diff options
Diffstat (limited to 'libc-top-half/musl/src/regex/regcomp.c')
-rw-r--r-- | libc-top-half/musl/src/regex/regcomp.c | 2953 |
1 files changed, 2953 insertions, 0 deletions
diff --git a/libc-top-half/musl/src/regex/regcomp.c b/libc-top-half/musl/src/regex/regcomp.c new file mode 100644 index 0000000..fb24556 --- /dev/null +++ b/libc-top-half/musl/src/regex/regcomp.c @@ -0,0 +1,2953 @@ +/* + regcomp.c - TRE POSIX compatible regex compilation functions. + + Copyright (c) 2001-2009 Ville Laurikari <vl@iki.fi> + All rights reserved. + + Redistribution and use in source and binary forms, with or without + modification, are permitted provided that the following conditions + are met: + + 1. Redistributions of source code must retain the above copyright + notice, this list of conditions and the following disclaimer. + + 2. Redistributions in binary form must reproduce the above copyright + notice, this list of conditions and the following disclaimer in the + documentation and/or other materials provided with the distribution. + + THIS SOFTWARE IS PROVIDED BY THE COPYRIGHT HOLDER AND CONTRIBUTORS + ``AS IS'' AND ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT + LIMITED TO, THE IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR + A PARTICULAR PURPOSE ARE DISCLAIMED. IN NO EVENT SHALL THE COPYRIGHT + HOLDER OR CONTRIBUTORS BE LIABLE FOR ANY DIRECT, INDIRECT, INCIDENTAL, + SPECIAL, EXEMPLARY, OR CONSEQUENTIAL DAMAGES (INCLUDING, BUT NOT + LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES; LOSS OF USE, + DATA, OR PROFITS; OR BUSINESS INTERRUPTION) HOWEVER CAUSED AND ON ANY + THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT LIABILITY, OR TORT + (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY OUT OF THE USE + OF THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF SUCH DAMAGE. + +*/ + +#include <string.h> +#include <stdlib.h> +#include <regex.h> +#include <limits.h> +#include <stdint.h> +#include <ctype.h> + +#include "tre.h" + +#include <assert.h> + +/*********************************************************************** + from tre-compile.h +***********************************************************************/ + +typedef struct { + int position; + int code_min; + int code_max; + int *tags; + int assertions; + tre_ctype_t class; + tre_ctype_t *neg_classes; + int backref; +} tre_pos_and_tags_t; + + +/*********************************************************************** + from tre-ast.c and tre-ast.h +***********************************************************************/ + +/* The different AST node types. */ +typedef enum { + LITERAL, + CATENATION, + ITERATION, + UNION +} tre_ast_type_t; + +/* Special subtypes of TRE_LITERAL. */ +#define EMPTY -1 /* Empty leaf (denotes empty string). */ +#define ASSERTION -2 /* Assertion leaf. */ +#define TAG -3 /* Tag leaf. */ +#define BACKREF -4 /* Back reference leaf. */ + +#define IS_SPECIAL(x) ((x)->code_min < 0) +#define IS_EMPTY(x) ((x)->code_min == EMPTY) +#define IS_ASSERTION(x) ((x)->code_min == ASSERTION) +#define IS_TAG(x) ((x)->code_min == TAG) +#define IS_BACKREF(x) ((x)->code_min == BACKREF) + + +/* A generic AST node. All AST nodes consist of this node on the top + level with `obj' pointing to the actual content. */ +typedef struct { + tre_ast_type_t type; /* Type of the node. */ + void *obj; /* Pointer to actual node. */ + int nullable; + int submatch_id; + int num_submatches; + int num_tags; + tre_pos_and_tags_t *firstpos; + tre_pos_and_tags_t *lastpos; +} tre_ast_node_t; + + +/* A "literal" node. These are created for assertions, back references, + tags, matching parameter settings, and all expressions that match one + character. */ +typedef struct { + long code_min; + long code_max; + int position; + tre_ctype_t class; + tre_ctype_t *neg_classes; +} tre_literal_t; + +/* A "catenation" node. These are created when two regexps are concatenated. + If there are more than one subexpressions in sequence, the `left' part + holds all but the last, and `right' part holds the last subexpression + (catenation is left associative). */ +typedef struct { + tre_ast_node_t *left; + tre_ast_node_t *right; +} tre_catenation_t; + +/* An "iteration" node. These are created for the "*", "+", "?", and "{m,n}" + operators. */ +typedef struct { + /* Subexpression to match. */ + tre_ast_node_t *arg; + /* Minimum number of consecutive matches. */ + int min; + /* Maximum number of consecutive matches. */ + int max; + /* If 0, match as many characters as possible, if 1 match as few as + possible. Note that this does not always mean the same thing as + matching as many/few repetitions as possible. */ + unsigned int minimal:1; +} tre_iteration_t; + +/* An "union" node. These are created for the "|" operator. */ +typedef struct { + tre_ast_node_t *left; + tre_ast_node_t *right; +} tre_union_t; + + +static tre_ast_node_t * +tre_ast_new_node(tre_mem_t mem, int type, void *obj) +{ + tre_ast_node_t *node = tre_mem_calloc(mem, sizeof *node); + if (!node || !obj) + return 0; + node->obj = obj; + node->type = type; + node->nullable = -1; + node->submatch_id = -1; + return node; +} + +static tre_ast_node_t * +tre_ast_new_literal(tre_mem_t mem, int code_min, int code_max, int position) +{ + tre_ast_node_t *node; + tre_literal_t *lit; + + lit = tre_mem_calloc(mem, sizeof *lit); + node = tre_ast_new_node(mem, LITERAL, lit); + if (!node) + return 0; + lit->code_min = code_min; + lit->code_max = code_max; + lit->position = position; + return node; +} + +static tre_ast_node_t * +tre_ast_new_iter(tre_mem_t mem, tre_ast_node_t *arg, int min, int max, int minimal) +{ + tre_ast_node_t *node; + tre_iteration_t *iter; + + iter = tre_mem_calloc(mem, sizeof *iter); + node = tre_ast_new_node(mem, ITERATION, iter); + if (!node) + return 0; + iter->arg = arg; + iter->min = min; + iter->max = max; + iter->minimal = minimal; + node->num_submatches = arg->num_submatches; + return node; +} + +static tre_ast_node_t * +tre_ast_new_union(tre_mem_t mem, tre_ast_node_t *left, tre_ast_node_t *right) +{ + tre_ast_node_t *node; + tre_union_t *un; + + if (!left) + return right; + un = tre_mem_calloc(mem, sizeof *un); + node = tre_ast_new_node(mem, UNION, un); + if (!node || !right) + return 0; + un->left = left; + un->right = right; + node->num_submatches = left->num_submatches + right->num_submatches; + return node; +} + +static tre_ast_node_t * +tre_ast_new_catenation(tre_mem_t mem, tre_ast_node_t *left, tre_ast_node_t *right) +{ + tre_ast_node_t *node; + tre_catenation_t *cat; + + if (!left) + return right; + cat = tre_mem_calloc(mem, sizeof *cat); + node = tre_ast_new_node(mem, CATENATION, cat); + if (!node) + return 0; + cat->left = left; + cat->right = right; + node->num_submatches = left->num_submatches + right->num_submatches; + return node; +} + + +/*********************************************************************** + from tre-stack.c and tre-stack.h +***********************************************************************/ + +typedef struct tre_stack_rec tre_stack_t; + +/* Creates a new stack object. `size' is initial size in bytes, `max_size' + is maximum size, and `increment' specifies how much more space will be + allocated with realloc() if all space gets used up. Returns the stack + object or NULL if out of memory. */ +static tre_stack_t * +tre_stack_new(int size, int max_size, int increment); + +/* Frees the stack object. */ +static void +tre_stack_destroy(tre_stack_t *s); + +/* Returns the current number of objects in the stack. */ +static int +tre_stack_num_objects(tre_stack_t *s); + +/* Each tre_stack_push_*(tre_stack_t *s, <type> value) function pushes + `value' on top of stack `s'. Returns REG_ESPACE if out of memory. + This tries to realloc() more space before failing if maximum size + has not yet been reached. Returns REG_OK if successful. */ +#define declare_pushf(typetag, type) \ + static reg_errcode_t tre_stack_push_ ## typetag(tre_stack_t *s, type value) + +declare_pushf(voidptr, void *); +declare_pushf(int, int); + +/* Each tre_stack_pop_*(tre_stack_t *s) function pops the topmost + element off of stack `s' and returns it. The stack must not be + empty. */ +#define declare_popf(typetag, type) \ + static type tre_stack_pop_ ## typetag(tre_stack_t *s) + +declare_popf(voidptr, void *); +declare_popf(int, int); + +/* Just to save some typing. */ +#define STACK_PUSH(s, typetag, value) \ + do \ + { \ + status = tre_stack_push_ ## typetag(s, value); \ + } \ + while (/*CONSTCOND*/0) + +#define STACK_PUSHX(s, typetag, value) \ + { \ + status = tre_stack_push_ ## typetag(s, value); \ + if (status != REG_OK) \ + break; \ + } + +#define STACK_PUSHR(s, typetag, value) \ + { \ + reg_errcode_t _status; \ + _status = tre_stack_push_ ## typetag(s, value); \ + if (_status != REG_OK) \ + return _status; \ + } + +union tre_stack_item { + void *voidptr_value; + int int_value; +}; + +struct tre_stack_rec { + int size; + int max_size; + int increment; + int ptr; + union tre_stack_item *stack; +}; + + +static tre_stack_t * +tre_stack_new(int size, int max_size, int increment) +{ + tre_stack_t *s; + + s = xmalloc(sizeof(*s)); + if (s != NULL) + { + s->stack = xmalloc(sizeof(*s->stack) * size); + if (s->stack == NULL) + { + xfree(s); + return NULL; + } + s->size = size; + s->max_size = max_size; + s->increment = increment; + s->ptr = 0; + } + return s; +} + +static void +tre_stack_destroy(tre_stack_t *s) +{ + xfree(s->stack); + xfree(s); +} + +static int +tre_stack_num_objects(tre_stack_t *s) +{ + return s->ptr; +} + +static reg_errcode_t +tre_stack_push(tre_stack_t *s, union tre_stack_item value) +{ + if (s->ptr < s->size) + { + s->stack[s->ptr] = value; + s->ptr++; + } + else + { + if (s->size >= s->max_size) + { + return REG_ESPACE; + } + else + { + union tre_stack_item *new_buffer; + int new_size; + new_size = s->size + s->increment; + if (new_size > s->max_size) + new_size = s->max_size; + new_buffer = xrealloc(s->stack, sizeof(*new_buffer) * new_size); + if (new_buffer == NULL) + { + return REG_ESPACE; + } + assert(new_size > s->size); + s->size = new_size; + s->stack = new_buffer; + tre_stack_push(s, value); + } + } + return REG_OK; +} + +#define define_pushf(typetag, type) \ + declare_pushf(typetag, type) { \ + union tre_stack_item item; \ + item.typetag ## _value = value; \ + return tre_stack_push(s, item); \ +} + +define_pushf(int, int) +define_pushf(voidptr, void *) + +#define define_popf(typetag, type) \ + declare_popf(typetag, type) { \ + return s->stack[--s->ptr].typetag ## _value; \ + } + +define_popf(int, int) +define_popf(voidptr, void *) + + +/*********************************************************************** + from tre-parse.c and tre-parse.h +***********************************************************************/ + +/* Parse context. */ +typedef struct { + /* Memory allocator. The AST is allocated using this. */ + tre_mem_t mem; + /* Stack used for keeping track of regexp syntax. */ + tre_stack_t *stack; + /* The parsed node after a parse function returns. */ + tre_ast_node_t *n; + /* Position in the regexp pattern after a parse function returns. */ + const char *s; + /* The first character of the last subexpression parsed. */ + const char *start; + /* Current submatch ID. */ + int submatch_id; + /* Current position (number of literal). */ + int position; + /* The highest back reference or -1 if none seen so far. */ + int max_backref; + /* Compilation flags. */ + int cflags; +} tre_parse_ctx_t; + +/* Some macros for expanding \w, \s, etc. */ +static const struct { + char c; + const char *expansion; +} tre_macros[] = { + {'t', "\t"}, {'n', "\n"}, {'r', "\r"}, + {'f', "\f"}, {'a', "\a"}, {'e', "\033"}, + {'w', "[[:alnum:]_]"}, {'W', "[^[:alnum:]_]"}, {'s', "[[:space:]]"}, + {'S', "[^[:space:]]"}, {'d', "[[:digit:]]"}, {'D', "[^[:digit:]]"}, + { 0, 0 } +}; + +/* Expands a macro delimited by `regex' and `regex_end' to `buf', which + must have at least `len' items. Sets buf[0] to zero if the there + is no match in `tre_macros'. */ +static const char *tre_expand_macro(const char *s) +{ + int i; + for (i = 0; tre_macros[i].c && tre_macros[i].c != *s; i++); + return tre_macros[i].expansion; +} + +static int +tre_compare_lit(const void *a, const void *b) +{ + const tre_literal_t *const *la = a; + const tre_literal_t *const *lb = b; + /* assumes the range of valid code_min is < INT_MAX */ + return la[0]->code_min - lb[0]->code_min; +} + +struct literals { + tre_mem_t mem; + tre_literal_t **a; + int len; + int cap; +}; + +static tre_literal_t *tre_new_lit(struct literals *p) +{ + tre_literal_t **a; + if (p->len >= p->cap) { + if (p->cap >= 1<<15) + return 0; + p->cap *= 2; + a = xrealloc(p->a, p->cap * sizeof *p->a); + if (!a) + return 0; + p->a = a; + } + a = p->a + p->len++; + *a = tre_mem_calloc(p->mem, sizeof **a); + return *a; +} + +static int add_icase_literals(struct literals *ls, int min, int max) +{ + tre_literal_t *lit; + int b, e, c; + for (c=min; c<=max; ) { + /* assumes islower(c) and isupper(c) are exclusive + and toupper(c)!=c if islower(c). + multiple opposite case characters are not supported */ + if (tre_islower(c)) { + b = e = tre_toupper(c); + for (c++, e++; c<=max; c++, e++) + if (tre_toupper(c) != e) break; + } else if (tre_isupper(c)) { + b = e = tre_tolower(c); + for (c++, e++; c<=max; c++, e++) + if (tre_tolower(c) != e) break; + } else { + c++; + continue; + } + lit = tre_new_lit(ls); + if (!lit) + return -1; + lit->code_min = b; + lit->code_max = e-1; + lit->position = -1; + } + return 0; +} + + +/* Maximum number of character classes in a negated bracket expression. */ +#define MAX_NEG_CLASSES 64 + +struct neg { + int negate; + int len; + tre_ctype_t a[MAX_NEG_CLASSES]; +}; + +// TODO: parse bracket into a set of non-overlapping [lo,hi] ranges + +/* +bracket grammar: +Bracket = '[' List ']' | '[^' List ']' +List = Term | List Term +Term = Char | Range | Chclass | Eqclass +Range = Char '-' Char | Char '-' '-' +Char = Coll | coll_single +Meta = ']' | '-' +Coll = '[.' coll_single '.]' | '[.' coll_multi '.]' | '[.' Meta '.]' +Eqclass = '[=' coll_single '=]' | '[=' coll_multi '=]' +Chclass = '[:' class ':]' + +coll_single is a single char collating element but it can be + '-' only at the beginning or end of a List and + ']' only at the beginning of a List and + '^' anywhere except after the openning '[' +*/ + +static reg_errcode_t parse_bracket_terms(tre_parse_ctx_t *ctx, const char *s, struct literals *ls, struct neg *neg) +{ + const char *start = s; + tre_ctype_t class; + int min, max; + wchar_t wc; + int len; + + for (;;) { + class = 0; + len = mbtowc(&wc, s, -1); + if (len <= 0) + return *s ? REG_BADPAT : REG_EBRACK; + if (*s == ']' && s != start) { + ctx->s = s+1; + return REG_OK; + } + if (*s == '-' && s != start && s[1] != ']' && + /* extension: [a-z--@] is accepted as [a-z]|[--@] */ + (s[1] != '-' || s[2] == ']')) + return REG_ERANGE; + if (*s == '[' && (s[1] == '.' || s[1] == '=')) + /* collating symbols and equivalence classes are not supported */ + return REG_ECOLLATE; + if (*s == '[' && s[1] == ':') { + char tmp[CHARCLASS_NAME_MAX+1]; + s += 2; + for (len=0; len < CHARCLASS_NAME_MAX && s[len]; len++) { + if (s[len] == ':') { + memcpy(tmp, s, len); + tmp[len] = 0; + class = tre_ctype(tmp); + break; + } + } + if (!class || s[len+1] != ']') + return REG_ECTYPE; + min = 0; + max = TRE_CHAR_MAX; + s += len+2; + } else { + min = max = wc; + s += len; + if (*s == '-' && s[1] != ']') { + s++; + len = mbtowc(&wc, s, -1); + max = wc; + /* XXX - Should use collation order instead of + encoding values in character ranges. */ + if (len <= 0 || min > max) + return REG_ERANGE; + s += len; + } + } + + if (class && neg->negate) { + if (neg->len >= MAX_NEG_CLASSES) + return REG_ESPACE; + neg->a[neg->len++] = class; + } else { + tre_literal_t *lit = tre_new_lit(ls); + if (!lit) + return REG_ESPACE; + lit->code_min = min; + lit->code_max = max; + lit->class = class; + lit->position = -1; + + /* Add opposite-case codepoints if REG_ICASE is present. + It seems that POSIX requires that bracket negation + should happen before case-folding, but most practical + implementations do it the other way around. Changing + the order would need efficient representation of + case-fold ranges and bracket range sets even with + simple patterns so this is ok for now. */ + if (ctx->cflags & REG_ICASE && !class) + if (add_icase_literals(ls, min, max)) + return REG_ESPACE; + } + } +} + +static reg_errcode_t parse_bracket(tre_parse_ctx_t *ctx, const char *s) +{ + int i, max, min, negmax, negmin; + tre_ast_node_t *node = 0, *n; + tre_ctype_t *nc = 0; + tre_literal_t *lit; + struct literals ls; + struct neg neg; + reg_errcode_t err; + + ls.mem = ctx->mem; + ls.len = 0; + ls.cap = 32; + ls.a = xmalloc(ls.cap * sizeof *ls.a); + if (!ls.a) + return REG_ESPACE; + neg.len = 0; + neg.negate = *s == '^'; + if (neg.negate) + s++; + + err = parse_bracket_terms(ctx, s, &ls, &neg); + if (err != REG_OK) + goto parse_bracket_done; + + if (neg.negate) { + /* + * With REG_NEWLINE, POSIX requires that newlines are not matched by + * any form of a non-matching list. + */ + if (ctx->cflags & REG_NEWLINE) { + lit = tre_new_lit(&ls); + if (!lit) { + err = REG_ESPACE; + goto parse_bracket_done; + } + lit->code_min = '\n'; + lit->code_max = '\n'; + lit->position = -1; + } + /* Sort the array if we need to negate it. */ + qsort(ls.a, ls.len, sizeof *ls.a, tre_compare_lit); + /* extra lit for the last negated range */ + lit = tre_new_lit(&ls); + if (!lit) { + err = REG_ESPACE; + goto parse_bracket_done; + } + lit->code_min = TRE_CHAR_MAX+1; + lit->code_max = TRE_CHAR_MAX+1; + lit->position = -1; + /* negated classes */ + if (neg.len) { + nc = tre_mem_alloc(ctx->mem, (neg.len+1)*sizeof *neg.a); + if (!nc) { + err = REG_ESPACE; + goto parse_bracket_done; + } + memcpy(nc, neg.a, neg.len*sizeof *neg.a); + nc[neg.len] = 0; + } + } + + /* Build a union of the items in the array, negated if necessary. */ + negmax = negmin = 0; + for (i = 0; i < ls.len; i++) { + lit = ls.a[i]; + min = lit->code_min; + max = lit->code_max; + if (neg.negate) { + if (min <= negmin) { + /* Overlap. */ + negmin = MAX(max + 1, negmin); + continue; + } + negmax = min - 1; + lit->code_min = negmin; + lit->code_max = negmax; + negmin = max + 1; + } + lit->position = ctx->position; + lit->neg_classes = nc; + n = tre_ast_new_node(ctx->mem, LITERAL, lit); + node = tre_ast_new_union(ctx->mem, node, n); + if (!node) { + err = REG_ESPACE; + break; + } + } + +parse_bracket_done: + xfree(ls.a); + ctx->position++; + ctx->n = node; + return err; +} + +static const char *parse_dup_count(const char *s, int *n) +{ + *n = -1; + if (!isdigit(*s)) + return s; + *n = 0; + for (;;) { + *n = 10 * *n + (*s - '0'); + s++; + if (!isdigit(*s) || *n > RE_DUP_MAX) + break; + } + return s; +} + +static const char *parse_dup(const char *s, int ere, int *pmin, int *pmax) +{ + int min, max; + + s = parse_dup_count(s, &min); + if (*s == ',') + s = parse_dup_count(s+1, &max); + else + max = min; + + if ( + (max < min && max >= 0) || + max > RE_DUP_MAX || + min > RE_DUP_MAX || + min < 0 || + (!ere && *s++ != '\\') || + *s++ != '}' + ) + return 0; + *pmin = min; + *pmax = max; + return s; +} + +static int hexval(unsigned c) +{ + if (c-'0'<10) return c-'0'; + c |= 32; + if (c-'a'<6) return c-'a'+10; + return -1; +} + +static reg_errcode_t marksub(tre_parse_ctx_t *ctx, tre_ast_node_t *node, int subid) +{ + if (node->submatch_id >= 0) { + tre_ast_node_t *n = tre_ast_new_literal(ctx->mem, EMPTY, -1, -1); + if (!n) + return REG_ESPACE; + n = tre_ast_new_catenation(ctx->mem, n, node); + if (!n) + return REG_ESPACE; + n->num_submatches = node->num_submatches; + node = n; + } + node->submatch_id = subid; + node->num_submatches++; + ctx->n = node; + return REG_OK; +} + +/* +BRE grammar: +Regex = Branch | '^' | '$' | '^$' | '^' Branch | Branch '$' | '^' Branch '$' +Branch = Atom | Branch Atom +Atom = char | quoted_char | '.' | Bracket | Atom Dup | '\(' Branch '\)' | back_ref +Dup = '*' | '\{' Count '\}' | '\{' Count ',\}' | '\{' Count ',' Count '\}' + +(leading ^ and trailing $ in a sub expr may be an anchor or literal as well) + +ERE grammar: +Regex = Branch | Regex '|' Branch +Branch = Atom | Branch Atom +Atom = char | quoted_char | '.' | Bracket | Atom Dup | '(' Regex ')' | '^' | '$' +Dup = '*' | '+' | '?' | '{' Count '}' | '{' Count ',}' | '{' Count ',' Count '}' + +(a*+?, ^*, $+, \X, {, (|a) are unspecified) +*/ + +static reg_errcode_t parse_atom(tre_parse_ctx_t *ctx, const char *s) +{ + int len, ere = ctx->cflags & REG_EXTENDED; + const char *p; + tre_ast_node_t *node; + wchar_t wc; + switch (*s) { + case '[': + return parse_bracket(ctx, s+1); + case '\\': + p = tre_expand_macro(s+1); + if (p) { + /* assume \X expansion is a single atom */ + reg_errcode_t err = parse_atom(ctx, p); + ctx->s = s+2; + return err; + } + /* extensions: \b, \B, \<, \>, \xHH \x{HHHH} */ + switch (*++s) { + case 0: + return REG_EESCAPE; + case 'b': + node = tre_ast_new_literal(ctx->mem, ASSERTION, ASSERT_AT_WB, -1); + break; + case 'B': + node = tre_ast_new_literal(ctx->mem, ASSERTION, ASSERT_AT_WB_NEG, -1); + break; + case '<': + node = tre_ast_new_literal(ctx->mem, ASSERTION, ASSERT_AT_BOW, -1); + break; + case '>': + node = tre_ast_new_literal(ctx->mem, ASSERTION, ASSERT_AT_EOW, -1); + break; + case 'x': + s++; + int i, v = 0, c; + len = 2; + if (*s == '{') { + len = 8; + s++; + } + for (i=0; i<len && v<0x110000; i++) { + c = hexval(s[i]); + if (c < 0) break; + v = 16*v + c; + } + s += i; + if (len == 8) { + if (*s != '}') + return REG_EBRACE; + s++; + } + node = tre_ast_new_literal(ctx->mem, v, v, ctx->position++); + s--; + break; + case '{': + case '+': + case '?': + /* extension: treat \+, \? as repetitions in BRE */ + /* reject repetitions after empty expression in BRE */ + if (!ere) + return REG_BADRPT; + case '|': + /* extension: treat \| as alternation in BRE */ + if (!ere) { + node = tre_ast_new_literal(ctx->mem, EMPTY, -1, -1); + s--; + goto end; + } + /* fallthrough */ + default: + if (!ere && (unsigned)*s-'1' < 9) { + /* back reference */ + int val = *s - '0'; + node = tre_ast_new_literal(ctx->mem, BACKREF, val, ctx->position++); + ctx->max_backref = MAX(val, ctx->max_backref); + } else { + /* extension: accept unknown escaped char + as a literal */ + goto parse_literal; + } + } + s++; + break; + case '.': + if (ctx->cflags & REG_NEWLINE) { + tre_ast_node_t *tmp1, *tmp2; + tmp1 = tre_ast_new_literal(ctx->mem, 0, '\n'-1, ctx->position++); + tmp2 = tre_ast_new_literal(ctx->mem, '\n'+1, TRE_CHAR_MAX, ctx->position++); + if (tmp1 && tmp2) + node = tre_ast_new_union(ctx->mem, tmp1, tmp2); + else + node = 0; + } else { + node = tre_ast_new_literal(ctx->mem, 0, TRE_CHAR_MAX, ctx->position++); + } + s++; + break; + case '^': + /* '^' has a special meaning everywhere in EREs, and at beginning of BRE. */ + if (!ere && s != ctx->start) + goto parse_literal; + node = tre_ast_new_literal(ctx->mem, ASSERTION, ASSERT_AT_BOL, -1); + s++; + break; + case '$': + /* '$' is special everywhere in EREs, and at the end of a BRE subexpression. */ + if (!ere && s[1] && (s[1]!='\\'|| (s[2]!=')' && s[2]!='|'))) + goto parse_literal; + node = tre_ast_new_literal(ctx->mem, ASSERTION, ASSERT_AT_EOL, -1); + s++; + break; + case '*': + case '{': + case '+': + case '?': + /* reject repetitions after empty expression in ERE */ + if (ere) + return REG_BADRPT; + case '|': + if (!ere) + goto parse_literal; + case 0: + node = tre_ast_new_literal(ctx->mem, EMPTY, -1, -1); + break; + default: +parse_literal: + len = mbtowc(&wc, s, -1); + if (len < 0) + return REG_BADPAT; + if (ctx->cflags & REG_ICASE && (tre_isupper(wc) || tre_islower(wc))) { + tre_ast_node_t *tmp1, *tmp2; + /* multiple opposite case characters are not supported */ + tmp1 = tre_ast_new_literal(ctx->mem, tre_toupper(wc), tre_toupper(wc), ctx->position); + tmp2 = tre_ast_new_literal(ctx->mem, tre_tolower(wc), tre_tolower(wc), ctx->position); + if (tmp1 && tmp2) + node = tre_ast_new_union(ctx->mem, tmp1, tmp2); + else + node = 0; + } else { + node = tre_ast_new_literal(ctx->mem, wc, wc, ctx->position); + } + ctx->position++; + s += len; + break; + } +end: + if (!node) + return REG_ESPACE; + ctx->n = node; + ctx->s = s; + return REG_OK; +} + +#define PUSHPTR(err, s, v) do { \ + if ((err = tre_stack_push_voidptr(s, v)) != REG_OK) \ + return err; \ +} while(0) + +#define PUSHINT(err, s, v) do { \ + if ((err = tre_stack_push_int(s, v)) != REG_OK) \ + return err; \ +} while(0) + +static reg_errcode_t tre_parse(tre_parse_ctx_t *ctx) +{ + tre_ast_node_t *nbranch=0, *nunion=0; + int ere = ctx->cflags & REG_EXTENDED; + const char *s = ctx->start; + int subid = 0; + int depth = 0; + reg_errcode_t err; + tre_stack_t *stack = ctx->stack; + + PUSHINT(err, stack, subid++); + for (;;) { + if ((!ere && *s == '\\' && s[1] == '(') || + (ere && *s == '(')) { + PUSHPTR(err, stack, nunion); + PUSHPTR(err, stack, nbranch); + PUSHINT(err, stack, subid++); + s++; + if (!ere) + s++; + depth++; + nbranch = nunion = 0; + ctx->start = s; + continue; + } + if ((!ere && *s == '\\' && s[1] == ')') || + (ere && *s == ')' && depth)) { + ctx->n = tre_ast_new_literal(ctx->mem, EMPTY, -1, -1); + if (!ctx->n) + return REG_ESPACE; + } else { + err = parse_atom(ctx, s); + if (err != REG_OK) + return err; + s = ctx->s; + } + + parse_iter: + for (;;) { + int min, max; + + if (*s!='\\' && *s!='*') { + if (!ere) + break; + if (*s!='+' && *s!='?' && *s!='{') + break; + } + if (*s=='\\' && ere) + break; + /* extension: treat \+, \? as repetitions in BRE */ + if (*s=='\\' && s[1]!='+' && s[1]!='?' && s[1]!='{') + break; + if (*s=='\\') + s++; + + /* handle ^* at the start of a BRE. */ + if (!ere && s==ctx->start+1 && s[-1]=='^') + break; + + /* extension: multiple consecutive *+?{,} is unspecified, + but (a+)+ has to be supported so accepting a++ makes + sense, note however that the RE_DUP_MAX limit can be + circumvented: (a{255}){255} uses a lot of memory.. */ + if (*s=='{') { + s = parse_dup(s+1, ere, &min, &max); + if (!s) + return REG_BADBR; + } else { + min=0; + max=-1; + if (*s == '+') + min = 1; + if (*s == '?') + max = 1; + s++; + } + if (max == 0) + ctx->n = tre_ast_new_literal(ctx->mem, EMPTY, -1, -1); + else + ctx->n = tre_ast_new_iter(ctx->mem, ctx->n, min, max, 0); + if (!ctx->n) + return REG_ESPACE; + } + + nbranch = tre_ast_new_catenation(ctx->mem, nbranch, ctx->n); + if ((ere && *s == '|') || + (ere && *s == ')' && depth) || + (!ere && *s == '\\' && s[1] == ')') || + /* extension: treat \| as alternation in BRE */ + (!ere && *s == '\\' && s[1] == '|') || + !