/* Copyright (C) 1991,1992,1993,1996,1997,1998,1999,2000,2001,2002,2003,2004,2005,2006 Free Software Foundation, Inc. This file is part of the GNU C Library. This program is free software; you can redistribute it and/or modify it under the terms of the GNU General Public License as published by the Free Software Foundation; either version 2, or (at your option) any later version. This program is distributed in the hope that it will be useful, but WITHOUT ANY WARRANTY; without even the implied warranty of MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the GNU General Public License for more details. You should have received a copy of the GNU General Public License along with this program; if not, write to the Free Software Foundation, Inc., 51 Franklin Street, Fifth Floor, Boston, MA 02110-1301, USA. */ /* Match STRING against the file name pattern PATTERN, returning zero if it matches, nonzero if not. */ static int EXT (INT opt, const CHAR *pattern, const CHAR *string, const CHAR *string_end, bool no_leading_period, int flags) internal_function; static const CHAR *END (const CHAR *patternp) internal_function; static int internal_function FCT (const CHAR *pattern, const CHAR *string, const CHAR *string_end, bool no_leading_period, int flags) { register const CHAR *p = pattern, *n = string; register UCHAR c; #ifdef _LIBC # if WIDE_CHAR_VERSION const char *collseq = (const char *) _NL_CURRENT(LC_COLLATE, _NL_COLLATE_COLLSEQWC); # else const UCHAR *collseq = (const UCHAR *) _NL_CURRENT(LC_COLLATE, _NL_COLLATE_COLLSEQMB); # endif #endif while ((c = *p++) != L_('\0')) { bool new_no_leading_period = false; c = FOLD (c); switch (c) { case L_('?'): if (__builtin_expect (flags & FNM_EXTMATCH, 0) && *p == '(') { int res; res = EXT (c, p, n, string_end, no_leading_period, flags); if (res != -1) return res; } if (n == string_end) return FNM_NOMATCH; else if (*n == L_('/') && (flags & FNM_FILE_NAME)) return FNM_NOMATCH; else if (*n == L_('.') && no_leading_period) return FNM_NOMATCH; break; case L_('\\'): if (!(flags & FNM_NOESCAPE)) { c = *p++; if (c == L_('\0')) /* Trailing \ loses. */ return FNM_NOMATCH; c = FOLD (c); } if (n == string_end || FOLD ((UCHAR) *n) != c) return FNM_NOMATCH; break; case L_('*'): if (__builtin_expect (flags & FNM_EXTMATCH, 0) && *p == '(') { int res; res = EXT (c, p, n, string_end, no_leading_period, flags); if (res != -1) return res; } if (n != string_end && *n == L_('.') && no_leading_period) return FNM_NOMATCH; for (c = *p++; c == L_('?') || c == L_('*'); c = *p++) { if (*p == L_('(') && (flags & FNM_EXTMATCH) != 0) { const CHAR *endp = END (p); if (endp != p) { /* This is a pattern. Skip over it. */ p = endp; continue; } } if (c == L_('?')) { /* A ? needs to match one character. */ if (n == string_end) /* There isn't another character; no match. */ return FNM_NOMATCH; else if (*n == L_('/') && __builtin_expect (flags & FNM_FILE_NAME, 0)) /* A slash does not match a wildcard under FNM_FILE_NAME. */ return FNM_NOMATCH; else /* One character of the string is consumed in matching this ? wildcard, so *??? won't match if there are less than three characters. */ ++n; } } if (c == L_('\0')) /* The wildcard(s) is/are the last element of the pattern. If the name is a file name and contains another slash this means it cannot match, unless the FNM_LEADING_DIR flag is set. */ { int result = (flags & FNM_FILE_NAME) == 0 ? 