqlite3MemGetMemsys3();
110553 #endif
110554 #ifdef SQLITE_ENABLE_MEMSYS5
110555 sqlite3GlobalConfig.m = *sqlite3MemGetMemsys5();
110556 #endif
110558 break;
110560 #endif
110562 case SQLITE_CONFIG_LOOKASIDE: {
110563 sqlite3GlobalConfig.szLookaside = va_arg(ap, int);
110564 sqlite3GlobalConfig.nLookaside = va_arg(ap, int);
110565 break;
110568 /* Record a pointer to the logger funcction and its first argument.
110569 ** The default is NULL. Logging is disabled if the function pointer is
110570 ** NULL.
110572 case SQLITE_CONFIG_LOG: {
110573 /* MSVC is picky about pulling func ptrs from va lists.
110574 ** http://support.microsoft.com/kb/47961
110575 ** sqlite3GlobalConfig.xLog = va_arg(ap, void(*)(void*,int,const char*));
110577 typedef void(*LOGFUNC_t)(void*,int,const char*);
110578 sqlite3GlobalConfig.xLog = va_arg(ap, LOGFUNC_t);
110579 sqlite3GlobalConfig.pLogArg = va_arg(ap, void*);
110580 break;
110583 case SQLITE_CONFIG_URI: {
110584 sqlite3GlobalConfig.bOpenUri = va_arg(ap, int);
110585 break;
110588 default: {
110589 rc = SQLITE_ERROR;
110590 break;
110593 va_end(ap);
110594 return rc;
110598 ** Set up the lookaside buffers for a database connection.
110599 ** Return SQLITE_OK on success.
110600 ** If lookaside is already active, return SQLITE_BUSY.
110602 ** The sz parameter is the number of bytes in each lookaside slot.
110603 ** The cnt parameter is the number of slots. If pStart is NULL the
110604 ** space for the lookaside memory is obtained from sqlite3_malloc().
110605 ** If pStart is not NULL then it is sz*cnt bytes of memory to use for
110606 ** the lookaside memory.
110608 static int setupLookaside(sqlite3 *db, void *pBuf, int sz, int cnt){
110609 void *pStart;
110610 if( db->lookaside.nOut ){
110611 return SQLITE_BUSY;
110613 /* Free any existing lookaside buffer for this handle before
110614 ** allocating a new one so we don't have to have space for
110615 ** both at the same time.
110617 if( db->lookaside.bMalloced ){
110618 sqlite3_free(db->lookaside.pStart);
110620 /* The size of a lookaside slot needs to be larger than a pointer
110621 ** to be useful.
110623 if( sz<=(int)sizeof(LookasideSlot*) ) sz = 0;
110624 if( cnt<0 ) cnt = 0;
110625 if( sz==0 || cnt==0 ){
110626 sz = 0;
110627 pStart = 0;
110628 }else if( pBuf==0 ){
110629 sz = ROUNDDOWN8(sz); /* IMP: R-33038-09382 */
110630 sqlite3BeginBenignMalloc();
110631 pStart = sqlite3Malloc( sz*cnt ); /* IMP: R-61949-35727 */
110632 sqlite3EndBenignMalloc();
110633 }else{
110634 sz = ROUNDDOWN8(sz); /* IMP: R-33038-09382 */
110635 pStart = pBuf;
110637 db->lookaside.pStart = pStart;
110638 db->lookaside.pFree = 0;
110639 db->lookaside.sz = (u16)sz;
110640 if( pStart ){
110641 int i;
110642 LookasideSlot *p;
110643 assert( sz > (int)sizeof(LookasideSlot*) );
110644 p = (LookasideSlot*)pStart;
110645 for(i=cnt-1; i>=0; i--){
110646 p->pNext = db->lookaside.pFree;
110647 db->lookaside.pFree = p;
110648 p = (LookasideSlot*)&((u8*)p)[sz];
110650 db->lookaside.pEnd = p;
110651 db->lookaside.bEnabled = 1;
110652 db->lookaside.bMalloced = pBuf==0 ?1:0;
110653 }else{
110654 db->lookaside.pEnd = 0;
110655 db->lookaside.bEnabled = 0;
110656 db->lookaside.bMalloced = 0;
110658 return SQLITE_OK;
110662 ** Return the mutex associated with a database connection.
110664 SQLITE_API sqlite3_mutex *sqlite3_db_mutex(sqlite3 *db){
110665 return db->mutex;
110669 ** Configuration settings for an individual database connection
110671 SQLITE_API int sqlite3_db_config(sqlite3 *db, int op, ...){
110672 va_list ap;
110673 int rc;
110674 va_start(ap, op);
110675 switch( op ){
110676 case SQLITE_DBCONFIG_LOOKASIDE: {
110677 void *pBuf = va_arg(ap, void*); /* IMP: R-26835-10964 */
110678 int sz = va_arg(ap, int); /* IMP: R-47871-25994 */
110679 int cnt = va_arg(ap, int); /* IMP: R-04460-53386 */
110680 rc = setupLookaside(db, pBuf, sz, cnt);
110681 break;
110683 default: {
110684 static const struct {
110685 int op; /* The opcode */
110686 u32 mask; /* Mask of the bit in sqlite3.flags to set/clear */
110687 } aFlagOp[] = {
110688 { SQLITE_DBCONFIG_ENABLE_FKEY, SQLITE_ForeignKeys },
110689 { SQLITE_DBCONFIG_ENABLE_TRIGGER, SQLITE_EnableTrigger },
110691 unsigned int i;
110692 rc = SQLITE_ERROR; /* IMP: R-42790-23372 */
110693 for(i=0; i<ArraySize(aFlagOp); i++){
110694 if( aFlagOp[i].op==op ){
110695 int onoff = va_arg(ap, int);
110696 int *pRes = va_arg(ap, int*);
110697 int oldFlags = db->flags;
110698 if( onoff>0 ){
110699 db->flags |= aFlagOp[i].mask;
110700 }else if( onoff==0 ){
110701 db->flags &= ~aFlagOp[i].mask;
110703 if( oldFlags!=db->flags ){
110704 sqlite3ExpirePreparedStatements(db);
110706 if( pRes ){
110707 *pRes = (db->flags & aFlagOp[i].mask)!=0;
110709 rc = SQLITE_OK;
110710 break;
110713 break;
110716 va_end(ap);
110717 return rc;
110722 ** Return true if the buffer z[0..n-1] contains all spaces.
110724 static int allSpaces(const char *z, int n){
110725 while( n>0 && z[n-1]==' ' ){ n--; }
110726 return n==0;
110730 ** This is the default collating function named "BINARY" which is always
110731 ** available.
110733 ** If the padFlag argument is not NULL then space padding at the end
110734 ** of strings is ignored. This implements the RTRIM collation.
110736 static int binCollFunc(
110737 void *padFlag,
110738 int nKey1, const void *pKey1,
110739 int nKey2, const void *pKey2
110741 int rc, n;
110742 n = nKey1<nKey2 ? nKey1 : nKey2;
110743 rc = memcmp(pKey1, pKey2, n);
110744 if( rc==0 ){
110745 if( padFlag
110746 && allSpaces(((char*)pKey1)+n, nKey1-n)
110747 && allSpaces(((char*)pKey2)+n, nKey2-n)
110749 /* Leave rc unchanged at 0 */
110750 }else{
110751 rc = nKey1 - nKey2;
110754 return rc;
110758 ** Another built-in collating sequence: NOCASE.
110760 ** This collating sequence is intended to be used for "case independant
110761 ** comparison". SQLite's knowledge of upper and lower case equivalents
110762 ** extends only to the 26 characters used in the English language.
110764 ** At the moment there is only a UTF-8 implementation.
110766 static int nocaseCollatingFunc(
110767 void *NotUsed,
110768 int nKey1, const void *pKey1,
110769 int nKey2, const void *pKey2
110771 int r = sqlite3StrNICmp(
110772 (const char *)pKey1, (const char *)pKey2, (nKey1<nKey2)?nKey1:nKey2);
110773 UNUSED_PARAMETER(NotUsed);
110774 if( 0==r ){
110775 r = nKey1-nKey2;
110777 return r;
110781 ** Return the ROWID of the most recent insert
110783 SQLITE_API sqlite_int64 sqlite3_last_insert_rowid(sqlite3 *db){
110784 return db->lastRowid;
110788 ** Return the number of changes in the most recent call to sqlite3_exec().
110790 SQLITE_API int sqlite3_changes(sqlite3 *db){
110791 return db->nChange;
110795 ** Return the number of changes since the database handle was opened.
110797 SQLITE_API int sqlite3_total_changes(sqlite3 *db){
110798 return db->nTotalChange;
110802 ** Close all open savepoints. This function only manipulates fields of the
110803 ** database handle object, it does not close any savepoints that may be open
110804 ** at the b-tree/pager level.
110806 SQLITE_PRIVATE void sqlite3CloseSavepoints(sqlite3 *db){
110807 while( db->pSavepoint ){
110808 Savepoint *pTmp = db->pSavepoint;
110809 db->pSavepoint = pTmp->pNext;
110810 sqlite3DbFree(db, pTmp);
110812 db->nSavepoint = 0;
110813 db->nStatement = 0;
110814 db->isTransactionSavepoint = 0;
110818 ** Invoke the destructor function associated with FuncDef p, if any. Except,
110819 ** if this is not the last copy of the function, do not invoke it. Multiple
110820 ** copies of a single function are created when create_function() is called
110821 ** with SQLITE_ANY as the encoding.
110823 static void functionDestroy(sqlite3 *db, FuncDef *p){
110824 FuncDestructor *pDestructor = p->pDestructor;
110825 if( pDestructor ){
110826 pDestructor->nRef--;
110827 if( pDestructor->nRef==0 ){
110828 pDestructor->xDestroy(pDestructor->pUserData);
110829 sqlite3DbFree(db, pDestructor);
110835 ** Close an existing SQLite database
110837 SQLITE_API int sqlite3_close(sqlite3 *db){
110838 HashElem *i; /* Hash table iterator */
110839 int j;
110841 if( !db ){
110842 return SQLITE_OK;
110844 if( !sqlite3SafetyCheckSickOrOk(db) ){
110845 return SQLITE_MISUSE_BKPT;
110847 sqlite3_mutex_enter(db->mutex);
110849 /* Force xDestroy calls on all virtual tables */
110850 sqlite3ResetInternalSchema(db, -1);
110852 /* If a transaction is open, the ResetInternalSchema() call above
110853 ** will not have called the xDisconnect() method on any virtual
110854 ** tables in the db->aVTrans[] array. The following sqlite3VtabRollback()
110855 ** call will do so. We need to do this before the check for active
110856 ** SQL statements below, as the v-table implementation may be storing
110857 ** some prepared statements internally.
110859 sqlite3VtabRollback(db);
110861 /* If there are any outstanding VMs, return SQLITE_BUSY. */
110862 if( db->pVdbe ){
110863 sqlite3Error(db, SQLITE_BUSY,
110864 "unable to close due to unfinalised statements");
110865 sqlite3_mutex_leave(db->mutex);
110866 return SQLITE_BUSY;
110868 assert( sqlite3SafetyCheckSickOrOk(db) );
110870 for(j=0; j<db->nDb; j++){
110871 Btree *pBt = db->aDb[j].pBt;
110872 if( pBt && sqlite3BtreeIsInBackup(pBt) ){
110873 sqlite3Error(db, SQLITE_BUSY,
110874 "unable to close due to unfinished backup operation");
110875 sqlite3_mutex_leave(db->mutex);
110876 return SQLITE_BUSY;
110880 /* Free any outstanding Savepoint structures. */
110881 sqlite3CloseSavepoints(db);
110883 for(j=0; j<db->nDb; j++){
110884 struct Db *pDb = &db->aDb[j];
110885 if( pDb->pBt ){
110886 sqlite3BtreeClose(pDb->pBt);
110887 pDb->pBt = 0;
110888 if( j!=1 ){
110889 pDb->pSchema = 0;
110893 sqlite3ResetInternalSchema(db, -1);
110895 /* Tell the code in notify.c that the connection no longer holds any
110896 ** locks and does not require any further unlock-notify callbacks.
110898 sqlite3ConnectionClosed(db);
110900 assert( db->nDb<=2 );
110901 assert( db->aDb==db->aDbStatic );
110902 for(j=0; j<ArraySize(db->aFunc.a); j++){
110903 FuncDef *pNext, *pHash, *p;
110904 for(p=db->aFunc.a[j]; p; p=pHash){
110905 pHash = p->pHash;
110906 while( p ){
110907 functionDestroy(db, p);
110908 pNext = p->pNext;
110909 sqlite3DbFree(db, p);
110910 p = pNext;
110914 for(i=sqliteHashFirst(&db->aCollSeq); i; i=sqliteHashNext(i)){
110915 CollSeq *pColl = (CollSeq *)sqliteHashData(i);
110916 /* Invoke any destructors registered for collation sequence user data. */
110917 for(j=0; j<3; j++){
110918 if( pColl[j].xDel ){
110919 pColl[j].xDel(pColl[j].pUser);
110922 sqlite3DbFree(db, pColl);
110924 sqlite3HashClear(&db->aCollSeq);
110925 #ifndef SQLITE_OMIT_VIRTUALTABLE
110926 for(i=sqliteHashFirst(&db->aModule); i; i=sqliteHashNext(i)){
110927 Module *pMod = (Module *)sqliteHashData(i);
110928 if( pMod->xDestroy ){
110929 pMod->xDestroy(pMod->pAux);
110931 sqlite3DbFree(db, pMod);
110933 sqlite3HashClear(&db->aModule);
110934 #endif
110936 sqlite3Error(db, SQLITE_OK, 0); /* Deallocates any cached error strings. */
110937 if( db->pErr ){
110938 sqlite3ValueFree(db->pErr);
110940 sqlite3CloseExtensions(db);
110942 db->magic = SQLITE_MAGIC_ERROR;
110944 /* The temp-database schema is allocated differently from the other schema
110945 ** objects (using sqliteMalloc() directly, instead of sqlite3BtreeSchema()).
110946 ** So it needs to be freed here. Todo: Why not roll the temp schema into
110947 ** the same sqliteMalloc() as the one that allocates the database
110948 ** structure?
110950 sqlite3DbFree(db, db->aDb[1].pSchema);
110951 sqlite3_mutex_leave(db->mutex);
110952 db->magic = SQLITE_MAGIC_CLOSED;
110953 sqlite3_mutex_free(db->mutex);
110954 assert( db->lookaside.nOut==0 ); /* Fails on a lookaside memory leak */
110955 if( db->lookaside.bMalloced ){
110956 sqlite3_free(db->lookaside.pStart);
110958 sqlite3_free(db);
110959 return SQLITE_OK;
110963 ** Rollback all database files.
110965 SQLITE_PRIVATE void sqlite3RollbackAll(sqlite3 *db){
110966 int i;
110967 int inTrans = 0;
110968 assert( sqlite3_mutex_held(db->mutex) );
110969 sqlite3BeginBenignMalloc();
110970 for(i=0; i<db->nDb; i++){
110971 if( db->aDb[i].pBt ){
110972 if( sqlite3BtreeIsInTrans(db->aDb[i].pBt) ){
110973 inTrans = 1;
110975 sqlite3BtreeRollback(db->aDb[i].pBt);
110976 db->aDb[i].inTrans = 0;
110979 sqlite3VtabRollback(db);
110980 sqlite3EndBenignMalloc();
110982 if( db->flags&SQLITE_InternChanges ){
110983 sqlite3ExpirePreparedStatements(db);
110984 sqlite3ResetInternalSchema(db, -1);
110987 /* Any deferred constraint violations have now been resolved. */
110988 db->nDeferredCons = 0;
110990 /* If one has been configured, invoke the rollback-hook callback */
110991 if( db->xRollbackCallback && (inTrans || !db->autoCommit) ){
110992 db->xRollbackCallback(db->pRollbackArg);
110997 ** Return a static string that describes the kind of error specified in the
110998 ** argument.
111000 SQLITE_PRIVATE const char *sqlite3ErrStr(int rc){
111001 static const char* const aMsg[] = {
111002 /* SQLITE_OK */ "not an error",
111003 /* SQLITE_ERROR */ "SQL logic error or missing database",
111004 /* SQLITE_INTERNAL */ 0,
111005 /* SQLITE_PERM */ "access permission denied",
111006 /* SQLITE_ABORT */ "callback requested query abort",
111007 /* SQLITE_BUSY */ "database is locked",
111008 /* SQLITE_LOCKED */ "database table is locked",
111009 /* SQLITE_NOMEM */ "out of memory",
111010 /* SQLITE_READONLY */ "attempt to write a readonly database",
111011 /* SQLITE_INTERRUPT */ "interrupted",
111012 /* SQLITE_IOERR */ "disk I/O error",
111013 /* SQLITE_CORRUPT */ "database disk image is malformed",
111014 /* SQLITE_NOTFOUND */ "unknown operation",
111015 /* SQLITE_FULL */ "database or disk is full",
111016 /* SQLITE_CANTOPEN */ "unable to open database file",
111017 /* SQLITE_PROTOCOL */ "locking protocol",
111018 /* SQLITE_EMPTY */ "table contains no data",
111019 /* SQLITE_SCHEMA */ "database schema has changed",
111020 /* SQLITE_TOOBIG */ "string or blob too big",
111021 /* SQLITE_CONSTRAINT */ "constraint failed",
111022 /* SQLITE_MISMATCH */ "datatype mismatch",
111023 /* SQLITE_MISUSE */ "library routine called out of sequence",
111024 /* SQLITE_NOLFS */ "large file support is disabled",
111025 /* SQLITE_AUTH */ "authorization denied",
111026 /* SQLITE_FORMAT */ "auxiliary database format error",
111027 /* SQLITE_RANGE */ "bind or column index out of range",
111028 /* SQLITE_NOTADB */ "file is encrypted or is not a database",
111030 rc &= 0xff;
111031 if( ALWAYS(rc>=0) && rc<(int)(sizeof(aMsg)/sizeof(aMsg[0])) && aMsg[rc]!=0 ){
111032 return aMsg[rc];
111033 }else{
111034 return "unknown error";
111039 ** This routine implements a busy callback that sleeps and tries
111040 ** again until a timeout value is reached. The timeout value is
111041 ** an integer number of milliseconds passed in as the first
111042 ** argument.
111044 static int sqliteDefaultBusyCallback(
111045 void *ptr, /* Database connection */
111046 int count /* Number of times table has been busy */
111048 #if SQLITE_OS_WIN || (defined(HAVE_USLEEP) && HAVE_USLEEP)
111049 static const u8 delays[] =
111050 { 1, 2, 5, 10, 15, 20, 25, 25, 25, 50, 50, 100 };
111051 static const u8 totals[] =
111052 { 0, 1, 3, 8, 18, 33, 53, 78, 103, 128, 178, 228 };
111053 # define NDELAY ArraySize(delays)
111054 sqlite3 *db = (sqlite3 *)ptr;
111055 int timeout = db->busyTimeout;
111056 int delay, prior;
111058 assert( count>=0 );
111059 if( count < NDELAY ){
111060 delay = delays[count];
111061 prior = totals[count];
111062 }else{
111063 delay = delays[NDELAY-1];
111064 prior = totals[NDELAY-1] + delay*(count-(NDELAY-1));
111066 if( prior + delay > timeout ){
111067 delay = timeout - prior;
111068 if( delay<=0 ) return 0;
111070 sqlite3OsSleep(db->pVfs, delay*1000);
111071 return 1;
111072 #else
111073 sqlite3 *db = (sqlite3 *)ptr;
111074 int timeout = ((sqlite3 *)ptr)->busyTimeout;
111075 if( (count+1)*1000 > timeout ){
111076 return 0;
111078 sqlite3OsSleep(db->pVfs, 1000000);
111079 return 1;
111080 #endif
111084 ** Invoke the given busy handler.
111086 ** This routine is called when an operation failed with a lock.
111087 ** If this routine returns non-zero, the lock is retried. If it
111088 ** returns 0, the operation aborts with an SQLITE_BUSY error.
111090 SQLITE_PRIVATE int sqlite3InvokeBusyHandler(BusyHandler *p){
111091 int rc;
111092 if( NEVER(p==0) || p->xFunc==0 || p->nBusy<0 ) return 0;
111093 rc = p->xFunc(p->pArg, p->nBusy);
111094 if( rc==0 ){
111095 p->nBusy = -1;
111096 }else{
111097 p->nBusy++;
111099 return rc;
111103 ** This routine sets the busy callback for an Sqlite database to the
111104 ** given callback function with the given argument.
111106 SQLITE_API int sqlite3_busy_handler(
111107 sqlite3 *db,
111108 int (*xBusy)(void*,int),
111109 void *pArg
111111 sqlite3_mutex_enter(db->mutex);
111112 db->busyHandler.xFunc = xBusy;
111113 db->busyHandler.pArg = pArg;
111114 db->busyHandler.nBusy = 0;
111115 sqlite3_mutex_leave(db->mutex);
111116 return SQLITE_OK;
111119 #ifndef SQLITE_OMIT_PROGRESS_CALLBACK
111121 ** This routine sets the progress callback for an Sqlite database to the
111122 ** given callback function with the given argument. The progress callback will
111123 ** be invoked every nOps opcodes.
111125 SQLITE_API void sqlite3_progress_handler(
111126 sqlite3 *db,
111127 int nOps,
111128 int (*xProgress)(void*),
111129 void *pArg
111131 sqlite3_mutex_enter(db->mutex);
111132 if( nOps>0 ){
111133 db->xProgress = xProgress;
111134 db->nProgressOps = nOps;
111135 db->pProgressArg = pArg;
111136 }else{
111137 db->xProgress = 0;
111138 db->nProgressOps = 0;
111139 db->pProgressArg = 0;
111141 sqlite3_mutex_leave(db->mutex);
111143 #endif
111147 ** This routine installs a default busy handler that waits for the
111148 ** specified number of milliseconds before returning 0.
111150 SQLITE_API int sqlite3_busy_timeout(sqlite3 *db, int ms){
111151 if( ms>0 ){
111152 db->busyTimeout = ms;
111153 sqlite3_busy_handler(db, sqliteDefaultBusyCallback, (void*)db);
111154 }else{
111155 sqlite3_busy_handler(db, 0, 0);
111157 return SQLITE_OK;
111161 ** Cause any pending operation to stop at its earliest opportunity.
111163 SQLITE_API void sqlite3_interrupt(sqlite3 *db){
111164 db->u1.isInterrupted = 1;
111169 ** This function is exactly the same as sqlite3_create_function(), except
111170 ** that it is designed to be called by internal code. The difference is
111171 ** that if a malloc() fails in sqlite3_create_function(), an error code
111172 ** is returned and the mallocFailed flag cleared.
111174 SQLITE_PRIVATE int sqlite3CreateFunc(
111175 sqlite3 *db,
111176 const char *zFunctionName,
111177 int nArg,
111178 int enc,
111179 void *pUserData,
111180 void (*xFunc)(sqlite3_context*,int,sqlite3_value **),
111181 void (*xStep)(sqlite3_context*,int,sqlite3_value **),
111182 void (*xFinal)(sqlite3_context*),
111183 FuncDestructor *pDestructor
111185 FuncDef *p;
111186 int nName;
111188 assert( sqlite3_mutex_held(db->mutex) );
111189 if( zFunctionName==0 ||
111190 (xFunc && (xFinal || xStep)) ||
111191 (!xFunc && (xFinal && !xStep)) ||
111192 (!xFunc && (!xFinal && xStep)) ||
111193 (nArg<-1 || nArg>SQLITE_MAX_FUNCTION_ARG) ||
111194 (255<(nName = sqlite3Strlen30( zFunctionName))) ){
111195 return SQLITE_MISUSE_BKPT;
111198 #ifndef SQLITE_OMIT_UTF16
111199 /* If SQLITE_UTF16 is specified as the encoding type, transform this
111200 ** to one of SQLITE_UTF16LE or SQLITE_UTF16BE using the
111201 ** SQLITE_UTF16NATIVE macro. SQLITE_UTF16 is not used internally.
111203 ** If SQLITE_ANY is specified, add three versions of the function
111204 ** to the hash table.
111206 if( enc==SQLITE_UTF16 ){
111207 enc = SQLITE_UTF16NATIVE;
111208 }else if( enc==SQLITE_ANY ){
111209 int rc;
111210 rc = sqlite3CreateFunc(db, zFunctionName, nArg, SQLITE_UTF8,
111211 pUserData, xFunc, xStep, xFinal, pDestructor);
111212 if( rc==SQLITE_OK ){
111213 rc = sqlite3CreateFunc(db, zFunctionName, nArg, SQLITE_UTF16LE,
111214 pUserData, xFunc, xStep, xFinal, pDestructor);
111216 if( rc!=SQLITE_OK ){
111217 return rc;
111219 enc = SQLITE_UTF16BE;
111221 #else
111222 enc = SQLITE_UTF8;
111223 #endif
111225 /* Check if an existing function is being overridden or deleted. If so,
111226 ** and there are active VMs, then return SQLITE_BUSY. If a function
111227 ** is being overridden/deleted but there are no active VMs, allow the
111228 ** operation to continue but invalidate all precompiled statements.
111230 p = sqlite3FindFunction(db, zFunctionName, nName, nArg, (u8)enc, 0);
111231 if( p && p->iPrefEnc==enc && p->nArg==nArg ){
111232 if( db->activeVdbeCnt ){
111233 sqlite3Error(db, SQLITE_BUSY,
111234 "unable to delete/modify user-function due to active statements");
111235 assert( !db->mallocFailed );
111236 return SQLITE_BUSY;
111237 }else{
111238 sqlite3ExpirePreparedStatements(db);
111242 p = sqlite3FindFunction(db, zFunctionName, nName, nArg, (u8)enc, 1);
111243 assert(p || db->mallocFailed);
111244 if( !p ){
111245 return SQLITE_NOMEM;
111248 /* If an older version of the function with a configured destructor is
111249 ** being replaced invoke the destructor function here. */
111250 functionDestroy(db, p);
111252 if( pDestructor ){
111253 pDestructor->nRef++;
111255 p->pDestructor = pDestructor;
111256 p->flags = 0;
111257 p->xFunc = xFunc;
111258 p->xStep = xStep;
111259 p->xFinalize = xFinal;
111260 p->pUserData = pUserData;
111261 p->nArg = (u16)nArg;
111262 return SQLITE_OK;
111266 ** Create new user functions.
111268 SQLITE_API int sqlite3_create_function(
111269 sqlite3 *db,
111270 const char *zFunc,
111271 int nArg,
111272 int enc,
111273 void *p,
111274 void (*xFunc)(sqlite3_context*,int,sqlite3_value **),
111275 void (*xStep)(sqlite3_context*,int,sqlite3_value **),
111276 void (*xFinal)(sqlite3_context*)
111278 return sqlite3_create_function_v2(db, zFunc, nArg, enc, p, xFunc, xStep,
111279 xFinal, 0);
111282 SQLITE_API int sqlite3_create_function_v2(
111283 sqlite3 *db,
111284 const char *zFunc,
111285 int nArg,
111286 int enc,
111287 void *p,
111288 void (*xFunc)(sqlite3_context*,int,sqlite3_value **),
111289 void (*xStep)(sqlite3_context*,int,sqlite3_value **),
111290 void (*xFinal)(sqlite3_context*),
111291 void (*xDestroy)(void *)
111293 int rc = SQLITE_ERROR;
111294 FuncDestructor *pArg = 0;
111295 sqlite3_mutex_enter(db->mutex);
111296 if( xDestroy ){
111297 pArg = (FuncDestructor *)sqlite3DbMallocZero(db, sizeof(FuncDestructor));
111298 if( !pArg ){
111299 xDestroy(p);
111300 goto out;
111302 pArg->xDestroy = xDestroy;
111303 pArg->pUserData = p;
111305 rc = sqlite3CreateFunc(db, zFunc, nArg, enc, p, xFunc, xStep, xFinal, pArg);
111306 if( pArg && pArg->nRef==0 ){
111307 assert( rc!=SQLITE_OK );
111308 xDestroy(p);
111309 sqlite3DbFree(db, pArg);
111313 rc = sqlite3ApiExit(db, rc);
111314 sqlite3_mutex_leave(db->mutex);
111315 return rc;
111318 #ifndef SQLITE_OMIT_UTF16
111319 SQLITE_API int sqlite3_create_function16(
111320 sqlite3 *db,
111321 const void *zFunctionName,
111322 int nArg,
111323 int eTextRep,
111324 void *p,
111325 void (*xFunc)(sqlite3_context*,int,sqlite3_value**),
111326 void (*xStep)(sqlite3_context*,int,sqlite3_value**),
111327 void (*xFinal)(sqlite3_context*)
111329 int rc;
111330 char *zFunc8;
111331 sqlite3_mutex_enter(db->mutex);
111332 assert( !db->mallocFailed );
111333 zFunc8 = sqlite3Utf16to8(db, zFunctionName, -1, SQLITE_UTF16NATIVE);
111334 rc = sqlite3CreateFunc(db, zFunc8, nArg, eTextRep, p, xFunc, xStep, xFinal,0);
111335 sqlite3DbFree(db, zFunc8);
111336 rc = sqlite3ApiExit(db, rc);
111337 sqlite3_mutex_leave(db->mutex);
111338 return rc;
111340 #endif
111344 ** Declare that a function has been overloaded by a virtual table.
111346 ** If the function already exists as a regular global function, then
111347 ** this routine is a no-op. If the function does not exist, then create
111348 ** a new one that always throws a run-time error.
111350 ** When virtual tables intend to provide an overloaded function, they
111351 ** should call this routine to make sure the global function exists.
111352 ** A global function must exist in order for name resolution to work
111353 ** properly.
111355 SQLITE_API int sqlite3_overload_function(
111356 sqlite3 *db,
111357 const char *zName,
111358 int nArg
111360 int nName = sqlite3Strlen30(zName);
111361 int rc;
111362 sqlite3_mutex_enter(db->mutex);
111363 if( sqlite3FindFunction(db, zName, nName, nArg, SQLITE_UTF8, 0)==0 ){
111364 sqlite3CreateFunc(db, zName, nArg, SQLITE_UTF8,
111365 0, sqlite3InvalidFunction, 0, 0, 0);
111367 rc = sqlite3ApiExit(db, SQLITE_OK);
111368 sqlite3_mutex_leave(db->mutex);
111369 return rc;
111372 #ifndef SQLITE_OMIT_TRACE
111374 ** Register a trace function. The pArg from the previously registered trace
111375 ** is returned.
111377 ** A NULL trace function means that no tracing is executes. A non-NULL
111378 ** trace is a pointer to a function that is invoked at the start of each
111379 ** SQL statement.
111381 SQLITE_API void *sqlite3_trace(sqlite3 *db, void (*xTrace)(void*,const char*), void *pArg){
111382 void *pOld;
111383 sqlite3_mutex_enter(db->mutex);
111384 pOld = db->pTraceArg;
111385 db->xTrace = xTrace;
111386 db->pTraceArg = pArg;
111387 sqlite3_mutex_leave(db->mutex);
111388 return pOld;
111391 ** Register a profile function. The pArg from the previously registered
111392 ** profile function is returned.
111394 ** A NULL profile function means that no profiling is executes. A non-NULL
111395 ** profile is a pointer to a function that is invoked at the conclusion of
111396 ** each SQL statement that is run.
111398 SQLITE_API void *sqlite3_profile(
111399 sqlite3 *db,
111400 void (*xProfile)(void*,const char*,sqlite_uint64),
111401 void *pArg
111403 void *pOld;
111404 sqlite3_mutex_enter(db->mutex);
111405 pOld = db->pProfileArg;
111406 db->xProfile = xProfile;
111407 db->pProfileArg = pArg;
111408 sqlite3_mutex_leave(db->mutex);
111409 return pOld;
111411 #endif /* SQLITE_OMIT_TRACE */
111413 /*** EXPERIMENTAL ***
111415 ** Register a function to be invoked when a transaction comments.
111416 ** If the invoked function returns non-zero, then the commit becomes a
111417 ** rollback.
111419 SQLITE_API void *sqlite3_commit_hook(
111420 sqlite3 *db, /* Attach the hook to this database */
111421 int (*xCallback)(void*), /* Function to invoke on each commit */
111422 void *pArg /* Argument to the function */
111424 void *pOld;
111425 sqlite3_mutex_enter(db->mutex);
111426 pOld = db->pCommitArg;
111427 db->xCommitCallback = xCallback;
111428 db->pCommitArg = pArg;
111429 sqlite3_mutex_leave(db->mutex);
111430 return pOld;
111434 ** Register a callback to be invoked each time a row is updated,
111435 ** inserted or deleted using this database connection.
111437 SQLITE_API void *sqlite3_update_hook(
111438 sqlite3 *db, /* Attach the hook to this database */
111439 void (*xCallback)(void*,int,char const *,char const *,sqlite_int64),
111440 void *pArg /* Argument to the function */
111442 void *pRet;
111443 sqlite3_mutex_enter(db->mutex);
111444 pRet = db->pUpdateArg;
111445 db->xUpdateCallback = xCallback;
111446 db->pUpdateArg = pArg;
111447 sqlite3_mutex_leave(db->mutex);
111448 return pRet;
111452 ** Register a callback to be invoked each time a transaction is rolled
111453 ** back by this database connection.
111455 SQLITE_API void *sqlite3_rollback_hook(
111456 sqlite3 *db, /* Attach the hook to this database */
111457 void (*xCallback)(void*), /* Callback function */
111458 void *pArg /* Argument to the function */
111460 void *pRet;
111461 sqlite3_mutex_enter(db->mutex);
111462 pRet = db->pRollbackArg;
111463 db->xRollbackCallback = xCallback;
111464 db->pRollbackArg = pArg;
111465 sqlite3_mutex_leave(db->mutex);
111466 return pRet;
111469 #ifndef SQLITE_OMIT_WAL
111471 ** The sqlite3_wal_hook() callback registered by sqlite3_wal_autocheckpoint().
111472 ** Invoke sqlite3_wal_checkpoint if the number of frames in the log file
111473 ** is greater than sqlite3.pWalArg cast to an integer (the value configured by
111474 ** wal_autocheckpoint()).
111476 SQLITE_PRIVATE int sqlite3WalDefaultHook(
111477 void *pClientData, /* Argument */
111478 sqlite3 *db, /* Connection */
111479 const char *zDb, /* Database */
111480 int nFrame /* Size of WAL */
111482 if( nFrame>=SQLITE_PTR_TO_INT(pClientData) ){
111483 sqlite3BeginBenignMalloc();
111484 sqlite3_wal_checkpoint(db, zDb);
111485 sqlite3EndBenignMalloc();
111487 return SQLITE_OK;
111489 #endif /* SQLITE_OMIT_WAL */
111492 ** Configure an sqlite3_wal_hook() callback to automatically checkpoint
111493 ** a database after committing a transaction if there are nFrame or
111494 ** more frames in the log file. Passing zero or a negative value as the
111495 ** nFrame parameter disables automatic checkpoints entirely.
111497 ** The callback registered by this function replaces any existing callback
111498 ** registered using sqlite3_wal_hook(). Likewise, registering a callback
111499 ** using sqlite3_wal_hook() disables the automatic checkpoint mechanism
111500 ** configured by this function.
111502 SQLITE_API int sqlite3_wal_autocheckpoint(sqlite3 *db, int nFrame){
111503 #ifdef SQLITE_OMIT_WAL
111504 UNUSED_PARAMETER(db);
111505 UNUSED_PARAMETER(nFrame);
111506 #else
111507 if( nFrame>0 ){
111508 sqlite3_wal_hook(db, sqlite3WalDefaultHook, SQLITE_INT_TO_PTR(nFrame));
111509 }else{
111510 sqlite3_wal_hook(db, 0, 0);
111512 #endif
111513 return SQLITE_OK;
111517 ** Register a callback to be invoked each time a transaction is written
111518 ** into the write-ahead-log by this database connection.
111520 SQLITE_API void *sqlite3_wal_hook(
111521 sqlite3 *db, /* Attach the hook to this db handle */
111522 int(*xCallback)(void *, sqlite3*, const char*, int),
111523 void *pArg /* First argument passed to xCallback() */
111525 #ifndef SQLITE_OMIT_WAL
111526 void *pRet;
111527 sqlite3_mutex_enter(db->mutex);
111528 pRet = db->pWalArg;
111529 db->xWalCallback = xCallback;
111530 db->pWalArg = pArg;
111531 sqlite3_mutex_leave(db->mutex);
111532 return pRet;
111533 #else
111534 return 0;
111535 #endif
111539 ** Checkpoint database zDb.
111541 SQLITE_API int sqlite3_wal_checkpoint_v2(
111542 sqlite3 *db, /* Database handle */
111543 const char *zDb, /* Name of attached database (or NULL) */
111544 int eMode, /* SQLITE_CHECKPOINT_* value */
111545 int *pnLog, /* OUT: Size of WAL log in frames */
111546 int *pnCkpt /* OUT: Total number of frames checkpointed */
111548 #ifdef SQLITE_OMIT_WAL
111549 return SQLITE_OK;
111550 #else
111551 int rc; /* Return code */
111552 int iDb = SQLITE_MAX_ATTACHED; /* sqlite3.aDb[] index of db to checkpoint */
111554 /* Initialize the output variables to -1 in case an error occurs. */
111555 if( pnLog ) *pnLog = -1;
111556 if( pnCkpt ) *pnCkpt = -1;
111558 assert( SQLITE_CHECKPOINT_FULL>SQLITE_CHECKPOINT_PASSIVE );
111559 assert( SQLITE_CHECKPOINT_FULL<SQLITE_CHECKPOINT_RESTART );
111560 assert( SQLITE_CHECKPOINT_PASSIVE+2==SQLITE_CHECKPOINT_RESTART );
111561 if( eMode<SQLITE_CHECKPOINT_PASSIVE || eMode>SQLITE_CHECKPOINT_RESTART ){
111562 return SQLITE_MISUSE;
111565 sqlite3_mutex_enter(db->mutex);
111566 if( zDb && zDb[0] ){
111567 iDb = sqlite3FindDbName(db, zDb);
111569 if( iDb<0 ){
111570 rc = SQLITE_ERROR;
111571 sqlite3Error(db, SQLITE_ERROR, "unknown database: %s", zDb);
111572 }else{
111573 rc = sqlite3Checkpoint(db, iDb, eMode, pnLog, pnCkpt);
111574 sqlite3Error(db, rc, 0);
111576 rc = sqlite3ApiExit(db, rc);
111577 sqlite3_mutex_leave(db->mutex);
111578 return rc;
111579 #endif
111584 ** Checkpoint database zDb. If zDb is NULL, or if the buffer zDb points
111585 ** to contains a zero-length string, all attached databases are
111586 ** checkpointed.
111588 SQLITE_API int sqlite3_wal_checkpoint(sqlite3 *db, const char *zDb){
111589 return sqlite3_wal_checkpoint_v2(db, zDb, SQLITE_CHECKPOINT_PASSIVE, 0, 0);
111592 #ifndef SQLITE_OMIT_WAL
111594 ** Run a checkpoint on database iDb. This is a no-op if database iDb is
111595 ** not currently open in WAL mode.
111597 ** If a transaction is open on the database being checkpointed, this
111598 ** function returns SQLITE_LOCKED and a checkpoint is not attempted. If
111599 ** an error occurs while running the checkpoint, an SQLite error code is
111600 ** returned (i.e. SQLITE_IOERR). Otherwise, SQLITE_OK.
111602 ** The mutex on database handle db should be held by the caller. The mutex
111603 ** associated with the specific b-tree being checkpointed is taken by
111604 ** this function while the checkpoint is running.
111606 ** If iDb is passed SQLITE_MAX_ATTACHED, then all attached databases are
111607 ** checkpointed. If an error is encountered it is returned immediately -
111608 ** no attempt is made to checkpoint any remaining databases.
111610 ** Parameter eMode is one of SQLITE_CHECKPOINT_PASSIVE, FULL or RESTART.
111612 SQLITE_PRIVATE int sqlite3Checkpoint(sqlite3 *db, int iDb, int eMode, int *pnLog, int *pnCkpt){
111613 int rc = SQLITE_OK; /* Return code */
111614 int i; /* Used to iterate through attached dbs */
111615 int bBusy = 0; /* True if SQLITE_BUSY has been encountered */
111617 assert( sqlite3_mutex_held(db->mutex) );
111618 assert( !pnLog || *pnLog==-1 );
111619 assert( !pnCkpt || *pnCkpt==-1 );
111621 for(i=0; i<db->nDb && rc==SQLITE_OK; i++){
111622 if( i==iDb || iDb==SQLITE_MAX_ATTACHED ){
111623 rc = sqlite3BtreeCheckpoint(db->aDb[i].pBt, eMode, pnLog, pnCkpt);
111624 pnLog = 0;
111625 pnCkpt = 0;
111626 if( rc==SQLITE_BUSY ){
111627 bBusy = 1;
111628 rc = SQLITE_OK;
111633 return (rc==SQLITE_OK && bBusy) ? SQLITE_BUSY : rc;
111635 #endif /* SQLITE_OMIT_WAL */
111638 ** This function returns true if main-memory should be used instead of
111639 ** a temporary file for transient pager files and statement journals.
111640 ** The value returned depends on the value of db->temp_store (runtime
111641 ** parameter) and the compile time value of SQLITE_TEMP_STORE. The
111642 ** following table describes the relationship between these two values
111643 ** and this functions return value.
111645 ** SQLITE_TEMP_STORE db->temp_store Location of temporary database
111646 ** ----------------- -------------- ------------------------------
111647 ** 0 any file (return 0)
111648 ** 1 1 file (return 0)
111649 ** 1 2 memory (return 1)
111650 ** 1 0 file (return 0)
111651 ** 2 1 file (return 0)
111652 ** 2 2 memory (return 1)
111653 ** 2 0 memory (return 1)
111654 ** 3 any memory (return 1)
111656 SQLITE_PRIVATE int sqlite3TempInMemory(const sqlite3 *db){
111657 #if SQLITE_TEMP_STORE==1
111658 return ( db->temp_store==2 );
111659 #endif
111660 #if SQLITE_TEMP_STORE==2
111661 return ( db->temp_store!=1 );
111662 #endif
111663 #if SQLITE_TEMP_STORE==3
111664 return 1;
111665 #endif
111666 #if SQLITE_TEMP_STORE<1 || SQLITE_TEMP_STORE>3
111667 return 0;
111668 #endif
111672 ** Return UTF-8 encoded English language explanation of the most recent
111673 ** error.
111675 SQLITE_API const char *sqlite3_errmsg(sqlite3 *db){
111676 const char *z;
111677 if( !db ){
111678 return sqlite3ErrStr(SQLITE_NOMEM);
111680 if( !sqlite3SafetyCheckSickOrOk(db) ){
111681 return sqlite3ErrStr(SQLITE_MISUSE_BKPT);
111683 sqlite3_mutex_enter(db->mutex);
111684 if( db->mallocFailed ){
111685 z = sqlite3ErrStr(SQLITE_NOMEM);
111686 }else{
111687 z = (char*)sqlite3_value_text(db->pErr);
111688 assert( !db->mallocFailed );
111689 if( z==0 ){
111690 z = sqlite3ErrStr(db->errCode);
111693 sqlite3_mutex_leave(db->mutex);
111694 return z;
111697 #ifndef SQLITE_OMIT_UTF16
111699 ** Return UTF-16 encoded English language explanation of the most recent
111700 ** error.
111702 SQLITE_API const void *sqlite3_errmsg16(sqlite3 *db){
111703 static const u16 outOfMem[] = {
111704 'o', 'u', 't', ' ', 'o', 'f', ' ', 'm', 'e', 'm', 'o', 'r', 'y', 0
111706 static const u16 misuse[] = {
111707 'l', 'i', 'b', 'r', 'a', 'r', 'y', ' ',
111708 'r', 'o', 'u', 't', 'i', 'n', 'e', ' ',
111709 'c', 'a', 'l', 'l', 'e', 'd', ' ',
111710 'o', 'u', 't', ' ',
111711 'o', 'f', ' ',
111712 's', 'e', 'q', 'u', 'e', 'n', 'c', 'e', 0
111715 const void *z;
111716 if( !db ){
111717 return (void *)outOfMem;
111719 if( !sqlite3SafetyCheckSickOrOk(db) ){
111720 return (void *)misuse;
111722 sqlite3_mutex_enter(db->mutex);
111723 if( db->mallocFailed ){
111724 z = (void *)outOfMem;
111725 }else{
111726 z = sqlite3_value_text16(db->pErr);
111727 if( z==0 ){
111728 sqlite3ValueSetStr(db->pErr, -1, sqlite3ErrStr(db->errCode),
111729 SQLITE_UTF8, SQLITE_STATIC);
111730 z = sqlite3_value_text16(db->pErr);
111732 /* A malloc() may have failed within the call to sqlite3_value_text16()
111733 ** above. If this is the case, then the db->mallocFailed flag needs to
111734 ** be cleared before returning. Do this directly, instead of via
111735 ** sqlite3ApiExit(), to avoid setting the database handle error message.
111737 db->mallocFailed = 0;
111739 sqlite3_mutex_leave(db->mutex);
111740 return z;
111742 #endif /* SQLITE_OMIT_UTF16 */
111745 ** Return the most recent error code generated by an SQLite routine. If NULL is
111746 ** passed to this function, we assume a malloc() failed during sqlite3_open().
111748 SQLITE_API int sqlite3_errcode(sqlite3 *db){
111749 if( db && !sqlite3SafetyCheckSickOrOk(db) ){
111750 return SQLITE_MISUSE_BKPT;
111752 if( !db || db->mallocFailed ){
111753 return SQLITE_NOMEM;
111755 return db->errCode & db->errMask;
111757 SQLITE_API int sqlite3_extended_errcode(sqlite3 *db){
111758 if( db && !sqlite3SafetyCheckSickOrOk(db) ){
111759 return SQLITE_MISUSE_BKPT;
111761 if( !db || db->mallocFailed ){
111762 return SQLITE_NOMEM;
111764 return db->errCode;
111768 ** Create a new collating function for database "db". The name is zName
111769 ** and the encoding is enc.
111771 static int createCollation(
111772 sqlite3* db,
111773 const char *zName,
111774 u8 enc,
111775 u8 collType,
111776 void* pCtx,
111777 int(*xCompare)(void*,int,const void*,int,const void*),
111778 void(*xDel)(void*)
111780 CollSeq *pColl;
111781 int enc2;
111782 int nName = sqlite3Strlen30(zName);
111784 assert( sqlite3_mutex_held(db->mutex) );
111786 /* If SQLITE_UTF16 is specified as the encoding type, transform this
111787 ** to one of SQLITE_UTF16LE or SQLITE_UTF16BE using the
111788 ** SQLITE_UTF16NATIVE macro. SQLITE_UTF16 is not used internally.
111790 enc2 = enc;
111791 testcase( enc2==SQLITE_UTF16 );
111792 testcase( enc2==SQLITE_UTF16_ALIGNED );
111793 if( enc2==SQLITE_UTF16 || enc2==SQLITE_UTF16_ALIGNED ){
111794 enc2 = SQLITE_UTF16NATIVE;
111796 if( enc2<SQLITE_UTF8 || enc2>SQLITE_UTF16BE ){
111797 return SQLITE_MISUSE_BKPT;
111800 /* Check if this call is removing or replacing an existing collation
111801 ** sequence. If so, and there are active VMs, return busy. If there
111802 ** are no active VMs, invalidate any pre-compiled statements.
111804 pColl = sqlite3FindCollSeq(db, (u8)enc2, zName, 0);
111805 if( pColl && pColl->xCmp ){
111806 if( db->activeVdbeCnt ){
111807 sqlite3Error(db, SQLITE_BUSY,
111808 "unable to delete/modify collation sequence due to active statements");
111809 return SQLITE_BUSY;
111811 sqlite3ExpirePreparedStatements(db);
111813 /* If collation sequence pColl was created directly by a call to
111814 ** sqlite3_create_collation, and not generated by synthCollSeq(),
111815 ** then any copies made by synthCollSeq() need to be invalidated.
111816 ** Also, collation destructor - CollSeq.xDel() - function may need
111817 ** to be called.
111819 if( (pColl->enc & ~SQLITE_UTF16_ALIGNED)==enc2 ){
111820 CollSeq *aColl = sqlite3HashFind(&db->aCollSeq, zName, nName);
111821 int j;
111822 for(j=0; j<3; j++){
111823 CollSeq *p = &aColl[j];
111824 if( p->enc==pColl->enc ){
111825 if( p->xDel ){
111826 p->xDel(p->pUser);
111828 p->xCmp = 0;
111834 pColl = sqlite3FindCollSeq(db, (u8)enc2, zName, 1);
111835 if( pColl==0 ) return SQLITE_NOMEM;
111836 pColl->xCmp = xCompare;
111837 pColl->pUser = pCtx;
111838 pColl->xDel = xDel;
111839 pColl->enc = (u8)(enc2 | (enc & SQLITE_UTF16_ALIGNED));
111840 pColl->type = collType;
111841 sqlite3Error(db, SQLITE_OK, 0);
111842 return SQLITE_OK;
111847 ** This array defines hard upper bounds on limit values. The
111848 ** initializer must be kept in sync with the SQLITE_LIMIT_*
111849 ** #defines in sqlite3.h.
111851 static const int aHardLimit[] = {
111852 SQLITE_MAX_LENGTH,
111853 SQLITE_MAX_SQL_LENGTH,
111854 SQLITE_MAX_COLUMN,
111855 SQLITE_MAX_EXPR_DEPTH,
111856 SQLITE_MAX_COMPOUND_SELECT,
111857 SQLITE_MAX_VDBE_OP,
111858 SQLITE_MAX_FUNCTION_ARG,
111859 SQLITE_MAX_ATTACHED,
111860 SQLITE_MAX_LIKE_PATTERN_LENGTH,
111861 SQLITE_MAX_VARIABLE_NUMBER,
111862 SQLITE_MAX_TRIGGER_DEPTH,
111866 ** Make sure the hard limits are set to reasonable values
111868 #if SQLITE_MAX_LENGTH<100
111869 # error SQLITE_MAX_LENGTH must be at least 100
111870 #endif
111871 #if SQLITE_MAX_SQL_LENGTH<100
111872 # error SQLITE_MAX_SQL_LENGTH must be at least 100
111873 #endif
111874 #if SQLITE_MAX_SQL_LENGTH>SQLITE_MAX_LENGTH
111875 # error SQLITE_MAX_SQL_LENGTH must not be greater than SQLITE_MAX_LENGTH
111876 #endif
111877 #if SQLITE_MAX_COMPOUND_SELECT<2
111878 # error SQLITE_MAX_COMPOUND_SELECT must be at least 2
111879 #endif
111880 #if SQLITE_MAX_VDBE_OP<40
111881 # error SQLITE_MAX_VDBE_OP must be at least 40
111882 #endif
111883 #if SQLITE_MAX_FUNCTION_ARG<0 || SQLITE_MAX_FUNCTION_ARG>1000
111884 # error SQLITE_MAX_FUNCTION_ARG must be between 0 and 1000
111885 #endif
111886 #if SQLITE_MAX_ATTACHED<0 || SQLITE_MAX_ATTACHED>62
111887 # error SQLITE_MAX_ATTACHED must be between 0 and 62
111888 #endif
111889 #if SQLITE_MAX_LIKE_PATTERN_LENGTH<1
111890 # error SQLITE_MAX_LIKE_PATTERN_LENGTH must be at least 1
111891 #endif
111892 #if SQLITE_MAX_COLUMN>32767
111893 # error SQLITE_MAX_COLUMN must not exceed 32767
111894 #endif
111895 #if SQLITE_MAX_TRIGGER_DEPTH<1
111896 # error SQLITE_MAX_TRIGGER_DEPTH must be at least 1
111897 #endif
111901 ** Change the value of a limit. Report the old value.
111902 ** If an invalid limit index is supplied, report -1.
111903 ** Make no changes but still report the old value if the
111904 ** new limit is negative.
111906 ** A new lower limit does not shrink existing constructs.
111907 ** It merely prevents new constructs that exceed the limit
111908 ** from forming.
111910 SQLITE_API int sqlite3_limit(sqlite3 *db, int limitId, int newLimit){
111911 int oldLimit;
111914 /* EVIDENCE-OF: R-30189-54097 For each limit category SQLITE_LIMIT_NAME
111915 ** there is a hard upper bound set at compile-time by a C preprocessor
111916 ** macro called SQLITE_MAX_NAME. (The "_LIMIT_" in the name is changed to
111917 ** "_MAX_".)
111919 assert( aHardLimit[SQLITE_LIMIT_LENGTH]==SQLITE_MAX_LENGTH );
111920 assert( aHardLimit[SQLITE_LIMIT_SQL_LENGTH]==SQLITE_MAX_SQL_LENGTH );
111921 assert( aHardLimit[SQLITE_LIMIT_COLUMN]==SQLITE_MAX_COLUMN );
111922 assert( aHardLimit[SQLITE_LIMIT_EXPR_DEPTH]==SQLITE_MAX_EXPR_DEPTH );
111923 assert( aHardLimit[SQLITE_LIMIT_COMPOUND_SELECT]==SQLITE_MAX_COMPOUND_SELECT);
111924 assert( aHardLimit[SQLITE_LIMIT_VDBE_OP]==SQLITE_MAX_VDBE_OP );
111925 assert( aHardLimit[SQLITE_LIMIT_FUNCTION_ARG]==SQLITE_MAX_FUNCTION_ARG );
111926 assert( aHardLimit[SQLITE_LIMIT_ATTACHED]==SQLITE_MAX_ATTACHED );
111927 assert( aHardLimit[SQLITE_LIMIT_LIKE_PATTERN_LENGTH]==
111928 SQLITE_MAX_LIKE_PATTERN_LENGTH );
111929 assert( aHardLimit[SQLITE_LIMIT_VARIABLE_NUMBER]==SQLITE_MAX_VARIABLE_NUMBER);
111930 assert( aHardLimit[SQLITE_LIMIT_TRIGGER_DEPTH]==SQLITE_MAX_TRIGGER_DEPTH );
111931 assert( SQLITE_LIMIT_TRIGGER_DEPTH==(SQLITE_N_LIMIT-1) );
111934 if( limitId<0 || limitId>=SQLITE_N_LIMIT ){
111935 return -1;
111937 oldLimit = db->aLimit[limitId];
111938 if( newLimit>=0 ){ /* IMP: R-52476-28732 */
111939 if( newLimit>aHardLimit[limitId] ){
111940 newLimit = aHardLimit[limitId]; /* IMP: R-51463-25634 */
111942 db->aLimit[limitId] = newLimit;
111944 return oldLimit; /* IMP: R-53341-35419 */
111948 ** This function is used to parse both URIs and non-URI filenames passed by the
111949 ** user to API functions sqlite3_open() or sqlite3_open_v2(), and for database
111950 ** URIs specified as part of ATTACH statements.
111952 ** The first argument to this function is the name of the VFS to use (or
111953 ** a NULL to signify the default VFS) if the URI does not contain a "vfs=xxx"
111954 ** query parameter. The second argument contains the URI (or non-URI filename)
111955 ** itself. When this function is called the *pFlags variable should contain
111956 ** the default flags to open the database handle with. The value stored in
111957 ** *pFlags may be updated before returning if the URI filename contains
111958 ** "cache=xxx" or "mode=xxx" query parameters.
111960 ** If successful, SQLITE_OK is returned. In this case *ppVfs is set to point to
111961 ** the VFS that should be used to open the database file. *pzFile is set to
111962 ** point to a buffer containing the name of the file to open. It is the
111963 ** responsibility of the caller to eventually call sqlite3_free() to release
111964 ** this buffer.
111966 ** If an error occurs, then an SQLite error code is returned and *pzErrMsg
111967 ** may be set to point to a buffer containing an English language error
111968 ** message. It is the responsibility of the caller to eventually release
111969 ** this buffer by calling sqlite3_free().
111971 SQLITE_PRIVATE int sqlite3ParseUri(
111972 const char *zDefaultVfs, /* VFS to use if no "vfs=xxx" query option */
111973 const char *zUri, /* Nul-terminated URI to parse */
111974 unsigned int *pFlags, /* IN/OUT: SQLITE_OPEN_XXX flags */
111975 sqlite3_vfs **ppVfs, /* OUT: VFS to use */
111976 char **pzFile, /* OUT: Filename component of URI */
111977 char **pzErrMsg /* OUT: Error message (if rc!=SQLITE_OK) */
111979 int rc = SQLITE_OK;
111980 unsigned int flags = *pFlags;
111981 const char *zVfs = zDefaultVfs;
111982 char *zFile;
111983 char c;
111984 int nUri = sqlite3Strlen30(zUri);
111986 assert( *pzErrMsg==0 );
111988 if( ((flags & SQLITE_OPEN_URI) || sqlite3GlobalConfig.bOpenUri)
111989 && nUri>=5 && memcmp(zUri, "file:", 5)==0
111991 char *zOpt;
111992 int eState; /* Parser state when parsing URI */
111993 int iIn; /* Input character index */
111994 int iOut = 0; /* Output character index */
111995 int nByte = nUri+2; /* Bytes of space to allocate */
111997 /* Make sure the SQLITE_OPEN_URI flag is set to indicate to the VFS xOpen
111998 ** method that there may be extra parameters following the file-name. */
111999 flags |= SQLITE_OPEN_URI;
112001 for(iIn=0; iIn<nUri; iIn++) nByte += (zUri[iIn]=='&');
112002 zFile = sqlite3_malloc(nByte);
112003 if( !zFile ) return SQLITE_NOMEM;
112005 /* Discard the scheme and authority segments of the URI. */
112006 if( zUri[5]=='/' && zUri[6]=='/' ){
112007 iIn = 7;
112008 while( zUri[iIn] && zUri[iIn]!='/' ) iIn++;
112010 if( iIn!=7 && (iIn!=16 || memcmp("localhost", &zUri[7], 9)) ){
112011 *pzErrMsg = sqlite3_mprintf("invalid uri authority: %.*s",
112012 iIn-7, &zUri[7]);
112013 rc = SQLITE_ERROR;
112014 goto parse_uri_out;
112016 }else{
112017 iIn = 5;
112020 /* Copy the filename and any query parameters into the zFile buffer.
112021 ** Decode %HH escape codes along the way.
112023 ** Within this loop, variable eState may be set to 0, 1 or 2, depending
112024 ** on the parsing context. As follows:
112026 ** 0: Parsing file-name.
112027 ** 1: Parsing name section of a name=value query parameter.
112028 ** 2: Parsing value section of a name=value query parameter.
112030 eState = 0;
112031 while( (c = zUri[iIn])!=0 && c!='#' ){
112032 iIn++;
112033 if( c=='%'
112034 && sqlite3Isxdigit(zUri[iIn])
112035 && sqlite3Isxdigit(zUri[iIn+1])
112037 int octet = (sqlite3HexToInt(zUri[iIn++]) << 4);
112038 octet += sqlite3HexToInt(zUri[iIn++]);
112040 assert( octet>=0 && octet<256 );
112041 if( octet==0 ){
112042 /* This branch is taken when "%00" appears within the URI. In this
112043 ** case we ignore all text in the remainder of the path, name or
112044 ** value currently being parsed. So ignore the current character
112045 ** and skip to the next "?", "=" or "&", as appropriate. */
112046 while( (c = zUri[iIn])!=0 && c!='#'
112047 && (eState!=0 || c!='?')
112048 && (eState!=1 || (c!='=' && c!='&'))
112049 && (eState!=2 || c!='&')
112051 iIn++;
112053 continue;
112055 c = octet;
112056 }else if( eState==1 && (c=='&' || c=='=') ){
112057 if( zFile[iOut-1]==0 ){
112058 /* An empty option name. Ignore this option altogether. */
112059 while( zUri[iIn] && zUri[iIn]!='#' && zUri[iIn-1]!='&' ) iIn++;
112060 continue;
112062 if( c=='&' ){
112063 zFile[iOut++] = '\0';
112064 }else{
112065 eState = 2;
112067 c = 0;
112068 }else if( (eState==0 && c=='?') || (eState==2 && c=='&') ){
112069 c = 0;
112070 eState = 1;
112072 zFile[iOut++] = c;
112074 if( eState==1 ) zFile[iOut++] = '\0';
112075 zFile[iOut++] = '\0';
112076 zFile[iOut++] = '\0';
112078 /* Check if there were any options specified that should be interpreted
112079 ** here. Options that are interpreted here include "vfs" and those that
112080 ** correspond to flags that may be passed to the sqlite3_open_v2()
112081 ** method. */
112082 zOpt = &zFile[sqlite3Strlen30(zFile)+1];
112083 while( zOpt[0] ){
112084 int nOpt = sqlite3Strlen30(zOpt);
112085 char *zVal = &zOpt[nOpt+1];
112086 int nVal = sqlite3Strlen30(zVal);
112088 if( nOpt==3 && memcmp("vfs", zOpt, 3)==0 ){
112089 zVfs = zVal;
112090 }else{
112091 struct OpenMode {
112092 const char *z;
112093 int mode;
112094 } *aMode = 0;
112095 char *zModeType = 0;
112096 int mask = 0;
112097 int limit = 0;
112099 if( nOpt==5 && memcmp("cache", zOpt, 5)==0 ){
112100 static struct OpenMode aCacheMode[] = {
112101 { "shared", SQLITE_OPEN_SHAREDCACHE },
112102 { "private", SQLITE_OPEN_PRIVATECACHE },
112103 { 0, 0 }
112106 mask = SQLITE_OPEN_SHAREDCACHE|SQLITE_OPEN_PRIVATECACHE;
112107 aMode = aCacheMode;
112108 limit = mask;
112109 zModeType = "cache";
112111 if( nOpt==4 && memcmp("mode", zOpt, 4)==0 ){
112112 static struct OpenMode aOpenMode[] = {
112113 { "ro", SQLITE_OPEN_READONLY },
112114 { "rw", SQLITE_OPEN_READWRITE },
112115 { "rwc", SQLITE_OPEN_READWRITE | SQLITE_OPEN_CREATE },
112116 { 0, 0 }
112119 mask = SQLITE_OPEN_READONLY|SQLITE_OPEN_READWRITE|SQLITE_OPEN_CREATE;
112120 aMode = aOpenMode;
112121 limit = mask & flags;
112122 zModeType = "access";
112125 if( aMode ){
112126 int i;
112127 int mode = 0;
112128 for(i=0; aMode[i].z; i++){
112129 const char *z = aMode[i].z;
112130 if( nVal==sqlite3Strlen30(z) && 0==memcmp(zVal, z, nVal) ){
112131 mode = aMode[i].mode;
112132 break;
112135 if( mode==0 ){
112136 *pzErrMsg = sqlite3_mprintf("no such %s mode: %s", zModeType, zVal);
112137 rc = SQLITE_ERROR;
112138 goto parse_uri_out;
112140 if( mode>limit ){
112141 *pzErrMsg = sqlite3_mprintf("%s mode not allowed: %s",
112142 zModeType, zVal);
112143 rc = SQLITE_PERM;
112144 goto parse_uri_out;
112146 flags = (flags & ~mask) | mode;
112150 zOpt = &zVal[nVal+1];
112153 }else{
112154 zFile = sqlite3_malloc(nUri+2);
112155 if( !zFile ) return SQLITE_NOMEM;
112156 memcpy(zFile, zUri, nUri);
112157 zFile[nUri] = '\0';
112158 zFile[nUri+1] = '\0';
112161 *ppVfs = sqlite3_vfs_find(zVfs);
112162 if( *ppVfs==0 ){
112163 *pzErrMsg = sqlite3_mprintf("no such vfs: %s", zVfs);
112164 rc = SQLITE_ERROR;
112166 parse_uri_out:
112167 if( rc!=SQLITE_OK ){
112168 sqlite3_free(zFile);
112169 zFile = 0;
112171 *pFlags = flags;
112172 *pzFile = zFile;
112173 return rc;
112178 ** This routine does the work of opening a database on behalf of
112179 ** sqlite3_open() and sqlite3_open16(). The database filename "zFilename"
112180 ** is UTF-8 encoded.
112182 static int openDatabase(
112183 const char *zFilename, /* Database filename UTF-8 encoded */
112184 sqlite3 **ppDb, /* OUT: Returned database handle */
112185 unsigned int flags, /* Operational flags */
112186 const char *zVfs /* Name of the VFS to use */
112188 sqlite3 *db; /* Store allocated handle here */
112189 int rc; /* Return code */
112190 int isThreadsafe; /* True for threadsafe connections */
112191 char *zOpen = 0; /* Filename argument to pass to BtreeOpen() */
112192 char *zErrMsg = 0; /* Error message from sqlite3ParseUri() */
112194 *ppDb = 0;
112195 #ifndef SQLITE_OMIT_AUTOINIT
112196 rc = sqlite3_initialize();
112197 if( rc ) return rc;
112198 #endif
112200 /* Only allow sensible combinations of bits in the flags argument.
112201 ** Throw an error if any non-sense combination is used. If we
112202 ** do not block illegal combinations here, it could trigger
112203 ** assert() statements in deeper layers. Sensible combinations
112204 ** are:
112206 ** 1: SQLITE_OPEN_READONLY
112207 ** 2: SQLITE_OPEN_READWRITE
112208 ** 6: SQLITE_OPEN_READWRITE | SQLITE_OPEN_CREATE
112210 assert( SQLITE_OPEN_READONLY == 0x01 );
112211 assert( SQLITE_OPEN_READWRITE == 0x02 );
112212 assert( SQLITE_OPEN_CREATE == 0x04 );
112213 testcase( (1<<(flags&7))==0x02 ); /* READONLY */
112214 testcase( (1<<(flags&7))==0x04 ); /* READWRITE */
112215 testcase( (1<<(flags&7))==0x40 ); /* READWRITE | CREATE */
112216 if( ((1<<(flags&7)) & 0x46)==0 ) return SQLITE_MISUSE_BKPT;
112218 if( sqlite3GlobalConfig.bCoreMutex==0 ){
112219 isThreadsafe = 0;
112220 }else if( flags & SQLITE_OPEN_NOMUTEX ){
112221 isThreadsafe = 0;
112222 }else if( flags & SQLITE_OPEN_FULLMUTEX ){
112223 isThreadsafe = 1;
112224 }else{
112225 isThreadsafe = sqlite3GlobalConfig.bFullMutex;
112227 if( flags & SQLITE_OPEN_PRIVATECACHE ){
112228 flags &= ~SQLITE_OPEN_SHAREDCACHE;
112229 }else if( sqlite3GlobalConfig.sharedCacheEnabled ){
112230 flags |= SQLITE_OPEN_SHAREDCACHE;
112233 /* Remove harmful bits from the flags parameter
112235 ** The SQLITE_OPEN_NOMUTEX and SQLITE_OPEN_FULLMUTEX flags were
112236 ** dealt with in the previous code block. Besides these, the only
112237 ** valid input flags for sqlite3_open_v2() are SQLITE_OPEN_READONLY,
112238 ** SQLITE_OPEN_READWRITE, SQLITE_OPEN_CREATE, SQLITE_OPEN_SHAREDCACHE,
112239 ** SQLITE_OPEN_PRIVATECACHE, and some reserved bits. Silently mask
112240 ** off all other flags.
112242 flags &= ~( SQLITE_OPEN_DELETEONCLOSE |
112243 SQLITE_OPEN_EXCLUSIVE |
112244 SQLITE_OPEN_MAIN_DB |
112245 SQLITE_OPEN_TEMP_DB |
112246 SQLITE_OPEN_TRANSIENT_DB |
112247 SQLITE_OPEN_MAIN_JOURNAL |
112248 SQLITE_OPEN_TEMP_JOURNAL |
112249 SQLITE_OPEN_SUBJOURNAL |
112250 SQLITE_OPEN_MASTER_JOURNAL |
112251 SQLITE_OPEN_NOMUTEX |
112252 SQLITE_OPEN_FULLMUTEX |
112253 SQLITE_OPEN_WAL
112256 /* Allocate the sqlite data structure */
112257 db = sqlite3MallocZero( sizeof(sqlite3) );
112258 if( db==0 ) goto opendb_out;
112259 if( isThreadsafe ){
112260 db->mutex = sqlite3MutexAlloc(SQLITE_MUTEX_RECURSIVE);
112261 if( db->mutex==0 ){
112262 sqlite3_free(db);
112263 db = 0;
112264 goto opendb_out;
112267 sqlite3_mutex_enter(db->mutex);
112268 db->errMask = 0xff;
112269 db->nDb = 2;
112270 db->magic = SQLITE_MAGIC_BUSY;
112271 db->aDb = db->aDbStatic;
112273 assert( sizeof(db->aLimit)==sizeof(aHardLimit) );
112274 memcpy(db->aLimit, aHardLimit, sizeof(db->aLimit));
112275 db->autoCommit = 1;
112276 db->nextAutovac = -1;
112277 db->nextPagesize = 0;
112278 db->flags |= SQLITE_ShortColNames | SQLITE_AutoIndex | SQLITE_EnableTrigger
112279 #if SQLITE_DEFAULT_FILE_FORMAT<4
112280 | SQLITE_LegacyFileFmt
112281 #endif
112282 #ifdef SQLITE_ENABLE_LOAD_EXTENSION
112283 | SQLITE_LoadExtension
112284 #endif
112285 #if SQLITE_DEFAULT_RECURSIVE_TRIGGERS
112286 | SQLITE_RecTriggers
112287 #endif
112288 #if defined(SQLITE_DEFAULT_FOREIGN_KEYS) && SQLITE_DEFAULT_FOREIGN_KEYS
112289 | SQLITE_ForeignKeys
112290 #endif
112292 sqlite3HashInit(&db->aCollSeq);
112293 #ifndef SQLITE_OMIT_VIRTUALTABLE
112294 sqlite3HashInit(&db->aModule);
112295 #endif
112297 /* Add the default collation sequence BINARY. BINARY works for both UTF-8
112298 ** and UTF-16, so add a version for each to avoid any unnecessary
112299 ** conversions. The only error that can occur here is a malloc() failure.
112301 createCollation(db, "BINARY", SQLITE_UTF8, SQLITE_COLL_BINARY, 0,
112302 binCollFunc, 0);
112303 createCollation(db, "BINARY", SQLITE_UTF16BE, SQLITE_COLL_BINARY, 0,
112304 binCollFunc, 0);
112305 createCollation(db, "BINARY", SQLITE_UTF16LE, SQLITE_COLL_BINARY, 0,
112306 binCollFunc, 0);
112307 createCollation(db, "RTRIM", SQLITE_UTF8, SQLITE_COLL_USER, (void*)1,
112308 binCollFunc, 0);
112309 if( db->mallocFailed ){
112310 goto opendb_out;
112312 db->pDfltColl = sqlite3FindCollSeq(db, SQLITE_UTF8, "BINARY", 0);
112313 assert( db->pDfltColl!=0 );
112315 /* Also add a UTF-8 case-insensitive collation sequence. */
112316 createCollation(db, "NOCASE", SQLITE_UTF8, SQLITE_COLL_NOCASE, 0,
112317 nocaseCollatingFunc, 0);
112319 /* Parse the filename/URI argument. */
112320 db->openFlags = flags;
112321 rc = sqlite3ParseUri(zVfs, zFilename, &flags, &db->pVfs, &zOpen, &zErrMsg);
112322 if( rc!=SQLITE_OK ){
112323 if( rc==SQLITE_NOMEM ) db->mallocFailed = 1;
112324 sqlite3Error(db, rc, zErrMsg ? "%s" : 0, zErrMsg);
112325 sqlite3_free(zErrMsg);
112326 goto opendb_out;
112329 /* Open the backend database driver */
112330 rc = sqlite3BtreeOpen(db->pVfs, zOpen, db, &db->aDb[0].pBt, 0,
112331 flags | SQLITE_OPEN_MAIN_DB);
112332 if( rc!=SQLITE_OK ){
112333 if( rc==SQLITE_IOERR_NOMEM ){
112334 rc = SQLITE_NOMEM;
112336 sqlite3Error(db, rc, 0);
112337 goto opendb_out;
112339 db->aDb[0].pSchema = sqlite3SchemaGet(db, db->aDb[0].pBt);
112340 db->aDb[1].pSchema = sqlite3SchemaGet(db, 0);
112343 /* The default safety_level for the main database is 'full'; for the temp
112344 ** database it is 'NONE'. This matches the pager layer defaults.
112346 db->aDb[0].zName = "main";
112347 db->aDb[0].safety_level = 3;
112348 db->aDb[1].zName = "temp";
112349 db->aDb[1].safety_level = 1;
112351 db->magic = SQLITE_MAGIC_OPEN;
112352 if( db->mallocFailed ){
112353 goto opendb_out;
112356 /* Register all built-in functions, but do not attempt to read the
112357 ** database schema yet. This is delayed until the first time the database
112358 ** is accessed.
112360 sqlite3Error(db, SQLITE_OK, 0);
112361 sqlite3RegisterBuiltinFunctions(db);
112363 /* Load automatic extensions - extensions that have been registered
112364 ** using the sqlite3_automatic_extension() API.
112366 sqlite3AutoLoadExtensions(db);
112367 rc = sqlite3_errcode(db);
112368 if( rc!=SQLITE_OK ){
112369 goto opendb_out;
112372 #ifdef SQLITE_ENABLE_FTS1
112373 if( !db->mallocFailed ){
112374 extern int sqlite3Fts1Init(sqlite3*);
112375 rc = sqlite3Fts1Init(db);
112377 #endif
112379 #ifdef SQLITE_ENABLE_FTS2
112380 if( !db->mallocFailed && rc==SQLITE_OK ){
112381 extern int sqlite3Fts2Init(sqlite3*);
112382 rc = sqlite3Fts2Init(db);
112384 #endif
112386 #ifdef SQLITE_ENABLE_FTS3
112387 if( !db->mallocFailed && rc==SQLITE_OK ){
112388 rc = sqlite3Fts3Init(db);
112390 #endif
112392 #ifdef SQLITE_ENABLE_ICU
112393 if( !db->mallocFailed && rc==SQLITE_OK ){
112394 rc = sqlite3IcuInit(db);
112396 #endif
112398 #ifdef SQLITE_ENABLE_RTREE
112399 if( !db->mallocFailed && rc==SQLITE_OK){
112400 rc = sqlite3RtreeInit(db);
112402 #endif
112404 sqlite3Error(db, rc, 0);
112406 /* -DSQLITE_DEFAULT_LOCKING_MODE=1 makes EXCLUSIVE the default locking
112407 ** mode. -DSQLITE_DEFAULT_LOCKING_MODE=0 make NORMAL the default locking
112408 ** mode. Doing nothing at all also makes NORMAL the default.
112410 #ifdef SQLITE_DEFAULT_LOCKING_MODE
112411 db->dfltLockMode = SQLITE_DEFAULT_LOCKING_MODE;
112412 sqlite3PagerLockingMode(sqlite3BtreePager(db->aDb[0].pBt),
112413 SQLITE_DEFAULT_LOCKING_MODE);
112414 #endif
112416 /* Enable the lookaside-malloc subsystem */
112417 setupLookaside(db, 0, sqlite3GlobalConfig.szLookaside,
112418 sqlite3GlobalConfig.nLookaside);
112420 sqlite3_wal_autocheckpoint(db, SQLITE_DEFAULT_WAL_AUTOCHECKPOINT);
112422 opendb_out:
112423 sqlite3_free(zOpen);
112424 if( db ){
112425 assert( db->mutex!=0 || isThreadsafe==0 || sqlite3GlobalConfig.bFullMutex==0 );
112426 sqlite3_mutex_leave(db->mutex);
112428 rc = sqlite3_errcode(db);
112429 if( rc==SQLITE_NOMEM ){
112430 sqlite3_close(db);
112431 db = 0;
112432 }else if( rc!=SQLITE_OK ){
112433 db->magic = SQLITE_MAGIC_SICK;
112435 *ppDb = db;
112436 return sqlite3ApiExit(0, rc);
112440 ** Open a new database handle.
112442 SQLITE_API int sqlite3_open(
112443 const char *zFilename,
112444 sqlite3 **ppDb
112446 return openDatabase(zFilename, ppDb,
112447 SQLITE_OPEN_READWRITE | SQLITE_OPEN_CREATE, 0);
112449 SQLITE_API int sqlite3_open_v2(
112450 const char *filename, /* Database filename (UTF-8) */
112451 sqlite3 **ppDb, /* OUT: SQLite db handle */
112452 int flags, /* Flags */
112453 const char *zVfs /* Name of VFS module to use */
112455 return openDatabase(filename, ppDb, (unsigned int)flags, zVfs);
112458 #ifndef SQLITE_OMIT_UTF16
112460 ** Open a new database handle.
112462 SQLITE_API int sqlite3_open16(
112463 const void *zFilename,
112464 sqlite3 **ppDb
112466 char const *zFilename8; /* zFilename encoded in UTF-8 instead of UTF-16 */
112467 sqlite3_value *pVal;
112468 int rc;
112470 assert( zFilename );
112471 assert( ppDb );
112472 *ppDb = 0;
112473 #ifndef SQLITE_OMIT_AUTOINIT
112474 rc = sqlite3_initialize();
112475 if( rc ) return rc;
112476 #endif
112477 pVal = sqlite3ValueNew(0);
112478 sqlite3ValueSetStr(pVal, -1, zFilename, SQLITE_UTF16NATIVE, SQLITE_STATIC);
112479 zFilename8 = sqlite3ValueText(pVal, SQLITE_UTF8);
112480 if( zFilename8 ){
112481 rc = openDatabase(zFilename8, ppDb,
112482 SQLITE_OPEN_READWRITE | SQLITE_OPEN_CREATE, 0);
112483 assert( *ppDb || rc==SQLITE_NOMEM );
112484 if( rc==SQLITE_OK && !DbHasProperty(*ppDb, 0, DB_SchemaLoaded) ){
112485 ENC(*ppDb) = SQLITE_UTF16NATIVE;
112487 }else{
112488 rc = SQLITE_NOMEM;
112490 sqlite3ValueFree(pVal);
112492 return sqlite3ApiExit(0, rc);
112494 #endif /* SQLITE_OMIT_UTF16 */
112497 ** Register a new collation sequence with the database handle db.
112499 SQLITE_API int sqlite3_create_collation(
112500 sqlite3* db,
112501 const char *zName,
112502 int enc,
112503 void* pCtx,
112504 int(*xCompare)(void*,int,const void*,int,const void*)
112506 int rc;
112507 sqlite3_mutex_enter(db->mutex);
112508 assert( !db->mallocFailed );
112509 rc = createCollation(db, zName, (u8)enc, SQLITE_COLL_USER, pCtx, xCompare, 0);
112510 rc = sqlite3ApiExit(db, rc);
112511 sqlite3_mutex_leave(db->mutex);
112512 return rc;
112516 ** Register a new collation sequence with the database handle db.
112518 SQLITE_API int sqlite3_create_collation_v2(
112519 sqlite3* db,
112520 const char *zName,
112521 int enc,
112522 void* pCtx,
112523 int(*xCompare)(void*,int,const void*,int,const void*),
112524 void(*xDel)(void*)
112526 int rc;
112527 sqlite3_mutex_enter(db->mutex);
112528 assert( !db->mallocFailed );
112529 rc = createCollation(db, zName, (u8)enc, SQLITE_COLL_USER, pCtx, xCompare, xDel);
112530 rc = sqlite3ApiExit(db, rc);
112531 sqlite3_mutex_leave(db->mutex);
112532 return rc;
112535 #ifndef SQLITE_OMIT_UTF16
112537 ** Register a new collation sequence with the database handle db.
112539 SQLITE_API int sqlite3_create_collation16(
112540 sqlite3* db,
112541 const void *zName,
112542 int enc,
112543 void* pCtx,
112544 int(*xCompare)(void*,int,const void*,int,const void*)
112546 int rc = SQLITE_OK;
112547 char *zName8;
112548 sqlite3_mutex_enter(db->mutex);
112549 assert( !db->mallocFailed );
112550 zName8 = sqlite3Utf16to8(db, zName, -1, SQLITE_UTF16NATIVE);
112551 if( zName8 ){
112552 rc = createCollation(db, zName8, (u8)enc, SQLITE_COLL_USER, pCtx, xCompare, 0);
112553 sqlite3DbFree(db, zName8);
112555 rc = sqlite3ApiExit(db, rc);
112556 sqlite3_mutex_leave(db->mutex);
112557 return rc;
112559 #endif /* SQLITE_OMIT_UTF16 */
112562 ** Register a collation sequence factory callback with the database handle
112563 ** db. Replace any previously installed collation sequence factory.
112565 SQLITE_API int sqlite3_collation_needed(
112566 sqlite3 *db,
112567 void *pCollNeededArg,
112568 void(*xCollNeeded)(void*,sqlite3*,int eTextRep,const char*)
112570 sqlite3_mutex_enter(db->mutex);
112571 db->xCollNeeded = xCollNeeded;
112572 db->xCollNeeded16 = 0;
112573 db->pCollNeededArg = pCollNeededArg;
112574 sqlite3_mutex_leave(db->mutex);
112575 return SQLITE_OK;
112578 #ifndef SQLITE_OMIT_UTF16
112580 ** Register a collation sequence factory callback with the database handle
112581 ** db. Replace any previously installed collation sequence factory.
112583 SQLITE_API int sqlite3_collation_needed16(
112584 sqlite3 *db,
112585 void *pCollNeededArg,
112586 void(*xCollNeeded16)(void*,sqlite3*,int eTextRep,const void*)
112588 sqlite3_mutex_enter(db->mutex);
112589 db->xCollNeeded = 0;
112590 db->xCollNeeded16 = xCollNeeded16;
112591 db->pCollNeededArg = pCollNeededArg;
112592 sqlite3_mutex_leave(db->mutex);
112593 return SQLITE_OK;
112595 #endif /* SQLITE_OMIT_UTF16 */
112597 #ifndef SQLITE_OMIT_DEPRECATED
112599 ** This function is now an anachronism. It used to be used to recover from a
112600 ** malloc() failure, but SQLite now does this automatically.
112602 SQLITE_API int sqlite3_global_recover(void){
112603 return SQLITE_OK;
112605 #endif
112608 ** Test to see whether or not the database connection is in autocommit
112609 ** mode. Return TRUE if it is and FALSE if not. Autocommit mode is on
112610 ** by default. Autocommit is disabled by a BEGIN statement and reenabled
112611 ** by the next COMMIT or ROLLBACK.
112613 ******* THIS IS AN EXPERIMENTAL API AND IS SUBJECT TO CHANGE ******
112615 SQLITE_API int sqlite3_get_autocommit(sqlite3 *db){
112616 return db->autoCommit;
112620 ** The following routines are subtitutes for constants SQLITE_CORRUPT,
112621 ** SQLITE_MISUSE, SQLITE_CANTOPEN, SQLITE_IOERR and possibly other error
112622 ** constants. They server two purposes:
112624 ** 1. Serve as a convenient place to set a breakpoint in a debugger
112625 ** to detect when version error conditions occurs.
112627 ** 2. Invoke sqlite3_log() to provide the source code location where
112628 ** a low-level error is first detected.
112630 SQLITE_PRIVATE int sqlite3CorruptError(int lineno){
112631 testcase( sqlite3GlobalConfig.xLog!=0 );
112632 sqlite3_log(SQLITE_CORRUPT,
112633 "database corruption at line %d of [%.10s]",
112634 lineno, 20+sqlite3_sourceid());
112635 return SQLITE_CORRUPT;
112637 SQLITE_PRIVATE int sqlite3MisuseError(int lineno){
112638 testcase( sqlite3GlobalConfig.xLog!=0 );
112639 sqlite3_log(SQLITE_MISUSE,
112640 "misuse at line %d of [%.10s]",
112641 lineno, 20+sqlite3_sourceid());
112642 return SQLITE_MISUSE;
112644 SQLITE_PRIVATE int sqlite3CantopenError(int lineno){
112645 testcase( sqlite3GlobalConfig.xLog!=0 );
112646 sqlite3_log(SQLITE_CANTOPEN,
112647 "cannot open file at line %d of [%.10s]",
112648 lineno, 20+sqlite3_sourceid());
112649 return SQLITE_CANTOPEN;
112653 #ifndef SQLITE_OMIT_DEPRECATED
112655 ** This is a convenience routine that makes sure that all thread-specific
112656 ** data for this thread has been deallocated.
112658 ** SQLite no longer uses thread-specific data so this routine is now a
112659 ** no-op. It is retained for historical compatibility.
112661 SQLITE_API void sqlite3_thread_cleanup(void){
112663 #endif
112666 ** Return meta information about a specific column of a database table.
112667 ** See comment in sqlite3.h (sqlite.h.in) for details.
112669 #ifdef SQLITE_ENABLE_COLUMN_METADATA
112670 SQLITE_API int sqlite3_table_column_metadata(
112671 sqlite3 *db, /* Connection handle */
112672 const char *zDbName, /* Database name or NULL */
112673 const char *zTableName, /* Table name */
112674 const char *zColumnName, /* Column name */
112675 char const **pzDataType, /* OUTPUT: Declared data type */
112676 char const **pzCollSeq, /* OUTPUT: Collation sequence name */
112677 int *pNotNull, /* OUTPUT: True if NOT NULL constraint exists */
112678 int *pPrimaryKey, /* OUTPUT: True if column part of PK */
112679 int *pAutoinc /* OUTPUT: True if column is auto-increment */
112681 int rc;
112682 char *zErrMsg = 0;
112683 Table *pTab = 0;
112684 Column *pCol = 0;
112685 int iCol;
112687 char const *zDataType = 0;
112688 char const *zCollSeq = 0;
112689 int notnull = 0;
112690 int primarykey = 0;
112691 int autoinc = 0;
112693 /* Ensure the database schema has been loaded */
112694 sqlite3_mutex_enter(db->mutex);
112695 sqlite3BtreeEnterAll(db);
112696 rc = sqlite3Init(db, &zErrMsg);
112697 if( SQLITE_OK!=rc ){
112698 goto error_out;
112701 /* Locate the table in question */
112702 pTab = sqlite3FindTable(db, zTableName, zDbName);
112703 if( !pTab || pTab->pSelect ){
112704 pTab = 0;
112705 goto error_out;
112708 /* Find the column for which info is requested */
112709 if( sqlite3IsRowid(zColumnName) ){
112710 iCol = pTab->iPKey;
112711 if( iCol>=0 ){
112712 pCol = &pTab->aCol[iCol];
112714 }else{
112715 for(iCol=0; iCol<pTab->nCol; iCol++){
112716 pCol = &pTab->aCol[iCol];
112717 if( 0==sqlite3StrICmp(pCol->zName, zColumnName) ){
112718 break;
112721 if( iCol==pTab->nCol ){
112722 pTab = 0;
112723 goto error_out;
112727 /* The following block stores the meta information that will be returned
112728 ** to the caller in local variables zDataType, zCollSeq, notnull, primarykey
112729 ** and autoinc. At this point there are two possibilities:
112731 ** 1. The specified column name was rowid", "oid" or "_rowid_"
112732 ** and there is no explicitly declared IPK column.
112734 ** 2. The table is not a view and the column name identified an
112735 ** explicitly declared column. Copy meta information from *pCol.
112737 if( pCol ){
112738 zDataType = pCol->zType;
112739 zCollSeq = pCol->zColl;
112740 notnull = pCol->notNull!=0;
112741 primarykey = pCol->isPrimKey!=0;
112742 autoinc = pTab->iPKey==iCol && (pTab->tabFlags & TF_Autoincrement)!=0;
112743 }else{
112744 zDataType = "INTEGER";
112745 primarykey = 1;
112747 if( !zCollSeq ){
112748 zCollSeq = "BINARY";
112751 error_out:
112752 sqlite3BtreeLeaveAll(db);
112754 /* Whether the function call succeeded or failed, set the output parameters
112755 ** to whatever their local counterparts contain. If an error did occur,
112756 ** this has the effect of zeroing all output parameters.
112758 if( pzDataType ) *pzDataType = zDataType;
112759 if( pzCollSeq ) *pzCollSeq = zCollSeq;
112760 if( pNotNull ) *pNotNull = notnull;
112761 if( pPrimaryKey ) *pPrimaryKey = primarykey;
112762 if( pAutoinc ) *pAutoinc = autoinc;
112764 if( SQLITE_OK==rc && !pTab ){
112765 sqlite3DbFree(db, zErrMsg);
112766 zErrMsg = sqlite3MPrintf(db, "no such table column: %s.%s", zTableName,
112767 zColumnName);
112768 rc = SQLITE_ERROR;
112770 sqlite3Error(db, rc, (zErrMsg?"%s":0), zErrMsg);
112771 sqlite3DbFree(db, zErrMsg);
112772 rc = sqlite3ApiExit(db, rc);
112773 sqlite3_mutex_leave(db->mutex);
112774 return rc;
112776 #endif
112779 ** Sleep for a little while. Return the amount of time slept.
112781 SQLITE_API int sqlite3_sleep(int ms){
112782 sqlite3_vfs *pVfs;
112783 int rc;
112784 pVfs = sqlite3_vfs_find(0);
112785 if( pVfs==0 ) return 0;
112787 /* This function works in milliseconds, but the underlying OsSleep()
112788 ** API uses microseconds. Hence the 1000's.
112790 rc = (sqlite3OsSleep(pVfs, 1000*ms)/1000);
112791 return rc;
112795 ** Enable or disable the extended result codes.
112797 SQLITE_API int sqlite3_extended_result_codes(sqlite3 *db, int onoff){
112798 sqlite3_mutex_enter(db->mutex);
112799 db->errMask = onoff ? 0xffffffff : 0xff;
112800 sqlite3_mutex_leave(db->mutex);
112801 return SQLITE_OK;
112805 ** Invoke the xFileControl method on a particular database.
112807 SQLITE_API int sqlite3_file_control(sqlite3 *db, const char *zDbName, int op, void *pArg){
112808 int rc = SQLITE_ERROR;
112809 int iDb;
112810 sqlite3_mutex_enter(db->mutex);
112811 if( zDbName==0 ){
112812 iDb = 0;
112813 }else{
112814 for(iDb=0; iDb<db->nDb; iDb++){
112815 if( strcmp(db->aDb[iDb].zName, zDbName)==0 ) break;
112818 if( iDb<db->nDb ){
112819 Btree *pBtree = db->aDb[iDb].pBt;
112820 if( pBtree ){
112821 Pager *pPager;
112822 sqlite3_file *fd;
112823 sqlite3BtreeEnter(pBtree);
112824 pPager = sqlite3BtreePager(pBtree);
112825 assert( pPager!=0 );
112826 fd = sqlite3PagerFile(pPager);
112827 assert( fd!=0 );
112828 if( op==SQLITE_FCNTL_FILE_POINTER ){
112829 *(sqlite3_file**)pArg = fd;
112830 rc = SQLITE_OK;
112831 }else if( fd->pMethods ){
112832 rc = sqlite3OsFileControl(fd, op, pArg);
112833 }else{
112834 rc = SQLITE_NOTFOUND;
112836 sqlite3BtreeLeave(pBtree);
112839 sqlite3_mutex_leave(db->mutex);
112840 return rc;
112844 ** Interface to the testing logic.
112846 SQLITE_API int sqlite3_test_control(int op, ...){
112847 int rc = 0;
112848 #ifndef SQLITE_OMIT_BUILTIN_TEST
112849 va_list ap;
112850 va_start(ap, op);
112851 switch( op ){
112854 ** Save the current state of the PRNG.
112856 case SQLITE_TESTCTRL_PRNG_SAVE: {
112857 sqlite3PrngSaveState();
112858 break;
112862 ** Restore the state of the PRNG to the last state saved using
112863 ** PRNG_SAVE. If PRNG_SAVE has never before been called, then
112864 ** this verb acts like PRNG_RESET.
112866 case SQLITE_TESTCTRL_PRNG_RESTORE: {
112867 sqlite3PrngRestoreState();
112868 break;
112872 ** Reset the PRNG back to its uninitialized state. The next call
112873 ** to sqlite3_randomness() will reseed the PRNG using a single call
112874 ** to the xRandomness method of the default VFS.
112876 case SQLITE_TESTCTRL_PRNG_RESET: {
112877 sqlite3PrngResetState();
112878 break;
112882 ** sqlite3_test_control(BITVEC_TEST, size, program)
112884 ** Run a test against a Bitvec object of size. The program argument
112885 ** is an array of integers that defines the test. Return -1 on a
112886 ** memory allocation error, 0 on success, or non-zero for an error.
112887 ** See the sqlite3BitvecBuiltinTest() for additional information.
112889 case SQLITE_TESTCTRL_BITVEC_TEST: {
112890 int sz = va_arg(ap, int);
112891 int *aProg = va_arg(ap, int*);
112892 rc = sqlite3BitvecBuiltinTest(sz, aProg);
112893 break;
112897 ** sqlite3_test_control(BENIGN_MALLOC_HOOKS, xBegin, xEnd)
112899 ** Register hooks to call to indicate which malloc() failures
112900 ** are benign.
112902 case SQLITE_TESTCTRL_BENIGN_MALLOC_HOOKS: {
112903 typedef void (*void_function)(void);
112904 void_function xBenignBegin;
112905 void_function xBenignEnd;
112906 xBenignBegin = va_arg(ap, void_function);
112907 xBenignEnd = va_arg(ap, void_function);
112908 sqlite3BenignMallocHooks(xBenignBegin, xBenignEnd);
112909 break;
112913 ** sqlite3_test_control(SQLITE_TESTCTRL_PENDING_BYTE, unsigned int X)
112915 ** Set the PENDING byte to the value in the argument, if X>0.
112916 ** Make no changes if X==0. Return the value of the pending byte
112917 ** as it existing before this routine was called.
112919 ** IMPORTANT: Changing the PENDING byte from 0x40000000 results in
112920 ** an incompatible database file format. Changing the PENDING byte
112921 ** while any database connection is open results in undefined and
112922 ** dileterious behavior.
112924 case SQLITE_TESTCTRL_PENDING_BYTE: {
112925 rc = PENDING_BYTE;
112926 #ifndef SQLITE_OMIT_WSD
112928 unsigned int newVal = va_arg(ap, unsigned int);
112929 if( newVal ) sqlite3PendingByte = newVal;
112931 #endif
112932 break;
112936 ** sqlite3_test_control(SQLITE_TESTCTRL_ASSERT, int X)
112938 ** This action provides a run-time test to see whether or not
112939 ** assert() was enabled at compile-time. If X is true and assert()
112940 ** is enabled, then the return value is true. If X is true and
112941 ** assert() is disabled, then the return value is zero. If X is
112942 ** false and assert() is enabled, then the assertion fires and the
112943 ** process aborts. If X is false and assert() is disabled, then the
112944 ** return value is zero.
112946 case SQLITE_TESTCTRL_ASSERT: {
112947 volatile int x = 0;
112948 assert( (x = va_arg(ap,int))!=0 );
112949 rc = x;
112950 break;
112955 ** sqlite3_test_control(SQLITE_TESTCTRL_ALWAYS, int X)
112957 ** This action provides a run-time test to see how the ALWAYS and
112958 ** NEVER macros were defined at compile-time.
112960 ** The return value is ALWAYS(X).
112962 ** The recommended test is X==2. If the return value is 2, that means
112963 ** ALWAYS() and NEVER() are both no-op pass-through macros, which is the
112964 ** default setting. If the return value is 1, then ALWAYS() is either
112965 ** hard-coded to true or else it asserts if its argument is false.
112966 ** The first behavior (hard-coded to true) is the case if
112967 ** SQLITE_TESTCTRL_ASSERT shows that assert() is disabled and the second
112968 ** behavior (assert if the argument to ALWAYS() is false) is the case if
112969 ** SQLITE_TESTCTRL_ASSERT shows that assert() is enabled.
112971 ** The run-time test procedure might look something like this:
112973 ** if( sqlite3_test_control(SQLITE_TESTCTRL_ALWAYS, 2)==2 ){
112974 ** // ALWAYS() and NEVER() are no-op pass-through macros
112975 ** }else if( sqlite3_test_control(SQLITE_TESTCTRL_ASSERT, 1) ){
112976 ** // ALWAYS(x) asserts that x is true. NEVER(x) asserts x is false.
112977 ** }else{
112978 ** // ALWAYS(x) is a constant 1. NEVER(x) is a constant 0.
112981 case SQLITE_TESTCTRL_ALWAYS: {
112982 int x = va_arg(ap,int);
112983 rc = ALWAYS(x);
112984 break;
112987 /* sqlite3_test_control(SQLITE_TESTCTRL_RESERVE, sqlite3 *db, int N)
112989 ** Set the nReserve size to N for the main database on the database
112990 ** connection db.
112992 case SQLITE_TESTCTRL_RESERVE: {
112993 sqlite3 *db = va_arg(ap, sqlite3*);
112994 int x = va_arg(ap,int);
112995 sqlite3_mutex_enter(db->mutex);
112996 sqlite3BtreeSetPageSize(db->aDb[0].pBt, 0, x, 0);
112997 sqlite3_mutex_leave(db->mutex);
112998 break;
113001 /* sqlite3_test_control(SQLITE_TESTCTRL_OPTIMIZATIONS, sqlite3 *db, int N)
113003 ** Enable or disable various optimizations for testing purposes. The
113004 ** argument N is a bitmask of optimizations to be disabled. For normal
113005 ** operation N should be 0. The idea is that a test program (like the
113006 ** SQL Logic Test or SLT test module) can run the same SQL multiple times
113007 ** with various optimizations disabled to verify that the same answer
113008 ** is obtained in every case.
113010 case SQLITE_TESTCTRL_OPTIMIZATIONS: {
113011 sqlite3 *db = va_arg(ap, sqlite3*);
113012 int x = va_arg(ap,int);
113013 db->flags = (x & SQLITE_OptMask) | (db->flags & ~SQLITE_OptMask);
113014 break;
113017 #ifdef SQLITE_N_KEYWORD
113018 /* sqlite3_test_control(SQLITE_TESTCTRL_ISKEYWORD, const char *zWord)
113020 ** If zWord is a keyword recognized by the parser, then return the
113021 ** number of keywords. Or if zWord is not a keyword, return 0.
113023 ** This test feature is only available in the amalgamation since
113024 ** the SQLITE_N_KEYWORD macro is not defined in this file if SQLite
113025 ** is built using separate source files.
113027 case SQLITE_TESTCTRL_ISKEYWORD: {
113028 const char *zWord = va_arg(ap, const char*);
113029 int n = sqlite3Strlen30(zWord);
113030 rc = (sqlite3KeywordCode((u8*)zWord, n)!=TK_ID) ? SQLITE_N_KEYWORD : 0;
113031 break;
113033 #endif
113035 /* sqlite3_test_control(SQLITE_TESTCTRL_PGHDRSZ)
113037 ** Return the size of a pcache header in bytes.
113039 case SQLITE_TESTCTRL_PGHDRSZ: {
113040 rc = sizeof(PgHdr);
113041 break;
113044 /* sqlite3_test_control(SQLITE_TESTCTRL_SCRATCHMALLOC, sz, &pNew, pFree);
113046 ** Pass pFree into sqlite3ScratchFree().
113047 ** If sz>0 then allocate a scratch buffer into pNew.
113049 case SQLITE_TESTCTRL_SCRATCHMALLOC: {
113050 void *pFree, **ppNew;
113051 int sz;
113052 sz = va_arg(ap, int);
113053 ppNew = va_arg(ap, void**);
113054 pFree = va_arg(ap, void*);
113055 if( sz ) *ppNew = sqlite3ScratchMalloc(sz);
113056 sqlite3ScratchFree(pFree);
113057 break;
113060 /* sqlite3_test_control(SQLITE_TESTCTRL_LOCALTIME_FAULT, int onoff);
113062 ** If parameter onoff is non-zero, configure the wrappers so that all
113063 ** subsequent calls to localtime() and variants fail. If onoff is zero,
113064 ** undo this setting.
113066 case SQLITE_TESTCTRL_LOCALTIME_FAULT: {
113067 sqlite3GlobalConfig.bLocaltimeFault = va_arg(ap, int);
113068 break;
113072 va_end(ap);
113073 #endif /* SQLITE_OMIT_BUILTIN_TEST */
113074 return rc;
113078 ** This is a utility routine, useful to VFS implementations, that checks
113079 ** to see if a database file was a URI that contained a specific query
113080 ** parameter, and if so obtains the value of the query parameter.
113082 ** The zFilename argument is the filename pointer passed into the xOpen()
113083 ** method of a VFS implementation. The zParam argument is the name of the
113084 ** query parameter we seek. This routine returns the value of the zParam
113085 ** parameter if it exists. If the parameter does not exist, this routine
113086 ** returns a NULL pointer.
113088 SQLITE_API const char *sqlite3_uri_parameter(const char *zFilename, const char *zParam){
113089 zFilename += sqlite3Strlen30(zFilename) + 1;
113090 while( zFilename[0] ){
113091 int x = strcmp(zFilename, zParam);
113092 zFilename += sqlite3Strlen30(zFilename) + 1;
113093 if( x==0 ) return zFilename;
113094 zFilename += sqlite3Strlen30(zFilename) + 1;
113096 return 0;
113099 /************** End of main.c ************************************************/
113100 /************** Begin file notify.c ******************************************/
113102 ** 2009 March 3
113104 ** The author disclaims copyright to this source code. In place of
113105 ** a legal notice, here is a blessing:
113107 ** May you do good and not evil.
113108 ** May you find forgiveness for yourself and forgive others.
113109 ** May you share freely, never taking more than you give.
113111 *************************************************************************
113113 ** This file contains the implementation of the sqlite3_unlock_notify()
113114 ** API method and its associated functionality.
