| 1 | /* Extended regular expression matching and search library, |
| 2 | version 0.12. |
| 3 | (Implements POSIX draft P1003.2/D11.2, except for some of the |
| 4 | internationalization features.) |
| 5 | |
| 6 | Copyright (C) 1993, 1994, 1995, 1996, 1997, 1998, 1999, 2000, 2001, |
| 7 | 2002, 2005, 2010, 2013 Free Software Foundation, Inc. |
| 8 | This file is part of the GNU C Library. |
| 9 | |
| 10 | The GNU C Library is free software; you can redistribute it and/or |
| 11 | modify it under the terms of the GNU Lesser General Public |
| 12 | License as published by the Free Software Foundation; either |
| 13 | version 2.1 of the License, or (at your option) any later version. |
| 14 | |
| 15 | The GNU C Library is distributed in the hope that it will be useful, |
| 16 | but WITHOUT ANY WARRANTY; without even the implied warranty of |
| 17 | MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the GNU |
| 18 | Lesser General Public License for more details. |
| 19 | |
| 20 | You should have received a copy of the GNU Lesser General Public |
| 21 | License along with the GNU C Library; if not, write to the Free |
| 22 | Software Foundation, Inc., 51 Franklin Street, Fifth Floor, Boston, MA |
| 23 | 02110-1301 USA. */ |
| 24 | |
| 25 | /* This file has been modified for usage in libiberty. It includes "xregex.h" |
| 26 | instead of <regex.h>. The "xregex.h" header file renames all external |
| 27 | routines with an "x" prefix so they do not collide with the native regex |
| 28 | routines or with other components regex routines. */ |
| 29 | /* AIX requires this to be the first thing in the file. */ |
| 30 | #if defined _AIX && !defined __GNUC__ && !defined REGEX_MALLOC |
| 31 | #pragma alloca |
| 32 | #endif |
| 33 | |
| 34 | #undef _GNU_SOURCE |
| 35 | #define _GNU_SOURCE |
| 36 | |
| 37 | #ifndef INSIDE_RECURSION |
| 38 | # ifdef HAVE_CONFIG_H |
| 39 | # include <config.h> |
| 40 | # endif |
| 41 | #endif |
| 42 | |
| 43 | #include <ansidecl.h> |
| 44 | |
| 45 | #ifndef INSIDE_RECURSION |
| 46 | |
| 47 | # if defined STDC_HEADERS && !defined emacs |
| 48 | # include <stddef.h> |
| 49 | # define PTR_INT_TYPE ptrdiff_t |
| 50 | # else |
| 51 | /* We need this for `regex.h', and perhaps for the Emacs include files. */ |
| 52 | # include <sys/types.h> |
| 53 | # define PTR_INT_TYPE long |
| 54 | # endif |
| 55 | |
| 56 | # define WIDE_CHAR_SUPPORT (HAVE_WCTYPE_H && HAVE_WCHAR_H && HAVE_BTOWC) |
| 57 | |
| 58 | /* For platform which support the ISO C amendement 1 functionality we |
| 59 | support user defined character classes. */ |
| 60 | # if defined _LIBC || WIDE_CHAR_SUPPORT |
| 61 | /* Solaris 2.5 has a bug: <wchar.h> must be included before <wctype.h>. */ |
| 62 | # include <wchar.h> |
| 63 | # include <wctype.h> |
| 64 | # endif |
| 65 | |
| 66 | # ifdef _LIBC |
| 67 | /* We have to keep the namespace clean. */ |
| 68 | # define regfree(preg) __regfree (preg) |
| 69 | # define regexec(pr, st, nm, pm, ef) __regexec (pr, st, nm, pm, ef) |
| 70 | # define regcomp(preg, pattern, cflags) __regcomp (preg, pattern, cflags) |
| 71 | # define regerror(errcode, preg, errbuf, errbuf_size) \ |
| 72 | __regerror(errcode, preg, errbuf, errbuf_size) |
| 73 | # define re_set_registers(bu, re, nu, st, en) \ |
| 74 | __re_set_registers (bu, re, nu, st, en) |
| 75 | # define re_match_2(bufp, string1, size1, string2, size2, pos, regs, stop) \ |
| 76 | __re_match_2 (bufp, string1, size1, string2, size2, pos, regs, stop) |
| 77 | # define re_match(bufp, string, size, pos, regs) \ |
| 78 | __re_match (bufp, string, size, pos, regs) |
| 79 | # define re_search(bufp, string, size, startpos, range, regs) \ |
| 80 | __re_search (bufp, string, size, startpos, range, regs) |
| 81 | # define re_compile_pattern(pattern, length, bufp) \ |
| 82 | __re_compile_pattern (pattern, length, bufp) |
| 83 | # define re_set_syntax(syntax) __re_set_syntax (syntax) |
| 84 | # define re_search_2(bufp, st1, s1, st2, s2, startpos, range, regs, stop) \ |
| 85 | __re_search_2 (bufp, st1, s1, st2, s2, startpos, range, regs, stop) |
| 86 | # define re_compile_fastmap(bufp) __re_compile_fastmap (bufp) |
| 87 | |
| 88 | # define btowc __btowc |
| 89 | |
| 90 | /* We are also using some library internals. */ |
| 91 | # include <locale/localeinfo.h> |
| 92 | # include <locale/elem-hash.h> |
| 93 | # include <langinfo.h> |
| 94 | # include <locale/coll-lookup.h> |
| 95 | # endif |
| 96 | |
| 97 | /* This is for other GNU distributions with internationalized messages. */ |
| 98 | # if (HAVE_LIBINTL_H && ENABLE_NLS) || defined _LIBC |
| 99 | # include <libintl.h> |
| 100 | # ifdef _LIBC |
| 101 | # undef gettext |
| 102 | # define gettext(msgid) __dcgettext ("libc", msgid, LC_MESSAGES) |
| 103 | # endif |
| 104 | # else |
| 105 | # define gettext(msgid) (msgid) |
| 106 | # endif |
| 107 | |
| 108 | # ifndef gettext_noop |
| 109 | /* This define is so xgettext can find the internationalizable |
| 110 | strings. */ |
| 111 | # define gettext_noop(String) String |
| 112 | # endif |
| 113 | |
| 114 | /* The `emacs' switch turns on certain matching commands |
| 115 | that make sense only in Emacs. */ |
| 116 | # ifdef emacs |
| 117 | |
| 118 | # include "lisp.h" |
| 119 | # include "buffer.h" |
| 120 | # include "syntax.h" |
| 121 | |
| 122 | # else /* not emacs */ |
| 123 | |
| 124 | /* If we are not linking with Emacs proper, |
| 125 | we can't use the relocating allocator |
| 126 | even if config.h says that we can. */ |
| 127 | # undef REL_ALLOC |
| 128 | |
| 129 | # if defined STDC_HEADERS || defined _LIBC |
| 130 | # include <stdlib.h> |
| 131 | # else |
| 132 | char *malloc (); |
| 133 | char *realloc (); |
| 134 | # endif |
| 135 | |
| 136 | /* When used in Emacs's lib-src, we need to get bzero and bcopy somehow. |
| 137 | If nothing else has been done, use the method below. */ |
| 138 | # ifdef INHIBIT_STRING_HEADER |
| 139 | # if !(defined HAVE_BZERO && defined HAVE_BCOPY) |
| 140 | # if !defined bzero && !defined bcopy |
| 141 | # undef INHIBIT_STRING_HEADER |
| 142 | # endif |
| 143 | # endif |
| 144 | # endif |
| 145 | |
| 146 | /* This is the normal way of making sure we have a bcopy and a bzero. |
| 147 | This is used in most programs--a few other programs avoid this |
| 148 | by defining INHIBIT_STRING_HEADER. */ |
| 149 | # ifndef INHIBIT_STRING_HEADER |
| 150 | # if defined HAVE_STRING_H || defined STDC_HEADERS || defined _LIBC |
| 151 | # include <string.h> |
| 152 | # ifndef bzero |
| 153 | # ifndef _LIBC |
| 154 | # define bzero(s, n) ((void) memset (s, '\0', n)) |
| 155 | # else |
| 156 | # define bzero(s, n) __bzero (s, n) |
| 157 | # endif |
| 158 | # endif |
| 159 | # else |
| 160 | # include <strings.h> |
| 161 | # ifndef memcmp |
| 162 | # define memcmp(s1, s2, n) bcmp (s1, s2, n) |
| 163 | # endif |
| 164 | # ifndef memcpy |
| 165 | # define memcpy(d, s, n) (bcopy (s, d, n), (d)) |
| 166 | # endif |
| 167 | # endif |
| 168 | # endif |
| 169 | |
| 170 | /* Define the syntax stuff for \<, \>, etc. */ |
| 171 | |
| 172 | /* This must be nonzero for the wordchar and notwordchar pattern |
| 173 | commands in re_match_2. */ |
| 174 | # ifndef Sword |
| 175 | # define Sword 1 |
| 176 | # endif |
| 177 | |
| 178 | # ifdef SWITCH_ENUM_BUG |
| 179 | # define SWITCH_ENUM_CAST(x) ((int)(x)) |
| 180 | # else |
| 181 | # define SWITCH_ENUM_CAST(x) (x) |
| 182 | # endif |
| 183 | |
| 184 | # endif /* not emacs */ |
| 185 | |
| 186 | # if defined _LIBC || HAVE_LIMITS_H |
| 187 | # include <limits.h> |
| 188 | # endif |
| 189 | |
| 190 | # ifndef MB_LEN_MAX |
| 191 | # define MB_LEN_MAX 1 |
| 192 | # endif |
| 193 | \f |
| 194 | /* Get the interface, including the syntax bits. */ |
| 195 | # include "xregex.h" /* change for libiberty */ |
| 196 | |
| 197 | /* isalpha etc. are used for the character classes. */ |
| 198 | # include <ctype.h> |
| 199 | |
| 200 | /* Jim Meyering writes: |
| 201 | |
| 202 | "... Some ctype macros are valid only for character codes that |
| 203 | isascii says are ASCII (SGI's IRIX-4.0.5 is one such system --when |
| 204 | using /bin/cc or gcc but without giving an ansi option). So, all |
| 205 | ctype uses should be through macros like ISPRINT... If |
| 206 | STDC_HEADERS is defined, then autoconf has verified that the ctype |
| 207 | macros don't need to be guarded with references to isascii. ... |
| 208 | Defining isascii to 1 should let any compiler worth its salt |
| 209 | eliminate the && through constant folding." |
| 210 | Solaris defines some of these symbols so we must undefine them first. */ |
| 211 | |
| 212 | # undef ISASCII |
| 213 | # if defined STDC_HEADERS || (!defined isascii && !defined HAVE_ISASCII) |
| 214 | # define ISASCII(c) 1 |
| 215 | # else |
| 216 | # define ISASCII(c) isascii(c) |
| 217 | # endif |
| 218 | |
| 219 | # ifdef isblank |
| 220 | # define ISBLANK(c) (ISASCII (c) && isblank (c)) |
| 221 | # else |
| 222 | # define ISBLANK(c) ((c) == ' ' || (c) == '\t') |
| 223 | # endif |
| 224 | # ifdef isgraph |
| 225 | # define ISGRAPH(c) (ISASCII (c) && isgraph (c)) |
| 226 | # else |
| 227 | # define ISGRAPH(c) (ISASCII (c) && isprint (c) && !isspace (c)) |
| 228 | # endif |
| 229 | |
| 230 | # undef ISPRINT |
| 231 | # define ISPRINT(c) (ISASCII (c) && isprint (c)) |
| 232 | # define ISDIGIT(c) (ISASCII (c) && isdigit (c)) |
| 233 | # define ISALNUM(c) (ISASCII (c) && isalnum (c)) |
| 234 | # define ISALPHA(c) (ISASCII (c) && isalpha (c)) |
| 235 | # define ISCNTRL(c) (ISASCII (c) && iscntrl (c)) |
| 236 | # define ISLOWER(c) (ISASCII (c) && islower (c)) |
| 237 | # define ISPUNCT(c) (ISASCII (c) && ispunct (c)) |
| 238 | # define ISSPACE(c) (ISASCII (c) && isspace (c)) |
| 239 | # define ISUPPER(c) (ISASCII (c) && isupper (c)) |
| 240 | # define ISXDIGIT(c) (ISASCII (c) && isxdigit (c)) |
| 241 | |
| 242 | # ifdef _tolower |
| 243 | # define TOLOWER(c) _tolower(c) |
| 244 | # else |
| 245 | # define TOLOWER(c) tolower(c) |
| 246 | # endif |
| 247 | |
| 248 | # ifndef NULL |
| 249 | # define NULL (void *)0 |
| 250 | # endif |
| 251 | |
| 252 | /* We remove any previous definition of `SIGN_EXTEND_CHAR', |
| 253 | since ours (we hope) works properly with all combinations of |
| 254 | machines, compilers, `char' and `unsigned char' argument types. |
| 255 | (Per Bothner suggested the basic approach.) */ |
| 256 | # undef SIGN_EXTEND_CHAR |
| 257 | # if __STDC__ |
| 258 | # define SIGN_EXTEND_CHAR(c) ((signed char) (c)) |
| 259 | # else /* not __STDC__ */ |
| 260 | /* As in Harbison and Steele. */ |
| 261 | # define SIGN_EXTEND_CHAR(c) ((((unsigned char) (c)) ^ 128) - 128) |
| 262 | # endif |
| 263 | \f |
| 264 | # ifndef emacs |
| 265 | /* How many characters in the character set. */ |
| 266 | # define CHAR_SET_SIZE 256 |
| 267 | |
| 268 | # ifdef SYNTAX_TABLE |
| 269 | |
| 270 | extern char *re_syntax_table; |
| 271 | |
| 272 | # else /* not SYNTAX_TABLE */ |
| 273 | |
| 274 | static char re_syntax_table[CHAR_SET_SIZE]; |
| 275 | |
| 276 | static void init_syntax_once (void); |
| 277 | |
| 278 | static void |
| 279 | init_syntax_once (void) |
| 280 | { |
| 281 | register int c; |
| 282 | static int done = 0; |
| 283 | |
| 284 | if (done) |
| 285 | return; |
| 286 | bzero (re_syntax_table, sizeof re_syntax_table); |
| 287 | |
| 288 | for (c = 0; c < CHAR_SET_SIZE; ++c) |
| 289 | if (ISALNUM (c)) |
| 290 | re_syntax_table[c] = Sword; |
| 291 | |
| 292 | re_syntax_table['_'] = Sword; |
| 293 | |
| 294 | done = 1; |
| 295 | } |
| 296 | |
| 297 | # endif /* not SYNTAX_TABLE */ |
| 298 | |
| 299 | # define SYNTAX(c) re_syntax_table[(unsigned char) (c)] |
| 300 | |
| 301 | # endif /* emacs */ |
| 302 | \f |
| 303 | /* Integer type for pointers. */ |
| 304 | # if !defined _LIBC && !defined HAVE_UINTPTR_T |
| 305 | typedef unsigned long int uintptr_t; |
| 306 | # endif |
| 307 | |
| 308 | /* Should we use malloc or alloca? If REGEX_MALLOC is not defined, we |
| 309 | use `alloca' instead of `malloc'. This is because using malloc in |
| 310 | re_search* or re_match* could cause memory leaks when C-g is used in |
| 311 | Emacs; also, malloc is slower and causes storage fragmentation. On |
| 312 | the other hand, malloc is more portable, and easier to debug. |
| 313 | |
| 314 | Because we sometimes use alloca, some routines have to be macros, |
| 315 | not functions -- `alloca'-allocated space disappears at the end of the |
| 316 | function it is called in. */ |
| 317 | |
| 318 | # ifdef REGEX_MALLOC |
| 319 | |
| 320 | # define REGEX_ALLOCATE malloc |
| 321 | # define REGEX_REALLOCATE(source, osize, nsize) realloc (source, nsize) |
| 322 | # define REGEX_FREE free |
| 323 | |
| 324 | # else /* not REGEX_MALLOC */ |
| 325 | |
| 326 | /* Emacs already defines alloca, sometimes. */ |
| 327 | # ifndef alloca |
| 328 | |
| 329 | /* Make alloca work the best possible way. */ |
| 330 | # ifdef __GNUC__ |
| 331 | # define alloca __builtin_alloca |
| 332 | # else /* not __GNUC__ */ |
| 333 | # if HAVE_ALLOCA_H |
| 334 | # include <alloca.h> |
| 335 | # endif /* HAVE_ALLOCA_H */ |
| 336 | # endif /* not __GNUC__ */ |
| 337 | |
| 338 | # endif /* not alloca */ |
| 339 | |
| 340 | # define REGEX_ALLOCATE alloca |
| 341 | |
| 342 | /* Assumes a `char *destination' variable. */ |
| 343 | # define REGEX_REALLOCATE(source, osize, nsize) \ |
| 344 | (destination = (char *) alloca (nsize), \ |
| 345 | memcpy (destination, source, osize)) |
| 346 | |
| 347 | /* No need to do anything to free, after alloca. */ |
| 348 | # define REGEX_FREE(arg) ((void)0) /* Do nothing! But inhibit gcc warning. */ |
| 349 | |
| 350 | # endif /* not REGEX_MALLOC */ |
| 351 | |
| 352 | /* Define how to allocate the failure stack. */ |
| 353 | |
| 354 | # if defined REL_ALLOC && defined REGEX_MALLOC |
| 355 | |
| 356 | # define REGEX_ALLOCATE_STACK(size) \ |
| 357 | r_alloc (&failure_stack_ptr, (size)) |
| 358 | # define REGEX_REALLOCATE_STACK(source, osize, nsize) \ |
| 359 | r_re_alloc (&failure_stack_ptr, (nsize)) |
| 360 | # define REGEX_FREE_STACK(ptr) \ |
| 361 | r_alloc_free (&failure_stack_ptr) |
| 362 | |
| 363 | # else /* not using relocating allocator */ |
| 364 | |
| 365 | # ifdef REGEX_MALLOC |
| 366 | |
| 367 | # define REGEX_ALLOCATE_STACK malloc |
| 368 | # define REGEX_REALLOCATE_STACK(source, osize, nsize) realloc (source, nsize) |
| 369 | # define REGEX_FREE_STACK free |
| 370 | |
| 371 | # else /* not REGEX_MALLOC */ |
| 372 | |
| 373 | # define REGEX_ALLOCATE_STACK alloca |
| 374 | |
| 375 | # define REGEX_REALLOCATE_STACK(source, osize, nsize) \ |
| 376 | REGEX_REALLOCATE (source, osize, nsize) |
| 377 | /* No need to explicitly free anything. */ |
| 378 | # define REGEX_FREE_STACK(arg) |
| 379 | |
| 380 | # endif /* not REGEX_MALLOC */ |
| 381 | # endif /* not using relocating allocator */ |
| 382 | |
| 383 | |
| 384 | /* True if `size1' is non-NULL and PTR is pointing anywhere inside |
| 385 | `string1' or just past its end. This works if PTR is NULL, which is |
| 386 | a good thing. */ |
| 387 | # define FIRST_STRING_P(ptr) \ |
| 388 | (size1 && string1 <= (ptr) && (ptr) <= string1 + size1) |
| 389 | |
| 390 | /* (Re)Allocate N items of type T using malloc, or fail. */ |
| 391 | # define TALLOC(n, t) ((t *) malloc ((n) * sizeof (t))) |
| 392 | # define RETALLOC(addr, n, t) ((addr) = (t *) realloc (addr, (n) * sizeof (t))) |
| 393 | # define RETALLOC_IF(addr, n, t) \ |
| 394 | if (addr) RETALLOC((addr), (n), t); else (addr) = TALLOC ((n), t) |
| 395 | # define REGEX_TALLOC(n, t) ((t *) REGEX_ALLOCATE ((n) * sizeof (t))) |
| 396 | |
| 397 | # define BYTEWIDTH 8 /* In bits. */ |
| 398 | |
| 399 | # define STREQ(s1, s2) ((strcmp (s1, s2) == 0)) |
| 400 | |
| 401 | # undef MAX |
| 402 | # undef MIN |
| 403 | # define MAX(a, b) ((a) > (b) ? (a) : (b)) |
| 404 | # define MIN(a, b) ((a) < (b) ? (a) : (b)) |
| 405 | |
| 406 | typedef char boolean; |
| 407 | # define false 0 |
| 408 | # define true 1 |
| 409 | |
| 410 | static reg_errcode_t byte_regex_compile (const char *pattern, size_t size, |
| 411 | reg_syntax_t syntax, |
| 412 | struct re_pattern_buffer *bufp); |
| 413 | |
| 414 | static int byte_re_match_2_internal (struct re_pattern_buffer *bufp, |
| 415 | const char *string1, int size1, |
| 416 | const char *string2, int size2, |
| 417 | int pos, |
| 418 | struct re_registers *regs, |
| 419 | int stop); |
| 420 | static int byte_re_search_2 (struct re_pattern_buffer *bufp, |
| 421 | const char *string1, int size1, |
| 422 | const char *string2, int size2, |
| 423 | int startpos, int range, |
| 424 | struct re_registers *regs, int stop); |
| 425 | static int byte_re_compile_fastmap (struct re_pattern_buffer *bufp); |
| 426 | |
| 427 | #ifdef MBS_SUPPORT |
| 428 | static reg_errcode_t wcs_regex_compile (const char *pattern, size_t size, |
| 429 | reg_syntax_t syntax, |
| 430 | struct re_pattern_buffer *bufp); |
| 431 | |
| 432 | |
| 433 | static int wcs_re_match_2_internal (struct re_pattern_buffer *bufp, |
| 434 | const char *cstring1, int csize1, |
| 435 | const char *cstring2, int csize2, |
| 436 | int pos, |
| 437 | struct re_registers *regs, |
| 438 | int stop, |
| 439 | wchar_t *string1, int size1, |
| 440 | wchar_t *string2, int size2, |
| 441 | int *mbs_offset1, int *mbs_offset2); |
| 442 | static int wcs_re_search_2 (struct re_pattern_buffer *bufp, |
| 443 | const char *string1, int size1, |
| 444 | const char *string2, int size2, |
| 445 | int startpos, int range, |
| 446 | struct re_registers *regs, int stop); |
| 447 | static int wcs_re_compile_fastmap (struct re_pattern_buffer *bufp); |
| 448 | #endif |
| 449 | \f |
| 450 | /* These are the command codes that appear in compiled regular |
| 451 | expressions. Some opcodes are followed by argument bytes. A |
| 452 | command code can specify any interpretation whatsoever for its |
| 453 | arguments. Zero bytes may appear in the compiled regular expression. */ |
| 454 | |
| 455 | typedef enum |
| 456 | { |
| 457 | no_op = 0, |
| 458 | |
| 459 | /* Succeed right away--no more backtracking. */ |
| 460 | succeed, |
| 461 | |
| 462 | /* Followed by one byte giving n, then by n literal bytes. */ |
| 463 | exactn, |
| 464 | |
| 465 | # ifdef MBS_SUPPORT |
| 466 | /* Same as exactn, but contains binary data. */ |
| 467 | exactn_bin, |
| 468 | # endif |
| 469 | |
| 470 | /* Matches any (more or less) character. */ |
| 471 | anychar, |
| 472 | |
| 473 | /* Matches any one char belonging to specified set. First |
| 474 | following byte is number of bitmap bytes. Then come bytes |
| 475 | for a bitmap saying which chars are in. Bits in each byte |
| 476 | are ordered low-bit-first. A character is in the set if its |
| 477 | bit is 1. A character too large to have a bit in the map is |
| 478 | automatically not in the set. */ |
| 479 | /* ifdef MBS_SUPPORT, following element is length of character |
| 480 | classes, length of collating symbols, length of equivalence |
| 481 | classes, length of character ranges, and length of characters. |
| 482 | Next, character class element, collating symbols elements, |
| 483 | equivalence class elements, range elements, and character |
| 484 | elements follow. |
| 485 | See regex_compile function. */ |
| 486 | charset, |
| 487 | |
| 488 | /* Same parameters as charset, but match any character that is |
| 489 | not one of those specified. */ |
| 490 | charset_not, |
| 491 | |
| 492 | /* Start remembering the text that is matched, for storing in a |
| 493 | register. Followed by one byte with the register number, in |
| 494 | the range 0 to one less than the pattern buffer's re_nsub |
| 495 | field. Then followed by one byte with the number of groups |
| 496 | inner to this one. (This last has to be part of the |
| 497 | start_memory only because we need it in the on_failure_jump |
| 498 | of re_match_2.) */ |
| 499 | start_memory, |
| 500 | |
| 501 | /* Stop remembering the text that is matched and store it in a |
| 502 | memory register. Followed by one byte with the register |
| 503 | number, in the range 0 to one less than `re_nsub' in the |
| 504 | pattern buffer, and one byte with the number of inner groups, |
| 505 | just like `start_memory'. (We need the number of inner |
| 506 | groups here because we don't have any easy way of finding the |
| 507 | corresponding start_memory when we're at a stop_memory.) */ |
| 508 | stop_memory, |
| 509 | |
| 510 | /* Match a duplicate of something remembered. Followed by one |
| 511 | byte containing the register number. */ |
| 512 | duplicate, |
| 513 | |
| 514 | /* Fail unless at beginning of line. */ |
| 515 | begline, |
| 516 | |
| 517 | /* Fail unless at end of line. */ |
| 518 | endline, |
| 519 | |
| 520 | /* Succeeds if at beginning of buffer (if emacs) or at beginning |
| 521 | of string to be matched (if not). */ |
| 522 | begbuf, |
| 523 | |
| 524 | /* Analogously, for end of buffer/string. */ |
| 525 | endbuf, |
| 526 | |
| 527 | /* Followed by two byte relative address to which to jump. */ |
| 528 | jump, |
| 529 | |
| 530 | /* Same as jump, but marks the end of an alternative. */ |
| 531 | jump_past_alt, |
| 532 | |
| 533 | /* Followed by two-byte relative address of place to resume at |
| 534 | in case of failure. */ |
| 535 | /* ifdef MBS_SUPPORT, the size of address is 1. */ |
| 536 | on_failure_jump, |
| 537 | |
| 538 | /* Like on_failure_jump, but pushes a placeholder instead of the |
| 539 | current string position when executed. */ |
| 540 | on_failure_keep_string_jump, |
| 541 | |
| 542 | /* Throw away latest failure point and then jump to following |
| 543 | two-byte relative address. */ |
| 544 | /* ifdef MBS_SUPPORT, the size of address is 1. */ |
| 545 | pop_failure_jump, |
| 546 | |
| 547 | /* Change to pop_failure_jump if know won't have to backtrack to |
| 548 | match; otherwise change to jump. This is used to jump |
| 549 | back to the beginning of a repeat. If what follows this jump |
| 550 | clearly won't match what the repeat does, such that we can be |
| 551 | sure that there is no use backtracking out of repetitions |
| 552 | already matched, then we change it to a pop_failure_jump. |
| 553 | Followed by two-byte address. */ |
| 554 | /* ifdef MBS_SUPPORT, the size of address is 1. */ |
| 555 | maybe_pop_jump, |
| 556 | |
| 557 | /* Jump to following two-byte address, and push a dummy failure |
| 558 | point. This failure point will be thrown away if an attempt |
| 559 | is made to use it for a failure. A `+' construct makes this |
| 560 | before the first repeat. Also used as an intermediary kind |
| 561 | of jump when compiling an alternative. */ |
| 562 | /* ifdef MBS_SUPPORT, the size of address is 1. */ |
| 563 | dummy_failure_jump, |
| 564 | |
| 565 | /* Push a dummy failure point and continue. Used at the end of |
| 566 | alternatives. */ |
| 567 | push_dummy_failure, |
| 568 | |
| 569 | /* Followed by two-byte relative address and two-byte number n. |
| 570 | After matching N times, jump to the address upon failure. */ |
| 571 | /* ifdef MBS_SUPPORT, the size of address is 1. */ |
| 572 | succeed_n, |
| 573 | |
| 574 | /* Followed by two-byte relative address, and two-byte number n. |
| 575 | Jump to the address N times, then fail. */ |
| 576 | /* ifdef MBS_SUPPORT, the size of address is 1. */ |
| 577 | jump_n, |
| 578 | |
| 579 | /* Set the following two-byte relative address to the |
| 580 | subsequent two-byte number. The address *includes* the two |
| 581 | bytes of number. */ |
| 582 | /* ifdef MBS_SUPPORT, the size of address is 1. */ |
| 583 | set_number_at, |
| 584 | |
| 585 | wordchar, /* Matches any word-constituent character. */ |
| 586 | notwordchar, /* Matches any char that is not a word-constituent. */ |
| 587 | |
| 588 | wordbeg, /* Succeeds if at word beginning. */ |
| 589 | wordend, /* Succeeds if at word end. */ |
| 590 | |
| 591 | wordbound, /* Succeeds if at a word boundary. */ |
| 592 | notwordbound /* Succeeds if not at a word boundary. */ |
| 593 | |
| 594 | # ifdef emacs |
| 595 | ,before_dot, /* Succeeds if before point. */ |
| 596 | at_dot, /* Succeeds if at point. */ |
| 597 | after_dot, /* Succeeds if after point. */ |
| 598 | |
| 599 | /* Matches any character whose syntax is specified. Followed by |
| 600 | a byte which contains a syntax code, e.g., Sword. */ |
| 601 | syntaxspec, |
| 602 | |
| 603 | /* Matches any character whose syntax is not that specified. */ |
| 604 | notsyntaxspec |
| 605 | # endif /* emacs */ |
| 606 | } re_opcode_t; |
| 607 | #endif /* not INSIDE_RECURSION */ |
| 608 | \f |
| 609 | |
| 610 | #ifdef BYTE |
| 611 | # define CHAR_T char |
| 612 | # define UCHAR_T unsigned char |
| 613 | # define COMPILED_BUFFER_VAR bufp->buffer |
| 614 | # define OFFSET_ADDRESS_SIZE 2 |
| 615 | # define PREFIX(name) byte_##name |
| 616 | # define ARG_PREFIX(name) name |
| 617 | # define PUT_CHAR(c) putchar (c) |
| 618 | #else |
| 619 | # ifdef WCHAR |
| 620 | # define CHAR_T wchar_t |
| 621 | # define UCHAR_T wchar_t |
| 622 | # define COMPILED_BUFFER_VAR wc_buffer |
| 623 | # define OFFSET_ADDRESS_SIZE 1 /* the size which STORE_NUMBER macro use */ |
| 624 | # define CHAR_CLASS_SIZE ((__alignof__(wctype_t)+sizeof(wctype_t))/sizeof(CHAR_T)+1) |
| 625 | # define PREFIX(name) wcs_##name |
| 626 | # define ARG_PREFIX(name) c##name |
| 627 | /* Should we use wide stream?? */ |
| 628 | # define PUT_CHAR(c) printf ("%C", c); |
| 629 | # define TRUE 1 |
| 630 | # define FALSE 0 |
| 631 | # else |
| 632 | # ifdef MBS_SUPPORT |
| 633 | # define WCHAR |
| 634 | # define INSIDE_RECURSION |
| 635 | # include "regex.c" |
| 636 | # undef INSIDE_RECURSION |
| 637 | # endif |
| 638 | # define BYTE |
| 639 | # define INSIDE_RECURSION |
| 640 | # include "regex.c" |
| 641 | # undef INSIDE_RECURSION |
| 642 | # endif |
| 643 | #endif |
| 644 | |
| 645 | #ifdef INSIDE_RECURSION |
| 646 | /* Common operations on the compiled pattern. */ |
| 647 | |
| 648 | /* Store NUMBER in two contiguous bytes starting at DESTINATION. */ |
| 649 | /* ifdef MBS_SUPPORT, we store NUMBER in 1 element. */ |
| 650 | |
| 651 | # ifdef WCHAR |
| 652 | # define STORE_NUMBER(destination, number) \ |
| 653 | do { \ |
| 654 | *(destination) = (UCHAR_T)(number); \ |
| 655 | } while (0) |
| 656 | # else /* BYTE */ |
| 657 | # define STORE_NUMBER(destination, number) \ |
| 658 | do { \ |
| 659 | (destination)[0] = (number) & 0377; \ |
| 660 | (destination)[1] = (number) >> 8; \ |
| 661 | } while (0) |
| 662 | # endif /* WCHAR */ |
| 663 | |
| 664 | /* Same as STORE_NUMBER, except increment DESTINATION to |
| 665 | the byte after where the number is stored. Therefore, DESTINATION |
| 666 | must be an lvalue. */ |
| 667 | /* ifdef MBS_SUPPORT, we store NUMBER in 1 element. */ |
| 668 | |
| 669 | # define STORE_NUMBER_AND_INCR(destination, number) \ |
| 670 | do { \ |
| 671 | STORE_NUMBER (destination, number); \ |
| 672 | (destination) += OFFSET_ADDRESS_SIZE; \ |
| 673 | } while (0) |
| 674 | |
| 675 | /* Put into DESTINATION a number stored in two contiguous bytes starting |
| 676 | at SOURCE. */ |
| 677 | /* ifdef MBS_SUPPORT, we store NUMBER in 1 element. */ |
| 678 | |
| 679 | # ifdef WCHAR |
| 680 | # define EXTRACT_NUMBER(destination, source) \ |
| 681 | do { \ |
| 682 | (destination) = *(source); \ |
| 683 | } while (0) |
| 684 | # else /* BYTE */ |
| 685 | # define EXTRACT_NUMBER(destination, source) \ |
| 686 | do { \ |
| 687 | (destination) = *(source) & 0377; \ |
| 688 | (destination) += SIGN_EXTEND_CHAR (*((source) + 1)) << 8; \ |
| 689 | } while (0) |
| 690 | # endif |
| 691 | |
| 692 | # ifdef DEBUG |
| 693 | static void PREFIX(extract_number) (int *dest, UCHAR_T *source); |
| 694 | static void |
| 695 | PREFIX(extract_number) (int *dest, UCHAR_T *source) |
| 696 | { |
| 697 | # ifdef WCHAR |
| 698 | *dest = *source; |
| 699 | # else /* BYTE */ |
| 700 | int temp = SIGN_EXTEND_CHAR (*(source + 1)); |
| 701 | *dest = *source & 0377; |
| 702 | *dest += temp << 8; |
| 703 | # endif |
| 704 | } |
| 705 | |
| 706 | # ifndef EXTRACT_MACROS /* To debug the macros. */ |
| 707 | # undef EXTRACT_NUMBER |
| 708 | # define EXTRACT_NUMBER(dest, src) PREFIX(extract_number) (&dest, src) |
| 709 | # endif /* not EXTRACT_MACROS */ |
| 710 | |
| 711 | # endif /* DEBUG */ |
| 712 | |
| 713 | /* Same as EXTRACT_NUMBER, except increment SOURCE to after the number. |
| 714 | SOURCE must be an lvalue. */ |
| 715 | |
| 716 | # define EXTRACT_NUMBER_AND_INCR(destination, source) \ |
| 717 | do { \ |
| 718 | EXTRACT_NUMBER (destination, source); \ |
| 719 | (source) += OFFSET_ADDRESS_SIZE; \ |
| 720 | } while (0) |
| 721 | |
| 722 | # ifdef DEBUG |
| 723 | static void PREFIX(extract_number_and_incr) (int *destination, |
| 724 | UCHAR_T **source); |
| 725 | static void |
| 726 | PREFIX(extract_number_and_incr) (int *destination, UCHAR_T **source) |
| 727 | { |
| 728 | PREFIX(extract_number) (destination, *source); |
| 729 | *source += OFFSET_ADDRESS_SIZE; |
| 730 | } |
| 731 | |
| 732 | # ifndef EXTRACT_MACROS |
| 733 | # undef EXTRACT_NUMBER_AND_INCR |
| 734 | # define EXTRACT_NUMBER_AND_INCR(dest, src) \ |
| 735 | PREFIX(extract_number_and_incr) (&dest, &src) |
| 736 | # endif /* not EXTRACT_MACROS */ |
| 737 | |
| 738 | # endif /* DEBUG */ |
| 739 | |
| 740 | \f |
| 741 | |
| 742 | /* If DEBUG is defined, Regex prints many voluminous messages about what |
| 743 | it is doing (if the variable `debug' is nonzero). If linked with the |
| 744 | main program in `iregex.c', you can enter patterns and strings |
| 745 | interactively. And if linked with the main program in `main.c' and |
| 746 | the other test files, you can run the already-written tests. */ |
| 747 | |
| 748 | # ifdef DEBUG |
| 749 | |
| 750 | # ifndef DEFINED_ONCE |
| 751 | |
| 752 | /* We use standard I/O for debugging. */ |
| 753 | # include <stdio.h> |
| 754 | |
| 755 | /* It is useful to test things that ``must'' be true when debugging. */ |
| 756 | # include <assert.h> |
| 757 | |
| 758 | static int debug; |
| 759 | |
| 760 | # define DEBUG_STATEMENT(e) e |
| 761 | # define DEBUG_PRINT1(x) if (debug) printf (x) |
| 762 | # define DEBUG_PRINT2(x1, x2) if (debug) printf (x1, x2) |
| 763 | # define DEBUG_PRINT3(x1, x2, x3) if (debug) printf (x1, x2, x3) |
| 764 | # define DEBUG_PRINT4(x1, x2, x3, x4) if (debug) printf (x1, x2, x3, x4) |
| 765 | # endif /* not DEFINED_ONCE */ |
| 766 | |
| 767 | # define DEBUG_PRINT_COMPILED_PATTERN(p, s, e) \ |
| 768 | if (debug) PREFIX(print_partial_compiled_pattern) (s, e) |
| 769 | # define DEBUG_PRINT_DOUBLE_STRING(w, s1, sz1, s2, sz2) \ |
| 770 | if (debug) PREFIX(print_double_string) (w, s1, sz1, s2, sz2) |
| 771 | |
| 772 | |
| 773 | /* Print the fastmap in human-readable form. */ |
| 774 | |
| 775 | # ifndef DEFINED_ONCE |
| 776 | void |
| 777 | print_fastmap (char *fastmap) |
| 778 | { |
| 779 | unsigned was_a_range = 0; |
| 780 | unsigned i = 0; |
| 781 | |
| 782 | while (i < (1 << BYTEWIDTH)) |
| 783 | { |
| 784 | if (fastmap[i++]) |
| 785 | { |
| 786 | was_a_range = 0; |
| 787 | putchar (i - 1); |
| 788 | while (i < (1 << BYTEWIDTH) && fastmap[i]) |
| 789 | { |
| 790 | was_a_range = 1; |
| 791 | i++; |
| 792 | } |
| 793 | if (was_a_range) |
| 794 | { |
| 795 | printf ("-"); |
| 796 | putchar (i - 1); |
| 797 | } |
| 798 | } |
| 799 | } |
| 800 | putchar ('\n'); |
| 801 | } |
| 802 | # endif /* not DEFINED_ONCE */ |
| 803 | |
| 804 | |
| 805 | /* Print a compiled pattern string in human-readable form, starting at |
| 806 | the START pointer into it and ending just before the pointer END. */ |
| 807 | |
| 808 | void |
| 809 | PREFIX(print_partial_compiled_pattern) (UCHAR_T *start, UCHAR_T *end) |
| 810 | { |
| 811 | int mcnt, mcnt2; |
| 812 | UCHAR_T *p1; |
| 813 | UCHAR_T *p = start; |
| 814 | UCHAR_T *pend = end; |
| 815 | |
| 816 | if (start == NULL) |
| 817 | { |
| 818 | printf ("(null)\n"); |
| 819 | return; |
| 820 | } |
| 821 | |
| 822 | /* Loop over pattern commands. */ |
| 823 | while (p < pend) |
| 824 | { |
| 825 | # ifdef _LIBC |
| 826 | printf ("%td:\t", p - start); |
| 827 | # else |
| 828 | printf ("%ld:\t", (long int) (p - start)); |
| 829 | # endif |
| 830 | |
| 831 | switch ((re_opcode_t) *p++) |
| 832 | { |
| 833 | case no_op: |
| 834 | printf ("/no_op"); |
| 835 | break; |
| 836 | |
| 837 | case exactn: |
| 838 | mcnt = *p++; |
| 839 | printf ("/exactn/%d", mcnt); |
| 840 | do |
| 841 | { |
| 842 | putchar ('/'); |
| 843 | PUT_CHAR (*p++); |
| 844 | } |
| 845 | while (--mcnt); |
| 846 | break; |
| 847 | |
| 848 | # ifdef MBS_SUPPORT |
| 849 | case exactn_bin: |
| 850 | mcnt = *p++; |
| 851 | printf ("/exactn_bin/%d", mcnt); |
| 852 | do |
| 853 | { |
| 854 | printf("/%lx", (long int) *p++); |
| 855 | } |
| 856 | while (--mcnt); |
| 857 | break; |
| 858 | # endif /* MBS_SUPPORT */ |
| 859 | |
| 860 | case start_memory: |
| 861 | mcnt = *p++; |
| 862 | printf ("/start_memory/%d/%ld", mcnt, (long int) *p++); |
| 863 | break; |
| 864 | |
| 865 | case stop_memory: |
| 866 | mcnt = *p++; |
| 867 | printf ("/stop_memory/%d/%ld", mcnt, (long int) *p++); |
| 868 | break; |
| 869 | |
| 870 | case duplicate: |
| 871 | printf ("/duplicate/%ld", (long int) *p++); |
| 872 | break; |
| 873 | |
| 874 | case anychar: |
| 875 | printf ("/anychar"); |
| 876 | break; |
| 877 | |
| 878 | case charset: |
| 879 | case charset_not: |
| 880 | { |
| 881 | # ifdef WCHAR |
| 882 | int i, length; |
| 883 | wchar_t *workp = p; |
| 884 | printf ("/charset [%s", |
| 885 | (re_opcode_t) *(workp - 1) == charset_not ? "^" : ""); |
| 886 | p += 5; |
| 887 | length = *workp++; /* the length of char_classes */ |
| 888 | for (i=0 ; i<length ; i++) |
| 889 | printf("[:%lx:]", (long int) *p++); |
| 890 | length = *workp++; /* the length of collating_symbol */ |
| 891 | for (i=0 ; i<length ;) |
| 892 | { |
| 893 | printf("[."); |
| 894 | while(*p != 0) |
| 895 | PUT_CHAR((i++,*p++)); |
| 896 | i++,p++; |
| 897 | printf(".]"); |
| 898 | } |
| 899 | length = *workp++; /* the length of equivalence_class */ |
| 900 | for (i=0 ; i<length ;) |
| 901 | { |
| 902 | printf("[="); |
| 903 | while(*p != 0) |
| 904 | PUT_CHAR((i++,*p++)); |
| 905 | i++,p++; |
| 906 | printf("=]"); |
| 907 | } |
| 908 | length = *workp++; /* the length of char_range */ |
| 909 | for (i=0 ; i<length ; i++) |
| 910 | { |
| 911 | wchar_t range_start = *p++; |
| 912 | wchar_t range_end = *p++; |
| 913 | printf("%C-%C", range_start, range_end); |
| 914 | } |
| 915 | length = *workp++; /* the length of char */ |
| 916 | for (i=0 ; i<length ; i++) |
| 917 | printf("%C", *p++); |
| 918 | putchar (']'); |
| 919 | # else |
| 920 | register int c, last = -100; |
| 921 | register int in_range = 0; |
| 922 | |
| 923 | printf ("/charset [%s", |
| 924 | (re_opcode_t) *(p - 1) == charset_not ? "^" : ""); |
| 925 | |
| 926 | assert (p + *p < pend); |
| 927 | |
| 928 | for (c = 0; c < 256; c++) |
| 929 | if (c / 8 < *p |
| 930 | && (p[1 + (c/8)] & (1 << (c % 8)))) |
| 931 | { |
| 932 | /* Are we starting a range? */ |
| 933 | if (last + 1 == c && ! in_range) |
| 934 | { |
| 935 | putchar ('-'); |
| 936 | in_range = 1; |
| 937 | } |
| 938 | /* Have we broken a range? */ |
| 939 | else if (last + 1 != c && in_range) |
| 940 | { |
| 941 | putchar (last); |
| 942 | in_range = 0; |
| 943 | } |
| 944 | |
| 945 | if (! in_range) |
| 946 | putchar (c); |
| 947 | |
| 948 | last = c; |
| 949 | } |
| 950 | |
| 951 | if (in_range) |
| 952 | putchar (last); |
| 953 | |
| 954 | putchar (']'); |
| 955 | |
| 956 | p += 1 + *p; |
| 957 | # endif /* WCHAR */ |
| 958 | } |
| 959 | break; |
| 960 | |
| 961 | case begline: |
| 962 | printf ("/begline"); |
| 963 | break; |
| 964 | |
| 965 | case endline: |
| 966 | printf ("/endline"); |
| 967 | break; |
| 968 | |
| 969 | case on_failure_jump: |
| 970 | PREFIX(extract_number_and_incr) (&mcnt, &p); |
| 971 | # ifdef _LIBC |
| 972 | printf ("/on_failure_jump to %td", p + mcnt - start); |
| 973 | # else |
| 974 | printf ("/on_failure_jump to %ld", (long int) (p + mcnt - start)); |
| 975 | # endif |
| 976 | break; |
| 977 | |
| 978 | case on_failure_keep_string_jump: |
| 979 | PREFIX(extract_number_and_incr) (&mcnt, &p); |
| 980 | # ifdef _LIBC |
| 981 | printf ("/on_failure_keep_string_jump to %td", p + mcnt - start); |
| 982 | # else |
| 983 | printf ("/on_failure_keep_string_jump to %ld", |
| 984 | (long int) (p + mcnt - start)); |
| 985 | # endif |
| 986 | break; |
| 987 | |
| 988 | case dummy_failure_jump: |
| 989 | PREFIX(extract_number_and_incr) (&mcnt, &p); |
| 990 | # ifdef _LIBC |
| 991 | printf ("/dummy_failure_jump to %td", p + mcnt - start); |
| 992 | # else |
| 993 | printf ("/dummy_failure_jump to %ld", (long int) (p + mcnt - start)); |
| 994 | # endif |
| 995 | break; |
| 996 | |
| 997 | case push_dummy_failure: |
| 998 | printf ("/push_dummy_failure"); |
| 999 | break; |
| 1000 | |
| 1001 | case maybe_pop_jump: |
| 1002 | PREFIX(extract_number_and_incr) (&mcnt, &p); |
| 1003 | # ifdef _LIBC |
| 1004 | printf ("/maybe_pop_jump to %td", p + mcnt - start); |
| 1005 | # else |
| 1006 | printf ("/maybe_pop_jump to %ld", (long int) (p + mcnt - start)); |
| 1007 | # endif |
| 1008 | break; |
| 1009 | |
| 1010 | case pop_failure_jump: |
| 1011 | PREFIX(extract_number_and_incr) (&mcnt, &p); |
| 1012 | # ifdef _LIBC |
| 1013 | printf ("/pop_failure_jump to %td", p + mcnt - start); |
| 1014 | # else |
| 1015 | printf ("/pop_failure_jump to %ld", (long int) (p + mcnt - start)); |
| 1016 | # endif |
| 1017 | break; |
| 1018 | |
