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Update autosetup to v0.6.8
[jimtcl.git] / jim.c
blob127033060b926cd07814c244eba7e797e09b5135
1 /* Jim - A small embeddable Tcl interpreter
2 *
3 * Copyright 2005 Salvatore Sanfilippo <antirez@invece.org>
4 * Copyright 2005 Clemens Hintze <c.hintze@gmx.net>
5 * Copyright 2005 patthoyts - Pat Thoyts <patthoyts@users.sf.net>
6 * Copyright 2008,2009 oharboe - Øyvind Harboe - oyvind.harboe@zylin.com
7 * Copyright 2008 Andrew Lunn <andrew@lunn.ch>
8 * Copyright 2008 Duane Ellis <openocd@duaneellis.com>
9 * Copyright 2008 Uwe Klein <uklein@klein-messgeraete.de>
10 * Copyright 2008 Steve Bennett <steveb@workware.net.au>
11 * Copyright 2009 Nico Coesel <ncoesel@dealogic.nl>
12 * Copyright 2009 Zachary T Welch zw@superlucidity.net
13 * Copyright 2009 David Brownell
14 *
15 * Redistribution and use in source and binary forms, with or without
16 * modification, are permitted provided that the following conditions
17 * are met:
18 *
19 * 1. Redistributions of source code must retain the above copyright
20 * notice, this list of conditions and the following disclaimer.
21 * 2. Redistributions in binary form must reproduce the above
22 * copyright notice, this list of conditions and the following
23 * disclaimer in the documentation and/or other materials
24 * provided with the distribution.
25 *
26 * THIS SOFTWARE IS PROVIDED BY THE JIM TCL PROJECT ``AS IS'' AND ANY
27 * EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO,
28 * THE IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A
29 * PARTICULAR PURPOSE ARE DISCLAIMED. IN NO EVENT SHALL THE
30 * JIM TCL PROJECT OR CONTRIBUTORS BE LIABLE FOR ANY DIRECT,
31 * INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR CONSEQUENTIAL DAMAGES
32 * (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS
33 * OR SERVICES; LOSS OF USE, DATA, OR PROFITS; OR BUSINESS INTERRUPTION)
34 * HOWEVER CAUSED AND ON ANY THEORY OF LIABILITY, WHETHER IN CONTRACT,
35 * STRICT LIABILITY, OR TORT (INCLUDING NEGLIGENCE OR OTHERWISE)
36 * ARISING IN ANY WAY OUT OF THE USE OF THIS SOFTWARE, EVEN IF
37 * ADVISED OF THE POSSIBILITY OF SUCH DAMAGE.
38 *
39 * The views and conclusions contained in the software and documentation
40 * are those of the authors and should not be interpreted as representing
41 * official policies, either expressed or implied, of the Jim Tcl Project.
42 **/
43 #define JIM_OPTIMIZATION /* comment to avoid optimizations and reduce size */
44 #ifndef _GNU_SOURCE
45 #define _GNU_SOURCE /* Mostly just for environ */
46 #endif
47
48 #include <stdio.h>
49 #include <stdlib.h>
50
51 #include <string.h>
52 #include <stdarg.h>
53 #include <ctype.h>
54 #include <limits.h>
55 #include <assert.h>
56 #include <errno.h>
57 #include <time.h>
58 #include <setjmp.h>
59
60 #include "jim.h"
61 #include "jimautoconf.h"
62 #include "utf8.h"
63
64 #ifdef HAVE_SYS_TIME_H
65 #include <sys/time.h>
66 #endif
67 #ifdef HAVE_BACKTRACE
68 #include <execinfo.h>
69 #endif
70 #ifdef HAVE_CRT_EXTERNS_H
71 #include <crt_externs.h>
72 #endif
73
74 /* For INFINITY, even if math functions are not enabled */
75 #include <math.h>
76
77 /* We may decide to switch to using $[...] after all, so leave it as an option */
78 /*#define EXPRSUGAR_BRACKET*/
79
80 /* For the no-autoconf case */
81 #ifndef TCL_LIBRARY
82 #define TCL_LIBRARY "."
83 #endif
84 #ifndef TCL_PLATFORM_OS
85 #define TCL_PLATFORM_OS "unknown"
86 #endif
87 #ifndef TCL_PLATFORM_PLATFORM
88 #define TCL_PLATFORM_PLATFORM "unknown"
89 #endif
90 #ifndef TCL_PLATFORM_PATH_SEPARATOR
91 #define TCL_PLATFORM_PATH_SEPARATOR ":"
92 #endif
93
94 /*#define DEBUG_SHOW_SCRIPT*/
95 /*#define DEBUG_SHOW_SCRIPT_TOKENS*/
96 /*#define DEBUG_SHOW_SUBST*/
97 /*#define DEBUG_SHOW_EXPR*/
98 /*#define DEBUG_SHOW_EXPR_TOKENS*/
99 /*#define JIM_DEBUG_GC*/
100 #ifdef JIM_MAINTAINER
101 #define JIM_DEBUG_COMMAND
102 #define JIM_DEBUG_PANIC
103 #endif
104 /* Enable this (in conjunction with valgrind) to help debug
105 * reference counting issues
106 */
107 /*#define JIM_DISABLE_OBJECT_POOL*/
108
109 /* Maximum size of an integer */
110 #define JIM_INTEGER_SPACE 24
111
112 const char *jim_tt_name(int type);
113
114 #ifdef JIM_DEBUG_PANIC
115 static void JimPanicDump(int fail_condition, const char *fmt, ...);
116 #define JimPanic(X) JimPanicDump X
117 #else
118 #define JimPanic(X)
119 #endif
120
121 #ifdef JIM_OPTIMIZATION
122 #define JIM_IF_OPTIM(X) X
123 #else
124 #define JIM_IF_OPTIM(X)
125 #endif
126
127 /* -----------------------------------------------------------------------------
128 * Global variables
129 * ---------------------------------------------------------------------------*/
130
131 /* A shared empty string for the objects string representation.
132 * Jim_InvalidateStringRep knows about it and doesn't try to free it. */
133 static char JimEmptyStringRep[] = "";
134
135 /* -----------------------------------------------------------------------------
136 * Required prototypes of not exported functions
137 * ---------------------------------------------------------------------------*/
138 static void JimFreeCallFrame(Jim_Interp *interp, Jim_CallFrame *cf, int action);
139 static int ListSetIndex(Jim_Interp *interp, Jim_Obj *listPtr, int listindex, Jim_Obj *newObjPtr,
140 int flags);
141 static int JimDeleteLocalProcs(Jim_Interp *interp, Jim_Stack *localCommands);
142 static Jim_Obj *JimExpandDictSugar(Jim_Interp *interp, Jim_Obj *objPtr);
143 static void SetDictSubstFromAny(Jim_Interp *interp, Jim_Obj *objPtr);
144 static Jim_Obj **JimDictPairs(Jim_Obj *dictPtr, int *len);
145 static void JimSetFailedEnumResult(Jim_Interp *interp, const char *arg, const char *badtype,
146 const char *prefix, const char *const *tablePtr, const char *name);
147 static int JimCallProcedure(Jim_Interp *interp, Jim_Cmd *cmd, int argc, Jim_Obj *const *argv);
148 static int JimGetWideNoErr(Jim_Interp *interp, Jim_Obj *objPtr, jim_wide * widePtr);
149 static int JimSign(jim_wide w);
150 static int JimValidName(Jim_Interp *interp, const char *type, Jim_Obj *nameObjPtr);
151 static void JimPrngSeed(Jim_Interp *interp, unsigned char *seed, int seedLen);
152 static void JimRandomBytes(Jim_Interp *interp, void *dest, unsigned int len);
153
154
155 /* Fast access to the int (wide) value of an object which is known to be of int type */
156 #define JimWideValue(objPtr) (objPtr)->internalRep.wideValue
157
158 #define JimObjTypeName(O) ((O)->typePtr ? (O)->typePtr->name : "none")
159
160 static int utf8_tounicode_case(const char *s, int *uc, int upper)
161 {
162 int l = utf8_tounicode(s, uc);
163 if (upper) {
164 *uc = utf8_upper(*uc);
165 }
166 return l;
167 }
168
169 /* These can be used in addition to JIM_CASESENS/JIM_NOCASE */
170 #define JIM_CHARSET_SCAN 2
171 #define JIM_CHARSET_GLOB 0
172
173 /**
174 * pattern points to a string like "[^a-z\ub5]"
175 *
176 * The pattern may contain trailing chars, which are ignored.
177 *
178 * The pattern is matched against unicode char 'c'.
179 *
180 * If (flags & JIM_NOCASE), case is ignored when matching.
181 * If (flags & JIM_CHARSET_SCAN), the considers ^ and ] special at the start
182 * of the charset, per scan, rather than glob/string match.
183 *
184 * If the unicode char 'c' matches that set, returns a pointer to the ']' character,
185 * or the null character if the ']' is missing.
186 *
187 * Returns NULL on no match.
188 */
189 static const char *JimCharsetMatch(const char *pattern, int c, int flags)
190 {
191 int not = 0;
192 int pchar;
193 int match = 0;
194 int nocase = 0;
195
196 if (flags & JIM_NOCASE) {
197 nocase++;
198 c = utf8_upper(c);
199 }
200
201 if (flags & JIM_CHARSET_SCAN) {
202 if (*pattern == '^') {
203 not++;
204 pattern++;
205 }
206
207 /* Special case. If the first char is ']', it is part of the set */
208 if (*pattern == ']') {
209 goto first;
210 }
211 }
212
213 while (*pattern && *pattern != ']') {
214 /* Exact match */
215 if (pattern[0] == '\\') {
216 first:
217 pattern += utf8_tounicode_case(pattern, &pchar, nocase);
218 }
219 else {
220 /* Is this a range? a-z */
221 int start;
222 int end;
223
224 pattern += utf8_tounicode_case(pattern, &start, nocase);
225 if (pattern[0] == '-' && pattern[1]) {
226 /* skip '-' */
227 pattern++;
228 pattern += utf8_tounicode_case(pattern, &end, nocase);
229
230 /* Handle reversed range too */
231 if ((c >= start && c <= end) || (c >= end && c <= start)) {
232 match = 1;
233 }
234 continue;
235 }
236 pchar = start;
237 }
238
239 if (pchar == c) {
240 match = 1;
241 }
242 }
243 if (not) {
244 match = !match;
245 }
246
247 return match ? pattern : NULL;
248 }
249
250 /* Glob-style pattern matching. */
251
252 /* Note: string *must* be valid UTF-8 sequences
253 */
254 static int JimGlobMatch(const char *pattern, const char *string, int nocase)
255 {
256 int c;
257 int pchar;
258 while (*pattern) {
259 switch (pattern[0]) {
260 case '*':
261 while (pattern[1] == '*') {
262 pattern++;
263 }
264 pattern++;
265 if (!pattern[0]) {
266 return 1; /* match */
267 }
268 while (*string) {
269 /* Recursive call - Does the remaining pattern match anywhere? */
270 if (JimGlobMatch(pattern, string, nocase))
271 return 1; /* match */
272 string += utf8_tounicode(string, &c);
273 }
274 return 0; /* no match */
275
276 case '?':
277 string += utf8_tounicode(string, &c);
278 break;
279
280 case '[': {
281 string += utf8_tounicode(string, &c);
282 pattern = JimCharsetMatch(pattern + 1, c, nocase ? JIM_NOCASE : 0);
283 if (!pattern) {
284 return 0;
285 }
286 if (!*pattern) {
287 /* Ran out of pattern (no ']') */
288 continue;
289 }
290 break;
291 }
292 case '\\':
293 if (pattern[1]) {
294 pattern++;
295 }
296 /* fall through */
297 default:
298 string += utf8_tounicode_case(string, &c, nocase);
299 utf8_tounicode_case(pattern, &pchar, nocase);
300 if (pchar != c) {
301 return 0;
302 }
303 break;
304 }
305 pattern += utf8_tounicode_case(pattern, &pchar, nocase);
306 if (!*string) {
307 while (*pattern == '*') {
308 pattern++;
309 }
310 break;
311 }
312 }
313 if (!*pattern && !*string) {
314 return 1;
315 }
316 return 0;
317 }
318
319 /**
320 * string comparison. Works on binary data.
321 *
322 * Returns -1, 0 or 1
323 *
324 * Note that the lengths are byte lengths, not char lengths.
325 */
326 static int JimStringCompare(const char *s1, int l1, const char *s2, int l2)
327 {
328 if (l1 < l2) {
329 return memcmp(s1, s2, l1) <= 0 ? -1 : 1;
330 }
331 else if (l2 < l1) {
332 return memcmp(s1, s2, l2) >= 0 ? 1 : -1;
333 }
334 else {
335 return JimSign(memcmp(s1, s2, l1));
336 }
337 }
338
339 /**
340 * Compare null terminated strings, up to a maximum of 'maxchars' characters,
341 * (or end of string if 'maxchars' is -1).
342 *
343 * Returns -1, 0, 1 for s1 < s2, s1 == s2, s1 > s2 respectively.
344 *
345 * Note: does not support embedded nulls.
346 */
347 static int JimStringCompareLen(const char *s1, const char *s2, int maxchars, int nocase)
348 {
349 while (*s1 && *s2 && maxchars) {
350 int c1, c2;
351 s1 += utf8_tounicode_case(s1, &c1, nocase);
352 s2 += utf8_tounicode_case(s2, &c2, nocase);
353 if (c1 != c2) {
354 return JimSign(c1 - c2);
355 }
356 maxchars--;
357 }
358 if (!maxchars) {
359 return 0;
360 }
361 /* One string or both terminated */
362 if (*s1) {
363 return 1;
364 }
365 if (*s2) {
366 return -1;
367 }
368 return 0;
369 }
370
371 /* Search for 's1' inside 's2', starting to search from char 'index' of 's2'.
372 * The index of the first occurrence of s1 in s2 is returned.
373 * If s1 is not found inside s2, -1 is returned.
374 *
375 * Note: Lengths and return value are in bytes, not chars.
376 */
377 static int JimStringFirst(const char *s1, int l1, const char *s2, int l2, int idx)
378 {
379 int i;
380 int l1bytelen;
381
382 if (!l1 || !l2 || l1 > l2) {
383 return -1;
384 }
385 if (idx < 0)
386 idx = 0;
387 s2 += utf8_index(s2, idx);
388
389 l1bytelen = utf8_index(s1, l1);
390
391 for (i = idx; i <= l2 - l1; i++) {
392 int c;
393 if (memcmp(s2, s1, l1bytelen) == 0) {
394 return i;
395 }
396 s2 += utf8_tounicode(s2, &c);
397 }
398 return -1;
399 }
400
401 /* Search for the last occurrence 's1' inside 's2', starting to search from char 'index' of 's2'.
402 * The index of the last occurrence of s1 in s2 is returned.
403 * If s1 is not found inside s2, -1 is returned.
404 *
405 * Note: Lengths and return value are in bytes, not chars.
406 */
407 static int JimStringLast(const char *s1, int l1, const char *s2, int l2)
408 {
409 const char *p;
410
411 if (!l1 || !l2 || l1 > l2)
412 return -1;
413
414 /* Now search for the needle */
415 for (p = s2 + l2 - 1; p != s2 - 1; p--) {
416 if (*p == *s1 && memcmp(s1, p, l1) == 0) {
417 return p - s2;
418 }
419 }
420 return -1;
421 }
422
423 #ifdef JIM_UTF8
424 /**
425 * Per JimStringLast but lengths and return value are in chars, not bytes.
426 */
427 static int JimStringLastUtf8(const char *s1, int l1, const char *s2, int l2)
428 {
429 int n = JimStringLast(s1, utf8_index(s1, l1), s2, utf8_index(s2, l2));
430 if (n > 0) {
431 n = utf8_strlen(s2, n);
432 }
433 return n;
434 }
435 #endif
436
437 /**
438 * After an strtol()/strtod()-like conversion,
439 * check whether something was converted and that
440 * the only thing left is white space.
441 *
442 * Returns JIM_OK or JIM_ERR.
443 */
444 static int JimCheckConversion(const char *str, const char *endptr)
445 {
446 if (str[0] == '\0' || str == endptr) {
447 return JIM_ERR;
448 }
449
450 if (endptr[0] != '\0') {
451 while (*endptr) {
452 if (!isspace(UCHAR(*endptr))) {
453 return JIM_ERR;
454 }
455 endptr++;
456 }
457 }
458 return JIM_OK;
459 }
460
461 /* Parses the front of a number to determine its sign and base.
462 * Returns the index to start parsing according to the given base
463 */
464 static int JimNumberBase(const char *str, int *base, int *sign)
465 {
466 int i = 0;
467
468 *base = 10;
469
470 while (isspace(UCHAR(str[i]))) {
471 i++;
472 }
473
474 if (str[i] == '-') {
475 *sign = -1;
476 i++;
477 }
478 else {
479 if (str[i] == '+') {
480 i++;
481 }
482 *sign = 1;
483 }
484
485 if (str[i] != '0') {
486 /* base 10 */
487 return 0;
488 }
489
490 /* We have 0<x>, so see if we can convert it */
491 switch (str[i + 1]) {
492 case 'x': case 'X': *base = 16; break;
493 case 'o': case 'O': *base = 8; break;
494 case 'b': case 'B': *base = 2; break;
495 default: return 0;
496 }
497 i += 2;
498 /* Ensure that (e.g.) 0x-5 fails to parse */
499 if (str[i] != '-' && str[i] != '+' && !isspace(UCHAR(str[i]))) {
500 /* Parse according to this base */
501 return i;
502 }
503 /* Parse as base 10 */
504 *base = 10;
505 return 0;
506 }
507
508 /* Converts a number as per strtol(..., 0) except leading zeros do *not*
509 * imply octal. Instead, decimal is assumed unless the number begins with 0x, 0o or 0b
510 */
511 static long jim_strtol(const char *str, char **endptr)
512 {
513 int sign;
514 int base;
515 int i = JimNumberBase(str, &base, &sign);
516
517 if (base != 10) {
518 long value = strtol(str + i, endptr, base);
519 if (endptr == NULL || *endptr != str + i) {
520 return value * sign;
521 }
522 }
523
524 /* Can just do a regular base-10 conversion */
525 return strtol(str, endptr, 10);
526 }
527
528
529 /* Converts a number as per strtoull(..., 0) except leading zeros do *not*
530 * imply octal. Instead, decimal is assumed unless the number begins with 0x, 0o or 0b
531 */
532 static jim_wide jim_strtoull(const char *str, char **endptr)
533 {
534 #ifdef HAVE_LONG_LONG
535 int sign;
536 int base;
537 int i = JimNumberBase(str, &base, &sign);
538
539 if (base != 10) {
540 jim_wide value = strtoull(str + i, endptr, base);
541 if (endptr == NULL || *endptr != str + i) {
542 return value * sign;
543 }
544 }
545
546 /* Can just do a regular base-10 conversion */
547 return strtoull(str, endptr, 10);
548 #else
549 return (unsigned long)jim_strtol(str, endptr);
550 #endif
551 }
552
553 int Jim_StringToWide(const char *str, jim_wide * widePtr, int base)
554 {
555 char *endptr;
556
557 if (base) {
558 *widePtr = strtoull(str, &endptr, base);
559 }
560 else {
561 *widePtr = jim_strtoull(str, &endptr);
562 }
563
564 return JimCheckConversion(str, endptr);
565 }
566
567 int Jim_StringToDouble(const char *str, double *doublePtr)
568 {
569 char *endptr;
570
571 /* Callers can check for underflow via ERANGE */
572 errno = 0;
573
574 *doublePtr = strtod(str, &endptr);
575
576 return JimCheckConversion(str, endptr);
577 }
578
579 static jim_wide JimPowWide(jim_wide b, jim_wide e)
580 {
581 jim_wide res = 1;
582
583 /* Special cases */
584 if (b == 1) {
585 /* 1 ^ any = 1 */
586 return 1;
587 }
588 if (e < 0) {
589 if (b != -1) {
590 return 0;
591 }
592 /* Only special case is -1 ^ -n
593 * -1^-1 = -1
594 * -1^-2 = 1
595 * i.e. same as +ve n
596 */
597 e = -e;
598 }
599 while (e)
600 {
601 if (e & 1) {
602 res *= b;
603 }
604 e >>= 1;
605 b *= b;
606 }
607 return res;
608 }
609
610 /* -----------------------------------------------------------------------------
611 * Special functions
612 * ---------------------------------------------------------------------------*/
613 #ifdef JIM_DEBUG_PANIC
614 static void JimPanicDump(int condition, const char *fmt, ...)
615 {
616 va_list ap;
617
618 if (!condition) {
619 return;
620 }
621
622 va_start(ap, fmt);
623
624 fprintf(stderr, "\nJIM INTERPRETER PANIC: ");
625 vfprintf(stderr, fmt, ap);
626 fprintf(stderr, "\n\n");
627 va_end(ap);
628
629 #ifdef HAVE_BACKTRACE
630 {
631 void *array[40];
632 int size, i;
633 char **strings;
634
635 size = backtrace(array, 40);
636 strings = backtrace_symbols(array, size);
637 for (i = 0; i < size; i++)
638 fprintf(stderr, "[backtrace] %s\n", strings[i]);
639 fprintf(stderr, "[backtrace] Include the above lines and the output\n");
640 fprintf(stderr, "[backtrace] of 'nm <executable>' in the bug report.\n");
641 }
642 #endif
643
644 exit(1);
645 }
646 #endif
647
648 /* -----------------------------------------------------------------------------
649 * Memory allocation
650 * ---------------------------------------------------------------------------*/
651
652 void *Jim_Alloc(int size)
653 {
654 return size ? malloc(size) : NULL;
655 }
656
657 void Jim_Free(void *ptr)
658 {
659 free(ptr);
660 }
661
662 void *Jim_Realloc(void *ptr, int size)
663 {
664 return realloc(ptr, size);
665 }
666
667 char *Jim_StrDup(const char *s)
668 {
669 return strdup(s);
670 }
671
672 char *Jim_StrDupLen(const char *s, int l)
673 {
674 char *copy = Jim_Alloc(l + 1);
675
676 memcpy(copy, s, l + 1);
677 copy[l] = 0; /* Just to be sure, original could be substring */
678 return copy;
679 }
680
681 /* -----------------------------------------------------------------------------
682 * Time related functions
683 * ---------------------------------------------------------------------------*/
684
685 /* Returns current time in microseconds */
686 static jim_wide JimClock(void)
687 {
688 struct timeval tv;
689
690 gettimeofday(&tv, NULL);
691 return (jim_wide) tv.tv_sec * 1000000 + tv.tv_usec;
692 }
693
694 /* -----------------------------------------------------------------------------
695 * Hash Tables
696 * ---------------------------------------------------------------------------*/
697
698 /* -------------------------- private prototypes ---------------------------- */
699 static void JimExpandHashTableIfNeeded(Jim_HashTable *ht);
700 static unsigned int JimHashTableNextPower(unsigned int size);
701 static Jim_HashEntry *JimInsertHashEntry(Jim_HashTable *ht, const void *key, int replace);
702
703 /* -------------------------- hash functions -------------------------------- */
704
705 /* Thomas Wang's 32 bit Mix Function */
706 unsigned int Jim_IntHashFunction(unsigned int key)
707 {
708 key += ~(key << 15);
709 key ^= (key >> 10);
710 key += (key << 3);
711 key ^= (key >> 6);
712 key += ~(key << 11);
713 key ^= (key >> 16);
714 return key;
715 }
716
717 /* Generic hash function (we are using to multiply by 9 and add the byte
718 * as Tcl) */
719 unsigned int Jim_GenHashFunction(const unsigned char *buf, int len)
720 {
721 unsigned int h = 0;
722
723 while (len--)
724 h += (h << 3) + *buf++;
725 return h;
726 }
727
728 /* ----------------------------- API implementation ------------------------- */
729
730 /* reset a hashtable already initialized */
731 static void JimResetHashTable(Jim_HashTable *ht)
732 {
733 ht->table = NULL;
734 ht->size = 0;
735 ht->sizemask = 0;
736 ht->used = 0;
737 ht->collisions = 0;
738 #ifdef JIM_RANDOMISE_HASH
739 /* This is initialised to a random value to avoid a hash collision attack.
740 * See: n.runs-SA-2011.004
741 */
742 ht->uniq = (rand() ^ time(NULL) ^ clock());
743 #else
744 ht->uniq = 0;
745 #endif
746 }
747
748 static void JimInitHashTableIterator(Jim_HashTable *ht, Jim_HashTableIterator *iter)
749 {
750 iter->ht = ht;
751 iter->index = -1;
752 iter->entry = NULL;
753 iter->nextEntry = NULL;
754 }
755
756 /* Initialize the hash table */
757 int Jim_InitHashTable(Jim_HashTable *ht, const Jim_HashTableType *type, void *privDataPtr)
758 {
759 JimResetHashTable(ht);
760 ht->type = type;
761 ht->privdata = privDataPtr;
762 return JIM_OK;
763 }
764
765 /* Resize the table to the minimal size that contains all the elements,
766 * but with the invariant of a USER/BUCKETS ration near to <= 1 */
767 void Jim_ResizeHashTable(Jim_HashTable *ht)
768 {
769 int minimal = ht->used;
770
771 if (minimal < JIM_HT_INITIAL_SIZE)
772 minimal = JIM_HT_INITIAL_SIZE;
773 Jim_ExpandHashTable(ht, minimal);
774 }
775
776 /* Expand or create the hashtable */
777 void Jim_ExpandHashTable(Jim_HashTable *ht, unsigned int size)
778 {
779 Jim_HashTable n; /* the new hashtable */
780 unsigned int realsize = JimHashTableNextPower(size), i;
781
782 /* the size is invalid if it is smaller than the number of
783 * elements already inside the hashtable */
784 if (size <= ht->used)
785 return;
786
787 Jim_InitHashTable(&n, ht->type, ht->privdata);
788 n.size = realsize;
789 n.sizemask = realsize - 1;
790 n.table = Jim_Alloc(realsize * sizeof(Jim_HashEntry *));
791 /* Keep the same 'uniq' as the original */
792 n.uniq = ht->uniq;
793
794 /* Initialize all the pointers to NULL */
795 memset(n.table, 0, realsize * sizeof(Jim_HashEntry *));
796
797 /* Copy all the elements from the old to the new table:
798 * note that if the old hash table is empty ht->used is zero,
799 * so Jim_ExpandHashTable just creates an empty hash table. */
800 n.used = ht->used;
801 for (i = 0; ht->used > 0; i++) {
802 Jim_HashEntry *he, *nextHe;
803
804 if (ht->table[i] == NULL)
805 continue;
806
807 /* For each hash entry on this slot... */
808 he = ht->table[i];
809 while (he) {
810 unsigned int h;
811
812 nextHe = he->next;
813 /* Get the new element index */
814 h = Jim_HashKey(ht, he->key) & n.sizemask;
815 he->next = n.table[h];
816 n.table[h] = he;
817 ht->used--;
818 /* Pass to the next element */
819 he = nextHe;
820 }
821 }
822 assert(ht->used == 0);
823 Jim_Free(ht->table);
824
825 /* Remap the new hashtable in the old */
826 *ht = n;
827 }
828
829 /* Add an element to the target hash table */
830 int Jim_AddHashEntry(Jim_HashTable *ht, const void *key, void *val)
831 {
832 Jim_HashEntry *entry;
833
834 /* Get the index of the new element, or -1 if
835 * the element already exists. */
836 entry = JimInsertHashEntry(ht, key, 0);
837 if (entry == NULL)
838 return JIM_ERR;
839
840 /* Set the hash entry fields. */
841 Jim_SetHashKey(ht, entry, key);
842 Jim_SetHashVal(ht, entry, val);
843 return JIM_OK;
844 }
845
846 /* Add an element, discarding the old if the key already exists */
847 int Jim_ReplaceHashEntry(Jim_HashTable *ht, const void *key, void *val)
848 {
849 int existed;
850 Jim_HashEntry *entry;
851
852 /* Get the index of the new element, or -1 if
853 * the element already exists. */
854 entry = JimInsertHashEntry(ht, key, 1);
855 if (entry->key) {
856 /* It already exists, so only replace the value.
857 * Note if both a destructor and a duplicate function exist,
858 * need to dup before destroy. perhaps they are the same
859 * reference counted object
860 */
861 if (ht->type->valDestructor && ht->type->valDup) {
862 void *newval = ht->type->valDup(ht->privdata, val);
863 ht->type->valDestructor(ht->privdata, entry->u.val);
864 entry->u.val = newval;
865 }
866 else {
867 Jim_FreeEntryVal(ht, entry);
868 Jim_SetHashVal(ht, entry, val);
869 }
870 existed = 1;
871 }
872 else {
873 /* Doesn't exist, so set the key */
874 Jim_SetHashKey(ht, entry, key);
875 Jim_SetHashVal(ht, entry, val);
876 existed = 0;
877 }
878
879 return existed;
880 }
881
882 /* Search and remove an element */
883 int Jim_DeleteHashEntry(Jim_HashTable *ht, const void *key)
884 {
885 unsigned int h;
886 Jim_HashEntry *he, *prevHe;
887
888 if (ht->used == 0)
889 return JIM_ERR;
890 h = Jim_HashKey(ht, key) & ht->sizemask;
891 he = ht->table[h];
892
893 prevHe = NULL;
894 while (he) {
895 if (Jim_CompareHashKeys(ht, key, he->key)) {
896 /* Unlink the element from the list */
897 if (prevHe)
898 prevHe->next = he->next;
899 else
900 ht->table[h] = he->next;
901 Jim_FreeEntryKey(ht, he);
902 Jim_FreeEntryVal(ht, he);
903 Jim_Free(he);
904 ht->used--;
905 return JIM_OK;
906 }
907 prevHe = he;
908 he = he->next;
909 }
910 return JIM_ERR; /* not found */
911 }
912
913 /* Destroy an entire hash table and leave it ready for reuse */
914 int Jim_FreeHashTable(Jim_HashTable *ht)
915 {
916 unsigned int i;
917
918 /* Free all the elements */
919 for (i = 0; ht->used > 0; i++) {
920 Jim_HashEntry *he, *nextHe;
921
922 if ((he = ht->table[i]) == NULL)
923 continue;
924 while (he) {
925 nextHe = he->next;
926 Jim_FreeEntryKey(ht, he);
927 Jim_FreeEntryVal(ht, he);
928 Jim_Free(he);
929 ht->used--;
930 he = nextHe;
931 }
932 }
933 /* Free the table and the allocated cache structure */
934 Jim_Free(ht->table);
935 /* Re-initialize the table */
936 JimResetHashTable(ht);
937 return JIM_OK; /* never fails */
938 }
939
940 Jim_HashEntry *Jim_FindHashEntry(Jim_HashTable *ht, const void *key)
941 {
942 Jim_HashEntry *he;
943 unsigned int h;
944
945 if (ht->used == 0)
946 return NULL;
947 h = Jim_HashKey(ht, key) & ht->sizemask;
948 he = ht->table[h];
949 while (he) {
950 if (Jim_CompareHashKeys(ht, key, he->key))
951 return he;
952 he = he->next;
953 }
954 return NULL;
955 }
956
957 Jim_HashTableIterator *Jim_GetHashTableIterator(Jim_HashTable *ht)
958 {
959 Jim_HashTableIterator *iter = Jim_Alloc(sizeof(*iter));
960 JimInitHashTableIterator(ht, iter);
961 return iter;
962 }
963
964 Jim_HashEntry *Jim_NextHashEntry(Jim_HashTableIterator *iter)
965 {
966 while (1) {
967 if (iter->entry == NULL) {
968 iter->index++;
969 if (iter->index >= (signed)iter->ht->size)
970 break;
971 iter->entry = iter->ht->table[iter->index];
972 }
973 else {
974 iter->entry = iter->nextEntry;
975 }
976 if (iter->entry) {
977 /* We need to save the 'next' here, the iterator user
978 * may delete the entry we are returning. */
979 iter->nextEntry = iter->entry->next;
980 return iter->entry;
981 }
982 }
983 return NULL;
984 }
985
986 /* ------------------------- private functions ------------------------------ */
987
988 /* Expand the hash table if needed */
989 static void JimExpandHashTableIfNeeded(Jim_HashTable *ht)
990 {
991 /* If the hash table is empty expand it to the intial size,
992 * if the table is "full" double its size. */
993 if (ht->size == 0)
994 Jim_ExpandHashTable(ht, JIM_HT_INITIAL_SIZE);
995 if (ht->size == ht->used)
996 Jim_ExpandHashTable(ht, ht->size * 2);
997 }
998
999 /* Our hash table capability is a power of two */
1000 static unsigned int JimHashTableNextPower(unsigned int size)
1001 {
1002 unsigned int i = JIM_HT_INITIAL_SIZE;
1003
1004 if (size >= 2147483648U)
1005 return 2147483648U;
1006 while (1) {
1007 if (i >= size)
1008 return i;
1009 i *= 2;
1010 }
1011 }
1012
1013 /* Returns the index of a free slot that can be populated with
1014 * a hash entry for the given 'key'.
1015 * If the key already exists, -1 is returned. */
1016 static Jim_HashEntry *JimInsertHashEntry(Jim_HashTable *ht, const void *key, int replace)
1017 {
1018 unsigned int h;
1019 Jim_HashEntry *he;
1020
1021 /* Expand the hashtable if needed */
1022 JimExpandHashTableIfNeeded(ht);
1023
1024 /* Compute the key hash value */
1025 h = Jim_HashKey(ht, key) & ht->sizemask;
1026 /* Search if this slot does not already contain the given key */
1027 he = ht->table[h];
1028 while (he) {
1029 if (Jim_CompareHashKeys(ht, key, he->key))
1030 return replace ? he : NULL;
1031 he = he->next;
1032 }
1033
1034 /* Allocates the memory and stores key */
1035 he = Jim_Alloc(sizeof(*he));
1036 he->next = ht->table[h];
1037 ht->table[h] = he;
1038 ht->used++;
1039 he->key = NULL;
1040
1041 return he;
1042 }
1043
1044 /* ----------------------- StringCopy Hash Table Type ------------------------*/
1045
1046 static unsigned int JimStringCopyHTHashFunction(const void *key)
1047 {
1048 return Jim_GenHashFunction(key, strlen(key));
1049 }
1050
1051 static void *JimStringCopyHTDup(void *privdata, const void *key)
1052 {
1053 return Jim_StrDup(key);
1054 }
1055
1056 static int JimStringCopyHTKeyCompare(void *privdata, const void *key1, const void *key2)
1057 {
1058 return strcmp(key1, key2) == 0;
1059 }
1060
1061 static void JimStringCopyHTKeyDestructor(void *privdata, void *key)
1062 {
1063 Jim_Free(key);
1064 }
1065
1066 static const Jim_HashTableType JimPackageHashTableType = {
1067 JimStringCopyHTHashFunction, /* hash function */
1068 JimStringCopyHTDup, /* key dup */
1069 NULL, /* val dup */
1070 JimStringCopyHTKeyCompare, /* key compare */
1071 JimStringCopyHTKeyDestructor, /* key destructor */
1072 NULL /* val destructor */
1073 };
1074
1075 typedef struct AssocDataValue
1076 {
1077 Jim_InterpDeleteProc *delProc;
1078 void *data;
1079 } AssocDataValue;
1080
1081 static void JimAssocDataHashTableValueDestructor(void *privdata, void *data)
1082 {
1083 AssocDataValue *assocPtr = (AssocDataValue *) data;
1084
1085 if (assocPtr->delProc != NULL)
1086 assocPtr->delProc((Jim_Interp *)privdata, assocPtr->data);
1087 Jim_Free(data);
1088 }
1089
1090 static const Jim_HashTableType JimAssocDataHashTableType = {
1091 JimStringCopyHTHashFunction, /* hash function */
1092 JimStringCopyHTDup, /* key dup */
1093 NULL, /* val dup */
1094 JimStringCopyHTKeyCompare, /* key compare */
1095 JimStringCopyHTKeyDestructor, /* key destructor */
1096 JimAssocDataHashTableValueDestructor /* val destructor */
1097 };
1098
1099 /* -----------------------------------------------------------------------------
1100 * Stack - This is a simple generic stack implementation. It is used for
1101 * example in the 'expr' expression compiler.
1102 * ---------------------------------------------------------------------------*/
1103 void Jim_InitStack(Jim_Stack *stack)
1104 {
1105 stack->len = 0;
1106 stack->maxlen = 0;
1107 stack->vector = NULL;
1108 }
1109
1110 void Jim_FreeStack(Jim_Stack *stack)
1111 {
1112 Jim_Free(stack->vector);
1113 }
1114
1115 int Jim_StackLen(Jim_Stack *stack)
1116 {
1117 return stack->len;
1118 }
1119
1120 void Jim_StackPush(Jim_Stack *stack, void *element)
1121 {
1122 int neededLen = stack->len + 1;
1123
1124 if (neededLen > stack->maxlen) {
1125 stack->maxlen = neededLen < 20 ? 20 : neededLen * 2;
1126 stack->vector = Jim_Realloc(stack->vector, sizeof(void *) * stack->maxlen);
1127 }
1128 stack->vector[stack->len] = element;
1129 stack->len++;
1130 }
1131
1132 void *Jim_StackPop(Jim_Stack *stack)
1133 {
1134 if (stack->len == 0)
1135 return NULL;
1136 stack->len--;
1137 return stack->vector[stack->len];
1138 }
1139
1140 void *Jim_StackPeek(Jim_Stack *stack)
1141 {
1142 if (stack->len == 0)
1143 return NULL;
1144 return stack->vector[stack->len - 1];
1145 }
1146
1147 void Jim_FreeStackElements(Jim_Stack *stack, void (*freeFunc) (void *ptr))
1148 {
1149 int i;
1150
1151 for (i = 0; i < stack->len; i++)
1152 freeFunc(stack->vector[i]);
1153 }
1154
1155 /* -----------------------------------------------------------------------------
1156 * Tcl Parser
1157 * ---------------------------------------------------------------------------*/
1158
1159 /* Token types */
1160 #define JIM_TT_NONE 0 /* No token returned */
1161 #define JIM_TT_STR 1 /* simple string */
1162 #define JIM_TT_ESC 2 /* string that needs escape chars conversion */
1163 #define JIM_TT_VAR 3 /* var substitution */
1164 #define JIM_TT_DICTSUGAR 4 /* Syntax sugar for [dict get], $foo(bar) */
1165 #define JIM_TT_CMD 5 /* command substitution */
1166 /* Note: Keep these three together for TOKEN_IS_SEP() */
1167 #define JIM_TT_SEP 6 /* word separator (white space) */
1168 #define JIM_TT_EOL 7 /* line separator */
1169 #define JIM_TT_EOF 8 /* end of script */
1170
1171 #define JIM_TT_LINE 9 /* special 'start-of-line' token. arg is # of arguments to the command. -ve if {*} */
1172 #define JIM_TT_WORD 10 /* special 'start-of-word' token. arg is # of tokens to combine. -ve if {*} */
1173
1174 /* Additional token types needed for expressions */
1175 #define JIM_TT_SUBEXPR_START 11
1176 #define JIM_TT_SUBEXPR_END 12
1177 #define JIM_TT_SUBEXPR_COMMA 13
1178 #define JIM_TT_EXPR_INT 14
1179 #define JIM_TT_EXPR_DOUBLE 15
1180 #define JIM_TT_EXPR_BOOLEAN 16
1181
1182 #define JIM_TT_EXPRSUGAR 17 /* $(expression) */
1183
1184 /* Operator token types start here */
1185 #define JIM_TT_EXPR_OP 20
1186
1187 #define TOKEN_IS_SEP(type) (type >= JIM_TT_SEP && type <= JIM_TT_EOF)
1188 /* Can this token start an expression? */
1189 #define TOKEN_IS_EXPR_START(type) (type == JIM_TT_NONE || type == JIM_TT_SUBEXPR_START || type == JIM_TT_SUBEXPR_COMMA)
1190 /* Is this token an expression operator? */
1191 #define TOKEN_IS_EXPR_OP(type) (type >= JIM_TT_EXPR_OP)
1192
1193 /**
1194 * Results of missing quotes, braces, etc. from parsing.
1195 */
1196 struct JimParseMissing {
1197 int ch; /* At end of parse, ' ' if complete or '{', '[', '"', '\\', '}' if incomplete */
1198 int line; /* Line number starting the missing token */
1199 };
1200
1201 /* Parser context structure. The same context is used to parse
1202 * Tcl scripts, expressions and lists. */
1203 struct JimParserCtx
1204 {
1205 const char *p; /* Pointer to the point of the program we are parsing */
1206 int len; /* Remaining length */
1207 int linenr; /* Current line number */
1208 const char *tstart;
1209 const char *tend; /* Returned token is at tstart-tend in 'prg'. */
1210 int tline; /* Line number of the returned token */
1211 int tt; /* Token type */
1212 int eof; /* Non zero if EOF condition is true. */
1213 int inquote; /* Parsing a quoted string */
1214 int comment; /* Non zero if the next chars may be a comment. */
1215 struct JimParseMissing missing; /* Details of any missing quotes, etc. */
1216 };
1217
1218 static int JimParseScript(struct JimParserCtx *pc);
1219 static int JimParseSep(struct JimParserCtx *pc);
1220 static int JimParseEol(struct JimParserCtx *pc);
1221 static int JimParseCmd(struct JimParserCtx *pc);
1222 static int JimParseQuote(struct JimParserCtx *pc);
1223 static int JimParseVar(struct JimParserCtx *pc);
1224 static int JimParseBrace(struct JimParserCtx *pc);
1225 static int JimParseStr(struct JimParserCtx *pc);
1226 static int JimParseComment(struct JimParserCtx *pc);
1227 static void JimParseSubCmd(struct JimParserCtx *pc);
1228 static int JimParseSubQuote(struct JimParserCtx *pc);
1229 static Jim_Obj *JimParserGetTokenObj(Jim_Interp *interp, struct JimParserCtx *pc);
1230
1231 /* Initialize a parser context.
1232 * 'prg' is a pointer to the program text, linenr is the line
1233 * number of the first line contained in the program. */
1234 static void JimParserInit(struct JimParserCtx *pc, const char *prg, int len, int linenr)
1235 {
1236 pc->p = prg;
1237 pc->len = len;
1238 pc->tstart = NULL;
1239 pc->tend = NULL;
1240 pc->tline = 0;
1241 pc->tt = JIM_TT_NONE;
1242 pc->eof = 0;
1243 pc->inquote = 0;
1244 pc->linenr = linenr;
1245 pc->comment = 1;
1246 pc->missing.ch = ' ';
1247 pc->missing.line = linenr;
1248 }
1249
1250 static int JimParseScript(struct JimParserCtx *pc)
1251 {
1252 while (1) { /* the while is used to reiterate with continue if needed */
1253 if (!pc->len) {
1254 pc->tstart = pc->p;
1255 pc->tend = pc->p - 1;
1256 pc->tline = pc->linenr;
1257 pc->tt = JIM_TT_EOL;
1258 pc->eof = 1;
1259 return JIM_OK;
1260 }
1261 switch (*(pc->p)) {
1262 case '\\':
1263 if (*(pc->p + 1) == '\n' && !pc->inquote) {
1264 return JimParseSep(pc);
1265 }
1266 pc->comment = 0;
1267 return JimParseStr(pc);
1268 case ' ':
1269 case '\t':
1270 case '\r':
1271 case '\f':
1272 if (!pc->inquote)
1273 return JimParseSep(pc);
1274 pc->comment = 0;
1275 return JimParseStr(pc);
1276 case '\n':
1277 case ';':
1278 pc->comment = 1;
1279 if (!pc->inquote)
1280 return JimParseEol(pc);
1281 return JimParseStr(pc);
1282 case '[':
1283 pc->comment = 0;
1284 return JimParseCmd(pc);
1285 case '$':
1286 pc->comment = 0;
1287 if (JimParseVar(pc) == JIM_ERR) {
1288 /* An orphan $. Create as a separate token */
1289 pc->tstart = pc->tend = pc->p++;
1290 pc->len--;
1291 pc->tt = JIM_TT_ESC;
1292 }
1293 return JIM_OK;
1294 case '#':
1295 if (pc->comment) {
1296 JimParseComment(pc);
1297 continue;
1298 }
1299 return JimParseStr(pc);
1300 default:
1301 pc->comment = 0;
1302 return JimParseStr(pc);
1303 }
1304 return JIM_OK;
1305 }
1306 }
1307
1308 static int JimParseSep(struct JimParserCtx *pc)
1309 {
1310 pc->tstart = pc->p;
1311 pc->tline = pc->linenr;
1312 while (isspace(UCHAR(*pc->p)) || (*pc->p == '\\' && *(pc->p + 1) == '\n')) {
1313 if (*pc->p == '\n') {
1314 break;
1315 }
1316 if (*pc->p == '\\') {
1317 pc->p++;
1318 pc->len--;
1319 pc->linenr++;
1320 }
1321 pc->p++;
1322 pc->len--;
1323 }
1324 pc->tend = pc->p - 1;
1325 pc->tt = JIM_TT_SEP;
1326 return JIM_OK;
1327 }
1328
1329 static int JimParseEol(struct JimParserCtx *pc)
1330 {
1331 pc->tstart = pc->p;
1332 pc->tline = pc->linenr;
1333 while (isspace(UCHAR(*pc->p)) || *pc->p == ';') {
1334 if (*pc->p == '\n')
1335 pc->linenr++;
1336 pc->p++;
1337 pc->len--;
1338 }
1339 pc->tend = pc->p - 1;
1340 pc->tt = JIM_TT_EOL;
1341 return JIM_OK;
1342 }
1343
1344 /*
1345 ** Here are the rules for parsing:
1346 ** {braced expression}
1347 ** - Count open and closing braces
1348 ** - Backslash escapes meaning of braces but doesn't remove the backslash
1349 **
1350 ** "quoted expression"
1351 ** - Unescaped double quote terminates the expression
1352 ** - Backslash escapes next char
1353 ** - [commands brackets] are counted/nested
1354 ** - command rules apply within [brackets], not quoting rules (i.e. brackets have their own rules)
1355 **
1356 ** [command expression]
1357 ** - Count open and closing brackets
1358 ** - Backslash escapes next char
1359 ** - [commands brackets] are counted/nested
1360 ** - "quoted expressions" are parsed according to quoting rules
1361 ** - {braced expressions} are parsed according to brace rules
1362 **
1363 ** For everything, backslash escapes the next char, newline increments current line
1364 */
1365
1366 /**
1367 * Parses a braced expression starting at pc->p.
1368 *
1369 * Positions the parser at the end of the braced expression,
1370 * sets pc->tend and possibly pc->missing.
1371 */
1372 static void JimParseSubBrace(struct JimParserCtx *pc)
1373 {
1374 int level = 1;
1375
1376 /* Skip the brace */
1377 pc->p++;
1378 pc->len--;
1379 while (pc->len) {
1380 switch (*pc->p) {
1381 case '\\':
1382 if (pc->len > 1) {
1383 if (*++pc->p == '\n') {
1384 pc->linenr++;
1385 }
1386 pc->len--;
1387 }
1388 break;
1389
1390 case '{':
1391 level++;
1392 break;
1393
1394 case '}':
1395 if (--level == 0) {
1396 pc->tend = pc->p - 1;
1397 pc->p++;
1398 pc->len--;
1399 return;
1400 }
1401 break;
1402
1403 case '\n':
1404 pc->linenr++;
1405 break;
1406 }
1407 pc->p++;
1408 pc->len--;
1409 }
1410 pc->missing.ch = '{';
1411 pc->missing.line = pc->tline;
1412 pc->tend = pc->p - 1;
1413 }
1414
1415 /**
1416 * Parses a quoted expression starting at pc->p.
1417 *
1418 * Positions the parser at the end of the quoted expression,
1419 * sets pc->tend and possibly pc->missing.
1420 *
1421 * Returns the type of the token of the string,
1422 * either JIM_TT_ESC (if it contains values which need to be [subst]ed)
1423 * or JIM_TT_STR.
1424 */
1425 static int JimParseSubQuote(struct JimParserCtx *pc)
1426 {
1427 int tt = JIM_TT_STR;
1428 int line = pc->tline;
1429
1430 /* Skip the quote */
1431 pc->p++;
1432 pc->len--;
1433 while (pc->len) {
1434 switch (*pc->p) {
1435 case '\\':
1436 if (pc->len > 1) {
1437 if (*++pc->p == '\n') {
1438 pc->linenr++;
1439 }
1440 pc->len--;
1441 tt = JIM_TT_ESC;
1442 }
1443 break;
1444
1445 case '"':
1446 pc->tend = pc->p - 1;
1447 pc->p++;
1448 pc->len--;
1449 return tt;
1450
1451 case '[':
1452 JimParseSubCmd(pc);
1453 tt = JIM_TT_ESC;
1454 continue;
1455
1456 case '\n':
1457 pc->linenr++;
1458 break;
1459
1460 case '$':
1461 tt = JIM_TT_ESC;
1462 break;
1463 }
1464 pc->p++;
1465 pc->len--;
1466 }
1467 pc->missing.ch = '"';
1468 pc->missing.line = line;
1469 pc->tend = pc->p - 1;
1470 return tt;
1471 }
1472
1473 /**
1474 * Parses a [command] expression starting at pc->p.
1475 *
1476 * Positions the parser at the end of the command expression,
1477 * sets pc->tend and possibly pc->missing.
1478 */
1479 static void JimParseSubCmd(struct JimParserCtx *pc)
1480 {
1481 int level = 1;
1482 int startofword = 1;
1483 int line = pc->tline;
1484
1485 /* Skip the bracket */
1486 pc->p++;
1487 pc->len--;
1488 while (pc->len) {
1489 switch (*pc->p) {
1490 case '\\':
1491 if (pc->len > 1) {
1492 if (*++pc->p == '\n') {
1493 pc->linenr++;
1494 }
1495 pc->len--;
1496 }
1497 break;
1498
1499 case '[':
1500 level++;
1501 break;
1502
1503 case ']':
1504 if (--level == 0) {
1505 pc->tend = pc->p - 1;
1506 pc->p++;
1507 pc->len--;
1508 return;
1509 }
1510 break;
1511
1512 case '"':
1513 if (startofword) {
1514 JimParseSubQuote(pc);
1515 continue;
1516 }
1517 break;
1518
1519 case '{':
1520 JimParseSubBrace(pc);
1521 startofword = 0;
1522 continue;
1523
1524 case '\n':
1525 pc->linenr++;
1526 break;
1527 }
1528 startofword = isspace(UCHAR(*pc->p));
1529 pc->p++;
1530 pc->len--;
1531 }
1532 pc->missing.ch = '[';
1533 pc->missing.line = line;
1534 pc->tend = pc->p - 1;
1535 }
1536
1537 static int JimParseBrace(struct JimParserCtx *pc)
1538 {
1539 pc->tstart = pc->p + 1;
1540 pc->tline = pc->linenr;
1541 pc->tt = JIM_TT_STR;
1542 JimParseSubBrace(pc);
1543 return JIM_OK;
1544 }
1545
1546 static int JimParseCmd(struct JimParserCtx *pc)
1547 {
1548 pc->tstart = pc->p + 1;
1549 pc->tline = pc->linenr;
1550 pc->tt = JIM_TT_CMD;
1551 JimParseSubCmd(pc);
1552 return JIM_OK;
1553 }
1554
1555 static int JimParseQuote(struct JimParserCtx *pc)
1556 {
1557 pc->tstart = pc->p + 1;
1558 pc->tline = pc->linenr;
1559 pc->tt = JimParseSubQuote(pc);
1560 return JIM_OK;
1561 }
1562
1563 static int JimParseVar(struct JimParserCtx *pc)
1564 {
1565 /* skip the $ */
1566 pc->p++;
1567 pc->len--;
1568
1569 #ifdef EXPRSUGAR_BRACKET
1570 if (*pc->p == '[') {
1571 /* Parse $[...] expr shorthand syntax */
1572 JimParseCmd(pc);
1573 pc->tt = JIM_TT_EXPRSUGAR;
1574 return JIM_OK;
1575 }
1576 #endif
1577
1578 pc->tstart = pc->p;
1579 pc->tt = JIM_TT_VAR;
1580 pc->tline = pc->linenr;
1581
1582 if (*pc->p == '{') {
1583 pc->tstart = ++pc->p;
1584 pc->len--;
1585
1586 while (pc->len && *pc->p != '}') {
1587 if (*pc->p == '\n') {
1588 pc->linenr++;
1589 }
1590 pc->p++;
1591 pc->len--;
1592 }
1593 pc->tend = pc->p - 1;
1594 if (pc->len) {
1595 pc->p++;
1596 pc->len--;
1597 }
1598 }
1599 else {
1600 while (1) {
1601 /* Skip double colon, but not single colon! */
1602 if (pc->p[0] == ':' && pc->p[1] == ':') {
1603 while (*pc->p == ':') {
1604 pc->p++;
1605 pc->len--;
1606 }
1607 continue;
1608 }
1609 /* Note that any char >= 0x80 must be part of a utf-8 char.
1610 * We consider all unicode points outside of ASCII as letters
1611 */
1612 if (isalnum(UCHAR(*pc->p)) || *pc->p == '_' || UCHAR(*pc->p) >= 0x80) {
1613 pc->p++;
1614 pc->len--;
1615 continue;
1616 }
1617 break;
1618 }
1619 /* Parse [dict get] syntax sugar. */
1620 if (*pc->p == '(') {
1621 int count = 1;
1622 const char *paren = NULL;
1623
1624 pc->tt = JIM_TT_DICTSUGAR;
1625
1626 while (count && pc->len) {
1627 pc->p++;
1628 pc->len--;
1629 if (*pc->p == '\\' && pc->len >= 1) {
1630 pc->p++;
1631 pc->len--;
1632 }
1633 else if (*pc->p == '(') {
1634 count++;
1635 }
1636 else if (*pc->p == ')') {
1637 paren = pc->p;
1638 count--;
1639 }
1640 }
1641 if (count == 0) {
1642 pc->p++;
1643 pc->len--;
1644 }
1645 else if (paren) {
1646 /* Did not find a matching paren. Back up */
1647 paren++;
1648 pc->len += (pc->p - paren);
1649 pc->p = paren;
1650 }
1651 #ifndef EXPRSUGAR_BRACKET
1652 if (*pc->tstart == '(') {
1653 pc->tt = JIM_TT_EXPRSUGAR;
1654 }
1655 #endif
1656 }
1657 pc->tend = pc->p - 1;
1658 }
1659 /* Check if we parsed just the '$' character.
1660 * That's not a variable so an error is returned
1661 * to tell the state machine to consider this '$' just
1662 * a string. */
1663 if (pc->tstart == pc->p) {
1664 pc->p--;
1665 pc->len++;
1666 return JIM_ERR;
1667 }
1668 return JIM_OK;
1669 }
1670
1671 static int JimParseStr(struct JimParserCtx *pc)
1672 {
1673 if (pc->tt == JIM_TT_SEP || pc->tt == JIM_TT_EOL ||
1674 pc->tt == JIM_TT_NONE || pc->tt == JIM_TT_STR) {
1675 /* Starting a new word */
1676 if (*pc->p == '{') {
1677 return JimParseBrace(pc);
1678 }
1679 if (*pc->p == '"') {
1680 pc->inquote = 1;
1681 pc->p++;
1682 pc->len--;
1683 /* In case the end quote is missing */
1684 pc->missing.line = pc->tline;
1685 }
1686 }
1687 pc->tstart = pc->p;
1688 pc->tline = pc->linenr;
1689 while (1) {
1690 if (pc->len == 0) {
1691 if (pc->inquote) {
1692 pc->missing.ch = '"';
1693 }
1694 pc->tend = pc->p - 1;
1695 pc->tt = JIM_TT_ESC;
1696 return JIM_OK;
1697 }
1698 switch (*pc->p) {
1699 case '\\':
1700 if (!pc->inquote && *(pc->p + 1) == '\n') {
1701 pc->tend = pc->p - 1;
1702 pc->tt = JIM_TT_ESC;
1703 return JIM_OK;
1704 }
1705 if (pc->len >= 2) {
1706 if (*(pc->p + 1) == '\n') {
1707 pc->linenr++;
1708 }
1709 pc->p++;
1710 pc->len--;
1711 }
1712 else if (pc->len == 1) {
1713 /* End of script with trailing backslash */
1714 pc->missing.ch = '\\';
1715 }
1716 break;
1717 case '(':
1718 /* If the following token is not '$' just keep going */
1719 if (pc->len > 1 && pc->p[1] != '$') {
1720 break;
1721 }
1722 /* fall through */
1723 case ')':
1724 /* Only need a separate ')' token if the previous was a var */
1725 if (*pc->p == '(' || pc->tt == JIM_TT_VAR) {
1726 if (pc->p == pc->tstart) {
1727 /* At the start of the token, so just return this char */
1728 pc->p++;
1729 pc->len--;
1730 }
1731 pc->tend = pc->p - 1;
1732 pc->tt = JIM_TT_ESC;
1733 return JIM_OK;
1734 }
1735 break;
1736
1737 case '$':
1738 case '[':
1739 pc->tend = pc->p - 1;
1740 pc->tt = JIM_TT_ESC;
1741 return JIM_OK;
1742 case ' ':
1743 case '\t':
1744 case '\n':
1745 case '\r':
1746 case '\f':
1747 case ';':
1748 if (!pc->inquote) {
1749 pc->tend = pc->p - 1;
1750 pc->tt = JIM_TT_ESC;
1751 return JIM_OK;
1752 }
1753 else if (*pc->p == '\n') {
1754 pc->linenr++;
1755 }
1756 break;
1757 case '"':
1758 if (pc->inquote) {
1759 pc->tend = pc->p - 1;
1760 pc->tt = JIM_TT_ESC;
1761 pc->p++;
1762 pc->len--;
1763 pc->inquote = 0;
1764 return JIM_OK;
1765 }
1766 break;
1767 }
1768 pc->p++;
1769 pc->len--;
1770 }
1771 return JIM_OK; /* unreached */
1772 }
1773
1774 static int JimParseComment(struct JimParserCtx *pc)
1775 {
1776 while (*pc->p) {
1777 if (*pc->p == '\\') {
1778 pc->p++;
1779 pc->len--;
1780 if (pc->len == 0) {
1781 pc->missing.ch = '\\';
1782 return JIM_OK;
1783 }
1784 if (*pc->p == '\n') {
1785 pc->linenr++;
1786 }
1787 }
1788 else if (*pc->p == '\n') {
1789 pc->p++;
1790 pc->len--;
1791 pc->linenr++;
1792 break;
1793 }
1794 pc->p++;
1795 pc->len--;
1796 }
1797 return JIM_OK;
1798 }
1799
1800 /* xdigitval and odigitval are helper functions for JimEscape() */
1801 static int xdigitval(int c)
1802 {
1803 if (c >= '0' && c <= '9')
1804 return c - '0';
1805 if (c >= 'a' && c <= 'f')
1806 return c - 'a' + 10;
1807 if (c >= 'A' && c <= 'F')
1808 return c - 'A' + 10;
1809 return -1;
1810 }
1811
1812 static int odigitval(int c)
1813 {
1814 if (c >= '0' && c <= '7')
1815 return c - '0';
1816 return -1;
1817 }
1818
1819 /* Perform Tcl escape substitution of 's', storing the result
1820 * string into 'dest'. The escaped string is guaranteed to
1821 * be the same length or shorter than the source string.
1822 * slen is the length of the string at 's'.
1823 *
1824 * The function returns the length of the resulting string. */
1825 static int JimEscape(char *dest, const char *s, int slen)
1826 {
1827 char *p = dest;
1828 int i, len;
1829
1830 for (i = 0; i < slen; i++) {
1831 switch (s[i]) {
1832 case '\\':
1833 switch (s[i + 1]) {
1834 case 'a':
1835 *p++ = 0x7;
1836 i++;
1837 break;
1838 case 'b':
1839 *p++ = 0x8;
1840 i++;
1841 break;
1842 case 'f':
1843 *p++ = 0xc;
1844 i++;
1845 break;
1846 case 'n':
1847 *p++ = 0xa;
1848 i++;
1849 break;
1850 case 'r':
1851 *p++ = 0xd;
1852 i++;
1853 break;
1854 case 't':
1855 *p++ = 0x9;
1856 i++;
1857 break;
1858 case 'u':
1859 case 'U':
1860 case 'x':
1861 /* A unicode or hex sequence.
1862 * \x Expect 1-2 hex chars and convert to hex.
1863 * \u Expect 1-4 hex chars and convert to utf-8.
1864 * \U Expect 1-8 hex chars and convert to utf-8.
1865 * \u{NNN} supports 1-6 hex chars and convert to utf-8.
1866 * An invalid sequence means simply the escaped char.
1867 */
1868 {
1869 unsigned val = 0;
1870 int k;
1871 int maxchars = 2;
1872
1873 i++;
1874
1875 if (s[i] == 'U') {
1876 maxchars = 8;
1877 }
1878 else if (s[i] == 'u') {
1879 if (s[i + 1] == '{') {
1880 maxchars = 6;
1881 i++;
1882 }
1883 else {
1884 maxchars = 4;
1885 }
1886 }
1887
1888 for (k = 0; k < maxchars; k++) {
1889 int c = xdigitval(s[i + k + 1]);
1890 if (c == -1) {
1891 break;
1892 }
1893 val = (val << 4) | c;
1894 }
1895 /* The \u{nnn} syntax supports up to 21 bit codepoints. */
1896 if (s[i] == '{') {
1897 if (k == 0 || val > 0x1fffff || s[i + k + 1] != '}') {
1898 /* Back up */
1899 i--;
1900 k = 0;
1901 }
1902 else {
1903 /* Skip the closing brace */
1904 k++;
1905 }
1906 }
1907 if (k) {
1908 /* Got a valid sequence, so convert */
1909 if (s[i] == 'x') {
1910 *p++ = val;
1911 }
1912 else {
1913 p += utf8_fromunicode(p, val);
1914 }
1915 i += k;
1916 break;
1917 }
1918 /* Not a valid codepoint, just an escaped char */
1919 *p++ = s[i];
1920 }
1921 break;
1922 case 'v':
1923 *p++ = 0xb;
1924 i++;
1925 break;
1926 case '\0':
1927 *p++ = '\\';
1928 i++;
1929 break;
1930 case '\n':
1931 /* Replace all spaces and tabs after backslash newline with a single space*/
1932 *p++ = ' ';
1933 do {
1934 i++;
1935 } while (s[i + 1] == ' ' || s[i + 1] == '\t');
1936 break;
1937 case '0':
1938 case '1':
1939 case '2':
1940 case '3':
1941 case '4':
1942 case '5':
1943 case '6':
1944 case '7':
1945 /* octal escape */
1946 {
1947 int val = 0;
1948 int c = odigitval(s[i + 1]);
1949
1950 val = c;
1951 c = odigitval(s[i + 2]);
1952 if (c == -1) {
1953 *p++ = val;
1954 i++;
1955 break;
1956 }
1957 val = (val * 8) + c;
1958 c = odigitval(s[i + 3]);
1959 if (c == -1) {
1960 *p++ = val;
1961 i += 2;
1962 break;
1963 }
1964 val = (val * 8) + c;
1965 *p++ = val;
1966 i += 3;
1967 }
1968 break;
1969 default:
1970 *p++ = s[i + 1];
1971 i++;
1972 break;
1973 }
1974 break;
1975 default:
1976 *p++ = s[i];
1977 break;
1978 }
1979 }
1980 len = p - dest;
1981 *p = '\0';
1982 return len;
1983 }
1984
1985 /* Returns a dynamically allocated copy of the current token in the
1986 * parser context. The function performs conversion of escapes if
1987 * the token is of type JIM_TT_ESC.
1988 *
1989 * Note that after the conversion, tokens that are grouped with
1990 * braces in the source code, are always recognizable from the
1991 * identical string obtained in a different way from the type.
1992 *
1993 * For example the string:
1994 *
1995 * {*}$a
1996 *
1997 * will return as first token "*", of type JIM_TT_STR
1998 *
1999 * While the string:
2000 *
2001 * *$a
2002 *
2003 * will return as first token "*", of type JIM_TT_ESC
2004 */
2005 static Jim_Obj *JimParserGetTokenObj(Jim_Interp *interp, struct JimParserCtx *pc)
2006 {
2007 const char *start, *end;
2008 char *token;
2009 int len;
2010
2011 start = pc->tstart;
2012 end = pc->tend;
2013 len = (end - start) + 1;
2014 if (len < 0) {
2015 len = 0;
2016 }
2017 token = Jim_Alloc(len + 1);
2018 if (pc->tt != JIM_TT_ESC) {
2019 /* No escape conversion needed? Just copy it. */
2020 memcpy(token, start, len);
2021 token[len] = '\0';
2022 }
2023 else {
2024 /* Else convert the escape chars. */
2025 len = JimEscape(token, start, len);
2026 }
2027
2028 return Jim_NewStringObjNoAlloc(interp, token, len);
2029 }
2030
2031 /* -----------------------------------------------------------------------------
2032 * Tcl Lists parsing
2033 * ---------------------------------------------------------------------------*/
2034 static int JimParseListSep(struct JimParserCtx *pc);
2035 static int JimParseListStr(struct JimParserCtx *pc);
2036 static int JimParseListQuote(struct JimParserCtx *pc);
2037
2038 static int JimParseList(struct JimParserCtx *pc)
2039 {
2040 if (isspace(UCHAR(*pc->p))) {
2041 return JimParseListSep(pc);
2042 }
2043 switch (*pc->p) {
2044 case '"':
2045 return JimParseListQuote(pc);
2046
2047 case '{':
2048 return JimParseBrace(pc);
2049
2050 default:
2051 if (pc->len) {
2052 return JimParseListStr(pc);
2053 }
2054 break;
2055 }
2056
2057 pc->tstart = pc->tend = pc->p;
2058 pc->tline = pc->linenr;
2059 pc->tt = JIM_TT_EOL;
2060 pc->eof = 1;
2061 return JIM_OK;
2062 }
2063
2064 static int JimParseListSep(struct JimParserCtx *pc)
2065 {
2066 pc->tstart = pc->p;
2067 pc->tline = pc->linenr;
2068 while (isspace(UCHAR(*pc->p))) {
2069 if (*pc->p == '\n') {
2070 pc->linenr++;
2071 }
2072 pc->p++;
2073 pc->len--;
2074 }
2075 pc->tend = pc->p - 1;
2076 pc->tt = JIM_TT_SEP;
2077 return JIM_OK;
2078 }
2079
2080 static int JimParseListQuote(struct JimParserCtx *pc)
2081 {
2082 pc->p++;
2083 pc->len--;
2084
2085 pc->tstart = pc->p;
2086 pc->tline = pc->linenr;
2087 pc->tt = JIM_TT_STR;
2088
2089 while (pc->len) {
2090 switch (*pc->p) {
2091 case '\\':
2092 pc->tt = JIM_TT_ESC;
2093 if (--pc->len == 0) {
2094 /* Trailing backslash */
2095 pc->tend = pc->p;
2096 return JIM_OK;
2097 }
2098 pc->p++;
2099 break;
2100 case '\n':
2101 pc->linenr++;
2102 break;
2103 case '"':
2104 pc->tend = pc->p - 1;
2105 pc->p++;
2106 pc->len--;
2107 return JIM_OK;
2108 }
2109 pc->p++;
2110 pc->len--;
2111 }
2112
2113 pc->tend = pc->p - 1;
2114 return JIM_OK;
2115 }
2116
2117 static int JimParseListStr(struct JimParserCtx *pc)
2118 {
2119 pc->tstart = pc->p;
2120 pc->tline = pc->linenr;
2121 pc->tt = JIM_TT_STR;
2122
2123 while (pc->len) {
2124 if (isspace(UCHAR(*pc->p))) {
2125 pc->tend = pc->p - 1;
2126 return JIM_OK;
2127 }
2128 if (*pc->p == '\\') {
2129 if (--pc->len == 0) {
2130 /* Trailing backslash */
2131 pc->tend = pc->p;
2132 return JIM_OK;
2133 }
2134 pc->tt = JIM_TT_ESC;
2135 pc->p++;
2136 }
2137 pc->p++;
2138 pc->len--;
2139 }
2140 pc->tend = pc->p - 1;
2141 return JIM_OK;
2142 }
2143
2144 /* -----------------------------------------------------------------------------
2145 * Jim_Obj related functions
2146 * ---------------------------------------------------------------------------*/
2147
2148 /* Return a new initialized object. */
2149 Jim_Obj *Jim_NewObj(Jim_Interp *interp)
2150 {
2151 Jim_Obj *objPtr;
2152
2153 /* -- Check if there are objects in the free list -- */
2154 if (interp->freeList != NULL) {
2155 /* -- Unlink the object from the free list -- */
2156 objPtr = interp->freeList;
2157 interp->freeList = objPtr->nextObjPtr;
2158 }
2159 else {
2160 /* -- No ready to use objects: allocate a new one -- */
2161 objPtr = Jim_Alloc(sizeof(*objPtr));
2162 }
2163
2164 /* Object is returned with refCount of 0. Every
2165 * kind of GC implemented should take care to avoid
2166 * scanning objects with refCount == 0. */
2167 objPtr->refCount = 0;
2168 /* All the other fields are left uninitialized to save time.
2169 * The caller will probably want to set them to the right
2170 * value anyway. */
2171
2172 /* -- Put the object into the live list -- */
2173 objPtr->prevObjPtr = NULL;
2174 objPtr->nextObjPtr = interp->liveList;
2175 if (interp->liveList)
2176 interp->liveList->prevObjPtr = objPtr;
2177 interp->liveList = objPtr;
2178
2179 return objPtr;
2180 }
2181
2182 /* Free an object. Actually objects are never freed, but
2183 * just moved to the free objects list, where they will be
2184 * reused by Jim_NewObj(). */
2185 void Jim_FreeObj(Jim_Interp *interp, Jim_Obj *objPtr)
2186 {
2187 /* Check if the object was already freed, panic. */
2188 JimPanic((objPtr->refCount != 0, "!!!Object %p freed with bad refcount %d, type=%s", objPtr,
2189 objPtr->refCount, objPtr->typePtr ? objPtr->typePtr->name : "<none>"));
2190
2191 /* Free the internal representation */
2192 Jim_FreeIntRep(interp, objPtr);
2193 /* Free the string representation */
2194 if (objPtr->bytes != NULL) {
2195 if (objPtr->bytes != JimEmptyStringRep)
2196 Jim_Free(objPtr->bytes);
2197 }
2198 /* Unlink the object from the live objects list */
2199 if (objPtr->prevObjPtr)
2200 objPtr->prevObjPtr->nextObjPtr = objPtr->nextObjPtr;
2201 if (objPtr->nextObjPtr)
2202 objPtr->nextObjPtr->prevObjPtr = objPtr->prevObjPtr;
2203 if (interp->liveList == objPtr)
2204 interp->liveList = objPtr->nextObjPtr;
2205 #ifdef JIM_DISABLE_OBJECT_POOL
2206 Jim_Free(objPtr);
2207 #else
2208 /* Link the object into the free objects list */
2209 objPtr->prevObjPtr = NULL;
2210 objPtr->nextObjPtr = interp->freeList;
2211 if (interp->freeList)
2212 interp->freeList->prevObjPtr = objPtr;
2213 interp->freeList = objPtr;
2214 objPtr->refCount = -1;
2215 #endif
2216 }
2217
2218 /* Invalidate the string representation of an object. */
2219 void Jim_InvalidateStringRep(Jim_Obj *objPtr)
2220 {
2221 if (objPtr->bytes != NULL) {
2222 if (objPtr->bytes != JimEmptyStringRep)
2223 Jim_Free(objPtr->bytes);
2224 }
2225 objPtr->bytes = NULL;
2226 }
2227
2228 /* Duplicate an object. The returned object has refcount = 0. */
2229 Jim_Obj *Jim_DuplicateObj(Jim_Interp *interp, Jim_Obj *objPtr)
2230 {
2231 Jim_Obj *dupPtr;
2232
2233 dupPtr = Jim_NewObj(interp);
2234 if (objPtr->bytes == NULL) {
2235 /* Object does not have a valid string representation. */
2236 dupPtr->bytes = NULL;
2237 }
2238 else if (objPtr->length == 0) {
2239 /* Zero length, so don't even bother with the type-specific dup,
2240 * since all zero length objects look the same
2241 */
2242 dupPtr->bytes = JimEmptyStringRep;
2243 dupPtr->length = 0;
2244 dupPtr->typePtr = NULL;
2245 return dupPtr;
2246 }
2247 else {
2248 dupPtr->bytes = Jim_Alloc(objPtr->length + 1);
2249 dupPtr->length = objPtr->length;
2250 /* Copy the null byte too */
2251 memcpy(dupPtr->bytes, objPtr->bytes, objPtr->length + 1);
2252 }
2253
2254 /* By default, the new object has the same type as the old object */
2255 dupPtr->typePtr = objPtr->typePtr;
2256 if (objPtr->typePtr != NULL) {
2257 if (objPtr->typePtr->dupIntRepProc == NULL) {
2258 dupPtr->internalRep = objPtr->internalRep;
2259 }
2260 else {
2261 /* The dup proc may set a different type, e.g. NULL */
2262 objPtr->typePtr->dupIntRepProc(interp, objPtr, dupPtr);
2263 }
2264 }
2265 return dupPtr;
2266 }
2267
2268 /* Return the string representation for objPtr. If the object's
2269 * string representation is invalid, calls the updateStringProc method to create
2270 * a new one from the internal representation of the object.