113117 /* Omit this entire file if SQLITE_ENABLE_UNLOCK_NOTIFY is not defined. */
113118 #ifdef SQLITE_ENABLE_UNLOCK_NOTIFY
113121 ** Public interfaces:
113123 ** sqlite3ConnectionBlocked()
113124 ** sqlite3ConnectionUnlocked()
113125 ** sqlite3ConnectionClosed()
113126 ** sqlite3_unlock_notify()
113129 #define assertMutexHeld() \
113130 assert( sqlite3_mutex_held(sqlite3MutexAlloc(SQLITE_MUTEX_STATIC_MASTER)) )
113133 ** Head of a linked list of all sqlite3 objects created by this process
113134 ** for which either sqlite3.pBlockingConnection or sqlite3.pUnlockConnection
113135 ** is not NULL. This variable may only accessed while the STATIC_MASTER
113136 ** mutex is held.
113138 static sqlite3 *SQLITE_WSD sqlite3BlockedList = 0;
113140 #ifndef NDEBUG
113142 ** This function is a complex assert() that verifies the following
113143 ** properties of the blocked connections list:
113145 ** 1) Each entry in the list has a non-NULL value for either
113146 ** pUnlockConnection or pBlockingConnection, or both.
113148 ** 2) All entries in the list that share a common value for
113149 ** xUnlockNotify are grouped together.
113151 ** 3) If the argument db is not NULL, then none of the entries in the
113152 ** blocked connections list have pUnlockConnection or pBlockingConnection
113153 ** set to db. This is used when closing connection db.
113155 static void checkListProperties(sqlite3 *db){
113156 sqlite3 *p;
113157 for(p=sqlite3BlockedList; p; p=p->pNextBlocked){
113158 int seen = 0;
113159 sqlite3 *p2;
113161 /* Verify property (1) */
113162 assert( p->pUnlockConnection || p->pBlockingConnection );
113164 /* Verify property (2) */
113165 for(p2=sqlite3BlockedList; p2!=p; p2=p2->pNextBlocked){
113166 if( p2->xUnlockNotify==p->xUnlockNotify ) seen = 1;
113167 assert( p2->xUnlockNotify==p->xUnlockNotify || !seen );
113168 assert( db==0 || p->pUnlockConnection!=db );
113169 assert( db==0 || p->pBlockingConnection!=db );
113173 #else
113174 # define checkListProperties(x)
113175 #endif
113178 ** Remove connection db from the blocked connections list. If connection
113179 ** db is not currently a part of the list, this function is a no-op.
113181 static void removeFromBlockedList(sqlite3 *db){
113182 sqlite3 **pp;
113183 assertMutexHeld();
113184 for(pp=&sqlite3BlockedList; *pp; pp = &(*pp)->pNextBlocked){
113185 if( *pp==db ){
113186 *pp = (*pp)->pNextBlocked;
113187 break;
113193 ** Add connection db to the blocked connections list. It is assumed
113194 ** that it is not already a part of the list.
113196 static void addToBlockedList(sqlite3 *db){
113197 sqlite3 **pp;
113198 assertMutexHeld();
113200 pp=&sqlite3BlockedList;
113201 *pp && (*pp)->xUnlockNotify!=db->xUnlockNotify;
113202 pp=&(*pp)->pNextBlocked
113204 db->pNextBlocked = *pp;
113205 *pp = db;
113209 ** Obtain the STATIC_MASTER mutex.
113211 static void enterMutex(void){
113212 sqlite3_mutex_enter(sqlite3MutexAlloc(SQLITE_MUTEX_STATIC_MASTER));
113213 checkListProperties(0);
113217 ** Release the STATIC_MASTER mutex.
113219 static void leaveMutex(void){
113220 assertMutexHeld();
113221 checkListProperties(0);
113222 sqlite3_mutex_leave(sqlite3MutexAlloc(SQLITE_MUTEX_STATIC_MASTER));
113226 ** Register an unlock-notify callback.
113228 ** This is called after connection "db" has attempted some operation
113229 ** but has received an SQLITE_LOCKED error because another connection
113230 ** (call it pOther) in the same process was busy using the same shared
113231 ** cache. pOther is found by looking at db->pBlockingConnection.
113233 ** If there is no blocking connection, the callback is invoked immediately,
113234 ** before this routine returns.
113236 ** If pOther is already blocked on db, then report SQLITE_LOCKED, to indicate
113237 ** a deadlock.
113239 ** Otherwise, make arrangements to invoke xNotify when pOther drops
113240 ** its locks.
113242 ** Each call to this routine overrides any prior callbacks registered
113243 ** on the same "db". If xNotify==0 then any prior callbacks are immediately
113244 ** cancelled.
113246 SQLITE_API int sqlite3_unlock_notify(
113247 sqlite3 *db,
113248 void (*xNotify)(void **, int),
113249 void *pArg
113251 int rc = SQLITE_OK;
113253 sqlite3_mutex_enter(db->mutex);
113254 enterMutex();
113256 if( xNotify==0 ){
113257 removeFromBlockedList(db);
113258 db->pBlockingConnection = 0;
113259 db->pUnlockConnection = 0;
113260 db->xUnlockNotify = 0;
113261 db->pUnlockArg = 0;
113262 }else if( 0==db->pBlockingConnection ){
113263 /* The blocking transaction has been concluded. Or there never was a
113264 ** blocking transaction. In either case, invoke the notify callback
113265 ** immediately.
113267 xNotify(&pArg, 1);
113268 }else{
113269 sqlite3 *p;
113271 for(p=db->pBlockingConnection; p && p!=db; p=p->pUnlockConnection){}
113272 if( p ){
113273 rc = SQLITE_LOCKED; /* Deadlock detected. */
113274 }else{
113275 db->pUnlockConnection = db->pBlockingConnection;
113276 db->xUnlockNotify = xNotify;
113277 db->pUnlockArg = pArg;
113278 removeFromBlockedList(db);
113279 addToBlockedList(db);
113283 leaveMutex();
113284 assert( !db->mallocFailed );
113285 sqlite3Error(db, rc, (rc?"database is deadlocked":0));
113286 sqlite3_mutex_leave(db->mutex);
113287 return rc;
113291 ** This function is called while stepping or preparing a statement
113292 ** associated with connection db. The operation will return SQLITE_LOCKED
113293 ** to the user because it requires a lock that will not be available
113294 ** until connection pBlocker concludes its current transaction.
113296 SQLITE_PRIVATE void sqlite3ConnectionBlocked(sqlite3 *db, sqlite3 *pBlocker){
113297 enterMutex();
113298 if( db->pBlockingConnection==0 && db->pUnlockConnection==0 ){
113299 addToBlockedList(db);
113301 db->pBlockingConnection = pBlocker;
113302 leaveMutex();
113306 ** This function is called when
113307 ** the transaction opened by database db has just finished. Locks held
113308 ** by database connection db have been released.
113310 ** This function loops through each entry in the blocked connections
113311 ** list and does the following:
113313 ** 1) If the sqlite3.pBlockingConnection member of a list entry is
113314 ** set to db, then set pBlockingConnection=0.
113316 ** 2) If the sqlite3.pUnlockConnection member of a list entry is
113317 ** set to db, then invoke the configured unlock-notify callback and
113318 ** set pUnlockConnection=0.
113320 ** 3) If the two steps above mean that pBlockingConnection==0 and
113321 ** pUnlockConnection==0, remove the entry from the blocked connections
113322 ** list.
113324 SQLITE_PRIVATE void sqlite3ConnectionUnlocked(sqlite3 *db){
113325 void (*xUnlockNotify)(void **, int) = 0; /* Unlock-notify cb to invoke */
113326 int nArg = 0; /* Number of entries in aArg[] */
113327 sqlite3 **pp; /* Iterator variable */
113328 void **aArg; /* Arguments to the unlock callback */
113329 void **aDyn = 0; /* Dynamically allocated space for aArg[] */
113330 void *aStatic[16]; /* Starter space for aArg[]. No malloc required */
113332 aArg = aStatic;
113333 enterMutex(); /* Enter STATIC_MASTER mutex */
113335 /* This loop runs once for each entry in the blocked-connections list. */
113336 for(pp=&sqlite3BlockedList; *pp; /* no-op */ ){
113337 sqlite3 *p = *pp;
113339 /* Step 1. */
113340 if( p->pBlockingConnection==db ){
113341 p->pBlockingConnection = 0;
113344 /* Step 2. */
113345 if( p->pUnlockConnection==db ){
113346 assert( p->xUnlockNotify );
113347 if( p->xUnlockNotify!=xUnlockNotify && nArg!=0 ){
113348 xUnlockNotify(aArg, nArg);
113349 nArg = 0;
113352 sqlite3BeginBenignMalloc();
113353 assert( aArg==aDyn || (aDyn==0 && aArg==aStatic) );
113354 assert( nArg<=(int)ArraySize(aStatic) || aArg==aDyn );
113355 if( (!aDyn && nArg==(int)ArraySize(aStatic))
113356 || (aDyn && nArg==(int)(sqlite3MallocSize(aDyn)/sizeof(void*)))
113358 /* The aArg[] array needs to grow. */
113359 void **pNew = (void **)sqlite3Malloc(nArg*sizeof(void *)*2);
113360 if( pNew ){
113361 memcpy(pNew, aArg, nArg*sizeof(void *));
113362 sqlite3_free(aDyn);
113363 aDyn = aArg = pNew;
113364 }else{
113365 /* This occurs when the array of context pointers that need to
113366 ** be passed to the unlock-notify callback is larger than the
113367 ** aStatic[] array allocated on the stack and the attempt to
113368 ** allocate a larger array from the heap has failed.
113370 ** This is a difficult situation to handle. Returning an error
113371 ** code to the caller is insufficient, as even if an error code
113372 ** is returned the transaction on connection db will still be
113373 ** closed and the unlock-notify callbacks on blocked connections
113374 ** will go unissued. This might cause the application to wait
113375 ** indefinitely for an unlock-notify callback that will never
113376 ** arrive.
113378 ** Instead, invoke the unlock-notify callback with the context
113379 ** array already accumulated. We can then clear the array and
113380 ** begin accumulating any further context pointers without
113381 ** requiring any dynamic allocation. This is sub-optimal because
113382 ** it means that instead of one callback with a large array of
113383 ** context pointers the application will receive two or more
113384 ** callbacks with smaller arrays of context pointers, which will
113385 ** reduce the applications ability to prioritize multiple
113386 ** connections. But it is the best that can be done under the
113387 ** circumstances.
113389 xUnlockNotify(aArg, nArg);
113390 nArg = 0;
113393 sqlite3EndBenignMalloc();
113395 aArg[nArg++] = p->pUnlockArg;
113396 xUnlockNotify = p->xUnlockNotify;
113397 p->pUnlockConnection = 0;
113398 p->xUnlockNotify = 0;
113399 p->pUnlockArg = 0;
113402 /* Step 3. */
113403 if( p->pBlockingConnection==0 && p->pUnlockConnection==0 ){
113404 /* Remove connection p from the blocked connections list. */
113405 *pp = p->pNextBlocked;
113406 p->pNextBlocked = 0;
113407 }else{
113408 pp = &p->pNextBlocked;
113412 if( nArg!=0 ){
113413 xUnlockNotify(aArg, nArg);
113415 sqlite3_free(aDyn);
113416 leaveMutex(); /* Leave STATIC_MASTER mutex */
113420 ** This is called when the database connection passed as an argument is
113421 ** being closed. The connection is removed from the blocked list.
113423 SQLITE_PRIVATE void sqlite3ConnectionClosed(sqlite3 *db){
113424 sqlite3ConnectionUnlocked(db);
113425 enterMutex();
113426 removeFromBlockedList(db);
113427 checkListProperties(db);
113428 leaveMutex();
113430 #endif
113432 /************** End of notify.c **********************************************/
113433 /************** Begin file fts3.c ********************************************/
113435 ** 2006 Oct 10
113437 ** The author disclaims copyright to this source code. In place of
113438 ** a legal notice, here is a blessing:
113440 ** May you do good and not evil.
113441 ** May you find forgiveness for yourself and forgive others.
113442 ** May you share freely, never taking more than you give.
113444 ******************************************************************************
113446 ** This is an SQLite module implementing full-text search.
113450 ** The code in this file is only compiled if:
113452 ** * The FTS3 module is being built as an extension
113453 ** (in which case SQLITE_CORE is not defined), or
113455 ** * The FTS3 module is being built into the core of
113456 ** SQLite (in which case SQLITE_ENABLE_FTS3 is defined).
113459 /* The full-text index is stored in a series of b+tree (-like)
113460 ** structures called segments which map terms to doclists. The
113461 ** structures are like b+trees in layout, but are constructed from the
113462 ** bottom up in optimal fashion and are not updatable. Since trees
113463 ** are built from the bottom up, things will be described from the
113464 ** bottom up.
113467 **** Varints ****
113468 ** The basic unit of encoding is a variable-length integer called a
113469 ** varint. We encode variable-length integers in little-endian order
113470 ** using seven bits * per byte as follows:
113472 ** KEY:
113473 ** A = 0xxxxxxx 7 bits of data and one flag bit
113474 ** B = 1xxxxxxx 7 bits of data and one flag bit
113476 ** 7 bits - A
113477 ** 14 bits - BA
113478 ** 21 bits - BBA
113479 ** and so on.
113481 ** This is similar in concept to how sqlite encodes "varints" but
113482 ** the encoding is not the same. SQLite varints are big-endian
113483 ** are are limited to 9 bytes in length whereas FTS3 varints are
113484 ** little-endian and can be up to 10 bytes in length (in theory).
113486 ** Example encodings:
113488 ** 1: 0x01
113489 ** 127: 0x7f
113490 ** 128: 0x81 0x00
113493 **** Document lists ****
113494 ** A doclist (document list) holds a docid-sorted list of hits for a
113495 ** given term. Doclists hold docids and associated token positions.
113496 ** A docid is the unique integer identifier for a single document.
113497 ** A position is the index of a word within the document. The first
113498 ** word of the document has a position of 0.
113500 ** FTS3 used to optionally store character offsets using a compile-time
113501 ** option. But that functionality is no longer supported.
113503 ** A doclist is stored like this:
113505 ** array {
113506 ** varint docid;
113507 ** array { (position list for column 0)
113508 ** varint position; (2 more than the delta from previous position)
113510 ** array {
113511 ** varint POS_COLUMN; (marks start of position list for new column)
113512 ** varint column; (index of new column)
113513 ** array {
113514 ** varint position; (2 more than the delta from previous position)
113517 ** varint POS_END; (marks end of positions for this document.
113520 ** Here, array { X } means zero or more occurrences of X, adjacent in
113521 ** memory. A "position" is an index of a token in the token stream
113522 ** generated by the tokenizer. Note that POS_END and POS_COLUMN occur
113523 ** in the same logical place as the position element, and act as sentinals
113524 ** ending a position list array. POS_END is 0. POS_COLUMN is 1.
113525 ** The positions numbers are not stored literally but rather as two more
113526 ** than the difference from the prior position, or the just the position plus
113527 ** 2 for the first position. Example:
113529 ** label: A B C D E F G H I J K
113530 ** value: 123 5 9 1 1 14 35 0 234 72 0
113532 ** The 123 value is the first docid. For column zero in this document
113533 ** there are two matches at positions 3 and 10 (5-2 and 9-2+3). The 1
113534 ** at D signals the start of a new column; the 1 at E indicates that the
113535 ** new column is column number 1. There are two positions at 12 and 45
113536 ** (14-2 and 35-2+12). The 0 at H indicate the end-of-document. The
113537 ** 234 at I is the next docid. It has one position 72 (72-2) and then
113538 ** terminates with the 0 at K.
113540 ** A "position-list" is the list of positions for multiple columns for
113541 ** a single docid. A "column-list" is the set of positions for a single
113542 ** column. Hence, a position-list consists of one or more column-lists,
113543 ** a document record consists of a docid followed by a position-list and
113544 ** a doclist consists of one or more document records.
113546 ** A bare doclist omits the position information, becoming an
113547 ** array of varint-encoded docids.
113549 **** Segment leaf nodes ****
113550 ** Segment leaf nodes store terms and doclists, ordered by term. Leaf
113551 ** nodes are written using LeafWriter, and read using LeafReader (to
113552 ** iterate through a single leaf node's data) and LeavesReader (to
113553 ** iterate through a segment's entire leaf layer). Leaf nodes have
113554 ** the format:
113556 ** varint iHeight; (height from leaf level, always 0)
113557 ** varint nTerm; (length of first term)
113558 ** char pTerm[nTerm]; (content of first term)
113559 ** varint nDoclist; (length of term's associated doclist)
113560 ** char pDoclist[nDoclist]; (content of doclist)
113561 ** array {
113562 ** (further terms are delta-encoded)
113563 ** varint nPrefix; (length of prefix shared with previous term)
113564 ** varint nSuffix; (length of unshared suffix)
113565 ** char pTermSuffix[nSuffix];(unshared suffix of next term)
113566 ** varint nDoclist; (length of term's associated doclist)
113567 ** char pDoclist[nDoclist]; (content of doclist)
113570 ** Here, array { X } means zero or more occurrences of X, adjacent in
113571 ** memory.
113573 ** Leaf nodes are broken into blocks which are stored contiguously in
113574 ** the %_segments table in sorted order. This means that when the end
113575 ** of a node is reached, the next term is in the node with the next
113576 ** greater node id.
113578 ** New data is spilled to a new leaf node when the current node
113579 ** exceeds LEAF_MAX bytes (default 2048). New data which itself is
113580 ** larger than STANDALONE_MIN (default 1024) is placed in a standalone
113581 ** node (a leaf node with a single term and doclist). The goal of
113582 ** these settings is to pack together groups of small doclists while
113583 ** making it efficient to directly access large doclists. The
113584 ** assumption is that large doclists represent terms which are more
113585 ** likely to be query targets.
113587 ** TODO(shess) It may be useful for blocking decisions to be more
113588 ** dynamic. For instance, it may make more sense to have a 2.5k leaf
113589 ** node rather than splitting into 2k and .5k nodes. My intuition is
113590 ** that this might extend through 2x or 4x the pagesize.
113593 **** Segment interior nodes ****
113594 ** Segment interior nodes store blockids for subtree nodes and terms
113595 ** to describe what data is stored by the each subtree. Interior
113596 ** nodes are written using InteriorWriter, and read using
113597 ** InteriorReader. InteriorWriters are created as needed when
113598 ** SegmentWriter creates new leaf nodes, or when an interior node
113599 ** itself grows too big and must be split. The format of interior
113600 ** nodes:
113602 ** varint iHeight; (height from leaf level, always >0)
113603 ** varint iBlockid; (block id of node's leftmost subtree)
113604 ** optional {
113605 ** varint nTerm; (length of first term)
113606 ** char pTerm[nTerm]; (content of first term)
113607 ** array {
113608 ** (further terms are delta-encoded)
113609 ** varint nPrefix; (length of shared prefix with previous term)
113610 ** varint nSuffix; (length of unshared suffix)
113611 ** char pTermSuffix[nSuffix]; (unshared suffix of next term)
113615 ** Here, optional { X } means an optional element, while array { X }
113616 ** means zero or more occurrences of X, adjacent in memory.
113618 ** An interior node encodes n terms separating n+1 subtrees. The
113619 ** subtree blocks are contiguous, so only the first subtree's blockid
113620 ** is encoded. The subtree at iBlockid will contain all terms less
113621 ** than the first term encoded (or all terms if no term is encoded).
113622 ** Otherwise, for terms greater than or equal to pTerm[i] but less
113623 ** than pTerm[i+1], the subtree for that term will be rooted at
113624 ** iBlockid+i. Interior nodes only store enough term data to
113625 ** distinguish adjacent children (if the rightmost term of the left
113626 ** child is "something", and the leftmost term of the right child is
113627 ** "wicked", only "w" is stored).
113629 ** New data is spilled to a new interior node at the same height when
113630 ** the current node exceeds INTERIOR_MAX bytes (default 2048).
113631 ** INTERIOR_MIN_TERMS (default 7) keeps large terms from monopolizing
113632 ** interior nodes and making the tree too skinny. The interior nodes
113633 ** at a given height are naturally tracked by interior nodes at
113634 ** height+1, and so on.
113637 **** Segment directory ****
113638 ** The segment directory in table %_segdir stores meta-information for
113639 ** merging and deleting segments, and also the root node of the
113640 ** segment's tree.
113642 ** The root node is the top node of the segment's tree after encoding
113643 ** the entire segment, restricted to ROOT_MAX bytes (default 1024).
113644 ** This could be either a leaf node or an interior node. If the top
113645 ** node requires more than ROOT_MAX bytes, it is flushed to %_segments
113646 ** and a new root interior node is generated (which should always fit
113647 ** within ROOT_MAX because it only needs space for 2 varints, the
113648 ** height and the blockid of the previous root).
113650 ** The meta-information in the segment directory is:
113651 ** level - segment level (see below)
113652 ** idx - index within level
113653 ** - (level,idx uniquely identify a segment)
113654 ** start_block - first leaf node
113655 ** leaves_end_block - last leaf node
113656 ** end_block - last block (including interior nodes)
113657 ** root - contents of root node
113659 ** If the root node is a leaf node, then start_block,
113660 ** leaves_end_block, and end_block are all 0.
113663 **** Segment merging ****
113664 ** To amortize update costs, segments are grouped into levels and
113665 ** merged in batches. Each increase in level represents exponentially
113666 ** more documents.
113668 ** New documents (actually, document updates) are tokenized and
113669 ** written individually (using LeafWriter) to a level 0 segment, with
113670 ** incrementing idx. When idx reaches MERGE_COUNT (default 16), all
113671 ** level 0 segments are merged into a single level 1 segment. Level 1
113672 ** is populated like level 0, and eventually MERGE_COUNT level 1
113673 ** segments are merged to a single level 2 segment (representing
113674 ** MERGE_COUNT^2 updates), and so on.
113676 ** A segment merge traverses all segments at a given level in
113677 ** parallel, performing a straightforward sorted merge. Since segment
113678 ** leaf nodes are written in to the %_segments table in order, this
113679 ** merge traverses the underlying sqlite disk structures efficiently.
113680 ** After the merge, all segment blocks from the merged level are
113681 ** deleted.
113683 ** MERGE_COUNT controls how often we merge segments. 16 seems to be
113684 ** somewhat of a sweet spot for insertion performance. 32 and 64 show
113685 ** very similar performance numbers to 16 on insertion, though they're
113686 ** a tiny bit slower (perhaps due to more overhead in merge-time
113687 ** sorting). 8 is about 20% slower than 16, 4 about 50% slower than
113688 ** 16, 2 about 66% slower than 16.
113690 ** At query time, high MERGE_COUNT increases the number of segments
113691 ** which need to be scanned and merged. For instance, with 100k docs
113692 ** inserted:
113694 ** MERGE_COUNT segments
113695 ** 16 25
113696 ** 8 12
113697 ** 4 10
113698 ** 2 6
113700 ** This appears to have only a moderate impact on queries for very
113701 ** frequent terms (which are somewhat dominated by segment merge
113702 ** costs), and infrequent and non-existent terms still seem to be fast
113703 ** even with many segments.
113705 ** TODO(shess) That said, it would be nice to have a better query-side
113706 ** argument for MERGE_COUNT of 16. Also, it is possible/likely that
113707 ** optimizations to things like doclist merging will swing the sweet
113708 ** spot around.
113712 **** Handling of deletions and updates ****
113713 ** Since we're using a segmented structure, with no docid-oriented
113714 ** index into the term index, we clearly cannot simply update the term
113715 ** index when a document is deleted or updated. For deletions, we
113716 ** write an empty doclist (varint(docid) varint(POS_END)), for updates
113717 ** we simply write the new doclist. Segment merges overwrite older
113718 ** data for a particular docid with newer data, so deletes or updates
113719 ** will eventually overtake the earlier data and knock it out. The
113720 ** query logic likewise merges doclists so that newer data knocks out
113721 ** older data.
113723 ** TODO(shess) Provide a VACUUM type operation to clear out all
113724 ** deletions and duplications. This would basically be a forced merge
113725 ** into a single segment.
113728 /************** Include fts3Int.h in the middle of fts3.c ********************/
113729 /************** Begin file fts3Int.h *****************************************/
113731 ** 2009 Nov 12
113733 ** The author disclaims copyright to this source code. In place of
113734 ** a legal notice, here is a blessing:
113736 ** May you do good and not evil.
113737 ** May you find forgiveness for yourself and forgive others.
113738 ** May you share freely, never taking more than you give.
113740 ******************************************************************************
113743 #ifndef _FTSINT_H
113744 #define _FTSINT_H
113746 #if !defined(NDEBUG) && !defined(SQLITE_DEBUG)
113747 # define NDEBUG 1
113748 #endif
113751 ** FTS4 is really an extension for FTS3. It is enabled using the
113752 ** SQLITE_ENABLE_FTS3 macro. But to avoid confusion we also all
113753 ** the SQLITE_ENABLE_FTS4 macro to serve as an alisse for SQLITE_ENABLE_FTS3.
113755 #if defined(SQLITE_ENABLE_FTS4) && !defined(SQLITE_ENABLE_FTS3)
113756 # define SQLITE_ENABLE_FTS3
113757 #endif
113759 #if !defined(SQLITE_CORE) || defined(SQLITE_ENABLE_FTS3)
113761 /* If not building as part of the core, include sqlite3ext.h. */
113762 #ifndef SQLITE_CORE
113763 SQLITE_API extern const sqlite3_api_routines *sqlite3_api;
113764 #endif
113766 /************** Include fts3_tokenizer.h in the middle of fts3Int.h **********/
113767 /************** Begin file fts3_tokenizer.h **********************************/
113769 ** 2006 July 10
113771 ** The author disclaims copyright to this source code.
113773 *************************************************************************
113774 ** Defines the interface to tokenizers used by fulltext-search. There
113775 ** are three basic components:
113777 ** sqlite3_tokenizer_module is a singleton defining the tokenizer
113778 ** interface functions. This is essentially the class structure for
113779 ** tokenizers.
113781 ** sqlite3_tokenizer is used to define a particular tokenizer, perhaps
113782 ** including customization information defined at creation time.
113784 ** sqlite3_tokenizer_cursor is generated by a tokenizer to generate
113785 ** tokens from a particular input.
113787 #ifndef _FTS3_TOKENIZER_H_
113788 #define _FTS3_TOKENIZER_H_
113790 /* TODO(shess) Only used for SQLITE_OK and SQLITE_DONE at this time.
113791 ** If tokenizers are to be allowed to call sqlite3_*() functions, then
113792 ** we will need a way to register the API consistently.
113796 ** Structures used by the tokenizer interface. When a new tokenizer
113797 ** implementation is registered, the caller provides a pointer to
113798 ** an sqlite3_tokenizer_module containing pointers to the callback
113799 ** functions that make up an implementation.
113801 ** When an fts3 table is created, it passes any arguments passed to
113802 ** the tokenizer clause of the CREATE VIRTUAL TABLE statement to the
113803 ** sqlite3_tokenizer_module.xCreate() function of the requested tokenizer
113804 ** implementation. The xCreate() function in turn returns an
113805 ** sqlite3_tokenizer structure representing the specific tokenizer to
113806 ** be used for the fts3 table (customized by the tokenizer clause arguments).
113808 ** To tokenize an input buffer, the sqlite3_tokenizer_module.xOpen()
113809 ** method is called. It returns an sqlite3_tokenizer_cursor object
113810 ** that may be used to tokenize a specific input buffer based on
113811 ** the tokenization rules supplied by a specific sqlite3_tokenizer
113812 ** object.
113814 typedef struct sqlite3_tokenizer_module sqlite3_tokenizer_module;
113815 typedef struct sqlite3_tokenizer sqlite3_tokenizer;
113816 typedef struct sqlite3_tokenizer_cursor sqlite3_tokenizer_cursor;
113818 struct sqlite3_tokenizer_module {
113821 ** Structure version. Should always be set to 0.
113823 int iVersion;
113826 ** Create a new tokenizer. The values in the argv[] array are the
113827 ** arguments passed to the "tokenizer" clause of the CREATE VIRTUAL
113828 ** TABLE statement that created the fts3 table. For example, if
113829 ** the following SQL is executed:
113831 ** CREATE .. USING fts3( ... , tokenizer <tokenizer-name> arg1 arg2)
113833 ** then argc is set to 2, and the argv[] array contains pointers
113834 ** to the strings "arg1" and "arg2".
113836 ** This method should return either SQLITE_OK (0), or an SQLite error
113837 ** code. If SQLITE_OK is returned, then *ppTokenizer should be set
113838 ** to point at the newly created tokenizer structure. The generic
113839 ** sqlite3_tokenizer.pModule variable should not be initialised by
113840 ** this callback. The caller will do so.
113842 int (*xCreate)(
113843 int argc, /* Size of argv array */
113844 const char *const*argv, /* Tokenizer argument strings */
113845 sqlite3_tokenizer **ppTokenizer /* OUT: Created tokenizer */
113849 ** Destroy an existing tokenizer. The fts3 module calls this method
113850 ** exactly once for each successful call to xCreate().
113852 int (*xDestroy)(sqlite3_tokenizer *pTokenizer);
113855 ** Create a tokenizer cursor to tokenize an input buffer. The caller
113856 ** is responsible for ensuring that the input buffer remains valid
113857 ** until the cursor is closed (using the xClose() method).
113859 int (*xOpen)(
113860 sqlite3_tokenizer *pTokenizer, /* Tokenizer object */
113861 const char *pInput, int nBytes, /* Input buffer */
113862 sqlite3_tokenizer_cursor **ppCursor /* OUT: Created tokenizer cursor */
113866 ** Destroy an existing tokenizer cursor. The fts3 module calls this
113867 ** method exactly once for each successful call to xOpen().
113869 int (*xClose)(sqlite3_tokenizer_cursor *pCursor);
113872 ** Retrieve the next token from the tokenizer cursor pCursor. This
113873 ** method should either return SQLITE_OK and set the values of the
113874 ** "OUT" variables identified below, or SQLITE_DONE to indicate that
113875 ** the end of the buffer has been reached, or an SQLite error code.
113877 ** *ppToken should be set to point at a buffer containing the
113878 ** normalized version of the token (i.e. after any case-folding and/or
113879 ** stemming has been performed). *pnBytes should be set to the length
113880 ** of this buffer in bytes. The input text that generated the token is
113881 ** identified by the byte offsets returned in *piStartOffset and
113882 ** *piEndOffset. *piStartOffset should be set to the index of the first
113883 ** byte of the token in the input buffer. *piEndOffset should be set
113884 ** to the index of the first byte just past the end of the token in
113885 ** the input buffer.
113887 ** The buffer *ppToken is set to point at is managed by the tokenizer
113888 ** implementation. It is only required to be valid until the next call
113889 ** to xNext() or xClose().
113891 /* TODO(shess) current implementation requires pInput to be
113892 ** nul-terminated. This should either be fixed, or pInput/nBytes
113893 ** should be converted to zInput.
113895 int (*xNext)(
113896 sqlite3_tokenizer_cursor *pCursor, /* Tokenizer cursor */
113897 const char **ppToken, int *pnBytes, /* OUT: Normalized text for token */
113898 int *piStartOffset, /* OUT: Byte offset of token in input buffer */
113899 int *piEndOffset, /* OUT: Byte offset of end of token in input buffer */
113900 int *piPosition /* OUT: Number of tokens returned before this one */
113904 struct sqlite3_tokenizer {
113905 const sqlite3_tokenizer_module *pModule; /* The module for this tokenizer */
113906 /* Tokenizer implementations will typically add additional fields */
113909 struct sqlite3_tokenizer_cursor {
113910 sqlite3_tokenizer *pTokenizer; /* Tokenizer for this cursor. */
113911 /* Tokenizer implementations will typically add additional fields */
113914 int fts3_global_term_cnt(int iTerm, int iCol);
113915 int fts3_term_cnt(int iTerm, int iCol);
113918 #endif /* _FTS3_TOKENIZER_H_ */
113920 /************** End of fts3_tokenizer.h **************************************/
113921 /************** Continuing where we left off in fts3Int.h ********************/
113922 /************** Include fts3_hash.h in the middle of fts3Int.h ***************/
113923 /************** Begin file fts3_hash.h ***************************************/
113925 ** 2001 September 22
113927 ** The author disclaims copyright to this source code. In place of
113928 ** a legal notice, here is a blessing:
113930 ** May you do good and not evil.
113931 ** May you find forgiveness for yourself and forgive others.
113932 ** May you share freely, never taking more than you give.
113934 *************************************************************************
113935 ** This is the header file for the generic hash-table implemenation
113936 ** used in SQLite. We've modified it slightly to serve as a standalone
113937 ** hash table implementation for the full-text indexing module.
113940 #ifndef _FTS3_HASH_H_
113941 #define _FTS3_HASH_H_
113943 /* Forward declarations of structures. */
113944 typedef struct Fts3Hash Fts3Hash;
113945 typedef struct Fts3HashElem Fts3HashElem;
113947 /* A complete hash table is an instance of the following structure.
113948 ** The internals of this structure are intended to be opaque -- client
113949 ** code should not attempt to access or modify the fields of this structure
113950 ** directly. Change this structure only by using the routines below.
113951 ** However, many of the "procedures" and "functions" for modifying and
113952 ** accessing this structure are really macros, so we can't really make
113953 ** this structure opaque.
113955 struct Fts3Hash {
113956 char keyClass; /* HASH_INT, _POINTER, _STRING, _BINARY */
113957 char copyKey; /* True if copy of key made on insert */
113958 int count; /* Number of entries in this table */
113959 Fts3HashElem *first; /* The first element of the array */
113960 int htsize; /* Number of buckets in the hash table */
113961 struct _fts3ht { /* the hash table */
113962 int count; /* Number of entries with this hash */
113963 Fts3HashElem *chain; /* Pointer to first entry with this hash */
113964 } *ht;
113967 /* Each element in the hash table is an instance of the following
113968 ** structure. All elements are stored on a single doubly-linked list.
113970 ** Again, this structure is intended to be opaque, but it can't really
113971 ** be opaque because it is used by macros.
113973 struct Fts3HashElem {
113974 Fts3HashElem *next, *prev; /* Next and previous elements in the table */
113975 void *data; /* Data associated with this element */
113976 void *pKey; int nKey; /* Key associated with this element */
113980 ** There are 2 different modes of operation for a hash table:
113982 ** FTS3_HASH_STRING pKey points to a string that is nKey bytes long
113983 ** (including the null-terminator, if any). Case
113984 ** is respected in comparisons.
113986 ** FTS3_HASH_BINARY pKey points to binary data nKey bytes long.
113987 ** memcmp() is used to compare keys.
113989 ** A copy of the key is made if the copyKey parameter to fts3HashInit is 1.
113991 #define FTS3_HASH_STRING 1
113992 #define FTS3_HASH_BINARY 2
113995 ** Access routines. To delete, insert a NULL pointer.
113997 SQLITE_PRIVATE void sqlite3Fts3HashInit(Fts3Hash *pNew, char keyClass, char copyKey);
113998 SQLITE_PRIVATE void *sqlite3Fts3HashInsert(Fts3Hash*, const void *pKey, int nKey, void *pData);
113999 SQLITE_PRIVATE void *sqlite3Fts3HashFind(const Fts3Hash*, const void *pKey, int nKey);
114000 SQLITE_PRIVATE void sqlite3Fts3HashClear(Fts3Hash*);
114001 SQLITE_PRIVATE Fts3HashElem *sqlite3Fts3HashFindElem(const Fts3Hash *, const void *, int);
114004 ** Shorthand for the functions above
114006 #define fts3HashInit sqlite3Fts3HashInit
114007 #define fts3HashInsert sqlite3Fts3HashInsert
114008 #define fts3HashFind sqlite3Fts3HashFind
114009 #define fts3HashClear sqlite3Fts3HashClear
114010 #define fts3HashFindElem sqlite3Fts3HashFindElem
114013 ** Macros for looping over all elements of a hash table. The idiom is
114014 ** like this:
114016 ** Fts3Hash h;
114017 ** Fts3HashElem *p;
114018 ** ...
114019 ** for(p=fts3HashFirst(&h); p; p=fts3HashNext(p)){
114020 ** SomeStructure *pData = fts3HashData(p);
114021 ** // do something with pData
114024 #define fts3HashFirst(H) ((H)->first)
114025 #define fts3HashNext(E) ((E)->next)
114026 #define fts3HashData(E) ((E)->data)
114027 #define fts3HashKey(E) ((E)->pKey)
114028 #define fts3HashKeysize(E) ((E)->nKey)
114031 ** Number of entries in a hash table
114033 #define fts3HashCount(H) ((H)->count)
114035 #endif /* _FTS3_HASH_H_ */
114037 /************** End of fts3_hash.h *******************************************/
114038 /************** Continuing where we left off in fts3Int.h ********************/
114041 ** This constant controls how often segments are merged. Once there are
114042 ** FTS3_MERGE_COUNT segments of level N, they are merged into a single
114043 ** segment of level N+1.
114045 #define FTS3_MERGE_COUNT 16
114048 ** This is the maximum amount of data (in bytes) to store in the
114049 ** Fts3Table.pendingTerms hash table. Normally, the hash table is
114050 ** populated as documents are inserted/updated/deleted in a transaction
114051 ** and used to create a new segment when the transaction is committed.
114052 ** However if this limit is reached midway through a transaction, a new
114053 ** segment is created and the hash table cleared immediately.
114055 #define FTS3_MAX_PENDING_DATA (1*1024*1024)
114058 ** Macro to return the number of elements in an array. SQLite has a
114059 ** similar macro called ArraySize(). Use a different name to avoid
114060 ** a collision when building an amalgamation with built-in FTS3.
114062 #define SizeofArray(X) ((int)(sizeof(X)/sizeof(X[0])))
114065 #ifndef MIN
114066 # define MIN(x,y) ((x)<(y)?(x):(y))
114067 #endif
114070 ** Maximum length of a varint encoded integer. The varint format is different
114071 ** from that used by SQLite, so the maximum length is 10, not 9.
114073 #define FTS3_VARINT_MAX 10
114076 ** FTS4 virtual tables may maintain multiple indexes - one index of all terms
114077 ** in the document set and zero or more prefix indexes. All indexes are stored
114078 ** as one or more b+-trees in the %_segments and %_segdir tables.
114080 ** It is possible to determine which index a b+-tree belongs to based on the
114081 ** value stored in the "%_segdir.level" column. Given this value L, the index
114082 ** that the b+-tree belongs to is (L<<10). In other words, all b+-trees with
114083 ** level values between 0 and 1023 (inclusive) belong to index 0, all levels
114084 ** between 1024 and 2047 to index 1, and so on.
114086 ** It is considered impossible for an index to use more than 1024 levels. In
114087 ** theory though this may happen, but only after at least
114088 ** (FTS3_MERGE_COUNT^1024) separate flushes of the pending-terms tables.
114090 #define FTS3_SEGDIR_MAXLEVEL 1024
114091 #define FTS3_SEGDIR_MAXLEVEL_STR "1024"
114094 ** The testcase() macro is only used by the amalgamation. If undefined,
114095 ** make it a no-op.
114097 #ifndef testcase
114098 # define testcase(X)
114099 #endif
114102 ** Terminator values for position-lists and column-lists.
114104 #define POS_COLUMN (1) /* Column-list terminator */
114105 #define POS_END (0) /* Position-list terminator */
114108 ** This section provides definitions to allow the
114109 ** FTS3 extension to be compiled outside of the
114110 ** amalgamation.
114112 #ifndef SQLITE_AMALGAMATION
114114 ** Macros indicating that conditional expressions are always true or
114115 ** false.
114117 #ifdef SQLITE_COVERAGE_TEST
114118 # define ALWAYS(x) (1)
114119 # define NEVER(X) (0)
114120 #else
114121 # define ALWAYS(x) (x)
114122 # define NEVER(X) (x)
114123 #endif
114126 ** Internal types used by SQLite.
114128 typedef unsigned char u8; /* 1-byte (or larger) unsigned integer */
114129 typedef short int i16; /* 2-byte (or larger) signed integer */
114130 typedef unsigned int u32; /* 4-byte unsigned integer */
114131 typedef sqlite3_uint64 u64; /* 8-byte unsigned integer */
114134 ** Macro used to suppress compiler warnings for unused parameters.
114136 #define UNUSED_PARAMETER(x) (void)(x)
114139 ** Activate assert() only if SQLITE_TEST is enabled.
114141 #if !defined(NDEBUG) && !defined(SQLITE_DEBUG)
114142 # define NDEBUG 1
114143 #endif
114146 ** The TESTONLY macro is used to enclose variable declarations or
114147 ** other bits of code that are needed to support the arguments
114148 ** within testcase() and assert() macros.
114150 #if defined(SQLITE_DEBUG) || defined(SQLITE_COVERAGE_TEST)
114151 # define TESTONLY(X) X
114152 #else
114153 # define TESTONLY(X)
114154 #endif
114156 #endif /* SQLITE_AMALGAMATION */
114158 typedef struct Fts3Table Fts3Table;
114159 typedef struct Fts3Cursor Fts3Cursor;
114160 typedef struct Fts3Expr Fts3Expr;
114161 typedef struct Fts3Phrase Fts3Phrase;
114162 typedef struct Fts3PhraseToken Fts3PhraseToken;
114164 typedef struct Fts3Doclist Fts3Doclist;
114165 typedef struct Fts3SegFilter Fts3SegFilter;
114166 typedef struct Fts3DeferredToken Fts3DeferredToken;
114167 typedef struct Fts3SegReader Fts3SegReader;
114168 typedef struct Fts3MultiSegReader Fts3MultiSegReader;
114171 ** A connection to a fulltext index is an instance of the following
114172 ** structure. The xCreate and xConnect methods create an instance
114173 ** of this structure and xDestroy and xDisconnect free that instance.
114174 ** All other methods receive a pointer to the structure as one of their
114175 ** arguments.
114177 struct Fts3Table {
114178 sqlite3_vtab base; /* Base class used by SQLite core */
114179 sqlite3 *db; /* The database connection */
114180 const char *zDb; /* logical database name */
114181 const char *zName; /* virtual table name */
114182 int nColumn; /* number of named columns in virtual table */
114183 char **azColumn; /* column names. malloced */
114184 sqlite3_tokenizer *pTokenizer; /* tokenizer for inserts and queries */
114186 /* Precompiled statements used by the implementation. Each of these
114187 ** statements is run and reset within a single virtual table API call.
114189 sqlite3_stmt *aStmt[27];
114191 char *zReadExprlist;
114192 char *zWriteExprlist;
114194 int nNodeSize; /* Soft limit for node size */
114195 u8 bHasStat; /* True if %_stat table exists */
114196 u8 bHasDocsize; /* True if %_docsize table exists */
114197 u8 bDescIdx; /* True if doclists are in reverse order */
114198 int nPgsz; /* Page size for host database */
114199 char *zSegmentsTbl; /* Name of %_segments table */
114200 sqlite3_blob *pSegments; /* Blob handle open on %_segments table */
114202 /* TODO: Fix the first paragraph of this comment.
114204 ** The following hash table is used to buffer pending index updates during
114205 ** transactions. Variable nPendingData estimates the memory size of the
114206 ** pending data, including hash table overhead, but not malloc overhead.
114207 ** When nPendingData exceeds nMaxPendingData, the buffer is flushed
114208 ** automatically. Variable iPrevDocid is the docid of the most recently
114209 ** inserted record.
114211 ** A single FTS4 table may have multiple full-text indexes. For each index
114212 ** there is an entry in the aIndex[] array. Index 0 is an index of all the
114213 ** terms that appear in the document set. Each subsequent index in aIndex[]
114214 ** is an index of prefixes of a specific length.
114216 int nIndex; /* Size of aIndex[] */
114217 struct Fts3Index {
114218 int nPrefix; /* Prefix length (0 for main terms index) */
114219 Fts3Hash hPending; /* Pending terms table for this index */
114220 } *aIndex;
114221 int nMaxPendingData; /* Max pending data before flush to disk */
114222 int nPendingData; /* Current bytes of pending data */
114223 sqlite_int64 iPrevDocid; /* Docid of most recently inserted document */
114225 #if defined(SQLITE_DEBUG)
114226 /* State variables used for validating that the transaction control
114227 ** methods of the virtual table are called at appropriate times. These
114228 ** values do not contribution to the FTS computation; they are used for
114229 ** verifying the SQLite core.
114231 int inTransaction; /* True after xBegin but before xCommit/xRollback */
114232 int mxSavepoint; /* Largest valid xSavepoint integer */
114233 #endif
114237 ** When the core wants to read from the virtual table, it creates a
114238 ** virtual table cursor (an instance of the following structure) using
114239 ** the xOpen method. Cursors are destroyed using the xClose method.
114241 struct Fts3Cursor {
114242 sqlite3_vtab_cursor base; /* Base class used by SQLite core */
114243 i16 eSearch; /* Search strategy (see below) */
114244 u8 isEof; /* True if at End Of Results */
114245 u8 isRequireSeek; /* True if must seek pStmt to %_content row */
114246 sqlite3_stmt *pStmt; /* Prepared statement in use by the cursor */
114247 Fts3Expr *pExpr; /* Parsed MATCH query string */
114248 int nPhrase; /* Number of matchable phrases in query */
114249 Fts3DeferredToken *pDeferred; /* Deferred search tokens, if any */
114250 sqlite3_int64 iPrevId; /* Previous id read from aDoclist */
114251 char *pNextId; /* Pointer into the body of aDoclist */
114252 char *aDoclist; /* List of docids for full-text queries */
114253 int nDoclist; /* Size of buffer at aDoclist */
114254 u8 bDesc; /* True to sort in descending order */
114255 int eEvalmode; /* An FTS3_EVAL_XX constant */
114256 int nRowAvg; /* Average size of database rows, in pages */
114257 sqlite3_int64 nDoc; /* Documents in table */
114259 int isMatchinfoNeeded; /* True when aMatchinfo[] needs filling in */
114260 u32 *aMatchinfo; /* Information about most recent match */
114261 int nMatchinfo; /* Number of elements in aMatchinfo[] */
114262 char *zMatchinfo; /* Matchinfo specification */
114265 #define FTS3_EVAL_FILTER 0
114266 #define FTS3_EVAL_NEXT 1
114267 #define FTS3_EVAL_MATCHINFO 2
114270 ** The Fts3Cursor.eSearch member is always set to one of the following.
114271 ** Actualy, Fts3Cursor.eSearch can be greater than or equal to
114272 ** FTS3_FULLTEXT_SEARCH. If so, then Fts3Cursor.eSearch - 2 is the index
114273 ** of the column to be searched. For example, in
114275 ** CREATE VIRTUAL TABLE ex1 USING fts3(a,b,c,d);
114276 ** SELECT docid FROM ex1 WHERE b MATCH 'one two three';
114278 ** Because the LHS of the MATCH operator is 2nd column "b",
114279 ** Fts3Cursor.eSearch will be set to FTS3_FULLTEXT_SEARCH+1. (+0 for a,
114280 ** +1 for b, +2 for c, +3 for d.) If the LHS of MATCH were "ex1"
114281 ** indicating that all columns should be searched,
114282 ** then eSearch would be set to FTS3_FULLTEXT_SEARCH+4.
114284 #define FTS3_FULLSCAN_SEARCH 0 /* Linear scan of %_content table */
114285 #define FTS3_DOCID_SEARCH 1 /* Lookup by rowid on %_content table */
114286 #define FTS3_FULLTEXT_SEARCH 2 /* Full-text index search */
114289 struct Fts3Doclist {
114290 char *aAll; /* Array containing doclist (or NULL) */
114291 int nAll; /* Size of a[] in bytes */
114292 char *pNextDocid; /* Pointer to next docid */
114294 sqlite3_int64 iDocid; /* Current docid (if pList!=0) */
114295 int bFreeList; /* True if pList should be sqlite3_free()d */
114296 char *pList; /* Pointer to position list following iDocid */
114297 int nList; /* Length of position list */
114301 ** A "phrase" is a sequence of one or more tokens that must match in
114302 ** sequence. A single token is the base case and the most common case.
114303 ** For a sequence of tokens contained in double-quotes (i.e. "one two three")
114304 ** nToken will be the number of tokens in the string.
114306 struct Fts3PhraseToken {
114307 char *z; /* Text of the token */
114308 int n; /* Number of bytes in buffer z */
114309 int isPrefix; /* True if token ends with a "*" character */
114311 /* Variables above this point are populated when the expression is
114312 ** parsed (by code in fts3_expr.c). Below this point the variables are
114313 ** used when evaluating the expression. */
114314 Fts3DeferredToken *pDeferred; /* Deferred token object for this token */
114315 Fts3MultiSegReader *pSegcsr; /* Segment-reader for this token */
114318 struct Fts3Phrase {
114319 /* Cache of doclist for this phrase. */
114320 Fts3Doclist doclist;
114321 int bIncr; /* True if doclist is loaded incrementally */
114322 int iDoclistToken;
114324 /* Variables below this point are populated by fts3_expr.c when parsing
114325 ** a MATCH expression. Everything above is part of the evaluation phase.
114327 int nToken; /* Number of tokens in the phrase */
114328 int iColumn; /* Index of column this phrase must match */
114329 Fts3PhraseToken aToken[1]; /* One entry for each token in the phrase */
114333 ** A tree of these objects forms the RHS of a MATCH operator.
114335 ** If Fts3Expr.eType is FTSQUERY_PHRASE and isLoaded is true, then aDoclist
114336 ** points to a malloced buffer, size nDoclist bytes, containing the results
114337 ** of this phrase query in FTS3 doclist format. As usual, the initial
114338 ** "Length" field found in doclists stored on disk is omitted from this
114339 ** buffer.
114341 ** Variable aMI is used only for FTSQUERY_NEAR nodes to store the global
114342 ** matchinfo data. If it is not NULL, it points to an array of size nCol*3,
114343 ** where nCol is the number of columns in the queried FTS table. The array
114344 ** is populated as follows:
114346 ** aMI[iCol*3 + 0] = Undefined
114347 ** aMI[iCol*3 + 1] = Number of occurrences
114348 ** aMI[iCol*3 + 2] = Number of rows containing at least one instance
114350 ** The aMI array is allocated using sqlite3_malloc(). It should be freed
114351 ** when the expression node is.
114353 struct Fts3Expr {
114354 int eType; /* One of the FTSQUERY_XXX values defined below */
114355 int nNear; /* Valid if eType==FTSQUERY_NEAR */
114356 Fts3Expr *pParent; /* pParent->pLeft==this or pParent->pRight==this */
114357 Fts3Expr *pLeft; /* Left operand */
114358 Fts3Expr *pRight; /* Right operand */
114359 Fts3Phrase *pPhrase; /* Valid if eType==FTSQUERY_PHRASE */
114361 /* The following are used by the fts3_eval.c module. */
114362 sqlite3_int64 iDocid; /* Current docid */
114363 u8 bEof; /* True this expression is at EOF already */
114364 u8 bStart; /* True if iDocid is valid */
114365 u8 bDeferred; /* True if this expression is entirely deferred */
114367 u32 *aMI;
114371 ** Candidate values for Fts3Query.eType. Note that the order of the first
114372 ** four values is in order of precedence when parsing expressions. For
114373 ** example, the following:
114375 ** "a OR b AND c NOT d NEAR e"
114377 ** is equivalent to:
114379 ** "a OR (b AND (c NOT (d NEAR e)))"
114381 #define FTSQUERY_NEAR 1
114382 #define FTSQUERY_NOT 2
114383 #define FTSQUERY_AND 3
114384 #define FTSQUERY_OR 4
114385 #define FTSQUERY_PHRASE 5
114388 /* fts3_write.c */
114389 SQLITE_PRIVATE int sqlite3Fts3UpdateMethod(sqlite3_vtab*,int,sqlite3_value**,sqlite3_int64*);
114390 SQLITE_PRIVATE int sqlite3Fts3PendingTermsFlush(Fts3Table *);
114391 SQLITE_PRIVATE void sqlite3Fts3PendingTermsClear(Fts3Table *);
114392 SQLITE_PRIVATE int sqlite3Fts3Optimize(Fts3Table *);
114393 SQLITE_PRIVATE int sqlite3Fts3SegReaderNew(int, sqlite3_int64,
114394 sqlite3_int64, sqlite3_int64, const char *, int, Fts3SegReader**);
114395 SQLITE_PRIVATE int sqlite3Fts3SegReaderPending(
114396 Fts3Table*,int,const char*,int,int,Fts3SegReader**);
114397 SQLITE_PRIVATE void sqlite3Fts3SegReaderFree(Fts3SegReader *);
114398 SQLITE_PRIVATE int sqlite3Fts3AllSegdirs(Fts3Table*, int, int, sqlite3_stmt **);
114399 SQLITE_PRIVATE int sqlite3Fts3ReadLock(Fts3Table *);
114400 SQLITE_PRIVATE int sqlite3Fts3ReadBlock(Fts3Table*, sqlite3_int64, char **, int*, int*);
114402 SQLITE_PRIVATE int sqlite3Fts3SelectDoctotal(Fts3Table *, sqlite3_stmt **);
114403 SQLITE_PRIVATE int sqlite3Fts3SelectDocsize(Fts3Table *, sqlite3_int64, sqlite3_stmt **);
114405 SQLITE_PRIVATE void sqlite3Fts3FreeDeferredTokens(Fts3Cursor *);
114406 SQLITE_PRIVATE int sqlite3Fts3DeferToken(Fts3Cursor *, Fts3PhraseToken *, int);
114407 SQLITE_PRIVATE int sqlite3Fts3CacheDeferredDoclists(Fts3Cursor *);
114408 SQLITE_PRIVATE void sqlite3Fts3FreeDeferredDoclists(Fts3Cursor *);
114409 SQLITE_PRIVATE void sqlite3Fts3SegmentsClose(Fts3Table *);
114411 /* Special values interpreted by sqlite3SegReaderCursor() */
114412 #define FTS3_SEGCURSOR_PENDING -1
114413 #define FTS3_SEGCURSOR_ALL -2
114415 SQLITE_PRIVATE int sqlite3Fts3SegReaderStart(Fts3Table*, Fts3MultiSegReader*, Fts3SegFilter*);
114416 SQLITE_PRIVATE int sqlite3Fts3SegReaderStep(Fts3Table *, Fts3MultiSegReader *);
114417 SQLITE_PRIVATE void sqlite3Fts3SegReaderFinish(Fts3MultiSegReader *);
114419 SQLITE_PRIVATE int sqlite3Fts3SegReaderCursor(
114420 Fts3Table *, int, int, const char *, int, int, int, Fts3MultiSegReader *);
114422 /* Flags allowed as part of the 4th argument to SegmentReaderIterate() */
114423 #define FTS3_SEGMENT_REQUIRE_POS 0x00000001
114424 #define FTS3_SEGMENT_IGNORE_EMPTY 0x00000002
114425 #define FTS3_SEGMENT_COLUMN_FILTER 0x00000004
114426 #define FTS3_SEGMENT_PREFIX 0x00000008
114427 #define FTS3_SEGMENT_SCAN 0x00000010
114429 /* Type passed as 4th argument to SegmentReaderIterate() */
114430 struct Fts3SegFilter {
114431 const char *zTerm;
114432 int nTerm;
114433 int iCol;
114434 int flags;
114437 struct Fts3MultiSegReader {
114438 /* Used internally by sqlite3Fts3SegReaderXXX() calls */
114439 Fts3SegReader **apSegment; /* Array of Fts3SegReader objects */
114440 int nSegment; /* Size of apSegment array */
114441 int nAdvance; /* How many seg-readers to advance */
114442 Fts3SegFilter *pFilter; /* Pointer to filter object */
114443 char *aBuffer; /* Buffer to merge doclists in */
114444 int nBuffer; /* Allocated size of aBuffer[] in bytes */
114446 int iColFilter; /* If >=0, filter for this column */
114447 int bRestart;
114449 /* Used by fts3.c only. */
114450 int nCost; /* Cost of running iterator */
114451 int bLookup; /* True if a lookup of a single entry. */
114453 /* Output values. Valid only after Fts3SegReaderStep() returns SQLITE_ROW. */
114454 char *zTerm; /* Pointer to term buffer */
114455 int nTerm; /* Size of zTerm in bytes */
114456 char *aDoclist; /* Pointer to doclist buffer */
114457 int nDoclist; /* Size of aDoclist[] in bytes */
114460 /* fts3.c */
114461 SQLITE_PRIVATE int sqlite3Fts3PutVarint(char *, sqlite3_int64);
114462 SQLITE_PRIVATE int sqlite3Fts3GetVarint(const char *, sqlite_int64 *);
114463 SQLITE_PRIVATE int sqlite3Fts3GetVarint32(const char *, int *);
114464 SQLITE_PRIVATE int sqlite3Fts3VarintLen(sqlite3_uint64);
114465 SQLITE_PRIVATE void sqlite3Fts3Dequote(char *);
114466 SQLITE_PRIVATE void sqlite3Fts3DoclistPrev(int,char*,int,char**,sqlite3_int64*,int*,u8*);
114468 SQLITE_PRIVATE int sqlite3Fts3EvalPhraseStats(Fts3Cursor *, Fts3Expr *, u32 *);
114470 /* fts3_tokenizer.c */
114471 SQLITE_PRIVATE const char *sqlite3Fts3NextToken(const char *, int *);
114472 SQLITE_PRIVATE int sqlite3Fts3InitHashTable(sqlite3 *, Fts3Hash *, const char *);
114473 SQLITE_PRIVATE int sqlite3Fts3InitTokenizer(Fts3Hash *pHash, const char *,
114474 sqlite3_tokenizer **, char **
114476 SQLITE_PRIVATE int sqlite3Fts3IsIdChar(char);
114478 /* fts3_snippet.c */
114479 SQLITE_PRIVATE void sqlite3Fts3Offsets(sqlite3_context*, Fts3Cursor*);
114480 SQLITE_PRIVATE void sqlite3Fts3Snippet(sqlite3_context *, Fts3Cursor *, const char *,
114481 const char *, const char *, int, int
114483 SQLITE_PRIVATE void sqlite3Fts3Matchinfo(sqlite3_context *, Fts3Cursor *, const char *);
114485 /* fts3_expr.c */
114486 SQLITE_PRIVATE int sqlite3Fts3ExprParse(sqlite3_tokenizer *,
114487 char **, int, int, const char *, int, Fts3Expr **
114489 SQLITE_PRIVATE void sqlite3Fts3ExprFree(Fts3Expr *);
114490 #ifdef SQLITE_TEST
114491 SQLITE_PRIVATE int sqlite3Fts3ExprInitTestInterface(sqlite3 *db);
114492 SQLITE_PRIVATE int sqlite3Fts3InitTerm(sqlite3 *db);
114493 #endif
114495 /* fts3_aux.c */
114496 SQLITE_PRIVATE int sqlite3Fts3InitAux(sqlite3 *db);
114498 SQLITE_PRIVATE void sqlite3Fts3EvalPhraseCleanup(Fts3Phrase *);
114500 SQLITE_PRIVATE int sqlite3Fts3MsrIncrStart(
114501 Fts3Table*, Fts3MultiSegReader*, int, const char*, int);
114502 SQLITE_PRIVATE int sqlite3Fts3MsrIncrNext(
114503 Fts3Table *, Fts3MultiSegReader *, sqlite3_int64 *, char **, int *);
114504 SQLITE_PRIVATE char *sqlite3Fts3EvalPhrasePoslist(Fts3Cursor *, Fts3Expr *, int iCol);
114505 SQLITE_PRIVATE int sqlite3Fts3MsrOvfl(Fts3Cursor *, Fts3MultiSegReader *, int *);
114506 SQLITE_PRIVATE int sqlite3Fts3MsrIncrRestart(Fts3MultiSegReader *pCsr);
114508 SQLITE_PRIVATE int sqlite3Fts3DeferredTokenList(Fts3DeferredToken *, char **, int *);
114510 #endif /* !SQLITE_CORE || SQLITE_ENABLE_FTS3 */
114511 #endif /* _FTSINT_H */
114513 /************** End of fts3Int.h *********************************************/
114514 /************** Continuing where we left off in fts3.c ***********************/
114515 #if !defined(SQLITE_CORE) || defined(SQLITE_ENABLE_FTS3)
114517 #if defined(SQLITE_ENABLE_FTS3) && !defined(SQLITE_CORE)
114518 # define SQLITE_CORE 1
114519 #endif
114521 /* #include <assert.h> */
114522 /* #include <stdlib.h> */
114523 /* #include <stddef.h> */
114524 /* #include <stdio.h> */
114525 /* #include <string.h> */
114526 /* #include <stdarg.h> */
114528 #ifndef SQLITE_CORE
114529 SQLITE_EXTENSION_INIT1
114530 #endif
114532 static int fts3EvalNext(Fts3Cursor *pCsr);
114533 static int fts3EvalStart(Fts3Cursor *pCsr);
114534 static int fts3TermSegReaderCursor(
114535 Fts3Cursor *, const char *, int, int, Fts3MultiSegReader **);
114538 ** Write a 64-bit variable-length integer to memory starting at p[0].
114539 ** The length of data written will be between 1 and FTS3_VARINT_MAX bytes.
114540 ** The number of bytes written is returned.
114542 SQLITE_PRIVATE int sqlite3Fts3PutVarint(char *p, sqlite_int64 v){
114543 unsigned char *q = (unsigned char *) p;
114544 sqlite_uint64 vu = v;
114546 *q++ = (unsigned char) ((vu & 0x7f) | 0x80);
114547 vu >>= 7;
114548 }while( vu!=0 );
114549 q[-1] &= 0x7f; /* turn off high bit in final byte */
114550 assert( q - (unsigned char *)p <= FTS3_VARINT_MAX );
114551 return (int) (q - (unsigned char *)p);
114555 ** Read a 64-bit variable-length integer from memory starting at p[0].
114556 ** Return the number of bytes read, or 0 on error.
114557 ** The value is stored in *v.
114559 SQLITE_PRIVATE int sqlite3Fts3GetVarint(const char *p, sqlite_int64 *v){
114560 const unsigned char *q = (const unsigned char *) p;
114561 sqlite_uint64 x = 0, y = 1;
114562 while( (*q&0x80)==0x80 && q-(unsigned char *)p<FTS3_VARINT_MAX ){
114563 x += y * (*q++ & 0x7f);
114564 y <<= 7;
114566 x += y * (*q++);
114567 *v = (sqlite_int64) x;
114568 return (int) (q - (unsigned char *)p);
114572 ** Similar to sqlite3Fts3GetVarint(), except that the output is truncated to a
114573 ** 32-bit integer before it is returned.
114575 SQLITE_PRIVATE int sqlite3Fts3GetVarint32(const char *p, int *pi){
114576 sqlite_int64 i;
114577 int ret = sqlite3Fts3GetVarint(p, &i);
114578 *pi = (int) i;
114579 return ret;
114583 ** Return the number of bytes required to encode v as a varint
114585 SQLITE_PRIVATE int sqlite3Fts3VarintLen(sqlite3_uint64 v){
114586 int i = 0;
114589 v >>= 7;
114590 }while( v!=0 );
114591 return i;
114595 ** Convert an SQL-style quoted string into a normal string by removing
114596 ** the quote characters. The conversion is done in-place. If the
114597 ** input does not begin with a quote character, then this routine
114598 ** is a no-op.
114600 ** Examples:
114602 ** "abc" becomes abc
114603 ** 'xyz' becomes xyz
114604 ** [pqr] becomes pqr
114605 ** `mno` becomes mno
114608 SQLITE_PRIVATE void sqlite3Fts3Dequote(char *z){
114609 char quote; /* Quote character (if any ) */
114611 quote = z[0];
114612 if( quote=='[' || quote=='\'' || quote=='"' || quote=='`' ){
114613 int iIn = 1; /* Index of next byte to read from input */
114614 int iOut = 0; /* Index of next byte to write to output */
114616 /* If the first byte was a '[', then the close-quote character is a ']' */
114617 if( quote=='[' ) quote = ']';
114619 while( ALWAYS(z[iIn]) ){
114620 if( z[iIn]==quote ){
114621 if( z[iIn+1]!=quote ) break;
114622 z[iOut++] = quote;
114623 iIn += 2;
114624 }else{
114625 z[iOut++] = z[iIn++];
114628 z[iOut] = '\0';
114633 ** Read a single varint from the doclist at *pp and advance *pp to point
114634 ** to the first byte past the end of the varint. Add the value of the varint
114635 ** to *pVal.
114637 static void fts3GetDeltaVarint(char **pp, sqlite3_int64 *pVal){
114638 sqlite3_int64 iVal;
114639 *pp += sqlite3Fts3GetVarint(*pp, &iVal);
114640 *pVal += iVal;
114644 ** When this function is called, *pp points to the first byte following a
114645 ** varint that is part of a doclist (or position-list, or any other list
114646 ** of varints). This function moves *pp to point to the start of that varint,
114647 ** and sets *pVal by the varint value.
114649 ** Argument pStart points to the first byte of the doclist that the
114650 ** varint is part of.
114652 static void fts3GetReverseVarint(
114653 char **pp,
114654 char *pStart,
114655 sqlite3_int64 *pVal
114657 sqlite3_int64 iVal;
114658 char *p = *pp;
114660 /* Pointer p now points at the first byte past the varint we are
114661 ** interested in. So, unless the doclist is corrupt, the 0x80 bit is
114662 ** clear on character p[-1]. */
114663 for(p = (*pp)-2; p>=pStart && *p&0x80; p--);
114665 *pp = p;
114667 sqlite3Fts3GetVarint(p, &iVal);
114668 *pVal = iVal;
114672 ** The xDisconnect() virtual table method.
114674 static int fts3DisconnectMethod(sqlite3_vtab *pVtab){
114675 Fts3Table *p = (Fts3Table *)pVtab;
114676 int i;
114678 assert( p->nPendingData==0 );
114679 assert( p->pSegments==0 );
114681 /* Free any prepared statements held */
114682 for(i=0; i<SizeofArray(p->aStmt); i++){
114683 sqlite3_finalize(p->aStmt[i]);
114685 sqlite3_free(p->zSegmentsTbl);
114686 sqlite3_free(p->zReadExprlist);
114687 sqlite3_free(p->zWriteExprlist);
114689 /* Invoke the tokenizer destructor to free the tokenizer. */
114690 p->pTokenizer->pModule->xDestroy(p->pTokenizer);
114692 sqlite3_free(p);
114693 return SQLITE_OK;
114697 ** Construct one or more SQL statements from the format string given
114698 ** and then evaluate those statements. The success code is written
114699 ** into *pRc.
114701 ** If *pRc is initially non-zero then this routine is a no-op.
114703 static void fts3DbExec(
114704 int *pRc, /* Success code */
114705 sqlite3 *db, /* Database in which to run SQL */
114706 const char *zFormat, /* Format string for SQL */
114707 ... /* Arguments to the format string */
114709 va_list ap;
114710 char *zSql;
114711 if( *pRc ) return;
114712 va_start(ap, zFormat);
114713 zSql = sqlite3_vmprintf(zFormat, ap);
114714 va_end(ap);
114715 if( zSql==0 ){
114716 *pRc = SQLITE_NOMEM;
114717 }else{
114718 *pRc = sqlite3_exec(db, zSql, 0, 0, 0);
114719 sqlite3_free(zSql);
114724 ** The xDestroy() virtual table method.
114726 static int fts3DestroyMethod(sqlite3_vtab *pVtab){
114727 int rc = SQLITE_OK; /* Return code */
114728 Fts3Table *p = (Fts3Table *)pVtab;
114729 sqlite3 *db = p->db;
114731 /* Drop the shadow tables */
114732 fts3DbExec(&rc, db, "DROP TABLE IF EXISTS %Q.'%q_content'", p->zDb, p->zName);
114733 fts3DbExec(&rc, db, "DROP TABLE IF EXISTS %Q.'%q_segments'", p->zDb,p->zName);
114734 fts3DbExec(&rc, db, "DROP TABLE IF EXISTS %Q.'%q_segdir'", p->zDb, p->zName);
114735 fts3DbExec(&rc, db, "DROP TABLE IF EXISTS %Q.'%q_docsize'", p->zDb, p->zName);
114736 fts3DbExec(&rc, db, "DROP TABLE IF EXISTS %Q.'%q_stat'", p->zDb, p->zName);
114738 /* If everything has worked, invoke fts3DisconnectMethod() to free the
114739 ** memory associated with the Fts3Table structure and return SQLITE_OK.
114740 ** Otherwise, return an SQLite error code.
114742 return (rc==SQLITE_OK ? fts3DisconnectMethod(pVtab) : rc);
114747 ** Invoke sqlite3_declare_vtab() to declare the schema for the FTS3 table
114748 ** passed as the first argument. This is done as part of the xConnect()
114749 ** and xCreate() methods.
114751 ** If *pRc is non-zero when this function is called, it is a no-op.
114752 ** Otherwise, if an error occurs, an SQLite error code is stored in *pRc
114753 ** before returning.
114755 static void fts3DeclareVtab(int *pRc, Fts3Table *p){
114756 if( *pRc==SQLITE_OK ){
114757 int i; /* Iterator variable */
114758 int rc; /* Return code */
114759 char *zSql; /* SQL statement passed to declare_vtab() */
114760 char *zCols; /* List of user defined columns */
114762 sqlite3_vtab_config(p->db, SQLITE_VTAB_CONSTRAINT_SUPPORT, 1);
114764 /* Create a list of user columns for the virtual table */
114765 zCols = sqlite3_mprintf("%Q, ", p->azColumn[0]);
114766 for(i=1; zCols && i<p->nColumn; i++){
114767 zCols = sqlite3_mprintf("%z%Q, ", zCols, p->azColumn[i]);
114770 /* Create the whole "CREATE TABLE" statement to pass to SQLite */
114771 zSql = sqlite3_mprintf(
114772 "CREATE TABLE x(%s %Q HIDDEN, docid HIDDEN)", zCols, p->zName
114774 if( !zCols || !zSql ){
114775 rc = SQLITE_NOMEM;
114776 }else{
114777 rc = sqlite3_declare_vtab(p->db, zSql);
114780 sqlite3_free(zSql);
114781 sqlite3_free(zCols);
114782 *pRc = rc;
114787 ** Create the backing store tables (%_content, %_segments and %_segdir)
114788 ** required by the FTS3 table passed as the only argument. This is done
114789 ** as part of the vtab xCreate() method.
114791 ** If the p->bHasDocsize boolean is true (indicating that this is an
114792 ** FTS4 table, not an FTS3 table) then also create the %_docsize and
114793 ** %_stat tables required by FTS4.
114795 static int fts3CreateTables(Fts3Table *p){
114796 int rc = SQLITE_OK; /* Return code */
114797 int i; /* Iterator variable */
114798 char *zContentCols; /* Columns of %_content table */
114799 sqlite3 *db = p->db; /* The database connection */
114801 /* Create a list of user columns for the content table */
114802 zContentCols = sqlite3_mprintf("docid INTEGER PRIMARY KEY");
114803 for(i=0; zContentCols && i<p->nColumn; i++){
114804 char *z = p->azColumn[i];
114805 zContentCols = sqlite3_mprintf("%z, 'c%d%q'", zContentCols, i, z);
114807 if( zContentCols==0 ) rc = SQLITE_NOMEM;
114809 /* Create the content table */
114810 fts3DbExec(&rc, db,
114811 "CREATE TABLE %Q.'%q_content'(%s)",
114812 p->zDb, p->zName, zContentCols
114814 sqlite3_free(zContentCols);
114815 /* Create other tables */
114816 fts3DbExec(&rc, db,
114817 "CREATE TABLE %Q.'%q_segments'(blockid INTEGER PRIMARY KEY, block BLOB);",
114818 p->zDb, p->zName
114820 fts3DbExec(&rc, db,
114821 "CREATE TABLE %Q.'%q_segdir'("
114822 "level INTEGER,"
114823 "idx INTEGER,"
114824 "start_block INTEGER,"
114825 "leaves_end_block INTEGER,"
114826 "end_block INTEGER,"
114827 "root BLOB,"
114828 "PRIMARY KEY(level, idx)"
114829 ");",
114830 p->zDb, p->zName
114832 if( p->bHasDocsize ){
114833 fts3DbExec(&rc, db,
114834 "CREATE TABLE %Q.'%q_docsize'(docid INTEGER PRIMARY KEY, size BLOB);",
114835 p->zDb, p->zName
114838 if( p->bHasStat ){
114839 fts3DbExec(&rc, db,
114840 "CREATE TABLE %Q.'%q_stat'(id INTEGER PRIMARY KEY, value BLOB);",
114841 p->zDb, p->zName
114844 return rc;
114848 ** Store the current database page-size in bytes in p->nPgsz.
114850 ** If *pRc is non-zero when this function is called, it is a no-op.
114851 ** Otherwise, if an error occurs, an SQLite error code is stored in *pRc
114852 ** before returning.
114854 static void fts3DatabasePageSize(int *pRc, Fts3Table *p){
114855 if( *pRc==SQLITE_OK ){
114856 int rc; /* Return code */
114857 char *zSql; /* SQL text "PRAGMA %Q.page_size" */
114858 sqlite3_stmt *pStmt; /* Compiled "PRAGMA %Q.page_size" statement */
114860 zSql = sqlite3_mprintf("PRAGMA %Q.page_size", p->zDb);
114861 if( !zSql ){
114862 rc = SQLITE_NOMEM;
114863 }else{
114864 rc = sqlite3_prepare(p->db, zSql, -1, &pStmt, 0);
114865 if( rc==SQLITE_OK ){
114866 sqlite3_step(pStmt);
114867 p->nPgsz = sqlite3_column_int(pStmt, 0);
114868 rc = sqlite3_finalize(pStmt);
114869 }else if( rc==SQLITE_AUTH ){
114870 p->nPgsz = 1024;
114871 rc = SQLITE_OK;
114874 assert( p->nPgsz>0 || rc!=SQLITE_OK );
114875 sqlite3_free(zSql);
114876 *pRc = rc;
114881 ** "Special" FTS4 arguments are column specifications of the following form:
114883 ** <key> = <value>
114885 ** There may not be whitespace surrounding the "=" character. The <value>
114886 ** term may be quoted, but the <key> may not.
114888 static int fts3IsSpecialColumn(
114889 const char *z,
114890 int *pnKey,
114891 char **pzValue
114893 char *zValue;
114894 const char *zCsr = z;
114896 while( *zCsr!='=' ){
114897 if( *zCsr=='\0' ) return 0;
114898 zCsr++;
114901 *pnKey = (int)(zCsr-z);
114902 zValue = sqlite3_mprintf("%s", &zCsr[1]);
114903 if( zValue ){
114904 sqlite3Fts3Dequote(zValue);
114906 *pzValue = zValue;
114907 return 1;
114911 ** Append the output of a printf() style formatting to an existing string.
114913 static void fts3Appendf(
114914 int *pRc, /* IN/OUT: Error code */
114915 char **pz, /* IN/OUT: Pointer to string buffer */
114916 const char *zFormat, /* Printf format string to append */
114917 ... /* Arguments for printf format string */
114919 if( *pRc==SQLITE_OK ){
114920 va_list ap;
114921 char *z;
114922 va_start(ap, zFormat);
114923 z = sqlite3_vmprintf(zFormat, ap);
114924 if( z && *pz ){
114925 char *z2 = sqlite3_mprintf("%s%s", *pz, z);
114926 sqlite3_free(z);
114927 z = z2;
114929 if( z==0 ) *pRc = SQLITE_NOMEM;
114930 sqlite3_free(*pz);
114931 *pz = z;
114936 ** Return a copy of input string zInput enclosed in double-quotes (") and
114937 ** with all double quote characters escaped. For example:
114939 ** fts3QuoteId("un \"zip\"") -> "un \"\"zip\"\""
114941 ** The pointer returned points to memory obtained from sqlite3_malloc(). It
114942 ** is the callers responsibility to call sqlite3_free() to release this
114943 ** memory.
114945 static char *fts3QuoteId(char const *zInput){
114946 int nRet;
114947 char *zRet;
114948 nRet = 2 + strlen(zInput)*2 + 1;
114949 zRet = sqlite3_malloc(nRet);
114950 if( zRet ){
114951 int i;
114952 char *z = zRet;
114953 *(z++) = '"';
114954 for(i=0; zInput[i]; i++){
114955 if( zInput[i]=='"' ) *(z++) = '"';
114956 *(z++) = zInput[i];
114958 *(z++) = '"';
114959 *(z++) = '\0';
114961 return zRet;
114965 ** Return a list of comma separated SQL expressions that could be used
114966 ** in a SELECT statement such as the following:
114968 ** SELECT <list of expressions> FROM %_content AS x ...
114970 ** to return the docid, followed by each column of text data in order
114971 ** from left to write. If parameter zFunc is not NULL, then instead of
114972 ** being returned directly each column of text data is passed to an SQL
114973 ** function named zFunc first. For example, if zFunc is "unzip" and the
114974 ** table has the three user-defined columns "a", "b", and "c", the following
114975 ** string is returned:
114977 ** "docid, unzip(x.'a'), unzip(x.'b'), unzip(x.'c')"
114979 ** The pointer returned points to a buffer allocated by sqlite3_malloc(). It
114980 ** is the responsibility of the caller to eventually free it.
114982 ** If *pRc is not SQLITE_OK when this function is called, it is a no-op (and
114983 ** a NULL pointer is returned). Otherwise, if an OOM error is encountered
114984 ** by this function, NULL is returned and *pRc is set to SQLITE_NOMEM. If
114985 ** no error occurs, *pRc is left unmodified.
114987 static char *fts3ReadExprList(Fts3Table *p, const char *zFunc, int *pRc){
114988 char *zRet = 0;
114989 char *zFree = 0;
114990 char *zFunction;
114991 int i;
114993 if( !zFunc ){
114994 zFunction = "";
114995 }else{
114996 zFree = zFunction = fts3QuoteId(zFunc);
114998 fts3Appendf(pRc, &zRet, "docid");
114999 for(i=0; i<p->nColumn; i++){
115000 fts3Appendf(pRc, &zRet, ",%s(x.'c%d%q')", zFunction, i, p->azColumn[i]);
115002 sqlite3_free(zFree);
115003 return zRet;
115007 ** Return a list of N comma separated question marks, where N is the number
115008 ** of columns in the %_content table (one for the docid plus one for each
115009 ** user-defined text column).
115011 ** If argument zFunc is not NULL, then all but the first question mark
115012 ** is preceded by zFunc and an open bracket, and followed by a closed
115013 ** bracket. For example, if zFunc is "zip" and the FTS3 table has three
115014 ** user-defined text columns, the following string is returned:
115016 ** "?, zip(?), zip(?), zip(?)"
115018 ** The pointer returned points to a buffer allocated by sqlite3_malloc(). It
115019 ** is the responsibility of the caller to eventually free it.
115021 ** If *pRc is not SQLITE_OK when this function is called, it is a no-op (and
115022 ** a NULL pointer is returned). Otherwise, if an OOM error is encountered
115023 ** by this function, NULL is returned and *pRc is set to SQLITE_NOMEM. If
115024 ** no error occurs, *pRc is left unmodified.
115026 static char *fts3WriteExprList(Fts3Table *p, const char *zFunc, int *pRc){
115027 char *zRet = 0;
115028 char *zFree = 0;
115029 char *zFunction;
115030 int i;
115032 if( !zFunc ){
115033 zFunction = "";
115034 }else{
115035 zFree = zFunction = fts3QuoteId(zFunc);
115037 fts3Appendf(pRc, &zRet, "?");
115038 for(i=0; i<p->nColumn; i++){
115039 fts3Appendf(pRc, &zRet, ",%s(?)", zFunction);
115041 sqlite3_free(zFree);
115042 return zRet;
115046 ** This function interprets the string at (*pp) as a non-negative integer
115047 ** value. It reads the integer and sets *pnOut to the value read, then
115048 ** sets *pp to point to the byte immediately following the last byte of
115049 ** the integer value.
115051 ** Only decimal digits ('0'..'9') may be part of an integer value.
115053 ** If *pp does not being with a decimal digit SQLITE_ERROR is returned and
115054 ** the output value undefined. Otherwise SQLITE_OK is returned.
115056 ** This function is used when parsing the "prefix=" FTS4 parameter.
115058 static int fts3GobbleInt(const char **pp, int *pnOut){
115059 const char *p = *pp; /* Iterator pointer */
115060 int nInt = 0; /* Output value */
115062 for(p=*pp; p[0]>='0' && p[0]<='9'; p++){
115063 nInt = nInt * 10 + (p[0] - '0');
115065 if( p==*pp ) return SQLITE_ERROR;
115066 *pnOut = nInt;
115067 *pp = p;
115068 return SQLITE_OK;
115072 ** This function is called to allocate an array of Fts3Index structures
115073 ** representing the indexes maintained by the current FTS table. FTS tables
115074 ** always maintain the main "terms" index, but may also maintain one or
115075 ** more "prefix" indexes, depending on the value of the "prefix=" parameter
115076 ** (if any) specified as part of the CREATE VIRTUAL TABLE statement.
115078 ** Argument zParam is passed the value of the "prefix=" option if one was
115079 ** specified, or NULL otherwise.
115081 ** If no error occurs, SQLITE_OK is returned and *apIndex set to point to
115082 ** the allocated array. *pnIndex is set to the number of elements in the
115083 ** array. If an error does occur, an SQLite error code is returned.
115085 ** Regardless of whether or not an error is returned, it is the responsibility
115086 ** of the caller to call sqlite3_free() on the output array to free it.
115088 static int fts3PrefixParameter(
115089 const char *zParam, /* ABC in prefix=ABC parameter to parse */
115090 int *pnIndex, /* OUT: size of *apIndex[] array */
115091 struct Fts3Index **apIndex /* OUT: Array of indexes for this table */
115093 struct Fts3Index *aIndex; /* Allocated array */
115094 int nIndex = 1; /* Number of entries in array */
115096 if( zParam && zParam[0] ){
115097 const char *p;
115098 nIndex++;
115099 for(p=zParam; *p; p++){
115100 if( *p==',' ) nIndex++;
115104 aIndex = sqlite3_malloc(sizeof(struct Fts3Index) * nIndex);
115105 *apIndex = aIndex;
115106 *pnIndex = nIndex;
115107 if( !aIndex ){
115108 return SQLITE_NOMEM;
115111 memset(aIndex, 0, sizeof(struct Fts3Index) * nIndex);
115112 if( zParam ){
115113 const char *p = zParam;
115114 int i;
115115 for(i=1; i<nIndex; i++){
115116 int nPrefix;
115117 if( fts3GobbleInt(&p, &nPrefix) ) return SQLITE_ERROR;
115118 aIndex[i].nPrefix = nPrefix;
115123 return SQLITE_OK;
115127 ** This function is the implementation of both the xConnect and xCreate
115128 ** methods of the FTS3 virtual table.
115130 ** The argv[] array contains the following:
115132 ** argv[0] -> module name ("fts3" or "fts4")
115133 ** argv[1] -> database name
115134 ** argv[2] -> table name
115135 ** argv[...] -> "column name" and other module argument fields.
115137 static int fts3InitVtab(
115138 int isCreate, /* True for xCreate, false for xConnect */
115139 sqlite3 *db, /* The SQLite database connection */
115140 void *pAux, /* Hash table containing tokenizers */
115141 int argc, /* Number of elements in argv array */
115142 const char * const *argv, /* xCreate/xConnect argument array */
115143 sqlite3_vtab **ppVTab, /* Write the resulting vtab structure here */
115144 char **pzErr /* Write any error message here */
115146 Fts3Hash *pHash = (Fts3Hash *)pAux;
115147 Fts3Table *p = 0; /* Pointer to allocated vtab */
115148 int rc = SQLITE_OK; /* Return code */
115149 int i; /* Iterator variable */
115150 int nByte; /* Size of allocation used for *p */
115151 int iCol; /* Column index */
115152 int nString = 0; /* Bytes required to hold all column names */
115153 int nCol = 0; /* Number of columns in the FTS table */
115154 char *zCsr; /* Space for holding column names */
115155 int nDb; /* Bytes required to hold database name */
115156 int nName; /* Bytes required to hold table name */
115157 int isFts4 = (argv[0][3]=='4'); /* True for FTS4, false for FTS3 */
115158 const char **aCol; /* Array of column names */
115159 sqlite3_tokenizer *pTokenizer = 0; /* Tokenizer for this table */
115161 int nIndex; /* Size of aIndex[] array */
115162 struct Fts3Index *aIndex = 0; /* Array of indexes for this table */
115164 /* The results of parsing supported FTS4 key=value options: */
115165 int bNoDocsize = 0; /* True to omit %_docsize table */
115166 int bDescIdx = 0; /* True to store descending indexes */
115167 char *zPrefix = 0; /* Prefix parameter value (or NULL) */
115168 char *zCompress = 0; /* compress=? parameter (or NULL) */
115169 char *zUncompress = 0; /* uncompress=? parameter (or NULL) */
115171 assert( strlen(argv[0])==4 );
115172 assert( (sqlite3_strnicmp(argv[0], "fts4", 4)==0 && isFts4)
115173 || (sqlite3_strnicmp(argv[0], "fts3", 4)==0 && !isFts4)
115176 nDb = (int)strlen(argv[1]) + 1;
115177 nName = (int)strlen(argv[2]) + 1;
115179 aCol = (const char **)sqlite3_malloc(sizeof(const char *) * (argc-2) );
115180 if( !aCol ) return SQLITE_NOMEM;
115181 memset((void *)aCol, 0, sizeof(const char *) * (argc-2));
115183 /* Loop through all of the arguments passed by the user to the FTS3/4
115184 ** module (i.e. all the column names and special arguments). This loop
115185 ** does the following:
115187 ** + Figures out the number of columns the FTSX table will have, and
115188 ** the number of bytes of space that must be allocated to store copies
115189 ** of the column names.
115191 ** + If there is a tokenizer specification included in the arguments,
115192 ** initializes the tokenizer pTokenizer.
115194 for(i=3; rc==SQLITE_OK && i<argc; i++){
115195 char const *z = argv[i];
115196 int nKey;
115197 char *zVal;
115199 /* Check if this is a tokenizer specification */
115200 if( !pTokenizer
115201 && strlen(z)>8
115202 && 0==sqlite3_strnicmp(z, "tokenize", 8)
115203 && 0==sqlite3Fts3IsIdChar(z[8])
115205 rc = sqlite3Fts3InitTokenizer(pHash, &z[9], &pTokenizer, pzErr);
115208 /* Check if it is an FTS4 special argument. */
115209 else if( isFts4 && fts3IsSpecialColumn(z, &nKey, &zVal) ){
115210 struct Fts4Option {
115211 const char *zOpt;
115212 int nOpt;
115213 char **pzVar;
115214 } aFts4Opt[] = {
115215 { "matchinfo", 9, 0 }, /* 0 -> MATCHINFO */
115216 { "prefix", 6, 0 }, /* 1 -> PREFIX */
115217 { "compress", 8, 0 }, /* 2 -> COMPRESS */
115218 { "uncompress", 10, 0 }, /* 3 -> UNCOMPRESS */
115219 { "order", 5, 0 } /* 4 -> ORDER */
115222 int iOpt;
115223 if( !zVal ){
115224 rc = SQLITE_NOMEM;
115225 }else{
115226 for(iOpt=0; iOpt<SizeofArray(aFts4Opt); iOpt++){
115227 struct Fts4Option *pOp = &aFts4Opt[iOpt];
115228 if( nKey==pOp->nOpt && !sqlite3_strnicmp(z, pOp->zOpt, pOp->nOpt) ){
115229 break;
115232 if( iOpt==SizeofArray(aFts4Opt) ){
115233 *pzErr = sqlite3_mprintf("unrecognized parameter: %s", z);
115234 rc = SQLITE_ERROR;
115235 }else{
115236 switch( iOpt ){
115237 case 0: /* MATCHINFO */
115238 if( strlen(zVal)!=4 || sqlite3_strnicmp(zVal, "fts3", 4) ){
115239 *pzErr = sqlite3_mprintf("unrecognized matchinfo: %s", zVal);
115240 rc = SQLITE_ERROR;
115242 bNoDocsize = 1;
115243 break;
115245 case 1: /* PREFIX */
115246 sqlite3_free(zPrefix);
115247 zPrefix = zVal;
115248 zVal = 0;
115249 break;
115251 case 2: /* COMPRESS */
115252 sqlite3_free(zCompress);
115253 zCompress = zVal;
115254 zVal = 0;
115255 break;
115257 case 3: /* UNCOMPRESS */
115258 sqlite3_free(zUncompress);
115259 zUncompress = zVal;
115260 zVal = 0;
115261 break;
115263 case 4: /* ORDER */
115264 if( (strlen(zVal)!=3 || sqlite3_strnicmp(zVal, "asc", 3))
115265 && (strlen(zVal)!=4 || sqlite3_strnicmp(zVal, "desc", 3))
115267 *pzErr = sqlite3_mprintf("unrecognized order: %s", zVal);
115268 rc = SQLITE_ERROR;
115270 bDescIdx = (zVal[0]=='d' || zVal[0]=='D');
115271 break;
115274 sqlite3_free(zVal);
115278 /* Otherwise, the argument is a column name. */
115279 else {
115280 nString += (int)(strlen(z) + 1);
115281 aCol[nCol++] = z;
115284 if( rc!=SQLITE_OK ) goto fts3_init_out;
115286 if( nCol==0 ){
115287 assert( nString==0 );
115288 aCol[0] = "content";
115289 nString = 8;
115290 nCol = 1;
115293 if( pTokenizer==0 ){
115294 rc = sqlite3Fts3InitTokenizer(pHash, "simple", &pTokenizer, pzErr);
115295 if( rc!=SQLITE_OK ) goto fts3_init_out;
115297 assert( pTokenizer );
115299 rc = fts3PrefixParameter(zPrefix, &nIndex, &aIndex);
115300 if( rc==SQLITE_ERROR ){
115301 assert( zPrefix );
115302 *pzErr = sqlite3_mprintf("error parsing prefix parameter: %s", zPrefix);
115304 if( rc!=SQLITE_OK ) goto fts3_init_out;
115306 /* Allocate and populate the Fts3Table structure. */
115307 nByte = sizeof(Fts3Table) + /* Fts3Table */
115308 nCol * sizeof(char *) + /* azColumn */
115309 nIndex * sizeof(struct Fts3Index) + /* aIndex */
115310 nName + /* zName */
115311 nDb + /* zDb */
115312 nString; /* Space for azColumn strings */
115313 p = (Fts3Table*)sqlite3_malloc(nByte);
115314 if( p==0 ){
115315 rc = SQLITE_NOMEM;
115316 goto fts3_init_out;
115318 memset(p, 0, nByte);
115319 p->db = db;
115320 p->nColumn = nCol;
115321 p->nPendingData = 0;
115322 p->azColumn = (char **)&p[1];
115323 p->pTokenizer = pTokenizer;
115324 p->nMaxPendingData = FTS3_MAX_PENDING_DATA;
115325 p->bHasDocsize = (isFts4 && bNoDocsize==0);
115326 p->bHasStat = isFts4;
115327 p->bDescIdx = bDescIdx;
115328 TESTONLY( p->inTransaction = -1 );
115329 TESTONLY( p->mxSavepoint = -1 );
115331 p->aIndex = (struct Fts3Index *)&p->azColumn[nCol];
115332 memcpy(p->aIndex, aIndex, sizeof(struct Fts3Index) * nIndex);
115333 p->nIndex = nIndex;
115334 for(i=0; i<nIndex; i++){
115335 fts3HashInit(&p->aIndex[i].hPending, FTS3_HASH_STRING, 1);
115338 /* Fill in the zName and zDb fields of the vtab structure. */
115339 zCsr = (char *)&p->aIndex[nIndex];
115340 p->zName = zCsr;
115341 memcpy(zCsr, argv[2], nName);
115342 zCsr += nName;
115343 p->zDb = zCsr;
115344 memcpy(zCsr, argv[1], nDb);
115345 zCsr += nDb;
115347 /* Fill in the azColumn array */
115348 for(iCol=0; iCol<nCol; iCol++){
115349 char *z;
115350 int n = 0;
115351 z = (char *)sqlite3Fts3NextToken(aCol[iCol], &n);
115352 memcpy(zCsr, z, n);
115353 zCsr[n] = '\0';
115354 sqlite3Fts3Dequote(zCsr);
115355 p->azColumn[iCol] = zCsr;
115356 zCsr += n+1;
115357 assert( zCsr <= &((char *)p)[nByte] );
115360 if( (zCompress==0)!=(zUncompress==0) ){
115361 char const *zMiss = (zCompress==0 ? "compress" : "uncompress");
115362 rc = SQLITE_ERROR;
115363 *pzErr = sqlite3_mprintf("missing %s parameter in fts4 constructor", zMiss);
115365 p->zReadExprlist = fts3ReadExprList(p, zUncompress, &rc);
115366 p->zWriteExprlist = fts3WriteExprList(p, zCompress, &rc);
115367 if( rc!=SQLITE_OK ) goto fts3_init_out;
115369 /* If this is an xCreate call, create the underlying tables in the
115370 ** database. TODO: For xConnect(), it could verify that said tables exist.
115372 if( isCreate ){
115373 rc = fts3CreateTables(p);
115376 /* Figure out the page-size for the database. This is required in order to
115377 ** estimate the cost of loading large doclists from the database. */
115378 fts3DatabasePageSize(&rc, p);
115379 p->nNodeSize = p->nPgsz-35;
115381 /* Declare the table schema to SQLite. */
115382 fts3DeclareVtab(&rc, p);
115384 fts3_init_out:
115385 sqlite3_free(zPrefix);
115386 sqlite3_free(aIndex);
115387 sqlite3_free(zCompress);
115388 sqlite3_free(zUncompress);
115389 sqlite3_free((void *)aCol);
115390 if( rc!=SQLITE_OK ){
115391 if( p ){
115392 fts3DisconnectMethod((sqlite3_vtab *)p);
115393 }else if( pTokenizer ){
115394 pTokenizer->pModule->xDestroy(pTokenizer);
115396 }else{
115397 assert( p->pSegments==0 );
115398 *ppVTab = &p->base;
115400 return rc;
115404 ** The xConnect() and xCreate() methods for the virtual table. All the
115405 ** work is done in function fts3InitVtab().
115407 static int fts3ConnectMethod(
115408 sqlite3 *db, /* Database connection */
115409 void *pAux, /* Pointer to tokenizer hash table */
115410 int argc, /* Number of elements in argv array */
115411 const char * const *argv, /* xCreate/xConnect argument array */
115412 sqlite3_vtab **ppVtab, /* OUT: New sqlite3_vtab object */
115413 char **pzErr /* OUT: sqlite3_malloc'd error message */
115415 return fts3InitVtab(0, db, pAux, argc, argv, ppVtab, pzErr);
115417 static int fts3CreateMethod(
115418 sqlite3 *db, /* Database connection */
115419 void *pAux, /* Pointer to tokenizer hash table */
115420 int argc, /* Number of elements in argv array */
115421 const char * const *argv, /* xCreate/xConnect argument array */
115422 sqlite3_vtab **ppVtab, /* OUT: New sqlite3_vtab object */
115423 char **pzErr /* OUT: sqlite3_malloc'd error message */
115425 return fts3InitVtab(1, db, pAux, argc, argv, ppVtab, pzErr);
115429 ** Implementation of the xBestIndex method for FTS3 tables. There
115430 ** are three possible strategies, in order of preference:
115432 ** 1. Direct lookup by rowid or docid.
115433 ** 2. Full-text search using a MATCH operator on a non-docid column.
115434 ** 3. Linear scan of %_content table.
115436 static int fts3BestIndexMethod(sqlite3_vtab *pVTab, sqlite3_index_info *pInfo){
115437 Fts3Table *p = (Fts3Table *)pVTab;
115438 int i; /* Iterator variable */
115439 int iCons = -1; /* Index of constraint to use */
115441 /* By default use a full table scan. This is an expensive option,
115442 ** so search through the constraints to see if a more efficient
115443 ** strategy is possible.
115445 pInfo->idxNum = FTS3_FULLSCAN_SEARCH;
115446 pInfo->estimatedCost = 500000;
115447 for(i=0; i<pInfo->nConstraint; i++){
115448 struct sqlite3_index_constraint *pCons = &pInfo->aConstraint[i];
115449 if( pCons->usable==0 ) continue;
115451 /* A direct lookup on the rowid or docid column. Assign a cost of 1.0. */
115452 if( pCons->op==SQLITE_INDEX_CONSTRAINT_EQ
115453 && (pCons->iColumn<0 || pCons->iColumn==p->nColumn+1 )
115455 pInfo->idxNum = FTS3_DOCID_SEARCH;
115456 pInfo->estimatedCost = 1.0;
115457 iCons = i;
115460 /* A MATCH constraint. Use a full-text search.
115462 ** If there is more than one MATCH constraint available, use the first
115463 ** one encountered. If there is both a MATCH constraint and a direct
115464 ** rowid/docid lookup, prefer the MATCH strategy. This is done even
115465 ** though the rowid/docid lookup is faster than a MATCH query, selecting
115466 ** it would lead to an "unable to use function MATCH in the requested
115467 ** context" error.
115469 if( pCons->op==SQLITE_INDEX_CONSTRAINT_MATCH
115470 && pCons->iColumn>=0 && pCons->iColumn<=p->nColumn
115472 pInfo->idxNum = FTS3_FULLTEXT_SEARCH + pCons->iColumn;
115473 pInfo->estimatedCost = 2.0;
115474 iCons = i;
115475 break;
115479 if( iCons>=0 ){
115480 pInfo->aConstraintUsage[iCons].argvIndex = 1;
115481 pInfo->aConstraintUsage[iCons].omit = 1;
115484 /* Regardless of the strategy selected, FTS can deliver rows in rowid (or
115485 ** docid) order. Both ascending and descending are possible.
115487 if( pInfo->nOrderBy==1 ){
115488 struct sqlite3_index_orderby *pOrder = &pInfo->aOrderBy[0];
115489 if( pOrder->iColumn<0 || pOrder->iColumn==p->nColumn+1 ){
115490 if( pOrder->desc ){
115491 pInfo->idxStr = "DESC";
115492 }else{
115493 pInfo->idxStr = "ASC";
115495 pInfo->orderByConsumed = 1;
115499 assert( p->pSegments==0 );
115500 return SQLITE_OK;
115504 ** Implementation of xOpen method.
115506 static int fts3OpenMethod(sqlite3_vtab *pVTab, sqlite3_vtab_cursor **ppCsr){
115507 sqlite3_vtab_cursor *pCsr; /* Allocated cursor */
115509 UNUSED_PARAMETER(pVTab);
115511 /* Allocate a buffer large enough for an Fts3Cursor structure. If the
115512 ** allocation succeeds, zero it and return SQLITE_OK. Otherwise,
115513 ** if the allocation fails, return SQLITE_NOMEM.
115515 *ppCsr = pCsr = (sqlite3_vtab_cursor *)sqlite3_malloc(sizeof(Fts3Cursor));
115516 if( !pCsr ){
115517 return SQLITE_NOMEM;
115519 memset(pCsr, 0, sizeof(Fts3Cursor));
115520 return SQLITE_OK;
115524 ** Close the cursor. For additional information see the documentation
115525 ** on the xClose method of the virtual table interface.
115527 static int fts3CloseMethod(sqlite3_vtab_cursor *pCursor){
115528 Fts3Cursor *pCsr = (Fts3Cursor *)pCursor;
115529 assert( ((Fts3Table *)pCsr->base.pVtab)->pSegments==0 );
115530 sqlite3_finalize(pCsr->pStmt);
115531 sqlite3Fts3ExprFree(pCsr->pExpr);
115532 sqlite3Fts3FreeDeferredTokens(pCsr);
115533 sqlite3_free(pCsr->aDoclist);
115534 sqlite3_free(pCsr->aMatchinfo);
115535 assert( ((Fts3Table *)pCsr->base.pVtab)->pSegments==0 );
115536 sqlite3_free(pCsr);
115537 return SQLITE_OK;
115541 ** Position the pCsr->pStmt statement so that it is on the row
115542 ** of the %_content table that contains the last match. Return
115543 ** SQLITE_OK on success.
115545 static int fts3CursorSeek(sqlite3_context *pContext, Fts3Cursor *pCsr){
115546 if( pCsr->isRequireSeek ){
115547 sqlite3_bind_int64(pCsr->pStmt, 1, pCsr->iPrevId);
115548 pCsr->isRequireSeek = 0;
115549 if( SQLITE_ROW==sqlite3_step(pCsr->pStmt) ){
115550 return SQLITE_OK;
115551 }else{
115552 int rc = sqlite3_reset(pCsr->pStmt);
115553 if( rc==SQLITE_OK ){
115554 /* If no row was found and no error has occured, then the %_content
115555 ** table is missing a row that is present in the full-text index.
115556 ** The data structures are corrupt.
115558 rc = SQLITE_CORRUPT_VTAB;
115560 pCsr->isEof = 1;
115561 if( pContext ){
115562 sqlite3_result_error_code(pContext, rc);
115564 return rc;
115566 }else{
115567 return SQLITE_OK;
115572 ** This function is used to process a single interior node when searching
115573 ** a b-tree for a term or term prefix. The node data is passed to this
115574 ** function via the zNode/nNode parameters. The term to search for is
115575 ** passed in zTerm/nTerm.
115577 ** If piFirst is not NULL, then this function sets *piFirst to the blockid
115578 ** of the child node that heads the sub-tree that may contain the term.
115580 ** If piLast is not NULL, then *piLast is set to the right-most child node
115581 ** that heads a sub-tree that may contain a term for which zTerm/nTerm is
115582 ** a prefix.
115584 ** If an OOM error occurs, SQLITE_NOMEM is returned. Otherwise, SQLITE_OK.
