/********************************************************************** regcomp.c - Oniguruma (regular expression library) **********************************************************************/ /*- * Copyright (c) 2002-2018 K.Kosako * 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; #if 0 typedef struct { int n; int alloc; int* v; } int_stack; static int make_int_stack(int_stack** rs, int init_size) { int_stack* s; int* v; *rs = 0; s = xmalloc(sizeof(*s)); if (IS_NULL(s)) return ONIGERR_MEMORY; v = (int* )xmalloc(sizeof(int) * init_size); if (IS_NULL(v)) { xfree(s); return ONIGERR_MEMORY; } s->n = 0; s->alloc = init_size; s->v = v; *rs = s; return ONIG_NORMAL; } static void free_int_stack(int_stack* s) { if (IS_NOT_NULL(s)) { if (IS_NOT_NULL(s->v)) xfree(s->v); xfree(s); } } static int int_stack_push(int_stack* s, int v) { if (s->n >= s->alloc) { int new_size = s->alloc * 2; int* nv = (int* )xrealloc(s->v, sizeof(int) * new_size); if (IS_NULL(nv)) return ONIGERR_MEMORY; s->alloc = new_size; s->v = nv; } s->v[s->n] = v; s->n++; return ONIG_NORMAL; } static int int_stack_pop(int_stack* s) { int v; #ifdef ONIG_DEBUG if (s->n <= 0) { fprintf(stderr, "int_stack_pop: fail empty. %p\n", s); return 0; } #endif v = s->v[s->n]; s->n--; return v; } #endif 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; } static int int_multiply_cmp(int x, int y, int v) { if (x == 0 || y == 0) return -1; if (x < INT_MAX / y) { int xy = x * y; if (xy > v) return 1; else { if (xy == v) return 0; else return -1; } } else return 1; } #ifndef PLATFORM_UNALIGNED_WORD_ACCESS static unsigned char PadBuf[WORD_ALIGNMENT_SIZE]; #endif static void swap_node(Node* a, Node* b) { Node c; c = *a; *a = *b; *b = c; if (NODE_TYPE(a) == NODE_STRING) { StrNode* sn = STR_(a); if (sn->capa == 0) { int len = (int )(sn->end - sn->s); sn->s = sn->buf; sn->end = sn->s + len; } } if (NODE_TYPE(b) == NODE_STRING) { StrNode* sn = STR_(b); if (sn->capa == 0) { int len = (int )(sn->end - sn->s); sn->s = sn->buf; sn->end = sn->s + len; } } } static OnigLen distance_add(OnigLen d1, OnigLen d2) { if (d1 == INFINITE_LEN || d2 == INFINITE_LEN) return INFINITE_LEN; else { if (d1 <= INFINITE_LEN - d2) return d1 + d2; else return INFINITE_LEN; } } static OnigLen distance_multiply(OnigLen d, int m) { if (m == 0) return 0; if (d < INFINITE_LEN / m) return d * m; else return INFINITE_LEN; } 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; } 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_CALL static int unset_addr_list_init(UnsetAddrList* list, int size) { UnsetAddr* p = (UnsetAddr* )xmalloc(sizeof(UnsetAddr)* size); CHECK_NULL_RETURN_MEMERR(p); list->num = 0; list->alloc = size; list->us = p; return 0; } static void unset_addr_list_end(UnsetAddrList* list) { if (IS_NOT_NULL(list->us)) xfree(list->us); } static int unset_addr_list_add(UnsetAddrList* list, int offset, struct _Node* node) { UnsetAddr* p; int size; if (list->num >= list->alloc) { size = list->alloc * 2; p = (UnsetAddr* )xrealloc(list->us, sizeof(UnsetAddr) * size); CHECK_NULL_RETURN_MEMERR(p); list->alloc = size; list->us = p; } list->us[list->num].offset = offset; list->us[list->num].target = node; list->num++; return 0; } #endif /* USE_CALL */ static int add_opcode(regex_t* reg, int opcode) { BB_ADD1(reg, opcode); return 0; } static int add_rel_addr(regex_t* reg, int addr) { RelAddrType ra = (RelAddrType )addr; BB_ADD(reg, &ra, SIZE_RELADDR); return 0; } static int add_abs_addr(regex_t* reg, int addr) { AbsAddrType ra = (AbsAddrType )addr; BB_ADD(reg, &ra, SIZE_ABSADDR); return 0; } static int add_length(regex_t* reg, int len) { LengthType l = (LengthType )len; BB_ADD(reg, &l, SIZE_LENGTH); return 0; } static int add_mem_num(regex_t* reg, int num) { MemNumType n = (MemNumType )num; BB_ADD(reg, &n, SIZE_MEMNUM); return 0; } #if 0 static int add_pointer(regex_t* reg, void* addr) { PointerType ptr = (PointerType )addr; BB_ADD(reg, &ptr, SIZE_POINTER); return 0; } #endif static int add_option(regex_t* reg, OnigOptionType option) { BB_ADD(reg, &option, SIZE_OPTION); return 0; } static int add_save_type(regex_t* reg, enum SaveType type) { SaveType t = (SaveType )type; BB_ADD(reg, &t, SIZE_SAVE_TYPE); return 0; } static int add_update_var_type(regex_t* reg, enum UpdateVarType type) { UpdateVarType t = (UpdateVarType )type; BB_ADD(reg, &t, SIZE_UPDATE_VAR_TYPE); return 0; } static int add_mode(regex_t* reg, ModeType mode) { BB_ADD(reg, &mode, SIZE_MODE); return 0; } static int add_opcode_rel_addr(regex_t* reg, int opcode, int addr) { int r; r = add_opcode(reg, opcode); if (r != 0) return r; r = add_rel_addr(reg, addr); return r; } static int add_bytes(regex_t* reg, UChar* bytes, int len) { BB_ADD(reg, bytes, len); return 0; } static int add_bitset(regex_t* reg, BitSetRef bs) { BB_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 != 0) 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, ScanEnv* env); #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, ScanEnv* env) { int r; int saved_num_null_check = reg->num_null_check; if (empty_info != QUANT_BODY_IS_NOT_EMPTY) { r = add_opcode(reg, OP_EMPTY_CHECK_START); if (r != 0) return r; r = add_mem_num(reg, reg->num_null_check); /* NULL CHECK ID */ if (r != 0) return r; reg->num_null_check++; } r = compile_tree(node, reg, env); if (r != 0) return r; if (empty_info != QUANT_BODY_IS_NOT_EMPTY) { if (empty_info == QUANT_BODY_IS_EMPTY) r = add_opcode(reg, OP_EMPTY_CHECK_END); else if (empty_info == QUANT_BODY_IS_EMPTY_MEM) r = add_opcode(reg, OP_EMPTY_CHECK_END_MEMST); else if (empty_info == QUANT_BODY_IS_EMPTY_REC) r = add_opcode(reg, OP_EMPTY_CHECK_END_MEMST_PUSH); if (r != 0) return r; r = add_mem_num(reg, saved_num_null_check); /* NULL CHECK ID */ } return r; } #ifdef USE_CALL static int compile_call(CallNode* node, regex_t* reg, ScanEnv* env) { int r; r = add_opcode(reg, OP_CALL); if (r != 0) return r; r = unset_addr_list_add(env->unset_addr_list, BB_GET_OFFSET_POS(reg), NODE_CALL_BODY(node)); if (r != 0) 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, ScanEnv* env) { int i, r; for (i = 0; i < n; i++) { r = compile_tree(node, reg, env); if (r != 0) 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; UChar *p, *prev; StrNode* sn; OnigEncoding enc = reg->enc; sn = STR_(node); if (sn->end <= sn->s) return 0; ambig = NODE_STRING_IS_AMBIG(node); p = prev = sn->s; prev_len = enclen(enc, p); p += prev_len; slen = 1; rlen = 0; for (; p < sn->end; ) { len = enclen(enc, p); 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 */, (int )(sn->end - sn->s), reg, 0); } static int compile_string_node(Node* node, regex_t* reg) { int r, len, prev_len, slen, ambig; UChar *p, *prev, *end; StrNode* sn; OnigEncoding enc = reg->enc; sn = STR_(node); if (sn->end <= sn->s) return 0; end = sn->end; ambig = NODE_STRING_IS_AMBIG(node); p = prev = sn->s; prev_len = enclen(enc, p); p += prev_len; slen = 1; for (; p < end; ) { len = enclen(enc, p); if (len == prev_len) { slen++; } else { r = add_compile_string(prev, prev_len, slen, reg, ambig); if (r != 0) 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 */, (int )(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 = BB_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_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_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 != 0) 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(QuantNode* qn, int target_len, int empty_info, regex_t* reg, ScanEnv* env) { int r; int num_repeat = reg->num_repeat; r = add_opcode(reg, qn->greedy ? OP_REPEAT : OP_REPEAT_NG); if (r != 0) return r; r = add_mem_num(reg, num_repeat); /* OP_REPEAT ID */ reg->num_repeat++; if (r != 0) return r; r = add_rel_addr(reg, target_len + SIZE_OP_REPEAT_INC); if (r != 0) return r; r = entry_repeat_range(reg, num_repeat, qn->lower, qn->upper); if (r != 0) return r; r = compile_tree_empty_check(NODE_QUANT_BODY(qn), reg, empty_info, env); if (r != 0) return r; if ( #ifdef USE_CALL NODE_IS_IN_MULTI_ENTRY(qn) || #endif NODE_IS_IN_REAL_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 != 0) return r; r = add_mem_num(reg, num_repeat); /* OP_REPEAT ID */ return r; } static int is_anychar_infinite_greedy(QuantNode* qn) { if (qn->greedy && IS_REPEAT_INFINITE(qn->upper) && NODE_IS_ANYCHAR(NODE_QUANT_BODY(qn))) return 1; else return 0; } #define QUANTIFIER_EXPAND_LIMIT_SIZE 50 #define CKN_ON (ckn > 0) static int compile_length_quantifier_node(QuantNode* qn, regex_t* reg) { int len, mod_tlen; int infinite = IS_REPEAT_INFINITE(qn->upper); enum QuantBodyEmpty empty_info = qn->body_empty_info; int tlen = compile_length_tree(NODE_QUANT_BODY(qn), reg); if (tlen < 0) return tlen; if (tlen == 0) return 0; /* anychar repeat */ if (is_anychar_infinite_greedy(qn)) { if (qn->lower <= 1 || int_multiply_cmp(tlen, qn->lower, QUANTIFIER_EXPAND_LIMIT_SIZE) <= 0) { 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 == QUANT_BODY_IS_NOT_EMPTY) mod_tlen = tlen; else mod_tlen = tlen + (SIZE_OP_EMPTY_CHECK_START + SIZE_OP_EMPTY_CHECK_END); if (infinite && (qn->lower <= 1 || int_multiply_cmp(tlen, qn->lower, QUANTIFIER_EXPAND_LIMIT_SIZE) <= 0)) { 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) { /* /(?..){0}/ */ len = SIZE_OP_JUMP + tlen; } else if (!infinite && qn->greedy && (qn->upper == 1 || int_multiply_cmp(tlen + SIZE_OP_PUSH, qn->upper, QUANTIFIER_EXPAND_LIMIT_SIZE) <= 0)) { 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(QuantNode* qn, regex_t* reg, ScanEnv* env) { int i, r, mod_tlen; int infinite = IS_REPEAT_INFINITE(qn->upper); enum QuantBodyEmpty empty_info = qn->body_empty_info; int tlen = compile_length_tree(NODE_QUANT_BODY(qn), reg); if (tlen < 0) return tlen; if (tlen == 0) return 0; if (is_anychar_infinite_greedy(qn) && (qn->lower <= 1 || int_multiply_cmp(tlen, qn->lower, QUANTIFIER_EXPAND_LIMIT_SIZE) <= 0)) { r = compile_tree_n_times(NODE_QUANT_BODY(qn), qn->lower, reg, env); if (r != 0) return r; if (IS_NOT_NULL(qn->next_head_exact)) { if (IS_MULTILINE(CTYPE_OPTION(NODE_QUANT_BODY(qn), reg))) r = add_opcode(reg, OP_ANYCHAR_ML_STAR_PEEK_NEXT); else r = add_opcode(reg, OP_ANYCHAR_STAR_PEEK_NEXT); if (r != 0) return r; return add_bytes(reg, STR_(qn->next_head_exact)->s, 1); } else { if (IS_MULTILINE(CTYPE_OPTION(NODE_QUANT_BODY(qn), reg))) return add_opcode(reg, OP_ANYCHAR_ML_STAR); else return add_opcode(reg, OP_ANYCHAR_STAR); } } if (empty_info == QUANT_BODY_IS_NOT_EMPTY) mod_tlen = tlen; else mod_tlen = tlen + (SIZE_OP_EMPTY_CHECK_START + SIZE_OP_EMPTY_CHECK_END); if (infinite && (qn->lower <= 1 || int_multiply_cmp(tlen, qn->lower, QUANTIFIER_EXPAND_LIMIT_SIZE) <= 0)) { 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 != 0) return r; } else { r = compile_tree_n_times(NODE_QUANT_BODY(qn), qn->lower, reg, env); if (r != 0) 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 != 0) return r; add_bytes(reg, STR_(qn->head_exact)->s, 1); r = compile_tree_empty_check(NODE_QUANT_BODY(qn), reg, empty_info, env); if (r != 0) 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 != 0) return r; add_bytes(reg, STR_(qn->next_head_exact)->s, 1); r = compile_tree_empty_check(NODE_QUANT_BODY(qn), reg, empty_info, env); if (r != 0) 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 != 0) return r; r = compile_tree_empty_check(NODE_QUANT_BODY(qn), reg, empty_info, env); if (r != 0) 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 != 0) return r; r = compile_tree_empty_check(NODE_QUANT_BODY(qn), reg, empty_info, env); if (r != 0) 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) { /* /(?..){0}/ */ r = add_opcode_rel_addr(reg, OP_JUMP, tlen); if (r != 0) return r; r = compile_tree(NODE_QUANT_BODY(qn), reg, env); } else if (! infinite && qn->greedy && (qn->upper == 1 || int_multiply_cmp(tlen + SIZE_OP_PUSH, qn->upper, QUANTIFIER_EXPAND_LIMIT_SIZE) <= 0)) { int n = qn->upper - qn->lower; r = compile_tree_n_times(NODE_QUANT_BODY(qn), qn->lower, reg, env); if (r != 0) 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 != 0) return r; r = compile_tree(NODE_QUANT_BODY(qn), reg, env); if (r != 0) 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 != 0) return r; r = add_opcode_rel_addr(reg, OP_JUMP, tlen); if (r != 0) return r; r = compile_tree(NODE_QUANT_BODY(qn), reg, env); } else { r = compile_range_repeat_node(qn, mod_tlen, empty_info, reg, env); } return r; } static int compile_length_option_node(EnclosureNode* node, regex_t* reg) { int tlen; OnigOptionType prev = reg->options; reg->options = node->o.options; tlen = compile_length_tree(NODE_ENCLOSURE_BODY(node), 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(EnclosureNode* node, regex_t* reg, ScanEnv* env) { int r; OnigOptionType prev = reg->options; if (IS_DYNAMIC_OPTION(prev ^ node->o.options)) { r = add_opcode_option(reg, OP_SET_OPTION_PUSH, node->o.options); if (r != 0) return r; r = add_opcode_option(reg, OP_SET_OPTION, prev); if (r != 0) return r; r = add_opcode(reg, OP_FAIL); if (r != 0) return r; } reg->options = node->o.options; r = compile_tree(NODE_ENCLOSURE_BODY(node), reg, env); reg->options = prev; if (IS_DYNAMIC_OPTION(prev ^ node->o.options)) { if (r != 0) return r; r = add_opcode_option(reg, OP_SET_OPTION, prev); } return r; } static int compile_length_enclosure_node(EnclosureNode* node, regex_t* reg) { int len; int tlen; if (node->type == ENCLOSURE_OPTION) return compile_length_option_node(node, reg); if (NODE_ENCLOSURE_BODY(node)) { tlen = compile_length_tree(NODE_ENCLOSURE_BODY(node), reg); if (tlen < 0) return tlen; } else tlen = 0; switch (node->type) { case ENCLOSURE_MEMORY: #ifdef USE_CALL if (node->m.regnum == 0 && NODE_IS_CALLED(node)) { len = tlen + SIZE_OP_CALL + SIZE_OP_JUMP + SIZE_OP_RETURN; return len; } if (NODE_IS_CALLED(node)) { len = SIZE_OP_MEMORY_START_PUSH + tlen + SIZE_OP_CALL + SIZE_OP_JUMP + SIZE_OP_RETURN; if (MEM_STATUS_AT0(reg->bt_mem_end, node->m.regnum)) len += (NODE_IS_RECURSION(node) ? SIZE_OP_MEMORY_END_PUSH_REC : SIZE_OP_MEMORY_END_PUSH); else len += (NODE_IS_RECURSION(node) ? SIZE_OP_MEMORY_END_REC : SIZE_OP_MEMORY_END); } else if (NODE_IS_RECURSION(node)) { len = SIZE_OP_MEMORY_START_PUSH; len += tlen + (MEM_STATUS_AT0(reg->bt_mem_end, node->m.regnum) ? SIZE_OP_MEMORY_END_PUSH_REC : SIZE_OP_MEMORY_END_REC); } else #endif { if (MEM_STATUS_AT0(reg->bt_mem_start, node->m.regnum)) len = SIZE_OP_MEMORY_START_PUSH; else len = SIZE_OP_MEMORY_START; len += tlen + (MEM_STATUS_AT0(reg->bt_mem_end, node->m.regnum) ? SIZE_OP_MEMORY_END_PUSH : SIZE_OP_MEMORY_END); } break; case ENCLOSURE_STOP_BACKTRACK: if (NODE_IS_STOP_BT_SIMPLE_REPEAT(node)) { QuantNode* qn = QUANT_(NODE_ENCLOSURE_BODY(node)); tlen = compile_length_tree(NODE_QUANT_BODY(qn), reg); if (tlen < 0) return tlen; len = tlen * qn->lower + SIZE_OP_PUSH + tlen + SIZE_OP_POP_OUT + SIZE_OP_JUMP; } else { len = SIZE_OP_ATOMIC_START + tlen + SIZE_OP_ATOMIC_END; } break; case ENCLOSURE_IF_ELSE: { Node* cond = NODE_ENCLOSURE_BODY(node); Node* Then = node->te.Then; Node* Else = node->te.Else; len = compile_length_tree(cond, reg); if (len < 0) return len; len += SIZE_OP_PUSH; len += SIZE_OP_ATOMIC_START + SIZE_OP_ATOMIC_END; if (IS_NOT_NULL(Then)) { tlen = compile_length_tree(Then, reg); if (tlen < 0) return tlen; len += tlen; } if (IS_NOT_NULL(Else)) { len += SIZE_OP_JUMP; tlen = compile_length_tree(Else, reg); if (tlen < 0) return tlen; len += tlen; } } 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_enclosure_memory_node(EnclosureNode* node, regex_t* reg, ScanEnv* env) { int r; int len; #ifdef USE_CALL if (node->m.regnum == 0 && NODE_IS_CALLED(node)) { r = add_opcode(reg, OP_CALL); if (r != 0) return r; node->m.called_addr = BB_GET_OFFSET_POS(reg) + SIZE_ABSADDR + SIZE_OP_JUMP; NODE_STATUS_ADD(node, NST_ADDR_FIXED); r = add_abs_addr(reg, (int )node->m.called_addr); if (r != 0) return r; len = compile_length_tree(NODE_ENCLOSURE_BODY(node), reg); len += SIZE_OP_RETURN; r = add_opcode_rel_addr(reg, OP_JUMP, len); if (r != 0) return r; r = compile_tree(NODE_ENCLOSURE_BODY(node), reg, env); if (r != 0) return r; r = add_opcode(reg, OP_RETURN); return r; } if (NODE_IS_CALLED(node)) { r = add_opcode(reg, OP_CALL); if (r != 0) return r; node->m.called_addr = BB_GET_OFFSET_POS(reg) + SIZE_ABSADDR + SIZE_OP_JUMP; NODE_STATUS_ADD(node, NST_ADDR_FIXED); r = add_abs_addr(reg, (int )node->m.called_addr); if (r != 0) return r; len = compile_length_tree(NODE_ENCLOSURE_BODY(node), reg); len += (SIZE_OP_MEMORY_START_PUSH + SIZE_OP_RETURN); if (MEM_STATUS_AT0(reg->bt_mem_end, node->m.regnum)) len += (NODE_IS_RECURSION(node) ? SIZE_OP_MEMORY_END_PUSH_REC : SIZE_OP_MEMORY_END_PUSH); else len += (NODE_IS_RECURSION(node) ? SIZE_OP_MEMORY_END_REC : SIZE_OP_MEMORY_END); r = add_opcode_rel_addr(reg, OP_JUMP, len); if (r != 0) return r; } #endif if (MEM_STATUS_AT0(reg->bt_mem_start, node->m.regnum)) r = add_opcode(reg, OP_MEMORY_START_PUSH); else r = add_opcode(reg, OP_MEMORY_START); if (r != 0) return r; r = add_mem_num(reg, node->m.regnum); if (r != 0) return r; r = compile_tree(NODE_ENCLOSURE_BODY(node), reg, env); if (r != 0) return r; #ifdef USE_CALL if (MEM_STATUS_AT0(reg->bt_mem_end, node->m.regnum)) r = add_opcode(reg, (NODE_IS_RECURSION(node) ? OP_MEMORY_END_PUSH_REC : OP_MEMORY_END_PUSH)); else r = add_opcode(reg, (NODE_IS_RECURSION(node) ? OP_MEMORY_END_REC : OP_MEMORY_END)); if (r != 0) return r; r = add_mem_num(reg, node->m.regnum); if (NODE_IS_CALLED(node)) { if (r != 0) return r; r = add_opcode(reg, OP_RETURN); } #else if (MEM_STATUS_AT0(reg->bt_mem_end, node->m.regnum)) r = add_opcode(reg, OP_MEMORY_END_PUSH); else r = add_opcode(reg, OP_MEMORY_END); if (r != 0) return r; r = add_mem_num(reg, node->m.regnum); #endif return r; } static int compile_enclosure_node(EnclosureNode* node, regex_t* reg, ScanEnv* env) { int r, len; switch (node->type) { case ENCLOSURE_MEMORY: r = compile_enclosure_memory_node(node, reg, env); break; case ENCLOSURE_OPTION: r = compile_option_node(node, reg, env); break; case ENCLOSURE_STOP_BACKTRACK: if (NODE_IS_STOP_BT_SIMPLE_REPEAT(node)) { QuantNode* qn = QUANT_(NODE_ENCLOSURE_BODY(node)); r = compile_tree_n_times(NODE_QUANT_BODY(qn), qn->lower, reg, env); if (r != 0) return r; len = compile_length_tree(NODE_QUANT_BODY(qn), reg); if (len < 0) return len; r = add_opcode_rel_addr(reg, OP_PUSH, len + SIZE_OP_POP_OUT + SIZE_OP_JUMP); if (r != 0) return r; r = compile_tree(NODE_QUANT_BODY(qn), reg, env); if (r != 0) return r; r = add_opcode(reg, OP_POP_OUT); if (r != 0) return r; r = add_opcode_rel_addr(reg, OP_JUMP, -((int )SIZE_OP_PUSH + len + (int )SIZE_OP_POP_OUT + (int )SIZE_OP_JUMP)); } else { r = add_opcode(reg, OP_ATOMIC_START); if (r != 0) return r; r = compile_tree(NODE_ENCLOSURE_BODY(node), reg, env); if (r != 0) return r; r = add_opcode(reg, OP_ATOMIC_END); } break; case ENCLOSURE_IF_ELSE: { int cond_len, then_len, jump_len; Node* cond = NODE_ENCLOSURE_BODY(node); Node* Then = node->te.Then; Node* Else = node->te.Else; r = add_opcode(reg, OP_ATOMIC_START); if (r != 0) return r; cond_len = compile_length_tree(cond, reg); if (cond_len < 0) return cond_len; if (IS_NOT_NULL(Then)) { then_len = compile_length_tree(Then, reg); if (then_len < 0) return then_len; } else then_len = 0; jump_len = cond_len + then_len + SIZE_OP_ATOMIC_END; if (IS_NOT_NULL(Else)) jump_len += SIZE_OP_JUMP; r = add_opcode_rel_addr(reg, OP_PUSH, jump_len); if (r != 0) return r; r = compile_tree(cond, reg, env); if (r != 0) return r; r = add_opcode(reg, OP_ATOMIC_END); if (r != 0) return r; if (IS_NOT_NULL(Then)) { r = compile_tree(Then, reg, env); if (r != 0) return r; } if (IS_NOT_NULL(Else)) { int else_len = compile_length_tree(Else, reg); r = add_opcode_rel_addr(reg, OP_JUMP, else_len); if (r != 0) return r; r = compile_tree(Else, reg, env); } } 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 (IS_NOT_NULL(NODE_ANCHOR_BODY(node))) { tlen = compile_length_tree(NODE_ANCHOR_BODY(node), reg); if (tlen < 0) return tlen; } switch (node->type) { case ANCHOR_PREC_READ: len = SIZE_OP_PREC_READ_START + tlen + SIZE_OP_PREC_READ_END; break; case ANCHOR_PREC_READ_NOT: len = SIZE_OP_PREC_READ_NOT_START + tlen + SIZE_OP_PREC_READ_NOT_END; break; case ANCHOR_LOOK_BEHIND: len = SIZE_OP_LOOK_BEHIND + tlen; break; case ANCHOR_LOOK_BEHIND_NOT: len = SIZE_OP_LOOK_BEHIND_NOT_START + tlen + SIZE_OP_LOOK_BEHIND_NOT_END; break; case ANCHOR_WORD_BOUNDARY: case ANCHOR_NO_WORD_BOUNDARY: #ifdef USE_WORD_BEGIN_END case ANCHOR_WORD_BEGIN: case ANCHOR_WORD_END: #endif len = SIZE_OP_WORD_BOUNDARY; break; case ANCHOR_EXTENDED_GRAPHEME_CLUSTER_BOUNDARY: case ANCHOR_NO_EXTENDED_GRAPHEME_CLUSTER_BOUNDARY: len = SIZE_OPCODE; break; default: len = SIZE_OPCODE; break; } return len; } static int compile_anchor_node(AnchorNode* node, regex_t* reg, ScanEnv* env) { int r, len; enum OpCode op; 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_BOUNDARY: op = OP_WORD_BOUNDARY; word: r = add_opcode(reg, op); if (r != 0) return r; r = add_mode(reg, (ModeType )node->ascii_mode); break; case ANCHOR_NO_WORD_BOUNDARY: op = OP_NO_WORD_BOUNDARY; goto word; break; #ifdef USE_WORD_BEGIN_END case ANCHOR_WORD_BEGIN: op = OP_WORD_BEGIN; goto word; break; case ANCHOR_WORD_END: op = OP_WORD_END; goto word; break; #endif case ANCHOR_EXTENDED_GRAPHEME_CLUSTER_BOUNDARY: r = add_opcode(reg, OP_EXTENDED_GRAPHEME_CLUSTER_BOUNDARY); break; case ANCHOR_NO_EXTENDED_GRAPHEME_CLUSTER_BOUNDARY: r = add_opcode(reg, OP_NO_EXTENDED_GRAPHEME_CLUSTER_BOUNDARY); break; case ANCHOR_PREC_READ: r = add_opcode(reg, OP_PREC_READ_START); if (r != 0) return r; r = compile_tree(NODE_ANCHOR_BODY(node), reg, env); if (r != 0) return r; r = add_opcode(reg, OP_PREC_READ_END); break; case ANCHOR_PREC_READ_NOT: len = compile_length_tree(NODE_ANCHOR_BODY(node), reg); if (len < 0) return len; r = add_opcode_rel_addr(reg, OP_PREC_READ_NOT_START, len + SIZE_OP_PREC_READ_NOT_END); if (r != 0) return r; r = compile_tree(NODE_ANCHOR_BODY(node), reg, env); if (r != 0) return r; r = add_opcode(reg, OP_PREC_READ_NOT_END); break; case ANCHOR_LOOK_BEHIND: { int n; r = add_opcode(reg, OP_LOOK_BEHIND); if (r != 0) return r; if (node->char_len < 0) { r = get_char_length_tree(NODE_ANCHOR_BODY(node), reg, &n); if (r != 0) return ONIGERR_INVALID_LOOK_BEHIND_PATTERN; } else n = node->char_len; r = add_length(reg, n); if (r != 0) return r; r = compile_tree(NODE_ANCHOR_BODY(node), reg, env); } break; case ANCHOR_LOOK_BEHIND_NOT: { int n; len = compile_length_tree(NODE_ANCHOR_BODY(node), reg); r = add_opcode_rel_addr(reg, OP_LOOK_BEHIND_NOT_START, len + SIZE_OP_LOOK_BEHIND_NOT_END); if (r != 0) return r; if (node->char_len < 0) { r = get_char_length_tree(NODE_ANCHOR_BODY(node), reg, &n); if (r != 0) return ONIGERR_INVALID_LOOK_BEHIND_PATTERN; } else n = node->char_len; r = add_length(reg, n); if (r != 0) return r; r = compile_tree(NODE_ANCHOR_BODY(node), reg, env); if (r != 0) return r; r = add_opcode(reg, OP_LOOK_BEHIND_NOT_END); } break; default: return ONIGERR_TYPE_BUG; break; } return r; } static int compile_gimmick_node(GimmickNode* node, regex_t* reg) { int r; switch (node->type) { case GIMMICK_FAIL: r = add_opcode(reg, OP_FAIL); break; case GIMMICK_KEEP: r = add_opcode(reg, OP_PUSH_SAVE_VAL); if (r != 0) return r; r = add_save_type(reg, SAVE_KEEP); if (r != 0) return r; r = add_mem_num(reg, node->id); break; case GIMMICK_SAVE: r = add_opcode(reg, OP_PUSH_SAVE_VAL); if (r != 0) return r; r = add_save_type(reg, node->detail_type); if (r != 0) return r; r = add_mem_num(reg, node->id); break; case GIMMICK_UPDATE_VAR: r = add_opcode(reg, OP_UPDATE_VAR); if (r != 0) return r; r = add_update_var_type(reg, node->detail_type); if (r != 0) return r; r = add_mem_num(reg, node->id); break; #ifdef USE_CALLOUT case GIMMICK_CALLOUT: switch (node->detail_type) { case ONIG_CALLOUT_OF_CONTENTS: case ONIG_CALLOUT_OF_NAME: { r = add_opcode(reg, (node->detail_type == ONIG_CALLOUT_OF_CONTENTS) ? OP_CALLOUT_CONTENTS : OP_CALLOUT_NAME); if (r != 0) return r; if (node->detail_type == ONIG_CALLOUT_OF_NAME) { r = add_mem_num(reg, node->id); if (r != 0) return r; } r = add_mem_num(reg, node->num); if (r != 0) return r; } break; default: r = ONIGERR_TYPE_BUG; break; } #endif } return r; } static int compile_length_gimmick_node(GimmickNode* node, regex_t* reg) { int len; switch (node->type) { case GIMMICK_FAIL: len = SIZE_OP_FAIL; break; case GIMMICK_KEEP: case GIMMICK_SAVE: len = SIZE_OP_PUSH_SAVE_VAL; break; case GIMMICK_UPDATE_VAR: len = SIZE_OP_UPDATE_VAR; break; #ifdef USE_CALLOUT case GIMMICK_CALLOUT: switch (node->detail_type) { case ONIG_CALLOUT_OF_CONTENTS: len = SIZE_OP_CALLOUT_CONTENTS; break; case ONIG_CALLOUT_OF_NAME: len = SIZE_OP_CALLOUT_NAME; break; default: len = ONIGERR_TYPE_BUG; break; } break; #endif } return len; } static int compile_length_tree(Node* node, regex_t* reg) { int len, r; switch (NODE_TYPE(node)) { case NODE_LIST: len = 0; do { r = compile_length_tree(NODE_CAR(node), reg); if (r < 0) return r; len += r; } while (IS_NOT_NULL(node = NODE_CDR(node))); r = len; break; case NODE_ALT: { int n; n = r = 0; do { r += compile_length_tree(NODE_CAR(node), reg); n++; } while (IS_NOT_NULL(node = NODE_CDR(node))); r += (SIZE_OP_PUSH + SIZE_OP_JUMP) * (n - 1); } break; case NODE_STRING: if (NODE_STRING_IS_RAW(node)) r = compile_length_string_raw_node(STR_(node), reg); else r = compile_length_string_node(node, reg); break; case NODE_CCLASS: r = compile_length_cclass_node(CCLASS_(node), reg); break; case NODE_CTYPE: r = SIZE_OPCODE; break; case NODE_BACKREF: { BackRefNode* br = BACKREF_(node); if (NODE_IS_CHECKER(node)) { #ifdef USE_BACKREF_WITH_LEVEL if (NODE_IS_NEST_LEVEL(node)) { r = SIZE_OPCODE + SIZE_LENGTH + SIZE_LENGTH + (SIZE_MEMNUM * br->back_num); } else #endif r = SIZE_OPCODE + SIZE_LENGTH + (SIZE_MEMNUM * br->back_num); } else { #ifdef USE_BACKREF_WITH_LEVEL if (NODE_IS_NEST_LEVEL(node)) { 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_CALL case NODE_CALL: r = SIZE_OP_CALL; break; #endif case NODE_QUANT: r = compile_length_quantifier_node(QUANT_(node), reg); break; case NODE_ENCLOSURE: r = compile_length_enclosure_node(ENCLOSURE_(node), reg); break; case NODE_ANCHOR: r = compile_length_anchor_node(ANCHOR_(node), reg); break; case NODE_GIMMICK: r = compile_length_gimmick_node(GIMMICK_(node), reg); break; default: return ONIGERR_TYPE_BUG; break; } return r; } static int compile_tree(Node* node, regex_t* reg, ScanEnv* env) { int n, len, pos, r = 0; switch (NODE_TYPE(node)) { case NODE_LIST: do { r = compile_tree(NODE_CAR(node), reg, env); } while (r == 0 && IS_NOT_NULL(node = NODE_CDR(node))); break; case NODE_ALT: { Node* x = node; len = 0; do { len += compile_length_tree(NODE_CAR(x), reg); if (IS_NOT_NULL(NODE_CDR(x))) { len += SIZE_OP_PUSH + SIZE_OP_JUMP; } } while (IS_NOT_NULL(x = NODE_CDR(x))); pos = reg->used + len; /* goal position */ do { len = compile_length_tree(NODE_CAR(node), reg); if (IS_NOT_NULL(NODE_CDR(node))) { enum OpCode push = NODE_IS_SUPER(node) ? OP_PUSH_SUPER : OP_PUSH; r = add_opcode_rel_addr(reg, push, len + SIZE_OP_JUMP); if (r != 0) break; } r = compile_tree(NODE_CAR(node), reg, env); if (r != 0) break; if (IS_NOT_NULL(NODE_CDR(node))) { len = pos - (reg->used + SIZE_OP_JUMP); r = add_opcode_rel_addr(reg, OP_JUMP, len); if (r != 0) break; } } while (IS_NOT_NULL(node = NODE_CDR(node))); } break; case NODE_STRING: if (NODE_STRING_IS_RAW(node)) r = compile_string_raw_node(STR_(node), reg); else r = compile_string_node(node, reg); break; case NODE_CCLASS: r = compile_cclass_node(CCLASS_(node), reg); break; case NODE_CTYPE: { int op; switch (CTYPE_(node)->ctype) { case CTYPE_ANYCHAR: if (IS_MULTILINE(CTYPE_OPTION(node, reg))) r = add_opcode(reg, OP_ANYCHAR_ML); else r = add_opcode(reg, OP_ANYCHAR); break; case ONIGENC_CTYPE_WORD: if (CTYPE_(node)->ascii_mode == 0) { op = CTYPE_(node)->not != 0 ? OP_NO_WORD : OP_WORD; } else { op = CTYPE_(node)->not != 0 ? OP_NO_WORD_ASCII : OP_WORD_ASCII; } r = add_opcode(reg, op); break; default: return ONIGERR_TYPE_BUG; break; } } break; case NODE_BACKREF: { BackRefNode* br = BACKREF_(node); if (NODE_IS_CHECKER(node)) { #ifdef USE_BACKREF_WITH_LEVEL if (NODE_IS_NEST_LEVEL(node)) { r = add_opcode(reg, OP_BACKREF_CHECK_WITH_LEVEL); if (r != 0) return r; r = add_length(reg, br->nest_level); if (r != 0) return r; } else #endif { r = add_opcode(reg, OP_BACKREF_CHECK); if (r != 0) return r; } goto add_bacref_mems; } else { #ifdef USE_BACKREF_WITH_LEVEL if (NODE_IS_NEST_LEVEL(node)) { r = add_opcode(reg, OP_BACKREF_WITH_LEVEL); if (r != 0) return r; r = add_option(reg, (reg->options & ONIG_OPTION_IGNORECASE)); if (r != 0) return r; r = add_length(reg, br->nest_level); if (r != 0) 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_BACKREF_N_IC); if (r != 0) 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_BACKREF_N); if (r != 0) 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 != 0) return r; add_bacref_mems: r = add_length(reg, br->back_num); if (r != 0) return r; p = BACKREFS_P(br); for (i = br->back_num - 1; i >= 0; i--) { r = add_mem_num(reg, p[i]); if (r != 0) return r; } } } } break; #ifdef USE_CALL case NODE_CALL: r = compile_call(CALL_(node), reg, env); break; #endif case NODE_QUANT: r = compile_quantifier_node(QUANT_(node), reg, env); break; case NODE_ENCLOSURE: r = compile_enclosure_node(ENCLOSURE_(node), reg, env); break; case NODE_ANCHOR: r = compile_anchor_node(ANCHOR_(node), reg, env); break; case NODE_GIMMICK: r = compile_gimmick_node(GIMMICK_(node), reg); break; default: #ifdef ONIG_DEBUG fprintf(stderr, "compile_tree: undefined node type %d\n", NODE_TYPE(node)); #endif break; } return r; } static int noname_disable_map(Node** plink, GroupNumRemap* map, int* counter) { int r = 0; Node* node = *plink; switch (NODE_TYPE(node)) { case NODE_LIST: case NODE_ALT: do { r = noname_disable_map(&(NODE_CAR(node)), map, counter); } while (r == 0 && IS_NOT_NULL(node = NODE_CDR(node))); break; case NODE_QUANT: { Node** ptarget = &(NODE_BODY(node)); Node* old = *ptarget; r = noname_disable_map(ptarget, map, counter); if (*ptarget != old && NODE_TYPE(*ptarget) == NODE_QUANT) { onig_reduce_nested_quantifier(node, *ptarget); } } break; case NODE_ENCLOSURE: { EnclosureNode* en = ENCLOSURE_(node); if (en->type == ENCLOSURE_MEMORY) { if (NODE_IS_NAMED_GROUP(node)) { (*counter)++; map[en->m.regnum].new_val = *counter; en->m.regnum = *counter; r = noname_disable_map(&(NODE_BODY(node)), map, counter); } else { *plink = NODE_BODY(node); NODE_BODY(node) = NULL_NODE; onig_node_free(node); r = noname_disable_map(plink, map, counter); } } else if (en->type == ENCLOSURE_IF_ELSE) { r = noname_disable_map(&(NODE_ENCLOSURE_BODY(en)), map, counter); if (r != 0) return r; if (IS_NOT_NULL(en->te.Then)) { r = noname_disable_map(&(en->te.Then), map, counter); if (r != 0) return r; } if (IS_NOT_NULL(en->te.Else)) { r = noname_disable_map(&(en->te.Else), map, counter); if (r != 0) return r; } } else r = noname_disable_map(&(NODE_BODY(node)), map, counter); } break; case NODE_ANCHOR: if (IS_NOT_NULL(NODE_BODY(node))) r = noname_disable_map(&(NODE_BODY(node)), map, counter); break; default: break; } return r; } static int renumber_node_backref(Node* node, GroupNumRemap* map) { int i, pos, n, old_num; int *backs; BackRefNode* bn = BACKREF_(node); if (! NODE_IS_BY_NAME(node)) 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 (NODE_TYPE(node)) { case NODE_LIST: case NODE_ALT: do { r = renumber_by_map(NODE_CAR(node), map); } while (r == 0 && IS_NOT_NULL(node = NODE_CDR(node))); break; case NODE_QUANT: r = renumber_by_map(NODE_BODY(node), map); break; case NODE_ENCLOSURE: { EnclosureNode* en = ENCLOSURE_(node); r = renumber_by_map(NODE_BODY(node), map); if (r != 0) return r; if (en->type == ENCLOSURE_IF_ELSE) { if (IS_NOT_NULL(en->te.Then)) { r = renumber_by_map(en->te.Then, map); if (r != 0) return r; } if (IS_NOT_NULL(en->te.Else)) { r = renumber_by_map(en->te.Else, map); if (r != 0) return r; } } } break; case NODE_BACKREF: r = renumber_node_backref(node, map); break; case NODE_ANCHOR: if (IS_NOT_NULL(NODE_BODY(node))) r = renumber_by_map(NODE_BODY(node), map); break; default: break; } return r; } static int numbered_ref_check(Node* node) { int r = 0; switch (NODE_TYPE(node)) { case NODE_LIST: case NODE_ALT: do { r = numbered_ref_check(NODE_CAR(node)); } while (r == 0 && IS_NOT_NULL(node = NODE_CDR(node))); break; case NODE_ANCHOR: if (IS_NULL(NODE_BODY(node))) break; /* fall */ case NODE_QUANT: r = numbered_ref_check(NODE_BODY(node)); break; case NODE_ENCLOSURE: { EnclosureNode* en = ENCLOSURE_(node); r = numbered_ref_check(NODE_BODY(node)); if (r != 0) return r; if (en->type == ENCLOSURE_IF_ELSE) { if (IS_NOT_NULL(en->te.Then)) { r = numbered_ref_check(en->te.Then); if (r != 0) return r; } if (IS_NOT_NULL(en->te.Else)) { r = numbered_ref_check(en->te.Else); if (r != 0) return r; } } } break; case NODE_BACKREF: if (! NODE_IS_BY_NAME(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; MemStatusType 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_MEMENV(env)[pos] = SCANENV_MEMENV(env)[i]; pos++; } } loc = env->capture_history; MEM_STATUS_CLEAR(env->capture_history); for (i = 1; i <= ONIG_MAX_CAPTURE_HISTORY_GROUP; i++) { if (MEM_STATUS_AT(loc, i)) { MEM_STATUS_ON_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); } #ifdef USE_CALL static int fix_unset_addr_list(UnsetAddrList* uslist, regex_t* reg) { int i, offset; EnclosureNode* en; AbsAddrType addr; for (i = 0; i < uslist->num; i++) { if (! NODE_IS_ADDR_FIXED(uslist->us[i].target)) return ONIGERR_PARSER_BUG; en = ENCLOSURE_(uslist->us[i].target); addr = en->m.called_addr; offset = uslist->us[i].offset; BB_WRITE(reg, offset, &addr, SIZE_ABSADDR); } return 0; } #endif #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 (NODE_TYPE(node)) { case NODE_LIST: do { r = get_char_length_tree1(NODE_CAR(node), reg, &tlen, level); if (r == 0) *len = distance_add(*len, tlen); } while (r == 0 && IS_NOT_NULL(node = NODE_CDR(node))); break; case NODE_ALT: { int tlen2; int varlen = 0; r = get_char_length_tree1(NODE_CAR(node), reg, &tlen, level); while (r == 0 && IS_NOT_NULL(node = NODE_CDR(node))) { r = get_char_length_tree1(NODE_CAR(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 NODE_STRING: { StrNode* sn = STR_(node); UChar *s = sn->s; while (s < sn->end) { s += enclen(reg->enc, s); (*len)++; } } break; case NODE_QUANT: { QuantNode* qn = QUANT_(node); if (qn->lower == qn->upper) { if (qn->upper == 0) { *len = 0; } else { r = get_char_length_tree1(NODE_BODY(node), reg, &tlen, level); if (r == 0) *len = distance_multiply(tlen, qn->lower); } } else r = GET_CHAR_LEN_VARLEN; } break; #ifdef USE_CALL case NODE_CALL: if (! NODE_IS_RECURSION(node)) r = get_char_length_tree1(NODE_BODY(node), reg, len, level); else r = GET_CHAR_LEN_VARLEN; break; #endif case NODE_CTYPE: case NODE_CCLASS: *len = 1; break; case NODE_ENCLOSURE: { EnclosureNode* en = ENCLOSURE_(node); switch (en->type) { case ENCLOSURE_MEMORY: #ifdef USE_CALL if (NODE_IS_CLEN_FIXED(node)) *len = en->char_len; else { r = get_char_length_tree1(NODE_BODY(node), reg, len, level); if (r == 0) { en->char_len = *len; NODE_STATUS_ADD(node, NST_CLEN_FIXED); } } break; #endif case ENCLOSURE_OPTION: case ENCLOSURE_STOP_BACKTRACK: r = get_char_length_tree1(NODE_BODY(node), reg, len, level); break; case ENCLOSURE_IF_ELSE: { int clen, elen; r = get_char_length_tree1(NODE_BODY(node), reg, &clen, level); if (r == 0) { if (IS_NOT_NULL(en->te.Then)) { r = get_char_length_tree1(en->te.Then, reg, &tlen, level); if (r != 0) break; } else tlen = 0; if (IS_NOT_NULL(en->te.Else)) { r = get_char_length_tree1(en->te.Else, reg, &elen, level); if (r != 0) break; } else elen = 0; if (clen + tlen != elen) { r = GET_CHAR_LEN_VARLEN; } else { *len = elen; } } } break; default: break; } } break; case NODE_ANCHOR: case NODE_GIMMICK: break; case NODE_BACKREF: if (NODE_IS_CHECKER(node)) break; /* fall */ 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_exclusive(Node* x, Node* y, regex_t* reg) { int i, len; OnigCodePoint code; UChar *p; NodeType ytype; retry: ytype = NODE_TYPE(y); switch (NODE_TYPE(x)) { case NODE_CTYPE: { if (CTYPE_(x)->ctype == CTYPE_ANYCHAR || CTYPE_(y)->ctype == CTYPE_ANYCHAR) break; switch (ytype) { case NODE_CTYPE: if (CTYPE_(y)->ctype == CTYPE_(x)->ctype && CTYPE_(y)->not != CTYPE_(x)->not && CTYPE_(y)->ascii_mode == CTYPE_(x)->ascii_mode) return 1; else return 0; break; case NODE_CCLASS: swap: { Node* tmp; tmp = x; x = y; y = tmp; goto retry; } break; case NODE_STRING: goto swap; break; default: break; } } break; case NODE_CCLASS: { int range; CClassNode* xc = CCLASS_(x); switch (ytype) { case NODE_CTYPE: switch (CTYPE_(y)->ctype) { case CTYPE_ANYCHAR: return 0; break; case ONIGENC_CTYPE_WORD: if (CTYPE_(y)->not == 0) { if (IS_NULL(xc->mbuf) && !IS_NCCLASS_NOT(xc)) { range = CTYPE_(y)->ascii_mode != 0 ? 128 : SINGLE_BYTE_SIZE; for (i = 0; i < range; i++) { if (BITSET_AT(xc->bs, i)) { if (ONIGENC_IS_CODE_WORD(reg->enc, i)) return 0; } } return 1; } return 0; } else { if (IS_NOT_NULL(xc->mbuf)) return 0; if (IS_NCCLASS_NOT(xc)) return 0; range = CTYPE_(y)->ascii_mode != 0 ? 