0 : FNM_NOMATCH; if (flags & FNM_FILE_NAME) { if (flags & FNM_LEADING_DIR) result = 0; else { if (MEMCHR (n, L_('/'), string_end - n) == NULL) result = 0; } } return result; } else { const CHAR *endp; endp = MEMCHR (n, (flags & FNM_FILE_NAME) ? L_('/') : L_('\0'), string_end - n); if (endp == NULL) endp = string_end; if (c == L_('[') || (__builtin_expect (flags & FNM_EXTMATCH, 0) != 0 && (c == L_('@') || c == L_('+') || c == L_('!')) && *p == L_('('))) { int flags2 = ((flags & FNM_FILE_NAME) ? flags : (flags & ~FNM_PERIOD)); bool no_leading_period2 = no_leading_period; for (--p; n < endp; ++n, no_leading_period2 = false) if (FCT (p, n, string_end, no_leading_period2, flags2) == 0) return 0; } else if (c == L_('/') && (flags & FNM_FILE_NAME)) { while (n < string_end && *n != L_('/')) ++n; if (n < string_end && *n == L_('/') && (FCT (p, n + 1, string_end, flags & FNM_PERIOD, flags) == 0)) return 0; } else { int flags2 = ((flags & FNM_FILE_NAME) ? flags : (flags & ~FNM_PERIOD)); int no_leading_period2 = no_leading_period; if (c == L_('\\') && !(flags & FNM_NOESCAPE)) c = *p; c = FOLD (c); for (--p; n < endp; ++n, no_leading_period2 = false) if (FOLD ((UCHAR) *n) == c && (FCT (p, n, string_end, no_leading_period2, flags2) == 0)) return 0; } } /* If we come here no match is possible with the wildcard. */ return FNM_NOMATCH; case L_('['): { /* Nonzero if the sense of the character class is inverted. */ register bool not; CHAR cold; UCHAR fn; if (posixly_correct == 0) posixly_correct = getenv ("POSIXLY_CORRECT") != NULL ? 1 : -1; if (n == string_end) return FNM_NOMATCH; if (*n == L_('.') && no_leading_period) return FNM_NOMATCH; if (*n == L_('/') && (flags & FNM_FILE_NAME)) /* `/' cannot be matched. */ return FNM_NOMATCH; not = (*p == L_('!') || (posixly_correct < 0 && *p == L_('^'))); if (not) ++p; fn = FOLD ((UCHAR) *n); c = *p++; for (;;) { if (!(flags & FNM_NOESCAPE) && c == L_('\\')) { if (*p == L_('\0')) return FNM_NOMATCH; c = FOLD ((UCHAR) *p); ++p; goto normal_bracket; } else if (c == L_('[') && *p == L_(':')) { /* Leave room for the null. */ CHAR str[CHAR_CLASS_MAX_LENGTH + 1]; size_t c1 = 0; #if defined _LIBC || WIDE_CHAR_SUPPORT wctype_t wt; #endif const CHAR *startp = p; for (;;) { if (c1 == CHAR_CLASS_MAX_LENGTH) /* The name is too long and therefore the pattern is ill-formed. */ return FNM_NOMATCH; c = *++p; if (c == L_(':') && p[1] == L_(']')) { p += 2; break; } if (c < L_('a') || c >= L_('z')) { /* This cannot possibly be a character class name. Match it as a normal range. */ p = startp; c = L_('['); goto normal_bracket; } str[c1++] = c; } str[c1] = L_('\0'); #if defined _LIBC || WIDE_CHAR_SUPPORT wt = IS_CHAR_CLASS (str); if (wt == 0) /* Invalid character class name. */ return FNM_NOMATCH; # if defined _LIBC && ! WIDE_CHAR_VERSION /* The following code is glibc specific but does there a good job in speeding up the code since we can avoid the btowc() call. */ if (_ISCTYPE ((UCHAR) *n, wt)) goto matched; # else if (ISWCTYPE (BTOWC ((UCHAR) *n), wt)) goto matched; # endif #else if ((STREQ (str, L_("alnum")) && isalnum ((UCHAR) *n)) || (STREQ (str, L_("alpha")) && isalpha ((UCHAR) *n)) || (STREQ (str, L_("blank")) && isblank ((UCHAR) *n)) || (STREQ (str, L_("cntrl")) && iscntrl ((UCHAR) *n)) || (STREQ (str, L_("digit")) && isdigit ((UCHAR) *n)) || (STREQ (str, L_("graph")) && isgraph ((UCHAR) *n)) || (STREQ (str, L_("lower")) && islower ((UCHAR) *n)) || (STREQ (str, L_("print")) && isprint ((UCHAR) *n)) || (STREQ (str, L_("punct")) && ispunct ((UCHAR) *n)) || (STREQ (str, L_("space")) && isspace ((UCHAR) *n)) || (STREQ (str, L_("upper")) && isupper ((UCHAR) *n)) || (STREQ (str, L_("xdigit")) && isxdigit ((UCHAR) *n))) goto matched; #endif c = *p++; } #ifdef _LIBC else if (c == L_('[') && *p == L_('=')) { UCHAR str[1]; uint32_t nrules = _NL_CURRENT_WORD (LC_COLLATE, _NL_COLLATE_NRULES); const CHAR *startp = p; c = *++p; if (c == L_('\0')) { p = startp; c = L_('['); goto normal_bracket; } str[0] = c; c = *++p; if (c != L_('=') || p[1] != L_(']')) { p = startp; c = L_('['); goto normal_bracket; } p += 2; if (nrules == 0) { if ((UCHAR) *n == str[0]) goto matched; } else { const int32_t *table; # if WIDE_CHAR_VERSION const int32_t *weights; const int32_t *extra; # else const unsigned char *weights; const unsigned char *extra; # endif const int32_t *indirect; int32_t idx; const UCHAR *cp = (const UCHAR *) str; /* This #include defines a local function! */ # if WIDE_CHAR_VERSION # include # else # include # endif # if WIDE_CHAR_VERSION table = (const int32_t *) _NL_CURRENT (LC_COLLATE, _NL_COLLATE_TABLEWC); weights = (const int32_t *) _NL_CURRENT (LC_COLLATE, _NL_COLLATE_WEIGHTWC); extra = (const int32_t *) _NL_CURRENT (LC_COLLATE, _NL_COLLATE_EXTRAWC); indirect = (const int32_t *) _NL_CURRENT (LC_COLLATE, _NL_COLLATE_INDIRECTWC); # else table = (const int32_t *) _NL_CURRENT (LC_COLLATE, _NL_COLLATE_TABLEMB); weights = (const unsigned char *) _NL_CURRENT (LC_COLLATE, _NL_COLLATE_WEIGHTMB); extra = (const unsigned char *) _NL_CURRENT (LC_COLLATE, _NL_COLLATE_EXTRAMB); indirect = (const int32_t *) _NL_CURRENT (LC_COLLATE, _NL_COLLATE_INDIRECTMB); # endif idx = findidx (&cp); if (idx != 0) { /* We found a table entry. Now see whether the character we are currently at has the same equivalance class value. */ int len = weights[idx]; int32_t idx2; const UCHAR *np = (const UCHAR *) n; idx2 = findidx (&np); if (idx2 != 0 && len == weights[idx2]) { int cnt = 0; while (cnt < len && (weights[idx + 1 + cnt] == weights[idx2 + 1 + cnt])) ++cnt; if (cnt == len) goto matched; } } } c = *p++; } #endif else if (c == L_('\0')) /* [ (unterminated) loses. */ return FNM_NOMATCH; else { bool is_range = false; #ifdef _LIBC bool is_seqval = false; if (c == L_('[') && *p == L_('.')) { uint32_t nrules = _NL_CURRENT_WORD (LC_COLLATE, _NL_COLLATE_NRULES); const CHAR *startp = p; size_t c1 = 0; while (1) { c = *++p; if (c == L_('.') && p[1] == L_(']')) { p += 2; break; } if (c == '\0') return FNM_NOMATCH; ++c1; } /* We have to handling the symbols differently in ranges since then the collation sequence is important. */ is_range = *p == L_('-') && p[1] != L_('\0'); if (nrules == 0) { /* There are no names defined in the collation data. Therefore we only accept the trivial names consisting of the character itself. */ if (c1 != 1) return FNM_NOMATCH; if (!is_range && *n == startp[1]) goto matched; cold = startp[1]; c = *p++; } else { int32_t table_size; const int32_t *symb_table; # ifdef WIDE_CHAR_VERSION char str[c1]; size_t strcnt; # else # define str (startp + 1) # endif const unsigned char *extra; int32_t idx; int32_t elem; int32_t second; int32_t hash; # ifdef WIDE_CHAR_VERSION /* We have to convert the name to a single-byte string. This is possible since the names consist of ASCII characters and the internal representation is UCS4. */ for (strcnt = 0; strcnt < c1; ++strcnt) str[strcnt] = startp[1 + strcnt]; # endif table_size = _NL_CURRENT_WORD (LC_COLLATE, _NL_COLLATE_SYMB_HASH_SIZEMB); symb_table = (const int32_t *) _NL_CURRENT (LC_COLLATE, _NL_COLLATE_SYMB_TABLEMB); extra = (const unsigned char *) _NL_CURRENT (LC_COLLATE, _NL_COLLATE_SYMB_EXTRAMB); /* Locate the character in the hashing table. */ hash = elem_hash (str, c1); idx = 0; elem = hash % table_size; if (symb_table[2 * elem] != 0) { second = hash % (table_size - 2) + 1; do { /* First compare the hashing value. */ if (symb_table[2 * elem] == hash && (c1 == extra[symb_table[2 * elem + 1]]) && memcmp (str, &extra[symb_table[2 * elem + 1] + 1], c1) == 0) { /* Yep, this is the entry. */ idx = symb_table[2 * elem + 1]; idx += 1 + extra[idx]; break; } /* Next entry. */ elem += second; } while (symb_table[2 * elem] != 0); } if (symb_table[2 * elem] != 0) { /* Compare the byte sequence but only if this is not part of a range. */ # ifdef WIDE_CHAR_VERSION int32_t *wextra; idx += 1 + extra[idx]; /* Adjust for the alignment. */ idx = (idx + 3) & ~3; wextra = (int32_t *) &extra[idx + 4]; # endif if (! is_range) { # ifdef WIDE_CHAR_VERSION for (c1 = 0; (int32_t) c1 < wextra[idx]; ++c1) if (n[c1] != wextra[1 + c1]) break; if ((int32_t) c1 == wextra[idx]) goto matched; # else for (c1 = 0; c1 < extra[idx]; ++c1) if (n[c1] != extra[1 + c1]) break; if (c1 == extra[idx]) goto matched; # endif } /* Get the collation sequence value. */ is_seqval = true; # ifdef WIDE_CHAR_VERSION cold = wextra[1 + wextra[idx]]; # else /* Adjust for the alignment. */ idx += 1 + extra[idx]; idx = (idx + 3) & ~4; cold = *((int32_t *) &extra[idx]); # endif c = *p++; } else if (c1 == 1) { /* No valid character. Match it as a single byte. */ if (!is_range && *n == str[0]) goto matched; cold = str[0]; c = *p++; } else return FNM_NOMATCH; } } else # undef str #endif { c = FOLD (c); normal_bracket: /* We have to handling the symbols differently in ranges since then the collation sequence is important. */ is_range = (*p == L_('-') && p[1] != L_('\0') && p[1] != L_(']')); if (!is_range && c == fn) goto matched; #if _LIBC /* This is needed if we goto normal_bracket; from outside of is_seqval's scope. */ is_seqval = false; #endif cold = c; c = *p++; } if (c == L_('-') && *p != L_(']')) { #if _LIBC /* We have to find the collation sequence value for C. Collation sequence is nothing we can regularly access. The sequence value is defined by the order in which the definitions of the collation values for the various characters appear in the source file. A strange concept, nowhere documented. */ uint32_t fcollseq; uint32_t lcollseq; UCHAR cend = *p++; # ifdef WIDE_CHAR_VERSION /* Search in the `names' array for the characters. */ fcollseq = __collseq_table_lookup (collseq, fn); if (fcollseq == ~((uint32_t) 0)) /* XXX We don't know anything about the character we are supposed to match. This means we are failing. */ goto range_not_matched; if (is_seqval) lcollseq = cold; else lcollseq = __collseq_table_lookup (collseq, cold); # else fcollseq = collseq[fn]; lcollseq = is_seqval ? cold : collseq[(UCHAR) cold]; # endif is_seqval = false; if (cend == L_('[') && *p == L_('.')) { uint32_t nrules = _NL_CURRENT_WORD (LC_COLLATE, _NL_COLLATE_NRULES); const CHAR *startp = p; size_t c1 = 0; while (1) { c = *++p; if (c == L_('.') && p[1] == L_(']')) { p += 2; break; } if (c == '\0') return FNM_NOMATCH; ++c1; } if (nrules == 0) { /* There are no names defined in the collation data. Therefore we only accept the trivial names consisting of the character itself. */ if (c1 != 1) return FNM_NOMATCH; cend = startp[1]; } else { int32_t table_size; const