| blob | 736a89258f5e5a721b2038cb7c906e5e3d84cce9 |
1 /* String search routines for GNU Emacs.
2 Copyright (C) 1985, 1986, 1987, 1993, 1994, 1997, 1998, 1999, 2001, 2002,
3 2003, 2004, 2005, 2006, 2007, 2008, 2009, 2010
4 Free Software Foundation, Inc.
6 This file is part of GNU Emacs.
8 GNU Emacs is free software: you can redistribute it and/or modify
9 it under the terms of the GNU General Public License as published by
10 the Free Software Foundation, either version 3 of the License, or
11 (at your option) any later version.
13 GNU Emacs is distributed in the hope that it will be useful,
14 but WITHOUT ANY WARRANTY; without even the implied warranty of
15 MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
16 GNU General Public License for more details.
18 You should have received a copy of the GNU General Public License
19 along with GNU Emacs. If not, see <http://www.gnu.org/licenses/>. */
22 #include <config.h>
23 #include <setjmp.h>
35 #include <sys/types.h>
38 #define REGEXP_CACHE_SIZE 20
40 /* If the regexp is non-nil, then the buffer contains the compiled form
41 of that regexp, suitable for searching. */
42 struct regexp_cache
43 {
46 /* Syntax table for which the regexp applies. We need this because
47 of character classes. If this is t, then the compiled pattern is valid
48 for any syntax-table. */
49 Lisp_Object syntax_table;
52 /* Nonzero means regexp was compiled to do full POSIX backtracking. */
54 };
56 /* The instances of that struct. */
59 /* The head of the linked list; points to the most recently used buffer. */
63 /* Every call to re_match, etc., must pass &search_regs as the regs
64 argument unless you can show it is unnecessary (i.e., if re_match
65 is certainly going to be called again before region-around-match
66 can be called).
68 Since the registers are now dynamically allocated, we need to make
69 sure not to refer to the Nth register before checking that it has
70 been allocated by checking search_regs.num_regs.
72 The regex code keeps track of whether it has allocated the search
73 buffer using bits in the re_pattern_buffer. This means that whenever
74 you compile a new pattern, it completely forgets whether it has
75 allocated any registers, and will allocate new registers the next
76 time you call a searching or matching function. Therefore, we need
77 to call re_set_registers after compiling a new pattern or after
78 setting the match registers, so that the regex functions will be
79 able to free or re-allocate it properly. */
82 /* The buffer in which the last search was performed, or
83 Qt if the last search was done in a string;
84 Qnil if no searching has been done yet. */
87 /* error condition signaled when regexp compile_pattern fails */
89 Lisp_Object Qinvalid_regexp;
91 /* Error condition used for failing searches */
92 Lisp_Object Qsearch_failed;
94 Lisp_Object Vsearch_spaces_regexp;
96 /* If non-nil, the match data will not be changed during call to
97 searching or matching functions. This variable is for internal use
98 only. */
99 Lisp_Object Vinhibit_changing_match_data;
115 static void
117 {
119 }
121 /* Compile a regexp and signal a Lisp error if anything goes wrong.
122 PATTERN is the pattern to compile.
123 CP is the place to put the result.
124 TRANSLATE is a translation table for ignoring case, or nil for none.
125 REGP is the structure that says where to store the "register"
126 values that will result from matching this pattern.
127 If it is 0, we should compile the pattern not to record any
128 subexpression bounds.
129 POSIX is nonzero if we want full backtracking (POSIX style)
130 for this pattern. 0 means backtrack only enough to get a valid match.
132 The behavior also depends on Vsearch_spaces_regexp. */
134 static void
137 Lisp_Object pattern;
138 Lisp_Object translate;
141 {
143 reg_syntax_t old;
152 else
155 /* rms: I think BLOCK_INPUT is not needed here any more,
156 because regex.c defines malloc to call xmalloc.
157 Using BLOCK_INPUT here means the debugger won't run if an error occurs.
158 So let's turn it off. */
159 /* BLOCK_INPUT; */
165 else
171 /* If the compiled pattern hard codes some of the contents of the
172 syntax-table, it can only be reused with *this* syntax table. */
178 /* UNBLOCK_INPUT; */
183 }
185 /* Shrink each compiled regexp buffer in the cache
186 to the size actually used right now.
187 This is called from garbage collection. */
189 void
191 {
195 {
199 }
200 }
202 /* Clear the regexp cache w.r.t. a particular syntax table,
203 because it was changed.
204 There is no danger of memory leak here because re_compile_pattern
205 automagically manages the memory in each re_pattern_buffer struct,
206 based on its `allocated' and `buffer' values. */
207 void
209 {
213 /* It's tempting to compare with the syntax-table we've actually changed,
214 but it's not sufficient because char-table inheritance means that
215 modifying one syntax-table can change others at the same time. */
218 }
220 /* Compile a regexp if necessary, but first check to see if there's one in
221 the cache.
222 PATTERN is the pattern to compile.
223 TRANSLATE is a translation table for ignoring case, or nil for none.
224 REGP is the structure that says where to store the "register"
225 values that will result from matching this pattern.
226 If it is 0, we should compile the pattern not to record any
227 subexpression bounds.
