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freebsd-dev/lib/libc/regex/regcomp.c
Kyle Evans 18a1e2e9b9 libregex: Implement a subset of the GNU extensions 
The entire patch-set is not yet mature enough for commit, but this usable
subset is generally enough for googletest to be happy with and mostly map to
some existing concepts, so they're not as invasive.

The specific changes included here are:

- Branching in BREs with \|
- \w and \W for [[:alnum:]] and [^[:alnum:]] respectively
- \s and \S for [[:space:]] and [^[:space:]] respectively
- Additional quantifiers in BREs, \? and \+ (self-explanatory)

There's some #ifdef'd out work for allowing empty branches as a match-all.
This is a feature that's under assessment... future work will determine
how standard this behavior is and act accordingly.
2020-08-04 02:14:51 +00:00

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/*-
* SPDX-License-Identifier: BSD-3-Clause
*
* Copyright (c) 1992, 1993, 1994 Henry Spencer.
* Copyright (c) 1992, 1993, 1994
* The Regents of the University of California. All rights reserved.
*
* Copyright (c) 2011 The FreeBSD Foundation
* All rights reserved.
* Portions of this software were developed by David Chisnall
* under sponsorship from the FreeBSD Foundation.
*
* This code is derived from software contributed to Berkeley by
* Henry Spencer.
*
* 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.
* 3. Neither the name of the University nor the names of its contributors
* may be used to endorse or promote products derived from this software
* without specific prior written permission.
*
* THIS SOFTWARE IS PROVIDED BY THE REGENTS 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 REGENTS 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.
*
* @(#)regcomp.c 8.5 (Berkeley) 3/20/94
*/
#if defined(LIBC_SCCS) && !defined(lint)
static char sccsid[] = "@(#)regcomp.c 8.5 (Berkeley) 3/20/94";
#endif /* LIBC_SCCS and not lint */
#include <sys/cdefs.h>
__FBSDID("$FreeBSD$");
#include <sys/types.h>
#include <stdio.h>
#include <string.h>
#include <ctype.h>
#include <limits.h>
#include <stdlib.h>
#include <regex.h>
#include <stdbool.h>
#include <wchar.h>
#include <wctype.h>
#ifndef LIBREGEX
#include "collate.h"
#endif
#include "utils.h"
#include "regex2.h"
#include "cname.h"
/*
* Branching context, used to keep track of branch state for all of the branch-
* aware functions. In addition to keeping track of branch positions for the
* p_branch_* functions, we use this to simplify some clumsiness in BREs for
* detection of whether ^ is acting as an anchor or being used erroneously and
* also for whether we're in a sub-expression or not.
*/
struct branchc {
sopno start;
sopno back;
sopno fwd;
int nbranch;
int nchain;
bool outer;
bool terminate;
};
/*
* parse structure, passed up and down to avoid global variables and
* other clumsinesses
*/
struct parse {
const char *next; /* next character in RE */
const char *end; /* end of string (-> NUL normally) */
int error; /* has an error been seen? */
int gnuext;
sop *strip; /* malloced strip */
sopno ssize; /* malloced strip size (allocated) */
sopno slen; /* malloced strip length (used) */
int ncsalloc; /* number of csets allocated */
struct re_guts *g;
# define NPAREN 10 /* we need to remember () 1-9 for back refs */
sopno pbegin[NPAREN]; /* -> ( ([0] unused) */
sopno pend[NPAREN]; /* -> ) ([0] unused) */
bool allowbranch; /* can this expression branch? */
bool bre; /* convenience; is this a BRE? */
int pflags; /* other parsing flags -- legacy escapes? */
bool (*parse_expr)(struct parse *, struct branchc *);
void (*pre_parse)(struct parse *, struct branchc *);
void (*post_parse)(struct parse *, struct branchc *);
};
#define PFLAG_LEGACY_ESC 0x00000001
/* ========= begin header generated by ./mkh ========= */
#ifdef __cplusplus
extern "C" {
#endif
/* === regcomp.c === */
static bool p_ere_exp(struct parse *p, struct branchc *bc);
static void p_str(struct parse *p);
static int p_branch_eat_delim(struct parse *p, struct branchc *bc);
static void p_branch_ins_offset(struct parse *p, struct branchc *bc);
static void p_branch_fix_tail(struct parse *p, struct branchc *bc);
static bool p_branch_empty(struct parse *p, struct branchc *bc);
static bool p_branch_do(struct parse *p, struct branchc *bc);
static void p_bre_pre_parse(struct parse *p, struct branchc *bc);
static void p_bre_post_parse(struct parse *p, struct branchc *bc);
static void p_re(struct parse *p, int end1, int end2);
static bool p_simp_re(struct parse *p, struct branchc *bc);
static int p_count(struct parse *p);
static void p_bracket(struct parse *p);
static int p_range_cmp(wchar_t c1, wchar_t c2);
static void p_b_term(struct parse *p, cset *cs);
static int p_b_pseudoclass(struct parse *p, char c);
static void p_b_cclass(struct parse *p, cset *cs);
static void p_b_cclass_named(struct parse *p, cset *cs, const char[]);
static void p_b_eclass(struct parse *p, cset *cs);
static wint_t p_b_symbol(struct parse *p);
static wint_t p_b_coll_elem(struct parse *p, wint_t endc);
static bool may_escape(struct parse *p, const wint_t ch);
static wint_t othercase(wint_t ch);
static void bothcases(struct parse *p, wint_t ch);
static void ordinary(struct parse *p, wint_t ch);
static void nonnewline(struct parse *p);
static void repeat(struct parse *p, sopno start, int from, int to);
static int seterr(struct parse *p, int e);
static cset *allocset(struct parse *p);
static void freeset(struct parse *p, cset *cs);
static void CHadd(struct parse *p, cset *cs, wint_t ch);
static void CHaddrange(struct parse *p, cset *cs, wint_t min, wint_t max);
static void CHaddtype(struct parse *p, cset *cs, wctype_t wct);
static wint_t singleton(cset *cs);
static sopno dupl(struct parse *p, sopno start, sopno finish);
static void doemit(struct parse *p, sop op, size_t opnd);
static void doinsert(struct parse *p, sop op, size_t opnd, sopno pos);
static void dofwd(struct parse *p, sopno pos, sop value);
static int enlarge(struct parse *p, sopno size);
static void stripsnug(struct parse *p, struct re_guts *g);
static void findmust(struct parse *p, struct re_guts *g);
static int altoffset(sop *scan, int offset);
static void computejumps(struct parse *p, struct re_guts *g);
static void computematchjumps(struct parse *p, struct re_guts *g);
static sopno pluscount(struct parse *p, struct re_guts *g);
static wint_t wgetnext(struct parse *p);
#ifdef __cplusplus
}
#endif
/* ========= end header generated by ./mkh ========= */
static char nuls[10]; /* place to point scanner in event of error */
/*
* macros for use with parse structure
* BEWARE: these know that the parse structure is named `p' !!!