115586 static int fts3ScanInteriorNode(
115587 const char *zTerm, /* Term to select leaves for */
115588 int nTerm, /* Size of term zTerm in bytes */
115589 const char *zNode, /* Buffer containing segment interior node */
115590 int nNode, /* Size of buffer at zNode */
115591 sqlite3_int64 *piFirst, /* OUT: Selected child node */
115592 sqlite3_int64 *piLast /* OUT: Selected child node */
115594 int rc = SQLITE_OK; /* Return code */
115595 const char *zCsr = zNode; /* Cursor to iterate through node */
115596 const char *zEnd = &zCsr[nNode];/* End of interior node buffer */
115597 char *zBuffer = 0; /* Buffer to load terms into */
115598 int nAlloc = 0; /* Size of allocated buffer */
115599 int isFirstTerm = 1; /* True when processing first term on page */
115600 sqlite3_int64 iChild; /* Block id of child node to descend to */
115602 /* Skip over the 'height' varint that occurs at the start of every
115603 ** interior node. Then load the blockid of the left-child of the b-tree
115604 ** node into variable iChild.
115606 ** Even if the data structure on disk is corrupted, this (reading two
115607 ** varints from the buffer) does not risk an overread. If zNode is a
115608 ** root node, then the buffer comes from a SELECT statement. SQLite does
115609 ** not make this guarantee explicitly, but in practice there are always
115610 ** either more than 20 bytes of allocated space following the nNode bytes of
115611 ** contents, or two zero bytes. Or, if the node is read from the %_segments
115612 ** table, then there are always 20 bytes of zeroed padding following the
115613 ** nNode bytes of content (see sqlite3Fts3ReadBlock() for details).
115615 zCsr += sqlite3Fts3GetVarint(zCsr, &iChild);
115616 zCsr += sqlite3Fts3GetVarint(zCsr, &iChild);
115617 if( zCsr>zEnd ){
115618 return SQLITE_CORRUPT_VTAB;
115621 while( zCsr<zEnd && (piFirst || piLast) ){
115622 int cmp; /* memcmp() result */
115623 int nSuffix; /* Size of term suffix */
115624 int nPrefix = 0; /* Size of term prefix */
115625 int nBuffer; /* Total term size */
115627 /* Load the next term on the node into zBuffer. Use realloc() to expand
115628 ** the size of zBuffer if required. */
115629 if( !isFirstTerm ){
115630 zCsr += sqlite3Fts3GetVarint32(zCsr, &nPrefix);
115632 isFirstTerm = 0;
115633 zCsr += sqlite3Fts3GetVarint32(zCsr, &nSuffix);
115635 if( nPrefix<0 || nSuffix<0 || &zCsr[nSuffix]>zEnd ){
115636 rc = SQLITE_CORRUPT_VTAB;
115637 goto finish_scan;
115639 if( nPrefix+nSuffix>nAlloc ){
115640 char *zNew;
115641 nAlloc = (nPrefix+nSuffix) * 2;
115642 zNew = (char *)sqlite3_realloc(zBuffer, nAlloc);
115643 if( !zNew ){
115644 rc = SQLITE_NOMEM;
115645 goto finish_scan;
115647 zBuffer = zNew;
115649 memcpy(&zBuffer[nPrefix], zCsr, nSuffix);
115650 nBuffer = nPrefix + nSuffix;
115651 zCsr += nSuffix;
115653 /* Compare the term we are searching for with the term just loaded from
115654 ** the interior node. If the specified term is greater than or equal
115655 ** to the term from the interior node, then all terms on the sub-tree
115656 ** headed by node iChild are smaller than zTerm. No need to search
115657 ** iChild.
115659 ** If the interior node term is larger than the specified term, then
115660 ** the tree headed by iChild may contain the specified term.
115662 cmp = memcmp(zTerm, zBuffer, (nBuffer>nTerm ? nTerm : nBuffer));
115663 if( piFirst && (cmp<0 || (cmp==0 && nBuffer>nTerm)) ){
115664 *piFirst = iChild;
115665 piFirst = 0;
115668 if( piLast && cmp<0 ){
115669 *piLast = iChild;
115670 piLast = 0;
115673 iChild++;
115676 if( piFirst ) *piFirst = iChild;
115677 if( piLast ) *piLast = iChild;
115679 finish_scan:
115680 sqlite3_free(zBuffer);
115681 return rc;
115686 ** The buffer pointed to by argument zNode (size nNode bytes) contains an
115687 ** interior node of a b-tree segment. The zTerm buffer (size nTerm bytes)
115688 ** contains a term. This function searches the sub-tree headed by the zNode
115689 ** node for the range of leaf nodes that may contain the specified term
115690 ** or terms for which the specified term is a prefix.
115692 ** If piLeaf is not NULL, then *piLeaf is set to the blockid of the
115693 ** left-most leaf node in the tree that may contain the specified term.
115694 ** If piLeaf2 is not NULL, then *piLeaf2 is set to the blockid of the
115695 ** right-most leaf node that may contain a term for which the specified
115696 ** term is a prefix.
115698 ** It is possible that the range of returned leaf nodes does not contain
115699 ** the specified term or any terms for which it is a prefix. However, if the
115700 ** segment does contain any such terms, they are stored within the identified
115701 ** range. Because this function only inspects interior segment nodes (and
115702 ** never loads leaf nodes into memory), it is not possible to be sure.
115704 ** If an error occurs, an error code other than SQLITE_OK is returned.
115706 static int fts3SelectLeaf(
115707 Fts3Table *p, /* Virtual table handle */
115708 const char *zTerm, /* Term to select leaves for */
115709 int nTerm, /* Size of term zTerm in bytes */
115710 const char *zNode, /* Buffer containing segment interior node */
115711 int nNode, /* Size of buffer at zNode */
115712 sqlite3_int64 *piLeaf, /* Selected leaf node */
115713 sqlite3_int64 *piLeaf2 /* Selected leaf node */
115715 int rc; /* Return code */
115716 int iHeight; /* Height of this node in tree */
115718 assert( piLeaf || piLeaf2 );
115720 sqlite3Fts3GetVarint32(zNode, &iHeight);
115721 rc = fts3ScanInteriorNode(zTerm, nTerm, zNode, nNode, piLeaf, piLeaf2);
115722 assert( !piLeaf2 || !piLeaf || rc!=SQLITE_OK || (*piLeaf<=*piLeaf2) );
115724 if( rc==SQLITE_OK && iHeight>1 ){
115725 char *zBlob = 0; /* Blob read from %_segments table */
115726 int nBlob; /* Size of zBlob in bytes */
115728 if( piLeaf && piLeaf2 && (*piLeaf!=*piLeaf2) ){
115729 rc = sqlite3Fts3ReadBlock(p, *piLeaf, &zBlob, &nBlob, 0);
115730 if( rc==SQLITE_OK ){
115731 rc = fts3SelectLeaf(p, zTerm, nTerm, zBlob, nBlob, piLeaf, 0);
115733 sqlite3_free(zBlob);
115734 piLeaf = 0;
115735 zBlob = 0;
115738 if( rc==SQLITE_OK ){
115739 rc = sqlite3Fts3ReadBlock(p, piLeaf?*piLeaf:*piLeaf2, &zBlob, &nBlob, 0);
115741 if( rc==SQLITE_OK ){
115742 rc = fts3SelectLeaf(p, zTerm, nTerm, zBlob, nBlob, piLeaf, piLeaf2);
115744 sqlite3_free(zBlob);
115747 return rc;
115751 ** This function is used to create delta-encoded serialized lists of FTS3
115752 ** varints. Each call to this function appends a single varint to a list.
115754 static void fts3PutDeltaVarint(
115755 char **pp, /* IN/OUT: Output pointer */
115756 sqlite3_int64 *piPrev, /* IN/OUT: Previous value written to list */
115757 sqlite3_int64 iVal /* Write this value to the list */
115759 assert( iVal-*piPrev > 0 || (*piPrev==0 && iVal==0) );
115760 *pp += sqlite3Fts3PutVarint(*pp, iVal-*piPrev);
115761 *piPrev = iVal;
115765 ** When this function is called, *ppPoslist is assumed to point to the
115766 ** start of a position-list. After it returns, *ppPoslist points to the
115767 ** first byte after the position-list.
115769 ** A position list is list of positions (delta encoded) and columns for
115770 ** a single document record of a doclist. So, in other words, this
115771 ** routine advances *ppPoslist so that it points to the next docid in
115772 ** the doclist, or to the first byte past the end of the doclist.
115774 ** If pp is not NULL, then the contents of the position list are copied
115775 ** to *pp. *pp is set to point to the first byte past the last byte copied
115776 ** before this function returns.
115778 static void fts3PoslistCopy(char **pp, char **ppPoslist){
115779 char *pEnd = *ppPoslist;
115780 char c = 0;
115782 /* The end of a position list is marked by a zero encoded as an FTS3
115783 ** varint. A single POS_END (0) byte. Except, if the 0 byte is preceded by
115784 ** a byte with the 0x80 bit set, then it is not a varint 0, but the tail
115785 ** of some other, multi-byte, value.
115787 ** The following while-loop moves pEnd to point to the first byte that is not
115788 ** immediately preceded by a byte with the 0x80 bit set. Then increments
115789 ** pEnd once more so that it points to the byte immediately following the
115790 ** last byte in the position-list.
115792 while( *pEnd | c ){
115793 c = *pEnd++ & 0x80;
115794 testcase( c!=0 && (*pEnd)==0 );
115796 pEnd++; /* Advance past the POS_END terminator byte */
115798 if( pp ){
115799 int n = (int)(pEnd - *ppPoslist);
115800 char *p = *pp;
115801 memcpy(p, *ppPoslist, n);
115802 p += n;
115803 *pp = p;
115805 *ppPoslist = pEnd;
115809 ** When this function is called, *ppPoslist is assumed to point to the
115810 ** start of a column-list. After it returns, *ppPoslist points to the
115811 ** to the terminator (POS_COLUMN or POS_END) byte of the column-list.
115813 ** A column-list is list of delta-encoded positions for a single column
115814 ** within a single document within a doclist.
115816 ** The column-list is terminated either by a POS_COLUMN varint (1) or
115817 ** a POS_END varint (0). This routine leaves *ppPoslist pointing to
115818 ** the POS_COLUMN or POS_END that terminates the column-list.
115820 ** If pp is not NULL, then the contents of the column-list are copied
115821 ** to *pp. *pp is set to point to the first byte past the last byte copied
115822 ** before this function returns. The POS_COLUMN or POS_END terminator
115823 ** is not copied into *pp.
115825 static void fts3ColumnlistCopy(char **pp, char **ppPoslist){
115826 char *pEnd = *ppPoslist;
115827 char c = 0;
115829 /* A column-list is terminated by either a 0x01 or 0x00 byte that is
115830 ** not part of a multi-byte varint.
115832 while( 0xFE & (*pEnd | c) ){
115833 c = *pEnd++ & 0x80;
115834 testcase( c!=0 && ((*pEnd)&0xfe)==0 );
115836 if( pp ){
115837 int n = (int)(pEnd - *ppPoslist);
115838 char *p = *pp;
115839 memcpy(p, *ppPoslist, n);
115840 p += n;
115841 *pp = p;
115843 *ppPoslist = pEnd;
115847 ** Value used to signify the end of an position-list. This is safe because
115848 ** it is not possible to have a document with 2^31 terms.
115850 #define POSITION_LIST_END 0x7fffffff
115853 ** This function is used to help parse position-lists. When this function is
115854 ** called, *pp may point to the start of the next varint in the position-list
115855 ** being parsed, or it may point to 1 byte past the end of the position-list
115856 ** (in which case **pp will be a terminator bytes POS_END (0) or
115857 ** (1)).
115859 ** If *pp points past the end of the current position-list, set *pi to
115860 ** POSITION_LIST_END and return. Otherwise, read the next varint from *pp,
115861 ** increment the current value of *pi by the value read, and set *pp to
115862 ** point to the next value before returning.
115864 ** Before calling this routine *pi must be initialized to the value of
115865 ** the previous position, or zero if we are reading the first position
115866 ** in the position-list. Because positions are delta-encoded, the value
115867 ** of the previous position is needed in order to compute the value of
115868 ** the next position.
115870 static void fts3ReadNextPos(
115871 char **pp, /* IN/OUT: Pointer into position-list buffer */
115872 sqlite3_int64 *pi /* IN/OUT: Value read from position-list */
115874 if( (**pp)&0xFE ){
115875 fts3GetDeltaVarint(pp, pi);
115876 *pi -= 2;
115877 }else{
115878 *pi = POSITION_LIST_END;
115883 ** If parameter iCol is not 0, write an POS_COLUMN (1) byte followed by
115884 ** the value of iCol encoded as a varint to *pp. This will start a new
115885 ** column list.
115887 ** Set *pp to point to the byte just after the last byte written before
115888 ** returning (do not modify it if iCol==0). Return the total number of bytes
115889 ** written (0 if iCol==0).
115891 static int fts3PutColNumber(char **pp, int iCol){
115892 int n = 0; /* Number of bytes written */
115893 if( iCol ){
115894 char *p = *pp; /* Output pointer */
115895 n = 1 + sqlite3Fts3PutVarint(&p[1], iCol);
115896 *p = 0x01;
115897 *pp = &p[n];
115899 return n;
115903 ** Compute the union of two position lists. The output written
115904 ** into *pp contains all positions of both *pp1 and *pp2 in sorted
115905 ** order and with any duplicates removed. All pointers are
115906 ** updated appropriately. The caller is responsible for insuring
115907 ** that there is enough space in *pp to hold the complete output.
115909 static void fts3PoslistMerge(
115910 char **pp, /* Output buffer */
115911 char **pp1, /* Left input list */
115912 char **pp2 /* Right input list */
115914 char *p = *pp;
115915 char *p1 = *pp1;
115916 char *p2 = *pp2;
115918 while( *p1 || *p2 ){
115919 int iCol1; /* The current column index in pp1 */
115920 int iCol2; /* The current column index in pp2 */
115922 if( *p1==POS_COLUMN ) sqlite3Fts3GetVarint32(&p1[1], &iCol1);
115923 else if( *p1==POS_END ) iCol1 = POSITION_LIST_END;
115924 else iCol1 = 0;
115926 if( *p2==POS_COLUMN ) sqlite3Fts3GetVarint32(&p2[1], &iCol2);
115927 else if( *p2==POS_END ) iCol2 = POSITION_LIST_END;
115928 else iCol2 = 0;
115930 if( iCol1==iCol2 ){
115931 sqlite3_int64 i1 = 0; /* Last position from pp1 */
115932 sqlite3_int64 i2 = 0; /* Last position from pp2 */
115933 sqlite3_int64 iPrev = 0;
115934 int n = fts3PutColNumber(&p, iCol1);
115935 p1 += n;
115936 p2 += n;
115938 /* At this point, both p1 and p2 point to the start of column-lists
115939 ** for the same column (the column with index iCol1 and iCol2).
115940 ** A column-list is a list of non-negative delta-encoded varints, each
115941 ** incremented by 2 before being stored. Each list is terminated by a
115942 ** POS_END (0) or POS_COLUMN (1). The following block merges the two lists
115943 ** and writes the results to buffer p. p is left pointing to the byte
115944 ** after the list written. No terminator (POS_END or POS_COLUMN) is
115945 ** written to the output.
115947 fts3GetDeltaVarint(&p1, &i1);
115948 fts3GetDeltaVarint(&p2, &i2);
115950 fts3PutDeltaVarint(&p, &iPrev, (i1<i2) ? i1 : i2);
115951 iPrev -= 2;
115952 if( i1==i2 ){
115953 fts3ReadNextPos(&p1, &i1);
115954 fts3ReadNextPos(&p2, &i2);
115955 }else if( i1<i2 ){
115956 fts3ReadNextPos(&p1, &i1);
115957 }else{
115958 fts3ReadNextPos(&p2, &i2);
115960 }while( i1!=POSITION_LIST_END || i2!=POSITION_LIST_END );
115961 }else if( iCol1<iCol2 ){
115962 p1 += fts3PutColNumber(&p, iCol1);
115963 fts3ColumnlistCopy(&p, &p1);
115964 }else{
115965 p2 += fts3PutColNumber(&p, iCol2);
115966 fts3ColumnlistCopy(&p, &p2);
115970 *p++ = POS_END;
115971 *pp = p;
115972 *pp1 = p1 + 1;
115973 *pp2 = p2 + 1;
115977 ** This function is used to merge two position lists into one. When it is
115978 ** called, *pp1 and *pp2 must both point to position lists. A position-list is
115979 ** the part of a doclist that follows each document id. For example, if a row
115980 ** contains:
115982 ** 'a b c'|'x y z'|'a b b a'
115984 ** Then the position list for this row for token 'b' would consist of:
115986 ** 0x02 0x01 0x02 0x03 0x03 0x00
115988 ** When this function returns, both *pp1 and *pp2 are left pointing to the
115989 ** byte following the 0x00 terminator of their respective position lists.
115991 ** If isSaveLeft is 0, an entry is added to the output position list for
115992 ** each position in *pp2 for which there exists one or more positions in
115993 ** *pp1 so that (pos(*pp2)>pos(*pp1) && pos(*pp2)-pos(*pp1)<=nToken). i.e.
115994 ** when the *pp1 token appears before the *pp2 token, but not more than nToken
115995 ** slots before it.
115997 ** e.g. nToken==1 searches for adjacent positions.
115999 static int fts3PoslistPhraseMerge(
116000 char **pp, /* IN/OUT: Preallocated output buffer */
116001 int nToken, /* Maximum difference in token positions */
116002 int isSaveLeft, /* Save the left position */
116003 int isExact, /* If *pp1 is exactly nTokens before *pp2 */
116004 char **pp1, /* IN/OUT: Left input list */
116005 char **pp2 /* IN/OUT: Right input list */
116007 char *p = (pp ? *pp : 0);
116008 char *p1 = *pp1;
116009 char *p2 = *pp2;
116010 int iCol1 = 0;
116011 int iCol2 = 0;
116013 /* Never set both isSaveLeft and isExact for the same invocation. */
116014 assert( isSaveLeft==0 || isExact==0 );
116016 assert( *p1!=0 && *p2!=0 );
116017 if( *p1==POS_COLUMN ){
116018 p1++;
116019 p1 += sqlite3Fts3GetVarint32(p1, &iCol1);
116021 if( *p2==POS_COLUMN ){
116022 p2++;
116023 p2 += sqlite3Fts3GetVarint32(p2, &iCol2);
116026 while( 1 ){
116027 if( iCol1==iCol2 ){
116028 char *pSave = p;
116029 sqlite3_int64 iPrev = 0;
116030 sqlite3_int64 iPos1 = 0;
116031 sqlite3_int64 iPos2 = 0;
116033 if( pp && iCol1 ){
116034 *p++ = POS_COLUMN;
116035 p += sqlite3Fts3PutVarint(p, iCol1);
116038 assert( *p1!=POS_END && *p1!=POS_COLUMN );
116039 assert( *p2!=POS_END && *p2!=POS_COLUMN );
116040 fts3GetDeltaVarint(&p1, &iPos1); iPos1 -= 2;
116041 fts3GetDeltaVarint(&p2, &iPos2); iPos2 -= 2;
116043 while( 1 ){
116044 if( iPos2==iPos1+nToken
116045 || (isExact==0 && iPos2>iPos1 && iPos2<=iPos1+nToken)
116047 sqlite3_int64 iSave;
116048 if( !pp ){
116049 fts3PoslistCopy(0, &p2);
116050 fts3PoslistCopy(0, &p1);
116051 *pp1 = p1;
116052 *pp2 = p2;
116053 return 1;
116055 iSave = isSaveLeft ? iPos1 : iPos2;
116056 fts3PutDeltaVarint(&p, &iPrev, iSave+2); iPrev -= 2;
116057 pSave = 0;
116059 if( (!isSaveLeft && iPos2<=(iPos1+nToken)) || iPos2<=iPos1 ){
116060 if( (*p2&0xFE)==0 ) break;
116061 fts3GetDeltaVarint(&p2, &iPos2); iPos2 -= 2;
116062 }else{
116063 if( (*p1&0xFE)==0 ) break;
116064 fts3GetDeltaVarint(&p1, &iPos1); iPos1 -= 2;
116068 if( pSave ){
116069 assert( pp && p );
116070 p = pSave;
116073 fts3ColumnlistCopy(0, &p1);
116074 fts3ColumnlistCopy(0, &p2);
116075 assert( (*p1&0xFE)==0 && (*p2&0xFE)==0 );
116076 if( 0==*p1 || 0==*p2 ) break;
116078 p1++;
116079 p1 += sqlite3Fts3GetVarint32(p1, &iCol1);
116080 p2++;
116081 p2 += sqlite3Fts3GetVarint32(p2, &iCol2);
116084 /* Advance pointer p1 or p2 (whichever corresponds to the smaller of
116085 ** iCol1 and iCol2) so that it points to either the 0x00 that marks the
116086 ** end of the position list, or the 0x01 that precedes the next
116087 ** column-number in the position list.
116089 else if( iCol1<iCol2 ){
116090 fts3ColumnlistCopy(0, &p1);
116091 if( 0==*p1 ) break;
116092 p1++;
116093 p1 += sqlite3Fts3GetVarint32(p1, &iCol1);
116094 }else{
116095 fts3ColumnlistCopy(0, &p2);
116096 if( 0==*p2 ) break;
116097 p2++;
116098 p2 += sqlite3Fts3GetVarint32(p2, &iCol2);
116102 fts3PoslistCopy(0, &p2);
116103 fts3PoslistCopy(0, &p1);
116104 *pp1 = p1;
116105 *pp2 = p2;
116106 if( !pp || *pp==p ){
116107 return 0;
116109 *p++ = 0x00;
116110 *pp = p;
116111 return 1;
116115 ** Merge two position-lists as required by the NEAR operator. The argument
116116 ** position lists correspond to the left and right phrases of an expression
116117 ** like:
116119 ** "phrase 1" NEAR "phrase number 2"
116121 ** Position list *pp1 corresponds to the left-hand side of the NEAR
116122 ** expression and *pp2 to the right. As usual, the indexes in the position
116123 ** lists are the offsets of the last token in each phrase (tokens "1" and "2"
116124 ** in the example above).
116126 ** The output position list - written to *pp - is a copy of *pp2 with those
116127 ** entries that are not sufficiently NEAR entries in *pp1 removed.
116129 static int fts3PoslistNearMerge(
116130 char **pp, /* Output buffer */
116131 char *aTmp, /* Temporary buffer space */
116132 int nRight, /* Maximum difference in token positions */
116133 int nLeft, /* Maximum difference in token positions */
116134 char **pp1, /* IN/OUT: Left input list */
116135 char **pp2 /* IN/OUT: Right input list */
116137 char *p1 = *pp1;
116138 char *p2 = *pp2;
116140 char *pTmp1 = aTmp;
116141 char *pTmp2;
116142 char *aTmp2;
116143 int res = 1;
116145 fts3PoslistPhraseMerge(&pTmp1, nRight, 0, 0, pp1, pp2);
116146 aTmp2 = pTmp2 = pTmp1;
116147 *pp1 = p1;
116148 *pp2 = p2;
116149 fts3PoslistPhraseMerge(&pTmp2, nLeft, 1, 0, pp2, pp1);
116150 if( pTmp1!=aTmp && pTmp2!=aTmp2 ){
116151 fts3PoslistMerge(pp, &aTmp, &aTmp2);
116152 }else if( pTmp1!=aTmp ){
116153 fts3PoslistCopy(pp, &aTmp);
116154 }else if( pTmp2!=aTmp2 ){
116155 fts3PoslistCopy(pp, &aTmp2);
116156 }else{
116157 res = 0;
116160 return res;
116164 ** An instance of this function is used to merge together the (potentially
116165 ** large number of) doclists for each term that matches a prefix query.
116166 ** See function fts3TermSelectMerge() for details.
116168 typedef struct TermSelect TermSelect;
116169 struct TermSelect {
116170 char *aaOutput[16]; /* Malloc'd output buffers */
116171 int anOutput[16]; /* Size each output buffer in bytes */
116175 ** This function is used to read a single varint from a buffer. Parameter
116176 ** pEnd points 1 byte past the end of the buffer. When this function is
116177 ** called, if *pp points to pEnd or greater, then the end of the buffer
116178 ** has been reached. In this case *pp is set to 0 and the function returns.
116180 ** If *pp does not point to or past pEnd, then a single varint is read
116181 ** from *pp. *pp is then set to point 1 byte past the end of the read varint.
116183 ** If bDescIdx is false, the value read is added to *pVal before returning.
116184 ** If it is true, the value read is subtracted from *pVal before this
116185 ** function returns.
116187 static void fts3GetDeltaVarint3(
116188 char **pp, /* IN/OUT: Point to read varint from */
116189 char *pEnd, /* End of buffer */
116190 int bDescIdx, /* True if docids are descending */
116191 sqlite3_int64 *pVal /* IN/OUT: Integer value */
116193 if( *pp>=pEnd ){
116194 *pp = 0;
116195 }else{
116196 sqlite3_int64 iVal;
116197 *pp += sqlite3Fts3GetVarint(*pp, &iVal);
116198 if( bDescIdx ){
116199 *pVal -= iVal;
116200 }else{
116201 *pVal += iVal;
116207 ** This function is used to write a single varint to a buffer. The varint
116208 ** is written to *pp. Before returning, *pp is set to point 1 byte past the
116209 ** end of the value written.
116211 ** If *pbFirst is zero when this function is called, the value written to
116212 ** the buffer is that of parameter iVal.
116214 ** If *pbFirst is non-zero when this function is called, then the value
116215 ** written is either (iVal-*piPrev) (if bDescIdx is zero) or (*piPrev-iVal)
116216 ** (if bDescIdx is non-zero).
116218 ** Before returning, this function always sets *pbFirst to 1 and *piPrev
116219 ** to the value of parameter iVal.
116221 static void fts3PutDeltaVarint3(
116222 char **pp, /* IN/OUT: Output pointer */
116223 int bDescIdx, /* True for descending docids */
116224 sqlite3_int64 *piPrev, /* IN/OUT: Previous value written to list */
116225 int *pbFirst, /* IN/OUT: True after first int written */
116226 sqlite3_int64 iVal /* Write this value to the list */
116228 sqlite3_int64 iWrite;
116229 if( bDescIdx==0 || *pbFirst==0 ){
116230 iWrite = iVal - *piPrev;
116231 }else{
116232 iWrite = *piPrev - iVal;
116234 assert( *pbFirst || *piPrev==0 );
116235 assert( *pbFirst==0 || iWrite>0 );
116236 *pp += sqlite3Fts3PutVarint(*pp, iWrite);
116237 *piPrev = iVal;
116238 *pbFirst = 1;
116243 ** This macro is used by various functions that merge doclists. The two
116244 ** arguments are 64-bit docid values. If the value of the stack variable
116245 ** bDescDoclist is 0 when this macro is invoked, then it returns (i1-i2).
116246 ** Otherwise, (i2-i1).
116248 ** Using this makes it easier to write code that can merge doclists that are
116249 ** sorted in either ascending or descending order.
116251 #define DOCID_CMP(i1, i2) ((bDescDoclist?-1:1) * (i1-i2))
116254 ** This function does an "OR" merge of two doclists (output contains all
116255 ** positions contained in either argument doclist). If the docids in the
116256 ** input doclists are sorted in ascending order, parameter bDescDoclist
116257 ** should be false. If they are sorted in ascending order, it should be
116258 ** passed a non-zero value.
116260 ** If no error occurs, *paOut is set to point at an sqlite3_malloc'd buffer
116261 ** containing the output doclist and SQLITE_OK is returned. In this case
116262 ** *pnOut is set to the number of bytes in the output doclist.
116264 ** If an error occurs, an SQLite error code is returned. The output values
116265 ** are undefined in this case.
116267 static int fts3DoclistOrMerge(
116268 int bDescDoclist, /* True if arguments are desc */
116269 char *a1, int n1, /* First doclist */
116270 char *a2, int n2, /* Second doclist */
116271 char **paOut, int *pnOut /* OUT: Malloc'd doclist */
116273 sqlite3_int64 i1 = 0;
116274 sqlite3_int64 i2 = 0;
116275 sqlite3_int64 iPrev = 0;
116276 char *pEnd1 = &a1[n1];
116277 char *pEnd2 = &a2[n2];
116278 char *p1 = a1;
116279 char *p2 = a2;
116280 char *p;
116281 char *aOut;
116282 int bFirstOut = 0;
116284 *paOut = 0;
116285 *pnOut = 0;
116287 /* Allocate space for the output. Both the input and output doclists
116288 ** are delta encoded. If they are in ascending order (bDescDoclist==0),
116289 ** then the first docid in each list is simply encoded as a varint. For
116290 ** each subsequent docid, the varint stored is the difference between the
116291 ** current and previous docid (a positive number - since the list is in
116292 ** ascending order).
116294 ** The first docid written to the output is therefore encoded using the
116295 ** same number of bytes as it is in whichever of the input lists it is
116296 ** read from. And each subsequent docid read from the same input list
116297 ** consumes either the same or less bytes as it did in the input (since
116298 ** the difference between it and the previous value in the output must
116299 ** be a positive value less than or equal to the delta value read from
116300 ** the input list). The same argument applies to all but the first docid
116301 ** read from the 'other' list. And to the contents of all position lists
116302 ** that will be copied and merged from the input to the output.
116304 ** However, if the first docid copied to the output is a negative number,
116305 ** then the encoding of the first docid from the 'other' input list may
116306 ** be larger in the output than it was in the input (since the delta value
116307 ** may be a larger positive integer than the actual docid).
116309 ** The space required to store the output is therefore the sum of the
116310 ** sizes of the two inputs, plus enough space for exactly one of the input
116311 ** docids to grow.
116313 ** A symetric argument may be made if the doclists are in descending
116314 ** order.
116316 aOut = sqlite3_malloc(n1+n2+FTS3_VARINT_MAX-1);
116317 if( !aOut ) return SQLITE_NOMEM;
116319 p = aOut;
116320 fts3GetDeltaVarint3(&p1, pEnd1, 0, &i1);
116321 fts3GetDeltaVarint3(&p2, pEnd2, 0, &i2);
116322 while( p1 || p2 ){
116323 sqlite3_int64 iDiff = DOCID_CMP(i1, i2);
116325 if( p2 && p1 && iDiff==0 ){
116326 fts3PutDeltaVarint3(&p, bDescDoclist, &iPrev, &bFirstOut, i1);
116327 fts3PoslistMerge(&p, &p1, &p2);
116328 fts3GetDeltaVarint3(&p1, pEnd1, bDescDoclist, &i1);
116329 fts3GetDeltaVarint3(&p2, pEnd2, bDescDoclist, &i2);
116330 }else if( !p2 || (p1 && iDiff<0) ){
116331 fts3PutDeltaVarint3(&p, bDescDoclist, &iPrev, &bFirstOut, i1);
116332 fts3PoslistCopy(&p, &p1);
116333 fts3GetDeltaVarint3(&p1, pEnd1, bDescDoclist, &i1);
116334 }else{
116335 fts3PutDeltaVarint3(&p, bDescDoclist, &iPrev, &bFirstOut, i2);
116336 fts3PoslistCopy(&p, &p2);
116337 fts3GetDeltaVarint3(&p2, pEnd2, bDescDoclist, &i2);
116341 *paOut = aOut;
116342 *pnOut = (p-aOut);
116343 assert( *pnOut<=n1+n2+FTS3_VARINT_MAX-1 );
116344 return SQLITE_OK;
116348 ** This function does a "phrase" merge of two doclists. In a phrase merge,
116349 ** the output contains a copy of each position from the right-hand input
116350 ** doclist for which there is a position in the left-hand input doclist
116351 ** exactly nDist tokens before it.
116353 ** If the docids in the input doclists are sorted in ascending order,
116354 ** parameter bDescDoclist should be false. If they are sorted in ascending
116355 ** order, it should be passed a non-zero value.
116357 ** The right-hand input doclist is overwritten by this function.
116359 static void fts3DoclistPhraseMerge(
116360 int bDescDoclist, /* True if arguments are desc */
116361 int nDist, /* Distance from left to right (1=adjacent) */
116362 char *aLeft, int nLeft, /* Left doclist */
116363 char *aRight, int *pnRight /* IN/OUT: Right/output doclist */
116365 sqlite3_int64 i1 = 0;
116366 sqlite3_int64 i2 = 0;
116367 sqlite3_int64 iPrev = 0;
116368 char *pEnd1 = &aLeft[nLeft];
116369 char *pEnd2 = &aRight[*pnRight];
116370 char *p1 = aLeft;
116371 char *p2 = aRight;
116372 char *p;
116373 int bFirstOut = 0;
116374 char *aOut = aRight;
116376 assert( nDist>0 );
116378 p = aOut;
116379 fts3GetDeltaVarint3(&p1, pEnd1, 0, &i1);
116380 fts3GetDeltaVarint3(&p2, pEnd2, 0, &i2);
116382 while( p1 && p2 ){
116383 sqlite3_int64 iDiff = DOCID_CMP(i1, i2);
116384 if( iDiff==0 ){
116385 char *pSave = p;
116386 sqlite3_int64 iPrevSave = iPrev;
116387 int bFirstOutSave = bFirstOut;
116389 fts3PutDeltaVarint3(&p, bDescDoclist, &iPrev, &bFirstOut, i1);
116390 if( 0==fts3PoslistPhraseMerge(&p, nDist, 0, 1, &p1, &p2) ){
116391 p = pSave;
116392 iPrev = iPrevSave;
116393 bFirstOut = bFirstOutSave;
116395 fts3GetDeltaVarint3(&p1, pEnd1, bDescDoclist, &i1);
116396 fts3GetDeltaVarint3(&p2, pEnd2, bDescDoclist, &i2);
116397 }else if( iDiff<0 ){
116398 fts3PoslistCopy(0, &p1);
116399 fts3GetDeltaVarint3(&p1, pEnd1, bDescDoclist, &i1);
116400 }else{
116401 fts3PoslistCopy(0, &p2);
116402 fts3GetDeltaVarint3(&p2, pEnd2, bDescDoclist, &i2);
116406 *pnRight = p - aOut;
116411 ** Merge all doclists in the TermSelect.aaOutput[] array into a single
116412 ** doclist stored in TermSelect.aaOutput[0]. If successful, delete all
116413 ** other doclists (except the aaOutput[0] one) and return SQLITE_OK.
116415 ** If an OOM error occurs, return SQLITE_NOMEM. In this case it is
116416 ** the responsibility of the caller to free any doclists left in the
116417 ** TermSelect.aaOutput[] array.
116419 static int fts3TermSelectFinishMerge(Fts3Table *p, TermSelect *pTS){
116420 char *aOut = 0;
116421 int nOut = 0;
116422 int i;
116424 /* Loop through the doclists in the aaOutput[] array. Merge them all
116425 ** into a single doclist.
116427 for(i=0; i<SizeofArray(pTS->aaOutput); i++){
116428 if( pTS->aaOutput[i] ){
116429 if( !aOut ){
116430 aOut = pTS->aaOutput[i];
116431 nOut = pTS->anOutput[i];
116432 pTS->aaOutput[i] = 0;
116433 }else{
116434 int nNew;
116435 char *aNew;
116437 int rc = fts3DoclistOrMerge(p->bDescIdx,
116438 pTS->aaOutput[i], pTS->anOutput[i], aOut, nOut, &aNew, &nNew
116440 if( rc!=SQLITE_OK ){
116441 sqlite3_free(aOut);
116442 return rc;
116445 sqlite3_free(pTS->aaOutput[i]);
116446 sqlite3_free(aOut);
116447 pTS->aaOutput[i] = 0;
116448 aOut = aNew;
116449 nOut = nNew;
116454 pTS->aaOutput[0] = aOut;
116455 pTS->anOutput[0] = nOut;
116456 return SQLITE_OK;
116460 ** Merge the doclist aDoclist/nDoclist into the TermSelect object passed
116461 ** as the first argument. The merge is an "OR" merge (see function
116462 ** fts3DoclistOrMerge() for details).
116464 ** This function is called with the doclist for each term that matches
116465 ** a queried prefix. It merges all these doclists into one, the doclist
116466 ** for the specified prefix. Since there can be a very large number of
116467 ** doclists to merge, the merging is done pair-wise using the TermSelect
116468 ** object.
116470 ** This function returns SQLITE_OK if the merge is successful, or an
116471 ** SQLite error code (SQLITE_NOMEM) if an error occurs.
116473 static int fts3TermSelectMerge(
116474 Fts3Table *p, /* FTS table handle */
116475 TermSelect *pTS, /* TermSelect object to merge into */
116476 char *aDoclist, /* Pointer to doclist */
116477 int nDoclist /* Size of aDoclist in bytes */
116479 if( pTS->aaOutput[0]==0 ){
116480 /* If this is the first term selected, copy the doclist to the output
116481 ** buffer using memcpy(). */
116482 pTS->aaOutput[0] = sqlite3_malloc(nDoclist);
116483 pTS->anOutput[0] = nDoclist;
116484 if( pTS->aaOutput[0] ){
116485 memcpy(pTS->aaOutput[0], aDoclist, nDoclist);
116486 }else{
116487 return SQLITE_NOMEM;
116489 }else{
116490 char *aMerge = aDoclist;
116491 int nMerge = nDoclist;
116492 int iOut;
116494 for(iOut=0; iOut<SizeofArray(pTS->aaOutput); iOut++){
116495 if( pTS->aaOutput[iOut]==0 ){
116496 assert( iOut>0 );
116497 pTS->aaOutput[iOut] = aMerge;
116498 pTS->anOutput[iOut] = nMerge;
116499 break;
116500 }else{
116501 char *aNew;
116502 int nNew;
116504 int rc = fts3DoclistOrMerge(p->bDescIdx, aMerge, nMerge,
116505 pTS->aaOutput[iOut], pTS->anOutput[iOut], &aNew, &nNew
116507 if( rc!=SQLITE_OK ){
116508 if( aMerge!=aDoclist ) sqlite3_free(aMerge);
116509 return rc;
116512 if( aMerge!=aDoclist ) sqlite3_free(aMerge);
116513 sqlite3_free(pTS->aaOutput[iOut]);
116514 pTS->aaOutput[iOut] = 0;
116516 aMerge = aNew;
116517 nMerge = nNew;
116518 if( (iOut+1)==SizeofArray(pTS->aaOutput) ){
116519 pTS->aaOutput[iOut] = aMerge;
116520 pTS->anOutput[iOut] = nMerge;
116525 return SQLITE_OK;
116529 ** Append SegReader object pNew to the end of the pCsr->apSegment[] array.
116531 static int fts3SegReaderCursorAppend(
116532 Fts3MultiSegReader *pCsr,
116533 Fts3SegReader *pNew
116535 if( (pCsr->nSegment%16)==0 ){
116536 Fts3SegReader **apNew;
116537 int nByte = (pCsr->nSegment + 16)*sizeof(Fts3SegReader*);
116538 apNew = (Fts3SegReader **)sqlite3_realloc(pCsr->apSegment, nByte);
116539 if( !apNew ){
116540 sqlite3Fts3SegReaderFree(pNew);
116541 return SQLITE_NOMEM;
116543 pCsr->apSegment = apNew;
116545 pCsr->apSegment[pCsr->nSegment++] = pNew;
116546 return SQLITE_OK;
116550 ** Add seg-reader objects to the Fts3MultiSegReader object passed as the
116551 ** 8th argument.
116553 ** This function returns SQLITE_OK if successful, or an SQLite error code
116554 ** otherwise.
116556 static int fts3SegReaderCursor(
116557 Fts3Table *p, /* FTS3 table handle */
116558 int iIndex, /* Index to search (from 0 to p->nIndex-1) */
116559 int iLevel, /* Level of segments to scan */
116560 const char *zTerm, /* Term to query for */
116561 int nTerm, /* Size of zTerm in bytes */
116562 int isPrefix, /* True for a prefix search */
116563 int isScan, /* True to scan from zTerm to EOF */
116564 Fts3MultiSegReader *pCsr /* Cursor object to populate */
116566 int rc = SQLITE_OK; /* Error code */
116567 sqlite3_stmt *pStmt = 0; /* Statement to iterate through segments */
116568 int rc2; /* Result of sqlite3_reset() */
116570 /* If iLevel is less than 0 and this is not a scan, include a seg-reader
116571 ** for the pending-terms. If this is a scan, then this call must be being
116572 ** made by an fts4aux module, not an FTS table. In this case calling
116573 ** Fts3SegReaderPending might segfault, as the data structures used by
116574 ** fts4aux are not completely populated. So it's easiest to filter these
116575 ** calls out here. */
116576 if( iLevel<0 && p->aIndex ){
116577 Fts3SegReader *pSeg = 0;
116578 rc = sqlite3Fts3SegReaderPending(p, iIndex, zTerm, nTerm, isPrefix, &pSeg);
116579 if( rc==SQLITE_OK && pSeg ){
116580 rc = fts3SegReaderCursorAppend(pCsr, pSeg);
116584 if( iLevel!=FTS3_SEGCURSOR_PENDING ){
116585 if( rc==SQLITE_OK ){
116586 rc = sqlite3Fts3AllSegdirs(p, iIndex, iLevel, &pStmt);
116589 while( rc==SQLITE_OK && SQLITE_ROW==(rc = sqlite3_step(pStmt)) ){
116590 Fts3SegReader *pSeg = 0;
116592 /* Read the values returned by the SELECT into local variables. */
116593 sqlite3_int64 iStartBlock = sqlite3_column_int64(pStmt, 1);
116594 sqlite3_int64 iLeavesEndBlock = sqlite3_column_int64(pStmt, 2);
116595 sqlite3_int64 iEndBlock = sqlite3_column_int64(pStmt, 3);
116596 int nRoot = sqlite3_column_bytes(pStmt, 4);
116597 char const *zRoot = sqlite3_column_blob(pStmt, 4);
116599 /* If zTerm is not NULL, and this segment is not stored entirely on its
116600 ** root node, the range of leaves scanned can be reduced. Do this. */
116601 if( iStartBlock && zTerm ){
116602 sqlite3_int64 *pi = (isPrefix ? &iLeavesEndBlock : 0);
116603 rc = fts3SelectLeaf(p, zTerm, nTerm, zRoot, nRoot, &iStartBlock, pi);
116604 if( rc!=SQLITE_OK ) goto finished;
116605 if( isPrefix==0 && isScan==0 ) iLeavesEndBlock = iStartBlock;
116608 rc = sqlite3Fts3SegReaderNew(pCsr->nSegment+1,
116609 iStartBlock, iLeavesEndBlock, iEndBlock, zRoot, nRoot, &pSeg
116611 if( rc!=SQLITE_OK ) goto finished;
116612 rc = fts3SegReaderCursorAppend(pCsr, pSeg);
116616 finished:
116617 rc2 = sqlite3_reset(pStmt);
116618 if( rc==SQLITE_DONE ) rc = rc2;
116620 return rc;
116624 ** Set up a cursor object for iterating through a full-text index or a
116625 ** single level therein.
116627 SQLITE_PRIVATE int sqlite3Fts3SegReaderCursor(
116628 Fts3Table *p, /* FTS3 table handle */
116629 int iIndex, /* Index to search (from 0 to p->nIndex-1) */
116630 int iLevel, /* Level of segments to scan */
116631 const char *zTerm, /* Term to query for */
116632 int nTerm, /* Size of zTerm in bytes */
116633 int isPrefix, /* True for a prefix search */
116634 int isScan, /* True to scan from zTerm to EOF */
116635 Fts3MultiSegReader *pCsr /* Cursor object to populate */
116637 assert( iIndex>=0 && iIndex<p->nIndex );
116638 assert( iLevel==FTS3_SEGCURSOR_ALL
116639 || iLevel==FTS3_SEGCURSOR_PENDING
116640 || iLevel>=0
116642 assert( iLevel<FTS3_SEGDIR_MAXLEVEL );
116643 assert( FTS3_SEGCURSOR_ALL<0 && FTS3_SEGCURSOR_PENDING<0 );
116644 assert( isPrefix==0 || isScan==0 );
116646 /* "isScan" is only set to true by the ft4aux module, an ordinary
116647 ** full-text tables. */
116648 assert( isScan==0 || p->aIndex==0 );
116650 memset(pCsr, 0, sizeof(Fts3MultiSegReader));
116652 return fts3SegReaderCursor(
116653 p, iIndex, iLevel, zTerm, nTerm, isPrefix, isScan, pCsr
116658 ** In addition to its current configuration, have the Fts3MultiSegReader
116659 ** passed as the 4th argument also scan the doclist for term zTerm/nTerm.
116661 ** SQLITE_OK is returned if no error occurs, otherwise an SQLite error code.
116663 static int fts3SegReaderCursorAddZero(
116664 Fts3Table *p, /* FTS virtual table handle */
116665 const char *zTerm, /* Term to scan doclist of */
116666 int nTerm, /* Number of bytes in zTerm */
116667 Fts3MultiSegReader *pCsr /* Fts3MultiSegReader to modify */
116669 return fts3SegReaderCursor(p, 0, FTS3_SEGCURSOR_ALL, zTerm, nTerm, 0, 0,pCsr);
116673 ** Open an Fts3MultiSegReader to scan the doclist for term zTerm/nTerm. Or,
116674 ** if isPrefix is true, to scan the doclist for all terms for which
116675 ** zTerm/nTerm is a prefix. If successful, return SQLITE_OK and write
116676 ** a pointer to the new Fts3MultiSegReader to *ppSegcsr. Otherwise, return
116677 ** an SQLite error code.
116679 ** It is the responsibility of the caller to free this object by eventually
116680 ** passing it to fts3SegReaderCursorFree()
116682 ** SQLITE_OK is returned if no error occurs, otherwise an SQLite error code.
116683 ** Output parameter *ppSegcsr is set to 0 if an error occurs.
116685 static int fts3TermSegReaderCursor(
116686 Fts3Cursor *pCsr, /* Virtual table cursor handle */
116687 const char *zTerm, /* Term to query for */
116688 int nTerm, /* Size of zTerm in bytes */
116689 int isPrefix, /* True for a prefix search */
116690 Fts3MultiSegReader **ppSegcsr /* OUT: Allocated seg-reader cursor */
116692 Fts3MultiSegReader *pSegcsr; /* Object to allocate and return */
116693 int rc = SQLITE_NOMEM; /* Return code */
116695 pSegcsr = sqlite3_malloc(sizeof(Fts3MultiSegReader));
116696 if( pSegcsr ){
116697 int i;
116698 int bFound = 0; /* True once an index has been found */
116699 Fts3Table *p = (Fts3Table *)pCsr->base.pVtab;
116701 if( isPrefix ){
116702 for(i=1; bFound==0 && i<p->nIndex; i++){
116703 if( p->aIndex[i].nPrefix==nTerm ){
116704 bFound = 1;
116705 rc = sqlite3Fts3SegReaderCursor(
116706 p, i, FTS3_SEGCURSOR_ALL, zTerm, nTerm, 0, 0, pSegcsr);
116707 pSegcsr->bLookup = 1;
116711 for(i=1; bFound==0 && i<p->nIndex; i++){
116712 if( p->aIndex[i].nPrefix==nTerm+1 ){
116713 bFound = 1;
116714 rc = sqlite3Fts3SegReaderCursor(
116715 p, i, FTS3_SEGCURSOR_ALL, zTerm, nTerm, 1, 0, pSegcsr
116717 if( rc==SQLITE_OK ){
116718 rc = fts3SegReaderCursorAddZero(p, zTerm, nTerm, pSegcsr);
116724 if( bFound==0 ){
116725 rc = sqlite3Fts3SegReaderCursor(
116726 p, 0, FTS3_SEGCURSOR_ALL, zTerm, nTerm, isPrefix, 0, pSegcsr
116728 pSegcsr->bLookup = !isPrefix;
116732 *ppSegcsr = pSegcsr;
116733 return rc;
116737 ** Free an Fts3MultiSegReader allocated by fts3TermSegReaderCursor().
116739 static void fts3SegReaderCursorFree(Fts3MultiSegReader *pSegcsr){
116740 sqlite3Fts3SegReaderFinish(pSegcsr);
116741 sqlite3_free(pSegcsr);
116745 ** This function retreives the doclist for the specified term (or term
116746 ** prefix) from the database.
116748 static int fts3TermSelect(
116749 Fts3Table *p, /* Virtual table handle */
116750 Fts3PhraseToken *pTok, /* Token to query for */
116751 int iColumn, /* Column to query (or -ve for all columns) */
116752 int *pnOut, /* OUT: Size of buffer at *ppOut */
116753 char **ppOut /* OUT: Malloced result buffer */
116755 int rc; /* Return code */
116756 Fts3MultiSegReader *pSegcsr; /* Seg-reader cursor for this term */
116757 TermSelect tsc; /* Object for pair-wise doclist merging */
116758 Fts3SegFilter filter; /* Segment term filter configuration */
116760 pSegcsr = pTok->pSegcsr;
116761 memset(&tsc, 0, sizeof(TermSelect));
116763 filter.flags = FTS3_SEGMENT_IGNORE_EMPTY | FTS3_SEGMENT_REQUIRE_POS
116764 | (pTok->isPrefix ? FTS3_SEGMENT_PREFIX : 0)
116765 | (iColumn<p->nColumn ? FTS3_SEGMENT_COLUMN_FILTER : 0);
116766 filter.iCol = iColumn;
116767 filter.zTerm = pTok->z;
116768 filter.nTerm = pTok->n;
116770 rc = sqlite3Fts3SegReaderStart(p, pSegcsr, &filter);
116771 while( SQLITE_OK==rc
116772 && SQLITE_ROW==(rc = sqlite3Fts3SegReaderStep(p, pSegcsr))
116774 rc = fts3TermSelectMerge(p, &tsc, pSegcsr->aDoclist, pSegcsr->nDoclist);
116777 if( rc==SQLITE_OK ){
116778 rc = fts3TermSelectFinishMerge(p, &tsc);
116780 if( rc==SQLITE_OK ){
116781 *ppOut = tsc.aaOutput[0];
116782 *pnOut = tsc.anOutput[0];
116783 }else{
116784 int i;
116785 for(i=0; i<SizeofArray(tsc.aaOutput); i++){
116786 sqlite3_free(tsc.aaOutput[i]);
116790 fts3SegReaderCursorFree(pSegcsr);
116791 pTok->pSegcsr = 0;
116792 return rc;
116796 ** This function counts the total number of docids in the doclist stored
116797 ** in buffer aList[], size nList bytes.
116799 ** If the isPoslist argument is true, then it is assumed that the doclist
116800 ** contains a position-list following each docid. Otherwise, it is assumed
116801 ** that the doclist is simply a list of docids stored as delta encoded
116802 ** varints.
116804 static int fts3DoclistCountDocids(char *aList, int nList){
116805 int nDoc = 0; /* Return value */
116806 if( aList ){
116807 char *aEnd = &aList[nList]; /* Pointer to one byte after EOF */
116808 char *p = aList; /* Cursor */
116809 while( p<aEnd ){
116810 nDoc++;
116811 while( (*p++)&0x80 ); /* Skip docid varint */
116812 fts3PoslistCopy(0, &p); /* Skip over position list */
116816 return nDoc;
116820 ** Advance the cursor to the next row in the %_content table that
116821 ** matches the search criteria. For a MATCH search, this will be
116822 ** the next row that matches. For a full-table scan, this will be
116823 ** simply the next row in the %_content table. For a docid lookup,
116824 ** this routine simply sets the EOF flag.
116826 ** Return SQLITE_OK if nothing goes wrong. SQLITE_OK is returned
116827 ** even if we reach end-of-file. The fts3EofMethod() will be called
116828 ** subsequently to determine whether or not an EOF was hit.
116830 static int fts3NextMethod(sqlite3_vtab_cursor *pCursor){
116831 int rc;
116832 Fts3Cursor *pCsr = (Fts3Cursor *)pCursor;
116833 if( pCsr->eSearch==FTS3_DOCID_SEARCH || pCsr->eSearch==FTS3_FULLSCAN_SEARCH ){
116834 if( SQLITE_ROW!=sqlite3_step(pCsr->pStmt) ){
116835 pCsr->isEof = 1;
116836 rc = sqlite3_reset(pCsr->pStmt);
116837 }else{
116838 pCsr->iPrevId = sqlite3_column_int64(pCsr->pStmt, 0);
116839 rc = SQLITE_OK;
116841 }else{
116842 rc = fts3EvalNext((Fts3Cursor *)pCursor);
116844 assert( ((Fts3Table *)pCsr->base.pVtab)->pSegments==0 );
116845 return rc;
116849 ** This is the xFilter interface for the virtual table. See
116850 ** the virtual table xFilter method documentation for additional
116851 ** information.
116853 ** If idxNum==FTS3_FULLSCAN_SEARCH then do a full table scan against
116854 ** the %_content table.
116856 ** If idxNum==FTS3_DOCID_SEARCH then do a docid lookup for a single entry
116857 ** in the %_content table.
116859 ** If idxNum>=FTS3_FULLTEXT_SEARCH then use the full text index. The
116860 ** column on the left-hand side of the MATCH operator is column
116861 ** number idxNum-FTS3_FULLTEXT_SEARCH, 0 indexed. argv[0] is the right-hand
116862 ** side of the MATCH operator.
116864 static int fts3FilterMethod(
116865 sqlite3_vtab_cursor *pCursor, /* The cursor used for this query */
116866 int idxNum, /* Strategy index */
116867 const char *idxStr, /* Unused */
116868 int nVal, /* Number of elements in apVal */
116869 sqlite3_value **apVal /* Arguments for the indexing scheme */
116871 int rc;
116872 char *zSql; /* SQL statement used to access %_content */
116873 Fts3Table *p = (Fts3Table *)pCursor->pVtab;
116874 Fts3Cursor *pCsr = (Fts3Cursor *)pCursor;
116876 UNUSED_PARAMETER(idxStr);
116877 UNUSED_PARAMETER(nVal);
116879 assert( idxNum>=0 && idxNum<=(FTS3_FULLTEXT_SEARCH+p->nColumn) );
116880 assert( nVal==0 || nVal==1 );
116881 assert( (nVal==0)==(idxNum==FTS3_FULLSCAN_SEARCH) );
116882 assert( p->pSegments==0 );
116884 /* In case the cursor has been used before, clear it now. */
116885 sqlite3_finalize(pCsr->pStmt);
116886 sqlite3_free(pCsr->aDoclist);
116887 sqlite3Fts3ExprFree(pCsr->pExpr);
116888 memset(&pCursor[1], 0, sizeof(Fts3Cursor)-sizeof(sqlite3_vtab_cursor));
116890 if( idxStr ){
116891 pCsr->bDesc = (idxStr[0]=='D');
116892 }else{
116893 pCsr->bDesc = p->bDescIdx;
116895 pCsr->eSearch = (i16)idxNum;
116897 if( idxNum!=FTS3_DOCID_SEARCH && idxNum!=FTS3_FULLSCAN_SEARCH ){
116898 int iCol = idxNum-FTS3_FULLTEXT_SEARCH;
116899 const char *zQuery = (const char *)sqlite3_value_text(apVal[0]);
116901 if( zQuery==0 && sqlite3_value_type(apVal[0])!=SQLITE_NULL ){
116902 return SQLITE_NOMEM;
116905 rc = sqlite3Fts3ExprParse(p->pTokenizer, p->azColumn, p->nColumn,
116906 iCol, zQuery, -1, &pCsr->pExpr
116908 if( rc!=SQLITE_OK ){
116909 if( rc==SQLITE_ERROR ){
116910 static const char *zErr = "malformed MATCH expression: [%s]";
116911 p->base.zErrMsg = sqlite3_mprintf(zErr, zQuery);
116913 return rc;
116916 rc = sqlite3Fts3ReadLock(p);
116917 if( rc!=SQLITE_OK ) return rc;
116919 rc = fts3EvalStart(pCsr);
116921 sqlite3Fts3SegmentsClose(p);
116922 if( rc!=SQLITE_OK ) return rc;
116923 pCsr->pNextId = pCsr->aDoclist;
116924 pCsr->iPrevId = 0;
116927 /* Compile a SELECT statement for this cursor. For a full-table-scan, the
116928 ** statement loops through all rows of the %_content table. For a
116929 ** full-text query or docid lookup, the statement retrieves a single
116930 ** row by docid.
116932 if( idxNum==FTS3_FULLSCAN_SEARCH ){
116933 const char *zSort = (pCsr->bDesc ? "DESC" : "ASC");
116934 const char *zTmpl = "SELECT %s FROM %Q.'%q_content' AS x ORDER BY docid %s";
116935 zSql = sqlite3_mprintf(zTmpl, p->zReadExprlist, p->zDb, p->zName, zSort);
116936 }else{
116937 const char *zTmpl = "SELECT %s FROM %Q.'%q_content' AS x WHERE docid = ?";
116938 zSql = sqlite3_mprintf(zTmpl, p->zReadExprlist, p->zDb, p->zName);
116940 if( !zSql ) return SQLITE_NOMEM;
116941 rc = sqlite3_prepare_v2(p->db, zSql, -1, &pCsr->pStmt, 0);
116942 sqlite3_free(zSql);
116943 if( rc!=SQLITE_OK ) return rc;
116945 if( idxNum==FTS3_DOCID_SEARCH ){
116946 rc = sqlite3_bind_value(pCsr->pStmt, 1, apVal[0]);
116947 if( rc!=SQLITE_OK ) return rc;
116950 return fts3NextMethod(pCursor);
116954 ** This is the xEof method of the virtual table. SQLite calls this
116955 ** routine to find out if it has reached the end of a result set.
116957 static int fts3EofMethod(sqlite3_vtab_cursor *pCursor){
116958 return ((Fts3Cursor *)pCursor)->isEof;
116962 ** This is the xRowid method. The SQLite core calls this routine to
116963 ** retrieve the rowid for the current row of the result set. fts3
116964 ** exposes %_content.docid as the rowid for the virtual table. The
116965 ** rowid should be written to *pRowid.
116967 static int fts3RowidMethod(sqlite3_vtab_cursor *pCursor, sqlite_int64 *pRowid){
116968 Fts3Cursor *pCsr = (Fts3Cursor *) pCursor;
116969 *pRowid = pCsr->iPrevId;
116970 return SQLITE_OK;
116974 ** This is the xColumn method, called by SQLite to request a value from
116975 ** the row that the supplied cursor currently points to.
116977 static int fts3ColumnMethod(
116978 sqlite3_vtab_cursor *pCursor, /* Cursor to retrieve value from */
116979 sqlite3_context *pContext, /* Context for sqlite3_result_xxx() calls */
116980 int iCol /* Index of column to read value from */
116982 int rc = SQLITE_OK; /* Return Code */
116983 Fts3Cursor *pCsr = (Fts3Cursor *) pCursor;
116984 Fts3Table *p = (Fts3Table *)pCursor->pVtab;
116986 /* The column value supplied by SQLite must be in range. */
116987 assert( iCol>=0 && iCol<=p->nColumn+1 );
116989 if( iCol==p->nColumn+1 ){
116990 /* This call is a request for the "docid" column. Since "docid" is an
116991 ** alias for "rowid", use the xRowid() method to obtain the value.
116993 sqlite3_result_int64(pContext, pCsr->iPrevId);
116994 }else if( iCol==p->nColumn ){
116995 /* The extra column whose name is the same as the table.
116996 ** Return a blob which is a pointer to the cursor.
116998 sqlite3_result_blob(pContext, &pCsr, sizeof(pCsr), SQLITE_TRANSIENT);
116999 }else{
117000 rc = fts3CursorSeek(0, pCsr);
117001 if( rc==SQLITE_OK ){
117002 sqlite3_result_value(pContext, sqlite3_column_value(pCsr->pStmt, iCol+1));
117006 assert( ((Fts3Table *)pCsr->base.pVtab)->pSegments==0 );
117007 return rc;
117011 ** This function is the implementation of the xUpdate callback used by
117012 ** FTS3 virtual tables. It is invoked by SQLite each time a row is to be
117013 ** inserted, updated or deleted.
117015 static int fts3UpdateMethod(
117016 sqlite3_vtab *pVtab, /* Virtual table handle */
117017 int nArg, /* Size of argument array */
117018 sqlite3_value **apVal, /* Array of arguments */
117019 sqlite_int64 *pRowid /* OUT: The affected (or effected) rowid */
117021 return sqlite3Fts3UpdateMethod(pVtab, nArg, apVal, pRowid);
117025 ** Implementation of xSync() method. Flush the contents of the pending-terms
117026 ** hash-table to the database.
117028 static int fts3SyncMethod(sqlite3_vtab *pVtab){
117029 int rc = sqlite3Fts3PendingTermsFlush((Fts3Table *)pVtab);
117030 sqlite3Fts3SegmentsClose((Fts3Table *)pVtab);
117031 return rc;
117035 ** Implementation of xBegin() method. This is a no-op.
117037 static int fts3BeginMethod(sqlite3_vtab *pVtab){
117038 TESTONLY( Fts3Table *p = (Fts3Table*)pVtab );
117039 UNUSED_PARAMETER(pVtab);
117040 assert( p->pSegments==0 );
117041 assert( p->nPendingData==0 );
117042 assert( p->inTransaction!=1 );
117043 TESTONLY( p->inTransaction = 1 );
117044 TESTONLY( p->mxSavepoint = -1; );
117045 return SQLITE_OK;
117049 ** Implementation of xCommit() method. This is a no-op. The contents of
117050 ** the pending-terms hash-table have already been flushed into the database
117051 ** by fts3SyncMethod().
117053 static int fts3CommitMethod(sqlite3_vtab *pVtab){
117054 TESTONLY( Fts3Table *p = (Fts3Table*)pVtab );
117055 UNUSED_PARAMETER(pVtab);
117056 assert( p->nPendingData==0 );
117057 assert( p->inTransaction!=0 );
117058 assert( p->pSegments==0 );
117059 TESTONLY( p->inTransaction = 0 );
117060 TESTONLY( p->mxSavepoint = -1; );
117061 return SQLITE_OK;
117065 ** Implementation of xRollback(). Discard the contents of the pending-terms
117066 ** hash-table. Any changes made to the database are reverted by SQLite.
117068 static int fts3RollbackMethod(sqlite3_vtab *pVtab){
117069 Fts3Table *p = (Fts3Table*)pVtab;
117070 sqlite3Fts3PendingTermsClear(p);
117071 assert( p->inTransaction!=0 );
117072 TESTONLY( p->inTransaction = 0 );
117073 TESTONLY( p->mxSavepoint = -1; );
117074 return SQLITE_OK;
117078 ** When called, *ppPoslist must point to the byte immediately following the
117079 ** end of a position-list. i.e. ( (*ppPoslist)[-1]==POS_END ). This function
117080 ** moves *ppPoslist so that it instead points to the first byte of the
117081 ** same position list.
117083 static void fts3ReversePoslist(char *pStart, char **ppPoslist){
117084 char *p = &(*ppPoslist)[-2];
117085 char c;
117087 while( p>pStart && (c=*p--)==0 );
117088 while( p>pStart && (*p & 0x80) | c ){
117089 c = *p--;
117091 if( p>pStart ){ p = &p[2]; }
117092 while( *p++&0x80 );
117093 *ppPoslist = p;
117097 ** Helper function used by the implementation of the overloaded snippet(),
117098 ** offsets() and optimize() SQL functions.
117100 ** If the value passed as the third argument is a blob of size
117101 ** sizeof(Fts3Cursor*), then the blob contents are copied to the
117102 ** output variable *ppCsr and SQLITE_OK is returned. Otherwise, an error
117103 ** message is written to context pContext and SQLITE_ERROR returned. The
117104 ** string passed via zFunc is used as part of the error message.
117106 static int fts3FunctionArg(
117107 sqlite3_context *pContext, /* SQL function call context */
117108 const char *zFunc, /* Function name */
117109 sqlite3_value *pVal, /* argv[0] passed to function */
117110 Fts3Cursor **ppCsr /* OUT: Store cursor handle here */
117112 Fts3Cursor *pRet;
117113 if( sqlite3_value_type(pVal)!=SQLITE_BLOB
117114 || sqlite3_value_bytes(pVal)!=sizeof(Fts3Cursor *)
117116 char *zErr = sqlite3_mprintf("illegal first argument to %s", zFunc);
117117 sqlite3_result_error(pContext, zErr, -1);
117118 sqlite3_free(zErr);
117119 return SQLITE_ERROR;
117121 memcpy(&pRet, sqlite3_value_blob(pVal), sizeof(Fts3Cursor *));
117122 *ppCsr = pRet;
117123 return SQLITE_OK;
117127 ** Implementation of the snippet() function for FTS3
117129 static void fts3SnippetFunc(
117130 sqlite3_context *pContext, /* SQLite function call context */
117131 int nVal, /* Size of apVal[] array */
117132 sqlite3_value **apVal /* Array of arguments */
117134 Fts3Cursor *pCsr; /* Cursor handle passed through apVal[0] */
117135 const char *zStart = "<b>";
117136 const char *zEnd = "</b>";
117137 const char *zEllipsis = "<b>...</b>";
117138 int iCol = -1;
117139 int nToken = 15; /* Default number of tokens in snippet */
117141 /* There must be at least one argument passed to this function (otherwise
117142 ** the non-overloaded version would have been called instead of this one).
117144 assert( nVal>=1 );
117146 if( nVal>6 ){
117147 sqlite3_result_error(pContext,
117148 "wrong number of arguments to function snippet()", -1);
117149 return;
117151 if( fts3FunctionArg(pContext, "snippet", apVal[0], &pCsr) ) return;
117153 switch( nVal ){
117154 case 6: nToken = sqlite3_value_int(apVal[5]);
117155 case 5: iCol = sqlite3_value_int(apVal[4]);
117156 case 4: zEllipsis = (const char*)sqlite3_value_text(apVal[3]);
117157 case 3: zEnd = (const char*)sqlite3_value_text(apVal[2]);
117158 case 2: zStart = (const char*)sqlite3_value_text(apVal[1]);
117160 if( !zEllipsis || !zEnd || !zStart ){
117161 sqlite3_result_error_nomem(pContext);
117162 }else if( SQLITE_OK==fts3CursorSeek(pContext, pCsr) ){
117163 sqlite3Fts3Snippet(pContext, pCsr, zStart, zEnd, zEllipsis, iCol, nToken);
117168 ** Implementation of the offsets() function for FTS3
117170 static void fts3OffsetsFunc(
117171 sqlite3_context *pContext, /* SQLite function call context */
117172 int nVal, /* Size of argument array */
117173 sqlite3_value **apVal /* Array of arguments */
117175 Fts3Cursor *pCsr; /* Cursor handle passed through apVal[0] */
117177 UNUSED_PARAMETER(nVal);
117179 assert( nVal==1 );
117180 if( fts3FunctionArg(pContext, "offsets", apVal[0], &pCsr) ) return;
117181 assert( pCsr );
117182 if( SQLITE_OK==fts3CursorSeek(pContext, pCsr) ){
117183 sqlite3Fts3Offsets(pContext, pCsr);
117188 ** Implementation of the special optimize() function for FTS3. This
117189 ** function merges all segments in the database to a single segment.
117190 ** Example usage is:
117192 ** SELECT optimize(t) FROM t LIMIT 1;
117194 ** where 't' is the name of an FTS3 table.
117196 static void fts3OptimizeFunc(
117197 sqlite3_context *pContext, /* SQLite function call context */
117198 int nVal, /* Size of argument array */
117199 sqlite3_value **apVal /* Array of arguments */
117201 int rc; /* Return code */
117202 Fts3Table *p; /* Virtual table handle */
117203 Fts3Cursor *pCursor; /* Cursor handle passed through apVal[0] */
117205 UNUSED_PARAMETER(nVal);
117207 assert( nVal==1 );
117208 if( fts3FunctionArg(pContext, "optimize", apVal[0], &pCursor) ) return;
117209 p = (Fts3Table *)pCursor->base.pVtab;
117210 assert( p );
117212 rc = sqlite3Fts3Optimize(p);
117214 switch( rc ){
117215 case SQLITE_OK:
117216 sqlite3_result_text(pContext, "Index optimized", -1, SQLITE_STATIC);
117217 break;
117218 case SQLITE_DONE:
117219 sqlite3_result_text(pContext, "Index already optimal", -1, SQLITE_STATIC);
117220 break;
117221 default:
117222 sqlite3_result_error_code(pContext, rc);
117223 break;
117228 ** Implementation of the matchinfo() function for FTS3
117230 static void fts3MatchinfoFunc(
117231 sqlite3_context *pContext, /* SQLite function call context */
117232 int nVal, /* Size of argument array */
117233 sqlite3_value **apVal /* Array of arguments */
117235 Fts3Cursor *pCsr; /* Cursor handle passed through apVal[0] */
117236 assert( nVal==1 || nVal==2 );
117237 if( SQLITE_OK==fts3FunctionArg(pContext, "matchinfo", apVal[0], &pCsr) ){
117238 const char *zArg = 0;
117239 if( nVal>1 ){
117240 zArg = (const char *)sqlite3_value_text(apVal[1]);
117242 sqlite3Fts3Matchinfo(pContext, pCsr, zArg);
117247 ** This routine implements the xFindFunction method for the FTS3
117248 ** virtual table.
117250 static int fts3FindFunctionMethod(
117251 sqlite3_vtab *pVtab, /* Virtual table handle */
117252 int nArg, /* Number of SQL function arguments */
117253 const char *zName, /* Name of SQL function */
117254 void (**pxFunc)(sqlite3_context*,int,sqlite3_value**), /* OUT: Result */
117255 void **ppArg /* Unused */
117257 struct Overloaded {
117258 const char *zName;
117259 void (*xFunc)(sqlite3_context*,int,sqlite3_value**);
117260 } aOverload[] = {
117261 { "snippet", fts3SnippetFunc },
117262 { "offsets", fts3OffsetsFunc },
117263 { "optimize", fts3OptimizeFunc },
117264 { "matchinfo", fts3MatchinfoFunc },
117266 int i; /* Iterator variable */
117268 UNUSED_PARAMETER(pVtab);
117269 UNUSED_PARAMETER(nArg);
117270 UNUSED_PARAMETER(ppArg);
117272 for(i=0; i<SizeofArray(aOverload); i++){
117273 if( strcmp(zName, aOverload[i].zName)==0 ){
117274 *pxFunc = aOverload[i].xFunc;
117275 return 1;
117279 /* No function of the specified name was found. Return 0. */
117280 return 0;
117284 ** Implementation of FTS3 xRename method. Rename an fts3 table.
117286 static int fts3RenameMethod(
117287 sqlite3_vtab *pVtab, /* Virtual table handle */
117288 const char *zName /* New name of table */
117290 Fts3Table *p = (Fts3Table *)pVtab;
117291 sqlite3 *db = p->db; /* Database connection */
117292 int rc; /* Return Code */
117294 rc = sqlite3Fts3PendingTermsFlush(p);
117295 if( rc!=SQLITE_OK ){
117296 return rc;
117299 fts3DbExec(&rc, db,
117300 "ALTER TABLE %Q.'%q_content' RENAME TO '%q_content';",
117301 p->zDb, p->zName, zName
117303 if( p->bHasDocsize ){
117304 fts3DbExec(&rc, db,
117305 "ALTER TABLE %Q.'%q_docsize' RENAME TO '%q_docsize';",
117306 p->zDb, p->zName, zName
117309 if( p->bHasStat ){
117310 fts3DbExec(&rc, db,
117311 "ALTER TABLE %Q.'%q_stat' RENAME TO '%q_stat';",
117312 p->zDb, p->zName, zName
117315 fts3DbExec(&rc, db,
117316 "ALTER TABLE %Q.'%q_segments' RENAME TO '%q_segments';",
117317 p->zDb, p->zName, zName
117319 fts3DbExec(&rc, db,
117320 "ALTER TABLE %Q.'%q_segdir' RENAME TO '%q_segdir';",
117321 p->zDb, p->zName, zName
117323 return rc;
117327 ** The xSavepoint() method.
117329 ** Flush the contents of the pending-terms table to disk.
117331 static int fts3SavepointMethod(sqlite3_vtab *pVtab, int iSavepoint){
117332 UNUSED_PARAMETER(iSavepoint);
117333 assert( ((Fts3Table *)pVtab)->inTransaction );
117334 assert( ((Fts3Table *)pVtab)->mxSavepoint < iSavepoint );
117335 TESTONLY( ((Fts3Table *)pVtab)->mxSavepoint = iSavepoint );
117336 return fts3SyncMethod(pVtab);
117340 ** The xRelease() method.
117342 ** This is a no-op.
117344 static int fts3ReleaseMethod(sqlite3_vtab *pVtab, int iSavepoint){
117345 TESTONLY( Fts3Table *p = (Fts3Table*)pVtab );
117346 UNUSED_PARAMETER(iSavepoint);
117347 UNUSED_PARAMETER(pVtab);
117348 assert( p->inTransaction );
117349 assert( p->mxSavepoint >= iSavepoint );
117350 TESTONLY( p->mxSavepoint = iSavepoint-1 );
117351 return SQLITE_OK;
117355 ** The xRollbackTo() method.
117357 ** Discard the contents of the pending terms table.
117359 static int fts3RollbackToMethod(sqlite3_vtab *pVtab, int iSavepoint){
117360 Fts3Table *p = (Fts3Table*)pVtab;
117361 UNUSED_PARAMETER(iSavepoint);
117362 assert( p->inTransaction );
117363 assert( p->mxSavepoint >= iSavepoint );
117364 TESTONLY( p->mxSavepoint = iSavepoint );
117365 sqlite3Fts3PendingTermsClear(p);
117366 return SQLITE_OK;
117369 static const sqlite3_module fts3Module = {
117370 /* iVersion */ 2,
117371 /* xCreate */ fts3CreateMethod,
117372 /* xConnect */ fts3ConnectMethod,
117373 /* xBestIndex */ fts3BestIndexMethod,
117374 /* xDisconnect */ fts3DisconnectMethod,
117375 /* xDestroy */ fts3DestroyMethod,
117376 /* xOpen */ fts3OpenMethod,
117377 /* xClose */ fts3CloseMethod,
117378 /* xFilter */ fts3FilterMethod,
117379 /* xNext */ fts3NextMethod,
117380 /* xEof */ fts3EofMethod,
117381 /* xColumn */ fts3ColumnMethod,
117382 /* xRowid */ fts3RowidMethod,
117383 /* xUpdate */ fts3UpdateMethod,
117384 /* xBegin */ fts3BeginMethod,
117385 /* xSync */ fts3SyncMethod,
117386 /* xCommit */ fts3CommitMethod,
117387 /* xRollback */ fts3RollbackMethod,
117388 /* xFindFunction */ fts3FindFunctionMethod,
117389 /* xRename */ fts3RenameMethod,
117390 /* xSavepoint */ fts3SavepointMethod,
117391 /* xRelease */ fts3ReleaseMethod,
117392 /* xRollbackTo */ fts3RollbackToMethod,
117396 ** This function is registered as the module destructor (called when an
117397 ** FTS3 enabled database connection is closed). It frees the memory
117398 ** allocated for the tokenizer hash table.
117400 static void hashDestroy(void *p){
117401 Fts3Hash *pHash = (Fts3Hash *)p;
117402 sqlite3Fts3HashClear(pHash);
117403 sqlite3_free(pHash);
117407 ** The fts3 built-in tokenizers - "simple", "porter" and "icu"- are
117408 ** implemented in files fts3_tokenizer1.c, fts3_porter.c and fts3_icu.c
117409 ** respectively. The following three forward declarations are for functions
117410 ** declared in these files used to retrieve the respective implementations.
117412 ** Calling sqlite3Fts3SimpleTokenizerModule() sets the value pointed
117413 ** to by the argument to point to the "simple" tokenizer implementation.
117414 ** And so on.
117416 SQLITE_PRIVATE void sqlite3Fts3SimpleTokenizerModule(sqlite3_tokenizer_module const**ppModule);
117417 SQLITE_PRIVATE void sqlite3Fts3PorterTokenizerModule(sqlite3_tokenizer_module const**ppModule);
117418 #ifdef SQLITE_ENABLE_ICU
117419 SQLITE_PRIVATE void sqlite3Fts3IcuTokenizerModule(sqlite3_tokenizer_module const**ppModule);
117420 #endif
117423 ** Initialise the fts3 extension. If this extension is built as part
117424 ** of the sqlite library, then this function is called directly by
117425 ** SQLite. If fts3 is built as a dynamically loadable extension, this
117426 ** function is called by the sqlite3_extension_init() entry point.
117428 SQLITE_PRIVATE int sqlite3Fts3Init(sqlite3 *db){
117429 int rc = SQLITE_OK;
117430 Fts3Hash *pHash = 0;
117431 const sqlite3_tokenizer_module *pSimple = 0;
117432 const sqlite3_tokenizer_module *pPorter = 0;
117434 #ifdef SQLITE_ENABLE_ICU
117435 const sqlite3_tokenizer_module *pIcu = 0;
117436 sqlite3Fts3IcuTokenizerModule(&pIcu);
117437 #endif
117439 #ifdef SQLITE_TEST
117440 rc = sqlite3Fts3InitTerm(db);
117441 if( rc!=SQLITE_OK ) return rc;
117442 #endif
117444 rc = sqlite3Fts3InitAux(db);
117445 if( rc!=SQLITE_OK ) return rc;
117447 sqlite3Fts3SimpleTokenizerModule(&pSimple);
117448 sqlite3Fts3PorterTokenizerModule(&pPorter);
117450 /* Allocate and initialise the hash-table used to store tokenizers. */
117451 pHash = sqlite3_malloc(sizeof(Fts3Hash));
117452 if( !pHash ){
117453 rc = SQLITE_NOMEM;
117454 }else{
117455 sqlite3Fts3HashInit(pHash, FTS3_HASH_STRING, 1);
117458 /* Load the built-in tokenizers into the hash table */
117459 if( rc==SQLITE_OK ){
117460 if( sqlite3Fts3HashInsert(pHash, "simple", 7, (void *)pSimple)
117461 || sqlite3Fts3HashInsert(pHash, "porter", 7, (void *)pPorter)
117462 #ifdef SQLITE_ENABLE_ICU
117463 || (pIcu && sqlite3Fts3HashInsert(pHash, "icu", 4, (void *)pIcu))
117464 #endif
117466 rc = SQLITE_NOMEM;
117470 #ifdef SQLITE_TEST
117471 if( rc==SQLITE_OK ){
117472 rc = sqlite3Fts3ExprInitTestInterface(db);
117474 #endif
117476 /* Create the virtual table wrapper around the hash-table and overload
117477 ** the two scalar functions. If this is successful, register the
117478 ** module with sqlite.
117480 if( SQLITE_OK==rc
117481 && SQLITE_OK==(rc = sqlite3Fts3InitHashTable(db, pHash, "fts3_tokenizer"))
117482 && SQLITE_OK==(rc = sqlite3_overload_function(db, "snippet", -1))
117483 && SQLITE_OK==(rc = sqlite3_overload_function(db, "offsets", 1))
117484 && SQLITE_OK==(rc = sqlite3_overload_function(db, "matchinfo", 1))
117485 && SQLITE_OK==(rc = sqlite3_overload_function(db, "matchinfo", 2))
117486 && SQLITE_OK==(rc = sqlite3_overload_function(db, "optimize", 1))
117488 rc = sqlite3_create_module_v2(
117489 db, "fts3", &fts3Module, (void *)pHash, hashDestroy
117491 if( rc==SQLITE_OK ){
117492 rc = sqlite3_create_module_v2(
117493 db, "fts4", &fts3Module, (void *)pHash, 0
117496 return rc;
117499 /* An error has occurred. Delete the hash table and return the error code. */
117500 assert( rc!=SQLITE_OK );
117501 if( pHash ){
117502 sqlite3Fts3HashClear(pHash);
117503 sqlite3_free(pHash);
117505 return rc;
117509 ** Allocate an Fts3MultiSegReader for each token in the expression headed
117510 ** by pExpr.
117512 ** An Fts3SegReader object is a cursor that can seek or scan a range of
117513 ** entries within a single segment b-tree. An Fts3MultiSegReader uses multiple
117514 ** Fts3SegReader objects internally to provide an interface to seek or scan
117515 ** within the union of all segments of a b-tree. Hence the name.
117517 ** If the allocated Fts3MultiSegReader just seeks to a single entry in a
117518 ** segment b-tree (if the term is not a prefix or it is a prefix for which
117519 ** there exists prefix b-tree of the right length) then it may be traversed
117520 ** and merged incrementally. Otherwise, it has to be merged into an in-memory
117521 ** doclist and then traversed.
117523 static void fts3EvalAllocateReaders(
117524 Fts3Cursor *pCsr, /* FTS cursor handle */
117525 Fts3Expr *pExpr, /* Allocate readers for this expression */
117526 int *pnToken, /* OUT: Total number of tokens in phrase. */
117527 int *pnOr, /* OUT: Total number of OR nodes in expr. */
117528 int *pRc /* IN/OUT: Error code */
117530 if( pExpr && SQLITE_OK==*pRc ){
117531 if( pExpr->eType==FTSQUERY_PHRASE ){
117532 int i;
117533 int nToken = pExpr->pPhrase->nToken;
117534 *pnToken += nToken;
117535 for(i=0; i<nToken; i++){
117536 Fts3PhraseToken *pToken = &pExpr->pPhrase->aToken[i];
117537 int rc = fts3TermSegReaderCursor(pCsr,
117538 pToken->z, pToken->n, pToken->isPrefix, &pToken->pSegcsr
117540 if( rc!=SQLITE_OK ){
117541 *pRc = rc;
117542 return;
117545 assert( pExpr->pPhrase->iDoclistToken==0 );
117546 pExpr->pPhrase->iDoclistToken = -1;
117547 }else{
117548 *pnOr += (pExpr->eType==FTSQUERY_OR);
117549 fts3EvalAllocateReaders(pCsr, pExpr->pLeft, pnToken, pnOr, pRc);
117550 fts3EvalAllocateReaders(pCsr, pExpr->pRight, pnToken, pnOr, pRc);
117556 ** Arguments pList/nList contain the doclist for token iToken of phrase p.
117557 ** It is merged into the main doclist stored in p->doclist.aAll/nAll.
117559 ** This function assumes that pList points to a buffer allocated using
117560 ** sqlite3_malloc(). This function takes responsibility for eventually
117561 ** freeing the buffer.
117563 static void fts3EvalPhraseMergeToken(
117564 Fts3Table *pTab, /* FTS Table pointer */
117565 Fts3Phrase *p, /* Phrase to merge pList/nList into */
117566 int iToken, /* Token pList/nList corresponds to */
117567 char *pList, /* Pointer to doclist */
117568 int nList /* Number of bytes in pList */
117570 assert( iToken!=p->iDoclistToken );
117572 if( pList==0 ){
117573 sqlite3_free(p->doclist.aAll);
117574 p->doclist.aAll = 0;
117575 p->doclist.nAll = 0;
117578 else if( p->iDoclistToken<0 ){
117579 p->doclist.aAll = pList;
117580 p->doclist.nAll = nList;
117583 else if( p->doclist.aAll==0 ){
117584 sqlite3_free(pList);
117587 else {
117588 char *pLeft;
117589 char *pRight;
117590 int nLeft;
117591 int nRight;
117592 int nDiff;
117594 if( p->iDoclistToken<iToken ){
117595 pLeft = p->doclist.aAll;
117596 nLeft = p->doclist.nAll;
117597 pRight = pList;
117598 nRight = nList;
117599 nDiff = iToken - p->iDoclistToken;
117600 }else{
117601 pRight = p->doclist.aAll;
117602 nRight = p->doclist.nAll;
117603 pLeft = pList;
117604 nLeft = nList;
117605 nDiff = p->iDoclistToken - iToken;
117608 fts3DoclistPhraseMerge(pTab->bDescIdx, nDiff, pLeft, nLeft, pRight,&nRight);
117609 sqlite3_free(pLeft);
117610 p->doclist.aAll = pRight;
117611 p->doclist.nAll = nRight;
117614 if( iToken>p->iDoclistToken ) p->iDoclistToken = iToken;
117618 ** Load the doclist for phrase p into p->doclist.aAll/nAll. The loaded doclist
117619 ** does not take deferred tokens into account.
117621 ** SQLITE_OK is returned if no error occurs, otherwise an SQLite error code.
117623 static int fts3EvalPhraseLoad(
117624 Fts3Cursor *pCsr, /* FTS Cursor handle */
117625 Fts3Phrase *p /* Phrase object */
117627 Fts3Table *pTab = (Fts3Table *)pCsr->base.pVtab;
117628 int iToken;
117629 int rc = SQLITE_OK;
117631 for(iToken=0; rc==SQLITE_OK && iToken<p->nToken; iToken++){
117632 Fts3PhraseToken *pToken = &p->aToken[iToken];
117633 assert( pToken->pDeferred==0 || pToken->pSegcsr==0 );
117635 if( pToken->pSegcsr ){
117636 int nThis = 0;
117637 char *pThis = 0;
117638 rc = fts3TermSelect(pTab, pToken, p->iColumn, &nThis, &pThis);
117639 if( rc==SQLITE_OK ){
117640 fts3EvalPhraseMergeToken(pTab, p, iToken, pThis, nThis);
117643 assert( pToken->pSegcsr==0 );
117646 return rc;
117650 ** This function is called on each phrase after the position lists for
117651 ** any deferred tokens have been loaded into memory. It updates the phrases
117652 ** current position list to include only those positions that are really
117653 ** instances of the phrase (after considering deferred tokens). If this
117654 ** means that the phrase does not appear in the current row, doclist.pList
117655 ** and doclist.nList are both zeroed.
117657 ** SQLITE_OK is returned if no error occurs, otherwise an SQLite error code.
117659 static int fts3EvalDeferredPhrase(Fts3Cursor *pCsr, Fts3Phrase *pPhrase){
117660 int iToken; /* Used to iterate through phrase tokens */
117661 int rc = SQLITE_OK; /* Return code */
117662 char *aPoslist = 0; /* Position list for deferred tokens */
117663 int nPoslist = 0; /* Number of bytes in aPoslist */
117664 int iPrev = -1; /* Token number of previous deferred token */
117666 assert( pPhrase->doclist.bFreeList==0 );
117668 for(iToken=0; rc==SQLITE_OK && iToken<pPhrase->nToken; iToken++){
117669 Fts3PhraseToken *pToken = &pPhrase->aToken[iToken];
117670 Fts3DeferredToken *pDeferred = pToken->pDeferred;
117672 if( pDeferred ){
117673 char *pList;
117674 int nList;
117675 rc = sqlite3Fts3DeferredTokenList(pDeferred, &pList, &nList);
117676 if( rc!=SQLITE_OK ) return rc;
117678 if( pList==0 ){
117679 sqlite3_free(aPoslist);
117680 pPhrase->doclist.pList = 0;
117681 pPhrase->doclist.nList = 0;
117682 return SQLITE_OK;
117684 }else if( aPoslist==0 ){
117685 aPoslist = pList;
117686 nPoslist = nList;
117688 }else{
117689 char *aOut = pList;
117690 char *p1 = aPoslist;
117691 char *p2 = aOut;
117693 assert( iPrev>=0 );
117694 fts3PoslistPhraseMerge(&aOut, iToken-iPrev, 0, 1, &p1, &p2);
117695 sqlite3_free(aPoslist);
117696 aPoslist = pList;
117697 nPoslist = aOut - aPoslist;
117698 if( nPoslist==0 ){
117699 sqlite3_free(aPoslist);
117700 pPhrase->doclist.pList = 0;
117701 pPhrase->doclist.nList = 0;
117702 return SQLITE_OK;
117705 iPrev = iToken;
117709 if( iPrev>=0 ){
117710 int nMaxUndeferred = pPhrase->iDoclistToken;
117711 if( nMaxUndeferred<0 ){
117712 pPhrase->doclist.pList = aPoslist;
117713 pPhrase->doclist.nList = nPoslist;
117714 pPhrase->doclist.iDocid = pCsr->iPrevId;
117715 pPhrase->doclist.bFreeList = 1;
117716 }else{
117717 int nDistance;
117718 char *p1;
117719 char *p2;
117720 char *aOut;
117722 if( nMaxUndeferred>iPrev ){
117723 p1 = aPoslist;
117724 p2 = pPhrase->doclist.pList;
117725 nDistance = nMaxUndeferred - iPrev;
117726 }else{
117727 p1 = pPhrase->doclist.pList;
117728 p2 = aPoslist;
117729 nDistance = iPrev - nMaxUndeferred;
117732 aOut = (char *)sqlite3_malloc(nPoslist+8);
117733 if( !aOut ){
117734 sqlite3_free(aPoslist);
117735 return SQLITE_NOMEM;
117738 pPhrase->doclist.pList = aOut;
117739 if( fts3PoslistPhraseMerge(&aOut, nDistance, 0, 1, &p1, &p2) ){
117740 pPhrase->doclist.bFreeList = 1;
117741 pPhrase->doclist.nList = (aOut - pPhrase->doclist.pList);
117742 }else{
117743 sqlite3_free(aOut);
117744 pPhrase->doclist.pList = 0;
117745 pPhrase->doclist.nList = 0;
117747 sqlite3_free(aPoslist);
117751 return SQLITE_OK;
117755 ** This function is called for each Fts3Phrase in a full-text query
117756 ** expression to initialize the mechanism for returning rows. Once this
117757 ** function has been called successfully on an Fts3Phrase, it may be
117758 ** used with fts3EvalPhraseNext() to iterate through the matching docids.
117760 ** If parameter bOptOk is true, then the phrase may (or may not) use the
117761 ** incremental loading strategy. Otherwise, the entire doclist is loaded into
117762 ** memory within this call.
117764 ** SQLITE_OK is returned if no error occurs, otherwise an SQLite error code.
117766 static int fts3EvalPhraseStart(Fts3Cursor *pCsr, int bOptOk, Fts3Phrase *p){
117767 int rc; /* Error code */
117768 Fts3PhraseToken *pFirst = &p->aToken[0];
117769 Fts3Table *pTab = (Fts3Table *)pCsr->base.pVtab;
117771 if( pCsr->bDesc==pTab->bDescIdx
117772 && bOptOk==1
117773 && p->nToken==1
117774 && pFirst->pSegcsr
117775 && pFirst->pSegcsr->bLookup
117777 /* Use the incremental approach. */
117778 int iCol = (p->iColumn >= pTab->nColumn ? -1 : p->iColumn);
117779 rc = sqlite3Fts3MsrIncrStart(
117780 pTab, pFirst->pSegcsr, iCol, pFirst->z, pFirst->n);
117781 p->bIncr = 1;
117783 }else{
117784 /* Load the full doclist for the phrase into memory. */
117785 rc = fts3EvalPhraseLoad(pCsr, p);
117786 p->bIncr = 0;
117789 assert( rc!=SQLITE_OK || p->nToken<1 || p->aToken[0].pSegcsr==0 || p->bIncr );
117790 return rc;
117794 ** This function is used to iterate backwards (from the end to start)
117795 ** through doclists. It is used by this module to iterate through phrase
117796 ** doclists in reverse and by the fts3_write.c module to iterate through
117797 ** pending-terms lists when writing to databases with "order=desc".
117799 ** The doclist may be sorted in ascending (parameter bDescIdx==0) or
117800 ** descending (parameter bDescIdx==1) order of docid. Regardless, this
117801 ** function iterates from the end of the doclist to the beginning.
117803 SQLITE_PRIVATE void sqlite3Fts3DoclistPrev(
117804 int bDescIdx, /* True if the doclist is desc */
117805 char *aDoclist, /* Pointer to entire doclist */
117806 int nDoclist, /* Length of aDoclist in bytes */
117807 char **ppIter, /* IN/OUT: Iterator pointer */
117808 sqlite3_int64 *piDocid, /* IN/OUT: Docid pointer */
117809 int *pnList, /* IN/OUT: List length pointer */
117810 u8 *pbEof /* OUT: End-of-file flag */
117812 char *p = *ppIter;
117814 assert( nDoclist>0 );
117815 assert( *pbEof==0 );
117816 assert( p || *piDocid==0 );
117817 assert( !p || (p>aDoclist && p<&aDoclist[nDoclist]) );
117819 if( p==0 ){
117820 sqlite3_int64 iDocid = 0;
117821 char *pNext = 0;
117822 char *pDocid = aDoclist;
117823 char *pEnd = &aDoclist[nDoclist];
117824 int iMul = 1;
117826 while( pDocid<pEnd ){
117827 sqlite3_int64 iDelta;
117828 pDocid += sqlite3Fts3GetVarint(pDocid, &iDelta);
117829 iDocid += (iMul * iDelta);
117830 pNext = pDocid;
117831 fts3PoslistCopy(0, &pDocid);
117832 while( pDocid<pEnd && *pDocid==0 ) pDocid++;
117833 iMul = (bDescIdx ? -1 : 1);
117836 *pnList = pEnd - pNext;
117837 *ppIter = pNext;
117838 *piDocid = iDocid;
117839 }else{
117840 int iMul = (bDescIdx ? -1 : 1);
117841 sqlite3_int64 iDelta;
117842 fts3GetReverseVarint(&p, aDoclist, &iDelta);
117843 *piDocid -= (iMul * iDelta);
117845 if( p==aDoclist ){
117846 *pbEof = 1;
117847 }else{
117848 char *pSave = p;
117849 fts3ReversePoslist(aDoclist, &p);
117850 *pnList = (pSave - p);
117852 *ppIter = p;
117857 ** Attempt to move the phrase iterator to point to the next matching docid.
117858 ** If an error occurs, return an SQLite error code. Otherwise, return
117859 ** SQLITE_OK.
117861 ** If there is no "next" entry and no error occurs, then *pbEof is set to
117862 ** 1 before returning. Otherwise, if no error occurs and the iterator is
117863 ** successfully advanced, *pbEof is set to 0.
117865 static int fts3EvalPhraseNext(
117866 Fts3Cursor *pCsr, /* FTS Cursor handle */
117867 Fts3Phrase *p, /* Phrase object to advance to next docid */
117868 u8 *pbEof /* OUT: Set to 1 if EOF */
117870 int rc = SQLITE_OK;
117871 Fts3Doclist *pDL = &p->doclist;
117872 Fts3Table *pTab = (Fts3Table *)pCsr->base.pVtab;
117874 if( p->bIncr ){
117875 assert( p->nToken==1 );
117876 assert( pDL->pNextDocid==0 );
117877 rc = sqlite3Fts3MsrIncrNext(pTab, p->aToken[0].pSegcsr,
117878 &pDL->iDocid, &pDL->pList, &pDL->nList
117880 if( rc==SQLITE_OK && !pDL->pList ){
117881 *pbEof = 1;
117883 }else if( pCsr->bDesc!=pTab->bDescIdx && pDL->nAll ){
117884 sqlite3Fts3DoclistPrev(pTab->bDescIdx, pDL->aAll, pDL->nAll,
117885 &pDL->pNextDocid, &pDL->iDocid, &pDL->nList, pbEof
117887 pDL->pList = pDL->pNextDocid;
117888 }else{
117889 char *pIter; /* Used to iterate through aAll */
117890 char *pEnd = &pDL->aAll[pDL->nAll]; /* 1 byte past end of aAll */
117891 if( pDL->pNextDocid ){
117892 pIter = pDL->pNextDocid;
117893 }else{
117894 pIter = pDL->aAll;
117897 if( pIter>=pEnd ){
117898 /* We have already reached the end of this doclist. EOF. */
117899 *pbEof = 1;
117900 }else{
117901 sqlite3_int64 iDelta;
117902 pIter += sqlite3Fts3GetVarint(pIter, &iDelta);
117903 if( pTab->bDescIdx==0 || pDL->pNextDocid==0 ){
117904 pDL->iDocid += iDelta;
117905 }else{
117906 pDL->iDocid -= iDelta;
117908 pDL->pList = pIter;
117909 fts3PoslistCopy(0, &pIter);
117910 pDL->nList = (pIter - pDL->pList);
117912 /* pIter now points just past the 0x00 that terminates the position-
117913 ** list for document pDL->iDocid. However, if this position-list was
117914 ** edited in place by fts3EvalNearTrim(), then pIter may not actually
117915 ** point to the start of the next docid value. The following line deals
117916 ** with this case by advancing pIter past the zero-padding added by
117917 ** fts3EvalNearTrim(). */
117918 while( pIter<pEnd && *pIter==0 ) pIter++;
117920 pDL->pNextDocid = pIter;
117921 assert( pIter>=&pDL->aAll[pDL->nAll] || *pIter );
117922 *pbEof = 0;
117926 return rc;
117931 ** If *pRc is not SQLITE_OK when this function is called, it is a no-op.
117932 ** Otherwise, fts3EvalPhraseStart() is called on all phrases within the
117933 ** expression. Also the Fts3Expr.bDeferred variable is set to true for any
117934 ** expressions for which all descendent tokens are deferred.
117936 ** If parameter bOptOk is zero, then it is guaranteed that the
117937 ** Fts3Phrase.doclist.aAll/nAll variables contain the entire doclist for
117938 ** each phrase in the expression (subject to deferred token processing).
117939 ** Or, if bOptOk is non-zero, then one or more tokens within the expression
117940 ** may be loaded incrementally, meaning doclist.aAll/nAll is not available.
117942 ** If an error occurs within this function, *pRc is set to an SQLite error
117943 ** code before returning.
117945 static void fts3EvalStartReaders(
117946 Fts3Cursor *pCsr, /* FTS Cursor handle */
117947 Fts3Expr *pExpr, /* Expression to initialize phrases in */
117948 int bOptOk, /* True to enable incremental loading */
117949 int *pRc /* IN/OUT: Error code */
117951 if( pExpr && SQLITE_OK==*pRc ){
117952 if( pExpr->eType==FTSQUERY_PHRASE ){
117953 int i;
117954 int nToken = pExpr->pPhrase->nToken;
117955 for(i=0; i<nToken; i++){
117956 if( pExpr->pPhrase->aToken[i].pDeferred==0 ) break;
117958 pExpr->bDeferred = (i==nToken);
117959 *pRc = fts3EvalPhraseStart(pCsr, bOptOk, pExpr->pPhrase);
117960 }else{
117961 fts3EvalStartReaders(pCsr, pExpr->pLeft, bOptOk, pRc);
117962 fts3EvalStartReaders(pCsr, pExpr->pRight, bOptOk, pRc);
117963 pExpr->bDeferred = (pExpr->pLeft->bDeferred && pExpr->pRight->bDeferred);
117969 ** An array of the following structures is assembled as part of the process
117970 ** of selecting tokens to defer before the query starts executing (as part
117971 ** of the xFilter() method). There is one element in the array for each
117972 ** token in the FTS expression.
117974 ** Tokens are divided into AND/NEAR clusters. All tokens in a cluster belong
117975 ** to phrases that are connected only by AND and NEAR operators (not OR or
117976 ** NOT). When determining tokens to defer, each AND/NEAR cluster is considered
117977 ** separately. The root of a tokens AND/NEAR cluster is stored in
117978 ** Fts3TokenAndCost.pRoot.
117980 typedef struct Fts3TokenAndCost Fts3TokenAndCost;
117981 struct Fts3TokenAndCost {
117982 Fts3Phrase *pPhrase; /* The phrase the token belongs to */
117983 int iToken; /* Position of token in phrase */
117984 Fts3PhraseToken *pToken; /* The token itself */
117985 Fts3Expr *pRoot; /* Root of NEAR/AND cluster */
117986 int nOvfl; /* Number of overflow pages to load doclist */
117987 int iCol; /* The column the token must match */
117991 ** This function is used to populate an allocated Fts3TokenAndCost array.
117993 ** If *pRc is not SQLITE_OK when this function is called, it is a no-op.
117994 ** Otherwise, if an error occurs during execution, *pRc is set to an
117995 ** SQLite error code.
117997 static void fts3EvalTokenCosts(
117998 Fts3Cursor *pCsr, /* FTS Cursor handle */
117999 Fts3Expr *pRoot, /* Root of current AND/NEAR cluster */
118000 Fts3Expr *pExpr, /* Expression to consider */
118001 Fts3TokenAndCost **ppTC, /* Write new entries to *(*ppTC)++ */
118002 Fts3Expr ***ppOr, /* Write new OR root to *(*ppOr)++ */
118003 int *pRc /* IN/OUT: Error code */
118005 if( *pRc==SQLITE_OK && pExpr ){
118006 if( pExpr->eType==FTSQUERY_PHRASE ){
118007 Fts3Phrase *pPhrase = pExpr->pPhrase;
118008 int i;
118009 for(i=0; *pRc==SQLITE_OK && i<pPhrase->nToken; i++){
118010 Fts3TokenAndCost *pTC = (*ppTC)++;
118011 pTC->pPhrase = pPhrase;
118012 pTC->iToken = i;
118013 pTC->pRoot = pRoot;
118014 pTC->pToken = &pPhrase->aToken[i];
118015 pTC->iCol = pPhrase->iColumn;
118016 *pRc = sqlite3Fts3MsrOvfl(pCsr, pTC->pToken->pSegcsr, &pTC->nOvfl);
118018 }else if( pExpr->eType!=FTSQUERY_NOT ){
118019 if( pExpr->eType==FTSQUERY_OR ){
118020 pRoot = pExpr->pLeft;
118021 **ppOr = pRoot;
118022 (*ppOr)++;
118024 fts3EvalTokenCosts(pCsr, pRoot, pExpr->pLeft, ppTC, ppOr, pRc);
118025 if( pExpr->eType==FTSQUERY_OR ){
118026 pRoot = pExpr->pRight;
118027 **ppOr = pRoot;
118028 (*ppOr)++;
118030 fts3EvalTokenCosts(pCsr, pRoot, pExpr->pRight, ppTC, ppOr, pRc);
118036 ** Determine the average document (row) size in pages. If successful,
118037 ** write this value to *pnPage and return SQLITE_OK. Otherwise, return
118038 ** an SQLite error code.