2271 */
2272 const char *Jim_GetString(Jim_Obj *objPtr, int *lenPtr)
2273 {
2274 if (objPtr->bytes == NULL) {
2275 /* Invalid string repr. Generate it. */
2276 JimPanic((objPtr->typePtr->updateStringProc == NULL, "UpdateStringProc called against '%s' type.", objPtr->typePtr->name));
2277 objPtr->typePtr->updateStringProc(objPtr);
2278 }
2279 if (lenPtr)
2280 *lenPtr = objPtr->length;
2281 return objPtr->bytes;
2282 }
2283
2284 /* Just returns the length (in bytes) of the object's string rep */
2285 int Jim_Length(Jim_Obj *objPtr)
2286 {
2287 if (objPtr->bytes == NULL) {
2288 /* Invalid string repr. Generate it. */
2289 Jim_GetString(objPtr, NULL);
2290 }
2291 return objPtr->length;
2292 }
2293
2294 /* Just returns object's string rep */
2295 const char *Jim_String(Jim_Obj *objPtr)
2296 {
2297 if (objPtr->bytes == NULL) {
2298 /* Invalid string repr. Generate it. */
2299 Jim_GetString(objPtr, NULL);
2300 }
2301 return objPtr->bytes;
2302 }
2303
2304 static void JimSetStringBytes(Jim_Obj *objPtr, const char *str)
2305 {
2306 objPtr->bytes = Jim_StrDup(str);
2307 objPtr->length = strlen(str);
2308 }
2309
2310 static void FreeDictSubstInternalRep(Jim_Interp *interp, Jim_Obj *objPtr);
2311 static void DupDictSubstInternalRep(Jim_Interp *interp, Jim_Obj *srcPtr, Jim_Obj *dupPtr);
2312
2313 static const Jim_ObjType dictSubstObjType = {
2314 "dict-substitution",
2315 FreeDictSubstInternalRep,
2316 DupDictSubstInternalRep,
2317 NULL,
2318 JIM_TYPE_NONE,
2319 };
2320
2321 static void FreeInterpolatedInternalRep(Jim_Interp *interp, Jim_Obj *objPtr);
2322 static void DupInterpolatedInternalRep(Jim_Interp *interp, Jim_Obj *srcPtr, Jim_Obj *dupPtr);
2323
2324 static const Jim_ObjType interpolatedObjType = {
2325 "interpolated",
2326 FreeInterpolatedInternalRep,
2327 DupInterpolatedInternalRep,
2328 NULL,
2329 JIM_TYPE_NONE,
2330 };
2331
2332 static void FreeInterpolatedInternalRep(Jim_Interp *interp, Jim_Obj *objPtr)
2333 {
2334 Jim_DecrRefCount(interp, objPtr->internalRep.dictSubstValue.indexObjPtr);
2335 }
2336
2337 static void DupInterpolatedInternalRep(Jim_Interp *interp, Jim_Obj *srcPtr, Jim_Obj *dupPtr)
2338 {
2339 /* Copy the interal rep */
2340 dupPtr->internalRep = srcPtr->internalRep;
2341 /* Need to increment the key ref count */
2342 Jim_IncrRefCount(dupPtr->internalRep.dictSubstValue.indexObjPtr);
2343 }
2344
2345 /* -----------------------------------------------------------------------------
2346 * String Object
2347 * ---------------------------------------------------------------------------*/
2348 static void DupStringInternalRep(Jim_Interp *interp, Jim_Obj *srcPtr, Jim_Obj *dupPtr);
2349 static int SetStringFromAny(Jim_Interp *interp, struct Jim_Obj *objPtr);
2350
2351 static const Jim_ObjType stringObjType = {
2352 "string",
2353 NULL,
2354 DupStringInternalRep,
2355 NULL,
2356 JIM_TYPE_REFERENCES,
2357 };
2358
2359 static void DupStringInternalRep(Jim_Interp *interp, Jim_Obj *srcPtr, Jim_Obj *dupPtr)
2360 {
2361 JIM_NOTUSED(interp);
2362
2363 /* This is a bit subtle: the only caller of this function
2364 * should be Jim_DuplicateObj(), that will copy the
2365 * string representaion. After the copy, the duplicated
2366 * object will not have more room in the buffer than
2367 * srcPtr->length bytes. So we just set it to length. */
2368 dupPtr->internalRep.strValue.maxLength = srcPtr->length;
2369 dupPtr->internalRep.strValue.charLength = srcPtr->internalRep.strValue.charLength;
2370 }
2371
2372 static int SetStringFromAny(Jim_Interp *interp, Jim_Obj *objPtr)
2373 {
2374 if (objPtr->typePtr != &stringObjType) {
2375 /* Get a fresh string representation. */
2376 if (objPtr->bytes == NULL) {
2377 /* Invalid string repr. Generate it. */
2378 JimPanic((objPtr->typePtr->updateStringProc == NULL, "UpdateStringProc called against '%s' type.", objPtr->typePtr->name));
2379 objPtr->typePtr->updateStringProc(objPtr);
2380 }
2381 /* Free any other internal representation. */
2382 Jim_FreeIntRep(interp, objPtr);
2383 /* Set it as string, i.e. just set the maxLength field. */
2384 objPtr->typePtr = &stringObjType;
2385 objPtr->internalRep.strValue.maxLength = objPtr->length;
2386 /* Don't know the utf-8 length yet */
2387 objPtr->internalRep.strValue.charLength = -1;
2388 }
2389 return JIM_OK;
2390 }
2391
2392 /**
2393 * Returns the length of the object string in chars, not bytes.
2394 *
2395 * These may be different for a utf-8 string.
2396 */
2397 int Jim_Utf8Length(Jim_Interp *interp, Jim_Obj *objPtr)
2398 {
2399 #ifdef JIM_UTF8
2400 SetStringFromAny(interp, objPtr);
2401
2402 if (objPtr->internalRep.strValue.charLength < 0) {
2403 objPtr->internalRep.strValue.charLength = utf8_strlen(objPtr->bytes, objPtr->length);
2404 }
2405 return objPtr->internalRep.strValue.charLength;
2406 #else
2407 return Jim_Length(objPtr);
2408 #endif
2409 }
2410
2411 /* len is in bytes -- see also Jim_NewStringObjUtf8() */
2412 Jim_Obj *Jim_NewStringObj(Jim_Interp *interp, const char *s, int len)
2413 {
2414 Jim_Obj *objPtr = Jim_NewObj(interp);
2415
2416 /* Need to find out how many bytes the string requires */
2417 if (len == -1)
2418 len = strlen(s);
2419 /* Alloc/Set the string rep. */
2420 if (len == 0) {
2421 objPtr->bytes = JimEmptyStringRep;
2422 }
2423 else {
2424 objPtr->bytes = Jim_StrDupLen(s, len);
2425 }
2426 objPtr->length = len;
2427
2428 /* No typePtr field for the vanilla string object. */
2429 objPtr->typePtr = NULL;
2430 return objPtr;
2431 }
2432
2433 /* charlen is in characters -- see also Jim_NewStringObj() */
2434 Jim_Obj *Jim_NewStringObjUtf8(Jim_Interp *interp, const char *s, int charlen)
2435 {
2436 #ifdef JIM_UTF8
2437 /* Need to find out how many bytes the string requires */
2438 int bytelen = utf8_index(s, charlen);
2439
2440 Jim_Obj *objPtr = Jim_NewStringObj(interp, s, bytelen);
2441
2442 /* Remember the utf8 length, so set the type */
2443 objPtr->typePtr = &stringObjType;
2444 objPtr->internalRep.strValue.maxLength = bytelen;
2445 objPtr->internalRep.strValue.charLength = charlen;
2446
2447 return objPtr;
2448 #else
2449 return Jim_NewStringObj(interp, s, charlen);
2450 #endif
2451 }
2452
2453 /* This version does not try to duplicate the 's' pointer, but
2454 * use it directly. */
2455 Jim_Obj *Jim_NewStringObjNoAlloc(Jim_Interp *interp, char *s, int len)
2456 {
2457 Jim_Obj *objPtr = Jim_NewObj(interp);
2458
2459 objPtr->bytes = s;
2460 objPtr->length = (len == -1) ? strlen(s) : len;
2461 objPtr->typePtr = NULL;
2462 return objPtr;
2463 }
2464
2465 /* Low-level string append. Use it only against unshared objects
2466 * of type "string". */
2467 static void StringAppendString(Jim_Obj *objPtr, const char *str, int len)
2468 {
2469 int needlen;
2470
2471 if (len == -1)
2472 len = strlen(str);
2473 needlen = objPtr->length + len;
2474 if (objPtr->internalRep.strValue.maxLength < needlen ||
2475 objPtr->internalRep.strValue.maxLength == 0) {
2476 needlen *= 2;
2477 /* Inefficient to malloc() for less than 8 bytes */
2478 if (needlen < 7) {
2479 needlen = 7;
2480 }
2481 if (objPtr->bytes == JimEmptyStringRep) {
2482 objPtr->bytes = Jim_Alloc(needlen + 1);
2483 }
2484 else {
2485 objPtr->bytes = Jim_Realloc(objPtr->bytes, needlen + 1);
2486 }
2487 objPtr->internalRep.strValue.maxLength = needlen;
2488 }
2489 memcpy(objPtr->bytes + objPtr->length, str, len);
2490 objPtr->bytes[objPtr->length + len] = '\0';
2491
2492 if (objPtr->internalRep.strValue.charLength >= 0) {
2493 /* Update the utf-8 char length */
2494 objPtr->internalRep.strValue.charLength += utf8_strlen(objPtr->bytes + objPtr->length, len);
2495 }
2496 objPtr->length += len;
2497 }
2498
2499 /* Higher level API to append strings to objects.
2500 * Object must not be unshared for each of these.
2501 */
2502 void Jim_AppendString(Jim_Interp *interp, Jim_Obj *objPtr, const char *str, int len)
2503 {
2504 JimPanic((Jim_IsShared(objPtr), "Jim_AppendString called with shared object"));
2505 SetStringFromAny(interp, objPtr);
2506 StringAppendString(objPtr, str, len);
2507 }
2508
2509 void Jim_AppendObj(Jim_Interp *interp, Jim_Obj *objPtr, Jim_Obj *appendObjPtr)
2510 {
2511 int len;
2512 const char *str = Jim_GetString(appendObjPtr, &len);
2513 Jim_AppendString(interp, objPtr, str, len);
2514 }
2515
2516 void Jim_AppendStrings(Jim_Interp *interp, Jim_Obj *objPtr, ...)
2517 {
2518 va_list ap;
2519
2520 SetStringFromAny(interp, objPtr);
2521 va_start(ap, objPtr);
2522 while (1) {
2523 const char *s = va_arg(ap, const char *);
2524
2525 if (s == NULL)
2526 break;
2527 Jim_AppendString(interp, objPtr, s, -1);
2528 }
2529 va_end(ap);
2530 }
2531
2532 int Jim_StringEqObj(Jim_Obj *aObjPtr, Jim_Obj *bObjPtr)
2533 {
2534 if (aObjPtr == bObjPtr) {
2535 return 1;
2536 }
2537 else {
2538 int Alen, Blen;
2539 const char *sA = Jim_GetString(aObjPtr, &Alen);
2540 const char *sB = Jim_GetString(bObjPtr, &Blen);
2541
2542 return Alen == Blen && memcmp(sA, sB, Alen) == 0;
2543 }
2544 }
2545
2546 /**
2547 * Note. Does not support embedded nulls in either the pattern or the object.
2548 */
2549 int Jim_StringMatchObj(Jim_Interp *interp, Jim_Obj *patternObjPtr, Jim_Obj *objPtr, int nocase)
2550 {
2551 return JimGlobMatch(Jim_String(patternObjPtr), Jim_String(objPtr), nocase);
2552 }
2553
2554 /*
2555 * Note: does not support embedded nulls for the nocase option.
2556 */
2557 int Jim_StringCompareObj(Jim_Interp *interp, Jim_Obj *firstObjPtr, Jim_Obj *secondObjPtr, int nocase)
2558 {
2559 int l1, l2;
2560 const char *s1 = Jim_GetString(firstObjPtr, &l1);
2561 const char *s2 = Jim_GetString(secondObjPtr, &l2);
2562
2563 if (nocase) {
2564 /* Do a character compare for nocase */
2565 return JimStringCompareLen(s1, s2, -1, nocase);
2566 }
2567 return JimStringCompare(s1, l1, s2, l2);
2568 }
2569
2570 /**
2571 * Like Jim_StringCompareObj() except compares to a maximum of the length of firstObjPtr.
2572 *
2573 * Note: does not support embedded nulls
2574 */
2575 int Jim_StringCompareLenObj(Jim_Interp *interp, Jim_Obj *firstObjPtr, Jim_Obj *secondObjPtr, int nocase)
2576 {
2577 const char *s1 = Jim_String(firstObjPtr);
2578 const char *s2 = Jim_String(secondObjPtr);
2579
2580 return JimStringCompareLen(s1, s2, Jim_Utf8Length(interp, firstObjPtr), nocase);
2581 }
2582
2583 /* Convert a range, as returned by Jim_GetRange(), into
2584 * an absolute index into an object of the specified length.
2585 * This function may return negative values, or values
2586 * greater than or equal to the length of the list if the index
2587 * is out of range. */
2588 static int JimRelToAbsIndex(int len, int idx)
2589 {
2590 if (idx < 0)
2591 return len + idx;
2592 return idx;
2593 }
2594
2595 /* Convert a pair of indexes (*firstPtr, *lastPtr) as normalized by JimRelToAbsIndex(),
2596 * into a form suitable for implementation of commands like [string range] and [lrange].
2597 *
2598 * The resulting range is guaranteed to address valid elements of
2599 * the structure.
2600 */
2601 static void JimRelToAbsRange(int len, int *firstPtr, int *lastPtr, int *rangeLenPtr)
2602 {
2603 int rangeLen;
2604
2605 if (*firstPtr > *lastPtr) {
2606 rangeLen = 0;
2607 }
2608 else {
2609 rangeLen = *lastPtr - *firstPtr + 1;
2610 if (rangeLen) {
2611 if (*firstPtr < 0) {
2612 rangeLen += *firstPtr;
2613 *firstPtr = 0;
2614 }
2615 if (*lastPtr >= len) {
2616 rangeLen -= (*lastPtr - (len - 1));
2617 *lastPtr = len - 1;
2618 }
2619 }
2620 }
2621 if (rangeLen < 0)
2622 rangeLen = 0;
2623
2624 *rangeLenPtr = rangeLen;
2625 }
2626
2627 static int JimStringGetRange(Jim_Interp *interp, Jim_Obj *firstObjPtr, Jim_Obj *lastObjPtr,
2628 int len, int *first, int *last, int *range)
2629 {
2630 if (Jim_GetIndex(interp, firstObjPtr, first) != JIM_OK) {
2631 return JIM_ERR;
2632 }
2633 if (Jim_GetIndex(interp, lastObjPtr, last) != JIM_OK) {
2634 return JIM_ERR;
2635 }
2636 *first = JimRelToAbsIndex(len, *first);
2637 *last = JimRelToAbsIndex(len, *last);
2638 JimRelToAbsRange(len, first, last, range);
2639 return JIM_OK;
2640 }
2641
2642 Jim_Obj *Jim_StringByteRangeObj(Jim_Interp *interp,
2643 Jim_Obj *strObjPtr, Jim_Obj *firstObjPtr, Jim_Obj *lastObjPtr)
2644 {
2645 int first, last;
2646 const char *str;
2647 int rangeLen;
2648 int bytelen;
2649
2650 str = Jim_GetString(strObjPtr, &bytelen);
2651
2652 if (JimStringGetRange(interp, firstObjPtr, lastObjPtr, bytelen, &first, &last, &rangeLen) != JIM_OK) {
2653 return NULL;
2654 }
2655
2656 if (first == 0 && rangeLen == bytelen) {
2657 return strObjPtr;
2658 }
2659 return Jim_NewStringObj(interp, str + first, rangeLen);
2660 }
2661
2662 Jim_Obj *Jim_StringRangeObj(Jim_Interp *interp,
2663 Jim_Obj *strObjPtr, Jim_Obj *firstObjPtr, Jim_Obj *lastObjPtr)
2664 {
2665 #ifdef JIM_UTF8
2666 int first, last;
2667 const char *str;
2668 int len, rangeLen;
2669 int bytelen;
2670
2671 str = Jim_GetString(strObjPtr, &bytelen);
2672 len = Jim_Utf8Length(interp, strObjPtr);
2673
2674 if (JimStringGetRange(interp, firstObjPtr, lastObjPtr, len, &first, &last, &rangeLen) != JIM_OK) {
2675 return NULL;
2676 }
2677
2678 if (first == 0 && rangeLen == len) {
2679 return strObjPtr;
2680 }
2681 if (len == bytelen) {
2682 /* ASCII optimisation */
2683 return Jim_NewStringObj(interp, str + first, rangeLen);
2684 }
2685 return Jim_NewStringObjUtf8(interp, str + utf8_index(str, first), rangeLen);
2686 #else
2687 return Jim_StringByteRangeObj(interp, strObjPtr, firstObjPtr, lastObjPtr);
2688 #endif
2689 }
2690
2691 Jim_Obj *JimStringReplaceObj(Jim_Interp *interp,
2692 Jim_Obj *strObjPtr, Jim_Obj *firstObjPtr, Jim_Obj *lastObjPtr, Jim_Obj *newStrObj)
2693 {
2694 int first, last;
2695 const char *str;
2696 int len, rangeLen;
2697 Jim_Obj *objPtr;
2698
2699 len = Jim_Utf8Length(interp, strObjPtr);
2700
2701 if (JimStringGetRange(interp, firstObjPtr, lastObjPtr, len, &first, &last, &rangeLen) != JIM_OK) {
2702 return NULL;
2703 }
2704
2705 if (last < first) {
2706 return strObjPtr;
2707 }
2708
2709 str = Jim_String(strObjPtr);
2710
2711 /* Before part */
2712 objPtr = Jim_NewStringObjUtf8(interp, str, first);
2713
2714 /* Replacement */
2715 if (newStrObj) {
2716 Jim_AppendObj(interp, objPtr, newStrObj);
2717 }
2718
2719 /* After part */
2720 Jim_AppendString(interp, objPtr, str + utf8_index(str, last + 1), len - last - 1);
2721
2722 return objPtr;
2723 }
2724
2725 /**
2726 * Note: does not support embedded nulls.
2727 */
2728 static void JimStrCopyUpperLower(char *dest, const char *str, int uc)
2729 {
2730 while (*str) {
2731 int c;
2732 str += utf8_tounicode(str, &c);
2733 dest += utf8_getchars(dest, uc ? utf8_upper(c) : utf8_lower(c));
2734 }
2735 *dest = 0;
2736 }
2737
2738 /**
2739 * Note: does not support embedded nulls.
2740 */
2741 static Jim_Obj *JimStringToLower(Jim_Interp *interp, Jim_Obj *strObjPtr)
2742 {
2743 char *buf;
2744 int len;
2745 const char *str;
2746
2747 str = Jim_GetString(strObjPtr, &len);
2748
2749 #ifdef JIM_UTF8
2750 /* Case mapping can change the utf-8 length of the string.
2751 * But at worst it will be by one extra byte per char
2752 */
2753 len *= 2;
2754 #endif
2755 buf = Jim_Alloc(len + 1);
2756 JimStrCopyUpperLower(buf, str, 0);
2757 return Jim_NewStringObjNoAlloc(interp, buf, -1);
2758 }
2759
2760 /**
2761 * Note: does not support embedded nulls.
2762 */
2763 static Jim_Obj *JimStringToUpper(Jim_Interp *interp, Jim_Obj *strObjPtr)
2764 {
2765 char *buf;
2766 const char *str;
2767 int len;
2768
2769 str = Jim_GetString(strObjPtr, &len);
2770
2771 #ifdef JIM_UTF8
2772 /* Case mapping can change the utf-8 length of the string.
2773 * But at worst it will be by one extra byte per char
2774 */
2775 len *= 2;
2776 #endif
2777 buf = Jim_Alloc(len + 1);
2778 JimStrCopyUpperLower(buf, str, 1);
2779 return Jim_NewStringObjNoAlloc(interp, buf, -1);
2780 }
2781
2782 /**
2783 * Note: does not support embedded nulls.
2784 */
2785 static Jim_Obj *JimStringToTitle(Jim_Interp *interp, Jim_Obj *strObjPtr)
2786 {
2787 char *buf, *p;
2788 int len;
2789 int c;
2790 const char *str;
2791
2792 str = Jim_GetString(strObjPtr, &len);
2793
2794 #ifdef JIM_UTF8
2795 /* Case mapping can change the utf-8 length of the string.
2796 * But at worst it will be by one extra byte per char
2797 */
2798 len *= 2;
2799 #endif
2800 buf = p = Jim_Alloc(len + 1);
2801
2802 str += utf8_tounicode(str, &c);
2803 p += utf8_getchars(p, utf8_title(c));
2804
2805 JimStrCopyUpperLower(p, str, 0);
2806
2807 return Jim_NewStringObjNoAlloc(interp, buf, -1);
2808 }
2809
2810 /* Similar to memchr() except searches a UTF-8 string 'str' of byte length 'len'
2811 * for unicode character 'c'.
2812 * Returns the position if found or NULL if not
2813 */
2814 static const char *utf8_memchr(const char *str, int len, int c)
2815 {
2816 #ifdef JIM_UTF8
2817 while (len) {
2818 int sc;
2819 int n = utf8_tounicode(str, &sc);
2820 if (sc == c) {
2821 return str;
2822 }
2823 str += n;
2824 len -= n;
2825 }
2826 return NULL;
2827 #else
2828 return memchr(str, c, len);
2829 #endif
2830 }
2831
2832 /**
2833 * Searches for the first non-trim char in string (str, len)
2834 *
2835 * If none is found, returns just past the last char.
2836 *
2837 * Lengths are in bytes.
2838 */
2839 static const char *JimFindTrimLeft(const char *str, int len, const char *trimchars, int trimlen)
2840 {
2841 while (len) {
2842 int c;
2843 int n = utf8_tounicode(str, &c);
2844
2845 if (utf8_memchr(trimchars, trimlen, c) == NULL) {
2846 /* Not a trim char, so stop */
2847 break;
2848 }
2849 str += n;
2850 len -= n;
2851 }
2852 return str;
2853 }
2854
2855 /**
2856 * Searches backwards for a non-trim char in string (str, len).
2857 *
2858 * Returns a pointer to just after the non-trim char, or NULL if not found.
2859 *
2860 * Lengths are in bytes.
2861 */
2862 static const char *JimFindTrimRight(const char *str, int len, const char *trimchars, int trimlen)
2863 {
2864 str += len;
2865
2866 while (len) {
2867 int c;
2868 int n = utf8_prev_len(str, len);
2869
2870 len -= n;
2871 str -= n;
2872
2873 n = utf8_tounicode(str, &c);
2874
2875 if (utf8_memchr(trimchars, trimlen, c) == NULL) {
2876 return str + n;
2877 }
2878 }
2879
2880 return NULL;
2881 }
2882
2883 static const char default_trim_chars[] = " \t\n\r";
2884 /* sizeof() here includes the null byte */
2885 static int default_trim_chars_len = sizeof(default_trim_chars);
2886
2887 static Jim_Obj *JimStringTrimLeft(Jim_Interp *interp, Jim_Obj *strObjPtr, Jim_Obj *trimcharsObjPtr)
2888 {
2889 int len;
2890 const char *str = Jim_GetString(strObjPtr, &len);
2891 const char *trimchars = default_trim_chars;
2892 int trimcharslen = default_trim_chars_len;
2893 const char *newstr;
2894
2895 if (trimcharsObjPtr) {
2896 trimchars = Jim_GetString(trimcharsObjPtr, &trimcharslen);
2897 }
2898
2899 newstr = JimFindTrimLeft(str, len, trimchars, trimcharslen);
2900 if (newstr == str) {
2901 return strObjPtr;
2902 }
2903
2904 return Jim_NewStringObj(interp, newstr, len - (newstr - str));
2905 }
2906
2907 static Jim_Obj *JimStringTrimRight(Jim_Interp *interp, Jim_Obj *strObjPtr, Jim_Obj *trimcharsObjPtr)
2908 {
2909 int len;
2910 const char *trimchars = default_trim_chars;
2911 int trimcharslen = default_trim_chars_len;
2912 const char *nontrim;
2913
2914 if (trimcharsObjPtr) {
2915 trimchars = Jim_GetString(trimcharsObjPtr, &trimcharslen);
2916 }
2917
2918 SetStringFromAny(interp, strObjPtr);
2919
2920 len = Jim_Length(strObjPtr);
2921 nontrim = JimFindTrimRight(strObjPtr->bytes, len, trimchars, trimcharslen);
2922
2923 if (nontrim == NULL) {
2924 /* All trim, so return a zero-length string */
2925 return Jim_NewEmptyStringObj(interp);
2926 }
2927 if (nontrim == strObjPtr->bytes + len) {
2928 /* All non-trim, so return the original object */
2929 return strObjPtr;
2930 }
2931
2932 if (Jim_IsShared(strObjPtr)) {
2933 strObjPtr = Jim_NewStringObj(interp, strObjPtr->bytes, (nontrim - strObjPtr->bytes));
2934 }
2935 else {
2936 /* Can modify this string in place */
2937 strObjPtr->bytes[nontrim - strObjPtr->bytes] = 0;
2938 strObjPtr->length = (nontrim - strObjPtr->bytes);
2939 }
2940
2941 return strObjPtr;
2942 }
2943
2944 static Jim_Obj *JimStringTrim(Jim_Interp *interp, Jim_Obj *strObjPtr, Jim_Obj *trimcharsObjPtr)
2945 {
2946 /* First trim left. */
2947 Jim_Obj *objPtr = JimStringTrimLeft(interp, strObjPtr, trimcharsObjPtr);
2948
2949 /* Now trim right */
2950 strObjPtr = JimStringTrimRight(interp, objPtr, trimcharsObjPtr);
2951
2952 /* Note: refCount check is needed since objPtr may be emptyObj */
2953 if (objPtr != strObjPtr && objPtr->refCount == 0) {
2954 /* We don't want this object to be leaked */
2955 Jim_FreeNewObj(interp, objPtr);
2956 }
2957
2958 return strObjPtr;
2959 }
2960
2961 /* Some platforms don't have isascii - need a non-macro version */
2962 #ifdef HAVE_ISASCII
2963 #define jim_isascii isascii
2964 #else
2965 static int jim_isascii(int c)
2966 {
2967 return !(c & ~0x7f);
2968 }
2969 #endif
2970
2971 static int JimStringIs(Jim_Interp *interp, Jim_Obj *strObjPtr, Jim_Obj *strClass, int strict)
2972 {
2973 static const char * const strclassnames[] = {
2974 "integer", "alpha", "alnum", "ascii", "digit",
2975 "double", "lower", "upper", "space", "xdigit",
2976 "control", "print", "graph", "punct", "boolean",
2977 NULL
2978 };
2979 enum {
2980 STR_IS_INTEGER, STR_IS_ALPHA, STR_IS_ALNUM, STR_IS_ASCII, STR_IS_DIGIT,
2981 STR_IS_DOUBLE, STR_IS_LOWER, STR_IS_UPPER, STR_IS_SPACE, STR_IS_XDIGIT,
2982 STR_IS_CONTROL, STR_IS_PRINT, STR_IS_GRAPH, STR_IS_PUNCT, STR_IS_BOOLEAN,
2983 };
2984 int strclass;
2985 int len;
2986 int i;
2987 const char *str;
2988 int (*isclassfunc)(int c) = NULL;
2989
2990 if (Jim_GetEnum(interp, strClass, strclassnames, &strclass, "class", JIM_ERRMSG | JIM_ENUM_ABBREV) != JIM_OK) {
2991 return JIM_ERR;
2992 }
2993
2994 str = Jim_GetString(strObjPtr, &len);
2995 if (len == 0) {
2996 Jim_SetResultBool(interp, !strict);
2997 return JIM_OK;
2998 }
2999
3000 switch (strclass) {
3001 case STR_IS_INTEGER:
3002 {
3003 jim_wide w;
3004 Jim_SetResultBool(interp, JimGetWideNoErr(interp, strObjPtr, &w) == JIM_OK);
3005 return JIM_OK;
3006 }
3007
3008 case STR_IS_DOUBLE:
3009 {
3010 double d;
3011 Jim_SetResultBool(interp, Jim_GetDouble(interp, strObjPtr, &d) == JIM_OK && errno != ERANGE);
3012 return JIM_OK;
3013 }
3014
3015 case STR_IS_BOOLEAN:
3016 {
3017 int b;
3018 Jim_SetResultBool(interp, Jim_GetBoolean(interp, strObjPtr, &b) == JIM_OK);
3019 return JIM_OK;
3020 }
3021
3022 case STR_IS_ALPHA: isclassfunc = isalpha; break;
3023 case STR_IS_ALNUM: isclassfunc = isalnum; break;
3024 case STR_IS_ASCII: isclassfunc = jim_isascii; break;
3025 case STR_IS_DIGIT: isclassfunc = isdigit; break;
3026 case STR_IS_LOWER: isclassfunc = islower; break;
3027 case STR_IS_UPPER: isclassfunc = isupper; break;
3028 case STR_IS_SPACE: isclassfunc = isspace; break;
3029 case STR_IS_XDIGIT: isclassfunc = isxdigit; break;
3030 case STR_IS_CONTROL: isclassfunc = iscntrl; break;
3031 case STR_IS_PRINT: isclassfunc = isprint; break;
3032 case STR_IS_GRAPH: isclassfunc = isgraph; break;
3033 case STR_IS_PUNCT: isclassfunc = ispunct; break;
3034 default:
3035 return JIM_ERR;
3036 }
3037
3038 for (i = 0; i < len; i++) {
3039 if (!isclassfunc(UCHAR(str[i]))) {
3040 Jim_SetResultBool(interp, 0);
3041 return JIM_OK;
3042 }
3043 }
3044 Jim_SetResultBool(interp, 1);
3045 return JIM_OK;
3046 }
3047
3048 /* -----------------------------------------------------------------------------
3049 * Compared String Object
3050 * ---------------------------------------------------------------------------*/
3051
3052 /* This is strange object that allows comparison of a C literal string
3053 * with a Jim object in a very short time if the same comparison is done
3054 * multiple times. For example every time the [if] command is executed,
3055 * Jim has to check if a given argument is "else".
3056 * If the code has no errors, this comparison is true most of the time,
3057 * so we can cache the pointer of the string of the last matching
3058 * comparison inside the object. Because most C compilers perform literal sharing,
3059 * so that: char *x = "foo", char *y = "foo", will lead to x == y,
3060 * this works pretty well even if comparisons are at different places
3061 * inside the C code. */
3062
3063 static const Jim_ObjType comparedStringObjType = {
3064 "compared-string",
3065 NULL,
3066 NULL,
3067 NULL,
3068 JIM_TYPE_REFERENCES,
3069 };
3070
3071 /* The only way this object is exposed to the API is via the following
3072 * function. Returns true if the string and the object string repr.
3073 * are the same, otherwise zero is returned.
3074 *
3075 * Note: this isn't binary safe, but it hardly needs to be.*/
3076 int Jim_CompareStringImmediate(Jim_Interp *interp, Jim_Obj *objPtr, const char *str)
3077 {
3078 if (objPtr->typePtr == &comparedStringObjType && objPtr->internalRep.ptr == str) {
3079 return 1;
3080 }
3081 else {
3082 if (strcmp(str, Jim_String(objPtr)) != 0)
3083 return 0;
3084
3085 if (objPtr->typePtr != &comparedStringObjType) {
3086 Jim_FreeIntRep(interp, objPtr);
3087 objPtr->typePtr = &comparedStringObjType;
3088 }
3089 objPtr->internalRep.ptr = (char *)str; /*ATTENTION: const cast */
3090 return 1;
3091 }
3092 }
3093
3094 static int qsortCompareStringPointers(const void *a, const void *b)
3095 {
3096 char *const *sa = (char *const *)a;
3097 char *const *sb = (char *const *)b;
3098
3099 return strcmp(*sa, *sb);
3100 }
3101
3102
3103 /* -----------------------------------------------------------------------------
3104 * Source Object
3105 *
3106 * This object is just a string from the language point of view, but
3107 * the internal representation contains the filename and line number
3108 * where this token was read. This information is used by
3109 * Jim_EvalObj() if the object passed happens to be of type "source".
3110 *
3111 * This allows propagation of the information about line numbers and file
3112 * names and gives error messages with absolute line numbers.
3113 *
3114 * Note that this object uses the internal representation of the Jim_Object,
3115 * so there is almost no memory overhead. (One Jim_Obj for each filename).
3116 *
3117 * Also the object will be converted to something else if the given
3118 * token it represents in the source file is not something to be
3119 * evaluated (not a script), and will be specialized in some other way,
3120 * so the time overhead is also almost zero.
3121 * ---------------------------------------------------------------------------*/
3122
3123 static void FreeSourceInternalRep(Jim_Interp *interp, Jim_Obj *objPtr);
3124 static void DupSourceInternalRep(Jim_Interp *interp, Jim_Obj *srcPtr, Jim_Obj *dupPtr);
3125
3126 static const Jim_ObjType sourceObjType = {
3127 "source",
3128 FreeSourceInternalRep,
3129 DupSourceInternalRep,
3130 NULL,
3131 JIM_TYPE_REFERENCES,
3132 };
3133
3134 void FreeSourceInternalRep(Jim_Interp *interp, Jim_Obj *objPtr)
3135 {
3136 Jim_DecrRefCount(interp, objPtr->internalRep.sourceValue.fileNameObj);
3137 }
3138
3139 void DupSourceInternalRep(Jim_Interp *interp, Jim_Obj *srcPtr, Jim_Obj *dupPtr)
3140 {
3141 dupPtr->internalRep.sourceValue = srcPtr->internalRep.sourceValue;
3142 Jim_IncrRefCount(dupPtr->internalRep.sourceValue.fileNameObj);
3143 }
3144
3145 static void JimSetSourceInfo(Jim_Interp *interp, Jim_Obj *objPtr,
3146 Jim_Obj *fileNameObj, int lineNumber)
3147 {
3148 JimPanic((Jim_IsShared(objPtr), "JimSetSourceInfo called with shared object"));
3149 JimPanic((objPtr->typePtr != NULL, "JimSetSourceInfo called with typed object"));
3150 Jim_IncrRefCount(fileNameObj);
3151 objPtr->internalRep.sourceValue.fileNameObj = fileNameObj;
3152 objPtr->internalRep.sourceValue.lineNumber = lineNumber;
3153 objPtr->typePtr = &sourceObjType;
3154 }
3155
3156 /* -----------------------------------------------------------------------------
3157 * ScriptLine Object
3158 *
3159 * This object is used only in the Script internal represenation.
3160 * For each line of the script, it holds the number of tokens on the line
3161 * and the source line number.
3162 */
3163 static const Jim_ObjType scriptLineObjType = {
3164 "scriptline",
3165 NULL,
3166 NULL,
3167 NULL,
3168 JIM_NONE,
3169 };
3170
3171 static Jim_Obj *JimNewScriptLineObj(Jim_Interp *interp, int argc, int line)
3172 {
3173 Jim_Obj *objPtr;
3174
3175 #ifdef DEBUG_SHOW_SCRIPT
3176 char buf[100];
3177 snprintf(buf, sizeof(buf), "line=%d, argc=%d", line, argc);
3178 objPtr = Jim_NewStringObj(interp, buf, -1);
3179 #else
3180 objPtr = Jim_NewEmptyStringObj(interp);
3181 #endif
3182 objPtr->typePtr = &scriptLineObjType;
3183 objPtr->internalRep.scriptLineValue.argc = argc;
3184 objPtr->internalRep.scriptLineValue.line = line;
3185
3186 return objPtr;
3187 }
3188
3189 /* -----------------------------------------------------------------------------
3190 * Script Object
3191 *
3192 * This object holds the parsed internal representation of a script.
3193 * This representation is help within an allocated ScriptObj (see below)
3194 */
3195 static void FreeScriptInternalRep(Jim_Interp *interp, Jim_Obj *objPtr);
3196 static void DupScriptInternalRep(Jim_Interp *interp, Jim_Obj *srcPtr, Jim_Obj *dupPtr);
3197
3198 static const Jim_ObjType scriptObjType = {
3199 "script",
3200 FreeScriptInternalRep,
3201 DupScriptInternalRep,
3202 NULL,
3203 JIM_TYPE_REFERENCES,
3204 };
3205
3206 /* Each token of a script is represented by a ScriptToken.
3207 * The ScriptToken contains a type and a Jim_Obj. The Jim_Obj
3208 * can be specialized by commands operating on it.
3209 */
3210 typedef struct ScriptToken
3211 {
3212 Jim_Obj *objPtr;
3213 int type;
3214 } ScriptToken;
3215
3216 /* This is the script object internal representation. An array of
3217 * ScriptToken structures, including a pre-computed representation of the
3218 * command length and arguments.
3219 *
3220 * For example the script:
3221 *
3222 * puts hello
3223 * set $i $x$y [foo]BAR
3224 *
3225 * will produce a ScriptObj with the following ScriptToken's:
3226 *
3227 * LIN 2
3228 * ESC puts
3229 * ESC hello
3230 * LIN 4
3231 * ESC set
3232 * VAR i
3233 * WRD 2
3234 * VAR x
3235 * VAR y
3236 * WRD 2
3237 * CMD foo
3238 * ESC BAR
3239 *
3240 * "puts hello" has two args (LIN 2), composed of single tokens.
3241 * (Note that the WRD token is omitted for the common case of a single token.)
3242 *
3243 * "set $i $x$y [foo]BAR" has four (LIN 4) args, the first word
3244 * has 1 token (ESC SET), and the last has two tokens (WRD 2 CMD foo ESC BAR)
3245 *
3246 * The precomputation of the command structure makes Jim_Eval() faster,
3247 * and simpler because there aren't dynamic lengths / allocations.
3248 *
3249 * -- {expand}/{*} handling --
3250 *
3251 * Expand is handled in a special way.
3252 *
3253 * If a "word" begins with {*}, the word token count is -ve.
3254 *
3255 * For example the command:
3256 *
3257 * list {*}{a b}
3258 *
3259 * Will produce the following cmdstruct array:
3260 *
3261 * LIN 2
3262 * ESC list
3263 * WRD -1
3264 * STR a b
3265 *
3266 * Note that the 'LIN' token also contains the source information for the
3267 * first word of the line for error reporting purposes
3268 *
3269 * -- the substFlags field of the structure --
3270 *
3271 * The scriptObj structure is used to represent both "script" objects
3272 * and "subst" objects. In the second case, there are no LIN and WRD
3273 * tokens. Instead SEP and EOL tokens are added as-is.
3274 * In addition, the field 'substFlags' is used to represent the flags used to turn
3275 * the string into the internal representation.
3276 * If these flags do not match what the application requires,
3277 * the scriptObj is created again. For example the script:
3278 *
3279 * subst -nocommands $string
3280 * subst -novariables $string
3281 *
3282 * Will (re)create the internal representation of the $string object
3283 * two times.
3284 */
3285 typedef struct ScriptObj
3286 {
3287 ScriptToken *token; /* Tokens array. */
3288 Jim_Obj *fileNameObj; /* Filename */
3289 int len; /* Length of token[] */
3290 int substFlags; /* flags used for the compilation of "subst" objects */
3291 int inUse; /* Used to share a ScriptObj. Currently
3292 only used by Jim_EvalObj() as protection against
3293 shimmering of the currently evaluated object. */
3294 int firstline; /* Line number of the first line */
3295 int linenr; /* Error line number, if any */
3296 int missing; /* Missing char if script failed to parse, (or space or backslash if OK) */
3297 } ScriptObj;
3298
3299 static void JimSetScriptFromAny(Jim_Interp *interp, struct Jim_Obj *objPtr);
3300 static int JimParseCheckMissing(Jim_Interp *interp, int ch);
3301 static ScriptObj *JimGetScript(Jim_Interp *interp, Jim_Obj *objPtr);
3302
3303 void FreeScriptInternalRep(Jim_Interp *interp, Jim_Obj *objPtr)
3304 {
3305 int i;
3306 struct ScriptObj *script = (void *)objPtr->internalRep.ptr;
3307
3308 if (--script->inUse != 0)
3309 return;
3310 for (i = 0; i < script->len; i++) {
3311 Jim_DecrRefCount(interp, script->token[i].objPtr);
3312 }
3313 Jim_Free(script->token);
3314 Jim_DecrRefCount(interp, script->fileNameObj);
3315 Jim_Free(script);
3316 }
3317
3318 void DupScriptInternalRep(Jim_Interp *interp, Jim_Obj *srcPtr, Jim_Obj *dupPtr)
3319 {
3320 JIM_NOTUSED(interp);
3321 JIM_NOTUSED(srcPtr);
3322
3323 /* Just return a simple string. We don't try to preserve the source info
3324 * since in practice scripts are never duplicated
3325 */
3326 dupPtr->typePtr = NULL;
3327 }
3328
3329 /* A simple parse token.
3330 * As the script is parsed, the created tokens point into the script string rep.
3331 */
3332 typedef struct
3333 {
3334 const char *token; /* Pointer to the start of the token */
3335 int len; /* Length of this token */
3336 int type; /* Token type */
3337 int line; /* Line number */
3338 } ParseToken;
3339
3340 /* A list of parsed tokens representing a script.
3341 * Tokens are added to this list as the script is parsed.
3342 * It grows as needed.
3343 */
3344 typedef struct
3345 {
3346 /* Start with a statically allocated list of tokens which will be expanded with realloc if needed */
3347 ParseToken *list; /* Array of tokens */
3348 int size; /* Current size of the list */
3349 int count; /* Number of entries used */
3350 ParseToken static_list[20]; /* Small initial token space to avoid allocation */
3351 } ParseTokenList;
3352
3353 static void ScriptTokenListInit(ParseTokenList *tokenlist)
3354 {
3355 tokenlist->list = tokenlist->static_list;
3356 tokenlist->size = sizeof(tokenlist->static_list) / sizeof(ParseToken);
3357 tokenlist->count = 0;
3358 }
3359
3360 static void ScriptTokenListFree(ParseTokenList *tokenlist)
3361 {
3362 if (tokenlist->list != tokenlist->static_list) {
3363 Jim_Free(tokenlist->list);
3364 }
3365 }
3366
3367 /**
3368 * Adds the new token to the tokenlist.
3369 * The token has the given length, type and line number.
3370 * The token list is resized as necessary.
3371 */
3372 static void ScriptAddToken(ParseTokenList *tokenlist, const char *token, int len, int type,
3373 int line)
3374 {
3375 ParseToken *t;
3376
3377 if (tokenlist->count == tokenlist->size) {
3378 /* Resize the list */
3379 tokenlist->size *= 2;
3380 if (tokenlist->list != tokenlist->static_list) {
3381 tokenlist->list =
3382 Jim_Realloc(tokenlist->list, tokenlist->size * sizeof(*tokenlist->list));
3383 }
3384 else {
3385 /* The list needs to become allocated */
3386 tokenlist->list = Jim_Alloc(tokenlist->size * sizeof(*tokenlist->list));
3387 memcpy(tokenlist->list, tokenlist->static_list,
3388 tokenlist->count * sizeof(*tokenlist->list));
3389 }
3390 }
3391 t = &tokenlist->list[tokenlist->count++];
3392 t->token = token;
3393 t->len = len;
3394 t->type = type;
3395 t->line = line;
3396 }
3397
3398 /* Counts the number of adjoining non-separator tokens.
3399 *
3400 * Returns -ve if the first token is the expansion
3401 * operator (in which case the count doesn't include
3402 * that token).
3403 */
3404 static int JimCountWordTokens(struct ScriptObj *script, ParseToken *t)
3405 {
3406 int expand = 1;
3407 int count = 0;
3408
3409 /* Is the first word {*} or {expand}? */
3410 if (t->type == JIM_TT_STR && !TOKEN_IS_SEP(t[1].type)) {
3411 if ((t->len == 1 && *t->token == '*') || (t->len == 6 && strncmp(t->token, "expand", 6) == 0)) {
3412 /* Create an expand token */
3413 expand = -1;
3414 t++;
3415 }
3416 else {
3417 if (script->missing == ' ') {
3418 /* This is a "extra characters after close-brace" error. Report the first error */
3419 script->missing = '}';
3420 script->linenr = t[1].line;
3421 }
3422 }
3423 }
3424
3425 /* Now count non-separator words */
3426 while (!TOKEN_IS_SEP(t->type)) {
3427 t++;
3428 count++;
3429 }
3430
3431 return count * expand;
3432 }
3433
3434 /**
3435 * Create a script/subst object from the given token.
3436 */
3437 static Jim_Obj *JimMakeScriptObj(Jim_Interp *interp, const ParseToken *t)
3438 {
3439 Jim_Obj *objPtr;
3440
3441 if (t->type == JIM_TT_ESC && memchr(t->token, '\\', t->len) != NULL) {
3442 /* Convert backlash escapes. The result will never be longer than the original */
3443 int len = t->len;
3444 char *str = Jim_Alloc(len + 1);
3445 len = JimEscape(str, t->token, len);
3446 objPtr = Jim_NewStringObjNoAlloc(interp, str, len);
3447 }
3448 else {
3449 /* XXX: For strict Tcl compatibility, JIM_TT_STR should replace <backslash><newline><whitespace>
3450 * with a single space.
3451 */
3452 objPtr = Jim_NewStringObj(interp, t->token, t->len);
3453 }
3454 return objPtr;
3455 }
3456
3457 /**
3458 * Takes a tokenlist and creates the allocated list of script tokens
3459 * in script->token, of length script->len.
3460 *
3461 * Unnecessary tokens are discarded, and LINE and WORD tokens are inserted
3462 * as required.
3463 *
3464 * Also sets script->line to the line number of the first token
3465 */
3466 static void ScriptObjAddTokens(Jim_Interp *interp, struct ScriptObj *script,
3467 ParseTokenList *tokenlist)
3468 {
3469 int i;
3470 struct ScriptToken *token;
3471 /* Number of tokens so far for the current command */
3472 int lineargs = 0;
3473 /* This is the first token for the current command */
3474 ScriptToken *linefirst;
3475 int count;
3476 int linenr;
3477
3478 #ifdef DEBUG_SHOW_SCRIPT_TOKENS
3479 printf("==== Tokens ====\n");
3480 for (i = 0; i < tokenlist->count; i++) {
3481 printf("[%2d]@%d %s '%.*s'\n", i, tokenlist->list[i].line, jim_tt_name(tokenlist->list[i].type),
3482 tokenlist->list[i].len, tokenlist->list[i].token);
3483 }
3484 #endif
3485
3486 /* May need up to one extra script token for each EOL in the worst case */
3487 count = tokenlist->count;
3488 for (i = 0; i < tokenlist->count; i++) {
3489 if (tokenlist->list[i].type == JIM_TT_EOL) {
3490 count++;
3491 }
3492 }
3493 linenr = script->firstline = tokenlist->list[0].line;
3494
3495 token = script->token = Jim_Alloc(sizeof(ScriptToken) * count);
3496
3497 /* This is the first token for the current command */
3498 linefirst = token++;
3499
3500 for (i = 0; i < tokenlist->count; ) {
3501 /* Look ahead to find out how many tokens make up the next word */
3502 int wordtokens;
3503
3504 /* Skip any leading separators */
3505 while (tokenlist->list[i].type == JIM_TT_SEP) {
3506 i++;
3507 }
3508
3509 wordtokens = JimCountWordTokens(script, tokenlist->list + i);
3510
3511 if (wordtokens == 0) {
3512 /* None, so at end of line */
3513 if (lineargs) {
3514 linefirst->type = JIM_TT_LINE;
3515 linefirst->objPtr = JimNewScriptLineObj(interp, lineargs, linenr);
3516 Jim_IncrRefCount(linefirst->objPtr);
3517
3518 /* Reset for new line */
3519 lineargs = 0;
3520 linefirst = token++;
3521 }
3522 i++;
3523 continue;
3524 }
3525 else if (wordtokens != 1) {
3526 /* More than 1, or {*}, so insert a WORD token */
3527 token->type = JIM_TT_WORD;
3528 token->objPtr = Jim_NewIntObj(interp, wordtokens);
3529 Jim_IncrRefCount(token->objPtr);
3530 token++;
3531 if (wordtokens < 0) {
3532 /* Skip the expand token */
3533 i++;
3534 wordtokens = -wordtokens - 1;
3535 lineargs--;
3536 }
3537 }
3538
3539 if (lineargs == 0) {
3540 /* First real token on the line, so record the line number */
3541 linenr = tokenlist->list[i].line;
3542 }
3543 lineargs++;
3544
3545 /* Add each non-separator word token to the line */
3546 while (wordtokens--) {
3547 const ParseToken *t = &tokenlist->list[i++];
3548
3549 token->type = t->type;
3550 token->objPtr = JimMakeScriptObj(interp, t);
3551 Jim_IncrRefCount(token->objPtr);
3552
3553 /* Every object is initially a string of type 'source', but the
3554 * internal type may be specialized during execution of the
3555 * script. */
3556 JimSetSourceInfo(interp, token->objPtr, script->fileNameObj, t->line);
3557 token++;
3558 }
3559 }
3560
3561 if (lineargs == 0) {
3562 token--;
3563 }
3564
3565 script->len = token - script->token;
3566
3567 JimPanic((script->len >= count, "allocated script array is too short"));
3568
3569 #ifdef DEBUG_SHOW_SCRIPT
3570 printf("==== Script (%s) ====\n", Jim_String(script->fileNameObj));
3571 for (i = 0; i < script->len; i++) {
3572 const ScriptToken *t = &script->token[i];
3573 printf("[%2d] %s %s\n", i, jim_tt_name(t->type), Jim_String(t->objPtr));
3574 }
3575 #endif
3576
3577 }
3578
3579 /* Parses the given string object to determine if it represents a complete script.
3580 *
3581 * This is useful for interactive shells implementation, for [info complete].
3582 *
3583 * If 'stateCharPtr' != NULL, the function stores ' ' on complete script,
3584 * '{' on scripts incomplete missing one or more '}' to be balanced.
3585 * '[' on scripts incomplete missing one or more ']' to be balanced.
3586 * '"' on scripts incomplete missing a '"' char.
3587 * '\\' on scripts with a trailing backslash.
3588 *
3589 * If the script is complete, 1 is returned, otherwise 0.
3590 *
3591 * If the script has extra characters after a close brace, this still returns 1,
3592 * but sets *stateCharPtr to '}'
3593 * Evaluating the script will give the error "extra characters after close-brace".
3594 */
3595 int Jim_ScriptIsComplete(Jim_Interp *interp, Jim_Obj *scriptObj, char *stateCharPtr)
3596 {
3597 ScriptObj *script = JimGetScript(interp, scriptObj);
3598 if (stateCharPtr) {
3599 *stateCharPtr = script->missing;
3600 }
3601 return script->missing == ' ' || script->missing == '}';
3602 }
3603
3604 /**
3605 * Sets an appropriate error message for a missing script/expression terminator.
3606 *
3607 * Returns JIM_ERR if 'ch' represents an unmatched/missing character.
3608 *
3609 * Note that a trailing backslash is not considered to be an error.
3610 */
3611 static int JimParseCheckMissing(Jim_Interp *interp, int ch)
3612 {
3613 const char *msg;
3614
3615 switch (ch) {
3616 case '\\':
3617 case ' ':
3618 return JIM_OK;
3619
3620 case '[':
3621 msg = "unmatched \"[\"";
3622 break;
3623 case '{':
3624 msg = "missing close-brace";
3625 break;
3626 case '}':
3627 msg = "extra characters after close-brace";
3628 break;
3629 case '"':
3630 default:
3631 msg = "missing quote";
3632 break;
3633 }
3634
3635 Jim_SetResultString(interp, msg, -1);
3636 return JIM_ERR;
3637 }
3638
3639 /**
3640 * Similar to ScriptObjAddTokens(), but for subst objects.
3641 */
3642 static void SubstObjAddTokens(Jim_Interp *interp, struct ScriptObj *script,
3643 ParseTokenList *tokenlist)
3644 {
3645 int i;
3646 struct ScriptToken *token;
3647
3648 token = script->token = Jim_Alloc(sizeof(ScriptToken) * tokenlist->count);
3649
3650 for (i = 0; i < tokenlist->count; i++) {
3651 const ParseToken *t = &tokenlist->list[i];
3652
3653 /* Create a token for 't' */
3654 token->type = t->type;
3655 token->objPtr = JimMakeScriptObj(interp, t);
3656 Jim_IncrRefCount(token->objPtr);
3657 token++;
3658 }
3659
3660 script->len = i;
3661 }
3662
3663 /* This method takes the string representation of an object
3664 * as a Tcl script, and generates the pre-parsed internal representation
3665 * of the script.
3666 *
3667 * On parse error, sets an error message and returns JIM_ERR
3668 * (Note: the object is still converted to a script, even if an error occurs)
3669 */
3670 static void JimSetScriptFromAny(Jim_Interp *interp, struct Jim_Obj *objPtr)
3671 {
3672 int scriptTextLen;
3673 const char *scriptText = Jim_GetString(objPtr, &scriptTextLen);
3674 struct JimParserCtx parser;
3675 struct ScriptObj *script;
3676 ParseTokenList tokenlist;
3677 int line = 1;
3678
3679 /* Try to get information about filename / line number */
3680 if (objPtr->typePtr == &sourceObjType) {
3681 line = objPtr->internalRep.sourceValue.lineNumber;
3682 }
3683
3684 /* Initially parse the script into tokens (in tokenlist) */
3685 ScriptTokenListInit(&tokenlist);
3686
3687 JimParserInit(&parser, scriptText, scriptTextLen, line);
3688 while (!parser.eof) {
3689 JimParseScript(&parser);
3690 ScriptAddToken(&tokenlist, parser.tstart, parser.tend - parser.tstart + 1, parser.tt,
3691 parser.tline);
3692 }
3693
3694 /* Add a final EOF token */
3695 ScriptAddToken(&tokenlist, scriptText + scriptTextLen, 0, JIM_TT_EOF, 0);
3696
3697 /* Create the "real" script tokens from the parsed tokens */
3698 script = Jim_Alloc(sizeof(*script));
3699 memset(script, 0, sizeof(*script));
3700 script->inUse = 1;
3701 if (objPtr->typePtr == &sourceObjType) {
3702 script->fileNameObj = objPtr->internalRep.sourceValue.fileNameObj;
3703 }
3704 else {
3705 script->fileNameObj = interp->emptyObj;
3706 }
3707 Jim_IncrRefCount(script->fileNameObj);
3708 script->missing = parser.missing.ch;
3709 script->linenr = parser.missing.line;
3710
3711 ScriptObjAddTokens(interp, script, &tokenlist);
3712
3713 /* No longer need the token list */
3714 ScriptTokenListFree(&tokenlist);
3715
3716 /* Free the old internal rep and set the new one. */
3717 Jim_FreeIntRep(interp, objPtr);
3718 Jim_SetIntRepPtr(objPtr, script);
3719 objPtr->typePtr = &scriptObjType;
3720 }
3721
3722 static void JimAddErrorToStack(Jim_Interp *interp, ScriptObj *script);
3723
3724 /**
3725 * Returns the parsed script.
3726 * Note that if there is any possibility that the script is not valid,
3727 * call JimScriptValid() to check
3728 */
3729 static ScriptObj *JimGetScript(Jim_Interp *interp, Jim_Obj *objPtr)
3730 {
3731 if (objPtr == interp->emptyObj) {
3732 /* Avoid converting emptyObj to a script. use nullScriptObj instead. */
3733 objPtr = interp->nullScriptObj;
3734 }
3735
3736 if (objPtr->typePtr != &scriptObjType || ((struct ScriptObj *)Jim_GetIntRepPtr(objPtr))->substFlags) {
3737 JimSetScriptFromAny(interp, objPtr);
3738 }
3739
3740 return (ScriptObj *)Jim_GetIntRepPtr(objPtr);
3741 }
3742
3743 /**
3744 * Returns 1 if the script is valid (parsed ok), otherwise returns 0
3745 * and leaves an error message in the interp result.
3746 *
3747 */
3748 static int JimScriptValid(Jim_Interp *interp, ScriptObj *script)
3749 {
3750 if (JimParseCheckMissing(interp, script->missing) == JIM_ERR) {
3751 JimAddErrorToStack(interp, script);
3752 return 0;
3753 }
3754 return 1;
3755 }
3756
3757
3758 /* -----------------------------------------------------------------------------
3759 * Commands
3760 * ---------------------------------------------------------------------------*/
3761 static void JimIncrCmdRefCount(Jim_Cmd *cmdPtr)
3762 {
3763 cmdPtr->inUse++;
3764 }
3765
3766 static void JimDecrCmdRefCount(Jim_Interp *interp, Jim_Cmd *cmdPtr)
3767 {
3768 if (--cmdPtr->inUse == 0) {
3769 if (cmdPtr->isproc) {
3770 Jim_DecrRefCount(interp, cmdPtr->u.proc.argListObjPtr);
3771 Jim_DecrRefCount(interp, cmdPtr->u.proc.bodyObjPtr);
3772 Jim_DecrRefCount(interp, cmdPtr->u.proc.nsObj);
3773 if (cmdPtr->u.proc.staticVars) {
3774 Jim_FreeHashTable(cmdPtr->u.proc.staticVars);
3775 Jim_Free(cmdPtr->u.proc.staticVars);
3776 }
3777 }
3778 else {
3779 /* native (C) */
3780 if (cmdPtr->u.native.delProc) {
3781 cmdPtr->u.native.delProc(interp, cmdPtr->u.native.privData);
3782 }
3783 }
3784 if (cmdPtr->prevCmd) {
3785 /* Delete any pushed command too */
3786 JimDecrCmdRefCount(interp, cmdPtr->prevCmd);
3787 }
3788 Jim_Free(cmdPtr);
3789 }
3790 }
3791
3792 /* Variables HashTable Type.
3793 *
3794 * Keys are dynamically allocated strings, Values are Jim_Var structures.
3795 */
3796 static void JimVariablesHTValDestructor(void *interp, void *val)
3797 {
3798 Jim_DecrRefCount(interp, ((Jim_Var *)val)->objPtr);
3799 Jim_Free(val);
3800 }
3801
3802 static const Jim_HashTableType JimVariablesHashTableType = {
3803 JimStringCopyHTHashFunction, /* hash function */
3804 JimStringCopyHTDup, /* key dup */
3805 NULL, /* val dup */
3806 JimStringCopyHTKeyCompare, /* key compare */
3807 JimStringCopyHTKeyDestructor, /* key destructor */
3808 JimVariablesHTValDestructor /* val destructor */
3809 };
3810
3811 /* Commands HashTable Type.
3812 *
3813 * Keys are dynamic allocated strings, Values are Jim_Cmd structures.
3814 */
3815 static void JimCommandsHT_ValDestructor(void *interp, void *val)
3816 {
3817 JimDecrCmdRefCount(interp, val);
3818 }
3819
3820 static const Jim_HashTableType JimCommandsHashTableType = {
3821 JimStringCopyHTHashFunction, /* hash function */
3822 JimStringCopyHTDup, /* key dup */
3823 NULL, /* val dup */
3824 JimStringCopyHTKeyCompare, /* key compare */
3825 JimStringCopyHTKeyDestructor, /* key destructor */
3826 JimCommandsHT_ValDestructor /* val destructor */
3827 };
3828
3829 /* ------------------------- Commands related functions --------------------- */
3830
3831 #ifdef jim_ext_namespace
3832 /**
3833 * Returns the "unscoped" version of the given namespace.
3834 * That is, the fully qualified name without the leading ::
3835 * The returned value is either nsObj, or an object with a zero ref count.
3836 */
3837 static Jim_Obj *JimQualifyNameObj(Jim_Interp *interp, Jim_Obj *nsObj)
3838 {
3839 const char *name = Jim_String(nsObj);
3840 if (name[0] == ':' && name[1] == ':') {
3841 /* This command is being defined in the global namespace */
3842 while (*++name == ':') {
3843 }
3844 nsObj = Jim_NewStringObj(interp, name, -1);
3845 }
3846 else if (Jim_Length(interp->framePtr->nsObj)) {
3847 /* This command is being defined in a non-global namespace */
3848 nsObj = Jim_DuplicateObj(interp, interp->framePtr->nsObj);
3849 Jim_AppendStrings(interp, nsObj, "::", name, NULL);
3850 }
3851 return nsObj;
3852 }
3853
3854 /**
3855 * If nameObjPtr starts with "::", returns it.
3856 * Otherwise returns a new object with nameObjPtr prefixed with "::".
3857 * In this case, decrements the ref count of nameObjPtr.
3858 */
3859 Jim_Obj *Jim_MakeGlobalNamespaceName(Jim_Interp *interp, Jim_Obj *nameObjPtr)
3860 {
3861 Jim_Obj *resultObj;
3862
3863 const char *name = Jim_String(nameObjPtr);
3864 if (name[0] == ':' && name[1] == ':') {
3865 return nameObjPtr;
3866 }
3867 Jim_IncrRefCount(nameObjPtr);
3868 resultObj = Jim_NewStringObj(interp, "::", -1);
3869 Jim_AppendObj(interp, resultObj, nameObjPtr);
3870 Jim_DecrRefCount(interp, nameObjPtr);
3871
3872 return resultObj;
3873 }
3874
3875 /**
3876 * An efficient version of JimQualifyNameObj() where the name is
3877 * available (and needed) as a 'const char *'.
3878 * Avoids creating an object if not necessary.
3879 * The object stored in *objPtrPtr should be disposed of with JimFreeQualifiedName() after use.
3880 */
3881 static const char *JimQualifyName(Jim_Interp *interp, const char *name, Jim_Obj **objPtrPtr)
3882 {
3883 Jim_Obj *objPtr = interp->emptyObj;
3884
3885 if (name[0] == ':' && name[1] == ':') {
3886 /* This command is being defined in the global namespace */
3887 while (*++name == ':') {
3888 }
3889 }
3890 else if (Jim_Length(interp->framePtr->nsObj)) {
3891 /* This command is being defined in a non-global namespace */
3892 objPtr = Jim_DuplicateObj(interp, interp->framePtr->nsObj);
3893 Jim_AppendStrings(interp, objPtr, "::", name, NULL);
3894 name = Jim_String(objPtr);
3895 }
3896 Jim_IncrRefCount(objPtr);
3897 *objPtrPtr = objPtr;
3898 return name;
3899 }
3900
3901 #define JimFreeQualifiedName(INTERP, OBJ) Jim_DecrRefCount((INTERP), (OBJ))
3902
3903 #else
3904 /* We can be more efficient in the no-namespace case */
3905 #define JimQualifyName(INTERP, NAME, DUMMY) (((NAME)[0] == ':' && (NAME)[1] == ':') ? (NAME) + 2 : (NAME))
3906 #define JimFreeQualifiedName(INTERP, DUMMY) (void)(DUMMY)
3907
3908 Jim_Obj *Jim_MakeGlobalNamespaceName(Jim_Interp *interp, Jim_Obj *nameObjPtr)
3909 {
3910 return nameObjPtr;
3911 }
3912 #endif
3913
3914 static int JimCreateCommand(Jim_Interp *interp, const char *name, Jim_Cmd *cmd)
3915 {
3916 /* It may already exist, so we try to delete the old one.
3917 * Note that reference count means that it won't be deleted yet if
3918 * it exists in the call stack.
3919 *
3920 * BUT, if 'local' is in force, instead of deleting the existing
3921 * proc, we stash a reference to the old proc here.
3922 */
3923 Jim_HashEntry *he = Jim_FindHashEntry(&interp->commands, name);
3924 if (he) {
3925 /* There was an old cmd with the same name,
3926 * so this requires a 'proc epoch' update. */
3927
3928 /* If a procedure with the same name didn't exist there is no need
3929 * to increment the 'proc epoch' because creation of a new procedure
3930 * can never affect existing cached commands. We don't do
3931 * negative caching. */
3932 Jim_InterpIncrProcEpoch(interp);
3933 }
3934
3935 if (he && interp->local) {
3936 /* Push this command over the top of the previous one */
3937 cmd->prevCmd = Jim_GetHashEntryVal(he);
3938 Jim_SetHashVal(&interp->commands, he, cmd);
3939 }
3940 else {
3941 if (he) {
3942 /* Replace the existing command */
3943 Jim_DeleteHashEntry(&interp->commands, name);
3944 }
3945
3946 Jim_AddHashEntry(&interp->commands, name, cmd);
3947 }
3948 return JIM_OK;
3949 }
3950
3951
3952 int Jim_CreateCommand(Jim_Interp *interp, const char *cmdNameStr,
3953 Jim_CmdProc *cmdProc, void *privData, Jim_DelCmdProc *delProc)
3954 {
3955 Jim_Cmd *cmdPtr = Jim_Alloc(sizeof(*cmdPtr));
3956
3957 /* Store the new details for this command */
3958 memset(cmdPtr, 0, sizeof(*cmdPtr));
3959 cmdPtr->inUse = 1;
3960 cmdPtr->u.native.delProc = delProc;
3961 cmdPtr->u.native.cmdProc = cmdProc;
3962 cmdPtr->u.native.privData = privData;
3963
3964 JimCreateCommand(interp, cmdNameStr, cmdPtr);
3965
3966 return JIM_OK;
3967 }
3968
3969 static int JimCreateProcedureStatics(Jim_Interp *interp, Jim_Cmd *cmdPtr, Jim_Obj *staticsListObjPtr)
3970 {
3971 int len, i;
3972
3973 len = Jim_ListLength(interp, staticsListObjPtr);
3974 if (len == 0) {
3975 return JIM_OK;
3976 }
3977
3978 cmdPtr->u.proc.staticVars = Jim_Alloc(sizeof(Jim_HashTable));
3979 Jim_InitHashTable(cmdPtr->u.proc.staticVars, &JimVariablesHashTableType, interp);
3980 for (i = 0; i < len; i++) {
3981 Jim_Obj *objPtr, *initObjPtr, *nameObjPtr;
3982 Jim_Var *varPtr;
3983 int subLen;
3984
3985 objPtr = Jim_ListGetIndex(interp, staticsListObjPtr, i);
3986 /* Check if it's composed of two elements. */
3987 subLen = Jim_ListLength(interp, objPtr);
3988 if (subLen == 1 || subLen == 2) {
3989 /* Try to get the variable value from the current
3990 * environment. */
3991 nameObjPtr = Jim_ListGetIndex(interp, objPtr, 0);
3992 if (subLen == 1) {
3993 initObjPtr = Jim_GetVariable(interp, nameObjPtr, JIM_NONE);
3994 if (initObjPtr == NULL) {
3995 Jim_SetResultFormatted(interp,
3996 "variable for initialization of static \"%#s\" not found in the local context",
3997 nameObjPtr);
3998 return JIM_ERR;
3999 }
4000 }
4001 else {
4002 initObjPtr = Jim_ListGetIndex(interp, objPtr, 1);
4003 }
4004 if (JimValidName(interp, "static variable", nameObjPtr) != JIM_OK) {
4005 return JIM_ERR;
4006 }
4007
4008 varPtr = Jim_Alloc(sizeof(*varPtr));
4009 varPtr->objPtr = initObjPtr;
4010 Jim_IncrRefCount(initObjPtr);
4011 varPtr->linkFramePtr = NULL;
4012 if (Jim_AddHashEntry(cmdPtr->u.proc.staticVars,
4013 Jim_String(nameObjPtr), varPtr) != JIM_OK) {
4014 Jim_SetResultFormatted(interp,
4015 "static variable name \"%#s\" duplicated in statics list", nameObjPtr);
4016 Jim_DecrRefCount(interp, initObjPtr);
4017 Jim_Free(varPtr);
4018 return JIM_ERR;
4019 }
4020 }
4021 else {
4022 Jim_SetResultFormatted(interp, "too many fields in static specifier \"%#s\"",
4023 objPtr);
4024 return JIM_ERR;
4025 }
4026 }
4027 return JIM_OK;
4028 }
4029
4030 /**
4031 * If the command is a proc, sets/updates the cached namespace (nsObj)
4032 * based on the command name.
4033 */
4034 static void JimUpdateProcNamespace(Jim_Interp *interp, Jim_Cmd *cmdPtr, const char *cmdname)
4035 {
4036 #ifdef jim_ext_namespace
4037 if (cmdPtr->isproc) {
4038 /* XXX: Really need JimNamespaceSplit() */
4039 const char *pt = strrchr(cmdname, ':');
4040 if (pt && pt != cmdname && pt[-1] == ':') {
4041 Jim_DecrRefCount(interp, cmdPtr->u.proc.nsObj);
4042 cmdPtr->u.proc.nsObj = Jim_NewStringObj(interp, cmdname, pt - cmdname - 1);
4043 Jim_IncrRefCount(cmdPtr->u.proc.nsObj);
4044
4045 if (Jim_FindHashEntry(&interp->commands, pt + 1)) {
4046 /* This command shadows a global command, so a proc epoch update is required */
4047 Jim_InterpIncrProcEpoch(interp);
4048 }
4049 }
4050 }
4051 #endif
4052 }
4053
4054 static Jim_Cmd *JimCreateProcedureCmd(Jim_Interp *interp, Jim_Obj *argListObjPtr,
4055 Jim_Obj *staticsListObjPtr, Jim_Obj *bodyObjPtr, Jim_Obj *nsObj)
4056 {
4057 Jim_Cmd *cmdPtr;
4058 int argListLen;
4059 int i;
4060
4061 argListLen = Jim_ListLength(interp, argListObjPtr);
4062
4063 /* Allocate space for both the command pointer and the arg list */
4064 cmdPtr = Jim_Alloc(sizeof(*cmdPtr) + sizeof(struct Jim_ProcArg) * argListLen);
4065 memset(cmdPtr, 0, sizeof(*cmdPtr));
4066 cmdPtr->inUse = 1;
4067 cmdPtr->isproc = 1;
4068 cmdPtr->u.proc.argListObjPtr = argListObjPtr;
4069 cmdPtr->u.proc.argListLen = argListLen;
4070 cmdPtr->u.proc.bodyObjPtr = bodyObjPtr;
4071 cmdPtr->u.proc.argsPos = -1;
4072 cmdPtr->u.proc.arglist = (struct Jim_ProcArg *)(cmdPtr + 1);
4073 cmdPtr->u.proc.nsObj = nsObj ? nsObj : interp->emptyObj;
4074 Jim_IncrRefCount(argListObjPtr);
4075 Jim_IncrRefCount(bodyObjPtr);
4076 Jim_IncrRefCount(cmdPtr->u.proc.nsObj);
4077
4078 /* Create the statics hash table. */
4079 if (staticsListObjPtr && JimCreateProcedureStatics(interp, cmdPtr, staticsListObjPtr) != JIM_OK) {
4080 goto err;
4081 }
4082
4083 /* Parse the args out into arglist, validating as we go */
4084 /* Examine the argument list for default parameters and 'args' */
4085 for (i = 0; i < argListLen; i++) {
4086 Jim_Obj *argPtr;
4087 Jim_Obj *nameObjPtr;
4088 Jim_Obj *defaultObjPtr;
4089 int len;
4090
4091 /* Examine a parameter */
4092 argPtr = Jim_ListGetIndex(interp, argListObjPtr, i);
4093 len = Jim_ListLength(interp, argPtr);
4094 if (len == 0) {
4095 Jim_SetResultString(interp, "argument with no name", -1);
4096 err:
4097 JimDecrCmdRefCount(interp, cmdPtr);
4098 return NULL;
4099 }
4100 if (len > 2) {
4101 Jim_SetResultFormatted(interp, "too many fields in argument specifier \"%#s\"", argPtr);
4102 goto err;
4103 }
4104
4105 if (len == 2) {
4106 /* Optional parameter */
4107 nameObjPtr = Jim_ListGetIndex(interp, argPtr, 0);
4108 defaultObjPtr = Jim_ListGetIndex(interp, argPtr, 1);
4109 }
4110 else {
4111 /* Required parameter */
4112 nameObjPtr = argPtr;
4113 defaultObjPtr = NULL;
4114 }
4115
4116
4117 if (Jim_CompareStringImmediate(interp, nameObjPtr, "args")) {
4118 if (cmdPtr->u.proc.argsPos >= 0) {
4119 Jim_SetResultString(interp, "'args' specified more than once", -1);
4120 goto err;
4121 }
4122 cmdPtr->u.proc.argsPos = i;
4123 }
4124 else {
4125 if (len == 2) {
4126 cmdPtr->u.proc.optArity++;
4127 }
4128 else {
4129 cmdPtr->u.proc.reqArity++;
4130 }
4131 }
4132
4133 cmdPtr->u.proc.arglist[i].nameObjPtr = nameObjPtr;
4134 cmdPtr->u.proc.arglist[i].defaultObjPtr = defaultObjPtr;
4135 }
4136
4137 return cmdPtr;
4138 }
4139
4140 int Jim_DeleteCommand(Jim_Interp *interp, const char *name)
4141 {
4142 int ret = JIM_OK;
4143 Jim_Obj *qualifiedNameObj;
4144 const char *qualname = JimQualifyName(interp, name, &qualifiedNameObj);
4145
4146 if (Jim_DeleteHashEntry(&interp->commands, qualname) == JIM_ERR) {
4147 Jim_SetResultFormatted(interp, "can't delete \"%s\": command doesn't exist", name);
4148 ret = JIM_ERR;
4149 }
4150 else {
4151 Jim_InterpIncrProcEpoch(interp);
4152 }
4153
4154 JimFreeQualifiedName(interp, qualifiedNameObj);
4155
4156 return ret;
4157 }
4158
4159 int Jim_RenameCommand(Jim_Interp *interp, const char *oldName, const char *newName)
4160 {
4161 int ret = JIM_ERR;
4162 Jim_HashEntry *he;
4163 Jim_Cmd *cmdPtr;
4164 Jim_Obj *qualifiedOldNameObj;
4165 Jim_Obj *qualifiedNewNameObj;
4166 const char *fqold;
4167 const char *fqnew;
4168
4169 if (newName[0] == 0) {
4170 return Jim_DeleteCommand(interp, oldName);
4171 }
4172
4173 fqold = JimQualifyName(interp, oldName, &qualifiedOldNameObj);
4174 fqnew = JimQualifyName(interp, newName, &qualifiedNewNameObj);
4175
4176 /* Does it exist? */
4177 he = Jim_FindHashEntry(&interp->commands, fqold);
4178 if (he == NULL) {
4179 Jim_SetResultFormatted(interp, "can't rename \"%s\": command doesn't exist", oldName);
4180 }
4181 else if (Jim_FindHashEntry(&interp->commands, fqnew)) {
4182 Jim_SetResultFormatted(interp, "can't rename to \"%s\": command already exists", newName);
4183 }
4184 else {
4185 /* Add the new name first */
4186 cmdPtr = Jim_GetHashEntryVal(he);
4187 JimIncrCmdRefCount(cmdPtr);
4188 JimUpdateProcNamespace(interp, cmdPtr, fqnew);
4189 Jim_AddHashEntry(&interp->commands, fqnew, cmdPtr);
4190
4191 /* Now remove the old name */
4192 Jim_DeleteHashEntry(&interp->commands, fqold);
4193
4194 /* Increment the epoch */
4195 Jim_InterpIncrProcEpoch(interp);
4196
4197 ret = JIM_OK;
4198 }
4199
4200 JimFreeQualifiedName(interp, qualifiedOldNameObj);
4201 JimFreeQualifiedName(interp, qualifiedNewNameObj);
4202
4203 return ret;
4204 }
4205
4206 /* -----------------------------------------------------------------------------
4207 * Command object
4208 * ---------------------------------------------------------------------------*/
4209
4210 static void FreeCommandInternalRep(Jim_Interp *interp, Jim_Obj *objPtr)
4211 {
4212 Jim_DecrRefCount(interp, objPtr->internalRep.cmdValue.nsObj);
4213 }
4214
4215 static void DupCommandInternalRep(Jim_Interp *interp, Jim_Obj *srcPtr, Jim_Obj *dupPtr)
4216 {
4217 dupPtr->internalRep.cmdValue = srcPtr->internalRep.cmdValue;
4218 dupPtr->typePtr = srcPtr->typePtr;
4219 Jim_IncrRefCount(dupPtr->internalRep.cmdValue.nsObj);
4220 }
4221
4222 static const Jim_ObjType commandObjType = {
4223 "command",
4224 FreeCommandInternalRep,
4225 DupCommandInternalRep,
4226 NULL,
4227 JIM_TYPE_REFERENCES,
4228 };
4229
4230 /* This function returns the command structure for the command name
4231 * stored in objPtr. It specializes the objPtr to contain
4232 * cached info instead of performing the lookup into the hash table
4233 * every time. The information cached may not be up-to-date, in this
4234 * case the lookup is performed and the cache updated.
