/* * MD4C: Markdown parser for C * (http://github.com/mity/md4c) * * Copyright (c) 2016-2019 Martin Mitas * * Permission is hereby granted, free of charge, to any person obtaining a * copy of this software and associated documentation files (the "Software"), * to deal in the Software without restriction, including without limitation * the rights to use, copy, modify, merge, publish, distribute, sublicense, * and/or sell copies of the Software, and to permit persons to whom the * Software is furnished to do so, subject to the following conditions: * * The above copyright notice and this permission notice shall be included in * all copies or substantial portions of the Software. * * THE SOFTWARE IS PROVIDED "AS IS", WITHOUT WARRANTY OF ANY KIND, EXPRESS * OR IMPLIED, INCLUDING BUT NOT LIMITED TO THE WARRANTIES OF MERCHANTABILITY, * FITNESS FOR A PARTICULAR PURPOSE AND NONINFRINGEMENT. IN NO EVENT SHALL THE * AUTHORS OR COPYRIGHT HOLDERS BE LIABLE FOR ANY CLAIM, DAMAGES OR OTHER * LIABILITY, WHETHER IN AN ACTION OF CONTRACT, TORT OR OTHERWISE, ARISING * FROM, OUT OF OR IN CONNECTION WITH THE SOFTWARE OR THE USE OR OTHER DEALINGS * IN THE SOFTWARE. */ #include "md4c.h" #include #include #include #include /***************************** *** Miscellaneous Stuff *** *****************************/ #ifdef _MSC_VER /* MSVC does not understand "inline" when building as pure C (not C++). * However it understands "__inline" */ #ifndef __cplusplus #define inline __inline #endif #endif #ifdef _T #undef _T #endif #if defined MD4C_USE_UTF16 #define _T(x) L##x #else #define _T(x) x #endif /* Misc. macros. */ #define SIZEOF_ARRAY(a) (sizeof(a) / sizeof(a[0])) #define STRINGIZE_(x) #x #define STRINGIZE(x) STRINGIZE_(x) #ifndef TRUE #define TRUE 1 #define FALSE 0 #endif /************************ *** Internal Types *** ************************/ /* These are omnipresent so lets save some typing. */ #define CHAR MD_CHAR #define SZ MD_SIZE #define OFF MD_OFFSET typedef struct MD_MARK_tag MD_MARK; typedef struct MD_BLOCK_tag MD_BLOCK; typedef struct MD_CONTAINER_tag MD_CONTAINER; typedef struct MD_REF_DEF_tag MD_REF_DEF; /* During analyzes of inline marks, we need to manage some "mark chains", * of (yet unresolved) openers. This structure holds start/end of the chain. * The chain internals are then realized through MD_MARK::prev and ::next. */ typedef struct MD_MARKCHAIN_tag MD_MARKCHAIN; struct MD_MARKCHAIN_tag { int head; /* Index of first mark in the chain, or -1 if empty. */ int tail; /* Index of last mark in the chain, or -1 if empty. */ }; /* Context propagated through all the parsing. */ typedef struct MD_CTX_tag MD_CTX; struct MD_CTX_tag { /* Immutable stuff (parameters of md_parse()). */ const CHAR* text; SZ size; MD_PARSER parser; void* userdata; /* When this is true, it allows some optimizations. */ int doc_ends_with_newline; /* Helper temporary growing buffer. */ CHAR* buffer; unsigned alloc_buffer; /* Reference definitions. */ MD_REF_DEF* ref_defs; int n_ref_defs; int alloc_ref_defs; void** ref_def_hashtable; int ref_def_hashtable_size; /* Stack of inline/span markers. * This is only used for parsing a single block contents but by storing it * here we may reuse the stack for subsequent blocks; i.e. we have fewer * (re)allocations. */ MD_MARK* marks; int n_marks; int alloc_marks; #if defined MD4C_USE_UTF16 char mark_char_map[128]; #else char mark_char_map[256]; #endif /* For resolving of inline spans. */ MD_MARKCHAIN mark_chains[12]; #define PTR_CHAIN ctx->mark_chains[0] #define TABLECELLBOUNDARIES ctx->mark_chains[1] #define ASTERISK_OPENERS_extraword_mod3_0 ctx->mark_chains[2] #define ASTERISK_OPENERS_extraword_mod3_1 ctx->mark_chains[3] #define ASTERISK_OPENERS_extraword_mod3_2 ctx->mark_chains[4] #define ASTERISK_OPENERS_intraword_mod3_0 ctx->mark_chains[5] #define ASTERISK_OPENERS_intraword_mod3_1 ctx->mark_chains[6] #define ASTERISK_OPENERS_intraword_mod3_2 ctx->mark_chains[7] #define UNDERSCORE_OPENERS ctx->mark_chains[8] #define TILDE_OPENERS ctx->mark_chains[9] #define BRACKET_OPENERS ctx->mark_chains[10] #define DOLLAR_OPENERS ctx->mark_chains[11] #define OPENERS_CHAIN_FIRST 2 #define OPENERS_CHAIN_LAST 11 int n_table_cell_boundaries; /* For resolving links. */ int unresolved_link_head; int unresolved_link_tail; /* For resolving raw HTML. */ OFF html_comment_horizon; OFF html_proc_instr_horizon; OFF html_decl_horizon; OFF html_cdata_horizon; /* For block analysis. * Notes: * -- It holds MD_BLOCK as well as MD_LINE structures. After each * MD_BLOCK, its (multiple) MD_LINE(s) follow. * -- For MD_BLOCK_HTML and MD_BLOCK_CODE, MD_VERBATIMLINE(s) are used * instead of MD_LINE(s). */ void* block_bytes; MD_BLOCK* current_block; int n_block_bytes; int alloc_block_bytes; /* For container block analysis. */ MD_CONTAINER* containers; int n_containers; int alloc_containers; /* Minimal indentation to call the block "indented code block". */ unsigned code_indent_offset; /* Contextual info for line analysis. */ SZ code_fence_length; /* For checking closing fence length. */ int html_block_type; /* For checking closing raw HTML condition. */ int last_line_has_list_loosening_effect; int last_list_item_starts_with_two_blank_lines; }; enum MD_LINETYPE_tag { MD_LINE_BLANK, MD_LINE_HR, MD_LINE_ATXHEADER, MD_LINE_SETEXTHEADER, MD_LINE_SETEXTUNDERLINE, MD_LINE_INDENTEDCODE, MD_LINE_FENCEDCODE, MD_LINE_HTML, MD_LINE_TEXT, MD_LINE_TABLE, MD_LINE_TABLEUNDERLINE }; typedef enum MD_LINETYPE_tag MD_LINETYPE; typedef struct MD_LINE_ANALYSIS_tag MD_LINE_ANALYSIS; struct MD_LINE_ANALYSIS_tag { MD_LINETYPE type : 16; unsigned data : 16; OFF beg; OFF end; unsigned indent; /* Indentation level. */ }; typedef struct MD_LINE_tag MD_LINE; struct MD_LINE_tag { OFF beg; OFF end; }; typedef struct MD_VERBATIMLINE_tag MD_VERBATIMLINE; struct MD_VERBATIMLINE_tag { OFF beg; OFF end; OFF indent; }; /******************* *** Debugging *** *******************/ #define MD_LOG(msg) \ do { \ if(ctx->parser.debug_log != NULL) \ ctx->parser.debug_log((msg), ctx->userdata); \ } while(0) #ifdef DEBUG #define MD_ASSERT(cond) \ do { \ if(!(cond)) { \ MD_LOG(__FILE__ ":" STRINGIZE(__LINE__) ": " \ "Assertion '" STRINGIZE(cond) "' failed."); \ exit(1); \ } \ } while(0) #define MD_UNREACHABLE() MD_ASSERT(1 == 0) #else #ifdef __GNUC__ #define MD_ASSERT(cond) do { if(!