118040 ** The average document size in pages is calculated by first calculating
118041 ** determining the average size in bytes, B. If B is less than the amount
118042 ** of data that will fit on a single leaf page of an intkey table in
118043 ** this database, then the average docsize is 1. Otherwise, it is 1 plus
118044 ** the number of overflow pages consumed by a record B bytes in size.
118046 static int fts3EvalAverageDocsize(Fts3Cursor *pCsr, int *pnPage){
118047 if( pCsr->nRowAvg==0 ){
118048 /* The average document size, which is required to calculate the cost
118049 ** of each doclist, has not yet been determined. Read the required
118050 ** data from the %_stat table to calculate it.
118052 ** Entry 0 of the %_stat table is a blob containing (nCol+1) FTS3
118053 ** varints, where nCol is the number of columns in the FTS3 table.
118054 ** The first varint is the number of documents currently stored in
118055 ** the table. The following nCol varints contain the total amount of
118056 ** data stored in all rows of each column of the table, from left
118057 ** to right.
118059 int rc;
118060 Fts3Table *p = (Fts3Table*)pCsr->base.pVtab;
118061 sqlite3_stmt *pStmt;
118062 sqlite3_int64 nDoc = 0;
118063 sqlite3_int64 nByte = 0;
118064 const char *pEnd;
118065 const char *a;
118067 rc = sqlite3Fts3SelectDoctotal(p, &pStmt);
118068 if( rc!=SQLITE_OK ) return rc;
118069 a = sqlite3_column_blob(pStmt, 0);
118070 assert( a );
118072 pEnd = &a[sqlite3_column_bytes(pStmt, 0)];
118073 a += sqlite3Fts3GetVarint(a, &nDoc);
118074 while( a<pEnd ){
118075 a += sqlite3Fts3GetVarint(a, &nByte);
118077 if( nDoc==0 || nByte==0 ){
118078 sqlite3_reset(pStmt);
118079 return SQLITE_CORRUPT_VTAB;
118082 pCsr->nDoc = nDoc;
118083 pCsr->nRowAvg = (int)(((nByte / nDoc) + p->nPgsz) / p->nPgsz);
118084 assert( pCsr->nRowAvg>0 );
118085 rc = sqlite3_reset(pStmt);
118086 if( rc!=SQLITE_OK ) return rc;
118089 *pnPage = pCsr->nRowAvg;
118090 return SQLITE_OK;
118094 ** This function is called to select the tokens (if any) that will be
118095 ** deferred. The array aTC[] has already been populated when this is
118096 ** called.
118098 ** This function is called once for each AND/NEAR cluster in the
118099 ** expression. Each invocation determines which tokens to defer within
118100 ** the cluster with root node pRoot. See comments above the definition
118101 ** of struct Fts3TokenAndCost for more details.
118103 ** If no error occurs, SQLITE_OK is returned and sqlite3Fts3DeferToken()
118104 ** called on each token to defer. Otherwise, an SQLite error code is
118105 ** returned.
118107 static int fts3EvalSelectDeferred(
118108 Fts3Cursor *pCsr, /* FTS Cursor handle */
118109 Fts3Expr *pRoot, /* Consider tokens with this root node */
118110 Fts3TokenAndCost *aTC, /* Array of expression tokens and costs */
118111 int nTC /* Number of entries in aTC[] */
118113 Fts3Table *pTab = (Fts3Table *)pCsr->base.pVtab;
118114 int nDocSize = 0; /* Number of pages per doc loaded */
118115 int rc = SQLITE_OK; /* Return code */
118116 int ii; /* Iterator variable for various purposes */
118117 int nOvfl = 0; /* Total overflow pages used by doclists */
118118 int nToken = 0; /* Total number of tokens in cluster */
118120 int nMinEst = 0; /* The minimum count for any phrase so far. */
118121 int nLoad4 = 1; /* (Phrases that will be loaded)^4. */
118123 /* Count the tokens in this AND/NEAR cluster. If none of the doclists
118124 ** associated with the tokens spill onto overflow pages, or if there is
118125 ** only 1 token, exit early. No tokens to defer in this case. */
118126 for(ii=0; ii<nTC; ii++){
118127 if( aTC[ii].pRoot==pRoot ){
118128 nOvfl += aTC[ii].nOvfl;
118129 nToken++;
118132 if( nOvfl==0 || nToken<2 ) return SQLITE_OK;
118134 /* Obtain the average docsize (in pages). */
118135 rc = fts3EvalAverageDocsize(pCsr, &nDocSize);
118136 assert( rc!=SQLITE_OK || nDocSize>0 );
118139 /* Iterate through all tokens in this AND/NEAR cluster, in ascending order
118140 ** of the number of overflow pages that will be loaded by the pager layer
118141 ** to retrieve the entire doclist for the token from the full-text index.
118142 ** Load the doclists for tokens that are either:
118144 ** a. The cheapest token in the entire query (i.e. the one visited by the
118145 ** first iteration of this loop), or
118147 ** b. Part of a multi-token phrase.
118149 ** After each token doclist is loaded, merge it with the others from the
118150 ** same phrase and count the number of documents that the merged doclist
118151 ** contains. Set variable "nMinEst" to the smallest number of documents in
118152 ** any phrase doclist for which 1 or more token doclists have been loaded.
118153 ** Let nOther be the number of other phrases for which it is certain that
118154 ** one or more tokens will not be deferred.
118156 ** Then, for each token, defer it if loading the doclist would result in
118157 ** loading N or more overflow pages into memory, where N is computed as:
118159 ** (nMinEst + 4^nOther - 1) / (4^nOther)
118161 for(ii=0; ii<nToken && rc==SQLITE_OK; ii++){
118162 int iTC; /* Used to iterate through aTC[] array. */
118163 Fts3TokenAndCost *pTC = 0; /* Set to cheapest remaining token. */
118165 /* Set pTC to point to the cheapest remaining token. */
118166 for(iTC=0; iTC<nTC; iTC++){
118167 if( aTC[iTC].pToken && aTC[iTC].pRoot==pRoot
118168 && (!pTC || aTC[iTC].nOvfl<pTC->nOvfl)
118170 pTC = &aTC[iTC];
118173 assert( pTC );
118175 if( ii && pTC->nOvfl>=((nMinEst+(nLoad4/4)-1)/(nLoad4/4))*nDocSize ){
118176 /* The number of overflow pages to load for this (and therefore all
118177 ** subsequent) tokens is greater than the estimated number of pages
118178 ** that will be loaded if all subsequent tokens are deferred.
118180 Fts3PhraseToken *pToken = pTC->pToken;
118181 rc = sqlite3Fts3DeferToken(pCsr, pToken, pTC->iCol);
118182 fts3SegReaderCursorFree(pToken->pSegcsr);
118183 pToken->pSegcsr = 0;
118184 }else{
118185 nLoad4 = nLoad4*4;
118186 if( ii==0 || pTC->pPhrase->nToken>1 ){
118187 /* Either this is the cheapest token in the entire query, or it is
118188 ** part of a multi-token phrase. Either way, the entire doclist will
118189 ** (eventually) be loaded into memory. It may as well be now. */
118190 Fts3PhraseToken *pToken = pTC->pToken;
118191 int nList = 0;
118192 char *pList = 0;
118193 rc = fts3TermSelect(pTab, pToken, pTC->iCol, &nList, &pList);
118194 assert( rc==SQLITE_OK || pList==0 );
118195 if( rc==SQLITE_OK ){
118196 int nCount;
118197 fts3EvalPhraseMergeToken(pTab, pTC->pPhrase, pTC->iToken,pList,nList);
118198 nCount = fts3DoclistCountDocids(
118199 pTC->pPhrase->doclist.aAll, pTC->pPhrase->doclist.nAll
118201 if( ii==0 || nCount<nMinEst ) nMinEst = nCount;
118205 pTC->pToken = 0;
118208 return rc;
118212 ** This function is called from within the xFilter method. It initializes
118213 ** the full-text query currently stored in pCsr->pExpr. To iterate through
118214 ** the results of a query, the caller does:
118216 ** fts3EvalStart(pCsr);
118217 ** while( 1 ){
118218 ** fts3EvalNext(pCsr);
118219 ** if( pCsr->bEof ) break;
118220 ** ... return row pCsr->iPrevId to the caller ...
118223 static int fts3EvalStart(Fts3Cursor *pCsr){
118224 Fts3Table *pTab = (Fts3Table *)pCsr->base.pVtab;
118225 int rc = SQLITE_OK;
118226 int nToken = 0;
118227 int nOr = 0;
118229 /* Allocate a MultiSegReader for each token in the expression. */
118230 fts3EvalAllocateReaders(pCsr, pCsr->pExpr, &nToken, &nOr, &rc);
118232 /* Determine which, if any, tokens in the expression should be deferred. */
118233 if( rc==SQLITE_OK && nToken>1 && pTab->bHasStat ){
118234 Fts3TokenAndCost *aTC;
118235 Fts3Expr **apOr;
118236 aTC = (Fts3TokenAndCost *)sqlite3_malloc(
118237 sizeof(Fts3TokenAndCost) * nToken
118238 + sizeof(Fts3Expr *) * nOr * 2
118240 apOr = (Fts3Expr **)&aTC[nToken];
118242 if( !aTC ){
118243 rc = SQLITE_NOMEM;
118244 }else{
118245 int ii;
118246 Fts3TokenAndCost *pTC = aTC;
118247 Fts3Expr **ppOr = apOr;
118249 fts3EvalTokenCosts(pCsr, 0, pCsr->pExpr, &pTC, &ppOr, &rc);
118250 nToken = pTC-aTC;
118251 nOr = ppOr-apOr;
118253 if( rc==SQLITE_OK ){
118254 rc = fts3EvalSelectDeferred(pCsr, 0, aTC, nToken);
118255 for(ii=0; rc==SQLITE_OK && ii<nOr; ii++){
118256 rc = fts3EvalSelectDeferred(pCsr, apOr[ii], aTC, nToken);
118260 sqlite3_free(aTC);
118264 fts3EvalStartReaders(pCsr, pCsr->pExpr, 1, &rc);
118265 return rc;
118269 ** Invalidate the current position list for phrase pPhrase.
118271 static void fts3EvalInvalidatePoslist(Fts3Phrase *pPhrase){
118272 if( pPhrase->doclist.bFreeList ){
118273 sqlite3_free(pPhrase->doclist.pList);
118275 pPhrase->doclist.pList = 0;
118276 pPhrase->doclist.nList = 0;
118277 pPhrase->doclist.bFreeList = 0;
118281 ** This function is called to edit the position list associated with
118282 ** the phrase object passed as the fifth argument according to a NEAR
118283 ** condition. For example:
118285 ** abc NEAR/5 "def ghi"
118287 ** Parameter nNear is passed the NEAR distance of the expression (5 in
118288 ** the example above). When this function is called, *paPoslist points to
118289 ** the position list, and *pnToken is the number of phrase tokens in, the
118290 ** phrase on the other side of the NEAR operator to pPhrase. For example,
118291 ** if pPhrase refers to the "def ghi" phrase, then *paPoslist points to
118292 ** the position list associated with phrase "abc".
118294 ** All positions in the pPhrase position list that are not sufficiently
118295 ** close to a position in the *paPoslist position list are removed. If this
118296 ** leaves 0 positions, zero is returned. Otherwise, non-zero.
118298 ** Before returning, *paPoslist is set to point to the position lsit
118299 ** associated with pPhrase. And *pnToken is set to the number of tokens in
118300 ** pPhrase.
118302 static int fts3EvalNearTrim(
118303 int nNear, /* NEAR distance. As in "NEAR/nNear". */
118304 char *aTmp, /* Temporary space to use */
118305 char **paPoslist, /* IN/OUT: Position list */
118306 int *pnToken, /* IN/OUT: Tokens in phrase of *paPoslist */
118307 Fts3Phrase *pPhrase /* The phrase object to trim the doclist of */
118309 int nParam1 = nNear + pPhrase->nToken;
118310 int nParam2 = nNear + *pnToken;
118311 int nNew;
118312 char *p2;
118313 char *pOut;
118314 int res;
118316 assert( pPhrase->doclist.pList );
118318 p2 = pOut = pPhrase->doclist.pList;
118319 res = fts3PoslistNearMerge(
118320 &pOut, aTmp, nParam1, nParam2, paPoslist, &p2
118322 if( res ){
118323 nNew = (pOut - pPhrase->doclist.pList) - 1;
118324 assert( pPhrase->doclist.pList[nNew]=='\0' );
118325 assert( nNew<=pPhrase->doclist.nList && nNew>0 );
118326 memset(&pPhrase->doclist.pList[nNew], 0, pPhrase->doclist.nList - nNew);
118327 pPhrase->doclist.nList = nNew;
118328 *paPoslist = pPhrase->doclist.pList;
118329 *pnToken = pPhrase->nToken;
118332 return res;
118336 ** This function is a no-op if *pRc is other than SQLITE_OK when it is called.
118337 ** Otherwise, it advances the expression passed as the second argument to
118338 ** point to the next matching row in the database. Expressions iterate through
118339 ** matching rows in docid order. Ascending order if Fts3Cursor.bDesc is zero,
118340 ** or descending if it is non-zero.
118342 ** If an error occurs, *pRc is set to an SQLite error code. Otherwise, if
118343 ** successful, the following variables in pExpr are set:
118345 ** Fts3Expr.bEof (non-zero if EOF - there is no next row)
118346 ** Fts3Expr.iDocid (valid if bEof==0. The docid of the next row)
118348 ** If the expression is of type FTSQUERY_PHRASE, and the expression is not
118349 ** at EOF, then the following variables are populated with the position list
118350 ** for the phrase for the visited row:
118352 ** FTs3Expr.pPhrase->doclist.nList (length of pList in bytes)
118353 ** FTs3Expr.pPhrase->doclist.pList (pointer to position list)
118355 ** It says above that this function advances the expression to the next
118356 ** matching row. This is usually true, but there are the following exceptions:
118358 ** 1. Deferred tokens are not taken into account. If a phrase consists
118359 ** entirely of deferred tokens, it is assumed to match every row in
118360 ** the db. In this case the position-list is not populated at all.
118362 ** Or, if a phrase contains one or more deferred tokens and one or
118363 ** more non-deferred tokens, then the expression is advanced to the
118364 ** next possible match, considering only non-deferred tokens. In other
118365 ** words, if the phrase is "A B C", and "B" is deferred, the expression
118366 ** is advanced to the next row that contains an instance of "A * C",
118367 ** where "*" may match any single token. The position list in this case
118368 ** is populated as for "A * C" before returning.
118370 ** 2. NEAR is treated as AND. If the expression is "x NEAR y", it is
118371 ** advanced to point to the next row that matches "x AND y".
118373 ** See fts3EvalTestDeferredAndNear() for details on testing if a row is
118374 ** really a match, taking into account deferred tokens and NEAR operators.
118376 static void fts3EvalNextRow(
118377 Fts3Cursor *pCsr, /* FTS Cursor handle */
118378 Fts3Expr *pExpr, /* Expr. to advance to next matching row */
118379 int *pRc /* IN/OUT: Error code */
118381 if( *pRc==SQLITE_OK ){
118382 int bDescDoclist = pCsr->bDesc; /* Used by DOCID_CMP() macro */
118383 assert( pExpr->bEof==0 );
118384 pExpr->bStart = 1;
118386 switch( pExpr->eType ){
118387 case FTSQUERY_NEAR:
118388 case FTSQUERY_AND: {
118389 Fts3Expr *pLeft = pExpr->pLeft;
118390 Fts3Expr *pRight = pExpr->pRight;
118391 assert( !pLeft->bDeferred || !pRight->bDeferred );
118393 if( pLeft->bDeferred ){
118394 /* LHS is entirely deferred. So we assume it matches every row.
118395 ** Advance the RHS iterator to find the next row visited. */
118396 fts3EvalNextRow(pCsr, pRight, pRc);
118397 pExpr->iDocid = pRight->iDocid;
118398 pExpr->bEof = pRight->bEof;
118399 }else if( pRight->bDeferred ){
118400 /* RHS is entirely deferred. So we assume it matches every row.
118401 ** Advance the LHS iterator to find the next row visited. */
118402 fts3EvalNextRow(pCsr, pLeft, pRc);
118403 pExpr->iDocid = pLeft->iDocid;
118404 pExpr->bEof = pLeft->bEof;
118405 }else{
118406 /* Neither the RHS or LHS are deferred. */
118407 fts3EvalNextRow(pCsr, pLeft, pRc);
118408 fts3EvalNextRow(pCsr, pRight, pRc);
118409 while( !pLeft->bEof && !pRight->bEof && *pRc==SQLITE_OK ){
118410 sqlite3_int64 iDiff = DOCID_CMP(pLeft->iDocid, pRight->iDocid);
118411 if( iDiff==0 ) break;
118412 if( iDiff<0 ){
118413 fts3EvalNextRow(pCsr, pLeft, pRc);
118414 }else{
118415 fts3EvalNextRow(pCsr, pRight, pRc);
118418 pExpr->iDocid = pLeft->iDocid;
118419 pExpr->bEof = (pLeft->bEof || pRight->bEof);
118421 break;
118424 case FTSQUERY_OR: {
118425 Fts3Expr *pLeft = pExpr->pLeft;
118426 Fts3Expr *pRight = pExpr->pRight;
118427 sqlite3_int64 iCmp = DOCID_CMP(pLeft->iDocid, pRight->iDocid);
118429 assert( pLeft->bStart || pLeft->iDocid==pRight->iDocid );
118430 assert( pRight->bStart || pLeft->iDocid==pRight->iDocid );
118432 if( pRight->bEof || (pLeft->bEof==0 && iCmp<0) ){
118433 fts3EvalNextRow(pCsr, pLeft, pRc);
118434 }else if( pLeft->bEof || (pRight->bEof==0 && iCmp>0) ){
118435 fts3EvalNextRow(pCsr, pRight, pRc);
118436 }else{
118437 fts3EvalNextRow(pCsr, pLeft, pRc);
118438 fts3EvalNextRow(pCsr, pRight, pRc);
118441 pExpr->bEof = (pLeft->bEof && pRight->bEof);
118442 iCmp = DOCID_CMP(pLeft->iDocid, pRight->iDocid);
118443 if( pRight->bEof || (pLeft->bEof==0 && iCmp<0) ){
118444 pExpr->iDocid = pLeft->iDocid;
118445 }else{
118446 pExpr->iDocid = pRight->iDocid;
118449 break;
118452 case FTSQUERY_NOT: {
118453 Fts3Expr *pLeft = pExpr->pLeft;
118454 Fts3Expr *pRight = pExpr->pRight;
118456 if( pRight->bStart==0 ){
118457 fts3EvalNextRow(pCsr, pRight, pRc);
118458 assert( *pRc!=SQLITE_OK || pRight->bStart );
118461 fts3EvalNextRow(pCsr, pLeft, pRc);
118462 if( pLeft->bEof==0 ){
118463 while( !*pRc
118464 && !pRight->bEof
118465 && DOCID_CMP(pLeft->iDocid, pRight->iDocid)>0
118467 fts3EvalNextRow(pCsr, pRight, pRc);
118470 pExpr->iDocid = pLeft->iDocid;
118471 pExpr->bEof = pLeft->bEof;
118472 break;
118475 default: {
118476 Fts3Phrase *pPhrase = pExpr->pPhrase;
118477 fts3EvalInvalidatePoslist(pPhrase);
118478 *pRc = fts3EvalPhraseNext(pCsr, pPhrase, &pExpr->bEof);
118479 pExpr->iDocid = pPhrase->doclist.iDocid;
118480 break;
118487 ** If *pRc is not SQLITE_OK, or if pExpr is not the root node of a NEAR
118488 ** cluster, then this function returns 1 immediately.
118490 ** Otherwise, it checks if the current row really does match the NEAR
118491 ** expression, using the data currently stored in the position lists
118492 ** (Fts3Expr->pPhrase.doclist.pList/nList) for each phrase in the expression.
118494 ** If the current row is a match, the position list associated with each
118495 ** phrase in the NEAR expression is edited in place to contain only those
118496 ** phrase instances sufficiently close to their peers to satisfy all NEAR
118497 ** constraints. In this case it returns 1. If the NEAR expression does not
118498 ** match the current row, 0 is returned. The position lists may or may not
118499 ** be edited if 0 is returned.
118501 static int fts3EvalNearTest(Fts3Expr *pExpr, int *pRc){
118502 int res = 1;
118504 /* The following block runs if pExpr is the root of a NEAR query.
118505 ** For example, the query:
118507 ** "w" NEAR "x" NEAR "y" NEAR "z"
118509 ** which is represented in tree form as:
118512 ** +--NEAR--+ <-- root of NEAR query
118513 ** | |
118514 ** +--NEAR--+ "z"
118515 ** | |
118516 ** +--NEAR--+ "y"
118517 ** | |
118518 ** "w" "x"
118520 ** The right-hand child of a NEAR node is always a phrase. The
118521 ** left-hand child may be either a phrase or a NEAR node. There are
118522 ** no exceptions to this - it's the way the parser in fts3_expr.c works.
118524 if( *pRc==SQLITE_OK
118525 && pExpr->eType==FTSQUERY_NEAR
118526 && pExpr->bEof==0
118527 && (pExpr->pParent==0 || pExpr->pParent->eType!=FTSQUERY_NEAR)
118529 Fts3Expr *p;
118530 int nTmp = 0; /* Bytes of temp space */
118531 char *aTmp; /* Temp space for PoslistNearMerge() */
118533 /* Allocate temporary working space. */
118534 for(p=pExpr; p->pLeft; p=p->pLeft){
118535 nTmp += p->pRight->pPhrase->doclist.nList;
118537 nTmp += p->pPhrase->doclist.nList;
118538 aTmp = sqlite3_malloc(nTmp*2);
118539 if( !aTmp ){
118540 *pRc = SQLITE_NOMEM;
118541 res = 0;
118542 }else{
118543 char *aPoslist = p->pPhrase->doclist.pList;
118544 int nToken = p->pPhrase->nToken;
118546 for(p=p->pParent;res && p && p->eType==FTSQUERY_NEAR; p=p->pParent){
118547 Fts3Phrase *pPhrase = p->pRight->pPhrase;
118548 int nNear = p->nNear;
118549 res = fts3EvalNearTrim(nNear, aTmp, &aPoslist, &nToken, pPhrase);
118552 aPoslist = pExpr->pRight->pPhrase->doclist.pList;
118553 nToken = pExpr->pRight->pPhrase->nToken;
118554 for(p=pExpr->pLeft; p && res; p=p->pLeft){
118555 int nNear = p->pParent->nNear;
118556 Fts3Phrase *pPhrase = (
118557 p->eType==FTSQUERY_NEAR ? p->pRight->pPhrase : p->pPhrase
118559 res = fts3EvalNearTrim(nNear, aTmp, &aPoslist, &nToken, pPhrase);
118563 sqlite3_free(aTmp);
118566 return res;
118570 ** This function is a helper function for fts3EvalTestDeferredAndNear().
118571 ** Assuming no error occurs or has occurred, It returns non-zero if the
118572 ** expression passed as the second argument matches the row that pCsr
118573 ** currently points to, or zero if it does not.
118575 ** If *pRc is not SQLITE_OK when this function is called, it is a no-op.
118576 ** If an error occurs during execution of this function, *pRc is set to
118577 ** the appropriate SQLite error code. In this case the returned value is
118578 ** undefined.
118580 static int fts3EvalTestExpr(
118581 Fts3Cursor *pCsr, /* FTS cursor handle */
118582 Fts3Expr *pExpr, /* Expr to test. May or may not be root. */
118583 int *pRc /* IN/OUT: Error code */
118585 int bHit = 1; /* Return value */
118586 if( *pRc==SQLITE_OK ){
118587 switch( pExpr->eType ){
118588 case FTSQUERY_NEAR:
118589 case FTSQUERY_AND:
118590 bHit = (
118591 fts3EvalTestExpr(pCsr, pExpr->pLeft, pRc)
118592 && fts3EvalTestExpr(pCsr, pExpr->pRight, pRc)
118593 && fts3EvalNearTest(pExpr, pRc)
118596 /* If the NEAR expression does not match any rows, zero the doclist for
118597 ** all phrases involved in the NEAR. This is because the snippet(),
118598 ** offsets() and matchinfo() functions are not supposed to recognize
118599 ** any instances of phrases that are part of unmatched NEAR queries.
118600 ** For example if this expression:
118602 ** ... MATCH 'a OR (b NEAR c)'
118604 ** is matched against a row containing:
118606 ** 'a b d e'
118608 ** then any snippet() should ony highlight the "a" term, not the "b"
118609 ** (as "b" is part of a non-matching NEAR clause).
118611 if( bHit==0
118612 && pExpr->eType==FTSQUERY_NEAR
118613 && (pExpr->pParent==0 || pExpr->pParent->eType!=FTSQUERY_NEAR)
118615 Fts3Expr *p;
118616 for(p=pExpr; p->pPhrase==0; p=p->pLeft){
118617 if( p->pRight->iDocid==pCsr->iPrevId ){
118618 fts3EvalInvalidatePoslist(p->pRight->pPhrase);
118621 if( p->iDocid==pCsr->iPrevId ){
118622 fts3EvalInvalidatePoslist(p->pPhrase);
118626 break;
118628 case FTSQUERY_OR: {
118629 int bHit1 = fts3EvalTestExpr(pCsr, pExpr->pLeft, pRc);
118630 int bHit2 = fts3EvalTestExpr(pCsr, pExpr->pRight, pRc);
118631 bHit = bHit1 || bHit2;
118632 break;
118635 case FTSQUERY_NOT:
118636 bHit = (
118637 fts3EvalTestExpr(pCsr, pExpr->pLeft, pRc)
118638 && !fts3EvalTestExpr(pCsr, pExpr->pRight, pRc)
118640 break;
118642 default: {
118643 if( pCsr->pDeferred
118644 && (pExpr->iDocid==pCsr->iPrevId || pExpr->bDeferred)
118646 Fts3Phrase *pPhrase = pExpr->pPhrase;
118647 assert( pExpr->bDeferred || pPhrase->doclist.bFreeList==0 );
118648 if( pExpr->bDeferred ){
118649 fts3EvalInvalidatePoslist(pPhrase);
118651 *pRc = fts3EvalDeferredPhrase(pCsr, pPhrase);
118652 bHit = (pPhrase->doclist.pList!=0);
118653 pExpr->iDocid = pCsr->iPrevId;
118654 }else{
118655 bHit = (pExpr->bEof==0 && pExpr->iDocid==pCsr->iPrevId);
118657 break;
118661 return bHit;
118665 ** This function is called as the second part of each xNext operation when
118666 ** iterating through the results of a full-text query. At this point the
118667 ** cursor points to a row that matches the query expression, with the
118668 ** following caveats:
118670 ** * Up until this point, "NEAR" operators in the expression have been
118671 ** treated as "AND".
118673 ** * Deferred tokens have not yet been considered.
118675 ** If *pRc is not SQLITE_OK when this function is called, it immediately
118676 ** returns 0. Otherwise, it tests whether or not after considering NEAR
118677 ** operators and deferred tokens the current row is still a match for the
118678 ** expression. It returns 1 if both of the following are true:
118680 ** 1. *pRc is SQLITE_OK when this function returns, and
118682 ** 2. After scanning the current FTS table row for the deferred tokens,
118683 ** it is determined that the row does *not* match the query.
118685 ** Or, if no error occurs and it seems the current row does match the FTS
118686 ** query, return 0.
118688 static int fts3EvalTestDeferredAndNear(Fts3Cursor *pCsr, int *pRc){
118689 int rc = *pRc;
118690 int bMiss = 0;
118691 if( rc==SQLITE_OK ){
118693 /* If there are one or more deferred tokens, load the current row into
118694 ** memory and scan it to determine the position list for each deferred
118695 ** token. Then, see if this row is really a match, considering deferred
118696 ** tokens and NEAR operators (neither of which were taken into account
118697 ** earlier, by fts3EvalNextRow()).
118699 if( pCsr->pDeferred ){
118700 rc = fts3CursorSeek(0, pCsr);
118701 if( rc==SQLITE_OK ){
118702 rc = sqlite3Fts3CacheDeferredDoclists(pCsr);
118705 bMiss = (0==fts3EvalTestExpr(pCsr, pCsr->pExpr, &rc));
118707 /* Free the position-lists accumulated for each deferred token above. */
118708 sqlite3Fts3FreeDeferredDoclists(pCsr);
118709 *pRc = rc;
118711 return (rc==SQLITE_OK && bMiss);
118715 ** Advance to the next document that matches the FTS expression in
118716 ** Fts3Cursor.pExpr.
118718 static int fts3EvalNext(Fts3Cursor *pCsr){
118719 int rc = SQLITE_OK; /* Return Code */
118720 Fts3Expr *pExpr = pCsr->pExpr;
118721 assert( pCsr->isEof==0 );
118722 if( pExpr==0 ){
118723 pCsr->isEof = 1;
118724 }else{
118726 if( pCsr->isRequireSeek==0 ){
118727 sqlite3_reset(pCsr->pStmt);
118729 assert( sqlite3_data_count(pCsr->pStmt)==0 );
118730 fts3EvalNextRow(pCsr, pExpr, &rc);
118731 pCsr->isEof = pExpr->bEof;
118732 pCsr->isRequireSeek = 1;
118733 pCsr->isMatchinfoNeeded = 1;
118734 pCsr->iPrevId = pExpr->iDocid;
118735 }while( pCsr->isEof==0 && fts3EvalTestDeferredAndNear(pCsr, &rc) );
118737 return rc;
118741 ** Restart interation for expression pExpr so that the next call to
118742 ** fts3EvalNext() visits the first row. Do not allow incremental
118743 ** loading or merging of phrase doclists for this iteration.
118745 ** If *pRc is other than SQLITE_OK when this function is called, it is
118746 ** a no-op. If an error occurs within this function, *pRc is set to an
118747 ** SQLite error code before returning.
118749 static void fts3EvalRestart(
118750 Fts3Cursor *pCsr,
118751 Fts3Expr *pExpr,
118752 int *pRc
118754 if( pExpr && *pRc==SQLITE_OK ){
118755 Fts3Phrase *pPhrase = pExpr->pPhrase;
118757 if( pPhrase ){
118758 fts3EvalInvalidatePoslist(pPhrase);
118759 if( pPhrase->bIncr ){
118760 assert( pPhrase->nToken==1 );
118761 assert( pPhrase->aToken[0].pSegcsr );
118762 sqlite3Fts3MsrIncrRestart(pPhrase->aToken[0].pSegcsr);
118763 *pRc = fts3EvalPhraseStart(pCsr, 0, pPhrase);
118766 pPhrase->doclist.pNextDocid = 0;
118767 pPhrase->doclist.iDocid = 0;
118770 pExpr->iDocid = 0;
118771 pExpr->bEof = 0;
118772 pExpr->bStart = 0;
118774 fts3EvalRestart(pCsr, pExpr->pLeft, pRc);
118775 fts3EvalRestart(pCsr, pExpr->pRight, pRc);
118780 ** After allocating the Fts3Expr.aMI[] array for each phrase in the
118781 ** expression rooted at pExpr, the cursor iterates through all rows matched
118782 ** by pExpr, calling this function for each row. This function increments
118783 ** the values in Fts3Expr.aMI[] according to the position-list currently
118784 ** found in Fts3Expr.pPhrase->doclist.pList for each of the phrase
118785 ** expression nodes.
118787 static void fts3EvalUpdateCounts(Fts3Expr *pExpr){
118788 if( pExpr ){
118789 Fts3Phrase *pPhrase = pExpr->pPhrase;
118790 if( pPhrase && pPhrase->doclist.pList ){
118791 int iCol = 0;
118792 char *p = pPhrase->doclist.pList;
118794 assert( *p );
118795 while( 1 ){
118796 u8 c = 0;
118797 int iCnt = 0;
118798 while( 0xFE & (*p | c) ){
118799 if( (c&0x80)==0 ) iCnt++;
118800 c = *p++ & 0x80;
118803 /* aMI[iCol*3 + 1] = Number of occurrences
118804 ** aMI[iCol*3 + 2] = Number of rows containing at least one instance
118806 pExpr->aMI[iCol*3 + 1] += iCnt;
118807 pExpr->aMI[iCol*3 + 2] += (iCnt>0);
118808 if( *p==0x00 ) break;
118810 p += sqlite3Fts3GetVarint32(p, &iCol);
118814 fts3EvalUpdateCounts(pExpr->pLeft);
118815 fts3EvalUpdateCounts(pExpr->pRight);
118820 ** Expression pExpr must be of type FTSQUERY_PHRASE.
118822 ** If it is not already allocated and populated, this function allocates and
118823 ** populates the Fts3Expr.aMI[] array for expression pExpr. If pExpr is part
118824 ** of a NEAR expression, then it also allocates and populates the same array
118825 ** for all other phrases that are part of the NEAR expression.
118827 ** SQLITE_OK is returned if the aMI[] array is successfully allocated and
118828 ** populated. Otherwise, if an error occurs, an SQLite error code is returned.
118830 static int fts3EvalGatherStats(
118831 Fts3Cursor *pCsr, /* Cursor object */
118832 Fts3Expr *pExpr /* FTSQUERY_PHRASE expression */
118834 int rc = SQLITE_OK; /* Return code */
118836 assert( pExpr->eType==FTSQUERY_PHRASE );
118837 if( pExpr->aMI==0 ){
118838 Fts3Table *pTab = (Fts3Table *)pCsr->base.pVtab;
118839 Fts3Expr *pRoot; /* Root of NEAR expression */
118840 Fts3Expr *p; /* Iterator used for several purposes */
118842 sqlite3_int64 iPrevId = pCsr->iPrevId;
118843 sqlite3_int64 iDocid;
118844 u8 bEof;
118846 /* Find the root of the NEAR expression */
118847 pRoot = pExpr;
118848 while( pRoot->pParent && pRoot->pParent->eType==FTSQUERY_NEAR ){
118849 pRoot = pRoot->pParent;
118851 iDocid = pRoot->iDocid;
118852 bEof = pRoot->bEof;
118853 assert( pRoot->bStart );
118855 /* Allocate space for the aMSI[] array of each FTSQUERY_PHRASE node */
118856 for(p=pRoot; p; p=p->pLeft){
118857 Fts3Expr *pE = (p->eType==FTSQUERY_PHRASE?p:p->pRight);
118858 assert( pE->aMI==0 );
118859 pE->aMI = (u32 *)sqlite3_malloc(pTab->nColumn * 3 * sizeof(u32));
118860 if( !pE->aMI ) return SQLITE_NOMEM;
118861 memset(pE->aMI, 0, pTab->nColumn * 3 * sizeof(u32));
118864 fts3EvalRestart(pCsr, pRoot, &rc);
118866 while( pCsr->isEof==0 && rc==SQLITE_OK ){
118869 /* Ensure the %_content statement is reset. */
118870 if( pCsr->isRequireSeek==0 ) sqlite3_reset(pCsr->pStmt);
118871 assert( sqlite3_data_count(pCsr->pStmt)==0 );
118873 /* Advance to the next document */
118874 fts3EvalNextRow(pCsr, pRoot, &rc);
118875 pCsr->isEof = pRoot->bEof;
118876 pCsr->isRequireSeek = 1;
118877 pCsr->isMatchinfoNeeded = 1;
118878 pCsr->iPrevId = pRoot->iDocid;
118879 }while( pCsr->isEof==0
118880 && pRoot->eType==FTSQUERY_NEAR
118881 && fts3EvalTestDeferredAndNear(pCsr, &rc)
118884 if( rc==SQLITE_OK && pCsr->isEof==0 ){
118885 fts3EvalUpdateCounts(pRoot);
118889 pCsr->isEof = 0;
118890 pCsr->iPrevId = iPrevId;
118892 if( bEof ){
118893 pRoot->bEof = bEof;
118894 }else{
118895 /* Caution: pRoot may iterate through docids in ascending or descending
118896 ** order. For this reason, even though it seems more defensive, the
118897 ** do loop can not be written:
118899 ** do {...} while( pRoot->iDocid<iDocid && rc==SQLITE_OK );
118901 fts3EvalRestart(pCsr, pRoot, &rc);
118903 fts3EvalNextRow(pCsr, pRoot, &rc);
118904 assert( pRoot->bEof==0 );
118905 }while( pRoot->iDocid!=iDocid && rc==SQLITE_OK );
118906 fts3EvalTestDeferredAndNear(pCsr, &rc);
118909 return rc;
118913 ** This function is used by the matchinfo() module to query a phrase
118914 ** expression node for the following information:
118916 ** 1. The total number of occurrences of the phrase in each column of
118917 ** the FTS table (considering all rows), and
118919 ** 2. For each column, the number of rows in the table for which the
118920 ** column contains at least one instance of the phrase.
118922 ** If no error occurs, SQLITE_OK is returned and the values for each column
118923 ** written into the array aiOut as follows:
118925 ** aiOut[iCol*3 + 1] = Number of occurrences
118926 ** aiOut[iCol*3 + 2] = Number of rows containing at least one instance
118928 ** Caveats:
118930 ** * If a phrase consists entirely of deferred tokens, then all output
118931 ** values are set to the number of documents in the table. In other
118932 ** words we assume that very common tokens occur exactly once in each
118933 ** column of each row of the table.
118935 ** * If a phrase contains some deferred tokens (and some non-deferred
118936 ** tokens), count the potential occurrence identified by considering
118937 ** the non-deferred tokens instead of actual phrase occurrences.
118939 ** * If the phrase is part of a NEAR expression, then only phrase instances
118940 ** that meet the NEAR constraint are included in the counts.
118942 SQLITE_PRIVATE int sqlite3Fts3EvalPhraseStats(
118943 Fts3Cursor *pCsr, /* FTS cursor handle */
118944 Fts3Expr *pExpr, /* Phrase expression */
118945 u32 *aiOut /* Array to write results into (see above) */
118947 Fts3Table *pTab = (Fts3Table *)pCsr->base.pVtab;
118948 int rc = SQLITE_OK;
118949 int iCol;
118951 if( pExpr->bDeferred && pExpr->pParent->eType!=FTSQUERY_NEAR ){
118952 assert( pCsr->nDoc>0 );
118953 for(iCol=0; iCol<pTab->nColumn; iCol++){
118954 aiOut[iCol*3 + 1] = (u32)pCsr->nDoc;
118955 aiOut[iCol*3 + 2] = (u32)pCsr->nDoc;
118957 }else{
118958 rc = fts3EvalGatherStats(pCsr, pExpr);
118959 if( rc==SQLITE_OK ){
118960 assert( pExpr->aMI );
118961 for(iCol=0; iCol<pTab->nColumn; iCol++){
118962 aiOut[iCol*3 + 1] = pExpr->aMI[iCol*3 + 1];
118963 aiOut[iCol*3 + 2] = pExpr->aMI[iCol*3 + 2];
118968 return rc;
118972 ** The expression pExpr passed as the second argument to this function
118973 ** must be of type FTSQUERY_PHRASE.
118975 ** The returned value is either NULL or a pointer to a buffer containing
118976 ** a position-list indicating the occurrences of the phrase in column iCol
118977 ** of the current row.
118979 ** More specifically, the returned buffer contains 1 varint for each
118980 ** occurence of the phrase in the column, stored using the normal (delta+2)
118981 ** compression and is terminated by either an 0x01 or 0x00 byte. For example,
118982 ** if the requested column contains "a b X c d X X" and the position-list
118983 ** for 'X' is requested, the buffer returned may contain:
118985 ** 0x04 0x05 0x03 0x01 or 0x04 0x05 0x03 0x00
118987 ** This function works regardless of whether or not the phrase is deferred,
118988 ** incremental, or neither.
118990 SQLITE_PRIVATE char *sqlite3Fts3EvalPhrasePoslist(
118991 Fts3Cursor *pCsr, /* FTS3 cursor object */
118992 Fts3Expr *pExpr, /* Phrase to return doclist for */
118993 int iCol /* Column to return position list for */
118995 Fts3Phrase *pPhrase = pExpr->pPhrase;
118996 Fts3Table *pTab = (Fts3Table *)pCsr->base.pVtab;
118997 char *pIter = pPhrase->doclist.pList;
118998 int iThis;
119000 assert( iCol>=0 && iCol<pTab->nColumn );
119001 if( !pIter
119002 || pExpr->bEof
119003 || pExpr->iDocid!=pCsr->iPrevId
119004 || (pPhrase->iColumn<pTab->nColumn && pPhrase->iColumn!=iCol)
119006 return 0;
119009 assert( pPhrase->doclist.nList>0 );
119010 if( *pIter==0x01 ){
119011 pIter++;
119012 pIter += sqlite3Fts3GetVarint32(pIter, &iThis);
119013 }else{
119014 iThis = 0;
119016 while( iThis<iCol ){
119017 fts3ColumnlistCopy(0, &pIter);
119018 if( *pIter==0x00 ) return 0;
119019 pIter++;
119020 pIter += sqlite3Fts3GetVarint32(pIter, &iThis);
119023 return ((iCol==iThis)?pIter:0);
119027 ** Free all components of the Fts3Phrase structure that were allocated by
119028 ** the eval module. Specifically, this means to free:
119030 ** * the contents of pPhrase->doclist, and
119031 ** * any Fts3MultiSegReader objects held by phrase tokens.
119033 SQLITE_PRIVATE void sqlite3Fts3EvalPhraseCleanup(Fts3Phrase *pPhrase){
119034 if( pPhrase ){
119035 int i;
119036 sqlite3_free(pPhrase->doclist.aAll);
119037 fts3EvalInvalidatePoslist(pPhrase);
119038 memset(&pPhrase->doclist, 0, sizeof(Fts3Doclist));
119039 for(i=0; i<pPhrase->nToken; i++){
119040 fts3SegReaderCursorFree(pPhrase->aToken[i].pSegcsr);
119041 pPhrase->aToken[i].pSegcsr = 0;
119046 #if !SQLITE_CORE
119048 ** Initialize API pointer table, if required.
119050 SQLITE_API int sqlite3_extension_init(
119051 sqlite3 *db,
119052 char **pzErrMsg,
119053 const sqlite3_api_routines *pApi
119055 SQLITE_EXTENSION_INIT2(pApi)
119056 return sqlite3Fts3Init(db);
119058 #endif
119060 #endif
119062 /************** End of fts3.c ************************************************/
119063 /************** Begin file fts3_aux.c ****************************************/
119065 ** 2011 Jan 27
119067 ** The author disclaims copyright to this source code. In place of
119068 ** a legal notice, here is a blessing:
119070 ** May you do good and not evil.
119071 ** May you find forgiveness for yourself and forgive others.
119072 ** May you share freely, never taking more than you give.
119074 ******************************************************************************
119077 #if !defined(SQLITE_CORE) || defined(SQLITE_ENABLE_FTS3)
119079 /* #include <string.h> */
119080 /* #include <assert.h> */
119082 typedef struct Fts3auxTable Fts3auxTable;
119083 typedef struct Fts3auxCursor Fts3auxCursor;
119085 struct Fts3auxTable {
119086 sqlite3_vtab base; /* Base class used by SQLite core */
119087 Fts3Table *pFts3Tab;
119090 struct Fts3auxCursor {
119091 sqlite3_vtab_cursor base; /* Base class used by SQLite core */
119092 Fts3MultiSegReader csr; /* Must be right after "base" */
119093 Fts3SegFilter filter;
119094 char *zStop;
119095 int nStop; /* Byte-length of string zStop */
119096 int isEof; /* True if cursor is at EOF */
119097 sqlite3_int64 iRowid; /* Current rowid */
119099 int iCol; /* Current value of 'col' column */
119100 int nStat; /* Size of aStat[] array */
119101 struct Fts3auxColstats {
119102 sqlite3_int64 nDoc; /* 'documents' values for current csr row */
119103 sqlite3_int64 nOcc; /* 'occurrences' values for current csr row */
119104 } *aStat;
119108 ** Schema of the terms table.
119110 #define FTS3_TERMS_SCHEMA "CREATE TABLE x(term, col, documents, occurrences)"
119113 ** This function does all the work for both the xConnect and xCreate methods.
119114 ** These tables have no persistent representation of their own, so xConnect
119115 ** and xCreate are identical operations.
119117 static int fts3auxConnectMethod(
119118 sqlite3 *db, /* Database connection */
119119 void *pUnused, /* Unused */
119120 int argc, /* Number of elements in argv array */
119121 const char * const *argv, /* xCreate/xConnect argument array */
119122 sqlite3_vtab **ppVtab, /* OUT: New sqlite3_vtab object */
119123 char **pzErr /* OUT: sqlite3_malloc'd error message */
119125 char const *zDb; /* Name of database (e.g. "main") */
119126 char const *zFts3; /* Name of fts3 table */
119127 int nDb; /* Result of strlen(zDb) */
119128 int nFts3; /* Result of strlen(zFts3) */
119129 int nByte; /* Bytes of space to allocate here */
119130 int rc; /* value returned by declare_vtab() */
119131 Fts3auxTable *p; /* Virtual table object to return */
119133 UNUSED_PARAMETER(pUnused);
119135 /* The user should specify a single argument - the name of an fts3 table. */
119136 if( argc!=4 ){
119137 *pzErr = sqlite3_mprintf(
119138 "wrong number of arguments to fts4aux constructor"
119140 return SQLITE_ERROR;
119143 zDb = argv[1];
119144 nDb = strlen(zDb);
119145 zFts3 = argv[3];
119146 nFts3 = strlen(zFts3);
119148 rc = sqlite3_declare_vtab(db, FTS3_TERMS_SCHEMA);
119149 if( rc!=SQLITE_OK ) return rc;
119151 nByte = sizeof(Fts3auxTable) + sizeof(Fts3Table) + nDb + nFts3 + 2;
119152 p = (Fts3auxTable *)sqlite3_malloc(nByte);
119153 if( !p ) return SQLITE_NOMEM;
119154 memset(p, 0, nByte);
119156 p->pFts3Tab = (Fts3Table *)&p[1];
119157 p->pFts3Tab->zDb = (char *)&p->pFts3Tab[1];
119158 p->pFts3Tab->zName = &p->pFts3Tab->zDb[nDb+1];
119159 p->pFts3Tab->db = db;
119160 p->pFts3Tab->nIndex = 1;
119162 memcpy((char *)p->pFts3Tab->zDb, zDb, nDb);
119163 memcpy((char *)p->pFts3Tab->zName, zFts3, nFts3);
119164 sqlite3Fts3Dequote((char *)p->pFts3Tab->zName);
119166 *ppVtab = (sqlite3_vtab *)p;
119167 return SQLITE_OK;
119171 ** This function does the work for both the xDisconnect and xDestroy methods.
119172 ** These tables have no persistent representation of their own, so xDisconnect
119173 ** and xDestroy are identical operations.
119175 static int fts3auxDisconnectMethod(sqlite3_vtab *pVtab){
119176 Fts3auxTable *p = (Fts3auxTable *)pVtab;
119177 Fts3Table *pFts3 = p->pFts3Tab;
119178 int i;
119180 /* Free any prepared statements held */
119181 for(i=0; i<SizeofArray(pFts3->aStmt); i++){
119182 sqlite3_finalize(pFts3->aStmt[i]);
119184 sqlite3_free(pFts3->zSegmentsTbl);
119185 sqlite3_free(p);
119186 return SQLITE_OK;
119189 #define FTS4AUX_EQ_CONSTRAINT 1
119190 #define FTS4AUX_GE_CONSTRAINT 2
119191 #define FTS4AUX_LE_CONSTRAINT 4
119194 ** xBestIndex - Analyze a WHERE and ORDER BY clause.
119196 static int fts3auxBestIndexMethod(
119197 sqlite3_vtab *pVTab,
119198 sqlite3_index_info *pInfo
119200 int i;
119201 int iEq = -1;
119202 int iGe = -1;
119203 int iLe = -1;
119205 UNUSED_PARAMETER(pVTab);
119207 /* This vtab delivers always results in "ORDER BY term ASC" order. */
119208 if( pInfo->nOrderBy==1
119209 && pInfo->aOrderBy[0].iColumn==0
119210 && pInfo->aOrderBy[0].desc==0
119212 pInfo->orderByConsumed = 1;
119215 /* Search for equality and range constraints on the "term" column. */
119216 for(i=0; i<pInfo->nConstraint; i++){
119217 if( pInfo->aConstraint[i].usable && pInfo->aConstraint[i].iColumn==0 ){
119218 int op = pInfo->aConstraint[i].op;
119219 if( op==SQLITE_INDEX_CONSTRAINT_EQ ) iEq = i;
119220 if( op==SQLITE_INDEX_CONSTRAINT_LT ) iLe = i;
119221 if( op==SQLITE_INDEX_CONSTRAINT_LE ) iLe = i;
119222 if( op==SQLITE_INDEX_CONSTRAINT_GT ) iGe = i;
119223 if( op==SQLITE_INDEX_CONSTRAINT_GE ) iGe = i;
119227 if( iEq>=0 ){
119228 pInfo->idxNum = FTS4AUX_EQ_CONSTRAINT;
119229 pInfo->aConstraintUsage[iEq].argvIndex = 1;
119230 pInfo->estimatedCost = 5;
119231 }else{
119232 pInfo->idxNum = 0;
119233 pInfo->estimatedCost = 20000;
119234 if( iGe>=0 ){
119235 pInfo->idxNum += FTS4AUX_GE_CONSTRAINT;
119236 pInfo->aConstraintUsage[iGe].argvIndex = 1;
119237 pInfo->estimatedCost /= 2;
119239 if( iLe>=0 ){
119240 pInfo->idxNum += FTS4AUX_LE_CONSTRAINT;
119241 pInfo->aConstraintUsage[iLe].argvIndex = 1 + (iGe>=0);
119242 pInfo->estimatedCost /= 2;
119246 return SQLITE_OK;
119250 ** xOpen - Open a cursor.
119252 static int fts3auxOpenMethod(sqlite3_vtab *pVTab, sqlite3_vtab_cursor **ppCsr){
119253 Fts3auxCursor *pCsr; /* Pointer to cursor object to return */
119255 UNUSED_PARAMETER(pVTab);
119257 pCsr = (Fts3auxCursor *)sqlite3_malloc(sizeof(Fts3auxCursor));
119258 if( !pCsr ) return SQLITE_NOMEM;
119259 memset(pCsr, 0, sizeof(Fts3auxCursor));
119261 *ppCsr = (sqlite3_vtab_cursor *)pCsr;
119262 return SQLITE_OK;
119266 ** xClose - Close a cursor.
119268 static int fts3auxCloseMethod(sqlite3_vtab_cursor *pCursor){
119269 Fts3Table *pFts3 = ((Fts3auxTable *)pCursor->pVtab)->pFts3Tab;
119270 Fts3auxCursor *pCsr = (Fts3auxCursor *)pCursor;
119272 sqlite3Fts3SegmentsClose(pFts3);
119273 sqlite3Fts3SegReaderFinish(&pCsr->csr);
119274 sqlite3_free((void *)pCsr->filter.zTerm);
119275 sqlite3_free(pCsr->zStop);
119276 sqlite3_free(pCsr->aStat);
119277 sqlite3_free(pCsr);
119278 return SQLITE_OK;
119281 static int fts3auxGrowStatArray(Fts3auxCursor *pCsr, int nSize){
119282 if( nSize>pCsr->nStat ){
119283 struct Fts3auxColstats *aNew;
119284 aNew = (struct Fts3auxColstats *)sqlite3_realloc(pCsr->aStat,
119285 sizeof(struct Fts3auxColstats) * nSize
119287 if( aNew==0 ) return SQLITE_NOMEM;
119288 memset(&aNew[pCsr->nStat], 0,
119289 sizeof(struct Fts3auxColstats) * (nSize - pCsr->nStat)
119291 pCsr->aStat = aNew;
119292 pCsr->nStat = nSize;
119294 return SQLITE_OK;
119298 ** xNext - Advance the cursor to the next row, if any.
119300 static int fts3auxNextMethod(sqlite3_vtab_cursor *pCursor){
119301 Fts3auxCursor *pCsr = (Fts3auxCursor *)pCursor;
119302 Fts3Table *pFts3 = ((Fts3auxTable *)pCursor->pVtab)->pFts3Tab;
119303 int rc;
119305 /* Increment our pretend rowid value. */
119306 pCsr->iRowid++;
119308 for(pCsr->iCol++; pCsr->iCol<pCsr->nStat; pCsr->iCol++){
119309 if( pCsr->aStat[pCsr->iCol].nDoc>0 ) return SQLITE_OK;
119312 rc = sqlite3Fts3SegReaderStep(pFts3, &pCsr->csr);
119313 if( rc==SQLITE_ROW ){
119314 int i = 0;
119315 int nDoclist = pCsr->csr.nDoclist;
119316 char *aDoclist = pCsr->csr.aDoclist;
119317 int iCol;
119319 int eState = 0;
119321 if( pCsr->zStop ){
119322 int n = (pCsr->nStop<pCsr->csr.nTerm) ? pCsr->nStop : pCsr->csr.nTerm;
119323 int mc = memcmp(pCsr->zStop, pCsr->csr.zTerm, n);
119324 if( mc<0 || (mc==0 && pCsr->csr.nTerm>pCsr->nStop) ){
119325 pCsr->isEof = 1;
119326 return SQLITE_OK;
119330 if( fts3auxGrowStatArray(pCsr, 2) ) return SQLITE_NOMEM;
119331 memset(pCsr->aStat, 0, sizeof(struct Fts3auxColstats) * pCsr->nStat);
119332 iCol = 0;
119334 while( i<nDoclist ){
119335 sqlite3_int64 v = 0;
119337 i += sqlite3Fts3GetVarint(&aDoclist[i], &v);
119338 switch( eState ){
119339 /* State 0. In this state the integer just read was a docid. */
119340 case 0:
119341 pCsr->aStat[0].nDoc++;
119342 eState = 1;
119343 iCol = 0;
119344 break;
119346 /* State 1. In this state we are expecting either a 1, indicating
119347 ** that the following integer will be a column number, or the
119348 ** start of a position list for column 0.
119350 ** The only difference between state 1 and state 2 is that if the
119351 ** integer encountered in state 1 is not 0 or 1, then we need to
119352 ** increment the column 0 "nDoc" count for this term.
119354 case 1:
119355 assert( iCol==0 );
119356 if( v>1 ){
119357 pCsr->aStat[1].nDoc++;
119359 eState = 2;
119360 /* fall through */
119362 case 2:
119363 if( v==0 ){ /* 0x00. Next integer will be a docid. */
119364 eState = 0;
119365 }else if( v==1 ){ /* 0x01. Next integer will be a column number. */
119366 eState = 3;
119367 }else{ /* 2 or greater. A position. */
119368 pCsr->aStat[iCol+1].nOcc++;
119369 pCsr->aStat[0].nOcc++;
119371 break;
119373 /* State 3. The integer just read is a column number. */
119374 default: assert( eState==3 );
119375 iCol = (int)v;
119376 if( fts3auxGrowStatArray(pCsr, iCol+2) ) return SQLITE_NOMEM;
119377 pCsr->aStat[iCol+1].nDoc++;
119378 eState = 2;
119379 break;
119383 pCsr->iCol = 0;
119384 rc = SQLITE_OK;
119385 }else{
119386 pCsr->isEof = 1;
119388 return rc;
119392 ** xFilter - Initialize a cursor to point at the start of its data.
119394 static int fts3auxFilterMethod(
119395 sqlite3_vtab_cursor *pCursor, /* The cursor used for this query */
119396 int idxNum, /* Strategy index */
119397 const char *idxStr, /* Unused */
119398 int nVal, /* Number of elements in apVal */
119399 sqlite3_value **apVal /* Arguments for the indexing scheme */
119401 Fts3auxCursor *pCsr = (Fts3auxCursor *)pCursor;
119402 Fts3Table *pFts3 = ((Fts3auxTable *)pCursor->pVtab)->pFts3Tab;
119403 int rc;
119404 int isScan;
119406 UNUSED_PARAMETER(nVal);
119407 UNUSED_PARAMETER(idxStr);
119409 assert( idxStr==0 );
119410 assert( idxNum==FTS4AUX_EQ_CONSTRAINT || idxNum==0
119411 || idxNum==FTS4AUX_LE_CONSTRAINT || idxNum==FTS4AUX_GE_CONSTRAINT
119412 || idxNum==(FTS4AUX_LE_CONSTRAINT|FTS4AUX_GE_CONSTRAINT)
119414 isScan = (idxNum!=FTS4AUX_EQ_CONSTRAINT);
119416 /* In case this cursor is being reused, close and zero it. */
119417 testcase(pCsr->filter.zTerm);
119418 sqlite3Fts3SegReaderFinish(&pCsr->csr);
119419 sqlite3_free((void *)pCsr->filter.zTerm);
119420 sqlite3_free(pCsr->aStat);
119421 memset(&pCsr->csr, 0, ((u8*)&pCsr[1]) - (u8*)&pCsr->csr);
119423 pCsr->filter.flags = FTS3_SEGMENT_REQUIRE_POS|FTS3_SEGMENT_IGNORE_EMPTY;
119424 if( isScan ) pCsr->filter.flags |= FTS3_SEGMENT_SCAN;
119426 if( idxNum&(FTS4AUX_EQ_CONSTRAINT|FTS4AUX_GE_CONSTRAINT) ){
119427 const unsigned char *zStr = sqlite3_value_text(apVal[0]);
119428 if( zStr ){
119429 pCsr->filter.zTerm = sqlite3_mprintf("%s", zStr);
119430 pCsr->filter.nTerm = sqlite3_value_bytes(apVal[0]);
119431 if( pCsr->filter.zTerm==0 ) return SQLITE_NOMEM;
119434 if( idxNum&FTS4AUX_LE_CONSTRAINT ){
119435 int iIdx = (idxNum&FTS4AUX_GE_CONSTRAINT) ? 1 : 0;
119436 pCsr->zStop = sqlite3_mprintf("%s", sqlite3_value_text(apVal[iIdx]));
119437 pCsr->nStop = sqlite3_value_bytes(apVal[iIdx]);
119438 if( pCsr->zStop==0 ) return SQLITE_NOMEM;
119441 rc = sqlite3Fts3SegReaderCursor(pFts3, 0, FTS3_SEGCURSOR_ALL,
119442 pCsr->filter.zTerm, pCsr->filter.nTerm, 0, isScan, &pCsr->csr
119444 if( rc==SQLITE_OK ){
119445 rc = sqlite3Fts3SegReaderStart(pFts3, &pCsr->csr, &pCsr->filter);
119448 if( rc==SQLITE_OK ) rc = fts3auxNextMethod(pCursor);
119449 return rc;
119453 ** xEof - Return true if the cursor is at EOF, or false otherwise.
119455 static int fts3auxEofMethod(sqlite3_vtab_cursor *pCursor){
119456 Fts3auxCursor *pCsr = (Fts3auxCursor *)pCursor;
119457 return pCsr->isEof;
119461 ** xColumn - Return a column value.
119463 static int fts3auxColumnMethod(
119464 sqlite3_vtab_cursor *pCursor, /* Cursor to retrieve value from */
119465 sqlite3_context *pContext, /* Context for sqlite3_result_xxx() calls */
119466 int iCol /* Index of column to read value from */
119468 Fts3auxCursor *p = (Fts3auxCursor *)pCursor;
119470 assert( p->isEof==0 );
119471 if( iCol==0 ){ /* Column "term" */
119472 sqlite3_result_text(pContext, p->csr.zTerm, p->csr.nTerm, SQLITE_TRANSIENT);
119473 }else if( iCol==1 ){ /* Column "col" */
119474 if( p->iCol ){
119475 sqlite3_result_int(pContext, p->iCol-1);
119476 }else{
119477 sqlite3_result_text(pContext, "*", -1, SQLITE_STATIC);
119479 }else if( iCol==2 ){ /* Column "documents" */
119480 sqlite3_result_int64(pContext, p->aStat[p->iCol].nDoc);
119481 }else{ /* Column "occurrences" */
119482 sqlite3_result_int64(pContext, p->aStat[p->iCol].nOcc);
119485 return SQLITE_OK;
119489 ** xRowid - Return the current rowid for the cursor.
119491 static int fts3auxRowidMethod(
119492 sqlite3_vtab_cursor *pCursor, /* Cursor to retrieve value from */
119493 sqlite_int64 *pRowid /* OUT: Rowid value */
119495 Fts3auxCursor *pCsr = (Fts3auxCursor *)pCursor;
119496 *pRowid = pCsr->iRowid;
119497 return SQLITE_OK;
119501 ** Register the fts3aux module with database connection db. Return SQLITE_OK
119502 ** if successful or an error code if sqlite3_create_module() fails.
119504 SQLITE_PRIVATE int sqlite3Fts3InitAux(sqlite3 *db){
119505 static const sqlite3_module fts3aux_module = {
119506 0, /* iVersion */
119507 fts3auxConnectMethod, /* xCreate */
119508 fts3auxConnectMethod, /* xConnect */
119509 fts3auxBestIndexMethod, /* xBestIndex */
119510 fts3auxDisconnectMethod, /* xDisconnect */
119511 fts3auxDisconnectMethod, /* xDestroy */
119512 fts3auxOpenMethod, /* xOpen */
119513 fts3auxCloseMethod, /* xClose */
119514 fts3auxFilterMethod, /* xFilter */
119515 fts3auxNextMethod, /* xNext */
119516 fts3auxEofMethod, /* xEof */
119517 fts3auxColumnMethod, /* xColumn */
119518 fts3auxRowidMethod, /* xRowid */
119519 0, /* xUpdate */
119520 0, /* xBegin */
119521 0, /* xSync */
119522 0, /* xCommit */
119523 0, /* xRollback */
119524 0, /* xFindFunction */
119525 0, /* xRename */
119526 0, /* xSavepoint */
119527 0, /* xRelease */
119528 0 /* xRollbackTo */
119530 int rc; /* Return code */
119532 rc = sqlite3_create_module(db, "fts4aux", &fts3aux_module, 0);
119533 return rc;
119536 #endif /* !defined(SQLITE_CORE) || defined(SQLITE_ENABLE_FTS3) */
119538 /************** End of fts3_aux.c ********************************************/
119539 /************** Begin file fts3_expr.c ***************************************/
119541 ** 2008 Nov 28
119543 ** The author disclaims copyright to this source code. In place of
119544 ** a legal notice, here is a blessing:
119546 ** May you do good and not evil.
119547 ** May you find forgiveness for yourself and forgive others.
119548 ** May you share freely, never taking more than you give.
119550 ******************************************************************************
119552 ** This module contains code that implements a parser for fts3 query strings
119553 ** (the right-hand argument to the MATCH operator). Because the supported
119554 ** syntax is relatively simple, the whole tokenizer/parser system is
119555 ** hand-coded.
119557 #if !defined(SQLITE_CORE) || defined(SQLITE_ENABLE_FTS3)
119560 ** By default, this module parses the legacy syntax that has been
119561 ** traditionally used by fts3. Or, if SQLITE_ENABLE_FTS3_PARENTHESIS
119562 ** is defined, then it uses the new syntax. The differences between
119563 ** the new and the old syntaxes are:
119565 ** a) The new syntax supports parenthesis. The old does not.
119567 ** b) The new syntax supports the AND and NOT operators. The old does not.
119569 ** c) The old syntax supports the "-" token qualifier. This is not
119570 ** supported by the new syntax (it is replaced by the NOT operator).
119572 ** d) When using the old syntax, the OR operator has a greater precedence
119573 ** than an implicit AND. When using the new, both implicity and explicit
119574 ** AND operators have a higher precedence than OR.
119576 ** If compiled with SQLITE_TEST defined, then this module exports the
119577 ** symbol "int sqlite3_fts3_enable_parentheses". Setting this variable
119578 ** to zero causes the module to use the old syntax. If it is set to
119579 ** non-zero the new syntax is activated. This is so both syntaxes can
119580 ** be tested using a single build of testfixture.
119582 ** The following describes the syntax supported by the fts3 MATCH
119583 ** operator in a similar format to that used by the lemon parser
119584 ** generator. This module does not use actually lemon, it uses a
119585 ** custom parser.
119587 ** query ::= andexpr (OR andexpr)*.
119589 ** andexpr ::= notexpr (AND? notexpr)*.
119591 ** notexpr ::= nearexpr (NOT nearexpr|-TOKEN)*.
119592 ** notexpr ::= LP query RP.
119594 ** nearexpr ::= phrase (NEAR distance_opt nearexpr)*.
119596 ** distance_opt ::= .
119597 ** distance_opt ::= / INTEGER.
119599 ** phrase ::= TOKEN.
119600 ** phrase ::= COLUMN:TOKEN.
119601 ** phrase ::= "TOKEN TOKEN TOKEN...".
119604 #ifdef SQLITE_TEST
119605 SQLITE_API int sqlite3_fts3_enable_parentheses = 0;
119606 #else
119607 # ifdef SQLITE_ENABLE_FTS3_PARENTHESIS
119608 # define sqlite3_fts3_enable_parentheses 1
119609 # else
119610 # define sqlite3_fts3_enable_parentheses 0
119611 # endif
119612 #endif
119615 ** Default span for NEAR operators.
119617 #define SQLITE_FTS3_DEFAULT_NEAR_PARAM 10
119619 /* #include <string.h> */
119620 /* #include <assert.h> */
119623 ** isNot:
119624 ** This variable is used by function getNextNode(). When getNextNode() is
119625 ** called, it sets ParseContext.isNot to true if the 'next node' is a
119626 ** FTSQUERY_PHRASE with a unary "-" attached to it. i.e. "mysql" in the
119627 ** FTS3 query "sqlite -mysql". Otherwise, ParseContext.isNot is set to
119628 ** zero.
119630 typedef struct ParseContext ParseContext;
119631 struct ParseContext {
119632 sqlite3_tokenizer *pTokenizer; /* Tokenizer module */
119633 const char **azCol; /* Array of column names for fts3 table */
119634 int nCol; /* Number of entries in azCol[] */
119635 int iDefaultCol; /* Default column to query */
119636 int isNot; /* True if getNextNode() sees a unary - */
119637 sqlite3_context *pCtx; /* Write error message here */
119638 int nNest; /* Number of nested brackets */
119642 ** This function is equivalent to the standard isspace() function.
119644 ** The standard isspace() can be awkward to use safely, because although it
119645 ** is defined to accept an argument of type int, its behaviour when passed
119646 ** an integer that falls outside of the range of the unsigned char type
119647 ** is undefined (and sometimes, "undefined" means segfault). This wrapper
119648 ** is defined to accept an argument of type char, and always returns 0 for
119649 ** any values that fall outside of the range of the unsigned char type (i.e.
119650 ** negative values).
119652 static int fts3isspace(char c){
119653 return c==' ' || c=='\t' || c=='\n' || c=='\r' || c=='\v' || c=='\f';
119657 ** Allocate nByte bytes of memory using sqlite3_malloc(). If successful,
119658 ** zero the memory before returning a pointer to it. If unsuccessful,
119659 ** return NULL.
119661 static void *fts3MallocZero(int nByte){
119662 void *pRet = sqlite3_malloc(nByte);
119663 if( pRet ) memset(pRet, 0, nByte);
119664 return pRet;
119669 ** Extract the next token from buffer z (length n) using the tokenizer
119670 ** and other information (column names etc.) in pParse. Create an Fts3Expr
119671 ** structure of type FTSQUERY_PHRASE containing a phrase consisting of this
119672 ** single token and set *ppExpr to point to it. If the end of the buffer is
119673 ** reached before a token is found, set *ppExpr to zero. It is the
119674 ** responsibility of the caller to eventually deallocate the allocated
119675 ** Fts3Expr structure (if any) by passing it to sqlite3_free().
119677 ** Return SQLITE_OK if successful, or SQLITE_NOMEM if a memory allocation
119678 ** fails.
119680 static int getNextToken(
119681 ParseContext *pParse, /* fts3 query parse context */
119682 int iCol, /* Value for Fts3Phrase.iColumn */
119683 const char *z, int n, /* Input string */
119684 Fts3Expr **ppExpr, /* OUT: expression */
119685 int *pnConsumed /* OUT: Number of bytes consumed */
119687 sqlite3_tokenizer *pTokenizer = pParse->pTokenizer;
119688 sqlite3_tokenizer_module const *pModule = pTokenizer->pModule;
119689 int rc;
119690 sqlite3_tokenizer_cursor *pCursor;
119691 Fts3Expr *pRet = 0;
119692 int nConsumed = 0;
119694 rc = pModule->xOpen(pTokenizer, z, n, &pCursor);
119695 if( rc==SQLITE_OK ){
119696 const char *zToken;
119697 int nToken, iStart, iEnd, iPosition;
119698 int nByte; /* total space to allocate */
119700 pCursor->pTokenizer = pTokenizer;
119701 rc = pModule->xNext(pCursor, &zToken, &nToken, &iStart, &iEnd, &iPosition);
119703 if( rc==SQLITE_OK ){
119704 nByte = sizeof(Fts3Expr) + sizeof(Fts3Phrase) + nToken;
119705 pRet = (Fts3Expr *)fts3MallocZero(nByte);
119706 if( !pRet ){
119707 rc = SQLITE_NOMEM;
119708 }else{
119709 pRet->eType = FTSQUERY_PHRASE;
119710 pRet->pPhrase = (Fts3Phrase *)&pRet[1];
119711 pRet->pPhrase->nToken = 1;
119712 pRet->pPhrase->iColumn = iCol;
119713 pRet->pPhrase->aToken[0].n = nToken;
119714 pRet->pPhrase->aToken[0].z = (char *)&pRet->pPhrase[1];
119715 memcpy(pRet->pPhrase->aToken[0].z, zToken, nToken);
119717 if( iEnd<n && z[iEnd]=='*' ){
119718 pRet->pPhrase->aToken[0].isPrefix = 1;
119719 iEnd++;
119721 if( !sqlite3_fts3_enable_parentheses && iStart>0 && z[iStart-1]=='-' ){
119722 pParse->isNot = 1;
119725 nConsumed = iEnd;
119728 pModule->xClose(pCursor);
119731 *pnConsumed = nConsumed;
119732 *ppExpr = pRet;
119733 return rc;
119738 ** Enlarge a memory allocation. If an out-of-memory allocation occurs,
119739 ** then free the old allocation.
119741 static void *fts3ReallocOrFree(void *pOrig, int nNew){
119742 void *pRet = sqlite3_realloc(pOrig, nNew);
119743 if( !pRet ){
119744 sqlite3_free(pOrig);
119746 return pRet;
119750 ** Buffer zInput, length nInput, contains the contents of a quoted string
119751 ** that appeared as part of an fts3 query expression. Neither quote character
119752 ** is included in the buffer. This function attempts to tokenize the entire
119753 ** input buffer and create an Fts3Expr structure of type FTSQUERY_PHRASE
119754 ** containing the results.
119756 ** If successful, SQLITE_OK is returned and *ppExpr set to point at the
119757 ** allocated Fts3Expr structure. Otherwise, either SQLITE_NOMEM (out of memory
119758 ** error) or SQLITE_ERROR (tokenization error) is returned and *ppExpr set
119759 ** to 0.
119761 static int getNextString(
119762 ParseContext *pParse, /* fts3 query parse context */
119763 const char *zInput, int nInput, /* Input string */
119764 Fts3Expr **ppExpr /* OUT: expression */
119766 sqlite3_tokenizer *pTokenizer = pParse->pTokenizer;
119767 sqlite3_tokenizer_module const *pModule = pTokenizer->pModule;
119768 int rc;
119769 Fts3Expr *p = 0;
119770 sqlite3_tokenizer_cursor *pCursor = 0;
119771 char *zTemp = 0;
119772 int nTemp = 0;
119774 const int nSpace = sizeof(Fts3Expr) + sizeof(Fts3Phrase);
119775 int nToken = 0;
119777 /* The final Fts3Expr data structure, including the Fts3Phrase,
119778 ** Fts3PhraseToken structures token buffers are all stored as a single
119779 ** allocation so that the expression can be freed with a single call to
119780 ** sqlite3_free(). Setting this up requires a two pass approach.
119782 ** The first pass, in the block below, uses a tokenizer cursor to iterate
119783 ** through the tokens in the expression. This pass uses fts3ReallocOrFree()
119784 ** to assemble data in two dynamic buffers:
119786 ** Buffer p: Points to the Fts3Expr structure, followed by the Fts3Phrase
119787 ** structure, followed by the array of Fts3PhraseToken
119788 ** structures. This pass only populates the Fts3PhraseToken array.
119790 ** Buffer zTemp: Contains copies of all tokens.
119792 ** The second pass, in the block that begins "if( rc==SQLITE_DONE )" below,
119793 ** appends buffer zTemp to buffer p, and fills in the Fts3Expr and Fts3Phrase
119794 ** structures.
119796 rc = pModule->xOpen(pTokenizer, zInput, nInput, &pCursor);
119797 if( rc==SQLITE_OK ){
119798 int ii;
119799 pCursor->pTokenizer = pTokenizer;
119800 for(ii=0; rc==SQLITE_OK; ii++){
119801 const char *zByte;
119802 int nByte, iBegin, iEnd, iPos;
119803 rc = pModule->xNext(pCursor, &zByte, &nByte, &iBegin, &iEnd, &iPos);
119804 if( rc==SQLITE_OK ){
119805 Fts3PhraseToken *pToken;
119807 p = fts3ReallocOrFree(p, nSpace + ii*sizeof(Fts3PhraseToken));
119808 if( !p ) goto no_mem;
119810 zTemp = fts3ReallocOrFree(zTemp, nTemp + nByte);
119811 if( !zTemp ) goto no_mem;
119813 assert( nToken==ii );
119814 pToken = &((Fts3Phrase *)(&p[1]))->aToken[ii];
119815 memset(pToken, 0, sizeof(Fts3PhraseToken));
119817 memcpy(&zTemp[nTemp], zByte, nByte);
119818 nTemp += nByte;
119820 pToken->n = nByte;
119821 pToken->isPrefix = (iEnd<nInput && zInput[iEnd]=='*');
119822 nToken = ii+1;
119826 pModule->xClose(pCursor);
119827 pCursor = 0;
119830 if( rc==SQLITE_DONE ){
119831 int jj;
119832 char *zBuf = 0;
119834 p = fts3ReallocOrFree(p, nSpace + nToken*sizeof(Fts3PhraseToken) + nTemp);
119835 if( !p ) goto no_mem;
119836 memset(p, 0, (char *)&(((Fts3Phrase *)&p[1])->aToken[0])-(char *)p);
119837 p->eType = FTSQUERY_PHRASE;
119838 p->pPhrase = (Fts3Phrase *)&p[1];
119839 p->pPhrase->iColumn = pParse->iDefaultCol;
119840 p->pPhrase->nToken = nToken;
119842 zBuf = (char *)&p->pPhrase->aToken[nToken];
119843 memcpy(zBuf, zTemp, nTemp);
119844 sqlite3_free(zTemp);
119846 for(jj=0; jj<p->pPhrase->nToken; jj++){
119847 p->pPhrase->aToken[jj].z = zBuf;
119848 zBuf += p->pPhrase->aToken[jj].n;
119850 rc = SQLITE_OK;
119853 *ppExpr = p;
119854 return rc;
119855 no_mem:
119857 if( pCursor ){
119858 pModule->xClose(pCursor);
119860 sqlite3_free(zTemp);
119861 sqlite3_free(p);
119862 *ppExpr = 0;
119863 return SQLITE_NOMEM;
119867 ** Function getNextNode(), which is called by fts3ExprParse(), may itself
119868 ** call fts3ExprParse(). So this forward declaration is required.
119870 static int fts3ExprParse(ParseContext *, const char *, int, Fts3Expr **, int *);
119873 ** The output variable *ppExpr is populated with an allocated Fts3Expr
119874 ** structure, or set to 0 if the end of the input buffer is reached.
119876 ** Returns an SQLite error code. SQLITE_OK if everything works, SQLITE_NOMEM
119877 ** if a malloc failure occurs, or SQLITE_ERROR if a parse error is encountered.
119878 ** If SQLITE_ERROR is returned, pContext is populated with an error message.
119880 static int getNextNode(
119881 ParseContext *pParse, /* fts3 query parse context */
119882 const char *z, int n, /* Input string */
119883 Fts3Expr **ppExpr, /* OUT: expression */
119884 int *pnConsumed /* OUT: Number of bytes consumed */
119886 static const struct Fts3Keyword {
119887 char *z; /* Keyword text */
119888 unsigned char n; /* Length of the keyword */
119889 unsigned char parenOnly; /* Only valid in paren mode */
119890 unsigned char eType; /* Keyword code */
119891 } aKeyword[] = {
119892 { "OR" , 2, 0, FTSQUERY_OR },
119893 { "AND", 3, 1, FTSQUERY_AND },
119894 { "NOT", 3, 1, FTSQUERY_NOT },
119895 { "NEAR", 4, 0, FTSQUERY_NEAR }
119897 int ii;
119898 int iCol;
119899 int iColLen;
119900 int rc;
119901 Fts3Expr *pRet = 0;
119903 const char *zInput = z;
119904 int nInput = n;
119906 pParse->isNot = 0;
119908 /* Skip over any whitespace before checking for a keyword, an open or
119909 ** close bracket, or a quoted string.
119911 while( nInput>0 && fts3isspace(*zInput) ){
119912 nInput--;
119913 zInput++;
119915 if( nInput==0 ){
119916 return SQLITE_DONE;
119919 /* See if we are dealing with a keyword. */
119920 for(ii=0; ii<(int)(sizeof(aKeyword)/sizeof(struct Fts3Keyword)); ii++){
119921 const struct Fts3Keyword *pKey = &aKeyword[ii];
119923 if( (pKey->parenOnly & ~sqlite3_fts3_enable_parentheses)!=0 ){
119924 continue;
119927 if( nInput>=pKey->n && 0==memcmp(zInput, pKey->z, pKey->n) ){
119928 int nNear = SQLITE_FTS3_DEFAULT_NEAR_PARAM;
119929 int nKey = pKey->n;
119930 char cNext;
119932 /* If this is a "NEAR" keyword, check for an explicit nearness. */
119933 if( pKey->eType==FTSQUERY_NEAR ){
119934 assert( nKey==4 );
119935 if( zInput[4]=='/' && zInput[5]>='0' && zInput[5]<='9' ){
119936 nNear = 0;
119937 for(nKey=5; zInput[nKey]>='0' && zInput[nKey]<='9'; nKey++){
119938 nNear = nNear * 10 + (zInput[nKey] - '0');
119943 /* At this point this is probably a keyword. But for that to be true,
119944 ** the next byte must contain either whitespace, an open or close
119945 ** parenthesis, a quote character, or EOF.
119947 cNext = zInput[nKey];
119948 if( fts3isspace(cNext)
119949 || cNext=='"' || cNext=='(' || cNext==')' || cNext==0
119951 pRet = (Fts3Expr *)fts3MallocZero(sizeof(Fts3Expr));
119952 if( !pRet ){
119953 return SQLITE_NOMEM;
119955 pRet->eType = pKey->eType;
119956 pRet->nNear = nNear;
119957 *ppExpr = pRet;
119958 *pnConsumed = (int)((zInput - z) + nKey);
119959 return SQLITE_OK;
119962 /* Turns out that wasn't a keyword after all. This happens if the
119963 ** user has supplied a token such as "ORacle". Continue.
119968 /* Check for an open bracket. */
119969 if( sqlite3_fts3_enable_parentheses ){
119970 if( *zInput=='(' ){
119971 int nConsumed;
119972 pParse->nNest++;
119973 rc = fts3ExprParse(pParse, &zInput[1], nInput-1, ppExpr, &nConsumed);
119974 if( rc==SQLITE_OK && !*ppExpr ){
119975 rc = SQLITE_DONE;
119977 *pnConsumed = (int)((zInput - z) + 1 + nConsumed);
119978 return rc;
119981 /* Check for a close bracket. */
119982 if( *zInput==')' ){
119983 pParse->nNest--;
119984 *pnConsumed = (int)((zInput - z) + 1);
119985 return SQLITE_DONE;
119989 /* See if we are dealing with a quoted phrase. If this is the case, then
119990 ** search for the closing quote and pass the whole string to getNextString()
119991 ** for processing. This is easy to do, as fts3 has no syntax for escaping
119992 ** a quote character embedded in a string.
119994 if( *zInput=='"' ){
119995 for(ii=1; ii<nInput && zInput[ii]!='"'; ii++);
119996 *pnConsumed = (int)((zInput - z) + ii + 1);
119997 if( ii==nInput ){
119998 return SQLITE_ERROR;
120000 return getNextString(pParse, &zInput[1], ii-1, ppExpr);
120004 /* If control flows to this point, this must be a regular token, or
120005 ** the end of the input. Read a regular token using the sqlite3_tokenizer
120006 ** interface. Before doing so, figure out if there is an explicit
120007 ** column specifier for the token.
120009 ** TODO: Strangely, it is not possible to associate a column specifier
120010 ** with a quoted phrase, only with a single token. Not sure if this was
120011 ** an implementation artifact or an intentional decision when fts3 was
120012 ** first implemented. Whichever it was, this module duplicates the
120013 ** limitation.
120015 iCol = pParse->iDefaultCol;
120016 iColLen = 0;
120017 for(ii=0; ii<pParse->nCol; ii++){
120018 const char *zStr = pParse->azCol[ii];
120019 int nStr = (int)strlen(zStr);
120020 if( nInput>nStr && zInput[nStr]==':'
120021 && sqlite3_strnicmp(zStr, zInput, nStr)==0
120023 iCol = ii;
120024 iColLen = (int)((zInput - z) + nStr + 1);
120025 break;
120028 rc = getNextToken(pParse, iCol, &z[iColLen], n-iColLen, ppExpr, pnConsumed);
120029 *pnConsumed += iColLen;
120030 return rc;
120034 ** The argument is an Fts3Expr structure for a binary operator (any type
120035 ** except an FTSQUERY_PHRASE). Return an integer value representing the
120036 ** precedence of the operator. Lower values have a higher precedence (i.e.
120037 ** group more tightly). For example, in the C language, the == operator
120038 ** groups more tightly than ||, and would therefore have a higher precedence.
120040 ** When using the new fts3 query syntax (when SQLITE_ENABLE_FTS3_PARENTHESIS
120041 ** is defined), the order of the operators in precedence from highest to
120042 ** lowest is:
120044 ** NEAR
120045 ** NOT
120046 ** AND (including implicit ANDs)
120047 ** OR
120049 ** Note that when using the old query syntax, the OR operator has a higher
120050 ** precedence than the AND operator.
120052 static int opPrecedence(Fts3Expr *p){
120053 assert( p->eType!=FTSQUERY_PHRASE );
120054 if( sqlite3_fts3_enable_parentheses ){
120055 return p->eType;
120056 }else if( p->eType==FTSQUERY_NEAR ){
120057 return 1;
120058 }else if( p->eType==FTSQUERY_OR ){
120059 return 2;
120061 assert( p->eType==FTSQUERY_AND );
120062 return 3;
120066 ** Argument ppHead contains a pointer to the current head of a query
120067 ** expression tree being parsed. pPrev is the expression node most recently
120068 ** inserted into the tree. This function adds pNew, which is always a binary
120069 ** operator node, into the expression tree based on the relative precedence
120070 ** of pNew and the existing nodes of the tree. This may result in the head
120071 ** of the tree changing, in which case *ppHead is set to the new root node.
120073 static void insertBinaryOperator(
120074 Fts3Expr **ppHead, /* Pointer to the root node of a tree */
120075 Fts3Expr *pPrev, /* Node most recently inserted into the tree */
120076 Fts3Expr *pNew /* New binary node to insert into expression tree */
120078 Fts3Expr *pSplit = pPrev;
120079 while( pSplit->pParent && opPrecedence(pSplit->pParent)<=opPrecedence(pNew) ){
120080 pSplit = pSplit->pParent;
120083 if( pSplit->pParent ){
120084 assert( pSplit->pParent->pRight==pSplit );
120085 pSplit->pParent->pRight = pNew;
120086 pNew->pParent = pSplit->pParent;
120087 }else{
120088 *ppHead = pNew;
120090 pNew->pLeft = pSplit;
120091 pSplit->pParent = pNew;
120095 ** Parse the fts3 query expression found in buffer z, length n. This function
120096 ** returns either when the end of the buffer is reached or an unmatched
120097 ** closing bracket - ')' - is encountered.
120099 ** If successful, SQLITE_OK is returned, *ppExpr is set to point to the
120100 ** parsed form of the expression and *pnConsumed is set to the number of
120101 ** bytes read from buffer z. Otherwise, *ppExpr is set to 0 and SQLITE_NOMEM
120102 ** (out of memory error) or SQLITE_ERROR (parse error) is returned.
120104 static int fts3ExprParse(
120105 ParseContext *pParse, /* fts3 query parse context */
120106 const char *z, int n, /* Text of MATCH query */
120107 Fts3Expr **ppExpr, /* OUT: Parsed query structure */
120108 int *pnConsumed /* OUT: Number of bytes consumed */
120110 Fts3Expr *pRet = 0;
120111 Fts3Expr *pPrev = 0;
120112 Fts3Expr *pNotBranch = 0; /* Only used in legacy parse mode */
120113 int nIn = n;
120114 const char *zIn = z;
120115 int rc = SQLITE_OK;
120116 int isRequirePhrase = 1;
120118 while( rc==SQLITE_OK ){
120119 Fts3Expr *p = 0;
120120 int nByte = 0;
120121 rc = getNextNode(pParse, zIn, nIn, &p, &nByte);
120122 if( rc==SQLITE_OK ){
120123 int isPhrase;
120125 if( !sqlite3_fts3_enable_parentheses
120126 && p->eType==FTSQUERY_PHRASE && pParse->isNot
120128 /* Create an implicit NOT operator. */
120129 Fts3Expr *pNot = fts3MallocZero(sizeof(Fts3Expr));
120130 if( !pNot ){
120131 sqlite3Fts3ExprFree(p);
120132 rc = SQLITE_NOMEM;
120133 goto exprparse_out;
120135 pNot->eType = FTSQUERY_NOT;
120136 pNot->pRight = p;
120137 if( pNotBranch ){
120138 pNot->pLeft = pNotBranch;
120140 pNotBranch = pNot;
120141 p = pPrev;
120142 }else{
120143 int eType = p->eType;
120144 isPhrase = (eType==FTSQUERY_PHRASE || p->pLeft);
120146 /* The isRequirePhrase variable is set to true if a phrase or
120147 ** an expression contained in parenthesis is required. If a
120148 ** binary operator (AND, OR, NOT or NEAR) is encounted when
120149 ** isRequirePhrase is set, this is a syntax error.
120151 if( !isPhrase && isRequirePhrase ){
120152 sqlite3Fts3ExprFree(p);
120153 rc = SQLITE_ERROR;
120154 goto exprparse_out;
120157 if( isPhrase && !isRequirePhrase ){
120158 /* Insert an implicit AND operator. */
120159 Fts3Expr *pAnd;
120160 assert( pRet && pPrev );
120161 pAnd = fts3MallocZero(sizeof(Fts3Expr));
120162 if( !pAnd ){
120163 sqlite3Fts3ExprFree(p);
120164 rc = SQLITE_NOMEM;
120165 goto exprparse_out;
120167 pAnd->eType = FTSQUERY_AND;
120168 insertBinaryOperator(&pRet, pPrev, pAnd);
120169 pPrev = pAnd;
120172 /* This test catches attempts to make either operand of a NEAR
120173 ** operator something other than a phrase. For example, either of
120174 ** the following:
120176 ** (bracketed expression) NEAR phrase
120177 ** phrase NEAR (bracketed expression)
120179 ** Return an error in either case.
120181 if( pPrev && (
120182 (eType==FTSQUERY_NEAR && !isPhrase && pPrev->eType!=FTSQUERY_PHRASE)
120183 || (eType!=FTSQUERY_PHRASE && isPhrase && pPrev->eType==FTSQUERY_NEAR)
120185 sqlite3Fts3ExprFree(p);
120186 rc = SQLITE_ERROR;
120187 goto exprparse_out;
120190 if( isPhrase ){
120191 if( pRet ){
120192 assert( pPrev && pPrev->pLeft && pPrev->pRight==0 );
120193 pPrev->pRight = p;
120194 p->pParent = pPrev;
120195 }else{
120196 pRet = p;
120198 }else{
120199 insertBinaryOperator(&pRet, pPrev, p);
120201 isRequirePhrase = !isPhrase;
120203 assert( nByte>0 );
120205 assert( rc!=SQLITE_OK || (nByte>0 && nByte<=nIn) );
120206 nIn -= nByte;
120207 zIn += nByte;
120208 pPrev = p;
120211 if( rc==SQLITE_DONE && pRet && isRequirePhrase ){
120212 rc = SQLITE_ERROR;
120215 if( rc==SQLITE_DONE ){
120216 rc = SQLITE_OK;
120217 if( !sqlite3_fts3_enable_parentheses && pNotBranch ){
120218 if( !pRet ){
120219 rc = SQLITE_ERROR;
120220 }else{
120221 Fts3Expr *pIter = pNotBranch;
120222 while( pIter->pLeft ){
120223 pIter = pIter->pLeft;
120225 pIter->pLeft = pRet;
120226 pRet = pNotBranch;
120230 *pnConsumed = n - nIn;
120232 exprparse_out:
120233 if( rc!=SQLITE_OK ){
120234 sqlite3Fts3ExprFree(pRet);
120235 sqlite3Fts3ExprFree(pNotBranch);
120236 pRet = 0;
120238 *ppExpr = pRet;
120239 return rc;
120243 ** Parameters z and n contain a pointer to and length of a buffer containing
120244 ** an fts3 query expression, respectively. This function attempts to parse the
120245 ** query expression and create a tree of Fts3Expr structures representing the
120246 ** parsed expression. If successful, *ppExpr is set to point to the head
120247 ** of the parsed expression tree and SQLITE_OK is returned. If an error
120248 ** occurs, either SQLITE_NOMEM (out-of-memory error) or SQLITE_ERROR (parse
120249 ** error) is returned and *ppExpr is set to 0.
120251 ** If parameter n is a negative number, then z is assumed to point to a
120252 ** nul-terminated string and the length is determined using strlen().
120254 ** The first parameter, pTokenizer, is passed the fts3 tokenizer module to
120255 ** use to normalize query tokens while parsing the expression. The azCol[]
120256 ** array, which is assumed to contain nCol entries, should contain the names
120257 ** of each column in the target fts3 table, in order from left to right.
120258 ** Column names must be nul-terminated strings.
120260 ** The iDefaultCol parameter should be passed the index of the table column
120261 ** that appears on the left-hand-side of the MATCH operator (the default
120262 ** column to match against for tokens for which a column name is not explicitly
120263 ** specified as part of the query string), or -1 if tokens may by default
120264 ** match any table column.
120266 SQLITE_PRIVATE int sqlite3Fts3ExprParse(
120267 sqlite3_tokenizer *pTokenizer, /* Tokenizer module */
120268 char **azCol, /* Array of column names for fts3 table */
120269 int nCol, /* Number of entries in azCol[] */
120270 int iDefaultCol, /* Default column to query */
120271 const char *z, int n, /* Text of MATCH query */
120272 Fts3Expr **ppExpr /* OUT: Parsed query structure */
120274 int nParsed;
120275 int rc;
120276 ParseContext sParse;
120277 sParse.pTokenizer = pTokenizer;
120278 sParse.azCol = (const char **)azCol;
120279 sParse.nCol = nCol;
120280 sParse.iDefaultCol = iDefaultCol;
120281 sParse.nNest = 0;
120282 if( z==0 ){
120283 *ppExpr = 0;
120284 return SQLITE_OK;
120286 if( n<0 ){
120287 n = (int)strlen(z);
120289 rc = fts3ExprParse(&sParse, z, n, ppExpr, &nParsed);
120291 /* Check for mismatched parenthesis */
120292 if( rc==SQLITE_OK && sParse.nNest ){
120293 rc = SQLITE_ERROR;
120294 sqlite3Fts3ExprFree(*ppExpr);
120295 *ppExpr = 0;
120298 return rc;
120302 ** Free a parsed fts3 query expression allocated by sqlite3Fts3ExprParse().
120304 SQLITE_PRIVATE void sqlite3Fts3ExprFree(Fts3Expr *p){
120305 if( p ){
120306 assert( p->eType==FTSQUERY_PHRASE || p->pPhrase==0 );
120307 sqlite3Fts3ExprFree(p->pLeft);
120308 sqlite3Fts3ExprFree(p->pRight);
120309 sqlite3Fts3EvalPhraseCleanup(p->pPhrase);
120310 sqlite3_free(p->aMI);
120311 sqlite3_free(p);
120315 /****************************************************************************
120316 *****************************************************************************
120317 ** Everything after this point is just test code.
120320 #ifdef SQLITE_TEST
120322 /* #include <stdio.h> */
120325 ** Function to query the hash-table of tokenizers (see README.tokenizers).
120327 static int queryTestTokenizer(
120328 sqlite3 *db,
120329 const char *zName,
120330 const sqlite3_tokenizer_module **pp
120332 int rc;
120333 sqlite3_stmt *pStmt;
120334 const char zSql[] = "SELECT fts3_tokenizer(?)";
120336 *pp = 0;
120337 rc = sqlite3_prepare_v2(db, zSql, -1, &pStmt, 0);
120338 if( rc!=SQLITE_OK ){
120339 return rc;
120342 sqlite3_bind_text(pStmt, 1, zName, -1, SQLITE_STATIC);
120343 if( SQLITE_ROW==sqlite3_step(pStmt) ){
120344 if( sqlite3_column_type(pStmt, 0)==SQLITE_BLOB ){
120345 memcpy((void *)pp, sqlite3_column_blob(pStmt, 0), sizeof(*pp));
120349 return sqlite3_finalize(pStmt);
120353 ** Return a pointer to a buffer containing a text representation of the
120354 ** expression passed as the first argument. The buffer is obtained from
120355 ** sqlite3_malloc(). It is the responsibility of the caller to use
120356 ** sqlite3_free() to release the memory. If an OOM condition is encountered,
120357 ** NULL is returned.
120359 ** If the second argument is not NULL, then its contents are prepended to
120360 ** the returned expression text and then freed using sqlite3_free().
120362 static char *exprToString(Fts3Expr *pExpr, char *zBuf){
120363 switch( pExpr->eType ){
120364 case FTSQUERY_PHRASE: {
120365 Fts3Phrase *pPhrase = pExpr->pPhrase;
120366 int i;
120367 zBuf = sqlite3_mprintf(
120368 "%zPHRASE %d 0", zBuf, pPhrase->iColumn);
120369 for(i=0; zBuf && i<pPhrase->nToken; i++){
120370 zBuf = sqlite3_mprintf("%z %.*s%s", zBuf,
120371 pPhrase->aToken[i].n, pPhrase->aToken[i].z,
120372 (pPhrase->aToken[i].isPrefix?"+":"")
120375 return zBuf;
120378 case FTSQUERY_NEAR:
120379 zBuf = sqlite3_mprintf("%zNEAR/%d ", zBuf, pExpr->nNear);
120380 break;
120381 case FTSQUERY_NOT:
120382 zBuf = sqlite3_mprintf("%zNOT ", zBuf);
120383 break;
120384 case FTSQUERY_AND:
120385 zBuf = sqlite3_mprintf("%zAND ", zBuf);
120386 break;
120387 case FTSQUERY_OR:
120388 zBuf = sqlite3_mprintf("%zOR ", zBuf);
120389 break;
120392 if( zBuf ) zBuf = sqlite3_mprintf("%z{", zBuf);
120393 if( zBuf ) zBuf = exprToString(pExpr->pLeft, zBuf);
120394 if( zBuf ) zBuf = sqlite3_mprintf("%z} {", zBuf);
120396 if( zBuf ) zBuf = exprToString(pExpr->pRight, zBuf);
120397 if( zBuf ) zBuf = sqlite3_mprintf("%z}", zBuf);
120399 return zBuf;
120403 ** This is the implementation of a scalar SQL function used to test the
120404 ** expression parser. It should be called as follows:
120406 ** fts3_exprtest(<tokenizer>, <expr>, <column 1>, ...);
120408 ** The first argument, <tokenizer>, is the name of the fts3 tokenizer used
120409 ** to parse the query expression (see README.tokenizers). The second argument
120410 ** is the query expression to parse. Each subsequent argument is the name
120411 ** of a column of the fts3 table that the query expression may refer to.
120412 ** For example:
120414 ** SELECT fts3_exprtest('simple', 'Bill col2:Bloggs', 'col1', 'col2');
120416 static void fts3ExprTest(
120417 sqlite3_context *context,
120418 int argc,
120419 sqlite3_value **argv
120421 sqlite3_tokenizer_module const *pModule = 0;
120422 sqlite3_tokenizer *pTokenizer = 0;
120423 int rc;
120424 char **azCol = 0;
120425 const char *zExpr;
120426 int nExpr;
120427 int nCol;
120428 int ii;
120429 Fts3Expr *pExpr;
120430 char *zBuf = 0;
120431 sqlite3 *db = sqlite3_context_db_handle(context);
120433 if( argc<3 ){
120434 sqlite3_result_error(context,
120435 "Usage: fts3_exprtest(tokenizer, expr, col1, ...", -1
120437 return;
120440 rc = queryTestTokenizer(db,
120441 (const char *)sqlite3_value_text(argv[0]), &pModule);
120442 if( rc==SQLITE_NOMEM ){
120443 sqlite3_result_error_nomem(context);
120444 goto exprtest_out;
120445 }else if( !pModule ){
120446 sqlite3_result_error(context, "No such tokenizer module", -1);
120447 goto exprtest_out;
120450 rc = pModule->xCreate(0, 0, &pTokenizer);
120451 assert( rc==SQLITE_NOMEM || rc==SQLITE_OK );
120452 if( rc==SQLITE_NOMEM ){
120453 sqlite3_result_error_nomem(context);
120454 goto exprtest_out;
120456 pTokenizer->pModule = pModule;
120458 zExpr = (const char *)sqlite3_value_text(argv[1]);
120459 nExpr = sqlite3_value_bytes(argv[1]);
120460 nCol = argc-2;
120461 azCol = (char **)sqlite3_malloc(nCol*sizeof(char *));
120462 if( !azCol ){
120463 sqlite3_result_error_nomem(context);
120464 goto exprtest_out;
120466 for(ii=0; ii<nCol; ii++){
120467 azCol[ii] = (char *)sqlite3_value_text(argv[ii+2]);
120470 rc = sqlite3Fts3ExprParse(
120471 pTokenizer, azCol, nCol, nCol, zExpr, nExpr, &pExpr
120473 if( rc!=SQLITE_OK && rc!=SQLITE_NOMEM ){
120474 sqlite3_result_error(context, "Error parsing expression", -1);
120475 }else if( rc==SQLITE_NOMEM || !(zBuf = exprToString(pExpr, 0)) ){
120476 sqlite3_result_error_nomem(context);
120477 }else{
120478 sqlite3_result_text(context, zBuf, -1, SQLITE_TRANSIENT);
120479 sqlite3_free(zBuf);
120482 sqlite3Fts3ExprFree(pExpr);
120484 exprtest_out:
120485 if( pModule && pTokenizer ){
120486 rc = pModule->xDestroy(pTokenizer);
120488 sqlite3_free(azCol);
120492 ** Register the query expression parser test function fts3_exprtest()
120493 ** with database connection db.
120495 SQLITE_PRIVATE int sqlite3Fts3ExprInitTestInterface(sqlite3* db){
120496 return sqlite3_create_function(
120497 db, "fts3_exprtest", -1, SQLITE_UTF8, 0, fts3ExprTest, 0, 0
120501 #endif
120502 #endif /* !defined(SQLITE_CORE) || defined(SQLITE_ENABLE_FTS3) */
120504 /************** End of fts3_expr.c *******************************************/
120505 /************** Begin file fts3_hash.c ***************************************/
120507 ** 2001 September 22
120509 ** The author disclaims copyright to this source code. In place of
120510 ** a legal notice, here is a blessing:
120512 ** May you do good and not evil.
120513 ** May you find forgiveness for yourself and forgive others.
120514 ** May you share freely, never taking more than you give.
120516 *************************************************************************
120517 ** This is the implementation of generic hash-tables used in SQLite.
120518 ** We've modified it slightly to serve as a standalone hash table
120519 ** implementation for the full-text indexing module.
120523 ** The code in this file is only compiled if:
120525 ** * The FTS3 module is being built as an extension
120526 ** (in which case SQLITE_CORE is not defined), or
120528 ** * The FTS3 module is being built into the core of
120529 ** SQLite (in which case SQLITE_ENABLE_FTS3 is defined).
120531 #if !defined(SQLITE_CORE) || defined(SQLITE_ENABLE_FTS3)
120533 /* #include <assert.h> */
120534 /* #include <stdlib.h> */
120535 /* #include <string.h> */
120539 ** Malloc and Free functions
120541 static void *fts3HashMalloc(int n){
120542 void *p = sqlite3_malloc(n);
120543 if( p ){
120544 memset(p, 0, n);
120546 return p;
120548 static void fts3HashFree(void *p){
120549 sqlite3_free(p);
120552 /* Turn bulk memory into a hash table object by initializing the
120553 ** fields of the Hash structure.
120555 ** "pNew" is a pointer to the hash table that is to be initialized.
120556 ** keyClass is one of the constants
120557 ** FTS3_HASH_BINARY or FTS3_HASH_STRING. The value of keyClass
120558 ** determines what kind of key the hash table will use. "copyKey" is
120559 ** true if the hash table should make its own private copy of keys and
120560 ** false if it should just use the supplied pointer.