*/
#define PEEK() (*p->next)
#define PEEK2() (*(p->next+1))
#define MORE() (p->next < p->end)
#define MORE2() (p->next+1 < p->end)
#define SEE(c) (MORE() && PEEK() == (c))
#define SEETWO(a, b) (MORE() && MORE2() && PEEK() == (a) && PEEK2() == (b))
#define SEESPEC(a) (p->bre ? SEETWO('\\', a) : SEE(a))
#define EAT(c) ((SEE(c)) ? (NEXT(), 1) : 0)
#define EATTWO(a, b) ((SEETWO(a, b)) ? (NEXT2(), 1) : 0)
#define EATSPEC(a) (p->bre ? EATTWO('\\', a) : EAT(a))
#define NEXT() (p->next++)
#define NEXT2() (p->next += 2)
#define NEXTn(n) (p->next += (n))
#define GETNEXT() (*p->next++)
#define WGETNEXT() wgetnext(p)
#define SETERROR(e) seterr(p, (e))
#define REQUIRE(co, e) ((co) || SETERROR(e))
#define MUSTSEE(c, e) (REQUIRE(MORE() && PEEK() == (c), e))
#define MUSTEAT(c, e) (REQUIRE(MORE() && GETNEXT() == (c), e))
#define MUSTNOTSEE(c, e) (REQUIRE(!MORE() || PEEK() != (c), e))
#define EMIT(op, sopnd) doemit(p, (sop)(op), (size_t)(sopnd))
#define INSERT(op, pos) doinsert(p, (sop)(op), HERE()-(pos)+1, pos)
#define AHEAD(pos) dofwd(p, pos, HERE()-(pos))
#define ASTERN(sop, pos) EMIT(sop, HERE()-pos)
#define HERE() (p->slen)
#define THERE() (p->slen - 1)
#define THERETHERE() (p->slen - 2)
#define DROP(n) (p->slen -= (n))
/* Macro used by computejump()/computematchjump() */
#define MIN(a,b) ((a)<(b)?(a):(b))
static int /* 0 success, otherwise REG_something */
regcomp_internal(regex_t * __restrict preg,
const char * __restrict pattern,
int cflags, int pflags)
{
struct parse pa;
struct re_guts *g;
struct parse *p = &pa;
int i;
size_t len;
size_t maxlen;
#ifdef REDEBUG
# define GOODFLAGS(f) (f)
#else
# define GOODFLAGS(f) ((f)&~REG_DUMP)
#endif
cflags = GOODFLAGS(cflags);
if ((cflags&REG_EXTENDED) && (cflags&REG_NOSPEC))
return(REG_INVARG);
if (cflags&REG_PEND) {
if (preg->re_endp < pattern)
return(REG_INVARG);
len = preg->re_endp - pattern;
} else
len = strlen(pattern);
/* do the mallocs early so failure handling is easy */
g = (struct re_guts *)malloc(sizeof(struct re_guts));
if (g == NULL)
return(REG_ESPACE);
/*
* Limit the pattern space to avoid a 32-bit overflow on buffer
* extension. Also avoid any signed overflow in case of conversion
* so make the real limit based on a 31-bit overflow.
*
* Likely not applicable on 64-bit systems but handle the case
* generically (who are we to stop people from using ~715MB+
* patterns?).
*/
maxlen = ((size_t)-1 >> 1) / sizeof(sop) * 2 / 3;
if (len >= maxlen) {
free((char *)g);
return(REG_ESPACE);
}
p->ssize = len/(size_t)2*(size_t)3 + (size_t)1; /* ugh */
assert(p->ssize >= len);
p->strip = (sop *)malloc(p->ssize * sizeof(sop));
p->slen = 0;
if (p->strip == NULL) {
free((char *)g);
return(REG_ESPACE);
}
/* set things up */
p->g = g;
p->next = pattern; /* convenience; we do not modify it */
p->end = p->next + len;
p->error = 0;
p->ncsalloc = 0;
p->pflags = pflags;
for (i = 0; i < NPAREN; i++) {
p->pbegin[i] = 0;
p->pend[i] = 0;
}
#ifdef LIBREGEX
if (cflags&REG_POSIX) {
p->gnuext = false;
p->allowbranch = (cflags & REG_EXTENDED) != 0;
} else
p->gnuext = p->allowbranch = true;
#else
p->gnuext = false;
p->allowbranch = (cflags & REG_EXTENDED) != 0;
#endif
if (cflags & REG_EXTENDED) {
p->bre = false;
p->parse_expr = p_ere_exp;
p->pre_parse = NULL;
p->post_parse = NULL;
} else {
p->bre = true;
p->parse_expr = p_simp_re;
p->pre_parse = p_bre_pre_parse;
p->post_parse = p_bre_post_parse;
}
g->sets = NULL;
g->ncsets = 0;
g->cflags = cflags;
g->iflags = 0;
g->nbol = 0;
g->neol = 0;
g->must = NULL;
g->moffset = -1;
g->charjump = NULL;
g->matchjump = NULL;
g->mlen = 0;
g->nsub = 0;
g->backrefs = 0;
/* do it */
EMIT(OEND, 0);
g->firststate = THERE();
if (cflags & REG_NOSPEC)
p_str(p);
else
p_re(p, OUT, OUT);
EMIT(OEND, 0);
g->laststate = THERE();
/* tidy up loose ends and fill things in */
stripsnug(p, g);
findmust(p, g);
/* only use Boyer-Moore algorithm if the pattern is bigger
* than three characters
*/
if(g->mlen > 3) {
computejumps(p, g);
computematchjumps(p, g);
if(g->matchjump == NULL && g->charjump != NULL) {
free(g->charjump);
g->charjump = NULL;
}
}
g->nplus = pluscount(p, g);
g->magic = MAGIC2;
preg->re_nsub = g->nsub;
preg->re_g = g;
preg->re_magic = MAGIC1;
#ifndef REDEBUG
/* not debugging, so can't rely on the assert() in regexec() */
if (g->iflags&BAD)
SETERROR(REG_ASSERT);
#endif
/* win or lose, we're done */
if (p->error != 0) /* lose */
regfree(preg);
return(p->error);
}
/*
- regcomp - interface for parser and compilation
= extern int regcomp(regex_t *, const char *, int);
= #define REG_BASIC 0000
= #define REG_EXTENDED 0001
= #define REG_ICASE 0002
= #define REG_NOSUB 0004
= #define REG_NEWLINE 0010
= #define REG_NOSPEC 0020
= #define REG_PEND 0040
= #define REG_DUMP 0200
*/
int /* 0 success, otherwise REG_something */
regcomp(regex_t * __restrict preg,
const char * __restrict pattern,
int cflags)
{
return (regcomp_internal(preg, pattern, cflags, 0));
}
#ifndef LIBREGEX
/*
* Legacy interface that requires more lax escaping behavior.
*/
int
freebsd12_regcomp(regex_t * __restrict preg,
const char * __restrict pattern,
int cflags, int pflags)
{
return (regcomp_internal(preg, pattern, cflags, PFLAG_LEGACY_ESC));
}
__sym_compat(regcomp, freebsd12_regcomp, FBSD_1.0);
#endif /* !LIBREGEX */
/*
- p_ere_exp - parse one subERE, an atom possibly followed by a repetition op,
- return whether we should terminate or not
== static bool p_ere_exp(struct parse *p);
*/
static bool
p_ere_exp(struct parse *p, struct branchc *bc)
{
char c;
wint_t wc;
sopno pos;
int count;
int count2;
#ifdef LIBREGEX
int i;
int handled;
#endif
sopno subno;
int wascaret = 0;
(void)bc;
assert(MORE()); /* caller should have ensured this */
c = GETNEXT();
#ifdef LIBREGEX
handled = 0;
#endif
pos = HERE();
switch (c) {
case '(':
(void)REQUIRE(MORE(), REG_EPAREN);
p->g->nsub++;
subno = p->g->nsub;
if (subno < NPAREN)
p->pbegin[subno] = HERE();
EMIT(OLPAREN, subno);
if (!SEE(')'))
p_re(p, ')', IGN);
if (subno < NPAREN) {
p->pend[subno] = HERE();
assert(p->pend[subno] != 0);
}
EMIT(ORPAREN, subno);
(void)MUSTEAT(')', REG_EPAREN);
break;
#ifndef POSIX_MISTAKE
case ')': /* happens only if no current unmatched ( */
/*
* You may ask, why the ifndef? Because I didn't notice
* this until slightly too late for 1003.2, and none of the
* other 1003.2 regular-expression reviewers noticed it at
* all. So an unmatched ) is legal POSIX, at least until
* we can get it fixed.
