Mercurial > gnulib
view lib/rx.c @ 20213:389f6a197bf5
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| author | Jim Meyering <jim@meyering.net> |
|---|---|
| date | Fri, 15 Dec 1995 15:12:58 +0000 |
| parents | dbf1f58553fd |
| children | f2c4a67c18cc |
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/* Copyright (C) 1992, 1993, 1994, 1995 Free Software Foundation, Inc. This file is part of the librx library. Librx is free software; you can redistribute it and/or modify it under the terms of the GNU Library General Public License as published by the Free Software Foundation; either version 2, or (at your option) any later version. Librx 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 Library General Public License along with this software; see the file COPYING.LIB. If not, write to the Free Software Foundation, 675 Mass Ave, Cambridge, MA 02139, USA. */ /* NOTE!!! AIX is so losing it requires this to be the first thing in the * file. * Do not put ANYTHING before it! */ #if !defined (__GNUC__) && defined (_AIX) #pragma alloca #endif /* To make linux happy? */ #ifndef _GNU_SOURCE #define _GNU_SOURCE #endif const char *rx_version_string = "GNU Rx version 0.07.2"; /* ``Too hard!'' * -- anon. */ #include <stdio.h> #include <ctype.h> #ifndef isgraph #define isgraph(c) (isprint (c) && !isspace (c)) #endif #ifndef isblank #define isblank(c) ((c) == ' ' || (c) == '\t') #endif #include <sys/types.h> #undef MAX #undef MIN #define MAX(a, b) ((a) > (b) ? (a) : (b)) #define MIN(a, b) ((a) < (b) ? (a) : (b)) typedef char boolean; #define false 0 #define true 1 #ifndef __GCC__ #undef __inline__ #define __inline__ #endif /* Emacs already defines alloca, sometimes. */ #ifndef alloca /* Make alloca work the best possible way. */ #ifdef __GNUC__ #define alloca __builtin_alloca #else /* not __GNUC__ */ #if HAVE_ALLOCA_H #include <alloca.h> #else /* not __GNUC__ or HAVE_ALLOCA_H */ #ifndef _AIX /* Already did AIX, up at the top. */ char *alloca (); #endif /* not _AIX */ #endif /* not HAVE_ALLOCA_H */ #endif /* not __GNUC__ */ #endif /* not alloca */ /* Memory management and stuff for emacs. */ #define CHARBITS 8 #define remalloc(M, S) (M ? realloc (M, S) : malloc (S)) /* Should we use malloc or alloca? If REGEX_MALLOC is not defined, we * use `alloca' instead of `malloc' for the backtracking stack. * * Emacs will die miserably if we don't do this. */ #ifdef REGEX_MALLOC #define REGEX_ALLOCATE malloc #else /* not REGEX_MALLOC */ #define REGEX_ALLOCATE alloca #endif /* not REGEX_MALLOC */ #ifdef RX_WANT_RX_DEFS #define RX_DECL extern #define RX_DEF_QUAL #else #define RX_WANT_RX_DEFS #define RX_DECL static #define RX_DEF_QUAL static #endif #include "rx.h" #undef RX_DECL #define RX_DECL RX_DEF_QUAL #ifndef emacs #ifdef SYNTAX_TABLE extern char *re_syntax_table; #else /* not SYNTAX_TABLE */ RX_DECL char re_syntax_table[CHAR_SET_SIZE]; #ifdef __STDC__ static void init_syntax_once (void) #else static void init_syntax_once () #endif { register int c; static int done = 0; if (done) return; bzero (re_syntax_table, sizeof re_syntax_table); for (c = 'a'; c <= 'z'; c++) re_syntax_table[c] = Sword; for (c = 'A'; c <= 'Z'; c++) re_syntax_table[c] = Sword; for (c = '0'; c <= '9'; c++) re_syntax_table[c] = Sword; re_syntax_table['_'] = Sword; done = 1; } #endif /* not SYNTAX_TABLE */ #endif /* not emacs */ /* Compile with `-DRX_DEBUG' and use the following flags. * * Debugging flags: * rx_debug - print information as a regexp is compiled * rx_debug_trace - print information as a regexp is executed */ #ifdef RX_DEBUG int rx_debug_compile = 0; int rx_debug_trace = 0; static struct re_pattern_buffer * dbug_rxb = 0; #ifdef __STDC__ typedef void (*side_effect_printer) (struct rx *, void *, FILE *); #else typedef void (*side_effect_printer) (); #endif #ifdef __STDC__ static void print_cset (struct rx *rx, rx_Bitset cset, FILE * fp); #else static void print_cset (); #endif #ifdef __STDC__ static void print_rexp (struct rx *rx, struct rexp_node *node, int depth, side_effect_printer seprint, FILE * fp) #else static void print_rexp (rx, node, depth, seprint, fp) struct rx *rx; struct rexp_node *node; int depth; side_effect_printer seprint; FILE * fp; #endif { if (!node) return; else { switch (node->type) { case r_cset: { fprintf (fp, "%*s", depth, ""); print_cset (rx, node->params.cset, fp); fputc ('\n', fp); break; } case r_opt: case r_star: fprintf (fp, "%*s%s\n", depth, "", node->type == r_opt ? "opt" : "star"); print_rexp (rx, node->params.pair.left, depth + 3, seprint, fp); break; case r_2phase_star: fprintf (fp, "%*s2phase star\n", depth, ""); print_rexp (rx, node->params.pair.right, depth + 3, seprint, fp); print_rexp (rx, node->params.pair.left, depth + 3, seprint, fp); break; case r_alternate: case r_concat: fprintf (fp, "%*s%s\n", depth, "", node->type == r_alternate ? "alt" : "concat"); print_rexp (rx, node->params.pair.left, depth + 3, seprint, fp); print_rexp (rx, node->params.pair.right, depth + 3, seprint, fp); break; case r_side_effect: fprintf (fp, "%*sSide effect: ", depth, ""); seprint (rx, node->params.side_effect, fp); fputc ('\n', fp); } } } #ifdef __STDC__ static void print_nfa (struct rx * rx, struct rx_nfa_state * n, side_effect_printer seprint, FILE * fp) #else static void print_nfa (rx, n, seprint, fp) struct rx * rx; struct rx_nfa_state * n; side_effect_printer seprint; FILE * fp; #endif { while (n) { struct rx_nfa_edge *e = n->edges; struct rx_possible_future *ec = n->futures; fprintf (fp, "node %d %s\n", n->id, n->is_final ? "final" : (n->is_start ? "start" : "")); while (e) { fprintf (fp, " edge to %d, ", e->dest->id); switch (e->type) { case ne_epsilon: fprintf (fp, "epsilon\n"); break; case ne_side_effect: fprintf (fp, "side effect "); seprint (rx, e->params.side_effect, fp); fputc ('\n', fp); break; case ne_cset: fprintf (fp, "cset "); print_cset (rx, e->params.cset, fp); fputc ('\n', fp); break; } e = e->next; } while (ec) { int x; struct rx_nfa_state_set * s; struct rx_se_list * l; fprintf (fp, " eclosure to {"); for (s = ec->destset; s; s = s->cdr) fprintf (fp, "%d ", s->car->id); fprintf (fp, "} ("); for (l = ec->effects; l; l = l->cdr) { seprint (rx, l->car, fp); fputc (' ', fp); } fprintf (fp, ")\n"); ec = ec->next; } n = n->next; } } static char * efnames [] = { "bogon", "re_se_try", "re_se_pushback", "re_se_push0", "re_se_pushpos", "re_se_chkpos", "re_se_poppos", "re_se_at_dot", "re_se_syntax", "re_se_not_syntax", "re_se_begbuf", "re_se_hat", "re_se_wordbeg", "re_se_wordbound", "re_se_notwordbound", "re_se_wordend", "re_se_endbuf", "re_se_dollar", "re_se_fail", }; static char * efnames2[] = { "re_se_win", "re_se_lparen", "re_se_rparen", "re_se_backref", "re_se_iter", "re_se_end_iter", "re_se_tv" }; static char * inx_names[] = { "rx_backtrack_point", "rx_do_side_effects", "rx_cache_miss", "rx_next_char", "rx_backtrack", "rx_error_inx", "rx_num_instructions" }; #ifdef __STDC__ static void re_seprint (struct rx * rx, void * effect, FILE * fp) #else static void re_seprint (rx, effect, fp) struct rx * rx; void * effect; FILE * fp; #endif { if ((int)effect < 0) fputs (efnames[-(int)effect], fp); else if (dbug_rxb) { struct re_se_params * p = &dbug_rxb->se_params[(int)effect]; fprintf (fp, "%s(%d,%d)", efnames2[p->se], p->op1, p->op2); } else fprintf (fp, "[complex op # %d]", (int)effect); } /* These are so the regex.c regression tests will compile. */ void print_compiled_pattern (rxb) struct re_pattern_buffer * rxb; { } void print_fastmap (fm) char * fm; { } #endif /* RX_DEBUG */ /* This page: Bitsets. Completely unintersting. */ #ifdef __STDC__ RX_DECL int rx_bitset_is_equal (int size, rx_Bitset a, rx_Bitset b) #else RX_DECL int rx_bitset_is_equal (size, a, b) int size; rx_Bitset a; rx_Bitset b; #endif { int x; RX_subset s = b[0]; b[0] = ~a[0]; for (x = rx_bitset_numb_subsets(size) - 1; a[x] == b[x]; --x) ; b[0] = s; return !x && s == a[0]; } #ifdef __STDC__ RX_DECL int rx_bitset_is_subset (int size, rx_Bitset a, rx_Bitset b) #else RX_DECL int rx_bitset_is_subset (size, a, b) int size; rx_Bitset a; rx_Bitset b; #endif { int x = rx_bitset_numb_subsets(size) - 1; while (x-- && (a[x] & b[x]) == a[x]); return x == -1; } #ifdef __STDC__ RX_DECL int rx_bitset_empty (int size, rx_Bitset set) #else RX_DECL int rx_bitset_empty (size, set) int size; rx_Bitset set; #endif { int x; RX_subset s = set[0]; set[0] = 1; for (x = rx_bitset_numb_subsets(size) - 1; !set[x]; --x) ; set[0] = s; return !s; } #ifdef __STDC__ RX_DECL void rx_bitset_null (int size, rx_Bitset b) #else RX_DECL void rx_bitset_null (size, b) int size; rx_Bitset b; #endif { bzero (b, rx_sizeof_bitset(size)); } #ifdef __STDC__ RX_DECL void rx_bitset_universe (int size, rx_Bitset b) #else RX_DECL void rx_bitset_universe (size, b) int size; rx_Bitset b; #endif { int x = rx_bitset_numb_subsets (size); while (x--) *b++ = ~(RX_subset)0; } #ifdef __STDC__ RX_DECL void rx_bitset_complement (int size, rx_Bitset b) #else RX_DECL void rx_bitset_complement (size, b) int size; rx_Bitset b; #endif { int x = rx_bitset_numb_subsets (size); while (x--) { *b = ~*b; ++b; } } #ifdef __STDC__ RX_DECL void rx_bitset_assign (int size, rx_Bitset a, rx_Bitset b) #else RX_DECL void rx_bitset_assign (size, a, b) int size; rx_Bitset a; rx_Bitset b; #endif { int x; for (x = rx_bitset_numb_subsets(size) - 1; x >=0; --x) a[x] = b[x]; } #ifdef __STDC__ RX_DECL void rx_bitset_union (int size, rx_Bitset a, rx_Bitset b) #else RX_DECL void rx_bitset_union (size, a, b) int size; rx_Bitset a; rx_Bitset b; #endif { int x; for (x = rx_bitset_numb_subsets(size) - 1; x >=0; --x) a[x] |= b[x]; } #ifdef __STDC__ RX_DECL void rx_bitset_intersection (int size, rx_Bitset a, rx_Bitset b) #else RX_DECL void rx_bitset_intersection (size, a, b) int size; rx_Bitset a; rx_Bitset b; #endif { int x; for (x = rx_bitset_numb_subsets(size) - 1; x >=0; --x) a[x] &= b[x]; } #ifdef __STDC__ RX_DECL void rx_bitset_difference (int size, rx_Bitset a, rx_Bitset b) #else RX_DECL void rx_bitset_difference (size, a, b) int size; rx_Bitset a; rx_Bitset b; #endif { int x; for (x = rx_bitset_numb_subsets(size) - 1; x >=0; --x) a[x] &= ~ b[x]; } #ifdef __STDC__ RX_DECL void rx_bitset_revdifference (int size, rx_Bitset a, rx_Bitset b) #else RX_DECL void rx_bitset_revdifference (size, a, b) int size; rx_Bitset a; rx_Bitset b; #endif { int x; for (x = rx_bitset_numb_subsets(size) - 1; x >=0; --x) a[x] = ~a[x] & b[x]; } #ifdef __STDC__ RX_DECL void rx_bitset_xor (int size, rx_Bitset a, rx_Bitset b) #else RX_DECL void rx_bitset_xor (size, a, b) int size; rx_Bitset a; rx_Bitset b; #endif { int x; for (x = rx_bitset_numb_subsets(size) - 1; x >=0; --x) a[x] ^= b[x]; } #ifdef __STDC__ RX_DECL unsigned long rx_bitset_hash (int size, rx_Bitset b) #else RX_DECL unsigned long rx_bitset_hash (size, b) int size; rx_Bitset b; #endif { int x; unsigned long hash = (unsigned long)rx_bitset_hash; for (x = rx_bitset_numb_subsets(size) - 1; x >= 0; --x) hash ^= rx_bitset_subset_val(b, x); return hash; } RX_DECL RX_subset rx_subset_singletons [RX_subset_bits] = { 0x1, 0x2, 0x4, 0x8, 0x10, 0x20, 0x40, 0x80, 0x100, 0x200, 0x400, 0x800, 0x1000, 0x2000, 0x4000, 0x8000, 0x10000, 0x20000, 0x40000, 0x80000, 0x100000, 0x200000, 0x400000, 0x800000, 0x1000000, 0x2000000, 0x4000000, 0x8000000, 0x10000000, 0x20000000, 0x40000000, 0x80000000 }; #ifdef RX_DEBUG #ifdef __STDC__ static void print_cset (struct rx *rx, rx_Bitset cset, FILE * fp) #else static void print_cset (rx, cset, fp) struct rx *rx; rx_Bitset cset; FILE * fp; #endif { int x; fputc ('[', fp); for (x = 0; x < rx->local_cset_size; ++x) if (RX_bitset_member (cset, x)) { if (isprint(x)) fputc (x, fp); else fprintf (fp, "\\0%o ", x); } fputc (']', fp); } #endif /* RX_DEBUG */ static unsigned long rx_hash_masks[4] = { 0x12488421, 0x96699669, 0xbe7dd7eb, 0xffffffff }; /* Hash tables */ #ifdef __STDC__ RX_DECL struct rx_hash_item * rx_hash_find (struct rx_hash * table, unsigned long hash, void * value, struct rx_hash_rules * rules) #else RX_DECL struct rx_hash_item * rx_hash_find (table, hash, value, rules) struct rx_hash * table; unsigned long hash; void * value; struct rx_hash_rules * rules; #endif { rx_hash_eq eq = rules->eq; int maskc = 0; long mask = rx_hash_masks [0]; int bucket = (hash & mask) % 13; while (table->children [bucket]) { table = table->children [bucket]; ++maskc; mask = rx_hash_masks[maskc]; bucket = (hash & mask) % 13; } { struct rx_hash_item * it = table->buckets[bucket]; while (it) if (eq (it->data, value)) return it; else it = it->next_same_hash; } return 0; } #ifdef __STDC__ RX_DECL struct rx_hash_item * rx_hash_store (struct rx_hash * table, unsigned long hash, void * value, struct rx_hash_rules * rules) #else RX_DECL struct rx_hash_item * rx_hash_store (table, hash, value, rules) struct rx_hash * table; unsigned long hash; void * value; struct rx_hash_rules * rules; #endif { rx_hash_eq eq = rules->eq; int maskc = 0; long mask = rx_hash_masks[0]; int bucket = (hash & mask) % 13; int depth = 0; while (table->children [bucket]) { table = table->children [bucket]; ++maskc; mask = rx_hash_masks[maskc]; bucket = (hash & mask) % 13; ++depth; } { struct rx_hash_item * it = table->buckets[bucket]; while (it) if (eq (it->data, value)) return it; else it = it->next_same_hash; } { if ( (depth < 3) && (table->bucket_size [bucket] >= 4)) { struct rx_hash * newtab = ((struct rx_hash *) rules->hash_alloc (rules)); if (!newtab) goto add_to_bucket; bzero (newtab, sizeof (*newtab)); newtab->parent = table; { struct rx_hash_item * them = table->buckets[bucket]; unsigned long newmask = rx_hash_masks[maskc + 1]; while (them) { struct rx_hash_item * save = them->next_same_hash; int new_buck = (them->hash & newmask) % 13; them->next_same_hash = newtab->buckets[new_buck]; newtab->buckets[new_buck] = them; them->table = newtab; them = save; ++newtab->bucket_size[new_buck]; ++newtab->refs; } table->refs = (table->refs - table->bucket_size[bucket] + 1); table->bucket_size[bucket] = 0; table->buckets[bucket] = 0; table->children[bucket] = newtab; table = newtab; bucket = (hash & newmask) % 13; } } } add_to_bucket: { struct rx_hash_item * it = ((struct rx_hash_item *) rules->hash_item_alloc (rules, value)); if (!it) return 0; it->hash = hash; it->table = table; /* DATA and BINDING are to be set in hash_item_alloc */ it->next_same_hash = table->buckets [bucket]; table->buckets[bucket] = it; ++table->bucket_size [bucket]; ++table->refs; return it; } } #ifdef __STDC__ RX_DECL void rx_hash_free (struct rx_hash_item * it, struct rx_hash_rules * rules) #else RX_DECL void rx_hash_free (it, rules) struct rx_hash_item * it; struct rx_hash_rules * rules; #endif { if (it) { struct rx_hash * table = it->table; unsigned long hash = it->hash; int depth = (table->parent ? (table->parent->parent ? (table->parent->parent->parent ? 3 : 2) : 1) : 0); int bucket = (hash & rx_hash_masks [depth]) % 13; struct rx_hash_item ** pos = &table->buckets [bucket]; while (*pos != it) pos = &(*pos)->next_same_hash; *pos = it->next_same_hash; rules->free_hash_item (it, rules); --table->bucket_size[bucket]; --table->refs; while (!table->refs && depth) { struct rx_hash * save = table; table = table->parent; --depth; bucket = (hash & rx_hash_masks [depth]) % 13; --table->refs; table->children[bucket] = 0; rules->free_hash (save, rules); } } } #ifdef __STDC__ RX_DECL void rx_free_hash_table (struct rx_hash * tab, rx_hash_freefn freefn, struct rx_hash_rules * rules) #else RX_DECL void rx_free_hash_table (tab, freefn, rules) struct rx_hash * tab; rx_hash_freefn freefn; struct rx_hash_rules * rules; #endif { int x; for (x = 0; x < 13; ++x) if (tab->children[x]) { rx_free_hash_table (tab->children[x], freefn, rules); rules->free_hash (tab->children[x], rules); } else { struct rx_hash_item * them = tab->buckets[x]; while (them) { struct rx_hash_item * that = them; them = that->next_same_hash; freefn (that); rules->free_hash_item (that, rules); } } } /* Utilities for manipulating bitset represntations of characters sets. */ #ifdef __STDC__ RX_DECL rx_Bitset rx_cset (struct rx *rx) #else RX_DECL rx_Bitset rx_cset (rx) struct rx *rx; #endif { rx_Bitset b = (rx_Bitset) malloc (rx_sizeof_bitset (rx->local_cset_size)); if (b) rx_bitset_null (rx->local_cset_size, b); return b; } #ifdef __STDC__ RX_DECL rx_Bitset rx_copy_cset (struct rx *rx, rx_Bitset a) #else RX_DECL rx_Bitset rx_copy_cset (rx, a) struct rx *rx; rx_Bitset a; #endif { rx_Bitset cs = rx_cset (rx); if (cs) rx_bitset_union (rx->local_cset_size, cs, a); return cs; } #ifdef __STDC__ RX_DECL void rx_free_cset (struct rx * rx, rx_Bitset c) #else RX_DECL void rx_free_cset (rx, c) struct rx * rx; rx_Bitset c; #endif { if (c) free ((char *)c); } /* Hash table memory allocation policy for the regexp compiler */ #ifdef __STDC__ static struct rx_hash * compiler_hash_alloc (struct rx_hash_rules * rules) #else static struct rx_hash * compiler_hash_alloc (rules) struct rx_hash_rules * rules; #endif { return (struct rx_hash *)malloc (sizeof (struct rx_hash)); } #ifdef __STDC__ static struct rx_hash_item * compiler_hash_item_alloc (struct rx_hash_rules * rules, void * value) #else static struct rx_hash_item * compiler_hash_item_alloc (rules, value) struct rx_hash_rules * rules; void * value; #endif { struct rx_hash_item * it; it = (struct rx_hash_item *)malloc (sizeof (*it)); if (it) { it->data = value; it->binding = 0; } return it; } #ifdef __STDC__ static void compiler_free_hash (struct rx_hash * tab, struct rx_hash_rules * rules) #else static void compiler_free_hash (tab, rules) struct rx_hash * tab; struct rx_hash_rules * rules; #endif { free ((char *)tab); } #ifdef __STDC__ static void compiler_free_hash_item (struct rx_hash_item * item, struct rx_hash_rules * rules) #else static void compiler_free_hash_item (item, rules) struct rx_hash_item * item; struct rx_hash_rules * rules; #endif { free ((char *)item); } /* This page: REXP_NODE (expression tree) structures. */ #ifdef __STDC__ RX_DECL struct rexp_node * rexp_node (struct rx *rx, enum rexp_node_type type) #else RX_DECL struct rexp_node * rexp_node (rx, type) struct rx *rx; enum rexp_node_type type; #endif { struct rexp_node *n; n = (struct rexp_node *)malloc (sizeof (*n)); bzero (n, sizeof (*n)); if (n) n->type = type; return n; } /* free_rexp_node assumes that the bitset passed to rx_mk_r_cset * can be freed using rx_free_cset. */ #ifdef __STDC__ RX_DECL struct rexp_node * rx_mk_r_cset (struct rx * rx, rx_Bitset b) #else RX_DECL struct rexp_node * rx_mk_r_cset (rx, b) struct rx * rx; rx_Bitset b; #endif { struct rexp_node * n = rexp_node (rx, r_cset); if (n) n->params.cset = b; return n; } #ifdef __STDC__ RX_DECL struct rexp_node * rx_mk_r_concat (struct rx * rx, struct rexp_node * a, struct rexp_node * b) #else RX_DECL struct rexp_node * rx_mk_r_concat (rx, a, b) struct rx * rx; struct rexp_node * a; struct rexp_node * b; #endif { struct rexp_node * n = rexp_node (rx, r_concat); if (n) { n->params.pair.left = a; n->params.pair.right = b; } return n; } #ifdef __STDC__ RX_DECL struct rexp_node * rx_mk_r_alternate (struct rx * rx, struct rexp_node * a, struct rexp_node * b) #else RX_DECL struct rexp_node * rx_mk_r_alternate (rx, a, b) struct rx * rx; struct rexp_node * a; struct rexp_node * b; #endif { struct rexp_node * n = rexp_node (rx, r_alternate); if (n) { n->params.pair.left = a; n->params.pair.right = b; } return n; } #ifdef __STDC__ RX_DECL struct rexp_node * rx_mk_r_opt (struct rx * rx, struct rexp_node * a) #else RX_DECL struct rexp_node * rx_mk_r_opt (rx, a) struct rx * rx; struct rexp_node * a; #endif { struct rexp_node * n = rexp_node (rx, r_opt); if (n) { n->params.pair.left = a; n->params.pair.right = 0; } return n; } #ifdef __STDC__ RX_DECL struct rexp_node * rx_mk_r_star (struct rx * rx, struct rexp_node * a) #else RX_DECL struct rexp_node * rx_mk_r_star (rx, a) struct rx * rx; struct rexp_node * a; #endif { struct rexp_node * n = rexp_node (rx, r_star); if (n) { n->params.pair.left = a; n->params.pair.right = 0; } return n; } #ifdef __STDC__ RX_DECL struct rexp_node * rx_mk_r_2phase_star (struct rx * rx, struct rexp_node * a, struct rexp_node * b) #else RX_DECL struct rexp_node * rx_mk_r_2phase_star (rx, a, b) struct rx * rx; struct rexp_node * a; struct rexp_node * b; #endif { struct rexp_node * n = rexp_node (rx, r_2phase_star); if (n) { n->params.pair.left = a; n->params.pair.right = b; } return n; } #ifdef __STDC__ RX_DECL struct rexp_node * rx_mk_r_side_effect (struct rx * rx, rx_side_effect a) #else RX_DECL struct rexp_node * rx_mk_r_side_effect (rx, a) struct rx * rx; rx_side_effect a; #endif { struct rexp_node * n = rexp_node (rx, r_side_effect); if (n) { n->params.side_effect = a; n->params.pair.right = 0; } return n; } #ifdef __STDC__ RX_DECL struct rexp_node * rx_mk_r_data (struct rx * rx, void * a) #else RX_DECL struct rexp_node * rx_mk_r_data (rx, a) struct rx * rx; void * a; #endif { struct rexp_node * n = rexp_node (rx, r_data); if (n) { n->params.pair.left = a; n->params.pair.right = 0; } return n; } #ifdef __STDC__ RX_DECL void rx_free_rexp (struct rx * rx, struct rexp_node * node) #else RX_DECL void rx_free_rexp (rx, node) struct rx * rx; struct rexp_node * node; #endif { if (node) { switch (node->type) { case r_cset: if (node->params.cset) rx_free_cset (rx, node->params.cset); case r_side_effect: break; case r_concat: case r_alternate: case r_2phase_star: case r_opt: case r_star: rx_free_rexp (rx, node->params.pair.left); rx_free_rexp (rx, node->params.pair.right); break; case r_data: /* This shouldn't occur. */ break; } free ((char *)node); } } #ifdef __STDC__ RX_DECL struct rexp_node * rx_copy_rexp (struct rx *rx, struct rexp_node *node) #else RX_DECL struct rexp_node * rx_copy_rexp (rx, node) struct rx *rx; struct rexp_node *node; #endif { if (!node) return 0; else { struct rexp_node *n = rexp_node (rx, node->type); if (!n) return 0; switch (node->type) { case r_cset: n->params.cset = rx_copy_cset (rx, node->params.cset); if (!n->params.cset) { rx_free_rexp (rx, n); return 0; } break; case r_side_effect: n->params.side_effect = node->params.side_effect; break; case r_concat: case r_alternate: case r_opt: case r_2phase_star: case r_star: n->params.pair.left = rx_copy_rexp (rx, node->params.pair.left); n->params.pair.right = rx_copy_rexp (rx, node->params.pair.right); if ( (node->params.pair.left && !n->params.pair.left) || (node->params.pair.right && !n->params.pair.right)) { rx_free_rexp (rx, n); return 0; } break; case r_data: /* shouldn't happen */ break; } return n; } } /* This page: functions to build and destroy graphs that describe nfa's */ /* Constructs a new nfa node. */ #ifdef __STDC__ RX_DECL struct rx_nfa_state * rx_nfa_state (struct rx *rx) #else RX_DECL struct rx_nfa_state * rx_nfa_state (rx) struct rx *rx; #endif { struct rx_nfa_state * n = (struct rx_nfa_state *)malloc (sizeof (*n)); if (!n) return 0; bzero (n, sizeof (*n)); n->next = rx->nfa_states; rx->nfa_states = n; return n; } #ifdef __STDC__ RX_DECL void rx_free_nfa_state (struct rx_nfa_state * n) #else RX_DECL void rx_free_nfa_state (n) struct rx_nfa_state * n; #endif { free ((char *)n); } /* This looks up an nfa node, given a numeric id. Numeric id's are * assigned after the nfa has been built. */ #ifdef __STDC__ RX_DECL struct rx_nfa_state * rx_id_to_nfa_state (struct rx * rx, int id) #else RX_DECL struct rx_nfa_state * rx_id_to_nfa_state (rx, id) struct rx * rx; int id; #endif { struct rx_nfa_state * n; for (n = rx->nfa_states; n; n = n->next) if (n->id == id) return n; return 0; } /* This adds an edge between two nodes, but doesn't initialize the * edge label. */ #ifdef __STDC__ RX_DECL struct rx_nfa_edge * rx_nfa_edge (struct rx *rx, enum rx_nfa_etype type, struct rx_nfa_state *start, struct rx_nfa_state *dest) #else RX_DECL struct rx_nfa_edge * rx_nfa_edge (rx, type, start, dest) struct rx *rx; enum rx_nfa_etype type; struct rx_nfa_state *start; struct rx_nfa_state *dest; #endif { struct rx_nfa_edge *e; e = (struct rx_nfa_edge *)malloc (sizeof (*e)); if (!e) return 0; e->next = start->edges; start->edges = e; e->type = type; e->dest = dest; return e; } #ifdef __STDC__ RX_DECL void rx_free_nfa_edge (struct rx_nfa_edge * e) #else RX_DECL void rx_free_nfa_edge (e) struct rx_nfa_edge * e; #endif { free ((char *)e); } /* This constructs a POSSIBLE_FUTURE, which is a kind epsilon-closure * of an NFA. These are added to an nfa automaticly by eclose_nfa. */ #ifdef __STDC__ static struct rx_possible_future * rx_possible_future (struct rx * rx, struct rx_se_list * effects) #else static struct rx_possible_future * rx_possible_future (rx, effects) struct rx * rx; struct rx_se_list * effects; #endif { struct rx_possible_future *ec; ec = (struct rx_possible_future *) malloc (sizeof (*ec)); if (!ec) return 0; ec->destset = 0; ec->next = 0; ec->effects = effects; return ec; } #ifdef __STDC__ static void rx_free_possible_future (struct rx_possible_future * pf) #else static void rx_free_possible_future (pf) struct rx_possible_future * pf; #endif { free ((char *)pf); } #ifdef __STDC__ RX_DECL void rx_free_nfa (struct rx *rx) #else RX_DECL void rx_free_nfa (rx) struct rx *rx; #endif { while (rx->nfa_states) { while (rx->nfa_states->edges) { switch (rx->nfa_states->edges->type) { case ne_cset: rx_free_cset (rx, rx->nfa_states->edges->params.cset); break; default: break; } { struct rx_nfa_edge * e; e = rx->nfa_states->edges; rx->nfa_states->edges = rx->nfa_states->edges->next; rx_free_nfa_edge (e); } } /* while (rx->nfa_states->edges) */ { /* Iterate over the partial epsilon closures of rx->nfa_states */ struct rx_possible_future * pf = rx->nfa_states->futures; while (pf) { struct rx_possible_future * pft = pf; pf = pf->next; rx_free_possible_future (pft); } } { struct rx_nfa_state *n; n = rx->nfa_states; rx->nfa_states = rx->nfa_states->next; rx_free_nfa_state (n); } } } /* This page: translating a pattern expression into an nfa and doing the * static part of the nfa->super-nfa translation. */ /* This is the thompson regexp->nfa algorithm. * It is modified to allow for `side-effect epsilons.' Those are * edges that are taken whenever a similar epsilon edge would be, * but which imply that some side effect occurs when the edge * is taken. * * Side effects are used to model parts of the pattern langauge * that are not regular (in the formal sense). */ #ifdef __STDC__ RX_DECL int rx_build_nfa (struct rx *rx, struct rexp_node *rexp, struct rx_nfa_state **start, struct rx_nfa_state **end) #else RX_DECL int rx_build_nfa (rx, rexp, start, end) struct rx *rx; struct rexp_node *rexp; struct rx_nfa_state **start; struct rx_nfa_state **end; #endif { struct rx_nfa_edge *edge; /* Start & end nodes may have been allocated by the caller. */ *start = *start ? *start : rx_nfa_state (rx); if (!*start) return 0; if (!rexp) { *end = *start; return 1; } *end = *end ? *end : rx_nfa_state (rx); if (!*end) { rx_free_nfa_state (*start); return 0; } switch (rexp->type) { case r_data: return 0; case r_cset: edge = rx_nfa_edge (rx, ne_cset, *start, *end); if (!edge) return 0; edge->params.cset = rx_copy_cset (rx, rexp->params.cset); if (!edge->params.cset) { rx_free_nfa_edge (edge); return 0; } return 1; case r_opt: return (rx_build_nfa (rx, rexp->params.pair.left, start, end) && rx_nfa_edge (rx, ne_epsilon, *start, *end)); case r_star: { struct rx_nfa_state * star_start = 0; struct rx_nfa_state * star_end = 0; return (rx_build_nfa (rx, rexp->params.pair.left, &star_start, &star_end) && star_start && star_end && rx_nfa_edge (rx, ne_epsilon, star_start, star_end) && rx_nfa_edge (rx, ne_epsilon, *start, star_start) && rx_nfa_edge (rx, ne_epsilon, star_end, *end) && rx_nfa_edge (rx, ne_epsilon, star_end, star_start)); } case r_2phase_star: { struct rx_nfa_state * star_start = 0; struct rx_nfa_state * star_end = 0; struct rx_nfa_state * loop_exp_start = 0; struct rx_nfa_state * loop_exp_end = 0; return (rx_build_nfa (rx, rexp->params.pair.left, &star_start, &star_end) && rx_build_nfa (rx, rexp->params.pair.right, &loop_exp_start, &loop_exp_end) && star_start && star_end && loop_exp_end && loop_exp_start && rx_nfa_edge (rx, ne_epsilon, star_start, *end) && rx_nfa_edge (rx, ne_epsilon, *start, star_start) && rx_nfa_edge (rx, ne_epsilon, star_end, *end) && rx_nfa_edge (rx, ne_epsilon, star_end, loop_exp_start) && rx_nfa_edge (rx, ne_epsilon, loop_exp_end, star_start)); } case r_concat: { struct rx_nfa_state *shared = 0; return (rx_build_nfa (rx, rexp->params.pair.left, start, &shared) && rx_build_nfa (rx, rexp->params.pair.right, &shared, end)); } case r_alternate: { struct rx_nfa_state *ls = 0; struct rx_nfa_state *le = 0; struct rx_nfa_state *rs = 0; struct rx_nfa_state *re = 0; return (rx_build_nfa (rx, rexp->params.pair.left, &ls, &le) && rx_build_nfa (rx, rexp->params.pair.right, &rs, &re) && rx_nfa_edge (rx, ne_epsilon, *start, ls) && rx_nfa_edge (rx, ne_epsilon, *start, rs) && rx_nfa_edge (rx, ne_epsilon, le, *end) && rx_nfa_edge (rx, ne_epsilon, re, *end)); } case r_side_effect: edge = rx_nfa_edge (rx, ne_side_effect, *start, *end); if (!edge) return 0; edge->params.side_effect = rexp->params.side_effect; return 1; } /* this should never happen */ return 0; } /* RX_NAME_NFA_STATES identifies all nodes with outgoing non-epsilon * transitions. Only these nodes can occur in super-states. * All nodes are given an integer id. * The id is non-negative if the node has non-epsilon out-transitions, negative * otherwise (this is because we want the non-negative ids to be used as * array indexes in a few places). */ #ifdef __STDC__ RX_DECL void rx_name_nfa_states (struct rx *rx) #else RX_DECL void rx_name_nfa_states (rx) struct rx *rx; #endif { struct rx_nfa_state *n = rx->nfa_states; rx->nodec = 0; rx->epsnodec = -1; while (n) { struct rx_nfa_edge *e = n->edges; if (n->is_start) n->eclosure_needed = 1; while (e) { switch (e->type) { case ne_epsilon: case ne_side_effect: break; case ne_cset: n->id = rx->nodec++; { struct rx_nfa_edge *from_n = n->edges; while (from_n) { from_n->dest->eclosure_needed = 1; from_n = from_n->next; } } goto cont; } e = e->next; } n->id = rx->epsnodec--; cont: n = n->next; } rx->epsnodec = -rx->epsnodec; } /* This page: data structures for the static part of the nfa->supernfa * translation. * * There are side effect lists -- lists of side effects occuring * along an uninterrupted, acyclic path of side-effect epsilon edges. * Such paths are collapsed to single edges in the course of computing * epsilon closures. Such single edges are labled with a list of all * the side effects entailed in crossing them. Like lists of side * effects are made == by the constructors below. * * There are also nfa state sets. These are used to hold a list of all * states reachable from a starting state for a given type of transition * and side effect list. These are also hash-consed. */ /* The next several functions compare, construct, etc. lists of side * effects. See ECLOSE_NFA (below) for details. */ /* Ordering of rx_se_list * (-1, 0, 1 return value convention). */ #ifdef __STDC__ static int se_list_cmp (void * va, void * vb) #else static int se_list_cmp (va, vb) void * va; void * vb; #endif { struct rx_se_list * a = (struct rx_se_list *)va; struct rx_se_list * b = (struct rx_se_list *)vb; return ((va == vb) ? 0 : (!va ? -1 : (!vb ? 1 : ((long)a->car < (long)b->car ? 1 : ((long)a->car > (long)b->car ? -1 : se_list_cmp ((void *)a->cdr, (void *)b->cdr)))))); } #ifdef __STDC__ static int se_list_equal (void * va, void * vb) #else static int se_list_equal (va, vb) void * va; void * vb; #endif { return !(se_list_cmp (va, vb)); } static struct rx_hash_rules se_list_hash_rules = { se_list_equal, compiler_hash_alloc, compiler_free_hash, compiler_hash_item_alloc, compiler_free_hash_item }; #ifdef __STDC__ static struct rx_se_list * side_effect_cons (struct rx * rx, void * se, struct rx_se_list * list) #else static struct rx_se_list * side_effect_cons (rx, se, list) struct rx * rx; void * se; struct rx_se_list * list; #endif { struct rx_se_list * l; l = ((struct rx_se_list *) malloc (sizeof (*l))); if (!l) return 0; l->car = se; l->cdr = list; return l; } #ifdef __STDC__ static struct rx_se_list * hash_cons_se_prog (struct rx * rx, struct rx_hash * memo, void * car, struct rx_se_list * cdr) #else static struct rx_se_list * hash_cons_se_prog (rx, memo, car, cdr) struct rx * rx; struct rx_hash * memo; void * car; struct rx_se_list * cdr; #endif { long hash = (long)car ^ (long)cdr; struct rx_se_list template; template.car = car; template.cdr = cdr; { struct rx_hash_item * it = rx_hash_store (memo, hash, (void *)&template, &se_list_hash_rules); if (!it) return 0; if (it->data == (void *)&template) { struct rx_se_list * consed; consed = (struct rx_se_list *) malloc (sizeof (*consed)); *consed = template; it->data = (void *)consed; } return (struct rx_se_list *)it->data; } } #ifdef __STDC__ static struct rx_se_list * hash_se_prog (struct rx * rx, struct rx_hash * memo, struct rx_se_list * prog) #else static struct rx_se_list * hash_se_prog (rx, memo, prog) struct rx * rx; struct rx_hash * memo; struct rx_se_list * prog; #endif { struct rx_se_list * answer = 0; while (prog) { answer = hash_cons_se_prog (rx, memo, prog->car, answer); if (!answer) return 0; prog = prog->cdr; } return answer; } #ifdef __STDC__ static int nfa_set_cmp (void * va, void * vb) #else static int nfa_set_cmp (va, vb) void * va; void * vb; #endif { struct rx_nfa_state_set * a = (struct rx_nfa_state_set *)va; struct rx_nfa_state_set * b = (struct rx_nfa_state_set *)vb; return ((va == vb) ? 0 : (!va ? -1 : (!vb ? 1 : (a->car->id < b->car->id ? 1 : (a->car->id > b->car->id ? -1 : nfa_set_cmp ((void *)a->cdr, (void *)b->cdr)))))); } #ifdef __STDC__ static int nfa_set_equal (void * va, void * vb) #else static int nfa_set_equal (va, vb) void * va; void * vb; #endif { return !nfa_set_cmp (va, vb); } static struct rx_hash_rules nfa_set_hash_rules = { nfa_set_equal, compiler_hash_alloc, compiler_free_hash, compiler_hash_item_alloc, compiler_free_hash_item }; #ifdef __STDC__ static struct rx_nfa_state_set * nfa_set_cons (struct rx * rx, struct rx_hash * memo, struct rx_nfa_state * state, struct rx_nfa_state_set * set) #else static struct rx_nfa_state_set * nfa_set_cons (rx, memo, state, set) struct rx * rx; struct rx_hash * memo; struct rx_nfa_state * state; struct rx_nfa_state_set * set; #endif { struct rx_nfa_state_set template; struct rx_hash_item * node; template.car = state; template.cdr = set; node = rx_hash_store (memo, (((long)state) >> 8) ^ (long)set, &template, &nfa_set_hash_rules); if (!node) return 0; if (node->data == &template) { struct rx_nfa_state_set * l; l = (struct rx_nfa_state_set *) malloc (sizeof (*l)); node->data = (void *) l; if (!l) return 0; *l = template; } return (struct rx_nfa_state_set *)node->data; } #ifdef __STDC__ static struct rx_nfa_state_set * nfa_set_enjoin (struct rx * rx, struct rx_hash * memo, struct rx_nfa_state * state, struct rx_nfa_state_set * set) #else static struct rx_nfa_state_set * nfa_set_enjoin (rx, memo, state, set) struct rx * rx; struct rx_hash * memo; struct rx_nfa_state * state; struct rx_nfa_state_set * set; #endif { if (!set || state->id < set->car->id) return nfa_set_cons (rx, memo, state, set); if (state->id == set->car->id) return set; else { struct rx_nfa_state_set * newcdr = nfa_set_enjoin (rx, memo, state, set->cdr); if (newcdr != set->cdr) set = nfa_set_cons (rx, memo, set->car, newcdr); return set; } } /* This page: computing epsilon closures. The closures aren't total. * Each node's closures are partitioned according to the side effects entailed * along the epsilon edges. Return true on success. */ struct eclose_frame { struct rx_se_list *prog_backwards; }; #ifdef __STDC__ static int eclose_node (struct rx *rx, struct rx_nfa_state *outnode, struct rx_nfa_state *node, struct eclose_frame *frame) #else static int eclose_node (rx, outnode, node, frame) struct rx *rx; struct rx_nfa_state *outnode; struct rx_nfa_state *node; struct eclose_frame *frame; #endif { struct rx_nfa_edge *e = node->edges; /* For each node, we follow all epsilon paths to build the closure. * The closure omits nodes that have only epsilon edges. * The closure is split into partial closures -- all the states in * a partial closure are reached by crossing the same list of * of side effects (though not necessarily the same path). */ if (node->mark) return 1; node->mark = 1; if (node->id >= 0 || node->is_final) { struct rx_possible_future **ec; struct rx_se_list * prog_in_order = ((struct rx_se_list *)hash_se_prog (rx, &rx->se_list_memo, frame->prog_backwards)); int cmp; ec = &outnode->futures; while (*ec) { cmp = se_list_cmp ((void *)(*ec)->effects, (void *)prog_in_order); if (cmp <= 0) break; ec = &(*ec)->next; } if (!*ec || (cmp < 0)) { struct rx_possible_future * saved = *ec; *ec = rx_possible_future (rx, prog_in_order); (*ec)->next = saved; if (!*ec) return 0; } if (node->id >= 0) { (*ec)->destset = nfa_set_enjoin (rx, &rx->set_list_memo, node, (*ec)->destset); if (!(*ec)->destset) return 0; } } while (e) { switch (e->type) { case ne_epsilon: if (!eclose_node (rx, outnode, e->dest, frame)) return 0; break; case ne_side_effect: { frame->prog_backwards = side_effect_cons (rx, e->params.side_effect, frame->prog_backwards); if (!frame->prog_backwards) return 0; if (!eclose_node (rx, outnode, e->dest, frame)) return 0; { struct rx_se_list * dying = frame->prog_backwards; frame->prog_backwards = frame->prog_backwards->cdr; free ((char *)dying); } break; } default: break; } e = e->next; } node->mark = 0; return 1; } #ifdef __STDC__ RX_DECL int rx_eclose_nfa (struct rx *rx) #else RX_DECL int rx_eclose_nfa (rx) struct rx *rx; #endif { struct rx_nfa_state *n = rx->nfa_states; struct eclose_frame frame; static int rx_id = 0; frame.prog_backwards = 0; rx->rx_id = rx_id++; bzero (&rx->se_list_memo, sizeof (rx->se_list_memo)); bzero (&rx->set_list_memo, sizeof (rx->set_list_memo)); while (n) { n->futures = 0; if (n->eclosure_needed && !eclose_node (rx, n, n, &frame)) return 0; /* clear_marks (rx); */ n = n->next; } return 1; } /* This deletes epsilon edges from an NFA. After running eclose_node, * we have no more need for these edges. They are removed to simplify * further operations on the NFA. */ #ifdef __STDC__ RX_DECL void rx_delete_epsilon_transitions (struct rx *rx) #else RX_DECL void rx_delete_epsilon_transitions (rx) struct rx *rx; #endif { struct rx_nfa_state *n = rx->nfa_states; struct rx_nfa_edge **e; while (n) { e = &n->edges; while (*e) { struct rx_nfa_edge *t; switch ((*e)->type) { case ne_epsilon: case ne_side_effect: t = *e; *e = t->next; rx_free_nfa_edge (t); break; default: e = &(*e)->next; break; } } n = n->next; } } /* This page: storing the nfa in a contiguous region of memory for * subsequent conversion to a super-nfa. */ /* This is for qsort on an array of nfa_states. The order * is based on state ids and goes * [0...MAX][MIN..