#include #ifndef HAVE_RE_COMP /* * These routines are BSD regex(3)/ed(1) compatible regular-expression * routines written by Ozan S. Yigit, Computer Science, York University. * Parts of the code that are not needed by Prospero have been removed, * but most of the accompanying information has been left intact. * This file is to be included on those operating systems that do not * support re_comp and re_exec. */ /* * regex - Regular expression pattern matching * and replacement * * by: Ozan S. Yigit (oz@nexus.yorku.ca) * Dept. of Computing Services * York University * * These routines are the PUBLIC DOMAIN equivalents * of regex routines as found in 4.nBSD UN*X, with minor * extensions. * * Modification history: * * $Log: regex.c,v $ * Revision 1.4 1996/04/25 20:06:29 blob * Added const's so that it will compile on OSs that have const in the prototype in * unistd.h * * Revision 1.3 1996/04/11 06:52:27 blob * *** empty log message *** * * Revision 1.2 1996/04/11 06:51:34 blob * Cleaned up warnings... * * Revision 1.1.1.2 1996/03/14 22:06:31 blob * Try 1000000... * * Revision 1.1.1.1 1996/03/13 20:34:40 blob * Initial Socks5 Beta import. * * Revision 1.1 1991/11/20 02:32:13 brendan * entered into RCS * * Revision 1.1 1991/11/20 02:32:13 brendan * entered into RCS * * Revision 1.3 89/04/01 14:18:09 oz * Change all references to a dfa: this is actually an nfa. * * Revision 1.2 88/08/28 15:36:04 oz * Use a complement bitmap to represent NCL. * This removes the need to have seperate * code in the pmatch case block - it is * just CCL code now. * * Use the actual CCL code in the CLO * section of pmatch. No need for a recursive * pmatch call. * * Use a bitmap table to set char bits in an * 8-bit chunk. * * Routines: * re_comp: compile a regular expression into * a NFA. * * char *re_comp(s) * char *s; * * re_exec: execute the NFA to match a pattern. * * int re_exec(s) * char *s; * * Regular Expressions: * * [1] char matches itself, unless it is a special * character (metachar): . \ [ ] * + ^ $ * * [2] . matches any character. * * [3] \ matches the character following it, except * when followed by a left or right round bracket, * a digit 1 to 9 or a left or right angle bracket. * (see [7], [8] and [9]) * It is used as an escape character for all * other meta-characters, and itself. When used * in a set ([4]), it is treated as an ordinary * character. * * [4] [set] matches one of the characters in the set. * If the first character in the set is "^", * it matches a character NOT in the set, i.e. * complements the set. A shorthand S-E is * used to specify a set of characters S upto * E, inclusive. The special characters "]" and * "-" have no special meaning if they appear * as the first chars in the set. * examples: match: * * [a-z] any lowercase alpha * * [^]-] any char except ] and - * * [^A-Z] any char except uppercase * alpha * * [a-zA-Z] any alpha * * [5] * any regular expression form [1] to [4], followed by * closure char (*) matches zero or more matches of * that form. * * [6] + same as [5], except it matches one or more. * * [7] a regular expression in the form [1] to [10], enclosed * as \(form\) matches what form matches. The enclosure * creates a set of tags, used for [8] and for * pattern substution. The tagged forms are numbered * starting from 1. * * [8] a \ followed by a digit 1 to 9 matches whatever a * previously tagged regular expression ([7]) matched. * * [9] \< a regular expression starting with a \< construct * \> and/or ending with a \> construct, restricts