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cpython/Modules/pypcre.c
Guido van Rossum dda6696be6 AMK's revised version of the previous patch.
1998-05-07 15:32:44 +00:00

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/*************************************************
* Perl-Compatible Regular Expressions *
*************************************************/
/* DO NOT EDIT THIS FILE! */
/* This file is automatically written by the merge-files.py script
included with the PCRE distribution for Python; it's produced from
several C files, and code is removed in the process. If you want to
modify the code or track down bugs, it will be much easier to work
with the code in its original, multiple-file form. Don't edit this
file by hand, or submit patches to it.
The Python-specific PCRE distribution can be retrieved from
http://starship.skyport.net/crew/amk/regex/
The unmodified original PCRE distribution is available at
ftp://ftp.cus.cam.ac.uk/pub/software/programs/pcre/, and is originally
written by: Philip Hazel <ph10@cam.ac.uk>
Extensively modified by the Python String-SIG: <string-sig@python.org>
Send bug reports to: <string-sig@python.org>
(They'll figure out if it's a bug in PCRE or in the Python-specific
changes.)
Copyright (c) 1997 University of Cambridge
-----------------------------------------------------------------------------
Permission is granted to anyone to use this software for any purpose on any
computer system, and to redistribute it freely, subject to the following
restrictions:
1. This software 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.
2. The origin of this software must not be misrepresented, either by
explicit claim or by omission.
3. Altered versions must be plainly marked as such, and must not be
misrepresented as being the original software.
-----------------------------------------------------------------------------
*/
#define FOR_PYTHON
#include "pcre-int.h"
#include "Python.h"
#include "mymalloc.h"
#include <ctype.h>
#include "graminit.h"
/*************************************************
* Perl-Compatible Regular Expressions *
*************************************************/
/* This file is automatically written by the makechartables auxiliary
program. If you edit it by hand, you might like to edit the Makefile to
prevent its ever being regenerated. */
/* This table is a lower casing table. */
unsigned char pcre_lcc[] = {
0, 1, 2, 3, 4, 5, 6, 7,
8, 9, 10, 11, 12, 13, 14, 15,
16, 17, 18, 19, 20, 21, 22, 23,
24, 25, 26, 27, 28, 29, 30, 31,
32, 33, 34, 35, 36, 37, 38, 39,
40, 41, 42, 43, 44, 45, 46, 47,
48, 49, 50, 51, 52, 53, 54, 55,
56, 57, 58, 59, 60, 61, 62, 63,
64, 97, 98, 99,100,101,102,103,
104,105,106,107,108,109,110,111,
112,113,114,115,116,117,118,119,
120,121,122, 91, 92, 93, 94, 95,
96, 97, 98, 99,100,101,102,103,
104,105,106,107,108,109,110,111,
112,113,114,115,116,117,118,119,
120,121,122,123,124,125,126,127,
128,129,130,131,132,133,134,135,
136,137,138,139,140,141,142,143,
144,145,146,147,148,149,150,151,
152,153,154,155,156,157,158,159,
160,161,162,163,164,165,166,167,
168,169,170,171,172,173,174,175,
176,177,178,179,180,181,182,183,
184,185,186,187,188,189,190,191,
192,193,194,195,196,197,198,199,
200,201,202,203,204,205,206,207,
208,209,210,211,212,213,214,215,
216,217,218,219,220,221,222,223,
224,225,226,227,228,229,230,231,
232,233,234,235,236,237,238,239,
240,241,242,243,244,245,246,247,
248,249,250,251,252,253,254,255 };
/* This table is a case flipping table. */
unsigned char pcre_fcc[] = {
0, 1, 2, 3, 4, 5, 6, 7,
8, 9, 10, 11, 12, 13, 14, 15,
16, 17, 18, 19, 20, 21, 22, 23,
24, 25, 26, 27, 28, 29, 30, 31,
32, 33, 34, 35, 36, 37, 38, 39,
40, 41, 42, 43, 44, 45, 46, 47,
48, 49, 50, 51, 52, 53, 54, 55,
56, 57, 58, 59, 60, 61, 62, 63,
64, 97, 98, 99,100,101,102,103,
104,105,106,107,108,109,110,111,
112,113,114,115,116,117,118,119,
120,121,122, 91, 92, 93, 94, 95,
96, 65, 66, 67, 68, 69, 70, 71,
72, 73, 74, 75, 76, 77, 78, 79,
80, 81, 82, 83, 84, 85, 86, 87,
88, 89, 90,123,124,125,126,127,
128,129,130,131,132,133,134,135,
136,137,138,139,140,141,142,143,
144,145,146,147,148,149,150,151,
152,153,154,155,156,157,158,159,
160,161,162,163,164,165,166,167,
168,169,170,171,172,173,174,175,
176,177,178,179,180,181,182,183,
184,185,186,187,188,189,190,191,
192,193,194,195,196,197,198,199,
200,201,202,203,204,205,206,207,
208,209,210,211,212,213,214,215,
216,217,218,219,220,221,222,223,
224,225,226,227,228,229,230,231,
232,233,234,235,236,237,238,239,
240,241,242,243,244,245,246,247,
248,249,250,251,252,253,254,255 };
/* This table contains bit maps for digits, letters, 'word' chars, and
white space. Each map is 32 bytes long and the bits run from the least
significant end of each byte. */
unsigned char pcre_cbits[] = {
0x00,0x00,0x00,0x00,0x00,0x00,0xff,0x03,
0x00,0x00,0x00,0x00,0x00,0x00,0x00,0x00,
0x00,0x00,0x00,0x00,0x00,0x00,0x00,0x00,
0x00,0x00,0x00,0x00,0x00,0x00,0x00,0x00,
0x00,0x00,0x00,0x00,0x00,0x00,0x00,0x00,
0xfe,0xff,0xff,0x07,0xfe,0xff,0xff,0x07,
0x00,0x00,0x00,0x00,0x00,0x00,0x00,0x00,
0x00,0x00,0x00,0x00,0x00,0x00,0x00,0x00,
0x00,0x00,0x00,0x00,0x00,0x00,0xff,0x03,
0xfe,0xff,0xff,0x87,0xfe,0xff,0xff,0x07,
0x00,0x00,0x00,0x00,0x00,0x00,0x00,0x00,
0x00,0x00,0x00,0x00,0x00,0x00,0x00,0x00,
0x00,0x3e,0x00,0x00,0x01,0x00,0x00,0x00,
0x00,0x00,0x00,0x00,0x00,0x00,0x00,0x00,
0x00,0x00,0x00,0x00,0x00,0x00,0x00,0x00,
0x00,0x00,0x00,0x00,0x00,0x00,0x00,0x00 };
/* This table identifies various classes of character by individual bits:
0x01 white space character
0x02 letter
0x04 decimal digit
0x08 hexadecimal digit
0x10 alphanumeric or '_'
0x80 regular expression metacharacter or binary zero
*/
unsigned char pcre_ctypes[] = {
0x80,0x00,0x00,0x00,0x00,0x00,0x00,0x00, /* 0- 7 */
0x00,0x01,0x01,0x01,0x01,0x01,0x00,0x00, /* 8- 15 */
0x00,0x00,0x00,0x00,0x00,0x00,0x00,0x00, /* 16- 23 */
0x00,0x00,0x00,0x00,0x00,0x00,0x00,0x00, /* 24- 31 */
0x01,0x00,0x00,0x00,0x80,0x00,0x00,0x00, /* - ' */
0x80,0x80,0x80,0x80,0x00,0x00,0x80,0x00, /* ( - / */
0x3c,0x3c,0x3c,0x3c,0x3c,0x3c,0x3c,0x3c, /* 0 - 7 */
0x1c,0x1c,0x00,0x00,0x00,0x00,0x00,0x80, /* 8 - ? */
0x00,0x1a,0x1a,0x1a,0x1a,0x1a,0x1a,0x12, /* @ - G */
0x12,0x12,0x12,0x12,0x12,0x12,0x12,0x12, /* H - O */
0x12,0x12,0x12,0x12,0x12,0x12,0x12,0x12, /* P - W */
0x12,0x12,0x12,0x80,0x00,0x00,0x80,0x10, /* X - _ */
0x00,0x1a,0x1a,0x1a,0x1a,0x1a,0x1a,0x12, /* ` - g */
0x12,0x12,0x12,0x12,0x12,0x12,0x12,0x12, /* h - o */
0x12,0x12,0x12,0x12,0x12,0x12,0x12,0x12, /* p - w */
0x12,0x12,0x12,0x80,0x80,0x00,0x00,0x00, /* x -127 */
0x00,0x00,0x00,0x00,0x00,0x00,0x00,0x00, /* 128-135 */
0x00,0x00,0x00,0x00,0x00,0x00,0x00,0x00, /* 136-143 */
0x00,0x00,0x00,0x00,0x00,0x00,0x00,0x00, /* 144-151 */
0x00,0x00,0x00,0x00,0x00,0x00,0x00,0x00, /* 152-159 */
0x00,0x00,0x00,0x00,0x00,0x00,0x00,0x00, /* 160-167 */
0x00,0x00,0x00,0x00,0x00,0x00,0x00,0x00, /* 168-175 */
0x00,0x00,0x00,0x00,0x00,0x00,0x00,0x00, /* 176-183 */
0x00,0x00,0x00,0x00,0x00,0x00,0x00,0x00, /* 184-191 */
0x00,0x00,0x00,0x00,0x00,0x00,0x00,0x00, /* 192-199 */
0x00,0x00,0x00,0x00,0x00,0x00,0x00,0x00, /* 200-207 */
0x00,0x00,0x00,0x00,0x00,0x00,0x00,0x00, /* 208-215 */
0x00,0x00,0x00,0x00,0x00,0x00,0x00,0x00, /* 216-223 */
0x00,0x00,0x00,0x00,0x00,0x00,0x00,0x00, /* 224-231 */
0x00,0x00,0x00,0x00,0x00,0x00,0x00,0x00, /* 232-239 */
0x00,0x00,0x00,0x00,0x00,0x00,0x00,0x00, /* 240-247 */
0x00,0x00,0x00,0x00,0x00,0x00,0x00,0x00};/* 248-255 */
/* End of chartables.c */
/*************************************************
* Perl-Compatible Regular Expressions *
*************************************************/
/*
This is a library of functions to support regular expressions whose syntax
and semantics are as close as possible to those of the Perl 5 language. See
the file Tech.Notes for some information on the internals.
Written by: Philip Hazel <ph10@cam.ac.uk>
Copyright (c) 1998 University of Cambridge
-----------------------------------------------------------------------------
Permission is granted to anyone to use this software for any purpose on any
computer system, and to redistribute it freely, subject to the following
restrictions:
1. This software 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.
2. The origin of this software must not be misrepresented, either by
explicit claim or by omission.
3. Altered versions must be plainly marked as such, and must not be
misrepresented as being the original software.
-----------------------------------------------------------------------------
*/
/* Include the internals header, which itself includes Standard C headers plus
the external pcre header. */
/*************************************************
* Create bitmap of starting chars *
*************************************************/
/* This function scans a compiled unanchored expression and attempts to build a
bitmap of the set of initial characters. If it can't, it returns FALSE. As time
goes by, we may be able to get more clever at doing this.
Arguments:
code points to an expression
start_bits points to a 32-byte table, initialized to 0
Returns: TRUE if table built, FALSE otherwise
*/
static BOOL
set_start_bits(const uschar *code, uschar *start_bits)
{
register int c;
do
{
const uschar *tcode = code + 3;
BOOL try_next = TRUE;
while (try_next)
{
try_next = FALSE;
if ((int)*tcode >= OP_BRA || *tcode == OP_ASSERT)
{
if (!set_start_bits(tcode, start_bits)) return FALSE;
}
else switch(*tcode)
{
default:
return FALSE;
/* BRAZERO does the bracket, but carries on. */
case OP_BRAZERO:
case OP_BRAMINZERO:
if (!set_start_bits(++tcode, start_bits)) return FALSE;
do tcode += (tcode[1] << 8) + tcode[2]; while (*tcode == OP_ALT);
tcode += 3;
try_next = TRUE;
break;
/* Single-char * or ? sets the bit and tries the next item */
case OP_STAR:
case OP_MINSTAR:
case OP_QUERY:
case OP_MINQUERY:
start_bits[tcode[1]/8] |= (1 << (tcode[1]&7));
tcode += 2;
try_next = TRUE;
break;
/* Single-char upto sets the bit and tries the next */
case OP_UPTO:
case OP_MINUPTO:
start_bits[tcode[3]/8] |= (1 << (tcode[3]&7));
tcode += 4;
try_next = TRUE;
break;
/* At least one single char sets the bit and stops */
case OP_EXACT: /* Fall through */
tcode++;
case OP_CHARS: /* Fall through */
tcode++;
case OP_PLUS:
case OP_MINPLUS:
start_bits[tcode[1]/8] |= (1 << (tcode[1]&7));
break;
/* Single character type sets the bits and stops */
case OP_NOT_DIGIT:
for (c = 0; c < 32; c++) start_bits[c] |= ~pcre_cbits[c+cbit_digit];
break;
case OP_DIGIT:
for (c = 0; c < 32; c++) start_bits[c] |= pcre_cbits[c+cbit_digit];
break;
case OP_NOT_WHITESPACE:
for (c = 0; c < 32; c++) start_bits[c] |= ~pcre_cbits[c+cbit_space];
break;
case OP_WHITESPACE:
for (c = 0; c < 32; c++) start_bits[c] |= pcre_cbits[c+cbit_space];
break;
case OP_NOT_WORDCHAR:
for (c = 0; c < 32; c++)
start_bits[c] |= ~(pcre_cbits[c] | pcre_cbits[c+cbit_word]);
break;
case OP_WORDCHAR:
for (c = 0; c < 32; c++)
start_bits[c] |= (pcre_cbits[c] | pcre_cbits[c+cbit_word]);
break;
/* One or more character type fudges the pointer and restarts, knowing
it will hit a single character type and stop there. */
case OP_TYPEPLUS:
case OP_TYPEMINPLUS:
tcode++;
try_next = TRUE;
break;
case OP_TYPEEXACT:
tcode += 3;
try_next = TRUE;
break;
/* Zero or more repeats of character types set the bits and then
try again. */
case OP_TYPEUPTO:
case OP_TYPEMINUPTO:
tcode += 2; /* Fall through */
case OP_TYPESTAR:
case OP_TYPEMINSTAR:
case OP_TYPEQUERY:
case OP_TYPEMINQUERY:
switch(tcode[1])
{
case OP_NOT_DIGIT:
for (c = 0; c < 32; c++) start_bits[c] |= ~pcre_cbits[c+cbit_digit];
break;
case OP_DIGIT:
for (c = 0; c < 32; c++) start_bits[c] |= pcre_cbits[c+cbit_digit];
break;
case OP_NOT_WHITESPACE:
for (c = 0; c < 32; c++) start_bits[c] |= ~pcre_cbits[c+cbit_space];
break;
case OP_WHITESPACE:
for (c = 0; c < 32; c++) start_bits[c] |= pcre_cbits[c+cbit_space];
break;
case OP_NOT_WORDCHAR:
for (c = 0; c < 32; c++)
start_bits[c] |= ~(pcre_cbits[c] | pcre_cbits[c+cbit_word]);
break;
case OP_WORDCHAR:
for (c = 0; c < 32; c++)
start_bits[c] |= (pcre_cbits[c] | pcre_cbits[c+cbit_word]);
break;
}
tcode += 2;
try_next = TRUE;
break;
/* Character class: set the bits and either carry on or not,
according to the repeat count. */
case OP_CLASS:
case OP_NEGCLASS:
{
tcode++;
for (c = 0; c < 32; c++) start_bits[c] |= tcode[c];
tcode += 32;
switch (*tcode)
{
case OP_CRSTAR:
case OP_CRMINSTAR:
case OP_CRQUERY:
case OP_CRMINQUERY:
tcode++;
try_next = TRUE;
break;
case OP_CRRANGE:
case OP_CRMINRANGE:
if (((tcode[1] << 8) + tcode[2]) == 0)
{
tcode += 5;
try_next = TRUE;
}
break;
}
}
break; /* End of class handling */
} /* End of switch */
} /* End of try_next loop */
code += (code[1] << 8) + code[2]; /* Advance to next branch */
}
while (*code == OP_ALT);
return TRUE;
}
/*************************************************
* Study a compiled expression *
*************************************************/
/* This function is handed a compiled expression that it must study to produce
information that will speed up the matching. It returns a pcre_extra block
which then gets handed back to pcre_exec().