*s) { + /* extension: empty branch is unspecified (), (|a), (a|) + here they are not rejected but match on empty string */ + int c = *s; + nunion = tre_ast_new_union(ctx->mem, nunion, nbranch); + nbranch = 0; + + if (c == '\\' && s[1] == '|') { + s+=2; + ctx->start = s; + } else if (c == '|') { + s++; + ctx->start = s; + } else { + if (c == '\\') { + if (!depth) return REG_EPAREN; + s+=2; + } else if (c == ')') + s++; + depth--; + err = marksub(ctx, nunion, tre_stack_pop_int(stack)); + if (err != REG_OK) + return err; + if (!c && depth<0) { + ctx->submatch_id = subid; + return REG_OK; + } + if (!c || depth<0) + return REG_EPAREN; + nbranch = tre_stack_pop_voidptr(stack); + nunion = tre_stack_pop_voidptr(stack); + goto parse_iter; + } + } + } +} + + +/*********************************************************************** + from tre-compile.c +***********************************************************************/ + + +/* + TODO: + - Fix tre_ast_to_tnfa() to recurse using a stack instead of recursive + function calls. +*/ + +/* + Algorithms to setup tags so that submatch addressing can be done. +*/ + + +/* Inserts a catenation node to the root of the tree given in `node'. + As the left child a new tag with number `tag_id' to `node' is added, + and the right child is the old root. */ +static reg_errcode_t +tre_add_tag_left(tre_mem_t mem, tre_ast_node_t *node, int tag_id) +{ + tre_catenation_t *c; + + c = tre_mem_alloc(mem, sizeof(*c)); + if (c == NULL) + return REG_ESPACE; + c->left = tre_ast_new_literal(mem, TAG, tag_id, -1); + if (c->left == NULL) + return REG_ESPACE; + c->right = tre_mem_alloc(mem, sizeof(tre_ast_node_t)); + if (c->right == NULL) + return REG_ESPACE; + + c->right->obj = node->obj; + c->right->type = node->type; + c->right->nullable = -1; + c->right->submatch_id = -1; + c->right->firstpos = NULL; + c->right->lastpos = NULL; + c->right->num_tags = 0; + c->right->num_submatches = 0; + node->obj = c; + node->type = CATENATION; + return REG_OK; +} + +/* Inserts a catenation node to the root of the tree given in `node'. + As the right child a new tag with number `tag_id' to `node' is added, + and the left child is the old root. */ +static reg_errcode_t +tre_add_tag_right(tre_mem_t mem, tre_ast_node_t *node, int tag_id) +{ + tre_catenation_t *c; + + c = tre_mem_alloc(mem, sizeof(*c)); + if (c == NULL) + return REG_ESPACE; + c->right = tre_ast_new_literal(mem, TAG, tag_id, -1); + if (c->right == NULL) + return REG_ESPACE; + c->left = tre_mem_alloc(mem, sizeof(tre_ast_node_t)); + if (c->left == NULL) + return REG_ESPACE; + + c->left->obj = node->obj; + c->left->type = node->type; + c->left->nullable = -1; + c->left->submatch_id = -1; + c->left->firstpos = NULL; + c->left->lastpos = NULL; + c->left->num_tags = 0; + c->left->num_submatches = 0; + node->obj = c; + node->type = CATENATION; + return REG_OK; +} + +typedef enum { + ADDTAGS_RECURSE, + ADDTAGS_AFTER_ITERATION, + ADDTAGS_AFTER_UNION_LEFT, + ADDTAGS_AFTER_UNION_RIGHT, + ADDTAGS_AFTER_CAT_LEFT, + ADDTAGS_AFTER_CAT_RIGHT, + ADDTAGS_SET_SUBMATCH_END +} tre_addtags_symbol_t; + + +typedef struct { + int tag; + int next_tag; +} tre_tag_states_t; + + +/* Go through `regset' and set submatch data for submatches that are + using this tag. */ +static void +tre_purge_regset(int *regset, tre_tnfa_t *tnfa, int tag) +{ + int i; + + for (i = 0; regset[i] >= 0; i++) + { + int id = regset[i] / 2; + int start = !(regset[i] % 2); + if (start) + tnfa->submatch_data[id].so_tag = tag; + else + tnfa->submatch_data[id].eo_tag = tag; + } + regset[0] = -1; +} + + +/* Adds tags to appropriate locations in the parse tree in `tree', so that + subexpressions marked for submatch addressing can be traced. */ +static reg_errcode_t +tre_add_tags(tre_mem_t mem, tre_stack_t *stack, tre_ast_node_t *tree, + tre_tnfa_t *tnfa) +{ + reg_errcode_t status = REG_OK; + tre_addtags_symbol_t symbol; + tre_ast_node_t *node = tree; /* Tree node we are currently looking at. */ + int bottom = tre_stack_num_objects(stack); + /* True for first pass (counting number of needed tags) */ + int first_pass = (mem == NULL || tnfa == NULL); + int *regset, *orig_regset; + int num_tags = 0; /* Total number of tags. */ + int num_minimals = 0; /* Number of special minimal tags. */ + int tag = 0; /* The tag that is to be added next. */ + int next_tag = 1; /* Next tag to use after this one. */ + int *parents; /* Stack of submatches the current submatch is + contained in. */ + int minimal_tag = -1; /* Tag that marks the beginning of a minimal match. */ + tre_tag_states_t *saved_states; + + tre_tag_direction_t direction = TRE_TAG_MINIMIZE; + if (!first_pass) + { + tnfa->end_tag = 0; + tnfa->minimal_tags[0] = -1; + } + + regset = xmalloc(sizeof(*regset) * ((tnfa->num_submatches + 1) * 2)); + if (regset == NULL) + return REG_ESPACE; + regset[0] = -1; + orig_regset = regset; + + parents = xmalloc(sizeof(*parents) * (tnfa->num_submatches + 1)); + if (parents == NULL) + { + xfree(regset); + return REG_ESPACE; + } + parents[0] = -1; + + saved_states = xmalloc(sizeof(*saved_states) * (tnfa->num_submatches + 1)); + if (saved_states == NULL) + { + xfree(regset); + xfree(parents); + return REG_ESPACE; + } + else + { + unsigned int i; + for (i = 0; i <= tnfa->num_submatches; i++) + saved_states[i].tag = -1; + } + + STACK_PUSH(stack, voidptr, node); + STACK_PUSH(stack, int, ADDTAGS_RECURSE); + + while (tre_stack_num_objects(stack) > bottom) + { + if (status != REG_OK) + break; + + symbol = (tre_addtags_symbol_t)tre_stack_pop_int(stack); + switch (symbol) + { + + case ADDTAGS_SET_SUBMATCH_END: + { + int id = tre_stack_pop_int(stack); + int i; + + /* Add end of this submatch to regset. */ + for (i = 0; regset[i] >= 0; i++); + regset[i] = id * 2 + 1; + regset[i + 1] = -1; + + /* Pop this submatch from the parents stack. */ + for (i = 0; parents[i] >= 0; i++); + parents[i - 1] = -1; + break; + } + + case ADDTAGS_RECURSE: + node = tre_stack_pop_voidptr(stack); + + if (node->submatch_id >= 0) + { + int id = node->submatch_id; + int i; + + + /* Add start of this submatch to regset. */ + for (i = 0; regset[i] >= 0; i++); + regset[i] = id * 2; + regset[i + 1] = -1; + + if (!first_pass) + { + for (i = 0; parents[i] >= 0; i++); + tnfa->submatch_data[id].parents = NULL; + if (i > 0) + { + int *p = xmalloc(sizeof(*p) * (i + 1)); + if (p == NULL) + { + status = REG_ESPACE; + break; + } + assert(tnfa->submatch_data[id].parents == NULL); + tnfa->submatch_data[id].parents = p; + for (i = 0; parents[i] >= 0; i++) + p[i] = parents[i]; + p[i] = -1; + } + } + + /* Add end of this submatch to regset after processing this + node. */ + STACK_PUSHX(stack, int, node->submatch_id); + STACK_PUSHX(stack, int, ADDTAGS_SET_SUBMATCH_END); + } + + switch (node->type) + { + case LITERAL: + { + tre_literal_t *lit = node->obj; + + if (!IS_SPECIAL(lit) || IS_BACKREF(lit)) + { + int i; + if (regset[0] >= 0) + { + /* Regset is not empty, so add a tag before the + literal or backref. */ + if (!first_pass) + { + status = tre_add_tag_left(mem, node, tag); + tnfa->tag_directions[tag] = direction; + if (minimal_tag >= 0) + { + for (i = 0; tnfa->minimal_tags[i] >= 0; i++); + tnfa->minimal_tags[i] = tag; + tnfa->minimal_tags[i + 1] = minimal_tag; + tnfa->minimal_tags[i + 2] = -1; + minimal_tag = -1; + num_minimals++; + } + tre_purge_regset(regset, tnfa, tag); + } + else + { + node->num_tags = 1; + } + + regset[0] = -1; + tag = next_tag; + num_tags++; + next_tag++; + } + } + else + { + assert(!IS_TAG(lit)); + } + break; + } + case CATENATION: + { + tre_catenation_t *cat = node->obj; + tre_ast_node_t *left = cat->left; + tre_ast_node_t *right = cat->right; + int reserved_tag = -1; + + + /* After processing right child. */ + STACK_PUSHX(stack, voidptr, node); + STACK_PUSHX(stack, int, ADDTAGS_AFTER_CAT_RIGHT); + + /* Process right child. */ + STACK_PUSHX(stack, voidptr, right); + STACK_PUSHX(stack, int, ADDTAGS_RECURSE); + + /* After processing left child. */ + STACK_PUSHX(stack, int, next_tag + left->num_tags); + if (left->num_tags > 0 && right->num_tags > 0) + { + /* Reserve the next tag to the right child. */ + reserved_tag = next_tag; + next_tag++; + } + STACK_PUSHX(stack, int, reserved_tag); + STACK_PUSHX(stack, int, ADDTAGS_AFTER_CAT_LEFT); + + /* Process left child. */ + STACK_PUSHX(stack, voidptr, left); + STACK_PUSHX(stack, int, ADDTAGS_RECURSE); + + } + break; + case ITERATION: + { + tre_iteration_t *iter = node->obj; + + if (first_pass) + { + STACK_PUSHX(stack, int, regset[0] >= 0 || iter->minimal); + } + else + { + STACK_PUSHX(stack, int, tag); + STACK_PUSHX(stack, int, iter->minimal); + } + STACK_PUSHX(stack, voidptr, node); + STACK_PUSHX(stack, int, ADDTAGS_AFTER_ITERATION); + + STACK_PUSHX(stack, voidptr, iter->arg); + STACK_PUSHX(stack, int, ADDTAGS_RECURSE); + + /* Regset is not empty, so add a tag here. */ + if (regset[0] >= 0 || iter->minimal) + { + if (!first_pass) + { + int i; + status = tre_add_tag_left(mem, node, tag); + if (iter->minimal) + tnfa->tag_directions[tag] = TRE_TAG_MAXIMIZE; + else + tnfa->tag_directions[tag] = direction; + if (minimal_tag >= 0) + { + for (i = 0; tnfa->minimal_tags[i] >= 0; i++); + tnfa->minimal_tags[i] = tag; + tnfa->minimal_tags[i + 1] = minimal_tag; + tnfa->minimal_tags[i + 2] = -1; + minimal_tag = -1; + num_minimals++; + } + tre_purge_regset(regset, tnfa, tag); + } + + regset[0] = -1; + tag = next_tag; + num_tags++; + next_tag++; + } + direction = TRE_TAG_MINIMIZE; + } + break; + case UNION: + { + tre_union_t *uni = node->obj; + tre_ast_node_t *left = uni->left; + tre_ast_node_t *right = uni->right; + int left_tag; + int right_tag; + + if (regset[0] >= 0) + { + left_tag = next_tag; + right_tag = next_tag + 1; + } + else + { + left_tag = tag; + right_tag = next_tag; + } + + /* After processing right child. */ + STACK_PUSHX(stack, int, right_tag); + STACK_PUSHX(stack, int, left_tag); + STACK_PUSHX(stack, voidptr, regset); + STACK_PUSHX(stack, int, regset[0] >= 