Ensure that sqlite3AuthRead() is only call for TK_COLUMN and TK_TRIGGER
[sqlite.git] / src / btree.c
bloba73896e1610e48a28d10e8b1c6c66676a2423869
1 /*
2 ** 2004 April 6
3 **
4 ** The author disclaims copyright to this source code. In place of
5 ** a legal notice, here is a blessing:
6 **
7 ** May you do good and not evil.
8 ** May you find forgiveness for yourself and forgive others.
9 ** May you share freely, never taking more than you give.
11 *************************************************************************
12 ** This file implements an external (disk-based) database using BTrees.
13 ** See the header comment on "btreeInt.h" for additional information.
14 ** Including a description of file format and an overview of operation.
16 #include "btreeInt.h"
19 ** The header string that appears at the beginning of every
20 ** SQLite database.
22 static const char zMagicHeader[] = SQLITE_FILE_HEADER;
25 ** Set this global variable to 1 to enable tracing using the TRACE
26 ** macro.
28 #if 0
29 int sqlite3BtreeTrace=1; /* True to enable tracing */
30 # define TRACE(X) if(sqlite3BtreeTrace){printf X;fflush(stdout);}
31 #else
32 # define TRACE(X)
33 #endif
36 ** Extract a 2-byte big-endian integer from an array of unsigned bytes.
37 ** But if the value is zero, make it 65536.
39 ** This routine is used to extract the "offset to cell content area" value
40 ** from the header of a btree page. If the page size is 65536 and the page
41 ** is empty, the offset should be 65536, but the 2-byte value stores zero.
42 ** This routine makes the necessary adjustment to 65536.
44 #define get2byteNotZero(X) (((((int)get2byte(X))-1)&0xffff)+1)
47 ** Values passed as the 5th argument to allocateBtreePage()
49 #define BTALLOC_ANY 0 /* Allocate any page */
50 #define BTALLOC_EXACT 1 /* Allocate exact page if possible */
51 #define BTALLOC_LE 2 /* Allocate any page <= the parameter */
54 ** Macro IfNotOmitAV(x) returns (x) if SQLITE_OMIT_AUTOVACUUM is not
55 ** defined, or 0 if it is. For example:
57 ** bIncrVacuum = IfNotOmitAV(pBtShared->incrVacuum);
59 #ifndef SQLITE_OMIT_AUTOVACUUM
60 #define IfNotOmitAV(expr) (expr)
61 #else
62 #define IfNotOmitAV(expr) 0
63 #endif
65 #ifndef SQLITE_OMIT_SHARED_CACHE
67 ** A list of BtShared objects that are eligible for participation
68 ** in shared cache. This variable has file scope during normal builds,
69 ** but the test harness needs to access it so we make it global for
70 ** test builds.
72 ** Access to this variable is protected by SQLITE_MUTEX_STATIC_MASTER.
74 #ifdef SQLITE_TEST
75 BtShared *SQLITE_WSD sqlite3SharedCacheList = 0;
76 #else
77 static BtShared *SQLITE_WSD sqlite3SharedCacheList = 0;
78 #endif
79 #endif /* SQLITE_OMIT_SHARED_CACHE */
81 #ifndef SQLITE_OMIT_SHARED_CACHE
83 ** Enable or disable the shared pager and schema features.
85 ** This routine has no effect on existing database connections.
86 ** The shared cache setting effects only future calls to
87 ** sqlite3_open(), sqlite3_open16(), or sqlite3_open_v2().
89 int sqlite3_enable_shared_cache(int enable){
90 sqlite3GlobalConfig.sharedCacheEnabled = enable;
91 return SQLITE_OK;
93 #endif
97 #ifdef SQLITE_OMIT_SHARED_CACHE
99 ** The functions querySharedCacheTableLock(), setSharedCacheTableLock(),
100 ** and clearAllSharedCacheTableLocks()
101 ** manipulate entries in the BtShared.pLock linked list used to store
102 ** shared-cache table level locks. If the library is compiled with the
103 ** shared-cache feature disabled, then there is only ever one user
104 ** of each BtShared structure and so this locking is not necessary.
105 ** So define the lock related functions as no-ops.
107 #define querySharedCacheTableLock(a,b,c) SQLITE_OK
108 #define setSharedCacheTableLock(a,b,c) SQLITE_OK
109 #define clearAllSharedCacheTableLocks(a)
110 #define downgradeAllSharedCacheTableLocks(a)
111 #define hasSharedCacheTableLock(a,b,c,d) 1
112 #define hasReadConflicts(a, b) 0
113 #endif
116 ** Implementation of the SQLITE_CORRUPT_PAGE() macro. Takes a single
117 ** (MemPage*) as an argument. The (MemPage*) must not be NULL.
119 ** If SQLITE_DEBUG is not defined, then this macro is equivalent to
120 ** SQLITE_CORRUPT_BKPT. Or, if SQLITE_DEBUG is set, then the log message
121 ** normally produced as a side-effect of SQLITE_CORRUPT_BKPT is augmented
122 ** with the page number and filename associated with the (MemPage*).
124 #ifdef SQLITE_DEBUG
125 int corruptPageError(int lineno, MemPage *p){
126 char *zMsg;
127 sqlite3BeginBenignMalloc();
128 zMsg = sqlite3_mprintf("database corruption page %d of %s",
129 (int)p->pgno, sqlite3PagerFilename(p->pBt->pPager, 0)
131 sqlite3EndBenignMalloc();
132 if( zMsg ){
133 sqlite3ReportError(SQLITE_CORRUPT, lineno, zMsg);
135 sqlite3_free(zMsg);
136 return SQLITE_CORRUPT_BKPT;
138 # define SQLITE_CORRUPT_PAGE(pMemPage) corruptPageError(__LINE__, pMemPage)
139 #else
140 # define SQLITE_CORRUPT_PAGE(pMemPage) SQLITE_CORRUPT_PGNO(pMemPage->pgno)
141 #endif
143 #ifndef SQLITE_OMIT_SHARED_CACHE
145 #ifdef SQLITE_DEBUG
147 **** This function is only used as part of an assert() statement. ***
149 ** Check to see if pBtree holds the required locks to read or write to the
150 ** table with root page iRoot. Return 1 if it does and 0 if not.
152 ** For example, when writing to a table with root-page iRoot via
153 ** Btree connection pBtree:
155 ** assert( hasSharedCacheTableLock(pBtree, iRoot, 0, WRITE_LOCK) );
157 ** When writing to an index that resides in a sharable database, the
158 ** caller should have first obtained a lock specifying the root page of
159 ** the corresponding table. This makes things a bit more complicated,
160 ** as this module treats each table as a separate structure. To determine
161 ** the table corresponding to the index being written, this
162 ** function has to search through the database schema.
164 ** Instead of a lock on the table/index rooted at page iRoot, the caller may
165 ** hold a write-lock on the schema table (root page 1). This is also
166 ** acceptable.
168 static int hasSharedCacheTableLock(
169 Btree *pBtree, /* Handle that must hold lock */
170 Pgno iRoot, /* Root page of b-tree */
171 int isIndex, /* True if iRoot is the root of an index b-tree */
172 int eLockType /* Required lock type (READ_LOCK or WRITE_LOCK) */
174 Schema *pSchema = (Schema *)pBtree->pBt->pSchema;
175 Pgno iTab = 0;
176 BtLock *pLock;
178 /* If this database is not shareable, or if the client is reading
179 ** and has the read-uncommitted flag set, then no lock is required.
180 ** Return true immediately.
182 if( (pBtree->sharable==0)
183 || (eLockType==READ_LOCK && (pBtree->db->flags & SQLITE_ReadUncommit))
185 return 1;
188 /* If the client is reading or writing an index and the schema is
189 ** not loaded, then it is too difficult to actually check to see if
190 ** the correct locks are held. So do not bother - just return true.
191 ** This case does not come up very often anyhow.
193 if( isIndex && (!pSchema || (pSchema->schemaFlags&DB_SchemaLoaded)==0) ){
194 return 1;
197 /* Figure out the root-page that the lock should be held on. For table
198 ** b-trees, this is just the root page of the b-tree being read or
199 ** written. For index b-trees, it is the root page of the associated
200 ** table. */
201 if( isIndex ){
202 HashElem *p;
203 for(p=sqliteHashFirst(&pSchema->idxHash); p; p=sqliteHashNext(p)){
204 Index *pIdx = (Index *)sqliteHashData(p);
205 if( pIdx->tnum==(int)iRoot ){
206 if( iTab ){
207 /* Two or more indexes share the same root page. There must
208 ** be imposter tables. So just return true. The assert is not
209 ** useful in that case. */
210 return 1;
212 iTab = pIdx->pTable->tnum;
215 }else{
216 iTab = iRoot;
219 /* Search for the required lock. Either a write-lock on root-page iTab, a
220 ** write-lock on the schema table, or (if the client is reading) a
221 ** read-lock on iTab will suffice. Return 1 if any of these are found. */
222 for(pLock=pBtree->pBt->pLock; pLock; pLock=pLock->pNext){
223 if( pLock->pBtree==pBtree
224 && (pLock->iTable==iTab || (pLock->eLock==WRITE_LOCK && pLock->iTable==1))
225 && pLock->eLock>=eLockType
227 return 1;
231 /* Failed to find the required lock. */
232 return 0;
234 #endif /* SQLITE_DEBUG */
236 #ifdef SQLITE_DEBUG
238 **** This function may be used as part of assert() statements only. ****
240 ** Return true if it would be illegal for pBtree to write into the
241 ** table or index rooted at iRoot because other shared connections are
242 ** simultaneously reading that same table or index.
244 ** It is illegal for pBtree to write if some other Btree object that
245 ** shares the same BtShared object is currently reading or writing
246 ** the iRoot table. Except, if the other Btree object has the
247 ** read-uncommitted flag set, then it is OK for the other object to
248 ** have a read cursor.
250 ** For example, before writing to any part of the table or index
251 ** rooted at page iRoot, one should call:
253 ** assert( !hasReadConflicts(pBtree, iRoot) );
255 static int hasReadConflicts(Btree *pBtree, Pgno iRoot){
256 BtCursor *p;
257 for(p=pBtree->pBt->pCursor; p; p=p->pNext){
258 if( p->pgnoRoot==iRoot
259 && p->pBtree!=pBtree
260 && 0==(p->pBtree->db->flags & SQLITE_ReadUncommit)
262 return 1;
265 return 0;
267 #endif /* #ifdef SQLITE_DEBUG */
270 ** Query to see if Btree handle p may obtain a lock of type eLock
271 ** (READ_LOCK or WRITE_LOCK) on the table with root-page iTab. Return
272 ** SQLITE_OK if the lock may be obtained (by calling
273 ** setSharedCacheTableLock()), or SQLITE_LOCKED if not.
275 static int querySharedCacheTableLock(Btree *p, Pgno iTab, u8 eLock){
276 BtShared *pBt = p->pBt;
277 BtLock *pIter;
279 assert( sqlite3BtreeHoldsMutex(p) );
280 assert( eLock==READ_LOCK || eLock==WRITE_LOCK );
281 assert( p->db!=0 );
282 assert( !(p->db->flags&SQLITE_ReadUncommit)||eLock==WRITE_LOCK||iTab==1 );
284 /* If requesting a write-lock, then the Btree must have an open write
285 ** transaction on this file. And, obviously, for this to be so there
286 ** must be an open write transaction on the file itself.
288 assert( eLock==READ_LOCK || (p==pBt->pWriter && p->inTrans==TRANS_WRITE) );
289 assert( eLock==READ_LOCK || pBt->inTransaction==TRANS_WRITE );
291 /* This routine is a no-op if the shared-cache is not enabled */
292 if( !p->sharable ){
293 return SQLITE_OK;
296 /* If some other connection is holding an exclusive lock, the
297 ** requested lock may not be obtained.
299 if( pBt->pWriter!=p && (pBt->btsFlags & BTS_EXCLUSIVE)!=0 ){
300 sqlite3ConnectionBlocked(p->db, pBt->pWriter->db);
301 return SQLITE_LOCKED_SHAREDCACHE;
304 for(pIter=pBt->pLock; pIter; pIter=pIter->pNext){
305 /* The condition (pIter->eLock!=eLock) in the following if(...)
306 ** statement is a simplification of:
308 ** (eLock==WRITE_LOCK || pIter->eLock==WRITE_LOCK)
310 ** since we know that if eLock==WRITE_LOCK, then no other connection
311 ** may hold a WRITE_LOCK on any table in this file (since there can
312 ** only be a single writer).
314 assert( pIter->eLock==READ_LOCK || pIter->eLock==WRITE_LOCK );
315 assert( eLock==READ_LOCK || pIter->pBtree==p || pIter->eLock==READ_LOCK);
316 if( pIter->pBtree!=p && pIter->iTable==iTab && pIter->eLock!=eLock ){
317 sqlite3ConnectionBlocked(p->db, pIter->pBtree->db);
318 if( eLock==WRITE_LOCK ){
319 assert( p==pBt->pWriter );
320 pBt->btsFlags |= BTS_PENDING;
322 return SQLITE_LOCKED_SHAREDCACHE;
325 return SQLITE_OK;
327 #endif /* !SQLITE_OMIT_SHARED_CACHE */
329 #ifndef SQLITE_OMIT_SHARED_CACHE
331 ** Add a lock on the table with root-page iTable to the shared-btree used
332 ** by Btree handle p. Parameter eLock must be either READ_LOCK or
333 ** WRITE_LOCK.
335 ** This function assumes the following:
337 ** (a) The specified Btree object p is connected to a sharable
338 ** database (one with the BtShared.sharable flag set), and
340 ** (b) No other Btree objects hold a lock that conflicts
341 ** with the requested lock (i.e. querySharedCacheTableLock() has
342 ** already been called and returned SQLITE_OK).
344 ** SQLITE_OK is returned if the lock is added successfully. SQLITE_NOMEM
345 ** is returned if a malloc attempt fails.
347 static int setSharedCacheTableLock(Btree *p, Pgno iTable, u8 eLock){
348 BtShared *pBt = p->pBt;
349 BtLock *pLock = 0;
350 BtLock *pIter;
352 assert( sqlite3BtreeHoldsMutex(p) );
353 assert( eLock==READ_LOCK || eLock==WRITE_LOCK );
354 assert( p->db!=0 );
356 /* A connection with the read-uncommitted flag set will never try to
357 ** obtain a read-lock using this function. The only read-lock obtained
358 ** by a connection in read-uncommitted mode is on the sqlite_master
359 ** table, and that lock is obtained in BtreeBeginTrans(). */
360 assert( 0==(p->db->flags&SQLITE_ReadUncommit) || eLock==WRITE_LOCK );
362 /* This function should only be called on a sharable b-tree after it
363 ** has been determined that no other b-tree holds a conflicting lock. */
364 assert( p->sharable );
365 assert( SQLITE_OK==querySharedCacheTableLock(p, iTable, eLock) );
367 /* First search the list for an existing lock on this table. */
368 for(pIter=pBt->pLock; pIter; pIter=pIter->pNext){
369 if( pIter->iTable==iTable && pIter->pBtree==p ){
370 pLock = pIter;
371 break;
375 /* If the above search did not find a BtLock struct associating Btree p
376 ** with table iTable, allocate one and link it into the list.
378 if( !pLock ){
379 pLock = (BtLock *)sqlite3MallocZero(sizeof(BtLock));
380 if( !pLock ){
381 return SQLITE_NOMEM_BKPT;
383 pLock->iTable = iTable;
384 pLock->pBtree = p;
385 pLock->pNext = pBt->pLock;
386 pBt->pLock = pLock;
389 /* Set the BtLock.eLock variable to the maximum of the current lock
390 ** and the requested lock. This means if a write-lock was already held
391 ** and a read-lock requested, we don't incorrectly downgrade the lock.
393 assert( WRITE_LOCK>READ_LOCK );
394 if( eLock>pLock->eLock ){
395 pLock->eLock = eLock;
398 return SQLITE_OK;
400 #endif /* !SQLITE_OMIT_SHARED_CACHE */
402 #ifndef SQLITE_OMIT_SHARED_CACHE
404 ** Release all the table locks (locks obtained via calls to
405 ** the setSharedCacheTableLock() procedure) held by Btree object p.
407 ** This function assumes that Btree p has an open read or write
408 ** transaction. If it does not, then the BTS_PENDING flag
409 ** may be incorrectly cleared.
411 static void clearAllSharedCacheTableLocks(Btree *p){
412 BtShared *pBt = p->pBt;
413 BtLock **ppIter = &pBt->pLock;
415 assert( sqlite3BtreeHoldsMutex(p) );
416 assert( p->sharable || 0==*ppIter );
417 assert( p->inTrans>0 );
419 while( *ppIter ){
420 BtLock *pLock = *ppIter;
421 assert( (pBt->btsFlags & BTS_EXCLUSIVE)==0 || pBt->pWriter==pLock->pBtree );
422 assert( pLock->pBtree->inTrans>=pLock->eLock );
423 if( pLock->pBtree==p ){
424 *ppIter = pLock->pNext;
425 assert( pLock->iTable!=1 || pLock==&p->lock );
426 if( pLock->iTable!=1 ){
427 sqlite3_free(pLock);
429 }else{
430 ppIter = &pLock->pNext;
434 assert( (pBt->btsFlags & BTS_PENDING)==0 || pBt->pWriter );
435 if( pBt->pWriter==p ){
436 pBt->pWriter = 0;
437 pBt->btsFlags &= ~(BTS_EXCLUSIVE|BTS_PENDING);
438 }else if( pBt->nTransaction==2 ){
439 /* This function is called when Btree p is concluding its
440 ** transaction. If there currently exists a writer, and p is not
441 ** that writer, then the number of locks held by connections other
442 ** than the writer must be about to drop to zero. In this case
443 ** set the BTS_PENDING flag to 0.
445 ** If there is not currently a writer, then BTS_PENDING must
446 ** be zero already. So this next line is harmless in that case.
448 pBt->btsFlags &= ~BTS_PENDING;
453 ** This function changes all write-locks held by Btree p into read-locks.
455 static void downgradeAllSharedCacheTableLocks(Btree *p){
456 BtShared *pBt = p->pBt;
457 if( pBt->pWriter==p ){
458 BtLock *pLock;
459 pBt->pWriter = 0;
460 pBt->btsFlags &= ~(BTS_EXCLUSIVE|BTS_PENDING);
461 for(pLock=pBt->pLock; pLock; pLock=pLock->pNext){
462 assert( pLock->eLock==READ_LOCK || pLock->pBtree==p );
463 pLock->eLock = READ_LOCK;
468 #endif /* SQLITE_OMIT_SHARED_CACHE */
470 static void releasePage(MemPage *pPage); /* Forward reference */
471 static void releasePageOne(MemPage *pPage); /* Forward reference */
472 static void releasePageNotNull(MemPage *pPage); /* Forward reference */
475 ***** This routine is used inside of assert() only ****
477 ** Verify that the cursor holds the mutex on its BtShared
479 #ifdef SQLITE_DEBUG
480 static int cursorHoldsMutex(BtCursor *p){
481 return sqlite3_mutex_held(p->pBt->mutex);
484 /* Verify that the cursor and the BtShared agree about what is the current
485 ** database connetion. This is important in shared-cache mode. If the database
486 ** connection pointers get out-of-sync, it is possible for routines like
487 ** btreeInitPage() to reference an stale connection pointer that references a
488 ** a connection that has already closed. This routine is used inside assert()
489 ** statements only and for the purpose of double-checking that the btree code
490 ** does keep the database connection pointers up-to-date.
492 static int cursorOwnsBtShared(BtCursor *p){
493 assert( cursorHoldsMutex(p) );
494 return (p->pBtree->db==p->pBt->db);
496 #endif
499 ** Invalidate the overflow cache of the cursor passed as the first argument.
500 ** on the shared btree structure pBt.
502 #define invalidateOverflowCache(pCur) (pCur->curFlags &= ~BTCF_ValidOvfl)
505 ** Invalidate the overflow page-list cache for all cursors opened
506 ** on the shared btree structure pBt.
508 static void invalidateAllOverflowCache(BtShared *pBt){
509 BtCursor *p;
510 assert( sqlite3_mutex_held(pBt->mutex) );
511 for(p=pBt->pCursor; p; p=p->pNext){
512 invalidateOverflowCache(p);
516 #ifndef SQLITE_OMIT_INCRBLOB
518 ** This function is called before modifying the contents of a table
519 ** to invalidate any incrblob cursors that are open on the
520 ** row or one of the rows being modified.
522 ** If argument isClearTable is true, then the entire contents of the
523 ** table is about to be deleted. In this case invalidate all incrblob
524 ** cursors open on any row within the table with root-page pgnoRoot.
526 ** Otherwise, if argument isClearTable is false, then the row with
527 ** rowid iRow is being replaced or deleted. In this case invalidate
528 ** only those incrblob cursors open on that specific row.
530 static void invalidateIncrblobCursors(
531 Btree *pBtree, /* The database file to check */
532 Pgno pgnoRoot, /* The table that might be changing */
533 i64 iRow, /* The rowid that might be changing */
534 int isClearTable /* True if all rows are being deleted */
536 BtCursor *p;
537 if( pBtree->hasIncrblobCur==0 ) return;
538 assert( sqlite3BtreeHoldsMutex(pBtree) );
539 pBtree->hasIncrblobCur = 0;
540 for(p=pBtree->pBt->pCursor; p; p=p->pNext){
541 if( (p->curFlags & BTCF_Incrblob)!=0 ){
542 pBtree->hasIncrblobCur = 1;
543 if( p->pgnoRoot==pgnoRoot && (isClearTable || p->info.nKey==iRow) ){
544 p->eState = CURSOR_INVALID;
550 #else
551 /* Stub function when INCRBLOB is omitted */
552 #define invalidateIncrblobCursors(w,x,y,z)
553 #endif /* SQLITE_OMIT_INCRBLOB */
556 ** Set bit pgno of the BtShared.pHasContent bitvec. This is called
557 ** when a page that previously contained data becomes a free-list leaf
558 ** page.
560 ** The BtShared.pHasContent bitvec exists to work around an obscure
561 ** bug caused by the interaction of two useful IO optimizations surrounding
562 ** free-list leaf pages:
564 ** 1) When all data is deleted from a page and the page becomes
565 ** a free-list leaf page, the page is not written to the database
566 ** (as free-list leaf pages contain no meaningful data). Sometimes
567 ** such a page is not even journalled (as it will not be modified,
568 ** why bother journalling it?).
570 ** 2) When a free-list leaf page is reused, its content is not read
571 ** from the database or written to the journal file (why should it
572 ** be, if it is not at all meaningful?).
574 ** By themselves, these optimizations work fine and provide a handy
575 ** performance boost to bulk delete or insert operations. However, if
576 ** a page is moved to the free-list and then reused within the same
577 ** transaction, a problem comes up. If the page is not journalled when
578 ** it is moved to the free-list and it is also not journalled when it
579 ** is extracted from the free-list and reused, then the original data
580 ** may be lost. In the event of a rollback, it may not be possible
581 ** to restore the database to its original configuration.
583 ** The solution is the BtShared.pHasContent bitvec. Whenever a page is
584 ** moved to become a free-list leaf page, the corresponding bit is
585 ** set in the bitvec. Whenever a leaf page is extracted from the free-list,
586 ** optimization 2 above is omitted if the corresponding bit is already
587 ** set in BtShared.pHasContent. The contents of the bitvec are cleared
588 ** at the end of every transaction.
590 static int btreeSetHasContent(BtShared *pBt, Pgno pgno){
591 int rc = SQLITE_OK;
592 if( !pBt->pHasContent ){
593 assert( pgno<=pBt->nPage );
594 pBt->pHasContent = sqlite3BitvecCreate(pBt->nPage);
595 if( !pBt->pHasContent ){
596 rc = SQLITE_NOMEM_BKPT;
599 if( rc==SQLITE_OK && pgno<=sqlite3BitvecSize(pBt->pHasContent) ){
600 rc = sqlite3BitvecSet(pBt->pHasContent, pgno);
602 return rc;
606 ** Query the BtShared.pHasContent vector.
608 ** This function is called when a free-list leaf page is removed from the
609 ** free-list for reuse. It returns false if it is safe to retrieve the
610 ** page from the pager layer with the 'no-content' flag set. True otherwise.
612 static int btreeGetHasContent(BtShared *pBt, Pgno pgno){
613 Bitvec *p = pBt->pHasContent;
614 return (p && (pgno>sqlite3BitvecSize(p) || sqlite3BitvecTest(p, pgno)));
618 ** Clear (destroy) the BtShared.pHasContent bitvec. This should be
619 ** invoked at the conclusion of each write-transaction.
621 static void btreeClearHasContent(BtShared *pBt){
622 sqlite3BitvecDestroy(pBt->pHasContent);
623 pBt->pHasContent = 0;
627 ** Release all of the apPage[] pages for a cursor.
629 static void btreeReleaseAllCursorPages(BtCursor *pCur){
630 int i;
631 if( pCur->iPage>=0 ){
632 for(i=0; i<pCur->iPage; i++){
633 releasePageNotNull(pCur->apPage[i]);
635 releasePageNotNull(pCur->pPage);
636 pCur->iPage = -1;
641 ** The cursor passed as the only argument must point to a valid entry
642 ** when this function is called (i.e. have eState==CURSOR_VALID). This
643 ** function saves the current cursor key in variables pCur->nKey and
644 ** pCur->pKey. SQLITE_OK is returned if successful or an SQLite error
645 ** code otherwise.
647 ** If the cursor is open on an intkey table, then the integer key
648 ** (the rowid) is stored in pCur->nKey and pCur->pKey is left set to
649 ** NULL. If the cursor is open on a non-intkey table, then pCur->pKey is
650 ** set to point to a malloced buffer pCur->nKey bytes in size containing
651 ** the key.
653 static int saveCursorKey(BtCursor *pCur){
654 int rc = SQLITE_OK;
655 assert( CURSOR_VALID==pCur->eState );
656 assert( 0==pCur->pKey );
657 assert( cursorHoldsMutex(pCur) );
659 if( pCur->curIntKey ){
660 /* Only the rowid is required for a table btree */
661 pCur->nKey = sqlite3BtreeIntegerKey(pCur);
662 }else{
663 /* For an index btree, save the complete key content */
664 void *pKey;
665 pCur->nKey = sqlite3BtreePayloadSize(pCur);
666 pKey = sqlite3Malloc( pCur->nKey );
667 if( pKey ){
668 rc = sqlite3BtreePayload(pCur, 0, (int)pCur->nKey, pKey);
669 if( rc==SQLITE_OK ){
670 pCur->pKey = pKey;
671 }else{
672 sqlite3_free(pKey);
674 }else{
675 rc = SQLITE_NOMEM_BKPT;
678 assert( !pCur->curIntKey || !pCur->pKey );
679 return rc;
683 ** Save the current cursor position in the variables BtCursor.nKey
684 ** and BtCursor.pKey. The cursor's state is set to CURSOR_REQUIRESEEK.
686 ** The caller must ensure that the cursor is valid (has eState==CURSOR_VALID)
687 ** prior to calling this routine.
689 static int saveCursorPosition(BtCursor *pCur){
690 int rc;
692 assert( CURSOR_VALID==pCur->eState || CURSOR_SKIPNEXT==pCur->eState );
693 assert( 0==pCur->pKey );
694 assert( cursorHoldsMutex(pCur) );
696 if( pCur->eState==CURSOR_SKIPNEXT ){
697 pCur->eState = CURSOR_VALID;
698 }else{
699 pCur->skipNext = 0;
702 rc = saveCursorKey(pCur);
703 if( rc==SQLITE_OK ){
704 btreeReleaseAllCursorPages(pCur);
705 pCur->eState = CURSOR_REQUIRESEEK;
708 pCur->curFlags &= ~(BTCF_ValidNKey|BTCF_ValidOvfl|BTCF_AtLast);
709 return rc;
712 /* Forward reference */
713 static int SQLITE_NOINLINE saveCursorsOnList(BtCursor*,Pgno,BtCursor*);
716 ** Save the positions of all cursors (except pExcept) that are open on
717 ** the table with root-page iRoot. "Saving the cursor position" means that
718 ** the location in the btree is remembered in such a way that it can be
719 ** moved back to the same spot after the btree has been modified. This
720 ** routine is called just before cursor pExcept is used to modify the
721 ** table, for example in BtreeDelete() or BtreeInsert().
723 ** If there are two or more cursors on the same btree, then all such
724 ** cursors should have their BTCF_Multiple flag set. The btreeCursor()
725 ** routine enforces that rule. This routine only needs to be called in
726 ** the uncommon case when pExpect has the BTCF_Multiple flag set.
728 ** If pExpect!=NULL and if no other cursors are found on the same root-page,
729 ** then the BTCF_Multiple flag on pExpect is cleared, to avoid another
730 ** pointless call to this routine.
732 ** Implementation note: This routine merely checks to see if any cursors
733 ** need to be saved. It calls out to saveCursorsOnList() in the (unusual)
734 ** event that cursors are in need to being saved.
736 static int saveAllCursors(BtShared *pBt, Pgno iRoot, BtCursor *pExcept){
737 BtCursor *p;
738 assert( sqlite3_mutex_held(pBt->mutex) );
739 assert( pExcept==0 || pExcept->pBt==pBt );
740 for(p=pBt->pCursor; p; p=p->pNext){
741 if( p!=pExcept && (0==iRoot || p->pgnoRoot==iRoot) ) break;
743 if( p ) return saveCursorsOnList(p, iRoot, pExcept);
744 if( pExcept ) pExcept->curFlags &= ~BTCF_Multiple;
745 return SQLITE_OK;
748 /* This helper routine to saveAllCursors does the actual work of saving
749 ** the cursors if and when a cursor is found that actually requires saving.
750 ** The common case is that no cursors need to be saved, so this routine is
751 ** broken out from its caller to avoid unnecessary stack pointer movement.
753 static int SQLITE_NOINLINE saveCursorsOnList(
754 BtCursor *p, /* The first cursor that needs saving */
755 Pgno iRoot, /* Only save cursor with this iRoot. Save all if zero */
756 BtCursor *pExcept /* Do not save this cursor */
759 if( p!=pExcept && (0==iRoot || p->pgnoRoot==iRoot) ){
760 if( p->eState==CURSOR_VALID || p->eState==CURSOR_SKIPNEXT ){
761 int rc = saveCursorPosition(p);
762 if( SQLITE_OK!=rc ){
763 return rc;
765 }else{
766 testcase( p->iPage>=0 );
767 btreeReleaseAllCursorPages(p);
770 p = p->pNext;
771 }while( p );
772 return SQLITE_OK;
776 ** Clear the current cursor position.
778 void sqlite3BtreeClearCursor(BtCursor *pCur){
779 assert( cursorHoldsMutex(pCur) );
780 sqlite3_free(pCur->pKey);
781 pCur->pKey = 0;
782 pCur->eState = CURSOR_INVALID;
786 ** In this version of BtreeMoveto, pKey is a packed index record
787 ** such as is generated by the OP_MakeRecord opcode. Unpack the
788 ** record and then call BtreeMovetoUnpacked() to do the work.
790 static int btreeMoveto(
791 BtCursor *pCur, /* Cursor open on the btree to be searched */
792 const void *pKey, /* Packed key if the btree is an index */
793 i64 nKey, /* Integer key for tables. Size of pKey for indices */
794 int bias, /* Bias search to the high end */
795 int *pRes /* Write search results here */
797 int rc; /* Status code */
798 UnpackedRecord *pIdxKey; /* Unpacked index key */
800 if( pKey ){
801 assert( nKey==(i64)(int)nKey );
802 pIdxKey = sqlite3VdbeAllocUnpackedRecord(pCur->pKeyInfo);
803 if( pIdxKey==0 ) return SQLITE_NOMEM_BKPT;
804 sqlite3VdbeRecordUnpack(pCur->pKeyInfo, (int)nKey, pKey, pIdxKey);
805 if( pIdxKey->nField==0 ){
806 rc = SQLITE_CORRUPT_BKPT;
807 goto moveto_done;
809 }else{
810 pIdxKey = 0;
812 rc = sqlite3BtreeMovetoUnpacked(pCur, pIdxKey, nKey, bias, pRes);
813 moveto_done:
814 if( pIdxKey ){
815 sqlite3DbFree(pCur->pKeyInfo->db, pIdxKey);
817 return rc;
821 ** Restore the cursor to the position it was in (or as close to as possible)
822 ** when saveCursorPosition() was called. Note that this call deletes the
823 ** saved position info stored by saveCursorPosition(), so there can be
824 ** at most one effective restoreCursorPosition() call after each
825 ** saveCursorPosition().
827 static int btreeRestoreCursorPosition(BtCursor *pCur){
828 int rc;
829 int skipNext;
830 assert( cursorOwnsBtShared(pCur) );
831 assert( pCur->eState>=CURSOR_REQUIRESEEK );
832 if( pCur->eState==CURSOR_FAULT ){
833 return pCur->skipNext;
835 pCur->eState = CURSOR_INVALID;
836 rc = btreeMoveto(pCur, pCur->pKey, pCur->nKey, 0, &skipNext);
837 if( rc==SQLITE_OK ){
838 sqlite3_free(pCur->pKey);
839 pCur->pKey = 0;
840 assert( pCur->eState==CURSOR_VALID || pCur->eState==CURSOR_INVALID );
841 pCur->skipNext |= skipNext;
842 if( pCur->skipNext && pCur->eState==CURSOR_VALID ){
843 pCur->eState = CURSOR_SKIPNEXT;
846 return rc;
849 #define restoreCursorPosition(p) \
850 (p->eState>=CURSOR_REQUIRESEEK ? \
851 btreeRestoreCursorPosition(p) : \
852 SQLITE_OK)
855 ** Determine whether or not a cursor has moved from the position where
856 ** it was last placed, or has been invalidated for any other reason.
857 ** Cursors can move when the row they are pointing at is deleted out
858 ** from under them, for example. Cursor might also move if a btree
859 ** is rebalanced.
861 ** Calling this routine with a NULL cursor pointer returns false.
863 ** Use the separate sqlite3BtreeCursorRestore() routine to restore a cursor
864 ** back to where it ought to be if this routine returns true.
866 int sqlite3BtreeCursorHasMoved(BtCursor *pCur){
867 return pCur->eState!=CURSOR_VALID;
871 ** Return a pointer to a fake BtCursor object that will always answer
872 ** false to the sqlite3BtreeCursorHasMoved() routine above. The fake
873 ** cursor returned must not be used with any other Btree interface.
875 BtCursor *sqlite3BtreeFakeValidCursor(void){
876 static u8 fakeCursor = CURSOR_VALID;
877 assert( offsetof(BtCursor, eState)==0 );
878 return (BtCursor*)&fakeCursor;
882 ** This routine restores a cursor back to its original position after it
883 ** has been moved by some outside activity (such as a btree rebalance or
884 ** a row having been deleted out from under the cursor).
886 ** On success, the *pDifferentRow parameter is false if the cursor is left
887 ** pointing at exactly the same row. *pDifferntRow is the row the cursor
888 ** was pointing to has been deleted, forcing the cursor to point to some
889 ** nearby row.
891 ** This routine should only be called for a cursor that just returned
892 ** TRUE from sqlite3BtreeCursorHasMoved().
894 int sqlite3BtreeCursorRestore(BtCursor *pCur, int *pDifferentRow){
895 int rc;
897 assert( pCur!=0 );
898 assert( pCur->eState!=CURSOR_VALID );
899 rc = restoreCursorPosition(pCur);
900 if( rc ){
901 *pDifferentRow = 1;
902 return rc;
904 if( pCur->eState!=CURSOR_VALID ){
905 *pDifferentRow = 1;
906 }else{
907 assert( pCur->skipNext==0 );
908 *pDifferentRow = 0;
910 return SQLITE_OK;
913 #ifdef SQLITE_ENABLE_CURSOR_HINTS
915 ** Provide hints to the cursor. The particular hint given (and the type
916 ** and number of the varargs parameters) is determined by the eHintType
917 ** parameter. See the definitions of the BTREE_HINT_* macros for details.
919 void sqlite3BtreeCursorHint(BtCursor *pCur, int eHintType, ...){
920 /* Used only by system that substitute their own storage engine */
922 #endif
925 ** Provide flag hints to the cursor.
927 void sqlite3BtreeCursorHintFlags(BtCursor *pCur, unsigned x){
928 assert( x==BTREE_SEEK_EQ || x==BTREE_BULKLOAD || x==0 );
929 pCur->hints = x;
933 #ifndef SQLITE_OMIT_AUTOVACUUM
935 ** Given a page number of a regular database page, return the page
936 ** number for the pointer-map page that contains the entry for the
937 ** input page number.
939 ** Return 0 (not a valid page) for pgno==1 since there is
940 ** no pointer map associated with page 1. The integrity_check logic
941 ** requires that ptrmapPageno(*,1)!=1.
943 static Pgno ptrmapPageno(BtShared *pBt, Pgno pgno){
944 int nPagesPerMapPage;
945 Pgno iPtrMap, ret;
946 assert( sqlite3_mutex_held(pBt->mutex) );
947 if( pgno<2 ) return 0;
948 nPagesPerMapPage = (pBt->usableSize/5)+1;
949 iPtrMap = (pgno-2)/nPagesPerMapPage;
950 ret = (iPtrMap*nPagesPerMapPage) + 2;
951 if( ret==PENDING_BYTE_PAGE(pBt) ){
952 ret++;
954 return ret;
958 ** Write an entry into the pointer map.
960 ** This routine updates the pointer map entry for page number 'key'
961 ** so that it maps to type 'eType' and parent page number 'pgno'.
963 ** If *pRC is initially non-zero (non-SQLITE_OK) then this routine is
964 ** a no-op. If an error occurs, the appropriate error code is written
965 ** into *pRC.
967 static void ptrmapPut(BtShared *pBt, Pgno key, u8 eType, Pgno parent, int *pRC){
968 DbPage *pDbPage; /* The pointer map page */
969 u8 *pPtrmap; /* The pointer map data */
970 Pgno iPtrmap; /* The pointer map page number */
971 int offset; /* Offset in pointer map page */
972 int rc; /* Return code from subfunctions */
974 if( *pRC ) return;
976 assert( sqlite3_mutex_held(pBt->mutex) );
977 /* The master-journal page number must never be used as a pointer map page */
978 assert( 0==PTRMAP_ISPAGE(pBt, PENDING_BYTE_PAGE(pBt)) );
980 assert( pBt->autoVacuum );
981 if( key==0 ){
982 *pRC = SQLITE_CORRUPT_BKPT;
983 return;
985 iPtrmap = PTRMAP_PAGENO(pBt, key);
986 rc = sqlite3PagerGet(pBt->pPager, iPtrmap, &pDbPage, 0);
987 if( rc!=SQLITE_OK ){
988 *pRC = rc;
989 return;
991 offset = PTRMAP_PTROFFSET(iPtrmap, key);
992 if( offset<0 ){
993 *pRC = SQLITE_CORRUPT_BKPT;
994 goto ptrmap_exit;
996 assert( offset <= (int)pBt->usableSize-5 );
997 pPtrmap = (u8 *)sqlite3PagerGetData(pDbPage);
999 if( eType!=pPtrmap[offset] || get4byte(&pPtrmap[offset+1])!=parent ){
1000 TRACE(("PTRMAP_UPDATE: %d->(%d,%d)\n", key, eType, parent));
1001 *pRC= rc = sqlite3PagerWrite(pDbPage);
1002 if( rc==SQLITE_OK ){
1003 pPtrmap[offset] = eType;
1004 put4byte(&pPtrmap[offset+1], parent);
1008 ptrmap_exit:
1009 sqlite3PagerUnref(pDbPage);
1013 ** Read an entry from the pointer map.
1015 ** This routine retrieves the pointer map entry for page 'key', writing
1016 ** the type and parent page number to *pEType and *pPgno respectively.
1017 ** An error code is returned if something goes wrong, otherwise SQLITE_OK.
1019 static int ptrmapGet(BtShared *pBt, Pgno key, u8 *pEType, Pgno *pPgno){
1020 DbPage *pDbPage; /* The pointer map page */
1021 int iPtrmap; /* Pointer map page index */
1022 u8 *pPtrmap; /* Pointer map page data */
1023 int offset; /* Offset of entry in pointer map */
1024 int rc;
1026 assert( sqlite3_mutex_held(pBt->mutex) );
1028 iPtrmap = PTRMAP_PAGENO(pBt, key);
1029 rc = sqlite3PagerGet(pBt->pPager, iPtrmap, &pDbPage, 0);
1030 if( rc!=0 ){
1031 return rc;
1033 pPtrmap = (u8 *)sqlite3PagerGetData(pDbPage);
1035 offset = PTRMAP_PTROFFSET(iPtrmap, key);
1036 if( offset<0 ){
1037 sqlite3PagerUnref(pDbPage);
1038 return SQLITE_CORRUPT_BKPT;
1040 assert( offset <= (int)pBt->usableSize-5 );
1041 assert( pEType!=0 );
1042 *pEType = pPtrmap[offset];
1043 if( pPgno ) *pPgno = get4byte(&pPtrmap[offset+1]);
1045 sqlite3PagerUnref(pDbPage);
1046 if( *pEType<1 || *pEType>5 ) return SQLITE_CORRUPT_PGNO(iPtrmap);
1047 return SQLITE_OK;
1050 #else /* if defined SQLITE_OMIT_AUTOVACUUM */
1051 #define ptrmapPut(w,x,y,z,rc)
1052 #define ptrmapGet(w,x,y,z) SQLITE_OK
1053 #define ptrmapPutOvflPtr(x, y, rc)
1054 #endif
1057 ** Given a btree page and a cell index (0 means the first cell on
1058 ** the page, 1 means the second cell, and so forth) return a pointer
1059 ** to the cell content.
1061 ** findCellPastPtr() does the same except it skips past the initial
1062 ** 4-byte child pointer found on interior pages, if there is one.
1064 ** This routine works only for pages that do not contain overflow cells.
1066 #define findCell(P,I) \
1067 ((P)->aData + ((P)->maskPage & get2byteAligned(&(P)->aCellIdx[2*(I)])))
1068 #define findCellPastPtr(P,I) \
1069 ((P)->aDataOfst + ((P)->maskPage & get2byteAligned(&(P)->aCellIdx[2*(I)])))
1073 ** This is common tail processing for btreeParseCellPtr() and
1074 ** btreeParseCellPtrIndex() for the case when the cell does not fit entirely
1075 ** on a single B-tree page. Make necessary adjustments to the CellInfo
1076 ** structure.
1078 static SQLITE_NOINLINE void btreeParseCellAdjustSizeForOverflow(
1079 MemPage *pPage, /* Page containing the cell */
1080 u8 *pCell, /* Pointer to the cell text. */
1081 CellInfo *pInfo /* Fill in this structure */
1083 /* If the payload will not fit completely on the local page, we have
1084 ** to decide how much to store locally and how much to spill onto
1085 ** overflow pages. The strategy is to minimize the amount of unused
1086 ** space on overflow pages while keeping the amount of local storage
1087 ** in between minLocal and maxLocal.
1089 ** Warning: changing the way overflow payload is distributed in any
1090 ** way will result in an incompatible file format.
1092 int minLocal; /* Minimum amount of payload held locally */
1093 int maxLocal; /* Maximum amount of payload held locally */
1094 int surplus; /* Overflow payload available for local storage */
1096 minLocal = pPage->minLocal;
1097 maxLocal = pPage->maxLocal;
1098 surplus = minLocal + (pInfo->nPayload - minLocal)%(pPage->pBt->usableSize-4);
1099 testcase( surplus==maxLocal );
1100 testcase( surplus==maxLocal+1 );
1101 if( surplus <= maxLocal ){
1102 pInfo->nLocal = (u16)surplus;
1103 }else{
1104 pInfo->nLocal = (u16)minLocal;
1106 pInfo->nSize = (u16)(&pInfo->pPayload[pInfo->nLocal] - pCell) + 4;
1110 ** The following routines are implementations of the MemPage.xParseCell()
1111 ** method.
1113 ** Parse a cell content block and fill in the CellInfo structure.
1115 ** btreeParseCellPtr() => table btree leaf nodes
1116 ** btreeParseCellNoPayload() => table btree internal nodes
1117 ** btreeParseCellPtrIndex() => index btree nodes
1119 ** There is also a wrapper function btreeParseCell() that works for
1120 ** all MemPage types and that references the cell by index rather than
1121 ** by pointer.
1123 static void btreeParseCellPtrNoPayload(
1124 MemPage *pPage, /* Page containing the cell */
1125 u8 *pCell, /* Pointer to the cell text. */
1126 CellInfo *pInfo /* Fill in this structure */
1128 assert( sqlite3_mutex_held(pPage->pBt->mutex) );
1129 assert( pPage->leaf==0 );
1130 assert( pPage->childPtrSize==4 );
1131 #ifndef SQLITE_DEBUG
1132 UNUSED_PARAMETER(pPage);
1133 #endif
1134 pInfo->nSize = 4 + getVarint(&pCell[4], (u64*)&pInfo->nKey);
1135 pInfo->nPayload = 0;
1136 pInfo->nLocal = 0;
1137 pInfo->pPayload = 0;
1138 return;
1140 static void btreeParseCellPtr(
1141 MemPage *pPage, /* Page containing the cell */
1142 u8 *pCell, /* Pointer to the cell text. */
1143 CellInfo *pInfo /* Fill in this structure */
1145 u8 *pIter; /* For scanning through pCell */
1146 u32 nPayload; /* Number of bytes of cell payload */
1147 u64 iKey; /* Extracted Key value */
1149 assert( sqlite3_mutex_held(pPage->pBt->mutex) );
1150 assert( pPage->leaf==0 || pPage->leaf==1 );
1151 assert( pPage->intKeyLeaf );
1152 assert( pPage->childPtrSize==0 );
1153 pIter = pCell;
1155 /* The next block of code is equivalent to:
1157 ** pIter += getVarint32(pIter, nPayload);
1159 ** The code is inlined to avoid a function call.
1161 nPayload = *pIter;
1162 if( nPayload>=0x80 ){
1163 u8 *pEnd = &pIter[8];
1164 nPayload &= 0x7f;
1166 nPayload = (nPayload<<7) | (*++pIter & 0x7f);
1167 }while( (*pIter)>=0x80 && pIter<pEnd );
1169 pIter++;
1171 /* The next block of code is equivalent to:
1173 ** pIter += getVarint(pIter, (u64*)&pInfo->nKey);
1175 ** The code is inlined to avoid a function call.
1177 iKey = *pIter;
1178 if( iKey>=0x80 ){
1179 u8 *pEnd = &pIter[7];
1180 iKey &= 0x7f;
1181 while(1){
1182 iKey = (iKey<<7) | (*++pIter & 0x7f);
1183 if( (*pIter)<0x80 ) break;
1184 if( pIter>=pEnd ){
1185 iKey = (iKey<<8) | *++pIter;
1186 break;
1190 pIter++;
1192 pInfo->nKey = *(i64*)&iKey;
1193 pInfo->nPayload = nPayload;
1194 pInfo->pPayload = pIter;
1195 testcase( nPayload==pPage->maxLocal );
1196 testcase( nPayload==pPage->maxLocal+1 );
1197 if( nPayload<=pPage->maxLocal ){
1198 /* This is the (easy) common case where the entire payload fits
1199 ** on the local page. No overflow is required.
1201 pInfo->nSize = nPayload + (u16)(pIter - pCell);
1202 if( pInfo->nSize<4 ) pInfo->nSize = 4;
1203 pInfo->nLocal = (u16)nPayload;
1204 }else{
1205 btreeParseCellAdjustSizeForOverflow(pPage, pCell, pInfo);
1208 static void btreeParseCellPtrIndex(
1209 MemPage *pPage, /* Page containing the cell */
1210 u8 *pCell, /* Pointer to the cell text. */
1211 CellInfo *pInfo /* Fill in this structure */
1213 u8 *pIter; /* For scanning through pCell */
1214 u32 nPayload; /* Number of bytes of cell payload */
1216 assert( sqlite3_mutex_held(pPage->pBt->mutex) );
1217 assert( pPage->leaf==0 || pPage->leaf==1 );
1218 assert( pPage->intKeyLeaf==0 );
1219 pIter = pCell + pPage->childPtrSize;
1220 nPayload = *pIter;
1221 if( nPayload>=0x80 ){
1222 u8 *pEnd = &pIter[8];
1223 nPayload &= 0x7f;
1225 nPayload = (nPayload<<7) | (*++pIter & 0x7f);
1226 }while( *(pIter)>=0x80 && pIter<pEnd );
1228 pIter++;
1229 pInfo->nKey = nPayload;
1230 pInfo->nPayload = nPayload;
1231 pInfo->pPayload = pIter;
1232 testcase( nPayload==pPage->maxLocal );
1233 testcase( nPayload==pPage->maxLocal+1 );
1234 if( nPayload<=pPage->maxLocal ){
1235 /* This is the (easy) common case where the entire payload fits
1236 ** on the local page. No overflow is required.
1238 pInfo->nSize = nPayload + (u16)(pIter - pCell);
1239 if( pInfo->nSize<4 ) pInfo->nSize = 4;
1240 pInfo->nLocal = (u16)nPayload;
1241 }else{
1242 btreeParseCellAdjustSizeForOverflow(pPage, pCell, pInfo);
1245 static void btreeParseCell(
1246 MemPage *pPage, /* Page containing the cell */
1247 int iCell, /* The cell index. First cell is 0 */
1248 CellInfo *pInfo /* Fill in this structure */
1250 pPage->xParseCell(pPage, findCell(pPage, iCell), pInfo);
1254 ** The following routines are implementations of the MemPage.xCellSize
1255 ** method.
1257 ** Compute the total number of bytes that a Cell needs in the cell
1258 ** data area of the btree-page. The return number includes the cell
1259 ** data header and the local payload, but not any overflow page or
1260 ** the space used by the cell pointer.
1262 ** cellSizePtrNoPayload() => table internal nodes
1263 ** cellSizePtr() => all index nodes & table leaf nodes
1265 static u16 cellSizePtr(MemPage *pPage, u8 *pCell){
1266 u8 *pIter = pCell + pPage->childPtrSize; /* For looping over bytes of pCell */
1267 u8 *pEnd; /* End mark for a varint */
1268 u32 nSize; /* Size value to return */
1270 #ifdef SQLITE_DEBUG
1271 /* The value returned by this function should always be the same as
1272 ** the (CellInfo.nSize) value found by doing a full parse of the
1273 ** cell. If SQLITE_DEBUG is defined, an assert() at the bottom of
1274 ** this function verifies that this invariant is not violated. */
1275 CellInfo debuginfo;
1276 pPage->xParseCell(pPage, pCell, &debuginfo);
1277 #endif
1279 nSize = *pIter;
1280 if( nSize>=0x80 ){
1281 pEnd = &pIter[8];
1282 nSize &= 0x7f;
1284 nSize = (nSize<<7) | (*++pIter & 0x7f);
1285 }while( *(pIter)>=0x80 && pIter<pEnd );
1287 pIter++;
1288 if( pPage->intKey ){
1289 /* pIter now points at the 64-bit integer key value, a variable length
1290 ** integer. The following block moves pIter to point at the first byte
1291 ** past the end of the key value. */
1292 pEnd = &pIter[9];
1293 while( (*pIter++)&0x80 && pIter<pEnd );
1295 testcase( nSize==pPage->maxLocal );
1296 testcase( nSize==pPage->maxLocal+1 );
1297 if( nSize<=pPage->maxLocal ){
1298 nSize += (u32)(pIter - pCell);
1299 if( nSize<4 ) nSize = 4;
1300 }else{
1301 int minLocal = pPage->minLocal;
1302 nSize = minLocal + (nSize - minLocal) % (pPage->pBt->usableSize - 4);
1303 testcase( nSize==pPage->maxLocal );
1304 testcase( nSize==pPage->maxLocal+1 );
1305 if( nSize>pPage->maxLocal ){
1306 nSize = minLocal;
1308 nSize += 4 + (u16)(pIter - pCell);
1310 assert( nSize==debuginfo.nSize || CORRUPT_DB );
1311 return (u16)nSize;
1313 static u16 cellSizePtrNoPayload(MemPage *pPage, u8 *pCell){
1314 u8 *pIter = pCell + 4; /* For looping over bytes of pCell */
1315 u8 *pEnd; /* End mark for a varint */
1317 #ifdef SQLITE_DEBUG
1318 /* The value returned by this function should always be the same as
1319 ** the (CellInfo.nSize) value found by doing a full parse of the
1320 ** cell. If SQLITE_DEBUG is defined, an assert() at the bottom of
1321 ** this function verifies that this invariant is not violated. */
1322 CellInfo debuginfo;
1323 pPage->xParseCell(pPage, pCell, &debuginfo);
1324 #else
1325 UNUSED_PARAMETER(pPage);
1326 #endif
1328 assert( pPage->childPtrSize==4 );
1329 pEnd = pIter + 9;
1330 while( (*pIter++)&0x80 && pIter<pEnd );
1331 assert( debuginfo.nSize==(u16)(pIter - pCell) || CORRUPT_DB );
1332 return (u16)(pIter - pCell);
1336 #ifdef SQLITE_DEBUG
1337 /* This variation on cellSizePtr() is used inside of assert() statements
1338 ** only. */
1339 static u16 cellSize(MemPage *pPage, int iCell){
1340 return pPage->xCellSize(pPage, findCell(pPage, iCell));
1342 #endif
1344 #ifndef SQLITE_OMIT_AUTOVACUUM
1346 ** If the cell pCell, part of page pPage contains a pointer
1347 ** to an overflow page, insert an entry into the pointer-map
1348 ** for the overflow page.