120562 SQLITE_PRIVATE void sqlite3Fts3HashInit(Fts3Hash *pNew, char keyClass, char copyKey){
120563 assert( pNew!=0 );
120564 assert( keyClass>=FTS3_HASH_STRING && keyClass<=FTS3_HASH_BINARY );
120565 pNew->keyClass = keyClass;
120566 pNew->copyKey = copyKey;
120567 pNew->first = 0;
120568 pNew->count = 0;
120569 pNew->htsize = 0;
120570 pNew->ht = 0;
120573 /* Remove all entries from a hash table. Reclaim all memory.
120574 ** Call this routine to delete a hash table or to reset a hash table
120575 ** to the empty state.
120577 SQLITE_PRIVATE void sqlite3Fts3HashClear(Fts3Hash *pH){
120578 Fts3HashElem *elem; /* For looping over all elements of the table */
120580 assert( pH!=0 );
120581 elem = pH->first;
120582 pH->first = 0;
120583 fts3HashFree(pH->ht);
120584 pH->ht = 0;
120585 pH->htsize = 0;
120586 while( elem ){
120587 Fts3HashElem *next_elem = elem->next;
120588 if( pH->copyKey && elem->pKey ){
120589 fts3HashFree(elem->pKey);
120591 fts3HashFree(elem);
120592 elem = next_elem;
120594 pH->count = 0;
120598 ** Hash and comparison functions when the mode is FTS3_HASH_STRING
120600 static int fts3StrHash(const void *pKey, int nKey){
120601 const char *z = (const char *)pKey;
120602 int h = 0;
120603 if( nKey<=0 ) nKey = (int) strlen(z);
120604 while( nKey > 0 ){
120605 h = (h<<3) ^ h ^ *z++;
120606 nKey--;
120608 return h & 0x7fffffff;
120610 static int fts3StrCompare(const void *pKey1, int n1, const void *pKey2, int n2){
120611 if( n1!=n2 ) return 1;
120612 return strncmp((const char*)pKey1,(const char*)pKey2,n1);
120616 ** Hash and comparison functions when the mode is FTS3_HASH_BINARY
120618 static int fts3BinHash(const void *pKey, int nKey){
120619 int h = 0;
120620 const char *z = (const char *)pKey;
120621 while( nKey-- > 0 ){
120622 h = (h<<3) ^ h ^ *(z++);
120624 return h & 0x7fffffff;
120626 static int fts3BinCompare(const void *pKey1, int n1, const void *pKey2, int n2){
120627 if( n1!=n2 ) return 1;
120628 return memcmp(pKey1,pKey2,n1);
120632 ** Return a pointer to the appropriate hash function given the key class.
120634 ** The C syntax in this function definition may be unfamilar to some
120635 ** programmers, so we provide the following additional explanation:
120637 ** The name of the function is "ftsHashFunction". The function takes a
120638 ** single parameter "keyClass". The return value of ftsHashFunction()
120639 ** is a pointer to another function. Specifically, the return value
120640 ** of ftsHashFunction() is a pointer to a function that takes two parameters
120641 ** with types "const void*" and "int" and returns an "int".
120643 static int (*ftsHashFunction(int keyClass))(const void*,int){
120644 if( keyClass==FTS3_HASH_STRING ){
120645 return &fts3StrHash;
120646 }else{
120647 assert( keyClass==FTS3_HASH_BINARY );
120648 return &fts3BinHash;
120653 ** Return a pointer to the appropriate hash function given the key class.
120655 ** For help in interpreted the obscure C code in the function definition,
120656 ** see the header comment on the previous function.
120658 static int (*ftsCompareFunction(int keyClass))(const void*,int,const void*,int){
120659 if( keyClass==FTS3_HASH_STRING ){
120660 return &fts3StrCompare;
120661 }else{
120662 assert( keyClass==FTS3_HASH_BINARY );
120663 return &fts3BinCompare;
120667 /* Link an element into the hash table
120669 static void fts3HashInsertElement(
120670 Fts3Hash *pH, /* The complete hash table */
120671 struct _fts3ht *pEntry, /* The entry into which pNew is inserted */
120672 Fts3HashElem *pNew /* The element to be inserted */
120674 Fts3HashElem *pHead; /* First element already in pEntry */
120675 pHead = pEntry->chain;
120676 if( pHead ){
120677 pNew->next = pHead;
120678 pNew->prev = pHead->prev;
120679 if( pHead->prev ){ pHead->prev->next = pNew; }
120680 else { pH->first = pNew; }
120681 pHead->prev = pNew;
120682 }else{
120683 pNew->next = pH->first;
120684 if( pH->first ){ pH->first->prev = pNew; }
120685 pNew->prev = 0;
120686 pH->first = pNew;
120688 pEntry->count++;
120689 pEntry->chain = pNew;
120693 /* Resize the hash table so that it cantains "new_size" buckets.
120694 ** "new_size" must be a power of 2. The hash table might fail
120695 ** to resize if sqliteMalloc() fails.
120697 ** Return non-zero if a memory allocation error occurs.
120699 static int fts3Rehash(Fts3Hash *pH, int new_size){
120700 struct _fts3ht *new_ht; /* The new hash table */
120701 Fts3HashElem *elem, *next_elem; /* For looping over existing elements */
120702 int (*xHash)(const void*,int); /* The hash function */
120704 assert( (new_size & (new_size-1))==0 );
120705 new_ht = (struct _fts3ht *)fts3HashMalloc( new_size*sizeof(struct _fts3ht) );
120706 if( new_ht==0 ) return 1;
120707 fts3HashFree(pH->ht);
120708 pH->ht = new_ht;
120709 pH->htsize = new_size;
120710 xHash = ftsHashFunction(pH->keyClass);
120711 for(elem=pH->first, pH->first=0; elem; elem = next_elem){
120712 int h = (*xHash)(elem->pKey, elem->nKey) & (new_size-1);
120713 next_elem = elem->next;
120714 fts3HashInsertElement(pH, &new_ht[h], elem);
120716 return 0;
120719 /* This function (for internal use only) locates an element in an
120720 ** hash table that matches the given key. The hash for this key has
120721 ** already been computed and is passed as the 4th parameter.
120723 static Fts3HashElem *fts3FindElementByHash(
120724 const Fts3Hash *pH, /* The pH to be searched */
120725 const void *pKey, /* The key we are searching for */
120726 int nKey,
120727 int h /* The hash for this key. */
120729 Fts3HashElem *elem; /* Used to loop thru the element list */
120730 int count; /* Number of elements left to test */
120731 int (*xCompare)(const void*,int,const void*,int); /* comparison function */
120733 if( pH->ht ){
120734 struct _fts3ht *pEntry = &pH->ht[h];
120735 elem = pEntry->chain;
120736 count = pEntry->count;
120737 xCompare = ftsCompareFunction(pH->keyClass);
120738 while( count-- && elem ){
120739 if( (*xCompare)(elem->pKey,elem->nKey,pKey,nKey)==0 ){
120740 return elem;
120742 elem = elem->next;
120745 return 0;
120748 /* Remove a single entry from the hash table given a pointer to that
120749 ** element and a hash on the element's key.
120751 static void fts3RemoveElementByHash(
120752 Fts3Hash *pH, /* The pH containing "elem" */
120753 Fts3HashElem* elem, /* The element to be removed from the pH */
120754 int h /* Hash value for the element */
120756 struct _fts3ht *pEntry;
120757 if( elem->prev ){
120758 elem->prev->next = elem->next;
120759 }else{
120760 pH->first = elem->next;
120762 if( elem->next ){
120763 elem->next->prev = elem->prev;
120765 pEntry = &pH->ht[h];
120766 if( pEntry->chain==elem ){
120767 pEntry->chain = elem->next;
120769 pEntry->count--;
120770 if( pEntry->count<=0 ){
120771 pEntry->chain = 0;
120773 if( pH->copyKey && elem->pKey ){
120774 fts3HashFree(elem->pKey);
120776 fts3HashFree( elem );
120777 pH->count--;
120778 if( pH->count<=0 ){
120779 assert( pH->first==0 );
120780 assert( pH->count==0 );
120781 fts3HashClear(pH);
120785 SQLITE_PRIVATE Fts3HashElem *sqlite3Fts3HashFindElem(
120786 const Fts3Hash *pH,
120787 const void *pKey,
120788 int nKey
120790 int h; /* A hash on key */
120791 int (*xHash)(const void*,int); /* The hash function */
120793 if( pH==0 || pH->ht==0 ) return 0;
120794 xHash = ftsHashFunction(pH->keyClass);
120795 assert( xHash!=0 );
120796 h = (*xHash)(pKey,nKey);
120797 assert( (pH->htsize & (pH->htsize-1))==0 );
120798 return fts3FindElementByHash(pH,pKey,nKey, h & (pH->htsize-1));
120802 ** Attempt to locate an element of the hash table pH with a key
120803 ** that matches pKey,nKey. Return the data for this element if it is
120804 ** found, or NULL if there is no match.
120806 SQLITE_PRIVATE void *sqlite3Fts3HashFind(const Fts3Hash *pH, const void *pKey, int nKey){
120807 Fts3HashElem *pElem; /* The element that matches key (if any) */
120809 pElem = sqlite3Fts3HashFindElem(pH, pKey, nKey);
120810 return pElem ? pElem->data : 0;
120813 /* Insert an element into the hash table pH. The key is pKey,nKey
120814 ** and the data is "data".
120816 ** If no element exists with a matching key, then a new
120817 ** element is created. A copy of the key is made if the copyKey
120818 ** flag is set. NULL is returned.
120820 ** If another element already exists with the same key, then the
120821 ** new data replaces the old data and the old data is returned.
120822 ** The key is not copied in this instance. If a malloc fails, then
120823 ** the new data is returned and the hash table is unchanged.
120825 ** If the "data" parameter to this function is NULL, then the
120826 ** element corresponding to "key" is removed from the hash table.
120828 SQLITE_PRIVATE void *sqlite3Fts3HashInsert(
120829 Fts3Hash *pH, /* The hash table to insert into */
120830 const void *pKey, /* The key */
120831 int nKey, /* Number of bytes in the key */
120832 void *data /* The data */
120834 int hraw; /* Raw hash value of the key */
120835 int h; /* the hash of the key modulo hash table size */
120836 Fts3HashElem *elem; /* Used to loop thru the element list */
120837 Fts3HashElem *new_elem; /* New element added to the pH */
120838 int (*xHash)(const void*,int); /* The hash function */
120840 assert( pH!=0 );
120841 xHash = ftsHashFunction(pH->keyClass);
120842 assert( xHash!=0 );
120843 hraw = (*xHash)(pKey, nKey);
120844 assert( (pH->htsize & (pH->htsize-1))==0 );
120845 h = hraw & (pH->htsize-1);
120846 elem = fts3FindElementByHash(pH,pKey,nKey,h);
120847 if( elem ){
120848 void *old_data = elem->data;
120849 if( data==0 ){
120850 fts3RemoveElementByHash(pH,elem,h);
120851 }else{
120852 elem->data = data;
120854 return old_data;
120856 if( data==0 ) return 0;
120857 if( (pH->htsize==0 && fts3Rehash(pH,8))
120858 || (pH->count>=pH->htsize && fts3Rehash(pH, pH->htsize*2))
120860 pH->count = 0;
120861 return data;
120863 assert( pH->htsize>0 );
120864 new_elem = (Fts3HashElem*)fts3HashMalloc( sizeof(Fts3HashElem) );
120865 if( new_elem==0 ) return data;
120866 if( pH->copyKey && pKey!=0 ){
120867 new_elem->pKey = fts3HashMalloc( nKey );
120868 if( new_elem->pKey==0 ){
120869 fts3HashFree(new_elem);
120870 return data;
120872 memcpy((void*)new_elem->pKey, pKey, nKey);
120873 }else{
120874 new_elem->pKey = (void*)pKey;
120876 new_elem->nKey = nKey;
120877 pH->count++;
120878 assert( pH->htsize>0 );
120879 assert( (pH->htsize & (pH->htsize-1))==0 );
120880 h = hraw & (pH->htsize-1);
120881 fts3HashInsertElement(pH, &pH->ht[h], new_elem);
120882 new_elem->data = data;
120883 return 0;
120886 #endif /* !defined(SQLITE_CORE) || defined(SQLITE_ENABLE_FTS3) */
120888 /************** End of fts3_hash.c *******************************************/
120889 /************** Begin file fts3_porter.c *************************************/
120891 ** 2006 September 30
120893 ** The author disclaims copyright to this source code. In place of
120894 ** a legal notice, here is a blessing:
120896 ** May you do good and not evil.
120897 ** May you find forgiveness for yourself and forgive others.
120898 ** May you share freely, never taking more than you give.
120900 *************************************************************************
120901 ** Implementation of the full-text-search tokenizer that implements
120902 ** a Porter stemmer.
120906 ** The code in this file is only compiled if:
120908 ** * The FTS3 module is being built as an extension
120909 ** (in which case SQLITE_CORE is not defined), or
120911 ** * The FTS3 module is being built into the core of
120912 ** SQLite (in which case SQLITE_ENABLE_FTS3 is defined).
120914 #if !defined(SQLITE_CORE) || defined(SQLITE_ENABLE_FTS3)
120916 /* #include <assert.h> */
120917 /* #include <stdlib.h> */
120918 /* #include <stdio.h> */
120919 /* #include <string.h> */
120923 ** Class derived from sqlite3_tokenizer
120925 typedef struct porter_tokenizer {
120926 sqlite3_tokenizer base; /* Base class */
120927 } porter_tokenizer;
120930 ** Class derived from sqlit3_tokenizer_cursor
120932 typedef struct porter_tokenizer_cursor {
120933 sqlite3_tokenizer_cursor base;
120934 const char *zInput; /* input we are tokenizing */
120935 int nInput; /* size of the input */
120936 int iOffset; /* current position in zInput */
120937 int iToken; /* index of next token to be returned */
120938 char *zToken; /* storage for current token */
120939 int nAllocated; /* space allocated to zToken buffer */
120940 } porter_tokenizer_cursor;
120944 ** Create a new tokenizer instance.
120946 static int porterCreate(
120947 int argc, const char * const *argv,
120948 sqlite3_tokenizer **ppTokenizer
120950 porter_tokenizer *t;
120952 UNUSED_PARAMETER(argc);
120953 UNUSED_PARAMETER(argv);
120955 t = (porter_tokenizer *) sqlite3_malloc(sizeof(*t));
120956 if( t==NULL ) return SQLITE_NOMEM;
120957 memset(t, 0, sizeof(*t));
120958 *ppTokenizer = &t->base;
120959 return SQLITE_OK;
120963 ** Destroy a tokenizer
120965 static int porterDestroy(sqlite3_tokenizer *pTokenizer){
120966 sqlite3_free(pTokenizer);
120967 return SQLITE_OK;
120971 ** Prepare to begin tokenizing a particular string. The input
120972 ** string to be tokenized is zInput[0..nInput-1]. A cursor
120973 ** used to incrementally tokenize this string is returned in
120974 ** *ppCursor.
120976 static int porterOpen(
120977 sqlite3_tokenizer *pTokenizer, /* The tokenizer */
120978 const char *zInput, int nInput, /* String to be tokenized */
120979 sqlite3_tokenizer_cursor **ppCursor /* OUT: Tokenization cursor */
120981 porter_tokenizer_cursor *c;
120983 UNUSED_PARAMETER(pTokenizer);
120985 c = (porter_tokenizer_cursor *) sqlite3_malloc(sizeof(*c));
120986 if( c==NULL ) return SQLITE_NOMEM;
120988 c->zInput = zInput;
120989 if( zInput==0 ){
120990 c->nInput = 0;
120991 }else if( nInput<0 ){
120992 c->nInput = (int)strlen(zInput);
120993 }else{
120994 c->nInput = nInput;
120996 c->iOffset = 0; /* start tokenizing at the beginning */
120997 c->iToken = 0;
120998 c->zToken = NULL; /* no space allocated, yet. */
120999 c->nAllocated = 0;
121001 *ppCursor = &c->base;
121002 return SQLITE_OK;
121006 ** Close a tokenization cursor previously opened by a call to
121007 ** porterOpen() above.
121009 static int porterClose(sqlite3_tokenizer_cursor *pCursor){
121010 porter_tokenizer_cursor *c = (porter_tokenizer_cursor *) pCursor;
121011 sqlite3_free(c->zToken);
121012 sqlite3_free(c);
121013 return SQLITE_OK;
121016 ** Vowel or consonant
121018 static const char cType[] = {
121019 0, 1, 1, 1, 0, 1, 1, 1, 0, 1, 1, 1, 1, 1, 0, 1, 1, 1, 1, 1, 0,
121020 1, 1, 1, 2, 1
121024 ** isConsonant() and isVowel() determine if their first character in
121025 ** the string they point to is a consonant or a vowel, according
121026 ** to Porter ruls.
121028 ** A consonate is any letter other than 'a', 'e', 'i', 'o', or 'u'.
121029 ** 'Y' is a consonant unless it follows another consonant,
121030 ** in which case it is a vowel.
121032 ** In these routine, the letters are in reverse order. So the 'y' rule
121033 ** is that 'y' is a consonant unless it is followed by another
121034 ** consonent.
121036 static int isVowel(const char*);
121037 static int isConsonant(const char *z){
121038 int j;
121039 char x = *z;
121040 if( x==0 ) return 0;
121041 assert( x>='a' && x<='z' );
121042 j = cType[x-'a'];
121043 if( j<2 ) return j;
121044 return z[1]==0 || isVowel(z + 1);
121046 static int isVowel(const char *z){
121047 int j;
121048 char x = *z;
121049 if( x==0 ) return 0;
121050 assert( x>='a' && x<='z' );
121051 j = cType[x-'a'];
121052 if( j<2 ) return 1-j;
121053 return isConsonant(z + 1);
121057 ** Let any sequence of one or more vowels be represented by V and let
121058 ** C be sequence of one or more consonants. Then every word can be
121059 ** represented as:
121061 ** [C] (VC){m} [V]
121063 ** In prose: A word is an optional consonant followed by zero or
121064 ** vowel-consonant pairs followed by an optional vowel. "m" is the
121065 ** number of vowel consonant pairs. This routine computes the value
121066 ** of m for the first i bytes of a word.
121068 ** Return true if the m-value for z is 1 or more. In other words,
121069 ** return true if z contains at least one vowel that is followed
121070 ** by a consonant.
121072 ** In this routine z[] is in reverse order. So we are really looking
121073 ** for an instance of of a consonant followed by a vowel.
121075 static int m_gt_0(const char *z){
121076 while( isVowel(z) ){ z++; }
121077 if( *z==0 ) return 0;
121078 while( isConsonant(z) ){ z++; }
121079 return *z!=0;
121082 /* Like mgt0 above except we are looking for a value of m which is
121083 ** exactly 1
121085 static int m_eq_1(const char *z){
121086 while( isVowel(z) ){ z++; }
121087 if( *z==0 ) return 0;
121088 while( isConsonant(z) ){ z++; }
121089 if( *z==0 ) return 0;
121090 while( isVowel(z) ){ z++; }
121091 if( *z==0 ) return 1;
121092 while( isConsonant(z) ){ z++; }
121093 return *z==0;
121096 /* Like mgt0 above except we are looking for a value of m>1 instead
121097 ** or m>0
121099 static int m_gt_1(const char *z){
121100 while( isVowel(z) ){ z++; }
121101 if( *z==0 ) return 0;
121102 while( isConsonant(z) ){ z++; }
121103 if( *z==0 ) return 0;
121104 while( isVowel(z) ){ z++; }
121105 if( *z==0 ) return 0;
121106 while( isConsonant(z) ){ z++; }
121107 return *z!=0;
121111 ** Return TRUE if there is a vowel anywhere within z[0..n-1]
121113 static int hasVowel(const char *z){
121114 while( isConsonant(z) ){ z++; }
121115 return *z!=0;
121119 ** Return TRUE if the word ends in a double consonant.
121121 ** The text is reversed here. So we are really looking at
121122 ** the first two characters of z[].
121124 static int doubleConsonant(const char *z){
121125 return isConsonant(z) && z[0]==z[1];
121129 ** Return TRUE if the word ends with three letters which
121130 ** are consonant-vowel-consonent and where the final consonant
121131 ** is not 'w', 'x', or 'y'.
121133 ** The word is reversed here. So we are really checking the
121134 ** first three letters and the first one cannot be in [wxy].
121136 static int star_oh(const char *z){
121137 return
121138 isConsonant(z) &&
121139 z[0]!='w' && z[0]!='x' && z[0]!='y' &&
121140 isVowel(z+1) &&
121141 isConsonant(z+2);
121145 ** If the word ends with zFrom and xCond() is true for the stem
121146 ** of the word that preceeds the zFrom ending, then change the
121147 ** ending to zTo.
121149 ** The input word *pz and zFrom are both in reverse order. zTo
121150 ** is in normal order.
121152 ** Return TRUE if zFrom matches. Return FALSE if zFrom does not
121153 ** match. Not that TRUE is returned even if xCond() fails and
121154 ** no substitution occurs.
121156 static int stem(
121157 char **pz, /* The word being stemmed (Reversed) */
121158 const char *zFrom, /* If the ending matches this... (Reversed) */
121159 const char *zTo, /* ... change the ending to this (not reversed) */
121160 int (*xCond)(const char*) /* Condition that must be true */
121162 char *z = *pz;
121163 while( *zFrom && *zFrom==*z ){ z++; zFrom++; }
121164 if( *zFrom!=0 ) return 0;
121165 if( xCond && !xCond(z) ) return 1;
121166 while( *zTo ){
121167 *(--z) = *(zTo++);
121169 *pz = z;
121170 return 1;
121174 ** This is the fallback stemmer used when the porter stemmer is
121175 ** inappropriate. The input word is copied into the output with
121176 ** US-ASCII case folding. If the input word is too long (more
121177 ** than 20 bytes if it contains no digits or more than 6 bytes if
121178 ** it contains digits) then word is truncated to 20 or 6 bytes
121179 ** by taking 10 or 3 bytes from the beginning and end.
121181 static void copy_stemmer(const char *zIn, int nIn, char *zOut, int *pnOut){
121182 int i, mx, j;
121183 int hasDigit = 0;
121184 for(i=0; i<nIn; i++){
121185 char c = zIn[i];
121186 if( c>='A' && c<='Z' ){
121187 zOut[i] = c - 'A' + 'a';
121188 }else{
121189 if( c>='0' && c<='9' ) hasDigit = 1;
121190 zOut[i] = c;
121193 mx = hasDigit ? 3 : 10;
121194 if( nIn>mx*2 ){
121195 for(j=mx, i=nIn-mx; i<nIn; i++, j++){
121196 zOut[j] = zOut[i];
121198 i = j;
121200 zOut[i] = 0;
121201 *pnOut = i;
121206 ** Stem the input word zIn[0..nIn-1]. Store the output in zOut.
121207 ** zOut is at least big enough to hold nIn bytes. Write the actual
121208 ** size of the output word (exclusive of the '\0' terminator) into *pnOut.
121210 ** Any upper-case characters in the US-ASCII character set ([A-Z])
121211 ** are converted to lower case. Upper-case UTF characters are
121212 ** unchanged.
121214 ** Words that are longer than about 20 bytes are stemmed by retaining
121215 ** a few bytes from the beginning and the end of the word. If the
121216 ** word contains digits, 3 bytes are taken from the beginning and
121217 ** 3 bytes from the end. For long words without digits, 10 bytes
121218 ** are taken from each end. US-ASCII case folding still applies.
121220 ** If the input word contains not digits but does characters not
121221 ** in [a-zA-Z] then no stemming is attempted and this routine just
121222 ** copies the input into the input into the output with US-ASCII
121223 ** case folding.
121225 ** Stemming never increases the length of the word. So there is
121226 ** no chance of overflowing the zOut buffer.
121228 static void porter_stemmer(const char *zIn, int nIn, char *zOut, int *pnOut){
121229 int i, j;
121230 char zReverse[28];
121231 char *z, *z2;
121232 if( nIn<3 || nIn>=(int)sizeof(zReverse)-7 ){
121233 /* The word is too big or too small for the porter stemmer.
121234 ** Fallback to the copy stemmer */
121235 copy_stemmer(zIn, nIn, zOut, pnOut);
121236 return;
121238 for(i=0, j=sizeof(zReverse)-6; i<nIn; i++, j--){
121239 char c = zIn[i];
121240 if( c>='A' && c<='Z' ){
121241 zReverse[j] = c + 'a' - 'A';
121242 }else if( c>='a' && c<='z' ){
121243 zReverse[j] = c;
121244 }else{
121245 /* The use of a character not in [a-zA-Z] means that we fallback
121246 ** to the copy stemmer */
121247 copy_stemmer(zIn, nIn, zOut, pnOut);
121248 return;
121251 memset(&zReverse[sizeof(zReverse)-5], 0, 5);
121252 z = &zReverse[j+1];
121255 /* Step 1a */
121256 if( z[0]=='s' ){
121258 !stem(&z, "sess", "ss", 0) &&
121259 !stem(&z, "sei", "i", 0) &&
121260 !stem(&z, "ss", "ss", 0)
121266 /* Step 1b */
121267 z2 = z;
121268 if( stem(&z, "dee", "ee", m_gt_0) ){
121269 /* Do nothing. The work was all in the test */
121270 }else if(
121271 (stem(&z, "gni", "", hasVowel) || stem(&z, "de", "", hasVowel))
121272 && z!=z2
121274 if( stem(&z, "ta", "ate", 0) ||
121275 stem(&z, "lb", "ble", 0) ||
121276 stem(&z, "zi", "ize", 0) ){
121277 /* Do nothing. The work was all in the test */
121278 }else if( doubleConsonant(z) && (*z!='l' && *z!='s' && *z!='z') ){
121280 }else if( m_eq_1(z) && star_oh(z) ){
121281 *(--z) = 'e';
121285 /* Step 1c */
121286 if( z[0]=='y' && hasVowel(z+1) ){
121287 z[0] = 'i';
121290 /* Step 2 */
121291 switch( z[1] ){
121292 case 'a':
121293 stem(&z, "lanoita", "ate", m_gt_0) ||
121294 stem(&z, "lanoit", "tion", m_gt_0);
121295 break;
121296 case 'c':
121297 stem(&z, "icne", "ence", m_gt_0) ||
121298 stem(&z, "icna", "ance", m_gt_0);
121299 break;
121300 case 'e':
121301 stem(&z, "rezi", "ize", m_gt_0);
121302 break;
121303 case 'g':
121304 stem(&z, "igol", "log", m_gt_0);
121305 break;
121306 case 'l':
121307 stem(&z, "ilb", "ble", m_gt_0) ||
121308 stem(&z, "illa", "al", m_gt_0) ||
121309 stem(&z, "iltne", "ent", m_gt_0) ||
121310 stem(&z, "ile", "e", m_gt_0) ||
121311 stem(&z, "ilsuo", "ous", m_gt_0);
121312 break;
121313 case 'o':
121314 stem(&z, "noitazi", "ize", m_gt_0) ||
121315 stem(&z, "noita", "ate", m_gt_0) ||
121316 stem(&z, "rota", "ate", m_gt_0);
121317 break;
121318 case 's':
121319 stem(&z, "msila", "al", m_gt_0) ||
121320 stem(&z, "ssenevi", "ive", m_gt_0) ||
121321 stem(&z, "ssenluf", "ful", m_gt_0) ||
121322 stem(&z, "ssensuo", "ous", m_gt_0);
121323 break;
121324 case 't':
121325 stem(&z, "itila", "al", m_gt_0) ||
121326 stem(&z, "itivi", "ive", m_gt_0) ||
121327 stem(&z, "itilib", "ble", m_gt_0);
121328 break;
121331 /* Step 3 */
121332 switch( z[0] ){
121333 case 'e':
121334 stem(&z, "etaci", "ic", m_gt_0) ||
121335 stem(&z, "evita", "", m_gt_0) ||
121336 stem(&z, "ezila", "al", m_gt_0);
121337 break;
121338 case 'i':
121339 stem(&z, "itici", "ic", m_gt_0);
121340 break;
121341 case 'l':
121342 stem(&z, "laci", "ic", m_gt_0) ||
121343 stem(&z, "luf", "", m_gt_0);
121344 break;
121345 case 's':
121346 stem(&z, "ssen", "", m_gt_0);
121347 break;
121350 /* Step 4 */
121351 switch( z[1] ){
121352 case 'a':
121353 if( z[0]=='l' && m_gt_1(z+2) ){
121354 z += 2;
121356 break;
121357 case 'c':
121358 if( z[0]=='e' && z[2]=='n' && (z[3]=='a' || z[3]=='e') && m_gt_1(z+4) ){
121359 z += 4;
121361 break;
121362 case 'e':
121363 if( z[0]=='r' && m_gt_1(z+2) ){
121364 z += 2;
121366 break;
121367 case 'i':
121368 if( z[0]=='c' && m_gt_1(z+2) ){
121369 z += 2;
121371 break;
121372 case 'l':
121373 if( z[0]=='e' && z[2]=='b' && (z[3]=='a' || z[3]=='i') && m_gt_1(z+4) ){
121374 z += 4;
121376 break;
121377 case 'n':
121378 if( z[0]=='t' ){
121379 if( z[2]=='a' ){
121380 if( m_gt_1(z+3) ){
121381 z += 3;
121383 }else if( z[2]=='e' ){
121384 stem(&z, "tneme", "", m_gt_1) ||
121385 stem(&z, "tnem", "", m_gt_1) ||
121386 stem(&z, "tne", "", m_gt_1);
121389 break;
121390 case 'o':
121391 if( z[0]=='u' ){
121392 if( m_gt_1(z+2) ){
121393 z += 2;
121395 }else if( z[3]=='s' || z[3]=='t' ){
121396 stem(&z, "noi", "", m_gt_1);
121398 break;
121399 case 's':
121400 if( z[0]=='m' && z[2]=='i' && m_gt_1(z+3) ){
121401 z += 3;
121403 break;
121404 case 't':
121405 stem(&z, "eta", "", m_gt_1) ||
121406 stem(&z, "iti", "", m_gt_1);
121407 break;
121408 case 'u':
121409 if( z[0]=='s' && z[2]=='o' && m_gt_1(z+3) ){
121410 z += 3;
121412 break;
121413 case 'v':
121414 case 'z':
121415 if( z[0]=='e' && z[2]=='i' && m_gt_1(z+3) ){
121416 z += 3;
121418 break;
121421 /* Step 5a */
121422 if( z[0]=='e' ){
121423 if( m_gt_1(z+1) ){
121425 }else if( m_eq_1(z+1) && !star_oh(z+1) ){
121430 /* Step 5b */
121431 if( m_gt_1(z) && z[0]=='l' && z[1]=='l' ){
121435 /* z[] is now the stemmed word in reverse order. Flip it back
121436 ** around into forward order and return.
121438 *pnOut = i = (int)strlen(z);
121439 zOut[i] = 0;
121440 while( *z ){
121441 zOut[--i] = *(z++);
121446 ** Characters that can be part of a token. We assume any character
121447 ** whose value is greater than 0x80 (any UTF character) can be
121448 ** part of a token. In other words, delimiters all must have
121449 ** values of 0x7f or lower.
121451 static const char porterIdChar[] = {
121452 /* x0 x1 x2 x3 x4 x5 x6 x7 x8 x9 xA xB xC xD xE xF */
121453 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 0, 0, 0, 0, 0, 0, /* 3x */
121454 0, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, /* 4x */
121455 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 0, 0, 0, 0, 1, /* 5x */
121456 0, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, /* 6x */
121457 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 0, 0, 0, 0, 0, /* 7x */
121459 #define isDelim(C) (((ch=C)&0x80)==0 && (ch<0x30 || !porterIdChar[ch-0x30]))
121462 ** Extract the next token from a tokenization cursor. The cursor must
121463 ** have been opened by a prior call to porterOpen().
121465 static int porterNext(
121466 sqlite3_tokenizer_cursor *pCursor, /* Cursor returned by porterOpen */
121467 const char **pzToken, /* OUT: *pzToken is the token text */
121468 int *pnBytes, /* OUT: Number of bytes in token */
121469 int *piStartOffset, /* OUT: Starting offset of token */
121470 int *piEndOffset, /* OUT: Ending offset of token */
121471 int *piPosition /* OUT: Position integer of token */
121473 porter_tokenizer_cursor *c = (porter_tokenizer_cursor *) pCursor;
121474 const char *z = c->zInput;
121476 while( c->iOffset<c->nInput ){
121477 int iStartOffset, ch;
121479 /* Scan past delimiter characters */
121480 while( c->iOffset<c->nInput && isDelim(z[c->iOffset]) ){
121481 c->iOffset++;
121484 /* Count non-delimiter characters. */
121485 iStartOffset = c->iOffset;
121486 while( c->iOffset<c->nInput && !isDelim(z[c->iOffset]) ){
121487 c->iOffset++;
121490 if( c->iOffset>iStartOffset ){
121491 int n = c->iOffset-iStartOffset;
121492 if( n>c->nAllocated ){
121493 char *pNew;
121494 c->nAllocated = n+20;
121495 pNew = sqlite3_realloc(c->zToken, c->nAllocated);
121496 if( !pNew ) return SQLITE_NOMEM;
121497 c->zToken = pNew;
121499 porter_stemmer(&z[iStartOffset], n, c->zToken, pnBytes);
121500 *pzToken = c->zToken;
121501 *piStartOffset = iStartOffset;
121502 *piEndOffset = c->iOffset;
121503 *piPosition = c->iToken++;
121504 return SQLITE_OK;
121507 return SQLITE_DONE;
121511 ** The set of routines that implement the porter-stemmer tokenizer
121513 static const sqlite3_tokenizer_module porterTokenizerModule = {
121515 porterCreate,
121516 porterDestroy,
121517 porterOpen,
121518 porterClose,
121519 porterNext,
121523 ** Allocate a new porter tokenizer. Return a pointer to the new
121524 ** tokenizer in *ppModule
121526 SQLITE_PRIVATE void sqlite3Fts3PorterTokenizerModule(
121527 sqlite3_tokenizer_module const**ppModule
121529 *ppModule = &porterTokenizerModule;
121532 #endif /* !defined(SQLITE_CORE) || defined(SQLITE_ENABLE_FTS3) */
121534 /************** End of fts3_porter.c *****************************************/
121535 /************** Begin file fts3_tokenizer.c **********************************/
121537 ** 2007 June 22
121539 ** The author disclaims copyright to this source code. In place of
121540 ** a legal notice, here is a blessing:
121542 ** May you do good and not evil.
121543 ** May you find forgiveness for yourself and forgive others.
121544 ** May you share freely, never taking more than you give.
121546 ******************************************************************************
121548 ** This is part of an SQLite module implementing full-text search.
121549 ** This particular file implements the generic tokenizer interface.
121553 ** The code in this file is only compiled if:
121555 ** * The FTS3 module is being built as an extension
121556 ** (in which case SQLITE_CORE is not defined), or
121558 ** * The FTS3 module is being built into the core of
121559 ** SQLite (in which case SQLITE_ENABLE_FTS3 is defined).
121561 #if !defined(SQLITE_CORE) || defined(SQLITE_ENABLE_FTS3)
121563 /* #include <assert.h> */
121564 /* #include <string.h> */
121567 ** Implementation of the SQL scalar function for accessing the underlying
121568 ** hash table. This function may be called as follows:
121570 ** SELECT <function-name>(<key-name>);
121571 ** SELECT <function-name>(<key-name>, <pointer>);
121573 ** where <function-name> is the name passed as the second argument
121574 ** to the sqlite3Fts3InitHashTable() function (e.g. 'fts3_tokenizer').
121576 ** If the <pointer> argument is specified, it must be a blob value
121577 ** containing a pointer to be stored as the hash data corresponding
121578 ** to the string <key-name>. If <pointer> is not specified, then
121579 ** the string <key-name> must already exist in the has table. Otherwise,
121580 ** an error is returned.
121582 ** Whether or not the <pointer> argument is specified, the value returned
121583 ** is a blob containing the pointer stored as the hash data corresponding
121584 ** to string <key-name> (after the hash-table is updated, if applicable).
121586 static void scalarFunc(
121587 sqlite3_context *context,
121588 int argc,
121589 sqlite3_value **argv
121591 Fts3Hash *pHash;
121592 void *pPtr = 0;
121593 const unsigned char *zName;
121594 int nName;
121596 assert( argc==1 || argc==2 );
121598 pHash = (Fts3Hash *)sqlite3_user_data(context);
121600 zName = sqlite3_value_text(argv[0]);
121601 nName = sqlite3_value_bytes(argv[0])+1;
121603 if( argc==2 ){
121604 void *pOld;
121605 int n = sqlite3_value_bytes(argv[1]);
121606 if( n!=sizeof(pPtr) ){
121607 sqlite3_result_error(context, "argument type mismatch", -1);
121608 return;
121610 pPtr = *(void **)sqlite3_value_blob(argv[1]);
121611 pOld = sqlite3Fts3HashInsert(pHash, (void *)zName, nName, pPtr);
121612 if( pOld==pPtr ){
121613 sqlite3_result_error(context, "out of memory", -1);
121614 return;
121616 }else{
121617 pPtr = sqlite3Fts3HashFind(pHash, zName, nName);
121618 if( !pPtr ){
121619 char *zErr = sqlite3_mprintf("unknown tokenizer: %s", zName);
121620 sqlite3_result_error(context, zErr, -1);
121621 sqlite3_free(zErr);
121622 return;
121626 sqlite3_result_blob(context, (void *)&pPtr, sizeof(pPtr), SQLITE_TRANSIENT);
121629 SQLITE_PRIVATE int sqlite3Fts3IsIdChar(char c){
121630 static const char isFtsIdChar[] = {
121631 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, /* 0x */
121632 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, /* 1x */
121633 0, 0, 0, 0, 1, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, /* 2x */
121634 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 0, 0, 0, 0, 0, 0, /* 3x */
121635 0, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, /* 4x */
121636 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 0, 0, 0, 0, 1, /* 5x */
121637 0, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, /* 6x */
121638 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 0, 0, 0, 0, 0, /* 7x */
121640 return (c&0x80 || isFtsIdChar[(int)(c)]);
121643 SQLITE_PRIVATE const char *sqlite3Fts3NextToken(const char *zStr, int *pn){
121644 const char *z1;
121645 const char *z2 = 0;
121647 /* Find the start of the next token. */
121648 z1 = zStr;
121649 while( z2==0 ){
121650 char c = *z1;
121651 switch( c ){
121652 case '\0': return 0; /* No more tokens here */
121653 case '\'':
121654 case '"':
121655 case '`': {
121656 z2 = z1;
121657 while( *++z2 && (*z2!=c || *++z2==c) );
121658 break;
121660 case '[':
121661 z2 = &z1[1];
121662 while( *z2 && z2[0]!=']' ) z2++;
121663 if( *z2 ) z2++;
121664 break;
121666 default:
121667 if( sqlite3Fts3IsIdChar(*z1) ){
121668 z2 = &z1[1];
121669 while( sqlite3Fts3IsIdChar(*z2) ) z2++;
121670 }else{
121671 z1++;
121676 *pn = (int)(z2-z1);
121677 return z1;
121680 SQLITE_PRIVATE int sqlite3Fts3InitTokenizer(
121681 Fts3Hash *pHash, /* Tokenizer hash table */
121682 const char *zArg, /* Tokenizer name */
121683 sqlite3_tokenizer **ppTok, /* OUT: Tokenizer (if applicable) */
121684 char **pzErr /* OUT: Set to malloced error message */
121686 int rc;
121687 char *z = (char *)zArg;
121688 int n = 0;
121689 char *zCopy;
121690 char *zEnd; /* Pointer to nul-term of zCopy */
121691 sqlite3_tokenizer_module *m;
121693 zCopy = sqlite3_mprintf("%s", zArg);
121694 if( !zCopy ) return SQLITE_NOMEM;
121695 zEnd = &zCopy[strlen(zCopy)];
121697 z = (char *)sqlite3Fts3NextToken(zCopy, &n);
121698 z[n] = '\0';
121699 sqlite3Fts3Dequote(z);
121701 m = (sqlite3_tokenizer_module *)sqlite3Fts3HashFind(pHash,z,(int)strlen(z)+1);
121702 if( !m ){
121703 *pzErr = sqlite3_mprintf("unknown tokenizer: %s", z);
121704 rc = SQLITE_ERROR;
121705 }else{
121706 char const **aArg = 0;
121707 int iArg = 0;
121708 z = &z[n+1];
121709 while( z<zEnd && (NULL!=(z = (char *)sqlite3Fts3NextToken(z, &n))) ){
121710 int nNew = sizeof(char *)*(iArg+1);
121711 char const **aNew = (const char **)sqlite3_realloc((void *)aArg, nNew);
121712 if( !aNew ){
121713 sqlite3_free(zCopy);
121714 sqlite3_free((void *)aArg);
121715 return SQLITE_NOMEM;
121717 aArg = aNew;
121718 aArg[iArg++] = z;
121719 z[n] = '\0';
121720 sqlite3Fts3Dequote(z);
121721 z = &z[n+1];
121723 rc = m->xCreate(iArg, aArg, ppTok);
121724 assert( rc!=SQLITE_OK || *ppTok );
121725 if( rc!=SQLITE_OK ){
121726 *pzErr = sqlite3_mprintf("unknown tokenizer");
121727 }else{
121728 (*ppTok)->pModule = m;
121730 sqlite3_free((void *)aArg);
121733 sqlite3_free(zCopy);
121734 return rc;
121738 #ifdef SQLITE_TEST
121740 /* #include <tcl.h> */
121741 /* #include <string.h> */
121744 ** Implementation of a special SQL scalar function for testing tokenizers
121745 ** designed to be used in concert with the Tcl testing framework. This
121746 ** function must be called with two arguments:
121748 ** SELECT <function-name>(<key-name>, <input-string>);
121749 ** SELECT <function-name>(<key-name>, <pointer>);
121751 ** where <function-name> is the name passed as the second argument
121752 ** to the sqlite3Fts3InitHashTable() function (e.g. 'fts3_tokenizer')
121753 ** concatenated with the string '_test' (e.g. 'fts3_tokenizer_test').
121755 ** The return value is a string that may be interpreted as a Tcl
121756 ** list. For each token in the <input-string>, three elements are
121757 ** added to the returned list. The first is the token position, the
121758 ** second is the token text (folded, stemmed, etc.) and the third is the
121759 ** substring of <input-string> associated with the token. For example,
121760 ** using the built-in "simple" tokenizer:
121762 ** SELECT fts_tokenizer_test('simple', 'I don't see how');
121764 ** will return the string:
121766 ** "{0 i I 1 dont don't 2 see see 3 how how}"
121769 static void testFunc(
121770 sqlite3_context *context,
121771 int argc,
121772 sqlite3_value **argv
121774 Fts3Hash *pHash;
121775 sqlite3_tokenizer_module *p;
121776 sqlite3_tokenizer *pTokenizer = 0;
121777 sqlite3_tokenizer_cursor *pCsr = 0;
121779 const char *zErr = 0;
121781 const char *zName;
121782 int nName;
121783 const char *zInput;
121784 int nInput;
121786 const char *zArg = 0;
121788 const char *zToken;
121789 int nToken;
121790 int iStart;
121791 int iEnd;
121792 int iPos;
121794 Tcl_Obj *pRet;
121796 assert( argc==2 || argc==3 );
121798 nName = sqlite3_value_bytes(argv[0]);
121799 zName = (const char *)sqlite3_value_text(argv[0]);
121800 nInput = sqlite3_value_bytes(argv[argc-1]);
121801 zInput = (const char *)sqlite3_value_text(argv[argc-1]);
121803 if( argc==3 ){
121804 zArg = (const char *)sqlite3_value_text(argv[1]);
121807 pHash = (Fts3Hash *)sqlite3_user_data(context);
121808 p = (sqlite3_tokenizer_module *)sqlite3Fts3HashFind(pHash, zName, nName+1);
121810 if( !p ){
121811 char *zErr = sqlite3_mprintf("unknown tokenizer: %s", zName);
121812 sqlite3_result_error(context, zErr, -1);
121813 sqlite3_free(zErr);
121814 return;
121817 pRet = Tcl_NewObj();
121818 Tcl_IncrRefCount(pRet);
121820 if( SQLITE_OK!=p->xCreate(zArg ? 1 : 0, &zArg, &pTokenizer) ){
121821 zErr = "error in xCreate()";
121822 goto finish;
121824 pTokenizer->pModule = p;
121825 if( SQLITE_OK!=p->xOpen(pTokenizer, zInput, nInput, &pCsr) ){
121826 zErr = "error in xOpen()";
121827 goto finish;
121829 pCsr->pTokenizer = pTokenizer;
121831 while( SQLITE_OK==p->xNext(pCsr, &zToken, &nToken, &iStart, &iEnd, &iPos) ){
121832 Tcl_ListObjAppendElement(0, pRet, Tcl_NewIntObj(iPos));
121833 Tcl_ListObjAppendElement(0, pRet, Tcl_NewStringObj(zToken, nToken));
121834 zToken = &zInput[iStart];
121835 nToken = iEnd-iStart;
121836 Tcl_ListObjAppendElement(0, pRet, Tcl_NewStringObj(zToken, nToken));
121839 if( SQLITE_OK!=p->xClose(pCsr) ){
121840 zErr = "error in xClose()";
121841 goto finish;
121843 if( SQLITE_OK!=p->xDestroy(pTokenizer) ){
121844 zErr = "error in xDestroy()";
121845 goto finish;
121848 finish:
121849 if( zErr ){
121850 sqlite3_result_error(context, zErr, -1);
121851 }else{
121852 sqlite3_result_text(context, Tcl_GetString(pRet), -1, SQLITE_TRANSIENT);
121854 Tcl_DecrRefCount(pRet);
121857 static
121858 int registerTokenizer(
121859 sqlite3 *db,
121860 char *zName,
121861 const sqlite3_tokenizer_module *p
121863 int rc;
121864 sqlite3_stmt *pStmt;
121865 const char zSql[] = "SELECT fts3_tokenizer(?, ?)";
121867 rc = sqlite3_prepare_v2(db, zSql, -1, &pStmt, 0);
121868 if( rc!=SQLITE_OK ){
121869 return rc;
121872 sqlite3_bind_text(pStmt, 1, zName, -1, SQLITE_STATIC);
121873 sqlite3_bind_blob(pStmt, 2, &p, sizeof(p), SQLITE_STATIC);
121874 sqlite3_step(pStmt);
121876 return sqlite3_finalize(pStmt);
121879 static
121880 int queryTokenizer(
121881 sqlite3 *db,
121882 char *zName,
121883 const sqlite3_tokenizer_module **pp
121885 int rc;
121886 sqlite3_stmt *pStmt;
121887 const char zSql[] = "SELECT fts3_tokenizer(?)";
121889 *pp = 0;
121890 rc = sqlite3_prepare_v2(db, zSql, -1, &pStmt, 0);
121891 if( rc!=SQLITE_OK ){
121892 return rc;
121895 sqlite3_bind_text(pStmt, 1, zName, -1, SQLITE_STATIC);
121896 if( SQLITE_ROW==sqlite3_step(pStmt) ){
121897 if( sqlite3_column_type(pStmt, 0)==SQLITE_BLOB ){
121898 memcpy((void *)pp, sqlite3_column_blob(pStmt, 0), sizeof(*pp));
121902 return sqlite3_finalize(pStmt);
121905 SQLITE_PRIVATE void sqlite3Fts3SimpleTokenizerModule(sqlite3_tokenizer_module const**ppModule);
121908 ** Implementation of the scalar function fts3_tokenizer_internal_test().
121909 ** This function is used for testing only, it is not included in the
121910 ** build unless SQLITE_TEST is defined.
121912 ** The purpose of this is to test that the fts3_tokenizer() function
121913 ** can be used as designed by the C-code in the queryTokenizer and
121914 ** registerTokenizer() functions above. These two functions are repeated
121915 ** in the README.tokenizer file as an example, so it is important to
121916 ** test them.
121918 ** To run the tests, evaluate the fts3_tokenizer_internal_test() scalar
121919 ** function with no arguments. An assert() will fail if a problem is
121920 ** detected. i.e.:
121922 ** SELECT fts3_tokenizer_internal_test();
121925 static void intTestFunc(
121926 sqlite3_context *context,
121927 int argc,
121928 sqlite3_value **argv
121930 int rc;
121931 const sqlite3_tokenizer_module *p1;
121932 const sqlite3_tokenizer_module *p2;
121933 sqlite3 *db = (sqlite3 *)sqlite3_user_data(context);
121935 UNUSED_PARAMETER(argc);
121936 UNUSED_PARAMETER(argv);
121938 /* Test the query function */
121939 sqlite3Fts3SimpleTokenizerModule(&p1);
121940 rc = queryTokenizer(db, "simple", &p2);
121941 assert( rc==SQLITE_OK );
121942 assert( p1==p2 );
121943 rc = queryTokenizer(db, "nosuchtokenizer", &p2);
121944 assert( rc==SQLITE_ERROR );
121945 assert( p2==0 );
121946 assert( 0==strcmp(sqlite3_errmsg(db), "unknown tokenizer: nosuchtokenizer") );
121948 /* Test the storage function */
121949 rc = registerTokenizer(db, "nosuchtokenizer", p1);
121950 assert( rc==SQLITE_OK );
121951 rc = queryTokenizer(db, "nosuchtokenizer", &p2);
121952 assert( rc==SQLITE_OK );
121953 assert( p2==p1 );
121955 sqlite3_result_text(context, "ok", -1, SQLITE_STATIC);
121958 #endif
121961 ** Set up SQL objects in database db used to access the contents of
121962 ** the hash table pointed to by argument pHash. The hash table must
121963 ** been initialised to use string keys, and to take a private copy
121964 ** of the key when a value is inserted. i.e. by a call similar to:
121966 ** sqlite3Fts3HashInit(pHash, FTS3_HASH_STRING, 1);
121968 ** This function adds a scalar function (see header comment above
121969 ** scalarFunc() in this file for details) and, if ENABLE_TABLE is
121970 ** defined at compilation time, a temporary virtual table (see header
121971 ** comment above struct HashTableVtab) to the database schema. Both
121972 ** provide read/write access to the contents of *pHash.
121974 ** The third argument to this function, zName, is used as the name
121975 ** of both the scalar and, if created, the virtual table.
121977 SQLITE_PRIVATE int sqlite3Fts3InitHashTable(
121978 sqlite3 *db,
121979 Fts3Hash *pHash,
121980 const char *zName
121982 int rc = SQLITE_OK;
121983 void *p = (void *)pHash;
121984 const int any = SQLITE_ANY;
121986 #ifdef SQLITE_TEST
121987 char *zTest = 0;
121988 char *zTest2 = 0;
121989 void *pdb = (void *)db;
121990 zTest = sqlite3_mprintf("%s_test", zName);
121991 zTest2 = sqlite3_mprintf("%s_internal_test", zName);
121992 if( !zTest || !zTest2 ){
121993 rc = SQLITE_NOMEM;
121995 #endif
121997 if( SQLITE_OK==rc ){
121998 rc = sqlite3_create_function(db, zName, 1, any, p, scalarFunc, 0, 0);
122000 if( SQLITE_OK==rc ){
122001 rc = sqlite3_create_function(db, zName, 2, any, p, scalarFunc, 0, 0);
122003 #ifdef SQLITE_TEST
122004 if( SQLITE_OK==rc ){
122005 rc = sqlite3_create_function(db, zTest, 2, any, p, testFunc, 0, 0);
122007 if( SQLITE_OK==rc ){
122008 rc = sqlite3_create_function(db, zTest, 3, any, p, testFunc, 0, 0);
122010 if( SQLITE_OK==rc ){
122011 rc = sqlite3_create_function(db, zTest2, 0, any, pdb, intTestFunc, 0, 0);
122013 #endif
122015 #ifdef SQLITE_TEST
122016 sqlite3_free(zTest);
122017 sqlite3_free(zTest2);
122018 #endif
122020 return rc;
122023 #endif /* !defined(SQLITE_CORE) || defined(SQLITE_ENABLE_FTS3) */
122025 /************** End of fts3_tokenizer.c **************************************/
122026 /************** Begin file fts3_tokenizer1.c *********************************/
122028 ** 2006 Oct 10
122030 ** The author disclaims copyright to this source code. In place of
122031 ** a legal notice, here is a blessing:
122033 ** May you do good and not evil.
122034 ** May you find forgiveness for yourself and forgive others.
122035 ** May you share freely, never taking more than you give.
122037 ******************************************************************************
122039 ** Implementation of the "simple" full-text-search tokenizer.
122043 ** The code in this file is only compiled if:
122045 ** * The FTS3 module is being built as an extension
122046 ** (in which case SQLITE_CORE is not defined), or
122048 ** * The FTS3 module is being built into the core of
122049 ** SQLite (in which case SQLITE_ENABLE_FTS3 is defined).
122051 #if !defined(SQLITE_CORE) || defined(SQLITE_ENABLE_FTS3)
122053 /* #include <assert.h> */
122054 /* #include <stdlib.h> */
122055 /* #include <stdio.h> */
122056 /* #include <string.h> */
122059 typedef struct simple_tokenizer {
122060 sqlite3_tokenizer base;
122061 char delim[128]; /* flag ASCII delimiters */
122062 } simple_tokenizer;
122064 typedef struct simple_tokenizer_cursor {
122065 sqlite3_tokenizer_cursor base;
122066 const char *pInput; /* input we are tokenizing */
122067 int nBytes; /* size of the input */
122068 int iOffset; /* current position in pInput */
122069 int iToken; /* index of next token to be returned */
122070 char *pToken; /* storage for current token */
122071 int nTokenAllocated; /* space allocated to zToken buffer */
122072 } simple_tokenizer_cursor;
122075 static int simpleDelim(simple_tokenizer *t, unsigned char c){
122076 return c<0x80 && t->delim[c];
122078 static int fts3_isalnum(int x){
122079 return (x>='0' && x<='9') || (x>='A' && x<='Z') || (x>='a' && x<='z');
122083 ** Create a new tokenizer instance.
122085 static int simpleCreate(
122086 int argc, const char * const *argv,
122087 sqlite3_tokenizer **ppTokenizer
122089 simple_tokenizer *t;
122091 t = (simple_tokenizer *) sqlite3_malloc(sizeof(*t));
122092 if( t==NULL ) return SQLITE_NOMEM;
122093 memset(t, 0, sizeof(*t));
122095 /* TODO(shess) Delimiters need to remain the same from run to run,
122096 ** else we need to reindex. One solution would be a meta-table to
122097 ** track such information in the database, then we'd only want this
122098 ** information on the initial create.
122100 if( argc>1 ){
122101 int i, n = (int)strlen(argv[1]);
122102 for(i=0; i<n; i++){
122103 unsigned char ch = argv[1][i];
122104 /* We explicitly don't support UTF-8 delimiters for now. */
122105 if( ch>=0x80 ){
122106 sqlite3_free(t);
122107 return SQLITE_ERROR;
122109 t->delim[ch] = 1;
122111 } else {
122112 /* Mark non-alphanumeric ASCII characters as delimiters */
122113 int i;
122114 for(i=1; i<0x80; i++){
122115 t->delim[i] = !fts3_isalnum(i) ? -1 : 0;
122119 *ppTokenizer = &t->base;
122120 return SQLITE_OK;
122124 ** Destroy a tokenizer
122126 static int simpleDestroy(sqlite3_tokenizer *pTokenizer){
122127 sqlite3_free(pTokenizer);
122128 return SQLITE_OK;
122132 ** Prepare to begin tokenizing a particular string. The input
122133 ** string to be tokenized is pInput[0..nBytes-1]. A cursor
122134 ** used to incrementally tokenize this string is returned in
122135 ** *ppCursor.
122137 static int simpleOpen(
122138 sqlite3_tokenizer *pTokenizer, /* The tokenizer */
122139 const char *pInput, int nBytes, /* String to be tokenized */
122140 sqlite3_tokenizer_cursor **ppCursor /* OUT: Tokenization cursor */
122142 simple_tokenizer_cursor *c;
122144 UNUSED_PARAMETER(pTokenizer);
122146 c = (simple_tokenizer_cursor *) sqlite3_malloc(sizeof(*c));
122147 if( c==NULL ) return SQLITE_NOMEM;
122149 c->pInput = pInput;
122150 if( pInput==0 ){
122151 c->nBytes = 0;
122152 }else if( nBytes<0 ){
122153 c->nBytes = (int)strlen(pInput);
122154 }else{
122155 c->nBytes = nBytes;
122157 c->iOffset = 0; /* start tokenizing at the beginning */
122158 c->iToken = 0;
122159 c->pToken = NULL; /* no space allocated, yet. */
122160 c->nTokenAllocated = 0;
122162 *ppCursor = &c->base;
122163 return SQLITE_OK;
122167 ** Close a tokenization cursor previously opened by a call to
122168 ** simpleOpen() above.
122170 static int simpleClose(sqlite3_tokenizer_cursor *pCursor){
122171 simple_tokenizer_cursor *c = (simple_tokenizer_cursor *) pCursor;
122172 sqlite3_free(c->pToken);
122173 sqlite3_free(c);
122174 return SQLITE_OK;
122178 ** Extract the next token from a tokenization cursor. The cursor must
122179 ** have been opened by a prior call to simpleOpen().
122181 static int simpleNext(
122182 sqlite3_tokenizer_cursor *pCursor, /* Cursor returned by simpleOpen */
122183 const char **ppToken, /* OUT: *ppToken is the token text */
122184 int *pnBytes, /* OUT: Number of bytes in token */
122185 int *piStartOffset, /* OUT: Starting offset of token */
122186 int *piEndOffset, /* OUT: Ending offset of token */
122187 int *piPosition /* OUT: Position integer of token */
122189 simple_tokenizer_cursor *c = (simple_tokenizer_cursor *) pCursor;
122190 simple_tokenizer *t = (simple_tokenizer *) pCursor->pTokenizer;
122191 unsigned char *p = (unsigned char *)c->pInput;
122193 while( c->iOffset<c->nBytes ){
122194 int iStartOffset;
122196 /* Scan past delimiter characters */
122197 while( c->iOffset<c->nBytes && simpleDelim(t, p[c->iOffset]) ){
122198 c->iOffset++;
122201 /* Count non-delimiter characters. */
122202 iStartOffset = c->iOffset;
122203 while( c->iOffset<c->nBytes && !simpleDelim(t, p[c->iOffset]) ){
122204 c->iOffset++;
122207 if( c->iOffset>iStartOffset ){
122208 int i, n = c->iOffset-iStartOffset;
122209 if( n>c->nTokenAllocated ){
122210 char *pNew;
122211 c->nTokenAllocated = n+20;
122212 pNew = sqlite3_realloc(c->pToken, c->nTokenAllocated);
122213 if( !pNew ) return SQLITE_NOMEM;
122214 c->pToken = pNew;
122216 for(i=0; i<n; i++){
122217 /* TODO(shess) This needs expansion to handle UTF-8
122218 ** case-insensitivity.
122220 unsigned char ch = p[iStartOffset+i];
122221 c->pToken[i] = (char)((ch>='A' && ch<='Z') ? ch-'A'+'a' : ch);
122223 *ppToken = c->pToken;
122224 *pnBytes = n;
122225 *piStartOffset = iStartOffset;
122226 *piEndOffset = c->iOffset;
122227 *piPosition = c->iToken++;
122229 return SQLITE_OK;
122232 return SQLITE_DONE;
122236 ** The set of routines that implement the simple tokenizer
122238 static const sqlite3_tokenizer_module simpleTokenizerModule = {
122240 simpleCreate,
122241 simpleDestroy,
122242 simpleOpen,
122243 simpleClose,
122244 simpleNext,
122248 ** Allocate a new simple tokenizer. Return a pointer to the new
122249 ** tokenizer in *ppModule
122251 SQLITE_PRIVATE void sqlite3Fts3SimpleTokenizerModule(
122252 sqlite3_tokenizer_module const**ppModule
122254 *ppModule = &simpleTokenizerModule;
122257 #endif /* !defined(SQLITE_CORE) || defined(SQLITE_ENABLE_FTS3) */
122259 /************** End of fts3_tokenizer1.c *************************************/
122260 /************** Begin file fts3_write.c **************************************/
122262 ** 2009 Oct 23
122264 ** The author disclaims copyright to this source code. In place of
122265 ** a legal notice, here is a blessing:
122267 ** May you do good and not evil.
122268 ** May you find forgiveness for yourself and forgive others.
122269 ** May you share freely, never taking more than you give.
122271 ******************************************************************************
122273 ** This file is part of the SQLite FTS3 extension module. Specifically,
122274 ** this file contains code to insert, update and delete rows from FTS3
122275 ** tables. It also contains code to merge FTS3 b-tree segments. Some
122276 ** of the sub-routines used to merge segments are also used by the query
122277 ** code in fts3.c.
122280 #if !defined(SQLITE_CORE) || defined(SQLITE_ENABLE_FTS3)
122282 /* #include <string.h> */
122283 /* #include <assert.h> */
122284 /* #include <stdlib.h> */
122287 ** When full-text index nodes are loaded from disk, the buffer that they
122288 ** are loaded into has the following number of bytes of padding at the end
122289 ** of it. i.e. if a full-text index node is 900 bytes in size, then a buffer
122290 ** of 920 bytes is allocated for it.
122292 ** This means that if we have a pointer into a buffer containing node data,
122293 ** it is always safe to read up to two varints from it without risking an
122294 ** overread, even if the node data is corrupted.
122296 #define FTS3_NODE_PADDING (FTS3_VARINT_MAX*2)
122299 ** Under certain circumstances, b-tree nodes (doclists) can be loaded into
122300 ** memory incrementally instead of all at once. This can be a big performance
122301 ** win (reduced IO and CPU) if SQLite stops calling the virtual table xNext()
122302 ** method before retrieving all query results (as may happen, for example,
122303 ** if a query has a LIMIT clause).
122305 ** Incremental loading is used for b-tree nodes FTS3_NODE_CHUNK_THRESHOLD
122306 ** bytes and larger. Nodes are loaded in chunks of FTS3_NODE_CHUNKSIZE bytes.
122307 ** The code is written so that the hard lower-limit for each of these values
122308 ** is 1. Clearly such small values would be inefficient, but can be useful
122309 ** for testing purposes.
122311 ** If this module is built with SQLITE_TEST defined, these constants may
122312 ** be overridden at runtime for testing purposes. File fts3_test.c contains
122313 ** a Tcl interface to read and write the values.
122315 #ifdef SQLITE_TEST
122316 int test_fts3_node_chunksize = (4*1024);
122317 int test_fts3_node_chunk_threshold = (4*1024)*4;
122318 # define FTS3_NODE_CHUNKSIZE test_fts3_node_chunksize
122319 # define FTS3_NODE_CHUNK_THRESHOLD test_fts3_node_chunk_threshold
122320 #else
122321 # define FTS3_NODE_CHUNKSIZE (4*1024)
122322 # define FTS3_NODE_CHUNK_THRESHOLD (FTS3_NODE_CHUNKSIZE*4)
122323 #endif
122325 typedef struct PendingList PendingList;
122326 typedef struct SegmentNode SegmentNode;
122327 typedef struct SegmentWriter SegmentWriter;
122330 ** An instance of the following data structure is used to build doclists
122331 ** incrementally. See function fts3PendingListAppend() for details.
122333 struct PendingList {
122334 int nData;
122335 char *aData;
122336 int nSpace;
122337 sqlite3_int64 iLastDocid;
122338 sqlite3_int64 iLastCol;
122339 sqlite3_int64 iLastPos;
122344 ** Each cursor has a (possibly empty) linked list of the following objects.
122346 struct Fts3DeferredToken {
122347 Fts3PhraseToken *pToken; /* Pointer to corresponding expr token */
122348 int iCol; /* Column token must occur in */
122349 Fts3DeferredToken *pNext; /* Next in list of deferred tokens */
122350 PendingList *pList; /* Doclist is assembled here */
122354 ** An instance of this structure is used to iterate through the terms on
122355 ** a contiguous set of segment b-tree leaf nodes. Although the details of
122356 ** this structure are only manipulated by code in this file, opaque handles
122357 ** of type Fts3SegReader* are also used by code in fts3.c to iterate through
122358 ** terms when querying the full-text index. See functions:
122360 ** sqlite3Fts3SegReaderNew()
122361 ** sqlite3Fts3SegReaderFree()
122362 ** sqlite3Fts3SegReaderIterate()
122364 ** Methods used to manipulate Fts3SegReader structures:
122366 ** fts3SegReaderNext()
122367 ** fts3SegReaderFirstDocid()
122368 ** fts3SegReaderNextDocid()
122370 struct Fts3SegReader {
122371 int iIdx; /* Index within level, or 0x7FFFFFFF for PT */
122373 sqlite3_int64 iStartBlock; /* Rowid of first leaf block to traverse */
122374 sqlite3_int64 iLeafEndBlock; /* Rowid of final leaf block to traverse */
122375 sqlite3_int64 iEndBlock; /* Rowid of final block in segment (or 0) */
122376 sqlite3_int64 iCurrentBlock; /* Current leaf block (or 0) */
122378 char *aNode; /* Pointer to node data (or NULL) */
122379 int nNode; /* Size of buffer at aNode (or 0) */
122380 int nPopulate; /* If >0, bytes of buffer aNode[] loaded */
122381 sqlite3_blob *pBlob; /* If not NULL, blob handle to read node */
122383 Fts3HashElem **ppNextElem;
122385 /* Variables set by fts3SegReaderNext(). These may be read directly
122386 ** by the caller. They are valid from the time SegmentReaderNew() returns
122387 ** until SegmentReaderNext() returns something other than SQLITE_OK
122388 ** (i.e. SQLITE_DONE).
122390 int nTerm; /* Number of bytes in current term */
122391 char *zTerm; /* Pointer to current term */
122392 int nTermAlloc; /* Allocated size of zTerm buffer */
122393 char *aDoclist; /* Pointer to doclist of current entry */
122394 int nDoclist; /* Size of doclist in current entry */
122396 /* The following variables are used by fts3SegReaderNextDocid() to iterate
122397 ** through the current doclist (aDoclist/nDoclist).
122399 char *pOffsetList;
122400 int nOffsetList; /* For descending pending seg-readers only */
122401 sqlite3_int64 iDocid;
122404 #define fts3SegReaderIsPending(p) ((p)->ppNextElem!=0)
122405 #define fts3SegReaderIsRootOnly(p) ((p)->aNode==(char *)&(p)[1])
122408 ** An instance of this structure is used to create a segment b-tree in the
122409 ** database. The internal details of this type are only accessed by the
122410 ** following functions:
122412 ** fts3SegWriterAdd()
122413 ** fts3SegWriterFlush()
122414 ** fts3SegWriterFree()
122416 struct SegmentWriter {
122417 SegmentNode *pTree; /* Pointer to interior tree structure */
122418 sqlite3_int64 iFirst; /* First slot in %_segments written */
122419 sqlite3_int64 iFree; /* Next free slot in %_segments */
122420 char *zTerm; /* Pointer to previous term buffer */
122421 int nTerm; /* Number of bytes in zTerm */
122422 int nMalloc; /* Size of malloc'd buffer at zMalloc */
122423 char *zMalloc; /* Malloc'd space (possibly) used for zTerm */
122424 int nSize; /* Size of allocation at aData */
122425 int nData; /* Bytes of data in aData */
122426 char *aData; /* Pointer to block from malloc() */
122430 ** Type SegmentNode is used by the following three functions to create
122431 ** the interior part of the segment b+-tree structures (everything except
122432 ** the leaf nodes). These functions and type are only ever used by code
122433 ** within the fts3SegWriterXXX() family of functions described above.
122435 ** fts3NodeAddTerm()
122436 ** fts3NodeWrite()
122437 ** fts3NodeFree()
122439 ** When a b+tree is written to the database (either as a result of a merge
122440 ** or the pending-terms table being flushed), leaves are written into the
122441 ** database file as soon as they are completely populated. The interior of
122442 ** the tree is assembled in memory and written out only once all leaves have
122443 ** been populated and stored. This is Ok, as the b+-tree fanout is usually
122444 ** very large, meaning that the interior of the tree consumes relatively
122445 ** little memory.
122447 struct SegmentNode {
122448 SegmentNode *pParent; /* Parent node (or NULL for root node) */
122449 SegmentNode *pRight; /* Pointer to right-sibling */
122450 SegmentNode *pLeftmost; /* Pointer to left-most node of this depth */
122451 int nEntry; /* Number of terms written to node so far */
122452 char *zTerm; /* Pointer to previous term buffer */
122453 int nTerm; /* Number of bytes in zTerm */
122454 int nMalloc; /* Size of malloc'd buffer at zMalloc */
122455 char *zMalloc; /* Malloc'd space (possibly) used for zTerm */
122456 int nData; /* Bytes of valid data so far */
122457 char *aData; /* Node data */
122461 ** Valid values for the second argument to fts3SqlStmt().
122463 #define SQL_DELETE_CONTENT 0
122464 #define SQL_IS_EMPTY 1
122465 #define SQL_DELETE_ALL_CONTENT 2
122466 #define SQL_DELETE_ALL_SEGMENTS 3
122467 #define SQL_DELETE_ALL_SEGDIR 4
122468 #define SQL_DELETE_ALL_DOCSIZE 5
122469 #define SQL_DELETE_ALL_STAT 6
122470 #define SQL_SELECT_CONTENT_BY_ROWID 7
122471 #define SQL_NEXT_SEGMENT_INDEX 8
122472 #define SQL_INSERT_SEGMENTS 9
122473 #define SQL_NEXT_SEGMENTS_ID 10
122474 #define SQL_INSERT_SEGDIR 11
122475 #define SQL_SELECT_LEVEL 12
122476 #define SQL_SELECT_LEVEL_RANGE 13
122477 #define SQL_SELECT_LEVEL_COUNT 14
122478 #define SQL_SELECT_SEGDIR_MAX_LEVEL 15
122479 #define SQL_DELETE_SEGDIR_LEVEL 16
122480 #define SQL_DELETE_SEGMENTS_RANGE 17
122481 #define SQL_CONTENT_INSERT 18
122482 #define SQL_DELETE_DOCSIZE 19
122483 #define SQL_REPLACE_DOCSIZE 20
122484 #define SQL_SELECT_DOCSIZE 21
122485 #define SQL_SELECT_DOCTOTAL 22
122486 #define SQL_REPLACE_DOCTOTAL 23
122488 #define SQL_SELECT_ALL_PREFIX_LEVEL 24
122489 #define SQL_DELETE_ALL_TERMS_SEGDIR 25
122491 #define SQL_DELETE_SEGDIR_RANGE 26
122494 ** This function is used to obtain an SQLite prepared statement handle
122495 ** for the statement identified by the second argument. If successful,
122496 ** *pp is set to the requested statement handle and SQLITE_OK returned.
122497 ** Otherwise, an SQLite error code is returned and *pp is set to 0.
122499 ** If argument apVal is not NULL, then it must point to an array with
122500 ** at least as many entries as the requested statement has bound
122501 ** parameters. The values are bound to the statements parameters before
122502 ** returning.
122504 static int fts3SqlStmt(
122505 Fts3Table *p, /* Virtual table handle */
122506 int eStmt, /* One of the SQL_XXX constants above */
122507 sqlite3_stmt **pp, /* OUT: Statement handle */
122508 sqlite3_value **apVal /* Values to bind to statement */
122510 const char *azSql[] = {
122511 /* 0 */ "DELETE FROM %Q.'%q_content' WHERE rowid = ?",
122512 /* 1 */ "SELECT NOT EXISTS(SELECT docid FROM %Q.'%q_content' WHERE rowid!=?)",
122513 /* 2 */ "DELETE FROM %Q.'%q_content'",
122514 /* 3 */ "DELETE FROM %Q.'%q_segments'",
122515 /* 4 */ "DELETE FROM %Q.'%q_segdir'",
122516 /* 5 */ "DELETE FROM %Q.'%q_docsize'",
122517 /* 6 */ "DELETE FROM %Q.'%q_stat'",
122518 /* 7 */ "SELECT %s FROM %Q.'%q_content' AS x WHERE rowid=?",
122519 /* 8 */ "SELECT (SELECT max(idx) FROM %Q.'%q_segdir' WHERE level = ?) + 1",
122520 /* 9 */ "INSERT INTO %Q.'%q_segments'(blockid, block) VALUES(?, ?)",
122521 /* 10 */ "SELECT coalesce((SELECT max(blockid) FROM %Q.'%q_segments') + 1, 1)",
122522 /* 11 */ "INSERT INTO %Q.'%q_segdir' VALUES(?,?,?,?,?,?)",
122524 /* Return segments in order from oldest to newest.*/
122525 /* 12 */ "SELECT idx, start_block, leaves_end_block, end_block, root "
122526 "FROM %Q.'%q_segdir' WHERE level = ? ORDER BY idx ASC",
122527 /* 13 */ "SELECT idx, start_block, leaves_end_block, end_block, root "
122528 "FROM %Q.'%q_segdir' WHERE level BETWEEN ? AND ?"
122529 "ORDER BY level DESC, idx ASC",
122531 /* 14 */ "SELECT count(*) FROM %Q.'%q_segdir' WHERE level = ?",
122532 /* 15 */ "SELECT max(level) FROM %Q.'%q_segdir' WHERE level BETWEEN ? AND ?",
122534 /* 16 */ "DELETE FROM %Q.'%q_segdir' WHERE level = ?",
122535 /* 17 */ "DELETE FROM %Q.'%q_segments' WHERE blockid BETWEEN ? AND ?",
122536 /* 18 */ "INSERT INTO %Q.'%q_content' VALUES(%s)",
122537 /* 19 */ "DELETE FROM %Q.'%q_docsize' WHERE docid = ?",
122538 /* 20 */ "REPLACE INTO %Q.'%q_docsize' VALUES(?,?)",
122539 /* 21 */ "SELECT size FROM %Q.'%q_docsize' WHERE docid=?",
122540 /* 22 */ "SELECT value FROM %Q.'%q_stat' WHERE id=0",
122541 /* 23 */ "REPLACE INTO %Q.'%q_stat' VALUES(0,?)",
122542 /* 24 */ "",
122543 /* 25 */ "",
122545 /* 26 */ "DELETE FROM %Q.'%q_segdir' WHERE level BETWEEN ? AND ?",
122548 int rc = SQLITE_OK;
122549 sqlite3_stmt *pStmt;
122551 assert( SizeofArray(azSql)==SizeofArray(p->aStmt) );
122552 assert( eStmt<SizeofArray(azSql) && eStmt>=0 );
122554 pStmt = p->aStmt[eStmt];
122555 if( !pStmt ){
122556 char *zSql;
122557 if( eStmt==SQL_CONTENT_INSERT ){
122558 zSql = sqlite3_mprintf(azSql[eStmt], p->zDb, p->zName, p->zWriteExprlist);
122559 }else if( eStmt==SQL_SELECT_CONTENT_BY_ROWID ){
122560 zSql = sqlite3_mprintf(azSql[eStmt], p->zReadExprlist, p->zDb, p->zName);
122561 }else{
122562 zSql = sqlite3_mprintf(azSql[eStmt], p->zDb, p->zName);
122564 if( !zSql ){
122565 rc = SQLITE_NOMEM;
122566 }else{
122567 rc = sqlite3_prepare_v2(p->db, zSql, -1, &pStmt, NULL);
122568 sqlite3_free(zSql);
122569 assert( rc==SQLITE_OK || pStmt==0 );
122570 p->aStmt[eStmt] = pStmt;
122573 if( apVal ){
122574 int i;
122575 int nParam = sqlite3_bind_parameter_count(pStmt);
122576 for(i=0; rc==SQLITE_OK && i<nParam; i++){
122577 rc = sqlite3_bind_value(pStmt, i+1, apVal[i]);
122580 *pp = pStmt;
122581 return rc;
122584 static int fts3SelectDocsize(
122585 Fts3Table *pTab, /* FTS3 table handle */
122586 int eStmt, /* Either SQL_SELECT_DOCSIZE or DOCTOTAL */
122587 sqlite3_int64 iDocid, /* Docid to bind for SQL_SELECT_DOCSIZE */
122588 sqlite3_stmt **ppStmt /* OUT: Statement handle */
122590 sqlite3_stmt *pStmt = 0; /* Statement requested from fts3SqlStmt() */
122591 int rc; /* Return code */
122593 assert( eStmt==SQL_SELECT_DOCSIZE || eStmt==SQL_SELECT_DOCTOTAL );
122595 rc = fts3SqlStmt(pTab, eStmt, &pStmt, 0);
122596 if( rc==SQLITE_OK ){
122597 if( eStmt==SQL_SELECT_DOCSIZE ){
122598 sqlite3_bind_int64(pStmt, 1, iDocid);
122600 rc = sqlite3_step(pStmt);
122601 if( rc!=SQLITE_ROW || sqlite3_column_type(pStmt, 0)!=SQLITE_BLOB ){
122602 rc = sqlite3_reset(pStmt);
122603 if( rc==SQLITE_OK ) rc = SQLITE_CORRUPT_VTAB;
122604 pStmt = 0;
122605 }else{
122606 rc = SQLITE_OK;
122610 *ppStmt = pStmt;
122611 return rc;
122614 SQLITE_PRIVATE int sqlite3Fts3SelectDoctotal(
122615 Fts3Table *pTab, /* Fts3 table handle */
122616 sqlite3_stmt **ppStmt /* OUT: Statement handle */
122618 return fts3SelectDocsize(pTab, SQL_SELECT_DOCTOTAL, 0, ppStmt);
122621 SQLITE_PRIVATE int sqlite3Fts3SelectDocsize(
122622 Fts3Table *pTab, /* Fts3 table handle */
122623 sqlite3_int64 iDocid, /* Docid to read size data for */
122624 sqlite3_stmt **ppStmt /* OUT: Statement handle */
122626 return fts3SelectDocsize(pTab, SQL_SELECT_DOCSIZE, iDocid, ppStmt);
122630 ** Similar to fts3SqlStmt(). Except, after binding the parameters in
122631 ** array apVal[] to the SQL statement identified by eStmt, the statement
122632 ** is executed.
122634 ** Returns SQLITE_OK if the statement is successfully executed, or an
122635 ** SQLite error code otherwise.
122637 static void fts3SqlExec(
122638 int *pRC, /* Result code */
122639 Fts3Table *p, /* The FTS3 table */
122640 int eStmt, /* Index of statement to evaluate */
122641 sqlite3_value **apVal /* Parameters to bind */
122643 sqlite3_stmt *pStmt;
122644 int rc;
122645 if( *pRC ) return;
122646 rc = fts3SqlStmt(p, eStmt, &pStmt, apVal);
122647 if( rc==SQLITE_OK ){
122648 sqlite3_step(pStmt);
122649 rc = sqlite3_reset(pStmt);
122651 *pRC = rc;
122656 ** This function ensures that the caller has obtained a shared-cache
122657 ** table-lock on the %_content table. This is required before reading
122658 ** data from the fts3 table. If this lock is not acquired first, then
122659 ** the caller may end up holding read-locks on the %_segments and %_segdir
122660 ** tables, but no read-lock on the %_content table. If this happens
122661 ** a second connection will be able to write to the fts3 table, but
122662 ** attempting to commit those writes might return SQLITE_LOCKED or
122663 ** SQLITE_LOCKED_SHAREDCACHE (because the commit attempts to obtain
122664 ** write-locks on the %_segments and %_segdir ** tables).
122666 ** We try to avoid this because if FTS3 returns any error when committing
122667 ** a transaction, the whole transaction will be rolled back. And this is
122668 ** not what users expect when they get SQLITE_LOCKED_SHAREDCACHE. It can
122669 ** still happen if the user reads data directly from the %_segments or
122670 ** %_segdir tables instead of going through FTS3 though.
122672 SQLITE_PRIVATE int sqlite3Fts3ReadLock(Fts3Table *p){
122673 int rc; /* Return code */
122674 sqlite3_stmt *pStmt; /* Statement used to obtain lock */
122676 rc = fts3SqlStmt(p, SQL_SELECT_CONTENT_BY_ROWID, &pStmt, 0);
122677 if( rc==SQLITE_OK ){
122678 sqlite3_bind_null(pStmt, 1);
122679 sqlite3_step(pStmt);
122680 rc = sqlite3_reset(pStmt);
122682 return rc;
122686 ** Set *ppStmt to a statement handle that may be used to iterate through
122687 ** all rows in the %_segdir table, from oldest to newest. If successful,
122688 ** return SQLITE_OK. If an error occurs while preparing the statement,
122689 ** return an SQLite error code.
122691 ** There is only ever one instance of this SQL statement compiled for
122692 ** each FTS3 table.
122694 ** The statement returns the following columns from the %_segdir table:
122696 ** 0: idx
122697 ** 1: start_block
122698 ** 2: leaves_end_block
122699 ** 3: end_block
122700 ** 4: root
122702 SQLITE_PRIVATE int sqlite3Fts3AllSegdirs(
122703 Fts3Table *p, /* FTS3 table */
122704 int iIndex, /* Index for p->aIndex[] */
122705 int iLevel, /* Level to select */
122706 sqlite3_stmt **ppStmt /* OUT: Compiled statement */
122708 int rc;
122709 sqlite3_stmt *pStmt = 0;
122711 assert( iLevel==FTS3_SEGCURSOR_ALL || iLevel>=0 );
122712 assert( iLevel<FTS3_SEGDIR_MAXLEVEL );
122713 assert( iIndex>=0 && iIndex<p->nIndex );
122715 if( iLevel<0 ){
122716 /* "SELECT * FROM %_segdir WHERE level BETWEEN ? AND ? ORDER BY ..." */
122717 rc = fts3SqlStmt(p, SQL_SELECT_LEVEL_RANGE, &pStmt, 0);
122718 if( rc==SQLITE_OK ){
122719 sqlite3_bind_int(pStmt, 1, iIndex*FTS3_SEGDIR_MAXLEVEL);
122720 sqlite3_bind_int(pStmt, 2, (iIndex+1)*FTS3_SEGDIR_MAXLEVEL-1);
122722 }else{
122723 /* "SELECT * FROM %_segdir WHERE level = ? ORDER BY ..." */
122724 rc = fts3SqlStmt(p, SQL_SELECT_LEVEL, &pStmt, 0);
122725 if( rc==SQLITE_OK ){
122726 sqlite3_bind_int(pStmt, 1, iLevel+iIndex*FTS3_SEGDIR_MAXLEVEL);
122729 *ppStmt = pStmt;
122730 return rc;
122735 ** Append a single varint to a PendingList buffer. SQLITE_OK is returned
122736 ** if successful, or an SQLite error code otherwise.
122738 ** This function also serves to allocate the PendingList structure itself.
122739 ** For example, to create a new PendingList structure containing two
122740 ** varints:
122742 ** PendingList *p = 0;
122743 ** fts3PendingListAppendVarint(&p, 1);
122744 ** fts3PendingListAppendVarint(&p, 2);
122746 static int fts3PendingListAppendVarint(
122747 PendingList **pp, /* IN/OUT: Pointer to PendingList struct */
122748 sqlite3_int64 i /* Value to append to data */
122750 PendingList *p = *pp;
122752 /* Allocate or grow the PendingList as required. */
122753 if( !p ){
122754 p = sqlite3_malloc(sizeof(*p) + 100);
122755 if( !p ){
122756 return SQLITE_NOMEM;
122758 p->nSpace = 100;
122759 p->aData = (char *)&p[1];
122760 p->nData = 0;
122762 else if( p->nData+FTS3_VARINT_MAX+1>p->nSpace ){
122763 int nNew = p->nSpace * 2;
122764 p = sqlite3_realloc(p, sizeof(*p) + nNew);
122765 if( !p ){
122766 sqlite3_free(*pp);
122767 *pp = 0;
122768 return SQLITE_NOMEM;
122770 p->nSpace = nNew;
122771 p->aData = (char *)&p[1];
122774 /* Append the new serialized varint to the end of the list. */
122775 p->nData += sqlite3Fts3PutVarint(&p->aData[p->nData], i);
122776 p->aData[p->nData] = '\0';
122777 *pp = p;
122778 return SQLITE_OK;
122782 ** Add a docid/column/position entry to a PendingList structure. Non-zero
122783 ** is returned if the structure is sqlite3_realloced as part of adding
122784 ** the entry. Otherwise, zero.
122786 ** If an OOM error occurs, *pRc is set to SQLITE_NOMEM before returning.
122787 ** Zero is always returned in this case. Otherwise, if no OOM error occurs,
122788 ** it is set to SQLITE_OK.
122790 static int fts3PendingListAppend(
122791 PendingList **pp, /* IN/OUT: PendingList structure */
122792 sqlite3_int64 iDocid, /* Docid for entry to add */
122793 sqlite3_int64 iCol, /* Column for entry to add */
122794 sqlite3_int64 iPos, /* Position of term for entry to add */
122795 int *pRc /* OUT: Return code */
122797 PendingList *p = *pp;
122798 int rc = SQLITE_OK;
122800 assert( !p || p->iLastDocid<=iDocid );
122802 if( !p || p->iLastDocid!=iDocid ){
122803 sqlite3_int64 iDelta = iDocid - (p ? p->iLastDocid : 0);
122804 if( p ){
122805 assert( p->nData<p->nSpace );
122806 assert( p->aData[p->nData]==0 );
122807 p->nData++;
122809 if( SQLITE_OK!=(rc = fts3PendingListAppendVarint(&p, iDelta)) ){
122810 goto pendinglistappend_out;
122812 p->iLastCol = -1;
122813 p->iLastPos = 0;
122814 p->iLastDocid = iDocid;
122816 if( iCol>0 && p->iLastCol!=iCol ){
122817 if( SQLITE_OK!=(rc = fts3PendingListAppendVarint(&p, 1))
122818 || SQLITE_OK!=(rc = fts3PendingListAppendVarint(&p, iCol))
122820 goto pendinglistappend_out;
122822 p->iLastCol = iCol;
122823 p->iLastPos = 0;
122825 if( iCol>=0 ){
122826 assert( iPos>p->iLastPos || (iPos==0 && p->iLastPos==0) );
122827 rc = fts3PendingListAppendVarint(&p, 2+iPos-p->iLastPos);
122828 if( rc==SQLITE_OK ){
122829 p->iLastPos = iPos;
122833 pendinglistappend_out:
122834 *pRc = rc;
122835 if( p!=*pp ){
122836 *pp = p;
122837 return 1;
122839 return 0;
122843 ** Free a PendingList object allocated by fts3PendingListAppend().
122845 static void fts3PendingListDelete(PendingList *pList){
122846 sqlite3_free(pList);
122850 ** Add an entry to one of the pending-terms hash tables.
122852 static int fts3PendingTermsAddOne(
122853 Fts3Table *p,
122854 int iCol,
122855 int iPos,
122856 Fts3Hash *pHash, /* Pending terms hash table to add entry to */
122857 const char *zToken,
122858 int nToken
122860 PendingList *pList;
122861 int rc = SQLITE_OK;
122863 pList = (PendingList *)fts3HashFind(pHash, zToken, nToken);
122864 if( pList ){
122865 p->nPendingData -= (pList->nData + nToken + sizeof(Fts3HashElem));
122867 if( fts3PendingListAppend(&pList, p->iPrevDocid, iCol, iPos, &rc) ){
122868 if( pList==fts3HashInsert(pHash, zToken, nToken, pList) ){
122869 /* Malloc failed while inserting the new entry. This can only
122870 ** happen if there was no previous entry for this token.
122872 assert( 0==fts3HashFind(pHash, zToken, nToken) );
122873 sqlite3_free(pList);
122874 rc = SQLITE_NOMEM;
122877 if( rc==SQLITE_OK ){
122878 p->nPendingData += (pList->nData + nToken + sizeof(Fts3HashElem));
122880 return rc;
122884 ** Tokenize the nul-terminated string zText and add all tokens to the
122885 ** pending-terms hash-table. The docid used is that currently stored in
122886 ** p->iPrevDocid, and the column is specified by argument iCol.
122888 ** If successful, SQLITE_OK is returned. Otherwise, an SQLite error code.
122890 static int fts3PendingTermsAdd(
122891 Fts3Table *p, /* Table into which text will be inserted */
122892 const char *zText, /* Text of document to be inserted */
122893 int iCol, /* Column into which text is being inserted */
122894 u32 *pnWord /* OUT: Number of tokens inserted */
122896 int rc;
122897 int iStart;
122898 int iEnd;
122899 int iPos;
122900 int nWord = 0;
122902 char const *zToken;
122903 int nToken;
122905 sqlite3_tokenizer *pTokenizer = p->pTokenizer;
122906 sqlite3_tokenizer_module const *pModule = pTokenizer->pModule;
122907 sqlite3_tokenizer_cursor *pCsr;
122908 int (*xNext)(sqlite3_tokenizer_cursor *pCursor,
122909 const char**,int*,int*,int*,int*);
122911 assert( pTokenizer && pModule );
122913 /* If the user has inserted a NULL value, this function may be called with
122914 ** zText==0. In this case, add zero token entries to the hash table and
122915 ** return early. */
122916 if( zText==0 ){
122917 *pnWord = 0;
122918 return SQLITE_OK;
122921 rc = pModule->xOpen(pTokenizer, zText, -1, &pCsr);
122922 if( rc!=SQLITE_OK ){
122923 return rc;
122925 pCsr->pTokenizer = pTokenizer;
122927 xNext = pModule->xNext;
122928 while( SQLITE_OK==rc
122929 && SQLITE_OK==(rc = xNext(pCsr, &zToken, &nToken, &iStart, &iEnd, &iPos))
122931 int i;
122932 if( iPos>=nWord ) nWord = iPos+1;
122934 /* Positions cannot be negative; we use -1 as a terminator internally.
122935 ** Tokens must have a non-zero length.
122937 if( iPos<0 || !zToken || nToken<=0 ){
122938 rc = SQLITE_ERROR;
122939 break;
122942 /* Add the term to the terms index */
122943 rc = fts3PendingTermsAddOne(
122944 p, iCol, iPos, &p->aIndex[0].hPending, zToken, nToken
122947 /* Add the term to each of the prefix indexes that it is not too
122948 ** short for. */
122949 for(i=1; rc==SQLITE_OK && i<p->nIndex; i++){
122950 struct Fts3Index *pIndex = &p->aIndex[i];
122951 if( nToken<pIndex->nPrefix ) continue;
122952 rc = fts3PendingTermsAddOne(
122953 p, iCol, iPos, &pIndex->hPending, zToken, pIndex->nPrefix
122958 pModule->xClose(pCsr);
122959 *pnWord = nWord;
122960 return (rc==SQLITE_DONE ? SQLITE_OK : rc);
122964 ** Calling this function indicates that subsequent calls to
122965 ** fts3PendingTermsAdd() are to add term/position-list pairs for the
122966 ** contents of the document with docid iDocid.
122968 static int fts3PendingTermsDocid(Fts3Table *p, sqlite_int64 iDocid){
122969 /* TODO(shess) Explore whether partially flushing the buffer on
122970 ** forced-flush would provide better performance. I suspect that if
122971 ** we ordered the doclists by size and flushed the largest until the
122972 ** buffer was half empty, that would let the less frequent terms
122973 ** generate longer doclists.
122975 if( iDocid<=p->iPrevDocid || p->nPendingData>p->nMaxPendingData ){
122976 int rc = sqlite3Fts3PendingTermsFlush(p);
122977 if( rc!=SQLITE_OK ) return rc;
122979 p->iPrevDocid = iDocid;
122980 return SQLITE_OK;
122984 ** Discard the contents of the pending-terms hash tables.
122986 SQLITE_PRIVATE void sqlite3Fts3PendingTermsClear(Fts3Table *p){
122987 int i;
122988 for(i=0; i<p->nIndex; i++){
122989 Fts3HashElem *pElem;
122990 Fts3Hash *pHash = &p->aIndex[i].hPending;
122991 for(pElem=fts3HashFirst(pHash); pElem; pElem=fts3HashNext(pElem)){
122992 PendingList *pList = (PendingList *)fts3HashData(pElem);
122993 fts3PendingListDelete(pList);
122995 fts3HashClear(pHash);
122997 p->nPendingData = 0;
123001 ** This function is called by the xUpdate() method as part of an INSERT
123002 ** operation. It adds entries for each term in the new record to the
123003 ** pendingTerms hash table.
123005 ** Argument apVal is the same as the similarly named argument passed to
123006 ** fts3InsertData(). Parameter iDocid is the docid of the new row.
123008 static int fts3InsertTerms(Fts3Table *p, sqlite3_value **apVal, u32 *aSz){
123009 int i; /* Iterator variable */
123010 for(i=2; i<p->nColumn+2; i++){
123011 const char *zText = (const char *)sqlite3_value_text(apVal[i]);
123012 int rc = fts3PendingTermsAdd(p, zText, i-2, &aSz[i-2]);
123013 if( rc!=SQLITE_OK ){
123014 return rc;
123016 aSz[p->nColumn] += sqlite3_value_bytes(apVal[i]);
123018 return SQLITE_OK;
123022 ** This function is called by the xUpdate() method for an INSERT operation.
123023 ** The apVal parameter is passed a copy of the apVal argument passed by
123024 ** SQLite to the xUpdate() method. i.e:
123026 ** apVal[0] Not used for INSERT.
123027 ** apVal[1] rowid
123028 ** apVal[2] Left-most user-defined column
123029 ** ...
123030 ** apVal[p->nColumn+1] Right-most user-defined column
123031 ** apVal[p->nColumn+2] Hidden column with same name as table
123032 ** apVal[p->nColumn+3] Hidden "docid" column (alias for rowid)
123034 static int fts3InsertData(
123035 Fts3Table *p, /* Full-text table */
123036 sqlite3_value **apVal, /* Array of values to insert */
123037 sqlite3_int64 *piDocid /* OUT: Docid for row just inserted */
123039 int rc; /* Return code */
123040 sqlite3_stmt *pContentInsert; /* INSERT INTO %_content VALUES(...) */
123042 /* Locate the statement handle used to insert data into the %_content
123043 ** table. The SQL for this statement is:
123045 ** INSERT INTO %_content VALUES(?, ?, ?, ...)
123047 ** The statement features N '?' variables, where N is the number of user
123048 ** defined columns in the FTS3 table, plus one for the docid field.
123050 rc = fts3SqlStmt(p, SQL_CONTENT_INSERT, &pContentInsert, &apVal[1]);
123051 if( rc!=SQLITE_OK ){
123052 return rc;
123055 /* There is a quirk here. The users INSERT statement may have specified
123056 ** a value for the "rowid" field, for the "docid" field, or for both.
123057 ** Which is a problem, since "rowid" and "docid" are aliases for the
123058 ** same value. For example:
123060 ** INSERT INTO fts3tbl(rowid, docid) VALUES(1, 2);
123062 ** In FTS3, this is an error. It is an error to specify non-NULL values
123063 ** for both docid and some other rowid alias.
123065 if( SQLITE_NULL!=sqlite3_value_type(apVal[3+p->nColumn]) ){
123066 if( SQLITE_NULL==sqlite3_value_type(apVal[0])
123067 && SQLITE_NULL!=sqlite3_value_type(apVal[1])
123069 /* A rowid/docid conflict. */
123070 return SQLITE_ERROR;
123072 rc = sqlite3_bind_value(pContentInsert, 1, apVal[3+p->nColumn]);
123073 if( rc!=SQLITE_OK ) return rc;
123076 /* Execute the statement to insert the record. Set *piDocid to the
123077 ** new docid value.
123079 sqlite3_step(pContentInsert);
123080 rc = sqlite3_reset(pContentInsert);
123082 *piDocid = sqlite3_last_insert_rowid(p->db);
123083 return rc;
123089 ** Remove all data from the FTS3 table. Clear the hash table containing
123090 ** pending terms.
123092 static int fts3DeleteAll(Fts3Table *p){
123093 int rc = SQLITE_OK; /* Return code */
123095 /* Discard the contents of the pending-terms hash table. */
123096 sqlite3Fts3PendingTermsClear(p);
123098 /* Delete everything from the %_content, %_segments and %_segdir tables. */
123099 fts3SqlExec(&rc, p, SQL_DELETE_ALL_CONTENT, 0);
123100 fts3SqlExec(&rc, p, SQL_DELETE_ALL_SEGMENTS, 0);
123101 fts3SqlExec(&rc, p, SQL_DELETE_ALL_SEGDIR, 0);
123102 if( p->bHasDocsize ){
123103 fts3SqlExec(&rc, p, SQL_DELETE_ALL_DOCSIZE, 0);
123105 if( p->bHasStat ){
123106 fts3SqlExec(&rc, p, SQL_DELETE_ALL_STAT, 0);
123108 return rc;
123112 ** The first element in the apVal[] array is assumed to contain the docid
123113 ** (an integer) of a row about to be deleted. Remove all terms from the
123114 ** full-text index.
123116 static void fts3DeleteTerms(
123117 int *pRC, /* Result code */
123118 Fts3Table *p, /* The FTS table to delete from */
123119 sqlite3_value *pRowid, /* The docid to be deleted */
123120 u32 *aSz /* Sizes of deleted document written here */
123122 int rc;
123123 sqlite3_stmt *pSelect;
123125 if( *pRC ) return;
123126 rc = fts3SqlStmt(p, SQL_SELECT_CONTENT_BY_ROWID, &pSelect, &pRowid);
123127 if( rc==SQLITE_OK ){
123128 if( SQLITE_ROW==sqlite3_step(pSelect) ){
123129 int i;
123130 for(i=1; i<=p->nColumn; i++){
123131 const char *zText = (const char *)sqlite3_column_text(pSelect, i);
123132 rc = fts3PendingTermsAdd(p, zText, -1, &aSz[i-1]);
123133 if( rc!=SQLITE_OK ){
123134 sqlite3_reset(pSelect);
123135 *pRC = rc;
123136 return;
123138 aSz[p->nColumn] += sqlite3_column_bytes(pSelect, i);
123141 rc = sqlite3_reset(pSelect);
123142 }else{
123143 sqlite3_reset(pSelect);
123145 *pRC = rc;
123149 ** Forward declaration to account for the circular dependency between
123150 ** functions fts3SegmentMerge() and fts3AllocateSegdirIdx().
123152 static int fts3SegmentMerge(Fts3Table *, int, int);
123155 ** This function allocates a new level iLevel index in the segdir table.
123156 ** Usually, indexes are allocated within a level sequentially starting
123157 ** with 0, so the allocated index is one greater than the value returned
123158 ** by:
123160 ** SELECT max(idx) FROM %_segdir WHERE level = :iLevel
123162 ** However, if there are already FTS3_MERGE_COUNT indexes at the requested
123163 ** level, they are merged into a single level (iLevel+1) segment and the
123164 ** allocated index is 0.
123166 ** If successful, *piIdx is set to the allocated index slot and SQLITE_OK
123167 ** returned. Otherwise, an SQLite error code is returned.
123169 static int fts3AllocateSegdirIdx(
123170 Fts3Table *p,
123171 int iIndex, /* Index for p->aIndex */
123172 int iLevel,
123173 int *piIdx
123175 int rc; /* Return Code */
123176 sqlite3_stmt *pNextIdx; /* Query for next idx at level iLevel */
123177 int iNext = 0; /* Result of query pNextIdx */
123179 /* Set variable iNext to the next available segdir index at level iLevel. */
123180 rc = fts3SqlStmt(p, SQL_NEXT_SEGMENT_INDEX, &pNextIdx, 0);
123181 if( rc==SQLITE_OK ){
123182 sqlite3_bind_int(pNextIdx, 1, iIndex*FTS3_SEGDIR_MAXLEVEL + iLevel);
123183 if( SQLITE_ROW==sqlite3_step(pNextIdx) ){
123184 iNext = sqlite3_column_int(pNextIdx, 0);
123186 rc = sqlite3_reset(pNextIdx);
123189 if( rc==SQLITE_OK ){
123190 /* If iNext is FTS3_MERGE_COUNT, indicating that level iLevel is already
123191 ** full, merge all segments in level iLevel into a single iLevel+1
123192 ** segment and allocate (newly freed) index 0 at level iLevel. Otherwise,
123193 ** if iNext is less than FTS3_MERGE_COUNT, allocate index iNext.
123195 if( iNext>=FTS3_MERGE_COUNT ){
123196 rc = fts3SegmentMerge(p, iIndex, iLevel);
123197 *piIdx = 0;
123198 }else{
123199 *piIdx = iNext;
123203 return rc;
123207 ** The %_segments table is declared as follows:
123209 ** CREATE TABLE %_segments(blockid INTEGER PRIMARY KEY, block BLOB)
123211 ** This function reads data from a single row of the %_segments table. The
123212 ** specific row is identified by the iBlockid parameter. If paBlob is not
123213 ** NULL, then a buffer is allocated using sqlite3_malloc() and populated
123214 ** with the contents of the blob stored in the "block" column of the
123215 ** identified table row is. Whether or not paBlob is NULL, *pnBlob is set
123216 ** to the size of the blob in bytes before returning.
123218 ** If an error occurs, or the table does not contain the specified row,
123219 ** an SQLite error code is returned. Otherwise, SQLITE_OK is returned. If
123220 ** paBlob is non-NULL, then it is the responsibility of the caller to
123221 ** eventually free the returned buffer.
123223 ** This function may leave an open sqlite3_blob* handle in the
123224 ** Fts3Table.pSegments variable. This handle is reused by subsequent calls
123225 ** to this function. The handle may be closed by calling the
123226 ** sqlite3Fts3SegmentsClose() function. Reusing a blob handle is a handy
123227 ** performance improvement, but the blob handle should always be closed
123228 ** before control is returned to the user (to prevent a lock being held
123229 ** on the database file for longer than necessary). Thus, any virtual table
123230 ** method (xFilter etc.) that may directly or indirectly call this function
123231 ** must call sqlite3Fts3SegmentsClose() before returning.
