/* * Secret Labs' Regular Expression Engine * * regular expression matching engine * * partial history: * 1999-10-24 fl created (based on existing template matcher code) * 2000-03-06 fl first alpha, sort of * 2000-08-01 fl fixes for 1.6b1 * 2000-08-07 fl use PyOS_CheckStack() if available * 2000-09-20 fl added expand method * 2001-03-20 fl lots of fixes for 2.1b2 * 2001-04-15 fl export copyright as Python attribute, not global * 2001-04-28 fl added __copy__ methods (work in progress) * 2001-05-14 fl fixes for 1.5.2 compatibility * 2001-07-01 fl added BIGCHARSET support (from Martin von Loewis) * 2001-10-18 fl fixed group reset issue (from Matthew Mueller) * 2001-10-20 fl added split primitive; reenable unicode for 1.6/2.0/2.1 * 2001-10-21 fl added sub/subn primitive * 2001-10-24 fl added finditer primitive (for 2.2 only) * 2001-12-07 fl fixed memory leak in sub/subn (Guido van Rossum) * 2002-11-09 fl fixed empty sub/subn return type * 2003-04-18 mvl fully support 4-byte codes * 2003-10-17 gn implemented non recursive scheme * * Copyright (c) 1997-2001 by Secret Labs AB. All rights reserved. * * This version of the SRE library can be redistributed under CNRI's * Python 1.6 license. For any other use, please contact Secret Labs * AB (info@pythonware.com). * * Portions of this engine have been developed in cooperation with * CNRI. Hewlett-Packard provided funding for 1.6 integration and * other compatibility work. */ #ifndef SRE_RECURSIVE static char copyright[] = " SRE 2.2.2 Copyright (c) 1997-2002 by Secret Labs AB "; #define PY_SSIZE_T_CLEAN #include "Python.h" #include "structmember.h" /* offsetof */ #include "sre.h" #include /* name of this module, minus the leading underscore */ #if !defined(SRE_MODULE) #define SRE_MODULE "sre" #endif #define SRE_PY_MODULE "re" /* defining this one enables tracing */ #undef VERBOSE /* defining this enables unicode support (default under 1.6a1 and later) */ #define HAVE_UNICODE /* -------------------------------------------------------------------- */ /* optional features */ /* enables fast searching */ #define USE_FAST_SEARCH /* enables aggressive inlining (always on for Visual C) */ #undef USE_INLINE /* enables copy/deepcopy handling (work in progress) */ #undef USE_BUILTIN_COPY #if PY_VERSION_HEX < 0x01060000 #define PyObject_DEL(op) PyMem_DEL((op)) #endif /* -------------------------------------------------------------------- */ #if defined(_MSC_VER) #pragma optimize("agtw", on) /* doesn't seem to make much difference... */ #pragma warning(disable: 4710) /* who cares if functions are not inlined ;-) */ /* fastest possible local call under MSVC */ #define LOCAL(type) static __inline type __fastcall #elif defined(USE_INLINE) #define LOCAL(type) static inline type #else #define LOCAL(type) static type #endif /* error codes */ #define SRE_ERROR_ILLEGAL -1 /* illegal opcode */ #define SRE_ERROR_STATE -2 /* illegal state */ #define SRE_ERROR_RECURSION_LIMIT -3 /* runaway recursion */ #define SRE_ERROR_MEMORY -9 /* out of memory */ #define SRE_ERROR_INTERRUPTED -10 /* signal handler raised exception */ #if defined(VERBOSE) #define TRACE(v) printf v #else #define TRACE(v) #endif /* -------------------------------------------------------------------- */ /* search engine state */ /* default character predicates (run sre_chars.py to regenerate tables) */ #define SRE_DIGIT_MASK 1 #define SRE_SPACE_MASK 2 #define SRE_LINEBREAK_MASK 4 #define SRE_ALNUM_MASK 8 #define SRE_WORD_MASK 16 /* FIXME: this assumes ASCII. create tables in init_sre() instead */ static char sre_char_info[128] = { 0, 0, 0, 0, 0, 0, 0, 0, 0, 2, 6, 2, 2, 2, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 2, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 25, 25, 25, 25, 25, 25, 25, 25, 25, 25, 0, 0, 0, 0, 0, 0, 0, 24, 24, 24, 24, 24, 24, 24, 24, 24, 24, 24, 24, 24, 24, 24, 24, 24, 24, 24, 24, 24, 24, 24, 24, 24, 24, 0, 0, 0, 0, 16, 0, 24, 24, 24, 24, 24, 24, 24, 24, 24, 24, 24, 24, 24, 24, 24, 24, 24, 24, 24, 24, 24, 24, 24, 24, 24, 24, 0, 0, 0, 0, 0 }; static char sre_char_lower[128] = { 0, 1, 2, 3, 4, 5, 6, 7, 8, 9, 10, 11, 12, 13, 14, 15, 16, 17, 18, 19, 20, 21, 22, 23, 24, 25, 26, 27, 28, 29, 30, 31, 32, 33, 34, 35, 36, 37, 38, 39, 40, 41, 42, 43, 44, 45, 46, 47, 48, 49, 50, 51, 52, 53, 54, 55, 56, 57, 58, 59, 60, 61, 62, 63, 64, 97, 98, 99, 100, 101, 102, 103, 104, 105, 106, 107, 108, 109, 110, 111, 112, 113, 114, 115, 116, 117, 118, 119, 120, 121, 122, 91, 92, 93, 94, 95, 96, 97, 98, 99, 100, 101, 102, 103, 104, 105, 106, 107, 108, 109, 110, 111, 112, 113, 114, 115, 116, 117, 118, 119, 120, 121, 122, 123, 124, 125, 126, 127 }; #define SRE_IS_DIGIT(ch)\ ((ch) < 128 ? (sre_char_info[(ch)] & SRE_DIGIT_MASK) : 0) #define SRE_IS_SPACE(ch)\ ((ch) < 128 ? (sre_char_info[(ch)] & SRE_SPACE_MASK) : 0) #define SRE_IS_LINEBREAK(ch)\ ((ch) < 128 ? (sre_char_info[(ch)] & SRE_LINEBREAK_MASK) : 0) #define SRE_IS_ALNUM(ch)\ ((ch) < 128 ? (sre_char_info[(ch)] & SRE_ALNUM_MASK) : 0) #define SRE_IS_WORD(ch)\ ((ch) < 128 ? (sre_char_info[(ch)] & SRE_WORD_MASK) : 0) static unsigned int sre_lower(unsigned int ch) { return ((ch) < 128 ? (unsigned int)sre_char_lower[ch] : ch); } /* locale-specific character predicates */ /* !(c & ~N) == (c < N+1) for any unsigned c, this avoids * warnings when c's type supports only numbers < N+1 */ #define SRE_LOC_IS_DIGIT(ch) (!((ch) & ~255) ? isdigit((ch)) : 0) #define SRE_LOC_IS_SPACE(ch) (!((ch) & ~255) ? isspace((ch)) : 0) #define SRE_LOC_IS_LINEBREAK(ch) ((ch) == '\n') #define SRE_LOC_IS_ALNUM(ch) (!((ch) & ~255) ? isalnum((ch)) : 0) #define SRE_LOC_IS_WORD(ch) (SRE_LOC_IS_ALNUM((ch)) || (ch) == '_') static unsigned int sre_lower_locale(unsigned int ch) { return ((ch) < 256 ? (unsigned int)tolower((ch)) : ch); } /* unicode-specific character predicates */ #if defined(HAVE_UNICODE) #define SRE_UNI_IS_DIGIT(ch) Py_UNICODE_ISDIGIT((Py_UNICODE)(ch)) #define SRE_UNI_IS_SPACE(ch) Py_UNICODE_ISSPACE((Py_UNICODE)(ch)) #define SRE_UNI_IS_LINEBREAK(ch) Py_UNICODE_ISLINEBREAK((Py_UNICODE)(ch)) #define SRE_UNI_IS_ALNUM(ch) Py_UNICODE_ISALNUM((Py_UNICODE)(ch)) #define SRE_UNI_IS_WORD(ch) (SRE_UNI_IS_ALNUM((ch)) || (ch) == '_') static unsigned int sre_lower_unicode(unsigned int ch) { return (unsigned int) Py_UNICODE_TOLOWER((Py_UNICODE)(ch)); } #endif LOCAL(int) sre_category(SRE_CODE category, unsigned int ch) { switch (category) { case SRE_CATEGORY_DIGIT: return SRE_IS_DIGIT(ch); case SRE_CATEGORY_NOT_DIGIT: return !SRE_IS_DIGIT(ch); case SRE_CATEGORY_SPACE: return SRE_IS_SPACE(ch); case SRE_CATEGORY_NOT_SPACE: return !SRE_IS_SPACE(ch); case SRE_CATEGORY_WORD: return SRE_IS_WORD(ch); case SRE_CATEGORY_NOT_WORD: return !SRE_IS_WORD(ch); case SRE_CATEGORY_LINEBREAK: return SRE_IS_LINEBREAK(ch); case SRE_CATEGORY_NOT_LINEBREAK: return !SRE_IS_LINEBREAK(ch); case SRE_CATEGORY_LOC_WORD: return SRE_LOC_IS_WORD(ch); case SRE_CATEGORY_LOC_NOT_WORD: return !SRE_LOC_IS_WORD(ch); #if defined(HAVE_UNICODE) case SRE_CATEGORY_UNI_DIGIT: return SRE_UNI_IS_DIGIT(ch); case SRE_CATEGORY_UNI_NOT_DIGIT: return !SRE_UNI_IS_DIGIT(ch); case SRE_CATEGORY_UNI_SPACE: return SRE_UNI_IS_SPACE(ch); case SRE_CATEGORY_UNI_NOT_SPACE: return !SRE_UNI_IS_SPACE(ch); case SRE_CATEGORY_UNI_WORD: return SRE_UNI_IS_WORD(ch); case SRE_CATEGORY_UNI_NOT_WORD: return !SRE_UNI_IS_WORD(ch); case SRE_CATEGORY_UNI_LINEBREAK: return SRE_UNI_IS_LINEBREAK(ch); case SRE_CATEGORY_UNI_NOT_LINEBREAK: return !SRE_UNI_IS_LINEBREAK(ch); #else case SRE_CATEGORY_UNI_DIGIT: return SRE_IS_DIGIT(ch); case SRE_CATEGORY_UNI_NOT_DIGIT: return !SRE_IS_DIGIT(ch); case SRE_CATEGORY_UNI_SPACE: return SRE_IS_SPACE(ch); case SRE_CATEGORY_UNI_NOT_SPACE: return !SRE_IS_SPACE(ch); case SRE_CATEGORY_UNI_WORD: return SRE_LOC_IS_WORD(ch); case SRE_CATEGORY_UNI_NOT_WORD: return !SRE_LOC_IS_WORD(ch); case SRE_CATEGORY_UNI_LINEBREAK: return SRE_IS_LINEBREAK(ch); case SRE_CATEGORY_UNI_NOT_LINEBREAK: return !SRE_IS_LINEBREAK(ch); #endif } return 0; } /* helpers */ static void data_stack_dealloc(SRE_STATE* state) { if (state->data_stack) { PyMem_FREE(state->data_stack); state->data_stack = NULL; } state->data_stack_size = state->data_stack_base = 0; } static int data_stack_grow(SRE_STATE* state, Py_ssize_t size) { Py_ssize_t minsize, cursize; minsize = state->data_stack_base+size; cursize = state->data_stack_size; if (cursize < minsize) { void* stack; cursize = minsize+minsize/4+1024; TRACE(("allocate/grow stack %d\n", cursize)); stack = PyMem_REALLOC(state->data_stack, cursize); if (!stack) { data_stack_dealloc(state); return SRE_ERROR_MEMORY; } state->data_stack = (char *)stack; state->data_stack_size = cursize; } return 0; } /* generate 8-bit version */ #define SRE_CHAR unsigned char #define SRE_AT sre_at #define SRE_COUNT sre_count #define SRE_CHARSET sre_charset #define SRE_INFO sre_info #define SRE_MATCH sre_match #define SRE_MATCH_CONTEXT sre_match_context #define SRE_SEARCH sre_search #define SRE_LITERAL_TEMPLATE sre_literal_template #if defined(HAVE_UNICODE) #define SRE_RECURSIVE #include "_sre.c" #undef SRE_RECURSIVE #undef SRE_LITERAL_TEMPLATE #undef SRE_SEARCH #undef SRE_MATCH #undef SRE_MATCH_CONTEXT #undef SRE_INFO #undef SRE_CHARSET #undef SRE_COUNT #undef SRE_AT #undef SRE_CHAR /* generate 16-bit unicode version */ #define SRE_CHAR Py_UNICODE #define SRE_AT sre_uat #define SRE_COUNT sre_ucount #define SRE_CHARSET sre_ucharset #define SRE_INFO sre_uinfo #define SRE_MATCH sre_umatch #define SRE_MATCH_CONTEXT sre_umatch_context #define SRE_SEARCH sre_usearch #define SRE_LITERAL_TEMPLATE sre_uliteral_template #endif #endif /* SRE_RECURSIVE */ /* -------------------------------------------------------------------- */ /* String matching engine */ /* the following section is compiled twice, with different character settings */ LOCAL(int) SRE_AT(SRE_STATE* state, SRE_CHAR* ptr, SRE_CODE at) { /* check if pointer is at given position */ Py_ssize_t thisp, thatp; switch (at) { case SRE_AT_BEGINNING: case SRE_AT_BEGINNING_STRING: return ((void*) ptr == state->beginning); case SRE_AT_BEGINNING_LINE: return ((void*) ptr == state->beginning || SRE_IS_LINEBREAK((int) ptr[-1])); case SRE_AT_END: return (((void*) (ptr+1) == state->end && SRE_IS_LINEBREAK((int) ptr[0])) || ((void*) ptr == state->end)); case SRE_AT_END_LINE: return ((void*) ptr == state->end || SRE_IS_LINEBREAK((int) ptr[0])); case SRE_AT_END_STRING: return ((void*) ptr == state->end); case SRE_AT_BOUNDARY: if (state->beginning == state->end) return 0; thatp = ((void*) ptr > state->beginning) ? SRE_IS_WORD((int) ptr[-1]) : 0; thisp = ((void*) ptr < state->end) ? SRE_IS_WORD((int) ptr[0]) : 0; return thisp != thatp; case SRE_AT_NON_BOUNDARY: if (state->beginning == state->end) return 0; thatp = ((void*) ptr > state->beginning) ? SRE_IS_WORD((int) ptr[-1]) : 0; thisp = ((void*) ptr < state->end) ? SRE_IS_WORD((int) ptr[0]) : 0; return thisp == thatp; case SRE_AT_LOC_BOUNDARY: if (state->beginning == state->end) return 0; thatp = ((void*) ptr > state->beginning) ? SRE_LOC_IS_WORD((int) ptr[-1]) : 0; thisp = ((void*) ptr < state->end) ? SRE_LOC_IS_WORD((int) ptr[0]) : 0; return thisp != thatp; case SRE_AT_LOC_NON_BOUNDARY: if (state->beginning == state->end) return 0; thatp = ((void*) ptr > state->beginning) ? SRE_LOC_IS_WORD((int) ptr[-1]) : 0; thisp = ((void*) ptr < state->end) ? SRE_LOC_IS_WORD((int) ptr[0]) : 0; return thisp == thatp; #if defined(HAVE_UNICODE) case SRE_AT_UNI_BOUNDARY: if (state->beginning == state->end) return 0; thatp = ((void*) ptr > state->beginning) ? SRE_UNI_IS_WORD((int) ptr[-1]) : 0; thisp = ((void*) ptr < state->end) ? SRE_UNI_IS_WORD((int) ptr[0]) : 0; return thisp != thatp; case SRE_AT_UNI_NON_BOUNDARY: if (state->beginning == state->end) return 0; thatp = ((void*) ptr > state->beginning) ? SRE_UNI_IS_WORD((int) ptr[-1]) : 0; thisp = ((void*) ptr < state->end) ? SRE_UNI_IS_WORD((int) ptr[0]) : 0; return thisp == thatp; #endif } return 0; } LOCAL(int) SRE_CHARSET(SRE_CODE* set, SRE_CODE ch) { /* check if character is a member of the given set */ int ok = 1; for (;;) { switch (*set++) { case SRE_OP_FAILURE: return !ok; case SRE_OP_LITERAL: /* */ if (ch == set[0]) return ok; set++; break; case SRE_OP_CATEGORY: /* */ if (sre_category(set[0], (int) ch)) return ok; set += 1; break; case SRE_OP_CHARSET: if (sizeof(SRE_CODE) == 2) { /* (16 bits per code word) */ if (ch < 256 && (set[ch >> 4] & (1 << (ch & 15)))) return ok; set += 16; } else { /* (32 bits per code word) */ if (ch < 256 && (set[ch >> 5] & (1 << (ch & 31)))) return ok; set += 8; } break; case SRE_OP_RANGE: /* */ if (set[0] <= ch && ch <= set[1]) return ok; set += 2; break; case SRE_OP_NEGATE: ok = !ok; break; case SRE_OP_BIGCHARSET: /* <256 blockindices> */ { Py_ssize_t count, block; count = *(set++); if (sizeof(SRE_CODE) == 2) { block = ((unsigned char*)set)[ch >> 8]; set += 128; if (set[block*16 + ((ch & 255)>>4)] & (1 << (ch & 15))) return ok; set += count*16; } else { /* !(c & ~N) == (c < N+1) for any unsigned c, this avoids * warnings when c's type supports only numbers < N+1 */ if (!(ch & ~65535)) block = ((unsigned char*)set)[ch >> 8]; else block = -1; set += 64; if (block >=0 && (set[block*8 + ((ch & 255)>>5)] & (1 << (ch & 31)))) return ok; set += count*8; } break; } default: /* internal error -- there's not much we can do about it here, so let's just pretend it didn't match... */ return 0; } } } LOCAL(Py_ssize_t) SRE_MATCH(SRE_STATE* state, SRE_CODE* pattern); LOCAL(Py_ssize_t) SRE_COUNT(SRE_STATE* state, SRE_CODE* pattern, Py_ssize_t maxcount) { SRE_CODE chr; SRE_CHAR* ptr = (SRE_CHAR *)state->ptr; SRE_CHAR* end = (SRE_CHAR *)state->end; Py_ssize_t i; /* adjust end */ if (maxcount < end - ptr && maxcount != 65535) end = ptr + maxcount; switch (pattern[0]) { case SRE_OP_IN: /* repeated set */ TRACE(("|%p|%p|COUNT IN\n", pattern, ptr)); while (ptr < end && SRE_CHARSET(pattern + 2, *ptr)) ptr++; break; case SRE_OP_ANY: /* repeated dot wildcard. */ TRACE(("|%p|%p|COUNT ANY\n", pattern, ptr)); while (ptr < end && !SRE_IS_LINEBREAK(*ptr)) ptr++; break; case SRE_OP_ANY_ALL: /* repeated dot wildcard. skip to the end of the target string, and backtrack from there */ TRACE(("|%p|%p|COUNT ANY_ALL\n", pattern, ptr)); ptr = end; break; case SRE_OP_LITERAL: /* repeated literal */ chr = pattern[1]; TRACE(("|%p|%p|COUNT LITERAL %d\n", pattern, ptr, chr)); while (ptr < end && (SRE_CODE) *ptr == chr) ptr++; break; case SRE_OP_LITERAL_IGNORE: /* repeated literal */ chr = pattern[1]; TRACE(("|%p|%p|COUNT LITERAL_IGNORE %d\n", pattern, ptr, chr)); while (ptr < end && (SRE_CODE) state->lower(*ptr) == chr) ptr++; break; case SRE_OP_NOT_LITERAL: /* repeated non-literal */ chr = pattern[1]; TRACE(("|%p|%p|COUNT NOT_LITERAL %d\n", pattern, ptr, chr)); while (ptr < end && (SRE_CODE) *ptr != chr) ptr++; break; case SRE_OP_NOT_LITERAL_IGNORE: /* repeated non-literal */ chr = pattern[1]; TRACE(("|%p|%p|COUNT NOT_LITERAL_IGNORE %d\n", pattern, ptr, chr)); while (ptr < end && (SRE_CODE) state->lower(*ptr) != chr) ptr++; break; default: /* repeated single character pattern */ TRACE(("|%p|%p|COUNT SUBPATTERN\n", pattern, ptr)); while ((SRE_CHAR*) state->ptr < end) { i = SRE_MATCH(state, pattern); if (i < 0) return i; if (!i) break; } TRACE(("|%p|%p|COUNT %d\n", pattern, ptr, (SRE_CHAR*) state->ptr - ptr)); return (SRE_CHAR*) state->ptr - ptr; } TRACE(("|%p|%p|COUNT %d\n", pattern, ptr, ptr - (SRE_CHAR*) state->ptr)); return ptr - (SRE_CHAR*) state->ptr; } #if 0 /* not used in this release */ LOCAL(int) SRE_INFO(SRE_STATE* state, SRE_CODE* pattern) { /* check if an SRE_OP_INFO block matches at the current position. returns the number of SRE_CODE objects to skip if successful, 0 if no match */ SRE_CHAR* end = state->end; SRE_CHAR* ptr = state->ptr; Py_ssize_t i; /* check minimal length */ if (pattern[3] && (end - ptr) < pattern[3]) return 0; /* check known prefix */ if (pattern[2] & SRE_INFO_PREFIX && pattern[5] > 1) { /* */ for (i = 0; i < pattern[5]; i++) if ((SRE_CODE) ptr[i] != pattern[7 + i]) return 0; return pattern[0] + 2 * pattern[6]; } return pattern[0]; } #endif /* The macros below should be used to protect recursive SRE_MATCH() * calls that *failed* and do *not* return immediately (IOW, those * that will backtrack). Explaining: * * - Recursive SRE_MATCH() returned true: that's usually a success * (besides atypical cases like ASSERT_NOT), therefore there's no * reason to restore lastmark; * * - Recursive SRE_MATCH() returned false but the current SRE_MATCH() * is returning to the caller: If the current SRE_MATCH() is the * top function of the recursion, returning false will be a matching * failure, and it doesn't matter where lastmark is pointing to. * If it's *not* the top function, it will be a recursive SRE_MATCH() * failure by itself, and the calling SRE_MATCH() will have to deal * with the failure by the same rules explained here (it will restore * lastmark by itself if necessary); * * - Recursive SRE_MATCH() returned false, and will continue the * outside 'for' loop: must be protected when breaking, since the next * OP could potentially depend on lastmark; * * - Recursive SRE_MATCH() returned false, and will be called again * inside a local for/while loop: must be protected between each * loop iteration, since the recursive SRE_MATCH() could do anything, * and could potentially depend on lastmark. * * For more information, check the discussion at SF patch #712900. */ #define LASTMARK_SAVE() \ do { \ ctx->lastmark = state->lastmark; \ ctx->lastindex = state->lastindex; \ } while (0) #define LASTMARK_RESTORE() \ do { \ state->lastmark = ctx->lastmark; \ state->lastindex = ctx->lastindex; \ } while (0) #define RETURN_ERROR(i) do { return i; } while(0) #define RETURN_FAILURE do { ret = 0; goto exit; } while(0) #define RETURN_SUCCESS do { ret = 1; goto exit; } while(0) #define RETURN_ON_ERROR(i) \ do { if (i < 0) RETURN_ERROR(i); } while (0) #define RETURN_ON_SUCCESS(i) \ do { RETURN_ON_ERROR(i); if (i > 0) RETURN_SUCCESS; } while (0) #define RETURN_ON_FAILURE(i) \ do { RETURN_ON_ERROR(i); if (i == 0) RETURN_FAILURE; } while (0) #define SFY(x) #x #define DATA_STACK_ALLOC(state, type, ptr) \ do { \ alloc_pos = state->data_stack_base; \ TRACE(("allocating %s in %d (%d)\n", \ SFY(type), alloc_pos, sizeof(type))); \ if (state->data_stack_size < alloc_pos+sizeof(type)) { \ int j = data_stack_grow(state, sizeof(type)); \ if (j < 0) return j; \ if (ctx_pos != -1) \ DATA_STACK_LOOKUP_AT(state, SRE_MATCH_CONTEXT, ctx, ctx_pos); \ } \ ptr = (type*)(state->data_stack+alloc_pos); \ state->data_stack_base += sizeof(type); \ } while (0) #define DATA_STACK_LOOKUP_AT(state, type, ptr, pos) \ do { \ TRACE(("looking up %s at %d\n", SFY(type), pos)); \ ptr = (type*)(state->data_stack+pos); \ } while (0) #define DATA_STACK_PUSH(state, data, size) \ do { \ TRACE(("copy data in %p to %d (%d)\n", \ data, state->data_stack_base, size)); \ if (state->data_stack_size < state->data_stack_base+size) { \ int j = data_stack_grow(state, size); \ if (j < 0) return j; \ if (ctx_pos != -1) \ DATA_STACK_LOOKUP_AT(state, SRE_MATCH_CONTEXT, ctx, ctx_pos); \ } \ memcpy(state->data_stack+state->data_stack_base, data, size); \ state->data_stack_base += size; \ } while (0) #define DATA_STACK_POP(state, data, size, discard) \ do { \ TRACE(("copy data to %p from %d (%d)\n", \ data, state->data_stack_base-size, size)); \ memcpy(data, state->data_stack+state->data_stack_base-size, size); \ if (discard) \ state->data_stack_base -= size; \ } while (0) #define DATA_STACK_POP_DISCARD(state, size) \ do { \ TRACE(("discard data from %d (%d)\n", \ state->data_stack_base-size, size)); \ state->data_stack_base -= size; \ } while(0) #define DATA_PUSH(x) \ DATA_STACK_PUSH(state, (x), sizeof(*(x))) #define DATA_POP(x) \ DATA_STACK_POP(state, (x), sizeof(*(x)), 1) #define DATA_POP_DISCARD(x) \ DATA_STACK_POP_DISCARD(state, sizeof(*(x))) #define DATA_ALLOC(t,p) \ DATA_STACK_ALLOC(state, t, p) #define DATA_LOOKUP_AT(t,p,pos) \ DATA_STACK_LOOKUP_AT(state,t,p,pos) #define MARK_PUSH(lastmark) \ do if (lastmark > 0) { \ i = lastmark; /* ctx->lastmark may change if reallocated */ \ DATA_STACK_PUSH(state, state->mark, (i+1)*sizeof(void*)); \ } while (0) #define MARK_POP(lastmark) \ do if (lastmark > 0) { \ DATA_STACK_POP(state, state->mark, (lastmark+1)*sizeof(void*), 1); \ } while (0) #define MARK_POP_KEEP(lastmark) \ do if (lastmark > 0) { \ DATA_STACK_POP(state, state->mark, (lastmark+1)*sizeof(void*), 0); \ } while (0) #define MARK_POP_DISCARD(lastmark) \ do if (lastmark > 0) { \ DATA_STACK_POP_DISCARD(state, (lastmark+1)*sizeof(void*)); \ } while (0) #define JUMP_NONE 0 #define JUMP_MAX_UNTIL_1 1 #define JUMP_MAX_UNTIL_2 2 #define JUMP_MAX_UNTIL_3 3 #define JUMP_MIN_UNTIL_1 4 #define JUMP_MIN_UNTIL_2 5 #define JUMP_MIN_UNTIL_3 6 #define JUMP_REPEAT 7 #define JUMP_REPEAT_ONE_1 8 #define JUMP_REPEAT_ONE_2 9 #define JUMP_MIN_REPEAT_ONE 10 #define JUMP_BRANCH 11 #define JUMP_ASSERT 12 #define JUMP_ASSERT_NOT 13 #define DO_JUMP(jumpvalue, jumplabel, nextpattern) \ DATA_ALLOC(SRE_MATCH_CONTEXT, nextctx); \ nextctx->last_ctx_pos = ctx_pos; \ nextctx->jump = jumpvalue; \ nextctx->pattern = nextpattern; \ ctx_pos = alloc_pos; \ ctx = nextctx; \ goto entrance; \ jumplabel: \ while (0) /* gcc doesn't like labels at end of scopes */ \ typedef struct { Py_ssize_t last_ctx_pos; Py_ssize_t jump; SRE_CHAR* ptr; SRE_CODE* pattern; Py_ssize_t count; Py_ssize_t lastmark; Py_ssize_t lastindex; union { SRE_CODE chr; SRE_REPEAT* rep; } u; } SRE_MATCH_CONTEXT; /* check if string matches the given pattern. returns <0 for error, 0 for failure, and 1 for success */ LOCAL(Py_ssize_t) SRE_MATCH(SRE_STATE* state, SRE_CODE* pattern) { SRE_CHAR* end = (SRE_CHAR *)state->end; Py_ssize_t alloc_pos, ctx_pos = -1; Py_ssize_t i, ret = 0; Py_ssize_t jump; unsigned int