1350 static void ptrmapPutOvflPtr(MemPage *pPage, u8 *pCell, int *pRC){
1351 CellInfo info;
1352 if( *pRC ) return;
1353 assert( pCell!=0 );
1354 pPage->xParseCell(pPage, pCell, &info);
1355 if( info.nLocal<info.nPayload ){
1356 Pgno ovfl = get4byte(&pCell[info.nSize-4]);
1357 ptrmapPut(pPage->pBt, ovfl, PTRMAP_OVERFLOW1, pPage->pgno, pRC);
1360 #endif
1364 ** Defragment the page given. This routine reorganizes cells within the
1365 ** page so that there are no free-blocks on the free-block list.
1367 ** Parameter nMaxFrag is the maximum amount of fragmented space that may be
1368 ** present in the page after this routine returns.
1370 ** EVIDENCE-OF: R-44582-60138 SQLite may from time to time reorganize a
1371 ** b-tree page so that there are no freeblocks or fragment bytes, all
1372 ** unused bytes are contained in the unallocated space region, and all
1373 ** cells are packed tightly at the end of the page.
1375 static int defragmentPage(MemPage *pPage, int nMaxFrag){
1376 int i; /* Loop counter */
1377 int pc; /* Address of the i-th cell */
1378 int hdr; /* Offset to the page header */
1379 int size; /* Size of a cell */
1380 int usableSize; /* Number of usable bytes on a page */
1381 int cellOffset; /* Offset to the cell pointer array */
1382 int cbrk; /* Offset to the cell content area */
1383 int nCell; /* Number of cells on the page */
1384 unsigned char *data; /* The page data */
1385 unsigned char *temp; /* Temp area for cell content */
1386 unsigned char *src; /* Source of content */
1387 int iCellFirst; /* First allowable cell index */
1388 int iCellLast; /* Last possible cell index */
1390 assert( sqlite3PagerIswriteable(pPage->pDbPage) );
1391 assert( pPage->pBt!=0 );
1392 assert( pPage->pBt->usableSize <= SQLITE_MAX_PAGE_SIZE );
1393 assert( pPage->nOverflow==0 );
1394 assert( sqlite3_mutex_held(pPage->pBt->mutex) );
1395 temp = 0;
1396 src = data = pPage->aData;
1397 hdr = pPage->hdrOffset;
1398 cellOffset = pPage->cellOffset;
1399 nCell = pPage->nCell;
1400 assert( nCell==get2byte(&data[hdr+3]) );
1401 iCellFirst = cellOffset + 2*nCell;
1402 usableSize = pPage->pBt->usableSize;
1404 /* This block handles pages with two or fewer free blocks and nMaxFrag
1405 ** or fewer fragmented bytes. In this case it is faster to move the
1406 ** two (or one) blocks of cells using memmove() and add the required
1407 ** offsets to each pointer in the cell-pointer array than it is to
1408 ** reconstruct the entire page. */
1409 if( (int)data[hdr+7]<=nMaxFrag ){
1410 int iFree = get2byte(&data[hdr+1]);
1411 if( iFree ){
1412 int iFree2 = get2byte(&data[iFree]);
1414 /* pageFindSlot() has already verified that free blocks are sorted
1415 ** in order of offset within the page, and that no block extends
1416 ** past the end of the page. Provided the two free slots do not
1417 ** overlap, this guarantees that the memmove() calls below will not
1418 ** overwrite the usableSize byte buffer, even if the database page
1419 ** is corrupt. */
1420 assert( iFree2==0 || iFree2>iFree );
1421 assert( iFree+get2byte(&data[iFree+2]) <= usableSize );
1422 assert( iFree2==0 || iFree2+get2byte(&data[iFree2+2]) <= usableSize );
1424 if( 0==iFree2 || (data[iFree2]==0 && data[iFree2+1]==0) ){
1425 u8 *pEnd = &data[cellOffset + nCell*2];
1426 u8 *pAddr;
1427 int sz2 = 0;
1428 int sz = get2byte(&data[iFree+2]);
1429 int top = get2byte(&data[hdr+5]);
1430 if( top>=iFree ){
1431 return SQLITE_CORRUPT_PAGE(pPage);
1433 if( iFree2 ){
1434 assert( iFree+sz<=iFree2 ); /* Verified by pageFindSlot() */
1435 sz2 = get2byte(&data[iFree2+2]);
1436 assert( iFree+sz+sz2+iFree2-(iFree+sz) <= usableSize );
1437 memmove(&data[iFree+sz+sz2], &data[iFree+sz], iFree2-(iFree+sz));
1438 sz += sz2;
1440 cbrk = top+sz;
1441 assert( cbrk+(iFree-top) <= usableSize );
1442 memmove(&data[cbrk], &data[top], iFree-top);
1443 for(pAddr=&data[cellOffset]; pAddr<pEnd; pAddr+=2){
1444 pc = get2byte(pAddr);
1445 if( pc<iFree ){ put2byte(pAddr, pc+sz); }
1446 else if( pc<iFree2 ){ put2byte(pAddr, pc+sz2); }
1448 goto defragment_out;
1453 cbrk = usableSize;
1454 iCellLast = usableSize - 4;
1455 for(i=0; i<nCell; i++){
1456 u8 *pAddr; /* The i-th cell pointer */
1457 pAddr = &data[cellOffset + i*2];
1458 pc = get2byte(pAddr);
1459 testcase( pc==iCellFirst );
1460 testcase( pc==iCellLast );
1461 /* These conditions have already been verified in btreeInitPage()
1462 ** if PRAGMA cell_size_check=ON.
1464 if( pc<iCellFirst || pc>iCellLast ){
1465 return SQLITE_CORRUPT_PAGE(pPage);
1467 assert( pc>=iCellFirst && pc<=iCellLast );
1468 size = pPage->xCellSize(pPage, &src[pc]);
1469 cbrk -= size;
1470 if( cbrk<iCellFirst || pc+size>usableSize ){
1471 return SQLITE_CORRUPT_PAGE(pPage);
1473 assert( cbrk+size<=usableSize && cbrk>=iCellFirst );
1474 testcase( cbrk+size==usableSize );
1475 testcase( pc+size==usableSize );
1476 put2byte(pAddr, cbrk);
1477 if( temp==0 ){
1478 int x;
1479 if( cbrk==pc ) continue;
1480 temp = sqlite3PagerTempSpace(pPage->pBt->pPager);
1481 x = get2byte(&data[hdr+5]);
1482 memcpy(&temp[x], &data[x], (cbrk+size) - x);
1483 src = temp;
1485 memcpy(&data[cbrk], &src[pc], size);
1487 data[hdr+7] = 0;
1489 defragment_out:
1490 if( data[hdr+7]+cbrk-iCellFirst!=pPage->nFree ){
1491 return SQLITE_CORRUPT_PAGE(pPage);
1493 assert( cbrk>=iCellFirst );
1494 put2byte(&data[hdr+5], cbrk);
1495 data[hdr+1] = 0;
1496 data[hdr+2] = 0;
1497 memset(&data[iCellFirst], 0, cbrk-iCellFirst);
1498 assert( sqlite3PagerIswriteable(pPage->pDbPage) );
1499 return SQLITE_OK;
1503 ** Search the free-list on page pPg for space to store a cell nByte bytes in
1504 ** size. If one can be found, return a pointer to the space and remove it
1505 ** from the free-list.
1507 ** If no suitable space can be found on the free-list, return NULL.
1509 ** This function may detect corruption within pPg. If corruption is
1510 ** detected then *pRc is set to SQLITE_CORRUPT and NULL is returned.
1512 ** Slots on the free list that are between 1 and 3 bytes larger than nByte
1513 ** will be ignored if adding the extra space to the fragmentation count
1514 ** causes the fragmentation count to exceed 60.
1516 static u8 *pageFindSlot(MemPage *pPg, int nByte, int *pRc){
1517 const int hdr = pPg->hdrOffset;
1518 u8 * const aData = pPg->aData;
1519 int iAddr = hdr + 1;
1520 int pc = get2byte(&aData[iAddr]);
1521 int x;
1522 int usableSize = pPg->pBt->usableSize;
1523 int size; /* Size of the free slot */
1525 assert( pc>0 );
1526 while( pc<=usableSize-4 ){
1527 /* EVIDENCE-OF: R-22710-53328 The third and fourth bytes of each
1528 ** freeblock form a big-endian integer which is the size of the freeblock
1529 ** in bytes, including the 4-byte header. */
1530 size = get2byte(&aData[pc+2]);
1531 if( (x = size - nByte)>=0 ){
1532 testcase( x==4 );
1533 testcase( x==3 );
1534 if( size+pc > usableSize ){
1535 *pRc = SQLITE_CORRUPT_PAGE(pPg);
1536 return 0;
1537 }else if( x<4 ){
1538 /* EVIDENCE-OF: R-11498-58022 In a well-formed b-tree page, the total
1539 ** number of bytes in fragments may not exceed 60. */
1540 if( aData[hdr+7]>57 ) return 0;
1542 /* Remove the slot from the free-list. Update the number of
1543 ** fragmented bytes within the page. */
1544 memcpy(&aData[iAddr], &aData[pc], 2);
1545 aData[hdr+7] += (u8)x;
1546 }else{
1547 /* The slot remains on the free-list. Reduce its size to account
1548 ** for the portion used by the new allocation. */
1549 put2byte(&aData[pc+2], x);
1551 return &aData[pc + x];
1553 iAddr = pc;
1554 pc = get2byte(&aData[pc]);
1555 if( pc<iAddr+size ) break;
1557 if( pc ){
1558 *pRc = SQLITE_CORRUPT_PAGE(pPg);
1561 return 0;
1565 ** Allocate nByte bytes of space from within the B-Tree page passed
1566 ** as the first argument. Write into *pIdx the index into pPage->aData[]
1567 ** of the first byte of allocated space. Return either SQLITE_OK or
1568 ** an error code (usually SQLITE_CORRUPT).
1570 ** The caller guarantees that there is sufficient space to make the
1571 ** allocation. This routine might need to defragment in order to bring
1572 ** all the space together, however. This routine will avoid using
1573 ** the first two bytes past the cell pointer area since presumably this
1574 ** allocation is being made in order to insert a new cell, so we will
1575 ** also end up needing a new cell pointer.
1577 static int allocateSpace(MemPage *pPage, int nByte, int *pIdx){
1578 const int hdr = pPage->hdrOffset; /* Local cache of pPage->hdrOffset */
1579 u8 * const data = pPage->aData; /* Local cache of pPage->aData */
1580 int top; /* First byte of cell content area */
1581 int rc = SQLITE_OK; /* Integer return code */
1582 int gap; /* First byte of gap between cell pointers and cell content */
1584 assert( sqlite3PagerIswriteable(pPage->pDbPage) );
1585 assert( pPage->pBt );
1586 assert( sqlite3_mutex_held(pPage->pBt->mutex) );
1587 assert( nByte>=0 ); /* Minimum cell size is 4 */
1588 assert( pPage->nFree>=nByte );
1589 assert( pPage->nOverflow==0 );
1590 assert( nByte < (int)(pPage->pBt->usableSize-8) );
1592 assert( pPage->cellOffset == hdr + 12 - 4*pPage->leaf );
1593 gap = pPage->cellOffset + 2*pPage->nCell;
1594 assert( gap<=65536 );
1595 /* EVIDENCE-OF: R-29356-02391 If the database uses a 65536-byte page size
1596 ** and the reserved space is zero (the usual value for reserved space)
1597 ** then the cell content offset of an empty page wants to be 65536.
1598 ** However, that integer is too large to be stored in a 2-byte unsigned
1599 ** integer, so a value of 0 is used in its place. */
1600 top = get2byte(&data[hdr+5]);
1601 assert( top<=(int)pPage->pBt->usableSize ); /* Prevent by getAndInitPage() */
1602 if( gap>top ){
1603 if( top==0 && pPage->pBt->usableSize==65536 ){
1604 top = 65536;
1605 }else{
1606 return SQLITE_CORRUPT_PAGE(pPage);
1610 /* If there is enough space between gap and top for one more cell pointer
1611 ** array entry offset, and if the freelist is not empty, then search the
1612 ** freelist looking for a free slot big enough to satisfy the request.
1614 testcase( gap+2==top );
1615 testcase( gap+1==top );
1616 testcase( gap==top );
1617 if( (data[hdr+2] || data[hdr+1]) && gap+2<=top ){
1618 u8 *pSpace = pageFindSlot(pPage, nByte, &rc);
1619 if( pSpace ){
1620 assert( pSpace>=data && (pSpace - data)<65536 );
1621 *pIdx = (int)(pSpace - data);
1622 return SQLITE_OK;
1623 }else if( rc ){
1624 return rc;
1628 /* The request could not be fulfilled using a freelist slot. Check
1629 ** to see if defragmentation is necessary.
1631 testcase( gap+2+nByte==top );
1632 if( gap+2+nByte>top ){
1633 assert( pPage->nCell>0 || CORRUPT_DB );
1634 rc = defragmentPage(pPage, MIN(4, pPage->nFree - (2+nByte)));
1635 if( rc ) return rc;
1636 top = get2byteNotZero(&data[hdr+5]);
1637 assert( gap+2+nByte<=top );
1641 /* Allocate memory from the gap in between the cell pointer array
1642 ** and the cell content area. The btreeInitPage() call has already
1643 ** validated the freelist. Given that the freelist is valid, there
1644 ** is no way that the allocation can extend off the end of the page.
1645 ** The assert() below verifies the previous sentence.
1647 top -= nByte;
1648 put2byte(&data[hdr+5], top);
1649 assert( top+nByte <= (int)pPage->pBt->usableSize );
1650 *pIdx = top;
1651 return SQLITE_OK;
1655 ** Return a section of the pPage->aData to the freelist.
1656 ** The first byte of the new free block is pPage->aData[iStart]
1657 ** and the size of the block is iSize bytes.
1659 ** Adjacent freeblocks are coalesced.
1661 ** Note that even though the freeblock list was checked by btreeInitPage(),
1662 ** that routine will not detect overlap between cells or freeblocks. Nor
1663 ** does it detect cells or freeblocks that encrouch into the reserved bytes
1664 ** at the end of the page. So do additional corruption checks inside this
1665 ** routine and return SQLITE_CORRUPT if any problems are found.
1667 static int freeSpace(MemPage *pPage, u16 iStart, u16 iSize){
1668 u16 iPtr; /* Address of ptr to next freeblock */
1669 u16 iFreeBlk; /* Address of the next freeblock */
1670 u8 hdr; /* Page header size. 0 or 100 */
1671 u8 nFrag = 0; /* Reduction in fragmentation */
1672 u16 iOrigSize = iSize; /* Original value of iSize */
1673 u16 x; /* Offset to cell content area */
1674 u32 iEnd = iStart + iSize; /* First byte past the iStart buffer */
1675 unsigned char *data = pPage->aData; /* Page content */
1677 assert( pPage->pBt!=0 );
1678 assert( sqlite3PagerIswriteable(pPage->pDbPage) );
1679 assert( CORRUPT_DB || iStart>=pPage->hdrOffset+6+pPage->childPtrSize );
1680 assert( CORRUPT_DB || iEnd <= pPage->pBt->usableSize );
1681 assert( sqlite3_mutex_held(pPage->pBt->mutex) );
1682 assert( iSize>=4 ); /* Minimum cell size is 4 */
1683 assert( iStart<=pPage->pBt->usableSize-4 );
1685 /* The list of freeblocks must be in ascending order. Find the
1686 ** spot on the list where iStart should be inserted.
1688 hdr = pPage->hdrOffset;
1689 iPtr = hdr + 1;
1690 if( data[iPtr+1]==0 && data[iPtr]==0 ){
1691 iFreeBlk = 0; /* Shortcut for the case when the freelist is empty */
1692 }else{
1693 while( (iFreeBlk = get2byte(&data[iPtr]))<iStart ){
1694 if( iFreeBlk<iPtr+4 ){
1695 if( iFreeBlk==0 ) break;
1696 return SQLITE_CORRUPT_PAGE(pPage);
1698 iPtr = iFreeBlk;
1700 if( iFreeBlk>pPage->pBt->usableSize-4 ){
1701 return SQLITE_CORRUPT_PAGE(pPage);
1703 assert( iFreeBlk>iPtr || iFreeBlk==0 );
1705 /* At this point:
1706 ** iFreeBlk: First freeblock after iStart, or zero if none
1707 ** iPtr: The address of a pointer to iFreeBlk
1709 ** Check to see if iFreeBlk should be coalesced onto the end of iStart.
1711 if( iFreeBlk && iEnd+3>=iFreeBlk ){
1712 nFrag = iFreeBlk - iEnd;
1713 if( iEnd>iFreeBlk ) return SQLITE_CORRUPT_PAGE(pPage);
1714 iEnd = iFreeBlk + get2byte(&data[iFreeBlk+2]);
1715 if( iEnd > pPage->pBt->usableSize ){
1716 return SQLITE_CORRUPT_PAGE(pPage);
1718 iSize = iEnd - iStart;
1719 iFreeBlk = get2byte(&data[iFreeBlk]);
1722 /* If iPtr is another freeblock (that is, if iPtr is not the freelist
1723 ** pointer in the page header) then check to see if iStart should be
1724 ** coalesced onto the end of iPtr.
1726 if( iPtr>hdr+1 ){
1727 int iPtrEnd = iPtr + get2byte(&data[iPtr+2]);
1728 if( iPtrEnd+3>=iStart ){
1729 if( iPtrEnd>iStart ) return SQLITE_CORRUPT_PAGE(pPage);
1730 nFrag += iStart - iPtrEnd;
1731 iSize = iEnd - iPtr;
1732 iStart = iPtr;
1735 if( nFrag>data[hdr+7] ) return SQLITE_CORRUPT_PAGE(pPage);
1736 data[hdr+7] -= nFrag;
1738 x = get2byte(&data[hdr+5]);
1739 if( iStart<=x ){
1740 /* The new freeblock is at the beginning of the cell content area,
1741 ** so just extend the cell content area rather than create another
1742 ** freelist entry */
1743 if( iStart<x || iPtr!=hdr+1 ) return SQLITE_CORRUPT_PAGE(pPage);
1744 put2byte(&data[hdr+1], iFreeBlk);
1745 put2byte(&data[hdr+5], iEnd);
1746 }else{
1747 /* Insert the new freeblock into the freelist */
1748 put2byte(&data[iPtr], iStart);
1750 if( pPage->pBt->btsFlags & BTS_FAST_SECURE ){
1751 /* Overwrite deleted information with zeros when the secure_delete
1752 ** option is enabled */
1753 memset(&data[iStart], 0, iSize);
1755 put2byte(&data[iStart], iFreeBlk);
1756 put2byte(&data[iStart+2], iSize);
1757 pPage->nFree += iOrigSize;
1758 return SQLITE_OK;
1762 ** Decode the flags byte (the first byte of the header) for a page
1763 ** and initialize fields of the MemPage structure accordingly.
1765 ** Only the following combinations are supported. Anything different
1766 ** indicates a corrupt database files:
1768 ** PTF_ZERODATA
1769 ** PTF_ZERODATA | PTF_LEAF
1770 ** PTF_LEAFDATA | PTF_INTKEY
1771 ** PTF_LEAFDATA | PTF_INTKEY | PTF_LEAF
1773 static int decodeFlags(MemPage *pPage, int flagByte){
1774 BtShared *pBt; /* A copy of pPage->pBt */
1776 assert( pPage->hdrOffset==(pPage->pgno==1 ? 100 : 0) );
1777 assert( sqlite3_mutex_held(pPage->pBt->mutex) );
1778 pPage->leaf = (u8)(flagByte>>3); assert( PTF_LEAF == 1<<3 );
1779 flagByte &= ~PTF_LEAF;
1780 pPage->childPtrSize = 4-4*pPage->leaf;
1781 pPage->xCellSize = cellSizePtr;
1782 pBt = pPage->pBt;
1783 if( flagByte==(PTF_LEAFDATA | PTF_INTKEY) ){
1784 /* EVIDENCE-OF: R-07291-35328 A value of 5 (0x05) means the page is an
1785 ** interior table b-tree page. */
1786 assert( (PTF_LEAFDATA|PTF_INTKEY)==5 );
1787 /* EVIDENCE-OF: R-26900-09176 A value of 13 (0x0d) means the page is a
1788 ** leaf table b-tree page. */
1789 assert( (PTF_LEAFDATA|PTF_INTKEY|PTF_LEAF)==13 );
1790 pPage->intKey = 1;
1791 if( pPage->leaf ){
1792 pPage->intKeyLeaf = 1;
1793 pPage->xParseCell = btreeParseCellPtr;
1794 }else{
1795 pPage->intKeyLeaf = 0;
1796 pPage->xCellSize = cellSizePtrNoPayload;
1797 pPage->xParseCell = btreeParseCellPtrNoPayload;
1799 pPage->maxLocal = pBt->maxLeaf;
1800 pPage->minLocal = pBt->minLeaf;
1801 }else if( flagByte==PTF_ZERODATA ){
1802 /* EVIDENCE-OF: R-43316-37308 A value of 2 (0x02) means the page is an
1803 ** interior index b-tree page. */
1804 assert( (PTF_ZERODATA)==2 );
1805 /* EVIDENCE-OF: R-59615-42828 A value of 10 (0x0a) means the page is a
1806 ** leaf index b-tree page. */
1807 assert( (PTF_ZERODATA|PTF_LEAF)==10 );
1808 pPage->intKey = 0;
1809 pPage->intKeyLeaf = 0;
1810 pPage->xParseCell = btreeParseCellPtrIndex;
1811 pPage->maxLocal = pBt->maxLocal;
1812 pPage->minLocal = pBt->minLocal;
1813 }else{
1814 /* EVIDENCE-OF: R-47608-56469 Any other value for the b-tree page type is
1815 ** an error. */
1816 return SQLITE_CORRUPT_PAGE(pPage);
1818 pPage->max1bytePayload = pBt->max1bytePayload;
1819 return SQLITE_OK;
1823 ** Initialize the auxiliary information for a disk block.
1825 ** Return SQLITE_OK on success. If we see that the page does
1826 ** not contain a well-formed database page, then return
1827 ** SQLITE_CORRUPT. Note that a return of SQLITE_OK does not
1828 ** guarantee that the page is well-formed. It only shows that
1829 ** we failed to detect any corruption.
1831 static int btreeInitPage(MemPage *pPage){
1832 int pc; /* Address of a freeblock within pPage->aData[] */
1833 u8 hdr; /* Offset to beginning of page header */
1834 u8 *data; /* Equal to pPage->aData */
1835 BtShared *pBt; /* The main btree structure */
1836 int usableSize; /* Amount of usable space on each page */
1837 u16 cellOffset; /* Offset from start of page to first cell pointer */
1838 int nFree; /* Number of unused bytes on the page */
1839 int top; /* First byte of the cell content area */
1840 int iCellFirst; /* First allowable cell or freeblock offset */
1841 int iCellLast; /* Last possible cell or freeblock offset */
1843 assert( pPage->pBt!=0 );
1844 assert( pPage->pBt->db!=0 );
1845 assert( sqlite3_mutex_held(pPage->pBt->mutex) );
1846 assert( pPage->pgno==sqlite3PagerPagenumber(pPage->pDbPage) );
1847 assert( pPage == sqlite3PagerGetExtra(pPage->pDbPage) );
1848 assert( pPage->aData == sqlite3PagerGetData(pPage->pDbPage) );
1849 assert( pPage->isInit==0 );
1851 pBt = pPage->pBt;
1852 hdr = pPage->hdrOffset;
1853 data = pPage->aData;
1854 /* EVIDENCE-OF: R-28594-02890 The one-byte flag at offset 0 indicating
1855 ** the b-tree page type. */
1856 if( decodeFlags(pPage, data[hdr]) ){
1857 return SQLITE_CORRUPT_PAGE(pPage);
1859 assert( pBt->pageSize>=512 && pBt->pageSize<=65536 );
1860 pPage->maskPage = (u16)(pBt->pageSize - 1);
1861 pPage->nOverflow = 0;
1862 usableSize = pBt->usableSize;
1863 pPage->cellOffset = cellOffset = hdr + 8 + pPage->childPtrSize;
1864 pPage->aDataEnd = &data[usableSize];
1865 pPage->aCellIdx = &data[cellOffset];
1866 pPage->aDataOfst = &data[pPage->childPtrSize];
1867 /* EVIDENCE-OF: R-58015-48175 The two-byte integer at offset 5 designates
1868 ** the start of the cell content area. A zero value for this integer is
1869 ** interpreted as 65536. */
1870 top = get2byteNotZero(&data[hdr+5]);
1871 /* EVIDENCE-OF: R-37002-32774 The two-byte integer at offset 3 gives the
1872 ** number of cells on the page. */
1873 pPage->nCell = get2byte(&data[hdr+3]);
1874 if( pPage->nCell>MX_CELL(pBt) ){
1875 /* To many cells for a single page. The page must be corrupt */
1876 return SQLITE_CORRUPT_PAGE(pPage);
1878 testcase( pPage->nCell==MX_CELL(pBt) );
1879 /* EVIDENCE-OF: R-24089-57979 If a page contains no cells (which is only
1880 ** possible for a root page of a table that contains no rows) then the
1881 ** offset to the cell content area will equal the page size minus the
1882 ** bytes of reserved space. */
1883 assert( pPage->nCell>0 || top==usableSize || CORRUPT_DB );
1885 /* A malformed database page might cause us to read past the end
1886 ** of page when parsing a cell.
1888 ** The following block of code checks early to see if a cell extends
1889 ** past the end of a page boundary and causes SQLITE_CORRUPT to be
1890 ** returned if it does.
1892 iCellFirst = cellOffset + 2*pPage->nCell;
1893 iCellLast = usableSize - 4;
1894 if( pBt->db->flags & SQLITE_CellSizeCk ){
1895 int i; /* Index into the cell pointer array */
1896 int sz; /* Size of a cell */
1898 if( !pPage->leaf ) iCellLast--;
1899 for(i=0; i<pPage->nCell; i++){
1900 pc = get2byteAligned(&data[cellOffset+i*2]);
1901 testcase( pc==iCellFirst );
1902 testcase( pc==iCellLast );
1903 if( pc<iCellFirst || pc>iCellLast ){
1904 return SQLITE_CORRUPT_PAGE(pPage);
1906 sz = pPage->xCellSize(pPage, &data[pc]);
1907 testcase( pc+sz==usableSize );
1908 if( pc+sz>usableSize ){
1909 return SQLITE_CORRUPT_PAGE(pPage);
1912 if( !pPage->leaf ) iCellLast++;
1915 /* Compute the total free space on the page
1916 ** EVIDENCE-OF: R-23588-34450 The two-byte integer at offset 1 gives the
1917 ** start of the first freeblock on the page, or is zero if there are no
1918 ** freeblocks. */
1919 pc = get2byte(&data[hdr+1]);
1920 nFree = data[hdr+7] + top; /* Init nFree to non-freeblock free space */
1921 if( pc>0 ){
1922 u32 next, size;
1923 if( pc<iCellFirst ){
1924 /* EVIDENCE-OF: R-55530-52930 In a well-formed b-tree page, there will
1925 ** always be at least one cell before the first freeblock.
1927 return SQLITE_CORRUPT_PAGE(pPage);
1929 while( 1 ){
1930 if( pc>iCellLast ){
1931 /* Freeblock off the end of the page */
1932 return SQLITE_CORRUPT_PAGE(pPage);
1934 next = get2byte(&data[pc]);
1935 size = get2byte(&data[pc+2]);
1936 nFree = nFree + size;
1937 if( next<=pc+size+3 ) break;
1938 pc = next;
1940 if( next>0 ){
1941 /* Freeblock not in ascending order */
1942 return SQLITE_CORRUPT_PAGE(pPage);
1944 if( pc+size>(unsigned int)usableSize ){
1945 /* Last freeblock extends past page end */
1946 return SQLITE_CORRUPT_PAGE(pPage);
1950 /* At this point, nFree contains the sum of the offset to the start
1951 ** of the cell-content area plus the number of free bytes within
1952 ** the cell-content area. If this is greater than the usable-size
1953 ** of the page, then the page must be corrupted. This check also
1954 ** serves to verify that the offset to the start of the cell-content
1955 ** area, according to the page header, lies within the page.
1957 if( nFree>usableSize ){
1958 return SQLITE_CORRUPT_PAGE(pPage);
1960 pPage->nFree = (u16)(nFree - iCellFirst);
1961 pPage->isInit = 1;
1962 return SQLITE_OK;
1966 ** Set up a raw page so that it looks like a database page holding
1967 ** no entries.
1969 static void zeroPage(MemPage *pPage, int flags){
1970 unsigned char *data = pPage->aData;
1971 BtShared *pBt = pPage->pBt;
1972 u8 hdr = pPage->hdrOffset;
1973 u16 first;
1975 assert( sqlite3PagerPagenumber(pPage->pDbPage)==pPage->pgno );
1976 assert( sqlite3PagerGetExtra(pPage->pDbPage) == (void*)pPage );
1977 assert( sqlite3PagerGetData(pPage->pDbPage) == data );
1978 assert( sqlite3PagerIswriteable(pPage->pDbPage) );
1979 assert( sqlite3_mutex_held(pBt->mutex) );
1980 if( pBt->btsFlags & BTS_FAST_SECURE ){
1981 memset(&data[hdr], 0, pBt->usableSize - hdr);
1983 data[hdr] = (char)flags;
1984 first = hdr + ((flags&PTF_LEAF)==0 ? 12 : 8);
1985 memset(&data[hdr+1], 0, 4);
1986 data[hdr+7] = 0;
1987 put2byte(&data[hdr+5], pBt->usableSize);
1988 pPage->nFree = (u16)(pBt->usableSize - first);
1989 decodeFlags(pPage, flags);
1990 pPage->cellOffset = first;
1991 pPage->aDataEnd = &data[pBt->usableSize];
1992 pPage->aCellIdx = &data[first];
1993 pPage->aDataOfst = &data[pPage->childPtrSize];
1994 pPage->nOverflow = 0;
1995 assert( pBt->pageSize>=512 && pBt->pageSize<=65536 );
1996 pPage->maskPage = (u16)(pBt->pageSize - 1);
1997 pPage->nCell = 0;
1998 pPage->isInit = 1;
2003 ** Convert a DbPage obtained from the pager into a MemPage used by
2004 ** the btree layer.
2006 static MemPage *btreePageFromDbPage(DbPage *pDbPage, Pgno pgno, BtShared *pBt){
2007 MemPage *pPage = (MemPage*)sqlite3PagerGetExtra(pDbPage);
2008 if( pgno!=pPage->pgno ){
2009 pPage->aData = sqlite3PagerGetData(pDbPage);
2010 pPage->pDbPage = pDbPage;
2011 pPage->pBt = pBt;
2012 pPage->pgno = pgno;
2013 pPage->hdrOffset = pgno==1 ? 100 : 0;
2015 assert( pPage->aData==sqlite3PagerGetData(pDbPage) );
2016 return pPage;
2020 ** Get a page from the pager. Initialize the MemPage.pBt and
2021 ** MemPage.aData elements if needed. See also: btreeGetUnusedPage().
2023 ** If the PAGER_GET_NOCONTENT flag is set, it means that we do not care
2024 ** about the content of the page at this time. So do not go to the disk
2025 ** to fetch the content. Just fill in the content with zeros for now.
2026 ** If in the future we call sqlite3PagerWrite() on this page, that
2027 ** means we have started to be concerned about content and the disk
2028 ** read should occur at that point.
2030 static int btreeGetPage(
2031 BtShared *pBt, /* The btree */
2032 Pgno pgno, /* Number of the page to fetch */
2033 MemPage **ppPage, /* Return the page in this parameter */
2034 int flags /* PAGER_GET_NOCONTENT or PAGER_GET_READONLY */
2036 int rc;
2037 DbPage *pDbPage;
2039 assert( flags==0 || flags==PAGER_GET_NOCONTENT || flags==PAGER_GET_READONLY );
2040 assert( sqlite3_mutex_held(pBt->mutex) );
2041 rc = sqlite3PagerGet(pBt->pPager, pgno, (DbPage**)&pDbPage, flags);
2042 if( rc ) return rc;
2043 *ppPage = btreePageFromDbPage(pDbPage, pgno, pBt);
2044 return SQLITE_OK;
2048 ** Retrieve a page from the pager cache. If the requested page is not
2049 ** already in the pager cache return NULL. Initialize the MemPage.pBt and
2050 ** MemPage.aData elements if needed.
2052 static MemPage *btreePageLookup(BtShared *pBt, Pgno pgno){
2053 DbPage *pDbPage;
2054 assert( sqlite3_mutex_held(pBt->mutex) );
2055 pDbPage = sqlite3PagerLookup(pBt->pPager, pgno);
2056 if( pDbPage ){
2057 return btreePageFromDbPage(pDbPage, pgno, pBt);
2059 return 0;
2063 ** Return the size of the database file in pages. If there is any kind of
2064 ** error, return ((unsigned int)-1).
2066 static Pgno btreePagecount(BtShared *pBt){
2067 return pBt->nPage;
2069 u32 sqlite3BtreeLastPage(Btree *p){
2070 assert( sqlite3BtreeHoldsMutex(p) );
2071 assert( ((p->pBt->nPage)&0x80000000)==0 );
2072 return btreePagecount(p->pBt);
2076 ** Get a page from the pager and initialize it.
2078 ** If pCur!=0 then the page is being fetched as part of a moveToChild()
2079 ** call. Do additional sanity checking on the page in this case.
2080 ** And if the fetch fails, this routine must decrement pCur->iPage.
2082 ** The page is fetched as read-write unless pCur is not NULL and is
2083 ** a read-only cursor.
2085 ** If an error occurs, then *ppPage is undefined. It
2086 ** may remain unchanged, or it may be set to an invalid value.
2088 static int getAndInitPage(
2089 BtShared *pBt, /* The database file */
2090 Pgno pgno, /* Number of the page to get */
2091 MemPage **ppPage, /* Write the page pointer here */
2092 BtCursor *pCur, /* Cursor to receive the page, or NULL */
2093 int bReadOnly /* True for a read-only page */
2095 int rc;
2096 DbPage *pDbPage;
2097 assert( sqlite3_mutex_held(pBt->mutex) );
2098 assert( pCur==0 || ppPage==&pCur->pPage );
2099 assert( pCur==0 || bReadOnly==pCur->curPagerFlags );
2100 assert( pCur==0 || pCur->iPage>0 );
2102 if( pgno>btreePagecount(pBt) ){
2103 rc = SQLITE_CORRUPT_BKPT;
2104 goto getAndInitPage_error;
2106 rc = sqlite3PagerGet(pBt->pPager, pgno, (DbPage**)&pDbPage, bReadOnly);
2107 if( rc ){
2108 goto getAndInitPage_error;
2110 *ppPage = (MemPage*)sqlite3PagerGetExtra(pDbPage);
2111 if( (*ppPage)->isInit==0 ){
2112 btreePageFromDbPage(pDbPage, pgno, pBt);
2113 rc = btreeInitPage(*ppPage);
2114 if( rc!=SQLITE_OK ){
2115 releasePage(*ppPage);
2116 goto getAndInitPage_error;
2119 assert( (*ppPage)->pgno==pgno );
2120 assert( (*ppPage)->aData==sqlite3PagerGetData(pDbPage) );
2122 /* If obtaining a child page for a cursor, we must verify that the page is
2123 ** compatible with the root page. */
2124 if( pCur && ((*ppPage)->nCell<1 || (*ppPage)->intKey!=pCur->curIntKey) ){
2125 rc = SQLITE_CORRUPT_PGNO(pgno);
2126 releasePage(*ppPage);
2127 goto getAndInitPage_error;
2129 return SQLITE_OK;
2131 getAndInitPage_error:
2132 if( pCur ){
2133 pCur->iPage--;
2134 pCur->pPage = pCur->apPage[pCur->iPage];
2136 testcase( pgno==0 );
2137 assert( pgno!=0 || rc==SQLITE_CORRUPT );
2138 return rc;
2142 ** Release a MemPage. This should be called once for each prior
2143 ** call to btreeGetPage.
2145 ** Page1 is a special case and must be released using releasePageOne().
2147 static void releasePageNotNull(MemPage *pPage){
2148 assert( pPage->aData );
2149 assert( pPage->pBt );
2150 assert( pPage->pDbPage!=0 );
2151 assert( sqlite3PagerGetExtra(pPage->pDbPage) == (void*)pPage );
2152 assert( sqlite3PagerGetData(pPage->pDbPage)==pPage->aData );
2153 assert( sqlite3_mutex_held(pPage->pBt->mutex) );
2154 sqlite3PagerUnrefNotNull(pPage->pDbPage);
2156 static void releasePage(MemPage *pPage){
2157 if( pPage ) releasePageNotNull(pPage);
2159 static void releasePageOne(MemPage *pPage){
2160 assert( pPage!=0 );
2161 assert( pPage->aData );
2162 assert( pPage->pBt );
2163 assert( pPage->pDbPage!=0 );
2164 assert( sqlite3PagerGetExtra(pPage->pDbPage) == (void*)pPage );
2165 assert( sqlite3PagerGetData(pPage->pDbPage)==pPage->aData );
2166 assert( sqlite3_mutex_held(pPage->pBt->mutex) );
2167 sqlite3PagerUnrefPageOne(pPage->pDbPage);
2171 ** Get an unused page.
2173 ** This works just like btreeGetPage() with the addition:
2175 ** * If the page is already in use for some other purpose, immediately
2176 ** release it and return an SQLITE_CURRUPT error.
2177 ** * Make sure the isInit flag is clear
2179 static int btreeGetUnusedPage(
2180 BtShared *pBt, /* The btree */
2181 Pgno pgno, /* Number of the page to fetch */
2182 MemPage **ppPage, /* Return the page in this parameter */
2183 int flags /* PAGER_GET_NOCONTENT or PAGER_GET_READONLY */
2185 int rc = btreeGetPage(pBt, pgno, ppPage, flags);
2186 if( rc==SQLITE_OK ){
2187 if( sqlite3PagerPageRefcount((*ppPage)->pDbPage)>1 ){
2188 releasePage(*ppPage);
2189 *ppPage = 0;
2190 return SQLITE_CORRUPT_BKPT;
2192 (*ppPage)->isInit = 0;
2193 }else{
2194 *ppPage = 0;
2196 return rc;
2201 ** During a rollback, when the pager reloads information into the cache
2202 ** so that the cache is restored to its original state at the start of
2203 ** the transaction, for each page restored this routine is called.
2205 ** This routine needs to reset the extra data section at the end of the
2206 ** page to agree with the restored data.
2208 static void pageReinit(DbPage *pData){
2209 MemPage *pPage;
2210 pPage = (MemPage *)sqlite3PagerGetExtra(pData);
2211 assert( sqlite3PagerPageRefcount(pData)>0 );
2212 if( pPage->isInit ){
2213 assert( sqlite3_mutex_held(pPage->pBt->mutex) );
2214 pPage->isInit = 0;
2215 if( sqlite3PagerPageRefcount(pData)>1 ){
2216 /* pPage might not be a btree page; it might be an overflow page
2217 ** or ptrmap page or a free page. In those cases, the following
2218 ** call to btreeInitPage() will likely return SQLITE_CORRUPT.
2219 ** But no harm is done by this. And it is very important that
2220 ** btreeInitPage() be called on every btree page so we make
2221 ** the call for every page that comes in for re-initing. */
2222 btreeInitPage(pPage);
2228 ** Invoke the busy handler for a btree.
2230 static int btreeInvokeBusyHandler(void *pArg){
2231 BtShared *pBt = (BtShared*)pArg;
2232 assert( pBt->db );
2233 assert( sqlite3_mutex_held(pBt->db->mutex) );
2234 return sqlite3InvokeBusyHandler(&pBt->db->busyHandler,
2235 sqlite3PagerFile(pBt->pPager));
2239 ** Open a database file.
2241 ** zFilename is the name of the database file. If zFilename is NULL
2242 ** then an ephemeral database is created. The ephemeral database might
2243 ** be exclusively in memory, or it might use a disk-based memory cache.
2244 ** Either way, the ephemeral database will be automatically deleted
2245 ** when sqlite3BtreeClose() is called.
2247 ** If zFilename is ":memory:" then an in-memory database is created
2248 ** that is automatically destroyed when it is closed.
2250 ** The "flags" parameter is a bitmask that might contain bits like
2251 ** BTREE_OMIT_JOURNAL and/or BTREE_MEMORY.
2253 ** If the database is already opened in the same database connection
2254 ** and we are in shared cache mode, then the open will fail with an
2255 ** SQLITE_CONSTRAINT error. We cannot allow two or more BtShared
2256 ** objects in the same database connection since doing so will lead
2257 ** to problems with locking.
2259 int sqlite3BtreeOpen(
2260 sqlite3_vfs *pVfs, /* VFS to use for this b-tree */
2261 const char *zFilename, /* Name of the file containing the BTree database */
2262 sqlite3 *db, /* Associated database handle */
2263 Btree **ppBtree, /* Pointer to new Btree object written here */
2264 int flags, /* Options */
2265 int vfsFlags /* Flags passed through to sqlite3_vfs.xOpen() */
2267 BtShared *pBt = 0; /* Shared part of btree structure */
2268 Btree *p; /* Handle to return */
2269 sqlite3_mutex *mutexOpen = 0; /* Prevents a race condition. Ticket #3537 */
2270 int rc = SQLITE_OK; /* Result code from this function */
2271 u8 nReserve; /* Byte of unused space on each page */
2272 unsigned char zDbHeader[100]; /* Database header content */
2274 /* True if opening an ephemeral, temporary database */
2275 const int isTempDb = zFilename==0 || zFilename[0]==0;
2277 /* Set the variable isMemdb to true for an in-memory database, or
2278 ** false for a file-based database.
2280 #ifdef SQLITE_OMIT_MEMORYDB
2281 const int isMemdb = 0;
2282 #else
2283 const int isMemdb = (zFilename && strcmp(zFilename, ":memory:")==0)
2284 || (isTempDb && sqlite3TempInMemory(db))
2285 || (vfsFlags & SQLITE_OPEN_MEMORY)!=0;
2286 #endif
2288 assert( db!=0 );
2289 assert( pVfs!=0 );
2290 assert( sqlite3_mutex_held(db->mutex) );
2291 assert( (flags&0xff)==flags ); /* flags fit in 8 bits */
2293 /* Only a BTREE_SINGLE database can be BTREE_UNORDERED */
2294 assert( (flags & BTREE_UNORDERED)==0 || (flags & BTREE_SINGLE)!=0 );
2296 /* A BTREE_SINGLE database is always a temporary and/or ephemeral */
2297 assert( (flags & BTREE_SINGLE)==0 || isTempDb );
2299 if( isMemdb ){
2300 flags |= BTREE_MEMORY;
2302 if( (vfsFlags & SQLITE_OPEN_MAIN_DB)!=0 && (isMemdb || isTempDb) ){
2303 vfsFlags = (vfsFlags & ~SQLITE_OPEN_MAIN_DB) | SQLITE_OPEN_TEMP_DB;
2305 p = sqlite3MallocZero(sizeof(Btree));
2306 if( !p ){
2307 return SQLITE_NOMEM_BKPT;
2309 p->inTrans = TRANS_NONE;
2310 p->db = db;
2311 #ifndef SQLITE_OMIT_SHARED_CACHE
2312 p->lock.pBtree = p;
2313 p->lock.iTable = 1;
2314 #endif
2316 #if !defined(SQLITE_OMIT_SHARED_CACHE) && !defined(SQLITE_OMIT_DISKIO)
2318 ** If this Btree is a candidate for shared cache, try to find an
2319 ** existing BtShared object that we can share with
2321 if( isTempDb==0 && (isMemdb==0 || (vfsFlags&SQLITE_OPEN_URI)!=0) ){
2322 if( vfsFlags & SQLITE_OPEN_SHAREDCACHE ){
2323 int nFilename = sqlite3Strlen30(zFilename)+1;
2324 int nFullPathname = pVfs->mxPathname+1;
2325 char *zFullPathname = sqlite3Malloc(MAX(nFullPathname,nFilename));
2326 MUTEX_LOGIC( sqlite3_mutex *mutexShared; )
2328 p->sharable = 1;
2329 if( !zFullPathname ){
2330 sqlite3_free(p);
2331 return SQLITE_NOMEM_BKPT;
2333 if( isMemdb ){
2334 memcpy(zFullPathname, zFilename, nFilename);
2335 }else{
2336 rc = sqlite3OsFullPathname(pVfs, zFilename,
2337 nFullPathname, zFullPathname);
2338 if( rc ){
2339 sqlite3_free(zFullPathname);
2340 sqlite3_free(p);
2341 return rc;
2344 #if SQLITE_THREADSAFE
2345 mutexOpen = sqlite3MutexAlloc(SQLITE_MUTEX_STATIC_OPEN);
2346 sqlite3_mutex_enter(mutexOpen);
2347 mutexShared = sqlite3MutexAlloc(SQLITE_MUTEX_STATIC_MASTER);
2348 sqlite3_mutex_enter(mutexShared);
2349 #endif
2350 for(pBt=GLOBAL(BtShared*,sqlite3SharedCacheList); pBt; pBt=pBt->pNext){
2351 assert( pBt->nRef>0 );
2352 if( 0==strcmp(zFullPathname, sqlite3PagerFilename(pBt->pPager, 0))
2353 && sqlite3PagerVfs(pBt->pPager)==pVfs ){
2354 int iDb;
2355 for(iDb=db->nDb-1; iDb>=0; iDb--){
2356 Btree *pExisting = db->aDb[iDb].pBt;
2357 if( pExisting && pExisting->pBt==pBt ){
2358 sqlite3_mutex_leave(mutexShared);
2359 sqlite3_mutex_leave(mutexOpen);
2360 sqlite3_free(zFullPathname);
2361 sqlite3_free(p);
2362 return SQLITE_CONSTRAINT;
2365 p->pBt = pBt;
2366 pBt->nRef++;
2367 break;
2370 sqlite3_mutex_leave(mutexShared);
2371 sqlite3_free(zFullPathname);
2373 #ifdef SQLITE_DEBUG
2374 else{
2375 /* In debug mode, we mark all persistent databases as sharable
2376 ** even when they are not. This exercises the locking code and
2377 ** gives more opportunity for asserts(sqlite3_mutex_held())
2378 ** statements to find locking problems.
2380 p->sharable = 1;
2382 #endif
2384 #endif
2385 if( pBt==0 ){
2387 ** The following asserts make sure that structures used by the btree are
2388 ** the right size. This is to guard against size changes that result
2389 ** when compiling on a different architecture.
2391 assert( sizeof(i64)==8 );
2392 assert( sizeof(u64)==8 );
2393 assert( sizeof(u32)==4 );
2394 assert( sizeof(u16)==2 );
2395 assert( sizeof(Pgno)==4 );
2397 pBt = sqlite3MallocZero( sizeof(*pBt) );
2398 if( pBt==0 ){
2399 rc = SQLITE_NOMEM_BKPT;
2400 goto btree_open_out;
2402 rc = sqlite3PagerOpen(pVfs, &pBt->pPager, zFilename,
2403 sizeof(MemPage), flags, vfsFlags, pageReinit);
2404 if( rc==SQLITE_OK ){
2405 sqlite3PagerSetMmapLimit(pBt->pPager, db->szMmap);
2406 rc = sqlite3PagerReadFileheader(pBt->pPager,sizeof(zDbHeader),zDbHeader);
2408 if( rc!=SQLITE_OK ){
2409 goto btree_open_out;
2411 pBt->openFlags = (u8)flags;
2412 pBt->db = db;
2413 sqlite3PagerSetBusyHandler(pBt->pPager, btreeInvokeBusyHandler, pBt);
2414 p->pBt = pBt;
2416 pBt->pCursor = 0;
2417 pBt->pPage1 = 0;
2418 if( sqlite3PagerIsreadonly(pBt->pPager) ) pBt->btsFlags |= BTS_READ_ONLY;
2419 #if defined(SQLITE_SECURE_DELETE)
2420 pBt->btsFlags |= BTS_SECURE_DELETE;
2421 #elif defined(SQLITE_FAST_SECURE_DELETE)
2422 pBt->btsFlags |= BTS_OVERWRITE;
2423 #endif
2424 /* EVIDENCE-OF: R-51873-39618 The page size for a database file is
2425 ** determined by the 2-byte integer located at an offset of 16 bytes from
2426 ** the beginning of the database file. */
2427 pBt->pageSize = (zDbHeader[16]<<8) | (zDbHeader[17]<<16);
2428 if( pBt->pageSize<512 || pBt->pageSize>SQLITE_MAX_PAGE_SIZE
2429 || ((pBt->pageSize-1)&pBt->pageSize)!=0 ){
2430 pBt->pageSize = 0;
2431 #ifndef SQLITE_OMIT_AUTOVACUUM
2432 /* If the magic name ":memory:" will create an in-memory database, then
2433 ** leave the autoVacuum mode at 0 (do not auto-vacuum), even if
2434 ** SQLITE_DEFAULT_AUTOVACUUM is true. On the other hand, if
2435 ** SQLITE_OMIT_MEMORYDB has been defined, then ":memory:" is just a
2436 ** regular file-name. In this case the auto-vacuum applies as per normal.
2438 if( zFilename && !isMemdb ){
2439 pBt->autoVacuum = (SQLITE_DEFAULT_AUTOVACUUM ? 1 : 0);
2440 pBt->incrVacuum = (SQLITE_DEFAULT_AUTOVACUUM==2 ? 1 : 0);
2442 #endif
2443 nReserve = 0;
2444 }else{
2445 /* EVIDENCE-OF: R-37497-42412 The size of the reserved region is
2446 ** determined by the one-byte unsigned integer found at an offset of 20
2447 ** into the database file header. */
2448 nReserve = zDbHeader[20];
2449 pBt->btsFlags |= BTS_PAGESIZE_FIXED;
2450 #ifndef SQLITE_OMIT_AUTOVACUUM
2451 pBt->autoVacuum = (get4byte(&zDbHeader[36 + 4*4])?1:0);
2452 pBt->incrVacuum = (get4byte(&zDbHeader[36 + 7*4])?1:0);
2453 #endif
2455 rc = sqlite3PagerSetPagesize(pBt->pPager, &pBt->pageSize, nReserve);
2456 if( rc ) goto btree_open_out;
2457 pBt->usableSize = pBt->pageSize - nReserve;
2458 assert( (pBt->pageSize & 7)==0 ); /* 8-byte alignment of pageSize */
2460 #if !defined(SQLITE_OMIT_SHARED_CACHE) && !defined(SQLITE_OMIT_DISKIO)
2461 /* Add the new BtShared object to the linked list sharable BtShareds.
2463 pBt->nRef = 1;
2464 if( p->sharable ){
2465 MUTEX_LOGIC( sqlite3_mutex *mutexShared; )
2466 MUTEX_LOGIC( mutexShared = sqlite3MutexAlloc(SQLITE_MUTEX_STATIC_MASTER);)
2467 if( SQLITE_THREADSAFE && sqlite3GlobalConfig.bCoreMutex ){
2468 pBt->mutex = sqlite3MutexAlloc(SQLITE_MUTEX_FAST);
2469 if( pBt->mutex==0 ){
2470 rc = SQLITE_NOMEM_BKPT;
2471 goto btree_open_out;
2474 sqlite3_mutex_enter(mutexShared);
2475 pBt->pNext = GLOBAL(BtShared*,sqlite3SharedCacheList);
2476 GLOBAL(BtShared*,sqlite3SharedCacheList) = pBt;
2477 sqlite3_mutex_leave(mutexShared);
2479 #endif
2482 #if !defined(SQLITE_OMIT_SHARED_CACHE) && !defined(SQLITE_OMIT_DISKIO)
2483 /* If the new Btree uses a sharable pBtShared, then link the new
2484 ** Btree into the list of all sharable Btrees for the same connection.
2485 ** The list is kept in ascending order by pBt address.
2487 if( p->sharable ){
2488 int i;
2489 Btree *pSib;
2490 for(i=0; i<db->nDb; i++){
2491 if( (pSib = db->aDb[i].pBt)!=0 && pSib->sharable ){
2492 while( pSib->pPrev ){ pSib = pSib->pPrev; }
2493 if( (uptr)p->pBt<(uptr)pSib->pBt ){
2494 p->pNext = pSib;
2495 p->pPrev = 0;
2496 pSib->pPrev = p;
2497 }else{
2498 while( pSib->pNext && (uptr)pSib->pNext->pBt<(uptr)p->pBt ){
2499 pSib = pSib->pNext;
2501 p->pNext = pSib->pNext;
2502 p->pPrev = pSib;
2503 if( p->pNext ){
2504 p->pNext->pPrev = p;
2506 pSib->pNext = p;
2508 break;
2512 #endif
2513 *ppBtree = p;
2515 btree_open_out:
2516 if( rc!=SQLITE_OK ){
2517 if( pBt && pBt->pPager ){
2518 sqlite3PagerClose(pBt->pPager, 0);
2520 sqlite3_free(pBt);
2521 sqlite3_free(p);
2522 *ppBtree = 0;
2523 }else{
2524 sqlite3_file *pFile;
2526 /* If the B-Tree was successfully opened, set the pager-cache size to the
2527 ** default value. Except, when opening on an existing shared pager-cache,
2528 ** do not change the pager-cache size.
2530 if( sqlite3BtreeSchema(p, 0, 0)==0 ){
2531 sqlite3PagerSetCachesize(p->pBt->pPager, SQLITE_DEFAULT_CACHE_SIZE);
2534 pFile = sqlite3PagerFile(pBt->pPager);
2535 if( pFile->pMethods ){
2536 sqlite3OsFileControlHint(pFile, SQLITE_FCNTL_PDB, (void*)&pBt->db);
2539 if( mutexOpen ){
2540 assert( sqlite3_mutex_held(mutexOpen) );
2541 sqlite3_mutex_leave(mutexOpen);
2543 assert( rc!=SQLITE_OK || sqlite3BtreeConnectionCount(*ppBtree)>0 );
2544 return rc;
2548 ** Decrement the BtShared.nRef counter. When it reaches zero,
2549 ** remove the BtShared structure from the sharing list. Return
2550 ** true if the BtShared.nRef counter reaches zero and return
2551 ** false if it is still positive.