4235 *
4236 * Respects the 'upcall' setting.
4237 */
4238 Jim_Cmd *Jim_GetCommand(Jim_Interp *interp, Jim_Obj *objPtr, int flags)
4239 {
4240 Jim_Cmd *cmd;
4241
4242 /* In order to be valid, the proc epoch must match and
4243 * the lookup must have occurred in the same namespace
4244 */
4245 if (objPtr->typePtr != &commandObjType ||
4246 objPtr->internalRep.cmdValue.procEpoch != interp->procEpoch
4247 #ifdef jim_ext_namespace
4248 || !Jim_StringEqObj(objPtr->internalRep.cmdValue.nsObj, interp->framePtr->nsObj)
4249 #endif
4250 ) {
4251 /* Not cached or out of date, so lookup */
4252
4253 /* Do we need to try the local namespace? */
4254 const char *name = Jim_String(objPtr);
4255 Jim_HashEntry *he;
4256
4257 if (name[0] == ':' && name[1] == ':') {
4258 while (*++name == ':') {
4259 }
4260 }
4261 #ifdef jim_ext_namespace
4262 else if (Jim_Length(interp->framePtr->nsObj)) {
4263 /* This command is being defined in a non-global namespace */
4264 Jim_Obj *nameObj = Jim_DuplicateObj(interp, interp->framePtr->nsObj);
4265 Jim_AppendStrings(interp, nameObj, "::", name, NULL);
4266 he = Jim_FindHashEntry(&interp->commands, Jim_String(nameObj));
4267 Jim_FreeNewObj(interp, nameObj);
4268 if (he) {
4269 goto found;
4270 }
4271 }
4272 #endif
4273
4274 /* Lookup in the global namespace */
4275 he = Jim_FindHashEntry(&interp->commands, name);
4276 if (he == NULL) {
4277 if (flags & JIM_ERRMSG) {
4278 Jim_SetResultFormatted(interp, "invalid command name \"%#s\"", objPtr);
4279 }
4280 return NULL;
4281 }
4282 #ifdef jim_ext_namespace
4283 found:
4284 #endif
4285 cmd = Jim_GetHashEntryVal(he);
4286
4287 /* Free the old internal rep and set the new one. */
4288 Jim_FreeIntRep(interp, objPtr);
4289 objPtr->typePtr = &commandObjType;
4290 objPtr->internalRep.cmdValue.procEpoch = interp->procEpoch;
4291 objPtr->internalRep.cmdValue.cmdPtr = cmd;
4292 objPtr->internalRep.cmdValue.nsObj = interp->framePtr->nsObj;
4293 Jim_IncrRefCount(interp->framePtr->nsObj);
4294 }
4295 else {
4296 cmd = objPtr->internalRep.cmdValue.cmdPtr;
4297 }
4298 while (cmd->u.proc.upcall) {
4299 cmd = cmd->prevCmd;
4300 }
4301 return cmd;
4302 }
4303
4304 /* -----------------------------------------------------------------------------
4305 * Variables
4306 * ---------------------------------------------------------------------------*/
4307
4308 /* -----------------------------------------------------------------------------
4309 * Variable object
4310 * ---------------------------------------------------------------------------*/
4311
4312 #define JIM_DICT_SUGAR 100 /* Only returned by SetVariableFromAny() */
4313
4314 static int SetVariableFromAny(Jim_Interp *interp, struct Jim_Obj *objPtr);
4315
4316 static const Jim_ObjType variableObjType = {
4317 "variable",
4318 NULL,
4319 NULL,
4320 NULL,
4321 JIM_TYPE_REFERENCES,
4322 };
4323
4324 /**
4325 * Check that the name does not contain embedded nulls.
4326 *
4327 * Variable and procedure names are manipulated as null terminated strings, so
4328 * don't allow names with embedded nulls.
4329 */
4330 static int JimValidName(Jim_Interp *interp, const char *type, Jim_Obj *nameObjPtr)
4331 {
4332 /* Variable names and proc names can't contain embedded nulls */
4333 if (nameObjPtr->typePtr != &variableObjType) {
4334 int len;
4335 const char *str = Jim_GetString(nameObjPtr, &len);
4336 if (memchr(str, '\0', len)) {
4337 Jim_SetResultFormatted(interp, "%s name contains embedded null", type);
4338 return JIM_ERR;
4339 }
4340 }
4341 return JIM_OK;
4342 }
4343
4344 /* This method should be called only by the variable API.
4345 * It returns JIM_OK on success (variable already exists),
4346 * JIM_ERR if it does not exist, JIM_DICT_SUGAR if it's not
4347 * a variable name, but syntax glue for [dict] i.e. the last
4348 * character is ')' */
4349 static int SetVariableFromAny(Jim_Interp *interp, struct Jim_Obj *objPtr)
4350 {
4351 const char *varName;
4352 Jim_CallFrame *framePtr;
4353 Jim_HashEntry *he;
4354 int global;
4355 int len;
4356
4357 /* Check if the object is already an uptodate variable */
4358 if (objPtr->typePtr == &variableObjType) {
4359 framePtr = objPtr->internalRep.varValue.global ? interp->topFramePtr : interp->framePtr;
4360 if (objPtr->internalRep.varValue.callFrameId == framePtr->id) {
4361 /* nothing to do */
4362 return JIM_OK;
4363 }
4364 /* Need to re-resolve the variable in the updated callframe */
4365 }
4366 else if (objPtr->typePtr == &dictSubstObjType) {
4367 return JIM_DICT_SUGAR;
4368 }
4369 else if (JimValidName(interp, "variable", objPtr) != JIM_OK) {
4370 return JIM_ERR;
4371 }
4372
4373
4374 varName = Jim_GetString(objPtr, &len);
4375
4376 /* Make sure it's not syntax glue to get/set dict. */
4377 if (len && varName[len - 1] == ')' && strchr(varName, '(') != NULL) {
4378 return JIM_DICT_SUGAR;
4379 }
4380
4381 if (varName[0] == ':' && varName[1] == ':') {
4382 while (*++varName == ':') {
4383 }
4384 global = 1;
4385 framePtr = interp->topFramePtr;
4386 }
4387 else {
4388 global = 0;
4389 framePtr = interp->framePtr;
4390 }
4391
4392 /* Resolve this name in the variables hash table */
4393 he = Jim_FindHashEntry(&framePtr->vars, varName);
4394 if (he == NULL) {
4395 if (!global && framePtr->staticVars) {
4396 /* Try with static vars. */
4397 he = Jim_FindHashEntry(framePtr->staticVars, varName);
4398 }
4399 if (he == NULL) {
4400 return JIM_ERR;
4401 }
4402 }
4403
4404 /* Free the old internal repr and set the new one. */
4405 Jim_FreeIntRep(interp, objPtr);
4406 objPtr->typePtr = &variableObjType;
4407 objPtr->internalRep.varValue.callFrameId = framePtr->id;
4408 objPtr->internalRep.varValue.varPtr = Jim_GetHashEntryVal(he);
4409 objPtr->internalRep.varValue.global = global;
4410 return JIM_OK;
4411 }
4412
4413 /* -------------------- Variables related functions ------------------------- */
4414 static int JimDictSugarSet(Jim_Interp *interp, Jim_Obj *ObjPtr, Jim_Obj *valObjPtr);
4415 static Jim_Obj *JimDictSugarGet(Jim_Interp *interp, Jim_Obj *ObjPtr, int flags);
4416
4417 static Jim_Var *JimCreateVariable(Jim_Interp *interp, Jim_Obj *nameObjPtr, Jim_Obj *valObjPtr)
4418 {
4419 const char *name;
4420 Jim_CallFrame *framePtr;
4421 int global;
4422
4423 /* New variable to create */
4424 Jim_Var *var = Jim_Alloc(sizeof(*var));
4425
4426 var->objPtr = valObjPtr;
4427 Jim_IncrRefCount(valObjPtr);
4428 var->linkFramePtr = NULL;
4429
4430 name = Jim_String(nameObjPtr);
4431 if (name[0] == ':' && name[1] == ':') {
4432 while (*++name == ':') {
4433 }
4434 framePtr = interp->topFramePtr;
4435 global = 1;
4436 }
4437 else {
4438 framePtr = interp->framePtr;
4439 global = 0;
4440 }
4441
4442 /* Insert the new variable */
4443 Jim_AddHashEntry(&framePtr->vars, name, var);
4444
4445 /* Make the object int rep a variable */
4446 Jim_FreeIntRep(interp, nameObjPtr);
4447 nameObjPtr->typePtr = &variableObjType;
4448 nameObjPtr->internalRep.varValue.callFrameId = framePtr->id;
4449 nameObjPtr->internalRep.varValue.varPtr = var;
4450 nameObjPtr->internalRep.varValue.global = global;
4451
4452 return var;
4453 }
4454
4455 /* For now that's dummy. Variables lookup should be optimized
4456 * in many ways, with caching of lookups, and possibly with
4457 * a table of pre-allocated vars in every CallFrame for local vars.
4458 * All the caching should also have an 'epoch' mechanism similar
4459 * to the one used by Tcl for procedures lookup caching. */
4460
4461 /**
4462 * Set the variable nameObjPtr to value valObjptr.
4463 */
4464 int Jim_SetVariable(Jim_Interp *interp, Jim_Obj *nameObjPtr, Jim_Obj *valObjPtr)
4465 {
4466 int err;
4467 Jim_Var *var;
4468
4469 switch (SetVariableFromAny(interp, nameObjPtr)) {
4470 case JIM_DICT_SUGAR:
4471 return JimDictSugarSet(interp, nameObjPtr, valObjPtr);
4472
4473 case JIM_ERR:
4474 if (JimValidName(interp, "variable", nameObjPtr) != JIM_OK) {
4475 return JIM_ERR;
4476 }
4477 JimCreateVariable(interp, nameObjPtr, valObjPtr);
4478 break;
4479
4480 case JIM_OK:
4481 var = nameObjPtr->internalRep.varValue.varPtr;
4482 if (var->linkFramePtr == NULL) {
4483 Jim_IncrRefCount(valObjPtr);
4484 Jim_DecrRefCount(interp, var->objPtr);
4485 var->objPtr = valObjPtr;
4486 }
4487 else { /* Else handle the link */
4488 Jim_CallFrame *savedCallFrame;
4489
4490 savedCallFrame = interp->framePtr;
4491 interp->framePtr = var->linkFramePtr;
4492 err = Jim_SetVariable(interp, var->objPtr, valObjPtr);
4493 interp->framePtr = savedCallFrame;
4494 if (err != JIM_OK)
4495 return err;
4496 }
4497 }
4498 return JIM_OK;
4499 }
4500
4501 int Jim_SetVariableStr(Jim_Interp *interp, const char *name, Jim_Obj *objPtr)
4502 {
4503 Jim_Obj *nameObjPtr;
4504 int result;
4505
4506 nameObjPtr = Jim_NewStringObj(interp, name, -1);
4507 Jim_IncrRefCount(nameObjPtr);
4508 result = Jim_SetVariable(interp, nameObjPtr, objPtr);
4509 Jim_DecrRefCount(interp, nameObjPtr);
4510 return result;
4511 }
4512
4513 int Jim_SetGlobalVariableStr(Jim_Interp *interp, const char *name, Jim_Obj *objPtr)
4514 {
4515 Jim_CallFrame *savedFramePtr;
4516 int result;
4517
4518 savedFramePtr = interp->framePtr;
4519 interp->framePtr = interp->topFramePtr;
4520 result = Jim_SetVariableStr(interp, name, objPtr);
4521 interp->framePtr = savedFramePtr;
4522 return result;
4523 }
4524
4525 int Jim_SetVariableStrWithStr(Jim_Interp *interp, const char *name, const char *val)
4526 {
4527 Jim_Obj *valObjPtr;
4528 int result;
4529
4530 valObjPtr = Jim_NewStringObj(interp, val, -1);
4531 Jim_IncrRefCount(valObjPtr);
4532 result = Jim_SetVariableStr(interp, name, valObjPtr);
4533 Jim_DecrRefCount(interp, valObjPtr);
4534 return result;
4535 }
4536
4537 int Jim_SetVariableLink(Jim_Interp *interp, Jim_Obj *nameObjPtr,
4538 Jim_Obj *targetNameObjPtr, Jim_CallFrame *targetCallFrame)
4539 {
4540 const char *varName;
4541 const char *targetName;
4542 Jim_CallFrame *framePtr;
4543 Jim_Var *varPtr;
4544
4545 /* Check for an existing variable or link */
4546 switch (SetVariableFromAny(interp, nameObjPtr)) {
4547 case JIM_DICT_SUGAR:
4548 /* XXX: This message seem unnecessarily verbose, but it matches Tcl */
4549 Jim_SetResultFormatted(interp, "bad variable name \"%#s\": upvar won't create a scalar variable that looks like an array element", nameObjPtr);
4550 return JIM_ERR;
4551
4552 case JIM_OK:
4553 varPtr = nameObjPtr->internalRep.varValue.varPtr;
4554
4555 if (varPtr->linkFramePtr == NULL) {
4556 Jim_SetResultFormatted(interp, "variable \"%#s\" already exists", nameObjPtr);
4557 return JIM_ERR;
4558 }
4559
4560 /* It exists, but is a link, so first delete the link */
4561 varPtr->linkFramePtr = NULL;
4562 break;
4563 }
4564
4565 /* Resolve the call frames for both variables */
4566 /* XXX: SetVariableFromAny() already did this! */
4567 varName = Jim_String(nameObjPtr);
4568
4569 if (varName[0] == ':' && varName[1] == ':') {
4570 while (*++varName == ':') {
4571 }
4572 /* Linking a global var does nothing */
4573 framePtr = interp->topFramePtr;
4574 }
4575 else {
4576 framePtr = interp->framePtr;
4577 }
4578
4579 targetName = Jim_String(targetNameObjPtr);
4580 if (targetName[0] == ':' && targetName[1] == ':') {
4581 while (*++targetName == ':') {
4582 }
4583 targetNameObjPtr = Jim_NewStringObj(interp, targetName, -1);
4584 targetCallFrame = interp->topFramePtr;
4585 }
4586 Jim_IncrRefCount(targetNameObjPtr);
4587
4588 if (framePtr->level < targetCallFrame->level) {
4589 Jim_SetResultFormatted(interp,
4590 "bad variable name \"%#s\": upvar won't create namespace variable that refers to procedure variable",
4591 nameObjPtr);
4592 Jim_DecrRefCount(interp, targetNameObjPtr);
4593 return JIM_ERR;
4594 }
4595
4596 /* Check for cycles. */
4597 if (framePtr == targetCallFrame) {
4598 Jim_Obj *objPtr = targetNameObjPtr;
4599
4600 /* Cycles are only possible with 'uplevel 0' */
4601 while (1) {
4602 if (strcmp(Jim_String(objPtr), varName) == 0) {
4603 Jim_SetResultString(interp, "can't upvar from variable to itself", -1);
4604 Jim_DecrRefCount(interp, targetNameObjPtr);
4605 return JIM_ERR;
4606 }
4607 if (SetVariableFromAny(interp, objPtr) != JIM_OK)
4608 break;
4609 varPtr = objPtr->internalRep.varValue.varPtr;
4610 if (varPtr->linkFramePtr != targetCallFrame)
4611 break;
4612 objPtr = varPtr->objPtr;
4613 }
4614 }
4615
4616 /* Perform the binding */
4617 Jim_SetVariable(interp, nameObjPtr, targetNameObjPtr);
4618 /* We are now sure 'nameObjPtr' type is variableObjType */
4619 nameObjPtr->internalRep.varValue.varPtr->linkFramePtr = targetCallFrame;
4620 Jim_DecrRefCount(interp, targetNameObjPtr);
4621 return JIM_OK;
4622 }
4623
4624 /* Return the Jim_Obj pointer associated with a variable name,
4625 * or NULL if the variable was not found in the current context.
4626 * The same optimization discussed in the comment to the
4627 * 'SetVariable' function should apply here.
4628 *
4629 * If JIM_UNSHARED is set and the variable is an array element (dict sugar)
4630 * in a dictionary which is shared, the array variable value is duplicated first.
4631 * This allows the array element to be updated (e.g. append, lappend) without
4632 * affecting other references to the dictionary.
4633 */
4634 Jim_Obj *Jim_GetVariable(Jim_Interp *interp, Jim_Obj *nameObjPtr, int flags)
4635 {
4636 switch (SetVariableFromAny(interp, nameObjPtr)) {
4637 case JIM_OK:{
4638 Jim_Var *varPtr = nameObjPtr->internalRep.varValue.varPtr;
4639
4640 if (varPtr->linkFramePtr == NULL) {
4641 return varPtr->objPtr;
4642 }
4643 else {
4644 Jim_Obj *objPtr;
4645
4646 /* The variable is a link? Resolve it. */
4647 Jim_CallFrame *savedCallFrame = interp->framePtr;
4648
4649 interp->framePtr = varPtr->linkFramePtr;
4650 objPtr = Jim_GetVariable(interp, varPtr->objPtr, flags);
4651 interp->framePtr = savedCallFrame;
4652 if (objPtr) {
4653 return objPtr;
4654 }
4655 /* Error, so fall through to the error message */
4656 }
4657 }
4658 break;
4659
4660 case JIM_DICT_SUGAR:
4661 /* [dict] syntax sugar. */
4662 return JimDictSugarGet(interp, nameObjPtr, flags);
4663 }
4664 if (flags & JIM_ERRMSG) {
4665 Jim_SetResultFormatted(interp, "can't read \"%#s\": no such variable", nameObjPtr);
4666 }
4667 return NULL;
4668 }
4669
4670 Jim_Obj *Jim_GetGlobalVariable(Jim_Interp *interp, Jim_Obj *nameObjPtr, int flags)
4671 {
4672 Jim_CallFrame *savedFramePtr;
4673 Jim_Obj *objPtr;
4674
4675 savedFramePtr = interp->framePtr;
4676 interp->framePtr = interp->topFramePtr;
4677 objPtr = Jim_GetVariable(interp, nameObjPtr, flags);
4678 interp->framePtr = savedFramePtr;
4679
4680 return objPtr;
4681 }
4682
4683 Jim_Obj *Jim_GetVariableStr(Jim_Interp *interp, const char *name, int flags)
4684 {
4685 Jim_Obj *nameObjPtr, *varObjPtr;
4686
4687 nameObjPtr = Jim_NewStringObj(interp, name, -1);
4688 Jim_IncrRefCount(nameObjPtr);
4689 varObjPtr = Jim_GetVariable(interp, nameObjPtr, flags);
4690 Jim_DecrRefCount(interp, nameObjPtr);
4691 return varObjPtr;
4692 }
4693
4694 Jim_Obj *Jim_GetGlobalVariableStr(Jim_Interp *interp, const char *name, int flags)
4695 {
4696 Jim_CallFrame *savedFramePtr;
4697 Jim_Obj *objPtr;
4698
4699 savedFramePtr = interp->framePtr;
4700 interp->framePtr = interp->topFramePtr;
4701 objPtr = Jim_GetVariableStr(interp, name, flags);
4702 interp->framePtr = savedFramePtr;
4703
4704 return objPtr;
4705 }
4706
4707 /* Unset a variable.
4708 * Note: On success unset invalidates all the (cached) variable objects
4709 * by incrementing callFrameEpoch
4710 */
4711 int Jim_UnsetVariable(Jim_Interp *interp, Jim_Obj *nameObjPtr, int flags)
4712 {
4713 Jim_Var *varPtr;
4714 int retval;
4715 Jim_CallFrame *framePtr;
4716
4717 retval = SetVariableFromAny(interp, nameObjPtr);
4718 if (retval == JIM_DICT_SUGAR) {
4719 /* [dict] syntax sugar. */
4720 return JimDictSugarSet(interp, nameObjPtr, NULL);
4721 }
4722 else if (retval == JIM_OK) {
4723 varPtr = nameObjPtr->internalRep.varValue.varPtr;
4724
4725 /* If it's a link call UnsetVariable recursively */
4726 if (varPtr->linkFramePtr) {
4727 framePtr = interp->framePtr;
4728 interp->framePtr = varPtr->linkFramePtr;
4729 retval = Jim_UnsetVariable(interp, varPtr->objPtr, JIM_NONE);
4730 interp->framePtr = framePtr;
4731 }
4732 else {
4733 const char *name = Jim_String(nameObjPtr);
4734 if (nameObjPtr->internalRep.varValue.global) {
4735 name += 2;
4736 framePtr = interp->topFramePtr;
4737 }
4738 else {
4739 framePtr = interp->framePtr;
4740 }
4741
4742 retval = Jim_DeleteHashEntry(&framePtr->vars, name);
4743 if (retval == JIM_OK) {
4744 /* Change the callframe id, invalidating var lookup caching */
4745 framePtr->id = interp->callFrameEpoch++;
4746 }
4747 }
4748 }
4749 if (retval != JIM_OK && (flags & JIM_ERRMSG)) {
4750 Jim_SetResultFormatted(interp, "can't unset \"%#s\": no such variable", nameObjPtr);
4751 }
4752 return retval;
4753 }
4754
4755 /* ---------- Dict syntax sugar (similar to array Tcl syntax) -------------- */
4756
4757 /* Given a variable name for [dict] operation syntax sugar,
4758 * this function returns two objects, the first with the name
4759 * of the variable to set, and the second with the respective key.
4760 * For example "foo(bar)" will return objects with string repr. of
4761 * "foo" and "bar".
4762 *
4763 * The returned objects have refcount = 1. The function can't fail. */
4764 static void JimDictSugarParseVarKey(Jim_Interp *interp, Jim_Obj *objPtr,
4765 Jim_Obj **varPtrPtr, Jim_Obj **keyPtrPtr)
4766 {
4767 const char *str, *p;
4768 int len, keyLen;
4769 Jim_Obj *varObjPtr, *keyObjPtr;
4770
4771 str = Jim_GetString(objPtr, &len);
4772
4773 p = strchr(str, '(');
4774 JimPanic((p == NULL, "JimDictSugarParseVarKey() called for non-dict-sugar (%s)", str));
4775
4776 varObjPtr = Jim_NewStringObj(interp, str, p - str);
4777
4778 p++;
4779 keyLen = (str + len) - p;
4780 if (str[len - 1] == ')') {
4781 keyLen--;
4782 }
4783
4784 /* Create the objects with the variable name and key. */
4785 keyObjPtr = Jim_NewStringObj(interp, p, keyLen);
4786
4787 Jim_IncrRefCount(varObjPtr);
4788 Jim_IncrRefCount(keyObjPtr);
4789 *varPtrPtr = varObjPtr;
4790 *keyPtrPtr = keyObjPtr;
4791 }
4792
4793 /* Helper of Jim_SetVariable() to deal with dict-syntax variable names.
4794 * Also used by Jim_UnsetVariable() with valObjPtr = NULL. */
4795 static int JimDictSugarSet(Jim_Interp *interp, Jim_Obj *objPtr, Jim_Obj *valObjPtr)
4796 {
4797 int err;
4798
4799 SetDictSubstFromAny(interp, objPtr);
4800
4801 err = Jim_SetDictKeysVector(interp, objPtr->internalRep.dictSubstValue.varNameObjPtr,
4802 &objPtr->internalRep.dictSubstValue.indexObjPtr, 1, valObjPtr, JIM_MUSTEXIST);
4803
4804 if (err == JIM_OK) {
4805 /* Don't keep an extra ref to the result */
4806 Jim_SetEmptyResult(interp);
4807 }
4808 else {
4809 if (!valObjPtr) {
4810 /* Better error message for unset a(2) where a exists but a(2) doesn't */
4811 if (Jim_GetVariable(interp, objPtr->internalRep.dictSubstValue.varNameObjPtr, JIM_NONE)) {
4812 Jim_SetResultFormatted(interp, "can't unset \"%#s\": no such element in array",
4813 objPtr);
4814 return err;
4815 }
4816 }
4817 /* Make the error more informative and Tcl-compatible */
4818 Jim_SetResultFormatted(interp, "can't %s \"%#s\": variable isn't array",
4819 (valObjPtr ? "set" : "unset"), objPtr);
4820 }
4821 return err;
4822 }
4823
4824 /**
4825 * Expands the array variable (dict sugar) and returns the result, or NULL on error.
4826 *
4827 * If JIM_UNSHARED is set and the dictionary is shared, it will be duplicated
4828 * and stored back to the variable before expansion.
4829 */
4830 static Jim_Obj *JimDictExpandArrayVariable(Jim_Interp *interp, Jim_Obj *varObjPtr,
4831 Jim_Obj *keyObjPtr, int flags)
4832 {
4833 Jim_Obj *dictObjPtr;
4834 Jim_Obj *resObjPtr = NULL;
4835 int ret;
4836
4837 dictObjPtr = Jim_GetVariable(interp, varObjPtr, JIM_ERRMSG);
4838 if (!dictObjPtr) {
4839 return NULL;
4840 }
4841
4842 ret = Jim_DictKey(interp, dictObjPtr, keyObjPtr, &resObjPtr, JIM_NONE);
4843 if (ret != JIM_OK) {
4844 Jim_SetResultFormatted(interp,
4845 "can't read \"%#s(%#s)\": %s array", varObjPtr, keyObjPtr,
4846 ret < 0 ? "variable isn't" : "no such element in");
4847 }
4848 else if ((flags & JIM_UNSHARED) && Jim_IsShared(dictObjPtr)) {
4849 /* Update the variable to have an unshared copy */
4850 Jim_SetVariable(interp, varObjPtr, Jim_DuplicateObj(interp, dictObjPtr));
4851 }
4852
4853 return resObjPtr;
4854 }
4855
4856 /* Helper of Jim_GetVariable() to deal with dict-syntax variable names */
4857 static Jim_Obj *JimDictSugarGet(Jim_Interp *interp, Jim_Obj *objPtr, int flags)
4858 {
4859 SetDictSubstFromAny(interp, objPtr);
4860
4861 return JimDictExpandArrayVariable(interp,
4862 objPtr->internalRep.dictSubstValue.varNameObjPtr,
4863 objPtr->internalRep.dictSubstValue.indexObjPtr, flags);
4864 }
4865
4866 /* --------- $var(INDEX) substitution, using a specialized object ----------- */
4867
4868 void FreeDictSubstInternalRep(Jim_Interp *interp, Jim_Obj *objPtr)
4869 {
4870 Jim_DecrRefCount(interp, objPtr->internalRep.dictSubstValue.varNameObjPtr);
4871 Jim_DecrRefCount(interp, objPtr->internalRep.dictSubstValue.indexObjPtr);
4872 }
4873
4874 static void DupDictSubstInternalRep(Jim_Interp *interp, Jim_Obj *srcPtr, Jim_Obj *dupPtr)
4875 {
4876 /* Copy the internal rep */
4877 dupPtr->internalRep = srcPtr->internalRep;
4878 /* Need to increment the ref counts */
4879 Jim_IncrRefCount(dupPtr->internalRep.dictSubstValue.varNameObjPtr);
4880 Jim_IncrRefCount(dupPtr->internalRep.dictSubstValue.indexObjPtr);
4881 }
4882
4883 /* Note: The object *must* be in dict-sugar format */
4884 static void SetDictSubstFromAny(Jim_Interp *interp, Jim_Obj *objPtr)
4885 {
4886 if (objPtr->typePtr != &dictSubstObjType) {
4887 Jim_Obj *varObjPtr, *keyObjPtr;
4888
4889 if (objPtr->typePtr == &interpolatedObjType) {
4890 /* An interpolated object in dict-sugar form */
4891
4892 varObjPtr = objPtr->internalRep.dictSubstValue.varNameObjPtr;
4893 keyObjPtr = objPtr->internalRep.dictSubstValue.indexObjPtr;
4894
4895 Jim_IncrRefCount(varObjPtr);
4896 Jim_IncrRefCount(keyObjPtr);
4897 }
4898 else {
4899 JimDictSugarParseVarKey(interp, objPtr, &varObjPtr, &keyObjPtr);
4900 }
4901
4902 Jim_FreeIntRep(interp, objPtr);
4903 objPtr->typePtr = &dictSubstObjType;
4904 objPtr->internalRep.dictSubstValue.varNameObjPtr = varObjPtr;
4905 objPtr->internalRep.dictSubstValue.indexObjPtr = keyObjPtr;
4906 }
4907 }
4908
4909 /* This function is used to expand [dict get] sugar in the form
4910 * of $var(INDEX). The function is mainly used by Jim_EvalObj()
4911 * to deal with tokens of type JIM_TT_DICTSUGAR. objPtr points to an
4912 * object that is *guaranteed* to be in the form VARNAME(INDEX).
4913 * The 'index' part is [subst]ituted, and is used to lookup a key inside
4914 * the [dict]ionary contained in variable VARNAME. */
4915 static Jim_Obj *JimExpandDictSugar(Jim_Interp *interp, Jim_Obj *objPtr)
4916 {
4917 Jim_Obj *resObjPtr = NULL;
4918 Jim_Obj *substKeyObjPtr = NULL;
4919
4920 SetDictSubstFromAny(interp, objPtr);
4921
4922 if (Jim_SubstObj(interp, objPtr->internalRep.dictSubstValue.indexObjPtr,
4923 &substKeyObjPtr, JIM_NONE)
4924 != JIM_OK) {
4925 return NULL;
4926 }
4927 Jim_IncrRefCount(substKeyObjPtr);
4928 resObjPtr =
4929 JimDictExpandArrayVariable(interp, objPtr->internalRep.dictSubstValue.varNameObjPtr,
4930 substKeyObjPtr, 0);
4931 Jim_DecrRefCount(interp, substKeyObjPtr);
4932
4933 return resObjPtr;
4934 }
4935
4936 static Jim_Obj *JimExpandExprSugar(Jim_Interp *interp, Jim_Obj *objPtr)
4937 {
4938 if (Jim_EvalExpression(interp, objPtr) == JIM_OK) {
4939 return Jim_GetResult(interp);
4940 }
4941 return NULL;
4942 }
4943
4944 /* -----------------------------------------------------------------------------
4945 * CallFrame
4946 * ---------------------------------------------------------------------------*/
4947
4948 static Jim_CallFrame *JimCreateCallFrame(Jim_Interp *interp, Jim_CallFrame *parent, Jim_Obj *nsObj)
4949 {
4950 Jim_CallFrame *cf;
4951
4952 if (interp->freeFramesList) {
4953 cf = interp->freeFramesList;
4954 interp->freeFramesList = cf->next;
4955
4956 cf->argv = NULL;
4957 cf->argc = 0;
4958 cf->procArgsObjPtr = NULL;
4959 cf->procBodyObjPtr = NULL;
4960 cf->next = NULL;
4961 cf->staticVars = NULL;
4962 cf->localCommands = NULL;
4963 cf->tailcallObj = NULL;
4964 cf->tailcallCmd = NULL;
4965 }
4966 else {
4967 cf = Jim_Alloc(sizeof(*cf));
4968 memset(cf, 0, sizeof(*cf));
4969
4970 Jim_InitHashTable(&cf->vars, &JimVariablesHashTableType, interp);
4971 }
4972
4973 cf->id = interp->callFrameEpoch++;
4974 cf->parent = parent;
4975 cf->level = parent ? parent->level + 1 : 0;
4976 cf->nsObj = nsObj;
4977 Jim_IncrRefCount(nsObj);
4978
4979 return cf;
4980 }
4981
4982 static int JimDeleteLocalProcs(Jim_Interp *interp, Jim_Stack *localCommands)
4983 {
4984 /* Delete any local procs */
4985 if (localCommands) {
4986 Jim_Obj *cmdNameObj;
4987
4988 while ((cmdNameObj = Jim_StackPop(localCommands)) != NULL) {
4989 Jim_HashEntry *he;
4990 Jim_Obj *fqObjName;
4991 Jim_HashTable *ht = &interp->commands;
4992
4993 const char *fqname = JimQualifyName(interp, Jim_String(cmdNameObj), &fqObjName);
4994
4995 he = Jim_FindHashEntry(ht, fqname);
4996
4997 if (he) {
4998 Jim_Cmd *cmd = Jim_GetHashEntryVal(he);
4999 if (cmd->prevCmd) {
5000 Jim_Cmd *prevCmd = cmd->prevCmd;
5001 cmd->prevCmd = NULL;
5002
5003 /* Delete the old command */
5004 JimDecrCmdRefCount(interp, cmd);
5005
5006 /* And restore the original */
5007 Jim_SetHashVal(ht, he, prevCmd);
5008 }
5009 else {
5010 Jim_DeleteHashEntry(ht, fqname);
5011 }
5012 Jim_InterpIncrProcEpoch(interp);
5013 }
5014 Jim_DecrRefCount(interp, cmdNameObj);
5015 JimFreeQualifiedName(interp, fqObjName);
5016 }
5017 Jim_FreeStack(localCommands);
5018 Jim_Free(localCommands);
5019 }
5020 return JIM_OK;
5021 }
5022
5023 /**
5024 * Run any $jim::defer scripts for the current call frame.
5025 *
5026 * retcode is the return code from the current proc.
5027 *
5028 * Returns the new return code.
5029 */
5030 static int JimInvokeDefer(Jim_Interp *interp, int retcode)
5031 {
5032 Jim_Obj *objPtr;
5033
5034 /* Fast check for the likely case that the variable doesn't exist */
5035 if (Jim_FindHashEntry(&interp->framePtr->vars, "jim::defer") == NULL) {
5036 return retcode;
5037 }
5038
5039 objPtr = Jim_GetVariableStr(interp, "jim::defer", JIM_NONE);
5040
5041 if (objPtr) {
5042 int ret = JIM_OK;
5043 int i;
5044 int listLen = Jim_ListLength(interp, objPtr);
5045 Jim_Obj *resultObjPtr;
5046
5047 Jim_IncrRefCount(objPtr);
5048
5049 /* Need to save away the current interp result and
5050 * restore it if appropriate
5051 */
5052 resultObjPtr = Jim_GetResult(interp);
5053 Jim_IncrRefCount(resultObjPtr);
5054 Jim_SetEmptyResult(interp);
5055
5056 /* Invoke in reverse order */
5057 for (i = listLen; i > 0; i--) {
5058 /* If a defer script returns an error, don't evaluate remaining scripts */
5059 Jim_Obj *scriptObjPtr = Jim_ListGetIndex(interp, objPtr, i - 1);
5060 ret = Jim_EvalObj(interp, scriptObjPtr);
5061 if (ret != JIM_OK) {
5062 break;
5063 }
5064 }
5065
5066 if (ret == JIM_OK || retcode == JIM_ERR) {
5067 /* defer script had no error, or proc had an error so restore proc result */
5068 Jim_SetResult(interp, resultObjPtr);
5069 }
5070 else {
5071 retcode = ret;
5072 }
5073
5074 Jim_DecrRefCount(interp, resultObjPtr);
5075 Jim_DecrRefCount(interp, objPtr);
5076 }
5077 return retcode;
5078 }
5079
5080 #define JIM_FCF_FULL 0 /* Always free the vars hash table */
5081 #define JIM_FCF_REUSE 1 /* Reuse the vars hash table if possible */
5082 static void JimFreeCallFrame(Jim_Interp *interp, Jim_CallFrame *cf, int action)
5083 {
5084 JimDeleteLocalProcs(interp, cf->localCommands);
5085
5086 if (cf->procArgsObjPtr)
5087 Jim_DecrRefCount(interp, cf->procArgsObjPtr);
5088 if (cf->procBodyObjPtr)
5089 Jim_DecrRefCount(interp, cf->procBodyObjPtr);
5090 Jim_DecrRefCount(interp, cf->nsObj);
5091 if (action == JIM_FCF_FULL || cf->vars.size != JIM_HT_INITIAL_SIZE)
5092 Jim_FreeHashTable(&cf->vars);
5093 else {
5094 int i;
5095 Jim_HashEntry **table = cf->vars.table, *he;
5096
5097 for (i = 0; i < JIM_HT_INITIAL_SIZE; i++) {
5098 he = table[i];
5099 while (he != NULL) {
5100 Jim_HashEntry *nextEntry = he->next;
5101 Jim_Var *varPtr = Jim_GetHashEntryVal(he);
5102
5103 Jim_DecrRefCount(interp, varPtr->objPtr);
5104 Jim_Free(Jim_GetHashEntryKey(he));
5105 Jim_Free(varPtr);
5106 Jim_Free(he);
5107 table[i] = NULL;
5108 he = nextEntry;
5109 }
5110 }
5111 cf->vars.used = 0;
5112 }
5113 cf->next = interp->freeFramesList;
5114 interp->freeFramesList = cf;
5115 }
5116
5117
5118 /* -----------------------------------------------------------------------------
5119 * References
5120 * ---------------------------------------------------------------------------*/
5121 #if defined(JIM_REFERENCES) && !defined(JIM_BOOTSTRAP)
5122
5123 /* References HashTable Type.
5124 *
5125 * Keys are unsigned long integers, dynamically allocated for now but in the
5126 * future it's worth to cache this 4 bytes objects. Values are pointers
5127 * to Jim_References. */
5128 static void JimReferencesHTValDestructor(void *interp, void *val)
5129 {
5130 Jim_Reference *refPtr = (void *)val;
5131
5132 Jim_DecrRefCount(interp, refPtr->objPtr);
5133 if (refPtr->finalizerCmdNamePtr != NULL) {
5134 Jim_DecrRefCount(interp, refPtr->finalizerCmdNamePtr);
5135 }
5136 Jim_Free(val);
5137 }
5138
5139 static unsigned int JimReferencesHTHashFunction(const void *key)
5140 {
5141 /* Only the least significant bits are used. */
5142 const unsigned long *widePtr = key;
5143 unsigned int intValue = (unsigned int)*widePtr;
5144
5145 return Jim_IntHashFunction(intValue);
5146 }
5147
5148 static void *JimReferencesHTKeyDup(void *privdata, const void *key)
5149 {
5150 void *copy = Jim_Alloc(sizeof(unsigned long));
5151
5152 JIM_NOTUSED(privdata);
5153
5154 memcpy(copy, key, sizeof(unsigned long));
5155 return copy;
5156 }
5157
5158 static int JimReferencesHTKeyCompare(void *privdata, const void *key1, const void *key2)
5159 {
5160 JIM_NOTUSED(privdata);
5161
5162 return memcmp(key1, key2, sizeof(unsigned long)) == 0;
5163 }
5164
5165 static void JimReferencesHTKeyDestructor(void *privdata, void *key)
5166 {
5167 JIM_NOTUSED(privdata);
5168
5169 Jim_Free(key);
5170 }
5171
5172 static const Jim_HashTableType JimReferencesHashTableType = {
5173 JimReferencesHTHashFunction, /* hash function */
5174 JimReferencesHTKeyDup, /* key dup */
5175 NULL, /* val dup */
5176 JimReferencesHTKeyCompare, /* key compare */
5177 JimReferencesHTKeyDestructor, /* key destructor */
5178 JimReferencesHTValDestructor /* val destructor */
5179 };
5180
5181 /* -----------------------------------------------------------------------------
5182 * Reference object type and References API
5183 * ---------------------------------------------------------------------------*/
5184
5185 /* The string representation of references has two features in order
5186 * to make the GC faster. The first is that every reference starts
5187 * with a non common character '<', in order to make the string matching
5188 * faster. The second is that the reference string rep is 42 characters
5189 * in length, this means that it is not necessary to check any object with a string
5190 * repr < 42, and usually there aren't many of these objects. */
5191
5192 #define JIM_REFERENCE_SPACE (35+JIM_REFERENCE_TAGLEN)
5193
5194 static int JimFormatReference(char *buf, Jim_Reference *refPtr, unsigned long id)
5195 {
5196 const char *fmt = "<reference.<%s>.%020lu>";
5197
5198 sprintf(buf, fmt, refPtr->tag, id);
5199 return JIM_REFERENCE_SPACE;
5200 }
5201
5202 static void UpdateStringOfReference(struct Jim_Obj *objPtr);
5203
5204 static const Jim_ObjType referenceObjType = {
5205 "reference",
5206 NULL,
5207 NULL,
5208 UpdateStringOfReference,
5209 JIM_TYPE_REFERENCES,
5210 };
5211
5212 static void UpdateStringOfReference(struct Jim_Obj *objPtr)
5213 {
5214 char buf[JIM_REFERENCE_SPACE + 1];
5215
5216 JimFormatReference(buf, objPtr->internalRep.refValue.refPtr, objPtr->internalRep.refValue.id);
5217 JimSetStringBytes(objPtr, buf);
5218 }
5219
5220 /* returns true if 'c' is a valid reference tag character.
5221 * i.e. inside the range [_a-zA-Z0-9] */
5222 static int isrefchar(int c)
5223 {
5224 return (c == '_' || isalnum(c));
5225 }
5226
5227 static int SetReferenceFromAny(Jim_Interp *interp, Jim_Obj *objPtr)
5228 {
5229 unsigned long value;
5230 int i, len;
5231 const char *str, *start, *end;
5232 char refId[21];
5233 Jim_Reference *refPtr;
5234 Jim_HashEntry *he;
5235 char *endptr;
5236
5237 /* Get the string representation */
5238 str = Jim_GetString(objPtr, &len);
5239 /* Check if it looks like a reference */
5240 if (len < JIM_REFERENCE_SPACE)
5241 goto badformat;
5242 /* Trim spaces */
5243 start = str;
5244 end = str + len - 1;
5245 while (*start == ' ')
5246 start++;
5247 while (*end == ' ' && end > start)
5248 end--;
5249 if (end - start + 1 != JIM_REFERENCE_SPACE)
5250 goto badformat;
5251 /* <reference.<1234567>.%020> */
5252 if (memcmp(start, "<reference.<", 12) != 0)
5253 goto badformat;
5254 if (start[12 + JIM_REFERENCE_TAGLEN] != '>' || end[0] != '>')
5255 goto badformat;
5256 /* The tag can't contain chars other than a-zA-Z0-9 + '_'. */
5257 for (i = 0; i < JIM_REFERENCE_TAGLEN; i++) {
5258 if (!isrefchar(start[12 + i]))
5259 goto badformat;
5260 }
5261 /* Extract info from the reference. */
5262 memcpy(refId, start + 14 + JIM_REFERENCE_TAGLEN, 20);
5263 refId[20] = '\0';
5264 /* Try to convert the ID into an unsigned long */
5265 value = strtoul(refId, &endptr, 10);
5266 if (JimCheckConversion(refId, endptr) != JIM_OK)
5267 goto badformat;
5268 /* Check if the reference really exists! */
5269 he = Jim_FindHashEntry(&interp->references, &value);
5270 if (he == NULL) {
5271 Jim_SetResultFormatted(interp, "invalid reference id \"%#s\"", objPtr);
5272 return JIM_ERR;
5273 }
5274 refPtr = Jim_GetHashEntryVal(he);
5275 /* Free the old internal repr and set the new one. */
5276 Jim_FreeIntRep(interp, objPtr);
5277 objPtr->typePtr = &referenceObjType;
5278 objPtr->internalRep.refValue.id = value;
5279 objPtr->internalRep.refValue.refPtr = refPtr;
5280 return JIM_OK;
5281
5282 badformat:
5283 Jim_SetResultFormatted(interp, "expected reference but got \"%#s\"", objPtr);
5284 return JIM_ERR;
5285 }
5286
5287 /* Returns a new reference pointing to objPtr, having cmdNamePtr
5288 * as finalizer command (or NULL if there is no finalizer).
5289 * The returned reference object has refcount = 0. */
5290 Jim_Obj *Jim_NewReference(Jim_Interp *interp, Jim_Obj *objPtr, Jim_Obj *tagPtr, Jim_Obj *cmdNamePtr)
5291 {
5292 struct Jim_Reference *refPtr;
5293 unsigned long id;
5294 Jim_Obj *refObjPtr;
5295 const char *tag;
5296 int tagLen, i;
5297
5298 /* Perform the Garbage Collection if needed. */
5299 Jim_CollectIfNeeded(interp);
5300
5301 refPtr = Jim_Alloc(sizeof(*refPtr));
5302 refPtr->objPtr = objPtr;
5303 Jim_IncrRefCount(objPtr);
5304 refPtr->finalizerCmdNamePtr = cmdNamePtr;
5305 if (cmdNamePtr)
5306 Jim_IncrRefCount(cmdNamePtr);
5307 id = interp->referenceNextId++;
5308 Jim_AddHashEntry(&interp->references, &id, refPtr);
5309 refObjPtr = Jim_NewObj(interp);
5310 refObjPtr->typePtr = &referenceObjType;
5311 refObjPtr->bytes = NULL;
5312 refObjPtr->internalRep.refValue.id = id;
5313 refObjPtr->internalRep.refValue.refPtr = refPtr;
5314 interp->referenceNextId++;
5315 /* Set the tag. Trimmed at JIM_REFERENCE_TAGLEN. Everything
5316 * that does not pass the 'isrefchar' test is replaced with '_' */
5317 tag = Jim_GetString(tagPtr, &tagLen);
5318 if (tagLen > JIM_REFERENCE_TAGLEN)
5319 tagLen = JIM_REFERENCE_TAGLEN;
5320 for (i = 0; i < JIM_REFERENCE_TAGLEN; i++) {
5321 if (i < tagLen && isrefchar(tag[i]))
5322 refPtr->tag[i] = tag[i];
5323 else
5324 refPtr->tag[i] = '_';
5325 }
5326 refPtr->tag[JIM_REFERENCE_TAGLEN] = '\0';
5327 return refObjPtr;
5328 }
5329
5330 Jim_Reference *Jim_GetReference(Jim_Interp *interp, Jim_Obj *objPtr)
5331 {
5332 if (objPtr->typePtr != &referenceObjType && SetReferenceFromAny(interp, objPtr) == JIM_ERR)
5333 return NULL;
5334 return objPtr->internalRep.refValue.refPtr;
5335 }
5336
5337 int Jim_SetFinalizer(Jim_Interp *interp, Jim_Obj *objPtr, Jim_Obj *cmdNamePtr)
5338 {
5339 Jim_Reference *refPtr;
5340
5341 if ((refPtr = Jim_GetReference(interp, objPtr)) == NULL)
5342 return JIM_ERR;
5343 Jim_IncrRefCount(cmdNamePtr);
5344 if (refPtr->finalizerCmdNamePtr)
5345 Jim_DecrRefCount(interp, refPtr->finalizerCmdNamePtr);
5346 refPtr->finalizerCmdNamePtr = cmdNamePtr;
5347 return JIM_OK;
5348 }
5349
5350 int Jim_GetFinalizer(Jim_Interp *interp, Jim_Obj *objPtr, Jim_Obj **cmdNamePtrPtr)
5351 {
5352 Jim_Reference *refPtr;
5353
5354 if ((refPtr = Jim_GetReference(interp, objPtr)) == NULL)
5355 return JIM_ERR;
5356 *cmdNamePtrPtr = refPtr->finalizerCmdNamePtr;
5357 return JIM_OK;
5358 }
5359
5360 /* -----------------------------------------------------------------------------
5361 * References Garbage Collection
5362 * ---------------------------------------------------------------------------*/
5363
5364 /* This the hash table type for the "MARK" phase of the GC */
5365 static const Jim_HashTableType JimRefMarkHashTableType = {
5366 JimReferencesHTHashFunction, /* hash function */
5367 JimReferencesHTKeyDup, /* key dup */
5368 NULL, /* val dup */
5369 JimReferencesHTKeyCompare, /* key compare */
5370 JimReferencesHTKeyDestructor, /* key destructor */
5371 NULL /* val destructor */
5372 };
5373
5374 /* Performs the garbage collection. */
5375 int Jim_Collect(Jim_Interp *interp)
5376 {
5377 int collected = 0;
5378 Jim_HashTable marks;
5379 Jim_HashTableIterator htiter;
5380 Jim_HashEntry *he;
5381 Jim_Obj *objPtr;
5382
5383 /* Avoid recursive calls */
5384 if (interp->lastCollectId == -1) {
5385 /* Jim_Collect() already running. Return just now. */
5386 return 0;
5387 }
5388 interp->lastCollectId = -1;
5389
5390 /* Mark all the references found into the 'mark' hash table.
5391 * The references are searched in every live object that
5392 * is of a type that can contain references. */
5393 Jim_InitHashTable(&marks, &JimRefMarkHashTableType, NULL);
5394 objPtr = interp->liveList;
5395 while (objPtr) {
5396 if (objPtr->typePtr == NULL || objPtr->typePtr->flags & JIM_TYPE_REFERENCES) {
5397 const char *str, *p;
5398 int len;
5399
5400 /* If the object is of type reference, to get the
5401 * Id is simple... */
5402 if (objPtr->typePtr == &referenceObjType) {
5403 Jim_AddHashEntry(&marks, &objPtr->internalRep.refValue.id, NULL);
5404 #ifdef JIM_DEBUG_GC
5405 printf("MARK (reference): %d refcount: %d\n",
5406 (int)objPtr->internalRep.refValue.id, objPtr->refCount);
5407 #endif
5408 objPtr = objPtr->nextObjPtr;
5409 continue;
5410 }
5411 /* Get the string repr of the object we want
5412 * to scan for references. */
5413 p = str = Jim_GetString(objPtr, &len);
5414 /* Skip objects too little to contain references. */
5415 if (len < JIM_REFERENCE_SPACE) {
5416 objPtr = objPtr->nextObjPtr;
5417 continue;
5418 }
5419 /* Extract references from the object string repr. */
5420 while (1) {
5421 int i;
5422 unsigned long id;
5423
5424 if ((p = strstr(p, "<reference.<")) == NULL)
5425 break;
5426 /* Check if it's a valid reference. */
5427 if (len - (p - str) < JIM_REFERENCE_SPACE)
5428 break;
5429 if (p[41] != '>' || p[19] != '>' || p[20] != '.')
5430 break;
5431 for (i = 21; i <= 40; i++)
5432 if (!isdigit(UCHAR(p[i])))
5433 break;
5434 /* Get the ID */
5435 id = strtoul(p + 21, NULL, 10);
5436
5437 /* Ok, a reference for the given ID
5438 * was found. Mark it. */
5439 Jim_AddHashEntry(&marks, &id, NULL);
5440 #ifdef JIM_DEBUG_GC
5441 printf("MARK: %d\n", (int)id);
5442 #endif
5443 p += JIM_REFERENCE_SPACE;
5444 }
5445 }
5446 objPtr = objPtr->nextObjPtr;
5447 }
5448
5449 /* Run the references hash table to destroy every reference that
5450 * is not referenced outside (not present in the mark HT). */
5451 JimInitHashTableIterator(&interp->references, &htiter);
5452 while ((he = Jim_NextHashEntry(&htiter)) != NULL) {
5453 const unsigned long *refId;
5454 Jim_Reference *refPtr;
5455
5456 refId = he->key;
5457 /* Check if in the mark phase we encountered
5458 * this reference. */
5459 if (Jim_FindHashEntry(&marks, refId) == NULL) {
5460 #ifdef JIM_DEBUG_GC
5461 printf("COLLECTING %d\n", (int)*refId);
5462 #endif
5463 collected++;
5464 /* Drop the reference, but call the
5465 * finalizer first if registered. */
5466 refPtr = Jim_GetHashEntryVal(he);
5467 if (refPtr->finalizerCmdNamePtr) {
5468 char *refstr = Jim_Alloc(JIM_REFERENCE_SPACE + 1);
5469 Jim_Obj *objv[3], *oldResult;
5470
5471 JimFormatReference(refstr, refPtr, *refId);
5472
5473 objv[0] = refPtr->finalizerCmdNamePtr;
5474 objv[1] = Jim_NewStringObjNoAlloc(interp, refstr, JIM_REFERENCE_SPACE);
5475 objv[2] = refPtr->objPtr;
5476
5477 /* Drop the reference itself */
5478 /* Avoid the finaliser being freed here */
5479 Jim_IncrRefCount(objv[0]);
5480 /* Don't remove the reference from the hash table just yet
5481 * since that will free refPtr, and hence refPtr->objPtr
5482 */
5483
5484 /* Call the finalizer. Errors ignored. (should we use bgerror?) */
5485 oldResult = interp->result;
5486 Jim_IncrRefCount(oldResult);
5487 Jim_EvalObjVector(interp, 3, objv);
5488 Jim_SetResult(interp, oldResult);
5489 Jim_DecrRefCount(interp, oldResult);
5490
5491 Jim_DecrRefCount(interp, objv[0]);
5492 }
5493 Jim_DeleteHashEntry(&interp->references, refId);
5494 }
5495 }
5496 Jim_FreeHashTable(&marks);
5497 interp->lastCollectId = interp->referenceNextId;
5498 interp->lastCollectTime = time(NULL);
5499 return collected;
5500 }
5501
5502 #define JIM_COLLECT_ID_PERIOD 5000
5503 #define JIM_COLLECT_TIME_PERIOD 300
5504
5505 void Jim_CollectIfNeeded(Jim_Interp *interp)
5506 {
5507 unsigned long elapsedId;
5508 int elapsedTime;
5509
5510 elapsedId = interp->referenceNextId - interp->lastCollectId;
5511 elapsedTime = time(NULL) - interp->lastCollectTime;
5512
5513
5514 if (elapsedId > JIM_COLLECT_ID_PERIOD || elapsedTime > JIM_COLLECT_TIME_PERIOD) {
5515 Jim_Collect(interp);
5516 }
5517 }
5518 #endif /* JIM_REFERENCES && !JIM_BOOTSTRAP */
5519
5520 int Jim_IsBigEndian(void)
5521 {
5522 union {
5523 unsigned short s;
5524 unsigned char c[2];
5525 } uval = {0x0102};
5526
5527 return uval.c[0] == 1;
5528 }
5529
5530 /* -----------------------------------------------------------------------------
5531 * Interpreter related functions
5532 * ---------------------------------------------------------------------------*/
5533
5534 Jim_Interp *Jim_CreateInterp(void)
5535 {
5536 Jim_Interp *i = Jim_Alloc(sizeof(*i));
5537
5538 memset(i, 0, sizeof(*i));
5539
5540 i->maxCallFrameDepth = JIM_MAX_CALLFRAME_DEPTH;
5541 i->maxEvalDepth = JIM_MAX_EVAL_DEPTH;
5542 i->lastCollectTime = time(NULL);
5543
5544 /* Note that we can create objects only after the
5545 * interpreter liveList and freeList pointers are
5546 * initialized to NULL. */
5547 Jim_InitHashTable(&i->commands, &JimCommandsHashTableType, i);
5548 #ifdef JIM_REFERENCES
5549 Jim_InitHashTable(&i->references, &JimReferencesHashTableType, i);
5550 #endif
5551 Jim_InitHashTable(&i->assocData, &JimAssocDataHashTableType, i);
5552 Jim_InitHashTable(&i->packages, &JimPackageHashTableType, NULL);
5553 i->emptyObj = Jim_NewEmptyStringObj(i);
5554 i->trueObj = Jim_NewIntObj(i, 1);
5555 i->falseObj = Jim_NewIntObj(i, 0);
5556 i->framePtr = i->topFramePtr = JimCreateCallFrame(i, NULL, i->emptyObj);
5557 i->errorFileNameObj = i->emptyObj;
5558 i->result = i->emptyObj;
5559 i->stackTrace = Jim_NewListObj(i, NULL, 0);
5560 i->unknown = Jim_NewStringObj(i, "unknown", -1);
5561 i->errorProc = i->emptyObj;
5562 i->currentScriptObj = Jim_NewEmptyStringObj(i);
5563 i->nullScriptObj = Jim_NewEmptyStringObj(i);
5564 Jim_IncrRefCount(i->emptyObj);
5565 Jim_IncrRefCount(i->errorFileNameObj);
5566 Jim_IncrRefCount(i->result);
5567 Jim_IncrRefCount(i->stackTrace);
5568 Jim_IncrRefCount(i->unknown);
5569 Jim_IncrRefCount(i->currentScriptObj);
5570 Jim_IncrRefCount(i->nullScriptObj);
5571 Jim_IncrRefCount(i->errorProc);
5572 Jim_IncrRefCount(i->trueObj);
5573 Jim_IncrRefCount(i->falseObj);
5574
5575 /* Initialize key variables every interpreter should contain */
5576 Jim_SetVariableStrWithStr(i, JIM_LIBPATH, TCL_LIBRARY);
5577 Jim_SetVariableStrWithStr(i, JIM_INTERACTIVE, "0");
5578
5579 Jim_SetVariableStrWithStr(i, "tcl_platform(engine)", "Jim");
5580 Jim_SetVariableStrWithStr(i, "tcl_platform(os)", TCL_PLATFORM_OS);
5581 Jim_SetVariableStrWithStr(i, "tcl_platform(platform)", TCL_PLATFORM_PLATFORM);
5582 Jim_SetVariableStrWithStr(i, "tcl_platform(pathSeparator)", TCL_PLATFORM_PATH_SEPARATOR);
5583 Jim_SetVariableStrWithStr(i, "tcl_platform(byteOrder)", Jim_IsBigEndian() ? "bigEndian" : "littleEndian");
5584 Jim_SetVariableStrWithStr(i, "tcl_platform(threaded)", "0");
5585 Jim_SetVariableStr(i, "tcl_platform(pointerSize)", Jim_NewIntObj(i, sizeof(void *)));
5586 Jim_SetVariableStr(i, "tcl_platform(wordSize)", Jim_NewIntObj(i, sizeof(jim_wide)));
5587
5588 return i;
5589 }
5590
5591 void Jim_FreeInterp(Jim_Interp *i)
5592 {
5593 Jim_CallFrame *cf, *cfx;
5594
5595 Jim_Obj *objPtr, *nextObjPtr;
5596
5597 /* Free the active call frames list - must be done before i->commands is destroyed */
5598 for (cf = i->framePtr; cf; cf = cfx) {
5599 /* Note that we ignore any errors */
5600 JimInvokeDefer(i, JIM_OK);
5601 cfx = cf->parent;
5602 JimFreeCallFrame(i, cf, JIM_FCF_FULL);
5603 }
5604
5605 Jim_DecrRefCount(i, i->emptyObj);
5606 Jim_DecrRefCount(i, i->trueObj);
5607 Jim_DecrRefCount(i, i->falseObj);
5608 Jim_DecrRefCount(i, i->result);
5609 Jim_DecrRefCount(i, i->stackTrace);
5610 Jim_DecrRefCount(i, i->errorProc);
5611 Jim_DecrRefCount(i, i->unknown);
5612 Jim_DecrRefCount(i, i->errorFileNameObj);
5613 Jim_DecrRefCount(i, i->currentScriptObj);
5614 Jim_DecrRefCount(i, i->nullScriptObj);
5615 Jim_FreeHashTable(&i->commands);
5616 #ifdef JIM_REFERENCES
5617 Jim_FreeHashTable(&i->references);
5618 #endif
5619 Jim_FreeHashTable(&i->packages);
5620 Jim_Free(i->prngState);
5621 Jim_FreeHashTable(&i->assocData);
5622
5623 /* Check that the live object list is empty, otherwise
5624 * there is a memory leak. */
5625 #ifdef JIM_MAINTAINER
5626 if (i->liveList != NULL) {
5627 objPtr = i->liveList;
5628
5629 printf("\n-------------------------------------\n");
5630 printf("Objects still in the free list:\n");
5631 while (objPtr) {
5632 const char *type = objPtr->typePtr ? objPtr->typePtr->name : "string";
5633 Jim_String(objPtr);
5634
5635 if (objPtr->bytes && strlen(objPtr->bytes) > 20) {
5636 printf("%p (%d) %-10s: '%.20s...'\n",
5637 (void *)objPtr, objPtr->refCount, type, objPtr->bytes);
5638 }
5639 else {
5640 printf("%p (%d) %-10s: '%s'\n",
5641 (void *)objPtr, objPtr->refCount, type, objPtr->bytes ? objPtr->bytes : "(null)");
5642 }
5643 if (objPtr->typePtr == &sourceObjType) {
5644 printf("FILE %s LINE %d\n",
5645 Jim_String(objPtr->internalRep.sourceValue.fileNameObj),
5646 objPtr->internalRep.sourceValue.lineNumber);
5647 }
5648 objPtr = objPtr->nextObjPtr;
5649 }
5650 printf("-------------------------------------\n\n");
5651 JimPanic((1, "Live list non empty freeing the interpreter! Leak?"));
5652 }
5653 #endif
5654
5655 /* Free all the freed objects. */
5656 objPtr = i->freeList;
5657 while (objPtr) {
5658 nextObjPtr = objPtr->nextObjPtr;
5659 Jim_Free(objPtr);
5660 objPtr = nextObjPtr;
5661 }
5662
5663 /* Free the free call frames list */
5664 for (cf = i->freeFramesList; cf; cf = cfx) {
5665 cfx = cf->next;
5666 if (cf->vars.table)
5667 Jim_FreeHashTable(&cf->vars);
5668 Jim_Free(cf);
5669 }
5670
5671 /* Free the interpreter structure. */
5672 Jim_Free(i);
5673 }
5674
5675 /* Returns the call frame relative to the level represented by
5676 * levelObjPtr. If levelObjPtr == NULL, the level is assumed to be '1'.
5677 *
5678 * This function accepts the 'level' argument in the form
5679 * of the commands [uplevel] and [upvar].
5680 *
5681 * Returns NULL on error.
5682 *
5683 * Note: for a function accepting a relative integer as level suitable
5684 * for implementation of [info level ?level?], see JimGetCallFrameByInteger()
5685 */
5686 Jim_CallFrame *Jim_GetCallFrameByLevel(Jim_Interp *interp, Jim_Obj *levelObjPtr)
5687 {
5688 long level;
5689 const char *str;
5690 Jim_CallFrame *framePtr;
5691
5692 if (levelObjPtr) {
5693 str = Jim_String(levelObjPtr);
5694 if (str[0] == '#') {
5695 char *endptr;
5696
5697 level = jim_strtol(str + 1, &endptr);
5698 if (str[1] == '\0' || endptr[0] != '\0') {
5699 level = -1;
5700 }
5701 }
5702 else {
5703 if (Jim_GetLong(interp, levelObjPtr, &level) != JIM_OK || level < 0) {
5704 level = -1;
5705 }
5706 else {
5707 /* Convert from a relative to an absolute level */
5708 level = interp->framePtr->level - level;
5709 }
5710 }
5711 }
5712 else {
5713 str = "1"; /* Needed to format the error message. */
5714 level = interp->framePtr->level - 1;
5715 }
5716
5717 if (level == 0) {
5718 return interp->topFramePtr;
5719 }
5720 if (level > 0) {
5721 /* Lookup */
5722 for (framePtr = interp->framePtr; framePtr; framePtr = framePtr->parent) {
5723 if (framePtr->level == level) {
5724 return framePtr;
5725 }
5726 }
5727 }
5728
5729 Jim_SetResultFormatted(interp, "bad level \"%s\"", str);
5730 return NULL;
5731 }
5732
5733 /* Similar to Jim_GetCallFrameByLevel() but the level is specified
5734 * as a relative integer like in the [info level ?level?] command.
5735 **/
5736 static Jim_CallFrame *JimGetCallFrameByInteger(Jim_Interp *interp, Jim_Obj *levelObjPtr)
5737 {
5738 long level;
5739 Jim_CallFrame *framePtr;
5740
5741 if (Jim_GetLong(interp, levelObjPtr, &level) == JIM_OK) {
5742 if (level <= 0) {
5743 /* Convert from a relative to an absolute level */
5744 level = interp->framePtr->level + level;
5745 }
5746
5747 if (level == 0) {
5748 return interp->topFramePtr;
5749 }
5750
5751 /* Lookup */
5752 for (framePtr = interp->framePtr; framePtr; framePtr = framePtr->parent) {
5753 if (framePtr->level == level) {
5754 return framePtr;
5755 }
5756 }
5757 }
5758
5759 Jim_SetResultFormatted(interp, "bad level \"%#s\"", levelObjPtr);
5760 return NULL;
5761 }
5762
5763 static void JimResetStackTrace(Jim_Interp *interp)
5764 {
5765 Jim_DecrRefCount(interp, interp->stackTrace);
5766 interp->stackTrace = Jim_NewListObj(interp, NULL, 0);
5767 Jim_IncrRefCount(interp->stackTrace);
5768 }
5769
5770 static void JimSetStackTrace(Jim_Interp *interp, Jim_Obj *stackTraceObj)
5771 {
5772 int len;
5773
5774 /* Increment reference first in case these are the same object */
5775 Jim_IncrRefCount(stackTraceObj);
5776 Jim_DecrRefCount(interp, interp->stackTrace);
5777 interp->stackTrace = stackTraceObj;
5778 interp->errorFlag = 1;
5779
5780 /* This is a bit ugly.
5781 * If the filename of the last entry of the stack trace is empty,
5782 * the next stack level should be added.
5783 */
5784 len = Jim_ListLength(interp, interp->stackTrace);
5785 if (len >= 3) {
5786 if (Jim_Length(Jim_ListGetIndex(interp, interp->stackTrace, len - 2)) == 0) {
5787 interp->addStackTrace = 1;
5788 }
5789 }
5790 }
5791
5792 static void JimAppendStackTrace(Jim_Interp *interp, const char *procname,
5793 Jim_Obj *fileNameObj, int linenr)
5794 {
5795 if (strcmp(procname, "unknown") == 0) {
5796 procname = "";
5797 }
5798 if (!*procname && !Jim_Length(fileNameObj)) {
5799 /* No useful info here */
5800 return;
5801 }
5802
5803 if (Jim_IsShared(interp->stackTrace)) {
5804 Jim_DecrRefCount(interp, interp->stackTrace);
5805 interp->stackTrace = Jim_DuplicateObj(interp, interp->stackTrace);
5806 Jim_IncrRefCount(interp->stackTrace);
5807 }
5808
5809 /* If we have no procname but the previous element did, merge with that frame */
5810 if (!*procname && Jim_Length(fileNameObj)) {
5811 /* Just a filename. Check the previous entry */
5812 int len = Jim_ListLength(interp, interp->stackTrace);
5813
5814 if (len >= 3) {
5815 Jim_Obj *objPtr = Jim_ListGetIndex(interp, interp->stackTrace, len - 3);
5816 if (Jim_Length(objPtr)) {
5817 /* Yes, the previous level had procname */
5818 objPtr = Jim_ListGetIndex(interp, interp->stackTrace, len - 2);
5819 if (Jim_Length(objPtr) == 0) {
5820 /* But no filename, so merge the new info with that frame */
5821 ListSetIndex(interp, interp->stackTrace, len - 2, fileNameObj, 0);
5822 ListSetIndex(interp, interp->stackTrace, len - 1, Jim_NewIntObj(interp, linenr), 0);
5823 return;
5824 }
5825 }
5826 }
5827 }
5828
5829 Jim_ListAppendElement(interp, interp->stackTrace, Jim_NewStringObj(interp, procname, -1));
5830 Jim_ListAppendElement(interp, interp->stackTrace, fileNameObj);
5831 Jim_ListAppendElement(interp, interp->stackTrace, Jim_NewIntObj(interp, linenr));
5832 }
5833
5834 int Jim_SetAssocData(Jim_Interp *interp, const char *key, Jim_InterpDeleteProc * delProc,
5835 void *data)
5836 {
5837 AssocDataValue *assocEntryPtr = (AssocDataValue *) Jim_Alloc(sizeof(AssocDataValue));
5838
5839 assocEntryPtr->delProc = delProc;
5840 assocEntryPtr->data = data;
5841 return Jim_AddHashEntry(&interp->assocData, key, assocEntryPtr);
5842 }
5843
5844 void *Jim_GetAssocData(Jim_Interp *interp, const char *key)
5845 {
5846 Jim_HashEntry *entryPtr = Jim_FindHashEntry(&interp->assocData, key);
5847
5848 if (entryPtr != NULL) {
5849 AssocDataValue *assocEntryPtr = Jim_GetHashEntryVal(entryPtr);
5850 return assocEntryPtr->data;
5851 }
5852 return NULL;
5853 }
5854
5855 int Jim_DeleteAssocData(Jim_Interp *interp, const char *key)
5856 {
5857 return Jim_DeleteHashEntry(&interp->assocData, key);
5858 }
5859
5860 int Jim_GetExitCode(Jim_Interp *interp)
5861 {
5862 return interp->exitCode;
5863 }
5864
5865 /* -----------------------------------------------------------------------------
5866 * Integer object
5867 * ---------------------------------------------------------------------------*/
5868 static void UpdateStringOfInt(struct Jim_Obj *objPtr);
5869 static int SetIntFromAny(Jim_Interp *interp, Jim_Obj *objPtr, int flags);
5870
5871 static const Jim_ObjType intObjType = {
5872 "int",
5873 NULL,
5874 NULL,
5875 UpdateStringOfInt,
5876 JIM_TYPE_NONE,
5877 };
5878
5879 /* A coerced double is closer to an int than a double.
5880 * It is an int value temporarily masquerading as a double value.
5881 * i.e. it has the same string value as an int and Jim_GetWide()
5882 * succeeds, but also Jim_GetDouble() returns the value directly.
5883 */
5884 static const Jim_ObjType coercedDoubleObjType = {
5885 "coerced-double",
5886 NULL,
5887 NULL,
5888 UpdateStringOfInt,
5889 JIM_TYPE_NONE,
5890 };
5891
5892
5893 static void UpdateStringOfInt(struct Jim_Obj *objPtr)
5894 {
5895 char buf[JIM_INTEGER_SPACE + 1];
5896 jim_wide wideValue = JimWideValue(objPtr);
5897 int pos = 0;
5898
5899 if (wideValue == 0) {
5900 buf[pos++] = '0';
5901 }
5902 else {
5903 char tmp[JIM_INTEGER_SPACE];
5904 int num = 0;
5905 int i;
5906
5907 if (wideValue < 0) {
5908 buf[pos++] = '-';
5909 i = wideValue % 10;
5910 /* C89 is implementation defined as to whether (-106 % 10) is -6 or 4,
5911 * whereas C99 is always -6
5912 * coverity[dead_error_line]
5913 */
5914 tmp[num++] = (i > 0) ? (10 - i) : -i;
5915 wideValue /= -10;
5916 }
5917
5918 while (wideValue) {
5919 tmp[num++] = wideValue % 10;
5920 wideValue /= 10;
5921 }
5922
5923 for (i = 0; i < num; i++) {
5924 buf[pos++] = '0' + tmp[num - i - 1];
5925 }
5926 }
5927 buf[pos] = 0;
5928
5929 JimSetStringBytes(objPtr, buf);
5930 }
5931
5932 static int SetIntFromAny(Jim_Interp *interp, Jim_Obj *objPtr, int flags)
5933 {
5934 jim_wide wideValue;
5935 const char *str;
5936
5937 if (objPtr->typePtr == &coercedDoubleObjType) {
5938 /* Simple switch */
5939 objPtr->typePtr = &intObjType;
5940 return JIM_OK;
5941 }
5942
5943 /* Get the string representation */
5944 str = Jim_String(objPtr);
5945 /* Try to convert into a jim_wide */
5946 if (Jim_StringToWide(str, &wideValue, 0) != JIM_OK) {
5947 if (flags & JIM_ERRMSG) {
5948 Jim_SetResultFormatted(interp, "expected integer but got \"%#s\"", objPtr);
5949 }
5950 return JIM_ERR;
5951 }
5952 if ((wideValue == JIM_WIDE_MIN || wideValue == JIM_WIDE_MAX) && errno == ERANGE) {
5953 Jim_SetResultString(interp, "Integer value too big to be represented", -1);
5954 return JIM_ERR;
5955 }
5956 /* Free the old internal repr and set the new one. */
5957 Jim_FreeIntRep(interp, objPtr);
5958 objPtr->typePtr = &intObjType;
5959 objPtr->internalRep.wideValue = wideValue;
5960 return JIM_OK;
5961 }
5962
5963 #ifdef JIM_OPTIMIZATION
5964 static int JimIsWide(Jim_Obj *objPtr)
5965 {
5966 return objPtr->typePtr == &intObjType;
5967 }
5968 #endif
5969
5970 int Jim_GetWide(Jim_Interp *interp, Jim_Obj *objPtr, jim_wide * widePtr)
5971 {
5972 if (objPtr->typePtr != &intObjType && SetIntFromAny(interp, objPtr, JIM_ERRMSG) == JIM_ERR)
5973 return JIM_ERR;
5974 *widePtr = JimWideValue(objPtr);
5975 return JIM_OK;
5976 }
5977
5978 /* Get a wide but does not set an error if the format is bad. */
5979 static int JimGetWideNoErr(Jim_Interp *interp, Jim_Obj *objPtr, jim_wide * widePtr)
5980 {
5981 if (objPtr->typePtr != &intObjType && SetIntFromAny(interp, objPtr, JIM_NONE) == JIM_ERR)
5982 return JIM_ERR;
5983 *widePtr = JimWideValue(objPtr);
5984 return JIM_OK;
5985 }
5986
5987 int Jim_GetLong(Jim_Interp *interp, Jim_Obj *objPtr, long *longPtr)
5988 {
5989 jim_wide wideValue;
5990 int retval;
5991
5992 retval = Jim_GetWide(interp, objPtr, &wideValue);
5993 if (retval == JIM_OK) {
5994 *longPtr = (long)wideValue;
5995 return JIM_OK;
5996 }
5997 return JIM_ERR;
5998 }
5999
6000 Jim_Obj *Jim_NewIntObj(Jim_Interp *interp, jim_wide wideValue)
6001 {
6002 Jim_Obj *objPtr;
6003
6004 objPtr = Jim_NewObj(interp);
6005 objPtr->typePtr = &intObjType;
6006 objPtr->bytes = NULL;
6007 objPtr->internalRep.wideValue = wideValue;
6008 return objPtr;
6009 }
6010
6011 /* -----------------------------------------------------------------------------
6012 * Double object
6013 * ---------------------------------------------------------------------------*/
6014 #define JIM_DOUBLE_SPACE 30
6015
6016 static void UpdateStringOfDouble(struct Jim_Obj *objPtr);
6017 static int SetDoubleFromAny(Jim_Interp *interp, Jim_Obj *objPtr);
6018
6019 static const Jim_ObjType doubleObjType = {
6020 "double",
6021 NULL,
6022 NULL,
6023 UpdateStringOfDouble,
6024 JIM_TYPE_NONE,
6025 };
6026
6027 #ifndef HAVE_ISNAN
6028 #undef isnan
6029 #define isnan(X) ((X) != (X))
6030 #endif
6031 #ifndef HAVE_ISINF
6032 #undef isinf
6033 #define isinf(X) (1.0 / (X) == 0.0)
6034 #endif
6035
6036 static void UpdateStringOfDouble(struct Jim_Obj *objPtr)
6037 {
6038 double value = objPtr->internalRep.doubleValue;
6039
6040 if (isnan(value)) {
6041 JimSetStringBytes(objPtr, "NaN");
6042 return;
6043 }
6044 if (isinf(value)) {
6045 if (value < 0) {
6046 JimSetStringBytes(objPtr, "-Inf");
6047 }
6048 else {
6049 JimSetStringBytes(objPtr, "Inf");
6050 }
6051 return;
6052 }
6053 {
6054 char buf[JIM_DOUBLE_SPACE + 1];
6055 int i;
6056 int len = sprintf(buf, "%.12g", value);
6057
6058 /* Add a final ".0" if necessary */
6059 for (i = 0; i < len; i++) {
6060 if (buf[i] == '.' || buf[i] == 'e') {
6061 #if defined(JIM_SPRINTF_DOUBLE_NEEDS_FIX)
6062 /* If 'buf' ends in e-0nn or e+0nn, remove
6063 * the 0 after the + or - and reduce the length by 1
6064 */
6065 char *e = strchr(buf, 'e');
6066 if (e && (e[1] == '-' || e[1] == '+') && e[2] == '0') {
6067 /* Move it up */
6068 e += 2;
6069 memmove(e, e + 1, len - (e - buf));
6070 }
6071 #endif
6072 break;
6073 }
6074 }
6075 if (buf[i] == '\0') {
6076 buf[i++] = '.';
6077 buf[i++] = '0';
6078 buf[i] = '\0';
6079 }
6080 JimSetStringBytes(objPtr, buf);
6081 }
6082 }
6083
6084 static int SetDoubleFromAny(Jim_Interp *interp, Jim_Obj *objPtr)
6085 {
6086 double doubleValue;
6087 jim_wide wideValue;
6088 const char *str;
6089
6090 #ifdef HAVE_LONG_LONG
6091 /* Assume a 53 bit mantissa */
6092 #define MIN_INT_IN_DOUBLE -(1LL << 53)
6093 #define MAX_INT_IN_DOUBLE -(MIN_INT_IN_DOUBLE + 1)
6094
6095 if (objPtr->typePtr == &intObjType
6096 && JimWideValue(objPtr) >= MIN_INT_IN_DOUBLE
6097 && JimWideValue(objPtr) <= MAX_INT_IN_DOUBLE) {
6098
6099 /* Direct conversion to coerced double */
6100 objPtr->typePtr = &coercedDoubleObjType;
6101 return JIM_OK;
6102 }
6103 #endif
6104 /* Preserve the string representation.