Arguments:
re points to the compiled expression
options contains option bits
errorptr points to where to place error messages;
set NULL unless error
Returns: pointer to a pcre_extra block,
NULL on error or if no optimization possible
*/
pcre_extra *
pcre_study(const pcre *external_re, int options, const char **errorptr)
{
BOOL caseless;
uschar start_bits[32];
real_pcre_extra *extra;
const real_pcre *re = (const real_pcre *)external_re;
*errorptr = NULL;
if (re == NULL || re->magic_number != MAGIC_NUMBER)
{
*errorptr = "argument is not a compiled regular expression";
return NULL;
}
if ((options & ~PUBLIC_STUDY_OPTIONS) != 0)
{
*errorptr = "unknown or incorrect option bit(s) set";
return NULL;
}
/* Caseless can either be from the compiled regex or from options. */
caseless = ((re->options | options) & PCRE_CASELESS) != 0;
/* For an anchored pattern, or an unchored pattern that has a first char, or a
multiline pattern that matches only at "line starts", no further processing at
present. */
if ((re->options & (PCRE_ANCHORED|PCRE_FIRSTSET|PCRE_STARTLINE)) != 0)
return NULL;
/* See if we can find a fixed set of initial characters for the pattern. */
memset(start_bits, 0, 32 * sizeof(uschar));
if (!set_start_bits(re->code, start_bits)) return NULL;
/* If this studying is caseless, scan the created bit map and duplicate the
bits for any letters. */
if (caseless)
{
register int c;
for (c = 0; c < 256; c++)
{
if ((start_bits[c/8] & (1 << (c&7))) != 0 &&
(pcre_ctypes[c] & ctype_letter) != 0)
{
int d = pcre_fcc[c];
start_bits[d/8] |= (1 << (d&7));
}
}
}
/* Get an "extra" block and put the information therein. */
extra = (real_pcre_extra *)(pcre_malloc)(sizeof(real_pcre_extra));
if (extra == NULL)
{
*errorptr = "failed to get memory";
return NULL;
}
extra->options = PCRE_STUDY_MAPPED | (caseless? PCRE_STUDY_CASELESS : 0);
memcpy(extra->start_bits, start_bits, sizeof(start_bits));
return (pcre_extra *)extra;
}
/* End of study.c */
/*************************************************
* Perl-Compatible Regular Expressions *
*************************************************/
/*
This is a library of functions to support regular expressions whose syntax
and semantics are as close as possible to those of the Perl 5 language. See
the file Tech.Notes for some information on the internals.
Written by: Philip Hazel <ph10@cam.ac.uk>
Copyright (c) 1998 University of Cambridge
-----------------------------------------------------------------------------
Permission is granted to anyone to use this software for any purpose on any
computer system, and to redistribute it freely, subject to the following
restrictions:
1. This software 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.
2. The origin of this software must not be misrepresented, either by
explicit claim or by omission.
3. Altered versions must be plainly marked as such, and must not be
misrepresented as being the original software.
-----------------------------------------------------------------------------
*/
/* Define DEBUG to get debugging output on stdout. */
/* #define DEBUG */
/* Use a macro for debugging printing, 'cause that eliminates the the use
of #ifdef inline, and there are *still* stupid compilers about that don't like
indented pre-processor statements. I suppose it's only been 10 years... */
#ifdef DEBUG
#define DPRINTF(p) printf p
#else
#define DPRINTF(p) /*nothing*/
#endif
/* Include the internals header, which itself includes Standard C headers plus
the external pcre header. */
#ifndef Py_eval_input
/* For Python 1.4, graminit.h has to be explicitly included */
#define Py_eval_input eval_input
#endif /* FOR_PYTHON */
/* Allow compilation as C++ source code, should anybody want to do that. */
#ifdef __cplusplus
#define class pcre_class
#endif
/* Min and max values for the common repeats; for the maxima, 0 => infinity */
static const char rep_min[] = { 0, 0, 1, 1, 0, 0 };
static const char rep_max[] = { 0, 0, 0, 0, 1, 1 };
/* Text forms of OP_ values and things, for debugging (not all used) */
#ifdef DEBUG
static const char *OP_names[] = {
"End", "\\A", "\\B", "\\b", "\\D", "\\d",
"\\S", "\\s", "\\W", "\\w", "Cut", "\\Z",
"localized \\B", "localized \\b", "localized \\W", "localized \\w",
"^", "$", "Any", "chars",
"not",
"*", "*?", "+", "+?", "?", "??", "{", "{", "{",
"*", "*?", "+", "+?", "?", "??", "{", "{", "{",
"*", "*?", "+", "+?", "?", "??", "{", "{", "{",
"*", "*?", "+", "+?", "?", "??", "{", "{",
"class", "negclass", "classL", "Ref",
"Alt", "Ket", "KetRmax", "KetRmin", "Assert", "Assert not", "Once",
"Brazero", "Braminzero", "Bra"
};
#endif
/* Table for handling escaped characters in the range '0'-'z'. Positive returns
are simple data values; negative values are for special things like \d and so
on. Zero means further processing is needed (for things like \x), or the escape
is invalid. */
static const short int escapes[] = {
0, 0, 0, 0, 0, 0, 0, 0, /* 0 - 7 */
0, 0, ':', ';', '<', '=', '>', '?', /* 8 - ? */
'@', -ESC_A, -ESC_B, 0, -ESC_D, 0, 0, 0, /* @ - G */
0, 0, 0, 0, 0, 0, 0, 0, /* H - O */
0, 0, 0, -ESC_S, 0, 0, 0, -ESC_W, /* P - W */
0, 0, -ESC_Z, '[', '\\', ']', '^', '_', /* X - _ */
'`', 7, -ESC_b, 0, -ESC_d, 0, '\f', 0, /* ` - g */
0, 0, 0, 0, 0, 0, '\n', 0, /* h - o */
0, 0, '\r', -ESC_s, '\t', 0, '\v', -ESC_w, /* p - w */
0, 0, 0 /* x - z */
};
/* Definition to allow mutual recursion */
static BOOL
compile_regex(int, int *, uschar **, const uschar **, const char **,
PyObject *);
/* Structure for passing "static" information around between the functions
doing the matching, so that they are thread-safe. */
typedef struct match_data {
int errorcode; /* As it says */
int *offset_vector; /* Offset vector */
int offset_end; /* One past the end */
BOOL offset_overflow; /* Set if too many extractions */
BOOL caseless; /* Case-independent flag */
BOOL runtime_caseless; /* Caseless forced at run time */
BOOL multiline; /* Multiline flag */
BOOL notbol; /* NOTBOL flag */
BOOL noteol; /* NOTEOL flag */
BOOL dotall; /* Dot matches any char */
BOOL endonly; /* Dollar not before final \n */
const uschar *start_subject; /* Start of the subject string */
const uschar *end_subject; /* End of the subject string */
jmp_buf fail_env; /* Environment for longjump() break out */
const uschar *end_match_ptr; /* Subject position at end match */
int end_offset_top; /* Highwater mark at end of match */
jmp_buf error_env; /* For longjmp() if an error occurs deep inside a
matching operation */
int length; /* Length of the allocated stacks */
int point; /* Point to add next item pushed onto stacks */
/* Pointers to the 6 stacks */
int *off_num, *offset_top, *r1, *r2;
const uschar **eptr, **ecode;
} match_data;
/*************************************************
* Global variables *
*************************************************/
/* PCRE is thread-clean and doesn't use any global variables in the normal
sense. However, it calls memory allocation and free functions via the two
indirections below, which are can be changed by the caller, but are shared
between all threads. */
void *(*pcre_malloc)(size_t) = malloc;
void (*pcre_free)(void *) = free;
/*************************************************
* Return version string *
*************************************************/
const char *
pcre_version(void)
{
return PCRE_VERSION;
}
/*************************************************
* Return info about a compiled pattern *
*************************************************/
/* This function picks potentially useful data out of the private
structure.
Arguments:
external_re points to compiled code
optptr where to pass back the options
first_char where to pass back the first character,
or -1 if multiline and all branches start ^,
or -2 otherwise
Returns: number of identifying extraction brackets
or negative values on error
*/
int
pcre_info(const pcre *external_re, int *optptr, int *first_char)
{
const real_pcre *re = (real_pcre *)external_re;
if (re == NULL) return PCRE_ERROR_NULL;
if (re->magic_number != MAGIC_NUMBER) return PCRE_ERROR_BADMAGIC;
if (optptr != NULL) *optptr = (re->options & PUBLIC_OPTIONS);
if (first_char != NULL)
*first_char = ((re->options & PCRE_FIRSTSET) != 0)? re->first_char :
((re->options & PCRE_STARTLINE) != 0)? -1 : -2;
return re->top_bracket;
}
#ifdef DEBUG
/*************************************************
* Debugging function to print chars *
*************************************************/
/* Print a sequence of chars in printable format, stopping at the end of the
subject if the requested.
Arguments:
p points to characters
length number to print
is_subject TRUE if printing from within md->start_subject
md pointer to matching data block, if is_subject is TRUE
Returns: nothing
*/
static void
pchars(const uschar *p, int length, BOOL is_subject, match_data *md)
{
int c;
if (is_subject && length > md->end_subject - p) length = md->end_subject - p;
while (length-- > 0)
if (isprint(c = *(p++))) printf("%c", c); else printf("\\x%02x", c);
}
#endif
/*************************************************
* Check subpattern for empty operand *
*************************************************/
/* This function checks a bracketed subpattern to see if any of the paths
through it could match an empty string. This is used to diagnose an error if
such a subpattern is followed by a quantifier with an unlimited upper bound.
Argument:
code points to the opening bracket
Returns: TRUE or FALSE
*/
static BOOL
could_be_empty(uschar *code)
{
do {
uschar *cc = code + 3;
/* Scan along the opcodes for this branch; as soon as we find something
that matches a non-empty string, break out and advance to test the next
branch. If we get to the end of the branch, return TRUE for the whole
sub-expression. */
for (;;)
{
/* Test an embedded subpattern; if it could not be empty, break the
loop. Otherwise carry on in the branch. */
if ((int)(*cc) >= OP_BRA || (int)(*cc) == OP_ONCE)
{
if (!could_be_empty(cc)) break;
do cc += (cc[1] << 8) + cc[2]; while (*cc == OP_ALT);
cc += 3;
}
else switch (*cc)
{
/* Reached end of a branch: the subpattern may match the empty string */
case OP_ALT:
case OP_KET:
case OP_KETRMAX:
case OP_KETRMIN:
return TRUE;
/* Skip over entire bracket groups with zero lower bound */
case OP_BRAZERO:
case OP_BRAMINZERO:
cc++;
/* Fall through */
/* Skip over assertive subpatterns */
case OP_ASSERT:
case OP_ASSERT_NOT:
do cc += (cc[1] << 8) + cc[2]; while (*cc == OP_ALT);
cc += 3;
break;
/* Skip over things that don't match chars */
case OP_SOD:
case OP_EOD:
case OP_CIRC:
case OP_DOLL:
case OP_NOT_WORD_BOUNDARY:
case OP_WORD_BOUNDARY:
case OP_NOT_WORD_BOUNDARY_L:
case OP_WORD_BOUNDARY_L:
cc++;
break;
/* Skip over simple repeats with zero lower bound */
case OP_STAR:
case OP_MINSTAR:
case OP_QUERY:
case OP_MINQUERY:
case OP_NOTSTAR:
case OP_NOTMINSTAR:
case OP_NOTQUERY:
case OP_NOTMINQUERY:
case OP_TYPESTAR:
case OP_TYPEMINSTAR:
case OP_TYPEQUERY:
case OP_TYPEMINQUERY:
cc += 2;
break;
/* Skip over UPTOs (lower bound is zero) */
case OP_UPTO:
case OP_MINUPTO:
case OP_TYPEUPTO:
case OP_TYPEMINUPTO:
cc += 4;
break;
/* Check a class or a back reference for a zero minimum */
case OP_CLASS:
case OP_NEGCLASS:
case OP_REF:
case OP_CLASS_L:
switch(*cc)
{
case (OP_REF): cc += 2; break;
case (OP_CLASS): case (OP_NEGCLASS): cc += 1+32; break;
case (OP_CLASS_L): cc += 1+1+32; break;
}
switch (*cc)
{
case OP_CRSTAR:
case OP_CRMINSTAR:
case OP_CRQUERY:
case OP_CRMINQUERY:
cc++;
break;
case OP_CRRANGE:
case OP_CRMINRANGE:
if ((cc[1] << 8) + cc[2] != 0) goto NEXT_BRANCH;
cc += 3;
break;
default:
goto NEXT_BRANCH;
}
break;
/* Anything else matches at least one character */
default:
goto NEXT_BRANCH;
}
}
NEXT_BRANCH:
code += (code[1] << 8) + code[2];
}
while (*code == OP_ALT);
/* No branches match the empty string */
return FALSE;
}
/* Determine the length of a group ID in an expression like
(?P<foo_123>...)
Arguments:
ptr pattern position pointer (say that 3 times fast)
finalchar the character that will mark the end of the ID
errorptr points to the pointer to the error message
*/
static int
get_group_id(const uschar *ptr, char finalchar, const char **errorptr)
{
const uschar *start = ptr;
/* If the first character is not in \w, or is in \w but is a digit,
report an error */
if (!(pcre_ctypes[*ptr] & ctype_word) ||
(pcre_ctypes[*ptr++] & ctype_digit))
{
*errorptr = "(?P identifier must start with a letter or underscore";
return 0;
}
/* Increment ptr until we either hit a null byte, the desired
final character, or a non-word character */
for(; (*ptr != 0) && (*ptr != finalchar) &&
(pcre_ctypes[*ptr] & ctype_word); ptr++)
{
/* Empty loop body */
}
if (*ptr==finalchar)
return ptr-start;
if (*ptr==0)
{
*errorptr = "unterminated (?P identifier";
return 0;
}
*errorptr = "illegal character in (?P identifier";
return 0;
}
/*************************************************
* Handle escapes *
*************************************************/
/* This function is called when a \ has been encountered. It either returns a
positive value for a simple escape such as \n, or a negative value which
encodes one of the more complicated things such as \d. On entry, ptr is
pointing at the \. On exit, it is on the final character of the escape
sequence.
Arguments:
ptrptr points to the pattern position pointer
errorptr points to the pointer to the error message
bracount number of previous extracting brackets
options the options bits
isclass TRUE if inside a character class
Returns: zero or positive => a data character
negative => a special escape sequence
on error, errorptr is set
*/
static int
check_escape(const uschar **ptrptr, const char **errorptr, int bracount,
int options, BOOL isclass)
{
const uschar *ptr = *ptrptr;
int c = *(++ptr) & 255; /* Ensure > 0 on signed-char systems */
int i;
if (c == 0) *errorptr = ERR1;
/* Digits or letters may have special meaning; all others are literals. */
else if (c < '0' || c > 'z') {}
/* Do an initial lookup in a table. A non-zero result is something that can be
returned immediately. Otherwise further processing may be required. */
else if ((i = escapes[c - '0']) != 0) c = i;
/* Escapes that need further processing, or are illegal. */
else
{
switch (c)
{
/* The handling of escape sequences consisting of a string of digits
starting with one that is not zero is not straightforward. By experiment,
the way Perl works seems to be as follows:
Outside a character class, the digits are read as a decimal number. If the
number is less than 10, or if there are that many previous extracting
left brackets, then it is a back reference. Otherwise, up to three octal
digits are read to form an escaped byte. Thus \123 is likely to be octal
123 (cf \0123, which is octal 012 followed by the literal 3). If the octal
value is greater than 377, the least significant 8 bits are taken. Inside a
character class, \ followed by a digit is always an octal number. */
case '1': case '2': case '3': case '4': case '5':
case '6': case '7': case '8': case '9':
{
/* PYTHON: Try to compute an octal value for a character */
for(c=0, i=0; ptr[i]!=0 && i<3; i++)
{
if (( pcre_ctypes[ ptr[i] ] & ctype_odigit) != 0)
c = c * 8 + ptr[i]-'0';
else
break; /* Non-octal character--break out of the loop */
}
/* It's a character if there were exactly 3 octal digits, or if
we're inside a character class and there was at least one
octal digit. */
if ( (i == 3) || (isclass && i!=0) )
{
ptr += i-1;
break;
}
c = ptr[0]; /* Restore the first character after the \ */
c -= '0'; i = 1;
while (i<2 && (pcre_ctypes[ptr[1]] & ctype_digit) != 0)
{
c = c * 10 + ptr[1] - '0';
ptr++; i++;
}
if (c > 255 - ESC_REF) *errorptr = "back reference too big";
c = -(ESC_REF + c);
}
break;
/* \0 always starts an octal number, but we may drop through to here with a
larger first octal digit */
case '0':
c -= '0';
while(i++ < 2 && (pcre_ctypes[ptr[1]] & ctype_digit) != 0 &&
ptr[1] != '8' && ptr[1] != '9')
c = c * 8 + *(++ptr) - '0';
break;
/* Special escapes not starting with a digit are straightforward */
case 'x':
c = 0;
while ( (pcre_ctypes[ptr[1]] & ctype_xdigit) != 0)
{
ptr++;
c = c * 16 + pcre_lcc[*ptr] -
(((pcre_ctypes[*ptr] & ctype_digit) != 0)? '0' : 'W');
c &= 255;
}
break;
/* PCRE_EXTRA enables extensions to Perl in the matter of escapes. Any
other alphameric following \ is an error if PCRE_EXTRA was set; otherwise,
for Perl compatibility, it is a literal. */
default:
if ((options & PCRE_EXTRA) != 0) switch(c)
{
case 'X':
c = -ESC_X; /* This could be a lookup if it ever got into Perl */
break;
default:
*errorptr = ERR3;
break;
}
break;
}
}
*ptrptr = ptr;
return c;
}
/*************************************************
* Check for counted repeat *
*************************************************/
/* This function is called when a '{' is encountered in a place where it might
start a quantifier. It looks ahead to see if it really is a quantifier or not.
