root/regcomp.c
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*/
DEFINITIONS
This source file includes following definitions.
- onig_get_default_case_fold_flag
- onig_set_default_case_fold_flag
- str_dup
- swap_node
- distance_add
- distance_multiply
- bitset_is_empty
- bitset_on_num
- onig_bbuf_init
- unset_addr_list_init
- unset_addr_list_end
- unset_addr_list_add
- add_opcode
- add_state_check_num
- add_rel_addr
- add_abs_addr
- add_length
- add_mem_num
- add_pointer
- add_option
- add_opcode_rel_addr
- add_bytes
- add_bitset
- add_opcode_option
- select_str_opcode
- compile_tree_empty_check
- compile_call
- compile_tree_n_times
- add_compile_string_length
- add_compile_string
- compile_length_string_node
- compile_length_string_raw_node
- compile_string_node
- compile_string_raw_node
- add_multi_byte_cclass
- compile_length_cclass_node
- compile_cclass_node
- entry_repeat_range
- compile_range_repeat_node
- is_anychar_star_quantifier
- compile_length_quantifier_node
- compile_quantifier_node
- compile_length_quantifier_node
- compile_quantifier_node
- compile_length_option_node
- compile_option_node
- compile_length_enclose_node
- compile_enclose_node
- compile_length_anchor_node
- compile_anchor_node
- compile_length_tree
- compile_tree
- noname_disable_map
- renumber_node_backref
- renumber_by_map
- numbered_ref_check
- disable_noname_group_capture
- unset_addr_list_fix
- quantifiers_memory_node_info
- get_min_match_length
- get_max_match_length
- get_char_length_tree1
- get_char_length_tree
- is_not_included
- get_head_value_node
- check_type_tree
- subexp_inf_recursive_check
- subexp_inf_recursive_check_trav
- subexp_recursive_check
- subexp_recursive_check_trav
- setup_subexp_call
- divide_look_behind_alternatives
- setup_look_behind
- next_setup
- update_string_node_case_fold
- expand_case_fold_make_rem_string
- expand_case_fold_string_alt
- expand_case_fold_string
- setup_comb_exp_check
- setup_tree
- set_bm_skip
- MinMaxLen
- OptEnv
- OptAncInfo
- OptExactInfo
- OptMapInfo
- NodeOptInfo
- map_position_value
- distance_value
- comp_distance_value
- is_equal_mml
- set_mml
- clear_mml
- copy_mml
- add_mml
- add_len_mml
- alt_merge_mml
- copy_opt_env
- clear_opt_anc_info
- copy_opt_anc_info
- concat_opt_anc_info
- is_left_anchor
- is_set_opt_anc_info
- add_opt_anc_info
- remove_opt_anc_info
- alt_merge_opt_anc_info
- is_full_opt_exact_info
- clear_opt_exact_info
- copy_opt_exact_info
- concat_opt_exact_info
- concat_opt_exact_info_str
- alt_merge_opt_exact_info
- select_opt_exact_info
- clear_opt_map_info
- copy_opt_map_info
- add_char_opt_map_info
- add_char_amb_opt_map_info
- select_opt_map_info
- comp_opt_exact_or_map_info
- alt_merge_opt_map_info
- set_bound_node_opt_info
- clear_node_opt_info
- copy_node_opt_info
- concat_left_node_opt_info
- alt_merge_node_opt_info
- optimize_node_left
- set_optimize_exact_info
- set_optimize_map_info
- set_sub_anchor
- set_optimize_info_from_tree
- clear_optimize_info
- print_enc_string
- print_distance_range
- print_anchor
- print_optimize_info
- onig_free_body
- onig_free
- onig_transfer
- onig_chain_link_add
- onig_chain_reduce
- onig_clone
- onig_compile
- onig_recompile
- onig_alloc_init
- onig_new
- onig_init
- onig_end
- onig_is_in_code_range
- onig_is_code_in_cc_len
- onig_is_code_in_cc
- op2name
- op2arg_type
- Indent
- p_string
- p_len_string
- onig_print_compiled_byte_code
- print_compiled_byte_code_list
- print_indent_tree
- print_tree
/**********************************************************************
regcomp.c - Oniguruma (regular expression library)
**********************************************************************/
/*-
* Copyright (c) 2002-2007 K.Kosako <sndgk393 AT ybb DOT ne DOT jp>
* All rights reserved.
*
* Redistribution and use in source and binary forms, with or without
* modification, are permitted provided that the following conditions
* are met:
* 1. Redistributions of source code must retain the above copyright
* notice, this list of conditions and the following disclaimer.
* 2. Redistributions in binary form must reproduce the above copyright
* notice, this list of conditions and the following disclaimer in the
* documentation and/or other materials provided with the distribution.
*
* THIS SOFTWARE IS PROVIDED BY THE AUTHOR AND CONTRIBUTORS ``AS IS'' AND
* ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE
* IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE
* ARE DISCLAIMED. IN NO EVENT SHALL THE AUTHOR OR CONTRIBUTORS BE LIABLE
* FOR ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR CONSEQUENTIAL
* DAMAGES (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS
* OR SERVICES; LOSS OF USE, DATA, OR PROFITS; OR BUSINESS INTERRUPTION)
* HOWEVER CAUSED AND ON ANY THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT
* LIABILITY, OR TORT (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY
* OUT OF THE USE OF THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF
* SUCH DAMAGE.
*/
#include "regparse.h"
OnigCaseFoldType OnigDefaultCaseFoldFlag = ONIGENC_CASE_FOLD_MIN;
extern OnigCaseFoldType
onig_get_default_case_fold_flag(void)
{
return OnigDefaultCaseFoldFlag;
}
extern int
onig_set_default_case_fold_flag(OnigCaseFoldType case_fold_flag)
{
OnigDefaultCaseFoldFlag = case_fold_flag;
return 0;
}
#ifndef PLATFORM_UNALIGNED_WORD_ACCESS
static unsigned char PadBuf[WORD_ALIGNMENT_SIZE];
#endif
static UChar*
str_dup(UChar* s, UChar* end)
{
int len = end - s;
if (len > 0) {
UChar* r = (UChar* )xmalloc(len + 1);
CHECK_NULL_RETURN(r);
xmemcpy(r, s, len);
r[len] = (UChar )0;
return r;
}
else return NULL;
}
static void
swap_node(Node* a, Node* b)
{
Node c;
c = *a; *a = *b; *b = c;
if (NTYPE(a) == NT_STR) {
StrNode* sn = NSTR(a);
if (sn->capa == 0) {
int len = sn->end - sn->s;
sn->s = sn->buf;
sn->end = sn->s + len;
}
}
if (NTYPE(b) == NT_STR) {
StrNode* sn = NSTR(b);
if (sn->capa == 0) {
int len = sn->end - sn->s;
sn->s = sn->buf;
sn->end = sn->s + len;
}
}
}
static OnigDistance
distance_add(OnigDistance d1, OnigDistance d2)
{
if (d1 == ONIG_INFINITE_DISTANCE || d2 == ONIG_INFINITE_DISTANCE)
return ONIG_INFINITE_DISTANCE;
else {
if (d1 <= ONIG_INFINITE_DISTANCE - d2) return d1 + d2;
else return ONIG_INFINITE_DISTANCE;
}
}
static OnigDistance
distance_multiply(OnigDistance d, int m)
{
if (m == 0) return 0;
if (d < ONIG_INFINITE_DISTANCE / m)
return d * m;
else
return ONIG_INFINITE_DISTANCE;
}
static int
bitset_is_empty(BitSetRef bs)
{
int i;
for (i = 0; i < (int )BITSET_SIZE; i++) {
if (bs[i] != 0) return 0;
}
return 1;
}
#ifdef ONIG_DEBUG
static int
bitset_on_num(BitSetRef bs)
{
int i, n;
n = 0;
for (i = 0; i < SINGLE_BYTE_SIZE; i++) {
if (BITSET_AT(bs, i)) n++;
}
return n;
}
#endif
extern int
onig_bbuf_init(BBuf* buf, int size)
{
if (size <= 0) {
size = 0;
buf->p = NULL;
}
else {
buf->p = (UChar* )xmalloc(size);
if (IS_NULL(buf->p)) return(ONIGERR_MEMORY);
}
buf->alloc = size;
buf->used = 0;
return 0;
}
#ifdef USE_SUBEXP_CALL
static int
unset_addr_list_init(UnsetAddrList* uslist, int size)
{
UnsetAddr* p;
p = (UnsetAddr* )xmalloc(sizeof(UnsetAddr)* size);
CHECK_NULL_RETURN_MEMERR(p);
uslist->num = 0;
uslist->alloc = size;
uslist->us = p;
return 0;
}
static void
unset_addr_list_end(UnsetAddrList* uslist)
{
if (IS_NOT_NULL(uslist->us))
xfree(uslist->us);
}
static int
unset_addr_list_add(UnsetAddrList* uslist, int offset, struct _Node* node)
{
UnsetAddr* p;
int size;
if (uslist->num >= uslist->alloc) {
size = uslist->alloc * 2;
p = (UnsetAddr* )xrealloc(uslist->us, sizeof(UnsetAddr) * size);
CHECK_NULL_RETURN_MEMERR(p);
uslist->alloc = size;
uslist->us = p;
}
uslist->us[uslist->num].offset = offset;
uslist->us[uslist->num].target = node;
uslist->num++;
return 0;
}
#endif /* USE_SUBEXP_CALL */
static int
add_opcode(regex_t* reg, int opcode)
{
BBUF_ADD1(reg, opcode);
return 0;
}
#ifdef USE_COMBINATION_EXPLOSION_CHECK
static int
add_state_check_num(regex_t* reg, int num)
{
StateCheckNumType n = (StateCheckNumType )num;
BBUF_ADD(reg, &n, SIZE_STATE_CHECK_NUM);
return 0;
}
#endif
static int
add_rel_addr(regex_t* reg, int addr)
{
RelAddrType ra = (RelAddrType )addr;
BBUF_ADD(reg, &ra, SIZE_RELADDR);
return 0;
}
static int
add_abs_addr(regex_t* reg, int addr)
{
AbsAddrType ra = (AbsAddrType )addr;
BBUF_ADD(reg, &ra, SIZE_ABSADDR);
return 0;
}
static int
add_length(regex_t* reg, int len)
{
LengthType l = (LengthType )len;
BBUF_ADD(reg, &l, SIZE_LENGTH);
return 0;
}
static int
add_mem_num(regex_t* reg, int num)
{
MemNumType n = (MemNumType )num;
BBUF_ADD(reg, &n, SIZE_MEMNUM);
return 0;
}
static int
add_pointer(regex_t* reg, void* addr)
{
PointerType ptr = (PointerType )addr;
BBUF_ADD(reg, &ptr, SIZE_POINTER);
return 0;
}
static int
add_option(regex_t* reg, OnigOptionType option)
{
BBUF_ADD(reg, &option, SIZE_OPTION);
return 0;
}
static int
add_opcode_rel_addr(regex_t* reg, int opcode, int addr)
{
int r;
r = add_opcode(reg, opcode);
if (r) return r;
r = add_rel_addr(reg, addr);
return r;
}
static int
add_bytes(regex_t* reg, UChar* bytes, int len)
{
BBUF_ADD(reg, bytes, len);
return 0;
}
static int
add_bitset(regex_t* reg, BitSetRef bs)
{
BBUF_ADD(reg, bs, SIZE_BITSET);
return 0;
}
static int
add_opcode_option(regex_t* reg, int opcode, OnigOptionType option)
{
int r;
r = add_opcode(reg, opcode);
if (r) return r;
r = add_option(reg, option);
return r;
}
static int compile_length_tree(Node* node, regex_t* reg);
static int compile_tree(Node* node, regex_t* reg);
#define IS_NEED_STR_LEN_OP_EXACT(op) \
((op) == OP_EXACTN || (op) == OP_EXACTMB2N ||\
(op) == OP_EXACTMB3N || (op) == OP_EXACTMBN || (op) == OP_EXACTN_IC)
static int
select_str_opcode(int mb_len, int str_len, int ignore_case)
{
int op;
if (ignore_case) {
switch (str_len) {
case 1: op = OP_EXACT1_IC; break;
default: op = OP_EXACTN_IC; break;
}
}
else {
switch (mb_len) {
case 1:
switch (str_len) {
case 1: op = OP_EXACT1; break;
case 2: op = OP_EXACT2; break;
case 3: op = OP_EXACT3; break;
case 4: op = OP_EXACT4; break;
case 5: op = OP_EXACT5; break;
default: op = OP_EXACTN; break;
}
break;
case 2:
switch (str_len) {
case 1: op = OP_EXACTMB2N1; break;
case 2: op = OP_EXACTMB2N2; break;
case 3: op = OP_EXACTMB2N3; break;
default: op = OP_EXACTMB2N; break;
}
break;
case 3:
op = OP_EXACTMB3N;
break;
default:
op = OP_EXACTMBN;
break;
}
}
return op;
}
static int
compile_tree_empty_check(Node* node, regex_t* reg, int empty_info)
{
int r;
int saved_num_null_check = reg->num_null_check;
if (empty_info != 0) {
r = add_opcode(reg, OP_NULL_CHECK_START);
if (r) return r;
r = add_mem_num(reg, reg->num_null_check); /* NULL CHECK ID */
if (r) return r;
reg->num_null_check++;
}
r = compile_tree(node, reg);
if (r) return r;
if (empty_info != 0) {
if (empty_info == NQ_TARGET_IS_EMPTY)
r = add_opcode(reg, OP_NULL_CHECK_END);
else if (empty_info == NQ_TARGET_IS_EMPTY_MEM)
r = add_opcode(reg, OP_NULL_CHECK_END_MEMST);
else if (empty_info == NQ_TARGET_IS_EMPTY_REC)
r = add_opcode(reg, OP_NULL_CHECK_END_MEMST_PUSH);
if (r) return r;
r = add_mem_num(reg, saved_num_null_check); /* NULL CHECK ID */
}
return r;
}
#ifdef USE_SUBEXP_CALL
static int
compile_call(CallNode* node, regex_t* reg)
{
int r;
r = add_opcode(reg, OP_CALL);
if (r) return r;
r = unset_addr_list_add(node->unset_addr_list, BBUF_GET_OFFSET_POS(reg),
node->target);
if (r) return r;
r = add_abs_addr(reg, 0 /*dummy addr.*/);
return r;
}
#endif
static int
compile_tree_n_times(Node* node, int n, regex_t* reg)
{
int i, r;
for (i = 0; i < n; i++) {
r = compile_tree(node, reg);
if (r) return r;
}
return 0;
}
static int
add_compile_string_length(UChar* s ARG_UNUSED, int mb_len, int str_len,
regex_t* reg ARG_UNUSED, int ignore_case)
{
int len;
int op = select_str_opcode(mb_len, str_len, ignore_case);
len = SIZE_OPCODE;
if (op == OP_EXACTMBN) len += SIZE_LENGTH;
if (IS_NEED_STR_LEN_OP_EXACT(op))
len += SIZE_LENGTH;
len += mb_len * str_len;
return len;
}
static int
add_compile_string(UChar* s, int mb_len, int str_len,
regex_t* reg, int ignore_case)
{
int op = select_str_opcode(mb_len, str_len, ignore_case);
add_opcode(reg, op);
if (op == OP_EXACTMBN)
add_length(reg, mb_len);
if (IS_NEED_STR_LEN_OP_EXACT(op)) {
if (op == OP_EXACTN_IC)
add_length(reg, mb_len * str_len);
else
add_length(reg, str_len);
}
add_bytes(reg, s, mb_len * str_len);
return 0;
}
static int
compile_length_string_node(Node* node, regex_t* reg)
{
int rlen, r, len, prev_len, slen, ambig;
OnigEncoding enc = reg->enc;
UChar *p, *prev;
StrNode* sn;
sn = NSTR(node);
if (sn->end <= sn->s)
return 0;
ambig = NSTRING_IS_AMBIG(node);
p = prev = sn->s;
prev_len = enclen(enc, p, sn->end);
p += prev_len;
slen = 1;
rlen = 0;
for (; p < sn->end; ) {
len = enclen(enc, p, sn->end);
if (len == prev_len) {
slen++;
}
else {
r = add_compile_string_length(prev, prev_len, slen, reg, ambig);
rlen += r;
prev = p;
slen = 1;
prev_len = len;
}
p += len;
}
r = add_compile_string_length(prev, prev_len, slen, reg, ambig);
rlen += r;
return rlen;
}
static int
compile_length_string_raw_node(StrNode* sn, regex_t* reg)
{
if (sn->end <= sn->s)
return 0;
return add_compile_string_length(sn->s, 1 /* sb */, sn->end - sn->s, reg, 0);
}
static int
compile_string_node(Node* node, regex_t* reg)
{
int r, len, prev_len, slen, ambig;
OnigEncoding enc = reg->enc;
UChar *p, *prev, *end;
StrNode* sn;
sn = NSTR(node);
if (sn->end <= sn->s)
return 0;
end = sn->end;
ambig = NSTRING_IS_AMBIG(node);
p = prev = sn->s;
prev_len = enclen(enc, p, end);
p += prev_len;
slen = 1;
for (; p < end; ) {
len = enclen(enc, p, end);
if (len == prev_len) {
slen++;
}
else {
r = add_compile_string(prev, prev_len, slen, reg, ambig);
if (r) return r;
prev = p;
slen = 1;
prev_len = len;
}
p += len;
}
return add_compile_string(prev, prev_len, slen, reg, ambig);
}
static int
compile_string_raw_node(StrNode* sn, regex_t* reg)
{
if (sn->end <= sn->s)
return 0;
return add_compile_string(sn->s, 1 /* sb */, sn->end - sn->s, reg, 0);
}
static int
add_multi_byte_cclass(BBuf* mbuf, regex_t* reg)
{
#ifdef PLATFORM_UNALIGNED_WORD_ACCESS
add_length(reg, mbuf->used);
return add_bytes(reg, mbuf->p, mbuf->used);
#else
int r, pad_size;
UChar* p = BBUF_GET_ADD_ADDRESS(reg) + SIZE_LENGTH;
GET_ALIGNMENT_PAD_SIZE(p, pad_size);
add_length(reg, mbuf->used + (WORD_ALIGNMENT_SIZE - 1));
if (pad_size != 0) add_bytes(reg, PadBuf, pad_size);
r = add_bytes(reg, mbuf->p, mbuf->used);
/* padding for return value from compile_length_cclass_node() to be fix. */
pad_size = (WORD_ALIGNMENT_SIZE - 1) - pad_size;
if (pad_size != 0) add_bytes(reg, PadBuf, pad_size);
return r;
#endif
}
static int
compile_length_cclass_node(CClassNode* cc, regex_t* reg)
{
int len;
if (IS_NCCLASS_SHARE(cc)) {
len = SIZE_OPCODE + SIZE_POINTER;
return len;
}
if (IS_NULL(cc->mbuf)) {
len = SIZE_OPCODE + SIZE_BITSET;
}
else {
if (ONIGENC_MBC_MINLEN(reg->enc) > 1 || bitset_is_empty(cc->bs)) {
len = SIZE_OPCODE;
}
else {
len = SIZE_OPCODE + SIZE_BITSET;
}
#ifdef PLATFORM_UNALIGNED_WORD_ACCESS
len += SIZE_LENGTH + cc->mbuf->used;
#else
len += SIZE_LENGTH + cc->mbuf->used + (WORD_ALIGNMENT_SIZE - 1);
#endif
}
return len;
}
static int
compile_cclass_node(CClassNode* cc, regex_t* reg)
{
int r;
if (IS_NCCLASS_SHARE(cc)) {
add_opcode(reg, OP_CCLASS_NODE);
r = add_pointer(reg, cc);
return r;
}
if (IS_NULL(cc->mbuf)) {
if (IS_NCCLASS_NOT(cc))
add_opcode(reg, OP_CCLASS_NOT);
else
add_opcode(reg, OP_CCLASS);
r = add_bitset(reg, cc->bs);
}
else {
if (ONIGENC_MBC_MINLEN(reg->enc) > 1 || bitset_is_empty(cc->bs)) {
if (IS_NCCLASS_NOT(cc))
add_opcode(reg, OP_CCLASS_MB_NOT);
else
add_opcode(reg, OP_CCLASS_MB);
r = add_multi_byte_cclass(cc->mbuf, reg);
}
else {
if (IS_NCCLASS_NOT(cc))
add_opcode(reg, OP_CCLASS_MIX_NOT);
else
add_opcode(reg, OP_CCLASS_MIX);
r = add_bitset(reg, cc->bs);
if (r) return r;
r = add_multi_byte_cclass(cc->mbuf, reg);
}
}
return r;
}
static int
entry_repeat_range(regex_t* reg, int id, int lower, int upper)
{
#define REPEAT_RANGE_ALLOC 4
OnigRepeatRange* p;
if (reg->repeat_range_alloc == 0) {
p = (OnigRepeatRange* )xmalloc(sizeof(OnigRepeatRange) * REPEAT_RANGE_ALLOC);
CHECK_NULL_RETURN_MEMERR(p);
reg->repeat_range = p;
reg->repeat_range_alloc = REPEAT_RANGE_ALLOC;
}
else if (reg->repeat_range_alloc <= id) {
int n;
n = reg->repeat_range_alloc + REPEAT_RANGE_ALLOC;
p = (OnigRepeatRange* )xrealloc(reg->repeat_range,
sizeof(OnigRepeatRange) * n);
CHECK_NULL_RETURN_MEMERR(p);
reg->repeat_range = p;
reg->repeat_range_alloc = n;
}
else {
p = reg->repeat_range;
}
p[id].lower = lower;
p[id].upper = (IS_REPEAT_INFINITE(upper) ? 0x7fffffff : upper);
return 0;
}
static int
compile_range_repeat_node(QtfrNode* qn, int target_len, int empty_info,
regex_t* reg)
{
int r;
int num_repeat = reg->num_repeat;
r = add_opcode(reg, qn->greedy ? OP_REPEAT : OP_REPEAT_NG);
if (r) return r;
r = add_mem_num(reg, num_repeat); /* OP_REPEAT ID */
reg->num_repeat++;
if (r) return r;
r = add_rel_addr(reg, target_len + SIZE_OP_REPEAT_INC);
if (r) return r;
r = entry_repeat_range(reg, num_repeat, qn->lower, qn->upper);
if (r) return r;
r = compile_tree_empty_check(qn->target, reg, empty_info);
if (r) return r;
if (
#ifdef USE_SUBEXP_CALL
reg->num_call > 0 ||
#endif
IS_QUANTIFIER_IN_REPEAT(qn)) {
r = add_opcode(reg, qn->greedy ? OP_REPEAT_INC_SG : OP_REPEAT_INC_NG_SG);
}
else {
r = add_opcode(reg, qn->greedy ? OP_REPEAT_INC : OP_REPEAT_INC_NG);
}
if (r) return r;
r = add_mem_num(reg, num_repeat); /* OP_REPEAT ID */
return r;
}
static int
is_anychar_star_quantifier(QtfrNode* qn)
{
if (qn->greedy && IS_REPEAT_INFINITE(qn->upper) &&
NTYPE(qn->target) == NT_CANY)
return 1;
else
return 0;
}
#define QUANTIFIER_EXPAND_LIMIT_SIZE 50
#define CKN_ON (ckn > 0)
#ifdef USE_COMBINATION_EXPLOSION_CHECK
static int
compile_length_quantifier_node(QtfrNode* qn, regex_t* reg)
{
int len, mod_tlen, cklen;
int ckn;
int infinite = IS_REPEAT_INFINITE(qn->upper);
int empty_info = qn->target_empty_info;
int tlen = compile_length_tree(qn->target, reg);
if (tlen < 0) return tlen;
ckn = ((reg->num_comb_exp_check > 0) ? qn->comb_exp_check_num : 0);
cklen = (CKN_ON ? SIZE_STATE_CHECK_NUM: 0);
/* anychar repeat */
if (NTYPE(qn->target) == NT_CANY) {
if (qn->greedy && infinite) {
if (IS_NOT_NULL(qn->next_head_exact) && !CKN_ON)
return SIZE_OP_ANYCHAR_STAR_PEEK_NEXT + tlen * qn->lower + cklen;
else
return SIZE_OP_ANYCHAR_STAR + tlen * qn->lower + cklen;
}
}
if (empty_info != 0)
mod_tlen = tlen + (SIZE_OP_NULL_CHECK_START + SIZE_OP_NULL_CHECK_END);
else
mod_tlen = tlen;
if (infinite && qn->lower <= 1) {
if (qn->greedy) {
if (qn->lower == 1)
len = SIZE_OP_JUMP;
else
len = 0;
len += SIZE_OP_PUSH + cklen + mod_tlen + SIZE_OP_JUMP;
}
else {
if (qn->lower == 0)
len = SIZE_OP_JUMP;
else
len = 0;
len += mod_tlen + SIZE_OP_PUSH + cklen;
}
}
else if (qn->upper == 0) {
if (qn->is_refered != 0) /* /(?<n>..){0}/ */
len = SIZE_OP_JUMP + tlen;
else
len = 0;
}
else if (qn->upper == 1 && qn->greedy) {
if (qn->lower == 0) {
if (CKN_ON) {
len = SIZE_OP_STATE_CHECK_PUSH + tlen;
}
else {
len = SIZE_OP_PUSH + tlen;
}
}
else {
len = tlen;
}
}
else if (!qn->greedy && qn->upper == 1 && qn->lower == 0) { /* '??' */
len = SIZE_OP_PUSH + cklen + SIZE_OP_JUMP + tlen;
}
else {
len = SIZE_OP_REPEAT_INC
+ mod_tlen + SIZE_OPCODE + SIZE_RELADDR + SIZE_MEMNUM;
if (CKN_ON)
len += SIZE_OP_STATE_CHECK;
}
return len;
}
static int
compile_quantifier_node(QtfrNode* qn, regex_t* reg)
{
int r, mod_tlen;
int ckn;
int infinite = IS_REPEAT_INFINITE(qn->upper);
int empty_info = qn->target_empty_info;
int tlen = compile_length_tree(qn->target, reg);
if (tlen < 0) return tlen;
ckn = ((reg->num_comb_exp_check > 0) ? qn->comb_exp_check_num : 0);
if (is_anychar_star_quantifier(qn)) {
r = compile_tree_n_times(qn->target, qn->lower, reg);
if (r) return r;
if (IS_NOT_NULL(qn->next_head_exact) && !CKN_ON) {
if (IS_MULTILINE(reg->options))
r = add_opcode(reg, OP_ANYCHAR_ML_STAR_PEEK_NEXT);
else
r = add_opcode(reg, OP_ANYCHAR_STAR_PEEK_NEXT);
if (r) return r;
if (CKN_ON) {
r = add_state_check_num(reg, ckn);
if (r) return r;
}
return add_bytes(reg, NSTR(qn->next_head_exact)->s, 1);
}
else {
if (IS_MULTILINE(reg->options)) {
r = add_opcode(reg, (CKN_ON ?