6105 * Needed so we can convert back to int without loss
6106 */
6107 str = Jim_String(objPtr);
6108
6109 if (Jim_StringToWide(str, &wideValue, 10) == JIM_OK) {
6110 /* Managed to convert to an int, so we can use this as a cooerced double */
6111 Jim_FreeIntRep(interp, objPtr);
6112 objPtr->typePtr = &coercedDoubleObjType;
6113 objPtr->internalRep.wideValue = wideValue;
6114 return JIM_OK;
6115 }
6116 else {
6117 /* Try to convert into a double */
6118 if (Jim_StringToDouble(str, &doubleValue) != JIM_OK) {
6119 Jim_SetResultFormatted(interp, "expected floating-point number but got \"%#s\"", objPtr);
6120 return JIM_ERR;
6121 }
6122 /* Free the old internal repr and set the new one. */
6123 Jim_FreeIntRep(interp, objPtr);
6124 }
6125 objPtr->typePtr = &doubleObjType;
6126 objPtr->internalRep.doubleValue = doubleValue;
6127 return JIM_OK;
6128 }
6129
6130 int Jim_GetDouble(Jim_Interp *interp, Jim_Obj *objPtr, double *doublePtr)
6131 {
6132 if (objPtr->typePtr == &coercedDoubleObjType) {
6133 *doublePtr = JimWideValue(objPtr);
6134 return JIM_OK;
6135 }
6136 if (objPtr->typePtr != &doubleObjType && SetDoubleFromAny(interp, objPtr) == JIM_ERR)
6137 return JIM_ERR;
6138
6139 if (objPtr->typePtr == &coercedDoubleObjType) {
6140 *doublePtr = JimWideValue(objPtr);
6141 }
6142 else {
6143 *doublePtr = objPtr->internalRep.doubleValue;
6144 }
6145 return JIM_OK;
6146 }
6147
6148 Jim_Obj *Jim_NewDoubleObj(Jim_Interp *interp, double doubleValue)
6149 {
6150 Jim_Obj *objPtr;
6151
6152 objPtr = Jim_NewObj(interp);
6153 objPtr->typePtr = &doubleObjType;
6154 objPtr->bytes = NULL;
6155 objPtr->internalRep.doubleValue = doubleValue;
6156 return objPtr;
6157 }
6158
6159 /* -----------------------------------------------------------------------------
6160 * Boolean conversion
6161 * ---------------------------------------------------------------------------*/
6162 static int SetBooleanFromAny(Jim_Interp *interp, Jim_Obj *objPtr, int flags);
6163
6164 int Jim_GetBoolean(Jim_Interp *interp, Jim_Obj *objPtr, int * booleanPtr)
6165 {
6166 if (objPtr->typePtr != &intObjType && SetBooleanFromAny(interp, objPtr, JIM_ERRMSG) == JIM_ERR)
6167 return JIM_ERR;
6168 *booleanPtr = (int) JimWideValue(objPtr);
6169 return JIM_OK;
6170 }
6171
6172 static int SetBooleanFromAny(Jim_Interp *interp, Jim_Obj *objPtr, int flags)
6173 {
6174 static const char * const falses[] = {
6175 "0", "false", "no", "off", NULL
6176 };
6177 static const char * const trues[] = {
6178 "1", "true", "yes", "on", NULL
6179 };
6180
6181 int boolean;
6182
6183 int index;
6184 if (Jim_GetEnum(interp, objPtr, falses, &index, NULL, 0) == JIM_OK) {
6185 boolean = 0;
6186 } else if (Jim_GetEnum(interp, objPtr, trues, &index, NULL, 0) == JIM_OK) {
6187 boolean = 1;
6188 } else {
6189 if (flags & JIM_ERRMSG) {
6190 Jim_SetResultFormatted(interp, "expected boolean but got \"%#s\"", objPtr);
6191 }
6192 return JIM_ERR;
6193 }
6194
6195 /* Free the old internal repr and set the new one. */
6196 Jim_FreeIntRep(interp, objPtr);
6197 objPtr->typePtr = &intObjType;
6198 objPtr->internalRep.wideValue = boolean;
6199 return JIM_OK;
6200 }
6201
6202 /* -----------------------------------------------------------------------------
6203 * List object
6204 * ---------------------------------------------------------------------------*/
6205 static void ListInsertElements(Jim_Obj *listPtr, int idx, int elemc, Jim_Obj *const *elemVec);
6206 static void ListAppendElement(Jim_Obj *listPtr, Jim_Obj *objPtr);
6207 static void FreeListInternalRep(Jim_Interp *interp, Jim_Obj *objPtr);
6208 static void DupListInternalRep(Jim_Interp *interp, Jim_Obj *srcPtr, Jim_Obj *dupPtr);
6209 static void UpdateStringOfList(struct Jim_Obj *objPtr);
6210 static int SetListFromAny(Jim_Interp *interp, struct Jim_Obj *objPtr);
6211
6212 /* Note that while the elements of the list may contain references,
6213 * the list object itself can't. This basically means that the
6214 * list object string representation as a whole can't contain references
6215 * that are not presents in the single elements. */
6216 static const Jim_ObjType listObjType = {
6217 "list",
6218 FreeListInternalRep,
6219 DupListInternalRep,
6220 UpdateStringOfList,
6221 JIM_TYPE_NONE,
6222 };
6223
6224 void FreeListInternalRep(Jim_Interp *interp, Jim_Obj *objPtr)
6225 {
6226 int i;
6227
6228 for (i = 0; i < objPtr->internalRep.listValue.len; i++) {
6229 Jim_DecrRefCount(interp, objPtr->internalRep.listValue.ele[i]);
6230 }
6231 Jim_Free(objPtr->internalRep.listValue.ele);
6232 }
6233
6234 void DupListInternalRep(Jim_Interp *interp, Jim_Obj *srcPtr, Jim_Obj *dupPtr)
6235 {
6236 int i;
6237
6238 JIM_NOTUSED(interp);
6239
6240 dupPtr->internalRep.listValue.len = srcPtr->internalRep.listValue.len;
6241 dupPtr->internalRep.listValue.maxLen = srcPtr->internalRep.listValue.maxLen;
6242 dupPtr->internalRep.listValue.ele =
6243 Jim_Alloc(sizeof(Jim_Obj *) * srcPtr->internalRep.listValue.maxLen);
6244 memcpy(dupPtr->internalRep.listValue.ele, srcPtr->internalRep.listValue.ele,
6245 sizeof(Jim_Obj *) * srcPtr->internalRep.listValue.len);
6246 for (i = 0; i < dupPtr->internalRep.listValue.len; i++) {
6247 Jim_IncrRefCount(dupPtr->internalRep.listValue.ele[i]);
6248 }
6249 dupPtr->typePtr = &listObjType;
6250 }
6251
6252 /* The following function checks if a given string can be encoded
6253 * into a list element without any kind of quoting, surrounded by braces,
6254 * or using escapes to quote. */
6255 #define JIM_ELESTR_SIMPLE 0
6256 #define JIM_ELESTR_BRACE 1
6257 #define JIM_ELESTR_QUOTE 2
6258 static unsigned char ListElementQuotingType(const char *s, int len)
6259 {
6260 int i, level, blevel, trySimple = 1;
6261
6262 /* Try with the SIMPLE case */
6263 if (len == 0)
6264 return JIM_ELESTR_BRACE;
6265 if (s[0] == '"' || s[0] == '{') {
6266 trySimple = 0;
6267 goto testbrace;
6268 }
6269 for (i = 0; i < len; i++) {
6270 switch (s[i]) {
6271 case ' ':
6272 case '$':
6273 case '"':
6274 case '[':
6275 case ']':
6276 case ';':
6277 case '\\':
6278 case '\r':
6279 case '\n':
6280 case '\t':
6281 case '\f':
6282 case '\v':
6283 trySimple = 0;
6284 /* fall through */
6285 case '{':
6286 case '}':
6287 goto testbrace;
6288 }
6289 }
6290 return JIM_ELESTR_SIMPLE;
6291
6292 testbrace:
6293 /* Test if it's possible to do with braces */
6294 if (s[len - 1] == '\\')
6295 return JIM_ELESTR_QUOTE;
6296 level = 0;
6297 blevel = 0;
6298 for (i = 0; i < len; i++) {
6299 switch (s[i]) {
6300 case '{':
6301 level++;
6302 break;
6303 case '}':
6304 level--;
6305 if (level < 0)
6306 return JIM_ELESTR_QUOTE;
6307 break;
6308 case '[':
6309 blevel++;
6310 break;
6311 case ']':
6312 blevel--;
6313 break;
6314 case '\\':
6315 if (s[i + 1] == '\n')
6316 return JIM_ELESTR_QUOTE;
6317 else if (s[i + 1] != '\0')
6318 i++;
6319 break;
6320 }
6321 }
6322 if (blevel < 0) {
6323 return JIM_ELESTR_QUOTE;
6324 }
6325
6326 if (level == 0) {
6327 if (!trySimple)
6328 return JIM_ELESTR_BRACE;
6329 for (i = 0; i < len; i++) {
6330 switch (s[i]) {
6331 case ' ':
6332 case '$':
6333 case '"':
6334 case '[':
6335 case ']':
6336 case ';':
6337 case '\\':
6338 case '\r':
6339 case '\n':
6340 case '\t':
6341 case '\f':
6342 case '\v':
6343 return JIM_ELESTR_BRACE;
6344 break;
6345 }
6346 }
6347 return JIM_ELESTR_SIMPLE;
6348 }
6349 return JIM_ELESTR_QUOTE;
6350 }
6351
6352 /* Backslashes-escapes the null-terminated string 's' into the buffer at 'q'
6353 * The buffer must be at least strlen(s) * 2 + 1 bytes long for the worst-case
6354 * scenario.
6355 * Returns the length of the result.
6356 */
6357 static int BackslashQuoteString(const char *s, int len, char *q)
6358 {
6359 char *p = q;
6360
6361 while (len--) {
6362 switch (*s) {
6363 case ' ':
6364 case '$':
6365 case '"':
6366 case '[':
6367 case ']':
6368 case '{':
6369 case '}':
6370 case ';':
6371 case '\\':
6372 *p++ = '\\';
6373 *p++ = *s++;
6374 break;
6375 case '\n':
6376 *p++ = '\\';
6377 *p++ = 'n';
6378 s++;
6379 break;
6380 case '\r':
6381 *p++ = '\\';
6382 *p++ = 'r';
6383 s++;
6384 break;
6385 case '\t':
6386 *p++ = '\\';
6387 *p++ = 't';
6388 s++;
6389 break;
6390 case '\f':
6391 *p++ = '\\';
6392 *p++ = 'f';
6393 s++;
6394 break;
6395 case '\v':
6396 *p++ = '\\';
6397 *p++ = 'v';
6398 s++;
6399 break;
6400 default:
6401 *p++ = *s++;
6402 break;
6403 }
6404 }
6405 *p = '\0';
6406
6407 return p - q;
6408 }
6409
6410 static void JimMakeListStringRep(Jim_Obj *objPtr, Jim_Obj **objv, int objc)
6411 {
6412 #define STATIC_QUOTING_LEN 32
6413 int i, bufLen, realLength;
6414 const char *strRep;
6415 char *p;
6416 unsigned char *quotingType, staticQuoting[STATIC_QUOTING_LEN];
6417
6418 /* Estimate the space needed. */
6419 if (objc > STATIC_QUOTING_LEN) {
6420 quotingType = Jim_Alloc(objc);
6421 }
6422 else {
6423 quotingType = staticQuoting;
6424 }
6425 bufLen = 0;
6426 for (i = 0; i < objc; i++) {
6427 int len;
6428
6429 strRep = Jim_GetString(objv[i], &len);
6430 quotingType[i] = ListElementQuotingType(strRep, len);
6431 switch (quotingType[i]) {
6432 case JIM_ELESTR_SIMPLE:
6433 if (i != 0 || strRep[0] != '#') {
6434 bufLen += len;
6435 break;
6436 }
6437 /* Special case '#' on first element needs braces */
6438 quotingType[i] = JIM_ELESTR_BRACE;
6439 /* fall through */
6440 case JIM_ELESTR_BRACE:
6441 bufLen += len + 2;
6442 break;
6443 case JIM_ELESTR_QUOTE:
6444 bufLen += len * 2;
6445 break;
6446 }
6447 bufLen++; /* elements separator. */
6448 }
6449 bufLen++;
6450
6451 /* Generate the string rep. */
6452 p = objPtr->bytes = Jim_Alloc(bufLen + 1);
6453 realLength = 0;
6454 for (i = 0; i < objc; i++) {
6455 int len, qlen;
6456
6457 strRep = Jim_GetString(objv[i], &len);
6458
6459 switch (quotingType[i]) {
6460 case JIM_ELESTR_SIMPLE:
6461 memcpy(p, strRep, len);
6462 p += len;
6463 realLength += len;
6464 break;
6465 case JIM_ELESTR_BRACE:
6466 *p++ = '{';
6467 memcpy(p, strRep, len);
6468 p += len;
6469 *p++ = '}';
6470 realLength += len + 2;
6471 break;
6472 case JIM_ELESTR_QUOTE:
6473 if (i == 0 && strRep[0] == '#') {
6474 *p++ = '\\';
6475 realLength++;
6476 }
6477 qlen = BackslashQuoteString(strRep, len, p);
6478 p += qlen;
6479 realLength += qlen;
6480 break;
6481 }
6482 /* Add a separating space */
6483 if (i + 1 != objc) {
6484 *p++ = ' ';
6485 realLength++;
6486 }
6487 }
6488 *p = '\0'; /* nul term. */
6489 objPtr->length = realLength;
6490
6491 if (quotingType != staticQuoting) {
6492 Jim_Free(quotingType);
6493 }
6494 }
6495
6496 static void UpdateStringOfList(struct Jim_Obj *objPtr)
6497 {
6498 JimMakeListStringRep(objPtr, objPtr->internalRep.listValue.ele, objPtr->internalRep.listValue.len);
6499 }
6500
6501 static int SetListFromAny(Jim_Interp *interp, struct Jim_Obj *objPtr)
6502 {
6503 struct JimParserCtx parser;
6504 const char *str;
6505 int strLen;
6506 Jim_Obj *fileNameObj;
6507 int linenr;
6508
6509 if (objPtr->typePtr == &listObjType) {
6510 return JIM_OK;
6511 }
6512
6513 /* Optimise dict -> list for object with no string rep. Note that this may only save a little time, but
6514 * it also preserves any source location of the dict elements
6515 * which can be very useful
6516 */
6517 if (Jim_IsDict(objPtr) && objPtr->bytes == NULL) {
6518 Jim_Obj **listObjPtrPtr;
6519 int len;
6520 int i;
6521
6522 listObjPtrPtr = JimDictPairs(objPtr, &len);
6523 for (i = 0; i < len; i++) {
6524 Jim_IncrRefCount(listObjPtrPtr[i]);
6525 }
6526
6527 /* Now just switch the internal rep */
6528 Jim_FreeIntRep(interp, objPtr);
6529 objPtr->typePtr = &listObjType;
6530 objPtr->internalRep.listValue.len = len;
6531 objPtr->internalRep.listValue.maxLen = len;
6532 objPtr->internalRep.listValue.ele = listObjPtrPtr;
6533
6534 return JIM_OK;
6535 }
6536
6537 /* Try to preserve information about filename / line number */
6538 if (objPtr->typePtr == &sourceObjType) {
6539 fileNameObj = objPtr->internalRep.sourceValue.fileNameObj;
6540 linenr = objPtr->internalRep.sourceValue.lineNumber;
6541 }
6542 else {
6543 fileNameObj = interp->emptyObj;
6544 linenr = 1;
6545 }
6546 Jim_IncrRefCount(fileNameObj);
6547
6548 /* Get the string representation */
6549 str = Jim_GetString(objPtr, &strLen);
6550
6551 /* Free the old internal repr just now and initialize the
6552 * new one just now. The string->list conversion can't fail. */
6553 Jim_FreeIntRep(interp, objPtr);
6554 objPtr->typePtr = &listObjType;
6555 objPtr->internalRep.listValue.len = 0;
6556 objPtr->internalRep.listValue.maxLen = 0;
6557 objPtr->internalRep.listValue.ele = NULL;
6558
6559 /* Convert into a list */
6560 if (strLen) {
6561 JimParserInit(&parser, str, strLen, linenr);
6562 while (!parser.eof) {
6563 Jim_Obj *elementPtr;
6564
6565 JimParseList(&parser);
6566 if (parser.tt != JIM_TT_STR && parser.tt != JIM_TT_ESC)
6567 continue;
6568 elementPtr = JimParserGetTokenObj(interp, &parser);
6569 JimSetSourceInfo(interp, elementPtr, fileNameObj, parser.tline);
6570 ListAppendElement(objPtr, elementPtr);
6571 }
6572 }
6573 Jim_DecrRefCount(interp, fileNameObj);
6574 return JIM_OK;
6575 }
6576
6577 Jim_Obj *Jim_NewListObj(Jim_Interp *interp, Jim_Obj *const *elements, int len)
6578 {
6579 Jim_Obj *objPtr;
6580
6581 objPtr = Jim_NewObj(interp);
6582 objPtr->typePtr = &listObjType;
6583 objPtr->bytes = NULL;
6584 objPtr->internalRep.listValue.ele = NULL;
6585 objPtr->internalRep.listValue.len = 0;
6586 objPtr->internalRep.listValue.maxLen = 0;
6587
6588 if (len) {
6589 ListInsertElements(objPtr, 0, len, elements);
6590 }
6591
6592 return objPtr;
6593 }
6594
6595 /* Return a vector of Jim_Obj with the elements of a Jim list, and the
6596 * length of the vector. Note that the user of this function should make
6597 * sure that the list object can't shimmer while the vector returned
6598 * is in use, this vector is the one stored inside the internal representation
6599 * of the list object. This function is not exported, extensions should
6600 * always access to the List object elements using Jim_ListIndex(). */
6601 static void JimListGetElements(Jim_Interp *interp, Jim_Obj *listObj, int *listLen,
6602 Jim_Obj ***listVec)
6603 {
6604 *listLen = Jim_ListLength(interp, listObj);
6605 *listVec = listObj->internalRep.listValue.ele;
6606 }
6607
6608 /* Sorting uses ints, but commands may return wide */
6609 static int JimSign(jim_wide w)
6610 {
6611 if (w == 0) {
6612 return 0;
6613 }
6614 else if (w < 0) {
6615 return -1;
6616 }
6617 return 1;
6618 }
6619
6620 /* ListSortElements type values */
6621 struct lsort_info {
6622 jmp_buf jmpbuf;
6623 Jim_Obj *command;
6624 Jim_Interp *interp;
6625 enum {
6626 JIM_LSORT_ASCII,
6627 JIM_LSORT_NOCASE,
6628 JIM_LSORT_INTEGER,
6629 JIM_LSORT_REAL,
6630 JIM_LSORT_COMMAND
6631 } type;
6632 int order;
6633 int index;
6634 int indexed;
6635 int unique;
6636 int (*subfn)(Jim_Obj **, Jim_Obj **);
6637 };
6638
6639 static struct lsort_info *sort_info;
6640
6641 static int ListSortIndexHelper(Jim_Obj **lhsObj, Jim_Obj **rhsObj)
6642 {
6643 Jim_Obj *lObj, *rObj;
6644
6645 if (Jim_ListIndex(sort_info->interp, *lhsObj, sort_info->index, &lObj, JIM_ERRMSG) != JIM_OK ||
6646 Jim_ListIndex(sort_info->interp, *rhsObj, sort_info->index, &rObj, JIM_ERRMSG) != JIM_OK) {
6647 longjmp(sort_info->jmpbuf, JIM_ERR);
6648 }
6649 return sort_info->subfn(&lObj, &rObj);
6650 }
6651
6652 /* Sort the internal rep of a list. */
6653 static int ListSortString(Jim_Obj **lhsObj, Jim_Obj **rhsObj)
6654 {
6655 return Jim_StringCompareObj(sort_info->interp, *lhsObj, *rhsObj, 0) * sort_info->order;
6656 }
6657
6658 static int ListSortStringNoCase(Jim_Obj **lhsObj, Jim_Obj **rhsObj)
6659 {
6660 return Jim_StringCompareObj(sort_info->interp, *lhsObj, *rhsObj, 1) * sort_info->order;
6661 }
6662
6663 static int ListSortInteger(Jim_Obj **lhsObj, Jim_Obj **rhsObj)
6664 {
6665 jim_wide lhs = 0, rhs = 0;
6666
6667 if (Jim_GetWide(sort_info->interp, *lhsObj, &lhs) != JIM_OK ||
6668 Jim_GetWide(sort_info->interp, *rhsObj, &rhs) != JIM_OK) {
6669 longjmp(sort_info->jmpbuf, JIM_ERR);
6670 }
6671
6672 return JimSign(lhs - rhs) * sort_info->order;
6673 }
6674
6675 static int ListSortReal(Jim_Obj **lhsObj, Jim_Obj **rhsObj)
6676 {
6677 double lhs = 0, rhs = 0;
6678
6679 if (Jim_GetDouble(sort_info->interp, *lhsObj, &lhs) != JIM_OK ||
6680 Jim_GetDouble(sort_info->interp, *rhsObj, &rhs) != JIM_OK) {
6681 longjmp(sort_info->jmpbuf, JIM_ERR);
6682 }
6683 if (lhs == rhs) {
6684 return 0;
6685 }
6686 if (lhs > rhs) {
6687 return sort_info->order;
6688 }
6689 return -sort_info->order;
6690 }
6691
6692 static int ListSortCommand(Jim_Obj **lhsObj, Jim_Obj **rhsObj)
6693 {
6694 Jim_Obj *compare_script;
6695 int rc;
6696
6697 jim_wide ret = 0;
6698
6699 /* This must be a valid list */
6700 compare_script = Jim_DuplicateObj(sort_info->interp, sort_info->command);
6701 Jim_ListAppendElement(sort_info->interp, compare_script, *lhsObj);
6702 Jim_ListAppendElement(sort_info->interp, compare_script, *rhsObj);
6703
6704 rc = Jim_EvalObj(sort_info->interp, compare_script);
6705
6706 if (rc != JIM_OK || Jim_GetWide(sort_info->interp, Jim_GetResult(sort_info->interp), &ret) != JIM_OK) {
6707 longjmp(sort_info->jmpbuf, rc);
6708 }
6709
6710 return JimSign(ret) * sort_info->order;
6711 }
6712
6713 /* Remove duplicate elements from the (sorted) list in-place, according to the
6714 * comparison function, comp.
6715 *
6716 * Note that the last unique value is kept, not the first
6717 */
6718 static void ListRemoveDuplicates(Jim_Obj *listObjPtr, int (*comp)(Jim_Obj **lhs, Jim_Obj **rhs))
6719 {
6720 int src;
6721 int dst = 0;
6722 Jim_Obj **ele = listObjPtr->internalRep.listValue.ele;
6723
6724 for (src = 1; src < listObjPtr->internalRep.listValue.len; src++) {
6725 if (comp(&ele[dst], &ele[src]) == 0) {
6726 /* Match, so replace the dest with the current source */
6727 Jim_DecrRefCount(sort_info->interp, ele[dst]);
6728 }
6729 else {
6730 /* No match, so keep the current source and move to the next destination */
6731 dst++;
6732 }
6733 ele[dst] = ele[src];
6734 }
6735
6736 /* At end of list, keep the final element unless all elements were kept */
6737 dst++;
6738 if (dst < listObjPtr->internalRep.listValue.len) {
6739 ele[dst] = ele[src];
6740 }
6741
6742 /* Set the new length */
6743 listObjPtr->internalRep.listValue.len = dst;
6744 }
6745
6746 /* Sort a list *in place*. MUST be called with a non-shared list. */
6747 static int ListSortElements(Jim_Interp *interp, Jim_Obj *listObjPtr, struct lsort_info *info)
6748 {
6749 struct lsort_info *prev_info;
6750
6751 typedef int (qsort_comparator) (const void *, const void *);
6752 int (*fn) (Jim_Obj **, Jim_Obj **);
6753 Jim_Obj **vector;
6754 int len;
6755 int rc;
6756
6757 JimPanic((Jim_IsShared(listObjPtr), "ListSortElements called with shared object"));
6758 SetListFromAny(interp, listObjPtr);
6759
6760 /* Allow lsort to be called reentrantly */
6761 prev_info = sort_info;
6762 sort_info = info;
6763
6764 vector = listObjPtr->internalRep.listValue.ele;
6765 len = listObjPtr->internalRep.listValue.len;
6766 switch (info->type) {
6767 case JIM_LSORT_ASCII:
6768 fn = ListSortString;
6769 break;
6770 case JIM_LSORT_NOCASE:
6771 fn = ListSortStringNoCase;
6772 break;
6773 case JIM_LSORT_INTEGER:
6774 fn = ListSortInteger;
6775 break;
6776 case JIM_LSORT_REAL:
6777 fn = ListSortReal;
6778 break;
6779 case JIM_LSORT_COMMAND:
6780 fn = ListSortCommand;
6781 break;
6782 default:
6783 fn = NULL; /* avoid warning */
6784 JimPanic((1, "ListSort called with invalid sort type"));
6785 return -1; /* Should not be run but keeps static analysers happy */
6786 }
6787
6788 if (info->indexed) {
6789 /* Need to interpose a "list index" function */
6790 info->subfn = fn;
6791 fn = ListSortIndexHelper;
6792 }
6793
6794 if ((rc = setjmp(info->jmpbuf)) == 0) {
6795 qsort(vector, len, sizeof(Jim_Obj *), (qsort_comparator *) fn);
6796
6797 if (info->unique && len > 1) {
6798 ListRemoveDuplicates(listObjPtr, fn);
6799 }
6800
6801 Jim_InvalidateStringRep(listObjPtr);
6802 }
6803 sort_info = prev_info;
6804
6805 return rc;
6806 }
6807
6808 /* This is the low-level function to insert elements into a list.
6809 * The higher-level Jim_ListInsertElements() performs shared object
6810 * check and invalidates the string repr. This version is used
6811 * in the internals of the List Object and is not exported.
6812 *
6813 * NOTE: this function can be called only against objects
6814 * with internal type of List.
6815 *
6816 * An insertion point (idx) of -1 means end-of-list.
6817 */
6818 static void ListInsertElements(Jim_Obj *listPtr, int idx, int elemc, Jim_Obj *const *elemVec)
6819 {
6820 int currentLen = listPtr->internalRep.listValue.len;
6821 int requiredLen = currentLen + elemc;
6822 int i;
6823 Jim_Obj **point;
6824
6825 if (requiredLen > listPtr->internalRep.listValue.maxLen) {
6826 if (requiredLen < 2) {
6827 /* Don't do allocations of under 4 pointers. */
6828 requiredLen = 4;
6829 }
6830 else {
6831 requiredLen *= 2;
6832 }
6833
6834 listPtr->internalRep.listValue.ele = Jim_Realloc(listPtr->internalRep.listValue.ele,
6835 sizeof(Jim_Obj *) * requiredLen);
6836
6837 listPtr->internalRep.listValue.maxLen = requiredLen;
6838 }
6839 if (idx < 0) {
6840 idx = currentLen;
6841 }
6842 point = listPtr->internalRep.listValue.ele + idx;
6843 memmove(point + elemc, point, (currentLen - idx) * sizeof(Jim_Obj *));
6844 for (i = 0; i < elemc; ++i) {
6845 point[i] = elemVec[i];
6846 Jim_IncrRefCount(point[i]);
6847 }
6848 listPtr->internalRep.listValue.len += elemc;
6849 }
6850
6851 /* Convenience call to ListInsertElements() to append a single element.
6852 */
6853 static void ListAppendElement(Jim_Obj *listPtr, Jim_Obj *objPtr)
6854 {
6855 ListInsertElements(listPtr, -1, 1, &objPtr);
6856 }
6857
6858 /* Appends every element of appendListPtr into listPtr.
6859 * Both have to be of the list type.
6860 * Convenience call to ListInsertElements()
6861 */
6862 static void ListAppendList(Jim_Obj *listPtr, Jim_Obj *appendListPtr)
6863 {
6864 ListInsertElements(listPtr, -1,
6865 appendListPtr->internalRep.listValue.len, appendListPtr->internalRep.listValue.ele);
6866 }
6867
6868 void Jim_ListAppendElement(Jim_Interp *interp, Jim_Obj *listPtr, Jim_Obj *objPtr)
6869 {
6870 JimPanic((Jim_IsShared(listPtr), "Jim_ListAppendElement called with shared object"));
6871 SetListFromAny(interp, listPtr);
6872 Jim_InvalidateStringRep(listPtr);
6873 ListAppendElement(listPtr, objPtr);
6874 }
6875
6876 void Jim_ListAppendList(Jim_Interp *interp, Jim_Obj *listPtr, Jim_Obj *appendListPtr)
6877 {
6878 JimPanic((Jim_IsShared(listPtr), "Jim_ListAppendList called with shared object"));
6879 SetListFromAny(interp, listPtr);
6880 SetListFromAny(interp, appendListPtr);
6881 Jim_InvalidateStringRep(listPtr);
6882 ListAppendList(listPtr, appendListPtr);
6883 }
6884
6885 int Jim_ListLength(Jim_Interp *interp, Jim_Obj *objPtr)
6886 {
6887 SetListFromAny(interp, objPtr);
6888 return objPtr->internalRep.listValue.len;
6889 }
6890
6891 void Jim_ListInsertElements(Jim_Interp *interp, Jim_Obj *listPtr, int idx,
6892 int objc, Jim_Obj *const *objVec)
6893 {
6894 JimPanic((Jim_IsShared(listPtr), "Jim_ListInsertElement called with shared object"));
6895 SetListFromAny(interp, listPtr);
6896 if (idx >= 0 && idx > listPtr->internalRep.listValue.len)
6897 idx = listPtr->internalRep.listValue.len;
6898 else if (idx < 0)
6899 idx = 0;
6900 Jim_InvalidateStringRep(listPtr);
6901 ListInsertElements(listPtr, idx, objc, objVec);
6902 }
6903
6904 Jim_Obj *Jim_ListGetIndex(Jim_Interp *interp, Jim_Obj *listPtr, int idx)
6905 {
6906 SetListFromAny(interp, listPtr);
6907 if ((idx >= 0 && idx >= listPtr->internalRep.listValue.len) ||
6908 (idx < 0 && (-idx - 1) >= listPtr->internalRep.listValue.len)) {
6909 return NULL;
6910 }
6911 if (idx < 0)
6912 idx = listPtr->internalRep.listValue.len + idx;
6913 return listPtr->internalRep.listValue.ele[idx];
6914 }
6915
6916 int Jim_ListIndex(Jim_Interp *interp, Jim_Obj *listPtr, int idx, Jim_Obj **objPtrPtr, int flags)
6917 {
6918 *objPtrPtr = Jim_ListGetIndex(interp, listPtr, idx);
6919 if (*objPtrPtr == NULL) {
6920 if (flags & JIM_ERRMSG) {
6921 Jim_SetResultString(interp, "list index out of range", -1);
6922 }
6923 return JIM_ERR;
6924 }
6925 return JIM_OK;
6926 }
6927
6928 static int ListSetIndex(Jim_Interp *interp, Jim_Obj *listPtr, int idx,
6929 Jim_Obj *newObjPtr, int flags)
6930 {
6931 SetListFromAny(interp, listPtr);
6932 if ((idx >= 0 && idx >= listPtr->internalRep.listValue.len) ||
6933 (idx < 0 && (-idx - 1) >= listPtr->internalRep.listValue.len)) {
6934 if (flags & JIM_ERRMSG) {
6935 Jim_SetResultString(interp, "list index out of range", -1);
6936 }
6937 return JIM_ERR;
6938 }
6939 if (idx < 0)
6940 idx = listPtr->internalRep.listValue.len + idx;
6941 Jim_DecrRefCount(interp, listPtr->internalRep.listValue.ele[idx]);
6942 listPtr->internalRep.listValue.ele[idx] = newObjPtr;
6943 Jim_IncrRefCount(newObjPtr);
6944 return JIM_OK;
6945 }
6946
6947 /* Modify the list stored in the variable named 'varNamePtr'
6948 * setting the element specified by the 'indexc' indexes objects in 'indexv',
6949 * with the new element 'newObjptr'. (implements the [lset] command) */
6950 int Jim_ListSetIndex(Jim_Interp *interp, Jim_Obj *varNamePtr,
6951 Jim_Obj *const *indexv, int indexc, Jim_Obj *newObjPtr)
6952 {
6953 Jim_Obj *varObjPtr, *objPtr, *listObjPtr;
6954 int shared, i, idx;
6955
6956 varObjPtr = objPtr = Jim_GetVariable(interp, varNamePtr, JIM_ERRMSG | JIM_UNSHARED);
6957 if (objPtr == NULL)
6958 return JIM_ERR;
6959 if ((shared = Jim_IsShared(objPtr)))
6960 varObjPtr = objPtr = Jim_DuplicateObj(interp, objPtr);
6961 for (i = 0; i < indexc - 1; i++) {
6962 listObjPtr = objPtr;
6963 if (Jim_GetIndex(interp, indexv[i], &idx) != JIM_OK)
6964 goto err;
6965 if (Jim_ListIndex(interp, listObjPtr, idx, &objPtr, JIM_ERRMSG) != JIM_OK) {
6966 goto err;
6967 }
6968 if (Jim_IsShared(objPtr)) {
6969 objPtr = Jim_DuplicateObj(interp, objPtr);
6970 ListSetIndex(interp, listObjPtr, idx, objPtr, JIM_NONE);
6971 }
6972 Jim_InvalidateStringRep(listObjPtr);
6973 }
6974 if (Jim_GetIndex(interp, indexv[indexc - 1], &idx) != JIM_OK)
6975 goto err;
6976 if (ListSetIndex(interp, objPtr, idx, newObjPtr, JIM_ERRMSG) == JIM_ERR)
6977 goto err;
6978 Jim_InvalidateStringRep(objPtr);
6979 Jim_InvalidateStringRep(varObjPtr);
6980 if (Jim_SetVariable(interp, varNamePtr, varObjPtr) != JIM_OK)
6981 goto err;
6982 Jim_SetResult(interp, varObjPtr);
6983 return JIM_OK;
6984 err:
6985 if (shared) {
6986 Jim_FreeNewObj(interp, varObjPtr);
6987 }
6988 return JIM_ERR;
6989 }
6990
6991 Jim_Obj *Jim_ListJoin(Jim_Interp *interp, Jim_Obj *listObjPtr, const char *joinStr, int joinStrLen)
6992 {
6993 int i;
6994 int listLen = Jim_ListLength(interp, listObjPtr);
6995 Jim_Obj *resObjPtr = Jim_NewEmptyStringObj(interp);
6996
6997 for (i = 0; i < listLen; ) {
6998 Jim_AppendObj(interp, resObjPtr, Jim_ListGetIndex(interp, listObjPtr, i));
6999 if (++i != listLen) {
7000 Jim_AppendString(interp, resObjPtr, joinStr, joinStrLen);
7001 }
7002 }
7003 return resObjPtr;
7004 }
7005
7006 Jim_Obj *Jim_ConcatObj(Jim_Interp *interp, int objc, Jim_Obj *const *objv)
7007 {
7008 int i;
7009
7010 /* If all the objects in objv are lists,
7011 * it's possible to return a list as result, that's the
7012 * concatenation of all the lists. */
7013 for (i = 0; i < objc; i++) {
7014 if (!Jim_IsList(objv[i]))
7015 break;
7016 }
7017 if (i == objc) {
7018 Jim_Obj *objPtr = Jim_NewListObj(interp, NULL, 0);
7019
7020 for (i = 0; i < objc; i++)
7021 ListAppendList(objPtr, objv[i]);
7022 return objPtr;
7023 }
7024 else {
7025 /* Else... we have to glue strings together */
7026 int len = 0, objLen;
7027 char *bytes, *p;
7028
7029 /* Compute the length */
7030 for (i = 0; i < objc; i++) {
7031 len += Jim_Length(objv[i]);
7032 }
7033 if (objc)
7034 len += objc - 1;
7035 /* Create the string rep, and a string object holding it. */
7036 p = bytes = Jim_Alloc(len + 1);
7037 for (i = 0; i < objc; i++) {
7038 const char *s = Jim_GetString(objv[i], &objLen);
7039
7040 /* Remove leading space */
7041 while (objLen && isspace(UCHAR(*s))) {
7042 s++;
7043 objLen--;
7044 len--;
7045 }
7046 /* And trailing space */
7047 while (objLen && isspace(UCHAR(s[objLen - 1]))) {
7048 /* Handle trailing backslash-space case */
7049 if (objLen > 1 && s[objLen - 2] == '\\') {
7050 break;
7051 }
7052 objLen--;
7053 len--;
7054 }
7055 memcpy(p, s, objLen);
7056 p += objLen;
7057 if (i + 1 != objc) {
7058 if (objLen)
7059 *p++ = ' ';
7060 else {
7061 /* Drop the space calculated for this
7062 * element that is instead null. */
7063 len--;
7064 }
7065 }
7066 }
7067 *p = '\0';
7068 return Jim_NewStringObjNoAlloc(interp, bytes, len);
7069 }
7070 }
7071
7072 /* Returns a list composed of the elements in the specified range.
7073 * first and start are directly accepted as Jim_Objects and
7074 * processed for the end?-index? case. */
7075 Jim_Obj *Jim_ListRange(Jim_Interp *interp, Jim_Obj *listObjPtr, Jim_Obj *firstObjPtr,
7076 Jim_Obj *lastObjPtr)
7077 {
7078 int first, last;
7079 int len, rangeLen;
7080
7081 if (Jim_GetIndex(interp, firstObjPtr, &first) != JIM_OK ||
7082 Jim_GetIndex(interp, lastObjPtr, &last) != JIM_OK)
7083 return NULL;
7084 len = Jim_ListLength(interp, listObjPtr); /* will convert into list */
7085 first = JimRelToAbsIndex(len, first);
7086 last = JimRelToAbsIndex(len, last);
7087 JimRelToAbsRange(len, &first, &last, &rangeLen);
7088 if (first == 0 && last == len) {
7089 return listObjPtr;
7090 }
7091 return Jim_NewListObj(interp, listObjPtr->internalRep.listValue.ele + first, rangeLen);
7092 }
7093
7094 /* -----------------------------------------------------------------------------
7095 * Dict object
7096 * ---------------------------------------------------------------------------*/
7097 static void FreeDictInternalRep(Jim_Interp *interp, Jim_Obj *objPtr);
7098 static void DupDictInternalRep(Jim_Interp *interp, Jim_Obj *srcPtr, Jim_Obj *dupPtr);
7099 static void UpdateStringOfDict(struct Jim_Obj *objPtr);
7100 static int SetDictFromAny(Jim_Interp *interp, struct Jim_Obj *objPtr);
7101
7102 /* Dict HashTable Type.
7103 *
7104 * Keys and Values are Jim objects. */
7105
7106 static unsigned int JimObjectHTHashFunction(const void *key)
7107 {
7108 int len;
7109 const char *str = Jim_GetString((Jim_Obj *)key, &len);
7110 return Jim_GenHashFunction((const unsigned char *)str, len);
7111 }
7112
7113 static int JimObjectHTKeyCompare(void *privdata, const void *key1, const void *key2)
7114 {
7115 return Jim_StringEqObj((Jim_Obj *)key1, (Jim_Obj *)key2);
7116 }
7117
7118 static void *JimObjectHTKeyValDup(void *privdata, const void *val)
7119 {
7120 Jim_IncrRefCount((Jim_Obj *)val);
7121 return (void *)val;
7122 }
7123
7124 static void JimObjectHTKeyValDestructor(void *interp, void *val)
7125 {
7126 Jim_DecrRefCount(interp, (Jim_Obj *)val);
7127 }
7128
7129 static const Jim_HashTableType JimDictHashTableType = {
7130 JimObjectHTHashFunction, /* hash function */
7131 JimObjectHTKeyValDup, /* key dup */
7132 JimObjectHTKeyValDup, /* val dup */
7133 JimObjectHTKeyCompare, /* key compare */
7134 JimObjectHTKeyValDestructor, /* key destructor */
7135 JimObjectHTKeyValDestructor /* val destructor */
7136 };
7137
7138 /* Note that while the elements of the dict may contain references,
7139 * the list object itself can't. This basically means that the
7140 * dict object string representation as a whole can't contain references
7141 * that are not presents in the single elements. */
7142 static const Jim_ObjType dictObjType = {
7143 "dict",
7144 FreeDictInternalRep,
7145 DupDictInternalRep,
7146 UpdateStringOfDict,
7147 JIM_TYPE_NONE,
7148 };
7149
7150 void FreeDictInternalRep(Jim_Interp *interp, Jim_Obj *objPtr)
7151 {
7152 JIM_NOTUSED(interp);
7153
7154 Jim_FreeHashTable(objPtr->internalRep.ptr);
7155 Jim_Free(objPtr->internalRep.ptr);
7156 }
7157
7158 void DupDictInternalRep(Jim_Interp *interp, Jim_Obj *srcPtr, Jim_Obj *dupPtr)
7159 {
7160 Jim_HashTable *ht, *dupHt;
7161 Jim_HashTableIterator htiter;
7162 Jim_HashEntry *he;
7163
7164 /* Create a new hash table */
7165 ht = srcPtr->internalRep.ptr;
7166 dupHt = Jim_Alloc(sizeof(*dupHt));
7167 Jim_InitHashTable(dupHt, &JimDictHashTableType, interp);
7168 if (ht->size != 0)
7169 Jim_ExpandHashTable(dupHt, ht->size);
7170 /* Copy every element from the source to the dup hash table */
7171 JimInitHashTableIterator(ht, &htiter);
7172 while ((he = Jim_NextHashEntry(&htiter)) != NULL) {
7173 Jim_AddHashEntry(dupHt, he->key, he->u.val);
7174 }
7175
7176 dupPtr->internalRep.ptr = dupHt;
7177 dupPtr->typePtr = &dictObjType;
7178 }
7179
7180 static Jim_Obj **JimDictPairs(Jim_Obj *dictPtr, int *len)
7181 {
7182 Jim_HashTable *ht;
7183 Jim_HashTableIterator htiter;
7184 Jim_HashEntry *he;
7185 Jim_Obj **objv;
7186 int i;
7187
7188 ht = dictPtr->internalRep.ptr;
7189
7190 /* Turn the hash table into a flat vector of Jim_Objects. */
7191 objv = Jim_Alloc((ht->used * 2) * sizeof(Jim_Obj *));
7192 JimInitHashTableIterator(ht, &htiter);
7193 i = 0;
7194 while ((he = Jim_NextHashEntry(&htiter)) != NULL) {
7195 objv[i++] = Jim_GetHashEntryKey(he);
7196 objv[i++] = Jim_GetHashEntryVal(he);
7197 }
7198 *len = i;
7199 return objv;
7200 }
7201
7202 static void UpdateStringOfDict(struct Jim_Obj *objPtr)
7203 {
7204 /* Turn the hash table into a flat vector of Jim_Objects. */
7205 int len;
7206 Jim_Obj **objv = JimDictPairs(objPtr, &len);
7207
7208 /* And now generate the string rep as a list */
7209 JimMakeListStringRep(objPtr, objv, len);
7210
7211 Jim_Free(objv);
7212 }
7213
7214 static int SetDictFromAny(Jim_Interp *interp, struct Jim_Obj *objPtr)
7215 {
7216 int listlen;
7217
7218 if (objPtr->typePtr == &dictObjType) {
7219 return JIM_OK;
7220 }
7221
7222 if (Jim_IsList(objPtr) && Jim_IsShared(objPtr)) {
7223 /* A shared list, so get the string representation now to avoid
7224 * changing the order in case of fast conversion to dict.
7225 */
7226 Jim_String(objPtr);
7227 }
7228
7229 /* For simplicity, convert a non-list object to a list and then to a dict */
7230 listlen = Jim_ListLength(interp, objPtr);
7231 if (listlen % 2) {
7232 Jim_SetResultString(interp, "missing value to go with key", -1);
7233 return JIM_ERR;
7234 }
7235 else {
7236 /* Converting from a list to a dict can't fail */
7237 Jim_HashTable *ht;
7238 int i;
7239
7240 ht = Jim_Alloc(sizeof(*ht));
7241 Jim_InitHashTable(ht, &JimDictHashTableType, interp);
7242
7243 for (i = 0; i < listlen; i += 2) {
7244 Jim_Obj *keyObjPtr = Jim_ListGetIndex(interp, objPtr, i);
7245 Jim_Obj *valObjPtr = Jim_ListGetIndex(interp, objPtr, i + 1);
7246
7247 Jim_ReplaceHashEntry(ht, keyObjPtr, valObjPtr);
7248 }
7249
7250 Jim_FreeIntRep(interp, objPtr);
7251 objPtr->typePtr = &dictObjType;
7252 objPtr->internalRep.ptr = ht;
7253
7254 return JIM_OK;
7255 }
7256 }
7257
7258 /* Dict object API */
7259
7260 /* Add an element to a dict. objPtr must be of the "dict" type.
7261 * The higher-level exported function is Jim_DictAddElement().
7262 * If an element with the specified key already exists, the value
7263 * associated is replaced with the new one.
7264 *
7265 * if valueObjPtr == NULL, the key is instead removed if it exists. */
7266 static int DictAddElement(Jim_Interp *interp, Jim_Obj *objPtr,
7267 Jim_Obj *keyObjPtr, Jim_Obj *valueObjPtr)
7268 {
7269 Jim_HashTable *ht = objPtr->internalRep.ptr;
7270
7271 if (valueObjPtr == NULL) { /* unset */
7272 return Jim_DeleteHashEntry(ht, keyObjPtr);
7273 }
7274 Jim_ReplaceHashEntry(ht, keyObjPtr, valueObjPtr);
7275 return JIM_OK;
7276 }
7277
7278 /* Add an element, higher-level interface for DictAddElement().
7279 * If valueObjPtr == NULL, the key is removed if it exists. */
7280 int Jim_DictAddElement(Jim_Interp *interp, Jim_Obj *objPtr,
7281 Jim_Obj *keyObjPtr, Jim_Obj *valueObjPtr)
7282 {
7283 JimPanic((Jim_IsShared(objPtr), "Jim_DictAddElement called with shared object"));
7284 if (SetDictFromAny(interp, objPtr) != JIM_OK) {
7285 return JIM_ERR;
7286 }
7287 Jim_InvalidateStringRep(objPtr);
7288 return DictAddElement(interp, objPtr, keyObjPtr, valueObjPtr);
7289 }
7290
7291 Jim_Obj *Jim_NewDictObj(Jim_Interp *interp, Jim_Obj *const *elements, int len)
7292 {
7293 Jim_Obj *objPtr;
7294 int i;
7295
7296 JimPanic((len % 2, "Jim_NewDictObj() 'len' argument must be even"));
7297
7298 objPtr = Jim_NewObj(interp);
7299 objPtr->typePtr = &dictObjType;
7300 objPtr->bytes = NULL;
7301 objPtr->internalRep.ptr = Jim_Alloc(sizeof(Jim_HashTable));
7302 Jim_InitHashTable(objPtr->internalRep.ptr, &JimDictHashTableType, interp);
7303 for (i = 0; i < len; i += 2)
7304 DictAddElement(interp, objPtr, elements[i], elements[i + 1]);
7305 return objPtr;
7306 }
7307
7308 /* Return the value associated to the specified dict key
7309 * Returns JIM_OK if OK, JIM_ERR if entry not found or -1 if can't create dict value
7310 *
7311 * Sets *objPtrPtr to non-NULL only upon success.
7312 */
7313 int Jim_DictKey(Jim_Interp *interp, Jim_Obj *dictPtr, Jim_Obj *keyPtr,
7314 Jim_Obj **objPtrPtr, int flags)
7315 {
7316 Jim_HashEntry *he;
7317 Jim_HashTable *ht;
7318
7319 if (SetDictFromAny(interp, dictPtr) != JIM_OK) {
7320 return -1;
7321 }
7322 ht = dictPtr->internalRep.ptr;
7323 if ((he = Jim_FindHashEntry(ht, keyPtr)) == NULL) {
7324 if (flags & JIM_ERRMSG) {
7325 Jim_SetResultFormatted(interp, "key \"%#s\" not known in dictionary", keyPtr);
7326 }
7327 return JIM_ERR;
7328 }
7329 else {
7330 *objPtrPtr = Jim_GetHashEntryVal(he);
7331 return JIM_OK;
7332 }
7333 }
7334
7335 /* Return an allocated array of key/value pairs for the dictionary. Stores the length in *len */
7336 int Jim_DictPairs(Jim_Interp *interp, Jim_Obj *dictPtr, Jim_Obj ***objPtrPtr, int *len)
7337 {
7338 if (SetDictFromAny(interp, dictPtr) != JIM_OK) {
7339 return JIM_ERR;
7340 }
7341 *objPtrPtr = JimDictPairs(dictPtr, len);
7342
7343 return JIM_OK;
7344 }
7345
7346
7347 /* Return the value associated to the specified dict keys */
7348 int Jim_DictKeysVector(Jim_Interp *interp, Jim_Obj *dictPtr,
7349 Jim_Obj *const *keyv, int keyc, Jim_Obj **objPtrPtr, int flags)
7350 {
7351 int i;
7352
7353 if (keyc == 0) {
7354 *objPtrPtr = dictPtr;
7355 return JIM_OK;
7356 }
7357
7358 for (i = 0; i < keyc; i++) {
7359 Jim_Obj *objPtr;
7360
7361 int rc = Jim_DictKey(interp, dictPtr, keyv[i], &objPtr, flags);
7362 if (rc != JIM_OK) {
7363 return rc;
7364 }
7365 dictPtr = objPtr;
7366 }
7367 *objPtrPtr = dictPtr;
7368 return JIM_OK;
7369 }
7370
7371 /* Modify the dict stored into the variable named 'varNamePtr'
7372 * setting the element specified by the 'keyc' keys objects in 'keyv',
7373 * with the new value of the element 'newObjPtr'.
7374 *
7375 * If newObjPtr == NULL the operation is to remove the given key
7376 * from the dictionary.
7377 *
7378 * If flags & JIM_ERRMSG, then failure to remove the key is considered an error
7379 * and JIM_ERR is returned. Otherwise it is ignored and JIM_OK is returned.
7380 */
7381 int Jim_SetDictKeysVector(Jim_Interp *interp, Jim_Obj *varNamePtr,
7382 Jim_Obj *const *keyv, int keyc, Jim_Obj *newObjPtr, int flags)
7383 {
7384 Jim_Obj *varObjPtr, *objPtr, *dictObjPtr;
7385 int shared, i;
7386
7387 varObjPtr = objPtr = Jim_GetVariable(interp, varNamePtr, flags);
7388 if (objPtr == NULL) {
7389 if (newObjPtr == NULL && (flags & JIM_MUSTEXIST)) {
7390 /* Cannot remove a key from non existing var */
7391 return JIM_ERR;
7392 }
7393 varObjPtr = objPtr = Jim_NewDictObj(interp, NULL, 0);
7394 if (Jim_SetVariable(interp, varNamePtr, objPtr) != JIM_OK) {
7395 Jim_FreeNewObj(interp, varObjPtr);
7396 return JIM_ERR;
7397 }
7398 }
7399 if ((shared = Jim_IsShared(objPtr)))
7400 varObjPtr = objPtr = Jim_DuplicateObj(interp, objPtr);
7401 for (i = 0; i < keyc; i++) {
7402 dictObjPtr = objPtr;
7403
7404 /* Check if it's a valid dictionary */
7405 if (SetDictFromAny(interp, dictObjPtr) != JIM_OK) {
7406 goto err;
7407 }
7408
7409 if (i == keyc - 1) {
7410 /* Last key: Note that error on unset with missing last key is OK */
7411 if (Jim_DictAddElement(interp, objPtr, keyv[keyc - 1], newObjPtr) != JIM_OK) {
7412 if (newObjPtr || (flags & JIM_MUSTEXIST)) {
7413 goto err;
7414 }
7415 }
7416 break;
7417 }
7418
7419 /* Check if the given key exists. */
7420 Jim_InvalidateStringRep(dictObjPtr);
7421 if (Jim_DictKey(interp, dictObjPtr, keyv[i], &objPtr,
7422 newObjPtr ? JIM_NONE : JIM_ERRMSG) == JIM_OK) {
7423 /* This key exists at the current level.
7424 * Make sure it's not shared!. */
7425 if (Jim_IsShared(objPtr)) {
7426 objPtr = Jim_DuplicateObj(interp, objPtr);
7427 DictAddElement(interp, dictObjPtr, keyv[i], objPtr);
7428 }
7429 }
7430 else {
7431 /* Key not found. If it's an [unset] operation
7432 * this is an error. Only the last key may not
7433 * exist. */
7434 if (newObjPtr == NULL) {
7435 goto err;
7436 }
7437 /* Otherwise set an empty dictionary
7438 * as key's value. */
7439 objPtr = Jim_NewDictObj(interp, NULL, 0);
7440 DictAddElement(interp, dictObjPtr, keyv[i], objPtr);
7441 }
7442 }
7443 /* XXX: Is this necessary? */
7444 Jim_InvalidateStringRep(objPtr);
7445 Jim_InvalidateStringRep(varObjPtr);
7446 if (Jim_SetVariable(interp, varNamePtr, varObjPtr) != JIM_OK) {
7447 goto err;
7448 }
7449 Jim_SetResult(interp, varObjPtr);
7450 return JIM_OK;
7451 err:
7452 if (shared) {
7453 Jim_FreeNewObj(interp, varObjPtr);
7454 }
7455 return JIM_ERR;
7456 }
7457
7458 /* -----------------------------------------------------------------------------
7459 * Index object
7460 * ---------------------------------------------------------------------------*/
7461 static void UpdateStringOfIndex(struct Jim_Obj *objPtr);
7462 static int SetIndexFromAny(Jim_Interp *interp, struct Jim_Obj *objPtr);
7463
7464 static const Jim_ObjType indexObjType = {
7465 "index",
7466 NULL,
7467 NULL,
7468 UpdateStringOfIndex,
7469 JIM_TYPE_NONE,
7470 };
7471
7472 static void UpdateStringOfIndex(struct Jim_Obj *objPtr)
7473 {
7474 if (objPtr->internalRep.intValue == -1) {
7475 JimSetStringBytes(objPtr, "end");
7476 }
7477 else {
7478 char buf[JIM_INTEGER_SPACE + 1];
7479 if (objPtr->internalRep.intValue >= 0) {
7480 sprintf(buf, "%d", objPtr->internalRep.intValue);
7481 }
7482 else {
7483 /* Must be <= -2 */
7484 sprintf(buf, "end%d", objPtr->internalRep.intValue + 1);
7485 }
7486 JimSetStringBytes(objPtr, buf);
7487 }
7488 }
7489
7490 static int SetIndexFromAny(Jim_Interp *interp, Jim_Obj *objPtr)
7491 {
7492 int idx, end = 0;
7493 const char *str;
7494 char *endptr;
7495
7496 /* Get the string representation */
7497 str = Jim_String(objPtr);
7498
7499 /* Try to convert into an index */
7500 if (strncmp(str, "end", 3) == 0) {
7501 end = 1;
7502 str += 3;
7503 idx = 0;
7504 }
7505 else {
7506 idx = jim_strtol(str, &endptr);
7507
7508 if (endptr == str) {
7509 goto badindex;
7510 }
7511 str = endptr;
7512 }
7513
7514 /* Now str may include or +<num> or -<num> */
7515 if (*str == '+' || *str == '-') {
7516 int sign = (*str == '+' ? 1 : -1);
7517
7518 idx += sign * jim_strtol(++str, &endptr);
7519 if (str == endptr || *endptr) {
7520 goto badindex;
7521 }
7522 str = endptr;
7523 }
7524 /* The only thing left should be spaces */
7525 while (isspace(UCHAR(*str))) {
7526 str++;
7527 }
7528 if (*str) {
7529 goto badindex;
7530 }
7531 if (end) {
7532 if (idx > 0) {
7533 idx = INT_MAX;
7534 }
7535 else {
7536 /* end-1 is repesented as -2 */
7537 idx--;
7538 }
7539 }
7540 else if (idx < 0) {
7541 idx = -INT_MAX;
7542 }
7543
7544 /* Free the old internal repr and set the new one. */
7545 Jim_FreeIntRep(interp, objPtr);
7546 objPtr->typePtr = &indexObjType;
7547 objPtr->internalRep.intValue = idx;
7548 return JIM_OK;
7549
7550 badindex:
7551 Jim_SetResultFormatted(interp,
7552 "bad index \"%#s\": must be integer?[+-]integer? or end?[+-]integer?", objPtr);
7553 return JIM_ERR;
7554 }
7555
7556 int Jim_GetIndex(Jim_Interp *interp, Jim_Obj *objPtr, int *indexPtr)
7557 {
7558 /* Avoid shimmering if the object is an integer. */
7559 if (objPtr->typePtr == &intObjType) {
7560 jim_wide val = JimWideValue(objPtr);
7561
7562 if (val < 0)
7563 *indexPtr = -INT_MAX;
7564 else if (val > INT_MAX)
7565 *indexPtr = INT_MAX;
7566 else
7567 *indexPtr = (int)val;
7568 return JIM_OK;
7569 }
7570 if (objPtr->typePtr != &indexObjType && SetIndexFromAny(interp, objPtr) == JIM_ERR)
7571 return JIM_ERR;
7572 *indexPtr = objPtr->internalRep.intValue;
7573 return JIM_OK;
7574 }
7575
7576 /* -----------------------------------------------------------------------------
7577 * Return Code Object.
7578 * ---------------------------------------------------------------------------*/
7579
7580 /* NOTE: These must be kept in the same order as JIM_OK, JIM_ERR, ... */
7581 static const char * const jimReturnCodes[] = {
7582 "ok",
7583 "error",
7584 "return",
7585 "break",
7586 "continue",
7587 "signal",
7588 "exit",
7589 "eval",
7590 NULL
7591 };
7592
7593 #define jimReturnCodesSize (sizeof(jimReturnCodes)/sizeof(*jimReturnCodes) - 1)
7594
7595 static const Jim_ObjType returnCodeObjType = {
7596 "return-code",
7597 NULL,
7598 NULL,
7599 NULL,
7600 JIM_TYPE_NONE,
7601 };
7602
7603 /* Converts a (standard) return code to a string. Returns "?" for
7604 * non-standard return codes.
7605 */
7606 const char *Jim_ReturnCode(int code)
7607 {
7608 if (code < 0 || code >= (int)jimReturnCodesSize) {
7609 return "?";
7610 }
7611 else {
7612 return jimReturnCodes[code];
7613 }
7614 }
7615
7616 static int SetReturnCodeFromAny(Jim_Interp *interp, Jim_Obj *objPtr)
7617 {
7618 int returnCode;
7619 jim_wide wideValue;
7620
7621 /* Try to convert into an integer */
7622 if (JimGetWideNoErr(interp, objPtr, &wideValue) != JIM_ERR)
7623 returnCode = (int)wideValue;
7624 else if (Jim_GetEnum(interp, objPtr, jimReturnCodes, &returnCode, NULL, JIM_NONE) != JIM_OK) {
7625 Jim_SetResultFormatted(interp, "expected return code but got \"%#s\"", objPtr);
7626 return JIM_ERR;
7627 }
7628 /* Free the old internal repr and set the new one. */
7629 Jim_FreeIntRep(interp, objPtr);
7630 objPtr->typePtr = &returnCodeObjType;
7631 objPtr->internalRep.intValue = returnCode;
7632 return JIM_OK;
7633 }
7634
7635 int Jim_GetReturnCode(Jim_Interp *interp, Jim_Obj *objPtr, int *intPtr)
7636 {
7637 if (objPtr->typePtr != &returnCodeObjType && SetReturnCodeFromAny(interp, objPtr) == JIM_ERR)
7638 return JIM_ERR;
7639 *intPtr = objPtr->internalRep.intValue;
7640 return JIM_OK;
7641 }
7642
7643 /* -----------------------------------------------------------------------------
7644 * Expression Parsing
7645 * ---------------------------------------------------------------------------*/
7646 static int JimParseExprOperator(struct JimParserCtx *pc);
7647 static int JimParseExprNumber(struct JimParserCtx *pc);
7648 static int JimParseExprIrrational(struct JimParserCtx *pc);
7649 static int JimParseExprBoolean(struct JimParserCtx *pc);
7650
7651 /* expr operator opcodes. */
7652 enum
7653 {
7654 /* Continues on from the JIM_TT_ space */
7655
7656 /* Binary operators (numbers) */
7657 JIM_EXPROP_MUL = JIM_TT_EXPR_OP, /* 20 */
7658 JIM_EXPROP_DIV,
7659 JIM_EXPROP_MOD,
7660 JIM_EXPROP_SUB,
7661 JIM_EXPROP_ADD,
7662 JIM_EXPROP_LSHIFT,
7663 JIM_EXPROP_RSHIFT,
7664 JIM_EXPROP_ROTL,
7665 JIM_EXPROP_ROTR,
7666 JIM_EXPROP_LT,
7667 JIM_EXPROP_GT,
7668 JIM_EXPROP_LTE,
7669 JIM_EXPROP_GTE,
7670 JIM_EXPROP_NUMEQ,
7671 JIM_EXPROP_NUMNE,
7672 JIM_EXPROP_BITAND, /* 35 */
7673 JIM_EXPROP_BITXOR,
7674 JIM_EXPROP_BITOR,
7675 JIM_EXPROP_LOGICAND, /* 38 */
7676 JIM_EXPROP_LOGICOR, /* 39 */
7677 JIM_EXPROP_TERNARY, /* 40 */
7678 JIM_EXPROP_COLON, /* 41 */
7679 JIM_EXPROP_POW, /* 42 */
7680
7681 /* Binary operators (strings) */
7682 JIM_EXPROP_STREQ, /* 43 */
7683 JIM_EXPROP_STRNE,
7684 JIM_EXPROP_STRIN,
7685 JIM_EXPROP_STRNI,
7686
7687 /* Unary operators (numbers) */
7688 JIM_EXPROP_NOT, /* 47 */
7689 JIM_EXPROP_BITNOT,
7690 JIM_EXPROP_UNARYMINUS,
7691 JIM_EXPROP_UNARYPLUS,
7692
7693 /* Functions */
7694 JIM_EXPROP_FUNC_INT, /* 51 */
7695 JIM_EXPROP_FUNC_WIDE,
7696 JIM_EXPROP_FUNC_ABS,
7697 JIM_EXPROP_FUNC_DOUBLE,
7698 JIM_EXPROP_FUNC_ROUND,
7699 JIM_EXPROP_FUNC_RAND,
7700 JIM_EXPROP_FUNC_SRAND,
7701
7702 /* math functions from libm */
7703 JIM_EXPROP_FUNC_SIN, /* 65 */
7704 JIM_EXPROP_FUNC_COS,
7705 JIM_EXPROP_FUNC_TAN,
7706 JIM_EXPROP_FUNC_ASIN,
7707 JIM_EXPROP_FUNC_ACOS,
7708 JIM_EXPROP_FUNC_ATAN,
7709 JIM_EXPROP_FUNC_ATAN2,
7710 JIM_EXPROP_FUNC_SINH,
7711 JIM_EXPROP_FUNC_COSH,
7712 JIM_EXPROP_FUNC_TANH,
7713 JIM_EXPROP_FUNC_CEIL,
7714 JIM_EXPROP_FUNC_FLOOR,
7715 JIM_EXPROP_FUNC_EXP,
7716 JIM_EXPROP_FUNC_LOG,
7717 JIM_EXPROP_FUNC_LOG10,
7718 JIM_EXPROP_FUNC_SQRT,
7719 JIM_EXPROP_FUNC_POW,
7720 JIM_EXPROP_FUNC_HYPOT,
7721 JIM_EXPROP_FUNC_FMOD,
7722 };
7723
7724 /* A expression node is either a term or an operator
7725 * If a node is an operator, 'op' points to the details of the operator and it's terms.
7726 */
7727 struct JimExprNode {
7728 int type; /* JIM_TT_xxx */
7729 struct Jim_Obj *objPtr; /* The object for a term, or NULL for an operator */
7730
7731 struct JimExprNode *left; /* For all operators */
7732 struct JimExprNode *right; /* For binary operators */
7733 struct JimExprNode *ternary; /* For ternary operator only */
7734 };
7735
7736 /* Operators table */
7737 typedef struct Jim_ExprOperator
7738 {
7739 const char *name;
7740 int (*funcop) (Jim_Interp *interp, struct JimExprNode *opnode);
7741 unsigned char precedence;
7742 unsigned char arity;
7743 unsigned char attr;
7744 unsigned char namelen;
7745 } Jim_ExprOperator;
7746
7747 static int JimExprGetTerm(Jim_Interp *interp, struct JimExprNode *node, Jim_Obj **objPtrPtr);
7748 static int JimExprGetTermBoolean(Jim_Interp *interp, struct JimExprNode *node);
7749 static int JimExprEvalTermNode(Jim_Interp *interp, struct JimExprNode *node);
7750
7751 static int JimExprOpNumUnary(Jim_Interp *interp, struct JimExprNode *node)
7752 {
7753 int intresult = 1;
7754 int rc;
7755 double dA, dC = 0;
7756 jim_wide wA, wC = 0;
7757 Jim_Obj *A;
7758
7759 if ((rc = JimExprGetTerm(interp, node->left, &A)) != JIM_OK) {
7760 return rc;
7761 }
7762
7763 if ((A->typePtr != &doubleObjType || A->bytes) && JimGetWideNoErr(interp, A, &wA) == JIM_OK) {
7764 switch (node->type) {
7765 case JIM_EXPROP_FUNC_INT:
7766 case JIM_EXPROP_FUNC_WIDE:
7767 case JIM_EXPROP_FUNC_ROUND:
7768 case JIM_EXPROP_UNARYPLUS:
7769 wC = wA;
7770 break;
7771 case JIM_EXPROP_FUNC_DOUBLE:
7772 dC = wA;
7773 intresult = 0;
7774 break;
7775 case JIM_EXPROP_FUNC_ABS:
7776 wC = wA >= 0 ? wA : -wA;
7777 break;
7778 case JIM_EXPROP_UNARYMINUS:
7779 wC = -wA;
7780 break;
7781 case JIM_EXPROP_NOT:
7782 wC = !wA;
7783 break;
7784 default:
7785 abort();
7786 }
7787 }
7788 else if ((rc = Jim_GetDouble(interp, A, &dA)) == JIM_OK) {
7789 switch (node->type) {
7790 case JIM_EXPROP_FUNC_INT:
7791 case JIM_EXPROP_FUNC_WIDE:
7792 wC = dA;
7793 break;
7794 case JIM_EXPROP_FUNC_ROUND:
7795 wC = dA < 0 ? (dA - 0.5) : (dA + 0.5);
7796 break;
7797 case JIM_EXPROP_FUNC_DOUBLE:
7798 case JIM_EXPROP_UNARYPLUS:
7799 dC = dA;
7800 intresult = 0;
7801 break;
7802 case JIM_EXPROP_FUNC_ABS:
7803 #ifdef JIM_MATH_FUNCTIONS
7804 dC = fabs(dA);
7805 #else
7806 dC = dA >= 0 ? dA : -dA;
7807 #endif
7808 intresult = 0;
7809 break;
7810 case JIM_EXPROP_UNARYMINUS:
7811 dC = -dA;
7812 intresult = 0;
7813 break;
7814 case JIM_EXPROP_NOT:
7815 wC = !dA;
7816 break;
7817 default:
7818 abort();
7819 }
7820 }
7821
7822 if (rc == JIM_OK) {
7823 if (intresult) {
7824 Jim_SetResultInt(interp, wC);
7825 }
7826 else {
7827 Jim_SetResult(interp, Jim_NewDoubleObj(interp, dC));
7828 }
7829 }
7830
7831 Jim_DecrRefCount(interp, A);
7832
7833 return rc;
7834 }
7835
7836 static double JimRandDouble(Jim_Interp *interp)
7837 {
7838 unsigned long x;
7839 JimRandomBytes(interp, &x, sizeof(x));
7840
7841 return (double)x / (unsigned long)~0;
7842 }
7843
7844 static int JimExprOpIntUnary(Jim_Interp *interp, struct JimExprNode *node)
7845 {
7846 jim_wide wA;
7847 Jim_Obj *A;
7848 int rc;
7849
7850 if ((rc = JimExprGetTerm(interp, node->left, &A)) != JIM_OK) {
7851 return rc;
7852 }
7853
7854 rc = Jim_GetWide(interp, A, &wA);
7855 if (rc == JIM_OK) {
7856 switch (node->type) {
7857 case JIM_EXPROP_BITNOT:
7858 Jim_SetResultInt(interp, ~wA);
7859 break;
7860 case JIM_EXPROP_FUNC_SRAND:
7861 JimPrngSeed(interp, (unsigned char *)&wA, sizeof(wA));
7862 Jim_SetResult(interp, Jim_NewDoubleObj(interp, JimRandDouble(interp)));
7863 break;
7864 default:
7865 abort();
7866 }
7867 }
7868
7869 Jim_DecrRefCount(interp, A);
7870
7871 return rc;
7872 }
7873
7874 static int JimExprOpNone(Jim_Interp *interp, struct JimExprNode *node)
7875 {
7876 JimPanic((node->type != JIM_EXPROP_FUNC_RAND, "JimExprOpNone only support rand()"));
7877
7878 Jim_SetResult(interp, Jim_NewDoubleObj(interp, JimRandDouble(interp)));
7879
7880 return JIM_OK;
7881 }
7882
7883 #ifdef JIM_MATH_FUNCTIONS
7884 static int JimExprOpDoubleUnary(Jim_Interp *interp, struct JimExprNode *node)
7885 {
7886 int rc;
7887 double dA, dC;
7888 Jim_Obj *A;
7889
7890 if ((rc = JimExprGetTerm(interp, node->left, &A)) != JIM_OK) {
7891 return rc;
7892 }
7893
7894 rc = Jim_GetDouble(interp, A, &dA);
7895 if (rc == JIM_OK) {
7896 switch (node->type) {
7897 case JIM_EXPROP_FUNC_SIN:
7898 dC = sin(dA);
7899 break;
7900 case JIM_EXPROP_FUNC_COS:
7901 dC = cos(dA);
7902 break;
7903 case JIM_EXPROP_FUNC_TAN:
7904 dC = tan(dA);
7905 break;
7906 case JIM_EXPROP_FUNC_ASIN:
7907 dC = asin(dA);
7908 break;
7909 case JIM_EXPROP_FUNC_ACOS:
7910 dC = acos(dA);
7911 break;
7912 case JIM_EXPROP_FUNC_ATAN:
7913 dC = atan(dA);
7914 break;
7915 case JIM_EXPROP_FUNC_SINH:
7916 dC = sinh(dA);
7917 break;
7918 case JIM_EXPROP_FUNC_COSH:
7919 dC = cosh(dA);
7920 break;
7921 case JIM_EXPROP_FUNC_TANH:
7922 dC = tanh(dA);
7923 break;
7924 case JIM_EXPROP_FUNC_CEIL:
7925 dC = ceil(dA);
7926 break;
7927 case JIM_EXPROP_FUNC_FLOOR:
7928 dC = floor(dA);
7929 break;
7930 case JIM_EXPROP_FUNC_EXP:
7931 dC = exp(dA);
7932 break;
7933 case JIM_EXPROP_FUNC_LOG:
7934 dC = log(dA);
7935 break;
7936 case JIM_EXPROP_FUNC_LOG10:
7937 dC = log10(dA);
7938 break;
7939 case JIM_EXPROP_FUNC_SQRT:
7940 dC = sqrt(dA);
7941 break;
7942 default:
7943 abort();
7944 }
7945 Jim_SetResult(interp, Jim_NewDoubleObj(interp, dC));
7946 }
7947
7948 Jim_DecrRefCount(interp, A);
7949
7950 return rc;
7951 }
7952 #endif
7953
7954 /* A binary operation on two ints */
7955 static int JimExprOpIntBin(Jim_Interp *interp, struct JimExprNode *node)
7956 {
7957 jim_wide wA, wB;
7958 int rc;
7959 Jim_Obj *A, *B;
7960
7961 if ((rc = JimExprGetTerm(interp, node->left, &A)) != JIM_OK) {
7962 return rc;
7963 }
7964 if ((rc = JimExprGetTerm(interp, node->right, &B)) != JIM_OK) {
7965 Jim_DecrRefCount(interp, A);
7966 return rc;
7967 }
7968
7969 rc = JIM_ERR;
7970
7971 if (Jim_GetWide(interp, A, &wA) == JIM_OK && Jim_GetWide(interp, B, &wB) == JIM_OK) {
7972 jim_wide wC;
7973
7974 rc = JIM_OK;
7975
7976 switch (node->type) {
7977 case JIM_EXPROP_LSHIFT:
7978 wC = wA << wB;
7979 break;
7980 case JIM_EXPROP_RSHIFT:
7981 wC = wA >> wB;
7982 break;
7983 case JIM_EXPROP_BITAND:
7984 wC = wA & wB;
7985 break;
7986 case JIM_EXPROP_BITXOR:
7987 wC = wA ^ wB;
7988 break;
7989 case JIM_EXPROP_BITOR:
7990 wC = wA | wB;
7991 break;
7992 case JIM_EXPROP_MOD:
7993 if (wB == 0) {
7994 wC = 0;
7995 Jim_SetResultString(interp, "Division by zero", -1);
7996 rc = JIM_ERR;
7997 }
7998 else {
7999 /*
8000 * From Tcl 8.x
8001 *
8002 * This code is tricky: C doesn't guarantee much
8003 * about the quotient or remainder, but Tcl does.