(cond)) __builtin_unreachable(); } while(0) #define MD_UNREACHABLE() do { __builtin_unreachable(); } while(0) #elif defined _MSC_VER && _MSC_VER > 120 #define MD_ASSERT(cond) do { __assume(cond); } while(0) #define MD_UNREACHABLE() do { __assume(0); } while(0) #else #define MD_ASSERT(cond) do {} while(0) #define MD_UNREACHABLE() do {} while(0) #endif #endif /***************** *** Helpers *** *****************/ /* Character accessors. */ #define CH(off) (ctx->text[(off)]) #define STR(off) (ctx->text + (off)) /* Character classification. * Note we assume ASCII compatibility of code points < 128 here. */ #define ISIN_(ch, ch_min, ch_max) ((ch_min) <= (unsigned)(ch) && (unsigned)(ch) <= (ch_max)) #define ISANYOF_(ch, palette) (md_strchr((palette), (ch)) != NULL) #define ISANYOF2_(ch, ch1, ch2) ((ch) == (ch1) || (ch) == (ch2)) #define ISANYOF3_(ch, ch1, ch2, ch3) ((ch) == (ch1) || (ch) == (ch2) || (ch) == (ch3)) #define ISASCII_(ch) ((unsigned)(ch) <= 127) #define ISBLANK_(ch) (ISANYOF2_((ch), _T(' '), _T('\t'))) #define ISNEWLINE_(ch) (ISANYOF2_((ch), _T('\r'), _T('\n'))) #define ISWHITESPACE_(ch) (ISBLANK_(ch) || ISANYOF2_((ch), _T('\v'), _T('\f'))) #define ISCNTRL_(ch) ((unsigned)(ch) <= 31 || (unsigned)(ch) == 127) #define ISPUNCT_(ch) (ISIN_(ch, 33, 47) || ISIN_(ch, 58, 64) || ISIN_(ch, 91, 96) || ISIN_(ch, 123, 126)) #define ISUPPER_(ch) (ISIN_(ch, _T('A'), _T('Z'))) #define ISLOWER_(ch) (ISIN_(ch, _T('a'), _T('z'))) #define ISALPHA_(ch) (ISUPPER_(ch) || ISLOWER_(ch)) #define ISDIGIT_(ch) (ISIN_(ch, _T('0'), _T('9'))) #define ISXDIGIT_(ch) (ISDIGIT_(ch) || ISIN_(ch, _T('A'), _T('F')) || ISIN_(ch, _T('a'), _T('f'))) #define ISALNUM_(ch) (ISALPHA_(ch) || ISDIGIT_(ch)) #define ISANYOF(off, palette) ISANYOF_(CH(off), (palette)) #define ISANYOF2(off, ch1, ch2) ISANYOF2_(CH(off), (ch1), (ch2)) #define ISANYOF3(off, ch1, ch2, ch3) ISANYOF3_(CH(off), (ch1), (ch2), (ch3)) #define ISASCII(off) ISASCII_(CH(off)) #define ISBLANK(off) ISBLANK_(CH(off)) #define ISNEWLINE(off) ISNEWLINE_(CH(off)) #define ISWHITESPACE(off) ISWHITESPACE_(CH(off)) #define ISCNTRL(off) ISCNTRL_(CH(off)) #define ISPUNCT(off) ISPUNCT_(CH(off)) #define ISUPPER(off) ISUPPER_(CH(off)) #define ISLOWER(off) ISLOWER_(CH(off)) #define ISALPHA(off) ISALPHA_(CH(off)) #define ISDIGIT(off) ISDIGIT_(CH(off)) #define ISXDIGIT(off) ISXDIGIT_(CH(off)) #define ISALNUM(off) ISALNUM_(CH(off)) static inline const CHAR* md_strchr(const CHAR* str, CHAR ch) { OFF i; for(i = 0; str[i] != _T('\0'); i++) { if(ch == str[i]) return (str + i); } return NULL; } /* Case insensitive check of string equality. */ static inline int md_ascii_case_eq(const CHAR* s1, const CHAR* s2, SZ n) { OFF i; for(i = 0; i < n; i++) { CHAR ch1 = s1[i]; CHAR ch2 = s2[i]; if(ISLOWER_(ch1)) ch1 += ('A'-'a'); if(ISLOWER_(ch2)) ch2 += ('A'-'a'); if(ch1 != ch2) return FALSE; } return TRUE; } static inline int md_ascii_eq(const CHAR* s1, const CHAR* s2, SZ n) { return memcmp(s1, s2, n * sizeof(CHAR)) == 0; } static int md_text_with_null_replacement(MD_CTX* ctx, MD_TEXTTYPE type, const CHAR* str, SZ size) { OFF off = 0; int ret = 0; while(1) { while(off < size && str[off] != _T('\0')) off++; if(off > 0) { ret = ctx->parser.text(type, str, off, ctx->userdata); if(ret != 0) return