228 POSIX is nonzero if we want full backtracking (POSIX style)
229 for this pattern. 0 means backtrack only enough to get a valid match. */
233 Lisp_Object pattern;
235 Lisp_Object translate;
237 {
241 {
243 /* Entries are initialized to nil, and may be set to nil by
244 compile_pattern_1 if the pattern isn't valid. Don't apply
245 string accessors in those cases. However, compile_pattern_1
246 is only applied to the cache entry we pick here to reuse. So
247 nil should never appear before a non-nil entry. */
261 /* If we're at the end of the cache, compile into the nil cell
262 we found, or the last (least recently used) cell with a
263 string value. */
265 {
266 compile_it:
269 }
270 }
272 /* When we get here, cp (aka *cpp) contains the compiled pattern,
273 either because we found it in the cache or because we just compiled it.
274 Move it to the front of the queue to mark it as most recently used. */
279 /* Advise the searching functions about the space we have allocated
280 for register data. */
284 /* The compiled pattern can be used both for multibyte and unibyte
285 target. But, we have to tell which the pattern is used for. */
289 }
291 \f
292 static Lisp_Object
294 Lisp_Object string;
296 {
297 Lisp_Object val;
306 /* This is so set_image_of_range_1 in regex.c can find the EQV table. */
316 posix,
322 /* Get pointers and sizes of the two strings
323 that make up the visible portion of the buffer. */
330 {
334 }
336 {
339 }
357 {
362 }
364 /* Set last_thing_searched only when match data is changed. */
369 }
373 This function modifies the match data that `match-beginning',
374 `match-end' and `match-data' access; save and restore the match
377 Lisp_Object regexp;
378 {
380 }
384 Find the longest match, in accord with Posix regular expression rules.
385 This function modifies the match data that `match-beginning',
386 `match-end' and `match-data' access; save and restore the match
389 Lisp_Object regexp;
390 {
392 }
393 \f
394 static Lisp_Object
398 {
412 else
413 {
423 }
425 /* This is so set_image_of_range_1 in regex.c can find the EQV table. */
434 posix,
446 /* Set last_thing_searched only when match data is changed. */
457 {
462 }
465 }
469 Matching ignores case if `case-fold-search' is non-nil.
470 If third arg START is non-nil, start search at that index in STRING.
471 For index of first char beyond the match, do (match-end 0).
472 `match-end' and `match-beginning' also give indices of substrings
473 matched by parenthesis constructs in the pattern.
475 You can use the function `match-string' to extract the substrings
479 {
481 }
485 Find the longest match, in accord with Posix regular expression rules.
486 Case is ignored if `case-fold-search' is non-nil in the current buffer.
487 If third arg START is non-nil, start search at that index in STRING.
488 For index of first char beyond the match, do (match-end 0).
489 `match-end' and `match-beginning' also give indices of substrings
493 {
495 }
497 /* Match REGEXP against STRING, searching all of STRING,
498 and return the index of the match, or negative on failure.
499 This does not clobber the match data. */
501 int
504 {
518 }
520 /* Match REGEXP against STRING, searching all of STRING ignoring case,
521 and return the index of the match, or negative on failure.
522 This does not clobber the match data.
523 We assume that STRING contains single-byte characters. */
527 int
529 Lisp_Object regexp;
531 {
545 }
547 /* Like fast_string_match but ignore case. */
549 int
552 {
566 }
567 \f
568 /* Match REGEXP against the characters after POS to LIMIT, and return
569 the number of matched characters. If STRING is non-nil, match
570 against the characters in it. In that case, POS and LIMIT are
571 indices into the string. This function doesn't modify the match
572 data. */
574 EMACS_INT
576 Lisp_Object regexp;
578 Lisp_Object string;
579 {
584 EMACS_INT len;
587 {
598 }
599 else
600 {
612 {
616 }
618 {
621 }
624 }
633 }
635 \f
636 /* The newline cache: remembering which sections of text have no newlines. */
638 /* If the user has requested newline caching, make sure it's on.
639 Otherwise, make sure it's off.
640 This is our cheezy way of associating an action with the change of
641 state of a buffer-local variable. */
642 static void
645 {
647 {
648 /* It should be off. */
650 {
653 }
654 }
655 else
656 {
657 /* It should be on. */
660 }
661 }
663 \f
664 /* Search for COUNT instances of the character TARGET between START and END.
666 If COUNT is positive, search forwards; END must be >= START.
667 If COUNT is negative, search backwards for the -COUNTth instance;
668 END must be <= START.
669 If COUNT is zero, do anything you please; run rogue, for all I care.
671 If END is zero, use BEGV or ZV instead, as appropriate for the
672 direction indicated by COUNT.
674 If we find COUNT instances, set *SHORTAGE to zero, and return the
675 position past the COUNTth match. Note that for reverse motion
676 this is not the same as the usual convention for Emacs motion commands.
678 If we don't find COUNT instances before reaching END, set *SHORTAGE
679 to the number of TARGETs left unfound, and return END.