2553 static int removeFromSharingList(BtShared *pBt){
2554 #ifndef SQLITE_OMIT_SHARED_CACHE
2555 MUTEX_LOGIC( sqlite3_mutex *pMaster; )
2556 BtShared *pList;
2557 int removed = 0;
2559 assert( sqlite3_mutex_notheld(pBt->mutex) );
2560 MUTEX_LOGIC( pMaster = sqlite3MutexAlloc(SQLITE_MUTEX_STATIC_MASTER); )
2561 sqlite3_mutex_enter(pMaster);
2562 pBt->nRef--;
2563 if( pBt->nRef<=0 ){
2564 if( GLOBAL(BtShared*,sqlite3SharedCacheList)==pBt ){
2565 GLOBAL(BtShared*,sqlite3SharedCacheList) = pBt->pNext;
2566 }else{
2567 pList = GLOBAL(BtShared*,sqlite3SharedCacheList);
2568 while( ALWAYS(pList) && pList->pNext!=pBt ){
2569 pList=pList->pNext;
2571 if( ALWAYS(pList) ){
2572 pList->pNext = pBt->pNext;
2575 if( SQLITE_THREADSAFE ){
2576 sqlite3_mutex_free(pBt->mutex);
2578 removed = 1;
2580 sqlite3_mutex_leave(pMaster);
2581 return removed;
2582 #else
2583 return 1;
2584 #endif
2588 ** Make sure pBt->pTmpSpace points to an allocation of
2589 ** MX_CELL_SIZE(pBt) bytes with a 4-byte prefix for a left-child
2590 ** pointer.
2592 static void allocateTempSpace(BtShared *pBt){
2593 if( !pBt->pTmpSpace ){
2594 pBt->pTmpSpace = sqlite3PageMalloc( pBt->pageSize );
2596 /* One of the uses of pBt->pTmpSpace is to format cells before
2597 ** inserting them into a leaf page (function fillInCell()). If
2598 ** a cell is less than 4 bytes in size, it is rounded up to 4 bytes
2599 ** by the various routines that manipulate binary cells. Which
2600 ** can mean that fillInCell() only initializes the first 2 or 3
2601 ** bytes of pTmpSpace, but that the first 4 bytes are copied from
2602 ** it into a database page. This is not actually a problem, but it
2603 ** does cause a valgrind error when the 1 or 2 bytes of unitialized
2604 ** data is passed to system call write(). So to avoid this error,
2605 ** zero the first 4 bytes of temp space here.
2607 ** Also: Provide four bytes of initialized space before the
2608 ** beginning of pTmpSpace as an area available to prepend the
2609 ** left-child pointer to the beginning of a cell.
2611 if( pBt->pTmpSpace ){
2612 memset(pBt->pTmpSpace, 0, 8);
2613 pBt->pTmpSpace += 4;
2619 ** Free the pBt->pTmpSpace allocation
2621 static void freeTempSpace(BtShared *pBt){
2622 if( pBt->pTmpSpace ){
2623 pBt->pTmpSpace -= 4;
2624 sqlite3PageFree(pBt->pTmpSpace);
2625 pBt->pTmpSpace = 0;
2630 ** Close an open database and invalidate all cursors.
2632 int sqlite3BtreeClose(Btree *p){
2633 BtShared *pBt = p->pBt;
2634 BtCursor *pCur;
2636 /* Close all cursors opened via this handle. */
2637 assert( sqlite3_mutex_held(p->db->mutex) );
2638 sqlite3BtreeEnter(p);
2639 pCur = pBt->pCursor;
2640 while( pCur ){
2641 BtCursor *pTmp = pCur;
2642 pCur = pCur->pNext;
2643 if( pTmp->pBtree==p ){
2644 sqlite3BtreeCloseCursor(pTmp);
2648 /* Rollback any active transaction and free the handle structure.
2649 ** The call to sqlite3BtreeRollback() drops any table-locks held by
2650 ** this handle.
2652 sqlite3BtreeRollback(p, SQLITE_OK, 0);
2653 sqlite3BtreeLeave(p);
2655 /* If there are still other outstanding references to the shared-btree
2656 ** structure, return now. The remainder of this procedure cleans
2657 ** up the shared-btree.
2659 assert( p->wantToLock==0 && p->locked==0 );
2660 if( !p->sharable || removeFromSharingList(pBt) ){
2661 /* The pBt is no longer on the sharing list, so we can access
2662 ** it without having to hold the mutex.
2664 ** Clean out and delete the BtShared object.
2666 assert( !pBt->pCursor );
2667 sqlite3PagerClose(pBt->pPager, p->db);
2668 if( pBt->xFreeSchema && pBt->pSchema ){
2669 pBt->xFreeSchema(pBt->pSchema);
2671 sqlite3DbFree(0, pBt->pSchema);
2672 freeTempSpace(pBt);
2673 sqlite3_free(pBt);
2676 #ifndef SQLITE_OMIT_SHARED_CACHE
2677 assert( p->wantToLock==0 );
2678 assert( p->locked==0 );
2679 if( p->pPrev ) p->pPrev->pNext = p->pNext;
2680 if( p->pNext ) p->pNext->pPrev = p->pPrev;
2681 #endif
2683 sqlite3_free(p);
2684 return SQLITE_OK;
2688 ** Change the "soft" limit on the number of pages in the cache.
2689 ** Unused and unmodified pages will be recycled when the number of
2690 ** pages in the cache exceeds this soft limit. But the size of the
2691 ** cache is allowed to grow larger than this limit if it contains
2692 ** dirty pages or pages still in active use.
2694 int sqlite3BtreeSetCacheSize(Btree *p, int mxPage){
2695 BtShared *pBt = p->pBt;
2696 assert( sqlite3_mutex_held(p->db->mutex) );
2697 sqlite3BtreeEnter(p);
2698 sqlite3PagerSetCachesize(pBt->pPager, mxPage);
2699 sqlite3BtreeLeave(p);
2700 return SQLITE_OK;
2704 ** Change the "spill" limit on the number of pages in the cache.
2705 ** If the number of pages exceeds this limit during a write transaction,
2706 ** the pager might attempt to "spill" pages to the journal early in
2707 ** order to free up memory.
2709 ** The value returned is the current spill size. If zero is passed
2710 ** as an argument, no changes are made to the spill size setting, so
2711 ** using mxPage of 0 is a way to query the current spill size.
2713 int sqlite3BtreeSetSpillSize(Btree *p, int mxPage){
2714 BtShared *pBt = p->pBt;
2715 int res;
2716 assert( sqlite3_mutex_held(p->db->mutex) );
2717 sqlite3BtreeEnter(p);
2718 res = sqlite3PagerSetSpillsize(pBt->pPager, mxPage);
2719 sqlite3BtreeLeave(p);
2720 return res;
2723 #if SQLITE_MAX_MMAP_SIZE>0
2725 ** Change the limit on the amount of the database file that may be
2726 ** memory mapped.
2728 int sqlite3BtreeSetMmapLimit(Btree *p, sqlite3_int64 szMmap){
2729 BtShared *pBt = p->pBt;
2730 assert( sqlite3_mutex_held(p->db->mutex) );
2731 sqlite3BtreeEnter(p);
2732 sqlite3PagerSetMmapLimit(pBt->pPager, szMmap);
2733 sqlite3BtreeLeave(p);
2734 return SQLITE_OK;
2736 #endif /* SQLITE_MAX_MMAP_SIZE>0 */
2739 ** Change the way data is synced to disk in order to increase or decrease
2740 ** how well the database resists damage due to OS crashes and power
2741 ** failures. Level 1 is the same as asynchronous (no syncs() occur and
2742 ** there is a high probability of damage) Level 2 is the default. There
2743 ** is a very low but non-zero probability of damage. Level 3 reduces the
2744 ** probability of damage to near zero but with a write performance reduction.
2746 #ifndef SQLITE_OMIT_PAGER_PRAGMAS
2747 int sqlite3BtreeSetPagerFlags(
2748 Btree *p, /* The btree to set the safety level on */
2749 unsigned pgFlags /* Various PAGER_* flags */
2751 BtShared *pBt = p->pBt;
2752 assert( sqlite3_mutex_held(p->db->mutex) );
2753 sqlite3BtreeEnter(p);
2754 sqlite3PagerSetFlags(pBt->pPager, pgFlags);
2755 sqlite3BtreeLeave(p);
2756 return SQLITE_OK;
2758 #endif
2761 ** Change the default pages size and the number of reserved bytes per page.
2762 ** Or, if the page size has already been fixed, return SQLITE_READONLY
2763 ** without changing anything.
2765 ** The page size must be a power of 2 between 512 and 65536. If the page
2766 ** size supplied does not meet this constraint then the page size is not
2767 ** changed.
2769 ** Page sizes are constrained to be a power of two so that the region
2770 ** of the database file used for locking (beginning at PENDING_BYTE,
2771 ** the first byte past the 1GB boundary, 0x40000000) needs to occur
2772 ** at the beginning of a page.
2774 ** If parameter nReserve is less than zero, then the number of reserved
2775 ** bytes per page is left unchanged.
2777 ** If the iFix!=0 then the BTS_PAGESIZE_FIXED flag is set so that the page size
2778 ** and autovacuum mode can no longer be changed.
2780 int sqlite3BtreeSetPageSize(Btree *p, int pageSize, int nReserve, int iFix){
2781 int rc = SQLITE_OK;
2782 BtShared *pBt = p->pBt;
2783 assert( nReserve>=-1 && nReserve<=255 );
2784 sqlite3BtreeEnter(p);
2785 #if SQLITE_HAS_CODEC
2786 if( nReserve>pBt->optimalReserve ) pBt->optimalReserve = (u8)nReserve;
2787 #endif
2788 if( pBt->btsFlags & BTS_PAGESIZE_FIXED ){
2789 sqlite3BtreeLeave(p);
2790 return SQLITE_READONLY;
2792 if( nReserve<0 ){
2793 nReserve = pBt->pageSize - pBt->usableSize;
2795 assert( nReserve>=0 && nReserve<=255 );
2796 if( pageSize>=512 && pageSize<=SQLITE_MAX_PAGE_SIZE &&
2797 ((pageSize-1)&pageSize)==0 ){
2798 assert( (pageSize & 7)==0 );
2799 assert( !pBt->pCursor );
2800 pBt->pageSize = (u32)pageSize;
2801 freeTempSpace(pBt);
2803 rc = sqlite3PagerSetPagesize(pBt->pPager, &pBt->pageSize, nReserve);
2804 pBt->usableSize = pBt->pageSize - (u16)nReserve;
2805 if( iFix ) pBt->btsFlags |= BTS_PAGESIZE_FIXED;
2806 sqlite3BtreeLeave(p);
2807 return rc;
2811 ** Return the currently defined page size
2813 int sqlite3BtreeGetPageSize(Btree *p){
2814 return p->pBt->pageSize;
2818 ** This function is similar to sqlite3BtreeGetReserve(), except that it
2819 ** may only be called if it is guaranteed that the b-tree mutex is already
2820 ** held.
2822 ** This is useful in one special case in the backup API code where it is
2823 ** known that the shared b-tree mutex is held, but the mutex on the
2824 ** database handle that owns *p is not. In this case if sqlite3BtreeEnter()
2825 ** were to be called, it might collide with some other operation on the
2826 ** database handle that owns *p, causing undefined behavior.
2828 int sqlite3BtreeGetReserveNoMutex(Btree *p){
2829 int n;
2830 assert( sqlite3_mutex_held(p->pBt->mutex) );
2831 n = p->pBt->pageSize - p->pBt->usableSize;
2832 return n;
2836 ** Return the number of bytes of space at the end of every page that
2837 ** are intentually left unused. This is the "reserved" space that is
2838 ** sometimes used by extensions.
2840 ** If SQLITE_HAS_MUTEX is defined then the number returned is the
2841 ** greater of the current reserved space and the maximum requested
2842 ** reserve space.
2844 int sqlite3BtreeGetOptimalReserve(Btree *p){
2845 int n;
2846 sqlite3BtreeEnter(p);
2847 n = sqlite3BtreeGetReserveNoMutex(p);
2848 #ifdef SQLITE_HAS_CODEC
2849 if( n<p->pBt->optimalReserve ) n = p->pBt->optimalReserve;
2850 #endif
2851 sqlite3BtreeLeave(p);
2852 return n;
2857 ** Set the maximum page count for a database if mxPage is positive.
2858 ** No changes are made if mxPage is 0 or negative.
2859 ** Regardless of the value of mxPage, return the maximum page count.
2861 int sqlite3BtreeMaxPageCount(Btree *p, int mxPage){
2862 int n;
2863 sqlite3BtreeEnter(p);
2864 n = sqlite3PagerMaxPageCount(p->pBt->pPager, mxPage);
2865 sqlite3BtreeLeave(p);
2866 return n;
2870 ** Change the values for the BTS_SECURE_DELETE and BTS_OVERWRITE flags:
2872 ** newFlag==0 Both BTS_SECURE_DELETE and BTS_OVERWRITE are cleared
2873 ** newFlag==1 BTS_SECURE_DELETE set and BTS_OVERWRITE is cleared
2874 ** newFlag==2 BTS_SECURE_DELETE cleared and BTS_OVERWRITE is set
2875 ** newFlag==(-1) No changes
2877 ** This routine acts as a query if newFlag is less than zero
2879 ** With BTS_OVERWRITE set, deleted content is overwritten by zeros, but
2880 ** freelist leaf pages are not written back to the database. Thus in-page
2881 ** deleted content is cleared, but freelist deleted content is not.
2883 ** With BTS_SECURE_DELETE, operation is like BTS_OVERWRITE with the addition
2884 ** that freelist leaf pages are written back into the database, increasing
2885 ** the amount of disk I/O.
2887 int sqlite3BtreeSecureDelete(Btree *p, int newFlag){
2888 int b;
2889 if( p==0 ) return 0;
2890 sqlite3BtreeEnter(p);
2891 assert( BTS_OVERWRITE==BTS_SECURE_DELETE*2 );
2892 assert( BTS_FAST_SECURE==(BTS_OVERWRITE|BTS_SECURE_DELETE) );
2893 if( newFlag>=0 ){
2894 p->pBt->btsFlags &= ~BTS_FAST_SECURE;
2895 p->pBt->btsFlags |= BTS_SECURE_DELETE*newFlag;
2897 b = (p->pBt->btsFlags & BTS_FAST_SECURE)/BTS_SECURE_DELETE;
2898 sqlite3BtreeLeave(p);
2899 return b;
2903 ** Change the 'auto-vacuum' property of the database. If the 'autoVacuum'
2904 ** parameter is non-zero, then auto-vacuum mode is enabled. If zero, it
2905 ** is disabled. The default value for the auto-vacuum property is
2906 ** determined by the SQLITE_DEFAULT_AUTOVACUUM macro.
2908 int sqlite3BtreeSetAutoVacuum(Btree *p, int autoVacuum){
2909 #ifdef SQLITE_OMIT_AUTOVACUUM
2910 return SQLITE_READONLY;
2911 #else
2912 BtShared *pBt = p->pBt;
2913 int rc = SQLITE_OK;
2914 u8 av = (u8)autoVacuum;
2916 sqlite3BtreeEnter(p);
2917 if( (pBt->btsFlags & BTS_PAGESIZE_FIXED)!=0 && (av ?1:0)!=pBt->autoVacuum ){
2918 rc = SQLITE_READONLY;
2919 }else{
2920 pBt->autoVacuum = av ?1:0;
2921 pBt->incrVacuum = av==2 ?1:0;
2923 sqlite3BtreeLeave(p);
2924 return rc;
2925 #endif
2929 ** Return the value of the 'auto-vacuum' property. If auto-vacuum is
2930 ** enabled 1 is returned. Otherwise 0.
2932 int sqlite3BtreeGetAutoVacuum(Btree *p){
2933 #ifdef SQLITE_OMIT_AUTOVACUUM
2934 return BTREE_AUTOVACUUM_NONE;
2935 #else
2936 int rc;
2937 sqlite3BtreeEnter(p);
2938 rc = (
2939 (!p->pBt->autoVacuum)?BTREE_AUTOVACUUM_NONE:
2940 (!p->pBt->incrVacuum)?BTREE_AUTOVACUUM_FULL:
2941 BTREE_AUTOVACUUM_INCR
2943 sqlite3BtreeLeave(p);
2944 return rc;
2945 #endif
2949 ** If the user has not set the safety-level for this database connection
2950 ** using "PRAGMA synchronous", and if the safety-level is not already
2951 ** set to the value passed to this function as the second parameter,
2952 ** set it so.
2954 #if SQLITE_DEFAULT_SYNCHRONOUS!=SQLITE_DEFAULT_WAL_SYNCHRONOUS \
2955 && !defined(SQLITE_OMIT_WAL)
2956 static void setDefaultSyncFlag(BtShared *pBt, u8 safety_level){
2957 sqlite3 *db;
2958 Db *pDb;
2959 if( (db=pBt->db)!=0 && (pDb=db->aDb)!=0 ){
2960 while( pDb->pBt==0 || pDb->pBt->pBt!=pBt ){ pDb++; }
2961 if( pDb->bSyncSet==0
2962 && pDb->safety_level!=safety_level
2963 && pDb!=&db->aDb[1]
2965 pDb->safety_level = safety_level;
2966 sqlite3PagerSetFlags(pBt->pPager,
2967 pDb->safety_level | (db->flags & PAGER_FLAGS_MASK));
2971 #else
2972 # define setDefaultSyncFlag(pBt,safety_level)
2973 #endif
2975 /* Forward declaration */
2976 static int newDatabase(BtShared*);
2980 ** Get a reference to pPage1 of the database file. This will
2981 ** also acquire a readlock on that file.
2983 ** SQLITE_OK is returned on success. If the file is not a
2984 ** well-formed database file, then SQLITE_CORRUPT is returned.
2985 ** SQLITE_BUSY is returned if the database is locked. SQLITE_NOMEM
2986 ** is returned if we run out of memory.
2988 static int lockBtree(BtShared *pBt){
2989 int rc; /* Result code from subfunctions */
2990 MemPage *pPage1; /* Page 1 of the database file */
2991 int nPage; /* Number of pages in the database */
2992 int nPageFile = 0; /* Number of pages in the database file */
2993 int nPageHeader; /* Number of pages in the database according to hdr */
2995 assert( sqlite3_mutex_held(pBt->mutex) );
2996 assert( pBt->pPage1==0 );
2997 rc = sqlite3PagerSharedLock(pBt->pPager);
2998 if( rc!=SQLITE_OK ) return rc;
2999 rc = btreeGetPage(pBt, 1, &pPage1, 0);
3000 if( rc!=SQLITE_OK ) return rc;
3002 /* Do some checking to help insure the file we opened really is
3003 ** a valid database file.
3005 nPage = nPageHeader = get4byte(28+(u8*)pPage1->aData);
3006 sqlite3PagerPagecount(pBt->pPager, &nPageFile);
3007 if( nPage==0 || memcmp(24+(u8*)pPage1->aData, 92+(u8*)pPage1->aData,4)!=0 ){
3008 nPage = nPageFile;
3010 if( (pBt->db->flags & SQLITE_ResetDatabase)!=0 ){
3011 nPage = 0;
3013 if( nPage>0 ){
3014 u32 pageSize;
3015 u32 usableSize;
3016 u8 *page1 = pPage1->aData;
3017 rc = SQLITE_NOTADB;
3018 /* EVIDENCE-OF: R-43737-39999 Every valid SQLite database file begins
3019 ** with the following 16 bytes (in hex): 53 51 4c 69 74 65 20 66 6f 72 6d
3020 ** 61 74 20 33 00. */
3021 if( memcmp(page1, zMagicHeader, 16)!=0 ){
3022 goto page1_init_failed;
3025 #ifdef SQLITE_OMIT_WAL
3026 if( page1[18]>1 ){
3027 pBt->btsFlags |= BTS_READ_ONLY;
3029 if( page1[19]>1 ){
3030 goto page1_init_failed;
3032 #else
3033 if( page1[18]>2 ){
3034 pBt->btsFlags |= BTS_READ_ONLY;
3036 if( page1[19]>2 ){
3037 goto page1_init_failed;
3040 /* If the write version is set to 2, this database should be accessed
3041 ** in WAL mode. If the log is not already open, open it now. Then
3042 ** return SQLITE_OK and return without populating BtShared.pPage1.
3043 ** The caller detects this and calls this function again. This is
3044 ** required as the version of page 1 currently in the page1 buffer
3045 ** may not be the latest version - there may be a newer one in the log
3046 ** file.
3048 if( page1[19]==2 && (pBt->btsFlags & BTS_NO_WAL)==0 ){
3049 int isOpen = 0;
3050 rc = sqlite3PagerOpenWal(pBt->pPager, &isOpen);
3051 if( rc!=SQLITE_OK ){
3052 goto page1_init_failed;
3053 }else{
3054 setDefaultSyncFlag(pBt, SQLITE_DEFAULT_WAL_SYNCHRONOUS+1);
3055 if( isOpen==0 ){
3056 releasePageOne(pPage1);
3057 return SQLITE_OK;
3060 rc = SQLITE_NOTADB;
3061 }else{
3062 setDefaultSyncFlag(pBt, SQLITE_DEFAULT_SYNCHRONOUS+1);
3064 #endif
3066 /* EVIDENCE-OF: R-15465-20813 The maximum and minimum embedded payload
3067 ** fractions and the leaf payload fraction values must be 64, 32, and 32.
3069 ** The original design allowed these amounts to vary, but as of
3070 ** version 3.6.0, we require them to be fixed.
3072 if( memcmp(&page1[21], "\100\040\040",3)!=0 ){
3073 goto page1_init_failed;
3075 /* EVIDENCE-OF: R-51873-39618 The page size for a database file is
3076 ** determined by the 2-byte integer located at an offset of 16 bytes from
3077 ** the beginning of the database file. */
3078 pageSize = (page1[16]<<8) | (page1[17]<<16);
3079 /* EVIDENCE-OF: R-25008-21688 The size of a page is a power of two
3080 ** between 512 and 65536 inclusive. */
3081 if( ((pageSize-1)&pageSize)!=0
3082 || pageSize>SQLITE_MAX_PAGE_SIZE
3083 || pageSize<=256
3085 goto page1_init_failed;
3087 assert( (pageSize & 7)==0 );
3088 /* EVIDENCE-OF: R-59310-51205 The "reserved space" size in the 1-byte
3089 ** integer at offset 20 is the number of bytes of space at the end of
3090 ** each page to reserve for extensions.
3092 ** EVIDENCE-OF: R-37497-42412 The size of the reserved region is
3093 ** determined by the one-byte unsigned integer found at an offset of 20
3094 ** into the database file header. */
3095 usableSize = pageSize - page1[20];
3096 if( (u32)pageSize!=pBt->pageSize ){
3097 /* After reading the first page of the database assuming a page size
3098 ** of BtShared.pageSize, we have discovered that the page-size is
3099 ** actually pageSize. Unlock the database, leave pBt->pPage1 at
3100 ** zero and return SQLITE_OK. The caller will call this function
3101 ** again with the correct page-size.
3103 releasePageOne(pPage1);
3104 pBt->usableSize = usableSize;
3105 pBt->pageSize = pageSize;
3106 freeTempSpace(pBt);
3107 rc = sqlite3PagerSetPagesize(pBt->pPager, &pBt->pageSize,
3108 pageSize-usableSize);
3109 return rc;
3111 if( (pBt->db->flags & SQLITE_WriteSchema)==0 && nPage>nPageFile ){
3112 rc = SQLITE_CORRUPT_BKPT;
3113 goto page1_init_failed;
3115 /* EVIDENCE-OF: R-28312-64704 However, the usable size is not allowed to
3116 ** be less than 480. In other words, if the page size is 512, then the
3117 ** reserved space size cannot exceed 32. */
3118 if( usableSize<480 ){
3119 goto page1_init_failed;
3121 pBt->pageSize = pageSize;
3122 pBt->usableSize = usableSize;
3123 #ifndef SQLITE_OMIT_AUTOVACUUM
3124 pBt->autoVacuum = (get4byte(&page1[36 + 4*4])?1:0);
3125 pBt->incrVacuum = (get4byte(&page1[36 + 7*4])?1:0);
3126 #endif
3129 /* maxLocal is the maximum amount of payload to store locally for
3130 ** a cell. Make sure it is small enough so that at least minFanout
3131 ** cells can will fit on one page. We assume a 10-byte page header.
3132 ** Besides the payload, the cell must store:
3133 ** 2-byte pointer to the cell
3134 ** 4-byte child pointer
3135 ** 9-byte nKey value
3136 ** 4-byte nData value
3137 ** 4-byte overflow page pointer
3138 ** So a cell consists of a 2-byte pointer, a header which is as much as
3139 ** 17 bytes long, 0 to N bytes of payload, and an optional 4 byte overflow
3140 ** page pointer.
3142 pBt->maxLocal = (u16)((pBt->usableSize-12)*64/255 - 23);
3143 pBt->minLocal = (u16)((pBt->usableSize-12)*32/255 - 23);
3144 pBt->maxLeaf = (u16)(pBt->usableSize - 35);
3145 pBt->minLeaf = (u16)((pBt->usableSize-12)*32/255 - 23);
3146 if( pBt->maxLocal>127 ){
3147 pBt->max1bytePayload = 127;
3148 }else{
3149 pBt->max1bytePayload = (u8)pBt->maxLocal;
3151 assert( pBt->maxLeaf + 23 <= MX_CELL_SIZE(pBt) );
3152 pBt->pPage1 = pPage1;
3153 pBt->nPage = nPage;
3154 return SQLITE_OK;
3156 page1_init_failed:
3157 releasePageOne(pPage1);
3158 pBt->pPage1 = 0;
3159 return rc;
3162 #ifndef NDEBUG
3164 ** Return the number of cursors open on pBt. This is for use
3165 ** in assert() expressions, so it is only compiled if NDEBUG is not
3166 ** defined.
3168 ** Only write cursors are counted if wrOnly is true. If wrOnly is
3169 ** false then all cursors are counted.
3171 ** For the purposes of this routine, a cursor is any cursor that
3172 ** is capable of reading or writing to the database. Cursors that
3173 ** have been tripped into the CURSOR_FAULT state are not counted.
3175 static int countValidCursors(BtShared *pBt, int wrOnly){
3176 BtCursor *pCur;
3177 int r = 0;
3178 for(pCur=pBt->pCursor; pCur; pCur=pCur->pNext){
3179 if( (wrOnly==0 || (pCur->curFlags & BTCF_WriteFlag)!=0)
3180 && pCur->eState!=CURSOR_FAULT ) r++;
3182 return r;
3184 #endif
3187 ** If there are no outstanding cursors and we are not in the middle
3188 ** of a transaction but there is a read lock on the database, then
3189 ** this routine unrefs the first page of the database file which
3190 ** has the effect of releasing the read lock.
3192 ** If there is a transaction in progress, this routine is a no-op.
3194 static void unlockBtreeIfUnused(BtShared *pBt){
3195 assert( sqlite3_mutex_held(pBt->mutex) );
3196 assert( countValidCursors(pBt,0)==0 || pBt->inTransaction>TRANS_NONE );
3197 if( pBt->inTransaction==TRANS_NONE && pBt->pPage1!=0 ){
3198 MemPage *pPage1 = pBt->pPage1;
3199 assert( pPage1->aData );
3200 assert( sqlite3PagerRefcount(pBt->pPager)==1 );
3201 pBt->pPage1 = 0;
3202 releasePageOne(pPage1);
3207 ** If pBt points to an empty file then convert that empty file
3208 ** into a new empty database by initializing the first page of
3209 ** the database.
3211 static int newDatabase(BtShared *pBt){
3212 MemPage *pP1;
3213 unsigned char *data;
3214 int rc;
3216 assert( sqlite3_mutex_held(pBt->mutex) );
3217 if( pBt->nPage>0 ){
3218 return SQLITE_OK;
3220 pP1 = pBt->pPage1;
3221 assert( pP1!=0 );
3222 data = pP1->aData;
3223 rc = sqlite3PagerWrite(pP1->pDbPage);
3224 if( rc ) return rc;
3225 memcpy(data, zMagicHeader, sizeof(zMagicHeader));
3226 assert( sizeof(zMagicHeader)==16 );
3227 data[16] = (u8)((pBt->pageSize>>8)&0xff);
3228 data[17] = (u8)((pBt->pageSize>>16)&0xff);
3229 data[18] = 1;
3230 data[19] = 1;
3231 assert( pBt->usableSize<=pBt->pageSize && pBt->usableSize+255>=pBt->pageSize);
3232 data[20] = (u8)(pBt->pageSize - pBt->usableSize);
3233 data[21] = 64;
3234 data[22] = 32;
3235 data[23] = 32;
3236 memset(&data[24], 0, 100-24);
3237 zeroPage(pP1, PTF_INTKEY|PTF_LEAF|PTF_LEAFDATA );
3238 pBt->btsFlags |= BTS_PAGESIZE_FIXED;
3239 #ifndef SQLITE_OMIT_AUTOVACUUM
3240 assert( pBt->autoVacuum==1 || pBt->autoVacuum==0 );
3241 assert( pBt->incrVacuum==1 || pBt->incrVacuum==0 );
3242 put4byte(&data[36 + 4*4], pBt->autoVacuum);
3243 put4byte(&data[36 + 7*4], pBt->incrVacuum);
3244 #endif
3245 pBt->nPage = 1;
3246 data[31] = 1;
3247 return SQLITE_OK;
3251 ** Initialize the first page of the database file (creating a database
3252 ** consisting of a single page and no schema objects). Return SQLITE_OK
3253 ** if successful, or an SQLite error code otherwise.
3255 int sqlite3BtreeNewDb(Btree *p){
3256 int rc;
3257 sqlite3BtreeEnter(p);
3258 p->pBt->nPage = 0;
3259 rc = newDatabase(p->pBt);
3260 sqlite3BtreeLeave(p);
3261 return rc;
3265 ** Attempt to start a new transaction. A write-transaction
3266 ** is started if the second argument is nonzero, otherwise a read-
3267 ** transaction. If the second argument is 2 or more and exclusive
3268 ** transaction is started, meaning that no other process is allowed
3269 ** to access the database. A preexisting transaction may not be
3270 ** upgraded to exclusive by calling this routine a second time - the
3271 ** exclusivity flag only works for a new transaction.
3273 ** A write-transaction must be started before attempting any
3274 ** changes to the database. None of the following routines
3275 ** will work unless a transaction is started first:
3277 ** sqlite3BtreeCreateTable()
3278 ** sqlite3BtreeCreateIndex()
3279 ** sqlite3BtreeClearTable()
3280 ** sqlite3BtreeDropTable()
3281 ** sqlite3BtreeInsert()
3282 ** sqlite3BtreeDelete()
3283 ** sqlite3BtreeUpdateMeta()
3285 ** If an initial attempt to acquire the lock fails because of lock contention
3286 ** and the database was previously unlocked, then invoke the busy handler
3287 ** if there is one. But if there was previously a read-lock, do not
3288 ** invoke the busy handler - just return SQLITE_BUSY. SQLITE_BUSY is
3289 ** returned when there is already a read-lock in order to avoid a deadlock.
3291 ** Suppose there are two processes A and B. A has a read lock and B has
3292 ** a reserved lock. B tries to promote to exclusive but is blocked because
3293 ** of A's read lock. A tries to promote to reserved but is blocked by B.
3294 ** One or the other of the two processes must give way or there can be
3295 ** no progress. By returning SQLITE_BUSY and not invoking the busy callback
3296 ** when A already has a read lock, we encourage A to give up and let B
3297 ** proceed.
3299 int sqlite3BtreeBeginTrans(Btree *p, int wrflag){
3300 BtShared *pBt = p->pBt;
3301 int rc = SQLITE_OK;
3303 sqlite3BtreeEnter(p);
3304 btreeIntegrity(p);
3306 /* If the btree is already in a write-transaction, or it
3307 ** is already in a read-transaction and a read-transaction
3308 ** is requested, this is a no-op.
3310 if( p->inTrans==TRANS_WRITE || (p->inTrans==TRANS_READ && !wrflag) ){
3311 goto trans_begun;
3313 assert( pBt->inTransaction==TRANS_WRITE || IfNotOmitAV(pBt->bDoTruncate)==0 );
3315 /* Write transactions are not possible on a read-only database */
3316 if( (pBt->btsFlags & BTS_READ_ONLY)!=0 && wrflag ){
3317 rc = SQLITE_READONLY;
3318 goto trans_begun;
3321 #ifndef SQLITE_OMIT_SHARED_CACHE
3323 sqlite3 *pBlock = 0;
3324 /* If another database handle has already opened a write transaction
3325 ** on this shared-btree structure and a second write transaction is
3326 ** requested, return SQLITE_LOCKED.
3328 if( (wrflag && pBt->inTransaction==TRANS_WRITE)
3329 || (pBt->btsFlags & BTS_PENDING)!=0
3331 pBlock = pBt->pWriter->db;
3332 }else if( wrflag>1 ){
3333 BtLock *pIter;
3334 for(pIter=pBt->pLock; pIter; pIter=pIter->pNext){
3335 if( pIter->pBtree!=p ){
3336 pBlock = pIter->pBtree->db;
3337 break;
3341 if( pBlock ){
3342 sqlite3ConnectionBlocked(p->db, pBlock);
3343 rc = SQLITE_LOCKED_SHAREDCACHE;
3344 goto trans_begun;
3347 #endif
3349 /* Any read-only or read-write transaction implies a read-lock on
3350 ** page 1. So if some other shared-cache client already has a write-lock
3351 ** on page 1, the transaction cannot be opened. */
3352 rc = querySharedCacheTableLock(p, MASTER_ROOT, READ_LOCK);
3353 if( SQLITE_OK!=rc ) goto trans_begun;
3355 pBt->btsFlags &= ~BTS_INITIALLY_EMPTY;
3356 if( pBt->nPage==0 ) pBt->btsFlags |= BTS_INITIALLY_EMPTY;
3357 do {
3358 /* Call lockBtree() until either pBt->pPage1 is populated or
3359 ** lockBtree() returns something other than SQLITE_OK. lockBtree()
3360 ** may return SQLITE_OK but leave pBt->pPage1 set to 0 if after
3361 ** reading page 1 it discovers that the page-size of the database
3362 ** file is not pBt->pageSize. In this case lockBtree() will update
3363 ** pBt->pageSize to the page-size of the file on disk.
3365 while( pBt->pPage1==0 && SQLITE_OK==(rc = lockBtree(pBt)) );
3367 if( rc==SQLITE_OK && wrflag ){
3368 if( (pBt->btsFlags & BTS_READ_ONLY)!=0 ){
3369 rc = SQLITE_READONLY;
3370 }else{
3371 rc = sqlite3PagerBegin(pBt->pPager,wrflag>1,sqlite3TempInMemory(p->db));
3372 if( rc==SQLITE_OK ){
3373 rc = newDatabase(pBt);
3378 if( rc!=SQLITE_OK ){
3379 unlockBtreeIfUnused(pBt);
3381 }while( (rc&0xFF)==SQLITE_BUSY && pBt->inTransaction==TRANS_NONE &&
3382 btreeInvokeBusyHandler(pBt) );
3383 sqlite3PagerResetLockTimeout(pBt->pPager);
3385 if( rc==SQLITE_OK ){
3386 if( p->inTrans==TRANS_NONE ){
3387 pBt->nTransaction++;
3388 #ifndef SQLITE_OMIT_SHARED_CACHE
3389 if( p->sharable ){
3390 assert( p->lock.pBtree==p && p->lock.iTable==1 );
3391 p->lock.eLock = READ_LOCK;
3392 p->lock.pNext = pBt->pLock;
3393 pBt->pLock = &p->lock;
3395 #endif
3397 p->inTrans = (wrflag?TRANS_WRITE:TRANS_READ);
3398 if( p->inTrans>pBt->inTransaction ){
3399 pBt->inTransaction = p->inTrans;
3401 if( wrflag ){
3402 MemPage *pPage1 = pBt->pPage1;
3403 #ifndef SQLITE_OMIT_SHARED_CACHE
3404 assert( !pBt->pWriter );
3405 pBt->pWriter = p;
3406 pBt->btsFlags &= ~BTS_EXCLUSIVE;
3407 if( wrflag>1 ) pBt->btsFlags |= BTS_EXCLUSIVE;
3408 #endif
3410 /* If the db-size header field is incorrect (as it may be if an old
3411 ** client has been writing the database file), update it now. Doing
3412 ** this sooner rather than later means the database size can safely
3413 ** re-read the database size from page 1 if a savepoint or transaction
3414 ** rollback occurs within the transaction.
3416 if( pBt->nPage!=get4byte(&pPage1->aData[28]) ){
3417 rc = sqlite3PagerWrite(pPage1->pDbPage);
3418 if( rc==SQLITE_OK ){
3419 put4byte(&pPage1->aData[28], pBt->nPage);
3426 trans_begun:
3427 if( rc==SQLITE_OK && wrflag ){
3428 /* This call makes sure that the pager has the correct number of
3429 ** open savepoints. If the second parameter is greater than 0 and
3430 ** the sub-journal is not already open, then it will be opened here.
3432 rc = sqlite3PagerOpenSavepoint(pBt->pPager, p->db->nSavepoint);
3435 btreeIntegrity(p);
3436 sqlite3BtreeLeave(p);
3437 return rc;
3440 #ifndef SQLITE_OMIT_AUTOVACUUM
3443 ** Set the pointer-map entries for all children of page pPage. Also, if
3444 ** pPage contains cells that point to overflow pages, set the pointer
3445 ** map entries for the overflow pages as well.
3447 static int setChildPtrmaps(MemPage *pPage){
3448 int i; /* Counter variable */
3449 int nCell; /* Number of cells in page pPage */
3450 int rc; /* Return code */
3451 BtShared *pBt = pPage->pBt;
3452 Pgno pgno = pPage->pgno;
3454 assert( sqlite3_mutex_held(pPage->pBt->mutex) );
3455 rc = pPage->isInit ? SQLITE_OK : btreeInitPage(pPage);
3456 if( rc!=SQLITE_OK ) return rc;
3457 nCell = pPage->nCell;
3459 for(i=0; i<nCell; i++){
3460 u8 *pCell = findCell(pPage, i);
3462 ptrmapPutOvflPtr(pPage, pCell, &rc);
3464 if( !pPage->leaf ){
3465 Pgno childPgno = get4byte(pCell);
3466 ptrmapPut(pBt, childPgno, PTRMAP_BTREE, pgno, &rc);
3470 if( !pPage->leaf ){
3471 Pgno childPgno = get4byte(&pPage->aData[pPage->hdrOffset+8]);
3472 ptrmapPut(pBt, childPgno, PTRMAP_BTREE, pgno, &rc);
3475 return rc;
3479 ** Somewhere on pPage is a pointer to page iFrom. Modify this pointer so
3480 ** that it points to iTo. Parameter eType describes the type of pointer to
3481 ** be modified, as follows:
3483 ** PTRMAP_BTREE: pPage is a btree-page. The pointer points at a child
3484 ** page of pPage.
3486 ** PTRMAP_OVERFLOW1: pPage is a btree-page. The pointer points at an overflow
3487 ** page pointed to by one of the cells on pPage.
3489 ** PTRMAP_OVERFLOW2: pPage is an overflow-page. The pointer points at the next
3490 ** overflow page in the list.
3492 static int modifyPagePointer(MemPage *pPage, Pgno iFrom, Pgno iTo, u8 eType){
3493 assert( sqlite3_mutex_held(pPage->pBt->mutex) );
3494 assert( sqlite3PagerIswriteable(pPage->pDbPage) );
3495 if( eType==PTRMAP_OVERFLOW2 ){
3496 /* The pointer is always the first 4 bytes of the page in this case. */
3497 if( get4byte(pPage->aData)!=iFrom ){
3498 return SQLITE_CORRUPT_PAGE(pPage);
3500 put4byte(pPage->aData, iTo);
3501 }else{
3502 int i;
3503 int nCell;
3504 int rc;
3506 rc = pPage->isInit ? SQLITE_OK : btreeInitPage(pPage);
3507 if( rc ) return rc;
3508 nCell = pPage->nCell;
3510 for(i=0; i<nCell; i++){
3511 u8 *pCell = findCell(pPage, i);
3512 if( eType==PTRMAP_OVERFLOW1 ){
3513 CellInfo info;
3514 pPage->xParseCell(pPage, pCell, &info);
3515 if( info.nLocal<info.nPayload ){
3516 if( pCell+info.nSize > pPage->aData+pPage->pBt->usableSize ){
3517 return SQLITE_CORRUPT_PAGE(pPage);
3519 if( iFrom==get4byte(pCell+info.nSize-4) ){
3520 put4byte(pCell+info.nSize-4, iTo);
3521 break;
3524 }else{
3525 if( get4byte(pCell)==iFrom ){
3526 put4byte(pCell, iTo);
3527 break;
3532 if( i==nCell ){
3533 if( eType!=PTRMAP_BTREE ||
3534 get4byte(&pPage->aData[pPage->hdrOffset+8])!=iFrom ){
3535 return SQLITE_CORRUPT_PAGE(pPage);
3537 put4byte(&pPage->aData[pPage->hdrOffset+8], iTo);
3540 return SQLITE_OK;
3545 ** Move the open database page pDbPage to location iFreePage in the
3546 ** database. The pDbPage reference remains valid.
3548 ** The isCommit flag indicates that there is no need to remember that
3549 ** the journal needs to be sync()ed before database page pDbPage->pgno
3550 ** can be written to. The caller has already promised not to write to that
3551 ** page.
3553 static int relocatePage(
3554 BtShared *pBt, /* Btree */
3555 MemPage *pDbPage, /* Open page to move */
3556 u8 eType, /* Pointer map 'type' entry for pDbPage */
3557 Pgno iPtrPage, /* Pointer map 'page-no' entry for pDbPage */
3558 Pgno iFreePage, /* The location to move pDbPage to */
3559 int isCommit /* isCommit flag passed to sqlite3PagerMovepage */
3561 MemPage *pPtrPage; /* The page that contains a pointer to pDbPage */
3562 Pgno iDbPage = pDbPage->pgno;
3563 Pager *pPager = pBt->pPager;
3564 int rc;
3566 assert( eType==PTRMAP_OVERFLOW2 || eType==PTRMAP_OVERFLOW1 ||
3567 eType==PTRMAP_BTREE || eType==PTRMAP_ROOTPAGE );
3568 assert( sqlite3_mutex_held(pBt->mutex) );
3569 assert( pDbPage->pBt==pBt );
3571 /* Move page iDbPage from its current location to page number iFreePage */
3572 TRACE(("AUTOVACUUM: Moving %d to free page %d (ptr page %d type %d)\n",
3573 iDbPage, iFreePage, iPtrPage, eType));
3574 rc = sqlite3PagerMovepage(pPager, pDbPage->pDbPage, iFreePage, isCommit);
3575 if( rc!=SQLITE_OK ){
3576 return rc;
3578 pDbPage->pgno = iFreePage;
3580 /* If pDbPage was a btree-page, then it may have child pages and/or cells
3581 ** that point to overflow pages. The pointer map entries for all these
3582 ** pages need to be changed.
3584 ** If pDbPage is an overflow page, then the first 4 bytes may store a
3585 ** pointer to a subsequent overflow page. If this is the case, then
3586 ** the pointer map needs to be updated for the subsequent overflow page.
3588 if( eType==PTRMAP_BTREE || eType==PTRMAP_ROOTPAGE ){
3589 rc = setChildPtrmaps(pDbPage);
3590 if( rc!=SQLITE_OK ){
3591 return rc;
3593 }else{
3594 Pgno nextOvfl = get4byte(pDbPage->aData);
3595 if( nextOvfl!=0 ){
3596 ptrmapPut(pBt, nextOvfl, PTRMAP_OVERFLOW2, iFreePage, &rc);
3597 if( rc!=SQLITE_OK ){
3598 return rc;
3603 /* Fix the database pointer on page iPtrPage that pointed at iDbPage so
3604 ** that it points at iFreePage. Also fix the pointer map entry for
3605 ** iPtrPage.
3607 if( eType!=PTRMAP_ROOTPAGE ){
3608 rc = btreeGetPage(pBt, iPtrPage, &pPtrPage, 0);
3609 if( rc!=SQLITE_OK ){
3610 return rc;
3612 rc = sqlite3PagerWrite(pPtrPage->pDbPage);
3613 if( rc!=SQLITE_OK ){
3614 releasePage(pPtrPage);
3615 return rc;
3617 rc = modifyPagePointer(pPtrPage, iDbPage, iFreePage, eType);
3618 releasePage(pPtrPage);
3619 if( rc==SQLITE_OK ){
3620 ptrmapPut(pBt, iFreePage, eType, iPtrPage, &rc);
3623 return rc;
3626 /* Forward declaration required by incrVacuumStep(). */
3627 static int allocateBtreePage(BtShared *, MemPage **, Pgno *, Pgno, u8);
3630 ** Perform a single step of an incremental-vacuum. If successful, return
3631 ** SQLITE_OK. If there is no work to do (and therefore no point in
3632 ** calling this function again), return SQLITE_DONE. Or, if an error
3633 ** occurs, return some other error code.
3635 ** More specifically, this function attempts to re-organize the database so
3636 ** that the last page of the file currently in use is no longer in use.
3638 ** Parameter nFin is the number of pages that this database would contain
3639 ** were this function called until it returns SQLITE_DONE.
3641 ** If the bCommit parameter is non-zero, this function assumes that the
3642 ** caller will keep calling incrVacuumStep() until it returns SQLITE_DONE
3643 ** or an error. bCommit is passed true for an auto-vacuum-on-commit
3644 ** operation, or false for an incremental vacuum.
3646 static int incrVacuumStep(BtShared *pBt, Pgno nFin, Pgno iLastPg, int bCommit){
3647 Pgno nFreeList; /* Number of pages still on the free-list */
3648 int rc;
3650 assert( sqlite3_mutex_held(pBt->mutex) );
3651 assert( iLastPg>nFin );
3653 if( !PTRMAP_ISPAGE(pBt, iLastPg) && iLastPg!=PENDING_BYTE_PAGE(pBt) ){
3654 u8 eType;
3655 Pgno iPtrPage;
3657 nFreeList = get4byte(&pBt->pPage1->aData[36]);
3658 if( nFreeList==0 ){
3659 return SQLITE_DONE;
3662 rc = ptrmapGet(pBt, iLastPg, &eType, &iPtrPage);
3663 if( rc!=SQLITE_OK ){
3664 return rc;
3666 if( eType==PTRMAP_ROOTPAGE ){
3667 return SQLITE_CORRUPT_BKPT;
3670 if( eType==PTRMAP_FREEPAGE ){
3671 if( bCommit==0 ){
3672 /* Remove the page from the files free-list. This is not required
3673 ** if bCommit is non-zero. In that case, the free-list will be
3674 ** truncated to zero after this function returns, so it doesn't
3675 ** matter if it still contains some garbage entries.
3677 Pgno iFreePg;
3678 MemPage *pFreePg;
3679 rc = allocateBtreePage(pBt, &pFreePg, &iFreePg, iLastPg, BTALLOC_EXACT);
3680 if( rc!=SQLITE_OK ){
3681 return rc;
3683 assert( iFreePg==iLastPg );
3684 releasePage(pFreePg);
3686 } else {
3687 Pgno iFreePg; /* Index of free page to move pLastPg to */
3688 MemPage *pLastPg;
3689 u8 eMode = BTALLOC_ANY; /* Mode parameter for allocateBtreePage() */
3690 Pgno iNear = 0; /* nearby parameter for allocateBtreePage() */
3692 rc = btreeGetPage(pBt, iLastPg, &pLastPg, 0);
3693 if( rc!=SQLITE_OK ){
3694 return rc;
3697 /* If bCommit is zero, this loop runs exactly once and page pLastPg
3698 ** is swapped with the first free page pulled off the free list.
3700 ** On the other hand, if bCommit is greater than zero, then keep
3701 ** looping until a free-page located within the first nFin pages
3702 ** of the file is found.
3704 if( bCommit==0 ){
3705 eMode = BTALLOC_LE;
3706 iNear = nFin;
3708 do {
3709 MemPage *pFreePg;
3710 rc = allocateBtreePage(pBt, &pFreePg, &iFreePg, iNear, eMode);
3711 if( rc!=SQLITE_OK ){
3712 releasePage(pLastPg);
3713 return rc;
3715 releasePage(pFreePg);
3716 }while( bCommit && iFreePg>nFin );
3717 assert( iFreePg<iLastPg );
3719 rc = relocatePage(pBt, pLastPg, eType, iPtrPage, iFreePg, bCommit);
3720 releasePage(pLastPg);
3721 if( rc!=SQLITE_OK ){
3722 return rc;
3727 if( bCommit==0 ){
3728 do {
3729 iLastPg--;
3730 }while( iLastPg==PENDING_BYTE_PAGE(pBt) || PTRMAP_ISPAGE(pBt, iLastPg) );
3731 pBt->bDoTruncate = 1;
3732 pBt->nPage = iLastPg;
3734 return SQLITE_OK;
3738 ** The database opened by the first argument is an auto-vacuum database
3739 ** nOrig pages in size containing nFree free pages. Return the expected
3740 ** size of the database in pages following an auto-vacuum operation.
3742 static Pgno finalDbSize(BtShared *pBt, Pgno nOrig, Pgno nFree){
3743 int nEntry; /* Number of entries on one ptrmap page */
3744 Pgno nPtrmap; /* Number of PtrMap pages to be freed */
3745 Pgno nFin; /* Return value */
3747 nEntry = pBt->usableSize/5;
3748 nPtrmap = (nFree-nOrig+PTRMAP_PAGENO(pBt, nOrig)+nEntry)/nEntry;
3749 nFin = nOrig - nFree - nPtrmap;
3750 if( nOrig>PENDING_BYTE_PAGE(pBt) && nFin<PENDING_BYTE_PAGE(pBt) ){
3751 nFin--;
3753 while( PTRMAP_ISPAGE(pBt, nFin) || nFin==PENDING_BYTE_PAGE(pBt) ){
3754 nFin--;
3757 return nFin;
3761 ** A write-transaction must be opened before calling this function.
3762 ** It performs a single unit of work towards an incremental vacuum.
3764 ** If the incremental vacuum is finished after this function has run,
3765 ** SQLITE_DONE is returned. If it is not finished, but no error occurred,
3766 ** SQLITE_OK is returned. Otherwise an SQLite error code.
3768 int sqlite3BtreeIncrVacuum(Btree *p){
3769 int rc;
3770 BtShared *pBt = p->pBt;
3772 sqlite3BtreeEnter(p);
3773 assert( pBt->inTransaction==TRANS_WRITE && p->inTrans==TRANS_WRITE );
3774 if( !pBt->autoVacuum ){
3775 rc = SQLITE_DONE;
3776 }else{
3777 Pgno nOrig = btreePagecount(pBt);
3778 Pgno nFree = get4byte(&pBt->pPage1->aData[36]);
3779 Pgno nFin = finalDbSize(pBt, nOrig, nFree);
3781 if( nOrig<nFin ){
3782 rc = SQLITE_CORRUPT_BKPT;
3783 }else if( nFree>0 ){
3784 rc = saveAllCursors(pBt, 0, 0);
3785 if( rc==SQLITE_OK ){
3786 invalidateAllOverflowCache(pBt);
3787 rc = incrVacuumStep(pBt, nFin, nOrig, 0);
3789 if( rc==SQLITE_OK ){
3790 rc = sqlite3PagerWrite(pBt->pPage1->pDbPage);
3791 put4byte(&pBt->pPage1->aData[28], pBt->nPage);
3793 }else{
3794 rc = SQLITE_DONE;
3797 sqlite3BtreeLeave(p);
3798 return rc;
3802 ** This routine is called prior to sqlite3PagerCommit when a transaction
3803 ** is committed for an auto-vacuum database.
3805 ** If SQLITE_OK is returned, then *pnTrunc is set to the number of pages
3806 ** the database file should be truncated to during the commit process.
3807 ** i.e. the database has been reorganized so that only the first *pnTrunc
3808 ** pages are in use.
3810 static int autoVacuumCommit(BtShared *pBt){
3811 int rc = SQLITE_OK;
3812 Pager *pPager = pBt->pPager;
3813 VVA_ONLY( int nRef = sqlite3PagerRefcount(pPager); )
3815 assert( sqlite3_mutex_held(pBt->mutex) );
3816 invalidateAllOverflowCache(pBt);
3817 assert(pBt->autoVacuum);
3818 if( !pBt->incrVacuum ){
3819 Pgno nFin; /* Number of pages in database after autovacuuming */
3820 Pgno nFree; /* Number of pages on the freelist initially */
3821 Pgno iFree; /* The next page to be freed */
3822 Pgno nOrig; /* Database size before freeing */
3824 nOrig = btreePagecount(pBt);
3825 if( PTRMAP_ISPAGE(pBt, nOrig) || nOrig==PENDING_BYTE_PAGE(pBt) ){
3826 /* It is not possible to create a database for which the final page
3827 ** is either a pointer-map page or the pending-byte page. If one
3828 ** is encountered, this indicates corruption.