0); + STACK_PUSHX(stack, voidptr, node); + STACK_PUSHX(stack, voidptr, right); + STACK_PUSHX(stack, voidptr, left); + STACK_PUSHX(stack, int, ADDTAGS_AFTER_UNION_RIGHT); + + /* Process right child. */ + STACK_PUSHX(stack, voidptr, right); + STACK_PUSHX(stack, int, ADDTAGS_RECURSE); + + /* After processing left child. */ + STACK_PUSHX(stack, int, ADDTAGS_AFTER_UNION_LEFT); + + /* Process left child. */ + STACK_PUSHX(stack, voidptr, left); + STACK_PUSHX(stack, int, ADDTAGS_RECURSE); + + /* Regset is not empty, so add a tag here. */ + if (regset[0] >= 0) + { + if (!first_pass) + { + int i; + status = tre_add_tag_left(mem, node, tag); + tnfa->tag_directions[tag] = direction; + if (minimal_tag >= 0) + { + for (i = 0; tnfa->minimal_tags[i] >= 0; i++); + tnfa->minimal_tags[i] = tag; + tnfa->minimal_tags[i + 1] = minimal_tag; + tnfa->minimal_tags[i + 2] = -1; + minimal_tag = -1; + num_minimals++; + } + tre_purge_regset(regset, tnfa, tag); + } + + regset[0] = -1; + tag = next_tag; + num_tags++; + next_tag++; + } + + if (node->num_submatches > 0) + { + /* The next two tags are reserved for markers. */ + next_tag++; + tag = next_tag; + next_tag++; + } + + break; + } + } + + if (node->submatch_id >= 0) + { + int i; + /* Push this submatch on the parents stack. */ + for (i = 0; parents[i] >= 0; i++); + parents[i] = node->submatch_id; + parents[i + 1] = -1; + } + + break; /* end case: ADDTAGS_RECURSE */ + + case ADDTAGS_AFTER_ITERATION: + { + int minimal = 0; + int enter_tag; + node = tre_stack_pop_voidptr(stack); + if (first_pass) + { + node->num_tags = ((tre_iteration_t *)node->obj)->arg->num_tags + + tre_stack_pop_int(stack); + minimal_tag = -1; + } + else + { + minimal = tre_stack_pop_int(stack); + enter_tag = tre_stack_pop_int(stack); + if (minimal) + minimal_tag = enter_tag; + } + + if (!first_pass) + { + if (minimal) + direction = TRE_TAG_MINIMIZE; + else + direction = TRE_TAG_MAXIMIZE; + } + break; + } + + case ADDTAGS_AFTER_CAT_LEFT: + { + int new_tag = tre_stack_pop_int(stack); + next_tag = tre_stack_pop_int(stack); + if (new_tag >= 0) + { + tag = new_tag; + } + break; + } + + case ADDTAGS_AFTER_CAT_RIGHT: + node = tre_stack_pop_voidptr(stack); + if (first_pass) + node->num_tags = ((tre_catenation_t *)node->obj)->left->num_tags + + ((tre_catenation_t *)node->obj)->right->num_tags; + break; + + case ADDTAGS_AFTER_UNION_LEFT: + /* Lift the bottom of the `regset' array so that when processing + the right operand the items currently in the array are + invisible. The original bottom was saved at ADDTAGS_UNION and + will be restored at ADDTAGS_AFTER_UNION_RIGHT below. */ + while (*regset >= 0) + regset++; + break; + + case ADDTAGS_AFTER_UNION_RIGHT: + { + int added_tags, tag_left, tag_right; + tre_ast_node_t *left = tre_stack_pop_voidptr(stack); + tre_ast_node_t *right = tre_stack_pop_voidptr(stack); + node = tre_stack_pop_voidptr(stack); + added_tags = tre_stack_pop_int(stack); + if (first_pass) + { + node->num_tags = ((tre_union_t *)node->obj)->left->num_tags + + ((tre_union_t *)node->obj)->right->num_tags + added_tags + + ((node->num_submatches > 0) ? 2 : 0); + } + regset = tre_stack_pop_voidptr(stack); + tag_left = tre_stack_pop_int(stack); + tag_right = tre_stack_pop_int(stack); + + /* Add tags after both children, the left child gets a smaller + tag than the right child. This guarantees that we prefer + the left child over the right child. */ + /* XXX - This is not always necessary (if the children have + tags which must be seen for every match of that child). */ + /* XXX - Check if this is the only place where tre_add_tag_right + is used. If so, use tre_add_tag_left (putting the tag before + the child as opposed after the child) and throw away + tre_add_tag_right. */ + if (node->num_submatches > 0) + { + if (!first_pass) + { + status = tre_add_tag_right(mem, left, tag_left); + tnfa->tag_directions[tag_left] = TRE_TAG_MAXIMIZE; + if (status == REG_OK) + status = tre_add_tag_right(mem, right, tag_right); + tnfa->tag_directions[tag_right] = TRE_TAG_MAXIMIZE; + } + num_tags += 2; + } + direction = TRE_TAG_MAXIMIZE; + break; + } + + default: + assert(0); + break; + + } /* end switch(symbol) */ + } /* end while(tre_stack_num_objects(stack) > bottom) */ + + if (!first_pass) + tre_purge_regset(regset, tnfa, tag); + + if (!first_pass && minimal_tag >= 0) + { + int i; + for (i = 0; tnfa->minimal_tags[i] >= 0; i++); + tnfa->minimal_tags[i] = tag; + tnfa->minimal_tags[i + 1] = minimal_tag; + tnfa->minimal_tags[i + 2] = -1; + minimal_tag = -1; + num_minimals++; + } + + assert(tree->num_tags == num_tags); + tnfa->end_tag = num_tags; + tnfa->num_tags = num_tags; + tnfa->num_minimals = num_minimals; + xfree(orig_regset); + xfree(parents); + xfree(saved_states); + return status; +} + + + +/* + AST to TNFA compilation routines. +*/ + +typedef enum { + COPY_RECURSE, + COPY_SET_RESULT_PTR +} tre_copyast_symbol_t; + +/* Flags for tre_copy_ast(). */ +#define COPY_REMOVE_TAGS 1 +#define COPY_MAXIMIZE_FIRST_TAG 2 + +static reg_errcode_t +tre_copy_ast(tre_mem_t mem, tre_stack_t *stack, tre_ast_node_t *ast, + int flags, int *pos_add, tre_tag_direction_t *tag_directions, + tre_ast_node_t **copy, int *max_pos) +{ + reg_errcode_t status = REG_OK; + int bottom = tre_stack_num_objects(stack); + int num_copied = 0; + int first_tag = 1; + tre_ast_node_t **result = copy; + tre_copyast_symbol_t symbol; + + STACK_PUSH(stack, voidptr, ast); + STACK_PUSH(stack, int, COPY_RECURSE); + + while (status == REG_OK && tre_stack_num_objects(stack) > bottom) + { + tre_ast_node_t *node; + if (status != REG_OK) + break; + + symbol = (tre_copyast_symbol_t)tre_stack_pop_int(stack); + switch (symbol) + { + case COPY_SET_RESULT_PTR: + result = tre_stack_pop_voidptr(stack); + break; + case COPY_RECURSE: + node = tre_stack_pop_voidptr(stack); + switch (node->type) + { + case LITERAL: + { + tre_literal_t *lit = node->obj; + int pos = lit->position; + int min = lit->code_min; + int max = lit->code_max; + if (!IS_SPECIAL(lit) || IS_BACKREF(lit)) + { + /* XXX - e.g. [ab] has only one position but two + nodes, so we are creating holes in the state space + here. Not fatal, just wastes memory. */ + pos += *pos_add; + num_copied++; + } + else if (IS_TAG(lit) && (flags & COPY_REMOVE_TAGS)) + { + /* Change this tag to empty. */ + min = EMPTY; + max = pos = -1; + } + else if (IS_TAG(lit) && (flags & COPY_MAXIMIZE_FIRST_TAG) + && first_tag) + { + /* Maximize the first tag. */ + tag_directions[max] = TRE_TAG_MAXIMIZE; + first_tag = 0; + } + *result = tre_ast_new_literal(mem, min, max, pos); + if (*result == NULL) + status = REG_ESPACE; + else { + tre_literal_t *p = (*result)->obj; + p->class = lit->class; + p->neg_classes = lit->neg_classes; + } + + if (pos > *max_pos) + *max_pos = pos; + break; + } + case UNION: + { + tre_union_t *uni = node->obj; + tre_union_t *tmp; + *result = tre_ast_new_union(mem, uni->left, uni->right); + if (*result == NULL) + { + status = REG_ESPACE; + break; + } + tmp = (*result)->obj; + result = &tmp->left; + STACK_PUSHX(stack, voidptr, uni->right); + STACK_PUSHX(stack, int, COPY_RECURSE); + STACK_PUSHX(stack, voidptr, &tmp->right); + STACK_PUSHX(stack, int, COPY_SET_RESULT_PTR); + STACK_PUSHX(stack, voidptr, uni->left); + STACK_PUSHX(stack, int, COPY_RECURSE); + break; + } + case CATENATION: + { + tre_catenation_t *cat = node->obj; + tre_catenation_t *tmp; + *result = tre_ast_new_catenation(mem, cat->left, cat->right); + if (*result == NULL) + { + status = REG_ESPACE; + break; + } + tmp = (*result)->obj; + tmp->left = NULL; + tmp->right = NULL; + result = &tmp->left; + + STACK_PUSHX(stack, voidptr, cat->right); + STACK_PUSHX(stack, int, COPY_RECURSE); + STACK_PUSHX(stack, voidptr, &tmp->right); + STACK_PUSHX(stack, int, COPY_SET_RESULT_PTR); + STACK_PUSHX(stack, voidptr, cat->left); + STACK_PUSHX(stack, int, COPY_RECURSE); + break; + } + case ITERATION: + { + tre_iteration_t *iter = node->obj; + STACK_PUSHX(stack, voidptr, iter->arg); + STACK_PUSHX(stack, int, COPY_RECURSE); + *result = tre_ast_new_iter(mem, iter->arg, iter->min, + iter->max, iter->minimal); + if (*result == NULL) + { + status = REG_ESPACE; + break; + } + iter = (*result)->obj; + result = &iter->arg; + break; + } + default: + assert(0); + break; + } + break; + } + } + *pos_add += num_copied; + return status; +} + +typedef enum { + EXPAND_RECURSE, + EXPAND_AFTER_ITER +} tre_expand_ast_symbol_t; + +/* Expands each iteration node that has a finite nonzero minimum or maximum + iteration count to a catenated sequence of copies of the node. */ +static reg_errcode_t +tre_expand_ast(tre_mem_t mem, tre_stack_t *stack, tre_ast_node_t *ast, + int *position, tre_tag_direction_t *tag_directions) +{ + reg_errcode_t status = REG_OK; + int bottom = tre_stack_num_objects(stack); + int pos_add = 0; + int pos_add_total = 0; + int max_pos = 0; + int iter_depth = 0; + + STACK_PUSHR(stack, voidptr, ast); + STACK_PUSHR(stack, int, EXPAND_RECURSE); + while (status == REG_OK && tre_stack_num_objects(stack) > bottom) + { + tre_ast_node_t *node; + tre_expand_ast_symbol_t symbol; + + if (status != REG_OK) + break; + + symbol = (tre_expand_ast_symbol_t)tre_stack_pop_int(stack); + node = tre_stack_pop_voidptr(stack); + switch (symbol) + { + case