ret; str += off; size -= off; off = 0; } if(off >= size) return 0; ret = ctx->parser.text(MD_TEXT_NULLCHAR, _T(""), 1, ctx->userdata); if(ret != 0) return ret; off++; } } #define MD_CHECK(func) \ do { \ ret = (func); \ if(ret < 0) \ goto abort; \ } while(0) #define MD_TEMP_BUFFER(sz) \ do { \ if(sz > ctx->alloc_buffer) { \ CHAR* new_buffer; \ SZ new_size = ((sz) + (sz) / 2 + 128) & ~127; \ \ new_buffer = realloc(ctx->buffer, new_size); \ if(new_buffer == NULL) { \ MD_LOG("realloc() failed."); \ ret = -1; \ goto abort; \ } \ \ ctx->buffer = new_buffer; \ ctx->alloc_buffer = new_size; \ } \ } while(0) #define MD_ENTER_BLOCK(type, arg) \ do { \ ret = ctx->parser.enter_block((type), (arg), ctx->userdata); \ if(ret != 0) { \ MD_LOG("Aborted from enter_block() callback."); \ goto abort; \ } \ } while(0) #define MD_LEAVE_BLOCK(type, arg) \ do { \ ret = ctx->parser.leave_block((type), (arg), ctx->userdata); \ if(ret != 0) { \ MD_LOG("Aborted from leave_block() callback."); \ goto abort; \ } \ } while(0) #define MD_ENTER_SPAN(type, arg) \ do { \ ret = ctx->parser.enter_span((type), (arg), ctx->userdata); \ if(ret != 0) { \ MD_LOG("Aborted from enter_span() callback."); \ goto abort; \ } \ } while(0) #define MD_LEAVE_SPAN(type, arg) \ do { \ ret = ctx->parser.leave_span((type), (arg), ctx->userdata); \ if(ret != 0) { \ MD_LOG("Aborted from leave_span() callback."); \ goto abort; \ } \ } while(0) #define MD_TEXT(type, str, size) \ do { \ if(size > 0) { \ ret = ctx->parser.text((type), (str), (size), ctx->userdata); \ if(ret != 0) { \ MD_LOG("Aborted from text() callback."); \ goto abort; \ } \ } \ } while(0) #define MD_TEXT_INSECURE(type, str, size) \ do { \ if(size > 0) { \ ret = md_text_with_null_replacement(ctx, type, str, size); \ if(ret != 0) { \ MD_LOG("Aborted from text() callback."); \ goto abort; \ } \ } \ } while(0) /************************* *** Unicode Support *** *************************/ typedef struct MD_UNICODE_FOLD_INFO_tag MD_UNICODE_FOLD_INFO; struct MD_UNICODE_FOLD_INFO_tag { unsigned codepoints[3]; int n_codepoints; }; #if defined MD4C_USE_UTF16 || defined MD4C_USE_UTF8 /* Binary search over sorted "map" of codepoints. Consecutive sequences * of codepoints may be encoded in the map by just using the * (MIN_CODEPOINT | 0x40000000) and (MAX_CODEPOINT | 0x80000000). * * Returns index of the found record in the map (in the case of ranges, * the minimal value is used); or -1 on failure. */ static int md_unicode_bsearch__(unsigned codepoint, const unsigned* map, size_t map_size) { int beg, end; int pivot_beg, pivot_end; beg = 0; end = (int) map_size-1; while(beg <= end) { /* Pivot may be a range, not just a single value. */ pivot_beg = pivot_end = (beg + end) / 2; if(map[pivot_end] & 0x40000000) pivot_end++; if(map[pivot_beg] & 0x80000000) pivot_beg--; if(codepoint < (map[pivot_beg] & 0x00ffffff)) end = pivot_beg - 1; else if(codepoint > (map[pivot_end] & 0x00ffffff)) beg = pivot_end + 1; else return pivot_beg; } return -1; } static int md_is_unicode_whitespace__(unsigned codepoint) { #define R(cp_min, cp_max) ((cp_min) | 0x40000000), ((cp_max) | 0x80000000) #define S(cp) (cp) /* Unicode "Zs" category. * (generated by