glibc/posix/regexec.c
Ulrich Drepper 81c64d407c Update.
2002-07-10  Ulrich Drepper  <drepper@redhat.com>
	* Versions.def [libpthread]: Add GLIBC_2.2.6.
	* posix/Versions [libc] (GLIBC_2.2.6): Add __nanosleep.

2002-07-06  Bruno Haible  <bruno@clisp.org>

	* sysdeps/unix/sysv/sysv4/bits/sigset.h (__NSSBITS): Correct value.
	* sysdeps/unix/sysv/linux/bits/statvfs.h (ST_NODIRATIME): Set to 2048.
2002-07-10 23:09:16 +00:00

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/* Extended regular expression matching and search library.
Copyright (C) 2002 Free Software Foundation, Inc.
This file is part of the GNU C Library.
Contributed by Isamu Hasegawa <isamu@yamato.ibm.com>.
The GNU C Library is free software; you can redistribute it and/or
modify it under the terms of the GNU Lesser General Public
License as published by the Free Software Foundation; either
version 2.1 of the License, or (at your option) any later version.
The GNU C Library 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
Lesser General Public License for more details.
You should have received a copy of the GNU Lesser General Public
License along with the GNU C Library; if not, write to the Free
Software Foundation, Inc., 59 Temple Place, Suite 330, Boston, MA
02111-1307 USA. */
#include <assert.h>
#include <ctype.h>
#include <stdio.h>
#include <stdlib.h>
#include <string.h>
#include <wchar.h>
#include <wctype.h>
#ifdef _LIBC
# ifndef _RE_DEFINE_LOCALE_FUNCTIONS
# define _RE_DEFINE_LOCALE_FUNCTIONS 1
# include <locale/localeinfo.h>
# include <locale/elem-hash.h>
# include <locale/coll-lookup.h>
# endif
#endif
#include "regex.h"
#include "regex_internal.h"
static reg_errcode_t match_ctx_init (re_match_context_t *cache, int eflags,
re_string_t *input, int n);
static void match_ctx_free (re_match_context_t *cache);
static reg_errcode_t match_ctx_add_entry (re_match_context_t *cache, int node,
int from, int to);
static reg_errcode_t re_search_internal (const regex_t *preg,
const char *string, int length,
int start, int range, size_t nmatch,
regmatch_t pmatch[], int eflags);
static inline re_dfastate_t *acquire_init_state_context (reg_errcode_t *err,
const regex_t *preg,
const re_match_context_t *mctx,
int idx);
static int check_matching (const regex_t *preg, re_match_context_t *mctx,
int fl_search, int fl_longest_match);
static int check_halt_node_context (const re_dfa_t *dfa, int node,
unsigned int context);
static int check_halt_state_context (const regex_t *preg,
const re_dfastate_t *state,
const re_match_context_t *mctx, int idx);
static void update_regs (re_dfa_t *dfa, regmatch_t *pmatch, int cur_node,
int cur_idx, int nmatch);
static int proceed_next_node (const regex_t *preg,
const re_match_context_t *mctx,
int *pidx, int node, re_node_set *eps_via_nodes);
static reg_errcode_t set_regs (const regex_t *preg,
const re_match_context_t *mctx,
size_t nmatch, regmatch_t *pmatch, int last);
#ifdef RE_ENABLE_I18N
static int sift_states_iter_mb (const regex_t *preg,
const re_match_context_t *mctx,
int node_idx, int str_idx, int max_str_idx);
#endif /* RE_ENABLE_I18N */
static int sift_states_iter_bkref (const re_dfa_t *dfa,
re_dfastate_t **state_log,
struct re_backref_cache_entry *mctx_entry,
int node_idx, int idx, int match_last);
static reg_errcode_t sift_states_backward (const regex_t *preg,
const re_match_context_t *mctx,
int last_node);
static reg_errcode_t clean_state_log_if_need (re_match_context_t *mctx,
int next_state_log_idx);
static reg_errcode_t add_epsilon_backreference (const re_dfa_t *dfa,
const re_match_context_t *mctx,
const re_node_set *plog,
int idx,
re_node_set *state_buf);
static re_dfastate_t *transit_state (reg_errcode_t *err, const regex_t *preg,
re_match_context_t *mctx,
re_dfastate_t *state, int fl_search);
static re_dfastate_t *transit_state_sb (reg_errcode_t *err, const regex_t *preg,
re_dfastate_t *pstate,
int fl_search,
re_match_context_t *mctx);
#ifdef RE_ENABLE_I18N
static reg_errcode_t transit_state_mb (const regex_t *preg,
re_dfastate_t *pstate,
re_match_context_t *mctx);
#endif /* RE_ENABLE_I18N */
static reg_errcode_t transit_state_bkref (const regex_t *preg,
re_dfastate_t *pstate,
re_match_context_t *mctx);
static reg_errcode_t transit_state_bkref_loop (const regex_t *preg,
re_node_set *nodes,
re_dfastate_t **work_state_log,
re_match_context_t *mctx);
static re_dfastate_t **build_trtable (const regex_t *dfa,
const re_dfastate_t *state,
int fl_search);
#ifdef RE_ENABLE_I18N
static int check_node_accept_bytes (const regex_t *preg, int node_idx,
const re_string_t *input, int idx);
# ifdef _LIBC
static unsigned int find_collation_sequence_value (const unsigned char *mbs,
size_t name_len);
# endif /* _LIBC */
#endif /* RE_ENABLE_I18N */
static int group_nodes_into_DFAstates (const regex_t *dfa,
const re_dfastate_t *state,
re_node_set *states_node,
bitset *states_ch);
static int check_node_accept (const regex_t *preg, const re_token_t *node,
const re_match_context_t *mctx, int idx);
static reg_errcode_t extend_buffers (re_match_context_t *mctx);
/* Entry point for POSIX code. */
/* 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. */
int
regexec (preg, string, nmatch, pmatch, eflags)
const regex_t *preg;
const char *string;
size_t nmatch;
regmatch_t pmatch[];
int eflags;
{
reg_errcode_t err;
int length = strlen (string);
if (preg->no_sub)
err = re_search_internal (preg, string, length, 0, length, 0,
NULL, eflags);
else
err = re_search_internal (preg, string, length, 0, length, nmatch,
pmatch, eflags);
return err != REG_NOERROR;
}
#ifdef _LIBC
weak_alias (__regexec, regexec)
#endif
/* Entry points for GNU code. */
/* re_match is like re_match_2 except it takes only a single string. */
int
re_match (buffer, string, length, start, regs)
struct re_pattern_buffer *buffer;
const char *string;
int length, start;
struct re_registers *regs;
{
reg_errcode_t result;
int i, tmp_nregs, nregs, rval, eflags = 0;
regmatch_t *pmatch;
eflags |= (buffer->not_bol) ? REG_NOTBOL : 0;
eflags |= (buffer->not_eol) ? REG_NOTEOL : 0;
/* We need at least 1 register. */
tmp_nregs = ((buffer->no_sub || regs == NULL || regs->num_regs < 1) ? 1
: regs->num_regs);
nregs = ((tmp_nregs < buffer->re_nsub + 1
&& buffer->regs_allocated == REGS_FIXED) ? tmp_nregs
: buffer->re_nsub + 1);
pmatch = re_malloc (regmatch_t, nregs);
if (BE (pmatch == NULL, 0))
return -2;
result = re_search_internal (buffer, string, length, start, 0,
nregs, pmatch, eflags);
/* If caller wants register contents data back, do it. */
if (regs && !buffer->no_sub)
{
/* Have the register data arrays been allocated? */
if (buffer->regs_allocated == REGS_UNALLOCATED)
{ /* No. So allocate them with malloc. We need one
extra element beyond `num_regs' for the `-1' marker
GNU code uses. */
regs->num_regs = buffer->re_nsub + 1;
regs->start = re_malloc (regoff_t, regs->num_regs);
regs->end = re_malloc (regoff_t, regs->num_regs);
if (BE (regs->start == NULL || regs->end == NULL, 0))
{
re_free (pmatch);
return -2;
}
buffer->regs_allocated = REGS_REALLOCATE;
}
else if (buffer->regs_allocated == REGS_REALLOCATE)
{ /* Yes. If we need more elements than were already
allocated, reallocate them. If we need fewer, just
leave it alone. */
if (regs->num_regs < buffer->re_nsub + 1)
{
regs->num_regs = buffer->re_nsub + 1;
regs->start = re_realloc (regs->start, regoff_t, regs->num_regs);
regs->end = re_realloc (regs->end, regoff_t, regs->num_regs);
if (BE (regs->start == NULL || regs->end == NULL, 0))
{
re_free (pmatch);
return -2;
}
}
}
else
{
/* These braces fend off a "empty body in an else-statement"
warning under GCC when assert expands to nothing. */
assert (buffer->regs_allocated == REGS_FIXED);
}
}
/* Restore registers. */
if (regs != NULL)
{
int max_regs = ((regs->num_regs < buffer->re_nsub + 1) ? regs->num_regs
: buffer->re_nsub + 1);
for (i = 0; i < max_regs; ++i)
{
regs->start[i] = pmatch[i].rm_so;
regs->end[i] = pmatch[i].rm_eo;
}
for ( ; i < regs->num_regs; ++i)
{
regs->start[i] = -1;
regs->end[i] = -1;
}
}
/* Return value is -1 if not match, the length of mathing otherwise. */
rval = (result != REG_NOERROR) ? -1 : pmatch[0].rm_eo - pmatch[0].rm_so;
re_free (pmatch);
return rval;
}
#ifdef _LIBC
weak_alias (__re_match, re_match)
#endif
/* re_match_2 matches the compiled pattern in BUFP against the
the (virtual) concatenation of STRING1 and STRING2 (of length SIZE1
and SIZE2, respectively). We start matching at POS, and stop
matching at STOP.
If REGS is non-null and the `no_sub' field of BUFP is nonzero, we
store offsets for the substring each group matched in REGS. See the
documentation for exactly how many groups we fill.