sigcount=0; SRE_MATCH_CONTEXT* ctx; SRE_MATCH_CONTEXT* nextctx; TRACE(("|%p|%p|ENTER\n", pattern, state->ptr)); DATA_ALLOC(SRE_MATCH_CONTEXT, ctx); ctx->last_ctx_pos = -1; ctx->jump = JUMP_NONE; ctx->pattern = pattern; ctx_pos = alloc_pos; entrance: ctx->ptr = (SRE_CHAR *)state->ptr; if (ctx->pattern[0] == SRE_OP_INFO) { /* optimization info block */ /* <1=skip> <2=flags> <3=min> ... */ if (ctx->pattern[3] && (end - ctx->ptr) < ctx->pattern[3]) { TRACE(("reject (got %d chars, need %d)\n", (end - ctx->ptr), ctx->pattern[3])); RETURN_FAILURE; } ctx->pattern += ctx->pattern[1] + 1; } for (;;) { ++sigcount; if ((0 == (sigcount & 0xfff)) && PyErr_CheckSignals()) RETURN_ERROR(SRE_ERROR_INTERRUPTED); switch (*ctx->pattern++) { case SRE_OP_MARK: /* set mark */ /* */ TRACE(("|%p|%p|MARK %d\n", ctx->pattern, ctx->ptr, ctx->pattern[0])); i = ctx->pattern[0]; if (i & 1) state->lastindex = i/2 + 1; if (i > state->lastmark) { /* state->lastmark is the highest valid index in the state->mark array. If it is increased by more than 1, the intervening marks must be set to NULL to signal that these marks have not been encountered. */ Py_ssize_t j = state->lastmark + 1; while (j < i) state->mark[j++] = NULL; state->lastmark = i; } state->mark[i] = ctx->ptr; ctx->pattern++; break; case SRE_OP_LITERAL: /* match literal string */ /* */ TRACE(("|%p|%p|LITERAL %d\n", ctx->pattern, ctx->ptr, *ctx->pattern)); if (ctx->ptr >= end || (SRE_CODE) ctx->ptr[0] != ctx->pattern[0]) RETURN_FAILURE; ctx->pattern++; ctx->ptr++; break; case SRE_OP_NOT_LITERAL: /* match anything that is not literal character */ /* */ TRACE(("|%p|%p|NOT_LITERAL %d\n", ctx->pattern, ctx->ptr, *ctx->pattern)); if (ctx->ptr >= end || (SRE_CODE) ctx->ptr[0] == ctx->pattern[0]) RETURN_FAILURE; ctx->pattern++; ctx->ptr++; break; case SRE_OP_SUCCESS: /* end of pattern */ TRACE(("|%p|%p|SUCCESS\n", ctx->pattern, ctx->ptr)); state->ptr = ctx->ptr; RETURN_SUCCESS; case SRE_OP_AT: /* match at given position */ /* */ TRACE(("|%p|%p|AT %d\n", ctx->pattern, ctx->ptr, *ctx->pattern)); if (!SRE_AT(state, ctx->ptr, *ctx->pattern)) RETURN_FAILURE; ctx->pattern++; break; case SRE_OP_CATEGORY: /* match at given category */ /* */ TRACE(("|%p|%p|CATEGORY %d\n", ctx->pattern, ctx->ptr, *ctx->pattern)); if (ctx->ptr >= end || !sre_category(ctx->pattern[0], ctx->ptr[0])) RETURN_FAILURE; ctx->pattern++; ctx->ptr++; break; case SRE_OP_ANY: /* match anything (except a newline) */ /* */ TRACE(("|%p|%p|ANY\n", ctx->pattern, ctx->ptr)); if (ctx->ptr >= end || SRE_IS_LINEBREAK(ctx->ptr[0])) RETURN_FAILURE; ctx->ptr++; break; case SRE_OP_ANY_ALL: /* match anything */ /* */ TRACE(("|%p|%p|ANY_ALL\n", ctx->pattern, ctx->ptr)); if (ctx->ptr >= end) RETURN_FAILURE; ctx->ptr++; break; case SRE_OP_IN: /* match set member (or non_member) */ /* */ TRACE(("|%p|%p|IN\n", ctx->pattern, ctx->ptr)); if (ctx->ptr >= end || !SRE_CHARSET(ctx->pattern + 1, *ctx->ptr)) RETURN_FAILURE; ctx->pattern += ctx->pattern[0]; ctx->ptr++; break; case SRE_OP_LITERAL_IGNORE: TRACE(("|%p|%p|LITERAL_IGNORE %d\n", ctx->pattern, ctx->ptr, ctx->pattern[0])); if (ctx->ptr >= end || state->lower(*ctx->ptr) != state->lower(*ctx->pattern)) RETURN_FAILURE; ctx->pattern++; ctx->ptr++; break; case SRE_OP_NOT_LITERAL_IGNORE: TRACE(("|%p|%p|NOT_LITERAL_IGNORE %d\n", ctx->pattern, ctx->ptr, *ctx->pattern)); if (ctx->ptr >= end || state->lower(*ctx->ptr) == state->lower(*ctx->pattern)) RETURN_FAILURE; ctx->pattern++; ctx->ptr++; break; case SRE_OP_IN_IGNORE: TRACE(("|%p|%p|IN_IGNORE\n", ctx->pattern, ctx->ptr)); if (ctx->ptr >= end || !SRE_CHARSET(ctx->pattern+1, (SRE_CODE)state->lower(*ctx->ptr))) RETURN_FAILURE; ctx->pattern += ctx->pattern[0]; ctx->ptr++; break; case SRE_OP_JUMP: case SRE_OP_INFO: /* jump forward */ /* */ TRACE(("|%p|%p|JUMP %d\n", ctx->pattern, ctx->ptr, ctx->pattern[0])); ctx->pattern += ctx->pattern[0]; break; case SRE_OP_BRANCH: /* alternation */ /* <0=skip> code ... */ TRACE(("|%p|%p|BRANCH\n", ctx->pattern, ctx->ptr)); LASTMARK_SAVE(); ctx->u.rep = state->repeat; if (ctx->u.rep) MARK_PUSH(ctx->lastmark); for (; ctx->pattern[0]; ctx->pattern += ctx->pattern[0]) { if (ctx->pattern[1] == SRE_OP_LITERAL && (ctx->ptr >= end || (SRE_CODE) *ctx->ptr != ctx->pattern[2])) continue; if (ctx->pattern[1] == SRE_OP_IN && (ctx->ptr >= end || !SRE_CHARSET(ctx->pattern + 3, (SRE_CODE) *ctx->ptr))) continue; state->ptr = ctx->ptr; DO_JUMP(JUMP_BRANCH, jump_branch, ctx->pattern+1); if (ret) { if (ctx->u.rep) MARK_POP_DISCARD(ctx->lastmark); RETURN_ON_ERROR(ret); RETURN_SUCCESS; } if (ctx->u.rep) MARK_POP_KEEP(ctx->lastmark); LASTMARK_RESTORE(); } if (ctx->u.rep) MARK_POP_DISCARD(ctx->lastmark); RETURN_FAILURE; case SRE_OP_REPEAT_ONE: /* match repeated sequence (maximizing regexp) */ /* this operator only works if the repeated item is exactly one character wide, and we're not already collecting backtracking points. for other cases, use the MAX_REPEAT operator */ /* <1=min> <2=max> item tail */ TRACE(("|%p|%p|REPEAT_ONE %d %d\n", ctx->pattern, ctx->ptr, ctx->pattern[1], ctx->pattern[2])); if (ctx->ptr + ctx->pattern[1] > end) RETURN_FAILURE; /* cannot match */ state->ptr = ctx->ptr; ret = SRE_COUNT(state, ctx->pattern+3, ctx->pattern[2]); RETURN_ON_ERROR(ret); DATA_LOOKUP_AT(SRE_MATCH_CONTEXT, ctx, ctx_pos); ctx->count = ret; ctx->ptr += ctx->count; /* when we arrive here, count contains the number of matches, and ctx->ptr points to the tail of the target string. check if the rest of the pattern matches, and backtrack if not. */ if (ctx->count < (Py_ssize_t) ctx->pattern[1]) RETURN_FAILURE; if (ctx->pattern[ctx->pattern[0]] == SRE_OP_SUCCESS) { /* tail is empty. we're finished */ state->ptr = ctx->ptr; RETURN_SUCCESS; } LASTMARK_SAVE(); if (ctx->pattern[ctx->pattern[0]] == SRE_OP_LITERAL) { /* tail starts with a literal. skip positions where the rest of the pattern cannot possibly match */ ctx->u.chr = ctx->pattern[ctx->pattern[0]+1]; for (;;) { while (ctx->count >= (Py_ssize_t) ctx->pattern[1] && (ctx->ptr >= end || *ctx->ptr != ctx->u.chr)) { ctx->ptr--; ctx->count--; } if (ctx->count < (Py_ssize_t) ctx->pattern[1]) break; state->ptr = ctx->ptr; DO_JUMP(JUMP_REPEAT_ONE_1, jump_repeat_one_1, ctx->pattern+ctx->pattern[0]); if (ret) { RETURN_ON_ERROR(ret); RETURN_SUCCESS; } LASTMARK_RESTORE(); ctx->ptr--; ctx->count--; } } else { /* general case */ while (ctx->count >= (Py_ssize_t) ctx->pattern[1]) { state->ptr = ctx->ptr; DO_JUMP(JUMP_REPEAT_ONE_2, jump_repeat_one_2, ctx->pattern+ctx->pattern[0]); if (ret) { RETURN_ON_ERROR(ret); RETURN_SUCCESS; } ctx->ptr--; ctx->count--; LASTMARK_RESTORE(); } } RETURN_FAILURE; case SRE_OP_MIN_REPEAT_ONE: /* match repeated sequence (minimizing regexp) */ /* this operator only works if the repeated item is exactly one character wide, and we're not already collecting backtracking points. for other cases, use the MIN_REPEAT operator */ /* <1=min> <2=max> item tail */ TRACE(("|%p|%p|MIN_REPEAT_ONE %d %d\n", ctx->pattern, ctx->ptr, ctx->pattern[1], ctx->pattern[2])); if (ctx->ptr + ctx->pattern[1] > end) RETURN_FAILURE; /* cannot match */ state->ptr = ctx->ptr; if (ctx->pattern[1] == 0) ctx->count = 0; else { /* count using pattern min as the maximum */ ret = SRE_COUNT(state, ctx->pattern+3, ctx->pattern[1]); RETURN_ON_ERROR(ret); DATA_LOOKUP_AT(SRE_MATCH_CONTEXT, ctx, ctx_pos); if (ret < (Py_ssize_t) ctx->pattern[1]) /* didn't match minimum number of times */ RETURN_FAILURE; /* advance past minimum matches of repeat */ ctx->count = ret; ctx->ptr += ctx->count; } if (ctx->pattern[ctx->pattern[0]] == SRE_OP_SUCCESS) { /* tail is empty. we're finished */ state->ptr = ctx->ptr; RETURN_SUCCESS; } else { /* general case */ LASTMARK_SAVE(); while ((Py_ssize_t)ctx->pattern[2] == 65535 || ctx->count <= (Py_ssize_t)ctx->pattern[2]) { state->ptr = ctx->ptr; DO_JUMP(JUMP_MIN_REPEAT_ONE,jump_min_repeat_one, ctx->pattern+ctx->pattern[0]); if (ret) { RETURN_ON_ERROR(ret); RETURN_SUCCESS; } state->ptr = ctx->ptr; ret = SRE_COUNT(state, ctx->pattern+3, 1); RETURN_ON_ERROR(ret); DATA_LOOKUP_AT(SRE_MATCH_CONTEXT, ctx, ctx_pos); if (ret == 0) break; assert(ret == 1); ctx->ptr++; ctx->count++; LASTMARK_RESTORE(); } } RETURN_FAILURE; case SRE_OP_REPEAT: /* create repeat context. all the hard work is done by the UNTIL operator (MAX_UNTIL, MIN_UNTIL) */ /* <1=min> <2=max> item tail */ TRACE(("|%p|%p|REPEAT %d %d\n", ctx->pattern, ctx->ptr, ctx->pattern[1], ctx->pattern[2])); /* install new repeat context */ ctx->u.rep = (SRE_REPEAT*) PyObject_MALLOC(sizeof(*ctx->u.rep)); if (!ctx->u.rep) { PyErr_NoMemory(); RETURN_FAILURE; } ctx->u.rep->count = -1; ctx->u.rep->pattern = ctx->pattern; ctx->u.rep->prev = state->repeat; ctx->u.rep->last_ptr = NULL; state->repeat = ctx->u.rep; state->ptr = ctx->ptr; DO_JUMP(JUMP_REPEAT, jump_repeat, ctx->pattern+ctx->pattern[0]); state->repeat = ctx->u.rep->prev; PyObject_FREE(ctx->u.rep); if (ret) { RETURN_ON_ERROR(ret); RETURN_SUCCESS; } RETURN_FAILURE; case SRE_OP_MAX_UNTIL: /* maximizing repeat */ /* <1=min> <2=max> item tail */ /* FIXME: we probably need to deal with zero-width matches in here... */ ctx->u.rep = state->repeat; if (!ctx->u.rep) RETURN_ERROR(SRE_ERROR_STATE); state->ptr = ctx->ptr; ctx->count = ctx->u.rep->count+1; TRACE(("|%p|%p|MAX_UNTIL %d\n", ctx->pattern, ctx->ptr, ctx->count)); if (ctx->count < ctx->u.rep->pattern[1]) { /* not enough matches */ ctx->u.rep->count = ctx->count; DO_JUMP(JUMP_MAX_UNTIL_1, jump_max_until_1, ctx->u.rep->pattern+3); if (ret) { RETURN_ON_ERROR(ret); RETURN_SUCCESS; } ctx->u.rep->count = ctx->count-1; state->ptr = ctx->ptr; RETURN_FAILURE; } if ((ctx->count < ctx->u.rep->pattern[2] || ctx->u.rep->pattern[2] == 65535) && state->ptr != ctx->u.rep->last_ptr) { /* we may have enough matches, but if we can match another item, do so */ ctx->u.rep->count = ctx->count; LASTMARK_SAVE(); MARK_PUSH(ctx->lastmark); /* zero-width match protection */ DATA_PUSH(&ctx->u.rep->last_ptr); ctx->u.rep->last_ptr = state->ptr; DO_JUMP(JUMP_MAX_UNTIL_2, jump_max_until_2, ctx->u.rep->pattern+3); DATA_POP(&ctx->u.rep->last_ptr); if (ret) { MARK_POP_DISCARD(ctx->lastmark); RETURN_ON_ERROR(ret); RETURN_SUCCESS; } MARK_POP(ctx->lastmark); LASTMARK_RESTORE(); ctx->u.rep->count = ctx->count-1; state->ptr = ctx->ptr; } /* cannot match more repeated items here. make sure the tail matches */ state->repeat = ctx->u.rep->prev; DO_JUMP(JUMP_MAX_UNTIL_3, jump_max_until_3, ctx->pattern); RETURN_ON_SUCCESS(ret); state->repeat = ctx->u.rep; state->ptr = ctx->ptr; RETURN_FAILURE; case SRE_OP_MIN_UNTIL: /* minimizing repeat */ /* <1=min> <2=max> item tail */ ctx->u.rep = state->repeat; if (!ctx->u.rep) RETURN_ERROR(SRE_ERROR_STATE); state->ptr = ctx->ptr; ctx->count = ctx->u.rep->count+1; TRACE(("|%p|%p|MIN_UNTIL %d %p\n", ctx->pattern, ctx->ptr, ctx->count, ctx->u.rep->pattern)); if (ctx->count < ctx->u.rep->pattern[1]) { /* not enough matches */ ctx->u.rep->count = ctx->count; DO_JUMP(JUMP_MIN_UNTIL_1, jump_min_until_1, ctx->u.rep->pattern+3); if (ret) { RETURN_ON_ERROR(ret); RETURN_SUCCESS; } ctx->u.rep->count = ctx->count-1; state->ptr = ctx->ptr; RETURN_FAILURE; } LASTMARK_SAVE(); /* see if the tail matches */ state->repeat = ctx->u.rep->prev; DO_JUMP(JUMP_MIN_UNTIL_2, jump_min_until_2, ctx->pattern); if (ret) { RETURN_ON_ERROR(ret); RETURN_SUCCESS; } state->repeat = ctx->u.rep; state->ptr = ctx->ptr; LASTMARK_RESTORE(); if (ctx->count >= ctx->u.rep->pattern[2] && ctx->u.rep->pattern[2] != 65535) RETURN_FAILURE; ctx->u.rep->count = ctx->count; DO_JUMP(JUMP_MIN_UNTIL_3,jump_min_until_3, ctx->u.rep->pattern+3); if (ret) { RETURN_ON_ERROR(ret); RETURN_SUCCESS; } ctx->u.rep->count = ctx->count-1; state->ptr = ctx->ptr; RETURN_FAILURE; case SRE_OP_GROUPREF: /* match backreference */ TRACE(("|%p|%p|GROUPREF %d\n", ctx->pattern, ctx->ptr, ctx->pattern[0])); i = ctx->pattern[0]; { Py_ssize_t groupref = i+i; if (groupref >= state->lastmark) { RETURN_FAILURE; } else { SRE_CHAR* p = (SRE_CHAR*) state->mark[groupref]; SRE_CHAR* e = (SRE_CHAR*) state->mark[groupref+1]; if (!p || !e || e < p) RETURN_FAILURE; while (p < e) { if (ctx->ptr >= end || *ctx->ptr != *p) RETURN_FAILURE; p++; ctx->ptr++; } } } ctx->pattern++; break; case SRE_OP_GROUPREF_IGNORE: /* match backreference */ TRACE(("|%p|%p|GROUPREF_IGNORE %d\n", ctx->pattern, ctx->ptr, ctx->pattern[0])); i = ctx->pattern[0]; { Py_ssize_t groupref = i+i; if (groupref >= state->lastmark) { RETURN_FAILURE; } else { SRE_CHAR* p = (SRE_CHAR*) state->mark[groupref]; SRE_CHAR* e = (SRE_CHAR*) state->mark[groupref+1]; if (!p || !e || e < p) RETURN_FAILURE; while (p < e) { if (ctx->ptr >= end || state->lower(*ctx->ptr) != state->lower(*p)) RETURN_FAILURE; p++; ctx->ptr++; } } } ctx->pattern++; break; case SRE_OP_GROUPREF_EXISTS: TRACE(("|%p|%p|GROUPREF_EXISTS %d\n", ctx->pattern, ctx->ptr, ctx->pattern[0])); /* codeyes codeno ... */ i = ctx->pattern[0]; { Py_ssize_t groupref = i+i; if (groupref >= state->lastmark) { ctx->pattern += ctx->pattern[1]; break; } else { SRE_CHAR* p = (SRE_CHAR*) state->mark[groupref]; SRE_CHAR* e = (SRE_CHAR*) state->mark[groupref+1]; if (!p || !e || e < p) { ctx->pattern += ctx->pattern[1]; break; } } } ctx->pattern += 2; break; case SRE_OP_ASSERT: /* assert subpattern */ /* */ TRACE(("|%p|%p|ASSERT %d\n", ctx->pattern, ctx->ptr, ctx->pattern[1])); state->ptr = ctx->ptr - ctx->pattern[1]; if (state->ptr < state->beginning) RETURN_FAILURE; DO_JUMP(JUMP_ASSERT, jump_assert, ctx->pattern+2); RETURN_ON_FAILURE(ret); ctx->pattern += ctx->pattern[0]; break; case SRE_OP_ASSERT_NOT: /* assert not subpattern */ /* */ TRACE(("|%p|%p|ASSERT_NOT %d\n", ctx->pattern, ctx->ptr, ctx->pattern[1])); state->ptr = ctx->ptr - ctx->pattern[1]; if (state->ptr >= state->beginning) { DO_JUMP(JUMP_ASSERT_NOT, jump_assert_not, ctx->pattern+2); if (ret) { RETURN_ON_ERROR(ret); RETURN_FAILURE; } } ctx->pattern += ctx->pattern[0]; break; case SRE_OP_FAILURE: /* immediate failure */ TRACE(("|%p|%p|FAILURE\n", ctx->pattern, ctx->ptr)); RETURN_FAILURE; default: TRACE(("|%p|%p|UNKNOWN %d\n", ctx->pattern, ctx->ptr, ctx->pattern[-1])); RETURN_ERROR(SRE_ERROR_ILLEGAL); } } exit: ctx_pos = ctx->last_ctx_pos; jump = ctx->jump; DATA_POP_DISCARD(ctx); if (ctx_pos == -1) return ret; DATA_LOOKUP_AT(SRE_MATCH_CONTEXT, ctx, ctx_pos); switch (jump) { case JUMP_MAX_UNTIL_2: TRACE(("|%p|%p|JUMP_MAX_UNTIL_2\n", ctx->pattern, ctx->ptr)); goto jump_max_until_2; case JUMP_MAX_UNTIL_3: TRACE(("|%p|%p|JUMP_MAX_UNTIL_3\n", ctx->pattern, ctx->ptr)); goto jump_max_until_3; case JUMP_MIN_UNTIL_2: TRACE(("|%p|%p|JUMP_MIN_UNTIL_2\n", ctx->pattern, ctx->ptr)); goto jump_min_until_2; case JUMP_MIN_UNTIL_3: TRACE(("|%p|%p|JUMP_MIN_UNTIL_3\n", ctx->pattern, ctx->ptr)); goto jump_min_until_3; case JUMP_BRANCH: TRACE(("|%p|%p|JUMP_BRANCH\n", ctx->pattern, ctx->ptr)); goto jump_branch; case JUMP_MAX_UNTIL_1: TRACE(("|%p|%p|JUMP_MAX_UNTIL_1\n", ctx->pattern, ctx->ptr)); goto jump_max_until_1; case JUMP_MIN_UNTIL_1: TRACE(("|%p|%p|JUMP_MIN_UNTIL_1\n", ctx->pattern, ctx->ptr)); goto jump_min_until_1; case JUMP_REPEAT: TRACE(("|%p|%p|JUMP_REPEAT\n", ctx->pattern, ctx->ptr)); goto jump_repeat; case JUMP_REPEAT_ONE_1: TRACE(("|%p|%p|JUMP_REPEAT_ONE_1\n", ctx->pattern, ctx->ptr)); goto jump_repeat_one_1; case JUMP_REPEAT_ONE_2: TRACE(("|%p|%p|JUMP_REPEAT_ONE_2\n", ctx->pattern, ctx->ptr)); goto jump_repeat_one_2; case JUMP_MIN_REPEAT_ONE: TRACE(("|%p|%p|JUMP_MIN_REPEAT_ONE\n", ctx->pattern, ctx->ptr)); goto jump_min_repeat_one; case JUMP_ASSERT: TRACE(("|%p|%p|JUMP_ASSERT\n", ctx->pattern, ctx->ptr)); goto jump_assert; case JUMP_ASSERT_NOT: TRACE(("|%p|%p|JUMP_ASSERT_NOT\n", ctx->pattern, ctx->ptr)); goto jump_assert_not; case JUMP_NONE: TRACE(("|%p|%p|RETURN %d\n", ctx->pattern, ctx->ptr, ret)); break; } return ret; /* should never get here */ } LOCAL(Py_ssize_t) SRE_SEARCH(SRE_STATE* state, SRE_CODE* pattern) { SRE_CHAR* ptr = (SRE_CHAR *)state->start; SRE_CHAR* end = (SRE_CHAR *)state->end; Py_ssize_t status = 0; Py_ssize_t prefix_len = 0; Py_ssize_t prefix_skip = 0; SRE_CODE* prefix = NULL; SRE_CODE* charset = NULL; SRE_CODE* overlap = NULL; int flags = 0; if (pattern[0] == SRE_OP_INFO) { /* optimization info block */ /* <1=skip> <2=flags> <3=min> <4=max> <5=prefix info> */ flags = pattern[2]; if (pattern[3] > 1) { /* adjust end point (but make sure we leave at least one character in there, so literal search will work) */ end -= pattern[3]-1; if (end <= ptr) end = ptr+1; } if (flags & SRE_INFO_PREFIX) { /* pattern starts with a known prefix */ /* */ prefix_len = pattern[5]; prefix_skip = pattern[6]; prefix = pattern + 7; overlap = prefix + prefix_len - 1; } else if (flags & SRE_INFO_CHARSET) /* pattern starts with a character from a known set */ /* */ charset = pattern + 5; pattern += 1 + pattern[1]; } TRACE(("prefix = %p %d %d\n", prefix, prefix_len, prefix_skip)); TRACE(("charset = %p\n", charset)); #if defined(USE_FAST_SEARCH) if (prefix_len > 1) { /* pattern starts with a known prefix. use the overlap table to skip forward as fast as we possibly can */ Py_ssize_t i = 0; end = (SRE_CHAR *)state->end; while (ptr < end) { for (;;) { if ((SRE_CODE) ptr[0] != prefix[i]) { if (!i) break; else i = overlap[i]; } else { if (++i == prefix_len) { /* found a potential match */ TRACE(("|%p|%p|SEARCH SCAN\n", pattern, ptr)); state->start = ptr + 1 - prefix_len; state->ptr = ptr + 1 - prefix_len + prefix_skip; if (flags & SRE_INFO_LITERAL) return 1; /* we got all of it */ status = SRE_MATCH(state, pattern + 2*prefix_skip); if (status != 0) return status; /* close but no cigar -- try again */ i = overlap[i]; } break; } } ptr++; } return 0; } #endif if (pattern[0] == SRE_OP_LITERAL) { /* pattern starts with a literal character. this is used for short prefixes, and if fast search is disabled */ SRE_CODE chr = pattern[1]; end = (SRE_CHAR *)state->end; for (;;) { while (ptr < end && (SRE_CODE) ptr[0] != chr) ptr++; if (ptr >= end) return 0; TRACE(("|%p|%p|SEARCH LITERAL\n", pattern, ptr)); state->start = ptr; state->ptr = ++ptr; if (flags & SRE_INFO_LITERAL) return 1; /* we got all of it */ status = SRE_MATCH(state, pattern + 2); if (status != 0) break; } } else if (charset) { /* pattern starts with a character from a known set */ end = (SRE_CHAR *)state->end; for (;;) { while (ptr < end && !SRE_CHARSET(charset, ptr[0])) ptr++; if (ptr >= end) return 0; TRACE(("|%p|%p|SEARCH CHARSET\n", pattern, ptr)); state->start = ptr; state->ptr = ptr; status = SRE_MATCH(state, pattern); if (status != 0) break; ptr++; } } else /* general case */ while (ptr <= end) { TRACE(("|%p|%p|SEARCH\n", pattern, ptr)); state->start = state->ptr = ptr++; status = SRE_MATCH(state, pattern); if (status != 0) break; } return status; } LOCAL(int) SRE_LITERAL_TEMPLATE(SRE_CHAR* ptr, Py_ssize_t len) { /* check if given string is a literal template (i.e. no escapes) */ while (len-- > 0) if (*ptr++ == '\\') return 0; return 1; } #if !defined(SRE_RECURSIVE) /* -------------------------------------------------------------------- */ /* factories and destructors */ /* see sre.h for object declarations */ static PyObject*pattern_new_match(PatternObject*, SRE_STATE*, int); static PyObject*pattern_scanner(PatternObject*, PyObject*); static PyObject * sre_codesize(PyObject* self, PyObject *unused) { return Py_BuildValue("l", sizeof(SRE_CODE)); } static PyObject * sre_getlower(PyObject* self, PyObject* args) { int character, flags; if (!PyArg_ParseTuple(args, "ii", &character, &flags)) return NULL; if (flags & SRE_FLAG_LOCALE) return Py_BuildValue("i", sre_lower_locale(character)); if (flags & SRE_FLAG_UNICODE) #if defined(HAVE_UNICODE) return Py_BuildValue("i", sre_lower_unicode(character)); #else return Py_BuildValue("i", sre_lower_locale(character)); #endif return Py_BuildValue("i", sre_lower(character)); } LOCAL(void) state_reset(SRE_STATE* state) { /* FIXME: dynamic! */ /*memset(state->mark, 0, sizeof(*state->mark) * SRE_MARK_SIZE);*/ state->lastmark = -1; state->lastindex = -1; state->repeat = NULL; data_stack_dealloc(state); } static void* getstring(PyObject* string, Py_ssize_t* p_length, int* p_charsize) { /* given a python object, return a data pointer, a length (in characters), and a character size. return NULL if the object is not a string (or not compatible) */ PyBufferProcs *buffer; Py_ssize_t size, bytes; int charsize; void* ptr; Py_buffer view; /* Unicode objects do not support the buffer API. So, get the data directly instead. */ if (PyUnicode_Check(string)) { ptr = (void *)PyUnicode_AS_DATA(string); *p_length = PyUnicode_GET_SIZE(string); *p_charsize = sizeof(Py_UNICODE); return ptr; } /* get pointer to string buffer */ view.len = -1; buffer = Py_TYPE(string)->tp_as_buffer; if (!buffer || !buffer->bf_getbuffer || (*buffer->bf_getbuffer)(string, &view, PyBUF_SIMPLE) < 0) { PyErr_SetString(PyExc_TypeError, "expected string or buffer"); return NULL; } /* determine buffer size */ bytes = view.len; ptr = view.buf; /* Release the buffer immediately --- possibly dangerous but doing something else would require some re-factoring */ PyObject_ReleaseBuffer(string, &view); if (bytes < 0) { PyErr_SetString(PyExc_TypeError, "buffer has negative size"); return NULL; } /* determine character size */ size = PyObject_Size(string); if (PyBytes_Check(string) || bytes == size) charsize = 1; #if defined(HAVE_UNICODE) else if (bytes == (Py_ssize_t) (size * sizeof(Py_UNICODE))) charsize = sizeof(Py_UNICODE); #endif else { PyErr_SetString(PyExc_TypeError, "buffer size mismatch"); return NULL; } *p_length = size; *p_charsize = charsize; if (ptr == NULL) { PyErr_SetString(PyExc_ValueError, "Buffer is NULL"); } return ptr; } LOCAL(PyObject*) state_init(SRE_STATE* state, PatternObject* pattern, PyObject* string, Py_ssize_t start, Py_ssize_t end) { /* prepare state object */ Py_ssize_t length; int charsize; void* ptr; memset(state, 