681 If ALLOW_QUIT is non-zero, set immediate_quit. That's good to do
682 except when inside redisplay. */
684 int
691 {
696 {
699 }
700 else
701 {
704 }
716 {
717 /* Our innermost scanning loop is very simple; it doesn't know
718 about gaps, buffer ends, or the newline cache. ceiling is
719 the position of the last character before the next such
720 obstacle --- the last character the dumb search loop should
721 examine. */
724 EMACS_INT tem;
726 /* If we're looking for a newline, consult the newline cache
727 to see where we can avoid some scanning. */
729 {
737 /* START should never be after END. */
741 /* Now the text after start is an unknown region, and
742 next_change is the position of the next known region. */
744 }
746 /* The dumb loop can only scan text stored in contiguous
747 bytes. BUFFER_CEILING_OF returns the last character
748 position that is contiguous, so the ceiling is the
749 position after that. */
753 {
754 /* The termination address of the dumb loop. */
762 {
765 /* The dumb loop. */
767 ;
769 /* If we're looking for newlines, cache the fact that
770 the region from start to cursor is free of them. */
776 /* Did we find the target character? */
778 {
780 {
783 }
784 cursor++;
785 }
786 }
789 }
790 }
791 else
793 {
794 /* The last character to check before the next obstacle. */
797 EMACS_INT tem;
799 /* Consult the newline cache, if appropriate. */
801 {
809 /* Start should never be at or before end. */
813 /* Now the text before start is an unknown region, and
814 next_change is the position of the next known region. */
816 }
818 /* Stop scanning before the gap. */
822 {
823 /* The termination address of the dumb loop. */
829 {
833 ;
835 /* If we're looking for newlines, cache the fact that
836 the region from after the cursor to start is free of them. */
842 /* Did we find the target character? */
844 {
846 {
849 }
850 cursor--;
851 }
852 }
855 }
856 }
862 }
863 \f
864 /* Search for COUNT instances of a line boundary, which means either a
865 newline or (if selective display enabled) a carriage return.
866 Start at START. If COUNT is negative, search backwards.
868 We report the resulting position by calling TEMP_SET_PT_BOTH.
870 If we find COUNT instances. we position after (always after,
871 even if scanning backwards) the COUNTth match, and return 0.
873 If we don't find COUNT instances before reaching the end of the
874 buffer (or the beginning, if scanning backwards), we return
875 the number of line boundaries left unfound, and position at
876 the limit we bumped up against.
878 If ALLOW_QUIT is non-zero, set immediate_quit. That's good to do
879 except in special cases. */
881 int
887 {
893 EMACS_INT ceiling;
898 /* The code that follows is like scan_buffer
899 but checks for either newline or carriage return. */
902 immediate_quit++;
907 {
909 {
915 {
917 ;
920 {
922 {
928 }
929 else
932 }
933 else
935 }
937 }
938 }
939 else
940 {
942 {
948 {
950 ;
953 {
955 {
957 /* Return the position AFTER the match we found. */
962 }
963 }
964 else
966 }
967 /* Here we add 1 to compensate for the last decrement
968 of CURSOR, which took it past the valid range. */
970 }
971 }
977 }
979 int
981 EMACS_INT from;
983 {
985 }
987 /* Like find_next_newline, but returns position before the newline,
988 not after, and only search up to TO. This isn't just
989 find_next_newline (...)-1, because you might hit TO. */
991 int
995 {
1000 pos--;
1003 }
1004 \f
1005 /* Subroutines of Lisp buffer search functions. */
1007 static Lisp_Object
1013 {
1019 {
1022 }
1026 {
1029 else
1031 }
1032 else
1033 {
1042 else
1044 }
1046 /* This is so set_image_of_range_1 in regex.c can find the EQV table. */
1057 posix);
1059 {
1064 {
1070 a value of nil here. */
1072 #endif
1073 }
1074 else
1076 }
1084 }
1085 \f
1086 /* Return 1 if REGEXP it matches just one constant string. */
1088 static int
1090 Lisp_Object regexp;
1091 {
1095 {
1097 {
1104 {
1112 }
1113 }
1114 }
1116 }
1118 /* Search for the n'th occurrence of STRING in the current buffer,
1119 starting at position POS and stopping at position LIM,
1120 treating STRING as a literal string if RE is false or as
1121 a regular expression if RE is true.
1123 If N is positive, searching is forward and LIM must be greater than POS.
1124 If N is negative, searching is backward and LIM must be less than POS.
1126 Returns -x if x occurrences remain to be found (x > 0),
1127 or else the position at the beginning of the Nth occurrence
1128 (if searching backward) or the end (if searching forward).
1130 POSIX is nonzero if we want full backtracking (POSIX style)
1131 for this pattern. 0 means backtrack only enough to get a valid match. */
1133 #define TRANSLATE(out, trt, d) \
1134 do \
1135 { \
1136 if (! NILP (trt)) \
1137 { \
1138 Lisp_Object temp; \
1139 temp = Faref (trt, make_number (d)); \
1140 if (INTEGERP (temp)) \
1141 out = XINT (temp); \
1142 else \
1143 out = d; \
1144 } \
1145 else \
1146 out = d; \
1147 } \
1148 while (0)
1150 /* Only used in search_buffer, to record the end position of the match
1151 when searching regexps and SEARCH_REGS should not be changed
1152 (i.e. Vinhibit_changing_match_data is non-nil). */
1155 static EMACS_INT
1158 Lisp_Object string;
1159 EMACS_INT pos;
1160 EMACS_INT pos_byte;
1161 EMACS_INT lim;
1162 EMACS_INT lim_byte;
1165 Lisp_Object trt;
1166 Lisp_Object inverse_trt;
1168 {
1176 /* Searching 0 times means don't move. */
1177 /* Null string is found at starting position. */
1179 {
1182 }
1185 {
1197 because letting this function finish
1198 can take too long. */
1200 to avoid paradoxical behavior */
1201 /* Get pointers and sizes of the two strings
1202 that make up the visible portion of the buffer. */
1209 {
1213 }
1215 {
1218 }
1222 {
1228 /* Don't allow match past current point */
1231 {
1233 }
1235 {
1237 {
1241 {
1246 }
1248 /* Set pos to the new position. */
1250 }
1251 else
1252 {
1254 /* Set pos to the new position. */
1256 }
1257 }
1258 else
1259 {
1262 }
1263 n++;
1264 }
1266 {
1274 {
1276 }
1278 {
1280 {
1284 {
1289 }
1292 }
1293 else
1294 {
1297 }
1298 }
1299 else
1300 {
1303 }
1304 n--;
1305 }
1308 }
1310 {
1317 /* Set to positive if we find a non-ASCII char that need
1318 translation. Otherwise set to zero later. */
1322 /* MULTIBYTE says whether the text to be searched is multibyte.