We return -1 if no match, -2 if an internal error.
Otherwise, we return the length of the matched substring. */
int
re_match_2 (buffer, string1, length1, string2, length2, start, regs, stop)
struct re_pattern_buffer *buffer;
const char *string1, *string2;
int length1, length2, start, stop;
struct re_registers *regs;
{
int len, ret;
char *str = re_malloc (char, length1 + length2);
if (BE (str == NULL, 0))
return -2;
memcpy (str, string1, length1);
memcpy (str + length1, string2, length2);
len = (length1 + length2 < stop) ? length1 + length2 : stop;
ret = re_match (buffer, str, len, start, regs);
re_free (str);
return ret;
}
#ifdef _LIBC
weak_alias (__re_match_2, re_match_2)
#endif
/* Like re_search_2, below, but only one string is specified, and
doesn't let you say where to stop matching. */
int
re_search (bufp, string, size, startpos, range, regs)
struct re_pattern_buffer *bufp;
const char *string;
int size, startpos, range;
struct re_registers *regs;
{
reg_errcode_t result;
int i, tmp_nregs, nregs, real_range, rval, eflags = 0;
regmatch_t *pmatch;
eflags |= (bufp->not_bol) ? REG_NOTBOL : 0;
eflags |= (bufp->not_eol) ? REG_NOTEOL : 0;
/* Check for out-of-range. */
if (BE (startpos < 0 || startpos > size, 0))
return -1;
/* We need at least 1 register. */
tmp_nregs = ((bufp->no_sub || regs == NULL || regs->num_regs < 1) ? 1
: regs->num_regs);
nregs = ((tmp_nregs < bufp->re_nsub + 1
&& bufp->regs_allocated == REGS_FIXED) ? tmp_nregs
: bufp->re_nsub + 1);
pmatch = re_malloc (regmatch_t, nregs);
if (BE (pmatch == NULL, 0))
return -2;
/* Correct range if we need. */
real_range = ((startpos + range > size) ? size - startpos
: ((startpos + range < 0) ? -startpos : range));
/* Compile fastmap if we haven't yet. */
if (bufp->fastmap != NULL && !bufp->fastmap_accurate)
re_compile_fastmap (bufp);
result = re_search_internal (bufp, string, size, startpos, real_range,
nregs, pmatch, eflags);
/* If caller wants register contents data back, do it. */
if (regs && !bufp->no_sub)
{
/* Have the register data arrays been allocated? */
if (bufp->regs_allocated == REGS_UNALLOCATED)
{ /* No. So allocate them with malloc. We need one
extra element beyond `num_regs' for the `-1' marker
GNU code uses. */
regs->num_regs = bufp->re_nsub + 1;
regs->start = re_malloc (regoff_t, regs->num_regs);
regs->end = re_malloc (regoff_t, regs->num_regs);
if (BE (regs->start == NULL || regs->end == NULL, 0))
{
re_free (pmatch);
return -2;
}
bufp->regs_allocated = REGS_REALLOCATE;
}
else if (bufp->regs_allocated == REGS_REALLOCATE)
{ /* Yes. If we need more elements than were already
allocated, reallocate them. If we need fewer, just
leave it alone. */
if (regs->num_regs < bufp->re_nsub + 1)
{
regs->num_regs = bufp->re_nsub + 1;
regs->start = re_realloc (regs->start, regoff_t, regs->num_regs);
regs->end = re_realloc (regs->end, regoff_t, regs->num_regs);
if (BE (regs->start == NULL || regs->end == NULL, 0))
{
re_free (pmatch);
return -2;
}
}
}
else
{
/* These braces fend off a "empty body in an else-statement"
warning under GCC when assert expands to nothing. */
assert (bufp->regs_allocated == REGS_FIXED);
}
}
/* Restore registers. */
if (regs != NULL)
{
int max_regs = ((regs->num_regs < bufp->re_nsub + 1) ? regs->num_regs
: bufp->re_nsub + 1);
for (i = 0; i < max_regs; ++i)
{
regs->start[i] = pmatch[i].rm_so;
regs->end[i] = pmatch[i].rm_eo;
}
for ( ; i < regs->num_regs; ++i)
{
regs->start[i] = -1;
regs->end[i] = -1;
}
}
/* Return value is -1 if not match, the position where the mathing starts
otherwise. */
rval = (result != REG_NOERROR) ? -1 : pmatch[0].rm_so;
re_free (pmatch);
return rval;
}
#ifdef _LIBC
weak_alias (__re_search, re_search)
#endif
/* Using the compiled pattern in BUFP, first tries to match the virtual
concatenation of STRING1 and STRING2, starting first at index
STARTPOS, then at STARTPOS + 1, and so on.
STRING1 and STRING2 have length SIZE1 and SIZE2, respectively.
RANGE is how far to scan while trying to match. RANGE = 0 means try
only at STARTPOS; in general, the last start tried is STARTPOS +
RANGE.
In REGS, return the indices of the virtual concatenation of STRING1
and STRING2 that matched the entire BUFP->buffer and its contained
subexpressions.
Do not consider matching one past the index STOP in the virtual
concatenation of STRING1 and STRING2.
We return either the position in the strings at which the match was
found, -1 if no match, or -2 if error. */
int
re_search_2 (bufp, string1, length1, string2, length2, start, range, regs,
stop)
struct re_pattern_buffer *bufp;
const char *string1, *string2;
int length1, length2, start, range, stop;
struct re_registers *regs;
{
int len, ret;
char *str = re_malloc (char, length1 + length2);
memcpy (str, string1, length1);
memcpy (str + length1, string2, length2);
len = (length1 + length2 < stop) ? length1 + length2 : stop;
ret = re_search (bufp, str, len, start, range, regs);
re_free (str);
return ret;
}
#ifdef _LIBC
weak_alias (__re_search_2, re_search_2)
#endif
/* 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. */
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, *ends;
{
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 _LIBC
weak_alias (__re_set_registers, re_set_registers)
#endif
/* Entry points compatible with 4.2 BSD regex library. We don't define
them unless specifically requested. */
#if defined _REGEX_RE_COMP || defined _LIBC
int
# ifdef _LIBC
weak_function
# endif
re_exec (s)
const char *s;
{
return 0 == regexec (&re_comp_buf, s, 0, NULL, 0);
}
#endif /* _REGEX_RE_COMP */
static re_node_set empty_set;
/* Internal entry point. */
/* Searches for a compiled pattern PREG in the string STRING, whose
length is LENGTH. NMATCH, PMATCH, and EFLAGS have the same
mingings with regexec. START, and RANGE have the same meanings
with re_search.
Return REG_NOERROR if we find a match, and REG_NOMATCH if not,
otherwise return the error code.
Note: We assume front end functions already check ranges.
(START + RANGE >= 0 && START + RANGE <= LENGTH) */
static reg_errcode_t
re_search_internal (preg, string, length, start, range, nmatch, pmatch, eflags)
const regex_t *preg;
const char *string;
int length, start, range, eflags;
size_t nmatch;
regmatch_t pmatch[];
{
reg_errcode_t err;
re_dfa_t *dfa = (re_dfa_t *)preg->buffer;
re_string_t input;
int left_lim, right_lim, incr;
int fl_longest_match, match_first, match_last = -1;
re_match_context_t mctx;
char *fastmap = ((preg->fastmap != NULL && preg->fastmap_accurate)
? preg->fastmap : NULL);
/* Check if the DFA haven't been compiled. */
if (BE (preg->used == 0 || dfa->init_state == NULL
|| dfa->init_state_word == NULL || dfa->init_state_nl == NULL
|| dfa->init_state_begbuf == NULL, 0))
return REG_NOMATCH;
re_node_set_init_empty (&empty_set);
/* We must check the longest matching, if nmatch > 0. */
fl_longest_match = (nmatch != 0);
err = re_string_allocate (&input, string, length, dfa->nodes_len + 1,
preg->translate, preg->syntax & RE_ICASE);
if (BE (err != REG_NOERROR, 0))
return err;
err = match_ctx_init (&mctx, eflags, &input, dfa->nbackref * 2);
if (BE (err != REG_NOERROR, 0))
return err;
/* We will log all the DFA states through which the dfa pass,
if nmatch > 1, or this dfa has "multibyte node", which is a
back-reference or a node which can accept multibyte character or
multi character collating element. */
if (nmatch > 1 || dfa->has_mb_node)
{
mctx.state_log = re_malloc (re_dfastate_t *, dfa->nodes_len + 1);
if (BE (mctx.state_log == NULL, 0))
return REG_ESPACE;
}
else
mctx.state_log = NULL;
#ifdef DEBUG
/* We assume front-end functions already check them. */
assert (start + range >= 0 && start + range <= length);
#endif
match_first = start;
input.tip_context = ((eflags & REG_NOTBOL) ? CONTEXT_BEGBUF
: CONTEXT_NEWLINE | CONTEXT_BEGBUF);
/* Check incrementally whether of not the input string match. */
incr = (range < 0) ? -1 : 1;
left_lim = (range < 0) ? start + range : start;
right_lim = (range < 0) ? start : start + range;
for (;;)
{
/* At first get the current byte from input string. */
int ch;
if (MB_CUR_MAX > 1 && (preg->syntax & RE_ICASE || preg->translate))
{
/* In this case, we can't determin easily the current byte,
since it might be a component byte of a multibyte character.
Then we use the constructed buffer instead. */
/* If MATCH_FIRST is out of the valid range, reconstruct the
buffers. */
if (input.raw_mbs_idx + input.valid_len <= match_first)
re_string_reconstruct (&input, match_first, eflags,
preg->newline_anchor);
/* If MATCH_FIRST is out of the buffer, leave it as '\0'.
Note that MATCH_FIRST must not be smaller than 0. */
ch = ((match_first >= length) ? 0
: re_string_byte_at (&input, match_first - input.raw_mbs_idx));
}
else
{
/* We apply translate/conversion manually, since it is trivial
in this case. */
/* If MATCH_FIRST is out of the buffer, leave it as '\0'.