*/
SETERROR(REG_EPAREN);
break;
#endif
case '^':
EMIT(OBOL, 0);
p->g->iflags |= USEBOL;
p->g->nbol++;
wascaret = 1;
break;
case '$':
EMIT(OEOL, 0);
p->g->iflags |= USEEOL;
p->g->neol++;
break;
case '|':
SETERROR(REG_EMPTY);
break;
case '*':
case '+':
case '?':
case '{':
SETERROR(REG_BADRPT);
break;
case '.':
if (p->g->cflags&REG_NEWLINE)
nonnewline(p);
else
EMIT(OANY, 0);
break;
case '[':
p_bracket(p);
break;
case '\\':
(void)REQUIRE(MORE(), REG_EESCAPE);
wc = WGETNEXT();
#ifdef LIBREGEX
if (p->gnuext) {
handled = 1;
switch (wc) {
case 'W':
case 'w':
case 'S':
case 's':
p_b_pseudoclass(p, wc);
break;
case '1':
case '2':
case '3':
case '4':
case '5':
case '6':
case '7':
case '8':
case '9':
i = wc - '0';
assert(i < NPAREN);
if (p->pend[i] != 0) {
assert(i <= p->g->nsub);
EMIT(OBACK_, i);
assert(p->pbegin[i] != 0);
assert(OP(p->strip[p->pbegin[i]]) == OLPAREN);
assert(OP(p->strip[p->pend[i]]) == ORPAREN);
(void) dupl(p, p->pbegin[i]+1, p->pend[i]);
EMIT(O_BACK, i);
} else
SETERROR(REG_ESUBREG);
p->g->backrefs = 1;
break;
default:
handled = 0;
}
/* Don't proceed to the POSIX bits if we've already handled it */
if (handled)
break;
}
#endif
switch (wc) {
case '<':
EMIT(OBOW, 0);
break;
case '>':
EMIT(OEOW, 0);
break;
default:
if (may_escape(p, wc))
ordinary(p, wc);
else
SETERROR(REG_EESCAPE);
break;
}
break;
default:
if (p->error != 0)
return (false);
p->next--;
wc = WGETNEXT();
ordinary(p, wc);
break;
}
if (!MORE())
return (false);
c = PEEK();
/* we call { a repetition if followed by a digit */
if (!( c == '*' || c == '+' || c == '?' || c == '{'))
return (false); /* no repetition, we're done */
else if (c == '{')
(void)REQUIRE(MORE2() && \
(isdigit((uch)PEEK2()) || PEEK2() == ','), REG_BADRPT);
NEXT();
(void)REQUIRE(!wascaret, REG_BADRPT);
switch (c) {
case '*': /* implemented as +? */
/* this case does not require the (y|) trick, noKLUDGE */
INSERT(OPLUS_, pos);
ASTERN(O_PLUS, pos);
INSERT(OQUEST_, pos);
ASTERN(O_QUEST, pos);
break;
case '+':
INSERT(OPLUS_, pos);
ASTERN(O_PLUS, pos);
break;
case '?':
/* KLUDGE: emit y? as (y|) until subtle bug gets fixed */
INSERT(OCH_, pos); /* offset slightly wrong */
ASTERN(OOR1, pos); /* this one's right */
AHEAD(pos); /* fix the OCH_ */
EMIT(OOR2, 0); /* offset very wrong... */
AHEAD(THERE()); /* ...so fix it */
ASTERN(O_CH, THERETHERE());
break;
case '{':
count = p_count(p);
if (EAT(',')) {
if (isdigit((uch)PEEK())) {
count2 = p_count(p);
(void)REQUIRE(count <= count2, REG_BADBR);
} else /* single number with comma */
count2 = INFINITY;
} else /* just a single number */
count2 = count;
repeat(p, pos, count, count2);
if (!EAT('}')) { /* error heuristics */
while (MORE() && PEEK() != '}')
NEXT();
(void)REQUIRE(MORE(), REG_EBRACE);
SETERROR(REG_BADBR);
}
break;
}
if (!MORE())
return (false);
c = PEEK();
if (!( c == '*' || c == '+' || c == '?' ||
(c == '{' && MORE2() && isdigit((uch)PEEK2())) ) )
return (false);
SETERROR(REG_BADRPT);
return (false);
}
/*
- p_str - string (no metacharacters) "parser"
== static void p_str(struct parse *p);
*/
static void
p_str(struct parse *p)
{
(void)REQUIRE(MORE(), REG_EMPTY);
while (MORE())
ordinary(p, WGETNEXT());
}
/*
* Eat consecutive branch delimiters for the kind of expression that we are
* parsing, return the number of delimiters that we ate.
*/
static int
p_branch_eat_delim(struct parse *p, struct branchc *bc)
{
int nskip;
(void)bc;
nskip = 0;
while (EATSPEC('|'))
++nskip;
return (nskip);
}
/*
* Insert necessary branch book-keeping operations. This emits a
* bogus 'next' offset, since we still have more to parse
*/
static void
p_branch_ins_offset(struct parse *p, struct branchc *bc)
{
if (bc->nbranch == 0) {
INSERT(OCH_, bc->start); /* offset is wrong */
bc->fwd = bc->start;
bc->back = bc->start;
}
ASTERN(OOR1, bc->back);
bc->back = THERE();
AHEAD(bc->fwd); /* fix previous offset */
bc->fwd = HERE();
EMIT(OOR2, 0); /* offset is very wrong */
++bc->nbranch;
}
/*
* Fix the offset of the tail branch, if we actually had any branches.
* This is to correct the bogus placeholder offset that we use.
*/
static void
p_branch_fix_tail(struct parse *p, struct branchc *bc)
{
/* Fix bogus offset at the tail if we actually have branches */
if (bc->nbranch > 0) {
AHEAD(bc->fwd);
ASTERN(O_CH, bc->back);
}
}
/*
* Signal to the parser that an empty branch has been encountered; this will,
* in the future, be used to allow for more permissive behavior with empty
* branches. The return value should indicate whether parsing may continue
* or not.
*/
static bool
p_branch_empty(struct parse *p, struct branchc *bc)
{
#if defined(LIBREGEX) && defined(NOTYET)
if (bc->outer)
p->g->iflags |= EMPTBR;
return (true);
#else
(void)bc;
SETERROR(REG_EMPTY);
return (false);
#endif
}
/*
* Take care of any branching requirements. This includes inserting the
* appropriate branching instructions as well as eating all of the branch
* delimiters until we either run out of pattern or need to parse more pattern.
*/
static bool
p_branch_do(struct parse *p, struct branchc *bc)
{
int ate = 0;
ate = p_branch_eat_delim(p, bc);
if (ate == 0)
return (false);
else if ((ate > 1 || (bc->outer && !MORE())) && !p_branch_empty(p, bc))
/*
* Halt parsing only if we have an empty branch and p_branch_empty
* indicates that we must not continue. In the future, this will not
* necessarily be an error.
*/
return (false);
p_branch_ins_offset(p, bc);
return (true);
}
static void
p_bre_pre_parse(struct parse *p, struct branchc *bc)
{
(void) bc;
/*
* Does not move cleanly into expression parser because of
* ordinary interpration of * at the beginning position of
* an expression.
*/
if (EAT('^')) {
EMIT(OBOL, 0);
p->g->iflags |= USEBOL;
p->g->nbol++;
}
}
static void
p_bre_post_parse(struct parse *p, struct branchc *bc)
{
/* Expression is terminating due to EOL token */
if (bc->terminate) {
DROP(1);
EMIT(OEOL, 0);
p->g->iflags |= USEEOL;
p->g->neol++;
}
}
/*
- p_re - Top level parser, concatenation and BRE anchoring
== static void p_re(struct parse *p, int end1, int end2);
* Giving end1 as OUT essentially eliminates the end1/end2 check.
*
* This implementation is a bit of a kludge, in that a trailing $ is first
* taken as an ordinary character and then revised to be an anchor.
* The amount of lookahead needed to avoid this kludge is excessive.