1323 We must convert PATTERN to match that, or we will not really
1324 find things right. */
1327 {
1331 }
1333 {
1335 raw_pattern_size_byte
1337 raw_pattern_size);
1341 }
1342 else
1343 {
1344 /* Converting multibyte to single-byte.
1346 ??? Perhaps this conversion should be done in a special way
1347 by subtracting nonascii-insert-offset from each non-ASCII char,
1348 so that only the multibyte chars which really correspond to
1349 the chosen single-byte character set can possibly match. */
1355 }
1357 /* Copy and optionally translate the pattern. */
1364 {
1365 /* Fill patbuf by translated characters in STRING while
1366 checking if we can use boyer-moore search. If TRT is
1367 non-nil, we can use boyer-moore search only if TRT can be
1368 represented by the byte array of 256 elements. For that,
1369 all non-ASCII case-equivalents of all case-senstive
1370 characters in STRING must belong to the same charset and
1371 row. */
1374 {
1379 /* If we got here and the RE flag is set, it's because we're
1380 dealing with a regexp known to be trivial, so the backslash
1381 just quotes the next character. */
1383 {
1384 len--;
1385 raw_pattern_size--;
1386 len_byte--;
1387 base_pat++;
1388 }
1393 {
1396 }
1397 else
1398 {
1399 /* Translate the character. */
1404 /* Check if C has any other case-equivalents. */
1406 /* If so, check if we can use boyer-moore. */
1408 {
1409 /* Check if all equivalents belong to the same
1410 group of characters. Note that the check of C
1411 itself is done by the last iteration. */
1415 {
1417 {
1420 else
1422 }
1424 /* Boyer-moore search can't handle a
1425 translation of an eight-bit
1426 character. */
1429 {
1435 }
1441 }
1442 }
1443 }
1445 /* Store this character into the translated pattern. */
1450 }
1452 /* If char_base is still negative we didn't find any translated
1453 non-ASCII characters. */
1456 }
1457 else
1458 {
1459 /* Unibyte buffer. */
1462 {
1465 /* If we got here and the RE flag is set, it's because we're
1466 dealing with a regexp known to be trivial, so the backslash
1467 just quotes the next character. */
1469 {
1470 len--;
1471 raw_pattern_size--;
1472 base_pat++;
1473 }
1477 }
1478 }
1487 char_base);
1488 else
1491 }
1492 }
1493 \f
1494 /* Do a simple string search N times for the string PAT,
1495 whose length is LEN/LEN_BYTE,
1496 from buffer position POS/POS_BYTE until LIM/LIM_BYTE.
1497 TRT is the translation table.
1499 Return the character position where the match is found.
1500 Otherwise, if M matches remained to be found, return -M.
1502 This kind of search works regardless of what is in PAT and
1503 regardless of what is in TRT. It is used in cases where
1504 boyer_moore cannot work. */
1506 static EMACS_INT
1511 Lisp_Object trt;
1514 {
1517 /* Number of buffer bytes matched. Note that this may be different
1518 from len_byte in a multibyte buffer. */
1523 {
1525 {
1526 /* Try matching at position POS. */
1535 {
1541 buf_charlen);
1547 this_len--;
1551 this_pos++;
1552 }
1555 {
1560 }
1563 }
1565 n--;
1566 }
1569 {
1571 {
1572 /* Try matching at position POS. */
1581 {
1589 this_len--;
1590 this_pos++;
1591 }
1594 {
1598 }
1600 pos++;
1601 }
1603 n--;
1604 }
1605 /* Backwards search. */
1608 {
1610 {
1611 /* Try matching at position POS. */
1621 {
1634 this_len--;
1635 }
1638 {
1643 }
1646 }
1648 n++;
1649 }
1652 {
1654 {
1655 /* Try matching at position POS. */
1664 {
1671 this_len--;
1672 this_pos++;
1673 }
1676 {
1680 }
1682 pos--;
1683 }
1685 n++;
1686 }
1688 stop:
1690 {
1693 else
1697 }
1700 else
1702 }
1703 \f
1704 /* Do Boyer-Moore search N times for the string BASE_PAT,
1705 whose length is LEN/LEN_BYTE,
1706 from buffer position POS/POS_BYTE until LIM/LIM_BYTE.
1707 DIRECTION says which direction we search in.
1708 TRT and INVERSE_TRT are translation tables.
1709 Characters in PAT are already translated by TRT.
1711 This kind of search works if all the characters in BASE_PAT that
1712 have nontrivial translation are the same aside from the last byte.