the * pattern matching to the beginning of a word, and/or * the end of a word. A word is defined to be a character * string beginning and/or ending with the characters * A-Z a-z 0-9 and _. It must also be preceded and/or * followed by any character outside those mentioned. * * [10] a composite regular expression xy where x and y * are in the form [1] to [10] matches the longest * match of x followed by a match for y. * * [11] ^ a regular expression starting with a ^ character * $ and/or ending with a $ character, restricts the * pattern matching to the beginning of the line, * or the end of line. [anchors] Elsewhere in the * pattern, ^ and $ are treated as ordinary characters. * * * Acknowledgements: * * HCR's Hugh Redelmeier has been most helpful in various * stages of development. He convinced me to include BOW * and EOW constructs, originally invented by Rob Pike at * the University of Toronto. * * References: * Software tools Kernighan & Plauger * Software tools in Pascal Kernighan & Plauger * Grep [rsx-11 C dist] David Conroy * ed - text editor Un*x Programmer's Manual * Advanced editing on Un*x B. W. Kernighan * regexp routines Henry Spencer * * Notes: * * This implementation uses a bit-set representation for character * classes for speed and compactness. Each character is represented * by one bit in a 128-bit block. Thus, CCL always takes a * constant 16 bytes in the internal nfa, and re_exec does a single * bit comparison to locate the character in the set. * * Examples: * * pattern: foo*.* * compile: CHR f CHR o CLO CHR o END CLO ANY END END * matches: fo foo fooo foobar fobar foxx ... * * pattern: fo[ob]a[rz] * compile: CHR f CHR o CCL bitset CHR a CCL bitset END * matches: fobar fooar fobaz fooaz * * pattern: foo\\+ * compile: CHR f CHR o CHR o CHR \ CLO CHR \ END END * matches: foo\ foo\\ foo\\\ ... * * pattern: \(foo\)[1-3]\1 (same as foo[1-3]foo) * compile: BOT 1 CHR f CHR o CHR o EOT 1 CCL bitset REF 1 END * matches: foo1foo foo2foo foo3foo * * pattern: \(fo.*\)-\1 * compile: BOT 1 CHR f CHR o CLO ANY END EOT 1 CHR - REF 1 END * matches: foo-foo fo-fo fob-fob foobar-foobar ... * */ #define MAXNFA 1024 #define MAXTAG 10 #define OKP 1 #define NOP 0 #define CHR 1 #define ANY 2 #define CCL 3 #define BOL 4 #define EOL 5 #define BOT 6 #define EOT 7 #define BOW 8 #define EOW 9 #define REF 10 #define CLO 11 #define END 0 /* * The following defines are not meant * to be changeable. They are for readability * only. * */ #define MAXCHR 128 #define CHRBIT 8 #define BITBLK MAXCHR/CHRBIT #define BLKIND 0170 #define BITIND 07 #define ASCIIB 0177 typedef /*unsigned*/ char CHAR; static int tagstk[MAXTAG]; /* subpat tag stack..*/ static CHAR nfa[MAXNFA]; /* automaton.. */ static int sta = NOP; /* status of lastpat */ static CHAR bittab[BITBLK]; /* bit table for CCL */ /* pre-set bits... */ static CHAR bitarr[] = {1,2,4,8,16,32,64,128}; static int internal_error; static void chset(c) register CHAR c; { bittab[((c) & BLKIND) >> 3] |= bitarr[(c) & BITIND]; } #define badpat(x) return (*nfa = END, x) #define store(x) *mp++ = x char * re_comp(pat) const char *pat; { register const char *p; /* pattern pointer */ register CHAR *mp = nfa; /* nfa pointer */ register CHAR *lp; /* saved pointer.. */ register CHAR *sp = nfa; /* another one.. */ register int tagi = 0; /* tag stack index */ register int tagc = 1; /* actual tag count */ register int n; register CHAR mask; /* xor mask -CCL/NCL */ int c1, c2; if (!pat || !