3830 return SQLITE_CORRUPT_BKPT;
3833 nFree = get4byte(&pBt->pPage1->aData[36]);
3834 nFin = finalDbSize(pBt, nOrig, nFree);
3835 if( nFin>nOrig ) return SQLITE_CORRUPT_BKPT;
3836 if( nFin<nOrig ){
3837 rc = saveAllCursors(pBt, 0, 0);
3839 for(iFree=nOrig; iFree>nFin && rc==SQLITE_OK; iFree--){
3840 rc = incrVacuumStep(pBt, nFin, iFree, 1);
3842 if( (rc==SQLITE_DONE || rc==SQLITE_OK) && nFree>0 ){
3843 rc = sqlite3PagerWrite(pBt->pPage1->pDbPage);
3844 put4byte(&pBt->pPage1->aData[32], 0);
3845 put4byte(&pBt->pPage1->aData[36], 0);
3846 put4byte(&pBt->pPage1->aData[28], nFin);
3847 pBt->bDoTruncate = 1;
3848 pBt->nPage = nFin;
3850 if( rc!=SQLITE_OK ){
3851 sqlite3PagerRollback(pPager);
3855 assert( nRef>=sqlite3PagerRefcount(pPager) );
3856 return rc;
3859 #else /* ifndef SQLITE_OMIT_AUTOVACUUM */
3860 # define setChildPtrmaps(x) SQLITE_OK
3861 #endif
3864 ** This routine does the first phase of a two-phase commit. This routine
3865 ** causes a rollback journal to be created (if it does not already exist)
3866 ** and populated with enough information so that if a power loss occurs
3867 ** the database can be restored to its original state by playing back
3868 ** the journal. Then the contents of the journal are flushed out to
3869 ** the disk. After the journal is safely on oxide, the changes to the
3870 ** database are written into the database file and flushed to oxide.
3871 ** At the end of this call, the rollback journal still exists on the
3872 ** disk and we are still holding all locks, so the transaction has not
3873 ** committed. See sqlite3BtreeCommitPhaseTwo() for the second phase of the
3874 ** commit process.
3876 ** This call is a no-op if no write-transaction is currently active on pBt.
3878 ** Otherwise, sync the database file for the btree pBt. zMaster points to
3879 ** the name of a master journal file that should be written into the
3880 ** individual journal file, or is NULL, indicating no master journal file
3881 ** (single database transaction).
3883 ** When this is called, the master journal should already have been
3884 ** created, populated with this journal pointer and synced to disk.
3886 ** Once this is routine has returned, the only thing required to commit
3887 ** the write-transaction for this database file is to delete the journal.
3889 int sqlite3BtreeCommitPhaseOne(Btree *p, const char *zMaster){
3890 int rc = SQLITE_OK;
3891 if( p->inTrans==TRANS_WRITE ){
3892 BtShared *pBt = p->pBt;
3893 sqlite3BtreeEnter(p);
3894 #ifndef SQLITE_OMIT_AUTOVACUUM
3895 if( pBt->autoVacuum ){
3896 rc = autoVacuumCommit(pBt);
3897 if( rc!=SQLITE_OK ){
3898 sqlite3BtreeLeave(p);
3899 return rc;
3902 if( pBt->bDoTruncate ){
3903 sqlite3PagerTruncateImage(pBt->pPager, pBt->nPage);
3905 #endif
3906 rc = sqlite3PagerCommitPhaseOne(pBt->pPager, zMaster, 0);
3907 sqlite3BtreeLeave(p);
3909 return rc;
3913 ** This function is called from both BtreeCommitPhaseTwo() and BtreeRollback()
3914 ** at the conclusion of a transaction.
3916 static void btreeEndTransaction(Btree *p){
3917 BtShared *pBt = p->pBt;
3918 sqlite3 *db = p->db;
3919 assert( sqlite3BtreeHoldsMutex(p) );
3921 #ifndef SQLITE_OMIT_AUTOVACUUM
3922 pBt->bDoTruncate = 0;
3923 #endif
3924 if( p->inTrans>TRANS_NONE && db->nVdbeRead>1 ){
3925 /* If there are other active statements that belong to this database
3926 ** handle, downgrade to a read-only transaction. The other statements
3927 ** may still be reading from the database. */
3928 downgradeAllSharedCacheTableLocks(p);
3929 p->inTrans = TRANS_READ;
3930 }else{
3931 /* If the handle had any kind of transaction open, decrement the
3932 ** transaction count of the shared btree. If the transaction count
3933 ** reaches 0, set the shared state to TRANS_NONE. The unlockBtreeIfUnused()
3934 ** call below will unlock the pager. */
3935 if( p->inTrans!=TRANS_NONE ){
3936 clearAllSharedCacheTableLocks(p);
3937 pBt->nTransaction--;
3938 if( 0==pBt->nTransaction ){
3939 pBt->inTransaction = TRANS_NONE;
3943 /* Set the current transaction state to TRANS_NONE and unlock the
3944 ** pager if this call closed the only read or write transaction. */
3945 p->inTrans = TRANS_NONE;
3946 unlockBtreeIfUnused(pBt);
3949 btreeIntegrity(p);
3953 ** Commit the transaction currently in progress.
3955 ** This routine implements the second phase of a 2-phase commit. The
3956 ** sqlite3BtreeCommitPhaseOne() routine does the first phase and should
3957 ** be invoked prior to calling this routine. The sqlite3BtreeCommitPhaseOne()
3958 ** routine did all the work of writing information out to disk and flushing the
3959 ** contents so that they are written onto the disk platter. All this
3960 ** routine has to do is delete or truncate or zero the header in the
3961 ** the rollback journal (which causes the transaction to commit) and
3962 ** drop locks.
3964 ** Normally, if an error occurs while the pager layer is attempting to
3965 ** finalize the underlying journal file, this function returns an error and
3966 ** the upper layer will attempt a rollback. However, if the second argument
3967 ** is non-zero then this b-tree transaction is part of a multi-file
3968 ** transaction. In this case, the transaction has already been committed
3969 ** (by deleting a master journal file) and the caller will ignore this
3970 ** functions return code. So, even if an error occurs in the pager layer,
3971 ** reset the b-tree objects internal state to indicate that the write
3972 ** transaction has been closed. This is quite safe, as the pager will have
3973 ** transitioned to the error state.
3975 ** This will release the write lock on the database file. If there
3976 ** are no active cursors, it also releases the read lock.
3978 int sqlite3BtreeCommitPhaseTwo(Btree *p, int bCleanup){
3980 if( p->inTrans==TRANS_NONE ) return SQLITE_OK;
3981 sqlite3BtreeEnter(p);
3982 btreeIntegrity(p);
3984 /* If the handle has a write-transaction open, commit the shared-btrees
3985 ** transaction and set the shared state to TRANS_READ.
3987 if( p->inTrans==TRANS_WRITE ){
3988 int rc;
3989 BtShared *pBt = p->pBt;
3990 assert( pBt->inTransaction==TRANS_WRITE );
3991 assert( pBt->nTransaction>0 );
3992 rc = sqlite3PagerCommitPhaseTwo(pBt->pPager);
3993 if( rc!=SQLITE_OK && bCleanup==0 ){
3994 sqlite3BtreeLeave(p);
3995 return rc;
3997 p->iDataVersion--; /* Compensate for pPager->iDataVersion++; */
3998 pBt->inTransaction = TRANS_READ;
3999 btreeClearHasContent(pBt);
4002 btreeEndTransaction(p);
4003 sqlite3BtreeLeave(p);
4004 return SQLITE_OK;
4008 ** Do both phases of a commit.
4010 int sqlite3BtreeCommit(Btree *p){
4011 int rc;
4012 sqlite3BtreeEnter(p);
4013 rc = sqlite3BtreeCommitPhaseOne(p, 0);
4014 if( rc==SQLITE_OK ){
4015 rc = sqlite3BtreeCommitPhaseTwo(p, 0);
4017 sqlite3BtreeLeave(p);
4018 return rc;
4022 ** This routine sets the state to CURSOR_FAULT and the error
4023 ** code to errCode for every cursor on any BtShared that pBtree
4024 ** references. Or if the writeOnly flag is set to 1, then only
4025 ** trip write cursors and leave read cursors unchanged.
4027 ** Every cursor is a candidate to be tripped, including cursors
4028 ** that belong to other database connections that happen to be
4029 ** sharing the cache with pBtree.
4031 ** This routine gets called when a rollback occurs. If the writeOnly
4032 ** flag is true, then only write-cursors need be tripped - read-only
4033 ** cursors save their current positions so that they may continue
4034 ** following the rollback. Or, if writeOnly is false, all cursors are
4035 ** tripped. In general, writeOnly is false if the transaction being
4036 ** rolled back modified the database schema. In this case b-tree root
4037 ** pages may be moved or deleted from the database altogether, making
4038 ** it unsafe for read cursors to continue.
4040 ** If the writeOnly flag is true and an error is encountered while
4041 ** saving the current position of a read-only cursor, all cursors,
4042 ** including all read-cursors are tripped.
4044 ** SQLITE_OK is returned if successful, or if an error occurs while
4045 ** saving a cursor position, an SQLite error code.
4047 int sqlite3BtreeTripAllCursors(Btree *pBtree, int errCode, int writeOnly){
4048 BtCursor *p;
4049 int rc = SQLITE_OK;
4051 assert( (writeOnly==0 || writeOnly==1) && BTCF_WriteFlag==1 );
4052 if( pBtree ){
4053 sqlite3BtreeEnter(pBtree);
4054 for(p=pBtree->pBt->pCursor; p; p=p->pNext){
4055 if( writeOnly && (p->curFlags & BTCF_WriteFlag)==0 ){
4056 if( p->eState==CURSOR_VALID || p->eState==CURSOR_SKIPNEXT ){
4057 rc = saveCursorPosition(p);
4058 if( rc!=SQLITE_OK ){
4059 (void)sqlite3BtreeTripAllCursors(pBtree, rc, 0);
4060 break;
4063 }else{
4064 sqlite3BtreeClearCursor(p);
4065 p->eState = CURSOR_FAULT;
4066 p->skipNext = errCode;
4068 btreeReleaseAllCursorPages(p);
4070 sqlite3BtreeLeave(pBtree);
4072 return rc;
4076 ** Rollback the transaction in progress.
4078 ** If tripCode is not SQLITE_OK then cursors will be invalidated (tripped).
4079 ** Only write cursors are tripped if writeOnly is true but all cursors are
4080 ** tripped if writeOnly is false. Any attempt to use
4081 ** a tripped cursor will result in an error.
4083 ** This will release the write lock on the database file. If there
4084 ** are no active cursors, it also releases the read lock.
4086 int sqlite3BtreeRollback(Btree *p, int tripCode, int writeOnly){
4087 int rc;
4088 BtShared *pBt = p->pBt;
4089 MemPage *pPage1;
4091 assert( writeOnly==1 || writeOnly==0 );
4092 assert( tripCode==SQLITE_ABORT_ROLLBACK || tripCode==SQLITE_OK );
4093 sqlite3BtreeEnter(p);
4094 if( tripCode==SQLITE_OK ){
4095 rc = tripCode = saveAllCursors(pBt, 0, 0);
4096 if( rc ) writeOnly = 0;
4097 }else{
4098 rc = SQLITE_OK;
4100 if( tripCode ){
4101 int rc2 = sqlite3BtreeTripAllCursors(p, tripCode, writeOnly);
4102 assert( rc==SQLITE_OK || (writeOnly==0 && rc2==SQLITE_OK) );
4103 if( rc2!=SQLITE_OK ) rc = rc2;
4105 btreeIntegrity(p);
4107 if( p->inTrans==TRANS_WRITE ){
4108 int rc2;
4110 assert( TRANS_WRITE==pBt->inTransaction );
4111 rc2 = sqlite3PagerRollback(pBt->pPager);
4112 if( rc2!=SQLITE_OK ){
4113 rc = rc2;
4116 /* The rollback may have destroyed the pPage1->aData value. So
4117 ** call btreeGetPage() on page 1 again to make
4118 ** sure pPage1->aData is set correctly. */
4119 if( btreeGetPage(pBt, 1, &pPage1, 0)==SQLITE_OK ){
4120 int nPage = get4byte(28+(u8*)pPage1->aData);
4121 testcase( nPage==0 );
4122 if( nPage==0 ) sqlite3PagerPagecount(pBt->pPager, &nPage);
4123 testcase( pBt->nPage!=nPage );
4124 pBt->nPage = nPage;
4125 releasePageOne(pPage1);
4127 assert( countValidCursors(pBt, 1)==0 );
4128 pBt->inTransaction = TRANS_READ;
4129 btreeClearHasContent(pBt);
4132 btreeEndTransaction(p);
4133 sqlite3BtreeLeave(p);
4134 return rc;
4138 ** Start a statement subtransaction. The subtransaction can be rolled
4139 ** back independently of the main transaction. You must start a transaction
4140 ** before starting a subtransaction. The subtransaction is ended automatically
4141 ** if the main transaction commits or rolls back.
4143 ** Statement subtransactions are used around individual SQL statements
4144 ** that are contained within a BEGIN...COMMIT block. If a constraint
4145 ** error occurs within the statement, the effect of that one statement
4146 ** can be rolled back without having to rollback the entire transaction.
4148 ** A statement sub-transaction is implemented as an anonymous savepoint. The
4149 ** value passed as the second parameter is the total number of savepoints,
4150 ** including the new anonymous savepoint, open on the B-Tree. i.e. if there
4151 ** are no active savepoints and no other statement-transactions open,
4152 ** iStatement is 1. This anonymous savepoint can be released or rolled back
4153 ** using the sqlite3BtreeSavepoint() function.
4155 int sqlite3BtreeBeginStmt(Btree *p, int iStatement){
4156 int rc;
4157 BtShared *pBt = p->pBt;
4158 sqlite3BtreeEnter(p);
4159 assert( p->inTrans==TRANS_WRITE );
4160 assert( (pBt->btsFlags & BTS_READ_ONLY)==0 );
4161 assert( iStatement>0 );
4162 assert( iStatement>p->db->nSavepoint );
4163 assert( pBt->inTransaction==TRANS_WRITE );
4164 /* At the pager level, a statement transaction is a savepoint with
4165 ** an index greater than all savepoints created explicitly using
4166 ** SQL statements. It is illegal to open, release or rollback any
4167 ** such savepoints while the statement transaction savepoint is active.
4169 rc = sqlite3PagerOpenSavepoint(pBt->pPager, iStatement);
4170 sqlite3BtreeLeave(p);
4171 return rc;
4175 ** The second argument to this function, op, is always SAVEPOINT_ROLLBACK
4176 ** or SAVEPOINT_RELEASE. This function either releases or rolls back the
4177 ** savepoint identified by parameter iSavepoint, depending on the value
4178 ** of op.
4180 ** Normally, iSavepoint is greater than or equal to zero. However, if op is
4181 ** SAVEPOINT_ROLLBACK, then iSavepoint may also be -1. In this case the
4182 ** contents of the entire transaction are rolled back. This is different
4183 ** from a normal transaction rollback, as no locks are released and the
4184 ** transaction remains open.
4186 int sqlite3BtreeSavepoint(Btree *p, int op, int iSavepoint){
4187 int rc = SQLITE_OK;
4188 if( p && p->inTrans==TRANS_WRITE ){
4189 BtShared *pBt = p->pBt;
4190 assert( op==SAVEPOINT_RELEASE || op==SAVEPOINT_ROLLBACK );
4191 assert( iSavepoint>=0 || (iSavepoint==-1 && op==SAVEPOINT_ROLLBACK) );
4192 sqlite3BtreeEnter(p);
4193 if( op==SAVEPOINT_ROLLBACK ){
4194 rc = saveAllCursors(pBt, 0, 0);
4196 if( rc==SQLITE_OK ){
4197 rc = sqlite3PagerSavepoint(pBt->pPager, op, iSavepoint);
4199 if( rc==SQLITE_OK ){
4200 if( iSavepoint<0 && (pBt->btsFlags & BTS_INITIALLY_EMPTY)!=0 ){
4201 pBt->nPage = 0;
4203 rc = newDatabase(pBt);
4204 pBt->nPage = get4byte(28 + pBt->pPage1->aData);
4206 /* The database size was written into the offset 28 of the header
4207 ** when the transaction started, so we know that the value at offset
4208 ** 28 is nonzero. */
4209 assert( pBt->nPage>0 );
4211 sqlite3BtreeLeave(p);
4213 return rc;
4217 ** Create a new cursor for the BTree whose root is on the page
4218 ** iTable. If a read-only cursor is requested, it is assumed that
4219 ** the caller already has at least a read-only transaction open
4220 ** on the database already. If a write-cursor is requested, then
4221 ** the caller is assumed to have an open write transaction.
4223 ** If the BTREE_WRCSR bit of wrFlag is clear, then the cursor can only
4224 ** be used for reading. If the BTREE_WRCSR bit is set, then the cursor
4225 ** can be used for reading or for writing if other conditions for writing
4226 ** are also met. These are the conditions that must be met in order
4227 ** for writing to be allowed:
4229 ** 1: The cursor must have been opened with wrFlag containing BTREE_WRCSR
4231 ** 2: Other database connections that share the same pager cache
4232 ** but which are not in the READ_UNCOMMITTED state may not have
4233 ** cursors open with wrFlag==0 on the same table. Otherwise
4234 ** the changes made by this write cursor would be visible to
4235 ** the read cursors in the other database connection.
4237 ** 3: The database must be writable (not on read-only media)
4239 ** 4: There must be an active transaction.
4241 ** The BTREE_FORDELETE bit of wrFlag may optionally be set if BTREE_WRCSR
4242 ** is set. If FORDELETE is set, that is a hint to the implementation that
4243 ** this cursor will only be used to seek to and delete entries of an index
4244 ** as part of a larger DELETE statement. The FORDELETE hint is not used by
4245 ** this implementation. But in a hypothetical alternative storage engine
4246 ** in which index entries are automatically deleted when corresponding table
4247 ** rows are deleted, the FORDELETE flag is a hint that all SEEK and DELETE
4248 ** operations on this cursor can be no-ops and all READ operations can
4249 ** return a null row (2-bytes: 0x01 0x00).
4251 ** No checking is done to make sure that page iTable really is the
4252 ** root page of a b-tree. If it is not, then the cursor acquired
4253 ** will not work correctly.
4255 ** It is assumed that the sqlite3BtreeCursorZero() has been called
4256 ** on pCur to initialize the memory space prior to invoking this routine.
4258 static int btreeCursor(
4259 Btree *p, /* The btree */
4260 int iTable, /* Root page of table to open */
4261 int wrFlag, /* 1 to write. 0 read-only */
4262 struct KeyInfo *pKeyInfo, /* First arg to comparison function */
4263 BtCursor *pCur /* Space for new cursor */
4265 BtShared *pBt = p->pBt; /* Shared b-tree handle */
4266 BtCursor *pX; /* Looping over other all cursors */
4268 assert( sqlite3BtreeHoldsMutex(p) );
4269 assert( wrFlag==0
4270 || wrFlag==BTREE_WRCSR
4271 || wrFlag==(BTREE_WRCSR|BTREE_FORDELETE)
4274 /* The following assert statements verify that if this is a sharable
4275 ** b-tree database, the connection is holding the required table locks,
4276 ** and that no other connection has any open cursor that conflicts with
4277 ** this lock. */
4278 assert( hasSharedCacheTableLock(p, iTable, pKeyInfo!=0, (wrFlag?2:1)) );
4279 assert( wrFlag==0 || !hasReadConflicts(p, iTable) );
4281 /* Assert that the caller has opened the required transaction. */
4282 assert( p->inTrans>TRANS_NONE );
4283 assert( wrFlag==0 || p->inTrans==TRANS_WRITE );
4284 assert( pBt->pPage1 && pBt->pPage1->aData );
4285 assert( wrFlag==0 || (pBt->btsFlags & BTS_READ_ONLY)==0 );
4287 if( wrFlag ){
4288 allocateTempSpace(pBt);
4289 if( pBt->pTmpSpace==0 ) return SQLITE_NOMEM_BKPT;
4291 if( iTable==1 && btreePagecount(pBt)==0 ){
4292 assert( wrFlag==0 );
4293 iTable = 0;
4296 /* Now that no other errors can occur, finish filling in the BtCursor
4297 ** variables and link the cursor into the BtShared list. */
4298 pCur->pgnoRoot = (Pgno)iTable;
4299 pCur->iPage = -1;
4300 pCur->pKeyInfo = pKeyInfo;
4301 pCur->pBtree = p;
4302 pCur->pBt = pBt;
4303 pCur->curFlags = wrFlag ? BTCF_WriteFlag : 0;
4304 pCur->curPagerFlags = wrFlag ? 0 : PAGER_GET_READONLY;
4305 /* If there are two or more cursors on the same btree, then all such
4306 ** cursors *must* have the BTCF_Multiple flag set. */
4307 for(pX=pBt->pCursor; pX; pX=pX->pNext){
4308 if( pX->pgnoRoot==(Pgno)iTable ){
4309 pX->curFlags |= BTCF_Multiple;
4310 pCur->curFlags |= BTCF_Multiple;
4313 pCur->pNext = pBt->pCursor;
4314 pBt->pCursor = pCur;
4315 pCur->eState = CURSOR_INVALID;
4316 return SQLITE_OK;
4318 int sqlite3BtreeCursor(
4319 Btree *p, /* The btree */
4320 int iTable, /* Root page of table to open */
4321 int wrFlag, /* 1 to write. 0 read-only */
4322 struct KeyInfo *pKeyInfo, /* First arg to xCompare() */
4323 BtCursor *pCur /* Write new cursor here */
4325 int rc;
4326 if( iTable<1 ){
4327 rc = SQLITE_CORRUPT_BKPT;
4328 }else{
4329 sqlite3BtreeEnter(p);
4330 rc = btreeCursor(p, iTable, wrFlag, pKeyInfo, pCur);
4331 sqlite3BtreeLeave(p);
4333 return rc;
4337 ** Return the size of a BtCursor object in bytes.
4339 ** This interfaces is needed so that users of cursors can preallocate
4340 ** sufficient storage to hold a cursor. The BtCursor object is opaque
4341 ** to users so they cannot do the sizeof() themselves - they must call
4342 ** this routine.
4344 int sqlite3BtreeCursorSize(void){
4345 return ROUND8(sizeof(BtCursor));
4349 ** Initialize memory that will be converted into a BtCursor object.
4351 ** The simple approach here would be to memset() the entire object
4352 ** to zero. But it turns out that the apPage[] and aiIdx[] arrays
4353 ** do not need to be zeroed and they are large, so we can save a lot
4354 ** of run-time by skipping the initialization of those elements.
4356 void sqlite3BtreeCursorZero(BtCursor *p){
4357 memset(p, 0, offsetof(BtCursor, BTCURSOR_FIRST_UNINIT));
4361 ** Close a cursor. The read lock on the database file is released
4362 ** when the last cursor is closed.
4364 int sqlite3BtreeCloseCursor(BtCursor *pCur){
4365 Btree *pBtree = pCur->pBtree;
4366 if( pBtree ){
4367 BtShared *pBt = pCur->pBt;
4368 sqlite3BtreeEnter(pBtree);
4369 assert( pBt->pCursor!=0 );
4370 if( pBt->pCursor==pCur ){
4371 pBt->pCursor = pCur->pNext;
4372 }else{
4373 BtCursor *pPrev = pBt->pCursor;
4375 if( pPrev->pNext==pCur ){
4376 pPrev->pNext = pCur->pNext;
4377 break;
4379 pPrev = pPrev->pNext;
4380 }while( ALWAYS(pPrev) );
4382 btreeReleaseAllCursorPages(pCur);
4383 unlockBtreeIfUnused(pBt);
4384 sqlite3_free(pCur->aOverflow);
4385 sqlite3_free(pCur->pKey);
4386 sqlite3BtreeLeave(pBtree);
4388 return SQLITE_OK;
4392 ** Make sure the BtCursor* given in the argument has a valid
4393 ** BtCursor.info structure. If it is not already valid, call
4394 ** btreeParseCell() to fill it in.
4396 ** BtCursor.info is a cache of the information in the current cell.
4397 ** Using this cache reduces the number of calls to btreeParseCell().
4399 #ifndef NDEBUG
4400 static int cellInfoEqual(CellInfo *a, CellInfo *b){
4401 if( a->nKey!=b->nKey ) return 0;
4402 if( a->pPayload!=b->pPayload ) return 0;
4403 if( a->nPayload!=b->nPayload ) return 0;
4404 if( a->nLocal!=b->nLocal ) return 0;
4405 if( a->nSize!=b->nSize ) return 0;
4406 return 1;
4408 static void assertCellInfo(BtCursor *pCur){
4409 CellInfo info;
4410 memset(&info, 0, sizeof(info));
4411 btreeParseCell(pCur->pPage, pCur->ix, &info);
4412 assert( CORRUPT_DB || cellInfoEqual(&info, &pCur->info) );
4414 #else
4415 #define assertCellInfo(x)
4416 #endif
4417 static SQLITE_NOINLINE void getCellInfo(BtCursor *pCur){
4418 if( pCur->info.nSize==0 ){
4419 pCur->curFlags |= BTCF_ValidNKey;
4420 btreeParseCell(pCur->pPage,pCur->ix,&pCur->info);
4421 }else{
4422 assertCellInfo(pCur);
4426 #ifndef NDEBUG /* The next routine used only within assert() statements */
4428 ** Return true if the given BtCursor is valid. A valid cursor is one
4429 ** that is currently pointing to a row in a (non-empty) table.
4430 ** This is a verification routine is used only within assert() statements.
4432 int sqlite3BtreeCursorIsValid(BtCursor *pCur){
4433 return pCur && pCur->eState==CURSOR_VALID;
4435 #endif /* NDEBUG */
4436 int sqlite3BtreeCursorIsValidNN(BtCursor *pCur){
4437 assert( pCur!=0 );
4438 return pCur->eState==CURSOR_VALID;
4442 ** Return the value of the integer key or "rowid" for a table btree.
4443 ** This routine is only valid for a cursor that is pointing into a
4444 ** ordinary table btree. If the cursor points to an index btree or
4445 ** is invalid, the result of this routine is undefined.
4447 i64 sqlite3BtreeIntegerKey(BtCursor *pCur){
4448 assert( cursorHoldsMutex(pCur) );
4449 assert( pCur->eState==CURSOR_VALID );
4450 assert( pCur->curIntKey );
4451 getCellInfo(pCur);
4452 return pCur->info.nKey;
4455 #ifdef SQLITE_ENABLE_OFFSET_SQL_FUNC
4457 ** Return the offset into the database file for the start of the
4458 ** payload to which the cursor is pointing.
4460 i64 sqlite3BtreeOffset(BtCursor *pCur){
4461 assert( cursorHoldsMutex(pCur) );
4462 assert( pCur->eState==CURSOR_VALID );
4463 getCellInfo(pCur);
4464 return (i64)pCur->pBt->pageSize*((i64)pCur->pPage->pgno - 1) +
4465 (i64)(pCur->info.pPayload - pCur->pPage->aData);
4467 #endif /* SQLITE_ENABLE_OFFSET_SQL_FUNC */
4470 ** Return the number of bytes of payload for the entry that pCur is
4471 ** currently pointing to. For table btrees, this will be the amount
4472 ** of data. For index btrees, this will be the size of the key.
4474 ** The caller must guarantee that the cursor is pointing to a non-NULL
4475 ** valid entry. In other words, the calling procedure must guarantee
4476 ** that the cursor has Cursor.eState==CURSOR_VALID.
4478 u32 sqlite3BtreePayloadSize(BtCursor *pCur){
4479 assert( cursorHoldsMutex(pCur) );
4480 assert( pCur->eState==CURSOR_VALID );
4481 getCellInfo(pCur);
4482 return pCur->info.nPayload;
4486 ** Given the page number of an overflow page in the database (parameter
4487 ** ovfl), this function finds the page number of the next page in the
4488 ** linked list of overflow pages. If possible, it uses the auto-vacuum
4489 ** pointer-map data instead of reading the content of page ovfl to do so.
4491 ** If an error occurs an SQLite error code is returned. Otherwise:
4493 ** The page number of the next overflow page in the linked list is
4494 ** written to *pPgnoNext. If page ovfl is the last page in its linked
4495 ** list, *pPgnoNext is set to zero.
4497 ** If ppPage is not NULL, and a reference to the MemPage object corresponding
4498 ** to page number pOvfl was obtained, then *ppPage is set to point to that
4499 ** reference. It is the responsibility of the caller to call releasePage()
4500 ** on *ppPage to free the reference. In no reference was obtained (because
4501 ** the pointer-map was used to obtain the value for *pPgnoNext), then
4502 ** *ppPage is set to zero.
4504 static int getOverflowPage(
4505 BtShared *pBt, /* The database file */
4506 Pgno ovfl, /* Current overflow page number */
4507 MemPage **ppPage, /* OUT: MemPage handle (may be NULL) */
4508 Pgno *pPgnoNext /* OUT: Next overflow page number */
4510 Pgno next = 0;
4511 MemPage *pPage = 0;
4512 int rc = SQLITE_OK;
4514 assert( sqlite3_mutex_held(pBt->mutex) );
4515 assert(pPgnoNext);
4517 #ifndef SQLITE_OMIT_AUTOVACUUM
4518 /* Try to find the next page in the overflow list using the
4519 ** autovacuum pointer-map pages. Guess that the next page in
4520 ** the overflow list is page number (ovfl+1). If that guess turns
4521 ** out to be wrong, fall back to loading the data of page
4522 ** number ovfl to determine the next page number.
4524 if( pBt->autoVacuum ){
4525 Pgno pgno;
4526 Pgno iGuess = ovfl+1;
4527 u8 eType;
4529 while( PTRMAP_ISPAGE(pBt, iGuess) || iGuess==PENDING_BYTE_PAGE(pBt) ){
4530 iGuess++;
4533 if( iGuess<=btreePagecount(pBt) ){
4534 rc = ptrmapGet(pBt, iGuess, &eType, &pgno);
4535 if( rc==SQLITE_OK && eType==PTRMAP_OVERFLOW2 && pgno==ovfl ){
4536 next = iGuess;
4537 rc = SQLITE_DONE;
4541 #endif
4543 assert( next==0 || rc==SQLITE_DONE );
4544 if( rc==SQLITE_OK ){
4545 rc = btreeGetPage(pBt, ovfl, &pPage, (ppPage==0) ? PAGER_GET_READONLY : 0);
4546 assert( rc==SQLITE_OK || pPage==0 );
4547 if( rc==SQLITE_OK ){
4548 next = get4byte(pPage->aData);
4552 *pPgnoNext = next;
4553 if( ppPage ){
4554 *ppPage = pPage;
4555 }else{
4556 releasePage(pPage);
4558 return (rc==SQLITE_DONE ? SQLITE_OK : rc);
4562 ** Copy data from a buffer to a page, or from a page to a buffer.
4564 ** pPayload is a pointer to data stored on database page pDbPage.
4565 ** If argument eOp is false, then nByte bytes of data are copied
4566 ** from pPayload to the buffer pointed at by pBuf. If eOp is true,
4567 ** then sqlite3PagerWrite() is called on pDbPage and nByte bytes
4568 ** of data are copied from the buffer pBuf to pPayload.
4570 ** SQLITE_OK is returned on success, otherwise an error code.
4572 static int copyPayload(
4573 void *pPayload, /* Pointer to page data */
4574 void *pBuf, /* Pointer to buffer */
4575 int nByte, /* Number of bytes to copy */
4576 int eOp, /* 0 -> copy from page, 1 -> copy to page */
4577 DbPage *pDbPage /* Page containing pPayload */
4579 if( eOp ){
4580 /* Copy data from buffer to page (a write operation) */
4581 int rc = sqlite3PagerWrite(pDbPage);
4582 if( rc!=SQLITE_OK ){
4583 return rc;
4585 memcpy(pPayload, pBuf, nByte);
4586 }else{
4587 /* Copy data from page to buffer (a read operation) */
4588 memcpy(pBuf, pPayload, nByte);
4590 return SQLITE_OK;
4594 ** This function is used to read or overwrite payload information
4595 ** for the entry that the pCur cursor is pointing to. The eOp
4596 ** argument is interpreted as follows:
4598 ** 0: The operation is a read. Populate the overflow cache.
4599 ** 1: The operation is a write. Populate the overflow cache.
4601 ** A total of "amt" bytes are read or written beginning at "offset".
4602 ** Data is read to or from the buffer pBuf.
4604 ** The content being read or written might appear on the main page
4605 ** or be scattered out on multiple overflow pages.
4607 ** If the current cursor entry uses one or more overflow pages
4608 ** this function may allocate space for and lazily populate
4609 ** the overflow page-list cache array (BtCursor.aOverflow).
4610 ** Subsequent calls use this cache to make seeking to the supplied offset
4611 ** more efficient.
4613 ** Once an overflow page-list cache has been allocated, it must be
4614 ** invalidated if some other cursor writes to the same table, or if
4615 ** the cursor is moved to a different row. Additionally, in auto-vacuum
4616 ** mode, the following events may invalidate an overflow page-list cache.
4618 ** * An incremental vacuum,
4619 ** * A commit in auto_vacuum="full" mode,
4620 ** * Creating a table (may require moving an overflow page).
4622 static int accessPayload(
4623 BtCursor *pCur, /* Cursor pointing to entry to read from */
4624 u32 offset, /* Begin reading this far into payload */
4625 u32 amt, /* Read this many bytes */
4626 unsigned char *pBuf, /* Write the bytes into this buffer */
4627 int eOp /* zero to read. non-zero to write. */
4629 unsigned char *aPayload;
4630 int rc = SQLITE_OK;
4631 int iIdx = 0;
4632 MemPage *pPage = pCur->pPage; /* Btree page of current entry */
4633 BtShared *pBt = pCur->pBt; /* Btree this cursor belongs to */
4634 #ifdef SQLITE_DIRECT_OVERFLOW_READ
4635 unsigned char * const pBufStart = pBuf; /* Start of original out buffer */
4636 #endif
4638 assert( pPage );
4639 assert( eOp==0 || eOp==1 );
4640 assert( pCur->eState==CURSOR_VALID );
4641 assert( pCur->ix<pPage->nCell );
4642 assert( cursorHoldsMutex(pCur) );
4644 getCellInfo(pCur);
4645 aPayload = pCur->info.pPayload;
4646 assert( offset+amt <= pCur->info.nPayload );
4648 assert( aPayload > pPage->aData );
4649 if( (uptr)(aPayload - pPage->aData) > (pBt->usableSize - pCur->info.nLocal) ){
4650 /* Trying to read or write past the end of the data is an error. The
4651 ** conditional above is really:
4652 ** &aPayload[pCur->info.nLocal] > &pPage->aData[pBt->usableSize]
4653 ** but is recast into its current form to avoid integer overflow problems
4655 return SQLITE_CORRUPT_PAGE(pPage);
4658 /* Check if data must be read/written to/from the btree page itself. */
4659 if( offset<pCur->info.nLocal ){
4660 int a = amt;
4661 if( a+offset>pCur->info.nLocal ){
4662 a = pCur->info.nLocal - offset;
4664 rc = copyPayload(&aPayload[offset], pBuf, a, eOp, pPage->pDbPage);
4665 offset = 0;
4666 pBuf += a;
4667 amt -= a;
4668 }else{
4669 offset -= pCur->info.nLocal;
4673 if( rc==SQLITE_OK && amt>0 ){
4674 const u32 ovflSize = pBt->usableSize - 4; /* Bytes content per ovfl page */
4675 Pgno nextPage;
4677 nextPage = get4byte(&aPayload[pCur->info.nLocal]);
4679 /* If the BtCursor.aOverflow[] has not been allocated, allocate it now.
4681 ** The aOverflow[] array is sized at one entry for each overflow page
4682 ** in the overflow chain. The page number of the first overflow page is
4683 ** stored in aOverflow[0], etc. A value of 0 in the aOverflow[] array
4684 ** means "not yet known" (the cache is lazily populated).
4686 if( (pCur->curFlags & BTCF_ValidOvfl)==0 ){
4687 int nOvfl = (pCur->info.nPayload-pCur->info.nLocal+ovflSize-1)/ovflSize;
4688 if( pCur->aOverflow==0
4689 || nOvfl*(int)sizeof(Pgno) > sqlite3MallocSize(pCur->aOverflow)
4691 Pgno *aNew = (Pgno*)sqlite3Realloc(
4692 pCur->aOverflow, nOvfl*2*sizeof(Pgno)
4694 if( aNew==0 ){
4695 return SQLITE_NOMEM_BKPT;
4696 }else{
4697 pCur->aOverflow = aNew;
4700 memset(pCur->aOverflow, 0, nOvfl*sizeof(Pgno));
4701 pCur->curFlags |= BTCF_ValidOvfl;
4702 }else{
4703 /* If the overflow page-list cache has been allocated and the
4704 ** entry for the first required overflow page is valid, skip
4705 ** directly to it.
4707 if( pCur->aOverflow[offset/ovflSize] ){
4708 iIdx = (offset/ovflSize);
4709 nextPage = pCur->aOverflow[iIdx];
4710 offset = (offset%ovflSize);
4714 assert( rc==SQLITE_OK && amt>0 );
4715 while( nextPage ){
4716 /* If required, populate the overflow page-list cache. */
4717 assert( pCur->aOverflow[iIdx]==0
4718 || pCur->aOverflow[iIdx]==nextPage
4719 || CORRUPT_DB );
4720 pCur->aOverflow[iIdx] = nextPage;
4722 if( offset>=ovflSize ){
4723 /* The only reason to read this page is to obtain the page
4724 ** number for the next page in the overflow chain. The page
4725 ** data is not required. So first try to lookup the overflow
4726 ** page-list cache, if any, then fall back to the getOverflowPage()
4727 ** function.
4729 assert( pCur->curFlags & BTCF_ValidOvfl );
4730 assert( pCur->pBtree->db==pBt->db );
4731 if( pCur->aOverflow[iIdx+1] ){
4732 nextPage = pCur->aOverflow[iIdx+1];
4733 }else{
4734 rc = getOverflowPage(pBt, nextPage, 0, &nextPage);
4736 offset -= ovflSize;
4737 }else{
4738 /* Need to read this page properly. It contains some of the
4739 ** range of data that is being read (eOp==0) or written (eOp!=0).
4741 #ifdef SQLITE_DIRECT_OVERFLOW_READ
4742 sqlite3_file *fd; /* File from which to do direct overflow read */
4743 #endif
4744 int a = amt;
4745 if( a + offset > ovflSize ){
4746 a = ovflSize - offset;
4749 #ifdef SQLITE_DIRECT_OVERFLOW_READ
4750 /* If all the following are true:
4752 ** 1) this is a read operation, and
4753 ** 2) data is required from the start of this overflow page, and
4754 ** 3) there is no open write-transaction, and
4755 ** 4) the database is file-backed, and
4756 ** 5) the page is not in the WAL file
4757 ** 6) at least 4 bytes have already been read into the output buffer
4759 ** then data can be read directly from the database file into the
4760 ** output buffer, bypassing the page-cache altogether. This speeds
4761 ** up loading large records that span many overflow pages.
4763 if( eOp==0 /* (1) */
4764 && offset==0 /* (2) */
4765 && pBt->inTransaction==TRANS_READ /* (3) */
4766 && (fd = sqlite3PagerFile(pBt->pPager))->pMethods /* (4) */
4767 && 0==sqlite3PagerUseWal(pBt->pPager, nextPage) /* (5) */
4768 && &pBuf[-4]>=pBufStart /* (6) */
4770 u8 aSave[4];
4771 u8 *aWrite = &pBuf[-4];
4772 assert( aWrite>=pBufStart ); /* due to (6) */
4773 memcpy(aSave, aWrite, 4);
4774 rc = sqlite3OsRead(fd, aWrite, a+4, (i64)pBt->pageSize*(nextPage-1));
4775 nextPage = get4byte(aWrite);
4776 memcpy(aWrite, aSave, 4);
4777 }else
4778 #endif
4781 DbPage *pDbPage;
4782 rc = sqlite3PagerGet(pBt->pPager, nextPage, &pDbPage,
4783 (eOp==0 ? PAGER_GET_READONLY : 0)
4785 if( rc==SQLITE_OK ){
4786 aPayload = sqlite3PagerGetData(pDbPage);
4787 nextPage = get4byte(aPayload);
4788 rc = copyPayload(&aPayload[offset+4], pBuf, a, eOp, pDbPage);
4789 sqlite3PagerUnref(pDbPage);
4790 offset = 0;
4793 amt -= a;
4794 if( amt==0 ) return rc;
4795 pBuf += a;
4797 if( rc ) break;
4798 iIdx++;
4802 if( rc==SQLITE_OK && amt>0 ){
4803 /* Overflow chain ends prematurely */
4804 return SQLITE_CORRUPT_PAGE(pPage);
4806 return rc;
4810 ** Read part of the payload for the row at which that cursor pCur is currently
4811 ** pointing. "amt" bytes will be transferred into pBuf[]. The transfer
4812 ** begins at "offset".
4814 ** pCur can be pointing to either a table or an index b-tree.
4815 ** If pointing to a table btree, then the content section is read. If
4816 ** pCur is pointing to an index b-tree then the key section is read.
4818 ** For sqlite3BtreePayload(), the caller must ensure that pCur is pointing
4819 ** to a valid row in the table. For sqlite3BtreePayloadChecked(), the
4820 ** cursor might be invalid or might need to be restored before being read.
4822 ** Return SQLITE_OK on success or an error code if anything goes
4823 ** wrong. An error is returned if "offset+amt" is larger than
4824 ** the available payload.
4826 int sqlite3BtreePayload(BtCursor *pCur, u32 offset, u32 amt, void *pBuf){
4827 assert( cursorHoldsMutex(pCur) );
4828 assert( pCur->eState==CURSOR_VALID );
4829 assert( pCur->iPage>=0 && pCur->pPage );
4830 assert( pCur->ix<pCur->pPage->nCell );
4831 return accessPayload(pCur, offset, amt, (unsigned char*)pBuf, 0);
4835 ** This variant of sqlite3BtreePayload() works even if the cursor has not
4836 ** in the CURSOR_VALID state. It is only used by the sqlite3_blob_read()
4837 ** interface.
4839 #ifndef SQLITE_OMIT_INCRBLOB
4840 static SQLITE_NOINLINE int accessPayloadChecked(
4841 BtCursor *pCur,
4842 u32 offset,
4843 u32 amt,
4844 void *pBuf
4846 int rc;
4847 if ( pCur->eState==CURSOR_INVALID ){
4848 return SQLITE_ABORT;
4850 assert( cursorOwnsBtShared(pCur) );
4851 rc = btreeRestoreCursorPosition(pCur);
4852 return rc ? rc : accessPayload(pCur, offset, amt, pBuf, 0);
4854 int sqlite3BtreePayloadChecked(BtCursor *pCur, u32 offset, u32 amt, void *pBuf){
4855 if( pCur->eState==CURSOR_VALID ){
4856 assert( cursorOwnsBtShared(pCur) );
4857 return accessPayload(pCur, offset, amt, pBuf, 0);
4858 }else{
4859 return accessPayloadChecked(pCur, offset, amt, pBuf);
4862 #endif /* SQLITE_OMIT_INCRBLOB */
4865 ** Return a pointer to payload information from the entry that the
4866 ** pCur cursor is pointing to. The pointer is to the beginning of
4867 ** the key if index btrees (pPage->intKey==0) and is the data for
4868 ** table btrees (pPage->intKey==1). The number of bytes of available
4869 ** key/data is written into *pAmt. If *pAmt==0, then the value
4870 ** returned will not be a valid pointer.
4872 ** This routine is an optimization. It is common for the entire key
4873 ** and data to fit on the local page and for there to be no overflow
4874 ** pages. When that is so, this routine can be used to access the
4875 ** key and data without making a copy. If the key and/or data spills
4876 ** onto overflow pages, then accessPayload() must be used to reassemble
4877 ** the key/data and copy it into a preallocated buffer.
4879 ** The pointer returned by this routine looks directly into the cached
4880 ** page of the database. The data might change or move the next time
4881 ** any btree routine is called.
4883 static const void *fetchPayload(
4884 BtCursor *pCur, /* Cursor pointing to entry to read from */
4885 u32 *pAmt /* Write the number of available bytes here */
4887 int amt;
4888 assert( pCur!=0 && pCur->iPage>=0 && pCur->pPage);
4889 assert( pCur->eState==CURSOR_VALID );
4890 assert( sqlite3_mutex_held(pCur->pBtree->db->mutex) );
4891 assert( cursorOwnsBtShared(pCur) );
4892 assert( pCur->ix<pCur->pPage->nCell );
4893 assert( pCur->info.nSize>0 );
4894 assert( pCur->info.pPayload>pCur->pPage->aData || CORRUPT_DB );
4895 assert( pCur->info.pPayload<pCur->pPage->aDataEnd ||CORRUPT_DB);
4896 amt = pCur->info.nLocal;
4897 if( amt>(int)(pCur->pPage->aDataEnd - pCur->info.pPayload) ){
4898 /* There is too little space on the page for the expected amount
4899 ** of local content. Database must be corrupt. */
4900 assert( CORRUPT_DB );
4901 amt = MAX(0, (int)(pCur->pPage->aDataEnd - pCur->info.pPayload));
4903 *pAmt = (u32)amt;
4904 return (void*)pCur->info.pPayload;
4909 ** For the entry that cursor pCur is point to, return as
4910 ** many bytes of the key or data as are available on the local
4911 ** b-tree page. Write the number of available bytes into *pAmt.
4913 ** The pointer returned is ephemeral. The key/data may move
4914 ** or be destroyed on the next call to any Btree routine,
4915 ** including calls from other threads against the same cache.
4916 ** Hence, a mutex on the BtShared should be held prior to calling
4917 ** this routine.
4919 ** These routines is used to get quick access to key and data
4920 ** in the common case where no overflow pages are used.
4922 const void *sqlite3BtreePayloadFetch(BtCursor *pCur, u32 *pAmt){
4923 return fetchPayload(pCur, pAmt);
4928 ** Move the cursor down to a new child page. The newPgno argument is the
4929 ** page number of the child page to move to.
4931 ** This function returns SQLITE_CORRUPT if the page-header flags field of
4932 ** the new child page does not match the flags field of the parent (i.e.
4933 ** if an intkey page appears to be the parent of a non-intkey page, or
4934 ** vice-versa).
4936 static int moveToChild(BtCursor *pCur, u32 newPgno){
4937 BtShared *pBt = pCur->pBt;
4939 assert( cursorOwnsBtShared(pCur) );
4940 assert( pCur->eState==CURSOR_VALID );
4941 assert( pCur->iPage<BTCURSOR_MAX_DEPTH );
4942 assert( pCur->iPage>=0 );
4943 if( pCur->iPage>=(BTCURSOR_MAX_DEPTH-1) ){
4944 return SQLITE_CORRUPT_BKPT;
4946 pCur->info.nSize = 0;
4947 pCur->curFlags &= ~(BTCF_ValidNKey|BTCF_ValidOvfl);
4948 pCur->aiIdx[pCur->iPage] = pCur->ix;
4949 pCur->apPage[pCur->iPage] = pCur->pPage;
4950 pCur->ix = 0;
4951 pCur->iPage++;
4952 return getAndInitPage(pBt, newPgno, &pCur->pPage, pCur, pCur->curPagerFlags);
4955 #ifdef SQLITE_DEBUG
4957 ** Page pParent is an internal (non-leaf) tree page. This function
4958 ** asserts that page number iChild is the left-child if the iIdx'th
4959 ** cell in page pParent. Or, if iIdx is equal to the total number of
4960 ** cells in pParent, that page number iChild is the right-child of
4961 ** the page.
4963 static void assertParentIndex(MemPage *pParent, int iIdx, Pgno iChild){
4964 if( CORRUPT_DB ) return; /* The conditions tested below might not be true
4965 ** in a corrupt database */
4966 assert( iIdx<=pParent->nCell );
4967 if( iIdx==pParent->nCell ){
4968 assert( get4byte(&pParent->aData[pParent->hdrOffset+8])==iChild );
4969 }else{
4970 assert( get4byte(findCell(pParent, iIdx))==iChild );
4973 #else
4974 # define assertParentIndex(x,y,z)
4975 #endif
4978 ** Move the cursor up to the parent page.
4980 ** pCur->idx is set to the cell index that contains the pointer
4981 ** to the page we are coming from. If we are coming from the
4982 ** right-most child page then pCur->idx is set to one more than
4983 ** the largest cell index.
4985 static void moveToParent(BtCursor *pCur){
4986 MemPage *pLeaf;
4987 assert( cursorOwnsBtShared(pCur) );
4988 assert( pCur->eState==CURSOR_VALID );
4989 assert( pCur->iPage>0 );
4990 assert( pCur->pPage );
4991 assertParentIndex(
4992 pCur->apPage[pCur->iPage-1],
4993 pCur->aiIdx[pCur->iPage-1],
4994 pCur->pPage->pgno
4996 testcase( pCur->aiIdx[pCur->iPage-1] > pCur->apPage[pCur->iPage-1]->nCell );
4997 pCur->info.nSize = 0;
4998 pCur->curFlags &= ~(BTCF_ValidNKey|BTCF_ValidOvfl);
4999 pCur->ix = pCur->aiIdx[pCur->iPage-1];
5000 pLeaf = pCur->pPage;
5001 pCur->pPage = pCur->apPage[--pCur->iPage];
5002 releasePageNotNull(pLeaf);
5006 ** Move the cursor to point to the root page of its b-tree structure.
5008 ** If the table has a virtual root page, then the cursor is moved to point
5009 ** to the virtual root page instead of the actual root page. A table has a
5010 ** virtual root page when the actual root page contains no cells and a
5011 ** single child page. This can only happen with the table rooted at page 1.
5013 ** If the b-tree structure is empty, the cursor state is set to
5014 ** CURSOR_INVALID and this routine returns SQLITE_EMPTY. Otherwise,
5015 ** the cursor is set to point to the first cell located on the root
5016 ** (or virtual root) page and the cursor state is set to CURSOR_VALID.
5018 ** If this function returns successfully, it may be assumed that the
5019 ** page-header flags indicate that the [virtual] root-page is the expected
5020 ** kind of b-tree page (i.e. if when opening the cursor the caller did not
5021 ** specify a KeyInfo structure the flags byte is set to 0x05 or 0x0D,
5022 ** indicating a table b-tree, or if the caller did specify a KeyInfo
5023 ** structure the flags byte is set to 0x02 or 0x0A, indicating an index
5024 ** b-tree).
5026 static int moveToRoot(BtCursor *pCur){
5027 MemPage *pRoot;
5028 int rc = SQLITE_OK;
5030 assert( cursorOwnsBtShared(pCur) );
5031 assert( CURSOR_INVALID < CURSOR_REQUIRESEEK );
5032 assert( CURSOR_VALID < CURSOR_REQUIRESEEK );
5033 assert( CURSOR_FAULT > CURSOR_REQUIRESEEK );
5034 assert( pCur->eState < CURSOR_REQUIRESEEK || pCur->iPage<0 );
5035 assert( pCur->pgnoRoot>0 || pCur->iPage<0 );
5037 if( pCur->iPage>=0 ){
5038 if( pCur->iPage ){
5039 releasePageNotNull(pCur->pPage);
5040 while( --pCur->iPage ){
5041 releasePageNotNull(pCur->apPage[pCur->iPage]);
5043 pCur->pPage = pCur->apPage[0];
5044 goto skip_init;
5046 }else if( pCur->pgnoRoot==0 ){
5047 pCur->eState = CURSOR_INVALID;
5048 return SQLITE_EMPTY;
5049 }else{
5050 assert( pCur->iPage==(-1) );
5051 if( pCur->eState>=CURSOR_REQUIRESEEK ){
5052 if( pCur->eState==CURSOR_FAULT ){
5053 assert( pCur->skipNext!=SQLITE_OK );
5054 return pCur->skipNext;
5056 sqlite3BtreeClearCursor(pCur);
5058 rc = getAndInitPage(pCur->pBtree->pBt, pCur->pgnoRoot, &pCur->pPage,
5059 0, pCur->curPagerFlags);
5060 if( rc!=SQLITE_OK ){
5061 pCur->eState = CURSOR_INVALID;
5062 return rc;
5064 pCur->iPage = 0;
5065 pCur->curIntKey = pCur->pPage->intKey;
5067 pRoot = pCur->pPage;
5068 assert( pRoot->pgno==pCur->pgnoRoot );
5070 /* If pCur->pKeyInfo is not NULL, then the caller that opened this cursor
5071 ** expected to open it on an index b-tree. Otherwise, if pKeyInfo is
5072 ** NULL, the caller expects a table b-tree. If this is not the case,
5073 ** return an SQLITE_CORRUPT error.
5075 ** Earlier versions of SQLite assumed that this test could not fail
5076 ** if the root page was already loaded when this function was called (i.e.
5077 ** if pCur->iPage>=0). But this is not so if the database is corrupted
5078 ** in such a way that page pRoot is linked into a second b-tree table
5079 ** (or the freelist). */
5080 assert( pRoot->intKey==1 || pRoot->intKey==0 );
5081 if( pRoot->isInit==0 || (pCur->pKeyInfo==0)!=pRoot->intKey ){
5082 return SQLITE_CORRUPT_PAGE(pCur->pPage);
5085 skip_init:
5086 pCur->ix = 0;
5087 pCur->info.nSize = 0;
5088 pCur->curFlags &= ~(BTCF_AtLast|BTCF_ValidNKey|BTCF_ValidOvfl);
5090 pRoot = pCur->pPage;
5091 if( pRoot->nCell>0 ){
5092 pCur->eState = CURSOR_VALID;
5093 }else if( !pRoot->leaf ){
5094 Pgno subpage;
5095 if( pRoot->pgno!=1 ) return SQLITE_CORRUPT_BKPT;
5096 subpage = get4byte(&pRoot->aData[pRoot->hdrOffset+8]);
5097 pCur->eState = CURSOR_VALID;
5098 rc = moveToChild(pCur, subpage);
5099 }else{
5100 pCur->eState = CURSOR_INVALID;
5101 rc = SQLITE_EMPTY;
5103 return rc;
5107 ** Move the cursor down to the left-most leaf entry beneath the
5108 ** entry to which it is currently pointing.