-1] where (MAX>=0) and (MIN<0) * This way, positive ids double as array indices. */ #ifdef __STDC__ static int nfacmp (void * va, void * vb) #else static int nfacmp (va, vb) void * va; void * vb; #endif { struct rx_nfa_state **a = (struct rx_nfa_state **)va; struct rx_nfa_state **b = (struct rx_nfa_state **)vb; return (*a == *b /* &&&& 3.18 */ ? 0 : (((*a)->id < 0) == ((*b)->id < 0) ? (((*a)->id < (*b)->id) ? -1 : 1) : (((*a)->id < 0) ? 1 : -1))); } #ifdef __STDC__ static int count_hash_nodes (struct rx_hash * st) #else static int count_hash_nodes (st) struct rx_hash * st; #endif { int x; int count = 0; for (x = 0; x < 13; ++x) count += ((st->children[x]) ? count_hash_nodes (st->children[x]) : st->bucket_size[x]); return count; } #ifdef __STDC__ static void se_memo_freer (struct rx_hash_item * node) #else static void se_memo_freer (node) struct rx_hash_item * node; #endif { free ((char *)node->data); } #ifdef __STDC__ static void nfa_set_freer (struct rx_hash_item * node) #else static void nfa_set_freer (node) struct rx_hash_item * node; #endif { free ((char *)node->data); } /* This copies an entire NFA into a single malloced block of memory. * Mostly this is for compatability with regex.c, though it is convenient * to have the nfa nodes in an array. */ #ifdef __STDC__ RX_DECL int rx_compactify_nfa (struct rx *rx, void **mem, unsigned long *size) #else RX_DECL int rx_compactify_nfa (rx, mem, size) struct rx *rx; void **mem; unsigned long *size; #endif { int total_nodec; struct rx_nfa_state *n; int edgec = 0; int eclosec = 0; int se_list_consc = count_hash_nodes (&rx->se_list_memo); int nfa_setc = count_hash_nodes (&rx->set_list_memo); unsigned long total_size; /* This takes place in two stages. First, the total size of the * nfa is computed, then structures are copied. */ n = rx->nfa_states; total_nodec = 0; while (n) { struct rx_nfa_edge *e = n->edges; struct rx_possible_future *ec = n->futures; ++total_nodec; while (e) { ++edgec; e = e->next; } while (ec) { ++eclosec; ec = ec->next; } n = n->next; } total_size = (total_nodec * sizeof (struct rx_nfa_state) + edgec * rx_sizeof_bitset (rx->local_cset_size) + edgec * sizeof (struct rx_nfa_edge) + nfa_setc * sizeof (struct rx_nfa_state_set) + eclosec * sizeof (struct rx_possible_future) + se_list_consc * sizeof (struct rx_se_list) + rx->reserved); if (total_size > *size) { *mem = remalloc (*mem, total_size); if (*mem) *size = total_size; else return 0; } /* Now we've allocated the memory; this copies the NFA. */ { static struct rx_nfa_state **scratch = 0; static int scratch_alloc = 0; struct rx_nfa_state *state_base = (struct rx_nfa_state *) * mem; struct rx_nfa_state *new_state = state_base; struct rx_nfa_edge *new_edge = (struct rx_nfa_edge *) ((char *) state_base + total_nodec * sizeof (struct rx_nfa_state)); struct rx_se_list * new_se_list = (struct rx_se_list *) ((char *)new_edge + edgec * sizeof (struct rx_nfa_edge)); struct rx_possible_future *new_close = ((struct rx_possible_future *) ((char *) new_se_list + se_list_consc * sizeof (struct rx_se_list))); struct rx_nfa_state_set * new_nfa_set = ((struct rx_nfa_state_set *) ((char *)new_close + eclosec * sizeof (struct rx_possible_future))); char *new_bitset = ((char *) new_nfa_set + nfa_setc * sizeof (struct rx_nfa_state_set)); int x; struct rx_nfa_state *n; if (scratch_alloc < total_nodec) { scratch = ((struct rx_nfa_state **) remalloc (scratch, total_nodec * sizeof (*scratch))); if (scratch) scratch_alloc = total_nodec; else { scratch_alloc = 0; return 0; } } for (x = 0, n = rx->nfa_states; n; n = n->next) scratch[x++] = n; qsort (scratch, total_nodec, sizeof (struct rx_nfa_state *), (int (*)())nfacmp); for (x = 0; x < total_nodec; ++x) { struct rx_possible_future *eclose = scratch[x]->futures; struct rx_nfa_edge *edge = scratch[x]->edges; struct rx_nfa_state *cn = new_state++; cn->futures = 0; cn->edges = 0; cn->next = (x == total_nodec - 1) ? 0 : (cn + 1); cn->id = scratch[x]->id; cn->is_final = scratch[x]->is_final; cn->is_start = scratch[x]->is_start; cn->mark = 0; while (edge) { int indx = (edge->dest->id < 0 ? (total_nodec + edge->dest->id) : edge->dest->id); struct rx_nfa_edge *e = new_edge++; rx_Bitset cset = (rx_Bitset) new_bitset; new_bitset += rx_sizeof_bitset (rx->local_cset_size); rx_bitset_null (rx->local_cset_size, cset); rx_bitset_union (rx->local_cset_size, cset, edge->params.cset); e->next = cn->edges; cn->edges = e; e->type = edge->type; e->dest = state_base + indx; e->params.cset = cset; edge = edge->next; } while (eclose) { struct rx_possible_future *ec = new_close++; struct rx_hash_item * sp; struct rx_se_list ** sepos; struct rx_se_list * sesrc; struct rx_nfa_state_set * destlst; struct rx_nfa_state_set ** destpos; ec->next = cn->futures; cn->futures = ec; for (sepos = &ec->effects, sesrc = eclose->effects; sesrc; sesrc = sesrc->cdr, sepos = &(*sepos)->cdr) { sp = rx_hash_find (&rx->se_list_memo, (long)sesrc->car ^ (long)sesrc->cdr, sesrc, &se_list_hash_rules); if (sp->binding) { sesrc = (struct rx_se_list *)sp->binding; break; } *new_se_list = *sesrc; sp->binding = (void *)new_se_list; *sepos = new_se_list; ++new_se_list; } *sepos = sesrc; for (destpos = &ec->destset, destlst = eclose->destset; destlst; destpos = &(*destpos)->cdr, destlst = destlst->cdr) { sp = rx_hash_find (&rx->set_list_memo, ((((long)destlst->car) >> 8) ^ (long)destlst->cdr), destlst, &nfa_set_hash_rules); if (sp->binding) { destlst = (struct rx_nfa_state_set *)sp->binding; break; } *new_nfa_set = *destlst; new_nfa_set->car = state_base + destlst->car->id; sp->binding = (void *)new_nfa_set; *destpos = new_nfa_set; ++new_nfa_set; } *destpos = destlst; eclose = eclose->next; } } } rx_free_hash_table (&rx->se_list_memo, se_memo_freer, &se_list_hash_rules); bzero (&rx->se_list_memo, sizeof (rx->se_list_memo)); rx_free_hash_table (&rx->set_list_memo, nfa_set_freer, &nfa_set_hash_rules); bzero (&rx->set_list_memo, sizeof (rx->set_list_memo)); rx_free_nfa (rx); rx->nfa_states = (struct rx_nfa_state *)*mem; return 1; } /* The functions in the next several pages define the lazy-NFA-conversion used * by matchers. The input to this construction is an NFA such as * is built by compactify_nfa (rx.c). The output is the superNFA. */ /* Match engines can use arbitrary values for opcodes. So, the parse tree * is built using instructions names (enum rx_opcode), but the superstate * nfa is populated with mystery opcodes (void *). * * For convenience, here is an id table. The opcodes are == to their inxs * * The lables in re_search_2 would make good values for instructions. */ void * rx_id_instruction_table[rx_num_instructions] = { (void *) rx_backtrack_point, (void *) rx_do_side_effects, (void *) rx_cache_miss, (void *) rx_next_char, (void *) rx_backtrack, (void *) rx_error_inx }; /* Memory mgt. for superstate graphs. */ #ifdef __STDC__ static char * rx_cache_malloc (struct rx_cache * cache, int bytes) #else static char * rx_cache_malloc (cache, bytes) struct rx_cache * cache; int bytes; #endif { while (cache->bytes_left < bytes) { if (cache->memory_pos) cache->memory_pos = cache->memory_pos->next; if (!cache->memory_pos) { cache->morecore (cache); if (!cache->memory_pos) return 0; } cache->bytes_left = cache->memory_pos->bytes; cache->memory_addr = ((char *)cache->memory_pos + sizeof (struct rx_blocklist)); } cache->bytes_left -= bytes; { char * addr = cache->memory_addr; cache->memory_addr += bytes; return addr; } } #ifdef __STDC__ static void rx_cache_free (struct rx_cache * cache, struct rx_freelist ** freelist, char * mem) #else static void rx_cache_free (cache, freelist, mem) struct rx_cache * cache; struct rx_freelist ** freelist; char * mem; #endif { struct rx_freelist * it = (struct rx_freelist *)mem; it->next = *freelist; *freelist = it; } /* The partially instantiated superstate graph has a transition * table at every node. There is one entry for every character. * This fills in the transition for a set. */ #ifdef __STDC__ static void install_transition (struct rx_superstate *super, struct rx_inx *answer, rx_Bitset trcset) #else static void install_transition (super, answer, trcset) struct rx_superstate *super; struct rx_inx *answer; rx_Bitset trcset; #endif { struct rx_inx * transitions = super->transitions; int chr; for (chr = 0; chr < 256; ) if (!*trcset) { ++trcset; chr += 32; } else { RX_subset sub = *trcset; RX_subset mask = 1; int bound = chr + 32; while (chr < bound) { if (sub & mask) transitions [chr] = *answer; ++chr; mask <<= 1; } ++trcset; } } #ifdef __STDC__ static int qlen (struct rx_superstate * q) #else static int qlen (q) struct rx_superstate * q; #endif { int count = 1; struct rx_superstate * it; if (!q) return 0; for (it = q->next_recyclable; it != q; it = it->next_recyclable) ++count; return count; } #ifdef __STDC__ static void check_cache (struct rx_cache * cache) #else static void check_cache (cache) struct rx_cache * cache; #endif { struct rx_cache * you_fucked_up = 0; int total = cache->superstates; int semi = cache->semifree_superstates; if (semi != qlen (cache->semifree_superstate)) check_cache (you_fucked_up); if ((total - semi) != qlen (cache->lru_superstate)) check_cache (you_fucked_up); } /* When a superstate is old and neglected, it can enter a * semi-free state. A semi-free state is slated to die. * Incoming transitions to a semi-free state are re-written * to cause an (interpreted) fault when they are taken. * The fault handler revives the semi-free state, patches * incoming transitions back to normal, and continues. * * The idea is basicly to free in two stages, aborting * between the two if the state turns out to be useful again. * When a free is aborted, the rescued superstate is placed * in the most-favored slot to maximize the time until it * is next semi-freed. */ #ifdef __STDC__ static void semifree_superstate (struct rx_cache * cache) #else static void semifree_superstate (cache) struct rx_cache * cache; #endif { int disqualified = cache->semifree_superstates; if (disqualified == cache->superstates) return; while (cache->lru_superstate->locks) { cache->lru_superstate = cache->lru_superstate->next_recyclable; ++disqualified; if (disqualified == cache->superstates) return; } { struct rx_superstate * it = cache->lru_superstate; it->next_recyclable->prev_recyclable = it->prev_recyclable; it->prev_recyclable->next_recyclable = it->next_recyclable; cache->lru_superstate = (it == it->next_recyclable ? 0 : it->next_recyclable); if (!cache->semifree_superstate) { cache->semifree_superstate = it; it->next_recyclable = it; it->prev_recyclable = it; } else { it->prev_recyclable = cache->semifree_superstate->prev_recyclable; it->next_recyclable = cache->semifree_superstate; it->prev_recyclable->next_recyclable = it; it->next_recyclable->prev_recyclable = it; } { struct rx_distinct_future *df; it->is_semifree = 1; ++cache->semifree_superstates; df = it->transition_refs; if (df) { df->prev_same_dest->next_same_dest = 0; for (df = it->transition_refs; df; df = df->next_same_dest) { df->future_frame.inx = cache->instruction_table[rx_cache_miss]; df->future_frame.data = 0; df->future_frame.data_2 = (void *) df; /* If there are any NEXT-CHAR instruction frames that * refer to this state, we convert them to CACHE-MISS frames. */ if (!df->effects && (df->edge->options->next_same_super_edge[0] == df->edge->options)) install_transition (df->present, &df->future_frame, df->edge->cset); } df = it->transition_refs; df->prev_same_dest->next_same_dest = df; } } } } #ifdef __STDC__ static void refresh_semifree_superstate (struct rx_cache * cache, struct rx_superstate * super) #else static void refresh_semifree_superstate (cache, super) struct rx_cache * cache; struct rx_superstate * super; #endif { struct rx_distinct_future *df; if (super->transition_refs) { super->transition_refs->prev_same_dest->next_same_dest = 0; for (df = super->transition_refs; df; df = df->next_same_dest) { df->future_frame.inx = cache->instruction_table[rx_next_char]; df->future_frame.data = (void *) super->transitions; /* CACHE-MISS instruction frames that refer to this state, * must be converted to NEXT-CHAR frames. */ if (!df->effects && (df->edge->options->next_same_super_edge[0] == df->edge->options)) install_transition (df->present, &df->future_frame, df->edge->cset); } super->transition_refs->prev_same_dest->next_same_dest = super->transition_refs; } if (cache->semifree_superstate == super) cache->semifree_superstate = (super->prev_recyclable == super ? 0 : super->prev_recyclable); super->next_recyclable->prev_recyclable = super->prev_recyclable; super->prev_recyclable->next_recyclable = super->next_recyclable; if (!cache->lru_superstate) (cache->lru_superstate = super->next_recyclable = super->prev_recyclable = super); else { super->next_recyclable = cache->lru_superstate; super->prev_recyclable = cache->lru_superstate->prev_recyclable; super->next_recyclable->prev_recyclable = super; super->prev_recyclable->next_recyclable = super; } super->is_semifree = 0; --cache->semifree_superstates; } #ifdef __STDC__ static void rx_refresh_this_superstate (struct rx_cache * cache, struct rx_superstate * superstate) #else static void rx_refresh_this_superstate (cache, superstate) struct rx_cache * cache; struct rx_superstate * superstate; #endif { if (superstate->is_semifree) refresh_semifree_superstate (cache, superstate); else if (cache->lru_superstate == superstate) cache->lru_superstate = superstate->next_recyclable; else if (superstate != cache->lru_superstate->prev_recyclable) { superstate->next_recyclable->prev_recyclable = superstate->prev_recyclable; superstate->prev_recyclable->next_recyclable = superstate->next_recyclable; superstate->next_recyclable = cache->lru_superstate; superstate->prev_recyclable = cache->lru_superstate->prev_recyclable; superstate->next_recyclable->prev_recyclable = superstate; superstate->prev_recyclable->next_recyclable = superstate; } } #ifdef __STDC__ static void release_superset_low (struct rx_cache * cache, struct rx_superset *set) #else static void release_superset_low (cache, set) struct rx_cache * cache; struct rx_superset *set; #endif { if (!--set->refs) { if (set->cdr) release_superset_low (cache, set->cdr); set->starts_for = 0; rx_hash_free (rx_hash_find (&cache->superset_table, (unsigned long)set->car ^ set->id ^ (unsigned long)set->cdr, (void *)set, &cache->superset_hash_rules), &cache->superset_hash_rules); rx_cache_free (cache, &cache->free_supersets, (char *)set); } } #ifdef __STDC__ RX_DECL void rx_release_superset (struct rx *rx, struct rx_superset *set) #else RX_DECL void rx_release_superset (rx, set) struct rx *rx; struct rx_superset *set; #endif { release_superset_low (rx->cache, set); } /* This tries to add a new superstate to the superstate freelist. * It might, as a result, free some edge pieces or hash tables. * If nothing can be freed because too many locks are being held, fail. */ #ifdef __STDC__ static int rx_really_free_superstate (struct rx_cache * cache) #else static int rx_really_free_superstate (cache) struct rx_cache * cache; #endif { int locked_superstates = 0; struct rx_superstate * it; if (!cache->superstates) return 0; { /* This is a total guess. The idea is that we should expect as * many misses as we've recently experienced. I.e., cache->misses * should be the same as cache->semifree_superstates. */ while ((cache->hits + cache->misses) > cache->superstates_allowed) { cache->hits >>= 1; cache->misses >>= 1; } if ( ((cache->hits + cache->misses) * cache->semifree_superstates) < (cache->superstates * cache->misses)) { semifree_superstate (cache); semifree_superstate (cache); } } while (cache->semifree_superstate && cache->semifree_superstate->locks) { refresh_semifree_superstate (cache, cache->semifree_superstate); ++locked_superstates; if (locked_superstates == cache->superstates) return 0; } if (cache->semifree_superstate) { it = cache->semifree_superstate; it->next_recyclable->prev_recyclable = it->prev_recyclable; it->prev_recyclable->next_recyclable = it->next_recyclable; cache->semifree_superstate = ((it == it->next_recyclable) ? 0 : it->next_recyclable); --cache->semifree_superstates; } else { while (cache->lru_superstate->locks) { cache->lru_superstate = cache->lru_superstate->next_recyclable; ++locked_superstates; if (locked_superstates == cache->superstates) return 0; } it = cache->lru_superstate; it->next_recyclable->prev_recyclable = it->prev_recyclable; it->prev_recyclable->next_recyclable = it->next_recyclable; cache->lru_superstate = ((it == it->next_recyclable) ? 0 : it->next_recyclable); } if (it->transition_refs) { struct rx_distinct_future *df; for (df = it->transition_refs, df->prev_same_dest->next_same_dest = 0; df; df = df->next_same_dest) { df->future_frame.inx = cache->instruction_table[rx_cache_miss]; df->future_frame.data = 0; df->future_frame.data_2 = (void *) df; df->future = 0; } it->transition_refs->prev_same_dest->next_same_dest = it->transition_refs; } { struct rx_super_edge *tc = it->edges; while (tc) { struct rx_distinct_future * df; struct rx_super_edge *tct = tc->next; df = tc->options; df->next_same_super_edge[1]->next_same_super_edge[0] = 0; while (df) { struct rx_distinct_future *dft = df; df = df->next_same_super_edge[0]; if (dft->future && dft->future->transition_refs == dft) { dft->future->transition_refs = dft->next_same_dest; if (dft->future->transition_refs == dft) dft->future->transition_refs = 0; } dft->next_same_dest->prev_same_dest = dft->prev_same_dest; dft->prev_same_dest->next_same_dest = dft->next_same_dest; rx_cache_free (cache, &cache->free_discernable_futures, (char *)dft); } rx_cache_free (cache, &cache->free_transition_classes, (char *)tc); tc = tct; } } if (it->contents->superstate == it) it->contents->superstate = 0; release_superset_low (cache, it->contents); rx_cache_free (cache, &cache->free_superstates, (char *)it); --cache->superstates; return 1; } #ifdef __STDC__ static char * rx_cache_get (struct rx_cache * cache, struct rx_freelist ** freelist) #else static char * rx_cache_get (cache, freelist) struct rx_cache * cache; struct rx_freelist ** freelist; #endif { while (!*freelist && rx_really_free_superstate (cache)) ; if (!