*pat) if (sta) return 0; else badpat("No previous regular expression"); sta = NOP; for (p = pat; *p; p++) { lp = mp; switch(*p) { case '.': /* match any char.. */ store(ANY); break; case '^': /* match beginning.. */ if (p == pat) store(BOL); else { store(CHR); store(*p); } break; case '$': /* match endofline.. */ if (!*(p+1)) store(EOL); else { store(CHR); store(*p); } break; case '[': /* match char class..*/ store(CCL); if (*++p == '^') { mask = 0377; p++; } else mask = 0; if (*p == '-') /* real dash */ chset(*p++); if (*p == ']') /* real brac */ chset(*p++); while (*p && *p != ']') { if (*p == '-' && *(p+1) && *(p+1) != ']') { p++; c1 = *(p-2) + 1; c2 = *p++; while (c1 <= c2) chset(c1++); } #ifdef EXTEND else if (*p == '\\' && *(p+1)) { p++; chset(*p++); } #endif else chset(*p++); } if (!*p) badpat("Missing ]"); for (n = 0; n < BITBLK; bittab[n++] = (char) 0) store(mask ^ bittab[n]); break; case '*': /* match 0 or more.. */ case '+': /* match 1 or more.. */ if (p == pat) badpat("Empty closure"); lp = sp; /* previous opcode */ if (*lp == CLO) /* equivalence.. */ break; switch(*lp) { case BOL: case BOT: case EOT: case BOW: case EOW: case REF: badpat("Illegal closure"); default: break; } if (*p == '+') for (sp = mp; lp < sp; lp++) store(*lp); store(END); store(END); sp = mp; while (--mp > lp) *mp = mp[-1]; store(CLO); mp = sp; break; case '\\': /* tags, backrefs .. */ switch(*++p) { case '(': if (tagc < MAXTAG) { tagstk[++tagi] = tagc; store(BOT); store(tagc++); } else badpat("Too many \\(\\) pairs"); break; case ')': if (*sp == BOT) badpat("Null pattern inside \\(\\)"); if (tagi > 0) { store(EOT); store(tagstk[tagi--]); } else badpat("Unmatched \\)"); break; case '<': store(BOW); break; case '>': if (*sp == BOW) badpat("Null pattern inside \\<\\>"); store(EOW); break; case '1': case '2': case '3': case '4': case '5': case '6': case '7': case '8': case '9': n = *p-'0'; if (tagi > 0 && tagstk[tagi] == n) badpat("Cyclical reference"); if (tagc > n) { store(REF); store(n); } else badpat("Undetermined reference"); break; #ifdef EXTEND case 'b': store(CHR); store('\b'); break; case 'n': store(CHR); store('\n'); break; case 'f': store(CHR); store('\f'); break; case 'r': store(CHR); store('\r'); break; case 't': store(CHR); store('\t'); break; #endif default: store(CHR); store(*p); } break; default : /* an ordinary char */ store(CHR); store(*p); break; } sp = lp; } if (tagi > 0) badpat("Unmatched \\("); store(END); sta = OKP; return 0; } static const char *bol; static const char *bopat[MAXTAG]; static const char *eopat[MAXTAG]; static const char *pmatch P((const char *, CHAR *)); /* * re_exec: * execute nfa to find a match. * * special cases: (nfa[0]) * BOL * Match only once, starting from the * beginning. * CHR * First locate the character without * calling pmatch, and if found, call * pmatch for the remaining string. * END * re_comp failed, poor luser did not * check for it. Fail fast. * * If a match is found, bopat[0] and eopat[0] are set * to the beginning and the end of the matched fragment, * respectively. * */ int re_exec(lp) register const char *lp; { register char c; register const char *ep = 0; register CHAR *ap = nfa; bol = lp; bopat[0] = 0; bopat[1] = 0; bopat[2] = 0; bopat[3] = 0; bopat[4] = 0; bopat[5] = 0; bopat[6] = 0; bopat[7] = 0; bopat[8] = 0; bopat[9] = 0; switch(*ap) { case BOL: /* anchored: match from BOL only */ ep = pmatch(lp,ap); break; case CHR: /* ordinary char: locate it fast */ c = *(ap+1); while (*lp && *lp != c) lp++; if (!