| 1019 | case jump_past_alt: |
| 1020 | PREFIX(extract_number_and_incr) (&mcnt, &p); |
| 1021 | # ifdef _LIBC |
| 1022 | printf ("/jump_past_alt to %td", p + mcnt - start); |
| 1023 | # else |
| 1024 | printf ("/jump_past_alt to %ld", (long int) (p + mcnt - start)); |
| 1025 | # endif |
| 1026 | break; |
| 1027 | |
| 1028 | case jump: |
| 1029 | PREFIX(extract_number_and_incr) (&mcnt, &p); |
| 1030 | # ifdef _LIBC |
| 1031 | printf ("/jump to %td", p + mcnt - start); |
| 1032 | # else |
| 1033 | printf ("/jump to %ld", (long int) (p + mcnt - start)); |
| 1034 | # endif |
| 1035 | break; |
| 1036 | |
| 1037 | case succeed_n: |
| 1038 | PREFIX(extract_number_and_incr) (&mcnt, &p); |
| 1039 | p1 = p + mcnt; |
| 1040 | PREFIX(extract_number_and_incr) (&mcnt2, &p); |
| 1041 | # ifdef _LIBC |
| 1042 | printf ("/succeed_n to %td, %d times", p1 - start, mcnt2); |
| 1043 | # else |
| 1044 | printf ("/succeed_n to %ld, %d times", |
| 1045 | (long int) (p1 - start), mcnt2); |
| 1046 | # endif |
| 1047 | break; |
| 1048 | |
| 1049 | case jump_n: |
| 1050 | PREFIX(extract_number_and_incr) (&mcnt, &p); |
| 1051 | p1 = p + mcnt; |
| 1052 | PREFIX(extract_number_and_incr) (&mcnt2, &p); |
| 1053 | printf ("/jump_n to %d, %d times", p1 - start, mcnt2); |
| 1054 | break; |
| 1055 | |
| 1056 | case set_number_at: |
| 1057 | PREFIX(extract_number_and_incr) (&mcnt, &p); |
| 1058 | p1 = p + mcnt; |
| 1059 | PREFIX(extract_number_and_incr) (&mcnt2, &p); |
| 1060 | # ifdef _LIBC |
| 1061 | printf ("/set_number_at location %td to %d", p1 - start, mcnt2); |
| 1062 | # else |
| 1063 | printf ("/set_number_at location %ld to %d", |
| 1064 | (long int) (p1 - start), mcnt2); |
| 1065 | # endif |
| 1066 | break; |
| 1067 | |
| 1068 | case wordbound: |
| 1069 | printf ("/wordbound"); |
| 1070 | break; |
| 1071 | |
| 1072 | case notwordbound: |
| 1073 | printf ("/notwordbound"); |
| 1074 | break; |
| 1075 | |
| 1076 | case wordbeg: |
| 1077 | printf ("/wordbeg"); |
| 1078 | break; |
| 1079 | |
| 1080 | case wordend: |
| 1081 | printf ("/wordend"); |
| 1082 | break; |
| 1083 | |
| 1084 | # ifdef emacs |
| 1085 | case before_dot: |
| 1086 | printf ("/before_dot"); |
| 1087 | break; |
| 1088 | |
| 1089 | case at_dot: |
| 1090 | printf ("/at_dot"); |
| 1091 | break; |
| 1092 | |
| 1093 | case after_dot: |
| 1094 | printf ("/after_dot"); |
| 1095 | break; |
| 1096 | |
| 1097 | case syntaxspec: |
| 1098 | printf ("/syntaxspec"); |
| 1099 | mcnt = *p++; |
| 1100 | printf ("/%d", mcnt); |
| 1101 | break; |
| 1102 | |
| 1103 | case notsyntaxspec: |
| 1104 | printf ("/notsyntaxspec"); |
| 1105 | mcnt = *p++; |
| 1106 | printf ("/%d", mcnt); |
| 1107 | break; |
| 1108 | # endif /* emacs */ |
| 1109 | |
| 1110 | case wordchar: |
| 1111 | printf ("/wordchar"); |
| 1112 | break; |
| 1113 | |
| 1114 | case notwordchar: |
| 1115 | printf ("/notwordchar"); |
| 1116 | break; |
| 1117 | |
| 1118 | case begbuf: |
| 1119 | printf ("/begbuf"); |
| 1120 | break; |
| 1121 | |
| 1122 | case endbuf: |
| 1123 | printf ("/endbuf"); |
| 1124 | break; |
| 1125 | |
| 1126 | default: |
| 1127 | printf ("?%ld", (long int) *(p-1)); |
| 1128 | } |
| 1129 | |
| 1130 | putchar ('\n'); |
| 1131 | } |
| 1132 | |
| 1133 | # ifdef _LIBC |
| 1134 | printf ("%td:\tend of pattern.\n", p - start); |
| 1135 | # else |
| 1136 | printf ("%ld:\tend of pattern.\n", (long int) (p - start)); |
| 1137 | # endif |
| 1138 | } |
| 1139 | |
| 1140 | |
| 1141 | void |
| 1142 | PREFIX(print_compiled_pattern) (struct re_pattern_buffer *bufp) |
| 1143 | { |
| 1144 | UCHAR_T *buffer = (UCHAR_T*) bufp->buffer; |
| 1145 | |
| 1146 | PREFIX(print_partial_compiled_pattern) (buffer, buffer |
| 1147 | + bufp->used / sizeof(UCHAR_T)); |
| 1148 | printf ("%ld bytes used/%ld bytes allocated.\n", |
| 1149 | bufp->used, bufp->allocated); |
| 1150 | |
| 1151 | if (bufp->fastmap_accurate && bufp->fastmap) |
| 1152 | { |
| 1153 | printf ("fastmap: "); |
| 1154 | print_fastmap (bufp->fastmap); |
| 1155 | } |
| 1156 | |
| 1157 | # ifdef _LIBC |
| 1158 | printf ("re_nsub: %Zd\t", bufp->re_nsub); |
| 1159 | # else |
| 1160 | printf ("re_nsub: %ld\t", (long int) bufp->re_nsub); |
| 1161 | # endif |
| 1162 | printf ("regs_alloc: %d\t", bufp->regs_allocated); |
| 1163 | printf ("can_be_null: %d\t", bufp->can_be_null); |
| 1164 | printf ("newline_anchor: %d\n", bufp->newline_anchor); |
| 1165 | printf ("no_sub: %d\t", bufp->no_sub); |
| 1166 | printf ("not_bol: %d\t", bufp->not_bol); |
| 1167 | printf ("not_eol: %d\t", bufp->not_eol); |
| 1168 | printf ("syntax: %lx\n", bufp->syntax); |
| 1169 | /* Perhaps we should print the translate table? */ |
| 1170 | } |
| 1171 | |
| 1172 | |
| 1173 | void |
| 1174 | PREFIX(print_double_string) (const CHAR_T *where, const CHAR_T *string1, |
| 1175 | int size1, const CHAR_T *string2, int size2) |
| 1176 | { |
| 1177 | int this_char; |
| 1178 | |
| 1179 | if (where == NULL) |
| 1180 | printf ("(null)"); |
| 1181 | else |
| 1182 | { |
| 1183 | int cnt; |
| 1184 | |
| 1185 | if (FIRST_STRING_P (where)) |
| 1186 | { |
| 1187 | for (this_char = where - string1; this_char < size1; this_char++) |
| 1188 | PUT_CHAR (string1[this_char]); |
| 1189 | |
| 1190 | where = string2; |
| 1191 | } |
| 1192 | |
| 1193 | cnt = 0; |
| 1194 | for (this_char = where - string2; this_char < size2; this_char++) |
| 1195 | { |
| 1196 | PUT_CHAR (string2[this_char]); |
| 1197 | if (++cnt > 100) |
| 1198 | { |
| 1199 | fputs ("...", stdout); |
| 1200 | break; |
| 1201 | } |
| 1202 | } |
| 1203 | } |
| 1204 | } |
| 1205 | |
| 1206 | # ifndef DEFINED_ONCE |
| 1207 | void |
| 1208 | printchar (int c) |
| 1209 | { |
| 1210 | putc (c, stderr); |
| 1211 | } |
| 1212 | # endif |
| 1213 | |
| 1214 | # else /* not DEBUG */ |
| 1215 | |
| 1216 | # ifndef DEFINED_ONCE |
| 1217 | # undef assert |
| 1218 | # define assert(e) |
| 1219 | |
| 1220 | # define DEBUG_STATEMENT(e) |
| 1221 | # define DEBUG_PRINT1(x) |
| 1222 | # define DEBUG_PRINT2(x1, x2) |
| 1223 | # define DEBUG_PRINT3(x1, x2, x3) |
| 1224 | # define DEBUG_PRINT4(x1, x2, x3, x4) |
| 1225 | # endif /* not DEFINED_ONCE */ |
| 1226 | # define DEBUG_PRINT_COMPILED_PATTERN(p, s, e) |
| 1227 | # define DEBUG_PRINT_DOUBLE_STRING(w, s1, sz1, s2, sz2) |
| 1228 | |
| 1229 | # endif /* not DEBUG */ |
| 1230 | |
| 1231 | \f |
| 1232 | |
| 1233 | # ifdef WCHAR |
| 1234 | /* This convert a multibyte string to a wide character string. |
| 1235 | And write their correspondances to offset_buffer(see below) |
| 1236 | and write whether each wchar_t is binary data to is_binary. |
| 1237 | This assume invalid multibyte sequences as binary data. |
| 1238 | We assume offset_buffer and is_binary is already allocated |
| 1239 | enough space. */ |
| 1240 | |
| 1241 | static size_t convert_mbs_to_wcs (CHAR_T *dest, const unsigned char* src, |
| 1242 | size_t len, int *offset_buffer, |
| 1243 | char *is_binary); |
| 1244 | static size_t |
| 1245 | convert_mbs_to_wcs (CHAR_T *dest, const unsigned char*src, size_t len, |
| 1246 | int *offset_buffer, char *is_binary) |
| 1247 | /* It hold correspondances between src(char string) and |
| 1248 | dest(wchar_t string) for optimization. |
| 1249 | e.g. src = "xxxyzz" |
| 1250 | dest = {'X', 'Y', 'Z'} |
| 1251 | (each "xxx", "y" and "zz" represent one multibyte character |
| 1252 | corresponding to 'X', 'Y' and 'Z'.) |
| 1253 | offset_buffer = {0, 0+3("xxx"), 0+3+1("y"), 0+3+1+2("zz")} |
| 1254 | = {0, 3, 4, 6} |
| 1255 | */ |
| 1256 | { |
| 1257 | wchar_t *pdest = dest; |
| 1258 | const unsigned char *psrc = src; |
| 1259 | size_t wc_count = 0; |
| 1260 | |
| 1261 | mbstate_t mbs; |
| 1262 | int i, consumed; |
| 1263 | size_t mb_remain = len; |
| 1264 | size_t mb_count = 0; |
| 1265 | |
| 1266 | /* Initialize the conversion state. */ |
| 1267 | memset (&mbs, 0, sizeof (mbstate_t)); |
| 1268 | |
| 1269 | offset_buffer[0] = 0; |
| 1270 | for( ; mb_remain > 0 ; ++wc_count, ++pdest, mb_remain -= consumed, |
| 1271 | psrc += consumed) |
| 1272 | { |
| 1273 | #ifdef _LIBC |
| 1274 | consumed = __mbrtowc (pdest, psrc, mb_remain, &mbs); |
| 1275 | #else |
| 1276 | consumed = mbrtowc (pdest, psrc, mb_remain, &mbs); |
| 1277 | #endif |
| 1278 | |
| 1279 | if (consumed <= 0) |
| 1280 | /* failed to convert. maybe src contains binary data. |
| 1281 | So we consume 1 byte manualy. */ |
| 1282 | { |
| 1283 | *pdest = *psrc; |
| 1284 | consumed = 1; |
| 1285 | is_binary[wc_count] = TRUE; |
| 1286 | } |
| 1287 | else |
| 1288 | is_binary[wc_count] = FALSE; |
| 1289 | /* In sjis encoding, we use yen sign as escape character in |
| 1290 | place of reverse solidus. So we convert 0x5c(yen sign in |
| 1291 | sjis) to not 0xa5(yen sign in UCS2) but 0x5c(reverse |
| 1292 | solidus in UCS2). */ |
| 1293 | if (consumed == 1 && (int) *psrc == 0x5c && (int) *pdest == 0xa5) |
| 1294 | *pdest = (wchar_t) *psrc; |
| 1295 | |
| 1296 | offset_buffer[wc_count + 1] = mb_count += consumed; |
| 1297 | } |
| 1298 | |
| 1299 | /* Fill remain of the buffer with sentinel. */ |
| 1300 | for (i = wc_count + 1 ; i <= len ; i++) |
| 1301 | offset_buffer[i] = mb_count + 1; |
| 1302 | |
| 1303 | return wc_count; |
| 1304 | } |
| 1305 | |
| 1306 | # endif /* WCHAR */ |
| 1307 | |
| 1308 | #else /* not INSIDE_RECURSION */ |
| 1309 | |
| 1310 | /* Set by `re_set_syntax' to the current regexp syntax to recognize. Can |
| 1311 | also be assigned to arbitrarily: each pattern buffer stores its own |
| 1312 | syntax, so it can be changed between regex compilations. */ |
| 1313 | /* This has no initializer because initialized variables in Emacs |
| 1314 | become read-only after dumping. */ |
| 1315 | reg_syntax_t re_syntax_options; |
| 1316 | |
| 1317 | |
| 1318 | /* Specify the precise syntax of regexps for compilation. This provides |
| 1319 | for compatibility for various utilities which historically have |
| 1320 | different, incompatible syntaxes. |
| 1321 | |
| 1322 | The argument SYNTAX is a bit mask comprised of the various bits |
| 1323 | defined in regex.h. We return the old syntax. */ |
| 1324 | |
| 1325 | reg_syntax_t |
| 1326 | re_set_syntax (reg_syntax_t syntax) |
| 1327 | { |
| 1328 | reg_syntax_t ret = re_syntax_options; |
| 1329 | |
| 1330 | re_syntax_options = syntax; |
| 1331 | # ifdef DEBUG |
| 1332 | if (syntax & RE_DEBUG) |
| 1333 | debug = 1; |
| 1334 | else if (debug) /* was on but now is not */ |
| 1335 | debug = 0; |
| 1336 | # endif /* DEBUG */ |
| 1337 | return ret; |
| 1338 | } |
| 1339 | # ifdef _LIBC |
| 1340 | weak_alias (__re_set_syntax, re_set_syntax) |
| 1341 | # endif |
| 1342 | \f |
| 1343 | /* This table gives an error message for each of the error codes listed |
| 1344 | in regex.h. Obviously the order here has to be same as there. |
| 1345 | POSIX doesn't require that we do anything for REG_NOERROR, |
| 1346 | but why not be nice? */ |
| 1347 | |
| 1348 | static const char *re_error_msgid[] = |
| 1349 | { |
| 1350 | gettext_noop ("Success"), /* REG_NOERROR */ |
| 1351 | gettext_noop ("No match"), /* REG_NOMATCH */ |
| 1352 | gettext_noop ("Invalid regular expression"), /* REG_BADPAT */ |
| 1353 | gettext_noop ("Invalid collation character"), /* REG_ECOLLATE */ |
| 1354 | gettext_noop ("Invalid character class name"), /* REG_ECTYPE */ |
| 1355 | gettext_noop ("Trailing backslash"), /* REG_EESCAPE */ |
| 1356 | gettext_noop ("Invalid back reference"), /* REG_ESUBREG */ |
| 1357 | gettext_noop ("Unmatched [ or [^"), /* REG_EBRACK */ |
| 1358 | gettext_noop ("Unmatched ( or \\("), /* REG_EPAREN */ |
| 1359 | gettext_noop ("Unmatched \\{"), /* REG_EBRACE */ |
| 1360 | gettext_noop ("Invalid content of \\{\\}"), /* REG_BADBR */ |
| 1361 | gettext_noop ("Invalid range end"), /* REG_ERANGE */ |
| 1362 | gettext_noop ("Memory exhausted"), /* REG_ESPACE */ |
| 1363 | gettext_noop ("Invalid preceding regular expression"), /* REG_BADRPT */ |
| 1364 | gettext_noop ("Premature end of regular expression"), /* REG_EEND */ |
| 1365 | gettext_noop ("Regular expression too big"), /* REG_ESIZE */ |
| 1366 | gettext_noop ("Unmatched ) or \\)") /* REG_ERPAREN */ |
| 1367 | }; |
| 1368 | \f |
| 1369 | #endif /* INSIDE_RECURSION */ |
| 1370 | |
| 1371 | #ifndef DEFINED_ONCE |
| 1372 | /* Avoiding alloca during matching, to placate r_alloc. */ |
| 1373 | |
| 1374 | /* Define MATCH_MAY_ALLOCATE unless we need to make sure that the |
| 1375 | searching and matching functions should not call alloca. On some |
| 1376 | systems, alloca is implemented in terms of malloc, and if we're |
| 1377 | using the relocating allocator routines, then malloc could cause a |
| 1378 | relocation, which might (if the strings being searched are in the |
| 1379 | ralloc heap) shift the data out from underneath the regexp |
| 1380 | routines. |
| 1381 | |
| 1382 | Here's another reason to avoid allocation: Emacs |
| 1383 | processes input from X in a signal handler; processing X input may |
| 1384 | call malloc; if input arrives while a matching routine is calling |
| 1385 | malloc, then we're scrod. But Emacs can't just block input while |
| 1386 | calling matching routines; then we don't notice interrupts when |
| 1387 | they come in. So, Emacs blocks input around all regexp calls |
| 1388 | except the matching calls, which it leaves unprotected, in the |
| 1389 | faith that they will not malloc. */ |
| 1390 | |
| 1391 | /* Normally, this is fine. */ |
| 1392 | # define MATCH_MAY_ALLOCATE |
| 1393 | |
| 1394 | /* When using GNU C, we are not REALLY using the C alloca, no matter |
| 1395 | what config.h may say. So don't take precautions for it. */ |
| 1396 | # ifdef __GNUC__ |
| 1397 | # undef C_ALLOCA |
| 1398 | # endif |
| 1399 | |
| 1400 | /* The match routines may not allocate if (1) they would do it with malloc |
| 1401 | and (2) it's not safe for them to use malloc. |
| 1402 | Note that if REL_ALLOC is defined, matching would not use malloc for the |
| 1403 | failure stack, but we would still use it for the register vectors; |
| 1404 | so REL_ALLOC should not affect this. */ |
| 1405 | # if (defined C_ALLOCA || defined REGEX_MALLOC) && defined emacs |
| 1406 | # undef MATCH_MAY_ALLOCATE |
| 1407 | # endif |
| 1408 | #endif /* not DEFINED_ONCE */ |
| 1409 | \f |
| 1410 | #ifdef INSIDE_RECURSION |
| 1411 | /* Failure stack declarations and macros; both re_compile_fastmap and |
| 1412 | re_match_2 use a failure stack. These have to be macros because of |
| 1413 | REGEX_ALLOCATE_STACK. */ |
| 1414 | |
| 1415 | |
| 1416 | /* Number of failure points for which to initially allocate space |
| 1417 | when matching. If this number is exceeded, we allocate more |
| 1418 | space, so it is not a hard limit. */ |
| 1419 | # ifndef INIT_FAILURE_ALLOC |
| 1420 | # define INIT_FAILURE_ALLOC 5 |
| 1421 | # endif |
| 1422 | |
| 1423 | /* Roughly the maximum number of failure points on the stack. Would be |
| 1424 | exactly that if always used MAX_FAILURE_ITEMS items each time we failed. |
| 1425 | This is a variable only so users of regex can assign to it; we never |
| 1426 | change it ourselves. */ |
| 1427 | |
| 1428 | # ifdef INT_IS_16BIT |
| 1429 | |
| 1430 | # ifndef DEFINED_ONCE |
| 1431 | # if defined MATCH_MAY_ALLOCATE |
| 1432 | /* 4400 was enough to cause a crash on Alpha OSF/1, |
| 1433 | whose default stack limit is 2mb. */ |
| 1434 | long int re_max_failures = 4000; |
| 1435 | # else |
| 1436 | long int re_max_failures = 2000; |
| 1437 | # endif |
| 1438 | # endif |
| 1439 | |
| 1440 | union PREFIX(fail_stack_elt) |
| 1441 | { |
| 1442 | UCHAR_T *pointer; |
| 1443 | long int integer; |
| 1444 | }; |
| 1445 | |
| 1446 | typedef union PREFIX(fail_stack_elt) PREFIX(fail_stack_elt_t); |
| 1447 | |
| 1448 | typedef struct |
| 1449 | { |
| 1450 | PREFIX(fail_stack_elt_t) *stack; |
| 1451 | unsigned long int size; |
| 1452 | unsigned long int avail; /* Offset of next open position. */ |
| 1453 | } PREFIX(fail_stack_type); |
| 1454 | |
| 1455 | # else /* not INT_IS_16BIT */ |
| 1456 | |
| 1457 | # ifndef DEFINED_ONCE |
| 1458 | # if defined MATCH_MAY_ALLOCATE |
| 1459 | /* 4400 was enough to cause a crash on Alpha OSF/1, |
| 1460 | whose default stack limit is 2mb. */ |
| 1461 | int re_max_failures = 4000; |
| 1462 | # else |
| 1463 | int re_max_failures = 2000; |
| 1464 | # endif |
| 1465 | # endif |
| 1466 | |
| 1467 | union PREFIX(fail_stack_elt) |
| 1468 | { |
| 1469 | UCHAR_T *pointer; |
| 1470 | int integer; |
| 1471 | }; |
| 1472 | |
| 1473 | typedef union PREFIX(fail_stack_elt) PREFIX(fail_stack_elt_t); |
| 1474 | |
| 1475 | typedef struct |
| 1476 | { |
| 1477 | PREFIX(fail_stack_elt_t) *stack; |
| 1478 | unsigned size; |
| 1479 | unsigned avail; /* Offset of next open position. */ |
| 1480 | } PREFIX(fail_stack_type); |
| 1481 | |
| 1482 | # endif /* INT_IS_16BIT */ |
| 1483 | |
| 1484 | # ifndef DEFINED_ONCE |
| 1485 | # define FAIL_STACK_EMPTY() (fail_stack.avail == 0) |
| 1486 | # define FAIL_STACK_PTR_EMPTY() (fail_stack_ptr->avail == 0) |
| 1487 | # define FAIL_STACK_FULL() (fail_stack.avail == fail_stack.size) |
| 1488 | # endif |
| 1489 | |
| 1490 | |
| 1491 | /* Define macros to initialize and free the failure stack. |
| 1492 | Do `return -2' if the alloc fails. */ |
| 1493 | |
| 1494 | # ifdef MATCH_MAY_ALLOCATE |
| 1495 | # define INIT_FAIL_STACK() \ |
| 1496 | do { \ |
| 1497 | fail_stack.stack = (PREFIX(fail_stack_elt_t) *) \ |
| 1498 | REGEX_ALLOCATE_STACK (INIT_FAILURE_ALLOC * sizeof (PREFIX(fail_stack_elt_t))); \ |
| 1499 | \ |
| 1500 | if (fail_stack.stack == NULL) \ |
| 1501 | return -2; \ |
| 1502 | \ |
| 1503 | fail_stack.size = INIT_FAILURE_ALLOC; \ |
| 1504 | fail_stack.avail = 0; \ |
| 1505 | } while (0) |
| 1506 | |
| 1507 | # define RESET_FAIL_STACK() REGEX_FREE_STACK (fail_stack.stack) |
| 1508 | # else |
| 1509 | # define INIT_FAIL_STACK() \ |
| 1510 | do { \ |
| 1511 | fail_stack.avail = 0; \ |
| 1512 | } while (0) |
| 1513 | |
| 1514 | # define RESET_FAIL_STACK() |
| 1515 | # endif |
| 1516 | |
| 1517 | |
| 1518 | /* Double the size of FAIL_STACK, up to approximately `re_max_failures' items. |
| 1519 | |
| 1520 | Return 1 if succeeds, and 0 if either ran out of memory |
| 1521 | allocating space for it or it was already too large. |
| 1522 | |
| 1523 | REGEX_REALLOCATE_STACK requires `destination' be declared. */ |
| 1524 | |
| 1525 | # define DOUBLE_FAIL_STACK(fail_stack) \ |
| 1526 | ((fail_stack).size > (unsigned) (re_max_failures * MAX_FAILURE_ITEMS) \ |
| 1527 | ? 0 \ |
| 1528 | : ((fail_stack).stack = (PREFIX(fail_stack_elt_t) *) \ |
| 1529 | REGEX_REALLOCATE_STACK ((fail_stack).stack, \ |
| 1530 | (fail_stack).size * sizeof (PREFIX(fail_stack_elt_t)), \ |
| 1531 | ((fail_stack).size << 1) * sizeof (PREFIX(fail_stack_elt_t))),\ |
| 1532 | \ |
| 1533 | (fail_stack).stack == NULL \ |
| 1534 | ? 0 \ |
| 1535 | : ((fail_stack).size <<= 1, \ |
| 1536 | 1))) |
| 1537 | |
| 1538 | |
| 1539 | /* Push pointer POINTER on FAIL_STACK. |
| 1540 | Return 1 if was able to do so and 0 if ran out of memory allocating |
| 1541 | space to do so. */ |
| 1542 | # define PUSH_PATTERN_OP(POINTER, FAIL_STACK) \ |
| 1543 | ((FAIL_STACK_FULL () \ |
| 1544 | && !DOUBLE_FAIL_STACK (FAIL_STACK)) \ |
| 1545 | ? 0 \ |
| 1546 | : ((FAIL_STACK).stack[(FAIL_STACK).avail++].pointer = POINTER, \ |
| 1547 | 1)) |
| 1548 | |
| 1549 | /* Push a pointer value onto the failure stack. |
| 1550 | Assumes the variable `fail_stack'. Probably should only |
| 1551 | be called from within `PUSH_FAILURE_POINT'. */ |
| 1552 | # define PUSH_FAILURE_POINTER(item) \ |
| 1553 | fail_stack.stack[fail_stack.avail++].pointer = (UCHAR_T *) (item) |
| 1554 | |
| 1555 | /* This pushes an integer-valued item onto the failure stack. |
| 1556 | Assumes the variable `fail_stack'. Probably should only |
| 1557 | be called from within `PUSH_FAILURE_POINT'. */ |
| 1558 | # define PUSH_FAILURE_INT(item) \ |
| 1559 | fail_stack.stack[fail_stack.avail++].integer = (item) |
| 1560 | |
| 1561 | /* Push a fail_stack_elt_t value onto the failure stack. |
| 1562 | Assumes the variable `fail_stack'. Probably should only |
| 1563 | be called from within `PUSH_FAILURE_POINT'. */ |
| 1564 | # define PUSH_FAILURE_ELT(item) \ |
| 1565 | fail_stack.stack[fail_stack.avail++] = (item) |
| 1566 | |
| 1567 | /* These three POP... operations complement the three PUSH... operations. |
| 1568 | All assume that `fail_stack' is nonempty. */ |
| 1569 | # define POP_FAILURE_POINTER() fail_stack.stack[--fail_stack.avail].pointer |
| 1570 | # define POP_FAILURE_INT() fail_stack.stack[--fail_stack.avail].integer |
| 1571 | # define POP_FAILURE_ELT() fail_stack.stack[--fail_stack.avail] |
| 1572 | |
| 1573 | /* Used to omit pushing failure point id's when we're not debugging. */ |
| 1574 | # ifdef DEBUG |
| 1575 | # define DEBUG_PUSH PUSH_FAILURE_INT |
| 1576 | # define DEBUG_POP(item_addr) *(item_addr) = POP_FAILURE_INT () |
| 1577 | # else |
| 1578 | # define DEBUG_PUSH(item) |
| 1579 | # define DEBUG_POP(item_addr) |
| 1580 | # endif |
| 1581 | |
| 1582 | |
| 1583 | /* Push the information about the state we will need |
| 1584 | if we ever fail back to it. |
| 1585 | |
| 1586 | Requires variables fail_stack, regstart, regend, reg_info, and |
| 1587 | num_regs_pushed be declared. DOUBLE_FAIL_STACK requires `destination' |
| 1588 | be declared. |
| 1589 | |
| 1590 | Does `return FAILURE_CODE' if runs out of memory. */ |
| 1591 | |
| 1592 | # define PUSH_FAILURE_POINT(pattern_place, string_place, failure_code) \ |
| 1593 | do { \ |
| 1594 | char *destination; \ |
| 1595 | /* Must be int, so when we don't save any registers, the arithmetic \ |
| 1596 | of 0 + -1 isn't done as unsigned. */ \ |
| 1597 | /* Can't be int, since there is not a shred of a guarantee that int \ |
| 1598 | is wide enough to hold a value of something to which pointer can \ |
| 1599 | be assigned */ \ |
| 1600 | active_reg_t this_reg; \ |
| 1601 | \ |
| 1602 | DEBUG_STATEMENT (failure_id++); \ |
| 1603 | DEBUG_STATEMENT (nfailure_points_pushed++); \ |
| 1604 | DEBUG_PRINT2 ("\nPUSH_FAILURE_POINT #%u:\n", failure_id); \ |
| 1605 | DEBUG_PRINT2 (" Before push, next avail: %d\n", (fail_stack).avail);\ |
| 1606 | DEBUG_PRINT2 (" size: %d\n", (fail_stack).size);\ |
| 1607 | \ |
| 1608 | DEBUG_PRINT2 (" slots needed: %ld\n", NUM_FAILURE_ITEMS); \ |
| 1609 | DEBUG_PRINT2 (" available: %d\n", REMAINING_AVAIL_SLOTS); \ |
| 1610 | \ |
| 1611 | /* Ensure we have enough space allocated for what we will push. */ \ |
| 1612 | while (REMAINING_AVAIL_SLOTS < NUM_FAILURE_ITEMS) \ |
| 1613 | { \ |
| 1614 | if (!DOUBLE_FAIL_STACK (fail_stack)) \ |
| 1615 | return failure_code; \ |
| 1616 | \ |
| 1617 | DEBUG_PRINT2 ("\n Doubled stack; size now: %d\n", \ |
| 1618 | (fail_stack).size); \ |
| 1619 | DEBUG_PRINT2 (" slots available: %d\n", REMAINING_AVAIL_SLOTS);\ |
| 1620 | } \ |
| 1621 | \ |
| 1622 | /* Push the info, starting with the registers. */ \ |
| 1623 | DEBUG_PRINT1 ("\n"); \ |
| 1624 | \ |
| 1625 | if (1) \ |
| 1626 | for (this_reg = lowest_active_reg; this_reg <= highest_active_reg; \ |
| 1627 | this_reg++) \ |
| 1628 | { \ |
| 1629 | DEBUG_PRINT2 (" Pushing reg: %lu\n", this_reg); \ |
| 1630 | DEBUG_STATEMENT (num_regs_pushed++); \ |
| 1631 | \ |
| 1632 | DEBUG_PRINT2 (" start: %p\n", regstart[this_reg]); \ |
| 1633 | PUSH_FAILURE_POINTER (regstart[this_reg]); \ |
| 1634 | \ |
| 1635 | DEBUG_PRINT2 (" end: %p\n", regend[this_reg]); \ |
| 1636 | PUSH_FAILURE_POINTER (regend[this_reg]); \ |
| 1637 | \ |
| 1638 | DEBUG_PRINT2 (" info: %p\n ", \ |
| 1639 | reg_info[this_reg].word.pointer); \ |
| 1640 | DEBUG_PRINT2 (" match_null=%d", \ |
| 1641 | REG_MATCH_NULL_STRING_P (reg_info[this_reg])); \ |
| 1642 | DEBUG_PRINT2 (" active=%d", IS_ACTIVE (reg_info[this_reg])); \ |
| 1643 | DEBUG_PRINT2 (" matched_something=%d", \ |
| 1644 | MATCHED_SOMETHING (reg_info[this_reg])); \ |
| 1645 | DEBUG_PRINT2 (" ever_matched=%d", \ |
| 1646 | EVER_MATCHED_SOMETHING (reg_info[this_reg])); \ |
| 1647 | DEBUG_PRINT1 ("\n"); \ |
| 1648 | PUSH_FAILURE_ELT (reg_info[this_reg].word); \ |
| 1649 | } \ |
| 1650 | \ |
| 1651 | DEBUG_PRINT2 (" Pushing low active reg: %ld\n", lowest_active_reg);\ |
| 1652 | PUSH_FAILURE_INT (lowest_active_reg); \ |
| 1653 | \ |
| 1654 | DEBUG_PRINT2 (" Pushing high active reg: %ld\n", highest_active_reg);\ |
| 1655 | PUSH_FAILURE_INT (highest_active_reg); \ |
| 1656 | \ |
| 1657 | DEBUG_PRINT2 (" Pushing pattern %p:\n", pattern_place); \ |
| 1658 | DEBUG_PRINT_COMPILED_PATTERN (bufp, pattern_place, pend); \ |
| 1659 | PUSH_FAILURE_POINTER (pattern_place); \ |
| 1660 | \ |
| 1661 | DEBUG_PRINT2 (" Pushing string %p: `", string_place); \ |
| 1662 | DEBUG_PRINT_DOUBLE_STRING (string_place, string1, size1, string2, \ |
| 1663 | size2); \ |
| 1664 | DEBUG_PRINT1 ("'\n"); \ |
| 1665 | PUSH_FAILURE_POINTER (string_place); \ |
| 1666 | \ |
| 1667 | DEBUG_PRINT2 (" Pushing failure id: %u\n", failure_id); \ |
| 1668 | DEBUG_PUSH (failure_id); \ |
| 1669 | } while (0) |
| 1670 | |
| 1671 | # ifndef DEFINED_ONCE |
| 1672 | /* This is the number of items that are pushed and popped on the stack |
| 1673 | for each register. */ |
| 1674 | # define NUM_REG_ITEMS 3 |
| 1675 | |
| 1676 | /* Individual items aside from the registers. */ |
| 1677 | # ifdef DEBUG |
| 1678 | # define NUM_NONREG_ITEMS 5 /* Includes failure point id. */ |
| 1679 | # else |
| 1680 | # define NUM_NONREG_ITEMS 4 |
| 1681 | # endif |
| 1682 | |
| 1683 | /* We push at most this many items on the stack. */ |
| 1684 | /* We used to use (num_regs - 1), which is the number of registers |
| 1685 | this regexp will save; but that was changed to 5 |
| 1686 | to avoid stack overflow for a regexp with lots of parens. */ |
| 1687 | # define MAX_FAILURE_ITEMS (5 * NUM_REG_ITEMS + NUM_NONREG_ITEMS) |
| 1688 | |
| 1689 | /* We actually push this many items. */ |
| 1690 | # define NUM_FAILURE_ITEMS \ |
| 1691 | (((0 \ |
| 1692 | ? 0 : highest_active_reg - lowest_active_reg + 1) \ |
| 1693 | * NUM_REG_ITEMS) \ |
| 1694 | + NUM_NONREG_ITEMS) |
| 1695 | |
| 1696 | /* How many items can still be added to the stack without overflowing it. */ |
| 1697 | # define REMAINING_AVAIL_SLOTS ((fail_stack).size - (fail_stack).avail) |
| 1698 | # endif /* not DEFINED_ONCE */ |
| 1699 | |
| 1700 | |
| 1701 | /* Pops what PUSH_FAIL_STACK pushes. |
| 1702 | |
| 1703 | We restore into the parameters, all of which should be lvalues: |
| 1704 | STR -- the saved data position. |
| 1705 | PAT -- the saved pattern position. |
| 1706 | LOW_REG, HIGH_REG -- the highest and lowest active registers. |
| 1707 | REGSTART, REGEND -- arrays of string positions. |
| 1708 | REG_INFO -- array of information about each subexpression. |
| 1709 | |
| 1710 | Also assumes the variables `fail_stack' and (if debugging), `bufp', |
| 1711 | `pend', `string1', `size1', `string2', and `size2'. */ |
| 1712 | # define POP_FAILURE_POINT(str, pat, low_reg, high_reg, regstart, regend, reg_info)\ |
| 1713 | { \ |
| 1714 | DEBUG_STATEMENT (unsigned failure_id;) \ |
| 1715 | active_reg_t this_reg; \ |
| 1716 | const UCHAR_T *string_temp; \ |
| 1717 | \ |
| 1718 | assert (!FAIL_STACK_EMPTY ()); \ |
| 1719 | \ |
| 1720 | /* Remove failure points and point to how many regs pushed. */ \ |
| 1721 | DEBUG_PRINT1 ("POP_FAILURE_POINT:\n"); \ |
| 1722 | DEBUG_PRINT2 (" Before pop, next avail: %d\n", fail_stack.avail); \ |
| 1723 | DEBUG_PRINT2 (" size: %d\n", fail_stack.size); \ |
| 1724 | \ |
| 1725 | assert (fail_stack.avail >= NUM_NONREG_ITEMS); \ |
| 1726 | \ |
| 1727 | DEBUG_POP (&failure_id); \ |
| 1728 | DEBUG_PRINT2 (" Popping failure id: %u\n", failure_id); \ |
| 1729 | \ |
| 1730 | /* If the saved string location is NULL, it came from an \ |
| 1731 | on_failure_keep_string_jump opcode, and we want to throw away the \ |
| 1732 | saved NULL, thus retaining our current position in the string. */ \ |
| 1733 | string_temp = POP_FAILURE_POINTER (); \ |
| 1734 | if (string_temp != NULL) \ |
| 1735 | str = (const CHAR_T *) string_temp; \ |
| 1736 | \ |
| 1737 | DEBUG_PRINT2 (" Popping string %p: `", str); \ |
| 1738 | DEBUG_PRINT_DOUBLE_STRING (str, string1, size1, string2, size2); \ |
| 1739 | DEBUG_PRINT1 ("'\n"); \ |
| 1740 | \ |
| 1741 | pat = (UCHAR_T *) POP_FAILURE_POINTER (); \ |
| 1742 | DEBUG_PRINT2 (" Popping pattern %p:\n", pat); \ |
| 1743 | DEBUG_PRINT_COMPILED_PATTERN (bufp, pat, pend); \ |
| 1744 | \ |
| 1745 | /* Restore register info. */ \ |
| 1746 | high_reg = (active_reg_t) POP_FAILURE_INT (); \ |
| 1747 | DEBUG_PRINT2 (" Popping high active reg: %ld\n", high_reg); \ |
| 1748 | \ |
| 1749 | low_reg = (active_reg_t) POP_FAILURE_INT (); \ |
| 1750 | DEBUG_PRINT2 (" Popping low active reg: %ld\n", low_reg); \ |
| 1751 | \ |
| 1752 | if (1) \ |
| 1753 | for (this_reg = high_reg; this_reg >= low_reg; this_reg--) \ |
| 1754 | { \ |
| 1755 | DEBUG_PRINT2 (" Popping reg: %ld\n", this_reg); \ |
| 1756 | \ |
| 1757 | reg_info[this_reg].word = POP_FAILURE_ELT (); \ |
| 1758 | DEBUG_PRINT2 (" info: %p\n", \ |
| 1759 | reg_info[this_reg].word.pointer); \ |
| 1760 | \ |
| 1761 | regend[this_reg] = (const CHAR_T *) POP_FAILURE_POINTER (); \ |
| 1762 | DEBUG_PRINT2 (" end: %p\n", regend[this_reg]); \ |
| 1763 | \ |
| 1764 | regstart[this_reg] = (const CHAR_T *) POP_FAILURE_POINTER (); \ |
| 1765 | DEBUG_PRINT2 (" start: %p\n", regstart[this_reg]); \ |
| 1766 | } \ |
| 1767 | else \ |
| 1768 | { \ |
| 1769 | for (this_reg = highest_active_reg; this_reg > high_reg; this_reg--) \ |
| 1770 | { \ |
| 1771 | reg_info[this_reg].word.integer = 0; \ |
| 1772 | regend[this_reg] = 0; \ |
| 1773 | regstart[this_reg] = 0; \ |
| 1774 | } \ |
| 1775 | highest_active_reg = high_reg; \ |
| 1776 | } \ |
| 1777 | \ |
| 1778 | set_regs_matched_done = 0; \ |
| 1779 | DEBUG_STATEMENT (nfailure_points_popped++); \ |
| 1780 | } /* POP_FAILURE_POINT */ |
| 1781 | \f |
| 1782 | /* Structure for per-register (a.k.a. per-group) information. |
| 1783 | Other register information, such as the |
| 1784 | starting and ending positions (which are addresses), and the list of |
| 1785 | inner groups (which is a bits list) are maintained in separate |
| 1786 | variables. |
| 1787 | |
| 1788 | We are making a (strictly speaking) nonportable assumption here: that |
| 1789 | the compiler will pack our bit fields into something that fits into |
| 1790 | the type of `word', i.e., is something that fits into one item on the |
| 1791 | failure stack. */ |
| 1792 | |
| 1793 | |
| 1794 | /* Declarations and macros for re_match_2. */ |
| 1795 | |
| 1796 | typedef union |
| 1797 | { |
| 1798 | PREFIX(fail_stack_elt_t) word; |
| 1799 | struct |
| 1800 | { |
| 1801 | /* This field is one if this group can match the empty string, |
| 1802 | zero if not. If not yet determined, `MATCH_NULL_UNSET_VALUE'. */ |
| 1803 | # define MATCH_NULL_UNSET_VALUE 3 |
| 1804 | unsigned match_null_string_p : 2; |
| 1805 | unsigned is_active : 1; |
| 1806 | unsigned matched_something : 1; |
| 1807 | unsigned ever_matched_something : 1; |
| 1808 | } bits; |
| 1809 | } PREFIX(register_info_type); |
| 1810 | |
| 1811 | # ifndef DEFINED_ONCE |
| 1812 | # define REG_MATCH_NULL_STRING_P(R) ((R).bits.match_null_string_p) |
| 1813 | # define IS_ACTIVE(R) ((R).bits.is_active) |
| 1814 | # define MATCHED_SOMETHING(R) ((R).bits.matched_something) |
| 1815 | # define EVER_MATCHED_SOMETHING(R) ((R).bits.ever_matched_something) |
| 1816 | |
| 1817 | |
| 1818 | /* Call this when have matched a real character; it sets `matched' flags |
| 1819 | for the subexpressions which we are currently inside. Also records |
| 1820 | that those subexprs have matched. */ |
| 1821 | # define SET_REGS_MATCHED() \ |
| 1822 | do \ |
| 1823 | { \ |
| 1824 | if (!set_regs_matched_done) \ |
| 1825 | { \ |
| 1826 | active_reg_t r; \ |
| 1827 | set_regs_matched_done = 1; \ |
| 1828 | for (r = lowest_active_reg; r <= highest_active_reg; r++) \ |
| 1829 | { \ |
| 1830 | MATCHED_SOMETHING (reg_info[r]) \ |
| 1831 | = EVER_MATCHED_SOMETHING (reg_info[r]) \ |
| 1832 | = 1; \ |
| 1833 | } \ |
| 1834 | } \ |
| 1835 | } \ |
| 1836 | while (0) |
| 1837 | # endif /* not DEFINED_ONCE */ |
| 1838 | |
| 1839 | /* Registers are set to a sentinel when they haven't yet matched. */ |
| 1840 | static CHAR_T PREFIX(reg_unset_dummy); |
| 1841 | # define REG_UNSET_VALUE (&PREFIX(reg_unset_dummy)) |
| 1842 | # define REG_UNSET(e) ((e) == REG_UNSET_VALUE) |
| 1843 | |
| 1844 | /* Subroutine declarations and macros for regex_compile. */ |
| 1845 | static void PREFIX(store_op1) (re_opcode_t op, UCHAR_T *loc, int arg); |
| 1846 | static void PREFIX(store_op2) (re_opcode_t op, UCHAR_T *loc, |
| 1847 | int arg1, int arg2); |
| 1848 | static void PREFIX(insert_op1) (re_opcode_t op, UCHAR_T *loc, |
| 1849 | int arg, UCHAR_T *end); |
| 1850 | static void PREFIX(insert_op2) (re_opcode_t op, UCHAR_T *loc, |
| 1851 | int arg1, int arg2, UCHAR_T *end); |
| 1852 | static boolean PREFIX(at_begline_loc_p) (const CHAR_T *pattern, |
| 1853 | const CHAR_T *p, |
| 1854 | reg_syntax_t syntax); |
| 1855 | static boolean PREFIX(at_endline_loc_p) (const CHAR_T *p, |
| 1856 | const CHAR_T *pend, |
| 1857 | reg_syntax_t syntax); |
| 1858 | # ifdef WCHAR |
| 1859 | static reg_errcode_t wcs_compile_range (CHAR_T range_start, |
| 1860 | const CHAR_T **p_ptr, |
| 1861 | const CHAR_T *pend, |
| 1862 | char *translate, |
| 1863 | reg_syntax_t syntax, |
| 1864 | UCHAR_T *b, |
| 1865 | CHAR_T *char_set); |
| 1866 | static void insert_space (int num, CHAR_T *loc, CHAR_T *end); |
| 1867 | # else /* BYTE */ |
| 1868 | static reg_errcode_t byte_compile_range (unsigned int range_start, |
| 1869 | const char **p_ptr, |
| 1870 | const char *pend, |
| 1871 | char *translate, |
| 1872 | reg_syntax_t syntax, |
| 1873 | unsigned char *b); |
| 1874 | # endif /* WCHAR */ |
| 1875 | |
| 1876 | /* Fetch the next character in the uncompiled pattern---translating it |
| 1877 | if necessary. Also cast from a signed character in the constant |
| 1878 | string passed to us by the user to an unsigned char that we can use |
| 1879 | as an array index (in, e.g., `translate'). */ |
| 1880 | /* ifdef MBS_SUPPORT, we translate only if character <= 0xff, |
| 1881 | because it is impossible to allocate 4GB array for some encodings |
| 1882 | which have 4 byte character_set like UCS4. */ |
| 1883 | # ifndef PATFETCH |
| 1884 | # ifdef WCHAR |
| 1885 | # define PATFETCH(c) \ |
| 1886 | do {if (p == pend) return REG_EEND; \ |
| 1887 | c = (UCHAR_T) *p++; \ |
| 1888 | if (translate && (c <= 0xff)) c = (UCHAR_T) translate[c]; \ |
| 1889 | } while (0) |
| 1890 | # else /* BYTE */ |
| 1891 | # define PATFETCH(c) \ |
| 1892 | do {if (p == pend) return REG_EEND; \ |
| 1893 | c = (unsigned char) *p++; \ |
| 1894 | if (translate) c = (unsigned char) translate[c]; \ |
| 1895 | } while (0) |
| 1896 | # endif /* WCHAR */ |
| 1897 | # endif |
| 1898 | |
| 1899 | /* Fetch the next character in the uncompiled pattern, with no |
| 1900 | translation. */ |
| 1901 | # define PATFETCH_RAW(c) \ |
| 1902 | do {if (p == pend) return REG_EEND; \ |
| 1903 | c = (UCHAR_T) *p++; \ |
| 1904 | } while (0) |
| 1905 | |
| 1906 | /* Go backwards one character in the pattern. */ |
| 1907 | # define PATUNFETCH p-- |
| 1908 | |
| 1909 | |
| 1910 | /* If `translate' is non-null, return translate[D], else just D. We |
| 1911 | cast the subscript to translate because some data is declared as |
| 1912 | `char *', to avoid warnings when a string constant is passed. But |
| 1913 | when we use a character as a subscript we must make it unsigned. */ |
| 1914 | /* ifdef MBS_SUPPORT, we translate only if character <= 0xff, |
| 1915 | because it is impossible to allocate 4GB array for some encodings |
| 1916 | which have 4 byte character_set like UCS4. */ |
| 1917 | |
| 1918 | # ifndef TRANSLATE |
| 1919 | # ifdef WCHAR |
| 1920 | # define TRANSLATE(d) \ |
| 1921 | ((translate && ((UCHAR_T) (d)) <= 0xff) \ |
| 1922 | ? (char) translate[(unsigned char) (d)] : (d)) |
| 1923 | # else /* BYTE */ |
| 1924 | # define TRANSLATE(d) \ |
| 1925 | (translate ? (char) translate[(unsigned char) (d)] : (char) (d)) |
| 1926 | # endif /* WCHAR */ |
| 1927 | # endif |
| 1928 | |
| 1929 | |
| 1930 | /* Macros for outputting the compiled pattern into `buffer'. */ |
| 1931 | |
| 1932 | /* If the buffer isn't allocated when it comes in, use this. */ |
| 1933 | # define INIT_BUF_SIZE (32 * sizeof(UCHAR_T)) |
| 1934 | |
| 1935 | /* Make sure we have at least N more bytes of space in buffer. */ |
| 1936 | # ifdef WCHAR |
| 1937 | # define GET_BUFFER_SPACE(n) \ |
| 1938 | while (((unsigned long)b - (unsigned long)COMPILED_BUFFER_VAR \ |
| 1939 | + (n)*sizeof(CHAR_T)) > bufp->allocated) \ |
| 1940 | EXTEND_BUFFER () |
| 1941 | # else /* BYTE */ |
| 1942 | # define GET_BUFFER_SPACE(n) \ |
| 1943 | while ((unsigned long) (b - bufp->buffer + (n)) > bufp->allocated) \ |
| 1944 | EXTEND_BUFFER () |
| 1945 | # endif /* WCHAR */ |
| 1946 | |
| 1947 | /* Make sure we have one more byte of buffer space and then add C to it. */ |
| 1948 | # define BUF_PUSH(c) \ |
| 1949 | do { \ |
| 1950 | GET_BUFFER_SPACE (1); \ |
| 1951 | *b++ = (UCHAR_T) (c); \ |
| 1952 | } while (0) |
| 1953 | |
| 1954 | |
| 1955 | /* Ensure we have two more bytes of buffer space and then append C1 and C2. */ |
| 1956 | # define BUF_PUSH_2(c1, c2) \ |
| 1957 | do { \ |
| 1958 | GET_BUFFER_SPACE (2); \ |
| 1959 | *b++ = (UCHAR_T) (c1); \ |
| 1960 | *b++ = (UCHAR_T) (c2); \ |
| 1961 | } while (0) |
| 1962 | |
| 1963 | |