OP_STATE_CHECK_ANYCHAR_ML_STAR
: OP_ANYCHAR_ML_STAR));
}
else {
r = add_opcode(reg, (CKN_ON ?
OP_STATE_CHECK_ANYCHAR_STAR
: OP_ANYCHAR_STAR));
}
if (r) return r;
if (CKN_ON)
r = add_state_check_num(reg, ckn);
return r;
}
}
if (empty_info != 0)
mod_tlen = tlen + (SIZE_OP_NULL_CHECK_START + SIZE_OP_NULL_CHECK_END);
else
mod_tlen = tlen;
if (infinite && qn->lower <= 1) {
if (qn->greedy) {
if (qn->lower == 1) {
r = add_opcode_rel_addr(reg, OP_JUMP,
(CKN_ON ? SIZE_OP_STATE_CHECK_PUSH : SIZE_OP_PUSH));
if (r) return r;
}
if (CKN_ON) {
r = add_opcode(reg, OP_STATE_CHECK_PUSH);
if (r) return r;
r = add_state_check_num(reg, ckn);
if (r) return r;
r = add_rel_addr(reg, mod_tlen + SIZE_OP_JUMP);
}
else {
r = add_opcode_rel_addr(reg, OP_PUSH, mod_tlen + SIZE_OP_JUMP);
}
if (r) return r;
r = compile_tree_empty_check(qn->target, reg, empty_info);
if (r) return r;
r = add_opcode_rel_addr(reg, OP_JUMP,
-(mod_tlen + (int )SIZE_OP_JUMP
+ (int )(CKN_ON ? SIZE_OP_STATE_CHECK_PUSH : SIZE_OP_PUSH)));
}
else {
if (qn->lower == 0) {
r = add_opcode_rel_addr(reg, OP_JUMP, mod_tlen);
if (r) return r;
}
r = compile_tree_empty_check(qn->target, reg, empty_info);
if (r) return r;
if (CKN_ON) {
r = add_opcode(reg, OP_STATE_CHECK_PUSH_OR_JUMP);
if (r) return r;
r = add_state_check_num(reg, ckn);
if (r) return r;
r = add_rel_addr(reg,
-(mod_tlen + (int )SIZE_OP_STATE_CHECK_PUSH_OR_JUMP));
}
else
r = add_opcode_rel_addr(reg, OP_PUSH, -(mod_tlen + (int )SIZE_OP_PUSH));
}
}
else if (qn->upper == 0) {
if (qn->is_refered != 0) { /* /(?<n>..){0}/ */
r = add_opcode_rel_addr(reg, OP_JUMP, tlen);
if (r) return r;
r = compile_tree(qn->target, reg);
}
else
r = 0;
}
else if (qn->upper == 1 && qn->greedy) {
if (qn->lower == 0) {
if (CKN_ON) {
r = add_opcode(reg, OP_STATE_CHECK_PUSH);
if (r) return r;
r = add_state_check_num(reg, ckn);
if (r) return r;
r = add_rel_addr(reg, tlen);
}
else {
r = add_opcode_rel_addr(reg, OP_PUSH, tlen);
}
if (r) return r;
}
r = compile_tree(qn->target, reg);
}
else if (!qn->greedy && qn->upper == 1 && qn->lower == 0) { /* '??' */
if (CKN_ON) {
r = add_opcode(reg, OP_STATE_CHECK_PUSH);
if (r) return r;
r = add_state_check_num(reg, ckn);
if (r) return r;
r = add_rel_addr(reg, SIZE_OP_JUMP);
}
else {
r = add_opcode_rel_addr(reg, OP_PUSH, SIZE_OP_JUMP);
}
if (r) return r;
r = add_opcode_rel_addr(reg, OP_JUMP, tlen);
if (r) return r;
r = compile_tree(qn->target, reg);
}
else {
r = compile_range_repeat_node(qn, mod_tlen, empty_info, reg);
if (CKN_ON) {
if (r) return r;
r = add_opcode(reg, OP_STATE_CHECK);
if (r) return r;
r = add_state_check_num(reg, ckn);
}
}
return r;
}
#else /* USE_COMBINATION_EXPLOSION_CHECK */
static int
compile_length_quantifier_node(QtfrNode* qn, regex_t* reg)
{
int len, mod_tlen;
int infinite = IS_REPEAT_INFINITE(qn->upper);
int empty_info = qn->target_empty_info;
int tlen = compile_length_tree(qn->target, reg);
if (tlen < 0) return tlen;
/* anychar repeat */
if (NTYPE(qn->target) == NT_CANY) {
if (qn->greedy && infinite) {
if (IS_NOT_NULL(qn->next_head_exact))
return SIZE_OP_ANYCHAR_STAR_PEEK_NEXT + tlen * qn->lower;
else
return SIZE_OP_ANYCHAR_STAR + tlen * qn->lower;
}
}
if (empty_info != 0)
mod_tlen = tlen + (SIZE_OP_NULL_CHECK_START + SIZE_OP_NULL_CHECK_END);
else
mod_tlen = tlen;
if (infinite &&
(qn->lower <= 1 || tlen * qn->lower <= QUANTIFIER_EXPAND_LIMIT_SIZE)) {
if (qn->lower == 1 && tlen > QUANTIFIER_EXPAND_LIMIT_SIZE) {
len = SIZE_OP_JUMP;
}
else {
len = tlen * qn->lower;
}
if (qn->greedy) {
if (IS_NOT_NULL(qn->head_exact))
len += SIZE_OP_PUSH_OR_JUMP_EXACT1 + mod_tlen + SIZE_OP_JUMP;
else if (IS_NOT_NULL(qn->next_head_exact))
len += SIZE_OP_PUSH_IF_PEEK_NEXT + mod_tlen + SIZE_OP_JUMP;
else
len += SIZE_OP_PUSH + mod_tlen + SIZE_OP_JUMP;
}
else
len += SIZE_OP_JUMP + mod_tlen + SIZE_OP_PUSH;
}
else if (qn->upper == 0 && qn->is_refered != 0) { /* /(?<n>..){0}/ */
len = SIZE_OP_JUMP + tlen;
}
else if (!infinite && qn->greedy &&
(qn->upper == 1 || (tlen + SIZE_OP_PUSH) * qn->upper
<= QUANTIFIER_EXPAND_LIMIT_SIZE)) {
len = tlen * qn->lower;
len += (SIZE_OP_PUSH + tlen) * (qn->upper - qn->lower);
}
else if (!qn->greedy && qn->upper == 1 && qn->lower == 0) { /* '??' */
len = SIZE_OP_PUSH + SIZE_OP_JUMP + tlen;
}
else {
len = SIZE_OP_REPEAT_INC
+ mod_tlen + SIZE_OPCODE + SIZE_RELADDR + SIZE_MEMNUM;
}
return len;
}
static int
compile_quantifier_node(QtfrNode* qn, regex_t* reg)
{
int i, r, mod_tlen;
int infinite = IS_REPEAT_INFINITE(qn->upper);
int empty_info = qn->target_empty_info;
int tlen = compile_length_tree(qn->target, reg);
if (tlen < 0) return tlen;
if (is_anychar_star_quantifier(qn)) {
r = compile_tree_n_times(qn->target, qn->lower, reg);
if (r) return r;
if (IS_NOT_NULL(qn->next_head_exact)) {
if (IS_MULTILINE(reg->options))
r = add_opcode(reg, OP_ANYCHAR_ML_STAR_PEEK_NEXT);
else
r = add_opcode(reg, OP_ANYCHAR_STAR_PEEK_NEXT);
if (r) return r;
return add_bytes(reg, NSTR(qn->next_head_exact)->s, 1);
}
else {
if (IS_MULTILINE(reg->options))
return add_opcode(reg, OP_ANYCHAR_ML_STAR);
else
return add_opcode(reg, OP_ANYCHAR_STAR);
}
}
if (empty_info != 0)
mod_tlen = tlen + (SIZE_OP_NULL_CHECK_START + SIZE_OP_NULL_CHECK_END);
else
mod_tlen = tlen;
if (infinite &&
(qn->lower <= 1 || tlen * qn->lower <= QUANTIFIER_EXPAND_LIMIT_SIZE)) {
if (qn->lower == 1 && tlen > QUANTIFIER_EXPAND_LIMIT_SIZE) {
if (qn->greedy) {
if (IS_NOT_NULL(qn->head_exact))
r = add_opcode_rel_addr(reg, OP_JUMP, SIZE_OP_PUSH_OR_JUMP_EXACT1);
else if (IS_NOT_NULL(qn->next_head_exact))
r = add_opcode_rel_addr(reg, OP_JUMP, SIZE_OP_PUSH_IF_PEEK_NEXT);
else
r = add_opcode_rel_addr(reg, OP_JUMP, SIZE_OP_PUSH);
}
else {
r = add_opcode_rel_addr(reg, OP_JUMP, SIZE_OP_JUMP);
}
if (r) return r;
}
else {
r = compile_tree_n_times(qn->target, qn->lower, reg);
if (r) return r;
}
if (qn->greedy) {
if (IS_NOT_NULL(qn->head_exact)) {
r = add_opcode_rel_addr(reg, OP_PUSH_OR_JUMP_EXACT1,
mod_tlen + SIZE_OP_JUMP);
if (r) return r;
add_bytes(reg, NSTR(qn->head_exact)->s, 1);
r = compile_tree_empty_check(qn->target, reg, empty_info);
if (r) return r;
r = add_opcode_rel_addr(reg, OP_JUMP,
-(mod_tlen + (int )SIZE_OP_JUMP + (int )SIZE_OP_PUSH_OR_JUMP_EXACT1));
}
else if (IS_NOT_NULL(qn->next_head_exact)) {
r = add_opcode_rel_addr(reg, OP_PUSH_IF_PEEK_NEXT,
mod_tlen + SIZE_OP_JUMP);
if (r) return r;
add_bytes(reg, NSTR(qn->next_head_exact)->s, 1);
r = compile_tree_empty_check(qn->target, reg, empty_info);
if (r) return r;
r = add_opcode_rel_addr(reg, OP_JUMP,
-(mod_tlen + (int )SIZE_OP_JUMP + (int )SIZE_OP_PUSH_IF_PEEK_NEXT));
}
else {
r = add_opcode_rel_addr(reg, OP_PUSH, mod_tlen + SIZE_OP_JUMP);
if (r) return r;
r = compile_tree_empty_check(qn->target, reg, empty_info);
if (r) return r;
r = add_opcode_rel_addr(reg, OP_JUMP,
-(mod_tlen + (int )SIZE_OP_JUMP + (int )SIZE_OP_PUSH));
}
}
else {
r = add_opcode_rel_addr(reg, OP_JUMP, mod_tlen);
if (r) return r;
r = compile_tree_empty_check(qn->target, reg, empty_info);
if (r) return r;
r = add_opcode_rel_addr(reg, OP_PUSH, -(mod_tlen + (int )SIZE_OP_PUSH));
}
}
else if (qn->upper == 0 && qn->is_refered != 0) { /* /(?<n>..){0}/ */
r = add_opcode_rel_addr(reg, OP_JUMP, tlen);
if (r) return r;
r = compile_tree(qn->target, reg);
}
else if (!infinite && qn->greedy &&
(qn->upper == 1 || (tlen + SIZE_OP_PUSH) * qn->upper
<= QUANTIFIER_EXPAND_LIMIT_SIZE)) {
int n = qn->upper - qn->lower;
r = compile_tree_n_times(qn->target, qn->lower, reg);
if (r) return r;
for (i = 0; i < n; i++) {
r = add_opcode_rel_addr(reg, OP_PUSH,
(n - i) * tlen + (n - i - 1) * SIZE_OP_PUSH);
if (r) return r;
r = compile_tree(qn->target, reg);
if (r) return r;
}
}
else if (!qn->greedy && qn->upper == 1 && qn->lower == 0) { /* '??' */
r = add_opcode_rel_addr(reg, OP_PUSH, SIZE_OP_JUMP);
if (r) return r;
r = add_opcode_rel_addr(reg, OP_JUMP, tlen);
if (r) return r;
r = compile_tree(qn->target, reg);
}
else {
r = compile_range_repeat_node(qn, mod_tlen, empty_info, reg);
}
return r;
}
#endif /* USE_COMBINATION_EXPLOSION_CHECK */
static int
compile_length_option_node(EncloseNode* node, regex_t* reg)
{
int tlen;
OnigOptionType prev = reg->options;
reg->options = node->option;
tlen = compile_length_tree(node->target, reg);
reg->options = prev;
if (tlen < 0) return tlen;
if (IS_DYNAMIC_OPTION(prev ^ node->option)) {
return SIZE_OP_SET_OPTION_PUSH + SIZE_OP_SET_OPTION + SIZE_OP_FAIL
+ tlen + SIZE_OP_SET_OPTION;
}
else
return tlen;
}
static int
compile_option_node(EncloseNode* node, regex_t* reg)
{
int r;
OnigOptionType prev = reg->options;
if (IS_DYNAMIC_OPTION(prev ^ node->option)) {
r = add_opcode_option(reg, OP_SET_OPTION_PUSH, node->option);
if (r) return r;
r = add_opcode_option(reg, OP_SET_OPTION, prev);
if (r) return r;
r = add_opcode(reg, OP_FAIL);
if (r) return r;
}
reg->options = node->option;
r = compile_tree(node->target, reg);
reg->options = prev;
if (IS_DYNAMIC_OPTION(prev ^ node->option)) {
if (r) return r;
r = add_opcode_option(reg, OP_SET_OPTION, prev);
}
return r;
}
static int
compile_length_enclose_node(EncloseNode* node, regex_t* reg)
{
int len;
int tlen;
if (node->type == ENCLOSE_OPTION)
return compile_length_option_node(node, reg);
if (node->target) {
tlen = compile_length_tree(node->target, reg);
if (tlen < 0) return tlen;
}
else
tlen = 0;
switch (node->type) {
case ENCLOSE_MEMORY:
#ifdef USE_SUBEXP_CALL
if (IS_ENCLOSE_CALLED(node)) {
len = SIZE_OP_MEMORY_START_PUSH + tlen
+ SIZE_OP_CALL + SIZE_OP_JUMP + SIZE_OP_RETURN;
if (BIT_STATUS_AT(reg->bt_mem_end, node->regnum))
len += (IS_ENCLOSE_RECURSION(node)
? SIZE_OP_MEMORY_END_PUSH_REC : SIZE_OP_MEMORY_END_PUSH);
else
len += (IS_ENCLOSE_RECURSION(node)
? SIZE_OP_MEMORY_END_REC : SIZE_OP_MEMORY_END);
}
else
#endif
{
if (BIT_STATUS_AT(reg->bt_mem_start, node->regnum))
len = SIZE_OP_MEMORY_START_PUSH;
else
len = SIZE_OP_MEMORY_START;
len += tlen + (BIT_STATUS_AT(reg->bt_mem_end, node->regnum)
? SIZE_OP_MEMORY_END_PUSH : SIZE_OP_MEMORY_END);
}
break;
case ENCLOSE_STOP_BACKTRACK:
if (IS_ENCLOSE_STOP_BT_SIMPLE_REPEAT(node)) {
QtfrNode* qn = NQTFR(node->target);
tlen = compile_length_tree(qn->target, reg);
if (tlen < 0) return tlen;
len = tlen * qn->lower
+ SIZE_OP_PUSH + tlen + SIZE_OP_POP + SIZE_OP_JUMP;
}
else {
len = SIZE_OP_PUSH_STOP_BT + tlen + SIZE_OP_POP_STOP_BT;
}
break;
default:
return ONIGERR_TYPE_BUG;
break;
}
return len;
}
static int get_char_length_tree(Node* node, regex_t* reg, int* len);
static int
compile_enclose_node(EncloseNode* node, regex_t* reg)
{
int r, len;
if (node->type == ENCLOSE_OPTION)
return compile_option_node(node, reg);
switch (node->type) {
case ENCLOSE_MEMORY:
#ifdef USE_SUBEXP_CALL
if (IS_ENCLOSE_CALLED(node)) {
r = add_opcode(reg, OP_CALL);
if (r) return r;
node->call_addr = BBUF_GET_OFFSET_POS(reg) + SIZE_ABSADDR + SIZE_OP_JUMP;
node->state |= NST_ADDR_FIXED;
r = add_abs_addr(reg, (int )node->call_addr);
if (r) return r;
len = compile_length_tree(node->target, reg);
len += (SIZE_OP_MEMORY_START_PUSH + SIZE_OP_RETURN);
if (BIT_STATUS_AT(reg->bt_mem_end, node->regnum))
len += (IS_ENCLOSE_RECURSION(node)
? SIZE_OP_MEMORY_END_PUSH_REC : SIZE_OP_MEMORY_END_PUSH);
else
len += (IS_ENCLOSE_RECURSION(node)
? SIZE_OP_MEMORY_END_REC : SIZE_OP_MEMORY_END);
r = add_opcode_rel_addr(reg, OP_JUMP, len);
if (r) return r;
}
#endif
if (BIT_STATUS_AT(reg->bt_mem_start, node->regnum))
r = add_opcode(reg, OP_MEMORY_START_PUSH);
else
r = add_opcode(reg, OP_MEMORY_START);
if (r) return r;
r = add_mem_num(reg, node->regnum);
if (r) return r;
r = compile_tree(node->target, reg);
if (r) return r;
#ifdef USE_SUBEXP_CALL
if (IS_ENCLOSE_CALLED(node)) {
if (BIT_STATUS_AT(reg->bt_mem_end, node->regnum))
r = add_opcode(reg, (IS_ENCLOSE_RECURSION(node)
? OP_MEMORY_END_PUSH_REC : OP_MEMORY_END_PUSH));
else
r = add_opcode(reg, (IS_ENCLOSE_RECURSION(node)
? OP_MEMORY_END_REC : OP_MEMORY_END));
if (r) return r;
r = add_mem_num(reg, node->regnum);
if (r) return r;
r = add_opcode(reg, OP_RETURN);
}
else
#endif
{
if (BIT_STATUS_AT(reg->bt_mem_end, node->regnum))
r = add_opcode(reg, OP_MEMORY_END_PUSH);
else
r = add_opcode(reg, OP_MEMORY_END);
if (r) return r;
r = add_mem_num(reg, node->regnum);
}
break;
case ENCLOSE_STOP_BACKTRACK:
if (IS_ENCLOSE_STOP_BT_SIMPLE_REPEAT(node)) {
QtfrNode* qn = NQTFR(node->target);
r = compile_tree_n_times(qn->target, qn->lower, reg);
if (r) return r;
len = compile_length_tree(qn->target, reg);
if (len < 0) return len;
r = add_opcode_rel_addr(reg, OP_PUSH, len + SIZE_OP_POP + SIZE_OP_JUMP);
if (r) return r;
r = compile_tree(qn->target, reg);
if (r) return r;
r = add_opcode(reg, OP_POP);
if (r) return r;
r = add_opcode_rel_addr(reg, OP_JUMP,
-((int )SIZE_OP_PUSH + len + (int )SIZE_OP_POP + (int )SIZE_OP_JUMP));
}
else {
r = add_opcode(reg, OP_PUSH_STOP_BT);
if (r) return r;
r = compile_tree(node->target, reg);
if (r) return r;
r = add_opcode(reg, OP_POP_STOP_BT);
}
break;
default:
return ONIGERR_TYPE_BUG;
break;
}
return r;
}
static int
compile_length_anchor_node(AnchorNode* node, regex_t* reg)
{
int len;
int tlen = 0;
if (node->target) {
tlen = compile_length_tree(node->target, reg);
if (tlen < 0) return tlen;
}
switch (node->type) {
case ANCHOR_PREC_READ:
len = SIZE_OP_PUSH_POS + tlen + SIZE_OP_POP_POS;
break;
case ANCHOR_PREC_READ_NOT:
len = SIZE_OP_PUSH_POS_NOT + tlen + SIZE_OP_FAIL_POS;
break;
case ANCHOR_LOOK_BEHIND:
len = SIZE_OP_LOOK_BEHIND + tlen;
break;
case ANCHOR_LOOK_BEHIND_NOT:
len = SIZE_OP_PUSH_LOOK_BEHIND_NOT + tlen + SIZE_OP_FAIL_LOOK_BEHIND_NOT;
break;
default:
len = SIZE_OPCODE;
break;
}
return len;
}
static int
compile_anchor_node(AnchorNode* node, regex_t* reg)
{
int r, len;
switch (node->type) {
case ANCHOR_BEGIN_BUF: r = add_opcode(reg, OP_BEGIN_BUF); break;
case ANCHOR_END_BUF: r = add_opcode(reg, OP_END_BUF); break;
case ANCHOR_BEGIN_LINE: r = add_opcode(reg, OP_BEGIN_LINE); break;
case ANCHOR_END_LINE: r = add_opcode(reg, OP_END_LINE); break;
case ANCHOR_SEMI_END_BUF: r = add_opcode(reg, OP_SEMI_END_BUF); break;
case ANCHOR_BEGIN_POSITION: r = add_opcode(reg, OP_BEGIN_POSITION); break;
case ANCHOR_WORD_BOUND: r = add_opcode(reg, OP_WORD_BOUND); break;
case ANCHOR_NOT_WORD_BOUND: r = add_opcode(reg, OP_NOT_WORD_BOUND); break;
#ifdef USE_WORD_BEGIN_END
case ANCHOR_WORD_BEGIN: r = add_opcode(reg, OP_WORD_BEGIN); break;
case ANCHOR_WORD_END: r = add_opcode(reg, OP_WORD_END); break;