int32_t *symb_table; # ifdef WIDE_CHAR_VERSION char str[c1]; size_t strcnt; # else # define str (startp + 1) # endif const unsigned char *extra; int32_t idx; int32_t elem; int32_t second; int32_t hash; # ifdef WIDE_CHAR_VERSION /* We have to convert the name to a single-byte string. This is possible since the names consist of ASCII characters and the internal representation is UCS4. */ for (strcnt = 0; strcnt < c1; ++strcnt) str[strcnt] = startp[1 + strcnt]; # endif table_size = _NL_CURRENT_WORD (LC_COLLATE, _NL_COLLATE_SYMB_HASH_SIZEMB); symb_table = (const int32_t *) _NL_CURRENT (LC_COLLATE, _NL_COLLATE_SYMB_TABLEMB); extra = (const unsigned char *) _NL_CURRENT (LC_COLLATE, _NL_COLLATE_SYMB_EXTRAMB); /* Locate the character in the hashing table. */ hash = elem_hash (str, c1); idx = 0; elem = hash % table_size; if (symb_table[2 * elem] != 0) { second = hash % (table_size - 2) + 1; do { /* First compare the hashing value. */ if (symb_table[2 * elem] == hash && (c1 == extra[symb_table[2 * elem + 1]]) && memcmp (str, &extra[symb_table[2 * elem + 1] + 1], c1) == 0) { /* Yep, this is the entry. */ idx = symb_table[2 * elem + 1]; idx += 1 + extra[idx]; break; } /* Next entry. */ elem += second; } while (symb_table[2 * elem] != 0); } if (symb_table[2 * elem] != 0) { /* Compare the byte sequence but only if this is not part of a range. */ # ifdef WIDE_CHAR_VERSION int32_t *wextra; idx += 1 + extra[idx]; /* Adjust for the alignment. */ idx = (idx + 3) & ~4; wextra = (int32_t *) &extra[idx + 4]; # endif /* Get the collation sequence value. */ is_seqval = true; # ifdef WIDE_CHAR_VERSION cend = wextra[1 + wextra[idx]]; # else /* Adjust for the alignment. */ idx += 1 + extra[idx]; idx = (idx + 3) & ~4; cend = *((int32_t *) &extra[idx]); # endif } else if (symb_table[2 * elem] != 0 && c1 == 1) { cend = str[0]; c = *p++; } else return FNM_NOMATCH; } # undef str } else { if (!(flags & FNM_NOESCAPE) && cend == L_('\\')) cend = *p++; if (cend == L_('\0')) return FNM_NOMATCH; cend = FOLD (cend); } /* XXX It is not entirely clear to me how to handle characters which are not mentioned in the collation specification. */ if ( # ifdef WIDE_CHAR_VERSION lcollseq == 0xffffffff || # endif lcollseq <= fcollseq) { /* We have to look at the upper bound. */ uint32_t hcollseq; if (is_seqval) hcollseq = cend; else { # ifdef WIDE_CHAR_VERSION hcollseq = __collseq_table_lookup (collseq, cend); if (hcollseq == ~((uint32_t) 0)) { /* Hum, no information about the upper bound. The matching succeeds if the lower bound is matched exactly. */ if (lcollseq != fcollseq) goto range_not_matched; goto matched; } # else hcollseq = collseq[cend]; # endif } if (lcollseq <= hcollseq && fcollseq <= hcollseq) goto matched; } # ifdef WIDE_CHAR_VERSION range_not_matched: # endif #else /* We use a boring value comparison of the character values. This is better than comparing using `strcoll' since the latter would have surprising and sometimes fatal consequences. */ UCHAR cend = *p++; if (!(flags & FNM_NOESCAPE) && cend == L_('\\')) cend = *p++; if (cend == L_('\0')) return FNM_NOMATCH; /* It is a range. */ if (cold <= fn && fn <= cend) goto matched; #endif c = *p++; } } if (c == L_(']')) break; } if (!not) return FNM_NOMATCH; break; matched: /* Skip the rest of the [...] that already matched. */ do { ignore_next: c = *p++; if (c == L_('\0')) /* [... (unterminated) loses. */ return FNM_NOMATCH; if (!