| 1964 | /* As with BUF_PUSH_2, except for three bytes. */ |
| 1965 | # define BUF_PUSH_3(c1, c2, c3) \ |
| 1966 | do { \ |
| 1967 | GET_BUFFER_SPACE (3); \ |
| 1968 | *b++ = (UCHAR_T) (c1); \ |
| 1969 | *b++ = (UCHAR_T) (c2); \ |
| 1970 | *b++ = (UCHAR_T) (c3); \ |
| 1971 | } while (0) |
| 1972 | |
| 1973 | /* Store a jump with opcode OP at LOC to location TO. We store a |
| 1974 | relative address offset by the three bytes the jump itself occupies. */ |
| 1975 | # define STORE_JUMP(op, loc, to) \ |
| 1976 | PREFIX(store_op1) (op, loc, (int) ((to) - (loc) - (1 + OFFSET_ADDRESS_SIZE))) |
| 1977 | |
| 1978 | /* Likewise, for a two-argument jump. */ |
| 1979 | # define STORE_JUMP2(op, loc, to, arg) \ |
| 1980 | PREFIX(store_op2) (op, loc, (int) ((to) - (loc) - (1 + OFFSET_ADDRESS_SIZE)), arg) |
| 1981 | |
| 1982 | /* Like `STORE_JUMP', but for inserting. Assume `b' is the buffer end. */ |
| 1983 | # define INSERT_JUMP(op, loc, to) \ |
| 1984 | PREFIX(insert_op1) (op, loc, (int) ((to) - (loc) - (1 + OFFSET_ADDRESS_SIZE)), b) |
| 1985 | |
| 1986 | /* Like `STORE_JUMP2', but for inserting. Assume `b' is the buffer end. */ |
| 1987 | # define INSERT_JUMP2(op, loc, to, arg) \ |
| 1988 | PREFIX(insert_op2) (op, loc, (int) ((to) - (loc) - (1 + OFFSET_ADDRESS_SIZE)),\ |
| 1989 | arg, b) |
| 1990 | |
| 1991 | /* This is not an arbitrary limit: the arguments which represent offsets |
| 1992 | into the pattern are two bytes long. So if 2^16 bytes turns out to |
| 1993 | be too small, many things would have to change. */ |
| 1994 | /* Any other compiler which, like MSC, has allocation limit below 2^16 |
| 1995 | bytes will have to use approach similar to what was done below for |
| 1996 | MSC and drop MAX_BUF_SIZE a bit. Otherwise you may end up |
| 1997 | reallocating to 0 bytes. Such thing is not going to work too well. |
| 1998 | You have been warned!! */ |
| 1999 | # ifndef DEFINED_ONCE |
| 2000 | # if defined _MSC_VER && !defined WIN32 |
| 2001 | /* Microsoft C 16-bit versions limit malloc to approx 65512 bytes. |
| 2002 | The REALLOC define eliminates a flurry of conversion warnings, |
| 2003 | but is not required. */ |
| 2004 | # define MAX_BUF_SIZE 65500L |
| 2005 | # define REALLOC(p,s) realloc ((p), (size_t) (s)) |
| 2006 | # else |
| 2007 | # define MAX_BUF_SIZE (1L << 16) |
| 2008 | # define REALLOC(p,s) realloc ((p), (s)) |
| 2009 | # endif |
| 2010 | |
| 2011 | /* Extend the buffer by twice its current size via realloc and |
| 2012 | reset the pointers that pointed into the old block to point to the |
| 2013 | correct places in the new one. If extending the buffer results in it |
| 2014 | being larger than MAX_BUF_SIZE, then flag memory exhausted. */ |
| 2015 | # if __BOUNDED_POINTERS__ |
| 2016 | # define SET_HIGH_BOUND(P) (__ptrhigh (P) = __ptrlow (P) + bufp->allocated) |
| 2017 | # define MOVE_BUFFER_POINTER(P) \ |
| 2018 | (__ptrlow (P) += incr, SET_HIGH_BOUND (P), __ptrvalue (P) += incr) |
| 2019 | # define ELSE_EXTEND_BUFFER_HIGH_BOUND \ |
| 2020 | else \ |
| 2021 | { \ |
| 2022 | SET_HIGH_BOUND (b); \ |
| 2023 | SET_HIGH_BOUND (begalt); \ |
| 2024 | if (fixup_alt_jump) \ |
| 2025 | SET_HIGH_BOUND (fixup_alt_jump); \ |
| 2026 | if (laststart) \ |
| 2027 | SET_HIGH_BOUND (laststart); \ |
| 2028 | if (pending_exact) \ |
| 2029 | SET_HIGH_BOUND (pending_exact); \ |
| 2030 | } |
| 2031 | # else |
| 2032 | # define MOVE_BUFFER_POINTER(P) (P) += incr |
| 2033 | # define ELSE_EXTEND_BUFFER_HIGH_BOUND |
| 2034 | # endif |
| 2035 | # endif /* not DEFINED_ONCE */ |
| 2036 | |
| 2037 | # ifdef WCHAR |
| 2038 | # define EXTEND_BUFFER() \ |
| 2039 | do { \ |
| 2040 | UCHAR_T *old_buffer = COMPILED_BUFFER_VAR; \ |
| 2041 | int wchar_count; \ |
| 2042 | if (bufp->allocated + sizeof(UCHAR_T) > MAX_BUF_SIZE) \ |
| 2043 | return REG_ESIZE; \ |
| 2044 | bufp->allocated <<= 1; \ |
| 2045 | if (bufp->allocated > MAX_BUF_SIZE) \ |
| 2046 | bufp->allocated = MAX_BUF_SIZE; \ |
| 2047 | /* How many characters the new buffer can have? */ \ |
| 2048 | wchar_count = bufp->allocated / sizeof(UCHAR_T); \ |
| 2049 | if (wchar_count == 0) wchar_count = 1; \ |
| 2050 | /* Truncate the buffer to CHAR_T align. */ \ |
| 2051 | bufp->allocated = wchar_count * sizeof(UCHAR_T); \ |
| 2052 | RETALLOC (COMPILED_BUFFER_VAR, wchar_count, UCHAR_T); \ |
| 2053 | bufp->buffer = (char*)COMPILED_BUFFER_VAR; \ |
| 2054 | if (COMPILED_BUFFER_VAR == NULL) \ |
| 2055 | return REG_ESPACE; \ |
| 2056 | /* If the buffer moved, move all the pointers into it. */ \ |
| 2057 | if (old_buffer != COMPILED_BUFFER_VAR) \ |
| 2058 | { \ |
| 2059 | PTR_INT_TYPE incr = COMPILED_BUFFER_VAR - old_buffer; \ |
| 2060 | MOVE_BUFFER_POINTER (b); \ |
| 2061 | MOVE_BUFFER_POINTER (begalt); \ |
| 2062 | if (fixup_alt_jump) \ |
| 2063 | MOVE_BUFFER_POINTER (fixup_alt_jump); \ |
| 2064 | if (laststart) \ |
| 2065 | MOVE_BUFFER_POINTER (laststart); \ |
| 2066 | if (pending_exact) \ |
| 2067 | MOVE_BUFFER_POINTER (pending_exact); \ |
| 2068 | } \ |
| 2069 | ELSE_EXTEND_BUFFER_HIGH_BOUND \ |
| 2070 | } while (0) |
| 2071 | # else /* BYTE */ |
| 2072 | # define EXTEND_BUFFER() \ |
| 2073 | do { \ |
| 2074 | UCHAR_T *old_buffer = COMPILED_BUFFER_VAR; \ |
| 2075 | if (bufp->allocated == MAX_BUF_SIZE) \ |
| 2076 | return REG_ESIZE; \ |
| 2077 | bufp->allocated <<= 1; \ |
| 2078 | if (bufp->allocated > MAX_BUF_SIZE) \ |
| 2079 | bufp->allocated = MAX_BUF_SIZE; \ |
| 2080 | bufp->buffer = (UCHAR_T *) REALLOC (COMPILED_BUFFER_VAR, \ |
| 2081 | bufp->allocated); \ |
| 2082 | if (COMPILED_BUFFER_VAR == NULL) \ |
| 2083 | return REG_ESPACE; \ |
| 2084 | /* If the buffer moved, move all the pointers into it. */ \ |
| 2085 | if (old_buffer != COMPILED_BUFFER_VAR) \ |
| 2086 | { \ |
| 2087 | PTR_INT_TYPE incr = COMPILED_BUFFER_VAR - old_buffer; \ |
| 2088 | MOVE_BUFFER_POINTER (b); \ |
| 2089 | MOVE_BUFFER_POINTER (begalt); \ |
| 2090 | if (fixup_alt_jump) \ |
| 2091 | MOVE_BUFFER_POINTER (fixup_alt_jump); \ |
| 2092 | if (laststart) \ |
| 2093 | MOVE_BUFFER_POINTER (laststart); \ |
| 2094 | if (pending_exact) \ |
| 2095 | MOVE_BUFFER_POINTER (pending_exact); \ |
| 2096 | } \ |
| 2097 | ELSE_EXTEND_BUFFER_HIGH_BOUND \ |
| 2098 | } while (0) |
| 2099 | # endif /* WCHAR */ |
| 2100 | |
| 2101 | # ifndef DEFINED_ONCE |
| 2102 | /* Since we have one byte reserved for the register number argument to |
| 2103 | {start,stop}_memory, the maximum number of groups we can report |
| 2104 | things about is what fits in that byte. */ |
| 2105 | # define MAX_REGNUM 255 |
| 2106 | |
| 2107 | /* But patterns can have more than `MAX_REGNUM' registers. We just |
| 2108 | ignore the excess. */ |
| 2109 | typedef unsigned regnum_t; |
| 2110 | |
| 2111 | |
| 2112 | /* Macros for the compile stack. */ |
| 2113 | |
| 2114 | /* Since offsets can go either forwards or backwards, this type needs to |
| 2115 | be able to hold values from -(MAX_BUF_SIZE - 1) to MAX_BUF_SIZE - 1. */ |
| 2116 | /* int may be not enough when sizeof(int) == 2. */ |
| 2117 | typedef long pattern_offset_t; |
| 2118 | |
| 2119 | typedef struct |
| 2120 | { |
| 2121 | pattern_offset_t begalt_offset; |
| 2122 | pattern_offset_t fixup_alt_jump; |
| 2123 | pattern_offset_t inner_group_offset; |
| 2124 | pattern_offset_t laststart_offset; |
| 2125 | regnum_t regnum; |
| 2126 | } compile_stack_elt_t; |
| 2127 | |
| 2128 | |
| 2129 | typedef struct |
| 2130 | { |
| 2131 | compile_stack_elt_t *stack; |
| 2132 | unsigned size; |
| 2133 | unsigned avail; /* Offset of next open position. */ |
| 2134 | } compile_stack_type; |
| 2135 | |
| 2136 | |
| 2137 | # define INIT_COMPILE_STACK_SIZE 32 |
| 2138 | |
| 2139 | # define COMPILE_STACK_EMPTY (compile_stack.avail == 0) |
| 2140 | # define COMPILE_STACK_FULL (compile_stack.avail == compile_stack.size) |
| 2141 | |
| 2142 | /* The next available element. */ |
| 2143 | # define COMPILE_STACK_TOP (compile_stack.stack[compile_stack.avail]) |
| 2144 | |
| 2145 | # endif /* not DEFINED_ONCE */ |
| 2146 | |
| 2147 | /* Set the bit for character C in a list. */ |
| 2148 | # ifndef DEFINED_ONCE |
| 2149 | # define SET_LIST_BIT(c) \ |
| 2150 | (b[((unsigned char) (c)) / BYTEWIDTH] \ |
| 2151 | |= 1 << (((unsigned char) c) % BYTEWIDTH)) |
| 2152 | # endif /* DEFINED_ONCE */ |
| 2153 | |
| 2154 | /* Get the next unsigned number in the uncompiled pattern. */ |
| 2155 | # define GET_UNSIGNED_NUMBER(num) \ |
| 2156 | { \ |
| 2157 | while (p != pend) \ |
| 2158 | { \ |
| 2159 | PATFETCH (c); \ |
| 2160 | if (c < '0' || c > '9') \ |
| 2161 | break; \ |
| 2162 | if (num <= RE_DUP_MAX) \ |
| 2163 | { \ |
| 2164 | if (num < 0) \ |
| 2165 | num = 0; \ |
| 2166 | num = num * 10 + c - '0'; \ |
| 2167 | } \ |
| 2168 | } \ |
| 2169 | } |
| 2170 | |
| 2171 | # ifndef DEFINED_ONCE |
| 2172 | # if defined _LIBC || WIDE_CHAR_SUPPORT |
| 2173 | /* The GNU C library provides support for user-defined character classes |
| 2174 | and the functions from ISO C amendement 1. */ |
| 2175 | # ifdef CHARCLASS_NAME_MAX |
| 2176 | # define CHAR_CLASS_MAX_LENGTH CHARCLASS_NAME_MAX |
| 2177 | # else |
| 2178 | /* This shouldn't happen but some implementation might still have this |
| 2179 | problem. Use a reasonable default value. */ |
| 2180 | # define CHAR_CLASS_MAX_LENGTH 256 |
| 2181 | # endif |
| 2182 | |
| 2183 | # ifdef _LIBC |
| 2184 | # define IS_CHAR_CLASS(string) __wctype (string) |
| 2185 | # else |
| 2186 | # define IS_CHAR_CLASS(string) wctype (string) |
| 2187 | # endif |
| 2188 | # else |
| 2189 | # define CHAR_CLASS_MAX_LENGTH 6 /* Namely, `xdigit'. */ |
| 2190 | |
| 2191 | # define IS_CHAR_CLASS(string) \ |
| 2192 | (STREQ (string, "alpha") || STREQ (string, "upper") \ |
| 2193 | || STREQ (string, "lower") || STREQ (string, "digit") \ |
| 2194 | || STREQ (string, "alnum") || STREQ (string, "xdigit") \ |
| 2195 | || STREQ (string, "space") || STREQ (string, "print") \ |
| 2196 | || STREQ (string, "punct") || STREQ (string, "graph") \ |
| 2197 | || STREQ (string, "cntrl") || STREQ (string, "blank")) |
| 2198 | # endif |
| 2199 | # endif /* DEFINED_ONCE */ |
| 2200 | \f |
| 2201 | # ifndef MATCH_MAY_ALLOCATE |
| 2202 | |
| 2203 | /* If we cannot allocate large objects within re_match_2_internal, |
| 2204 | we make the fail stack and register vectors global. |
| 2205 | The fail stack, we grow to the maximum size when a regexp |
| 2206 | is compiled. |
| 2207 | The register vectors, we adjust in size each time we |
| 2208 | compile a regexp, according to the number of registers it needs. */ |
| 2209 | |
| 2210 | static PREFIX(fail_stack_type) fail_stack; |
| 2211 | |
| 2212 | /* Size with which the following vectors are currently allocated. |
| 2213 | That is so we can make them bigger as needed, |
| 2214 | but never make them smaller. */ |
| 2215 | # ifdef DEFINED_ONCE |
| 2216 | static int regs_allocated_size; |
| 2217 | |
| 2218 | static const char ** regstart, ** regend; |
| 2219 | static const char ** old_regstart, ** old_regend; |
| 2220 | static const char **best_regstart, **best_regend; |
| 2221 | static const char **reg_dummy; |
| 2222 | # endif /* DEFINED_ONCE */ |
| 2223 | |
| 2224 | static PREFIX(register_info_type) *PREFIX(reg_info); |
| 2225 | static PREFIX(register_info_type) *PREFIX(reg_info_dummy); |
| 2226 | |
| 2227 | /* Make the register vectors big enough for NUM_REGS registers, |
| 2228 | but don't make them smaller. */ |
| 2229 | |
| 2230 | static void |
| 2231 | PREFIX(regex_grow_registers) (int num_regs) |
| 2232 | { |
| 2233 | if (num_regs > regs_allocated_size) |
| 2234 | { |
| 2235 | RETALLOC_IF (regstart, num_regs, const char *); |
| 2236 | RETALLOC_IF (regend, num_regs, const char *); |
| 2237 | RETALLOC_IF (old_regstart, num_regs, const char *); |
| 2238 | RETALLOC_IF (old_regend, num_regs, const char *); |
| 2239 | RETALLOC_IF (best_regstart, num_regs, const char *); |
| 2240 | RETALLOC_IF (best_regend, num_regs, const char *); |
| 2241 | RETALLOC_IF (PREFIX(reg_info), num_regs, PREFIX(register_info_type)); |
| 2242 | RETALLOC_IF (reg_dummy, num_regs, const char *); |
| 2243 | RETALLOC_IF (PREFIX(reg_info_dummy), num_regs, PREFIX(register_info_type)); |
| 2244 | |
| 2245 | regs_allocated_size = num_regs; |
| 2246 | } |
| 2247 | } |
| 2248 | |
| 2249 | # endif /* not MATCH_MAY_ALLOCATE */ |
| 2250 | \f |
| 2251 | # ifndef DEFINED_ONCE |
| 2252 | static boolean group_in_compile_stack (compile_stack_type compile_stack, |
| 2253 | regnum_t regnum); |
| 2254 | # endif /* not DEFINED_ONCE */ |
| 2255 | |
| 2256 | /* `regex_compile' compiles PATTERN (of length SIZE) according to SYNTAX. |
| 2257 | Returns one of error codes defined in `regex.h', or zero for success. |
| 2258 | |
| 2259 | Assumes the `allocated' (and perhaps `buffer') and `translate' |
| 2260 | fields are set in BUFP on entry. |
| 2261 | |
| 2262 | If it succeeds, results are put in BUFP (if it returns an error, the |
| 2263 | contents of BUFP are undefined): |
| 2264 | `buffer' is the compiled pattern; |
| 2265 | `syntax' is set to SYNTAX; |
| 2266 | `used' is set to the length of the compiled pattern; |
| 2267 | `fastmap_accurate' is zero; |
| 2268 | `re_nsub' is the number of subexpressions in PATTERN; |
| 2269 | `not_bol' and `not_eol' are zero; |
| 2270 | |
| 2271 | The `fastmap' and `newline_anchor' fields are neither |
| 2272 | examined nor set. */ |
| 2273 | |
| 2274 | /* Return, freeing storage we allocated. */ |
| 2275 | # ifdef WCHAR |
| 2276 | # define FREE_STACK_RETURN(value) \ |
| 2277 | return (free(pattern), free(mbs_offset), free(is_binary), free (compile_stack.stack), value) |
| 2278 | # else |
| 2279 | # define FREE_STACK_RETURN(value) \ |
| 2280 | return (free (compile_stack.stack), value) |
| 2281 | # endif /* WCHAR */ |
| 2282 | |
| 2283 | static reg_errcode_t |
| 2284 | PREFIX(regex_compile) (const char *ARG_PREFIX(pattern), |
| 2285 | size_t ARG_PREFIX(size), reg_syntax_t syntax, |
| 2286 | struct re_pattern_buffer *bufp) |
| 2287 | { |
| 2288 | /* We fetch characters from PATTERN here. Even though PATTERN is |
| 2289 | `char *' (i.e., signed), we declare these variables as unsigned, so |
| 2290 | they can be reliably used as array indices. */ |
| 2291 | register UCHAR_T c, c1; |
| 2292 | |
| 2293 | #ifdef WCHAR |
| 2294 | /* A temporary space to keep wchar_t pattern and compiled pattern. */ |
| 2295 | CHAR_T *pattern, *COMPILED_BUFFER_VAR; |
| 2296 | size_t size; |
| 2297 | /* offset buffer for optimization. See convert_mbs_to_wc. */ |
| 2298 | int *mbs_offset = NULL; |
| 2299 | /* It hold whether each wchar_t is binary data or not. */ |
| 2300 | char *is_binary = NULL; |
| 2301 | /* A flag whether exactn is handling binary data or not. */ |
| 2302 | char is_exactn_bin = FALSE; |
| 2303 | #endif /* WCHAR */ |
| 2304 | |
| 2305 | /* A random temporary spot in PATTERN. */ |
| 2306 | const CHAR_T *p1; |
| 2307 | |
| 2308 | /* Points to the end of the buffer, where we should append. */ |
| 2309 | register UCHAR_T *b; |
| 2310 | |
| 2311 | /* Keeps track of unclosed groups. */ |
| 2312 | compile_stack_type compile_stack; |
| 2313 | |
| 2314 | /* Points to the current (ending) position in the pattern. */ |
| 2315 | #ifdef WCHAR |
| 2316 | const CHAR_T *p; |
| 2317 | const CHAR_T *pend; |
| 2318 | #else /* BYTE */ |
| 2319 | const CHAR_T *p = pattern; |
| 2320 | const CHAR_T *pend = pattern + size; |
| 2321 | #endif /* WCHAR */ |
| 2322 | |
| 2323 | /* How to translate the characters in the pattern. */ |
| 2324 | RE_TRANSLATE_TYPE translate = bufp->translate; |
| 2325 | |
| 2326 | /* Address of the count-byte of the most recently inserted `exactn' |
| 2327 | command. This makes it possible to tell if a new exact-match |
| 2328 | character can be added to that command or if the character requires |
| 2329 | a new `exactn' command. */ |
| 2330 | UCHAR_T *pending_exact = 0; |
| 2331 | |
| 2332 | /* Address of start of the most recently finished expression. |
| 2333 | This tells, e.g., postfix * where to find the start of its |
| 2334 | operand. Reset at the beginning of groups and alternatives. */ |
| 2335 | UCHAR_T *laststart = 0; |
| 2336 | |
| 2337 | /* Address of beginning of regexp, or inside of last group. */ |
| 2338 | UCHAR_T *begalt; |
| 2339 | |
| 2340 | /* Address of the place where a forward jump should go to the end of |
| 2341 | the containing expression. Each alternative of an `or' -- except the |
| 2342 | last -- ends with a forward jump of this sort. */ |
| 2343 | UCHAR_T *fixup_alt_jump = 0; |
| 2344 | |
| 2345 | /* Counts open-groups as they are encountered. Remembered for the |
| 2346 | matching close-group on the compile stack, so the same register |
| 2347 | number is put in the stop_memory as the start_memory. */ |
| 2348 | regnum_t regnum = 0; |
| 2349 | |
| 2350 | #ifdef WCHAR |
| 2351 | /* Initialize the wchar_t PATTERN and offset_buffer. */ |
| 2352 | p = pend = pattern = TALLOC(csize + 1, CHAR_T); |
| 2353 | mbs_offset = TALLOC(csize + 1, int); |
| 2354 | is_binary = TALLOC(csize + 1, char); |
| 2355 | if (pattern == NULL || mbs_offset == NULL || is_binary == NULL) |
| 2356 | { |
| 2357 | free(pattern); |
| 2358 | free(mbs_offset); |
| 2359 | free(is_binary); |
| 2360 | return REG_ESPACE; |
| 2361 | } |
| 2362 | pattern[csize] = L'\0'; /* sentinel */ |
| 2363 | size = convert_mbs_to_wcs(pattern, cpattern, csize, mbs_offset, is_binary); |
| 2364 | pend = p + size; |
| 2365 | if (size < 0) |
| 2366 | { |
| 2367 | free(pattern); |
| 2368 | free(mbs_offset); |
| 2369 | free(is_binary); |
| 2370 | return REG_BADPAT; |
| 2371 | } |
| 2372 | #endif |
| 2373 | |
| 2374 | #ifdef DEBUG |
| 2375 | DEBUG_PRINT1 ("\nCompiling pattern: "); |
| 2376 | if (debug) |
| 2377 | { |
| 2378 | unsigned debug_count; |
| 2379 | |
| 2380 | for (debug_count = 0; debug_count < size; debug_count++) |
| 2381 | PUT_CHAR (pattern[debug_count]); |
| 2382 | putchar ('\n'); |
| 2383 | } |
| 2384 | #endif /* DEBUG */ |
| 2385 | |
| 2386 | /* Initialize the compile stack. */ |
| 2387 | compile_stack.stack = TALLOC (INIT_COMPILE_STACK_SIZE, compile_stack_elt_t); |
| 2388 | if (compile_stack.stack == NULL) |
| 2389 | { |
| 2390 | #ifdef WCHAR |
| 2391 | free(pattern); |
| 2392 | free(mbs_offset); |
| 2393 | free(is_binary); |
| 2394 | #endif |
| 2395 | return REG_ESPACE; |
| 2396 | } |
| 2397 | |
| 2398 | compile_stack.size = INIT_COMPILE_STACK_SIZE; |
| 2399 | compile_stack.avail = 0; |
| 2400 | |
| 2401 | /* Initialize the pattern buffer. */ |
| 2402 | bufp->syntax = syntax; |
| 2403 | bufp->fastmap_accurate = 0; |
| 2404 | bufp->not_bol = bufp->not_eol = 0; |
| 2405 | |
| 2406 | /* Set `used' to zero, so that if we return an error, the pattern |
| 2407 | printer (for debugging) will think there's no pattern. We reset it |
| 2408 | at the end. */ |
| 2409 | bufp->used = 0; |
| 2410 | |
| 2411 | /* Always count groups, whether or not bufp->no_sub is set. */ |
| 2412 | bufp->re_nsub = 0; |
| 2413 | |
| 2414 | #if !defined emacs && !defined SYNTAX_TABLE |
| 2415 | /* Initialize the syntax table. */ |
| 2416 | init_syntax_once (); |
| 2417 | #endif |
| 2418 | |
| 2419 | if (bufp->allocated == 0) |
| 2420 | { |
| 2421 | if (bufp->buffer) |
| 2422 | { /* If zero allocated, but buffer is non-null, try to realloc |
| 2423 | enough space. This loses if buffer's address is bogus, but |
| 2424 | that is the user's responsibility. */ |
| 2425 | #ifdef WCHAR |
| 2426 | /* Free bufp->buffer and allocate an array for wchar_t pattern |
| 2427 | buffer. */ |
| 2428 | free(bufp->buffer); |
| 2429 | COMPILED_BUFFER_VAR = TALLOC (INIT_BUF_SIZE/sizeof(UCHAR_T), |
| 2430 | UCHAR_T); |
| 2431 | #else |
| 2432 | RETALLOC (COMPILED_BUFFER_VAR, INIT_BUF_SIZE, UCHAR_T); |
| 2433 | #endif /* WCHAR */ |
| 2434 | } |
| 2435 | else |
| 2436 | { /* Caller did not allocate a buffer. Do it for them. */ |
| 2437 | COMPILED_BUFFER_VAR = TALLOC (INIT_BUF_SIZE / sizeof(UCHAR_T), |
| 2438 | UCHAR_T); |
| 2439 | } |
| 2440 | |
| 2441 | if (!COMPILED_BUFFER_VAR) FREE_STACK_RETURN (REG_ESPACE); |
| 2442 | #ifdef WCHAR |
| 2443 | bufp->buffer = (char*)COMPILED_BUFFER_VAR; |
| 2444 | #endif /* WCHAR */ |
| 2445 | bufp->allocated = INIT_BUF_SIZE; |
| 2446 | } |
| 2447 | #ifdef WCHAR |
| 2448 | else |
| 2449 | COMPILED_BUFFER_VAR = (UCHAR_T*) bufp->buffer; |
| 2450 | #endif |
| 2451 | |
| 2452 | begalt = b = COMPILED_BUFFER_VAR; |
| 2453 | |
| 2454 | /* Loop through the uncompiled pattern until we're at the end. */ |
| 2455 | while (p != pend) |
| 2456 | { |
| 2457 | PATFETCH (c); |
| 2458 | |
| 2459 | switch (c) |
| 2460 | { |
| 2461 | case '^': |
| 2462 | { |
| 2463 | if ( /* If at start of pattern, it's an operator. */ |
| 2464 | p == pattern + 1 |
| 2465 | /* If context independent, it's an operator. */ |
| 2466 | || syntax & RE_CONTEXT_INDEP_ANCHORS |
| 2467 | /* Otherwise, depends on what's come before. */ |
| 2468 | || PREFIX(at_begline_loc_p) (pattern, p, syntax)) |
| 2469 | BUF_PUSH (begline); |
| 2470 | else |
| 2471 | goto normal_char; |
| 2472 | } |
| 2473 | break; |
| 2474 | |
| 2475 | |
| 2476 | case '$': |
| 2477 | { |
| 2478 | if ( /* If at end of pattern, it's an operator. */ |
| 2479 | p == pend |
| 2480 | /* If context independent, it's an operator. */ |
| 2481 | || syntax & RE_CONTEXT_INDEP_ANCHORS |
| 2482 | /* Otherwise, depends on what's next. */ |
| 2483 | || PREFIX(at_endline_loc_p) (p, pend, syntax)) |
| 2484 | BUF_PUSH (endline); |
| 2485 | else |
| 2486 | goto normal_char; |
| 2487 | } |
| 2488 | break; |
| 2489 | |
| 2490 | |
| 2491 | case '+': |
| 2492 | case '?': |
| 2493 | if ((syntax & RE_BK_PLUS_QM) |
| 2494 | || (syntax & RE_LIMITED_OPS)) |
| 2495 | goto normal_char; |
| 2496 | handle_plus: |
| 2497 | case '*': |
| 2498 | /* If there is no previous pattern... */ |
| 2499 | if (!laststart) |
| 2500 | { |
| 2501 | if (syntax & RE_CONTEXT_INVALID_OPS) |
| 2502 | FREE_STACK_RETURN (REG_BADRPT); |
| 2503 | else if (!(syntax & RE_CONTEXT_INDEP_OPS)) |
| 2504 | goto normal_char; |
| 2505 | } |
| 2506 | |
| 2507 | { |
| 2508 | /* Are we optimizing this jump? */ |
| 2509 | boolean keep_string_p = false; |
| 2510 | |
| 2511 | /* 1 means zero (many) matches is allowed. */ |
| 2512 | char zero_times_ok = 0, many_times_ok = 0; |
| 2513 | |
| 2514 | /* If there is a sequence of repetition chars, collapse it |
| 2515 | down to just one (the right one). We can't combine |
| 2516 | interval operators with these because of, e.g., `a{2}*', |
| 2517 | which should only match an even number of `a's. */ |
| 2518 | |
| 2519 | for (;;) |
| 2520 | { |
| 2521 | zero_times_ok |= c != '+'; |
| 2522 | many_times_ok |= c != '?'; |
| 2523 | |
| 2524 | if (p == pend) |
| 2525 | break; |
| 2526 | |
| 2527 | PATFETCH (c); |
| 2528 | |
| 2529 | if (c == '*' |
| 2530 | || (!(syntax & RE_BK_PLUS_QM) && (c == '+' || c == '?'))) |
| 2531 | ; |
| 2532 | |
| 2533 | else if (syntax & RE_BK_PLUS_QM && c == '\\') |
| 2534 | { |
| 2535 | if (p == pend) FREE_STACK_RETURN (REG_EESCAPE); |
| 2536 | |
| 2537 | PATFETCH (c1); |
| 2538 | if (!(c1 == '+' || c1 == '?')) |
| 2539 | { |
| 2540 | PATUNFETCH; |
| 2541 | PATUNFETCH; |
| 2542 | break; |
| 2543 | } |
| 2544 | |
| 2545 | c = c1; |
| 2546 | } |
| 2547 | else |
| 2548 | { |
| 2549 | PATUNFETCH; |
| 2550 | break; |
| 2551 | } |
| 2552 | |
| 2553 | /* If we get here, we found another repeat character. */ |
| 2554 | } |
| 2555 | |
| 2556 | /* Star, etc. applied to an empty pattern is equivalent |
| 2557 | to an empty pattern. */ |
| 2558 | if (!laststart) |
| 2559 | break; |
| 2560 | |
| 2561 | /* Now we know whether or not zero matches is allowed |
| 2562 | and also whether or not two or more matches is allowed. */ |
| 2563 | if (many_times_ok) |
| 2564 | { /* More than one repetition is allowed, so put in at the |
| 2565 | end a backward relative jump from `b' to before the next |
| 2566 | jump we're going to put in below (which jumps from |
| 2567 | laststart to after this jump). |
| 2568 | |
| 2569 | But if we are at the `*' in the exact sequence `.*\n', |
| 2570 | insert an unconditional jump backwards to the ., |
| 2571 | instead of the beginning of the loop. This way we only |
| 2572 | push a failure point once, instead of every time |
| 2573 | through the loop. */ |
| 2574 | assert (p - 1 > pattern); |
| 2575 | |
| 2576 | /* Allocate the space for the jump. */ |
| 2577 | GET_BUFFER_SPACE (1 + OFFSET_ADDRESS_SIZE); |
| 2578 | |
| 2579 | /* We know we are not at the first character of the pattern, |
| 2580 | because laststart was nonzero. And we've already |
| 2581 | incremented `p', by the way, to be the character after |
| 2582 | the `*'. Do we have to do something analogous here |
| 2583 | for null bytes, because of RE_DOT_NOT_NULL? */ |
| 2584 | if (TRANSLATE (*(p - 2)) == TRANSLATE ('.') |
| 2585 | && zero_times_ok |
| 2586 | && p < pend && TRANSLATE (*p) == TRANSLATE ('\n') |
| 2587 | && !(syntax & RE_DOT_NEWLINE)) |
| 2588 | { /* We have .*\n. */ |
| 2589 | STORE_JUMP (jump, b, laststart); |
| 2590 | keep_string_p = true; |
| 2591 | } |
| 2592 | else |
| 2593 | /* Anything else. */ |
| 2594 | STORE_JUMP (maybe_pop_jump, b, laststart - |
| 2595 | (1 + OFFSET_ADDRESS_SIZE)); |
| 2596 | |
| 2597 | /* We've added more stuff to the buffer. */ |
| 2598 | b += 1 + OFFSET_ADDRESS_SIZE; |
| 2599 | } |
| 2600 | |
| 2601 | /* On failure, jump from laststart to b + 3, which will be the |
| 2602 | end of the buffer after this jump is inserted. */ |
| 2603 | /* ifdef WCHAR, 'b + 1 + OFFSET_ADDRESS_SIZE' instead of |
| 2604 | 'b + 3'. */ |
| 2605 | GET_BUFFER_SPACE (1 + OFFSET_ADDRESS_SIZE); |
| 2606 | INSERT_JUMP (keep_string_p ? on_failure_keep_string_jump |
| 2607 | : on_failure_jump, |
| 2608 | laststart, b + 1 + OFFSET_ADDRESS_SIZE); |
| 2609 | pending_exact = 0; |
| 2610 | b += 1 + OFFSET_ADDRESS_SIZE; |
| 2611 | |
| 2612 | if (!zero_times_ok) |
| 2613 | { |
| 2614 | /* At least one repetition is required, so insert a |
| 2615 | `dummy_failure_jump' before the initial |
| 2616 | `on_failure_jump' instruction of the loop. This |
| 2617 | effects a skip over that instruction the first time |
| 2618 | we hit that loop. */ |
| 2619 | GET_BUFFER_SPACE (1 + OFFSET_ADDRESS_SIZE); |
| 2620 | INSERT_JUMP (dummy_failure_jump, laststart, laststart + |
| 2621 | 2 + 2 * OFFSET_ADDRESS_SIZE); |
| 2622 | b += 1 + OFFSET_ADDRESS_SIZE; |
| 2623 | } |
| 2624 | } |
| 2625 | break; |
| 2626 | |
| 2627 | |
| 2628 | case '.': |
| 2629 | laststart = b; |
| 2630 | BUF_PUSH (anychar); |
| 2631 | break; |
| 2632 | |
| 2633 | |
| 2634 | case '[': |
| 2635 | { |
| 2636 | boolean had_char_class = false; |
| 2637 | #ifdef WCHAR |
| 2638 | CHAR_T range_start = 0xffffffff; |
| 2639 | #else |
| 2640 | unsigned int range_start = 0xffffffff; |
| 2641 | #endif |
| 2642 | if (p == pend) FREE_STACK_RETURN (REG_EBRACK); |
| 2643 | |
| 2644 | #ifdef WCHAR |
| 2645 | /* We assume a charset(_not) structure as a wchar_t array. |
| 2646 | charset[0] = (re_opcode_t) charset(_not) |
| 2647 | charset[1] = l (= length of char_classes) |
| 2648 | charset[2] = m (= length of collating_symbols) |
| 2649 | charset[3] = n (= length of equivalence_classes) |
| 2650 | charset[4] = o (= length of char_ranges) |
| 2651 | charset[5] = p (= length of chars) |
| 2652 | |
| 2653 | charset[6] = char_class (wctype_t) |
| 2654 | charset[6+CHAR_CLASS_SIZE] = char_class (wctype_t) |
| 2655 | ... |
| 2656 | charset[l+5] = char_class (wctype_t) |
| 2657 | |
| 2658 | charset[l+6] = collating_symbol (wchar_t) |
| 2659 | ... |
| 2660 | charset[l+m+5] = collating_symbol (wchar_t) |
| 2661 | ifdef _LIBC we use the index if |
| 2662 | _NL_COLLATE_SYMB_EXTRAMB instead of |
| 2663 | wchar_t string. |
| 2664 | |
| 2665 | charset[l+m+6] = equivalence_classes (wchar_t) |
| 2666 | ... |
| 2667 | charset[l+m+n+5] = equivalence_classes (wchar_t) |
| 2668 | ifdef _LIBC we use the index in |
| 2669 | _NL_COLLATE_WEIGHT instead of |
| 2670 | wchar_t string. |
| 2671 | |
| 2672 | charset[l+m+n+6] = range_start |
| 2673 | charset[l+m+n+7] = range_end |
| 2674 | ... |
| 2675 | charset[l+m+n+2o+4] = range_start |
| 2676 | charset[l+m+n+2o+5] = range_end |
| 2677 | ifdef _LIBC we use the value looked up |
| 2678 | in _NL_COLLATE_COLLSEQ instead of |
| 2679 | wchar_t character. |
| 2680 | |
| 2681 | charset[l+m+n+2o+6] = char |
| 2682 | ... |
| 2683 | charset[l+m+n+2o+p+5] = char |
| 2684 | |
| 2685 | */ |
| 2686 | |
| 2687 | /* We need at least 6 spaces: the opcode, the length of |
| 2688 | char_classes, the length of collating_symbols, the length of |
| 2689 | equivalence_classes, the length of char_ranges, the length of |
| 2690 | chars. */ |
| 2691 | GET_BUFFER_SPACE (6); |
| 2692 | |
| 2693 | /* Save b as laststart. And We use laststart as the pointer |
| 2694 | to the first element of the charset here. |
| 2695 | In other words, laststart[i] indicates charset[i]. */ |
| 2696 | laststart = b; |
| 2697 | |
| 2698 | /* We test `*p == '^' twice, instead of using an if |
| 2699 | statement, so we only need one BUF_PUSH. */ |
| 2700 | BUF_PUSH (*p == '^' ? charset_not : charset); |
| 2701 | if (*p == '^') |
| 2702 | p++; |
| 2703 | |
| 2704 | /* Push the length of char_classes, the length of |
| 2705 | collating_symbols, the length of equivalence_classes, the |
| 2706 | length of char_ranges and the length of chars. */ |
| 2707 | BUF_PUSH_3 (0, 0, 0); |
| 2708 | BUF_PUSH_2 (0, 0); |
| 2709 | |
| 2710 | /* Remember the first position in the bracket expression. */ |
| 2711 | p1 = p; |
| 2712 | |
| 2713 | /* charset_not matches newline according to a syntax bit. */ |
| 2714 | if ((re_opcode_t) b[-6] == charset_not |
| 2715 | && (syntax & RE_HAT_LISTS_NOT_NEWLINE)) |
| 2716 | { |
| 2717 | BUF_PUSH('\n'); |
| 2718 | laststart[5]++; /* Update the length of characters */ |
| 2719 | } |
| 2720 | |
| 2721 | /* Read in characters and ranges, setting map bits. */ |
| 2722 | for (;;) |
| 2723 | { |
| 2724 | if (p == pend) FREE_STACK_RETURN (REG_EBRACK); |
| 2725 | |
| 2726 | PATFETCH (c); |
| 2727 | |
| 2728 | /* \ might escape characters inside [...] and [^...]. */ |
| 2729 | if ((syntax & RE_BACKSLASH_ESCAPE_IN_LISTS) && c == '\\') |
| 2730 | { |
| 2731 | if (p == pend) FREE_STACK_RETURN (REG_EESCAPE); |
| 2732 | |
| 2733 | PATFETCH (c1); |
| 2734 | BUF_PUSH(c1); |
| 2735 | laststart[5]++; /* Update the length of chars */ |
| 2736 | range_start = c1; |
| 2737 | continue; |
| 2738 | } |
| 2739 | |
| 2740 | /* Could be the end of the bracket expression. If it's |
| 2741 | not (i.e., when the bracket expression is `[]' so |
| 2742 | far), the ']' character bit gets set way below. */ |
| 2743 | if (c == ']' && p != p1 + 1) |
| 2744 | break; |
| 2745 | |
| 2746 | /* Look ahead to see if it's a range when the last thing |
| 2747 | was a character class. */ |
| 2748 | if (had_char_class && c == '-' && *p != ']') |
| 2749 | FREE_STACK_RETURN (REG_ERANGE); |
| 2750 | |
| 2751 | /* Look ahead to see if it's a range when the last thing |
| 2752 | was a character: if this is a hyphen not at the |
| 2753 | beginning or the end of a list, then it's the range |
| 2754 | operator. */ |
| 2755 | if (c == '-' |
| 2756 | && !(p - 2 >= pattern && p[-2] == '[') |
| 2757 | && !(p - 3 >= pattern && p[-3] == '[' && p[-2] == '^') |
| 2758 | && *p != ']') |
| 2759 | { |
| 2760 | reg_errcode_t ret; |
| 2761 | /* Allocate the space for range_start and range_end. */ |
| 2762 | GET_BUFFER_SPACE (2); |
| 2763 | /* Update the pointer to indicate end of buffer. */ |
| 2764 | b += 2; |
| 2765 | ret = wcs_compile_range (range_start, &p, pend, translate, |
| 2766 | syntax, b, laststart); |
| 2767 | if (ret != REG_NOERROR) FREE_STACK_RETURN (ret); |
| 2768 | range_start = 0xffffffff; |
| 2769 | } |
| 2770 | else if (p[0] == '-' && p[1] != ']') |
| 2771 | { /* This handles ranges made up of characters only. */ |
| 2772 | reg_errcode_t ret; |
| 2773 | |
| 2774 | /* Move past the `-'. */ |
| 2775 | PATFETCH (c1); |
| 2776 | /* Allocate the space for range_start and range_end. */ |
| 2777 | GET_BUFFER_SPACE (2); |
| 2778 | /* Update the pointer to indicate end of buffer. */ |
| 2779 | b += 2; |
| 2780 | ret = wcs_compile_range (c, &p, pend, translate, syntax, b, |
| 2781 | laststart); |
| 2782 | if (ret != REG_NOERROR) FREE_STACK_RETURN (ret); |
| 2783 | range_start = 0xffffffff; |
| 2784 | } |
| 2785 | |
| 2786 | /* See if we're at the beginning of a possible character |
| 2787 | class. */ |
| 2788 | else if (syntax & RE_CHAR_CLASSES && c == '[' && *p == ':') |
| 2789 | { /* Leave room for the null. */ |
| 2790 | char str[CHAR_CLASS_MAX_LENGTH + 1]; |
| 2791 | |
| 2792 | PATFETCH (c); |
| 2793 | c1 = 0; |
| 2794 | |
| 2795 | /* If pattern is `[[:'. */ |
| 2796 | if (p == pend) FREE_STACK_RETURN (REG_EBRACK); |
| 2797 | |
| 2798 | for (;;) |
| 2799 | { |
| 2800 | PATFETCH (c); |
| 2801 | if ((c == ':' && *p == ']') || p == pend) |
| 2802 | break; |
| 2803 | if (c1 < CHAR_CLASS_MAX_LENGTH) |
| 2804 | str[c1++] = c; |
| 2805 | else |
| 2806 | /* This is in any case an invalid class name. */ |
| 2807 | str[0] = '\0'; |
| 2808 | } |
| 2809 | str[c1] = '\0'; |
| 2810 | |
| 2811 | /* If isn't a word bracketed by `[:' and `:]': |
| 2812 | undo the ending character, the letters, and leave |
| 2813 | the leading `:' and `[' (but store them as character). */ |
| 2814 | if (c == ':' && *p == ']') |
| 2815 | { |
| 2816 | wctype_t wt; |
| 2817 | uintptr_t alignedp; |
| 2818 | |
| 2819 | /* Query the character class as wctype_t. */ |
| 2820 | wt = IS_CHAR_CLASS (str); |
| 2821 | if (wt == 0) |
| 2822 | FREE_STACK_RETURN (REG_ECTYPE); |
| 2823 | |
| 2824 | /* Throw away the ] at the end of the character |
| 2825 | class. */ |
| 2826 | PATFETCH (c); |
| 2827 | |
| 2828 | if (p == pend) FREE_STACK_RETURN (REG_EBRACK); |
| 2829 | |
| 2830 | /* Allocate the space for character class. */ |
| 2831 | GET_BUFFER_SPACE(CHAR_CLASS_SIZE); |
| 2832 | /* Update the pointer to indicate end of buffer. */ |
| 2833 | b += CHAR_CLASS_SIZE; |
| 2834 | /* Move data which follow character classes |
| 2835 | not to violate the data. */ |
| 2836 | insert_space(CHAR_CLASS_SIZE, |
| 2837 | laststart + 6 + laststart[1], |
| 2838 | b - 1); |
| 2839 | alignedp = ((uintptr_t)(laststart + 6 + laststart[1]) |
| 2840 | + __alignof__(wctype_t) - 1) |
| 2841 | & ~(uintptr_t)(__alignof__(wctype_t) - 1); |
| 2842 | /* Store the character class. */ |
| 2843 | *((wctype_t*)alignedp) = wt; |
| 2844 | /* Update length of char_classes */ |
| 2845 | laststart[1] += CHAR_CLASS_SIZE; |
| 2846 | |
| 2847 | had_char_class = true; |
| 2848 | } |
| 2849 | else |
| 2850 | { |
| 2851 | c1++; |
| 2852 | while (c1--) |
| 2853 | PATUNFETCH; |
| 2854 | BUF_PUSH ('['); |
| 2855 | BUF_PUSH (':'); |
| 2856 | laststart[5] += 2; /* Update the length of characters */ |
| 2857 | range_start = ':'; |
| 2858 | had_char_class = false; |
| 2859 | } |
| 2860 | } |
| 2861 | else if (syntax & RE_CHAR_CLASSES && c == '[' && (*p == '=' |
| 2862 | || *p == '.')) |
| 2863 | { |
| 2864 | CHAR_T str[128]; /* Should be large enough. */ |
| 2865 | CHAR_T delim = *p; /* '=' or '.' */ |
| 2866 | # ifdef _LIBC |
| 2867 | uint32_t nrules = |
| 2868 | _NL_CURRENT_WORD (LC_COLLATE, _NL_COLLATE_NRULES); |
| 2869 | # endif |
| 2870 | PATFETCH (c); |
| 2871 | c1 = 0; |
| 2872 | |
| 2873 | /* If pattern is `[[=' or '[[.'. */ |
| 2874 | if (p == pend) FREE_STACK_RETURN (REG_EBRACK); |
| 2875 | |
| 2876 | for (;;) |
| 2877 | { |
| 2878 | PATFETCH (c); |
| 2879 | if ((c == delim && *p == ']') || p == pend) |
| 2880 | break; |
| 2881 | if (c1 < sizeof (str) - 1) |
| 2882 | str[c1++] = c; |
| 2883 | else |
| 2884 | /* This is in any case an invalid class name. */ |
| 2885 | str[0] = '\0'; |
| 2886 | } |
| 2887 | str[c1] = '\0'; |
| 2888 | |
| 2889 | if (c == delim && *p == ']' && str[0] != '\0') |
| 2890 | { |
| 2891 | unsigned int i, offset; |
| 2892 | /* If we have no collation data we use the default |
| 2893 | collation in which each character is in a class |
| 2894 | by itself. It also means that ASCII is the |
| 2895 | character set and therefore we cannot have character |
| 2896 | with more than one byte in the multibyte |
| 2897 | representation. */ |
| 2898 | |
| 2899 | /* If not defined _LIBC, we push the name and |
| 2900 | `\0' for the sake of matching performance. */ |
| 2901 | int datasize = c1 + 1; |
| 2902 | |
| 2903 | # ifdef _LIBC |
| 2904 | int32_t idx = 0; |
| 2905 | if (nrules == 0) |
| 2906 | # endif |
| 2907 | { |
| 2908 | if (c1 != 1) |
| 2909 | FREE_STACK_RETURN (REG_ECOLLATE); |
| 2910 | } |
| 2911 | # ifdef _LIBC |
| 2912 | else |
| 2913 | { |
| 2914 | const int32_t *table; |
| 2915 | const int32_t *weights; |
| 2916 | const int32_t *extra; |
| 2917 | const int32_t *indirect; |
| 2918 | wint_t *cp; |
| 2919 | |
| 2920 | /* This #include defines a local function! */ |
| 2921 | # include <locale/weightwc.h> |
| 2922 | |
| 2923 | if(delim == '=') |
| 2924 | { |
| 2925 | /* We push the index for equivalence class. */ |
| 2926 | cp = (wint_t*)str; |
| 2927 | |
| 2928 | table = (const int32_t *) |
| 2929 | _NL_CURRENT (LC_COLLATE, |
| 2930 | _NL_COLLATE_TABLEWC); |
| 2931 | weights = (const int32_t *) |
| 2932 | _NL_CURRENT (LC_COLLATE, |
| 2933 | _NL_COLLATE_WEIGHTWC); |
| 2934 | extra = (const int32_t *) |
| 2935 | _NL_CURRENT (LC_COLLATE, |
| 2936 | _NL_COLLATE_EXTRAWC); |
| 2937 | indirect = (const int32_t *) |
| 2938 | _NL_CURRENT (LC_COLLATE, |
| 2939 | _NL_COLLATE_INDIRECTWC); |
| 2940 | |
| 2941 | idx = findidx ((const wint_t**)&cp); |
| 2942 | if (idx == 0 || cp < (wint_t*) str + c1) |