*/
static void
p_re(struct parse *p,
int end1, /* first terminating character */
int end2) /* second terminating character; ignored for EREs */
{
struct branchc bc;
bc.nbranch = 0;
if (end1 == OUT && end2 == OUT)
bc.outer = true;
else
bc.outer = false;
#define SEEEND() (!p->bre ? SEE(end1) : SEETWO(end1, end2))
for (;;) {
bc.start = HERE();
bc.nchain = 0;
bc.terminate = false;
if (p->pre_parse != NULL)
p->pre_parse(p, &bc);
while (MORE() && (!p->allowbranch || !SEESPEC('|')) && !SEEEND()) {
bc.terminate = p->parse_expr(p, &bc);
++bc.nchain;
}
if (p->post_parse != NULL)
p->post_parse(p, &bc);
(void) REQUIRE(p->gnuext || HERE() != bc.start, REG_EMPTY);
#ifdef LIBREGEX
if (HERE() == bc.start && !p_branch_empty(p, &bc))
break;
#endif
if (!p->allowbranch)
break;
/*
* p_branch_do's return value indicates whether we should
* continue parsing or not. This is both for correctness and
* a slight optimization, because it will check if we've
* encountered an empty branch or the end of the string
* immediately following a branch delimiter.
*/
if (!p_branch_do(p, &bc))
break;
}
#undef SEE_END
if (p->allowbranch)
p_branch_fix_tail(p, &bc);
assert(!MORE() || SEE(end1));
}
/*
- p_simp_re - parse a simple RE, an atom possibly followed by a repetition
== static bool p_simp_re(struct parse *p, struct branchc *bc);
*/
static bool /* was the simple RE an unbackslashed $? */
p_simp_re(struct parse *p, struct branchc *bc)
{
int c;
int cc; /* convenient/control character */
int count;
int count2;
sopno pos;
bool handled;
int i;
wint_t wc;
sopno subno;
# define BACKSL (1<<CHAR_BIT)
pos = HERE(); /* repetition op, if any, covers from here */
handled = false;
assert(MORE()); /* caller should have ensured this */
c = GETNEXT();
if (c == '\\') {
(void)REQUIRE(MORE(), REG_EESCAPE);
cc = GETNEXT();
c = BACKSL | cc;
#ifdef LIBREGEX
if (p->gnuext) {
handled = true;
switch (c) {
case BACKSL|'W':
case BACKSL|'w':
case BACKSL|'S':
case BACKSL|'s':
p_b_pseudoclass(p, cc);
break;
default:
handled = false;
}
}
#endif
}
if (!handled) {
switch (c) {
case '.':
if (p->g->cflags&REG_NEWLINE)
nonnewline(p);
else
EMIT(OANY, 0);
break;
case '[':
p_bracket(p);
break;
case BACKSL|'<':
EMIT(OBOW, 0);
break;
case BACKSL|'>':
EMIT(OEOW, 0);
break;
case BACKSL|'{':
SETERROR(REG_BADRPT);
break;
case BACKSL|'(':
p->g->nsub++;
subno = p->g->nsub;
if (subno < NPAREN)
p->pbegin[subno] = HERE();
EMIT(OLPAREN, subno);
/* the MORE here is an error heuristic */
if (MORE() && !SEETWO('\\', ')'))
p_re(p, '\\', ')');
if (subno < NPAREN) {
p->pend[subno] = HERE();
assert(p->pend[subno] != 0);
}
EMIT(ORPAREN, subno);
(void)REQUIRE(EATTWO('\\', ')'), REG_EPAREN);
break;
case BACKSL|')': /* should not get here -- must be user */
SETERROR(REG_EPAREN);
break;
case BACKSL|'1':
case BACKSL|'2':
case BACKSL|'3':
case BACKSL|'4':
case BACKSL|'5':
case BACKSL|'6':
case BACKSL|'7':
case BACKSL|'8':
case BACKSL|'9':
i = (c&~BACKSL) - '0';
assert(i < NPAREN);
if (p->pend[i] != 0) {
assert(i <= p->g->nsub);
EMIT(OBACK_, i);
assert(p->pbegin[i] != 0);
assert(OP(p->strip[p->pbegin[i]]) == OLPAREN);
assert(OP(p->strip[p->pend[i]]) == ORPAREN);
(void) dupl(p, p->pbegin[i]+1, p->pend[i]);
EMIT(O_BACK, i);
} else
SETERROR(REG_ESUBREG);
p->g->backrefs = 1;
break;
case '*':
/*
* Ordinary if used as the first character beyond BOL anchor of
* a (sub-)expression, counts as a bad repetition operator if it
* appears otherwise.
*/
(void)REQUIRE(bc->nchain == 0, REG_BADRPT);
/* FALLTHROUGH */
default:
if (p->error != 0)
return (false); /* Definitely not $... */
p->next--;
wc = WGETNEXT();
if ((c & BACKSL) == 0 || may_escape(p, wc))
ordinary(p, wc);
else
SETERROR(REG_EESCAPE);
break;
}
}
if (EAT('*')) { /* implemented as +? */
/* this case does not require the (y|) trick, noKLUDGE */
INSERT(OPLUS_, pos);
ASTERN(O_PLUS, pos);
INSERT(OQUEST_, pos);
ASTERN(O_QUEST, pos);
#ifdef LIBREGEX
} else if (p->gnuext && EATTWO('\\', '?')) {
INSERT(OQUEST_, pos);
ASTERN(O_QUEST, pos);
} else if (p->gnuext && EATTWO('\\', '+')) {
INSERT(OPLUS_, pos);
ASTERN(O_PLUS, pos);
#endif
} else if (EATTWO('\\', '{')) {
count = p_count(p);
if (EAT(',')) {
if (MORE() && isdigit((uch)PEEK())) {
count2 = p_count(p);
(void)REQUIRE(count <= count2, REG_BADBR);
} else /* single number with comma */
count2 = INFINITY;
} else /* just a single number */
count2 = count;
repeat(p, pos, count, count2);
if (!EATTWO('\\', '}')) { /* error heuristics */
while (MORE() && !SEETWO('\\', '}'))
NEXT();
(void)REQUIRE(MORE(), REG_EBRACE);
SETERROR(REG_BADBR);
}
} else if (c == '$') /* $ (but not \$) ends it */
return (true);
return (false);
}
/*
- p_count - parse a repetition count
== static int p_count(struct parse *p);
*/
static int /* the value */
p_count(struct parse *p)
{
int count = 0;
int ndigits = 0;
while (MORE() && isdigit((uch)PEEK()) && count <= DUPMAX) {
count = count*10 + (GETNEXT() - '0');
ndigits++;
}
(void)REQUIRE(ndigits > 0 && count <= DUPMAX, REG_BADBR);
return(count);
}
/*
- p_bracket - parse a bracketed character list
== static void p_bracket(struct parse *p);
*/
static void
p_bracket(struct parse *p)
{
cset *cs;
wint_t ch;
/* Dept of Truly Sickening Special-Case Kludges */
if (p->next + 5 < p->end && strncmp(p->next, "[:<:]]", 6) == 0) {
EMIT(OBOW, 0);
NEXTn(6);
return;
}
if (p->next + 5 < p->end && strncmp(p->next, "[:>:]]", 6) == 0) {
EMIT(OEOW, 0);
NEXTn(6);
return;
}
if ((cs = allocset(p)) == NULL)
return;
if (p->g->cflags&REG_ICASE)
cs->icase = 1;
if (EAT('^'))
cs->invert = 1;
if (EAT(']'))
CHadd(p, cs, ']');
else if (EAT('-'))
CHadd(p, cs, '-');
while (MORE() && PEEK() != ']' && !SEETWO('-', ']'))
p_b_term(p, cs);
if (EAT('-'))
CHadd(p, cs, '-');
(void)MUSTEAT(']', REG_EBRACK);
if (p->error != 0) /* don't mess things up further */
return;
if (cs->invert && p->g->cflags&REG_NEWLINE)