It is only a quantifier if it is one of the forms {ddd} {ddd,} or {ddd,ddd}
where the ddds are digits.
Arguments:
p pointer to the first char after '{'
Returns: TRUE or FALSE
*/
static BOOL
is_counted_repeat(const uschar *p)
{
if ((pcre_ctypes[*p++] & ctype_digit) == 0) return FALSE;
while ((pcre_ctypes[*p] & ctype_digit) != 0) p++;
if (*p == '}') return TRUE;
if (*p++ != ',') return FALSE;
if (*p == '}') return TRUE;
if ((pcre_ctypes[*p++] & ctype_digit) == 0) return FALSE;
while ((pcre_ctypes[*p] & ctype_digit) != 0) p++;
return (*p == '}');
}
/*************************************************
* Read repeat counts *
*************************************************/
/* Read an item of the form {n,m} and return the values. This is called only
after is_counted_repeat() has confirmed that a repeat-count quantifier exists,
so the syntax is guaranteed to be correct, but we need to check the values.
Arguments:
p pointer to first char after '{'
minp pointer to int for min
maxp pointer to int for max
returned as -1 if no max
errorptr points to pointer to error message
Returns: pointer to '}' on success;
current ptr on error, with errorptr set
*/
static const uschar *
read_repeat_counts(const uschar *p, int *minp, int *maxp, const char **errorptr)
{
int min = 0;
int max = -1;
while ((pcre_ctypes[*p] & ctype_digit) != 0) min = min * 10 + *p++ - '0';
if (*p == '}') max = min; else
{
if (*(++p) != '}')
{
max = 0;
while((pcre_ctypes[*p] & ctype_digit) != 0) max = max * 10 + *p++ - '0';
if (max < min)
{
*errorptr = ERR4;
return p;
}
}
}
/* Do paranoid checks, then fill in the required variables, and pass back the
pointer to the terminating '}'. */
if (min > 65535 || max > 65535)
*errorptr = ERR5;
else
{
*minp = min;
*maxp = max;
}
return p;
}
/*************************************************
* Compile one branch *
*************************************************/
/* Scan the pattern, compiling it into the code vector.
Arguments:
options the option bits
bracket points to number of brackets used
code points to the pointer to the current code point
ptrptr points to the current pattern pointer
errorptr points to pointer to error message
Returns: TRUE on success
FALSE, with *errorptr set on error
*/
static BOOL
compile_branch(int options, int *brackets, uschar **codeptr,
const uschar **ptrptr, const char **errorptr, PyObject *dictionary)
{
int repeat_type, op_type;
int repeat_min, repeat_max;
int bravalue, length;
int greedy_default, greedy_non_default;
register int c;
register uschar *code = *codeptr;
const uschar *ptr = *ptrptr;
const uschar *oldptr;
uschar *previous = NULL;
uschar class[32];
uschar *class_flag; /* Pointer to the single-byte flag for OP_CLASS_L */
/* Set up the default and non-default settings for greediness */
greedy_default = ((options & PCRE_UNGREEDY) != 0);
greedy_non_default = greedy_default ^ 1;
/* Switch on next character until the end of the branch */
for (;; ptr++)
{
BOOL negate_class;
int class_charcount;
int class_lastchar;
c = *ptr;
if ((options & PCRE_EXTENDED) != 0)
{
if ((pcre_ctypes[c] & ctype_space) != 0) continue;
if (c == '#')
{
while ((c = *(++ptr)) != 0 && c != '\n');
continue;
}
}
switch(c)
{
/* The branch terminates at end of string, |, or ). */
case 0:
case '|':
case ')':
*codeptr = code;
*ptrptr = ptr;
return TRUE;
/* Handle single-character metacharacters */
case '^':
previous = NULL;
*code++ = OP_CIRC;
break;
case '$':
previous = NULL;
*code++ = OP_DOLL;
break;
case '.':
previous = code;
*code++ = OP_ANY;
break;
/* Character classes. These always build a 32-byte bitmap of the permitted
characters, except in the special case where there is only one character.
For negated classes, we build the map as usual, then invert it at the end.
*/
case '[':
previous = code;
if (options & PCRE_LOCALE)
{
*code++ = OP_CLASS_L;
/* Set the flag for localized classes (like \w) to 0 */
class_flag = code;
*class_flag = 0;
}
else
{
*code++ = OP_CLASS;
class_flag = NULL;
}
/* If the first character is '^', set the negation flag, and use a
different opcode. This only matters if caseless matching is specified at
runtime. */
if ((c = *(++ptr)) == '^')
{
negate_class = TRUE;
if (*(code-1)==OP_CLASS) *(code-1) = OP_NEGCLASS;
c = *(++ptr);
}
else negate_class = FALSE;
/* Keep a count of chars so that we can optimize the case of just a single
character. */
class_charcount = 0;
class_lastchar = -1;
/* Initialize the 32-char bit map to all zeros. We have to build the
map in a temporary bit of store, in case the class contains only 1
character, because in that case the compiled code doesn't use the
bit map. */
memset(class, 0, 32 * sizeof(uschar));
/* Process characters until ] is reached. By writing this as a "do" it
means that an initial ] is taken as a data character. */
do
{
if (c == 0)
{
*errorptr = ERR6;
goto FAILED;
}
/* Backslash may introduce a single character, or it may introduce one
of the specials, which just set a flag. Escaped items are checked for
validity in the pre-compiling pass. The sequence \b is a special case.
Inside a class (and only there) it is treated as backspace. Elsewhere
it marks a word boundary. Other escapes have preset maps ready to
or into the one we are building. We assume they have more than one
character in them, so set class_count bigger than one. */
if (c == '\\')
{
c = check_escape(&ptr, errorptr, *brackets, options, TRUE);
if (-c == ESC_b) c = '\b';
else if (c < 0)
{
class_charcount = 10;
switch (-c)
{
case ESC_d:
{
for (c = 0; c < 32; c++) class[c] |= pcre_cbits[c+cbit_digit];
}
continue;
case ESC_D:
{
for (c = 0; c < 32; c++) class[c] |= ~pcre_cbits[c+cbit_digit];
}
continue;
case ESC_w:
if (options & PCRE_LOCALE)
{
*class_flag |= 1;
}
else
{
for (c = 0; c < 32; c++)
class[c] |= (pcre_cbits[c] | pcre_cbits[c+cbit_word]);
}
continue;
case ESC_W:
if (options & PCRE_LOCALE)
{
*class_flag |= 2;
}
else
{
for (c = 0; c < 32; c++)
class[c] |= ~(pcre_cbits[c] | pcre_cbits[c+cbit_word]);
}
continue;
case ESC_s:
{
for (c = 0; c < 32; c++) class[c] |= pcre_cbits[c+cbit_space];
}
continue;
case ESC_S:
{
for (c = 0; c < 32; c++) class[c] |= ~pcre_cbits[c+cbit_space];
}
continue;
default:
*errorptr = ERR7;
goto FAILED;
}
}
/* Fall through if single character */
}
/* A single character may be followed by '-' to form a range. However,
Perl does not permit ']' to be the end of the range. A '-' character
here is treated as a literal. */
if (ptr[1] == '-' && ptr[2] != ']')
{
int d;
ptr += 2;
d = *ptr;
if (d == 0)
{
*errorptr = ERR6;
goto FAILED;
}
/* The second part of a range can be a single-character escape, but
not any of the other escapes. */
if (d == '\\')
{
d = check_escape(&ptr, errorptr, *brackets, options, TRUE);
if (d < 0)
{
if (d == -ESC_b) d = '\b'; else
{
*errorptr = ERR7;
goto FAILED;
}
}
}
if (d < c)
{
*errorptr = ERR8;
goto FAILED;
}
for (; c <= d; c++)
{
class[c/8] |= (1 << (c&7));
if ((options & PCRE_CASELESS) != 0)
{
int uc = pcre_fcc[c]; /* flip case */
class[uc/8] |= (1 << (uc&7));
}
class_charcount++; /* in case a one-char range */
class_lastchar = c;
}
continue; /* Go get the next char in the class */
}
/* Handle a lone single character - we can get here for a normal
non-escape char, or after \ that introduces a single character. */
class [c/8] |= (1 << (c&7));
if ((options & PCRE_CASELESS) != 0)
{
c = pcre_fcc[c]; /* flip case */
class[c/8] |= (1 << (c&7));
}
class_charcount++;
class_lastchar = c;
}
/* Loop until ']' reached; the check for end of string happens inside the
loop. This "while" is the end of the "do" above. */
while ((c = *(++ptr)) != ']');
/* If class_charcount is 1 and class_lastchar is not negative, we saw
precisely one character. This doesn't need the whole 32-byte bit map.
We turn it into a 1-character OP_CHAR if it's positive, or OP_NOT if
it's negative. */
if (class_charcount == 1 && class_lastchar >= 0)
{
if (negate_class)
{
code[-1] = OP_NOT;
}
else
{
code[-1] = OP_CHARS;
*code++ = 1;
}
*code++ = class_lastchar;
}
/* Otherwise, negate the 32-byte map if necessary, and copy it into
the code vector. */
else
{
/* If this is a localized opcode, bump the code pointer up */
if (class_flag) code++;
if (negate_class)
{
if (class_flag) *class_flag = (*class_flag) ^ 63;
for (c = 0; c < 32; c++) code[c] = ~class[c];
}
else
memcpy(code, class, 32);
code += 32;
}
break;
/* Various kinds of repeat */
case '{':
if (!is_counted_repeat(ptr+1)) goto NORMAL_CHAR;
ptr = read_repeat_counts(ptr+1, &repeat_min, &repeat_max, errorptr);
if (*errorptr != NULL) goto FAILED;
goto REPEAT;
case '*':
repeat_min = 0;
repeat_max = -1;
goto REPEAT;
case '+':
repeat_min = 1;
repeat_max = -1;
goto REPEAT;
case '?':
repeat_min = 0;
repeat_max = 1;
REPEAT:
if (previous == NULL)
{
*errorptr = ERR9;
goto FAILED;
}
/* If the next character is '?' this is a minimizing repeat, by default,
but if PCRE_UNGREEDY is set, it works the other way round. Advance to the
next character. */
if (ptr[1] == '?')
{ repeat_type = greedy_non_default; ptr++; }
else repeat_type = greedy_default;
/* If the maximum is zero then the minimum must also be zero; Perl allows
this case, so we do too - by simply omitting the item altogether. */
if (repeat_max == 0) code = previous;
/* If previous was a string of characters, chop off the last one and use it
as the subject of the repeat. If there was only one character, we can
abolish the previous item altogether. */
else if (*previous == OP_CHARS)
{
int len = previous[1];
if (len == 1)
{
c = previous[2];
code = previous;
}
else
{
c = previous[len+1];
previous[1]--;
code--;
}
op_type = 0; /* Use single-char op codes */
goto OUTPUT_SINGLE_REPEAT; /* Code shared with single character types */
}
/* If previous was a single negated character ([^a] or similar), we use
one of the special opcodes, replacing it. The code is shared with single-
character repeats by adding a suitable offset into repeat_type. */
else if ((int)*previous == OP_NOT)
{
op_type = OP_NOTSTAR - OP_STAR; /* Use "not" opcodes */
c = previous[1];
code = previous;
goto OUTPUT_SINGLE_REPEAT;
}
/* If previous was a character type match (\d or similar), abolish it and
create a suitable repeat item. The code is shared with single-character
repeats by adding a suitable offset into repeat_type. */
else if ((int)*previous < OP_CIRC || *previous == OP_ANY)
{
op_type = OP_TYPESTAR - OP_STAR; /* Use type opcodes */
c = *previous;
code = previous;
OUTPUT_SINGLE_REPEAT:
repeat_type += op_type; /* Combine both values for many cases */
/* A minimum of zero is handled either as the special case * or ?, or as
an UPTO, with the maximum given. */
if (repeat_min == 0)
{
if (repeat_max == -1) *code++ = OP_STAR + repeat_type;
else if (repeat_max == 1) *code++ = OP_QUERY + repeat_type;
else
{
*code++ = OP_UPTO + repeat_type;
*code++ = repeat_max >> 8;
*code++ = (repeat_max & 255);
}
}
/* The case {1,} is handled as the special case + */
else if (repeat_min == 1 && repeat_max == -1)
*code++ = OP_PLUS + repeat_type;
/* The case {n,n} is just an EXACT, while the general case {n,m} is
handled as an EXACT followed by an UPTO. An EXACT of 1 is optimized. */
else
{
if (repeat_min != 1)
{
*code++ = OP_EXACT + op_type; /* NB EXACT doesn't have repeat_type */
*code++ = repeat_min >> 8;
*code++ = (repeat_min & 255);
}
/* If the mininum is 1 and the previous item was a character string,
we either have to put back the item that got cancelled if the string
length was 1, or add the character back onto the end of a longer
string. For a character type nothing need be done; it will just get
put back naturally. Note that the final character is always going to
get added below. */
else if (*previous == OP_CHARS)
{
if (code == previous) code += 2; else previous[1]++;
}
/* For a single negated character we also have to put back the
item that got cancelled. */
else if (*previous == OP_NOT) code++;
/* If the maximum is unlimited, insert an OP_STAR. */
if (repeat_max < 0)
{
*code++ = c;
*code++ = OP_STAR + repeat_type;
}
/* Else insert an UPTO if the max is greater than the min. */
else if (repeat_max != repeat_min)
{
*code++ = c;
repeat_max -= repeat_min;
*code++ = OP_UPTO + repeat_type;
*code++ = repeat_max >> 8;
*code++ = (repeat_max & 255);
}
}
/* The character or character type itself comes last in all cases. */
*code++ = c;
}
/* If previous was a character class or a back reference, we put the repeat
stuff after it. */
else if (*previous == OP_CLASS || *previous == OP_NEGCLASS ||
*previous==OP_CLASS_L || *previous == OP_REF)
{
if (repeat_min == 0 && repeat_max == -1)
*code++ = OP_CRSTAR + repeat_type;
else if (repeat_min == 1 && repeat_max == -1)
*code++ = OP_CRPLUS + repeat_type;
else if (repeat_min == 0 && repeat_max == 1)
*code++ = OP_CRQUERY + repeat_type;
else
{
*code++ = OP_CRRANGE + repeat_type;
*code++ = repeat_min >> 8;
*code++ = repeat_min & 255;
if (repeat_max == -1) repeat_max = 0; /* 2-byte encoding for max */
*code++ = repeat_max >> 8;
*code++ = repeat_max & 255;
}
}
/* If previous was a bracket group, we may have to replicate it in certain
cases. If the maximum repeat count is unlimited, check that the bracket
group cannot match the empty string, and diagnose an error if it can. */
else if ((int)*previous >= OP_BRA)
{
int i;
int len = code - previous;
if (repeat_max == -1 && could_be_empty(previous))
{
*errorptr = ERR10;
goto FAILED;
}
/* If the minimum is greater than zero, and the maximum is unlimited or
equal to the minimum, the first copy remains where it is, and is
replicated up to the minimum number of times. This case includes the +
repeat, but of course no replication is needed in that case. */
if (repeat_min > 0 && (repeat_max == -1 || repeat_max == repeat_min))
{
for (i = 1; i < repeat_min; i++)
{
memcpy(code, previous, len);
code += len;
}
}
/* If the minimum is zero, stick BRAZERO in front of the first copy.