| 2943 | /* This is no valid character. */ |
| 2944 | FREE_STACK_RETURN (REG_ECOLLATE); |
| 2945 | |
| 2946 | str[0] = (wchar_t)idx; |
| 2947 | } |
| 2948 | else /* delim == '.' */ |
| 2949 | { |
| 2950 | /* We push collation sequence value |
| 2951 | for collating symbol. */ |
| 2952 | int32_t table_size; |
| 2953 | const int32_t *symb_table; |
| 2954 | const unsigned char *extra; |
| 2955 | int32_t idx; |
| 2956 | int32_t elem; |
| 2957 | int32_t second; |
| 2958 | int32_t hash; |
| 2959 | char char_str[c1]; |
| 2960 | |
| 2961 | /* We have to convert the name to a single-byte |
| 2962 | string. This is possible since the names |
| 2963 | consist of ASCII characters and the internal |
| 2964 | representation is UCS4. */ |
| 2965 | for (i = 0; i < c1; ++i) |
| 2966 | char_str[i] = str[i]; |
| 2967 | |
| 2968 | table_size = |
| 2969 | _NL_CURRENT_WORD (LC_COLLATE, |
| 2970 | _NL_COLLATE_SYMB_HASH_SIZEMB); |
| 2971 | symb_table = (const int32_t *) |
| 2972 | _NL_CURRENT (LC_COLLATE, |
| 2973 | _NL_COLLATE_SYMB_TABLEMB); |
| 2974 | extra = (const unsigned char *) |
| 2975 | _NL_CURRENT (LC_COLLATE, |
| 2976 | _NL_COLLATE_SYMB_EXTRAMB); |
| 2977 | |
| 2978 | /* Locate the character in the hashing table. */ |
| 2979 | hash = elem_hash (char_str, c1); |
| 2980 | |
| 2981 | idx = 0; |
| 2982 | elem = hash % table_size; |
| 2983 | second = hash % (table_size - 2); |
| 2984 | while (symb_table[2 * elem] != 0) |
| 2985 | { |
| 2986 | /* First compare the hashing value. */ |
| 2987 | if (symb_table[2 * elem] == hash |
| 2988 | && c1 == extra[symb_table[2 * elem + 1]] |
| 2989 | && memcmp (char_str, |
| 2990 | &extra[symb_table[2 * elem + 1] |
| 2991 | + 1], c1) == 0) |
| 2992 | { |
| 2993 | /* Yep, this is the entry. */ |
| 2994 | idx = symb_table[2 * elem + 1]; |
| 2995 | idx += 1 + extra[idx]; |
| 2996 | break; |
| 2997 | } |
| 2998 | |
| 2999 | /* Next entry. */ |
| 3000 | elem += second; |
| 3001 | } |
| 3002 | |
| 3003 | if (symb_table[2 * elem] != 0) |
| 3004 | { |
| 3005 | /* Compute the index of the byte sequence |
| 3006 | in the table. */ |
| 3007 | idx += 1 + extra[idx]; |
| 3008 | /* Adjust for the alignment. */ |
| 3009 | idx = (idx + 3) & ~3; |
| 3010 | |
| 3011 | str[0] = (wchar_t) idx + 4; |
| 3012 | } |
| 3013 | else if (symb_table[2 * elem] == 0 && c1 == 1) |
| 3014 | { |
| 3015 | /* No valid character. Match it as a |
| 3016 | single byte character. */ |
| 3017 | had_char_class = false; |
| 3018 | BUF_PUSH(str[0]); |
| 3019 | /* Update the length of characters */ |
| 3020 | laststart[5]++; |
| 3021 | range_start = str[0]; |
| 3022 | |
| 3023 | /* Throw away the ] at the end of the |
| 3024 | collating symbol. */ |
| 3025 | PATFETCH (c); |
| 3026 | /* exit from the switch block. */ |
| 3027 | continue; |
| 3028 | } |
| 3029 | else |
| 3030 | FREE_STACK_RETURN (REG_ECOLLATE); |
| 3031 | } |
| 3032 | datasize = 1; |
| 3033 | } |
| 3034 | # endif |
| 3035 | /* Throw away the ] at the end of the equivalence |
| 3036 | class (or collating symbol). */ |
| 3037 | PATFETCH (c); |
| 3038 | |
| 3039 | /* Allocate the space for the equivalence class |
| 3040 | (or collating symbol) (and '\0' if needed). */ |
| 3041 | GET_BUFFER_SPACE(datasize); |
| 3042 | /* Update the pointer to indicate end of buffer. */ |
| 3043 | b += datasize; |
| 3044 | |
| 3045 | if (delim == '=') |
| 3046 | { /* equivalence class */ |
| 3047 | /* Calculate the offset of char_ranges, |
| 3048 | which is next to equivalence_classes. */ |
| 3049 | offset = laststart[1] + laststart[2] |
| 3050 | + laststart[3] +6; |
| 3051 | /* Insert space. */ |
| 3052 | insert_space(datasize, laststart + offset, b - 1); |
| 3053 | |
| 3054 | /* Write the equivalence_class and \0. */ |
| 3055 | for (i = 0 ; i < datasize ; i++) |
| 3056 | laststart[offset + i] = str[i]; |
| 3057 | |
| 3058 | /* Update the length of equivalence_classes. */ |
| 3059 | laststart[3] += datasize; |
| 3060 | had_char_class = true; |
| 3061 | } |
| 3062 | else /* delim == '.' */ |
| 3063 | { /* collating symbol */ |
| 3064 | /* Calculate the offset of the equivalence_classes, |
| 3065 | which is next to collating_symbols. */ |
| 3066 | offset = laststart[1] + laststart[2] + 6; |
| 3067 | /* Insert space and write the collationg_symbol |
| 3068 | and \0. */ |
| 3069 | insert_space(datasize, laststart + offset, b-1); |
| 3070 | for (i = 0 ; i < datasize ; i++) |
| 3071 | laststart[offset + i] = str[i]; |
| 3072 | |
| 3073 | /* In re_match_2_internal if range_start < -1, we |
| 3074 | assume -range_start is the offset of the |
| 3075 | collating symbol which is specified as |
| 3076 | the character of the range start. So we assign |
| 3077 | -(laststart[1] + laststart[2] + 6) to |
| 3078 | range_start. */ |
| 3079 | range_start = -(laststart[1] + laststart[2] + 6); |
| 3080 | /* Update the length of collating_symbol. */ |
| 3081 | laststart[2] += datasize; |
| 3082 | had_char_class = false; |
| 3083 | } |
| 3084 | } |
| 3085 | else |
| 3086 | { |
| 3087 | c1++; |
| 3088 | while (c1--) |
| 3089 | PATUNFETCH; |
| 3090 | BUF_PUSH ('['); |
| 3091 | BUF_PUSH (delim); |
| 3092 | laststart[5] += 2; /* Update the length of characters */ |
| 3093 | range_start = delim; |
| 3094 | had_char_class = false; |
| 3095 | } |
| 3096 | } |
| 3097 | else |
| 3098 | { |
| 3099 | had_char_class = false; |
| 3100 | BUF_PUSH(c); |
| 3101 | laststart[5]++; /* Update the length of characters */ |
| 3102 | range_start = c; |
| 3103 | } |
| 3104 | } |
| 3105 | |
| 3106 | #else /* BYTE */ |
| 3107 | /* Ensure that we have enough space to push a charset: the |
| 3108 | opcode, the length count, and the bitset; 34 bytes in all. */ |
| 3109 | GET_BUFFER_SPACE (34); |
| 3110 | |
| 3111 | laststart = b; |
| 3112 | |
| 3113 | /* We test `*p == '^' twice, instead of using an if |
| 3114 | statement, so we only need one BUF_PUSH. */ |
| 3115 | BUF_PUSH (*p == '^' ? charset_not : charset); |
| 3116 | if (*p == '^') |
| 3117 | p++; |
| 3118 | |
| 3119 | /* Remember the first position in the bracket expression. */ |
| 3120 | p1 = p; |
| 3121 | |
| 3122 | /* Push the number of bytes in the bitmap. */ |
| 3123 | BUF_PUSH ((1 << BYTEWIDTH) / BYTEWIDTH); |
| 3124 | |
| 3125 | /* Clear the whole map. */ |
| 3126 | bzero (b, (1 << BYTEWIDTH) / BYTEWIDTH); |
| 3127 | |
| 3128 | /* charset_not matches newline according to a syntax bit. */ |
| 3129 | if ((re_opcode_t) b[-2] == charset_not |
| 3130 | && (syntax & RE_HAT_LISTS_NOT_NEWLINE)) |
| 3131 | SET_LIST_BIT ('\n'); |
| 3132 | |
| 3133 | /* Read in characters and ranges, setting map bits. */ |
| 3134 | for (;;) |
| 3135 | { |
| 3136 | if (p == pend) FREE_STACK_RETURN (REG_EBRACK); |
| 3137 | |
| 3138 | PATFETCH (c); |
| 3139 | |
| 3140 | /* \ might escape characters inside [...] and [^...]. */ |
| 3141 | if ((syntax & RE_BACKSLASH_ESCAPE_IN_LISTS) && c == '\\') |
| 3142 | { |
| 3143 | if (p == pend) FREE_STACK_RETURN (REG_EESCAPE); |
| 3144 | |
| 3145 | PATFETCH (c1); |
| 3146 | SET_LIST_BIT (c1); |
| 3147 | range_start = c1; |
| 3148 | continue; |
| 3149 | } |
| 3150 | |
| 3151 | /* Could be the end of the bracket expression. If it's |
| 3152 | not (i.e., when the bracket expression is `[]' so |
| 3153 | far), the ']' character bit gets set way below. */ |
| 3154 | if (c == ']' && p != p1 + 1) |
| 3155 | break; |
| 3156 | |
| 3157 | /* Look ahead to see if it's a range when the last thing |
| 3158 | was a character class. */ |
| 3159 | if (had_char_class && c == '-' && *p != ']') |
| 3160 | FREE_STACK_RETURN (REG_ERANGE); |
| 3161 | |
| 3162 | /* Look ahead to see if it's a range when the last thing |
| 3163 | was a character: if this is a hyphen not at the |
| 3164 | beginning or the end of a list, then it's the range |
| 3165 | operator. */ |
| 3166 | if (c == '-' |
| 3167 | && !(p - 2 >= pattern && p[-2] == '[') |
| 3168 | && !(p - 3 >= pattern && p[-3] == '[' && p[-2] == '^') |
| 3169 | && *p != ']') |
| 3170 | { |
| 3171 | reg_errcode_t ret |
| 3172 | = byte_compile_range (range_start, &p, pend, translate, |
| 3173 | syntax, b); |
| 3174 | if (ret != REG_NOERROR) FREE_STACK_RETURN (ret); |
| 3175 | range_start = 0xffffffff; |
| 3176 | } |
| 3177 | |
| 3178 | else if (p[0] == '-' && p[1] != ']') |
| 3179 | { /* This handles ranges made up of characters only. */ |
| 3180 | reg_errcode_t ret; |
| 3181 | |
| 3182 | /* Move past the `-'. */ |
| 3183 | PATFETCH (c1); |
| 3184 | |
| 3185 | ret = byte_compile_range (c, &p, pend, translate, syntax, b); |
| 3186 | if (ret != REG_NOERROR) FREE_STACK_RETURN (ret); |
| 3187 | range_start = 0xffffffff; |
| 3188 | } |
| 3189 | |
| 3190 | /* See if we're at the beginning of a possible character |
| 3191 | class. */ |
| 3192 | |
| 3193 | else if (syntax & RE_CHAR_CLASSES && c == '[' && *p == ':') |
| 3194 | { /* Leave room for the null. */ |
| 3195 | char str[CHAR_CLASS_MAX_LENGTH + 1]; |
| 3196 | |
| 3197 | PATFETCH (c); |
| 3198 | c1 = 0; |
| 3199 | |
| 3200 | /* If pattern is `[[:'. */ |
| 3201 | if (p == pend) FREE_STACK_RETURN (REG_EBRACK); |
| 3202 | |
| 3203 | for (;;) |
| 3204 | { |
| 3205 | PATFETCH (c); |
| 3206 | if ((c == ':' && *p == ']') || p == pend) |
| 3207 | break; |
| 3208 | if (c1 < CHAR_CLASS_MAX_LENGTH) |
| 3209 | str[c1++] = c; |
| 3210 | else |
| 3211 | /* This is in any case an invalid class name. */ |
| 3212 | str[0] = '\0'; |
| 3213 | } |
| 3214 | str[c1] = '\0'; |
| 3215 | |
| 3216 | /* If isn't a word bracketed by `[:' and `:]': |
| 3217 | undo the ending character, the letters, and leave |
| 3218 | the leading `:' and `[' (but set bits for them). */ |
| 3219 | if (c == ':' && *p == ']') |
| 3220 | { |
| 3221 | # if defined _LIBC || WIDE_CHAR_SUPPORT |
| 3222 | boolean is_lower = STREQ (str, "lower"); |
| 3223 | boolean is_upper = STREQ (str, "upper"); |
| 3224 | wctype_t wt; |
| 3225 | int ch; |
| 3226 | |
| 3227 | wt = IS_CHAR_CLASS (str); |
| 3228 | if (wt == 0) |
| 3229 | FREE_STACK_RETURN (REG_ECTYPE); |
| 3230 | |
| 3231 | /* Throw away the ] at the end of the character |
| 3232 | class. */ |
| 3233 | PATFETCH (c); |
| 3234 | |
| 3235 | if (p == pend) FREE_STACK_RETURN (REG_EBRACK); |
| 3236 | |
| 3237 | for (ch = 0; ch < 1 << BYTEWIDTH; ++ch) |
| 3238 | { |
| 3239 | # ifdef _LIBC |
| 3240 | if (__iswctype (__btowc (ch), wt)) |
| 3241 | SET_LIST_BIT (ch); |
| 3242 | # else |
| 3243 | if (iswctype (btowc (ch), wt)) |
| 3244 | SET_LIST_BIT (ch); |
| 3245 | # endif |
| 3246 | |
| 3247 | if (translate && (is_upper || is_lower) |
| 3248 | && (ISUPPER (ch) || ISLOWER (ch))) |
| 3249 | SET_LIST_BIT (ch); |
| 3250 | } |
| 3251 | |
| 3252 | had_char_class = true; |
| 3253 | # else |
| 3254 | int ch; |
| 3255 | boolean is_alnum = STREQ (str, "alnum"); |
| 3256 | boolean is_alpha = STREQ (str, "alpha"); |
| 3257 | boolean is_blank = STREQ (str, "blank"); |
| 3258 | boolean is_cntrl = STREQ (str, "cntrl"); |
| 3259 | boolean is_digit = STREQ (str, "digit"); |
| 3260 | boolean is_graph = STREQ (str, "graph"); |
| 3261 | boolean is_lower = STREQ (str, "lower"); |
| 3262 | boolean is_print = STREQ (str, "print"); |
| 3263 | boolean is_punct = STREQ (str, "punct"); |
| 3264 | boolean is_space = STREQ (str, "space"); |
| 3265 | boolean is_upper = STREQ (str, "upper"); |
| 3266 | boolean is_xdigit = STREQ (str, "xdigit"); |
| 3267 | |
| 3268 | if (!IS_CHAR_CLASS (str)) |
| 3269 | FREE_STACK_RETURN (REG_ECTYPE); |
| 3270 | |
| 3271 | /* Throw away the ] at the end of the character |
| 3272 | class. */ |
| 3273 | PATFETCH (c); |
| 3274 | |
| 3275 | if (p == pend) FREE_STACK_RETURN (REG_EBRACK); |
| 3276 | |
| 3277 | for (ch = 0; ch < 1 << BYTEWIDTH; ch++) |
| 3278 | { |
| 3279 | /* This was split into 3 if's to |
| 3280 | avoid an arbitrary limit in some compiler. */ |
| 3281 | if ( (is_alnum && ISALNUM (ch)) |
| 3282 | || (is_alpha && ISALPHA (ch)) |
| 3283 | || (is_blank && ISBLANK (ch)) |
| 3284 | || (is_cntrl && ISCNTRL (ch))) |
| 3285 | SET_LIST_BIT (ch); |
| 3286 | if ( (is_digit && ISDIGIT (ch)) |
| 3287 | || (is_graph && ISGRAPH (ch)) |
| 3288 | || (is_lower && ISLOWER (ch)) |
| 3289 | || (is_print && ISPRINT (ch))) |
| 3290 | SET_LIST_BIT (ch); |
| 3291 | if ( (is_punct && ISPUNCT (ch)) |
| 3292 | || (is_space && ISSPACE (ch)) |
| 3293 | || (is_upper && ISUPPER (ch)) |
| 3294 | || (is_xdigit && ISXDIGIT (ch))) |
| 3295 | SET_LIST_BIT (ch); |
| 3296 | if ( translate && (is_upper || is_lower) |
| 3297 | && (ISUPPER (ch) || ISLOWER (ch))) |
| 3298 | SET_LIST_BIT (ch); |
| 3299 | } |
| 3300 | had_char_class = true; |
| 3301 | # endif /* libc || wctype.h */ |
| 3302 | } |
| 3303 | else |
| 3304 | { |
| 3305 | c1++; |
| 3306 | while (c1--) |
| 3307 | PATUNFETCH; |
| 3308 | SET_LIST_BIT ('['); |
| 3309 | SET_LIST_BIT (':'); |
| 3310 | range_start = ':'; |
| 3311 | had_char_class = false; |
| 3312 | } |
| 3313 | } |
| 3314 | else if (syntax & RE_CHAR_CLASSES && c == '[' && *p == '=') |
| 3315 | { |
| 3316 | unsigned char str[MB_LEN_MAX + 1]; |
| 3317 | # ifdef _LIBC |
| 3318 | uint32_t nrules = |
| 3319 | _NL_CURRENT_WORD (LC_COLLATE, _NL_COLLATE_NRULES); |
| 3320 | # endif |
| 3321 | |
| 3322 | PATFETCH (c); |
| 3323 | c1 = 0; |
| 3324 | |
| 3325 | /* If pattern is `[[='. */ |
| 3326 | if (p == pend) FREE_STACK_RETURN (REG_EBRACK); |
| 3327 | |
| 3328 | for (;;) |
| 3329 | { |
| 3330 | PATFETCH (c); |
| 3331 | if ((c == '=' && *p == ']') || p == pend) |
| 3332 | break; |
| 3333 | if (c1 < MB_LEN_MAX) |
| 3334 | str[c1++] = c; |
| 3335 | else |
| 3336 | /* This is in any case an invalid class name. */ |
| 3337 | str[0] = '\0'; |
| 3338 | } |
| 3339 | str[c1] = '\0'; |
| 3340 | |
| 3341 | if (c == '=' && *p == ']' && str[0] != '\0') |
| 3342 | { |
| 3343 | /* If we have no collation data we use the default |
| 3344 | collation in which each character is in a class |
| 3345 | by itself. It also means that ASCII is the |
| 3346 | character set and therefore we cannot have character |
| 3347 | with more than one byte in the multibyte |
| 3348 | representation. */ |
| 3349 | # ifdef _LIBC |
| 3350 | if (nrules == 0) |
| 3351 | # endif |
| 3352 | { |
| 3353 | if (c1 != 1) |
| 3354 | FREE_STACK_RETURN (REG_ECOLLATE); |
| 3355 | |
| 3356 | /* Throw away the ] at the end of the equivalence |
| 3357 | class. */ |
| 3358 | PATFETCH (c); |
| 3359 | |
| 3360 | /* Set the bit for the character. */ |
| 3361 | SET_LIST_BIT (str[0]); |
| 3362 | } |
| 3363 | # ifdef _LIBC |
| 3364 | else |
| 3365 | { |
| 3366 | /* Try to match the byte sequence in `str' against |
| 3367 | those known to the collate implementation. |
| 3368 | First find out whether the bytes in `str' are |
| 3369 | actually from exactly one character. */ |
| 3370 | const int32_t *table; |
| 3371 | const unsigned char *weights; |
| 3372 | const unsigned char *extra; |
| 3373 | const int32_t *indirect; |
| 3374 | int32_t idx; |
| 3375 | const unsigned char *cp = str; |
| 3376 | int ch; |
| 3377 | |
| 3378 | /* This #include defines a local function! */ |
| 3379 | # include <locale/weight.h> |
| 3380 | |
| 3381 | table = (const int32_t *) |
| 3382 | _NL_CURRENT (LC_COLLATE, _NL_COLLATE_TABLEMB); |
| 3383 | weights = (const unsigned char *) |
| 3384 | _NL_CURRENT (LC_COLLATE, _NL_COLLATE_WEIGHTMB); |
| 3385 | extra = (const unsigned char *) |
| 3386 | _NL_CURRENT (LC_COLLATE, _NL_COLLATE_EXTRAMB); |
| 3387 | indirect = (const int32_t *) |
| 3388 | _NL_CURRENT (LC_COLLATE, _NL_COLLATE_INDIRECTMB); |
| 3389 | |
| 3390 | idx = findidx (&cp); |
| 3391 | if (idx == 0 || cp < str + c1) |
| 3392 | /* This is no valid character. */ |
| 3393 | FREE_STACK_RETURN (REG_ECOLLATE); |
| 3394 | |
| 3395 | /* Throw away the ] at the end of the equivalence |
| 3396 | class. */ |
| 3397 | PATFETCH (c); |
| 3398 | |
| 3399 | /* Now we have to go through the whole table |
| 3400 | and find all characters which have the same |
| 3401 | first level weight. |
| 3402 | |
| 3403 | XXX Note that this is not entirely correct. |
| 3404 | we would have to match multibyte sequences |
| 3405 | but this is not possible with the current |
| 3406 | implementation. */ |
| 3407 | for (ch = 1; ch < 256; ++ch) |
| 3408 | /* XXX This test would have to be changed if we |
| 3409 | would allow matching multibyte sequences. */ |
| 3410 | if (table[ch] > 0) |
| 3411 | { |
| 3412 | int32_t idx2 = table[ch]; |
| 3413 | size_t len = weights[idx2]; |
| 3414 | |
| 3415 | /* Test whether the lenghts match. */ |
| 3416 | if (weights[idx] == len) |
| 3417 | { |
| 3418 | /* They do. New compare the bytes of |
| 3419 | the weight. */ |
| 3420 | size_t cnt = 0; |
| 3421 | |
| 3422 | while (cnt < len |
| 3423 | && (weights[idx + 1 + cnt] |
| 3424 | == weights[idx2 + 1 + cnt])) |
| 3425 | ++cnt; |
| 3426 | |
| 3427 | if (cnt == len) |
| 3428 | /* They match. Mark the character as |
| 3429 | acceptable. */ |
| 3430 | SET_LIST_BIT (ch); |
| 3431 | } |
| 3432 | } |
| 3433 | } |
| 3434 | # endif |
| 3435 | had_char_class = true; |
| 3436 | } |
| 3437 | else |
| 3438 | { |
| 3439 | c1++; |
| 3440 | while (c1--) |
| 3441 | PATUNFETCH; |
| 3442 | SET_LIST_BIT ('['); |
| 3443 | SET_LIST_BIT ('='); |
| 3444 | range_start = '='; |
| 3445 | had_char_class = false; |
| 3446 | } |
| 3447 | } |
| 3448 | else if (syntax & RE_CHAR_CLASSES && c == '[' && *p == '.') |
| 3449 | { |
| 3450 | unsigned char str[128]; /* Should be large enough. */ |
| 3451 | # ifdef _LIBC |
| 3452 | uint32_t nrules = |
| 3453 | _NL_CURRENT_WORD (LC_COLLATE, _NL_COLLATE_NRULES); |
| 3454 | # endif |
| 3455 | |
| 3456 | PATFETCH (c); |
| 3457 | c1 = 0; |
| 3458 | |
| 3459 | /* If pattern is `[[.'. */ |
| 3460 | if (p == pend) FREE_STACK_RETURN (REG_EBRACK); |
| 3461 | |
| 3462 | for (;;) |
| 3463 | { |
| 3464 | PATFETCH (c); |
| 3465 | if ((c == '.' && *p == ']') || p == pend) |
| 3466 | break; |
| 3467 | if (c1 < sizeof (str)) |
| 3468 | str[c1++] = c; |
| 3469 | else |
| 3470 | /* This is in any case an invalid class name. */ |
| 3471 | str[0] = '\0'; |
| 3472 | } |
| 3473 | str[c1] = '\0'; |
| 3474 | |
| 3475 | if (c == '.' && *p == ']' && str[0] != '\0') |
| 3476 | { |
| 3477 | /* If we have no collation data we use the default |
| 3478 | collation in which each character is the name |
| 3479 | for its own class which contains only the one |
| 3480 | character. It also means that ASCII is the |
| 3481 | character set and therefore we cannot have character |
| 3482 | with more than one byte in the multibyte |
| 3483 | representation. */ |
| 3484 | # ifdef _LIBC |
| 3485 | if (nrules == 0) |
| 3486 | # endif |
| 3487 | { |
| 3488 | if (c1 != 1) |
| 3489 | FREE_STACK_RETURN (REG_ECOLLATE); |
| 3490 | |
| 3491 | /* Throw away the ] at the end of the equivalence |
| 3492 | class. */ |
| 3493 | PATFETCH (c); |
| 3494 | |
| 3495 | /* Set the bit for the character. */ |
| 3496 | SET_LIST_BIT (str[0]); |
| 3497 | range_start = ((const unsigned char *) str)[0]; |
| 3498 | } |
| 3499 | # ifdef _LIBC |
| 3500 | else |
| 3501 | { |
| 3502 | /* Try to match the byte sequence in `str' against |
| 3503 | those known to the collate implementation. |
| 3504 | First find out whether the bytes in `str' are |
| 3505 | actually from exactly one character. */ |
| 3506 | int32_t table_size; |
| 3507 | const int32_t *symb_table; |
| 3508 | const unsigned char *extra; |
| 3509 | int32_t idx; |
| 3510 | int32_t elem; |
| 3511 | int32_t second; |
| 3512 | int32_t hash; |
| 3513 | |
| 3514 | table_size = |
| 3515 | _NL_CURRENT_WORD (LC_COLLATE, |
| 3516 | _NL_COLLATE_SYMB_HASH_SIZEMB); |
| 3517 | symb_table = (const int32_t *) |
| 3518 | _NL_CURRENT (LC_COLLATE, |
| 3519 | _NL_COLLATE_SYMB_TABLEMB); |
| 3520 | extra = (const unsigned char *) |
| 3521 | _NL_CURRENT (LC_COLLATE, |
| 3522 | _NL_COLLATE_SYMB_EXTRAMB); |
| 3523 | |
| 3524 | /* Locate the character in the hashing table. */ |
| 3525 | hash = elem_hash (str, c1); |
| 3526 | |
| 3527 | idx = 0; |
| 3528 | elem = hash % table_size; |
| 3529 | second = hash % (table_size - 2); |
| 3530 | while (symb_table[2 * elem] != 0) |
| 3531 | { |
| 3532 | /* First compare the hashing value. */ |
| 3533 | if (symb_table[2 * elem] == hash |
| 3534 | && c1 == extra[symb_table[2 * elem + 1]] |
| 3535 | && memcmp (str, |
| 3536 | &extra[symb_table[2 * elem + 1] |
| 3537 | + 1], |
| 3538 | c1) == 0) |
| 3539 | { |
| 3540 | /* Yep, this is the entry. */ |
| 3541 | idx = symb_table[2 * elem + 1]; |
| 3542 | idx += 1 + extra[idx]; |
| 3543 | break; |
| 3544 | } |
| 3545 | |
| 3546 | /* Next entry. */ |
| 3547 | elem += second; |
| 3548 | } |
| 3549 | |
| 3550 | if (symb_table[2 * elem] == 0) |
| 3551 | /* This is no valid character. */ |
| 3552 | FREE_STACK_RETURN (REG_ECOLLATE); |
| 3553 | |
| 3554 | /* Throw away the ] at the end of the equivalence |
| 3555 | class. */ |
| 3556 | PATFETCH (c); |
| 3557 | |
| 3558 | /* Now add the multibyte character(s) we found |
| 3559 | to the accept list. |
| 3560 | |
| 3561 | XXX Note that this is not entirely correct. |
| 3562 | we would have to match multibyte sequences |
| 3563 | but this is not possible with the current |
| 3564 | implementation. Also, we have to match |
| 3565 | collating symbols, which expand to more than |
| 3566 | one file, as a whole and not allow the |
| 3567 | individual bytes. */ |
| 3568 | c1 = extra[idx++]; |
| 3569 | if (c1 == 1) |
| 3570 | range_start = extra[idx]; |
| 3571 | while (c1-- > 0) |
| 3572 | { |
| 3573 | SET_LIST_BIT (extra[idx]); |
| 3574 | ++idx; |
| 3575 | } |
| 3576 | } |
| 3577 | # endif |
| 3578 | had_char_class = false; |
| 3579 | } |
| 3580 | else |
| 3581 | { |
| 3582 | c1++; |
| 3583 | while (c1--) |
| 3584 | PATUNFETCH; |
| 3585 | SET_LIST_BIT ('['); |
| 3586 | SET_LIST_BIT ('.'); |
| 3587 | range_start = '.'; |
| 3588 | had_char_class = false; |
| 3589 | } |
| 3590 | } |
| 3591 | else |
| 3592 | { |
| 3593 | had_char_class = false; |
| 3594 | SET_LIST_BIT (c); |
| 3595 | range_start = c; |
| 3596 | } |
| 3597 | } |
| 3598 | |
| 3599 | /* Discard any (non)matching list bytes that are all 0 at the |
| 3600 | end of the map. Decrease the map-length byte too. */ |
| 3601 | while ((int) b[-1] > 0 && b[b[-1] - 1] == 0) |
| 3602 | b[-1]--; |
| 3603 | b += b[-1]; |
| 3604 | #endif /* WCHAR */ |
| 3605 | } |
| 3606 | break; |
| 3607 | |
| 3608 | |
| 3609 | case '(': |
| 3610 | if (syntax & RE_NO_BK_PARENS) |
| 3611 | goto handle_open; |
| 3612 | else |
| 3613 | goto normal_char; |
| 3614 | |
| 3615 | |
| 3616 | case ')': |
| 3617 | if (syntax & RE_NO_BK_PARENS) |
| 3618 | goto handle_close; |
| 3619 | else |
| 3620 | goto normal_char; |
| 3621 | |
| 3622 | |
| 3623 | case '\n': |
| 3624 | if (syntax & RE_NEWLINE_ALT) |
| 3625 | goto handle_alt; |
| 3626 | else |
| 3627 | goto normal_char; |
| 3628 | |
| 3629 | |
| 3630 | case '|': |
| 3631 | if (syntax & RE_NO_BK_VBAR) |
| 3632 | goto handle_alt; |
| 3633 | else |
| 3634 | goto normal_char; |
| 3635 | |
| 3636 | |
| 3637 | case '{': |
| 3638 | if (syntax & RE_INTERVALS && syntax & RE_NO_BK_BRACES) |
| 3639 | goto handle_interval; |
| 3640 | else |
| 3641 | goto normal_char; |
| 3642 | |
| 3643 | |
| 3644 | case '\\': |
| 3645 | if (p == pend) FREE_STACK_RETURN (REG_EESCAPE); |
| 3646 | |
| 3647 | /* Do not translate the character after the \, so that we can |
| 3648 | distinguish, e.g., \B from \b, even if we normally would |
| 3649 | translate, e.g., B to b. */ |
| 3650 | PATFETCH_RAW (c); |
| 3651 | |
| 3652 | switch (c) |
| 3653 | { |
| 3654 | case '(': |
| 3655 | if (syntax & RE_NO_BK_PARENS) |
| 3656 | goto normal_backslash; |
| 3657 | |
| 3658 | handle_open: |
| 3659 | bufp->re_nsub++; |
| 3660 | regnum++; |
| 3661 | |
| 3662 | if (COMPILE_STACK_FULL) |
| 3663 | { |
| 3664 | RETALLOC (compile_stack.stack, compile_stack.size << 1, |
| 3665 | compile_stack_elt_t); |
| 3666 | if (compile_stack.stack == NULL) return REG_ESPACE; |
| 3667 | |
| 3668 | compile_stack.size <<= 1; |
| 3669 | } |
| 3670 | |
| 3671 | /* These are the values to restore when we hit end of this |
| 3672 | group. They are all relative offsets, so that if the |
| 3673 | whole pattern moves because of realloc, they will still |
| 3674 | be valid. */ |
| 3675 | COMPILE_STACK_TOP.begalt_offset = begalt - COMPILED_BUFFER_VAR; |
| 3676 | COMPILE_STACK_TOP.fixup_alt_jump |
| 3677 | = fixup_alt_jump ? fixup_alt_jump - COMPILED_BUFFER_VAR + 1 : 0; |
| 3678 | COMPILE_STACK_TOP.laststart_offset = b - COMPILED_BUFFER_VAR; |
| 3679 | COMPILE_STACK_TOP.regnum = regnum; |
| 3680 | |
| 3681 | /* We will eventually replace the 0 with the number of |
| 3682 | groups inner to this one. But do not push a |
| 3683 | start_memory for groups beyond the last one we can |
| 3684 | represent in the compiled pattern. */ |
| 3685 | if (regnum <= MAX_REGNUM) |
| 3686 | { |
| 3687 | COMPILE_STACK_TOP.inner_group_offset = b |
| 3688 | - COMPILED_BUFFER_VAR + 2; |
| 3689 | BUF_PUSH_3 (start_memory, regnum, 0); |
| 3690 | } |
| 3691 | |
| 3692 | compile_stack.avail++; |
| 3693 | |
| 3694 | fixup_alt_jump = 0; |
| 3695 | laststart = 0; |
| 3696 | begalt = b; |
| 3697 | /* If we've reached MAX_REGNUM groups, then this open |
| 3698 | won't actually generate any code, so we'll have to |
| 3699 | clear pending_exact explicitly. */ |
| 3700 | pending_exact = 0; |
| 3701 | break; |
| 3702 | |
| 3703 | |
| 3704 | case ')': |
| 3705 | if (syntax & RE_NO_BK_PARENS) goto normal_backslash; |
| 3706 | |
| 3707 | if (COMPILE_STACK_EMPTY) |
| 3708 | { |
| 3709 | if (syntax & RE_UNMATCHED_RIGHT_PAREN_ORD) |
| 3710 | goto normal_backslash; |
| 3711 | else |
| 3712 | FREE_STACK_RETURN (REG_ERPAREN); |
| 3713 | } |
| 3714 | |
| 3715 | handle_close: |
| 3716 | if (fixup_alt_jump) |
| 3717 | { /* Push a dummy failure point at the end of the |
| 3718 | alternative for a possible future |
| 3719 | `pop_failure_jump' to pop. See comments at |
| 3720 | `push_dummy_failure' in `re_match_2'. */ |
| 3721 | BUF_PUSH (push_dummy_failure); |
| 3722 | |
| 3723 | /* We allocated space for this jump when we assigned |
| 3724 | to `fixup_alt_jump', in the `handle_alt' case below. */ |
| 3725 | STORE_JUMP (jump_past_alt, fixup_alt_jump, b - 1); |
| 3726 | } |
| 3727 | |
| 3728 | /* See similar code for backslashed left paren above. */ |
| 3729 | if (COMPILE_STACK_EMPTY) |
| 3730 | { |
| 3731 | if (syntax & RE_UNMATCHED_RIGHT_PAREN_ORD) |
| 3732 | goto normal_char; |
| 3733 | else |
| 3734 | FREE_STACK_RETURN (REG_ERPAREN); |
| 3735 | } |
| 3736 | |
| 3737 | /* Since we just checked for an empty stack above, this |
| 3738 | ``can't happen''. */ |
| 3739 | assert (compile_stack.avail != 0); |
| 3740 | { |
| 3741 | /* We don't just want to restore into `regnum', because |
| 3742 | later groups should continue to be numbered higher, |
| 3743 | as in `(ab)c(de)' -- the second group is #2. */ |
| 3744 | regnum_t this_group_regnum; |
| 3745 | |
| 3746 | compile_stack.avail--; |
| 3747 | begalt = COMPILED_BUFFER_VAR + COMPILE_STACK_TOP.begalt_offset; |
| 3748 | fixup_alt_jump |
| 3749 | = COMPILE_STACK_TOP.fixup_alt_jump |
| 3750 | ? COMPILED_BUFFER_VAR + COMPILE_STACK_TOP.fixup_alt_jump - 1 |
| 3751 | : 0; |
| 3752 | laststart = COMPILED_BUFFER_VAR + COMPILE_STACK_TOP.laststart_offset; |
| 3753 | this_group_regnum = COMPILE_STACK_TOP.regnum; |
| 3754 | /* If we've reached MAX_REGNUM groups, then this open |
| 3755 | won't actually generate any code, so we'll have to |
| 3756 | clear pending_exact explicitly. */ |
| 3757 | pending_exact = 0; |
| 3758 | |
| 3759 | /* We're at the end of the group, so now we know how many |
| 3760 | groups were inside this one. */ |
| 3761 | if (this_group_regnum <= MAX_REGNUM) |
| 3762 | { |
| 3763 | UCHAR_T *inner_group_loc |
| 3764 | = COMPILED_BUFFER_VAR + COMPILE_STACK_TOP.inner_group_offset; |
| 3765 | |
| 3766 | *inner_group_loc = regnum - this_group_regnum; |
| 3767 | BUF_PUSH_3 (stop_memory, this_group_regnum, |
| 3768 | regnum - this_group_regnum); |
| 3769 | } |
| 3770 | } |
| 3771 | break; |
| 3772 | |
| 3773 | |
| 3774 | case '|': /* `\|'. */ |
| 3775 | if (syntax & RE_LIMITED_OPS || syntax & RE_NO_BK_VBAR) |
| 3776 | goto normal_backslash; |
| 3777 | handle_alt: |
| 3778 | if (syntax & RE_LIMITED_OPS) |
| 3779 | goto normal_char; |
| 3780 | |
| 3781 | /* Insert before the previous alternative a jump which |
| 3782 | jumps to this alternative if the former fails. */ |
| 3783 | GET_BUFFER_SPACE (1 + OFFSET_ADDRESS_SIZE); |
| 3784 | INSERT_JUMP (on_failure_jump, begalt, |
| 3785 | b + 2 + 2 * OFFSET_ADDRESS_SIZE); |
| 3786 | pending_exact = 0; |
| 3787 | b += 1 + OFFSET_ADDRESS_SIZE; |
| 3788 | |
| 3789 | /* The alternative before this one has a jump after it |
| 3790 | which gets executed if it gets matched. Adjust that |
| 3791 | jump so it will jump to this alternative's analogous |
| 3792 | jump (put in below, which in turn will jump to the next |
| 3793 | (if any) alternative's such jump, etc.). The last such |
| 3794 | jump jumps to the correct final destination. A picture: |
| 3795 | _____ _____ |
| 3796 | | | | | |
| 3797 | | v | v |
| 3798 | a | b | c |
| 3799 | |
| 3800 | If we are at `b', then fixup_alt_jump right now points to a |
| 3801 | three-byte space after `a'. We'll put in the jump, set |
| 3802 | fixup_alt_jump to right after `b', and leave behind three |
| 3803 | bytes which we'll fill in when we get to after `c'. */ |
| 3804 | |
| 3805 | if (fixup_alt_jump) |
| 3806 | STORE_JUMP (jump_past_alt, fixup_alt_jump, b); |
| 3807 | |
| 3808 | /* Mark and leave space for a jump after this alternative, |
| 3809 | to be filled in later either by next alternative or |
| 3810 | when know we're at the end of a series of alternatives. */ |
| 3811 | fixup_alt_jump = b; |
| 3812 | GET_BUFFER_SPACE (1 + OFFSET_ADDRESS_SIZE); |
| 3813 | b += 1 + OFFSET_ADDRESS_SIZE; |
| 3814 | |
| 3815 | laststart = 0; |
| 3816 | begalt = b; |
| 3817 | break; |
| 3818 | |
| 3819 | |
| 3820 | case '{': |
| 3821 | /* If \{ is a literal. */ |
| 3822 | if (!(syntax & RE_INTERVALS) |
| 3823 | /* If we're at `\{' and it's not the open-interval |
| 3824 | operator. */ |
| 3825 | || (syntax & RE_NO_BK_BRACES)) |
| 3826 | goto normal_backslash; |
| 3827 | |
| 3828 | handle_interval: |
| 3829 | { |
| 3830 | /* If got here, then the syntax allows intervals. */ |
| 3831 | |
| 3832 | /* At least (most) this many matches must be made. */ |
| 3833 | int lower_bound = -1, upper_bound = -1; |
| 3834 | |
| 3835 | /* Place in the uncompiled pattern (i.e., just after |
| 3836 | the '{') to go back to if the interval is invalid. */ |
| 3837 | const CHAR_T *beg_interval = p; |
| 3838 | |
| 3839 | if (p == pend) |
| 3840 | goto invalid_interval; |
| 3841 | |
| 3842 | GET_UNSIGNED_NUMBER (lower_bound); |
| 3843 | |
| 3844 | if (c == ',') |
| 3845 | { |
| 3846 | GET_UNSIGNED_NUMBER (upper_bound); |
| 3847 | if (upper_bound < 0) |
| 3848 | upper_bound = RE_DUP_MAX; |
| 3849 | } |
| 3850 | else |
| 3851 | /* Interval such as `{1}' => match exactly once. */ |
| 3852 | upper_bound = lower_bound; |
| 3853 | |
| 3854 | if (! (0 <= lower_bound && lower_bound <= upper_bound)) |
| 3855 | goto invalid_interval; |
| 3856 | |
| 3857 | if (!(syntax & RE_NO_BK_BRACES)) |
| 3858 | { |
| 3859 | if (c != '\\' || p == pend) |
| 3860 | goto invalid_interval; |
| 3861 | PATFETCH (c); |
| 3862 | } |
| 3863 | |
| 3864 | if (c != '}') |
| 3865 | goto invalid_interval; |
| 3866 | |
| 3867 | /* If it's invalid to have no preceding re. */ |
| 3868 | if (!laststart) |
| 3869 | { |
| 3870 | if (syntax & RE_CONTEXT_INVALID_OPS |
| 3871 | && !(syntax & RE_INVALID_INTERVAL_ORD)) |
| 3872 | FREE_STACK_RETURN (REG_BADRPT); |
| 3873 | else if (syntax & RE_CONTEXT_INDEP_OPS) |
| 3874 | laststart = b; |
| 3875 | else |
| 3876 | goto unfetch_interval; |
| 3877 | } |
| 3878 | |
| 3879 | /* We just parsed a valid interval. */ |
| 3880 | |
| 3881 | if (RE_DUP_MAX < upper_bound) |
| 3882 | FREE_STACK_RETURN (REG_BADBR); |
| 3883 | |
| 3884 | /* If the upper bound is zero, don't want to succeed at |
| 3885 | all; jump from `laststart' to `b + 3', which will be |
| 3886 | the end of the buffer after we insert the jump. */ |
| 3887 | /* ifdef WCHAR, 'b + 1 + OFFSET_ADDRESS_SIZE' |
| 3888 | instead of 'b + 3'. */ |
| 3889 | if (upper_bound == 0) |
| 3890 | { |
| 3891 | GET_BUFFER_SPACE (1 + OFFSET_ADDRESS_SIZE); |
| 3892 | INSERT_JUMP (jump, laststart, b + 1 |
| 3893 | + OFFSET_ADDRESS_SIZE); |
| 3894 | b += 1 + OFFSET_ADDRESS_SIZE; |
| 3895 | } |
| 3896 | |
| 3897 | /* Otherwise, we have a nontrivial interval. When |
| 3898 | we're all done, the pattern will look like: |
| 3899 | set_number_at <jump count> <upper bound> |
| 3900 | set_number_at <succeed_n count> <lower bound> |
| 3901 | succeed_n <after jump addr> <succeed_n count> |
| 3902 | <body of loop> |
| 3903 | jump_n <succeed_n addr> <jump count> |
| 3904 | (The upper bound and `jump_n' are omitted if |
| 3905 | `upper_bound' is 1, though.) */ |
| 3906 | else |
| 3907 | { /* If the upper bound is > 1, we need to insert |
| 3908 | more at the end of the loop. */ |
| 3909 | unsigned nbytes = 2 + 4 * OFFSET_ADDRESS_SIZE + |
| 3910 | (upper_bound > 1) * (2 + 4 * OFFSET_ADDRESS_SIZE); |
| 3911 | |
| 3912 | GET_BUFFER_SPACE (nbytes); |
| 3913 | |
| 3914 | /* Initialize lower bound of the `succeed_n', even |
| 3915 | though it will be set during matching by its |
| 3916 | attendant `set_number_at' (inserted next), |
| 3917 | because `re_compile_fastmap' needs to know. |
| 3918 | Jump to the `jump_n' we might insert below. */ |
| 3919 | INSERT_JUMP2 (succeed_n, laststart, |
| 3920 | b + 1 + 2 * OFFSET_ADDRESS_SIZE |
| 3921 | + (upper_bound > 1) * (1 + 2 * OFFSET_ADDRESS_SIZE) |
| 3922 | , lower_bound); |
| 3923 | b += 1 + 2 * OFFSET_ADDRESS_SIZE; |
| 3924 | |
| 3925 | /* Code to initialize the lower bound. Insert |
| 3926 | before the `succeed_n'. The `5' is the last two |
| 3927 | bytes of this `set_number_at', plus 3 bytes of |
| 3928 | the following `succeed_n'. */ |
| 3929 | /* ifdef WCHAR, The '1+2*OFFSET_ADDRESS_SIZE' |
| 3930 | is the 'set_number_at', plus '1+OFFSET_ADDRESS_SIZE' |
| 3931 | of the following `succeed_n'. */ |
| 3932 | PREFIX(insert_op2) (set_number_at, laststart, 1 |
| 3933 | + 2 * OFFSET_ADDRESS_SIZE, lower_bound, b); |
| 3934 | b += 1 + 2 * OFFSET_ADDRESS_SIZE; |
| 3935 | |
| 3936 | if (upper_bound > 1) |
| 3937 | { /* More than one repetition is allowed, so |
| 3938 | append a backward jump to the `succeed_n' |
| 3939 | that starts this interval. |
| 3940 | |
| 3941 | When we've reached this during matching, |
| 3942 | we'll have matched the interval once, so |
| 3943 | jump back only `upper_bound - 1' times. */ |
| 3944 | STORE_JUMP2 (jump_n, b, laststart |
| 3945 | + 2 * OFFSET_ADDRESS_SIZE + 1, |
| 3946 | upper_bound - 1); |
| 3947 | b += 1 + 2 * OFFSET_ADDRESS_SIZE; |
| 3948 | |
| 3949 | /* The location we want to set is the second |
| 3950 | parameter of the `jump_n'; that is `b-2' as |
| 3951 | an absolute address. `laststart' will be |
| 3952 | the `set_number_at' we're about to insert; |
| 3953 | `laststart+3' the number to set, the source |
| 3954 | for the relative address. But we are |
| 3955 | inserting into the middle of the pattern -- |
| 3956 | so everything is getting moved up by 5. |
| 3957 | Conclusion: (b - 2) - (laststart + 3) + 5, |
| 3958 | i.e., b - laststart. |
| 3959 | |
| 3960 | We insert this at the beginning of the loop |
| 3961 | so that if we fail during matching, we'll |
| 3962 | reinitialize the bounds. */ |
| 3963 | PREFIX(insert_op2) (set_number_at, laststart, |
| 3964 | b - laststart, |
| 3965 | upper_bound - 1, b); |
| 3966 | b += 1 + 2 * OFFSET_ADDRESS_SIZE; |
| 3967 | } |
| 3968 | } |
| 3969 | pending_exact = 0; |
| 3970 | break; |
| 3971 | |
| 3972 | invalid_interval: |
| 3973 | if (!(syntax & RE_INVALID_INTERVAL_ORD)) |
| 3974 | FREE_STACK_RETURN (p == pend ? REG_EBRACE : REG_BADBR); |
| 3975 | unfetch_interval: |
| 3976 | /* Match the characters as literals. */ |
| 3977 | p = beg_interval; |
| 3978 | c = '{'; |
| 3979 | if (syntax & RE_NO_BK_BRACES) |
| 3980 | goto normal_char; |
| 3981 | else |
| 3982 | goto normal_backslash; |
| 3983 | } |
| 3984 | |
| 3985 | #ifdef emacs |
| 3986 | /* There is no way to specify the before_dot and after_dot |
| 3987 | operators. rms says this is ok. --karl */ |
| 3988 | case '=': |
| 3989 | BUF_PUSH (at_dot); |
| 3990 | break; |
| 3991 | |
| 3992 | case 's': |
| 3993 | laststart = b; |
| 3994 | PATFETCH (c); |
| 3995 | BUF_PUSH_2 (syntaxspec, syntax_spec_code[c]); |
| 3996 | break; |
| 3997 | |
| 3998 | case 'S': |
| 3999 | laststart = b; |
| 4000 | PATFETCH (c); |
| 4001 | BUF_PUSH_2 (notsyntaxspec, syntax_spec_code[c]); |
| 4002 | break; |
| 4003 | #endif /* emacs */ |
| 4004 | |
| 4005 | |
| 4006 | case 'w': |
| 4007 | if (syntax & RE_NO_GNU_OPS) |
| 4008 | goto normal_char; |
| 4009 | laststart = b; |
| 4010 | BUF_PUSH (wordchar); |
| 4011 | break; |
| 4012 | |
| 4013 | |
| 4014 | case 'W': |
| 4015 | if (syntax & RE_NO_GNU_OPS) |
| 4016 | goto normal_char; |
| 4017 | laststart = b; |
| 4018 | BUF_PUSH (notwordchar); |
| 4019 | break; |
| 4020 | |
| 4021 | |
| 4022 | case '<': |
| 4023 | if (syntax & RE_NO_GNU_OPS) |
| 4024 | goto normal_char; |
| 4025 | BUF_PUSH (wordbeg); |
| 4026 | break; |
| 4027 | |
| 4028 | case '>': |
| 4029 | if (syntax & RE_NO_GNU_OPS) |
| 4030 | goto normal_char; |
| 4031 | BUF_PUSH (wordend); |
| 4032 | break; |
| 4033 | |
| 4034 | case 'b': |
| 4035 | if (syntax & RE_NO_GNU_OPS) |
| 4036 | goto normal_char; |
| 4037 | BUF_PUSH (wordbound); |
| 4038 | break; |
| 4039 | |