#endif
case ANCHOR_PREC_READ:
r = add_opcode(reg, OP_PUSH_POS);
if (r) return r;
r = compile_tree(node->target, reg);
if (r) return r;
r = add_opcode(reg, OP_POP_POS);
break;
case ANCHOR_PREC_READ_NOT:
len = compile_length_tree(node->target, reg);
if (len < 0) return len;
r = add_opcode_rel_addr(reg, OP_PUSH_POS_NOT, len + SIZE_OP_FAIL_POS);
if (r) return r;
r = compile_tree(node->target, reg);
if (r) return r;
r = add_opcode(reg, OP_FAIL_POS);
break;
case ANCHOR_LOOK_BEHIND:
{
int n;
r = add_opcode(reg, OP_LOOK_BEHIND);
if (r) return r;
if (node->char_len < 0) {
r = get_char_length_tree(node->target, reg, &n);
if (r) return ONIGERR_INVALID_LOOK_BEHIND_PATTERN;
}
else
n = node->char_len;
r = add_length(reg, n);
if (r) return r;
r = compile_tree(node->target, reg);
}
break;
case ANCHOR_LOOK_BEHIND_NOT:
{
int n;
len = compile_length_tree(node->target, reg);
r = add_opcode_rel_addr(reg, OP_PUSH_LOOK_BEHIND_NOT,
len + SIZE_OP_FAIL_LOOK_BEHIND_NOT);
if (r) return r;
if (node->char_len < 0) {
r = get_char_length_tree(node->target, reg, &n);
if (r) return ONIGERR_INVALID_LOOK_BEHIND_PATTERN;
}
else
n = node->char_len;
r = add_length(reg, n);
if (r) return r;
r = compile_tree(node->target, reg);
if (r) return r;
r = add_opcode(reg, OP_FAIL_LOOK_BEHIND_NOT);
}
break;
default:
return ONIGERR_TYPE_BUG;
break;
}
return r;
}
static int
compile_length_tree(Node* node, regex_t* reg)
{
int len, type, r;
type = NTYPE(node);
switch (type) {
case NT_LIST:
len = 0;
do {
r = compile_length_tree(NCAR(node), reg);
if (r < 0) return r;
len += r;
} while (IS_NOT_NULL(node = NCDR(node)));
r = len;
break;
case NT_ALT:
{
int n;
n = r = 0;
do {
r += compile_length_tree(NCAR(node), reg);
n++;
} while (IS_NOT_NULL(node = NCDR(node)));
r += (SIZE_OP_PUSH + SIZE_OP_JUMP) * (n - 1);
}
break;
case NT_STR:
if (NSTRING_IS_RAW(node))
r = compile_length_string_raw_node(NSTR(node), reg);
else
r = compile_length_string_node(node, reg);
break;
case NT_CCLASS:
r = compile_length_cclass_node(NCCLASS(node), reg);
break;
case NT_CTYPE:
case NT_CANY:
r = SIZE_OPCODE;
break;
case NT_BREF:
{
BRefNode* br = NBREF(node);
#ifdef USE_BACKREF_WITH_LEVEL
if (IS_BACKREF_NEST_LEVEL(br)) {
r = SIZE_OPCODE + SIZE_OPTION + SIZE_LENGTH +
SIZE_LENGTH + (SIZE_MEMNUM * br->back_num);
}
else
#endif
if (br->back_num == 1) {
r = ((!IS_IGNORECASE(reg->options) && br->back_static[0] <= 2)
? SIZE_OPCODE : (SIZE_OPCODE + SIZE_MEMNUM));
}
else {
r = SIZE_OPCODE + SIZE_LENGTH + (SIZE_MEMNUM * br->back_num);
}
}
break;
#ifdef USE_SUBEXP_CALL
case NT_CALL:
r = SIZE_OP_CALL;
break;
#endif
case NT_QTFR:
r = compile_length_quantifier_node(NQTFR(node), reg);
break;
case NT_ENCLOSE:
r = compile_length_enclose_node(NENCLOSE(node), reg);
break;
case NT_ANCHOR:
r = compile_length_anchor_node(NANCHOR(node), reg);
break;
default:
return ONIGERR_TYPE_BUG;
break;
}
return r;
}
static int
compile_tree(Node* node, regex_t* reg)
{
int n, type, len, pos, r = 0;
type = NTYPE(node);
switch (type) {
case NT_LIST:
do {
r = compile_tree(NCAR(node), reg);
} while (r == 0 && IS_NOT_NULL(node = NCDR(node)));
break;
case NT_ALT:
{
Node* x = node;
len = 0;
do {
len += compile_length_tree(NCAR(x), reg);
if (NCDR(x) != NULL) {
len += SIZE_OP_PUSH + SIZE_OP_JUMP;
}
} while (IS_NOT_NULL(x = NCDR(x)));
pos = reg->used + len; /* goal position */
do {
len = compile_length_tree(NCAR(node), reg);
if (IS_NOT_NULL(NCDR(node))) {
r = add_opcode_rel_addr(reg, OP_PUSH, len + SIZE_OP_JUMP);
if (r) break;
}
r = compile_tree(NCAR(node), reg);
if (r) break;
if (IS_NOT_NULL(NCDR(node))) {
len = pos - (reg->used + SIZE_OP_JUMP);
r = add_opcode_rel_addr(reg, OP_JUMP, len);
if (r) break;
}
} while (IS_NOT_NULL(node = NCDR(node)));
}
break;
case NT_STR:
if (NSTRING_IS_RAW(node))
r = compile_string_raw_node(NSTR(node), reg);
else
r = compile_string_node(node, reg);
break;
case NT_CCLASS:
r = compile_cclass_node(NCCLASS(node), reg);
break;
case NT_CTYPE:
{
int op;
switch (NCTYPE(node)->ctype) {
case ONIGENC_CTYPE_WORD:
if (NCTYPE(node)->not != 0) op = OP_NOT_WORD;
else op = OP_WORD;
break;
default:
return ONIGERR_TYPE_BUG;
break;
}
r = add_opcode(reg, op);
}
break;
case NT_CANY:
if (IS_MULTILINE(reg->options))
r = add_opcode(reg, OP_ANYCHAR_ML);
else
r = add_opcode(reg, OP_ANYCHAR);
break;
case NT_BREF:
{
BRefNode* br = NBREF(node);
#ifdef USE_BACKREF_WITH_LEVEL
if (IS_BACKREF_NEST_LEVEL(br)) {
r = add_opcode(reg, OP_BACKREF_WITH_LEVEL);
if (r) return r;
r = add_option(reg, (reg->options & ONIG_OPTION_IGNORECASE));
if (r) return r;
r = add_length(reg, br->nest_level);
if (r) return r;
goto add_bacref_mems;
}
else
#endif
if (br->back_num == 1) {
n = br->back_static[0];
if (IS_IGNORECASE(reg->options)) {
r = add_opcode(reg, OP_BACKREFN_IC);
if (r) return r;
r = add_mem_num(reg, n);
}
else {
switch (n) {
case 1: r = add_opcode(reg, OP_BACKREF1); break;
case 2: r = add_opcode(reg, OP_BACKREF2); break;
default:
r = add_opcode(reg, OP_BACKREFN);
if (r) return r;
r = add_mem_num(reg, n);
break;
}
}
}
else {
int i;
int* p;
if (IS_IGNORECASE(reg->options)) {
r = add_opcode(reg, OP_BACKREF_MULTI_IC);
}
else {
r = add_opcode(reg, OP_BACKREF_MULTI);
}
if (r) return r;
#ifdef USE_BACKREF_WITH_LEVEL
add_bacref_mems:
#endif
r = add_length(reg, br->back_num);
if (r) return r;
p = BACKREFS_P(br);
for (i = br->back_num - 1; i >= 0; i--) {
r = add_mem_num(reg, p[i]);
if (r) return r;
}
}
}
break;
#ifdef USE_SUBEXP_CALL
case NT_CALL:
r = compile_call(NCALL(node), reg);
break;
#endif
case NT_QTFR:
r = compile_quantifier_node(NQTFR(node), reg);
break;
case NT_ENCLOSE:
r = compile_enclose_node(NENCLOSE(node), reg);
break;
case NT_ANCHOR:
r = compile_anchor_node(NANCHOR(node), reg);
break;
default:
#ifdef ONIG_DEBUG
fprintf(stderr, "compile_tree: undefined node type %d\n", NTYPE(node));
#endif
break;
}
return r;
}
#ifdef USE_NAMED_GROUP
static int
noname_disable_map(Node** plink, GroupNumRemap* map, int* counter)
{
int r = 0;
Node* node = *plink;
switch (NTYPE(node)) {
case NT_LIST:
case NT_ALT:
do {
r = noname_disable_map(&(NCAR(node)), map, counter);
} while (r == 0 && IS_NOT_NULL(node = NCDR(node)));
break;
case NT_QTFR:
{
Node** ptarget = &(NQTFR(node)->target);
Node* old = *ptarget;
r = noname_disable_map(ptarget, map, counter);
if (*ptarget != old && NTYPE(*ptarget) == NT_QTFR) {
onig_reduce_nested_quantifier(node, *ptarget);
}
}
break;
case NT_ENCLOSE:
{
EncloseNode* en = NENCLOSE(node);
if (en->type == ENCLOSE_MEMORY) {
if (IS_ENCLOSE_NAMED_GROUP(en)) {
(*counter)++;
map[en->regnum].new_val = *counter;
en->regnum = *counter;
r = noname_disable_map(&(en->target), map, counter);
}
else {
*plink = en->target;
en->target = NULL_NODE;
onig_node_free(node);
r = noname_disable_map(plink, map, counter);
}
}
else
r = noname_disable_map(&(en->target), map, counter);
}
break;
default:
break;
}
return r;
}
static int
renumber_node_backref(Node* node, GroupNumRemap* map)
{
int i, pos, n, old_num;
int *backs;
BRefNode* bn = NBREF(node);
if (! IS_BACKREF_NAME_REF(bn))
return ONIGERR_NUMBERED_BACKREF_OR_CALL_NOT_ALLOWED;
old_num = bn->back_num;
if (IS_NULL(bn->back_dynamic))
backs = bn->back_static;
else
backs = bn->back_dynamic;
for (i = 0, pos = 0; i < old_num; i++) {
n = map[backs[i]].new_val;
if (n > 0) {
backs[pos] = n;
pos++;
}
}
bn->back_num = pos;
return 0;
}
static int
renumber_by_map(Node* node, GroupNumRemap* map)
{
int r = 0;
switch (NTYPE(node)) {
case NT_LIST:
case NT_ALT:
do {
r = renumber_by_map(NCAR(node), map);
} while (r == 0 && IS_NOT_NULL(node = NCDR(node)));
break;
case NT_QTFR:
r = renumber_by_map(NQTFR(node)->target, map);
break;
case NT_ENCLOSE:
r = renumber_by_map(NENCLOSE(node)->target, map);
break;
case NT_BREF:
r = renumber_node_backref(node, map);
break;
default:
break;
}
return r;
}
static int
numbered_ref_check(Node* node)
{
int r = 0;
switch (NTYPE(node)) {
case NT_LIST:
case NT_ALT:
do {
r = numbered_ref_check(NCAR(node));
} while (r == 0 && IS_NOT_NULL(node = NCDR(node)));
break;
case NT_QTFR:
r = numbered_ref_check(NQTFR(node)->target);
break;
case NT_ENCLOSE:
r = numbered_ref_check(NENCLOSE(node)->target);
break;
case NT_BREF:
if (! IS_BACKREF_NAME_REF(NBREF(node)))
return ONIGERR_NUMBERED_BACKREF_OR_CALL_NOT_ALLOWED;
break;
default:
break;
}
return r;
}
static int
disable_noname_group_capture(Node** root, regex_t* reg, ScanEnv* env)
{
int r, i, pos, counter;
BitStatusType loc;
GroupNumRemap* map;
map = (GroupNumRemap* )xalloca(sizeof(GroupNumRemap) * (env->num_mem + 1));
CHECK_NULL_RETURN_MEMERR(map);
for (i = 1; i <= env->num_mem; i++) {
map[i].new_val = 0;
}
counter = 0;
r = noname_disable_map(root, map, &counter);
if (r != 0) return r;
r = renumber_by_map(*root, map);
if (r != 0) return r;
for (i = 1, pos = 1; i <= env->num_mem; i++) {
if (map[i].new_val > 0) {
SCANENV_MEM_NODES(env)[pos] = SCANENV_MEM_NODES(env)[i];
pos++;
}
}
loc = env->capture_history;
BIT_STATUS_CLEAR(env->capture_history);
for (i = 1; i <= ONIG_MAX_CAPTURE_HISTORY_GROUP; i++) {
if (BIT_STATUS_AT(loc, i)) {
BIT_STATUS_ON_AT_SIMPLE(env->capture_history, map[i].new_val);
}
}
env->num_mem = env->num_named;
reg->num_mem = env->num_named;
return onig_renumber_name_table(reg, map);
}
#endif /* USE_NAMED_GROUP */
#ifdef USE_SUBEXP_CALL
static int
unset_addr_list_fix(UnsetAddrList* uslist, regex_t* reg)
{
int i, offset;
EncloseNode* en;
AbsAddrType addr;
for (i = 0; i < uslist->num; i++) {
en = NENCLOSE(uslist->us[i].target);
if (! IS_ENCLOSE_ADDR_FIXED(en)) return ONIGERR_PARSER_BUG;
addr = en->call_addr;
offset = uslist->us[i].offset;
BBUF_WRITE(reg, offset, &addr, SIZE_ABSADDR);
}
return 0;
}
#endif
#ifdef USE_MONOMANIAC_CHECK_CAPTURES_IN_ENDLESS_REPEAT
static int
quantifiers_memory_node_info(Node* node)
{
int r = 0;
switch (NTYPE(node)) {
case NT_LIST:
case NT_ALT:
{
int v;
do {
v = quantifiers_memory_node_info(NCAR(node));
if (v > r) r = v;
} while (v >= 0 && IS_NOT_NULL(node = NCDR(node)));
}
break;
#ifdef USE_SUBEXP_CALL
case NT_CALL:
if (IS_CALL_RECURSION(NCALL(node))) {
return NQ_TARGET_IS_EMPTY_REC; /* tiny version */
}
else
r = quantifiers_memory_node_info(NCALL(node)->target);
break;
#endif
case NT_QTFR:
{
QtfrNode* qn = NQTFR(node);
if (qn->upper != 0) {
r = quantifiers_memory_node_info(qn->target);
}
}
break;
case NT_ENCLOSE:
{
EncloseNode* en = NENCLOSE(node);
switch (en->type) {
case ENCLOSE_MEMORY:
return NQ_TARGET_IS_EMPTY_MEM;
break;
case ENCLOSE_OPTION:
case ENCLOSE_STOP_BACKTRACK:
r = quantifiers_memory_node_info(en->target);
break;
default:
break;
}
}
break;
case NT_BREF:
case NT_STR:
case NT_CTYPE:
case NT_CCLASS:
case NT_CANY:
case NT_ANCHOR:
default:
break;
}
return r;
}
#endif /* USE_MONOMANIAC_CHECK_CAPTURES_IN_ENDLESS_REPEAT */
static int
get_min_match_length(Node* node, OnigDistance *min, ScanEnv* env)
{
OnigDistance tmin;
int r = 0;
*min = 0;
switch (NTYPE(node)) {
case NT_BREF:
{
int i;
int* backs;
Node** nodes = SCANENV_MEM_NODES(env);
BRefNode* br = NBREF(node);
if (br->state & NST_RECURSION) break;
backs = BACKREFS_P(br);
if (backs[0] > env->num_mem) return ONIGERR_INVALID_BACKREF;
r = get_min_match_length(nodes[backs[0]], min, env);
if (r != 0) break;
for (i = 1; i < br->back_num; i++) {
if (backs[i] > env->num_mem) return ONIGERR_INVALID_BACKREF;
r = get_min_match_length(nodes[backs[i]], &tmin, env);
if (r != 0) break;
if (*min > tmin) *min = tmin;
}
}
break;
#ifdef USE_SUBEXP_CALL
case NT_CALL:
if (IS_CALL_RECURSION(NCALL(node))) {
EncloseNode* en = NENCLOSE(NCALL(node)->target);
if (IS_ENCLOSE_MIN_FIXED(en))
*min = en->min_len;
}
else
r = get_min_match_length(NCALL(node)->target, min, env);
break;
#endif
case NT_LIST:
do {
r = get_min_match_length(NCAR(node), &tmin, env);
if (r == 0) *min += tmin;
} while (r == 0 && IS_NOT_NULL(node = NCDR(node)));
break;
case NT_ALT:
{
Node *x, *y;
y = node;
do {
x = NCAR(y);
r = get_min_match_length(x, &tmin, env);
if (r != 0) break;
if (y == node) *min = tmin;
else if (*min > tmin) *min = tmin;
} while (r == 0 && IS_NOT_NULL(y = NCDR(y)));
}
break;
case NT_STR:
{
StrNode* sn = NSTR(node);
*min = sn->end - sn->s;
}
break;
case NT_CTYPE:
*min = 1;
break;
case NT_CCLASS:
case NT_CANY:
*min = 1;
break;
case NT_QTFR:
{
QtfrNode* qn = NQTFR(node);
if (qn->lower > 0) {
r = get_min_match_length(qn->target, min, env);
if (r == 0)
*min = distance_multiply(*min, qn->lower);
}
}
break;
case NT_ENCLOSE:
{
EncloseNode* en = NENCLOSE(node);
switch (en->type) {
case ENCLOSE_MEMORY:
#ifdef USE_SUBEXP_CALL
if (IS_ENCLOSE_MIN_FIXED(en))
*min = en->min_len;
else {
r = get_min_match_length(en->target, min, env);
if (r == 0) {
en->min_len = *min;
SET_ENCLOSE_STATUS(node, NST_MIN_FIXED);
}
}
break;
#endif
case ENCLOSE_OPTION:
case ENCLOSE_STOP_BACKTRACK:
r = get_min_match_length(en->target, min, env);
break;
}
}
break;
case NT_ANCHOR:
default:
break;
}
return r;
}
static int
get_max_match_length(Node* node, OnigDistance *max, ScanEnv* env)
{
OnigDistance tmax;
int r = 0;
*max = 0;
switch (NTYPE(node)) {
case NT_LIST:
do {
r = get_max_match_length(NCAR(node), &tmax, env);
if (r == 0)
*max = distance_add(*max, tmax);
} while (r == 0 && IS_NOT_NULL(node = NCDR(node)));
break;
case NT_ALT:
do {
r = get_max_match_length(NCAR(node), &tmax, env);
if (r == 0 && *max < tmax) *max = tmax;
} while (r == 0 && IS_NOT_NULL(node = NCDR(node)));
break;
case NT_STR:
{
StrNode* sn = NSTR(node);
*max = sn->end - sn->s;
}
break;
case NT_CTYPE:
*max = ONIGENC_MBC_MAXLEN_DIST(env->enc);
break;
case NT_CCLASS:
case NT_CANY:
*max = ONIGENC_MBC_MAXLEN_DIST(env->enc);
break;
case NT_BREF:
{
int i;
int* backs;
Node** nodes = SCANENV_MEM_NODES(env);
BRefNode* br = NBREF(node);
if (br->state & NST_RECURSION) {
*max = ONIG_INFINITE_DISTANCE;
break;
}
backs = BACKREFS_P(br);
for (i = 0; i < br->back_num; i++) {
if (backs[i] > env->num_mem) return ONIGERR_INVALID_BACKREF;
r = get_max_match_length(nodes[backs[i]], &tmax, env);
if (r != 0) break;
if (*max < tmax) *max = tmax;
}
}
break;
#ifdef USE_SUBEXP_CALL
case NT_CALL:
if (! IS_CALL_RECURSION(NCALL(node)))
r = get_max_match_length(NCALL(node)->target, max, env);
else
*max = ONIG_INFINITE_DISTANCE;
break;
#endif
case NT_QTFR:
{
QtfrNode* qn = NQTFR(node);
if (qn->upper != 0) {
r = get_max_match_length(qn->target, max, env);
if (r == 0 && *max != 0) {
if (! IS_REPEAT_INFINITE(qn->upper))