0, sizeof(SRE_STATE)); state->lastmark = -1; state->lastindex = -1; ptr = getstring(string, &length, &charsize); if (!ptr) return NULL; /* adjust boundaries */ if (start < 0) start = 0; else if (start > length) start = length; if (end < 0) end = 0; else if (end > length) end = length; state->charsize = charsize; state->beginning = ptr; state->start = (void*) ((char*) ptr + start * state->charsize); state->end = (void*) ((char*) ptr + end * state->charsize); Py_INCREF(string); state->string = string; state->pos = start; state->endpos = end; if (pattern->flags & SRE_FLAG_LOCALE) state->lower = sre_lower_locale; else if (pattern->flags & SRE_FLAG_UNICODE) #if defined(HAVE_UNICODE) state->lower = sre_lower_unicode; #else state->lower = sre_lower_locale; #endif else state->lower = sre_lower; return string; } LOCAL(void) state_fini(SRE_STATE* state) { Py_XDECREF(state->string); data_stack_dealloc(state); } /* calculate offset from start of string */ #define STATE_OFFSET(state, member)\ (((char*)(member) - (char*)(state)->beginning) / (state)->charsize) LOCAL(PyObject*) state_getslice(SRE_STATE* state, Py_ssize_t index, PyObject* string, int empty) { Py_ssize_t i, j; index = (index - 1) * 2; if (string == Py_None || index >= state->lastmark || !state->mark[index] || !state->mark[index+1]) { if (empty) /* want empty string */ i = j = 0; else { Py_INCREF(Py_None); return Py_None; } } else { i = STATE_OFFSET(state, state->mark[index]); j = STATE_OFFSET(state, state->mark[index+1]); } return PySequence_GetSlice(string, i, j); } static void pattern_error(int status) { switch (status) { case SRE_ERROR_RECURSION_LIMIT: PyErr_SetString( PyExc_RuntimeError, "maximum recursion limit exceeded" ); break; case SRE_ERROR_MEMORY: PyErr_NoMemory(); break; case SRE_ERROR_INTERRUPTED: /* An exception has already been raised, so let it fly */ break; default: /* other error codes indicate compiler/engine bugs */ PyErr_SetString( PyExc_RuntimeError, "internal error in regular expression engine" ); } } static void pattern_dealloc(PatternObject* self) { if (self->weakreflist != NULL) PyObject_ClearWeakRefs((PyObject *) self); Py_XDECREF(self->pattern); Py_XDECREF(self->groupindex); Py_XDECREF(self->indexgroup); PyObject_DEL(self); } static PyObject* pattern_match(PatternObject* self, PyObject* args, PyObject* kw) { SRE_STATE state; int status; PyObject* string; Py_ssize_t start = 0; Py_ssize_t end = PY_SSIZE_T_MAX; static char* kwlist[] = { "pattern", "pos", "endpos", NULL }; if (!PyArg_ParseTupleAndKeywords(args, kw, "O|nn:match", kwlist, &string, &start, &end)) return NULL; string = state_init(&state, self, string, start, end); if (!string) return NULL; state.ptr = state.start; TRACE(("|%p|%p|MATCH\n", PatternObject_GetCode(self), state.ptr)); if (state.charsize == 1) { status = sre_match(&state, PatternObject_GetCode(self)); } else { #if defined(HAVE_UNICODE) status = sre_umatch(&state, PatternObject_GetCode(self)); #endif } TRACE(("|%p|%p|END\n", PatternObject_GetCode(self), state.ptr)); if (PyErr_Occurred()) return NULL; state_fini(&state); return pattern_new_match(self, &state, status); } static PyObject* pattern_search(PatternObject* self, PyObject* args, PyObject* kw) { SRE_STATE state; int status; PyObject* string; Py_ssize_t start = 0; Py_ssize_t end = PY_SSIZE_T_MAX; static char* kwlist[] = { "pattern", "pos", "endpos", NULL }; if (!PyArg_ParseTupleAndKeywords(args, kw, "O|nn:search", kwlist, &string, &start, &end)) return NULL; string = state_init(&state, self, string, start, end); if (!string) return NULL; TRACE(("|%p|%p|SEARCH\n", PatternObject_GetCode(self), state.ptr)); if (state.charsize == 1) { status = sre_search(&state, PatternObject_GetCode(self)); } else { #if defined(HAVE_UNICODE) status = sre_usearch(&state, PatternObject_GetCode(self)); #endif } TRACE(("|%p|%p|END\n", PatternObject_GetCode(self), state.ptr)); state_fini(&state); if (PyErr_Occurred()) return NULL; return pattern_new_match(self, &state, status); } static PyObject* call(char* module, char* function, PyObject* args) { PyObject* name; PyObject* mod; PyObject* func; PyObject* result; if (!args) return NULL; name = PyUnicode_FromString(module); if (!name) return NULL; mod = PyImport_Import(name); Py_DECREF(name); if (!mod) return NULL; func = PyObject_GetAttrString(mod, function); Py_DECREF(mod); if (!func) return NULL; result = PyObject_CallObject(func, args); Py_DECREF(func); Py_DECREF(args); return result; } #ifdef USE_BUILTIN_COPY static int deepcopy(PyObject** object, PyObject* memo) { PyObject* copy; copy = call( "copy", "deepcopy", PyTuple_Pack(2, *object, memo) ); if (!copy) return 0; Py_DECREF(*object); *object = copy; return 1; /* success */ } #endif static PyObject* join_list(PyObject* list, PyObject* string) { /* join list elements */ PyObject* joiner; #if PY_VERSION_HEX >= 0x01060000 PyObject* function; PyObject* args; #endif PyObject* result; joiner = PySequence_GetSlice(string, 0, 0); if (!joiner) return NULL; if (PyList_GET_SIZE(list) == 0) { Py_DECREF(list); return joiner; } #if PY_VERSION_HEX >= 0x01060000 function = PyObject_GetAttrString(joiner, "join"); if (!function) { Py_DECREF(joiner); return NULL; } args = PyTuple_New(1); if (!args) { Py_DECREF(function); Py_DECREF(joiner); return NULL; } PyTuple_SET_ITEM(args, 0, list); result = PyObject_CallObject(function, args); Py_DECREF(args); /* also removes list */ Py_DECREF(function); #else result = call( "string", "join", PyTuple_Pack(2, list, joiner) ); #endif Py_DECREF(joiner); return result; } static PyObject* pattern_findall(PatternObject* self, PyObject* args, PyObject* kw) { SRE_STATE state; PyObject* list; int status; Py_ssize_t i, b, e; PyObject* string; Py_ssize_t start = 0; Py_ssize_t end = PY_SSIZE_T_MAX; static char* kwlist[] = { "source", "pos", "endpos", NULL }; if (!PyArg_ParseTupleAndKeywords(args, kw, "O|nn:findall", kwlist, &string, &start, &end)) return NULL; string = state_init(&state, self, string, start, end); if (!string) return NULL; list = PyList_New(0); if (!list) { state_fini(&state); return NULL; } while (state.start <= state.end) { PyObject* item; state_reset(&state); state.ptr = state.start; if (state.charsize == 1) { status = sre_search(&state, PatternObject_GetCode(self)); } else { #if defined(HAVE_UNICODE) status = sre_usearch(&state, PatternObject_GetCode(self)); #endif } if (PyErr_Occurred()) goto error; if (status <= 0) { if (status == 0) break; pattern_error(status); goto error; } /* don't bother to build a match object */ switch (self->groups) { case 0: b = STATE_OFFSET(&state, state.start); e = STATE_OFFSET(&state, state.ptr); item = PySequence_GetSlice(string, b, e); if (!item) goto error; break; case 1: item = state_getslice(&state, 1, string, 1); if (!item) goto error; break; default: item = PyTuple_New(self->groups); if (!item) goto error; for (i = 0; i < self->groups; i++) { PyObject* o = state_getslice(&state, i+1, string, 1); if (!o) { Py_DECREF(item); goto error; } PyTuple_SET_ITEM(item, i, o); } break; } status = PyList_Append(list, item); Py_DECREF(item); if (status < 0) goto error; if (state.ptr == state.start) state.start = (void*) ((char*) state.ptr + state.charsize); else state.start = state.ptr; } state_fini(&state); return list; error: Py_DECREF(list); state_fini(&state); return NULL; } #if PY_VERSION_HEX >= 0x02020000 static PyObject* pattern_finditer(PatternObject* pattern, PyObject* args) { PyObject* scanner; PyObject* search; PyObject* iterator; scanner = pattern_scanner(pattern, args); if (!scanner) return NULL; search = PyObject_GetAttrString(scanner, "search"); Py_DECREF(scanner); if (!search) return NULL; iterator = PyCallIter_New(search, Py_None); Py_DECREF(search); return iterator; } #endif static PyObject* pattern_split(PatternObject* self, PyObject* args, PyObject* kw) { SRE_STATE state; PyObject* list; PyObject* item; int status; Py_ssize_t n; Py_ssize_t i; void* last; PyObject* string; Py_ssize_t maxsplit = 0; static char* kwlist[] = { "source", "maxsplit", NULL }; if (!PyArg_ParseTupleAndKeywords(args, kw, "O|n:split", kwlist, &string, &maxsplit)) return NULL; string = state_init(&state, self, string, 0, PY_SSIZE_T_MAX); if (!string) return NULL; list = PyList_New(0); if (!list) { state_fini(&state); return NULL; } n = 0; last = state.start; while (!maxsplit || n < maxsplit) { state_reset(&state); state.ptr = state.start; if (state.charsize == 1) { status = sre_search(&state, PatternObject_GetCode(self)); } else { #if defined(HAVE_UNICODE) status = sre_usearch(&state, PatternObject_GetCode(self)); #endif } if (PyErr_Occurred()) goto error; if (status <= 0) { if (status == 0) break; pattern_error(status); goto error; } if (state.start == state.ptr) { if (last == state.end) break; /* skip one character */ state.start = (void*) ((char*) state.ptr + state.charsize); continue; } /* get segment before this match */ item = PySequence_GetSlice( string, STATE_OFFSET(&state, last), STATE_OFFSET(&state, state.start) ); if (!item) goto error; status = PyList_Append(list, item); Py_DECREF(item); if (status < 0) goto error; /* add groups (if any) */ for (i = 0; i < self->groups; i++) { item = state_getslice(&state, i+1, string, 0); if (!item) goto error; status = PyList_Append(list, item); Py_DECREF(item); if (status < 0) goto error; } n = n + 1; last = state.start = state.ptr; } /* get segment following last match (even if empty) */ item = PySequence_GetSlice( string, STATE_OFFSET(&state, last), state.endpos ); if (!item) goto error; status = PyList_Append(list, item); Py_DECREF(item); if (status < 0) goto error; state_fini(&state); return list; error: Py_DECREF(list); state_fini(&state); return NULL; } static PyObject* pattern_subx(PatternObject* self, PyObject* ptemplate, PyObject* string, Py_ssize_t count, Py_ssize_t subn) { SRE_STATE state; PyObject* list; PyObject* item; PyObject* filter; PyObject* args; PyObject* match; void* ptr; int status; Py_ssize_t n; Py_ssize_t i, b, e; int bint; int filter_is_callable; if (PyCallable_Check(ptemplate)) { /* sub/subn takes either a function or a template */ filter = ptemplate; Py_INCREF(filter); filter_is_callable = 1; } else { /* if not callable, check if it's a literal string */ int literal; ptr = getstring(ptemplate, &n, &bint); b = bint; if (ptr) { if (b == 1) { literal = sre_literal_template((unsigned char *)ptr, n); } else { #if defined(HAVE_UNICODE) literal = sre_uliteral_template((Py_UNICODE *)ptr, n); #endif } } else { PyErr_Clear(); literal = 0; } if (literal) { filter = ptemplate; Py_INCREF(filter); filter_is_callable = 0; } else { /* not a literal; hand it over to the template compiler */ filter = call( SRE_PY_MODULE, "_subx", PyTuple_Pack(2, self, ptemplate) ); if (!filter) return NULL; filter_is_callable = PyCallable_Check(filter); } } string = state_init(&state, self, string, 0, PY_SSIZE_T_MAX); if (!string) { Py_DECREF(filter); return NULL; } list = PyList_New(0); if (!list) { Py_DECREF(filter); state_fini(&state); return NULL; } n = i = 0; while (!count || n < count) { state_reset(&state); state.ptr = state.start; if (state.charsize == 1) { status = sre_search(&state, PatternObject_GetCode(self)); } else { #if defined(HAVE_UNICODE) status = sre_usearch(&state, PatternObject_GetCode(self)); #endif } if (PyErr_Occurred()) goto error; if (status <= 0) { if (status == 0) break; pattern_error(status); goto error; } b = STATE_OFFSET(&state, state.start); e = STATE_OFFSET(&state, state.ptr); if (i < b) { /* get segment before this match */ item = PySequence_GetSlice(string, i, b); if (!item) goto error; status = PyList_Append(list, item); Py_DECREF(item); if (status < 0) goto error; } else if (i == b && i == e && n > 0) /* ignore empty match on latest position */ goto next; if (filter_is_callable) { /* pass match object through filter */ match = pattern_new_match(self, &state, 1); if (!match) goto error; args = PyTuple_Pack(1, match); if (!args) { Py_DECREF(match); goto error; } item = PyObject_CallObject(filter, args); Py_DECREF(args); Py_DECREF(match); if (!item) goto error; } else { /* filter is literal string */ item = filter; Py_INCREF(item); } /* add to list */ if (item != Py_None) { status = PyList_Append(list, item); Py_DECREF(item); if (status < 0) goto error; } i = e; n = n + 1; next: /* move on */ if (state.ptr == state.start) state.start = (void*) ((char*) state.ptr + state.charsize); else state.start = state.ptr; } /* get segment following last match */ if (i < state.endpos) { item = PySequence_GetSlice(string, i, state.endpos); if (!item) goto error; status = PyList_Append(list, item); Py_DECREF(item); if (status < 0) goto error; } state_fini(&state); Py_DECREF(filter); /* convert list to single string (also removes list) */ item = join_list(list, string); if (!item) return NULL; if (subn) return Py_BuildValue("Ni", item, n); return item; error: Py_DECREF(list); state_fini(&state); Py_DECREF(filter); return NULL; } static PyObject* pattern_sub(PatternObject* self, PyObject* args, PyObject* kw) { PyObject* ptemplate; PyObject* string; Py_ssize_t count = 0; static char* kwlist[] = { "repl", "string", "count", NULL }; if (!PyArg_ParseTupleAndKeywords(args, kw, "OO|n:sub", kwlist, &ptemplate, &string, &count)) return NULL; return pattern_subx(self, ptemplate, string, count, 0); } static PyObject* pattern_subn(PatternObject* self, PyObject* args, PyObject* kw) { PyObject* ptemplate; PyObject* string; Py_ssize_t count = 0; static char* kwlist[] = { "repl", "string", "count", NULL }; if (!PyArg_ParseTupleAndKeywords(args, kw, "OO|n:subn", kwlist, &ptemplate, &string, &count)) return NULL; return pattern_subx(self, ptemplate, string, count, 1); } static PyObject* pattern_copy(PatternObject* self, PyObject *unused) { #ifdef USE_BUILTIN_COPY PatternObject* copy; int offset; copy = PyObject_NEW_VAR(PatternObject, &Pattern_Type, self->codesize); if (!copy) return NULL; offset = offsetof(PatternObject, groups); Py_XINCREF(self->groupindex); Py_XINCREF(self->indexgroup); Py_XINCREF(self->pattern); memcpy((char*) copy + offset, (char*) self + offset, sizeof(PatternObject) + self->codesize * sizeof(SRE_CODE) - offset); copy->weakreflist = NULL; return (PyObject*) copy; #else PyErr_SetString(PyExc_TypeError, "cannot copy this pattern object"); return NULL; #endif } static PyObject* pattern_deepcopy(PatternObject* self, PyObject* memo) { #ifdef USE_BUILTIN_COPY PatternObject* copy; copy = (PatternObject*) pattern_copy(self); if (!copy) return NULL; if (!deepcopy(©->groupindex, memo) || !deepcopy(©->indexgroup, memo) || !deepcopy(©->pattern, memo)) { Py_DECREF(copy); return NULL; } #else PyErr_SetString(PyExc_TypeError, "cannot deepcopy this pattern object"); return NULL; #endif } PyDoc_STRVAR(pattern_match_doc, "match(string[, pos[, endpos]]) --> match object or None.\n\ Matches zero or more characters at the beginning of the string"); PyDoc_STRVAR(pattern_search_doc, "search(string[, pos[, endpos]]) --> match object or None.\n\ Scan through string looking for a match, and return a corresponding\n\ MatchObject instance. Return None if no position in the string matches."); PyDoc_STRVAR(pattern_split_doc, "split(string[, maxsplit = 0]) --> list.\n\ Split string by the occurrences of pattern."); PyDoc_STRVAR(pattern_findall_doc, "findall(string[, pos[, endpos]]) --> list.\n\ Return a list of all non-overlapping matches of pattern in string."); PyDoc_STRVAR(pattern_finditer_doc, "finditer(string[, pos[, endpos]]) --> iterator.\n\ Return an iterator over all non-overlapping matches for the \n\ RE pattern in string. For each match, the iterator returns a\n\ match object."); PyDoc_STRVAR(pattern_sub_doc, "sub(repl, string[, count = 0]) --> newstring\n\ Return the string obtained by replacing the leftmost non-overlapping\n\ occurrences of pattern in string by the replacement repl."); PyDoc_STRVAR(pattern_subn_doc, "subn(repl, string[, count = 0]) --> (newstring, number of subs)\n\ Return the tuple (new_string, number_of_subs_made) found by replacing\n\ the leftmost non-overlapping occurrences of pattern with the\n\ replacement repl."); PyDoc_STRVAR(pattern_doc, "Compiled regular expression objects"); static PyMethodDef pattern_methods[] = { {"match", (PyCFunction) pattern_match, METH_VARARGS|METH_KEYWORDS, pattern_match_doc}, {"search", (PyCFunction) pattern_search, METH_VARARGS|METH_KEYWORDS, pattern_search_doc}, {"sub", (PyCFunction) pattern_sub, METH_VARARGS|METH_KEYWORDS, pattern_sub_doc}, {"subn", (PyCFunction) pattern_subn, METH_VARARGS|METH_KEYWORDS, pattern_subn_doc}, {"split", (PyCFunction) pattern_split, METH_VARARGS|METH_KEYWORDS, pattern_split_doc}, {"findall", (PyCFunction) pattern_findall, METH_VARARGS|METH_KEYWORDS, pattern_findall_doc}, #if PY_VERSION_HEX >= 0x02020000 {"finditer", (PyCFunction) pattern_finditer, METH_VARARGS, pattern_finditer_doc}, #endif {"scanner", (PyCFunction) pattern_scanner, METH_VARARGS}, {"__copy__", (PyCFunction) pattern_copy, METH_NOARGS}, {"__deepcopy__", (PyCFunction) pattern_deepcopy, METH_O}, {NULL, NULL} }; #define PAT_OFF(x) offsetof(PatternObject, x) static PyMemberDef pattern_members[] = { {"pattern", T_OBJECT, PAT_OFF(pattern), READONLY}, {"flags", T_INT, PAT_OFF(flags), READONLY}, {"groups", T_PYSSIZET, PAT_OFF(groups), READONLY}, {"groupindex", T_OBJECT, PAT_OFF(groupindex), READONLY}, {NULL} /* Sentinel */ }; static PyTypeObject Pattern_Type = { PyVarObject_HEAD_INIT(NULL, 0) "_" SRE_MODULE ".SRE_Pattern", sizeof(PatternObject), sizeof(SRE_CODE), (destructor)pattern_dealloc, /* tp_dealloc */ 0, /* tp_print */ 0, /* tp_getattr */ 0, /* tp_setattr */ 0, /* tp_compare */ 0, /* tp_repr */ 0, /* tp_as_number */ 0, /* tp_as_sequence */ 0, /* tp_as_mapping */ 0, /* tp_hash */ 0, /* tp_call */ 0, /* tp_str */ 0, /* tp_getattro */ 0, /* tp_setattro */ 0, /* tp_as_buffer */ Py_TPFLAGS_DEFAULT, /* tp_flags */ pattern_doc, /* tp_doc */ 0, /* tp_traverse */ 0, /* tp_clear */ 0, /* tp_richcompare */ offsetof(PatternObject, weakreflist), /* tp_weaklistoffset */ 0, /* tp_iter */ 0, /* tp_iternext */ pattern_methods, /* tp_methods */ pattern_members, /* tp_members */ }; static int _validate(PatternObject *self); /* Forward */ static PyObject * _compile(PyObject* self_, PyObject* args) { /* "compile" pattern descriptor to pattern object */ PatternObject* self; Py_ssize_t i, n; PyObject* pattern; int flags = 0; PyObject* code; Py_ssize_t groups = 0; PyObject* groupindex = NULL; PyObject* indexgroup = NULL; if (!PyArg_ParseTuple(args, "OiO!|nOO", &pattern, &flags, &PyList_Type, &code, &groups, &groupindex, &indexgroup)) return NULL; n = PyList_GET_SIZE(code); /* coverity[ampersand_in_size] */ self = PyObject_NEW_VAR(PatternObject, &Pattern_Type, n); if (!self) return NULL; self->codesize = n; for (i = 0; i < n; i++) { PyObject *o = PyList_GET_ITEM(code, i); unsigned long value = PyLong_AsUnsignedLong(o); self->code[i] = (SRE_CODE) value; if ((unsigned long) self->code[i] != value) { PyErr_SetString(PyExc_OverflowError, "regular expression code size limit exceeded"); break; } } if (PyErr_Occurred()) { PyObject_DEL(self); return NULL; } Py_INCREF(pattern); self->pattern = pattern; self->flags = flags; self->groups = groups; Py_XINCREF(groupindex); self->groupindex = groupindex; Py_XINCREF(indexgroup); self->indexgroup = indexgroup; self->weakreflist = NULL; if (!_validate(self)) { Py_DECREF(self); return NULL; } return (PyObject*) self; } /* -------------------------------------------------------------------- */ /* Code validation */ /* To learn more about this code, have a look at the _compile() function in Lib/sre_compile.py. The validation functions below checks the code array for conformance with the code patterns generated there. The nice thing about the generated code is that it is position-independent: all jumps are relative jumps forward. Also, jumps don't cross each other: the target of a later jump is always earlier than the target of an earlier jump. IOW, this is okay: J---------J-------T--------T \ \_____/ / \______________________/ but this is not: J---------J-------T--------T \_________\_____/ / \____________/ It also helps that SRE_CODE is always an unsigned type, either 2 bytes or 4 bytes wide (the latter if Python is compiled for "wide" unicode support). */ /* Defining this one enables tracing of the validator */ #undef VVERBOSE /* Trace macro for the validator */ #if defined(VVERBOSE) #define VTRACE(v) printf v #else #define VTRACE(v) #endif /* Report failure */ #define FAIL do { VTRACE(("FAIL: %d\n", __LINE__)); return 0; } while (0) /* Extract opcode, argument, or skip count from code array */ #define GET_OP \ do { \ VTRACE(("%p: ", code)); \ if (code >= end) FAIL; \ op = *code++; \ VTRACE(("%lu (op)\n", (unsigned long)op)); \ } while (0) #define GET_ARG \ do { \ VTRACE(("%p= ", code)); \ if (code >= end) FAIL; \ arg = *code++; \ VTRACE(("%lu (arg)\n", (unsigned long)arg)); \ } while (0) #define GET_SKIP \ do { \ VTRACE(("%p= ", code)); \ if (code >= end) FAIL; \ skip = *code; \ VTRACE(("%lu (skip to %p)\n", \ (unsigned long)skip, code+skip)); \ if (code+skip < code || code+skip > end) \ FAIL; \ code++; \ } while (0) static int _validate_charset(SRE_CODE *code, SRE_CODE *end) { /* Some variables are manipulated by the macros above */ SRE_CODE op; SRE_CODE arg; SRE_CODE offset; int i; while (code < end) { GET_OP; switch (op) { case SRE_OP_NEGATE: break; case SRE_OP_LITERAL: GET_ARG; break; case SRE_OP_RANGE: GET_ARG; GET_ARG; break; case SRE_OP_CHARSET: offset = 32/sizeof(SRE_CODE); /* 32-byte bitmap */ if (code+offset < code || code+offset > end) FAIL; code += offset; break; case SRE_OP_BIGCHARSET: GET_ARG; /* Number of blocks */ offset = 256/sizeof(SRE_CODE); /* 256-byte table */ if (code+offset < code || code+offset > end) FAIL; /* Make sure that each byte points to a valid block */ for (i = 0; i < 