Note that MATCH_FIRST must not be smaller than 0. */
ch = (match_first < length) ? (unsigned char)string[match_first] : 0;
/* Apply translation if we need. */
ch = preg->translate ? preg->translate[ch] : ch;
/* In case of case insensitive mode, convert to upper case. */
ch = ((preg->syntax & RE_ICASE) && islower (ch)) ? toupper (ch) : ch;
}
/* Eliminate inappropriate one by fastmap. */
if (preg->can_be_null || fastmap == NULL || fastmap[ch])
{
/* Reconstruct the buffers so that the matcher can assume that
the matching starts from the begining of the buffer. */
re_string_reconstruct (&input, match_first, eflags,
preg->newline_anchor);
#ifdef RE_ENABLE_I18N
/* Eliminate it when it is a component of a multibyte character
and isn't the head of a multibyte character. */
if (MB_CUR_MAX == 1 || re_string_first_byte (&input, 0))
#endif
{
/* It seems to be appropriate one, then use the matcher. */
/* We assume that the matching starts from 0. */
mctx.state_log_top = mctx.nbkref_ents = mctx.max_bkref_len = 0;
match_last = check_matching (preg, &mctx, 0, fl_longest_match);
if (match_last != -1)
{
if (BE (match_last == -2, 0))
return REG_ESPACE;
else
break; /* We found a matching. */
}
}
}
/* Update counter. */
match_first += incr;
if (match_first < left_lim || right_lim < match_first)
break;
}
/* Set pmatch[] if we need. */
if (match_last != -1 && nmatch > 0)
{
int reg_idx;
/* Initialize registers. */
for (reg_idx = 0; reg_idx < nmatch; ++reg_idx)
pmatch[reg_idx].rm_so = pmatch[reg_idx].rm_eo = -1;
/* Set the points where matching start/end. */
pmatch[0].rm_so = 0;
mctx.match_last = pmatch[0].rm_eo = match_last;
if (!preg->no_sub && nmatch > 1)
{
/* We need the ranges of all the subexpressions. */
int halt_node;
re_dfastate_t *pstate = mctx.state_log[match_last];
#ifdef DEBUG
assert (mctx.state_log != NULL);
#endif
halt_node = check_halt_state_context (preg, pstate, &mctx,
match_last);
err = sift_states_backward (preg, &mctx, halt_node);
if (BE (err != REG_NOERROR, 0))
return err;
err = set_regs (preg, &mctx, nmatch, pmatch, halt_node);
if (BE (err != REG_NOERROR, 0))
return err;
}
/* At last, add the offset to the each registers, since we slided
the buffers so that We can assume that the matching starts from 0. */
for (reg_idx = 0; reg_idx < nmatch; ++reg_idx)
if (pmatch[reg_idx].rm_so != -1)
{
pmatch[reg_idx].rm_so += match_first;
pmatch[reg_idx].rm_eo += match_first;
}
}
re_free (mctx.state_log);
if (dfa->nbackref)
match_ctx_free (&mctx);
re_string_destruct (&input);
return (match_last == -1) ? REG_NOMATCH : REG_NOERROR;
}
/* Acquire an initial state and return it.
We must select appropriate initial state depending on the context,
since initial states may have constraints like "\<", "^", etc.. */
static inline re_dfastate_t *
acquire_init_state_context (err, preg, mctx, idx)
reg_errcode_t *err;
const regex_t *preg;
const re_match_context_t *mctx;
int idx;
{
re_dfa_t *dfa = (re_dfa_t *) preg->buffer;
*err = REG_NOERROR;
if (dfa->init_state->has_constraint)
{
unsigned int context;
context = re_string_context_at (mctx->input, idx - 1, mctx->eflags,
preg->newline_anchor);
if (IS_WORD_CONTEXT (context))
return dfa->init_state_word;
else if (IS_ORDINARY_CONTEXT (context))
return dfa->init_state;
else if (IS_BEGBUF_CONTEXT (context) && IS_NEWLINE_CONTEXT (context))
return dfa->init_state_begbuf;
else if (IS_NEWLINE_CONTEXT (context))
return dfa->init_state_nl;
else if (IS_BEGBUF_CONTEXT (context))
{
/* It is relatively rare case, then calculate on demand. */
return re_acquire_state_context (err, dfa,
dfa->init_state->entrance_nodes,
context);
}
else
/* Must not happen? */
return dfa->init_state;
}
else
return dfa->init_state;
}
/* Check whether the regular expression match input string INPUT or not,
and return the index where the matching end, return -1 if not match,
or return -2 in case of an error.
FL_SEARCH means we must search where the matching starts,
FL_LONGEST_MATCH means we want the POSIX longest matching.
Note that the matcher assume that the maching starts from the current
index of the buffer. */
static int
check_matching (preg, mctx, fl_search, fl_longest_match)
const regex_t *preg;
re_match_context_t *mctx;
int fl_search, fl_longest_match;
{
reg_errcode_t err;
int match = 0;
int match_last = -1;
int cur_str_idx = re_string_cur_idx (mctx->input);
re_dfastate_t *cur_state;
cur_state = acquire_init_state_context (&err, preg, mctx, cur_str_idx);
/* An initial state must not be NULL(invalid state). */
if (BE (cur_state == NULL, 0))
return -2;
if (mctx->state_log != NULL)
mctx->state_log[cur_str_idx] = cur_state;
/* If the RE accepts NULL string. */
if (cur_state->halt)
{
if (!cur_state->has_constraint
|| check_halt_state_context (preg, cur_state, mctx, cur_str_idx))
{
if (!fl_longest_match)
return cur_str_idx;
else
{
match_last = cur_str_idx;
match = 1;
}
}
}
while (!re_string_eoi (mctx->input))
{
cur_state = transit_state (&err, preg, mctx, cur_state,
fl_search && !match);
if (cur_state == NULL) /* Reached at the invalid state or an error. */
{
cur_str_idx = re_string_cur_idx (mctx->input);
if (BE (err != REG_NOERROR, 0))
return -2;
if (fl_search && !match)
{
/* Restart from initial state, since we are searching
the point from where matching start. */
#ifdef RE_ENABLE_I18N
if (MB_CUR_MAX == 1
|| re_string_first_byte (mctx->input, cur_str_idx))
#endif /* RE_ENABLE_I18N */
cur_state = acquire_init_state_context (&err, preg, mctx,
cur_str_idx);
if (BE (cur_state == NULL && err != REG_NOERROR, 0))
return -2;
if (mctx->state_log != NULL)
mctx->state_log[cur_str_idx] = cur_state;
}
else if (!fl_longest_match && match)
break;
else /* (fl_longest_match && match) || (!fl_search && !match) */
{
if (mctx->state_log == NULL)
break;
else
{
int max = mctx->state_log_top;
for (; cur_str_idx <= max; ++cur_str_idx)
if (mctx->state_log[cur_str_idx] != NULL)
break;
if (cur_str_idx > max)
break;
}
}
}
if (cur_state != NULL && cur_state->halt)
{
/* Reached at a halt state.
Check the halt state can satisfy the current context. */
if (!cur_state->has_constraint
|| check_halt_state_context (preg, cur_state, mctx,
re_string_cur_idx (mctx->input)))
{
/* We found an appropriate halt state. */
match_last = re_string_cur_idx (mctx->input);
match = 1;
if (!fl_longest_match)
break;
}
}
}
return match_last;
}
/* Check NODE match the current context. */
static int check_halt_node_context (dfa, node, context)
const re_dfa_t *dfa;
int node;
unsigned int context;
{
int entity;
re_token_type_t type = dfa->nodes[node].type;
if (type == END_OF_RE)
return 1;
if (type != OP_CONTEXT_NODE)
return 0;
entity = dfa->nodes[node].opr.ctx_info->entity;
if (dfa->nodes[entity].type != END_OF_RE
|| NOT_SATISFY_NEXT_CONSTRAINT (dfa->nodes[node].constraint, context))
return 0;
return 1;
}
/* Check the halt state STATE match the current context.
Return 0 if not match, if the node, STATE has, is a halt node and
match the context, return the node. */
static int
check_halt_state_context (preg, state, mctx, idx)
const regex_t *preg;
const re_dfastate_t *state;
const re_match_context_t *mctx;
int idx;
{
re_dfa_t *dfa = (re_dfa_t *) preg->buffer;
int i;
unsigned int context;
#ifdef DEBUG
assert (state->halt);
#endif
context = re_string_context_at (mctx->input, idx, mctx->eflags,
preg->newline_anchor);
for (i = 0; i < state->nodes.nelem; ++i)
if (check_halt_node_context (dfa, state->nodes.elems[i], context))
return state->nodes.elems[i];
return 0;
}
/* Compute the next node to which "NFA" transit from NODE("NFA" is a NFA
corresponding to the DFA).