123233 SQLITE_PRIVATE int sqlite3Fts3ReadBlock(
123234 Fts3Table *p, /* FTS3 table handle */
123235 sqlite3_int64 iBlockid, /* Access the row with blockid=$iBlockid */
123236 char **paBlob, /* OUT: Blob data in malloc'd buffer */
123237 int *pnBlob, /* OUT: Size of blob data */
123238 int *pnLoad /* OUT: Bytes actually loaded */
123240 int rc; /* Return code */
123242 /* pnBlob must be non-NULL. paBlob may be NULL or non-NULL. */
123243 assert( pnBlob);
123245 if( p->pSegments ){
123246 rc = sqlite3_blob_reopen(p->pSegments, iBlockid);
123247 }else{
123248 if( 0==p->zSegmentsTbl ){
123249 p->zSegmentsTbl = sqlite3_mprintf("%s_segments", p->zName);
123250 if( 0==p->zSegmentsTbl ) return SQLITE_NOMEM;
123252 rc = sqlite3_blob_open(
123253 p->db, p->zDb, p->zSegmentsTbl, "block", iBlockid, 0, &p->pSegments
123257 if( rc==SQLITE_OK ){
123258 int nByte = sqlite3_blob_bytes(p->pSegments);
123259 *pnBlob = nByte;
123260 if( paBlob ){
123261 char *aByte = sqlite3_malloc(nByte + FTS3_NODE_PADDING);
123262 if( !aByte ){
123263 rc = SQLITE_NOMEM;
123264 }else{
123265 if( pnLoad && nByte>(FTS3_NODE_CHUNK_THRESHOLD) ){
123266 nByte = FTS3_NODE_CHUNKSIZE;
123267 *pnLoad = nByte;
123269 rc = sqlite3_blob_read(p->pSegments, aByte, nByte, 0);
123270 memset(&aByte[nByte], 0, FTS3_NODE_PADDING);
123271 if( rc!=SQLITE_OK ){
123272 sqlite3_free(aByte);
123273 aByte = 0;
123276 *paBlob = aByte;
123280 return rc;
123284 ** Close the blob handle at p->pSegments, if it is open. See comments above
123285 ** the sqlite3Fts3ReadBlock() function for details.
123287 SQLITE_PRIVATE void sqlite3Fts3SegmentsClose(Fts3Table *p){
123288 sqlite3_blob_close(p->pSegments);
123289 p->pSegments = 0;
123292 static int fts3SegReaderIncrRead(Fts3SegReader *pReader){
123293 int nRead; /* Number of bytes to read */
123294 int rc; /* Return code */
123296 nRead = MIN(pReader->nNode - pReader->nPopulate, FTS3_NODE_CHUNKSIZE);
123297 rc = sqlite3_blob_read(
123298 pReader->pBlob,
123299 &pReader->aNode[pReader->nPopulate],
123300 nRead,
123301 pReader->nPopulate
123304 if( rc==SQLITE_OK ){
123305 pReader->nPopulate += nRead;
123306 memset(&pReader->aNode[pReader->nPopulate], 0, FTS3_NODE_PADDING);
123307 if( pReader->nPopulate==pReader->nNode ){
123308 sqlite3_blob_close(pReader->pBlob);
123309 pReader->pBlob = 0;
123310 pReader->nPopulate = 0;
123313 return rc;
123316 static int fts3SegReaderRequire(Fts3SegReader *pReader, char *pFrom, int nByte){
123317 int rc = SQLITE_OK;
123318 assert( !pReader->pBlob
123319 || (pFrom>=pReader->aNode && pFrom<&pReader->aNode[pReader->nNode])
123321 while( pReader->pBlob && rc==SQLITE_OK
123322 && (pFrom - pReader->aNode + nByte)>pReader->nPopulate
123324 rc = fts3SegReaderIncrRead(pReader);
123326 return rc;
123330 ** Move the iterator passed as the first argument to the next term in the
123331 ** segment. If successful, SQLITE_OK is returned. If there is no next term,
123332 ** SQLITE_DONE. Otherwise, an SQLite error code.
123334 static int fts3SegReaderNext(
123335 Fts3Table *p,
123336 Fts3SegReader *pReader,
123337 int bIncr
123339 int rc; /* Return code of various sub-routines */
123340 char *pNext; /* Cursor variable */
123341 int nPrefix; /* Number of bytes in term prefix */
123342 int nSuffix; /* Number of bytes in term suffix */
123344 if( !pReader->aDoclist ){
123345 pNext = pReader->aNode;
123346 }else{
123347 pNext = &pReader->aDoclist[pReader->nDoclist];
123350 if( !pNext || pNext>=&pReader->aNode[pReader->nNode] ){
123352 if( fts3SegReaderIsPending(pReader) ){
123353 Fts3HashElem *pElem = *(pReader->ppNextElem);
123354 if( pElem==0 ){
123355 pReader->aNode = 0;
123356 }else{
123357 PendingList *pList = (PendingList *)fts3HashData(pElem);
123358 pReader->zTerm = (char *)fts3HashKey(pElem);
123359 pReader->nTerm = fts3HashKeysize(pElem);
123360 pReader->nNode = pReader->nDoclist = pList->nData + 1;
123361 pReader->aNode = pReader->aDoclist = pList->aData;
123362 pReader->ppNextElem++;
123363 assert( pReader->aNode );
123365 return SQLITE_OK;
123368 if( !fts3SegReaderIsRootOnly(pReader) ){
123369 sqlite3_free(pReader->aNode);
123370 sqlite3_blob_close(pReader->pBlob);
123371 pReader->pBlob = 0;
123373 pReader->aNode = 0;
123375 /* If iCurrentBlock>=iLeafEndBlock, this is an EOF condition. All leaf
123376 ** blocks have already been traversed. */
123377 assert( pReader->iCurrentBlock<=pReader->iLeafEndBlock );
123378 if( pReader->iCurrentBlock>=pReader->iLeafEndBlock ){
123379 return SQLITE_OK;
123382 rc = sqlite3Fts3ReadBlock(
123383 p, ++pReader->iCurrentBlock, &pReader->aNode, &pReader->nNode,
123384 (bIncr ? &pReader->nPopulate : 0)
123386 if( rc!=SQLITE_OK ) return rc;
123387 assert( pReader->pBlob==0 );
123388 if( bIncr && pReader->nPopulate<pReader->nNode ){
123389 pReader->pBlob = p->pSegments;
123390 p->pSegments = 0;
123392 pNext = pReader->aNode;
123395 assert( !fts3SegReaderIsPending(pReader) );
123397 rc = fts3SegReaderRequire(pReader, pNext, FTS3_VARINT_MAX*2);
123398 if( rc!=SQLITE_OK ) return rc;
123400 /* Because of the FTS3_NODE_PADDING bytes of padding, the following is
123401 ** safe (no risk of overread) even if the node data is corrupted. */
123402 pNext += sqlite3Fts3GetVarint32(pNext, &nPrefix);
123403 pNext += sqlite3Fts3GetVarint32(pNext, &nSuffix);
123404 if( nPrefix<0 || nSuffix<=0
123405 || &pNext[nSuffix]>&pReader->aNode[pReader->nNode]
123407 return SQLITE_CORRUPT_VTAB;
123410 if( nPrefix+nSuffix>pReader->nTermAlloc ){
123411 int nNew = (nPrefix+nSuffix)*2;
123412 char *zNew = sqlite3_realloc(pReader->zTerm, nNew);
123413 if( !zNew ){
123414 return SQLITE_NOMEM;
123416 pReader->zTerm = zNew;
123417 pReader->nTermAlloc = nNew;
123420 rc = fts3SegReaderRequire(pReader, pNext, nSuffix+FTS3_VARINT_MAX);
123421 if( rc!=SQLITE_OK ) return rc;
123423 memcpy(&pReader->zTerm[nPrefix], pNext, nSuffix);
123424 pReader->nTerm = nPrefix+nSuffix;
123425 pNext += nSuffix;
123426 pNext += sqlite3Fts3GetVarint32(pNext, &pReader->nDoclist);
123427 pReader->aDoclist = pNext;
123428 pReader->pOffsetList = 0;
123430 /* Check that the doclist does not appear to extend past the end of the
123431 ** b-tree node. And that the final byte of the doclist is 0x00. If either
123432 ** of these statements is untrue, then the data structure is corrupt.
123434 if( &pReader->aDoclist[pReader->nDoclist]>&pReader->aNode[pReader->nNode]
123435 || (pReader->nPopulate==0 && pReader->aDoclist[pReader->nDoclist-1])
123437 return SQLITE_CORRUPT_VTAB;
123439 return SQLITE_OK;
123443 ** Set the SegReader to point to the first docid in the doclist associated
123444 ** with the current term.
123446 static int fts3SegReaderFirstDocid(Fts3Table *pTab, Fts3SegReader *pReader){
123447 int rc = SQLITE_OK;
123448 assert( pReader->aDoclist );
123449 assert( !pReader->pOffsetList );
123450 if( pTab->bDescIdx && fts3SegReaderIsPending(pReader) ){
123451 u8 bEof = 0;
123452 pReader->iDocid = 0;
123453 pReader->nOffsetList = 0;
123454 sqlite3Fts3DoclistPrev(0,
123455 pReader->aDoclist, pReader->nDoclist, &pReader->pOffsetList,
123456 &pReader->iDocid, &pReader->nOffsetList, &bEof
123458 }else{
123459 rc = fts3SegReaderRequire(pReader, pReader->aDoclist, FTS3_VARINT_MAX);
123460 if( rc==SQLITE_OK ){
123461 int n = sqlite3Fts3GetVarint(pReader->aDoclist, &pReader->iDocid);
123462 pReader->pOffsetList = &pReader->aDoclist[n];
123465 return rc;
123469 ** Advance the SegReader to point to the next docid in the doclist
123470 ** associated with the current term.
123472 ** If arguments ppOffsetList and pnOffsetList are not NULL, then
123473 ** *ppOffsetList is set to point to the first column-offset list
123474 ** in the doclist entry (i.e. immediately past the docid varint).
123475 ** *pnOffsetList is set to the length of the set of column-offset
123476 ** lists, not including the nul-terminator byte. For example:
123478 static int fts3SegReaderNextDocid(
123479 Fts3Table *pTab,
123480 Fts3SegReader *pReader, /* Reader to advance to next docid */
123481 char **ppOffsetList, /* OUT: Pointer to current position-list */
123482 int *pnOffsetList /* OUT: Length of *ppOffsetList in bytes */
123484 int rc = SQLITE_OK;
123485 char *p = pReader->pOffsetList;
123486 char c = 0;
123488 assert( p );
123490 if( pTab->bDescIdx && fts3SegReaderIsPending(pReader) ){
123491 /* A pending-terms seg-reader for an FTS4 table that uses order=desc.
123492 ** Pending-terms doclists are always built up in ascending order, so
123493 ** we have to iterate through them backwards here. */
123494 u8 bEof = 0;
123495 if( ppOffsetList ){
123496 *ppOffsetList = pReader->pOffsetList;
123497 *pnOffsetList = pReader->nOffsetList - 1;
123499 sqlite3Fts3DoclistPrev(0,
123500 pReader->aDoclist, pReader->nDoclist, &p, &pReader->iDocid,
123501 &pReader->nOffsetList, &bEof
123503 if( bEof ){
123504 pReader->pOffsetList = 0;
123505 }else{
123506 pReader->pOffsetList = p;
123508 }else{
123509 char *pEnd = &pReader->aDoclist[pReader->nDoclist];
123511 /* Pointer p currently points at the first byte of an offset list. The
123512 ** following block advances it to point one byte past the end of
123513 ** the same offset list. */
123514 while( 1 ){
123516 /* The following line of code (and the "p++" below the while() loop) is
123517 ** normally all that is required to move pointer p to the desired
123518 ** position. The exception is if this node is being loaded from disk
123519 ** incrementally and pointer "p" now points to the first byte passed
123520 ** the populated part of pReader->aNode[].
123522 while( *p | c ) c = *p++ & 0x80;
123523 assert( *p==0 );
123525 if( pReader->pBlob==0 || p<&pReader->aNode[pReader->nPopulate] ) break;
123526 rc = fts3SegReaderIncrRead(pReader);
123527 if( rc!=SQLITE_OK ) return rc;
123531 /* If required, populate the output variables with a pointer to and the
123532 ** size of the previous offset-list.
123534 if( ppOffsetList ){
123535 *ppOffsetList = pReader->pOffsetList;
123536 *pnOffsetList = (int)(p - pReader->pOffsetList - 1);
123539 while( p<pEnd && *p==0 ) p++;
123541 /* If there are no more entries in the doclist, set pOffsetList to
123542 ** NULL. Otherwise, set Fts3SegReader.iDocid to the next docid and
123543 ** Fts3SegReader.pOffsetList to point to the next offset list before
123544 ** returning.
123546 if( p>=pEnd ){
123547 pReader->pOffsetList = 0;
123548 }else{
123549 rc = fts3SegReaderRequire(pReader, p, FTS3_VARINT_MAX);
123550 if( rc==SQLITE_OK ){
123551 sqlite3_int64 iDelta;
123552 pReader->pOffsetList = p + sqlite3Fts3GetVarint(p, &iDelta);
123553 if( pTab->bDescIdx ){
123554 pReader->iDocid -= iDelta;
123555 }else{
123556 pReader->iDocid += iDelta;
123562 return SQLITE_OK;
123566 SQLITE_PRIVATE int sqlite3Fts3MsrOvfl(
123567 Fts3Cursor *pCsr,
123568 Fts3MultiSegReader *pMsr,
123569 int *pnOvfl
123571 Fts3Table *p = (Fts3Table*)pCsr->base.pVtab;
123572 int nOvfl = 0;
123573 int ii;
123574 int rc = SQLITE_OK;
123575 int pgsz = p->nPgsz;
123577 assert( p->bHasStat );
123578 assert( pgsz>0 );
123580 for(ii=0; rc==SQLITE_OK && ii<pMsr->nSegment; ii++){
123581 Fts3SegReader *pReader = pMsr->apSegment[ii];
123582 if( !fts3SegReaderIsPending(pReader)
123583 && !fts3SegReaderIsRootOnly(pReader)
123585 sqlite3_int64 jj;
123586 for(jj=pReader->iStartBlock; jj<=pReader->iLeafEndBlock; jj++){
123587 int nBlob;
123588 rc = sqlite3Fts3ReadBlock(p, jj, 0, &nBlob, 0);
123589 if( rc!=SQLITE_OK ) break;
123590 if( (nBlob+35)>pgsz ){
123591 nOvfl += (nBlob + 34)/pgsz;
123596 *pnOvfl = nOvfl;
123597 return rc;
123601 ** Free all allocations associated with the iterator passed as the
123602 ** second argument.
123604 SQLITE_PRIVATE void sqlite3Fts3SegReaderFree(Fts3SegReader *pReader){
123605 if( pReader && !fts3SegReaderIsPending(pReader) ){
123606 sqlite3_free(pReader->zTerm);
123607 if( !fts3SegReaderIsRootOnly(pReader) ){
123608 sqlite3_free(pReader->aNode);
123609 sqlite3_blob_close(pReader->pBlob);
123612 sqlite3_free(pReader);
123616 ** Allocate a new SegReader object.
123618 SQLITE_PRIVATE int sqlite3Fts3SegReaderNew(
123619 int iAge, /* Segment "age". */
123620 sqlite3_int64 iStartLeaf, /* First leaf to traverse */
123621 sqlite3_int64 iEndLeaf, /* Final leaf to traverse */
123622 sqlite3_int64 iEndBlock, /* Final block of segment */
123623 const char *zRoot, /* Buffer containing root node */
123624 int nRoot, /* Size of buffer containing root node */
123625 Fts3SegReader **ppReader /* OUT: Allocated Fts3SegReader */
123627 int rc = SQLITE_OK; /* Return code */
123628 Fts3SegReader *pReader; /* Newly allocated SegReader object */
123629 int nExtra = 0; /* Bytes to allocate segment root node */
123631 assert( iStartLeaf<=iEndLeaf );
123632 if( iStartLeaf==0 ){
123633 nExtra = nRoot + FTS3_NODE_PADDING;
123636 pReader = (Fts3SegReader *)sqlite3_malloc(sizeof(Fts3SegReader) + nExtra);
123637 if( !pReader ){
123638 return SQLITE_NOMEM;
123640 memset(pReader, 0, sizeof(Fts3SegReader));
123641 pReader->iIdx = iAge;
123642 pReader->iStartBlock = iStartLeaf;
123643 pReader->iLeafEndBlock = iEndLeaf;
123644 pReader->iEndBlock = iEndBlock;
123646 if( nExtra ){
123647 /* The entire segment is stored in the root node. */
123648 pReader->aNode = (char *)&pReader[1];
123649 pReader->nNode = nRoot;
123650 memcpy(pReader->aNode, zRoot, nRoot);
123651 memset(&pReader->aNode[nRoot], 0, FTS3_NODE_PADDING);
123652 }else{
123653 pReader->iCurrentBlock = iStartLeaf-1;
123656 if( rc==SQLITE_OK ){
123657 *ppReader = pReader;
123658 }else{
123659 sqlite3Fts3SegReaderFree(pReader);
123661 return rc;
123665 ** This is a comparison function used as a qsort() callback when sorting
123666 ** an array of pending terms by term. This occurs as part of flushing
123667 ** the contents of the pending-terms hash table to the database.
123669 static int fts3CompareElemByTerm(const void *lhs, const void *rhs){
123670 char *z1 = fts3HashKey(*(Fts3HashElem **)lhs);
123671 char *z2 = fts3HashKey(*(Fts3HashElem **)rhs);
123672 int n1 = fts3HashKeysize(*(Fts3HashElem **)lhs);
123673 int n2 = fts3HashKeysize(*(Fts3HashElem **)rhs);
123675 int n = (n1<n2 ? n1 : n2);
123676 int c = memcmp(z1, z2, n);
123677 if( c==0 ){
123678 c = n1 - n2;
123680 return c;
123684 ** This function is used to allocate an Fts3SegReader that iterates through
123685 ** a subset of the terms stored in the Fts3Table.pendingTerms array.
123687 ** If the isPrefixIter parameter is zero, then the returned SegReader iterates
123688 ** through each term in the pending-terms table. Or, if isPrefixIter is
123689 ** non-zero, it iterates through each term and its prefixes. For example, if
123690 ** the pending terms hash table contains the terms "sqlite", "mysql" and
123691 ** "firebird", then the iterator visits the following 'terms' (in the order
123692 ** shown):
123694 ** f fi fir fire fireb firebi firebir firebird
123695 ** m my mys mysq mysql
123696 ** s sq sql sqli sqlit sqlite
123698 ** Whereas if isPrefixIter is zero, the terms visited are:
123700 ** firebird mysql sqlite
123702 SQLITE_PRIVATE int sqlite3Fts3SegReaderPending(
123703 Fts3Table *p, /* Virtual table handle */
123704 int iIndex, /* Index for p->aIndex */
123705 const char *zTerm, /* Term to search for */
123706 int nTerm, /* Size of buffer zTerm */
123707 int bPrefix, /* True for a prefix iterator */
123708 Fts3SegReader **ppReader /* OUT: SegReader for pending-terms */
123710 Fts3SegReader *pReader = 0; /* Fts3SegReader object to return */
123711 Fts3HashElem **aElem = 0; /* Array of term hash entries to scan */
123712 int nElem = 0; /* Size of array at aElem */
123713 int rc = SQLITE_OK; /* Return Code */
123714 Fts3Hash *pHash;
123716 pHash = &p->aIndex[iIndex].hPending;
123717 if( bPrefix ){
123718 int nAlloc = 0; /* Size of allocated array at aElem */
123719 Fts3HashElem *pE = 0; /* Iterator variable */
123721 for(pE=fts3HashFirst(pHash); pE; pE=fts3HashNext(pE)){
123722 char *zKey = (char *)fts3HashKey(pE);
123723 int nKey = fts3HashKeysize(pE);
123724 if( nTerm==0 || (nKey>=nTerm && 0==memcmp(zKey, zTerm, nTerm)) ){
123725 if( nElem==nAlloc ){
123726 Fts3HashElem **aElem2;
123727 nAlloc += 16;
123728 aElem2 = (Fts3HashElem **)sqlite3_realloc(
123729 aElem, nAlloc*sizeof(Fts3HashElem *)
123731 if( !aElem2 ){
123732 rc = SQLITE_NOMEM;
123733 nElem = 0;
123734 break;
123736 aElem = aElem2;
123739 aElem[nElem++] = pE;
123743 /* If more than one term matches the prefix, sort the Fts3HashElem
123744 ** objects in term order using qsort(). This uses the same comparison
123745 ** callback as is used when flushing terms to disk.
123747 if( nElem>1 ){
123748 qsort(aElem, nElem, sizeof(Fts3HashElem *), fts3CompareElemByTerm);
123751 }else{
123752 /* The query is a simple term lookup that matches at most one term in
123753 ** the index. All that is required is a straight hash-lookup. */
123754 Fts3HashElem *pE = fts3HashFindElem(pHash, zTerm, nTerm);
123755 if( pE ){
123756 aElem = &pE;
123757 nElem = 1;
123761 if( nElem>0 ){
123762 int nByte = sizeof(Fts3SegReader) + (nElem+1)*sizeof(Fts3HashElem *);
123763 pReader = (Fts3SegReader *)sqlite3_malloc(nByte);
123764 if( !pReader ){
123765 rc = SQLITE_NOMEM;
123766 }else{
123767 memset(pReader, 0, nByte);
123768 pReader->iIdx = 0x7FFFFFFF;
123769 pReader->ppNextElem = (Fts3HashElem **)&pReader[1];
123770 memcpy(pReader->ppNextElem, aElem, nElem*sizeof(Fts3HashElem *));
123774 if( bPrefix ){
123775 sqlite3_free(aElem);
123777 *ppReader = pReader;
123778 return rc;
123782 ** Compare the entries pointed to by two Fts3SegReader structures.
123783 ** Comparison is as follows:
123785 ** 1) EOF is greater than not EOF.
123787 ** 2) The current terms (if any) are compared using memcmp(). If one
123788 ** term is a prefix of another, the longer term is considered the
123789 ** larger.
123791 ** 3) By segment age. An older segment is considered larger.
123793 static int fts3SegReaderCmp(Fts3SegReader *pLhs, Fts3SegReader *pRhs){
123794 int rc;
123795 if( pLhs->aNode && pRhs->aNode ){
123796 int rc2 = pLhs->nTerm - pRhs->nTerm;
123797 if( rc2<0 ){
123798 rc = memcmp(pLhs->zTerm, pRhs->zTerm, pLhs->nTerm);
123799 }else{
123800 rc = memcmp(pLhs->zTerm, pRhs->zTerm, pRhs->nTerm);
123802 if( rc==0 ){
123803 rc = rc2;
123805 }else{
123806 rc = (pLhs->aNode==0) - (pRhs->aNode==0);
123808 if( rc==0 ){
123809 rc = pRhs->iIdx - pLhs->iIdx;
123811 assert( rc!=0 );
123812 return rc;
123816 ** A different comparison function for SegReader structures. In this
123817 ** version, it is assumed that each SegReader points to an entry in
123818 ** a doclist for identical terms. Comparison is made as follows:
123820 ** 1) EOF (end of doclist in this case) is greater than not EOF.
123822 ** 2) By current docid.
123824 ** 3) By segment age. An older segment is considered larger.
123826 static int fts3SegReaderDoclistCmp(Fts3SegReader *pLhs, Fts3SegReader *pRhs){
123827 int rc = (pLhs->pOffsetList==0)-(pRhs->pOffsetList==0);
123828 if( rc==0 ){
123829 if( pLhs->iDocid==pRhs->iDocid ){
123830 rc = pRhs->iIdx - pLhs->iIdx;
123831 }else{
123832 rc = (pLhs->iDocid > pRhs->iDocid) ? 1 : -1;
123835 assert( pLhs->aNode && pRhs->aNode );
123836 return rc;
123838 static int fts3SegReaderDoclistCmpRev(Fts3SegReader *pLhs, Fts3SegReader *pRhs){
123839 int rc = (pLhs->pOffsetList==0)-(pRhs->pOffsetList==0);
123840 if( rc==0 ){
123841 if( pLhs->iDocid==pRhs->iDocid ){
123842 rc = pRhs->iIdx - pLhs->iIdx;
123843 }else{
123844 rc = (pLhs->iDocid < pRhs->iDocid) ? 1 : -1;
123847 assert( pLhs->aNode && pRhs->aNode );
123848 return rc;
123852 ** Compare the term that the Fts3SegReader object passed as the first argument
123853 ** points to with the term specified by arguments zTerm and nTerm.
123855 ** If the pSeg iterator is already at EOF, return 0. Otherwise, return
123856 ** -ve if the pSeg term is less than zTerm/nTerm, 0 if the two terms are
123857 ** equal, or +ve if the pSeg term is greater than zTerm/nTerm.
123859 static int fts3SegReaderTermCmp(
123860 Fts3SegReader *pSeg, /* Segment reader object */
123861 const char *zTerm, /* Term to compare to */
123862 int nTerm /* Size of term zTerm in bytes */
123864 int res = 0;
123865 if( pSeg->aNode ){
123866 if( pSeg->nTerm>nTerm ){
123867 res = memcmp(pSeg->zTerm, zTerm, nTerm);
123868 }else{
123869 res = memcmp(pSeg->zTerm, zTerm, pSeg->nTerm);
123871 if( res==0 ){
123872 res = pSeg->nTerm-nTerm;
123875 return res;
123879 ** Argument apSegment is an array of nSegment elements. It is known that
123880 ** the final (nSegment-nSuspect) members are already in sorted order
123881 ** (according to the comparison function provided). This function shuffles
123882 ** the array around until all entries are in sorted order.
123884 static void fts3SegReaderSort(
123885 Fts3SegReader **apSegment, /* Array to sort entries of */
123886 int nSegment, /* Size of apSegment array */
123887 int nSuspect, /* Unsorted entry count */
123888 int (*xCmp)(Fts3SegReader *, Fts3SegReader *) /* Comparison function */
123890 int i; /* Iterator variable */
123892 assert( nSuspect<=nSegment );
123894 if( nSuspect==nSegment ) nSuspect--;
123895 for(i=nSuspect-1; i>=0; i--){
123896 int j;
123897 for(j=i; j<(nSegment-1); j++){
123898 Fts3SegReader *pTmp;
123899 if( xCmp(apSegment[j], apSegment[j+1])<0 ) break;
123900 pTmp = apSegment[j+1];
123901 apSegment[j+1] = apSegment[j];
123902 apSegment[j] = pTmp;
123906 #ifndef NDEBUG
123907 /* Check that the list really is sorted now. */
123908 for(i=0; i<(nSuspect-1); i++){
123909 assert( xCmp(apSegment[i], apSegment[i+1])<0 );
123911 #endif
123915 ** Insert a record into the %_segments table.
123917 static int fts3WriteSegment(
123918 Fts3Table *p, /* Virtual table handle */
123919 sqlite3_int64 iBlock, /* Block id for new block */
123920 char *z, /* Pointer to buffer containing block data */
123921 int n /* Size of buffer z in bytes */
123923 sqlite3_stmt *pStmt;
123924 int rc = fts3SqlStmt(p, SQL_INSERT_SEGMENTS, &pStmt, 0);
123925 if( rc==SQLITE_OK ){
123926 sqlite3_bind_int64(pStmt, 1, iBlock);
123927 sqlite3_bind_blob(pStmt, 2, z, n, SQLITE_STATIC);
123928 sqlite3_step(pStmt);
123929 rc = sqlite3_reset(pStmt);
123931 return rc;
123935 ** Insert a record into the %_segdir table.
123937 static int fts3WriteSegdir(
123938 Fts3Table *p, /* Virtual table handle */
123939 int iLevel, /* Value for "level" field */
123940 int iIdx, /* Value for "idx" field */
123941 sqlite3_int64 iStartBlock, /* Value for "start_block" field */
123942 sqlite3_int64 iLeafEndBlock, /* Value for "leaves_end_block" field */
123943 sqlite3_int64 iEndBlock, /* Value for "end_block" field */
123944 char *zRoot, /* Blob value for "root" field */
123945 int nRoot /* Number of bytes in buffer zRoot */
123947 sqlite3_stmt *pStmt;
123948 int rc = fts3SqlStmt(p, SQL_INSERT_SEGDIR, &pStmt, 0);
123949 if( rc==SQLITE_OK ){
123950 sqlite3_bind_int(pStmt, 1, iLevel);
123951 sqlite3_bind_int(pStmt, 2, iIdx);
123952 sqlite3_bind_int64(pStmt, 3, iStartBlock);
123953 sqlite3_bind_int64(pStmt, 4, iLeafEndBlock);
123954 sqlite3_bind_int64(pStmt, 5, iEndBlock);
123955 sqlite3_bind_blob(pStmt, 6, zRoot, nRoot, SQLITE_STATIC);
123956 sqlite3_step(pStmt);
123957 rc = sqlite3_reset(pStmt);
123959 return rc;
123963 ** Return the size of the common prefix (if any) shared by zPrev and
123964 ** zNext, in bytes. For example,
123966 ** fts3PrefixCompress("abc", 3, "abcdef", 6) // returns 3
123967 ** fts3PrefixCompress("abX", 3, "abcdef", 6) // returns 2
123968 ** fts3PrefixCompress("abX", 3, "Xbcdef", 6) // returns 0
123970 static int fts3PrefixCompress(
123971 const char *zPrev, /* Buffer containing previous term */
123972 int nPrev, /* Size of buffer zPrev in bytes */
123973 const char *zNext, /* Buffer containing next term */
123974 int nNext /* Size of buffer zNext in bytes */
123976 int n;
123977 UNUSED_PARAMETER(nNext);
123978 for(n=0; n<nPrev && zPrev[n]==zNext[n]; n++);
123979 return n;
123983 ** Add term zTerm to the SegmentNode. It is guaranteed that zTerm is larger
123984 ** (according to memcmp) than the previous term.
123986 static int fts3NodeAddTerm(
123987 Fts3Table *p, /* Virtual table handle */
123988 SegmentNode **ppTree, /* IN/OUT: SegmentNode handle */
123989 int isCopyTerm, /* True if zTerm/nTerm is transient */
123990 const char *zTerm, /* Pointer to buffer containing term */
123991 int nTerm /* Size of term in bytes */
123993 SegmentNode *pTree = *ppTree;
123994 int rc;
123995 SegmentNode *pNew;
123997 /* First try to append the term to the current node. Return early if
123998 ** this is possible.
124000 if( pTree ){
124001 int nData = pTree->nData; /* Current size of node in bytes */
124002 int nReq = nData; /* Required space after adding zTerm */
124003 int nPrefix; /* Number of bytes of prefix compression */
124004 int nSuffix; /* Suffix length */
124006 nPrefix = fts3PrefixCompress(pTree->zTerm, pTree->nTerm, zTerm, nTerm);
124007 nSuffix = nTerm-nPrefix;
124009 nReq += sqlite3Fts3VarintLen(nPrefix)+sqlite3Fts3VarintLen(nSuffix)+nSuffix;
124010 if( nReq<=p->nNodeSize || !pTree->zTerm ){
124012 if( nReq>p->nNodeSize ){
124013 /* An unusual case: this is the first term to be added to the node
124014 ** and the static node buffer (p->nNodeSize bytes) is not large
124015 ** enough. Use a separately malloced buffer instead This wastes
124016 ** p->nNodeSize bytes, but since this scenario only comes about when
124017 ** the database contain two terms that share a prefix of almost 2KB,
124018 ** this is not expected to be a serious problem.
124020 assert( pTree->aData==(char *)&pTree[1] );
124021 pTree->aData = (char *)sqlite3_malloc(nReq);
124022 if( !pTree->aData ){
124023 return SQLITE_NOMEM;
124027 if( pTree->zTerm ){
124028 /* There is no prefix-length field for first term in a node */
124029 nData += sqlite3Fts3PutVarint(&pTree->aData[nData], nPrefix);
124032 nData += sqlite3Fts3PutVarint(&pTree->aData[nData], nSuffix);
124033 memcpy(&pTree->aData[nData], &zTerm[nPrefix], nSuffix);
124034 pTree->nData = nData + nSuffix;
124035 pTree->nEntry++;
124037 if( isCopyTerm ){
124038 if( pTree->nMalloc<nTerm ){
124039 char *zNew = sqlite3_realloc(pTree->zMalloc, nTerm*2);
124040 if( !zNew ){
124041 return SQLITE_NOMEM;
124043 pTree->nMalloc = nTerm*2;
124044 pTree->zMalloc = zNew;
124046 pTree->zTerm = pTree->zMalloc;
124047 memcpy(pTree->zTerm, zTerm, nTerm);
124048 pTree->nTerm = nTerm;
124049 }else{
124050 pTree->zTerm = (char *)zTerm;
124051 pTree->nTerm = nTerm;
124053 return SQLITE_OK;
124057 /* If control flows to here, it was not possible to append zTerm to the
124058 ** current node. Create a new node (a right-sibling of the current node).
124059 ** If this is the first node in the tree, the term is added to it.
124061 ** Otherwise, the term is not added to the new node, it is left empty for
124062 ** now. Instead, the term is inserted into the parent of pTree. If pTree
124063 ** has no parent, one is created here.
124065 pNew = (SegmentNode *)sqlite3_malloc(sizeof(SegmentNode) + p->nNodeSize);
124066 if( !pNew ){
124067 return SQLITE_NOMEM;
124069 memset(pNew, 0, sizeof(SegmentNode));
124070 pNew->nData = 1 + FTS3_VARINT_MAX;
124071 pNew->aData = (char *)&pNew[1];
124073 if( pTree ){
124074 SegmentNode *pParent = pTree->pParent;
124075 rc = fts3NodeAddTerm(p, &pParent, isCopyTerm, zTerm, nTerm);
124076 if( pTree->pParent==0 ){
124077 pTree->pParent = pParent;
124079 pTree->pRight = pNew;
124080 pNew->pLeftmost = pTree->pLeftmost;
124081 pNew->pParent = pParent;
124082 pNew->zMalloc = pTree->zMalloc;
124083 pNew->nMalloc = pTree->nMalloc;
124084 pTree->zMalloc = 0;
124085 }else{
124086 pNew->pLeftmost = pNew;
124087 rc = fts3NodeAddTerm(p, &pNew, isCopyTerm, zTerm, nTerm);
124090 *ppTree = pNew;
124091 return rc;
124095 ** Helper function for fts3NodeWrite().
124097 static int fts3TreeFinishNode(
124098 SegmentNode *pTree,
124099 int iHeight,
124100 sqlite3_int64 iLeftChild
124102 int nStart;
124103 assert( iHeight>=1 && iHeight<128 );
124104 nStart = FTS3_VARINT_MAX - sqlite3Fts3VarintLen(iLeftChild);
124105 pTree->aData[nStart] = (char)iHeight;
124106 sqlite3Fts3PutVarint(&pTree->aData[nStart+1], iLeftChild);
124107 return nStart;
124111 ** Write the buffer for the segment node pTree and all of its peers to the
124112 ** database. Then call this function recursively to write the parent of
124113 ** pTree and its peers to the database.
124115 ** Except, if pTree is a root node, do not write it to the database. Instead,
124116 ** set output variables *paRoot and *pnRoot to contain the root node.
124118 ** If successful, SQLITE_OK is returned and output variable *piLast is
124119 ** set to the largest blockid written to the database (or zero if no
124120 ** blocks were written to the db). Otherwise, an SQLite error code is
124121 ** returned.
124123 static int fts3NodeWrite(
124124 Fts3Table *p, /* Virtual table handle */
124125 SegmentNode *pTree, /* SegmentNode handle */
124126 int iHeight, /* Height of this node in tree */
124127 sqlite3_int64 iLeaf, /* Block id of first leaf node */
124128 sqlite3_int64 iFree, /* Block id of next free slot in %_segments */
124129 sqlite3_int64 *piLast, /* OUT: Block id of last entry written */
124130 char **paRoot, /* OUT: Data for root node */
124131 int *pnRoot /* OUT: Size of root node in bytes */
124133 int rc = SQLITE_OK;
124135 if( !pTree->pParent ){
124136 /* Root node of the tree. */
124137 int nStart = fts3TreeFinishNode(pTree, iHeight, iLeaf);
124138 *piLast = iFree-1;
124139 *pnRoot = pTree->nData - nStart;
124140 *paRoot = &pTree->aData[nStart];
124141 }else{
124142 SegmentNode *pIter;
124143 sqlite3_int64 iNextFree = iFree;
124144 sqlite3_int64 iNextLeaf = iLeaf;
124145 for(pIter=pTree->pLeftmost; pIter && rc==SQLITE_OK; pIter=pIter->pRight){
124146 int nStart = fts3TreeFinishNode(pIter, iHeight, iNextLeaf);
124147 int nWrite = pIter->nData - nStart;
124149 rc = fts3WriteSegment(p, iNextFree, &pIter->aData[nStart], nWrite);
124150 iNextFree++;
124151 iNextLeaf += (pIter->nEntry+1);
124153 if( rc==SQLITE_OK ){
124154 assert( iNextLeaf==iFree );
124155 rc = fts3NodeWrite(
124156 p, pTree->pParent, iHeight+1, iFree, iNextFree, piLast, paRoot, pnRoot
124161 return rc;
124165 ** Free all memory allocations associated with the tree pTree.
124167 static void fts3NodeFree(SegmentNode *pTree){
124168 if( pTree ){
124169 SegmentNode *p = pTree->pLeftmost;
124170 fts3NodeFree(p->pParent);
124171 while( p ){
124172 SegmentNode *pRight = p->pRight;
124173 if( p->aData!=(char *)&p[1] ){
124174 sqlite3_free(p->aData);
124176 assert( pRight==0 || p->zMalloc==0 );
124177 sqlite3_free(p->zMalloc);
124178 sqlite3_free(p);
124179 p = pRight;
124185 ** Add a term to the segment being constructed by the SegmentWriter object
124186 ** *ppWriter. When adding the first term to a segment, *ppWriter should
124187 ** be passed NULL. This function will allocate a new SegmentWriter object
124188 ** and return it via the input/output variable *ppWriter in this case.
124190 ** If successful, SQLITE_OK is returned. Otherwise, an SQLite error code.
124192 static int fts3SegWriterAdd(
124193 Fts3Table *p, /* Virtual table handle */
124194 SegmentWriter **ppWriter, /* IN/OUT: SegmentWriter handle */
124195 int isCopyTerm, /* True if buffer zTerm must be copied */
124196 const char *zTerm, /* Pointer to buffer containing term */
124197 int nTerm, /* Size of term in bytes */
124198 const char *aDoclist, /* Pointer to buffer containing doclist */
124199 int nDoclist /* Size of doclist in bytes */
124201 int nPrefix; /* Size of term prefix in bytes */
124202 int nSuffix; /* Size of term suffix in bytes */
124203 int nReq; /* Number of bytes required on leaf page */
124204 int nData;
124205 SegmentWriter *pWriter = *ppWriter;
124207 if( !pWriter ){
124208 int rc;
124209 sqlite3_stmt *pStmt;
124211 /* Allocate the SegmentWriter structure */
124212 pWriter = (SegmentWriter *)sqlite3_malloc(sizeof(SegmentWriter));
124213 if( !pWriter ) return SQLITE_NOMEM;
124214 memset(pWriter, 0, sizeof(SegmentWriter));
124215 *ppWriter = pWriter;
124217 /* Allocate a buffer in which to accumulate data */
124218 pWriter->aData = (char *)sqlite3_malloc(p->nNodeSize);
124219 if( !pWriter->aData ) return SQLITE_NOMEM;
124220 pWriter->nSize = p->nNodeSize;
124222 /* Find the next free blockid in the %_segments table */
124223 rc = fts3SqlStmt(p, SQL_NEXT_SEGMENTS_ID, &pStmt, 0);
124224 if( rc!=SQLITE_OK ) return rc;
124225 if( SQLITE_ROW==sqlite3_step(pStmt) ){
124226 pWriter->iFree = sqlite3_column_int64(pStmt, 0);
124227 pWriter->iFirst = pWriter->iFree;
124229 rc = sqlite3_reset(pStmt);
124230 if( rc!=SQLITE_OK ) return rc;
124232 nData = pWriter->nData;
124234 nPrefix = fts3PrefixCompress(pWriter->zTerm, pWriter->nTerm, zTerm, nTerm);
124235 nSuffix = nTerm-nPrefix;
124237 /* Figure out how many bytes are required by this new entry */
124238 nReq = sqlite3Fts3VarintLen(nPrefix) + /* varint containing prefix size */
124239 sqlite3Fts3VarintLen(nSuffix) + /* varint containing suffix size */
124240 nSuffix + /* Term suffix */
124241 sqlite3Fts3VarintLen(nDoclist) + /* Size of doclist */
124242 nDoclist; /* Doclist data */
124244 if( nData>0 && nData+nReq>p->nNodeSize ){
124245 int rc;
124247 /* The current leaf node is full. Write it out to the database. */
124248 rc = fts3WriteSegment(p, pWriter->iFree++, pWriter->aData, nData);
124249 if( rc!=SQLITE_OK ) return rc;
124251 /* Add the current term to the interior node tree. The term added to
124252 ** the interior tree must:
124254 ** a) be greater than the largest term on the leaf node just written
124255 ** to the database (still available in pWriter->zTerm), and
124257 ** b) be less than or equal to the term about to be added to the new
124258 ** leaf node (zTerm/nTerm).
124260 ** In other words, it must be the prefix of zTerm 1 byte longer than
124261 ** the common prefix (if any) of zTerm and pWriter->zTerm.
124263 assert( nPrefix<nTerm );
124264 rc = fts3NodeAddTerm(p, &pWriter->pTree, isCopyTerm, zTerm, nPrefix+1);
124265 if( rc!=SQLITE_OK ) return rc;
124267 nData = 0;
124268 pWriter->nTerm = 0;
124270 nPrefix = 0;
124271 nSuffix = nTerm;
124272 nReq = 1 + /* varint containing prefix size */
124273 sqlite3Fts3VarintLen(nTerm) + /* varint containing suffix size */
124274 nTerm + /* Term suffix */
124275 sqlite3Fts3VarintLen(nDoclist) + /* Size of doclist */
124276 nDoclist; /* Doclist data */
124279 /* If the buffer currently allocated is too small for this entry, realloc
124280 ** the buffer to make it large enough.
124282 if( nReq>pWriter->nSize ){
124283 char *aNew = sqlite3_realloc(pWriter->aData, nReq);
124284 if( !aNew ) return SQLITE_NOMEM;
124285 pWriter->aData = aNew;
124286 pWriter->nSize = nReq;
124288 assert( nData+nReq<=pWriter->nSize );
124290 /* Append the prefix-compressed term and doclist to the buffer. */
124291 nData += sqlite3Fts3PutVarint(&pWriter->aData[nData], nPrefix);
124292 nData += sqlite3Fts3PutVarint(&pWriter->aData[nData], nSuffix);
124293 memcpy(&pWriter->aData[nData], &zTerm[nPrefix], nSuffix);
124294 nData += nSuffix;
124295 nData += sqlite3Fts3PutVarint(&pWriter->aData[nData], nDoclist);
124296 memcpy(&pWriter->aData[nData], aDoclist, nDoclist);
124297 pWriter->nData = nData + nDoclist;
124299 /* Save the current term so that it can be used to prefix-compress the next.
124300 ** If the isCopyTerm parameter is true, then the buffer pointed to by
124301 ** zTerm is transient, so take a copy of the term data. Otherwise, just
124302 ** store a copy of the pointer.
124304 if( isCopyTerm ){
124305 if( nTerm>pWriter->nMalloc ){
124306 char *zNew = sqlite3_realloc(pWriter->zMalloc, nTerm*2);
124307 if( !zNew ){
124308 return SQLITE_NOMEM;
124310 pWriter->nMalloc = nTerm*2;
124311 pWriter->zMalloc = zNew;
124312 pWriter->zTerm = zNew;
124314 assert( pWriter->zTerm==pWriter->zMalloc );
124315 memcpy(pWriter->zTerm, zTerm, nTerm);
124316 }else{
124317 pWriter->zTerm = (char *)zTerm;
124319 pWriter->nTerm = nTerm;
124321 return SQLITE_OK;
124325 ** Flush all data associated with the SegmentWriter object pWriter to the
124326 ** database. This function must be called after all terms have been added
124327 ** to the segment using fts3SegWriterAdd(). If successful, SQLITE_OK is
124328 ** returned. Otherwise, an SQLite error code.
124330 static int fts3SegWriterFlush(
124331 Fts3Table *p, /* Virtual table handle */
124332 SegmentWriter *pWriter, /* SegmentWriter to flush to the db */
124333 int iLevel, /* Value for 'level' column of %_segdir */
124334 int iIdx /* Value for 'idx' column of %_segdir */
124336 int rc; /* Return code */
124337 if( pWriter->pTree ){
124338 sqlite3_int64 iLast = 0; /* Largest block id written to database */
124339 sqlite3_int64 iLastLeaf; /* Largest leaf block id written to db */
124340 char *zRoot = NULL; /* Pointer to buffer containing root node */
124341 int nRoot = 0; /* Size of buffer zRoot */
124343 iLastLeaf = pWriter->iFree;
124344 rc = fts3WriteSegment(p, pWriter->iFree++, pWriter->aData, pWriter->nData);
124345 if( rc==SQLITE_OK ){
124346 rc = fts3NodeWrite(p, pWriter->pTree, 1,
124347 pWriter->iFirst, pWriter->iFree, &iLast, &zRoot, &nRoot);
124349 if( rc==SQLITE_OK ){
124350 rc = fts3WriteSegdir(
124351 p, iLevel, iIdx, pWriter->iFirst, iLastLeaf, iLast, zRoot, nRoot);
124353 }else{
124354 /* The entire tree fits on the root node. Write it to the segdir table. */
124355 rc = fts3WriteSegdir(
124356 p, iLevel, iIdx, 0, 0, 0, pWriter->aData, pWriter->nData);
124358 return rc;
124362 ** Release all memory held by the SegmentWriter object passed as the
124363 ** first argument.
124365 static void fts3SegWriterFree(SegmentWriter *pWriter){
124366 if( pWriter ){
124367 sqlite3_free(pWriter->aData);
124368 sqlite3_free(pWriter->zMalloc);
124369 fts3NodeFree(pWriter->pTree);
124370 sqlite3_free(pWriter);
124375 ** The first value in the apVal[] array is assumed to contain an integer.
124376 ** This function tests if there exist any documents with docid values that
124377 ** are different from that integer. i.e. if deleting the document with docid
124378 ** pRowid would mean the FTS3 table were empty.
124380 ** If successful, *pisEmpty is set to true if the table is empty except for
124381 ** document pRowid, or false otherwise, and SQLITE_OK is returned. If an
124382 ** error occurs, an SQLite error code is returned.
124384 static int fts3IsEmpty(Fts3Table *p, sqlite3_value *pRowid, int *pisEmpty){
124385 sqlite3_stmt *pStmt;
124386 int rc;
124387 rc = fts3SqlStmt(p, SQL_IS_EMPTY, &pStmt, &pRowid);
124388 if( rc==SQLITE_OK ){
124389 if( SQLITE_ROW==sqlite3_step(pStmt) ){
124390 *pisEmpty = sqlite3_column_int(pStmt, 0);
124392 rc = sqlite3_reset(pStmt);
124394 return rc;
124398 ** Set *pnMax to the largest segment level in the database for the index
124399 ** iIndex.
124401 ** Segment levels are stored in the 'level' column of the %_segdir table.
124403 ** Return SQLITE_OK if successful, or an SQLite error code if not.
124405 static int fts3SegmentMaxLevel(Fts3Table *p, int iIndex, int *pnMax){
124406 sqlite3_stmt *pStmt;
124407 int rc;
124408 assert( iIndex>=0 && iIndex<p->nIndex );
124410 /* Set pStmt to the compiled version of:
124412 ** SELECT max(level) FROM %Q.'%q_segdir' WHERE level BETWEEN ? AND ?
124414 ** (1024 is actually the value of macro FTS3_SEGDIR_PREFIXLEVEL_STR).
124416 rc = fts3SqlStmt(p, SQL_SELECT_SEGDIR_MAX_LEVEL, &pStmt, 0);
124417 if( rc!=SQLITE_OK ) return rc;
124418 sqlite3_bind_int(pStmt, 1, iIndex*FTS3_SEGDIR_MAXLEVEL);
124419 sqlite3_bind_int(pStmt, 2, (iIndex+1)*FTS3_SEGDIR_MAXLEVEL - 1);
124420 if( SQLITE_ROW==sqlite3_step(pStmt) ){
124421 *pnMax = sqlite3_column_int(pStmt, 0);
124423 return sqlite3_reset(pStmt);
124427 ** This function is used after merging multiple segments into a single large
124428 ** segment to delete the old, now redundant, segment b-trees. Specifically,
124429 ** it:
124431 ** 1) Deletes all %_segments entries for the segments associated with
124432 ** each of the SegReader objects in the array passed as the third
124433 ** argument, and
124435 ** 2) deletes all %_segdir entries with level iLevel, or all %_segdir
124436 ** entries regardless of level if (iLevel<0).
124438 ** SQLITE_OK is returned if successful, otherwise an SQLite error code.
124440 static int fts3DeleteSegdir(
124441 Fts3Table *p, /* Virtual table handle */
124442 int iIndex, /* Index for p->aIndex */
124443 int iLevel, /* Level of %_segdir entries to delete */
124444 Fts3SegReader **apSegment, /* Array of SegReader objects */
124445 int nReader /* Size of array apSegment */
124447 int rc; /* Return Code */
124448 int i; /* Iterator variable */
124449 sqlite3_stmt *pDelete; /* SQL statement to delete rows */
124451 rc = fts3SqlStmt(p, SQL_DELETE_SEGMENTS_RANGE, &pDelete, 0);
124452 for(i=0; rc==SQLITE_OK && i<nReader; i++){
124453 Fts3SegReader *pSegment = apSegment[i];
124454 if( pSegment->iStartBlock ){
124455 sqlite3_bind_int64(pDelete, 1, pSegment->iStartBlock);
124456 sqlite3_bind_int64(pDelete, 2, pSegment->iEndBlock);
124457 sqlite3_step(pDelete);
124458 rc = sqlite3_reset(pDelete);
124461 if( rc!=SQLITE_OK ){
124462 return rc;
124465 assert( iLevel>=0 || iLevel==FTS3_SEGCURSOR_ALL );
124466 if( iLevel==FTS3_SEGCURSOR_ALL ){
124467 rc = fts3SqlStmt(p, SQL_DELETE_SEGDIR_RANGE, &pDelete, 0);
124468 if( rc==SQLITE_OK ){
124469 sqlite3_bind_int(pDelete, 1, iIndex*FTS3_SEGDIR_MAXLEVEL);
124470 sqlite3_bind_int(pDelete, 2, (iIndex+1) * FTS3_SEGDIR_MAXLEVEL - 1);
124472 }else{
124473 rc = fts3SqlStmt(p, SQL_DELETE_SEGDIR_LEVEL, &pDelete, 0);
124474 if( rc==SQLITE_OK ){
124475 sqlite3_bind_int(pDelete, 1, iIndex*FTS3_SEGDIR_MAXLEVEL + iLevel);
124479 if( rc==SQLITE_OK ){
124480 sqlite3_step(pDelete);
124481 rc = sqlite3_reset(pDelete);
124484 return rc;
124488 ** When this function is called, buffer *ppList (size *pnList bytes) contains
124489 ** a position list that may (or may not) feature multiple columns. This
124490 ** function adjusts the pointer *ppList and the length *pnList so that they
124491 ** identify the subset of the position list that corresponds to column iCol.
124493 ** If there are no entries in the input position list for column iCol, then
124494 ** *pnList is set to zero before returning.
124496 static void fts3ColumnFilter(
124497 int iCol, /* Column to filter on */
124498 char **ppList, /* IN/OUT: Pointer to position list */
124499 int *pnList /* IN/OUT: Size of buffer *ppList in bytes */
124501 char *pList = *ppList;
124502 int nList = *pnList;
124503 char *pEnd = &pList[nList];
124504 int iCurrent = 0;
124505 char *p = pList;
124507 assert( iCol>=0 );
124508 while( 1 ){
124509 char c = 0;
124510 while( p<pEnd && (c | *p)&0xFE ) c = *p++ & 0x80;
124512 if( iCol==iCurrent ){
124513 nList = (int)(p - pList);
124514 break;
124517 nList -= (int)(p - pList);
124518 pList = p;
124519 if( nList==0 ){
124520 break;
124522 p = &pList[1];
124523 p += sqlite3Fts3GetVarint32(p, &iCurrent);
124526 *ppList = pList;
124527 *pnList = nList;
124531 ** Cache data in the Fts3MultiSegReader.aBuffer[] buffer (overwriting any
124532 ** existing data). Grow the buffer if required.
124534 ** If successful, return SQLITE_OK. Otherwise, if an OOM error is encountered
124535 ** trying to resize the buffer, return SQLITE_NOMEM.
124537 static int fts3MsrBufferData(
124538 Fts3MultiSegReader *pMsr, /* Multi-segment-reader handle */
124539 char *pList,
124540 int nList
124542 if( nList>pMsr->nBuffer ){
124543 char *pNew;
124544 pMsr->nBuffer = nList*2;
124545 pNew = (char *)sqlite3_realloc(pMsr->aBuffer, pMsr->nBuffer);
124546 if( !pNew ) return SQLITE_NOMEM;
124547 pMsr->aBuffer = pNew;
124550 memcpy(pMsr->aBuffer, pList, nList);
124551 return SQLITE_OK;
124554 SQLITE_PRIVATE int sqlite3Fts3MsrIncrNext(
124555 Fts3Table *p, /* Virtual table handle */
124556 Fts3MultiSegReader *pMsr, /* Multi-segment-reader handle */
124557 sqlite3_int64 *piDocid, /* OUT: Docid value */
124558 char **paPoslist, /* OUT: Pointer to position list */
124559 int *pnPoslist /* OUT: Size of position list in bytes */
124561 int nMerge = pMsr->nAdvance;
124562 Fts3SegReader **apSegment = pMsr->apSegment;
124563 int (*xCmp)(Fts3SegReader *, Fts3SegReader *) = (
124564 p->bDescIdx ? fts3SegReaderDoclistCmpRev : fts3SegReaderDoclistCmp
124567 if( nMerge==0 ){
124568 *paPoslist = 0;
124569 return SQLITE_OK;
124572 while( 1 ){
124573 Fts3SegReader *pSeg;
124574 pSeg = pMsr->apSegment[0];
124576 if( pSeg->pOffsetList==0 ){
124577 *paPoslist = 0;
124578 break;
124579 }else{
124580 int rc;
124581 char *pList;
124582 int nList;
124583 int j;
124584 sqlite3_int64 iDocid = apSegment[0]->iDocid;
124586 rc = fts3SegReaderNextDocid(p, apSegment[0], &pList, &nList);
124587 j = 1;
124588 while( rc==SQLITE_OK
124589 && j<nMerge
124590 && apSegment[j]->pOffsetList
124591 && apSegment[j]->iDocid==iDocid
124593 rc = fts3SegReaderNextDocid(p, apSegment[j], 0, 0);
124596 if( rc!=SQLITE_OK ) return rc;
124597 fts3SegReaderSort(pMsr->apSegment, nMerge, j, xCmp);
124599 if( pMsr->iColFilter>=0 ){
124600 fts3ColumnFilter(pMsr->iColFilter, &pList, &nList);
124603 if( nList>0 ){
124604 if( fts3SegReaderIsPending(apSegment[0]) ){
124605 rc = fts3MsrBufferData(pMsr, pList, nList+1);
124606 if( rc!=SQLITE_OK ) return rc;
124607 *paPoslist = pMsr->aBuffer;
124608 assert( (pMsr->aBuffer[nList] & 0xFE)==0x00 );
124609 }else{
124610 *paPoslist = pList;
124612 *piDocid = iDocid;
124613 *pnPoslist = nList;
124614 break;
124619 return SQLITE_OK;
124622 static int fts3SegReaderStart(
124623 Fts3Table *p, /* Virtual table handle */
124624 Fts3MultiSegReader *pCsr, /* Cursor object */
124625 const char *zTerm, /* Term searched for (or NULL) */
124626 int nTerm /* Length of zTerm in bytes */
124628 int i;
124629 int nSeg = pCsr->nSegment;
124631 /* If the Fts3SegFilter defines a specific term (or term prefix) to search
124632 ** for, then advance each segment iterator until it points to a term of
124633 ** equal or greater value than the specified term. This prevents many
124634 ** unnecessary merge/sort operations for the case where single segment
124635 ** b-tree leaf nodes contain more than one term.
124637 for(i=0; pCsr->bRestart==0 && i<pCsr->nSegment; i++){
124638 Fts3SegReader *pSeg = pCsr->apSegment[i];
124640 int rc = fts3SegReaderNext(p, pSeg, 0);
124641 if( rc!=SQLITE_OK ) return rc;
124642 }while( zTerm && fts3SegReaderTermCmp(pSeg, zTerm, nTerm)<0 );
124644 fts3SegReaderSort(pCsr->apSegment, nSeg, nSeg, fts3SegReaderCmp);
124646 return SQLITE_OK;
124649 SQLITE_PRIVATE int sqlite3Fts3SegReaderStart(
124650 Fts3Table *p, /* Virtual table handle */
124651 Fts3MultiSegReader *pCsr, /* Cursor object */
124652 Fts3SegFilter *pFilter /* Restrictions on range of iteration */
124654 pCsr->pFilter = pFilter;
124655 return fts3SegReaderStart(p, pCsr, pFilter->zTerm, pFilter->nTerm);
124658 SQLITE_PRIVATE int sqlite3Fts3MsrIncrStart(
124659 Fts3Table *p, /* Virtual table handle */
124660 Fts3MultiSegReader *pCsr, /* Cursor object */
124661 int iCol, /* Column to match on. */
124662 const char *zTerm, /* Term to iterate through a doclist for */
124663 int nTerm /* Number of bytes in zTerm */
124665 int i;
124666 int rc;
124667 int nSegment = pCsr->nSegment;
124668 int (*xCmp)(Fts3SegReader *, Fts3SegReader *) = (
124669 p->bDescIdx ? fts3SegReaderDoclistCmpRev : fts3SegReaderDoclistCmp
124672 assert( pCsr->pFilter==0 );
124673 assert( zTerm && nTerm>0 );
124675 /* Advance each segment iterator until it points to the term zTerm/nTerm. */
124676 rc = fts3SegReaderStart(p, pCsr, zTerm, nTerm);
124677 if( rc!=SQLITE_OK ) return rc;
124679 /* Determine how many of the segments actually point to zTerm/nTerm. */
124680 for(i=0; i<nSegment; i++){
124681 Fts3SegReader *pSeg = pCsr->apSegment[i];
124682 if( !pSeg->aNode || fts3SegReaderTermCmp(pSeg, zTerm, nTerm) ){
124683 break;
124686 pCsr->nAdvance = i;
124688 /* Advance each of the segments to point to the first docid. */
124689 for(i=0; i<pCsr->nAdvance; i++){
124690 rc = fts3SegReaderFirstDocid(p, pCsr->apSegment[i]);
124691 if( rc!=SQLITE_OK ) return rc;
124693 fts3SegReaderSort(pCsr->apSegment, i, i, xCmp);
124695 assert( iCol<0 || iCol<p->nColumn );
124696 pCsr->iColFilter = iCol;
124698 return SQLITE_OK;
124702 ** This function is called on a MultiSegReader that has been started using
124703 ** sqlite3Fts3MsrIncrStart(). One or more calls to MsrIncrNext() may also
124704 ** have been made. Calling this function puts the MultiSegReader in such
124705 ** a state that if the next two calls are:
124707 ** sqlite3Fts3SegReaderStart()
124708 ** sqlite3Fts3SegReaderStep()
124710 ** then the entire doclist for the term is available in
124711 ** MultiSegReader.aDoclist/nDoclist.
124713 SQLITE_PRIVATE int sqlite3Fts3MsrIncrRestart(Fts3MultiSegReader *pCsr){
124714 int i; /* Used to iterate through segment-readers */
124716 assert( pCsr->zTerm==0 );
124717 assert( pCsr->nTerm==0 );
124718 assert( pCsr->aDoclist==0 );
124719 assert( pCsr->nDoclist==0 );
124721 pCsr->nAdvance = 0;
124722 pCsr->bRestart = 1;
124723 for(i=0; i<pCsr->nSegment; i++){
124724 pCsr->apSegment[i]->pOffsetList = 0;
124725 pCsr->apSegment[i]->nOffsetList = 0;
124726 pCsr->apSegment[i]->iDocid = 0;
124729 return SQLITE_OK;
124733 SQLITE_PRIVATE int sqlite3Fts3SegReaderStep(
124734 Fts3Table *p, /* Virtual table handle */
124735 Fts3MultiSegReader *pCsr /* Cursor object */
124737 int rc = SQLITE_OK;
124739 int isIgnoreEmpty = (pCsr->pFilter->flags & FTS3_SEGMENT_IGNORE_EMPTY);
124740 int isRequirePos = (pCsr->pFilter->flags & FTS3_SEGMENT_REQUIRE_POS);
124741 int isColFilter = (pCsr->pFilter->flags & FTS3_SEGMENT_COLUMN_FILTER);
124742 int isPrefix = (pCsr->pFilter->flags & FTS3_SEGMENT_PREFIX);
124743 int isScan = (pCsr->pFilter->flags & FTS3_SEGMENT_SCAN);
124745 Fts3SegReader **apSegment = pCsr->apSegment;
124746 int nSegment = pCsr->nSegment;
124747 Fts3SegFilter *pFilter = pCsr->pFilter;
124748 int (*xCmp)(Fts3SegReader *, Fts3SegReader *) = (
124749 p->bDescIdx ? fts3SegReaderDoclistCmpRev : fts3SegReaderDoclistCmp
124752 if( pCsr->nSegment==0 ) return SQLITE_OK;
124755 int nMerge;
124756 int i;
124758 /* Advance the first pCsr->nAdvance entries in the apSegment[] array
124759 ** forward. Then sort the list in order of current term again.
124761 for(i=0; i<pCsr->nAdvance; i++){
124762 rc = fts3SegReaderNext(p, apSegment[i], 0);
124763 if( rc!=SQLITE_OK ) return rc;
124765 fts3SegReaderSort(apSegment, nSegment, pCsr->nAdvance, fts3SegReaderCmp);
124766 pCsr->nAdvance = 0;
124768 /* If all the seg-readers are at EOF, we're finished. return SQLITE_OK. */
124769 assert( rc==SQLITE_OK );
124770 if( apSegment[0]->aNode==0 ) break;
124772 pCsr->nTerm = apSegment[0]->nTerm;
124773 pCsr->zTerm = apSegment[0]->zTerm;
124775 /* If this is a prefix-search, and if the term that apSegment[0] points
124776 ** to does not share a suffix with pFilter->zTerm/nTerm, then all
124777 ** required callbacks have been made. In this case exit early.
124779 ** Similarly, if this is a search for an exact match, and the first term
124780 ** of segment apSegment[0] is not a match, exit early.
124782 if( pFilter->zTerm && !isScan ){
124783 if( pCsr->nTerm<pFilter->nTerm
124784 || (!isPrefix && pCsr->nTerm>pFilter->nTerm)
124785 || memcmp(pCsr->zTerm, pFilter->zTerm, pFilter->nTerm)
124787 break;
124791 nMerge = 1;
124792 while( nMerge<nSegment
124793 && apSegment[nMerge]->aNode
124794 && apSegment[nMerge]->nTerm==pCsr->nTerm
124795 && 0==memcmp(pCsr->zTerm, apSegment[nMerge]->zTerm, pCsr->nTerm)
124797 nMerge++;
124800 assert( isIgnoreEmpty || (isRequirePos && !isColFilter) );
124801 if( nMerge==1
124802 && !isIgnoreEmpty
124803 && (p->bDescIdx==0 || fts3SegReaderIsPending(apSegment[0])==0)
124805 pCsr->nDoclist = apSegment[0]->nDoclist;
124806 if( fts3SegReaderIsPending(apSegment[0]) ){
124807 rc = fts3MsrBufferData(pCsr, apSegment[0]->aDoclist, pCsr->nDoclist);
124808 pCsr->aDoclist = pCsr->aBuffer;
124809 }else{
124810 pCsr->aDoclist = apSegment[0]->aDoclist;
124812 if( rc==SQLITE_OK ) rc = SQLITE_ROW;
124813 }else{
124814 int nDoclist = 0; /* Size of doclist */
124815 sqlite3_int64 iPrev = 0; /* Previous docid stored in doclist */
124817 /* The current term of the first nMerge entries in the array
124818 ** of Fts3SegReader objects is the same. The doclists must be merged
124819 ** and a single term returned with the merged doclist.
124821 for(i=0; i<nMerge; i++){
124822 fts3SegReaderFirstDocid(p, apSegment[i]);
124824 fts3SegReaderSort(apSegment, nMerge, nMerge, xCmp);
124825 while( apSegment[0]->pOffsetList ){
124826 int j; /* Number of segments that share a docid */
124827 char *pList;
124828 int nList;
124829 int nByte;
124830 sqlite3_int64 iDocid = apSegment[0]->iDocid;
124831 fts3SegReaderNextDocid(p, apSegment[0], &pList, &nList);
124832 j = 1;
124833 while( j<nMerge
124834 && apSegment[j]->pOffsetList
124835 && apSegment[j]->iDocid==iDocid
124837 fts3SegReaderNextDocid(p, apSegment[j], 0, 0);
124841 if( isColFilter ){
124842 fts3ColumnFilter(pFilter->iCol, &pList, &nList);
124845 if( !isIgnoreEmpty || nList>0 ){
124847 /* Calculate the 'docid' delta value to write into the merged
124848 ** doclist. */
124849 sqlite3_int64 iDelta;
124850 if( p->bDescIdx && nDoclist>0 ){
124851 iDelta = iPrev - iDocid;
124852 }else{
124853 iDelta = iDocid - iPrev;
124855 assert( iDelta>0 || (nDoclist==0 && iDelta==iDocid) );
124856 assert( nDoclist>0 || iDelta==iDocid );
124858 nByte = sqlite3Fts3VarintLen(iDelta) + (isRequirePos?nList+1:0);
124859 if( nDoclist+nByte>pCsr->nBuffer ){
124860 char *aNew;
124861 pCsr->nBuffer = (nDoclist+nByte)*2;
124862 aNew = sqlite3_realloc(pCsr->aBuffer, pCsr->nBuffer);
124863 if( !aNew ){
124864 return SQLITE_NOMEM;
124866 pCsr->aBuffer = aNew;
124868 nDoclist += sqlite3Fts3PutVarint(&pCsr->aBuffer[nDoclist], iDelta);
124869 iPrev = iDocid;
124870 if( isRequirePos ){
124871 memcpy(&pCsr->aBuffer[nDoclist], pList, nList);
124872 nDoclist += nList;
124873 pCsr->aBuffer[nDoclist++] = '\0';
124877 fts3SegReaderSort(apSegment, nMerge, j, xCmp);
124879 if( nDoclist>0 ){
124880 pCsr->aDoclist = pCsr->aBuffer;
124881 pCsr->nDoclist = nDoclist;
124882 rc = SQLITE_ROW;
124885 pCsr->nAdvance = nMerge;
124886 }while( rc==SQLITE_OK );
124888 return rc;
124892 SQLITE_PRIVATE void sqlite3Fts3SegReaderFinish(
124893 Fts3MultiSegReader *pCsr /* Cursor object */
124895 if( pCsr ){
124896 int i;
124897 for(i=0; i<pCsr->nSegment; i++){
124898 sqlite3Fts3SegReaderFree(pCsr->apSegment[i]);
124900 sqlite3_free(pCsr->apSegment);
124901 sqlite3_free(pCsr->aBuffer);
124903 pCsr->nSegment = 0;
124904 pCsr->apSegment = 0;
124905 pCsr->aBuffer = 0;
124910 ** Merge all level iLevel segments in the database into a single
124911 ** iLevel+1 segment. Or, if iLevel<0, merge all segments into a
124912 ** single segment with a level equal to the numerically largest level
124913 ** currently present in the database.
124915 ** If this function is called with iLevel<0, but there is only one
124916 ** segment in the database, SQLITE_DONE is returned immediately.
124917 ** Otherwise, if successful, SQLITE_OK is returned. If an error occurs,
124918 ** an SQLite error code is returned.
124920 static int fts3SegmentMerge(Fts3Table *p, int iIndex, int iLevel){
124921 int rc; /* Return code */
124922 int iIdx = 0; /* Index of new segment */
124923 int iNewLevel = 0; /* Level/index to create new segment at */
124924 SegmentWriter *pWriter = 0; /* Used to write the new, merged, segment */
124925 Fts3SegFilter filter; /* Segment term filter condition */
124926 Fts3MultiSegReader csr; /* Cursor to iterate through level(s) */
124927 int bIgnoreEmpty = 0; /* True to ignore empty segments */
124929 assert( iLevel==FTS3_SEGCURSOR_ALL
124930 || iLevel==FTS3_SEGCURSOR_PENDING
124931 || iLevel>=0
124933 assert( iLevel<FTS3_SEGDIR_MAXLEVEL );
124934 assert( iIndex>=0 && iIndex<p->nIndex );
124936 rc = sqlite3Fts3SegReaderCursor(p, iIndex, iLevel, 0, 0, 1, 0, &csr);
124937 if( rc!=SQLITE_OK || csr.nSegment==0 ) goto finished;
124939 if( iLevel==FTS3_SEGCURSOR_ALL ){
124940 /* This call is to merge all segments in the database to a single
124941 ** segment. The level of the new segment is equal to the the numerically
124942 ** greatest segment level currently present in the database for this
124943 ** index. The idx of the new segment is always 0. */
124944 if( csr.nSegment==1 ){
124945 rc = SQLITE_DONE;
124946 goto finished;
124948 rc = fts3SegmentMaxLevel(p, iIndex, &iNewLevel);
124949 bIgnoreEmpty = 1;
124951 }else if( iLevel==FTS3_SEGCURSOR_PENDING ){
124952 iNewLevel = iIndex * FTS3_SEGDIR_MAXLEVEL;
124953 rc = fts3AllocateSegdirIdx(p, iIndex, 0, &iIdx);
124954 }else{
124955 /* This call is to merge all segments at level iLevel. find the next
124956 ** available segment index at level iLevel+1. The call to
124957 ** fts3AllocateSegdirIdx() will merge the segments at level iLevel+1 to
124958 ** a single iLevel+2 segment if necessary. */
124959 rc = fts3AllocateSegdirIdx(p, iIndex, iLevel+1, &iIdx);
124960 iNewLevel = iIndex * FTS3_SEGDIR_MAXLEVEL + iLevel+1;
124962 if( rc!=SQLITE_OK ) goto finished;
124963 assert( csr.nSegment>0 );
124964 assert( iNewLevel>=(iIndex*FTS3_SEGDIR_MAXLEVEL) );
124965 assert( iNewLevel<((iIndex+1)*FTS3_SEGDIR_MAXLEVEL) );
124967 memset(&filter, 0, sizeof(Fts3SegFilter));
124968 filter.flags = FTS3_SEGMENT_REQUIRE_POS;
124969 filter.flags |= (bIgnoreEmpty ? FTS3_SEGMENT_IGNORE_EMPTY : 0);
124971 rc = sqlite3Fts3SegReaderStart(p, &csr, &filter);
124972 while( SQLITE_OK==rc ){
124973 rc = sqlite3Fts3SegReaderStep(p, &csr);
124974 if( rc!=SQLITE_ROW ) break;
124975 rc = fts3SegWriterAdd(p, &pWriter, 1,
124976 csr.zTerm, csr.nTerm, csr.aDoclist, csr.nDoclist);
124978 if( rc!=SQLITE_OK ) goto finished;
124979 assert( pWriter );
124981 if( iLevel!=FTS3_SEGCURSOR_PENDING ){
124982 rc = fts3DeleteSegdir(p, iIndex, iLevel, csr.apSegment, csr.nSegment);
124983 if( rc!=SQLITE_OK ) goto finished;
124985 rc = fts3SegWriterFlush(p, pWriter, iNewLevel, iIdx);
124987 finished:
124988 fts3SegWriterFree(pWriter);
124989 sqlite3Fts3SegReaderFinish(&csr);
124990 return rc;
124995 ** Flush the contents of pendingTerms to level 0 segments.
124997 SQLITE_PRIVATE int sqlite3Fts3PendingTermsFlush(Fts3Table *p){
124998 int rc = SQLITE_OK;
124999 int i;
125000 for(i=0; rc==SQLITE_OK && i<p->nIndex; i++){
125001 rc = fts3SegmentMerge(p, i, FTS3_SEGCURSOR_PENDING);
125002 if( rc==SQLITE_DONE ) rc = SQLITE_OK;
125004 sqlite3Fts3PendingTermsClear(p);
125005 return rc;
125009 ** Encode N integers as varints into a blob.
125011 static void fts3EncodeIntArray(
125012 int N, /* The number of integers to encode */
125013 u32 *a, /* The integer values */
125014 char *zBuf, /* Write the BLOB here */
125015 int *pNBuf /* Write number of bytes if zBuf[] used here */
125017 int i, j;
125018 for(i=j=0; i<N; i++){
125019 j += sqlite3Fts3PutVarint(&zBuf[j], (sqlite3_int64)a[i]);
125021 *pNBuf = j;
125025 ** Decode a blob of varints into N integers
125027 static void fts3DecodeIntArray(
125028 int N, /* The number of integers to decode */
125029 u32 *a, /* Write the integer values */
125030 const char *zBuf, /* The BLOB containing the varints */
125031 int nBuf /* size of the BLOB */
125033 int i, j;
125034 UNUSED_PARAMETER(nBuf);
125035 for(i=j=0; i<N; i++){
125036 sqlite3_int64 x;
125037 j += sqlite3Fts3GetVarint(&zBuf[j], &x);
125038 assert(j<=nBuf);
125039 a[i] = (u32)(x & 0xffffffff);
125044 ** Insert the sizes (in tokens) for each column of the document
125045 ** with docid equal to p->iPrevDocid. The sizes are encoded as
125046 ** a blob of varints.
125048 static void fts3InsertDocsize(
125049 int *pRC, /* Result code */
125050 Fts3Table *p, /* Table into which to insert */
125051 u32 *aSz /* Sizes of each column */
125053 char *pBlob; /* The BLOB encoding of the document size */
125054 int nBlob; /* Number of bytes in the BLOB */
125055 sqlite3_stmt *pStmt; /* Statement used to insert the encoding */
125056 int rc; /* Result code from subfunctions */
125058 if( *pRC ) return;
125059 pBlob = sqlite3_malloc( 10*p->nColumn );
125060 if( pBlob==0 ){
125061 *pRC = SQLITE_NOMEM;
125062 return;
125064 fts3EncodeIntArray(p->nColumn, aSz, pBlob, &nBlob);
125065 rc = fts3SqlStmt(p, SQL_REPLACE_DOCSIZE, &pStmt, 0);
125066 if( rc ){
125067 sqlite3_free(pBlob);
125068 *pRC = rc;
125069 return;
125071 sqlite3_bind_int64(pStmt, 1, p->iPrevDocid);
125072 sqlite3_bind_blob(pStmt, 2, pBlob, nBlob, sqlite3_free);
125073 sqlite3_step(pStmt);
125074 *pRC = sqlite3_reset(pStmt);
125078 ** Record 0 of the %_stat table contains a blob consisting of N varints,
125079 ** where N is the number of user defined columns in the fts3 table plus
125080 ** two. If nCol is the number of user defined columns, then values of the
125081 ** varints are set as follows:
125083 ** Varint 0: Total number of rows in the table.
125085 ** Varint 1..nCol: For each column, the total number of tokens stored in
125086 ** the column for all rows of the table.
125088 ** Varint 1+nCol: The total size, in bytes, of all text values in all
125089 ** columns of all rows of the table.
125092 static void fts3UpdateDocTotals(
125093 int *pRC, /* The result code */
125094 Fts3Table *p, /* Table being updated */
125095 u32 *aSzIns, /* Size increases */
125096 u32 *aSzDel, /* Size decreases */
125097 int nChng /* Change in the number of documents */
125099 char *pBlob; /* Storage for BLOB written into %_stat */
125100 int nBlob; /* Size of BLOB written into %_stat */
125101 u32 *a; /* Array of integers that becomes the BLOB */
125102 sqlite3_stmt *pStmt; /* Statement for reading and writing */
125103 int i; /* Loop counter */
125104 int rc; /* Result code from subfunctions */
125106 const int nStat = p->nColumn+2;
125108 if( *pRC ) return;
125109 a = sqlite3_malloc( (sizeof(u32)+10)*nStat );
125110 if( a==0 ){
125111 *pRC = SQLITE_NOMEM;
125112 return;
125114 pBlob = (char*)&a[nStat];
125115 rc = fts3SqlStmt(p, SQL_SELECT_DOCTOTAL, &pStmt, 0);
125116 if( rc ){
125117 sqlite3_free(a);
125118 *pRC = rc;
125119 return;
125121 if( sqlite3_step(pStmt)==SQLITE_ROW ){
125122 fts3DecodeIntArray(nStat, a,
125123 sqlite3_column_blob(pStmt, 0),
125124 sqlite3_column_bytes(pStmt, 0));
125125 }else{
125126 memset(a, 0, sizeof(u32)*(nStat) );
125128 sqlite3_reset(pStmt);
125129 if( nChng<0 && a[0]<(u32)(-nChng) ){
125130 a[0] = 0;
125131 }else{
125132 a[0] += nChng;
125134 for(i=0; i<p->nColumn+1; i++){
125135 u32 x = a[i+1];
125136 if( x+aSzIns[i] < aSzDel[i] ){
125137 x = 0;
125138 }else{
125139 x = x + aSzIns[i] - aSzDel[i];
125141 a[i+1] = x;
125143 fts3EncodeIntArray(nStat, a, pBlob, &nBlob);
125144 rc = fts3SqlStmt(p, SQL_REPLACE_DOCTOTAL, &pStmt, 0);
125145 if( rc ){
125146 sqlite3_free(a);
125147 *pRC = rc;
125148 return;
125150 sqlite3_bind_blob(pStmt, 1, pBlob, nBlob, SQLITE_STATIC);
125151 sqlite3_step(pStmt);
125152 *pRC = sqlite3_reset(pStmt);
125153 sqlite3_free(a);
125156 static int fts3DoOptimize(Fts3Table *p, int bReturnDone){
125157 int i;
125158 int bSeenDone = 0;
125159 int rc = SQLITE_OK;
125160 for(i=0; rc==SQLITE_OK && i<p->nIndex; i++){
125161 rc = fts3SegmentMerge(p, i, FTS3_SEGCURSOR_ALL);
125162 if( rc==SQLITE_DONE ){
125163 bSeenDone = 1;
125164 rc = SQLITE_OK;
125167 sqlite3Fts3SegmentsClose(p);
125168 sqlite3Fts3PendingTermsClear(p);
125170 return (rc==SQLITE_OK && bReturnDone && bSeenDone) ? SQLITE_DONE : rc;
125174 ** Handle a 'special' INSERT of the form:
125176 ** "INSERT INTO tbl(tbl) VALUES(<expr>)"
125178 ** Argument pVal contains the result of <expr>. Currently the only
125179 ** meaningful value to insert is the text 'optimize'.
125181 static int fts3SpecialInsert(Fts3Table *p, sqlite3_value *pVal){
125182 int rc; /* Return Code */
125183 const char *zVal = (const char *)sqlite3_value_text(pVal);
125184 int nVal = sqlite3_value_bytes(pVal);
125186 if( !zVal ){
125187 return SQLITE_NOMEM;
125188 }else if( nVal==8 && 0==sqlite3_strnicmp(zVal, "optimize", 8) ){
125189 rc = fts3DoOptimize(p, 0);
125190 #ifdef SQLITE_TEST
125191 }else if( nVal>9 && 0==sqlite3_strnicmp(zVal, "nodesize=", 9) ){
125192 p->nNodeSize = atoi(&zVal[9]);
125193 rc = SQLITE_OK;
125194 }else if( nVal>11 && 0==sqlite3_strnicmp(zVal, "maxpending=", 9) ){
125195 p->nMaxPendingData = atoi(&zVal[11]);
125196 rc = SQLITE_OK;
125197 #endif
125198 }else{
125199 rc = SQLITE_ERROR;
125202 return rc;
125206 ** Delete all cached deferred doclists. Deferred doclists are cached
125207 ** (allocated) by the sqlite3Fts3CacheDeferredDoclists() function.
125209 SQLITE_PRIVATE void sqlite3Fts3FreeDeferredDoclists(Fts3Cursor *pCsr){
125210 Fts3DeferredToken *pDef;
125211 for(pDef=pCsr->pDeferred; pDef; pDef=pDef->pNext){
125212 fts3PendingListDelete(pDef->pList);
125213 pDef->pList = 0;
125218 ** Free all entries in the pCsr->pDeffered list. Entries are added to
125219 ** this list using sqlite3Fts3DeferToken().
125221 SQLITE_PRIVATE void sqlite3Fts3FreeDeferredTokens(Fts3Cursor *pCsr){
125222 Fts3DeferredToken *pDef;
125223 Fts3DeferredToken *pNext;
125224 for(pDef=pCsr->pDeferred; pDef; pDef=pNext){
125225 pNext = pDef->pNext;
125226 fts3PendingListDelete(pDef->pList);
125227 sqlite3_free(pDef);
125229 pCsr->pDeferred = 0;
125233 ** Generate deferred-doclists for all tokens in the pCsr->pDeferred list
125234 ** based on the row that pCsr currently points to.
125236 ** A deferred-doclist is like any other doclist with position information
125237 ** included, except that it only contains entries for a single row of the
125238 ** table, not for all rows.
125240 SQLITE_PRIVATE int sqlite3Fts3CacheDeferredDoclists(Fts3Cursor *pCsr){
125241 int rc = SQLITE_OK; /* Return code */
125242 if( pCsr->pDeferred ){
125243 int i; /* Used to iterate through table columns */
125244 sqlite3_int64 iDocid; /* Docid of the row pCsr points to */
125245 Fts3DeferredToken *pDef; /* Used to iterate through deferred tokens */
125247 Fts3Table *p = (Fts3Table *)pCsr->base.pVtab;
125248 sqlite3_tokenizer *pT = p->pTokenizer;
125249 sqlite3_tokenizer_module const *pModule = pT->pModule;
125251 assert( pCsr->isRequireSeek==0 );
125252 iDocid = sqlite3_column_int64(pCsr->pStmt, 0);
125254 for(i=0; i<p->nColumn && rc==SQLITE_OK; i++){
125255 const char *zText = (const char *)sqlite3_column_text(pCsr->pStmt, i+1);
125256 sqlite3_tokenizer_cursor *pTC = 0;
125258 rc = pModule->xOpen(pT, zText, -1, &pTC);
125259 while( rc==SQLITE_OK ){
125260 char const *zToken; /* Buffer containing token */
125261 int nToken; /* Number of bytes in token */
125262 int iDum1, iDum2; /* Dummy variables */
125263 int iPos; /* Position of token in zText */
125265 pTC->pTokenizer = pT;
125266 rc = pModule->xNext(pTC, &zToken, &nToken, &iDum1, &iDum2, &iPos);
125267 for(pDef=pCsr->pDeferred; pDef && rc==SQLITE_OK; pDef=pDef->pNext){
125268 Fts3PhraseToken *pPT = pDef->pToken;
125269 if( (pDef->iCol>=p->nColumn || pDef->iCol==i)
125270 && (pPT->n==nToken || (pPT->isPrefix && pPT->n<nToken))
125271 && (0==memcmp(zToken, pPT->z, pPT->n))
125273 fts3PendingListAppend(&pDef->pList, iDocid, i, iPos, &rc);
125277 if( pTC ) pModule->xClose(pTC);
125278 if( rc==SQLITE_DONE ) rc = SQLITE_OK;
125281 for(pDef=pCsr->pDeferred; pDef && rc==SQLITE_OK; pDef=pDef->pNext){
125282 if( pDef->pList ){
125283 rc = fts3PendingListAppendVarint(&pDef->pList, 0);
125288 return rc;
125291 SQLITE_PRIVATE int sqlite3Fts3DeferredTokenList(
125292 Fts3DeferredToken *p,
125293 char **ppData,
125294 int *pnData
125296 char *pRet;
125297 int nSkip;
125298 sqlite3_int64 dummy;
125300 *ppData = 0;
125301 *pnData = 0;
125303 if( p->pList==0 ){
125304 return SQLITE_OK;
125307 pRet = (char *)sqlite3_malloc(p->pList->nData);
125308 if( !pRet ) return SQLITE_NOMEM;
125310 nSkip = sqlite3Fts3GetVarint(p->pList->aData, &dummy);
125311 *pnData = p->pList->nData - nSkip;
125312 *ppData = pRet;
125314 memcpy(pRet, &p->pList->aData[nSkip], *pnData);
125315 return SQLITE_OK;
125319 ** Add an entry for token pToken to the pCsr->pDeferred list.
125321 SQLITE_PRIVATE int sqlite3Fts3DeferToken(
125322 Fts3Cursor *pCsr, /* Fts3 table cursor */
125323 Fts3PhraseToken *pToken, /* Token to defer */
125324 int iCol /* Column that token must appear in (or -1) */
125326 Fts3DeferredToken *pDeferred;
125327 pDeferred = sqlite3_malloc(sizeof(*pDeferred));
125328 if( !pDeferred ){
125329 return SQLITE_NOMEM;
125331 memset(pDeferred, 0, sizeof(*pDeferred));
125332 pDeferred->pToken = pToken;
125333 pDeferred->pNext = pCsr->pDeferred;
125334 pDeferred->iCol = iCol;
125335 pCsr->pDeferred = pDeferred;
125337 assert( pToken->pDeferred==0 );
125338 pToken->pDeferred = pDeferred;
125340 return SQLITE_OK;
125344 ** SQLite value pRowid contains the rowid of a row that may or may not be
125345 ** present in the FTS3 table. If it is, delete it and adjust the contents
125346 ** of subsiduary data structures accordingly.
125348 static int fts3DeleteByRowid(
125349 Fts3Table *p,
125350 sqlite3_value *pRowid,
125351 int *pnDoc,
125352 u32 *aSzDel
125354 int isEmpty = 0;
125355 int rc = fts3IsEmpty(p, pRowid, &isEmpty);
125356 if( rc==SQLITE_OK ){
125357 if( isEmpty ){
125358 /* Deleting this row means the whole table is empty. In this case
125359 ** delete the contents of all three tables and throw away any
125360 ** data in the pendingTerms hash table. */
125361 rc = fts3DeleteAll(p);
125362 *pnDoc = *pnDoc - 1;
125363 }else{
125364 sqlite3_int64 iRemove = sqlite3_value_int64(pRowid);
125365 rc = fts3PendingTermsDocid(p, iRemove);
125366 fts3DeleteTerms(&rc, p, pRowid, aSzDel);
125367 fts3SqlExec(&rc, p, SQL_DELETE_CONTENT, &pRowid);
125368 if( sqlite3_changes(p->db) ) *pnDoc = *pnDoc - 1;
125369 if( p->bHasDocsize ){
125370 fts3SqlExec(&rc, p, SQL_DELETE_DOCSIZE, &pRowid);
125375 return rc;
125379 ** This function does the work for the xUpdate method of FTS3 virtual
125380 ** tables.
125382 SQLITE_PRIVATE int sqlite3Fts3UpdateMethod(
125383 sqlite3_vtab *pVtab, /* FTS3 vtab object */
125384 int nArg, /* Size of argument array */
125385 sqlite3_value **apVal, /* Array of arguments */
125386 sqlite_int64 *pRowid /* OUT: The affected (or effected) rowid */
125388 Fts3Table *p = (Fts3Table *)pVtab;
125389 int rc = SQLITE_OK; /* Return Code */
125390 int isRemove = 0; /* True for an UPDATE or DELETE */
125391 sqlite3_int64 iRemove = 0; /* Rowid removed by UPDATE or DELETE */
125392 u32 *aSzIns = 0; /* Sizes of inserted documents */
125393 u32 *aSzDel; /* Sizes of deleted documents */
125394 int nChng = 0; /* Net change in number of documents */
125395 int bInsertDone = 0;
125397 assert( p->pSegments==0 );
125399 /* Check for a "special" INSERT operation. One of the form:
125401 ** INSERT INTO xyz(xyz) VALUES('command');
125403 if( nArg>1
125404 && sqlite3_value_type(apVal[0])==SQLITE_NULL
125405 && sqlite3_value_type(apVal[p->nColumn+2])!=SQLITE_NULL
125407 rc = fts3SpecialInsert(p, apVal[p->nColumn+2]);
125408 goto update_out;
125411 /* Allocate space to hold the change in document sizes */
125412 aSzIns = sqlite3_malloc( sizeof(aSzIns[0])*(p->nColumn+1)*2 );
125413 if( aSzIns==0 ){
125414 rc = SQLITE_NOMEM;
125415 goto update_out;
125417 aSzDel = &aSzIns[p->nColumn+1];
125418 memset(aSzIns, 0, sizeof(aSzIns[0])*(p->nColumn+1)*2);
125420 /* If this is an INSERT operation, or an UPDATE that modifies the rowid
125421 ** value, then this operation requires constraint handling.
125423 ** If the on-conflict mode is REPLACE, this means that the existing row
125424 ** should be deleted from the database before inserting the new row. Or,
125425 ** if the on-conflict mode is other than REPLACE, then this method must
125426 ** detect the conflict and return SQLITE_CONSTRAINT before beginning to
125427 ** modify the database file.
125429 if( nArg>1 ){
125430 /* Find the value object that holds the new rowid value. */
125431 sqlite3_value *pNewRowid = apVal[3+p->nColumn];
125432 if( sqlite3_value_type(pNewRowid)==SQLITE_NULL ){
125433 pNewRowid = apVal[1];
125436 if( sqlite3_value_type(pNewRowid)!=SQLITE_NULL && (
125437 sqlite3_value_type(apVal[0])==SQLITE_NULL
125438 || sqlite3_value_int64(apVal[0])!=sqlite3_value_int64(pNewRowid)
125440 /* The new rowid is not NULL (in this case the rowid will be
125441 ** automatically assigned and there is no chance of a conflict), and
125442 ** the statement is either an INSERT or an UPDATE that modifies the
125443 ** rowid column. So if the conflict mode is REPLACE, then delete any
125444 ** existing row with rowid=pNewRowid.
125446 ** Or, if the conflict mode is not REPLACE, insert the new record into
125447 ** the %_content table. If we hit the duplicate rowid constraint (or any
125448 ** other error) while doing so, return immediately.
125450 ** This branch may also run if pNewRowid contains a value that cannot
125451 ** be losslessly converted to an integer. In this case, the eventual
125452 ** call to fts3InsertData() (either just below or further on in this
125453 ** function) will return SQLITE_MISMATCH. If fts3DeleteByRowid is
125454 ** invoked, it will delete zero rows (since no row will have
125455 ** docid=$pNewRowid if $pNewRowid is not an integer value).
125457 if( sqlite3_vtab_on_conflict(p->db)==SQLITE_REPLACE ){
125458 rc = fts3DeleteByRowid(p, pNewRowid, &nChng, aSzDel);
125459 }else{
125460 rc = fts3InsertData(p, apVal, pRowid);
125461 bInsertDone = 1;
125465 if( rc!=SQLITE_OK ){
125466 goto update_out;
125469 /* If this is a DELETE or UPDATE operation, remove the old record. */
125470 if( sqlite3_value_type(apVal[0])!=SQLITE_NULL ){
125471 assert( sqlite3_value_type(apVal[0])==SQLITE_INTEGER );
125472 rc = fts3DeleteByRowid(p, apVal[0], &nChng, aSzDel);
125473 isRemove = 1;
125474 iRemove = sqlite3_value_int64(apVal[0]);
125477 /* If this is an INSERT or UPDATE operation, insert the new record. */
125478 if( nArg>1 && rc==SQLITE_OK ){
125479 if( bInsertDone==0 ){
125480 rc = fts3InsertData(p, apVal, pRowid);
125481 if( rc==SQLITE_CONSTRAINT ) rc = SQLITE_CORRUPT_VTAB;
125483 if( rc==SQLITE_OK && (!isRemove || *pRowid!=iRemove) ){
125484 rc = fts3PendingTermsDocid(p, *pRowid);
125486 if( rc==SQLITE_OK ){
125487 rc = fts3InsertTerms(p, apVal, aSzIns);
125489 if( p->bHasDocsize ){
125490 fts3InsertDocsize(&rc, p, aSzIns);
125492 nChng++;
125495 if( p->bHasStat ){
125496 fts3UpdateDocTotals(&rc, p, aSzIns, aSzDel, nChng);
125499 update_out:
125500 sqlite3_free(aSzIns);
125501 sqlite3Fts3SegmentsClose(p);
125502 return rc;
125506 ** Flush any data in the pending-terms hash table to disk. If successful,
125507 ** merge all segments in the database (including the new segment, if
125508 ** there was any data to flush) into a single segment.
125510 SQLITE_PRIVATE int sqlite3Fts3Optimize(Fts3Table *p){
125511 int rc;
125512 rc = sqlite3_exec(p->db, "SAVEPOINT fts3", 0, 0, 0);
125513 if( rc==SQLITE_OK ){
125514 rc = fts3DoOptimize(p, 1);
125515 if( rc==SQLITE_OK || rc==SQLITE_DONE ){
125516 int rc2 = sqlite3_exec(p->db, "RELEASE fts3", 0, 0, 0);
125517 if( rc2!=SQLITE_OK ) rc = rc2;
125518 }else{
125519 sqlite3_exec(p->db, "ROLLBACK TO fts3", 0, 0, 0);
125520 sqlite3_exec(p->db, "RELEASE fts3", 0, 0, 0);
125523 sqlite3Fts3SegmentsClose(p);
125524 return rc;
125527 #endif
125529 /************** End of fts3_write.c ******************************************/
125530 /************** Begin file fts3_snippet.c ************************************/
125532 ** 2009 Oct 23
125534 ** The author disclaims copyright to this source code. In place of
125535 ** a legal notice, here is a blessing:
125537 ** May you do good and not evil.
125538 ** May you find forgiveness for yourself and forgive others.
125539 ** May you share freely, never taking more than you give.
125541 ******************************************************************************
125544 #if !defined(SQLITE_CORE) || defined(SQLITE_ENABLE_FTS3)
125546 /* #include <string.h> */
125547 /* #include <assert.h> */
125550 ** Characters that may appear in the second argument to matchinfo().
125552 #define FTS3_MATCHINFO_NPHRASE 'p' /* 1 value */
125553 #define FTS3_MATCHINFO_NCOL 'c' /* 1 value */
125554 #define FTS3_MATCHINFO_NDOC 'n' /* 1 value */
125555 #define FTS3_MATCHINFO_AVGLENGTH 'a' /* nCol values */
125556 #define FTS3_MATCHINFO_LENGTH 'l' /* nCol values */
125557 #define FTS3_MATCHINFO_LCS 's' /* nCol values */
125558 #define FTS3_MATCHINFO_HITS 'x' /* 3*nCol*nPhrase values */
125561 ** The default value for the second argument to matchinfo().
125563 #define FTS3_MATCHINFO_DEFAULT "pcx"
125567 ** Used as an fts3ExprIterate() context when loading phrase doclists to
125568 ** Fts3Expr.aDoclist[]/nDoclist.
125570 typedef struct LoadDoclistCtx LoadDoclistCtx;
125571 struct LoadDoclistCtx {
125572 Fts3Cursor *pCsr; /* FTS3 Cursor */
125573 int nPhrase; /* Number of phrases seen so far */
125574 int nToken; /* Number of tokens seen so far */
125578 ** The following types are used as part of the implementation of the
125579 ** fts3BestSnippet() routine.
125581 typedef struct SnippetIter SnippetIter;
125582 typedef struct SnippetPhrase SnippetPhrase;
125583 typedef struct SnippetFragment SnippetFragment;
125585 struct SnippetIter {
125586 Fts3Cursor *pCsr; /* Cursor snippet is being generated from */
125587 int iCol; /* Extract snippet from this column */
125588 int nSnippet; /* Requested snippet length (in tokens) */
125589 int nPhrase; /* Number of phrases in query */
125590 SnippetPhrase *aPhrase; /* Array of size nPhrase */
125591 int iCurrent; /* First token of current snippet */
125594 struct SnippetPhrase {
125595 int nToken; /* Number of tokens in phrase */
125596 char *pList; /* Pointer to start of phrase position list */
125597 int iHead; /* Next value in position list */
125598 char *pHead; /* Position list data following iHead */
125599 int iTail; /* Next value in trailing position list */
125600 char *pTail; /* Position list data following iTail */
125603 struct SnippetFragment {
125604 int iCol; /* Column snippet is extracted from */
125605 int iPos; /* Index of first token in snippet */
125606 u64 covered; /* Mask of query phrases covered */
125607 u64 hlmask; /* Mask of snippet terms to highlight */
125611 ** This type is used as an fts3ExprIterate() context object while
125612 ** accumulating the data returned by the matchinfo() function.
125614 typedef struct MatchInfo MatchInfo;
125615 struct MatchInfo {
125616 Fts3Cursor *pCursor; /* FTS3 Cursor */
125617 int nCol; /* Number of columns in table */
125618 int nPhrase; /* Number of matchable phrases in query */
125619 sqlite3_int64 nDoc; /* Number of docs in database */
125620 u32 *aMatchinfo; /* Pre-allocated buffer */
125626 ** The snippet() and offsets() functions both return text values. An instance
125627 ** of the following structure is used to accumulate those values while the
125628 ** functions are running. See fts3StringAppend() for details.
125630 typedef struct StrBuffer StrBuffer;
125631 struct StrBuffer {
125632 char *z; /* Pointer to buffer containing string */
125633 int n; /* Length of z in bytes (excl. nul-term) */
125634 int nAlloc; /* Allocated size of buffer z in bytes */
125639 ** This function is used to help iterate through a position-list. A position
125640 ** list is a list of unique integers, sorted from smallest to largest. Each
125641 ** element of the list is represented by an FTS3 varint that takes the value
125642 ** of the difference between the current element and the previous one plus
125643 ** two. For example, to store the position-list:
125645 ** 4 9 113
125647 ** the three varints:
125649 ** 6 7 106
125651 ** are encoded.
125653 ** When this function is called, *pp points to the start of an element of
125654 ** the list. *piPos contains the value of the previous entry in the list.
125655 ** After it returns, *piPos contains the value of the next element of the
125656 ** list and *pp is advanced to the following varint.
125658 static void fts3GetDeltaPosition(char **pp, int *piPos){
125659 int iVal;
125660 *pp += sqlite3Fts3GetVarint32(*pp, &iVal);
125661 *piPos += (iVal-2);
125665 ** Helper function for fts3ExprIterate() (see below).
125667 static int fts3ExprIterate2(
125668 Fts3Expr *pExpr, /* Expression to iterate phrases of */
125669 int *piPhrase, /* Pointer to phrase counter */
125670 int (*x)(Fts3Expr*,int,void*), /* Callback function to invoke for phrases */
125671 void *pCtx /* Second argument to pass to callback */
125673 int rc; /* Return code */
125674 int eType = pExpr->eType; /* Type of expression node pExpr */
125676 if( eType!=FTSQUERY_PHRASE ){
125677 assert( pExpr->pLeft && pExpr->pRight );
125678 rc = fts3ExprIterate2(pExpr->pLeft, piPhrase, x, pCtx);
125679 if( rc==SQLITE_OK && eType!=FTSQUERY_NOT ){
125680 rc = fts3ExprIterate2(pExpr->pRight, piPhrase, x, pCtx);
125682 }else{
125683 rc = x(pExpr, *piPhrase, pCtx);
125684 (*piPhrase)++;
125686 return rc;
125690 ** Iterate through all phrase nodes in an FTS3 query, except those that
125691 ** are part of a sub-tree that is the right-hand-side of a NOT operator.
125692 ** For each phrase node found, the supplied callback function is invoked.
125694 ** If the callback function returns anything other than SQLITE_OK,
125695 ** the iteration is abandoned and the error code returned immediately.
125696 ** Otherwise, SQLITE_OK is returned after a callback has been made for
125697 ** all eligible phrase nodes.
125699 static int fts3ExprIterate(
125700 Fts3Expr *pExpr, /* Expression to iterate phrases of */
125701 int (*x)(Fts3Expr*,int,void*), /* Callback function to invoke for phrases */
125702 void *pCtx /* Second argument to pass to callback */
125704 int iPhrase = 0; /* Variable used as the phrase counter */
125705 return fts3ExprIterate2(pExpr, &iPhrase, x, pCtx);
125709 ** This is an fts3ExprIterate() callback used while loading the doclists
125710 ** for each phrase into Fts3Expr.aDoclist[]/nDoclist. See also
125711 ** fts3ExprLoadDoclists().
125713 static int fts3ExprLoadDoclistsCb(Fts3Expr *pExpr, int iPhrase, void *ctx){
125714 int rc = SQLITE_OK;
125715 Fts3Phrase *pPhrase = pExpr->pPhrase;
125716 LoadDoclistCtx *p = (LoadDoclistCtx *)ctx;
125718 UNUSED_PARAMETER(iPhrase);
125720 p->nPhrase++;
125721 p->nToken += pPhrase->nToken;
125723 return rc;
125727 ** Load the doclists for each phrase in the query associated with FTS3 cursor
125728 ** pCsr.