1713 This makes it possible to translate just the last byte of a
1714 character, and do so after just a simple test of the context.
1715 CHAR_BASE is nonzero if there is such a non-ASCII character.
1717 If that criterion is not satisfied, do not call this function. */
1719 static EMACS_INT
1725 Lisp_Object trt;
1726 Lisp_Object inverse_trt;
1730 {
1733 EMACS_INT limit;
1742 /* These are set to the preceding bytes of a byte to be translated
1743 if char_base is nonzero. As the maximum byte length of a
1744 multibyte character is 5, we have to check at most four previous
1745 bytes. */
1751 /* The general approach is that we are going to maintain that we know
1752 the first (closest to the present position, in whatever direction
1753 we're searching) character that could possibly be the last
1754 (furthest from present position) character of a valid match. We
1755 advance the state of our knowledge by looking at that character
1756 and seeing whether it indeed matches the last character of the
1757 pattern. If it does, we take a closer look. If it does not, we
1758 move our pointer (to putative last characters) as far as is
1759 logically possible. This amount of movement, which I call a
1760 stride, will be the length of the pattern if the actual character
1761 appears nowhere in the pattern, otherwise it will be the distance
1762 from the last occurrence of that character to the end of the
1763 pattern. If the amount is zero we have a possible match. */
1765 /* Here we make a "mickey mouse" BM table. The stride of the search
1766 is determined only by the last character of the putative match.
1767 If that character does not match, we will stride the proper
1768 distance to propose a match that superimposes it on the last
1769 instance of a character that matches it (per trt), or misses
1770 it entirely if there is none. */
1774 /* Record position after the end of the pattern. */
1776 /* BASE_PAT points to a character that we start scanning from.
1777 It is the first character in a forward search,
1778 the last character in a backward search. */
1782 /* A character that does not appear in the pattern induces a
1783 stride equal to the pattern length. */
1787 /* We use this for translation, instead of TRT itself.
1788 We fill this in to handle the characters that actually
1789 occur in the pattern. Others don't matter anyway! */
1794 {
1795 /* Setup translate_prev_byte1/2/3/4 from CHAR_BASE. Only a
1796 byte following them are the target of translation. */
1802 {
1805 {
1809 }
1810 }
1811 }
1815 {
1819 {
1820 /* If the byte currently looking at is the last of a
1821 character to check case-equivalents, set CH to that
1822 character. An ASCII character and a non-ASCII character
1823 matching with CHAR_BASE are to be checked. */
1830 {
1834 charstart--;
1838 }
1842 else
1849 /* A translation table is accompanied by its inverse -- see */
1850 /* comment following downcase_table for details */
1852 {
1857 {
1861 else
1864 /* For all the characters that map into CH,
1865 set up simple_translate to map the last byte
1866 into STARTING_J. */
1871 }
1872 }
1873 }
1874 else
1875 {
1881 }
1882 /* stride_for_teases tells how much to stride if we get a
1883 match on the far character but are subsequently
1884 disappointed, by recording what the stride would have been
1885 for that character if the last character had been
1886 different. */
1887 }
1889 /* loop invariant - POS_BYTE points at where last char (first
1890 char if reverse) of pattern would align in a possible match. */
1892 {
1893 EMACS_INT tail_end;
1896 /* It's been reported that some (broken) compiler thinks that
1897 Boolean expressions in an arithmetic context are unsigned.
1898 Using an explicit ?1:0 prevents this. */
1902 /* First we do the part we can by pointers (maybe nothing) */
1903 QUIT;
1907 {
1909 /* LIMIT is now the last (not beyond-last!) value POS_BYTE
1910 can take on without hitting edge of buffer or the gap. */
1913 }
1914 else
1915 {
1917 /* LIMIT is now the last (not beyond-last!) value POS_BYTE
1918 can take on without hitting edge of buffer or the gap. */
1921 }
1926 {
1931 /* In this loop, pos + cursor - p2 is the surrogate for pos. */
1933 {
1935 {
1937 {
1941 }
1942 }
1943 else
1944 {
1946 {
1950 }
1951 }
1952 /* If you are here, cursor is beyond the end of the
1953 searched region. You fail to match within the
1954 permitted region and would otherwise try a character
1955 beyond that region. */
1958 hit:
1961 {
1963 {
1966 /* Translate only the last byte of a character. */
1971 /* Check if this is the last byte of
1972 a translable character. */
1979 else
1983 }
1984 }
1985 else
1986 {
1988 {
1992 }
1993 }
1996 {
2006 {
2009 }
2010 else
2011 /* If Vinhibit_changing_match_data is non-nil,
2012 search_regs will not be changed. So let's
2013 compute start and end here. */
2014 {
2017 }
2021 else
2023 }
2024 else
2026 }
2028 }
2029 else
2030 /* Now we'll pick up a clump that has to be done the hard
2031 way because it covers a discontinuity. */
2032 {
2039 /* LIMIT is now the last value POS_BYTE can have
2040 and still be valid for a possible match. */
2042 {
2043 /* This loop can be coded for space rather than
2044 speed because it will usually run only once.