128 : SINGLE_BYTE_SIZE; for (i = 0; i < range; i++) { if (! ONIGENC_IS_CODE_WORD(reg->enc, i)) { if (BITSET_AT(xc->bs, i)) return 0; } } for (i = range; i < SINGLE_BYTE_SIZE; i++) { if (BITSET_AT(xc->bs, i)) return 0; } return 1; } break; default: break; } break; case NODE_CCLASS: { int v; CClassNode* yc = CCLASS_(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 NODE_STRING: goto swap; break; default: break; } } break; case NODE_STRING: { StrNode* xs = STR_(x); if (NODE_STRING_LEN(x) == 0) break; switch (ytype) { case NODE_CTYPE: switch (CTYPE_(y)->ctype) { case CTYPE_ANYCHAR: break; case ONIGENC_CTYPE_WORD: if (CTYPE_(y)->ascii_mode == 0) { if (ONIGENC_IS_MBC_WORD(reg->enc, xs->s, xs->end)) return CTYPE_(y)->not; else return !(CTYPE_(y)->not); } else { if (ONIGENC_IS_MBC_WORD_ASCII(reg->enc, xs->s, xs->end)) return CTYPE_(y)->not; else return !(CTYPE_(y)->not); } break; default: break; } break; case NODE_CCLASS: { CClassNode* cc = CCLASS_(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 NODE_STRING: { UChar *q; StrNode* ys = STR_(y); len = NODE_STRING_LEN(x); if (len > NODE_STRING_LEN(y)) len = NODE_STRING_LEN(y); if (NODE_STRING_IS_AMBIG(x) || NODE_STRING_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 (NODE_TYPE(node)) { case NODE_BACKREF: case NODE_ALT: #ifdef USE_CALL case NODE_CALL: #endif break; case NODE_CTYPE: if (CTYPE_(node)->ctype == CTYPE_ANYCHAR) break; /* fall */ case NODE_CCLASS: if (exact == 0) { n = node; } break; case NODE_LIST: n = get_head_value_node(NODE_CAR(node), exact, reg); break; case NODE_STRING: { StrNode* sn = STR_(node); if (sn->end <= sn->s) break; if (exact != 0 && !NODE_STRING_IS_RAW(node) && IS_IGNORECASE(reg->options)) { } else { n = node; } } break; case NODE_QUANT: { QuantNode* qn = QUANT_(node); if (qn->lower > 0) { if (IS_NOT_NULL(qn->head_exact)) n = qn->head_exact; else n = get_head_value_node(NODE_BODY(node), exact, reg); } } break; case NODE_ENCLOSURE: { EnclosureNode* en = ENCLOSURE_(node); switch (en->type) { case ENCLOSURE_OPTION: { OnigOptionType options = reg->options; reg->options = ENCLOSURE_(node)->o.options; n = get_head_value_node(NODE_BODY(node), exact, reg); reg->options = options; } break; case ENCLOSURE_MEMORY: case ENCLOSURE_STOP_BACKTRACK: case ENCLOSURE_IF_ELSE: n = get_head_value_node(NODE_BODY(node), exact, reg); break; } } break; case NODE_ANCHOR: if (ANCHOR_(node)->type == ANCHOR_PREC_READ) n = get_head_value_node(NODE_BODY(node), exact, reg); break; case NODE_GIMMICK: default: break; } return n; } static int check_type_tree(Node* node, int type_mask, int enclosure_mask, int anchor_mask) { NodeType type; int r = 0; type = NODE_TYPE(node); if ((NODE_TYPE2BIT(type) & type_mask) == 0) return 1; switch (type) { case NODE_LIST: case NODE_ALT: do { r = check_type_tree(NODE_CAR(node), type_mask, enclosure_mask, anchor_mask); } while (r == 0 && IS_NOT_NULL(node = NODE_CDR(node))); break; case NODE_QUANT: r = check_type_tree(NODE_BODY(node), type_mask, enclosure_mask, anchor_mask); break; case NODE_ENCLOSURE: { EnclosureNode* en = ENCLOSURE_(node); if (((1<type) & enclosure_mask) == 0) return 1; r = check_type_tree(NODE_BODY(node), type_mask, enclosure_mask, anchor_mask); if (r == 0 && en->type == ENCLOSURE_IF_ELSE) { if (IS_NOT_NULL(en->te.Then)) { r = check_type_tree(en->te.Then, type_mask, enclosure_mask, anchor_mask); if (r != 0) break; } if (IS_NOT_NULL(en->te.Else)) { r = check_type_tree(en->te.Else, type_mask, enclosure_mask, anchor_mask); } } } break; case NODE_ANCHOR: type = ANCHOR_(node)->type; if ((type & anchor_mask) == 0) return 1; if (IS_NOT_NULL(NODE_BODY(node))) r = check_type_tree(NODE_BODY(node), type_mask, enclosure_mask, anchor_mask); break; case NODE_GIMMICK: default: break; } return r; } static OnigLen tree_min_len(Node* node, ScanEnv* env) { OnigLen len; OnigLen tmin; len = 0; switch (NODE_TYPE(node)) { case NODE_BACKREF: if (! NODE_IS_CHECKER(node)) { int i; int* backs; MemEnv* mem_env = SCANENV_MEMENV(env); BackRefNode* br = BACKREF_(node); if (NODE_IS_RECURSION(node)) break; backs = BACKREFS_P(br); len = tree_min_len(mem_env[backs[0]].node, env); for (i = 1; i < br->back_num; i++) { tmin = tree_min_len(mem_env[backs[i]].node, env); if (len > tmin) len = tmin; } } break; #ifdef USE_CALL case NODE_CALL: { Node* t = NODE_BODY(node); if (NODE_IS_RECURSION(node)) { if (NODE_IS_MIN_FIXED(t)) len = ENCLOSURE_(t)->min_len; } else len = tree_min_len(t, env); } break; #endif case NODE_LIST: do { tmin = tree_min_len(NODE_CAR(node), env); len = distance_add(len, tmin); } while (IS_NOT_NULL(node = NODE_CDR(node))); break; case NODE_ALT: { Node *x, *y; y = node; do { x = NODE_CAR(y); tmin = tree_min_len(x, env); if (y == node) len = tmin; else if (len > tmin) len = tmin; } while (IS_NOT_NULL(y = NODE_CDR(y))); } break; case NODE_STRING: { StrNode* sn = STR_(node); len = (int )(sn->end - sn->s); } break; case NODE_CTYPE: case NODE_CCLASS: len = ONIGENC_MBC_MINLEN(env->enc); break; case NODE_QUANT: { QuantNode* qn = QUANT_(node); if (qn->lower > 0) { len = tree_min_len(NODE_BODY(node), env); len = distance_multiply(len, qn->lower); } } break; case NODE_ENCLOSURE: { EnclosureNode* en = ENCLOSURE_(node); switch (en->type) { case ENCLOSURE_MEMORY: if (NODE_IS_MIN_FIXED(node)) len = en->min_len; else { if (NODE_IS_MARK1(node)) len = 0; /* recursive */ else { NODE_STATUS_ADD(node, NST_MARK1); len = tree_min_len(NODE_BODY(node), env); NODE_STATUS_REMOVE(node, NST_MARK1); en->min_len = len; NODE_STATUS_ADD(node, NST_MIN_FIXED); } } break; case ENCLOSURE_OPTION: case ENCLOSURE_STOP_BACKTRACK: len = tree_min_len(NODE_BODY(node), env); break; case ENCLOSURE_IF_ELSE: { OnigLen elen; len = tree_min_len(NODE_BODY(node), env); if (IS_NOT_NULL(en->te.Then)) len += tree_min_len(en->te.Then, env); if (IS_NOT_NULL(en->te.Else)) elen = tree_min_len(en->te.Else, env); else elen = 0; if (elen < len) len = elen; } break; } } break; case NODE_GIMMICK: { GimmickNode* g = GIMMICK_(node); if (g->type == GIMMICK_FAIL) { len = INFINITE_LEN; break; } } /* fall */ case NODE_ANCHOR: default: break; } return len; } static OnigLen tree_max_len(Node* node, ScanEnv* env) { OnigLen len; OnigLen tmax; len = 0; switch (NODE_TYPE(node)) { case NODE_LIST: do { tmax = tree_max_len(NODE_CAR(node), env); len = distance_add(len, tmax); } while (IS_NOT_NULL(node = NODE_CDR(node))); break; case NODE_ALT: do { tmax = tree_max_len(NODE_CAR(node), env); if (len < tmax) len = tmax; } while (IS_NOT_NULL(node = NODE_CDR(node))); break; case NODE_STRING: { StrNode* sn = STR_(node); len = (OnigLen )(sn->end - sn->s); } break; case NODE_CTYPE: case NODE_CCLASS: len = ONIGENC_MBC_MAXLEN_DIST(env->enc); break; case NODE_BACKREF: if (! NODE_IS_CHECKER(node)) { int i; int* backs; MemEnv* mem_env = SCANENV_MEMENV(env); BackRefNode* br = BACKREF_(node); if (NODE_IS_RECURSION(node)) { len = INFINITE_LEN; break; } backs = BACKREFS_P(br); for (i = 0; i < br->back_num; i++) { tmax = tree_max_len(mem_env[backs[i]].node, env); if (len < tmax) len = tmax; } } break; #ifdef USE_CALL case NODE_CALL: if (! NODE_IS_RECURSION(node)) len = tree_max_len(NODE_BODY(node), env); else len = INFINITE_LEN; break; #endif case NODE_QUANT: { QuantNode* qn = QUANT_(node); if (qn->upper != 0) { len = tree_max_len(NODE_BODY(node), env); if (len != 0) { if (! IS_REPEAT_INFINITE(qn->upper)) len = distance_multiply(len, qn->upper); else len = INFINITE_LEN; } } } break; case NODE_ENCLOSURE: { EnclosureNode* en = ENCLOSURE_(node); switch (en->type) { case ENCLOSURE_MEMORY: if (NODE_IS_MAX_FIXED(node)) len = en->max_len; else { if (NODE_IS_MARK1(node)) len = INFINITE_LEN; else { NODE_STATUS_ADD(node, NST_MARK1); len = tree_max_len(NODE_BODY(node), env); NODE_STATUS_REMOVE(node, NST_MARK1); en->max_len = len; NODE_STATUS_ADD(node, NST_MAX_FIXED); } } break; case ENCLOSURE_OPTION: case ENCLOSURE_STOP_BACKTRACK: len = tree_max_len(NODE_BODY(node), env); break; case ENCLOSURE_IF_ELSE: { OnigLen tlen, elen; len = tree_max_len(NODE_BODY(node), env); if (IS_NOT_NULL(en->te.Then)) { tlen = tree_max_len(en->te.Then, env); len = distance_add(len, tlen); } if (IS_NOT_NULL(en->te.Else)) elen = tree_max_len(en->te.Else, env); else elen = 0; if (elen > len) len = elen; } break; } } break; case NODE_ANCHOR: case NODE_GIMMICK: default: break; } return len; } static int check_backrefs(Node* node, ScanEnv* env) { int r; switch (NODE_TYPE(node)) { case NODE_LIST: case NODE_ALT: do { r = check_backrefs(NODE_CAR(node), env); } while (r == 0 && IS_NOT_NULL(node = NODE_CDR(node))); break; case NODE_ANCHOR: if (! ANCHOR_HAS_BODY(ANCHOR_(node))) { r = 0; break; } /* fall */ case NODE_QUANT: r = check_backrefs(NODE_BODY(node), env); break; case NODE_ENCLOSURE: r = check_backrefs(NODE_BODY(node), env); { EnclosureNode* en = ENCLOSURE_(node); if (en->type == ENCLOSURE_IF_ELSE) { if (r != 0) return r; if (IS_NOT_NULL(en->te.Then)) { r = check_backrefs(en->te.Then, env); if (r != 0) return r; } if (IS_NOT_NULL(en->te.Else)) { r = check_backrefs(en->te.Else, env); } } } break; case NODE_BACKREF: { int i; BackRefNode* br = BACKREF_(node); int* backs = BACKREFS_P(br); MemEnv* mem_env = SCANENV_MEMENV(env); for (i = 0; i < br->back_num; i++) { if (backs[i] > env->num_mem) return ONIGERR_INVALID_BACKREF; NODE_STATUS_ADD(mem_env[backs[i]].node, NST_BACKREF); } r = 0; } break; default: r = 0; break; } return r; } #ifdef USE_CALL #define RECURSION_EXIST (1<<0) #define RECURSION_MUST (1<<1) #define RECURSION_INFINITE (1<<2) static int infinite_recursive_call_check(Node* node, ScanEnv* env, int head) { int ret; int r = 0; switch (NODE_TYPE(node)) { case NODE_LIST: { Node *x; OnigLen min; x = node; do { ret = infinite_recursive_call_check(NODE_CAR(x), env, head); if (ret < 0 || (ret & RECURSION_INFINITE) != 0) return ret; r |= ret; if (head != 0) { min = tree_min_len(NODE_CAR(x), env); if (min != 0) head = 0; } } while (IS_NOT_NULL(x = NODE_CDR(x))); } break; case NODE_ALT: { int must; must = RECURSION_MUST; do { ret = infinite_recursive_call_check(NODE_CAR(node), env, head); if (ret < 0 || (ret & RECURSION_INFINITE) != 0) return ret; r |= (ret & RECURSION_EXIST); must &= ret; } while (IS_NOT_NULL(node = NODE_CDR(node))); r |= must; } break; case NODE_QUANT: r = infinite_recursive_call_check(NODE_BODY(node), env, head); if (r < 0) return r; if ((r & RECURSION_MUST) != 0) { if (QUANT_(node)->lower == 0) r &= ~RECURSION_MUST; } break; case NODE_ANCHOR: if (! ANCHOR_HAS_BODY(ANCHOR_(node))) break; /* fall */ case NODE_CALL: r = infinite_recursive_call_check(NODE_BODY(node), env, head); break; case NODE_ENCLOSURE: { EnclosureNode* en = ENCLOSURE_(node); if (en->type == ENCLOSURE_MEMORY) { if (NODE_IS_MARK2(node)) return 0; else if (NODE_IS_MARK1(node)) return (head == 0 ? RECURSION_EXIST | RECURSION_MUST : RECURSION_EXIST | RECURSION_MUST | RECURSION_INFINITE); else { NODE_STATUS_ADD(node, NST_MARK2); r = infinite_recursive_call_check(NODE_BODY(node), env, head); NODE_STATUS_REMOVE(node, NST_MARK2); } } else if (en->type == ENCLOSURE_IF_ELSE) { int eret; ret = infinite_recursive_call_check(NODE_BODY(node), env, head); if (ret < 0 || (ret & RECURSION_INFINITE) != 0) return ret; r |= ret; if (IS_NOT_NULL(en->te.Then)) { OnigLen min; if (head != 0) { min = tree_min_len(NODE_BODY(node), env); } else min = 0; ret = infinite_recursive_call_check(en->te.Then, env, min != 0 ? 