*max = distance_multiply(*max, qn->upper);
else
*max = ONIG_INFINITE_DISTANCE;
}
}
}
break;
case NT_ENCLOSE:
{
EncloseNode* en = NENCLOSE(node);
switch (en->type) {
case ENCLOSE_MEMORY:
#ifdef USE_SUBEXP_CALL
if (IS_ENCLOSE_MAX_FIXED(en))
*max = en->max_len;
else {
r = get_max_match_length(en->target, max, env);
if (r == 0) {
en->max_len = *max;
SET_ENCLOSE_STATUS(node, NST_MAX_FIXED);
}
}
break;
#endif
case ENCLOSE_OPTION:
case ENCLOSE_STOP_BACKTRACK:
r = get_max_match_length(en->target, max, env);
break;
}
}
break;
case NT_ANCHOR:
default:
break;
}
return r;
}
#define GET_CHAR_LEN_VARLEN -1
#define GET_CHAR_LEN_TOP_ALT_VARLEN -2
/* fixed size pattern node only */
static int
get_char_length_tree1(Node* node, regex_t* reg, int* len, int level)
{
int tlen;
int r = 0;
level++;
*len = 0;
switch (NTYPE(node)) {
case NT_LIST:
do {
r = get_char_length_tree1(NCAR(node), reg, &tlen, level);
if (r == 0)
*len = distance_add(*len, tlen);
} while (r == 0 && IS_NOT_NULL(node = NCDR(node)));
break;
case NT_ALT:
{
int tlen2;
int varlen = 0;
r = get_char_length_tree1(NCAR(node), reg, &tlen, level);
while (r == 0 && IS_NOT_NULL(node = NCDR(node))) {
r = get_char_length_tree1(NCAR(node), reg, &tlen2, level);
if (r == 0) {
if (tlen != tlen2)
varlen = 1;
}
}
if (r == 0) {
if (varlen != 0) {
if (level == 1)
r = GET_CHAR_LEN_TOP_ALT_VARLEN;
else
r = GET_CHAR_LEN_VARLEN;
}
else
*len = tlen;
}
}
break;
case NT_STR:
{
StrNode* sn = NSTR(node);
UChar *s = sn->s;
while (s < sn->end) {
s += enclen(reg->enc, s, sn->end);
(*len)++;
}
}
break;
case NT_QTFR:
{
QtfrNode* qn = NQTFR(node);
if (qn->lower == qn->upper) {
r = get_char_length_tree1(qn->target, reg, &tlen, level);
if (r == 0)
*len = distance_multiply(tlen, qn->lower);
}
else
r = GET_CHAR_LEN_VARLEN;
}
break;
#ifdef USE_SUBEXP_CALL
case NT_CALL:
if (! IS_CALL_RECURSION(NCALL(node)))
r = get_char_length_tree1(NCALL(node)->target, reg, len, level);
else
r = GET_CHAR_LEN_VARLEN;
break;
#endif
case NT_CTYPE:
*len = 1;
break;
case NT_CCLASS:
case NT_CANY:
*len = 1;
break;
case NT_ENCLOSE:
{
EncloseNode* en = NENCLOSE(node);
switch (en->type) {
case ENCLOSE_MEMORY:
#ifdef USE_SUBEXP_CALL
if (IS_ENCLOSE_CLEN_FIXED(en))
*len = en->char_len;
else {
r = get_char_length_tree1(en->target, reg, len, level);
if (r == 0) {
en->char_len = *len;
SET_ENCLOSE_STATUS(node, NST_CLEN_FIXED);
}
}
break;
#endif
case ENCLOSE_OPTION:
case ENCLOSE_STOP_BACKTRACK:
r = get_char_length_tree1(en->target, reg, len, level);
break;
default:
break;
}
}
break;
case NT_ANCHOR:
break;
default:
r = GET_CHAR_LEN_VARLEN;
break;
}
return r;
}
static int
get_char_length_tree(Node* node, regex_t* reg, int* len)
{
return get_char_length_tree1(node, reg, len, 0);
}
/* x is not included y ==> 1 : 0 */
static int
is_not_included(Node* x, Node* y, regex_t* reg)
{
int i, len;
OnigCodePoint code;
UChar *p, c;
int ytype;
retry:
ytype = NTYPE(y);
switch (NTYPE(x)) {
case NT_CTYPE:
{
switch (ytype) {
case NT_CTYPE:
if (NCTYPE(y)->ctype == NCTYPE(x)->ctype &&
NCTYPE(y)->not != NCTYPE(x)->not)
return 1;
else
return 0;
break;
case NT_CCLASS:
swap:
{
Node* tmp;
tmp = x; x = y; y = tmp;
goto retry;
}
break;
case NT_STR:
goto swap;
break;
default:
break;
}
}
break;
case NT_CCLASS:
{
CClassNode* xc = NCCLASS(x);
switch (ytype) {
case NT_CTYPE:
switch (NCTYPE(y)->ctype) {
case ONIGENC_CTYPE_WORD:
if (NCTYPE(y)->not == 0) {
if (IS_NULL(xc->mbuf) && !IS_NCCLASS_NOT(xc)) {
for (i = 0; i < SINGLE_BYTE_SIZE; i++) {
if (BITSET_AT(xc->bs, i)) {
if (IS_CODE_SB_WORD(reg->enc, i)) return 0;
}
}
return 1;
}
return 0;
}
else {
for (i = 0; i < SINGLE_BYTE_SIZE; i++) {
if (! IS_CODE_SB_WORD(reg->enc, i)) {
if (!IS_NCCLASS_NOT(xc)) {
if (BITSET_AT(xc->bs, i))
return 0;
}
else {
if (! BITSET_AT(xc->bs, i))
return 0;
}
}
}
return 1;
}
break;
default:
break;
}
break;
case NT_CCLASS:
{
int v;
CClassNode* yc = NCCLASS(y);
for (i = 0; i < SINGLE_BYTE_SIZE; i++) {
v = BITSET_AT(xc->bs, i);
if ((v != 0 && !IS_NCCLASS_NOT(xc)) ||
(v == 0 && IS_NCCLASS_NOT(xc))) {
v = BITSET_AT(yc->bs, i);
if ((v != 0 && !IS_NCCLASS_NOT(yc)) ||
(v == 0 && IS_NCCLASS_NOT(yc)))
return 0;
}
}
if ((IS_NULL(xc->mbuf) && !IS_NCCLASS_NOT(xc)) ||
(IS_NULL(yc->mbuf) && !IS_NCCLASS_NOT(yc)))
return 1;
return 0;
}
break;
case NT_STR:
goto swap;
break;
default:
break;
}
}
break;
case NT_STR:
{
StrNode* xs = NSTR(x);
if (NSTRING_LEN(x) == 0)
break;
c = *(xs->s);
switch (ytype) {
case NT_CTYPE:
switch (NCTYPE(y)->ctype) {
case ONIGENC_CTYPE_WORD:
if (ONIGENC_IS_MBC_WORD(reg->enc, xs->s, xs->end))
return NCTYPE(y)->not;
else
return !(NCTYPE(y)->not);
break;
default:
break;
}
break;
case NT_CCLASS:
{
CClassNode* cc = NCCLASS(y);
code = ONIGENC_MBC_TO_CODE(reg->enc, xs->s,
xs->s + ONIGENC_MBC_MAXLEN(reg->enc));
return (onig_is_code_in_cc(reg->enc, code, cc) != 0 ? 0 : 1);
}
break;
case NT_STR:
{
UChar *q;
StrNode* ys = NSTR(y);
len = NSTRING_LEN(x);
if (len > NSTRING_LEN(y)) len = NSTRING_LEN(y);
if (NSTRING_IS_AMBIG(x) || NSTRING_IS_AMBIG(y)) {
/* tiny version */
return 0;
}
else {
for (i = 0, p = ys->s, q = xs->s; i < len; i++, p++, q++) {
if (*p != *q) return 1;
}
}
}
break;
default:
break;
}
}
break;
default:
break;
}
return 0;
}
static Node*
get_head_value_node(Node* node, int exact, regex_t* reg)
{
Node* n = NULL_NODE;
switch (NTYPE(node)) {
case NT_BREF:
case NT_ALT:
case NT_CANY:
#ifdef USE_SUBEXP_CALL
case NT_CALL:
#endif
break;
case NT_CTYPE:
case NT_CCLASS:
if (exact == 0) {
n = node;
}
break;
case NT_LIST:
n = get_head_value_node(NCAR(node), exact, reg);
break;
case NT_STR:
{
StrNode* sn = NSTR(node);
if (sn->end <= sn->s)
break;
if (exact != 0 &&
!NSTRING_IS_RAW(node) && IS_IGNORECASE(reg->options)) {
}
else {
n = node;
}
}
break;
case NT_QTFR:
{
QtfrNode* qn = NQTFR(node);
if (qn->lower > 0) {
if (IS_NOT_NULL(qn->head_exact))
n = qn->head_exact;
else
n = get_head_value_node(qn->target, exact, reg);
}
}
break;
case NT_ENCLOSE:
{
EncloseNode* en = NENCLOSE(node);
switch (en->type) {
case ENCLOSE_OPTION:
{
OnigOptionType options = reg->options;
reg->options = NENCLOSE(node)->option;
n = get_head_value_node(NENCLOSE(node)->target, exact, reg);
reg->options = options;
}
break;
case ENCLOSE_MEMORY:
case ENCLOSE_STOP_BACKTRACK:
n = get_head_value_node(en->target, exact, reg);
break;
}
}
break;
case NT_ANCHOR:
if (NANCHOR(node)->type == ANCHOR_PREC_READ)
n = get_head_value_node(NANCHOR(node)->target, exact, reg);
break;
default:
break;
}
return n;
}
static int
check_type_tree(Node* node, int type_mask, int enclose_mask, int anchor_mask)
{
int type, r = 0;
type = NTYPE(node);
if ((NTYPE2BIT(type) & type_mask) == 0)
return 1;
switch (type) {
case NT_LIST:
case NT_ALT:
do {
r = check_type_tree(NCAR(node), type_mask, enclose_mask,
anchor_mask);
} while (r == 0 && IS_NOT_NULL(node = NCDR(node)));
break;
case NT_QTFR:
r = check_type_tree(NQTFR(node)->target, type_mask, enclose_mask,
anchor_mask);
break;
case NT_ENCLOSE:
{
EncloseNode* en = NENCLOSE(node);
if ((en->type & enclose_mask) == 0)
return 1;
r = check_type_tree(en->target, type_mask, enclose_mask, anchor_mask);
}
break;
case NT_ANCHOR:
type = NANCHOR(node)->type;
if ((type & anchor_mask) == 0)
return 1;
if (NANCHOR(node)->target)
r = check_type_tree(NANCHOR(node)->target,
type_mask, enclose_mask, anchor_mask);
break;
default:
break;
}
return r;
}
#ifdef USE_SUBEXP_CALL
#define RECURSION_EXIST 1
#define RECURSION_INFINITE 2
static int
subexp_inf_recursive_check(Node* node, ScanEnv* env, int head)
{
int type;
int r = 0;
type = NTYPE(node);
switch (type) {
case NT_LIST:
{
Node *x;
OnigDistance min;
int ret;
x = node;
do {
ret = subexp_inf_recursive_check(NCAR(x), env, head);
if (ret < 0 || ret == RECURSION_INFINITE) return ret;
r |= ret;
if (head) {
ret = get_min_match_length(NCAR(x), &min, env);
if (ret != 0) return ret;
if (min != 0) head = 0;
}
} while (IS_NOT_NULL(x = NCDR(x)));
}
break;
case NT_ALT:
{
int ret;
r = RECURSION_EXIST;
do {
ret = subexp_inf_recursive_check(NCAR(node), env, head);
if (ret < 0 || ret == RECURSION_INFINITE) return ret;
r &= ret;
} while (IS_NOT_NULL(node = NCDR(node)));
}
break;
case NT_QTFR:
r = subexp_inf_recursive_check(NQTFR(node)->target, env, head);
if (r == RECURSION_EXIST) {
if (NQTFR(node)->lower == 0) r = 0;
}
break;
case NT_ANCHOR:
{
AnchorNode* an = NANCHOR(node);
switch (an->type) {
case ANCHOR_PREC_READ:
case ANCHOR_PREC_READ_NOT:
case ANCHOR_LOOK_BEHIND:
case ANCHOR_LOOK_BEHIND_NOT:
r = subexp_inf_recursive_check(an->target, env, head);
break;
}
}
break;
case NT_CALL:
r = subexp_inf_recursive_check(NCALL(node)->target, env, head);
break;
case NT_ENCLOSE:
if (IS_ENCLOSE_MARK2(NENCLOSE(node)))
return 0;
else if (IS_ENCLOSE_MARK1(NENCLOSE(node)))
return (head == 0 ? RECURSION_EXIST : RECURSION_INFINITE);
else {
SET_ENCLOSE_STATUS(node, NST_MARK2);
r = subexp_inf_recursive_check(NENCLOSE(node)->target, env, head);
CLEAR_ENCLOSE_STATUS(node, NST_MARK2);
}
break;
default:
break;
}
return r;
}
static int
subexp_inf_recursive_check_trav(Node* node, ScanEnv* env)
{
int type;
int r = 0;
type = NTYPE(node);
switch (type) {
case NT_LIST:
case NT_ALT:
do {
r = subexp_inf_recursive_check_trav(NCAR(node), env);
} while (r == 0 && IS_NOT_NULL(node = NCDR(node)));
break;
case NT_QTFR:
r = subexp_inf_recursive_check_trav(NQTFR(node)->target, env);
break;
case NT_ANCHOR:
{
AnchorNode* an = NANCHOR(node);
switch (an->type) {
case ANCHOR_PREC_READ:
case ANCHOR_PREC_READ_NOT:
case ANCHOR_LOOK_BEHIND:
case ANCHOR_LOOK_BEHIND_NOT:
r = subexp_inf_recursive_check_trav(an->target, env);
break;
}
}
break;
case NT_ENCLOSE:
{
EncloseNode* en = NENCLOSE(node);
if (IS_ENCLOSE_RECURSION(en)) {
SET_ENCLOSE_STATUS(node, NST_MARK1);
r = subexp_inf_recursive_check(en->target, env, 1);
if (r > 0) return ONIGERR_NEVER_ENDING_RECURSION;
CLEAR_ENCLOSE_STATUS(node, NST_MARK1);
}
r = subexp_inf_recursive_check_trav(en->target, env);
}
break;
default:
break;
}
return r;
}
static int
subexp_recursive_check(Node* node)
{
int r = 0;
switch (NTYPE(node)) {
case NT_LIST:
case NT_ALT:
do {
r |= subexp_recursive_check(NCAR(node));
} while (IS_NOT_NULL(node = NCDR(node)));
break;
case NT_QTFR:
r = subexp_recursive_check(NQTFR(node)->target);
break;
case NT_ANCHOR:
{
AnchorNode* an = NANCHOR(node);
switch (an->type) {
case ANCHOR_PREC_READ:
case ANCHOR_PREC_READ_NOT:
case ANCHOR_LOOK_BEHIND:
case ANCHOR_LOOK_BEHIND_NOT:
r = subexp_recursive_check(an->target);
break;
}
}
break;
case NT_CALL:
r = subexp_recursive_check(NCALL(node)->target);
if (r != 0) SET_CALL_RECURSION(node);
break;
case NT_ENCLOSE:
if (IS_ENCLOSE_MARK2(NENCLOSE(node)))
return 0;
else if (IS_ENCLOSE_MARK1(NENCLOSE(node)))
return 1; /* recursion */
else {
SET_ENCLOSE_STATUS(node, NST_MARK2);
r = subexp_recursive_check(NENCLOSE(node)->target);
CLEAR_ENCLOSE_STATUS(node, NST_MARK2);
}
break;
default:
break;
}
return r;
}
static int
subexp_recursive_check_trav(Node* node, ScanEnv* env)
{
#define FOUND_CALLED_NODE 1
int type;
int r = 0;
type = NTYPE(node);
switch (type) {
case NT_LIST:
case NT_ALT:
{
int ret;
do {
ret = subexp_recursive_check_trav(NCAR(node), env);
if (ret == FOUND_CALLED_NODE) r = FOUND_CALLED_NODE;
else if (ret < 0) return ret;
} while (IS_NOT_NULL(node = NCDR(node)));
}
break;
case NT_QTFR:
r = subexp_recursive_check_trav(NQTFR(node)->target, env);
if (NQTFR(node)->upper == 0) {
if (r == FOUND_CALLED_NODE)
NQTFR(node)->is_refered = 1;
}
break;
case NT_ANCHOR:
{
AnchorNode* an = NANCHOR(node);
switch (an->type) {
case ANCHOR_PREC_READ:
case ANCHOR_PREC_READ_NOT:
case ANCHOR_LOOK_BEHIND:
case ANCHOR_LOOK_BEHIND_NOT:
r = subexp_recursive_check_trav(an->target, env);
break;
}
}
break;
case NT_ENCLOSE:
{
EncloseNode* en = NENCLOSE(node);
if (! IS_ENCLOSE_RECURSION(en)) {
if (IS_ENCLOSE_CALLED(en)) {
SET_ENCLOSE_STATUS(node, NST_MARK1);
r = subexp_recursive_check(en->target);
if (r != 0) SET_ENCLOSE_STATUS(node, NST_RECURSION);
CLEAR_ENCLOSE_STATUS(node, NST_MARK1);
}
}
r = subexp_recursive_check_trav(en->target, env);
if (IS_ENCLOSE_CALLED(en))
r |= FOUND_CALLED_NODE;
}
break;
default:
break;
}
return r;
}
static int
setup_subexp_call(Node* node, ScanEnv* env)
{
int type;
int r = 0;
type = NTYPE(node);
switch (type) {
case NT_LIST:
do {
r = setup_subexp_call(NCAR(node), env);
} while (r == 0 && IS_NOT_NULL(node = NCDR(node)));
break;
case NT_ALT:
do {
r = setup_subexp_call(NCAR(node), env);
} while (r == 0 && IS_NOT_NULL(node = NCDR(node)));
break;
case NT_QTFR:
r = setup_subexp_call(NQTFR(node)->target, env);
break;
case NT_ENCLOSE:
r = setup_subexp_call(NENCLOSE(node)->target, env);
break;
case NT_CALL:
{
CallNode* cn = NCALL(node);
Node** nodes = SCANENV_MEM_NODES(env);
if (cn->group_num != 0) {
int gnum = cn->group_num;
#ifdef USE_NAMED_GROUP
if (env->num_named > 0 &&
IS_SYNTAX_BV(env->syntax, ONIG_SYN_CAPTURE_ONLY_NAMED_GROUP) &&
!ONIG_IS_OPTION_ON(env->option, ONIG_OPTION_CAPTURE_GROUP)) {
return ONIGERR_NUMBERED_BACKREF_OR_CALL_NOT_ALLOWED;
}
#endif
if (gnum > env->num_mem) {
onig_scan_env_set_error_string(env,
ONIGERR_UNDEFINED_GROUP_REFERENCE, cn->name, cn->name_end);
return ONIGERR_UNDEFINED_GROUP_REFERENCE;
}
#ifdef USE_NAMED_GROUP
set_call_attr:
#endif
cn->target = nodes[cn->group_num];
if (IS_NULL(cn->target)) {
onig_scan_env_set_error_string(env,
ONIGERR_UNDEFINED_NAME_REFERENCE, cn->name, cn->name_end);
return ONIGERR_UNDEFINED_NAME_REFERENCE;
}
SET_ENCLOSE_STATUS(cn->target, NST_CALLED);
BIT_STATUS_ON_AT(env->bt_mem_start, cn->group_num);
cn->unset_addr_list = env->unset_addr_list;
}
#ifdef USE_NAMED_GROUP
else {
int *refs;
int n = onig_name_to_group_numbers(env->reg, cn->name, cn->name_end,
&refs);
if (n <= 0) {
onig_scan_env_set_error_string(env,
ONIGERR_UNDEFINED_NAME_REFERENCE, cn->name, cn->name_end);
return ONIGERR_UNDEFINED_NAME_REFERENCE;
}
else if (n > 1) {
onig_scan_env_set_error_string(env,
ONIGERR_MULTIPLEX_DEFINITION_NAME_CALL, cn->name, cn->name_end);
return ONIGERR_MULTIPLEX_DEFINITION_NAME_CALL;
}
else {
cn->group_num = refs[0];
goto set_call_attr;
}
}
#endif
}
break;
case NT_ANCHOR:
{
AnchorNode* an = NANCHOR(node);
switch (an->type) {
case ANCHOR_PREC_READ:
case ANCHOR_PREC_READ_NOT:
case ANCHOR_LOOK_BEHIND:
case ANCHOR_LOOK_BEHIND_NOT:
r = setup_subexp_call(an->target, env);
break;
}
}
break;
default:
break;
}
return r;
}
#endif
/* divide different length alternatives in look-behind.