scripts/build_whitespace_map.py) */ static const unsigned WHITESPACE_MAP[] = { S(0x0020), S(0x00a0), S(0x1680), R(0x2000,0x200a), S(0x202f), S(0x205f), S(0x3000) }; #undef R #undef S /* The ASCII ones are the most frequently used ones, also CommonMark * specification requests few more in this range. */ if(codepoint <= 0x7f) return ISWHITESPACE_(codepoint); return (md_unicode_bsearch__(codepoint, WHITESPACE_MAP, SIZEOF_ARRAY(WHITESPACE_MAP)) >= 0); } static int md_is_unicode_punct__(unsigned codepoint) { #define R(cp_min, cp_max) ((cp_min) | 0x40000000), ((cp_max) | 0x80000000) #define S(cp) (cp) /* Unicode "Pc", "Pd", "Pe", "Pf", "Pi", "Po", "Ps" categories. * (generated by scripts/build_punct_map.py) */ static const unsigned PUNCT_MAP[] = { R(0x0021,0x0023), R(0x0025,0x002a), R(0x002c,0x002f), R(0x003a,0x003b), R(0x003f,0x0040), R(0x005b,0x005d), S(0x005f), S(0x007b), S(0x007d), S(0x00a1), S(0x00a7), S(0x00ab), R(0x00b6,0x00b7), S(0x00bb), S(0x00bf), S(0x037e), S(0x0387), R(0x055a,0x055f), R(0x0589,0x058a), S(0x05be), S(0x05c0), S(0x05c3), S(0x05c6), R(0x05f3,0x05f4), R(0x0609,0x060a), R(0x060c,0x060d), S(0x061b), R(0x061e,0x061f), R(0x066a,0x066d), S(0x06d4), R(0x0700,0x070d), R(0x07f7,0x07f9), R(0x0830,0x083e), S(0x085e), R(0x0964,0x0965), S(0x0970), S(0x09fd), S(0x0a76), S(0x0af0), S(0x0c77), S(0x0c84), S(0x0df4), S(0x0e4f), R(0x0e5a,0x0e5b), R(0x0f04,0x0f12), S(0x0f14), R(0x0f3a,0x0f3d), S(0x0f85), R(0x0fd0,0x0fd4), R(0x0fd9,0x0fda), R(0x104a,0x104f), S(0x10fb), R(0x1360,0x1368), S(0x1400), S(0x166e), R(0x169b,0x169c), R(0x16eb,0x16ed), R(0x1735,0x1736), R(0x17d4,0x17d6), R(0x17d8,0x17da), R(0x1800,0x180a), R(0x1944,0x1945), R(0x1a1e,0x1a1f), R(0x1aa0,0x1aa6), R(0x1aa8,0x1aad), R(0x1b5a,0x1b60), R(0x1bfc,0x1bff), R(0x1c3b,0x1c3f), R(0x1c7e,0x1c7f), R(0x1cc0,0x1cc7), S(0x1cd3), R(0x2010,0x2027), R(0x2030,0x2043), R(0x2045,0x2051), R(0x2053,0x205e), R(0x207d,0x207e), R(0x208d,0x208e), R(0x2308,0x230b), R(0x2329,0x232a), R(0x2768,0x2775), R(0x27c5,0x27c6), R(0x27e6,0x27ef), R(0x2983,0x2998), R(0x29d8,0x29db), R(0x29fc,0x29fd), R(0x2cf9,0x2cfc), R(0x2cfe,0x2cff), S(0x2d70), R(0x2e00,0x2e2e), R(0x2e30,0x2e4f), R(0x3001,0x3003), R(0x3008,0x3011), R(0x3014,0x301f), S(0x3030), S(0x303d), S(0x30a0), S(0x30fb), R(0xa4fe,0xa4ff), R(0xa60d,0xa60f), S(0xa673), S(0xa67e), R(0xa6f2,0xa6f7), R(0xa874,0xa877), R(0xa8ce,0xa8cf), R(0xa8f8,0xa8fa), S(0xa8fc), R(0xa92e,0xa92f), S(0xa95f), R(0xa9c1,0xa9cd), R(0xa9de,0xa9df), R(0xaa5c,0xaa5f), R(0xaade,0xaadf), R(0xaaf0,0xaaf1), S(0xabeb), R(0xfd3e,0xfd3f), R(0xfe10,0xfe19), R(0xfe30,0xfe52), R(0xfe54,0xfe61), S(0xfe63), S(0xfe68), R(0xfe6a,0xfe6b), R(0xff01,0xff03), R(0xff05,0xff0a), R(0xff0c,0xff0f), R(0xff1a,0xff1b), R(0xff1f,0xff20), R(0xff3b,0xff3d), S(0xff3f), S(0xff5b), S(0xff5d), R(0xff5f,0xff65), R(0x10100,0x10102), S(0x1039f), S(0x103d0), S(0x1056f), S(0x10857), S(0x1091f), S(0x1093f), R(0x10a50,0x10a58), S(0x10a7f), R(0x10af0,0x10af6), R(0x10b39,0x10b3f), R(0x10b99,0x10b9c), R(0x10f55,0x10f59), R(0x11047,0x1104d), R(0x110bb,0x110bc), R(0x110be,0x110c1), R(0x11140,0x11143), R(0x11174,0x11175), R(0x111c5,0x111c8), S(0x111cd), S(0x111db), R(0x111dd,0x111df), R(0x11238,0x1123d), S(0x112a9), R(0x1144b,0x1144f), S(0x1145b), S(0x1145d), S(0x114c6), R(0x115c1,0x115d7), R(0x11641,0x11643), R(0x11660,0x1166c), R(0x1173c,0x1173e), S(0x1183b), S(0x119e2), R(0x11a3f,0x11a46), R(0x11a9a,0x11a9c), R(0x11a9e,0x11aa2), R(0x11c41,0x11c45), R(0x11c70,0x11c71), R(0x11ef7,0x11ef8), S(0x11fff), R(0x12470,0x12474), R(0x16a6e,0x16a6f), S(0x16af5), R(0x16b37,0x16b3b), S(0x16b44), R(0x16e97,0x16e9a), S(0x16fe2), S(0x1bc9f), R(0x1da87,0x1da8b), R(0x1e95e,0x1e95f) }; #undef