cs->bmp['\n' >> 3] |= 1 << ('\n' & 7);
if ((ch = singleton(cs)) != OUT) { /* optimize singleton sets */
ordinary(p, ch);
freeset(p, cs);
} else
EMIT(OANYOF, (int)(cs - p->g->sets));
}
static int
p_range_cmp(wchar_t c1, wchar_t c2)
{
#ifndef LIBREGEX
return __wcollate_range_cmp(c1, c2);
#else
/* Copied from libc/collate __wcollate_range_cmp */
wchar_t s1[2], s2[2];
s1[0] = c1;
s1[1] = L'\0';
s2[0] = c2;
s2[1] = L'\0';
return (wcscoll(s1, s2));
#endif
}
/*
- p_b_term - parse one term of a bracketed character list
== static void p_b_term(struct parse *p, cset *cs);
*/
static void
p_b_term(struct parse *p, cset *cs)
{
char c;
wint_t start, finish;
wint_t i;
#ifndef LIBREGEX
struct xlocale_collate *table =
(struct xlocale_collate*)__get_locale()->components[XLC_COLLATE];
#endif
/* classify what we've got */
switch ((MORE()) ? PEEK() : '\0') {
case '[':
c = (MORE2()) ? PEEK2() : '\0';
break;
case '-':
SETERROR(REG_ERANGE);
return; /* NOTE RETURN */
default:
c = '\0';
break;
}
switch (c) {
case ':': /* character class */
NEXT2();
(void)REQUIRE(MORE(), REG_EBRACK);
c = PEEK();
(void)REQUIRE(c != '-' && c != ']', REG_ECTYPE);
p_b_cclass(p, cs);
(void)REQUIRE(MORE(), REG_EBRACK);
(void)REQUIRE(EATTWO(':', ']'), REG_ECTYPE);
break;
case '=': /* equivalence class */
NEXT2();
(void)REQUIRE(MORE(), REG_EBRACK);
c = PEEK();
(void)REQUIRE(c != '-' && c != ']', REG_ECOLLATE);
p_b_eclass(p, cs);
(void)REQUIRE(MORE(), REG_EBRACK);
(void)REQUIRE(EATTWO('=', ']'), REG_ECOLLATE);
break;
default: /* symbol, ordinary character, or range */
start = p_b_symbol(p);
if (SEE('-') && MORE2() && PEEK2() != ']') {
/* range */
NEXT();
if (EAT('-'))
finish = '-';
else
finish = p_b_symbol(p);
} else
finish = start;
if (start == finish)
CHadd(p, cs, start);
else {
#ifndef LIBREGEX
if (table->__collate_load_error || MB_CUR_MAX > 1) {
#else
if (MB_CUR_MAX > 1) {
#endif
(void)REQUIRE(start <= finish, REG_ERANGE);
CHaddrange(p, cs, start, finish);
} else {
(void)REQUIRE(p_range_cmp(start, finish) <= 0, REG_ERANGE);
for (i = 0; i <= UCHAR_MAX; i++) {
if (p_range_cmp(start, i) <= 0 &&
p_range_cmp(i, finish) <= 0 )
CHadd(p, cs, i);
}
}
}
break;
}
}
/*
- p_b_pseudoclass - parse a pseudo-class (\w, \W, \s, \S)
== static int p_b_pseudoclass(struct parse *p, char c)
*/
static int
p_b_pseudoclass(struct parse *p, char c) {
cset *cs;
if ((cs = allocset(p)) == NULL)
return(0);
if (p->g->cflags&REG_ICASE)
cs->icase = 1;
switch (c) {
case 'W':
cs->invert = 1;
/* PASSTHROUGH */
case 'w':
p_b_cclass_named(p, cs, "alnum");
break;
case 'S':
cs->invert = 1;
/* PASSTHROUGH */
case 's':
p_b_cclass_named(p, cs, "space");
break;
default:
return(0);
}
EMIT(OANYOF, (int)(cs - p->g->sets));
return(1);
}
/*
- p_b_cclass - parse a character-class name and deal with it
== static void p_b_cclass(struct parse *p, cset *cs);
*/
static void
p_b_cclass(struct parse *p, cset *cs)
{
const char *sp = p->next;
size_t len;
char clname[16];
while (MORE() && isalpha((uch)PEEK()))
NEXT();
len = p->next - sp;
if (len >= sizeof(clname) - 1) {
SETERROR(REG_ECTYPE);
return;
}
memcpy(clname, sp, len);
clname[len] = '\0';
p_b_cclass_named(p, cs, clname);
}
/*
- p_b_cclass_named - deal with a named character class
== static void p_b_cclass_named(struct parse *p, cset *cs, const char []);
*/
static void
p_b_cclass_named(struct parse *p, cset *cs, const char clname[]) {
wctype_t wct;
if ((wct = wctype(clname)) == 0) {
SETERROR(REG_ECTYPE);
return;
}
CHaddtype(p, cs, wct);
}
/*
- p_b_eclass - parse an equivalence-class name and deal with it
== static void p_b_eclass(struct parse *p, cset *cs);
*
* This implementation is incomplete. xxx
*/
static void
p_b_eclass(struct parse *p, cset *cs)
{
wint_t c;
c = p_b_coll_elem(p, '=');
CHadd(p, cs, c);
}
/*
- p_b_symbol - parse a character or [..]ed multicharacter collating symbol
== static wint_t p_b_symbol(struct parse *p);
*/
static wint_t /* value of symbol */
p_b_symbol(struct parse *p)
{
wint_t value;
(void)REQUIRE(MORE(), REG_EBRACK);
if (!EATTWO('[', '.'))
return(WGETNEXT());
/* collating symbol */
value = p_b_coll_elem(p, '.');
(void)REQUIRE(EATTWO('.', ']'), REG_ECOLLATE);
return(value);
}
/*
- p_b_coll_elem - parse a collating-element name and look it up
== static wint_t p_b_coll_elem(struct parse *p, wint_t endc);
*/
static wint_t /* value of collating element */
p_b_coll_elem(struct parse *p,
wint_t endc) /* name ended by endc,']' */
{
const char *sp = p->next;
struct cname *cp;
mbstate_t mbs;
wchar_t wc;
size_t clen, len;
while (MORE() && !SEETWO(endc, ']'))
NEXT();
if (!MORE()) {
SETERROR(REG_EBRACK);
return(0);
}
len = p->next - sp;
for (cp = cnames; cp->name != NULL; cp++)
if (strncmp(cp->name, sp, len) == 0 && strlen(cp->name) == len)
return(cp->code); /* known name */
memset(&mbs, 0, sizeof(mbs));
if ((clen = mbrtowc(&wc, sp, len, &mbs)) == len)
return (wc); /* single character */
else if (clen == (size_t)-1 || clen == (size_t)-2)
SETERROR(REG_ILLSEQ);
else
SETERROR(REG_ECOLLATE); /* neither */
return(0);
}
/*
- may_escape - determine whether 'ch' is escape-able in the current context
== static int may_escape(struct parse *p, const wint_t ch)
*/
static bool
may_escape(struct parse *p, const wint_t ch)
{
if ((p->pflags & PFLAG_LEGACY_ESC) != 0)
return (true);
if (isalpha(ch) || ch == '\'' || ch == '`')
return (false);
return (true);
#ifdef NOTYET
/*
* Build a whitelist of characters that may be escaped to produce an
* ordinary in the current context. This assumes that these have not
* been otherwise interpreted as a special character. Escaping an
* ordinary character yields undefined results according to
* IEEE 1003.1-2008. Some extensions (notably, some GNU extensions) take
* advantage of this and use escaped ordinary characters to provide
* special meaning, e.g. \b, \B, \w, \W, \s, \S.