0:head); if (ret < 0 || (ret & RECURSION_INFINITE) != 0) return ret; r |= ret; } if (IS_NOT_NULL(en->te.Else)) { eret = infinite_recursive_call_check(en->te.Else, env, head); if (eret < 0 || (eret & RECURSION_INFINITE) != 0) return eret; r |= (eret & RECURSION_EXIST); if ((eret & RECURSION_MUST) == 0) r &= ~RECURSION_MUST; } } else { r = infinite_recursive_call_check(NODE_BODY(node), env, head); } } break; default: break; } return r; } static int infinite_recursive_call_check_trav(Node* node, ScanEnv* env) { int r; switch (NODE_TYPE(node)) { case NODE_LIST: case NODE_ALT: do { r = infinite_recursive_call_check_trav(NODE_CAR(node), env); } while (r == 0 && IS_NOT_NULL(node = NODE_CDR(node))); break; case NODE_ANCHOR: if (! ANCHOR_HAS_BODY(ANCHOR_(node))) { r = 0; break; } /* fall */ case NODE_QUANT: r = infinite_recursive_call_check_trav(NODE_BODY(node), env); break; case NODE_ENCLOSURE: { EnclosureNode* en = ENCLOSURE_(node); if (en->type == ENCLOSURE_MEMORY) { if (NODE_IS_RECURSION(node) && NODE_IS_CALLED(node)) { int ret; NODE_STATUS_ADD(node, NST_MARK1); ret = infinite_recursive_call_check(NODE_BODY(node), env, 1); if (ret < 0) return ret; else if ((ret & (RECURSION_MUST | RECURSION_INFINITE)) != 0) return ONIGERR_NEVER_ENDING_RECURSION; NODE_STATUS_REMOVE(node, NST_MARK1); } } else if (en->type == ENCLOSURE_IF_ELSE) { if (IS_NOT_NULL(en->te.Then)) { r = infinite_recursive_call_check_trav(en->te.Then, env); if (r != 0) return r; } if (IS_NOT_NULL(en->te.Else)) { r = infinite_recursive_call_check_trav(en->te.Else, env); if (r != 0) return r; } } } r = infinite_recursive_call_check_trav(NODE_BODY(node), env); break; default: r = 0; break; } return r; } static int recursive_call_check(Node* node) { int r; switch (NODE_TYPE(node)) { case NODE_LIST: case NODE_ALT: r = 0; do { r |= recursive_call_check(NODE_CAR(node)); } while (IS_NOT_NULL(node = NODE_CDR(node))); break; case NODE_ANCHOR: if (! ANCHOR_HAS_BODY(ANCHOR_(node))) { r = 0; break; } /* fall */ case NODE_QUANT: r = recursive_call_check(NODE_BODY(node)); break; case NODE_CALL: r = recursive_call_check(NODE_BODY(node)); if (r != 0) { if (NODE_IS_MARK1(NODE_BODY(node))) NODE_STATUS_ADD(node, NST_RECURSION); } break; case NODE_ENCLOSURE: { EnclosureNode* en = ENCLOSURE_(node); if (en->type == ENCLOSURE_MEMORY) { if (NODE_IS_MARK2(node)) return 0; else if (NODE_IS_MARK1(node)) return 1; /* recursion */ else { NODE_STATUS_ADD(node, NST_MARK2); r = recursive_call_check(NODE_BODY(node)); NODE_STATUS_REMOVE(node, NST_MARK2); } } else if (en->type == ENCLOSURE_IF_ELSE) { r = 0; if (IS_NOT_NULL(en->te.Then)) { r |= recursive_call_check(en->te.Then); } if (IS_NOT_NULL(en->te.Else)) { r |= recursive_call_check(en->te.Else); } r |= recursive_call_check(NODE_BODY(node)); } else { r = recursive_call_check(NODE_BODY(node)); } } break; default: r = 0; break; } return r; } #define IN_RECURSION (1<<0) #define FOUND_CALLED_NODE 1 static int recursive_call_check_trav(Node* node, ScanEnv* env, int state) { int r = 0; switch (NODE_TYPE(node)) { case NODE_LIST: case NODE_ALT: { int ret; do { ret = recursive_call_check_trav(NODE_CAR(node), env, state); if (ret == FOUND_CALLED_NODE) r = FOUND_CALLED_NODE; else if (ret < 0) return ret; } while (IS_NOT_NULL(node = NODE_CDR(node))); } break; case NODE_QUANT: r = recursive_call_check_trav(NODE_BODY(node), env, state); if (QUANT_(node)->upper == 0) { if (r == FOUND_CALLED_NODE) QUANT_(node)->is_refered = 1; } break; case NODE_ANCHOR: { AnchorNode* an = ANCHOR_(node); if (ANCHOR_HAS_BODY(an)) r = recursive_call_check_trav(NODE_ANCHOR_BODY(an), env, state); } break; case NODE_ENCLOSURE: { int ret; int state1; EnclosureNode* en = ENCLOSURE_(node); if (en->type == ENCLOSURE_MEMORY) { if (NODE_IS_CALLED(node) || (state & IN_RECURSION) != 0) { if (! NODE_IS_RECURSION(node)) { NODE_STATUS_ADD(node, NST_MARK1); r = recursive_call_check(NODE_BODY(node)); if (r != 0) NODE_STATUS_ADD(node, NST_RECURSION); NODE_STATUS_REMOVE(node, NST_MARK1); } if (NODE_IS_CALLED(node)) r = FOUND_CALLED_NODE; } } state1 = state; if (NODE_IS_RECURSION(node)) state1 |= IN_RECURSION; ret = recursive_call_check_trav(NODE_BODY(node), env, state1); if (ret == FOUND_CALLED_NODE) r = FOUND_CALLED_NODE; if (en->type == ENCLOSURE_IF_ELSE) { if (IS_NOT_NULL(en->te.Then)) { ret = recursive_call_check_trav(en->te.Then, env, state1); if (ret == FOUND_CALLED_NODE) r = FOUND_CALLED_NODE; } if (IS_NOT_NULL(en->te.Else)) { ret = recursive_call_check_trav(en->te.Else, env, state1); if (ret == FOUND_CALLED_NODE) r = FOUND_CALLED_NODE; } } } break; default: break; } return r; } #endif /* divide different length alternatives in look-behind. (?<=A|B) ==> (?<=A)|(?<=B) (? (?type; head = NODE_ANCHOR_BODY(an); np = NODE_CAR(head); swap_node(node, head); NODE_CAR(node) = head; NODE_BODY(head) = np; np = node; while (IS_NOT_NULL(np = NODE_CDR(np))) { insert_node = onig_node_new_anchor(anc_type, an->ascii_mode); CHECK_NULL_RETURN_MEMERR(insert_node); NODE_BODY(insert_node) = NODE_CAR(np); NODE_CAR(np) = insert_node; } if (anc_type == ANCHOR_LOOK_BEHIND_NOT) { np = node; do { NODE_SET_TYPE(np, NODE_LIST); /* alt -> list */ } while (IS_NOT_NULL(np = NODE_CDR(np))); } return 0; } static int setup_look_behind(Node* node, regex_t* reg, ScanEnv* env) { int r, len; AnchorNode* an = ANCHOR_(node); r = get_char_length_tree(NODE_ANCHOR_BODY(an), 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) { NodeType type; retry: type = NODE_TYPE(node); if (type == NODE_QUANT) { QuantNode* qn = QUANT_(node); if (qn->greedy && IS_REPEAT_INFINITE(qn->upper)) { #ifdef USE_QUANT_PEEK_NEXT Node* n = get_head_value_node(next_node, 1, reg); /* '\0': for UTF-16BE etc... */ if (IS_NOT_NULL(n) && STR_(n)->s[0] != '\0') { qn->next_head_exact = n; } #endif /* automatic posseivation a*b ==> (?>a*)b */ if (qn->lower <= 1) { if (NODE_IS_SIMPLE_TYPE(NODE_BODY(node))) { Node *x, *y; x = get_head_value_node(NODE_BODY(node), 0, reg); if (IS_NOT_NULL(x)) { y = get_head_value_node(next_node, 0, reg); if (IS_NOT_NULL(y) && is_exclusive(x, y, reg)) { Node* en = onig_node_new_enclosure(ENCLOSURE_STOP_BACKTRACK); CHECK_NULL_RETURN_MEMERR(en); NODE_STATUS_ADD(en, NST_STOP_BT_SIMPLE_REPEAT); swap_node(node, en); NODE_BODY(node) = en; } } } } } } else if (type == NODE_ENCLOSURE) { EnclosureNode* en = ENCLOSURE_(node); if (en->type == ENCLOSURE_MEMORY) { node = NODE_BODY(node); goto retry; } } return 0; } static int update_string_node_case_fold(regex_t* reg, Node *node) { UChar *p, *end, buf[ONIGENC_MBC_CASE_FOLD_MAXLEN]; UChar *sbuf, *ebuf, *sp; int r, i, len, sbuf_size; StrNode* sn = STR_(node); end = sn->end; sbuf_size = (int )(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); 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; } NODE_STRING_SET_AMBIG(node); NODE_STRING_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; int len; int 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; NODE_CAR(var_anode) = xnode; anode = onig_node_new_alt(NULL_NODE, NULL_NODE); if (IS_NULL(anode)) goto mem_err; NODE_CAR(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; NODE_CAR(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; } NODE_CAR(an) = xnode; } else { NODE_CAR(an) = snode; } NODE_CDR(var_anode) = an; var_anode = an; } else { NODE_CAR(an) = snode; NODE_CDR(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 = STR_(node); if (NODE_STRING_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); 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 = NODE_CAR(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_INSISTENT_CHECK_CAPTURES_IN_EMPTY_REPEAT static enum QuantBodyEmpty quantifiers_memory_node_info(Node* node) { int r = QUANT_BODY_IS_EMPTY; switch (NODE_TYPE(node)) { case NODE_LIST: case NODE_ALT: { int v; do { v = quantifiers_memory_node_info(NODE_CAR(node)); if (v > r) r = v; } while (IS_NOT_NULL(node = NODE_CDR(node))); } break; #ifdef USE_CALL case NODE_CALL: if (NODE_IS_RECURSION(node)) { return QUANT_BODY_IS_EMPTY_REC; /* tiny version */ } else r = quantifiers_memory_node_info(NODE_BODY(node)); break; #endif case NODE_QUANT: { QuantNode* qn = QUANT_(node); if (qn->upper != 0) { r = quantifiers_memory_node_info(NODE_BODY(node)); } } break; case NODE_ENCLOSURE: { EnclosureNode* en = ENCLOSURE_(node); switch (en->type) { case ENCLOSURE_MEMORY: if (NODE_IS_RECURSION(node)) { return QUANT_BODY_IS_EMPTY_REC; } return QUANT_BODY_IS_EMPTY_MEM; break; case ENCLOSURE_OPTION: case ENCLOSURE_STOP_BACKTRACK: r = quantifiers_memory_node_info(NODE_BODY(node)); break; case ENCLOSURE_IF_ELSE: { int v; r = quantifiers_memory_node_info(NODE_BODY(node)); if (IS_NOT_NULL(en->te.Then)) { v = quantifiers_memory_node_info(en->te.Then); if (v > r) r = v; } if (IS_NOT_NULL(en->te.Else)) { v = quantifiers_memory_node_info(en->te.Else); if (v > r) r = v; } } break; default: break; } } break; case NODE_BACKREF: case NODE_STRING: case NODE_CTYPE: case NODE_CCLASS: case NODE_ANCHOR: case NODE_GIMMICK: default: break; } return r; } #endif /* USE_INSISTENT_CHECK_CAPTURES_IN_EMPTY_REPEAT */ #define IN_ALT (1<<0) #define IN_NOT (1<<1) #define IN_REAL_REPEAT (1<<2) #define IN_VAR_REPEAT (1<<3) #define IN_ZERO_REPEAT (1<<4) #define IN_MULTI_ENTRY (1<<5) #ifdef USE_CALL #ifdef __GNUC__ __inline #endif static int setup_call_node_call(CallNode* cn, ScanEnv* env, int state) { MemEnv* mem_env = SCANENV_MEMENV(env); if (cn->by_number != 0) { int gnum = cn->group_num; if (env->num_named > 0 && IS_SYNTAX_BV(env->syntax, ONIG_SYN_CAPTURE_ONLY_NAMED_GROUP) && ! ONIG_IS_OPTION_ON(env->options, ONIG_OPTION_CAPTURE_GROUP)) { return ONIGERR_NUMBERED_BACKREF_OR_CALL_NOT_ALLOWED; } 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; } set_call_attr: NODE_CALL_BODY(cn) = mem_env[cn->group_num].node; if (IS_NULL(NODE_CALL_BODY(cn))) { onig_scan_env_set_error_string(env, ONIGERR_UNDEFINED_NAME_REFERENCE, cn->name, cn->name_end); return ONIGERR_UNDEFINED_NAME_REFERENCE; } } 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; } } return 0; } static void setup_call2_call(Node* node) { switch (NODE_TYPE(node)) { case NODE_LIST: case NODE_ALT: do { setup_call2_call(NODE_CAR(node)); } while (IS_NOT_NULL(node = NODE_CDR(node))); break; case NODE_QUANT: setup_call2_call(NODE_BODY(node)); break; case NODE_ANCHOR: if (ANCHOR_HAS_BODY(ANCHOR_(node))) setup_call2_call(NODE_BODY(node)); break; case NODE_ENCLOSURE: { EnclosureNode* en = ENCLOSURE_(node); if (en->type == ENCLOSURE_MEMORY) { if (! NODE_IS_MARK1(node)) { NODE_STATUS_ADD(node, NST_MARK1); setup_call2_call(NODE_BODY(node)); NODE_STATUS_REMOVE(node, NST_MARK1); } } else if (en->type == ENCLOSURE_IF_ELSE) { setup_call2_call(NODE_BODY(node)); if (IS_NOT_NULL(en->te.Then)) setup_call2_call(en->te.Then); if (IS_NOT_NULL(en->te.Else)) setup_call2_call(en->te.Else); } else { setup_call2_call(NODE_BODY(node)); } } break; case NODE_CALL: if (! NODE_IS_MARK1(node)) { NODE_STATUS_ADD(node, NST_MARK1); { CallNode* cn = CALL_(node); Node* called = NODE_CALL_BODY(cn); cn->entry_count++; NODE_STATUS_ADD(called, NST_CALLED); ENCLOSURE_(called)->m.entry_count++; setup_call2_call(called); } NODE_STATUS_REMOVE(node, NST_MARK1); } break; default: break; } } static int setup_call(Node* node, ScanEnv* env, int state) { int r; switch (NODE_TYPE(node)) { case NODE_LIST: case NODE_ALT: do { r = setup_call(NODE_CAR(node), env, state); } while (r == 0 && IS_NOT_NULL(node = NODE_CDR(node))); break; case NODE_QUANT: if (QUANT_(node)->upper == 0) state |= IN_ZERO_REPEAT; r = setup_call(NODE_BODY(node), env, state); break; case NODE_ANCHOR: if (ANCHOR_HAS_BODY(ANCHOR_(node))) r = setup_call(NODE_BODY(node), env, state); else r = 0; break; case NODE_ENCLOSURE: { EnclosureNode* en = ENCLOSURE_(node); if (en->type == ENCLOSURE_MEMORY) { if ((state & IN_ZERO_REPEAT) != 0) { NODE_STATUS_ADD(node, NST_IN_ZERO_REPEAT); ENCLOSURE_(node)->m.entry_count--; } r = setup_call(NODE_BODY(node), env, state); } else if (en->type == ENCLOSURE_IF_ELSE) { r = setup_call(NODE_BODY(node), env, state); if (r != 0) return r; if (IS_NOT_NULL(en->te.Then)) { r = setup_call(en->te.Then, env, state); if (r != 0) return r; } if (IS_NOT_NULL(en->te.Else)) r = setup_call(en->te.Else, env, state); } else r = setup_call(NODE_BODY(node), env, state); } break; case NODE_CALL: if ((state & IN_ZERO_REPEAT) != 0) { NODE_STATUS_ADD(node, NST_IN_ZERO_REPEAT); CALL_(node)->entry_count--; } r = setup_call_node_call(CALL_(node), env, state); break; default: r = 0; break; } return r; } static int setup_call2(Node* node) { int r = 0; switch (NODE_TYPE(node)) { case NODE_LIST: case NODE_ALT: do { r = setup_call2(NODE_CAR(node)); } while (r == 0 && IS_NOT_NULL(node = NODE_CDR(node))); break; case NODE_QUANT: if (QUANT_(node)->upper != 0) r = setup_call2(NODE_BODY(node)); break; case NODE_ANCHOR: if (ANCHOR_HAS_BODY(ANCHOR_(node))) r = setup_call2(NODE_BODY(node)); break; case NODE_ENCLOSURE: if (! NODE_IS_IN_ZERO_REPEAT(node)) r = setup_call2(NODE_BODY(node)); { EnclosureNode* en = ENCLOSURE_(node); if (r != 0) return r; if (en->type == ENCLOSURE_IF_ELSE) { if (IS_NOT_NULL(en->te.Then)) { r = setup_call2(en->te.Then); if (r != 0) return r; } if (IS_NOT_NULL(en->te.Else)) r = setup_call2(en->te.Else); } } break; case NODE_CALL: if (! NODE_IS_IN_ZERO_REPEAT(node)) { setup_call2_call(node); } break; default: break; } return r; } static void setup_called_state_call(Node* node, int state) { switch (NODE_TYPE(node)) { case NODE_ALT: state |= IN_ALT; /* fall */ case NODE_LIST: do { setup_called_state_call(NODE_CAR(node), state); } while (IS_NOT_NULL(node = NODE_CDR(node))); break; case NODE_QUANT: { QuantNode* qn = QUANT_(node); if (IS_REPEAT_INFINITE(qn->upper) || qn->upper >= 2) state |= IN_REAL_REPEAT; if (qn->lower != qn->upper) state |= IN_VAR_REPEAT; setup_called_state_call(NODE_QUANT_BODY(qn), state); } break; case NODE_ANCHOR: { AnchorNode* an = ANCHOR_(node); switch (an->type) { case ANCHOR_PREC_READ_NOT: case ANCHOR_LOOK_BEHIND_NOT: state |= IN_NOT; /* fall */ case ANCHOR_PREC_READ: case ANCHOR_LOOK_BEHIND: setup_called_state_call(NODE_ANCHOR_BODY(an), state); break; default: break; } } break; case NODE_ENCLOSURE: { EnclosureNode* en = ENCLOSURE_(node); if (en->type == ENCLOSURE_MEMORY) { if (NODE_IS_MARK1(node)) { if ((~en->m.called_state & state) != 0) { en->m.called_state |= state; setup_called_state_call(NODE_BODY(node), state); } } else { NODE_STATUS_ADD(node, NST_MARK1); en->m.called_state |= state; setup_called_state_call(NODE_BODY(node), state); NODE_STATUS_REMOVE(node, NST_MARK1); } } else if (en->type == ENCLOSURE_IF_ELSE) { if (IS_NOT_NULL(en->te.Then)) { setup_called_state_call(en->te.Then, state); } if (IS_NOT_NULL(en->te.Else)) setup_called_state_call(en->te.Else, state); } else { setup_called_state_call(NODE_BODY(node), state); } } break; case NODE_CALL: setup_called_state_call(NODE_BODY(node), state); break; default: break; } } static void setup_called_state(Node* node, int state) { switch (NODE_TYPE(node)) { case NODE_ALT: state |= IN_ALT; /* fall */ case NODE_LIST: do { setup_called_state(NODE_CAR(node), state); } while (IS_NOT_NULL(node = NODE_CDR(node))); break; #ifdef USE_CALL case NODE_CALL: setup_called_state_call(node, state); break; #endif case NODE_ENCLOSURE: { EnclosureNode* en = ENCLOSURE_(node); switch (en->type) { case ENCLOSURE_MEMORY: if (en->m.entry_count > 1) state |= IN_MULTI_ENTRY; en->m.called_state |= state; /* fall */ case ENCLOSURE_OPTION: case ENCLOSURE_STOP_BACKTRACK: setup_called_state(NODE_BODY(node), state); break; case ENCLOSURE_IF_ELSE: setup_called_state(NODE_BODY(node), state); if (IS_NOT_NULL(en->te.Then)) setup_called_state(en->te.Then, state); if (IS_NOT_NULL(en->te.Else)) setup_called_state(en->te.Else, state); break; } } break; case NODE_QUANT: { QuantNode* qn = QUANT_(node); if (IS_REPEAT_INFINITE(qn->upper) || qn->upper >= 2) state |= IN_REAL_REPEAT; if (qn->lower != qn->upper) state |= IN_VAR_REPEAT; setup_called_state(NODE_QUANT_BODY(qn), state); } break; case NODE_ANCHOR: { AnchorNode* an = ANCHOR_(node); switch (an->type) { case ANCHOR_PREC_READ_NOT: case ANCHOR_LOOK_BEHIND_NOT: state |= IN_NOT; /* fall */ case ANCHOR_PREC_READ: case ANCHOR_LOOK_BEHIND: setup_called_state(NODE_ANCHOR_BODY(an), state); break; default: break; } } break; case NODE_BACKREF: case NODE_STRING: case NODE_CTYPE: case NODE_CCLASS: case NODE_GIMMICK: default: break; } } #endif /* USE_CALL */ static int setup_tree(Node* node, regex_t* reg, int state, ScanEnv* env); #ifdef __GNUC__ __inline #endif static int setup_anchor(Node* node, regex_t* reg, int state, ScanEnv* env) { /* allowed node types in look-behind */ #define ALLOWED_TYPE_IN_LB \ ( BIT_NODE_LIST | BIT_NODE_ALT | BIT_NODE_STRING | BIT_NODE_CCLASS \ | BIT_NODE_CTYPE | BIT_NODE_ANCHOR | BIT_NODE_ENCLOSURE | BIT_NODE_QUANT \ | BIT_NODE_CALL | BIT_NODE_GIMMICK) #define ALLOWED_ENCLOSURE_IN_LB ( 1<type) { case ANCHOR_PREC_READ: r = setup_tree(NODE_ANCHOR_BODY(an), reg, state, env); break; case ANCHOR_PREC_READ_NOT: r = setup_tree(NODE_ANCHOR_BODY(an), reg, (state | IN_NOT), env); break; case ANCHOR_LOOK_BEHIND: { r = check_type_tree(NODE_ANCHOR_BODY(an), ALLOWED_TYPE_IN_LB, ALLOWED_ENCLOSURE_IN_LB, ALLOWED_ANCHOR_IN_LB); if (r < 0) return r; if (r > 0) return ONIGERR_INVALID_LOOK_BEHIND_PATTERN; r = setup_tree(NODE_ANCHOR_BODY(an), reg, state, env); if (r != 0) return r; r = setup_look_behind(node, reg, env); } break; case ANCHOR_LOOK_BEHIND_NOT: { r = check_type_tree(NODE_ANCHOR_BODY(an), ALLOWED_TYPE_IN_LB, ALLOWED_ENCLOSURE_IN_LB_NOT, ALLOWED_ANCHOR_IN_LB_NOT); if (r < 0) return r; if (r > 0) return ONIGERR_INVALID_LOOK_BEHIND_PATTERN; r = setup_tree(NODE_ANCHOR_BODY(an), reg, (state | IN_NOT), env); if (r != 0) return r; r = setup_look_behind(node, reg, env); } break; default: r = 0; break; } return r; } #ifdef __GNUC__ __inline #endif static int setup_quant(Node* node, regex_t* reg, int state, ScanEnv* env) { int r; OnigLen d; QuantNode* qn = QUANT_(node); Node* body = NODE_BODY(node); if ((state & IN_REAL_REPEAT) != 0) { NODE_STATUS_ADD(node, NST_IN_REAL_REPEAT); } if ((state & IN_MULTI_ENTRY) != 0) { NODE_STATUS_ADD(node, NST_IN_MULTI_ENTRY); } if (IS_REPEAT_INFINITE(qn->upper) || qn->upper >= 1) { d = tree_min_len(body, env); if (d == 0) { #ifdef USE_INSISTENT_CHECK_CAPTURES_IN_EMPTY_REPEAT qn->body_empty_info = quantifiers_memory_node_info(body); if (qn->body_empty_info == QUANT_BODY_IS_EMPTY_REC) { if (NODE_TYPE(body) == NODE_ENCLOSURE && ENCLOSURE_(body)->type == ENCLOSURE_MEMORY) { MEM_STATUS_ON(env->bt_mem_end, ENCLOSURE_(body)->m.regnum); } } #else qn->body_empty_info = QUANT_BODY_IS_EMPTY; #endif } } if (IS_REPEAT_INFINITE(qn->upper) || qn->upper >= 2) state |= IN_REAL_REPEAT; if (qn->lower != qn->upper) state |= IN_VAR_REPEAT; r = setup_tree(body, reg, state, env); if (r != 0) return r; /* expand string */ #define EXPAND_STRING_MAX_LENGTH 100 if (NODE_TYPE(body) == NODE_STRING) { if (!IS_REPEAT_INFINITE(qn->lower) && qn->lower == qn->upper && qn->lower > 1 && qn->lower <= EXPAND_STRING_MAX_LENGTH) { int len = NODE_STRING_LEN(body); StrNode* sn = STR_(body); if (len * qn->lower <= EXPAND_STRING_MAX_LENGTH) { int i, n = qn->lower; onig_node_conv_to_str_node(node, STR_(body)->flag); for (i = 0; i < n; i++) { r = onig_node_str_cat(node, sn->s, sn->end); if (r != 0) return r; } onig_node_free(body); return r; } } } #ifdef USE_OP_PUSH_OR_JUMP_EXACT if (qn->greedy && (qn->body_empty_info != QUANT_BODY_IS_NOT_EMPTY)) { if (NODE_TYPE(body) == NODE_QUANT) { QuantNode* tqn = QUANT_(body); 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(NODE_BODY(node), 1, reg); } } #endif return r; } /* setup_tree does the following work. 1. check empty loop. (set qn->body_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 r = 0; switch (NODE_TYPE(node)) { case NODE_LIST: { Node* prev = NULL_NODE; do { r = setup_tree(NODE_CAR(node), reg, state, env); if (IS_NOT_NULL(prev) && r == 0) { r = next_setup(prev, NODE_CAR(node), reg); } prev = NODE_CAR(node); } while (r == 0 && IS_NOT_NULL(node = NODE_CDR(node))); } break; case NODE_ALT: do { r = setup_tree(NODE_CAR(node), reg, (state | IN_ALT), env); } while (r == 0 && IS_NOT_NULL(node = NODE_CDR(node))); break; case NODE_STRING: if (IS_IGNORECASE(reg->options) && !NODE_STRING_IS_RAW(node)) { r = expand_case_fold_string(node, reg); } break; case NODE_BACKREF: { int i; int* p; BackRefNode* br = BACKREF_(node); p = BACKREFS_P(br); for (i = 0; i < br->back_num; i++) { if (p[i] > env->num_mem) return ONIGERR_INVALID_BACKREF; MEM_STATUS_ON(env->backrefed_mem, p[i]); MEM_STATUS_ON(env->bt_mem_start, p[i]); #ifdef USE_BACKREF_WITH_LEVEL if (NODE_IS_NEST_LEVEL(node)) { MEM_STATUS_ON(env->bt_mem_end, p[i]); } #endif } } break; case NODE_ENCLOSURE: { EnclosureNode* en = ENCLOSURE_(node); switch (en->type) { case ENCLOSURE_OPTION: { OnigOptionType options = reg->options; reg->options = ENCLOSURE_(node)->o.options; r = setup_tree(NODE_BODY(node), reg, state, env); reg->options = options; } break; case ENCLOSURE_MEMORY: #ifdef USE_CALL state |= en->m.called_state; #endif if ((state & (IN_ALT | IN_NOT | IN_VAR_REPEAT | IN_MULTI_ENTRY)) != 0 || NODE_IS_RECURSION(node)) { MEM_STATUS_ON(env->bt_mem_start, en->m.regnum); } r = setup_tree(NODE_BODY(node), reg, state, env); break; case ENCLOSURE_STOP_BACKTRACK: { Node* target = NODE_BODY(node); r = setup_tree(target, reg, state, env); if (NODE_TYPE(target) == NODE_QUANT) { QuantNode* tqn = QUANT_(target); if (IS_REPEAT_INFINITE(tqn->upper) && tqn->lower <= 1 && tqn->greedy != 0) { /* (?>a*), a*+ etc... */ if (NODE_IS_SIMPLE_TYPE(NODE_BODY(target))) NODE_STATUS_ADD(node, NST_STOP_BT_SIMPLE_REPEAT); } } } break; case ENCLOSURE_IF_ELSE: r = setup_tree(NODE_BODY(node), reg, (state | IN_ALT), env); if (r != 0) return r; if (IS_NOT_NULL(en->te.Then)) { r = setup_tree(en->te.Then, reg, (state | IN_ALT), env); if (r != 0) return r; } if (IS_NOT_NULL(en->te.Else)) r = setup_tree(en->te.Else, reg, (state | IN_ALT), env); break; } } break; case NODE_QUANT: r = setup_quant(node, reg, state, env); break; case NODE_ANCHOR: r = setup_anchor(node, reg, state, env); break; #ifdef USE_CALL case NODE_CALL: #endif case NODE_CTYPE: case NODE_CCLASS: case NODE_GIMMICK: default: break; } return r; } /* set skip map for Boyer-Moore search */ static int set_bm_skip(UChar* s, UChar* end, OnigEncoding enc ARG_UNUSED, UChar skip[], int** int_skip) { int i, len; len = (int )(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 { OnigLen min; /* min byte length */ OnigLen max; /* max byte length */ } MinMax; typedef struct { MinMax mmd; OnigEncoding enc; OnigOptionType options; OnigCaseFoldType case_fold_flag; ScanEnv* scan_env; } OptEnv; typedef struct { int left; int right; } OptAnc; typedef struct { MinMax mmd; /* position */ OptAnc anc; int reach_end; int ignore_case; int len; UChar s[OPT_EXACT_MAXLEN]; } OptExact; typedef struct { MinMax mmd; /* position */ OptAnc anc; int value; /* weighted value */ UChar map[ONIG_CHAR_TABLE_SIZE]; } OptMap; typedef struct { MinMax len; OptAnc anc; OptExact exb; /* boundary */ OptExact exm; /* middle */ OptExact expr; /* prec read (?=...) */ OptMap map; /* boundary */ } NodeOpt; static int map_position_value(OnigEncoding enc, int i) { static const short int Vals[] = { 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(Vals)/sizeof(Vals[0]))) { if (i == 0 && ONIGENC_MBC_MINLEN(enc) > 1) return 20; else return (int )Vals[i]; } else return 4; /* Take it easy. */ } static int distance_value(MinMax* 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 }; OnigLen d; if (mm->max == INFINITE_LEN) return 0; d = mm->max - mm->min; if (d < (OnigLen )(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(MinMax* d1, MinMax* 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(MinMax* a, MinMax* b) { return (a->min == b->min && a->max == b->max) ? 1 : 0; } static void set_mml(MinMax* l, OnigLen min, OnigLen max) { l->min = min; l->max = max; } static void clear_mml(MinMax* l) { l->min = l->max = 0; } static void copy_mml(MinMax* to, MinMax* from) { to->min = from->min; to->max = from->max; } static void add_mml(MinMax* to, MinMax* from) { to->min = distance_add(to->min, from->min); to->max = distance_add(to->max, from->max); } static void alt_merge_mml(MinMax* to, MinMax* 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(OptAnc* a) { a->left = 0; a->right = 0; } static void copy_opt_anc_info(OptAnc* to, OptAnc* from) { *to = *from; } static void concat_opt_anc_info(OptAnc* to, OptAnc* left, OptAnc* right, OnigLen left_len, OnigLen right_len) { clear_opt_anc_info(to); to->left = left->left; if (left_len == 0) { to->left |= right->left; } to->right = right->right; if (right_len == 0) { to->right |= left->right; } else { to->right |= (left->right & ANCHOR_PREC_READ_NOT); } } static int is_left(int a) { if (a == ANCHOR_END_BUF || a == ANCHOR_SEMI_END_BUF || a == ANCHOR_END_LINE || a == ANCHOR_PREC_READ || a == ANCHOR_PREC_READ_NOT) return 0; return 1; } static int is_set_opt_anc_info(OptAnc* to, int anc) { if ((to->left & anc) != 0) return 1; return ((to->right & anc) != 0 ? 1 : 0); } static void add_opt_anc_info(OptAnc* to, int anc) { if (is_left(anc)) to->left |= anc; else to->right |= anc; } static void remove_opt_anc_info(OptAnc* to, int anc) { if (is_left(anc)) to->left &= ~anc; else to->right &= ~anc; } static void alt_merge_opt_anc_info(OptAnc* to, OptAnc* add) { to->left &= add->left; to->right &= add->right; } static int is_full_opt_exact(OptExact* e) { return (e->len >= OPT_EXACT_MAXLEN ? 