5110 ** The left-most leaf is the one with the smallest key - the first
5111 ** in ascending order.
5113 static int moveToLeftmost(BtCursor *pCur){
5114 Pgno pgno;
5115 int rc = SQLITE_OK;
5116 MemPage *pPage;
5118 assert( cursorOwnsBtShared(pCur) );
5119 assert( pCur->eState==CURSOR_VALID );
5120 while( rc==SQLITE_OK && !(pPage = pCur->pPage)->leaf ){
5121 assert( pCur->ix<pPage->nCell );
5122 pgno = get4byte(findCell(pPage, pCur->ix));
5123 rc = moveToChild(pCur, pgno);
5125 return rc;
5129 ** Move the cursor down to the right-most leaf entry beneath the
5130 ** page to which it is currently pointing. Notice the difference
5131 ** between moveToLeftmost() and moveToRightmost(). moveToLeftmost()
5132 ** finds the left-most entry beneath the *entry* whereas moveToRightmost()
5133 ** finds the right-most entry beneath the *page*.
5135 ** The right-most entry is the one with the largest key - the last
5136 ** key in ascending order.
5138 static int moveToRightmost(BtCursor *pCur){
5139 Pgno pgno;
5140 int rc = SQLITE_OK;
5141 MemPage *pPage = 0;
5143 assert( cursorOwnsBtShared(pCur) );
5144 assert( pCur->eState==CURSOR_VALID );
5145 while( !(pPage = pCur->pPage)->leaf ){
5146 pgno = get4byte(&pPage->aData[pPage->hdrOffset+8]);
5147 pCur->ix = pPage->nCell;
5148 rc = moveToChild(pCur, pgno);
5149 if( rc ) return rc;
5151 pCur->ix = pPage->nCell-1;
5152 assert( pCur->info.nSize==0 );
5153 assert( (pCur->curFlags & BTCF_ValidNKey)==0 );
5154 return SQLITE_OK;
5157 /* Move the cursor to the first entry in the table. Return SQLITE_OK
5158 ** on success. Set *pRes to 0 if the cursor actually points to something
5159 ** or set *pRes to 1 if the table is empty.
5161 int sqlite3BtreeFirst(BtCursor *pCur, int *pRes){
5162 int rc;
5164 assert( cursorOwnsBtShared(pCur) );
5165 assert( sqlite3_mutex_held(pCur->pBtree->db->mutex) );
5166 rc = moveToRoot(pCur);
5167 if( rc==SQLITE_OK ){
5168 assert( pCur->pPage->nCell>0 );
5169 *pRes = 0;
5170 rc = moveToLeftmost(pCur);
5171 }else if( rc==SQLITE_EMPTY ){
5172 assert( pCur->pgnoRoot==0 || pCur->pPage->nCell==0 );
5173 *pRes = 1;
5174 rc = SQLITE_OK;
5176 return rc;
5179 /* Move the cursor to the last entry in the table. Return SQLITE_OK
5180 ** on success. Set *pRes to 0 if the cursor actually points to something
5181 ** or set *pRes to 1 if the table is empty.
5183 int sqlite3BtreeLast(BtCursor *pCur, int *pRes){
5184 int rc;
5186 assert( cursorOwnsBtShared(pCur) );
5187 assert( sqlite3_mutex_held(pCur->pBtree->db->mutex) );
5189 /* If the cursor already points to the last entry, this is a no-op. */
5190 if( CURSOR_VALID==pCur->eState && (pCur->curFlags & BTCF_AtLast)!=0 ){
5191 #ifdef SQLITE_DEBUG
5192 /* This block serves to assert() that the cursor really does point
5193 ** to the last entry in the b-tree. */
5194 int ii;
5195 for(ii=0; ii<pCur->iPage; ii++){
5196 assert( pCur->aiIdx[ii]==pCur->apPage[ii]->nCell );
5198 assert( pCur->ix==pCur->pPage->nCell-1 );
5199 assert( pCur->pPage->leaf );
5200 #endif
5201 return SQLITE_OK;
5204 rc = moveToRoot(pCur);
5205 if( rc==SQLITE_OK ){
5206 assert( pCur->eState==CURSOR_VALID );
5207 *pRes = 0;
5208 rc = moveToRightmost(pCur);
5209 if( rc==SQLITE_OK ){
5210 pCur->curFlags |= BTCF_AtLast;
5211 }else{
5212 pCur->curFlags &= ~BTCF_AtLast;
5214 }else if( rc==SQLITE_EMPTY ){
5215 assert( pCur->pgnoRoot==0 || pCur->pPage->nCell==0 );
5216 *pRes = 1;
5217 rc = SQLITE_OK;
5219 return rc;
5222 /* Move the cursor so that it points to an entry near the key
5223 ** specified by pIdxKey or intKey. Return a success code.
5225 ** For INTKEY tables, the intKey parameter is used. pIdxKey
5226 ** must be NULL. For index tables, pIdxKey is used and intKey
5227 ** is ignored.
5229 ** If an exact match is not found, then the cursor is always
5230 ** left pointing at a leaf page which would hold the entry if it
5231 ** were present. The cursor might point to an entry that comes
5232 ** before or after the key.
5234 ** An integer is written into *pRes which is the result of
5235 ** comparing the key with the entry to which the cursor is
5236 ** pointing. The meaning of the integer written into
5237 ** *pRes is as follows:
5239 ** *pRes<0 The cursor is left pointing at an entry that
5240 ** is smaller than intKey/pIdxKey or if the table is empty
5241 ** and the cursor is therefore left point to nothing.
5243 ** *pRes==0 The cursor is left pointing at an entry that
5244 ** exactly matches intKey/pIdxKey.
5246 ** *pRes>0 The cursor is left pointing at an entry that
5247 ** is larger than intKey/pIdxKey.
5249 ** For index tables, the pIdxKey->eqSeen field is set to 1 if there
5250 ** exists an entry in the table that exactly matches pIdxKey.
5252 int sqlite3BtreeMovetoUnpacked(
5253 BtCursor *pCur, /* The cursor to be moved */
5254 UnpackedRecord *pIdxKey, /* Unpacked index key */
5255 i64 intKey, /* The table key */
5256 int biasRight, /* If true, bias the search to the high end */
5257 int *pRes /* Write search results here */
5259 int rc;
5260 RecordCompare xRecordCompare;
5262 assert( cursorOwnsBtShared(pCur) );
5263 assert( sqlite3_mutex_held(pCur->pBtree->db->mutex) );
5264 assert( pRes );
5265 assert( (pIdxKey==0)==(pCur->pKeyInfo==0) );
5266 assert( pCur->eState!=CURSOR_VALID || (pIdxKey==0)==(pCur->curIntKey!=0) );
5268 /* If the cursor is already positioned at the point we are trying
5269 ** to move to, then just return without doing any work */
5270 if( pIdxKey==0
5271 && pCur->eState==CURSOR_VALID && (pCur->curFlags & BTCF_ValidNKey)!=0
5273 if( pCur->info.nKey==intKey ){
5274 *pRes = 0;
5275 return SQLITE_OK;
5277 if( pCur->info.nKey<intKey ){
5278 if( (pCur->curFlags & BTCF_AtLast)!=0 ){
5279 *pRes = -1;
5280 return SQLITE_OK;
5282 /* If the requested key is one more than the previous key, then
5283 ** try to get there using sqlite3BtreeNext() rather than a full
5284 ** binary search. This is an optimization only. The correct answer
5285 ** is still obtained without this case, only a little more slowely */
5286 if( pCur->info.nKey+1==intKey && !pCur->skipNext ){
5287 *pRes = 0;
5288 rc = sqlite3BtreeNext(pCur, 0);
5289 if( rc==SQLITE_OK ){
5290 getCellInfo(pCur);
5291 if( pCur->info.nKey==intKey ){
5292 return SQLITE_OK;
5294 }else if( rc==SQLITE_DONE ){
5295 rc = SQLITE_OK;
5296 }else{
5297 return rc;
5303 if( pIdxKey ){
5304 xRecordCompare = sqlite3VdbeFindCompare(pIdxKey);
5305 pIdxKey->errCode = 0;
5306 assert( pIdxKey->default_rc==1
5307 || pIdxKey->default_rc==0
5308 || pIdxKey->default_rc==-1
5310 }else{
5311 xRecordCompare = 0; /* All keys are integers */
5314 rc = moveToRoot(pCur);
5315 if( rc ){
5316 if( rc==SQLITE_EMPTY ){
5317 assert( pCur->pgnoRoot==0 || pCur->pPage->nCell==0 );
5318 *pRes = -1;
5319 return SQLITE_OK;
5321 return rc;
5323 assert( pCur->pPage );
5324 assert( pCur->pPage->isInit );
5325 assert( pCur->eState==CURSOR_VALID );
5326 assert( pCur->pPage->nCell > 0 );
5327 assert( pCur->iPage==0 || pCur->apPage[0]->intKey==pCur->curIntKey );
5328 assert( pCur->curIntKey || pIdxKey );
5329 for(;;){
5330 int lwr, upr, idx, c;
5331 Pgno chldPg;
5332 MemPage *pPage = pCur->pPage;
5333 u8 *pCell; /* Pointer to current cell in pPage */
5335 /* pPage->nCell must be greater than zero. If this is the root-page
5336 ** the cursor would have been INVALID above and this for(;;) loop
5337 ** not run. If this is not the root-page, then the moveToChild() routine
5338 ** would have already detected db corruption. Similarly, pPage must
5339 ** be the right kind (index or table) of b-tree page. Otherwise
5340 ** a moveToChild() or moveToRoot() call would have detected corruption. */
5341 assert( pPage->nCell>0 );
5342 assert( pPage->intKey==(pIdxKey==0) );
5343 lwr = 0;
5344 upr = pPage->nCell-1;
5345 assert( biasRight==0 || biasRight==1 );
5346 idx = upr>>(1-biasRight); /* idx = biasRight ? upr : (lwr+upr)/2; */
5347 pCur->ix = (u16)idx;
5348 if( xRecordCompare==0 ){
5349 for(;;){
5350 i64 nCellKey;
5351 pCell = findCellPastPtr(pPage, idx);
5352 if( pPage->intKeyLeaf ){
5353 while( 0x80 <= *(pCell++) ){
5354 if( pCell>=pPage->aDataEnd ){
5355 return SQLITE_CORRUPT_PAGE(pPage);
5359 getVarint(pCell, (u64*)&nCellKey);
5360 if( nCellKey<intKey ){
5361 lwr = idx+1;
5362 if( lwr>upr ){ c = -1; break; }
5363 }else if( nCellKey>intKey ){
5364 upr = idx-1;
5365 if( lwr>upr ){ c = +1; break; }
5366 }else{
5367 assert( nCellKey==intKey );
5368 pCur->ix = (u16)idx;
5369 if( !pPage->leaf ){
5370 lwr = idx;
5371 goto moveto_next_layer;
5372 }else{
5373 pCur->curFlags |= BTCF_ValidNKey;
5374 pCur->info.nKey = nCellKey;
5375 pCur->info.nSize = 0;
5376 *pRes = 0;
5377 return SQLITE_OK;
5380 assert( lwr+upr>=0 );
5381 idx = (lwr+upr)>>1; /* idx = (lwr+upr)/2; */
5383 }else{
5384 for(;;){
5385 int nCell; /* Size of the pCell cell in bytes */
5386 pCell = findCellPastPtr(pPage, idx);
5388 /* The maximum supported page-size is 65536 bytes. This means that
5389 ** the maximum number of record bytes stored on an index B-Tree
5390 ** page is less than 16384 bytes and may be stored as a 2-byte
5391 ** varint. This information is used to attempt to avoid parsing
5392 ** the entire cell by checking for the cases where the record is
5393 ** stored entirely within the b-tree page by inspecting the first
5394 ** 2 bytes of the cell.
5396 nCell = pCell[0];
5397 if( nCell<=pPage->max1bytePayload ){
5398 /* This branch runs if the record-size field of the cell is a
5399 ** single byte varint and the record fits entirely on the main
5400 ** b-tree page. */
5401 testcase( pCell+nCell+1==pPage->aDataEnd );
5402 c = xRecordCompare(nCell, (void*)&pCell[1], pIdxKey);
5403 }else if( !(pCell[1] & 0x80)
5404 && (nCell = ((nCell&0x7f)<<7) + pCell[1])<=pPage->maxLocal
5406 /* The record-size field is a 2 byte varint and the record
5407 ** fits entirely on the main b-tree page. */
5408 testcase( pCell+nCell+2==pPage->aDataEnd );
5409 c = xRecordCompare(nCell, (void*)&pCell[2], pIdxKey);
5410 }else{
5411 /* The record flows over onto one or more overflow pages. In
5412 ** this case the whole cell needs to be parsed, a buffer allocated
5413 ** and accessPayload() used to retrieve the record into the
5414 ** buffer before VdbeRecordCompare() can be called.
5416 ** If the record is corrupt, the xRecordCompare routine may read
5417 ** up to two varints past the end of the buffer. An extra 18
5418 ** bytes of padding is allocated at the end of the buffer in
5419 ** case this happens. */
5420 void *pCellKey;
5421 u8 * const pCellBody = pCell - pPage->childPtrSize;
5422 pPage->xParseCell(pPage, pCellBody, &pCur->info);
5423 nCell = (int)pCur->info.nKey;
5424 testcase( nCell<0 ); /* True if key size is 2^32 or more */
5425 testcase( nCell==0 ); /* Invalid key size: 0x80 0x80 0x00 */
5426 testcase( nCell==1 ); /* Invalid key size: 0x80 0x80 0x01 */
5427 testcase( nCell==2 ); /* Minimum legal index key size */
5428 if( nCell<2 ){
5429 rc = SQLITE_CORRUPT_PAGE(pPage);
5430 goto moveto_finish;
5432 pCellKey = sqlite3Malloc( nCell+18 );
5433 if( pCellKey==0 ){
5434 rc = SQLITE_NOMEM_BKPT;
5435 goto moveto_finish;
5437 pCur->ix = (u16)idx;
5438 rc = accessPayload(pCur, 0, nCell, (unsigned char*)pCellKey, 0);
5439 pCur->curFlags &= ~BTCF_ValidOvfl;
5440 if( rc ){
5441 sqlite3_free(pCellKey);
5442 goto moveto_finish;
5444 c = xRecordCompare(nCell, pCellKey, pIdxKey);
5445 sqlite3_free(pCellKey);
5447 assert(
5448 (pIdxKey->errCode!=SQLITE_CORRUPT || c==0)
5449 && (pIdxKey->errCode!=SQLITE_NOMEM || pCur->pBtree->db->mallocFailed)
5451 if( c<0 ){
5452 lwr = idx+1;
5453 }else if( c>0 ){
5454 upr = idx-1;
5455 }else{
5456 assert( c==0 );
5457 *pRes = 0;
5458 rc = SQLITE_OK;
5459 pCur->ix = (u16)idx;
5460 if( pIdxKey->errCode ) rc = SQLITE_CORRUPT_BKPT;
5461 goto moveto_finish;
5463 if( lwr>upr ) break;
5464 assert( lwr+upr>=0 );
5465 idx = (lwr+upr)>>1; /* idx = (lwr+upr)/2 */
5468 assert( lwr==upr+1 || (pPage->intKey && !pPage->leaf) );
5469 assert( pPage->isInit );
5470 if( pPage->leaf ){
5471 assert( pCur->ix<pCur->pPage->nCell );
5472 pCur->ix = (u16)idx;
5473 *pRes = c;
5474 rc = SQLITE_OK;
5475 goto moveto_finish;
5477 moveto_next_layer:
5478 if( lwr>=pPage->nCell ){
5479 chldPg = get4byte(&pPage->aData[pPage->hdrOffset+8]);
5480 }else{
5481 chldPg = get4byte(findCell(pPage, lwr));
5483 pCur->ix = (u16)lwr;
5484 rc = moveToChild(pCur, chldPg);
5485 if( rc ) break;
5487 moveto_finish:
5488 pCur->info.nSize = 0;
5489 assert( (pCur->curFlags & BTCF_ValidOvfl)==0 );
5490 return rc;
5495 ** Return TRUE if the cursor is not pointing at an entry of the table.
5497 ** TRUE will be returned after a call to sqlite3BtreeNext() moves
5498 ** past the last entry in the table or sqlite3BtreePrev() moves past
5499 ** the first entry. TRUE is also returned if the table is empty.
5501 int sqlite3BtreeEof(BtCursor *pCur){
5502 /* TODO: What if the cursor is in CURSOR_REQUIRESEEK but all table entries
5503 ** have been deleted? This API will need to change to return an error code
5504 ** as well as the boolean result value.
5506 return (CURSOR_VALID!=pCur->eState);
5510 ** Return an estimate for the number of rows in the table that pCur is
5511 ** pointing to. Return a negative number if no estimate is currently
5512 ** available.
5514 i64 sqlite3BtreeRowCountEst(BtCursor *pCur){
5515 i64 n;
5516 u8 i;
5518 assert( cursorOwnsBtShared(pCur) );
5519 assert( sqlite3_mutex_held(pCur->pBtree->db->mutex) );
5521 /* Currently this interface is only called by the OP_IfSmaller
5522 ** opcode, and it that case the cursor will always be valid and
5523 ** will always point to a leaf node. */
5524 if( NEVER(pCur->eState!=CURSOR_VALID) ) return -1;
5525 if( NEVER(pCur->pPage->leaf==0) ) return -1;
5527 n = pCur->pPage->nCell;
5528 for(i=0; i<pCur->iPage; i++){
5529 n *= pCur->apPage[i]->nCell;
5531 return n;
5535 ** Advance the cursor to the next entry in the database.
5536 ** Return value:
5538 ** SQLITE_OK success
5539 ** SQLITE_DONE cursor is already pointing at the last element
5540 ** otherwise some kind of error occurred
5542 ** The main entry point is sqlite3BtreeNext(). That routine is optimized
5543 ** for the common case of merely incrementing the cell counter BtCursor.aiIdx
5544 ** to the next cell on the current page. The (slower) btreeNext() helper
5545 ** routine is called when it is necessary to move to a different page or
5546 ** to restore the cursor.
5548 ** If bit 0x01 of the F argument in sqlite3BtreeNext(C,F) is 1, then the
5549 ** cursor corresponds to an SQL index and this routine could have been
5550 ** skipped if the SQL index had been a unique index. The F argument
5551 ** is a hint to the implement. SQLite btree implementation does not use
5552 ** this hint, but COMDB2 does.
5554 static SQLITE_NOINLINE int btreeNext(BtCursor *pCur){
5555 int rc;
5556 int idx;
5557 MemPage *pPage;
5559 assert( cursorOwnsBtShared(pCur) );
5560 assert( pCur->skipNext==0 || pCur->eState!=CURSOR_VALID );
5561 if( pCur->eState!=CURSOR_VALID ){
5562 assert( (pCur->curFlags & BTCF_ValidOvfl)==0 );
5563 rc = restoreCursorPosition(pCur);
5564 if( rc!=SQLITE_OK ){
5565 return rc;
5567 if( CURSOR_INVALID==pCur->eState ){
5568 return SQLITE_DONE;
5570 if( pCur->skipNext ){
5571 assert( pCur->eState==CURSOR_VALID || pCur->eState==CURSOR_SKIPNEXT );
5572 pCur->eState = CURSOR_VALID;
5573 if( pCur->skipNext>0 ){
5574 pCur->skipNext = 0;
5575 return SQLITE_OK;
5577 pCur->skipNext = 0;
5581 pPage = pCur->pPage;
5582 idx = ++pCur->ix;
5583 assert( pPage->isInit );
5585 /* If the database file is corrupt, it is possible for the value of idx
5586 ** to be invalid here. This can only occur if a second cursor modifies
5587 ** the page while cursor pCur is holding a reference to it. Which can
5588 ** only happen if the database is corrupt in such a way as to link the
5589 ** page into more than one b-tree structure. */
5590 testcase( idx>pPage->nCell );
5592 if( idx>=pPage->nCell ){
5593 if( !pPage->leaf ){
5594 rc = moveToChild(pCur, get4byte(&pPage->aData[pPage->hdrOffset+8]));
5595 if( rc ) return rc;
5596 return moveToLeftmost(pCur);
5599 if( pCur->iPage==0 ){
5600 pCur->eState = CURSOR_INVALID;
5601 return SQLITE_DONE;
5603 moveToParent(pCur);
5604 pPage = pCur->pPage;
5605 }while( pCur->ix>=pPage->nCell );
5606 if( pPage->intKey ){
5607 return sqlite3BtreeNext(pCur, 0);
5608 }else{
5609 return SQLITE_OK;
5612 if( pPage->leaf ){
5613 return SQLITE_OK;
5614 }else{
5615 return moveToLeftmost(pCur);
5618 int sqlite3BtreeNext(BtCursor *pCur, int flags){
5619 MemPage *pPage;
5620 UNUSED_PARAMETER( flags ); /* Used in COMDB2 but not native SQLite */
5621 assert( cursorOwnsBtShared(pCur) );
5622 assert( flags==0 || flags==1 );
5623 assert( pCur->skipNext==0 || pCur->eState!=CURSOR_VALID );
5624 pCur->info.nSize = 0;
5625 pCur->curFlags &= ~(BTCF_ValidNKey|BTCF_ValidOvfl);
5626 if( pCur->eState!=CURSOR_VALID ) return btreeNext(pCur);
5627 pPage = pCur->pPage;
5628 if( (++pCur->ix)>=pPage->nCell ){
5629 pCur->ix--;
5630 return btreeNext(pCur);
5632 if( pPage->leaf ){
5633 return SQLITE_OK;
5634 }else{
5635 return moveToLeftmost(pCur);
5640 ** Step the cursor to the back to the previous entry in the database.
5641 ** Return values:
5643 ** SQLITE_OK success
5644 ** SQLITE_DONE the cursor is already on the first element of the table
5645 ** otherwise some kind of error occurred
5647 ** The main entry point is sqlite3BtreePrevious(). That routine is optimized
5648 ** for the common case of merely decrementing the cell counter BtCursor.aiIdx
5649 ** to the previous cell on the current page. The (slower) btreePrevious()
5650 ** helper routine is called when it is necessary to move to a different page
5651 ** or to restore the cursor.
5653 ** If bit 0x01 of the F argument to sqlite3BtreePrevious(C,F) is 1, then
5654 ** the cursor corresponds to an SQL index and this routine could have been
5655 ** skipped if the SQL index had been a unique index. The F argument is a
5656 ** hint to the implement. The native SQLite btree implementation does not
5657 ** use this hint, but COMDB2 does.
5659 static SQLITE_NOINLINE int btreePrevious(BtCursor *pCur){
5660 int rc;
5661 MemPage *pPage;
5663 assert( cursorOwnsBtShared(pCur) );
5664 assert( pCur->skipNext==0 || pCur->eState!=CURSOR_VALID );
5665 assert( (pCur->curFlags & (BTCF_AtLast|BTCF_ValidOvfl|BTCF_ValidNKey))==0 );
5666 assert( pCur->info.nSize==0 );
5667 if( pCur->eState!=CURSOR_VALID ){
5668 rc = restoreCursorPosition(pCur);
5669 if( rc!=SQLITE_OK ){
5670 return rc;
5672 if( CURSOR_INVALID==pCur->eState ){
5673 return SQLITE_DONE;
5675 if( pCur->skipNext ){
5676 assert( pCur->eState==CURSOR_VALID || pCur->eState==CURSOR_SKIPNEXT );
5677 pCur->eState = CURSOR_VALID;
5678 if( pCur->skipNext<0 ){
5679 pCur->skipNext = 0;
5680 return SQLITE_OK;
5682 pCur->skipNext = 0;
5686 pPage = pCur->pPage;
5687 assert( pPage->isInit );
5688 if( !pPage->leaf ){
5689 int idx = pCur->ix;
5690 rc = moveToChild(pCur, get4byte(findCell(pPage, idx)));
5691 if( rc ) return rc;
5692 rc = moveToRightmost(pCur);
5693 }else{
5694 while( pCur->ix==0 ){
5695 if( pCur->iPage==0 ){
5696 pCur->eState = CURSOR_INVALID;
5697 return SQLITE_DONE;
5699 moveToParent(pCur);
5701 assert( pCur->info.nSize==0 );
5702 assert( (pCur->curFlags & (BTCF_ValidOvfl))==0 );
5704 pCur->ix--;
5705 pPage = pCur->pPage;
5706 if( pPage->intKey && !pPage->leaf ){
5707 rc = sqlite3BtreePrevious(pCur, 0);
5708 }else{
5709 rc = SQLITE_OK;
5712 return rc;
5714 int sqlite3BtreePrevious(BtCursor *pCur, int flags){
5715 assert( cursorOwnsBtShared(pCur) );
5716 assert( flags==0 || flags==1 );
5717 assert( pCur->skipNext==0 || pCur->eState!=CURSOR_VALID );
5718 UNUSED_PARAMETER( flags ); /* Used in COMDB2 but not native SQLite */
5719 pCur->curFlags &= ~(BTCF_AtLast|BTCF_ValidOvfl|BTCF_ValidNKey);
5720 pCur->info.nSize = 0;
5721 if( pCur->eState!=CURSOR_VALID
5722 || pCur->ix==0
5723 || pCur->pPage->leaf==0
5725 return btreePrevious(pCur);
5727 pCur->ix--;
5728 return SQLITE_OK;
5732 ** Allocate a new page from the database file.
5734 ** The new page is marked as dirty. (In other words, sqlite3PagerWrite()
5735 ** has already been called on the new page.) The new page has also
5736 ** been referenced and the calling routine is responsible for calling
5737 ** sqlite3PagerUnref() on the new page when it is done.
5739 ** SQLITE_OK is returned on success. Any other return value indicates
5740 ** an error. *ppPage is set to NULL in the event of an error.
5742 ** If the "nearby" parameter is not 0, then an effort is made to
5743 ** locate a page close to the page number "nearby". This can be used in an
5744 ** attempt to keep related pages close to each other in the database file,
5745 ** which in turn can make database access faster.
5747 ** If the eMode parameter is BTALLOC_EXACT and the nearby page exists
5748 ** anywhere on the free-list, then it is guaranteed to be returned. If
5749 ** eMode is BTALLOC_LT then the page returned will be less than or equal
5750 ** to nearby if any such page exists. If eMode is BTALLOC_ANY then there
5751 ** are no restrictions on which page is returned.
5753 static int allocateBtreePage(
5754 BtShared *pBt, /* The btree */
5755 MemPage **ppPage, /* Store pointer to the allocated page here */
5756 Pgno *pPgno, /* Store the page number here */
5757 Pgno nearby, /* Search for a page near this one */
5758 u8 eMode /* BTALLOC_EXACT, BTALLOC_LT, or BTALLOC_ANY */
5760 MemPage *pPage1;
5761 int rc;
5762 u32 n; /* Number of pages on the freelist */
5763 u32 k; /* Number of leaves on the trunk of the freelist */
5764 MemPage *pTrunk = 0;
5765 MemPage *pPrevTrunk = 0;
5766 Pgno mxPage; /* Total size of the database file */
5768 assert( sqlite3_mutex_held(pBt->mutex) );
5769 assert( eMode==BTALLOC_ANY || (nearby>0 && IfNotOmitAV(pBt->autoVacuum)) );
5770 pPage1 = pBt->pPage1;
5771 mxPage = btreePagecount(pBt);
5772 /* EVIDENCE-OF: R-05119-02637 The 4-byte big-endian integer at offset 36
5773 ** stores stores the total number of pages on the freelist. */
5774 n = get4byte(&pPage1->aData[36]);
5775 testcase( n==mxPage-1 );
5776 if( n>=mxPage ){
5777 return SQLITE_CORRUPT_BKPT;
5779 if( n>0 ){
5780 /* There are pages on the freelist. Reuse one of those pages. */
5781 Pgno iTrunk;
5782 u8 searchList = 0; /* If the free-list must be searched for 'nearby' */
5783 u32 nSearch = 0; /* Count of the number of search attempts */
5785 /* If eMode==BTALLOC_EXACT and a query of the pointer-map
5786 ** shows that the page 'nearby' is somewhere on the free-list, then
5787 ** the entire-list will be searched for that page.
5789 #ifndef SQLITE_OMIT_AUTOVACUUM
5790 if( eMode==BTALLOC_EXACT ){
5791 if( nearby<=mxPage ){
5792 u8 eType;
5793 assert( nearby>0 );
5794 assert( pBt->autoVacuum );
5795 rc = ptrmapGet(pBt, nearby, &eType, 0);
5796 if( rc ) return rc;
5797 if( eType==PTRMAP_FREEPAGE ){
5798 searchList = 1;
5801 }else if( eMode==BTALLOC_LE ){
5802 searchList = 1;
5804 #endif
5806 /* Decrement the free-list count by 1. Set iTrunk to the index of the
5807 ** first free-list trunk page. iPrevTrunk is initially 1.
5809 rc = sqlite3PagerWrite(pPage1->pDbPage);
5810 if( rc ) return rc;
5811 put4byte(&pPage1->aData[36], n-1);
5813 /* The code within this loop is run only once if the 'searchList' variable
5814 ** is not true. Otherwise, it runs once for each trunk-page on the
5815 ** free-list until the page 'nearby' is located (eMode==BTALLOC_EXACT)
5816 ** or until a page less than 'nearby' is located (eMode==BTALLOC_LT)
5818 do {
5819 pPrevTrunk = pTrunk;
5820 if( pPrevTrunk ){
5821 /* EVIDENCE-OF: R-01506-11053 The first integer on a freelist trunk page
5822 ** is the page number of the next freelist trunk page in the list or
5823 ** zero if this is the last freelist trunk page. */
5824 iTrunk = get4byte(&pPrevTrunk->aData[0]);
5825 }else{
5826 /* EVIDENCE-OF: R-59841-13798 The 4-byte big-endian integer at offset 32
5827 ** stores the page number of the first page of the freelist, or zero if
5828 ** the freelist is empty. */
5829 iTrunk = get4byte(&pPage1->aData[32]);
5831 testcase( iTrunk==mxPage );
5832 if( iTrunk>mxPage || nSearch++ > n ){
5833 rc = SQLITE_CORRUPT_PGNO(pPrevTrunk ? pPrevTrunk->pgno : 1);
5834 }else{
5835 rc = btreeGetUnusedPage(pBt, iTrunk, &pTrunk, 0);
5837 if( rc ){
5838 pTrunk = 0;
5839 goto end_allocate_page;
5841 assert( pTrunk!=0 );
5842 assert( pTrunk->aData!=0 );
5843 /* EVIDENCE-OF: R-13523-04394 The second integer on a freelist trunk page
5844 ** is the number of leaf page pointers to follow. */
5845 k = get4byte(&pTrunk->aData[4]);
5846 if( k==0 && !searchList ){
5847 /* The trunk has no leaves and the list is not being searched.
5848 ** So extract the trunk page itself and use it as the newly
5849 ** allocated page */
5850 assert( pPrevTrunk==0 );
5851 rc = sqlite3PagerWrite(pTrunk->pDbPage);
5852 if( rc ){
5853 goto end_allocate_page;
5855 *pPgno = iTrunk;
5856 memcpy(&pPage1->aData[32], &pTrunk->aData[0], 4);
5857 *ppPage = pTrunk;
5858 pTrunk = 0;
5859 TRACE(("ALLOCATE: %d trunk - %d free pages left\n", *pPgno, n-1));
5860 }else if( k>(u32)(pBt->usableSize/4 - 2) ){
5861 /* Value of k is out of range. Database corruption */
5862 rc = SQLITE_CORRUPT_PGNO(iTrunk);
5863 goto end_allocate_page;
5864 #ifndef SQLITE_OMIT_AUTOVACUUM
5865 }else if( searchList
5866 && (nearby==iTrunk || (iTrunk<nearby && eMode==BTALLOC_LE))
5868 /* The list is being searched and this trunk page is the page
5869 ** to allocate, regardless of whether it has leaves.
5871 *pPgno = iTrunk;
5872 *ppPage = pTrunk;
5873 searchList = 0;
5874 rc = sqlite3PagerWrite(pTrunk->pDbPage);
5875 if( rc ){
5876 goto end_allocate_page;
5878 if( k==0 ){
5879 if( !pPrevTrunk ){
5880 memcpy(&pPage1->aData[32], &pTrunk->aData[0], 4);
5881 }else{
5882 rc = sqlite3PagerWrite(pPrevTrunk->pDbPage);
5883 if( rc!=SQLITE_OK ){
5884 goto end_allocate_page;
5886 memcpy(&pPrevTrunk->aData[0], &pTrunk->aData[0], 4);
5888 }else{
5889 /* The trunk page is required by the caller but it contains
5890 ** pointers to free-list leaves. The first leaf becomes a trunk
5891 ** page in this case.
5893 MemPage *pNewTrunk;
5894 Pgno iNewTrunk = get4byte(&pTrunk->aData[8]);
5895 if( iNewTrunk>mxPage ){
5896 rc = SQLITE_CORRUPT_PGNO(iTrunk);
5897 goto end_allocate_page;
5899 testcase( iNewTrunk==mxPage );
5900 rc = btreeGetUnusedPage(pBt, iNewTrunk, &pNewTrunk, 0);
5901 if( rc!=SQLITE_OK ){
5902 goto end_allocate_page;
5904 rc = sqlite3PagerWrite(pNewTrunk->pDbPage);
5905 if( rc!=SQLITE_OK ){
5906 releasePage(pNewTrunk);
5907 goto end_allocate_page;
5909 memcpy(&pNewTrunk->aData[0], &pTrunk->aData[0], 4);
5910 put4byte(&pNewTrunk->aData[4], k-1);
5911 memcpy(&pNewTrunk->aData[8], &pTrunk->aData[12], (k-1)*4);
5912 releasePage(pNewTrunk);
5913 if( !pPrevTrunk ){
5914 assert( sqlite3PagerIswriteable(pPage1->pDbPage) );
5915 put4byte(&pPage1->aData[32], iNewTrunk);
5916 }else{
5917 rc = sqlite3PagerWrite(pPrevTrunk->pDbPage);
5918 if( rc ){
5919 goto end_allocate_page;
5921 put4byte(&pPrevTrunk->aData[0], iNewTrunk);
5924 pTrunk = 0;
5925 TRACE(("ALLOCATE: %d trunk - %d free pages left\n", *pPgno, n-1));
5926 #endif
5927 }else if( k>0 ){
5928 /* Extract a leaf from the trunk */
5929 u32 closest;
5930 Pgno iPage;
5931 unsigned char *aData = pTrunk->aData;
5932 if( nearby>0 ){
5933 u32 i;
5934 closest = 0;
5935 if( eMode==BTALLOC_LE ){
5936 for(i=0; i<k; i++){
5937 iPage = get4byte(&aData[8+i*4]);
5938 if( iPage<=nearby ){
5939 closest = i;
5940 break;
5943 }else{
5944 int dist;
5945 dist = sqlite3AbsInt32(get4byte(&aData[8]) - nearby);
5946 for(i=1; i<k; i++){
5947 int d2 = sqlite3AbsInt32(get4byte(&aData[8+i*4]) - nearby);
5948 if( d2<dist ){
5949 closest = i;
5950 dist = d2;
5954 }else{
5955 closest = 0;
5958 iPage = get4byte(&aData[8+closest*4]);
5959 testcase( iPage==mxPage );
5960 if( iPage>mxPage ){
5961 rc = SQLITE_CORRUPT_PGNO(iTrunk);
5962 goto end_allocate_page;
5964 testcase( iPage==mxPage );
5965 if( !searchList
5966 || (iPage==nearby || (iPage<nearby && eMode==BTALLOC_LE))
5968 int noContent;
5969 *pPgno = iPage;
5970 TRACE(("ALLOCATE: %d was leaf %d of %d on trunk %d"
5971 ": %d more free pages\n",
5972 *pPgno, closest+1, k, pTrunk->pgno, n-1));
5973 rc = sqlite3PagerWrite(pTrunk->pDbPage);
5974 if( rc ) goto end_allocate_page;
5975 if( closest<k-1 ){
5976 memcpy(&aData[8+closest*4], &aData[4+k*4], 4);
5978 put4byte(&aData[4], k-1);
5979 noContent = !btreeGetHasContent(pBt, *pPgno)? PAGER_GET_NOCONTENT : 0;
5980 rc = btreeGetUnusedPage(pBt, *pPgno, ppPage, noContent);
5981 if( rc==SQLITE_OK ){
5982 rc = sqlite3PagerWrite((*ppPage)->pDbPage);
5983 if( rc!=SQLITE_OK ){
5984 releasePage(*ppPage);
5985 *ppPage = 0;
5988 searchList = 0;
5991 releasePage(pPrevTrunk);
5992 pPrevTrunk = 0;
5993 }while( searchList );
5994 }else{
5995 /* There are no pages on the freelist, so append a new page to the
5996 ** database image.
5998 ** Normally, new pages allocated by this block can be requested from the
5999 ** pager layer with the 'no-content' flag set. This prevents the pager
6000 ** from trying to read the pages content from disk. However, if the
6001 ** current transaction has already run one or more incremental-vacuum
6002 ** steps, then the page we are about to allocate may contain content
6003 ** that is required in the event of a rollback. In this case, do
6004 ** not set the no-content flag. This causes the pager to load and journal
6005 ** the current page content before overwriting it.
6007 ** Note that the pager will not actually attempt to load or journal
6008 ** content for any page that really does lie past the end of the database
6009 ** file on disk. So the effects of disabling the no-content optimization
6010 ** here are confined to those pages that lie between the end of the
6011 ** database image and the end of the database file.
6013 int bNoContent = (0==IfNotOmitAV(pBt->bDoTruncate))? PAGER_GET_NOCONTENT:0;
6015 rc = sqlite3PagerWrite(pBt->pPage1->pDbPage);
6016 if( rc ) return rc;
6017 pBt->nPage++;
6018 if( pBt->nPage==PENDING_BYTE_PAGE(pBt) ) pBt->nPage++;
6020 #ifndef SQLITE_OMIT_AUTOVACUUM
6021 if( pBt->autoVacuum && PTRMAP_ISPAGE(pBt, pBt->nPage) ){
6022 /* If *pPgno refers to a pointer-map page, allocate two new pages
6023 ** at the end of the file instead of one. The first allocated page
6024 ** becomes a new pointer-map page, the second is used by the caller.
6026 MemPage *pPg = 0;
6027 TRACE(("ALLOCATE: %d from end of file (pointer-map page)\n", pBt->nPage));
6028 assert( pBt->nPage!=PENDING_BYTE_PAGE(pBt) );
6029 rc = btreeGetUnusedPage(pBt, pBt->nPage, &pPg, bNoContent);
6030 if( rc==SQLITE_OK ){
6031 rc = sqlite3PagerWrite(pPg->pDbPage);
6032 releasePage(pPg);
6034 if( rc ) return rc;
6035 pBt->nPage++;
6036 if( pBt->nPage==PENDING_BYTE_PAGE(pBt) ){ pBt->nPage++; }
6038 #endif
6039 put4byte(28 + (u8*)pBt->pPage1->aData, pBt->nPage);
6040 *pPgno = pBt->nPage;
6042 assert( *pPgno!=PENDING_BYTE_PAGE(pBt) );
6043 rc = btreeGetUnusedPage(pBt, *pPgno, ppPage, bNoContent);
6044 if( rc ) return rc;
6045 rc = sqlite3PagerWrite((*ppPage)->pDbPage);
6046 if( rc!=SQLITE_OK ){
6047 releasePage(*ppPage);
6048 *ppPage = 0;
6050 TRACE(("ALLOCATE: %d from end of file\n", *pPgno));
6053 assert( *pPgno!=PENDING_BYTE_PAGE(pBt) );
6055 end_allocate_page:
6056 releasePage(pTrunk);
6057 releasePage(pPrevTrunk);
6058 assert( rc!=SQLITE_OK || sqlite3PagerPageRefcount((*ppPage)->pDbPage)<=1 );
6059 assert( rc!=SQLITE_OK || (*ppPage)->isInit==0 );
6060 return rc;
6064 ** This function is used to add page iPage to the database file free-list.
6065 ** It is assumed that the page is not already a part of the free-list.
6067 ** The value passed as the second argument to this function is optional.
6068 ** If the caller happens to have a pointer to the MemPage object
6069 ** corresponding to page iPage handy, it may pass it as the second value.
6070 ** Otherwise, it may pass NULL.
6072 ** If a pointer to a MemPage object is passed as the second argument,
6073 ** its reference count is not altered by this function.
6075 static int freePage2(BtShared *pBt, MemPage *pMemPage, Pgno iPage){
6076 MemPage *pTrunk = 0; /* Free-list trunk page */
6077 Pgno iTrunk = 0; /* Page number of free-list trunk page */
6078 MemPage *pPage1 = pBt->pPage1; /* Local reference to page 1 */
6079 MemPage *pPage; /* Page being freed. May be NULL. */
6080 int rc; /* Return Code */
6081 int nFree; /* Initial number of pages on free-list */
6083 assert( sqlite3_mutex_held(pBt->mutex) );
6084 assert( CORRUPT_DB || iPage>1 );
6085 assert( !pMemPage || pMemPage->pgno==iPage );
6087 if( iPage<2 ) return SQLITE_CORRUPT_BKPT;
6088 if( pMemPage ){
6089 pPage = pMemPage;
6090 sqlite3PagerRef(pPage->pDbPage);
6091 }else{
6092 pPage = btreePageLookup(pBt, iPage);
6095 /* Increment the free page count on pPage1 */
6096 rc = sqlite3PagerWrite(pPage1->pDbPage);
6097 if( rc ) goto freepage_out;
6098 nFree = get4byte(&pPage1->aData[36]);
6099 put4byte(&pPage1->aData[36], nFree+1);
6101 if( pBt->btsFlags & BTS_SECURE_DELETE ){
6102 /* If the secure_delete option is enabled, then
6103 ** always fully overwrite deleted information with zeros.
6105 if( (!pPage && ((rc = btreeGetPage(pBt, iPage, &pPage, 0))!=0) )
6106 || ((rc = sqlite3PagerWrite(pPage->pDbPage))!=0)
6108 goto freepage_out;
6110 memset(pPage->aData, 0, pPage->pBt->pageSize);
6113 /* If the database supports auto-vacuum, write an entry in the pointer-map
6114 ** to indicate that the page is free.
6116 if( ISAUTOVACUUM ){
6117 ptrmapPut(pBt, iPage, PTRMAP_FREEPAGE, 0, &rc);
6118 if( rc ) goto freepage_out;
6121 /* Now manipulate the actual database free-list structure. There are two
6122 ** possibilities. If the free-list is currently empty, or if the first
6123 ** trunk page in the free-list is full, then this page will become a
6124 ** new free-list trunk page. Otherwise, it will become a leaf of the
6125 ** first trunk page in the current free-list. This block tests if it
6126 ** is possible to add the page as a new free-list leaf.
6128 if( nFree!=0 ){
6129 u32 nLeaf; /* Initial number of leaf cells on trunk page */
6131 iTrunk = get4byte(&pPage1->aData[32]);
6132 rc = btreeGetPage(pBt, iTrunk, &pTrunk, 0);
6133 if( rc!=SQLITE_OK ){
6134 goto freepage_out;
6137 nLeaf = get4byte(&pTrunk->aData[4]);
6138 assert( pBt->usableSize>32 );
6139 if( nLeaf > (u32)pBt->usableSize/4 - 2 ){
6140 rc = SQLITE_CORRUPT_BKPT;
6141 goto freepage_out;
6143 if( nLeaf < (u32)pBt->usableSize/4 - 8 ){
6144 /* In this case there is room on the trunk page to insert the page
6145 ** being freed as a new leaf.
6147 ** Note that the trunk page is not really full until it contains
6148 ** usableSize/4 - 2 entries, not usableSize/4 - 8 entries as we have
6149 ** coded. But due to a coding error in versions of SQLite prior to
6150 ** 3.6.0, databases with freelist trunk pages holding more than
6151 ** usableSize/4 - 8 entries will be reported as corrupt. In order
6152 ** to maintain backwards compatibility with older versions of SQLite,
6153 ** we will continue to restrict the number of entries to usableSize/4 - 8
6154 ** for now. At some point in the future (once everyone has upgraded
6155 ** to 3.6.0 or later) we should consider fixing the conditional above
6156 ** to read "usableSize/4-2" instead of "usableSize/4-8".
6158 ** EVIDENCE-OF: R-19920-11576 However, newer versions of SQLite still
6159 ** avoid using the last six entries in the freelist trunk page array in
6160 ** order that database files created by newer versions of SQLite can be
6161 ** read by older versions of SQLite.
6163 rc = sqlite3PagerWrite(pTrunk->pDbPage);
6164 if( rc==SQLITE_OK ){
6165 put4byte(&pTrunk->aData[4], nLeaf+1);
6166 put4byte(&pTrunk->aData[8+nLeaf*4], iPage);
6167 if( pPage && (pBt->btsFlags & BTS_SECURE_DELETE)==0 ){
6168 sqlite3PagerDontWrite(pPage->pDbPage);
6170 rc = btreeSetHasContent(pBt, iPage);
6172 TRACE(("FREE-PAGE: %d leaf on trunk page %d\n",pPage->pgno,pTrunk->pgno));
6173 goto freepage_out;
6177 /* If control flows to this point, then it was not possible to add the
6178 ** the page being freed as a leaf page of the first trunk in the free-list.
6179 ** Possibly because the free-list is empty, or possibly because the
6180 ** first trunk in the free-list is full. Either way, the page being freed
6181 ** will become the new first trunk page in the free-list.
6183 if( pPage==0 && SQLITE_OK!=(rc = btreeGetPage(pBt, iPage, &pPage, 0)) ){
6184 goto freepage_out;
6186 rc = sqlite3PagerWrite(pPage->pDbPage);
6187 if( rc!=SQLITE_OK ){
6188 goto freepage_out;
6190 put4byte(pPage->aData, iTrunk);
6191 put4byte(&pPage->aData[4], 0);
6192 put4byte(&pPage1->aData[32], iPage);
6193 TRACE(("FREE-PAGE: %d new trunk page replacing %d\n", pPage->pgno, iTrunk));
6195 freepage_out:
6196 if( pPage ){
6197 pPage->isInit = 0;
6199 releasePage(pPage);
6200 releasePage(pTrunk);
6201 return rc;
6203 static void freePage(MemPage *pPage, int *pRC){
6204 if( (*pRC)==SQLITE_OK ){
6205 *pRC = freePage2(pPage->pBt, pPage, pPage->pgno);
6210 ** Free any overflow pages associated with the given Cell. Store
6211 ** size information about the cell in pInfo.
6213 static int clearCell(
6214 MemPage *pPage, /* The page that contains the Cell */
6215 unsigned char *pCell, /* First byte of the Cell */
6216 CellInfo *pInfo /* Size information about the cell */
6218 BtShared *pBt;
6219 Pgno ovflPgno;
6220 int rc;
6221 int nOvfl;
6222 u32 ovflPageSize;
6224 assert( sqlite3_mutex_held(pPage->pBt->mutex) );
6225 pPage->xParseCell(pPage, pCell, pInfo);
6226 if( pInfo->nLocal==pInfo->nPayload ){
6227 return SQLITE_OK; /* No overflow pages. Return without doing anything */
6229 testcase( pCell + pInfo->nSize == pPage->aDataEnd );
6230 testcase( pCell + (pInfo->nSize-1) == pPage->aDataEnd );
6231 if( pCell + pInfo->nSize > pPage->aDataEnd ){
6232 /* Cell extends past end of page */
6233 return SQLITE_CORRUPT_PAGE(pPage);
6235 ovflPgno = get4byte(pCell + pInfo->nSize - 4);
6236 pBt = pPage->pBt;
6237 assert( pBt->usableSize > 4 );
6238 ovflPageSize = pBt->usableSize - 4;
6239 nOvfl = (pInfo->nPayload - pInfo->nLocal + ovflPageSize - 1)/ovflPageSize;
6240 assert( nOvfl>0 ||
6241 (CORRUPT_DB && (pInfo->nPayload + ovflPageSize)<ovflPageSize)
6243 while( nOvfl-- ){
6244 Pgno iNext = 0;
6245 MemPage *pOvfl = 0;
6246 if( ovflPgno<2 || ovflPgno>btreePagecount(pBt) ){
6247 /* 0 is not a legal page number and page 1 cannot be an
6248 ** overflow page. Therefore if ovflPgno<2 or past the end of the
6249 ** file the database must be corrupt. */
6250 return SQLITE_CORRUPT_BKPT;
6252 if( nOvfl ){
6253 rc = getOverflowPage(pBt, ovflPgno, &pOvfl, &iNext);
6254 if( rc ) return rc;
6257 if( ( pOvfl || ((pOvfl = btreePageLookup(pBt, ovflPgno))!=0) )
6258 && sqlite3PagerPageRefcount(pOvfl->pDbPage)!=1
6260 /* There is no reason any cursor should have an outstanding reference
6261 ** to an overflow page belonging to a cell that is being deleted/updated.
6262 ** So if there exists more than one reference to this page, then it
6263 ** must not really be an overflow page and the database must be corrupt.
6264 ** It is helpful to detect this before calling freePage2(), as
6265 ** freePage2() may zero the page contents if secure-delete mode is
6266 ** enabled. If this 'overflow' page happens to be a page that the
6267 ** caller is iterating through or using in some other way, this
6268 ** can be problematic.
6270 rc = SQLITE_CORRUPT_BKPT;
6271 }else{
6272 rc = freePage2(pBt, pOvfl, ovflPgno);
6275 if( pOvfl ){
6276 sqlite3PagerUnref(pOvfl->pDbPage);
6278 if( rc ) return rc;
6279 ovflPgno = iNext;
6281 return SQLITE_OK;
6285 ** Create the byte sequence used to represent a cell on page pPage
6286 ** and write that byte sequence into pCell[]. Overflow pages are
6287 ** allocated and filled in as necessary. The calling procedure
6288 ** is responsible for making sure sufficient space has been allocated
6289 ** for pCell[].
6291 ** Note that pCell does not necessary need to point to the pPage->aData
6292 ** area. pCell might point to some temporary storage. The cell will
6293 ** be constructed in this temporary area then copied into pPage->aData
6294 ** later.
6296 static int fillInCell(
6297 MemPage *pPage, /* The page that contains the cell */
6298 unsigned char *pCell, /* Complete text of the cell */
6299 const BtreePayload *pX, /* Payload with which to construct the cell */
6300 int *pnSize /* Write cell size here */
6302 int nPayload;
6303 const u8 *pSrc;
6304 int nSrc, n, rc, mn;
6305 int spaceLeft;
6306 MemPage *pToRelease;
6307 unsigned char *pPrior;
6308 unsigned char *pPayload;
6309 BtShared *pBt;
6310 Pgno pgnoOvfl;
6311 int nHeader;
6313 assert( sqlite3_mutex_held(pPage->pBt->mutex) );
6315 /* pPage is not necessarily writeable since pCell might be auxiliary
6316 ** buffer space that is separate from the pPage buffer area */
6317 assert( pCell<pPage->aData || pCell>=&pPage->aData[pPage->pBt->pageSize]
6318 || sqlite3PagerIswriteable(pPage->pDbPage) );
6320 /* Fill in the header. */
6321 nHeader = pPage->childPtrSize;
6322 if( pPage->intKey ){
6323 nPayload = pX->nData + pX->nZero;
6324 pSrc = pX->pData;
6325 nSrc = pX->nData;
6326 assert( pPage->intKeyLeaf ); /* fillInCell() only called for leaves */
6327 nHeader += putVarint32(&pCell[nHeader], nPayload);
6328 nHeader += putVarint(&pCell[nHeader], *(u64*)&pX->nKey);
6329 }else{
6330 assert( pX->nKey<=0x7fffffff && pX->pKey!=0 );
6331 nSrc = nPayload = (int)pX->nKey;
6332 pSrc = pX->pKey;
6333 nHeader += putVarint32(&pCell[nHeader], nPayload);
6336 /* Fill in the payload */
6337 pPayload = &pCell[nHeader];
6338 if( nPayload<=pPage->maxLocal ){
6339 /* This is the common case where everything fits on the btree page
6340 ** and no overflow pages are required. */
6341 n = nHeader + nPayload;
6342 testcase( n==3 );
6343 testcase( n==4 );
6344 if( n<4 ) n = 4;
6345 *pnSize = n;
6346 assert( nSrc<=nPayload );
6347 testcase( nSrc<nPayload );
6348 memcpy(pPayload, pSrc, nSrc);
6349 memset(pPayload+nSrc, 0, nPayload-nSrc);
6350 return SQLITE_OK;
6353 /* If we reach this point, it means that some of the content will need
6354 ** to spill onto overflow pages.
6356 mn = pPage->minLocal;
6357 n = mn + (nPayload - mn) % (pPage->pBt->usableSize - 4);
6358 testcase( n==pPage->maxLocal );
6359 testcase( n==pPage->maxLocal+1 );
6360 if( n > pPage->maxLocal ) n = mn;
6361 spaceLeft = n;
6362 *pnSize = n + nHeader + 4;
6363 pPrior = &pCell[nHeader+n];
6364 pToRelease = 0;
6365 pgnoOvfl = 0;
6366 pBt = pPage->pBt;
6368 /* At this point variables should be set as follows:
6370 ** nPayload Total payload size in bytes
6371 ** pPayload Begin writing payload here
6372 ** spaceLeft Space available at pPayload. If nPayload>spaceLeft,
6373 ** that means content must spill into overflow pages.
6374 ** *pnSize Size of the local cell (not counting overflow pages)
6375 ** pPrior Where to write the pgno of the first overflow page
6377 ** Use a call to btreeParseCellPtr() to verify that the values above
6378 ** were computed correctly.