2045 (the reach is at most len + 21, and typically
2046 does not exceed len). */
2048 {
2053 }
2056 hit2:
2057 /* Found what might be a match. */
2060 {
2065 /* Translate only the last byte of a character. */
2070 /* Check if this is the last byte of a
2071 translable character. */
2078 else
2082 }
2083 /* Above loop has moved POS_BYTE part or all the way
2084 back to the first pos (last pos if reverse).
2085 Set it once again at the last (first if reverse) char. */
2088 {
2096 {
2099 }
2100 else
2101 /* If Vinhibit_changing_match_data is non-nil,
2102 search_regs will not be changed. So let's
2103 compute start and end here. */
2104 {
2107 }
2111 else
2113 }
2114 else
2116 }
2117 }
2118 /* We have done one clump. Can we continue? */
2121 }
2123 }
2125 /* Record beginning BEG_BYTE and end BEG_BYTE + NBYTES
2126 for the overall match just found in the current buffer.
2127 Also clear out the match data for registers 1 and up. */
2129 static void
2132 {
2138 /* Make sure we have registers in which to store
2139 the match position. */
2141 {
2145 }
2147 /* Clear out the other registers. */
2149 {
2152 }
2157 }
2158 \f
2159 /* Given STRING, a string of words separated by word delimiters,
2160 compute a regexp that matches those exact words separated by
2161 arbitrary punctuation. If LAX is nonzero, the end of the string
2162 need not match a word boundary unless it ends in whitespace. */
2164 static Lisp_Object
2166 Lisp_Object string;
2168 {
2171 Lisp_Object val;
2180 {
2186 {
2187 punct_count++;
2189 word_count++;
2190 }
2193 }
2196 {
2197 word_count++;
2199 }
2200 else
2212 else
2221 {
2228 {
2232 }
2234 {
2240 }
2243 }
2246 {
2249 }
2252 }
2253 \f
2257 Set point to the beginning of the occurrence found, and return point.
2258 An optional second argument bounds the search; it is a buffer position.
2259 The match found must not extend before that position.
2260 Optional third argument, if t, means if fail just return nil (no error).
2261 If not nil and not t, position at limit of search and return nil.
2262 Optional fourth argument is repeat count--search for successive occurrences.
2264 Search case-sensitivity is determined by the value of the variable
2265 `case-fold-search', which see.
2270 {
2272 }
2276 Set point to the end of the occurrence found, and return point.
2277 An optional second argument bounds the search; it is a buffer position.
2278 The match found must not extend after that position. A value of nil is
2279 equivalent to (point-max).
2280 Optional third argument, if t, means if fail just return nil (no error).
2281 If not nil and not t, move to limit of search and return nil.
2282 Optional fourth argument is repeat count--search for successive occurrences.
2284 Search case-sensitivity is determined by the value of the variable
2285 `case-fold-search', which see.
2290 {
2292 }
2297 Set point to the beginning of the occurrence found, and return point.
2298 An optional second argument bounds the search; it is a buffer position.
2299 The match found must not extend before that position.
2300 Optional third argument, if t, means if fail just return nil (no error).
2301 If not nil and not t, move to limit of search and return nil.
2305 {
2307 }
2312 Set point to the end of the occurrence found, and return point.
2313 An optional second argument bounds the search; it is a buffer position.
2314 The match found must not extend after that position.
2315 Optional third argument, if t, means if fail just return nil (no error).
2316 If not nil and not t, move to limit of search and return nil.
2320 {
2322 }
2327 Set point to the beginning of the occurrence found, and return point.
2329 Unlike `word-search-backward', the end of STRING need not match a word
2330 boundary unless it ends in whitespace.
2332 An optional second argument bounds the search; it is a buffer position.
2333 The match found must not extend before that position.
2334 Optional third argument, if t, means if fail just return nil (no error).
2335 If not nil and not t, move to limit of search and return nil.
2339 {
2341 }
2346 Set point to the end of the occurrence found, and return point.
2348 Unlike `word-search-forward', the end of STRING need not match a word
2349 boundary unless it ends in whitespace.
2351 An optional second argument bounds the search; it is a buffer position.
2352 The match found must not extend after that position.
2353 Optional third argument, if t, means if fail just return nil (no error).
2354 If not nil and not t, move to limit of search and return nil.
2358 {
2360 }
2365 Set point to the beginning of the match, and return point.
2366 The match found is the one starting last in the buffer
2367 and yet ending before the origin of the search.
2368 An optional second argument bounds the search; it is a buffer position.
2369 The match found must start at or after that position.
2370 Optional third argument, if t, means if fail just return nil (no error).
2371 If not nil and not t, move to limit of search and return nil.
2372 Optional fourth argument is repeat count--search for successive occurrences.
2373 See also the functions `match-beginning', `match-end', `match-string',
2377 {
2379 }
2384 Set point to the end of the occurrence found, and return point.
2385 An optional second argument bounds the search; it is a buffer position.
2386 The match found must not extend after that position.
2387 Optional third argument, if t, means if fail just return nil (no error).
2388 If not nil and not t, move to limit of search and return nil.
2389 Optional fourth argument is repeat count--search for successive occurrences.
2390 See also the functions `match-beginning', `match-end', `match-string',
2394 {
2396 }
2401 Find the longest match in accord with Posix regular expression rules.
2402 Set point to the beginning of the match, and return point.
2403 The match found is the one starting last in the buffer
2404 and yet ending before the origin of the search.