R #undef S /* The ASCII ones are the most frequently used ones, also CommonMark * specification requests few more in this range. */ if(codepoint <= 0x7f) return ISPUNCT_(codepoint); return (md_unicode_bsearch__(codepoint, PUNCT_MAP, SIZEOF_ARRAY(PUNCT_MAP)) >= 0); } static void md_get_unicode_fold_info(unsigned codepoint, MD_UNICODE_FOLD_INFO* info) { #define R(cp_min, cp_max) ((cp_min) | 0x40000000), ((cp_max) | 0x80000000) #define S(cp) (cp) /* Unicode "Pc", "Pd", "Pe", "Pf", "Pi", "Po", "Ps" categories. * (generated by scripts/build_punct_map.py) */ static const unsigned FOLD_MAP_1[] = { R(0x0041,0x005a), S(0x00b5), R(0x00c0,0x00d6), R(0x00d8,0x00de), R(0x0100,0x012e), R(0x0132,0x0136), R(0x0139,0x0147), R(0x014a,0x0176), S(0x0178), R(0x0179,0x017d), S(0x017f), S(0x0181), S(0x0182), S(0x0186), S(0x0187), S(0x0189), S(0x018b), S(0x018e), S(0x018f), S(0x0190), S(0x0191), S(0x0193), S(0x0194), S(0x0196), S(0x0197), S(0x0198), S(0x019c), S(0x019d), S(0x019f), R(0x01a0,0x01a4), S(0x01a6), S(0x01a7), S(0x01a9), S(0x01ac), S(0x01ae), S(0x01af), S(0x01b1), S(0x01b3), S(0x01b7), S(0x01b8), S(0x01bc), S(0x01c4), S(0x01c5), S(0x01c7), S(0x01c8), S(0x01ca), R(0x01cb,0x01db), R(0x01de,0x01ee), S(0x01f1), S(0x01f2), S(0x01f6), S(0x01f7), R(0x01f8,0x021e), S(0x0220), R(0x0222,0x0232), S(0x023a), S(0x023b), S(0x023d), S(0x023e), S(0x0241), S(0x0243), S(0x0244), S(0x0245), R(0x0246,0x024e), S(0x0345), S(0x0370), S(0x0376), S(0x037f), S(0x0386), R(0x0388,0x038a), S(0x038c), S(0x038e), R(0x0391,0x03a1), R(0x03a3,0x03ab), S(0x03c2), S(0x03cf), S(0x03d0), S(0x03d1), S(0x03d5), S(0x03d6), R(0x03d8,0x03ee), S(0x03f0), S(0x03f1), S(0x03f4), S(0x03f5), S(0x03f7), S(0x03f9), S(0x03fa), R(0x03fd,0x03ff), R(0x0400,0x040f), R(0x0410,0x042f), R(0x0460,0x0480), R(0x048a,0x04be), S(0x04c0), R(0x04c1,0x04cd), R(0x04d0,0x052e), R(0x0531,0x0556), R(0x10a0,0x10c5), S(0x10c7), S(0x10cd), R(0x13f8,0x13fd), S(0x1c80), S(0x1c81), S(0x1c82), S(0x1c83), S(0x1c85), S(0x1c86), S(0x1c87), S(0x1c88), R(0x1c90,0x1cba), R(0x1cbd,0x1cbf), R(0x1e00,0x1e94), S(0x1e9b), R(0x1ea0,0x1efe), R(0x1f08,0x1f0f), R(0x1f18,0x1f1d), R(0x1f28,0x1f2f), R(0x1f38,0x1f3f), R(0x1f48,0x1f4d), S(0x1f59), S(0x1f5b), S(0x1f5d), S(0x1f5f), R(0x1f68,0x1f6f), S(0x1fb8), S(0x1fba), S(0x1fbe), R(0x1fc8,0x1fcb), S(0x1fd8), S(0x1fda), S(0x1fe8), S(0x1fea), S(0x1fec), S(0x1ff8), S(0x1ffa), S(0x2126), S(0x212a), S(0x212b), S(0x2132), R(0x2160,0x216f), S(0x2183), R(0x24b6,0x24cf), R(0x2c00,0x2c2e), S(0x2c60), S(0x2c62), S(0x2c63), S(0x2c64), R(0x2c67,0x2c6b), S(0x2c6d), S(0x2c6e), S(0x2c6f), S(0x2c70), S(0x2c72), S(0x2c75), S(0x2c7e), R(0x2c80,0x2ce2), S(0x2ceb), S(0x2cf2), R(0xa640,0xa66c), R(0xa680,0xa69a), R(0xa722,0xa72e), R(0xa732,0xa76e), S(0xa779), S(0xa77d), R(0xa77e,0xa786), S(0xa78b), S(0xa78d), S(0xa790), R(0xa796,0xa7a8), S(0xa7aa), S(0xa7ab), S(0xa7ac), S(0xa7ad), S(0xa7ae), S(0xa7b0), S(0xa7b1), S(0xa7b2), S(0xa7b3), R(0xa7b4,0xa7be), S(0xa7c2), S(0xa7c4), S(0xa7c5), S(0xa7c6), R(0xab70,0xabbf), R(0xff21,0xff3a), R(0x10400,0x10427), R(0x104b0,0x104d3), R(0x10c80,0x10cb2), R(0x118a0,0x118bf), R(0x16e40,0x16e5f), R(0x1e900,0x1e921) }; static