6380 #ifdef SQLITE_DEBUG
6382 CellInfo info;
6383 pPage->xParseCell(pPage, pCell, &info);
6384 assert( nHeader==(int)(info.pPayload - pCell) );
6385 assert( info.nKey==pX->nKey );
6386 assert( *pnSize == info.nSize );
6387 assert( spaceLeft == info.nLocal );
6389 #endif
6391 /* Write the payload into the local Cell and any extra into overflow pages */
6392 while( 1 ){
6393 n = nPayload;
6394 if( n>spaceLeft ) n = spaceLeft;
6396 /* If pToRelease is not zero than pPayload points into the data area
6397 ** of pToRelease. Make sure pToRelease is still writeable. */
6398 assert( pToRelease==0 || sqlite3PagerIswriteable(pToRelease->pDbPage) );
6400 /* If pPayload is part of the data area of pPage, then make sure pPage
6401 ** is still writeable */
6402 assert( pPayload<pPage->aData || pPayload>=&pPage->aData[pBt->pageSize]
6403 || sqlite3PagerIswriteable(pPage->pDbPage) );
6405 if( nSrc>=n ){
6406 memcpy(pPayload, pSrc, n);
6407 }else if( nSrc>0 ){
6408 n = nSrc;
6409 memcpy(pPayload, pSrc, n);
6410 }else{
6411 memset(pPayload, 0, n);
6413 nPayload -= n;
6414 if( nPayload<=0 ) break;
6415 pPayload += n;
6416 pSrc += n;
6417 nSrc -= n;
6418 spaceLeft -= n;
6419 if( spaceLeft==0 ){
6420 MemPage *pOvfl = 0;
6421 #ifndef SQLITE_OMIT_AUTOVACUUM
6422 Pgno pgnoPtrmap = pgnoOvfl; /* Overflow page pointer-map entry page */
6423 if( pBt->autoVacuum ){
6425 pgnoOvfl++;
6426 } while(
6427 PTRMAP_ISPAGE(pBt, pgnoOvfl) || pgnoOvfl==PENDING_BYTE_PAGE(pBt)
6430 #endif
6431 rc = allocateBtreePage(pBt, &pOvfl, &pgnoOvfl, pgnoOvfl, 0);
6432 #ifndef SQLITE_OMIT_AUTOVACUUM
6433 /* If the database supports auto-vacuum, and the second or subsequent
6434 ** overflow page is being allocated, add an entry to the pointer-map
6435 ** for that page now.
6437 ** If this is the first overflow page, then write a partial entry
6438 ** to the pointer-map. If we write nothing to this pointer-map slot,
6439 ** then the optimistic overflow chain processing in clearCell()
6440 ** may misinterpret the uninitialized values and delete the
6441 ** wrong pages from the database.
6443 if( pBt->autoVacuum && rc==SQLITE_OK ){
6444 u8 eType = (pgnoPtrmap?PTRMAP_OVERFLOW2:PTRMAP_OVERFLOW1);
6445 ptrmapPut(pBt, pgnoOvfl, eType, pgnoPtrmap, &rc);
6446 if( rc ){
6447 releasePage(pOvfl);
6450 #endif
6451 if( rc ){
6452 releasePage(pToRelease);
6453 return rc;
6456 /* If pToRelease is not zero than pPrior points into the data area
6457 ** of pToRelease. Make sure pToRelease is still writeable. */
6458 assert( pToRelease==0 || sqlite3PagerIswriteable(pToRelease->pDbPage) );
6460 /* If pPrior is part of the data area of pPage, then make sure pPage
6461 ** is still writeable */
6462 assert( pPrior<pPage->aData || pPrior>=&pPage->aData[pBt->pageSize]
6463 || sqlite3PagerIswriteable(pPage->pDbPage) );
6465 put4byte(pPrior, pgnoOvfl);
6466 releasePage(pToRelease);
6467 pToRelease = pOvfl;
6468 pPrior = pOvfl->aData;
6469 put4byte(pPrior, 0);
6470 pPayload = &pOvfl->aData[4];
6471 spaceLeft = pBt->usableSize - 4;
6474 releasePage(pToRelease);
6475 return SQLITE_OK;
6479 ** Remove the i-th cell from pPage. This routine effects pPage only.
6480 ** The cell content is not freed or deallocated. It is assumed that
6481 ** the cell content has been copied someplace else. This routine just
6482 ** removes the reference to the cell from pPage.
6484 ** "sz" must be the number of bytes in the cell.
6486 static void dropCell(MemPage *pPage, int idx, int sz, int *pRC){
6487 u32 pc; /* Offset to cell content of cell being deleted */
6488 u8 *data; /* pPage->aData */
6489 u8 *ptr; /* Used to move bytes around within data[] */
6490 int rc; /* The return code */
6491 int hdr; /* Beginning of the header. 0 most pages. 100 page 1 */
6493 if( *pRC ) return;
6494 assert( idx>=0 && idx<pPage->nCell );
6495 assert( CORRUPT_DB || sz==cellSize(pPage, idx) );
6496 assert( sqlite3PagerIswriteable(pPage->pDbPage) );
6497 assert( sqlite3_mutex_held(pPage->pBt->mutex) );
6498 data = pPage->aData;
6499 ptr = &pPage->aCellIdx[2*idx];
6500 pc = get2byte(ptr);
6501 hdr = pPage->hdrOffset;
6502 testcase( pc==get2byte(&data[hdr+5]) );
6503 testcase( pc+sz==pPage->pBt->usableSize );
6504 if( pc+sz > pPage->pBt->usableSize ){
6505 *pRC = SQLITE_CORRUPT_BKPT;
6506 return;
6508 rc = freeSpace(pPage, pc, sz);
6509 if( rc ){
6510 *pRC = rc;
6511 return;
6513 pPage->nCell--;
6514 if( pPage->nCell==0 ){
6515 memset(&data[hdr+1], 0, 4);
6516 data[hdr+7] = 0;
6517 put2byte(&data[hdr+5], pPage->pBt->usableSize);
6518 pPage->nFree = pPage->pBt->usableSize - pPage->hdrOffset
6519 - pPage->childPtrSize - 8;
6520 }else{
6521 memmove(ptr, ptr+2, 2*(pPage->nCell - idx));
6522 put2byte(&data[hdr+3], pPage->nCell);
6523 pPage->nFree += 2;
6528 ** Insert a new cell on pPage at cell index "i". pCell points to the
6529 ** content of the cell.
6531 ** If the cell content will fit on the page, then put it there. If it
6532 ** will not fit, then make a copy of the cell content into pTemp if
6533 ** pTemp is not null. Regardless of pTemp, allocate a new entry
6534 ** in pPage->apOvfl[] and make it point to the cell content (either
6535 ** in pTemp or the original pCell) and also record its index.
6536 ** Allocating a new entry in pPage->aCell[] implies that
6537 ** pPage->nOverflow is incremented.
6539 ** *pRC must be SQLITE_OK when this routine is called.
6541 static void insertCell(
6542 MemPage *pPage, /* Page into which we are copying */
6543 int i, /* New cell becomes the i-th cell of the page */
6544 u8 *pCell, /* Content of the new cell */
6545 int sz, /* Bytes of content in pCell */
6546 u8 *pTemp, /* Temp storage space for pCell, if needed */
6547 Pgno iChild, /* If non-zero, replace first 4 bytes with this value */
6548 int *pRC /* Read and write return code from here */
6550 int idx = 0; /* Where to write new cell content in data[] */
6551 int j; /* Loop counter */
6552 u8 *data; /* The content of the whole page */
6553 u8 *pIns; /* The point in pPage->aCellIdx[] where no cell inserted */
6555 assert( *pRC==SQLITE_OK );
6556 assert( i>=0 && i<=pPage->nCell+pPage->nOverflow );
6557 assert( MX_CELL(pPage->pBt)<=10921 );
6558 assert( pPage->nCell<=MX_CELL(pPage->pBt) || CORRUPT_DB );
6559 assert( pPage->nOverflow<=ArraySize(pPage->apOvfl) );
6560 assert( ArraySize(pPage->apOvfl)==ArraySize(pPage->aiOvfl) );
6561 assert( sqlite3_mutex_held(pPage->pBt->mutex) );
6562 /* The cell should normally be sized correctly. However, when moving a
6563 ** malformed cell from a leaf page to an interior page, if the cell size
6564 ** wanted to be less than 4 but got rounded up to 4 on the leaf, then size
6565 ** might be less than 8 (leaf-size + pointer) on the interior node. Hence
6566 ** the term after the || in the following assert(). */
6567 assert( sz==pPage->xCellSize(pPage, pCell) || (sz==8 && iChild>0) );
6568 if( pPage->nOverflow || sz+2>pPage->nFree ){
6569 if( pTemp ){
6570 memcpy(pTemp, pCell, sz);
6571 pCell = pTemp;
6573 if( iChild ){
6574 put4byte(pCell, iChild);
6576 j = pPage->nOverflow++;
6577 /* Comparison against ArraySize-1 since we hold back one extra slot
6578 ** as a contingency. In other words, never need more than 3 overflow
6579 ** slots but 4 are allocated, just to be safe. */
6580 assert( j < ArraySize(pPage->apOvfl)-1 );
6581 pPage->apOvfl[j] = pCell;
6582 pPage->aiOvfl[j] = (u16)i;
6584 /* When multiple overflows occur, they are always sequential and in
6585 ** sorted order. This invariants arise because multiple overflows can
6586 ** only occur when inserting divider cells into the parent page during
6587 ** balancing, and the dividers are adjacent and sorted.
6589 assert( j==0 || pPage->aiOvfl[j-1]<(u16)i ); /* Overflows in sorted order */
6590 assert( j==0 || i==pPage->aiOvfl[j-1]+1 ); /* Overflows are sequential */
6591 }else{
6592 int rc = sqlite3PagerWrite(pPage->pDbPage);
6593 if( rc!=SQLITE_OK ){
6594 *pRC = rc;
6595 return;
6597 assert( sqlite3PagerIswriteable(pPage->pDbPage) );
6598 data = pPage->aData;
6599 assert( &data[pPage->cellOffset]==pPage->aCellIdx );
6600 rc = allocateSpace(pPage, sz, &idx);
6601 if( rc ){ *pRC = rc; return; }
6602 /* The allocateSpace() routine guarantees the following properties
6603 ** if it returns successfully */
6604 assert( idx >= 0 );
6605 assert( idx >= pPage->cellOffset+2*pPage->nCell+2 || CORRUPT_DB );
6606 assert( idx+sz <= (int)pPage->pBt->usableSize );
6607 pPage->nFree -= (u16)(2 + sz);
6608 memcpy(&data[idx], pCell, sz);
6609 if( iChild ){
6610 put4byte(&data[idx], iChild);
6612 pIns = pPage->aCellIdx + i*2;
6613 memmove(pIns+2, pIns, 2*(pPage->nCell - i));
6614 put2byte(pIns, idx);
6615 pPage->nCell++;
6616 /* increment the cell count */
6617 if( (++data[pPage->hdrOffset+4])==0 ) data[pPage->hdrOffset+3]++;
6618 assert( get2byte(&data[pPage->hdrOffset+3])==pPage->nCell );
6619 #ifndef SQLITE_OMIT_AUTOVACUUM
6620 if( pPage->pBt->autoVacuum ){
6621 /* The cell may contain a pointer to an overflow page. If so, write
6622 ** the entry for the overflow page into the pointer map.
6624 ptrmapPutOvflPtr(pPage, pCell, pRC);
6626 #endif
6631 ** A CellArray object contains a cache of pointers and sizes for a
6632 ** consecutive sequence of cells that might be held on multiple pages.
6634 typedef struct CellArray CellArray;
6635 struct CellArray {
6636 int nCell; /* Number of cells in apCell[] */
6637 MemPage *pRef; /* Reference page */
6638 u8 **apCell; /* All cells begin balanced */
6639 u16 *szCell; /* Local size of all cells in apCell[] */
6643 ** Make sure the cell sizes at idx, idx+1, ..., idx+N-1 have been
6644 ** computed.
6646 static void populateCellCache(CellArray *p, int idx, int N){
6647 assert( idx>=0 && idx+N<=p->nCell );
6648 while( N>0 ){
6649 assert( p->apCell[idx]!=0 );
6650 if( p->szCell[idx]==0 ){
6651 p->szCell[idx] = p->pRef->xCellSize(p->pRef, p->apCell[idx]);
6652 }else{
6653 assert( CORRUPT_DB ||
6654 p->szCell[idx]==p->pRef->xCellSize(p->pRef, p->apCell[idx]) );
6656 idx++;
6657 N--;
6662 ** Return the size of the Nth element of the cell array
6664 static SQLITE_NOINLINE u16 computeCellSize(CellArray *p, int N){
6665 assert( N>=0 && N<p->nCell );
6666 assert( p->szCell[N]==0 );
6667 p->szCell[N] = p->pRef->xCellSize(p->pRef, p->apCell[N]);
6668 return p->szCell[N];
6670 static u16 cachedCellSize(CellArray *p, int N){
6671 assert( N>=0 && N<p->nCell );
6672 if( p->szCell[N] ) return p->szCell[N];
6673 return computeCellSize(p, N);
6677 ** Array apCell[] contains pointers to nCell b-tree page cells. The
6678 ** szCell[] array contains the size in bytes of each cell. This function
6679 ** replaces the current contents of page pPg with the contents of the cell
6680 ** array.
6682 ** Some of the cells in apCell[] may currently be stored in pPg. This
6683 ** function works around problems caused by this by making a copy of any
6684 ** such cells before overwriting the page data.
6686 ** The MemPage.nFree field is invalidated by this function. It is the
6687 ** responsibility of the caller to set it correctly.
6689 static int rebuildPage(
6690 MemPage *pPg, /* Edit this page */
6691 int nCell, /* Final number of cells on page */
6692 u8 **apCell, /* Array of cells */
6693 u16 *szCell /* Array of cell sizes */
6695 const int hdr = pPg->hdrOffset; /* Offset of header on pPg */
6696 u8 * const aData = pPg->aData; /* Pointer to data for pPg */
6697 const int usableSize = pPg->pBt->usableSize;
6698 u8 * const pEnd = &aData[usableSize];
6699 int i;
6700 u8 *pCellptr = pPg->aCellIdx;
6701 u8 *pTmp = sqlite3PagerTempSpace(pPg->pBt->pPager);
6702 u8 *pData;
6704 i = get2byte(&aData[hdr+5]);
6705 memcpy(&pTmp[i], &aData[i], usableSize - i);
6707 pData = pEnd;
6708 for(i=0; i<nCell; i++){
6709 u8 *pCell = apCell[i];
6710 if( SQLITE_WITHIN(pCell,aData,pEnd) ){
6711 pCell = &pTmp[pCell - aData];
6713 pData -= szCell[i];
6714 put2byte(pCellptr, (pData - aData));
6715 pCellptr += 2;
6716 if( pData < pCellptr ) return SQLITE_CORRUPT_BKPT;
6717 memcpy(pData, pCell, szCell[i]);
6718 assert( szCell[i]==pPg->xCellSize(pPg, pCell) || CORRUPT_DB );
6719 testcase( szCell[i]!=pPg->xCellSize(pPg,pCell) );
6722 /* The pPg->nFree field is now set incorrectly. The caller will fix it. */
6723 pPg->nCell = nCell;
6724 pPg->nOverflow = 0;
6726 put2byte(&aData[hdr+1], 0);
6727 put2byte(&aData[hdr+3], pPg->nCell);
6728 put2byte(&aData[hdr+5], pData - aData);
6729 aData[hdr+7] = 0x00;
6730 return SQLITE_OK;
6734 ** Array apCell[] contains nCell pointers to b-tree cells. Array szCell
6735 ** contains the size in bytes of each such cell. This function attempts to
6736 ** add the cells stored in the array to page pPg. If it cannot (because
6737 ** the page needs to be defragmented before the cells will fit), non-zero
6738 ** is returned. Otherwise, if the cells are added successfully, zero is
6739 ** returned.
6741 ** Argument pCellptr points to the first entry in the cell-pointer array
6742 ** (part of page pPg) to populate. After cell apCell[0] is written to the
6743 ** page body, a 16-bit offset is written to pCellptr. And so on, for each
6744 ** cell in the array. It is the responsibility of the caller to ensure
6745 ** that it is safe to overwrite this part of the cell-pointer array.
6747 ** When this function is called, *ppData points to the start of the
6748 ** content area on page pPg. If the size of the content area is extended,
6749 ** *ppData is updated to point to the new start of the content area
6750 ** before returning.
6752 ** Finally, argument pBegin points to the byte immediately following the
6753 ** end of the space required by this page for the cell-pointer area (for
6754 ** all cells - not just those inserted by the current call). If the content
6755 ** area must be extended to before this point in order to accomodate all
6756 ** cells in apCell[], then the cells do not fit and non-zero is returned.
6758 static int pageInsertArray(
6759 MemPage *pPg, /* Page to add cells to */
6760 u8 *pBegin, /* End of cell-pointer array */
6761 u8 **ppData, /* IN/OUT: Page content -area pointer */
6762 u8 *pCellptr, /* Pointer to cell-pointer area */
6763 int iFirst, /* Index of first cell to add */
6764 int nCell, /* Number of cells to add to pPg */
6765 CellArray *pCArray /* Array of cells */
6767 int i;
6768 u8 *aData = pPg->aData;
6769 u8 *pData = *ppData;
6770 int iEnd = iFirst + nCell;
6771 assert( CORRUPT_DB || pPg->hdrOffset==0 ); /* Never called on page 1 */
6772 for(i=iFirst; i<iEnd; i++){
6773 int sz, rc;
6774 u8 *pSlot;
6775 sz = cachedCellSize(pCArray, i);
6776 if( (aData[1]==0 && aData[2]==0) || (pSlot = pageFindSlot(pPg,sz,&rc))==0 ){
6777 if( (pData - pBegin)<sz ) return 1;
6778 pData -= sz;
6779 pSlot = pData;
6781 /* pSlot and pCArray->apCell[i] will never overlap on a well-formed
6782 ** database. But they might for a corrupt database. Hence use memmove()
6783 ** since memcpy() sends SIGABORT with overlapping buffers on OpenBSD */
6784 assert( (pSlot+sz)<=pCArray->apCell[i]
6785 || pSlot>=(pCArray->apCell[i]+sz)
6786 || CORRUPT_DB );
6787 memmove(pSlot, pCArray->apCell[i], sz);
6788 put2byte(pCellptr, (pSlot - aData));
6789 pCellptr += 2;
6791 *ppData = pData;
6792 return 0;
6796 ** Array apCell[] contains nCell pointers to b-tree cells. Array szCell
6797 ** contains the size in bytes of each such cell. This function adds the
6798 ** space associated with each cell in the array that is currently stored
6799 ** within the body of pPg to the pPg free-list. The cell-pointers and other
6800 ** fields of the page are not updated.
6802 ** This function returns the total number of cells added to the free-list.
6804 static int pageFreeArray(
6805 MemPage *pPg, /* Page to edit */
6806 int iFirst, /* First cell to delete */
6807 int nCell, /* Cells to delete */
6808 CellArray *pCArray /* Array of cells */
6810 u8 * const aData = pPg->aData;
6811 u8 * const pEnd = &aData[pPg->pBt->usableSize];
6812 u8 * const pStart = &aData[pPg->hdrOffset + 8 + pPg->childPtrSize];
6813 int nRet = 0;
6814 int i;
6815 int iEnd = iFirst + nCell;
6816 u8 *pFree = 0;
6817 int szFree = 0;
6819 for(i=iFirst; i<iEnd; i++){
6820 u8 *pCell = pCArray->apCell[i];
6821 if( SQLITE_WITHIN(pCell, pStart, pEnd) ){
6822 int sz;
6823 /* No need to use cachedCellSize() here. The sizes of all cells that
6824 ** are to be freed have already been computing while deciding which
6825 ** cells need freeing */
6826 sz = pCArray->szCell[i]; assert( sz>0 );
6827 if( pFree!=(pCell + sz) ){
6828 if( pFree ){
6829 assert( pFree>aData && (pFree - aData)<65536 );
6830 freeSpace(pPg, (u16)(pFree - aData), szFree);
6832 pFree = pCell;
6833 szFree = sz;
6834 if( pFree+sz>pEnd ) return 0;
6835 }else{
6836 pFree = pCell;
6837 szFree += sz;
6839 nRet++;
6842 if( pFree ){
6843 assert( pFree>aData && (pFree - aData)<65536 );
6844 freeSpace(pPg, (u16)(pFree - aData), szFree);
6846 return nRet;
6850 ** apCell[] and szCell[] contains pointers to and sizes of all cells in the
6851 ** pages being balanced. The current page, pPg, has pPg->nCell cells starting
6852 ** with apCell[iOld]. After balancing, this page should hold nNew cells
6853 ** starting at apCell[iNew].
6855 ** This routine makes the necessary adjustments to pPg so that it contains
6856 ** the correct cells after being balanced.
6858 ** The pPg->nFree field is invalid when this function returns. It is the
6859 ** responsibility of the caller to set it correctly.
6861 static int editPage(
6862 MemPage *pPg, /* Edit this page */
6863 int iOld, /* Index of first cell currently on page */
6864 int iNew, /* Index of new first cell on page */
6865 int nNew, /* Final number of cells on page */
6866 CellArray *pCArray /* Array of cells and sizes */
6868 u8 * const aData = pPg->aData;
6869 const int hdr = pPg->hdrOffset;
6870 u8 *pBegin = &pPg->aCellIdx[nNew * 2];
6871 int nCell = pPg->nCell; /* Cells stored on pPg */
6872 u8 *pData;
6873 u8 *pCellptr;
6874 int i;
6875 int iOldEnd = iOld + pPg->nCell + pPg->nOverflow;
6876 int iNewEnd = iNew + nNew;
6878 #ifdef SQLITE_DEBUG
6879 u8 *pTmp = sqlite3PagerTempSpace(pPg->pBt->pPager);
6880 memcpy(pTmp, aData, pPg->pBt->usableSize);
6881 #endif
6883 /* Remove cells from the start and end of the page */
6884 if( iOld<iNew ){
6885 int nShift = pageFreeArray(pPg, iOld, iNew-iOld, pCArray);
6886 memmove(pPg->aCellIdx, &pPg->aCellIdx[nShift*2], nCell*2);
6887 nCell -= nShift;
6889 if( iNewEnd < iOldEnd ){
6890 nCell -= pageFreeArray(pPg, iNewEnd, iOldEnd - iNewEnd, pCArray);
6893 pData = &aData[get2byteNotZero(&aData[hdr+5])];
6894 if( pData<pBegin ) goto editpage_fail;
6896 /* Add cells to the start of the page */
6897 if( iNew<iOld ){
6898 int nAdd = MIN(nNew,iOld-iNew);
6899 assert( (iOld-iNew)<nNew || nCell==0 || CORRUPT_DB );
6900 pCellptr = pPg->aCellIdx;
6901 memmove(&pCellptr[nAdd*2], pCellptr, nCell*2);
6902 if( pageInsertArray(
6903 pPg, pBegin, &pData, pCellptr,
6904 iNew, nAdd, pCArray
6905 ) ) goto editpage_fail;
6906 nCell += nAdd;
6909 /* Add any overflow cells */
6910 for(i=0; i<pPg->nOverflow; i++){
6911 int iCell = (iOld + pPg->aiOvfl[i]) - iNew;
6912 if( iCell>=0 && iCell<nNew ){
6913 pCellptr = &pPg->aCellIdx[iCell * 2];
6914 memmove(&pCellptr[2], pCellptr, (nCell - iCell) * 2);
6915 nCell++;
6916 if( pageInsertArray(
6917 pPg, pBegin, &pData, pCellptr,
6918 iCell+iNew, 1, pCArray
6919 ) ) goto editpage_fail;
6923 /* Append cells to the end of the page */
6924 pCellptr = &pPg->aCellIdx[nCell*2];
6925 if( pageInsertArray(
6926 pPg, pBegin, &pData, pCellptr,
6927 iNew+nCell, nNew-nCell, pCArray
6928 ) ) goto editpage_fail;
6930 pPg->nCell = nNew;
6931 pPg->nOverflow = 0;
6933 put2byte(&aData[hdr+3], pPg->nCell);
6934 put2byte(&aData[hdr+5], pData - aData);
6936 #ifdef SQLITE_DEBUG
6937 for(i=0; i<nNew && !CORRUPT_DB; i++){
6938 u8 *pCell = pCArray->apCell[i+iNew];
6939 int iOff = get2byteAligned(&pPg->aCellIdx[i*2]);
6940 if( SQLITE_WITHIN(pCell, aData, &aData[pPg->pBt->usableSize]) ){
6941 pCell = &pTmp[pCell - aData];
6943 assert( 0==memcmp(pCell, &aData[iOff],
6944 pCArray->pRef->xCellSize(pCArray->pRef, pCArray->apCell[i+iNew])) );
6946 #endif
6948 return SQLITE_OK;
6949 editpage_fail:
6950 /* Unable to edit this page. Rebuild it from scratch instead. */
6951 populateCellCache(pCArray, iNew, nNew);
6952 return rebuildPage(pPg, nNew, &pCArray->apCell[iNew], &pCArray->szCell[iNew]);
6956 ** The following parameters determine how many adjacent pages get involved
6957 ** in a balancing operation. NN is the number of neighbors on either side
6958 ** of the page that participate in the balancing operation. NB is the
6959 ** total number of pages that participate, including the target page and
6960 ** NN neighbors on either side.
6962 ** The minimum value of NN is 1 (of course). Increasing NN above 1
6963 ** (to 2 or 3) gives a modest improvement in SELECT and DELETE performance
6964 ** in exchange for a larger degradation in INSERT and UPDATE performance.
6965 ** The value of NN appears to give the best results overall.
6967 #define NN 1 /* Number of neighbors on either side of pPage */
6968 #define NB (NN*2+1) /* Total pages involved in the balance */
6971 #ifndef SQLITE_OMIT_QUICKBALANCE
6973 ** This version of balance() handles the common special case where
6974 ** a new entry is being inserted on the extreme right-end of the
6975 ** tree, in other words, when the new entry will become the largest
6976 ** entry in the tree.
6978 ** Instead of trying to balance the 3 right-most leaf pages, just add
6979 ** a new page to the right-hand side and put the one new entry in
6980 ** that page. This leaves the right side of the tree somewhat
6981 ** unbalanced. But odds are that we will be inserting new entries
6982 ** at the end soon afterwards so the nearly empty page will quickly
6983 ** fill up. On average.
6985 ** pPage is the leaf page which is the right-most page in the tree.
6986 ** pParent is its parent. pPage must have a single overflow entry
6987 ** which is also the right-most entry on the page.
6989 ** The pSpace buffer is used to store a temporary copy of the divider
6990 ** cell that will be inserted into pParent. Such a cell consists of a 4
6991 ** byte page number followed by a variable length integer. In other
6992 ** words, at most 13 bytes. Hence the pSpace buffer must be at
6993 ** least 13 bytes in size.
6995 static int balance_quick(MemPage *pParent, MemPage *pPage, u8 *pSpace){
6996 BtShared *const pBt = pPage->pBt; /* B-Tree Database */
6997 MemPage *pNew; /* Newly allocated page */
6998 int rc; /* Return Code */
6999 Pgno pgnoNew; /* Page number of pNew */
7001 assert( sqlite3_mutex_held(pPage->pBt->mutex) );
7002 assert( sqlite3PagerIswriteable(pParent->pDbPage) );
7003 assert( pPage->nOverflow==1 );
7005 /* This error condition is now caught prior to reaching this function */
7006 if( NEVER(pPage->nCell==0) ) return SQLITE_CORRUPT_BKPT;
7008 /* Allocate a new page. This page will become the right-sibling of
7009 ** pPage. Make the parent page writable, so that the new divider cell
7010 ** may be inserted. If both these operations are successful, proceed.
7012 rc = allocateBtreePage(pBt, &pNew, &pgnoNew, 0, 0);
7014 if( rc==SQLITE_OK ){
7016 u8 *pOut = &pSpace[4];
7017 u8 *pCell = pPage->apOvfl[0];
7018 u16 szCell = pPage->xCellSize(pPage, pCell);
7019 u8 *pStop;
7021 assert( sqlite3PagerIswriteable(pNew->pDbPage) );
7022 assert( pPage->aData[0]==(PTF_INTKEY|PTF_LEAFDATA|PTF_LEAF) );
7023 zeroPage(pNew, PTF_INTKEY|PTF_LEAFDATA|PTF_LEAF);
7024 rc = rebuildPage(pNew, 1, &pCell, &szCell);
7025 if( NEVER(rc) ) return rc;
7026 pNew->nFree = pBt->usableSize - pNew->cellOffset - 2 - szCell;
7028 /* If this is an auto-vacuum database, update the pointer map
7029 ** with entries for the new page, and any pointer from the
7030 ** cell on the page to an overflow page. If either of these
7031 ** operations fails, the return code is set, but the contents
7032 ** of the parent page are still manipulated by thh code below.
7033 ** That is Ok, at this point the parent page is guaranteed to
7034 ** be marked as dirty. Returning an error code will cause a
7035 ** rollback, undoing any changes made to the parent page.
7037 if( ISAUTOVACUUM ){
7038 ptrmapPut(pBt, pgnoNew, PTRMAP_BTREE, pParent->pgno, &rc);
7039 if( szCell>pNew->minLocal ){
7040 ptrmapPutOvflPtr(pNew, pCell, &rc);
7044 /* Create a divider cell to insert into pParent. The divider cell
7045 ** consists of a 4-byte page number (the page number of pPage) and
7046 ** a variable length key value (which must be the same value as the
7047 ** largest key on pPage).
7049 ** To find the largest key value on pPage, first find the right-most
7050 ** cell on pPage. The first two fields of this cell are the
7051 ** record-length (a variable length integer at most 32-bits in size)
7052 ** and the key value (a variable length integer, may have any value).
7053 ** The first of the while(...) loops below skips over the record-length
7054 ** field. The second while(...) loop copies the key value from the
7055 ** cell on pPage into the pSpace buffer.
7057 pCell = findCell(pPage, pPage->nCell-1);
7058 pStop = &pCell[9];
7059 while( (*(pCell++)&0x80) && pCell<pStop );
7060 pStop = &pCell[9];
7061 while( ((*(pOut++) = *(pCell++))&0x80) && pCell<pStop );
7063 /* Insert the new divider cell into pParent. */
7064 if( rc==SQLITE_OK ){
7065 insertCell(pParent, pParent->nCell, pSpace, (int)(pOut-pSpace),
7066 0, pPage->pgno, &rc);
7069 /* Set the right-child pointer of pParent to point to the new page. */
7070 put4byte(&pParent->aData[pParent->hdrOffset+8], pgnoNew);
7072 /* Release the reference to the new page. */
7073 releasePage(pNew);
7076 return rc;
7078 #endif /* SQLITE_OMIT_QUICKBALANCE */
7080 #if 0
7082 ** This function does not contribute anything to the operation of SQLite.
7083 ** it is sometimes activated temporarily while debugging code responsible
7084 ** for setting pointer-map entries.
7086 static int ptrmapCheckPages(MemPage **apPage, int nPage){
7087 int i, j;
7088 for(i=0; i<nPage; i++){
7089 Pgno n;
7090 u8 e;
7091 MemPage *pPage = apPage[i];
7092 BtShared *pBt = pPage->pBt;
7093 assert( pPage->isInit );
7095 for(j=0; j<pPage->nCell; j++){
7096 CellInfo info;
7097 u8 *z;
7099 z = findCell(pPage, j);
7100 pPage->xParseCell(pPage, z, &info);
7101 if( info.nLocal<info.nPayload ){
7102 Pgno ovfl = get4byte(&z[info.nSize-4]);
7103 ptrmapGet(pBt, ovfl, &e, &n);
7104 assert( n==pPage->pgno && e==PTRMAP_OVERFLOW1 );
7106 if( !pPage->leaf ){
7107 Pgno child = get4byte(z);
7108 ptrmapGet(pBt, child, &e, &n);
7109 assert( n==pPage->pgno && e==PTRMAP_BTREE );
7112 if( !pPage->leaf ){
7113 Pgno child = get4byte(&pPage->aData[pPage->hdrOffset+8]);
7114 ptrmapGet(pBt, child, &e, &n);
7115 assert( n==pPage->pgno && e==PTRMAP_BTREE );
7118 return 1;
7120 #endif
7123 ** This function is used to copy the contents of the b-tree node stored
7124 ** on page pFrom to page pTo. If page pFrom was not a leaf page, then
7125 ** the pointer-map entries for each child page are updated so that the
7126 ** parent page stored in the pointer map is page pTo. If pFrom contained
7127 ** any cells with overflow page pointers, then the corresponding pointer
7128 ** map entries are also updated so that the parent page is page pTo.
7130 ** If pFrom is currently carrying any overflow cells (entries in the
7131 ** MemPage.apOvfl[] array), they are not copied to pTo.
7133 ** Before returning, page pTo is reinitialized using btreeInitPage().
7135 ** The performance of this function is not critical. It is only used by
7136 ** the balance_shallower() and balance_deeper() procedures, neither of
7137 ** which are called often under normal circumstances.
7139 static void copyNodeContent(MemPage *pFrom, MemPage *pTo, int *pRC){
7140 if( (*pRC)==SQLITE_OK ){
7141 BtShared * const pBt = pFrom->pBt;
7142 u8 * const aFrom = pFrom->aData;
7143 u8 * const aTo = pTo->aData;
7144 int const iFromHdr = pFrom->hdrOffset;
7145 int const iToHdr = ((pTo->pgno==1) ? 100 : 0);
7146 int rc;
7147 int iData;
7150 assert( pFrom->isInit );
7151 assert( pFrom->nFree>=iToHdr );
7152 assert( get2byte(&aFrom[iFromHdr+5]) <= (int)pBt->usableSize );
7154 /* Copy the b-tree node content from page pFrom to page pTo. */
7155 iData = get2byte(&aFrom[iFromHdr+5]);
7156 memcpy(&aTo[iData], &aFrom[iData], pBt->usableSize-iData);
7157 memcpy(&aTo[iToHdr], &aFrom[iFromHdr], pFrom->cellOffset + 2*pFrom->nCell);
7159 /* Reinitialize page pTo so that the contents of the MemPage structure
7160 ** match the new data. The initialization of pTo can actually fail under
7161 ** fairly obscure circumstances, even though it is a copy of initialized
7162 ** page pFrom.
7164 pTo->isInit = 0;
7165 rc = btreeInitPage(pTo);
7166 if( rc!=SQLITE_OK ){
7167 *pRC = rc;
7168 return;
7171 /* If this is an auto-vacuum database, update the pointer-map entries
7172 ** for any b-tree or overflow pages that pTo now contains the pointers to.
7174 if( ISAUTOVACUUM ){
7175 *pRC = setChildPtrmaps(pTo);
7181 ** This routine redistributes cells on the iParentIdx'th child of pParent
7182 ** (hereafter "the page") and up to 2 siblings so that all pages have about the
7183 ** same amount of free space. Usually a single sibling on either side of the
7184 ** page are used in the balancing, though both siblings might come from one
7185 ** side if the page is the first or last child of its parent. If the page
7186 ** has fewer than 2 siblings (something which can only happen if the page
7187 ** is a root page or a child of a root page) then all available siblings
7188 ** participate in the balancing.
7190 ** The number of siblings of the page might be increased or decreased by
7191 ** one or two in an effort to keep pages nearly full but not over full.
7193 ** Note that when this routine is called, some of the cells on the page
7194 ** might not actually be stored in MemPage.aData[]. This can happen
7195 ** if the page is overfull. This routine ensures that all cells allocated
7196 ** to the page and its siblings fit into MemPage.aData[] before returning.
7198 ** In the course of balancing the page and its siblings, cells may be
7199 ** inserted into or removed from the parent page (pParent). Doing so
7200 ** may cause the parent page to become overfull or underfull. If this
7201 ** happens, it is the responsibility of the caller to invoke the correct
7202 ** balancing routine to fix this problem (see the balance() routine).
7204 ** If this routine fails for any reason, it might leave the database
7205 ** in a corrupted state. So if this routine fails, the database should
7206 ** be rolled back.
7208 ** The third argument to this function, aOvflSpace, is a pointer to a
7209 ** buffer big enough to hold one page. If while inserting cells into the parent
7210 ** page (pParent) the parent page becomes overfull, this buffer is
7211 ** used to store the parent's overflow cells. Because this function inserts
7212 ** a maximum of four divider cells into the parent page, and the maximum
7213 ** size of a cell stored within an internal node is always less than 1/4
7214 ** of the page-size, the aOvflSpace[] buffer is guaranteed to be large
7215 ** enough for all overflow cells.
7217 ** If aOvflSpace is set to a null pointer, this function returns
7218 ** SQLITE_NOMEM.
7220 static int balance_nonroot(
7221 MemPage *pParent, /* Parent page of siblings being balanced */
7222 int iParentIdx, /* Index of "the page" in pParent */
7223 u8 *aOvflSpace, /* page-size bytes of space for parent ovfl */
7224 int isRoot, /* True if pParent is a root-page */
7225 int bBulk /* True if this call is part of a bulk load */
7227 BtShared *pBt; /* The whole database */
7228 int nMaxCells = 0; /* Allocated size of apCell, szCell, aFrom. */
7229 int nNew = 0; /* Number of pages in apNew[] */
7230 int nOld; /* Number of pages in apOld[] */
7231 int i, j, k; /* Loop counters */
7232 int nxDiv; /* Next divider slot in pParent->aCell[] */
7233 int rc = SQLITE_OK; /* The return code */
7234 u16 leafCorrection; /* 4 if pPage is a leaf. 0 if not */
7235 int leafData; /* True if pPage is a leaf of a LEAFDATA tree */
7236 int usableSpace; /* Bytes in pPage beyond the header */
7237 int pageFlags; /* Value of pPage->aData[0] */
7238 int iSpace1 = 0; /* First unused byte of aSpace1[] */
7239 int iOvflSpace = 0; /* First unused byte of aOvflSpace[] */
7240 int szScratch; /* Size of scratch memory requested */
7241 MemPage *apOld[NB]; /* pPage and up to two siblings */
7242 MemPage *apNew[NB+2]; /* pPage and up to NB siblings after balancing */
7243 u8 *pRight; /* Location in parent of right-sibling pointer */
7244 u8 *apDiv[NB-1]; /* Divider cells in pParent */
7245 int cntNew[NB+2]; /* Index in b.paCell[] of cell after i-th page */
7246 int cntOld[NB+2]; /* Old index in b.apCell[] */
7247 int szNew[NB+2]; /* Combined size of cells placed on i-th page */
7248 u8 *aSpace1; /* Space for copies of dividers cells */
7249 Pgno pgno; /* Temp var to store a page number in */
7250 u8 abDone[NB+2]; /* True after i'th new page is populated */
7251 Pgno aPgno[NB+2]; /* Page numbers of new pages before shuffling */
7252 Pgno aPgOrder[NB+2]; /* Copy of aPgno[] used for sorting pages */
7253 u16 aPgFlags[NB+2]; /* flags field of new pages before shuffling */
7254 CellArray b; /* Parsed information on cells being balanced */
7256 memset(abDone, 0, sizeof(abDone));
7257 b.nCell = 0;
7258 b.apCell = 0;
7259 pBt = pParent->pBt;
7260 assert( sqlite3_mutex_held(pBt->mutex) );
7261 assert( sqlite3PagerIswriteable(pParent->pDbPage) );
7263 #if 0
7264 TRACE(("BALANCE: begin page %d child of %d\n", pPage->pgno, pParent->pgno));
7265 #endif
7267 /* At this point pParent may have at most one overflow cell. And if
7268 ** this overflow cell is present, it must be the cell with
7269 ** index iParentIdx. This scenario comes about when this function
7270 ** is called (indirectly) from sqlite3BtreeDelete().
7272 assert( pParent->nOverflow==0 || pParent->nOverflow==1 );
7273 assert( pParent->nOverflow==0 || pParent->aiOvfl[0]==iParentIdx );
7275 if( !aOvflSpace ){
7276 return SQLITE_NOMEM_BKPT;
7279 /* Find the sibling pages to balance. Also locate the cells in pParent
7280 ** that divide the siblings. An attempt is made to find NN siblings on
7281 ** either side of pPage. More siblings are taken from one side, however,
7282 ** if there are fewer than NN siblings on the other side. If pParent
7283 ** has NB or fewer children then all children of pParent are taken.
7285 ** This loop also drops the divider cells from the parent page. This
7286 ** way, the remainder of the function does not have to deal with any
7287 ** overflow cells in the parent page, since if any existed they will
7288 ** have already been removed.
7290 i = pParent->nOverflow + pParent->nCell;
7291 if( i<2 ){
7292 nxDiv = 0;
7293 }else{
7294 assert( bBulk==0 || bBulk==1 );
7295 if( iParentIdx==0 ){
7296 nxDiv = 0;
7297 }else if( iParentIdx==i ){
7298 nxDiv = i-2+bBulk;
7299 }else{
7300 nxDiv = iParentIdx-1;
7302 i = 2-bBulk;
7304 nOld = i+1;
7305 if( (i+nxDiv-pParent->nOverflow)==pParent->nCell ){
7306 pRight = &pParent->aData[pParent->hdrOffset+8];
7307 }else{
7308 pRight = findCell(pParent, i+nxDiv-pParent->nOverflow);
7310 pgno = get4byte(pRight);
7311 while( 1 ){
7312 rc = getAndInitPage(pBt, pgno, &apOld[i], 0, 0);
7313 if( rc ){
7314 memset(apOld, 0, (i+1)*sizeof(MemPage*));
7315 goto balance_cleanup;
7317 nMaxCells += 1+apOld[i]->nCell+apOld[i]->nOverflow;
7318 if( (i--)==0 ) break;
7320 if( pParent->nOverflow && i+nxDiv==pParent->aiOvfl[0] ){
7321 apDiv[i] = pParent->apOvfl[0];
7322 pgno = get4byte(apDiv[i]);
7323 szNew[i] = pParent->xCellSize(pParent, apDiv[i]);
7324 pParent->nOverflow = 0;
7325 }else{
7326 apDiv[i] = findCell(pParent, i+nxDiv-pParent->nOverflow);
7327 pgno = get4byte(apDiv[i]);
7328 szNew[i] = pParent->xCellSize(pParent, apDiv[i]);
7330 /* Drop the cell from the parent page. apDiv[i] still points to
7331 ** the cell within the parent, even though it has been dropped.
7332 ** This is safe because dropping a cell only overwrites the first
7333 ** four bytes of it, and this function does not need the first
7334 ** four bytes of the divider cell. So the pointer is safe to use
7335 ** later on.
7337 ** But not if we are in secure-delete mode. In secure-delete mode,
7338 ** the dropCell() routine will overwrite the entire cell with zeroes.
7339 ** In this case, temporarily copy the cell into the aOvflSpace[]
7340 ** buffer. It will be copied out again as soon as the aSpace[] buffer
7341 ** is allocated. */
7342 if( pBt->btsFlags & BTS_FAST_SECURE ){
7343 int iOff;
7345 iOff = SQLITE_PTR_TO_INT(apDiv[i]) - SQLITE_PTR_TO_INT(pParent->aData);
7346 if( (iOff+szNew[i])>(int)pBt->usableSize ){
7347 rc = SQLITE_CORRUPT_BKPT;
7348 memset(apOld, 0, (i+1)*sizeof(MemPage*));
7349 goto balance_cleanup;
7350 }else{
7351 memcpy(&aOvflSpace[iOff], apDiv[i], szNew[i]);
7352 apDiv[i] = &aOvflSpace[apDiv[i]-pParent->aData];
7355 dropCell(pParent, i+nxDiv-pParent->nOverflow, szNew[i], &rc);
7359 /* Make nMaxCells a multiple of 4 in order to preserve 8-byte
7360 ** alignment */
7361 nMaxCells = (nMaxCells + 3)&~3;
7364 ** Allocate space for memory structures
7366 szScratch =
7367 nMaxCells*sizeof(u8*) /* b.apCell */
7368 + nMaxCells*sizeof(u16) /* b.szCell */
7369 + pBt->pageSize; /* aSpace1 */
7371 assert( szScratch<=6*(int)pBt->pageSize );
7372 b.apCell = sqlite3StackAllocRaw(0, szScratch );
7373 if( b.apCell==0 ){
7374 rc = SQLITE_NOMEM_BKPT;
7375 goto balance_cleanup;
7377 b.szCell = (u16*)&b.apCell[nMaxCells];
7378 aSpace1 = (u8*)&b.szCell[nMaxCells];
7379 assert( EIGHT_BYTE_ALIGNMENT(aSpace1) );
7382 ** Load pointers to all cells on sibling pages and the divider cells
7383 ** into the local b.apCell[] array. Make copies of the divider cells
7384 ** into space obtained from aSpace1[]. The divider cells have already
7385 ** been removed from pParent.
7387 ** If the siblings are on leaf pages, then the child pointers of the
7388 ** divider cells are stripped from the cells before they are copied
7389 ** into aSpace1[]. In this way, all cells in b.apCell[] are without
7390 ** child pointers. If siblings are not leaves, then all cell in
7391 ** b.apCell[] include child pointers. Either way, all cells in b.apCell[]
7392 ** are alike.
7394 ** leafCorrection: 4 if pPage is a leaf. 0 if pPage is not a leaf.
7395 ** leafData: 1 if pPage holds key+data and pParent holds only keys.
7397 b.pRef = apOld[0];
7398 leafCorrection = b.pRef->leaf*4;
7399 leafData = b.pRef->intKeyLeaf;
7400 for(i=0; i<nOld; i++){
7401 MemPage *pOld = apOld[i];
7402 int limit = pOld->nCell;
7403 u8 *aData = pOld->aData;
7404 u16 maskPage = pOld->maskPage;
7405 u8 *piCell = aData + pOld->cellOffset;
7406 u8 *piEnd;
7408 /* Verify that all sibling pages are of the same "type" (table-leaf,
7409 ** table-interior, index-leaf, or index-interior).
7411 if( pOld->aData[0]!=apOld[0]->aData[0] ){
7412 rc = SQLITE_CORRUPT_BKPT;
7413 goto balance_cleanup;
7416 /* Load b.apCell[] with pointers to all cells in pOld. If pOld
7417 ** contains overflow cells, include them in the b.apCell[] array
7418 ** in the correct spot.
7420 ** Note that when there are multiple overflow cells, it is always the
7421 ** case that they are sequential and adjacent. This invariant arises
7422 ** because multiple overflows can only occurs when inserting divider
7423 ** cells into a parent on a prior balance, and divider cells are always
7424 ** adjacent and are inserted in order. There is an assert() tagged
7425 ** with "NOTE 1" in the overflow cell insertion loop to prove this
7426 ** invariant.
7428 ** This must be done in advance. Once the balance starts, the cell
7429 ** offset section of the btree page will be overwritten and we will no
7430 ** long be able to find the cells if a pointer to each cell is not saved
7431 ** first.
7433 memset(&b.szCell[b.nCell], 0, sizeof(b.szCell[0])*(limit+pOld->nOverflow));
7434 if( pOld->nOverflow>0 ){
7435 limit = pOld->aiOvfl[0];
7436 for(j=0; j<limit; j++){
7437 b.apCell[b.nCell] = aData + (maskPage & get2byteAligned(piCell));
7438 piCell += 2;
7439 b.nCell++;
7441 for(k=0; k<pOld->nOverflow; k++){
7442 assert( k==0 || pOld->aiOvfl[k-1]+1==pOld->aiOvfl[k] );/* NOTE 1 */
7443 b.apCell[b.nCell] = pOld->apOvfl[k];
7444 b.nCell++;
7447 piEnd = aData + pOld->cellOffset + 2*pOld->nCell;
7448 while( piCell<piEnd ){
7449 assert( b.nCell<nMaxCells );
7450 b.apCell[b.nCell] = aData + (maskPage & get2byteAligned(piCell));
7451 piCell += 2;
7452 b.nCell++;
7455 cntOld[i] = b.nCell;
7456 if( i<nOld-1 && !leafData){
7457 u16 sz = (u16)szNew[i];
7458 u8 *pTemp;
7459 assert( b.nCell<nMaxCells );
7460 b.szCell[b.nCell] = sz;
7461 pTemp = &aSpace1[iSpace1];
7462 iSpace1 += sz;
7463 assert( sz<=pBt->maxLocal+23 );
7464 assert( iSpace1 <= (int)pBt->pageSize );
7465 memcpy(pTemp, apDiv[i], sz);
7466 b.apCell[b.nCell] = pTemp+leafCorrection;
7467 assert( leafCorrection==0 || leafCorrection==4 );
7468 b.szCell[b.nCell] = b.szCell[b.nCell] - leafCorrection;
7469 if( !pOld->leaf ){
7470 assert( leafCorrection==0 );
7471 assert( pOld->hdrOffset==0 );
7472 /* The right pointer of the child page pOld becomes the left
7473 ** pointer of the divider cell */
7474 memcpy(b.apCell[b.nCell], &pOld->aData[8], 4);
7475 }else{
7476 assert( leafCorrection==4 );
7477 while( b.szCell[b.nCell]<4 ){
7478 /* Do not allow any cells smaller than 4 bytes. If a smaller cell
7479 ** does exist, pad it with 0x00 bytes. */
7480 assert( b.szCell[b.nCell]==3 || CORRUPT_DB );
7481 assert( b.apCell[b.nCell]==&aSpace1[iSpace1-3] || CORRUPT_DB );
7482 aSpace1[iSpace1++] = 0x00;
7483 b.szCell[b.nCell]++;
7486 b.nCell++;
7491 ** Figure out the number of pages needed to hold all b.nCell cells.
7492 ** Store this number in "k". Also compute szNew[] which is the total
7493 ** size of all cells on the i-th page and cntNew[] which is the index
7494 ** in b.apCell[] of the cell that divides page i from page i+1.
7495 ** cntNew[k] should equal b.nCell.
7497 ** Values computed by this block:
7499 ** k: The total number of sibling pages
7500 ** szNew[i]: Spaced used on the i-th sibling page.
7501 ** cntNew[i]: Index in b.apCell[] and b.szCell[] for the first cell to
7502 ** the right of the i-th sibling page.
7503 ** usableSpace: Number of bytes of space available on each sibling.
7506 usableSpace = pBt->usableSize - 12 + leafCorrection;
7507 for(i=0; i<nOld; i++){
7508 MemPage *p = apOld[i];
7509 szNew[i] = usableSpace - p->nFree;
7510 for(j=0; j<p->nOverflow; j++){
7511 szNew[i] += 2 + p->xCellSize(p, p->apOvfl[j]);
7513 cntNew[i] = cntOld[i];
7515 k = nOld;
7516 for(i=0; i<k; i++){
7517 int sz;
7518 while( szNew[i]>usableSpace ){
7519 if( i+1>=k ){
7520 k = i+2;
7521 if( k>NB+2 ){ rc = SQLITE_CORRUPT_BKPT; goto balance_cleanup; }
7522 szNew[k-1] = 0;
7523 cntNew[k-1] = b.nCell;
7525 sz = 2 + cachedCellSize(&b, cntNew[i]-1);
7526 szNew[i] -= sz;
7527 if( !leafData ){
7528 if( cntNew[i]<b.nCell ){
7529 sz = 2 + cachedCellSize(&b, cntNew[i]);
7530 }else{
7531 sz = 0;
7534 szNew[i+1] += sz;
7535 cntNew[i]--;
7537 while( cntNew[i]<b.nCell ){
7538 sz = 2 + cachedCellSize(&b, cntNew[i]);
7539 if( szNew[i]+sz>usableSpace ) break;
7540 szNew[i] += sz;
7541 cntNew[i]++;
7542 if( !leafData ){
7543 if( cntNew[i]<b.nCell ){
7544 sz = 2 + cachedCellSize(&b, cntNew[i]);
7545 }else{
7546 sz = 0;
7549 szNew[i+1] -= sz;
7551 if( cntNew[i]>=b.nCell ){
7552 k = i+1;
7553 }else if( cntNew[i] <= (i>0 ? cntNew[i-1] : 0) ){
7554 rc = SQLITE_CORRUPT_BKPT;
7555 goto balance_cleanup;
7560 ** The packing computed by the previous block is biased toward the siblings
7561 ** on the left side (siblings with smaller keys). The left siblings are
7562 ** always nearly full, while the right-most sibling might be nearly empty.
7563 ** The next block of code attempts to adjust the packing of siblings to
7564 ** get a better balance.
7566 ** This adjustment is more than an optimization. The packing above might
7567 ** be so out of balance as to be illegal. For example, the right-most
7568 ** sibling might be completely empty. This adjustment is not optional.
7570 for(i=k-1; i>0; i--){
7571 int szRight = szNew[i]; /* Size of sibling on the right */
7572 int szLeft = szNew[i-1]; /* Size of sibling on the left */
7573 int r; /* Index of right-most cell in left sibling */
7574 int d; /* Index of first cell to the left of right sibling */
7576 r = cntNew[i-1] - 1;
7577 d = r + 1 - leafData;
7578 (void)cachedCellSize(&b, d);
7580 assert( d<nMaxCells );
7581 assert( r<nMaxCells );
7582 (void)cachedCellSize(&b, r);
7583 if( szRight!=0
7584 && (bBulk || szRight+b.szCell[d]+2 > szLeft-(b.szCell[r]+(i==k-1?0:2)))){
7585 break;
7587 szRight += b.szCell[d] + 2;
7588 szLeft -= b.szCell[r] + 2;
7589 cntNew[i-1] = r;
7590 r--;
7591 d--;
7592 }while( r>=0 );
7593 szNew[i] = szRight;
7594 szNew[i-1] = szLeft;
7595 if( cntNew[i-1] <= (i>1 ? cntNew[i-2] : 0) ){
7596 rc = SQLITE_CORRUPT_BKPT;
7597 goto balance_cleanup;
7601 /* Sanity check: For a non-corrupt database file one of the follwing
7602 ** must be true:
7603 ** (1) We found one or more cells (cntNew[0])>0), or
7604 ** (2) pPage is a virtual root page. A virtual root page is when
7605 ** the real root page is page 1 and we are the only child of
7606 ** that page.