Then, if there is a fixed upper limit, replicated up to that many times,
sticking BRAZERO in front of all the optional ones. */
else
{
if (repeat_min == 0)
{
memmove(previous+1, previous, len);
code++;
*previous++ = OP_BRAZERO + repeat_type;
}
for (i = 1; i < repeat_min; i++)
{
memcpy(code, previous, len);
code += len;
}
for (i = (repeat_min > 0)? repeat_min : 1; i < repeat_max; i++)
{
*code++ = OP_BRAZERO + repeat_type;
memcpy(code, previous, len);
code += len;
}
}
/* If the maximum is unlimited, set a repeater in the final copy. */
if (repeat_max == -1) code[-3] = OP_KETRMAX + repeat_type;
}
/* Else there's some kind of shambles */
else
{
*errorptr = ERR11;
goto FAILED;
}
/* In all case we no longer have a previous item. */
previous = NULL;
break;
/* Start of nested bracket sub-expression, or comment or lookahead.
First deal with special things that can come after a bracket; all are
introduced by ?, and the appearance of any of them means that this is not a
referencing group. They were checked for validity in the first pass over
the string, so we don't have to check for syntax errors here. */
case '(':
previous = code; /* Only real brackets can be repeated */
if (*(++ptr) == '?')
{
bravalue = OP_BRA;
switch (*(++ptr))
{
case '#':
case 'i':
case 'L':
case 'm':
case 's':
case 'x':
ptr++;
while (*ptr != ')') ptr++;
previous = NULL;
continue;
case ':': /* Non-extracting bracket */
ptr++;
break;
case '=': /* Assertions can't be repeated */
bravalue = OP_ASSERT;
ptr++;
previous = NULL;
break;
case '!':
bravalue = OP_ASSERT_NOT;
ptr++;
previous = NULL;
break;
case ('P'):
ptr++;
if (*ptr=='<')
{
/* (?P<groupname>...) */
int idlen;
PyObject *string, *intobj;
ptr++;
idlen = get_group_id(ptr, '>', errorptr);
if (*errorptr) {
goto FAILED;
}
string = PyString_FromStringAndSize((char*)ptr, idlen);
intobj = PyInt_FromLong( brackets[0] + 1 );
if (intobj == NULL || string == NULL)
{
Py_XDECREF(string);
Py_XDECREF(intobj);
*errorptr = "exception raised";
goto FAILED;
}
PyDict_SetItem(dictionary, string, intobj);
Py_DECREF(string); Py_DECREF(intobj); /* XXX DECREF commented out! */
ptr += idlen+1; /* Point to rest of expression */
goto do_grouping_bracket;
}
if (*ptr=='=')
{
/* (?P=groupname) */
int idlen, refnum;
PyObject *string, *intobj;
ptr++;
idlen = get_group_id(ptr, ')', errorptr);
if (*errorptr) {
goto FAILED;
}
string = PyString_FromStringAndSize((char *)ptr, idlen);
if (string==NULL) {
*errorptr = "exception raised";
goto FAILED;
}
intobj = PyDict_GetItem(dictionary, string);
if (intobj==NULL) {
Py_DECREF(string);
*errorptr = "?P= group identifier isn't defined";
goto FAILED;
}
refnum = PyInt_AsLong(intobj);
Py_DECREF(string);
/* The caller doesn't own the reference to the value
returned from PyDict_GetItem, so intobj is not
DECREF'ed. */
*code++ = OP_REF;
*code++ = refnum;
/* The continue will cause the top-level for() loop to
be resumed, so ptr will be immediately incremented.
Therefore, the following line adds just idlen, not
idlen+1 */
ptr += idlen;
continue;
}
/* The character after ?P is neither < nor =, so
report an error. Add more Python-extensions here. */
*errorptr="unknown after (?P";
goto FAILED;
break;
case '>': /* "Match once" brackets */
if ((options & PCRE_EXTRA) != 0) /* Not yet standard */
{
bravalue = OP_ONCE;
ptr++;
previous = NULL;
break;
}
/* Else fall through */
default:
*errorptr = ERR12;
goto FAILED;
}
}
/* Else we have a referencing group */
else
{
do_grouping_bracket:
if (++(*brackets) > EXTRACT_MAX)
{
*errorptr = ERR13;
goto FAILED;
}
bravalue = OP_BRA + *brackets;
}
/* Process nested bracketed re; at end pointer is on the bracket. We copy
code into a non-register variable in order to be able to pass its address
because some compilers complain otherwise. */
*code = bravalue;
{
uschar *mcode = code;
if (!compile_regex(options, brackets, &mcode, &ptr, errorptr, dictionary))
goto FAILED;
code = mcode;
}
if (*ptr != ')')
{
*errorptr = ERR14;
goto FAILED;
}
break;
/* Check \ for being a real metacharacter; if not, fall through and handle
it as a data character at the start of a string. Escape items are checked
for validity in the pre-compiling pass. */
case '\\':
oldptr = ptr;
c = check_escape(&ptr, errorptr, *brackets, options, FALSE);
/* Handle metacharacters introduced by \. For ones like \d, the ESC_ values
are arranged to be the negation of the corresponding OP_values. For the
back references, the values are ESC_REF plus the reference number. Only
back references and those types that consume a character may be repeated.
We can test for values between ESC_b and ESC_Z for the latter; this may
have to change if any new ones are ever created. */
if (c < 0)
{
if (-c >= ESC_REF)
{
int refnum = -c - ESC_REF;
if (*brackets < refnum)
{
*errorptr = ERR15;
goto FAILED;
}
previous = code;
*code++ = OP_REF;
*code++ = refnum;
}
else
{
previous = (-c > ESC_b && -c < ESC_X)? code : NULL;
if ( (options & PCRE_LOCALE) != 0)
{
switch (c)
{
case (-ESC_b): c = -OP_WORD_BOUNDARY_L; break;
case (-ESC_B): c = -OP_NOT_WORD_BOUNDARY_L; break;
case (-ESC_w): c = -OP_WORDCHAR_L; break;
case (-ESC_W): c = -OP_NOT_WORDCHAR_L; break;
}
}
*code++ = -c;
}
continue;
}
/* Data character: Reset and fall through */
ptr = oldptr;
c = '\\';
/* Handle a run of data characters until a metacharacter is encountered.
The first character is guaranteed not to be whitespace or # when the
extended flag is set. */
NORMAL_CHAR:
default:
previous = code;
*code = OP_CHARS;
code += 2;
length = 0;
do
{
if ((options & PCRE_EXTENDED) != 0)
{
if ((pcre_ctypes[c] & ctype_space) != 0) continue;
if (c == '#')
{
while ((c = *(++ptr)) != 0 && c != '\n');
if (c == 0) break;
continue;
}
}
/* Backslash may introduce a data char or a metacharacter. Escaped items
are checked for validity in the pre-compiling pass. Stop the string
before a metaitem. */
if (c == '\\')
{
oldptr = ptr;
c = check_escape(&ptr, errorptr, *brackets, options, FALSE);
if (c < 0) { ptr = oldptr; break; }
}
/* Ordinary character or single-char escape */
*code++ = c;
length++;
}
/* This "while" is the end of the "do" above. */
while (length < 255 && (pcre_ctypes[c = *(++ptr)] & ctype_meta) == 0);
/* Compute the length and set it in the data vector, and advance to
the next state. */
previous[1] = length;
if (length < 255) ptr--;
break;
}
} /* end of big loop */
/* Control never reaches here by falling through, only by a goto for all the
error states. Pass back the position in the pattern so that it can be displayed
to the user for diagnosing the error. */
FAILED:
*ptrptr = ptr;
return FALSE;
}
/*************************************************
* Compile sequence of alternatives *
*************************************************/
/* On entry, ptr is pointing past the bracket character, but on return
it points to the closing bracket, or vertical bar, or end of string.
The code variable is pointing at the byte into which the BRA operator has been
stored.
Argument:
options the option bits
brackets -> int containing the number of extracting brackets used
codeptr -> the address of the current code pointer
ptrptr -> the address of the current pattern pointer
errorptr -> pointer to error message
Returns: TRUE on success
*/
static BOOL
compile_regex(int options, int *brackets, uschar **codeptr,
const uschar **ptrptr, const char **errorptr, PyObject *dictionary)
{
const uschar *ptr = *ptrptr;
uschar *code = *codeptr;
uschar *start_bracket = code;
for (;;)
{
int length;
uschar *last_branch = code;
code += 3;
if (!compile_branch(options, brackets, &code, &ptr, errorptr, dictionary))
{
*ptrptr = ptr;
return FALSE;
}
/* Fill in the length of the last branch */
length = code - last_branch;
last_branch[1] = length >> 8;
last_branch[2] = length & 255;
/* Reached end of expression, either ')' or end of pattern. Insert a
terminating ket and the length of the whole bracketed item, and return,
leaving the pointer at the terminating char. */
if (*ptr != '|')
{
length = code - start_bracket;
*code++ = OP_KET;
*code++ = length >> 8;
*code++ = length & 255;
*codeptr = code;
*ptrptr = ptr;
return TRUE;
}
/* Another branch follows; insert an "or" node and advance the pointer. */
*code = OP_ALT;
ptr++;
}
/* Control never reaches here */
}
/*************************************************
* Check for anchored expression *
*************************************************/
/* Try to find out if this is an anchored regular expression. Consider each
alternative branch. If they all start with OP_SOD or OP_CIRC, or with a bracket
all of whose alternatives start with OP_SOD or OP_CIRC (recurse ad lib), then
it's anchored. However, if this is a multiline pattern, then only OP_SOD
counts, since OP_CIRC can match in the middle.
A branch is also implicitly anchored if it starts with .* because that will try
the rest of the pattern at all possible matching points, so there is no point
trying them again.
Argument: points to start of expression (the bracket)
Returns: TRUE or FALSE
*/
static BOOL
is_anchored(register const uschar *code, BOOL multiline)
{
do {
int op = (int)code[3];
if (op >= OP_BRA || op == OP_ASSERT || op == OP_ONCE)
{ if (!is_anchored(code+3, multiline)) return FALSE; }
else if (op == OP_TYPESTAR || op == OP_TYPEMINSTAR)
{ if (code[4] != OP_ANY) return FALSE; }
else if (op != OP_SOD && (multiline || op != OP_CIRC)) return FALSE;
code += (code[1] << 8) + code[2];
}
while (*code == OP_ALT);
return TRUE;
}
/*************************************************
* Check for start with \n line expression *
*************************************************/
/* This is called for multiline expressions to try to find out if every branch
starts with ^ so that "first char" processing can be done to speed things up.
Argument: points to start of expression (the bracket)
Returns: TRUE or FALSE
*/
static BOOL
is_startline(const uschar *code)
{
do {
if ((int)code[3] >= OP_BRA || code[3] == OP_ASSERT)
{ if (!is_startline(code+3)) return FALSE; }
else if (code[3] != OP_CIRC) return FALSE;
code += (code[1] << 8) + code[2];
}
while (*code == OP_ALT);
return TRUE;
}
/*************************************************
* Check for fixed first char *
*************************************************/
/* Try to find out if there is a fixed first character. This is called for
unanchored expressions, as it speeds up their processing quite considerably.
Consider each alternative branch. If they all start with the same char, or with
a bracket all of whose alternatives start with the same char (recurse ad lib),
then we return that char, otherwise -1.
Argument: points to start of expression (the bracket)
Returns: -1 or the fixed first char
*/
static int
find_firstchar(uschar *code)
{
register int c = -1;
do
{
register int charoffset = 4;
if ((int)code[3] >= OP_BRA || code[3] == OP_ASSERT)
{
register int d;
if ((d = find_firstchar(code+3)) < 0) return -1;
if (c < 0) c = d; else if (c != d) return -1;
}
else switch(code[3])
{
default:
return -1;
case OP_EXACT: /* Fall through */
charoffset++;
case OP_CHARS: /* Fall through */
charoffset++;
case OP_PLUS:
case OP_MINPLUS:
if (c < 0) c = code[charoffset]; else if (c != code[charoffset]) return -1;
break;
}
code += (code[1] << 8) + code[2];
}
while (*code == OP_ALT);
return c;
}
/*************************************************
* Compile a Regular Expression *
*************************************************/
/* This function takes a string and returns a pointer to a block of store
holding a compiled version of the expression.
Arguments:
pattern the regular expression
options various option bits
errorptr pointer to pointer to error text
erroroffset ptr offset in pattern where error was detected
Returns: pointer to compiled data block, or NULL on error,
with errorptr and erroroffset set
*/
pcre *
pcre_compile(const char *pattern, int options, const char **errorptr,
int *erroroffset, PyObject *dictionary)
{
real_pcre *re;
int spaces = 0;
int length = 3; /* For initial BRA plus length */
int runlength;
int c, size;
int bracount = 0;
int brastack[200];
int top_backref = 0;
unsigned int brastackptr = 0;
uschar *code;
const uschar *ptr;
#ifdef DEBUG
uschar *code_base, *code_end;
#endif
/* We can't pass back an error message if errorptr is NULL; I guess the best we
can do is just return NULL. */
if (errorptr == NULL) return NULL;
*errorptr = NULL;
/* However, we can give a message for this error */
if (erroroffset == NULL)
{
*errorptr = ERR16;
return NULL;
}
*erroroffset = 0;
if ((options & ~PUBLIC_OPTIONS) != 0)
{
*errorptr = ERR17;
return NULL;
}
DPRINTF(("------------------------------------------------------------------\n"));
DPRINTF(("%s\n", pattern));
/* The first thing to do is to make a pass over the pattern to compute the
amount of store required to hold the compiled code. This does not have to be
perfect as long as errors are overestimates. At the same time we can detect any
internal flag settings. Make an attempt to correct for any counted white space
if an "extended" flag setting appears late in the pattern. We can't be so
clever for #-comments. */
ptr = (const uschar *)(pattern - 1);
while ((c = *(++ptr)) != 0)
{
int min, max;
int class_charcount;
if ((pcre_ctypes[c] & ctype_space) != 0)
{
if ((options & PCRE_EXTENDED) != 0) continue;
spaces++;
}
if (c == '#' && (options & PCRE_EXTENDED) != 0)
{
while ((c = *(++ptr)) != 0 && c != '\n');
continue;
}
switch(c)
{
/* A backslashed item may be an escaped "normal" character or a
character type. For a "normal" character, put the pointers and
character back so that tests for whitespace etc. in the input
are done correctly. */
case '\\':
{
const uschar *save_ptr = ptr;
c = check_escape(&ptr, errorptr, bracount, options, FALSE);
if (*errorptr != NULL) goto PCRE_ERROR_RETURN;
if (c >= 0)
{
ptr = save_ptr;
c = '\\';
goto NORMAL_CHAR;
}
}
length++;
/* A back reference needs an additional char, plus either one or 5
bytes for a repeat. We also need to keep the value of the highest
back reference. */
if (c <= -ESC_REF)
{
int refnum = -c - ESC_REF;
if (refnum > top_backref) top_backref = refnum;
length++; /* For single back reference */
if (ptr[1] == '{' && is_counted_repeat(ptr+2))
{
ptr = read_repeat_counts(ptr+2, &min, &max, errorptr);
if (*errorptr != NULL) goto PCRE_ERROR_RETURN;
if ((min == 0 && (max == 1 || max == -1)) ||
(min == 1 && max == -1))
length++;
else length += 5;
if (ptr[1] == '?') ptr++;
}
}
continue;
case '^':
case '.':
case '$':
case '*': /* These repeats won't be after brackets; */
case '+': /* those are handled separately */
case '?':
length++;
continue;
/* This covers the cases of repeats after a single char, metachar, class,
or back reference. */
case '{':
if (!is_counted_repeat(ptr+1)) goto NORMAL_CHAR;
ptr = read_repeat_counts(ptr+1, &min, &max, errorptr);
if (*errorptr != NULL) goto PCRE_ERROR_RETURN;
if ((min == 0 && (max == 1 || max == -1)) ||
(min == 1 && max == -1))
length++;
else
{
length--; /* Uncount the original char or metachar */
if (min == 1) length++; else if (min > 0) length += 4;
if (max > 0) length += 4; else length += 2;
}
if (ptr[1] == '?') ptr++;
continue;
/* An alternation contains an offset to the next branch or ket. */
case '|':
length += 3;
continue;
/* A character class uses 33 characters. Don't worry about character types
that aren't allowed in classes - they'll get picked up during the compile.