Return the destination node, and update EPS_VIA_NODES, return -1 in case
of errors. */
static int
proceed_next_node (preg, mctx, pidx, node, eps_via_nodes)
const regex_t *preg;
const re_match_context_t *mctx;
int *pidx, node;
re_node_set *eps_via_nodes;
{
re_dfa_t *dfa = (re_dfa_t *)preg->buffer;
int i, err, dest_node, cur_entity;
dest_node = -1;
cur_entity = ((dfa->nodes[node].type == OP_CONTEXT_NODE)
? dfa->nodes[node].opr.ctx_info->entity : node);
if (IS_EPSILON_NODE (dfa->nodes[node].type))
{
int dest_entity = INT_MAX;
err = re_node_set_insert (eps_via_nodes, node);
if (BE (err < 0, 0))
return -1;
for (i = 0; i < mctx->state_log[*pidx]->nodes.nelem; ++i)
{
int candidate, candidate_entity;
candidate = mctx->state_log[*pidx]->nodes.elems[i];
candidate_entity = ((dfa->nodes[candidate].type == OP_CONTEXT_NODE)
? dfa->nodes[candidate].opr.ctx_info->entity
: candidate);
if (!re_node_set_contains (dfa->edests + node, candidate))
if (candidate == candidate_entity
|| !re_node_set_contains (dfa->edests + node, candidate_entity))
continue;
/* In order to avoid infinite loop like "(a*)*". */
if (cur_entity > candidate_entity
&& re_node_set_contains (eps_via_nodes, candidate))
continue;
if (dest_entity > candidate_entity)
{
dest_node = candidate;
dest_entity = candidate_entity;
}
}
#ifdef DEBUG
assert (dest_node != -1);
#endif
return dest_node;
}
else
{
int naccepted = 0, entity = node;
re_token_type_t type = dfa->nodes[node].type;
if (type == OP_CONTEXT_NODE)
{
entity = dfa->nodes[node].opr.ctx_info->entity;
type = dfa->nodes[entity].type;
}
#ifdef RE_ENABLE_I18N
if (ACCEPT_MB_NODE (type))
naccepted = check_node_accept_bytes (preg, entity, mctx->input, *pidx);
else
#endif /* RE_ENABLE_I18N */
if (type == OP_BACK_REF)
{
for (i = 0; i < mctx->nbkref_ents; ++i)
{
if (mctx->bkref_ents[i].node == node
&& mctx->bkref_ents[i].from == *pidx)
naccepted = mctx->bkref_ents[i].to - *pidx;
}
if (naccepted == 0)
{
err = re_node_set_insert (eps_via_nodes, node);
if (BE (err < 0, 0))
return -1;
dest_node = dfa->nexts[node];
if (re_node_set_contains (&mctx->state_log[*pidx]->nodes,
dest_node))
return dest_node;
for (i = 0; i < mctx->state_log[*pidx]->nodes.nelem; ++i)
{
dest_node = mctx->state_log[*pidx]->nodes.elems[i];
if ((dfa->nodes[dest_node].type == OP_CONTEXT_NODE
&& (dfa->nexts[node]
== dfa->nodes[dest_node].opr.ctx_info->entity)))
return dest_node;
}
}
}
if (naccepted != 0
|| check_node_accept (preg, dfa->nodes + node, mctx, *pidx))
{
dest_node = dfa->nexts[node];
*pidx = (naccepted == 0) ? *pidx + 1 : *pidx + naccepted;
#ifdef DEBUG
assert (mctx->state_log[*pidx] != NULL);
#endif
re_node_set_empty (eps_via_nodes);
return dest_node;
}
}
/* Must not reach here. */
#ifdef DEBUG
assert (0);
#endif
return 0;
}
/* Set the positions where the subexpressions are starts/ends to registers
PMATCH.
Note: We assume that pmatch[0] is already set, and
pmatch[i].rm_so == pmatch[i].rm_eo == -1 (i > 1). */
static reg_errcode_t
set_regs (preg, mctx, nmatch, pmatch, last_node)
const regex_t *preg;
const re_match_context_t *mctx;
size_t nmatch;
regmatch_t *pmatch;
int last_node;
{
re_dfa_t *dfa = (re_dfa_t *)preg->buffer;
int idx, cur_node, real_nmatch;
re_node_set eps_via_nodes;
#ifdef DEBUG
assert (nmatch > 1);
assert (mctx->state_log != NULL);
#endif
cur_node = dfa->init_node;
real_nmatch = (nmatch <= preg->re_nsub) ? nmatch : preg->re_nsub + 1;
re_node_set_init_empty (&eps_via_nodes);
for (idx = pmatch[0].rm_so; idx <= pmatch[0].rm_eo ;)
{
update_regs (dfa, pmatch, cur_node, idx, real_nmatch);
if (idx == pmatch[0].rm_eo && cur_node == last_node)
break;
/* Proceed to next node. */
cur_node = proceed_next_node (preg, mctx, &idx, cur_node, &eps_via_nodes);
if (BE (cur_node < 0, 0))
return REG_ESPACE;
}
re_node_set_free (&eps_via_nodes);
return REG_NOERROR;
}
static void
update_regs (dfa, pmatch, cur_node, cur_idx, nmatch)
re_dfa_t *dfa;
regmatch_t *pmatch;
int cur_node, cur_idx, nmatch;
{
int type = dfa->nodes[cur_node].type;
int reg_num;
if (type != OP_OPEN_SUBEXP && type != OP_CLOSE_SUBEXP)
return;
reg_num = dfa->nodes[cur_node].opr.idx + 1;
if (reg_num >= nmatch)
return;
if (type == OP_OPEN_SUBEXP)
{
/* We are at the first node of this sub expression. */
pmatch[reg_num].rm_so = cur_idx;
pmatch[reg_num].rm_eo = -1;
}
else if (type == OP_CLOSE_SUBEXP)
/* We are at the first node of this sub expression. */
pmatch[reg_num].rm_eo = cur_idx;
}
#define NUMBER_OF_STATE 1
/* This function checks the STATE_LOG from the MCTX->match_last to 0
and sift the nodes in each states according to the following rules.
Updated state_log will be wrote to STATE_LOG.
Rules: We throw away the Node `a' in the STATE_LOG[STR_IDX] if...
1. When STR_IDX == MATCH_LAST(the last index in the state_log):
If `a' isn't the LAST_NODE and `a' can't epsilon transit to
the LAST_NODE, we throw away the node `a'.
2. When 0 <= STR_IDX < MATCH_LAST and `a' accepts
string `s' and transit to `b':
i. If 'b' isn't in the STATE_LOG[STR_IDX+strlen('s')], we throw
away the node `a'.
ii. If 'b' is in the STATE_LOG[STR_IDX+strlen('s')] but 'b' is
throwed away, we throw away the node `a'.
3. When 0 <= STR_IDX < n and 'a' epsilon transit to 'b':
i. If 'b' isn't in the STATE_LOG[STR_IDX], we throw away the
node `a'.
ii. If 'b' is in the STATE_LOG[STR_IDX] but 'b' is throwed away,
we throw away the node `a'. */
#define STATE_NODE_CONTAINS(state,node) \
((state) != NULL && re_node_set_contains (&(state)->nodes, node))
static reg_errcode_t
sift_states_backward (preg, mctx, last_node)
const regex_t *preg;
const re_match_context_t *mctx;
int last_node;
{
reg_errcode_t err;
re_dfa_t *dfa = (re_dfa_t *)preg->buffer;
re_node_set state_buf;
int str_idx = mctx->match_last;
re_node_set *plog; /* Points the state_log[str_idx]->nodes */
#ifdef DEBUG
assert (mctx->state_log != NULL && mctx->state_log[str_idx] != NULL);
#endif
err = re_node_set_alloc (&state_buf, NUMBER_OF_STATE);
if (BE (err != REG_NOERROR, 0))
return err;
plog = &mctx->state_log[str_idx]->nodes;
/* Build sifted state_log[str_idx]. It has the nodes which can epsilon
transit to the last_node and the last_node itself. */
err = re_node_set_intersect (&state_buf, plog, dfa->inveclosures + last_node);
if (BE (err != REG_NOERROR, 0))
return err;
if (mctx->state_log[str_idx] != NULL
&& mctx->state_log[str_idx]->has_backref)
{
err = add_epsilon_backreference (dfa, mctx, plog, str_idx, &state_buf);
if (BE (err != REG_NOERROR, 0))
return err;
}
/* Update state log. */
mctx->state_log[str_idx] = re_acquire_state (&err, dfa, &state_buf);
if (BE (mctx->state_log[str_idx] == NULL && err != REG_NOERROR, 0))
return err;
/* Then check each states in the state_log. */
while (str_idx > 0)
{
int i, j;
/* Update counters. */
re_node_set_empty (&state_buf);
--str_idx;
plog = ((mctx->state_log[str_idx] == NULL) ? &empty_set
: &mctx->state_log[str_idx]->nodes);
/* Then build the next sifted state.
We build the next sifted state on `state_buf', and update
`state_log[str_idx]' with `state_buf'.
Note:
`state_buf' is the sifted state from `state_log[str_idx + 1]'.