| 4040 | case 'B': |
| 4041 | if (syntax & RE_NO_GNU_OPS) |
| 4042 | goto normal_char; |
| 4043 | BUF_PUSH (notwordbound); |
| 4044 | break; |
| 4045 | |
| 4046 | case '`': |
| 4047 | if (syntax & RE_NO_GNU_OPS) |
| 4048 | goto normal_char; |
| 4049 | BUF_PUSH (begbuf); |
| 4050 | break; |
| 4051 | |
| 4052 | case '\'': |
| 4053 | if (syntax & RE_NO_GNU_OPS) |
| 4054 | goto normal_char; |
| 4055 | BUF_PUSH (endbuf); |
| 4056 | break; |
| 4057 | |
| 4058 | case '1': case '2': case '3': case '4': case '5': |
| 4059 | case '6': case '7': case '8': case '9': |
| 4060 | if (syntax & RE_NO_BK_REFS) |
| 4061 | goto normal_char; |
| 4062 | |
| 4063 | c1 = c - '0'; |
| 4064 | |
| 4065 | if (c1 > regnum) |
| 4066 | FREE_STACK_RETURN (REG_ESUBREG); |
| 4067 | |
| 4068 | /* Can't back reference to a subexpression if inside of it. */ |
| 4069 | if (group_in_compile_stack (compile_stack, (regnum_t) c1)) |
| 4070 | goto normal_char; |
| 4071 | |
| 4072 | laststart = b; |
| 4073 | BUF_PUSH_2 (duplicate, c1); |
| 4074 | break; |
| 4075 | |
| 4076 | |
| 4077 | case '+': |
| 4078 | case '?': |
| 4079 | if (syntax & RE_BK_PLUS_QM) |
| 4080 | goto handle_plus; |
| 4081 | else |
| 4082 | goto normal_backslash; |
| 4083 | |
| 4084 | default: |
| 4085 | normal_backslash: |
| 4086 | /* You might think it would be useful for \ to mean |
| 4087 | not to translate; but if we don't translate it |
| 4088 | it will never match anything. */ |
| 4089 | c = TRANSLATE (c); |
| 4090 | goto normal_char; |
| 4091 | } |
| 4092 | break; |
| 4093 | |
| 4094 | |
| 4095 | default: |
| 4096 | /* Expects the character in `c'. */ |
| 4097 | normal_char: |
| 4098 | /* If no exactn currently being built. */ |
| 4099 | if (!pending_exact |
| 4100 | #ifdef WCHAR |
| 4101 | /* If last exactn handle binary(or character) and |
| 4102 | new exactn handle character(or binary). */ |
| 4103 | || is_exactn_bin != is_binary[p - 1 - pattern] |
| 4104 | #endif /* WCHAR */ |
| 4105 | |
| 4106 | /* If last exactn not at current position. */ |
| 4107 | || pending_exact + *pending_exact + 1 != b |
| 4108 | |
| 4109 | /* We have only one byte following the exactn for the count. */ |
| 4110 | || *pending_exact == (1 << BYTEWIDTH) - 1 |
| 4111 | |
| 4112 | /* If followed by a repetition operator. */ |
| 4113 | || *p == '*' || *p == '^' |
| 4114 | || ((syntax & RE_BK_PLUS_QM) |
| 4115 | ? *p == '\\' && (p[1] == '+' || p[1] == '?') |
| 4116 | : (*p == '+' || *p == '?')) |
| 4117 | || ((syntax & RE_INTERVALS) |
| 4118 | && ((syntax & RE_NO_BK_BRACES) |
| 4119 | ? *p == '{' |
| 4120 | : (p[0] == '\\' && p[1] == '{')))) |
| 4121 | { |
| 4122 | /* Start building a new exactn. */ |
| 4123 | |
| 4124 | laststart = b; |
| 4125 | |
| 4126 | #ifdef WCHAR |
| 4127 | /* Is this exactn binary data or character? */ |
| 4128 | is_exactn_bin = is_binary[p - 1 - pattern]; |
| 4129 | if (is_exactn_bin) |
| 4130 | BUF_PUSH_2 (exactn_bin, 0); |
| 4131 | else |
| 4132 | BUF_PUSH_2 (exactn, 0); |
| 4133 | #else |
| 4134 | BUF_PUSH_2 (exactn, 0); |
| 4135 | #endif /* WCHAR */ |
| 4136 | pending_exact = b - 1; |
| 4137 | } |
| 4138 | |
| 4139 | BUF_PUSH (c); |
| 4140 | (*pending_exact)++; |
| 4141 | break; |
| 4142 | } /* switch (c) */ |
| 4143 | } /* while p != pend */ |
| 4144 | |
| 4145 | |
| 4146 | /* Through the pattern now. */ |
| 4147 | |
| 4148 | if (fixup_alt_jump) |
| 4149 | STORE_JUMP (jump_past_alt, fixup_alt_jump, b); |
| 4150 | |
| 4151 | if (!COMPILE_STACK_EMPTY) |
| 4152 | FREE_STACK_RETURN (REG_EPAREN); |
| 4153 | |
| 4154 | /* If we don't want backtracking, force success |
| 4155 | the first time we reach the end of the compiled pattern. */ |
| 4156 | if (syntax & RE_NO_POSIX_BACKTRACKING) |
| 4157 | BUF_PUSH (succeed); |
| 4158 | |
| 4159 | #ifdef WCHAR |
| 4160 | free (pattern); |
| 4161 | free (mbs_offset); |
| 4162 | free (is_binary); |
| 4163 | #endif |
| 4164 | free (compile_stack.stack); |
| 4165 | |
| 4166 | /* We have succeeded; set the length of the buffer. */ |
| 4167 | #ifdef WCHAR |
| 4168 | bufp->used = (uintptr_t) b - (uintptr_t) COMPILED_BUFFER_VAR; |
| 4169 | #else |
| 4170 | bufp->used = b - bufp->buffer; |
| 4171 | #endif |
| 4172 | |
| 4173 | #ifdef DEBUG |
| 4174 | if (debug) |
| 4175 | { |
| 4176 | DEBUG_PRINT1 ("\nCompiled pattern: \n"); |
| 4177 | PREFIX(print_compiled_pattern) (bufp); |
| 4178 | } |
| 4179 | #endif /* DEBUG */ |
| 4180 | |
| 4181 | #ifndef MATCH_MAY_ALLOCATE |
| 4182 | /* Initialize the failure stack to the largest possible stack. This |
| 4183 | isn't necessary unless we're trying to avoid calling alloca in |
| 4184 | the search and match routines. */ |
| 4185 | { |
| 4186 | int num_regs = bufp->re_nsub + 1; |
| 4187 | |
| 4188 | /* Since DOUBLE_FAIL_STACK refuses to double only if the current size |
| 4189 | is strictly greater than re_max_failures, the largest possible stack |
| 4190 | is 2 * re_max_failures failure points. */ |
| 4191 | if (fail_stack.size < (2 * re_max_failures * MAX_FAILURE_ITEMS)) |
| 4192 | { |
| 4193 | fail_stack.size = (2 * re_max_failures * MAX_FAILURE_ITEMS); |
| 4194 | |
| 4195 | # ifdef emacs |
| 4196 | if (! fail_stack.stack) |
| 4197 | fail_stack.stack |
| 4198 | = (PREFIX(fail_stack_elt_t) *) xmalloc (fail_stack.size |
| 4199 | * sizeof (PREFIX(fail_stack_elt_t))); |
| 4200 | else |
| 4201 | fail_stack.stack |
| 4202 | = (PREFIX(fail_stack_elt_t) *) xrealloc (fail_stack.stack, |
| 4203 | (fail_stack.size |
| 4204 | * sizeof (PREFIX(fail_stack_elt_t)))); |
| 4205 | # else /* not emacs */ |
| 4206 | if (! fail_stack.stack) |
| 4207 | fail_stack.stack |
| 4208 | = (PREFIX(fail_stack_elt_t) *) malloc (fail_stack.size |
| 4209 | * sizeof (PREFIX(fail_stack_elt_t))); |
| 4210 | else |
| 4211 | fail_stack.stack |
| 4212 | = (PREFIX(fail_stack_elt_t) *) realloc (fail_stack.stack, |
| 4213 | (fail_stack.size |
| 4214 | * sizeof (PREFIX(fail_stack_elt_t)))); |
| 4215 | # endif /* not emacs */ |
| 4216 | } |
| 4217 | |
| 4218 | PREFIX(regex_grow_registers) (num_regs); |
| 4219 | } |
| 4220 | #endif /* not MATCH_MAY_ALLOCATE */ |
| 4221 | |
| 4222 | return REG_NOERROR; |
| 4223 | } /* regex_compile */ |
| 4224 | |
| 4225 | /* Subroutines for `regex_compile'. */ |
| 4226 | |
| 4227 | /* Store OP at LOC followed by two-byte integer parameter ARG. */ |
| 4228 | /* ifdef WCHAR, integer parameter is 1 wchar_t. */ |
| 4229 | |
| 4230 | static void |
| 4231 | PREFIX(store_op1) (re_opcode_t op, UCHAR_T *loc, int arg) |
| 4232 | { |
| 4233 | *loc = (UCHAR_T) op; |
| 4234 | STORE_NUMBER (loc + 1, arg); |
| 4235 | } |
| 4236 | |
| 4237 | |
| 4238 | /* Like `store_op1', but for two two-byte parameters ARG1 and ARG2. */ |
| 4239 | /* ifdef WCHAR, integer parameter is 1 wchar_t. */ |
| 4240 | |
| 4241 | static void |
| 4242 | PREFIX(store_op2) (re_opcode_t op, UCHAR_T *loc, int arg1, int arg2) |
| 4243 | { |
| 4244 | *loc = (UCHAR_T) op; |
| 4245 | STORE_NUMBER (loc + 1, arg1); |
| 4246 | STORE_NUMBER (loc + 1 + OFFSET_ADDRESS_SIZE, arg2); |
| 4247 | } |
| 4248 | |
| 4249 | |
| 4250 | /* Copy the bytes from LOC to END to open up three bytes of space at LOC |
| 4251 | for OP followed by two-byte integer parameter ARG. */ |
| 4252 | /* ifdef WCHAR, integer parameter is 1 wchar_t. */ |
| 4253 | |
| 4254 | static void |
| 4255 | PREFIX(insert_op1) (re_opcode_t op, UCHAR_T *loc, int arg, UCHAR_T *end) |
| 4256 | { |
| 4257 | register UCHAR_T *pfrom = end; |
| 4258 | register UCHAR_T *pto = end + 1 + OFFSET_ADDRESS_SIZE; |
| 4259 | |
| 4260 | while (pfrom != loc) |
| 4261 | *--pto = *--pfrom; |
| 4262 | |
| 4263 | PREFIX(store_op1) (op, loc, arg); |
| 4264 | } |
| 4265 | |
| 4266 | |
| 4267 | /* Like `insert_op1', but for two two-byte parameters ARG1 and ARG2. */ |
| 4268 | /* ifdef WCHAR, integer parameter is 1 wchar_t. */ |
| 4269 | |
| 4270 | static void |
| 4271 | PREFIX(insert_op2) (re_opcode_t op, UCHAR_T *loc, int arg1, |
| 4272 | int arg2, UCHAR_T *end) |
| 4273 | { |
| 4274 | register UCHAR_T *pfrom = end; |
| 4275 | register UCHAR_T *pto = end + 1 + 2 * OFFSET_ADDRESS_SIZE; |
| 4276 | |
| 4277 | while (pfrom != loc) |
| 4278 | *--pto = *--pfrom; |
| 4279 | |
| 4280 | PREFIX(store_op2) (op, loc, arg1, arg2); |
| 4281 | } |
| 4282 | |
| 4283 | |
| 4284 | /* P points to just after a ^ in PATTERN. Return true if that ^ comes |
| 4285 | after an alternative or a begin-subexpression. We assume there is at |
| 4286 | least one character before the ^. */ |
| 4287 | |
| 4288 | static boolean |
| 4289 | PREFIX(at_begline_loc_p) (const CHAR_T *pattern, const CHAR_T *p, |
| 4290 | reg_syntax_t syntax) |
| 4291 | { |
| 4292 | const CHAR_T *prev = p - 2; |
| 4293 | boolean prev_prev_backslash = prev > pattern && prev[-1] == '\\'; |
| 4294 | |
| 4295 | return |
| 4296 | /* After a subexpression? */ |
| 4297 | (*prev == '(' && (syntax & RE_NO_BK_PARENS || prev_prev_backslash)) |
| 4298 | /* After an alternative? */ |
| 4299 | || (*prev == '|' && (syntax & RE_NO_BK_VBAR || prev_prev_backslash)); |
| 4300 | } |
| 4301 | |
| 4302 | |
| 4303 | /* The dual of at_begline_loc_p. This one is for $. We assume there is |
| 4304 | at least one character after the $, i.e., `P < PEND'. */ |
| 4305 | |
| 4306 | static boolean |
| 4307 | PREFIX(at_endline_loc_p) (const CHAR_T *p, const CHAR_T *pend, |
| 4308 | reg_syntax_t syntax) |
| 4309 | { |
| 4310 | const CHAR_T *next = p; |
| 4311 | boolean next_backslash = *next == '\\'; |
| 4312 | const CHAR_T *next_next = p + 1 < pend ? p + 1 : 0; |
| 4313 | |
| 4314 | return |
| 4315 | /* Before a subexpression? */ |
| 4316 | (syntax & RE_NO_BK_PARENS ? *next == ')' |
| 4317 | : next_backslash && next_next && *next_next == ')') |
| 4318 | /* Before an alternative? */ |
| 4319 | || (syntax & RE_NO_BK_VBAR ? *next == '|' |
| 4320 | : next_backslash && next_next && *next_next == '|'); |
| 4321 | } |
| 4322 | |
| 4323 | #else /* not INSIDE_RECURSION */ |
| 4324 | |
| 4325 | /* Returns true if REGNUM is in one of COMPILE_STACK's elements and |
| 4326 | false if it's not. */ |
| 4327 | |
| 4328 | static boolean |
| 4329 | group_in_compile_stack (compile_stack_type compile_stack, regnum_t regnum) |
| 4330 | { |
| 4331 | int this_element; |
| 4332 | |
| 4333 | for (this_element = compile_stack.avail - 1; |
| 4334 | this_element >= 0; |
| 4335 | this_element--) |
| 4336 | if (compile_stack.stack[this_element].regnum == regnum) |
| 4337 | return true; |
| 4338 | |
| 4339 | return false; |
| 4340 | } |
| 4341 | #endif /* not INSIDE_RECURSION */ |
| 4342 | |
| 4343 | #ifdef INSIDE_RECURSION |
| 4344 | |
| 4345 | #ifdef WCHAR |
| 4346 | /* This insert space, which size is "num", into the pattern at "loc". |
| 4347 | "end" must point the end of the allocated buffer. */ |
| 4348 | static void |
| 4349 | insert_space (int num, CHAR_T *loc, CHAR_T *end) |
| 4350 | { |
| 4351 | register CHAR_T *pto = end; |
| 4352 | register CHAR_T *pfrom = end - num; |
| 4353 | |
| 4354 | while (pfrom >= loc) |
| 4355 | *pto-- = *pfrom--; |
| 4356 | } |
| 4357 | #endif /* WCHAR */ |
| 4358 | |
| 4359 | #ifdef WCHAR |
| 4360 | static reg_errcode_t |
| 4361 | wcs_compile_range (CHAR_T range_start_char, const CHAR_T **p_ptr, |
| 4362 | const CHAR_T *pend, RE_TRANSLATE_TYPE translate, |
| 4363 | reg_syntax_t syntax, CHAR_T *b, CHAR_T *char_set) |
| 4364 | { |
| 4365 | const CHAR_T *p = *p_ptr; |
| 4366 | CHAR_T range_start, range_end; |
| 4367 | reg_errcode_t ret; |
| 4368 | # ifdef _LIBC |
| 4369 | uint32_t nrules; |
| 4370 | uint32_t start_val, end_val; |
| 4371 | # endif |
| 4372 | if (p == pend) |
| 4373 | return REG_ERANGE; |
| 4374 | |
| 4375 | # ifdef _LIBC |
| 4376 | nrules = _NL_CURRENT_WORD (LC_COLLATE, _NL_COLLATE_NRULES); |
| 4377 | if (nrules != 0) |
| 4378 | { |
| 4379 | const char *collseq = (const char *) _NL_CURRENT(LC_COLLATE, |
| 4380 | _NL_COLLATE_COLLSEQWC); |
| 4381 | const unsigned char *extra = (const unsigned char *) |
| 4382 | _NL_CURRENT (LC_COLLATE, _NL_COLLATE_SYMB_EXTRAMB); |
| 4383 | |
| 4384 | if (range_start_char < -1) |
| 4385 | { |
| 4386 | /* range_start is a collating symbol. */ |
| 4387 | int32_t *wextra; |
| 4388 | /* Retreive the index and get collation sequence value. */ |
| 4389 | wextra = (int32_t*)(extra + char_set[-range_start_char]); |
| 4390 | start_val = wextra[1 + *wextra]; |
| 4391 | } |
| 4392 | else |
| 4393 | start_val = collseq_table_lookup(collseq, TRANSLATE(range_start_char)); |
| 4394 | |
| 4395 | end_val = collseq_table_lookup (collseq, TRANSLATE (p[0])); |
| 4396 | |
| 4397 | /* Report an error if the range is empty and the syntax prohibits |
| 4398 | this. */ |
| 4399 | ret = ((syntax & RE_NO_EMPTY_RANGES) |
| 4400 | && (start_val > end_val))? REG_ERANGE : REG_NOERROR; |
| 4401 | |
| 4402 | /* Insert space to the end of the char_ranges. */ |
| 4403 | insert_space(2, b - char_set[5] - 2, b - 1); |
| 4404 | *(b - char_set[5] - 2) = (wchar_t)start_val; |
| 4405 | *(b - char_set[5] - 1) = (wchar_t)end_val; |
| 4406 | char_set[4]++; /* ranges_index */ |
| 4407 | } |
| 4408 | else |
| 4409 | # endif |
| 4410 | { |
| 4411 | range_start = (range_start_char >= 0)? TRANSLATE (range_start_char): |
| 4412 | range_start_char; |
| 4413 | range_end = TRANSLATE (p[0]); |
| 4414 | /* Report an error if the range is empty and the syntax prohibits |
| 4415 | this. */ |
| 4416 | ret = ((syntax & RE_NO_EMPTY_RANGES) |
| 4417 | && (range_start > range_end))? REG_ERANGE : REG_NOERROR; |
| 4418 | |
| 4419 | /* Insert space to the end of the char_ranges. */ |
| 4420 | insert_space(2, b - char_set[5] - 2, b - 1); |
| 4421 | *(b - char_set[5] - 2) = range_start; |
| 4422 | *(b - char_set[5] - 1) = range_end; |
| 4423 | char_set[4]++; /* ranges_index */ |
| 4424 | } |
| 4425 | /* Have to increment the pointer into the pattern string, so the |
| 4426 | caller isn't still at the ending character. */ |
| 4427 | (*p_ptr)++; |
| 4428 | |
| 4429 | return ret; |
| 4430 | } |
| 4431 | #else /* BYTE */ |
| 4432 | /* Read the ending character of a range (in a bracket expression) from the |
| 4433 | uncompiled pattern *P_PTR (which ends at PEND). We assume the |
| 4434 | starting character is in `P[-2]'. (`P[-1]' is the character `-'.) |
| 4435 | Then we set the translation of all bits between the starting and |
| 4436 | ending characters (inclusive) in the compiled pattern B. |
| 4437 | |
| 4438 | Return an error code. |
| 4439 | |
| 4440 | We use these short variable names so we can use the same macros as |
| 4441 | `regex_compile' itself. */ |
| 4442 | |
| 4443 | static reg_errcode_t |
| 4444 | byte_compile_range (unsigned int range_start_char, const char **p_ptr, |
| 4445 | const char *pend, RE_TRANSLATE_TYPE translate, |
| 4446 | reg_syntax_t syntax, unsigned char *b) |
| 4447 | { |
| 4448 | unsigned this_char; |
| 4449 | const char *p = *p_ptr; |
| 4450 | reg_errcode_t ret; |
| 4451 | # if _LIBC |
| 4452 | const unsigned char *collseq; |
| 4453 | unsigned int start_colseq; |
| 4454 | unsigned int end_colseq; |
| 4455 | # else |
| 4456 | unsigned end_char; |
| 4457 | # endif |
| 4458 | |
| 4459 | if (p == pend) |
| 4460 | return REG_ERANGE; |
| 4461 | |
| 4462 | /* Have to increment the pointer into the pattern string, so the |
| 4463 | caller isn't still at the ending character. */ |
| 4464 | (*p_ptr)++; |
| 4465 | |
| 4466 | /* Report an error if the range is empty and the syntax prohibits this. */ |
| 4467 | ret = syntax & RE_NO_EMPTY_RANGES ? REG_ERANGE : REG_NOERROR; |
| 4468 | |
| 4469 | # if _LIBC |
| 4470 | collseq = (const unsigned char *) _NL_CURRENT (LC_COLLATE, |
| 4471 | _NL_COLLATE_COLLSEQMB); |
| 4472 | |
| 4473 | start_colseq = collseq[(unsigned char) TRANSLATE (range_start_char)]; |
| 4474 | end_colseq = collseq[(unsigned char) TRANSLATE (p[0])]; |
| 4475 | for (this_char = 0; this_char <= (unsigned char) -1; ++this_char) |
| 4476 | { |
| 4477 | unsigned int this_colseq = collseq[(unsigned char) TRANSLATE (this_char)]; |
| 4478 | |
| 4479 | if (start_colseq <= this_colseq && this_colseq <= end_colseq) |
| 4480 | { |
| 4481 | SET_LIST_BIT (TRANSLATE (this_char)); |
| 4482 | ret = REG_NOERROR; |
| 4483 | } |
| 4484 | } |
| 4485 | # else |
| 4486 | /* Here we see why `this_char' has to be larger than an `unsigned |
| 4487 | char' -- we would otherwise go into an infinite loop, since all |
| 4488 | characters <= 0xff. */ |
| 4489 | range_start_char = TRANSLATE (range_start_char); |
| 4490 | /* TRANSLATE(p[0]) is casted to char (not unsigned char) in TRANSLATE, |
| 4491 | and some compilers cast it to int implicitly, so following for_loop |
| 4492 | may fall to (almost) infinite loop. |
| 4493 | e.g. If translate[p[0]] = 0xff, end_char may equals to 0xffffffff. |
| 4494 | To avoid this, we cast p[0] to unsigned int and truncate it. */ |
| 4495 | end_char = ((unsigned)TRANSLATE(p[0]) & ((1 << BYTEWIDTH) - 1)); |
| 4496 | |
| 4497 | for (this_char = range_start_char; this_char <= end_char; ++this_char) |
| 4498 | { |
| 4499 | SET_LIST_BIT (TRANSLATE (this_char)); |
| 4500 | ret = REG_NOERROR; |
| 4501 | } |
| 4502 | # endif |
| 4503 | |
| 4504 | return ret; |
| 4505 | } |
| 4506 | #endif /* WCHAR */ |
| 4507 | \f |
| 4508 | /* re_compile_fastmap computes a ``fastmap'' for the compiled pattern in |
| 4509 | BUFP. A fastmap records which of the (1 << BYTEWIDTH) possible |
| 4510 | characters can start a string that matches the pattern. This fastmap |
| 4511 | is used by re_search to skip quickly over impossible starting points. |
| 4512 | |
| 4513 | The caller must supply the address of a (1 << BYTEWIDTH)-byte data |
| 4514 | area as BUFP->fastmap. |
| 4515 | |
| 4516 | We set the `fastmap', `fastmap_accurate', and `can_be_null' fields in |
| 4517 | the pattern buffer. |
| 4518 | |
| 4519 | Returns 0 if we succeed, -2 if an internal error. */ |
| 4520 | |
| 4521 | #ifdef WCHAR |
| 4522 | /* local function for re_compile_fastmap. |
| 4523 | truncate wchar_t character to char. */ |
| 4524 | static unsigned char truncate_wchar (CHAR_T c); |
| 4525 | |
| 4526 | static unsigned char |
| 4527 | truncate_wchar (CHAR_T c) |
| 4528 | { |
| 4529 | unsigned char buf[MB_CUR_MAX]; |
| 4530 | mbstate_t state; |
| 4531 | int retval; |
| 4532 | memset (&state, '\0', sizeof (state)); |
| 4533 | # ifdef _LIBC |
| 4534 | retval = __wcrtomb (buf, c, &state); |
| 4535 | # else |
| 4536 | retval = wcrtomb (buf, c, &state); |
| 4537 | # endif |
| 4538 | return retval > 0 ? buf[0] : (unsigned char) c; |
| 4539 | } |
| 4540 | #endif /* WCHAR */ |
| 4541 | |
| 4542 | static int |
| 4543 | PREFIX(re_compile_fastmap) (struct re_pattern_buffer *bufp) |
| 4544 | { |
| 4545 | int j, k; |
| 4546 | #ifdef MATCH_MAY_ALLOCATE |
| 4547 | PREFIX(fail_stack_type) fail_stack; |
| 4548 | #endif |
| 4549 | #ifndef REGEX_MALLOC |
| 4550 | char *destination; |
| 4551 | #endif |
| 4552 | |
| 4553 | register char *fastmap = bufp->fastmap; |
| 4554 | |
| 4555 | #ifdef WCHAR |
| 4556 | /* We need to cast pattern to (wchar_t*), because we casted this compiled |
| 4557 | pattern to (char*) in regex_compile. */ |
| 4558 | UCHAR_T *pattern = (UCHAR_T*)bufp->buffer; |
| 4559 | register UCHAR_T *pend = (UCHAR_T*) (bufp->buffer + bufp->used); |
| 4560 | #else /* BYTE */ |
| 4561 | UCHAR_T *pattern = bufp->buffer; |
| 4562 | register UCHAR_T *pend = pattern + bufp->used; |
| 4563 | #endif /* WCHAR */ |
| 4564 | UCHAR_T *p = pattern; |
| 4565 | |
| 4566 | #ifdef REL_ALLOC |
| 4567 | /* This holds the pointer to the failure stack, when |
| 4568 | it is allocated relocatably. */ |
| 4569 | fail_stack_elt_t *failure_stack_ptr; |
| 4570 | #endif |
| 4571 | |
| 4572 | /* Assume that each path through the pattern can be null until |
| 4573 | proven otherwise. We set this false at the bottom of switch |
| 4574 | statement, to which we get only if a particular path doesn't |
| 4575 | match the empty string. */ |
| 4576 | boolean path_can_be_null = true; |
| 4577 | |
| 4578 | /* We aren't doing a `succeed_n' to begin with. */ |
| 4579 | boolean succeed_n_p = false; |
| 4580 | |
| 4581 | assert (fastmap != NULL && p != NULL); |
| 4582 | |
| 4583 | INIT_FAIL_STACK (); |
| 4584 | bzero (fastmap, 1 << BYTEWIDTH); /* Assume nothing's valid. */ |
| 4585 | bufp->fastmap_accurate = 1; /* It will be when we're done. */ |
| 4586 | bufp->can_be_null = 0; |
| 4587 | |
| 4588 | while (1) |
| 4589 | { |
| 4590 | if (p == pend || *p == (UCHAR_T) succeed) |
| 4591 | { |
| 4592 | /* We have reached the (effective) end of pattern. */ |
| 4593 | if (!FAIL_STACK_EMPTY ()) |
| 4594 | { |
| 4595 | bufp->can_be_null |= path_can_be_null; |
| 4596 | |
| 4597 | /* Reset for next path. */ |
| 4598 | path_can_be_null = true; |
| 4599 | |
| 4600 | p = fail_stack.stack[--fail_stack.avail].pointer; |
| 4601 | |
| 4602 | continue; |
| 4603 | } |
| 4604 | else |
| 4605 | break; |
| 4606 | } |
| 4607 | |
| 4608 | /* We should never be about to go beyond the end of the pattern. */ |
| 4609 | assert (p < pend); |
| 4610 | |
| 4611 | switch (SWITCH_ENUM_CAST ((re_opcode_t) *p++)) |
| 4612 | { |
| 4613 | |
| 4614 | /* I guess the idea here is to simply not bother with a fastmap |
| 4615 | if a backreference is used, since it's too hard to figure out |
| 4616 | the fastmap for the corresponding group. Setting |
| 4617 | `can_be_null' stops `re_search_2' from using the fastmap, so |
| 4618 | that is all we do. */ |
| 4619 | case duplicate: |
| 4620 | bufp->can_be_null = 1; |
| 4621 | goto done; |
| 4622 | |
| 4623 | |
| 4624 | /* Following are the cases which match a character. These end |
| 4625 | with `break'. */ |
| 4626 | |
| 4627 | #ifdef WCHAR |
| 4628 | case exactn: |
| 4629 | fastmap[truncate_wchar(p[1])] = 1; |
| 4630 | break; |
| 4631 | #else /* BYTE */ |
| 4632 | case exactn: |
| 4633 | fastmap[p[1]] = 1; |
| 4634 | break; |
| 4635 | #endif /* WCHAR */ |
| 4636 | #ifdef MBS_SUPPORT |
| 4637 | case exactn_bin: |
| 4638 | fastmap[p[1]] = 1; |
| 4639 | break; |
| 4640 | #endif |
| 4641 | |
| 4642 | #ifdef WCHAR |
| 4643 | /* It is hard to distinguish fastmap from (multi byte) characters |
| 4644 | which depends on current locale. */ |
| 4645 | case charset: |
| 4646 | case charset_not: |
| 4647 | case wordchar: |
| 4648 | case notwordchar: |
| 4649 | bufp->can_be_null = 1; |
| 4650 | goto done; |
| 4651 | #else /* BYTE */ |
| 4652 | case charset: |
| 4653 | for (j = *p++ * BYTEWIDTH - 1; j >= 0; j--) |
| 4654 | if (p[j / BYTEWIDTH] & (1 << (j % BYTEWIDTH))) |
| 4655 | fastmap[j] = 1; |
| 4656 | break; |
| 4657 | |
| 4658 | |
| 4659 | case charset_not: |
| 4660 | /* Chars beyond end of map must be allowed. */ |
| 4661 | for (j = *p * BYTEWIDTH; j < (1 << BYTEWIDTH); j++) |
| 4662 | fastmap[j] = 1; |
| 4663 | |
| 4664 | for (j = *p++ * BYTEWIDTH - 1; j >= 0; j--) |
| 4665 | if (!(p[j / BYTEWIDTH] & (1 << (j % BYTEWIDTH)))) |
| 4666 | fastmap[j] = 1; |
| 4667 | break; |
| 4668 | |
| 4669 | |
| 4670 | case wordchar: |
| 4671 | for (j = 0; j < (1 << BYTEWIDTH); j++) |
| 4672 | if (SYNTAX (j) == Sword) |
| 4673 | fastmap[j] = 1; |
| 4674 | break; |
| 4675 | |
| 4676 | |
| 4677 | case notwordchar: |
| 4678 | for (j = 0; j < (1 << BYTEWIDTH); j++) |
| 4679 | if (SYNTAX (j) != Sword) |
| 4680 | fastmap[j] = 1; |
| 4681 | break; |
| 4682 | #endif /* WCHAR */ |
| 4683 | |
| 4684 | case anychar: |
| 4685 | { |
| 4686 | int fastmap_newline = fastmap['\n']; |
| 4687 | |
| 4688 | /* `.' matches anything ... */ |
| 4689 | for (j = 0; j < (1 << BYTEWIDTH); j++) |
| 4690 | fastmap[j] = 1; |
| 4691 | |
| 4692 | /* ... except perhaps newline. */ |
| 4693 | if (!(bufp->syntax & RE_DOT_NEWLINE)) |
| 4694 | fastmap['\n'] = fastmap_newline; |
| 4695 | |
| 4696 | /* Return if we have already set `can_be_null'; if we have, |
| 4697 | then the fastmap is irrelevant. Something's wrong here. */ |
| 4698 | else if (bufp->can_be_null) |
| 4699 | goto done; |
| 4700 | |
| 4701 | /* Otherwise, have to check alternative paths. */ |
| 4702 | break; |
| 4703 | } |
| 4704 | |
| 4705 | #ifdef emacs |
| 4706 | case syntaxspec: |
| 4707 | k = *p++; |
| 4708 | for (j = 0; j < (1 << BYTEWIDTH); j++) |
| 4709 | if (SYNTAX (j) == (enum syntaxcode) k) |
| 4710 | fastmap[j] = 1; |
| 4711 | break; |
| 4712 | |
| 4713 | |
| 4714 | case notsyntaxspec: |
| 4715 | k = *p++; |
| 4716 | for (j = 0; j < (1 << BYTEWIDTH); j++) |
| 4717 | if (SYNTAX (j) != (enum syntaxcode) k) |
| 4718 | fastmap[j] = 1; |
| 4719 | break; |
| 4720 | |
| 4721 | |
| 4722 | /* All cases after this match the empty string. These end with |
| 4723 | `continue'. */ |
| 4724 | |
| 4725 | |
| 4726 | case before_dot: |
| 4727 | case at_dot: |
| 4728 | case after_dot: |
| 4729 | continue; |
| 4730 | #endif /* emacs */ |
| 4731 | |
| 4732 | |
| 4733 | case no_op: |
| 4734 | case begline: |
| 4735 | case endline: |
| 4736 | case begbuf: |
| 4737 | case endbuf: |
| 4738 | case wordbound: |
| 4739 | case notwordbound: |
| 4740 | case wordbeg: |
| 4741 | case wordend: |
| 4742 | case push_dummy_failure: |
| 4743 | continue; |
| 4744 | |
| 4745 | |
| 4746 | case jump_n: |
| 4747 | case pop_failure_jump: |
| 4748 | case maybe_pop_jump: |
| 4749 | case jump: |
| 4750 | case jump_past_alt: |
| 4751 | case dummy_failure_jump: |
| 4752 | EXTRACT_NUMBER_AND_INCR (j, p); |
| 4753 | p += j; |
| 4754 | if (j > 0) |
| 4755 | continue; |
| 4756 | |
| 4757 | /* Jump backward implies we just went through the body of a |
| 4758 | loop and matched nothing. Opcode jumped to should be |
| 4759 | `on_failure_jump' or `succeed_n'. Just treat it like an |
| 4760 | ordinary jump. For a * loop, it has pushed its failure |
| 4761 | point already; if so, discard that as redundant. */ |
| 4762 | if ((re_opcode_t) *p != on_failure_jump |
| 4763 | && (re_opcode_t) *p != succeed_n) |
| 4764 | continue; |
| 4765 | |
| 4766 | p++; |
| 4767 | EXTRACT_NUMBER_AND_INCR (j, p); |
| 4768 | p += j; |
| 4769 | |
| 4770 | /* If what's on the stack is where we are now, pop it. */ |
| 4771 | if (!FAIL_STACK_EMPTY () |
| 4772 | && fail_stack.stack[fail_stack.avail - 1].pointer == p) |
| 4773 | fail_stack.avail--; |
| 4774 | |
| 4775 | continue; |
| 4776 | |
| 4777 | |
| 4778 | case on_failure_jump: |
| 4779 | case on_failure_keep_string_jump: |
| 4780 | handle_on_failure_jump: |
| 4781 | EXTRACT_NUMBER_AND_INCR (j, p); |
| 4782 | |
| 4783 | /* For some patterns, e.g., `(a?)?', `p+j' here points to the |
| 4784 | end of the pattern. We don't want to push such a point, |
| 4785 | since when we restore it above, entering the switch will |
| 4786 | increment `p' past the end of the pattern. We don't need |
| 4787 | to push such a point since we obviously won't find any more |
| 4788 | fastmap entries beyond `pend'. Such a pattern can match |
| 4789 | the null string, though. */ |
| 4790 | if (p + j < pend) |
| 4791 | { |
| 4792 | if (!PUSH_PATTERN_OP (p + j, fail_stack)) |
| 4793 | { |
| 4794 | RESET_FAIL_STACK (); |
| 4795 | return -2; |
| 4796 | } |
| 4797 | } |
| 4798 | else |
| 4799 | bufp->can_be_null = 1; |
| 4800 | |
| 4801 | if (succeed_n_p) |
| 4802 | { |
| 4803 | EXTRACT_NUMBER_AND_INCR (k, p); /* Skip the n. */ |
| 4804 | succeed_n_p = false; |
| 4805 | } |
| 4806 | |
| 4807 | continue; |
| 4808 | |
| 4809 | |
| 4810 | case succeed_n: |
| 4811 | /* Get to the number of times to succeed. */ |
| 4812 | p += OFFSET_ADDRESS_SIZE; |
| 4813 | |
| 4814 | /* Increment p past the n for when k != 0. */ |
| 4815 | EXTRACT_NUMBER_AND_INCR (k, p); |
| 4816 | if (k == 0) |
| 4817 | { |
| 4818 | p -= 2 * OFFSET_ADDRESS_SIZE; |
| 4819 | succeed_n_p = true; /* Spaghetti code alert. */ |
| 4820 | goto handle_on_failure_jump; |
| 4821 | } |
| 4822 | continue; |
| 4823 | |
| 4824 | |
| 4825 | case set_number_at: |
| 4826 | p += 2 * OFFSET_ADDRESS_SIZE; |
| 4827 | continue; |
| 4828 | |
| 4829 | |
| 4830 | case start_memory: |
| 4831 | case stop_memory: |
| 4832 | p += 2; |
| 4833 | continue; |
| 4834 | |
| 4835 | |
| 4836 | default: |
| 4837 | abort (); /* We have listed all the cases. */ |
| 4838 | } /* switch *p++ */ |
| 4839 | |
| 4840 | /* Getting here means we have found the possible starting |
| 4841 | characters for one path of the pattern -- and that the empty |
| 4842 | string does not match. We need not follow this path further. |
| 4843 | Instead, look at the next alternative (remembered on the |
| 4844 | stack), or quit if no more. The test at the top of the loop |
| 4845 | does these things. */ |
| 4846 | path_can_be_null = false; |
| 4847 | p = pend; |
| 4848 | } /* while p */ |
| 4849 | |
| 4850 | /* Set `can_be_null' for the last path (also the first path, if the |
| 4851 | pattern is empty). */ |
| 4852 | bufp->can_be_null |= path_can_be_null; |
| 4853 | |
| 4854 | done: |
| 4855 | RESET_FAIL_STACK (); |
| 4856 | return 0; |
| 4857 | } |
| 4858 | |
| 4859 | #else /* not INSIDE_RECURSION */ |
| 4860 | |
| 4861 | int |
| 4862 | re_compile_fastmap (struct re_pattern_buffer *bufp) |
| 4863 | { |
| 4864 | # ifdef MBS_SUPPORT |
| 4865 | if (MB_CUR_MAX != 1) |
| 4866 | return wcs_re_compile_fastmap(bufp); |
| 4867 | else |
| 4868 | # endif |
| 4869 | return byte_re_compile_fastmap(bufp); |
| 4870 | } /* re_compile_fastmap */ |
| 4871 | #ifdef _LIBC |
| 4872 | weak_alias (__re_compile_fastmap, re_compile_fastmap) |
| 4873 | #endif |
| 4874 | \f |
| 4875 | |
| 4876 | /* Set REGS to hold NUM_REGS registers, storing them in STARTS and |
| 4877 | ENDS. Subsequent matches using PATTERN_BUFFER and REGS will use |
| 4878 | this memory for recording register information. STARTS and ENDS |
| 4879 | must be allocated using the malloc library routine, and must each |
| 4880 | be at least NUM_REGS * sizeof (regoff_t) bytes long. |
| 4881 | |
| 4882 | If NUM_REGS == 0, then subsequent matches should allocate their own |
| 4883 | register data. |
| 4884 | |
| 4885 | Unless this function is called, the first search or match using |
| 4886 | PATTERN_BUFFER will allocate its own register data, without |
| 4887 | freeing the old data. */ |
| 4888 | |
| 4889 | void |
| 4890 | re_set_registers (struct re_pattern_buffer *bufp, |
| 4891 | struct re_registers *regs, unsigned num_regs, |
| 4892 | regoff_t *starts, regoff_t *ends) |
| 4893 | { |
| 4894 | if (num_regs) |
| 4895 | { |
| 4896 | bufp->regs_allocated = REGS_REALLOCATE; |
| 4897 | regs->num_regs = num_regs; |
| 4898 | regs->start = starts; |
| 4899 | regs->end = ends; |
| 4900 | } |
| 4901 | else |
| 4902 | { |
| 4903 | bufp->regs_allocated = REGS_UNALLOCATED; |
| 4904 | regs->num_regs = 0; |
| 4905 | regs->start = regs->end = (regoff_t *) 0; |
| 4906 | } |
| 4907 | } |
| 4908 | #ifdef _LIBC |
| 4909 | weak_alias (__re_set_registers, re_set_registers) |
| 4910 | #endif |
| 4911 | \f |
| 4912 | /* Searching routines. */ |
| 4913 | |
| 4914 | /* Like re_search_2, below, but only one string is specified, and |
| 4915 | doesn't let you say where to stop matching. */ |
| 4916 | |
| 4917 | int |
| 4918 | re_search (struct re_pattern_buffer *bufp, const char *string, int size, |
| 4919 | int startpos, int range, struct re_registers *regs) |
| 4920 | { |
| 4921 | return re_search_2 (bufp, NULL, 0, string, size, startpos, range, |
| 4922 | regs, size); |
| 4923 | } |
| 4924 | #ifdef _LIBC |
| 4925 | weak_alias (__re_search, re_search) |
| 4926 | #endif |
| 4927 | |
| 4928 | |
| 4929 | /* Using the compiled pattern in BUFP->buffer, first tries to match the |
| 4930 | virtual concatenation of STRING1 and STRING2, starting first at index |
| 4931 | STARTPOS, then at STARTPOS + 1, and so on. |
| 4932 | |
| 4933 | STRING1 and STRING2 have length SIZE1 and SIZE2, respectively. |
| 4934 | |
| 4935 | RANGE is how far to scan while trying to match. RANGE = 0 means try |
| 4936 | only at STARTPOS; in general, the last start tried is STARTPOS + |
| 4937 | RANGE. |
| 4938 | |
| 4939 | In REGS, return the indices of the virtual concatenation of STRING1 |
| 4940 | and STRING2 that matched the entire BUFP->buffer and its contained |
| 4941 | subexpressions. |
| 4942 | |
| 4943 | Do not consider matching one past the index STOP in the virtual |
| 4944 | concatenation of STRING1 and STRING2. |
| 4945 | |
| 4946 | We return either the position in the strings at which the match was |
| 4947 | found, -1 if no match, or -2 if error (such as failure |
| 4948 | stack overflow). */ |
| 4949 | |
| 4950 | int |
| 4951 | re_search_2 (struct re_pattern_buffer *bufp, const char *string1, int size1, |
| 4952 | const char *string2, int size2, int startpos, int range, |
| 4953 | struct re_registers *regs, int stop) |
| 4954 | { |
| 4955 | # ifdef MBS_SUPPORT |
| 4956 | if (MB_CUR_MAX != 1) |
| 4957 | return wcs_re_search_2 (bufp, string1, size1, string2, size2, startpos, |
| 4958 | range, regs, stop); |
| 4959 | else |
| 4960 | # endif |
| 4961 | return byte_re_search_2 (bufp, string1, size1, string2, size2, startpos, |
| 4962 | range, regs, stop); |
| 4963 | } /* re_search_2 */ |
| 4964 | #ifdef _LIBC |
| 4965 | weak_alias (__re_search_2, re_search_2) |
| 4966 | #endif |
| 4967 | |
| 4968 | #endif /* not INSIDE_RECURSION */ |
| 4969 | |
| 4970 | #ifdef INSIDE_RECURSION |
| 4971 | |
| 4972 | #ifdef MATCH_MAY_ALLOCATE |
| 4973 | # define FREE_VAR(var) if (var) REGEX_FREE (var); var = NULL |
| 4974 | #else |
| 4975 | # define FREE_VAR(var) free (var); var = NULL |
| 4976 | #endif |
| 4977 | |
| 4978 | #ifdef WCHAR |
| 4979 | # define MAX_ALLOCA_SIZE 2000 |
| 4980 | |
| 4981 | # define FREE_WCS_BUFFERS() \ |
| 4982 | do { \ |
| 4983 | if (size1 > MAX_ALLOCA_SIZE) \ |
| 4984 | { \ |
| 4985 | free (wcs_string1); \ |
| 4986 | free (mbs_offset1); \ |
| 4987 | } \ |
| 4988 | else \ |
| 4989 | { \ |
| 4990 | FREE_VAR (wcs_string1); \ |
| 4991 | FREE_VAR (mbs_offset1); \ |
| 4992 | } \ |
| 4993 | if (size2 > MAX_ALLOCA_SIZE) \ |
| 4994 | { \ |
| 4995 | free (wcs_string2); \ |
| 4996 | free (mbs_offset2); \ |
| 4997 | } \ |
| 4998 | else \ |
| 4999 | { \ |
| 5000 | FREE_VAR (wcs_string2); \ |
| 5001 | FREE_VAR (mbs_offset2); \ |
| 5002 | } \ |
| 5003 | } while (0) |
| 5004 | |
| 5005 | #endif |
| 5006 | |
| 5007 | |
| 5008 | static int |
| 5009 | PREFIX(re_search_2) (struct re_pattern_buffer *bufp, const char *string1, |
| 5010 | int size1, const char *string2, int size2, |
| 5011 | int startpos, int range, |
| 5012 | struct re_registers *regs, int stop) |
| 5013 | { |
| 5014 | int val; |
| 5015 | register char *fastmap = bufp->fastmap; |
| 5016 | register RE_TRANSLATE_TYPE translate = bufp->translate; |
| 5017 | int total_size = size1 + size2; |
| 5018 | int endpos = startpos + range; |
| 5019 | #ifdef WCHAR |
| 5020 | /* We need wchar_t* buffers correspond to cstring1, cstring2. */ |
| 5021 | wchar_t *wcs_string1 = NULL, *wcs_string2 = NULL; |
| 5022 | /* We need the size of wchar_t buffers correspond to csize1, csize2. */ |
| 5023 | int wcs_size1 = 0, wcs_size2 = 0; |
| 5024 | /* offset buffer for optimizatoin. See convert_mbs_to_wc. */ |
| 5025 | int *mbs_offset1 = NULL, *mbs_offset2 = NULL; |
| 5026 | /* They hold whether each wchar_t is binary data or not. */ |
| 5027 | char *is_binary = NULL; |
| 5028 | #endif /* WCHAR */ |
| 5029 | |
| 5030 | /* Check for out-of-range STARTPOS. */ |
| 5031 | if (startpos < 0 || startpos > total_size) |
| 5032 | return -1; |
| 5033 | |
| 5034 | /* Fix up RANGE if it might eventually take us outside |
| 5035 | the virtual concatenation of STRING1 and STRING2. |
| 5036 | Make sure we won't move STARTPOS below 0 or above TOTAL_SIZE. */ |
| 5037 | if (endpos < 0) |
| 5038 | range = 0 - startpos; |
| 5039 | else if (endpos > total_size) |
| 5040 | range = total_size - startpos; |
| 5041 | |
| 5042 | /* If the search isn't to be a backwards one, don't waste time in a |
| 5043 | search for a pattern that must be anchored. */ |
| 5044 | if (bufp->used > 0 && range > 0 |
| 5045 | && ((re_opcode_t) bufp->buffer[0] == begbuf |
| 5046 | /* `begline' is like `begbuf' if it cannot match at newlines. */ |
| 5047 | || ((re_opcode_t) bufp->buffer[0] == begline |
| 5048 | && !bufp->newline_anchor))) |
| 5049 | { |
| 5050 | if (startpos > 0) |
| 5051 | return -1; |
| 5052 | else |
| 5053 | range = 1; |
| 5054 | } |
| 5055 | |
| 5056 | #ifdef emacs |
| 5057 | /* In a forward search for something that starts with \=. |
| 5058 | don't keep searching past point. */ |
| 5059 | if (bufp->used > 0 && (re_opcode_t) bufp->buffer[0] == at_dot && range > 0) |
| 5060 | { |
| 5061 | range = PT - startpos; |
| 5062 | if (range <= 0) |
| 5063 | return -1; |
| 5064 | } |
| 5065 | #endif /* emacs */ |
| 5066 | |
| 5067 | /* Update the fastmap now if not correct already. */ |
| 5068 | if (fastmap && !bufp->fastmap_accurate) |
| 5069 | if (re_compile_fastmap (bufp) == -2) |
| 5070 | return -2; |
| 5071 | |
| 5072 | #ifdef WCHAR |
| 5073 | /* Allocate wchar_t array for wcs_string1 and wcs_string2 and |
| 5074 | fill them with converted string. */ |
| 5075 | if (size1 != 0) |
| 5076 | { |
| 5077 | if (size1 > MAX_ALLOCA_SIZE) |
| 5078 | { |
| 5079 | wcs_string1 = TALLOC (size1 + 1, CHAR_T); |
| 5080 | mbs_offset1 = TALLOC (size1 + 1, int); |
| 5081 | is_binary = TALLOC (size1 + 1, char); |
| 5082 | } |
| 5083 | else |
| 5084 | { |
| 5085 | wcs_string1 = REGEX_TALLOC (size1 + 1, CHAR_T); |
| 5086 | mbs_offset1 = REGEX_TALLOC (size1 + 1, int); |
| 5087 | is_binary = REGEX_TALLOC (size1 + 1, char); |
| 5088 | } |
| 5089 | if (!wcs_string1 || !mbs_offset1 || !is_binary) |
| 5090 | { |
| 5091 | if (size1 > MAX_ALLOCA_SIZE) |
| 5092 | { |
| 5093 | free (wcs_string1); |
| 5094 | free (mbs_offset1); |
| 5095 | free (is_binary); |
| 5096 | } |
| 5097 | else |
| 5098 | { |