125730 ** If pnPhrase is not NULL, then *pnPhrase is set to the number of matchable
125731 ** phrases in the expression (all phrases except those directly or
125732 ** indirectly descended from the right-hand-side of a NOT operator). If
125733 ** pnToken is not NULL, then it is set to the number of tokens in all
125734 ** matchable phrases of the expression.
125736 static int fts3ExprLoadDoclists(
125737 Fts3Cursor *pCsr, /* Fts3 cursor for current query */
125738 int *pnPhrase, /* OUT: Number of phrases in query */
125739 int *pnToken /* OUT: Number of tokens in query */
125741 int rc; /* Return Code */
125742 LoadDoclistCtx sCtx = {0,0,0}; /* Context for fts3ExprIterate() */
125743 sCtx.pCsr = pCsr;
125744 rc = fts3ExprIterate(pCsr->pExpr, fts3ExprLoadDoclistsCb, (void *)&sCtx);
125745 if( pnPhrase ) *pnPhrase = sCtx.nPhrase;
125746 if( pnToken ) *pnToken = sCtx.nToken;
125747 return rc;
125750 static int fts3ExprPhraseCountCb(Fts3Expr *pExpr, int iPhrase, void *ctx){
125751 (*(int *)ctx)++;
125752 UNUSED_PARAMETER(pExpr);
125753 UNUSED_PARAMETER(iPhrase);
125754 return SQLITE_OK;
125756 static int fts3ExprPhraseCount(Fts3Expr *pExpr){
125757 int nPhrase = 0;
125758 (void)fts3ExprIterate(pExpr, fts3ExprPhraseCountCb, (void *)&nPhrase);
125759 return nPhrase;
125763 ** Advance the position list iterator specified by the first two
125764 ** arguments so that it points to the first element with a value greater
125765 ** than or equal to parameter iNext.
125767 static void fts3SnippetAdvance(char **ppIter, int *piIter, int iNext){
125768 char *pIter = *ppIter;
125769 if( pIter ){
125770 int iIter = *piIter;
125772 while( iIter<iNext ){
125773 if( 0==(*pIter & 0xFE) ){
125774 iIter = -1;
125775 pIter = 0;
125776 break;
125778 fts3GetDeltaPosition(&pIter, &iIter);
125781 *piIter = iIter;
125782 *ppIter = pIter;
125787 ** Advance the snippet iterator to the next candidate snippet.
125789 static int fts3SnippetNextCandidate(SnippetIter *pIter){
125790 int i; /* Loop counter */
125792 if( pIter->iCurrent<0 ){
125793 /* The SnippetIter object has just been initialized. The first snippet
125794 ** candidate always starts at offset 0 (even if this candidate has a
125795 ** score of 0.0).
125797 pIter->iCurrent = 0;
125799 /* Advance the 'head' iterator of each phrase to the first offset that
125800 ** is greater than or equal to (iNext+nSnippet).
125802 for(i=0; i<pIter->nPhrase; i++){
125803 SnippetPhrase *pPhrase = &pIter->aPhrase[i];
125804 fts3SnippetAdvance(&pPhrase->pHead, &pPhrase->iHead, pIter->nSnippet);
125806 }else{
125807 int iStart;
125808 int iEnd = 0x7FFFFFFF;
125810 for(i=0; i<pIter->nPhrase; i++){
125811 SnippetPhrase *pPhrase = &pIter->aPhrase[i];
125812 if( pPhrase->pHead && pPhrase->iHead<iEnd ){
125813 iEnd = pPhrase->iHead;
125816 if( iEnd==0x7FFFFFFF ){
125817 return 1;
125820 pIter->iCurrent = iStart = iEnd - pIter->nSnippet + 1;
125821 for(i=0; i<pIter->nPhrase; i++){
125822 SnippetPhrase *pPhrase = &pIter->aPhrase[i];
125823 fts3SnippetAdvance(&pPhrase->pHead, &pPhrase->iHead, iEnd+1);
125824 fts3SnippetAdvance(&pPhrase->pTail, &pPhrase->iTail, iStart);
125828 return 0;
125832 ** Retrieve information about the current candidate snippet of snippet
125833 ** iterator pIter.
125835 static void fts3SnippetDetails(
125836 SnippetIter *pIter, /* Snippet iterator */
125837 u64 mCovered, /* Bitmask of phrases already covered */
125838 int *piToken, /* OUT: First token of proposed snippet */
125839 int *piScore, /* OUT: "Score" for this snippet */
125840 u64 *pmCover, /* OUT: Bitmask of phrases covered */
125841 u64 *pmHighlight /* OUT: Bitmask of terms to highlight */
125843 int iStart = pIter->iCurrent; /* First token of snippet */
125844 int iScore = 0; /* Score of this snippet */
125845 int i; /* Loop counter */
125846 u64 mCover = 0; /* Mask of phrases covered by this snippet */
125847 u64 mHighlight = 0; /* Mask of tokens to highlight in snippet */
125849 for(i=0; i<pIter->nPhrase; i++){
125850 SnippetPhrase *pPhrase = &pIter->aPhrase[i];
125851 if( pPhrase->pTail ){
125852 char *pCsr = pPhrase->pTail;
125853 int iCsr = pPhrase->iTail;
125855 while( iCsr<(iStart+pIter->nSnippet) ){
125856 int j;
125857 u64 mPhrase = (u64)1 << i;
125858 u64 mPos = (u64)1 << (iCsr - iStart);
125859 assert( iCsr>=iStart );
125860 if( (mCover|mCovered)&mPhrase ){
125861 iScore++;
125862 }else{
125863 iScore += 1000;
125865 mCover |= mPhrase;
125867 for(j=0; j<pPhrase->nToken; j++){
125868 mHighlight |= (mPos>>j);
125871 if( 0==(*pCsr & 0x0FE) ) break;
125872 fts3GetDeltaPosition(&pCsr, &iCsr);
125877 /* Set the output variables before returning. */
125878 *piToken = iStart;
125879 *piScore = iScore;
125880 *pmCover = mCover;
125881 *pmHighlight = mHighlight;
125885 ** This function is an fts3ExprIterate() callback used by fts3BestSnippet().
125886 ** Each invocation populates an element of the SnippetIter.aPhrase[] array.
125888 static int fts3SnippetFindPositions(Fts3Expr *pExpr, int iPhrase, void *ctx){
125889 SnippetIter *p = (SnippetIter *)ctx;
125890 SnippetPhrase *pPhrase = &p->aPhrase[iPhrase];
125891 char *pCsr;
125893 pPhrase->nToken = pExpr->pPhrase->nToken;
125895 pCsr = sqlite3Fts3EvalPhrasePoslist(p->pCsr, pExpr, p->iCol);
125896 if( pCsr ){
125897 int iFirst = 0;
125898 pPhrase->pList = pCsr;
125899 fts3GetDeltaPosition(&pCsr, &iFirst);
125900 pPhrase->pHead = pCsr;
125901 pPhrase->pTail = pCsr;
125902 pPhrase->iHead = iFirst;
125903 pPhrase->iTail = iFirst;
125904 }else{
125905 assert( pPhrase->pList==0 && pPhrase->pHead==0 && pPhrase->pTail==0 );
125908 return SQLITE_OK;
125912 ** Select the fragment of text consisting of nFragment contiguous tokens
125913 ** from column iCol that represent the "best" snippet. The best snippet
125914 ** is the snippet with the highest score, where scores are calculated
125915 ** by adding:
125917 ** (a) +1 point for each occurence of a matchable phrase in the snippet.
125919 ** (b) +1000 points for the first occurence of each matchable phrase in
125920 ** the snippet for which the corresponding mCovered bit is not set.
125922 ** The selected snippet parameters are stored in structure *pFragment before
125923 ** returning. The score of the selected snippet is stored in *piScore
125924 ** before returning.
125926 static int fts3BestSnippet(
125927 int nSnippet, /* Desired snippet length */
125928 Fts3Cursor *pCsr, /* Cursor to create snippet for */
125929 int iCol, /* Index of column to create snippet from */
125930 u64 mCovered, /* Mask of phrases already covered */
125931 u64 *pmSeen, /* IN/OUT: Mask of phrases seen */
125932 SnippetFragment *pFragment, /* OUT: Best snippet found */
125933 int *piScore /* OUT: Score of snippet pFragment */
125935 int rc; /* Return Code */
125936 int nList; /* Number of phrases in expression */
125937 SnippetIter sIter; /* Iterates through snippet candidates */
125938 int nByte; /* Number of bytes of space to allocate */
125939 int iBestScore = -1; /* Best snippet score found so far */
125940 int i; /* Loop counter */
125942 memset(&sIter, 0, sizeof(sIter));
125944 /* Iterate through the phrases in the expression to count them. The same
125945 ** callback makes sure the doclists are loaded for each phrase.
125947 rc = fts3ExprLoadDoclists(pCsr, &nList, 0);
125948 if( rc!=SQLITE_OK ){
125949 return rc;
125952 /* Now that it is known how many phrases there are, allocate and zero
125953 ** the required space using malloc().
125955 nByte = sizeof(SnippetPhrase) * nList;
125956 sIter.aPhrase = (SnippetPhrase *)sqlite3_malloc(nByte);
125957 if( !sIter.aPhrase ){
125958 return SQLITE_NOMEM;
125960 memset(sIter.aPhrase, 0, nByte);
125962 /* Initialize the contents of the SnippetIter object. Then iterate through
125963 ** the set of phrases in the expression to populate the aPhrase[] array.
125965 sIter.pCsr = pCsr;
125966 sIter.iCol = iCol;
125967 sIter.nSnippet = nSnippet;
125968 sIter.nPhrase = nList;
125969 sIter.iCurrent = -1;
125970 (void)fts3ExprIterate(pCsr->pExpr, fts3SnippetFindPositions, (void *)&sIter);
125972 /* Set the *pmSeen output variable. */
125973 for(i=0; i<nList; i++){
125974 if( sIter.aPhrase[i].pHead ){
125975 *pmSeen |= (u64)1 << i;
125979 /* Loop through all candidate snippets. Store the best snippet in
125980 ** *pFragment. Store its associated 'score' in iBestScore.
125982 pFragment->iCol = iCol;
125983 while( !fts3SnippetNextCandidate(&sIter) ){
125984 int iPos;
125985 int iScore;
125986 u64 mCover;
125987 u64 mHighlight;
125988 fts3SnippetDetails(&sIter, mCovered, &iPos, &iScore, &mCover, &mHighlight);
125989 assert( iScore>=0 );
125990 if( iScore>iBestScore ){
125991 pFragment->iPos = iPos;
125992 pFragment->hlmask = mHighlight;
125993 pFragment->covered = mCover;
125994 iBestScore = iScore;
125998 sqlite3_free(sIter.aPhrase);
125999 *piScore = iBestScore;
126000 return SQLITE_OK;
126005 ** Append a string to the string-buffer passed as the first argument.
126007 ** If nAppend is negative, then the length of the string zAppend is
126008 ** determined using strlen().
126010 static int fts3StringAppend(
126011 StrBuffer *pStr, /* Buffer to append to */
126012 const char *zAppend, /* Pointer to data to append to buffer */
126013 int nAppend /* Size of zAppend in bytes (or -1) */
126015 if( nAppend<0 ){
126016 nAppend = (int)strlen(zAppend);
126019 /* If there is insufficient space allocated at StrBuffer.z, use realloc()
126020 ** to grow the buffer until so that it is big enough to accomadate the
126021 ** appended data.
126023 if( pStr->n+nAppend+1>=pStr->nAlloc ){
126024 int nAlloc = pStr->nAlloc+nAppend+100;
126025 char *zNew = sqlite3_realloc(pStr->z, nAlloc);
126026 if( !zNew ){
126027 return SQLITE_NOMEM;
126029 pStr->z = zNew;
126030 pStr->nAlloc = nAlloc;
126033 /* Append the data to the string buffer. */
126034 memcpy(&pStr->z[pStr->n], zAppend, nAppend);
126035 pStr->n += nAppend;
126036 pStr->z[pStr->n] = '\0';
126038 return SQLITE_OK;
126042 ** The fts3BestSnippet() function often selects snippets that end with a
126043 ** query term. That is, the final term of the snippet is always a term
126044 ** that requires highlighting. For example, if 'X' is a highlighted term
126045 ** and '.' is a non-highlighted term, BestSnippet() may select:
126047 ** ........X.....X
126049 ** This function "shifts" the beginning of the snippet forward in the
126050 ** document so that there are approximately the same number of
126051 ** non-highlighted terms to the right of the final highlighted term as there
126052 ** are to the left of the first highlighted term. For example, to this:
126054 ** ....X.....X....
126056 ** This is done as part of extracting the snippet text, not when selecting
126057 ** the snippet. Snippet selection is done based on doclists only, so there
126058 ** is no way for fts3BestSnippet() to know whether or not the document
126059 ** actually contains terms that follow the final highlighted term.
126061 static int fts3SnippetShift(
126062 Fts3Table *pTab, /* FTS3 table snippet comes from */
126063 int nSnippet, /* Number of tokens desired for snippet */
126064 const char *zDoc, /* Document text to extract snippet from */
126065 int nDoc, /* Size of buffer zDoc in bytes */
126066 int *piPos, /* IN/OUT: First token of snippet */
126067 u64 *pHlmask /* IN/OUT: Mask of tokens to highlight */
126069 u64 hlmask = *pHlmask; /* Local copy of initial highlight-mask */
126071 if( hlmask ){
126072 int nLeft; /* Tokens to the left of first highlight */
126073 int nRight; /* Tokens to the right of last highlight */
126074 int nDesired; /* Ideal number of tokens to shift forward */
126076 for(nLeft=0; !(hlmask & ((u64)1 << nLeft)); nLeft++);
126077 for(nRight=0; !(hlmask & ((u64)1 << (nSnippet-1-nRight))); nRight++);
126078 nDesired = (nLeft-nRight)/2;
126080 /* Ideally, the start of the snippet should be pushed forward in the
126081 ** document nDesired tokens. This block checks if there are actually
126082 ** nDesired tokens to the right of the snippet. If so, *piPos and
126083 ** *pHlMask are updated to shift the snippet nDesired tokens to the
126084 ** right. Otherwise, the snippet is shifted by the number of tokens
126085 ** available.
126087 if( nDesired>0 ){
126088 int nShift; /* Number of tokens to shift snippet by */
126089 int iCurrent = 0; /* Token counter */
126090 int rc; /* Return Code */
126091 sqlite3_tokenizer_module *pMod;
126092 sqlite3_tokenizer_cursor *pC;
126093 pMod = (sqlite3_tokenizer_module *)pTab->pTokenizer->pModule;
126095 /* Open a cursor on zDoc/nDoc. Check if there are (nSnippet+nDesired)
126096 ** or more tokens in zDoc/nDoc.
126098 rc = pMod->xOpen(pTab->pTokenizer, zDoc, nDoc, &pC);
126099 if( rc!=SQLITE_OK ){
126100 return rc;
126102 pC->pTokenizer = pTab->pTokenizer;
126103 while( rc==SQLITE_OK && iCurrent<(nSnippet+nDesired) ){
126104 const char *ZDUMMY; int DUMMY1, DUMMY2, DUMMY3;
126105 rc = pMod->xNext(pC, &ZDUMMY, &DUMMY1, &DUMMY2, &DUMMY3, &iCurrent);
126107 pMod->xClose(pC);
126108 if( rc!=SQLITE_OK && rc!=SQLITE_DONE ){ return rc; }
126110 nShift = (rc==SQLITE_DONE)+iCurrent-nSnippet;
126111 assert( nShift<=nDesired );
126112 if( nShift>0 ){
126113 *piPos += nShift;
126114 *pHlmask = hlmask >> nShift;
126118 return SQLITE_OK;
126122 ** Extract the snippet text for fragment pFragment from cursor pCsr and
126123 ** append it to string buffer pOut.
126125 static int fts3SnippetText(
126126 Fts3Cursor *pCsr, /* FTS3 Cursor */
126127 SnippetFragment *pFragment, /* Snippet to extract */
126128 int iFragment, /* Fragment number */
126129 int isLast, /* True for final fragment in snippet */
126130 int nSnippet, /* Number of tokens in extracted snippet */
126131 const char *zOpen, /* String inserted before highlighted term */
126132 const char *zClose, /* String inserted after highlighted term */
126133 const char *zEllipsis, /* String inserted between snippets */
126134 StrBuffer *pOut /* Write output here */
126136 Fts3Table *pTab = (Fts3Table *)pCsr->base.pVtab;
126137 int rc; /* Return code */
126138 const char *zDoc; /* Document text to extract snippet from */
126139 int nDoc; /* Size of zDoc in bytes */
126140 int iCurrent = 0; /* Current token number of document */
126141 int iEnd = 0; /* Byte offset of end of current token */
126142 int isShiftDone = 0; /* True after snippet is shifted */
126143 int iPos = pFragment->iPos; /* First token of snippet */
126144 u64 hlmask = pFragment->hlmask; /* Highlight-mask for snippet */
126145 int iCol = pFragment->iCol+1; /* Query column to extract text from */
126146 sqlite3_tokenizer_module *pMod; /* Tokenizer module methods object */
126147 sqlite3_tokenizer_cursor *pC; /* Tokenizer cursor open on zDoc/nDoc */
126148 const char *ZDUMMY; /* Dummy argument used with tokenizer */
126149 int DUMMY1; /* Dummy argument used with tokenizer */
126151 zDoc = (const char *)sqlite3_column_text(pCsr->pStmt, iCol);
126152 if( zDoc==0 ){
126153 if( sqlite3_column_type(pCsr->pStmt, iCol)!=SQLITE_NULL ){
126154 return SQLITE_NOMEM;
126156 return SQLITE_OK;
126158 nDoc = sqlite3_column_bytes(pCsr->pStmt, iCol);
126160 /* Open a token cursor on the document. */
126161 pMod = (sqlite3_tokenizer_module *)pTab->pTokenizer->pModule;
126162 rc = pMod->xOpen(pTab->pTokenizer, zDoc, nDoc, &pC);
126163 if( rc!=SQLITE_OK ){
126164 return rc;
126166 pC->pTokenizer = pTab->pTokenizer;
126168 while( rc==SQLITE_OK ){
126169 int iBegin; /* Offset in zDoc of start of token */
126170 int iFin; /* Offset in zDoc of end of token */
126171 int isHighlight; /* True for highlighted terms */
126173 rc = pMod->xNext(pC, &ZDUMMY, &DUMMY1, &iBegin, &iFin, &iCurrent);
126174 if( rc!=SQLITE_OK ){
126175 if( rc==SQLITE_DONE ){
126176 /* Special case - the last token of the snippet is also the last token
126177 ** of the column. Append any punctuation that occurred between the end
126178 ** of the previous token and the end of the document to the output.
126179 ** Then break out of the loop. */
126180 rc = fts3StringAppend(pOut, &zDoc[iEnd], -1);
126182 break;
126184 if( iCurrent<iPos ){ continue; }
126186 if( !isShiftDone ){
126187 int n = nDoc - iBegin;
126188 rc = fts3SnippetShift(pTab, nSnippet, &zDoc[iBegin], n, &iPos, &hlmask);
126189 isShiftDone = 1;
126191 /* Now that the shift has been done, check if the initial "..." are
126192 ** required. They are required if (a) this is not the first fragment,
126193 ** or (b) this fragment does not begin at position 0 of its column.
126195 if( rc==SQLITE_OK && (iPos>0 || iFragment>0) ){
126196 rc = fts3StringAppend(pOut, zEllipsis, -1);
126198 if( rc!=SQLITE_OK || iCurrent<iPos ) continue;
126201 if( iCurrent>=(iPos+nSnippet) ){
126202 if( isLast ){
126203 rc = fts3StringAppend(pOut, zEllipsis, -1);
126205 break;
126208 /* Set isHighlight to true if this term should be highlighted. */
126209 isHighlight = (hlmask & ((u64)1 << (iCurrent-iPos)))!=0;
126211 if( iCurrent>iPos ) rc = fts3StringAppend(pOut, &zDoc[iEnd], iBegin-iEnd);
126212 if( rc==SQLITE_OK && isHighlight ) rc = fts3StringAppend(pOut, zOpen, -1);
126213 if( rc==SQLITE_OK ) rc = fts3StringAppend(pOut, &zDoc[iBegin], iFin-iBegin);
126214 if( rc==SQLITE_OK && isHighlight ) rc = fts3StringAppend(pOut, zClose, -1);
126216 iEnd = iFin;
126219 pMod->xClose(pC);
126220 return rc;
126225 ** This function is used to count the entries in a column-list (a
126226 ** delta-encoded list of term offsets within a single column of a single
126227 ** row). When this function is called, *ppCollist should point to the
126228 ** beginning of the first varint in the column-list (the varint that
126229 ** contains the position of the first matching term in the column data).
126230 ** Before returning, *ppCollist is set to point to the first byte after
126231 ** the last varint in the column-list (either the 0x00 signifying the end
126232 ** of the position-list, or the 0x01 that precedes the column number of
126233 ** the next column in the position-list).
126235 ** The number of elements in the column-list is returned.
126237 static int fts3ColumnlistCount(char **ppCollist){
126238 char *pEnd = *ppCollist;
126239 char c = 0;
126240 int nEntry = 0;
126242 /* A column-list is terminated by either a 0x01 or 0x00. */
126243 while( 0xFE & (*pEnd | c) ){
126244 c = *pEnd++ & 0x80;
126245 if( !c ) nEntry++;
126248 *ppCollist = pEnd;
126249 return nEntry;
126253 ** fts3ExprIterate() callback used to collect the "global" matchinfo stats
126254 ** for a single query.
126256 ** fts3ExprIterate() callback to load the 'global' elements of a
126257 ** FTS3_MATCHINFO_HITS matchinfo array. The global stats are those elements
126258 ** of the matchinfo array that are constant for all rows returned by the
126259 ** current query.
126261 ** Argument pCtx is actually a pointer to a struct of type MatchInfo. This
126262 ** function populates Matchinfo.aMatchinfo[] as follows:
126264 ** for(iCol=0; iCol<nCol; iCol++){
126265 ** aMatchinfo[3*iPhrase*nCol + 3*iCol + 1] = X;
126266 ** aMatchinfo[3*iPhrase*nCol + 3*iCol + 2] = Y;
126269 ** where X is the number of matches for phrase iPhrase is column iCol of all
126270 ** rows of the table. Y is the number of rows for which column iCol contains
126271 ** at least one instance of phrase iPhrase.
126273 ** If the phrase pExpr consists entirely of deferred tokens, then all X and
126274 ** Y values are set to nDoc, where nDoc is the number of documents in the
126275 ** file system. This is done because the full-text index doclist is required
126276 ** to calculate these values properly, and the full-text index doclist is
126277 ** not available for deferred tokens.
126279 static int fts3ExprGlobalHitsCb(
126280 Fts3Expr *pExpr, /* Phrase expression node */
126281 int iPhrase, /* Phrase number (numbered from zero) */
126282 void *pCtx /* Pointer to MatchInfo structure */
126284 MatchInfo *p = (MatchInfo *)pCtx;
126285 return sqlite3Fts3EvalPhraseStats(
126286 p->pCursor, pExpr, &p->aMatchinfo[3*iPhrase*p->nCol]
126291 ** fts3ExprIterate() callback used to collect the "local" part of the
126292 ** FTS3_MATCHINFO_HITS array. The local stats are those elements of the
126293 ** array that are different for each row returned by the query.
126295 static int fts3ExprLocalHitsCb(
126296 Fts3Expr *pExpr, /* Phrase expression node */
126297 int iPhrase, /* Phrase number */
126298 void *pCtx /* Pointer to MatchInfo structure */
126300 MatchInfo *p = (MatchInfo *)pCtx;
126301 int iStart = iPhrase * p->nCol * 3;
126302 int i;
126304 for(i=0; i<p->nCol; i++){
126305 char *pCsr;
126306 pCsr = sqlite3Fts3EvalPhrasePoslist(p->pCursor, pExpr, i);
126307 if( pCsr ){
126308 p->aMatchinfo[iStart+i*3] = fts3ColumnlistCount(&pCsr);
126309 }else{
126310 p->aMatchinfo[iStart+i*3] = 0;
126314 return SQLITE_OK;
126317 static int fts3MatchinfoCheck(
126318 Fts3Table *pTab,
126319 char cArg,
126320 char **pzErr
126322 if( (cArg==FTS3_MATCHINFO_NPHRASE)
126323 || (cArg==FTS3_MATCHINFO_NCOL)
126324 || (cArg==FTS3_MATCHINFO_NDOC && pTab->bHasStat)
126325 || (cArg==FTS3_MATCHINFO_AVGLENGTH && pTab->bHasStat)
126326 || (cArg==FTS3_MATCHINFO_LENGTH && pTab->bHasDocsize)
126327 || (cArg==FTS3_MATCHINFO_LCS)
126328 || (cArg==FTS3_MATCHINFO_HITS)
126330 return SQLITE_OK;
126332 *pzErr = sqlite3_mprintf("unrecognized matchinfo request: %c", cArg);
126333 return SQLITE_ERROR;
126336 static int fts3MatchinfoSize(MatchInfo *pInfo, char cArg){
126337 int nVal; /* Number of integers output by cArg */
126339 switch( cArg ){
126340 case FTS3_MATCHINFO_NDOC:
126341 case FTS3_MATCHINFO_NPHRASE:
126342 case FTS3_MATCHINFO_NCOL:
126343 nVal = 1;
126344 break;
126346 case FTS3_MATCHINFO_AVGLENGTH:
126347 case FTS3_MATCHINFO_LENGTH:
126348 case FTS3_MATCHINFO_LCS:
126349 nVal = pInfo->nCol;
126350 break;
126352 default:
126353 assert( cArg==FTS3_MATCHINFO_HITS );
126354 nVal = pInfo->nCol * pInfo->nPhrase * 3;
126355 break;
126358 return nVal;
126361 static int fts3MatchinfoSelectDoctotal(
126362 Fts3Table *pTab,
126363 sqlite3_stmt **ppStmt,
126364 sqlite3_int64 *pnDoc,
126365 const char **paLen
126367 sqlite3_stmt *pStmt;
126368 const char *a;
126369 sqlite3_int64 nDoc;
126371 if( !*ppStmt ){
126372 int rc = sqlite3Fts3SelectDoctotal(pTab, ppStmt);
126373 if( rc!=SQLITE_OK ) return rc;
126375 pStmt = *ppStmt;
126376 assert( sqlite3_data_count(pStmt)==1 );
126378 a = sqlite3_column_blob(pStmt, 0);
126379 a += sqlite3Fts3GetVarint(a, &nDoc);
126380 if( nDoc==0 ) return SQLITE_CORRUPT_VTAB;
126381 *pnDoc = (u32)nDoc;
126383 if( paLen ) *paLen = a;
126384 return SQLITE_OK;
126388 ** An instance of the following structure is used to store state while
126389 ** iterating through a multi-column position-list corresponding to the
126390 ** hits for a single phrase on a single row in order to calculate the
126391 ** values for a matchinfo() FTS3_MATCHINFO_LCS request.
126393 typedef struct LcsIterator LcsIterator;
126394 struct LcsIterator {
126395 Fts3Expr *pExpr; /* Pointer to phrase expression */
126396 int iPosOffset; /* Tokens count up to end of this phrase */
126397 char *pRead; /* Cursor used to iterate through aDoclist */
126398 int iPos; /* Current position */
126402 ** If LcsIterator.iCol is set to the following value, the iterator has
126403 ** finished iterating through all offsets for all columns.
126405 #define LCS_ITERATOR_FINISHED 0x7FFFFFFF;
126407 static int fts3MatchinfoLcsCb(
126408 Fts3Expr *pExpr, /* Phrase expression node */
126409 int iPhrase, /* Phrase number (numbered from zero) */
126410 void *pCtx /* Pointer to MatchInfo structure */
126412 LcsIterator *aIter = (LcsIterator *)pCtx;
126413 aIter[iPhrase].pExpr = pExpr;
126414 return SQLITE_OK;
126418 ** Advance the iterator passed as an argument to the next position. Return
126419 ** 1 if the iterator is at EOF or if it now points to the start of the
126420 ** position list for the next column.
126422 static int fts3LcsIteratorAdvance(LcsIterator *pIter){
126423 char *pRead = pIter->pRead;
126424 sqlite3_int64 iRead;
126425 int rc = 0;
126427 pRead += sqlite3Fts3GetVarint(pRead, &iRead);
126428 if( iRead==0 || iRead==1 ){
126429 pRead = 0;
126430 rc = 1;
126431 }else{
126432 pIter->iPos += (int)(iRead-2);
126435 pIter->pRead = pRead;
126436 return rc;
126440 ** This function implements the FTS3_MATCHINFO_LCS matchinfo() flag.
126442 ** If the call is successful, the longest-common-substring lengths for each
126443 ** column are written into the first nCol elements of the pInfo->aMatchinfo[]
126444 ** array before returning. SQLITE_OK is returned in this case.
126446 ** Otherwise, if an error occurs, an SQLite error code is returned and the
126447 ** data written to the first nCol elements of pInfo->aMatchinfo[] is
126448 ** undefined.
126450 static int fts3MatchinfoLcs(Fts3Cursor *pCsr, MatchInfo *pInfo){
126451 LcsIterator *aIter;
126452 int i;
126453 int iCol;
126454 int nToken = 0;
126456 /* Allocate and populate the array of LcsIterator objects. The array
126457 ** contains one element for each matchable phrase in the query.
126459 aIter = sqlite3_malloc(sizeof(LcsIterator) * pCsr->nPhrase);
126460 if( !aIter ) return SQLITE_NOMEM;
126461 memset(aIter, 0, sizeof(LcsIterator) * pCsr->nPhrase);
126462 (void)fts3ExprIterate(pCsr->pExpr, fts3MatchinfoLcsCb, (void*)aIter);
126464 for(i=0; i<pInfo->nPhrase; i++){
126465 LcsIterator *pIter = &aIter[i];
126466 nToken -= pIter->pExpr->pPhrase->nToken;
126467 pIter->iPosOffset = nToken;
126470 for(iCol=0; iCol<pInfo->nCol; iCol++){
126471 int nLcs = 0; /* LCS value for this column */
126472 int nLive = 0; /* Number of iterators in aIter not at EOF */
126474 for(i=0; i<pInfo->nPhrase; i++){
126475 LcsIterator *pIt = &aIter[i];
126476 pIt->pRead = sqlite3Fts3EvalPhrasePoslist(pCsr, pIt->pExpr, iCol);
126477 if( pIt->pRead ){
126478 pIt->iPos = pIt->iPosOffset;
126479 fts3LcsIteratorAdvance(&aIter[i]);
126480 nLive++;
126484 while( nLive>0 ){
126485 LcsIterator *pAdv = 0; /* The iterator to advance by one position */
126486 int nThisLcs = 0; /* LCS for the current iterator positions */
126488 for(i=0; i<pInfo->nPhrase; i++){
126489 LcsIterator *pIter = &aIter[i];
126490 if( pIter->pRead==0 ){
126491 /* This iterator is already at EOF for this column. */
126492 nThisLcs = 0;
126493 }else{
126494 if( pAdv==0 || pIter->iPos<pAdv->iPos ){
126495 pAdv = pIter;
126497 if( nThisLcs==0 || pIter->iPos==pIter[-1].iPos ){
126498 nThisLcs++;
126499 }else{
126500 nThisLcs = 1;
126502 if( nThisLcs>nLcs ) nLcs = nThisLcs;
126505 if( fts3LcsIteratorAdvance(pAdv) ) nLive--;
126508 pInfo->aMatchinfo[iCol] = nLcs;
126511 sqlite3_free(aIter);
126512 return SQLITE_OK;
126516 ** Populate the buffer pInfo->aMatchinfo[] with an array of integers to
126517 ** be returned by the matchinfo() function. Argument zArg contains the
126518 ** format string passed as the second argument to matchinfo (or the
126519 ** default value "pcx" if no second argument was specified). The format
126520 ** string has already been validated and the pInfo->aMatchinfo[] array
126521 ** is guaranteed to be large enough for the output.
126523 ** If bGlobal is true, then populate all fields of the matchinfo() output.
126524 ** If it is false, then assume that those fields that do not change between
126525 ** rows (i.e. FTS3_MATCHINFO_NPHRASE, NCOL, NDOC, AVGLENGTH and part of HITS)
126526 ** have already been populated.
126528 ** Return SQLITE_OK if successful, or an SQLite error code if an error
126529 ** occurs. If a value other than SQLITE_OK is returned, the state the
126530 ** pInfo->aMatchinfo[] buffer is left in is undefined.
126532 static int fts3MatchinfoValues(
126533 Fts3Cursor *pCsr, /* FTS3 cursor object */
126534 int bGlobal, /* True to grab the global stats */
126535 MatchInfo *pInfo, /* Matchinfo context object */
126536 const char *zArg /* Matchinfo format string */
126538 int rc = SQLITE_OK;
126539 int i;
126540 Fts3Table *pTab = (Fts3Table *)pCsr->base.pVtab;
126541 sqlite3_stmt *pSelect = 0;
126543 for(i=0; rc==SQLITE_OK && zArg[i]; i++){
126545 switch( zArg[i] ){
126546 case FTS3_MATCHINFO_NPHRASE:
126547 if( bGlobal ) pInfo->aMatchinfo[0] = pInfo->nPhrase;
126548 break;
126550 case FTS3_MATCHINFO_NCOL:
126551 if( bGlobal ) pInfo->aMatchinfo[0] = pInfo->nCol;
126552 break;
126554 case FTS3_MATCHINFO_NDOC:
126555 if( bGlobal ){
126556 sqlite3_int64 nDoc = 0;
126557 rc = fts3MatchinfoSelectDoctotal(pTab, &pSelect, &nDoc, 0);
126558 pInfo->aMatchinfo[0] = (u32)nDoc;
126560 break;
126562 case FTS3_MATCHINFO_AVGLENGTH:
126563 if( bGlobal ){
126564 sqlite3_int64 nDoc; /* Number of rows in table */
126565 const char *a; /* Aggregate column length array */
126567 rc = fts3MatchinfoSelectDoctotal(pTab, &pSelect, &nDoc, &a);
126568 if( rc==SQLITE_OK ){
126569 int iCol;
126570 for(iCol=0; iCol<pInfo->nCol; iCol++){
126571 u32 iVal;
126572 sqlite3_int64 nToken;
126573 a += sqlite3Fts3GetVarint(a, &nToken);
126574 iVal = (u32)(((u32)(nToken&0xffffffff)+nDoc/2)/nDoc);
126575 pInfo->aMatchinfo[iCol] = iVal;
126579 break;
126581 case FTS3_MATCHINFO_LENGTH: {
126582 sqlite3_stmt *pSelectDocsize = 0;
126583 rc = sqlite3Fts3SelectDocsize(pTab, pCsr->iPrevId, &pSelectDocsize);
126584 if( rc==SQLITE_OK ){
126585 int iCol;
126586 const char *a = sqlite3_column_blob(pSelectDocsize, 0);
126587 for(iCol=0; iCol<pInfo->nCol; iCol++){
126588 sqlite3_int64 nToken;
126589 a += sqlite3Fts3GetVarint(a, &nToken);
126590 pInfo->aMatchinfo[iCol] = (u32)nToken;
126593 sqlite3_reset(pSelectDocsize);
126594 break;
126597 case FTS3_MATCHINFO_LCS:
126598 rc = fts3ExprLoadDoclists(pCsr, 0, 0);
126599 if( rc==SQLITE_OK ){
126600 rc = fts3MatchinfoLcs(pCsr, pInfo);
126602 break;
126604 default: {
126605 Fts3Expr *pExpr;
126606 assert( zArg[i]==FTS3_MATCHINFO_HITS );
126607 pExpr = pCsr->pExpr;
126608 rc = fts3ExprLoadDoclists(pCsr, 0, 0);
126609 if( rc!=SQLITE_OK ) break;
126610 if( bGlobal ){
126611 if( pCsr->pDeferred ){
126612 rc = fts3MatchinfoSelectDoctotal(pTab, &pSelect, &pInfo->nDoc, 0);
126613 if( rc!=SQLITE_OK ) break;
126615 rc = fts3ExprIterate(pExpr, fts3ExprGlobalHitsCb,(void*)pInfo);
126616 if( rc!=SQLITE_OK ) break;
126618 (void)fts3ExprIterate(pExpr, fts3ExprLocalHitsCb,(void*)pInfo);
126619 break;
126623 pInfo->aMatchinfo += fts3MatchinfoSize(pInfo, zArg[i]);
126626 sqlite3_reset(pSelect);
126627 return rc;
126632 ** Populate pCsr->aMatchinfo[] with data for the current row. The
126633 ** 'matchinfo' data is an array of 32-bit unsigned integers (C type u32).
126635 static int fts3GetMatchinfo(
126636 Fts3Cursor *pCsr, /* FTS3 Cursor object */
126637 const char *zArg /* Second argument to matchinfo() function */
126639 MatchInfo sInfo;
126640 Fts3Table *pTab = (Fts3Table *)pCsr->base.pVtab;
126641 int rc = SQLITE_OK;
126642 int bGlobal = 0; /* Collect 'global' stats as well as local */
126644 memset(&sInfo, 0, sizeof(MatchInfo));
126645 sInfo.pCursor = pCsr;
126646 sInfo.nCol = pTab->nColumn;
126648 /* If there is cached matchinfo() data, but the format string for the
126649 ** cache does not match the format string for this request, discard
126650 ** the cached data. */
126651 if( pCsr->zMatchinfo && strcmp(pCsr->zMatchinfo, zArg) ){
126652 assert( pCsr->aMatchinfo );
126653 sqlite3_free(pCsr->aMatchinfo);
126654 pCsr->zMatchinfo = 0;
126655 pCsr->aMatchinfo = 0;
126658 /* If Fts3Cursor.aMatchinfo[] is NULL, then this is the first time the
126659 ** matchinfo function has been called for this query. In this case
126660 ** allocate the array used to accumulate the matchinfo data and
126661 ** initialize those elements that are constant for every row.
126663 if( pCsr->aMatchinfo==0 ){
126664 int nMatchinfo = 0; /* Number of u32 elements in match-info */
126665 int nArg; /* Bytes in zArg */
126666 int i; /* Used to iterate through zArg */
126668 /* Determine the number of phrases in the query */
126669 pCsr->nPhrase = fts3ExprPhraseCount(pCsr->pExpr);
126670 sInfo.nPhrase = pCsr->nPhrase;
126672 /* Determine the number of integers in the buffer returned by this call. */
126673 for(i=0; zArg[i]; i++){
126674 nMatchinfo += fts3MatchinfoSize(&sInfo, zArg[i]);
126677 /* Allocate space for Fts3Cursor.aMatchinfo[] and Fts3Cursor.zMatchinfo. */
126678 nArg = (int)strlen(zArg);
126679 pCsr->aMatchinfo = (u32 *)sqlite3_malloc(sizeof(u32)*nMatchinfo + nArg + 1);
126680 if( !pCsr->aMatchinfo ) return SQLITE_NOMEM;
126682 pCsr->zMatchinfo = (char *)&pCsr->aMatchinfo[nMatchinfo];
126683 pCsr->nMatchinfo = nMatchinfo;
126684 memcpy(pCsr->zMatchinfo, zArg, nArg+1);
126685 memset(pCsr->aMatchinfo, 0, sizeof(u32)*nMatchinfo);
126686 pCsr->isMatchinfoNeeded = 1;
126687 bGlobal = 1;
126690 sInfo.aMatchinfo = pCsr->aMatchinfo;
126691 sInfo.nPhrase = pCsr->nPhrase;
126692 if( pCsr->isMatchinfoNeeded ){
126693 rc = fts3MatchinfoValues(pCsr, bGlobal, &sInfo, zArg);
126694 pCsr->isMatchinfoNeeded = 0;
126697 return rc;
126701 ** Implementation of snippet() function.
126703 SQLITE_PRIVATE void sqlite3Fts3Snippet(
126704 sqlite3_context *pCtx, /* SQLite function call context */
126705 Fts3Cursor *pCsr, /* Cursor object */
126706 const char *zStart, /* Snippet start text - "<b>" */
126707 const char *zEnd, /* Snippet end text - "</b>" */
126708 const char *zEllipsis, /* Snippet ellipsis text - "<b>...</b>" */
126709 int iCol, /* Extract snippet from this column */
126710 int nToken /* Approximate number of tokens in snippet */
126712 Fts3Table *pTab = (Fts3Table *)pCsr->base.pVtab;
126713 int rc = SQLITE_OK;
126714 int i;
126715 StrBuffer res = {0, 0, 0};
126717 /* The returned text includes up to four fragments of text extracted from
126718 ** the data in the current row. The first iteration of the for(...) loop
126719 ** below attempts to locate a single fragment of text nToken tokens in
126720 ** size that contains at least one instance of all phrases in the query
126721 ** expression that appear in the current row. If such a fragment of text
126722 ** cannot be found, the second iteration of the loop attempts to locate
126723 ** a pair of fragments, and so on.
126725 int nSnippet = 0; /* Number of fragments in this snippet */
126726 SnippetFragment aSnippet[4]; /* Maximum of 4 fragments per snippet */
126727 int nFToken = -1; /* Number of tokens in each fragment */
126729 if( !pCsr->pExpr ){
126730 sqlite3_result_text(pCtx, "", 0, SQLITE_STATIC);
126731 return;
126734 for(nSnippet=1; 1; nSnippet++){
126736 int iSnip; /* Loop counter 0..nSnippet-1 */
126737 u64 mCovered = 0; /* Bitmask of phrases covered by snippet */
126738 u64 mSeen = 0; /* Bitmask of phrases seen by BestSnippet() */
126740 if( nToken>=0 ){
126741 nFToken = (nToken+nSnippet-1) / nSnippet;
126742 }else{
126743 nFToken = -1 * nToken;
126746 for(iSnip=0; iSnip<nSnippet; iSnip++){
126747 int iBestScore = -1; /* Best score of columns checked so far */
126748 int iRead; /* Used to iterate through columns */
126749 SnippetFragment *pFragment = &aSnippet[iSnip];
126751 memset(pFragment, 0, sizeof(*pFragment));
126753 /* Loop through all columns of the table being considered for snippets.
126754 ** If the iCol argument to this function was negative, this means all
126755 ** columns of the FTS3 table. Otherwise, only column iCol is considered.
126757 for(iRead=0; iRead<pTab->nColumn; iRead++){
126758 SnippetFragment sF = {0, 0, 0, 0};
126759 int iS;
126760 if( iCol>=0 && iRead!=iCol ) continue;
126762 /* Find the best snippet of nFToken tokens in column iRead. */
126763 rc = fts3BestSnippet(nFToken, pCsr, iRead, mCovered, &mSeen, &sF, &iS);
126764 if( rc!=SQLITE_OK ){
126765 goto snippet_out;
126767 if( iS>iBestScore ){
126768 *pFragment = sF;
126769 iBestScore = iS;
126773 mCovered |= pFragment->covered;
126776 /* If all query phrases seen by fts3BestSnippet() are present in at least
126777 ** one of the nSnippet snippet fragments, break out of the loop.
126779 assert( (mCovered&mSeen)==mCovered );
126780 if( mSeen==mCovered || nSnippet==SizeofArray(aSnippet) ) break;
126783 assert( nFToken>0 );
126785 for(i=0; i<nSnippet && rc==SQLITE_OK; i++){
126786 rc = fts3SnippetText(pCsr, &aSnippet[i],
126787 i, (i==nSnippet-1), nFToken, zStart, zEnd, zEllipsis, &res
126791 snippet_out:
126792 sqlite3Fts3SegmentsClose(pTab);
126793 if( rc!=SQLITE_OK ){
126794 sqlite3_result_error_code(pCtx, rc);
126795 sqlite3_free(res.z);
126796 }else{
126797 sqlite3_result_text(pCtx, res.z, -1, sqlite3_free);
126802 typedef struct TermOffset TermOffset;
126803 typedef struct TermOffsetCtx TermOffsetCtx;
126805 struct TermOffset {
126806 char *pList; /* Position-list */
126807 int iPos; /* Position just read from pList */
126808 int iOff; /* Offset of this term from read positions */
126811 struct TermOffsetCtx {
126812 Fts3Cursor *pCsr;
126813 int iCol; /* Column of table to populate aTerm for */
126814 int iTerm;
126815 sqlite3_int64 iDocid;
126816 TermOffset *aTerm;
126820 ** This function is an fts3ExprIterate() callback used by sqlite3Fts3Offsets().
126822 static int fts3ExprTermOffsetInit(Fts3Expr *pExpr, int iPhrase, void *ctx){
126823 TermOffsetCtx *p = (TermOffsetCtx *)ctx;
126824 int nTerm; /* Number of tokens in phrase */
126825 int iTerm; /* For looping through nTerm phrase terms */
126826 char *pList; /* Pointer to position list for phrase */
126827 int iPos = 0; /* First position in position-list */
126829 UNUSED_PARAMETER(iPhrase);
126830 pList = sqlite3Fts3EvalPhrasePoslist(p->pCsr, pExpr, p->iCol);
126831 nTerm = pExpr->pPhrase->nToken;
126832 if( pList ){
126833 fts3GetDeltaPosition(&pList, &iPos);
126834 assert( iPos>=0 );
126837 for(iTerm=0; iTerm<nTerm; iTerm++){
126838 TermOffset *pT = &p->aTerm[p->iTerm++];
126839 pT->iOff = nTerm-iTerm-1;
126840 pT->pList = pList;
126841 pT->iPos = iPos;
126844 return SQLITE_OK;
126848 ** Implementation of offsets() function.
126850 SQLITE_PRIVATE void sqlite3Fts3Offsets(
126851 sqlite3_context *pCtx, /* SQLite function call context */
126852 Fts3Cursor *pCsr /* Cursor object */
126854 Fts3Table *pTab = (Fts3Table *)pCsr->base.pVtab;
126855 sqlite3_tokenizer_module const *pMod = pTab->pTokenizer->pModule;
126856 const char *ZDUMMY; /* Dummy argument used with xNext() */
126857 int NDUMMY; /* Dummy argument used with xNext() */
126858 int rc; /* Return Code */
126859 int nToken; /* Number of tokens in query */
126860 int iCol; /* Column currently being processed */
126861 StrBuffer res = {0, 0, 0}; /* Result string */
126862 TermOffsetCtx sCtx; /* Context for fts3ExprTermOffsetInit() */
126864 if( !pCsr->pExpr ){
126865 sqlite3_result_text(pCtx, "", 0, SQLITE_STATIC);
126866 return;
126869 memset(&sCtx, 0, sizeof(sCtx));
126870 assert( pCsr->isRequireSeek==0 );
126872 /* Count the number of terms in the query */
126873 rc = fts3ExprLoadDoclists(pCsr, 0, &nToken);
126874 if( rc!=SQLITE_OK ) goto offsets_out;
126876 /* Allocate the array of TermOffset iterators. */
126877 sCtx.aTerm = (TermOffset *)sqlite3_malloc(sizeof(TermOffset)*nToken);
126878 if( 0==sCtx.aTerm ){
126879 rc = SQLITE_NOMEM;
126880 goto offsets_out;
126882 sCtx.iDocid = pCsr->iPrevId;
126883 sCtx.pCsr = pCsr;
126885 /* Loop through the table columns, appending offset information to
126886 ** string-buffer res for each column.
126888 for(iCol=0; iCol<pTab->nColumn; iCol++){
126889 sqlite3_tokenizer_cursor *pC; /* Tokenizer cursor */
126890 int iStart;
126891 int iEnd;
126892 int iCurrent;
126893 const char *zDoc;
126894 int nDoc;
126896 /* Initialize the contents of sCtx.aTerm[] for column iCol. There is
126897 ** no way that this operation can fail, so the return code from
126898 ** fts3ExprIterate() can be discarded.
126900 sCtx.iCol = iCol;
126901 sCtx.iTerm = 0;
126902 (void)fts3ExprIterate(pCsr->pExpr, fts3ExprTermOffsetInit, (void *)&sCtx);
126904 /* Retreive the text stored in column iCol. If an SQL NULL is stored
126905 ** in column iCol, jump immediately to the next iteration of the loop.
126906 ** If an OOM occurs while retrieving the data (this can happen if SQLite
126907 ** needs to transform the data from utf-16 to utf-8), return SQLITE_NOMEM
126908 ** to the caller.
126910 zDoc = (const char *)sqlite3_column_text(pCsr->pStmt, iCol+1);
126911 nDoc = sqlite3_column_bytes(pCsr->pStmt, iCol+1);
126912 if( zDoc==0 ){
126913 if( sqlite3_column_type(pCsr->pStmt, iCol+1)==SQLITE_NULL ){
126914 continue;
126916 rc = SQLITE_NOMEM;
126917 goto offsets_out;
126920 /* Initialize a tokenizer iterator to iterate through column iCol. */
126921 rc = pMod->xOpen(pTab->pTokenizer, zDoc, nDoc, &pC);
126922 if( rc!=SQLITE_OK ) goto offsets_out;
126923 pC->pTokenizer = pTab->pTokenizer;
126925 rc = pMod->xNext(pC, &ZDUMMY, &NDUMMY, &iStart, &iEnd, &iCurrent);
126926 while( rc==SQLITE_OK ){
126927 int i; /* Used to loop through terms */
126928 int iMinPos = 0x7FFFFFFF; /* Position of next token */
126929 TermOffset *pTerm = 0; /* TermOffset associated with next token */
126931 for(i=0; i<nToken; i++){
126932 TermOffset *pT = &sCtx.aTerm[i];
126933 if( pT->pList && (pT->iPos-pT->iOff)<iMinPos ){
126934 iMinPos = pT->iPos-pT->iOff;
126935 pTerm = pT;
126939 if( !pTerm ){
126940 /* All offsets for this column have been gathered. */
126941 break;
126942 }else{
126943 assert( iCurrent<=iMinPos );
126944 if( 0==(0xFE&*pTerm->pList) ){
126945 pTerm->pList = 0;
126946 }else{
126947 fts3GetDeltaPosition(&pTerm->pList, &pTerm->iPos);
126949 while( rc==SQLITE_OK && iCurrent<iMinPos ){
126950 rc = pMod->xNext(pC, &ZDUMMY, &NDUMMY, &iStart, &iEnd, &iCurrent);
126952 if( rc==SQLITE_OK ){
126953 char aBuffer[64];
126954 sqlite3_snprintf(sizeof(aBuffer), aBuffer,
126955 "%d %d %d %d ", iCol, pTerm-sCtx.aTerm, iStart, iEnd-iStart
126957 rc = fts3StringAppend(&res, aBuffer, -1);
126958 }else if( rc==SQLITE_DONE ){
126959 rc = SQLITE_CORRUPT_VTAB;
126963 if( rc==SQLITE_DONE ){
126964 rc = SQLITE_OK;
126967 pMod->xClose(pC);
126968 if( rc!=SQLITE_OK ) goto offsets_out;
126971 offsets_out:
126972 sqlite3_free(sCtx.aTerm);
126973 assert( rc!=SQLITE_DONE );
126974 sqlite3Fts3SegmentsClose(pTab);
126975 if( rc!=SQLITE_OK ){
126976 sqlite3_result_error_code(pCtx, rc);
126977 sqlite3_free(res.z);
126978 }else{
126979 sqlite3_result_text(pCtx, res.z, res.n-1, sqlite3_free);
126981 return;
126985 ** Implementation of matchinfo() function.
126987 SQLITE_PRIVATE void sqlite3Fts3Matchinfo(
126988 sqlite3_context *pContext, /* Function call context */
126989 Fts3Cursor *pCsr, /* FTS3 table cursor */
126990 const char *zArg /* Second arg to matchinfo() function */
126992 Fts3Table *pTab = (Fts3Table *)pCsr->base.pVtab;
126993 int rc;
126994 int i;
126995 const char *zFormat;
126997 if( zArg ){
126998 for(i=0; zArg[i]; i++){
126999 char *zErr = 0;
127000 if( fts3MatchinfoCheck(pTab, zArg[i], &zErr) ){
127001 sqlite3_result_error(pContext, zErr, -1);
127002 sqlite3_free(zErr);
127003 return;
127006 zFormat = zArg;
127007 }else{
127008 zFormat = FTS3_MATCHINFO_DEFAULT;
127011 if( !pCsr->pExpr ){
127012 sqlite3_result_blob(pContext, "", 0, SQLITE_STATIC);
127013 return;
127016 /* Retrieve matchinfo() data. */
127017 rc = fts3GetMatchinfo(pCsr, zFormat);
127018 sqlite3Fts3SegmentsClose(pTab);
127020 if( rc!=SQLITE_OK ){
127021 sqlite3_result_error_code(pContext, rc);
127022 }else{
127023 int n = pCsr->nMatchinfo * sizeof(u32);
127024 sqlite3_result_blob(pContext, pCsr->aMatchinfo, n, SQLITE_TRANSIENT);
127028 #endif
127030 /************** End of fts3_snippet.c ****************************************/
127031 /************** Begin file rtree.c *******************************************/
127033 ** 2001 September 15
127035 ** The author disclaims copyright to this source code. In place of
127036 ** a legal notice, here is a blessing:
127038 ** May you do good and not evil.
127039 ** May you find forgiveness for yourself and forgive others.
127040 ** May you share freely, never taking more than you give.
127042 *************************************************************************
127043 ** This file contains code for implementations of the r-tree and r*-tree
127044 ** algorithms packaged as an SQLite virtual table module.
127048 ** Database Format of R-Tree Tables
127049 ** --------------------------------
127051 ** The data structure for a single virtual r-tree table is stored in three
127052 ** native SQLite tables declared as follows. In each case, the '%' character
127053 ** in the table name is replaced with the user-supplied name of the r-tree
127054 ** table.
127056 ** CREATE TABLE %_node(nodeno INTEGER PRIMARY KEY, data BLOB)
127057 ** CREATE TABLE %_parent(nodeno INTEGER PRIMARY KEY, parentnode INTEGER)
127058 ** CREATE TABLE %_rowid(rowid INTEGER PRIMARY KEY, nodeno INTEGER)
127060 ** The data for each node of the r-tree structure is stored in the %_node
127061 ** table. For each node that is not the root node of the r-tree, there is
127062 ** an entry in the %_parent table associating the node with its parent.
127063 ** And for each row of data in the table, there is an entry in the %_rowid
127064 ** table that maps from the entries rowid to the id of the node that it
127065 ** is stored on.
127067 ** The root node of an r-tree always exists, even if the r-tree table is
127068 ** empty. The nodeno of the root node is always 1. All other nodes in the
127069 ** table must be the same size as the root node. The content of each node
127070 ** is formatted as follows:
127072 ** 1. If the node is the root node (node 1), then the first 2 bytes
127073 ** of the node contain the tree depth as a big-endian integer.
127074 ** For non-root nodes, the first 2 bytes are left unused.
127076 ** 2. The next 2 bytes contain the number of entries currently
127077 ** stored in the node.
127079 ** 3. The remainder of the node contains the node entries. Each entry
127080 ** consists of a single 8-byte integer followed by an even number
127081 ** of 4-byte coordinates. For leaf nodes the integer is the rowid
127082 ** of a record. For internal nodes it is the node number of a
127083 ** child page.
127086 #if !defined(SQLITE_CORE) || defined(SQLITE_ENABLE_RTREE)
127089 ** This file contains an implementation of a couple of different variants
127090 ** of the r-tree algorithm. See the README file for further details. The
127091 ** same data-structure is used for all, but the algorithms for insert and
127092 ** delete operations vary. The variants used are selected at compile time
127093 ** by defining the following symbols:
127096 /* Either, both or none of the following may be set to activate
127097 ** r*tree variant algorithms.
127099 #define VARIANT_RSTARTREE_CHOOSESUBTREE 0
127100 #define VARIANT_RSTARTREE_REINSERT 1
127103 ** Exactly one of the following must be set to 1.
127105 #define VARIANT_GUTTMAN_QUADRATIC_SPLIT 0
127106 #define VARIANT_GUTTMAN_LINEAR_SPLIT 0
127107 #define VARIANT_RSTARTREE_SPLIT 1
127109 #define VARIANT_GUTTMAN_SPLIT \
127110 (VARIANT_GUTTMAN_LINEAR_SPLIT||VARIANT_GUTTMAN_QUADRATIC_SPLIT)
127112 #if VARIANT_GUTTMAN_QUADRATIC_SPLIT
127113 #define PickNext QuadraticPickNext
127114 #define PickSeeds QuadraticPickSeeds
127115 #define AssignCells splitNodeGuttman
127116 #endif
127117 #if VARIANT_GUTTMAN_LINEAR_SPLIT
127118 #define PickNext LinearPickNext
127119 #define PickSeeds LinearPickSeeds
127120 #define AssignCells splitNodeGuttman
127121 #endif
127122 #if VARIANT_RSTARTREE_SPLIT
127123 #define AssignCells splitNodeStartree
127124 #endif
127126 #if !defined(NDEBUG) && !defined(SQLITE_DEBUG)
127127 # define NDEBUG 1
127128 #endif
127130 #ifndef SQLITE_CORE
127131 SQLITE_EXTENSION_INIT1
127132 #else
127133 #endif
127135 /* #include <string.h> */
127136 /* #include <assert.h> */
127138 #ifndef SQLITE_AMALGAMATION
127139 #include "sqlite3rtree.h"
127140 typedef sqlite3_int64 i64;
127141 typedef unsigned char u8;
127142 typedef unsigned int u32;
127143 #endif
127145 /* The following macro is used to suppress compiler warnings.
127147 #ifndef UNUSED_PARAMETER
127148 # define UNUSED_PARAMETER(x) (void)(x)
127149 #endif
127151 typedef struct Rtree Rtree;
127152 typedef struct RtreeCursor RtreeCursor;
127153 typedef struct RtreeNode RtreeNode;
127154 typedef struct RtreeCell RtreeCell;
127155 typedef struct RtreeConstraint RtreeConstraint;
127156 typedef struct RtreeMatchArg RtreeMatchArg;
127157 typedef struct RtreeGeomCallback RtreeGeomCallback;
127158 typedef union RtreeCoord RtreeCoord;
127160 /* The rtree may have between 1 and RTREE_MAX_DIMENSIONS dimensions. */
127161 #define RTREE_MAX_DIMENSIONS 5
127163 /* Size of hash table Rtree.aHash. This hash table is not expected to
127164 ** ever contain very many entries, so a fixed number of buckets is
127165 ** used.
127167 #define HASHSIZE 128
127170 ** An rtree virtual-table object.
127172 struct Rtree {
127173 sqlite3_vtab base;
127174 sqlite3 *db; /* Host database connection */
127175 int iNodeSize; /* Size in bytes of each node in the node table */
127176 int nDim; /* Number of dimensions */
127177 int nBytesPerCell; /* Bytes consumed per cell */
127178 int iDepth; /* Current depth of the r-tree structure */
127179 char *zDb; /* Name of database containing r-tree table */
127180 char *zName; /* Name of r-tree table */
127181 RtreeNode *aHash[HASHSIZE]; /* Hash table of in-memory nodes. */
127182 int nBusy; /* Current number of users of this structure */
127184 /* List of nodes removed during a CondenseTree operation. List is
127185 ** linked together via the pointer normally used for hash chains -
127186 ** RtreeNode.pNext. RtreeNode.iNode stores the depth of the sub-tree
127187 ** headed by the node (leaf nodes have RtreeNode.iNode==0).
127189 RtreeNode *pDeleted;
127190 int iReinsertHeight; /* Height of sub-trees Reinsert() has run on */
127192 /* Statements to read/write/delete a record from xxx_node */
127193 sqlite3_stmt *pReadNode;
127194 sqlite3_stmt *pWriteNode;
127195 sqlite3_stmt *pDeleteNode;
127197 /* Statements to read/write/delete a record from xxx_rowid */
127198 sqlite3_stmt *pReadRowid;
127199 sqlite3_stmt *pWriteRowid;
127200 sqlite3_stmt *pDeleteRowid;
127202 /* Statements to read/write/delete a record from xxx_parent */
127203 sqlite3_stmt *pReadParent;
127204 sqlite3_stmt *pWriteParent;
127205 sqlite3_stmt *pDeleteParent;
127207 int eCoordType;
127210 /* Possible values for eCoordType: */
127211 #define RTREE_COORD_REAL32 0
127212 #define RTREE_COORD_INT32 1
127215 ** The minimum number of cells allowed for a node is a third of the
127216 ** maximum. In Gutman's notation:
127218 ** m = M/3
127220 ** If an R*-tree "Reinsert" operation is required, the same number of
127221 ** cells are removed from the overfull node and reinserted into the tree.
127223 #define RTREE_MINCELLS(p) ((((p)->iNodeSize-4)/(p)->nBytesPerCell)/3)
127224 #define RTREE_REINSERT(p) RTREE_MINCELLS(p)
127225 #define RTREE_MAXCELLS 51
127228 ** The smallest possible node-size is (512-64)==448 bytes. And the largest
127229 ** supported cell size is 48 bytes (8 byte rowid + ten 4 byte coordinates).
127230 ** Therefore all non-root nodes must contain at least 3 entries. Since
127231 ** 2^40 is greater than 2^64, an r-tree structure always has a depth of
127232 ** 40 or less.
127234 #define RTREE_MAX_DEPTH 40
127237 ** An rtree cursor object.
127239 struct RtreeCursor {
127240 sqlite3_vtab_cursor base;
127241 RtreeNode *pNode; /* Node cursor is currently pointing at */
127242 int iCell; /* Index of current cell in pNode */
127243 int iStrategy; /* Copy of idxNum search parameter */
127244 int nConstraint; /* Number of entries in aConstraint */
127245 RtreeConstraint *aConstraint; /* Search constraints. */
127248 union RtreeCoord {
127249 float f;
127250 int i;
127254 ** The argument is an RtreeCoord. Return the value stored within the RtreeCoord
127255 ** formatted as a double. This macro assumes that local variable pRtree points
127256 ** to the Rtree structure associated with the RtreeCoord.
127258 #define DCOORD(coord) ( \
127259 (pRtree->eCoordType==RTREE_COORD_REAL32) ? \
127260 ((double)coord.f) : \
127261 ((double)coord.i) \
127265 ** A search constraint.
127267 struct RtreeConstraint {
127268 int iCoord; /* Index of constrained coordinate */
127269 int op; /* Constraining operation */
127270 double rValue; /* Constraint value. */
127271 int (*xGeom)(sqlite3_rtree_geometry *, int, double *, int *);
127272 sqlite3_rtree_geometry *pGeom; /* Constraint callback argument for a MATCH */
127275 /* Possible values for RtreeConstraint.op */
127276 #define RTREE_EQ 0x41
127277 #define RTREE_LE 0x42
127278 #define RTREE_LT 0x43
127279 #define RTREE_GE 0x44
127280 #define RTREE_GT 0x45
127281 #define RTREE_MATCH 0x46
127284 ** An rtree structure node.
127286 struct RtreeNode {
127287 RtreeNode *pParent; /* Parent node */
127288 i64 iNode;
127289 int nRef;
127290 int isDirty;
127291 u8 *zData;
127292 RtreeNode *pNext; /* Next node in this hash chain */
127294 #define NCELL(pNode) readInt16(&(pNode)->zData[2])
127297 ** Structure to store a deserialized rtree record.
127299 struct RtreeCell {
127300 i64 iRowid;
127301 RtreeCoord aCoord[RTREE_MAX_DIMENSIONS*2];
127306 ** Value for the first field of every RtreeMatchArg object. The MATCH
127307 ** operator tests that the first field of a blob operand matches this
127308 ** value to avoid operating on invalid blobs (which could cause a segfault).
127310 #define RTREE_GEOMETRY_MAGIC 0x891245AB
127313 ** An instance of this structure must be supplied as a blob argument to
127314 ** the right-hand-side of an SQL MATCH operator used to constrain an
127315 ** r-tree query.
127317 struct RtreeMatchArg {
127318 u32 magic; /* Always RTREE_GEOMETRY_MAGIC */
127319 int (*xGeom)(sqlite3_rtree_geometry *, int, double *, int *);
127320 void *pContext;
127321 int nParam;
127322 double aParam[1];
127326 ** When a geometry callback is created (see sqlite3_rtree_geometry_callback),
127327 ** a single instance of the following structure is allocated. It is used
127328 ** as the context for the user-function created by by s_r_g_c(). The object
127329 ** is eventually deleted by the destructor mechanism provided by
127330 ** sqlite3_create_function_v2() (which is called by s_r_g_c() to create
127331 ** the geometry callback function).
127333 struct RtreeGeomCallback {
127334 int (*xGeom)(sqlite3_rtree_geometry *, int, double *, int *);
127335 void *pContext;
127338 #ifndef MAX
127339 # define MAX(x,y) ((x) < (y) ? (y) : (x))
127340 #endif
127341 #ifndef MIN
127342 # define MIN(x,y) ((x) > (y) ? (y) : (x))
127343 #endif
127346 ** Functions to deserialize a 16 bit integer, 32 bit real number and
127347 ** 64 bit integer. The deserialized value is returned.
127349 static int readInt16(u8 *p){
127350 return (p[0]<<8) + p[1];
127352 static void readCoord(u8 *p, RtreeCoord *pCoord){
127353 u32 i = (
127354 (((u32)p[0]) << 24) +
127355 (((u32)p[1]) << 16) +
127356 (((u32)p[2]) << 8) +
127357 (((u32)p[3]) << 0)
127359 *(u32 *)pCoord = i;
127361 static i64 readInt64(u8 *p){
127362 return (
127363 (((i64)p[0]) << 56) +
127364 (((i64)p[1]) << 48) +
127365 (((i64)p[2]) << 40) +
127366 (((i64)p[3]) << 32) +
127367 (((i64)p[4]) << 24) +
127368 (((i64)p[5]) << 16) +
127369 (((i64)p[6]) << 8) +
127370 (((i64)p[7]) << 0)
127375 ** Functions to serialize a 16 bit integer, 32 bit real number and
127376 ** 64 bit integer. The value returned is the number of bytes written
127377 ** to the argument buffer (always 2, 4 and 8 respectively).
127379 static int writeInt16(u8 *p, int i){
127380 p[0] = (i>> 8)&0xFF;
127381 p[1] = (i>> 0)&0xFF;
127382 return 2;
127384 static int writeCoord(u8 *p, RtreeCoord *pCoord){
127385 u32 i;
127386 assert( sizeof(RtreeCoord)==4 );
127387 assert( sizeof(u32)==4 );
127388 i = *(u32 *)pCoord;
127389 p[0] = (i>>24)&0xFF;
127390 p[1] = (i>>16)&0xFF;
127391 p[2] = (i>> 8)&0xFF;
127392 p[3] = (i>> 0)&0xFF;
127393 return 4;
127395 static int writeInt64(u8 *p, i64 i){
127396 p[0] = (i>>56)&0xFF;
127397 p[1] = (i>>48)&0xFF;
127398 p[2] = (i>>40)&0xFF;
127399 p[3] = (i>>32)&0xFF;
127400 p[4] = (i>>24)&0xFF;
127401 p[5] = (i>>16)&0xFF;
127402 p[6] = (i>> 8)&0xFF;
127403 p[7] = (i>> 0)&0xFF;
127404 return 8;
127408 ** Increment the reference count of node p.
127410 static void nodeReference(RtreeNode *p){
127411 if( p ){
127412 p->nRef++;
127417 ** Clear the content of node p (set all bytes to 0x00).
127419 static void nodeZero(Rtree *pRtree, RtreeNode *p){
127420 memset(&p->zData[2], 0, pRtree->iNodeSize-2);
127421 p->isDirty = 1;
127425 ** Given a node number iNode, return the corresponding key to use
127426 ** in the Rtree.aHash table.
127428 static int nodeHash(i64 iNode){
127429 return (
127430 (iNode>>56) ^ (iNode>>48) ^ (iNode>>40) ^ (iNode>>32) ^
127431 (iNode>>24) ^ (iNode>>16) ^ (iNode>> 8) ^ (iNode>> 0)
127432 ) % HASHSIZE;
127436 ** Search the node hash table for node iNode. If found, return a pointer
127437 ** to it. Otherwise, return 0.
127439 static RtreeNode *nodeHashLookup(Rtree *pRtree, i64 iNode){
127440 RtreeNode *p;
127441 for(p=pRtree->aHash[nodeHash(iNode)]; p && p->iNode!=iNode; p=p->pNext);
127442 return p;
127446 ** Add node pNode to the node hash table.
127448 static void nodeHashInsert(Rtree *pRtree, RtreeNode *pNode){
127449 int iHash;
127450 assert( pNode->pNext==0 );
127451 iHash = nodeHash(pNode->iNode);
127452 pNode->pNext = pRtree->aHash[iHash];
127453 pRtree->aHash[iHash] = pNode;
127457 ** Remove node pNode from the node hash table.
127459 static void nodeHashDelete(Rtree *pRtree, RtreeNode *pNode){
127460 RtreeNode **pp;
127461 if( pNode->iNode!=0 ){
127462 pp = &pRtree->aHash[nodeHash(pNode->iNode)];
127463 for( ; (*pp)!=pNode; pp = &(*pp)->pNext){ assert(*pp); }
127464 *pp = pNode->pNext;
127465 pNode->pNext = 0;
127470 ** Allocate and return new r-tree node. Initially, (RtreeNode.iNode==0),
127471 ** indicating that node has not yet been assigned a node number. It is
127472 ** assigned a node number when nodeWrite() is called to write the
127473 ** node contents out to the database.
127475 static RtreeNode *nodeNew(Rtree *pRtree, RtreeNode *pParent){
127476 RtreeNode *pNode;
127477 pNode = (RtreeNode *)sqlite3_malloc(sizeof(RtreeNode) + pRtree->iNodeSize);
127478 if( pNode ){
127479 memset(pNode, 0, sizeof(RtreeNode) + pRtree->iNodeSize);
127480 pNode->zData = (u8 *)&pNode[1];
127481 pNode->nRef = 1;
127482 pNode->pParent = pParent;
127483 pNode->isDirty = 1;
127484 nodeReference(pParent);
127486 return pNode;
127490 ** Obtain a reference to an r-tree node.
127492 static int
127493 nodeAcquire(
127494 Rtree *pRtree, /* R-tree structure */
127495 i64 iNode, /* Node number to load */
127496 RtreeNode *pParent, /* Either the parent node or NULL */
127497 RtreeNode **ppNode /* OUT: Acquired node */
127499 int rc;
127500 int rc2 = SQLITE_OK;
127501 RtreeNode *pNode;
127503 /* Check if the requested node is already in the hash table. If so,
127504 ** increase its reference count and return it.
127506 if( (pNode = nodeHashLookup(pRtree, iNode)) ){
127507 assert( !pParent || !pNode->pParent || pNode->pParent==pParent );
127508 if( pParent && !pNode->pParent ){
127509 nodeReference(pParent);
127510 pNode->pParent = pParent;
127512 pNode->nRef++;
127513 *ppNode = pNode;
127514 return SQLITE_OK;
127517 sqlite3_bind_int64(pRtree->pReadNode, 1, iNode);
127518 rc = sqlite3_step(pRtree->pReadNode);
127519 if( rc==SQLITE_ROW ){
127520 const u8 *zBlob = sqlite3_column_blob(pRtree->pReadNode, 0);
127521 if( pRtree->iNodeSize==sqlite3_column_bytes(pRtree->pReadNode, 0) ){
127522 pNode = (RtreeNode *)sqlite3_malloc(sizeof(RtreeNode)+pRtree->iNodeSize);
127523 if( !pNode ){
127524 rc2 = SQLITE_NOMEM;
127525 }else{
127526 pNode->pParent = pParent;
127527 pNode->zData = (u8 *)&pNode[1];
127528 pNode->nRef = 1;
127529 pNode->iNode = iNode;
127530 pNode->isDirty = 0;
127531 pNode->pNext = 0;
127532 memcpy(pNode->zData, zBlob, pRtree->iNodeSize);
127533 nodeReference(pParent);
127537 rc = sqlite3_reset(pRtree->pReadNode);
127538 if( rc==SQLITE_OK ) rc = rc2;
127540 /* If the root node was just loaded, set pRtree->iDepth to the height
127541 ** of the r-tree structure. A height of zero means all data is stored on
127542 ** the root node. A height of one means the children of the root node
127543 ** are the leaves, and so on. If the depth as specified on the root node
127544 ** is greater than RTREE_MAX_DEPTH, the r-tree structure must be corrupt.
127546 if( pNode && iNode==1 ){
127547 pRtree->iDepth = readInt16(pNode->zData);
127548 if( pRtree->iDepth>RTREE_MAX_DEPTH ){
127549 rc = SQLITE_CORRUPT_VTAB;
127553 /* If no error has occurred so far, check if the "number of entries"
127554 ** field on the node is too large. If so, set the return code to
127555 ** SQLITE_CORRUPT_VTAB.
127557 if( pNode && rc==SQLITE_OK ){
127558 if( NCELL(pNode)>((pRtree->iNodeSize-4)/pRtree->nBytesPerCell) ){
127559 rc = SQLITE_CORRUPT_VTAB;
127563 if( rc==SQLITE_OK ){
127564 if( pNode!=0 ){
127565 nodeHashInsert(pRtree, pNode);
127566 }else{
127567 rc = SQLITE_CORRUPT_VTAB;
127569 *ppNode = pNode;
127570 }else{
127571 sqlite3_free(pNode);
127572 *ppNode = 0;
127575 return rc;
127579 ** Overwrite cell iCell of node pNode with the contents of pCell.
127581 static void nodeOverwriteCell(
127582 Rtree *pRtree,
127583 RtreeNode *pNode,
127584 RtreeCell *pCell,
127585 int iCell
127587 int ii;
127588 u8 *p = &pNode->zData[4 + pRtree->nBytesPerCell*iCell];
127589 p += writeInt64(p, pCell->iRowid);
127590 for(ii=0; ii<(pRtree->nDim*2); ii++){
127591 p += writeCoord(p, &pCell->aCoord[ii]);
127593 pNode->isDirty = 1;
127597 ** Remove cell the cell with index iCell from node pNode.
127599 static void nodeDeleteCell(Rtree *pRtree, RtreeNode *pNode, int iCell){
127600 u8 *pDst = &pNode->zData[4 + pRtree->nBytesPerCell*iCell];
127601 u8 *pSrc = &pDst[pRtree->nBytesPerCell];
127602 int nByte = (NCELL(pNode) - iCell - 1) * pRtree->nBytesPerCell;
127603 memmove(pDst, pSrc, nByte);
127604 writeInt16(&pNode->zData[2], NCELL(pNode)-1);
127605 pNode->isDirty = 1;
127609 ** Insert the contents of cell pCell into node pNode. If the insert
127610 ** is successful, return SQLITE_OK.
127612 ** If there is not enough free space in pNode, return SQLITE_FULL.
127614 static int
127615 nodeInsertCell(
127616 Rtree *pRtree,
127617 RtreeNode *pNode,
127618 RtreeCell *pCell
127620 int nCell; /* Current number of cells in pNode */
127621 int nMaxCell; /* Maximum number of cells for pNode */
127623 nMaxCell = (pRtree->iNodeSize-4)/pRtree->nBytesPerCell;
127624 nCell = NCELL(pNode);
127626 assert( nCell<=nMaxCell );
127627 if( nCell<nMaxCell ){
127628 nodeOverwriteCell(pRtree, pNode, pCell, nCell);
127629 writeInt16(&pNode->zData[2], nCell+1);
127630 pNode->isDirty = 1;
127633 return (nCell==nMaxCell);
127637 ** If the node is dirty, write it out to the database.
127639 static int
127640 nodeWrite(Rtree *pRtree, RtreeNode *pNode){
127641 int rc = SQLITE_OK;
127642 if( pNode->isDirty ){
127643 sqlite3_stmt *p = pRtree->pWriteNode;
127644 if( pNode->iNode ){
127645 sqlite3_bind_int64(p, 1, pNode->iNode);
127646 }else{
127647 sqlite3_bind_null(p, 1);
127649 sqlite3_bind_blob(p, 2, pNode->zData, pRtree->iNodeSize, SQLITE_STATIC);
127650 sqlite3_step(p);
127651 pNode->isDirty = 0;
127652 rc = sqlite3_reset(p);
127653 if( pNode->iNode==0 && rc==SQLITE_OK ){
127654 pNode->iNode = sqlite3_last_insert_rowid(pRtree->db);
127655 nodeHashInsert(pRtree, pNode);
127658 return rc;
127662 ** Release a reference to a node. If the node is dirty and the reference
127663 ** count drops to zero, the node data is written to the database.
127665 static int
127666 nodeRelease(Rtree *pRtree, RtreeNode *pNode){
127667 int rc = SQLITE_OK;
127668 if( pNode ){
127669 assert( pNode->nRef>0 );
127670 pNode->nRef--;
127671 if( pNode->nRef==0 ){
127672 if( pNode->iNode==1 ){
127673 pRtree->iDepth = -1;
127675 if( pNode->pParent ){
127676 rc = nodeRelease(pRtree, pNode->pParent);
127678 if( rc==SQLITE_OK ){
127679 rc = nodeWrite(pRtree, pNode);
127681 nodeHashDelete(pRtree, pNode);
127682 sqlite3_free(pNode);
127685 return rc;
127689 ** Return the 64-bit integer value associated with cell iCell of
127690 ** node pNode. If pNode is a leaf node, this is a rowid. If it is
127691 ** an internal node, then the 64-bit integer is a child page number.
127693 static i64 nodeGetRowid(
127694 Rtree *pRtree,
127695 RtreeNode *pNode,
127696 int iCell
127698 assert( iCell<NCELL(pNode) );
127699 return readInt64(&pNode->zData[4 + pRtree->nBytesPerCell*iCell]);
127703 ** Return coordinate iCoord from cell iCell in node pNode.
127705 static void nodeGetCoord(
127706 Rtree *pRtree,
127707 RtreeNode *pNode,
127708 int iCell,
127709 int iCoord,
127710 RtreeCoord *pCoord /* Space to write result to */
127712 readCoord(&pNode->zData[12 + pRtree->nBytesPerCell*iCell + 4*iCoord], pCoord);
127716 ** Deserialize cell iCell of node pNode. Populate the structure pointed
127717 ** to by pCell with the results.
127719 static void nodeGetCell(
127720 Rtree *pRtree,
127721 RtreeNode *pNode,
127722 int iCell,
127723 RtreeCell *pCell
127725 int ii;
127726 pCell->iRowid = nodeGetRowid(pRtree, pNode, iCell);
127727 for(ii=0; ii<pRtree->nDim*2; ii++){
127728 nodeGetCoord(pRtree, pNode, iCell, ii, &pCell->aCoord[ii]);
127733 /* Forward declaration for the function that does the work of
127734 ** the virtual table module xCreate() and xConnect() methods.
127736 static int rtreeInit(
127737 sqlite3 *, void *, int, const char *const*, sqlite3_vtab **, char **, int
127741 ** Rtree virtual table module xCreate method.
127743 static int rtreeCreate(
127744 sqlite3 *db,
127745 void *pAux,
127746 int argc, const char *const*argv,
127747 sqlite3_vtab **ppVtab,
127748 char **pzErr
127750 return rtreeInit(db, pAux, argc, argv, ppVtab, pzErr, 1);
127754 ** Rtree virtual table module xConnect method.
127756 static int rtreeConnect(
127757 sqlite3 *db,
127758 void *pAux,
127759 int argc, const char *const*argv,
127760 sqlite3_vtab **ppVtab,
127761 char **pzErr
127763 return rtreeInit(db, pAux, argc, argv, ppVtab, pzErr, 0);
127767 ** Increment the r-tree reference count.
127769 static void rtreeReference(Rtree *pRtree){
127770 pRtree->nBusy++;
127774 ** Decrement the r-tree reference count. When the reference count reaches
127775 ** zero the structure is deleted.
127777 static void rtreeRelease(Rtree *pRtree){
127778 pRtree->nBusy--;
127779 if( pRtree->nBusy==0 ){
127780 sqlite3_finalize(pRtree->pReadNode);
127781 sqlite3_finalize(pRtree->pWriteNode);
127782 sqlite3_finalize(pRtree->pDeleteNode);
127783 sqlite3_finalize(pRtree->pReadRowid);
127784 sqlite3_finalize(pRtree->pWriteRowid);
127785 sqlite3_finalize(pRtree->pDeleteRowid);
127786 sqlite3_finalize(pRtree->pReadParent);
127787 sqlite3_finalize(pRtree->pWriteParent);
127788 sqlite3_finalize(pRtree->pDeleteParent);
127789 sqlite3_free(pRtree);
127794 ** Rtree virtual table module xDisconnect method.
127796 static int rtreeDisconnect(sqlite3_vtab *pVtab){
127797 rtreeRelease((Rtree *)pVtab);
127798 return SQLITE_OK;
127802 ** Rtree virtual table module xDestroy method.
127804 static int rtreeDestroy(sqlite3_vtab *pVtab){
127805 Rtree *pRtree = (Rtree *)pVtab;
127806 int rc;
127807 char *zCreate = sqlite3_mprintf(
127808 "DROP TABLE '%q'.'%q_node';"
127809 "DROP TABLE '%q'.'%q_rowid';"
127810 "DROP TABLE '%q'.'%q_parent';",
127811 pRtree->zDb, pRtree->zName,
127812 pRtree->zDb, pRtree->zName,
127813 pRtree->zDb, pRtree->zName
127815 if( !zCreate ){
127816 rc = SQLITE_NOMEM;
127817 }else{
127818 rc = sqlite3_exec(pRtree->db, zCreate, 0, 0, 0);
127819 sqlite3_free(zCreate);
127821 if( rc==SQLITE_OK ){
127822 rtreeRelease(pRtree);
127825 return rc;
127829 ** Rtree virtual table module xOpen method.
127831 static int rtreeOpen(sqlite3_vtab *pVTab, sqlite3_vtab_cursor **ppCursor){
127832 int rc = SQLITE_NOMEM;
127833 RtreeCursor *pCsr;
127835 pCsr = (RtreeCursor *)sqlite3_malloc(sizeof(RtreeCursor));
127836 if( pCsr ){
127837 memset(pCsr, 0, sizeof(RtreeCursor));
127838 pCsr->base.pVtab = pVTab;
127839 rc = SQLITE_OK;
127841 *ppCursor = (sqlite3_vtab_cursor *)pCsr;
127843 return rc;
127848 ** Free the RtreeCursor.aConstraint[] array and its contents.
127850 static void freeCursorConstraints(RtreeCursor *pCsr){
127851 if( pCsr->aConstraint ){
127852 int i; /* Used to iterate through constraint array */
127853 for(i=0; i<pCsr->nConstraint; i++){
127854 sqlite3_rtree_geometry *pGeom = pCsr->aConstraint[i].pGeom;
127855 if( pGeom ){
127856 if( pGeom->xDelUser ) pGeom->xDelUser(pGeom->pUser);
127857 sqlite3_free(pGeom);
127860 sqlite3_free(pCsr->aConstraint);
127861 pCsr->aConstraint = 0;
127866 ** Rtree virtual table module xClose method.
127868 static int rtreeClose(sqlite3_vtab_cursor *cur){
127869 Rtree *pRtree = (Rtree *)(cur->pVtab);
127870 int rc;
127871 RtreeCursor *pCsr = (RtreeCursor *)cur;
127872 freeCursorConstraints(pCsr);
127873 rc = nodeRelease(pRtree, pCsr->pNode);
127874 sqlite3_free(pCsr);
127875 return rc;
127879 ** Rtree virtual table module xEof method.
127881 ** Return non-zero if the cursor does not currently point to a valid
127882 ** record (i.e if the scan has finished), or zero otherwise.
127884 static int rtreeEof(sqlite3_vtab_cursor *cur){
127885 RtreeCursor *pCsr = (RtreeCursor *)cur;
127886 return (pCsr->pNode==0);
127890 ** The r-tree constraint passed as the second argument to this function is
127891 ** guaranteed to be a MATCH constraint.
127893 static int testRtreeGeom(
127894 Rtree *pRtree, /* R-Tree object */
127895 RtreeConstraint *pConstraint, /* MATCH constraint to test */
127896 RtreeCell *pCell, /* Cell to test */
127897 int *pbRes /* OUT: Test result */
127899 int i;
127900 double aCoord[RTREE_MAX_DIMENSIONS*2];
127901 int nCoord = pRtree->nDim*2;
127903 assert( pConstraint->op==RTREE_MATCH );
127904 assert( pConstraint->pGeom );
127906 for(i=0; i<nCoord; i++){
127907 aCoord[i] = DCOORD(pCell->aCoord[i]);
127909 return pConstraint->xGeom(pConstraint->pGeom, nCoord, aCoord, pbRes);
127913 ** Cursor pCursor currently points to a cell in a non-leaf page.
127914 ** Set *pbEof to true if the sub-tree headed by the cell is filtered
127915 ** (excluded) by the constraints in the pCursor->aConstraint[]
127916 ** array, or false otherwise.
127918 ** Return SQLITE_OK if successful or an SQLite error code if an error
127919 ** occurs within a geometry callback.
127921 static int testRtreeCell(Rtree *pRtree, RtreeCursor *pCursor, int *pbEof){
127922 RtreeCell cell;
127923 int ii;
127924 int bRes = 0;
127925 int rc = SQLITE_OK;
127927 nodeGetCell(pRtree, pCursor->pNode, pCursor->iCell, &cell);
127928 for(ii=0; bRes==0 && ii<pCursor->nConstraint; ii++){
127929 RtreeConstraint *p = &pCursor->aConstraint[ii];
127930 double cell_min = DCOORD(cell.aCoord[(p->iCoord>>1)*2]);
127931 double cell_max = DCOORD(cell.aCoord[(p->iCoord>>1)*2+1]);
127933 assert(p->op==RTREE_LE || p->op==RTREE_LT || p->op==RTREE_GE
127934 || p->op==RTREE_GT || p->op==RTREE_EQ || p->op==RTREE_MATCH
127937 switch( p->op ){
127938 case RTREE_LE: case RTREE_LT:
127939 bRes = p->rValue<cell_min;
127940 break;
127942 case RTREE_GE: case RTREE_GT:
127943 bRes = p->rValue>cell_max;
127944 break;
127946 case RTREE_EQ:
127947 bRes = (p->rValue>cell_max || p->rValue<cell_min);
127948 break;
127950 default: {
127951 assert( p->op==RTREE_MATCH );
127952 rc = testRtreeGeom(pRtree, p, &cell, &bRes);
127953 bRes = !bRes;
127954 break;
127959 *pbEof = bRes;
127960 return rc;
127964 ** Test if the cell that cursor pCursor currently points to
127965 ** would be filtered (excluded) by the constraints in the
127966 ** pCursor->aConstraint[] array. If so, set *pbEof to true before
127967 ** returning. If the cell is not filtered (excluded) by the constraints,
127968 ** set pbEof to zero.
127970 ** Return SQLITE_OK if successful or an SQLite error code if an error
127971 ** occurs within a geometry callback.
127973 ** This function assumes that the cell is part of a leaf node.
127975 static int testRtreeEntry(Rtree *pRtree, RtreeCursor *pCursor, int *pbEof){
127976 RtreeCell cell;
127977 int ii;
127978 *pbEof = 0;
127980 nodeGetCell(pRtree, pCursor->pNode, pCursor->iCell, &cell);
127981 for(ii=0; ii<pCursor->nConstraint; ii++){
127982 RtreeConstraint *p = &pCursor->aConstraint[ii];
127983 double coord = DCOORD(cell.aCoord[p->iCoord]);
127984 int res;
127985 assert(p->op==RTREE_LE || p->op==RTREE_LT || p->op==RTREE_GE
127986 || p->op==RTREE_GT || p->op==RTREE_EQ || p->op==RTREE_MATCH
127988 switch( p->op ){
127989 case RTREE_LE: res = (coord<=p->rValue); break;
127990 case RTREE_LT: res = (coord<p->rValue); break;
127991 case RTREE_GE: res = (coord>=p->rValue); break;
127992 case RTREE_GT: res = (coord>p->rValue); break;
127993 case RTREE_EQ: res = (coord==p->rValue); break;
127994 default: {
127995 int rc;
127996 assert( p->op==RTREE_MATCH );
127997 rc = testRtreeGeom(pRtree, p, &cell, &res);
127998 if( rc!=SQLITE_OK ){
127999 return rc;
128001 break;
128005 if( !res ){
128006 *pbEof = 1;
128007 return SQLITE_OK;
128011 return SQLITE_OK;
128015 ** Cursor pCursor currently points at a node that heads a sub-tree of
128016 ** height iHeight (if iHeight==0, then the node is a leaf). Descend
128017 ** to point to the left-most cell of the sub-tree that matches the
128018 ** configured constraints.
128020 static int descendToCell(
128021 Rtree *pRtree,
128022 RtreeCursor *pCursor,
128023 int iHeight,
128024 int *pEof /* OUT: Set to true if cannot descend */
128026 int isEof;
128027 int rc;
128028 int ii;
128029 RtreeNode *pChild;
128030 sqlite3_int64 iRowid;
128032 RtreeNode *pSavedNode = pCursor->pNode;
128033 int iSavedCell = pCursor->iCell;
128035 assert( iHeight>=0 );
128037 if( iHeight==0 ){
128038 rc = testRtreeEntry(pRtree, pCursor, &isEof);
128039 }else{
128040 rc = testRtreeCell(pRtree, pCursor, &isEof);
128042 if( rc!=SQLITE_OK || isEof || iHeight==0 ){
128043 goto descend_to_cell_out;
128046 iRowid = nodeGetRowid(pRtree, pCursor->pNode, pCursor->iCell);
128047 rc = nodeAcquire(pRtree, iRowid, pCursor->pNode, &pChild);
128048 if( rc!=SQLITE_OK ){
128049 goto descend_to_cell_out;
128052 nodeRelease(pRtree, pCursor->pNode);
128053 pCursor->pNode = pChild;
128054 isEof = 1;
128055 for(ii=0; isEof && ii<NCELL(pChild); ii++){
128056 pCursor->iCell = ii;
128057 rc = descendToCell(pRtree, pCursor, iHeight-1, &isEof);
128058 if( rc!=SQLITE_OK ){
128059 goto descend_to_cell_out;
128063 if( isEof ){
128064 assert( pCursor->pNode==pChild );
128065 nodeReference(pSavedNode);
128066 nodeRelease(pRtree, pChild);
128067 pCursor->pNode = pSavedNode;
128068 pCursor->iCell = iSavedCell;
128071 descend_to_cell_out:
128072 *pEof = isEof;
128073 return rc;
128077 ** One of the cells in node pNode is guaranteed to have a 64-bit
128078 ** integer value equal to iRowid. Return the index of this cell.
128080 static int nodeRowidIndex(
128081 Rtree *pRtree,
128082 RtreeNode *pNode,
128083 i64 iRowid,
128084 int *piIndex
128086 int ii;
128087 int nCell = NCELL(pNode);
128088 for(ii=0; ii<nCell; ii++){
128089 if( nodeGetRowid(pRtree, pNode, ii)==iRowid ){
128090 *piIndex = ii;
128091 return SQLITE_OK;
128094 return SQLITE_CORRUPT_VTAB;
128098 ** Return the index of the cell containing a pointer to node pNode
128099 ** in its parent. If pNode is the root node, return -1.
128101 static int nodeParentIndex(Rtree *pRtree, RtreeNode *pNode, int *piIndex){
128102 RtreeNode *pParent = pNode->pParent;
128103 if( pParent ){
128104 return nodeRowidIndex(pRtree, pParent, pNode->iNode, piIndex);
128106 *piIndex = -1;
128107 return SQLITE_OK;
128111 ** Rtree virtual table module xNext method.
128113 static int rtreeNext(sqlite3_vtab_cursor *pVtabCursor){
128114 Rtree *pRtree = (Rtree *)(pVtabCursor->pVtab);
128115 RtreeCursor *pCsr = (RtreeCursor *)pVtabCursor;
128116 int rc = SQLITE_OK;
128118 /* RtreeCursor.pNode must not be NULL. If is is NULL, then this cursor is
128119 ** already at EOF. It is against the rules to call the xNext() method of
128120 ** a cursor that has already reached EOF.
128122 assert( pCsr->pNode );
128124 if( pCsr->iStrategy==1 ){
128125 /* This "scan" is a direct lookup by rowid. There is no next entry. */
128126 nodeRelease(pRtree, pCsr->pNode);
128127 pCsr->pNode = 0;
128128 }else{
128129 /* Move to the next entry that matches the configured constraints. */
128130 int iHeight = 0;
128131 while( pCsr->pNode ){
128132 RtreeNode *pNode = pCsr->pNode;
128133 int nCell = NCELL(pNode);
128134 for(pCsr->iCell++; pCsr->iCell<nCell; pCsr->iCell++){
128135 int isEof;
128136 rc = descendToCell(pRtree, pCsr, iHeight, &isEof);
128137 if( rc!=SQLITE_OK || !isEof ){
128138 return rc;
128141 pCsr->pNode = pNode->pParent;
128142 rc = nodeParentIndex(pRtree, pNode, &pCsr->iCell);
128143 if( rc!=SQLITE_OK ){
128144 return rc;
128146 nodeReference(pCsr->pNode);
128147 nodeRelease(pRtree, pNode);
128148 iHeight++;
128152 return rc;
128156 ** Rtree virtual table module xRowid method.
128158 static int rtreeRowid(sqlite3_vtab_cursor *pVtabCursor, sqlite_int64 *pRowid){
128159 Rtree *pRtree = (Rtree *)pVtabCursor->pVtab;
128160 RtreeCursor *pCsr = (RtreeCursor *)pVtabCursor;
128162 assert(pCsr->pNode);
128163 *pRowid = nodeGetRowid(pRtree, pCsr->pNode, pCsr->iCell);
128165 return SQLITE_OK;
128169 ** Rtree virtual table module xColumn method.
128171 static int rtreeColumn(sqlite3_vtab_cursor *cur, sqlite3_context *ctx, int i){
128172 Rtree *pRtree = (Rtree *)cur->pVtab;
128173 RtreeCursor *pCsr = (RtreeCursor *)cur;
128175 if( i==0 ){
128176 i64 iRowid = nodeGetRowid(pRtree, pCsr->pNode, pCsr->iCell);
128177 sqlite3_result_int64(ctx, iRowid);
128178 }else{
128179 RtreeCoord c;
128180 nodeGetCoord(pRtree, pCsr->pNode, pCsr->iCell, i-1, &c);
128181 if( pRtree->eCoordType==RTREE_COORD_REAL32 ){
128182 sqlite3_result_double(ctx, c.f);
128183 }else{
128184 assert( pRtree->eCoordType==RTREE_COORD_INT32 );
128185 sqlite3_result_int(ctx, c.i);
128189 return SQLITE_OK;
128193 ** Use nodeAcquire() to obtain the leaf node containing the record with
128194 ** rowid iRowid. If successful, set *ppLeaf to point to the node and
128195 ** return SQLITE_OK. If there is no such record in the table, set
128196 ** *ppLeaf to 0 and return SQLITE_OK. If an error occurs, set *ppLeaf
128197 ** to zero and return an SQLite error code.
128199 static int findLeafNode(Rtree *pRtree, i64 iRowid, RtreeNode **ppLeaf){
128200 int rc;
128201 *ppLeaf = 0;
128202 sqlite3_bind_int64(pRtree->pReadRowid, 1, iRowid);
128203 if( sqlite3_step(pRtree->pReadRowid)==SQLITE_ROW ){
128204 i64 iNode = sqlite3_column_int64(pRtree->pReadRowid, 0);
128205 rc = nodeAcquire(pRtree, iNode, 0, ppLeaf);
128206 sqlite3_reset(pRtree->pReadRowid);
128207 }else{
128208 rc = sqlite3_reset(pRtree->pReadRowid);
128210 return rc;
128214 ** This function is called to configure the RtreeConstraint object passed
128215 ** as the second argument for a MATCH constraint. The value passed as the
128216 ** first argument to this function is the right-hand operand to the MATCH
128217 ** operator.
128219 static int deserializeGeometry(sqlite3_value *pValue, RtreeConstraint *pCons){
128220 RtreeMatchArg *p;
128221 sqlite3_rtree_geometry *pGeom;
128222 int nBlob;
128224 /* Check that value is actually a blob. */
128225 if( !sqlite3_value_type(pValue)==SQLITE_BLOB ) return SQLITE_ERROR;
128227 /* Check that the blob is roughly the right size. */
128228 nBlob = sqlite3_value_bytes(pValue);
128229 if( nBlob<(int)sizeof(RtreeMatchArg)
128230 || ((nBlob-sizeof(RtreeMatchArg))%sizeof(double))!=0
128232 return SQLITE_ERROR;
128235 pGeom = (sqlite3_rtree_geometry *)sqlite3_malloc(
128236 sizeof(sqlite3_rtree_geometry) + nBlob
128238 if( !pGeom ) return SQLITE_NOMEM;
128239 memset(pGeom, 0, sizeof(sqlite3_rtree_geometry));
128240 p = (RtreeMatchArg *)&pGeom[1];
128242 memcpy(p, sqlite3_value_blob(pValue), nBlob);
128243 if( p->magic!=RTREE_GEOMETRY_MAGIC
128244 || nBlob!=(int)(sizeof(RtreeMatchArg) + (p->nParam-1)*sizeof(double))
128246 sqlite3_free(pGeom);
128247 return SQLITE_ERROR;
128250 pGeom->pContext = p->pContext;
128251 pGeom->nParam = p->nParam;
128252 pGeom->aParam = p->aParam;
128254 pCons->xGeom = p->xGeom;
128255 pCons->pGeom = pGeom;
128256 return SQLITE_OK;
128260 ** Rtree virtual table module xFilter method.
128262 static int rtreeFilter(
128263 sqlite3_vtab_cursor *pVtabCursor,
128264 int idxNum, const char *idxStr,
128265 int argc, sqlite3_value **argv
128267 Rtree *pRtree = (Rtree *)pVtabCursor->pVtab;
128268 RtreeCursor *pCsr = (RtreeCursor *)pVtabCursor;
128270 RtreeNode *pRoot = 0;
128271 int ii;
128272 int rc = SQLITE_OK;
128274 rtreeReference(pRtree);
128276 freeCursorConstraints(pCsr);
128277 pCsr->iStrategy = idxNum;
128279 if( idxNum==1 ){
128280 /* Special case - lookup by rowid. */
128281 RtreeNode *pLeaf; /* Leaf on which the required cell resides */
128282 i64 iRowid = sqlite3_value_int64(argv[0]);
128283 rc = findLeafNode(pRtree, iRowid, &pLeaf);
128284 pCsr->pNode = pLeaf;
128285 if( pLeaf ){
128286 assert( rc==SQLITE_OK );
128287 rc = nodeRowidIndex(pRtree, pLeaf, iRowid, &pCsr->iCell);
128289 }else{
128290 /* Normal case - r-tree scan. Set up the RtreeCursor.aConstraint array
128291 ** with the configured constraints.
128293 if( argc>0 ){
128294 pCsr->aConstraint = sqlite3_malloc(sizeof(RtreeConstraint)*argc);
128295 pCsr->nConstraint = argc;
128296 if( !pCsr->aConstraint ){
128297 rc = SQLITE_NOMEM;
128298 }else{
128299 memset(pCsr->aConstraint, 0, sizeof(RtreeConstraint)*argc);
128300 assert( (idxStr==0 && argc==0) || (int)strlen(idxStr)==argc*2 );
128301 for(ii=0; ii<argc; ii++){
128302 RtreeConstraint *p = &pCsr->aConstraint[ii];
128303 p->op = idxStr[ii*2];
128304 p->iCoord = idxStr[ii*2+1]-'a';
128305 if( p->op==RTREE_MATCH ){
128306 /* A MATCH operator. The right-hand-side must be a blob that
128307 ** can be cast into an RtreeMatchArg object. One created using
128308 ** an sqlite3_rtree_geometry_callback() SQL user function.
128310 rc = deserializeGeometry(argv[ii], p);
128311 if( rc!=SQLITE_OK ){
128312 break;
128314 }else{
128315 p->rValue = sqlite3_value_double(argv[ii]);
128321 if( rc==SQLITE_OK ){
128322 pCsr->pNode = 0;
128323 rc = nodeAcquire(pRtree, 1, 0, &pRoot);
128325 if( rc==SQLITE_OK ){
128326 int isEof = 1;
128327 int nCell = NCELL(pRoot);
128328 pCsr->pNode = pRoot;
128329 for(pCsr->iCell=0; rc==SQLITE_OK && pCsr->iCell<nCell; pCsr->iCell++){
128330 assert( pCsr->pNode==pRoot );
128331 rc = descendToCell(pRtree, pCsr, pRtree->iDepth, &isEof);
128332 if( !isEof ){
128333 break;
128336 if( rc==SQLITE_OK && isEof ){
128337 assert( pCsr->pNode==pRoot );
128338 nodeRelease(pRtree, pRoot);
128339 pCsr->pNode = 0;
128341 assert( rc!=SQLITE_OK || !pCsr->pNode || pCsr->iCell<NCELL(pCsr->pNode) );
128345 rtreeRelease(pRtree);
128346 return rc;
128350 ** Rtree virtual table module xBestIndex method. There are three
128351 ** table scan strategies to choose from (in order from most to
128352 ** least desirable):
128354 ** idxNum idxStr Strategy
128355 ** ------------------------------------------------
128356 ** 1 Unused Direct lookup by rowid.
128357 ** 2 See below R-tree query or full-table scan.
128358 ** ------------------------------------------------
128360 ** If strategy 1 is used, then idxStr is not meaningful. If strategy
128361 ** 2 is used, idxStr is formatted to contain 2 bytes for each
128362 ** constraint used. The first two bytes of idxStr correspond to
128363 ** the constraint in sqlite3_index_info.aConstraintUsage[] with
128364 ** (argvIndex==1) etc.