(?<=A|B) ==> (?<=A)|(?<=B)
(?<!A|B) ==> (?<!A)(?<!B)
*/
static int
divide_look_behind_alternatives(Node* node)
{
Node *head, *np, *insert_node;
AnchorNode* an = NANCHOR(node);
int anc_type = an->type;
head = an->target;
np = NCAR(head);
swap_node(node, head);
NCAR(node) = head;
NANCHOR(head)->target = np;
np = node;
while ((np = NCDR(np)) != NULL_NODE) {
insert_node = onig_node_new_anchor(anc_type);
CHECK_NULL_RETURN_MEMERR(insert_node);
NANCHOR(insert_node)->target = NCAR(np);
NCAR(np) = insert_node;
}
if (anc_type == ANCHOR_LOOK_BEHIND_NOT) {
np = node;
do {
SET_NTYPE(np, NT_LIST); /* alt -> list */
} while ((np = NCDR(np)) != NULL_NODE);
}
return 0;
}
static int
setup_look_behind(Node* node, regex_t* reg, ScanEnv* env)
{
int r, len;
AnchorNode* an = NANCHOR(node);
r = get_char_length_tree(an->target, reg, &len);
if (r == 0)
an->char_len = len;
else if (r == GET_CHAR_LEN_VARLEN)
r = ONIGERR_INVALID_LOOK_BEHIND_PATTERN;
else if (r == GET_CHAR_LEN_TOP_ALT_VARLEN) {
if (IS_SYNTAX_BV(env->syntax, ONIG_SYN_DIFFERENT_LEN_ALT_LOOK_BEHIND))
r = divide_look_behind_alternatives(node);
else
r = ONIGERR_INVALID_LOOK_BEHIND_PATTERN;
}
return r;
}
static int
next_setup(Node* node, Node* next_node, regex_t* reg)
{
int type;
retry:
type = NTYPE(node);
if (type == NT_QTFR) {
QtfrNode* qn = NQTFR(node);
if (qn->greedy && IS_REPEAT_INFINITE(qn->upper)) {
#ifdef USE_QTFR_PEEK_NEXT
Node* n = get_head_value_node(next_node, 1, reg);
/* '\0': for UTF-16BE etc... */
if (IS_NOT_NULL(n) && NSTR(n)->s[0] != '\0') {
qn->next_head_exact = n;
}
#endif
/* automatic posseivation a*b ==> (?>a*)b */
if (qn->lower <= 1) {
int ttype = NTYPE(qn->target);
if (IS_NODE_TYPE_SIMPLE(ttype)) {
Node *x, *y;
x = get_head_value_node(qn->target, 0, reg);
if (IS_NOT_NULL(x)) {
y = get_head_value_node(next_node, 0, reg);
if (IS_NOT_NULL(y) && is_not_included(x, y, reg)) {
Node* en = onig_node_new_enclose(ENCLOSE_STOP_BACKTRACK);
CHECK_NULL_RETURN_MEMERR(en);
SET_ENCLOSE_STATUS(en, NST_STOP_BT_SIMPLE_REPEAT);
swap_node(node, en);
NENCLOSE(node)->target = en;
}
}
}
}
}
}
else if (type == NT_ENCLOSE) {
EncloseNode* en = NENCLOSE(node);
if (en->type == ENCLOSE_MEMORY) {
node = en->target;
goto retry;
}
}
return 0;
}
static int
update_string_node_case_fold(regex_t* reg, Node *node)
{
UChar *p, *q, *end, buf[ONIGENC_MBC_CASE_FOLD_MAXLEN];
UChar *sbuf, *ebuf, *sp;
int r, i, len, sbuf_size;
StrNode* sn = NSTR(node);
end = sn->end;
sbuf_size = (end - sn->s) * 2;
sbuf = (UChar* )xmalloc(sbuf_size);
CHECK_NULL_RETURN_MEMERR(sbuf);
ebuf = sbuf + sbuf_size;
sp = sbuf;
p = sn->s;
while (p < end) {
len = ONIGENC_MBC_CASE_FOLD(reg->enc, reg->case_fold_flag, &p, end, buf);
q = buf;
for (i = 0; i < len; i++) {
if (sp >= ebuf) {
sbuf = (UChar* )xrealloc(sbuf, sbuf_size * 2);
CHECK_NULL_RETURN_MEMERR(sbuf);
sp = sbuf + sbuf_size;
sbuf_size *= 2;
ebuf = sbuf + sbuf_size;
}
*sp++ = buf[i];
}
}
r = onig_node_str_set(node, sbuf, sp);
if (r != 0) {
xfree(sbuf);
return r;
}
xfree(sbuf);
return 0;
}
static int
expand_case_fold_make_rem_string(Node** rnode, UChar *s, UChar *end,
regex_t* reg)
{
int r;
Node *node;
node = onig_node_new_str(s, end);
if (IS_NULL(node)) return ONIGERR_MEMORY;
r = update_string_node_case_fold(reg, node);
if (r != 0) {
onig_node_free(node);
return r;
}
NSTRING_SET_AMBIG(node);
NSTRING_SET_DONT_GET_OPT_INFO(node);
*rnode = node;
return 0;
}
static int
expand_case_fold_string_alt(int item_num, OnigCaseFoldCodeItem items[],
UChar *p, int slen, UChar *end,
regex_t* reg, Node **rnode)
{
int r, i, j, len, varlen;
Node *anode, *var_anode, *snode, *xnode, *an;
UChar buf[ONIGENC_CODE_TO_MBC_MAXLEN];
*rnode = var_anode = NULL_NODE;
varlen = 0;
for (i = 0; i < item_num; i++) {
if (items[i].byte_len != slen) {
varlen = 1;
break;
}
}
if (varlen != 0) {
*rnode = var_anode = onig_node_new_alt(NULL_NODE, NULL_NODE);
if (IS_NULL(var_anode)) return ONIGERR_MEMORY;
xnode = onig_node_new_list(NULL, NULL);
if (IS_NULL(xnode)) goto mem_err;
NCAR(var_anode) = xnode;
anode = onig_node_new_alt(NULL_NODE, NULL_NODE);
if (IS_NULL(anode)) goto mem_err;
NCAR(xnode) = anode;
}
else {
*rnode = anode = onig_node_new_alt(NULL_NODE, NULL_NODE);
if (IS_NULL(anode)) return ONIGERR_MEMORY;
}
snode = onig_node_new_str(p, p + slen);
if (IS_NULL(snode)) goto mem_err;
NCAR(anode) = snode;
for (i = 0; i < item_num; i++) {
snode = onig_node_new_str(NULL, NULL);
if (IS_NULL(snode)) goto mem_err;
for (j = 0; j < items[i].code_len; j++) {
len = ONIGENC_CODE_TO_MBC(reg->enc, items[i].code[j], buf);
if (len < 0) {
r = len;
goto mem_err2;
}
r = onig_node_str_cat(snode, buf, buf + len);
if (r != 0) goto mem_err2;
}
an = onig_node_new_alt(NULL_NODE, NULL_NODE);
if (IS_NULL(an)) {
goto mem_err2;
}
if (items[i].byte_len != slen) {
Node *rem;
UChar *q = p + items[i].byte_len;
if (q < end) {
r = expand_case_fold_make_rem_string(&rem, q, end, reg);
if (r != 0) {
onig_node_free(an);
goto mem_err2;
}
xnode = onig_node_list_add(NULL_NODE, snode);
if (IS_NULL(xnode)) {
onig_node_free(an);
onig_node_free(rem);
goto mem_err2;
}
if (IS_NULL(onig_node_list_add(xnode, rem))) {
onig_node_free(an);
onig_node_free(xnode);
onig_node_free(rem);
goto mem_err;
}
NCAR(an) = xnode;
}
else {
NCAR(an) = snode;
}
NCDR(var_anode) = an;
var_anode = an;
}
else {
NCAR(an) = snode;
NCDR(anode) = an;
anode = an;
}
}
return varlen;
mem_err2:
onig_node_free(snode);
mem_err:
onig_node_free(*rnode);
return ONIGERR_MEMORY;
}
static int
expand_case_fold_string(Node* node, regex_t* reg)
{
#define THRESHOLD_CASE_FOLD_ALT_FOR_EXPANSION 8
int r, n, len, alt_num;
UChar *start, *end, *p;
Node *top_root, *root, *snode, *prev_node;
OnigCaseFoldCodeItem items[ONIGENC_GET_CASE_FOLD_CODES_MAX_NUM];
StrNode* sn = NSTR(node);
if (NSTRING_IS_AMBIG(node)) return 0;
start = sn->s;
end = sn->end;
if (start >= end) return 0;
r = 0;
top_root = root = prev_node = snode = NULL_NODE;
alt_num = 1;
p = start;
while (p < end) {
n = ONIGENC_GET_CASE_FOLD_CODES_BY_STR(reg->enc, reg->case_fold_flag,
p, end, items);
if (n < 0) {
r = n;
goto err;
}
len = enclen(reg->enc, p, end);
if (n == 0) {
if (IS_NULL(snode)) {
if (IS_NULL(root) && IS_NOT_NULL(prev_node)) {
top_root = root = onig_node_list_add(NULL_NODE, prev_node);
if (IS_NULL(root)) {
onig_node_free(prev_node);
goto mem_err;
}
}
prev_node = snode = onig_node_new_str(NULL, NULL);
if (IS_NULL(snode)) goto mem_err;
if (IS_NOT_NULL(root)) {
if (IS_NULL(onig_node_list_add(root, snode))) {
onig_node_free(snode);
goto mem_err;
}
}
}
r = onig_node_str_cat(snode, p, p + len);
if (r != 0) goto err;
}
else {
alt_num *= (n + 1);
if (alt_num > THRESHOLD_CASE_FOLD_ALT_FOR_EXPANSION) break;
if (IS_NULL(root) && IS_NOT_NULL(prev_node)) {
top_root = root = onig_node_list_add(NULL_NODE, prev_node);
if (IS_NULL(root)) {
onig_node_free(prev_node);
goto mem_err;
}
}
r = expand_case_fold_string_alt(n, items, p, len, end, reg, &prev_node);
if (r < 0) goto mem_err;
if (r == 1) {
if (IS_NULL(root)) {
top_root = prev_node;
}
else {
if (IS_NULL(onig_node_list_add(root, prev_node))) {
onig_node_free(prev_node);
goto mem_err;
}
}
root = NCAR(prev_node);
}
else { /* r == 0 */
if (IS_NOT_NULL(root)) {
if (IS_NULL(onig_node_list_add(root, prev_node))) {
onig_node_free(prev_node);
goto mem_err;
}
}
}
snode = NULL_NODE;
}
p += len;
}
if (p < end) {
Node *srem;
r = expand_case_fold_make_rem_string(&srem, p, end, reg);
if (r != 0) goto mem_err;
if (IS_NOT_NULL(prev_node) && IS_NULL(root)) {
top_root = root = onig_node_list_add(NULL_NODE, prev_node);
if (IS_NULL(root)) {
onig_node_free(srem);
onig_node_free(prev_node);
goto mem_err;
}
}
if (IS_NULL(root)) {
prev_node = srem;
}
else {
if (IS_NULL(onig_node_list_add(root, srem))) {
onig_node_free(srem);
goto mem_err;
}
}
}
/* ending */
top_root = (IS_NOT_NULL(top_root) ? top_root : prev_node);
swap_node(node, top_root);
onig_node_free(top_root);
return 0;
mem_err:
r = ONIGERR_MEMORY;
err:
onig_node_free(top_root);
return r;
}
#ifdef USE_COMBINATION_EXPLOSION_CHECK
#define CEC_THRES_NUM_BIG_REPEAT 512
#define CEC_INFINITE_NUM 0x7fffffff
#define CEC_IN_INFINITE_REPEAT (1<<0)
#define CEC_IN_FINITE_REPEAT (1<<1)
#define CEC_CONT_BIG_REPEAT (1<<2)
static int
setup_comb_exp_check(Node* node, int state, ScanEnv* env)
{
int type;
int r = state;
type = NTYPE(node);
switch (type) {
case NT_LIST:
{
Node* prev = NULL_NODE;
do {
r = setup_comb_exp_check(NCAR(node), r, env);
prev = NCAR(node);
} while (r >= 0 && IS_NOT_NULL(node = NCDR(node)));
}
break;
case NT_ALT:
{
int ret;
do {
ret = setup_comb_exp_check(NCAR(node), state, env);
r |= ret;
} while (ret >= 0 && IS_NOT_NULL(node = NCDR(node)));
}
break;
case NT_QTFR:
{
int child_state = state;
int add_state = 0;
QtfrNode* qn = NQTFR(node);
Node* target = qn->target;
int var_num;
if (! IS_REPEAT_INFINITE(qn->upper)) {
if (qn->upper > 1) {
/* {0,1}, {1,1} are allowed */
child_state |= CEC_IN_FINITE_REPEAT;
/* check (a*){n,m}, (a+){n,m} => (a*){n,n}, (a+){n,n} */
if (env->backrefed_mem == 0) {
if (NTYPE(qn->target) == NT_ENCLOSE) {
EncloseNode* en = NENCLOSE(qn->target);
if (en->type == ENCLOSE_MEMORY) {
if (NTYPE(en->target) == NT_QTFR) {
QtfrNode* q = NQTFR(en->target);
if (IS_REPEAT_INFINITE(q->upper)
&& q->greedy == qn->greedy) {
qn->upper = (qn->lower == 0 ? 1 : qn->lower);
if (qn->upper == 1)
child_state = state;
}
}
}
}
}
}
}
if (state & CEC_IN_FINITE_REPEAT) {
qn->comb_exp_check_num = -1;
}
else {
if (IS_REPEAT_INFINITE(qn->upper)) {
var_num = CEC_INFINITE_NUM;
child_state |= CEC_IN_INFINITE_REPEAT;
}
else {
var_num = qn->upper - qn->lower;
}
if (var_num >= CEC_THRES_NUM_BIG_REPEAT)
add_state |= CEC_CONT_BIG_REPEAT;
if (((state & CEC_IN_INFINITE_REPEAT) != 0 && var_num != 0) ||
((state & CEC_CONT_BIG_REPEAT) != 0 &&
var_num >= CEC_THRES_NUM_BIG_REPEAT)) {
if (qn->comb_exp_check_num == 0) {
env->num_comb_exp_check++;
qn->comb_exp_check_num = env->num_comb_exp_check;
if (env->curr_max_regnum > env->comb_exp_max_regnum)
env->comb_exp_max_regnum = env->curr_max_regnum;
}
}
}
r = setup_comb_exp_check(target, child_state, env);
r |= add_state;
}
break;
case NT_ENCLOSE:
{
EncloseNode* en = NENCLOSE(node);
switch (en->type) {
case ENCLOSE_MEMORY:
{
if (env->curr_max_regnum < en->regnum)
env->curr_max_regnum = en->regnum;
r = setup_comb_exp_check(en->target, state, env);
}
break;
default:
r = setup_comb_exp_check(en->target, state, env);
break;
}
}
break;
#ifdef USE_SUBEXP_CALL
case NT_CALL:
if (IS_CALL_RECURSION(NCALL(node)))
env->has_recursion = 1;
else
r = setup_comb_exp_check(NCALL(node)->target, state, env);
break;
#endif
default:
break;
}
return r;
}
#endif
#define IN_ALT (1<<0)
#define IN_NOT (1<<1)
#define IN_REPEAT (1<<2)
#define IN_VAR_REPEAT (1<<3)
/* setup_tree does the following work.
1. check empty loop. (set qn->target_empty_info)
2. expand ignore-case in char class.
3. set memory status bit flags. (reg->mem_stats)
4. set qn->head_exact for [push, exact] -> [push_or_jump_exact1, exact].
5. find invalid patterns in look-behind.
6. expand repeated string.
*/
static int
setup_tree(Node* node, regex_t* reg, int state, ScanEnv* env)
{
int type;
int r = 0;
type = NTYPE(node);
switch (type) {
case NT_LIST:
{
Node* prev = NULL_NODE;
do {
r = setup_tree(NCAR(node), reg, state, env);
if (IS_NOT_NULL(prev) && r == 0) {
r = next_setup(prev, NCAR(node), reg);
}
prev = NCAR(node);
} while (r == 0 && IS_NOT_NULL(node = NCDR(node)));
}
break;
case NT_ALT:
do {
r = setup_tree(NCAR(node), reg, (state | IN_ALT), env);
} while (r == 0 && IS_NOT_NULL(node = NCDR(node)));
break;
case NT_CCLASS:
break;
case NT_STR:
if (IS_IGNORECASE(reg->options) && !NSTRING_IS_RAW(node)) {
r = expand_case_fold_string(node, reg);
}
break;
case NT_CTYPE:
case NT_CANY:
break;
#ifdef USE_SUBEXP_CALL
case NT_CALL:
break;
#endif
case NT_BREF:
{
int i;
int* p;
Node** nodes = SCANENV_MEM_NODES(env);
BRefNode* br = NBREF(node);
p = BACKREFS_P(br);
for (i = 0; i < br->back_num; i++) {
if (p[i] > env->num_mem) return ONIGERR_INVALID_BACKREF;
BIT_STATUS_ON_AT(env->backrefed_mem, p[i]);
BIT_STATUS_ON_AT(env->bt_mem_start, p[i]);
#ifdef USE_BACKREF_WITH_LEVEL
if (IS_BACKREF_NEST_LEVEL(br)) {
BIT_STATUS_ON_AT(env->bt_mem_end, p[i]);
}
#endif
SET_ENCLOSE_STATUS(nodes[p[i]], NST_MEM_BACKREFED);
}
}
break;
case NT_QTFR:
{
OnigDistance d;
QtfrNode* qn = NQTFR(node);
Node* target = qn->target;
if ((state & IN_REPEAT) != 0) {
qn->state |= NST_IN_REPEAT;
}
if (IS_REPEAT_INFINITE(qn->upper) || qn->upper >= 1) {
r = get_min_match_length(target, &d, env);
if (r) break;
if (d == 0) {
qn->target_empty_info = NQ_TARGET_IS_EMPTY;
#ifdef USE_MONOMANIAC_CHECK_CAPTURES_IN_ENDLESS_REPEAT
r = quantifiers_memory_node_info(target);
if (r < 0) break;
if (r > 0) {
qn->target_empty_info = r;
}
#endif
#if 0
r = get_max_match_length(target, &d, env);
if (r == 0 && d == 0) {
/* ()* ==> ()?, ()+ ==> () */
qn->upper = 1;
if (qn->lower > 1) qn->lower = 1;
if (NTYPE(target) == NT_STR) {
qn->upper = qn->lower = 0; /* /(?:)+/ ==> // */
}
}
#endif
}
}
state |= IN_REPEAT;
if (qn->lower != qn->upper)
state |= IN_VAR_REPEAT;
r = setup_tree(target, reg, state, env);
if (r) break;
/* expand string */
#define EXPAND_STRING_MAX_LENGTH 100
if (NTYPE(target) == NT_STR) {
if (!IS_REPEAT_INFINITE(qn->lower) && qn->lower == qn->upper &&
qn->lower > 1 && qn->lower <= EXPAND_STRING_MAX_LENGTH) {
int len = NSTRING_LEN(target);
StrNode* sn = NSTR(target);
if (len * qn->lower <= EXPAND_STRING_MAX_LENGTH) {
int i, n = qn->lower;
onig_node_conv_to_str_node(node, NSTR(target)->flag);
for (i = 0; i < n; i++) {
r = onig_node_str_cat(node, sn->s, sn->end);
if (r) break;
}
onig_node_free(target);
break; /* break case NT_QTFR: */
}
}
}
#ifdef USE_OP_PUSH_OR_JUMP_EXACT
if (qn->greedy && (qn->target_empty_info != 0)) {
if (NTYPE(target) == NT_QTFR) {
QtfrNode* tqn = NQTFR(target);
if (IS_NOT_NULL(tqn->head_exact)) {
qn->head_exact = tqn->head_exact;
tqn->head_exact = NULL;
}
}
else {
qn->head_exact = get_head_value_node(qn->target, 1, reg);
}
}
#endif
}
break;
case NT_ENCLOSE:
{
EncloseNode* en = NENCLOSE(node);
switch (en->type) {
case ENCLOSE_OPTION:
{
OnigOptionType options = reg->options;
reg->options = NENCLOSE(node)->option;
r = setup_tree(NENCLOSE(node)->target, reg, state, env);
reg->options = options;
}
break;
case ENCLOSE_MEMORY:
if ((state & (IN_ALT | IN_NOT | IN_VAR_REPEAT)) != 0) {
BIT_STATUS_ON_AT(env->bt_mem_start, en->regnum);
/* SET_ENCLOSE_STATUS(node, NST_MEM_IN_ALT_NOT); */
}
r = setup_tree(en->target, reg, state, env);
break;
case ENCLOSE_STOP_BACKTRACK:
{
Node* target = en->target;
r = setup_tree(target, reg, state, env);
if (NTYPE(target) == NT_QTFR) {
QtfrNode* tqn = NQTFR(target);
if (IS_REPEAT_INFINITE(tqn->upper) && tqn->lower <= 1 &&
tqn->greedy != 0) { /* (?>a*), a*+ etc... */
int qtype = NTYPE(tqn->target);
if (IS_NODE_TYPE_SIMPLE(qtype))
SET_ENCLOSE_STATUS(node, NST_STOP_BT_SIMPLE_REPEAT);
}
}
}
break;
}
}
break;
case NT_ANCHOR:
{
AnchorNode* an = NANCHOR(node);
switch (an->type) {
case ANCHOR_PREC_READ:
r = setup_tree(an->target, reg, state, env);
break;
case ANCHOR_PREC_READ_NOT:
r = setup_tree(an->target, reg, (state | IN_NOT), env);
break;
/* allowed node types in look-behind */
#define ALLOWED_TYPE_IN_LB \
( BIT_NT_LIST | BIT_NT_ALT | BIT_NT_STR | BIT_NT_CCLASS | BIT_NT_CTYPE | \
BIT_NT_CANY | BIT_NT_ANCHOR | BIT_NT_ENCLOSE | BIT_NT_QTFR | BIT_NT_CALL )
#define ALLOWED_ENCLOSE_IN_LB ( ENCLOSE_MEMORY )
#define ALLOWED_ENCLOSE_IN_LB_NOT 0
#define ALLOWED_ANCHOR_IN_LB \
( ANCHOR_LOOK_BEHIND | ANCHOR_BEGIN_LINE | ANCHOR_END_LINE | ANCHOR_BEGIN_BUF | ANCHOR_BEGIN_POSITION )
#define ALLOWED_ANCHOR_IN_LB_NOT \
( ANCHOR_LOOK_BEHIND | ANCHOR_LOOK_BEHIND_NOT | ANCHOR_BEGIN_LINE | ANCHOR_END_LINE | ANCHOR_BEGIN_BUF | ANCHOR_BEGIN_POSITION )
case ANCHOR_LOOK_BEHIND:
{
r = check_type_tree(an->target, ALLOWED_TYPE_IN_LB,
ALLOWED_ENCLOSE_IN_LB, ALLOWED_ANCHOR_IN_LB);
if (r < 0) return r;
if (r > 0) return ONIGERR_INVALID_LOOK_BEHIND_PATTERN;
r = setup_look_behind(node, reg, env);
if (r != 0) return r;
r = setup_tree(an->target, reg, state, env);
}
break;
case ANCHOR_LOOK_BEHIND_NOT:
{
r = check_type_tree(an->target, ALLOWED_TYPE_IN_LB,
ALLOWED_ENCLOSE_IN_LB_NOT, ALLOWED_ANCHOR_IN_LB_NOT);
if (r < 0) return r;
if (r > 0) return ONIGERR_INVALID_LOOK_BEHIND_PATTERN;
r = setup_look_behind(node, reg, env);
if (r != 0) return r;
r = setup_tree(an->target, reg, (state | IN_NOT), env);
}
break;
}
}
break;
default:
break;
}
return r;
}
/* set skip map for Boyer-Moor search */
static int
set_bm_skip(UChar* s, UChar* end, OnigEncoding enc ARG_UNUSED,
UChar skip[], int** int_skip)
{
int i, len;
len = end - s;
if (len < ONIG_CHAR_TABLE_SIZE) {
for (i = 0; i < ONIG_CHAR_TABLE_SIZE; i++) skip[i] = len;
for (i = 0; i < len - 1; i++)
skip[s[i]] = len - 1 - i;
}
else {
if (IS_NULL(*int_skip)) {
*int_skip = (int* )xmalloc(sizeof(int) * ONIG_CHAR_TABLE_SIZE);
if (IS_NULL(*int_skip)) return ONIGERR_MEMORY;
}