`plog' points the node_set of the old `state_log[str_idx]'. */
for (i = 0; i < plog->nelem; i++)
{
int prev_node = plog->elems[i];
int entity = prev_node;
int naccepted = 0;
re_token_type_t type = dfa->nodes[prev_node].type;
if (type == OP_CONTEXT_NODE)
{
entity = dfa->nodes[prev_node].opr.ctx_info->entity;
type = dfa->nodes[entity].type;
}
#ifdef RE_ENABLE_I18N
/* If the node may accept `multi byte'. */
if (ACCEPT_MB_NODE (type))
naccepted = sift_states_iter_mb (preg, mctx, entity, str_idx,
mctx->match_last);
/* If the node is a back reference. */
else
#endif /* RE_ENABLE_I18N */
if (type == OP_BACK_REF)
for (j = 0; j < mctx->nbkref_ents; ++j)
{
naccepted = sift_states_iter_bkref (dfa, mctx->state_log,
mctx->bkref_ents + j,
prev_node, str_idx,
mctx->match_last);
if (naccepted)
break;
}
if (!naccepted
&& check_node_accept (preg, dfa->nodes + prev_node, mctx,
str_idx)
&& STATE_NODE_CONTAINS (mctx->state_log[str_idx + 1],
dfa->nexts[prev_node]))
naccepted = 1;
if (naccepted == 0)
continue;
/* `prev_node' may point the entity of the OP_CONTEXT_NODE,
then we use plog->elems[i] instead. */
err = re_node_set_add_intersect (&state_buf, plog,
dfa->inveclosures + prev_node);
if (BE (err != REG_NOERROR, 0))
return err;
}
if (mctx->state_log[str_idx] != NULL
&& mctx->state_log[str_idx]->has_backref)
{
err = add_epsilon_backreference (dfa, mctx, plog, str_idx, &state_buf);
if (BE (err != REG_NOERROR, 0))
return err;
}
/* Update state_log. */
mctx->state_log[str_idx] = re_acquire_state (&err, dfa, &state_buf);
if (BE (mctx->state_log[str_idx] == NULL && err != REG_NOERROR, 0))
return err;
}
re_node_set_free (&state_buf);
return REG_NOERROR;
}
/* Helper functions. */
static inline reg_errcode_t
clean_state_log_if_need (mctx, next_state_log_idx)
re_match_context_t *mctx;
int next_state_log_idx;
{
int top = mctx->state_log_top;
if (next_state_log_idx >= mctx->input->bufs_len
|| (next_state_log_idx >= mctx->input->valid_len
&& mctx->input->valid_len < mctx->input->len))
{
reg_errcode_t err;
err = extend_buffers (mctx);
if (BE (err != REG_NOERROR, 0))
return err;
}
if (top < next_state_log_idx)
{
memset (mctx->state_log + top + 1, '\0',
sizeof (re_dfastate_t *) * (next_state_log_idx - top));
mctx->state_log_top = next_state_log_idx;
}
return REG_NOERROR;
}
#ifdef RE_ENABLE_I18N
static int
sift_states_iter_mb (preg, mctx, node_idx, str_idx, max_str_idx)
const regex_t *preg;
const re_match_context_t *mctx;
int node_idx, str_idx, max_str_idx;
{
re_dfa_t *dfa = (re_dfa_t *) preg->buffer;
int naccepted;
/* Check the node can accept `multi byte'. */
naccepted = check_node_accept_bytes (preg, node_idx, mctx->input, str_idx);
if (naccepted > 0 && str_idx + naccepted <= max_str_idx &&
!STATE_NODE_CONTAINS (mctx->state_log[str_idx + naccepted],
dfa->nexts[node_idx]))
/* The node can't accept the `multi byte', or the
destination was already throwed away, then the node
could't accept the current input `multi byte'. */
naccepted = 0;
/* Otherwise, it is sure that the node could accept
`naccepted' bytes input. */
return naccepted;
}
#endif /* RE_ENABLE_I18N */
static int
sift_states_iter_bkref (dfa, state_log, mctx_entry, node_idx, idx, match_last)
const re_dfa_t *dfa;
re_dfastate_t **state_log;
struct re_backref_cache_entry *mctx_entry;
int node_idx, idx, match_last;
{
int naccepted = 0;
int from_idx, to_idx;
from_idx = mctx_entry->from;
to_idx = mctx_entry->to;
if (mctx_entry->node == node_idx
&& from_idx == idx && to_idx <= match_last
&& STATE_NODE_CONTAINS (state_log[to_idx], dfa->nexts[node_idx]))
naccepted = to_idx - from_idx;
return naccepted;
}
static reg_errcode_t
add_epsilon_backreference (dfa, mctx, plog, idx, state_buf)
const re_dfa_t *dfa;
const re_match_context_t *mctx;
const re_node_set *plog;
int idx;
re_node_set *state_buf;
{
int i, j;
for (i = 0; i < plog->nelem; ++i)
{
int node_idx = plog->elems[i];
re_token_type_t type = dfa->nodes[node_idx].type;
if (type == OP_CONTEXT_NODE)
type = dfa->nodes[dfa->nodes[node_idx].opr.ctx_info->entity].type;
if (type == OP_BACK_REF &&
!re_node_set_contains (state_buf, node_idx))
{
for (j = 0; j < mctx->nbkref_ents; ++j)
{
struct re_backref_cache_entry *entry;
entry = mctx->bkref_ents + j;
if (entry->from == entry->to && entry->from == idx)
break;
}
if (j < mctx->nbkref_ents || idx == 0)
{
reg_errcode_t err;
err = re_node_set_add_intersect (state_buf, plog,
dfa->inveclosures + node_idx);
if (BE (err != REG_NOERROR, 0))
return err;
i = 0;
}
}
}
return REG_NOERROR;
}
/* Functions for state transition. */
/* Return the next state to which the current state STATE will transit by
accepting the current input byte, and update STATE_LOG if necessary.
If STATE can accept a multibyte char/collating element/back reference
update the destination of STATE_LOG. */
static re_dfastate_t *
transit_state (err, preg, mctx, state, fl_search)
reg_errcode_t *err;
const regex_t *preg;
re_match_context_t *mctx;
re_dfastate_t *state;
int fl_search;
{
re_dfa_t *dfa = (re_dfa_t *) preg->buffer;
re_dfastate_t **trtable, *next_state;
unsigned char ch;
if (re_string_cur_idx (mctx->input) + 1 >= mctx->input->bufs_len
|| (re_string_cur_idx (mctx->input) + 1 >= mctx->input->valid_len
&& mctx->input->valid_len < mctx->input->len))
{
*err = extend_buffers (mctx);
if (BE (*err != REG_NOERROR, 0))
return NULL;
}
*err = REG_NOERROR;
if (state == NULL)
{
next_state = state;
re_string_skip_bytes (mctx->input, 1);
}
else
{
#ifdef RE_ENABLE_I18N
/* If the current state can accept multibyte. */
if (state->accept_mb)
{
*err = transit_state_mb (preg, state, mctx);
if (BE (*err != REG_NOERROR, 0))
return NULL;
}
#endif /* RE_ENABLE_I18N */
/* Then decide the next state with the single byte. */
if (1)
{
/* Use transition table */
ch = re_string_fetch_byte (mctx->input);
trtable = fl_search ? state->trtable_search : state->trtable;
if (trtable == NULL)
{
trtable = build_trtable (preg, state, fl_search);
if (fl_search)
state->trtable_search = trtable;
else
state->trtable = trtable;
}
next_state = trtable[ch];
}
else
{
/* don't use transition table */
next_state = transit_state_sb (err, preg, state, fl_search, mctx);
if (BE (next_state == NULL && err != REG_NOERROR, 0))
return NULL;
}
}
/* Update the state_log if we need. */
if (mctx->state_log != NULL)
{
int cur_idx = re_string_cur_idx (mctx->input);
if (cur_idx > mctx->state_log_top)
{
mctx->state_log[cur_idx] = next_state;
mctx->state_log_top = cur_idx;
}
else if (mctx->state_log[cur_idx] == 0)
{
mctx->state_log[cur_idx] = next_state;
}
else
{
re_dfastate_t *pstate;
unsigned int context;
re_node_set next_nodes, *log_nodes, *table_nodes = NULL;
/* If (state_log[cur_idx] != 0), it implies that cur_idx is
the destination of a multibyte char/collating element/
back reference. Then the next state is the union set of
these destinations and the results of the transition table. */
pstate = mctx->state_log[cur_idx];
log_nodes = pstate->entrance_nodes;
if (next_state != NULL)
{
table_nodes = next_state->entrance_nodes;
*err = re_node_set_init_union (&next_nodes, table_nodes,
log_nodes);
if (BE (*err != REG_NOERROR, 0))
return NULL;
}
else
next_nodes = *log_nodes;
/* Note: We already add the nodes of the initial state,
then we don't need to add them here. */
context = re_string_context_at (mctx->input,
re_string_cur_idx (mctx->input) - 1,
mctx->eflags, preg->newline_anchor);
next_state = mctx->state_log[cur_idx]
= re_acquire_state_context (err, dfa, &next_nodes, context);
/* We don't need to check errors here, since the return value of
this function is next_state and ERR is already set. */
if (table_nodes != NULL)
re_node_set_free (&next_nodes);
}
/* If the next state has back references. */
if (next_state != NULL && next_state->has_backref)
{
*err = transit_state_bkref (preg, next_state, mctx);
if (BE (*err != REG_NOERROR, 0))
return NULL;
next_state = mctx->state_log[cur_idx];
}
}
return next_state;
}
/* Helper functions for transit_state. */
/* Return the next state to which the current state STATE will transit by
accepting the current input byte. */
static re_dfastate_t *
transit_state_sb (err, preg, state, fl_search, mctx)
reg_errcode_t *err;
const regex_t *preg;
re_dfastate_t *state;