2405 An optional second argument bounds the search; it is a buffer position.
2406 The match found must start at or after that position.
2407 Optional third argument, if t, means if fail just return nil (no error).
2408 If not nil and not t, move to limit of search and return nil.
2409 Optional fourth argument is repeat count--search for successive occurrences.
2410 See also the functions `match-beginning', `match-end', `match-string',
2414 {
2416 }
2421 Find the longest match in accord with Posix regular expression rules.
2422 Set point to the end of the occurrence found, and return point.
2423 An optional second argument bounds the search; it is a buffer position.
2424 The match found must not extend after that position.
2425 Optional third argument, if t, means if fail just return nil (no error).
2426 If not nil and not t, move to limit of search and return nil.
2427 Optional fourth argument is repeat count--search for successive occurrences.
2428 See also the functions `match-beginning', `match-end', `match-string',
2432 {
2434 }
2435 \f
2438 Leave point at the end of the replacement text.
2440 If second arg FIXEDCASE is non-nil, do not alter case of replacement text.
2441 Otherwise maybe capitalize the whole text, or maybe just word initials,
2442 based on the replaced text.
2443 If the replaced text has only capital letters
2444 and has at least one multiletter word, convert NEWTEXT to all caps.
2445 Otherwise if all words are capitalized in the replaced text,
2446 capitalize each word in NEWTEXT.
2448 If third arg LITERAL is non-nil, insert NEWTEXT literally.
2449 Otherwise treat `\\' as special:
2450 `\\&' in NEWTEXT means substitute original matched text.
2451 `\\N' means substitute what matched the Nth `\\(...\\)'.
2452 If Nth parens didn't match, substitute nothing.
2453 `\\\\' means insert one `\\'.
2454 Case conversion does not apply to these substitutions.
2456 FIXEDCASE and LITERAL are optional arguments.
2458 The optional fourth argument STRING can be a string to modify.
2459 This is meaningful when the previous match was done against STRING,
2460 using `string-match'. When used this way, `replace-match'
2461 creates and returns a new string made by copying STRING and replacing
2462 the part of STRING that was matched.
2464 The optional fifth argument SUBEXP specifies a subexpression;
2465 it says to replace just that subexpression with NEWTEXT,
2466 rather than replacing the entire matched text.
2467 This is, in a vague sense, the inverse of using `\\N' in NEWTEXT;
2468 `\\N' copies subexp N into NEWTEXT, but using N as SUBEXP puts
2469 NEWTEXT in place of subexp N.
2470 This is useful only after a regular expression search or match,
2474 {
2491 /* but some C compilers blew it */
2498 else
2499 {
2504 }
2507 {
2513 }
2514 else
2515 {
2521 }
2524 {
2525 /* Decide how to casify by examining the matched text. */
2526 EMACS_INT last;
2533 else
2539 /* some_multiletter_word is set nonzero if any original word
2540 is more than one letter long. */
2547 {
2549 {
2552 }
2553 else
2557 {
2558 /* Cannot be all caps if any original char is lower case */
2563 else
2565 }
2567 {
2570 ;
2571 else
2573 }
2574 else
2575 {
2576 /* If the initial is a caseless word constituent,
2577 treat that like a lowercase initial. */
2580 }
2583 }
2585 /* Convert to all caps if the old text is all caps
2586 and has at least one multiletter word. */
2589 /* Capitalize each word, if the old text has all capitalized words. */
2593 /* Should x -> yz, operating on X, give Yz or YZ?
2594 We'll assume the latter. */
2596 else
2598 }
2600 /* Do replacement in a string. */
2602 {
2609 /* Substitute parts of the match into NEWTEXT
2610 if desired. */
2612 {
2615 /* We build up the substituted string in ACCUM. */
2616 Lisp_Object accum;
2617 Lisp_Object middle;
2623 {
2631 {
2635 {
2638 }
2640 {
2643 {
2646 }
2647 else
2648 {
2649 /* If that subexp did not match,
2650 replace \\N with nothing. */
2653 }
2654 }
2657 else
2659 }
2661 {
2664 lastpos_byte,
2666 else
2674 }
2676 {
2678 lastpos_byte,
2684 }
2685 }
2689 lastpos_byte,
2691 else
2695 }
2697 /* Do case substitution in NEWTEXT if desired. */
2704 }
2706 /* Record point, then move (quietly) to the start of the match. */
2711 else
2714 /* If we want non-literal replacement,
2715 perform substitution on the replacement string. */
2717 {
2723 Lisp_Object rev_tbl;
2732 /* Go thru NEWTEXT, producing the actual text to insert in
2733 SUBSTED while adjusting multibyteness to that of the current
2734 buffer. */
2737 {
2744 {
2748 }
2749 else
2750 {
2751 /* Note that we don't have to increment POS. */
2755 }
2757 /* Either set ADD_STUFF and ADD_LEN to the text to put in SUBSTED,
2758 or set IDX to a match index, which means put that part
2759 of the buffer text into SUBSTED. */
2762 {
2766 {
2771 }
2772 else
2773 {
2777 }
2782 {
2785 }
2788 else
2789 {
2792 }
2793 }
2794 else
2795 {
2798 }
2800 /* If we want to copy part of a previous match,
2801 set up ADD_STUFF and ADD_LEN to point to it. */
2803 {
2809 }
2811 /* Now the stuff we want to add to SUBSTED
2812 is invariably ADD_LEN bytes starting at ADD_STUFF. */
2814 /* Make sure SUBSTED is big enough. */
2816 {
2820 }
2822 /* Now add to the end of SUBSTED. */
2824 {
2827 }
2828 }
2831 {
2833 {
2837 }
2838 else
2840 }
2842 }
2844 /* Replace the old text with the new in the cleanest possible way. */
2856 /* Adjust search data for this change. */
2857 {
2864 {
2873 }
2874 }
2876 /* Put point back where it was in the text. */
2879 else
2882 /* Now move point "officially" to the start of the inserted replacement. */
2886 }
2887 \f
2888 static Lisp_Object
2890 Lisp_Object num;
2892 {
2906 }
2910 SUBEXP, a number, specifies which parenthesized expression in the last
2911 regexp.