for (i = 0; i < ONIG_CHAR_TABLE_SIZE; i++) (*int_skip)[i] = len;
for (i = 0; i < len - 1; i++)
(*int_skip)[s[i]] = len - 1 - i;
}
return 0;
}
#define OPT_EXACT_MAXLEN 24
typedef struct {
OnigDistance min; /* min byte length */
OnigDistance max; /* max byte length */
} MinMaxLen;
typedef struct {
MinMaxLen mmd;
OnigEncoding enc;
OnigOptionType options;
OnigCaseFoldType case_fold_flag;
ScanEnv* scan_env;
} OptEnv;
typedef struct {
int left_anchor;
int right_anchor;
} OptAncInfo;
typedef struct {
MinMaxLen mmd; /* info position */
OptAncInfo anc;
int reach_end;
int ignore_case;
int len;
UChar s[OPT_EXACT_MAXLEN];
} OptExactInfo;
typedef struct {
MinMaxLen mmd; /* info position */
OptAncInfo anc;
int value; /* weighted value */
UChar map[ONIG_CHAR_TABLE_SIZE];
} OptMapInfo;
typedef struct {
MinMaxLen len;
OptAncInfo anc;
OptExactInfo exb; /* boundary */
OptExactInfo exm; /* middle */
OptExactInfo expr; /* prec read (?=...) */
OptMapInfo map; /* boundary */
} NodeOptInfo;
static int
map_position_value(OnigEncoding enc, int i)
{
static const short int ByteValTable[] = {
5, 1, 1, 1, 1, 1, 1, 1, 1, 10, 10, 1, 1, 10, 1, 1,
1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1,
12, 4, 7, 4, 4, 4, 4, 4, 4, 5, 5, 5, 5, 5, 5, 5,
6, 6, 6, 6, 6, 6, 6, 6, 6, 6, 5, 5, 5, 5, 5, 5,
5, 6, 6, 6, 6, 7, 6, 6, 6, 6, 6, 6, 6, 6, 6, 6,
6, 6, 6, 6, 6, 6, 6, 6, 6, 6, 6, 5, 6, 5, 5, 5,
5, 6, 6, 6, 6, 7, 6, 6, 6, 6, 6, 6, 6, 6, 6, 6,
6, 6, 6, 6, 6, 6, 6, 6, 6, 6, 6, 5, 5, 5, 5, 1
};
if (i < (int )(sizeof(ByteValTable)/sizeof(ByteValTable[0]))) {
if (i == 0 && ONIGENC_MBC_MINLEN(enc) > 1)
return 20;
else
return (int )ByteValTable[i];
}
else
return 4; /* Take it easy. */
}
static int
distance_value(MinMaxLen* mm)
{
/* 1000 / (min-max-dist + 1) */
static const short int dist_vals[] = {
1000, 500, 333, 250, 200, 167, 143, 125, 111, 100,
91, 83, 77, 71, 67, 63, 59, 56, 53, 50,
48, 45, 43, 42, 40, 38, 37, 36, 34, 33,
32, 31, 30, 29, 29, 28, 27, 26, 26, 25,
24, 24, 23, 23, 22, 22, 21, 21, 20, 20,
20, 19, 19, 19, 18, 18, 18, 17, 17, 17,
16, 16, 16, 16, 15, 15, 15, 15, 14, 14,
14, 14, 14, 14, 13, 13, 13, 13, 13, 13,
12, 12, 12, 12, 12, 12, 11, 11, 11, 11,
11, 11, 11, 11, 11, 10, 10, 10, 10, 10
};
int d;
if (mm->max == ONIG_INFINITE_DISTANCE) return 0;
d = mm->max - mm->min;
if (d < (int )(sizeof(dist_vals)/sizeof(dist_vals[0])))
/* return dist_vals[d] * 16 / (mm->min + 12); */
return (int )dist_vals[d];
else
return 1;
}
static int
comp_distance_value(MinMaxLen* d1, MinMaxLen* d2, int v1, int v2)
{
if (v2 <= 0) return -1;
if (v1 <= 0) return 1;
v1 *= distance_value(d1);
v2 *= distance_value(d2);
if (v2 > v1) return 1;
if (v2 < v1) return -1;
if (d2->min < d1->min) return 1;
if (d2->min > d1->min) return -1;
return 0;
}
static int
is_equal_mml(MinMaxLen* a, MinMaxLen* b)
{
return (a->min == b->min && a->max == b->max) ? 1 : 0;
}
static void
set_mml(MinMaxLen* mml, OnigDistance min, OnigDistance max)
{
mml->min = min;
mml->max = max;
}
static void
clear_mml(MinMaxLen* mml)
{
mml->min = mml->max = 0;
}
static void
copy_mml(MinMaxLen* to, MinMaxLen* from)
{
to->min = from->min;
to->max = from->max;
}
static void
add_mml(MinMaxLen* to, MinMaxLen* from)
{
to->min = distance_add(to->min, from->min);
to->max = distance_add(to->max, from->max);
}
#if 0
static void
add_len_mml(MinMaxLen* to, OnigDistance len)
{
to->min = distance_add(to->min, len);
to->max = distance_add(to->max, len);
}
#endif
static void
alt_merge_mml(MinMaxLen* to, MinMaxLen* from)
{
if (to->min > from->min) to->min = from->min;
if (to->max < from->max) to->max = from->max;
}
static void
copy_opt_env(OptEnv* to, OptEnv* from)
{
*to = *from;
}
static void
clear_opt_anc_info(OptAncInfo* anc)
{
anc->left_anchor = 0;
anc->right_anchor = 0;
}
static void
copy_opt_anc_info(OptAncInfo* to, OptAncInfo* from)
{
*to = *from;
}
static void
concat_opt_anc_info(OptAncInfo* to, OptAncInfo* left, OptAncInfo* right,
OnigDistance left_len, OnigDistance right_len)
{
clear_opt_anc_info(to);
to->left_anchor = left->left_anchor;
if (left_len == 0) {
to->left_anchor |= right->left_anchor;
}
to->right_anchor = right->right_anchor;
if (right_len == 0) {
to->right_anchor |= left->right_anchor;
}
}
static int
is_left_anchor(int anc)
{
if (anc == ANCHOR_END_BUF || anc == ANCHOR_SEMI_END_BUF ||
anc == ANCHOR_END_LINE || anc == ANCHOR_PREC_READ ||
anc == ANCHOR_PREC_READ_NOT)
return 0;
return 1;
}
static int
is_set_opt_anc_info(OptAncInfo* to, int anc)
{
if ((to->left_anchor & anc) != 0) return 1;
return ((to->right_anchor & anc) != 0 ? 1 : 0);
}
static void
add_opt_anc_info(OptAncInfo* to, int anc)
{
if (is_left_anchor(anc))
to->left_anchor |= anc;
else
to->right_anchor |= anc;
}
static void
remove_opt_anc_info(OptAncInfo* to, int anc)
{
if (is_left_anchor(anc))
to->left_anchor &= ~anc;
else
to->right_anchor &= ~anc;
}
static void
alt_merge_opt_anc_info(OptAncInfo* to, OptAncInfo* add)
{
to->left_anchor &= add->left_anchor;
to->right_anchor &= add->right_anchor;
}
static int
is_full_opt_exact_info(OptExactInfo* ex)
{
return (ex->len >= OPT_EXACT_MAXLEN ? 1 : 0);
}
static void
clear_opt_exact_info(OptExactInfo* ex)
{
clear_mml(&ex->mmd);
clear_opt_anc_info(&ex->anc);
ex->reach_end = 0;
ex->ignore_case = 0;
ex->len = 0;
ex->s[0] = '\0';
}
static void
copy_opt_exact_info(OptExactInfo* to, OptExactInfo* from)
{
*to = *from;
}
static void
concat_opt_exact_info(OptExactInfo* to, OptExactInfo* add, OnigEncoding enc)
{
int i, j, len;
UChar *p, *end;
OptAncInfo tanc;
if (! to->ignore_case && add->ignore_case) {
if (to->len >= add->len) return ; /* avoid */
to->ignore_case = 1;
}
p = add->s;
end = p + add->len;
for (i = to->len; p < end; ) {
len = enclen(enc, p, end);
if (i + len > OPT_EXACT_MAXLEN) break;
for (j = 0; j < len && p < end; j++)
to->s[i++] = *p++;
}
to->len = i;
to->reach_end = (p == end ? add->reach_end : 0);
concat_opt_anc_info(&tanc, &to->anc, &add->anc, 1, 1);
if (! to->reach_end) tanc.right_anchor = 0;
copy_opt_anc_info(&to->anc, &tanc);
}
static void
concat_opt_exact_info_str(OptExactInfo* to, UChar* s, UChar* end,
int raw ARG_UNUSED, OnigEncoding enc)
{
int i, j, len;
UChar *p;
for (i = to->len, p = s; p < end && i < OPT_EXACT_MAXLEN; ) {
len = enclen(enc, p, end);
if (i + len > OPT_EXACT_MAXLEN) break;
for (j = 0; j < len && p < end; j++)
to->s[i++] = *p++;
}
to->len = i;
}
static void
alt_merge_opt_exact_info(OptExactInfo* to, OptExactInfo* add, OptEnv* env)
{
int i, j, len;
if (add->len == 0 || to->len == 0) {
clear_opt_exact_info(to);
return ;
}
if (! is_equal_mml(&to->mmd, &add->mmd)) {
clear_opt_exact_info(to);
return ;
}
for (i = 0; i < to->len && i < add->len; ) {
if (to->s[i] != add->s[i]) break;
len = enclen(env->enc, to->s + i, to->s + to->len);
for (j = 1; j < len; j++) {
if (to->s[i+j] != add->s[i+j]) break;
}
if (j < len) break;
i += len;
}
if (! add->reach_end || i < add->len || i < to->len) {
to->reach_end = 0;
}
to->len = i;
to->ignore_case |= add->ignore_case;
alt_merge_opt_anc_info(&to->anc, &add->anc);
if (! to->reach_end) to->anc.right_anchor = 0;
}
static void
select_opt_exact_info(OnigEncoding enc, OptExactInfo* now, OptExactInfo* alt)
{
int v1, v2;
v1 = now->len;
v2 = alt->len;
if (v2 == 0) {
return ;
}
else if (v1 == 0) {
copy_opt_exact_info(now, alt);
return ;
}
else if (v1 <= 2 && v2 <= 2) {
/* ByteValTable[x] is big value --> low price */
v2 = map_position_value(enc, now->s[0]);
v1 = map_position_value(enc, alt->s[0]);
if (now->len > 1) v1 += 5;
if (alt->len > 1) v2 += 5;
}
if (now->ignore_case == 0) v1 *= 2;
if (alt->ignore_case == 0) v2 *= 2;
if (comp_distance_value(&now->mmd, &alt->mmd, v1, v2) > 0)
copy_opt_exact_info(now, alt);
}
static void
clear_opt_map_info(OptMapInfo* map)
{
static const OptMapInfo clean_info = {
{0, 0}, {0, 0}, 0,
{
0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0,
0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0,
0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0,
0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0,
0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0,
0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0,
0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0,
0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0,
0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0,
0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0,
0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0,
0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0,
0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0,
0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0,
0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0,
0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0
}
};
xmemcpy(map, &clean_info, sizeof(OptMapInfo));
}
static void
copy_opt_map_info(OptMapInfo* to, OptMapInfo* from)
{
*to = *from;
}
static void
add_char_opt_map_info(OptMapInfo* map, UChar c, OnigEncoding enc)
{
if (map->map[c] == 0) {
map->map[c] = 1;
map->value += map_position_value(enc, c);
}
}
static int
add_char_amb_opt_map_info(OptMapInfo* map, UChar* p, UChar* end,
OnigEncoding enc, OnigCaseFoldType case_fold_flag)
{
OnigCaseFoldCodeItem items[ONIGENC_GET_CASE_FOLD_CODES_MAX_NUM];
UChar buf[ONIGENC_CODE_TO_MBC_MAXLEN];
int i, n;
add_char_opt_map_info(map, p[0], enc);
case_fold_flag = DISABLE_CASE_FOLD_MULTI_CHAR(case_fold_flag);
n = ONIGENC_GET_CASE_FOLD_CODES_BY_STR(enc, case_fold_flag, p, end, items);
if (n < 0) return n;
for (i = 0; i < n; i++) {
ONIGENC_CODE_TO_MBC(enc, items[i].code[0], buf);
add_char_opt_map_info(map, buf[0], enc);
}
return 0;
}
static void
select_opt_map_info(OptMapInfo* now, OptMapInfo* alt)
{
const int z = 1<<15; /* 32768: something big value */
int v1, v2;
if (alt->value == 0) return ;
if (now->value == 0) {
copy_opt_map_info(now, alt);
return ;
}
v1 = z / now->value;
v2 = z / alt->value;
if (comp_distance_value(&now->mmd, &alt->mmd, v1, v2) > 0)
copy_opt_map_info(now, alt);
}
static int
comp_opt_exact_or_map_info(OptExactInfo* e, OptMapInfo* m)
{
#define COMP_EM_BASE 20
int ve, vm;
if (m->value <= 0) return -1;
ve = COMP_EM_BASE * e->len * (e->ignore_case ? 1 : 2);
vm = COMP_EM_BASE * 5 * 2 / m->value;
return comp_distance_value(&e->mmd, &m->mmd, ve, vm);
}
static void
alt_merge_opt_map_info(OnigEncoding enc, OptMapInfo* to, OptMapInfo* add)
{
int i, val;
/* if (! is_equal_mml(&to->mmd, &add->mmd)) return ; */
if (to->value == 0) return ;
if (add->value == 0 || to->mmd.max < add->mmd.min) {
clear_opt_map_info(to);
return ;
}
alt_merge_mml(&to->mmd, &add->mmd);
val = 0;
for (i = 0; i < ONIG_CHAR_TABLE_SIZE; i++) {
if (add->map[i])
to->map[i] = 1;
if (to->map[i])
val += map_position_value(enc, i);
}
to->value = val;
alt_merge_opt_anc_info(&to->anc, &add->anc);
}
static void
set_bound_node_opt_info(NodeOptInfo* opt, MinMaxLen* mmd)
{
copy_mml(&(opt->exb.mmd), mmd);
copy_mml(&(opt->expr.mmd), mmd);
copy_mml(&(opt->map.mmd), mmd);
}
static void
clear_node_opt_info(NodeOptInfo* opt)
{
clear_mml(&opt->len);
clear_opt_anc_info(&opt->anc);
clear_opt_exact_info(&opt->exb);
clear_opt_exact_info(&opt->exm);
clear_opt_exact_info(&opt->expr);
clear_opt_map_info(&opt->map);
}
static void
copy_node_opt_info(NodeOptInfo* to, NodeOptInfo* from)
{
*to = *from;
}
static void
concat_left_node_opt_info(OnigEncoding enc, NodeOptInfo* to, NodeOptInfo* add)
{
int exb_reach, exm_reach;
OptAncInfo tanc;
concat_opt_anc_info(&tanc, &to->anc, &add->anc, to->len.max, add->len.max);
copy_opt_anc_info(&to->anc, &tanc);
if (add->exb.len > 0 && to->len.max == 0) {
concat_opt_anc_info(&tanc, &to->anc, &add->exb.anc,
to->len.max, add->len.max);
copy_opt_anc_info(&add->exb.anc, &tanc);
}
if (add->map.value > 0 && to->len.max == 0) {
if (add->map.mmd.max == 0)
add->map.anc.left_anchor |= to->anc.left_anchor;
}
exb_reach = to->exb.reach_end;
exm_reach = to->exm.reach_end;
if (add->len.max != 0)
to->exb.reach_end = to->exm.reach_end = 0;
if (add->exb.len > 0) {
if (exb_reach) {
concat_opt_exact_info(&to->exb, &add->exb, enc);
clear_opt_exact_info(&add->exb);
}
else if (exm_reach) {
concat_opt_exact_info(&to->exm, &add->exb, enc);
clear_opt_exact_info(&add->exb);
}
}
select_opt_exact_info(enc, &to->exm, &add->exb);
select_opt_exact_info(enc, &to->exm, &add->exm);
if (to->expr.len > 0) {
if (add->len.max > 0) {
if (to->expr.len > (int )add->len.max)
to->expr.len = add->len.max;
if (to->expr.mmd.max == 0)
select_opt_exact_info(enc, &to->exb, &to->expr);
else
select_opt_exact_info(enc, &to->exm, &to->expr);
}
}
else if (add->expr.len > 0) {
copy_opt_exact_info(&to->expr, &add->expr);
}
select_opt_map_info(&to->map, &add->map);
add_mml(&to->len, &add->len);
}
static void
alt_merge_node_opt_info(NodeOptInfo* to, NodeOptInfo* add, OptEnv* env)
{
alt_merge_opt_anc_info (&to->anc, &add->anc);
alt_merge_opt_exact_info(&to->exb, &add->exb, env);
alt_merge_opt_exact_info(&to->exm, &add->exm, env);
alt_merge_opt_exact_info(&to->expr, &add->expr, env);
alt_merge_opt_map_info(env->enc, &to->map, &add->map);
alt_merge_mml(&to->len, &add->len);
}
#define MAX_NODE_OPT_INFO_REF_COUNT 5
static int
optimize_node_left(Node* node, NodeOptInfo* opt, OptEnv* env)
{
int type;
int r = 0;
clear_node_opt_info(opt);
set_bound_node_opt_info(opt, &env->mmd);
type = NTYPE(node);
switch (type) {
case NT_LIST:
{
OptEnv nenv;
NodeOptInfo nopt;
Node* nd = node;
copy_opt_env(&nenv, env);
do {
r = optimize_node_left(NCAR(nd), &nopt, &nenv);
if (r == 0) {
add_mml(&nenv.mmd, &nopt.len);
concat_left_node_opt_info(env->enc, opt, &nopt);
}
} while (r == 0 && IS_NOT_NULL(nd = NCDR(nd)));
}
break;
case NT_ALT:
{
NodeOptInfo nopt;
Node* nd = node;
do {
r = optimize_node_left(NCAR(nd), &nopt, env);
if (r == 0) {
if (nd == node) copy_node_opt_info(opt, &nopt);
else alt_merge_node_opt_info(opt, &nopt, env);
}
} while ((r == 0) && IS_NOT_NULL(nd = NCDR(nd)));
}
break;
case NT_STR:
{
StrNode* sn = NSTR(node);
int slen = sn->end - sn->s;
int is_raw = NSTRING_IS_RAW(node);
if (! NSTRING_IS_AMBIG(node)) {
concat_opt_exact_info_str(&opt->exb, sn->s, sn->end,
NSTRING_IS_RAW(node), env->enc);
if (slen > 0) {
add_char_opt_map_info(&opt->map, *(sn->s), env->enc);
}
set_mml(&opt->len, slen, slen);
}
else {
int max;
if (NSTRING_IS_DONT_GET_OPT_INFO(node)) {
int n = onigenc_strlen(env->enc, sn->s, sn->end);
max = ONIGENC_MBC_MAXLEN_DIST(env->enc) * n;
}
else {
concat_opt_exact_info_str(&opt->exb, sn->s, sn->end,
is_raw, env->enc);
opt->exb.ignore_case = 1;
if (slen > 0) {
r = add_char_amb_opt_map_info(&opt->map, sn->s, sn->end,
env->enc, env->case_fold_flag);
if (r != 0) break;
}
max = slen;
}
set_mml(&opt->len, slen, max);
}
if (opt->exb.len == slen)
opt->exb.reach_end = 1;
}
break;
case NT_CCLASS:
{
int i, z;
CClassNode* cc = NCCLASS(node);
/* no need to check ignore case. (setted in setup_tree()) */
if (IS_NOT_NULL(cc->mbuf) || IS_NCCLASS_NOT(cc)) {
OnigDistance min = ONIGENC_MBC_MINLEN(env->enc);
OnigDistance max = ONIGENC_MBC_MAXLEN_DIST(env->enc);
set_mml(&opt->len, min, max);
}
else {
for (i = 0; i < SINGLE_BYTE_SIZE; i++) {
z = BITSET_AT(cc->bs, i);
if ((z && !IS_NCCLASS_NOT(cc)) || (!z && IS_NCCLASS_NOT(cc))) {
add_char_opt_map_info(&opt->map, (UChar )i, env->enc);
}
}
set_mml(&opt->len, 1, 1);
}
}
break;
case NT_CTYPE:
{
int i, min, max;
max = ONIGENC_MBC_MAXLEN_DIST(env->enc);
if (max == 1) {
min = 1;
switch (NCTYPE(node)->ctype) {
case ONIGENC_CTYPE_WORD:
if (NCTYPE(node)->not != 0) {
for (i = 0; i < SINGLE_BYTE_SIZE; i++) {
if (! ONIGENC_IS_CODE_WORD(env->enc, i)) {
add_char_opt_map_info(&opt->map, (UChar )i, env->enc);
}
}
}
else {
for (i = 0; i < SINGLE_BYTE_SIZE; i++) {
if (ONIGENC_IS_CODE_WORD(env->enc, i)) {
add_char_opt_map_info(&opt->map, (UChar )i, env->enc);
}
}
}
break;
}
}
else {
min = ONIGENC_MBC_MINLEN(env->enc);
}
set_mml(&opt->len, min, max);
}
break;
case NT_CANY:
{
OnigDistance min = ONIGENC_MBC_MINLEN(env->enc);
OnigDistance max = ONIGENC_MBC_MAXLEN_DIST(env->enc);
set_mml(&opt->len, min, max);
}
break;
case NT_ANCHOR:
switch (NANCHOR(node)->type) {
case ANCHOR_BEGIN_BUF:
case ANCHOR_BEGIN_POSITION:
case ANCHOR_BEGIN_LINE:
case ANCHOR_END_BUF:
case ANCHOR_SEMI_END_BUF:
case ANCHOR_END_LINE:
add_opt_anc_info(&opt->anc, NANCHOR(node)->type);
break;
case ANCHOR_PREC_READ:
{
NodeOptInfo nopt;
r = optimize_node_left(NANCHOR(node)->target, &nopt, env);
if (r == 0) {
if (nopt.exb.len > 0)
copy_opt_exact_info(&opt->expr, &nopt.exb);
else if (nopt.exm.len > 0)
copy_opt_exact_info(&opt->expr, &nopt.exm);
opt->expr.reach_end = 0;
if (nopt.map.value > 0)
copy_opt_map_info(&opt->map, &nopt.map);
}
}
break;
case ANCHOR_PREC_READ_NOT:
case ANCHOR_LOOK_BEHIND: /* Sorry, I can't make use of it. */
case ANCHOR_LOOK_BEHIND_NOT:
break;
}
break;
case NT_BREF:
{
int i;
int* backs;
OnigDistance min, max, tmin, tmax;
Node** nodes = SCANENV_MEM_NODES(env->scan_env);
BRefNode* br = NBREF(node);
if (br->state & NST_RECURSION) {
set_mml(&opt->len, 0, ONIG_INFINITE_DISTANCE);
break;
}