*freelist) return 0; { struct rx_freelist * it = *freelist; *freelist = it->next; return (char *)it; } } #ifdef __STDC__ static char * rx_cache_malloc_or_get (struct rx_cache * cache, struct rx_freelist ** freelist, int bytes) #else static char * rx_cache_malloc_or_get (cache, freelist, bytes) struct rx_cache * cache; struct rx_freelist ** freelist; int bytes; #endif { if (!*freelist) { char * answer = rx_cache_malloc (cache, bytes); if (answer) return answer; } return rx_cache_get (cache, freelist); } #ifdef __STDC__ static char * rx_cache_get_superstate (struct rx_cache * cache) #else static char * rx_cache_get_superstate (cache) struct rx_cache * cache; #endif { char * answer; int bytes = ( sizeof (struct rx_superstate) + cache->local_cset_size * sizeof (struct rx_inx)); if (!cache->free_superstates && (cache->superstates < cache->superstates_allowed)) { answer = rx_cache_malloc (cache, bytes); if (answer) { ++cache->superstates; return answer; } } answer = rx_cache_get (cache, &cache->free_superstates); if (!answer) { answer = rx_cache_malloc (cache, bytes); if (answer) ++cache->superstates_allowed; } ++cache->superstates; return answer; } #ifdef __STDC__ static int supersetcmp (void * va, void * vb) #else static int supersetcmp (va, vb) void * va; void * vb; #endif { struct rx_superset * a = (struct rx_superset *)va; struct rx_superset * b = (struct rx_superset *)vb; return ( (a == b) || (a && b && (a->car == b->car) && (a->cdr == b->cdr))); } #ifdef __STDC__ static struct rx_hash_item * superset_allocator (struct rx_hash_rules * rules, void * val) #else static struct rx_hash_item * superset_allocator (rules, val) struct rx_hash_rules * rules; void * val; #endif { struct rx_cache * cache = ((struct rx_cache *) ((char *)rules - (unsigned long)(&((struct rx_cache *)0)->superset_hash_rules))); struct rx_superset * template = (struct rx_superset *)val; struct rx_superset * newset = ((struct rx_superset *) rx_cache_malloc_or_get (cache, &cache->free_supersets, sizeof (*template))); if (!newset) return 0; newset->refs = 0; newset->car = template->car; newset->id = template->car->id; newset->cdr = template->cdr; newset->superstate = 0; rx_protect_superset (rx, template->cdr); newset->hash_item.data = (void *)newset; newset->hash_item.binding = 0; return &newset->hash_item; } #ifdef __STDC__ static struct rx_hash * super_hash_allocator (struct rx_hash_rules * rules) #else static struct rx_hash * super_hash_allocator (rules) struct rx_hash_rules * rules; #endif { struct rx_cache * cache = ((struct rx_cache *) ((char *)rules - (unsigned long)(&((struct rx_cache *)0)->superset_hash_rules))); return ((struct rx_hash *) rx_cache_malloc_or_get (cache, &cache->free_hash, sizeof (struct rx_hash))); } #ifdef __STDC__ static void super_hash_liberator (struct rx_hash * hash, struct rx_hash_rules * rules) #else static void super_hash_liberator (hash, rules) struct rx_hash * hash; struct rx_hash_rules * rules; #endif { struct rx_cache * cache = ((struct rx_cache *) (char *)rules - (long)(&((struct rx_cache *)0)->superset_hash_rules)); rx_cache_free (cache, &cache->free_hash, (char *)hash); } #ifdef __STDC__ static void superset_hash_item_liberator (struct rx_hash_item * it, struct rx_hash_rules * rules) #else static void superset_hash_item_liberator (it, rules) /* Well, it does ya know. */ struct rx_hash_item * it; struct rx_hash_rules * rules; #endif { } int rx_cache_bound = 128; static int rx_default_cache_got = 0; #ifdef __STDC__ static int bytes_for_cache_size (int supers, int cset_size) #else static int bytes_for_cache_size (supers, cset_size) int supers; int cset_size; #endif { /* What the hell is this? !!!*/ return (int) ((float)supers * ( (1.03 * (float) ( rx_sizeof_bitset (cset_size) + sizeof (struct rx_super_edge))) + (1.80 * (float) sizeof (struct rx_possible_future)) + (float) ( sizeof (struct rx_superstate) + cset_size * sizeof (struct rx_inx)))); } #ifdef __STDC__ static void rx_morecore (struct rx_cache * cache) #else static void rx_morecore (cache) struct rx_cache * cache; #endif { if (rx_default_cache_got >= rx_cache_bound) return; rx_default_cache_got += 16; cache->superstates_allowed = rx_cache_bound; { struct rx_blocklist ** pos = &cache->memory; int size = bytes_for_cache_size (16, cache->local_cset_size); while (*pos) pos = &(*pos)->next; *pos = ((struct rx_blocklist *) malloc (size + sizeof (struct rx_blocklist))); if (!*pos) return; (*pos)->next = 0; (*pos)->bytes = size; cache->memory_pos = *pos; cache->memory_addr = (char *)*pos + sizeof (**pos); cache->bytes_left = size; } } static struct rx_cache default_cache = { { supersetcmp, super_hash_allocator, super_hash_liberator, superset_allocator, superset_hash_item_liberator, }, 0, 0, 0, 0, rx_morecore, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 128, 256, rx_id_instruction_table, { 0, 0, {0}, {0}, {0} } }; /* This adds an element to a superstate set. These sets are lists, such * that lists with == elements are ==. The empty set is returned by * superset_cons (rx, 0, 0) and is NOT equivelent to * (struct rx_superset)0. */ #ifdef __STDC__ RX_DECL struct rx_superset * rx_superset_cons (struct rx * rx, struct rx_nfa_state *car, struct rx_superset *cdr) #else RX_DECL struct rx_superset * rx_superset_cons (rx, car, cdr) struct rx * rx; struct rx_nfa_state *car; struct rx_superset *cdr; #endif { struct rx_cache * cache = rx->cache; if (!car && !cdr) { if (!cache->empty_superset) { cache->empty_superset = ((struct rx_superset *) rx_cache_malloc_or_get (cache, &cache->free_supersets, sizeof (struct rx_superset))); if (!cache->empty_superset) return 0; bzero (cache->empty_superset, sizeof (struct rx_superset)); cache->empty_superset->refs = 1000; } return cache->empty_superset; } { struct rx_superset template; struct rx_hash_item * hit; template.car = car; template.cdr = cdr; template.id = car->id; hit = rx_hash_store (&cache->superset_table, (unsigned long)car ^ car->id ^ (unsigned long)cdr, (void *)&template, &cache->superset_hash_rules); return (hit ? (struct rx_superset *)hit->data : 0); } } /* This computes a union of two NFA state sets. The sets do not have the * same representation though. One is a RX_SUPERSET structure (part * of the superstate NFA) and the other is an NFA_STATE_SET (part of the NFA). */ #ifdef __STDC__ RX_DECL struct rx_superset * rx_superstate_eclosure_union (struct rx * rx, struct rx_superset *set, struct rx_nfa_state_set *ecl) #else RX_DECL struct rx_superset * rx_superstate_eclosure_union (rx, set, ecl) struct rx * rx; struct rx_superset *set; struct rx_nfa_state_set *ecl; #endif { if (!ecl) return set; if (!set->car) return rx_superset_cons (rx, ecl->car, rx_superstate_eclosure_union (rx, set, ecl->cdr)); if (set->car == ecl->car) return rx_superstate_eclosure_union (rx, set, ecl->cdr); { struct rx_superset * tail; struct rx_nfa_state * first; if (set->car > ecl->car) { tail = rx_superstate_eclosure_union (rx, set->cdr, ecl); first = set->car; } else { tail = rx_superstate_eclosure_union (rx, set, ecl->cdr); first = ecl->car; } if (!tail) return 0; else { struct rx_superset * answer; answer = rx_superset_cons (rx, first, tail); if (!answer) { rx_protect_superset (rx, tail); rx_release_superset (rx, tail); return 0; } else return answer; } } } /* * This makes sure that a list of rx_distinct_futures contains * a future for each possible set of side effects in the eclosure * of a given state. This is some of the work of filling in a * superstate transition. */ #ifdef __STDC__ static struct rx_distinct_future * include_futures (struct rx *rx, struct rx_distinct_future *df, struct rx_nfa_state *state, struct rx_superstate *superstate) #else static struct rx_distinct_future * include_futures (rx, df, state, superstate) struct rx *rx; struct rx_distinct_future *df; struct rx_nfa_state *state; struct rx_superstate *superstate; #endif { struct rx_possible_future *future; struct rx_cache * cache = rx->cache; for (future = state->futures; future; future = future->next) { struct rx_distinct_future *dfp; struct rx_distinct_future *insert_before = 0; if (df) df->next_same_super_edge[1]->next_same_super_edge[0] = 0; for (dfp = df; dfp; dfp = dfp->next_same_super_edge[0]) if (dfp->effects == future->effects) break; else { int order = rx->se_list_cmp (rx, dfp->effects, future->effects); if (order > 0) { insert_before = dfp; dfp = 0; break; } } if (df) df->next_same_super_edge[1]->next_same_super_edge[0] = df; if (!dfp) { dfp = ((struct rx_distinct_future *) rx_cache_malloc_or_get (cache, &cache->free_discernable_futures, sizeof (struct rx_distinct_future))); if (!dfp) return 0; if (!df) { df = insert_before = dfp; df->next_same_super_edge[0] = df->next_same_super_edge[1] = df; } else if (!insert_before) insert_before = df; else if (insert_before == df) df = dfp; dfp->next_same_super_edge[0] = insert_before; dfp->next_same_super_edge[1] = insert_before->next_same_super_edge[1]; dfp->next_same_super_edge[1]->next_same_super_edge[0] = dfp; dfp->next_same_super_edge[0]->next_same_super_edge[1] = dfp; dfp->next_same_dest = dfp->prev_same_dest = dfp; dfp->future = 0; dfp->present = superstate; dfp->future_frame.inx = rx->instruction_table[rx_cache_miss]; dfp->future_frame.data = 0; dfp->future_frame.data_2 = (void *) dfp; dfp->side_effects_frame.inx = rx->instruction_table[rx_do_side_effects]; dfp->side_effects_frame.data = 0; dfp->side_effects_frame.data_2 = (void *) dfp; dfp->effects = future->effects; } } return df; } /* This constructs a new superstate from its state set. The only * complexity here is memory management. */ #ifdef __STDC__ RX_DECL struct rx_superstate * rx_superstate (struct rx *rx, struct rx_superset *set) #else RX_DECL struct rx_superstate * rx_superstate (rx, set) struct rx *rx; struct rx_superset *set; #endif { struct rx_cache * cache = rx->cache; struct rx_superstate * superstate = 0; /* Does the superstate already exist in the cache? */ if (set->superstate) { if (set->superstate->rx_id != rx->rx_id) { /* Aha. It is in the cache, but belongs to a superstate * that refers to an NFA that no longer exists. * (We know it no longer exists because it was evidently * stored in the same region of memory as the current nfa * yet it has a different id.) */ superstate = set->superstate; if (!superstate->is_semifree) { if (cache->lru_superstate == superstate) { cache->lru_superstate = superstate->next_recyclable; if (cache->lru_superstate == superstate) cache->lru_superstate = 0; } { superstate->next_recyclable->prev_recyclable = superstate->prev_recyclable; superstate->prev_recyclable->next_recyclable = superstate->next_recyclable; if (!cache->semifree_superstate) { (cache->semifree_superstate = superstate->next_recyclable = superstate->prev_recyclable = superstate); } else { superstate->next_recyclable = cache->semifree_superstate; superstate->prev_recyclable = cache->semifree_superstate->prev_recyclable; superstate->next_recyclable->prev_recyclable = superstate; superstate->prev_recyclable->next_recyclable = superstate; cache->semifree_superstate = superstate; } ++cache->semifree_superstates; } } set->superstate = 0; goto handle_cache_miss; } ++cache->hits; superstate = set->superstate; rx_refresh_this_superstate (cache, superstate); return superstate; } handle_cache_miss: /* This point reached only for cache misses. */ ++cache->misses; #if RX_DEBUG if (rx_debug_trace > 1) { struct rx_superset * setp = set; fprintf (stderr, "Building a superstet %d(%d): ", rx->rx_id, set); while (setp) { fprintf (stderr, "%d ", setp->id); setp = setp->cdr; } fprintf (stderr, "(%d)\n", set); } #endif superstate = (struct rx_superstate *)rx_cache_get_superstate (cache); if (!superstate) return 0; if (!cache->lru_superstate) (cache->lru_superstate = superstate->next_recyclable = superstate->prev_recyclable = superstate); else { superstate->next_recyclable = cache->lru_superstate; superstate->prev_recyclable = cache->lru_superstate->prev_recyclable; ( superstate->prev_recyclable->next_recyclable = superstate->next_recyclable->prev_recyclable = superstate); } superstate->rx_id = rx->rx_id; superstate->transition_refs = 0; superstate->locks = 0; superstate->is_semifree = 0; set->superstate = superstate; superstate->contents = set; rx_protect_superset (rx, set); superstate->edges = 0; { int x; /* None of the transitions from this superstate are known yet. */ for (x = 0; x < rx->local_cset_size; ++x) /* &&&&& 3.8 % */ { struct rx_inx * ifr = &superstate->transitions[x]; ifr->inx = rx->instruction_table [rx_cache_miss]; ifr->data = ifr->data_2 = 0; } } return superstate; } /* This computes the destination set of one edge of the superstate NFA. * Note that a RX_DISTINCT_FUTURE is a superstate edge. * Returns 0 on an allocation failure. */ #ifdef __STDC__ static int solve_destination (struct rx *rx, struct rx_distinct_future *df) #else static int solve_destination (rx, df) struct rx *rx; struct rx_distinct_future *df; #endif { struct rx_super_edge *tc = df->edge; struct rx_superset *nfa_state; struct rx_superset *nil_set = rx_superset_cons (rx, 0, 0); struct rx_superset *solution = nil_set; struct rx_superstate *dest; rx_protect_superset (rx, solution); /* Iterate over all NFA states in the state set of this superstate. */ for (nfa_state = df->present->contents; nfa_state->car; nfa_state = nfa_state->cdr) { struct rx_nfa_edge *e; /* Iterate over all edges of each NFA state. */ for (e = nfa_state->car->edges; e; e = e->next) /* If we find an edge that is labeled with * the characters we are solving for..... */ if (rx_bitset_is_subset (rx->local_cset_size, tc->cset, e->params.cset)) { struct rx_nfa_state *n = e->dest; struct rx_possible_future *pf; /* ....search the partial epsilon closures of the destination * of that edge for a path that involves the same set of * side effects we are solving for. * If we find such a RX_POSSIBLE_FUTURE, we add members to the * stateset we are computing. */ for (pf = n->futures; pf; pf = pf->next) if (pf->effects == df->effects) { struct rx_superset * old_sol; old_sol = solution; solution = rx_superstate_eclosure_union (rx, solution, pf->destset); if (!solution) return 0; rx_protect_superset (rx, solution); rx_release_superset (rx, old_sol); } } } /* It is possible that the RX_DISTINCT_FUTURE we are working on has * the empty set of NFA states as its definition. In that case, this * is a failure point. */ if (solution == nil_set) { df->future_frame.inx = (void *) rx_backtrack; df->future_frame.data = 0; df->future_frame.data_2 = 0; return 1; } dest = rx_superstate (rx, solution); rx_release_superset (rx, solution); if (!dest) return 0; { struct rx_distinct_future *dft; dft = df; df->prev_same_dest->next_same_dest = 0; while (dft) { dft->future = dest; dft->future_frame.inx = rx->instruction_table[rx_next_char]; dft->future_frame.data = (void *) dest->transitions; dft = dft->next_same_dest; } df->prev_same_dest->next_same_dest = df; } if (!dest->transition_refs) dest->transition_refs = df; else { struct rx_distinct_future *dft = dest->transition_refs->next_same_dest; dest->transition_refs->next_same_dest = df->next_same_dest; df->next_same_dest->prev_same_dest = dest->transition_refs; df->next_same_dest = dft; dft->prev_same_dest = df; } return 1; } /* This takes a superstate and a character, and computes some edges * from the superstate NFA. In particular, this computes all edges * that lead from SUPERSTATE given CHR. This function also * computes the set of characters that share this edge set. * This returns 0 on allocation error. * The character set and list of edges are returned through * the paramters CSETOUT and DFOUT. } */ #ifdef __STDC__ static int compute_super_edge (struct rx *rx, struct rx_distinct_future **dfout, rx_Bitset csetout, struct rx_superstate *superstate, unsigned char chr) #else static int compute_super_edge (rx, dfout, csetout, superstate, chr) struct rx *rx; struct rx_distinct_future **dfout; rx_Bitset csetout; struct rx_superstate *superstate; unsigned char chr; #endif { struct rx_superset *stateset = superstate->contents; /* To compute the set of characters that share edges with CHR, * we start with the full character set, and subtract. */ rx_bitset_universe (rx->local_cset_size, csetout); *dfout = 0; /* Iterate over the NFA states in the superstate state-set. */ while (stateset->car) { struct rx_nfa_edge *e; for (e = stateset->car->edges; e; e = e->next) if (RX_bitset_member (e->params.cset, chr)) { /* If we find an NFA edge that applies, we make sure there * are corresponding edges in the superstate NFA. */ { struct rx_distinct_future * saved; saved = *dfout; *dfout = include_futures (rx, *dfout, e->dest, superstate); if (!