256; i++) { if (((unsigned char *)code)[i] >= arg) FAIL; } code += offset; offset = arg * 32/sizeof(SRE_CODE); /* 32-byte bitmap times arg */ if (code+offset < code || code+offset > end) FAIL; code += offset; break; case SRE_OP_CATEGORY: GET_ARG; switch (arg) { case SRE_CATEGORY_DIGIT: case SRE_CATEGORY_NOT_DIGIT: case SRE_CATEGORY_SPACE: case SRE_CATEGORY_NOT_SPACE: case SRE_CATEGORY_WORD: case SRE_CATEGORY_NOT_WORD: case SRE_CATEGORY_LINEBREAK: case SRE_CATEGORY_NOT_LINEBREAK: case SRE_CATEGORY_LOC_WORD: case SRE_CATEGORY_LOC_NOT_WORD: case SRE_CATEGORY_UNI_DIGIT: case SRE_CATEGORY_UNI_NOT_DIGIT: case SRE_CATEGORY_UNI_SPACE: case SRE_CATEGORY_UNI_NOT_SPACE: case SRE_CATEGORY_UNI_WORD: case SRE_CATEGORY_UNI_NOT_WORD: case SRE_CATEGORY_UNI_LINEBREAK: case SRE_CATEGORY_UNI_NOT_LINEBREAK: break; default: FAIL; } break; default: FAIL; } } return 1; } static int _validate_inner(SRE_CODE *code, SRE_CODE *end, Py_ssize_t groups) { /* Some variables are manipulated by the macros above */ SRE_CODE op; SRE_CODE arg; SRE_CODE skip; VTRACE(("code=%p, end=%p\n", code, end)); if (code > end) FAIL; while (code < end) { GET_OP; switch (op) { case SRE_OP_MARK: /* We don't check whether marks are properly nested; the sre_match() code is robust even if they don't, and the worst you can get is nonsensical match results. */ GET_ARG; if (arg > 2*groups+1) { VTRACE(("arg=%d, groups=%d\n", (int)arg, (int)groups)); FAIL; } break; case SRE_OP_LITERAL: case SRE_OP_NOT_LITERAL: case SRE_OP_LITERAL_IGNORE: case SRE_OP_NOT_LITERAL_IGNORE: GET_ARG; /* The arg is just a character, nothing to check */ break; case SRE_OP_SUCCESS: case SRE_OP_FAILURE: /* Nothing to check; these normally end the matching process */ break; case SRE_OP_AT: GET_ARG; switch (arg) { case SRE_AT_BEGINNING: case SRE_AT_BEGINNING_STRING: case SRE_AT_BEGINNING_LINE: case SRE_AT_END: case SRE_AT_END_LINE: case SRE_AT_END_STRING: case SRE_AT_BOUNDARY: case SRE_AT_NON_BOUNDARY: case SRE_AT_LOC_BOUNDARY: case SRE_AT_LOC_NON_BOUNDARY: case SRE_AT_UNI_BOUNDARY: case SRE_AT_UNI_NON_BOUNDARY: break; default: FAIL; } break; case SRE_OP_ANY: case SRE_OP_ANY_ALL: /* These have no operands */ break; case SRE_OP_IN: case SRE_OP_IN_IGNORE: GET_SKIP; /* Stop 1 before the end; we check the FAILURE below */ if (!_validate_charset(code, code+skip-2)) FAIL; if (code[skip-2] != SRE_OP_FAILURE) FAIL; code += skip-1; break; case SRE_OP_INFO: { /* A minimal info field is <1=skip> <2=flags> <3=min> <4=max>; If SRE_INFO_PREFIX or SRE_INFO_CHARSET is in the flags, more follows. */ SRE_CODE flags, min, max, i; SRE_CODE *newcode; GET_SKIP; newcode = code+skip-1; GET_ARG; flags = arg; GET_ARG; min = arg; GET_ARG; max = arg; /* Check that only valid flags are present */ if ((flags & ~(SRE_INFO_PREFIX | SRE_INFO_LITERAL | SRE_INFO_CHARSET)) != 0) FAIL; /* PREFIX and CHARSET are mutually exclusive */ if ((flags & SRE_INFO_PREFIX) && (flags & SRE_INFO_CHARSET)) FAIL; /* LITERAL implies PREFIX */ if ((flags & SRE_INFO_LITERAL) && !(flags & SRE_INFO_PREFIX)) FAIL; /* Validate the prefix */ if (flags & SRE_INFO_PREFIX) { SRE_CODE prefix_len, prefix_skip; GET_ARG; prefix_len = arg; GET_ARG; prefix_skip = arg; /* Here comes the prefix string */ if (code+prefix_len < code || code+prefix_len > newcode) FAIL; code += prefix_len; /* And here comes the overlap table */ if (code+prefix_len < code || code+prefix_len > newcode) FAIL; /* Each overlap value should be < prefix_len */ for (i = 0; i < prefix_len; i++) { if (code[i] >= prefix_len) FAIL; } code += prefix_len; } /* Validate the charset */ if (flags & SRE_INFO_CHARSET) { if (!_validate_charset(code, newcode-1)) FAIL; if (newcode[-1] != SRE_OP_FAILURE) FAIL; code = newcode; } else if (code != newcode) { VTRACE(("code=%p, newcode=%p\n", code, newcode)); FAIL; } } break; case SRE_OP_BRANCH: { SRE_CODE *target = NULL; for (;;) { GET_SKIP; if (skip == 0) break; /* Stop 2 before the end; we check the JUMP below */ if (!_validate_inner(code, code+skip-3, groups)) FAIL; code += skip-3; /* Check that it ends with a JUMP, and that each JUMP has the same target */ GET_OP; if (op != SRE_OP_JUMP) FAIL; GET_SKIP; if (target == NULL) target = code+skip-1; else if (code+skip-1 != target) FAIL; } } break; case SRE_OP_REPEAT_ONE: case SRE_OP_MIN_REPEAT_ONE: { SRE_CODE min, max; GET_SKIP; GET_ARG; min = arg; GET_ARG; max = arg; if (min > max) FAIL; #ifdef Py_UNICODE_WIDE if (max > 65535) FAIL; #endif if (!_validate_inner(code, code+skip-4, groups)) FAIL; code += skip-4; GET_OP; if (op != SRE_OP_SUCCESS) FAIL; } break; case SRE_OP_REPEAT: { SRE_CODE min, max; GET_SKIP; GET_ARG; min = arg; GET_ARG; max = arg; if (min > max) FAIL; #ifdef Py_UNICODE_WIDE if (max > 65535) FAIL; #endif if (!_validate_inner(code, code+skip-3, groups)) FAIL; code += skip-3; GET_OP; if (op != SRE_OP_MAX_UNTIL && op != SRE_OP_MIN_UNTIL) FAIL; } break; case SRE_OP_GROUPREF: case SRE_OP_GROUPREF_IGNORE: GET_ARG; if (arg >= groups) FAIL; break; case SRE_OP_GROUPREF_EXISTS: /* The regex syntax for this is: '(?(group)then|else)', where 'group' is either an integer group number or a group name, 'then' and 'else' are sub-regexes, and 'else' is optional. */ GET_ARG; if (arg >= groups) FAIL; GET_SKIP; code--; /* The skip is relative to the first arg! */ /* There are two possibilities here: if there is both a 'then' part and an 'else' part, the generated code looks like: GROUPREF_EXISTS ...then part... JUMP ( jumps here) ...else part... ( jumps here) If there is only a 'then' part, it looks like: GROUPREF_EXISTS ...then part... ( jumps here) There is no direct way to decide which it is, and we don't want to allow arbitrary jumps anywhere in the code; so we just look for a JUMP opcode preceding our skip target. */ if (skip >= 3 && code+skip-3 >= code && code[skip-3] == SRE_OP_JUMP) { VTRACE(("both then and else parts present\n")); if (!_validate_inner(code+1, code+skip-3, groups)) FAIL; code += skip-2; /* Position after JUMP, at */ GET_SKIP; if (!_validate_inner(code, code+skip-1, groups)) FAIL; code += skip-1; } else { VTRACE(("only a then part present\n")); if (!_validate_inner(code+1, code+skip-1, groups)) FAIL; code += skip-1; } break; case SRE_OP_ASSERT: case SRE_OP_ASSERT_NOT: GET_SKIP; GET_ARG; /* 0 for lookahead, width for lookbehind */ code--; /* Back up over arg to simplify math below */ if (arg & 0x80000000) FAIL; /* Width too large */ /* Stop 1 before the end; we check the SUCCESS below */ if (!_validate_inner(code+1, code+skip-2, groups)) FAIL; code += skip-2; GET_OP; if (op != SRE_OP_SUCCESS) FAIL; break; default: FAIL; } } VTRACE(("okay\n")); return 1; } static int _validate_outer(SRE_CODE *code, SRE_CODE *end, Py_ssize_t groups) { if (groups < 0 || groups > 100 || code >= end || end[-1] != SRE_OP_SUCCESS) FAIL; if (groups == 0) /* fix for simplejson */ groups = 100; /* 100 groups should always be safe */ return _validate_inner(code, end-1, groups); } static int _validate(PatternObject *self) { if (!_validate_outer(self->code, self->code+self->codesize, self->groups)) { PyErr_SetString(PyExc_RuntimeError, "invalid SRE code"); return 0; } else VTRACE(("Success!\n")); return 1; } /* -------------------------------------------------------------------- */ /* match methods */ static void match_dealloc(MatchObject* self) { Py_XDECREF(self->regs); Py_XDECREF(self->string); Py_DECREF(self->pattern); PyObject_DEL(self); } static PyObject* match_getslice_by_index(MatchObject* self, Py_ssize_t index, PyObject* def) { if (index < 0 || index >= self->groups) { /* raise IndexError if we were given a bad group number */ PyErr_SetString( PyExc_IndexError, "no such group" ); return NULL; } index *= 2; if (self->string == Py_None || self->mark[index] < 0) { /* return default value if the string or group is undefined */ Py_INCREF(def); return def; } return PySequence_GetSlice( self->string, self->mark[index], self->mark[index+1] ); } static Py_ssize_t match_getindex(MatchObject* self, PyObject* index) { Py_ssize_t i; if (index == NULL) /* Default value */ return 0; if (PyLong_Check(index)) return PyLong_AsSsize_t(index); i = -1; if (self->pattern->groupindex) { index = PyObject_GetItem(self->pattern->groupindex, index); if (index) { if (PyLong_Check(index)) i = PyLong_AsSsize_t(index); Py_DECREF(index); } else PyErr_Clear(); } return i; } static PyObject* match_getslice(MatchObject* self, PyObject* index, PyObject* def) { return match_getslice_by_index(self, match_getindex(self, index), def); } static PyObject* match_expand(MatchObject* self, PyObject* ptemplate) { /* delegate to Python code */ return call( SRE_PY_MODULE, "_expand", PyTuple_Pack(3, self->pattern, self, ptemplate) ); } static PyObject* match_group(MatchObject* self, PyObject* args) { PyObject* result; Py_ssize_t i, size; size = PyTuple_GET_SIZE(args); switch (size) { case 0: result = match_getslice(self, Py_False, Py_None); break; case 1: result = match_getslice(self, PyTuple_GET_ITEM(args, 0), Py_None); break; default: /* fetch multiple items */ result = PyTuple_New(size); if (!result) return NULL; for (i = 0; i < size; i++) { PyObject* item = match_getslice( self, PyTuple_GET_ITEM(args, i), Py_None ); if (!item) { Py_DECREF(result); return NULL; } PyTuple_SET_ITEM(result, i, item); } break; } return result; } static PyObject* match_groups(MatchObject* self, PyObject* args, PyObject* kw) { PyObject* result; Py_ssize_t index; PyObject* def = Py_None; static char* kwlist[] = { "default", NULL }; if (!PyArg_ParseTupleAndKeywords(args, kw, "|O:groups", kwlist, &def)) return NULL; result = PyTuple_New(self->groups-1); if (!result) return NULL; for (index = 1; index < self->groups; index++) { PyObject* item; item = match_getslice_by_index(self, index, def); if (!item) { Py_DECREF(result); return NULL; } PyTuple_SET_ITEM(result, index-1, item); } return result; } static PyObject* match_groupdict(MatchObject* self, PyObject* args, PyObject* kw) { PyObject* result; PyObject* keys; Py_ssize_t index; PyObject* def = Py_None; static char* kwlist[] = { "default", NULL }; if (!PyArg_ParseTupleAndKeywords(args, kw, "|O:groupdict", kwlist, &def)) return NULL; result = PyDict_New(); if (!result || !self->pattern->groupindex) return result; keys = PyMapping_Keys(self->pattern->groupindex); if (!keys) goto failed; for (index = 0; index < PyList_GET_SIZE(keys); index++) { int status; PyObject* key; PyObject* value; key = PyList_GET_ITEM(keys, index); if (!key) goto failed; value = match_getslice(self, key, def); if (!value) { Py_DECREF(key); goto failed; } status = PyDict_SetItem(result, key, value); Py_DECREF(value); if (status < 0) goto failed; } Py_DECREF(keys); return result; failed: Py_XDECREF(keys); Py_DECREF(result); return NULL; } static PyObject* match_start(MatchObject* self, PyObject* args) { Py_ssize_t index; PyObject* index_ = NULL; if (!PyArg_UnpackTuple(args, "start", 0, 1, &index_)) return NULL; index = match_getindex(self, index_); if (index < 0 || index >= self->groups) { PyErr_SetString( PyExc_IndexError, "no such group" ); return NULL; } /* mark is -1 if group is undefined */ return Py_BuildValue("i", self->mark[index*2]); } static PyObject* match_end(MatchObject* self, PyObject* args) { Py_ssize_t index; PyObject* index_ = NULL; if (!PyArg_UnpackTuple(args, "end", 0, 1, &index_)) return NULL; index = match_getindex(self, index_); if (index < 0 || index >= self->groups) { PyErr_SetString( PyExc_IndexError, "no such group" ); return NULL; } /* mark is -1 if group is undefined */ return Py_BuildValue("i", self->mark[index*2+1]); } LOCAL(PyObject*) _pair(Py_ssize_t i1, Py_ssize_t i2) { PyObject* pair; PyObject* item; pair = PyTuple_New(2); if (!pair) return NULL; item = PyLong_FromSsize_t(i1); if (!item) goto error; PyTuple_SET_ITEM(pair, 0, item); item = PyLong_FromSsize_t(i2); if (!item) goto error; PyTuple_SET_ITEM(pair, 1, item); return pair; error: Py_DECREF(pair); return NULL; } static PyObject* match_span(MatchObject* self, PyObject* args) { Py_ssize_t index; PyObject* index_ = NULL; if (!PyArg_UnpackTuple(args, "span", 0, 1, &index_)) return NULL; index = match_getindex(self, index_); if (index < 0 || index >= self->groups) { PyErr_SetString( PyExc_IndexError, "no such group" ); return NULL; } /* marks are -1 if group is undefined */ return _pair(self->mark[index*2], self->mark[index*2+1]); } static PyObject* match_regs(MatchObject* self) { PyObject* regs; PyObject* item; Py_ssize_t index; regs = PyTuple_New(self->groups); if (!regs) return NULL; for (index = 0; index < self->groups; index++) { item = _pair(self->mark[index*2], self->mark[index*2+1]); if (!item) { Py_DECREF(regs); return NULL; } PyTuple_SET_ITEM(regs, index, item); } Py_INCREF(regs); self->regs = regs; return regs; } static PyObject* match_copy(MatchObject* self, PyObject *unused) { #ifdef USE_BUILTIN_COPY MatchObject* copy; Py_ssize_t slots, offset; slots = 2 * (self->pattern->groups+1); copy = PyObject_NEW_VAR(MatchObject, &Match_Type, slots); if (!copy) return NULL; /* this value a constant, but any compiler should be able to figure that out all by itself */ offset = offsetof(MatchObject, string); Py_XINCREF(self->pattern); Py_XINCREF(self->string); Py_XINCREF(self->regs); memcpy((char*) copy + offset, (char*) self + offset, sizeof(MatchObject) + slots * sizeof(Py_ssize_t) - offset); return (PyObject*) copy; #else PyErr_SetString(PyExc_TypeError, "cannot copy this match object"); return NULL; #endif } static PyObject* match_deepcopy(MatchObject* self, PyObject* memo) { #ifdef USE_BUILTIN_COPY MatchObject* copy; copy = (MatchObject*) match_copy(self); if (!copy) return NULL; if (!deepcopy((PyObject**) ©->pattern, memo) || !deepcopy(©->string, memo) || !deepcopy(©->regs, memo)) { Py_DECREF(copy); return NULL; } #else PyErr_SetString(PyExc_TypeError, "cannot deepcopy this match object"); return NULL; #endif } static PyMethodDef match_methods[] = { {"group", (PyCFunction) match_group, METH_VARARGS}, {"start", (PyCFunction) match_start, METH_VARARGS}, {"end", (PyCFunction) match_end, METH_VARARGS}, {"span", (PyCFunction) match_span, METH_VARARGS}, {"groups", (PyCFunction) match_groups, METH_VARARGS|METH_KEYWORDS}, {"groupdict", (PyCFunction) match_groupdict, METH_VARARGS|METH_KEYWORDS}, {"expand", (PyCFunction) match_expand, METH_O}, {"__copy__", (PyCFunction) match_copy, METH_NOARGS}, {"__deepcopy__", (PyCFunction) match_deepcopy, METH_O}, {NULL, NULL} }; static PyObject * match_lastindex_get(MatchObject *self) { if (self->lastindex >= 0) return Py_BuildValue("i", self->lastindex); Py_INCREF(Py_None); return Py_None; } static PyObject * match_lastgroup_get(MatchObject *self) { if (self->pattern->indexgroup && self->lastindex >= 0) { PyObject* result = PySequence_GetItem( self->pattern->indexgroup, self->lastindex ); if (result) return result; PyErr_Clear(); } Py_INCREF(Py_None); return Py_None; } static PyObject * match_regs_get(MatchObject *self) { if (self->regs) { Py_INCREF(self->regs); return self->regs; } else return match_regs(self); } static PyGetSetDef match_getset[] = { {"lastindex", (getter)match_lastindex_get, (setter)NULL}, {"lastgroup", (getter)match_lastgroup_get, (setter)NULL}, {"regs", (getter)match_regs_get, (setter)NULL}, {NULL} }; #define MATCH_OFF(x) offsetof(MatchObject, x) static PyMemberDef match_members[] = { {"string", T_OBJECT, MATCH_OFF(string), READONLY}, {"re", T_OBJECT, MATCH_OFF(pattern), READONLY}, {"pos", T_PYSSIZET, MATCH_OFF(pos), READONLY}, {"endpos", T_PYSSIZET, MATCH_OFF(endpos), READONLY}, {NULL} }; /* FIXME: implement setattr("string", None) as a special case (to detach the associated string, if any */ static PyTypeObject Match_Type = { PyVarObject_HEAD_INIT(NULL,0) "_" SRE_MODULE ".SRE_Match", sizeof(MatchObject), sizeof(Py_ssize_t), (destructor)match_dealloc, /* tp_dealloc */ 0, /* tp_print */ 0, /* tp_getattr */ 0, /* tp_setattr */ 0, /* tp_compare */ 0, /* tp_repr */ 0, /* tp_as_number */ 0, /* tp_as_sequence */ 0, /* tp_as_mapping */ 0, /* tp_hash */ 0, /* tp_call */ 0, /* tp_str */ 0, /* tp_getattro */ 0, /* tp_setattro */ 0, /* tp_as_buffer */ Py_TPFLAGS_DEFAULT, /* tp_flags */ 0, /* tp_doc */ 0, /* tp_traverse */ 0, /* tp_clear */ 0, /* tp_richcompare */ 0, /* tp_weaklistoffset */ 0, /* tp_iter */ 0, /* tp_iternext */ match_methods, /* tp_methods */ match_members, /* tp_members */ match_getset, /* tp_getset */ }; static PyObject* pattern_new_match(PatternObject* pattern, SRE_STATE* state, int status) { /* create match object (from state object) */ MatchObject* match; Py_ssize_t i, j; char* base; int n; if (status > 0) { /* create match object (with room for extra group marks) */ /* coverity[ampersand_in_size] */ match = PyObject_NEW_VAR(MatchObject, &Match_Type, 2*(pattern->groups+1)); if (!match) return NULL; Py_INCREF(pattern); match->pattern = pattern; Py_INCREF(state->string); match->string = state->string; match->regs = NULL; match->groups = pattern->groups+1; /* fill in group slices */ base = (char*) state->beginning; n = state->charsize; match->mark[0] = ((char*) state->start - base) / n; match->mark[1] = ((char*) state->ptr - base) / n; for (i = j = 0; i < pattern->groups; i++, j+=2) if (j+1 <= state->lastmark && state->mark[j] && state->mark[j+1]) { match->mark[j+2] = ((char*) state->mark[j] - base) / n; match->mark[j+3] = ((char*) state->mark[j+1] - base) / n; } else match->mark[j+2] = match->mark[j+3] = -1; /* undefined */ match->pos = state->pos; match->endpos = state->endpos; match->lastindex = state->lastindex; return (PyObject*) match; } else if (status == 0) { /* no match */ Py_INCREF(Py_None); return Py_None; } /* internal error */ pattern_error(status); return NULL; } /* -------------------------------------------------------------------- */ /* scanner methods (experimental) */ static void scanner_dealloc(ScannerObject* self) { state_fini(&self->state); Py_DECREF(self->pattern); PyObject_DEL(self); } static PyObject* scanner_match(ScannerObject* self, PyObject *unused) { SRE_STATE* state = &self->state; PyObject* match; int status; state_reset(state); state->ptr = state->start; if (state->charsize == 1) { status = sre_match(state, PatternObject_GetCode(self->pattern)); } else { #if defined(HAVE_UNICODE) status = sre_umatch(state, PatternObject_GetCode(self->pattern)); #endif } if (PyErr_Occurred()) return NULL; match = pattern_new_match((PatternObject*) self->pattern, state, status); if (status == 0 || state->ptr == state->start) state->start = (void*) ((char*) state->ptr + state->charsize); else state->start = state->ptr; return match; } static PyObject* scanner_search(ScannerObject* self, PyObject *unused) { SRE_STATE* state = &self->state; PyObject* match; int status; state_reset(state); state->ptr = state->start; if (state->charsize == 1) { status = sre_search(state, PatternObject_GetCode(self->pattern)); } else { #if defined(HAVE_UNICODE) status = sre_usearch(state, PatternObject_GetCode(self->pattern)); #endif } if (PyErr_Occurred()) return NULL; match = pattern_new_match((PatternObject*) self->pattern, state, status); if (status == 0 || state->ptr == state->start) state->start = (void*) ((char*) state->ptr + state->charsize); else state->start = state->ptr; return match; } static PyMethodDef scanner_methods[] = { {"match", (PyCFunction) scanner_match, METH_NOARGS}, {"search", (PyCFunction) scanner_search, METH_NOARGS}, {NULL, NULL} }; #define SCAN_OFF(x) offsetof(ScannerObject, x) static PyMemberDef scanner_members[] = { {"pattern", T_OBJECT, SCAN_OFF(pattern), READONLY}, {NULL} /* Sentinel */ }; static PyTypeObject Scanner_Type = { PyVarObject_HEAD_INIT(NULL, 0) "_" SRE_MODULE ".SRE_Scanner", sizeof(ScannerObject), 0, (destructor)scanner_dealloc,/* tp_dealloc */ 0, /* tp_print */ 0, /* tp_getattr */ 0, /* tp_setattr */ 0, /* tp_compare */ 0, /* tp_repr */ 0, /* tp_as_number */ 0, /* tp_as_sequence */ 0, /* tp_as_mapping */ 0, /* tp_hash */ 0, /* tp_call */ 0, /* tp_str */ 0, /* tp_getattro */ 0, /* tp_setattro */ 0, /* tp_as_buffer */ Py_TPFLAGS_DEFAULT, /* tp_flags */ 0, /* tp_doc */ 0, /* tp_traverse */ 0, /* tp_clear */ 0, /* tp_richcompare */ 0, /* tp_weaklistoffset */ 0, /* tp_iter */ 0, /* tp_iternext */ scanner_methods, /* tp_methods */ scanner_members, /* tp_members */ 0, /* tp_getset */ }; static PyObject* pattern_scanner(PatternObject* pattern, PyObject* args) { /* create search state object */ ScannerObject* self; PyObject* string; Py_ssize_t start = 0; Py_ssize_t end = PY_SSIZE_T_MAX; if (!PyArg_ParseTuple(args, "O|nn:scanner", &string, &start, &end)) return NULL; /* create scanner object */ self = PyObject_NEW(ScannerObject, &Scanner_Type); if (!self) return NULL; string = state_init(&self->state, pattern, string, start, end); if (!string) { PyObject_DEL(self); return NULL; } Py_INCREF(pattern); self->pattern = (PyObject*) pattern; return (PyObject*) self; } static PyMethodDef _functions[] = { {"compile", _compile, METH_VARARGS}, {"getcodesize", sre_codesize, METH_NOARGS}, {"getlower", sre_getlower, METH_VARARGS}, {NULL, NULL} }; static struct PyModuleDef sremodule = { PyModuleDef_HEAD_INIT, "_" SRE_MODULE, NULL, -1, _functions, NULL, NULL, NULL, NULL }; PyMODINIT_FUNC PyInit__sre(void) { PyObject* m; PyObject* d; PyObject* x; /* Initialize object types */ if (PyType_Ready(&Pattern_Type) < 0) return NULL; if (PyType_Ready(&Match_Type) < 0) return NULL; if (PyType_Ready(&Scanner_Type) < 0) return NULL; m = PyModule_Create(&sremodule); if (m == NULL) return NULL; d = PyModule_GetDict(m); x = PyLong_FromLong(SRE_MAGIC); if (x) { PyDict_SetItemString(d, "MAGIC", x); Py_DECREF(x); } x = PyLong_FromLong(sizeof(SRE_CODE)); if (x) { PyDict_SetItemString(d, "CODESIZE", x); Py_DECREF(x); } x = PyUnicode_FromString(copyright); if (x) { PyDict_SetItemString(d, "copyright", x); Py_DECREF(x); } return m; } #endif /* !defined(SRE_RECURSIVE) */ /* vim:ts=4:sw=4:et */