backs = BACKREFS_P(br);
r = get_min_match_length(nodes[backs[0]], &min, env->scan_env);
if (r != 0) break;
r = get_max_match_length(nodes[backs[0]], &max, env->scan_env);
if (r != 0) break;
for (i = 1; i < br->back_num; i++) {
r = get_min_match_length(nodes[backs[i]], &tmin, env->scan_env);
if (r != 0) break;
r = get_max_match_length(nodes[backs[i]], &tmax, env->scan_env);
if (r != 0) break;
if (min > tmin) min = tmin;
if (max < tmax) max = tmax;
}
if (r == 0) set_mml(&opt->len, min, max);
}
break;
#ifdef USE_SUBEXP_CALL
case NT_CALL:
if (IS_CALL_RECURSION(NCALL(node)))
set_mml(&opt->len, 0, ONIG_INFINITE_DISTANCE);
else {
OnigOptionType save = env->options;
env->options = NENCLOSE(NCALL(node)->target)->option;
r = optimize_node_left(NCALL(node)->target, opt, env);
env->options = save;
}
break;
#endif
case NT_QTFR:
{
int i;
OnigDistance min, max;
NodeOptInfo nopt;
QtfrNode* qn = NQTFR(node);
r = optimize_node_left(qn->target, &nopt, env);
if (r) break;
if (qn->lower == 0 && IS_REPEAT_INFINITE(qn->upper)) {
if (env->mmd.max == 0 &&
NTYPE(qn->target) == NT_CANY && qn->greedy) {
if (IS_MULTILINE(env->options))
add_opt_anc_info(&opt->anc, ANCHOR_ANYCHAR_STAR_ML);
else
add_opt_anc_info(&opt->anc, ANCHOR_ANYCHAR_STAR);
}
}
else {
if (qn->lower > 0) {
copy_node_opt_info(opt, &nopt);
if (nopt.exb.len > 0) {
if (nopt.exb.reach_end) {
for (i = 2; i < qn->lower &&
! is_full_opt_exact_info(&opt->exb); i++) {
concat_opt_exact_info(&opt->exb, &nopt.exb, env->enc);
}
if (i < qn->lower) {
opt->exb.reach_end = 0;
}
}
}
if (qn->lower != qn->upper) {
opt->exb.reach_end = 0;
opt->exm.reach_end = 0;
}
if (qn->lower > 1)
opt->exm.reach_end = 0;
}
}
min = distance_multiply(nopt.len.min, qn->lower);
if (IS_REPEAT_INFINITE(qn->upper))
max = (nopt.len.max > 0 ? ONIG_INFINITE_DISTANCE : 0);
else
max = distance_multiply(nopt.len.max, qn->upper);
set_mml(&opt->len, min, max);
}
break;
case NT_ENCLOSE:
{
EncloseNode* en = NENCLOSE(node);
switch (en->type) {
case ENCLOSE_OPTION:
{
OnigOptionType save = env->options;
env->options = en->option;
r = optimize_node_left(en->target, opt, env);
env->options = save;
}
break;
case ENCLOSE_MEMORY:
#ifdef USE_SUBEXP_CALL
en->opt_count++;
if (en->opt_count > MAX_NODE_OPT_INFO_REF_COUNT) {
OnigDistance min, max;
min = 0;
max = ONIG_INFINITE_DISTANCE;
if (IS_ENCLOSE_MIN_FIXED(en)) min = en->min_len;
if (IS_ENCLOSE_MAX_FIXED(en)) max = en->max_len;
set_mml(&opt->len, min, max);
}
else
#endif
{
r = optimize_node_left(en->target, opt, env);
if (is_set_opt_anc_info(&opt->anc, ANCHOR_ANYCHAR_STAR_MASK)) {
if (BIT_STATUS_AT(env->scan_env->backrefed_mem, en->regnum))
remove_opt_anc_info(&opt->anc, ANCHOR_ANYCHAR_STAR_MASK);
}
}
break;
case ENCLOSE_STOP_BACKTRACK:
r = optimize_node_left(en->target, opt, env);
break;
}
}
break;
default:
#ifdef ONIG_DEBUG
fprintf(stderr, "optimize_node_left: undefined node type %d\n",
NTYPE(node));
#endif
r = ONIGERR_TYPE_BUG;
break;
}
return r;
}
static int
set_optimize_exact_info(regex_t* reg, OptExactInfo* e)
{
int r;
if (e->len == 0) return 0;
if (e->ignore_case) {
reg->exact = (UChar* )xmalloc(e->len);
CHECK_NULL_RETURN_MEMERR(reg->exact);
xmemcpy(reg->exact, e->s, e->len);
reg->exact_end = reg->exact + e->len;
reg->optimize = ONIG_OPTIMIZE_EXACT_IC;
}
else {
int allow_reverse;
reg->exact = str_dup(e->s, e->s + e->len);
CHECK_NULL_RETURN_MEMERR(reg->exact);
reg->exact_end = reg->exact + e->len;
allow_reverse =
ONIGENC_IS_ALLOWED_REVERSE_MATCH(reg->enc, reg->exact, reg->exact_end);
if (e->len >= 3 || (e->len >= 2 && allow_reverse)) {
r = set_bm_skip(reg->exact, reg->exact_end, reg->enc,
reg->map, &(reg->int_map));
if (r) return r;
reg->optimize = (allow_reverse != 0
? ONIG_OPTIMIZE_EXACT_BM : ONIG_OPTIMIZE_EXACT_BM_NOT_REV);
}
else {
reg->optimize = ONIG_OPTIMIZE_EXACT;
}
}
reg->dmin = e->mmd.min;
reg->dmax = e->mmd.max;
if (reg->dmin != ONIG_INFINITE_DISTANCE) {
reg->threshold_len = reg->dmin + (reg->exact_end - reg->exact);
}
return 0;
}
static void
set_optimize_map_info(regex_t* reg, OptMapInfo* m)
{
int i;
for (i = 0; i < ONIG_CHAR_TABLE_SIZE; i++)
reg->map[i] = m->map[i];
reg->optimize = ONIG_OPTIMIZE_MAP;
reg->dmin = m->mmd.min;
reg->dmax = m->mmd.max;
if (reg->dmin != ONIG_INFINITE_DISTANCE) {
reg->threshold_len = reg->dmin + 1;
}
}
static void
set_sub_anchor(regex_t* reg, OptAncInfo* anc)
{
reg->sub_anchor |= anc->left_anchor & ANCHOR_BEGIN_LINE;
reg->sub_anchor |= anc->right_anchor & ANCHOR_END_LINE;
}
#ifdef ONIG_DEBUG
static void print_optimize_info(FILE* f, regex_t* reg);
#endif
static int
set_optimize_info_from_tree(Node* node, regex_t* reg, ScanEnv* scan_env)
{
int r;
NodeOptInfo opt;
OptEnv env;
env.enc = reg->enc;
env.options = reg->options;
env.case_fold_flag = reg->case_fold_flag;
env.scan_env = scan_env;
clear_mml(&env.mmd);
r = optimize_node_left(node, &opt, &env);
if (r) return r;
reg->anchor = opt.anc.left_anchor & (ANCHOR_BEGIN_BUF |
ANCHOR_BEGIN_POSITION | ANCHOR_ANYCHAR_STAR | ANCHOR_ANYCHAR_STAR_ML);
reg->anchor |= opt.anc.right_anchor & (ANCHOR_END_BUF | ANCHOR_SEMI_END_BUF);
if (reg->anchor & (ANCHOR_END_BUF | ANCHOR_SEMI_END_BUF)) {
reg->anchor_dmin = opt.len.min;
reg->anchor_dmax = opt.len.max;
}
if (opt.exb.len > 0 || opt.exm.len > 0) {
select_opt_exact_info(reg->enc, &opt.exb, &opt.exm);
if (opt.map.value > 0 &&
comp_opt_exact_or_map_info(&opt.exb, &opt.map) > 0) {
goto set_map;
}
else {
r = set_optimize_exact_info(reg, &opt.exb);
set_sub_anchor(reg, &opt.exb.anc);
}
}
else if (opt.map.value > 0) {
set_map:
set_optimize_map_info(reg, &opt.map);
set_sub_anchor(reg, &opt.map.anc);
}
else {
reg->sub_anchor |= opt.anc.left_anchor & ANCHOR_BEGIN_LINE;
if (opt.len.max == 0)
reg->sub_anchor |= opt.anc.right_anchor & ANCHOR_END_LINE;
}
#if defined(ONIG_DEBUG_COMPILE) || defined(ONIG_DEBUG_MATCH)
print_optimize_info(stderr, reg);
#endif
return r;
}
static void
clear_optimize_info(regex_t* reg)
{
reg->optimize = ONIG_OPTIMIZE_NONE;
reg->anchor = 0;
reg->anchor_dmin = 0;
reg->anchor_dmax = 0;
reg->sub_anchor = 0;
reg->exact_end = (UChar* )NULL;
reg->threshold_len = 0;
if (IS_NOT_NULL(reg->exact)) {
xfree(reg->exact);
reg->exact = (UChar* )NULL;
}
}
#ifdef ONIG_DEBUG
static void print_enc_string(FILE* fp, OnigEncoding enc,
const UChar *s, const UChar *end)
{
fprintf(fp, "\nPATTERN: /");
if (ONIGENC_MBC_MINLEN(enc) > 1) {
const UChar *p;
OnigCodePoint code;
p = s;
while (p < end) {
code = ONIGENC_MBC_TO_CODE(enc, p, end);
if (code >= 0x80) {
fprintf(fp, " 0x%04x ", (int )code);
}
else {
fputc((int )code, fp);
}
p += enclen(enc, p);
}
}
else {
while (s < end) {
fputc((int )*s, fp);
s++;
}
}
fprintf(fp, "/\n");
}
static void
print_distance_range(FILE* f, OnigDistance a, OnigDistance b)
{
if (a == ONIG_INFINITE_DISTANCE)
fputs("inf", f);
else
fprintf(f, "(%u)", a);
fputs("-", f);
if (b == ONIG_INFINITE_DISTANCE)
fputs("inf", f);
else
fprintf(f, "(%u)", b);
}
static void
print_anchor(FILE* f, int anchor)
{
int q = 0;
fprintf(f, "[");
if (anchor & ANCHOR_BEGIN_BUF) {
fprintf(f, "begin-buf");
q = 1;
}
if (anchor & ANCHOR_BEGIN_LINE) {
if (q) fprintf(f, ", ");
q = 1;
fprintf(f, "begin-line");
}
if (anchor & ANCHOR_BEGIN_POSITION) {
if (q) fprintf(f, ", ");
q = 1;
fprintf(f, "begin-pos");
}
if (anchor & ANCHOR_END_BUF) {
if (q) fprintf(f, ", ");
q = 1;
fprintf(f, "end-buf");
}
if (anchor & ANCHOR_SEMI_END_BUF) {
if (q) fprintf(f, ", ");
q = 1;
fprintf(f, "semi-end-buf");
}
if (anchor & ANCHOR_END_LINE) {
if (q) fprintf(f, ", ");
q = 1;
fprintf(f, "end-line");
}
if (anchor & ANCHOR_ANYCHAR_STAR) {
if (q) fprintf(f, ", ");
q = 1;
fprintf(f, "anychar-star");
}
if (anchor & ANCHOR_ANYCHAR_STAR_ML) {
if (q) fprintf(f, ", ");
fprintf(f, "anychar-star-pl");
}
fprintf(f, "]");
}
static void
print_optimize_info(FILE* f, regex_t* reg)
{
static const char* on[] = { "NONE", "EXACT", "EXACT_BM", "EXACT_BM_NOT_REV",
"EXACT_IC", "MAP" };
fprintf(f, "optimize: %s\n", on[reg->optimize]);
fprintf(f, " anchor: "); print_anchor(f, reg->anchor);
if ((reg->anchor & ANCHOR_END_BUF_MASK) != 0)
print_distance_range(f, reg->anchor_dmin, reg->anchor_dmax);
fprintf(f, "\n");
if (reg->optimize) {
fprintf(f, " sub anchor: "); print_anchor(f, reg->sub_anchor);
fprintf(f, "\n");
}
fprintf(f, "\n");
if (reg->exact) {
UChar *p;
fprintf(f, "exact: [");
for (p = reg->exact; p < reg->exact_end; p++) {
fputc(*p, f);
}
fprintf(f, "]: length: %d\n", (reg->exact_end - reg->exact));
}
else if (reg->optimize & ONIG_OPTIMIZE_MAP) {
int c, i, n = 0;
for (i = 0; i < ONIG_CHAR_TABLE_SIZE; i++)
if (reg->map[i]) n++;
fprintf(f, "map: n=%d\n", n);
if (n > 0) {
c = 0;
fputc('[', f);
for (i = 0; i < ONIG_CHAR_TABLE_SIZE; i++) {
if (reg->map[i] != 0) {
if (c > 0) fputs(", ", f);
c++;
if (ONIGENC_MBC_MAXLEN(reg->enc) == 1 &&
ONIGENC_IS_CODE_PRINT(reg->enc, (OnigCodePoint )i))
fputc(i, f);
else
fprintf(f, "%d", i);
}
}
fprintf(f, "]\n");
}
}
}
#endif /* ONIG_DEBUG */
static void
onig_free_body(regex_t* reg)
{
if (IS_NOT_NULL(reg->p)) xfree(reg->p);
if (IS_NOT_NULL(reg->exact)) xfree(reg->exact);
if (IS_NOT_NULL(reg->int_map)) xfree(reg->int_map);
if (IS_NOT_NULL(reg->int_map_backward)) xfree(reg->int_map_backward);
if (IS_NOT_NULL(reg->repeat_range)) xfree(reg->repeat_range);
if (IS_NOT_NULL(reg->chain)) onig_free(reg->chain);
#ifdef USE_NAMED_GROUP
onig_names_free(reg);
#endif
}
extern void
onig_free(regex_t* reg)
{
if (IS_NOT_NULL(reg)) {
onig_free_body(reg);
xfree(reg);
}
}
#define REGEX_TRANSFER(to,from) do {\
(to)->state = ONIG_STATE_MODIFY;\
onig_free_body(to);\
xmemcpy(to, from, sizeof(regex_t));\
xfree(from);\
} while (0)
extern void
onig_transfer(regex_t* to, regex_t* from)
{
THREAD_ATOMIC_START;
REGEX_TRANSFER(to, from);
THREAD_ATOMIC_END;
}
#define REGEX_CHAIN_HEAD(reg) do {\
while (IS_NOT_NULL((reg)->chain)) {\
(reg) = (reg)->chain;\
}\
} while (0)
extern void
onig_chain_link_add(regex_t* to, regex_t* add)
{
THREAD_ATOMIC_START;
REGEX_CHAIN_HEAD(to);
to->chain = add;
THREAD_ATOMIC_END;
}
extern void
onig_chain_reduce(regex_t* reg)
{
regex_t *head, *prev;
prev = reg;
head = prev->chain;
if (IS_NOT_NULL(head)) {
reg->state = ONIG_STATE_MODIFY;
while (IS_NOT_NULL(head->chain)) {
prev = head;
head = head->chain;
}
prev->chain = (regex_t* )NULL;
REGEX_TRANSFER(reg, head);
}
}
#if 0
extern int
onig_clone(regex_t** to, regex_t* from)
{
int r, size;
regex_t* reg;
#ifdef USE_MULTI_THREAD_SYSTEM
if (ONIG_STATE(from) >= ONIG_STATE_NORMAL) {
ONIG_STATE_INC(from);
if (IS_NOT_NULL(from->chain) && ONIG_STATE(reg) == ONIG_STATE_NORMAL) {
onig_chain_reduce(from);
ONIG_STATE_INC(from);
}
}
else {
int n = 0;
while (ONIG_STATE(from) < ONIG_STATE_NORMAL) {
if (++n > THREAD_PASS_LIMIT_COUNT)
return ONIGERR_OVER_THREAD_PASS_LIMIT_COUNT;
THREAD_PASS;
}
ONIG_STATE_INC(from);
}
#endif /* USE_MULTI_THREAD_SYSTEM */
r = onig_alloc_init(®, ONIG_OPTION_NONE, ONIGENC_CASE_FOLD_DEFAULT,
from->enc, ONIG_SYNTAX_DEFAULT);
if (r != 0) {
ONIG_STATE_DEC(from);
return r;
}
xmemcpy(reg, from, sizeof(onig_t));
reg->chain = (regex_t* )NULL;
reg->state = ONIG_STATE_NORMAL;
if (from->p) {
reg->p = (UChar* )xmalloc(reg->alloc);
if (IS_NULL(reg->p)) goto mem_error;
xmemcpy(reg->p, from->p, reg->alloc);
}
if (from->exact) {
reg->exact = (UChar* )xmalloc(from->exact_end - from->exact);
if (IS_NULL(reg->exact)) goto mem_error;
reg->exact_end = reg->exact + (from->exact_end - from->exact);
xmemcpy(reg->exact, from->exact, reg->exact_end - reg->exact);
}
if (from->int_map) {
size = sizeof(int) * ONIG_CHAR_TABLE_SIZE;
reg->int_map = (int* )xmalloc(size);
if (IS_NULL(reg->int_map)) goto mem_error;
xmemcpy(reg->int_map, from->int_map, size);
}
if (from->int_map_backward) {
size = sizeof(int) * ONIG_CHAR_TABLE_SIZE;
reg->int_map_backward = (int* )xmalloc(size);
if (IS_NULL(reg->int_map_backward)) goto mem_error;
xmemcpy(reg->int_map_backward, from->int_map_backward, size);
}
#ifdef USE_NAMED_GROUP
reg->name_table = names_clone(from); /* names_clone is not implemented */
#endif
ONIG_STATE_DEC(from);
*to = reg;
return 0;
mem_error:
ONIG_STATE_DEC(from);
return ONIGERR_MEMORY;
}
#endif
#ifdef ONIG_DEBUG
static void print_compiled_byte_code_list P_((FILE* f, regex_t* reg));
#endif
#ifdef ONIG_DEBUG_PARSE_TREE
static void print_tree P_((FILE* f, Node* node));
#endif
extern int
onig_compile(regex_t* reg, const UChar* pattern, const UChar* pattern_end,
OnigErrorInfo* einfo)
{
#define COMPILE_INIT_SIZE 20
int r, init_size;
Node* root;
ScanEnv scan_env;
#ifdef USE_SUBEXP_CALL
UnsetAddrList uslist;
#endif
reg->state = ONIG_STATE_COMPILING;
#ifdef ONIG_DEBUG
print_enc_string(stderr, reg->enc, pattern, pattern_end);
#endif
if (reg->alloc == 0) {
init_size = (pattern_end - pattern) * 2;
if (init_size <= 0) init_size = COMPILE_INIT_SIZE;
r = BBUF_INIT(reg, init_size);
if (r != 0) goto end;
}
else
reg->used = 0;
reg->num_mem = 0;
reg->num_repeat = 0;
reg->num_null_check = 0;
reg->repeat_range_alloc = 0;
reg->repeat_range = (OnigRepeatRange* )NULL;
#ifdef USE_COMBINATION_EXPLOSION_CHECK
reg->num_comb_exp_check = 0;
#endif
r = onig_parse_make_tree(&root, pattern, pattern_end, reg, &scan_env);
if (r != 0) goto err;
#ifdef USE_NAMED_GROUP
/* mixed use named group and no-named group */
if (scan_env.num_named > 0 &&
IS_SYNTAX_BV(scan_env.syntax, ONIG_SYN_CAPTURE_ONLY_NAMED_GROUP) &&
!ONIG_IS_OPTION_ON(reg->options, ONIG_OPTION_CAPTURE_GROUP)) {
if (scan_env.num_named != scan_env.num_mem)
r = disable_noname_group_capture(&root, reg, &scan_env);
else
r = numbered_ref_check(root);
if (r != 0) goto err;
}
#endif
#ifdef USE_SUBEXP_CALL
if (scan_env.num_call > 0) {
r = unset_addr_list_init(&uslist, scan_env.num_call);
if (r != 0) goto err;
scan_env.unset_addr_list = &uslist;
r = setup_subexp_call(root, &scan_env);
if (r != 0) goto err_unset;
r = subexp_recursive_check_trav(root, &scan_env);
if (r < 0) goto err_unset;
r = subexp_inf_recursive_check_trav(root, &scan_env);
if (r != 0) goto err_unset;
reg->num_call = scan_env.num_call;
}
else
reg->num_call = 0;
#endif
r = setup_tree(root, reg, 0, &scan_env);
if (r != 0) goto err_unset;
#ifdef ONIG_DEBUG_PARSE_TREE
print_tree(stderr, root);
#endif
reg->capture_history = scan_env.capture_history;
reg->bt_mem_start = scan_env.bt_mem_start;
reg->bt_mem_start |= reg->capture_history;
if (IS_FIND_CONDITION(reg->options))
BIT_STATUS_ON_ALL(reg->bt_mem_end);
else {
reg->bt_mem_end = scan_env.bt_mem_end;
reg->bt_mem_end |= reg->capture_history;
}
#ifdef USE_COMBINATION_EXPLOSION_CHECK
if (scan_env.backrefed_mem == 0
#ifdef USE_SUBEXP_CALL
|| scan_env.num_call == 0
#endif
) {
setup_comb_exp_check(root, 0, &scan_env);
#ifdef USE_SUBEXP_CALL
if (scan_env.has_recursion != 0) {
scan_env.num_comb_exp_check = 0;
}
else
#endif
if (scan_env.comb_exp_max_regnum > 0) {
int i;
for (i = 1; i <= scan_env.comb_exp_max_regnum; i++) {
if (BIT_STATUS_AT(scan_env.backrefed_mem, i) != 0) {
scan_env.num_comb_exp_check = 0;
break;
}
}
}
}
reg->num_comb_exp_check = scan_env.num_comb_exp_check;
#endif
clear_optimize_info(reg);
#ifndef ONIG_DONT_OPTIMIZE
r = set_optimize_info_from_tree(root, reg, &scan_env);
if (r != 0) goto err_unset;
#endif
if (IS_NOT_NULL(scan_env.mem_nodes_dynamic)) {
xfree(scan_env.mem_nodes_dynamic);
scan_env.mem_nodes_dynamic = (Node** )NULL;
}
r = compile_tree(root, reg);
if (r == 0) {
r = add_opcode(reg, OP_END);
#ifdef USE_SUBEXP_CALL
if (scan_env.num_call > 0) {
r = unset_addr_list_fix(&uslist, reg);
unset_addr_list_end(&uslist);
if (r) goto err;
}
#endif
if ((reg->num_repeat != 0) || (reg->bt_mem_end != 0))
reg->stack_pop_level = STACK_POP_LEVEL_ALL;
else {
if (reg->bt_mem_start != 0)
reg->stack_pop_level = STACK_POP_LEVEL_MEM_START;
else
reg->stack_pop_level = STACK_POP_LEVEL_FREE;
}
}
#ifdef USE_SUBEXP_CALL
else if (scan_env.num_call > 0) {
unset_addr_list_end(&uslist);
}
#endif
onig_node_free(root);
#ifdef ONIG_DEBUG_COMPILE
#ifdef USE_NAMED_GROUP
onig_print_names(stderr, reg);
#endif
print_compiled_byte_code_list(stderr, reg);
#endif
end:
reg->state = ONIG_STATE_NORMAL;
return r;
err_unset:
#ifdef USE_SUBEXP_CALL
if (scan_env.num_call > 0) {
unset_addr_list_end(&uslist);
}
#endif
err:
if (IS_NOT_NULL(scan_env.error)) {
if (IS_NOT_NULL(einfo)) {
einfo->enc = scan_env.enc;
einfo->par = scan_env.error;
einfo->par_end = scan_env.error_end;
}
}
onig_node_free(root);
if (IS_NOT_NULL(scan_env.mem_nodes_dynamic))
xfree(scan_env.mem_nodes_dynamic);
return r;
}
#ifdef USE_RECOMPILE_API
extern int
onig_recompile(regex_t* reg, const UChar* pattern, const UChar* pattern_end,
OnigOptionType option, OnigEncoding enc, OnigSyntaxType* syntax,
OnigErrorInfo* einfo)
{
int r;
regex_t *new_reg;
r = onig_new(&new_reg, pattern, pattern_end, option, enc, syntax, einfo);
if (r) return r;
if (ONIG_STATE(reg) == ONIG_STATE_NORMAL) {
onig_transfer(reg, new_reg);
}
else {
onig_chain_link_add(reg, new_reg);
}
return 0;
}
#endif
static int onig_inited = 0;
extern int
onig_alloc_init(regex_t** reg, OnigOptionType option,
OnigCaseFoldType case_fold_flag,