*dfout) { struct rx_distinct_future * df; df = saved; if (df) df->next_same_super_edge[1]->next_same_super_edge[0] = 0; while (df) { struct rx_distinct_future *dft; dft = df; df = df->next_same_super_edge[0]; if (dft->future && dft->future->transition_refs == dft) { dft->future->transition_refs = dft->next_same_dest; if (dft->future->transition_refs == dft) dft->future->transition_refs = 0; } dft->next_same_dest->prev_same_dest = dft->prev_same_dest; dft->prev_same_dest->next_same_dest = dft->next_same_dest; rx_cache_free (rx->cache, &rx->cache->free_discernable_futures, (char *)dft); } return 0; } } /* We also trim the character set a bit. */ rx_bitset_intersection (rx->local_cset_size, csetout, e->params.cset); } else /* An edge that doesn't apply at least tells us some characters * that don't share the same edge set as CHR. */ rx_bitset_difference (rx->local_cset_size, csetout, e->params.cset); stateset = stateset->cdr; } return 1; } /* This is a constructor for RX_SUPER_EDGE structures. These are * wrappers for lists of superstate NFA edges that share character sets labels. * If a transition class contains more than one rx_distinct_future (superstate * edge), then it represents a non-determinism in the superstate NFA. */ #ifdef __STDC__ static struct rx_super_edge * rx_super_edge (struct rx *rx, struct rx_superstate *super, rx_Bitset cset, struct rx_distinct_future *df) #else static struct rx_super_edge * rx_super_edge (rx, super, cset, df) struct rx *rx; struct rx_superstate *super; rx_Bitset cset; struct rx_distinct_future *df; #endif { struct rx_super_edge *tc = (struct rx_super_edge *)rx_cache_malloc_or_get (rx->cache, &rx->cache->free_transition_classes, sizeof (struct rx_super_edge) + rx_sizeof_bitset (rx->local_cset_size)); if (!tc) return 0; tc->next = super->edges; super->edges = tc; tc->rx_backtrack_frame.inx = rx->instruction_table[rx_backtrack_point]; tc->rx_backtrack_frame.data = 0; tc->rx_backtrack_frame.data_2 = (void *) tc; tc->options = df; tc->cset = (rx_Bitset) ((char *) tc + sizeof (*tc)); rx_bitset_assign (rx->local_cset_size, tc->cset, cset); if (df) { struct rx_distinct_future * dfp = df; df->next_same_super_edge[1]->next_same_super_edge[0] = 0; while (dfp) { dfp->edge = tc; dfp = dfp->next_same_super_edge[0]; } df->next_same_super_edge[1]->next_same_super_edge[0] = df; } return tc; } /* There are three kinds of cache miss. The first occurs when a * transition is taken that has never been computed during the * lifetime of the source superstate. That cache miss is handled by * calling COMPUTE_SUPER_EDGE. The second kind of cache miss * occurs when the destination superstate of a transition doesn't * exist. SOLVE_DESTINATION is used to construct the destination superstate. * Finally, the third kind of cache miss occurs when the destination * superstate of a transition is in a `semi-free state'. That case is * handled by UNFREE_SUPERSTATE. * * The function of HANDLE_CACHE_MISS is to figure out which of these * cases applies. */ #ifdef __STDC__ static void install_partial_transition (struct rx_superstate *super, struct rx_inx *answer, RX_subset set, int offset) #else static void install_partial_transition (super, answer, set, offset) struct rx_superstate *super; struct rx_inx *answer; RX_subset set; int offset; #endif { int start = offset; int end = start + 32; RX_subset pos = 1; struct rx_inx * transitions = super->transitions; while (start < end) { if (set & pos) transitions[start] = *answer; pos <<= 1; ++start; } } #ifdef __STDC__ RX_DECL struct rx_inx * rx_handle_cache_miss (struct rx *rx, struct rx_superstate *super, unsigned char chr, void *data) #else RX_DECL struct rx_inx * rx_handle_cache_miss (rx, super, chr, data) struct rx *rx; struct rx_superstate *super; unsigned char chr; void *data; #endif { int offset = chr / RX_subset_bits; struct rx_distinct_future *df = data; if (!df) /* must be the shared_cache_miss_frame */ { /* Perhaps this is just a transition waiting to be filled. */ struct rx_super_edge *tc; RX_subset mask = rx_subset_singletons [chr % RX_subset_bits]; for (tc = super->edges; tc; tc = tc->next) if (tc->cset[offset] & mask) { struct rx_inx * answer; df = tc->options; answer = ((tc->options->next_same_super_edge[0] != tc->options) ? &tc->rx_backtrack_frame : (df->effects ? &df->side_effects_frame : &df->future_frame)); install_partial_transition (super, answer, tc->cset [offset], offset * 32); return answer; } /* Otherwise, it's a flushed or newly encountered edge. */ { char cset_space[1024]; /* this limit is far from unreasonable */ rx_Bitset trcset; struct rx_inx *answer; if (rx_sizeof_bitset (rx->local_cset_size) > sizeof (cset_space)) return 0; /* If the arbitrary limit is hit, always fail */ /* cleanly. */ trcset = (rx_Bitset)cset_space; rx_lock_superstate (rx, super); if (!compute_super_edge (rx, &df, trcset, super, chr)) { rx_unlock_superstate (rx, super); return 0; } if (!df) /* We just computed the fail transition. */ { static struct rx_inx shared_fail_frame = { 0, 0, (void *)rx_backtrack, 0 }; answer = &shared_fail_frame; } else { tc = rx_super_edge (rx, super, trcset, df); if (!tc) { rx_unlock_superstate (rx, super); return 0; } answer = ((tc->options->next_same_super_edge[0] != tc->options) ? &tc->rx_backtrack_frame : (df->effects ? &df->side_effects_frame : &df->future_frame)); } install_partial_transition (super, answer, trcset[offset], offset * 32); rx_unlock_superstate (rx, super); return answer; } } else if (df->future) /* A cache miss on an edge with a future? Must be * a semi-free destination. */ { if (df->future->is_semifree) refresh_semifree_superstate (rx->cache, df->future); return &df->future_frame; } else /* no future superstate on an existing edge */ { rx_lock_superstate (rx, super); if (!solve_destination (rx, df)) { rx_unlock_superstate (rx, super); return 0; } if (!df->effects && (df->edge->options->next_same_super_edge[0] == df->edge->options)) install_partial_transition (super, &df->future_frame, df->edge->cset[offset], offset * 32); rx_unlock_superstate (rx, super); return &df->future_frame; } } /* The rest of the code provides a regex.c compatable interface. */ __const__ char *re_error_msg[] = { 0, /* REG_NOUT */ "No match", /* REG_NOMATCH */ "Invalid regular expression", /* REG_BADPAT */ "Invalid collation character", /* REG_ECOLLATE */ "Invalid character class name", /* REG_ECTYPE */ "Trailing backslash", /* REG_EESCAPE */ "Invalid back reference", /* REG_ESUBREG */ "Unmatched [ or [^", /* REG_EBRACK */ "Unmatched ( or \\(", /* REG_EPAREN */ "Unmatched \\{", /* REG_EBRACE */ "Invalid content of \\{\\}", /* REG_BADBR */ "Invalid range end", /* REG_ERANGE */ "Memory exhausted", /* REG_ESPACE */ "Invalid preceding regular expression", /* REG_BADRPT */ "Premature end of regular expression", /* REG_EEND */ "Regular expression too big", /* REG_ESIZE */ "Unmatched ) or \\)", /* REG_ERPAREN */ }; /* * Macros used while compiling patterns. * * By convention, PEND points just past the end of the uncompiled pattern, * P points to the read position in the pattern. `translate' is the name * of the translation table (`TRANSLATE' is the name of a macro that looks * things up in `translate'). */ /* * Fetch the next character in the uncompiled pattern---translating it * if necessary. *Also cast from a signed character in the constant * string passed to us by the user to an unsigned char that we can use * as an array index (in, e.g., `translate'). */ #define PATFETCH(c) \ do {if (p == pend) return REG_EEND; \ c = (unsigned char) *p++; \ c = translate[c]; \ } while (0) /* * Fetch the next character in the uncompiled pattern, with no * translation. */ #define PATFETCH_RAW(c) \ do {if (p == pend) return REG_EEND; \ c = (unsigned char) *p++; \ } while (0) /* Go backwards one character in the pattern. */ #define PATUNFETCH p-- #define TRANSLATE(d) translate[(unsigned char) (d)] typedef unsigned regnum_t; /* Since offsets can go either forwards or backwards, this type needs to * be able to hold values from -(MAX_BUF_SIZE - 1) to MAX_BUF_SIZE - 1. */ typedef int pattern_offset_t; typedef struct { struct rexp_node ** top_expression; /* was begalt */ struct rexp_node ** last_expression; /* was laststart */ pattern_offset_t inner_group_offset; regnum_t regnum; } compile_stack_elt_t; typedef struct { compile_stack_elt_t *stack; unsigned size; unsigned avail; /* Offset of next open position. */ } compile_stack_type; #define INIT_COMPILE_STACK_SIZE 32 #define COMPILE_STACK_EMPTY (compile_stack.avail == 0) #define COMPILE_STACK_FULL (compile_stack.avail == compile_stack.size) /* The next available element. */ #define COMPILE_STACK_TOP (compile_stack.stack[compile_stack.avail]) /* Set the bit for character C in a list. */ #define SET_LIST_BIT(c) \ (b[((unsigned char) (c)) / CHARBITS] \ |= 1 << (((unsigned char) c) % CHARBITS)) /* Get the next unsigned number in the uncompiled pattern. */ #define GET_UNSIGNED_NUMBER(num) \ { if (p != pend) \ { \ PATFETCH (c); \ while (isdigit (c)) \ { \ if (num < 0) \ num = 0; \ num = num * 10 + c - '0'; \ if (p == pend) \ break; \ PATFETCH (c); \ } \ } \ } #define CHAR_CLASS_MAX_LENGTH 6 /* Namely, `xdigit'. */ #define IS_CHAR_CLASS(string) \ (!strcmp (string, "alpha") || !strcmp (string, "upper") \ || !strcmp (string, "lower") || !strcmp (string, "digit") \ || !strcmp (string, "alnum") || !strcmp (string, "xdigit") \ || !strcmp (string, "space") || !strcmp (string, "print") \ || !strcmp (string, "punct") || !strcmp (string, "graph") \ || !strcmp (string, "cntrl") || !strcmp (string, "blank")) /* These predicates are used in regex_compile. */ /* P points to just after a ^ in PATTERN. Return true if that ^ comes * after an alternative or a begin-subexpression. We assume there is at * least one character before the ^. */ #ifdef __STDC__ static boolean at_begline_loc_p (__const__ char *pattern, __const__ char * p, reg_syntax_t syntax) #else static boolean at_begline_loc_p (pattern, p, syntax) __const__ char *pattern; __const__ char * p; reg_syntax_t syntax; #endif { __const__ char *prev = p - 2; boolean prev_prev_backslash = ((prev > pattern) && (prev[-1] == '\\')); return (/* After a subexpression? */ ((*prev == '(') && ((syntax & RE_NO_BK_PARENS) || prev_prev_backslash)) || /* After an alternative? */ ((*prev == '|') && ((syntax & RE_NO_BK_VBAR) || prev_prev_backslash)) ); } /* The dual of at_begline_loc_p. This one is for $. We assume there is * at least one character after the $, i.e., `P < PEND'. */ #ifdef __STDC__ static boolean at_endline_loc_p (__const__ char *p, __const__ char *pend, int syntax) #else static boolean at_endline_loc_p (p, pend, syntax) __const__ char *p; __const__ char *pend; int syntax; #endif { __const__ char *next = p; boolean next_backslash = (*next == '\\'); __const__ char *next_next = (p + 1 < pend) ? (p + 1) : 0; return ( /* Before a subexpression? */ ((syntax & RE_NO_BK_PARENS) ? (*next == ')') : (next_backslash && next_next && (*next_next == ')'))) || /* Before an alternative? */ ((syntax & RE_NO_BK_VBAR) ? (*next == '|') : (next_backslash && next_next && (*next_next == '|'))) ); } unsigned char rx_id_translation[256] = { 0, 1, 2, 3, 4, 5, 6, 7, 8, 9, 10, 11, 12, 13, 14, 15, 16, 17, 18, 19, 20, 21, 22, 23, 24, 25, 26, 27, 28, 29, 30, 31, 32, 33, 34, 35, 36, 37, 38, 39, 40, 41, 42, 43, 44, 45, 46, 47, 48, 49, 50, 51, 52, 53, 54, 55, 56, 57, 58, 59, 60, 61, 62, 63, 64, 65, 66, 67, 68, 69, 70, 71, 72, 73, 74, 75, 76, 77, 78, 79, 80, 81, 82, 83, 84, 85, 86, 87, 88, 89, 90, 91, 92, 93, 94, 95, 96, 97, 98, 99, 100, 101, 102, 103, 104, 105, 106, 107, 108, 109, 110, 111, 112, 113, 114, 115, 116, 117, 118, 119, 120, 121, 122, 123, 124, 125, 126, 127, 128, 129, 130, 131, 132, 133, 134, 135, 136, 137, 138, 139, 140, 141, 142, 143, 144, 145, 146, 147, 148, 149, 150, 151, 152, 153, 154, 155, 156, 157, 158, 159, 160, 161, 162, 163, 164, 165, 166, 167, 168, 169, 170, 171, 172, 173, 174, 175, 176, 177, 178, 179, 180, 181, 182, 183, 184, 185, 186, 187, 188, 189, 190, 191, 192, 193, 194, 195, 196, 197, 198, 199, 200, 201, 202, 203, 204, 205, 206, 207, 208, 209, 210, 211, 212, 213, 214, 215, 216, 217, 218, 219, 220, 221, 222, 223, 224, 225, 226, 227, 228, 229, 230, 231, 232, 233, 234, 235, 236, 237, 238, 239, 240, 241, 242, 243, 244, 245, 246, 247, 248, 249, 250, 251, 252, 253, 254, 255 }; /* The compiler keeps an inverted translation table. * This looks up/inititalize elements. * VALID is an array of booleans that validate CACHE. */ #ifdef __STDC__ static rx_Bitset inverse_translation (struct re_pattern_buffer * rxb, char * valid, rx_Bitset cache, unsigned char * translate, int c) #else static rx_Bitset inverse_translation (rxb, valid, cache, translate, c) struct re_pattern_buffer * rxb; char * valid; rx_Bitset cache; unsigned char * translate; int c; #endif { rx_Bitset cs = cache + c * rx_bitset_numb_subsets (rxb->rx.local_cset_size); if (!valid[c]) { int x; int c_tr = TRANSLATE(c); rx_bitset_null (rxb->rx.local_cset_size, cs); for (x = 0; x < 256; ++x) /* &&&& 13.37 */ if (TRANSLATE(x) == c_tr) RX_bitset_enjoin (cs, x); valid[c] = 1; } return cs; } /* More subroutine declarations and macros for regex_compile. */ /* Returns true if REGNUM is in one of COMPILE_STACK's elements and false if it's not. */ #ifdef __STDC__ static boolean group_in_compile_stack (compile_stack_type compile_stack, regnum_t regnum) #else static boolean group_in_compile_stack (compile_stack, regnum) compile_stack_type compile_stack; regnum_t regnum; #endif { int this_element; for (this_element = compile_stack.avail - 1; this_element >= 0; this_element--) if (compile_stack.stack[this_element].regnum == regnum) return true; return false; } /* * Read the ending character of a range (in a bracket expression) from the * uncompiled pattern *P_PTR (which ends at PEND). We assume the * starting character is in `P[-2]'. (`P[-1]' is the character `-'.) * Then we set the translation of all bits between the starting and * ending characters (inclusive) in the compiled pattern B. * * Return an error code. * * We use these short variable names so we can use the same macros as * `regex_compile' itself. */ #ifdef __STDC__ static reg_errcode_t compile_range (struct re_pattern_buffer * rxb, rx_Bitset cs, __const__ char ** p_ptr, __const__ char * pend, unsigned char * translate, reg_syntax_t syntax, rx_Bitset inv_tr, char * valid_inv_tr) #else static reg_errcode_t compile_range (rxb, cs, p_ptr, pend, translate, syntax, inv_tr, valid_inv_tr) struct re_pattern_buffer * rxb; rx_Bitset cs; __const__ char ** p_ptr; __const__ char * pend; unsigned char * translate; reg_syntax_t syntax; rx_Bitset inv_tr; char * valid_inv_tr; #endif { unsigned this_char; __const__ char *p = *p_ptr; unsigned char range_end; unsigned char range_start = TRANSLATE(p[-2]); if (p == pend) return REG_ERANGE; PATFETCH (range_end); (*p_ptr)++; if (range_start > range_end) return syntax & RE_NO_EMPTY_RANGES ? REG_ERANGE : REG_NOERROR; for (this_char = range_start; this_char <= range_end; this_char++) { rx_Bitset it = inverse_translation (rxb, valid_inv_tr, inv_tr, translate, this_char); rx_bitset_union (rxb->rx.local_cset_size, cs, it); } return REG_NOERROR; } /* This searches a regexp for backreference side effects. * It fills in the array OUT with 1 at the index of every register pair * referenced by a backreference. * * This is used to help optimize patterns for searching. The information is * useful because, if the caller doesn't want register values, backreferenced * registers are the only registers for which we need rx_backtrack. */ #ifdef __STDC__ static void find_backrefs (char * out, struct rexp_node * rexp, struct re_se_params * params) #else static void find_backrefs (out, rexp, params) char * out; struct rexp_node * rexp; struct re_se_params * params; #endif { if (rexp) switch (rexp->type) { case r_cset: case r_data: return; case r_alternate: case r_concat: case r_opt: case r_star: case r_2phase_star: find_backrefs (out, rexp->params.pair.left, params); find_backrefs (out, rexp->params.pair.right, params); return; case r_side_effect: if ( ((long)rexp->params.side_effect >= 0) && (params [(long)rexp->params.side_effect].se == re_se_backref)) out[ params [(long)rexp->params.side_effect].op1] = 1; return; } } /* Returns 0 unless the pattern can match the empty string. */ #ifdef __STDC__ static int compute_fastset (struct re_pattern_buffer * rxb, struct rexp_node * rexp) #else static int compute_fastset (rxb, rexp) struct re_pattern_buffer * rxb; struct rexp_node * rexp; #endif { if (!rexp) return 1; switch (rexp->type) { case r_data: return 1; case r_cset: { rx_bitset_union (rxb->rx.local_cset_size, rxb->fastset, rexp->params.cset); } return 0; case r_concat: return (compute_fastset (rxb, rexp->params.pair.left) && compute_fastset (rxb, rexp->params.pair.right)); case r_2phase_star: compute_fastset (rxb, rexp->params.pair.left); /* compute_fastset (rxb, rexp->params.pair.right); nope... */ return 1; case r_alternate: return !!(compute_fastset (rxb, rexp->params.pair.left) + compute_fastset (rxb, rexp->params.pair.right)); case r_opt: case r_star: compute_fastset (rxb, rexp->params.pair.left); return 1; case r_side_effect: return 1; } /* this should never happen */ return 0; } /* returns * 1 -- yes, definately anchored by the given side effect. * 2 -- maybe anchored, maybe the empty string. * 0 -- definately not anchored * There is simply no other possibility. */ #ifdef __STDC__ static int is_anchored (struct rexp_node * rexp, rx_side_effect se) #else static int is_anchored (rexp, se) struct rexp_node * rexp; rx_side_effect se; #endif { if (!rexp) return 2; switch (rexp->type) { case r_cset: case r_data: return 0; case r_concat: case r_2phase_star: { int l = is_anchored (rexp->params.pair.left, se); return (l == 2 ? is_anchored (rexp->params.pair.right, se) : l); } case r_alternate: { int l = is_anchored (rexp->params.pair.left, se); int r = l ? is_anchored (rexp->params.pair.right, se) : 0; if (l == r) return l; else if ((l == 0) || (r == 0)) return 0; else return 2; } case r_opt: case r_star: return is_anchored (rexp->params.pair.left, se) ? 2 : 0; case r_side_effect: return ((rexp->params.side_effect == se) ? 1 : 2); } /* this should never happen */ return 0; } /* This removes register assignments that aren't required by backreferencing. * This can speed up explore_future, especially if it eliminates * non-determinism in the superstate NFA. * * NEEDED is an array of characters, presumably filled in by FIND_BACKREFS. * The non-zero elements of the array indicate which register assignments * can NOT be removed from the expression. */ #ifdef __STDC__ static struct rexp_node * remove_unecessary_side_effects (struct rx * rx, char * needed, struct rexp_node * rexp, struct re_se_params * params) #else static struct rexp_node * remove_unecessary_side_effects (rx, needed, rexp, params) struct rx * rx; char * needed; struct rexp_node * rexp; struct re_se_params * params; #endif { struct rexp_node * l; struct rexp_node * r; if (!rexp) return 0; else switch (rexp->type) { case r_cset: case r_data: return rexp; case r_alternate: case r_concat: case r_2phase_star: l = remove_unecessary_side_effects (rx, needed, rexp->params.pair.left, params); r = remove_unecessary_side_effects (rx, needed, rexp->params.pair.right, params); if ((l && r) || (rexp->type != r_concat)) { rexp->params.pair.left = l; rexp->params.pair.right = r; return rexp; } else { rexp->params.pair.left = rexp->params.pair.right = 0; rx_free_rexp (rx, rexp); return l ? l : r; } case r_opt: case r_star: l = remove_unecessary_side_effects (rx, needed, rexp->params.pair.left, params); if (l) { rexp->params.pair.left = l; return rexp; } else { rexp->params.pair.left = 0; rx_free_rexp (rx, rexp); return 0; } case r_side_effect: { int se = (long)rexp->params.side_effect; if ( (se >= 0) && ( ((enum re_side_effects)params[se].se == re_se_lparen) || ((enum re_side_effects)params[se].se == re_se_rparen)) && (params [se].op1 > 0) && (!needed [params [se].op1])) { rx_free_rexp (rx, rexp); return 0; } else return rexp; } } /* this should never happen */ return 0; } #ifdef __STDC__ static int pointless_if_repeated (struct rexp_node * node, struct re_se_params * params) #else static int pointless_if_repeated (node, params) struct rexp_node * node; struct re_se_params * params; #endif { if (!node) return 1; switch (node->type) { case r_cset: return 0; case r_alternate: case r_concat: case r_2phase_star: return (pointless_if_repeated (node->params.pair.left, params) && pointless_if_repeated (node->params.pair.right, params)); case r_opt: case r_star: return pointless_if_repeated (node->params.pair.left, params); case r_side_effect: switch (((long)node->params.side_effect < 0) ? (enum re_side_effects)node->params.side_effect : (enum re_side_effects)params[(long)node->params.side_effect].se) { case re_se_try: case re_se_at_dot: case re_se_begbuf: case re_se_hat: case re_se_wordbeg: case re_se_wordbound: case re_se_notwordbound: case re_se_wordend: case re_se_endbuf: case re_se_dollar: case re_se_fail: case re_se_win: return 1; case re_se_lparen: case re_se_rparen: case re_se_iter: case re_se_end_iter: case re_se_syntax: case re_se_not_syntax: case re_se_backref: return 0; } case r_data: default: return 0; } } #ifdef __STDC__ static int registers_on_stack (struct re_pattern_buffer * rxb, struct rexp_node * rexp, int in_danger, struct re_se_params * params) #else static int registers_on_stack (rxb, rexp, in_danger, params) struct re_pattern_buffer * rxb; struct rexp_node * rexp; int in_danger; struct re_se_params * params; #endif { if (!rexp) return 0; else switch (rexp->type) { case r_cset: case r_data: return 0; case r_alternate: case r_concat: return ( registers_on_stack (rxb, rexp->params.pair.left, in_danger, params) || (registers_on_stack (rxb, rexp->params.pair.right, in_danger, params))); case r_opt: return registers_on_stack (rxb, rexp->params.pair.left, 0, params); case r_star: return registers_on_stack (rxb, rexp->params.pair.left, 1, params); case r_2phase_star: return ( registers_on_stack (rxb, rexp->params.pair.left, 1, params) || registers_on_stack (rxb, rexp->params.pair.right, 1, params)); case r_side_effect: { int se = (long)rexp->params.side_effect; if ( in_danger && (se >= 0) && (params [se].op1 > 0) && ( ((enum re_side_effects)params[se].se == re_se_lparen) || ((enum re_side_effects)params[se].se == re_se_rparen))) return 1; else return 0; } } /* this should never happen */ return 0; } static char idempotent_complex_se[] = { #define RX_WANT_SE_DEFS 1 #undef RX_DEF_SE #undef RX_DEF_CPLX_SE #define RX_DEF_SE(IDEM, NAME, VALUE) #define RX_DEF_CPLX_SE(IDEM, NAME, VALUE) IDEM, #include "rx.h" #undef RX_DEF_SE #undef RX_DEF_CPLX_SE #undef RX_WANT_SE_DEFS 23 }; static char idempotent_se[] = { 13, #define RX_WANT_SE_DEFS 1 #undef RX_DEF_SE #undef RX_DEF_CPLX_SE #define RX_DEF_SE(IDEM, NAME, VALUE) IDEM, #define RX_DEF_CPLX_SE(IDEM, NAME, VALUE) #include "rx.h" #undef RX_DEF_SE #undef RX_DEF_CPLX_SE #undef RX_WANT_SE_DEFS 42 }; #ifdef __STDC__ static int has_any_se (struct rx * rx, struct rexp_node * rexp) #else static int has_any_se (rx, rexp) struct rx * rx; struct rexp_node * rexp; #endif { if (!rexp) return 0; switch (rexp->type) { case r_cset: case r_data: return 0; case r_side_effect: return 1; case r_2phase_star: case r_concat: case r_alternate: return ( has_any_se (rx, rexp->params.pair.left) || has_any_se (rx, rexp->params.pair.right)); case r_opt: case r_star: return has_any_se (rx, rexp->params.pair.left); } /* this should never happen */ return 0; } /* This must be called AFTER `convert_hard_loops' for a given REXP. */ #ifdef __STDC__ static int has_non_idempotent_epsilon_path (struct rx * rx, struct rexp_node * rexp, struct re_se_params * params) #else static int has_non_idempotent_epsilon_path (rx, rexp, params) struct rx * rx; struct rexp_node * rexp; struct re_se_params * params; #endif { if (!rexp) return 0; switch (rexp->type) { case r_cset: case r_data: case r_star: return 0; case r_side_effect: return !