int fl_search;
re_match_context_t *mctx;
{
re_dfa_t *dfa = (re_dfa_t *) preg->buffer;
re_node_set next_nodes;
re_dfastate_t *next_state;
int node_cnt, cur_str_idx = re_string_cur_idx (mctx->input);
unsigned int context;
*err = re_node_set_alloc (&next_nodes, state->nodes.nelem + 1);
if (BE (*err != REG_NOERROR, 0))
return NULL;
for (node_cnt = 0; node_cnt < state->nodes.nelem; ++node_cnt)
{
int cur_node = state->nodes.elems[node_cnt];
if (check_node_accept (preg, dfa->nodes + cur_node, mctx, cur_str_idx))
{
*err = re_node_set_merge (&next_nodes,
dfa->eclosures + dfa->nexts[cur_node]);
if (BE (*err != REG_NOERROR, 0))
return NULL;
}
}
if (fl_search)
{
#ifdef RE_ENABLE_I18N
int not_initial = 0;
if (MB_CUR_MAX > 1)
for (node_cnt = 0; node_cnt < next_nodes.nelem; ++node_cnt)
if (dfa->nodes[next_nodes.elems[node_cnt]].type == CHARACTER)
{
not_initial = dfa->nodes[next_nodes.elems[node_cnt]].mb_partial;
break;
}
if (!not_initial)
#endif
{
*err = re_node_set_merge (&next_nodes,
dfa->init_state->entrance_nodes);
if (BE (*err != REG_NOERROR, 0))
return NULL;
}
}
context = re_string_context_at (mctx->input, cur_str_idx, mctx->eflags,
preg->newline_anchor);
next_state = re_acquire_state_context (err, dfa, &next_nodes, context);
/* We don't need to check errors here, since the return value of
this function is next_state and ERR is already set. */
re_node_set_free (&next_nodes);
re_string_skip_bytes (mctx->input, 1);
return next_state;
}
#ifdef RE_ENABLE_I18N
static reg_errcode_t
transit_state_mb (preg, pstate, mctx)
const regex_t *preg;
re_dfastate_t *pstate;
re_match_context_t *mctx;
{
reg_errcode_t err;
re_dfa_t *dfa = (re_dfa_t *) preg->buffer;
int i;
for (i = 0; i < pstate->nodes.nelem; ++i)
{
re_node_set dest_nodes, *new_nodes;
int cur_node_idx = pstate->nodes.elems[i];
int naccepted = 0, dest_idx;
unsigned int context;
re_dfastate_t *dest_state;
if (dfa->nodes[cur_node_idx].type == OP_CONTEXT_NODE)
{
context = re_string_context_at (mctx->input,
re_string_cur_idx (mctx->input),
mctx->eflags, preg->newline_anchor);
if (NOT_SATISFY_NEXT_CONSTRAINT (dfa->nodes[cur_node_idx].constraint,
context))
continue;
cur_node_idx = dfa->nodes[cur_node_idx].opr.ctx_info->entity;
}
/* How many bytes the node can accepts? */
if (ACCEPT_MB_NODE (dfa->nodes[cur_node_idx].type))
naccepted = check_node_accept_bytes (preg, cur_node_idx, mctx->input,
re_string_cur_idx (mctx->input));
if (naccepted == 0)
continue;
/* The node can accepts `naccepted' bytes. */
dest_idx = re_string_cur_idx (mctx->input) + naccepted;
err = clean_state_log_if_need (mctx, dest_idx);
if (BE (err != REG_NOERROR, 0))
return err;
#ifdef DEBUG
assert (dfa->nexts[cur_node_idx] != -1);
#endif
/* `cur_node_idx' may point the entity of the OP_CONTEXT_NODE,
then we use pstate->nodes.elems[i] instead. */
new_nodes = dfa->eclosures + dfa->nexts[pstate->nodes.elems[i]];
dest_state = mctx->state_log[dest_idx];
if (dest_state == NULL)
dest_nodes = *new_nodes;
else
{
err = re_node_set_init_union (&dest_nodes,
dest_state->entrance_nodes, new_nodes);
if (BE (err != REG_NOERROR, 0))
return err;
}
context = re_string_context_at (mctx->input, dest_idx - 1, mctx->eflags,
preg->newline_anchor);
mctx->state_log[dest_idx]
= re_acquire_state_context (&err, dfa, &dest_nodes, context);
if (BE (mctx->state_log[dest_idx] == NULL && err != REG_NOERROR, 0))
return err;
if (dest_state != NULL)
re_node_set_free (&dest_nodes);
}
return REG_NOERROR;
}
#endif /* RE_ENABLE_I18N */
static reg_errcode_t
transit_state_bkref (preg, pstate, mctx)
const regex_t *preg;
re_dfastate_t *pstate;
re_match_context_t *mctx;
{
reg_errcode_t err;
re_dfastate_t **work_state_log;
work_state_log = re_malloc (re_dfastate_t *,
re_string_cur_idx (mctx->input) + 1);
if (BE (work_state_log == NULL, 0))
return REG_ESPACE;
err = transit_state_bkref_loop (preg, &pstate->nodes, work_state_log, mctx);
re_free (work_state_log);
return err;
}
/* Caller must allocate `work_state_log'. */
static reg_errcode_t
transit_state_bkref_loop (preg, nodes, work_state_log, mctx)
const regex_t *preg;
re_node_set *nodes;
re_dfastate_t **work_state_log;
re_match_context_t *mctx;
{
reg_errcode_t err;
re_dfa_t *dfa = (re_dfa_t *) preg->buffer;
int i, j;
re_dfastate_t **state_log_bak;
regmatch_t *cur_regs = re_malloc (regmatch_t, preg->re_nsub + 1);
int cur_str_idx = re_string_cur_idx (mctx->input);
if (BE (cur_regs == NULL, 0))
return REG_ESPACE;
for (i = 0; i < nodes->nelem; ++i)
{
unsigned char *buf;
int dest_str_idx, subexp_idx, prev_nelem, subexp_len;
int node_idx = nodes->elems[i];
unsigned int context;
re_token_t *node = dfa->nodes + node_idx;
re_dfastate_t *dest_state;
re_node_set *new_dest_nodes;
/* Check whether `node' is a backreference or not. */
if (node->type == OP_BACK_REF)
subexp_idx = node->opr.idx;
else if (node->type == OP_CONTEXT_NODE &&
dfa->nodes[node->opr.ctx_info->entity].type == OP_BACK_REF)
{
context = re_string_context_at (mctx->input, cur_str_idx,
mctx->eflags, preg->newline_anchor);
if (NOT_SATISFY_NEXT_CONSTRAINT (node->constraint, context))
continue;
subexp_idx = dfa->nodes[node->opr.ctx_info->entity].opr.idx;
}
else
continue;
/* `node' is a backreference.
At first, set registers to check the backreference. */
cur_regs[0].rm_so = 0;
cur_regs[0].rm_eo = cur_str_idx;
memcpy (work_state_log, mctx->state_log,
sizeof (re_dfastate_t *) * (cur_str_idx + 1));
mctx->match_last = cur_str_idx;
state_log_bak = mctx->state_log;
mctx->state_log = work_state_log;
sift_states_backward (preg, mctx, node_idx);
if (!STATE_NODE_CONTAINS (work_state_log[0], dfa->init_node))
continue;
for (j = 1; j <= preg->re_nsub; ++j)
cur_regs[j].rm_so = cur_regs[j].rm_eo = -1;
set_regs (preg, mctx, subexp_idx + 1, cur_regs, node_idx);
mctx->state_log = state_log_bak;
/* Then check that the backreference can match the input string. */
subexp_len = cur_regs[subexp_idx].rm_eo - cur_regs[subexp_idx].rm_so;
if (subexp_len < 0 || cur_str_idx + subexp_len > mctx->input->len)
continue;
if (cur_str_idx + subexp_len > mctx->input->valid_len
&& mctx->input->valid_len < mctx->input->len)
{
reg_errcode_t err;
err = extend_buffers (mctx);
if (BE (err != REG_NOERROR, 0))
return err;
}
buf = re_string_get_buffer (mctx->input);
if (strncmp (buf + cur_regs[subexp_idx].rm_so, buf + cur_str_idx,
subexp_len) != 0)
continue;
/* Successfully matched, add a new cache entry. */
dest_str_idx = cur_str_idx + subexp_len;
err = match_ctx_add_entry (mctx, node_idx, cur_str_idx, dest_str_idx);
if (BE (err != REG_NOERROR, 0))
return err;
err = clean_state_log_if_need (mctx, dest_str_idx);
if (BE (err != REG_NOERROR, 0))
return err;
/* And add the epsilon closures (which is `new_dest_nodes') of
the backreference to appropriate state_log. */
#ifdef DEBUG
assert (dfa->nexts[node_idx] != -1);
#endif
if (node->type == OP_CONTEXT_NODE && subexp_len == 0)
new_dest_nodes = dfa->nodes[node_idx].opr.ctx_info->bkref_eclosure;
else
new_dest_nodes = dfa->eclosures + dfa->nexts[node_idx];
context = (IS_WORD_CHAR (re_string_byte_at (mctx->input,
dest_str_idx - 1))
? CONTEXT_WORD : 0);
dest_state = mctx->state_log[dest_str_idx];
prev_nelem = ((mctx->state_log[cur_str_idx] == NULL) ? 0
: mctx->state_log[cur_str_idx]->nodes.nelem);
/* Add `new_dest_node' to state_log. */
if (dest_state == NULL)
{
mctx->state_log[dest_str_idx]
= re_acquire_state_context (&err, dfa, new_dest_nodes, context);
if (BE (mctx->state_log[dest_str_idx] == NULL
&& err != REG_NOERROR, 0))
return err;
}
else
{
re_node_set dest_nodes;
err = re_node_set_init_union (&dest_nodes, dest_state->entrance_nodes,
new_dest_nodes);
if (BE (err != REG_NOERROR, 0))
return err;
mctx->state_log[dest_str_idx]
= re_acquire_state_context (&err, dfa, &dest_nodes, context);
if (BE (mctx->state_log[dest_str_idx] == NULL
&& err != REG_NOERROR, 0))
return err;
re_node_set_free (&dest_nodes);
}
/* We need to check recursively if the backreference can epsilon
transit. */
if (subexp_len == 0
&& mctx->state_log[cur_str_idx]->nodes.nelem > prev_nelem)
{
err = transit_state_bkref_loop (preg, new_dest_nodes, work_state_log,
mctx);
if (BE (err != REG_NOERROR, 0))
return err;
}
}
re_free (cur_regs);
return REG_NOERROR;
}
/* Build transition table for the state.