EXPAND_RECURSE: + switch (node->type) + { + case LITERAL: + { + tre_literal_t *lit= node->obj; + if (!IS_SPECIAL(lit) || IS_BACKREF(lit)) + { + lit->position += pos_add; + if (lit->position > max_pos) + max_pos = lit->position; + } + break; + } + case UNION: + { + tre_union_t *uni = node->obj; + STACK_PUSHX(stack, voidptr, uni->right); + STACK_PUSHX(stack, int, EXPAND_RECURSE); + STACK_PUSHX(stack, voidptr, uni->left); + STACK_PUSHX(stack, int, EXPAND_RECURSE); + break; + } + case CATENATION: + { + tre_catenation_t *cat = node->obj; + STACK_PUSHX(stack, voidptr, cat->right); + STACK_PUSHX(stack, int, EXPAND_RECURSE); + STACK_PUSHX(stack, voidptr, cat->left); + STACK_PUSHX(stack, int, EXPAND_RECURSE); + break; + } + case ITERATION: + { + tre_iteration_t *iter = node->obj; + STACK_PUSHX(stack, int, pos_add); + STACK_PUSHX(stack, voidptr, node); + STACK_PUSHX(stack, int, EXPAND_AFTER_ITER); + STACK_PUSHX(stack, voidptr, iter->arg); + STACK_PUSHX(stack, int, EXPAND_RECURSE); + /* If we are going to expand this node at EXPAND_AFTER_ITER + then don't increase the `pos' fields of the nodes now, it + will get done when expanding. */ + if (iter->min > 1 || iter->max > 1) + pos_add = 0; + iter_depth++; + break; + } + default: + assert(0); + break; + } + break; + case EXPAND_AFTER_ITER: + { + tre_iteration_t *iter = node->obj; + int pos_add_last; + pos_add = tre_stack_pop_int(stack); + pos_add_last = pos_add; + if (iter->min > 1 || iter->max > 1) + { + tre_ast_node_t *seq1 = NULL, *seq2 = NULL; + int j; + int pos_add_save = pos_add; + + /* Create a catenated sequence of copies of the node. */ + for (j = 0; j < iter->min; j++) + { + tre_ast_node_t *copy; + /* Remove tags from all but the last copy. */ + int flags = ((j + 1 < iter->min) + ? COPY_REMOVE_TAGS + : COPY_MAXIMIZE_FIRST_TAG); + pos_add_save = pos_add; + status = tre_copy_ast(mem, stack, iter->arg, flags, + &pos_add, tag_directions, ©, + &max_pos); + if (status != REG_OK) + return status; + if (seq1 != NULL) + seq1 = tre_ast_new_catenation(mem, seq1, copy); + else + seq1 = copy; + if (seq1 == NULL) + return REG_ESPACE; + } + + if (iter->max == -1) + { + /* No upper limit. */ + pos_add_save = pos_add; + status = tre_copy_ast(mem, stack, iter->arg, 0, + &pos_add, NULL, &seq2, &max_pos); + if (status != REG_OK) + return status; + seq2 = tre_ast_new_iter(mem, seq2, 0, -1, 0); + if (seq2 == NULL) + return REG_ESPACE; + } + else + { + for (j = iter->min; j < iter->max; j++) + { + tre_ast_node_t *tmp, *copy; + pos_add_save = pos_add; + status = tre_copy_ast(mem, stack, iter->arg, 0, + &pos_add, NULL, ©, &max_pos); + if (status != REG_OK) + return status; + if (seq2 != NULL) + seq2 = tre_ast_new_catenation(mem, copy, seq2); + else + seq2 = copy; + if (seq2 == NULL) + return REG_ESPACE; + tmp = tre_ast_new_literal(mem, EMPTY, -1, -1); + if (tmp == NULL) + return REG_ESPACE; + seq2 = tre_ast_new_union(mem, tmp, seq2); + if (seq2 == NULL) + return REG_ESPACE; + } + } + + pos_add = pos_add_save; + if (seq1 == NULL) + seq1 = seq2; + else if (seq2 != NULL) + seq1 = tre_ast_new_catenation(mem, seq1, seq2); + if (seq1 == NULL) + return REG_ESPACE; + node->obj = seq1->obj; + node->type = seq1->type; + } + + iter_depth--; + pos_add_total += pos_add - pos_add_last; + if (iter_depth == 0) + pos_add = pos_add_total; + + break; + } + default: + assert(0); + break; + } + } + + *position += pos_add_total; + + /* `max_pos' should never be larger than `*position' if the above + code works, but just an extra safeguard let's make sure + `*position' is set large enough so enough memory will be + allocated for the transition table. */ + if (max_pos > *position) + *position = max_pos; + + return status; +} + +static tre_pos_and_tags_t * +tre_set_empty(tre_mem_t mem) +{ + tre_pos_and_tags_t *new_set; + + new_set = tre_mem_calloc(mem, sizeof(*new_set)); + if (new_set == NULL) + return NULL; + + new_set[0].position = -1; + new_set[0].code_min = -1; + new_set[0].code_max = -1; + + return new_set; +} + +static tre_pos_and_tags_t * +tre_set_one(tre_mem_t mem, int position, int code_min, int code_max, + tre_ctype_t class, tre_ctype_t *neg_classes, int backref) +{ + tre_pos_and_tags_t *new_set; + + new_set = tre_mem_calloc(mem, sizeof(*new_set) * 2); + if (new_set == NULL) + return NULL; + + new_set[0].position = position; + new_set[0].code_min = code_min; + new_set[0].code_max = code_max; + new_set[0].class = class; + new_set[0].neg_classes = neg_classes; + new_set[0].backref = backref; + new_set[1].position = -1; + new_set[1].code_min = -1; + new_set[1].code_max = -1; + + return new_set; +} + +static tre_pos_and_tags_t * +tre_set_union(tre_mem_t mem, tre_pos_and_tags_t *set1, tre_pos_and_tags_t *set2, + int *tags, int assertions) +{ + int s1, s2, i, j; + tre_pos_and_tags_t *new_set; + int *new_tags; + int num_tags; + + for (num_tags = 0; tags != NULL && tags[num_tags] >= 0; num_tags++); + for (s1 = 0; set1[s1].position >= 0; s1++); + for (s2 = 0; set2[s2].position >= 0; s2++); + new_set = tre_mem_calloc(mem, sizeof(*new_set) * (s1 + s2 + 1)); + if (!new_set ) + return NULL; + + for (s1 = 0; set1[s1].position >= 0; s1++) + { + new_set[s1].position = set1[s1].position; + new_set[s1].code_min = set1[s1].code_min; + new_set[s1].code_max = set1[s1].code_max; + new_set[s1].assertions = set1[s1].assertions | assertions; + new_set[s1].class = set1[s1].class; + new_set[s1].neg_classes = set1[s1].neg_classes; + new_set[s1].backref = set1[s1].backref; + if (set1[s1].tags == NULL && tags == NULL) + new_set[s1].tags = NULL; + else + { + for (i = 0; set1[s1].tags != NULL && set1[s1].tags[i] >= 0; i++); + new_tags = tre_mem_alloc(mem, (sizeof(*new_tags) + * (i + num_tags + 1))); + if (new_tags == NULL) + return NULL; + for (j = 0; j < i; j++) + new_tags[j] = set1[s1].tags[j]; + for (i = 0; i < num_tags; i++) + new_tags[j + i] = tags[i]; + new_tags[j + i] = -1; + new_set[s1].tags = new_tags; + } + } + + for (s2 = 0; set2[s2].position >= 0; s2++) + { + new_set[s1 + s2].position = set2[s2].position; + new_set[s1 + s2].code_min = set2[s2].code_min; + new_set[s1 + s2].code_max = set2[s2].code_max; + /* XXX - why not | assertions here as well? */ + new_set[s1 + s2].assertions = set2[s2].assertions; + new_set[s1 + s2].class = set2[s2].class; + new_set[s1 + s2].neg_classes = set2[s2].neg_classes; + new_set[s1 + s2].backref = set2[s2].backref; + if (set2[s2].tags == NULL) + new_set[s1 + s2].tags = NULL; + else + { + for (i = 0; set2[s2].tags[i] >= 0; i++); + new_tags = tre_mem_alloc(mem, sizeof(*new_tags) * (i + 1)); + if (new_tags == NULL) + return NULL; + for (j = 0; j < i; j++) + new_tags[j] = set2[s2].tags[j]; + new_tags[j] = -1; + new_set[s1 + s2].tags = new_tags; + } + } + new_set[s1 + s2].position = -1; + return new_set; +} + +/* Finds the empty path through `node' which is the one that should be + taken according to POSIX.2 rules, and adds the tags on that path to + `tags'. `tags' may be NULL. If `num_tags_seen' is not NULL, it is + set to the number of tags seen on the path. */ +static reg_errcode_t +tre_match_empty(tre_stack_t *stack, tre_ast_node_t *node, int *tags, + int *assertions, int *num_tags_seen) +{ + tre_literal_t *lit; + tre_union_t *uni; + tre_catenation_t *cat; + tre_iteration_t *iter; + int i; + int bottom = tre_stack_num_objects(stack); + reg_errcode_t status = REG_OK; + if (num_tags_seen) + *num_tags_seen = 0; + + status = tre_stack_push_voidptr(stack, node); + + /* Walk through the tree recursively. */ + while (status == REG_OK && tre_stack_num_objects(stack) > bottom) + { + node = tre_stack_pop_voidptr(stack); + + switch (node->type) + { + case LITERAL: + lit = (tre_literal_t *)node->obj; + switch (lit->code_min) + { + case TAG: + if (lit->code_max >= 0) + { + if (tags != NULL) + { + /* Add the tag to `tags'. */ + for (i = 0; tags[i] >= 0; i++) + if (tags[i] == lit->code_max) + break; + if (tags[i] < 0) + { + tags[i] = lit->code_max; + tags[i + 1] = -1; + } + } + if (num_tags_seen) + (*num_tags_seen)++; + } + break; + case ASSERTION: + assert(lit->code_max >= 1 + || lit->code_max <= ASSERT_LAST); + if (assertions != NULL) + *assertions |= lit->code_max; + break; + case EMPTY: + break; + default: + assert(0); + break; + } + break; + + case UNION: + /* Subexpressions starting earlier take priority over ones + starting later, so we prefer the left subexpression over the + right subexpression. */ + uni = (tre_union_t *)node->obj; + if (uni->left->nullable) + STACK_PUSHX(stack, voidptr, uni->left) + else if (uni->right->nullable) + STACK_PUSHX(stack, voidptr, uni->right) + else + assert(0); + break; + + case CATENATION: + /* The path must go through both children. */ + cat = (tre_catenation_t *)node->obj; + assert(cat->left->nullable); + assert(cat->right->nullable); + STACK_PUSHX(stack, voidptr, cat->left); + STACK_PUSHX(stack, voidptr, cat->right); + break; + + case ITERATION: + /* A match with an empty string is preferred over no match at + all, so we go through the argument if possible. */ + iter = (tre_iteration_t *)node->obj; + if (iter->arg->nullable) + STACK_PUSHX(stack, voidptr, iter->arg); + break; + + default: + assert(0); + break; + } + } + + return