((long)rexp->params.side_effect > 0 ? idempotent_complex_se [ params [(long)rexp->params.side_effect].se ] : idempotent_se [-(long)rexp->params.side_effect]); case r_alternate: return ( has_non_idempotent_epsilon_path (rx, rexp->params.pair.left, params) || has_non_idempotent_epsilon_path (rx, rexp->params.pair.right, params)); case r_2phase_star: case r_concat: return ( has_non_idempotent_epsilon_path (rx, rexp->params.pair.left, params) && has_non_idempotent_epsilon_path (rx, rexp->params.pair.right, params)); case r_opt: return has_non_idempotent_epsilon_path (rx, rexp->params.pair.left, params); } /* this should never happen */ return 0; } /* This computes rougly what it's name suggests. It can (and does) go wrong * in the direction of returning spurious 0 without causing disasters. */ #ifdef __STDC__ static int begins_with_complex_se (struct rx * rx, struct rexp_node * rexp) #else static int begins_with_complex_se (rx, rexp) struct rx * rx; struct rexp_node * rexp; #endif { if (!rexp) return 0; switch (rexp->type) { case r_cset: case r_data: return 0; case r_side_effect: return ((long)rexp->params.side_effect >= 0); case r_alternate: return ( begins_with_complex_se (rx, rexp->params.pair.left) && begins_with_complex_se (rx, rexp->params.pair.right)); case r_concat: return has_any_se (rx, rexp->params.pair.left); case r_opt: case r_star: case r_2phase_star: return 0; } /* this should never happen */ return 0; } /* This destructively removes some of the re_se_tv side effects from * a rexp tree. In particular, during parsing re_se_tv was inserted on the * right half of every | to guarantee that posix path preference could be * honored. This function removes some which it can be determined aren't * needed. */ #ifdef __STDC__ static void speed_up_alt (struct rx * rx, struct rexp_node * rexp, int unposix) #else static void speed_up_alt (rx, rexp, unposix) struct rx * rx; struct rexp_node * rexp; int unposix; #endif { if (!rexp) return; switch (rexp->type) { case r_cset: case r_data: case r_side_effect: return; case r_opt: case r_star: speed_up_alt (rx, rexp->params.pair.left, unposix); return; case r_2phase_star: case r_concat: speed_up_alt (rx, rexp->params.pair.left, unposix); speed_up_alt (rx, rexp->params.pair.right, unposix); return; case r_alternate: /* the right child is guaranteed to be (concat re_se_tv <subexp>) */ speed_up_alt (rx, rexp->params.pair.left, unposix); speed_up_alt (rx, rexp->params.pair.right->params.pair.right, unposix); if ( unposix || (begins_with_complex_se (rx, rexp->params.pair.right->params.pair.right)) || !( has_any_se (rx, rexp->params.pair.right->params.pair.right) || has_any_se (rx, rexp->params.pair.left))) { struct rexp_node * conc = rexp->params.pair.right; rexp->params.pair.right = conc->params.pair.right; conc->params.pair.right = 0; rx_free_rexp (rx, conc); } } } /* `regex_compile' compiles PATTERN (of length SIZE) according to SYNTAX. Returns one of error codes defined in `regex.h', or zero for success. Assumes the `allocated' (and perhaps `buffer') and `translate' fields are set in BUFP on entry. If it succeeds, results are put in BUFP (if it returns an error, the contents of BUFP are undefined): `buffer' is the compiled pattern; `syntax' is set to SYNTAX; `used' is set to the length of the compiled pattern; `fastmap_accurate' is set to zero; `re_nsub' is set to the number of groups in PATTERN; `not_bol' and `not_eol' are set to zero. The `fastmap' and `newline_anchor' fields are neither examined nor set. */ #ifdef __STDC__ RX_DECL reg_errcode_t rx_compile (__const__ char *pattern, int size, reg_syntax_t syntax, struct re_pattern_buffer * rxb) #else RX_DECL reg_errcode_t rx_compile (pattern, size, syntax, rxb) __const__ char *pattern; int size; reg_syntax_t syntax; struct re_pattern_buffer * rxb; #endif { RX_subset inverse_translate [CHAR_SET_SIZE * rx_bitset_numb_subsets(CHAR_SET_SIZE)]; char validate_inv_tr [CHAR_SET_SIZE * rx_bitset_numb_subsets(CHAR_SET_SIZE)]; /* We fetch characters from PATTERN here. Even though PATTERN is `char *' (i.e., signed), we declare these variables as unsigned, so they can be reliably used as array indices. */ register unsigned char c, c1; /* A random tempory spot in PATTERN. */ __const__ char *p1; /* Keeps track of unclosed groups. */ compile_stack_type compile_stack; /* Points to the current (ending) position in the pattern. */ __const__ char *p = pattern; __const__ char *pend = pattern + size; /* How to translate the characters in the pattern. */ unsigned char *translate = (rxb->translate ? rxb->translate : rx_id_translation); /* When parsing is done, this will hold the expression tree. */ struct rexp_node * rexp = 0; /* In the midst of compilation, this holds onto the regexp * first parst while rexp goes on to aquire additional constructs. */ struct rexp_node * orig_rexp = 0; struct rexp_node * fewer_side_effects = 0; /* This and top_expression are saved on the compile stack. */ struct rexp_node ** top_expression = &rexp; struct rexp_node ** last_expression = top_expression; /* Parameter to `goto append_node' */ struct rexp_node * append; /* Counts open-groups as they are encountered. This is the index of the * innermost group being compiled. */ regnum_t regnum = 0; /* Place in the uncompiled pattern (i.e., the {) to * which to go back if the interval is invalid. */ __const__ char *beg_interval; struct re_se_params * params = 0; int paramc = 0; /* How many complex side effects so far? */ rx_side_effect side; /* param to `goto add_side_effect' */ bzero (validate_inv_tr, sizeof (validate_inv_tr)); rxb->rx.instruction_table = rx_id_instruction_table; /* Initialize the compile stack. */ compile_stack.stack = (( compile_stack_elt_t *) malloc ((INIT_COMPILE_STACK_SIZE) * sizeof ( compile_stack_elt_t))); if (compile_stack.stack == 0) return REG_ESPACE; compile_stack.size = INIT_COMPILE_STACK_SIZE; compile_stack.avail = 0; /* Initialize the pattern buffer. */ rxb->rx.cache = &default_cache; rxb->syntax = syntax; rxb->fastmap_accurate = 0; rxb->not_bol = rxb->not_eol = 0; rxb->least_subs = 0; /* Always count groups, whether or not rxb->no_sub is set. * The whole pattern is implicitly group 0, so counting begins * with 1. */ rxb->re_nsub = 0; #if !defined (emacs) && !defined (SYNTAX_TABLE) /* Initialize the syntax table. */ init_syntax_once (); #endif /* Loop through the uncompiled pattern until we're at the end. */ while (p != pend) { PATFETCH (c); switch (c) { case '^': { if ( /* If at start of pattern, it's an operator. */ p == pattern + 1 /* If context independent, it's an operator. */ || syntax & RE_CONTEXT_INDEP_ANCHORS /* Otherwise, depends on what's come before. */ || at_begline_loc_p (pattern, p, syntax)) { struct rexp_node * n = rx_mk_r_side_effect (&rxb->rx, (rx_side_effect)re_se_hat); if (!n) return REG_ESPACE; append = n; goto append_node; } else goto normal_char; } break; case '$': { if ( /* If at end of pattern, it's an operator. */ p == pend /* If context independent, it's an operator. */ || syntax & RE_CONTEXT_INDEP_ANCHORS /* Otherwise, depends on what's next. */ || at_endline_loc_p (p, pend, syntax)) { struct rexp_node * n = rx_mk_r_side_effect (&rxb->rx, (rx_side_effect)re_se_dollar); if (!n) return REG_ESPACE; append = n; goto append_node; } else goto normal_char; } break; case '+': case '?': if ((syntax & RE_BK_PLUS_QM) || (syntax & RE_LIMITED_OPS)) goto normal_char; handle_plus: case '*': /* If there is no previous pattern... */ if (pointless_if_repeated (*last_expression, params)) { if (syntax & RE_CONTEXT_INVALID_OPS) return REG_BADRPT; else if (!(syntax & RE_CONTEXT_INDEP_OPS)) goto normal_char; } { /* 1 means zero (many) matches is allowed. */ char zero_times_ok = 0, many_times_ok = 0; /* If there is a sequence of repetition chars, collapse it down to just one (the right one). We can't combine interval operators with these because of, e.g., `a{2}*', which should only match an even number of `a's. */ for (;;) { zero_times_ok |= c != '+'; many_times_ok |= c != '?'; if (p == pend) break; PATFETCH (c); if (c == '*' || (!(syntax & RE_BK_PLUS_QM) && (c == '+' || c == '?'))) ; else if (syntax & RE_BK_PLUS_QM && c == '\\') { if (p == pend) return REG_EESCAPE; PATFETCH (c1); if (!(c1 == '+' || c1 == '?')) { PATUNFETCH; PATUNFETCH; break; } c = c1; } else { PATUNFETCH; break; } /* If we get here, we found another repeat character. */ } /* Star, etc. applied to an empty pattern is equivalent to an empty pattern. */ if (!last_expression) break; /* Now we know whether or not zero matches is allowed * and also whether or not two or more matches is allowed. */ { struct rexp_node * inner_exp = *last_expression; int need_sync = 0; if (many_times_ok && has_non_idempotent_epsilon_path (&rxb->rx, inner_exp, params)) { struct rexp_node * pusher = rx_mk_r_side_effect (&rxb->rx, (rx_side_effect)re_se_pushpos); struct rexp_node * checker = rx_mk_r_side_effect (&rxb->rx, (rx_side_effect)re_se_chkpos); struct rexp_node * pushback = rx_mk_r_side_effect (&rxb->rx, (rx_side_effect)re_se_pushback); rx_Bitset cs = rx_cset (&rxb->rx); struct rexp_node * lit_t = rx_mk_r_cset (&rxb->rx, cs); struct rexp_node * fake_state = rx_mk_r_concat (&rxb->rx, pushback, lit_t); struct rexp_node * phase2 = rx_mk_r_concat (&rxb->rx, checker, fake_state); struct rexp_node * popper = rx_mk_r_side_effect (&rxb->rx, (rx_side_effect)re_se_poppos); struct rexp_node * star = rx_mk_r_2phase_star (&rxb->rx, inner_exp, phase2); struct rexp_node * a = rx_mk_r_concat (&rxb->rx, pusher, star); struct rexp_node * whole_thing = rx_mk_r_concat (&rxb->rx, a, popper); if (!(pusher && star && pushback && lit_t && fake_state && lit_t && phase2 && checker && popper && a && whole_thing)) return REG_ESPACE; RX_bitset_enjoin (cs, 't'); *last_expression = whole_thing; } else { struct rexp_node * star = (many_times_ok ? rx_mk_r_star : rx_mk_r_opt) (&rxb->rx, *last_expression); if (!star) return REG_ESPACE; *last_expression = star; need_sync = has_any_se (&rxb->rx, *last_expression); } if (!zero_times_ok) { struct rexp_node * concat = rx_mk_r_concat (&rxb->rx, inner_exp, rx_copy_rexp (&rxb->rx, *last_expression)); if (!concat) return REG_ESPACE; *last_expression = concat; } if (need_sync) { int sync_se = paramc; params = (params ? ((struct re_se_params *) realloc (params, sizeof (*params) * (1 + paramc))) : ((struct re_se_params *) malloc (sizeof (*params)))); if (!params) return REG_ESPACE; ++paramc; params [sync_se].se = re_se_tv; side = (rx_side_effect)sync_se; goto add_side_effect; } } /* The old regex.c used to optimize `.*\n'. * Maybe rx should too? */ } break; case '.': { rx_Bitset cs = rx_cset (&rxb->rx); struct rexp_node * n = rx_mk_r_cset (&rxb->rx, cs); if (!(cs && n)) return REG_ESPACE; rx_bitset_universe (rxb->rx.local_cset_size, cs); if (!(rxb->syntax & RE_DOT_NEWLINE)) RX_bitset_remove (cs, '\n'); if (!(rxb->syntax & RE_DOT_NOT_NULL)) RX_bitset_remove (cs, 0); append = n; goto append_node; break; } case '[': if (p == pend) return REG_EBRACK; { boolean had_char_class = false; rx_Bitset cs = rx_cset (&rxb->rx); struct rexp_node * node = rx_mk_r_cset (&rxb->rx, cs); int is_inverted = *p == '^'; if (!(node && cs)) return REG_ESPACE; /* This branch of the switch is normally exited with *`goto append_node' */ append = node; if (is_inverted) p++; /* Remember the first position in the bracket expression. */ p1 = p; /* Read in characters and ranges, setting map bits. */ for (;;) { if (p == pend) return REG_EBRACK; PATFETCH (c); /* \ might escape characters inside [...] and [^...]. */ if ((syntax & RE_BACKSLASH_ESCAPE_IN_LISTS) && c == '\\') { if (p == pend) return REG_EESCAPE; PATFETCH (c1); { rx_Bitset it = inverse_translation (rxb, validate_inv_tr, inverse_translate, translate, c1); rx_bitset_union (rxb->rx.local_cset_size, cs, it); } continue; } /* Could be the end of the bracket expression. If it's not (i.e., when the bracket expression is `[]' so far), the ']' character bit gets set way below. */ if (c == ']' && p != p1 + 1) goto finalize_class_and_append; /* Look ahead to see if it's a range when the last thing was a character class. */ if (had_char_class && c == '-' && *p != ']') return REG_ERANGE; /* Look ahead to see if it's a range when the last thing was a character: if this is a hyphen not at the beginning or the end of a list, then it's the range operator. */ if (c == '-' && !(p - 2 >= pattern && p[-2] == '[') && !(p - 3 >= pattern && p[-3] == '[' && p[-2] == '^') && *p != ']') { reg_errcode_t ret = compile_range (rxb, cs, &p, pend, translate, syntax, inverse_translate, validate_inv_tr); if (ret != REG_NOERROR) return ret; } else if (p[0] == '-' && p[1] != ']') { /* This handles ranges made up of characters only. */ reg_errcode_t ret; /* Move past the `-'. */ PATFETCH (c1); ret = compile_range (rxb, cs, &p, pend, translate, syntax, inverse_translate, validate_inv_tr); if (ret != REG_NOERROR) return ret; } /* See if we're at the beginning of a possible character class. */ else if ((syntax & RE_CHAR_CLASSES) && (c == '[') && (*p == ':')) { char str[CHAR_CLASS_MAX_LENGTH + 1]; PATFETCH (c); c1 = 0; /* If pattern is `[[:'. */ if (p == pend) return REG_EBRACK; for (;;) { PATFETCH (c); if (c == ':' || c == ']' || p == pend || c1 == CHAR_CLASS_MAX_LENGTH) break; str[c1++] = c; } str[c1] = '\0'; /* If isn't a word bracketed by `[:' and:`]': undo the ending character, the letters, and leave the leading `:' and `[' (but set bits for them). */ if (c == ':' && *p == ']') { int ch; boolean is_alnum = !strcmp (str, "alnum"); boolean is_alpha = !strcmp (str, "alpha"); boolean is_blank = !strcmp (str, "blank"); boolean is_cntrl = !strcmp (str, "cntrl"); boolean is_digit = !strcmp (str, "digit"); boolean is_graph = !strcmp (str, "graph"); boolean is_lower = !strcmp (str, "lower"); boolean is_print = !strcmp (str, "print"); boolean is_punct = !strcmp (str, "punct"); boolean is_space = !strcmp (str, "space"); boolean is_upper = !strcmp (str, "upper"); boolean is_xdigit = !strcmp (str, "xdigit"); if (!IS_CHAR_CLASS (str)) return REG_ECTYPE; /* Throw away the ] at the end of the character class. */ PATFETCH (c); if (p == pend) return REG_EBRACK; for (ch = 0; ch < 1 << CHARBITS; ch++) { if ( (is_alnum && isalnum (ch)) || (is_alpha && isalpha (ch)) || (is_blank && isblank (ch)) || (is_cntrl && iscntrl (ch)) || (is_digit && isdigit (ch)) || (is_graph && isgraph (ch)) || (is_lower && islower (ch)) || (is_print && isprint (ch)) || (is_punct && ispunct (ch)) || (is_space && isspace (ch)) || (is_upper && isupper (ch)) || (is_xdigit && isxdigit (ch))) { rx_Bitset it = inverse_translation (rxb, validate_inv_tr, inverse_translate, translate, ch); rx_bitset_union (rxb->rx.local_cset_size, cs, it); } } had_char_class = true; } else { c1++; while (c1--) PATUNFETCH; { rx_Bitset it = inverse_translation (rxb, validate_inv_tr, inverse_translate, translate, '['); rx_bitset_union (rxb->rx.local_cset_size, cs, it); } { rx_Bitset it = inverse_translation (rxb, validate_inv_tr, inverse_translate, translate, ':'); rx_bitset_union (rxb->rx.local_cset_size, cs, it); } had_char_class = false; } } else { had_char_class = false; { rx_Bitset it = inverse_translation (rxb, validate_inv_tr, inverse_translate, translate, c); rx_bitset_union (rxb->rx.local_cset_size, cs, it); } } } finalize_class_and_append: if (is_inverted) { rx_bitset_complement (rxb->rx.local_cset_size, cs); if (syntax & RE_HAT_LISTS_NOT_NEWLINE) RX_bitset_remove (cs, '\n'); } goto append_node; } break; case '(': if (syntax & RE_NO_BK_PARENS) goto handle_open; else goto normal_char; case ')': if (syntax & RE_NO_BK_PARENS) goto handle_close; else goto normal_char; case '\n': if (syntax & RE_NEWLINE_ALT) goto handle_alt; else goto normal_char; case '|': if (syntax & RE_NO_BK_VBAR) goto handle_alt; else goto normal_char; case '{': if ((syntax & RE_INTERVALS) && (syntax & RE_NO_BK_BRACES)) goto handle_interval; else goto normal_char; case '\\': if (p == pend) return REG_EESCAPE; /* Do not translate the character after the \, so that we can distinguish, e.g., \B from \b, even if we normally would translate, e.g., B to b. */ PATFETCH_RAW (c); switch (c) { case '(': if (syntax & RE_NO_BK_PARENS) goto normal_backslash; handle_open: rxb->re_nsub++; regnum++; if (COMPILE_STACK_FULL) { ((compile_stack.stack) = (compile_stack_elt_t *) realloc (compile_stack.stack, ( compile_stack.size << 1) * sizeof ( compile_stack_elt_t))); if (compile_stack.stack == 0) return REG_ESPACE; compile_stack.size <<= 1; } if (*last_expression) { struct rexp_node * concat = rx_mk_r_concat (&rxb->rx, *last_expression, 0); if (!concat) return REG_ESPACE; *last_expression = concat; last_expression = &concat->params.pair.right; } /* * These are the values to restore when we hit end of this * group. */ COMPILE_STACK_TOP.top_expression = top_expression; COMPILE_STACK_TOP.last_expression = last_expression; COMPILE_STACK_TOP.regnum = regnum; compile_stack.avail++; top_expression = last_expression; break; case ')': if (syntax & RE_NO_BK_PARENS) goto normal_backslash; handle_close: /* See similar code for backslashed left paren above. */ if (COMPILE_STACK_EMPTY) if (syntax & RE_UNMATCHED_RIGHT_PAREN_ORD) goto normal_char; else return REG_ERPAREN; /* Since we just checked for an empty stack above, this ``can't happen''. */ { /* We don't just want to restore into `regnum', because later groups should continue to be numbered higher, as in `(ab)c(de)' -- the second group is #2. */ regnum_t this_group_regnum; struct rexp_node ** inner = top_expression; compile_stack.avail--; top_expression = COMPILE_STACK_TOP.top_expression; last_expression = COMPILE_STACK_TOP.last_expression; this_group_regnum = COMPILE_STACK_TOP.regnum; { int left_se = paramc; int right_se = paramc + 1; params = (params ? ((struct re_se_params *) realloc (params, (paramc + 2) * sizeof (params[0]))) : ((struct re_se_params *) malloc (2 * sizeof (params[0])))); if (!params) return REG_ESPACE; paramc += 2; params[left_se].se = re_se_lparen; params[left_se].op1 = this_group_regnum; params[right_se].se = re_se_rparen; params[right_se].op1 = this_group_regnum; { struct rexp_node * left = rx_mk_r_side_effect (&rxb->rx, (rx_side_effect)left_se); struct rexp_node * right = rx_mk_r_side_effect (&rxb->rx, (rx_side_effect)right_se); struct rexp_node * c1 = (*inner ? rx_mk_r_concat (&rxb->rx, left, *inner) : left); struct rexp_node * c2 = rx_mk_r_concat (&rxb->rx, c1, right); if (!