8004 * The remainder always has the same sign as the
8005 * divisor and a smaller absolute value.
8006 */
8007 int negative = 0;
8008
8009 if (wB < 0) {
8010 wB = -wB;
8011 wA = -wA;
8012 negative = 1;
8013 }
8014 wC = wA % wB;
8015 if (wC < 0) {
8016 wC += wB;
8017 }
8018 if (negative) {
8019 wC = -wC;
8020 }
8021 }
8022 break;
8023 case JIM_EXPROP_ROTL:
8024 case JIM_EXPROP_ROTR:{
8025 /* uint32_t would be better. But not everyone has inttypes.h? */
8026 unsigned long uA = (unsigned long)wA;
8027 unsigned long uB = (unsigned long)wB;
8028 const unsigned int S = sizeof(unsigned long) * 8;
8029
8030 /* Shift left by the word size or more is undefined. */
8031 uB %= S;
8032
8033 if (node->type == JIM_EXPROP_ROTR) {
8034 uB = S - uB;
8035 }
8036 wC = (unsigned long)(uA << uB) | (uA >> (S - uB));
8037 break;
8038 }
8039 default:
8040 abort();
8041 }
8042 Jim_SetResultInt(interp, wC);
8043 }
8044
8045 Jim_DecrRefCount(interp, A);
8046 Jim_DecrRefCount(interp, B);
8047
8048 return rc;
8049 }
8050
8051
8052 /* A binary operation on two ints or two doubles (or two strings for some ops) */
8053 static int JimExprOpBin(Jim_Interp *interp, struct JimExprNode *node)
8054 {
8055 int rc = JIM_OK;
8056 double dA, dB, dC = 0;
8057 jim_wide wA, wB, wC = 0;
8058 Jim_Obj *A, *B;
8059
8060 if ((rc = JimExprGetTerm(interp, node->left, &A)) != JIM_OK) {
8061 return rc;
8062 }
8063 if ((rc = JimExprGetTerm(interp, node->right, &B)) != JIM_OK) {
8064 Jim_DecrRefCount(interp, A);
8065 return rc;
8066 }
8067
8068 if ((A->typePtr != &doubleObjType || A->bytes) &&
8069 (B->typePtr != &doubleObjType || B->bytes) &&
8070 JimGetWideNoErr(interp, A, &wA) == JIM_OK && JimGetWideNoErr(interp, B, &wB) == JIM_OK) {
8071
8072 /* Both are ints */
8073
8074 switch (node->type) {
8075 case JIM_EXPROP_POW:
8076 case JIM_EXPROP_FUNC_POW:
8077 if (wA == 0 && wB < 0) {
8078 Jim_SetResultString(interp, "exponentiation of zero by negative power", -1);
8079 rc = JIM_ERR;
8080 goto done;
8081 }
8082 wC = JimPowWide(wA, wB);
8083 goto intresult;
8084 case JIM_EXPROP_ADD:
8085 wC = wA + wB;
8086 goto intresult;
8087 case JIM_EXPROP_SUB:
8088 wC = wA - wB;
8089 goto intresult;
8090 case JIM_EXPROP_MUL:
8091 wC = wA * wB;
8092 goto intresult;
8093 case JIM_EXPROP_DIV:
8094 if (wB == 0) {
8095 Jim_SetResultString(interp, "Division by zero", -1);
8096 rc = JIM_ERR;
8097 goto done;
8098 }
8099 else {
8100 /*
8101 * From Tcl 8.x
8102 *
8103 * This code is tricky: C doesn't guarantee much
8104 * about the quotient or remainder, but Tcl does.
8105 * The remainder always has the same sign as the
8106 * divisor and a smaller absolute value.
8107 */
8108 if (wB < 0) {
8109 wB = -wB;
8110 wA = -wA;
8111 }
8112 wC = wA / wB;
8113 if (wA % wB < 0) {
8114 wC--;
8115 }
8116 goto intresult;
8117 }
8118 case JIM_EXPROP_LT:
8119 wC = wA < wB;
8120 goto intresult;
8121 case JIM_EXPROP_GT:
8122 wC = wA > wB;
8123 goto intresult;
8124 case JIM_EXPROP_LTE:
8125 wC = wA <= wB;
8126 goto intresult;
8127 case JIM_EXPROP_GTE:
8128 wC = wA >= wB;
8129 goto intresult;
8130 case JIM_EXPROP_NUMEQ:
8131 wC = wA == wB;
8132 goto intresult;
8133 case JIM_EXPROP_NUMNE:
8134 wC = wA != wB;
8135 goto intresult;
8136 }
8137 }
8138 if (Jim_GetDouble(interp, A, &dA) == JIM_OK && Jim_GetDouble(interp, B, &dB) == JIM_OK) {
8139 switch (node->type) {
8140 #ifndef JIM_MATH_FUNCTIONS
8141 case JIM_EXPROP_POW:
8142 case JIM_EXPROP_FUNC_POW:
8143 case JIM_EXPROP_FUNC_ATAN2:
8144 case JIM_EXPROP_FUNC_HYPOT:
8145 case JIM_EXPROP_FUNC_FMOD:
8146 Jim_SetResultString(interp, "unsupported", -1);
8147 rc = JIM_ERR;
8148 goto done;
8149 #else
8150 case JIM_EXPROP_POW:
8151 case JIM_EXPROP_FUNC_POW:
8152 dC = pow(dA, dB);
8153 goto doubleresult;
8154 case JIM_EXPROP_FUNC_ATAN2:
8155 dC = atan2(dA, dB);
8156 goto doubleresult;
8157 case JIM_EXPROP_FUNC_HYPOT:
8158 dC = hypot(dA, dB);
8159 goto doubleresult;
8160 case JIM_EXPROP_FUNC_FMOD:
8161 dC = fmod(dA, dB);
8162 goto doubleresult;
8163 #endif
8164 case JIM_EXPROP_ADD:
8165 dC = dA + dB;
8166 goto doubleresult;
8167 case JIM_EXPROP_SUB:
8168 dC = dA - dB;
8169 goto doubleresult;
8170 case JIM_EXPROP_MUL:
8171 dC = dA * dB;
8172 goto doubleresult;
8173 case JIM_EXPROP_DIV:
8174 if (dB == 0) {
8175 #ifdef INFINITY
8176 dC = dA < 0 ? -INFINITY : INFINITY;
8177 #else
8178 dC = (dA < 0 ? -1.0 : 1.0) * strtod("Inf", NULL);
8179 #endif
8180 }
8181 else {
8182 dC = dA / dB;
8183 }
8184 goto doubleresult;
8185 case JIM_EXPROP_LT:
8186 wC = dA < dB;
8187 goto intresult;
8188 case JIM_EXPROP_GT:
8189 wC = dA > dB;
8190 goto intresult;
8191 case JIM_EXPROP_LTE:
8192 wC = dA <= dB;
8193 goto intresult;
8194 case JIM_EXPROP_GTE:
8195 wC = dA >= dB;
8196 goto intresult;
8197 case JIM_EXPROP_NUMEQ:
8198 wC = dA == dB;
8199 goto intresult;
8200 case JIM_EXPROP_NUMNE:
8201 wC = dA != dB;
8202 goto intresult;
8203 }
8204 }
8205 else {
8206 /* Handle the string case */
8207
8208 /* XXX: Could optimise the eq/ne case by checking lengths */
8209 int i = Jim_StringCompareObj(interp, A, B, 0);
8210
8211 switch (node->type) {
8212 case JIM_EXPROP_LT:
8213 wC = i < 0;
8214 goto intresult;
8215 case JIM_EXPROP_GT:
8216 wC = i > 0;
8217 goto intresult;
8218 case JIM_EXPROP_LTE:
8219 wC = i <= 0;
8220 goto intresult;
8221 case JIM_EXPROP_GTE:
8222 wC = i >= 0;
8223 goto intresult;
8224 case JIM_EXPROP_NUMEQ:
8225 wC = i == 0;
8226 goto intresult;
8227 case JIM_EXPROP_NUMNE:
8228 wC = i != 0;
8229 goto intresult;
8230 }
8231 }
8232 /* If we get here, it is an error */
8233 rc = JIM_ERR;
8234 done:
8235 Jim_DecrRefCount(interp, A);
8236 Jim_DecrRefCount(interp, B);
8237 return rc;
8238 intresult:
8239 Jim_SetResultInt(interp, wC);
8240 goto done;
8241 doubleresult:
8242 Jim_SetResult(interp, Jim_NewDoubleObj(interp, dC));
8243 goto done;
8244 }
8245
8246 static int JimSearchList(Jim_Interp *interp, Jim_Obj *listObjPtr, Jim_Obj *valObj)
8247 {
8248 int listlen;
8249 int i;
8250
8251 listlen = Jim_ListLength(interp, listObjPtr);
8252 for (i = 0; i < listlen; i++) {
8253 if (Jim_StringEqObj(Jim_ListGetIndex(interp, listObjPtr, i), valObj)) {
8254 return 1;
8255 }
8256 }
8257 return 0;
8258 }
8259
8260
8261
8262 static int JimExprOpStrBin(Jim_Interp *interp, struct JimExprNode *node)
8263 {
8264 Jim_Obj *A, *B;
8265 jim_wide wC;
8266 int rc;
8267
8268 if ((rc = JimExprGetTerm(interp, node->left, &A)) != JIM_OK) {
8269 return rc;
8270 }
8271 if ((rc = JimExprGetTerm(interp, node->right, &B)) != JIM_OK) {
8272 Jim_DecrRefCount(interp, A);
8273 return rc;
8274 }
8275
8276 switch (node->type) {
8277 case JIM_EXPROP_STREQ:
8278 case JIM_EXPROP_STRNE:
8279 wC = Jim_StringEqObj(A, B);
8280 if (node->type == JIM_EXPROP_STRNE) {
8281 wC = !wC;
8282 }
8283 break;
8284 case JIM_EXPROP_STRIN:
8285 wC = JimSearchList(interp, B, A);
8286 break;
8287 case JIM_EXPROP_STRNI:
8288 wC = !JimSearchList(interp, B, A);
8289 break;
8290 default:
8291 abort();
8292 }
8293 Jim_SetResultInt(interp, wC);
8294
8295 Jim_DecrRefCount(interp, A);
8296 Jim_DecrRefCount(interp, B);
8297
8298 return rc;
8299 }
8300
8301 static int ExprBool(Jim_Interp *interp, Jim_Obj *obj)
8302 {
8303 long l;
8304 double d;
8305 int b;
8306 int ret = -1;
8307
8308 /* In case the object is interp->result with refcount 1*/
8309 Jim_IncrRefCount(obj);
8310
8311 if (Jim_GetLong(interp, obj, &l) == JIM_OK) {
8312 ret = (l != 0);
8313 }
8314 else if (Jim_GetDouble(interp, obj, &d) == JIM_OK) {
8315 ret = (d != 0);
8316 }
8317 else if (Jim_GetBoolean(interp, obj, &b) == JIM_OK) {
8318 ret = (b != 0);
8319 }
8320
8321 Jim_DecrRefCount(interp, obj);
8322 return ret;
8323 }
8324
8325 static int JimExprOpAnd(Jim_Interp *interp, struct JimExprNode *node)
8326 {
8327 /* evaluate left */
8328 int result = JimExprGetTermBoolean(interp, node->left);
8329
8330 if (result == 1) {
8331 /* true so evaluate right */
8332 result = JimExprGetTermBoolean(interp, node->right);
8333 }
8334 if (result == -1) {
8335 return JIM_ERR;
8336 }
8337 Jim_SetResultInt(interp, result);
8338 return JIM_OK;
8339 }
8340
8341 static int JimExprOpOr(Jim_Interp *interp, struct JimExprNode *node)
8342 {
8343 /* evaluate left */
8344 int result = JimExprGetTermBoolean(interp, node->left);
8345
8346 if (result == 0) {
8347 /* false so evaluate right */
8348 result = JimExprGetTermBoolean(interp, node->right);
8349 }
8350 if (result == -1) {
8351 return JIM_ERR;
8352 }
8353 Jim_SetResultInt(interp, result);
8354 return JIM_OK;
8355 }
8356
8357 static int JimExprOpTernary(Jim_Interp *interp, struct JimExprNode *node)
8358 {
8359 /* evaluate left */
8360 int result = JimExprGetTermBoolean(interp, node->left);
8361
8362 if (result == 1) {
8363 /* true so select right */
8364 return JimExprEvalTermNode(interp, node->right);
8365 }
8366 else if (result == 0) {
8367 /* false so select ternary */
8368 return JimExprEvalTermNode(interp, node->ternary);
8369 }
8370 /* error */
8371 return JIM_ERR;
8372 }
8373
8374 enum
8375 {
8376 OP_FUNC = 0x0001, /* function syntax */
8377 OP_RIGHT_ASSOC = 0x0002, /* right associative */
8378 };
8379
8380 /* name - precedence - arity - opcode
8381 *
8382 * This array *must* be kept in sync with the JIM_EXPROP enum.
8383 *
8384 * The following macros pre-compute the string length at compile time.
8385 */
8386 #define OPRINIT_ATTR(N, P, ARITY, F, ATTR) {N, F, P, ARITY, ATTR, sizeof(N) - 1}
8387 #define OPRINIT(N, P, ARITY, F) OPRINIT_ATTR(N, P, ARITY, F, 0)
8388
8389 static const struct Jim_ExprOperator Jim_ExprOperators[] = {
8390 OPRINIT("*", 110, 2, JimExprOpBin),
8391 OPRINIT("/", 110, 2, JimExprOpBin),
8392 OPRINIT("%", 110, 2, JimExprOpIntBin),
8393
8394 OPRINIT("-", 100, 2, JimExprOpBin),
8395 OPRINIT("+", 100, 2, JimExprOpBin),
8396
8397 OPRINIT("<<", 90, 2, JimExprOpIntBin),
8398 OPRINIT(">>", 90, 2, JimExprOpIntBin),
8399
8400 OPRINIT("<<<", 90, 2, JimExprOpIntBin),
8401 OPRINIT(">>>", 90, 2, JimExprOpIntBin),
8402
8403 OPRINIT("<", 80, 2, JimExprOpBin),
8404 OPRINIT(">", 80, 2, JimExprOpBin),
8405 OPRINIT("<=", 80, 2, JimExprOpBin),
8406 OPRINIT(">=", 80, 2, JimExprOpBin),
8407
8408 OPRINIT("==", 70, 2, JimExprOpBin),
8409 OPRINIT("!=", 70, 2, JimExprOpBin),
8410
8411 OPRINIT("&", 50, 2, JimExprOpIntBin),
8412 OPRINIT("^", 49, 2, JimExprOpIntBin),
8413 OPRINIT("|", 48, 2, JimExprOpIntBin),
8414
8415 OPRINIT("&&", 10, 2, JimExprOpAnd),
8416 OPRINIT("||", 9, 2, JimExprOpOr),
8417 OPRINIT_ATTR("?", 5, 3, JimExprOpTernary, OP_RIGHT_ASSOC),
8418 OPRINIT_ATTR(":", 5, 3, NULL, OP_RIGHT_ASSOC),
8419
8420 /* Precedence is higher than * and / but lower than ! and ~, and right-associative */
8421 OPRINIT_ATTR("**", 120, 2, JimExprOpBin, OP_RIGHT_ASSOC),
8422
8423 OPRINIT("eq", 60, 2, JimExprOpStrBin),
8424 OPRINIT("ne", 60, 2, JimExprOpStrBin),
8425
8426 OPRINIT("in", 55, 2, JimExprOpStrBin),
8427 OPRINIT("ni", 55, 2, JimExprOpStrBin),
8428
8429 OPRINIT_ATTR("!", 150, 1, JimExprOpNumUnary, OP_RIGHT_ASSOC),
8430 OPRINIT_ATTR("~", 150, 1, JimExprOpIntUnary, OP_RIGHT_ASSOC),
8431 OPRINIT_ATTR(" -", 150, 1, JimExprOpNumUnary, OP_RIGHT_ASSOC),
8432 OPRINIT_ATTR(" +", 150, 1, JimExprOpNumUnary, OP_RIGHT_ASSOC),
8433
8434
8435
8436 OPRINIT_ATTR("int", 200, 1, JimExprOpNumUnary, OP_FUNC),
8437 OPRINIT_ATTR("wide", 200, 1, JimExprOpNumUnary, OP_FUNC),
8438 OPRINIT_ATTR("abs", 200, 1, JimExprOpNumUnary, OP_FUNC),
8439 OPRINIT_ATTR("double", 200, 1, JimExprOpNumUnary, OP_FUNC),
8440 OPRINIT_ATTR("round", 200, 1, JimExprOpNumUnary, OP_FUNC),
8441 OPRINIT_ATTR("rand", 200, 0, JimExprOpNone, OP_FUNC),
8442 OPRINIT_ATTR("srand", 200, 1, JimExprOpIntUnary, OP_FUNC),
8443
8444 #ifdef JIM_MATH_FUNCTIONS
8445 OPRINIT_ATTR("sin", 200, 1, JimExprOpDoubleUnary, OP_FUNC),
8446 OPRINIT_ATTR("cos", 200, 1, JimExprOpDoubleUnary, OP_FUNC),
8447 OPRINIT_ATTR("tan", 200, 1, JimExprOpDoubleUnary, OP_FUNC),
8448 OPRINIT_ATTR("asin", 200, 1, JimExprOpDoubleUnary, OP_FUNC),
8449 OPRINIT_ATTR("acos", 200, 1, JimExprOpDoubleUnary, OP_FUNC),
8450 OPRINIT_ATTR("atan", 200, 1, JimExprOpDoubleUnary, OP_FUNC),
8451 OPRINIT_ATTR("atan2", 200, 2, JimExprOpBin, OP_FUNC),
8452 OPRINIT_ATTR("sinh", 200, 1, JimExprOpDoubleUnary, OP_FUNC),
8453 OPRINIT_ATTR("cosh", 200, 1, JimExprOpDoubleUnary, OP_FUNC),
8454 OPRINIT_ATTR("tanh", 200, 1, JimExprOpDoubleUnary, OP_FUNC),
8455 OPRINIT_ATTR("ceil", 200, 1, JimExprOpDoubleUnary, OP_FUNC),
8456 OPRINIT_ATTR("floor", 200, 1, JimExprOpDoubleUnary, OP_FUNC),
8457 OPRINIT_ATTR("exp", 200, 1, JimExprOpDoubleUnary, OP_FUNC),
8458 OPRINIT_ATTR("log", 200, 1, JimExprOpDoubleUnary, OP_FUNC),
8459 OPRINIT_ATTR("log10", 200, 1, JimExprOpDoubleUnary, OP_FUNC),
8460 OPRINIT_ATTR("sqrt", 200, 1, JimExprOpDoubleUnary, OP_FUNC),
8461 OPRINIT_ATTR("pow", 200, 2, JimExprOpBin, OP_FUNC),
8462 OPRINIT_ATTR("hypot", 200, 2, JimExprOpBin, OP_FUNC),
8463 OPRINIT_ATTR("fmod", 200, 2, JimExprOpBin, OP_FUNC),
8464 #endif
8465 };
8466 #undef OPRINIT
8467 #undef OPRINIT_ATTR
8468
8469 #define JIM_EXPR_OPERATORS_NUM \
8470 (sizeof(Jim_ExprOperators)/sizeof(struct Jim_ExprOperator))
8471
8472 static int JimParseExpression(struct JimParserCtx *pc)
8473 {
8474 /* Discard spaces and quoted newline */
8475 while (isspace(UCHAR(*pc->p)) || (*(pc->p) == '\\' && *(pc->p + 1) == '\n')) {
8476 if (*pc->p == '\n') {
8477 pc->linenr++;
8478 }
8479 pc->p++;
8480 pc->len--;
8481 }
8482
8483 /* Common case */
8484 pc->tline = pc->linenr;
8485 pc->tstart = pc->p;
8486
8487 if (pc->len == 0) {
8488 pc->tend = pc->p;
8489 pc->tt = JIM_TT_EOL;
8490 pc->eof = 1;
8491 return JIM_OK;
8492 }
8493 switch (*(pc->p)) {
8494 case '(':
8495 pc->tt = JIM_TT_SUBEXPR_START;
8496 goto singlechar;
8497 case ')':
8498 pc->tt = JIM_TT_SUBEXPR_END;
8499 goto singlechar;
8500 case ',':
8501 pc->tt = JIM_TT_SUBEXPR_COMMA;
8502 singlechar:
8503 pc->tend = pc->p;
8504 pc->p++;
8505 pc->len--;
8506 break;
8507 case '[':
8508 return JimParseCmd(pc);
8509 case '$':
8510 if (JimParseVar(pc) == JIM_ERR)
8511 return JimParseExprOperator(pc);
8512 else {
8513 /* Don't allow expr sugar in expressions */
8514 if (pc->tt == JIM_TT_EXPRSUGAR) {
8515 return JIM_ERR;
8516 }
8517 return JIM_OK;
8518 }
8519 break;
8520 case '0':
8521 case '1':
8522 case '2':
8523 case '3':
8524 case '4':
8525 case '5':
8526 case '6':
8527 case '7':
8528 case '8':
8529 case '9':
8530 case '.':
8531 return JimParseExprNumber(pc);
8532 case '"':
8533 return JimParseQuote(pc);
8534 case '{':
8535 return JimParseBrace(pc);
8536
8537 case 'N':
8538 case 'I':
8539 case 'n':
8540 case 'i':
8541 if (JimParseExprIrrational(pc) == JIM_ERR)
8542 if (JimParseExprBoolean(pc) == JIM_ERR)
8543 return JimParseExprOperator(pc);
8544 break;
8545 case 't':
8546 case 'f':
8547 case 'o':
8548 case 'y':
8549 if (JimParseExprBoolean(pc) == JIM_ERR)
8550 return JimParseExprOperator(pc);
8551 break;
8552 default:
8553 return JimParseExprOperator(pc);
8554 break;
8555 }
8556 return JIM_OK;
8557 }
8558
8559 static int JimParseExprNumber(struct JimParserCtx *pc)
8560 {
8561 char *end;
8562
8563 /* Assume an integer for now */
8564 pc->tt = JIM_TT_EXPR_INT;
8565
8566 jim_strtoull(pc->p, (char **)&pc->p);
8567 /* Tried as an integer, but perhaps it parses as a double */
8568 if (strchr("eENnIi.", *pc->p) || pc->p == pc->tstart) {
8569 /* Some stupid compilers insist they are cleverer that
8570 * we are. Even a (void) cast doesn't prevent this warning!
8571 */
8572 if (strtod(pc->tstart, &end)) { /* nothing */ }
8573 if (end == pc->tstart)
8574 return JIM_ERR;
8575 if (end > pc->p) {
8576 /* Yes, double captured more chars */
8577 pc->tt = JIM_TT_EXPR_DOUBLE;
8578 pc->p = end;
8579 }
8580 }
8581 pc->tend = pc->p - 1;
8582 pc->len -= (pc->p - pc->tstart);
8583 return JIM_OK;
8584 }
8585
8586 static int JimParseExprIrrational(struct JimParserCtx *pc)
8587 {
8588 const char *irrationals[] = { "NaN", "nan", "NAN", "Inf", "inf", "INF", NULL };
8589 int i;
8590
8591 for (i = 0; irrationals[i]; i++) {
8592 const char *irr = irrationals[i];
8593
8594 if (strncmp(irr, pc->p, 3) == 0) {
8595 pc->p += 3;
8596 pc->len -= 3;
8597 pc->tend = pc->p - 1;
8598 pc->tt = JIM_TT_EXPR_DOUBLE;
8599 return JIM_OK;
8600 }
8601 }
8602 return JIM_ERR;
8603 }
8604
8605 static int JimParseExprBoolean(struct JimParserCtx *pc)
8606 {
8607 const char *booleans[] = { "false", "no", "off", "true", "yes", "on", NULL };
8608 const int lengths[] = { 5, 2, 3, 4, 3, 2, 0 };
8609 int i;
8610
8611 for (i = 0; booleans[i]; i++) {
8612 const char *boolean = booleans[i];
8613 int length = lengths[i];
8614
8615 if (strncmp(boolean, pc->p, length) == 0) {
8616 pc->p += length;
8617 pc->len -= length;
8618 pc->tend = pc->p - 1;
8619 pc->tt = JIM_TT_EXPR_BOOLEAN;
8620 return JIM_OK;
8621 }
8622 }
8623 return JIM_ERR;
8624 }
8625
8626 static const struct Jim_ExprOperator *JimExprOperatorInfoByOpcode(int opcode)
8627 {
8628 static Jim_ExprOperator dummy_op;
8629 if (opcode < JIM_TT_EXPR_OP) {
8630 return &dummy_op;
8631 }
8632 return &Jim_ExprOperators[opcode - JIM_TT_EXPR_OP];
8633 }
8634
8635 static int JimParseExprOperator(struct JimParserCtx *pc)
8636 {
8637 int i;
8638 const struct Jim_ExprOperator *bestOp = NULL;
8639 int bestLen = 0;
8640
8641 /* Try to get the longest match. */
8642 for (i = 0; i < (signed)JIM_EXPR_OPERATORS_NUM; i++) {
8643 const struct Jim_ExprOperator *op = &Jim_ExprOperators[i];
8644
8645 if (op->name[0] != pc->p[0]) {
8646 continue;
8647 }
8648
8649 if (op->namelen > bestLen && strncmp(op->name, pc->p, op->namelen) == 0) {
8650 bestOp = op;
8651 bestLen = op->namelen;
8652 }
8653 }
8654 if (bestOp == NULL) {
8655 return JIM_ERR;
8656 }
8657
8658 /* Validate paretheses around function arguments */
8659 if (bestOp->attr & OP_FUNC) {
8660 const char *p = pc->p + bestLen;
8661 int len = pc->len - bestLen;
8662
8663 while (len && isspace(UCHAR(*p))) {
8664 len--;
8665 p++;
8666 }
8667 if (*p != '(') {
8668 return JIM_ERR;
8669 }
8670 }
8671 pc->tend = pc->p + bestLen - 1;
8672 pc->p += bestLen;
8673 pc->len -= bestLen;
8674
8675 pc->tt = (bestOp - Jim_ExprOperators) + JIM_TT_EXPR_OP;
8676 return JIM_OK;
8677 }
8678
8679 const char *jim_tt_name(int type)
8680 {
8681 static const char * const tt_names[JIM_TT_EXPR_OP] =
8682 { "NIL", "STR", "ESC", "VAR", "ARY", "CMD", "SEP", "EOL", "EOF", "LIN", "WRD", "(((", ")))", ",,,", "INT",
8683 "DBL", "BOO", "$()" };
8684 if (type < JIM_TT_EXPR_OP) {
8685 return tt_names[type];
8686 }
8687 else if (type == JIM_EXPROP_UNARYMINUS) {
8688 return "-VE";
8689 }
8690 else if (type == JIM_EXPROP_UNARYPLUS) {
8691 return "+VE";
8692 }
8693 else {
8694 const struct Jim_ExprOperator *op = JimExprOperatorInfoByOpcode(type);
8695 static char buf[20];
8696
8697 if (op->name) {
8698 return op->name;
8699 }
8700 sprintf(buf, "(%d)", type);
8701 return buf;
8702 }
8703 }
8704
8705 /* -----------------------------------------------------------------------------
8706 * Expression Object
8707 * ---------------------------------------------------------------------------*/
8708 static void FreeExprInternalRep(Jim_Interp *interp, Jim_Obj *objPtr);
8709 static void DupExprInternalRep(Jim_Interp *interp, Jim_Obj *srcPtr, Jim_Obj *dupPtr);
8710 static int SetExprFromAny(Jim_Interp *interp, struct Jim_Obj *objPtr);
8711
8712 static const Jim_ObjType exprObjType = {
8713 "expression",
8714 FreeExprInternalRep,
8715 DupExprInternalRep,
8716 NULL,
8717 JIM_TYPE_REFERENCES,
8718 };
8719
8720 /* expr tree structure */
8721 struct ExprTree
8722 {
8723 struct JimExprNode *expr; /* The first operator or term */
8724 struct JimExprNode *nodes; /* Storage of all nodes in the tree */
8725 int len; /* Number of nodes in use */
8726 int inUse; /* Used for sharing. */
8727 };
8728
8729 static void ExprTreeFreeNodes(Jim_Interp *interp, struct JimExprNode *nodes, int num)
8730 {
8731 int i;
8732 for (i = 0; i < num; i++) {
8733 if (nodes[i].objPtr) {
8734 Jim_DecrRefCount(interp, nodes[i].objPtr);
8735 }
8736 }
8737 Jim_Free(nodes);
8738 }
8739
8740 static void ExprTreeFree(Jim_Interp *interp, struct ExprTree *expr)
8741 {
8742 ExprTreeFreeNodes(interp, expr->nodes, expr->len);
8743 Jim_Free(expr);
8744 }
8745
8746 static void FreeExprInternalRep(Jim_Interp *interp, Jim_Obj *objPtr)
8747 {
8748 struct ExprTree *expr = (void *)objPtr->internalRep.ptr;
8749
8750 if (expr) {
8751 if (--expr->inUse != 0) {
8752 return;
8753 }
8754
8755 ExprTreeFree(interp, expr);
8756 }
8757 }
8758
8759 static void DupExprInternalRep(Jim_Interp *interp, Jim_Obj *srcPtr, Jim_Obj *dupPtr)
8760 {
8761 JIM_NOTUSED(interp);
8762 JIM_NOTUSED(srcPtr);
8763
8764 /* Just returns an simple string. */
8765 dupPtr->typePtr = NULL;
8766 }
8767
8768 struct ExprBuilder {
8769 int parencount; /* count of outstanding parentheses */
8770 int level; /* recursion depth */
8771 ParseToken *token; /* The current token */
8772 ParseToken *first_token; /* The first token */
8773 Jim_Stack stack; /* stack of pending terms */
8774 Jim_Obj *exprObjPtr; /* the original expression */
8775 Jim_Obj *fileNameObj; /* filename of the original expression */
8776 struct JimExprNode *nodes; /* storage for all nodes */
8777 struct JimExprNode *next; /* storage for the next node */
8778 };
8779
8780 #ifdef DEBUG_SHOW_EXPR
8781 static void JimShowExprNode(struct JimExprNode *node, int level)
8782 {
8783 int i;
8784 for (i = 0; i < level; i++) {
8785 printf(" ");
8786 }
8787 if (TOKEN_IS_EXPR_OP(node->type)) {
8788 printf("%s\n", jim_tt_name(node->type));
8789 if (node->left) {
8790 JimShowExprNode(node->left, level + 1);
8791 }
8792 if (node->right) {
8793 JimShowExprNode(node->right, level + 1);
8794 }
8795 if (node->ternary) {
8796 JimShowExprNode(node->ternary, level + 1);
8797 }
8798 }
8799 else {
8800 printf("[%s] %s\n", jim_tt_name(node->type), Jim_String(node->objPtr));
8801 }
8802 }
8803 #endif
8804
8805 #define EXPR_UNTIL_CLOSE 0x0001
8806 #define EXPR_FUNC_ARGS 0x0002
8807 #define EXPR_TERNARY 0x0004
8808
8809 /**
8810 * Parse the subexpression at builder->token and return with the node on the stack.
8811 * builder->token is advanced to the next unconsumed token.
8812 * Returns JIM_OK if OK or JIM_ERR on error and leaves a message in the interpreter result.
8813 *
8814 * 'precedence' is the precedence of the current operator. Tokens are consumed until an operator
8815 * with an equal or lower precedence is reached (or strictly lower if right associative).
8816 *
8817 * If EXPR_UNTIL_CLOSE is set, the subexpression extends up to and including the next close parenthesis.
8818 * If EXPR_FUNC_ARGS is set, multiple subexpressions (terms) are expected separated by comma
8819 * If EXPR_TERNARY is set, two subexpressions (terms) are expected separated by colon
8820 *
8821 * 'exp_numterms' indicates how many terms are expected. Normally this is 1, but may be more for EXPR_FUNC_ARGS and EXPR_TERNARY.
8822 */
8823 static int ExprTreeBuildTree(Jim_Interp *interp, struct ExprBuilder *builder, int precedence, int flags, int exp_numterms)
8824 {
8825 int rc;
8826 struct JimExprNode *node;
8827 /* Calculate the stack length expected after pushing the number of expected terms */
8828 int exp_stacklen = builder->stack.len + exp_numterms;
8829
8830 if (builder->level++ > 200) {
8831 Jim_SetResultString(interp, "Expression too complex", -1);
8832 return JIM_ERR;
8833 }
8834
8835 while (builder->token->type != JIM_TT_EOL) {
8836 ParseToken *t = builder->token++;
8837 int prevtt;
8838
8839 if (t == builder->first_token) {
8840 prevtt = JIM_TT_NONE;
8841 }
8842 else {
8843 prevtt = t[-1].type;
8844 }
8845
8846 if (t->type == JIM_TT_SUBEXPR_START) {
8847 if (builder->stack.len == exp_stacklen) {
8848 Jim_SetResultFormatted(interp, "unexpected open parenthesis in expression: \"%#s\"", builder->exprObjPtr);
8849 return JIM_ERR;
8850 }
8851 builder->parencount++;
8852 rc = ExprTreeBuildTree(interp, builder, 0, EXPR_UNTIL_CLOSE, 1);
8853 if (rc != JIM_OK) {
8854 return rc;
8855 }
8856 /* A complete subexpression is on the stack */
8857 }
8858 else if (t->type == JIM_TT_SUBEXPR_END) {
8859 if (!(flags & EXPR_UNTIL_CLOSE)) {
8860 if (builder->stack.len == exp_stacklen && builder->level > 1) {
8861 builder->token--;
8862 builder->level--;
8863 return JIM_OK;
8864 }
8865 Jim_SetResultFormatted(interp, "unexpected closing parenthesis in expression: \"%#s\"", builder->exprObjPtr);
8866 return JIM_ERR;
8867 }
8868 builder->parencount--;
8869 if (builder->stack.len == exp_stacklen) {
8870 /* Return with the expected number of subexpressions on the stack */
8871 break;
8872 }
8873 }
8874 else if (t->type == JIM_TT_SUBEXPR_COMMA) {
8875 if (!(flags & EXPR_FUNC_ARGS)) {
8876 if (builder->stack.len == exp_stacklen) {
8877 /* handle the comma back at the parent level */
8878 builder->token--;
8879 builder->level--;
8880 return JIM_OK;
8881 }
8882 Jim_SetResultFormatted(interp, "unexpected comma in expression: \"%#s\"", builder->exprObjPtr);
8883 return JIM_ERR;
8884 }
8885 else {
8886 /* If we see more terms than expected, it is an error */
8887 if (builder->stack.len > exp_stacklen) {
8888 Jim_SetResultFormatted(interp, "too many arguments to math function");
8889 return JIM_ERR;
8890 }
8891 }
8892 /* just go onto the next arg */
8893 }
8894 else if (t->type == JIM_EXPROP_COLON) {
8895 if (!(flags & EXPR_TERNARY)) {
8896 if (builder->level != 1) {
8897 /* handle the comma back at the parent level */
8898 builder->token--;
8899 builder->level--;
8900 return JIM_OK;
8901 }
8902 Jim_SetResultFormatted(interp, ": without ? in expression: \"%#s\"", builder->exprObjPtr);
8903 return JIM_ERR;
8904 }
8905 if (builder->stack.len == exp_stacklen) {
8906 /* handle the comma back at the parent level */
8907 builder->token--;
8908 builder->level--;
8909 return JIM_OK;
8910 }
8911 /* just go onto the next term */
8912 }
8913 else if (TOKEN_IS_EXPR_OP(t->type)) {
8914 const struct Jim_ExprOperator *op;
8915
8916 /* Convert -/+ to unary minus or unary plus if necessary */
8917 if (TOKEN_IS_EXPR_OP(prevtt) || TOKEN_IS_EXPR_START(prevtt)) {
8918 if (t->type == JIM_EXPROP_SUB) {
8919 t->type = JIM_EXPROP_UNARYMINUS;
8920 }
8921 else if (t->type == JIM_EXPROP_ADD) {
8922 t->type = JIM_EXPROP_UNARYPLUS;
8923 }
8924 }
8925
8926 op = JimExprOperatorInfoByOpcode(t->type);
8927
8928 if (op->precedence < precedence || (!(op->attr & OP_RIGHT_ASSOC) && op->precedence == precedence)) {
8929 /* next op is lower precedence, or equal and left associative, so done here */
8930 builder->token--;
8931 break;
8932 }
8933
8934 if (op->attr & OP_FUNC) {
8935 if (builder->token->type != JIM_TT_SUBEXPR_START) {
8936 Jim_SetResultString(interp, "missing arguments for math function", -1);
8937 return JIM_ERR;
8938 }
8939 builder->token++;
8940 if (op->arity == 0) {
8941 if (builder->token->type != JIM_TT_SUBEXPR_END) {
8942 Jim_SetResultString(interp, "too many arguments for math function", -1);
8943 return JIM_ERR;
8944 }
8945 builder->token++;
8946 goto noargs;
8947 }
8948 builder->parencount++;
8949
8950 /* This will push left and return right */
8951 rc = ExprTreeBuildTree(interp, builder, 0, EXPR_FUNC_ARGS | EXPR_UNTIL_CLOSE, op->arity);
8952 }
8953 else if (t->type == JIM_EXPROP_TERNARY) {
8954 /* Collect the two arguments to the ternary operator */
8955 rc = ExprTreeBuildTree(interp, builder, op->precedence, EXPR_TERNARY, 2);
8956 }
8957 else {
8958 /* Recursively handle everything on the right until we see a precendence <= op->precedence or == and right associative
8959 * and push that on the term stack
8960 */
8961 rc = ExprTreeBuildTree(interp, builder, op->precedence, 0, 1);
8962 }
8963
8964 if (rc != JIM_OK) {
8965 return rc;
8966 }
8967
8968 noargs:
8969 node = builder->next++;
8970 node->type = t->type;
8971
8972 if (op->arity >= 3) {
8973 node->ternary = Jim_StackPop(&builder->stack);
8974 if (node->ternary == NULL) {
8975 goto missingoperand;
8976 }
8977 }
8978 if (op->arity >= 2) {
8979 node->right = Jim_StackPop(&builder->stack);
8980 if (node->right == NULL) {
8981 goto missingoperand;
8982 }
8983 }
8984 if (op->arity >= 1) {
8985 node->left = Jim_StackPop(&builder->stack);
8986 if (node->left == NULL) {
8987 missingoperand:
8988 Jim_SetResultFormatted(interp, "missing operand to %s in expression: \"%#s\"", op->name, builder->exprObjPtr);
8989 builder->next--;
8990 return JIM_ERR;
8991
8992 }
8993 }
8994
8995 /* Now push the node */
8996 Jim_StackPush(&builder->stack, node);
8997 }
8998 else {
8999 Jim_Obj *objPtr = NULL;
9000
9001 /* This is a simple non-operator term, so create and push the appropriate object */
9002
9003 /* Two consecutive terms without an operator is invalid */
9004 if (!TOKEN_IS_EXPR_START(prevtt) && !TOKEN_IS_EXPR_OP(prevtt)) {
9005 Jim_SetResultFormatted(interp, "missing operator in expression: \"%#s\"", builder->exprObjPtr);
9006 return JIM_ERR;
9007 }
9008
9009 /* Immediately create a double or int object? */
9010 if (t->type == JIM_TT_EXPR_INT || t->type == JIM_TT_EXPR_DOUBLE) {
9011 char *endptr;
9012 if (t->type == JIM_TT_EXPR_INT) {
9013 objPtr = Jim_NewIntObj(interp, jim_strtoull(t->token, &endptr));
9014 }
9015 else {
9016 objPtr = Jim_NewDoubleObj(interp, strtod(t->token, &endptr));
9017 }
9018 if (endptr != t->token + t->len) {
9019 /* Conversion failed, so just store it as a string */
9020 Jim_FreeNewObj(interp, objPtr);
9021 objPtr = NULL;
9022 }
9023 }
9024
9025 if (!objPtr) {
9026 /* Everything else is stored a simple string term */
9027 objPtr = Jim_NewStringObj(interp, t->token, t->len);
9028 if (t->type == JIM_TT_CMD) {
9029 /* Only commands need source info */
9030 JimSetSourceInfo(interp, objPtr, builder->fileNameObj, t->line);
9031 }
9032 }
9033
9034 /* Now push a term node */
9035 node = builder->next++;
9036 node->objPtr = objPtr;
9037 Jim_IncrRefCount(node->objPtr);
9038 node->type = t->type;
9039 Jim_StackPush(&builder->stack, node);
9040 }
9041 }
9042
9043 if (builder->stack.len == exp_stacklen) {
9044 builder->level--;
9045 return JIM_OK;
9046 }
9047
9048 if ((flags & EXPR_FUNC_ARGS)) {
9049 Jim_SetResultFormatted(interp, "too %s arguments for math function", (builder->stack.len < exp_stacklen) ? "few" : "many");
9050 }
9051 else {
9052 if (builder->stack.len < exp_stacklen) {
9053 if (builder->level == 0) {
9054 Jim_SetResultFormatted(interp, "empty expression");
9055 }
9056 else {
9057 Jim_SetResultFormatted(interp, "syntax error in expression \"%#s\": premature end of expression", builder->exprObjPtr);
9058 }
9059 }
9060 else {
9061 Jim_SetResultFormatted(interp, "extra terms after expression");
9062 }
9063 }
9064
9065 return JIM_ERR;
9066 }
9067
9068 static struct ExprTree *ExprTreeCreateTree(Jim_Interp *interp, const ParseTokenList *tokenlist, Jim_Obj *exprObjPtr, Jim_Obj *fileNameObj)
9069 {
9070 struct ExprTree *expr;
9071 struct ExprBuilder builder;
9072 int rc;
9073 struct JimExprNode *top = NULL;
9074
9075 builder.parencount = 0;
9076 builder.level = 0;
9077 builder.token = builder.first_token = tokenlist->list;
9078 builder.exprObjPtr = exprObjPtr;
9079 builder.fileNameObj = fileNameObj;
9080 /* The bytecode will never produce more nodes than there are tokens - 1 (for EOL)*/
9081 builder.nodes = malloc(sizeof(struct JimExprNode) * (tokenlist->count - 1));
9082 memset(builder.nodes, 0, sizeof(struct JimExprNode) * (tokenlist->count - 1));
9083 builder.next = builder.nodes;
9084 Jim_InitStack(&builder.stack);
9085
9086 rc = ExprTreeBuildTree(interp, &builder, 0, 0, 1);
9087
9088 if (rc == JIM_OK) {
9089 top = Jim_StackPop(&builder.stack);
9090
9091 if (builder.parencount) {
9092 Jim_SetResultString(interp, "missing close parenthesis", -1);
9093 rc = JIM_ERR;
9094 }
9095 }
9096
9097 /* Free the stack used for the compilation. */
9098 Jim_FreeStack(&builder.stack);
9099
9100 if (rc != JIM_OK) {
9101 ExprTreeFreeNodes(interp, builder.nodes, builder.next - builder.nodes);
9102 return NULL;
9103 }
9104
9105 expr = Jim_Alloc(sizeof(*expr));
9106 expr->inUse = 1;
9107 expr->expr = top;
9108 expr->nodes = builder.nodes;
9109 expr->len = builder.next - builder.nodes;
9110
9111 assert(expr->len <= tokenlist->count - 1);
9112
9113 return expr;
9114 }
9115
9116 /* This method takes the string representation of an expression
9117 * and generates a program for the expr engine */
9118 static int SetExprFromAny(Jim_Interp *interp, struct Jim_Obj *objPtr)
9119 {
9120 int exprTextLen;
9121 const char *exprText;
9122 struct JimParserCtx parser;
9123 struct ExprTree *expr;
9124 ParseTokenList tokenlist;
9125 int line;
9126 Jim_Obj *fileNameObj;
9127 int rc = JIM_ERR;
9128
9129 /* Try to get information about filename / line number */
9130 if (objPtr->typePtr == &sourceObjType) {
9131 fileNameObj = objPtr->internalRep.sourceValue.fileNameObj;
9132 line = objPtr->internalRep.sourceValue.lineNumber;
9133 }
9134 else {
9135 fileNameObj = interp->emptyObj;
9136 line = 1;
9137 }
9138 Jim_IncrRefCount(fileNameObj);
9139
9140 exprText = Jim_GetString(objPtr, &exprTextLen);
9141
9142 /* Initially tokenise the expression into tokenlist */
9143 ScriptTokenListInit(&tokenlist);
9144
9145 JimParserInit(&parser, exprText, exprTextLen, line);
9146 while (!parser.eof) {
9147 if (JimParseExpression(&parser) != JIM_OK) {
9148 ScriptTokenListFree(&tokenlist);
9149 Jim_SetResultFormatted(interp, "syntax error in expression: \"%#s\"", objPtr);
9150 expr = NULL;
9151 goto err;
9152 }
9153
9154 ScriptAddToken(&tokenlist, parser.tstart, parser.tend - parser.tstart + 1, parser.tt,
9155 parser.tline);
9156 }
9157
9158 #ifdef DEBUG_SHOW_EXPR_TOKENS
9159 {
9160 int i;
9161 printf("==== Expr Tokens (%s) ====\n", Jim_String(fileNameObj));
9162 for (i = 0; i < tokenlist.count; i++) {
9163 printf("[%2d]@%d %s '%.*s'\n", i, tokenlist.list[i].line, jim_tt_name(tokenlist.list[i].type),
9164 tokenlist.list[i].len, tokenlist.list[i].token);
9165 }
9166 }
9167 #endif
9168
9169 if (JimParseCheckMissing(interp, parser.missing.ch) == JIM_ERR) {
9170 ScriptTokenListFree(&tokenlist);
9171 Jim_DecrRefCount(interp, fileNameObj);
9172 return JIM_ERR;
9173 }
9174
9175 /* Now create the expression bytecode from the tokenlist */
9176 expr = ExprTreeCreateTree(interp, &tokenlist, objPtr, fileNameObj);
9177
9178 /* No longer need the token list */
9179 ScriptTokenListFree(&tokenlist);
9180
9181 if (!expr) {
9182 goto err;
9183 }
9184
9185 #ifdef DEBUG_SHOW_EXPR
9186 printf("==== Expr ====\n");
9187 JimShowExprNode(expr->expr, 0);
9188 #endif
9189
9190 rc = JIM_OK;
9191
9192 err:
9193 /* Free the old internal rep and set the new one. */
9194 Jim_DecrRefCount(interp, fileNameObj);
9195 Jim_FreeIntRep(interp, objPtr);
9196 Jim_SetIntRepPtr(objPtr, expr);
9197 objPtr->typePtr = &exprObjType;
9198 return rc;
9199 }
9200
9201 static struct ExprTree *JimGetExpression(Jim_Interp *interp, Jim_Obj *objPtr)
9202 {
9203 if (objPtr->typePtr != &exprObjType) {
9204 if (SetExprFromAny(interp, objPtr) != JIM_OK) {
9205 return NULL;
9206 }
9207 }
9208 return (struct ExprTree *) Jim_GetIntRepPtr(objPtr);
9209 }
9210
9211 #ifdef JIM_OPTIMIZATION
9212 static Jim_Obj *JimExprIntValOrVar(Jim_Interp *interp, struct JimExprNode *node)
9213 {
9214 if (node->type == JIM_TT_EXPR_INT)
9215 return node->objPtr;
9216 else if (node->type == JIM_TT_VAR)
9217 return Jim_GetVariable(interp, node->objPtr, JIM_NONE);
9218 else if (node->type == JIM_TT_DICTSUGAR)
9219 return JimExpandDictSugar(interp, node->objPtr);
9220 else
9221 return NULL;
9222 }
9223 #endif
9224
9225 /* -----------------------------------------------------------------------------
9226 * Expressions evaluation.
9227 * Jim uses a recursive evaluation engine for expressions,
9228 * that takes advantage of the fact that expr's operators
9229 * can't be redefined.
9230 *
9231 * Jim_EvalExpression() uses the expression tree compiled by
9232 * SetExprFromAny() method of the "expression" object.
9233 *
9234 * On success a Tcl Object containing the result of the evaluation
9235 * is stored into expResultPtrPtr (having refcount of 1), and JIM_OK is
9236 * returned.
9237 * On error the function returns a retcode != to JIM_OK and set a suitable
9238 * error on the interp.
9239 * ---------------------------------------------------------------------------*/
9240
9241 static int JimExprEvalTermNode(Jim_Interp *interp, struct JimExprNode *node)
9242 {
9243 if (TOKEN_IS_EXPR_OP(node->type)) {
9244 const struct Jim_ExprOperator *op = JimExprOperatorInfoByOpcode(node->type);
9245 return op->funcop(interp, node);
9246 }
9247 else {
9248 Jim_Obj *objPtr;
9249
9250 /* A term */
9251 switch (node->type) {
9252 case JIM_TT_EXPR_INT:
9253 case JIM_TT_EXPR_DOUBLE:
9254 case JIM_TT_EXPR_BOOLEAN:
9255 case JIM_TT_STR:
9256 Jim_SetResult(interp, node->objPtr);
9257 return JIM_OK;
9258
9259 case JIM_TT_VAR:
9260 objPtr = Jim_GetVariable(interp, node->objPtr, JIM_ERRMSG);
9261 if (objPtr) {
9262 Jim_SetResult(interp, objPtr);
9263 return JIM_OK;
9264 }
9265 return JIM_ERR;
9266
9267 case JIM_TT_DICTSUGAR:
9268 objPtr = JimExpandDictSugar(interp, node->objPtr);
9269 if (objPtr) {
9270 Jim_SetResult(interp, objPtr);
9271 return JIM_OK;
9272 }
9273 return JIM_ERR;
9274
9275 case JIM_TT_ESC:
9276 if (Jim_SubstObj(interp, node->objPtr, &objPtr, JIM_NONE) == JIM_OK) {
9277 Jim_SetResult(interp, objPtr);
9278 return JIM_OK;
9279 }
9280 return JIM_ERR;
9281
9282 case JIM_TT_CMD:
9283 return Jim_EvalObj(interp, node->objPtr);
9284
9285 default:
9286 /* Should never get here */
9287 return JIM_ERR;
9288 }
9289 }
9290 }
9291
9292 static int JimExprGetTerm(Jim_Interp *interp, struct JimExprNode *node, Jim_Obj **objPtrPtr)
9293 {
9294 int rc = JimExprEvalTermNode(interp, node);
9295 if (rc == JIM_OK) {
9296 *objPtrPtr = Jim_GetResult(interp);
9297 Jim_IncrRefCount(*objPtrPtr);
9298 }
9299 return rc;
9300 }
9301
9302 static int JimExprGetTermBoolean(Jim_Interp *interp, struct JimExprNode *node)
9303 {
9304 if (JimExprEvalTermNode(interp, node) == JIM_OK) {
9305 return ExprBool(interp, Jim_GetResult(interp));
9306 }
9307 return -1;
9308 }
9309
9310 int Jim_EvalExpression(Jim_Interp *interp, Jim_Obj *exprObjPtr)
9311 {
9312 struct ExprTree *expr;
9313 int retcode = JIM_OK;
9314
9315 expr = JimGetExpression(interp, exprObjPtr);
9316 if (!expr) {
9317 return JIM_ERR; /* error in expression. */
9318 }
9319
9320 #ifdef JIM_OPTIMIZATION
9321 /* Check for one of the following common expressions used by while/for
9322 *
9323 * CONST
9324 * $a
9325 * !$a
9326 * $a < CONST, $a < $b
9327 * $a <= CONST, $a <= $b
9328 * $a > CONST, $a > $b
9329 * $a >= CONST, $a >= $b
9330 * $a != CONST, $a != $b
9331 * $a == CONST, $a == $b
9332 */
9333 {
9334 Jim_Obj *objPtr;
9335
9336 /* STEP 1 -- Check if there are the conditions to run the specialized
9337 * version of while */
9338
9339 switch (expr->len) {
9340 case 1:
9341 objPtr = JimExprIntValOrVar(interp, expr->expr);
9342 if (objPtr) {
9343 Jim_SetResult(interp, objPtr);
9344 return JIM_OK;
9345 }
9346 break;
9347
9348 case 2:
9349 if (expr->expr->type == JIM_EXPROP_NOT) {
9350 objPtr = JimExprIntValOrVar(interp, expr->expr->left);
9351
9352 if (objPtr && JimIsWide(objPtr)) {
9353 Jim_SetResult(interp, JimWideValue(objPtr) ? interp->falseObj : interp->trueObj);
9354 return JIM_OK;
9355 }
9356 }
9357 break;
9358
9359 case 3:
9360 objPtr = JimExprIntValOrVar(interp, expr->expr->left);
9361 if (objPtr && JimIsWide(objPtr)) {
9362 Jim_Obj *objPtr2 = JimExprIntValOrVar(interp, expr->expr->right);
9363 if (objPtr2 && JimIsWide(objPtr2)) {
9364 jim_wide wideValueA = JimWideValue(objPtr);
9365 jim_wide wideValueB = JimWideValue(objPtr2);
9366 int cmpRes;
9367 switch (expr->expr->type) {
9368 case JIM_EXPROP_LT:
9369 cmpRes = wideValueA < wideValueB;
9370 break;
9371 case JIM_EXPROP_LTE:
9372 cmpRes = wideValueA <= wideValueB;
9373 break;
9374 case JIM_EXPROP_GT:
9375 cmpRes = wideValueA > wideValueB;
9376 break;
9377 case JIM_EXPROP_GTE:
9378 cmpRes = wideValueA >= wideValueB;
9379 break;
9380 case JIM_EXPROP_NUMEQ:
9381 cmpRes = wideValueA == wideValueB;
9382 break;
9383 case JIM_EXPROP_NUMNE:
9384 cmpRes = wideValueA != wideValueB;
9385 break;
9386 default:
9387 goto noopt;
9388 }
9389 Jim_SetResult(interp, cmpRes ? interp->trueObj : interp->falseObj);
9390 return JIM_OK;
9391 }
9392 }
9393 break;
9394 }
9395 }
9396 noopt:
9397 #endif
9398
9399 /* In order to avoid the internal repr being freed due to
9400 * shimmering of the exprObjPtr's object, we make the internal rep
9401 * shared. */
9402 expr->inUse++;
9403
9404 /* Evaluate with the recursive expr engine */
9405 retcode = JimExprEvalTermNode(interp, expr->expr);
9406
9407 expr->inUse--;
9408
9409 return retcode;
9410 }
9411
9412 int Jim_GetBoolFromExpr(Jim_Interp *interp, Jim_Obj *exprObjPtr, int *boolPtr)
9413 {
9414 int retcode = Jim_EvalExpression(interp, exprObjPtr);
9415
9416 if (retcode == JIM_OK) {
9417 switch (ExprBool(interp, Jim_GetResult(interp))) {
9418 case 0:
9419 *boolPtr = 0;
9420 break;
9421
9422 case 1:
9423 *boolPtr = 1;
9424 break;
9425
9426 case -1:
9427 retcode = JIM_ERR;
9428 break;
9429 }
9430 }
9431 return retcode;
9432 }
9433
9434 /* -----------------------------------------------------------------------------
9435 * ScanFormat String Object
9436 * ---------------------------------------------------------------------------*/
9437
9438 /* This Jim_Obj will held a parsed representation of a format string passed to
9439 * the Jim_ScanString command. For error diagnostics, the scanformat string has
9440 * to be parsed in its entirely first and then, if correct, can be used for
9441 * scanning. To avoid endless re-parsing, the parsed representation will be
9442 * stored in an internal representation and re-used for performance reason. */
9443
9444 /* A ScanFmtPartDescr will held the information of /one/ part of the whole
9445 * scanformat string. This part will later be used to extract information
9446 * out from the string to be parsed by Jim_ScanString */
9447
9448 typedef struct ScanFmtPartDescr
9449 {
9450 const char *arg; /* Specification of a CHARSET conversion */
9451 const char *prefix; /* Prefix to be scanned literally before conversion */
9452 size_t width; /* Maximal width of input to be converted */
9453 int pos; /* -1 - no assign, 0 - natural pos, >0 - XPG3 pos */
9454 char type; /* Type of conversion (e.g. c, d, f) */
9455 char modifier; /* Modify type (e.g. l - long, h - short */
9456 } ScanFmtPartDescr;
9457
9458 /* The ScanFmtStringObj will hold the internal representation of a scanformat
9459 * string parsed and separated in part descriptions. Furthermore it contains
9460 * the original string representation of the scanformat string to allow for
9461 * fast update of the Jim_Obj's string representation part.
9462 *
9463 * As an add-on the internal object representation adds some scratch pad area
9464 * for usage by Jim_ScanString to avoid endless allocating and freeing of
9465 * memory for purpose of string scanning.
9466 *
9467 * The error member points to a static allocated string in case of a mal-
9468 * formed scanformat string or it contains '0' (NULL) in case of a valid
9469 * parse representation.
9470 *
9471 * The whole memory of the internal representation is allocated as a single
9472 * area of memory that will be internally separated. So freeing and duplicating
9473 * of such an object is cheap */
9474
9475 typedef struct ScanFmtStringObj
9476 {
9477 jim_wide size; /* Size of internal repr in bytes */
9478 char *stringRep; /* Original string representation */
9479 size_t count; /* Number of ScanFmtPartDescr contained */
9480 size_t convCount; /* Number of conversions that will assign */
9481 size_t maxPos; /* Max position index if XPG3 is used */
9482 const char *error; /* Ptr to error text (NULL if no error */
9483 char *scratch; /* Some scratch pad used by Jim_ScanString */
9484 ScanFmtPartDescr descr[1]; /* The vector of partial descriptions */
9485 } ScanFmtStringObj;
9486
9487
9488 static void FreeScanFmtInternalRep(Jim_Interp *interp, Jim_Obj *objPtr);
9489 static void DupScanFmtInternalRep(Jim_Interp *interp, Jim_Obj *srcPtr, Jim_Obj *dupPtr);
9490 static void UpdateStringOfScanFmt(Jim_Obj *objPtr);
9491
9492 static const Jim_ObjType scanFmtStringObjType = {
9493 "scanformatstring",
9494 FreeScanFmtInternalRep,
9495 DupScanFmtInternalRep,
9496 UpdateStringOfScanFmt,
9497 JIM_TYPE_NONE,
9498 };
9499
9500 void FreeScanFmtInternalRep(Jim_Interp *interp, Jim_Obj *objPtr)
9501 {
9502 JIM_NOTUSED(interp);
9503 Jim_Free((char *)objPtr->internalRep.ptr);
9504 objPtr->internalRep.ptr = 0;
9505 }
9506
9507 void DupScanFmtInternalRep(Jim_Interp *interp, Jim_Obj *srcPtr, Jim_Obj *dupPtr)
9508 {
9509 size_t size = (size_t) ((ScanFmtStringObj *) srcPtr->internalRep.ptr)->size;
9510 ScanFmtStringObj *newVec = (ScanFmtStringObj *) Jim_Alloc(size);
9511
9512 JIM_NOTUSED(interp);
9513 memcpy(newVec, srcPtr->internalRep.ptr, size);
9514 dupPtr->internalRep.ptr = newVec;
9515 dupPtr->typePtr = &scanFmtStringObjType;
9516 }
9517
9518 static void UpdateStringOfScanFmt(Jim_Obj *objPtr)
9519 {
9520 JimSetStringBytes(objPtr, ((ScanFmtStringObj *) objPtr->internalRep.ptr)->stringRep);
9521 }
9522
9523 /* SetScanFmtFromAny will parse a given string and create the internal
9524 * representation of the format specification. In case of an error
9525 * the error data member of the internal representation will be set
9526 * to an descriptive error text and the function will be left with
9527 * JIM_ERR to indicate unsucessful parsing (aka. malformed scanformat
9528 * specification */
9529
9530 static int SetScanFmtFromAny(Jim_Interp *interp, Jim_Obj *objPtr)
9531 {
9532 ScanFmtStringObj *fmtObj;
9533 char *buffer;
9534 int maxCount, i, approxSize, lastPos = -1;
9535 const char *fmt = Jim_String(objPtr);
9536 int maxFmtLen = Jim_Length(objPtr);
9537 const char *fmtEnd = fmt + maxFmtLen;
9538 int curr;
9539
9540 Jim_FreeIntRep(interp, objPtr);
9541 /* Count how many conversions could take place maximally */
9542 for (i = 0, maxCount = 0; i < maxFmtLen; ++i)
9543 if (fmt[i] == '%')
9544 ++maxCount;
9545 /* Calculate an approximation of the memory necessary */
9546 approxSize = sizeof(ScanFmtStringObj) /* Size of the container */
9547 +(maxCount + 1) * sizeof(ScanFmtPartDescr) /* Size of all partials */
9548 +maxFmtLen * sizeof(char) + 3 + 1 /* Scratch + "%n" + '\0' */
9549 + maxFmtLen * sizeof(char) + 1 /* Original stringrep */
9550 + maxFmtLen * sizeof(char) /* Arg for CHARSETs */
9551 +(maxCount + 1) * sizeof(char) /* '\0' for every partial */
9552 +1; /* safety byte */
9553 fmtObj = (ScanFmtStringObj *) Jim_Alloc(approxSize);
9554 memset(fmtObj, 0, approxSize);
9555 fmtObj->size = approxSize;
9556 fmtObj->maxPos = 0;
9557 fmtObj->scratch = (char *)&fmtObj->descr[maxCount + 1];
9558 fmtObj->stringRep = fmtObj->scratch + maxFmtLen + 3 + 1;
9559 memcpy(fmtObj->stringRep, fmt, maxFmtLen);
9560 buffer = fmtObj->stringRep + maxFmtLen + 1;
9561 objPtr->internalRep.ptr = fmtObj;
9562 objPtr->typePtr = &scanFmtStringObjType;
9563 for (i = 0, curr = 0; fmt < fmtEnd; ++fmt) {
9564 int width = 0, skip;
9565 ScanFmtPartDescr *descr = &fmtObj->descr[curr];
9566
9567 fmtObj->count++;
9568 descr->width = 0; /* Assume width unspecified */
9569 /* Overread and store any "literal" prefix */
9570 if (*fmt != '%' || fmt[1] == '%') {
9571 descr->type = 0;
9572 descr->prefix = &buffer[i];
9573 for (; fmt < fmtEnd; ++fmt) {
9574 if (*fmt == '%') {
9575 if (fmt[1] != '%')
9576 break;
9577 ++fmt;
9578 }
9579 buffer[i++] = *fmt;
9580 }
9581 buffer[i++] = 0;
9582 }
9583 /* Skip the conversion introducing '%' sign */
9584 ++fmt;
9585 /* End reached due to non-conversion literal only? */
9586 if (fmt >= fmtEnd)
9587 goto done;
9588 descr->pos = 0; /* Assume "natural" positioning */
9589 if (*fmt == '*') {
9590 descr->pos = -1; /* Okay, conversion will not be assigned */
9591 ++fmt;
9592 }
9593 else
9594 fmtObj->convCount++; /* Otherwise count as assign-conversion */
9595 /* Check if next token is a number (could be width or pos */
9596 if (sscanf(fmt, "%d%n", &width, &skip) == 1) {
9597 fmt += skip;
9598 /* Was the number a XPG3 position specifier? */
9599 if (descr->pos != -1 && *fmt == '$') {
9600 int prev;
9601
9602 ++fmt;
9603 descr->pos = width;
9604 width = 0;
9605 /* Look if "natural" postioning and XPG3 one was mixed */
9606 if ((lastPos == 0 && descr->pos > 0)
9607 || (lastPos > 0 && descr->pos == 0)) {
9608 fmtObj->error = "cannot mix \"%\" and \"%n$\" conversion specifiers";
9609 return JIM_ERR;
9610 }
9611 /* Look if this position was already used */
9612 for (prev = 0; prev < curr; ++prev) {
9613 if (fmtObj->descr[prev].pos == -1)
9614 continue;
9615 if (fmtObj->descr[prev].pos == descr->pos) {
9616 fmtObj->error =
9617 "variable is assigned by multiple \"%n$\" conversion specifiers";
9618 return JIM_ERR;
9619 }
9620 }
9621 if (descr->pos < 0) {
9622 fmtObj->error =
9623 "\"%n$\" conversion specifier is negative";
9624 return JIM_ERR;
9625 }
9626 /* Try to find a width after the XPG3 specifier */
9627 if (sscanf(fmt, "%d%n", &width, &skip) == 1) {
9628 descr->width = width;
9629 fmt += skip;
9630 }
9631 if (descr->pos > 0 && (size_t) descr->pos > fmtObj->maxPos)
9632 fmtObj->maxPos = descr->pos;
9633 }
9634 else {
9635 /* Number was not a XPG3, so it has to be a width */
9636 descr->width = width;
9637 }
9638 }
9639 /* If positioning mode was undetermined yet, fix this */
9640 if (lastPos == -1)
9641 lastPos = descr->pos;
9642 /* Handle CHARSET conversion type ... */
9643 if (*fmt == '[') {
9644 int swapped = 1, beg = i, end, j;
9645
9646 descr->type = '[';
9647 descr->arg = &buffer[i];
9648 ++fmt;
9649 if (*fmt == '^')
9650 buffer[i++] = *fmt++;
9651 if (*fmt == ']')
9652 buffer[i++] = *fmt++;
9653 while (*fmt && *fmt != ']')
9654 buffer[i++] = *fmt++;
9655 if (*fmt != ']') {
9656 fmtObj->error = "unmatched [ in format string";
9657 return JIM_ERR;
9658 }
9659 end = i;
9660 buffer[i++] = 0;
9661 /* In case a range fence was given "backwards", swap it */
9662 while (swapped) {
9663 swapped = 0;
9664 for (j = beg + 1; j < end - 1; ++j) {
9665 if (buffer[j] == '-' && buffer[j - 1] > buffer[j + 1]) {
9666 char tmp = buffer[j - 1];
9667
9668 buffer[j - 1] = buffer[j + 1];
9669 buffer[j + 1] = tmp;
9670 swapped = 1;
9671 }
9672 }
9673 }
9674 }
9675 else {
9676 /* Remember any valid modifier if given */
9677 if (fmt < fmtEnd && strchr("hlL", *fmt))
9678 descr->modifier = tolower((int)*fmt++);
9679
9680 if (fmt >= fmtEnd) {
9681 fmtObj->error = "missing scan conversion character";
9682 return JIM_ERR;
9683 }
9684
9685 descr->type = *fmt;
9686 if (strchr("efgcsndoxui", *fmt) == 0) {
9687 fmtObj->error = "bad scan conversion character";
9688 return JIM_ERR;
9689 }
9690 else if (*fmt == 'c' && descr->width != 0) {
9691 fmtObj->error = "field width may not be specified in %c " "conversion";
9692 return JIM_ERR;
9693 }
9694 else if (*fmt == 'u' && descr->modifier == 'l') {
9695 fmtObj->error = "unsigned wide not supported";
9696 return JIM_ERR;
9697 }
9698 }
9699 curr++;
9700 }
9701 done:
9702 return JIM_OK;
9703 }
9704
9705 /* Some accessor macros to allow lowlevel access to fields of internal repr */
9706
9707 #define FormatGetCnvCount(_fo_) \
9708 ((ScanFmtStringObj*)((_fo_)->internalRep.ptr))->convCount
9709 #define FormatGetMaxPos(_fo_) \
9710 ((ScanFmtStringObj*)((_fo_)->internalRep.ptr))->maxPos
9711 #define FormatGetError(_fo_) \
9712 ((ScanFmtStringObj*)((_fo_)->internalRep.ptr))->error
9713
9714 /* JimScanAString is used to scan an unspecified string that ends with
9715 * next WS, or a string that is specified via a charset.
9716 *
9717 */
9718 static Jim_Obj *JimScanAString(Jim_Interp *interp, const char *sdescr, const char *str)
9719 {
9720 char *buffer = Jim_StrDup(str);
9721 char *p = buffer;
9722
9723 while (*str) {
9724 int c;
9725 int n;
9726
9727 if (!sdescr && isspace(UCHAR(*str)))
9728 break; /* EOS via WS if unspecified */
9729
9730 n = utf8_tounicode(str, &c);
9731 if (sdescr && !JimCharsetMatch(sdescr, c, JIM_CHARSET_SCAN))
9732 break;
9733 while (n--)
9734 *p++ = *str++;
9735 }
9736 *p = 0;
9737 return Jim_NewStringObjNoAlloc(interp, buffer, p - buffer);
9738 }
9739
9740 /* ScanOneEntry will scan one entry out of the string passed as argument.
9741 * It use the sscanf() function for this task. After extracting and
9742 * converting of the value, the count of scanned characters will be
9743 * returned of -1 in case of no conversion tool place and string was
9744 * already scanned thru */
9745
9746 static int ScanOneEntry(Jim_Interp *interp, const char *str, int pos, int strLen,
9747 ScanFmtStringObj * fmtObj, long idx, Jim_Obj **valObjPtr)
9748 {
9749 const char *tok;
9750 const ScanFmtPartDescr *descr = &fmtObj->descr[idx];
9751 size_t scanned = 0;
9752 size_t anchor = pos;
9753 int i;
9754 Jim_Obj *tmpObj = NULL;
9755
9756 /* First pessimistically assume, we will not scan anything :-) */
9757 *valObjPtr = 0;
9758 if (descr->prefix) {
9759 /* There was a prefix given before the conversion, skip it and adjust
9760 * the string-to-be-parsed accordingly */
9761 for (i = 0; pos < strLen && descr->prefix[i]; ++i) {
9762 /* If prefix require, skip WS */
9763 if (isspace(UCHAR(descr->prefix[i])))
9764 while (pos < strLen && isspace(UCHAR(str[pos])))
9765 ++pos;
9766 else if (descr->prefix[i] != str[pos])
9767 break; /* Prefix do not match here, leave the loop */
9768 else
9769 ++pos; /* Prefix matched so far, next round */
9770 }
9771 if (pos >= strLen) {
9772 return -1; /* All of str consumed: EOF condition */
9773 }
9774 else if (descr->prefix[i] != 0)
9775 return 0; /* Not whole prefix consumed, no conversion possible */
9776 }
9777 /* For all but following conversion, skip leading WS */
9778 if (descr->type != 'c' && descr->type != '[' && descr->type != 'n')
9779 while (isspace(UCHAR(str[pos])))
9780 ++pos;
9781 /* Determine how much skipped/scanned so far */
9782 scanned = pos - anchor;
9783
9784 /* %c is a special, simple case. no width */
9785 if (descr->type == 'n') {
9786 /* Return pseudo conversion means: how much scanned so far? */
9787 *valObjPtr = Jim_NewIntObj(interp, anchor + scanned);
9788 }
9789 else if (pos >= strLen) {
9790 /* Cannot scan anything, as str is totally consumed */
9791 return -1;
9792 }
9793 else if (descr->type == 'c') {
9794 int c;
9795 scanned += utf8_tounicode(&str[pos], &c);
9796 *valObjPtr = Jim_NewIntObj(interp, c);
9797 return scanned;
9798 }
9799 else {
9800 /* Processing of conversions follows ... */
9801 if (descr->width > 0) {
9802 /* Do not try to scan as fas as possible but only the given width.