const unsigned FOLD_MAP_1_DATA[] = { 0x0061, 0x007a, 0x03bc, 0x00e0, 0x00f6, 0x00f8, 0x00fe, 0x0101, 0x012f, 0x0133, 0x0137, 0x013a, 0x0148, 0x014b, 0x0177, 0x00ff, 0x017a, 0x017e, 0x0073, 0x0253, 0x0183, 0x0254, 0x0188, 0x0256, 0x018c, 0x01dd, 0x0259, 0x025b, 0x0192, 0x0260, 0x0263, 0x0269, 0x0268, 0x0199, 0x026f, 0x0272, 0x0275, 0x01a1, 0x01a5, 0x0280, 0x01a8, 0x0283, 0x01ad, 0x0288, 0x01b0, 0x028a, 0x01b4, 0x0292, 0x01b9, 0x01bd, 0x01c6, 0x01c6, 0x01c9, 0x01c9, 0x01cc, 0x01cc, 0x01dc, 0x01df, 0x01ef, 0x01f3, 0x01f3, 0x0195, 0x01bf, 0x01f9, 0x021f, 0x019e, 0x0223, 0x0233, 0x2c65, 0x023c, 0x019a, 0x2c66, 0x0242, 0x0180, 0x0289, 0x028c, 0x0247, 0x024f, 0x03b9, 0x0371, 0x0377, 0x03f3, 0x03ac, 0x03ad, 0x03af, 0x03cc, 0x03cd, 0x03b1, 0x03c1, 0x03c3, 0x03cb, 0x03c3, 0x03d7, 0x03b2, 0x03b8, 0x03c6, 0x03c0, 0x03d9, 0x03ef, 0x03ba, 0x03c1, 0x03b8, 0x03b5, 0x03f8, 0x03f2, 0x03fb, 0x037b, 0x037d, 0x0450, 0x045f, 0x0430, 0x044f, 0x0461, 0x0481, 0x048b, 0x04bf, 0x04cf, 0x04c2, 0x04ce, 0x04d1, 0x052f, 0x0561, 0x0586, 0x2d00, 0x2d25, 0x2d27, 0x2d2d, 0x13f0, 0x13f5, 0x0432, 0x0434, 0x043e, 0x0441, 0x0442, 0x044a, 0x0463, 0xa64b, 0x10d0, 0x10fa, 0x10fd, 0x10ff, 0x1e01, 0x1e95, 0x1e61, 0x1ea1, 0x1eff, 0x1f00, 0x1f07, 0x1f10, 0x1f15, 0x1f20, 0x1f27, 0x1f30, 0x1f37, 0x1f40, 0x1f45, 0x1f51, 0x1f53, 0x1f55, 0x1f57, 0x1f60, 0x1f67, 0x1fb0, 0x1f70, 0x03b9, 0x1f72, 0x1f75, 0x1fd0, 0x1f76, 0x1fe0, 0x1f7a, 0x1fe5, 0x1f78, 0x1f7c, 0x03c9, 0x006b, 0x00e5, 0x214e, 0x2170, 0x217f, 0x2184, 0x24d0, 0x24e9, 0x2c30, 0x2c5e, 0x2c61, 0x026b, 0x1d7d, 0x027d, 0x2c68, 0x2c6c, 0x0251, 0x0271, 0x0250, 0x0252, 0x2c73, 0x2c76, 0x023f, 0x2c81, 0x2ce3, 0x2cec, 0x2cf3, 0xa641, 0xa66d, 0xa681, 0xa69b, 0xa723, 0xa72f, 0xa733, 0xa76f, 0xa77a, 0x1d79, 0xa77f, 0xa787, 0xa78c, 0x0265, 0xa791, 0xa797, 0xa7a9, 0x0266, 0x025c, 0x0261, 0x026c, 0x026a, 0x029e, 0x0287, 0x029d, 0xab53, 0xa7b5, 0xa7bf, 0xa7c3, 0xa794, 0x0282, 0x1d8e, 0x13a0, 0x13ef, 0xff41, 0xff5a, 0x10428, 0x1044f, 0x104d8, 0x104fb, 0x10cc0, 0x10cf2, 0x118c0, 0x118df, 0x16e60, 0x16e7f, 0x1e922, 0x1e943 }; static const unsigned FOLD_MAP_2[] = { S(0x00df), S(0x0130), S(0x0149), S(0x01f0), S(0x0587), S(0x1e96), S(0x1e97), S(0x1e98), S(0x1e99), S(0x1e9a), S(0x1e9e), S(0x1f50), R(0x1f80,0x1f87), R(0x1f88,0x1f8f), R(0x1f90,0x1f97), R(0x1f98,0x1f9f), R(0x1fa0,0x1fa7), R(0x1fa8,0x1faf), S(0x1fb2), S(0x1fb3), S(0x1fb4), S(0x1fb6), S(0x1fbc), S(0x1fc2), S(0x1fc3), S(0x1fc4), S(0x1fc6), S(0x1fcc), S(0x1fd6), S(0x1fe4), S(0x1fe6), S(0x1ff2), S(0x1ff3), S(0x1ff4), S(0x1ff6), S(0x1ffc), S(0xfb00), S(0xfb01), S(0xfb02), S(0xfb05), S(0xfb06), S(0xfb13), S(0xfb14), S(0xfb15), S(0xfb16), S(0xfb17) }; static const unsigned FOLD_MAP_2_DATA[] = { 0x0073,0x0073, 0x0069,0x0307, 0x02bc,0x006e, 0x006a,0x030c, 0x0565,0x0582, 0x0068,0x0331, 0x0074,0x0308, 