(left && right && c1 && c2)) return REG_ESPACE; *inner = c2; } } break; } case '|': /* `\|'. */ if ((syntax & RE_LIMITED_OPS) || (syntax & RE_NO_BK_VBAR)) goto normal_backslash; handle_alt: if (syntax & RE_LIMITED_OPS) goto normal_char; { struct rexp_node * alt = rx_mk_r_alternate (&rxb->rx, *top_expression, 0); if (!alt) return REG_ESPACE; *top_expression = alt; last_expression = &alt->params.pair.right; { int sync_se = paramc; params = (params ? ((struct re_se_params *) realloc (params, (paramc + 1) * sizeof (params[0]))) : ((struct re_se_params *) malloc (sizeof (params[0])))); if (!params) return REG_ESPACE; ++paramc; params[sync_se].se = re_se_tv; { struct rexp_node * sync = rx_mk_r_side_effect (&rxb->rx, (rx_side_effect)sync_se); struct rexp_node * conc = rx_mk_r_concat (&rxb->rx, sync, 0); if (!sync || !conc) return REG_ESPACE; *last_expression = conc; last_expression = &conc->params.pair.right; } } } break; case '{': /* If \{ is a literal. */ if (!(syntax & RE_INTERVALS) /* If we're at `\{' and it's not the open-interval operator. */ || ((syntax & RE_INTERVALS) && (syntax & RE_NO_BK_BRACES)) || (p - 2 == pattern && p == pend)) goto normal_backslash; handle_interval: { /* If got here, then the syntax allows intervals. */ /* At least (most) this many matches must be made. */ int lower_bound = -1, upper_bound = -1; beg_interval = p - 1; if (p == pend) { if (syntax & RE_NO_BK_BRACES) goto unfetch_interval; else return REG_EBRACE; } GET_UNSIGNED_NUMBER (lower_bound); if (c == ',') { GET_UNSIGNED_NUMBER (upper_bound); if (upper_bound < 0) upper_bound = RE_DUP_MAX; } else /* Interval such as `{1}' => match exactly once. */ upper_bound = lower_bound; if (lower_bound < 0 || upper_bound > RE_DUP_MAX || lower_bound > upper_bound) { if (syntax & RE_NO_BK_BRACES) goto unfetch_interval; else return REG_BADBR; } if (!(syntax & RE_NO_BK_BRACES)) { if (c != '\\') return REG_EBRACE; PATFETCH (c); } if (c != '}') { if (syntax & RE_NO_BK_BRACES) goto unfetch_interval; else return REG_BADBR; } /* We just parsed a valid interval. */ /* If it's invalid to have no preceding re. */ if (pointless_if_repeated (*last_expression, params)) { if (syntax & RE_CONTEXT_INVALID_OPS) return REG_BADRPT; else if (!(syntax & RE_CONTEXT_INDEP_OPS)) goto unfetch_interval; /* was: else laststart = b; */ } /* If the upper bound is zero, don't want to iterate * at all. */ if (upper_bound == 0) { if (*last_expression) { rx_free_rexp (&rxb->rx, *last_expression); *last_expression = 0; } } else /* Otherwise, we have a nontrivial interval. */ { int iter_se = paramc; int end_se = paramc + 1; params = (params ? ((struct re_se_params *) realloc (params, sizeof (*params) * (2 + paramc))) : ((struct re_se_params *) malloc (2 * sizeof (*params)))); if (!params) return REG_ESPACE; paramc += 2; params [iter_se].se = re_se_iter; params [iter_se].op1 = lower_bound; params[iter_se].op2 = upper_bound; params[end_se].se = re_se_end_iter; params[end_se].op1 = lower_bound; params[end_se].op2 = upper_bound; { struct rexp_node * push0 = rx_mk_r_side_effect (&rxb->rx, (rx_side_effect)re_se_push0); struct rexp_node * start_one_iter = rx_mk_r_side_effect (&rxb->rx, (rx_side_effect)iter_se); struct rexp_node * phase1 = rx_mk_r_concat (&rxb->rx, start_one_iter, *last_expression); struct rexp_node * pushback = rx_mk_r_side_effect (&rxb->rx, (rx_side_effect)re_se_pushback); rx_Bitset cs = rx_cset (&rxb->rx); struct rexp_node * lit_t = rx_mk_r_cset (&rxb->rx, cs); struct rexp_node * phase2 = rx_mk_r_concat (&rxb->rx, pushback, lit_t); struct rexp_node * loop = rx_mk_r_2phase_star (&rxb->rx, phase1, phase2); struct rexp_node * push_n_loop = rx_mk_r_concat (&rxb->rx, push0, loop); struct rexp_node * final_test = rx_mk_r_side_effect (&rxb->rx, (rx_side_effect)end_se); struct rexp_node * full_exp = rx_mk_r_concat (&rxb->rx, push_n_loop, final_test); if (!(push0 && start_one_iter && phase1 && pushback && lit_t && phase2 && loop && push_n_loop && final_test && full_exp)) return REG_ESPACE; RX_bitset_enjoin(cs, 't'); *last_expression = full_exp; } } beg_interval = 0; } break; unfetch_interval: /* If an invalid interval, match the characters as literals. */ p = beg_interval; beg_interval = 0; /* normal_char and normal_backslash need `c'. */ PATFETCH (c); if (!(syntax & RE_NO_BK_BRACES)) { if (p > pattern && p[-1] == '\\') goto normal_backslash; } goto normal_char; #ifdef emacs /* There is no way to specify the before_dot and after_dot operators. rms says this is ok. --karl */ case '=': side = (rx_side_effect)rx_se_at_dot; goto add_side_effect; break; case 's': case 'S': { rx_Bitset cs = rx_cset (&rxb->rx); struct rexp_node * set = rx_mk_r_cset (&rxb->rx, cs); if (!(cs && set)) return REG_ESPACE; if (c == 'S') rx_bitset_universe (rxb->rx.local_cset_size, cs); PATFETCH (c); { int x; enum syntaxcode code = syntax_spec_code [c]; for (x = 0; x < 256; ++x) { if (SYNTAX (x) == code) { rx_Bitset it = inverse_translation (rxb, validate_inv_tr, inverse_translate, translate, x); rx_bitset_xor (rxb->rx.local_cset_size, cs, it); } } } append = set; goto append_node; } break; #endif /* emacs */ case 'w': case 'W': { rx_Bitset cs = rx_cset (&rxb->rx); struct rexp_node * n = (cs ? rx_mk_r_cset (&rxb->rx, cs) : 0); if (!(cs && n)) return REG_ESPACE; if (c == 'W') rx_bitset_universe (rxb->rx.local_cset_size ,cs); { int x; for (x = rxb->rx.local_cset_size - 1; x > 0; --x) if (SYNTAX(x) & Sword) RX_bitset_toggle (cs, x); } append = n; goto append_node; } break; /* With a little extra work, some of these side effects could be optimized * away (basicly by looking at what we already know about the surrounding * chars). */ case '<': side = (rx_side_effect)re_se_wordbeg; goto add_side_effect; break; case '>': side = (rx_side_effect)re_se_wordend; goto add_side_effect; break; case 'b': side = (rx_side_effect)re_se_wordbound; goto add_side_effect; break; case 'B': side = (rx_side_effect)re_se_notwordbound; goto add_side_effect; break; case '`': side = (rx_side_effect)re_se_begbuf; goto add_side_effect; break; case '\'': side = (rx_side_effect)re_se_endbuf; goto add_side_effect; break; add_side_effect: { struct rexp_node * se = rx_mk_r_side_effect (&rxb->rx, side); if (!se) return REG_ESPACE; append = se; goto append_node; } break; case '1': case '2': case '3': case '4': case '5': case '6': case '7': case '8': case '9': if (syntax & RE_NO_BK_REFS) goto normal_char; c1 = c - '0'; if (c1 > regnum) return REG_ESUBREG; /* Can't back reference to a subexpression if inside of it. */ if (group_in_compile_stack (compile_stack, c1)) return REG_ESUBREG; { int backref_se = paramc; params = (params ? ((struct re_se_params *) realloc (params, sizeof (*params) * (1 + paramc))) : ((struct re_se_params *) malloc (sizeof (*params)))); if (!params) return REG_ESPACE; ++paramc; params[backref_se].se = re_se_backref; params[backref_se].op1 = c1; side = (rx_side_effect)backref_se; goto add_side_effect; } break; case '+': case '?': if (syntax & RE_BK_PLUS_QM) goto handle_plus; else goto normal_backslash; default: normal_backslash: /* You might think it would be useful for \ to mean not to translate; but if we don't translate it it will never match anything. */ c = TRANSLATE (c); goto normal_char; } break; default: /* Expects the character in `c'. */ normal_char: { rx_Bitset cs = rx_cset(&rxb->rx); struct rexp_node * match = rx_mk_r_cset (&rxb->rx, cs); rx_Bitset it; if (!(cs && match)) return REG_ESPACE; it = inverse_translation (rxb, validate_inv_tr, inverse_translate, translate, c); rx_bitset_union (CHAR_SET_SIZE, cs, it); append = match; append_node: /* This genericly appends the rexp APPEND to *LAST_EXPRESSION * and then parses the next character normally. */ if (*last_expression) { struct rexp_node * concat = rx_mk_r_concat (&rxb->rx, *last_expression, append); if (!concat) return REG_ESPACE; *last_expression = concat; last_expression = &concat->params.pair.right; } else *last_expression = append; } } /* switch (c) */ } /* while p != pend */ { int win_se = paramc; params = (params ? ((struct re_se_params *) realloc (params, sizeof (*params) * (1 + paramc))) : ((struct re_se_params *) malloc (sizeof (*params)))); if (!params) return REG_ESPACE; ++paramc; params[win_se].se = re_se_win; { struct rexp_node * se = rx_mk_r_side_effect (&rxb->rx, (rx_side_effect)win_se); struct rexp_node * concat = rx_mk_r_concat (&rxb->rx, rexp, se); if (!(se && concat)) return REG_ESPACE; rexp = concat; } } /* Through the pattern now. */ if (!COMPILE_STACK_EMPTY) return REG_EPAREN; free (compile_stack.stack); orig_rexp = rexp; #ifdef RX_DEBUG if (rx_debug_compile) { dbug_rxb = rxb; fputs ("\n\nCompiling ", stdout); fwrite (pattern, 1, size, stdout); fputs (":\n", stdout); rxb->se_params = params; print_rexp (&rxb->rx, orig_rexp, 2, re_seprint, stdout); } #endif { rx_Bitset cs = rx_cset(&rxb->rx); rx_Bitset cs2 = rx_cset(&rxb->rx); char * se_map = (char *) alloca (paramc); struct rexp_node * new_rexp = 0; bzero (se_map, paramc); find_backrefs (se_map, rexp, params); fewer_side_effects = remove_unecessary_side_effects (&rxb->rx, se_map, rx_copy_rexp (&rxb->rx, rexp), params); speed_up_alt (&rxb->rx, rexp, 0); speed_up_alt (&rxb->rx, fewer_side_effects, 1); { char * syntax_parens = rxb->syntax_parens; if (syntax_parens == (char *)0x1) rexp = remove_unecessary_side_effects (&rxb->rx, se_map, rexp, params); else if (syntax_parens) { int x; for (x = 0; x < paramc; ++x) if (( (params[x].se == re_se_lparen) || (params[x].se == re_se_rparen)) && (!syntax_parens [params[x].op1])) se_map [x] = 1; rexp = remove_unecessary_side_effects (&rxb->rx, se_map, rexp, params); } } /* At least one more optimization would be nice to have here but i ran out * of time. The idea would be to delay side effects. * For examle, `(abc)' is the same thing as `abc()' except that the * left paren is offset by 3 (which we know at compile time). * (In this comment, write that second pattern `abc(:3:)' * where `(:3:' is a syntactic unit.) * * Trickier: `(abc|defg)' is the same as `(abc(:3:|defg(:4:))' * (The paren nesting may be hard to follow -- that's an alternation * of `abc(:3:' and `defg(:4:' inside (purely syntactic) parens * followed by the closing paren from the original expression.) * * Neither the expression tree representation nor the the nfa make * this very easy to write. :( */ /* What we compile is different than what the parser returns. * Suppose the parser returns expression R. * Let R' be R with unnecessary register assignments removed * (see REMOVE_UNECESSARY_SIDE_EFFECTS, above). * * What we will compile is the expression: * * m{try}R{win}\|s{try}R'{win} * * {try} and {win} denote side effect epsilons (see EXPLORE_FUTURE). * * When trying a match, we insert an `m' at the beginning of the * string if the user wants registers to be filled, `s' if not. */ new_rexp = rx_mk_r_alternate (&rxb->rx, rx_mk_r_concat (&rxb->rx, rx_mk_r_cset (&rxb->rx, cs2), rexp), rx_mk_r_concat (&rxb->rx, rx_mk_r_cset (&rxb->rx, cs), fewer_side_effects)); if (!(new_rexp && cs && cs2)) return REG_ESPACE; RX_bitset_enjoin (cs2, '\0'); /* prefixed to the rexp used for matching. */ RX_bitset_enjoin (cs, '\1'); /* prefixed to the rexp used for searching. */ rexp = new_rexp; } #ifdef RX_DEBUG if (rx_debug_compile) { fputs ("\n...which is compiled as:\n", stdout); print_rexp (&rxb->rx, rexp, 2, re_seprint, stdout); } #endif { struct rx_nfa_state *start = 0; struct rx_nfa_state *end = 0; if (!rx_build_nfa (&rxb->rx, rexp, &start, &end)) return REG_ESPACE; /* */ else { void * mem = (void *)rxb->buffer; unsigned long size = rxb->allocated; int start_id; char * perm_mem; int iterator_size = paramc * sizeof (params[0]); end->is_final = 1; start->is_start = 1; rx_name_nfa_states (&rxb->rx); start_id = start->id; #ifdef RX_DEBUG if (rx_debug_compile) { fputs ("...giving the NFA: \n", stdout); dbug_rxb = rxb; print_nfa (&rxb->rx, rxb->rx.nfa_states, re_seprint, stdout); } #endif if (!rx_eclose_nfa (&rxb->rx)) return REG_ESPACE; else { rx_delete_epsilon_transitions (&rxb->rx); /* For compatability reasons, we need to shove the * compiled nfa into one chunk of malloced memory. */ rxb->rx.reserved = ( sizeof (params[0]) * paramc + rx_sizeof_bitset (rxb->rx.local_cset_size)); #ifdef RX_DEBUG if (rx_debug_compile) { dbug_rxb = rxb; fputs ("...which cooks down (uncompactified) to: \n", stdout); print_nfa (&rxb->rx, rxb->rx.nfa_states, re_seprint, stdout); } #endif if (!rx_compactify_nfa (&rxb->rx, &mem, &size)) return REG_ESPACE; rxb->buffer = mem; rxb->allocated = size; rxb->rx.buffer = mem; rxb->rx.allocated = size; perm_mem = ((char *)rxb->rx.buffer + rxb->rx.allocated - rxb->rx.reserved); rxb->se_params = ((struct re_se_params *)perm_mem); bcopy (params, rxb->se_params, iterator_size); perm_mem += iterator_size; rxb->fastset = (rx_Bitset) perm_mem; rxb->start = rx_id_to_nfa_state (&rxb->rx, start_id); } rx_bitset_null (rxb->rx.local_cset_size, rxb->fastset); rxb->can_match_empty = compute_fastset (rxb, orig_rexp); rxb->match_regs_on_stack = registers_on_stack (rxb, orig_rexp, 0, params); rxb->search_regs_on_stack = registers_on_stack (rxb, fewer_side_effects, 0, params); if (rxb->can_match_empty) rx_bitset_universe (rxb->rx.local_cset_size, rxb->fastset); rxb->is_anchored = is_anchored (orig_rexp, (rx_side_effect) re_se_hat); rxb->begbuf_only = is_anchored (orig_rexp, (rx_side_effect) re_se_begbuf); } rx_free_rexp (&rxb->rx, rexp); if (params) free (params); #ifdef RX_DEBUG if (rx_debug_compile) { dbug_rxb = rxb; fputs ("...which cooks down to: \n", stdout); print_nfa (&rxb->rx, rxb->rx.nfa_states, re_seprint, stdout); } #endif } return REG_NOERROR; } /* This table gives an error message for each of the error codes listed in regex.h. Obviously the order here has to be same as there. */ __const__ char * rx_error_msg[] = { 0, /* REG_NOERROR */ "No match", /* REG_NOMATCH */ "Invalid regular expression", /* REG_BADPAT */ "Invalid collation character", /* REG_ECOLLATE */ "Invalid character class name", /* REG_ECTYPE */ "Trailing backslash", /* REG_EESCAPE */ "Invalid back reference", /* REG_ESUBREG */ "Unmatched [ or [^", /* REG_EBRACK */ "Unmatched ( or \\(", /* REG_EPAREN */ "Unmatched \\{", /* REG_EBRACE */ "Invalid content of \\{\\}", /* REG_BADBR */ "Invalid range end", /* REG_ERANGE */ "Memory exhausted", /* REG_ESPACE */ "Invalid preceding regular expression", /* REG_BADRPT */ "Premature end of regular expression", /* REG_EEND */ "Regular expression too big", /* REG_ESIZE */ "Unmatched ) or \\)", /* REG_ERPAREN */ }; char rx_slowmap [256] = { 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, 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, 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, 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, 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, 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, 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, 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, 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, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, }; #ifdef __STDC__ RX_DECL void rx_blow_up_fastmap (struct re_pattern_buffer * rxb) #else RX_DECL void rx_blow_up_fastmap (rxb) struct re_pattern_buffer * rxb; #endif { int x; for (x = 0; x < 256; ++x) /* &&&& 3.6 % */ rxb->fastmap [x] = !!RX_bitset_member (rxb->fastset, x); rxb->fastmap_accurate = 1; } #if !defined(REGEX_MALLOC) && !defined(__GNUC__) #define RE_SEARCH_2_FN inner_re_search_2 #define RE_S2_QUAL static #else #define RE_SEARCH_2_FN re_search_2 #define RE_S2_QUAL #endif struct re_search_2_closure { __const__ unsigned char * string1; int size1; __const__ unsigned char * string2; int size2; }; static __inline__ enum rx_get_burst_return re_search_2_get_burst (pos, vclosure, stop) struct rx_string_position * pos; void * vclosure; int stop; { struct re_search_2_closure * closure; closure = (struct re_search_2_closure *)vclosure; if (!closure->string2) { int inset; inset = pos->pos - pos->string; if ((inset < -1) || (inset > closure->size1)) return rx_get_burst_no_more; else { pos->pos = (__const__ unsigned char *) closure->string1 + inset; pos->string = (__const__ unsigned char *) closure->string1; pos->size = closure->size1; pos->end = ((__const__ unsigned char *) MIN(closure->string1 + closure->size1, closure->string1 + stop)); pos->offset = 0; return ((pos->pos < pos->end) ? rx_get_burst_ok : rx_get_burst_no_more); } } else if (!closure->string1) { int inset; inset = pos->pos - pos->string; pos->pos = (__const__ unsigned char *) closure->string2 + inset; pos->string = (__const__ unsigned char *) closure->string2; pos->size = closure->size2; pos->end = ((__const__ unsigned char *) MIN(closure->string2 + closure->size2, closure->string2 + stop)); pos->offset = 0; return ((pos->pos < pos->end) ? rx_get_burst_ok : rx_get_burst_no_more); } else { int inset; inset = pos->pos - pos->string + pos->offset; if (inset < closure->size1) { pos->pos = (__const__ unsigned char *) closure->string1 + inset; pos->string = (__const__ unsigned char *) closure->string1; pos->size = closure->size1; pos->end = ((__const__ unsigned char *) MIN(closure->string1 + closure->size1, closure->string1 + stop)); pos->offset = 0; return rx_get_burst_ok; } else { pos->pos = ((__const__ unsigned char *) closure->string2 + inset - closure->size1); pos->string = (__const__ unsigned char *) closure->string2; pos->size = closure->size2; pos->end = ((__const__ unsigned char *) MIN(closure->string2 + closure->size2, closure->string2 + stop - closure->size1)); pos->offset = closure->size1; return ((pos->pos < pos->end) ? rx_get_burst_ok : rx_get_burst_no_more); } } } static __inline__ enum rx_back_check_return re_search_2_back_check (pos, lparen, rparen, translate, vclosure, stop) struct rx_string_position * pos; int lparen; int rparen; unsigned char * translate; void * vclosure; int stop; { struct rx_string_position there; struct rx_string_position past; there = *pos; there.pos = there.string + lparen - there.offset; re_search_2_get_burst (&there, vclosure, stop); past = *pos; past.pos = past.string + rparen - there.offset; re_search_2_get_burst (&past, vclosure, stop); ++pos->pos; re_search_2_get_burst (pos, vclosure, stop); while ( (there.pos != past.pos) && (pos->pos != pos->end)) if (TRANSLATE(*there.pos) != TRANSLATE(*pos->pos)) return rx_back_check_fail; else { ++there.pos; ++pos->pos; if (there.pos == there.end) re_search_2_get_burst (&there, vclosure, stop); if (pos->pos == pos->end) re_search_2_get_burst (pos, vclosure, stop); } if (there.pos != past.pos) return rx_back_check_fail; --pos->pos; re_search_2_get_burst (pos, vclosure, stop); return rx_back_check_pass; } static __inline__ int re_search_2_fetch_char (pos, offset, app_closure, stop) struct rx_string_position * pos; int offset; void * app_closure; int stop; { struct re_search_2_closure * closure; closure = (struct re_search_2_closure *)app_closure; if (offset == 0) { if (pos->pos >= pos->string) return *pos->pos; else { if ( (pos->string == closure->string2) && (closure->string1) && (closure->size1)) return closure->string1[closure->size1 - 1]; else return 0; /* sure, why not. */ } } if (pos->pos == pos->end) return *closure->string2; else return pos->pos[1]; } #ifdef __STDC__ RE_S2_QUAL int RE_SEARCH_2_FN (struct re_pattern_buffer *rxb, __const__ char * string1, int size1, __const__ char * string2, int size2, int startpos, int range, struct re_registers *regs, int stop) #else RE_S2_QUAL int RE_SEARCH_2_FN (rxb, string1, size1, string2, size2, startpos, range, regs, stop) struct re_pattern_buffer *rxb; __const__ char * string1; int size1; __const__ char * string2; int size2; int startpos; int range; struct re_registers *regs; int stop; #endif { int answer; struct re_search_2_closure closure; closure.string1 = string1; closure.size1 = size1; closure.string2 = string2; closure.size2 = size2; answer = rx_search (rxb, startpos, range, stop, size1 + size2, re_search_2_get_burst, re_search_2_back_check, re_search_2_fetch_char, (void *)&closure, regs, 0, 0); switch (answer) { case rx_search_continuation: abort (); case rx_search_error: return -2; case rx_search_soft_fail: case rx_search_fail: return -1; default: return answer; } } /* Export rx_search to callers outside this file. */ int re_rx_search (rxb, startpos, range, stop, total_size, get_burst, back_check, fetch_char, app_closure, regs, resume_state, save_state) struct re_pattern_buffer * rxb; int startpos; int range; int stop; int total_size; rx_get_burst_fn get_burst; rx_back_check_fn back_check; rx_fetch_char_fn fetch_char; void * app_closure; struct re_registers * regs; struct rx_search_state * resume_state; struct rx_search_state * save_state; { return rx_search (rxb, startpos, range, stop, total_size, get_burst, back_check, fetch_char, app_closure, regs, resume_state, save_state); } #if !defined(REGEX_MALLOC) && !defined(__GNUC__) #ifdef __STDC__ int re_search_2 (struct re_pattern_buffer *rxb, __const__ char * string1, int size1, __const__ char * string2, int size2, int startpos, int range, struct re_registers *regs, int stop) #else int re_search_2 (rxb, string1, size1, string2, size2, startpos, range, regs, stop) struct re_pattern_buffer *rxb; __const__ char * string1; int size1; __const__ char * string2; int size2; int startpos; int range; struct re_registers *regs; int stop; #endif { int ret; ret = inner_re_search_2 (rxb, string1, size1, string2, size2, startpos, range, regs, stop); alloca (0); return ret; } #endif /* Like re_search_2, above, but only one string is specified, and * doesn't let you say where to stop matching. */ #ifdef __STDC__ int re_search (struct re_pattern_buffer * rxb, __const__ char *string, int size, int startpos, int range, struct re_registers *regs) #else int re_search (rxb, string, size, startpos, range, regs) struct re_pattern_buffer * rxb; __const__ char * string; int size; int startpos; int range; struct re_registers *regs; #endif { return re_search_2 (rxb, 0, 0, string, size, startpos, range, regs, size); } #ifdef __STDC__ int re_match_2 (struct re_pattern_buffer * rxb, __const__ char * string1, int size1, __const__ char * string2, int size2, int pos, struct re_registers *regs, int stop) #else int re_match_2 (rxb, string1, size1, string2, size2, pos, regs, stop) struct re_pattern_buffer * rxb; __const__ char * string1; int size1; __const__ char * string2; int size2; int pos; struct re_registers *regs; int stop; #endif { struct re_registers some_regs; regoff_t start; regoff_t end; int srch; int save = rxb->regs_allocated; struct re_registers * regs_to_pass = regs; if (!regs) { some_regs.start = &start; some_regs.end = &end; some_regs.num_regs = 1; regs_to_pass = &some_regs; rxb->regs_allocated = REGS_FIXED; } srch = re_search_2 (rxb, string1, size1, string2, size2, pos, 1, regs_to_pass, stop); if (regs_to_pass != regs) rxb->regs_allocated = save; if (srch < 0) return srch; return regs_to_pass->end[0] - regs_to_pass->start[0]; } /* re_match is like re_match_2 except it takes only a single string. */ #ifdef __STDC__ int re_match (struct re_pattern_buffer * rxb, __const__ char * string, int size, int pos, struct re_registers *regs) #else int re_match (rxb, string, size, pos, regs) struct re_pattern_buffer * rxb; __const__ char *string; int size; int pos; struct re_registers *regs; #endif { return re_match_2 (rxb, string, size, 0, 0, pos, regs, size); } /* Set by `re_set_syntax' to the current regexp syntax to recognize. Can also be assigned to arbitrarily: each pattern buffer stores its own syntax, so it can be changed between regex compilations. */ reg_syntax_t re_syntax_options = RE_SYNTAX_EMACS; /* Specify the precise syntax of regexps for compilation. This provides for compatibility for various utilities which historically have different, incompatible syntaxes. The argument SYNTAX is a bit mask comprised of the various bits defined in regex.h. We return the old syntax. */ #ifdef __STDC__ reg_syntax_t re_set_syntax (reg_syntax_t syntax) #else reg_syntax_t re_set_syntax (syntax) reg_syntax_t syntax; #endif { reg_syntax_t ret = re_syntax_options; re_syntax_options = syntax; return ret; } /* Set REGS to hold NUM_REGS registers, storing them in STARTS and ENDS. Subsequent matches using PATTERN_BUFFER and REGS will use this memory for recording register information. STARTS and ENDS must be allocated using the malloc library routine, and must each be at least NUM_REGS * sizeof (regoff_t) bytes long. If NUM_REGS == 0, then subsequent matches should allocate their own register data. Unless this function is called, the first search or match using PATTERN_BUFFER will allocate its own register data, without freeing the old data. */ #ifdef __STDC__ void re_set_registers (struct re_pattern_buffer *bufp, struct re_registers *regs, unsigned num_regs, regoff_t * starts, regoff_t * ends) #else void re_set_registers (bufp, regs, num_regs, starts, ends) struct re_pattern_buffer *bufp; struct re_registers *regs; unsigned num_regs; regoff_t * starts; regoff_t * ends; #endif { if (num_regs) { bufp->regs_allocated = REGS_REALLOCATE; regs->num_regs = num_regs; regs->start = starts; regs->end = ends; } else { bufp->regs_allocated = REGS_UNALLOCATED; regs->num_regs = 0; regs->start = regs->end = (regoff_t) 0; } } #ifdef __STDC__ static int cplx_se_sublist_len (struct rx_se_list * list) #else static int cplx_se_sublist_len (list) struct rx_se_list * list; #endif { int x = 0; while (list) { if ((long)list->car >= 0) ++x; list = list->cdr; } return x; } /* For rx->se_list_cmp */ #ifdef __STDC__ static int posix_se_list_order (struct rx * rx, struct rx_se_list * a, struct rx_se_list * b) #else static int posix_se_list_order (rx, a, b) struct rx * rx; struct rx_se_list * a; struct rx_se_list * b; #endif { int al = cplx_se_sublist_len (a); int bl = cplx_se_sublist_len (b); if (!al && !bl) return ((a == b) ? 0 : ((a < b) ? -1 : 1)); else if (!al) return -1; else if (!bl) return 1; else { rx_side_effect * av = ((rx_side_effect *) alloca (sizeof (rx_side_effect) * (al + 1))); rx_side_effect * bv = ((rx_side_effect *) alloca (sizeof (rx_side_effect) * (bl + 1))); struct rx_se_list * ap = a; struct rx_se_list * bp = b; int ai, bi; for (ai = al - 1; ai >= 0; --ai) { while ((long)ap->car < 0) ap = ap->cdr; av[ai] = ap->car; ap = ap->cdr; } av[al] = (rx_side_effect)-2; for (bi = bl - 1; bi >= 0; --bi) { while ((long)bp->car < 0) bp = bp->cdr; bv[bi] = bp->car; bp = bp->cdr; } bv[bl] = (rx_side_effect)-1; { int ret; int x = 0; while (av[x] == bv[x]) ++x; ret = (((unsigned *)(av[x]) < (unsigned *)(bv[x])) ? -1 : 1); return ret; } } } /* re_compile_pattern is the GNU regular expression compiler: it compiles PATTERN (of length SIZE) and puts the result in RXB. Returns 0 if the pattern was valid, otherwise an error string. Assumes the `allocated' (and perhaps `buffer') and `translate' fields are set in RXB on entry. We call rx_compile to do the actual compilation. */ #ifdef __STDC__ __const__ char * re_compile_pattern (__const__ char *pattern, int length, struct re_pattern_buffer * rxb) #else __const__ char * re_compile_pattern (pattern, length, rxb) __const__ char *pattern; int length; struct re_pattern_buffer * rxb; #endif { reg_errcode_t ret; /* GNU code is written to assume at least RE_NREGS registers will be set (and at least one extra will be -1). */ rxb->regs_allocated = REGS_UNALLOCATED; /* And GNU code determines whether or not to get register information by passing null for the REGS argument to re_match, etc., not by setting no_sub. */ rxb->no_sub = 0; rxb->rx.local_cset_size = 256; /* Match anchors at newline. */ rxb->newline_anchor = 1; rxb->re_nsub = 0; rxb->start = 0; rxb->se_params = 0; rxb->rx.nodec = 0; rxb->rx.epsnodec = 0; rxb->rx.instruction_table = 0; rxb->rx.nfa_states = 0; rxb->rx.se_list_cmp = posix_se_list_order; rxb->rx.start_set = 0; ret = rx_compile (pattern, length, re_syntax_options, rxb); alloca (0); return rx_error_msg[(int) ret]; } #ifdef __STDC__ int re_compile_fastmap (struct re_pattern_buffer * rxb) #else int re_compile_fastmap (rxb) struct re_pattern_buffer * rxb; #endif { rx_blow_up_fastmap (rxb); return 0; } /* Entry points compatible with 4.2 BSD regex library. We don't define them if this is an Emacs or POSIX compilation. */ #if (!defined (emacs) && !defined (_POSIX_SOURCE)) || defined(USE_BSD_REGEX) /* BSD has one and only one pattern buffer. */ static struct re_pattern_buffer rx_comp_buf; #ifdef __STDC__ char * re_comp (__const__ char *s) #else char * re_comp (s) __const__ char *s; #endif { reg_errcode_t ret; if (!s || (*s == '\0')) { if (!rx_comp_buf.buffer) return "No previous regular expression"; return 0; } if (!rx_comp_buf.fastmap) { rx_comp_buf.fastmap = (char *) malloc (1 << CHARBITS); if (!rx_comp_buf.fastmap) return "Memory exhausted"; } /* Since `rx_exec' always passes NULL for the `regs' argument, we don't need to initialize the pattern buffer fields which affect it. */ /* Match anchors at newlines. */ rx_comp_buf.newline_anchor = 1; rx_comp_buf.fastmap_accurate = 0; rx_comp_buf.re_nsub = 0; rx_comp_buf.start = 0; rx_comp_buf.se_params = 0; rx_comp_buf.rx.nodec = 0; rx_comp_buf.rx.epsnodec = 0; rx_comp_buf.rx.instruction_table = 0; rx_comp_buf.rx.nfa_states = 0; rx_comp_buf.rx.start = 0; rx_comp_buf.rx.se_list_cmp = posix_se_list_order; rx_comp_buf.rx.start_set = 0; rx_comp_buf.rx.local_cset_size = 256; ret = rx_compile (s, strlen (s), re_syntax_options, &rx_comp_buf); alloca (0); /* Yes, we're discarding `__const__' here. */ return (char *) rx_error_msg[(int) ret]; } #ifdef __STDC__ int re_exec (__const__ char *s) #else int re_exec (s) __const__ char *s; #endif { __const__ int len = strlen (s); return 0 <= re_search (&rx_comp_buf, s, len, 0, len, (struct re_registers *) 0); } #endif /* not emacs and not _POSIX_SOURCE */ /* POSIX.2 functions. Don't define these for Emacs. */ #if !defined(emacs) /* regcomp takes a regular expression as a string and compiles it. PREG is a regex_t *. We do not expect any fields to be initialized, since POSIX says we shouldn't. Thus, we set `buffer' to the compiled pattern; `used' to the length of the compiled pattern; `syntax' to RE_SYNTAX_POSIX_EXTENDED if the REG_EXTENDED bit in CFLAGS is set; otherwise, to RE_SYNTAX_POSIX_BASIC; `newline_anchor' to REG_NEWLINE being set in CFLAGS; `fastmap' and `fastmap_accurate' to zero; `re_nsub' to the number of subexpressions in PATTERN. PATTERN is the address of the pattern string. CFLAGS is a series of bits which affect compilation. If REG_EXTENDED is set, we use POSIX extended syntax; otherwise, we use POSIX basic syntax. If REG_NEWLINE is set, then . and [^...] don't match newline. Also, regexec will try a match beginning after every newline. If REG_ICASE is set, then we considers upper- and lowercase versions of letters to be equivalent when matching. If REG_NOSUB is set, then when PREG is passed to regexec, that routine will report only success or failure, and nothing about the registers. It returns 0 if it succeeds, nonzero if it doesn't. (See regex.h for the return codes and their meanings.) */ #ifdef __STDC__ int regcomp (regex_t * preg, __const__ char * pattern, int cflags) #else int regcomp (preg, pattern, cflags) regex_t * preg; __const__ char * pattern; int cflags; #endif { reg_errcode_t ret; unsigned syntax = cflags & REG_EXTENDED ? RE_SYNTAX_POSIX_EXTENDED : RE_SYNTAX_POSIX_BASIC; /* regex_compile will allocate the space for the compiled pattern. */ preg->buffer = 0; preg->allocated = 0; preg->fastmap = malloc (256); if (!preg->fastmap) return REG_ESPACE; preg->fastmap_accurate = 0; if (cflags & REG_ICASE) { unsigned i; preg->translate = (unsigned char *) malloc (256); if (!preg->translate) return (int) REG_ESPACE; /* Map uppercase characters to corresponding lowercase ones. */ for (i = 0; i < CHAR_SET_SIZE; i++) preg->translate[i] = isupper (i) ? tolower (i) : i; } else preg->translate = 0; /* If REG_NEWLINE is set, newlines are treated differently. */ if (cflags & REG_NEWLINE) { /* REG_NEWLINE implies neither . nor [^...] match newline. */ syntax &= ~RE_DOT_NEWLINE; syntax |= RE_HAT_LISTS_NOT_NEWLINE; /* It also changes the matching behavior. */ preg->newline_anchor = 1; } else preg->newline_anchor = 0; preg->no_sub = !!(cflags & REG_NOSUB); /* POSIX says a null character in the pattern terminates it, so we can use strlen here in compiling the pattern. */ preg->re_nsub = 0; preg->start = 0; preg->se_params = 0; preg->syntax_parens = 0; preg->rx.nodec = 0; preg->rx.epsnodec = 0; preg->rx.instruction_table = 0; preg->rx.nfa_states = 0; preg->rx.local_cset_size = 256; preg->rx.start = 0; preg->rx.se_list_cmp = posix_se_list_order; preg->rx.start_set = 0; ret = rx_compile (pattern, strlen (pattern), syntax, preg); alloca (0); /* POSIX doesn't distinguish between an unmatched open-group and an unmatched close-group: both are REG_EPAREN. */ if (ret == REG_ERPAREN) ret = REG_EPAREN; return (int) ret; } /* regexec searches for a given pattern, specified by PREG, in the string STRING. If NMATCH is zero or REG_NOSUB was set in the cflags argument to `regcomp', we ignore PMATCH. Otherwise, we assume PMATCH has at least NMATCH elements, and we set them to the offsets of the corresponding matched substrings. EFLAGS specifies `execution flags' which affect matching: if REG_NOTBOL is set, then ^ does not match at the beginning of the string; if REG_NOTEOL is set, then $ does not match at the end. We return 0 if we find a match and REG_NOMATCH if not. */ #ifdef __STDC__ int regexec (__const__ regex_t *preg, __const__ char *string, size_t nmatch, regmatch_t pmatch[], int eflags) #else int regexec (preg, string, nmatch, pmatch, eflags) __const__ regex_t *preg; __const__ char *string; size_t nmatch; regmatch_t pmatch[]; int eflags; #endif { int ret; struct re_registers regs; regex_t private_preg; int len = strlen (string); boolean want_reg_info = !preg->no_sub && nmatch > 0; private_preg = *preg; private_preg.not_bol = !!(eflags & REG_NOTBOL); private_preg.not_eol = !!(eflags & REG_NOTEOL); /* The user has told us exactly how many registers to return * information about, via `nmatch'. We have to pass that on to the * matching routines. */ private_preg.regs_allocated = REGS_FIXED; if (want_reg_info) { regs.num_regs = nmatch; regs.start = (( regoff_t *) malloc ((nmatch) * sizeof ( regoff_t))); regs.end = (( regoff_t *) malloc ((nmatch) * sizeof ( regoff_t))); if (regs.start == 0 || regs.end == 0) return (int) REG_NOMATCH; } /* Perform the searching operation. */ ret = re_search (&private_preg, string, len, /* start: */ 0, /* range: */ len, want_reg_info ? ®s : (struct re_registers *) 0); /* Copy the register information to the POSIX structure. */ if (want_reg_info) { if (ret >= 0) { unsigned r; for (r = 0; r < nmatch; r++) { pmatch[r].rm_so = regs.start[r]; pmatch[r].rm_eo = regs.end[r]; } } /* If we needed the temporary register info, free the space now. */ free (regs.start); free (regs.end); } /* We want zero return to mean success, unlike `re_search'. */ return ret >= 0 ? (int) REG_NOERROR : (int) REG_NOMATCH; } /* Returns a message corresponding to an error code, ERRCODE, returned from either regcomp or regexec. */ #ifdef __STDC__ size_t regerror (int errcode, __const__ regex_t *preg, char *errbuf, size_t errbuf_size) #else size_t regerror (errcode, preg, errbuf, errbuf_size) int errcode; __const__ regex_t *preg; char *errbuf; size_t errbuf_size; #endif { __const__ char *msg = rx_error_msg[errcode] == 0 ? "Success" : rx_error_msg[errcode]; size_t msg_size = strlen (msg) + 1; /* Includes the 0. */ if (errbuf_size != 0) { if (msg_size > errbuf_size) { strncpy (errbuf, msg, errbuf_size - 1); errbuf[errbuf_size - 1] = 0; } else strcpy (errbuf, msg); } return msg_size; } /* Free dynamically allocated space used by PREG. */ #ifdef __STDC__ void regfree (regex_t *preg) #else void regfree (preg) regex_t *preg; #endif { if (preg->buffer != 0) free (preg->buffer); preg->buffer = 0; preg->allocated = 0; if (preg->fastmap != 0) free (preg->fastmap); preg->fastmap = 0; preg->fastmap_accurate = 0; if (preg->translate != 0) free (preg->translate); preg->translate = 0; } #endif /* not emacs */