1 : 0); } static void clear_opt_exact(OptExact* e) { clear_mml(&e->mmd); clear_opt_anc_info(&e->anc); e->reach_end = 0; e->ignore_case = 0; e->len = 0; e->s[0] = '\0'; } static void copy_opt_exact(OptExact* to, OptExact* from) { *to = *from; } static int concat_opt_exact(OptExact* to, OptExact* add, OnigEncoding enc) { int i, j, len, r; UChar *p, *end; OptAnc tanc; if (! to->ignore_case && add->ignore_case) { if (to->len >= add->len) return 0; /* avoid */ to->ignore_case = 1; } r = 0; p = add->s; end = p + add->len; for (i = to->len; p < end; ) { len = enclen(enc, p); if (i + len > OPT_EXACT_MAXLEN) { r = 1; /* 1:full */ 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 = 0; copy_opt_anc_info(&to->anc, &tanc); return r; } static void concat_opt_exact_str(OptExact* to, UChar* s, UChar* end, OnigEncoding enc) { int i, j, len; UChar *p; for (i = to->len, p = s; p < end && i < OPT_EXACT_MAXLEN; ) { len = enclen(enc, p); 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(OptExact* to, OptExact* add, OptEnv* env) { int i, j, len; if (add->len == 0 || to->len == 0) { clear_opt_exact(to); return ; } if (! is_equal_mml(&to->mmd, &add->mmd)) { clear_opt_exact(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); 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 = 0; } static void select_opt_exact(OnigEncoding enc, OptExact* now, OptExact* alt) { int vn, va; vn = now->len; va = alt->len; if (va == 0) { return ; } else if (vn == 0) { copy_opt_exact(now, alt); return ; } else if (vn <= 2 && va <= 2) { /* ByteValTable[x] is big value --> low price */ va = map_position_value(enc, now->s[0]); vn = map_position_value(enc, alt->s[0]); if (now->len > 1) vn += 5; if (alt->len > 1) va += 5; } if (now->ignore_case == 0) vn *= 2; if (alt->ignore_case == 0) va *= 2; if (comp_distance_value(&now->mmd, &alt->mmd, vn, va) > 0) copy_opt_exact(now, alt); } static void clear_opt_map(OptMap* map) { static const OptMap 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(OptMap)); } static void copy_opt_map(OptMap* to, OptMap* from) { *to = *from; } static void add_char_opt_map(OptMap* m, UChar c, OnigEncoding enc) { if (m->map[c] == 0) { m->map[c] = 1; m->value += map_position_value(enc, c); } } static int add_char_amb_opt_map(OptMap* map, UChar* p, UChar* end, OnigEncoding enc, OnigCaseFoldType 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(map, p[0], enc); fold_flag = DISABLE_CASE_FOLD_MULTI_CHAR(fold_flag); n = ONIGENC_GET_CASE_FOLD_CODES_BY_STR(enc, 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(map, buf[0], enc); } return 0; } static void select_opt_map(OptMap* now, OptMap* alt) { static int z = 1<<15; /* 32768: something big value */ int vn, va; if (alt->value == 0) return ; if (now->value == 0) { copy_opt_map(now, alt); return ; } vn = z / now->value; va = z / alt->value; if (comp_distance_value(&now->mmd, &alt->mmd, vn, va) > 0) copy_opt_map(now, alt); } static int comp_opt_exact_or_map(OptExact* e, OptMap* m) { #define COMP_EM_BASE 20 int ae, am; if (m->value <= 0) return -1; ae = COMP_EM_BASE * e->len * (e->ignore_case ? 1 : 2); am = COMP_EM_BASE * 5 * 2 / m->value; return comp_distance_value(&e->mmd, &m->mmd, ae, am); } static void alt_merge_opt_map(OnigEncoding enc, OptMap* to, OptMap* 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(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(NodeOpt* opt, MinMax* plen) { copy_mml(&(opt->exb.mmd), plen); copy_mml(&(opt->expr.mmd), plen); copy_mml(&(opt->map.mmd), plen); } static void clear_node_opt_info(NodeOpt* opt) { clear_mml(&opt->len); clear_opt_anc_info(&opt->anc); clear_opt_exact(&opt->exb); clear_opt_exact(&opt->exm); clear_opt_exact(&opt->expr); clear_opt_map(&opt->map); } static void copy_node_opt_info(NodeOpt* to, NodeOpt* from) { *to = *from; } static void concat_left_node_opt_info(OnigEncoding enc, NodeOpt* to, NodeOpt* add) { int exb_reach, exm_reach; OptAnc 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 |= to->anc.left; } 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(&to->exb, &add->exb, enc); clear_opt_exact(&add->exb); } else if (exm_reach) { concat_opt_exact(&to->exm, &add->exb, enc); clear_opt_exact(&add->exb); } } select_opt_exact(enc, &to->exm, &add->exb); select_opt_exact(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(enc, &to->exb, &to->expr); else select_opt_exact(enc, &to->exm, &to->expr); } } else if (add->expr.len > 0) { copy_opt_exact(&to->expr, &add->expr); } select_opt_map(&to->map, &add->map); add_mml(&to->len, &add->len); } static void alt_merge_node_opt_info(NodeOpt* to, NodeOpt* add, OptEnv* env) { alt_merge_opt_anc_info(&to->anc, &add->anc); alt_merge_opt_exact(&to->exb, &add->exb, env); alt_merge_opt_exact(&to->exm, &add->exm, env); alt_merge_opt_exact(&to->expr, &add->expr, env); alt_merge_opt_map(env->enc, &to->map, &add->map); alt_merge_mml(&to->len, &add->len); } #define MAX_NODE_OPT_INFO_REF_COUNT 5 static int optimize_nodes(Node* node, NodeOpt* opt, OptEnv* env) { int i; int r; NodeOpt xo; OnigEncoding enc; r = 0; enc = env->enc; clear_node_opt_info(opt); set_bound_node_opt_info(opt, &env->mmd); switch (NODE_TYPE(node)) { case NODE_LIST: { OptEnv nenv; Node* nd = node; copy_opt_env(&nenv, env); do { r = optimize_nodes(NODE_CAR(nd), &xo, &nenv); if (r == 0) { add_mml(&nenv.mmd, &xo.len); concat_left_node_opt_info(enc, opt, &xo); } } while (r == 0 && IS_NOT_NULL(nd = NODE_CDR(nd))); } break; case NODE_ALT: { Node* nd = node; do { r = optimize_nodes(NODE_CAR(nd), &xo, env); if (r == 0) { if (nd == node) copy_node_opt_info(opt, &xo); else alt_merge_node_opt_info(opt, &xo, env); } } while ((r == 0) && IS_NOT_NULL(nd = NODE_CDR(nd))); } break; case NODE_STRING: { StrNode* sn = STR_(node); int slen = (int )(sn->end - sn->s); /* int is_raw = NODE_STRING_IS_RAW(node); */ if (! NODE_STRING_IS_AMBIG(node)) { concat_opt_exact_str(&opt->exb, sn->s, sn->end, enc); if (slen > 0) { add_char_opt_map(&opt->map, *(sn->s), enc); } set_mml(&opt->len, slen, slen); } else { int max; if (NODE_STRING_IS_DONT_GET_OPT_INFO(node)) { int n = onigenc_strlen(enc, sn->s, sn->end); max = ONIGENC_MBC_MAXLEN_DIST(enc) * n; } else { concat_opt_exact_str(&opt->exb, sn->s, sn->end, enc); opt->exb.ignore_case = 1; if (slen > 0) { r = add_char_amb_opt_map(&opt->map, sn->s, sn->end, 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 NODE_CCLASS: { int z; CClassNode* cc = CCLASS_(node); /* no need to check ignore case. (set in setup_tree()) */ if (IS_NOT_NULL(cc->mbuf) || IS_NCCLASS_NOT(cc)) { OnigLen min = ONIGENC_MBC_MINLEN(enc); OnigLen max = ONIGENC_MBC_MAXLEN_DIST(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(&opt->map, (UChar )i, enc); } } set_mml(&opt->len, 1, 1); } } break; case NODE_CTYPE: { int min, max; int range; max = ONIGENC_MBC_MAXLEN_DIST(enc); if (max == 1) { min = 1; switch (CTYPE_(node)->ctype) { case CTYPE_ANYCHAR: break; case ONIGENC_CTYPE_WORD: range = CTYPE_(node)->ascii_mode != 0 ? 128 : SINGLE_BYTE_SIZE; if (CTYPE_(node)->not != 0) { for (i = 0; i < range; i++) { if (! ONIGENC_IS_CODE_WORD(enc, i)) { add_char_opt_map(&opt->map, (UChar )i, enc); } } for (i = range; i < SINGLE_BYTE_SIZE; i++) { add_char_opt_map(&opt->map, (UChar )i, enc); } } else { for (i = 0; i < range; i++) { if (ONIGENC_IS_CODE_WORD(enc, i)) { add_char_opt_map(&opt->map, (UChar )i, enc); } } } break; } } else { min = ONIGENC_MBC_MINLEN(enc); } set_mml(&opt->len, min, max); } break; case NODE_ANCHOR: switch (ANCHOR_(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: case ANCHOR_PREC_READ_NOT: case ANCHOR_LOOK_BEHIND: add_opt_anc_info(&opt->anc, ANCHOR_(node)->type); break; case ANCHOR_PREC_READ: { r = optimize_nodes(NODE_BODY(node), &xo, env); if (r == 0) { if (xo.exb.len > 0) copy_opt_exact(&opt->expr, &xo.exb); else if (xo.exm.len > 0) copy_opt_exact(&opt->expr, &xo.exm); opt->expr.reach_end = 0; if (xo.map.value > 0) copy_opt_map(&opt->map, &xo.map); } } break; case ANCHOR_LOOK_BEHIND_NOT: break; } break; case NODE_BACKREF: if (! NODE_IS_CHECKER(node)) { int* backs; OnigLen min, max, tmin, tmax; MemEnv* mem_env = SCANENV_MEMENV(env->scan_env); BackRefNode* br = BACKREF_(node); if (NODE_IS_RECURSION(node)) { set_mml(&opt->len, 0, INFINITE_LEN); break; } backs = BACKREFS_P(br); min = tree_min_len(mem_env[backs[0]].node, env->scan_env); max = tree_max_len(mem_env[backs[0]].node, env->scan_env); for (i = 1; i < br->back_num; i++) { tmin = tree_min_len(mem_env[backs[i]].node, env->scan_env); tmax = tree_max_len(mem_env[backs[i]].node, env->scan_env); if (min > tmin) min = tmin; if (max < tmax) max = tmax; } set_mml(&opt->len, min, max); } break; #ifdef USE_CALL case NODE_CALL: if (NODE_IS_RECURSION(node)) set_mml(&opt->len, 0, INFINITE_LEN); else { OnigOptionType save = env->options; env->options = ENCLOSURE_(NODE_BODY(node))->o.options; r = optimize_nodes(NODE_BODY(node), opt, env); env->options = save; } break; #endif case NODE_QUANT: { OnigLen min, max; QuantNode* qn = QUANT_(node); r = optimize_nodes(NODE_BODY(node), &xo, env); if (r != 0) break; if (qn->lower > 0) { copy_node_opt_info(opt, &xo); if (xo.exb.len > 0) { if (xo.exb.reach_end) { for (i = 2; i <= qn->lower && ! is_full_opt_exact(&opt->exb); i++) { int rc = concat_opt_exact(&opt->exb, &xo.exb, enc); if (rc > 0) break; } 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; } if (IS_REPEAT_INFINITE(qn->upper)) { if (env->mmd.max == 0 && NODE_IS_ANYCHAR(NODE_BODY(node)) && qn->greedy != 0) { if (IS_MULTILINE(CTYPE_OPTION(NODE_QUANT_BODY(qn), env))) add_opt_anc_info(&opt->anc, ANCHOR_ANYCHAR_INF_ML); else add_opt_anc_info(&opt->anc, ANCHOR_ANYCHAR_INF); } max = (xo.len.max > 0 ? INFINITE_LEN : 0); } else { max = distance_multiply(xo.len.max, qn->upper); } min = distance_multiply(xo.len.min, qn->lower); set_mml(&opt->len, min, max); } break; case NODE_ENCLOSURE: { EnclosureNode* en = ENCLOSURE_(node); switch (en->type) { case ENCLOSURE_OPTION: { OnigOptionType save = env->options; env->options = en->o.options; r = optimize_nodes(NODE_BODY(node), opt, env); env->options = save; } break; case ENCLOSURE_MEMORY: #ifdef USE_CALL en->opt_count++; if (en->opt_count > MAX_NODE_OPT_INFO_REF_COUNT) { OnigLen min, max; min = 0; max = INFINITE_LEN; if (NODE_IS_MIN_FIXED(node)) min = en->min_len; if (NODE_IS_MAX_FIXED(node)) max = en->max_len; set_mml(&opt->len, min, max); } else #endif { r = optimize_nodes(NODE_BODY(node), opt, env); if (is_set_opt_anc_info(&opt->anc, ANCHOR_ANYCHAR_INF_MASK)) { if (MEM_STATUS_AT0(env->scan_env->backrefed_mem, en->m.regnum)) remove_opt_anc_info(&opt->anc, ANCHOR_ANYCHAR_INF_MASK); } } break; case ENCLOSURE_STOP_BACKTRACK: r = optimize_nodes(NODE_BODY(node), opt, env); break; case ENCLOSURE_IF_ELSE: { OptEnv nenv; copy_opt_env(&nenv, env); r = optimize_nodes(NODE_ENCLOSURE_BODY(en), &xo, &nenv); if (r == 0) { add_mml(&nenv.mmd, &xo.len); concat_left_node_opt_info(enc, opt, &xo); if (IS_NOT_NULL(en->te.Then)) { r = optimize_nodes(en->te.Then, &xo, &nenv); if (r == 0) { concat_left_node_opt_info(enc, opt, &xo); } } if (IS_NOT_NULL(en->te.Else)) { r = optimize_nodes(en->te.Else, &xo, env); if (r == 0) alt_merge_node_opt_info(opt, &xo, env); } } } break; } } break; case NODE_GIMMICK: break; default: #ifdef ONIG_DEBUG fprintf(stderr, "optimize_nodes: undefined node type %d\n", NODE_TYPE(node)); #endif r = ONIGERR_TYPE_BUG; break; } return r; } static int set_optimize_exact(regex_t* reg, OptExact* 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 = OPTIMIZE_EXACT_IC; } else { int allow_reverse; reg->exact = onigenc_strdup(reg->enc, 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 != 0) return r; reg->optimize = (allow_reverse != 0 ? OPTIMIZE_EXACT_BM : OPTIMIZE_EXACT_BM_NO_REV); } else { reg->optimize = OPTIMIZE_EXACT; } } reg->dmin = e->mmd.min; reg->dmax = e->mmd.max; if (reg->dmin != INFINITE_LEN) { reg->threshold_len = reg->dmin + (int )(reg->exact_end - reg->exact); } return 0; } static void set_optimize_map(regex_t* reg, OptMap* m) { int i; for (i = 0; i < ONIG_CHAR_TABLE_SIZE; i++) reg->map[i] = m->map[i]; reg->optimize = OPTIMIZE_MAP; reg->dmin = m->mmd.min; reg->dmax = m->mmd.max; if (reg->dmin != INFINITE_LEN) { reg->threshold_len = reg->dmin + 1; } } static void set_sub_anchor(regex_t* reg, OptAnc* anc) { reg->sub_anchor |= anc->left & ANCHOR_BEGIN_LINE; reg->sub_anchor |= anc->right & ANCHOR_END_LINE; } #if defined(ONIG_DEBUG_COMPILE) || defined(ONIG_DEBUG_MATCH) 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; NodeOpt 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_nodes(node, &opt, &env); if (r != 0) return r; reg->anchor = opt.anc.left & (ANCHOR_BEGIN_BUF | ANCHOR_BEGIN_POSITION | ANCHOR_ANYCHAR_INF | ANCHOR_ANYCHAR_INF_ML | ANCHOR_LOOK_BEHIND); if ((opt.anc.left & (ANCHOR_LOOK_BEHIND | ANCHOR_PREC_READ_NOT)) != 0) reg->anchor &= ~ANCHOR_ANYCHAR_INF_ML; reg->anchor |= opt.anc.right & (ANCHOR_END_BUF | ANCHOR_SEMI_END_BUF | ANCHOR_PREC_READ_NOT); 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(reg->enc, &opt.exb, &opt.exm); if (opt.map.value > 0 && comp_opt_exact_or_map(&opt.exb, &opt.map) > 0) { goto set_map; } else { r = set_optimize_exact(reg, &opt.exb); set_sub_anchor(reg, &opt.exb.anc); } } else if (opt.map.value > 0) { set_map: set_optimize_map(reg, &opt.map); set_sub_anchor(reg, &opt.map.anc); } else { reg->sub_anchor |= opt.anc.left & ANCHOR_BEGIN_LINE; if (opt.len.max == 0) reg->sub_anchor |= opt.anc.right & 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 = 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"); } #endif /* ONIG_DEBUG */ #if defined(ONIG_DEBUG_COMPILE) || defined(ONIG_DEBUG_MATCH) static void print_distance_range(FILE* f, OnigLen a, OnigLen b) { if (a == INFINITE_LEN) fputs("inf", f); else fprintf(f, "(%u)", a); fputs("-", f); if (b == INFINITE_LEN) 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_INF) { if (q) fprintf(f, ", "); q = 1; fprintf(f, "anychar-inf"); } if (anchor & ANCHOR_ANYCHAR_INF_ML) { if (q) fprintf(f, ", "); fprintf(f, "anychar-inf-ml"); } 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: %ld\n", (reg->exact_end - reg->exact)); } else if (reg->optimize & 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 extern RegexExt* onig_get_regex_ext(regex_t* reg) { if (IS_NULL(REG_EXTP(reg))) { RegexExt* ext = (RegexExt* )xmalloc(sizeof(*ext)); if (IS_NULL(ext)) return 0; ext->pattern = 0; ext->pattern_end = 0; #ifdef USE_CALLOUT ext->tag_table = 0; ext->callout_num = 0; ext->callout_list_alloc = 0; ext->callout_list = 0; #endif REG_EXTPL(reg) = (void* )ext; } return REG_EXTP(reg); } static void free_regex_ext(RegexExt* ext) { if (IS_NOT_NULL(ext)) { if (IS_NOT_NULL(ext->pattern)) xfree((void* )ext->pattern); #ifdef USE_CALLOUT if (IS_NOT_NULL(ext->tag_table)) onig_callout_tag_table_free(ext->tag_table); if (IS_NOT_NULL(ext->callout_list)) onig_free_reg_callout_list(ext->callout_num, ext->callout_list); #endif xfree(ext); } } extern int onig_ext_set_pattern(regex_t* reg, const UChar* pattern, const UChar* pattern_end) { RegexExt* ext; UChar* s; ext = onig_get_regex_ext(reg); CHECK_NULL_RETURN_MEMERR(ext); s = onigenc_strdup(reg->enc, pattern, pattern_end); CHECK_NULL_RETURN_MEMERR(s); ext->pattern = s; ext->pattern_end = s + (pattern_end - pattern); return ONIG_NORMAL; } extern void onig_free_body(regex_t* reg) { if (IS_NOT_NULL(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_EXTP(reg))) { free_regex_ext(REG_EXTP(reg)); REG_EXTPL(reg) = 0; } onig_names_free(reg); } } extern void onig_free(regex_t* reg) { if (IS_NOT_NULL(reg)) { onig_free_body(reg); xfree(reg); } } #define REGEX_TRANSFER(to,from) do {\ onig_free_body(to);\ xmemcpy(to, from, sizeof(regex_t));\ xfree(from);\ } while (0) extern void onig_transfer(regex_t* to, regex_t* from) { REGEX_TRANSFER(to, from); } #ifdef ONIG_DEBUG_PARSE 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_CALL UnsetAddrList uslist; #endif root = 0; if (IS_NOT_NULL(einfo)) { einfo->enc = reg->enc; einfo->par = (UChar* )NULL; } #ifdef ONIG_DEBUG print_enc_string(stderr, reg->enc, pattern, pattern_end); #endif if (reg->alloc == 0) { init_size = (int )(pattern_end - pattern) * 2; if (init_size <= 0) init_size = COMPILE_INIT_SIZE; r = BB_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; r = onig_parse_tree(&root, pattern, pattern_end, reg, &scan_env); if (r != 0) goto err; /* 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; } r = check_backrefs(root, &scan_env); if (r != 0) goto err; #ifdef USE_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_call(root, &scan_env, 0); if (r != 0) goto err_unset; r = setup_call2(root); if (r != 0) goto err_unset; r = recursive_call_check_trav(root, &scan_env, 0); if (r < 0) goto err_unset; r = infinite_recursive_call_check_trav(root, &scan_env); if (r != 0) goto err_unset; setup_called_state(root, 0); } reg->num_call = scan_env.num_call; #endif r = setup_tree(root, reg, 0, &scan_env); if (r != 0) goto err_unset; #ifdef ONIG_DEBUG_PARSE 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)) MEM_STATUS_ON_ALL(reg->bt_mem_end); else { reg->bt_mem_end = scan_env.bt_mem_end; reg->bt_mem_end |= reg->capture_history; } reg->bt_mem_start |= reg->bt_mem_end; 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_env_dynamic)) { xfree(scan_env.mem_env_dynamic); scan_env.mem_env_dynamic = (MemEnv* )NULL; } r = compile_tree(root, reg, &scan_env); if (r == 0) { if (scan_env.keep_num > 0) { r = add_opcode(reg, OP_UPDATE_VAR); if (r != 0) goto err; r = add_update_var_type(reg, UPDATE_VAR_KEEP_FROM_STACK_LAST); if (r != 0) goto err; r = add_mem_num(reg, 0 /* not used */); if (r != 0) goto err; } r = add_opcode(reg, OP_END); #ifdef USE_CALL if (scan_env.num_call > 0) { r = fix_unset_addr_list(&uslist, reg); unset_addr_list_end(&uslist); if (r != 0) goto err; } #endif if ((reg->num_repeat != 0) || (reg->bt_mem_end != 0) #ifdef USE_CALLOUT || (IS_NOT_NULL(REG_EXTP(reg)) && REG_EXTP(reg)->callout_num != 0) #endif ) 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_CALL else if (scan_env.num_call > 0) { unset_addr_list_end(&uslist); } #endif onig_node_free(root); #ifdef ONIG_DEBUG_COMPILE onig_print_names(stderr, reg); onig_print_compiled_byte_code_list(stderr, reg); #endif end: return r; err_unset: #ifdef USE_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->par = scan_env.error; einfo->par_end = scan_env.error_end; } } onig_node_free(root); if (IS_NOT_NULL(scan_env.mem_env_dynamic)) xfree(scan_env.mem_env_dynamic); return r; } static int onig_inited = 0; extern int onig_reg_init(regex_t* reg, OnigOptionType option, OnigCaseFoldType case_fold_flag, OnigEncoding enc, OnigSyntaxType* syntax) { int r; xmemset(reg, 0, sizeof(*reg)); if (onig_inited == 0) { #if 0 return ONIGERR_LIBRARY_IS_NOT_INITIALIZED; #else r = onig_initialize(&enc, 1); if (r != 0) return ONIGERR_FAIL_TO_INITIALIZE; onig_warning("You didn't call onig_initialize() explicitly"); #endif } if (IS_NULL(reg)) return ONIGERR_INVALID_ARGUMENT; 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; } 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_EXTPL(reg) = 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_without_alloc(regex_t* reg, const UChar* pattern, const UChar* pattern_end, OnigOptionType option, OnigEncoding enc, OnigSyntaxType* syntax, OnigErrorInfo* einfo) { int r; r = onig_reg_init(reg, option, ONIGENC_CASE_FOLD_DEFAULT, enc, syntax); if (r != 0) return r; r = onig_compile(reg, pattern, pattern_end, einfo); return r; } extern int onig_new(regex_t** reg, const UChar* pattern, const UChar* pattern_end, OnigOptionType option, OnigEncoding enc, OnigSyntaxType* syntax, OnigErrorInfo* einfo) { int r; *reg = (regex_t* )xmalloc(sizeof(regex_t)); if (IS_NULL(*reg)) return ONIGERR_MEMORY; r = onig_reg_init(*reg, option, ONIGENC_CASE_FOLD_DEFAULT, enc, syntax); if (r != 0) goto err; r = onig_compile(*reg, pattern, pattern_end, einfo); if (r != 0) { err: onig_free(*reg); *reg = NULL; } return r; } extern int onig_initialize(OnigEncoding encodings[], int n) { int i; int r; if (onig_inited != 0) return 0; onigenc_init(); onig_inited = 1; for (i = 0; i < n; i++) { OnigEncoding enc = encodings[i]; r = onig_initialize_encoding(enc); if (r != 0) return r; } return ONIG_NORMAL; } typedef struct EndCallListItem { struct EndCallListItem* next; void (*func)(void); } EndCallListItemType; static EndCallListItemType* EndCallTop; extern void onig_add_end_call(void (*func)(void)) { EndCallListItemType* item; item = (EndCallListItemType* )xmalloc(sizeof(*item)); if (item == 0) return ; item->next = EndCallTop; item->func = func; EndCallTop = item; } static void exec_end_call_list(void) { EndCallListItemType* prev; void (*func)(void); while (EndCallTop != 0) { func = EndCallTop->func; (*func)(); prev = EndCallTop; EndCallTop = EndCallTop->next; xfree(prev); } } extern int onig_end(void) { exec_end_call_list(); #ifdef USE_CALLOUT onig_global_callout_names_free(); #endif onigenc_end(); onig_inited = 0; 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* */ void* cc_arg) { int found; CClassNode* cc = (CClassNode* )cc_arg; 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_PARSE static void p_string(FILE* f, int len, UChar* s) { fputs(":", f); while (len-- > 0) { fputc(*s++, f); } } static void Indent(FILE* f, int indent) { int i; for (i = 0; i < indent; i++) putc(' ', f); } static void print_indent_tree(FILE* f, Node* node, int indent) { int i; NodeType type; UChar* p; int add = 3; Indent(f, indent); if (IS_NULL(node)) { fprintf(f, "ERROR: null node!!!\n"); exit (0); } type = NODE_TYPE(node); switch (type) { case NODE_LIST: case NODE_ALT: if (type == NODE_LIST) fprintf(f, "\n", node); else fprintf(f, "\n", node); print_indent_tree(f, NODE_CAR(node), indent + add); while (IS_NOT_NULL(node = NODE_CDR(node))) { if (NODE_TYPE(node) != type) { fprintf(f, "ERROR: list/alt right is not a cons. %d\n", NODE_TYPE(node)); exit(0); } print_indent_tree(f, NODE_CAR(node), indent + add); } break; case NODE_STRING: fprintf(f, "", (NODE_STRING_IS_RAW(node) ? "-raw" : ""), node); for (p = STR_(node)->s; p < STR_(node)->end; p++) { if (*p >= 0x20 && *p < 0x7f) fputc(*p, f); else { fprintf(f, " 0x%02x", *p); } } break; case NODE_CCLASS: fprintf(f, "", node); if (IS_NCCLASS_NOT(CCLASS_(node))) fputs(" not", f); if (CCLASS_(node)->mbuf) { BBuf* bbuf = CCLASS_(node)->mbuf; for (i = 0; i < bbuf->used; i++) { if (i > 0) fprintf(f, ","); fprintf(f, "%0x", bbuf->p[i]); } } break; case NODE_CTYPE: fprintf(f, " ", node); switch (CTYPE_(node)->ctype) { case CTYPE_ANYCHAR: fprintf(f, "", node); break; case ONIGENC_CTYPE_WORD: if (CTYPE_(node)->not != 0) fputs("not word", f); else fputs("word", f); if (CTYPE_(node)->ascii_mode != 0) fputs(" (ascii)", f); break; default: fprintf(f, "ERROR: undefined ctype.\n"); exit(0); } break; case NODE_ANCHOR: fprintf(f, " ", node); switch (ANCHOR_(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_BOUNDARY: fputs("word boundary", f); break; case ANCHOR_NO_WORD_BOUNDARY: fputs("not word boundary", 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_EXTENDED_GRAPHEME_CLUSTER_BOUNDARY: fputs("extended-grapheme-cluster boundary", f); break; case ANCHOR_NO_EXTENDED_GRAPHEME_CLUSTER_BOUNDARY: fputs("no-extended-grapheme-cluster boundary", f); break; case ANCHOR_PREC_READ: fprintf(f, "prec read\n"); print_indent_tree(f, NODE_BODY(node), indent + add); break; case ANCHOR_PREC_READ_NOT: fprintf(f, "prec read not\n"); print_indent_tree(f, NODE_BODY(node), indent + add); break; case ANCHOR_LOOK_BEHIND: fprintf(f, "look behind\n"); print_indent_tree(f, NODE_BODY(node), indent + add); break; case ANCHOR_LOOK_BEHIND_NOT: fprintf(f, "look behind not\n"); print_indent_tree(f, NODE_BODY(node), indent + add); break; default: fprintf(f, "ERROR: undefined anchor type.\n"); break; } break; case NODE_BACKREF: { int* p; BackRefNode* br = BACKREF_(node); p = BACKREFS_P(br); fprintf(f, "", NODE_IS_CHECKER(node) ? "-checker" : "", node); for (i = 0; i < br->back_num; i++) { if (i > 0) fputs(", ", f); fprintf(f, "%d", p[i]); } } break; #ifdef USE_CALL case NODE_CALL: { CallNode* cn = CALL_(node); fprintf(f, "", node); p_string(f, cn->name_end - cn->name, cn->name); } break; #endif case NODE_QUANT: fprintf(f, "{%d,%d}%s\n", node, QUANT_(node)->lower, QUANT_(node)->upper, (QUANT_(node)->greedy ? "" : "?")); print_indent_tree(f, NODE_BODY(node), indent + add); break; case NODE_ENCLOSURE: fprintf(f, " ", node); switch (ENCLOSURE_(node)->type) { case ENCLOSURE_OPTION: fprintf(f, "option:%d", ENCLOSURE_(node)->o.options); break; case ENCLOSURE_MEMORY: fprintf(f, "memory:%d", ENCLOSURE_(node)->m.regnum); break; case ENCLOSURE_STOP_BACKTRACK: fprintf(f, "stop-bt"); break; default: break; } fprintf(f, "\n"); print_indent_tree(f, NODE_BODY(node), indent + add); break; case NODE_GIMMICK: fprintf(f, " ", node); switch (GIMMICK_(node)->type) { case GIMMICK_FAIL: fprintf(f, "fail"); break; case GIMMICK_KEEP: fprintf(f, "keep:%d", GIMMICK_(node)->id); break; case GIMMICK_SAVE: fprintf(f, "save:%d:%d", GIMMICK_(node)->detail_type, GIMMICK_(node)->id); break; case GIMMICK_UPDATE_VAR: fprintf(f, "update_var:%d:%d", GIMMICK_(node)->detail_type, GIMMICK_(node)->id); break; #ifdef USE_CALLOUT case GIMMICK_CALLOUT: switch (GIMMICK_(node)->detail_type) { case ONIG_CALLOUT_OF_CONTENTS: fprintf(f, "callout:contents:%d", GIMMICK_(node)->num); break; case ONIG_CALLOUT_OF_NAME: fprintf(f, "callout:name:%d:%d", GIMMICK_(node)->id, GIMMICK_(node)->num); break; } #endif } break; default: fprintf(f, "print_indent_tree: undefined node type %d\n", NODE_TYPE(node)); break; } if (type != NODE_LIST && type != NODE_ALT && type != NODE_QUANT && type != NODE_ENCLOSURE) fprintf(f, "\n"); fflush(f); } static void print_tree(FILE* f, Node* node) { print_indent_tree(f, node, 0); } #endif