9803 * To ensure this, we copy the part that should be scanned. */
9804 size_t sLen = utf8_strlen(&str[pos], strLen - pos);
9805 size_t tLen = descr->width > sLen ? sLen : descr->width;
9806
9807 tmpObj = Jim_NewStringObjUtf8(interp, str + pos, tLen);
9808 tok = tmpObj->bytes;
9809 }
9810 else {
9811 /* As no width was given, simply refer to the original string */
9812 tok = &str[pos];
9813 }
9814 switch (descr->type) {
9815 case 'd':
9816 case 'o':
9817 case 'x':
9818 case 'u':
9819 case 'i':{
9820 char *endp; /* Position where the number finished */
9821 jim_wide w;
9822
9823 int base = descr->type == 'o' ? 8
9824 : descr->type == 'x' ? 16 : descr->type == 'i' ? 0 : 10;
9825
9826 /* Try to scan a number with the given base */
9827 if (base == 0) {
9828 w = jim_strtoull(tok, &endp);
9829 }
9830 else {
9831 w = strtoull(tok, &endp, base);
9832 }
9833
9834 if (endp != tok) {
9835 /* There was some number sucessfully scanned! */
9836 *valObjPtr = Jim_NewIntObj(interp, w);
9837
9838 /* Adjust the number-of-chars scanned so far */
9839 scanned += endp - tok;
9840 }
9841 else {
9842 /* Nothing was scanned. We have to determine if this
9843 * happened due to e.g. prefix mismatch or input str
9844 * exhausted */
9845 scanned = *tok ? 0 : -1;
9846 }
9847 break;
9848 }
9849 case 's':
9850 case '[':{
9851 *valObjPtr = JimScanAString(interp, descr->arg, tok);
9852 scanned += Jim_Length(*valObjPtr);
9853 break;
9854 }
9855 case 'e':
9856 case 'f':
9857 case 'g':{
9858 char *endp;
9859 double value = strtod(tok, &endp);
9860
9861 if (endp != tok) {
9862 /* There was some number sucessfully scanned! */
9863 *valObjPtr = Jim_NewDoubleObj(interp, value);
9864 /* Adjust the number-of-chars scanned so far */
9865 scanned += endp - tok;
9866 }
9867 else {
9868 /* Nothing was scanned. We have to determine if this
9869 * happened due to e.g. prefix mismatch or input str
9870 * exhausted */
9871 scanned = *tok ? 0 : -1;
9872 }
9873 break;
9874 }
9875 }
9876 /* If a substring was allocated (due to pre-defined width) do not
9877 * forget to free it */
9878 if (tmpObj) {
9879 Jim_FreeNewObj(interp, tmpObj);
9880 }
9881 }
9882 return scanned;
9883 }
9884
9885 /* Jim_ScanString is the workhorse of string scanning. It will scan a given
9886 * string and returns all converted (and not ignored) values in a list back
9887 * to the caller. If an error occured, a NULL pointer will be returned */
9888
9889 Jim_Obj *Jim_ScanString(Jim_Interp *interp, Jim_Obj *strObjPtr, Jim_Obj *fmtObjPtr, int flags)
9890 {
9891 size_t i, pos;
9892 int scanned = 1;
9893 const char *str = Jim_String(strObjPtr);
9894 int strLen = Jim_Utf8Length(interp, strObjPtr);
9895 Jim_Obj *resultList = 0;
9896 Jim_Obj **resultVec = 0;
9897 int resultc;
9898 Jim_Obj *emptyStr = 0;
9899 ScanFmtStringObj *fmtObj;
9900
9901 /* This should never happen. The format object should already be of the correct type */
9902 JimPanic((fmtObjPtr->typePtr != &scanFmtStringObjType, "Jim_ScanString() for non-scan format"));
9903
9904 fmtObj = (ScanFmtStringObj *) fmtObjPtr->internalRep.ptr;
9905 /* Check if format specification was valid */
9906 if (fmtObj->error != 0) {
9907 if (flags & JIM_ERRMSG)
9908 Jim_SetResultString(interp, fmtObj->error, -1);
9909 return 0;
9910 }
9911 /* Allocate a new "shared" empty string for all unassigned conversions */
9912 emptyStr = Jim_NewEmptyStringObj(interp);
9913 Jim_IncrRefCount(emptyStr);
9914 /* Create a list and fill it with empty strings up to max specified XPG3 */
9915 resultList = Jim_NewListObj(interp, NULL, 0);
9916 if (fmtObj->maxPos > 0) {
9917 for (i = 0; i < fmtObj->maxPos; ++i)
9918 Jim_ListAppendElement(interp, resultList, emptyStr);
9919 JimListGetElements(interp, resultList, &resultc, &resultVec);
9920 }
9921 /* Now handle every partial format description */
9922 for (i = 0, pos = 0; i < fmtObj->count; ++i) {
9923 ScanFmtPartDescr *descr = &(fmtObj->descr[i]);
9924 Jim_Obj *value = 0;
9925
9926 /* Only last type may be "literal" w/o conversion - skip it! */
9927 if (descr->type == 0)
9928 continue;
9929 /* As long as any conversion could be done, we will proceed */
9930 if (scanned > 0)
9931 scanned = ScanOneEntry(interp, str, pos, strLen, fmtObj, i, &value);
9932 /* In case our first try results in EOF, we will leave */
9933 if (scanned == -1 && i == 0)
9934 goto eof;
9935 /* Advance next pos-to-be-scanned for the amount scanned already */
9936 pos += scanned;
9937
9938 /* value == 0 means no conversion took place so take empty string */
9939 if (value == 0)
9940 value = Jim_NewEmptyStringObj(interp);
9941 /* If value is a non-assignable one, skip it */
9942 if (descr->pos == -1) {
9943 Jim_FreeNewObj(interp, value);
9944 }
9945 else if (descr->pos == 0)
9946 /* Otherwise append it to the result list if no XPG3 was given */
9947 Jim_ListAppendElement(interp, resultList, value);
9948 else if (resultVec[descr->pos - 1] == emptyStr) {
9949 /* But due to given XPG3, put the value into the corr. slot */
9950 Jim_DecrRefCount(interp, resultVec[descr->pos - 1]);
9951 Jim_IncrRefCount(value);
9952 resultVec[descr->pos - 1] = value;
9953 }
9954 else {
9955 /* Otherwise, the slot was already used - free obj and ERROR */
9956 Jim_FreeNewObj(interp, value);
9957 goto err;
9958 }
9959 }
9960 Jim_DecrRefCount(interp, emptyStr);
9961 return resultList;
9962 eof:
9963 Jim_DecrRefCount(interp, emptyStr);
9964 Jim_FreeNewObj(interp, resultList);
9965 return (Jim_Obj *)EOF;
9966 err:
9967 Jim_DecrRefCount(interp, emptyStr);
9968 Jim_FreeNewObj(interp, resultList);
9969 return 0;
9970 }
9971
9972 /* -----------------------------------------------------------------------------
9973 * Pseudo Random Number Generation
9974 * ---------------------------------------------------------------------------*/
9975 /* Initialize the sbox with the numbers from 0 to 255 */
9976 static void JimPrngInit(Jim_Interp *interp)
9977 {
9978 #define PRNG_SEED_SIZE 256
9979 int i;
9980 unsigned int *seed;
9981 time_t t = time(NULL);
9982
9983 interp->prngState = Jim_Alloc(sizeof(Jim_PrngState));
9984
9985 seed = Jim_Alloc(PRNG_SEED_SIZE * sizeof(*seed));
9986 for (i = 0; i < PRNG_SEED_SIZE; i++) {
9987 seed[i] = (rand() ^ t ^ clock());
9988 }
9989 JimPrngSeed(interp, (unsigned char *)seed, PRNG_SEED_SIZE * sizeof(*seed));
9990 Jim_Free(seed);
9991 }
9992
9993 /* Generates N bytes of random data */
9994 static void JimRandomBytes(Jim_Interp *interp, void *dest, unsigned int len)
9995 {
9996 Jim_PrngState *prng;
9997 unsigned char *destByte = (unsigned char *)dest;
9998 unsigned int si, sj, x;
9999
10000 /* initialization, only needed the first time */
10001 if (interp->prngState == NULL)
10002 JimPrngInit(interp);
10003 prng = interp->prngState;
10004 /* generates 'len' bytes of pseudo-random numbers */
10005 for (x = 0; x < len; x++) {
10006 prng->i = (prng->i + 1) & 0xff;
10007 si = prng->sbox[prng->i];
10008 prng->j = (prng->j + si) & 0xff;
10009 sj = prng->sbox[prng->j];
10010 prng->sbox[prng->i] = sj;
10011 prng->sbox[prng->j] = si;
10012 *destByte++ = prng->sbox[(si + sj) & 0xff];
10013 }
10014 }
10015
10016 /* Re-seed the generator with user-provided bytes */
10017 static void JimPrngSeed(Jim_Interp *interp, unsigned char *seed, int seedLen)
10018 {
10019 int i;
10020 Jim_PrngState *prng;
10021
10022 /* initialization, only needed the first time */
10023 if (interp->prngState == NULL)
10024 JimPrngInit(interp);
10025 prng = interp->prngState;
10026
10027 /* Set the sbox[i] with i */
10028 for (i = 0; i < 256; i++)
10029 prng->sbox[i] = i;
10030 /* Now use the seed to perform a random permutation of the sbox */
10031 for (i = 0; i < seedLen; i++) {
10032 unsigned char t;
10033
10034 t = prng->sbox[i & 0xFF];
10035 prng->sbox[i & 0xFF] = prng->sbox[seed[i]];
10036 prng->sbox[seed[i]] = t;
10037 }
10038 prng->i = prng->j = 0;
10039
10040 /* discard at least the first 256 bytes of stream.
10041 * borrow the seed buffer for this
10042 */
10043 for (i = 0; i < 256; i += seedLen) {
10044 JimRandomBytes(interp, seed, seedLen);
10045 }
10046 }
10047
10048 /* [incr] */
10049 static int Jim_IncrCoreCommand(Jim_Interp *interp, int argc, Jim_Obj *const *argv)
10050 {
10051 jim_wide wideValue, increment = 1;
10052 Jim_Obj *intObjPtr;
10053
10054 if (argc != 2 && argc != 3) {
10055 Jim_WrongNumArgs(interp, 1, argv, "varName ?increment?");
10056 return JIM_ERR;
10057 }
10058 if (argc == 3) {
10059 if (Jim_GetWide(interp, argv[2], &increment) != JIM_OK)
10060 return JIM_ERR;
10061 }
10062 intObjPtr = Jim_GetVariable(interp, argv[1], JIM_UNSHARED);
10063 if (!intObjPtr) {
10064 /* Set missing variable to 0 */
10065 wideValue = 0;
10066 }
10067 else if (Jim_GetWide(interp, intObjPtr, &wideValue) != JIM_OK) {
10068 return JIM_ERR;
10069 }
10070 if (!intObjPtr || Jim_IsShared(intObjPtr)) {
10071 intObjPtr = Jim_NewIntObj(interp, wideValue + increment);
10072 if (Jim_SetVariable(interp, argv[1], intObjPtr) != JIM_OK) {
10073 Jim_FreeNewObj(interp, intObjPtr);
10074 return JIM_ERR;
10075 }
10076 }
10077 else {
10078 /* Can do it the quick way */
10079 Jim_InvalidateStringRep(intObjPtr);
10080 JimWideValue(intObjPtr) = wideValue + increment;
10081
10082 /* The following step is required in order to invalidate the
10083 * string repr of "FOO" if the var name is on the form of "FOO(IDX)" */
10084 if (argv[1]->typePtr != &variableObjType) {
10085 /* Note that this can't fail since GetVariable already succeeded */
10086 Jim_SetVariable(interp, argv[1], intObjPtr);
10087 }
10088 }
10089 Jim_SetResult(interp, intObjPtr);
10090 return JIM_OK;
10091 }
10092
10093
10094 /* -----------------------------------------------------------------------------
10095 * Eval
10096 * ---------------------------------------------------------------------------*/
10097 #define JIM_EVAL_SARGV_LEN 8 /* static arguments vector length */
10098 #define JIM_EVAL_SINTV_LEN 8 /* static interpolation vector length */
10099
10100 /* Handle calls to the [unknown] command */
10101 static int JimUnknown(Jim_Interp *interp, int argc, Jim_Obj *const *argv)
10102 {
10103 int retcode;
10104
10105 /* If JimUnknown() is recursively called too many times...
10106 * done here
10107 */
10108 if (interp->unknown_called > 50) {
10109 return JIM_ERR;
10110 }
10111
10112 /* The object interp->unknown just contains
10113 * the "unknown" string, it is used in order to
10114 * avoid to lookup the unknown command every time
10115 * but instead to cache the result. */
10116
10117 /* If the [unknown] command does not exist ... */
10118 if (Jim_GetCommand(interp, interp->unknown, JIM_NONE) == NULL)
10119 return JIM_ERR;
10120
10121 interp->unknown_called++;
10122 /* XXX: Are we losing fileNameObj and linenr? */
10123 retcode = Jim_EvalObjPrefix(interp, interp->unknown, argc, argv);
10124 interp->unknown_called--;
10125
10126 return retcode;
10127 }
10128
10129 static int JimInvokeCommand(Jim_Interp *interp, int objc, Jim_Obj *const *objv)
10130 {
10131 int retcode;
10132 Jim_Cmd *cmdPtr;
10133 void *prevPrivData;
10134
10135 #if 0
10136 printf("invoke");
10137 int j;
10138 for (j = 0; j < objc; j++) {
10139 printf(" '%s'", Jim_String(objv[j]));
10140 }
10141 printf("\n");
10142 #endif
10143
10144 if (interp->framePtr->tailcallCmd) {
10145 /* Special tailcall command was pre-resolved */
10146 cmdPtr = interp->framePtr->tailcallCmd;
10147 interp->framePtr->tailcallCmd = NULL;
10148 }
10149 else {
10150 cmdPtr = Jim_GetCommand(interp, objv[0], JIM_ERRMSG);
10151 if (cmdPtr == NULL) {
10152 return JimUnknown(interp, objc, objv);
10153 }
10154 JimIncrCmdRefCount(cmdPtr);
10155 }
10156
10157 if (interp->evalDepth == interp->maxEvalDepth) {
10158 Jim_SetResultString(interp, "Infinite eval recursion", -1);
10159 retcode = JIM_ERR;
10160 goto out;
10161 }
10162 interp->evalDepth++;
10163 prevPrivData = interp->cmdPrivData;
10164
10165 /* Call it -- Make sure result is an empty object. */
10166 Jim_SetEmptyResult(interp);
10167 if (cmdPtr->isproc) {
10168 retcode = JimCallProcedure(interp, cmdPtr, objc, objv);
10169 }
10170 else {
10171 interp->cmdPrivData = cmdPtr->u.native.privData;
10172 retcode = cmdPtr->u.native.cmdProc(interp, objc, objv);
10173 }
10174 interp->cmdPrivData = prevPrivData;
10175 interp->evalDepth--;
10176
10177 out:
10178 JimDecrCmdRefCount(interp, cmdPtr);
10179
10180 return retcode;
10181 }
10182
10183 /* Eval the object vector 'objv' composed of 'objc' elements.
10184 * Every element is used as single argument.
10185 * Jim_EvalObj() will call this function every time its object
10186 * argument is of "list" type, with no string representation.
10187 *
10188 * This is possible because the string representation of a
10189 * list object generated by the UpdateStringOfList is made
10190 * in a way that ensures that every list element is a different
10191 * command argument. */
10192 int Jim_EvalObjVector(Jim_Interp *interp, int objc, Jim_Obj *const *objv)
10193 {
10194 int i, retcode;
10195
10196 /* Incr refcount of arguments. */
10197 for (i = 0; i < objc; i++)
10198 Jim_IncrRefCount(objv[i]);
10199
10200 retcode = JimInvokeCommand(interp, objc, objv);
10201
10202 /* Decr refcount of arguments and return the retcode */
10203 for (i = 0; i < objc; i++)
10204 Jim_DecrRefCount(interp, objv[i]);
10205
10206 return retcode;
10207 }
10208
10209 /**
10210 * Invokes 'prefix' as a command with the objv array as arguments.
10211 */
10212 int Jim_EvalObjPrefix(Jim_Interp *interp, Jim_Obj *prefix, int objc, Jim_Obj *const *objv)
10213 {
10214 int ret;
10215 Jim_Obj **nargv = Jim_Alloc((objc + 1) * sizeof(*nargv));
10216
10217 nargv[0] = prefix;
10218 memcpy(&nargv[1], &objv[0], sizeof(nargv[0]) * objc);
10219 ret = Jim_EvalObjVector(interp, objc + 1, nargv);
10220 Jim_Free(nargv);
10221 return ret;
10222 }
10223
10224 static void JimAddErrorToStack(Jim_Interp *interp, ScriptObj *script)
10225 {
10226 if (!interp->errorFlag) {
10227 /* This is the first error, so save the file/line information and reset the stack */
10228 interp->errorFlag = 1;
10229 Jim_IncrRefCount(script->fileNameObj);
10230 Jim_DecrRefCount(interp, interp->errorFileNameObj);
10231 interp->errorFileNameObj = script->fileNameObj;
10232 interp->errorLine = script->linenr;
10233
10234 JimResetStackTrace(interp);
10235 /* Always add a level where the error first occurs */
10236 interp->addStackTrace++;
10237 }
10238
10239 /* Now if this is an "interesting" level, add it to the stack trace */
10240 if (interp->addStackTrace > 0) {
10241 /* Add the stack info for the current level */
10242
10243 JimAppendStackTrace(interp, Jim_String(interp->errorProc), script->fileNameObj, script->linenr);
10244
10245 /* Note: if we didn't have a filename for this level,
10246 * don't clear the addStackTrace flag
10247 * so we can pick it up at the next level
10248 */
10249 if (Jim_Length(script->fileNameObj)) {
10250 interp->addStackTrace = 0;
10251 }
10252
10253 Jim_DecrRefCount(interp, interp->errorProc);
10254 interp->errorProc = interp->emptyObj;
10255 Jim_IncrRefCount(interp->errorProc);
10256 }
10257 }
10258
10259 static int JimSubstOneToken(Jim_Interp *interp, const ScriptToken *token, Jim_Obj **objPtrPtr)
10260 {
10261 Jim_Obj *objPtr;
10262
10263 switch (token->type) {
10264 case JIM_TT_STR:
10265 case JIM_TT_ESC:
10266 objPtr = token->objPtr;
10267 break;
10268 case JIM_TT_VAR:
10269 objPtr = Jim_GetVariable(interp, token->objPtr, JIM_ERRMSG);
10270 break;
10271 case JIM_TT_DICTSUGAR:
10272 objPtr = JimExpandDictSugar(interp, token->objPtr);
10273 break;
10274 case JIM_TT_EXPRSUGAR:
10275 objPtr = JimExpandExprSugar(interp, token->objPtr);
10276 break;
10277 case JIM_TT_CMD:
10278 switch (Jim_EvalObj(interp, token->objPtr)) {
10279 case JIM_OK:
10280 case JIM_RETURN:
10281 objPtr = interp->result;
10282 break;
10283 case JIM_BREAK:
10284 /* Stop substituting */
10285 return JIM_BREAK;
10286 case JIM_CONTINUE:
10287 /* just skip this one */
10288 return JIM_CONTINUE;
10289 default:
10290 return JIM_ERR;
10291 }
10292 break;
10293 default:
10294 JimPanic((1,
10295 "default token type (%d) reached " "in Jim_SubstObj().", token->type));
10296 objPtr = NULL;
10297 break;
10298 }
10299 if (objPtr) {
10300 *objPtrPtr = objPtr;
10301 return JIM_OK;
10302 }
10303 return JIM_ERR;
10304 }
10305
10306 /* Interpolate the given tokens into a unique Jim_Obj returned by reference
10307 * via *objPtrPtr. This function is only called by Jim_EvalObj() and Jim_SubstObj()
10308 * The returned object has refcount = 0.
10309 */
10310 static Jim_Obj *JimInterpolateTokens(Jim_Interp *interp, const ScriptToken * token, int tokens, int flags)
10311 {
10312 int totlen = 0, i;
10313 Jim_Obj **intv;
10314 Jim_Obj *sintv[JIM_EVAL_SINTV_LEN];
10315 Jim_Obj *objPtr;
10316 char *s;
10317
10318 if (tokens <= JIM_EVAL_SINTV_LEN)
10319 intv = sintv;
10320 else
10321 intv = Jim_Alloc(sizeof(Jim_Obj *) * tokens);
10322
10323 /* Compute every token forming the argument
10324 * in the intv objects vector. */
10325 for (i = 0; i < tokens; i++) {
10326 switch (JimSubstOneToken(interp, &token[i], &intv[i])) {
10327 case JIM_OK:
10328 case JIM_RETURN:
10329 break;
10330 case JIM_BREAK:
10331 if (flags & JIM_SUBST_FLAG) {
10332 /* Stop here */
10333 tokens = i;
10334 continue;
10335 }
10336 /* XXX: Should probably set an error about break outside loop */
10337 /* fall through to error */
10338 case JIM_CONTINUE:
10339 if (flags & JIM_SUBST_FLAG) {
10340 intv[i] = NULL;
10341 continue;
10342 }
10343 /* XXX: Ditto continue outside loop */
10344 /* fall through to error */
10345 default:
10346 while (i--) {
10347 Jim_DecrRefCount(interp, intv[i]);
10348 }
10349 if (intv != sintv) {
10350 Jim_Free(intv);
10351 }
10352 return NULL;
10353 }
10354 Jim_IncrRefCount(intv[i]);
10355 Jim_String(intv[i]);
10356 totlen += intv[i]->length;
10357 }
10358
10359 /* Fast path return for a single token */
10360 if (tokens == 1 && intv[0] && intv == sintv) {
10361 /* Reverse the Jim_IncrRefCount() above, but don't free the object */
10362 intv[0]->refCount--;
10363 return intv[0];
10364 }
10365
10366 /* Concatenate every token in an unique
10367 * object. */
10368 objPtr = Jim_NewStringObjNoAlloc(interp, NULL, 0);
10369
10370 if (tokens == 4 && token[0].type == JIM_TT_ESC && token[1].type == JIM_TT_ESC
10371 && token[2].type == JIM_TT_VAR) {
10372 /* May be able to do fast interpolated object -> dictSubst */
10373 objPtr->typePtr = &interpolatedObjType;
10374 objPtr->internalRep.dictSubstValue.varNameObjPtr = token[0].objPtr;
10375 objPtr->internalRep.dictSubstValue.indexObjPtr = intv[2];
10376 Jim_IncrRefCount(intv[2]);
10377 }
10378 else if (tokens && intv[0] && intv[0]->typePtr == &sourceObjType) {
10379 /* The first interpolated token is source, so preserve the source info */
10380 JimSetSourceInfo(interp, objPtr, intv[0]->internalRep.sourceValue.fileNameObj, intv[0]->internalRep.sourceValue.lineNumber);
10381 }
10382
10383
10384 s = objPtr->bytes = Jim_Alloc(totlen + 1);
10385 objPtr->length = totlen;
10386 for (i = 0; i < tokens; i++) {
10387 if (intv[i]) {
10388 memcpy(s, intv[i]->bytes, intv[i]->length);
10389 s += intv[i]->length;
10390 Jim_DecrRefCount(interp, intv[i]);
10391 }
10392 }
10393 objPtr->bytes[totlen] = '\0';
10394 /* Free the intv vector if not static. */
10395 if (intv != sintv) {
10396 Jim_Free(intv);
10397 }
10398
10399 return objPtr;
10400 }
10401
10402
10403 /* listPtr *must* be a list.
10404 * The contents of the list is evaluated with the first element as the command and
10405 * the remaining elements as the arguments.
10406 */
10407 static int JimEvalObjList(Jim_Interp *interp, Jim_Obj *listPtr)
10408 {
10409 int retcode = JIM_OK;
10410
10411 JimPanic((Jim_IsList(listPtr) == 0, "JimEvalObjList() invoked on non-list."));
10412
10413 if (listPtr->internalRep.listValue.len) {
10414 Jim_IncrRefCount(listPtr);
10415 retcode = JimInvokeCommand(interp,
10416 listPtr->internalRep.listValue.len,
10417 listPtr->internalRep.listValue.ele);
10418 Jim_DecrRefCount(interp, listPtr);
10419 }
10420 return retcode;
10421 }
10422
10423 int Jim_EvalObjList(Jim_Interp *interp, Jim_Obj *listPtr)
10424 {
10425 SetListFromAny(interp, listPtr);
10426 return JimEvalObjList(interp, listPtr);
10427 }
10428
10429 int Jim_EvalObj(Jim_Interp *interp, Jim_Obj *scriptObjPtr)
10430 {
10431 int i;
10432 ScriptObj *script;
10433 ScriptToken *token;
10434 int retcode = JIM_OK;
10435 Jim_Obj *sargv[JIM_EVAL_SARGV_LEN], **argv = NULL;
10436 Jim_Obj *prevScriptObj;
10437
10438 /* If the object is of type "list", with no string rep we can call
10439 * a specialized version of Jim_EvalObj() */
10440 if (Jim_IsList(scriptObjPtr) && scriptObjPtr->bytes == NULL) {
10441 return JimEvalObjList(interp, scriptObjPtr);
10442 }
10443
10444 Jim_IncrRefCount(scriptObjPtr); /* Make sure it's shared. */
10445 script = JimGetScript(interp, scriptObjPtr);
10446 if (!JimScriptValid(interp, script)) {
10447 Jim_DecrRefCount(interp, scriptObjPtr);
10448 return JIM_ERR;
10449 }
10450
10451 /* Reset the interpreter result. This is useful to
10452 * return the empty result in the case of empty program. */
10453 Jim_SetEmptyResult(interp);
10454
10455 token = script->token;
10456
10457 #ifdef JIM_OPTIMIZATION
10458 /* Check for one of the following common scripts used by for, while
10459 *
10460 * {}
10461 * incr a
10462 */
10463 if (script->len == 0) {
10464 Jim_DecrRefCount(interp, scriptObjPtr);
10465 return JIM_OK;
10466 }
10467 if (script->len == 3
10468 && token[1].objPtr->typePtr == &commandObjType
10469 && token[1].objPtr->internalRep.cmdValue.cmdPtr->isproc == 0
10470 && token[1].objPtr->internalRep.cmdValue.cmdPtr->u.native.cmdProc == Jim_IncrCoreCommand
10471 && token[2].objPtr->typePtr == &variableObjType) {
10472
10473 Jim_Obj *objPtr = Jim_GetVariable(interp, token[2].objPtr, JIM_NONE);
10474
10475 if (objPtr && !Jim_IsShared(objPtr) && objPtr->typePtr == &intObjType) {
10476 JimWideValue(objPtr)++;
10477 Jim_InvalidateStringRep(objPtr);
10478 Jim_DecrRefCount(interp, scriptObjPtr);
10479 Jim_SetResult(interp, objPtr);
10480 return JIM_OK;
10481 }
10482 }
10483 #endif
10484
10485 /* Now we have to make sure the internal repr will not be
10486 * freed on shimmering.
10487 *
10488 * Think for example to this:
10489 *
10490 * set x {llength $x; ... some more code ...}; eval $x
10491 *
10492 * In order to preserve the internal rep, we increment the
10493 * inUse field of the script internal rep structure. */
10494 script->inUse++;
10495
10496 /* Stash the current script */
10497 prevScriptObj = interp->currentScriptObj;
10498 interp->currentScriptObj = scriptObjPtr;
10499
10500 interp->errorFlag = 0;
10501 argv = sargv;
10502
10503 /* Execute every command sequentially until the end of the script
10504 * or an error occurs.
10505 */
10506 for (i = 0; i < script->len && retcode == JIM_OK; ) {
10507 int argc;
10508 int j;
10509
10510 /* First token of the line is always JIM_TT_LINE */
10511 argc = token[i].objPtr->internalRep.scriptLineValue.argc;
10512 script->linenr = token[i].objPtr->internalRep.scriptLineValue.line;
10513
10514 /* Allocate the arguments vector if required */
10515 if (argc > JIM_EVAL_SARGV_LEN)
10516 argv = Jim_Alloc(sizeof(Jim_Obj *) * argc);
10517
10518 /* Skip the JIM_TT_LINE token */
10519 i++;
10520
10521 /* Populate the arguments objects.
10522 * If an error occurs, retcode will be set and
10523 * 'j' will be set to the number of args expanded
10524 */
10525 for (j = 0; j < argc; j++) {
10526 long wordtokens = 1;
10527 int expand = 0;
10528 Jim_Obj *wordObjPtr = NULL;
10529
10530 if (token[i].type == JIM_TT_WORD) {
10531 wordtokens = JimWideValue(token[i++].objPtr);
10532 if (wordtokens < 0) {
10533 expand = 1;
10534 wordtokens = -wordtokens;
10535 }
10536 }
10537
10538 if (wordtokens == 1) {
10539 /* Fast path if the token does not
10540 * need interpolation */
10541
10542 switch (token[i].type) {
10543 case JIM_TT_ESC:
10544 case JIM_TT_STR:
10545 wordObjPtr = token[i].objPtr;
10546 break;
10547 case JIM_TT_VAR:
10548 wordObjPtr = Jim_GetVariable(interp, token[i].objPtr, JIM_ERRMSG);
10549 break;
10550 case JIM_TT_EXPRSUGAR:
10551 wordObjPtr = JimExpandExprSugar(interp, token[i].objPtr);
10552 break;
10553 case JIM_TT_DICTSUGAR:
10554 wordObjPtr = JimExpandDictSugar(interp, token[i].objPtr);
10555 break;
10556 case JIM_TT_CMD:
10557 retcode = Jim_EvalObj(interp, token[i].objPtr);
10558 if (retcode == JIM_OK) {
10559 wordObjPtr = Jim_GetResult(interp);
10560 }
10561 break;
10562 default:
10563 JimPanic((1, "default token type reached " "in Jim_EvalObj()."));
10564 }
10565 }
10566 else {
10567 /* For interpolation we call a helper
10568 * function to do the work for us. */
10569 wordObjPtr = JimInterpolateTokens(interp, token + i, wordtokens, JIM_NONE);
10570 }
10571
10572 if (!wordObjPtr) {
10573 if (retcode == JIM_OK) {
10574 retcode = JIM_ERR;
10575 }
10576 break;
10577 }
10578
10579 Jim_IncrRefCount(wordObjPtr);
10580 i += wordtokens;
10581
10582 if (!expand) {
10583 argv[j] = wordObjPtr;
10584 }
10585 else {
10586 /* Need to expand wordObjPtr into multiple args from argv[j] ... */
10587 int len = Jim_ListLength(interp, wordObjPtr);
10588 int newargc = argc + len - 1;
10589 int k;
10590
10591 if (len > 1) {
10592 if (argv == sargv) {
10593 if (newargc > JIM_EVAL_SARGV_LEN) {
10594 argv = Jim_Alloc(sizeof(*argv) * newargc);
10595 memcpy(argv, sargv, sizeof(*argv) * j);
10596 }
10597 }
10598 else {
10599 /* Need to realloc to make room for (len - 1) more entries */
10600 argv = Jim_Realloc(argv, sizeof(*argv) * newargc);
10601 }
10602 }
10603
10604 /* Now copy in the expanded version */
10605 for (k = 0; k < len; k++) {
10606 argv[j++] = wordObjPtr->internalRep.listValue.ele[k];
10607 Jim_IncrRefCount(wordObjPtr->internalRep.listValue.ele[k]);
10608 }
10609
10610 /* The original object reference is no longer needed,
10611 * after the expansion it is no longer present on
10612 * the argument vector, but the single elements are
10613 * in its place. */
10614 Jim_DecrRefCount(interp, wordObjPtr);
10615
10616 /* And update the indexes */
10617 j--;
10618 argc += len - 1;
10619 }
10620 }
10621
10622 if (retcode == JIM_OK && argc) {
10623 /* Invoke the command */
10624 retcode = JimInvokeCommand(interp, argc, argv);
10625 /* Check for a signal after each command */
10626 if (Jim_CheckSignal(interp)) {
10627 retcode = JIM_SIGNAL;
10628 }
10629 }
10630
10631 /* Finished with the command, so decrement ref counts of each argument */
10632 while (j-- > 0) {
10633 Jim_DecrRefCount(interp, argv[j]);
10634 }
10635
10636 if (argv != sargv) {
10637 Jim_Free(argv);
10638 argv = sargv;
10639 }
10640 }
10641
10642 /* Possibly add to the error stack trace */
10643 if (retcode == JIM_ERR) {
10644 JimAddErrorToStack(interp, script);
10645 }
10646 /* Propagate the addStackTrace value through 'return -code error' */
10647 else if (retcode != JIM_RETURN || interp->returnCode != JIM_ERR) {
10648 /* No need to add stack trace */
10649 interp->addStackTrace = 0;
10650 }
10651
10652 /* Restore the current script */
10653 interp->currentScriptObj = prevScriptObj;
10654
10655 /* Note that we don't have to decrement inUse, because the
10656 * following code transfers our use of the reference again to
10657 * the script object. */
10658 Jim_FreeIntRep(interp, scriptObjPtr);
10659 scriptObjPtr->typePtr = &scriptObjType;
10660 Jim_SetIntRepPtr(scriptObjPtr, script);
10661 Jim_DecrRefCount(interp, scriptObjPtr);
10662
10663 return retcode;
10664 }
10665
10666 static int JimSetProcArg(Jim_Interp *interp, Jim_Obj *argNameObj, Jim_Obj *argValObj)
10667 {
10668 int retcode;
10669 /* If argObjPtr begins with '&', do an automatic upvar */
10670 const char *varname = Jim_String(argNameObj);
10671 if (*varname == '&') {
10672 /* First check that the target variable exists */
10673 Jim_Obj *objPtr;
10674 Jim_CallFrame *savedCallFrame = interp->framePtr;
10675
10676 interp->framePtr = interp->framePtr->parent;
10677 objPtr = Jim_GetVariable(interp, argValObj, JIM_ERRMSG);
10678 interp->framePtr = savedCallFrame;
10679 if (!objPtr) {
10680 return JIM_ERR;
10681 }
10682
10683 /* It exists, so perform the binding. */
10684 objPtr = Jim_NewStringObj(interp, varname + 1, -1);
10685 Jim_IncrRefCount(objPtr);
10686 retcode = Jim_SetVariableLink(interp, objPtr, argValObj, interp->framePtr->parent);
10687 Jim_DecrRefCount(interp, objPtr);
10688 }
10689 else {
10690 retcode = Jim_SetVariable(interp, argNameObj, argValObj);
10691 }
10692 return retcode;
10693 }
10694
10695 /**
10696 * Sets the interp result to be an error message indicating the required proc args.
10697 */
10698 static void JimSetProcWrongArgs(Jim_Interp *interp, Jim_Obj *procNameObj, Jim_Cmd *cmd)
10699 {
10700 /* Create a nice error message, consistent with Tcl 8.5 */
10701 Jim_Obj *argmsg = Jim_NewStringObj(interp, "", 0);
10702 int i;
10703
10704 for (i = 0; i < cmd->u.proc.argListLen; i++) {
10705 Jim_AppendString(interp, argmsg, " ", 1);
10706
10707 if (i == cmd->u.proc.argsPos) {
10708 if (cmd->u.proc.arglist[i].defaultObjPtr) {
10709 /* Renamed args */
10710 Jim_AppendString(interp, argmsg, "?", 1);
10711 Jim_AppendObj(interp, argmsg, cmd->u.proc.arglist[i].defaultObjPtr);
10712 Jim_AppendString(interp, argmsg, " ...?", -1);
10713 }
10714 else {
10715 /* We have plain args */
10716 Jim_AppendString(interp, argmsg, "?arg...?", -1);
10717 }
10718 }
10719 else {
10720 if (cmd->u.proc.arglist[i].defaultObjPtr) {
10721 Jim_AppendString(interp, argmsg, "?", 1);
10722 Jim_AppendObj(interp, argmsg, cmd->u.proc.arglist[i].nameObjPtr);
10723 Jim_AppendString(interp, argmsg, "?", 1);
10724 }
10725 else {
10726 const char *arg = Jim_String(cmd->u.proc.arglist[i].nameObjPtr);
10727 if (*arg == '&') {
10728 arg++;
10729 }
10730 Jim_AppendString(interp, argmsg, arg, -1);
10731 }
10732 }
10733 }
10734 Jim_SetResultFormatted(interp, "wrong # args: should be \"%#s%#s\"", procNameObj, argmsg);
10735 }
10736
10737 #ifdef jim_ext_namespace
10738 /*
10739 * [namespace eval]
10740 */
10741 int Jim_EvalNamespace(Jim_Interp *interp, Jim_Obj *scriptObj, Jim_Obj *nsObj)
10742 {
10743 Jim_CallFrame *callFramePtr;
10744 int retcode;
10745
10746 /* Create a new callframe */
10747 callFramePtr = JimCreateCallFrame(interp, interp->framePtr, nsObj);
10748 callFramePtr->argv = &interp->emptyObj;
10749 callFramePtr->argc = 0;
10750 callFramePtr->procArgsObjPtr = NULL;
10751 callFramePtr->procBodyObjPtr = scriptObj;
10752 callFramePtr->staticVars = NULL;
10753 callFramePtr->fileNameObj = interp->emptyObj;
10754 callFramePtr->line = 0;
10755 Jim_IncrRefCount(scriptObj);
10756 interp->framePtr = callFramePtr;
10757
10758 /* Check if there are too nested calls */
10759 if (interp->framePtr->level == interp->maxCallFrameDepth) {
10760 Jim_SetResultString(interp, "Too many nested calls. Infinite recursion?", -1);
10761 retcode = JIM_ERR;
10762 }
10763 else {
10764 /* Eval the body */
10765 retcode = Jim_EvalObj(interp, scriptObj);
10766 }
10767
10768 /* Destroy the callframe */
10769 interp->framePtr = interp->framePtr->parent;
10770 JimFreeCallFrame(interp, callFramePtr, JIM_FCF_REUSE);
10771
10772 return retcode;
10773 }
10774 #endif
10775
10776 /* Call a procedure implemented in Tcl.
10777 * It's possible to speed-up a lot this function, currently
10778 * the callframes are not cached, but allocated and
10779 * destroied every time. What is expecially costly is
10780 * to create/destroy the local vars hash table every time.
10781 *
10782 * This can be fixed just implementing callframes caching
10783 * in JimCreateCallFrame() and JimFreeCallFrame(). */
10784 static int JimCallProcedure(Jim_Interp *interp, Jim_Cmd *cmd, int argc, Jim_Obj *const *argv)
10785 {
10786 Jim_CallFrame *callFramePtr;
10787 int i, d, retcode, optargs;
10788 ScriptObj *script;
10789
10790 /* Check arity */
10791 if (argc - 1 < cmd->u.proc.reqArity ||
10792 (cmd->u.proc.argsPos < 0 && argc - 1 > cmd->u.proc.reqArity + cmd->u.proc.optArity)) {
10793 JimSetProcWrongArgs(interp, argv[0], cmd);
10794 return JIM_ERR;
10795 }
10796
10797 if (Jim_Length(cmd->u.proc.bodyObjPtr) == 0) {
10798 /* Optimise for procedure with no body - useful for optional debugging */
10799 return JIM_OK;
10800 }
10801
10802 /* Check if there are too nested calls */
10803 if (interp->framePtr->level == interp->maxCallFrameDepth) {
10804 Jim_SetResultString(interp, "Too many nested calls. Infinite recursion?", -1);
10805 return JIM_ERR;
10806 }
10807
10808 /* Create a new callframe */
10809 callFramePtr = JimCreateCallFrame(interp, interp->framePtr, cmd->u.proc.nsObj);
10810 callFramePtr->argv = argv;
10811 callFramePtr->argc = argc;
10812 callFramePtr->procArgsObjPtr = cmd->u.proc.argListObjPtr;
10813 callFramePtr->procBodyObjPtr = cmd->u.proc.bodyObjPtr;
10814 callFramePtr->staticVars = cmd->u.proc.staticVars;
10815
10816 /* Remember where we were called from. */
10817 script = JimGetScript(interp, interp->currentScriptObj);
10818 callFramePtr->fileNameObj = script->fileNameObj;
10819 callFramePtr->line = script->linenr;
10820
10821 Jim_IncrRefCount(cmd->u.proc.argListObjPtr);
10822 Jim_IncrRefCount(cmd->u.proc.bodyObjPtr);
10823 interp->framePtr = callFramePtr;
10824
10825 /* How many optional args are available */
10826 optargs = (argc - 1 - cmd->u.proc.reqArity);
10827
10828 /* Step 'i' along the actual args, and step 'd' along the formal args */
10829 i = 1;
10830 for (d = 0; d < cmd->u.proc.argListLen; d++) {
10831 Jim_Obj *nameObjPtr = cmd->u.proc.arglist[d].nameObjPtr;
10832 if (d == cmd->u.proc.argsPos) {
10833 /* assign $args */
10834 Jim_Obj *listObjPtr;
10835 int argsLen = 0;
10836 if (cmd->u.proc.reqArity + cmd->u.proc.optArity < argc - 1) {
10837 argsLen = argc - 1 - (cmd->u.proc.reqArity + cmd->u.proc.optArity);
10838 }
10839 listObjPtr = Jim_NewListObj(interp, &argv[i], argsLen);
10840
10841 /* It is possible to rename args. */
10842 if (cmd->u.proc.arglist[d].defaultObjPtr) {
10843 nameObjPtr =cmd->u.proc.arglist[d].defaultObjPtr;
10844 }
10845 retcode = Jim_SetVariable(interp, nameObjPtr, listObjPtr);
10846 if (retcode != JIM_OK) {
10847 goto badargset;
10848 }
10849
10850 i += argsLen;
10851 continue;
10852 }
10853
10854 /* Optional or required? */
10855 if (cmd->u.proc.arglist[d].defaultObjPtr == NULL || optargs-- > 0) {
10856 retcode = JimSetProcArg(interp, nameObjPtr, argv[i++]);
10857 }
10858 else {
10859 /* Ran out, so use the default */
10860 retcode = Jim_SetVariable(interp, nameObjPtr, cmd->u.proc.arglist[d].defaultObjPtr);
10861 }
10862 if (retcode != JIM_OK) {
10863 goto badargset;
10864 }
10865 }
10866
10867 /* Eval the body */
10868 retcode = Jim_EvalObj(interp, cmd->u.proc.bodyObjPtr);
10869
10870 badargset:
10871
10872 /* Invoke $jim::defer then destroy the callframe */
10873 retcode = JimInvokeDefer(interp, retcode);
10874 interp->framePtr = interp->framePtr->parent;
10875 JimFreeCallFrame(interp, callFramePtr, JIM_FCF_REUSE);
10876
10877 /* Now chain any tailcalls in the parent frame */
10878 if (interp->framePtr->tailcallObj) {
10879 do {
10880 Jim_Obj *tailcallObj = interp->framePtr->tailcallObj;
10881
10882 interp->framePtr->tailcallObj = NULL;
10883
10884 if (retcode == JIM_EVAL) {
10885 retcode = Jim_EvalObjList(interp, tailcallObj);
10886 if (retcode == JIM_RETURN) {
10887 /* If the result of the tailcall is 'return', push
10888 * it up to the caller
10889 */
10890 interp->returnLevel++;
10891 }
10892 }
10893 Jim_DecrRefCount(interp, tailcallObj);
10894 } while (interp->framePtr->tailcallObj);
10895
10896 /* If the tailcall chain finished early, may need to manually discard the command */
10897 if (interp->framePtr->tailcallCmd) {
10898 JimDecrCmdRefCount(interp, interp->framePtr->tailcallCmd);
10899 interp->framePtr->tailcallCmd = NULL;
10900 }
10901 }
10902
10903 /* Handle the JIM_RETURN return code */
10904 if (retcode == JIM_RETURN) {
10905 if (--interp->returnLevel <= 0) {
10906 retcode = interp->returnCode;
10907 interp->returnCode = JIM_OK;
10908 interp->returnLevel = 0;
10909 }
10910 }
10911 else if (retcode == JIM_ERR) {
10912 interp->addStackTrace++;
10913 Jim_DecrRefCount(interp, interp->errorProc);
10914 interp->errorProc = argv[0];
10915 Jim_IncrRefCount(interp->errorProc);
10916 }
10917
10918 return retcode;
10919 }
10920
10921 int Jim_EvalSource(Jim_Interp *interp, const char *filename, int lineno, const char *script)
10922 {
10923 int retval;
10924 Jim_Obj *scriptObjPtr;
10925
10926 scriptObjPtr = Jim_NewStringObj(interp, script, -1);
10927 Jim_IncrRefCount(scriptObjPtr);
10928
10929 if (filename) {
10930 Jim_Obj *prevScriptObj;
10931
10932 JimSetSourceInfo(interp, scriptObjPtr, Jim_NewStringObj(interp, filename, -1), lineno);
10933
10934 prevScriptObj = interp->currentScriptObj;
10935 interp->currentScriptObj = scriptObjPtr;
10936
10937 retval = Jim_EvalObj(interp, scriptObjPtr);
10938
10939 interp->currentScriptObj = prevScriptObj;
10940 }
10941 else {
10942 retval = Jim_EvalObj(interp, scriptObjPtr);
10943 }
10944 Jim_DecrRefCount(interp, scriptObjPtr);
10945 return retval;
10946 }
10947
10948 int Jim_Eval(Jim_Interp *interp, const char *script)
10949 {
10950 return Jim_EvalObj(interp, Jim_NewStringObj(interp, script, -1));
10951 }
10952
10953 /* Execute script in the scope of the global level */
10954 int Jim_EvalGlobal(Jim_Interp *interp, const char *script)
10955 {
10956 int retval;
10957 Jim_CallFrame *savedFramePtr = interp->framePtr;
10958
10959 interp->framePtr = interp->topFramePtr;
10960 retval = Jim_Eval(interp, script);
10961 interp->framePtr = savedFramePtr;
10962
10963 return retval;
10964 }
10965
10966 int Jim_EvalFileGlobal(Jim_Interp *interp, const char *filename)
10967 {
10968 int retval;
10969 Jim_CallFrame *savedFramePtr = interp->framePtr;
10970
10971 interp->framePtr = interp->topFramePtr;
10972 retval = Jim_EvalFile(interp, filename);
10973 interp->framePtr = savedFramePtr;
10974
10975 return retval;
10976 }
10977
10978 #include <sys/stat.h>
10979
10980 int Jim_EvalFile(Jim_Interp *interp, const char *filename)
10981 {
10982 FILE *fp;
10983 char *buf;
10984 Jim_Obj *scriptObjPtr;
10985 Jim_Obj *prevScriptObj;
10986 struct stat sb;
10987 int retcode;
10988 int readlen;
10989
10990 if (stat(filename, &sb) != 0 || (fp = fopen(filename, "rt")) == NULL) {
10991 Jim_SetResultFormatted(interp, "couldn't read file \"%s\": %s", filename, strerror(errno));
10992 return JIM_ERR;
10993 }
10994 if (sb.st_size == 0) {
10995 fclose(fp);
10996 return JIM_OK;
10997 }
10998
10999 buf = Jim_Alloc(sb.st_size + 1);
11000 readlen = fread(buf, 1, sb.st_size, fp);
11001 if (ferror(fp)) {
11002 fclose(fp);
11003 Jim_Free(buf);
11004 Jim_SetResultFormatted(interp, "failed to load file \"%s\": %s", filename, strerror(errno));
11005 return JIM_ERR;
11006 }
11007 fclose(fp);
11008 buf[readlen] = 0;
11009
11010 scriptObjPtr = Jim_NewStringObjNoAlloc(interp, buf, readlen);
11011 JimSetSourceInfo(interp, scriptObjPtr, Jim_NewStringObj(interp, filename, -1), 1);
11012 Jim_IncrRefCount(scriptObjPtr);
11013
11014 prevScriptObj = interp->currentScriptObj;
11015 interp->currentScriptObj = scriptObjPtr;
11016
11017 retcode = Jim_EvalObj(interp, scriptObjPtr);
11018
11019 /* Handle the JIM_RETURN return code */
11020 if (retcode == JIM_RETURN) {
11021 if (--interp->returnLevel <= 0) {
11022 retcode = interp->returnCode;
11023 interp->returnCode = JIM_OK;
11024 interp->returnLevel = 0;
11025 }
11026 }
11027 if (retcode == JIM_ERR) {
11028 /* EvalFile changes context, so add a stack frame here */
11029 interp->addStackTrace++;
11030 }
11031
11032 interp->currentScriptObj = prevScriptObj;
11033
11034 Jim_DecrRefCount(interp, scriptObjPtr);
11035
11036 return retcode;
11037 }
11038
11039 /* -----------------------------------------------------------------------------
11040 * Subst
11041 * ---------------------------------------------------------------------------*/
11042 static void JimParseSubst(struct JimParserCtx *pc, int flags)
11043 {
11044 pc->tstart = pc->p;
11045 pc->tline = pc->linenr;
11046
11047 if (pc->len == 0) {
11048 pc->tend = pc->p;
11049 pc->tt = JIM_TT_EOL;
11050 pc->eof = 1;
11051 return;
11052 }
11053 if (*pc->p == '[' && !(flags & JIM_SUBST_NOCMD)) {
11054 JimParseCmd(pc);
11055 return;
11056 }
11057 if (*pc->p == '$' && !(flags & JIM_SUBST_NOVAR)) {
11058 if (JimParseVar(pc) == JIM_OK) {
11059 return;
11060 }
11061 /* Not a var, so treat as a string */
11062 pc->tstart = pc->p;
11063 flags |= JIM_SUBST_NOVAR;
11064 }
11065 while (pc->len) {
11066 if (*pc->p == '$' && !(flags & JIM_SUBST_NOVAR)) {
11067 break;
11068 }
11069 if (*pc->p == '[' && !(flags & JIM_SUBST_NOCMD)) {
11070 break;
11071 }
11072 if (*pc->p == '\\' && pc->len > 1) {
11073 pc->p++;
11074 pc->len--;
11075 }
11076 pc->p++;
11077 pc->len--;
11078 }
11079 pc->tend = pc->p - 1;
11080 pc->tt = (flags & JIM_SUBST_NOESC) ? JIM_TT_STR : JIM_TT_ESC;
11081 }
11082
11083 /* The subst object type reuses most of the data structures and functions
11084 * of the script object. Script's data structures are a bit more complex
11085 * for what is needed for [subst]itution tasks, but the reuse helps to
11086 * deal with a single data structure at the cost of some more memory
11087 * usage for substitutions. */
11088
11089 /* This method takes the string representation of an object
11090 * as a Tcl string where to perform [subst]itution, and generates
11091 * the pre-parsed internal representation. */
11092 static int SetSubstFromAny(Jim_Interp *interp, struct Jim_Obj *objPtr, int flags)
11093 {
11094 int scriptTextLen;
11095 const char *scriptText = Jim_GetString(objPtr, &scriptTextLen);
11096 struct JimParserCtx parser;
11097 struct ScriptObj *script = Jim_Alloc(sizeof(*script));
11098 ParseTokenList tokenlist;
11099
11100 /* Initially parse the subst into tokens (in tokenlist) */
11101 ScriptTokenListInit(&tokenlist);
11102
11103 JimParserInit(&parser, scriptText, scriptTextLen, 1);
11104 while (1) {
11105 JimParseSubst(&parser, flags);
11106 if (parser.eof) {
11107 /* Note that subst doesn't need the EOL token */
11108 break;
11109 }
11110 ScriptAddToken(&tokenlist, parser.tstart, parser.tend - parser.tstart + 1, parser.tt,
11111 parser.tline);
11112 }
11113
11114 /* Create the "real" subst/script tokens from the initial token list */
11115 script->inUse = 1;
11116 script->substFlags = flags;
11117 script->fileNameObj = interp->emptyObj;
11118 Jim_IncrRefCount(script->fileNameObj);
11119 SubstObjAddTokens(interp, script, &tokenlist);
11120
11121 /* No longer need the token list */
11122 ScriptTokenListFree(&tokenlist);
11123
11124 #ifdef DEBUG_SHOW_SUBST
11125 {
11126 int i;
11127
11128 printf("==== Subst ====\n");
11129 for (i = 0; i < script->len; i++) {
11130 printf("[%2d] %s '%s'\n", i, jim_tt_name(script->token[i].type),
11131 Jim_String(script->token[i].objPtr));
11132 }
11133 }
11134 #endif
11135
11136 /* Free the old internal rep and set the new one. */
11137 Jim_FreeIntRep(interp, objPtr);
11138 Jim_SetIntRepPtr(objPtr, script);
11139 objPtr->typePtr = &scriptObjType;
11140 return JIM_OK;
11141 }
11142
11143 static ScriptObj *Jim_GetSubst(Jim_Interp *interp, Jim_Obj *objPtr, int flags)
11144 {
11145 if (objPtr->typePtr != &scriptObjType || ((ScriptObj *)Jim_GetIntRepPtr(objPtr))->substFlags != flags)
11146 SetSubstFromAny(interp, objPtr, flags);
11147 return (ScriptObj *) Jim_GetIntRepPtr(objPtr);
11148 }
11149
11150 /* Performs commands,variables,blackslashes substitution,
11151 * storing the result object (with refcount 0) into
11152 * resObjPtrPtr. */
11153 int Jim_SubstObj(Jim_Interp *interp, Jim_Obj *substObjPtr, Jim_Obj **resObjPtrPtr, int flags)
11154 {
11155 ScriptObj *script = Jim_GetSubst(interp, substObjPtr, flags);
11156
11157 Jim_IncrRefCount(substObjPtr); /* Make sure it's shared. */
11158 /* In order to preserve the internal rep, we increment the
11159 * inUse field of the script internal rep structure. */
11160 script->inUse++;
11161
11162 *resObjPtrPtr = JimInterpolateTokens(interp, script->token, script->len, flags);
11163
11164 script->inUse--;
11165 Jim_DecrRefCount(interp, substObjPtr);
11166 if (*resObjPtrPtr == NULL) {
11167 return JIM_ERR;
11168 }
11169 return JIM_OK;
11170 }
11171
11172 /* -----------------------------------------------------------------------------
11173 * Core commands utility functions
11174 * ---------------------------------------------------------------------------*/
11175 void Jim_WrongNumArgs(Jim_Interp *interp, int argc, Jim_Obj *const *argv, const char *msg)
11176 {
11177 Jim_Obj *objPtr;
11178 Jim_Obj *listObjPtr;
11179
11180 JimPanic((argc == 0, "Jim_WrongNumArgs() called with argc=0"));
11181
11182 listObjPtr = Jim_NewListObj(interp, argv, argc);
11183
11184 if (msg && *msg) {
11185 Jim_ListAppendElement(interp, listObjPtr, Jim_NewStringObj(interp, msg, -1));
11186 }
11187 Jim_IncrRefCount(listObjPtr);
11188 objPtr = Jim_ListJoin(interp, listObjPtr, " ", 1);
11189 Jim_DecrRefCount(interp, listObjPtr);
11190
11191 Jim_SetResultFormatted(interp, "wrong # args: should be \"%#s\"", objPtr);
11192 }
11193
11194 /**
11195 * May add the key and/or value to the list.
11196 */
11197 typedef void JimHashtableIteratorCallbackType(Jim_Interp *interp, Jim_Obj *listObjPtr,
11198 Jim_HashEntry *he, int type);
11199
11200 #define JimTrivialMatch(pattern) (strpbrk((pattern), "*[?\\") == NULL)
11201
11202 /**
11203 * For each key of the hash table 'ht' (with string keys) which matches the glob pattern (all if NULL),
11204 * invoke the callback to add entries to a list.
11205 * Returns the list.
11206 */
11207 static Jim_Obj *JimHashtablePatternMatch(Jim_Interp *interp, Jim_HashTable *ht, Jim_Obj *patternObjPtr,
11208 JimHashtableIteratorCallbackType *callback, int type)
11209 {
11210 Jim_HashEntry *he;
11211 Jim_Obj *listObjPtr = Jim_NewListObj(interp, NULL, 0);
11212
11213 /* Check for the non-pattern case. We can do this much more efficiently. */
11214 if (patternObjPtr && JimTrivialMatch(Jim_String(patternObjPtr))) {
11215 he = Jim_FindHashEntry(ht, Jim_String(patternObjPtr));
11216 if (he) {
11217 callback(interp, listObjPtr, he, type);
11218 }
11219 }
11220 else {
11221 Jim_HashTableIterator htiter;
11222 JimInitHashTableIterator(ht, &htiter);
11223 while ((he = Jim_NextHashEntry(&htiter)) != NULL) {
11224 if (patternObjPtr == NULL || JimGlobMatch(Jim_String(patternObjPtr), he->key, 0)) {
11225 callback(interp, listObjPtr, he, type);
11226 }
11227 }
11228 }
11229 return listObjPtr;
11230 }
11231
11232 /* Keep these in order */
11233 #define JIM_CMDLIST_COMMANDS 0
11234 #define JIM_CMDLIST_PROCS 1
11235 #define JIM_CMDLIST_CHANNELS 2
11236
11237 /**
11238 * Adds matching command names (procs, channels) to the list.
11239 */
11240 static void JimCommandMatch(Jim_Interp *interp, Jim_Obj *listObjPtr,
11241 Jim_HashEntry *he, int type)
11242 {
11243 Jim_Cmd *cmdPtr = Jim_GetHashEntryVal(he);
11244 Jim_Obj *objPtr;
11245
11246 if (type == JIM_CMDLIST_PROCS && !cmdPtr->isproc) {
11247 /* not a proc */
11248 return;
11249 }
11250
11251 objPtr = Jim_NewStringObj(interp, he->key, -1);
11252 Jim_IncrRefCount(objPtr);
11253
11254 if (type != JIM_CMDLIST_CHANNELS || Jim_AioFilehandle(interp, objPtr)) {
11255 Jim_ListAppendElement(interp, listObjPtr, objPtr);
11256 }
11257 Jim_DecrRefCount(interp, objPtr);
11258 }
11259
11260 /* type is JIM_CMDLIST_xxx */
11261 static Jim_Obj *JimCommandsList(Jim_Interp *interp, Jim_Obj *patternObjPtr, int type)
11262 {
11263 return JimHashtablePatternMatch(interp, &interp->commands, patternObjPtr, JimCommandMatch, type);
11264 }
11265
11266 /* Keep these in order */
11267 #define JIM_VARLIST_GLOBALS 0
11268 #define JIM_VARLIST_LOCALS 1
11269 #define JIM_VARLIST_VARS 2
11270
11271 #define JIM_VARLIST_VALUES 0x1000
11272
11273 /**
11274 * Adds matching variable names to the list.
11275 */
11276 static void JimVariablesMatch(Jim_Interp *interp, Jim_Obj *listObjPtr,
11277 Jim_HashEntry *he, int type)
11278 {
11279 Jim_Var *varPtr = Jim_GetHashEntryVal(he);
11280
11281 if (type != JIM_VARLIST_LOCALS || varPtr->linkFramePtr == NULL) {
11282 Jim_ListAppendElement(interp, listObjPtr, Jim_NewStringObj(interp, he->key, -1));
11283 if (type & JIM_VARLIST_VALUES) {
11284 Jim_ListAppendElement(interp, listObjPtr, varPtr->objPtr);
11285 }
11286 }
11287 }
11288
11289 /* mode is JIM_VARLIST_xxx */
11290 static Jim_Obj *JimVariablesList(Jim_Interp *interp, Jim_Obj *patternObjPtr, int mode)
11291 {
11292 if (mode == JIM_VARLIST_LOCALS && interp->framePtr == interp->topFramePtr) {
11293 /* For [info locals], if we are at top level an emtpy list
11294 * is returned. I don't agree, but we aim at compatibility (SS) */
11295 return interp->emptyObj;
11296 }
11297 else {
11298 Jim_CallFrame *framePtr = (mode == JIM_VARLIST_GLOBALS) ? interp->topFramePtr : interp->framePtr;
11299 return JimHashtablePatternMatch(interp, &framePtr->vars, patternObjPtr, JimVariablesMatch, mode);
11300 }
11301 }
11302
11303 static int JimInfoLevel(Jim_Interp *interp, Jim_Obj *levelObjPtr,
11304 Jim_Obj **objPtrPtr, int info_level_cmd)
11305 {
11306 Jim_CallFrame *targetCallFrame;
11307
11308 targetCallFrame = JimGetCallFrameByInteger(interp, levelObjPtr);
11309 if (targetCallFrame == NULL) {
11310 return JIM_ERR;
11311 }
11312 /* No proc call at toplevel callframe */
11313 if (targetCallFrame == interp->topFramePtr) {
11314 Jim_SetResultFormatted(interp, "bad level \"%#s\"", levelObjPtr);
11315 return JIM_ERR;
11316 }
11317 if (info_level_cmd) {
11318 *objPtrPtr = Jim_NewListObj(interp, targetCallFrame->argv, targetCallFrame->argc);
11319 }
11320 else {
11321 Jim_Obj *listObj = Jim_NewListObj(interp, NULL, 0);
11322
11323 Jim_ListAppendElement(interp, listObj, targetCallFrame->argv[0]);
11324 Jim_ListAppendElement(interp, listObj, targetCallFrame->fileNameObj);
11325 Jim_ListAppendElement(interp, listObj, Jim_NewIntObj(interp, targetCallFrame->line));
11326 *objPtrPtr = listObj;
11327 }
11328 return JIM_OK;
11329 }
11330
11331 /* -----------------------------------------------------------------------------
11332 * Core commands
11333 * ---------------------------------------------------------------------------*/
11334
11335 /* fake [puts] -- not the real puts, just for debugging. */
11336 static int Jim_PutsCoreCommand(Jim_Interp *interp, int argc, Jim_Obj *const *argv)
11337 {
11338 if (argc != 2 && argc != 3) {
11339 Jim_WrongNumArgs(interp, 1, argv, "?-nonewline? string");
11340 return JIM_ERR;
11341 }
11342 if (argc == 3) {
11343 if (!Jim_CompareStringImmediate(interp, argv[1], "-nonewline")) {
11344 Jim_SetResultString(interp, "The second argument must " "be -nonewline", -1);
11345 return JIM_ERR;
11346 }
11347 else {
11348 fputs(Jim_String(argv[2]), stdout);
11349 }
11350 }
11351 else {
11352 puts(Jim_String(argv[1]));
11353 }
11354 return JIM_OK;
11355 }
11356
11357 /* Helper for [+] and [*] */
11358 static int JimAddMulHelper(Jim_Interp *interp, int argc, Jim_Obj *const *argv, int op)
11359 {
11360 jim_wide wideValue, res;
11361 double doubleValue, doubleRes;
11362 int i;
11363
11364 res = (op == JIM_EXPROP_ADD) ? 0 : 1;
11365
11366 for (i = 1; i < argc; i++) {
11367 if (Jim_GetWide(interp, argv[i], &wideValue) != JIM_OK)
11368 goto trydouble;
11369 if (op == JIM_EXPROP_ADD)
11370 res += wideValue;
11371 else
11372 res *= wideValue;
11373 }
11374 Jim_SetResultInt(interp, res);
11375 return JIM_OK;
11376 trydouble:
11377 doubleRes = (double)res;
11378 for (; i < argc; i++) {
11379 if (Jim_GetDouble(interp, argv[i], &doubleValue) != JIM_OK)
11380 return JIM_ERR;
11381 if (op == JIM_EXPROP_ADD)
11382 doubleRes += doubleValue;
11383 else
11384 doubleRes *= doubleValue;
11385 }
11386 Jim_SetResult(interp, Jim_NewDoubleObj(interp, doubleRes));
11387 return JIM_OK;
11388 }
11389
11390 /* Helper for [-] and [/] */
11391 static int JimSubDivHelper(Jim_Interp *interp, int argc, Jim_Obj *const *argv, int op)
11392 {
11393 jim_wide wideValue, res = 0;
11394 double doubleValue, doubleRes = 0;
11395 int i = 2;
11396
11397 if (argc < 2) {
11398 Jim_WrongNumArgs(interp, 1, argv, "number ?number ... number?");
11399 return JIM_ERR;
11400 }
11401 else if (argc == 2) {
11402 /* The arity = 2 case is different. For [- x] returns -x,
11403 * while [/ x] returns 1/x. */
11404 if (Jim_GetWide(interp, argv[1], &wideValue) != JIM_OK) {
11405 if (Jim_GetDouble(interp, argv[1], &doubleValue) != JIM_OK) {
11406 return JIM_ERR;
11407 }
11408 else {
11409 if (op == JIM_EXPROP_SUB)
11410 doubleRes = -doubleValue;
11411 else
11412 doubleRes = 1.0 / doubleValue;
11413 Jim_SetResult(interp, Jim_NewDoubleObj(interp, doubleRes));
11414 return JIM_OK;
11415 }
11416 }
11417 if (op == JIM_EXPROP_SUB) {
11418 res = -wideValue;
11419 Jim_SetResultInt(interp, res);
11420 }
11421 else {
11422 doubleRes = 1.0 / wideValue;
11423 Jim_SetResult(interp, Jim_NewDoubleObj(interp, doubleRes));
11424 }
11425 return JIM_OK;
11426 }
11427 else {
11428 if (Jim_GetWide(interp, argv[1], &res) != JIM_OK) {
11429 if (Jim_GetDouble(interp, argv[1], &doubleRes)
11430 != JIM_OK) {
11431 return JIM_ERR;
11432 }
11433 else {
11434 goto trydouble;
11435 }
11436 }
11437 }
11438 for (i = 2; i < argc; i++) {
11439 if (Jim_GetWide(interp, argv[i], &wideValue) != JIM_OK) {
11440 doubleRes = (double)res;
11441 goto trydouble;
11442 }
11443 if (op == JIM_EXPROP_SUB)
11444 res -= wideValue;
11445 else {
11446 if (wideValue == 0) {
11447 Jim_SetResultString(interp, "Division by zero", -1);
11448 return JIM_ERR;
11449 }
11450 res /= wideValue;
11451 }
11452 }
11453 Jim_SetResultInt(interp, res);
11454 return JIM_OK;
11455 trydouble:
11456 for (; i < argc; i++) {
11457 if (Jim_GetDouble(interp, argv[i], &doubleValue) != JIM_OK)
11458 return JIM_ERR;
11459 if (op == JIM_EXPROP_SUB)
11460 doubleRes -= doubleValue;
11461 else
11462 doubleRes /= doubleValue;
11463 }
11464 Jim_SetResult(interp, Jim_NewDoubleObj(interp, doubleRes));
11465 return JIM_OK;
11466 }
11467
11468
11469 /* [+] */
11470 static int Jim_AddCoreCommand(Jim_Interp *interp, int argc, Jim_Obj *const *argv)
11471 {
11472 return JimAddMulHelper(interp, argc, argv, JIM_EXPROP_ADD);
11473 }
11474
11475 /* [*] */
11476 static int Jim_MulCoreCommand(Jim_Interp *interp, int argc, Jim_Obj *const *argv)
11477 {
11478 return JimAddMulHelper(interp, argc, argv, JIM_EXPROP_MUL);
11479 }
11480
11481 /* [-] */
11482 static int Jim_SubCoreCommand(Jim_Interp *interp, int argc, Jim_Obj *const *argv)
11483 {
11484 return JimSubDivHelper(interp, argc, argv, JIM_EXPROP_SUB);
11485 }
11486
11487 /* [/] */
11488 static int Jim_DivCoreCommand(Jim_Interp *interp, int argc, Jim_Obj *const *argv)
11489 {
11490 return JimSubDivHelper(interp, argc, argv, JIM_EXPROP_DIV);
11491 }
11492
11493 /* [set] */
11494 static int Jim_SetCoreCommand(Jim_Interp *interp, int argc, Jim_Obj *const *argv)
11495 {
11496 if (argc != 2 && argc != 3) {
11497 Jim_WrongNumArgs(interp, 1, argv, "varName ?newValue?");
11498 return JIM_ERR;
11499 }
11500 if (argc == 2) {
11501 Jim_Obj *objPtr;
11502
11503 objPtr = Jim_GetVariable(interp, argv[1], JIM_ERRMSG);
11504 if (!objPtr)
11505 return JIM_ERR;
11506 Jim_SetResult(interp, objPtr);
11507 return JIM_OK;
11508 }
11509 /* argc == 3 case. */
11510 if (Jim_SetVariable(interp, argv[1], argv[2]) != JIM_OK)
11511 return JIM_ERR;
11512 Jim_SetResult(interp, argv[2]);
11513 return JIM_OK;
11514 }
11515
11516 /* [unset]
11517 *
11518 * unset ?-nocomplain? ?--? ?varName ...?
11519 */
11520 static int Jim_UnsetCoreCommand(Jim_Interp *interp, int argc, Jim_Obj *const *argv)
11521 {
11522 int i = 1;
11523 int complain = 1;
11524
11525 while (i < argc) {
11526 if (Jim_CompareStringImmediate(interp, argv[i], "--")) {
11527 i++;
11528 break;
11529 }
11530 if (Jim_CompareStringImmediate(interp, argv[i], "-nocomplain")) {
11531 complain = 0;
11532 i++;
11533 continue;
11534 }
11535 break;
11536 }
11537
11538 while (i < argc) {
11539 if (Jim_UnsetVariable(interp, argv[i], complain ? JIM_ERRMSG : JIM_NONE) != JIM_OK
11540 && complain) {
11541 return JIM_ERR;
11542 }
11543 i++;
11544 }
11545 return JIM_OK;
11546 }
11547
11548 /* [while] */
11549 static int Jim_WhileCoreCommand(Jim_Interp *interp, int argc, Jim_Obj *const *argv)
11550 {
11551 if (argc != 3) {
11552 Jim_WrongNumArgs(interp, 1, argv, "condition body");
11553 return JIM_ERR;
11554 }
11555
11556 /* The general purpose implementation of while starts here */
11557 while (1) {
11558 int boolean, retval;
11559
11560 if ((retval = Jim_GetBoolFromExpr(interp, argv[1], &boolean)) != JIM_OK)
11561 return retval;
11562 if (!boolean)
11563 break;
11564
11565 if ((retval = Jim_EvalObj(interp, argv[2])) != JIM_OK) {
11566 switch (retval) {
11567 case JIM_BREAK:
11568 goto out;
11569 break;
11570 case JIM_CONTINUE:
11571 continue;
11572 break;
11573 default:
11574 return retval;
11575 }
11576 }
11577 }
11578 out:
11579 Jim_SetEmptyResult(interp);
11580 return JIM_OK;
11581 }
11582
11583 /* [for] */
11584 static int Jim_ForCoreCommand(Jim_Interp *interp, int argc, Jim_Obj *const *argv)
11585 {
11586 int retval;
11587 int boolean = 1;
11588 Jim_Obj *varNamePtr = NULL;
11589 Jim_Obj *stopVarNamePtr = NULL;
11590
11591 if (argc != 5) {
11592 Jim_WrongNumArgs(interp, 1, argv, "start test next body");
11593 return JIM_ERR;
11594 }
11595
11596 /* Do the initialisation */
11597 if ((retval = Jim_EvalObj(interp, argv[1])) != JIM_OK) {
11598 return retval;
11599 }
11600
11601 /* And do the first test now. Better for optimisation
11602 * if we can do next/test at the bottom of the loop
11603 */
11604 retval = Jim_GetBoolFromExpr(interp, argv[2], &boolean);
11605
11606 /* Ready to do the body as follows:
11607 * while (1) {
11608 * body // check retcode
11609 * next // check retcode
11610 * test // check retcode/test bool
11611 * }
11612 */
11613
11614 #ifdef JIM_OPTIMIZATION
11615 /* Check if the for is on the form:
11616 * for ... {$i < CONST} {incr i}
11617 * for ... {$i < $j} {incr i}
11618 */
11619 if (retval == JIM_OK && boolean) {
11620 ScriptObj *incrScript;
11621 struct ExprTree *expr;
11622 jim_wide stop, currentVal;
11623 Jim_Obj *objPtr;
11624 int cmpOffset;
11625
11626 /* Do it only if there aren't shared arguments */
11627 expr = JimGetExpression(interp, argv[2]);
11628 incrScript = JimGetScript(interp, argv[3]);
11629
11630 /* Ensure proper lengths to start */
11631 if (incrScript == NULL || incrScript->len != 3 || !expr || expr->len != 3) {
11632 goto evalstart;
11633 }
11634 /* Ensure proper token types. */
11635 if (incrScript->token[1].type != JIM_TT_ESC) {
11636 goto evalstart;
11637 }
11638
11639 if (expr->expr->type == JIM_EXPROP_LT) {
11640 cmpOffset = 0;
11641 }
11642 else if (expr->expr->type == JIM_EXPROP_LTE) {
11643 cmpOffset = 1;
11644 }
11645 else {
11646 goto evalstart;
11647 }
11648
11649 if (expr->expr->left->type != JIM_TT_VAR) {
11650 goto evalstart;
11651 }
11652
11653 if (expr->expr->right->type != JIM_TT_VAR && expr->expr->right->type != JIM_TT_EXPR_INT) {
11654 goto evalstart;
11655 }
11656
11657 /* Update command must be incr */
11658 if (!Jim_CompareStringImmediate(interp, incrScript->token[1].objPtr, "incr")) {
11659 goto evalstart;
11660 }
11661
11662 /* incr, expression must be about the same variable */
11663 if (!Jim_StringEqObj(incrScript->token[2].objPtr, expr->expr->left->objPtr)) {
11664 goto evalstart;
11665 }
11666
11667 /* Get the stop condition (must be a variable or integer) */
11668 if (expr->expr->right->type == JIM_TT_EXPR_INT) {
11669 if (Jim_GetWide(interp, expr->expr->right->objPtr, &stop) == JIM_ERR) {
11670 goto evalstart;
11671 }
11672 }
11673 else {
11674 stopVarNamePtr = expr->expr->right->objPtr;
11675 Jim_IncrRefCount(stopVarNamePtr);
11676 /* Keep the compiler happy */
11677 stop = 0;
11678 }
11679
11680 /* Initialization */
11681 varNamePtr = expr->expr->left->objPtr;
11682 Jim_IncrRefCount(varNamePtr);
11683
11684 objPtr = Jim_GetVariable(interp, varNamePtr, JIM_NONE);
11685 if (objPtr == NULL || Jim_GetWide(interp, objPtr, &currentVal) != JIM_OK) {
11686 goto testcond;
11687 }
11688
11689 /* --- OPTIMIZED FOR --- */
11690 while (retval == JIM_OK) {
11691 /* === Check condition === */
11692 /* Note that currentVal is already set here */
11693
11694 /* Immediate or Variable? get the 'stop' value if the latter. */
11695 if (stopVarNamePtr) {
11696 objPtr = Jim_GetVariable(interp, stopVarNamePtr, JIM_NONE);
11697 if (objPtr == NULL || Jim_GetWide(interp, objPtr, &stop) != JIM_OK) {
11698 goto testcond;
11699 }
11700 }
11701
11702 if (currentVal >= stop + cmpOffset) {
11703 break;
11704 }
11705
11706 /* Eval body */
11707 retval = Jim_EvalObj(interp, argv[4]);
11708 if (retval == JIM_OK || retval == JIM_CONTINUE) {
11709 retval = JIM_OK;
11710
11711 objPtr = Jim_GetVariable(interp, varNamePtr, JIM_ERRMSG);
11712
11713 /* Increment */
11714 if (objPtr == NULL) {
11715 retval = JIM_ERR;
11716 goto out;
11717 }
11718 if (!Jim_IsShared(objPtr) && objPtr->typePtr == &intObjType) {
11719 currentVal = ++JimWideValue(objPtr);
11720 Jim_InvalidateStringRep(objPtr);
11721 }
11722 else {
11723 if (Jim_GetWide(interp, objPtr, &currentVal) != JIM_OK ||
11724 Jim_SetVariable(interp, varNamePtr, Jim_NewIntObj(interp,
11725 ++currentVal)) != JIM_OK) {
11726 goto evalnext;
11727 }
11728 }
11729 }
11730 }
11731 goto out;
11732 }
11733 evalstart:
11734 #endif
11735
11736 while (boolean && (retval == JIM_OK || retval == JIM_CONTINUE)) {
11737 /* Body */
11738 retval = Jim_EvalObj(interp, argv[4]);
11739
11740 if (retval == JIM_OK || retval == JIM_CONTINUE) {
11741 /* increment */
11742 JIM_IF_OPTIM(evalnext:)
11743 retval = Jim_EvalObj(interp, argv[3]);
11744 if (retval == JIM_OK || retval == JIM_CONTINUE) {
11745 /* test */
11746 JIM_IF_OPTIM(testcond:)
11747 retval = Jim_GetBoolFromExpr(interp, argv[2], &boolean);
11748 }
11749 }
11750 }
11751 JIM_IF_OPTIM(out:)
11752 if (stopVarNamePtr) {
11753 Jim_DecrRefCount(interp, stopVarNamePtr);
11754 }
11755 if (varNamePtr) {
11756 Jim_DecrRefCount(interp, varNamePtr);
11757 }
11758
11759 if (retval == JIM_CONTINUE || retval == JIM_BREAK || retval == JIM_OK) {
11760 Jim_SetEmptyResult(interp);
11761 return JIM_OK;
11762 }
11763
11764 return retval;
11765 }
11766
11767 /* [loop] */
11768 static int Jim_LoopCoreCommand(Jim_Interp *interp, int argc, Jim_Obj *const *argv)
11769 {
11770 int retval;
11771 jim_wide i;
11772 jim_wide limit;
11773 jim_wide incr = 1;
11774 Jim_Obj *bodyObjPtr;
11775
11776 if (argc != 5 && argc != 6) {
11777 Jim_WrongNumArgs(interp, 1, argv, "var first limit ?incr? body");
11778 return JIM_ERR;
11779 }
11780
11781 if (Jim_GetWide(interp, argv[2], &i) != JIM_OK ||
11782 Jim_GetWide(interp, argv[3], &limit) != JIM_OK ||
11783 (argc == 6 && Jim_GetWide(interp, argv[4], &incr) != JIM_OK)) {
11784 return JIM_ERR;
11785 }
11786 bodyObjPtr = (argc == 5) ? argv[4] : argv[5];
11787
11788 retval = Jim_SetVariable(interp, argv[1], argv[2]);
11789
11790 while (((i < limit && incr > 0) || (i > limit && incr < 0)) && retval == JIM_OK) {
11791 retval = Jim_EvalObj(interp, bodyObjPtr);
11792 if (retval == JIM_OK || retval == JIM_CONTINUE) {
11793 Jim_Obj *objPtr = Jim_GetVariable(interp, argv[1], JIM_ERRMSG);
11794
11795 retval = JIM_OK;
11796
11797 /* Increment */
11798 i += incr;
11799
11800 if (objPtr && !Jim_IsShared(objPtr) && objPtr->typePtr == &intObjType) {
11801 if (argv[1]->typePtr != &variableObjType) {
11802 if (Jim_SetVariable(interp, argv[1], objPtr) != JIM_OK) {
11803 return JIM_ERR;
11804 }
11805 }
11806 JimWideValue(objPtr) = i;
11807 Jim_InvalidateStringRep(objPtr);
11808
11809 /* The following step is required in order to invalidate the
11810 * string repr of "FOO" if the var name is of the form of "FOO(IDX)" */
11811 if (argv[1]->typePtr != &variableObjType) {
11812 if (Jim_SetVariable(interp, argv[1], objPtr) != JIM_OK) {
11813 retval = JIM_ERR;
11814 break;
11815 }
11816 }
11817 }
11818 else {
11819 objPtr = Jim_NewIntObj(interp, i);
11820 retval = Jim_SetVariable(interp, argv[1], objPtr);
11821 if (retval != JIM_OK) {
11822 Jim_FreeNewObj(interp, objPtr);
11823 }
11824 }
11825 }
11826 }
11827
11828 if (retval == JIM_OK || retval == JIM_CONTINUE || retval == JIM_BREAK) {
11829 Jim_SetEmptyResult(interp);
11830 return JIM_OK;
11831 }
11832 return retval;
11833 }
11834
11835 /* List iterators make it easy to iterate over a list.