A character class that contains only one character uses 2 or 3 bytes,
depending on whether it is negated or not. Notice this where we can. */
case '[':
class_charcount = 0;
if (*(++ptr) == '^') ptr++;
do
{
if (*ptr == '\\')
{
int ch = check_escape(&ptr, errorptr, bracount, options, TRUE);
if (*errorptr != NULL) goto PCRE_ERROR_RETURN;
if (-ch == ESC_b) class_charcount++; else class_charcount = 10;
}
else class_charcount++;
ptr++;
}
while (*ptr != 0 && *ptr != ']');
/* Repeats for negated single chars are handled by the general code */
if (class_charcount == 1) length += 3; else
{
length += 33;
if (options & PCRE_LOCALE) length++; /* Add a byte for the localization flag */
/* A repeat needs either 1 or 5 bytes. */
if (*ptr != 0 && ptr[1] == '{' && is_counted_repeat(ptr+2))
{
ptr = read_repeat_counts(ptr+2, &min, &max, errorptr);
if (*errorptr != NULL) goto PCRE_ERROR_RETURN;
if ((min == 0 && (max == 1 || max == -1)) ||
(min == 1 && max == -1))
length++;
else length += 5;
if (ptr[1] == '?') ptr++;
}
}
continue;
/* Brackets may be genuine groups or special things */
case '(':
/* Handle special forms of bracket, which all start (? */
if (ptr[1] == '?') switch (c = ptr[2])
{
/* Skip over comments entirely */
case '#':
ptr += 3;
while (*ptr != 0 && *ptr != ')') ptr++;
if (*ptr == 0)
{
*errorptr = ERR18;
goto PCRE_ERROR_RETURN;
}
continue;
/* Non-referencing groups and lookaheads just move the pointer on, and
then behave like a non-special bracket, except that they don't increment
the count of extracting brackets. */
case ':':
case '=':
case '!':
ptr += 2;
break;
case ('P'):
{
int idlen;
switch (*ptr++) {
case ('<'):
idlen = get_group_id(ptr++, '>', errorptr);
if (*errorptr) goto PCRE_ERROR_RETURN;
ptr += idlen+1;
break;
case ('='):
idlen = get_group_id(ptr++, ')', errorptr);
if (*errorptr) goto PCRE_ERROR_RETURN;
ptr += idlen+1;
length++;
break;
}
}
break;
/* Ditto for the "once only" bracket, allowed only if the extra bit
is set. */
case '>':
if ((options & PCRE_EXTRA) != 0)
{
ptr += 2;
break;
}
/* Else fall through */
/* Else loop setting valid options until ) is met. Anything else is an
error. */
default:
ptr += 2;
for (;; ptr++)
{
if ((c = *ptr) == 'i')
{
options |= PCRE_CASELESS;
continue;
}
else if ((c = *ptr) == 'L')
{
options |= PCRE_LOCALE;
continue;
}
else if ((c = *ptr) == 'm')
{
options |= PCRE_MULTILINE;
continue;
}
else if (c == 's')
{
options |= PCRE_DOTALL;
continue;
}
else if (c == 'x')
{
options |= PCRE_EXTENDED;
length -= spaces; /* Already counted spaces */
continue;
}
else if (c == ')') break;
*errorptr = ERR12;
goto PCRE_ERROR_RETURN;
}
continue; /* End of this bracket handling */
}
/* Extracting brackets must be counted so we can process escapes in a
Perlish way. */
else bracount++;
/* Non-special forms of bracket. Save length for computing whole length
at end if there's a repeat that requires duplication of the group. */
if (brastackptr >= sizeof(brastack)/sizeof(int))
{
*errorptr = ERR19;
goto PCRE_ERROR_RETURN;
}
brastack[brastackptr++] = length;
length += 3;
continue;
/* Handle ket. Look for subsequent max/min; for certain sets of values we
have to replicate this bracket up to that many times. If brastackptr is
0 this is an unmatched bracket which will generate an error, but take care
not to try to access brastack[-1]. */
case ')':
length += 3;
{
int minval = 1;
int maxval = 1;
int duplength = (brastackptr > 0)? length - brastack[--brastackptr] : 0;
/* Leave ptr at the final char; for read_repeat_counts this happens
automatically; for the others we need an increment. */
if ((c = ptr[1]) == '{' && is_counted_repeat(ptr+2))
{
ptr = read_repeat_counts(ptr+2, &minval, &maxval, errorptr);
if (*errorptr != NULL) goto PCRE_ERROR_RETURN;
}
else if (c == '*') { minval = 0; maxval = -1; ptr++; }
else if (c == '+') { maxval = -1; ptr++; }
else if (c == '?') { minval = 0; ptr++; }
/* If there is a minimum > 1 we have to replicate up to minval-1 times;
if there is a limited maximum we have to replicate up to maxval-1 times
and allow for a BRAZERO item before each optional copy, as we also have
to do before the first copy if the minimum is zero. */
if (minval == 0) length++;
else if (minval > 1) length += (minval - 1) * duplength;
if (maxval > minval) length += (maxval - minval) * (duplength + 1);
}
continue;
/* Non-special character. For a run of such characters the length required
is the number of characters + 2, except that the maximum run length is 255.
We won't get a skipped space or a non-data escape or the start of a #
comment as the first character, so the length can't be zero. */
NORMAL_CHAR:
default:
length += 2;
runlength = 0;
do
{
if ((pcre_ctypes[c] & ctype_space) != 0)
{
if ((options & PCRE_EXTENDED) != 0) continue;
spaces++;
}
if (c == '#' && (options & PCRE_EXTENDED) != 0)
{
while ((c = *(++ptr)) != 0 && c != '\n');
continue;
}
/* Backslash may introduce a data char or a metacharacter; stop the
string before the latter. */
if (c == '\\')
{
const uschar *saveptr = ptr;
c = check_escape(&ptr, errorptr, bracount, options, FALSE);
if (*errorptr != NULL) goto PCRE_ERROR_RETURN;
if (c < 0) { ptr = saveptr; break; }
}
/* Ordinary character or single-char escape */
runlength++;
}
/* This "while" is the end of the "do" above. */
while (runlength < 255 && (pcre_ctypes[c = *(++ptr)] & ctype_meta) == 0);
ptr--;
length += runlength;
continue;
}
}
length += 4; /* For final KET and END */
if (length > 65539)
{
*errorptr = ERR20;
return NULL;
}
/* Compute the size of data block needed and get it, either from malloc or
externally provided function. We specify "code[0]" in the offsetof() expression
rather than just "code", because it has been reported that one broken compiler
fails on "code" because it is also an independent variable. It should make no
difference to the value of the offsetof(). */
size = length + offsetof(real_pcre, code[0]);
re = (real_pcre *)(pcre_malloc)(size+50);
if (re == NULL)
{
*errorptr = ERR21;
return NULL;
}
/* Put in the magic number and the options. */
re->magic_number = MAGIC_NUMBER;
re->options = options;
/* Set up a starting, non-extracting bracket, then compile the expression. On
error, *errorptr will be set non-NULL, so we don't need to look at the result
of the function here. */
ptr = (const uschar *)pattern;
code = re->code;
*code = OP_BRA;
bracount = 0;
(void)compile_regex(options, &bracount, &code, &ptr, errorptr, dictionary);
re->top_bracket = bracount;
re->top_backref = top_backref;
/* If not reached end of pattern on success, there's an excess bracket. */
if (*errorptr == NULL && *ptr != 0) *errorptr = ERR22;
/* Fill in the terminating state and check for disastrous overflow, but
if debugging, leave the test till after things are printed out. */
*code++ = OP_END;
#ifndef DEBUG
if (code - re->code > length) *errorptr = ERR23;
#endif
/* Failed to compile */
if (*errorptr != NULL)
{
(pcre_free)(re);
PCRE_ERROR_RETURN:
*erroroffset = ptr - (const uschar *)pattern;
return NULL;
}
/* If the anchored option was not passed, set flag if we can determine that it
is anchored by virtue of ^ characters or \A or anything else. Otherwise, see if
we can determine what the first character has to be, because that speeds up
unanchored matches no end. In the case of multiline matches, an alternative is
to set the PCRE_STARTLINE flag if all branches start with ^. */
if ((options & PCRE_ANCHORED) == 0)
{
if (is_anchored(re->code, (options & PCRE_MULTILINE) != 0))
re->options |= PCRE_ANCHORED;
else
{
int ch = find_firstchar(re->code);
if (ch >= 0)
{
re->first_char = ch;
re->options |= PCRE_FIRSTSET;
}
else if (is_startline(re->code))
re->options |= PCRE_STARTLINE;
}
}
/* Print out the compiled data for debugging */
#ifdef DEBUG
printf("Length = %d top_bracket = %d top_backref=%d\n",
length, re->top_bracket, re->top_backref);
if (re->options != 0)
{
printf("%s%s%s%s%s%s%s%s\n",
((re->options & PCRE_ANCHORED) != 0)? "anchored " : "",
((re->options & PCRE_CASELESS) != 0)? "caseless " : "",
((re->options & PCRE_EXTENDED) != 0)? "extended " : "",
((re->options & PCRE_MULTILINE) != 0)? "multiline " : "",
((re->options & PCRE_DOTALL) != 0)? "dotall " : "",
((re->options & PCRE_DOLLAR_ENDONLY) != 0)? "endonly " : "",
((re->options & PCRE_EXTRA) != 0)? "extra " : "",
((re->options & PCRE_UNGREEDY) != 0)? "ungreedy " : "");
}
if ((re->options & PCRE_FIRSTSET) != 0)
{
if (isprint(re->first_char)) printf("First char = %c\n", re->first_char);
else printf("First char = \\x%02x\n", re->first_char);
}
code_end = code;
code_base = code = re->code;
while (code < code_end)
{
int charlength;
printf("%3d ", code - code_base);
if (*code >= OP_BRA)
{
printf("%3d Bra %d", (code[1] << 8) + code[2], *code - OP_BRA);
code += 2;
}
else switch(*code)
{
case OP_CHARS:
charlength = *(++code);
printf("%3d ", charlength);
while (charlength-- > 0)
if (isprint(c = *(++code))) printf("%c", c); else printf("\\x%02x", c);
break;
case OP_KETRMAX:
case OP_KETRMIN:
case OP_ALT:
case OP_KET:
case OP_ASSERT:
case OP_ASSERT_NOT:
case OP_ONCE:
printf("%3d %s", (code[1] << 8) + code[2], OP_names[*code]);
code += 2;
break;
case OP_STAR:
case OP_MINSTAR:
case OP_PLUS:
case OP_MINPLUS:
case OP_QUERY:
case OP_MINQUERY:
case OP_TYPESTAR:
case OP_TYPEMINSTAR:
case OP_TYPEPLUS:
case OP_TYPEMINPLUS:
case OP_TYPEQUERY:
case OP_TYPEMINQUERY:
if (*code >= OP_TYPESTAR)
printf(" %s", OP_names[code[1]]);
else if (isprint(c = code[1])) printf(" %c", c);
else printf(" \\x%02x", c);
printf("%s", OP_names[*code++]);
break;
case OP_EXACT:
case OP_UPTO:
case OP_MINUPTO:
if (isprint(c = code[3])) printf(" %c{", c);
else printf(" \\x%02x{", c);
if (*code != OP_EXACT) printf("0,");
printf("%d}", (code[1] << 8) + code[2]);
if (*code == OP_MINUPTO) printf("?");
code += 3;
break;
case OP_TYPEEXACT:
case OP_TYPEUPTO:
case OP_TYPEMINUPTO:
printf(" %s{", OP_names[code[3]]);
if (*code != OP_TYPEEXACT) printf(",");
printf("%d}", (code[1] << 8) + code[2]);
if (*code == OP_TYPEMINUPTO) printf("?");
code += 3;
break;
case OP_NOT:
if (isprint(c = *(++code))) printf(" [^%c]", c);
else printf(" [^\\x%02x]", c);
break;
case OP_NOTSTAR:
case OP_NOTMINSTAR:
case OP_NOTPLUS:
case OP_NOTMINPLUS:
case OP_NOTQUERY:
case OP_NOTMINQUERY:
if (isprint(c = code[1])) printf(" [^%c]", c);
else printf(" [^\\x%02x]", c);
printf("%s", OP_names[*code++]);
break;
case OP_NOTEXACT:
case OP_NOTUPTO:
case OP_NOTMINUPTO:
if (isprint(c = code[3])) printf(" [^%c]{", c);
else printf(" [^\\x%02x]{", c);
if (*code != OP_NOTEXACT) printf(",");
printf("%d}", (code[1] << 8) + code[2]);
if (*code == OP_NOTMINUPTO) printf("?");
code += 3;
break;
case OP_REF:
printf(" \\%d", *(++code));
code ++;
goto CLASS_REF_REPEAT;
case OP_CLASS:
case OP_NEGCLASS:
case OP_CLASS_L:
{
int i, min, max;
if (*code==OP_CLASS_L)
{
code++;
printf("Locflag = %i ", *code++);
printf(" [");
}
else
{
if (*code++ == OP_CLASS) printf(" [");
else printf(" ^[");
}
for (i = 0; i < 256; i++)
{
if ((code[i/8] & (1 << (i&7))) != 0)
{
int j;
for (j = i+1; j < 256; j++)
if ((code[j/8] & (1 << (j&7))) == 0) break;
if (i == '-' || i == ']') printf("\\");
if (isprint(i)) printf("%c", i); else printf("\\x%02x", i);
if (--j > i)
{
printf("-");
if (j == '-' || j == ']') printf("\\");
if (isprint(j)) printf("%c", j); else printf("\\x%02x", j);
}
i = j;
}
}
printf("]");
code += 32;
/* code ++;*/
CLASS_REF_REPEAT:
switch(*code)
{
case OP_CRSTAR:
case OP_CRMINSTAR:
case OP_CRPLUS:
case OP_CRMINPLUS:
case OP_CRQUERY:
case OP_CRMINQUERY:
printf("%s", OP_names[*code]);
break;
case OP_CRRANGE:
case OP_CRMINRANGE:
min = (code[1] << 8) + code[2];
max = (code[3] << 8) + code[4];
if (max == 0) printf("{%d,}", min);
else printf("{%d,%d}", min, max);
if (*code == OP_CRMINRANGE) printf("?");
code += 4;
break;
default:
code--;
}
}
break;
/* Anything else is just a one-node item */
default:
printf(" %s", OP_names[*code]);
break;
}
code++;
printf("\n");
}
printf("------------------------------------------------------------------\n");
/* This check is done here in the debugging case so that the code that
was compiled can be seen. */
if (code - re->code > length)
{
printf("length=%i, code length=%i\n", length, code-re->code);
*errorptr = ERR23;
(pcre_free)(re);
*erroroffset = ptr - (uschar *)pattern;
return NULL;
}
#endif
return (pcre *)re;
}
/*************************************************
* Match a character type *
*************************************************/
/* Not used in all the places it might be as it's sometimes faster
to put the code inline.
Arguments:
type the character type
c the character
dotall the dotall flag
Returns: TRUE if character is of the type
*/
static BOOL
match_type(int type, int c, BOOL dotall)
{
#ifdef DEBUG
if (isprint(c)) printf("matching subject %c against ", c);
else printf("matching subject \\x%02x against ", c);
printf("%s\n", OP_names[type]);
#endif
switch(type)
{
case OP_ANY: return dotall || c != '\n';
case OP_NOT_DIGIT: return (pcre_ctypes[c] & ctype_digit) == 0;
case OP_DIGIT: return (pcre_ctypes[c] & ctype_digit) != 0;
case OP_NOT_WHITESPACE: return (pcre_ctypes[c] & ctype_space) == 0;
case OP_WHITESPACE: return (pcre_ctypes[c] & ctype_space) != 0;
case OP_NOT_WORDCHAR: return (pcre_ctypes[c] & ctype_word) == 0;
case OP_WORDCHAR: return (pcre_ctypes[c] & ctype_word) != 0;
case OP_NOT_WORDCHAR_L: return (c!='_' && !isalnum(c));
case OP_WORDCHAR_L: return (c=='_' || isalnum(c));
}
return FALSE;
}
/*************************************************
* Match a back-reference *
*************************************************/
/* If a back reference hasn't been set, the match fails.