7608 assert( cntNew[0]>0 || (pParent->pgno==1 && pParent->nCell==0) || CORRUPT_DB);
7609 TRACE(("BALANCE: old: %d(nc=%d) %d(nc=%d) %d(nc=%d)\n",
7610 apOld[0]->pgno, apOld[0]->nCell,
7611 nOld>=2 ? apOld[1]->pgno : 0, nOld>=2 ? apOld[1]->nCell : 0,
7612 nOld>=3 ? apOld[2]->pgno : 0, nOld>=3 ? apOld[2]->nCell : 0
7616 ** Allocate k new pages. Reuse old pages where possible.
7618 pageFlags = apOld[0]->aData[0];
7619 for(i=0; i<k; i++){
7620 MemPage *pNew;
7621 if( i<nOld ){
7622 pNew = apNew[i] = apOld[i];
7623 apOld[i] = 0;
7624 rc = sqlite3PagerWrite(pNew->pDbPage);
7625 nNew++;
7626 if( rc ) goto balance_cleanup;
7627 }else{
7628 assert( i>0 );
7629 rc = allocateBtreePage(pBt, &pNew, &pgno, (bBulk ? 1 : pgno), 0);
7630 if( rc ) goto balance_cleanup;
7631 zeroPage(pNew, pageFlags);
7632 apNew[i] = pNew;
7633 nNew++;
7634 cntOld[i] = b.nCell;
7636 /* Set the pointer-map entry for the new sibling page. */
7637 if( ISAUTOVACUUM ){
7638 ptrmapPut(pBt, pNew->pgno, PTRMAP_BTREE, pParent->pgno, &rc);
7639 if( rc!=SQLITE_OK ){
7640 goto balance_cleanup;
7647 ** Reassign page numbers so that the new pages are in ascending order.
7648 ** This helps to keep entries in the disk file in order so that a scan
7649 ** of the table is closer to a linear scan through the file. That in turn
7650 ** helps the operating system to deliver pages from the disk more rapidly.
7652 ** An O(n^2) insertion sort algorithm is used, but since n is never more
7653 ** than (NB+2) (a small constant), that should not be a problem.
7655 ** When NB==3, this one optimization makes the database about 25% faster
7656 ** for large insertions and deletions.
7658 for(i=0; i<nNew; i++){
7659 aPgOrder[i] = aPgno[i] = apNew[i]->pgno;
7660 aPgFlags[i] = apNew[i]->pDbPage->flags;
7661 for(j=0; j<i; j++){
7662 if( aPgno[j]==aPgno[i] ){
7663 /* This branch is taken if the set of sibling pages somehow contains
7664 ** duplicate entries. This can happen if the database is corrupt.
7665 ** It would be simpler to detect this as part of the loop below, but
7666 ** we do the detection here in order to avoid populating the pager
7667 ** cache with two separate objects associated with the same
7668 ** page number. */
7669 assert( CORRUPT_DB );
7670 rc = SQLITE_CORRUPT_BKPT;
7671 goto balance_cleanup;
7675 for(i=0; i<nNew; i++){
7676 int iBest = 0; /* aPgno[] index of page number to use */
7677 for(j=1; j<nNew; j++){
7678 if( aPgOrder[j]<aPgOrder[iBest] ) iBest = j;
7680 pgno = aPgOrder[iBest];
7681 aPgOrder[iBest] = 0xffffffff;
7682 if( iBest!=i ){
7683 if( iBest>i ){
7684 sqlite3PagerRekey(apNew[iBest]->pDbPage, pBt->nPage+iBest+1, 0);
7686 sqlite3PagerRekey(apNew[i]->pDbPage, pgno, aPgFlags[iBest]);
7687 apNew[i]->pgno = pgno;
7691 TRACE(("BALANCE: new: %d(%d nc=%d) %d(%d nc=%d) %d(%d nc=%d) "
7692 "%d(%d nc=%d) %d(%d nc=%d)\n",
7693 apNew[0]->pgno, szNew[0], cntNew[0],
7694 nNew>=2 ? apNew[1]->pgno : 0, nNew>=2 ? szNew[1] : 0,
7695 nNew>=2 ? cntNew[1] - cntNew[0] - !leafData : 0,
7696 nNew>=3 ? apNew[2]->pgno : 0, nNew>=3 ? szNew[2] : 0,
7697 nNew>=3 ? cntNew[2] - cntNew[1] - !leafData : 0,
7698 nNew>=4 ? apNew[3]->pgno : 0, nNew>=4 ? szNew[3] : 0,
7699 nNew>=4 ? cntNew[3] - cntNew[2] - !leafData : 0,
7700 nNew>=5 ? apNew[4]->pgno : 0, nNew>=5 ? szNew[4] : 0,
7701 nNew>=5 ? cntNew[4] - cntNew[3] - !leafData : 0
7704 assert( sqlite3PagerIswriteable(pParent->pDbPage) );
7705 put4byte(pRight, apNew[nNew-1]->pgno);
7707 /* If the sibling pages are not leaves, ensure that the right-child pointer
7708 ** of the right-most new sibling page is set to the value that was
7709 ** originally in the same field of the right-most old sibling page. */
7710 if( (pageFlags & PTF_LEAF)==0 && nOld!=nNew ){
7711 MemPage *pOld = (nNew>nOld ? apNew : apOld)[nOld-1];
7712 memcpy(&apNew[nNew-1]->aData[8], &pOld->aData[8], 4);
7715 /* Make any required updates to pointer map entries associated with
7716 ** cells stored on sibling pages following the balance operation. Pointer
7717 ** map entries associated with divider cells are set by the insertCell()
7718 ** routine. The associated pointer map entries are:
7720 ** a) if the cell contains a reference to an overflow chain, the
7721 ** entry associated with the first page in the overflow chain, and
7723 ** b) if the sibling pages are not leaves, the child page associated
7724 ** with the cell.
7726 ** If the sibling pages are not leaves, then the pointer map entry
7727 ** associated with the right-child of each sibling may also need to be
7728 ** updated. This happens below, after the sibling pages have been
7729 ** populated, not here.
7731 if( ISAUTOVACUUM ){
7732 MemPage *pNew = apNew[0];
7733 u8 *aOld = pNew->aData;
7734 int cntOldNext = pNew->nCell + pNew->nOverflow;
7735 int usableSize = pBt->usableSize;
7736 int iNew = 0;
7737 int iOld = 0;
7739 for(i=0; i<b.nCell; i++){
7740 u8 *pCell = b.apCell[i];
7741 if( i==cntOldNext ){
7742 MemPage *pOld = (++iOld)<nNew ? apNew[iOld] : apOld[iOld];
7743 cntOldNext += pOld->nCell + pOld->nOverflow + !leafData;
7744 aOld = pOld->aData;
7746 if( i==cntNew[iNew] ){
7747 pNew = apNew[++iNew];
7748 if( !leafData ) continue;
7751 /* Cell pCell is destined for new sibling page pNew. Originally, it
7752 ** was either part of sibling page iOld (possibly an overflow cell),
7753 ** or else the divider cell to the left of sibling page iOld. So,
7754 ** if sibling page iOld had the same page number as pNew, and if
7755 ** pCell really was a part of sibling page iOld (not a divider or
7756 ** overflow cell), we can skip updating the pointer map entries. */
7757 if( iOld>=nNew
7758 || pNew->pgno!=aPgno[iOld]
7759 || !SQLITE_WITHIN(pCell,aOld,&aOld[usableSize])
7761 if( !leafCorrection ){
7762 ptrmapPut(pBt, get4byte(pCell), PTRMAP_BTREE, pNew->pgno, &rc);
7764 if( cachedCellSize(&b,i)>pNew->minLocal ){
7765 ptrmapPutOvflPtr(pNew, pCell, &rc);
7767 if( rc ) goto balance_cleanup;
7772 /* Insert new divider cells into pParent. */
7773 for(i=0; i<nNew-1; i++){
7774 u8 *pCell;
7775 u8 *pTemp;
7776 int sz;
7777 MemPage *pNew = apNew[i];
7778 j = cntNew[i];
7780 assert( j<nMaxCells );
7781 assert( b.apCell[j]!=0 );
7782 pCell = b.apCell[j];
7783 sz = b.szCell[j] + leafCorrection;
7784 pTemp = &aOvflSpace[iOvflSpace];
7785 if( !pNew->leaf ){
7786 memcpy(&pNew->aData[8], pCell, 4);
7787 }else if( leafData ){
7788 /* If the tree is a leaf-data tree, and the siblings are leaves,
7789 ** then there is no divider cell in b.apCell[]. Instead, the divider
7790 ** cell consists of the integer key for the right-most cell of
7791 ** the sibling-page assembled above only.
7793 CellInfo info;
7794 j--;
7795 pNew->xParseCell(pNew, b.apCell[j], &info);
7796 pCell = pTemp;
7797 sz = 4 + putVarint(&pCell[4], info.nKey);
7798 pTemp = 0;
7799 }else{
7800 pCell -= 4;
7801 /* Obscure case for non-leaf-data trees: If the cell at pCell was
7802 ** previously stored on a leaf node, and its reported size was 4
7803 ** bytes, then it may actually be smaller than this
7804 ** (see btreeParseCellPtr(), 4 bytes is the minimum size of
7805 ** any cell). But it is important to pass the correct size to
7806 ** insertCell(), so reparse the cell now.
7808 ** This can only happen for b-trees used to evaluate "IN (SELECT ...)"
7809 ** and WITHOUT ROWID tables with exactly one column which is the
7810 ** primary key.
7812 if( b.szCell[j]==4 ){
7813 assert(leafCorrection==4);
7814 sz = pParent->xCellSize(pParent, pCell);
7817 iOvflSpace += sz;
7818 assert( sz<=pBt->maxLocal+23 );
7819 assert( iOvflSpace <= (int)pBt->pageSize );
7820 insertCell(pParent, nxDiv+i, pCell, sz, pTemp, pNew->pgno, &rc);
7821 if( rc!=SQLITE_OK ) goto balance_cleanup;
7822 assert( sqlite3PagerIswriteable(pParent->pDbPage) );
7825 /* Now update the actual sibling pages. The order in which they are updated
7826 ** is important, as this code needs to avoid disrupting any page from which
7827 ** cells may still to be read. In practice, this means:
7829 ** (1) If cells are moving left (from apNew[iPg] to apNew[iPg-1])
7830 ** then it is not safe to update page apNew[iPg] until after
7831 ** the left-hand sibling apNew[iPg-1] has been updated.
7833 ** (2) If cells are moving right (from apNew[iPg] to apNew[iPg+1])
7834 ** then it is not safe to update page apNew[iPg] until after
7835 ** the right-hand sibling apNew[iPg+1] has been updated.
7837 ** If neither of the above apply, the page is safe to update.
7839 ** The iPg value in the following loop starts at nNew-1 goes down
7840 ** to 0, then back up to nNew-1 again, thus making two passes over
7841 ** the pages. On the initial downward pass, only condition (1) above
7842 ** needs to be tested because (2) will always be true from the previous
7843 ** step. On the upward pass, both conditions are always true, so the
7844 ** upwards pass simply processes pages that were missed on the downward
7845 ** pass.
7847 for(i=1-nNew; i<nNew; i++){
7848 int iPg = i<0 ? -i : i;
7849 assert( iPg>=0 && iPg<nNew );
7850 if( abDone[iPg] ) continue; /* Skip pages already processed */
7851 if( i>=0 /* On the upwards pass, or... */
7852 || cntOld[iPg-1]>=cntNew[iPg-1] /* Condition (1) is true */
7854 int iNew;
7855 int iOld;
7856 int nNewCell;
7858 /* Verify condition (1): If cells are moving left, update iPg
7859 ** only after iPg-1 has already been updated. */
7860 assert( iPg==0 || cntOld[iPg-1]>=cntNew[iPg-1] || abDone[iPg-1] );
7862 /* Verify condition (2): If cells are moving right, update iPg
7863 ** only after iPg+1 has already been updated. */
7864 assert( cntNew[iPg]>=cntOld[iPg] || abDone[iPg+1] );
7866 if( iPg==0 ){
7867 iNew = iOld = 0;
7868 nNewCell = cntNew[0];
7869 }else{
7870 iOld = iPg<nOld ? (cntOld[iPg-1] + !leafData) : b.nCell;
7871 iNew = cntNew[iPg-1] + !leafData;
7872 nNewCell = cntNew[iPg] - iNew;
7875 rc = editPage(apNew[iPg], iOld, iNew, nNewCell, &b);
7876 if( rc ) goto balance_cleanup;
7877 abDone[iPg]++;
7878 apNew[iPg]->nFree = usableSpace-szNew[iPg];
7879 assert( apNew[iPg]->nOverflow==0 );
7880 assert( apNew[iPg]->nCell==nNewCell );
7884 /* All pages have been processed exactly once */
7885 assert( memcmp(abDone, "\01\01\01\01\01", nNew)==0 );
7887 assert( nOld>0 );
7888 assert( nNew>0 );
7890 if( isRoot && pParent->nCell==0 && pParent->hdrOffset<=apNew[0]->nFree ){
7891 /* The root page of the b-tree now contains no cells. The only sibling
7892 ** page is the right-child of the parent. Copy the contents of the
7893 ** child page into the parent, decreasing the overall height of the
7894 ** b-tree structure by one. This is described as the "balance-shallower"
7895 ** sub-algorithm in some documentation.
7897 ** If this is an auto-vacuum database, the call to copyNodeContent()
7898 ** sets all pointer-map entries corresponding to database image pages
7899 ** for which the pointer is stored within the content being copied.
7901 ** It is critical that the child page be defragmented before being
7902 ** copied into the parent, because if the parent is page 1 then it will
7903 ** by smaller than the child due to the database header, and so all the
7904 ** free space needs to be up front.
7906 assert( nNew==1 || CORRUPT_DB );
7907 rc = defragmentPage(apNew[0], -1);
7908 testcase( rc!=SQLITE_OK );
7909 assert( apNew[0]->nFree ==
7910 (get2byte(&apNew[0]->aData[5])-apNew[0]->cellOffset-apNew[0]->nCell*2)
7911 || rc!=SQLITE_OK
7913 copyNodeContent(apNew[0], pParent, &rc);
7914 freePage(apNew[0], &rc);
7915 }else if( ISAUTOVACUUM && !leafCorrection ){
7916 /* Fix the pointer map entries associated with the right-child of each
7917 ** sibling page. All other pointer map entries have already been taken
7918 ** care of. */
7919 for(i=0; i<nNew; i++){
7920 u32 key = get4byte(&apNew[i]->aData[8]);
7921 ptrmapPut(pBt, key, PTRMAP_BTREE, apNew[i]->pgno, &rc);
7925 assert( pParent->isInit );
7926 TRACE(("BALANCE: finished: old=%d new=%d cells=%d\n",
7927 nOld, nNew, b.nCell));
7929 /* Free any old pages that were not reused as new pages.
7931 for(i=nNew; i<nOld; i++){
7932 freePage(apOld[i], &rc);
7935 #if 0
7936 if( ISAUTOVACUUM && rc==SQLITE_OK && apNew[0]->isInit ){
7937 /* The ptrmapCheckPages() contains assert() statements that verify that
7938 ** all pointer map pages are set correctly. This is helpful while
7939 ** debugging. This is usually disabled because a corrupt database may
7940 ** cause an assert() statement to fail. */
7941 ptrmapCheckPages(apNew, nNew);
7942 ptrmapCheckPages(&pParent, 1);
7944 #endif
7947 ** Cleanup before returning.
7949 balance_cleanup:
7950 sqlite3StackFree(0, b.apCell);
7951 for(i=0; i<nOld; i++){
7952 releasePage(apOld[i]);
7954 for(i=0; i<nNew; i++){
7955 releasePage(apNew[i]);
7958 return rc;
7963 ** This function is called when the root page of a b-tree structure is
7964 ** overfull (has one or more overflow pages).
7966 ** A new child page is allocated and the contents of the current root
7967 ** page, including overflow cells, are copied into the child. The root
7968 ** page is then overwritten to make it an empty page with the right-child
7969 ** pointer pointing to the new page.
7971 ** Before returning, all pointer-map entries corresponding to pages
7972 ** that the new child-page now contains pointers to are updated. The
7973 ** entry corresponding to the new right-child pointer of the root
7974 ** page is also updated.
7976 ** If successful, *ppChild is set to contain a reference to the child
7977 ** page and SQLITE_OK is returned. In this case the caller is required
7978 ** to call releasePage() on *ppChild exactly once. If an error occurs,
7979 ** an error code is returned and *ppChild is set to 0.
7981 static int balance_deeper(MemPage *pRoot, MemPage **ppChild){
7982 int rc; /* Return value from subprocedures */
7983 MemPage *pChild = 0; /* Pointer to a new child page */
7984 Pgno pgnoChild = 0; /* Page number of the new child page */
7985 BtShared *pBt = pRoot->pBt; /* The BTree */
7987 assert( pRoot->nOverflow>0 );
7988 assert( sqlite3_mutex_held(pBt->mutex) );
7990 /* Make pRoot, the root page of the b-tree, writable. Allocate a new
7991 ** page that will become the new right-child of pPage. Copy the contents
7992 ** of the node stored on pRoot into the new child page.
7994 rc = sqlite3PagerWrite(pRoot->pDbPage);
7995 if( rc==SQLITE_OK ){
7996 rc = allocateBtreePage(pBt,&pChild,&pgnoChild,pRoot->pgno,0);
7997 copyNodeContent(pRoot, pChild, &rc);
7998 if( ISAUTOVACUUM ){
7999 ptrmapPut(pBt, pgnoChild, PTRMAP_BTREE, pRoot->pgno, &rc);
8002 if( rc ){
8003 *ppChild = 0;
8004 releasePage(pChild);
8005 return rc;
8007 assert( sqlite3PagerIswriteable(pChild->pDbPage) );
8008 assert( sqlite3PagerIswriteable(pRoot->pDbPage) );
8009 assert( pChild->nCell==pRoot->nCell );
8011 TRACE(("BALANCE: copy root %d into %d\n", pRoot->pgno, pChild->pgno));
8013 /* Copy the overflow cells from pRoot to pChild */
8014 memcpy(pChild->aiOvfl, pRoot->aiOvfl,
8015 pRoot->nOverflow*sizeof(pRoot->aiOvfl[0]));
8016 memcpy(pChild->apOvfl, pRoot->apOvfl,
8017 pRoot->nOverflow*sizeof(pRoot->apOvfl[0]));
8018 pChild->nOverflow = pRoot->nOverflow;
8020 /* Zero the contents of pRoot. Then install pChild as the right-child. */
8021 zeroPage(pRoot, pChild->aData[0] & ~PTF_LEAF);
8022 put4byte(&pRoot->aData[pRoot->hdrOffset+8], pgnoChild);
8024 *ppChild = pChild;
8025 return SQLITE_OK;
8029 ** The page that pCur currently points to has just been modified in
8030 ** some way. This function figures out if this modification means the
8031 ** tree needs to be balanced, and if so calls the appropriate balancing
8032 ** routine. Balancing routines are:
8034 ** balance_quick()
8035 ** balance_deeper()
8036 ** balance_nonroot()
8038 static int balance(BtCursor *pCur){
8039 int rc = SQLITE_OK;
8040 const int nMin = pCur->pBt->usableSize * 2 / 3;
8041 u8 aBalanceQuickSpace[13];
8042 u8 *pFree = 0;
8044 VVA_ONLY( int balance_quick_called = 0 );
8045 VVA_ONLY( int balance_deeper_called = 0 );
8047 do {
8048 int iPage = pCur->iPage;
8049 MemPage *pPage = pCur->pPage;
8051 if( iPage==0 ){
8052 if( pPage->nOverflow ){
8053 /* The root page of the b-tree is overfull. In this case call the
8054 ** balance_deeper() function to create a new child for the root-page
8055 ** and copy the current contents of the root-page to it. The
8056 ** next iteration of the do-loop will balance the child page.
8058 assert( balance_deeper_called==0 );
8059 VVA_ONLY( balance_deeper_called++ );
8060 rc = balance_deeper(pPage, &pCur->apPage[1]);
8061 if( rc==SQLITE_OK ){
8062 pCur->iPage = 1;
8063 pCur->ix = 0;
8064 pCur->aiIdx[0] = 0;
8065 pCur->apPage[0] = pPage;
8066 pCur->pPage = pCur->apPage[1];
8067 assert( pCur->pPage->nOverflow );
8069 }else{
8070 break;
8072 }else if( pPage->nOverflow==0 && pPage->nFree<=nMin ){
8073 break;
8074 }else{
8075 MemPage * const pParent = pCur->apPage[iPage-1];
8076 int const iIdx = pCur->aiIdx[iPage-1];
8078 rc = sqlite3PagerWrite(pParent->pDbPage);
8079 if( rc==SQLITE_OK ){
8080 #ifndef SQLITE_OMIT_QUICKBALANCE
8081 if( pPage->intKeyLeaf
8082 && pPage->nOverflow==1
8083 && pPage->aiOvfl[0]==pPage->nCell
8084 && pParent->pgno!=1
8085 && pParent->nCell==iIdx
8087 /* Call balance_quick() to create a new sibling of pPage on which
8088 ** to store the overflow cell. balance_quick() inserts a new cell
8089 ** into pParent, which may cause pParent overflow. If this
8090 ** happens, the next iteration of the do-loop will balance pParent
8091 ** use either balance_nonroot() or balance_deeper(). Until this
8092 ** happens, the overflow cell is stored in the aBalanceQuickSpace[]
8093 ** buffer.
8095 ** The purpose of the following assert() is to check that only a
8096 ** single call to balance_quick() is made for each call to this
8097 ** function. If this were not verified, a subtle bug involving reuse
8098 ** of the aBalanceQuickSpace[] might sneak in.
8100 assert( balance_quick_called==0 );
8101 VVA_ONLY( balance_quick_called++ );
8102 rc = balance_quick(pParent, pPage, aBalanceQuickSpace);
8103 }else
8104 #endif
8106 /* In this case, call balance_nonroot() to redistribute cells
8107 ** between pPage and up to 2 of its sibling pages. This involves
8108 ** modifying the contents of pParent, which may cause pParent to
8109 ** become overfull or underfull. The next iteration of the do-loop
8110 ** will balance the parent page to correct this.
8112 ** If the parent page becomes overfull, the overflow cell or cells
8113 ** are stored in the pSpace buffer allocated immediately below.
8114 ** A subsequent iteration of the do-loop will deal with this by
8115 ** calling balance_nonroot() (balance_deeper() may be called first,
8116 ** but it doesn't deal with overflow cells - just moves them to a
8117 ** different page). Once this subsequent call to balance_nonroot()
8118 ** has completed, it is safe to release the pSpace buffer used by
8119 ** the previous call, as the overflow cell data will have been
8120 ** copied either into the body of a database page or into the new
8121 ** pSpace buffer passed to the latter call to balance_nonroot().
8123 u8 *pSpace = sqlite3PageMalloc(pCur->pBt->pageSize);
8124 rc = balance_nonroot(pParent, iIdx, pSpace, iPage==1,
8125 pCur->hints&BTREE_BULKLOAD);
8126 if( pFree ){
8127 /* If pFree is not NULL, it points to the pSpace buffer used
8128 ** by a previous call to balance_nonroot(). Its contents are
8129 ** now stored either on real database pages or within the
8130 ** new pSpace buffer, so it may be safely freed here. */
8131 sqlite3PageFree(pFree);
8134 /* The pSpace buffer will be freed after the next call to
8135 ** balance_nonroot(), or just before this function returns, whichever
8136 ** comes first. */
8137 pFree = pSpace;
8141 pPage->nOverflow = 0;
8143 /* The next iteration of the do-loop balances the parent page. */
8144 releasePage(pPage);
8145 pCur->iPage--;
8146 assert( pCur->iPage>=0 );
8147 pCur->pPage = pCur->apPage[pCur->iPage];
8149 }while( rc==SQLITE_OK );
8151 if( pFree ){
8152 sqlite3PageFree(pFree);
8154 return rc;
8157 /* Overwrite content from pX into pDest. Only do the write if the
8158 ** content is different from what is already there.
8160 static int btreeOverwriteContent(
8161 MemPage *pPage, /* MemPage on which writing will occur */
8162 u8 *pDest, /* Pointer to the place to start writing */
8163 const BtreePayload *pX, /* Source of data to write */
8164 int iOffset, /* Offset of first byte to write */
8165 int iAmt /* Number of bytes to be written */
8167 int nData = pX->nData - iOffset;
8168 if( nData<=0 ){
8169 /* Overwritting with zeros */
8170 int i;
8171 for(i=0; i<iAmt && pDest[i]==0; i++){}
8172 if( i<iAmt ){
8173 int rc = sqlite3PagerWrite(pPage->pDbPage);
8174 if( rc ) return rc;
8175 memset(pDest + i, 0, iAmt - i);
8177 }else{
8178 if( nData<iAmt ){
8179 /* Mixed read data and zeros at the end. Make a recursive call
8180 ** to write the zeros then fall through to write the real data */
8181 int rc = btreeOverwriteContent(pPage, pDest+nData, pX, iOffset+nData,
8182 iAmt-nData);
8183 if( rc ) return rc;
8184 iAmt = nData;
8186 if( memcmp(pDest, ((u8*)pX->pData) + iOffset, iAmt)!=0 ){
8187 int rc = sqlite3PagerWrite(pPage->pDbPage);
8188 if( rc ) return rc;
8189 memcpy(pDest, ((u8*)pX->pData) + iOffset, iAmt);
8192 return SQLITE_OK;
8196 ** Overwrite the cell that cursor pCur is pointing to with fresh content
8197 ** contained in pX.
8199 static int btreeOverwriteCell(BtCursor *pCur, const BtreePayload *pX){
8200 int iOffset; /* Next byte of pX->pData to write */
8201 int nTotal = pX->nData + pX->nZero; /* Total bytes of to write */
8202 int rc; /* Return code */
8203 MemPage *pPage = pCur->pPage; /* Page being written */
8204 BtShared *pBt; /* Btree */
8205 Pgno ovflPgno; /* Next overflow page to write */
8206 u32 ovflPageSize; /* Size to write on overflow page */
8208 if( pCur->info.pPayload + pCur->info.nLocal > pPage->aDataEnd ){
8209 return SQLITE_CORRUPT_BKPT;
8211 /* Overwrite the local portion first */
8212 rc = btreeOverwriteContent(pPage, pCur->info.pPayload, pX,
8213 0, pCur->info.nLocal);
8214 if( rc ) return rc;
8215 if( pCur->info.nLocal==nTotal ) return SQLITE_OK;
8217 /* Now overwrite the overflow pages */
8218 iOffset = pCur->info.nLocal;
8219 assert( nTotal>=0 );
8220 assert( iOffset>=0 );
8221 ovflPgno = get4byte(pCur->info.pPayload + iOffset);
8222 pBt = pPage->pBt;
8223 ovflPageSize = pBt->usableSize - 4;
8225 rc = btreeGetPage(pBt, ovflPgno, &pPage, 0);
8226 if( rc ) return rc;
8227 if( sqlite3PagerPageRefcount(pPage->pDbPage)!=1 ){
8228 rc = SQLITE_CORRUPT_BKPT;
8229 }else{
8230 if( iOffset+ovflPageSize<(u32)nTotal ){
8231 ovflPgno = get4byte(pPage->aData);
8232 }else{
8233 ovflPageSize = nTotal - iOffset;
8235 rc = btreeOverwriteContent(pPage, pPage->aData+4, pX,
8236 iOffset, ovflPageSize);
8238 sqlite3PagerUnref(pPage->pDbPage);
8239 if( rc ) return rc;
8240 iOffset += ovflPageSize;
8241 }while( iOffset<nTotal );
8242 return SQLITE_OK;
8247 ** Insert a new record into the BTree. The content of the new record
8248 ** is described by the pX object. The pCur cursor is used only to
8249 ** define what table the record should be inserted into, and is left
8250 ** pointing at a random location.
8252 ** For a table btree (used for rowid tables), only the pX.nKey value of
8253 ** the key is used. The pX.pKey value must be NULL. The pX.nKey is the
8254 ** rowid or INTEGER PRIMARY KEY of the row. The pX.nData,pData,nZero fields
8255 ** hold the content of the row.
8257 ** For an index btree (used for indexes and WITHOUT ROWID tables), the
8258 ** key is an arbitrary byte sequence stored in pX.pKey,nKey. The
8259 ** pX.pData,nData,nZero fields must be zero.
8261 ** If the seekResult parameter is non-zero, then a successful call to
8262 ** MovetoUnpacked() to seek cursor pCur to (pKey,nKey) has already
8263 ** been performed. In other words, if seekResult!=0 then the cursor
8264 ** is currently pointing to a cell that will be adjacent to the cell
8265 ** to be inserted. If seekResult<0 then pCur points to a cell that is
8266 ** smaller then (pKey,nKey). If seekResult>0 then pCur points to a cell
8267 ** that is larger than (pKey,nKey).
8269 ** If seekResult==0, that means pCur is pointing at some unknown location.
8270 ** In that case, this routine must seek the cursor to the correct insertion
8271 ** point for (pKey,nKey) before doing the insertion. For index btrees,
8272 ** if pX->nMem is non-zero, then pX->aMem contains pointers to the unpacked
8273 ** key values and pX->aMem can be used instead of pX->pKey to avoid having
8274 ** to decode the key.
8276 int sqlite3BtreeInsert(
8277 BtCursor *pCur, /* Insert data into the table of this cursor */
8278 const BtreePayload *pX, /* Content of the row to be inserted */
8279 int flags, /* True if this is likely an append */
8280 int seekResult /* Result of prior MovetoUnpacked() call */
8282 int rc;
8283 int loc = seekResult; /* -1: before desired location +1: after */
8284 int szNew = 0;
8285 int idx;
8286 MemPage *pPage;
8287 Btree *p = pCur->pBtree;
8288 BtShared *pBt = p->pBt;
8289 unsigned char *oldCell;
8290 unsigned char *newCell = 0;
8292 assert( (flags & (BTREE_SAVEPOSITION|BTREE_APPEND))==flags );
8294 if( pCur->eState==CURSOR_FAULT ){
8295 assert( pCur->skipNext!=SQLITE_OK );
8296 return pCur->skipNext;
8299 assert( cursorOwnsBtShared(pCur) );
8300 assert( (pCur->curFlags & BTCF_WriteFlag)!=0
8301 && pBt->inTransaction==TRANS_WRITE
8302 && (pBt->btsFlags & BTS_READ_ONLY)==0 );
8303 assert( hasSharedCacheTableLock(p, pCur->pgnoRoot, pCur->pKeyInfo!=0, 2) );
8305 /* Assert that the caller has been consistent. If this cursor was opened
8306 ** expecting an index b-tree, then the caller should be inserting blob
8307 ** keys with no associated data. If the cursor was opened expecting an
8308 ** intkey table, the caller should be inserting integer keys with a
8309 ** blob of associated data. */
8310 assert( (pX->pKey==0)==(pCur->pKeyInfo==0) );
8312 /* Save the positions of any other cursors open on this table.
8314 ** In some cases, the call to btreeMoveto() below is a no-op. For
8315 ** example, when inserting data into a table with auto-generated integer
8316 ** keys, the VDBE layer invokes sqlite3BtreeLast() to figure out the
8317 ** integer key to use. It then calls this function to actually insert the
8318 ** data into the intkey B-Tree. In this case btreeMoveto() recognizes
8319 ** that the cursor is already where it needs to be and returns without
8320 ** doing any work. To avoid thwarting these optimizations, it is important
8321 ** not to clear the cursor here.
8323 if( pCur->curFlags & BTCF_Multiple ){
8324 rc = saveAllCursors(pBt, pCur->pgnoRoot, pCur);
8325 if( rc ) return rc;
8328 if( pCur->pKeyInfo==0 ){
8329 assert( pX->pKey==0 );
8330 /* If this is an insert into a table b-tree, invalidate any incrblob
8331 ** cursors open on the row being replaced */
8332 invalidateIncrblobCursors(p, pCur->pgnoRoot, pX->nKey, 0);
8334 /* If BTREE_SAVEPOSITION is set, the cursor must already be pointing
8335 ** to a row with the same key as the new entry being inserted.
8337 #ifdef SQLITE_DEBUG
8338 if( flags & BTREE_SAVEPOSITION ){
8339 assert( pCur->curFlags & BTCF_ValidNKey );
8340 assert( pX->nKey==pCur->info.nKey );
8341 assert( pCur->info.nSize!=0 );
8342 assert( loc==0 );
8344 #endif
8346 /* On the other hand, BTREE_SAVEPOSITION==0 does not imply
8347 ** that the cursor is not pointing to a row to be overwritten.
8348 ** So do a complete check.
8350 if( (pCur->curFlags&BTCF_ValidNKey)!=0 && pX->nKey==pCur->info.nKey ){
8351 /* The cursor is pointing to the entry that is to be
8352 ** overwritten */
8353 assert( pX->nData>=0 && pX->nZero>=0 );
8354 if( pCur->info.nSize!=0
8355 && pCur->info.nPayload==(u32)pX->nData+pX->nZero
8357 /* New entry is the same size as the old. Do an overwrite */
8358 return btreeOverwriteCell(pCur, pX);
8360 assert( loc==0 );
8361 }else if( loc==0 ){
8362 /* The cursor is *not* pointing to the cell to be overwritten, nor
8363 ** to an adjacent cell. Move the cursor so that it is pointing either
8364 ** to the cell to be overwritten or an adjacent cell.
8366 rc = sqlite3BtreeMovetoUnpacked(pCur, 0, pX->nKey, flags!=0, &loc);
8367 if( rc ) return rc;
8369 }else{
8370 /* This is an index or a WITHOUT ROWID table */
8372 /* If BTREE_SAVEPOSITION is set, the cursor must already be pointing
8373 ** to a row with the same key as the new entry being inserted.
8375 assert( (flags & BTREE_SAVEPOSITION)==0 || loc==0 );
8377 /* If the cursor is not already pointing either to the cell to be
8378 ** overwritten, or if a new cell is being inserted, if the cursor is
8379 ** not pointing to an immediately adjacent cell, then move the cursor
8380 ** so that it does.
8382 if( loc==0 && (flags & BTREE_SAVEPOSITION)==0 ){
8383 if( pX->nMem ){
8384 UnpackedRecord r;
8385 r.pKeyInfo = pCur->pKeyInfo;
8386 r.aMem = pX->aMem;
8387 r.nField = pX->nMem;
8388 r.default_rc = 0;
8389 r.errCode = 0;
8390 r.r1 = 0;
8391 r.r2 = 0;
8392 r.eqSeen = 0;
8393 rc = sqlite3BtreeMovetoUnpacked(pCur, &r, 0, flags!=0, &loc);
8394 }else{
8395 rc = btreeMoveto(pCur, pX->pKey, pX->nKey, flags!=0, &loc);
8397 if( rc ) return rc;
8400 /* If the cursor is currently pointing to an entry to be overwritten
8401 ** and the new content is the same as as the old, then use the
8402 ** overwrite optimization.
8404 if( loc==0 ){
8405 getCellInfo(pCur);
8406 if( pCur->info.nKey==pX->nKey ){
8407 BtreePayload x2;
8408 x2.pData = pX->pKey;
8409 x2.nData = pX->nKey;
8410 x2.nZero = 0;
8411 return btreeOverwriteCell(pCur, &x2);
8416 assert( pCur->eState==CURSOR_VALID || (pCur->eState==CURSOR_INVALID && loc) );
8418 pPage = pCur->pPage;
8419 assert( pPage->intKey || pX->nKey>=0 );
8420 assert( pPage->leaf || !pPage->intKey );
8422 TRACE(("INSERT: table=%d nkey=%lld ndata=%d page=%d %s\n",
8423 pCur->pgnoRoot, pX->nKey, pX->nData, pPage->pgno,
8424 loc==0 ? "overwrite" : "new entry"));
8425 assert( pPage->isInit );
8426 newCell = pBt->pTmpSpace;
8427 assert( newCell!=0 );
8428 rc = fillInCell(pPage, newCell, pX, &szNew);
8429 if( rc ) goto end_insert;
8430 assert( szNew==pPage->xCellSize(pPage, newCell) );
8431 assert( szNew <= MX_CELL_SIZE(pBt) );
8432 idx = pCur->ix;
8433 if( loc==0 ){
8434 CellInfo info;
8435 assert( idx<pPage->nCell );
8436 rc = sqlite3PagerWrite(pPage->pDbPage);
8437 if( rc ){
8438 goto end_insert;
8440 oldCell = findCell(pPage, idx);
8441 if( !pPage->leaf ){
8442 memcpy(newCell, oldCell, 4);
8444 rc = clearCell(pPage, oldCell, &info);
8445 if( info.nSize==szNew && info.nLocal==info.nPayload
8446 && (!ISAUTOVACUUM || szNew<pPage->minLocal)
8448 /* Overwrite the old cell with the new if they are the same size.
8449 ** We could also try to do this if the old cell is smaller, then add
8450 ** the leftover space to the free list. But experiments show that
8451 ** doing that is no faster then skipping this optimization and just
8452 ** calling dropCell() and insertCell().
8454 ** This optimization cannot be used on an autovacuum database if the
8455 ** new entry uses overflow pages, as the insertCell() call below is
8456 ** necessary to add the PTRMAP_OVERFLOW1 pointer-map entry. */
8457 assert( rc==SQLITE_OK ); /* clearCell never fails when nLocal==nPayload */
8458 if( oldCell+szNew > pPage->aDataEnd ) return SQLITE_CORRUPT_BKPT;
8459 memcpy(oldCell, newCell, szNew);
8460 return SQLITE_OK;
8462 dropCell(pPage, idx, info.nSize, &rc);
8463 if( rc ) goto end_insert;
8464 }else if( loc<0 && pPage->nCell>0 ){
8465 assert( pPage->leaf );
8466 idx = ++pCur->ix;
8467 pCur->curFlags &= ~BTCF_ValidNKey;
8468 }else{
8469 assert( pPage->leaf );
8471 insertCell(pPage, idx, newCell, szNew, 0, 0, &rc);
8472 assert( pPage->nOverflow==0 || rc==SQLITE_OK );
8473 assert( rc!=SQLITE_OK || pPage->nCell>0 || pPage->nOverflow>0 );
8475 /* If no error has occurred and pPage has an overflow cell, call balance()
8476 ** to redistribute the cells within the tree. Since balance() may move
8477 ** the cursor, zero the BtCursor.info.nSize and BTCF_ValidNKey
8478 ** variables.
8480 ** Previous versions of SQLite called moveToRoot() to move the cursor
8481 ** back to the root page as balance() used to invalidate the contents
8482 ** of BtCursor.apPage[] and BtCursor.aiIdx[]. Instead of doing that,
8483 ** set the cursor state to "invalid". This makes common insert operations
8484 ** slightly faster.
8486 ** There is a subtle but important optimization here too. When inserting
8487 ** multiple records into an intkey b-tree using a single cursor (as can
8488 ** happen while processing an "INSERT INTO ... SELECT" statement), it
8489 ** is advantageous to leave the cursor pointing to the last entry in
8490 ** the b-tree if possible. If the cursor is left pointing to the last
8491 ** entry in the table, and the next row inserted has an integer key
8492 ** larger than the largest existing key, it is possible to insert the
8493 ** row without seeking the cursor. This can be a big performance boost.
8495 pCur->info.nSize = 0;
8496 if( pPage->nOverflow ){
8497 assert( rc==SQLITE_OK );
8498 pCur->curFlags &= ~(BTCF_ValidNKey);
8499 rc = balance(pCur);
8501 /* Must make sure nOverflow is reset to zero even if the balance()
8502 ** fails. Internal data structure corruption will result otherwise.
8503 ** Also, set the cursor state to invalid. This stops saveCursorPosition()
8504 ** from trying to save the current position of the cursor. */
8505 pCur->pPage->nOverflow = 0;
8506 pCur->eState = CURSOR_INVALID;
8507 if( (flags & BTREE_SAVEPOSITION) && rc==SQLITE_OK ){
8508 btreeReleaseAllCursorPages(pCur);
8509 if( pCur->pKeyInfo ){
8510 assert( pCur->pKey==0 );
8511 pCur->pKey = sqlite3Malloc( pX->nKey );
8512 if( pCur->pKey==0 ){
8513 rc = SQLITE_NOMEM;
8514 }else{
8515 memcpy(pCur->pKey, pX->pKey, pX->nKey);
8518 pCur->eState = CURSOR_REQUIRESEEK;
8519 pCur->nKey = pX->nKey;
8522 assert( pCur->iPage<0 || pCur->pPage->nOverflow==0 );
8524 end_insert:
8525 return rc;
8529 ** Delete the entry that the cursor is pointing to.
8531 ** If the BTREE_SAVEPOSITION bit of the flags parameter is zero, then
8532 ** the cursor is left pointing at an arbitrary location after the delete.
8533 ** But if that bit is set, then the cursor is left in a state such that
8534 ** the next call to BtreeNext() or BtreePrev() moves it to the same row
8535 ** as it would have been on if the call to BtreeDelete() had been omitted.
8537 ** The BTREE_AUXDELETE bit of flags indicates that is one of several deletes
8538 ** associated with a single table entry and its indexes. Only one of those
8539 ** deletes is considered the "primary" delete. The primary delete occurs
8540 ** on a cursor that is not a BTREE_FORDELETE cursor. All but one delete
8541 ** operation on non-FORDELETE cursors is tagged with the AUXDELETE flag.
8542 ** The BTREE_AUXDELETE bit is a hint that is not used by this implementation,
8543 ** but which might be used by alternative storage engines.
8545 int sqlite3BtreeDelete(BtCursor *pCur, u8 flags){
8546 Btree *p = pCur->pBtree;
8547 BtShared *pBt = p->pBt;
8548 int rc; /* Return code */
8549 MemPage *pPage; /* Page to delete cell from */
8550 unsigned char *pCell; /* Pointer to cell to delete */
8551 int iCellIdx; /* Index of cell to delete */
8552 int iCellDepth; /* Depth of node containing pCell */
8553 CellInfo info; /* Size of the cell being deleted */
8554 int bSkipnext = 0; /* Leaf cursor in SKIPNEXT state */
8555 u8 bPreserve = flags & BTREE_SAVEPOSITION; /* Keep cursor valid */
8557 assert( cursorOwnsBtShared(pCur) );
8558 assert( pBt->inTransaction==TRANS_WRITE );
8559 assert( (pBt->btsFlags & BTS_READ_ONLY)==0 );
8560 assert( pCur->curFlags & BTCF_WriteFlag );
8561 assert( hasSharedCacheTableLock(p, pCur->pgnoRoot, pCur->pKeyInfo!=0, 2) );
8562 assert( !hasReadConflicts(p, pCur->pgnoRoot) );
8563 assert( pCur->ix<pCur->pPage->nCell );
8564 assert( pCur->eState==CURSOR_VALID );
8565 assert( (flags & ~(BTREE_SAVEPOSITION | BTREE_AUXDELETE))==0 );
8567 iCellDepth = pCur->iPage;
8568 iCellIdx = pCur->ix;
8569 pPage = pCur->pPage;
8570 pCell = findCell(pPage, iCellIdx);
8572 /* If the bPreserve flag is set to true, then the cursor position must
8573 ** be preserved following this delete operation. If the current delete
8574 ** will cause a b-tree rebalance, then this is done by saving the cursor
8575 ** key and leaving the cursor in CURSOR_REQUIRESEEK state before
8576 ** returning.
8578 ** Or, if the current delete will not cause a rebalance, then the cursor
8579 ** will be left in CURSOR_SKIPNEXT state pointing to the entry immediately
8580 ** before or after the deleted entry. In this case set bSkipnext to true. */
8581 if( bPreserve ){
8582 if( !pPage->leaf
8583 || (pPage->nFree+cellSizePtr(pPage,pCell)+2)>(int)(pBt->usableSize*2/3)
8585 /* A b-tree rebalance will be required after deleting this entry.
8586 ** Save the cursor key. */
8587 rc = saveCursorKey(pCur);
8588 if( rc ) return rc;
8589 }else{
8590 bSkipnext = 1;
8594 /* If the page containing the entry to delete is not a leaf page, move
8595 ** the cursor to the largest entry in the tree that is smaller than
8596 ** the entry being deleted. This cell will replace the cell being deleted
8597 ** from the internal node. The 'previous' entry is used for this instead
8598 ** of the 'next' entry, as the previous entry is always a part of the
8599 ** sub-tree headed by the child page of the cell being deleted. This makes
8600 ** balancing the tree following the delete operation easier. */
8601 if( !pPage->leaf ){
8602 rc = sqlite3BtreePrevious(pCur, 0);
8603 assert( rc!=SQLITE_DONE );
8604 if( rc ) return rc;
8607 /* Save the positions of any other cursors open on this table before
8608 ** making any modifications. */
8609 if( pCur->curFlags & BTCF_Multiple ){
8610 rc = saveAllCursors(pBt, pCur->pgnoRoot, pCur);
8611 if( rc ) return rc;
8614 /* If this is a delete operation to remove a row from a table b-tree,
8615 ** invalidate any incrblob cursors open on the row being deleted. */
8616 if( pCur->pKeyInfo==0 ){
8617 invalidateIncrblobCursors(p, pCur->pgnoRoot, pCur->info.nKey, 0);
8620 /* Make the page containing the entry to be deleted writable. Then free any
8621 ** overflow pages associated with the entry and finally remove the cell
8622 ** itself from within the page. */
8623 rc = sqlite3PagerWrite(pPage->pDbPage);
8624 if( rc ) return rc;
8625 rc = clearCell(pPage, pCell, &info);
8626 dropCell(pPage, iCellIdx, info.nSize, &rc);
8627 if( rc ) return rc;
8629 /* If the cell deleted was not located on a leaf page, then the cursor
8630 ** is currently pointing to the largest entry in the sub-tree headed
8631 ** by the child-page of the cell that was just deleted from an internal
8632 ** node. The cell from the leaf node needs to be moved to the internal
8633 ** node to replace the deleted cell. */
8634 if( !pPage->leaf ){
8635 MemPage *pLeaf = pCur->pPage;
8636 int nCell;
8637 Pgno n;
8638 unsigned char *pTmp;
8640 if( iCellDepth<pCur->iPage-1 ){
8641 n = pCur->apPage[iCellDepth+1]->pgno;
8642 }else{
8643 n = pCur->pPage->pgno;
8645 pCell = findCell(pLeaf, pLeaf->nCell-1);
8646 if( pCell<&pLeaf->aData[4] ) return SQLITE_CORRUPT_BKPT;
8647 nCell = pLeaf->xCellSize(pLeaf, pCell);
8648 assert( MX_CELL_SIZE(pBt) >= nCell );
8649 pTmp = pBt->pTmpSpace;
8650 assert( pTmp!=0 );
8651 rc = sqlite3PagerWrite(pLeaf->pDbPage);
8652 if( rc==SQLITE_OK ){
8653 insertCell(pPage, iCellIdx, pCell-4, nCell+4, pTmp, n, &rc);
8655 dropCell(pLeaf, pLeaf->nCell-1, nCell, &rc);
8656 if( rc ) return rc;
8659 /* Balance the tree. If the entry deleted was located on a leaf page,
8660 ** then the cursor still points to that page. In this case the first
8661 ** call to balance() repairs the tree, and the if(...) condition is
8662 ** never true.
8664 ** Otherwise, if the entry deleted was on an internal node page, then
8665 ** pCur is pointing to the leaf page from which a cell was removed to
8666 ** replace the cell deleted from the internal node. This is slightly
8667 ** tricky as the leaf node may be underfull, and the internal node may
8668 ** be either under or overfull. In this case run the balancing algorithm
8669 ** on the leaf node first. If the balance proceeds far enough up the
8670 ** tree that we can be sure that any problem in the internal node has
8671 ** been corrected, so be it. Otherwise, after balancing the leaf node,
8672 ** walk the cursor up the tree to the internal node and balance it as
8673 ** well. */
8674 rc = balance(pCur);
8675 if( rc==SQLITE_OK && pCur->iPage>iCellDepth ){
8676 releasePageNotNull(pCur->pPage);
8677 pCur->iPage--;
8678 while( pCur->iPage>iCellDepth ){
8679 releasePage(pCur->apPage[pCur->iPage--]);
8681 pCur->pPage = pCur->apPage[pCur->iPage];
8682 rc = balance(pCur);
8685 if( rc==SQLITE_OK ){
8686 if( bSkipnext ){
8687 assert( bPreserve && (pCur->iPage==iCellDepth || CORRUPT_DB) );
8688 assert( pPage==pCur->pPage || CORRUPT_DB );
8689 assert( (pPage->nCell>0 || CORRUPT_DB) && iCellIdx<=pPage->nCell );
8690 pCur->eState = CURSOR_SKIPNEXT;
8691 if( iCellIdx>=pPage->nCell ){
8692 pCur->skipNext = -1;
8693 pCur->ix = pPage->nCell-1;
8694 }else{
8695 pCur->skipNext = 1;
8697 }else{
8698 rc = moveToRoot(pCur);
8699 if( bPreserve ){
8700 btreeReleaseAllCursorPages(pCur);
8701 pCur->eState = CURSOR_REQUIRESEEK;
8703 if( rc==SQLITE_EMPTY ) rc = SQLITE_OK;
8706 return rc;
8710 ** Create a new BTree table. Write into *piTable the page
8711 ** number for the root page of the new table.
8713 ** The type of type is determined by the flags parameter. Only the
8714 ** following values of flags are currently in use. Other values for
8715 ** flags might not work:
8717 ** BTREE_INTKEY|BTREE_LEAFDATA Used for SQL tables with rowid keys
8718 ** BTREE_ZERODATA Used for SQL indices
8720 static int btreeCreateTable(Btree *p, int *piTable, int createTabFlags){
8721 BtShared *pBt = p->pBt;
8722 MemPage *pRoot;
8723 Pgno pgnoRoot;
8724 int rc;
8725 int ptfFlags; /* Page-type flage for the root page of new table */
8727 assert( sqlite3BtreeHoldsMutex(p) );
8728 assert( pBt->inTransaction==TRANS_WRITE );
8729 assert( (pBt->btsFlags & BTS_READ_ONLY)==0 );
8731 #ifdef SQLITE_OMIT_AUTOVACUUM
8732 rc = allocateBtreePage(pBt, &pRoot, &pgnoRoot, 1, 0);
8733 if( rc ){
8734 return rc;
8736 #else
8737 if( pBt->autoVacuum ){
8738 Pgno pgnoMove; /* Move a page here to make room for the root-page */
8739 MemPage *pPageMove; /* The page to move to. */
8741 /* Creating a new table may probably require moving an existing database
8742 ** to make room for the new tables root page. In case this page turns
8743 ** out to be an overflow page, delete all overflow page-map caches
8744 ** held by open cursors.
8746 invalidateAllOverflowCache(pBt);
8748 /* Read the value of meta[3] from the database to determine where the
8749 ** root page of the new table should go. meta[3] is the largest root-page
8750 ** created so far, so the new root-page is (meta[3]+1).
8752 sqlite3BtreeGetMeta(p, BTREE_LARGEST_ROOT_PAGE, &pgnoRoot);
8753 pgnoRoot++;
8755 /* The new root-page may not be allocated on a pointer-map page, or the
8756 ** PENDING_BYTE page.
8758 while( pgnoRoot==PTRMAP_PAGENO(pBt, pgnoRoot) ||
8759 pgnoRoot==PENDING_BYTE_PAGE(pBt) ){
8760 pgnoRoot++;
8762 assert( pgnoRoot>=3 || CORRUPT_DB );
8763 testcase( pgnoRoot<3 );
8765 /* Allocate a page. The page that currently resides at pgnoRoot will
8766 ** be moved to the allocated page (unless the allocated page happens
8767 ** to reside at pgnoRoot).
8769 rc = allocateBtreePage(pBt, &pPageMove, &pgnoMove, pgnoRoot, BTALLOC_EXACT);
8770 if( rc!=SQLITE_OK ){
8771 return rc;
8774 if( pgnoMove!=pgnoRoot ){
8775 /* pgnoRoot is the page that will be used for the root-page of
8776 ** the new table (assuming an error did not occur). But we were
8777 ** allocated pgnoMove. If required (i.e. if it was not allocated
8778 ** by extending the file), the current page at position pgnoMove
8779 ** is already journaled.
8781 u8 eType = 0;
8782 Pgno iPtrPage = 0;
8784 /* Save the positions of any open cursors. This is required in
8785 ** case they are holding a reference to an xFetch reference
8786 ** corresponding to page pgnoRoot. */
8787 rc = saveAllCursors(pBt, 0, 0);
8788 releasePage(pPageMove);
8789 if( rc!=SQLITE_OK ){
8790 return rc;
8793 /* Move the page currently at pgnoRoot to pgnoMove. */
8794 rc = btreeGetPage(pBt, pgnoRoot, &pRoot, 0);
8795 if( rc!=SQLITE_OK ){
8796 return rc;
8798 rc = ptrmapGet(pBt, pgnoRoot, &eType, &iPtrPage);
8799 if( eType==PTRMAP_ROOTPAGE || eType==PTRMAP_FREEPAGE ){
8800 rc = SQLITE_CORRUPT_BKPT;
8802 if( rc!=SQLITE_OK ){
8803 releasePage(pRoot);
8804 return rc;
8806 assert( eType!=PTRMAP_ROOTPAGE );
8807 assert( eType!=PTRMAP_FREEPAGE );
8808 rc = relocatePage(pBt, pRoot, eType, iPtrPage, pgnoMove, 0);
8809 releasePage(pRoot);
8811 /* Obtain the page at pgnoRoot */
8812 if( rc!=SQLITE_OK ){
8813 return rc;
8815 rc = btreeGetPage(pBt, pgnoRoot, &pRoot, 0);
8816 if( rc!=SQLITE_OK ){
8817 return rc;
8819 rc = sqlite3PagerWrite(pRoot->pDbPage);
8820 if( rc!=SQLITE_OK ){
8821 releasePage(pRoot);
8822 return rc;
8824 }else{
8825 pRoot = pPageMove;
8828 /* Update the pointer-map and meta-data with the new root-page number. */
8829 ptrmapPut(pBt, pgnoRoot, PTRMAP_ROOTPAGE, 0, &rc);
8830 if( rc ){
8831 releasePage(pRoot);
8832 return rc;
8835 /* When the new root page was allocated, page 1 was made writable in
8836 ** order either to increase the database filesize, or to decrement the
8837 ** freelist count. Hence, the sqlite3BtreeUpdateMeta() call cannot fail.