Return the new table if succeeded, otherwise return NULL. */
static re_dfastate_t **
build_trtable (preg, state, fl_search)
const regex_t *preg;
const re_dfastate_t *state;
int fl_search;
{
reg_errcode_t err;
re_dfa_t *dfa = (re_dfa_t *) preg->buffer;
int i, j, k, ch;
int ndests; /* Number of the destination states from `state'. */
re_dfastate_t **trtable, **dest_states, **dest_states_word, **dest_states_nl;
re_node_set follows, *dests_node;
bitset *dests_ch;
bitset acceptable;
/* We build DFA states which corresponds to the destination nodes
from `state'. `dests_node[i]' represents the nodes which i-th
destination state contains, and `dests_ch[i]' represents the
characters which i-th destination state accepts. */
dests_node = re_malloc (re_node_set, SBC_MAX);
dests_ch = re_malloc (bitset, SBC_MAX);
/* Initialize transiton table. */
trtable = (re_dfastate_t **) calloc (sizeof (re_dfastate_t *), SBC_MAX);
if (BE (dests_node == NULL || dests_ch == NULL || trtable == NULL, 0))
return NULL;
/* At first, group all nodes belonging to `state' into several
destinations. */
ndests = group_nodes_into_DFAstates (preg, state, dests_node, dests_ch);
if (BE (ndests <= 0, 0))
{
re_free (dests_node);
re_free (dests_ch);
/* Return NULL in case of an error, trtable otherwise. */
return (ndests < 0) ? NULL : trtable;
}
dest_states = re_malloc (re_dfastate_t *, ndests);
dest_states_word = re_malloc (re_dfastate_t *, ndests);
dest_states_nl = re_malloc (re_dfastate_t *, ndests);
bitset_empty (acceptable);
err = re_node_set_alloc (&follows, ndests + 1);
if (BE (dest_states == NULL || dest_states_word == NULL
|| dest_states_nl == NULL || err != REG_NOERROR, 0))
return NULL;
/* Then build the states for all destinations. */
for (i = 0; i < ndests; ++i)
{
int next_node;
re_node_set_empty (&follows);
/* Merge the follows of this destination states. */
for (j = 0; j < dests_node[i].nelem; ++j)
{
next_node = dfa->nexts[dests_node[i].elems[j]];
if (next_node != -1)
{
err = re_node_set_merge (&follows, dfa->eclosures + next_node);
if (BE (err != REG_NOERROR, 0))
return NULL;
}
}
/* If search flag is set, merge the initial state. */
if (fl_search)
{
#ifdef RE_ENABLE_I18N
int not_initial = 0;
for (j = 0; j < follows.nelem; ++j)
if (dfa->nodes[follows.elems[j]].type == CHARACTER)
{
not_initial = dfa->nodes[follows.elems[j]].mb_partial;
break;
}
if (!not_initial)
#endif
{
err = re_node_set_merge (&follows,
dfa->init_state->entrance_nodes);
if (BE (err != REG_NOERROR, 0))
return NULL;
}
}
dest_states[i] = re_acquire_state_context (&err, dfa, &follows, 0);
if (BE (dest_states[i] == NULL && err != REG_NOERROR, 0))
return NULL;
/* If the new state has context constraint,
build appropriate states for these contexts. */
if (dest_states[i]->has_constraint)
{
dest_states_word[i] = re_acquire_state_context (&err, dfa, &follows,
CONTEXT_WORD);
if (BE (dest_states_word[i] == NULL && err != REG_NOERROR, 0))
return NULL;
dest_states_nl[i] = re_acquire_state_context (&err, dfa, &follows,
CONTEXT_NEWLINE);
if (BE (dest_states_nl[i] == NULL && err != REG_NOERROR, 0))
return NULL;
}
else
{
dest_states_word[i] = dest_states[i];
dest_states_nl[i] = dest_states[i];
}
bitset_merge (acceptable, dests_ch[i]);
}
/* Update the transition table. */
for (i = 0, ch = 0; i < BITSET_UINTS; ++i)
for (j = 0; j < UINT_BITS; ++j, ++ch)
if ((acceptable[i] >> j) & 1)
{
if (IS_WORD_CHAR (ch))
{
for (k = 0; k < ndests; ++k)
if ((dests_ch[k][i] >> j) & 1)
trtable[ch] = dest_states_word[k];
}
else /* not WORD_CHAR */
{
for (k = 0; k < ndests; ++k)
if ((dests_ch[k][i] >> j) & 1)
trtable[ch] = dest_states[k];
}
}
/* new line */
for (k = 0; k < ndests; ++k)
if (bitset_contain (acceptable, NEWLINE_CHAR))
trtable[NEWLINE_CHAR] = dest_states_nl[k];
re_free (dest_states_nl);
re_free (dest_states_word);
re_free (dest_states);
re_node_set_free (&follows);
for (i = 0; i < ndests; ++i)
re_node_set_free (dests_node + i);
re_free (dests_ch);
re_free (dests_node);
return trtable;
}
/* Group all nodes belonging to STATE into several destinations.
Then for all destinations, set the nodes belonging to the destination
to DESTS_NODE[i] and set the characters accepted by the destination
to DEST_CH[i]. This function return the number of destinations. */
static int
group_nodes_into_DFAstates (preg, state, dests_node, dests_ch)
const regex_t *preg;
const re_dfastate_t *state;
re_node_set *dests_node;
bitset *dests_ch;
{
reg_errcode_t err;
const re_dfa_t *dfa = (re_dfa_t *) preg->buffer;
int i, j, k;
int ndests; /* Number of the destinations from `state'. */
bitset accepts; /* Characters a node can accept. */
const re_node_set *cur_nodes = &state->nodes;
bitset_empty (accepts);
ndests = 0;
/* For all the nodes belonging to `state', */
for (i = 0; i < cur_nodes->nelem; ++i)
{
unsigned int constraint = 0;
re_token_t *node = &dfa->nodes[cur_nodes->elems[i]];
re_token_type_t type = node->type;
if (type == OP_CONTEXT_NODE)
{
constraint = node->constraint;
node = dfa->nodes + node->opr.ctx_info->entity;
type = node->type;
}
/* Enumerate all single byte character this node can accept. */
if (type == CHARACTER)
bitset_set (accepts, node->opr.c);
else if (type == SIMPLE_BRACKET)
{
bitset_merge (accepts, node->opr.sbcset);
}
else if (type == OP_PERIOD)
{
bitset_set_all (accepts);
if (!(preg->syntax & RE_DOT_NEWLINE))
bitset_clear (accepts, '\n');
if (preg->syntax & RE_DOT_NOT_NULL)
bitset_clear (accepts, '\0');
}
else
continue;
/* Check the `accepts' and sift the characters which are not
match it the context. */
if (constraint)
{
if (constraint & NEXT_WORD_CONSTRAINT)
for (j = 0; j < BITSET_UINTS; ++j)
accepts[j] &= dfa->word_char[j];
else if (constraint & NEXT_NOTWORD_CONSTRAINT)
for (j = 0; j < BITSET_UINTS; ++j)
accepts[j] &= ~dfa->word_char[j];
else if (constraint & NEXT_NEWLINE_CONSTRAINT)
{
int accepts_newline = bitset_contain (accepts, NEWLINE_CHAR);
bitset_empty (accepts);
if (accepts_newline)
bitset_set (accepts, NEWLINE_CHAR);
else
continue;
}
}
/* Then divide `accepts' into DFA states, or create a new
state. */
for (j = 0; j < ndests; ++j)
{
bitset intersec; /* Intersection sets, see below. */
bitset remains;
/* Flags, see below. */
int has_intersec, not_subset, not_consumed;
/* Optimization, skip if this state doesn't accept the character. */
if (type == CHARACTER && !bitset_contain (dests_ch[j], node->opr.c))
continue;
/* Enumerate the intersection set of this state and `accepts'. */
has_intersec = 0;
for (k = 0; k < BITSET_UINTS; ++k)
has_intersec |= intersec[k] = accepts[k] & dests_ch[j][k];
/* And skip if the intersection set is empty. */
if (!has_intersec)
continue;
/* Then check if this state is a subset of `accepts'. */
not_subset = not_consumed = 0;
for (k = 0; k < BITSET_UINTS; ++k)
{
not_subset |= remains[k] = ~accepts[k] & dests_ch[j][k];
not_consumed |= accepts[k] = accepts[k] & ~dests_ch[j][k];
}
/* If this state isn't a subset of `accepts', create a
new group state, which has the `remains'. */
if (not_subset)
{
bitset_copy (dests_ch[ndests], remains);
bitset_copy (dests_ch[j], intersec);
err = re_node_set_init_copy (dests_node + ndests, &dests_node[j]);
if (BE (err != REG_NOERROR, 0))
return -1;
++ndests;
}
/* Put the position in the current group. */
err = re_node_set_insert (&dests_node[j], cur_nodes->elems[i]);
if (BE (err < 0, 0))
return -1;
/* If all characters are consumed, go to next node. */
if (!not_consumed)
break;
}
/* Some characters remain, create a new group. */
if (j == ndests)
{
bitset_copy (dests_ch[ndests], accepts);
err = re_node_set_init_1 (dests_node + ndests, cur_nodes->elems[i]);
if (BE (err != REG_NOERROR, 0))
return -1;
++ndests;
bitset_empty (accepts);
}
}
return ndests;
}
#ifdef RE_ENABLE_I18N
/* Check how many bytes the node `dfa->nodes[node_idx]' accepts.
Return the number of the bytes the node accepts.
STR_IDX is the current index of the input string.