Arguments:
number reference number
eptr points into the subject
length length to be matched
md points to match data block
Returns: TRUE if matched
*/
static BOOL
match_ref(int number, register const uschar *eptr, int length, match_data *md)
{
const uschar *p = md->start_subject + md->offset_vector[number];
#ifdef DEBUG
if (eptr >= md->end_subject)
printf("matching subject <null>");
else
{
printf("matching subject ");
pchars(eptr, length, TRUE, md);
}
printf(" against backref ");
pchars(p, length, FALSE, md);
printf("\n");
#endif
/* Always fail if not enough characters left */
if (length > md->end_subject - p) return FALSE;
/* Separate the caseless case for speed */
if (md->caseless)
{ while (length-- > 0) if (pcre_lcc[*p++] != pcre_lcc[*eptr++]) return FALSE; }
else
{ while (length-- > 0) if (*p++ != *eptr++) return FALSE; }
return TRUE;
}
static int free_stack(match_data *md)
{
/* Free any stack space that was allocated by the call to match(). */
if (md->off_num) free(md->off_num);
if (md->offset_top) free(md->offset_top);
if (md->r1) free(md->r1);
if (md->r2) free(md->r2);
if (md->eptr) free((char *)md->eptr);
if (md->ecode) free((char *)md->ecode);
return 0;
}
static int grow_stack(match_data *md)
{
if (md->length != 0)
{
md->length = md->length + md->length/2;
}
else
{
int string_len = md->end_subject - md->start_subject + 1;
if (string_len < 80) {md->length = string_len; }
else {md->length = 80;}
}
PyMem_RESIZE(md->offset_top, int, md->length);
PyMem_RESIZE(md->eptr, const uschar *, md->length);
PyMem_RESIZE(md->ecode, const uschar *, md->length);
PyMem_RESIZE(md->off_num, int, md->length);
PyMem_RESIZE(md->r1, int, md->length);
PyMem_RESIZE(md->r2, int, md->length);
if (md->offset_top == NULL || md->eptr == NULL || md->ecode == NULL ||
md->off_num == NULL || md->r1 == NULL || md->r2 == NULL)
{
PyErr_NoMemory();
longjmp(md->error_env, 1);
}
return 0;
}
/*************************************************
* Match from current position *
*************************************************/
/* On entry ecode points to the first opcode, and eptr to the first character.
Arguments:
eptr pointer in subject
ecode position in code
offset_top current top pointer
md pointer to "static" info for the match
Returns: TRUE if matched
*/
static BOOL
match(register const uschar *eptr, register const uschar *ecode, int offset_top,
match_data *md)
{
int save_stack_position = md->point;
match_loop:
#define SUCCEED goto succeed
#define FAIL goto fail
for (;;)
{
int min, max, ctype;
register int i;
register int c;
BOOL minimize = FALSE;
/* Opening bracket. Check the alternative branches in turn, failing if none
match. We have to set the start offset if required and there is space
in the offset vector so that it is available for subsequent back references
if the bracket matches. However, if the bracket fails, we must put back the
previous value of both offsets in case they were set by a previous copy of
the same bracket. Don't worry about setting the flag for the error case here;
that is handled in the code for KET. */
if ((int)*ecode >= OP_BRA)
{
int number = (*ecode - OP_BRA) << 1;
int save_offset1 = 0, save_offset2 = 0;
DPRINTF(("start bracket %d\n", number/2));
if (number > 0 && number < md->offset_end)
{
save_offset1 = md->offset_vector[number];
save_offset2 = md->offset_vector[number+1];
md->offset_vector[number] = eptr - md->start_subject;
DPRINTF(("saving %d %d\n", save_offset1, save_offset2));
}
/* Recurse for all the alternatives. */
do
{
if (match(eptr, ecode+3, offset_top, md)) SUCCEED;
ecode += (ecode[1] << 8) + ecode[2];
}
while (*ecode == OP_ALT);
DPRINTF(("bracket %d failed\n", number/2));
if (number > 0 && number < md->offset_end)
{
md->offset_vector[number] = save_offset1;
md->offset_vector[number+1] = save_offset2;
}
FAIL;
}
/* Other types of node can be handled by a switch */
switch(*ecode)
{
case OP_END:
md->end_match_ptr = eptr; /* Record where we ended */
md->end_offset_top = offset_top; /* and how many extracts were taken */
SUCCEED;
/* The equivalent of Prolog's "cut" - if the rest doesn't match, the
whole thing doesn't match, so we have to get out via a longjmp(). */
case OP_CUT:
if (match(eptr, ecode+1, offset_top, md)) SUCCEED;
longjmp(md->fail_env, 1);
/* Assertion brackets. Check the alternative branches in turn - the
matching won't pass the KET for an assertion. If any one branch matches,
the assertion is true. */
case OP_ASSERT:
do
{
if (match(eptr, ecode+3, offset_top, md)) break;
ecode += (ecode[1] << 8) + ecode[2];
}
while (*ecode == OP_ALT);
if (*ecode == OP_KET) FAIL;
/* Continue from after the assertion, updating the offsets high water
mark, since extracts may have been taken during the assertion. */
do ecode += (ecode[1] << 8) + ecode[2]; while (*ecode == OP_ALT);
ecode += 3;
offset_top = md->end_offset_top;
continue;
/* Negative assertion: all branches must fail to match */
case OP_ASSERT_NOT:
do
{
if (match(eptr, ecode+3, offset_top, md)) FAIL;
ecode += (ecode[1] << 8) + ecode[2];
}
while (*ecode == OP_ALT);
ecode += 3;
continue;
/* "Once" brackets are like assertion brackets except that after a match,
the point in the subject string is not moved back. Thus there can never be
a move back into the brackets. Check the alternative branches in turn - the
matching won't pass the KET for this kind of subpattern. If any one branch
matches, we carry on, leaving the subject pointer. */
case OP_ONCE:
do
{
if (match(eptr, ecode+3, offset_top, md)) break;
ecode += (ecode[1] << 8) + ecode[2];
}
while (*ecode == OP_ALT);
if (*ecode == OP_KET) FAIL;
/* Continue as from after the assertion, updating the offsets high water
mark, since extracts may have been taken. */
do ecode += (ecode[1] << 8) + ecode[2]; while (*ecode == OP_ALT);
ecode += 3;
offset_top = md->end_offset_top;
eptr = md->end_match_ptr;
continue;
/* An alternation is the end of a branch; scan along to find the end of the
bracketed group and go to there. */
case OP_ALT:
do ecode += (ecode[1] << 8) + ecode[2]; while (*ecode == OP_ALT);
break;
/* BRAZERO and BRAMINZERO occur just before a bracket group, indicating
that it may occur zero times. It may repeat infinitely, or not at all -
i.e. it could be ()* or ()? in the pattern. Brackets with fixed upper
repeat limits are compiled as a number of copies, with the optional ones
preceded by BRAZERO or BRAMINZERO. */
case OP_BRAZERO:
{
const uschar *next = ecode+1;
if (match(eptr, next, offset_top, md)) SUCCEED;
do next += (next[1] << 8) + next[2]; while (*next == OP_ALT);
ecode = next + 3;
}
break;
case OP_BRAMINZERO:
{
const uschar *next = ecode+1;
do next += (next[1] << 8) + next[2]; while (*next == OP_ALT);
if (match(eptr, next+3, offset_top, md)) SUCCEED;
ecode++;
}
break;;
/* End of a group, repeated or non-repeating. If we are at the end of
an assertion "group", stop matching and SUCCEED, but record the
current high water mark for use by positive assertions. */
case OP_KET:
case OP_KETRMIN:
case OP_KETRMAX:
{
int number;
const uschar *prev = ecode - (ecode[1] << 8) - ecode[2];
if (*prev == OP_ASSERT || *prev == OP_ASSERT_NOT || *prev == OP_ONCE)
{
md->end_match_ptr = eptr; /* For ONCE */
md->end_offset_top = offset_top;
SUCCEED;
}
/* In all other cases we have to check the group number back at the
start and if necessary complete handling an extraction by setting the
final offset and bumping the high water mark. */
number = (*prev - OP_BRA) << 1;
DPRINTF(("end bracket %d\n", number/2));
if (number > 0)
{
if (number >= md->offset_end) md->offset_overflow = TRUE; else
{
md->offset_vector[number+1] = eptr - md->start_subject;
if (offset_top <= number) offset_top = number + 2;
}
}
/* For a non-repeating ket, just advance to the next node and continue at
this level. */
if (*ecode == OP_KET)
{
ecode += 3;
break;
}
/* The repeating kets try the rest of the pattern or restart from the
preceding bracket, in the appropriate order. */
if (*ecode == OP_KETRMIN)
{
const uschar *ptr;
if (match(eptr, ecode+3, offset_top, md)) goto succeed;
/* Handle alternation inside the BRA...KET; push the additional
alternatives onto the stack */
ptr=prev;
do {
ptr += (ptr[1]<<8)+ ptr[2];
if (*ptr==OP_ALT)
{
if (md->length == md->point)
{
grow_stack(md);
}
md->offset_top[md->point] = offset_top;
md->eptr[md->point] = eptr;
md->ecode[md->point] = ptr+3;
md->r1[md->point] = 0;
md->r2[md->point] = 0;
md->off_num[md->point] = 0;
md->point++;
}
} while (*ptr==OP_ALT);
ecode=prev+3; goto match_loop;
}
else /* OP_KETRMAX */
{
const uschar *ptr;
/*int points_pushed=0;*/
/* Push one failure point, that will resume matching at the code after
the KETRMAX opcode. */
if (md->length == md->point)
{
grow_stack(md);
}
md->offset_top[md->point] = offset_top;
md->eptr[md->point] = eptr;
md->ecode[md->point] = ecode+3;
md->r1[md->point] = md->offset_vector[number];
md->r2[md->point] = md->offset_vector[number+1];
md->off_num[md->point] = number;
md->point++;
md->offset_vector[number] = eptr - md->start_subject;
/* Handle alternation inside the BRA...KET; push each of the
additional alternatives onto the stack */
ptr=prev;
do {
ptr += (ptr[1]<<8)+ ptr[2];
if (*ptr==OP_ALT)
{
if (md->length == md->point)
if (md->length == md->point)
{
grow_stack(md);
}
md->offset_top[md->point] = offset_top;
md->eptr[md->point] = eptr;
md->ecode[md->point] = ptr+3;
md->r1[md->point] = 0;
md->r2[md->point] = 0;
md->off_num[md->point] = 0;
md->point++;
/*points_pushed++;*/
}
} while (*ptr==OP_ALT);
/* Jump to the first (or only) alternative and resume trying to match */
ecode=prev+3; goto match_loop;
}
}
break;
/* Start of subject unless notbol, or after internal newline if multiline */
case OP_CIRC:
if (md->notbol && eptr == md->start_subject) FAIL;
if (md->multiline)
{
if (eptr != md->start_subject && eptr[-1] != '\n') FAIL;
ecode++;
break;
}
/* ... else fall through */
/* Start of subject assertion */
case OP_SOD:
if (eptr != md->start_subject) FAIL;
ecode++;
break;
/* Assert before internal newline if multiline, or before
a terminating newline unless endonly is set, else end of subject unless
noteol is set. */
case OP_DOLL:
if (md->noteol && eptr >= md->end_subject) FAIL;
if (md->multiline)
{
if (eptr < md->end_subject && *eptr != '\n') FAIL;
ecode++;
break;
}
else if (!md->endonly)
{
if (eptr < md->end_subject - 1 ||
(eptr == md->end_subject - 1 && *eptr != '\n')) FAIL;
ecode++;
break;
}
/* ... else fall through */
/* End of subject assertion */
case OP_EOD:
if (eptr < md->end_subject) FAIL;
ecode++;
break;
/* Word boundary assertions */
case OP_NOT_WORD_BOUNDARY:
case OP_WORD_BOUNDARY:
{
BOOL prev_is_word = (eptr != md->start_subject) &&
((pcre_ctypes[eptr[-1]] & ctype_word) != 0);
BOOL cur_is_word = (eptr < md->end_subject) &&
((pcre_ctypes[*eptr] & ctype_word) != 0);
if ((*ecode++ == OP_WORD_BOUNDARY)?
cur_is_word == prev_is_word : cur_is_word != prev_is_word)
FAIL;
}
break;
case OP_NOT_WORD_BOUNDARY_L:
case OP_WORD_BOUNDARY_L:
{
BOOL prev_is_word = (eptr != md->start_subject) &&
(isalnum(eptr[-1]) || eptr[-1]=='_');
BOOL cur_is_word = (eptr < md->end_subject) &&
(isalnum(*eptr) || *eptr=='_');
if ((*ecode++ == OP_WORD_BOUNDARY_L)?
cur_is_word == prev_is_word : cur_is_word != prev_is_word)
FAIL;
}
break;
/* Match a single character type; inline for speed */
case OP_ANY:
if (!md->dotall && eptr < md->end_subject && *eptr == '\n') FAIL;
if (eptr++ >= md->end_subject) FAIL;
ecode++;
break;
case OP_NOT_DIGIT:
if (eptr >= md->end_subject || (pcre_ctypes[*eptr++] & ctype_digit) != 0)
FAIL;
ecode++;
break;
case OP_DIGIT:
if (eptr >= md->end_subject || (pcre_ctypes[*eptr++] & ctype_digit) == 0)
FAIL;
ecode++;
break;
case OP_NOT_WHITESPACE:
if (eptr >= md->end_subject || (pcre_ctypes[*eptr++] & ctype_space) != 0)
FAIL;
ecode++;
break;
case OP_WHITESPACE:
if (eptr >= md->end_subject || (pcre_ctypes[*eptr++] & ctype_space) == 0)
FAIL;
ecode++;
break;
case OP_NOT_WORDCHAR:
if (eptr >= md->end_subject || (pcre_ctypes[*eptr++] & ctype_word) != 0)
FAIL;
ecode++;
break;
case OP_WORDCHAR:
if (eptr >= md->end_subject || (pcre_ctypes[*eptr++] & ctype_word) == 0)
FAIL;
ecode++;
break;
case OP_NOT_WORDCHAR_L:
if (eptr >= md->end_subject || (*eptr=='_' || isalnum(*eptr) ))
FAIL;
eptr++;
ecode++;
break;
case OP_WORDCHAR_L:
if (eptr >= md->end_subject || (*eptr!='_' && !isalnum(*eptr) ))
FAIL;
eptr++;
ecode++;
break;
/* Match a back reference, possibly repeatedly. Look past the end of the
item to see if there is repeat information following. The code is similar
to that for character classes, but repeated for efficiency. Then obey
similar code to character type repeats - written out again for speed.
However, if the referenced string is the empty string, always treat
it as matched, any number of times (otherwise there could be infinite
loops). */
case OP_REF:
{
int length;
int number = ecode[1] << 1; /* Doubled reference number */
ecode += 2; /* Advance past the item */
if (number >= offset_top || md->offset_vector[number] < 0)
{
md->errorcode = PCRE_ERROR_BADREF;
FAIL;
}
length = md->offset_vector[number+1] - md->offset_vector[number];
switch (*ecode)
{
case OP_CRSTAR:
case OP_CRMINSTAR:
case OP_CRPLUS:
case OP_CRMINPLUS:
case OP_CRQUERY:
case OP_CRMINQUERY:
c = *ecode++ - OP_CRSTAR;
minimize = (c & 1) != 0;
min = rep_min[c]; /* Pick up values from tables; */
max = rep_max[c]; /* zero for max => infinity */
if (max == 0) max = INT_MAX;
break;
case OP_CRRANGE:
case OP_CRMINRANGE:
minimize = (*ecode == OP_CRMINRANGE);
min = (ecode[1] << 8) + ecode[2];
max = (ecode[3] << 8) + ecode[4];
if (max == 0) max = INT_MAX;
ecode += 5;
break;
default: /* No repeat follows */
if (!match_ref(number, eptr, length, md)) FAIL;
eptr += length;
continue; /* With the main loop */
}
/* If the length of the reference is zero, just continue with the
main loop. */
if (length == 0) continue;
/* First, ensure the minimum number of matches are present. We get back
the length of the reference string explicitly rather than passing the
address of eptr, so that eptr can be a register variable. */
for (i = 1; i <= min; i++)
{
if (!match_ref(number, eptr, length, md)) FAIL;
eptr += length;
}
/* If min = max, continue at the same level without recursion.