| 5099 | FREE_VAR (wcs_string1); |
| 5100 | FREE_VAR (mbs_offset1); |
| 5101 | FREE_VAR (is_binary); |
| 5102 | } |
| 5103 | return -2; |
| 5104 | } |
| 5105 | wcs_size1 = convert_mbs_to_wcs(wcs_string1, string1, size1, |
| 5106 | mbs_offset1, is_binary); |
| 5107 | wcs_string1[wcs_size1] = L'\0'; /* for a sentinel */ |
| 5108 | if (size1 > MAX_ALLOCA_SIZE) |
| 5109 | free (is_binary); |
| 5110 | else |
| 5111 | FREE_VAR (is_binary); |
| 5112 | } |
| 5113 | if (size2 != 0) |
| 5114 | { |
| 5115 | if (size2 > MAX_ALLOCA_SIZE) |
| 5116 | { |
| 5117 | wcs_string2 = TALLOC (size2 + 1, CHAR_T); |
| 5118 | mbs_offset2 = TALLOC (size2 + 1, int); |
| 5119 | is_binary = TALLOC (size2 + 1, char); |
| 5120 | } |
| 5121 | else |
| 5122 | { |
| 5123 | wcs_string2 = REGEX_TALLOC (size2 + 1, CHAR_T); |
| 5124 | mbs_offset2 = REGEX_TALLOC (size2 + 1, int); |
| 5125 | is_binary = REGEX_TALLOC (size2 + 1, char); |
| 5126 | } |
| 5127 | if (!wcs_string2 || !mbs_offset2 || !is_binary) |
| 5128 | { |
| 5129 | FREE_WCS_BUFFERS (); |
| 5130 | if (size2 > MAX_ALLOCA_SIZE) |
| 5131 | free (is_binary); |
| 5132 | else |
| 5133 | FREE_VAR (is_binary); |
| 5134 | return -2; |
| 5135 | } |
| 5136 | wcs_size2 = convert_mbs_to_wcs(wcs_string2, string2, size2, |
| 5137 | mbs_offset2, is_binary); |
| 5138 | wcs_string2[wcs_size2] = L'\0'; /* for a sentinel */ |
| 5139 | if (size2 > MAX_ALLOCA_SIZE) |
| 5140 | free (is_binary); |
| 5141 | else |
| 5142 | FREE_VAR (is_binary); |
| 5143 | } |
| 5144 | #endif /* WCHAR */ |
| 5145 | |
| 5146 | |
| 5147 | /* Loop through the string, looking for a place to start matching. */ |
| 5148 | for (;;) |
| 5149 | { |
| 5150 | /* If a fastmap is supplied, skip quickly over characters that |
| 5151 | cannot be the start of a match. If the pattern can match the |
| 5152 | null string, however, we don't need to skip characters; we want |
| 5153 | the first null string. */ |
| 5154 | if (fastmap && startpos < total_size && !bufp->can_be_null) |
| 5155 | { |
| 5156 | if (range > 0) /* Searching forwards. */ |
| 5157 | { |
| 5158 | register const char *d; |
| 5159 | register int lim = 0; |
| 5160 | int irange = range; |
| 5161 | |
| 5162 | if (startpos < size1 && startpos + range >= size1) |
| 5163 | lim = range - (size1 - startpos); |
| 5164 | |
| 5165 | d = (startpos >= size1 ? string2 - size1 : string1) + startpos; |
| 5166 | |
| 5167 | /* Written out as an if-else to avoid testing `translate' |
| 5168 | inside the loop. */ |
| 5169 | if (translate) |
| 5170 | while (range > lim |
| 5171 | && !fastmap[(unsigned char) |
| 5172 | translate[(unsigned char) *d++]]) |
| 5173 | range--; |
| 5174 | else |
| 5175 | while (range > lim && !fastmap[(unsigned char) *d++]) |
| 5176 | range--; |
| 5177 | |
| 5178 | startpos += irange - range; |
| 5179 | } |
| 5180 | else /* Searching backwards. */ |
| 5181 | { |
| 5182 | register CHAR_T c = (size1 == 0 || startpos >= size1 |
| 5183 | ? string2[startpos - size1] |
| 5184 | : string1[startpos]); |
| 5185 | |
| 5186 | if (!fastmap[(unsigned char) TRANSLATE (c)]) |
| 5187 | goto advance; |
| 5188 | } |
| 5189 | } |
| 5190 | |
| 5191 | /* If can't match the null string, and that's all we have left, fail. */ |
| 5192 | if (range >= 0 && startpos == total_size && fastmap |
| 5193 | && !bufp->can_be_null) |
| 5194 | { |
| 5195 | #ifdef WCHAR |
| 5196 | FREE_WCS_BUFFERS (); |
| 5197 | #endif |
| 5198 | return -1; |
| 5199 | } |
| 5200 | |
| 5201 | #ifdef WCHAR |
| 5202 | val = wcs_re_match_2_internal (bufp, string1, size1, string2, |
| 5203 | size2, startpos, regs, stop, |
| 5204 | wcs_string1, wcs_size1, |
| 5205 | wcs_string2, wcs_size2, |
| 5206 | mbs_offset1, mbs_offset2); |
| 5207 | #else /* BYTE */ |
| 5208 | val = byte_re_match_2_internal (bufp, string1, size1, string2, |
| 5209 | size2, startpos, regs, stop); |
| 5210 | #endif /* BYTE */ |
| 5211 | |
| 5212 | #ifndef REGEX_MALLOC |
| 5213 | # ifdef C_ALLOCA |
| 5214 | alloca (0); |
| 5215 | # endif |
| 5216 | #endif |
| 5217 | |
| 5218 | if (val >= 0) |
| 5219 | { |
| 5220 | #ifdef WCHAR |
| 5221 | FREE_WCS_BUFFERS (); |
| 5222 | #endif |
| 5223 | return startpos; |
| 5224 | } |
| 5225 | |
| 5226 | if (val == -2) |
| 5227 | { |
| 5228 | #ifdef WCHAR |
| 5229 | FREE_WCS_BUFFERS (); |
| 5230 | #endif |
| 5231 | return -2; |
| 5232 | } |
| 5233 | |
| 5234 | advance: |
| 5235 | if (!range) |
| 5236 | break; |
| 5237 | else if (range > 0) |
| 5238 | { |
| 5239 | range--; |
| 5240 | startpos++; |
| 5241 | } |
| 5242 | else |
| 5243 | { |
| 5244 | range++; |
| 5245 | startpos--; |
| 5246 | } |
| 5247 | } |
| 5248 | #ifdef WCHAR |
| 5249 | FREE_WCS_BUFFERS (); |
| 5250 | #endif |
| 5251 | return -1; |
| 5252 | } |
| 5253 | |
| 5254 | #ifdef WCHAR |
| 5255 | /* This converts PTR, a pointer into one of the search wchar_t strings |
| 5256 | `string1' and `string2' into an multibyte string offset from the |
| 5257 | beginning of that string. We use mbs_offset to optimize. |
| 5258 | See convert_mbs_to_wcs. */ |
| 5259 | # define POINTER_TO_OFFSET(ptr) \ |
| 5260 | (FIRST_STRING_P (ptr) \ |
| 5261 | ? ((regoff_t)(mbs_offset1 != NULL? mbs_offset1[(ptr)-string1] : 0)) \ |
| 5262 | : ((regoff_t)((mbs_offset2 != NULL? mbs_offset2[(ptr)-string2] : 0) \ |
| 5263 | + csize1))) |
| 5264 | #else /* BYTE */ |
| 5265 | /* This converts PTR, a pointer into one of the search strings `string1' |
| 5266 | and `string2' into an offset from the beginning of that string. */ |
| 5267 | # define POINTER_TO_OFFSET(ptr) \ |
| 5268 | (FIRST_STRING_P (ptr) \ |
| 5269 | ? ((regoff_t) ((ptr) - string1)) \ |
| 5270 | : ((regoff_t) ((ptr) - string2 + size1))) |
| 5271 | #endif /* WCHAR */ |
| 5272 | |
| 5273 | /* Macros for dealing with the split strings in re_match_2. */ |
| 5274 | |
| 5275 | #define MATCHING_IN_FIRST_STRING (dend == end_match_1) |
| 5276 | |
| 5277 | /* Call before fetching a character with *d. This switches over to |
| 5278 | string2 if necessary. */ |
| 5279 | #define PREFETCH() \ |
| 5280 | while (d == dend) \ |
| 5281 | { \ |
| 5282 | /* End of string2 => fail. */ \ |
| 5283 | if (dend == end_match_2) \ |
| 5284 | goto fail; \ |
| 5285 | /* End of string1 => advance to string2. */ \ |
| 5286 | d = string2; \ |
| 5287 | dend = end_match_2; \ |
| 5288 | } |
| 5289 | |
| 5290 | /* Test if at very beginning or at very end of the virtual concatenation |
| 5291 | of `string1' and `string2'. If only one string, it's `string2'. */ |
| 5292 | #define AT_STRINGS_BEG(d) ((d) == (size1 ? string1 : string2) || !size2) |
| 5293 | #define AT_STRINGS_END(d) ((d) == end2) |
| 5294 | |
| 5295 | |
| 5296 | /* Test if D points to a character which is word-constituent. We have |
| 5297 | two special cases to check for: if past the end of string1, look at |
| 5298 | the first character in string2; and if before the beginning of |
| 5299 | string2, look at the last character in string1. */ |
| 5300 | #ifdef WCHAR |
| 5301 | /* Use internationalized API instead of SYNTAX. */ |
| 5302 | # define WORDCHAR_P(d) \ |
| 5303 | (iswalnum ((wint_t)((d) == end1 ? *string2 \ |
| 5304 | : (d) == string2 - 1 ? *(end1 - 1) : *(d))) != 0 \ |
| 5305 | || ((d) == end1 ? *string2 \ |
| 5306 | : (d) == string2 - 1 ? *(end1 - 1) : *(d)) == L'_') |
| 5307 | #else /* BYTE */ |
| 5308 | # define WORDCHAR_P(d) \ |
| 5309 | (SYNTAX ((d) == end1 ? *string2 \ |
| 5310 | : (d) == string2 - 1 ? *(end1 - 1) : *(d)) \ |
| 5311 | == Sword) |
| 5312 | #endif /* WCHAR */ |
| 5313 | |
| 5314 | /* Disabled due to a compiler bug -- see comment at case wordbound */ |
| 5315 | #if 0 |
| 5316 | /* Test if the character before D and the one at D differ with respect |
| 5317 | to being word-constituent. */ |
| 5318 | #define AT_WORD_BOUNDARY(d) \ |
| 5319 | (AT_STRINGS_BEG (d) || AT_STRINGS_END (d) \ |
| 5320 | || WORDCHAR_P (d - 1) != WORDCHAR_P (d)) |
| 5321 | #endif |
| 5322 | |
| 5323 | /* Free everything we malloc. */ |
| 5324 | #ifdef MATCH_MAY_ALLOCATE |
| 5325 | # ifdef WCHAR |
| 5326 | # define FREE_VARIABLES() \ |
| 5327 | do { \ |
| 5328 | REGEX_FREE_STACK (fail_stack.stack); \ |
| 5329 | FREE_VAR (regstart); \ |
| 5330 | FREE_VAR (regend); \ |
| 5331 | FREE_VAR (old_regstart); \ |
| 5332 | FREE_VAR (old_regend); \ |
| 5333 | FREE_VAR (best_regstart); \ |
| 5334 | FREE_VAR (best_regend); \ |
| 5335 | FREE_VAR (reg_info); \ |
| 5336 | FREE_VAR (reg_dummy); \ |
| 5337 | FREE_VAR (reg_info_dummy); \ |
| 5338 | if (!cant_free_wcs_buf) \ |
| 5339 | { \ |
| 5340 | FREE_VAR (string1); \ |
| 5341 | FREE_VAR (string2); \ |
| 5342 | FREE_VAR (mbs_offset1); \ |
| 5343 | FREE_VAR (mbs_offset2); \ |
| 5344 | } \ |
| 5345 | } while (0) |
| 5346 | # else /* BYTE */ |
| 5347 | # define FREE_VARIABLES() \ |
| 5348 | do { \ |
| 5349 | REGEX_FREE_STACK (fail_stack.stack); \ |
| 5350 | FREE_VAR (regstart); \ |
| 5351 | FREE_VAR (regend); \ |
| 5352 | FREE_VAR (old_regstart); \ |
| 5353 | FREE_VAR (old_regend); \ |
| 5354 | FREE_VAR (best_regstart); \ |
| 5355 | FREE_VAR (best_regend); \ |
| 5356 | FREE_VAR (reg_info); \ |
| 5357 | FREE_VAR (reg_dummy); \ |
| 5358 | FREE_VAR (reg_info_dummy); \ |
| 5359 | } while (0) |
| 5360 | # endif /* WCHAR */ |
| 5361 | #else |
| 5362 | # ifdef WCHAR |
| 5363 | # define FREE_VARIABLES() \ |
| 5364 | do { \ |
| 5365 | if (!cant_free_wcs_buf) \ |
| 5366 | { \ |
| 5367 | FREE_VAR (string1); \ |
| 5368 | FREE_VAR (string2); \ |
| 5369 | FREE_VAR (mbs_offset1); \ |
| 5370 | FREE_VAR (mbs_offset2); \ |
| 5371 | } \ |
| 5372 | } while (0) |
| 5373 | # else /* BYTE */ |
| 5374 | # define FREE_VARIABLES() ((void)0) /* Do nothing! But inhibit gcc warning. */ |
| 5375 | # endif /* WCHAR */ |
| 5376 | #endif /* not MATCH_MAY_ALLOCATE */ |
| 5377 | |
| 5378 | /* These values must meet several constraints. They must not be valid |
| 5379 | register values; since we have a limit of 255 registers (because |
| 5380 | we use only one byte in the pattern for the register number), we can |
| 5381 | use numbers larger than 255. They must differ by 1, because of |
| 5382 | NUM_FAILURE_ITEMS above. And the value for the lowest register must |
| 5383 | be larger than the value for the highest register, so we do not try |
| 5384 | to actually save any registers when none are active. */ |
| 5385 | #define NO_HIGHEST_ACTIVE_REG (1 << BYTEWIDTH) |
| 5386 | #define NO_LOWEST_ACTIVE_REG (NO_HIGHEST_ACTIVE_REG + 1) |
| 5387 | \f |
| 5388 | #else /* not INSIDE_RECURSION */ |
| 5389 | /* Matching routines. */ |
| 5390 | |
| 5391 | #ifndef emacs /* Emacs never uses this. */ |
| 5392 | /* re_match is like re_match_2 except it takes only a single string. */ |
| 5393 | |
| 5394 | int |
| 5395 | re_match (struct re_pattern_buffer *bufp, const char *string, |
| 5396 | int size, int pos, struct re_registers *regs) |
| 5397 | { |
| 5398 | int result; |
| 5399 | # ifdef MBS_SUPPORT |
| 5400 | if (MB_CUR_MAX != 1) |
| 5401 | result = wcs_re_match_2_internal (bufp, NULL, 0, string, size, |
| 5402 | pos, regs, size, |
| 5403 | NULL, 0, NULL, 0, NULL, NULL); |
| 5404 | else |
| 5405 | # endif |
| 5406 | result = byte_re_match_2_internal (bufp, NULL, 0, string, size, |
| 5407 | pos, regs, size); |
| 5408 | # ifndef REGEX_MALLOC |
| 5409 | # ifdef C_ALLOCA |
| 5410 | alloca (0); |
| 5411 | # endif |
| 5412 | # endif |
| 5413 | return result; |
| 5414 | } |
| 5415 | # ifdef _LIBC |
| 5416 | weak_alias (__re_match, re_match) |
| 5417 | # endif |
| 5418 | #endif /* not emacs */ |
| 5419 | |
| 5420 | #endif /* not INSIDE_RECURSION */ |
| 5421 | |
| 5422 | #ifdef INSIDE_RECURSION |
| 5423 | static boolean PREFIX(group_match_null_string_p) (UCHAR_T **p, |
| 5424 | UCHAR_T *end, |
| 5425 | PREFIX(register_info_type) *reg_info); |
| 5426 | static boolean PREFIX(alt_match_null_string_p) (UCHAR_T *p, |
| 5427 | UCHAR_T *end, |
| 5428 | PREFIX(register_info_type) *reg_info); |
| 5429 | static boolean PREFIX(common_op_match_null_string_p) (UCHAR_T **p, |
| 5430 | UCHAR_T *end, |
| 5431 | PREFIX(register_info_type) *reg_info); |
| 5432 | static int PREFIX(bcmp_translate) (const CHAR_T *s1, const CHAR_T *s2, |
| 5433 | int len, char *translate); |
| 5434 | #else /* not INSIDE_RECURSION */ |
| 5435 | |
| 5436 | /* re_match_2 matches the compiled pattern in BUFP against the |
| 5437 | the (virtual) concatenation of STRING1 and STRING2 (of length SIZE1 |
| 5438 | and SIZE2, respectively). We start matching at POS, and stop |
| 5439 | matching at STOP. |
| 5440 | |
| 5441 | If REGS is non-null and the `no_sub' field of BUFP is nonzero, we |
| 5442 | store offsets for the substring each group matched in REGS. See the |
| 5443 | documentation for exactly how many groups we fill. |
| 5444 | |
| 5445 | We return -1 if no match, -2 if an internal error (such as the |
| 5446 | failure stack overflowing). Otherwise, we return the length of the |
| 5447 | matched substring. */ |
| 5448 | |
| 5449 | int |
| 5450 | re_match_2 (struct re_pattern_buffer *bufp, const char *string1, int size1, |
| 5451 | const char *string2, int size2, int pos, |
| 5452 | struct re_registers *regs, int stop) |
| 5453 | { |
| 5454 | int result; |
| 5455 | # ifdef MBS_SUPPORT |
| 5456 | if (MB_CUR_MAX != 1) |
| 5457 | result = wcs_re_match_2_internal (bufp, string1, size1, string2, size2, |
| 5458 | pos, regs, stop, |
| 5459 | NULL, 0, NULL, 0, NULL, NULL); |
| 5460 | else |
| 5461 | # endif |
| 5462 | result = byte_re_match_2_internal (bufp, string1, size1, string2, size2, |
| 5463 | pos, regs, stop); |
| 5464 | |
| 5465 | #ifndef REGEX_MALLOC |
| 5466 | # ifdef C_ALLOCA |
| 5467 | alloca (0); |
| 5468 | # endif |
| 5469 | #endif |
| 5470 | return result; |
| 5471 | } |
| 5472 | #ifdef _LIBC |
| 5473 | weak_alias (__re_match_2, re_match_2) |
| 5474 | #endif |
| 5475 | |
| 5476 | #endif /* not INSIDE_RECURSION */ |
| 5477 | |
| 5478 | #ifdef INSIDE_RECURSION |
| 5479 | |
| 5480 | #ifdef WCHAR |
| 5481 | static int count_mbs_length (int *, int); |
| 5482 | |
| 5483 | /* This check the substring (from 0, to length) of the multibyte string, |
| 5484 | to which offset_buffer correspond. And count how many wchar_t_characters |
| 5485 | the substring occupy. We use offset_buffer to optimization. |
| 5486 | See convert_mbs_to_wcs. */ |
| 5487 | |
| 5488 | static int |
| 5489 | count_mbs_length(int *offset_buffer, int length) |
| 5490 | { |
| 5491 | int upper, lower; |
| 5492 | |
| 5493 | /* Check whether the size is valid. */ |
| 5494 | if (length < 0) |
| 5495 | return -1; |
| 5496 | |
| 5497 | if (offset_buffer == NULL) |
| 5498 | return 0; |
| 5499 | |
| 5500 | /* If there are no multibyte character, offset_buffer[i] == i. |
| 5501 | Optmize for this case. */ |
| 5502 | if (offset_buffer[length] == length) |
| 5503 | return length; |
| 5504 | |
| 5505 | /* Set up upper with length. (because for all i, offset_buffer[i] >= i) */ |
| 5506 | upper = length; |
| 5507 | lower = 0; |
| 5508 | |
| 5509 | while (true) |
| 5510 | { |
| 5511 | int middle = (lower + upper) / 2; |
| 5512 | if (middle == lower || middle == upper) |
| 5513 | break; |
| 5514 | if (offset_buffer[middle] > length) |
| 5515 | upper = middle; |
| 5516 | else if (offset_buffer[middle] < length) |
| 5517 | lower = middle; |
| 5518 | else |
| 5519 | return middle; |
| 5520 | } |
| 5521 | |
| 5522 | return -1; |
| 5523 | } |
| 5524 | #endif /* WCHAR */ |
| 5525 | |
| 5526 | /* This is a separate function so that we can force an alloca cleanup |
| 5527 | afterwards. */ |
| 5528 | #ifdef WCHAR |
| 5529 | static int |
| 5530 | wcs_re_match_2_internal (struct re_pattern_buffer *bufp, |
| 5531 | const char *cstring1, int csize1, |
| 5532 | const char *cstring2, int csize2, |
| 5533 | int pos, |
| 5534 | struct re_registers *regs, |
| 5535 | int stop, |
| 5536 | /* string1 == string2 == NULL means string1/2, size1/2 and |
| 5537 | mbs_offset1/2 need seting up in this function. */ |
| 5538 | /* We need wchar_t* buffers correspond to cstring1, cstring2. */ |
| 5539 | wchar_t *string1, int size1, |
| 5540 | wchar_t *string2, int size2, |
| 5541 | /* offset buffer for optimizatoin. See convert_mbs_to_wc. */ |
| 5542 | int *mbs_offset1, int *mbs_offset2) |
| 5543 | #else /* BYTE */ |
| 5544 | static int |
| 5545 | byte_re_match_2_internal (struct re_pattern_buffer *bufp, |
| 5546 | const char *string1, int size1, |
| 5547 | const char *string2, int size2, |
| 5548 | int pos, |
| 5549 | struct re_registers *regs, int stop) |
| 5550 | #endif /* BYTE */ |
| 5551 | { |
| 5552 | /* General temporaries. */ |
| 5553 | int mcnt; |
| 5554 | UCHAR_T *p1; |
| 5555 | #ifdef WCHAR |
| 5556 | /* They hold whether each wchar_t is binary data or not. */ |
| 5557 | char *is_binary = NULL; |
| 5558 | /* If true, we can't free string1/2, mbs_offset1/2. */ |
| 5559 | int cant_free_wcs_buf = 1; |
| 5560 | #endif /* WCHAR */ |
| 5561 | |
| 5562 | /* Just past the end of the corresponding string. */ |
| 5563 | const CHAR_T *end1, *end2; |
| 5564 | |
| 5565 | /* Pointers into string1 and string2, just past the last characters in |
| 5566 | each to consider matching. */ |
| 5567 | const CHAR_T *end_match_1, *end_match_2; |
| 5568 | |
| 5569 | /* Where we are in the data, and the end of the current string. */ |
| 5570 | const CHAR_T *d, *dend; |
| 5571 | |
| 5572 | /* Where we are in the pattern, and the end of the pattern. */ |
| 5573 | #ifdef WCHAR |
| 5574 | UCHAR_T *pattern, *p; |
| 5575 | register UCHAR_T *pend; |
| 5576 | #else /* BYTE */ |
| 5577 | UCHAR_T *p = bufp->buffer; |
| 5578 | register UCHAR_T *pend = p + bufp->used; |
| 5579 | #endif /* WCHAR */ |
| 5580 | |
| 5581 | /* Mark the opcode just after a start_memory, so we can test for an |
| 5582 | empty subpattern when we get to the stop_memory. */ |
| 5583 | UCHAR_T *just_past_start_mem = 0; |
| 5584 | |
| 5585 | /* We use this to map every character in the string. */ |
| 5586 | RE_TRANSLATE_TYPE translate = bufp->translate; |
| 5587 | |
| 5588 | /* Failure point stack. Each place that can handle a failure further |
| 5589 | down the line pushes a failure point on this stack. It consists of |
| 5590 | restart, regend, and reg_info for all registers corresponding to |
| 5591 | the subexpressions we're currently inside, plus the number of such |
| 5592 | registers, and, finally, two char *'s. The first char * is where |
| 5593 | to resume scanning the pattern; the second one is where to resume |
| 5594 | scanning the strings. If the latter is zero, the failure point is |
| 5595 | a ``dummy''; if a failure happens and the failure point is a dummy, |
| 5596 | it gets discarded and the next next one is tried. */ |
| 5597 | #ifdef MATCH_MAY_ALLOCATE /* otherwise, this is global. */ |
| 5598 | PREFIX(fail_stack_type) fail_stack; |
| 5599 | #endif |
| 5600 | #ifdef DEBUG |
| 5601 | static unsigned failure_id; |
| 5602 | unsigned nfailure_points_pushed = 0, nfailure_points_popped = 0; |
| 5603 | #endif |
| 5604 | |
| 5605 | #ifdef REL_ALLOC |
| 5606 | /* This holds the pointer to the failure stack, when |
| 5607 | it is allocated relocatably. */ |
| 5608 | fail_stack_elt_t *failure_stack_ptr; |
| 5609 | #endif |
| 5610 | |
| 5611 | /* We fill all the registers internally, independent of what we |
| 5612 | return, for use in backreferences. The number here includes |
| 5613 | an element for register zero. */ |
| 5614 | size_t num_regs = bufp->re_nsub + 1; |
| 5615 | |
| 5616 | /* The currently active registers. */ |
| 5617 | active_reg_t lowest_active_reg = NO_LOWEST_ACTIVE_REG; |
| 5618 | active_reg_t highest_active_reg = NO_HIGHEST_ACTIVE_REG; |
| 5619 | |
| 5620 | /* Information on the contents of registers. These are pointers into |
| 5621 | the input strings; they record just what was matched (on this |
| 5622 | attempt) by a subexpression part of the pattern, that is, the |
| 5623 | regnum-th regstart pointer points to where in the pattern we began |
| 5624 | matching and the regnum-th regend points to right after where we |
| 5625 | stopped matching the regnum-th subexpression. (The zeroth register |
| 5626 | keeps track of what the whole pattern matches.) */ |
| 5627 | #ifdef MATCH_MAY_ALLOCATE /* otherwise, these are global. */ |
| 5628 | const CHAR_T **regstart, **regend; |
| 5629 | #endif |
| 5630 | |
| 5631 | /* If a group that's operated upon by a repetition operator fails to |
| 5632 | match anything, then the register for its start will need to be |
| 5633 | restored because it will have been set to wherever in the string we |
| 5634 | are when we last see its open-group operator. Similarly for a |
| 5635 | register's end. */ |
| 5636 | #ifdef MATCH_MAY_ALLOCATE /* otherwise, these are global. */ |
| 5637 | const CHAR_T **old_regstart, **old_regend; |
| 5638 | #endif |
| 5639 | |
| 5640 | /* The is_active field of reg_info helps us keep track of which (possibly |
| 5641 | nested) subexpressions we are currently in. The matched_something |
| 5642 | field of reg_info[reg_num] helps us tell whether or not we have |
| 5643 | matched any of the pattern so far this time through the reg_num-th |
| 5644 | subexpression. These two fields get reset each time through any |
| 5645 | loop their register is in. */ |
| 5646 | #ifdef MATCH_MAY_ALLOCATE /* otherwise, this is global. */ |
| 5647 | PREFIX(register_info_type) *reg_info; |
| 5648 | #endif |
| 5649 | |
| 5650 | /* The following record the register info as found in the above |
| 5651 | variables when we find a match better than any we've seen before. |
| 5652 | This happens as we backtrack through the failure points, which in |
| 5653 | turn happens only if we have not yet matched the entire string. */ |
| 5654 | unsigned best_regs_set = false; |
| 5655 | #ifdef MATCH_MAY_ALLOCATE /* otherwise, these are global. */ |
| 5656 | const CHAR_T **best_regstart, **best_regend; |
| 5657 | #endif |
| 5658 | |
| 5659 | /* Logically, this is `best_regend[0]'. But we don't want to have to |
| 5660 | allocate space for that if we're not allocating space for anything |
| 5661 | else (see below). Also, we never need info about register 0 for |
| 5662 | any of the other register vectors, and it seems rather a kludge to |
| 5663 | treat `best_regend' differently than the rest. So we keep track of |
| 5664 | the end of the best match so far in a separate variable. We |
| 5665 | initialize this to NULL so that when we backtrack the first time |
| 5666 | and need to test it, it's not garbage. */ |
| 5667 | const CHAR_T *match_end = NULL; |
| 5668 | |
| 5669 | /* This helps SET_REGS_MATCHED avoid doing redundant work. */ |
| 5670 | int set_regs_matched_done = 0; |
| 5671 | |
| 5672 | /* Used when we pop values we don't care about. */ |
| 5673 | #ifdef MATCH_MAY_ALLOCATE /* otherwise, these are global. */ |
| 5674 | const CHAR_T **reg_dummy; |
| 5675 | PREFIX(register_info_type) *reg_info_dummy; |
| 5676 | #endif |
| 5677 | |
| 5678 | #ifdef DEBUG |
| 5679 | /* Counts the total number of registers pushed. */ |
| 5680 | unsigned num_regs_pushed = 0; |
| 5681 | #endif |
| 5682 | |
| 5683 | DEBUG_PRINT1 ("\n\nEntering re_match_2.\n"); |
| 5684 | |
| 5685 | INIT_FAIL_STACK (); |
| 5686 | |
| 5687 | #ifdef MATCH_MAY_ALLOCATE |
| 5688 | /* Do not bother to initialize all the register variables if there are |
| 5689 | no groups in the pattern, as it takes a fair amount of time. If |
| 5690 | there are groups, we include space for register 0 (the whole |
| 5691 | pattern), even though we never use it, since it simplifies the |
| 5692 | array indexing. We should fix this. */ |
| 5693 | if (bufp->re_nsub) |
| 5694 | { |
| 5695 | regstart = REGEX_TALLOC (num_regs, const CHAR_T *); |
| 5696 | regend = REGEX_TALLOC (num_regs, const CHAR_T *); |
| 5697 | old_regstart = REGEX_TALLOC (num_regs, const CHAR_T *); |
| 5698 | old_regend = REGEX_TALLOC (num_regs, const CHAR_T *); |
| 5699 | best_regstart = REGEX_TALLOC (num_regs, const CHAR_T *); |
| 5700 | best_regend = REGEX_TALLOC (num_regs, const CHAR_T *); |
| 5701 | reg_info = REGEX_TALLOC (num_regs, PREFIX(register_info_type)); |
| 5702 | reg_dummy = REGEX_TALLOC (num_regs, const CHAR_T *); |
| 5703 | reg_info_dummy = REGEX_TALLOC (num_regs, PREFIX(register_info_type)); |
| 5704 | |
| 5705 | if (!(regstart && regend && old_regstart && old_regend && reg_info |
| 5706 | && best_regstart && best_regend && reg_dummy && reg_info_dummy)) |
| 5707 | { |
| 5708 | FREE_VARIABLES (); |
| 5709 | return -2; |
| 5710 | } |
| 5711 | } |
| 5712 | else |
| 5713 | { |
| 5714 | /* We must initialize all our variables to NULL, so that |
| 5715 | `FREE_VARIABLES' doesn't try to free them. */ |
| 5716 | regstart = regend = old_regstart = old_regend = best_regstart |
| 5717 | = best_regend = reg_dummy = NULL; |
| 5718 | reg_info = reg_info_dummy = (PREFIX(register_info_type) *) NULL; |
| 5719 | } |
| 5720 | #endif /* MATCH_MAY_ALLOCATE */ |
| 5721 | |
| 5722 | /* The starting position is bogus. */ |
| 5723 | #ifdef WCHAR |
| 5724 | if (pos < 0 || pos > csize1 + csize2) |
| 5725 | #else /* BYTE */ |
| 5726 | if (pos < 0 || pos > size1 + size2) |
| 5727 | #endif |
| 5728 | { |
| 5729 | FREE_VARIABLES (); |
| 5730 | return -1; |
| 5731 | } |
| 5732 | |
| 5733 | #ifdef WCHAR |
| 5734 | /* Allocate wchar_t array for string1 and string2 and |
| 5735 | fill them with converted string. */ |
| 5736 | if (string1 == NULL && string2 == NULL) |
| 5737 | { |
| 5738 | /* We need seting up buffers here. */ |
| 5739 | |
| 5740 | /* We must free wcs buffers in this function. */ |
| 5741 | cant_free_wcs_buf = 0; |
| 5742 | |
| 5743 | if (csize1 != 0) |
| 5744 | { |
| 5745 | string1 = REGEX_TALLOC (csize1 + 1, CHAR_T); |
| 5746 | mbs_offset1 = REGEX_TALLOC (csize1 + 1, int); |
| 5747 | is_binary = REGEX_TALLOC (csize1 + 1, char); |
| 5748 | if (!string1 || !mbs_offset1 || !is_binary) |
| 5749 | { |
| 5750 | FREE_VAR (string1); |
| 5751 | FREE_VAR (mbs_offset1); |
| 5752 | FREE_VAR (is_binary); |
| 5753 | return -2; |
| 5754 | } |
| 5755 | } |
| 5756 | if (csize2 != 0) |
| 5757 | { |
| 5758 | string2 = REGEX_TALLOC (csize2 + 1, CHAR_T); |
| 5759 | mbs_offset2 = REGEX_TALLOC (csize2 + 1, int); |
| 5760 | is_binary = REGEX_TALLOC (csize2 + 1, char); |
| 5761 | if (!string2 || !mbs_offset2 || !is_binary) |
| 5762 | { |
| 5763 | FREE_VAR (string1); |
| 5764 | FREE_VAR (mbs_offset1); |
| 5765 | FREE_VAR (string2); |
| 5766 | FREE_VAR (mbs_offset2); |
| 5767 | FREE_VAR (is_binary); |
| 5768 | return -2; |
| 5769 | } |
| 5770 | size2 = convert_mbs_to_wcs(string2, cstring2, csize2, |
| 5771 | mbs_offset2, is_binary); |
| 5772 | string2[size2] = L'\0'; /* for a sentinel */ |
| 5773 | FREE_VAR (is_binary); |
| 5774 | } |
| 5775 | } |
| 5776 | |
| 5777 | /* We need to cast pattern to (wchar_t*), because we casted this compiled |
| 5778 | pattern to (char*) in regex_compile. */ |
| 5779 | p = pattern = (CHAR_T*)bufp->buffer; |
| 5780 | pend = (CHAR_T*)(bufp->buffer + bufp->used); |
| 5781 | |
| 5782 | #endif /* WCHAR */ |
| 5783 | |
| 5784 | /* Initialize subexpression text positions to -1 to mark ones that no |
| 5785 | start_memory/stop_memory has been seen for. Also initialize the |
| 5786 | register information struct. */ |
| 5787 | for (mcnt = 1; (unsigned) mcnt < num_regs; mcnt++) |
| 5788 | { |
| 5789 | regstart[mcnt] = regend[mcnt] |
| 5790 | = old_regstart[mcnt] = old_regend[mcnt] = REG_UNSET_VALUE; |
| 5791 | |
| 5792 | REG_MATCH_NULL_STRING_P (reg_info[mcnt]) = MATCH_NULL_UNSET_VALUE; |
| 5793 | IS_ACTIVE (reg_info[mcnt]) = 0; |
| 5794 | MATCHED_SOMETHING (reg_info[mcnt]) = 0; |
| 5795 | EVER_MATCHED_SOMETHING (reg_info[mcnt]) = 0; |
| 5796 | } |
| 5797 | |
| 5798 | /* We move `string1' into `string2' if the latter's empty -- but not if |
| 5799 | `string1' is null. */ |
| 5800 | if (size2 == 0 && string1 != NULL) |
| 5801 | { |
| 5802 | string2 = string1; |
| 5803 | size2 = size1; |
| 5804 | string1 = 0; |
| 5805 | size1 = 0; |
| 5806 | #ifdef WCHAR |
| 5807 | mbs_offset2 = mbs_offset1; |
| 5808 | csize2 = csize1; |
| 5809 | mbs_offset1 = NULL; |
| 5810 | csize1 = 0; |
| 5811 | #endif |
| 5812 | } |
| 5813 | end1 = string1 + size1; |
| 5814 | end2 = string2 + size2; |
| 5815 | |
| 5816 | /* Compute where to stop matching, within the two strings. */ |
| 5817 | #ifdef WCHAR |
| 5818 | if (stop <= csize1) |
| 5819 | { |
| 5820 | mcnt = count_mbs_length(mbs_offset1, stop); |
| 5821 | end_match_1 = string1 + mcnt; |
| 5822 | end_match_2 = string2; |
| 5823 | } |
| 5824 | else |
| 5825 | { |
| 5826 | if (stop > csize1 + csize2) |
| 5827 | stop = csize1 + csize2; |
| 5828 | end_match_1 = end1; |
| 5829 | mcnt = count_mbs_length(mbs_offset2, stop-csize1); |
| 5830 | end_match_2 = string2 + mcnt; |
| 5831 | } |
| 5832 | if (mcnt < 0) |
| 5833 | { /* count_mbs_length return error. */ |
| 5834 | FREE_VARIABLES (); |
| 5835 | return -1; |
| 5836 | } |
| 5837 | #else |
| 5838 | if (stop <= size1) |
| 5839 | { |
| 5840 | end_match_1 = string1 + stop; |
| 5841 | end_match_2 = string2; |
| 5842 | } |
| 5843 | else |
| 5844 | { |
| 5845 | end_match_1 = end1; |
| 5846 | end_match_2 = string2 + stop - size1; |
| 5847 | } |
| 5848 | #endif /* WCHAR */ |
| 5849 | |
| 5850 | /* `p' scans through the pattern as `d' scans through the data. |
| 5851 | `dend' is the end of the input string that `d' points within. `d' |
| 5852 | is advanced into the following input string whenever necessary, but |
| 5853 | this happens before fetching; therefore, at the beginning of the |
| 5854 | loop, `d' can be pointing at the end of a string, but it cannot |
| 5855 | equal `string2'. */ |
| 5856 | #ifdef WCHAR |
| 5857 | if (size1 > 0 && pos <= csize1) |
| 5858 | { |
| 5859 | mcnt = count_mbs_length(mbs_offset1, pos); |
| 5860 | d = string1 + mcnt; |
| 5861 | dend = end_match_1; |
| 5862 | } |
| 5863 | else |
| 5864 | { |
| 5865 | mcnt = count_mbs_length(mbs_offset2, pos-csize1); |
| 5866 | d = string2 + mcnt; |
| 5867 | dend = end_match_2; |
| 5868 | } |
| 5869 | |
| 5870 | if (mcnt < 0) |
| 5871 | { /* count_mbs_length return error. */ |
| 5872 | FREE_VARIABLES (); |
| 5873 | return -1; |
| 5874 | } |
| 5875 | #else |
| 5876 | if (size1 > 0 && pos <= size1) |
| 5877 | { |
| 5878 | d = string1 + pos; |
| 5879 | dend = end_match_1; |
| 5880 | } |
| 5881 | else |
| 5882 | { |
| 5883 | d = string2 + pos - size1; |
| 5884 | dend = end_match_2; |
| 5885 | } |
| 5886 | #endif /* WCHAR */ |
| 5887 | |
| 5888 | DEBUG_PRINT1 ("The compiled pattern is:\n"); |
| 5889 | DEBUG_PRINT_COMPILED_PATTERN (bufp, p, pend); |
| 5890 | DEBUG_PRINT1 ("The string to match is: `"); |
| 5891 | DEBUG_PRINT_DOUBLE_STRING (d, string1, size1, string2, size2); |
| 5892 | DEBUG_PRINT1 ("'\n"); |
| 5893 | |
| 5894 | /* This loops over pattern commands. It exits by returning from the |
| 5895 | function if the match is complete, or it drops through if the match |
| 5896 | fails at this starting point in the input data. */ |
| 5897 | for (;;) |
| 5898 | { |
| 5899 | #ifdef _LIBC |
| 5900 | DEBUG_PRINT2 ("\n%p: ", p); |
| 5901 | #else |
| 5902 | DEBUG_PRINT2 ("\n0x%x: ", p); |
| 5903 | #endif |
| 5904 | |
| 5905 | if (p == pend) |
| 5906 | { /* End of pattern means we might have succeeded. */ |
| 5907 | DEBUG_PRINT1 ("end of pattern ... "); |
| 5908 | |
| 5909 | /* If we haven't matched the entire string, and we want the |
| 5910 | longest match, try backtracking. */ |
| 5911 | if (d != end_match_2) |
| 5912 | { |
| 5913 | /* 1 if this match ends in the same string (string1 or string2) |
| 5914 | as the best previous match. */ |
| 5915 | boolean same_str_p; |
| 5916 | |
| 5917 | /* 1 if this match is the best seen so far. */ |
| 5918 | boolean best_match_p; |
| 5919 | |
| 5920 | same_str_p = (FIRST_STRING_P (match_end) |
| 5921 | == MATCHING_IN_FIRST_STRING); |
| 5922 | |
| 5923 | /* AIX compiler got confused when this was combined |
| 5924 | with the previous declaration. */ |
| 5925 | if (same_str_p) |
| 5926 | best_match_p = d > match_end; |
| 5927 | else |
| 5928 | best_match_p = !MATCHING_IN_FIRST_STRING; |
| 5929 | |
| 5930 | DEBUG_PRINT1 ("backtracking.\n"); |
| 5931 | |
| 5932 | if (!FAIL_STACK_EMPTY ()) |
| 5933 | { /* More failure points to try. */ |
| 5934 | |
| 5935 | /* If exceeds best match so far, save it. */ |
| 5936 | if (!best_regs_set || best_match_p) |
| 5937 | { |
| 5938 | best_regs_set = true; |
| 5939 | match_end = d; |
| 5940 | |
| 5941 | DEBUG_PRINT1 ("\nSAVING match as best so far.\n"); |
| 5942 | |
| 5943 | for (mcnt = 1; (unsigned) mcnt < num_regs; mcnt++) |
| 5944 | { |
| 5945 | best_regstart[mcnt] = regstart[mcnt]; |
| 5946 | best_regend[mcnt] = regend[mcnt]; |
| 5947 | } |
| 5948 | } |
| 5949 | goto fail; |
| 5950 | } |
| 5951 | |
| 5952 | /* If no failure points, don't restore garbage. And if |
| 5953 | last match is real best match, don't restore second |
| 5954 | best one. */ |
| 5955 | else if (best_regs_set && !best_match_p) |
| 5956 | { |
| 5957 | restore_best_regs: |
| 5958 | /* Restore best match. It may happen that `dend == |
| 5959 | end_match_1' while the restored d is in string2. |
| 5960 | For example, the pattern `x.*y.*z' against the |
| 5961 | strings `x-' and `y-z-', if the two strings are |
| 5962 | not consecutive in memory. */ |
| 5963 | DEBUG_PRINT1 ("Restoring best registers.\n"); |
| 5964 | |
| 5965 | d = match_end; |
| 5966 | dend = ((d >= string1 && d <= end1) |
| 5967 | ? end_match_1 : end_match_2); |
| 5968 | |
| 5969 | for (mcnt = 1; (unsigned) mcnt < num_regs; mcnt++) |
| 5970 | { |
| 5971 | regstart[mcnt] = best_regstart[mcnt]; |
| 5972 | regend[mcnt] = best_regend[mcnt]; |
| 5973 | } |
| 5974 | } |
| 5975 | } /* d != end_match_2 */ |
| 5976 | |
| 5977 | succeed_label: |
| 5978 | DEBUG_PRINT1 ("Accepting match.\n"); |
| 5979 | /* If caller wants register contents data back, do it. */ |
| 5980 | if (regs && !bufp->no_sub) |
| 5981 | { |
| 5982 | /* Have the register data arrays been allocated? */ |
| 5983 | if (bufp->regs_allocated == REGS_UNALLOCATED) |
| 5984 | { /* No. So allocate them with malloc. We need one |
| 5985 | extra element beyond `num_regs' for the `-1' marker |
| 5986 | GNU code uses. */ |
| 5987 | regs->num_regs = MAX (RE_NREGS, num_regs + 1); |
| 5988 | regs->start = TALLOC (regs->num_regs, regoff_t); |
| 5989 | regs->end = TALLOC (regs->num_regs, regoff_t); |
| 5990 | if (regs->start == NULL || regs->end == NULL) |
| 5991 | { |
| 5992 | FREE_VARIABLES (); |
| 5993 | return -2; |
| 5994 | } |
| 5995 | bufp->regs_allocated = REGS_REALLOCATE; |
| 5996 | } |
| 5997 | else if (bufp->regs_allocated == REGS_REALLOCATE) |
| 5998 | { /* Yes. If we need more elements than were already |
| 5999 | allocated, reallocate them. If we need fewer, just |
| 6000 | leave it alone. */ |
| 6001 | if (regs->num_regs < num_regs + 1) |
| 6002 | { |
| 6003 | regs->num_regs = num_regs + 1; |
| 6004 | RETALLOC (regs->start, regs->num_regs, regoff_t); |
| 6005 | RETALLOC (regs->end, regs->num_regs, regoff_t); |
| 6006 | if (regs->start == NULL || regs->end == NULL) |
| 6007 | { |
| 6008 | FREE_VARIABLES (); |
| 6009 | return -2; |
| 6010 | } |
| 6011 | } |
| 6012 | } |
| 6013 | else |
| 6014 | { |
| 6015 | /* These braces fend off a "empty body in an else-statement" |
| 6016 | warning under GCC when assert expands to nothing. */ |
| 6017 | assert (bufp->regs_allocated == REGS_FIXED); |
| 6018 | } |
| 6019 | |
| 6020 | /* Convert the pointer data in `regstart' and `regend' to |
| 6021 | indices. Register zero has to be set differently, |
| 6022 | since we haven't kept track of any info for it. */ |
| 6023 | if (regs->num_regs > 0) |
| 6024 | { |
| 6025 | regs->start[0] = pos; |
| 6026 | #ifdef WCHAR |
| 6027 | if (MATCHING_IN_FIRST_STRING) |
| 6028 | regs->end[0] = mbs_offset1 != NULL ? |
| 6029 | mbs_offset1[d-string1] : 0; |
| 6030 | else |
| 6031 | regs->end[0] = csize1 + (mbs_offset2 != NULL ? |
| 6032 | mbs_offset2[d-string2] : 0); |
| 6033 | #else |
| 6034 | regs->end[0] = (MATCHING_IN_FIRST_STRING |
| 6035 | ? ((regoff_t) (d - string1)) |
| 6036 | : ((regoff_t) (d - string2 + size1))); |
| 6037 | #endif /* WCHAR */ |
| 6038 | } |
| 6039 | |
| 6040 | /* Go through the first `min (num_regs, regs->num_regs)' |
| 6041 | registers, since that is all we initialized. */ |
| 6042 | for (mcnt = 1; (unsigned) mcnt < MIN (num_regs, regs->num_regs); |
| 6043 | mcnt++) |
| 6044 | { |
| 6045 | if (REG_UNSET (regstart[mcnt]) || REG_UNSET (regend[mcnt])) |
| 6046 | regs->start[mcnt] = regs->end[mcnt] = -1; |
| 6047 | else |
| 6048 | { |
| 6049 | regs->start[mcnt] |
| 6050 | = (regoff_t) POINTER_TO_OFFSET (regstart[mcnt]); |
| 6051 | regs->end[mcnt] |
| 6052 | = (regoff_t) POINTER_TO_OFFSET (regend[mcnt]); |
| 6053 | } |
| 6054 | } |
| 6055 | |
| 6056 | /* If the regs structure we return has more elements than |
| 6057 | were in the pattern, set the extra elements to -1. If |
| 6058 | we (re)allocated the registers, this is the case, |
| 6059 | because we always allocate enough to have at least one |
| 6060 | -1 at the end. */ |
| 6061 | for (mcnt = num_regs; (unsigned) mcnt < regs->num_regs; mcnt++) |
| 6062 | regs->start[mcnt] = regs->end[mcnt] = -1; |
| 6063 | } /* regs && !bufp->no_sub */ |
| 6064 | |
| 6065 | DEBUG_PRINT4 ("%u failure points pushed, %u popped (%u remain).\n", |
| 6066 | nfailure_points_pushed, nfailure_points_popped, |
| 6067 | nfailure_points_pushed - nfailure_points_popped); |
| 6068 | DEBUG_PRINT2 ("%u registers pushed.\n", num_regs_pushed); |
| 6069 | |
| 6070 | #ifdef WCHAR |
| 6071 | if (MATCHING_IN_FIRST_STRING) |
| 6072 | mcnt = mbs_offset1 != NULL ? mbs_offset1[d-string1] : 0; |
| 6073 | else |