This function handles the nodes which can accept one character, or
one collating element like '.', '[a-z]', opposite to the other nodes
can only accept one byte. */
static int
check_node_accept_bytes (preg, node_idx, input, str_idx)
const regex_t *preg;
int node_idx, str_idx;
const re_string_t *input;
{
const re_dfa_t *dfa = (re_dfa_t *) preg->buffer;
const re_token_t *node = dfa->nodes + node_idx;
int elem_len = re_string_elem_size_at (input, str_idx);
int char_len = re_string_char_size_at (input, str_idx);
int i;
# ifdef _LIBC
int j;
uint32_t nrules = _NL_CURRENT_WORD (LC_COLLATE, _NL_COLLATE_NRULES);
# endif /* _LIBC */
if (elem_len <= 1 && char_len <= 1)
return 0;
if (node->type == OP_PERIOD)
{
/* '.' accepts any one character except the following two cases. */
if ((!(preg->syntax & RE_DOT_NEWLINE) &&
re_string_byte_at (input, str_idx) == '\n') ||
((preg->syntax & RE_DOT_NOT_NULL) &&
re_string_byte_at (input, str_idx) == '\0'))
return 0;
return char_len;
}
else if (node->type == COMPLEX_BRACKET)
{
const re_charset_t *cset = node->opr.mbcset;
# ifdef _LIBC
const unsigned char *pin = re_string_get_buffer (input) + str_idx;
# endif /* _LIBC */
int match_len = 0;
wchar_t wc = ((cset->nranges || cset->nchar_classes || cset->nmbchars)
? re_string_wchar_at (input, str_idx) : 0);
/* match with multibyte character? */
for (i = 0; i < cset->nmbchars; ++i)
if (wc == cset->mbchars[i])
{
match_len = char_len;
goto check_node_accept_bytes_match;
}
/* match with character_class? */
for (i = 0; i < cset->nchar_classes; ++i)
{
wctype_t wt = cset->char_classes[i];
if (__iswctype (wc, wt))
{
match_len = char_len;
goto check_node_accept_bytes_match;
}
}
# ifdef _LIBC
if (nrules != 0)
{
unsigned int in_collseq = 0;
const int32_t *table, *indirect;
const unsigned char *weights, *extra, *collseqwc;
int32_t idx;
/* This #include defines a local function! */
# include <locale/weight.h>
/* match with collating_symbol? */
if (cset->ncoll_syms)
extra = (const unsigned char *)
_NL_CURRENT (LC_COLLATE, _NL_COLLATE_SYMB_EXTRAMB);
for (i = 0; i < cset->ncoll_syms; ++i)
{
const unsigned char *coll_sym = extra + cset->coll_syms[i];
/* Compare the length of input collating element and
the length of current collating element. */
if (*coll_sym != elem_len)
continue;
/* Compare each bytes. */
for (j = 0; j < *coll_sym; j++)
if (pin[j] != coll_sym[1 + j])
break;
if (j == *coll_sym)
{
/* Match if every bytes is equal. */
match_len = j;
goto check_node_accept_bytes_match;
}
}
if (cset->nranges)
{
if (elem_len <= char_len)
{
collseqwc = _NL_CURRENT (LC_COLLATE, _NL_COLLATE_COLLSEQWC);
in_collseq = collseq_table_lookup (collseqwc, wc);
}
else
in_collseq = find_collation_sequence_value (pin, elem_len);
}
/* match with range expression? */
for (i = 0; i < cset->nranges; ++i)
if (cset->range_starts[i] <= in_collseq
&& in_collseq <= cset->range_ends[i])
{
match_len = elem_len;
goto check_node_accept_bytes_match;
}
/* match with equivalence_class? */
if (cset->nequiv_classes)
{
const unsigned char *cp = pin;
table = (const int32_t *)
_NL_CURRENT (LC_COLLATE, _NL_COLLATE_TABLEMB);
weights = (const unsigned char *)
_NL_CURRENT (LC_COLLATE, _NL_COLLATE_WEIGHTMB);
extra = (const unsigned char *)
_NL_CURRENT (LC_COLLATE, _NL_COLLATE_EXTRAMB);
indirect = (const int32_t *)
_NL_CURRENT (LC_COLLATE, _NL_COLLATE_INDIRECTMB);
idx = findidx (&cp);
if (idx > 0)
for (i = 0; i < cset->nequiv_classes; ++i)
{
int32_t equiv_class_idx = cset->equiv_classes[i];
size_t weight_len = weights[idx];
if (weight_len == weights[equiv_class_idx])
{
int cnt = 0;
while (cnt <= weight_len
&& (weights[equiv_class_idx + 1 + cnt]
== weights[idx + 1 + cnt]))
++cnt;
if (cnt > weight_len)
{
match_len = elem_len;
goto check_node_accept_bytes_match;
}
}
}
}
}
else
# endif /* _LIBC */
{
/* match with range expression? */
wchar_t cmp_buf[6] = {L'\0', L'\0', wc, L'\0', L'\0', L'\0'};
for (i = 0; i < cset->nranges; ++i)
{
cmp_buf[0] = cset->range_starts[i];
cmp_buf[4] = cset->range_ends[i];
if (wcscoll (cmp_buf, cmp_buf + 2) <= 0
&& wcscoll (cmp_buf + 2, cmp_buf + 4) <= 0)
{
match_len = char_len;
goto check_node_accept_bytes_match;
}
}
}
check_node_accept_bytes_match:
if (!cset->non_match)
return match_len;
else
{
if (match_len > 0)
return 0;
else
return (elem_len > char_len) ? elem_len : char_len;
}
}
return 0;
}
# ifdef _LIBC
static unsigned int
find_collation_sequence_value (mbs, mbs_len)
const unsigned char *mbs;
size_t mbs_len;
{
uint32_t nrules = _NL_CURRENT_WORD (LC_COLLATE, _NL_COLLATE_NRULES);
if (nrules == 0)
{
if (mbs_len == 1)
{
/* No valid character. Match it as a single byte character. */
const unsigned char *collseq = (const unsigned char *)
_NL_CURRENT (LC_COLLATE, _NL_COLLATE_COLLSEQMB);
return collseq[mbs[0]];
}
return UINT_MAX;
}
else
{
int32_t idx;
const unsigned char *extra = (const unsigned char *)
_NL_CURRENT (LC_COLLATE, _NL_COLLATE_SYMB_EXTRAMB);
for (idx = 0; ;)
{
int mbs_cnt, found = 0;
int32_t elem_mbs_len;
/* Skip the name of collating element name. */
idx = idx + extra[idx] + 1;
elem_mbs_len = extra[idx++];
if (mbs_len == elem_mbs_len)
{
for (mbs_cnt = 0; mbs_cnt < elem_mbs_len; ++mbs_cnt)
if (extra[idx + mbs_cnt] != mbs[mbs_cnt])
break;
if (mbs_cnt == elem_mbs_len)
/* Found the entry. */
found = 1;
}
/* Skip the byte sequence of the collating element. */
idx += elem_mbs_len;
/* Adjust for the alignment. */
idx = (idx + 3) & ~3;
/* Skip the collation sequence value. */
idx += sizeof (uint32_t);
/* Skip the wide char sequence of the collating element. */
idx = idx + sizeof (uint32_t) * (extra[idx] + 1);
/* If we found the entry, return the sequence value. */
if (found)
return *(uint32_t *) (extra + idx);
/* Skip the collation sequence value. */
idx += sizeof (uint32_t);
}
}
}
# endif /* _LIBC */
#endif /* RE_ENABLE_I18N */
/* Check whether the node accepts the byte which is IDX-th
byte of the INPUT. */
static int
check_node_accept (preg, node, mctx, idx)
const regex_t *preg;
const re_token_t *node;
const re_match_context_t *mctx;
int idx;
{
const re_dfa_t *dfa = (re_dfa_t *) preg->buffer;
const re_token_t *cur_node;
unsigned char ch;
if (node->type == OP_CONTEXT_NODE)
{
/* The node has constraints. Check whether the current context
satisfies the constraints. */
unsigned int context = re_string_context_at (mctx->input, idx,
mctx->eflags,
preg->newline_anchor);
if (NOT_SATISFY_NEXT_CONSTRAINT (node->constraint, context))
return 0;
cur_node = dfa->nodes + node->opr.ctx_info->entity;
}
else
cur_node = node;
ch = re_string_byte_at (mctx->input, idx);
if (cur_node->type == CHARACTER)
return cur_node->opr.c == ch;
else if (cur_node->type == SIMPLE_BRACKET)
return bitset_contain (cur_node->opr.sbcset, ch);
else if (cur_node->type == OP_PERIOD)
return !((ch == '\n' && !(preg->syntax & RE_DOT_NEWLINE))
|| (ch == '\0' && (preg->syntax & RE_DOT_NOT_NULL)));
else
return 0;
}
/* Extend the buffers, if the buffers have run out. */
static reg_errcode_t
extend_buffers (mctx)
re_match_context_t *mctx;
{
reg_errcode_t ret;
re_string_t *pstr = mctx->input;
/* Double the lengthes of the buffers. */
ret = re_string_realloc_buffers (pstr, pstr->bufs_len * 2);
if (BE (ret != REG_NOERROR, 0))
return ret;
if (mctx->state_log != NULL)
{
/* And double the length of state_log. */
mctx->state_log = re_realloc (mctx->state_log, re_dfastate_t *,
pstr->bufs_len * 2);
if (BE (mctx->state_log == NULL, 0))
return REG_ESPACE;
}
/* Then reconstruct the buffers. */
if (pstr->icase)
{
#ifdef RE_ENABLE_I18N
if (MB_CUR_MAX > 1)
build_wcs_upper_buffer (pstr);
else
#endif /* RE_ENABLE_I18N */
build_upper_buffer (pstr);
}
else
{
#ifdef RE_ENABLE_I18N
if (MB_CUR_MAX > 1)
build_wcs_buffer (pstr);
else
#endif /* RE_ENABLE_I18N */
{
if (pstr->trans != NULL)
re_string_translate_buffer (pstr);
else
pstr->valid_len = pstr->bufs_len;
}
}
return REG_NOERROR;
}
/* Functions for matching context. */
static reg_errcode_t
match_ctx_init (mctx, eflags, input, n)
re_match_context_t *mctx;
int eflags, n;
re_string_t *input;
{
mctx->eflags = eflags;
mctx->input = input;
mctx->match_last = -1;
if (n > 0)
{
mctx->bkref_ents = re_malloc (struct re_backref_cache_entry, n);
if (BE (mctx->bkref_ents == NULL, 0))
return REG_ESPACE;
}
else
mctx->bkref_ents = NULL;
mctx->nbkref_ents = 0;
mctx->abkref_ents = n;
mctx->max_bkref_len = 0;
return REG_NOERROR;
}
static void
match_ctx_free (mctx)
re_match_context_t *mctx;
{
re_free (mctx->bkref_ents);
}
/* Add a new backreference entry to the cache. */
static reg_errcode_t
match_ctx_add_entry (mctx, node, from, to)
re_match_context_t *mctx;
int node, from, to;
{
if (mctx->nbkref_ents >= mctx->abkref_ents)
{
mctx->bkref_ents = re_realloc (mctx->bkref_ents,
struct re_backref_cache_entry,
mctx->abkref_ents * 2);
if (BE (mctx->bkref_ents == NULL, 0))
return REG_ESPACE;
memset (mctx->bkref_ents + mctx->nbkref_ents, '\0',
sizeof (struct re_backref_cache_entry) * mctx->abkref_ents);
mctx->abkref_ents *= 2;
}
mctx->bkref_ents[mctx->nbkref_ents].node = node;
mctx->bkref_ents[mctx->nbkref_ents].from = from;
mctx->bkref_ents[mctx->nbkref_ents++].to = to;
if (mctx->max_bkref_len < to - from)
mctx->max_bkref_len = to - from;
return REG_NOERROR;
}