status; +} + + +typedef enum { + NFL_RECURSE, + NFL_POST_UNION, + NFL_POST_CATENATION, + NFL_POST_ITERATION +} tre_nfl_stack_symbol_t; + + +/* Computes and fills in the fields `nullable', `firstpos', and `lastpos' for + the nodes of the AST `tree'. */ +static reg_errcode_t +tre_compute_nfl(tre_mem_t mem, tre_stack_t *stack, tre_ast_node_t *tree) +{ + int bottom = tre_stack_num_objects(stack); + + STACK_PUSHR(stack, voidptr, tree); + STACK_PUSHR(stack, int, NFL_RECURSE); + + while (tre_stack_num_objects(stack) > bottom) + { + tre_nfl_stack_symbol_t symbol; + tre_ast_node_t *node; + + symbol = (tre_nfl_stack_symbol_t)tre_stack_pop_int(stack); + node = tre_stack_pop_voidptr(stack); + switch (symbol) + { + case NFL_RECURSE: + switch (node->type) + { + case LITERAL: + { + tre_literal_t *lit = (tre_literal_t *)node->obj; + if (IS_BACKREF(lit)) + { + /* Back references: nullable = false, firstpos = {i}, + lastpos = {i}. */ + node->nullable = 0; + node->firstpos = tre_set_one(mem, lit->position, 0, + TRE_CHAR_MAX, 0, NULL, -1); + if (!node->firstpos) + return REG_ESPACE; + node->lastpos = tre_set_one(mem, lit->position, 0, + TRE_CHAR_MAX, 0, NULL, + (int)lit->code_max); + if (!node->lastpos) + return REG_ESPACE; + } + else if (lit->code_min < 0) + { + /* Tags, empty strings, params, and zero width assertions: + nullable = true, firstpos = {}, and lastpos = {}. */ + node->nullable = 1; + node->firstpos = tre_set_empty(mem); + if (!node->firstpos) + return REG_ESPACE; + node->lastpos = tre_set_empty(mem); + if (!node->lastpos) + return REG_ESPACE; + } + else + { + /* Literal at position i: nullable = false, firstpos = {i}, + lastpos = {i}. */ + node->nullable = 0; + node->firstpos = + tre_set_one(mem, lit->position, (int)lit->code_min, + (int)lit->code_max, 0, NULL, -1); + if (!node->firstpos) + return REG_ESPACE; + node->lastpos = tre_set_one(mem, lit->position, + (int)lit->code_min, + (int)lit->code_max, + lit->class, lit->neg_classes, + -1); + if (!node->lastpos) + return REG_ESPACE; + } + break; + } + + case UNION: + /* Compute the attributes for the two subtrees, and after that + for this node. */ + STACK_PUSHR(stack, voidptr, node); + STACK_PUSHR(stack, int, NFL_POST_UNION); + STACK_PUSHR(stack, voidptr, ((tre_union_t *)node->obj)->right); + STACK_PUSHR(stack, int, NFL_RECURSE); + STACK_PUSHR(stack, voidptr, ((tre_union_t *)node->obj)->left); + STACK_PUSHR(stack, int, NFL_RECURSE); + break; + + case CATENATION: + /* Compute the attributes for the two subtrees, and after that + for this node. */ + STACK_PUSHR(stack, voidptr, node); + STACK_PUSHR(stack, int, NFL_POST_CATENATION); + STACK_PUSHR(stack, voidptr, ((tre_catenation_t *)node->obj)->right); + STACK_PUSHR(stack, int, NFL_RECURSE); + STACK_PUSHR(stack, voidptr, ((tre_catenation_t *)node->obj)->left); + STACK_PUSHR(stack, int, NFL_RECURSE); + break; + + case ITERATION: + /* Compute the attributes for the subtree, and after that for + this node. */ + STACK_PUSHR(stack, voidptr, node); + STACK_PUSHR(stack, int, NFL_POST_ITERATION); + STACK_PUSHR(stack, voidptr, ((tre_iteration_t *)node->obj)->arg); + STACK_PUSHR(stack, int, NFL_RECURSE); + break; + } + break; /* end case: NFL_RECURSE */ + + case NFL_POST_UNION: + { + tre_union_t *uni = (tre_union_t *)node->obj; + node->nullable = uni->left->nullable || uni->right->nullable; + node->firstpos = tre_set_union(mem, uni->left->firstpos, + uni->right->firstpos, NULL, 0); + if (!node->firstpos) + return REG_ESPACE; + node->lastpos = tre_set_union(mem, uni->left->lastpos, + uni->right->lastpos, NULL, 0); + if (!node->lastpos) + return REG_ESPACE; + break; + } + + case NFL_POST_ITERATION: + { + tre_iteration_t *iter = (tre_iteration_t *)node->obj; + + if (iter->min == 0 || iter->arg->nullable) + node->nullable = 1; + else + node->nullable = 0; + node->firstpos = iter->arg->firstpos; + node->lastpos = iter->arg->lastpos; + break; + } + + case NFL_POST_CATENATION: + { + int num_tags, *tags, assertions; + reg_errcode_t status; + tre_catenation_t *cat = node->obj; + node->nullable = cat->left->nullable && cat->right->nullable; + + /* Compute firstpos. */ + if (cat->left->nullable) + { + /* The left side matches the empty string. Make a first pass + with tre_match_empty() to get the number of tags and + parameters. */ + status = tre_match_empty(stack, cat->left, + NULL, NULL, &num_tags); + if (status != REG_OK) + return status; + /* Allocate arrays for the tags and parameters. */ + tags = xmalloc(sizeof(*tags) * (num_tags + 1)); + if (!tags) + return REG_ESPACE; + tags[0] = -1; + assertions = 0; + /* Second pass with tre_mach_empty() to get the list of + tags and parameters. */ + status = tre_match_empty(stack, cat->left, tags, + &assertions, NULL); + if (status != REG_OK) + { + xfree(tags); + return status; + } + node->firstpos = + tre_set_union(mem, cat->right->firstpos, cat->left->firstpos, + tags, assertions); + xfree(tags); + if (!node->firstpos) + return REG_ESPACE; + } + else + { + node->firstpos = cat->left->firstpos; + } + + /* Compute lastpos. */ + if (cat->right->nullable) + { + /* The right side matches the empty string. Make a first pass + with tre_match_empty() to get the number of tags and + parameters. */ + status = tre_match_empty(stack, cat->right, + NULL, NULL, &num_tags); + if (status != REG_OK) + return status; + /* Allocate arrays for the tags and parameters. */ + tags = xmalloc(sizeof(int) * (num_tags + 1)); + if (!tags) + return REG_ESPACE; + tags[0] = -1; + assertions = 0; + /* Second pass with tre_mach_empty() to get the list of + tags and parameters. */ + status = tre_match_empty(stack, cat->right, tags, + &assertions, NULL); + if (status != REG_OK) + { + xfree(tags); + return status; + } + node->lastpos = + tre_set_union(mem, cat->left->lastpos, cat->right->lastpos, + tags, assertions); + xfree(tags); + if (!node->lastpos) + return REG_ESPACE; + } + else + { + node->lastpos = cat->right->lastpos; + } + break; + } + + default: + assert(0); + break; + } + } + + return REG_OK; +} + + +/* Adds a transition from each position in `p1' to each position in `p2'. */ +static reg_errcode_t +tre_make_trans(tre_pos_and_tags_t *p1, tre_pos_and_tags_t *p2, + tre_tnfa_transition_t *transitions, + int *counts, int *offs) +{ + tre_pos_and_tags_t *orig_p2 = p2; + tre_tnfa_transition_t *trans; + int i, j, k, l, dup, prev_p2_pos; + + if (transitions != NULL) + while (p1->position >= 0) + { + p2 = orig_p2; + prev_p2_pos = -1; + while (p2->position >= 0) + { + /* Optimization: if this position was already handled, skip it. */ + if (p2->position == prev_p2_pos) + { + p2++; + continue; + } + prev_p2_pos = p2->position; + /* Set `trans' to point to the next unused transition from + position `p1->position'. */ + trans = transitions + offs[p1->position]; + while (trans->state != NULL) + { +#if 0 + /* If we find a previous transition from `p1->position' to + `p2->position', it is overwritten. This can happen only + if there are nested loops in the regexp, like in "((a)*)*". + In POSIX.2 repetition using the outer loop is always + preferred over using the inner loop. Therefore the + transition for the inner loop is useless and can be thrown + away. */ + /* XXX - The same position is used for all nodes in a bracket + expression, so this optimization cannot be used (it will + break bracket expressions) unless I figure out a way to + detect it here. */ + if (trans->state_id == p2->position) + { + break; + } +#endif + trans++; + } + + if (trans->state == NULL) + (trans + 1)->state = NULL; + /* Use the character ranges, assertions, etc. from `p1' for + the transition from `p1' to `p2'. */ + trans->code_min = p1->code_min; + trans->code_max = p1->code_max; + trans->state = transitions + offs[p2->position]; + trans->state_id = p2->position; + trans->assertions = p1->assertions | p2->assertions + | (p1->class ? ASSERT_CHAR_CLASS : 0) + | (p1->neg_classes != NULL ? ASSERT_CHAR_CLASS_NEG : 0); + if (p1->backref >= 0) + { + assert((trans->assertions & ASSERT_CHAR_CLASS) == 0); + assert(p2->backref < 0); + trans->u.backref = p1->backref; + trans->assertions |= ASSERT_BACKREF; + } + else + trans->u.class = p1->class; + if (p1->neg_classes != NULL) + { + for (i = 0; p1->neg_classes[i] != (tre_ctype_t)0; i++); + trans->neg_classes = + xmalloc(sizeof(*trans->neg_classes) * (i + 1)); + if (trans->neg_classes == NULL) + return REG_ESPACE; + for (i = 0; p1->neg_classes[i] != (tre_ctype_t)0; i++) + trans->neg_classes[i] = p1->neg_classes[i]; + trans->neg_classes[i] = (tre_ctype_t)0; + } + else + trans->neg_classes = NULL; + + /* Find out how many tags this transition has. */ + i = 0; + if (p1->tags != NULL) + while(p1->tags[i] >= 0) + i++; + j = 0; + if (p2->tags != NULL) + while(p2->tags[j] >= 0) + j++; + + /* If we are overwriting a transition, free the old tag array. */ + if (trans->tags != NULL) + xfree(trans->tags); + trans->tags = NULL; + + /* If there were any tags, allocate an array and fill it. */ + if (i + j > 0) + { + trans->tags = xmalloc(sizeof(*trans->tags) * (i + j + 1)); + if (!trans->tags) + return REG_ESPACE; + i = 0; + if (p1->tags != NULL) + while(p1->tags[i] >= 0) + { + trans->tags[i] = p1->tags[i]; + i++; + } + l = i; + j = 0; + if (p2->tags != NULL) + while (p2->tags[j] >= 0) + { + /* Don't add duplicates. */ + dup = 0; + for (k = 0; k < i; k++) + if (trans->tags[k] == p2->tags[j]) + { + dup = 1; + break; + } + if (!dup) + trans->tags[l++] = p2->tags[j]; + j++; + } + trans->tags[l] = -1; + } + + p2++; + } + p1++; + } + else + /* Compute a maximum limit for the number of transitions leaving + from each state. */ + while (p1->position >= 0) + { + p2 = orig_p2; + while (p2->position >= 0) + { + counts[p1->position]++; + p2++; + } + p1++; + } + return REG_OK; +} + +/* Converts the syntax tree to a TNFA. All the transitions in the TNFA are + labelled with one character range (there are no transitions on empty + strings). The TNFA takes O(n^2) space in the worst case, `n' is size of + the regexp. */ +static reg_errcode_t +tre_ast_to_tnfa(tre_ast_node_t *node, tre_tnfa_transition_t *transitions, + int *counts, int *offs) +{ + tre_union_t *uni; + tre_catenation_t *cat; + tre_iteration_t *iter; + reg_errcode_t errcode = REG_OK; + + /* XXX - recurse using a stack!. */ + switch (node->type) + { + case LITERAL: + break; + case UNION: + uni = (tre_union_t *)node->obj; + errcode = tre_ast_to_tnfa(uni->left, transitions, counts, offs); + if (errcode != REG_OK) + return errcode; + errcode = tre_ast_to_tnfa(uni->right, transitions, counts, offs); + break; + + case CATENATION: + cat = (tre_catenation_t *)node->obj; + /* Add a transition from each position in cat->left->lastpos + to each position in cat->right->firstpos. */ + errcode = tre_make_trans(cat->left->lastpos, cat->right->firstpos, + transitions, counts, offs); + if (errcode != REG_OK) + return errcode; + errcode = tre_ast_to_tnfa(cat->left, transitions, counts, offs); + if (errcode != REG_OK) + return errcode; + errcode = tre_ast_to_tnfa(cat->right, transitions, counts, offs); + break; + + case ITERATION: + iter = (tre_iteration_t *)node->obj; + assert(iter->max == -1 || iter->max == 1); + + if (iter->max == -1) + { + assert(iter->min == 0 || iter->min == 1); + /* Add a transition from each last position in the iterated + expression to each first position. */ + errcode = tre_make_trans(iter->arg->lastpos, iter->arg->firstpos, + transitions, counts, offs); + if (errcode != REG_OK) + return errcode; + } + errcode = tre_ast_to_tnfa(iter->arg, transitions, counts, offs); + break; + } + return errcode; +} + + +#define ERROR_EXIT(err) \ + do \ + { \ + errcode = err; \ + if (/*CONSTCOND*/1) \ + goto error_exit; \ + } \ + while (/*CONSTCOND*/0) + + +int +regcomp(regex_t *restrict preg, const char *restrict regex, int cflags) +{ + tre_stack_t *stack; + tre_ast_node_t *tree, *tmp_ast_l, *tmp_ast_r; + tre_pos_and_tags_t *p; + int *counts = NULL, *offs = NULL; + int i, add = 0; + tre_tnfa_transition_t *transitions, *initial; + tre_tnfa_t *tnfa = NULL; + tre_submatch_data_t *submatch_data; + tre_tag_direction_t *tag_directions = NULL; + reg_errcode_t errcode; + tre_mem_t mem; + + /* Parse context. */ + tre_parse_ctx_t parse_ctx; + + /* Allocate a stack used throughout the compilation process for various + purposes. */ + stack = tre_stack_new(512, 1024000, 128); + if (!stack) + return REG_ESPACE; + /* Allocate a fast memory allocator. */ + mem = tre_mem_new(); + if (!mem) + { + tre_stack_destroy(stack); + return REG_ESPACE; + } + + /* Parse the regexp. */ + memset(&parse_ctx, 0, sizeof(parse_ctx)); + parse_ctx.mem = mem; + parse_ctx.stack = stack; + parse_ctx.start = regex; + parse_ctx.cflags = cflags; + parse_ctx.max_backref = -1; + errcode = tre_parse(&parse_ctx); + if (errcode != REG_OK) + ERROR_EXIT(errcode); + preg->re_nsub = parse_ctx.submatch_id - 1; + tree = parse_ctx.n; + +#ifdef TRE_DEBUG + tre_ast_print(tree); +#endif /* TRE_DEBUG */ + + /* Referring to nonexistent subexpressions is illegal. */ + if (parse_ctx.max_backref > (int)preg->re_nsub) + ERROR_EXIT(REG_ESUBREG); + + /* Allocate the TNFA struct. */ + tnfa = xcalloc(1, sizeof(tre_tnfa_t)); + if (tnfa == NULL) + ERROR_EXIT(REG_ESPACE); + tnfa->have_backrefs = parse_ctx.max_backref >= 0; + tnfa->have_approx = 0; + tnfa->num_submatches = parse_ctx.submatch_id; + + /* Set up tags for submatch addressing. If REG_NOSUB is set and the + regexp does not have back references, this can be skipped. */ + if (tnfa->have_backrefs || !(cflags & REG_NOSUB)) + { + + /* Figure out how many tags we will need. */ + errcode = tre_add_tags(NULL, stack, tree, tnfa); + if (errcode != REG_OK) + ERROR_EXIT(errcode); + + if (tnfa->num_tags > 0) + { + tag_directions = xmalloc(sizeof(*tag_directions) + * (tnfa->num_tags + 1)); + if (tag_directions == NULL) + ERROR_EXIT(REG_ESPACE); + tnfa->tag_directions = tag_directions; + memset(tag_directions, -1, + sizeof(*tag_directions) * (tnfa->num_tags + 1)); + } + tnfa->minimal_tags = xcalloc((unsigned)tnfa->num_tags * 2 + 1, + sizeof(*tnfa->minimal_tags)); + if (tnfa->minimal_tags == NULL) + ERROR_EXIT(REG_ESPACE); + + submatch_data = xcalloc((unsigned)parse_ctx.submatch_id, + sizeof(*submatch_data)); + if (submatch_data == NULL) + ERROR_EXIT(REG_ESPACE); + tnfa->submatch_data = submatch_data; + + errcode = tre_add_tags(mem, stack, tree, tnfa); + if (errcode != REG_OK) + ERROR_EXIT(errcode); + + } + + /* Expand iteration nodes. */ + errcode = tre_expand_ast(mem, stack, tree, &parse_ctx.position, + tag_directions); + if (errcode != REG_OK) + ERROR_EXIT(errcode); + + /* Add a dummy node for the final state. + XXX - For certain patterns this dummy node can be optimized away, + for example "a*" or "ab*". Figure out a simple way to detect + this possibility. */ + tmp_ast_l = tree; + tmp_ast_r = tre_ast_new_literal(mem, 0, 0, parse_ctx.position++); + if (tmp_ast_r == NULL) + ERROR_EXIT(REG_ESPACE); + + tree = tre_ast_new_catenation(mem, tmp_ast_l, tmp_ast_r); + if (tree == NULL) + ERROR_EXIT(REG_ESPACE); + + errcode = tre_compute_nfl(mem, stack, tree); + if (errcode != REG_OK) + ERROR_EXIT(errcode); + + counts = xmalloc(sizeof(int) * parse_ctx.position); + if (counts == NULL) + ERROR_EXIT(REG_ESPACE); + + offs = xmalloc(sizeof(int) * parse_ctx.position); + if (offs == NULL) + ERROR_EXIT(REG_ESPACE); + + for (i = 0; i < parse_ctx.position; i++) + counts[i] = 0; + tre_ast_to_tnfa(tree, NULL, counts, NULL); + + add = 0; + for (i = 0; i < parse_ctx.position; i++) + { + offs[i] = add; + add += counts[i] + 1; + counts[i] = 0; + } + transitions = xcalloc((unsigned)add + 1, sizeof(*transitions)); + if (transitions == NULL) + ERROR_EXIT(REG_ESPACE); + tnfa->transitions = transitions; + tnfa->num_transitions = add; + + errcode = tre_ast_to_tnfa(tree, transitions, counts, offs); + if (errcode != REG_OK) + ERROR_EXIT(errcode); + + tnfa->firstpos_chars = NULL; + + p = tree->firstpos; + i = 0; + while (p->position >= 0) + { + i++; + p++; + } + + initial = xcalloc((unsigned)i + 1, sizeof(tre_tnfa_transition_t)); + if (initial == NULL) + ERROR_EXIT(REG_ESPACE); + tnfa->initial = initial; + + i = 0; + for (p = tree->firstpos; p->position >= 0; p++) + { + initial[i].state = transitions + offs[p->position]; + initial[i].state_id = p->position; + initial[i].tags = NULL; + /* Copy the arrays p->tags, and p->params, they are allocated + from a tre_mem object. */ + if (p->tags) + { + int j; + for (j = 0; p->tags[j] >= 0; j++); + initial[i].tags = xmalloc(sizeof(*p->tags) * (j + 1)); + if (!initial[i].tags) + ERROR_EXIT(REG_ESPACE); + memcpy(initial[i].tags, p->tags, sizeof(*p->tags) * (j + 1)); + } + initial[i].assertions = p->assertions; + i++; + } + initial[i].state = NULL; + + tnfa->num_transitions = add; + tnfa->final = transitions + offs[tree->lastpos[0].position]; + tnfa->num_states = parse_ctx.position; + tnfa->cflags = cflags; + + tre_mem_destroy(mem); + tre_stack_destroy(stack); + xfree(counts); + xfree(offs); + + preg->TRE_REGEX_T_FIELD = (void *)tnfa; + return REG_OK; + + error_exit: + /* Free everything that was allocated and return the error code. */ + tre_mem_destroy(mem); + if (stack != NULL) + tre_stack_destroy(stack); + if (counts != NULL) + xfree(counts); + if (offs != NULL) + xfree(offs); + preg->TRE_REGEX_T_FIELD = (void *)tnfa; + regfree(preg); + return errcode; +} + + + + +void +regfree(regex_t *preg) +{ + tre_tnfa_t *tnfa; + unsigned int i; + tre_tnfa_transition_t *trans; + + tnfa = (void *)preg->TRE_REGEX_T_FIELD; + if (!tnfa) + return; + + for (i = 0; i < tnfa->num_transitions; i++) + if (tnfa->transitions[i].state) + { + if (tnfa->transitions[i].tags) + xfree(tnfa->transitions[i].tags); + if (tnfa->transitions[i].neg_classes) + xfree(tnfa->transitions[i].neg_classes); + } + if (tnfa->transitions) + xfree(tnfa->transitions); + + if (tnfa->initial) + { + for (trans = tnfa->initial; trans->state; trans++) + { + if (trans->tags) + xfree(trans->tags); + } + xfree(tnfa->initial); + } + + if (tnfa->submatch_data) + { + for (i = 0; i < tnfa->num_submatches; i++) + if (tnfa->submatch_data[i].parents) + xfree(tnfa->submatch_data[i].parents); + xfree(tnfa->submatch_data); + } + + if (tnfa->tag_directions) + xfree(tnfa->tag_directions); + if (tnfa->firstpos_chars) + xfree(tnfa->firstpos_chars); + if (tnfa->minimal_tags) + xfree(tnfa->minimal_tags); + xfree(tnfa); +} |