(flags & FNM_NOESCAPE) && c == L_('\\')) { if (*p == L_('\0')) return FNM_NOMATCH; /* XXX 1003.2d11 is unclear if this is right. */ ++p; } else if (c == L_('[') && *p == L_(':')) { int c1 = 0; const CHAR *startp = p; while (1) { c = *++p; if (++c1 == CHAR_CLASS_MAX_LENGTH) return FNM_NOMATCH; if (*p == L_(':') && p[1] == L_(']')) break; if (c < L_('a') || c >= L_('z')) { p = startp; goto ignore_next; } } p += 2; c = *p++; } else if (c == L_('[') && *p == L_('=')) { c = *++p; if (c == L_('\0')) return FNM_NOMATCH; c = *++p; if (c != L_('=') || p[1] != L_(']')) return FNM_NOMATCH; p += 2; c = *p++; } else if (c == L_('[') && *p == L_('.')) { ++p; while (1) { c = *++p; if (c == '\0') return FNM_NOMATCH; if (*p == L_('.') && p[1] == L_(']')) break; } p += 2; c = *p++; } } while (c != L_(']')); if (not) return FNM_NOMATCH; } break; case L_('+'): case L_('@'): case L_('!'): if (__builtin_expect (flags & FNM_EXTMATCH, 0) && *p == '(') { int res; res = EXT (c, p, n, string_end, no_leading_period, flags); if (res != -1) return res; } goto normal_match; case L_('/'): if (NO_LEADING_PERIOD (flags)) { if (n == string_end || c != (UCHAR) *n) return FNM_NOMATCH; new_no_leading_period = true; break; } /* FALLTHROUGH */ default: normal_match: if (n == string_end || c != FOLD ((UCHAR) *n)) return FNM_NOMATCH; } no_leading_period = new_no_leading_period; ++n; } if (n == string_end) return 0; if ((flags & FNM_LEADING_DIR) && n != string_end && *n == L_('/')) /* The FNM_LEADING_DIR flag says that "foo*" matches "foobar/frobozz". */ return 0; return FNM_NOMATCH; } static const CHAR * internal_function END (const CHAR *pattern) { const CHAR *p = pattern; while (1) if (*++p == L_('\0')) /* This is an invalid pattern. */ return pattern; else if (*p == L_('[')) { /* Handle brackets special. */ if (posixly_correct == 0) posixly_correct = getenv ("POSIXLY_CORRECT") != NULL ? 1 : -1; /* Skip the not sign. We have to recognize it because of a possibly following ']'. */ if (*++p == L_('!') || (posixly_correct < 0 && *p == L_('^'))) ++p; /* A leading ']' is recognized as such. */ if (*p == L_(']')) ++p; /* Skip over all characters of the list. */ while (*p != L_(']')) if (*p++ == L_('\0')) /* This is no valid pattern. */ return pattern; } else if ((*p == L_('?') || *p == L_('*') || *p == L_('+') || *p == L_('@') || *p == L_('!')) && p[1] == L_('(')) p = END (p + 1); else if (*p == L_(')')) break; return p + 1; } static int internal_function EXT (INT opt, const CHAR *pattern, const CHAR *string, const CHAR *string_end, bool no_leading_period, int flags) { const CHAR *startp; size_t level; struct patternlist { struct patternlist *next; CHAR str[1]; } *list = NULL; struct patternlist **lastp = &list; size_t pattern_len = STRLEN (pattern); const CHAR *p; const CHAR *rs; enum { ALLOCA_LIMIT = 8000 }; /* Parse the pattern. Store the individual parts in the list. */ level = 0; for (startp = p = pattern + 1; ; ++p) if (*p == L_('\0')) /* This is an invalid pattern. */ return -1; else if (*p == L_('[')) { /* Handle brackets special. */ if (posixly_correct == 0) posixly_correct = getenv ("POSIXLY_CORRECT") != NULL ? 