| 6074 | mcnt = (mbs_offset2 != NULL ? mbs_offset2[d-string2] : 0) + |
| 6075 | csize1; |
| 6076 | mcnt -= pos; |
| 6077 | #else |
| 6078 | mcnt = d - pos - (MATCHING_IN_FIRST_STRING |
| 6079 | ? string1 |
| 6080 | : string2 - size1); |
| 6081 | #endif /* WCHAR */ |
| 6082 | |
| 6083 | DEBUG_PRINT2 ("Returning %d from re_match_2.\n", mcnt); |
| 6084 | |
| 6085 | FREE_VARIABLES (); |
| 6086 | return mcnt; |
| 6087 | } |
| 6088 | |
| 6089 | /* Otherwise match next pattern command. */ |
| 6090 | switch (SWITCH_ENUM_CAST ((re_opcode_t) *p++)) |
| 6091 | { |
| 6092 | /* Ignore these. Used to ignore the n of succeed_n's which |
| 6093 | currently have n == 0. */ |
| 6094 | case no_op: |
| 6095 | DEBUG_PRINT1 ("EXECUTING no_op.\n"); |
| 6096 | break; |
| 6097 | |
| 6098 | case succeed: |
| 6099 | DEBUG_PRINT1 ("EXECUTING succeed.\n"); |
| 6100 | goto succeed_label; |
| 6101 | |
| 6102 | /* Match the next n pattern characters exactly. The following |
| 6103 | byte in the pattern defines n, and the n bytes after that |
| 6104 | are the characters to match. */ |
| 6105 | case exactn: |
| 6106 | #ifdef MBS_SUPPORT |
| 6107 | case exactn_bin: |
| 6108 | #endif |
| 6109 | mcnt = *p++; |
| 6110 | DEBUG_PRINT2 ("EXECUTING exactn %d.\n", mcnt); |
| 6111 | |
| 6112 | /* This is written out as an if-else so we don't waste time |
| 6113 | testing `translate' inside the loop. */ |
| 6114 | if (translate) |
| 6115 | { |
| 6116 | do |
| 6117 | { |
| 6118 | PREFETCH (); |
| 6119 | #ifdef WCHAR |
| 6120 | if (*d <= 0xff) |
| 6121 | { |
| 6122 | if ((UCHAR_T) translate[(unsigned char) *d++] |
| 6123 | != (UCHAR_T) *p++) |
| 6124 | goto fail; |
| 6125 | } |
| 6126 | else |
| 6127 | { |
| 6128 | if (*d++ != (CHAR_T) *p++) |
| 6129 | goto fail; |
| 6130 | } |
| 6131 | #else |
| 6132 | if ((UCHAR_T) translate[(unsigned char) *d++] |
| 6133 | != (UCHAR_T) *p++) |
| 6134 | goto fail; |
| 6135 | #endif /* WCHAR */ |
| 6136 | } |
| 6137 | while (--mcnt); |
| 6138 | } |
| 6139 | else |
| 6140 | { |
| 6141 | do |
| 6142 | { |
| 6143 | PREFETCH (); |
| 6144 | if (*d++ != (CHAR_T) *p++) goto fail; |
| 6145 | } |
| 6146 | while (--mcnt); |
| 6147 | } |
| 6148 | SET_REGS_MATCHED (); |
| 6149 | break; |
| 6150 | |
| 6151 | |
| 6152 | /* Match any character except possibly a newline or a null. */ |
| 6153 | case anychar: |
| 6154 | DEBUG_PRINT1 ("EXECUTING anychar.\n"); |
| 6155 | |
| 6156 | PREFETCH (); |
| 6157 | |
| 6158 | if ((!(bufp->syntax & RE_DOT_NEWLINE) && TRANSLATE (*d) == '\n') |
| 6159 | || (bufp->syntax & RE_DOT_NOT_NULL && TRANSLATE (*d) == '\000')) |
| 6160 | goto fail; |
| 6161 | |
| 6162 | SET_REGS_MATCHED (); |
| 6163 | DEBUG_PRINT2 (" Matched `%ld'.\n", (long int) *d); |
| 6164 | d++; |
| 6165 | break; |
| 6166 | |
| 6167 | |
| 6168 | case charset: |
| 6169 | case charset_not: |
| 6170 | { |
| 6171 | register UCHAR_T c; |
| 6172 | #ifdef WCHAR |
| 6173 | unsigned int i, char_class_length, coll_symbol_length, |
| 6174 | equiv_class_length, ranges_length, chars_length, length; |
| 6175 | CHAR_T *workp, *workp2, *charset_top; |
| 6176 | #define WORK_BUFFER_SIZE 128 |
| 6177 | CHAR_T str_buf[WORK_BUFFER_SIZE]; |
| 6178 | # ifdef _LIBC |
| 6179 | uint32_t nrules; |
| 6180 | # endif /* _LIBC */ |
| 6181 | #endif /* WCHAR */ |
| 6182 | boolean negate = (re_opcode_t) *(p - 1) == charset_not; |
| 6183 | |
| 6184 | DEBUG_PRINT2 ("EXECUTING charset%s.\n", negate ? "_not" : ""); |
| 6185 | PREFETCH (); |
| 6186 | c = TRANSLATE (*d); /* The character to match. */ |
| 6187 | #ifdef WCHAR |
| 6188 | # ifdef _LIBC |
| 6189 | nrules = _NL_CURRENT_WORD (LC_COLLATE, _NL_COLLATE_NRULES); |
| 6190 | # endif /* _LIBC */ |
| 6191 | charset_top = p - 1; |
| 6192 | char_class_length = *p++; |
| 6193 | coll_symbol_length = *p++; |
| 6194 | equiv_class_length = *p++; |
| 6195 | ranges_length = *p++; |
| 6196 | chars_length = *p++; |
| 6197 | /* p points charset[6], so the address of the next instruction |
| 6198 | (charset[l+m+n+2o+k+p']) equals p[l+m+n+2*o+p'], |
| 6199 | where l=length of char_classes, m=length of collating_symbol, |
| 6200 | n=equivalence_class, o=length of char_range, |
| 6201 | p'=length of character. */ |
| 6202 | workp = p; |
| 6203 | /* Update p to indicate the next instruction. */ |
| 6204 | p += char_class_length + coll_symbol_length+ equiv_class_length + |
| 6205 | 2*ranges_length + chars_length; |
| 6206 | |
| 6207 | /* match with char_class? */ |
| 6208 | for (i = 0; i < char_class_length ; i += CHAR_CLASS_SIZE) |
| 6209 | { |
| 6210 | wctype_t wctype; |
| 6211 | uintptr_t alignedp = ((uintptr_t)workp |
| 6212 | + __alignof__(wctype_t) - 1) |
| 6213 | & ~(uintptr_t)(__alignof__(wctype_t) - 1); |
| 6214 | wctype = *((wctype_t*)alignedp); |
| 6215 | workp += CHAR_CLASS_SIZE; |
| 6216 | # ifdef _LIBC |
| 6217 | if (__iswctype((wint_t)c, wctype)) |
| 6218 | goto char_set_matched; |
| 6219 | # else |
| 6220 | if (iswctype((wint_t)c, wctype)) |
| 6221 | goto char_set_matched; |
| 6222 | # endif |
| 6223 | } |
| 6224 | |
| 6225 | /* match with collating_symbol? */ |
| 6226 | # ifdef _LIBC |
| 6227 | if (nrules != 0) |
| 6228 | { |
| 6229 | const unsigned char *extra = (const unsigned char *) |
| 6230 | _NL_CURRENT (LC_COLLATE, _NL_COLLATE_SYMB_EXTRAMB); |
| 6231 | |
| 6232 | for (workp2 = workp + coll_symbol_length ; workp < workp2 ; |
| 6233 | workp++) |
| 6234 | { |
| 6235 | int32_t *wextra; |
| 6236 | wextra = (int32_t*)(extra + *workp++); |
| 6237 | for (i = 0; i < *wextra; ++i) |
| 6238 | if (TRANSLATE(d[i]) != wextra[1 + i]) |
| 6239 | break; |
| 6240 | |
| 6241 | if (i == *wextra) |
| 6242 | { |
| 6243 | /* Update d, however d will be incremented at |
| 6244 | char_set_matched:, we decrement d here. */ |
| 6245 | d += i - 1; |
| 6246 | goto char_set_matched; |
| 6247 | } |
| 6248 | } |
| 6249 | } |
| 6250 | else /* (nrules == 0) */ |
| 6251 | # endif |
| 6252 | /* If we can't look up collation data, we use wcscoll |
| 6253 | instead. */ |
| 6254 | { |
| 6255 | for (workp2 = workp + coll_symbol_length ; workp < workp2 ;) |
| 6256 | { |
| 6257 | const CHAR_T *backup_d = d, *backup_dend = dend; |
| 6258 | # ifdef _LIBC |
| 6259 | length = __wcslen (workp); |
| 6260 | # else |
| 6261 | length = wcslen (workp); |
| 6262 | # endif |
| 6263 | |
| 6264 | /* If wcscoll(the collating symbol, whole string) > 0, |
| 6265 | any substring of the string never match with the |
| 6266 | collating symbol. */ |
| 6267 | # ifdef _LIBC |
| 6268 | if (__wcscoll (workp, d) > 0) |
| 6269 | # else |
| 6270 | if (wcscoll (workp, d) > 0) |
| 6271 | # endif |
| 6272 | { |
| 6273 | workp += length + 1; |
| 6274 | continue; |
| 6275 | } |
| 6276 | |
| 6277 | /* First, we compare the collating symbol with |
| 6278 | the first character of the string. |
| 6279 | If it don't match, we add the next character to |
| 6280 | the compare buffer in turn. */ |
| 6281 | for (i = 0 ; i < WORK_BUFFER_SIZE-1 ; i++, d++) |
| 6282 | { |
| 6283 | int match; |
| 6284 | if (d == dend) |
| 6285 | { |
| 6286 | if (dend == end_match_2) |
| 6287 | break; |
| 6288 | d = string2; |
| 6289 | dend = end_match_2; |
| 6290 | } |
| 6291 | |
| 6292 | /* add next character to the compare buffer. */ |
| 6293 | str_buf[i] = TRANSLATE(*d); |
| 6294 | str_buf[i+1] = '\0'; |
| 6295 | |
| 6296 | # ifdef _LIBC |
| 6297 | match = __wcscoll (workp, str_buf); |
| 6298 | # else |
| 6299 | match = wcscoll (workp, str_buf); |
| 6300 | # endif |
| 6301 | if (match == 0) |
| 6302 | goto char_set_matched; |
| 6303 | |
| 6304 | if (match < 0) |
| 6305 | /* (str_buf > workp) indicate (str_buf + X > workp), |
| 6306 | because for all X (str_buf + X > str_buf). |
| 6307 | So we don't need continue this loop. */ |
| 6308 | break; |
| 6309 | |
| 6310 | /* Otherwise(str_buf < workp), |
| 6311 | (str_buf+next_character) may equals (workp). |
| 6312 | So we continue this loop. */ |
| 6313 | } |
| 6314 | /* not matched */ |
| 6315 | d = backup_d; |
| 6316 | dend = backup_dend; |
| 6317 | workp += length + 1; |
| 6318 | } |
| 6319 | } |
| 6320 | /* match with equivalence_class? */ |
| 6321 | # ifdef _LIBC |
| 6322 | if (nrules != 0) |
| 6323 | { |
| 6324 | const CHAR_T *backup_d = d, *backup_dend = dend; |
| 6325 | /* Try to match the equivalence class against |
| 6326 | those known to the collate implementation. */ |
| 6327 | const int32_t *table; |
| 6328 | const int32_t *weights; |
| 6329 | const int32_t *extra; |
| 6330 | const int32_t *indirect; |
| 6331 | int32_t idx, idx2; |
| 6332 | wint_t *cp; |
| 6333 | size_t len; |
| 6334 | |
| 6335 | /* This #include defines a local function! */ |
| 6336 | # include <locale/weightwc.h> |
| 6337 | |
| 6338 | table = (const int32_t *) |
| 6339 | _NL_CURRENT (LC_COLLATE, _NL_COLLATE_TABLEWC); |
| 6340 | weights = (const wint_t *) |
| 6341 | _NL_CURRENT (LC_COLLATE, _NL_COLLATE_WEIGHTWC); |
| 6342 | extra = (const wint_t *) |
| 6343 | _NL_CURRENT (LC_COLLATE, _NL_COLLATE_EXTRAWC); |
| 6344 | indirect = (const int32_t *) |
| 6345 | _NL_CURRENT (LC_COLLATE, _NL_COLLATE_INDIRECTWC); |
| 6346 | |
| 6347 | /* Write 1 collating element to str_buf, and |
| 6348 | get its index. */ |
| 6349 | idx2 = 0; |
| 6350 | |
| 6351 | for (i = 0 ; idx2 == 0 && i < WORK_BUFFER_SIZE - 1; i++) |
| 6352 | { |
| 6353 | cp = (wint_t*)str_buf; |
| 6354 | if (d == dend) |
| 6355 | { |
| 6356 | if (dend == end_match_2) |
| 6357 | break; |
| 6358 | d = string2; |
| 6359 | dend = end_match_2; |
| 6360 | } |
| 6361 | str_buf[i] = TRANSLATE(*(d+i)); |
| 6362 | str_buf[i+1] = '\0'; /* sentinel */ |
| 6363 | idx2 = findidx ((const wint_t**)&cp); |
| 6364 | } |
| 6365 | |
| 6366 | /* Update d, however d will be incremented at |
| 6367 | char_set_matched:, we decrement d here. */ |
| 6368 | d = backup_d + ((wchar_t*)cp - (wchar_t*)str_buf - 1); |
| 6369 | if (d >= dend) |
| 6370 | { |
| 6371 | if (dend == end_match_2) |
| 6372 | d = dend; |
| 6373 | else |
| 6374 | { |
| 6375 | d = string2; |
| 6376 | dend = end_match_2; |
| 6377 | } |
| 6378 | } |
| 6379 | |
| 6380 | len = weights[idx2]; |
| 6381 | |
| 6382 | for (workp2 = workp + equiv_class_length ; workp < workp2 ; |
| 6383 | workp++) |
| 6384 | { |
| 6385 | idx = (int32_t)*workp; |
| 6386 | /* We already checked idx != 0 in regex_compile. */ |
| 6387 | |
| 6388 | if (idx2 != 0 && len == weights[idx]) |
| 6389 | { |
| 6390 | int cnt = 0; |
| 6391 | while (cnt < len && (weights[idx + 1 + cnt] |
| 6392 | == weights[idx2 + 1 + cnt])) |
| 6393 | ++cnt; |
| 6394 | |
| 6395 | if (cnt == len) |
| 6396 | goto char_set_matched; |
| 6397 | } |
| 6398 | } |
| 6399 | /* not matched */ |
| 6400 | d = backup_d; |
| 6401 | dend = backup_dend; |
| 6402 | } |
| 6403 | else /* (nrules == 0) */ |
| 6404 | # endif |
| 6405 | /* If we can't look up collation data, we use wcscoll |
| 6406 | instead. */ |
| 6407 | { |
| 6408 | for (workp2 = workp + equiv_class_length ; workp < workp2 ;) |
| 6409 | { |
| 6410 | const CHAR_T *backup_d = d, *backup_dend = dend; |
| 6411 | # ifdef _LIBC |
| 6412 | length = __wcslen (workp); |
| 6413 | # else |
| 6414 | length = wcslen (workp); |
| 6415 | # endif |
| 6416 | |
| 6417 | /* If wcscoll(the collating symbol, whole string) > 0, |
| 6418 | any substring of the string never match with the |
| 6419 | collating symbol. */ |
| 6420 | # ifdef _LIBC |
| 6421 | if (__wcscoll (workp, d) > 0) |
| 6422 | # else |
| 6423 | if (wcscoll (workp, d) > 0) |
| 6424 | # endif |
| 6425 | { |
| 6426 | workp += length + 1; |
| 6427 | break; |
| 6428 | } |
| 6429 | |
| 6430 | /* First, we compare the equivalence class with |
| 6431 | the first character of the string. |
| 6432 | If it don't match, we add the next character to |
| 6433 | the compare buffer in turn. */ |
| 6434 | for (i = 0 ; i < WORK_BUFFER_SIZE - 1 ; i++, d++) |
| 6435 | { |
| 6436 | int match; |
| 6437 | if (d == dend) |
| 6438 | { |
| 6439 | if (dend == end_match_2) |
| 6440 | break; |
| 6441 | d = string2; |
| 6442 | dend = end_match_2; |
| 6443 | } |
| 6444 | |
| 6445 | /* add next character to the compare buffer. */ |
| 6446 | str_buf[i] = TRANSLATE(*d); |
| 6447 | str_buf[i+1] = '\0'; |
| 6448 | |
| 6449 | # ifdef _LIBC |
| 6450 | match = __wcscoll (workp, str_buf); |
| 6451 | # else |
| 6452 | match = wcscoll (workp, str_buf); |
| 6453 | # endif |
| 6454 | |
| 6455 | if (match == 0) |
| 6456 | goto char_set_matched; |
| 6457 | |
| 6458 | if (match < 0) |
| 6459 | /* (str_buf > workp) indicate (str_buf + X > workp), |
| 6460 | because for all X (str_buf + X > str_buf). |
| 6461 | So we don't need continue this loop. */ |
| 6462 | break; |
| 6463 | |
| 6464 | /* Otherwise(str_buf < workp), |
| 6465 | (str_buf+next_character) may equals (workp). |
| 6466 | So we continue this loop. */ |
| 6467 | } |
| 6468 | /* not matched */ |
| 6469 | d = backup_d; |
| 6470 | dend = backup_dend; |
| 6471 | workp += length + 1; |
| 6472 | } |
| 6473 | } |
| 6474 | |
| 6475 | /* match with char_range? */ |
| 6476 | # ifdef _LIBC |
| 6477 | if (nrules != 0) |
| 6478 | { |
| 6479 | uint32_t collseqval; |
| 6480 | const char *collseq = (const char *) |
| 6481 | _NL_CURRENT(LC_COLLATE, _NL_COLLATE_COLLSEQWC); |
| 6482 | |
| 6483 | collseqval = collseq_table_lookup (collseq, c); |
| 6484 | |
| 6485 | for (; workp < p - chars_length ;) |
| 6486 | { |
| 6487 | uint32_t start_val, end_val; |
| 6488 | |
| 6489 | /* We already compute the collation sequence value |
| 6490 | of the characters (or collating symbols). */ |
| 6491 | start_val = (uint32_t) *workp++; /* range_start */ |
| 6492 | end_val = (uint32_t) *workp++; /* range_end */ |
| 6493 | |
| 6494 | if (start_val <= collseqval && collseqval <= end_val) |
| 6495 | goto char_set_matched; |
| 6496 | } |
| 6497 | } |
| 6498 | else |
| 6499 | # endif |
| 6500 | { |
| 6501 | /* We set range_start_char at str_buf[0], range_end_char |
| 6502 | at str_buf[4], and compared char at str_buf[2]. */ |
| 6503 | str_buf[1] = 0; |
| 6504 | str_buf[2] = c; |
| 6505 | str_buf[3] = 0; |
| 6506 | str_buf[5] = 0; |
| 6507 | for (; workp < p - chars_length ;) |
| 6508 | { |
| 6509 | wchar_t *range_start_char, *range_end_char; |
| 6510 | |
| 6511 | /* match if (range_start_char <= c <= range_end_char). */ |
| 6512 | |
| 6513 | /* If range_start(or end) < 0, we assume -range_start(end) |
| 6514 | is the offset of the collating symbol which is specified |
| 6515 | as the character of the range start(end). */ |
| 6516 | |
| 6517 | /* range_start */ |
| 6518 | if (*workp < 0) |
| 6519 | range_start_char = charset_top - (*workp++); |
| 6520 | else |
| 6521 | { |
| 6522 | str_buf[0] = *workp++; |
| 6523 | range_start_char = str_buf; |
| 6524 | } |
| 6525 | |
| 6526 | /* range_end */ |
| 6527 | if (*workp < 0) |
| 6528 | range_end_char = charset_top - (*workp++); |
| 6529 | else |
| 6530 | { |
| 6531 | str_buf[4] = *workp++; |
| 6532 | range_end_char = str_buf + 4; |
| 6533 | } |
| 6534 | |
| 6535 | # ifdef _LIBC |
| 6536 | if (__wcscoll (range_start_char, str_buf+2) <= 0 |
| 6537 | && __wcscoll (str_buf+2, range_end_char) <= 0) |
| 6538 | # else |
| 6539 | if (wcscoll (range_start_char, str_buf+2) <= 0 |
| 6540 | && wcscoll (str_buf+2, range_end_char) <= 0) |
| 6541 | # endif |
| 6542 | goto char_set_matched; |
| 6543 | } |
| 6544 | } |
| 6545 | |
| 6546 | /* match with char? */ |
| 6547 | for (; workp < p ; workp++) |
| 6548 | if (c == *workp) |
| 6549 | goto char_set_matched; |
| 6550 | |
| 6551 | negate = !negate; |
| 6552 | |
| 6553 | char_set_matched: |
| 6554 | if (negate) goto fail; |
| 6555 | #else |
| 6556 | /* Cast to `unsigned' instead of `unsigned char' in case the |
| 6557 | bit list is a full 32 bytes long. */ |
| 6558 | if (c < (unsigned) (*p * BYTEWIDTH) |
| 6559 | && p[1 + c / BYTEWIDTH] & (1 << (c % BYTEWIDTH))) |
| 6560 | negate = !negate; |
| 6561 | |
| 6562 | p += 1 + *p; |
| 6563 | |
| 6564 | if (!negate) goto fail; |
| 6565 | #undef WORK_BUFFER_SIZE |
| 6566 | #endif /* WCHAR */ |
| 6567 | SET_REGS_MATCHED (); |
| 6568 | d++; |
| 6569 | break; |
| 6570 | } |
| 6571 | |
| 6572 | |
| 6573 | /* The beginning of a group is represented by start_memory. |
| 6574 | The arguments are the register number in the next byte, and the |
| 6575 | number of groups inner to this one in the next. The text |
| 6576 | matched within the group is recorded (in the internal |
| 6577 | registers data structure) under the register number. */ |
| 6578 | case start_memory: |
| 6579 | DEBUG_PRINT3 ("EXECUTING start_memory %ld (%ld):\n", |
| 6580 | (long int) *p, (long int) p[1]); |
| 6581 | |
| 6582 | /* Find out if this group can match the empty string. */ |
| 6583 | p1 = p; /* To send to group_match_null_string_p. */ |
| 6584 | |
| 6585 | if (REG_MATCH_NULL_STRING_P (reg_info[*p]) == MATCH_NULL_UNSET_VALUE) |
| 6586 | REG_MATCH_NULL_STRING_P (reg_info[*p]) |
| 6587 | = PREFIX(group_match_null_string_p) (&p1, pend, reg_info); |
| 6588 | |
| 6589 | /* Save the position in the string where we were the last time |
| 6590 | we were at this open-group operator in case the group is |
| 6591 | operated upon by a repetition operator, e.g., with `(a*)*b' |
| 6592 | against `ab'; then we want to ignore where we are now in |
| 6593 | the string in case this attempt to match fails. */ |
| 6594 | old_regstart[*p] = REG_MATCH_NULL_STRING_P (reg_info[*p]) |
| 6595 | ? REG_UNSET (regstart[*p]) ? d : regstart[*p] |
| 6596 | : regstart[*p]; |
| 6597 | DEBUG_PRINT2 (" old_regstart: %d\n", |
| 6598 | POINTER_TO_OFFSET (old_regstart[*p])); |
| 6599 | |
| 6600 | regstart[*p] = d; |
| 6601 | DEBUG_PRINT2 (" regstart: %d\n", POINTER_TO_OFFSET (regstart[*p])); |
| 6602 | |
| 6603 | IS_ACTIVE (reg_info[*p]) = 1; |
| 6604 | MATCHED_SOMETHING (reg_info[*p]) = 0; |
| 6605 | |
| 6606 | /* Clear this whenever we change the register activity status. */ |
| 6607 | set_regs_matched_done = 0; |
| 6608 | |
| 6609 | /* This is the new highest active register. */ |
| 6610 | highest_active_reg = *p; |
| 6611 | |
| 6612 | /* If nothing was active before, this is the new lowest active |
| 6613 | register. */ |
| 6614 | if (lowest_active_reg == NO_LOWEST_ACTIVE_REG) |
| 6615 | lowest_active_reg = *p; |
| 6616 | |
| 6617 | /* Move past the register number and inner group count. */ |
| 6618 | p += 2; |
| 6619 | just_past_start_mem = p; |
| 6620 | |
| 6621 | break; |
| 6622 | |
| 6623 | |
| 6624 | /* The stop_memory opcode represents the end of a group. Its |
| 6625 | arguments are the same as start_memory's: the register |
| 6626 | number, and the number of inner groups. */ |
| 6627 | case stop_memory: |
| 6628 | DEBUG_PRINT3 ("EXECUTING stop_memory %ld (%ld):\n", |
| 6629 | (long int) *p, (long int) p[1]); |
| 6630 | |
| 6631 | /* We need to save the string position the last time we were at |
| 6632 | this close-group operator in case the group is operated |
| 6633 | upon by a repetition operator, e.g., with `((a*)*(b*)*)*' |
| 6634 | against `aba'; then we want to ignore where we are now in |
| 6635 | the string in case this attempt to match fails. */ |
| 6636 | old_regend[*p] = REG_MATCH_NULL_STRING_P (reg_info[*p]) |
| 6637 | ? REG_UNSET (regend[*p]) ? d : regend[*p] |
| 6638 | : regend[*p]; |
| 6639 | DEBUG_PRINT2 (" old_regend: %d\n", |
| 6640 | POINTER_TO_OFFSET (old_regend[*p])); |
| 6641 | |
| 6642 | regend[*p] = d; |
| 6643 | DEBUG_PRINT2 (" regend: %d\n", POINTER_TO_OFFSET (regend[*p])); |
| 6644 | |
| 6645 | /* This register isn't active anymore. */ |
| 6646 | IS_ACTIVE (reg_info[*p]) = 0; |
| 6647 | |
| 6648 | /* Clear this whenever we change the register activity status. */ |
| 6649 | set_regs_matched_done = 0; |
| 6650 | |
| 6651 | /* If this was the only register active, nothing is active |
| 6652 | anymore. */ |
| 6653 | if (lowest_active_reg == highest_active_reg) |
| 6654 | { |
| 6655 | lowest_active_reg = NO_LOWEST_ACTIVE_REG; |
| 6656 | highest_active_reg = NO_HIGHEST_ACTIVE_REG; |
| 6657 | } |
| 6658 | else |
| 6659 | { /* We must scan for the new highest active register, since |
| 6660 | it isn't necessarily one less than now: consider |
| 6661 | (a(b)c(d(e)f)g). When group 3 ends, after the f), the |
| 6662 | new highest active register is 1. */ |
| 6663 | UCHAR_T r = *p - 1; |
| 6664 | while (r > 0 && !IS_ACTIVE (reg_info[r])) |
| 6665 | r--; |
| 6666 | |
| 6667 | /* If we end up at register zero, that means that we saved |
| 6668 | the registers as the result of an `on_failure_jump', not |
| 6669 | a `start_memory', and we jumped to past the innermost |
| 6670 | `stop_memory'. For example, in ((.)*) we save |
| 6671 | registers 1 and 2 as a result of the *, but when we pop |
| 6672 | back to the second ), we are at the stop_memory 1. |
| 6673 | Thus, nothing is active. */ |
| 6674 | if (r == 0) |
| 6675 | { |
| 6676 | lowest_active_reg = NO_LOWEST_ACTIVE_REG; |
| 6677 | highest_active_reg = NO_HIGHEST_ACTIVE_REG; |
| 6678 | } |
| 6679 | else |
| 6680 | highest_active_reg = r; |
| 6681 | } |
| 6682 | |
| 6683 | /* If just failed to match something this time around with a |
| 6684 | group that's operated on by a repetition operator, try to |
| 6685 | force exit from the ``loop'', and restore the register |
| 6686 | information for this group that we had before trying this |
| 6687 | last match. */ |
| 6688 | if ((!MATCHED_SOMETHING (reg_info[*p]) |
| 6689 | || just_past_start_mem == p - 1) |
| 6690 | && (p + 2) < pend) |
| 6691 | { |
| 6692 | boolean is_a_jump_n = false; |
| 6693 | |
| 6694 | p1 = p + 2; |
| 6695 | mcnt = 0; |
| 6696 | switch ((re_opcode_t) *p1++) |
| 6697 | { |
| 6698 | case jump_n: |
| 6699 | is_a_jump_n = true; |
| 6700 | case pop_failure_jump: |
| 6701 | case maybe_pop_jump: |
| 6702 | case jump: |
| 6703 | case dummy_failure_jump: |
| 6704 | EXTRACT_NUMBER_AND_INCR (mcnt, p1); |
| 6705 | if (is_a_jump_n) |
| 6706 | p1 += OFFSET_ADDRESS_SIZE; |
| 6707 | break; |
| 6708 | |
| 6709 | default: |
| 6710 | /* do nothing */ ; |
| 6711 | } |
| 6712 | p1 += mcnt; |
| 6713 | |
| 6714 | /* If the next operation is a jump backwards in the pattern |
| 6715 | to an on_failure_jump right before the start_memory |
| 6716 | corresponding to this stop_memory, exit from the loop |
| 6717 | by forcing a failure after pushing on the stack the |
| 6718 | on_failure_jump's jump in the pattern, and d. */ |
| 6719 | if (mcnt < 0 && (re_opcode_t) *p1 == on_failure_jump |
| 6720 | && (re_opcode_t) p1[1+OFFSET_ADDRESS_SIZE] == start_memory |
| 6721 | && p1[2+OFFSET_ADDRESS_SIZE] == *p) |
| 6722 | { |
| 6723 | /* If this group ever matched anything, then restore |
| 6724 | what its registers were before trying this last |
| 6725 | failed match, e.g., with `(a*)*b' against `ab' for |
| 6726 | regstart[1], and, e.g., with `((a*)*(b*)*)*' |
| 6727 | against `aba' for regend[3]. |
| 6728 | |
| 6729 | Also restore the registers for inner groups for, |
| 6730 | e.g., `((a*)(b*))*' against `aba' (register 3 would |
| 6731 | otherwise get trashed). */ |
| 6732 | |
| 6733 | if (EVER_MATCHED_SOMETHING (reg_info[*p])) |
| 6734 | { |
| 6735 | unsigned r; |
| 6736 | |
| 6737 | EVER_MATCHED_SOMETHING (reg_info[*p]) = 0; |
| 6738 | |
| 6739 | /* Restore this and inner groups' (if any) registers. */ |
| 6740 | for (r = *p; r < (unsigned) *p + (unsigned) *(p + 1); |
| 6741 | r++) |
| 6742 | { |
| 6743 | regstart[r] = old_regstart[r]; |
| 6744 | |
| 6745 | /* xx why this test? */ |
| 6746 | if (old_regend[r] >= regstart[r]) |
| 6747 | regend[r] = old_regend[r]; |
| 6748 | } |
| 6749 | } |
| 6750 | p1++; |
| 6751 | EXTRACT_NUMBER_AND_INCR (mcnt, p1); |
| 6752 | PUSH_FAILURE_POINT (p1 + mcnt, d, -2); |
| 6753 | |
| 6754 | goto fail; |
| 6755 | } |
| 6756 | } |
| 6757 | |
| 6758 | /* Move past the register number and the inner group count. */ |
| 6759 | p += 2; |
| 6760 | break; |
| 6761 | |
| 6762 | |
| 6763 | /* \<digit> has been turned into a `duplicate' command which is |
| 6764 | followed by the numeric value of <digit> as the register number. */ |
| 6765 | case duplicate: |
| 6766 | { |
| 6767 | register const CHAR_T *d2, *dend2; |
| 6768 | int regno = *p++; /* Get which register to match against. */ |
| 6769 | DEBUG_PRINT2 ("EXECUTING duplicate %d.\n", regno); |
| 6770 | |
| 6771 | /* Can't back reference a group which we've never matched. */ |
| 6772 | if (REG_UNSET (regstart[regno]) || REG_UNSET (regend[regno])) |
| 6773 | goto fail; |
| 6774 | |
| 6775 | /* Where in input to try to start matching. */ |
| 6776 | d2 = regstart[regno]; |
| 6777 | |
| 6778 | /* Where to stop matching; if both the place to start and |
| 6779 | the place to stop matching are in the same string, then |
| 6780 | set to the place to stop, otherwise, for now have to use |
| 6781 | the end of the first string. */ |
| 6782 | |
| 6783 | dend2 = ((FIRST_STRING_P (regstart[regno]) |
| 6784 | == FIRST_STRING_P (regend[regno])) |
| 6785 | ? regend[regno] : end_match_1); |
| 6786 | for (;;) |
| 6787 | { |
| 6788 | /* If necessary, advance to next segment in register |
| 6789 | contents. */ |
| 6790 | while (d2 == dend2) |
| 6791 | { |
| 6792 | if (dend2 == end_match_2) break; |
| 6793 | if (dend2 == regend[regno]) break; |
| 6794 | |
| 6795 | /* End of string1 => advance to string2. */ |
| 6796 | d2 = string2; |
| 6797 | dend2 = regend[regno]; |
| 6798 | } |
| 6799 | /* At end of register contents => success */ |
| 6800 | if (d2 == dend2) break; |
| 6801 | |
| 6802 | /* If necessary, advance to next segment in data. */ |
| 6803 | PREFETCH (); |
| 6804 | |
| 6805 | /* How many characters left in this segment to match. */ |
| 6806 | mcnt = dend - d; |
| 6807 | |
| 6808 | /* Want how many consecutive characters we can match in |
| 6809 | one shot, so, if necessary, adjust the count. */ |
| 6810 | if (mcnt > dend2 - d2) |
| 6811 | mcnt = dend2 - d2; |
| 6812 | |
| 6813 | /* Compare that many; failure if mismatch, else move |
| 6814 | past them. */ |
| 6815 | if (translate |
| 6816 | ? PREFIX(bcmp_translate) (d, d2, mcnt, translate) |
| 6817 | : memcmp (d, d2, mcnt*sizeof(UCHAR_T))) |
| 6818 | goto fail; |
| 6819 | d += mcnt, d2 += mcnt; |
| 6820 | |
| 6821 | /* Do this because we've match some characters. */ |
| 6822 | SET_REGS_MATCHED (); |
| 6823 | } |
| 6824 | } |
| 6825 | break; |
| 6826 | |
| 6827 | |
| 6828 | /* begline matches the empty string at the beginning of the string |
| 6829 | (unless `not_bol' is set in `bufp'), and, if |
| 6830 | `newline_anchor' is set, after newlines. */ |
| 6831 | case begline: |
| 6832 | DEBUG_PRINT1 ("EXECUTING begline.\n"); |
| 6833 | |
| 6834 | if (AT_STRINGS_BEG (d)) |
| 6835 | { |
| 6836 | if (!bufp->not_bol) break; |
| 6837 | } |
| 6838 | else if (d[-1] == '\n' && bufp->newline_anchor) |
| 6839 | { |
| 6840 | break; |
| 6841 | } |
| 6842 | /* In all other cases, we fail. */ |
| 6843 | goto fail; |
| 6844 | |
| 6845 | |
| 6846 | /* endline is the dual of begline. */ |
| 6847 | case endline: |
| 6848 | DEBUG_PRINT1 ("EXECUTING endline.\n"); |
| 6849 | |
| 6850 | if (AT_STRINGS_END (d)) |
| 6851 | { |
| 6852 | if (!bufp->not_eol) break; |
| 6853 | } |
| 6854 | |
| 6855 | /* We have to ``prefetch'' the next character. */ |
| 6856 | else if ((d == end1 ? *string2 : *d) == '\n' |
| 6857 | && bufp->newline_anchor) |
| 6858 | { |
| 6859 | break; |
| 6860 | } |
| 6861 | goto fail; |
| 6862 | |
| 6863 | |
| 6864 | /* Match at the very beginning of the data. */ |
| 6865 | case begbuf: |
| 6866 | DEBUG_PRINT1 ("EXECUTING begbuf.\n"); |
| 6867 | if (AT_STRINGS_BEG (d)) |
| 6868 | break; |
| 6869 | goto fail; |
| 6870 | |
| 6871 | |
| 6872 | /* Match at the very end of the data. */ |
| 6873 | case endbuf: |
| 6874 | DEBUG_PRINT1 ("EXECUTING endbuf.\n"); |
| 6875 | if (AT_STRINGS_END (d)) |
| 6876 | break; |
| 6877 | goto fail; |
| 6878 | |
| 6879 | |
| 6880 | /* on_failure_keep_string_jump is used to optimize `.*\n'. It |
| 6881 | pushes NULL as the value for the string on the stack. Then |
| 6882 | `pop_failure_point' will keep the current value for the |
| 6883 | string, instead of restoring it. To see why, consider |
| 6884 | matching `foo\nbar' against `.*\n'. The .* matches the foo; |
| 6885 | then the . fails against the \n. But the next thing we want |
| 6886 | to do is match the \n against the \n; if we restored the |
| 6887 | string value, we would be back at the foo. |
| 6888 | |
| 6889 | Because this is used only in specific cases, we don't need to |
| 6890 | check all the things that `on_failure_jump' does, to make |
| 6891 | sure the right things get saved on the stack. Hence we don't |
| 6892 | share its code. The only reason to push anything on the |
| 6893 | stack at all is that otherwise we would have to change |
| 6894 | `anychar's code to do something besides goto fail in this |
| 6895 | case; that seems worse than this. */ |
| 6896 | case on_failure_keep_string_jump: |
| 6897 | DEBUG_PRINT1 ("EXECUTING on_failure_keep_string_jump"); |
| 6898 | |
| 6899 | EXTRACT_NUMBER_AND_INCR (mcnt, p); |
| 6900 | #ifdef _LIBC |
| 6901 | DEBUG_PRINT3 (" %d (to %p):\n", mcnt, p + mcnt); |
| 6902 | #else |
| 6903 | DEBUG_PRINT3 (" %d (to 0x%x):\n", mcnt, p + mcnt); |
| 6904 | #endif |
| 6905 | |
| 6906 | PUSH_FAILURE_POINT (p + mcnt, NULL, -2); |
| 6907 | break; |
| 6908 | |
| 6909 | |
| 6910 | /* Uses of on_failure_jump: |
| 6911 | |
| 6912 | Each alternative starts with an on_failure_jump that points |
| 6913 | to the beginning of the next alternative. Each alternative |
| 6914 | except the last ends with a jump that in effect jumps past |
| 6915 | the rest of the alternatives. (They really jump to the |
| 6916 | ending jump of the following alternative, because tensioning |
| 6917 | these jumps is a hassle.) |
| 6918 | |
| 6919 | Repeats start with an on_failure_jump that points past both |
| 6920 | the repetition text and either the following jump or |
| 6921 | pop_failure_jump back to this on_failure_jump. */ |
| 6922 | case on_failure_jump: |
| 6923 | on_failure: |
| 6924 | DEBUG_PRINT1 ("EXECUTING on_failure_jump"); |
| 6925 | |
| 6926 | EXTRACT_NUMBER_AND_INCR (mcnt, p); |
| 6927 | #ifdef _LIBC |
| 6928 | DEBUG_PRINT3 (" %d (to %p)", mcnt, p + mcnt); |
| 6929 | #else |
| 6930 | DEBUG_PRINT3 (" %d (to 0x%x)", mcnt, p + mcnt); |
| 6931 | #endif |
| 6932 | |
| 6933 | /* If this on_failure_jump comes right before a group (i.e., |
| 6934 | the original * applied to a group), save the information |
| 6935 | for that group and all inner ones, so that if we fail back |
| 6936 | to this point, the group's information will be correct. |
| 6937 | For example, in \(a*\)*\1, we need the preceding group, |
| 6938 | and in \(zz\(a*\)b*\)\2, we need the inner group. */ |
| 6939 | |
| 6940 | /* We can't use `p' to check ahead because we push |
| 6941 | a failure point to `p + mcnt' after we do this. */ |
| 6942 | p1 = p; |
| 6943 | |
| 6944 | /* We need to skip no_op's before we look for the |
| 6945 | start_memory in case this on_failure_jump is happening as |
| 6946 | the result of a completed succeed_n, as in \(a\)\{1,3\}b\1 |
| 6947 | against aba. */ |
| 6948 | while (p1 < pend && (re_opcode_t) *p1 == no_op) |
| 6949 | p1++; |
| 6950 | |
| 6951 | if (p1 < pend && (re_opcode_t) *p1 == start_memory) |
| 6952 | { |
| 6953 | /* We have a new highest active register now. This will |
| 6954 | get reset at the start_memory we are about to get to, |
| 6955 | but we will have saved all the registers relevant to |
| 6956 | this repetition op, as described above. */ |
| 6957 | highest_active_reg = *(p1 + 1) + *(p1 + 2); |
| 6958 | if (lowest_active_reg == NO_LOWEST_ACTIVE_REG) |
| 6959 | lowest_active_reg = *(p1 + 1); |
| 6960 | } |
| 6961 | |
| 6962 | DEBUG_PRINT1 (":\n"); |
| 6963 | PUSH_FAILURE_POINT (p + mcnt, d, -2); |
| 6964 | break; |
| 6965 | |
| 6966 | |
| 6967 | /* A smart repeat ends with `maybe_pop_jump'. |
| 6968 | We change it to either `pop_failure_jump' or `jump'. */ |
| 6969 | case maybe_pop_jump: |
| 6970 | EXTRACT_NUMBER_AND_INCR (mcnt, p); |
| 6971 | DEBUG_PRINT2 ("EXECUTING maybe_pop_jump %d.\n", mcnt); |
| 6972 | { |
| 6973 | register UCHAR_T *p2 = p; |
| 6974 | |
| 6975 | /* Compare the beginning of the repeat with what in the |
| 6976 | pattern follows its end. If we can establish that there |
| 6977 | is nothing that they would both match, i.e., that we |
| 6978 | would have to backtrack because of (as in, e.g., `a*a') |
| 6979 | then we can change to pop_failure_jump, because we'll |
| 6980 | never have to backtrack. |
| 6981 | |
| 6982 | This is not true in the case of alternatives: in |
| 6983 | `(a|ab)*' we do need to backtrack to the `ab' alternative |
| 6984 | (e.g., if the string was `ab'). But instead of trying to |
| 6985 | detect that here, the alternative has put on a dummy |
| 6986 | failure point which is what we will end up popping. */ |
| 6987 | |
| 6988 | /* Skip over open/close-group commands. |
| 6989 | If what follows this loop is a ...+ construct, |
| 6990 | look at what begins its body, since we will have to |
| 6991 | match at least one of that. */ |
| 6992 | while (1) |
| 6993 | { |
| 6994 | if (p2 + 2 < pend |
| 6995 | && ((re_opcode_t) *p2 == stop_memory |
| 6996 | || (re_opcode_t) *p2 == start_memory)) |
| 6997 | p2 += 3; |
| 6998 | else if (p2 + 2 + 2 * OFFSET_ADDRESS_SIZE < pend |
| 6999 | && (re_opcode_t) *p2 == dummy_failure_jump) |
| 7000 | p2 += 2 + 2 * OFFSET_ADDRESS_SIZE; |
| 7001 | else |
| 7002 | break; |
| 7003 | } |
| 7004 | |
| 7005 | p1 = p + mcnt; |
| 7006 | /* p1[0] ... p1[2] are the `on_failure_jump' corresponding |
| 7007 | to the `maybe_finalize_jump' of this case. Examine what |
| 7008 | follows. */ |
| 7009 | |
| 7010 | /* If we're at the end of the pattern, we can change. */ |
| 7011 | if (p2 == pend) |
| 7012 | { |
| 7013 | /* Consider what happens when matching ":\(.*\)" |
| 7014 | against ":/". I don't really understand this code |
| 7015 | yet. */ |
| 7016 | p[-(1+OFFSET_ADDRESS_SIZE)] = (UCHAR_T) |
| 7017 | pop_failure_jump; |
| 7018 | DEBUG_PRINT1 |
| 7019 | (" End of pattern: change to `pop_failure_jump'.\n"); |
| 7020 | } |
| 7021 | |
| 7022 | else if ((re_opcode_t) *p2 == exactn |
| 7023 | #ifdef MBS_SUPPORT |
| 7024 | || (re_opcode_t) *p2 == exactn_bin |
| 7025 | #endif |
| 7026 | || (bufp->newline_anchor && (re_opcode_t) *p2 == endline)) |
| 7027 | { |
| 7028 | register UCHAR_T c |
| 7029 | = *p2 == (UCHAR_T) endline ? '\n' : p2[2]; |
| 7030 | |
| 7031 | if (((re_opcode_t) p1[1+OFFSET_ADDRESS_SIZE] == exactn |
| 7032 | #ifdef MBS_SUPPORT |
| 7033 | || (re_opcode_t) p1[1+OFFSET_ADDRESS_SIZE] == exactn_bin |
| 7034 | #endif |
| 7035 | ) && p1[3+OFFSET_ADDRESS_SIZE] != c) |
| 7036 | { |
| 7037 | p[-(1+OFFSET_ADDRESS_SIZE)] = (UCHAR_T) |
| 7038 | pop_failure_jump; |
| 7039 | #ifdef WCHAR |
| 7040 | DEBUG_PRINT3 (" %C != %C => pop_failure_jump.\n", |
| 7041 | (wint_t) c, |
| 7042 | (wint_t) p1[3+OFFSET_ADDRESS_SIZE]); |
| 7043 | #else |
| 7044 | DEBUG_PRINT3 (" %c != %c => pop_failure_jump.\n", |
| 7045 | (char) c, |
| 7046 | (char) p1[3+OFFSET_ADDRESS_SIZE]); |
| 7047 | #endif |
| 7048 | } |
| 7049 | |
| 7050 | #ifndef WCHAR |
| 7051 | else if ((re_opcode_t) p1[3] == charset |
| 7052 | || (re_opcode_t) p1[3] == charset_not) |
| 7053 | { |
| 7054 | int negate = (re_opcode_t) p1[3] == charset_not; |
| 7055 | |
| 7056 | if (c < (unsigned) (p1[4] * BYTEWIDTH) |
| 7057 | && p1[5 + c / BYTEWIDTH] & (1 << (c % BYTEWIDTH))) |
| 7058 | negate = !negate; |
| 7059 | |
| 7060 | /* `negate' is equal to 1 if c would match, which means |
| 7061 | that we can't change to pop_failure_jump. */ |
| 7062 | if (!negate) |
| 7063 | { |
| 7064 | p[-3] = (unsigned char) pop_failure_jump; |
| 7065 | DEBUG_PRINT1 (" No match => pop_failure_jump.\n"); |
| 7066 | } |
| 7067 | } |
| 7068 | #endif /* not WCHAR */ |
| 7069 | } |
| 7070 | #ifndef WCHAR |
| 7071 | else if ((re_opcode_t) *p2 == charset) |
| 7072 | { |
| 7073 | /* We win if the first character of the loop is not part |
| 7074 | of the charset. */ |
| 7075 | if ((re_opcode_t) p1[3] == exactn |
| 7076 | && ! ((int) p2[1] * BYTEWIDTH > (int) p1[5] |
| 7077 | && (p2[2 + p1[5] / BYTEWIDTH] |
| 7078 | & (1 << (p1[5] % BYTEWIDTH))))) |
| 7079 | { |
| 7080 | p[-3] = (unsigned char) pop_failure_jump; |
| 7081 | DEBUG_PRINT1 (" No match => pop_failure_jump.\n"); |
| 7082 | } |
| 7083 | |
| 7084 | else if ((re_opcode_t) p1[3] == charset_not) |
| 7085 | { |
| 7086 | int idx; |
| 7087 | /* We win if the charset_not inside the loop |
| 7088 | lists every character listed in the charset after. */ |
| 7089 | for (idx = 0; idx < (int) p2[1]; idx++) |
| 7090 | if (! (p2[2 + idx] == 0 |
| 7091 | || (idx < (int) p1[4] |
| 7092 | && ((p2[2 + idx] & ~ p1[5 + idx]) == 0)))) |
| 7093 | break; |
| 7094 | |
| 7095 | if (idx == p2[1]) |
| 7096 | { |
| 7097 | p[-3] = (unsigned char) pop_failure_jump; |
| 7098 | DEBUG_PRINT1 (" No match => pop_failure_jump.\n"); |
| 7099 | } |
| 7100 | } |
| 7101 | else if ((re_opcode_t) p1[3] == charset) |
| 7102 | { |
| 7103 | int idx; |
| 7104 | /* We win if the charset inside the loop |
| 7105 | has no overlap with the one after the loop. */ |
| 7106 | for (idx = 0; |
| 7107 | idx < (int) p2[1] && idx < (int) p1[4]; |
| 7108 | idx++) |
| 7109 | if ((p2[2 + idx] & p1[5 + idx]) != 0) |
| 7110 | break; |
| 7111 | |
| 7112 | if (idx == p2[1] || idx == p1[4]) |
| 7113 | { |
| 7114 | p[-3] = (unsigned char) pop_failure_jump; |
| 7115 | DEBUG_PRINT1 (" No match => pop_failure_jump.\n"); |
| 7116 | } |
| 7117 | } |
| 7118 | } |
| 7119 | #endif /* not WCHAR */ |
| 7120 | } |
| 7121 | p -= OFFSET_ADDRESS_SIZE; /* Point at relative address again. */ |