2912 Value is nil if SUBEXPth pair didn't match, or there were less than
2913 SUBEXP pairs.
2916 Lisp_Object subexp;
2917 {
2919 }
2923 SUBEXP, a number, specifies which parenthesized expression in the last
2924 regexp.
2925 Value is nil if SUBEXPth pair didn't match, or there were less than
2926 SUBEXP pairs.
2929 Lisp_Object subexp;
2930 {
2932 }
2936 Element 2N is `(match-beginning N)'; element 2N + 1 is `(match-end N)'.
2937 All the elements are markers or nil (nil if the Nth pair didn't match)
2938 if the last match was on a buffer; integers or nil if a string was matched.
2939 Use `set-match-data' to reinstate the data in this list.
2941 If INTEGERS (the optional first argument) is non-nil, always use
2942 integers \(rather than markers) to represent buffer positions. In
2943 this case, and if the last match was in a buffer, the buffer will get
2944 stored as one additional element at the end of the list.
2946 If REUSE is a list, reuse it as part of the value. If REUSE is long
2947 enough to hold all the values, and if INTEGERS is non-nil, no consing
2948 is done.
2950 If optional third arg RESEAT is non-nil, any previous markers on the
2951 REUSE list will be modified to point to nowhere.
2956 {
2964 {
2967 }
2979 {
2982 {
2985 {
2988 }
2990 {
2994 last_thing_searched);
2998 last_thing_searched);
2999 }
3000 else
3001 /* last_thing_searched must always be Qt, a buffer, or Qnil. */
3005 }
3006 else
3008 }
3011 {
3013 len++;
3014 }
3016 /* If REUSE is not usable, cons up the values and return them. */
3020 /* If REUSE is a list, store as many value elements as will fit
3021 into the elements of REUSE. */
3024 {
3027 else
3030 }
3032 /* If we couldn't fit all value elements into REUSE,
3033 cons up the rest of them and add them to the end of REUSE. */
3038 }
3040 /* We used to have an internal use variant of `reseat' described as:
3042 If RESEAT is `evaporate', put the markers back on the free list
3043 immediately. No other references to the markers must exist in this
3044 case, so it is used only internally on the unwind stack and
3045 save-match-data from Lisp.
3047 But it was ill-conceived: those supposedly-internal markers get exposed via
3048 the undo-list, so freeing them here is unsafe. */
3052 LIST should have been created by calling `match-data' previously.
3057 {
3066 /* Unless we find a marker with a buffer or an explicit buffer
3067 in LIST, assume that this match data came from a string. */
3070 /* Allocate registers if they don't already exist. */
3071 {
3075 {
3077 {
3078 search_regs.start
3080 search_regs.end
3082 }
3083 else
3084 {
3085 search_regs.start
3088 search_regs.end
3091 }
3097 }
3100 {
3103 {
3106 }
3110 {
3113 }
3114 else
3115 {
3116 EMACS_INT from;
3117 Lisp_Object m;
3121 {
3124 else
3126 }
3132 {
3135 }
3150 {
3153 }
3154 }
3156 }
3160 }
3163 }
3165 /* If non-zero the match data have been saved in saved_search_regs
3166 during the execution of a sentinel or filter. */
3171 /* Called from Flooking_at, Fstring_match, search_buffer, Fstore_match_data
3172 if asynchronous code (filter or sentinel) is running. */
3173 static void
3175 {
3177 {
3188 }
3189 }
3191 /* Called upon exit from filters and sentinels. */
3192 void
3194 {
3196 {
3198 {
3201 }
3208 }
3209 }
3211 static Lisp_Object
3213 Lisp_Object list;
3214 {
3215 /* It is NOT ALWAYS safe to free (evaporate) the markers immediately. */
3217 }
3219 /* Called to unwind protect the match data. */
3220 void
3222 {
3225 }
3227 /* Quote a string to inactivate reg-expr chars */
3232 Lisp_Object string;
3233 {
3242 /* Now copy the data into the new string, inserting escapes. */
3249 {
3256 }
3262 }
3263 \f
3264 void
3266 {
3270 {
3281 }
3307 Some commands use this for user-specified regexps.
3308 Spaces that occur inside character classes or repetition operators
3309 or other such regexp constructs are not replaced with this.
3315 If non-nil, the primitive searching and matching functions
3316 such as `looking-at', `string-match', `re-search-forward', etc.,
3317 do not set the match data. The proper way to use this variable
3341 }
3343 /* arch-tag: a6059d79-0552-4f14-a2cb-d379a4e3c78f
3344 (do not change this comment) */