*/
switch(ch) {
case '|':
case '+':
case '?':
/* The above characters may not be escaped in BREs */
if (!(p->g->cflags&REG_EXTENDED))
return (false);
/* Fallthrough */
case '(':
case ')':
case '{':
case '}':
case '.':
case '[':
case ']':
case '\\':
case '*':
case '^':
case '$':
return (true);
default:
return (false);
}
#endif
}
/*
- othercase - return the case counterpart of an alphabetic
== static wint_t othercase(wint_t ch);
*/
static wint_t /* if no counterpart, return ch */
othercase(wint_t ch)
{
assert(iswalpha(ch));
if (iswupper(ch))
return(towlower(ch));
else if (iswlower(ch))
return(towupper(ch));
else /* peculiar, but could happen */
return(ch);
}
/*
- bothcases - emit a dualcase version of a two-case character
== static void bothcases(struct parse *p, wint_t ch);
*
* Boy, is this implementation ever a kludge...
*/
static void
bothcases(struct parse *p, wint_t ch)
{
const char *oldnext = p->next;
const char *oldend = p->end;
char bracket[3 + MB_LEN_MAX];
size_t n;
mbstate_t mbs;
assert(othercase(ch) != ch); /* p_bracket() would recurse */
p->next = bracket;
memset(&mbs, 0, sizeof(mbs));
n = wcrtomb(bracket, ch, &mbs);
assert(n != (size_t)-1);
bracket[n] = ']';
bracket[n + 1] = '\0';
p->end = bracket+n+1;
p_bracket(p);
assert(p->next == p->end);
p->next = oldnext;
p->end = oldend;
}
/*
- ordinary - emit an ordinary character
== static void ordinary(struct parse *p, wint_t ch);
*/
static void
ordinary(struct parse *p, wint_t ch)
{
cset *cs;
if ((p->g->cflags&REG_ICASE) && iswalpha(ch) && othercase(ch) != ch)
bothcases(p, ch);
else if ((ch & OPDMASK) == ch)
EMIT(OCHAR, ch);
else {
/*
* Kludge: character is too big to fit into an OCHAR operand.
* Emit a singleton set.
*/
if ((cs = allocset(p)) == NULL)
return;
CHadd(p, cs, ch);
EMIT(OANYOF, (int)(cs - p->g->sets));
}
}
/*
- nonnewline - emit REG_NEWLINE version of OANY
== static void nonnewline(struct parse *p);
*
* Boy, is this implementation ever a kludge...
*/
static void
nonnewline(struct parse *p)
{
const char *oldnext = p->next;
const char *oldend = p->end;
char bracket[4];
p->next = bracket;
p->end = bracket+3;
bracket[0] = '^';
bracket[1] = '\n';
bracket[2] = ']';
bracket[3] = '\0';
p_bracket(p);
assert(p->next == bracket+3);
p->next = oldnext;
p->end = oldend;
}
/*
- repeat - generate code for a bounded repetition, recursively if needed
== static void repeat(struct parse *p, sopno start, int from, int to);
*/
static void
repeat(struct parse *p,
sopno start, /* operand from here to end of strip */
int from, /* repeated from this number */
int to) /* to this number of times (maybe INFINITY) */
{
sopno finish = HERE();
# define N 2
# define INF 3
# define REP(f, t) ((f)*8 + (t))
# define MAP(n) (((n) <= 1) ? (n) : ((n) == INFINITY) ? INF : N)
sopno copy;
if (p->error != 0) /* head off possible runaway recursion */
return;
assert(from <= to);
switch (REP(MAP(from), MAP(to))) {
case REP(0, 0): /* must be user doing this */
DROP(finish-start); /* drop the operand */
break;
case REP(0, 1): /* as x{1,1}? */
case REP(0, N): /* as x{1,n}? */
case REP(0, INF): /* as x{1,}? */
/* KLUDGE: emit y? as (y|) until subtle bug gets fixed */
INSERT(OCH_, start); /* offset is wrong... */
repeat(p, start+1, 1, to);
ASTERN(OOR1, start);
AHEAD(start); /* ... fix it */
EMIT(OOR2, 0);
AHEAD(THERE());
ASTERN(O_CH, THERETHERE());
break;
case REP(1, 1): /* trivial case */
/* done */
break;
case REP(1, N): /* as x?x{1,n-1} */
/* KLUDGE: emit y? as (y|) until subtle bug gets fixed */
INSERT(OCH_, start);
ASTERN(OOR1, start);
AHEAD(start);
EMIT(OOR2, 0); /* offset very wrong... */
AHEAD(THERE()); /* ...so fix it */
ASTERN(O_CH, THERETHERE());
copy = dupl(p, start+1, finish+1);
assert(copy == finish+4);
repeat(p, copy, 1, to-1);
break;
case REP(1, INF): /* as x+ */
INSERT(OPLUS_, start);
ASTERN(O_PLUS, start);
break;
case REP(N, N): /* as xx{m-1,n-1} */
copy = dupl(p, start, finish);
repeat(p, copy, from-1, to-1);
break;
case REP(N, INF): /* as xx{n-1,INF} */
copy = dupl(p, start, finish);
repeat(p, copy, from-1, to);
break;
default: /* "can't happen" */
SETERROR(REG_ASSERT); /* just in case */
break;
}
}
/*
- wgetnext - helper function for WGETNEXT() macro. Gets the next wide
- character from the parse struct, signals a REG_ILLSEQ error if the
- character can't be converted. Returns the number of bytes consumed.
*/
static wint_t
wgetnext(struct parse *p)
{
mbstate_t mbs;
wchar_t wc;
size_t n;
memset(&mbs, 0, sizeof(mbs));
n = mbrtowc(&wc, p->next, p->end - p->next, &mbs);
if (n == (size_t)-1 || n == (size_t)-2) {
SETERROR(REG_ILLSEQ);
return (0);
}
if (n == 0)
n = 1;
p->next += n;
return (wc);
}
/*
- seterr - set an error condition
== static int seterr(struct parse *p, int e);
*/
static int /* useless but makes type checking happy */
seterr(struct parse *p, int e)
{
if (p->error == 0) /* keep earliest error condition */
p->error = e;
p->next = nuls; /* try to bring things to a halt */
p->end = nuls;
return(0); /* make the return value well-defined */
}
/*
- allocset - allocate a set of characters for []
== static cset *allocset(struct parse *p);
*/
static cset *
allocset(struct parse *p)
{
cset *cs, *ncs;
ncs = reallocarray(p->g->sets, p->g->ncsets + 1, sizeof(*ncs));
if (ncs == NULL) {
SETERROR(REG_ESPACE);
return (NULL);
}
p->g->sets = ncs;
cs = &p->g->sets[p->g->ncsets++];
memset(cs, 0, sizeof(*cs));
return(cs);
}
/*
- freeset - free a now-unused set
== static void freeset(struct parse *p, cset *cs);
*/
static void
freeset(struct parse *p, cset *cs)
{
cset *top = &p->g->sets[p->g->ncsets];
free(cs->wides);
free(cs->ranges);
free(cs->types);
memset(cs, 0, sizeof(*cs));
if (cs == top-1) /* recover only the easy case */
p->g->ncsets--;
}
/*
- singleton - Determine whether a set contains only one character,
- returning it if so, otherwise returning OUT.
*/
static wint_t
singleton(cset *cs)
{
wint_t i, s, n;
for (i = n = 0; i < NC; i++)
if (CHIN(cs, i)) {
n++;
s = i;
}
if (n == 1)
return (s);
if (cs->nwides == 1 && cs->nranges == 0 && cs->ntypes == 0 &&
cs->icase == 0)
return (cs->wides[0]);
/* Don't bother handling the other cases. */
return (OUT);
}
/*
- CHadd - add character to character set.