| 7122 | if ((re_opcode_t) p[-1] != pop_failure_jump) |
| 7123 | { |
| 7124 | p[-1] = (UCHAR_T) jump; |
| 7125 | DEBUG_PRINT1 (" Match => jump.\n"); |
| 7126 | goto unconditional_jump; |
| 7127 | } |
| 7128 | /* Note fall through. */ |
| 7129 | |
| 7130 | |
| 7131 | /* The end of a simple repeat has a pop_failure_jump back to |
| 7132 | its matching on_failure_jump, where the latter will push a |
| 7133 | failure point. The pop_failure_jump takes off failure |
| 7134 | points put on by this pop_failure_jump's matching |
| 7135 | on_failure_jump; we got through the pattern to here from the |
| 7136 | matching on_failure_jump, so didn't fail. */ |
| 7137 | case pop_failure_jump: |
| 7138 | { |
| 7139 | /* We need to pass separate storage for the lowest and |
| 7140 | highest registers, even though we don't care about the |
| 7141 | actual values. Otherwise, we will restore only one |
| 7142 | register from the stack, since lowest will == highest in |
| 7143 | `pop_failure_point'. */ |
| 7144 | active_reg_t dummy_low_reg, dummy_high_reg; |
| 7145 | UCHAR_T *pdummy ATTRIBUTE_UNUSED = NULL; |
| 7146 | const CHAR_T *sdummy ATTRIBUTE_UNUSED = NULL; |
| 7147 | |
| 7148 | DEBUG_PRINT1 ("EXECUTING pop_failure_jump.\n"); |
| 7149 | POP_FAILURE_POINT (sdummy, pdummy, |
| 7150 | dummy_low_reg, dummy_high_reg, |
| 7151 | reg_dummy, reg_dummy, reg_info_dummy); |
| 7152 | } |
| 7153 | /* Note fall through. */ |
| 7154 | |
| 7155 | unconditional_jump: |
| 7156 | #ifdef _LIBC |
| 7157 | DEBUG_PRINT2 ("\n%p: ", p); |
| 7158 | #else |
| 7159 | DEBUG_PRINT2 ("\n0x%x: ", p); |
| 7160 | #endif |
| 7161 | /* Note fall through. */ |
| 7162 | |
| 7163 | /* Unconditionally jump (without popping any failure points). */ |
| 7164 | case jump: |
| 7165 | EXTRACT_NUMBER_AND_INCR (mcnt, p); /* Get the amount to jump. */ |
| 7166 | DEBUG_PRINT2 ("EXECUTING jump %d ", mcnt); |
| 7167 | p += mcnt; /* Do the jump. */ |
| 7168 | #ifdef _LIBC |
| 7169 | DEBUG_PRINT2 ("(to %p).\n", p); |
| 7170 | #else |
| 7171 | DEBUG_PRINT2 ("(to 0x%x).\n", p); |
| 7172 | #endif |
| 7173 | break; |
| 7174 | |
| 7175 | |
| 7176 | /* We need this opcode so we can detect where alternatives end |
| 7177 | in `group_match_null_string_p' et al. */ |
| 7178 | case jump_past_alt: |
| 7179 | DEBUG_PRINT1 ("EXECUTING jump_past_alt.\n"); |
| 7180 | goto unconditional_jump; |
| 7181 | |
| 7182 | |
| 7183 | /* Normally, the on_failure_jump pushes a failure point, which |
| 7184 | then gets popped at pop_failure_jump. We will end up at |
| 7185 | pop_failure_jump, also, and with a pattern of, say, `a+', we |
| 7186 | are skipping over the on_failure_jump, so we have to push |
| 7187 | something meaningless for pop_failure_jump to pop. */ |
| 7188 | case dummy_failure_jump: |
| 7189 | DEBUG_PRINT1 ("EXECUTING dummy_failure_jump.\n"); |
| 7190 | /* It doesn't matter what we push for the string here. What |
| 7191 | the code at `fail' tests is the value for the pattern. */ |
| 7192 | PUSH_FAILURE_POINT (NULL, NULL, -2); |
| 7193 | goto unconditional_jump; |
| 7194 | |
| 7195 | |
| 7196 | /* At the end of an alternative, we need to push a dummy failure |
| 7197 | point in case we are followed by a `pop_failure_jump', because |
| 7198 | we don't want the failure point for the alternative to be |
| 7199 | popped. For example, matching `(a|ab)*' against `aab' |
| 7200 | requires that we match the `ab' alternative. */ |
| 7201 | case push_dummy_failure: |
| 7202 | DEBUG_PRINT1 ("EXECUTING push_dummy_failure.\n"); |
| 7203 | /* See comments just above at `dummy_failure_jump' about the |
| 7204 | two zeroes. */ |
| 7205 | PUSH_FAILURE_POINT (NULL, NULL, -2); |
| 7206 | break; |
| 7207 | |
| 7208 | /* Have to succeed matching what follows at least n times. |
| 7209 | After that, handle like `on_failure_jump'. */ |
| 7210 | case succeed_n: |
| 7211 | EXTRACT_NUMBER (mcnt, p + OFFSET_ADDRESS_SIZE); |
| 7212 | DEBUG_PRINT2 ("EXECUTING succeed_n %d.\n", mcnt); |
| 7213 | |
| 7214 | assert (mcnt >= 0); |
| 7215 | /* Originally, this is how many times we HAVE to succeed. */ |
| 7216 | if (mcnt > 0) |
| 7217 | { |
| 7218 | mcnt--; |
| 7219 | p += OFFSET_ADDRESS_SIZE; |
| 7220 | STORE_NUMBER_AND_INCR (p, mcnt); |
| 7221 | #ifdef _LIBC |
| 7222 | DEBUG_PRINT3 (" Setting %p to %d.\n", p - OFFSET_ADDRESS_SIZE |
| 7223 | , mcnt); |
| 7224 | #else |
| 7225 | DEBUG_PRINT3 (" Setting 0x%x to %d.\n", p - OFFSET_ADDRESS_SIZE |
| 7226 | , mcnt); |
| 7227 | #endif |
| 7228 | } |
| 7229 | else if (mcnt == 0) |
| 7230 | { |
| 7231 | #ifdef _LIBC |
| 7232 | DEBUG_PRINT2 (" Setting two bytes from %p to no_op.\n", |
| 7233 | p + OFFSET_ADDRESS_SIZE); |
| 7234 | #else |
| 7235 | DEBUG_PRINT2 (" Setting two bytes from 0x%x to no_op.\n", |
| 7236 | p + OFFSET_ADDRESS_SIZE); |
| 7237 | #endif /* _LIBC */ |
| 7238 | |
| 7239 | #ifdef WCHAR |
| 7240 | p[1] = (UCHAR_T) no_op; |
| 7241 | #else |
| 7242 | p[2] = (UCHAR_T) no_op; |
| 7243 | p[3] = (UCHAR_T) no_op; |
| 7244 | #endif /* WCHAR */ |
| 7245 | goto on_failure; |
| 7246 | } |
| 7247 | break; |
| 7248 | |
| 7249 | case jump_n: |
| 7250 | EXTRACT_NUMBER (mcnt, p + OFFSET_ADDRESS_SIZE); |
| 7251 | DEBUG_PRINT2 ("EXECUTING jump_n %d.\n", mcnt); |
| 7252 | |
| 7253 | /* Originally, this is how many times we CAN jump. */ |
| 7254 | if (mcnt) |
| 7255 | { |
| 7256 | mcnt--; |
| 7257 | STORE_NUMBER (p + OFFSET_ADDRESS_SIZE, mcnt); |
| 7258 | |
| 7259 | #ifdef _LIBC |
| 7260 | DEBUG_PRINT3 (" Setting %p to %d.\n", p + OFFSET_ADDRESS_SIZE, |
| 7261 | mcnt); |
| 7262 | #else |
| 7263 | DEBUG_PRINT3 (" Setting 0x%x to %d.\n", p + OFFSET_ADDRESS_SIZE, |
| 7264 | mcnt); |
| 7265 | #endif /* _LIBC */ |
| 7266 | goto unconditional_jump; |
| 7267 | } |
| 7268 | /* If don't have to jump any more, skip over the rest of command. */ |
| 7269 | else |
| 7270 | p += 2 * OFFSET_ADDRESS_SIZE; |
| 7271 | break; |
| 7272 | |
| 7273 | case set_number_at: |
| 7274 | { |
| 7275 | DEBUG_PRINT1 ("EXECUTING set_number_at.\n"); |
| 7276 | |
| 7277 | EXTRACT_NUMBER_AND_INCR (mcnt, p); |
| 7278 | p1 = p + mcnt; |
| 7279 | EXTRACT_NUMBER_AND_INCR (mcnt, p); |
| 7280 | #ifdef _LIBC |
| 7281 | DEBUG_PRINT3 (" Setting %p to %d.\n", p1, mcnt); |
| 7282 | #else |
| 7283 | DEBUG_PRINT3 (" Setting 0x%x to %d.\n", p1, mcnt); |
| 7284 | #endif |
| 7285 | STORE_NUMBER (p1, mcnt); |
| 7286 | break; |
| 7287 | } |
| 7288 | |
| 7289 | #if 0 |
| 7290 | /* The DEC Alpha C compiler 3.x generates incorrect code for the |
| 7291 | test WORDCHAR_P (d - 1) != WORDCHAR_P (d) in the expansion of |
| 7292 | AT_WORD_BOUNDARY, so this code is disabled. Expanding the |
| 7293 | macro and introducing temporary variables works around the bug. */ |
| 7294 | |
| 7295 | case wordbound: |
| 7296 | DEBUG_PRINT1 ("EXECUTING wordbound.\n"); |
| 7297 | if (AT_WORD_BOUNDARY (d)) |
| 7298 | break; |
| 7299 | goto fail; |
| 7300 | |
| 7301 | case notwordbound: |
| 7302 | DEBUG_PRINT1 ("EXECUTING notwordbound.\n"); |
| 7303 | if (AT_WORD_BOUNDARY (d)) |
| 7304 | goto fail; |
| 7305 | break; |
| 7306 | #else |
| 7307 | case wordbound: |
| 7308 | { |
| 7309 | boolean prevchar, thischar; |
| 7310 | |
| 7311 | DEBUG_PRINT1 ("EXECUTING wordbound.\n"); |
| 7312 | if (AT_STRINGS_BEG (d) || AT_STRINGS_END (d)) |
| 7313 | break; |
| 7314 | |
| 7315 | prevchar = WORDCHAR_P (d - 1); |
| 7316 | thischar = WORDCHAR_P (d); |
| 7317 | if (prevchar != thischar) |
| 7318 | break; |
| 7319 | goto fail; |
| 7320 | } |
| 7321 | |
| 7322 | case notwordbound: |
| 7323 | { |
| 7324 | boolean prevchar, thischar; |
| 7325 | |
| 7326 | DEBUG_PRINT1 ("EXECUTING notwordbound.\n"); |
| 7327 | if (AT_STRINGS_BEG (d) || AT_STRINGS_END (d)) |
| 7328 | goto fail; |
| 7329 | |
| 7330 | prevchar = WORDCHAR_P (d - 1); |
| 7331 | thischar = WORDCHAR_P (d); |
| 7332 | if (prevchar != thischar) |
| 7333 | goto fail; |
| 7334 | break; |
| 7335 | } |
| 7336 | #endif |
| 7337 | |
| 7338 | case wordbeg: |
| 7339 | DEBUG_PRINT1 ("EXECUTING wordbeg.\n"); |
| 7340 | if (!AT_STRINGS_END (d) && WORDCHAR_P (d) |
| 7341 | && (AT_STRINGS_BEG (d) || !WORDCHAR_P (d - 1))) |
| 7342 | break; |
| 7343 | goto fail; |
| 7344 | |
| 7345 | case wordend: |
| 7346 | DEBUG_PRINT1 ("EXECUTING wordend.\n"); |
| 7347 | if (!AT_STRINGS_BEG (d) && WORDCHAR_P (d - 1) |
| 7348 | && (AT_STRINGS_END (d) || !WORDCHAR_P (d))) |
| 7349 | break; |
| 7350 | goto fail; |
| 7351 | |
| 7352 | #ifdef emacs |
| 7353 | case before_dot: |
| 7354 | DEBUG_PRINT1 ("EXECUTING before_dot.\n"); |
| 7355 | if (PTR_CHAR_POS ((unsigned char *) d) >= point) |
| 7356 | goto fail; |
| 7357 | break; |
| 7358 | |
| 7359 | case at_dot: |
| 7360 | DEBUG_PRINT1 ("EXECUTING at_dot.\n"); |
| 7361 | if (PTR_CHAR_POS ((unsigned char *) d) != point) |
| 7362 | goto fail; |
| 7363 | break; |
| 7364 | |
| 7365 | case after_dot: |
| 7366 | DEBUG_PRINT1 ("EXECUTING after_dot.\n"); |
| 7367 | if (PTR_CHAR_POS ((unsigned char *) d) <= point) |
| 7368 | goto fail; |
| 7369 | break; |
| 7370 | |
| 7371 | case syntaxspec: |
| 7372 | DEBUG_PRINT2 ("EXECUTING syntaxspec %d.\n", mcnt); |
| 7373 | mcnt = *p++; |
| 7374 | goto matchsyntax; |
| 7375 | |
| 7376 | case wordchar: |
| 7377 | DEBUG_PRINT1 ("EXECUTING Emacs wordchar.\n"); |
| 7378 | mcnt = (int) Sword; |
| 7379 | matchsyntax: |
| 7380 | PREFETCH (); |
| 7381 | /* Can't use *d++ here; SYNTAX may be an unsafe macro. */ |
| 7382 | d++; |
| 7383 | if (SYNTAX (d[-1]) != (enum syntaxcode) mcnt) |
| 7384 | goto fail; |
| 7385 | SET_REGS_MATCHED (); |
| 7386 | break; |
| 7387 | |
| 7388 | case notsyntaxspec: |
| 7389 | DEBUG_PRINT2 ("EXECUTING notsyntaxspec %d.\n", mcnt); |
| 7390 | mcnt = *p++; |
| 7391 | goto matchnotsyntax; |
| 7392 | |
| 7393 | case notwordchar: |
| 7394 | DEBUG_PRINT1 ("EXECUTING Emacs notwordchar.\n"); |
| 7395 | mcnt = (int) Sword; |
| 7396 | matchnotsyntax: |
| 7397 | PREFETCH (); |
| 7398 | /* Can't use *d++ here; SYNTAX may be an unsafe macro. */ |
| 7399 | d++; |
| 7400 | if (SYNTAX (d[-1]) == (enum syntaxcode) mcnt) |
| 7401 | goto fail; |
| 7402 | SET_REGS_MATCHED (); |
| 7403 | break; |
| 7404 | |
| 7405 | #else /* not emacs */ |
| 7406 | case wordchar: |
| 7407 | DEBUG_PRINT1 ("EXECUTING non-Emacs wordchar.\n"); |
| 7408 | PREFETCH (); |
| 7409 | if (!WORDCHAR_P (d)) |
| 7410 | goto fail; |
| 7411 | SET_REGS_MATCHED (); |
| 7412 | d++; |
| 7413 | break; |
| 7414 | |
| 7415 | case notwordchar: |
| 7416 | DEBUG_PRINT1 ("EXECUTING non-Emacs notwordchar.\n"); |
| 7417 | PREFETCH (); |
| 7418 | if (WORDCHAR_P (d)) |
| 7419 | goto fail; |
| 7420 | SET_REGS_MATCHED (); |
| 7421 | d++; |
| 7422 | break; |
| 7423 | #endif /* not emacs */ |
| 7424 | |
| 7425 | default: |
| 7426 | abort (); |
| 7427 | } |
| 7428 | continue; /* Successfully executed one pattern command; keep going. */ |
| 7429 | |
| 7430 | |
| 7431 | /* We goto here if a matching operation fails. */ |
| 7432 | fail: |
| 7433 | if (!FAIL_STACK_EMPTY ()) |
| 7434 | { /* A restart point is known. Restore to that state. */ |
| 7435 | DEBUG_PRINT1 ("\nFAIL:\n"); |
| 7436 | POP_FAILURE_POINT (d, p, |
| 7437 | lowest_active_reg, highest_active_reg, |
| 7438 | regstart, regend, reg_info); |
| 7439 | |
| 7440 | /* If this failure point is a dummy, try the next one. */ |
| 7441 | if (!p) |
| 7442 | goto fail; |
| 7443 | |
| 7444 | /* If we failed to the end of the pattern, don't examine *p. */ |
| 7445 | assert (p <= pend); |
| 7446 | if (p < pend) |
| 7447 | { |
| 7448 | boolean is_a_jump_n = false; |
| 7449 | |
| 7450 | /* If failed to a backwards jump that's part of a repetition |
| 7451 | loop, need to pop this failure point and use the next one. */ |
| 7452 | switch ((re_opcode_t) *p) |
| 7453 | { |
| 7454 | case jump_n: |
| 7455 | is_a_jump_n = true; |
| 7456 | case maybe_pop_jump: |
| 7457 | case pop_failure_jump: |
| 7458 | case jump: |
| 7459 | p1 = p + 1; |
| 7460 | EXTRACT_NUMBER_AND_INCR (mcnt, p1); |
| 7461 | p1 += mcnt; |
| 7462 | |
| 7463 | if ((is_a_jump_n && (re_opcode_t) *p1 == succeed_n) |
| 7464 | || (!is_a_jump_n |
| 7465 | && (re_opcode_t) *p1 == on_failure_jump)) |
| 7466 | goto fail; |
| 7467 | break; |
| 7468 | default: |
| 7469 | /* do nothing */ ; |
| 7470 | } |
| 7471 | } |
| 7472 | |
| 7473 | if (d >= string1 && d <= end1) |
| 7474 | dend = end_match_1; |
| 7475 | } |
| 7476 | else |
| 7477 | break; /* Matching at this starting point really fails. */ |
| 7478 | } /* for (;;) */ |
| 7479 | |
| 7480 | if (best_regs_set) |
| 7481 | goto restore_best_regs; |
| 7482 | |
| 7483 | FREE_VARIABLES (); |
| 7484 | |
| 7485 | return -1; /* Failure to match. */ |
| 7486 | } /* re_match_2 */ |
| 7487 | \f |
| 7488 | /* Subroutine definitions for re_match_2. */ |
| 7489 | |
| 7490 | |
| 7491 | /* We are passed P pointing to a register number after a start_memory. |
| 7492 | |
| 7493 | Return true if the pattern up to the corresponding stop_memory can |
| 7494 | match the empty string, and false otherwise. |
| 7495 | |
| 7496 | If we find the matching stop_memory, sets P to point to one past its number. |
| 7497 | Otherwise, sets P to an undefined byte less than or equal to END. |
| 7498 | |
| 7499 | We don't handle duplicates properly (yet). */ |
| 7500 | |
| 7501 | static boolean |
| 7502 | PREFIX(group_match_null_string_p) (UCHAR_T **p, UCHAR_T *end, |
| 7503 | PREFIX(register_info_type) *reg_info) |
| 7504 | { |
| 7505 | int mcnt; |
| 7506 | /* Point to after the args to the start_memory. */ |
| 7507 | UCHAR_T *p1 = *p + 2; |
| 7508 | |
| 7509 | while (p1 < end) |
| 7510 | { |
| 7511 | /* Skip over opcodes that can match nothing, and return true or |
| 7512 | false, as appropriate, when we get to one that can't, or to the |
| 7513 | matching stop_memory. */ |
| 7514 | |
| 7515 | switch ((re_opcode_t) *p1) |
| 7516 | { |
| 7517 | /* Could be either a loop or a series of alternatives. */ |
| 7518 | case on_failure_jump: |
| 7519 | p1++; |
| 7520 | EXTRACT_NUMBER_AND_INCR (mcnt, p1); |
| 7521 | |
| 7522 | /* If the next operation is not a jump backwards in the |
| 7523 | pattern. */ |
| 7524 | |
| 7525 | if (mcnt >= 0) |
| 7526 | { |
| 7527 | /* Go through the on_failure_jumps of the alternatives, |
| 7528 | seeing if any of the alternatives cannot match nothing. |
| 7529 | The last alternative starts with only a jump, |
| 7530 | whereas the rest start with on_failure_jump and end |
| 7531 | with a jump, e.g., here is the pattern for `a|b|c': |
| 7532 | |
| 7533 | /on_failure_jump/0/6/exactn/1/a/jump_past_alt/0/6 |
| 7534 | /on_failure_jump/0/6/exactn/1/b/jump_past_alt/0/3 |
| 7535 | /exactn/1/c |
| 7536 | |
| 7537 | So, we have to first go through the first (n-1) |
| 7538 | alternatives and then deal with the last one separately. */ |
| 7539 | |
| 7540 | |
| 7541 | /* Deal with the first (n-1) alternatives, which start |
| 7542 | with an on_failure_jump (see above) that jumps to right |
| 7543 | past a jump_past_alt. */ |
| 7544 | |
| 7545 | while ((re_opcode_t) p1[mcnt-(1+OFFSET_ADDRESS_SIZE)] == |
| 7546 | jump_past_alt) |
| 7547 | { |
| 7548 | /* `mcnt' holds how many bytes long the alternative |
| 7549 | is, including the ending `jump_past_alt' and |
| 7550 | its number. */ |
| 7551 | |
| 7552 | if (!PREFIX(alt_match_null_string_p) (p1, p1 + mcnt - |
| 7553 | (1 + OFFSET_ADDRESS_SIZE), |
| 7554 | reg_info)) |
| 7555 | return false; |
| 7556 | |
| 7557 | /* Move to right after this alternative, including the |
| 7558 | jump_past_alt. */ |
| 7559 | p1 += mcnt; |
| 7560 | |
| 7561 | /* Break if it's the beginning of an n-th alternative |
| 7562 | that doesn't begin with an on_failure_jump. */ |
| 7563 | if ((re_opcode_t) *p1 != on_failure_jump) |
| 7564 | break; |
| 7565 | |
| 7566 | /* Still have to check that it's not an n-th |
| 7567 | alternative that starts with an on_failure_jump. */ |
| 7568 | p1++; |
| 7569 | EXTRACT_NUMBER_AND_INCR (mcnt, p1); |
| 7570 | if ((re_opcode_t) p1[mcnt-(1+OFFSET_ADDRESS_SIZE)] != |
| 7571 | jump_past_alt) |
| 7572 | { |
| 7573 | /* Get to the beginning of the n-th alternative. */ |
| 7574 | p1 -= 1 + OFFSET_ADDRESS_SIZE; |
| 7575 | break; |
| 7576 | } |
| 7577 | } |
| 7578 | |
| 7579 | /* Deal with the last alternative: go back and get number |
| 7580 | of the `jump_past_alt' just before it. `mcnt' contains |
| 7581 | the length of the alternative. */ |
| 7582 | EXTRACT_NUMBER (mcnt, p1 - OFFSET_ADDRESS_SIZE); |
| 7583 | |
| 7584 | if (!PREFIX(alt_match_null_string_p) (p1, p1 + mcnt, reg_info)) |
| 7585 | return false; |
| 7586 | |
| 7587 | p1 += mcnt; /* Get past the n-th alternative. */ |
| 7588 | } /* if mcnt > 0 */ |
| 7589 | break; |
| 7590 | |
| 7591 | |
| 7592 | case stop_memory: |
| 7593 | assert (p1[1] == **p); |
| 7594 | *p = p1 + 2; |
| 7595 | return true; |
| 7596 | |
| 7597 | |
| 7598 | default: |
| 7599 | if (!PREFIX(common_op_match_null_string_p) (&p1, end, reg_info)) |
| 7600 | return false; |
| 7601 | } |
| 7602 | } /* while p1 < end */ |
| 7603 | |
| 7604 | return false; |
| 7605 | } /* group_match_null_string_p */ |
| 7606 | |
| 7607 | |
| 7608 | /* Similar to group_match_null_string_p, but doesn't deal with alternatives: |
| 7609 | It expects P to be the first byte of a single alternative and END one |
| 7610 | byte past the last. The alternative can contain groups. */ |
| 7611 | |
| 7612 | static boolean |
| 7613 | PREFIX(alt_match_null_string_p) (UCHAR_T *p, UCHAR_T *end, |
| 7614 | PREFIX(register_info_type) *reg_info) |
| 7615 | { |
| 7616 | int mcnt; |
| 7617 | UCHAR_T *p1 = p; |
| 7618 | |
| 7619 | while (p1 < end) |
| 7620 | { |
| 7621 | /* Skip over opcodes that can match nothing, and break when we get |
| 7622 | to one that can't. */ |
| 7623 | |
| 7624 | switch ((re_opcode_t) *p1) |
| 7625 | { |
| 7626 | /* It's a loop. */ |
| 7627 | case on_failure_jump: |
| 7628 | p1++; |
| 7629 | EXTRACT_NUMBER_AND_INCR (mcnt, p1); |
| 7630 | p1 += mcnt; |
| 7631 | break; |
| 7632 | |
| 7633 | default: |
| 7634 | if (!PREFIX(common_op_match_null_string_p) (&p1, end, reg_info)) |
| 7635 | return false; |
| 7636 | } |
| 7637 | } /* while p1 < end */ |
| 7638 | |
| 7639 | return true; |
| 7640 | } /* alt_match_null_string_p */ |
| 7641 | |
| 7642 | |
| 7643 | /* Deals with the ops common to group_match_null_string_p and |
| 7644 | alt_match_null_string_p. |
| 7645 | |
| 7646 | Sets P to one after the op and its arguments, if any. */ |
| 7647 | |
| 7648 | static boolean |
| 7649 | PREFIX(common_op_match_null_string_p) (UCHAR_T **p, UCHAR_T *end, |
| 7650 | PREFIX(register_info_type) *reg_info) |
| 7651 | { |
| 7652 | int mcnt; |
| 7653 | boolean ret; |
| 7654 | int reg_no; |
| 7655 | UCHAR_T *p1 = *p; |
| 7656 | |
| 7657 | switch ((re_opcode_t) *p1++) |
| 7658 | { |
| 7659 | case no_op: |
| 7660 | case begline: |
| 7661 | case endline: |
| 7662 | case begbuf: |
| 7663 | case endbuf: |
| 7664 | case wordbeg: |
| 7665 | case wordend: |
| 7666 | case wordbound: |
| 7667 | case notwordbound: |
| 7668 | #ifdef emacs |
| 7669 | case before_dot: |
| 7670 | case at_dot: |
| 7671 | case after_dot: |
| 7672 | #endif |
| 7673 | break; |
| 7674 | |
| 7675 | case start_memory: |
| 7676 | reg_no = *p1; |
| 7677 | assert (reg_no > 0 && reg_no <= MAX_REGNUM); |
| 7678 | ret = PREFIX(group_match_null_string_p) (&p1, end, reg_info); |
| 7679 | |
| 7680 | /* Have to set this here in case we're checking a group which |
| 7681 | contains a group and a back reference to it. */ |
| 7682 | |
| 7683 | if (REG_MATCH_NULL_STRING_P (reg_info[reg_no]) == MATCH_NULL_UNSET_VALUE) |
| 7684 | REG_MATCH_NULL_STRING_P (reg_info[reg_no]) = ret; |
| 7685 | |
| 7686 | if (!ret) |
| 7687 | return false; |
| 7688 | break; |
| 7689 | |
| 7690 | /* If this is an optimized succeed_n for zero times, make the jump. */ |
| 7691 | case jump: |
| 7692 | EXTRACT_NUMBER_AND_INCR (mcnt, p1); |
| 7693 | if (mcnt >= 0) |
| 7694 | p1 += mcnt; |
| 7695 | else |
| 7696 | return false; |
| 7697 | break; |
| 7698 | |
| 7699 | case succeed_n: |
| 7700 | /* Get to the number of times to succeed. */ |
| 7701 | p1 += OFFSET_ADDRESS_SIZE; |
| 7702 | EXTRACT_NUMBER_AND_INCR (mcnt, p1); |
| 7703 | |
| 7704 | if (mcnt == 0) |
| 7705 | { |
| 7706 | p1 -= 2 * OFFSET_ADDRESS_SIZE; |
| 7707 | EXTRACT_NUMBER_AND_INCR (mcnt, p1); |
| 7708 | p1 += mcnt; |
| 7709 | } |
| 7710 | else |
| 7711 | return false; |
| 7712 | break; |
| 7713 | |
| 7714 | case duplicate: |
| 7715 | if (!REG_MATCH_NULL_STRING_P (reg_info[*p1])) |
| 7716 | return false; |
| 7717 | break; |
| 7718 | |
| 7719 | case set_number_at: |
| 7720 | p1 += 2 * OFFSET_ADDRESS_SIZE; |
| 7721 | |
| 7722 | default: |
| 7723 | /* All other opcodes mean we cannot match the empty string. */ |
| 7724 | return false; |
| 7725 | } |
| 7726 | |
| 7727 | *p = p1; |
| 7728 | return true; |
| 7729 | } /* common_op_match_null_string_p */ |
| 7730 | |
| 7731 | |
| 7732 | /* Return zero if TRANSLATE[S1] and TRANSLATE[S2] are identical for LEN |
| 7733 | bytes; nonzero otherwise. */ |
| 7734 | |
| 7735 | static int |
| 7736 | PREFIX(bcmp_translate) (const CHAR_T *s1, const CHAR_T *s2, register int len, |
| 7737 | RE_TRANSLATE_TYPE translate) |
| 7738 | { |
| 7739 | register const UCHAR_T *p1 = (const UCHAR_T *) s1; |
| 7740 | register const UCHAR_T *p2 = (const UCHAR_T *) s2; |
| 7741 | while (len) |
| 7742 | { |
| 7743 | #ifdef WCHAR |
| 7744 | if (((*p1<=0xff)?translate[*p1++]:*p1++) |
| 7745 | != ((*p2<=0xff)?translate[*p2++]:*p2++)) |
| 7746 | return 1; |
| 7747 | #else /* BYTE */ |
| 7748 | if (translate[*p1++] != translate[*p2++]) return 1; |
| 7749 | #endif /* WCHAR */ |
| 7750 | len--; |
| 7751 | } |
| 7752 | return 0; |
| 7753 | } |
| 7754 | \f |
| 7755 | |
| 7756 | #else /* not INSIDE_RECURSION */ |
| 7757 | |
| 7758 | /* Entry points for GNU code. */ |
| 7759 | |
| 7760 | /* re_compile_pattern is the GNU regular expression compiler: it |
| 7761 | compiles PATTERN (of length SIZE) and puts the result in BUFP. |
| 7762 | Returns 0 if the pattern was valid, otherwise an error string. |
| 7763 | |
| 7764 | Assumes the `allocated' (and perhaps `buffer') and `translate' fields |
| 7765 | are set in BUFP on entry. |
| 7766 | |
| 7767 | We call regex_compile to do the actual compilation. */ |
| 7768 | |
| 7769 | const char * |
| 7770 | re_compile_pattern (const char *pattern, size_t length, |
| 7771 | struct re_pattern_buffer *bufp) |
| 7772 | { |
| 7773 | reg_errcode_t ret; |
| 7774 | |
| 7775 | /* GNU code is written to assume at least RE_NREGS registers will be set |
| 7776 | (and at least one extra will be -1). */ |
| 7777 | bufp->regs_allocated = REGS_UNALLOCATED; |
| 7778 | |
| 7779 | /* And GNU code determines whether or not to get register information |
| 7780 | by passing null for the REGS argument to re_match, etc., not by |
| 7781 | setting no_sub. */ |
| 7782 | bufp->no_sub = 0; |
| 7783 | |
| 7784 | /* Match anchors at newline. */ |
| 7785 | bufp->newline_anchor = 1; |
| 7786 | |
| 7787 | # ifdef MBS_SUPPORT |
| 7788 | if (MB_CUR_MAX != 1) |
| 7789 | ret = wcs_regex_compile (pattern, length, re_syntax_options, bufp); |
| 7790 | else |
| 7791 | # endif |
| 7792 | ret = byte_regex_compile (pattern, length, re_syntax_options, bufp); |
| 7793 | |
| 7794 | if (!ret) |
| 7795 | return NULL; |
| 7796 | return gettext (re_error_msgid[(int) ret]); |
| 7797 | } |
| 7798 | #ifdef _LIBC |
| 7799 | weak_alias (__re_compile_pattern, re_compile_pattern) |
| 7800 | #endif |
| 7801 | \f |
| 7802 | /* Entry points compatible with 4.2 BSD regex library. We don't define |
| 7803 | them unless specifically requested. */ |
| 7804 | |
| 7805 | #if defined _REGEX_RE_COMP || defined _LIBC |
| 7806 | |
| 7807 | /* BSD has one and only one pattern buffer. */ |
| 7808 | static struct re_pattern_buffer re_comp_buf; |
| 7809 | |
| 7810 | char * |
| 7811 | #ifdef _LIBC |
| 7812 | /* Make these definitions weak in libc, so POSIX programs can redefine |
| 7813 | these names if they don't use our functions, and still use |
| 7814 | regcomp/regexec below without link errors. */ |
| 7815 | weak_function |
| 7816 | #endif |
| 7817 | re_comp (const char *s) |
| 7818 | { |
| 7819 | reg_errcode_t ret; |
| 7820 | |
| 7821 | if (!s) |
| 7822 | { |
| 7823 | if (!re_comp_buf.buffer) |
| 7824 | return (char *) gettext ("No previous regular expression"); |
| 7825 | return 0; |
| 7826 | } |
| 7827 | |
| 7828 | if (!re_comp_buf.buffer) |
| 7829 | { |
| 7830 | re_comp_buf.buffer = (unsigned char *) malloc (200); |
| 7831 | if (re_comp_buf.buffer == NULL) |
| 7832 | return (char *) gettext (re_error_msgid[(int) REG_ESPACE]); |
| 7833 | re_comp_buf.allocated = 200; |
| 7834 | |
| 7835 | re_comp_buf.fastmap = (char *) malloc (1 << BYTEWIDTH); |
| 7836 | if (re_comp_buf.fastmap == NULL) |
| 7837 | return (char *) gettext (re_error_msgid[(int) REG_ESPACE]); |
| 7838 | } |
| 7839 | |
| 7840 | /* Since `re_exec' always passes NULL for the `regs' argument, we |
| 7841 | don't need to initialize the pattern buffer fields which affect it. */ |
| 7842 | |
| 7843 | /* Match anchors at newlines. */ |
| 7844 | re_comp_buf.newline_anchor = 1; |
| 7845 | |
| 7846 | # ifdef MBS_SUPPORT |
| 7847 | if (MB_CUR_MAX != 1) |
| 7848 | ret = wcs_regex_compile (s, strlen (s), re_syntax_options, &re_comp_buf); |
| 7849 | else |
| 7850 | # endif |
| 7851 | ret = byte_regex_compile (s, strlen (s), re_syntax_options, &re_comp_buf); |
| 7852 | |
| 7853 | if (!ret) |
| 7854 | return NULL; |
| 7855 | |
| 7856 | /* Yes, we're discarding `const' here if !HAVE_LIBINTL. */ |
| 7857 | return (char *) gettext (re_error_msgid[(int) ret]); |
| 7858 | } |
| 7859 | |
| 7860 | |
| 7861 | int |
| 7862 | #ifdef _LIBC |
| 7863 | weak_function |
| 7864 | #endif |
| 7865 | re_exec (const char *s) |
| 7866 | { |
| 7867 | const int len = strlen (s); |
| 7868 | return |
| 7869 | 0 <= re_search (&re_comp_buf, s, len, 0, len, (struct re_registers *) 0); |
| 7870 | } |
| 7871 | |
| 7872 | #endif /* _REGEX_RE_COMP */ |
| 7873 | \f |
| 7874 | /* POSIX.2 functions. Don't define these for Emacs. */ |
| 7875 | |
| 7876 | #ifndef emacs |
| 7877 | |
| 7878 | /* regcomp takes a regular expression as a string and compiles it. |
| 7879 | |
| 7880 | PREG is a regex_t *. We do not expect any fields to be initialized, |
| 7881 | since POSIX says we shouldn't. Thus, we set |
| 7882 | |
| 7883 | `buffer' to the compiled pattern; |
| 7884 | `used' to the length of the compiled pattern; |
| 7885 | `syntax' to RE_SYNTAX_POSIX_EXTENDED if the |
| 7886 | REG_EXTENDED bit in CFLAGS is set; otherwise, to |
| 7887 | RE_SYNTAX_POSIX_BASIC; |
| 7888 | `newline_anchor' to REG_NEWLINE being set in CFLAGS; |
| 7889 | `fastmap' to an allocated space for the fastmap; |
| 7890 | `fastmap_accurate' to zero; |
| 7891 | `re_nsub' to the number of subexpressions in PATTERN. |
| 7892 | |
| 7893 | PATTERN is the address of the pattern string. |
| 7894 | |
| 7895 | CFLAGS is a series of bits which affect compilation. |
| 7896 | |
| 7897 | If REG_EXTENDED is set, we use POSIX extended syntax; otherwise, we |
| 7898 | use POSIX basic syntax. |
| 7899 | |
| 7900 | If REG_NEWLINE is set, then . and [^...] don't match newline. |
| 7901 | Also, regexec will try a match beginning after every newline. |
| 7902 | |
| 7903 | If REG_ICASE is set, then we considers upper- and lowercase |
| 7904 | versions of letters to be equivalent when matching. |
| 7905 | |
| 7906 | If REG_NOSUB is set, then when PREG is passed to regexec, that |
| 7907 | routine will report only success or failure, and nothing about the |
| 7908 | registers. |
| 7909 | |
| 7910 | It returns 0 if it succeeds, nonzero if it doesn't. (See regex.h for |
| 7911 | the return codes and their meanings.) */ |
| 7912 | |
| 7913 | int |
| 7914 | regcomp (regex_t *preg, const char *pattern, int cflags) |
| 7915 | { |
| 7916 | reg_errcode_t ret; |
| 7917 | reg_syntax_t syntax |
| 7918 | = (cflags & REG_EXTENDED) ? |
| 7919 | RE_SYNTAX_POSIX_EXTENDED : RE_SYNTAX_POSIX_BASIC; |
| 7920 | |
| 7921 | /* regex_compile will allocate the space for the compiled pattern. */ |
| 7922 | preg->buffer = 0; |
| 7923 | preg->allocated = 0; |
| 7924 | preg->used = 0; |
| 7925 | |
| 7926 | /* Try to allocate space for the fastmap. */ |
| 7927 | preg->fastmap = (char *) malloc (1 << BYTEWIDTH); |
| 7928 | |
| 7929 | if (cflags & REG_ICASE) |
| 7930 | { |
| 7931 | int i; |
| 7932 | |
| 7933 | preg->translate |
| 7934 | = (RE_TRANSLATE_TYPE) malloc (CHAR_SET_SIZE |
| 7935 | * sizeof (*(RE_TRANSLATE_TYPE)0)); |
| 7936 | if (preg->translate == NULL) |
| 7937 | return (int) REG_ESPACE; |
| 7938 | |
| 7939 | /* Map uppercase characters to corresponding lowercase ones. */ |
| 7940 | for (i = 0; i < CHAR_SET_SIZE; i++) |
| 7941 | preg->translate[i] = ISUPPER (i) ? TOLOWER (i) : i; |
| 7942 | } |
| 7943 | else |
| 7944 | preg->translate = NULL; |
| 7945 | |
| 7946 | /* If REG_NEWLINE is set, newlines are treated differently. */ |
| 7947 | if (cflags & REG_NEWLINE) |
| 7948 | { /* REG_NEWLINE implies neither . nor [^...] match newline. */ |
| 7949 | syntax &= ~RE_DOT_NEWLINE; |
| 7950 | syntax |= RE_HAT_LISTS_NOT_NEWLINE; |
| 7951 | /* It also changes the matching behavior. */ |
| 7952 | preg->newline_anchor = 1; |
| 7953 | } |
| 7954 | else |
| 7955 | preg->newline_anchor = 0; |
| 7956 | |
| 7957 | preg->no_sub = !!(cflags & REG_NOSUB); |
| 7958 | |
| 7959 | /* POSIX says a null character in the pattern terminates it, so we |
| 7960 | can use strlen here in compiling the pattern. */ |
| 7961 | # ifdef MBS_SUPPORT |
| 7962 | if (MB_CUR_MAX != 1) |
| 7963 | ret = wcs_regex_compile (pattern, strlen (pattern), syntax, preg); |
| 7964 | else |
| 7965 | # endif |
| 7966 | ret = byte_regex_compile (pattern, strlen (pattern), syntax, preg); |
| 7967 | |
| 7968 | /* POSIX doesn't distinguish between an unmatched open-group and an |
| 7969 | unmatched close-group: both are REG_EPAREN. */ |
| 7970 | if (ret == REG_ERPAREN) ret = REG_EPAREN; |
| 7971 | |
| 7972 | if (ret == REG_NOERROR && preg->fastmap) |
| 7973 | { |
| 7974 | /* Compute the fastmap now, since regexec cannot modify the pattern |
| 7975 | buffer. */ |
| 7976 | if (re_compile_fastmap (preg) == -2) |
| 7977 | { |
| 7978 | /* Some error occurred while computing the fastmap, just forget |
| 7979 | about it. */ |
| 7980 | free (preg->fastmap); |
| 7981 | preg->fastmap = NULL; |
| 7982 | } |
| 7983 | } |
| 7984 | |
| 7985 | return (int) ret; |
| 7986 | } |
| 7987 | #ifdef _LIBC |
| 7988 | weak_alias (__regcomp, regcomp) |
| 7989 | #endif |
| 7990 | |
| 7991 | |
| 7992 | /* regexec searches for a given pattern, specified by PREG, in the |
| 7993 | string STRING. |
| 7994 | |
| 7995 | If NMATCH is zero or REG_NOSUB was set in the cflags argument to |
| 7996 | `regcomp', we ignore PMATCH. Otherwise, we assume PMATCH has at |
| 7997 | least NMATCH elements, and we set them to the offsets of the |
| 7998 | corresponding matched substrings. |
| 7999 | |
| 8000 | EFLAGS specifies `execution flags' which affect matching: if |
| 8001 | REG_NOTBOL is set, then ^ does not match at the beginning of the |
| 8002 | string; if REG_NOTEOL is set, then $ does not match at the end. |
| 8003 | |
| 8004 | We return 0 if we find a match and REG_NOMATCH if not. */ |
| 8005 | |
| 8006 | int |
| 8007 | regexec (const regex_t *preg, const char *string, size_t nmatch, |
| 8008 | regmatch_t pmatch[], int eflags) |
| 8009 | { |
| 8010 | int ret; |
| 8011 | struct re_registers regs; |
| 8012 | regex_t private_preg; |
| 8013 | int len = strlen (string); |
| 8014 | boolean want_reg_info = !preg->no_sub && nmatch > 0; |
| 8015 | |
| 8016 | private_preg = *preg; |
| 8017 | |
| 8018 | private_preg.not_bol = !!(eflags & REG_NOTBOL); |
| 8019 | private_preg.not_eol = !!(eflags & REG_NOTEOL); |
| 8020 | |
| 8021 | /* The user has told us exactly how many registers to return |
| 8022 | information about, via `nmatch'. We have to pass that on to the |
| 8023 | matching routines. */ |
| 8024 | private_preg.regs_allocated = REGS_FIXED; |
| 8025 | |
| 8026 | if (want_reg_info) |
| 8027 | { |
| 8028 | regs.num_regs = nmatch; |
| 8029 | regs.start = TALLOC (nmatch * 2, regoff_t); |
| 8030 | if (regs.start == NULL) |
| 8031 | return (int) REG_NOMATCH; |
| 8032 | regs.end = regs.start + nmatch; |
| 8033 | } |
| 8034 | |
| 8035 | /* Perform the searching operation. */ |
| 8036 | ret = re_search (&private_preg, string, len, |
| 8037 | /* start: */ 0, /* range: */ len, |
| 8038 | want_reg_info ? ®s : (struct re_registers *) 0); |
| 8039 | |
| 8040 | /* Copy the register information to the POSIX structure. */ |
| 8041 | if (want_reg_info) |
| 8042 | { |
| 8043 | if (ret >= 0) |
| 8044 | { |
| 8045 | unsigned r; |
| 8046 | |
| 8047 | for (r = 0; r < nmatch; r++) |
| 8048 | { |
| 8049 | pmatch[r].rm_so = regs.start[r]; |
| 8050 | pmatch[r].rm_eo = regs.end[r]; |
| 8051 | } |
| 8052 | } |
| 8053 | |
| 8054 | /* If we needed the temporary register info, free the space now. */ |
| 8055 | free (regs.start); |
| 8056 | } |
| 8057 | |
| 8058 | /* We want zero return to mean success, unlike `re_search'. */ |
| 8059 | return ret >= 0 ? (int) REG_NOERROR : (int) REG_NOMATCH; |
| 8060 | } |
| 8061 | #ifdef _LIBC |
| 8062 | weak_alias (__regexec, regexec) |
| 8063 | #endif |
| 8064 | |
| 8065 | |
| 8066 | /* Returns a message corresponding to an error code, ERRCODE, returned |
| 8067 | from either regcomp or regexec. We don't use PREG here. */ |
| 8068 | |
| 8069 | size_t |
| 8070 | regerror (int errcode, const regex_t *preg ATTRIBUTE_UNUSED, |
| 8071 | char *errbuf, size_t errbuf_size) |
| 8072 | { |
| 8073 | const char *msg; |
| 8074 | size_t msg_size; |
| 8075 | |
| 8076 | if (errcode < 0 |
| 8077 | || errcode >= (int) (sizeof (re_error_msgid) |
| 8078 | / sizeof (re_error_msgid[0]))) |
| 8079 | /* Only error codes returned by the rest of the code should be passed |
| 8080 | to this routine. If we are given anything else, or if other regex |
| 8081 | code generates an invalid error code, then the program has a bug. |
| 8082 | Dump core so we can fix it. */ |
| 8083 | abort (); |
| 8084 | |
| 8085 | msg = gettext (re_error_msgid[errcode]); |
| 8086 | |
| 8087 | msg_size = strlen (msg) + 1; /* Includes the null. */ |
| 8088 | |
| 8089 | if (errbuf_size != 0) |
| 8090 | { |
| 8091 | if (msg_size > errbuf_size) |
| 8092 | { |
| 8093 | #if defined HAVE_MEMPCPY || defined _LIBC |
| 8094 | *((char *) mempcpy (errbuf, msg, errbuf_size - 1)) = '\0'; |
| 8095 | #else |
| 8096 | (void) memcpy (errbuf, msg, errbuf_size - 1); |
| 8097 | errbuf[errbuf_size - 1] = 0; |
| 8098 | #endif |
| 8099 | } |
| 8100 | else |
| 8101 | (void) memcpy (errbuf, msg, msg_size); |
| 8102 | } |
| 8103 | |
| 8104 | return msg_size; |
| 8105 | } |
| 8106 | #ifdef _LIBC |
| 8107 | weak_alias (__regerror, regerror) |
| 8108 | #endif |
| 8109 | |
| 8110 | |
| 8111 | /* Free dynamically allocated space used by PREG. */ |
| 8112 | |
| 8113 | void |
| 8114 | regfree (regex_t *preg) |
| 8115 | { |
| 8116 | free (preg->buffer); |
| 8117 | preg->buffer = NULL; |
| 8118 | |
| 8119 | preg->allocated = 0; |
| 8120 | preg->used = 0; |
| 8121 | |
| 8122 | free (preg->fastmap); |
| 8123 | preg->fastmap = NULL; |
| 8124 | preg->fastmap_accurate = 0; |
| 8125 | |
| 8126 | free (preg->translate); |
| 8127 | preg->translate = NULL; |
| 8128 | } |
| 8129 | #ifdef _LIBC |
| 8130 | weak_alias (__regfree, regfree) |
| 8131 | #endif |
| 8132 | |
| 8133 | #endif /* not emacs */ |
| 8134 | |
| 8135 | #endif /* not INSIDE_RECURSION */ |
| 8136 | |
| 8137 | \f |
| 8138 | #undef STORE_NUMBER |
| 8139 | #undef STORE_NUMBER_AND_INCR |
| 8140 | #undef EXTRACT_NUMBER |
| 8141 | #undef EXTRACT_NUMBER_AND_INCR |
| 8142 | |
| 8143 | #undef DEBUG_PRINT_COMPILED_PATTERN |
| 8144 | #undef DEBUG_PRINT_DOUBLE_STRING |
| 8145 | |
| 8146 | #undef INIT_FAIL_STACK |
| 8147 | #undef RESET_FAIL_STACK |
| 8148 | #undef DOUBLE_FAIL_STACK |
| 8149 | #undef PUSH_PATTERN_OP |
| 8150 | #undef PUSH_FAILURE_POINTER |
| 8151 | #undef PUSH_FAILURE_INT |
| 8152 | #undef PUSH_FAILURE_ELT |
| 8153 | #undef POP_FAILURE_POINTER |
| 8154 | #undef POP_FAILURE_INT |
| 8155 | #undef POP_FAILURE_ELT |
| 8156 | #undef DEBUG_PUSH |
| 8157 | #undef DEBUG_POP |
| 8158 | #undef PUSH_FAILURE_POINT |
| 8159 | #undef POP_FAILURE_POINT |
| 8160 | |
| 8161 | #undef REG_UNSET_VALUE |
| 8162 | #undef REG_UNSET |
| 8163 | |
| 8164 | #undef PATFETCH |
| 8165 | #undef PATFETCH_RAW |
| 8166 | #undef PATUNFETCH |
| 8167 | #undef TRANSLATE |
| 8168 | |
| 8169 | #undef INIT_BUF_SIZE |
| 8170 | #undef GET_BUFFER_SPACE |
| 8171 | #undef BUF_PUSH |
| 8172 | #undef BUF_PUSH_2 |
| 8173 | #undef BUF_PUSH_3 |
| 8174 | #undef STORE_JUMP |
| 8175 | #undef STORE_JUMP2 |
| 8176 | #undef INSERT_JUMP |
| 8177 | #undef INSERT_JUMP2 |
| 8178 | #undef EXTEND_BUFFER |
| 8179 | #undef GET_UNSIGNED_NUMBER |
| 8180 | #undef FREE_STACK_RETURN |
| 8181 | |
| 8182 | # undef POINTER_TO_OFFSET |
| 8183 | # undef MATCHING_IN_FRST_STRING |
| 8184 | # undef PREFETCH |
| 8185 | # undef AT_STRINGS_BEG |
| 8186 | # undef AT_STRINGS_END |
| 8187 | # undef WORDCHAR_P |
| 8188 | # undef FREE_VAR |
| 8189 | # undef FREE_VARIABLES |
| 8190 | # undef NO_HIGHEST_ACTIVE_REG |
| 8191 | # undef NO_LOWEST_ACTIVE_REG |
| 8192 | |
| 8193 | # undef CHAR_T |
| 8194 | # undef UCHAR_T |
| 8195 | # undef COMPILED_BUFFER_VAR |
| 8196 | # undef OFFSET_ADDRESS_SIZE |
| 8197 | # undef CHAR_CLASS_SIZE |
| 8198 | # undef PREFIX |
| 8199 | # undef ARG_PREFIX |
| 8200 | # undef PUT_CHAR |
| 8201 | # undef BYTE |
| 8202 | # undef WCHAR |
| 8203 | |
| 8204 | # define DEFINED_ONCE |