They are not both allowed to be zero. */
if (min == max) continue;
/* If minimizing, keep trying and advancing the pointer */
if (minimize)
{
for (i = min;; i++)
{
if (match(eptr, ecode, offset_top, md)) SUCCEED;
if (i >= max || !match_ref(number, eptr, length, md))
FAIL;
eptr += length;
}
/* Control never gets here */
}
/* If maximizing, find the longest string and work backwards */
else
{
const uschar *pp = eptr;
for (i = min; i < max; i++)
{
if (!match_ref(number, eptr, length, md)) break;
eptr += length;
}
while (eptr >= pp)
{
if (match(eptr, ecode, offset_top, md)) SUCCEED;
eptr -= length;
}
FAIL;
}
}
/* Control never gets here */
/* Match a character class, possibly repeatedly. Look past the end of the
item to see if there is repeat information following. Then obey similar
code to character type repeats - written out again for speed. If caseless
matching was set at runtime but not at compile time, we have to check both
versions of a character, and we have to behave differently for positive and
negative classes. This is the only time where OP_CLASS and OP_NEGCLASS are
treated differently. */
case OP_CLASS:
case OP_NEGCLASS:
{
BOOL nasty_case = *ecode == OP_NEGCLASS && md->runtime_caseless;
const uschar *data = ecode + 1; /* Save for matching */
ecode += 33; /* Advance past the item */
switch (*ecode)
{
case OP_CRSTAR:
case OP_CRMINSTAR:
case OP_CRPLUS:
case OP_CRMINPLUS:
case OP_CRQUERY:
case OP_CRMINQUERY:
c = *ecode++ - OP_CRSTAR;
minimize = (c & 1) != 0;
min = rep_min[c]; /* Pick up values from tables; */
max = rep_max[c]; /* zero for max => infinity */
if (max == 0) max = INT_MAX;
break;
case OP_CRRANGE:
case OP_CRMINRANGE:
minimize = (*ecode == OP_CRMINRANGE);
min = (ecode[1] << 8) + ecode[2];
max = (ecode[3] << 8) + ecode[4];
if (max == 0) max = INT_MAX;
ecode += 5;
break;
default: /* No repeat follows */
min = max = 1;
break;
}
/* First, ensure the minimum number of matches are present. */
for (i = 1; i <= min; i++)
{
if (eptr >= md->end_subject) FAIL;
c = *eptr++;
/* Either not runtime caseless, or it was a positive class. For
runtime caseless, continue if either case is in the map. */
if (!nasty_case)
{
if ((data[c/8] & (1 << (c&7))) != 0) continue;
if (md->runtime_caseless)
{
c = pcre_fcc[c];
if ((data[c/8] & (1 << (c&7))) != 0) continue;
}
}
/* Runtime caseless and it was a negative class. Continue only if
both cases are in the map. */
else
{
if ((data[c/8] & (1 << (c&7))) == 0) FAIL;
c = pcre_fcc[c];
if ((data[c/8] & (1 << (c&7))) != 0) continue;
}
FAIL;
}
/* If max == min we can continue with the main loop without the
need to recurse. */
if (min == max) continue;
/* If minimizing, keep testing the rest of the expression and advancing
the pointer while it matches the class. */
if (minimize)
{
for (i = min;; i++)
{
if (match(eptr, ecode, offset_top, md)) SUCCEED;
if (i >= max || eptr >= md->end_subject) FAIL;
c = *eptr++;
/* Either not runtime caseless, or it was a positive class. For
runtime caseless, continue if either case is in the map. */
if (!nasty_case)
{
if ((data[c/8] & (1 << (c&7))) != 0) continue;
if (md->runtime_caseless)
{
c = pcre_fcc[c];
if ((data[c/8] & (1 << (c&7))) != 0) continue;
}
}
/* Runtime caseless and it was a negative class. Continue only if
both cases are in the map. */
else
{
if ((data[c/8] & (1 << (c&7))) == 0) return FALSE;
c = pcre_fcc[c];
if ((data[c/8] & (1 << (c&7))) != 0) continue;
}
FAIL;
}
/* Control never gets here */
}
/* If maximizing, find the longest possible run, then work backwards. */
else
{
const uschar *pp = eptr;
for (i = min; i < max; eptr++, i++)
{
if (eptr >= md->end_subject) break;
c = *eptr;
/* Either not runtime caseless, or it was a positive class. For
runtime caseless, continue if either case is in the map. */
if (!nasty_case)
{
if ((data[c/8] & (1 << (c&7))) != 0) continue;
if (md->runtime_caseless)
{
c = pcre_fcc[c];
if ((data[c/8] & (1 << (c&7))) != 0) continue;
}
}
/* Runtime caseless and it was a negative class. Continue only if
both cases are in the map. */
else
{
if ((data[c/8] & (1 << (c&7))) == 0) break;
c = pcre_fcc[c];
if ((data[c/8] & (1 << (c&7))) != 0) continue;
}
break;
}
while (eptr >= pp)
if (match(eptr--, ecode, offset_top, md)) SUCCEED;
FAIL;
}
}
/* Control never gets here */
/* OP_CLASS_L opcode: handles localized character classes */
case OP_CLASS_L:
{
const uschar *data = ecode + 1; /* Save for matching */
const uschar locale_flag = *data;
ecode++; data++; /* The localization support adds an extra byte */
ecode += 33; /* Advance past the item */
switch (*ecode)
{
case OP_CRSTAR:
case OP_CRMINSTAR:
case OP_CRPLUS:
case OP_CRMINPLUS:
case OP_CRQUERY:
case OP_CRMINQUERY:
c = *ecode++ - OP_CRSTAR;
minimize = (c & 1) != 0;
min = rep_min[c]; /* Pick up values from tables; */
max = rep_max[c]; /* zero for max => infinity */
if (max == 0) max = INT_MAX;
break;
case OP_CRRANGE:
case OP_CRMINRANGE:
minimize = (*ecode == OP_CRMINRANGE);
min = (ecode[1] << 8) + ecode[2];
max = (ecode[3] << 8) + ecode[4];
if (max == 0) max = INT_MAX;
ecode += 5;
break;
default: /* No repeat follows */
if (eptr >= md->end_subject) FAIL;
c = *eptr++;
if ((data[c/8] & (1 << (c&7))) != 0) continue; /* With main loop */
if ( (locale_flag & 1) && (isalnum(c) || c=='_') ) continue; /* Locale \w */
if ( (locale_flag & 2) && (!isalnum(c) && c!='_') ) continue; /* Locale \W */
#if 0
if ( (locale_flag & 4) && isdigit(c) ) continue; /* Locale \d */
if ( (locale_flag & 8) && !isdigit(c) ) continue; /* Locale \D */
if ( (locale_flag & 16) && isspace(c) ) continue; /* Locale \s */
if ( (locale_flag & 32) && !isspace(c) ) continue; /* Locale \S */
#endif
if (md->runtime_caseless)
{
c = pcre_fcc[c];
if ((data[c/8] & (1 << (c&7))) != 0) continue; /* With main loop */
if ( (locale_flag & 1) && (isalnum(c) || c=='_') ) continue; /* Locale \w */
if ( (locale_flag & 2) && (!isalnum(c) && c!='_') ) continue; /* Locale \W */
}
FAIL;
}
/* First, ensure the minimum number of matches are present. */
for (i = 1; i <= min; i++)
{
if (eptr >= md->end_subject) FAIL;
c = *eptr++;
if ((data[c/8] & (1 << (c&7))) != 0) continue;
if ( (locale_flag & 1) && (isalnum(c) || c=='_') ) continue; /* Locale \w */
if ( (locale_flag & 2) && (!isalnum(c) && c!='_') ) continue; /* Locale \W */
if (md->runtime_caseless)
{
c = pcre_fcc[c];
if ((data[c/8] & (1 << (c&7))) != 0) continue;
if ( (locale_flag & 1) && (isalnum(c) || c=='_') ) continue; /* Locale \w */
if ( (locale_flag & 2) && (!isalnum(c) && c!='_') ) continue; /* Locale \W */
}
FAIL;
}
/* If max == min we can continue with the main loop without the
need to recurse. */
if (min == max) continue;
/* If minimizing, keep testing the rest of the expression and advancing
the pointer while it matches the class. */
if (minimize)
{
for (i = min;; i++)
{
if (match(eptr, ecode, offset_top, md)) SUCCEED;
if (i >= max || eptr >= md->end_subject) FAIL;
c = *eptr++;
if ((data[c/8] & (1 << (c&7))) != 0) continue;
if ( (locale_flag & 1) && (isalnum(c) || c=='_') ) continue; /* Locale \w */
if ( (locale_flag & 2) && (!isalnum(c) && c!='_') ) continue; /* Locale \W */
if (md->runtime_caseless)
{
c = pcre_fcc[c];
if ((data[c/8] & (1 << (c&7))) != 0) continue;
if ( (locale_flag & 1) && (isalnum(c) || c=='_') ) continue; /* Locale \w */
if ( (locale_flag & 2) && (!isalnum(c) && c!='_') ) continue; /* Locale \W */
}
FAIL;
}
/* Control never gets here */
}
/* If maximizing, find the longest possible run, then work backwards. */
else
{
const uschar *pp = eptr;
for (i = min; i < max; eptr++, i++)
{
if (eptr >= md->end_subject) break;
c = *eptr;
if ((data[c/8] & (1 << (c&7))) != 0) continue;
if ( (locale_flag & 1) && (isalnum(c) || c=='_') ) continue; /* Locale \w */
if ( (locale_flag & 2) && (!isalnum(c) && c!='_') ) continue; /* Locale \W */
if (md->runtime_caseless)
{
c = pcre_fcc[c];
if ((data[c/8] & (1 << (c&7))) != 0) continue;
if ( (locale_flag & 1) && (isalnum(c) || c=='_') ) continue; /* Locale \w */
if ( (locale_flag & 2) && (!isalnum(c) && c!='_') ) continue; /* Locale \W */
}
break;
}
while (eptr >= pp)
if (match(eptr--, ecode, offset_top, md)) SUCCEED;
FAIL;
}
}
/* Control never gets here */
/* Match a run of characters */
case OP_CHARS:
{
register int length = ecode[1];
ecode += 2;
#ifdef DEBUG /* Sigh. Some compilers never learn. */
if (eptr >= md->end_subject)
printf("matching subject <null> against pattern ");
else
{
printf("matching subject ");
pchars(eptr, length, TRUE, md);
printf(" against pattern ");
}
pchars(ecode, length, FALSE, md);
printf("\n");
#endif
if (length > md->end_subject - eptr) FAIL;
if (md->caseless)
{
while (length-- > 0) if (pcre_lcc[*ecode++] != pcre_lcc[*eptr++]) FAIL;
}
else
{
while (length-- > 0) if (*ecode++ != *eptr++) FAIL;
}
}
break;
/* Match a single character repeatedly; different opcodes share code. */
case OP_EXACT:
min = max = (ecode[1] << 8) + ecode[2];
ecode += 3;
goto REPEATCHAR;
case OP_UPTO:
case OP_MINUPTO:
min = 0;
max = (ecode[1] << 8) + ecode[2];
minimize = *ecode == OP_MINUPTO;
ecode += 3;
goto REPEATCHAR;
case OP_STAR:
case OP_MINSTAR:
case OP_PLUS:
case OP_MINPLUS:
case OP_QUERY:
case OP_MINQUERY:
c = *ecode++ - OP_STAR;
minimize = (c & 1) != 0;
min = rep_min[c]; /* Pick up values from tables; */
max = rep_max[c]; /* zero for max => infinity */
if (max == 0) max = INT_MAX;
/* Common code for all repeated single-character matches. We can give
up quickly if there are fewer than the minimum number of characters left in
the subject. */
REPEATCHAR:
if (min > md->end_subject - eptr) FAIL;
c = *ecode++;
/* The code is duplicated for the caseless and caseful cases, for speed,
since matching characters is likely to be quite common. First, ensure the
minimum number of matches are present. If min = max, continue at the same
level without recursing. Otherwise, if minimizing, keep trying the rest of
the expression and advancing one matching character if failing, up to the
maximum. Alternatively, if maximizing, find the maximum number of
characters and work backwards. */
DPRINTF(("matching %c{%d,%d} against subject %.*s\n", c, min, max,
max, eptr));
if (md->caseless)
{
c = pcre_lcc[c];
for (i = 1; i <= min; i++) if (c != pcre_lcc[*eptr++]) FAIL;
if (min == max) continue;
if (minimize)
{
for (i = min;; i++)
{
if (match(eptr, ecode, offset_top, md)) SUCCEED;
if (i >= max || eptr >= md->end_subject || c != pcre_lcc[*eptr++])
FAIL;
}
/* Control never gets here */
}
else
{
const uschar *pp = eptr;
for (i = min; i < max; i++)
{
if (eptr >= md->end_subject || c != pcre_lcc[*eptr]) break;
eptr++;
}
while (eptr >= pp)
if (match(eptr--, ecode, offset_top, md)) SUCCEED;
FAIL;
}
/* Control never gets here */
}
/* Caseful comparisons */
else
{
for (i = 1; i <= min; i++) if (c != *eptr++) FAIL;
if (min == max) continue;
if (minimize)
{
for (i = min;; i++)
{
if (match(eptr, ecode, offset_top, md)) SUCCEED;
if (i >= max || eptr >= md->end_subject || c != *eptr++) FAIL;
}
/* Control never gets here */
}
else
{
const uschar *pp = eptr;
for (i = min; i < max; i++)
{
if (eptr >= md->end_subject || c != *eptr) break;
eptr++;
}
while (eptr >= pp)
if (match(eptr--, ecode, offset_top, md)) SUCCEED;
FAIL;
}
}
/* Control never gets here */
/* Match a negated single character */
case OP_NOT:
if (eptr >= md->end_subject) FAIL;
ecode++;
if (md->caseless)
{
if (pcre_lcc[*ecode++] == pcre_lcc[*eptr++]) FAIL;
}
else
{
if (*ecode++ == *eptr++) FAIL;
}
break;
/* Match a negated single character repeatedly. This is almost a repeat of
the code for a repeated single character, but I haven't found a nice way of
commoning these up that doesn't require a test of the positive/negative
option for each character match. Maybe that wouldn't add very much to the
time taken, but character matching *is* what this is all about... */
case OP_NOTEXACT:
min = max = (ecode[1] << 8) + ecode[2];
ecode += 3;
goto REPEATNOTCHAR;
case OP_NOTUPTO:
case OP_NOTMINUPTO:
min = 0;
max = (ecode[1] << 8) + ecode[2];
minimize = *ecode == OP_NOTMINUPTO;
ecode += 3;
goto REPEATNOTCHAR;
case OP_NOTSTAR:
case OP_NOTMINSTAR:
case OP_NOTPLUS:
case OP_NOTMINPLUS:
case OP_NOTQUERY:
case OP_NOTMINQUERY:
c = *ecode++ - OP_NOTSTAR;
minimize = (c & 1) != 0;
min = rep_min[c]; /* Pick up values from tables; */
max = rep_max[c]; /* zero for max => infinity */
if (max == 0) max = INT_MAX;
/* Common code for all repeated single-character matches. We can give
up quickly if there are fewer than the minimum number of characters left in
the subject. */
REPEATNOTCHAR:
if (min > md->end_subject - eptr) FAIL;
c = *ecode++;
/* The code is duplicated for the caseless and caseful cases, for speed,
since matching characters is likely to be quite common. First, ensure the
minimum number of matches are present. If min = max, continue at the same
level without recursing. Otherwise, if minimizing, keep trying the rest of
the expression and advancing one matching character if failing, up to the
maximum. Alternatively, if maximizing, find the maximum number of
characters and work backwards. */
DPRINTF(("negative matching %c{%d,%d} against subject %.*s\n", c, min, max,
max, eptr));
if (md->caseless)
{
c = pcre_lcc[c];
for (i = 1; i <= min; i++) if (c == pcre_lcc[*eptr++]) FAIL;
if (min == max) continue;
if (minimize)
{
for (i = min;; i++)
{
if (match(eptr, ecode, offset_top, md)) SUCCEED;
if (i >= max || eptr >= md->end_subject || c == pcre_lcc[*eptr++])
FAIL;
}
/* Control never gets here */
}
else
{
const uschar *pp = eptr;
for (i = min; i < max; i++)
{
if (eptr >= md->end_subject || c == pcre_lcc[*eptr]) break;
eptr++;
}
while (eptr >= pp)
if (match(eptr--, ecode, offset_top, md)) SUCCEED;
FAIL;
}
/* Control never gets here */
}
/* Caseful comparisons */
else
{
for (i = 1; i <= min; i++) if (c == *eptr++) FAIL;
if (min == max) continue;
if (minimize)
{
for (i = min;; i++)
{
if (match(eptr, ecode, offset_top, md)) SUCCEED;
if (i >= max || eptr >= md->end_subject || c == *eptr++) FAIL;
}
/* Control never gets here */
}
else
{
const uschar *pp = eptr;
for (i = min; i < max; i++)
{
if (eptr >= md->end_subject || c == *eptr) break;
eptr++;
}
while (eptr >= pp)
if (match(eptr--, ecode, offset_top, md)) SUCCEED;
FAIL;
}
}
/* Control never gets here */
/* Match a single character type repeatedly; several different opcodes
share code. This is very similar to the code for single characters, but we
repeat it in the interests of efficiency. */
case OP_TYPEEXACT:
min = max = (ecode[1] << 8) + ecode[2];
minimize = TRUE;
ecode += 3;
goto REPEATTYPE;
case OP_TYPEUPTO:
case OP_TYPEMINUPTO:
min = 0;
max = (ecode[1] << 8) + ecode[2];
minimize = *ecode == OP_TYPEMINUPTO;
ecode += 3;
goto REPEATTYPE;
case OP_TYPESTAR:
case OP_TYPEMINSTAR:
case OP_TYPEPLUS:
case OP_TYPEMINPLUS:
case OP_TYPEQUERY:
case OP_TYPEMINQUERY:
c = *ecode++ - OP_TYPESTAR;
minimize = (c & 1) != 0;
min = rep_min[c]; /* Pick up values from tables; */
max = rep_max[c]; /* zero for max => infinity */
if (max == 0) max = INT_MAX;
/* Common code for all repeated single character type matches */
REPEATTYPE:
ctype = *ecode++; /* Code for the character type */
/* First, ensure the minimum number of matches are present. Use inline
code for maximizing the speed, and do the type test once at the start
(i.e. keep it out of the loop). Also test that there are at least the
minimum number of characters before we start. */
if (min > md->end_subject - eptr) FAIL;
if (min > 0) switch(ctype)
{
case OP_ANY:
if (!md->dotall)
{ for (i = 1; i <= min; i++) if (*eptr++ == '\n') FAIL; }
else eptr += min;
break;
case OP_NOT_DIGIT:
for (i = 1; i <= min; i++)
if ((pcre_ctypes[*eptr++] & ctype_digit) != 0) FAIL;
break;
case OP_DIGIT:
for (i = 1; i <= min; i++)
if ((pcre_ctypes[*eptr++] & ctype_digit) == 0) FAIL;
break;
case OP_NOT_WHITESPACE:
for (i = 1; i <= min; i++)
if ((pcre_ctypes[*eptr++] & ctype_space) != 0) FAIL;
break;
case OP_WHITESPACE:
for (i = 1; i <= min; i++)
if ((pcre_ctypes[*eptr++] & ctype_space) == 0) FAIL;
break;
case OP_NOT_WORDCHAR:
for (i = 1; i <= min; i++) if ((pcre_ctypes[*eptr++] & ctype_word) != 0)
FAIL;
break;
case OP_WORDCHAR:
for (i = 1; i <= min; i++) if ((pcre_ctypes[*eptr++] & ctype_word) == 0)
FAIL;
break;
case OP_NOT_WORDCHAR_L:
for (i = 1; i <= min; i++, eptr++) if (*eptr=='_' || isalnum(*eptr))
FAIL;
break;
case OP_WORDCHAR_L:
for (i = 1; i <= min; i++, eptr++) if (*eptr!='_' && !isalnum(*eptr))
FAIL;
break;
}
/* If min = max, continue at the same level without recursing */
if (min == max) continue;
/* If minimizing, we have to test the rest of the pattern before each
subsequent match, so inlining isn't much help; just use the function. */
if (minimize)
{
for (i = min;; i++)
{
if (match(eptr, ecode, offset_top, md)) SUCCEED;
if (i >= max || eptr >= md->end_subject ||
!match_type(ctype, *eptr++, md->dotall))
FAIL;
}
/* Control never gets here */
}
/* If maximizing it is worth using inline code for speed, doing the type
test once at the start (i.e. keep it out of the loop). */
else
{
const uschar *pp = eptr;
switch(ctype)
{
case OP_ANY:
if (!md->dotall)
{
for (i = min; i < max; i++)
{
if (eptr >= md->end_subject || *eptr == '\n') break;
eptr++;
}
}
else
{
c = max - min;
if (c > md->end_subject - eptr) c = md->end_subject - eptr;
eptr += c;
}
break;
case OP_NOT_DIGIT:
for (i = min; i < max; i++)
{
if (eptr >= md->end_subject || (pcre_ctypes[*eptr] & ctype_digit) != 0)
break;
eptr++;
}
break;
case OP_DIGIT:
for (i = min; i < max; i++)
{
if (eptr >= md->end_subject || (pcre_ctypes[*eptr] & ctype_digit) == 0)
break;
eptr++;
}
break;
case OP_NOT_WHITESPACE:
for (i = min; i < max; i++)
{
if (eptr >= md->end_subject || (pcre_ctypes[*eptr] & ctype_space) != 0)
break;
eptr++;
}
break;
case OP_WHITESPACE:
for (i = min; i < max; i++)
{
if (eptr >= md->end_subject || (pcre_ctypes[*eptr] & ctype_space) == 0)
break;
eptr++;
}
break;
case OP_NOT_WORDCHAR:
for (i = min; i < max; i++)
{
if (eptr >= md->end_subject || (pcre_ctypes[*eptr] & ctype_word) != 0)
break;
eptr++;
}
break;
case OP_WORDCHAR:
for (i = min; i < max; i++)
{
if (eptr >= md->end_subject || (pcre_ctypes[*eptr] & ctype_word) == 0)
break;
eptr++;
}
break;
case OP_NOT_WORDCHAR_L:
for (i = min; i < max; i++)
{
if (eptr >= md->end_subject || (*eptr=='_' || isalnum(*eptr) ) )
break;
eptr++;
}
break;
case OP_WORDCHAR_L:
for (i = min; i < max; i++)
{
if (eptr >= md->end_subject || (*eptr!='_' && !isalnum(*eptr) ) )
break;
eptr++;
}
break;
}
while (eptr >= pp)
if (match(eptr--, ecode, offset_top, md)) SUCCEED;
FAIL;
}
/* Control never gets here */
/* There's been some horrible disaster. */
default:
DPRINTF(("Unknown opcode %d\n", *ecode));
md->errorcode = PCRE_ERROR_UNKNOWN_NODE;
FAIL;
}
/* Do not stick any code in here without much thought; it is assumed
that "continue" in the code above comes out to here to repeat the main
loop. */
} /* End of main loop */
/* Control never reaches here */
fail:
if (md->point > save_stack_position)
{
/* If there are still points remaining on the stack, pop the next one off */
int off_num;
md->point--;
offset_top = md->offset_top[md->point];
eptr = md->eptr[md->point];
ecode = md->ecode[md->point];
off_num = md->off_num[md->point];
md->offset_vector[off_num] = md->r1[md->point];
md->offset_vector[off_num+1] = md->r2[md->point];
goto match_loop;
}
/* Failure, and nothing left on the stack, so end this function call */
/* Restore the top of the stack to where it was before this function
call. This lets us use one stack for everything; recursive calls
can push and pop information, and may increase the stack. When
the call returns, the parent function can resume pushing and
popping wherever it was. */
md->point = save_stack_position;
return FALSE;
succeed:
return TRUE;
}
/*************************************************
* Segregate setjmp() *
*************************************************/
/* The -Wall option of gcc gives warnings for all local variables when setjmp()
is used, even if the coding conforms to the rules of ANSI C. To avoid this, we
hide it in a separate function. This is called only when PCRE_EXTRA is set,
since it's needed only for the extension \X option, and with any luck, a good
compiler will spot the tail recursion and compile it efficiently.
Arguments:
eptr pointer in subject
ecode position in code
offset_top current top pointer
md pointer to "static" info for the match
Returns: TRUE if matched
*/
static BOOL
match_with_setjmp(const uschar *eptr, const uschar *ecode, int offset_top,
match_data *match_block)
{
return setjmp(match_block->fail_env) == 0 &&
match(eptr, ecode, offset_top, match_block);
}
/*************************************************
* Execute a Regular Expression *
*************************************************/
/* This function applies a compiled re to a subject string and picks out
portions of the string if it matches. Two elements in the vector are set for
each substring: the offsets to the start and end of the substring.
Arguments:
external_re points to the compiled expression
external_extra points to "hints" from pcre_study() or is NULL
subject points to the subject string
length length of subject string (may contain binary zeros)
options option bits
offsets points to a vector of ints to be filled in with offsets
offsetcount the number of elements in the vector
Returns: > 0 => success; value is the number of elements filled in
= 0 => success, but offsets is not big enough
-1 => failed to match
< -1 => some kind of unexpected problem
*/
int
pcre_exec(const pcre *external_re, const pcre_extra *external_extra,
const char *subject, int length, int start_pos, int options,
int *offsets, int offsetcount)
{
/* The "volatile" directives are to make gcc -Wall stop complaining
that these variables can be clobbered by the longjmp. Hopefully
they won't cost too much performance. */
volatile int resetcount, ocount;
volatile int first_char = -1;
match_data match_block;
const uschar *start_bits = NULL;
const uschar *start_match = (const uschar *)subject + start_pos;
const uschar *end_subject;
const real_pcre *re = (const real_pcre *)external_re;
const real_pcre_extra *extra = (const real_pcre_extra *)external_extra;
volatile BOOL using_temporary_offsets = FALSE;
volatile BOOL anchored = ((re->options | options) & PCRE_ANCHORED) != 0;
volatile BOOL startline = (re->options & PCRE_STARTLINE) != 0;
if ((options & ~PUBLIC_EXEC_OPTIONS) != 0) return PCRE_ERROR_BADOPTION;
if (re == NULL || subject == NULL ||
(offsets == NULL && offsetcount > 0)) return PCRE_ERROR_NULL;
if (re->magic_number != MAGIC_NUMBER) return PCRE_ERROR_BADMAGIC;
match_block.start_subject = (const uschar *)subject;
match_block.end_subject = match_block.start_subject + length;
end_subject = match_block.end_subject;
match_block.caseless = ((re->options | options) & PCRE_CASELESS) != 0;
match_block.runtime_caseless = match_block.caseless &&
(re->options & PCRE_CASELESS) == 0;
match_block.multiline = ((re->options | options) & PCRE_MULTILINE) != 0;
match_block.dotall = ((re->options | options) & PCRE_DOTALL) != 0;
match_block.endonly = ((re->options | options) & PCRE_DOLLAR_ENDONLY) != 0;
match_block.notbol = (options & PCRE_NOTBOL) != 0;
match_block.noteol = (options & PCRE_NOTEOL) != 0;
match_block.errorcode = PCRE_ERROR_NOMATCH; /* Default error */
/* Set the stack state to empty */
match_block.off_num = match_block.offset_top = NULL;
match_block.r1 = match_block.r2 = NULL;
match_block.eptr = match_block.ecode = NULL;
match_block.point = match_block.length = 0;
/* If the expression has got more back references than the offsets supplied can
hold, we get a temporary bit of working store to use during the matching.
Otherwise, we can use the vector supplied, rounding down its size to a multiple
of 2. */
ocount = offsetcount & (-2);
if (re->top_backref > 0 && re->top_backref >= ocount/2)
{
ocount = re->top_backref * 2 + 2;
match_block.offset_vector = (int *)(pcre_malloc)(ocount * sizeof(int));
if (match_block.offset_vector == NULL) return PCRE_ERROR_NOMEMORY;
using_temporary_offsets = TRUE;
DPRINTF(("Got memory to hold back references\n"));
}
else match_block.offset_vector = offsets;
match_block.offset_end = ocount;
match_block.offset_overflow = FALSE;
/* Compute the minimum number of offsets that we need to reset each time. Doing
this makes a huge difference to execution time when there aren't many brackets
in the pattern. */
resetcount = 2 + re->top_bracket * 2;
if (resetcount > offsetcount) resetcount = ocount;
/* If MULTILINE is set at exec time but was not set at compile time, and the
anchored flag is set, we must re-check because a setting provoked by ^ in the
pattern is not right in multi-line mode. Calling is_anchored() again here does
the right check, because multiline is now set. If it now yields FALSE, the
expression must have had ^ starting some of its branches. Check to see if
that is true for *all* branches, and if so, set the startline flag. */
if (match_block.multiline && anchored && (re->options & PCRE_MULTILINE) == 0 &&
!is_anchored(re->code, match_block.multiline))
{
anchored = FALSE;
if (is_startline(re->code)) startline = TRUE;
}
/* Set up the first character to match, if available. The first_char value is
never set for an anchored regular expression, but the anchoring may be forced
at run time, so we have to test for anchoring. The first char may be unset for
an unanchored pattern, of course. If there's no first char and the pattern was
studied, the may be a bitmap of possible first characters. However, we can
use this only if the caseless state of the studying was correct. */
if (!anchored)
{
if ((re->options & PCRE_FIRSTSET) != 0)
{
first_char = re->first_char;
if (match_block.caseless) first_char = pcre_lcc[first_char];
}
else
if (!startline && extra != NULL &&
(extra->options & PCRE_STUDY_MAPPED) != 0 &&
((extra->options & PCRE_STUDY_CASELESS) != 0) == match_block.caseless)
start_bits = extra->start_bits;
}
/* Loop for unanchored matches; for anchored regexps the loop runs just once. */
do
{
int rc;
register int *iptr = match_block.offset_vector;
register int *iend = iptr + resetcount;
/* Reset the maximum number of extractions we might see. */
while (iptr < iend) *iptr++ = -1;
/* Advance to a unique first char if possible */
if (first_char >= 0)
{
if (match_block.caseless)
while (start_match < end_subject && pcre_lcc[*start_match] != first_char)
start_match++;
else
while (start_match < end_subject && *start_match != first_char)
start_match++;
}
/* Or to just after \n for a multiline match if possible */
else if (startline)
{
if (start_match > match_block.start_subject)
{
while (start_match < end_subject && start_match[-1] != '\n')
start_match++;
}
}
/* Or to a non-unique first char */
else if (start_bits != NULL)
{
while (start_match < end_subject)
{
register int c = *start_match;
if ((start_bits[c/8] & (1 << (c&7))) == 0) start_match++; else break;
}
}
#ifdef DEBUG /* Sigh. Some compilers never learn. */
printf(">>>> Match against: ");
pchars(start_match, end_subject - start_match, TRUE, &match_block);
printf("\n");
#endif
/* When a match occurs, substrings will be set for all internal extractions;
we just need to set up the whole thing as substring 0 before returning. If
there were too many extractions, set the return code to zero. In the case
where we had to get some local store to hold offsets for backreferences, copy
those back references that we can. In this case there need not be overflow
if certain parts of the pattern were not used.
Before starting the match, we have to set up a longjmp() target to enable
the "cut" operation to fail a match completely without backtracking. This
is done in a separate function to avoid compiler warnings. We need not do
it unless PCRE_EXTRA is set, since only in that case is the "cut" operation
enabled. */
/* To handle errors such as running out of memory for the failure
stack, we need to save this location via setjmp(), so
error-handling code can call longjmp() to jump out of deeply-nested code. */
if (setjmp(match_block.error_env)==0)
{
if ((re->options & PCRE_EXTRA) != 0)
{
if (!match_with_setjmp(start_match, re->code, 2, &match_block))
continue;
}
else if (!match(start_match, re->code, 2, &match_block)) continue;
/* Copy the offset information from temporary store if necessary */
if (using_temporary_offsets)
{
if (offsetcount >= 4)
{
memcpy(offsets + 2, match_block.offset_vector + 2,
(offsetcount - 2) * sizeof(int));
DPRINTF(("Copied offsets from temporary memory\n"));
}
if (match_block.end_offset_top > offsetcount)
match_block.offset_overflow = TRUE;
DPRINTF(("Freeing temporary memory\n"));
(pcre_free)(match_block.offset_vector);
}
rc = match_block.offset_overflow? 0 : match_block.end_offset_top/2;
if (match_block.offset_end < 2) rc = 0; else
{
offsets[0] = start_match - match_block.start_subject;
offsets[1] = match_block.end_match_ptr - match_block.start_subject;
}
DPRINTF((">>>> returning %d\n", rc));
free_stack(&match_block);
return rc;
} /* End of (if setjmp(match_block.error_env)...) */
free_stack(&match_block);
/* Return an error code; pcremodule.c will preserve the exception */
if (PyErr_Occurred()) return PCRE_ERROR_NOMEMORY;
}
while (!anchored &&
match_block.errorcode == PCRE_ERROR_NOMATCH &&
start_match++ < end_subject);
if (using_temporary_offsets)
{
DPRINTF(("Freeing temporary memory\n"));
(pcre_free)(match_block.offset_vector);
}
#ifdef DEBUG
printf(">>>> returning %d\n", match_block.errorcode);
#endif
return match_block.errorcode;
}
/* End of pcre.c */
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