11836 * At some point iterators will be expanded to support generators.
11837 */
11838 typedef struct {
11839 Jim_Obj *objPtr;
11840 int idx;
11841 } Jim_ListIter;
11842
11843 /**
11844 * Initialise the iterator at the start of the list.
11845 */
11846 static void JimListIterInit(Jim_ListIter *iter, Jim_Obj *objPtr)
11847 {
11848 iter->objPtr = objPtr;
11849 iter->idx = 0;
11850 }
11851
11852 /**
11853 * Returns the next object from the list, or NULL on end-of-list.
11854 */
11855 static Jim_Obj *JimListIterNext(Jim_Interp *interp, Jim_ListIter *iter)
11856 {
11857 if (iter->idx >= Jim_ListLength(interp, iter->objPtr)) {
11858 return NULL;
11859 }
11860 return iter->objPtr->internalRep.listValue.ele[iter->idx++];
11861 }
11862
11863 /**
11864 * Returns 1 if end-of-list has been reached.
11865 */
11866 static int JimListIterDone(Jim_Interp *interp, Jim_ListIter *iter)
11867 {
11868 return iter->idx >= Jim_ListLength(interp, iter->objPtr);
11869 }
11870
11871 /* foreach + lmap implementation. */
11872 static int JimForeachMapHelper(Jim_Interp *interp, int argc, Jim_Obj *const *argv, int doMap)
11873 {
11874 int result = JIM_OK;
11875 int i, numargs;
11876 Jim_ListIter twoiters[2]; /* Avoid allocation for a single list */
11877 Jim_ListIter *iters;
11878 Jim_Obj *script;
11879 Jim_Obj *resultObj;
11880
11881 if (argc < 4 || argc % 2 != 0) {
11882 Jim_WrongNumArgs(interp, 1, argv, "varList list ?varList list ...? script");
11883 return JIM_ERR;
11884 }
11885 script = argv[argc - 1]; /* Last argument is a script */
11886 numargs = (argc - 1 - 1); /* argc - 'foreach' - script */
11887
11888 if (numargs == 2) {
11889 iters = twoiters;
11890 }
11891 else {
11892 iters = Jim_Alloc(numargs * sizeof(*iters));
11893 }
11894 for (i = 0; i < numargs; i++) {
11895 JimListIterInit(&iters[i], argv[i + 1]);
11896 if (i % 2 == 0 && JimListIterDone(interp, &iters[i])) {
11897 result = JIM_ERR;
11898 }
11899 }
11900 if (result != JIM_OK) {
11901 Jim_SetResultString(interp, "foreach varlist is empty", -1);
11902 goto empty_varlist;
11903 }
11904
11905 if (doMap) {
11906 resultObj = Jim_NewListObj(interp, NULL, 0);
11907 }
11908 else {
11909 resultObj = interp->emptyObj;
11910 }
11911 Jim_IncrRefCount(resultObj);
11912
11913 while (1) {
11914 /* Have we expired all lists? */
11915 for (i = 0; i < numargs; i += 2) {
11916 if (!JimListIterDone(interp, &iters[i + 1])) {
11917 break;
11918 }
11919 }
11920 if (i == numargs) {
11921 /* All done */
11922 break;
11923 }
11924
11925 /* For each list */
11926 for (i = 0; i < numargs; i += 2) {
11927 Jim_Obj *varName;
11928
11929 /* foreach var */
11930 JimListIterInit(&iters[i], argv[i + 1]);
11931 while ((varName = JimListIterNext(interp, &iters[i])) != NULL) {
11932 Jim_Obj *valObj = JimListIterNext(interp, &iters[i + 1]);
11933 if (!valObj) {
11934 /* Ran out, so store the empty string */
11935 valObj = interp->emptyObj;
11936 }
11937 /* Avoid shimmering */
11938 Jim_IncrRefCount(valObj);
11939 result = Jim_SetVariable(interp, varName, valObj);
11940 Jim_DecrRefCount(interp, valObj);
11941 if (result != JIM_OK) {
11942 goto err;
11943 }
11944 }
11945 }
11946 switch (result = Jim_EvalObj(interp, script)) {
11947 case JIM_OK:
11948 if (doMap) {
11949 Jim_ListAppendElement(interp, resultObj, interp->result);
11950 }
11951 break;
11952 case JIM_CONTINUE:
11953 break;
11954 case JIM_BREAK:
11955 goto out;
11956 default:
11957 goto err;
11958 }
11959 }
11960 out:
11961 result = JIM_OK;
11962 Jim_SetResult(interp, resultObj);
11963 err:
11964 Jim_DecrRefCount(interp, resultObj);
11965 empty_varlist:
11966 if (numargs > 2) {
11967 Jim_Free(iters);
11968 }
11969 return result;
11970 }
11971
11972 /* [foreach] */
11973 static int Jim_ForeachCoreCommand(Jim_Interp *interp, int argc, Jim_Obj *const *argv)
11974 {
11975 return JimForeachMapHelper(interp, argc, argv, 0);
11976 }
11977
11978 /* [lmap] */
11979 static int Jim_LmapCoreCommand(Jim_Interp *interp, int argc, Jim_Obj *const *argv)
11980 {
11981 return JimForeachMapHelper(interp, argc, argv, 1);
11982 }
11983
11984 /* [lassign] */
11985 static int Jim_LassignCoreCommand(Jim_Interp *interp, int argc, Jim_Obj *const *argv)
11986 {
11987 int result = JIM_ERR;
11988 int i;
11989 Jim_ListIter iter;
11990 Jim_Obj *resultObj;
11991
11992 if (argc < 2) {
11993 Jim_WrongNumArgs(interp, 1, argv, "varList list ?varName ...?");
11994 return JIM_ERR;
11995 }
11996
11997 JimListIterInit(&iter, argv[1]);
11998
11999 for (i = 2; i < argc; i++) {
12000 Jim_Obj *valObj = JimListIterNext(interp, &iter);
12001 result = Jim_SetVariable(interp, argv[i], valObj ? valObj : interp->emptyObj);
12002 if (result != JIM_OK) {
12003 return result;
12004 }
12005 }
12006
12007 resultObj = Jim_NewListObj(interp, NULL, 0);
12008 while (!JimListIterDone(interp, &iter)) {
12009 Jim_ListAppendElement(interp, resultObj, JimListIterNext(interp, &iter));
12010 }
12011
12012 Jim_SetResult(interp, resultObj);
12013
12014 return JIM_OK;
12015 }
12016
12017 /* [if] */
12018 static int Jim_IfCoreCommand(Jim_Interp *interp, int argc, Jim_Obj *const *argv)
12019 {
12020 int boolean, retval, current = 1, falsebody = 0;
12021
12022 if (argc >= 3) {
12023 while (1) {
12024 /* Far not enough arguments given! */
12025 if (current >= argc)
12026 goto err;
12027 if ((retval = Jim_GetBoolFromExpr(interp, argv[current++], &boolean))
12028 != JIM_OK)
12029 return retval;
12030 /* There lacks something, isn't it? */
12031 if (current >= argc)
12032 goto err;
12033 if (Jim_CompareStringImmediate(interp, argv[current], "then"))
12034 current++;
12035 /* Tsk tsk, no then-clause? */
12036 if (current >= argc)
12037 goto err;
12038 if (boolean)
12039 return Jim_EvalObj(interp, argv[current]);
12040 /* Ok: no else-clause follows */
12041 if (++current >= argc) {
12042 Jim_SetResult(interp, Jim_NewEmptyStringObj(interp));
12043 return JIM_OK;
12044 }
12045 falsebody = current++;
12046 if (Jim_CompareStringImmediate(interp, argv[falsebody], "else")) {
12047 /* IIICKS - else-clause isn't last cmd? */
12048 if (current != argc - 1)
12049 goto err;
12050 return Jim_EvalObj(interp, argv[current]);
12051 }
12052 else if (Jim_CompareStringImmediate(interp, argv[falsebody], "elseif"))
12053 /* Ok: elseif follows meaning all the stuff
12054 * again (how boring...) */
12055 continue;
12056 /* OOPS - else-clause is not last cmd? */
12057 else if (falsebody != argc - 1)
12058 goto err;
12059 return Jim_EvalObj(interp, argv[falsebody]);
12060 }
12061 return JIM_OK;
12062 }
12063 err:
12064 Jim_WrongNumArgs(interp, 1, argv, "condition ?then? trueBody ?elseif ...? ?else? falseBody");
12065 return JIM_ERR;
12066 }
12067
12068
12069 /* Returns 1 if match, 0 if no match or -<error> on error (e.g. -JIM_ERR, -JIM_BREAK)*/
12070 int Jim_CommandMatchObj(Jim_Interp *interp, Jim_Obj *commandObj, Jim_Obj *patternObj,
12071 Jim_Obj *stringObj, int nocase)
12072 {
12073 Jim_Obj *parms[4];
12074 int argc = 0;
12075 long eq;
12076 int rc;
12077
12078 parms[argc++] = commandObj;
12079 if (nocase) {
12080 parms[argc++] = Jim_NewStringObj(interp, "-nocase", -1);
12081 }
12082 parms[argc++] = patternObj;
12083 parms[argc++] = stringObj;
12084
12085 rc = Jim_EvalObjVector(interp, argc, parms);
12086
12087 if (rc != JIM_OK || Jim_GetLong(interp, Jim_GetResult(interp), &eq) != JIM_OK) {
12088 eq = -rc;
12089 }
12090
12091 return eq;
12092 }
12093
12094 /* [switch] */
12095 static int Jim_SwitchCoreCommand(Jim_Interp *interp, int argc, Jim_Obj *const *argv)
12096 {
12097 enum { SWITCH_EXACT, SWITCH_GLOB, SWITCH_RE, SWITCH_CMD };
12098 int matchOpt = SWITCH_EXACT, opt = 1, patCount, i;
12099 Jim_Obj *command = NULL, *scriptObj = NULL, *strObj;
12100 Jim_Obj **caseList;
12101
12102 if (argc < 3) {
12103 wrongnumargs:
12104 Jim_WrongNumArgs(interp, 1, argv, "?options? string "
12105 "pattern body ... ?default body? or " "{pattern body ?pattern body ...?}");
12106 return JIM_ERR;
12107 }
12108 for (opt = 1; opt < argc; ++opt) {
12109 const char *option = Jim_String(argv[opt]);
12110
12111 if (*option != '-')
12112 break;
12113 else if (strncmp(option, "--", 2) == 0) {
12114 ++opt;
12115 break;
12116 }
12117 else if (strncmp(option, "-exact", 2) == 0)
12118 matchOpt = SWITCH_EXACT;
12119 else if (strncmp(option, "-glob", 2) == 0)
12120 matchOpt = SWITCH_GLOB;
12121 else if (strncmp(option, "-regexp", 2) == 0)
12122 matchOpt = SWITCH_RE;
12123 else if (strncmp(option, "-command", 2) == 0) {
12124 matchOpt = SWITCH_CMD;
12125 if ((argc - opt) < 2)
12126 goto wrongnumargs;
12127 command = argv[++opt];
12128 }
12129 else {
12130 Jim_SetResultFormatted(interp,
12131 "bad option \"%#s\": must be -exact, -glob, -regexp, -command procname or --",
12132 argv[opt]);
12133 return JIM_ERR;
12134 }
12135 if ((argc - opt) < 2)
12136 goto wrongnumargs;
12137 }
12138 strObj = argv[opt++];
12139 patCount = argc - opt;
12140 if (patCount == 1) {
12141 JimListGetElements(interp, argv[opt], &patCount, &caseList);
12142 }
12143 else
12144 caseList = (Jim_Obj **)&argv[opt];
12145 if (patCount == 0 || patCount % 2 != 0)
12146 goto wrongnumargs;
12147 for (i = 0; scriptObj == NULL && i < patCount; i += 2) {
12148 Jim_Obj *patObj = caseList[i];
12149
12150 if (!Jim_CompareStringImmediate(interp, patObj, "default")
12151 || i < (patCount - 2)) {
12152 switch (matchOpt) {
12153 case SWITCH_EXACT:
12154 if (Jim_StringEqObj(strObj, patObj))
12155 scriptObj = caseList[i + 1];
12156 break;
12157 case SWITCH_GLOB:
12158 if (Jim_StringMatchObj(interp, patObj, strObj, 0))
12159 scriptObj = caseList[i + 1];
12160 break;
12161 case SWITCH_RE:
12162 command = Jim_NewStringObj(interp, "regexp", -1);
12163 /* Fall thru intentionally */
12164 case SWITCH_CMD:{
12165 int rc = Jim_CommandMatchObj(interp, command, patObj, strObj, 0);
12166
12167 /* After the execution of a command we need to
12168 * make sure to reconvert the object into a list
12169 * again. Only for the single-list style [switch]. */
12170 if (argc - opt == 1) {
12171 JimListGetElements(interp, argv[opt], &patCount, &caseList);
12172 }
12173 /* command is here already decref'd */
12174 if (rc < 0) {
12175 return -rc;
12176 }
12177 if (rc)
12178 scriptObj = caseList[i + 1];
12179 break;
12180 }
12181 }
12182 }
12183 else {
12184 scriptObj = caseList[i + 1];
12185 }
12186 }
12187 for (; i < patCount && Jim_CompareStringImmediate(interp, scriptObj, "-"); i += 2)
12188 scriptObj = caseList[i + 1];
12189 if (scriptObj && Jim_CompareStringImmediate(interp, scriptObj, "-")) {
12190 Jim_SetResultFormatted(interp, "no body specified for pattern \"%#s\"", caseList[i - 2]);
12191 return JIM_ERR;
12192 }
12193 Jim_SetEmptyResult(interp);
12194 if (scriptObj) {
12195 return Jim_EvalObj(interp, scriptObj);
12196 }
12197 return JIM_OK;
12198 }
12199
12200 /* [list] */
12201 static int Jim_ListCoreCommand(Jim_Interp *interp, int argc, Jim_Obj *const *argv)
12202 {
12203 Jim_Obj *listObjPtr;
12204
12205 listObjPtr = Jim_NewListObj(interp, argv + 1, argc - 1);
12206 Jim_SetResult(interp, listObjPtr);
12207 return JIM_OK;
12208 }
12209
12210 /* [lindex] */
12211 static int Jim_LindexCoreCommand(Jim_Interp *interp, int argc, Jim_Obj *const *argv)
12212 {
12213 Jim_Obj *objPtr, *listObjPtr;
12214 int i;
12215 int idx;
12216
12217 if (argc < 2) {
12218 Jim_WrongNumArgs(interp, 1, argv, "list ?index ...?");
12219 return JIM_ERR;
12220 }
12221 objPtr = argv[1];
12222 Jim_IncrRefCount(objPtr);
12223 for (i = 2; i < argc; i++) {
12224 listObjPtr = objPtr;
12225 if (Jim_GetIndex(interp, argv[i], &idx) != JIM_OK) {
12226 Jim_DecrRefCount(interp, listObjPtr);
12227 return JIM_ERR;
12228 }
12229 if (Jim_ListIndex(interp, listObjPtr, idx, &objPtr, JIM_NONE) != JIM_OK) {
12230 /* Returns an empty object if the index
12231 * is out of range. */
12232 Jim_DecrRefCount(interp, listObjPtr);
12233 Jim_SetEmptyResult(interp);
12234 return JIM_OK;
12235 }
12236 Jim_IncrRefCount(objPtr);
12237 Jim_DecrRefCount(interp, listObjPtr);
12238 }
12239 Jim_SetResult(interp, objPtr);
12240 Jim_DecrRefCount(interp, objPtr);
12241 return JIM_OK;
12242 }
12243
12244 /* [llength] */
12245 static int Jim_LlengthCoreCommand(Jim_Interp *interp, int argc, Jim_Obj *const *argv)
12246 {
12247 if (argc != 2) {
12248 Jim_WrongNumArgs(interp, 1, argv, "list");
12249 return JIM_ERR;
12250 }
12251 Jim_SetResultInt(interp, Jim_ListLength(interp, argv[1]));
12252 return JIM_OK;
12253 }
12254
12255 /* [lsearch] */
12256 static int Jim_LsearchCoreCommand(Jim_Interp *interp, int argc, Jim_Obj *const *argv)
12257 {
12258 static const char * const options[] = {
12259 "-bool", "-not", "-nocase", "-exact", "-glob", "-regexp", "-all", "-inline", "-command",
12260 NULL
12261 };
12262 enum
12263 { OPT_BOOL, OPT_NOT, OPT_NOCASE, OPT_EXACT, OPT_GLOB, OPT_REGEXP, OPT_ALL, OPT_INLINE,
12264 OPT_COMMAND };
12265 int i;
12266 int opt_bool = 0;
12267 int opt_not = 0;
12268 int opt_nocase = 0;
12269 int opt_all = 0;
12270 int opt_inline = 0;
12271 int opt_match = OPT_EXACT;
12272 int listlen;
12273 int rc = JIM_OK;
12274 Jim_Obj *listObjPtr = NULL;
12275 Jim_Obj *commandObj = NULL;
12276
12277 if (argc < 3) {
12278 wrongargs:
12279 Jim_WrongNumArgs(interp, 1, argv,
12280 "?-exact|-glob|-regexp|-command 'command'? ?-bool|-inline? ?-not? ?-nocase? ?-all? list value");
12281 return JIM_ERR;
12282 }
12283
12284 for (i = 1; i < argc - 2; i++) {
12285 int option;
12286
12287 if (Jim_GetEnum(interp, argv[i], options, &option, NULL, JIM_ERRMSG) != JIM_OK) {
12288 return JIM_ERR;
12289 }
12290 switch (option) {
12291 case OPT_BOOL:
12292 opt_bool = 1;
12293 opt_inline = 0;
12294 break;
12295 case OPT_NOT:
12296 opt_not = 1;
12297 break;
12298 case OPT_NOCASE:
12299 opt_nocase = 1;
12300 break;
12301 case OPT_INLINE:
12302 opt_inline = 1;
12303 opt_bool = 0;
12304 break;
12305 case OPT_ALL:
12306 opt_all = 1;
12307 break;
12308 case OPT_COMMAND:
12309 if (i >= argc - 2) {
12310 goto wrongargs;
12311 }
12312 commandObj = argv[++i];
12313 /* fallthru */
12314 case OPT_EXACT:
12315 case OPT_GLOB:
12316 case OPT_REGEXP:
12317 opt_match = option;
12318 break;
12319 }
12320 }
12321
12322 argv += i;
12323
12324 if (opt_all) {
12325 listObjPtr = Jim_NewListObj(interp, NULL, 0);
12326 }
12327 if (opt_match == OPT_REGEXP) {
12328 commandObj = Jim_NewStringObj(interp, "regexp", -1);
12329 }
12330 if (commandObj) {
12331 Jim_IncrRefCount(commandObj);
12332 }
12333
12334 listlen = Jim_ListLength(interp, argv[0]);
12335 for (i = 0; i < listlen; i++) {
12336 int eq = 0;
12337 Jim_Obj *objPtr = Jim_ListGetIndex(interp, argv[0], i);
12338
12339 switch (opt_match) {
12340 case OPT_EXACT:
12341 eq = Jim_StringCompareObj(interp, argv[1], objPtr, opt_nocase) == 0;
12342 break;
12343
12344 case OPT_GLOB:
12345 eq = Jim_StringMatchObj(interp, argv[1], objPtr, opt_nocase);
12346 break;
12347
12348 case OPT_REGEXP:
12349 case OPT_COMMAND:
12350 eq = Jim_CommandMatchObj(interp, commandObj, argv[1], objPtr, opt_nocase);
12351 if (eq < 0) {
12352 if (listObjPtr) {
12353 Jim_FreeNewObj(interp, listObjPtr);
12354 }
12355 rc = JIM_ERR;
12356 goto done;
12357 }
12358 break;
12359 }
12360
12361 /* If we have a non-match with opt_bool, opt_not, !opt_all, can't exit early */
12362 if (!eq && opt_bool && opt_not && !opt_all) {
12363 continue;
12364 }
12365
12366 if ((!opt_bool && eq == !opt_not) || (opt_bool && (eq || opt_all))) {
12367 /* Got a match (or non-match for opt_not), or (opt_bool && opt_all) */
12368 Jim_Obj *resultObj;
12369
12370 if (opt_bool) {
12371 resultObj = Jim_NewIntObj(interp, eq ^ opt_not);
12372 }
12373 else if (!opt_inline) {
12374 resultObj = Jim_NewIntObj(interp, i);
12375 }
12376 else {
12377 resultObj = objPtr;
12378 }
12379
12380 if (opt_all) {
12381 Jim_ListAppendElement(interp, listObjPtr, resultObj);
12382 }
12383 else {
12384 Jim_SetResult(interp, resultObj);
12385 goto done;
12386 }
12387 }
12388 }
12389
12390 if (opt_all) {
12391 Jim_SetResult(interp, listObjPtr);
12392 }
12393 else {
12394 /* No match */
12395 if (opt_bool) {
12396 Jim_SetResultBool(interp, opt_not);
12397 }
12398 else if (!opt_inline) {
12399 Jim_SetResultInt(interp, -1);
12400 }
12401 }
12402
12403 done:
12404 if (commandObj) {
12405 Jim_DecrRefCount(interp, commandObj);
12406 }
12407 return rc;
12408 }
12409
12410 /* [lappend] */
12411 static int Jim_LappendCoreCommand(Jim_Interp *interp, int argc, Jim_Obj *const *argv)
12412 {
12413 Jim_Obj *listObjPtr;
12414 int new_obj = 0;
12415 int i;
12416
12417 if (argc < 2) {
12418 Jim_WrongNumArgs(interp, 1, argv, "varName ?value value ...?");
12419 return JIM_ERR;
12420 }
12421 listObjPtr = Jim_GetVariable(interp, argv[1], JIM_UNSHARED);
12422 if (!listObjPtr) {
12423 /* Create the list if it does not exist */
12424 listObjPtr = Jim_NewListObj(interp, NULL, 0);
12425 new_obj = 1;
12426 }
12427 else if (Jim_IsShared(listObjPtr)) {
12428 listObjPtr = Jim_DuplicateObj(interp, listObjPtr);
12429 new_obj = 1;
12430 }
12431 for (i = 2; i < argc; i++)
12432 Jim_ListAppendElement(interp, listObjPtr, argv[i]);
12433 if (Jim_SetVariable(interp, argv[1], listObjPtr) != JIM_OK) {
12434 if (new_obj)
12435 Jim_FreeNewObj(interp, listObjPtr);
12436 return JIM_ERR;
12437 }
12438 Jim_SetResult(interp, listObjPtr);
12439 return JIM_OK;
12440 }
12441
12442 /* [linsert] */
12443 static int Jim_LinsertCoreCommand(Jim_Interp *interp, int argc, Jim_Obj *const *argv)
12444 {
12445 int idx, len;
12446 Jim_Obj *listPtr;
12447
12448 if (argc < 3) {
12449 Jim_WrongNumArgs(interp, 1, argv, "list index ?element ...?");
12450 return JIM_ERR;
12451 }
12452 listPtr = argv[1];
12453 if (Jim_IsShared(listPtr))
12454 listPtr = Jim_DuplicateObj(interp, listPtr);
12455 if (Jim_GetIndex(interp, argv[2], &idx) != JIM_OK)
12456 goto err;
12457 len = Jim_ListLength(interp, listPtr);
12458 if (idx >= len)
12459 idx = len;
12460 else if (idx < 0)
12461 idx = len + idx + 1;
12462 Jim_ListInsertElements(interp, listPtr, idx, argc - 3, &argv[3]);
12463 Jim_SetResult(interp, listPtr);
12464 return JIM_OK;
12465 err:
12466 if (listPtr != argv[1]) {
12467 Jim_FreeNewObj(interp, listPtr);
12468 }
12469 return JIM_ERR;
12470 }
12471
12472 /* [lreplace] */
12473 static int Jim_LreplaceCoreCommand(Jim_Interp *interp, int argc, Jim_Obj *const *argv)
12474 {
12475 int first, last, len, rangeLen;
12476 Jim_Obj *listObj;
12477 Jim_Obj *newListObj;
12478
12479 if (argc < 4) {
12480 Jim_WrongNumArgs(interp, 1, argv, "list first last ?element ...?");
12481 return JIM_ERR;
12482 }
12483 if (Jim_GetIndex(interp, argv[2], &first) != JIM_OK ||
12484 Jim_GetIndex(interp, argv[3], &last) != JIM_OK) {
12485 return JIM_ERR;
12486 }
12487
12488 listObj = argv[1];
12489 len = Jim_ListLength(interp, listObj);
12490
12491 first = JimRelToAbsIndex(len, first);
12492 last = JimRelToAbsIndex(len, last);
12493 JimRelToAbsRange(len, &first, &last, &rangeLen);
12494
12495 /* Now construct a new list which consists of:
12496 * <elements before first> <supplied elements> <elements after last>
12497 */
12498
12499 /* Check to see if trying to replace past the end of the list */
12500 if (first < len) {
12501 /* OK. Not past the end */
12502 }
12503 else if (len == 0) {
12504 /* Special for empty list, adjust first to 0 */
12505 first = 0;
12506 }
12507 else {
12508 Jim_SetResultString(interp, "list doesn't contain element ", -1);
12509 Jim_AppendObj(interp, Jim_GetResult(interp), argv[2]);
12510 return JIM_ERR;
12511 }
12512
12513 /* Add the first set of elements */
12514 newListObj = Jim_NewListObj(interp, listObj->internalRep.listValue.ele, first);
12515
12516 /* Add supplied elements */
12517 ListInsertElements(newListObj, -1, argc - 4, argv + 4);
12518
12519 /* Add the remaining elements */
12520 ListInsertElements(newListObj, -1, len - first - rangeLen, listObj->internalRep.listValue.ele + first + rangeLen);
12521
12522 Jim_SetResult(interp, newListObj);
12523 return JIM_OK;
12524 }
12525
12526 /* [lset] */
12527 static int Jim_LsetCoreCommand(Jim_Interp *interp, int argc, Jim_Obj *const *argv)
12528 {
12529 if (argc < 3) {
12530 Jim_WrongNumArgs(interp, 1, argv, "listVar ?index...? newVal");
12531 return JIM_ERR;
12532 }
12533 else if (argc == 3) {
12534 /* With no indexes, simply implements [set] */
12535 if (Jim_SetVariable(interp, argv[1], argv[2]) != JIM_OK)
12536 return JIM_ERR;
12537 Jim_SetResult(interp, argv[2]);
12538 return JIM_OK;
12539 }
12540 return Jim_ListSetIndex(interp, argv[1], argv + 2, argc - 3, argv[argc - 1]);
12541 }
12542
12543 /* [lsort] */
12544 static int Jim_LsortCoreCommand(Jim_Interp *interp, int argc, Jim_Obj *const argv[])
12545 {
12546 static const char * const options[] = {
12547 "-ascii", "-nocase", "-increasing", "-decreasing", "-command", "-integer", "-real", "-index", "-unique", NULL
12548 };
12549 enum
12550 { OPT_ASCII, OPT_NOCASE, OPT_INCREASING, OPT_DECREASING, OPT_COMMAND, OPT_INTEGER, OPT_REAL, OPT_INDEX, OPT_UNIQUE };
12551 Jim_Obj *resObj;
12552 int i;
12553 int retCode;
12554 int shared;
12555
12556 struct lsort_info info;
12557
12558 if (argc < 2) {
12559 Jim_WrongNumArgs(interp, 1, argv, "?options? list");
12560 return JIM_ERR;
12561 }
12562
12563 info.type = JIM_LSORT_ASCII;
12564 info.order = 1;
12565 info.indexed = 0;
12566 info.unique = 0;
12567 info.command = NULL;
12568 info.interp = interp;
12569
12570 for (i = 1; i < (argc - 1); i++) {
12571 int option;
12572
12573 if (Jim_GetEnum(interp, argv[i], options, &option, NULL, JIM_ENUM_ABBREV | JIM_ERRMSG)
12574 != JIM_OK)
12575 return JIM_ERR;
12576 switch (option) {
12577 case OPT_ASCII:
12578 info.type = JIM_LSORT_ASCII;
12579 break;
12580 case OPT_NOCASE:
12581 info.type = JIM_LSORT_NOCASE;
12582 break;
12583 case OPT_INTEGER:
12584 info.type = JIM_LSORT_INTEGER;
12585 break;
12586 case OPT_REAL:
12587 info.type = JIM_LSORT_REAL;
12588 break;
12589 case OPT_INCREASING:
12590 info.order = 1;
12591 break;
12592 case OPT_DECREASING:
12593 info.order = -1;
12594 break;
12595 case OPT_UNIQUE:
12596 info.unique = 1;
12597 break;
12598 case OPT_COMMAND:
12599 if (i >= (argc - 2)) {
12600 Jim_SetResultString(interp, "\"-command\" option must be followed by comparison command", -1);
12601 return JIM_ERR;
12602 }
12603 info.type = JIM_LSORT_COMMAND;
12604 info.command = argv[i + 1];
12605 i++;
12606 break;
12607 case OPT_INDEX:
12608 if (i >= (argc - 2)) {
12609 Jim_SetResultString(interp, "\"-index\" option must be followed by list index", -1);
12610 return JIM_ERR;
12611 }
12612 if (Jim_GetIndex(interp, argv[i + 1], &info.index) != JIM_OK) {
12613 return JIM_ERR;
12614 }
12615 info.indexed = 1;
12616 i++;
12617 break;
12618 }
12619 }
12620 resObj = argv[argc - 1];
12621 if ((shared = Jim_IsShared(resObj)))
12622 resObj = Jim_DuplicateObj(interp, resObj);
12623 retCode = ListSortElements(interp, resObj, &info);
12624 if (retCode == JIM_OK) {
12625 Jim_SetResult(interp, resObj);
12626 }
12627 else if (shared) {
12628 Jim_FreeNewObj(interp, resObj);
12629 }
12630 return retCode;
12631 }
12632
12633 /* [append] */
12634 static int Jim_AppendCoreCommand(Jim_Interp *interp, int argc, Jim_Obj *const *argv)
12635 {
12636 Jim_Obj *stringObjPtr;
12637 int i;
12638
12639 if (argc < 2) {
12640 Jim_WrongNumArgs(interp, 1, argv, "varName ?value ...?");
12641 return JIM_ERR;
12642 }
12643 if (argc == 2) {
12644 stringObjPtr = Jim_GetVariable(interp, argv[1], JIM_ERRMSG);
12645 if (!stringObjPtr)
12646 return JIM_ERR;
12647 }
12648 else {
12649 int new_obj = 0;
12650 stringObjPtr = Jim_GetVariable(interp, argv[1], JIM_UNSHARED);
12651 if (!stringObjPtr) {
12652 /* Create the string if it doesn't exist */
12653 stringObjPtr = Jim_NewEmptyStringObj(interp);
12654 new_obj = 1;
12655 }
12656 else if (Jim_IsShared(stringObjPtr)) {
12657 new_obj = 1;
12658 stringObjPtr = Jim_DuplicateObj(interp, stringObjPtr);
12659 }
12660 for (i = 2; i < argc; i++) {
12661 Jim_AppendObj(interp, stringObjPtr, argv[i]);
12662 }
12663 if (Jim_SetVariable(interp, argv[1], stringObjPtr) != JIM_OK) {
12664 if (new_obj) {
12665 Jim_FreeNewObj(interp, stringObjPtr);
12666 }
12667 return JIM_ERR;
12668 }
12669 }
12670 Jim_SetResult(interp, stringObjPtr);
12671 return JIM_OK;
12672 }
12673
12674 #if defined(JIM_DEBUG_COMMAND) && !defined(JIM_BOOTSTRAP)
12675 /**
12676 * Returns a zero-refcount list describing the expression at 'node'
12677 */
12678 static Jim_Obj *JimGetExprAsList(Jim_Interp *interp, struct JimExprNode *node)
12679 {
12680 Jim_Obj *listObjPtr = Jim_NewListObj(interp, NULL, 0);
12681
12682 Jim_ListAppendElement(interp, listObjPtr, Jim_NewStringObj(interp, jim_tt_name(node->type), -1));
12683 if (TOKEN_IS_EXPR_OP(node->type)) {
12684 if (node->left) {
12685 Jim_ListAppendElement(interp, listObjPtr, JimGetExprAsList(interp, node->left));
12686 }
12687 if (node->right) {
12688 Jim_ListAppendElement(interp, listObjPtr, JimGetExprAsList(interp, node->right));
12689 }
12690 if (node->ternary) {
12691 Jim_ListAppendElement(interp, listObjPtr, JimGetExprAsList(interp, node->ternary));
12692 }
12693 }
12694 else {
12695 Jim_ListAppendElement(interp, listObjPtr, node->objPtr);
12696 }
12697 return listObjPtr;
12698 }
12699 #endif /* JIM_DEBUG_COMMAND && !JIM_BOOTSTRAP */
12700
12701 /* [debug] */
12702 static int Jim_DebugCoreCommand(Jim_Interp *interp, int argc, Jim_Obj *const *argv)
12703 {
12704 #if defined(JIM_DEBUG_COMMAND) && !defined(JIM_BOOTSTRAP)
12705 static const char * const options[] = {
12706 "refcount", "objcount", "objects", "invstr", "scriptlen", "exprlen",
12707 "exprbc", "show",
12708 NULL
12709 };
12710 enum
12711 {
12712 OPT_REFCOUNT, OPT_OBJCOUNT, OPT_OBJECTS, OPT_INVSTR, OPT_SCRIPTLEN,
12713 OPT_EXPRLEN, OPT_EXPRBC, OPT_SHOW,
12714 };
12715 int option;
12716
12717 if (argc < 2) {
12718 Jim_WrongNumArgs(interp, 1, argv, "subcommand ?...?");
12719 return JIM_ERR;
12720 }
12721 if (Jim_GetEnum(interp, argv[1], options, &option, "subcommand", JIM_ERRMSG) != JIM_OK)
12722 return Jim_CheckShowCommands(interp, argv[1], options);
12723 if (option == OPT_REFCOUNT) {
12724 if (argc != 3) {
12725 Jim_WrongNumArgs(interp, 2, argv, "object");
12726 return JIM_ERR;
12727 }
12728 Jim_SetResultInt(interp, argv[2]->refCount);
12729 return JIM_OK;
12730 }
12731 else if (option == OPT_OBJCOUNT) {
12732 int freeobj = 0, liveobj = 0;
12733 char buf[256];
12734 Jim_Obj *objPtr;
12735
12736 if (argc != 2) {
12737 Jim_WrongNumArgs(interp, 2, argv, "");
12738 return JIM_ERR;
12739 }
12740 /* Count the number of free objects. */
12741 objPtr = interp->freeList;
12742 while (objPtr) {
12743 freeobj++;
12744 objPtr = objPtr->nextObjPtr;
12745 }
12746 /* Count the number of live objects. */
12747 objPtr = interp->liveList;
12748 while (objPtr) {
12749 liveobj++;
12750 objPtr = objPtr->nextObjPtr;
12751 }
12752 /* Set the result string and return. */
12753 sprintf(buf, "free %d used %d", freeobj, liveobj);
12754 Jim_SetResultString(interp, buf, -1);
12755 return JIM_OK;
12756 }
12757 else if (option == OPT_OBJECTS) {
12758 Jim_Obj *objPtr, *listObjPtr, *subListObjPtr;
12759
12760 /* Count the number of live objects. */
12761 objPtr = interp->liveList;
12762 listObjPtr = Jim_NewListObj(interp, NULL, 0);
12763 while (objPtr) {
12764 char buf[128];
12765 const char *type = objPtr->typePtr ? objPtr->typePtr->name : "";
12766
12767 subListObjPtr = Jim_NewListObj(interp, NULL, 0);
12768 sprintf(buf, "%p", objPtr);
12769 Jim_ListAppendElement(interp, subListObjPtr, Jim_NewStringObj(interp, buf, -1));
12770 Jim_ListAppendElement(interp, subListObjPtr, Jim_NewStringObj(interp, type, -1));
12771 Jim_ListAppendElement(interp, subListObjPtr, Jim_NewIntObj(interp, objPtr->refCount));
12772 Jim_ListAppendElement(interp, subListObjPtr, objPtr);
12773 Jim_ListAppendElement(interp, listObjPtr, subListObjPtr);
12774 objPtr = objPtr->nextObjPtr;
12775 }
12776 Jim_SetResult(interp, listObjPtr);
12777 return JIM_OK;
12778 }
12779 else if (option == OPT_INVSTR) {
12780 Jim_Obj *objPtr;
12781
12782 if (argc != 3) {
12783 Jim_WrongNumArgs(interp, 2, argv, "object");
12784 return JIM_ERR;
12785 }
12786 objPtr = argv[2];
12787 if (objPtr->typePtr != NULL)
12788 Jim_InvalidateStringRep(objPtr);
12789 Jim_SetEmptyResult(interp);
12790 return JIM_OK;
12791 }
12792 else if (option == OPT_SHOW) {
12793 const char *s;
12794 int len, charlen;
12795
12796 if (argc != 3) {
12797 Jim_WrongNumArgs(interp, 2, argv, "object");
12798 return JIM_ERR;
12799 }
12800 s = Jim_GetString(argv[2], &len);
12801 #ifdef JIM_UTF8
12802 charlen = utf8_strlen(s, len);
12803 #else
12804 charlen = len;
12805 #endif
12806 printf("refcount: %d, type: %s\n", argv[2]->refCount, JimObjTypeName(argv[2]));
12807 printf("chars (%d): <<%s>>\n", charlen, s);
12808 printf("bytes (%d):", len);
12809 while (len--) {
12810 printf(" %02x", (unsigned char)*s++);
12811 }
12812 printf("\n");
12813 return JIM_OK;
12814 }
12815 else if (option == OPT_SCRIPTLEN) {
12816 ScriptObj *script;
12817
12818 if (argc != 3) {
12819 Jim_WrongNumArgs(interp, 2, argv, "script");
12820 return JIM_ERR;
12821 }
12822 script = JimGetScript(interp, argv[2]);
12823 if (script == NULL)
12824 return JIM_ERR;
12825 Jim_SetResultInt(interp, script->len);
12826 return JIM_OK;
12827 }
12828 else if (option == OPT_EXPRLEN) {
12829 struct ExprTree *expr;
12830
12831 if (argc != 3) {
12832 Jim_WrongNumArgs(interp, 2, argv, "expression");
12833 return JIM_ERR;
12834 }
12835 expr = JimGetExpression(interp, argv[2]);
12836 if (expr == NULL)
12837 return JIM_ERR;
12838 Jim_SetResultInt(interp, expr->len);
12839 return JIM_OK;
12840 }
12841 else if (option == OPT_EXPRBC) {
12842 struct ExprTree *expr;
12843
12844 if (argc != 3) {
12845 Jim_WrongNumArgs(interp, 2, argv, "expression");
12846 return JIM_ERR;
12847 }
12848 expr = JimGetExpression(interp, argv[2]);
12849 if (expr == NULL)
12850 return JIM_ERR;
12851 Jim_SetResult(interp, JimGetExprAsList(interp, expr->expr));
12852 return JIM_OK;
12853 }
12854 else {
12855 Jim_SetResultString(interp,
12856 "bad option. Valid options are refcount, " "objcount, objects, invstr", -1);
12857 return JIM_ERR;
12858 }
12859 /* unreached */
12860 #endif /* JIM_DEBUG_COMMAND && !JIM_BOOTSTRAP */
12861 #if !defined(JIM_DEBUG_COMMAND)
12862 Jim_SetResultString(interp, "unsupported", -1);
12863 return JIM_ERR;
12864 #endif
12865 }
12866
12867 /* [eval] */
12868 static int Jim_EvalCoreCommand(Jim_Interp *interp, int argc, Jim_Obj *const *argv)
12869 {
12870 int rc;
12871
12872 if (argc < 2) {
12873 Jim_WrongNumArgs(interp, 1, argv, "arg ?arg ...?");
12874 return JIM_ERR;
12875 }
12876
12877 if (argc == 2) {
12878 rc = Jim_EvalObj(interp, argv[1]);
12879 }
12880 else {
12881 rc = Jim_EvalObj(interp, Jim_ConcatObj(interp, argc - 1, argv + 1));
12882 }
12883
12884 if (rc == JIM_ERR) {
12885 /* eval is "interesting", so add a stack frame here */
12886 interp->addStackTrace++;
12887 }
12888 return rc;
12889 }
12890
12891 /* [uplevel] */
12892 static int Jim_UplevelCoreCommand(Jim_Interp *interp, int argc, Jim_Obj *const *argv)
12893 {
12894 if (argc >= 2) {
12895 int retcode;
12896 Jim_CallFrame *savedCallFrame, *targetCallFrame;
12897 const char *str;
12898
12899 /* Save the old callframe pointer */
12900 savedCallFrame = interp->framePtr;
12901
12902 /* Lookup the target frame pointer */
12903 str = Jim_String(argv[1]);
12904 if ((str[0] >= '0' && str[0] <= '9') || str[0] == '#') {
12905 targetCallFrame = Jim_GetCallFrameByLevel(interp, argv[1]);
12906 argc--;
12907 argv++;
12908 }
12909 else {
12910 targetCallFrame = Jim_GetCallFrameByLevel(interp, NULL);
12911 }
12912 if (targetCallFrame == NULL) {
12913 return JIM_ERR;
12914 }
12915 if (argc < 2) {
12916 Jim_WrongNumArgs(interp, 1, argv - 1, "?level? command ?arg ...?");
12917 return JIM_ERR;
12918 }
12919 /* Eval the code in the target callframe. */
12920 interp->framePtr = targetCallFrame;
12921 if (argc == 2) {
12922 retcode = Jim_EvalObj(interp, argv[1]);
12923 }
12924 else {
12925 retcode = Jim_EvalObj(interp, Jim_ConcatObj(interp, argc - 1, argv + 1));
12926 }
12927 interp->framePtr = savedCallFrame;
12928 return retcode;
12929 }
12930 else {
12931 Jim_WrongNumArgs(interp, 1, argv, "?level? command ?arg ...?");
12932 return JIM_ERR;
12933 }
12934 }
12935
12936 /* [expr] */
12937 static int Jim_ExprCoreCommand(Jim_Interp *interp, int argc, Jim_Obj *const *argv)
12938 {
12939 int retcode;
12940
12941 if (argc == 2) {
12942 retcode = Jim_EvalExpression(interp, argv[1]);
12943 }
12944 else if (argc > 2) {
12945 Jim_Obj *objPtr;
12946
12947 objPtr = Jim_ConcatObj(interp, argc - 1, argv + 1);
12948 Jim_IncrRefCount(objPtr);
12949 retcode = Jim_EvalExpression(interp, objPtr);
12950 Jim_DecrRefCount(interp, objPtr);
12951 }
12952 else {
12953 Jim_WrongNumArgs(interp, 1, argv, "expression ?...?");
12954 return JIM_ERR;
12955 }
12956 if (retcode != JIM_OK)
12957 return retcode;
12958 return JIM_OK;
12959 }
12960
12961 /* [break] */
12962 static int Jim_BreakCoreCommand(Jim_Interp *interp, int argc, Jim_Obj *const *argv)
12963 {
12964 if (argc != 1) {
12965 Jim_WrongNumArgs(interp, 1, argv, "");
12966 return JIM_ERR;
12967 }
12968 return JIM_BREAK;
12969 }
12970
12971 /* [continue] */
12972 static int Jim_ContinueCoreCommand(Jim_Interp *interp, int argc, Jim_Obj *const *argv)
12973 {
12974 if (argc != 1) {
12975 Jim_WrongNumArgs(interp, 1, argv, "");
12976 return JIM_ERR;
12977 }
12978 return JIM_CONTINUE;
12979 }
12980
12981 /* [return] */
12982 static int Jim_ReturnCoreCommand(Jim_Interp *interp, int argc, Jim_Obj *const *argv)
12983 {
12984 int i;
12985 Jim_Obj *stackTraceObj = NULL;
12986 Jim_Obj *errorCodeObj = NULL;
12987 int returnCode = JIM_OK;
12988 long level = 1;
12989
12990 for (i = 1; i < argc - 1; i += 2) {
12991 if (Jim_CompareStringImmediate(interp, argv[i], "-code")) {
12992 if (Jim_GetReturnCode(interp, argv[i + 1], &returnCode) == JIM_ERR) {
12993 return JIM_ERR;
12994 }
12995 }
12996 else if (Jim_CompareStringImmediate(interp, argv[i], "-errorinfo")) {
12997 stackTraceObj = argv[i + 1];
12998 }
12999 else if (Jim_CompareStringImmediate(interp, argv[i], "-errorcode")) {
13000 errorCodeObj = argv[i + 1];
13001 }
13002 else if (Jim_CompareStringImmediate(interp, argv[i], "-level")) {
13003 if (Jim_GetLong(interp, argv[i + 1], &level) != JIM_OK || level < 0) {
13004 Jim_SetResultFormatted(interp, "bad level \"%#s\"", argv[i + 1]);
13005 return JIM_ERR;
13006 }
13007 }
13008 else {
13009 break;
13010 }
13011 }
13012
13013 if (i != argc - 1 && i != argc) {
13014 Jim_WrongNumArgs(interp, 1, argv,
13015 "?-code code? ?-errorinfo stacktrace? ?-level level? ?result?");
13016 }
13017
13018 /* If a stack trace is supplied and code is error, set the stack trace */
13019 if (stackTraceObj && returnCode == JIM_ERR) {
13020 JimSetStackTrace(interp, stackTraceObj);
13021 }
13022 /* If an error code list is supplied, set the global $errorCode */
13023 if (errorCodeObj && returnCode == JIM_ERR) {
13024 Jim_SetGlobalVariableStr(interp, "errorCode", errorCodeObj);
13025 }
13026 interp->returnCode = returnCode;
13027 interp->returnLevel = level;
13028
13029 if (i == argc - 1) {
13030 Jim_SetResult(interp, argv[i]);
13031 }
13032 return JIM_RETURN;
13033 }
13034
13035 /* [tailcall] */
13036 static int Jim_TailcallCoreCommand(Jim_Interp *interp, int argc, Jim_Obj *const *argv)
13037 {
13038 if (interp->framePtr->level == 0) {
13039 Jim_SetResultString(interp, "tailcall can only be called from a proc or lambda", -1);
13040 return JIM_ERR;
13041 }
13042 else if (argc >= 2) {
13043 /* Need to resolve the tailcall command in the current context */
13044 Jim_CallFrame *cf = interp->framePtr->parent;
13045
13046 Jim_Cmd *cmdPtr = Jim_GetCommand(interp, argv[1], JIM_ERRMSG);
13047 if (cmdPtr == NULL) {
13048 return JIM_ERR;
13049 }
13050
13051 JimPanic((cf->tailcallCmd != NULL, "Already have a tailcallCmd"));
13052
13053 /* And stash this pre-resolved command */
13054 JimIncrCmdRefCount(cmdPtr);
13055 cf->tailcallCmd = cmdPtr;
13056
13057 /* And stash the command list */
13058 JimPanic((cf->tailcallObj != NULL, "Already have a tailcallobj"));
13059
13060 cf->tailcallObj = Jim_NewListObj(interp, argv + 1, argc - 1);
13061 Jim_IncrRefCount(cf->tailcallObj);
13062
13063 /* When the stack unwinds to the previous proc, the stashed command will be evaluated */
13064 return JIM_EVAL;
13065 }
13066 return JIM_OK;
13067 }
13068
13069 static int JimAliasCmd(Jim_Interp *interp, int argc, Jim_Obj *const *argv)
13070 {
13071 Jim_Obj *cmdList;
13072 Jim_Obj *prefixListObj = Jim_CmdPrivData(interp);
13073
13074 /* prefixListObj is a list to which the args need to be appended */
13075 cmdList = Jim_DuplicateObj(interp, prefixListObj);
13076 Jim_ListInsertElements(interp, cmdList, Jim_ListLength(interp, cmdList), argc - 1, argv + 1);
13077
13078 return JimEvalObjList(interp, cmdList);
13079 }
13080
13081 static void JimAliasCmdDelete(Jim_Interp *interp, void *privData)
13082 {
13083 Jim_Obj *prefixListObj = privData;
13084 Jim_DecrRefCount(interp, prefixListObj);
13085 }
13086
13087 static int Jim_AliasCoreCommand(Jim_Interp *interp, int argc, Jim_Obj *const *argv)
13088 {
13089 Jim_Obj *prefixListObj;
13090 const char *newname;
13091
13092 if (argc < 3) {
13093 Jim_WrongNumArgs(interp, 1, argv, "newname command ?args ...?");
13094 return JIM_ERR;
13095 }
13096
13097 prefixListObj = Jim_NewListObj(interp, argv + 2, argc - 2);
13098 Jim_IncrRefCount(prefixListObj);
13099 newname = Jim_String(argv[1]);
13100 if (newname[0] == ':' && newname[1] == ':') {
13101 while (*++newname == ':') {
13102 }
13103 }
13104
13105 Jim_SetResult(interp, argv[1]);
13106
13107 return Jim_CreateCommand(interp, newname, JimAliasCmd, prefixListObj, JimAliasCmdDelete);
13108 }
13109
13110 /* [proc] */
13111 static int Jim_ProcCoreCommand(Jim_Interp *interp, int argc, Jim_Obj *const *argv)
13112 {
13113 Jim_Cmd *cmd;
13114
13115 if (argc != 4 && argc != 5) {
13116 Jim_WrongNumArgs(interp, 1, argv, "name arglist ?statics? body");
13117 return JIM_ERR;
13118 }
13119
13120 if (JimValidName(interp, "procedure", argv[1]) != JIM_OK) {
13121 return JIM_ERR;
13122 }
13123
13124 if (argc == 4) {
13125 cmd = JimCreateProcedureCmd(interp, argv[2], NULL, argv[3], NULL);
13126 }
13127 else {
13128 cmd = JimCreateProcedureCmd(interp, argv[2], argv[3], argv[4], NULL);
13129 }
13130
13131 if (cmd) {
13132 /* Add the new command */
13133 Jim_Obj *qualifiedCmdNameObj;
13134 const char *cmdname = JimQualifyName(interp, Jim_String(argv[1]), &qualifiedCmdNameObj);
13135
13136 JimCreateCommand(interp, cmdname, cmd);
13137
13138 /* Calculate and set the namespace for this proc */
13139 JimUpdateProcNamespace(interp, cmd, cmdname);
13140
13141 JimFreeQualifiedName(interp, qualifiedCmdNameObj);
13142
13143 /* Unlike Tcl, set the name of the proc as the result */
13144 Jim_SetResult(interp, argv[1]);
13145 return JIM_OK;
13146 }
13147 return JIM_ERR;
13148 }
13149
13150 /* [local] */
13151 static int Jim_LocalCoreCommand(Jim_Interp *interp, int argc, Jim_Obj *const *argv)
13152 {
13153 int retcode;
13154
13155 if (argc < 2) {
13156 Jim_WrongNumArgs(interp, 1, argv, "cmd ?args ...?");
13157 return JIM_ERR;
13158 }
13159
13160 /* Evaluate the arguments with 'local' in force */
13161 interp->local++;
13162 retcode = Jim_EvalObjVector(interp, argc - 1, argv + 1);
13163 interp->local--;
13164
13165
13166 /* If OK, and the result is a proc, add it to the list of local procs */
13167 if (retcode == 0) {
13168 Jim_Obj *cmdNameObj = Jim_GetResult(interp);
13169
13170 if (Jim_GetCommand(interp, cmdNameObj, JIM_ERRMSG) == NULL) {
13171 return JIM_ERR;
13172 }
13173 if (interp->framePtr->localCommands == NULL) {
13174 interp->framePtr->localCommands = Jim_Alloc(sizeof(*interp->framePtr->localCommands));
13175 Jim_InitStack(interp->framePtr->localCommands);
13176 }
13177 Jim_IncrRefCount(cmdNameObj);
13178 Jim_StackPush(interp->framePtr->localCommands, cmdNameObj);
13179 }
13180
13181 return retcode;
13182 }
13183
13184 /* [upcall] */
13185 static int Jim_UpcallCoreCommand(Jim_Interp *interp, int argc, Jim_Obj *const *argv)
13186 {
13187 if (argc < 2) {
13188 Jim_WrongNumArgs(interp, 1, argv, "cmd ?args ...?");
13189 return JIM_ERR;
13190 }
13191 else {
13192 int retcode;
13193
13194 Jim_Cmd *cmdPtr = Jim_GetCommand(interp, argv[1], JIM_ERRMSG);
13195 if (cmdPtr == NULL || !cmdPtr->isproc || !cmdPtr->prevCmd) {
13196 Jim_SetResultFormatted(interp, "no previous command: \"%#s\"", argv[1]);
13197 return JIM_ERR;
13198 }
13199 /* OK. Mark this command as being in an upcall */
13200 cmdPtr->u.proc.upcall++;
13201 JimIncrCmdRefCount(cmdPtr);
13202
13203 /* Invoke the command as normal */
13204 retcode = Jim_EvalObjVector(interp, argc - 1, argv + 1);
13205
13206 /* No longer in an upcall */
13207 cmdPtr->u.proc.upcall--;
13208 JimDecrCmdRefCount(interp, cmdPtr);
13209
13210 return retcode;
13211 }
13212 }
13213
13214 /* [apply] */
13215 static int Jim_ApplyCoreCommand(Jim_Interp *interp, int argc, Jim_Obj *const *argv)
13216 {
13217 if (argc < 2) {
13218 Jim_WrongNumArgs(interp, 1, argv, "lambdaExpr ?arg ...?");
13219 return JIM_ERR;
13220 }
13221 else {
13222 int ret;
13223 Jim_Cmd *cmd;
13224 Jim_Obj *argListObjPtr;
13225 Jim_Obj *bodyObjPtr;
13226 Jim_Obj *nsObj = NULL;
13227 Jim_Obj **nargv;
13228
13229 int len = Jim_ListLength(interp, argv[1]);
13230 if (len != 2 && len != 3) {
13231 Jim_SetResultFormatted(interp, "can't interpret \"%#s\" as a lambda expression", argv[1]);
13232 return JIM_ERR;
13233 }
13234
13235 if (len == 3) {
13236 #ifdef jim_ext_namespace
13237 /* Need to canonicalise the given namespace. */
13238 nsObj = JimQualifyNameObj(interp, Jim_ListGetIndex(interp, argv[1], 2));
13239 #else
13240 Jim_SetResultString(interp, "namespaces not enabled", -1);
13241 return JIM_ERR;
13242 #endif
13243 }
13244 argListObjPtr = Jim_ListGetIndex(interp, argv[1], 0);
13245 bodyObjPtr = Jim_ListGetIndex(interp, argv[1], 1);
13246
13247 cmd = JimCreateProcedureCmd(interp, argListObjPtr, NULL, bodyObjPtr, nsObj);
13248
13249 if (cmd) {
13250 /* Create a new argv array with a dummy argv[0], for error messages */
13251 nargv = Jim_Alloc((argc - 2 + 1) * sizeof(*nargv));
13252 nargv[0] = Jim_NewStringObj(interp, "apply lambdaExpr", -1);
13253 Jim_IncrRefCount(nargv[0]);
13254 memcpy(&nargv[1], argv + 2, (argc - 2) * sizeof(*nargv));
13255 ret = JimCallProcedure(interp, cmd, argc - 2 + 1, nargv);
13256 Jim_DecrRefCount(interp, nargv[0]);
13257 Jim_Free(nargv);
13258
13259 JimDecrCmdRefCount(interp, cmd);
13260 return ret;
13261 }
13262 return JIM_ERR;
13263 }
13264 }
13265
13266
13267 /* [concat] */
13268 static int Jim_ConcatCoreCommand(Jim_Interp *interp, int argc, Jim_Obj *const *argv)
13269 {
13270 Jim_SetResult(interp, Jim_ConcatObj(interp, argc - 1, argv + 1));
13271 return JIM_OK;
13272 }
13273
13274 /* [upvar] */
13275 static int Jim_UpvarCoreCommand(Jim_Interp *interp, int argc, Jim_Obj *const *argv)
13276 {
13277 int i;
13278 Jim_CallFrame *targetCallFrame;
13279
13280 /* Lookup the target frame pointer */
13281 if (argc > 3 && (argc % 2 == 0)) {
13282 targetCallFrame = Jim_GetCallFrameByLevel(interp, argv[1]);
13283 argc--;
13284 argv++;
13285 }
13286 else {
13287 targetCallFrame = Jim_GetCallFrameByLevel(interp, NULL);
13288 }
13289 if (targetCallFrame == NULL) {
13290 return JIM_ERR;
13291 }
13292
13293 /* Check for arity */
13294 if (argc < 3) {
13295 Jim_WrongNumArgs(interp, 1, argv, "?level? otherVar localVar ?otherVar localVar ...?");
13296 return JIM_ERR;
13297 }
13298
13299 /* Now... for every other/local couple: */
13300 for (i = 1; i < argc; i += 2) {
13301 if (Jim_SetVariableLink(interp, argv[i + 1], argv[i], targetCallFrame) != JIM_OK)
13302 return JIM_ERR;
13303 }
13304 return JIM_OK;
13305 }
13306
13307 /* [global] */
13308 static int Jim_GlobalCoreCommand(Jim_Interp *interp, int argc, Jim_Obj *const *argv)
13309 {
13310 int i;
13311
13312 if (argc < 2) {
13313 Jim_WrongNumArgs(interp, 1, argv, "varName ?varName ...?");
13314 return JIM_ERR;
13315 }
13316 /* Link every var to the toplevel having the same name */
13317 if (interp->framePtr->level == 0)
13318 return JIM_OK; /* global at toplevel... */
13319 for (i = 1; i < argc; i++) {
13320 /* global ::blah does nothing */
13321 const char *name = Jim_String(argv[i]);
13322 if (name[0] != ':' || name[1] != ':') {
13323 if (Jim_SetVariableLink(interp, argv[i], argv[i], interp->topFramePtr) != JIM_OK)
13324 return JIM_ERR;
13325 }
13326 }
13327 return JIM_OK;
13328 }
13329
13330 /* does the [string map] operation. On error NULL is returned,
13331 * otherwise a new string object with the result, having refcount = 0,
13332 * is returned. */
13333 static Jim_Obj *JimStringMap(Jim_Interp *interp, Jim_Obj *mapListObjPtr,
13334 Jim_Obj *objPtr, int nocase)
13335 {
13336 int numMaps;
13337 const char *str, *noMatchStart = NULL;
13338 int strLen, i;
13339 Jim_Obj *resultObjPtr;
13340
13341 numMaps = Jim_ListLength(interp, mapListObjPtr);
13342 if (numMaps % 2) {
13343 Jim_SetResultString(interp, "list must contain an even number of elements", -1);
13344 return NULL;
13345 }
13346
13347 str = Jim_String(objPtr);
13348 strLen = Jim_Utf8Length(interp, objPtr);
13349
13350 /* Map it */
13351 resultObjPtr = Jim_NewStringObj(interp, "", 0);
13352 while (strLen) {
13353 for (i = 0; i < numMaps; i += 2) {
13354 Jim_Obj *eachObjPtr;
13355 const char *k;
13356 int kl;
13357
13358 eachObjPtr = Jim_ListGetIndex(interp, mapListObjPtr, i);
13359 k = Jim_String(eachObjPtr);
13360 kl = Jim_Utf8Length(interp, eachObjPtr);
13361
13362 if (strLen >= kl && kl) {
13363 int rc;
13364 rc = JimStringCompareLen(str, k, kl, nocase);
13365 if (rc == 0) {
13366 if (noMatchStart) {
13367 Jim_AppendString(interp, resultObjPtr, noMatchStart, str - noMatchStart);
13368 noMatchStart = NULL;
13369 }
13370 Jim_AppendObj(interp, resultObjPtr, Jim_ListGetIndex(interp, mapListObjPtr, i + 1));
13371 str += utf8_index(str, kl);
13372 strLen -= kl;
13373 break;
13374 }
13375 }
13376 }
13377 if (i == numMaps) { /* no match */
13378 int c;
13379 if (noMatchStart == NULL)
13380 noMatchStart = str;
13381 str += utf8_tounicode(str, &c);
13382 strLen--;
13383 }
13384 }
13385 if (noMatchStart) {
13386 Jim_AppendString(interp, resultObjPtr, noMatchStart, str - noMatchStart);
13387 }
13388 return resultObjPtr;
13389 }
13390
13391 /* [string] */
13392 static int Jim_StringCoreCommand(Jim_Interp *interp, int argc, Jim_Obj *const *argv)
13393 {
13394 int len;
13395 int opt_case = 1;
13396 int option;
13397 static const char * const options[] = {
13398 "bytelength", "length", "compare", "match", "equal", "is", "byterange", "range", "replace",
13399 "map", "repeat", "reverse", "index", "first", "last", "cat",
13400 "trim", "trimleft", "trimright", "tolower", "toupper", "totitle", NULL
13401 };
13402 enum
13403 {
13404 OPT_BYTELENGTH, OPT_LENGTH, OPT_COMPARE, OPT_MATCH, OPT_EQUAL, OPT_IS, OPT_BYTERANGE, OPT_RANGE, OPT_REPLACE,
13405 OPT_MAP, OPT_REPEAT, OPT_REVERSE, OPT_INDEX, OPT_FIRST, OPT_LAST, OPT_CAT,
13406 OPT_TRIM, OPT_TRIMLEFT, OPT_TRIMRIGHT, OPT_TOLOWER, OPT_TOUPPER, OPT_TOTITLE
13407 };
13408 static const char * const nocase_options[] = {
13409 "-nocase", NULL
13410 };
13411 static const char * const nocase_length_options[] = {
13412 "-nocase", "-length", NULL
13413 };
13414
13415 if (argc < 2) {
13416 Jim_WrongNumArgs(interp, 1, argv, "option ?arguments ...?");
13417 return JIM_ERR;
13418 }
13419 if (Jim_GetEnum(interp, argv[1], options, &option, NULL,
13420 JIM_ERRMSG | JIM_ENUM_ABBREV) != JIM_OK)
13421 return Jim_CheckShowCommands(interp, argv[1], options);
13422
13423 switch (option) {
13424 case OPT_LENGTH:
13425 case OPT_BYTELENGTH:
13426 if (argc != 3) {
13427 Jim_WrongNumArgs(interp, 2, argv, "string");
13428 return JIM_ERR;
13429 }
13430 if (option == OPT_LENGTH) {
13431 len = Jim_Utf8Length(interp, argv[2]);
13432 }
13433 else {
13434 len = Jim_Length(argv[2]);
13435 }
13436 Jim_SetResultInt(interp, len);
13437 return JIM_OK;
13438
13439 case OPT_CAT:{
13440 Jim_Obj *objPtr;
13441 if (argc == 3) {
13442 /* optimise the one-arg case */
13443 objPtr = argv[2];
13444 }
13445 else {
13446 int i;
13447
13448 objPtr = Jim_NewStringObj(interp, "", 0);
13449
13450 for (i = 2; i < argc; i++) {
13451 Jim_AppendObj(interp, objPtr, argv[i]);
13452 }
13453 }
13454 Jim_SetResult(interp, objPtr);
13455 return JIM_OK;
13456 }
13457
13458 case OPT_COMPARE:
13459 case OPT_EQUAL:
13460 {
13461 /* n is the number of remaining option args */
13462 long opt_length = -1;
13463 int n = argc - 4;
13464 int i = 2;
13465 while (n > 0) {
13466 int subopt;
13467 if (Jim_GetEnum(interp, argv[i++], nocase_length_options, &subopt, NULL,
13468 JIM_ENUM_ABBREV) != JIM_OK) {
13469 badcompareargs:
13470 Jim_WrongNumArgs(interp, 2, argv, "?-nocase? ?-length int? string1 string2");
13471 return JIM_ERR;
13472 }
13473 if (subopt == 0) {
13474 /* -nocase */
13475 opt_case = 0;
13476 n--;
13477 }
13478 else {
13479 /* -length */
13480 if (n < 2) {
13481 goto badcompareargs;
13482 }
13483 if (Jim_GetLong(interp, argv[i++], &opt_length) != JIM_OK) {
13484 return JIM_ERR;
13485 }
13486 n -= 2;
13487 }
13488 }
13489 if (n) {
13490 goto badcompareargs;
13491 }
13492 argv += argc - 2;
13493 if (opt_length < 0 && option != OPT_COMPARE && opt_case) {
13494 /* Fast version - [string equal], case sensitive, no length */
13495 Jim_SetResultBool(interp, Jim_StringEqObj(argv[0], argv[1]));
13496 }
13497 else {
13498 if (opt_length >= 0) {
13499 n = JimStringCompareLen(Jim_String(argv[0]), Jim_String(argv[1]), opt_length, !opt_case);
13500 }
13501 else {
13502 n = Jim_StringCompareObj(interp, argv[0], argv[1], !opt_case);
13503 }
13504 Jim_SetResultInt(interp, option == OPT_COMPARE ? n : n == 0);
13505 }
13506 return JIM_OK;
13507 }
13508
13509 case OPT_MATCH:
13510 if (argc != 4 &&
13511 (argc != 5 ||
13512 Jim_GetEnum(interp, argv[2], nocase_options, &opt_case, NULL,
13513 JIM_ENUM_ABBREV) != JIM_OK)) {
13514 Jim_WrongNumArgs(interp, 2, argv, "?-nocase? pattern string");
13515 return JIM_ERR;
13516 }
13517 if (opt_case == 0) {
13518 argv++;
13519 }
13520 Jim_SetResultBool(interp, Jim_StringMatchObj(interp, argv[2], argv[3], !opt_case));
13521 return JIM_OK;
13522
13523 case OPT_MAP:{
13524 Jim_Obj *objPtr;
13525
13526 if (argc != 4 &&
13527 (argc != 5 ||
13528 Jim_GetEnum(interp, argv[2], nocase_options, &opt_case, NULL,
13529 JIM_ENUM_ABBREV) != JIM_OK)) {
13530 Jim_WrongNumArgs(interp, 2, argv, "?-nocase? mapList string");
13531 return JIM_ERR;
13532 }
13533
13534 if (opt_case == 0) {
13535 argv++;
13536 }
13537 objPtr = JimStringMap(interp, argv[2], argv[3], !opt_case);
13538 if (objPtr == NULL) {
13539 return JIM_ERR;
13540 }
13541 Jim_SetResult(interp, objPtr);
13542 return JIM_OK;
13543 }
13544
13545 case OPT_RANGE:
13546 case OPT_BYTERANGE:{
13547 Jim_Obj *objPtr;
13548
13549 if (argc != 5) {
13550 Jim_WrongNumArgs(interp, 2, argv, "string first last");
13551 return JIM_ERR;
13552 }
13553 if (option == OPT_RANGE) {
13554 objPtr = Jim_StringRangeObj(interp, argv[2], argv[3], argv[4]);
13555 }
13556 else
13557 {
13558 objPtr = Jim_StringByteRangeObj(interp, argv[2], argv[3], argv[4]);
13559 }
13560
13561 if (objPtr == NULL) {
13562 return JIM_ERR;
13563 }
13564 Jim_SetResult(interp, objPtr);
13565 return JIM_OK;
13566 }
13567
13568 case OPT_REPLACE:{
13569 Jim_Obj *objPtr;
13570
13571 if (argc != 5 && argc != 6) {
13572 Jim_WrongNumArgs(interp, 2, argv, "string first last ?string?");
13573 return JIM_ERR;
13574 }
13575 objPtr = JimStringReplaceObj(interp, argv[2], argv[3], argv[4], argc == 6 ? argv[5] : NULL);
13576 if (objPtr == NULL) {
13577 return JIM_ERR;
13578 }
13579 Jim_SetResult(interp, objPtr);
13580 return JIM_OK;
13581 }
13582
13583
13584 case OPT_REPEAT:{
13585 Jim_Obj *objPtr;
13586 jim_wide count;
13587
13588 if (argc != 4) {
13589 Jim_WrongNumArgs(interp, 2, argv, "string count");
13590 return JIM_ERR;
13591 }
13592 if (Jim_GetWide(interp, argv[3], &count) != JIM_OK) {
13593 return JIM_ERR;
13594 }
13595 objPtr = Jim_NewStringObj(interp, "", 0);
13596 if (count > 0) {
13597 while (count--) {
13598 Jim_AppendObj(interp, objPtr, argv[2]);
13599 }
13600 }
13601 Jim_SetResult(interp, objPtr);
13602 return JIM_OK;
13603 }
13604
13605 case OPT_REVERSE:{
13606 char *buf, *p;
13607 const char *str;
13608 int i;
13609
13610 if (argc != 3) {
13611 Jim_WrongNumArgs(interp, 2, argv, "string");
13612 return JIM_ERR;
13613 }
13614
13615 str = Jim_GetString(argv[2], &len);
13616 buf = Jim_Alloc(len + 1);
13617 p = buf + len;
13618 *p = 0;
13619 for (i = 0; i < len; ) {
13620 int c;
13621 int l = utf8_tounicode(str, &c);
13622 memcpy(p - l, str, l);
13623 p -= l;
13624 i += l;
13625 str += l;
13626 }
13627 Jim_SetResult(interp, Jim_NewStringObjNoAlloc(interp, buf, len));
13628 return JIM_OK;
13629 }
13630
13631 case OPT_INDEX:{
13632 int idx;
13633 const char *str;
13634
13635 if (argc != 4) {
13636 Jim_WrongNumArgs(interp, 2, argv, "string index");
13637 return JIM_ERR;
13638 }
13639 if (Jim_GetIndex(interp, argv[3], &idx) != JIM_OK) {
13640 return JIM_ERR;
13641 }
13642 str = Jim_String(argv[2]);
13643 len = Jim_Utf8Length(interp, argv[2]);
13644 if (idx != INT_MIN && idx != INT_MAX) {
13645 idx = JimRelToAbsIndex(len, idx);
13646 }
13647 if (idx < 0 || idx >= len || str == NULL) {
13648 Jim_SetResultString(interp, "", 0);
13649 }
13650 else if (len == Jim_Length(argv[2])) {
13651 /* ASCII optimisation */
13652 Jim_SetResultString(interp, str + idx, 1);
13653 }
13654 else {
13655 int c;
13656 int i = utf8_index(str, idx);
13657 Jim_SetResultString(interp, str + i, utf8_tounicode(str + i, &c));
13658 }
13659 return JIM_OK;
13660 }
13661
13662 case OPT_FIRST:
13663 case OPT_LAST:{
13664 int idx = 0, l1, l2;
13665 const char *s1, *s2;
13666
13667 if (argc != 4 && argc != 5) {
13668 Jim_WrongNumArgs(interp, 2, argv, "subString string ?index?");
13669 return JIM_ERR;
13670 }
13671 s1 = Jim_String(argv[2]);
13672 s2 = Jim_String(argv[3]);
13673 l1 = Jim_Utf8Length(interp, argv[2]);
13674 l2 = Jim_Utf8Length(interp, argv[3]);
13675 if (argc == 5) {
13676 if (Jim_GetIndex(interp, argv[4], &idx) != JIM_OK) {
13677 return JIM_ERR;
13678 }
13679 idx = JimRelToAbsIndex(l2, idx);
13680 }
13681 else if (option == OPT_LAST) {
13682 idx = l2;
13683 }
13684 if (option == OPT_FIRST) {
13685 Jim_SetResultInt(interp, JimStringFirst(s1, l1, s2, l2, idx));
13686 }
13687 else {
13688 #ifdef JIM_UTF8
13689 Jim_SetResultInt(interp, JimStringLastUtf8(s1, l1, s2, idx));
13690 #else
13691 Jim_SetResultInt(interp, JimStringLast(s1, l1, s2, idx));
13692 #endif
13693 }
13694 return JIM_OK;
13695 }
13696
13697 case OPT_TRIM:
13698 case OPT_TRIMLEFT:
13699 case OPT_TRIMRIGHT:{
13700 Jim_Obj *trimchars;
13701
13702 if (argc != 3 && argc != 4) {
13703 Jim_WrongNumArgs(interp, 2, argv, "string ?trimchars?");
13704 return JIM_ERR;
13705 }
13706 trimchars = (argc == 4 ? argv[3] : NULL);
13707 if (option == OPT_TRIM) {
13708 Jim_SetResult(interp, JimStringTrim(interp, argv[2], trimchars));
13709 }
13710 else if (option == OPT_TRIMLEFT) {
13711 Jim_SetResult(interp, JimStringTrimLeft(interp, argv[2], trimchars));
13712 }
13713 else if (option == OPT_TRIMRIGHT) {
13714 Jim_SetResult(interp, JimStringTrimRight(interp, argv[2], trimchars));
13715 }
13716 return JIM_OK;
13717 }
13718
13719 case OPT_TOLOWER:
13720 case OPT_TOUPPER:
13721 case OPT_TOTITLE:
13722 if (argc != 3) {
13723 Jim_WrongNumArgs(interp, 2, argv, "string");
13724 return JIM_ERR;
13725 }
13726 if (option == OPT_TOLOWER) {
13727 Jim_SetResult(interp, JimStringToLower(interp, argv[2]));
13728 }
13729 else if (option == OPT_TOUPPER) {
13730 Jim_SetResult(interp, JimStringToUpper(interp, argv[2]));
13731 }
13732 else {
13733 Jim_SetResult(interp, JimStringToTitle(interp, argv[2]));
13734 }
13735 return JIM_OK;
13736
13737 case OPT_IS:
13738 if (argc == 4 || (argc == 5 && Jim_CompareStringImmediate(interp, argv[3], "-strict"))) {
13739 return JimStringIs(interp, argv[argc - 1], argv[2], argc == 5);
13740 }
13741 Jim_WrongNumArgs(interp, 2, argv, "class ?-strict? str");
13742 return JIM_ERR;
13743 }
13744 return JIM_OK;
13745 }
13746
13747 /* [time] */
13748 static int Jim_TimeCoreCommand(Jim_Interp *interp, int argc, Jim_Obj *const *argv)
13749 {
13750 long i, count = 1;
13751 jim_wide start, elapsed;
13752 char buf[60];
13753 const char *fmt = "%" JIM_WIDE_MODIFIER " microseconds per iteration";
13754
13755 if (argc < 2) {
13756 Jim_WrongNumArgs(interp, 1, argv, "script ?count?");
13757 return JIM_ERR;
13758 }
13759 if (argc == 3) {
13760 if (Jim_GetLong(interp, argv[2], &count) != JIM_OK)
13761 return JIM_ERR;
13762 }
13763 if (count < 0)
13764 return JIM_OK;
13765 i = count;
13766 start = JimClock();
13767 while (i-- > 0) {
13768 int retval;
13769
13770 retval = Jim_EvalObj(interp, argv[1]);
13771 if (retval != JIM_OK) {
13772 return retval;
13773 }
13774 }
13775 elapsed = JimClock() - start;
13776 sprintf(buf, fmt, count == 0 ? 0 : elapsed / count);
13777 Jim_SetResultString(interp, buf, -1);
13778 return JIM_OK;
13779 }
13780
13781 /* [exit] */
13782 static int Jim_ExitCoreCommand(Jim_Interp *interp, int argc, Jim_Obj *const *argv)
13783 {
13784 long exitCode = 0;
13785
13786 if (argc > 2) {
13787 Jim_WrongNumArgs(interp, 1, argv, "?exitCode?");
13788 return JIM_ERR;
13789 }
13790 if (argc == 2) {
13791 if (Jim_GetLong(interp, argv[1], &exitCode) != JIM_OK)
13792 return JIM_ERR;
13793 }
13794 interp->exitCode = exitCode;
13795 return JIM_EXIT;
13796 }
13797
13798 /* [catch] */
13799 static int Jim_CatchCoreCommand(Jim_Interp *interp, int argc, Jim_Obj *const *argv)
13800 {
13801 int exitCode = 0;
13802 int i;
13803 int sig = 0;
13804
13805 /* Which return codes are ignored (passed through)? By default, only exit, eval and signal */
13806 jim_wide ignore_mask = (1 << JIM_EXIT) | (1 << JIM_EVAL) | (1 << JIM_SIGNAL);
13807 static const int max_ignore_code = sizeof(ignore_mask) * 8;
13808
13809 /* Reset the error code before catch.