*lp) /* if EOS, fail, else fall thru. */ return 0; default: /* regular matching all the way. */ while (*lp) { if ((ep = pmatch(lp,ap))) break; lp++; } break; case END: /* munged automaton. fail always */ return 0; } if (!ep) return 0; if (internal_error) return -1; bopat[0] = lp; eopat[0] = ep; return 1; } /* * pmatch: * internal routine for the hard part * * This code is mostly snarfed from an early * grep written by David Conroy. The backref and * tag stuff, and various other mods are by oZ. * * special cases: (nfa[n], nfa[n+1]) * CLO ANY * We KNOW ".*" will match ANYTHING * upto the end of line. Thus, go to * the end of line straight, without * calling pmatch recursively. As in * the other closure cases, the remaining * pattern must be matched by moving * backwards on the string recursively, * to find a match for xy (x is ".*" and * y is the remaining pattern) where * the match satisfies the LONGEST match * for x followed by a match for y. * CLO CHR * We can again scan the string forward * for the single char without recursion, * and at the point of failure, we execute * the remaining nfa recursively, as * described above. * * At the end of a successful match, bopat[n] and eopat[n] * are set to the beginning and end of subpatterns matched * by tagged expressions (n = 1 to 9). * */ /* * character classification table for word boundary * operators BOW and EOW. the reason for not using * ctype macros is that we can let the user add into * our own table. see re_modw. This table is not in * the bitset form, since we may wish to extend it * in the future for other character classifications. * * TRUE for 0-9 A-Z a-z _ */ static char chrtyp[MAXCHR] = { 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 0, 0, 0, 0, 0, 0, 0, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 0, 0, 0, 0, 1, 0, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 0, 0, 0, 0, 0 }; #define inascii(x) (0177&(x)) #define iswordc(x) chrtyp[inascii(x)] #define isinset(x,y) ((x)[((y)&BLKIND)>>3] & bitarr[(y)&BITIND]) /* * skip values for CLO XXX to skip past the closure * */ #define ANYSKIP 2 /* [CLO] ANY END ... */ #define CHRSKIP 3 /* [CLO] CHR chr END ... */ #define CCLSKIP 18 /* [CLO] CCL 16bytes END ... */ static const char * pmatch(lp, ap) register const char *lp; register CHAR *ap; { register int op, c, n; register const char *e; /* extra pointer for CLO */ register const char *bp; /* beginning of subpat.. */ register const char *ep; /* ending of subpat.. */ const char *are; /* to save the line ptr. */ while ((op = *ap++) != END) switch(op) { case CHR: if (*lp++ != *ap++) return 0; break; case ANY: if (!*lp++) return 0; break; case CCL: c = *lp++; if (!isinset(ap,c)) return 0; ap += BITBLK; break; case BOL: if (lp != bol) return 0; break; case EOL: if (*lp) return 0; break; case BOT: bopat[(int)(*ap++)] = lp; break; case EOT: eopat[(int)(*ap++)] = lp; break; case BOW: if ((lp!=bol && iswordc(lp[-1])) || !iswordc(*lp)) return 0; break; case EOW: if (lp==bol || !iswordc(lp[-1]) || iswordc(*lp)) return 0; break; case REF: n = *ap++; bp = bopat[n]; ep = eopat[n]; while (bp < ep) if (*bp++ != *lp++) return 0; break; case CLO: are = lp; switch(*ap) { case ANY: while (*lp) lp++; n = ANYSKIP; break; case CHR: c = *(ap+1); while (*lp && c == *lp) lp++; n = CHRSKIP; break; case CCL: while ((c = *lp) && isinset(ap+1,c)) lp++; n = CCLSKIP; break; default: internal_error++; return 0; } ap += n; while (lp >= are) { if ((e = pmatch(lp, ap))) return e; --lp; } return 0; default: internal_error++; return 0; } return lp; } #endif /* Need regex libraries? Compile to nothing if not. */