8839 assert( sqlite3PagerIswriteable(pBt->pPage1->pDbPage) );
8840 rc = sqlite3BtreeUpdateMeta(p, 4, pgnoRoot);
8841 if( NEVER(rc) ){
8842 releasePage(pRoot);
8843 return rc;
8846 }else{
8847 rc = allocateBtreePage(pBt, &pRoot, &pgnoRoot, 1, 0);
8848 if( rc ) return rc;
8850 #endif
8851 assert( sqlite3PagerIswriteable(pRoot->pDbPage) );
8852 if( createTabFlags & BTREE_INTKEY ){
8853 ptfFlags = PTF_INTKEY | PTF_LEAFDATA | PTF_LEAF;
8854 }else{
8855 ptfFlags = PTF_ZERODATA | PTF_LEAF;
8857 zeroPage(pRoot, ptfFlags);
8858 sqlite3PagerUnref(pRoot->pDbPage);
8859 assert( (pBt->openFlags & BTREE_SINGLE)==0 || pgnoRoot==2 );
8860 *piTable = (int)pgnoRoot;
8861 return SQLITE_OK;
8863 int sqlite3BtreeCreateTable(Btree *p, int *piTable, int flags){
8864 int rc;
8865 sqlite3BtreeEnter(p);
8866 rc = btreeCreateTable(p, piTable, flags);
8867 sqlite3BtreeLeave(p);
8868 return rc;
8872 ** Erase the given database page and all its children. Return
8873 ** the page to the freelist.
8875 static int clearDatabasePage(
8876 BtShared *pBt, /* The BTree that contains the table */
8877 Pgno pgno, /* Page number to clear */
8878 int freePageFlag, /* Deallocate page if true */
8879 int *pnChange /* Add number of Cells freed to this counter */
8881 MemPage *pPage;
8882 int rc;
8883 unsigned char *pCell;
8884 int i;
8885 int hdr;
8886 CellInfo info;
8888 assert( sqlite3_mutex_held(pBt->mutex) );
8889 if( pgno>btreePagecount(pBt) ){
8890 return SQLITE_CORRUPT_BKPT;
8892 rc = getAndInitPage(pBt, pgno, &pPage, 0, 0);
8893 if( rc ) return rc;
8894 if( pPage->bBusy ){
8895 rc = SQLITE_CORRUPT_BKPT;
8896 goto cleardatabasepage_out;
8898 pPage->bBusy = 1;
8899 hdr = pPage->hdrOffset;
8900 for(i=0; i<pPage->nCell; i++){
8901 pCell = findCell(pPage, i);
8902 if( !pPage->leaf ){
8903 rc = clearDatabasePage(pBt, get4byte(pCell), 1, pnChange);
8904 if( rc ) goto cleardatabasepage_out;
8906 rc = clearCell(pPage, pCell, &info);
8907 if( rc ) goto cleardatabasepage_out;
8909 if( !pPage->leaf ){
8910 rc = clearDatabasePage(pBt, get4byte(&pPage->aData[hdr+8]), 1, pnChange);
8911 if( rc ) goto cleardatabasepage_out;
8912 }else if( pnChange ){
8913 assert( pPage->intKey || CORRUPT_DB );
8914 testcase( !pPage->intKey );
8915 *pnChange += pPage->nCell;
8917 if( freePageFlag ){
8918 freePage(pPage, &rc);
8919 }else if( (rc = sqlite3PagerWrite(pPage->pDbPage))==0 ){
8920 zeroPage(pPage, pPage->aData[hdr] | PTF_LEAF);
8923 cleardatabasepage_out:
8924 pPage->bBusy = 0;
8925 releasePage(pPage);
8926 return rc;
8930 ** Delete all information from a single table in the database. iTable is
8931 ** the page number of the root of the table. After this routine returns,
8932 ** the root page is empty, but still exists.
8934 ** This routine will fail with SQLITE_LOCKED if there are any open
8935 ** read cursors on the table. Open write cursors are moved to the
8936 ** root of the table.
8938 ** If pnChange is not NULL, then table iTable must be an intkey table. The
8939 ** integer value pointed to by pnChange is incremented by the number of
8940 ** entries in the table.
8942 int sqlite3BtreeClearTable(Btree *p, int iTable, int *pnChange){
8943 int rc;
8944 BtShared *pBt = p->pBt;
8945 sqlite3BtreeEnter(p);
8946 assert( p->inTrans==TRANS_WRITE );
8948 rc = saveAllCursors(pBt, (Pgno)iTable, 0);
8950 if( SQLITE_OK==rc ){
8951 /* Invalidate all incrblob cursors open on table iTable (assuming iTable
8952 ** is the root of a table b-tree - if it is not, the following call is
8953 ** a no-op). */
8954 invalidateIncrblobCursors(p, (Pgno)iTable, 0, 1);
8955 rc = clearDatabasePage(pBt, (Pgno)iTable, 0, pnChange);
8957 sqlite3BtreeLeave(p);
8958 return rc;
8962 ** Delete all information from the single table that pCur is open on.
8964 ** This routine only work for pCur on an ephemeral table.
8966 int sqlite3BtreeClearTableOfCursor(BtCursor *pCur){
8967 return sqlite3BtreeClearTable(pCur->pBtree, pCur->pgnoRoot, 0);
8971 ** Erase all information in a table and add the root of the table to
8972 ** the freelist. Except, the root of the principle table (the one on
8973 ** page 1) is never added to the freelist.
8975 ** This routine will fail with SQLITE_LOCKED if there are any open
8976 ** cursors on the table.
8978 ** If AUTOVACUUM is enabled and the page at iTable is not the last
8979 ** root page in the database file, then the last root page
8980 ** in the database file is moved into the slot formerly occupied by
8981 ** iTable and that last slot formerly occupied by the last root page
8982 ** is added to the freelist instead of iTable. In this say, all
8983 ** root pages are kept at the beginning of the database file, which
8984 ** is necessary for AUTOVACUUM to work right. *piMoved is set to the
8985 ** page number that used to be the last root page in the file before
8986 ** the move. If no page gets moved, *piMoved is set to 0.
8987 ** The last root page is recorded in meta[3] and the value of
8988 ** meta[3] is updated by this procedure.
8990 static int btreeDropTable(Btree *p, Pgno iTable, int *piMoved){
8991 int rc;
8992 MemPage *pPage = 0;
8993 BtShared *pBt = p->pBt;
8995 assert( sqlite3BtreeHoldsMutex(p) );
8996 assert( p->inTrans==TRANS_WRITE );
8997 assert( iTable>=2 );
8999 rc = btreeGetPage(pBt, (Pgno)iTable, &pPage, 0);
9000 if( rc ) return rc;
9001 rc = sqlite3BtreeClearTable(p, iTable, 0);
9002 if( rc ){
9003 releasePage(pPage);
9004 return rc;
9007 *piMoved = 0;
9009 #ifdef SQLITE_OMIT_AUTOVACUUM
9010 freePage(pPage, &rc);
9011 releasePage(pPage);
9012 #else
9013 if( pBt->autoVacuum ){
9014 Pgno maxRootPgno;
9015 sqlite3BtreeGetMeta(p, BTREE_LARGEST_ROOT_PAGE, &maxRootPgno);
9017 if( iTable==maxRootPgno ){
9018 /* If the table being dropped is the table with the largest root-page
9019 ** number in the database, put the root page on the free list.
9021 freePage(pPage, &rc);
9022 releasePage(pPage);
9023 if( rc!=SQLITE_OK ){
9024 return rc;
9026 }else{
9027 /* The table being dropped does not have the largest root-page
9028 ** number in the database. So move the page that does into the
9029 ** gap left by the deleted root-page.
9031 MemPage *pMove;
9032 releasePage(pPage);
9033 rc = btreeGetPage(pBt, maxRootPgno, &pMove, 0);
9034 if( rc!=SQLITE_OK ){
9035 return rc;
9037 rc = relocatePage(pBt, pMove, PTRMAP_ROOTPAGE, 0, iTable, 0);
9038 releasePage(pMove);
9039 if( rc!=SQLITE_OK ){
9040 return rc;
9042 pMove = 0;
9043 rc = btreeGetPage(pBt, maxRootPgno, &pMove, 0);
9044 freePage(pMove, &rc);
9045 releasePage(pMove);
9046 if( rc!=SQLITE_OK ){
9047 return rc;
9049 *piMoved = maxRootPgno;
9052 /* Set the new 'max-root-page' value in the database header. This
9053 ** is the old value less one, less one more if that happens to
9054 ** be a root-page number, less one again if that is the
9055 ** PENDING_BYTE_PAGE.
9057 maxRootPgno--;
9058 while( maxRootPgno==PENDING_BYTE_PAGE(pBt)
9059 || PTRMAP_ISPAGE(pBt, maxRootPgno) ){
9060 maxRootPgno--;
9062 assert( maxRootPgno!=PENDING_BYTE_PAGE(pBt) );
9064 rc = sqlite3BtreeUpdateMeta(p, 4, maxRootPgno);
9065 }else{
9066 freePage(pPage, &rc);
9067 releasePage(pPage);
9069 #endif
9070 return rc;
9072 int sqlite3BtreeDropTable(Btree *p, int iTable, int *piMoved){
9073 int rc;
9074 sqlite3BtreeEnter(p);
9075 rc = btreeDropTable(p, iTable, piMoved);
9076 sqlite3BtreeLeave(p);
9077 return rc;
9082 ** This function may only be called if the b-tree connection already
9083 ** has a read or write transaction open on the database.
9085 ** Read the meta-information out of a database file. Meta[0]
9086 ** is the number of free pages currently in the database. Meta[1]
9087 ** through meta[15] are available for use by higher layers. Meta[0]
9088 ** is read-only, the others are read/write.
9090 ** The schema layer numbers meta values differently. At the schema
9091 ** layer (and the SetCookie and ReadCookie opcodes) the number of
9092 ** free pages is not visible. So Cookie[0] is the same as Meta[1].
9094 ** This routine treats Meta[BTREE_DATA_VERSION] as a special case. Instead
9095 ** of reading the value out of the header, it instead loads the "DataVersion"
9096 ** from the pager. The BTREE_DATA_VERSION value is not actually stored in the
9097 ** database file. It is a number computed by the pager. But its access
9098 ** pattern is the same as header meta values, and so it is convenient to
9099 ** read it from this routine.
9101 void sqlite3BtreeGetMeta(Btree *p, int idx, u32 *pMeta){
9102 BtShared *pBt = p->pBt;
9104 sqlite3BtreeEnter(p);
9105 assert( p->inTrans>TRANS_NONE );
9106 assert( SQLITE_OK==querySharedCacheTableLock(p, MASTER_ROOT, READ_LOCK) );
9107 assert( pBt->pPage1 );
9108 assert( idx>=0 && idx<=15 );
9110 if( idx==BTREE_DATA_VERSION ){
9111 *pMeta = sqlite3PagerDataVersion(pBt->pPager) + p->iDataVersion;
9112 }else{
9113 *pMeta = get4byte(&pBt->pPage1->aData[36 + idx*4]);
9116 /* If auto-vacuum is disabled in this build and this is an auto-vacuum
9117 ** database, mark the database as read-only. */
9118 #ifdef SQLITE_OMIT_AUTOVACUUM
9119 if( idx==BTREE_LARGEST_ROOT_PAGE && *pMeta>0 ){
9120 pBt->btsFlags |= BTS_READ_ONLY;
9122 #endif
9124 sqlite3BtreeLeave(p);
9128 ** Write meta-information back into the database. Meta[0] is
9129 ** read-only and may not be written.
9131 int sqlite3BtreeUpdateMeta(Btree *p, int idx, u32 iMeta){
9132 BtShared *pBt = p->pBt;
9133 unsigned char *pP1;
9134 int rc;
9135 assert( idx>=1 && idx<=15 );
9136 sqlite3BtreeEnter(p);
9137 assert( p->inTrans==TRANS_WRITE );
9138 assert( pBt->pPage1!=0 );
9139 pP1 = pBt->pPage1->aData;
9140 rc = sqlite3PagerWrite(pBt->pPage1->pDbPage);
9141 if( rc==SQLITE_OK ){
9142 put4byte(&pP1[36 + idx*4], iMeta);
9143 #ifndef SQLITE_OMIT_AUTOVACUUM
9144 if( idx==BTREE_INCR_VACUUM ){
9145 assert( pBt->autoVacuum || iMeta==0 );
9146 assert( iMeta==0 || iMeta==1 );
9147 pBt->incrVacuum = (u8)iMeta;
9149 #endif
9151 sqlite3BtreeLeave(p);
9152 return rc;
9155 #ifndef SQLITE_OMIT_BTREECOUNT
9157 ** The first argument, pCur, is a cursor opened on some b-tree. Count the
9158 ** number of entries in the b-tree and write the result to *pnEntry.
9160 ** SQLITE_OK is returned if the operation is successfully executed.
9161 ** Otherwise, if an error is encountered (i.e. an IO error or database
9162 ** corruption) an SQLite error code is returned.
9164 int sqlite3BtreeCount(BtCursor *pCur, i64 *pnEntry){
9165 i64 nEntry = 0; /* Value to return in *pnEntry */
9166 int rc; /* Return code */
9168 rc = moveToRoot(pCur);
9169 if( rc==SQLITE_EMPTY ){
9170 *pnEntry = 0;
9171 return SQLITE_OK;
9174 /* Unless an error occurs, the following loop runs one iteration for each
9175 ** page in the B-Tree structure (not including overflow pages).
9177 while( rc==SQLITE_OK ){
9178 int iIdx; /* Index of child node in parent */
9179 MemPage *pPage; /* Current page of the b-tree */
9181 /* If this is a leaf page or the tree is not an int-key tree, then
9182 ** this page contains countable entries. Increment the entry counter
9183 ** accordingly.
9185 pPage = pCur->pPage;
9186 if( pPage->leaf || !pPage->intKey ){
9187 nEntry += pPage->nCell;
9190 /* pPage is a leaf node. This loop navigates the cursor so that it
9191 ** points to the first interior cell that it points to the parent of
9192 ** the next page in the tree that has not yet been visited. The
9193 ** pCur->aiIdx[pCur->iPage] value is set to the index of the parent cell
9194 ** of the page, or to the number of cells in the page if the next page
9195 ** to visit is the right-child of its parent.
9197 ** If all pages in the tree have been visited, return SQLITE_OK to the
9198 ** caller.
9200 if( pPage->leaf ){
9201 do {
9202 if( pCur->iPage==0 ){
9203 /* All pages of the b-tree have been visited. Return successfully. */
9204 *pnEntry = nEntry;
9205 return moveToRoot(pCur);
9207 moveToParent(pCur);
9208 }while ( pCur->ix>=pCur->pPage->nCell );
9210 pCur->ix++;
9211 pPage = pCur->pPage;
9214 /* Descend to the child node of the cell that the cursor currently
9215 ** points at. This is the right-child if (iIdx==pPage->nCell).
9217 iIdx = pCur->ix;
9218 if( iIdx==pPage->nCell ){
9219 rc = moveToChild(pCur, get4byte(&pPage->aData[pPage->hdrOffset+8]));
9220 }else{
9221 rc = moveToChild(pCur, get4byte(findCell(pPage, iIdx)));
9225 /* An error has occurred. Return an error code. */
9226 return rc;
9228 #endif
9231 ** Return the pager associated with a BTree. This routine is used for
9232 ** testing and debugging only.
9234 Pager *sqlite3BtreePager(Btree *p){
9235 return p->pBt->pPager;
9238 #ifndef SQLITE_OMIT_INTEGRITY_CHECK
9240 ** Append a message to the error message string.
9242 static void checkAppendMsg(
9243 IntegrityCk *pCheck,
9244 const char *zFormat,
9247 va_list ap;
9248 if( !pCheck->mxErr ) return;
9249 pCheck->mxErr--;
9250 pCheck->nErr++;
9251 va_start(ap, zFormat);
9252 if( pCheck->errMsg.nChar ){
9253 sqlite3_str_append(&pCheck->errMsg, "\n", 1);
9255 if( pCheck->zPfx ){
9256 sqlite3_str_appendf(&pCheck->errMsg, pCheck->zPfx, pCheck->v1, pCheck->v2);
9258 sqlite3_str_vappendf(&pCheck->errMsg, zFormat, ap);
9259 va_end(ap);
9260 if( pCheck->errMsg.accError==SQLITE_NOMEM ){
9261 pCheck->mallocFailed = 1;
9264 #endif /* SQLITE_OMIT_INTEGRITY_CHECK */
9266 #ifndef SQLITE_OMIT_INTEGRITY_CHECK
9269 ** Return non-zero if the bit in the IntegrityCk.aPgRef[] array that
9270 ** corresponds to page iPg is already set.
9272 static int getPageReferenced(IntegrityCk *pCheck, Pgno iPg){
9273 assert( iPg<=pCheck->nPage && sizeof(pCheck->aPgRef[0])==1 );
9274 return (pCheck->aPgRef[iPg/8] & (1 << (iPg & 0x07)));
9278 ** Set the bit in the IntegrityCk.aPgRef[] array that corresponds to page iPg.
9280 static void setPageReferenced(IntegrityCk *pCheck, Pgno iPg){
9281 assert( iPg<=pCheck->nPage && sizeof(pCheck->aPgRef[0])==1 );
9282 pCheck->aPgRef[iPg/8] |= (1 << (iPg & 0x07));
9287 ** Add 1 to the reference count for page iPage. If this is the second
9288 ** reference to the page, add an error message to pCheck->zErrMsg.
9289 ** Return 1 if there are 2 or more references to the page and 0 if
9290 ** if this is the first reference to the page.
9292 ** Also check that the page number is in bounds.
9294 static int checkRef(IntegrityCk *pCheck, Pgno iPage){
9295 if( iPage==0 ) return 1;
9296 if( iPage>pCheck->nPage ){
9297 checkAppendMsg(pCheck, "invalid page number %d", iPage);
9298 return 1;
9300 if( getPageReferenced(pCheck, iPage) ){
9301 checkAppendMsg(pCheck, "2nd reference to page %d", iPage);
9302 return 1;
9304 setPageReferenced(pCheck, iPage);
9305 return 0;
9308 #ifndef SQLITE_OMIT_AUTOVACUUM
9310 ** Check that the entry in the pointer-map for page iChild maps to
9311 ** page iParent, pointer type ptrType. If not, append an error message
9312 ** to pCheck.
9314 static void checkPtrmap(
9315 IntegrityCk *pCheck, /* Integrity check context */
9316 Pgno iChild, /* Child page number */
9317 u8 eType, /* Expected pointer map type */
9318 Pgno iParent /* Expected pointer map parent page number */
9320 int rc;
9321 u8 ePtrmapType;
9322 Pgno iPtrmapParent;
9324 rc = ptrmapGet(pCheck->pBt, iChild, &ePtrmapType, &iPtrmapParent);
9325 if( rc!=SQLITE_OK ){
9326 if( rc==SQLITE_NOMEM || rc==SQLITE_IOERR_NOMEM ) pCheck->mallocFailed = 1;
9327 checkAppendMsg(pCheck, "Failed to read ptrmap key=%d", iChild);
9328 return;
9331 if( ePtrmapType!=eType || iPtrmapParent!=iParent ){
9332 checkAppendMsg(pCheck,
9333 "Bad ptr map entry key=%d expected=(%d,%d) got=(%d,%d)",
9334 iChild, eType, iParent, ePtrmapType, iPtrmapParent);
9337 #endif
9340 ** Check the integrity of the freelist or of an overflow page list.
9341 ** Verify that the number of pages on the list is N.
9343 static void checkList(
9344 IntegrityCk *pCheck, /* Integrity checking context */
9345 int isFreeList, /* True for a freelist. False for overflow page list */
9346 int iPage, /* Page number for first page in the list */
9347 int N /* Expected number of pages in the list */
9349 int i;
9350 int expected = N;
9351 int iFirst = iPage;
9352 while( N-- > 0 && pCheck->mxErr ){
9353 DbPage *pOvflPage;
9354 unsigned char *pOvflData;
9355 if( iPage<1 ){
9356 checkAppendMsg(pCheck,
9357 "%d of %d pages missing from overflow list starting at %d",
9358 N+1, expected, iFirst);
9359 break;
9361 if( checkRef(pCheck, iPage) ) break;
9362 if( sqlite3PagerGet(pCheck->pPager, (Pgno)iPage, &pOvflPage, 0) ){
9363 checkAppendMsg(pCheck, "failed to get page %d", iPage);
9364 break;
9366 pOvflData = (unsigned char *)sqlite3PagerGetData(pOvflPage);
9367 if( isFreeList ){
9368 int n = get4byte(&pOvflData[4]);
9369 #ifndef SQLITE_OMIT_AUTOVACUUM
9370 if( pCheck->pBt->autoVacuum ){
9371 checkPtrmap(pCheck, iPage, PTRMAP_FREEPAGE, 0);
9373 #endif
9374 if( n>(int)pCheck->pBt->usableSize/4-2 ){
9375 checkAppendMsg(pCheck,
9376 "freelist leaf count too big on page %d", iPage);
9377 N--;
9378 }else{
9379 for(i=0; i<n; i++){
9380 Pgno iFreePage = get4byte(&pOvflData[8+i*4]);
9381 #ifndef SQLITE_OMIT_AUTOVACUUM
9382 if( pCheck->pBt->autoVacuum ){
9383 checkPtrmap(pCheck, iFreePage, PTRMAP_FREEPAGE, 0);
9385 #endif
9386 checkRef(pCheck, iFreePage);
9388 N -= n;
9391 #ifndef SQLITE_OMIT_AUTOVACUUM
9392 else{
9393 /* If this database supports auto-vacuum and iPage is not the last
9394 ** page in this overflow list, check that the pointer-map entry for
9395 ** the following page matches iPage.
9397 if( pCheck->pBt->autoVacuum && N>0 ){
9398 i = get4byte(pOvflData);
9399 checkPtrmap(pCheck, i, PTRMAP_OVERFLOW2, iPage);
9402 #endif
9403 iPage = get4byte(pOvflData);
9404 sqlite3PagerUnref(pOvflPage);
9406 if( isFreeList && N<(iPage!=0) ){
9407 checkAppendMsg(pCheck, "free-page count in header is too small");
9411 #endif /* SQLITE_OMIT_INTEGRITY_CHECK */
9414 ** An implementation of a min-heap.
9416 ** aHeap[0] is the number of elements on the heap. aHeap[1] is the
9417 ** root element. The daughter nodes of aHeap[N] are aHeap[N*2]
9418 ** and aHeap[N*2+1].
9420 ** The heap property is this: Every node is less than or equal to both
9421 ** of its daughter nodes. A consequence of the heap property is that the
9422 ** root node aHeap[1] is always the minimum value currently in the heap.
9424 ** The btreeHeapInsert() routine inserts an unsigned 32-bit number onto
9425 ** the heap, preserving the heap property. The btreeHeapPull() routine
9426 ** removes the root element from the heap (the minimum value in the heap)
9427 ** and then moves other nodes around as necessary to preserve the heap
9428 ** property.
9430 ** This heap is used for cell overlap and coverage testing. Each u32
9431 ** entry represents the span of a cell or freeblock on a btree page.
9432 ** The upper 16 bits are the index of the first byte of a range and the
9433 ** lower 16 bits are the index of the last byte of that range.
9435 static void btreeHeapInsert(u32 *aHeap, u32 x){
9436 u32 j, i = ++aHeap[0];
9437 aHeap[i] = x;
9438 while( (j = i/2)>0 && aHeap[j]>aHeap[i] ){
9439 x = aHeap[j];
9440 aHeap[j] = aHeap[i];
9441 aHeap[i] = x;
9442 i = j;
9445 static int btreeHeapPull(u32 *aHeap, u32 *pOut){
9446 u32 j, i, x;
9447 if( (x = aHeap[0])==0 ) return 0;
9448 *pOut = aHeap[1];
9449 aHeap[1] = aHeap[x];
9450 aHeap[x] = 0xffffffff;
9451 aHeap[0]--;
9452 i = 1;
9453 while( (j = i*2)<=aHeap[0] ){
9454 if( aHeap[j]>aHeap[j+1] ) j++;
9455 if( aHeap[i]<aHeap[j] ) break;
9456 x = aHeap[i];
9457 aHeap[i] = aHeap[j];
9458 aHeap[j] = x;
9459 i = j;
9461 return 1;
9464 #ifndef SQLITE_OMIT_INTEGRITY_CHECK
9466 ** Do various sanity checks on a single page of a tree. Return
9467 ** the tree depth. Root pages return 0. Parents of root pages
9468 ** return 1, and so forth.
9470 ** These checks are done:
9472 ** 1. Make sure that cells and freeblocks do not overlap
9473 ** but combine to completely cover the page.
9474 ** 2. Make sure integer cell keys are in order.
9475 ** 3. Check the integrity of overflow pages.
9476 ** 4. Recursively call checkTreePage on all children.
9477 ** 5. Verify that the depth of all children is the same.
9479 static int checkTreePage(
9480 IntegrityCk *pCheck, /* Context for the sanity check */
9481 int iPage, /* Page number of the page to check */
9482 i64 *piMinKey, /* Write minimum integer primary key here */
9483 i64 maxKey /* Error if integer primary key greater than this */
9485 MemPage *pPage = 0; /* The page being analyzed */
9486 int i; /* Loop counter */
9487 int rc; /* Result code from subroutine call */
9488 int depth = -1, d2; /* Depth of a subtree */
9489 int pgno; /* Page number */
9490 int nFrag; /* Number of fragmented bytes on the page */
9491 int hdr; /* Offset to the page header */
9492 int cellStart; /* Offset to the start of the cell pointer array */
9493 int nCell; /* Number of cells */
9494 int doCoverageCheck = 1; /* True if cell coverage checking should be done */
9495 int keyCanBeEqual = 1; /* True if IPK can be equal to maxKey
9496 ** False if IPK must be strictly less than maxKey */
9497 u8 *data; /* Page content */
9498 u8 *pCell; /* Cell content */
9499 u8 *pCellIdx; /* Next element of the cell pointer array */
9500 BtShared *pBt; /* The BtShared object that owns pPage */
9501 u32 pc; /* Address of a cell */
9502 u32 usableSize; /* Usable size of the page */
9503 u32 contentOffset; /* Offset to the start of the cell content area */
9504 u32 *heap = 0; /* Min-heap used for checking cell coverage */
9505 u32 x, prev = 0; /* Next and previous entry on the min-heap */
9506 const char *saved_zPfx = pCheck->zPfx;
9507 int saved_v1 = pCheck->v1;
9508 int saved_v2 = pCheck->v2;
9509 u8 savedIsInit = 0;
9511 /* Check that the page exists
9513 pBt = pCheck->pBt;
9514 usableSize = pBt->usableSize;
9515 if( iPage==0 ) return 0;
9516 if( checkRef(pCheck, iPage) ) return 0;
9517 pCheck->zPfx = "Page %d: ";
9518 pCheck->v1 = iPage;
9519 if( (rc = btreeGetPage(pBt, (Pgno)iPage, &pPage, 0))!=0 ){
9520 checkAppendMsg(pCheck,
9521 "unable to get the page. error code=%d", rc);
9522 goto end_of_check;
9525 /* Clear MemPage.isInit to make sure the corruption detection code in
9526 ** btreeInitPage() is executed. */
9527 savedIsInit = pPage->isInit;
9528 pPage->isInit = 0;
9529 if( (rc = btreeInitPage(pPage))!=0 ){
9530 assert( rc==SQLITE_CORRUPT ); /* The only possible error from InitPage */
9531 checkAppendMsg(pCheck,
9532 "btreeInitPage() returns error code %d", rc);
9533 goto end_of_check;
9535 data = pPage->aData;
9536 hdr = pPage->hdrOffset;
9538 /* Set up for cell analysis */
9539 pCheck->zPfx = "On tree page %d cell %d: ";
9540 contentOffset = get2byteNotZero(&data[hdr+5]);
9541 assert( contentOffset<=usableSize ); /* Enforced by btreeInitPage() */
9543 /* EVIDENCE-OF: R-37002-32774 The two-byte integer at offset 3 gives the
9544 ** number of cells on the page. */
9545 nCell = get2byte(&data[hdr+3]);
9546 assert( pPage->nCell==nCell );
9548 /* EVIDENCE-OF: R-23882-45353 The cell pointer array of a b-tree page
9549 ** immediately follows the b-tree page header. */
9550 cellStart = hdr + 12 - 4*pPage->leaf;
9551 assert( pPage->aCellIdx==&data[cellStart] );
9552 pCellIdx = &data[cellStart + 2*(nCell-1)];
9554 if( !pPage->leaf ){
9555 /* Analyze the right-child page of internal pages */
9556 pgno = get4byte(&data[hdr+8]);
9557 #ifndef SQLITE_OMIT_AUTOVACUUM
9558 if( pBt->autoVacuum ){
9559 pCheck->zPfx = "On page %d at right child: ";
9560 checkPtrmap(pCheck, pgno, PTRMAP_BTREE, iPage);
9562 #endif
9563 depth = checkTreePage(pCheck, pgno, &maxKey, maxKey);
9564 keyCanBeEqual = 0;
9565 }else{
9566 /* For leaf pages, the coverage check will occur in the same loop
9567 ** as the other cell checks, so initialize the heap. */
9568 heap = pCheck->heap;
9569 heap[0] = 0;
9572 /* EVIDENCE-OF: R-02776-14802 The cell pointer array consists of K 2-byte
9573 ** integer offsets to the cell contents. */
9574 for(i=nCell-1; i>=0 && pCheck->mxErr; i--){
9575 CellInfo info;
9577 /* Check cell size */
9578 pCheck->v2 = i;
9579 assert( pCellIdx==&data[cellStart + i*2] );
9580 pc = get2byteAligned(pCellIdx);
9581 pCellIdx -= 2;
9582 if( pc<contentOffset || pc>usableSize-4 ){
9583 checkAppendMsg(pCheck, "Offset %d out of range %d..%d",
9584 pc, contentOffset, usableSize-4);
9585 doCoverageCheck = 0;
9586 continue;
9588 pCell = &data[pc];
9589 pPage->xParseCell(pPage, pCell, &info);
9590 if( pc+info.nSize>usableSize ){
9591 checkAppendMsg(pCheck, "Extends off end of page");
9592 doCoverageCheck = 0;
9593 continue;
9596 /* Check for integer primary key out of range */
9597 if( pPage->intKey ){
9598 if( keyCanBeEqual ? (info.nKey > maxKey) : (info.nKey >= maxKey) ){
9599 checkAppendMsg(pCheck, "Rowid %lld out of order", info.nKey);
9601 maxKey = info.nKey;
9602 keyCanBeEqual = 0; /* Only the first key on the page may ==maxKey */
9605 /* Check the content overflow list */
9606 if( info.nPayload>info.nLocal ){
9607 int nPage; /* Number of pages on the overflow chain */
9608 Pgno pgnoOvfl; /* First page of the overflow chain */
9609 assert( pc + info.nSize - 4 <= usableSize );
9610 nPage = (info.nPayload - info.nLocal + usableSize - 5)/(usableSize - 4);
9611 pgnoOvfl = get4byte(&pCell[info.nSize - 4]);
9612 #ifndef SQLITE_OMIT_AUTOVACUUM
9613 if( pBt->autoVacuum ){
9614 checkPtrmap(pCheck, pgnoOvfl, PTRMAP_OVERFLOW1, iPage);
9616 #endif
9617 checkList(pCheck, 0, pgnoOvfl, nPage);
9620 if( !pPage->leaf ){
9621 /* Check sanity of left child page for internal pages */
9622 pgno = get4byte(pCell);
9623 #ifndef SQLITE_OMIT_AUTOVACUUM
9624 if( pBt->autoVacuum ){
9625 checkPtrmap(pCheck, pgno, PTRMAP_BTREE, iPage);
9627 #endif
9628 d2 = checkTreePage(pCheck, pgno, &maxKey, maxKey);
9629 keyCanBeEqual = 0;
9630 if( d2!=depth ){
9631 checkAppendMsg(pCheck, "Child page depth differs");
9632 depth = d2;
9634 }else{
9635 /* Populate the coverage-checking heap for leaf pages */
9636 btreeHeapInsert(heap, (pc<<16)|(pc+info.nSize-1));
9639 *piMinKey = maxKey;
9641 /* Check for complete coverage of the page
9643 pCheck->zPfx = 0;
9644 if( doCoverageCheck && pCheck->mxErr>0 ){
9645 /* For leaf pages, the min-heap has already been initialized and the
9646 ** cells have already been inserted. But for internal pages, that has
9647 ** not yet been done, so do it now */
9648 if( !pPage->leaf ){
9649 heap = pCheck->heap;
9650 heap[0] = 0;
9651 for(i=nCell-1; i>=0; i--){
9652 u32 size;
9653 pc = get2byteAligned(&data[cellStart+i*2]);
9654 size = pPage->xCellSize(pPage, &data[pc]);
9655 btreeHeapInsert(heap, (pc<<16)|(pc+size-1));
9658 /* Add the freeblocks to the min-heap
9660 ** EVIDENCE-OF: R-20690-50594 The second field of the b-tree page header
9661 ** is the offset of the first freeblock, or zero if there are no
9662 ** freeblocks on the page.
9664 i = get2byte(&data[hdr+1]);
9665 while( i>0 ){
9666 int size, j;
9667 assert( (u32)i<=usableSize-4 ); /* Enforced by btreeInitPage() */
9668 size = get2byte(&data[i+2]);
9669 assert( (u32)(i+size)<=usableSize ); /* Enforced by btreeInitPage() */
9670 btreeHeapInsert(heap, (((u32)i)<<16)|(i+size-1));
9671 /* EVIDENCE-OF: R-58208-19414 The first 2 bytes of a freeblock are a
9672 ** big-endian integer which is the offset in the b-tree page of the next
9673 ** freeblock in the chain, or zero if the freeblock is the last on the
9674 ** chain. */
9675 j = get2byte(&data[i]);
9676 /* EVIDENCE-OF: R-06866-39125 Freeblocks are always connected in order of
9677 ** increasing offset. */
9678 assert( j==0 || j>i+size ); /* Enforced by btreeInitPage() */
9679 assert( (u32)j<=usableSize-4 ); /* Enforced by btreeInitPage() */
9680 i = j;
9682 /* Analyze the min-heap looking for overlap between cells and/or
9683 ** freeblocks, and counting the number of untracked bytes in nFrag.
9685 ** Each min-heap entry is of the form: (start_address<<16)|end_address.
9686 ** There is an implied first entry the covers the page header, the cell
9687 ** pointer index, and the gap between the cell pointer index and the start
9688 ** of cell content.
9690 ** The loop below pulls entries from the min-heap in order and compares
9691 ** the start_address against the previous end_address. If there is an
9692 ** overlap, that means bytes are used multiple times. If there is a gap,
9693 ** that gap is added to the fragmentation count.
9695 nFrag = 0;
9696 prev = contentOffset - 1; /* Implied first min-heap entry */
9697 while( btreeHeapPull(heap,&x) ){
9698 if( (prev&0xffff)>=(x>>16) ){
9699 checkAppendMsg(pCheck,
9700 "Multiple uses for byte %u of page %d", x>>16, iPage);
9701 break;
9702 }else{
9703 nFrag += (x>>16) - (prev&0xffff) - 1;
9704 prev = x;
9707 nFrag += usableSize - (prev&0xffff) - 1;
9708 /* EVIDENCE-OF: R-43263-13491 The total number of bytes in all fragments
9709 ** is stored in the fifth field of the b-tree page header.
9710 ** EVIDENCE-OF: R-07161-27322 The one-byte integer at offset 7 gives the
9711 ** number of fragmented free bytes within the cell content area.
9713 if( heap[0]==0 && nFrag!=data[hdr+7] ){
9714 checkAppendMsg(pCheck,
9715 "Fragmentation of %d bytes reported as %d on page %d",
9716 nFrag, data[hdr+7], iPage);
9720 end_of_check:
9721 if( !doCoverageCheck ) pPage->isInit = savedIsInit;
9722 releasePage(pPage);
9723 pCheck->zPfx = saved_zPfx;
9724 pCheck->v1 = saved_v1;
9725 pCheck->v2 = saved_v2;
9726 return depth+1;
9728 #endif /* SQLITE_OMIT_INTEGRITY_CHECK */
9730 #ifndef SQLITE_OMIT_INTEGRITY_CHECK
9732 ** This routine does a complete check of the given BTree file. aRoot[] is
9733 ** an array of pages numbers were each page number is the root page of
9734 ** a table. nRoot is the number of entries in aRoot.
9736 ** A read-only or read-write transaction must be opened before calling
9737 ** this function.
9739 ** Write the number of error seen in *pnErr. Except for some memory
9740 ** allocation errors, an error message held in memory obtained from
9741 ** malloc is returned if *pnErr is non-zero. If *pnErr==0 then NULL is
9742 ** returned. If a memory allocation error occurs, NULL is returned.
9744 char *sqlite3BtreeIntegrityCheck(
9745 Btree *p, /* The btree to be checked */
9746 int *aRoot, /* An array of root pages numbers for individual trees */
9747 int nRoot, /* Number of entries in aRoot[] */
9748 int mxErr, /* Stop reporting errors after this many */
9749 int *pnErr /* Write number of errors seen to this variable */
9751 Pgno i;
9752 IntegrityCk sCheck;
9753 BtShared *pBt = p->pBt;
9754 int savedDbFlags = pBt->db->flags;
9755 char zErr[100];
9756 VVA_ONLY( int nRef );
9758 sqlite3BtreeEnter(p);
9759 assert( p->inTrans>TRANS_NONE && pBt->inTransaction>TRANS_NONE );
9760 VVA_ONLY( nRef = sqlite3PagerRefcount(pBt->pPager) );
9761 assert( nRef>=0 );
9762 sCheck.pBt = pBt;
9763 sCheck.pPager = pBt->pPager;
9764 sCheck.nPage = btreePagecount(sCheck.pBt);
9765 sCheck.mxErr = mxErr;
9766 sCheck.nErr = 0;
9767 sCheck.mallocFailed = 0;
9768 sCheck.zPfx = 0;
9769 sCheck.v1 = 0;
9770 sCheck.v2 = 0;
9771 sCheck.aPgRef = 0;
9772 sCheck.heap = 0;
9773 sqlite3StrAccumInit(&sCheck.errMsg, 0, zErr, sizeof(zErr), SQLITE_MAX_LENGTH);
9774 sCheck.errMsg.printfFlags = SQLITE_PRINTF_INTERNAL;
9775 if( sCheck.nPage==0 ){
9776 goto integrity_ck_cleanup;
9779 sCheck.aPgRef = sqlite3MallocZero((sCheck.nPage / 8)+ 1);
9780 if( !sCheck.aPgRef ){
9781 sCheck.mallocFailed = 1;
9782 goto integrity_ck_cleanup;
9784 sCheck.heap = (u32*)sqlite3PageMalloc( pBt->pageSize );
9785 if( sCheck.heap==0 ){
9786 sCheck.mallocFailed = 1;
9787 goto integrity_ck_cleanup;
9790 i = PENDING_BYTE_PAGE(pBt);
9791 if( i<=sCheck.nPage ) setPageReferenced(&sCheck, i);
9793 /* Check the integrity of the freelist
9795 sCheck.zPfx = "Main freelist: ";
9796 checkList(&sCheck, 1, get4byte(&pBt->pPage1->aData[32]),
9797 get4byte(&pBt->pPage1->aData[36]));
9798 sCheck.zPfx = 0;
9800 /* Check all the tables.
9802 testcase( pBt->db->flags & SQLITE_CellSizeCk );
9803 pBt->db->flags &= ~SQLITE_CellSizeCk;
9804 for(i=0; (int)i<nRoot && sCheck.mxErr; i++){
9805 i64 notUsed;
9806 if( aRoot[i]==0 ) continue;
9807 #ifndef SQLITE_OMIT_AUTOVACUUM
9808 if( pBt->autoVacuum && aRoot[i]>1 ){
9809 checkPtrmap(&sCheck, aRoot[i], PTRMAP_ROOTPAGE, 0);
9811 #endif
9812 checkTreePage(&sCheck, aRoot[i], &notUsed, LARGEST_INT64);
9814 pBt->db->flags = savedDbFlags;
9816 /* Make sure every page in the file is referenced
9818 for(i=1; i<=sCheck.nPage && sCheck.mxErr; i++){
9819 #ifdef SQLITE_OMIT_AUTOVACUUM
9820 if( getPageReferenced(&sCheck, i)==0 ){
9821 checkAppendMsg(&sCheck, "Page %d is never used", i);
9823 #else
9824 /* If the database supports auto-vacuum, make sure no tables contain
9825 ** references to pointer-map pages.
9827 if( getPageReferenced(&sCheck, i)==0 &&
9828 (PTRMAP_PAGENO(pBt, i)!=i || !pBt->autoVacuum) ){
9829 checkAppendMsg(&sCheck, "Page %d is never used", i);
9831 if( getPageReferenced(&sCheck, i)!=0 &&
9832 (PTRMAP_PAGENO(pBt, i)==i && pBt->autoVacuum) ){
9833 checkAppendMsg(&sCheck, "Pointer map page %d is referenced", i);
9835 #endif
9838 /* Clean up and report errors.
9840 integrity_ck_cleanup:
9841 sqlite3PageFree(sCheck.heap);
9842 sqlite3_free(sCheck.aPgRef);
9843 if( sCheck.mallocFailed ){
9844 sqlite3_str_reset(&sCheck.errMsg);
9845 sCheck.nErr++;
9847 *pnErr = sCheck.nErr;
9848 if( sCheck.nErr==0 ) sqlite3_str_reset(&sCheck.errMsg);
9849 /* Make sure this analysis did not leave any unref() pages. */
9850 assert( nRef==sqlite3PagerRefcount(pBt->pPager) );
9851 sqlite3BtreeLeave(p);
9852 return sqlite3StrAccumFinish(&sCheck.errMsg);
9854 #endif /* SQLITE_OMIT_INTEGRITY_CHECK */
9857 ** Return the full pathname of the underlying database file. Return
9858 ** an empty string if the database is in-memory or a TEMP database.
9860 ** The pager filename is invariant as long as the pager is
9861 ** open so it is safe to access without the BtShared mutex.
9863 const char *sqlite3BtreeGetFilename(Btree *p){
9864 assert( p->pBt->pPager!=0 );
9865 return sqlite3PagerFilename(p->pBt->pPager, 1);
9869 ** Return the pathname of the journal file for this database. The return
9870 ** value of this routine is the same regardless of whether the journal file
9871 ** has been created or not.
9873 ** The pager journal filename is invariant as long as the pager is
9874 ** open so it is safe to access without the BtShared mutex.
9876 const char *sqlite3BtreeGetJournalname(Btree *p){
9877 assert( p->pBt->pPager!=0 );
9878 return sqlite3PagerJournalname(p->pBt->pPager);
9882 ** Return non-zero if a transaction is active.
9884 int sqlite3BtreeIsInTrans(Btree *p){
9885 assert( p==0 || sqlite3_mutex_held(p->db->mutex) );
9886 return (p && (p->inTrans==TRANS_WRITE));
9889 #ifndef SQLITE_OMIT_WAL
9891 ** Run a checkpoint on the Btree passed as the first argument.
9893 ** Return SQLITE_LOCKED if this or any other connection has an open
9894 ** transaction on the shared-cache the argument Btree is connected to.
9896 ** Parameter eMode is one of SQLITE_CHECKPOINT_PASSIVE, FULL or RESTART.
9898 int sqlite3BtreeCheckpoint(Btree *p, int eMode, int *pnLog, int *pnCkpt){
9899 int rc = SQLITE_OK;
9900 if( p ){
9901 BtShared *pBt = p->pBt;
9902 sqlite3BtreeEnter(p);
9903 if( pBt->inTransaction!=TRANS_NONE ){
9904 rc = SQLITE_LOCKED;
9905 }else{
9906 rc = sqlite3PagerCheckpoint(pBt->pPager, p->db, eMode, pnLog, pnCkpt);
9908 sqlite3BtreeLeave(p);
9910 return rc;
9912 #endif
9915 ** Return non-zero if a read (or write) transaction is active.
9917 int sqlite3BtreeIsInReadTrans(Btree *p){
9918 assert( p );
9919 assert( sqlite3_mutex_held(p->db->mutex) );
9920 return p->inTrans!=TRANS_NONE;
9923 int sqlite3BtreeIsInBackup(Btree *p){
9924 assert( p );
9925 assert( sqlite3_mutex_held(p->db->mutex) );
9926 return p->nBackup!=0;
9930 ** This function returns a pointer to a blob of memory associated with
9931 ** a single shared-btree. The memory is used by client code for its own
9932 ** purposes (for example, to store a high-level schema associated with
9933 ** the shared-btree). The btree layer manages reference counting issues.
9935 ** The first time this is called on a shared-btree, nBytes bytes of memory
9936 ** are allocated, zeroed, and returned to the caller. For each subsequent
9937 ** call the nBytes parameter is ignored and a pointer to the same blob
9938 ** of memory returned.
9940 ** If the nBytes parameter is 0 and the blob of memory has not yet been
9941 ** allocated, a null pointer is returned. If the blob has already been
9942 ** allocated, it is returned as normal.
9944 ** Just before the shared-btree is closed, the function passed as the
9945 ** xFree argument when the memory allocation was made is invoked on the
9946 ** blob of allocated memory. The xFree function should not call sqlite3_free()
9947 ** on the memory, the btree layer does that.
9949 void *sqlite3BtreeSchema(Btree *p, int nBytes, void(*xFree)(void *)){
9950 BtShared *pBt = p->pBt;
9951 sqlite3BtreeEnter(p);
9952 if( !pBt->pSchema && nBytes ){
9953 pBt->pSchema = sqlite3DbMallocZero(0, nBytes);
9954 pBt->xFreeSchema = xFree;
9956 sqlite3BtreeLeave(p);
9957 return pBt->pSchema;
9961 ** Return SQLITE_LOCKED_SHAREDCACHE if another user of the same shared
9962 ** btree as the argument handle holds an exclusive lock on the
9963 ** sqlite_master table. Otherwise SQLITE_OK.
9965 int sqlite3BtreeSchemaLocked(Btree *p){
9966 int rc;
9967 assert( sqlite3_mutex_held(p->db->mutex) );
9968 sqlite3BtreeEnter(p);
9969 rc = querySharedCacheTableLock(p, MASTER_ROOT, READ_LOCK);
9970 assert( rc==SQLITE_OK || rc==SQLITE_LOCKED_SHAREDCACHE );
9971 sqlite3BtreeLeave(p);
9972 return rc;
9976 #ifndef SQLITE_OMIT_SHARED_CACHE
9978 ** Obtain a lock on the table whose root page is iTab. The
9979 ** lock is a write lock if isWritelock is true or a read lock
9980 ** if it is false.
9982 int sqlite3BtreeLockTable(Btree *p, int iTab, u8 isWriteLock){
9983 int rc = SQLITE_OK;
9984 assert( p->inTrans!=TRANS_NONE );
9985 if( p->sharable ){
9986 u8 lockType = READ_LOCK + isWriteLock;
9987 assert( READ_LOCK+1==WRITE_LOCK );
9988 assert( isWriteLock==0 || isWriteLock==1 );
9990 sqlite3BtreeEnter(p);
9991 rc = querySharedCacheTableLock(p, iTab, lockType);
9992 if( rc==SQLITE_OK ){
9993 rc = setSharedCacheTableLock(p, iTab, lockType);
9995 sqlite3BtreeLeave(p);
9997 return rc;
9999 #endif
10001 #ifndef SQLITE_OMIT_INCRBLOB
10003 ** Argument pCsr must be a cursor opened for writing on an
10004 ** INTKEY table currently pointing at a valid table entry.
10005 ** This function modifies the data stored as part of that entry.
10007 ** Only the data content may only be modified, it is not possible to
10008 ** change the length of the data stored. If this function is called with
10009 ** parameters that attempt to write past the end of the existing data,
10010 ** no modifications are made and SQLITE_CORRUPT is returned.
10012 int sqlite3BtreePutData(BtCursor *pCsr, u32 offset, u32 amt, void *z){
10013 int rc;
10014 assert( cursorOwnsBtShared(pCsr) );
10015 assert( sqlite3_mutex_held(pCsr->pBtree->db->mutex) );
10016 assert( pCsr->curFlags & BTCF_Incrblob );
10018 rc = restoreCursorPosition(pCsr);
10019 if( rc!=SQLITE_OK ){
10020 return rc;
10022 assert( pCsr->eState!=CURSOR_REQUIRESEEK );
10023 if( pCsr->eState!=CURSOR_VALID ){
10024 return SQLITE_ABORT;
10027 /* Save the positions of all other cursors open on this table. This is
10028 ** required in case any of them are holding references to an xFetch
10029 ** version of the b-tree page modified by the accessPayload call below.
10031 ** Note that pCsr must be open on a INTKEY table and saveCursorPosition()
10032 ** and hence saveAllCursors() cannot fail on a BTREE_INTKEY table, hence
10033 ** saveAllCursors can only return SQLITE_OK.
10035 VVA_ONLY(rc =) saveAllCursors(pCsr->pBt, pCsr->pgnoRoot, pCsr);
10036 assert( rc==SQLITE_OK );
10038 /* Check some assumptions:
10039 ** (a) the cursor is open for writing,
10040 ** (b) there is a read/write transaction open,
10041 ** (c) the connection holds a write-lock on the table (if required),
10042 ** (d) there are no conflicting read-locks, and
10043 ** (e) the cursor points at a valid row of an intKey table.
10045 if( (pCsr->curFlags & BTCF_WriteFlag)==0 ){
10046 return SQLITE_READONLY;
10048 assert( (pCsr->pBt->btsFlags & BTS_READ_ONLY)==0
10049 && pCsr->pBt->inTransaction==TRANS_WRITE );
10050 assert( hasSharedCacheTableLock(pCsr->pBtree, pCsr->pgnoRoot, 0, 2) );
10051 assert( !hasReadConflicts(pCsr->pBtree, pCsr->pgnoRoot) );
10052 assert( pCsr->pPage->intKey );
10054 return accessPayload(pCsr, offset, amt, (unsigned char *)z, 1);
10058 ** Mark this cursor as an incremental blob cursor.
10060 void sqlite3BtreeIncrblobCursor(BtCursor *pCur){
10061 pCur->curFlags |= BTCF_Incrblob;
10062 pCur->pBtree->hasIncrblobCur = 1;
10064 #endif
10067 ** Set both the "read version" (single byte at byte offset 18) and
10068 ** "write version" (single byte at byte offset 19) fields in the database
10069 ** header to iVersion.
10071 int sqlite3BtreeSetVersion(Btree *pBtree, int iVersion){
10072 BtShared *pBt = pBtree->pBt;
10073 int rc; /* Return code */
10075 assert( iVersion==1 || iVersion==2 );
10077 /* If setting the version fields to 1, do not automatically open the
10078 ** WAL connection, even if the version fields are currently set to 2.
10080 pBt->btsFlags &= ~BTS_NO_WAL;
10081 if( iVersion==1 ) pBt->btsFlags |= BTS_NO_WAL;
10083 rc = sqlite3BtreeBeginTrans(pBtree, 0);
10084 if( rc==SQLITE_OK ){
10085 u8 *aData = pBt->pPage1->aData;
10086 if( aData[18]!=(u8)iVersion || aData[19]!=(u8)iVersion ){
10087 rc = sqlite3BtreeBeginTrans(pBtree, 2);
10088 if( rc==SQLITE_OK ){
10089 rc = sqlite3PagerWrite(pBt->pPage1->pDbPage);
10090 if( rc==SQLITE_OK ){
10091 aData[18] = (u8)iVersion;
10092 aData[19] = (u8)iVersion;
10098 pBt->btsFlags &= ~BTS_NO_WAL;
10099 return rc;
10103 ** Return true if the cursor has a hint specified. This routine is
10104 ** only used from within assert() statements
10106 int sqlite3BtreeCursorHasHint(BtCursor *pCsr, unsigned int mask){
10107 return (pCsr->hints & mask)!=0;
10111 ** Return true if the given Btree is read-only.
10113 int sqlite3BtreeIsReadonly(Btree *p){
10114 return (p->pBt->btsFlags & BTS_READ_ONLY)!=0;
10118 ** Return the size of the header added to each page by this module.
10120 int sqlite3HeaderSizeBtree(void){ return ROUND8(sizeof(MemPage)); }
10122 #if !defined(SQLITE_OMIT_SHARED_CACHE)
10124 ** Return true if the Btree passed as the only argument is sharable.
10126 int sqlite3BtreeSharable(Btree *p){
10127 return p->sharable;
10131 ** Return the number of connections to the BtShared object accessed by
10132 ** the Btree handle passed as the only argument. For private caches
10133 ** this is always 1. For shared caches it may be 1 or greater.
10135 int sqlite3BtreeConnectionCount(Btree *p){
10136 testcase( p->sharable );
10137 return p->pBt->nRef;
10139 #endif