*/
static void
CHadd(struct parse *p, cset *cs, wint_t ch)
{
wint_t nch, *newwides;
assert(ch >= 0);
if (ch < NC)
cs->bmp[ch >> 3] |= 1 << (ch & 7);
else {
newwides = reallocarray(cs->wides, cs->nwides + 1,
sizeof(*cs->wides));
if (newwides == NULL) {
SETERROR(REG_ESPACE);
return;
}
cs->wides = newwides;
cs->wides[cs->nwides++] = ch;
}
if (cs->icase) {
if ((nch = towlower(ch)) < NC)
cs->bmp[nch >> 3] |= 1 << (nch & 7);
if ((nch = towupper(ch)) < NC)
cs->bmp[nch >> 3] |= 1 << (nch & 7);
}
}
/*
- CHaddrange - add all characters in the range [min,max] to a character set.
*/
static void
CHaddrange(struct parse *p, cset *cs, wint_t min, wint_t max)
{
crange *newranges;
for (; min < NC && min <= max; min++)
CHadd(p, cs, min);
if (min >= max)
return;
newranges = reallocarray(cs->ranges, cs->nranges + 1,
sizeof(*cs->ranges));
if (newranges == NULL) {
SETERROR(REG_ESPACE);
return;
}
cs->ranges = newranges;
cs->ranges[cs->nranges].min = min;
cs->ranges[cs->nranges].max = max;
cs->nranges++;
}
/*
- CHaddtype - add all characters of a certain type to a character set.
*/
static void
CHaddtype(struct parse *p, cset *cs, wctype_t wct)
{
wint_t i;
wctype_t *newtypes;
for (i = 0; i < NC; i++)
if (iswctype(i, wct))
CHadd(p, cs, i);
newtypes = reallocarray(cs->types, cs->ntypes + 1,
sizeof(*cs->types));
if (newtypes == NULL) {
SETERROR(REG_ESPACE);
return;
}
cs->types = newtypes;
cs->types[cs->ntypes++] = wct;
}
/*
- dupl - emit a duplicate of a bunch of sops
== static sopno dupl(struct parse *p, sopno start, sopno finish);
*/
static sopno /* start of duplicate */
dupl(struct parse *p,
sopno start, /* from here */
sopno finish) /* to this less one */
{
sopno ret = HERE();
sopno len = finish - start;
assert(finish >= start);
if (len == 0)
return(ret);
if (!enlarge(p, p->ssize + len)) /* this many unexpected additions */
return(ret);
(void) memcpy((char *)(p->strip + p->slen),
(char *)(p->strip + start), (size_t)len*sizeof(sop));
p->slen += len;
return(ret);
}
/*
- doemit - emit a strip operator
== static void doemit(struct parse *p, sop op, size_t opnd);
*
* It might seem better to implement this as a macro with a function as
* hard-case backup, but it's just too big and messy unless there are
* some changes to the data structures. Maybe later.
*/
static void
doemit(struct parse *p, sop op, size_t opnd)
{
/* avoid making error situations worse */
if (p->error != 0)
return;
/* deal with oversize operands ("can't happen", more or less) */
assert(opnd < 1<<OPSHIFT);
/* deal with undersized strip */
if (p->slen >= p->ssize)
if (!enlarge(p, (p->ssize+1) / 2 * 3)) /* +50% */
return;
/* finally, it's all reduced to the easy case */
p->strip[p->slen++] = SOP(op, opnd);
}
/*
- doinsert - insert a sop into the strip
== static void doinsert(struct parse *p, sop op, size_t opnd, sopno pos);
*/
static void
doinsert(struct parse *p, sop op, size_t opnd, sopno pos)
{
sopno sn;
sop s;
int i;
/* avoid making error situations worse */
if (p->error != 0)
return;
sn = HERE();
EMIT(op, opnd); /* do checks, ensure space */
assert(HERE() == sn+1);
s = p->strip[sn];
/* adjust paren pointers */
assert(pos > 0);
for (i = 1; i < NPAREN; i++) {
if (p->pbegin[i] >= pos) {
p->pbegin[i]++;
}
if (p->pend[i] >= pos) {
p->pend[i]++;
}
}
memmove((char *)&p->strip[pos+1], (char *)&p->strip[pos],
(HERE()-pos-1)*sizeof(sop));
p->strip[pos] = s;
}
/*
- dofwd - complete a forward reference
== static void dofwd(struct parse *p, sopno pos, sop value);
*/
static void
dofwd(struct parse *p, sopno pos, sop value)
{
/* avoid making error situations worse */
if (p->error != 0)
return;
assert(value < 1<<OPSHIFT);
p->strip[pos] = OP(p->strip[pos]) | value;
}
/*
- enlarge - enlarge the strip
== static int enlarge(struct parse *p, sopno size);
*/
static int
enlarge(struct parse *p, sopno size)
{
sop *sp;
if (p->ssize >= size)
return 1;
sp = reallocarray(p->strip, size, sizeof(sop));
if (sp == NULL) {
SETERROR(REG_ESPACE);
return 0;
}
p->strip = sp;
p->ssize = size;
return 1;
}
/*
- stripsnug - compact the strip
== static void stripsnug(struct parse *p, struct re_guts *g);
*/
static void
stripsnug(struct parse *p, struct re_guts *g)
{
g->nstates = p->slen;
g->strip = reallocarray((char *)p->strip, p->slen, sizeof(sop));
if (g->strip == NULL) {
SETERROR(REG_ESPACE);
g->strip = p->strip;
}
}
/*
- findmust - fill in must and mlen with longest mandatory literal string
== static void findmust(struct parse *p, struct re_guts *g);
*
* This algorithm could do fancy things like analyzing the operands of |
* for common subsequences. Someday. This code is simple and finds most
* of the interesting cases.
*
* Note that must and mlen got initialized during setup.
*/
static void
findmust(struct parse *p, struct re_guts *g)
{
sop *scan;
sop *start = NULL;
sop *newstart = NULL;
sopno newlen;
sop s;
char *cp;
int offset;
char buf[MB_LEN_MAX];
size_t clen;
mbstate_t mbs;
/* avoid making error situations worse */
if (p->error != 0)
return;
/*
* It's not generally safe to do a ``char'' substring search on
* multibyte character strings, but it's safe for at least
* UTF-8 (see RFC 3629).
*/
if (MB_CUR_MAX > 1 &&
strcmp(_CurrentRuneLocale->__encoding, "UTF-8") != 0)
return;
/* find the longest OCHAR sequence in strip */
newlen = 0;
offset = 0;
g->moffset = 0;
scan = g->strip + 1;
do {
s = *scan++;
switch (OP(s)) {
case OCHAR: /* sequence member */
if (newlen == 0) { /* new sequence */
memset(&mbs, 0, sizeof(mbs));
newstart = scan - 1;
}
clen = wcrtomb(buf, OPND(s), &mbs);
if (clen == (size_t)-1)
goto toohard;
newlen += clen;
break;
case OPLUS_: /* things that don't break one */
case OLPAREN:
case ORPAREN:
break;
case OQUEST_: /* things that must be skipped */
case OCH_:
offset = altoffset(scan, offset);
scan--;
do {
scan += OPND(s);
s = *scan;
/* assert() interferes w debug printouts */
if (OP(s) != (sop)O_QUEST &&
OP(s) != (sop)O_CH && OP(s) != (sop)OOR2) {
g->iflags |= BAD;
return;
}
} while (OP(s) != (sop)O_QUEST && OP(s) != (sop)O_CH);
/* FALLTHROUGH */
case OBOW: /* things that break a sequence */
case OEOW:
case OBOL:
case OEOL:
case O_QUEST:
case O_CH:
case OEND:
if (newlen > (sopno)g->mlen) { /* ends one */
start = newstart;
g->mlen = newlen;
if (offset > -1) {
g->moffset += offset;
offset = newlen;
} else
g->moffset = offset;
} else {
if (offset > -1)
offset += newlen;
}
newlen = 0;
break;
case OANY:
if (newlen > (sopno)g->mlen) { /* ends one */
start = newstart;
g->mlen = newlen;
if (offset > -1) {
g->moffset += offset;
offset = newlen;
} else
g->moffset = offset;
} else {
if (offset > -1)
offset += newlen;
}
if (offset > -1)
offset++;
newlen = 0;
break;
case OANYOF: /* may or may not invalidate offset */
/* First, everything as OANY */
if (newlen > (sopno)g->mlen) { /* ends one */
start = newstart;
g->mlen = newlen;
if (offset > -1) {
g->moffset += offset;
offset = newlen;
} else
g->moffset = offset;
} else {
if (offset > -1)
offset += newlen;
}
if (offset > -1)
offset++;
newlen = 0;
break;
toohard:
default:
/* Anything here makes it impossible or too hard
* to calculate the offset -- so we give up;
* save the last known good offset, in case the
* must sequence doesn't occur later.