1 : -1; /* Skip the not sign. We have to recognize it because of a possibly following ']'. */ if (*++p == L_('!') || (posixly_correct < 0 && *p == L_('^'))) ++p; /* A leading ']' is recognized as such. */ if (*p == L_(']')) ++p; /* Skip over all characters of the list. */ while (*p != L_(']')) if (*p++ == L_('\0')) /* This is no valid pattern. */ return -1; } else if ((*p == L_('?') || *p == L_('*') || *p == L_('+') || *p == L_('@') || *p == L_('!')) && p[1] == L_('(')) /* Remember the nesting level. */ ++level; else if (*p == L_(')')) { if (level-- == 0) { /* This means we found the end of the pattern. */ #define NEW_PATTERN \ struct patternlist *newp; \ size_t plen; \ size_t plensize; \ size_t newpsize; \ \ assert (p > startp); \ plen = (opt == L_('?') || opt == L_('@') \ ? pattern_len \ : (unsigned) (p - startp) + 1); \ plensize = plen * sizeof (CHAR); \ newpsize = offsetof (struct patternlist, str) + plensize; \ if ((size_t) -1 / sizeof (CHAR) < plen \ || newpsize < offsetof (struct patternlist, str) \ || ALLOCA_LIMIT <= newpsize) \ return -1; \ newp = (struct patternlist *) alloca (newpsize); \ *((CHAR *) MEMPCPY (newp->str, startp, p - startp)) = L_('\0'); \ newp->next = NULL; \ *lastp = newp; \ lastp = &newp->next NEW_PATTERN; break; } } else if (*p == L_('|')) { if (level == 0) { NEW_PATTERN; startp = p + 1; } } assert (list != NULL); assert (p[-1] == L_(')')); #undef NEW_PATTERN switch (opt) { case L_('*'): if (FCT (p, string, string_end, no_leading_period, flags) == 0) return 0; /* FALLTHROUGH */ case L_('+'): do { for (rs = string; rs <= string_end; ++rs) /* First match the prefix with the current pattern with the current pattern. */ if (FCT (list->str, string, rs, no_leading_period, flags & FNM_FILE_NAME ? flags : flags & ~FNM_PERIOD) == 0 /* This was successful. Now match the rest with the rest of the pattern. */ && (FCT (p, rs, string_end, rs == string ? no_leading_period : rs[-1] == '/' && NO_LEADING_PERIOD (flags), flags & FNM_FILE_NAME ? flags : flags & ~FNM_PERIOD) == 0 /* This didn't work. Try the whole pattern. */ || (rs != string && FCT (pattern - 1, rs, string_end, rs == string ? no_leading_period : rs[-1] == '/' && NO_LEADING_PERIOD (flags), flags & FNM_FILE_NAME ? flags : flags & ~FNM_PERIOD) == 0))) /* It worked. Signal success. */ return 0; } while ((list = list->next) != NULL); /* None of the patterns lead to a match. */ return FNM_NOMATCH; case L_('?'): if (FCT (p, string, string_end, no_leading_period, flags) == 0) return 0; /* FALLTHROUGH */ case L_('@'): do /* I cannot believe it but `strcat' is actually acceptable here. Match the entire string with the prefix from the pattern list and the rest of the pattern following the pattern list. */ if (FCT (STRCAT (list->str, p), string, string_end, no_leading_period, flags & FNM_FILE_NAME ? flags : flags & ~FNM_PERIOD) == 0) /* It worked. Signal success. */ return 0; while ((list = list->next) != NULL); /* None of the patterns lead to a match. */ return FNM_NOMATCH; case L_('!'): for (rs = string; rs <= string_end; ++rs) { struct patternlist *runp; for (runp = list; runp != NULL; runp = runp->next) if (FCT (runp->str, string, rs, no_leading_period, flags & FNM_FILE_NAME ? flags : flags & ~FNM_PERIOD) == 0) break; /* If none of the patterns matched see whether the rest does. */ if (runp == NULL && (FCT (p, rs, string_end, rs == string ? no_leading_period : rs[-1] == '/' && NO_LEADING_PERIOD (flags), flags & FNM_FILE_NAME ? flags : flags & ~FNM_PERIOD) == 0)) /* This is successful. */ return 0; } /* None of the patterns together with the rest of the pattern lead to a match. */ return FNM_NOMATCH; default: assert (! "Invalid extended matching operator"); break; } return -1; } #undef FOLD #undef CHAR #undef UCHAR #undef INT #undef FCT #undef EXT #undef END #undef MEMPCPY #undef MEMCHR #undef STRCOLL #undef STRLEN #undef STRCAT #undef L_ #undef BTOWC