128366 ** The first of each pair of bytes in idxStr identifies the constraint
128367 ** operator as follows:
128369 ** Operator Byte Value
128370 ** ----------------------
128371 ** = 0x41 ('A')
128372 ** <= 0x42 ('B')
128373 ** < 0x43 ('C')
128374 ** >= 0x44 ('D')
128375 ** > 0x45 ('E')
128376 ** MATCH 0x46 ('F')
128377 ** ----------------------
128379 ** The second of each pair of bytes identifies the coordinate column
128380 ** to which the constraint applies. The leftmost coordinate column
128381 ** is 'a', the second from the left 'b' etc.
128383 static int rtreeBestIndex(sqlite3_vtab *tab, sqlite3_index_info *pIdxInfo){
128384 int rc = SQLITE_OK;
128385 int ii;
128387 int iIdx = 0;
128388 char zIdxStr[RTREE_MAX_DIMENSIONS*8+1];
128389 memset(zIdxStr, 0, sizeof(zIdxStr));
128390 UNUSED_PARAMETER(tab);
128392 assert( pIdxInfo->idxStr==0 );
128393 for(ii=0; ii<pIdxInfo->nConstraint && iIdx<(int)(sizeof(zIdxStr)-1); ii++){
128394 struct sqlite3_index_constraint *p = &pIdxInfo->aConstraint[ii];
128396 if( p->usable && p->iColumn==0 && p->op==SQLITE_INDEX_CONSTRAINT_EQ ){
128397 /* We have an equality constraint on the rowid. Use strategy 1. */
128398 int jj;
128399 for(jj=0; jj<ii; jj++){
128400 pIdxInfo->aConstraintUsage[jj].argvIndex = 0;
128401 pIdxInfo->aConstraintUsage[jj].omit = 0;
128403 pIdxInfo->idxNum = 1;
128404 pIdxInfo->aConstraintUsage[ii].argvIndex = 1;
128405 pIdxInfo->aConstraintUsage[jj].omit = 1;
128407 /* This strategy involves a two rowid lookups on an B-Tree structures
128408 ** and then a linear search of an R-Tree node. This should be
128409 ** considered almost as quick as a direct rowid lookup (for which
128410 ** sqlite uses an internal cost of 0.0).
128412 pIdxInfo->estimatedCost = 10.0;
128413 return SQLITE_OK;
128416 if( p->usable && (p->iColumn>0 || p->op==SQLITE_INDEX_CONSTRAINT_MATCH) ){
128417 u8 op;
128418 switch( p->op ){
128419 case SQLITE_INDEX_CONSTRAINT_EQ: op = RTREE_EQ; break;
128420 case SQLITE_INDEX_CONSTRAINT_GT: op = RTREE_GT; break;
128421 case SQLITE_INDEX_CONSTRAINT_LE: op = RTREE_LE; break;
128422 case SQLITE_INDEX_CONSTRAINT_LT: op = RTREE_LT; break;
128423 case SQLITE_INDEX_CONSTRAINT_GE: op = RTREE_GE; break;
128424 default:
128425 assert( p->op==SQLITE_INDEX_CONSTRAINT_MATCH );
128426 op = RTREE_MATCH;
128427 break;
128429 zIdxStr[iIdx++] = op;
128430 zIdxStr[iIdx++] = p->iColumn - 1 + 'a';
128431 pIdxInfo->aConstraintUsage[ii].argvIndex = (iIdx/2);
128432 pIdxInfo->aConstraintUsage[ii].omit = 1;
128436 pIdxInfo->idxNum = 2;
128437 pIdxInfo->needToFreeIdxStr = 1;
128438 if( iIdx>0 && 0==(pIdxInfo->idxStr = sqlite3_mprintf("%s", zIdxStr)) ){
128439 return SQLITE_NOMEM;
128441 assert( iIdx>=0 );
128442 pIdxInfo->estimatedCost = (2000000.0 / (double)(iIdx + 1));
128443 return rc;
128447 ** Return the N-dimensional volumn of the cell stored in *p.
128449 static float cellArea(Rtree *pRtree, RtreeCell *p){
128450 float area = 1.0;
128451 int ii;
128452 for(ii=0; ii<(pRtree->nDim*2); ii+=2){
128453 area = (float)(area * (DCOORD(p->aCoord[ii+1]) - DCOORD(p->aCoord[ii])));
128455 return area;
128459 ** Return the margin length of cell p. The margin length is the sum
128460 ** of the objects size in each dimension.
128462 static float cellMargin(Rtree *pRtree, RtreeCell *p){
128463 float margin = 0.0;
128464 int ii;
128465 for(ii=0; ii<(pRtree->nDim*2); ii+=2){
128466 margin += (float)(DCOORD(p->aCoord[ii+1]) - DCOORD(p->aCoord[ii]));
128468 return margin;
128472 ** Store the union of cells p1 and p2 in p1.
128474 static void cellUnion(Rtree *pRtree, RtreeCell *p1, RtreeCell *p2){
128475 int ii;
128476 if( pRtree->eCoordType==RTREE_COORD_REAL32 ){
128477 for(ii=0; ii<(pRtree->nDim*2); ii+=2){
128478 p1->aCoord[ii].f = MIN(p1->aCoord[ii].f, p2->aCoord[ii].f);
128479 p1->aCoord[ii+1].f = MAX(p1->aCoord[ii+1].f, p2->aCoord[ii+1].f);
128481 }else{
128482 for(ii=0; ii<(pRtree->nDim*2); ii+=2){
128483 p1->aCoord[ii].i = MIN(p1->aCoord[ii].i, p2->aCoord[ii].i);
128484 p1->aCoord[ii+1].i = MAX(p1->aCoord[ii+1].i, p2->aCoord[ii+1].i);
128490 ** Return true if the area covered by p2 is a subset of the area covered
128491 ** by p1. False otherwise.
128493 static int cellContains(Rtree *pRtree, RtreeCell *p1, RtreeCell *p2){
128494 int ii;
128495 int isInt = (pRtree->eCoordType==RTREE_COORD_INT32);
128496 for(ii=0; ii<(pRtree->nDim*2); ii+=2){
128497 RtreeCoord *a1 = &p1->aCoord[ii];
128498 RtreeCoord *a2 = &p2->aCoord[ii];
128499 if( (!isInt && (a2[0].f<a1[0].f || a2[1].f>a1[1].f))
128500 || ( isInt && (a2[0].i<a1[0].i || a2[1].i>a1[1].i))
128502 return 0;
128505 return 1;
128509 ** Return the amount cell p would grow by if it were unioned with pCell.
128511 static float cellGrowth(Rtree *pRtree, RtreeCell *p, RtreeCell *pCell){
128512 float area;
128513 RtreeCell cell;
128514 memcpy(&cell, p, sizeof(RtreeCell));
128515 area = cellArea(pRtree, &cell);
128516 cellUnion(pRtree, &cell, pCell);
128517 return (cellArea(pRtree, &cell)-area);
128520 #if VARIANT_RSTARTREE_CHOOSESUBTREE || VARIANT_RSTARTREE_SPLIT
128521 static float cellOverlap(
128522 Rtree *pRtree,
128523 RtreeCell *p,
128524 RtreeCell *aCell,
128525 int nCell,
128526 int iExclude
128528 int ii;
128529 float overlap = 0.0;
128530 for(ii=0; ii<nCell; ii++){
128531 #if VARIANT_RSTARTREE_CHOOSESUBTREE
128532 if( ii!=iExclude )
128533 #else
128534 assert( iExclude==-1 );
128535 UNUSED_PARAMETER(iExclude);
128536 #endif
128538 int jj;
128539 float o = 1.0;
128540 for(jj=0; jj<(pRtree->nDim*2); jj+=2){
128541 double x1;
128542 double x2;
128544 x1 = MAX(DCOORD(p->aCoord[jj]), DCOORD(aCell[ii].aCoord[jj]));
128545 x2 = MIN(DCOORD(p->aCoord[jj+1]), DCOORD(aCell[ii].aCoord[jj+1]));
128547 if( x2<x1 ){
128548 o = 0.0;
128549 break;
128550 }else{
128551 o = o * (float)(x2-x1);
128554 overlap += o;
128557 return overlap;
128559 #endif
128561 #if VARIANT_RSTARTREE_CHOOSESUBTREE
128562 static float cellOverlapEnlargement(
128563 Rtree *pRtree,
128564 RtreeCell *p,
128565 RtreeCell *pInsert,
128566 RtreeCell *aCell,
128567 int nCell,
128568 int iExclude
128570 double before;
128571 double after;
128572 before = cellOverlap(pRtree, p, aCell, nCell, iExclude);
128573 cellUnion(pRtree, p, pInsert);
128574 after = cellOverlap(pRtree, p, aCell, nCell, iExclude);
128575 return (float)(after-before);
128577 #endif
128581 ** This function implements the ChooseLeaf algorithm from Gutman[84].
128582 ** ChooseSubTree in r*tree terminology.
128584 static int ChooseLeaf(
128585 Rtree *pRtree, /* Rtree table */
128586 RtreeCell *pCell, /* Cell to insert into rtree */
128587 int iHeight, /* Height of sub-tree rooted at pCell */
128588 RtreeNode **ppLeaf /* OUT: Selected leaf page */
128590 int rc;
128591 int ii;
128592 RtreeNode *pNode;
128593 rc = nodeAcquire(pRtree, 1, 0, &pNode);
128595 for(ii=0; rc==SQLITE_OK && ii<(pRtree->iDepth-iHeight); ii++){
128596 int iCell;
128597 sqlite3_int64 iBest = 0;
128599 float fMinGrowth = 0.0;
128600 float fMinArea = 0.0;
128601 float fMinOverlap = 0.0;
128603 int nCell = NCELL(pNode);
128604 RtreeCell cell;
128605 RtreeNode *pChild;
128607 RtreeCell *aCell = 0;
128609 #if VARIANT_RSTARTREE_CHOOSESUBTREE
128610 if( ii==(pRtree->iDepth-1) ){
128611 int jj;
128612 aCell = sqlite3_malloc(sizeof(RtreeCell)*nCell);
128613 if( !aCell ){
128614 rc = SQLITE_NOMEM;
128615 nodeRelease(pRtree, pNode);
128616 pNode = 0;
128617 continue;
128619 for(jj=0; jj<nCell; jj++){
128620 nodeGetCell(pRtree, pNode, jj, &aCell[jj]);
128623 #endif
128625 /* Select the child node which will be enlarged the least if pCell
128626 ** is inserted into it. Resolve ties by choosing the entry with
128627 ** the smallest area.
128629 for(iCell=0; iCell<nCell; iCell++){
128630 int bBest = 0;
128631 float growth;
128632 float area;
128633 float overlap = 0.0;
128634 nodeGetCell(pRtree, pNode, iCell, &cell);
128635 growth = cellGrowth(pRtree, &cell, pCell);
128636 area = cellArea(pRtree, &cell);
128638 #if VARIANT_RSTARTREE_CHOOSESUBTREE
128639 if( ii==(pRtree->iDepth-1) ){
128640 overlap = cellOverlapEnlargement(pRtree,&cell,pCell,aCell,nCell,iCell);
128642 if( (iCell==0)
128643 || (overlap<fMinOverlap)
128644 || (overlap==fMinOverlap && growth<fMinGrowth)
128645 || (overlap==fMinOverlap && growth==fMinGrowth && area<fMinArea)
128647 bBest = 1;
128649 #else
128650 if( iCell==0||growth<fMinGrowth||(growth==fMinGrowth && area<fMinArea) ){
128651 bBest = 1;
128653 #endif
128654 if( bBest ){
128655 fMinOverlap = overlap;
128656 fMinGrowth = growth;
128657 fMinArea = area;
128658 iBest = cell.iRowid;
128662 sqlite3_free(aCell);
128663 rc = nodeAcquire(pRtree, iBest, pNode, &pChild);
128664 nodeRelease(pRtree, pNode);
128665 pNode = pChild;
128668 *ppLeaf = pNode;
128669 return rc;
128673 ** A cell with the same content as pCell has just been inserted into
128674 ** the node pNode. This function updates the bounding box cells in
128675 ** all ancestor elements.
128677 static int AdjustTree(
128678 Rtree *pRtree, /* Rtree table */
128679 RtreeNode *pNode, /* Adjust ancestry of this node. */
128680 RtreeCell *pCell /* This cell was just inserted */
128682 RtreeNode *p = pNode;
128683 while( p->pParent ){
128684 RtreeNode *pParent = p->pParent;
128685 RtreeCell cell;
128686 int iCell;
128688 if( nodeParentIndex(pRtree, p, &iCell) ){
128689 return SQLITE_CORRUPT_VTAB;
128692 nodeGetCell(pRtree, pParent, iCell, &cell);
128693 if( !cellContains(pRtree, &cell, pCell) ){
128694 cellUnion(pRtree, &cell, pCell);
128695 nodeOverwriteCell(pRtree, pParent, &cell, iCell);
128698 p = pParent;
128700 return SQLITE_OK;
128704 ** Write mapping (iRowid->iNode) to the <rtree>_rowid table.
128706 static int rowidWrite(Rtree *pRtree, sqlite3_int64 iRowid, sqlite3_int64 iNode){
128707 sqlite3_bind_int64(pRtree->pWriteRowid, 1, iRowid);
128708 sqlite3_bind_int64(pRtree->pWriteRowid, 2, iNode);
128709 sqlite3_step(pRtree->pWriteRowid);
128710 return sqlite3_reset(pRtree->pWriteRowid);
128714 ** Write mapping (iNode->iPar) to the <rtree>_parent table.
128716 static int parentWrite(Rtree *pRtree, sqlite3_int64 iNode, sqlite3_int64 iPar){
128717 sqlite3_bind_int64(pRtree->pWriteParent, 1, iNode);
128718 sqlite3_bind_int64(pRtree->pWriteParent, 2, iPar);
128719 sqlite3_step(pRtree->pWriteParent);
128720 return sqlite3_reset(pRtree->pWriteParent);
128723 static int rtreeInsertCell(Rtree *, RtreeNode *, RtreeCell *, int);
128725 #if VARIANT_GUTTMAN_LINEAR_SPLIT
128727 ** Implementation of the linear variant of the PickNext() function from
128728 ** Guttman[84].
128730 static RtreeCell *LinearPickNext(
128731 Rtree *pRtree,
128732 RtreeCell *aCell,
128733 int nCell,
128734 RtreeCell *pLeftBox,
128735 RtreeCell *pRightBox,
128736 int *aiUsed
128738 int ii;
128739 for(ii=0; aiUsed[ii]; ii++);
128740 aiUsed[ii] = 1;
128741 return &aCell[ii];
128745 ** Implementation of the linear variant of the PickSeeds() function from
128746 ** Guttman[84].
128748 static void LinearPickSeeds(
128749 Rtree *pRtree,
128750 RtreeCell *aCell,
128751 int nCell,
128752 int *piLeftSeed,
128753 int *piRightSeed
128755 int i;
128756 int iLeftSeed = 0;
128757 int iRightSeed = 1;
128758 float maxNormalInnerWidth = 0.0;
128760 /* Pick two "seed" cells from the array of cells. The algorithm used
128761 ** here is the LinearPickSeeds algorithm from Gutman[1984]. The
128762 ** indices of the two seed cells in the array are stored in local
128763 ** variables iLeftSeek and iRightSeed.
128765 for(i=0; i<pRtree->nDim; i++){
128766 float x1 = DCOORD(aCell[0].aCoord[i*2]);
128767 float x2 = DCOORD(aCell[0].aCoord[i*2+1]);
128768 float x3 = x1;
128769 float x4 = x2;
128770 int jj;
128772 int iCellLeft = 0;
128773 int iCellRight = 0;
128775 for(jj=1; jj<nCell; jj++){
128776 float left = DCOORD(aCell[jj].aCoord[i*2]);
128777 float right = DCOORD(aCell[jj].aCoord[i*2+1]);
128779 if( left<x1 ) x1 = left;
128780 if( right>x4 ) x4 = right;
128781 if( left>x3 ){
128782 x3 = left;
128783 iCellRight = jj;
128785 if( right<x2 ){
128786 x2 = right;
128787 iCellLeft = jj;
128791 if( x4!=x1 ){
128792 float normalwidth = (x3 - x2) / (x4 - x1);
128793 if( normalwidth>maxNormalInnerWidth ){
128794 iLeftSeed = iCellLeft;
128795 iRightSeed = iCellRight;
128800 *piLeftSeed = iLeftSeed;
128801 *piRightSeed = iRightSeed;
128803 #endif /* VARIANT_GUTTMAN_LINEAR_SPLIT */
128805 #if VARIANT_GUTTMAN_QUADRATIC_SPLIT
128807 ** Implementation of the quadratic variant of the PickNext() function from
128808 ** Guttman[84].
128810 static RtreeCell *QuadraticPickNext(
128811 Rtree *pRtree,
128812 RtreeCell *aCell,
128813 int nCell,
128814 RtreeCell *pLeftBox,
128815 RtreeCell *pRightBox,
128816 int *aiUsed
128818 #define FABS(a) ((a)<0.0?-1.0*(a):(a))
128820 int iSelect = -1;
128821 float fDiff;
128822 int ii;
128823 for(ii=0; ii<nCell; ii++){
128824 if( aiUsed[ii]==0 ){
128825 float left = cellGrowth(pRtree, pLeftBox, &aCell[ii]);
128826 float right = cellGrowth(pRtree, pLeftBox, &aCell[ii]);
128827 float diff = FABS(right-left);
128828 if( iSelect<0 || diff>fDiff ){
128829 fDiff = diff;
128830 iSelect = ii;
128834 aiUsed[iSelect] = 1;
128835 return &aCell[iSelect];
128839 ** Implementation of the quadratic variant of the PickSeeds() function from
128840 ** Guttman[84].
128842 static void QuadraticPickSeeds(
128843 Rtree *pRtree,
128844 RtreeCell *aCell,
128845 int nCell,
128846 int *piLeftSeed,
128847 int *piRightSeed
128849 int ii;
128850 int jj;
128852 int iLeftSeed = 0;
128853 int iRightSeed = 1;
128854 float fWaste = 0.0;
128856 for(ii=0; ii<nCell; ii++){
128857 for(jj=ii+1; jj<nCell; jj++){
128858 float right = cellArea(pRtree, &aCell[jj]);
128859 float growth = cellGrowth(pRtree, &aCell[ii], &aCell[jj]);
128860 float waste = growth - right;
128862 if( waste>fWaste ){
128863 iLeftSeed = ii;
128864 iRightSeed = jj;
128865 fWaste = waste;
128870 *piLeftSeed = iLeftSeed;
128871 *piRightSeed = iRightSeed;
128873 #endif /* VARIANT_GUTTMAN_QUADRATIC_SPLIT */
128876 ** Arguments aIdx, aDistance and aSpare all point to arrays of size
128877 ** nIdx. The aIdx array contains the set of integers from 0 to
128878 ** (nIdx-1) in no particular order. This function sorts the values
128879 ** in aIdx according to the indexed values in aDistance. For
128880 ** example, assuming the inputs:
128882 ** aIdx = { 0, 1, 2, 3 }
128883 ** aDistance = { 5.0, 2.0, 7.0, 6.0 }
128885 ** this function sets the aIdx array to contain:
128887 ** aIdx = { 0, 1, 2, 3 }
128889 ** The aSpare array is used as temporary working space by the
128890 ** sorting algorithm.
128892 static void SortByDistance(
128893 int *aIdx,
128894 int nIdx,
128895 float *aDistance,
128896 int *aSpare
128898 if( nIdx>1 ){
128899 int iLeft = 0;
128900 int iRight = 0;
128902 int nLeft = nIdx/2;
128903 int nRight = nIdx-nLeft;
128904 int *aLeft = aIdx;
128905 int *aRight = &aIdx[nLeft];
128907 SortByDistance(aLeft, nLeft, aDistance, aSpare);
128908 SortByDistance(aRight, nRight, aDistance, aSpare);
128910 memcpy(aSpare, aLeft, sizeof(int)*nLeft);
128911 aLeft = aSpare;
128913 while( iLeft<nLeft || iRight<nRight ){
128914 if( iLeft==nLeft ){
128915 aIdx[iLeft+iRight] = aRight[iRight];
128916 iRight++;
128917 }else if( iRight==nRight ){
128918 aIdx[iLeft+iRight] = aLeft[iLeft];
128919 iLeft++;
128920 }else{
128921 float fLeft = aDistance[aLeft[iLeft]];
128922 float fRight = aDistance[aRight[iRight]];
128923 if( fLeft<fRight ){
128924 aIdx[iLeft+iRight] = aLeft[iLeft];
128925 iLeft++;
128926 }else{
128927 aIdx[iLeft+iRight] = aRight[iRight];
128928 iRight++;
128933 #if 0
128934 /* Check that the sort worked */
128936 int jj;
128937 for(jj=1; jj<nIdx; jj++){
128938 float left = aDistance[aIdx[jj-1]];
128939 float right = aDistance[aIdx[jj]];
128940 assert( left<=right );
128943 #endif
128948 ** Arguments aIdx, aCell and aSpare all point to arrays of size
128949 ** nIdx. The aIdx array contains the set of integers from 0 to
128950 ** (nIdx-1) in no particular order. This function sorts the values
128951 ** in aIdx according to dimension iDim of the cells in aCell. The
128952 ** minimum value of dimension iDim is considered first, the
128953 ** maximum used to break ties.
128955 ** The aSpare array is used as temporary working space by the
128956 ** sorting algorithm.
128958 static void SortByDimension(
128959 Rtree *pRtree,
128960 int *aIdx,
128961 int nIdx,
128962 int iDim,
128963 RtreeCell *aCell,
128964 int *aSpare
128966 if( nIdx>1 ){
128968 int iLeft = 0;
128969 int iRight = 0;
128971 int nLeft = nIdx/2;
128972 int nRight = nIdx-nLeft;
128973 int *aLeft = aIdx;
128974 int *aRight = &aIdx[nLeft];
128976 SortByDimension(pRtree, aLeft, nLeft, iDim, aCell, aSpare);
128977 SortByDimension(pRtree, aRight, nRight, iDim, aCell, aSpare);
128979 memcpy(aSpare, aLeft, sizeof(int)*nLeft);
128980 aLeft = aSpare;
128981 while( iLeft<nLeft || iRight<nRight ){
128982 double xleft1 = DCOORD(aCell[aLeft[iLeft]].aCoord[iDim*2]);
128983 double xleft2 = DCOORD(aCell[aLeft[iLeft]].aCoord[iDim*2+1]);
128984 double xright1 = DCOORD(aCell[aRight[iRight]].aCoord[iDim*2]);
128985 double xright2 = DCOORD(aCell[aRight[iRight]].aCoord[iDim*2+1]);
128986 if( (iLeft!=nLeft) && ((iRight==nRight)
128987 || (xleft1<xright1)
128988 || (xleft1==xright1 && xleft2<xright2)
128990 aIdx[iLeft+iRight] = aLeft[iLeft];
128991 iLeft++;
128992 }else{
128993 aIdx[iLeft+iRight] = aRight[iRight];
128994 iRight++;
128998 #if 0
128999 /* Check that the sort worked */
129001 int jj;
129002 for(jj=1; jj<nIdx; jj++){
129003 float xleft1 = aCell[aIdx[jj-1]].aCoord[iDim*2];
129004 float xleft2 = aCell[aIdx[jj-1]].aCoord[iDim*2+1];
129005 float xright1 = aCell[aIdx[jj]].aCoord[iDim*2];
129006 float xright2 = aCell[aIdx[jj]].aCoord[iDim*2+1];
129007 assert( xleft1<=xright1 && (xleft1<xright1 || xleft2<=xright2) );
129010 #endif
129014 #if VARIANT_RSTARTREE_SPLIT
129016 ** Implementation of the R*-tree variant of SplitNode from Beckman[1990].
129018 static int splitNodeStartree(
129019 Rtree *pRtree,
129020 RtreeCell *aCell,
129021 int nCell,
129022 RtreeNode *pLeft,
129023 RtreeNode *pRight,
129024 RtreeCell *pBboxLeft,
129025 RtreeCell *pBboxRight
129027 int **aaSorted;
129028 int *aSpare;
129029 int ii;
129031 int iBestDim = 0;
129032 int iBestSplit = 0;
129033 float fBestMargin = 0.0;
129035 int nByte = (pRtree->nDim+1)*(sizeof(int*)+nCell*sizeof(int));
129037 aaSorted = (int **)sqlite3_malloc(nByte);
129038 if( !aaSorted ){
129039 return SQLITE_NOMEM;
129042 aSpare = &((int *)&aaSorted[pRtree->nDim])[pRtree->nDim*nCell];
129043 memset(aaSorted, 0, nByte);
129044 for(ii=0; ii<pRtree->nDim; ii++){
129045 int jj;
129046 aaSorted[ii] = &((int *)&aaSorted[pRtree->nDim])[ii*nCell];
129047 for(jj=0; jj<nCell; jj++){
129048 aaSorted[ii][jj] = jj;
129050 SortByDimension(pRtree, aaSorted[ii], nCell, ii, aCell, aSpare);
129053 for(ii=0; ii<pRtree->nDim; ii++){
129054 float margin = 0.0;
129055 float fBestOverlap = 0.0;
129056 float fBestArea = 0.0;
129057 int iBestLeft = 0;
129058 int nLeft;
129061 nLeft=RTREE_MINCELLS(pRtree);
129062 nLeft<=(nCell-RTREE_MINCELLS(pRtree));
129063 nLeft++
129065 RtreeCell left;
129066 RtreeCell right;
129067 int kk;
129068 float overlap;
129069 float area;
129071 memcpy(&left, &aCell[aaSorted[ii][0]], sizeof(RtreeCell));
129072 memcpy(&right, &aCell[aaSorted[ii][nCell-1]], sizeof(RtreeCell));
129073 for(kk=1; kk<(nCell-1); kk++){
129074 if( kk<nLeft ){
129075 cellUnion(pRtree, &left, &aCell[aaSorted[ii][kk]]);
129076 }else{
129077 cellUnion(pRtree, &right, &aCell[aaSorted[ii][kk]]);
129080 margin += cellMargin(pRtree, &left);
129081 margin += cellMargin(pRtree, &right);
129082 overlap = cellOverlap(pRtree, &left, &right, 1, -1);
129083 area = cellArea(pRtree, &left) + cellArea(pRtree, &right);
129084 if( (nLeft==RTREE_MINCELLS(pRtree))
129085 || (overlap<fBestOverlap)
129086 || (overlap==fBestOverlap && area<fBestArea)
129088 iBestLeft = nLeft;
129089 fBestOverlap = overlap;
129090 fBestArea = area;
129094 if( ii==0 || margin<fBestMargin ){
129095 iBestDim = ii;
129096 fBestMargin = margin;
129097 iBestSplit = iBestLeft;
129101 memcpy(pBboxLeft, &aCell[aaSorted[iBestDim][0]], sizeof(RtreeCell));
129102 memcpy(pBboxRight, &aCell[aaSorted[iBestDim][iBestSplit]], sizeof(RtreeCell));
129103 for(ii=0; ii<nCell; ii++){
129104 RtreeNode *pTarget = (ii<iBestSplit)?pLeft:pRight;
129105 RtreeCell *pBbox = (ii<iBestSplit)?pBboxLeft:pBboxRight;
129106 RtreeCell *pCell = &aCell[aaSorted[iBestDim][ii]];
129107 nodeInsertCell(pRtree, pTarget, pCell);
129108 cellUnion(pRtree, pBbox, pCell);
129111 sqlite3_free(aaSorted);
129112 return SQLITE_OK;
129114 #endif
129116 #if VARIANT_GUTTMAN_SPLIT
129118 ** Implementation of the regular R-tree SplitNode from Guttman[1984].
129120 static int splitNodeGuttman(
129121 Rtree *pRtree,
129122 RtreeCell *aCell,
129123 int nCell,
129124 RtreeNode *pLeft,
129125 RtreeNode *pRight,
129126 RtreeCell *pBboxLeft,
129127 RtreeCell *pBboxRight
129129 int iLeftSeed = 0;
129130 int iRightSeed = 1;
129131 int *aiUsed;
129132 int i;
129134 aiUsed = sqlite3_malloc(sizeof(int)*nCell);
129135 if( !aiUsed ){
129136 return SQLITE_NOMEM;
129138 memset(aiUsed, 0, sizeof(int)*nCell);
129140 PickSeeds(pRtree, aCell, nCell, &iLeftSeed, &iRightSeed);
129142 memcpy(pBboxLeft, &aCell[iLeftSeed], sizeof(RtreeCell));
129143 memcpy(pBboxRight, &aCell[iRightSeed], sizeof(RtreeCell));
129144 nodeInsertCell(pRtree, pLeft, &aCell[iLeftSeed]);
129145 nodeInsertCell(pRtree, pRight, &aCell[iRightSeed]);
129146 aiUsed[iLeftSeed] = 1;
129147 aiUsed[iRightSeed] = 1;
129149 for(i=nCell-2; i>0; i--){
129150 RtreeCell *pNext;
129151 pNext = PickNext(pRtree, aCell, nCell, pBboxLeft, pBboxRight, aiUsed);
129152 float diff =
129153 cellGrowth(pRtree, pBboxLeft, pNext) -
129154 cellGrowth(pRtree, pBboxRight, pNext)
129156 if( (RTREE_MINCELLS(pRtree)-NCELL(pRight)==i)
129157 || (diff>0.0 && (RTREE_MINCELLS(pRtree)-NCELL(pLeft)!=i))
129159 nodeInsertCell(pRtree, pRight, pNext);
129160 cellUnion(pRtree, pBboxRight, pNext);
129161 }else{
129162 nodeInsertCell(pRtree, pLeft, pNext);
129163 cellUnion(pRtree, pBboxLeft, pNext);
129167 sqlite3_free(aiUsed);
129168 return SQLITE_OK;
129170 #endif
129172 static int updateMapping(
129173 Rtree *pRtree,
129174 i64 iRowid,
129175 RtreeNode *pNode,
129176 int iHeight
129178 int (*xSetMapping)(Rtree *, sqlite3_int64, sqlite3_int64);
129179 xSetMapping = ((iHeight==0)?rowidWrite:parentWrite);
129180 if( iHeight>0 ){
129181 RtreeNode *pChild = nodeHashLookup(pRtree, iRowid);
129182 if( pChild ){
129183 nodeRelease(pRtree, pChild->pParent);
129184 nodeReference(pNode);
129185 pChild->pParent = pNode;
129188 return xSetMapping(pRtree, iRowid, pNode->iNode);
129191 static int SplitNode(
129192 Rtree *pRtree,
129193 RtreeNode *pNode,
129194 RtreeCell *pCell,
129195 int iHeight
129197 int i;
129198 int newCellIsRight = 0;
129200 int rc = SQLITE_OK;
129201 int nCell = NCELL(pNode);
129202 RtreeCell *aCell;
129203 int *aiUsed;
129205 RtreeNode *pLeft = 0;
129206 RtreeNode *pRight = 0;
129208 RtreeCell leftbbox;
129209 RtreeCell rightbbox;
129211 /* Allocate an array and populate it with a copy of pCell and
129212 ** all cells from node pLeft. Then zero the original node.
129214 aCell = sqlite3_malloc((sizeof(RtreeCell)+sizeof(int))*(nCell+1));
129215 if( !aCell ){
129216 rc = SQLITE_NOMEM;
129217 goto splitnode_out;
129219 aiUsed = (int *)&aCell[nCell+1];
129220 memset(aiUsed, 0, sizeof(int)*(nCell+1));
129221 for(i=0; i<nCell; i++){
129222 nodeGetCell(pRtree, pNode, i, &aCell[i]);
129224 nodeZero(pRtree, pNode);
129225 memcpy(&aCell[nCell], pCell, sizeof(RtreeCell));
129226 nCell++;
129228 if( pNode->iNode==1 ){
129229 pRight = nodeNew(pRtree, pNode);
129230 pLeft = nodeNew(pRtree, pNode);
129231 pRtree->iDepth++;
129232 pNode->isDirty = 1;
129233 writeInt16(pNode->zData, pRtree->iDepth);
129234 }else{
129235 pLeft = pNode;
129236 pRight = nodeNew(pRtree, pLeft->pParent);
129237 nodeReference(pLeft);
129240 if( !pLeft || !pRight ){
129241 rc = SQLITE_NOMEM;
129242 goto splitnode_out;
129245 memset(pLeft->zData, 0, pRtree->iNodeSize);
129246 memset(pRight->zData, 0, pRtree->iNodeSize);
129248 rc = AssignCells(pRtree, aCell, nCell, pLeft, pRight, &leftbbox, &rightbbox);
129249 if( rc!=SQLITE_OK ){
129250 goto splitnode_out;
129253 /* Ensure both child nodes have node numbers assigned to them by calling
129254 ** nodeWrite(). Node pRight always needs a node number, as it was created
129255 ** by nodeNew() above. But node pLeft sometimes already has a node number.
129256 ** In this case avoid the all to nodeWrite().
129258 if( SQLITE_OK!=(rc = nodeWrite(pRtree, pRight))
129259 || (0==pLeft->iNode && SQLITE_OK!=(rc = nodeWrite(pRtree, pLeft)))
129261 goto splitnode_out;
129264 rightbbox.iRowid = pRight->iNode;
129265 leftbbox.iRowid = pLeft->iNode;
129267 if( pNode->iNode==1 ){
129268 rc = rtreeInsertCell(pRtree, pLeft->pParent, &leftbbox, iHeight+1);
129269 if( rc!=SQLITE_OK ){
129270 goto splitnode_out;
129272 }else{
129273 RtreeNode *pParent = pLeft->pParent;
129274 int iCell;
129275 rc = nodeParentIndex(pRtree, pLeft, &iCell);
129276 if( rc==SQLITE_OK ){
129277 nodeOverwriteCell(pRtree, pParent, &leftbbox, iCell);
129278 rc = AdjustTree(pRtree, pParent, &leftbbox);
129280 if( rc!=SQLITE_OK ){
129281 goto splitnode_out;
129284 if( (rc = rtreeInsertCell(pRtree, pRight->pParent, &rightbbox, iHeight+1)) ){
129285 goto splitnode_out;
129288 for(i=0; i<NCELL(pRight); i++){
129289 i64 iRowid = nodeGetRowid(pRtree, pRight, i);
129290 rc = updateMapping(pRtree, iRowid, pRight, iHeight);
129291 if( iRowid==pCell->iRowid ){
129292 newCellIsRight = 1;
129294 if( rc!=SQLITE_OK ){
129295 goto splitnode_out;
129298 if( pNode->iNode==1 ){
129299 for(i=0; i<NCELL(pLeft); i++){
129300 i64 iRowid = nodeGetRowid(pRtree, pLeft, i);
129301 rc = updateMapping(pRtree, iRowid, pLeft, iHeight);
129302 if( rc!=SQLITE_OK ){
129303 goto splitnode_out;
129306 }else if( newCellIsRight==0 ){
129307 rc = updateMapping(pRtree, pCell->iRowid, pLeft, iHeight);
129310 if( rc==SQLITE_OK ){
129311 rc = nodeRelease(pRtree, pRight);
129312 pRight = 0;
129314 if( rc==SQLITE_OK ){
129315 rc = nodeRelease(pRtree, pLeft);
129316 pLeft = 0;
129319 splitnode_out:
129320 nodeRelease(pRtree, pRight);
129321 nodeRelease(pRtree, pLeft);
129322 sqlite3_free(aCell);
129323 return rc;
129327 ** If node pLeaf is not the root of the r-tree and its pParent pointer is
129328 ** still NULL, load all ancestor nodes of pLeaf into memory and populate
129329 ** the pLeaf->pParent chain all the way up to the root node.
129331 ** This operation is required when a row is deleted (or updated - an update
129332 ** is implemented as a delete followed by an insert). SQLite provides the
129333 ** rowid of the row to delete, which can be used to find the leaf on which
129334 ** the entry resides (argument pLeaf). Once the leaf is located, this
129335 ** function is called to determine its ancestry.
129337 static int fixLeafParent(Rtree *pRtree, RtreeNode *pLeaf){
129338 int rc = SQLITE_OK;
129339 RtreeNode *pChild = pLeaf;
129340 while( rc==SQLITE_OK && pChild->iNode!=1 && pChild->pParent==0 ){
129341 int rc2 = SQLITE_OK; /* sqlite3_reset() return code */
129342 sqlite3_bind_int64(pRtree->pReadParent, 1, pChild->iNode);
129343 rc = sqlite3_step(pRtree->pReadParent);
129344 if( rc==SQLITE_ROW ){
129345 RtreeNode *pTest; /* Used to test for reference loops */
129346 i64 iNode; /* Node number of parent node */
129348 /* Before setting pChild->pParent, test that we are not creating a
129349 ** loop of references (as we would if, say, pChild==pParent). We don't
129350 ** want to do this as it leads to a memory leak when trying to delete
129351 ** the referenced counted node structures.
129353 iNode = sqlite3_column_int64(pRtree->pReadParent, 0);
129354 for(pTest=pLeaf; pTest && pTest->iNode!=iNode; pTest=pTest->pParent);
129355 if( !pTest ){
129356 rc2 = nodeAcquire(pRtree, iNode, 0, &pChild->pParent);
129359 rc = sqlite3_reset(pRtree->pReadParent);
129360 if( rc==SQLITE_OK ) rc = rc2;
129361 if( rc==SQLITE_OK && !pChild->pParent ) rc = SQLITE_CORRUPT_VTAB;
129362 pChild = pChild->pParent;
129364 return rc;
129367 static int deleteCell(Rtree *, RtreeNode *, int, int);
129369 static int removeNode(Rtree *pRtree, RtreeNode *pNode, int iHeight){
129370 int rc;
129371 int rc2;
129372 RtreeNode *pParent = 0;
129373 int iCell;
129375 assert( pNode->nRef==1 );
129377 /* Remove the entry in the parent cell. */
129378 rc = nodeParentIndex(pRtree, pNode, &iCell);
129379 if( rc==SQLITE_OK ){
129380 pParent = pNode->pParent;
129381 pNode->pParent = 0;
129382 rc = deleteCell(pRtree, pParent, iCell, iHeight+1);
129384 rc2 = nodeRelease(pRtree, pParent);
129385 if( rc==SQLITE_OK ){
129386 rc = rc2;
129388 if( rc!=SQLITE_OK ){
129389 return rc;
129392 /* Remove the xxx_node entry. */
129393 sqlite3_bind_int64(pRtree->pDeleteNode, 1, pNode->iNode);
129394 sqlite3_step(pRtree->pDeleteNode);
129395 if( SQLITE_OK!=(rc = sqlite3_reset(pRtree->pDeleteNode)) ){
129396 return rc;
129399 /* Remove the xxx_parent entry. */
129400 sqlite3_bind_int64(pRtree->pDeleteParent, 1, pNode->iNode);
129401 sqlite3_step(pRtree->pDeleteParent);
129402 if( SQLITE_OK!=(rc = sqlite3_reset(pRtree->pDeleteParent)) ){
129403 return rc;
129406 /* Remove the node from the in-memory hash table and link it into
129407 ** the Rtree.pDeleted list. Its contents will be re-inserted later on.
129409 nodeHashDelete(pRtree, pNode);
129410 pNode->iNode = iHeight;
129411 pNode->pNext = pRtree->pDeleted;
129412 pNode->nRef++;
129413 pRtree->pDeleted = pNode;
129415 return SQLITE_OK;
129418 static int fixBoundingBox(Rtree *pRtree, RtreeNode *pNode){
129419 RtreeNode *pParent = pNode->pParent;
129420 int rc = SQLITE_OK;
129421 if( pParent ){
129422 int ii;
129423 int nCell = NCELL(pNode);
129424 RtreeCell box; /* Bounding box for pNode */
129425 nodeGetCell(pRtree, pNode, 0, &box);
129426 for(ii=1; ii<nCell; ii++){
129427 RtreeCell cell;
129428 nodeGetCell(pRtree, pNode, ii, &cell);
129429 cellUnion(pRtree, &box, &cell);
129431 box.iRowid = pNode->iNode;
129432 rc = nodeParentIndex(pRtree, pNode, &ii);
129433 if( rc==SQLITE_OK ){
129434 nodeOverwriteCell(pRtree, pParent, &box, ii);
129435 rc = fixBoundingBox(pRtree, pParent);
129438 return rc;
129442 ** Delete the cell at index iCell of node pNode. After removing the
129443 ** cell, adjust the r-tree data structure if required.
129445 static int deleteCell(Rtree *pRtree, RtreeNode *pNode, int iCell, int iHeight){
129446 RtreeNode *pParent;
129447 int rc;
129449 if( SQLITE_OK!=(rc = fixLeafParent(pRtree, pNode)) ){
129450 return rc;
129453 /* Remove the cell from the node. This call just moves bytes around
129454 ** the in-memory node image, so it cannot fail.
129456 nodeDeleteCell(pRtree, pNode, iCell);
129458 /* If the node is not the tree root and now has less than the minimum
129459 ** number of cells, remove it from the tree. Otherwise, update the
129460 ** cell in the parent node so that it tightly contains the updated
129461 ** node.
129463 pParent = pNode->pParent;
129464 assert( pParent || pNode->iNode==1 );
129465 if( pParent ){
129466 if( NCELL(pNode)<RTREE_MINCELLS(pRtree) ){
129467 rc = removeNode(pRtree, pNode, iHeight);
129468 }else{
129469 rc = fixBoundingBox(pRtree, pNode);
129473 return rc;
129476 static int Reinsert(
129477 Rtree *pRtree,
129478 RtreeNode *pNode,
129479 RtreeCell *pCell,
129480 int iHeight
129482 int *aOrder;
129483 int *aSpare;
129484 RtreeCell *aCell;
129485 float *aDistance;
129486 int nCell;
129487 float aCenterCoord[RTREE_MAX_DIMENSIONS];
129488 int iDim;
129489 int ii;
129490 int rc = SQLITE_OK;
129492 memset(aCenterCoord, 0, sizeof(float)*RTREE_MAX_DIMENSIONS);
129494 nCell = NCELL(pNode)+1;
129496 /* Allocate the buffers used by this operation. The allocation is
129497 ** relinquished before this function returns.
129499 aCell = (RtreeCell *)sqlite3_malloc(nCell * (
129500 sizeof(RtreeCell) + /* aCell array */
129501 sizeof(int) + /* aOrder array */
129502 sizeof(int) + /* aSpare array */
129503 sizeof(float) /* aDistance array */
129505 if( !aCell ){
129506 return SQLITE_NOMEM;
129508 aOrder = (int *)&aCell[nCell];
129509 aSpare = (int *)&aOrder[nCell];
129510 aDistance = (float *)&aSpare[nCell];
129512 for(ii=0; ii<nCell; ii++){
129513 if( ii==(nCell-1) ){
129514 memcpy(&aCell[ii], pCell, sizeof(RtreeCell));
129515 }else{
129516 nodeGetCell(pRtree, pNode, ii, &aCell[ii]);
129518 aOrder[ii] = ii;
129519 for(iDim=0; iDim<pRtree->nDim; iDim++){
129520 aCenterCoord[iDim] += (float)DCOORD(aCell[ii].aCoord[iDim*2]);
129521 aCenterCoord[iDim] += (float)DCOORD(aCell[ii].aCoord[iDim*2+1]);
129524 for(iDim=0; iDim<pRtree->nDim; iDim++){
129525 aCenterCoord[iDim] = (float)(aCenterCoord[iDim]/((float)nCell*2.0));
129528 for(ii=0; ii<nCell; ii++){
129529 aDistance[ii] = 0.0;
129530 for(iDim=0; iDim<pRtree->nDim; iDim++){
129531 float coord = (float)(DCOORD(aCell[ii].aCoord[iDim*2+1]) -
129532 DCOORD(aCell[ii].aCoord[iDim*2]));
129533 aDistance[ii] += (coord-aCenterCoord[iDim])*(coord-aCenterCoord[iDim]);
129537 SortByDistance(aOrder, nCell, aDistance, aSpare);
129538 nodeZero(pRtree, pNode);
129540 for(ii=0; rc==SQLITE_OK && ii<(nCell-(RTREE_MINCELLS(pRtree)+1)); ii++){
129541 RtreeCell *p = &aCell[aOrder[ii]];
129542 nodeInsertCell(pRtree, pNode, p);
129543 if( p->iRowid==pCell->iRowid ){
129544 if( iHeight==0 ){
129545 rc = rowidWrite(pRtree, p->iRowid, pNode->iNode);
129546 }else{
129547 rc = parentWrite(pRtree, p->iRowid, pNode->iNode);
129551 if( rc==SQLITE_OK ){
129552 rc = fixBoundingBox(pRtree, pNode);
129554 for(; rc==SQLITE_OK && ii<nCell; ii++){
129555 /* Find a node to store this cell in. pNode->iNode currently contains
129556 ** the height of the sub-tree headed by the cell.
129558 RtreeNode *pInsert;
129559 RtreeCell *p = &aCell[aOrder[ii]];
129560 rc = ChooseLeaf(pRtree, p, iHeight, &pInsert);
129561 if( rc==SQLITE_OK ){
129562 int rc2;
129563 rc = rtreeInsertCell(pRtree, pInsert, p, iHeight);
129564 rc2 = nodeRelease(pRtree, pInsert);
129565 if( rc==SQLITE_OK ){
129566 rc = rc2;
129571 sqlite3_free(aCell);
129572 return rc;
129576 ** Insert cell pCell into node pNode. Node pNode is the head of a
129577 ** subtree iHeight high (leaf nodes have iHeight==0).
129579 static int rtreeInsertCell(
129580 Rtree *pRtree,
129581 RtreeNode *pNode,
129582 RtreeCell *pCell,
129583 int iHeight
129585 int rc = SQLITE_OK;
129586 if( iHeight>0 ){
129587 RtreeNode *pChild = nodeHashLookup(pRtree, pCell->iRowid);
129588 if( pChild ){
129589 nodeRelease(pRtree, pChild->pParent);
129590 nodeReference(pNode);
129591 pChild->pParent = pNode;
129594 if( nodeInsertCell(pRtree, pNode, pCell) ){
129595 #if VARIANT_RSTARTREE_REINSERT
129596 if( iHeight<=pRtree->iReinsertHeight || pNode->iNode==1){
129597 rc = SplitNode(pRtree, pNode, pCell, iHeight);
129598 }else{
129599 pRtree->iReinsertHeight = iHeight;
129600 rc = Reinsert(pRtree, pNode, pCell, iHeight);
129602 #else
129603 rc = SplitNode(pRtree, pNode, pCell, iHeight);
129604 #endif
129605 }else{
129606 rc = AdjustTree(pRtree, pNode, pCell);
129607 if( rc==SQLITE_OK ){
129608 if( iHeight==0 ){
129609 rc = rowidWrite(pRtree, pCell->iRowid, pNode->iNode);
129610 }else{
129611 rc = parentWrite(pRtree, pCell->iRowid, pNode->iNode);
129615 return rc;
129618 static int reinsertNodeContent(Rtree *pRtree, RtreeNode *pNode){
129619 int ii;
129620 int rc = SQLITE_OK;
129621 int nCell = NCELL(pNode);
129623 for(ii=0; rc==SQLITE_OK && ii<nCell; ii++){
129624 RtreeNode *pInsert;
129625 RtreeCell cell;
129626 nodeGetCell(pRtree, pNode, ii, &cell);
129628 /* Find a node to store this cell in. pNode->iNode currently contains
129629 ** the height of the sub-tree headed by the cell.
129631 rc = ChooseLeaf(pRtree, &cell, (int)pNode->iNode, &pInsert);
129632 if( rc==SQLITE_OK ){
129633 int rc2;
129634 rc = rtreeInsertCell(pRtree, pInsert, &cell, (int)pNode->iNode);
129635 rc2 = nodeRelease(pRtree, pInsert);
129636 if( rc==SQLITE_OK ){
129637 rc = rc2;
129641 return rc;
129645 ** Select a currently unused rowid for a new r-tree record.
129647 static int newRowid(Rtree *pRtree, i64 *piRowid){
129648 int rc;
129649 sqlite3_bind_null(pRtree->pWriteRowid, 1);
129650 sqlite3_bind_null(pRtree->pWriteRowid, 2);
129651 sqlite3_step(pRtree->pWriteRowid);
129652 rc = sqlite3_reset(pRtree->pWriteRowid);
129653 *piRowid = sqlite3_last_insert_rowid(pRtree->db);
129654 return rc;
129658 ** Remove the entry with rowid=iDelete from the r-tree structure.
129660 static int rtreeDeleteRowid(Rtree *pRtree, sqlite3_int64 iDelete){
129661 int rc; /* Return code */
129662 RtreeNode *pLeaf; /* Leaf node containing record iDelete */
129663 int iCell; /* Index of iDelete cell in pLeaf */
129664 RtreeNode *pRoot; /* Root node of rtree structure */
129667 /* Obtain a reference to the root node to initialise Rtree.iDepth */
129668 rc = nodeAcquire(pRtree, 1, 0, &pRoot);
129670 /* Obtain a reference to the leaf node that contains the entry
129671 ** about to be deleted.
129673 if( rc==SQLITE_OK ){
129674 rc = findLeafNode(pRtree, iDelete, &pLeaf);
129677 /* Delete the cell in question from the leaf node. */
129678 if( rc==SQLITE_OK ){
129679 int rc2;
129680 rc = nodeRowidIndex(pRtree, pLeaf, iDelete, &iCell);
129681 if( rc==SQLITE_OK ){
129682 rc = deleteCell(pRtree, pLeaf, iCell, 0);
129684 rc2 = nodeRelease(pRtree, pLeaf);
129685 if( rc==SQLITE_OK ){
129686 rc = rc2;
129690 /* Delete the corresponding entry in the <rtree>_rowid table. */
129691 if( rc==SQLITE_OK ){
129692 sqlite3_bind_int64(pRtree->pDeleteRowid, 1, iDelete);
129693 sqlite3_step(pRtree->pDeleteRowid);
129694 rc = sqlite3_reset(pRtree->pDeleteRowid);
129697 /* Check if the root node now has exactly one child. If so, remove
129698 ** it, schedule the contents of the child for reinsertion and
129699 ** reduce the tree height by one.
129701 ** This is equivalent to copying the contents of the child into
129702 ** the root node (the operation that Gutman's paper says to perform
129703 ** in this scenario).
129705 if( rc==SQLITE_OK && pRtree->iDepth>0 && NCELL(pRoot)==1 ){
129706 int rc2;
129707 RtreeNode *pChild;
129708 i64 iChild = nodeGetRowid(pRtree, pRoot, 0);
129709 rc = nodeAcquire(pRtree, iChild, pRoot, &pChild);
129710 if( rc==SQLITE_OK ){
129711 rc = removeNode(pRtree, pChild, pRtree->iDepth-1);
129713 rc2 = nodeRelease(pRtree, pChild);
129714 if( rc==SQLITE_OK ) rc = rc2;
129715 if( rc==SQLITE_OK ){
129716 pRtree->iDepth--;
129717 writeInt16(pRoot->zData, pRtree->iDepth);
129718 pRoot->isDirty = 1;
129722 /* Re-insert the contents of any underfull nodes removed from the tree. */
129723 for(pLeaf=pRtree->pDeleted; pLeaf; pLeaf=pRtree->pDeleted){
129724 if( rc==SQLITE_OK ){
129725 rc = reinsertNodeContent(pRtree, pLeaf);
129727 pRtree->pDeleted = pLeaf->pNext;
129728 sqlite3_free(pLeaf);
129731 /* Release the reference to the root node. */
129732 if( rc==SQLITE_OK ){
129733 rc = nodeRelease(pRtree, pRoot);
129734 }else{
129735 nodeRelease(pRtree, pRoot);
129738 return rc;
129742 ** The xUpdate method for rtree module virtual tables.
129744 static int rtreeUpdate(
129745 sqlite3_vtab *pVtab,
129746 int nData,
129747 sqlite3_value **azData,
129748 sqlite_int64 *pRowid
129750 Rtree *pRtree = (Rtree *)pVtab;
129751 int rc = SQLITE_OK;
129752 RtreeCell cell; /* New cell to insert if nData>1 */
129753 int bHaveRowid = 0; /* Set to 1 after new rowid is determined */
129755 rtreeReference(pRtree);
129756 assert(nData>=1);
129758 /* Constraint handling. A write operation on an r-tree table may return
129759 ** SQLITE_CONSTRAINT for two reasons:
129761 ** 1. A duplicate rowid value, or
129762 ** 2. The supplied data violates the "x2>=x1" constraint.
129764 ** In the first case, if the conflict-handling mode is REPLACE, then
129765 ** the conflicting row can be removed before proceeding. In the second
129766 ** case, SQLITE_CONSTRAINT must be returned regardless of the
129767 ** conflict-handling mode specified by the user.
129769 if( nData>1 ){
129770 int ii;
129772 /* Populate the cell.aCoord[] array. The first coordinate is azData[3]. */
129773 assert( nData==(pRtree->nDim*2 + 3) );
129774 if( pRtree->eCoordType==RTREE_COORD_REAL32 ){
129775 for(ii=0; ii<(pRtree->nDim*2); ii+=2){
129776 cell.aCoord[ii].f = (float)sqlite3_value_double(azData[ii+3]);
129777 cell.aCoord[ii+1].f = (float)sqlite3_value_double(azData[ii+4]);
129778 if( cell.aCoord[ii].f>cell.aCoord[ii+1].f ){
129779 rc = SQLITE_CONSTRAINT;
129780 goto constraint;
129783 }else{
129784 for(ii=0; ii<(pRtree->nDim*2); ii+=2){
129785 cell.aCoord[ii].i = sqlite3_value_int(azData[ii+3]);
129786 cell.aCoord[ii+1].i = sqlite3_value_int(azData[ii+4]);
129787 if( cell.aCoord[ii].i>cell.aCoord[ii+1].i ){
129788 rc = SQLITE_CONSTRAINT;
129789 goto constraint;
129794 /* If a rowid value was supplied, check if it is already present in
129795 ** the table. If so, the constraint has failed. */
129796 if( sqlite3_value_type(azData[2])!=SQLITE_NULL ){
129797 cell.iRowid = sqlite3_value_int64(azData[2]);
129798 if( sqlite3_value_type(azData[0])==SQLITE_NULL
129799 || sqlite3_value_int64(azData[0])!=cell.iRowid
129801 int steprc;
129802 sqlite3_bind_int64(pRtree->pReadRowid, 1, cell.iRowid);
129803 steprc = sqlite3_step(pRtree->pReadRowid);
129804 rc = sqlite3_reset(pRtree->pReadRowid);
129805 if( SQLITE_ROW==steprc ){
129806 if( sqlite3_vtab_on_conflict(pRtree->db)==SQLITE_REPLACE ){
129807 rc = rtreeDeleteRowid(pRtree, cell.iRowid);
129808 }else{
129809 rc = SQLITE_CONSTRAINT;
129810 goto constraint;
129814 bHaveRowid = 1;
129818 /* If azData[0] is not an SQL NULL value, it is the rowid of a
129819 ** record to delete from the r-tree table. The following block does
129820 ** just that.
129822 if( sqlite3_value_type(azData[0])!=SQLITE_NULL ){
129823 rc = rtreeDeleteRowid(pRtree, sqlite3_value_int64(azData[0]));
129826 /* If the azData[] array contains more than one element, elements
129827 ** (azData[2]..azData[argc-1]) contain a new record to insert into
129828 ** the r-tree structure.
129830 if( rc==SQLITE_OK && nData>1 ){
129831 /* Insert the new record into the r-tree */
129832 RtreeNode *pLeaf;
129834 /* Figure out the rowid of the new row. */
129835 if( bHaveRowid==0 ){
129836 rc = newRowid(pRtree, &cell.iRowid);
129838 *pRowid = cell.iRowid;
129840 if( rc==SQLITE_OK ){
129841 rc = ChooseLeaf(pRtree, &cell, 0, &pLeaf);
129843 if( rc==SQLITE_OK ){
129844 int rc2;
129845 pRtree->iReinsertHeight = -1;
129846 rc = rtreeInsertCell(pRtree, pLeaf, &cell, 0);
129847 rc2 = nodeRelease(pRtree, pLeaf);
129848 if( rc==SQLITE_OK ){
129849 rc = rc2;
129854 constraint:
129855 rtreeRelease(pRtree);
129856 return rc;
129860 ** The xRename method for rtree module virtual tables.
129862 static int rtreeRename(sqlite3_vtab *pVtab, const char *zNewName){
129863 Rtree *pRtree = (Rtree *)pVtab;
129864 int rc = SQLITE_NOMEM;
129865 char *zSql = sqlite3_mprintf(
129866 "ALTER TABLE %Q.'%q_node' RENAME TO \"%w_node\";"
129867 "ALTER TABLE %Q.'%q_parent' RENAME TO \"%w_parent\";"
129868 "ALTER TABLE %Q.'%q_rowid' RENAME TO \"%w_rowid\";"
129869 , pRtree->zDb, pRtree->zName, zNewName
129870 , pRtree->zDb, pRtree->zName, zNewName
129871 , pRtree->zDb, pRtree->zName, zNewName
129873 if( zSql ){
129874 rc = sqlite3_exec(pRtree->db, zSql, 0, 0, 0);
129875 sqlite3_free(zSql);
129877 return rc;
129880 static sqlite3_module rtreeModule = {
129881 0, /* iVersion */
129882 rtreeCreate, /* xCreate - create a table */
129883 rtreeConnect, /* xConnect - connect to an existing table */
129884 rtreeBestIndex, /* xBestIndex - Determine search strategy */
129885 rtreeDisconnect, /* xDisconnect - Disconnect from a table */
129886 rtreeDestroy, /* xDestroy - Drop a table */
129887 rtreeOpen, /* xOpen - open a cursor */
129888 rtreeClose, /* xClose - close a cursor */
129889 rtreeFilter, /* xFilter - configure scan constraints */
129890 rtreeNext, /* xNext - advance a cursor */
129891 rtreeEof, /* xEof */
129892 rtreeColumn, /* xColumn - read data */
129893 rtreeRowid, /* xRowid - read data */
129894 rtreeUpdate, /* xUpdate - write data */
129895 0, /* xBegin - begin transaction */
129896 0, /* xSync - sync transaction */
129897 0, /* xCommit - commit transaction */
129898 0, /* xRollback - rollback transaction */
129899 0, /* xFindFunction - function overloading */
129900 rtreeRename, /* xRename - rename the table */
129901 0, /* xSavepoint */
129902 0, /* xRelease */
129903 0 /* xRollbackTo */
129906 static int rtreeSqlInit(
129907 Rtree *pRtree,
129908 sqlite3 *db,
129909 const char *zDb,
129910 const char *zPrefix,
129911 int isCreate
129913 int rc = SQLITE_OK;
129915 #define N_STATEMENT 9
129916 static const char *azSql[N_STATEMENT] = {
129917 /* Read and write the xxx_node table */
129918 "SELECT data FROM '%q'.'%q_node' WHERE nodeno = :1",
129919 "INSERT OR REPLACE INTO '%q'.'%q_node' VALUES(:1, :2)",
129920 "DELETE FROM '%q'.'%q_node' WHERE nodeno = :1",
129922 /* Read and write the xxx_rowid table */
129923 "SELECT nodeno FROM '%q'.'%q_rowid' WHERE rowid = :1",
129924 "INSERT OR REPLACE INTO '%q'.'%q_rowid' VALUES(:1, :2)",
129925 "DELETE FROM '%q'.'%q_rowid' WHERE rowid = :1",
129927 /* Read and write the xxx_parent table */
129928 "SELECT parentnode FROM '%q'.'%q_parent' WHERE nodeno = :1",
129929 "INSERT OR REPLACE INTO '%q'.'%q_parent' VALUES(:1, :2)",
129930 "DELETE FROM '%q'.'%q_parent' WHERE nodeno = :1"
129932 sqlite3_stmt **appStmt[N_STATEMENT];
129933 int i;
129935 pRtree->db = db;
129937 if( isCreate ){
129938 char *zCreate = sqlite3_mprintf(
129939 "CREATE TABLE \"%w\".\"%w_node\"(nodeno INTEGER PRIMARY KEY, data BLOB);"
129940 "CREATE TABLE \"%w\".\"%w_rowid\"(rowid INTEGER PRIMARY KEY, nodeno INTEGER);"
129941 "CREATE TABLE \"%w\".\"%w_parent\"(nodeno INTEGER PRIMARY KEY, parentnode INTEGER);"
129942 "INSERT INTO '%q'.'%q_node' VALUES(1, zeroblob(%d))",
129943 zDb, zPrefix, zDb, zPrefix, zDb, zPrefix, zDb, zPrefix, pRtree->iNodeSize
129945 if( !zCreate ){
129946 return SQLITE_NOMEM;
129948 rc = sqlite3_exec(db, zCreate, 0, 0, 0);
129949 sqlite3_free(zCreate);
129950 if( rc!=SQLITE_OK ){
129951 return rc;
129955 appStmt[0] = &pRtree->pReadNode;
129956 appStmt[1] = &pRtree->pWriteNode;
129957 appStmt[2] = &pRtree->pDeleteNode;
129958 appStmt[3] = &pRtree->pReadRowid;
129959 appStmt[4] = &pRtree->pWriteRowid;
129960 appStmt[5] = &pRtree->pDeleteRowid;
129961 appStmt[6] = &pRtree->pReadParent;
129962 appStmt[7] = &pRtree->pWriteParent;
129963 appStmt[8] = &pRtree->pDeleteParent;
129965 for(i=0; i<N_STATEMENT && rc==SQLITE_OK; i++){
129966 char *zSql = sqlite3_mprintf(azSql[i], zDb, zPrefix);
129967 if( zSql ){
129968 rc = sqlite3_prepare_v2(db, zSql, -1, appStmt[i], 0);
129969 }else{
129970 rc = SQLITE_NOMEM;
129972 sqlite3_free(zSql);
129975 return rc;
129979 ** The second argument to this function contains the text of an SQL statement
129980 ** that returns a single integer value. The statement is compiled and executed
129981 ** using database connection db. If successful, the integer value returned
129982 ** is written to *piVal and SQLITE_OK returned. Otherwise, an SQLite error
129983 ** code is returned and the value of *piVal after returning is not defined.
129985 static int getIntFromStmt(sqlite3 *db, const char *zSql, int *piVal){
129986 int rc = SQLITE_NOMEM;
129987 if( zSql ){
129988 sqlite3_stmt *pStmt = 0;
129989 rc = sqlite3_prepare_v2(db, zSql, -1, &pStmt, 0);
129990 if( rc==SQLITE_OK ){
129991 if( SQLITE_ROW==sqlite3_step(pStmt) ){
129992 *piVal = sqlite3_column_int(pStmt, 0);
129994 rc = sqlite3_finalize(pStmt);
129997 return rc;
130001 ** This function is called from within the xConnect() or xCreate() method to
130002 ** determine the node-size used by the rtree table being created or connected
130003 ** to. If successful, pRtree->iNodeSize is populated and SQLITE_OK returned.
130004 ** Otherwise, an SQLite error code is returned.
130006 ** If this function is being called as part of an xConnect(), then the rtree
130007 ** table already exists. In this case the node-size is determined by inspecting
130008 ** the root node of the tree.
130010 ** Otherwise, for an xCreate(), use 64 bytes less than the database page-size.
130011 ** This ensures that each node is stored on a single database page. If the
130012 ** database page-size is so large that more than RTREE_MAXCELLS entries
130013 ** would fit in a single node, use a smaller node-size.
130015 static int getNodeSize(
130016 sqlite3 *db, /* Database handle */
130017 Rtree *pRtree, /* Rtree handle */
130018 int isCreate /* True for xCreate, false for xConnect */
130020 int rc;
130021 char *zSql;
130022 if( isCreate ){
130023 int iPageSize = 0;
130024 zSql = sqlite3_mprintf("PRAGMA %Q.page_size", pRtree->zDb);
130025 rc = getIntFromStmt(db, zSql, &iPageSize);
130026 if( rc==SQLITE_OK ){
130027 pRtree->iNodeSize = iPageSize-64;
130028 if( (4+pRtree->nBytesPerCell*RTREE_MAXCELLS)<pRtree->iNodeSize ){
130029 pRtree->iNodeSize = 4+pRtree->nBytesPerCell*RTREE_MAXCELLS;
130032 }else{
130033 zSql = sqlite3_mprintf(
130034 "SELECT length(data) FROM '%q'.'%q_node' WHERE nodeno = 1",
130035 pRtree->zDb, pRtree->zName
130037 rc = getIntFromStmt(db, zSql, &pRtree->iNodeSize);
130040 sqlite3_free(zSql);
130041 return rc;
130045 ** This function is the implementation of both the xConnect and xCreate
130046 ** methods of the r-tree virtual table.
130048 ** argv[0] -> module name
130049 ** argv[1] -> database name
130050 ** argv[2] -> table name
130051 ** argv[...] -> column names...
130053 static int rtreeInit(
130054 sqlite3 *db, /* Database connection */
130055 void *pAux, /* One of the RTREE_COORD_* constants */
130056 int argc, const char *const*argv, /* Parameters to CREATE TABLE statement */
130057 sqlite3_vtab **ppVtab, /* OUT: New virtual table */
130058 char **pzErr, /* OUT: Error message, if any */
130059 int isCreate /* True for xCreate, false for xConnect */
130061 int rc = SQLITE_OK;
130062 Rtree *pRtree;
130063 int nDb; /* Length of string argv[1] */
130064 int nName; /* Length of string argv[2] */
130065 int eCoordType = (pAux ? RTREE_COORD_INT32 : RTREE_COORD_REAL32);
130067 const char *aErrMsg[] = {
130068 0, /* 0 */
130069 "Wrong number of columns for an rtree table", /* 1 */
130070 "Too few columns for an rtree table", /* 2 */
130071 "Too many columns for an rtree table" /* 3 */
130074 int iErr = (argc<6) ? 2 : argc>(RTREE_MAX_DIMENSIONS*2+4) ? 3 : argc%2;
130075 if( aErrMsg[iErr] ){
130076 *pzErr = sqlite3_mprintf("%s", aErrMsg[iErr]);
130077 return SQLITE_ERROR;
130080 sqlite3_vtab_config(db, SQLITE_VTAB_CONSTRAINT_SUPPORT, 1);
130082 /* Allocate the sqlite3_vtab structure */
130083 nDb = strlen(argv[1]);
130084 nName = strlen(argv[2]);
130085 pRtree = (Rtree *)sqlite3_malloc(sizeof(Rtree)+nDb+nName+2);
130086 if( !pRtree ){
130087 return SQLITE_NOMEM;
130089 memset(pRtree, 0, sizeof(Rtree)+nDb+nName+2);
130090 pRtree->nBusy = 1;
130091 pRtree->base.pModule = &rtreeModule;
130092 pRtree->zDb = (char *)&pRtree[1];
130093 pRtree->zName = &pRtree->zDb[nDb+1];
130094 pRtree->nDim = (argc-4)/2;
130095 pRtree->nBytesPerCell = 8 + pRtree->nDim*4*2;
130096 pRtree->eCoordType = eCoordType;
130097 memcpy(pRtree->zDb, argv[1], nDb);
130098 memcpy(pRtree->zName, argv[2], nName);
130100 /* Figure out the node size to use. */
130101 rc = getNodeSize(db, pRtree, isCreate);
130103 /* Create/Connect to the underlying relational database schema. If
130104 ** that is successful, call sqlite3_declare_vtab() to configure
130105 ** the r-tree table schema.
130107 if( rc==SQLITE_OK ){
130108 if( (rc = rtreeSqlInit(pRtree, db, argv[1], argv[2], isCreate)) ){
130109 *pzErr = sqlite3_mprintf("%s", sqlite3_errmsg(db));
130110 }else{
130111 char *zSql = sqlite3_mprintf("CREATE TABLE x(%s", argv[3]);
130112 char *zTmp;
130113 int ii;
130114 for(ii=4; zSql && ii<argc; ii++){
130115 zTmp = zSql;
130116 zSql = sqlite3_mprintf("%s, %s", zTmp, argv[ii]);
130117 sqlite3_free(zTmp);
130119 if( zSql ){
130120 zTmp = zSql;
130121 zSql = sqlite3_mprintf("%s);", zTmp);
130122 sqlite3_free(zTmp);
130124 if( !zSql ){
130125 rc = SQLITE_NOMEM;
130126 }else if( SQLITE_OK!=(rc = sqlite3_declare_vtab(db, zSql)) ){
130127 *pzErr = sqlite3_mprintf("%s", sqlite3_errmsg(db));
130129 sqlite3_free(zSql);
130133 if( rc==SQLITE_OK ){
130134 *ppVtab = (sqlite3_vtab *)pRtree;
130135 }else{
130136 rtreeRelease(pRtree);
130138 return rc;
130143 ** Implementation of a scalar function that decodes r-tree nodes to
130144 ** human readable strings. This can be used for debugging and analysis.
130146 ** The scalar function takes two arguments, a blob of data containing
130147 ** an r-tree node, and the number of dimensions the r-tree indexes.
130148 ** For a two-dimensional r-tree structure called "rt", to deserialize
130149 ** all nodes, a statement like:
130151 ** SELECT rtreenode(2, data) FROM rt_node;
130153 ** The human readable string takes the form of a Tcl list with one
130154 ** entry for each cell in the r-tree node. Each entry is itself a
130155 ** list, containing the 8-byte rowid/pageno followed by the
130156 ** <num-dimension>*2 coordinates.
130158 static void rtreenode(sqlite3_context *ctx, int nArg, sqlite3_value **apArg){
130159 char *zText = 0;
130160 RtreeNode node;
130161 Rtree tree;
130162 int ii;
130164 UNUSED_PARAMETER(nArg);
130165 memset(&node, 0, sizeof(RtreeNode));
130166 memset(&tree, 0, sizeof(Rtree));
130167 tree.nDim = sqlite3_value_int(apArg[0]);
130168 tree.nBytesPerCell = 8 + 8 * tree.nDim;
130169 node.zData = (u8 *)sqlite3_value_blob(apArg[1]);
130171 for(ii=0; ii<NCELL(&node); ii++){
130172 char zCell[512];
130173 int nCell = 0;
130174 RtreeCell cell;
130175 int jj;
130177 nodeGetCell(&tree, &node, ii, &cell);
130178 sqlite3_snprintf(512-nCell,&zCell[nCell],"%lld", cell.iRowid);
130179 nCell = strlen(zCell);
130180 for(jj=0; jj<tree.nDim*2; jj++){
130181 sqlite3_snprintf(512-nCell,&zCell[nCell]," %f",(double)cell.aCoord[jj].f);
130182 nCell = strlen(zCell);
130185 if( zText ){
130186 char *zTextNew = sqlite3_mprintf("%s {%s}", zText, zCell);
130187 sqlite3_free(zText);
130188 zText = zTextNew;
130189 }else{
130190 zText = sqlite3_mprintf("{%s}", zCell);
130194 sqlite3_result_text(ctx, zText, -1, sqlite3_free);
130197 static void rtreedepth(sqlite3_context *ctx, int nArg, sqlite3_value **apArg){
130198 UNUSED_PARAMETER(nArg);
130199 if( sqlite3_value_type(apArg[0])!=SQLITE_BLOB
130200 || sqlite3_value_bytes(apArg[0])<2
130202 sqlite3_result_error(ctx, "Invalid argument to rtreedepth()", -1);
130203 }else{
130204 u8 *zBlob = (u8 *)sqlite3_value_blob(apArg[0]);
130205 sqlite3_result_int(ctx, readInt16(zBlob));
130210 ** Register the r-tree module with database handle db. This creates the
130211 ** virtual table module "rtree" and the debugging/analysis scalar
130212 ** function "rtreenode".
130214 SQLITE_PRIVATE int sqlite3RtreeInit(sqlite3 *db){
130215 const int utf8 = SQLITE_UTF8;
130216 int rc;
130218 rc = sqlite3_create_function(db, "rtreenode", 2, utf8, 0, rtreenode, 0, 0);
130219 if( rc==SQLITE_OK ){
130220 rc = sqlite3_create_function(db, "rtreedepth", 1, utf8, 0,rtreedepth, 0, 0);
130222 if( rc==SQLITE_OK ){
130223 void *c = (void *)RTREE_COORD_REAL32;
130224 rc = sqlite3_create_module_v2(db, "rtree", &rtreeModule, c, 0);
130226 if( rc==SQLITE_OK ){
130227 void *c = (void *)RTREE_COORD_INT32;
130228 rc = sqlite3_create_module_v2(db, "rtree_i32", &rtreeModule, c, 0);
130231 return rc;
130235 ** A version of sqlite3_free() that can be used as a callback. This is used
130236 ** in two places - as the destructor for the blob value returned by the
130237 ** invocation of a geometry function, and as the destructor for the geometry
130238 ** functions themselves.
130240 static void doSqlite3Free(void *p){
130241 sqlite3_free(p);
130245 ** Each call to sqlite3_rtree_geometry_callback() creates an ordinary SQLite
130246 ** scalar user function. This C function is the callback used for all such
130247 ** registered SQL functions.
130249 ** The scalar user functions return a blob that is interpreted by r-tree
130250 ** table MATCH operators.
130252 static void geomCallback(sqlite3_context *ctx, int nArg, sqlite3_value **aArg){
130253 RtreeGeomCallback *pGeomCtx = (RtreeGeomCallback *)sqlite3_user_data(ctx);
130254 RtreeMatchArg *pBlob;
130255 int nBlob;
130257 nBlob = sizeof(RtreeMatchArg) + (nArg-1)*sizeof(double);
130258 pBlob = (RtreeMatchArg *)sqlite3_malloc(nBlob);
130259 if( !pBlob ){
130260 sqlite3_result_error_nomem(ctx);
130261 }else{
130262 int i;
130263 pBlob->magic = RTREE_GEOMETRY_MAGIC;
130264 pBlob->xGeom = pGeomCtx->xGeom;
130265 pBlob->pContext = pGeomCtx->pContext;
130266 pBlob->nParam = nArg;
130267 for(i=0; i<nArg; i++){
130268 pBlob->aParam[i] = sqlite3_value_double(aArg[i]);
130270 sqlite3_result_blob(ctx, pBlob, nBlob, doSqlite3Free);
130275 ** Register a new geometry function for use with the r-tree MATCH operator.
130277 SQLITE_API int sqlite3_rtree_geometry_callback(
130278 sqlite3 *db,
130279 const char *zGeom,
130280 int (*xGeom)(sqlite3_rtree_geometry *, int, double *, int *),
130281 void *pContext
130283 RtreeGeomCallback *pGeomCtx; /* Context object for new user-function */
130285 /* Allocate and populate the context object. */
130286 pGeomCtx = (RtreeGeomCallback *)sqlite3_malloc(sizeof(RtreeGeomCallback));
130287 if( !pGeomCtx ) return SQLITE_NOMEM;
130288 pGeomCtx->xGeom = xGeom;
130289 pGeomCtx->pContext = pContext;
130291 /* Create the new user-function. Register a destructor function to delete
130292 ** the context object when it is no longer required. */
130293 return sqlite3_create_function_v2(db, zGeom, -1, SQLITE_ANY,
130294 (void *)pGeomCtx, geomCallback, 0, 0, doSqlite3Free
130298 #if !SQLITE_CORE
130299 SQLITE_API int sqlite3_extension_init(
130300 sqlite3 *db,
130301 char **pzErrMsg,
130302 const sqlite3_api_routines *pApi
130304 SQLITE_EXTENSION_INIT2(pApi)
130305 return sqlite3RtreeInit(db);
130307 #endif
130309 #endif
130311 /************** End of rtree.c ***********************************************/
130312 /************** Begin file icu.c *********************************************/
130314 ** 2007 May 6
130316 ** The author disclaims copyright to this source code. In place of
130317 ** a legal notice, here is a blessing:
130319 ** May you do good and not evil.
130320 ** May you find forgiveness for yourself and forgive others.
130321 ** May you share freely, never taking more than you give.
130323 *************************************************************************
130324 ** $Id: icu.c,v 1.7 2007/12/13 21:54:11 drh Exp $
130326 ** This file implements an integration between the ICU library
130327 ** ("International Components for Unicode", an open-source library
130328 ** for handling unicode data) and SQLite. The integration uses
130329 ** ICU to provide the following to SQLite:
130331 ** * An implementation of the SQL regexp() function (and hence REGEXP
130332 ** operator) using the ICU uregex_XX() APIs.
130334 ** * Implementations of the SQL scalar upper() and lower() functions
130335 ** for case mapping.
130337 ** * Integration of ICU and SQLite collation seqences.
130339 ** * An implementation of the LIKE operator that uses ICU to
130340 ** provide case-independent matching.
130343 #if !defined(SQLITE_CORE) || defined(SQLITE_ENABLE_ICU)
130345 /* Include ICU headers */
130346 #include <unicode/utypes.h>
130347 #include <unicode/uregex.h>
130348 #include <unicode/ustring.h>
130349 #include <unicode/ucol.h>
130351 /* #include <assert.h> */
130353 #ifndef SQLITE_CORE
130354 SQLITE_EXTENSION_INIT1
130355 #else
130356 #endif
130359 ** Maximum length (in bytes) of the pattern in a LIKE or GLOB
130360 ** operator.
130362 #ifndef SQLITE_MAX_LIKE_PATTERN_LENGTH
130363 # define SQLITE_MAX_LIKE_PATTERN_LENGTH 50000
130364 #endif
130367 ** Version of sqlite3_free() that is always a function, never a macro.
130369 static void xFree(void *p){
130370 sqlite3_free(p);
130374 ** Compare two UTF-8 strings for equality where the first string is
130375 ** a "LIKE" expression. Return true (1) if they are the same and
130376 ** false (0) if they are different.
130378 static int icuLikeCompare(
130379 const uint8_t *zPattern, /* LIKE pattern */
130380 const uint8_t *zString, /* The UTF-8 string to compare against */
130381 const UChar32 uEsc /* The escape character */
130383 static const int MATCH_ONE = (UChar32)'_';
130384 static const int MATCH_ALL = (UChar32)'%';
130386 int iPattern = 0; /* Current byte index in zPattern */
130387 int iString = 0; /* Current byte index in zString */
130389 int prevEscape = 0; /* True if the previous character was uEsc */
130391 while( zPattern[iPattern]!=0 ){
130393 /* Read (and consume) the next character from the input pattern. */
130394 UChar32 uPattern;
130395 U8_NEXT_UNSAFE(zPattern, iPattern, uPattern);
130396 assert(uPattern!=0);
130398 /* There are now 4 possibilities:
130400 ** 1. uPattern is an unescaped match-all character "%",
130401 ** 2. uPattern is an unescaped match-one character "_",
130402 ** 3. uPattern is an unescaped escape character, or
130403 ** 4. uPattern is to be handled as an ordinary character
130405 if( !prevEscape && uPattern==MATCH_ALL ){
130406 /* Case 1. */
130407 uint8_t c;
130409 /* Skip any MATCH_ALL or MATCH_ONE characters that follow a
130410 ** MATCH_ALL. For each MATCH_ONE, skip one character in the
130411 ** test string.
130413 while( (c=zPattern[iPattern]) == MATCH_ALL || c == MATCH_ONE ){
130414 if( c==MATCH_ONE ){
130415 if( zString[iString]==0 ) return 0;
130416 U8_FWD_1_UNSAFE(zString, iString);
130418 iPattern++;
130421 if( zPattern[iPattern]==0 ) return 1;
130423 while( zString[iString] ){
130424 if( icuLikeCompare(&zPattern[iPattern], &zString[iString], uEsc) ){
130425 return 1;
130427 U8_FWD_1_UNSAFE(zString, iString);
130429 return 0;
130431 }else if( !prevEscape && uPattern==MATCH_ONE ){
130432 /* Case 2. */
130433 if( zString[iString]==0 ) return 0;
130434 U8_FWD_1_UNSAFE(zString, iString);
130436 }else if( !prevEscape && uPattern==uEsc){
130437 /* Case 3. */
130438 prevEscape = 1;
130440 }else{
130441 /* Case 4. */
130442 UChar32 uString;
130443 U8_NEXT_UNSAFE(zString, iString, uString);
130444 uString = u_foldCase(uString, U_FOLD_CASE_DEFAULT);
130445 uPattern = u_foldCase(uPattern, U_FOLD_CASE_DEFAULT);
130446 if( uString!=uPattern ){
130447 return 0;
130449 prevEscape = 0;
130453 return zString[iString]==0;
130457 ** Implementation of the like() SQL function. This function implements
130458 ** the build-in LIKE operator. The first argument to the function is the
130459 ** pattern and the second argument is the string. So, the SQL statements:
130461 ** A LIKE B
130463 ** is implemented as like(B, A). If there is an escape character E,
130465 ** A LIKE B ESCAPE E
130467 ** is mapped to like(B, A, E).
130469 static void icuLikeFunc(
130470 sqlite3_context *context,
130471 int argc,
130472 sqlite3_value **argv
130474 const unsigned char *zA = sqlite3_value_text(argv[0]);
130475 const unsigned char *zB = sqlite3_value_text(argv[1]);
130476 UChar32 uEsc = 0;
130478 /* Limit the length of the LIKE or GLOB pattern to avoid problems
130479 ** of deep recursion and N*N behavior in patternCompare().
130481 if( sqlite3_value_bytes(argv[0])>SQLITE_MAX_LIKE_PATTERN_LENGTH ){
130482 sqlite3_result_error(context, "LIKE or GLOB pattern too complex", -1);
130483 return;
130487 if( argc==3 ){
130488 /* The escape character string must consist of a single UTF-8 character.
130489 ** Otherwise, return an error.
130491 int nE= sqlite3_value_bytes(argv[2]);
130492 const unsigned char *zE = sqlite3_value_text(argv[2]);
130493 int i = 0;
130494 if( zE==0 ) return;
130495 U8_NEXT(zE, i, nE, uEsc);
130496 if( i!=nE){
130497 sqlite3_result_error(context,
130498 "ESCAPE expression must be a single character", -1);
130499 return;
130503 if( zA && zB ){
130504 sqlite3_result_int(context, icuLikeCompare(zA, zB, uEsc));
130509 ** This function is called when an ICU function called from within
130510 ** the implementation of an SQL scalar function returns an error.
130512 ** The scalar function context passed as the first argument is
130513 ** loaded with an error message based on the following two args.
130515 static void icuFunctionError(
130516 sqlite3_context *pCtx, /* SQLite scalar function context */
130517 const char *zName, /* Name of ICU function that failed */
130518 UErrorCode e /* Error code returned by ICU function */
130520 char zBuf[128];
130521 sqlite3_snprintf(128, zBuf, "ICU error: %s(): %s", zName, u_errorName(e));
130522 zBuf[127] = '\0';
130523 sqlite3_result_error(pCtx, zBuf, -1);
130527 ** Function to delete compiled regexp objects. Registered as
130528 ** a destructor function with sqlite3_set_auxdata().
130530 static void icuRegexpDelete(void *p){
130531 URegularExpression *pExpr = (URegularExpression *)p;
130532 uregex_close(pExpr);
130536 ** Implementation of SQLite REGEXP operator. This scalar function takes
130537 ** two arguments. The first is a regular expression pattern to compile
130538 ** the second is a string to match against that pattern. If either
130539 ** argument is an SQL NULL, then NULL Is returned. Otherwise, the result
130540 ** is 1 if the string matches the pattern, or 0 otherwise.
130542 ** SQLite maps the regexp() function to the regexp() operator such
130543 ** that the following two are equivalent:
130545 ** zString REGEXP zPattern
130546 ** regexp(zPattern, zString)
130548 ** Uses the following ICU regexp APIs:
130550 ** uregex_open()
130551 ** uregex_matches()
130552 ** uregex_close()
130554 static void icuRegexpFunc(sqlite3_context *p, int nArg, sqlite3_value **apArg){
130555 UErrorCode status = U_ZERO_ERROR;
130556 URegularExpression *pExpr;
130557 UBool res;
130558 const UChar *zString = sqlite3_value_text16(apArg[1]);
130560 (void)nArg; /* Unused parameter */
130562 /* If the left hand side of the regexp operator is NULL,
130563 ** then the result is also NULL.
130565 if( !zString ){
130566 return;
130569 pExpr = sqlite3_get_auxdata(p, 0);
130570 if( !pExpr ){
130571 const UChar *zPattern = sqlite3_value_text16(apArg[0]);
130572 if( !zPattern ){
130573 return;
130575 pExpr = uregex_open(zPattern, -1, 0, 0, &status);
130577 if( U_SUCCESS(status) ){
130578 sqlite3_set_auxdata(p, 0, pExpr, icuRegexpDelete);
130579 }else{
130580 assert(!pExpr);
130581 icuFunctionError(p, "uregex_open", status);
130582 return;
130586 /* Configure the text that the regular expression operates on. */
130587 uregex_setText(pExpr, zString, -1, &status);
130588 if( !U_SUCCESS(status) ){
130589 icuFunctionError(p, "uregex_setText", status);
130590 return;
130593 /* Attempt the match */
130594 res = uregex_matches(pExpr, 0, &status);
130595 if( !U_SUCCESS(status) ){
130596 icuFunctionError(p, "uregex_matches", status);
130597 return;
130600 /* Set the text that the regular expression operates on to a NULL
130601 ** pointer. This is not really necessary, but it is tidier than
130602 ** leaving the regular expression object configured with an invalid
130603 ** pointer after this function returns.
130605 uregex_setText(pExpr, 0, 0, &status);
130607 /* Return 1 or 0. */
130608 sqlite3_result_int(p, res ? 1 : 0);
130612 ** Implementations of scalar functions for case mapping - upper() and
130613 ** lower(). Function upper() converts its input to upper-case (ABC).
130614 ** Function lower() converts to lower-case (abc).
130616 ** ICU provides two types of case mapping, "general" case mapping and
130617 ** "language specific". Refer to ICU documentation for the differences
130618 ** between the two.
130620 ** To utilise "general" case mapping, the upper() or lower() scalar
130621 ** functions are invoked with one argument:
130623 ** upper('ABC') -> 'abc'
130624 ** lower('abc') -> 'ABC'
130626 ** To access ICU "language specific" case mapping, upper() or lower()
130627 ** should be invoked with two arguments. The second argument is the name
130628 ** of the locale to use. Passing an empty string ("") or SQL NULL value
130629 ** as the second argument is the same as invoking the 1 argument version
130630 ** of upper() or lower().
130632 ** lower('I', 'en_us') -> 'i'
130633 ** lower('I', 'tr_tr') -> 'ı' (small dotless i)
130635 ** http://www.icu-project.org/userguide/posix.html#case_mappings
130637 static void icuCaseFunc16(sqlite3_context *p, int nArg, sqlite3_value **apArg){
130638 const UChar *zInput;
130639 UChar *zOutput;
130640 int nInput;
130641 int nOutput;
130643 UErrorCode status = U_ZERO_ERROR;
130644 const char *zLocale = 0;
130646 assert(nArg==1 || nArg==2);
130647 if( nArg==2 ){
130648 zLocale = (const char *)sqlite3_value_text(apArg[1]);
130651 zInput = sqlite3_value_text16(apArg[0]);
130652 if( !zInput ){
130653 return;
130655 nInput = sqlite3_value_bytes16(apArg[0]);
130657 nOutput = nInput * 2 + 2;
130658 zOutput = sqlite3_malloc(nOutput);
130659 if( !zOutput ){
130660 return;
130663 if( sqlite3_user_data(p) ){
130664 u_strToUpper(zOutput, nOutput/2, zInput, nInput/2, zLocale, &status);
130665 }else{
130666 u_strToLower(zOutput, nOutput/2, zInput, nInput/2, zLocale, &status);
130669 if( !U_SUCCESS(status) ){
130670 icuFunctionError(p, "u_strToLower()/u_strToUpper", status);
130671 return;
130674 sqlite3_result_text16(p, zOutput, -1, xFree);
130678 ** Collation sequence destructor function. The pCtx argument points to
130679 ** a UCollator structure previously allocated using ucol_open().
130681 static void icuCollationDel(void *pCtx){
130682 UCollator *p = (UCollator *)pCtx;
130683 ucol_close(p);
130687 ** Collation sequence comparison function. The pCtx argument points to
130688 ** a UCollator structure previously allocated using ucol_open().
130690 static int icuCollationColl(
130691 void *pCtx,
130692 int nLeft,
130693 const void *zLeft,
130694 int nRight,
130695 const void *zRight
130697 UCollationResult res;
130698 UCollator *p = (UCollator *)pCtx;
130699 res = ucol_strcoll(p, (UChar *)zLeft, nLeft/2, (UChar *)zRight, nRight/2);
130700 switch( res ){
130701 case UCOL_LESS: return -1;
130702 case UCOL_GREATER: return +1;
130703 case UCOL_EQUAL: return 0;
130705 assert(!"Unexpected return value from ucol_strcoll()");
130706 return 0;
130710 ** Implementation of the scalar function icu_load_collation().
130712 ** This scalar function is used to add ICU collation based collation
130713 ** types to an SQLite database connection. It is intended to be called
130714 ** as follows:
130716 ** SELECT icu_load_collation(<locale>, <collation-name>);
130718 ** Where <locale> is a string containing an ICU locale identifier (i.e.
130719 ** "en_AU", "tr_TR" etc.) and <collation-name> is the name of the
130720 ** collation sequence to create.
130722 static void icuLoadCollation(
130723 sqlite3_context *p,
130724 int nArg,
130725 sqlite3_value **apArg
130727 sqlite3 *db = (sqlite3 *)sqlite3_user_data(p);
130728 UErrorCode status = U_ZERO_ERROR;
130729 const char *zLocale; /* Locale identifier - (eg. "jp_JP") */
130730 const char *zName; /* SQL Collation sequence name (eg. "japanese") */
130731 UCollator *pUCollator; /* ICU library collation object */
130732 int rc; /* Return code from sqlite3_create_collation_x() */
130734 assert(nArg==2);
130735 zLocale = (const char *)sqlite3_value_text(apArg[0]);
130736 zName = (const char *)sqlite3_value_text(apArg[1]);
130738 if( !zLocale || !zName ){
130739 return;
130742 pUCollator = ucol_open(zLocale, &status);
130743 if( !U_SUCCESS(status) ){
130744 icuFunctionError(p, "ucol_open", status);
130745 return;
130747 assert(p);
130749 rc = sqlite3_create_collation_v2(db, zName, SQLITE_UTF16, (void *)pUCollator,
130750 icuCollationColl, icuCollationDel
130752 if( rc!=SQLITE_OK ){
130753 ucol_close(pUCollator);
130754 sqlite3_result_error(p, "Error registering collation function", -1);
130759 ** Register the ICU extension functions with database db.
130761 SQLITE_PRIVATE int sqlite3IcuInit(sqlite3 *db){
130762 struct IcuScalar {
130763 const char *zName; /* Function name */
130764 int nArg; /* Number of arguments */
130765 int enc; /* Optimal text encoding */
130766 void *pContext; /* sqlite3_user_data() context */
130767 void (*xFunc)(sqlite3_context*,int,sqlite3_value**);
130768 } scalars[] = {
130769 {"regexp", 2, SQLITE_ANY, 0, icuRegexpFunc},
130771 {"lower", 1, SQLITE_UTF16, 0, icuCaseFunc16},
130772 {"lower", 2, SQLITE_UTF16, 0, icuCaseFunc16},
130773 {"upper", 1, SQLITE_UTF16, (void*)1, icuCaseFunc16},
130774 {"upper", 2, SQLITE_UTF16, (void*)1, icuCaseFunc16},
130776 {"lower", 1, SQLITE_UTF8, 0, icuCaseFunc16},
130777 {"lower", 2, SQLITE_UTF8, 0, icuCaseFunc16},
130778 {"upper", 1, SQLITE_UTF8, (void*)1, icuCaseFunc16},
130779 {"upper", 2, SQLITE_UTF8, (void*)1, icuCaseFunc16},
130781 {"like", 2, SQLITE_UTF8, 0, icuLikeFunc},
130782 {"like", 3, SQLITE_UTF8, 0, icuLikeFunc},
130784 {"icu_load_collation", 2, SQLITE_UTF8, (void*)db, icuLoadCollation},
130787 int rc = SQLITE_OK;
130788 int i;
130790 for(i=0; rc==SQLITE_OK && i<(int)(sizeof(scalars)/sizeof(scalars[0])); i++){
130791 struct IcuScalar *p = &scalars[i];
130792 rc = sqlite3_create_function(
130793 db, p->zName, p->nArg, p->enc, p->pContext, p->xFunc, 0, 0
130797 return rc;
130800 #if !SQLITE_CORE
130801 SQLITE_API int sqlite3_extension_init(
130802 sqlite3 *db,
130803 char **pzErrMsg,
130804 const sqlite3_api_routines *pApi
130806 SQLITE_EXTENSION_INIT2(pApi)
130807 return sqlite3IcuInit(db);
130809 #endif
130811 #endif
130813 /************** End of icu.c *************************************************/
130814 /************** Begin file fts3_icu.c ****************************************/
130816 ** 2007 June 22
130818 ** The author disclaims copyright to this source code. In place of
130819 ** a legal notice, here is a blessing:
130821 ** May you do good and not evil.
130822 ** May you find forgiveness for yourself and forgive others.
130823 ** May you share freely, never taking more than you give.
130825 *************************************************************************
130826 ** This file implements a tokenizer for fts3 based on the ICU library.
130828 #if !defined(SQLITE_CORE) || defined(SQLITE_ENABLE_FTS3)
130829 #ifdef SQLITE_ENABLE_ICU
130831 /* #include <assert.h> */
130832 /* #include <string.h> */
130834 #include <unicode/ubrk.h>
130835 /* #include <unicode/ucol.h> */
130836 /* #include <unicode/ustring.h> */
130837 #include <unicode/utf16.h>
130839 typedef struct IcuTokenizer IcuTokenizer;
130840 typedef struct IcuCursor IcuCursor;
130842 struct IcuTokenizer {
130843 sqlite3_tokenizer base;
130844 char *zLocale;
130847 struct IcuCursor {
130848 sqlite3_tokenizer_cursor base;
130850 UBreakIterator *pIter; /* ICU break-iterator object */
130851 int nChar; /* Number of UChar elements in pInput */
130852 UChar *aChar; /* Copy of input using utf-16 encoding */
130853 int *aOffset; /* Offsets of each character in utf-8 input */
130855 int nBuffer;
130856 char *zBuffer;
130858 int iToken;
130862 ** Create a new tokenizer instance.
130864 static int icuCreate(
130865 int argc, /* Number of entries in argv[] */
130866 const char * const *argv, /* Tokenizer creation arguments */
130867 sqlite3_tokenizer **ppTokenizer /* OUT: Created tokenizer */
130869 IcuTokenizer *p;
130870 int n = 0;
130872 if( argc>0 ){
130873 n = strlen(argv[0])+1;
130875 p = (IcuTokenizer *)sqlite3_malloc(sizeof(IcuTokenizer)+n);
130876 if( !p ){
130877 return SQLITE_NOMEM;
130879 memset(p, 0, sizeof(IcuTokenizer));
130881 if( n ){
130882 p->zLocale = (char *)&p[1];
130883 memcpy(p->zLocale, argv[0], n);
130886 *ppTokenizer = (sqlite3_tokenizer *)p;
130888 return SQLITE_OK;
130892 ** Destroy a tokenizer
130894 static int icuDestroy(sqlite3_tokenizer *pTokenizer){
130895 IcuTokenizer *p = (IcuTokenizer *)pTokenizer;
130896 sqlite3_free(p);
130897 return SQLITE_OK;
130901 ** Prepare to begin tokenizing a particular string. The input
130902 ** string to be tokenized is pInput[0..nBytes-1]. A cursor
130903 ** used to incrementally tokenize this string is returned in
130904 ** *ppCursor.
130906 static int icuOpen(
130907 sqlite3_tokenizer *pTokenizer, /* The tokenizer */
130908 const char *zInput, /* Input string */
130909 int nInput, /* Length of zInput in bytes */
130910 sqlite3_tokenizer_cursor **ppCursor /* OUT: Tokenization cursor */
130912 IcuTokenizer *p = (IcuTokenizer *)pTokenizer;
130913 IcuCursor *pCsr;
130915 const int32_t opt = U_FOLD_CASE_DEFAULT;
130916 UErrorCode status = U_ZERO_ERROR;
130917 int nChar;
130919 UChar32 c;
130920 int iInput = 0;
130921 int iOut = 0;
130923 *ppCursor = 0;
130925 if( nInput<0 ){
130926 nInput = strlen(zInput);
130928 nChar = nInput+1;
130929 pCsr = (IcuCursor *)sqlite3_malloc(
130930 sizeof(IcuCursor) + /* IcuCursor */
130931 nChar * sizeof(UChar) + /* IcuCursor.aChar[] */
130932 (nChar+1) * sizeof(int) /* IcuCursor.aOffset[] */
130934 if( !pCsr ){
130935 return SQLITE_NOMEM;
130937 memset(pCsr, 0, sizeof(IcuCursor));
130938 pCsr->aChar = (UChar *)&pCsr[1];
130939 pCsr->aOffset = (int *)&pCsr->aChar[nChar];
130941 pCsr->aOffset[iOut] = iInput;
130942 U8_NEXT(zInput, iInput, nInput, c);
130943 while( c>0 ){
130944 int isError = 0;
130945 c = u_foldCase(c, opt);
130946 U16_APPEND(pCsr->aChar, iOut, nChar, c, isError);
130947 if( isError ){
130948 sqlite3_free(pCsr);
130949 return SQLITE_ERROR;
130951 pCsr->aOffset[iOut] = iInput;
130953 if( iInput<nInput ){
130954 U8_NEXT(zInput, iInput, nInput, c);
130955 }else{
130956 c = 0;
130960 pCsr->pIter = ubrk_open(UBRK_WORD, p->zLocale, pCsr->aChar, iOut, &status);
130961 if( !U_SUCCESS(status) ){
130962 sqlite3_free(pCsr);
130963 return SQLITE_ERROR;
130965 pCsr->nChar = iOut;
130967 ubrk_first(pCsr->pIter);
130968 *ppCursor = (sqlite3_tokenizer_cursor *)pCsr;
130969 return SQLITE_OK;
130973 ** Close a tokenization cursor previously opened by a call to icuOpen().
130975 static int icuClose(sqlite3_tokenizer_cursor *pCursor){
130976 IcuCursor *pCsr = (IcuCursor *)pCursor;
130977 ubrk_close(pCsr->pIter);
130978 sqlite3_free(pCsr->zBuffer);
130979 sqlite3_free(pCsr);
130980 return SQLITE_OK;
130984 ** Extract the next token from a tokenization cursor.
130986 static int icuNext(
130987 sqlite3_tokenizer_cursor *pCursor, /* Cursor returned by simpleOpen */
130988 const char **ppToken, /* OUT: *ppToken is the token text */
130989 int *pnBytes, /* OUT: Number of bytes in token */
130990 int *piStartOffset, /* OUT: Starting offset of token */
130991 int *piEndOffset, /* OUT: Ending offset of token */
130992 int *piPosition /* OUT: Position integer of token */
130994 IcuCursor *pCsr = (IcuCursor *)pCursor;
130996 int iStart = 0;
130997 int iEnd = 0;
130998 int nByte = 0;
131000 while( iStart==iEnd ){
131001 UChar32 c;
131003 iStart = ubrk_current(pCsr->pIter);
131004 iEnd = ubrk_next(pCsr->pIter);
131005 if( iEnd==UBRK_DONE ){
131006 return SQLITE_DONE;
131009 while( iStart<iEnd ){
131010 int iWhite = iStart;
131011 U8_NEXT(pCsr->aChar, iWhite, pCsr->nChar, c);
131012 if( u_isspace(c) ){
131013 iStart = iWhite;
131014 }else{
131015 break;
131018 assert(iStart<=iEnd);
131022 UErrorCode status = U_ZERO_ERROR;
131023 if( nByte ){
131024 char *zNew = sqlite3_realloc(pCsr->zBuffer, nByte);
131025 if( !zNew ){
131026 return SQLITE_NOMEM;
131028 pCsr->zBuffer = zNew;
131029 pCsr->nBuffer = nByte;
131032 u_strToUTF8(
131033 pCsr->zBuffer, pCsr->nBuffer, &nByte, /* Output vars */
131034 &pCsr->aChar[iStart], iEnd-iStart, /* Input vars */
131035 &status /* Output success/failure */
131037 } while( nByte>pCsr->nBuffer );
131039 *ppToken = pCsr->zBuffer;
131040 *pnBytes = nByte;
131041 *piStartOffset = pCsr->aOffset[iStart];
131042 *piEndOffset = pCsr->aOffset[iEnd];
131043 *piPosition = pCsr->iToken++;
131045 return SQLITE_OK;
131049 ** The set of routines that implement the simple tokenizer
131051 static const sqlite3_tokenizer_module icuTokenizerModule = {
131052 0, /* iVersion */
131053 icuCreate, /* xCreate */
131054 icuDestroy, /* xCreate */
131055 icuOpen, /* xOpen */
131056 icuClose, /* xClose */
131057 icuNext, /* xNext */
131061 ** Set *ppModule to point at the implementation of the ICU tokenizer.
131063 SQLITE_PRIVATE void sqlite3Fts3IcuTokenizerModule(
131064 sqlite3_tokenizer_module const**ppModule
131066 *ppModule = &icuTokenizerModule;
131069 #endif /* defined(SQLITE_ENABLE_ICU) */
131070 #endif /* !defined(SQLITE_CORE) || defined(SQLITE_ENABLE_FTS3) */
131072 /************** End of fts3_icu.c ********************************************/