*/
if (newlen > (sopno)g->mlen) { /* ends one */
start = newstart;
g->mlen = newlen;
if (offset > -1)
g->moffset += offset;
else
g->moffset = offset;
}
offset = -1;
newlen = 0;
break;
}
} while (OP(s) != OEND);
if (g->mlen == 0) { /* there isn't one */
g->moffset = -1;
return;
}
/* turn it into a character string */
g->must = malloc((size_t)g->mlen + 1);
if (g->must == NULL) { /* argh; just forget it */
g->mlen = 0;
g->moffset = -1;
return;
}
cp = g->must;
scan = start;
memset(&mbs, 0, sizeof(mbs));
while (cp < g->must + g->mlen) {
while (OP(s = *scan++) != OCHAR)
continue;
clen = wcrtomb(cp, OPND(s), &mbs);
assert(clen != (size_t)-1);
cp += clen;
}
assert(cp == g->must + g->mlen);
*cp++ = '\0'; /* just on general principles */
}
/*
- altoffset - choose biggest offset among multiple choices
== static int altoffset(sop *scan, int offset);
*
* Compute, recursively if necessary, the largest offset among multiple
* re paths.
*/
static int
altoffset(sop *scan, int offset)
{
int largest;
int try;
sop s;
/* If we gave up already on offsets, return */
if (offset == -1)
return -1;
largest = 0;
try = 0;
s = *scan++;
while (OP(s) != (sop)O_QUEST && OP(s) != (sop)O_CH) {
switch (OP(s)) {
case OOR1:
if (try > largest)
largest = try;
try = 0;
break;
case OQUEST_:
case OCH_:
try = altoffset(scan, try);
if (try == -1)
return -1;
scan--;
do {
scan += OPND(s);
s = *scan;
if (OP(s) != (sop)O_QUEST &&
OP(s) != (sop)O_CH && OP(s) != (sop)OOR2)
return -1;
} while (OP(s) != (sop)O_QUEST && OP(s) != (sop)O_CH);
/* We must skip to the next position, or we'll
* leave altoffset() too early.
*/
scan++;
break;
case OANYOF:
case OCHAR:
case OANY:
try++;
case OBOW:
case OEOW:
case OLPAREN:
case ORPAREN:
case OOR2:
break;
default:
try = -1;
break;
}
if (try == -1)
return -1;
s = *scan++;
}
if (try > largest)
largest = try;
return largest+offset;
}
/*
- computejumps - compute char jumps for BM scan
== static void computejumps(struct parse *p, struct re_guts *g);
*
* This algorithm assumes g->must exists and is has size greater than
* zero. It's based on the algorithm found on Computer Algorithms by
* Sara Baase.
*
* A char jump is the number of characters one needs to jump based on
* the value of the character from the text that was mismatched.
*/
static void
computejumps(struct parse *p, struct re_guts *g)
{
int ch;
int mindex;
/* Avoid making errors worse */
if (p->error != 0)
return;
g->charjump = (int *)malloc((NC_MAX + 1) * sizeof(int));
if (g->charjump == NULL) /* Not a fatal error */
return;
/* Adjust for signed chars, if necessary */
g->charjump = &g->charjump[-(CHAR_MIN)];
/* If the character does not exist in the pattern, the jump
* is equal to the number of characters in the pattern.
*/
for (ch = CHAR_MIN; ch < (CHAR_MAX + 1); ch++)
g->charjump[ch] = g->mlen;
/* If the character does exist, compute the jump that would
* take us to the last character in the pattern equal to it
* (notice that we match right to left, so that last character
* is the first one that would be matched).
*/
for (mindex = 0; mindex < g->mlen; mindex++)
g->charjump[(int)g->must[mindex]] = g->mlen - mindex - 1;
}
/*
- computematchjumps - compute match jumps for BM scan
== static void computematchjumps(struct parse *p, struct re_guts *g);
*
* This algorithm assumes g->must exists and is has size greater than
* zero. It's based on the algorithm found on Computer Algorithms by
* Sara Baase.
*
* A match jump is the number of characters one needs to advance based
* on the already-matched suffix.
* Notice that all values here are minus (g->mlen-1), because of the way
* the search algorithm works.
*/
static void
computematchjumps(struct parse *p, struct re_guts *g)
{
int mindex; /* General "must" iterator */
int suffix; /* Keeps track of matching suffix */
int ssuffix; /* Keeps track of suffixes' suffix */
int* pmatches; /* pmatches[k] points to the next i
* such that i+1...mlen is a substring
* of k+1...k+mlen-i-1
*/
/* Avoid making errors worse */
if (p->error != 0)
return;
pmatches = (int*) malloc(g->mlen * sizeof(int));
if (pmatches == NULL) {
g->matchjump = NULL;
return;
}
g->matchjump = (int*) malloc(g->mlen * sizeof(int));
if (g->matchjump == NULL) { /* Not a fatal error */
free(pmatches);
return;
}
/* Set maximum possible jump for each character in the pattern */
for (mindex = 0; mindex < g->mlen; mindex++)
g->matchjump[mindex] = 2*g->mlen - mindex - 1;
/* Compute pmatches[] */
for (mindex = g->mlen - 1, suffix = g->mlen; mindex >= 0;
mindex--, suffix--) {
pmatches[mindex] = suffix;
/* If a mismatch is found, interrupting the substring,
* compute the matchjump for that position. If no
* mismatch is found, then a text substring mismatched
* against the suffix will also mismatch against the
* substring.
*/
while (suffix < g->mlen
&& g->must[mindex] != g->must[suffix]) {
g->matchjump[suffix] = MIN(g->matchjump[suffix],
g->mlen - mindex - 1);
suffix = pmatches[suffix];
}
}
/* Compute the matchjump up to the last substring found to jump
* to the beginning of the largest must pattern prefix matching
* it's own suffix.
*/
for (mindex = 0; mindex <= suffix; mindex++)
g->matchjump[mindex] = MIN(g->matchjump[mindex],
g->mlen + suffix - mindex);
ssuffix = pmatches[suffix];
while (suffix < g->mlen) {
while (suffix <= ssuffix && suffix < g->mlen) {
g->matchjump[suffix] = MIN(g->matchjump[suffix],
g->mlen + ssuffix - suffix);
suffix++;
}
if (suffix < g->mlen)
ssuffix = pmatches[ssuffix];
}
free(pmatches);
}
/*
- pluscount - count + nesting
== static sopno pluscount(struct parse *p, struct re_guts *g);
*/
static sopno /* nesting depth */
pluscount(struct parse *p, struct re_guts *g)
{
sop *scan;
sop s;
sopno plusnest = 0;
sopno maxnest = 0;
if (p->error != 0)
return(0); /* there may not be an OEND */
scan = g->strip + 1;
do {
s = *scan++;
switch (OP(s)) {
case OPLUS_:
plusnest++;
break;
case O_PLUS:
if (plusnest > maxnest)
maxnest = plusnest;
plusnest--;
break;
}
} while (OP(s) != OEND);
if (plusnest != 0)
g->iflags |= BAD;
return(maxnest);
}
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