13810 * Note that this is not strictly correct.
13811 */
13812 Jim_SetGlobalVariableStr(interp, "errorCode", Jim_NewStringObj(interp, "NONE", -1));
13813
13814 for (i = 1; i < argc - 1; i++) {
13815 const char *arg = Jim_String(argv[i]);
13816 jim_wide option;
13817 int ignore;
13818
13819 /* It's a pity we can't use Jim_GetEnum here :-( */
13820 if (strcmp(arg, "--") == 0) {
13821 i++;
13822 break;
13823 }
13824 if (*arg != '-') {
13825 break;
13826 }
13827
13828 if (strncmp(arg, "-no", 3) == 0) {
13829 arg += 3;
13830 ignore = 1;
13831 }
13832 else {
13833 arg++;
13834 ignore = 0;
13835 }
13836
13837 if (Jim_StringToWide(arg, &option, 10) != JIM_OK) {
13838 option = -1;
13839 }
13840 if (option < 0) {
13841 option = Jim_FindByName(arg, jimReturnCodes, jimReturnCodesSize);
13842 }
13843 if (option < 0) {
13844 goto wrongargs;
13845 }
13846
13847 if (ignore) {
13848 ignore_mask |= ((jim_wide)1 << option);
13849 }
13850 else {
13851 ignore_mask &= (~((jim_wide)1 << option));
13852 }
13853 }
13854
13855 argc -= i;
13856 if (argc < 1 || argc > 3) {
13857 wrongargs:
13858 Jim_WrongNumArgs(interp, 1, argv,
13859 "?-?no?code ... --? script ?resultVarName? ?optionVarName?");
13860 return JIM_ERR;
13861 }
13862 argv += i;
13863
13864 if ((ignore_mask & (1 << JIM_SIGNAL)) == 0) {
13865 sig++;
13866 }
13867
13868 interp->signal_level += sig;
13869 if (Jim_CheckSignal(interp)) {
13870 /* If a signal is set, don't even try to execute the body */
13871 exitCode = JIM_SIGNAL;
13872 }
13873 else {
13874 exitCode = Jim_EvalObj(interp, argv[0]);
13875 /* Don't want any caught error included in a later stack trace */
13876 interp->errorFlag = 0;
13877 }
13878 interp->signal_level -= sig;
13879
13880 /* Catch or pass through? Only the first 32/64 codes can be passed through */
13881 if (exitCode >= 0 && exitCode < max_ignore_code && (((unsigned jim_wide)1 << exitCode) & ignore_mask)) {
13882 /* Not caught, pass it up */
13883 return exitCode;
13884 }
13885
13886 if (sig && exitCode == JIM_SIGNAL) {
13887 /* Catch the signal at this level */
13888 if (interp->signal_set_result) {
13889 interp->signal_set_result(interp, interp->sigmask);
13890 }
13891 else {
13892 Jim_SetResultInt(interp, interp->sigmask);
13893 }
13894 interp->sigmask = 0;
13895 }
13896
13897 if (argc >= 2) {
13898 if (Jim_SetVariable(interp, argv[1], Jim_GetResult(interp)) != JIM_OK) {
13899 return JIM_ERR;
13900 }
13901 if (argc == 3) {
13902 Jim_Obj *optListObj = Jim_NewListObj(interp, NULL, 0);
13903
13904 Jim_ListAppendElement(interp, optListObj, Jim_NewStringObj(interp, "-code", -1));
13905 Jim_ListAppendElement(interp, optListObj,
13906 Jim_NewIntObj(interp, exitCode == JIM_RETURN ? interp->returnCode : exitCode));
13907 Jim_ListAppendElement(interp, optListObj, Jim_NewStringObj(interp, "-level", -1));
13908 Jim_ListAppendElement(interp, optListObj, Jim_NewIntObj(interp, interp->returnLevel));
13909 if (exitCode == JIM_ERR) {
13910 Jim_Obj *errorCode;
13911 Jim_ListAppendElement(interp, optListObj, Jim_NewStringObj(interp, "-errorinfo",
13912 -1));
13913 Jim_ListAppendElement(interp, optListObj, interp->stackTrace);
13914
13915 errorCode = Jim_GetGlobalVariableStr(interp, "errorCode", JIM_NONE);
13916 if (errorCode) {
13917 Jim_ListAppendElement(interp, optListObj, Jim_NewStringObj(interp, "-errorcode", -1));
13918 Jim_ListAppendElement(interp, optListObj, errorCode);
13919 }
13920 }
13921 if (Jim_SetVariable(interp, argv[2], optListObj) != JIM_OK) {
13922 return JIM_ERR;
13923 }
13924 }
13925 }
13926 Jim_SetResultInt(interp, exitCode);
13927 return JIM_OK;
13928 }
13929
13930 #if defined(JIM_REFERENCES) && !defined(JIM_BOOTSTRAP)
13931
13932 /* [ref] */
13933 static int Jim_RefCoreCommand(Jim_Interp *interp, int argc, Jim_Obj *const *argv)
13934 {
13935 if (argc != 3 && argc != 4) {
13936 Jim_WrongNumArgs(interp, 1, argv, "string tag ?finalizer?");
13937 return JIM_ERR;
13938 }
13939 if (argc == 3) {
13940 Jim_SetResult(interp, Jim_NewReference(interp, argv[1], argv[2], NULL));
13941 }
13942 else {
13943 Jim_SetResult(interp, Jim_NewReference(interp, argv[1], argv[2], argv[3]));
13944 }
13945 return JIM_OK;
13946 }
13947
13948 /* [getref] */
13949 static int Jim_GetrefCoreCommand(Jim_Interp *interp, int argc, Jim_Obj *const *argv)
13950 {
13951 Jim_Reference *refPtr;
13952
13953 if (argc != 2) {
13954 Jim_WrongNumArgs(interp, 1, argv, "reference");
13955 return JIM_ERR;
13956 }
13957 if ((refPtr = Jim_GetReference(interp, argv[1])) == NULL)
13958 return JIM_ERR;
13959 Jim_SetResult(interp, refPtr->objPtr);
13960 return JIM_OK;
13961 }
13962
13963 /* [setref] */
13964 static int Jim_SetrefCoreCommand(Jim_Interp *interp, int argc, Jim_Obj *const *argv)
13965 {
13966 Jim_Reference *refPtr;
13967
13968 if (argc != 3) {
13969 Jim_WrongNumArgs(interp, 1, argv, "reference newValue");
13970 return JIM_ERR;
13971 }
13972 if ((refPtr = Jim_GetReference(interp, argv[1])) == NULL)
13973 return JIM_ERR;
13974 Jim_IncrRefCount(argv[2]);
13975 Jim_DecrRefCount(interp, refPtr->objPtr);
13976 refPtr->objPtr = argv[2];
13977 Jim_SetResult(interp, argv[2]);
13978 return JIM_OK;
13979 }
13980
13981 /* [collect] */
13982 static int Jim_CollectCoreCommand(Jim_Interp *interp, int argc, Jim_Obj *const *argv)
13983 {
13984 if (argc != 1) {
13985 Jim_WrongNumArgs(interp, 1, argv, "");
13986 return JIM_ERR;
13987 }
13988 Jim_SetResultInt(interp, Jim_Collect(interp));
13989
13990 /* Free all the freed objects. */
13991 while (interp->freeList) {
13992 Jim_Obj *nextObjPtr = interp->freeList->nextObjPtr;
13993 Jim_Free(interp->freeList);
13994 interp->freeList = nextObjPtr;
13995 }
13996
13997 return JIM_OK;
13998 }
13999
14000 /* [finalize] reference ?newValue? */
14001 static int Jim_FinalizeCoreCommand(Jim_Interp *interp, int argc, Jim_Obj *const *argv)
14002 {
14003 if (argc != 2 && argc != 3) {
14004 Jim_WrongNumArgs(interp, 1, argv, "reference ?finalizerProc?");
14005 return JIM_ERR;
14006 }
14007 if (argc == 2) {
14008 Jim_Obj *cmdNamePtr;
14009
14010 if (Jim_GetFinalizer(interp, argv[1], &cmdNamePtr) != JIM_OK)
14011 return JIM_ERR;
14012 if (cmdNamePtr != NULL) /* otherwise the null string is returned. */
14013 Jim_SetResult(interp, cmdNamePtr);
14014 }
14015 else {
14016 if (Jim_SetFinalizer(interp, argv[1], argv[2]) != JIM_OK)
14017 return JIM_ERR;
14018 Jim_SetResult(interp, argv[2]);
14019 }
14020 return JIM_OK;
14021 }
14022
14023 /* [info references] */
14024 static int JimInfoReferences(Jim_Interp *interp, int argc, Jim_Obj *const *argv)
14025 {
14026 Jim_Obj *listObjPtr;
14027 Jim_HashTableIterator htiter;
14028 Jim_HashEntry *he;
14029
14030 listObjPtr = Jim_NewListObj(interp, NULL, 0);
14031
14032 JimInitHashTableIterator(&interp->references, &htiter);
14033 while ((he = Jim_NextHashEntry(&htiter)) != NULL) {
14034 char buf[JIM_REFERENCE_SPACE + 1];
14035 Jim_Reference *refPtr = Jim_GetHashEntryVal(he);
14036 const unsigned long *refId = he->key;
14037
14038 JimFormatReference(buf, refPtr, *refId);
14039 Jim_ListAppendElement(interp, listObjPtr, Jim_NewStringObj(interp, buf, -1));
14040 }
14041 Jim_SetResult(interp, listObjPtr);
14042 return JIM_OK;
14043 }
14044 #endif /* JIM_REFERENCES && !JIM_BOOTSTRAP */
14045
14046 /* [rename] */
14047 static int Jim_RenameCoreCommand(Jim_Interp *interp, int argc, Jim_Obj *const *argv)
14048 {
14049 if (argc != 3) {
14050 Jim_WrongNumArgs(interp, 1, argv, "oldName newName");
14051 return JIM_ERR;
14052 }
14053
14054 if (JimValidName(interp, "new procedure", argv[2])) {
14055 return JIM_ERR;
14056 }
14057
14058 return Jim_RenameCommand(interp, Jim_String(argv[1]), Jim_String(argv[2]));
14059 }
14060
14061 #define JIM_DICTMATCH_KEYS 0x0001
14062 #define JIM_DICTMATCH_VALUES 0x002
14063
14064 /**
14065 * match_type must be one of JIM_DICTMATCH_KEYS or JIM_DICTMATCH_VALUES
14066 * return_types should be either or both
14067 */
14068 int Jim_DictMatchTypes(Jim_Interp *interp, Jim_Obj *objPtr, Jim_Obj *patternObj, int match_type, int return_types)
14069 {
14070 Jim_HashEntry *he;
14071 Jim_Obj *listObjPtr;
14072 Jim_HashTableIterator htiter;
14073
14074 if (SetDictFromAny(interp, objPtr) != JIM_OK) {
14075 return JIM_ERR;
14076 }
14077
14078 listObjPtr = Jim_NewListObj(interp, NULL, 0);
14079
14080 JimInitHashTableIterator(objPtr->internalRep.ptr, &htiter);
14081 while ((he = Jim_NextHashEntry(&htiter)) != NULL) {
14082 if (patternObj) {
14083 Jim_Obj *matchObj = (match_type == JIM_DICTMATCH_KEYS) ? (Jim_Obj *)he->key : Jim_GetHashEntryVal(he);
14084 if (!JimGlobMatch(Jim_String(patternObj), Jim_String(matchObj), 0)) {
14085 /* no match */
14086 continue;
14087 }
14088 }
14089 if (return_types & JIM_DICTMATCH_KEYS) {
14090 Jim_ListAppendElement(interp, listObjPtr, (Jim_Obj *)he->key);
14091 }
14092 if (return_types & JIM_DICTMATCH_VALUES) {
14093 Jim_ListAppendElement(interp, listObjPtr, Jim_GetHashEntryVal(he));
14094 }
14095 }
14096
14097 Jim_SetResult(interp, listObjPtr);
14098 return JIM_OK;
14099 }
14100
14101 int Jim_DictSize(Jim_Interp *interp, Jim_Obj *objPtr)
14102 {
14103 if (SetDictFromAny(interp, objPtr) != JIM_OK) {
14104 return -1;
14105 }
14106 return ((Jim_HashTable *)objPtr->internalRep.ptr)->used;
14107 }
14108
14109 /**
14110 * Must be called with at least one object.
14111 * Returns the new dictionary, or NULL on error.
14112 */
14113 Jim_Obj *Jim_DictMerge(Jim_Interp *interp, int objc, Jim_Obj *const *objv)
14114 {
14115 Jim_Obj *objPtr = Jim_NewDictObj(interp, NULL, 0);
14116 int i;
14117
14118 JimPanic((objc == 0, "Jim_DictMerge called with objc=0"));
14119
14120 /* Note that we don't optimise the trivial case of a single argument */
14121
14122 for (i = 0; i < objc; i++) {
14123 Jim_HashTable *ht;
14124 Jim_HashTableIterator htiter;
14125 Jim_HashEntry *he;
14126
14127 if (SetDictFromAny(interp, objv[i]) != JIM_OK) {
14128 Jim_FreeNewObj(interp, objPtr);
14129 return NULL;
14130 }
14131 ht = objv[i]->internalRep.ptr;
14132 JimInitHashTableIterator(ht, &htiter);
14133 while ((he = Jim_NextHashEntry(&htiter)) != NULL) {
14134 Jim_ReplaceHashEntry(objPtr->internalRep.ptr, Jim_GetHashEntryKey(he), Jim_GetHashEntryVal(he));
14135 }
14136 }
14137 return objPtr;
14138 }
14139
14140 int Jim_DictInfo(Jim_Interp *interp, Jim_Obj *objPtr)
14141 {
14142 Jim_HashTable *ht;
14143 unsigned int i;
14144 char buffer[100];
14145 int sum = 0;
14146 int nonzero_count = 0;
14147 Jim_Obj *output;
14148 int bucket_counts[11] = { 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0 };
14149
14150 if (SetDictFromAny(interp, objPtr) != JIM_OK) {
14151 return JIM_ERR;
14152 }
14153
14154 ht = (Jim_HashTable *)objPtr->internalRep.ptr;
14155
14156 /* Note that this uses internal knowledge of the hash table */
14157 snprintf(buffer, sizeof(buffer), "%d entries in table, %d buckets\n", ht->used, ht->size);
14158 output = Jim_NewStringObj(interp, buffer, -1);
14159
14160 for (i = 0; i < ht->size; i++) {
14161 Jim_HashEntry *he = ht->table[i];
14162 int entries = 0;
14163 while (he) {
14164 entries++;
14165 he = he->next;
14166 }
14167 if (entries > 9) {
14168 bucket_counts[10]++;
14169 }
14170 else {
14171 bucket_counts[entries]++;
14172 }
14173 if (entries) {
14174 sum += entries;
14175 nonzero_count++;
14176 }
14177 }
14178 for (i = 0; i < 10; i++) {
14179 snprintf(buffer, sizeof(buffer), "number of buckets with %d entries: %d\n", i, bucket_counts[i]);
14180 Jim_AppendString(interp, output, buffer, -1);
14181 }
14182 snprintf(buffer, sizeof(buffer), "number of buckets with 10 or more entries: %d\n", bucket_counts[10]);
14183 Jim_AppendString(interp, output, buffer, -1);
14184 snprintf(buffer, sizeof(buffer), "average search distance for entry: %.1f", nonzero_count ? (double)sum / nonzero_count : 0.0);
14185 Jim_AppendString(interp, output, buffer, -1);
14186 Jim_SetResult(interp, output);
14187 return JIM_OK;
14188 }
14189
14190 static int Jim_EvalEnsemble(Jim_Interp *interp, const char *basecmd, const char *subcmd, int argc, Jim_Obj *const *argv)
14191 {
14192 Jim_Obj *prefixObj = Jim_NewStringObj(interp, basecmd, -1);
14193
14194 Jim_AppendString(interp, prefixObj, " ", 1);
14195 Jim_AppendString(interp, prefixObj, subcmd, -1);
14196
14197 return Jim_EvalObjPrefix(interp, prefixObj, argc, argv);
14198 }
14199
14200 /**
14201 * Implements the [dict with] command
14202 */
14203 static int JimDictWith(Jim_Interp *interp, Jim_Obj *dictVarName, Jim_Obj *const *keyv, int keyc, Jim_Obj *scriptObj)
14204 {
14205 int i;
14206 Jim_Obj *objPtr;
14207 Jim_Obj *dictObj;
14208 Jim_Obj **dictValues;
14209 int len;
14210 int ret = JIM_OK;
14211
14212 /* Open up the appropriate level of the dictionary */
14213 dictObj = Jim_GetVariable(interp, dictVarName, JIM_ERRMSG);
14214 if (dictObj == NULL || Jim_DictKeysVector(interp, dictObj, keyv, keyc, &objPtr, JIM_ERRMSG) != JIM_OK) {
14215 return JIM_ERR;
14216 }
14217 /* Set the local variables */
14218 if (Jim_DictPairs(interp, objPtr, &dictValues, &len) == JIM_ERR) {
14219 return JIM_ERR;
14220 }
14221 for (i = 0; i < len; i += 2) {
14222 if (Jim_SetVariable(interp, dictValues[i], dictValues[i + 1]) == JIM_ERR) {
14223 Jim_Free(dictValues);
14224 return JIM_ERR;
14225 }
14226 }
14227
14228 /* As an optimisation, if the script is empty, no need to evaluate it or update the dict */
14229 if (Jim_Length(scriptObj)) {
14230 ret = Jim_EvalObj(interp, scriptObj);
14231
14232 /* Now if the dictionary still exists, update it based on the local variables */
14233 if (ret == JIM_OK && Jim_GetVariable(interp, dictVarName, 0) != NULL) {
14234 /* We need a copy of keyv with one extra element at the end for Jim_SetDictKeysVector() */
14235 Jim_Obj **newkeyv = Jim_Alloc(sizeof(*newkeyv) * (keyc + 1));
14236 for (i = 0; i < keyc; i++) {
14237 newkeyv[i] = keyv[i];
14238 }
14239
14240 for (i = 0; i < len; i += 2) {
14241 /* This will be NULL if the variable no longer exists, thus deleting the variable */
14242 objPtr = Jim_GetVariable(interp, dictValues[i], 0);
14243 newkeyv[keyc] = dictValues[i];
14244 Jim_SetDictKeysVector(interp, dictVarName, newkeyv, keyc + 1, objPtr, 0);
14245 }
14246 Jim_Free(newkeyv);
14247 }
14248 }
14249
14250 Jim_Free(dictValues);
14251
14252 return ret;
14253 }
14254
14255 /* [dict] */
14256 static int Jim_DictCoreCommand(Jim_Interp *interp, int argc, Jim_Obj *const *argv)
14257 {
14258 Jim_Obj *objPtr;
14259 int types = JIM_DICTMATCH_KEYS;
14260 int option;
14261 static const char * const options[] = {
14262 "create", "get", "set", "unset", "exists", "keys", "size", "info",
14263 "merge", "with", "append", "lappend", "incr", "remove", "values", "for",
14264 "replace", "update", NULL
14265 };
14266 enum
14267 {
14268 OPT_CREATE, OPT_GET, OPT_SET, OPT_UNSET, OPT_EXISTS, OPT_KEYS, OPT_SIZE, OPT_INFO,
14269 OPT_MERGE, OPT_WITH, OPT_APPEND, OPT_LAPPEND, OPT_INCR, OPT_REMOVE, OPT_VALUES, OPT_FOR,
14270 OPT_REPLACE, OPT_UPDATE,
14271 };
14272
14273 if (argc < 2) {
14274 Jim_WrongNumArgs(interp, 1, argv, "subcommand ?arguments ...?");
14275 return JIM_ERR;
14276 }
14277
14278 if (Jim_GetEnum(interp, argv[1], options, &option, "subcommand", JIM_ERRMSG) != JIM_OK) {
14279 return Jim_CheckShowCommands(interp, argv[1], options);
14280 }
14281
14282 switch (option) {
14283 case OPT_GET:
14284 if (argc < 3) {
14285 Jim_WrongNumArgs(interp, 2, argv, "dictionary ?key ...?");
14286 return JIM_ERR;
14287 }
14288 if (Jim_DictKeysVector(interp, argv[2], argv + 3, argc - 3, &objPtr,
14289 JIM_ERRMSG) != JIM_OK) {
14290 return JIM_ERR;
14291 }
14292 Jim_SetResult(interp, objPtr);
14293 return JIM_OK;
14294
14295 case OPT_SET:
14296 if (argc < 5) {
14297 Jim_WrongNumArgs(interp, 2, argv, "varName key ?key ...? value");
14298 return JIM_ERR;
14299 }
14300 return Jim_SetDictKeysVector(interp, argv[2], argv + 3, argc - 4, argv[argc - 1], JIM_ERRMSG);
14301
14302 case OPT_EXISTS:
14303 if (argc < 4) {
14304 Jim_WrongNumArgs(interp, 2, argv, "dictionary key ?key ...?");
14305 return JIM_ERR;
14306 }
14307 else {
14308 int rc = Jim_DictKeysVector(interp, argv[2], argv + 3, argc - 3, &objPtr, JIM_ERRMSG);
14309 if (rc < 0) {
14310 return JIM_ERR;
14311 }
14312 Jim_SetResultBool(interp, rc == JIM_OK);
14313 return JIM_OK;
14314 }
14315
14316 case OPT_UNSET:
14317 if (argc < 4) {
14318 Jim_WrongNumArgs(interp, 2, argv, "varName key ?key ...?");
14319 return JIM_ERR;
14320 }
14321 if (Jim_SetDictKeysVector(interp, argv[2], argv + 3, argc - 3, NULL, 0) != JIM_OK) {
14322 return JIM_ERR;
14323 }
14324 return JIM_OK;
14325
14326 case OPT_VALUES:
14327 types = JIM_DICTMATCH_VALUES;
14328 /* fallthru */
14329 case OPT_KEYS:
14330 if (argc != 3 && argc != 4) {
14331 Jim_WrongNumArgs(interp, 2, argv, "dictionary ?pattern?");
14332 return JIM_ERR;
14333 }
14334 return Jim_DictMatchTypes(interp, argv[2], argc == 4 ? argv[3] : NULL, types, types);
14335
14336 case OPT_SIZE:
14337 if (argc != 3) {
14338 Jim_WrongNumArgs(interp, 2, argv, "dictionary");
14339 return JIM_ERR;
14340 }
14341 else if (Jim_DictSize(interp, argv[2]) < 0) {
14342 return JIM_ERR;
14343 }
14344 Jim_SetResultInt(interp, Jim_DictSize(interp, argv[2]));
14345 return JIM_OK;
14346
14347 case OPT_MERGE:
14348 if (argc == 2) {
14349 return JIM_OK;
14350 }
14351 objPtr = Jim_DictMerge(interp, argc - 2, argv + 2);
14352 if (objPtr == NULL) {
14353 return JIM_ERR;
14354 }
14355 Jim_SetResult(interp, objPtr);
14356 return JIM_OK;
14357
14358 case OPT_UPDATE:
14359 if (argc < 6 || argc % 2) {
14360 /* Better error message */
14361 argc = 2;
14362 }
14363 break;
14364
14365 case OPT_CREATE:
14366 if (argc % 2) {
14367 Jim_WrongNumArgs(interp, 2, argv, "?key value ...?");
14368 return JIM_ERR;
14369 }
14370 objPtr = Jim_NewDictObj(interp, argv + 2, argc - 2);
14371 Jim_SetResult(interp, objPtr);
14372 return JIM_OK;
14373
14374 case OPT_INFO:
14375 if (argc != 3) {
14376 Jim_WrongNumArgs(interp, 2, argv, "dictionary");
14377 return JIM_ERR;
14378 }
14379 return Jim_DictInfo(interp, argv[2]);
14380
14381 case OPT_WITH:
14382 if (argc < 4) {
14383 Jim_WrongNumArgs(interp, 2, argv, "dictVar ?key ...? script");
14384 return JIM_ERR;
14385 }
14386 return JimDictWith(interp, argv[2], argv + 3, argc - 4, argv[argc - 1]);
14387 }
14388 /* Handle command as an ensemble */
14389 return Jim_EvalEnsemble(interp, "dict", options[option], argc - 2, argv + 2);
14390 }
14391
14392 /* [subst] */
14393 static int Jim_SubstCoreCommand(Jim_Interp *interp, int argc, Jim_Obj *const *argv)
14394 {
14395 static const char * const options[] = {
14396 "-nobackslashes", "-nocommands", "-novariables", NULL
14397 };
14398 enum
14399 { OPT_NOBACKSLASHES, OPT_NOCOMMANDS, OPT_NOVARIABLES };
14400 int i;
14401 int flags = JIM_SUBST_FLAG;
14402 Jim_Obj *objPtr;
14403
14404 if (argc < 2) {
14405 Jim_WrongNumArgs(interp, 1, argv, "?options? string");
14406 return JIM_ERR;
14407 }
14408 for (i = 1; i < (argc - 1); i++) {
14409 int option;
14410
14411 if (Jim_GetEnum(interp, argv[i], options, &option, NULL,
14412 JIM_ERRMSG | JIM_ENUM_ABBREV) != JIM_OK) {
14413 return JIM_ERR;
14414 }
14415 switch (option) {
14416 case OPT_NOBACKSLASHES:
14417 flags |= JIM_SUBST_NOESC;
14418 break;
14419 case OPT_NOCOMMANDS:
14420 flags |= JIM_SUBST_NOCMD;
14421 break;
14422 case OPT_NOVARIABLES:
14423 flags |= JIM_SUBST_NOVAR;
14424 break;
14425 }
14426 }
14427 if (Jim_SubstObj(interp, argv[argc - 1], &objPtr, flags) != JIM_OK) {
14428 return JIM_ERR;
14429 }
14430 Jim_SetResult(interp, objPtr);
14431 return JIM_OK;
14432 }
14433
14434 /* [info] */
14435 static int Jim_InfoCoreCommand(Jim_Interp *interp, int argc, Jim_Obj *const *argv)
14436 {
14437 int cmd;
14438 Jim_Obj *objPtr;
14439 int mode = 0;
14440
14441 static const char * const commands[] = {
14442 "body", "statics", "commands", "procs", "channels", "exists", "globals", "level", "frame", "locals",
14443 "vars", "version", "patchlevel", "complete", "args", "hostname",
14444 "script", "source", "stacktrace", "nameofexecutable", "returncodes",
14445 "references", "alias", NULL
14446 };
14447 enum
14448 { INFO_BODY, INFO_STATICS, INFO_COMMANDS, INFO_PROCS, INFO_CHANNELS, INFO_EXISTS, INFO_GLOBALS, INFO_LEVEL,
14449 INFO_FRAME, INFO_LOCALS, INFO_VARS, INFO_VERSION, INFO_PATCHLEVEL, INFO_COMPLETE, INFO_ARGS,
14450 INFO_HOSTNAME, INFO_SCRIPT, INFO_SOURCE, INFO_STACKTRACE, INFO_NAMEOFEXECUTABLE,
14451 INFO_RETURNCODES, INFO_REFERENCES, INFO_ALIAS,
14452 };
14453
14454 #ifdef jim_ext_namespace
14455 int nons = 0;
14456
14457 if (argc > 2 && Jim_CompareStringImmediate(interp, argv[1], "-nons")) {
14458 /* This is for internal use only */
14459 argc--;
14460 argv++;
14461 nons = 1;
14462 }
14463 #endif
14464
14465 if (argc < 2) {
14466 Jim_WrongNumArgs(interp, 1, argv, "subcommand ?args ...?");
14467 return JIM_ERR;
14468 }
14469 if (Jim_GetEnum(interp, argv[1], commands, &cmd, "subcommand", JIM_ERRMSG | JIM_ENUM_ABBREV) != JIM_OK) {
14470 return Jim_CheckShowCommands(interp, argv[1], commands);
14471 }
14472
14473 /* Test for the most common commands first, just in case it makes a difference */
14474 switch (cmd) {
14475 case INFO_EXISTS:
14476 if (argc != 3) {
14477 Jim_WrongNumArgs(interp, 2, argv, "varName");
14478 return JIM_ERR;
14479 }
14480 Jim_SetResultBool(interp, Jim_GetVariable(interp, argv[2], 0) != NULL);
14481 break;
14482
14483 case INFO_ALIAS:{
14484 Jim_Cmd *cmdPtr;
14485
14486 if (argc != 3) {
14487 Jim_WrongNumArgs(interp, 2, argv, "command");
14488 return JIM_ERR;
14489 }
14490 if ((cmdPtr = Jim_GetCommand(interp, argv[2], JIM_ERRMSG)) == NULL) {
14491 return JIM_ERR;
14492 }
14493 if (cmdPtr->isproc || cmdPtr->u.native.cmdProc != JimAliasCmd) {
14494 Jim_SetResultFormatted(interp, "command \"%#s\" is not an alias", argv[2]);
14495 return JIM_ERR;
14496 }
14497 Jim_SetResult(interp, (Jim_Obj *)cmdPtr->u.native.privData);
14498 return JIM_OK;
14499 }
14500
14501 case INFO_CHANNELS:
14502 mode++; /* JIM_CMDLIST_CHANNELS */
14503 #ifndef jim_ext_aio
14504 Jim_SetResultString(interp, "aio not enabled", -1);
14505 return JIM_ERR;
14506 #endif
14507 /* fall through */
14508 case INFO_PROCS:
14509 mode++; /* JIM_CMDLIST_PROCS */
14510 /* fall through */
14511 case INFO_COMMANDS:
14512 /* mode 0 => JIM_CMDLIST_COMMANDS */
14513 if (argc != 2 && argc != 3) {
14514 Jim_WrongNumArgs(interp, 2, argv, "?pattern?");
14515 return JIM_ERR;
14516 }
14517 #ifdef jim_ext_namespace
14518 if (!nons) {
14519 if (Jim_Length(interp->framePtr->nsObj) || (argc == 3 && JimGlobMatch("::*", Jim_String(argv[2]), 0))) {
14520 return Jim_EvalPrefix(interp, "namespace info", argc - 1, argv + 1);
14521 }
14522 }
14523 #endif
14524 Jim_SetResult(interp, JimCommandsList(interp, (argc == 3) ? argv[2] : NULL, mode));
14525 break;
14526
14527 case INFO_VARS:
14528 mode++; /* JIM_VARLIST_VARS */
14529 /* fall through */
14530 case INFO_LOCALS:
14531 mode++; /* JIM_VARLIST_LOCALS */
14532 /* fall through */
14533 case INFO_GLOBALS:
14534 /* mode 0 => JIM_VARLIST_GLOBALS */
14535 if (argc != 2 && argc != 3) {
14536 Jim_WrongNumArgs(interp, 2, argv, "?pattern?");
14537 return JIM_ERR;
14538 }
14539 #ifdef jim_ext_namespace
14540 if (!nons) {
14541 if (Jim_Length(interp->framePtr->nsObj) || (argc == 3 && JimGlobMatch("::*", Jim_String(argv[2]), 0))) {
14542 return Jim_EvalPrefix(interp, "namespace info", argc - 1, argv + 1);
14543 }
14544 }
14545 #endif
14546 Jim_SetResult(interp, JimVariablesList(interp, argc == 3 ? argv[2] : NULL, mode));
14547 break;
14548
14549 case INFO_SCRIPT:
14550 if (argc != 2) {
14551 Jim_WrongNumArgs(interp, 2, argv, "");
14552 return JIM_ERR;
14553 }
14554 Jim_SetResult(interp, JimGetScript(interp, interp->currentScriptObj)->fileNameObj);
14555 break;
14556
14557 case INFO_SOURCE:{
14558 jim_wide line;
14559 Jim_Obj *resObjPtr;
14560 Jim_Obj *fileNameObj;
14561
14562 if (argc != 3 && argc != 5) {
14563 Jim_WrongNumArgs(interp, 2, argv, "source ?filename line?");
14564 return JIM_ERR;
14565 }
14566 if (argc == 5) {
14567 if (Jim_GetWide(interp, argv[4], &line) != JIM_OK) {
14568 return JIM_ERR;
14569 }
14570 resObjPtr = Jim_NewStringObj(interp, Jim_String(argv[2]), Jim_Length(argv[2]));
14571 JimSetSourceInfo(interp, resObjPtr, argv[3], line);
14572 }
14573 else {
14574 if (argv[2]->typePtr == &sourceObjType) {
14575 fileNameObj = argv[2]->internalRep.sourceValue.fileNameObj;
14576 line = argv[2]->internalRep.sourceValue.lineNumber;
14577 }
14578 else if (argv[2]->typePtr == &scriptObjType) {
14579 ScriptObj *script = JimGetScript(interp, argv[2]);
14580 fileNameObj = script->fileNameObj;
14581 line = script->firstline;
14582 }
14583 else {
14584 fileNameObj = interp->emptyObj;
14585 line = 1;
14586 }
14587 resObjPtr = Jim_NewListObj(interp, NULL, 0);
14588 Jim_ListAppendElement(interp, resObjPtr, fileNameObj);
14589 Jim_ListAppendElement(interp, resObjPtr, Jim_NewIntObj(interp, line));
14590 }
14591 Jim_SetResult(interp, resObjPtr);
14592 break;
14593 }
14594
14595 case INFO_STACKTRACE:
14596 Jim_SetResult(interp, interp->stackTrace);
14597 break;
14598
14599 case INFO_LEVEL:
14600 case INFO_FRAME:
14601 switch (argc) {
14602 case 2:
14603 Jim_SetResultInt(interp, interp->framePtr->level);
14604 break;
14605
14606 case 3:
14607 if (JimInfoLevel(interp, argv[2], &objPtr, cmd == INFO_LEVEL) != JIM_OK) {
14608 return JIM_ERR;
14609 }
14610 Jim_SetResult(interp, objPtr);
14611 break;
14612
14613 default:
14614 Jim_WrongNumArgs(interp, 2, argv, "?levelNum?");
14615 return JIM_ERR;
14616 }
14617 break;
14618
14619 case INFO_BODY:
14620 case INFO_STATICS:
14621 case INFO_ARGS:{
14622 Jim_Cmd *cmdPtr;
14623
14624 if (argc != 3) {
14625 Jim_WrongNumArgs(interp, 2, argv, "procname");
14626 return JIM_ERR;
14627 }
14628 if ((cmdPtr = Jim_GetCommand(interp, argv[2], JIM_ERRMSG)) == NULL) {
14629 return JIM_ERR;
14630 }
14631 if (!cmdPtr->isproc) {
14632 Jim_SetResultFormatted(interp, "command \"%#s\" is not a procedure", argv[2]);
14633 return JIM_ERR;
14634 }
14635 switch (cmd) {
14636 case INFO_BODY:
14637 Jim_SetResult(interp, cmdPtr->u.proc.bodyObjPtr);
14638 break;
14639 case INFO_ARGS:
14640 Jim_SetResult(interp, cmdPtr->u.proc.argListObjPtr);
14641 break;
14642 case INFO_STATICS:
14643 if (cmdPtr->u.proc.staticVars) {
14644 Jim_SetResult(interp, JimHashtablePatternMatch(interp, cmdPtr->u.proc.staticVars,
14645 NULL, JimVariablesMatch, JIM_VARLIST_LOCALS | JIM_VARLIST_VALUES));
14646 }
14647 break;
14648 }
14649 break;
14650 }
14651
14652 case INFO_VERSION:
14653 case INFO_PATCHLEVEL:{
14654 char buf[(JIM_INTEGER_SPACE * 2) + 1];
14655
14656 sprintf(buf, "%d.%d", JIM_VERSION / 100, JIM_VERSION % 100);
14657 Jim_SetResultString(interp, buf, -1);
14658 break;
14659 }
14660
14661 case INFO_COMPLETE:
14662 if (argc != 3 && argc != 4) {
14663 Jim_WrongNumArgs(interp, 2, argv, "script ?missing?");
14664 return JIM_ERR;
14665 }
14666 else {
14667 char missing;
14668
14669 Jim_SetResultBool(interp, Jim_ScriptIsComplete(interp, argv[2], &missing));
14670 if (missing != ' ' && argc == 4) {
14671 Jim_SetVariable(interp, argv[3], Jim_NewStringObj(interp, &missing, 1));
14672 }
14673 }
14674 break;
14675
14676 case INFO_HOSTNAME:
14677 /* Redirect to os.gethostname if it exists */
14678 return Jim_Eval(interp, "os.gethostname");
14679
14680 case INFO_NAMEOFEXECUTABLE:
14681 /* Redirect to Tcl proc */
14682 return Jim_Eval(interp, "{info nameofexecutable}");
14683
14684 case INFO_RETURNCODES:
14685 if (argc == 2) {
14686 int i;
14687 Jim_Obj *listObjPtr = Jim_NewListObj(interp, NULL, 0);
14688
14689 for (i = 0; jimReturnCodes[i]; i++) {
14690 Jim_ListAppendElement(interp, listObjPtr, Jim_NewIntObj(interp, i));
14691 Jim_ListAppendElement(interp, listObjPtr, Jim_NewStringObj(interp,
14692 jimReturnCodes[i], -1));
14693 }
14694
14695 Jim_SetResult(interp, listObjPtr);
14696 }
14697 else if (argc == 3) {
14698 long code;
14699 const char *name;
14700
14701 if (Jim_GetLong(interp, argv[2], &code) != JIM_OK) {
14702 return JIM_ERR;
14703 }
14704 name = Jim_ReturnCode(code);
14705 if (*name == '?') {
14706 Jim_SetResultInt(interp, code);
14707 }
14708 else {
14709 Jim_SetResultString(interp, name, -1);
14710 }
14711 }
14712 else {
14713 Jim_WrongNumArgs(interp, 2, argv, "?code?");
14714 return JIM_ERR;
14715 }
14716 break;
14717 case INFO_REFERENCES:
14718 #ifdef JIM_REFERENCES
14719 return JimInfoReferences(interp, argc, argv);
14720 #else
14721 Jim_SetResultString(interp, "not supported", -1);
14722 return JIM_ERR;
14723 #endif
14724 }
14725 return JIM_OK;
14726 }
14727
14728 /* [exists] */
14729 static int Jim_ExistsCoreCommand(Jim_Interp *interp, int argc, Jim_Obj *const *argv)
14730 {
14731 Jim_Obj *objPtr;
14732 int result = 0;
14733
14734 static const char * const options[] = {
14735 "-command", "-proc", "-alias", "-var", NULL
14736 };
14737 enum
14738 {
14739 OPT_COMMAND, OPT_PROC, OPT_ALIAS, OPT_VAR
14740 };
14741 int option;
14742
14743 if (argc == 2) {
14744 option = OPT_VAR;
14745 objPtr = argv[1];
14746 }
14747 else if (argc == 3) {
14748 if (Jim_GetEnum(interp, argv[1], options, &option, NULL, JIM_ERRMSG | JIM_ENUM_ABBREV) != JIM_OK) {
14749 return JIM_ERR;
14750 }
14751 objPtr = argv[2];
14752 }
14753 else {
14754 Jim_WrongNumArgs(interp, 1, argv, "?option? name");
14755 return JIM_ERR;
14756 }
14757
14758 if (option == OPT_VAR) {
14759 result = Jim_GetVariable(interp, objPtr, 0) != NULL;
14760 }
14761 else {
14762 /* Now different kinds of commands */
14763 Jim_Cmd *cmd = Jim_GetCommand(interp, objPtr, JIM_NONE);
14764
14765 if (cmd) {
14766 switch (option) {
14767 case OPT_COMMAND:
14768 result = 1;
14769 break;
14770
14771 case OPT_ALIAS:
14772 result = cmd->isproc == 0 && cmd->u.native.cmdProc == JimAliasCmd;
14773 break;
14774
14775 case OPT_PROC:
14776 result = cmd->isproc;
14777 break;
14778 }
14779 }
14780 }
14781 Jim_SetResultBool(interp, result);
14782 return JIM_OK;
14783 }
14784
14785 /* [split] */
14786 static int Jim_SplitCoreCommand(Jim_Interp *interp, int argc, Jim_Obj *const *argv)
14787 {
14788 const char *str, *splitChars, *noMatchStart;
14789 int splitLen, strLen;
14790 Jim_Obj *resObjPtr;
14791 int c;
14792 int len;
14793
14794 if (argc != 2 && argc != 3) {
14795 Jim_WrongNumArgs(interp, 1, argv, "string ?splitChars?");
14796 return JIM_ERR;
14797 }
14798
14799 str = Jim_GetString(argv[1], &len);
14800 if (len == 0) {
14801 return JIM_OK;
14802 }
14803 strLen = Jim_Utf8Length(interp, argv[1]);
14804
14805 /* Init */
14806 if (argc == 2) {
14807 splitChars = " \n\t\r";
14808 splitLen = 4;
14809 }
14810 else {
14811 splitChars = Jim_String(argv[2]);
14812 splitLen = Jim_Utf8Length(interp, argv[2]);
14813 }
14814
14815 noMatchStart = str;
14816 resObjPtr = Jim_NewListObj(interp, NULL, 0);
14817
14818 /* Split */
14819 if (splitLen) {
14820 Jim_Obj *objPtr;
14821 while (strLen--) {
14822 const char *sc = splitChars;
14823 int scLen = splitLen;
14824 int sl = utf8_tounicode(str, &c);
14825 while (scLen--) {
14826 int pc;
14827 sc += utf8_tounicode(sc, &pc);
14828 if (c == pc) {
14829 objPtr = Jim_NewStringObj(interp, noMatchStart, (str - noMatchStart));
14830 Jim_ListAppendElement(interp, resObjPtr, objPtr);
14831 noMatchStart = str + sl;
14832 break;
14833 }
14834 }
14835 str += sl;
14836 }
14837 objPtr = Jim_NewStringObj(interp, noMatchStart, (str - noMatchStart));
14838 Jim_ListAppendElement(interp, resObjPtr, objPtr);
14839 }
14840 else {
14841 /* This handles the special case of splitchars eq {}
14842 * Optimise by sharing common (ASCII) characters
14843 */
14844 Jim_Obj **commonObj = NULL;
14845 #define NUM_COMMON (128 - 9)
14846 while (strLen--) {
14847 int n = utf8_tounicode(str, &c);
14848 #ifdef JIM_OPTIMIZATION
14849 if (c >= 9 && c < 128) {
14850 /* Common ASCII char. Note that 9 is the tab character */
14851 c -= 9;
14852 if (!commonObj) {
14853 commonObj = Jim_Alloc(sizeof(*commonObj) * NUM_COMMON);
14854 memset(commonObj, 0, sizeof(*commonObj) * NUM_COMMON);
14855 }
14856 if (!commonObj[c]) {
14857 commonObj[c] = Jim_NewStringObj(interp, str, 1);
14858 }
14859 Jim_ListAppendElement(interp, resObjPtr, commonObj[c]);
14860 str++;
14861 continue;
14862 }
14863 #endif
14864 Jim_ListAppendElement(interp, resObjPtr, Jim_NewStringObjUtf8(interp, str, 1));
14865 str += n;
14866 }
14867 Jim_Free(commonObj);
14868 }
14869
14870 Jim_SetResult(interp, resObjPtr);
14871 return JIM_OK;
14872 }
14873
14874 /* [join] */
14875 static int Jim_JoinCoreCommand(Jim_Interp *interp, int argc, Jim_Obj *const *argv)
14876 {
14877 const char *joinStr;
14878 int joinStrLen;
14879
14880 if (argc != 2 && argc != 3) {
14881 Jim_WrongNumArgs(interp, 1, argv, "list ?joinString?");
14882 return JIM_ERR;
14883 }
14884 /* Init */
14885 if (argc == 2) {
14886 joinStr = " ";
14887 joinStrLen = 1;
14888 }
14889 else {
14890 joinStr = Jim_GetString(argv[2], &joinStrLen);
14891 }
14892 Jim_SetResult(interp, Jim_ListJoin(interp, argv[1], joinStr, joinStrLen));
14893 return JIM_OK;
14894 }
14895
14896 /* [format] */
14897 static int Jim_FormatCoreCommand(Jim_Interp *interp, int argc, Jim_Obj *const *argv)
14898 {
14899 Jim_Obj *objPtr;
14900
14901 if (argc < 2) {
14902 Jim_WrongNumArgs(interp, 1, argv, "formatString ?arg arg ...?");
14903 return JIM_ERR;
14904 }
14905 objPtr = Jim_FormatString(interp, argv[1], argc - 2, argv + 2);
14906 if (objPtr == NULL)
14907 return JIM_ERR;
14908 Jim_SetResult(interp, objPtr);
14909 return JIM_OK;
14910 }
14911
14912 /* [scan] */
14913 static int Jim_ScanCoreCommand(Jim_Interp *interp, int argc, Jim_Obj *const *argv)
14914 {
14915 Jim_Obj *listPtr, **outVec;
14916 int outc, i;
14917
14918 if (argc < 3) {
14919 Jim_WrongNumArgs(interp, 1, argv, "string format ?varName varName ...?");
14920 return JIM_ERR;
14921 }
14922 if (argv[2]->typePtr != &scanFmtStringObjType)
14923 SetScanFmtFromAny(interp, argv[2]);
14924 if (FormatGetError(argv[2]) != 0) {
14925 Jim_SetResultString(interp, FormatGetError(argv[2]), -1);
14926 return JIM_ERR;
14927 }
14928 if (argc > 3) {
14929 int maxPos = FormatGetMaxPos(argv[2]);
14930 int count = FormatGetCnvCount(argv[2]);
14931
14932 if (maxPos > argc - 3) {
14933 Jim_SetResultString(interp, "\"%n$\" argument index out of range", -1);
14934 return JIM_ERR;
14935 }
14936 else if (count > argc - 3) {
14937 Jim_SetResultString(interp, "different numbers of variable names and "
14938 "field specifiers", -1);
14939 return JIM_ERR;
14940 }
14941 else if (count < argc - 3) {
14942 Jim_SetResultString(interp, "variable is not assigned by any "
14943 "conversion specifiers", -1);
14944 return JIM_ERR;
14945 }
14946 }
14947 listPtr = Jim_ScanString(interp, argv[1], argv[2], JIM_ERRMSG);
14948 if (listPtr == 0)
14949 return JIM_ERR;
14950 if (argc > 3) {
14951 int rc = JIM_OK;
14952 int count = 0;
14953
14954 if (listPtr != 0 && listPtr != (Jim_Obj *)EOF) {
14955 int len = Jim_ListLength(interp, listPtr);
14956
14957 if (len != 0) {
14958 JimListGetElements(interp, listPtr, &outc, &outVec);
14959 for (i = 0; i < outc; ++i) {
14960 if (Jim_Length(outVec[i]) > 0) {
14961 ++count;
14962 if (Jim_SetVariable(interp, argv[3 + i], outVec[i]) != JIM_OK) {
14963 rc = JIM_ERR;
14964 }
14965 }
14966 }
14967 }
14968 Jim_FreeNewObj(interp, listPtr);
14969 }
14970 else {
14971 count = -1;
14972 }
14973 if (rc == JIM_OK) {
14974 Jim_SetResultInt(interp, count);
14975 }
14976 return rc;
14977 }
14978 else {
14979 if (listPtr == (Jim_Obj *)EOF) {
14980 Jim_SetResult(interp, Jim_NewListObj(interp, 0, 0));
14981 return JIM_OK;
14982 }
14983 Jim_SetResult(interp, listPtr);
14984 }
14985 return JIM_OK;
14986 }
14987
14988 /* [error] */
14989 static int Jim_ErrorCoreCommand(Jim_Interp *interp, int argc, Jim_Obj *const *argv)
14990 {
14991 if (argc != 2 && argc != 3) {
14992 Jim_WrongNumArgs(interp, 1, argv, "message ?stacktrace?");
14993 return JIM_ERR;
14994 }
14995 Jim_SetResult(interp, argv[1]);
14996 if (argc == 3) {
14997 JimSetStackTrace(interp, argv[2]);
14998 return JIM_ERR;
14999 }
15000 interp->addStackTrace++;
15001 return JIM_ERR;
15002 }
15003
15004 /* [lrange] */
15005 static int Jim_LrangeCoreCommand(Jim_Interp *interp, int argc, Jim_Obj *const *argv)
15006 {
15007 Jim_Obj *objPtr;
15008
15009 if (argc != 4) {
15010 Jim_WrongNumArgs(interp, 1, argv, "list first last");
15011 return JIM_ERR;
15012 }
15013 if ((objPtr = Jim_ListRange(interp, argv[1], argv[2], argv[3])) == NULL)
15014 return JIM_ERR;
15015 Jim_SetResult(interp, objPtr);
15016 return JIM_OK;
15017 }
15018
15019 /* [lrepeat] */
15020 static int Jim_LrepeatCoreCommand(Jim_Interp *interp, int argc, Jim_Obj *const *argv)
15021 {
15022 Jim_Obj *objPtr;
15023 long count;
15024
15025 if (argc < 2 || Jim_GetLong(interp, argv[1], &count) != JIM_OK || count < 0) {
15026 Jim_WrongNumArgs(interp, 1, argv, "count ?value ...?");
15027 return JIM_ERR;
15028 }
15029
15030 if (count == 0 || argc == 2) {
15031 return JIM_OK;
15032 }
15033
15034 argc -= 2;
15035 argv += 2;
15036
15037 objPtr = Jim_NewListObj(interp, argv, argc);
15038 while (--count) {
15039 ListInsertElements(objPtr, -1, argc, argv);
15040 }
15041
15042 Jim_SetResult(interp, objPtr);
15043 return JIM_OK;
15044 }
15045
15046 char **Jim_GetEnviron(void)
15047 {
15048 #if defined(HAVE__NSGETENVIRON)
15049 return *_NSGetEnviron();
15050 #else
15051 #if !defined(NO_ENVIRON_EXTERN)
15052 extern char **environ;
15053 #endif
15054
15055 return environ;
15056 #endif
15057 }
15058
15059 void Jim_SetEnviron(char **env)
15060 {
15061 #if defined(HAVE__NSGETENVIRON)
15062 *_NSGetEnviron() = env;
15063 #else
15064 #if !defined(NO_ENVIRON_EXTERN)
15065 extern char **environ;
15066 #endif
15067
15068 environ = env;
15069 #endif
15070 }
15071
15072 /* [env] */
15073 static int Jim_EnvCoreCommand(Jim_Interp *interp, int argc, Jim_Obj *const *argv)
15074 {
15075 const char *key;
15076 const char *val;
15077
15078 if (argc == 1) {
15079 char **e = Jim_GetEnviron();
15080
15081 int i;
15082 Jim_Obj *listObjPtr = Jim_NewListObj(interp, NULL, 0);
15083
15084 for (i = 0; e[i]; i++) {
15085 const char *equals = strchr(e[i], '=');
15086
15087 if (equals) {
15088 Jim_ListAppendElement(interp, listObjPtr, Jim_NewStringObj(interp, e[i],
15089 equals - e[i]));
15090 Jim_ListAppendElement(interp, listObjPtr, Jim_NewStringObj(interp, equals + 1, -1));
15091 }
15092 }
15093
15094 Jim_SetResult(interp, listObjPtr);
15095 return JIM_OK;
15096 }
15097
15098 if (argc < 2) {
15099 Jim_WrongNumArgs(interp, 1, argv, "varName ?default?");
15100 return JIM_ERR;
15101 }
15102 key = Jim_String(argv[1]);
15103 val = getenv(key);
15104 if (val == NULL) {
15105 if (argc < 3) {
15106 Jim_SetResultFormatted(interp, "environment variable \"%#s\" does not exist", argv[1]);
15107 return JIM_ERR;
15108 }
15109 val = Jim_String(argv[2]);
15110 }
15111 Jim_SetResult(interp, Jim_NewStringObj(interp, val, -1));
15112 return JIM_OK;
15113 }
15114
15115 /* [source] */
15116 static int Jim_SourceCoreCommand(Jim_Interp *interp, int argc, Jim_Obj *const *argv)
15117 {
15118 int retval;
15119
15120 if (argc != 2) {
15121 Jim_WrongNumArgs(interp, 1, argv, "fileName");
15122 return JIM_ERR;
15123 }
15124 retval = Jim_EvalFile(interp, Jim_String(argv[1]));
15125 if (retval == JIM_RETURN)
15126 return JIM_OK;
15127 return retval;
15128 }
15129
15130 /* [lreverse] */
15131 static int Jim_LreverseCoreCommand(Jim_Interp *interp, int argc, Jim_Obj *const *argv)
15132 {
15133 Jim_Obj *revObjPtr, **ele;
15134 int len;
15135
15136 if (argc != 2) {
15137 Jim_WrongNumArgs(interp, 1, argv, "list");
15138 return JIM_ERR;
15139 }
15140 JimListGetElements(interp, argv[1], &len, &ele);
15141 len--;
15142 revObjPtr = Jim_NewListObj(interp, NULL, 0);
15143 while (len >= 0)
15144 ListAppendElement(revObjPtr, ele[len--]);
15145 Jim_SetResult(interp, revObjPtr);
15146 return JIM_OK;
15147 }
15148
15149 static int JimRangeLen(jim_wide start, jim_wide end, jim_wide step)
15150 {
15151 jim_wide len;
15152
15153 if (step == 0)
15154 return -1;
15155 if (start == end)
15156 return 0;
15157 else if (step > 0 && start > end)
15158 return -1;
15159 else if (step < 0 && end > start)
15160 return -1;
15161 len = end - start;
15162 if (len < 0)
15163 len = -len; /* abs(len) */
15164 if (step < 0)
15165 step = -step; /* abs(step) */
15166 len = 1 + ((len - 1) / step);
15167 /* We can truncate safely to INT_MAX, the range command
15168 * will always return an error for a such long range
15169 * because Tcl lists can't be so long. */
15170 if (len > INT_MAX)
15171 len = INT_MAX;
15172 return (int)((len < 0) ? -1 : len);
15173 }
15174
15175 /* [range] */
15176 static int Jim_RangeCoreCommand(Jim_Interp *interp, int argc, Jim_Obj *const *argv)
15177 {
15178 jim_wide start = 0, end, step = 1;
15179 int len, i;
15180 Jim_Obj *objPtr;
15181
15182 if (argc < 2 || argc > 4) {
15183 Jim_WrongNumArgs(interp, 1, argv, "?start? end ?step?");
15184 return JIM_ERR;
15185 }
15186 if (argc == 2) {
15187 if (Jim_GetWide(interp, argv[1], &end) != JIM_OK)
15188 return JIM_ERR;
15189 }
15190 else {
15191 if (Jim_GetWide(interp, argv[1], &start) != JIM_OK ||
15192 Jim_GetWide(interp, argv[2], &end) != JIM_OK)
15193 return JIM_ERR;
15194 if (argc == 4 && Jim_GetWide(interp, argv[3], &step) != JIM_OK)
15195 return JIM_ERR;
15196 }
15197 if ((len = JimRangeLen(start, end, step)) == -1) {
15198 Jim_SetResultString(interp, "Invalid (infinite?) range specified", -1);
15199 return JIM_ERR;
15200 }
15201 objPtr = Jim_NewListObj(interp, NULL, 0);
15202 for (i = 0; i < len; i++)
15203 ListAppendElement(objPtr, Jim_NewIntObj(interp, start + i * step));
15204 Jim_SetResult(interp, objPtr);
15205 return JIM_OK;
15206 }
15207
15208 /* [rand] */
15209 static int Jim_RandCoreCommand(Jim_Interp *interp, int argc, Jim_Obj *const *argv)
15210 {
15211 jim_wide min = 0, max = 0, len, maxMul;
15212
15213 if (argc < 1 || argc > 3) {
15214 Jim_WrongNumArgs(interp, 1, argv, "?min? max");
15215 return JIM_ERR;
15216 }
15217 if (argc == 1) {
15218 max = JIM_WIDE_MAX;
15219 } else if (argc == 2) {
15220 if (Jim_GetWide(interp, argv[1], &max) != JIM_OK)
15221 return JIM_ERR;
15222 } else if (argc == 3) {
15223 if (Jim_GetWide(interp, argv[1], &min) != JIM_OK ||
15224 Jim_GetWide(interp, argv[2], &max) != JIM_OK)
15225 return JIM_ERR;
15226 }
15227 len = max-min;
15228 if (len < 0) {
15229 Jim_SetResultString(interp, "Invalid arguments (max < min)", -1);
15230 return JIM_ERR;
15231 }
15232 maxMul = JIM_WIDE_MAX - (len ? (JIM_WIDE_MAX%len) : 0);
15233 while (1) {
15234 jim_wide r;
15235
15236 JimRandomBytes(interp, &r, sizeof(jim_wide));
15237 if (r < 0 || r >= maxMul) continue;
15238 r = (len == 0) ? 0 : r%len;
15239 Jim_SetResultInt(interp, min+r);
15240 return JIM_OK;
15241 }
15242 }
15243
15244 static const struct {
15245 const char *name;
15246 Jim_CmdProc *cmdProc;
15247 } Jim_CoreCommandsTable[] = {
15248 {"alias", Jim_AliasCoreCommand},
15249 {"set", Jim_SetCoreCommand},
15250 {"unset", Jim_UnsetCoreCommand},
15251 {"puts", Jim_PutsCoreCommand},
15252 {"+", Jim_AddCoreCommand},
15253 {"*", Jim_MulCoreCommand},
15254 {"-", Jim_SubCoreCommand},
15255 {"/", Jim_DivCoreCommand},
15256 {"incr", Jim_IncrCoreCommand},
15257 {"while", Jim_WhileCoreCommand},
15258 {"loop", Jim_LoopCoreCommand},
15259 {"for", Jim_ForCoreCommand},
15260 {"foreach", Jim_ForeachCoreCommand},
15261 {"lmap", Jim_LmapCoreCommand},
15262 {"lassign", Jim_LassignCoreCommand},
15263 {"if", Jim_IfCoreCommand},
15264 {"switch", Jim_SwitchCoreCommand},
15265 {"list", Jim_ListCoreCommand},
15266 {"lindex", Jim_LindexCoreCommand},
15267 {"lset", Jim_LsetCoreCommand},
15268 {"lsearch", Jim_LsearchCoreCommand},
15269 {"llength", Jim_LlengthCoreCommand},
15270 {"lappend", Jim_LappendCoreCommand},
15271 {"linsert", Jim_LinsertCoreCommand},
15272 {"lreplace", Jim_LreplaceCoreCommand},
15273 {"lsort", Jim_LsortCoreCommand},
15274 {"append", Jim_AppendCoreCommand},
15275 {"debug", Jim_DebugCoreCommand},
15276 {"eval", Jim_EvalCoreCommand},
15277 {"uplevel", Jim_UplevelCoreCommand},
15278 {"expr", Jim_ExprCoreCommand},
15279 {"break", Jim_BreakCoreCommand},
15280 {"continue", Jim_ContinueCoreCommand},
15281 {"proc", Jim_ProcCoreCommand},
15282 {"concat", Jim_ConcatCoreCommand},
15283 {"return", Jim_ReturnCoreCommand},
15284 {"upvar", Jim_UpvarCoreCommand},
15285 {"global", Jim_GlobalCoreCommand},
15286 {"string", Jim_StringCoreCommand},
15287 {"time", Jim_TimeCoreCommand},
15288 {"exit", Jim_ExitCoreCommand},
15289 {"catch", Jim_CatchCoreCommand},
15290 #ifdef JIM_REFERENCES
15291 {"ref", Jim_RefCoreCommand},
15292 {"getref", Jim_GetrefCoreCommand},
15293 {"setref", Jim_SetrefCoreCommand},
15294 {"finalize", Jim_FinalizeCoreCommand},
15295 {"collect", Jim_CollectCoreCommand},
15296 #endif
15297 {"rename", Jim_RenameCoreCommand},
15298 {"dict", Jim_DictCoreCommand},
15299 {"subst", Jim_SubstCoreCommand},
15300 {"info", Jim_InfoCoreCommand},
15301 {"exists", Jim_ExistsCoreCommand},
15302 {"split", Jim_SplitCoreCommand},
15303 {"join", Jim_JoinCoreCommand},
15304 {"format", Jim_FormatCoreCommand},
15305 {"scan", Jim_ScanCoreCommand},
15306 {"error", Jim_ErrorCoreCommand},
15307 {"lrange", Jim_LrangeCoreCommand},
15308 {"lrepeat", Jim_LrepeatCoreCommand},
15309 {"env", Jim_EnvCoreCommand},
15310 {"source", Jim_SourceCoreCommand},
15311 {"lreverse", Jim_LreverseCoreCommand},
15312 {"range", Jim_RangeCoreCommand},
15313 {"rand", Jim_RandCoreCommand},
15314 {"tailcall", Jim_TailcallCoreCommand},
15315 {"local", Jim_LocalCoreCommand},
15316 {"upcall", Jim_UpcallCoreCommand},
15317 {"apply", Jim_ApplyCoreCommand},
15318 {NULL, NULL},
15319 };
15320
15321 void Jim_RegisterCoreCommands(Jim_Interp *interp)
15322 {
15323 int i = 0;
15324
15325 while (Jim_CoreCommandsTable[i].name != NULL) {
15326 Jim_CreateCommand(interp,
15327 Jim_CoreCommandsTable[i].name, Jim_CoreCommandsTable[i].cmdProc, NULL, NULL);
15328 i++;
15329 }
15330 }
15331
15332 /* -----------------------------------------------------------------------------
15333 * Interactive prompt
15334 * ---------------------------------------------------------------------------*/
15335 void Jim_MakeErrorMessage(Jim_Interp *interp)
15336 {
15337 Jim_Obj *argv[2];
15338
15339 argv[0] = Jim_NewStringObj(interp, "errorInfo", -1);
15340 argv[1] = interp->result;
15341
15342 Jim_EvalObjVector(interp, 2, argv);
15343 }
15344
15345 /*
15346 * Given a null terminated array of strings, returns an allocated, sorted
15347 * copy of the array.
15348 */
15349 static char **JimSortStringTable(const char *const *tablePtr)
15350 {
15351 int count;
15352 char **tablePtrSorted;
15353
15354 /* Find the size of the table */
15355 for (count = 0; tablePtr[count]; count++) {
15356 }
15357
15358 /* Allocate one extra for the terminating NULL pointer */
15359 tablePtrSorted = Jim_Alloc(sizeof(char *) * (count + 1));
15360 memcpy(tablePtrSorted, tablePtr, sizeof(char *) * count);
15361 qsort(tablePtrSorted, count, sizeof(char *), qsortCompareStringPointers);
15362 tablePtrSorted[count] = NULL;
15363
15364 return tablePtrSorted;
15365 }
15366
15367 static void JimSetFailedEnumResult(Jim_Interp *interp, const char *arg, const char *badtype,
15368 const char *prefix, const char *const *tablePtr, const char *name)
15369 {
15370 char **tablePtrSorted;
15371 int i;
15372
15373 if (name == NULL) {
15374 name = "option";
15375 }
15376
15377 Jim_SetResultFormatted(interp, "%s%s \"%s\": must be ", badtype, name, arg);
15378 tablePtrSorted = JimSortStringTable(tablePtr);
15379 for (i = 0; tablePtrSorted[i]; i++) {
15380 if (tablePtrSorted[i + 1] == NULL && i > 0) {
15381 Jim_AppendString(interp, Jim_GetResult(interp), "or ", -1);
15382 }
15383 Jim_AppendStrings(interp, Jim_GetResult(interp), prefix, tablePtrSorted[i], NULL);
15384 if (tablePtrSorted[i + 1]) {
15385 Jim_AppendString(interp, Jim_GetResult(interp), ", ", -1);
15386 }
15387 }
15388 Jim_Free(tablePtrSorted);
15389 }
15390
15391
15392 /*
15393 * If objPtr is "-commands" sets the Jim result as a sorted list of options in the table
15394 * and returns JIM_OK.
15395 *
15396 * Otherwise returns JIM_ERR.
15397 */
15398 int Jim_CheckShowCommands(Jim_Interp *interp, Jim_Obj *objPtr, const char *const *tablePtr)
15399 {
15400 if (Jim_CompareStringImmediate(interp, objPtr, "-commands")) {
15401 int i;
15402 char **tablePtrSorted = JimSortStringTable(tablePtr);
15403 Jim_SetResult(interp, Jim_NewListObj(interp, NULL, 0));
15404 for (i = 0; tablePtrSorted[i]; i++) {
15405 Jim_ListAppendElement(interp, Jim_GetResult(interp), Jim_NewStringObj(interp, tablePtrSorted[i], -1));
15406 }
15407 Jim_Free(tablePtrSorted);
15408 return JIM_OK;
15409 }
15410 return JIM_ERR;
15411 }
15412
15413 /* internal rep is stored in ptrIntvalue
15414 * ptr = tablePtr
15415 * int1 = flags
15416 * int2 = index
15417 */
15418 static const Jim_ObjType getEnumObjType = {
15419 "get-enum",
15420 NULL,
15421 NULL,
15422 NULL,
15423 JIM_TYPE_REFERENCES
15424 };
15425
15426 int Jim_GetEnum(Jim_Interp *interp, Jim_Obj *objPtr,
15427 const char *const *tablePtr, int *indexPtr, const char *name, int flags)
15428 {
15429 const char *bad = "bad ";
15430 const char *const *entryPtr = NULL;
15431 int i;
15432 int match = -1;
15433 int arglen;
15434 const char *arg;
15435
15436 if (objPtr->typePtr == &getEnumObjType) {
15437 if (objPtr->internalRep.ptrIntValue.ptr == tablePtr && objPtr->internalRep.ptrIntValue.int1 == flags) {
15438 *indexPtr = objPtr->internalRep.ptrIntValue.int2;
15439 return JIM_OK;
15440 }
15441 }
15442
15443 arg = Jim_GetString(objPtr, &arglen);
15444
15445 *indexPtr = -1;
15446
15447 for (entryPtr = tablePtr, i = 0; *entryPtr != NULL; entryPtr++, i++) {
15448 if (Jim_CompareStringImmediate(interp, objPtr, *entryPtr)) {
15449 /* Found an exact match */
15450 match = i;
15451 goto found;
15452 }
15453 if (flags & JIM_ENUM_ABBREV) {
15454 /* Accept an unambiguous abbreviation.
15455 * Note that '-' doesnt' consitute a valid abbreviation
15456 */
15457 if (strncmp(arg, *entryPtr, arglen) == 0) {
15458 if (*arg == '-' && arglen == 1) {
15459 break;
15460 }
15461 if (match >= 0) {
15462 bad = "ambiguous ";
15463 goto ambiguous;
15464 }
15465 match = i;
15466 }
15467 }
15468 }
15469
15470 /* If we had an unambiguous partial match */
15471 if (match >= 0) {
15472 found:
15473 /* Record the match in the object */
15474 Jim_FreeIntRep(interp, objPtr);
15475 objPtr->typePtr = &getEnumObjType;
15476 objPtr->internalRep.ptrIntValue.ptr = (void *)tablePtr;
15477 objPtr->internalRep.ptrIntValue.int1 = flags;
15478 objPtr->internalRep.ptrIntValue.int2 = match;
15479 /* Return the result */
15480 *indexPtr = match;
15481 return JIM_OK;
15482 }
15483
15484 ambiguous:
15485 if (flags & JIM_ERRMSG) {
15486 JimSetFailedEnumResult(interp, arg, bad, "", tablePtr, name);
15487 }
15488 return JIM_ERR;
15489 }
15490
15491 int Jim_FindByName(const char *name, const char * const array[], size_t len)
15492 {
15493 int i;
15494
15495 for (i = 0; i < (int)len; i++) {
15496 if (array[i] && strcmp(array[i], name) == 0) {
15497 return i;
15498 }
15499 }
15500 return -1;
15501 }
15502
15503 int Jim_IsDict(Jim_Obj *objPtr)
15504 {
15505 return objPtr->typePtr == &dictObjType;
15506 }
15507
15508 int Jim_IsList(Jim_Obj *objPtr)
15509 {
15510 return objPtr->typePtr == &listObjType;
15511 }
15512
15513 /**
15514 * Very simple printf-like formatting, designed for error messages.
15515 *
15516 * The format may contain up to 5 '%s' or '%#s', corresponding to variable arguments.
15517 * The resulting string is created and set as the result.
15518 *
15519 * Each '%s' should correspond to a regular string parameter.
15520 * Each '%#s' should correspond to a (Jim_Obj *) parameter.
15521 * Any other printf specifier is not allowed (but %% is allowed for the % character).
15522 *
15523 * e.g. Jim_SetResultFormatted(interp, "Bad option \"%#s\" in proc \"%#s\"", optionObjPtr, procNamePtr);
15524 *
15525 * Note: We take advantage of the fact that printf has the same behaviour for both %s and %#s
15526 *
15527 * Note that any Jim_Obj parameters with zero ref count will be freed as a result of this call.
15528 */
15529 void Jim_SetResultFormatted(Jim_Interp *interp, const char *format, ...)
15530 {
15531 /* Initial space needed */
15532 int len = strlen(format);
15533 int extra = 0;
15534 int n = 0;
15535 const char *params[5];
15536 int nobjparam = 0;
15537 Jim_Obj *objparam[5];
15538 char *buf;
15539 va_list args;
15540 int i;
15541
15542 va_start(args, format);
15543
15544 for (i = 0; i < len && n < 5; i++) {
15545 int l;
15546
15547 if (strncmp(format + i, "%s", 2) == 0) {
15548 params[n] = va_arg(args, char *);
15549
15550 l = strlen(params[n]);
15551 }
15552 else if (strncmp(format + i, "%#s", 3) == 0) {
15553 Jim_Obj *objPtr = va_arg(args, Jim_Obj *);
15554
15555 params[n] = Jim_GetString(objPtr, &l);
15556 objparam[nobjparam++] = objPtr;
15557 Jim_IncrRefCount(objPtr);
15558 }
15559 else {
15560 if (format[i] == '%') {
15561 i++;
15562 }
15563 continue;
15564 }
15565 n++;
15566 extra += l;
15567 }
15568
15569 len += extra;
15570 buf = Jim_Alloc(len + 1);
15571 len = snprintf(buf, len + 1, format, params[0], params[1], params[2], params[3], params[4]);
15572
15573 va_end(args);
15574
15575 Jim_SetResult(interp, Jim_NewStringObjNoAlloc(interp, buf, len));
15576
15577 for (i = 0; i < nobjparam; i++) {
15578 Jim_DecrRefCount(interp, objparam[i]);
15579 }
15580 }
15581
15582 /* stubs */
15583 #ifndef jim_ext_package
15584 int Jim_PackageProvide(Jim_Interp *interp, const char *name, const char *ver, int flags)
15585 {
15586 return JIM_OK;
15587 }
15588 #endif
15589 #ifndef jim_ext_aio
15590 FILE *Jim_AioFilehandle(Jim_Interp *interp, Jim_Obj *fhObj)
15591 {
15592 Jim_SetResultString(interp, "aio not enabled", -1);
15593 return NULL;
15594 }
15595 #endif
15596
15597
15598 /*
15599 * Local Variables: ***
15600 * c-basic-offset: 4 ***
15601 * tab-width: 4 ***
15602 * End: ***
15603 */
Jim Tcl project