OnigEncoding enc, const OnigSyntaxType* syntax)
{
if (! onig_inited)
onig_init();
if (ONIGENC_IS_UNDEF(enc))
return ONIGERR_DEFAULT_ENCODING_IS_NOT_SETTED;
if ((option & (ONIG_OPTION_DONT_CAPTURE_GROUP|ONIG_OPTION_CAPTURE_GROUP))
== (ONIG_OPTION_DONT_CAPTURE_GROUP|ONIG_OPTION_CAPTURE_GROUP)) {
return ONIGERR_INVALID_COMBINATION_OF_OPTIONS;
}
*reg = (regex_t* )xmalloc(sizeof(regex_t));
if (IS_NULL(*reg)) return ONIGERR_MEMORY;
(*reg)->state = ONIG_STATE_MODIFY;
if ((option & ONIG_OPTION_NEGATE_SINGLELINE) != 0) {
option |= syntax->options;
option &= ~ONIG_OPTION_SINGLELINE;
}
else
option |= syntax->options;
(*reg)->enc = enc;
(*reg)->options = option;
(*reg)->syntax = syntax;
(*reg)->optimize = 0;
(*reg)->exact = (UChar* )NULL;
(*reg)->int_map = (int* )NULL;
(*reg)->int_map_backward = (int* )NULL;
(*reg)->chain = (regex_t* )NULL;
(*reg)->p = (UChar* )NULL;
(*reg)->alloc = 0;
(*reg)->used = 0;
(*reg)->name_table = (void* )NULL;
(*reg)->case_fold_flag = case_fold_flag;
return 0;
}
extern int
onig_new(regex_t** reg, const UChar* pattern, const UChar* pattern_end,
OnigOptionType option, OnigEncoding enc, const OnigSyntaxType* syntax,
OnigErrorInfo* einfo)
{
int r;
if (IS_NOT_NULL(einfo)) einfo->par = (UChar* )NULL;
r = onig_alloc_init(reg, option, ONIGENC_CASE_FOLD_DEFAULT,
enc, syntax);
if (r) return r;
r = onig_compile(*reg, pattern, pattern_end, einfo);
if (r) {
onig_free(*reg);
*reg = NULL;
}
return r;
}
extern int
onig_init(void)
{
if (onig_inited != 0)
return 0;
THREAD_SYSTEM_INIT;
THREAD_ATOMIC_START;
onig_inited = 1;
onigenc_init();
/* onigenc_set_default_caseconv_table((UChar* )0); */
#ifdef ONIG_DEBUG_STATISTICS
onig_statistics_init();
#endif
THREAD_ATOMIC_END;
return 0;
}
extern int
onig_end(void)
{
THREAD_ATOMIC_START;
#ifdef ONIG_DEBUG_STATISTICS
onig_print_statistics(stderr);
#endif
#ifdef USE_SHARED_CCLASS_TABLE
onig_free_shared_cclass_table();
#endif
#ifdef USE_PARSE_TREE_NODE_RECYCLE
onig_free_node_list();
#endif
onig_inited = 0;
THREAD_ATOMIC_END;
THREAD_SYSTEM_END;
return 0;
}
extern int
onig_is_in_code_range(const UChar* p, OnigCodePoint code)
{
OnigCodePoint n, *data;
OnigCodePoint low, high, x;
GET_CODE_POINT(n, p);
data = (OnigCodePoint* )p;
data++;
for (low = 0, high = n; low < high; ) {
x = (low + high) >> 1;
if (code > data[x * 2 + 1])
low = x + 1;
else
high = x;
}
return ((low < n && code >= data[low * 2]) ? 1 : 0);
}
extern int
onig_is_code_in_cc_len(int elen, OnigCodePoint code, CClassNode* cc)
{
int found;
if (elen > 1 || (code >= SINGLE_BYTE_SIZE)) {
if (IS_NULL(cc->mbuf)) {
found = 0;
}
else {
found = (onig_is_in_code_range(cc->mbuf->p, code) != 0 ? 1 : 0);
}
}
else {
found = (BITSET_AT(cc->bs, code) == 0 ? 0 : 1);
}
if (IS_NCCLASS_NOT(cc))
return !found;
else
return found;
}
extern int
onig_is_code_in_cc(OnigEncoding enc, OnigCodePoint code, CClassNode* cc)
{
int len;
if (ONIGENC_MBC_MINLEN(enc) > 1) {
len = 2;
}
else {
len = ONIGENC_CODE_TO_MBCLEN(enc, code);
}
return onig_is_code_in_cc_len(len, code, cc);
}
#ifdef ONIG_DEBUG
/* arguments type */
#define ARG_SPECIAL -1
#define ARG_NON 0
#define ARG_RELADDR 1
#define ARG_ABSADDR 2
#define ARG_LENGTH 3
#define ARG_MEMNUM 4
#define ARG_OPTION 5
#define ARG_STATE_CHECK 6
OnigOpInfoType OnigOpInfo[] = {
{ OP_FINISH, "finish", ARG_NON },
{ OP_END, "end", ARG_NON },
{ OP_EXACT1, "exact1", ARG_SPECIAL },
{ OP_EXACT2, "exact2", ARG_SPECIAL },
{ OP_EXACT3, "exact3", ARG_SPECIAL },
{ OP_EXACT4, "exact4", ARG_SPECIAL },
{ OP_EXACT5, "exact5", ARG_SPECIAL },
{ OP_EXACTN, "exactn", ARG_SPECIAL },
{ OP_EXACTMB2N1, "exactmb2-n1", ARG_SPECIAL },
{ OP_EXACTMB2N2, "exactmb2-n2", ARG_SPECIAL },
{ OP_EXACTMB2N3, "exactmb2-n3", ARG_SPECIAL },
{ OP_EXACTMB2N, "exactmb2-n", ARG_SPECIAL },
{ OP_EXACTMB3N, "exactmb3n" , ARG_SPECIAL },
{ OP_EXACTMBN, "exactmbn", ARG_SPECIAL },
{ OP_EXACT1_IC, "exact1-ic", ARG_SPECIAL },
{ OP_EXACTN_IC, "exactn-ic", ARG_SPECIAL },
{ OP_CCLASS, "cclass", ARG_SPECIAL },
{ OP_CCLASS_MB, "cclass-mb", ARG_SPECIAL },
{ OP_CCLASS_MIX, "cclass-mix", ARG_SPECIAL },
{ OP_CCLASS_NOT, "cclass-not", ARG_SPECIAL },
{ OP_CCLASS_MB_NOT, "cclass-mb-not", ARG_SPECIAL },
{ OP_CCLASS_MIX_NOT, "cclass-mix-not", ARG_SPECIAL },
{ OP_CCLASS_NODE, "cclass-node", ARG_SPECIAL },
{ OP_ANYCHAR, "anychar", ARG_NON },
{ OP_ANYCHAR_ML, "anychar-ml", ARG_NON },
{ OP_ANYCHAR_STAR, "anychar*", ARG_NON },
{ OP_ANYCHAR_ML_STAR, "anychar-ml*", ARG_NON },
{ OP_ANYCHAR_STAR_PEEK_NEXT, "anychar*-peek-next", ARG_SPECIAL },
{ OP_ANYCHAR_ML_STAR_PEEK_NEXT, "anychar-ml*-peek-next", ARG_SPECIAL },
{ OP_WORD, "word", ARG_NON },
{ OP_NOT_WORD, "not-word", ARG_NON },
{ OP_WORD_BOUND, "word-bound", ARG_NON },
{ OP_NOT_WORD_BOUND, "not-word-bound", ARG_NON },
{ OP_WORD_BEGIN, "word-begin", ARG_NON },
{ OP_WORD_END, "word-end", ARG_NON },
{ OP_BEGIN_BUF, "begin-buf", ARG_NON },
{ OP_END_BUF, "end-buf", ARG_NON },
{ OP_BEGIN_LINE, "begin-line", ARG_NON },
{ OP_END_LINE, "end-line", ARG_NON },
{ OP_SEMI_END_BUF, "semi-end-buf", ARG_NON },
{ OP_BEGIN_POSITION, "begin-position", ARG_NON },
{ OP_BACKREF1, "backref1", ARG_NON },
{ OP_BACKREF2, "backref2", ARG_NON },
{ OP_BACKREFN, "backrefn", ARG_MEMNUM },
{ OP_BACKREFN_IC, "backrefn-ic", ARG_SPECIAL },
{ OP_BACKREF_MULTI, "backref_multi", ARG_SPECIAL },
{ OP_BACKREF_MULTI_IC, "backref_multi-ic", ARG_SPECIAL },
{ OP_BACKREF_WITH_LEVEL, "backref_at_level", ARG_SPECIAL },
{ OP_MEMORY_START_PUSH, "mem-start-push", ARG_MEMNUM },
{ OP_MEMORY_START, "mem-start", ARG_MEMNUM },
{ OP_MEMORY_END_PUSH, "mem-end-push", ARG_MEMNUM },
{ OP_MEMORY_END_PUSH_REC, "mem-end-push-rec", ARG_MEMNUM },
{ OP_MEMORY_END, "mem-end", ARG_MEMNUM },
{ OP_MEMORY_END_REC, "mem-end-rec", ARG_MEMNUM },
{ OP_SET_OPTION_PUSH, "set-option-push", ARG_OPTION },
{ OP_SET_OPTION, "set-option", ARG_OPTION },
{ OP_FAIL, "fail", ARG_NON },
{ OP_JUMP, "jump", ARG_RELADDR },
{ OP_PUSH, "push", ARG_RELADDR },
{ OP_POP, "pop", ARG_NON },
{ OP_PUSH_OR_JUMP_EXACT1, "push-or-jump-e1", ARG_SPECIAL },
{ OP_PUSH_IF_PEEK_NEXT, "push-if-peek-next", ARG_SPECIAL },
{ OP_REPEAT, "repeat", ARG_SPECIAL },
{ OP_REPEAT_NG, "repeat-ng", ARG_SPECIAL },
{ OP_REPEAT_INC, "repeat-inc", ARG_MEMNUM },
{ OP_REPEAT_INC_NG, "repeat-inc-ng", ARG_MEMNUM },
{ OP_REPEAT_INC_SG, "repeat-inc-sg", ARG_MEMNUM },
{ OP_REPEAT_INC_NG_SG, "repeat-inc-ng-sg", ARG_MEMNUM },
{ OP_NULL_CHECK_START, "null-check-start", ARG_MEMNUM },
{ OP_NULL_CHECK_END, "null-check-end", ARG_MEMNUM },
{ OP_NULL_CHECK_END_MEMST,"null-check-end-memst", ARG_MEMNUM },
{ OP_NULL_CHECK_END_MEMST_PUSH,"null-check-end-memst-push", ARG_MEMNUM },
{ OP_PUSH_POS, "push-pos", ARG_NON },
{ OP_POP_POS, "pop-pos", ARG_NON },
{ OP_PUSH_POS_NOT, "push-pos-not", ARG_RELADDR },
{ OP_FAIL_POS, "fail-pos", ARG_NON },
{ OP_PUSH_STOP_BT, "push-stop-bt", ARG_NON },
{ OP_POP_STOP_BT, "pop-stop-bt", ARG_NON },
{ OP_LOOK_BEHIND, "look-behind", ARG_SPECIAL },
{ OP_PUSH_LOOK_BEHIND_NOT, "push-look-behind-not", ARG_SPECIAL },
{ OP_FAIL_LOOK_BEHIND_NOT, "fail-look-behind-not", ARG_NON },
{ OP_CALL, "call", ARG_ABSADDR },
{ OP_RETURN, "return", ARG_NON },
{ OP_STATE_CHECK_PUSH, "state-check-push", ARG_SPECIAL },
{ OP_STATE_CHECK_PUSH_OR_JUMP, "state-check-push-or-jump", ARG_SPECIAL },
{ OP_STATE_CHECK, "state-check", ARG_STATE_CHECK },
{ OP_STATE_CHECK_ANYCHAR_STAR, "state-check-anychar*", ARG_STATE_CHECK },
{ OP_STATE_CHECK_ANYCHAR_ML_STAR,
"state-check-anychar-ml*", ARG_STATE_CHECK },
{ -1, "", ARG_NON }
};
static char*
op2name(int opcode)
{
int i;
for (i = 0; OnigOpInfo[i].opcode >= 0; i++) {
if (opcode == OnigOpInfo[i].opcode)
return OnigOpInfo[i].name;
}
return "";
}
static int
op2arg_type(int opcode)
{
int i;
for (i = 0; OnigOpInfo[i].opcode >= 0; i++) {
if (opcode == OnigOpInfo[i].opcode)
return OnigOpInfo[i].arg_type;
}
return ARG_SPECIAL;
}
static void
Indent(FILE* f, int indent)
{
int i;
for (i = 0; i < indent; i++) putc(' ', f);
}
static void
p_string(FILE* f, int len, UChar* s)
{
fputs(":", f);
while (len-- > 0) { fputc(*s++, f); }
}
static void
p_len_string(FILE* f, LengthType len, int mb_len, UChar* s)
{
int x = len * mb_len;
fprintf(f, ":%d:", len);
while (x-- > 0) { fputc(*s++, f); }
}
extern void
onig_print_compiled_byte_code(FILE* f, UChar* bp, UChar** nextp,
OnigEncoding enc)
{
int i, n, arg_type;
RelAddrType addr;
LengthType len;
MemNumType mem;
StateCheckNumType scn;
OnigCodePoint code;
UChar *q;
fprintf(f, "[%s", op2name(*bp));
arg_type = op2arg_type(*bp);
if (arg_type != ARG_SPECIAL) {
bp++;
switch (arg_type) {
case ARG_NON:
break;
case ARG_RELADDR:
GET_RELADDR_INC(addr, bp);
fprintf(f, ":(%d)", addr);
break;
case ARG_ABSADDR:
GET_ABSADDR_INC(addr, bp);
fprintf(f, ":(%d)", addr);
break;
case ARG_LENGTH:
GET_LENGTH_INC(len, bp);
fprintf(f, ":%d", len);
break;
case ARG_MEMNUM:
mem = *((MemNumType* )bp);
bp += SIZE_MEMNUM;
fprintf(f, ":%d", mem);
break;
case ARG_OPTION:
{
OnigOptionType option = *((OnigOptionType* )bp);
bp += SIZE_OPTION;
fprintf(f, ":%d", option);
}
break;
case ARG_STATE_CHECK:
scn = *((StateCheckNumType* )bp);
bp += SIZE_STATE_CHECK_NUM;
fprintf(f, ":%d", scn);
break;
}
}
else {
switch (*bp++) {
case OP_EXACT1:
case OP_ANYCHAR_STAR_PEEK_NEXT:
case OP_ANYCHAR_ML_STAR_PEEK_NEXT:
p_string(f, 1, bp++); break;
case OP_EXACT2:
p_string(f, 2, bp); bp += 2; break;
case OP_EXACT3:
p_string(f, 3, bp); bp += 3; break;
case OP_EXACT4:
p_string(f, 4, bp); bp += 4; break;
case OP_EXACT5:
p_string(f, 5, bp); bp += 5; break;
case OP_EXACTN:
GET_LENGTH_INC(len, bp);
p_len_string(f, len, 1, bp);
bp += len;
break;
case OP_EXACTMB2N1:
p_string(f, 2, bp); bp += 2; break;
case OP_EXACTMB2N2:
p_string(f, 4, bp); bp += 4; break;
case OP_EXACTMB2N3:
p_string(f, 6, bp); bp += 6; break;
case OP_EXACTMB2N:
GET_LENGTH_INC(len, bp);
p_len_string(f, len, 2, bp);
bp += len * 2;
break;
case OP_EXACTMB3N:
GET_LENGTH_INC(len, bp);
p_len_string(f, len, 3, bp);
bp += len * 3;
break;
case OP_EXACTMBN:
{
int mb_len;
GET_LENGTH_INC(mb_len, bp);
GET_LENGTH_INC(len, bp);
fprintf(f, ":%d:%d:", mb_len, len);
n = len * mb_len;
while (n-- > 0) { fputc(*bp++, f); }
}
break;
case OP_EXACT1_IC:
len = enclen(enc, bp);
p_string(f, len, bp);
bp += len;
break;
case OP_EXACTN_IC:
GET_LENGTH_INC(len, bp);
p_len_string(f, len, 1, bp);
bp += len;
break;
case OP_CCLASS:
n = bitset_on_num((BitSetRef )bp);
bp += SIZE_BITSET;
fprintf(f, ":%d", n);
break;
case OP_CCLASS_NOT:
n = bitset_on_num((BitSetRef )bp);
bp += SIZE_BITSET;
fprintf(f, ":%d", n);
break;
case OP_CCLASS_MB:
case OP_CCLASS_MB_NOT:
GET_LENGTH_INC(len, bp);
q = bp;
#ifndef PLATFORM_UNALIGNED_WORD_ACCESS
ALIGNMENT_RIGHT(q);
#endif
GET_CODE_POINT(code, q);
bp += len;
fprintf(f, ":%d:%d", (int )code, len);
break;
case OP_CCLASS_MIX:
case OP_CCLASS_MIX_NOT:
n = bitset_on_num((BitSetRef )bp);
bp += SIZE_BITSET;
GET_LENGTH_INC(len, bp);
q = bp;
#ifndef PLATFORM_UNALIGNED_WORD_ACCESS
ALIGNMENT_RIGHT(q);
#endif
GET_CODE_POINT(code, q);
bp += len;
fprintf(f, ":%d:%d:%d", n, (int )code, len);
break;
case OP_CCLASS_NODE:
{
CClassNode *cc;
GET_POINTER_INC(cc, bp);
n = bitset_on_num(cc->bs);
fprintf(f, ":%u:%d", (unsigned int )cc, n);
}
break;
case OP_BACKREFN_IC:
mem = *((MemNumType* )bp);
bp += SIZE_MEMNUM;
fprintf(f, ":%d", mem);
break;
case OP_BACKREF_MULTI_IC:
case OP_BACKREF_MULTI:
fputs(" ", f);
GET_LENGTH_INC(len, bp);
for (i = 0; i < len; i++) {
GET_MEMNUM_INC(mem, bp);
if (i > 0) fputs(", ", f);
fprintf(f, "%d", mem);
}
break;
case OP_BACKREF_WITH_LEVEL:
{
OnigOptionType option;
LengthType level;
GET_OPTION_INC(option, bp);
fprintf(f, ":%d", option);
GET_LENGTH_INC(level, bp);
fprintf(f, ":%d", level);
fputs(" ", f);
GET_LENGTH_INC(len, bp);
for (i = 0; i < len; i++) {
GET_MEMNUM_INC(mem, bp);
if (i > 0) fputs(", ", f);
fprintf(f, "%d", mem);
}
}
break;
case OP_REPEAT:
case OP_REPEAT_NG:
{
mem = *((MemNumType* )bp);
bp += SIZE_MEMNUM;
addr = *((RelAddrType* )bp);
bp += SIZE_RELADDR;
fprintf(f, ":%d:%d", mem, addr);
}
break;
case OP_PUSH_OR_JUMP_EXACT1:
case OP_PUSH_IF_PEEK_NEXT:
addr = *((RelAddrType* )bp);
bp += SIZE_RELADDR;
fprintf(f, ":(%d)", addr);
p_string(f, 1, bp);
bp += 1;
break;
case OP_LOOK_BEHIND:
GET_LENGTH_INC(len, bp);
fprintf(f, ":%d", len);
break;
case OP_PUSH_LOOK_BEHIND_NOT:
GET_RELADDR_INC(addr, bp);
GET_LENGTH_INC(len, bp);
fprintf(f, ":%d:(%d)", len, addr);
break;
case OP_STATE_CHECK_PUSH:
case OP_STATE_CHECK_PUSH_OR_JUMP:
scn = *((StateCheckNumType* )bp);
bp += SIZE_STATE_CHECK_NUM;
addr = *((RelAddrType* )bp);
bp += SIZE_RELADDR;
fprintf(f, ":%d:(%d)", scn, addr);
break;
default:
fprintf(stderr, "onig_print_compiled_byte_code: undefined code %d\n",
*--bp);
}
}
fputs("]", f);
if (nextp) *nextp = bp;
}
static void
print_compiled_byte_code_list(FILE* f, regex_t* reg)
{
int ncode;
UChar* bp = reg->p;
UChar* end = reg->p + reg->used;
fprintf(f, "code length: %d\n", reg->used);
ncode = 0;
while (bp < end) {
ncode++;
if (bp > reg->p) {
if (ncode % 5 == 0)
fprintf(f, "\n");
else
fputs(" ", f);
}
onig_print_compiled_byte_code(f, bp, &bp, reg->enc);
}
fprintf(f, "\n");
}
static void
print_indent_tree(FILE* f, Node* node, int indent)
{
int i, type;
int add = 3;
UChar* p;
Indent(f, indent);
if (IS_NULL(node)) {
fprintf(f, "ERROR: null node!!!\n");
exit (0);
}
type = NTYPE(node);
switch (type) {
case NT_LIST:
case NT_ALT:
if (NTYPE(node) == NT_LIST)
fprintf(f, "<list:%x>\n", (int )node);
else
fprintf(f, "<alt:%x>\n", (int )node);
print_indent_tree(f, NCAR(node), indent + add);
while (IS_NOT_NULL(node = NCDR(node))) {
if (NTYPE(node) != type) {
fprintf(f, "ERROR: list/alt right is not a cons. %d\n", NTYPE(node));
exit(0);
}
print_indent_tree(f, NCAR(node), indent + add);
}
break;
case NT_STR:
fprintf(f, "<string%s:%x>",
(NSTRING_IS_RAW(node) ? "-raw" : ""), (int )node);
for (p = NSTR(node)->s; p < NSTR(node)->end; p++) {
if (*p >= 0x20 && *p < 0x7f)
fputc(*p, f);
else {
fprintf(f, " 0x%02x", *p);
}
}
break;
case NT_CCLASS:
fprintf(f, "<cclass:%x>", (int )node);
if (IS_NCCLASS_NOT(NCCLASS(node))) fputs(" not", f);
if (NCCLASS(node)->mbuf) {
BBuf* bbuf = NCCLASS(node)->mbuf;
for (i = 0; i < bbuf->used; i++) {
if (i > 0) fprintf(f, ",");
fprintf(f, "%0x", bbuf->p[i]);
}
}
break;
case NT_CTYPE:
fprintf(f, "<ctype:%x> ", (int )node);
switch (NCTYPE(node)->ctype) {
case ONIGENC_CTYPE_WORD:
if (NCTYPE(node)->not != 0)
fputs("not word", f);
else
fputs("word", f);
break;
default:
fprintf(f, "ERROR: undefined ctype.\n");
exit(0);
}
break;
case NT_CANY:
fprintf(f, "<anychar:%x>", (int )node);
break;
case NT_ANCHOR:
fprintf(f, "<anchor:%x> ", (int )node);
switch (NANCHOR(node)->type) {
case ANCHOR_BEGIN_BUF: fputs("begin buf", f); break;
case ANCHOR_END_BUF: fputs("end buf", f); break;
case ANCHOR_BEGIN_LINE: fputs("begin line", f); break;
case ANCHOR_END_LINE: fputs("end line", f); break;
case ANCHOR_SEMI_END_BUF: fputs("semi end buf", f); break;
case ANCHOR_BEGIN_POSITION: fputs("begin position", f); break;
case ANCHOR_WORD_BOUND: fputs("word bound", f); break;
case ANCHOR_NOT_WORD_BOUND: fputs("not word bound", f); break;
#ifdef USE_WORD_BEGIN_END
case ANCHOR_WORD_BEGIN: fputs("word begin", f); break;
case ANCHOR_WORD_END: fputs("word end", f); break;
#endif
case ANCHOR_PREC_READ: fputs("prec read", f); break;
case ANCHOR_PREC_READ_NOT: fputs("prec read not", f); break;
case ANCHOR_LOOK_BEHIND: fputs("look_behind", f); break;
case ANCHOR_LOOK_BEHIND_NOT: fputs("look_behind_not",f); break;
default:
fprintf(f, "ERROR: undefined anchor type.\n");
break;
}
break;
case NT_BREF:
{
int* p;
BRefNode* br = NBREF(node);
p = BACKREFS_P(br);
fprintf(f, "<backref:%x>", (int )node);
for (i = 0; i < br->back_num; i++) {
if (i > 0) fputs(", ", f);
fprintf(f, "%d", p[i]);
}
}
break;
#ifdef USE_SUBEXP_CALL
case NT_CALL:
{
CallNode* cn = NCALL(node);
fprintf(f, "<call:%x>", (int )node);
p_string(f, cn->name_end - cn->name, cn->name);
}
break;
#endif
case NT_QTFR:
fprintf(f, "<quantifier:%x>{%d,%d}%s\n", (int )node,
NQTFR(node)->lower, NQTFR(node)->upper,
(NQTFR(node)->greedy ? "" : "?"));
print_indent_tree(f, NQTFR(node)->target, indent + add);
break;
case NT_ENCLOSE:
fprintf(f, "<enclose:%x> ", (int )node);
switch (NENCLOSE(node)->type) {
case ENCLOSE_OPTION:
fprintf(f, "option:%d\n", NENCLOSE(node)->option);
print_indent_tree(f, NENCLOSE(node)->target, indent + add);
break;
case ENCLOSE_MEMORY:
fprintf(f, "memory:%d", NENCLOSE(node)->regnum);
break;
case ENCLOSE_STOP_BACKTRACK:
fprintf(f, "stop-bt");
break;
default:
break;
}
fprintf(f, "\n");
print_indent_tree(f, NENCLOSE(node)->target, indent + add);
break;
default:
fprintf(f, "print_indent_tree: undefined node type %d\n", NTYPE(node));
break;
}
if (type != NT_LIST && type != NT_ALT && type != NT_QTFR &&
type != NT_ENCLOSE)
fprintf(f, "\n");
fflush(f);
}
#endif /* ONIG_DEBUG */
#ifdef ONIG_DEBUG_PARSE_TREE
static void
print_tree(FILE* f, Node* node)
{
print_indent_tree(f, node, 0);
}
#endif
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