0x0077,0x030a, 0x0079,0x030a, 0x0061,0x02be, 0x0073,0x0073, 0x03c5,0x0313, 0x1f00,0x03b9, 0x1f07,0x03b9, 0x1f00,0x03b9, 0x1f07,0x03b9, 0x1f20,0x03b9, 0x1f27,0x03b9, 0x1f20,0x03b9, 0x1f27,0x03b9, 0x1f60,0x03b9, 0x1f67,0x03b9, 0x1f60,0x03b9, 0x1f67,0x03b9, 0x1f70,0x03b9, 0x03b1,0x03b9, 0x03ac,0x03b9, 0x03b1,0x0342, 0x03b1,0x03b9, 0x1f74,0x03b9, 0x03b7,0x03b9, 0x03ae,0x03b9, 0x03b7,0x0342, 0x03b7,0x03b9, 0x03b9,0x0342, 0x03c1,0x0313, 0x03c5,0x0342, 0x1f7c,0x03b9, 0x03c9,0x03b9, 0x03ce,0x03b9, 0x03c9,0x0342, 0x03c9,0x03b9, 0x0066,0x0066, 0x0066,0x0069, 0x0066,0x006c, 0x0073,0x0074, 0x0073,0x0074, 0x0574,0x0576, 0x0574,0x0565, 0x0574,0x056b, 0x057e,0x0576, 0x0574,0x056d }; static const unsigned FOLD_MAP_3[] = { S(0x0390), S(0x03b0), S(0x1f52), S(0x1f54), S(0x1f56), S(0x1fb7), S(0x1fc7), S(0x1fd2), S(0x1fd3), S(0x1fd7), S(0x1fe2), S(0x1fe3), S(0x1fe7), S(0x1ff7), S(0xfb03), S(0xfb04) }; static const unsigned FOLD_MAP_3_DATA[] = { 0x03b9,0x0308,0x0301, 0x03c5,0x0308,0x0301, 0x03c5,0x0313,0x0300, 0x03c5,0x0313,0x0301, 0x03c5,0x0313,0x0342, 0x03b1,0x0342,0x03b9, 0x03b7,0x0342,0x03b9, 0x03b9,0x0308,0x0300, 0x03b9,0x0308,0x0301, 0x03b9,0x0308,0x0342, 0x03c5,0x0308,0x0300, 0x03c5,0x0308,0x0301, 0x03c5,0x0308,0x0342, 0x03c9,0x0342,0x03b9, 0x0066,0x0066,0x0069, 0x0066,0x0066,0x006c }; #undef R #undef S static const struct { const unsigned* map; const unsigned* data; size_t map_size; int n_codepoints; } FOLD_MAP_LIST[] = { { FOLD_MAP_1, FOLD_MAP_1_DATA, SIZEOF_ARRAY(FOLD_MAP_1), 1 }, { FOLD_MAP_2, FOLD_MAP_2_DATA, SIZEOF_ARRAY(FOLD_MAP_2), 2 }, { FOLD_MAP_3, FOLD_MAP_3_DATA, SIZEOF_ARRAY(FOLD_MAP_3), 3 } }; int i; /* Fast path for ASCII characters. */ if(codepoint <= 0x7f) { info->codepoints[0] = codepoint; if(ISUPPER_(codepoint)) info->codepoints[0] += 'a' - 'A'; info->n_codepoints = 1; return; } /* Try to locate the codepoint in any of the maps. */ for(i = 0; i < (int) SIZEOF_ARRAY(FOLD_MAP_LIST); i++) { int index; index = md_unicode_bsearch__(codepoint, FOLD_MAP_LIST[i].map, FOLD_MAP_LIST[i].map_size); if(index >= 0) { /* Found the mapping. */ int n_codepoints = FOLD_MAP_LIST[i].n_codepoints; const unsigned* map = FOLD_MAP_LIST[i].map; const unsigned* codepoints = FOLD_MAP_LIST[i].data + (index * n_codepoints); memcpy(info->codepoints, codepoints, sizeof(unsigned) * n_codepoints); info->n_codepoints = n_codepoints; if(FOLD_MAP_LIST[i].map[index] != codepoint) { /* The found mapping maps whole range of codepoints, * i.e. we have to offset info->codepoints[0] accordingly. */ if((map[index] & 0x00ffffff)+1 == codepoints[0]) { /* Alternating type of the range. */ info->codepoints[0] = codepoint + ((codepoint & 0x1) == (map[index] & 0x1) ? 1 : 0); } else { /* Range to range kind of mapping. */ info->codepoints[0] += (codepoint - (map[index] & 0x00ffffff)); } } return; } } /* No mapping found. Map the codepoint to itself. */ info->codepoints[0] = codepoint; info->n_codepoints = 1; } #endif #if defined MD4C_USE_UTF16 #define IS_UTF16_SURROGATE_HI(word) (((WORD)(word) & 0xfc00) == 0xd800) #define IS_UTF16_SURROGATE_LO(word) (((WORD)(word) & 0xfc00) == 0xdc00) #define UTF16_DECODE_SURROGATE(hi, lo) (0x10000 + ((((unsigned)(hi) & 0x3ff) << 10) | (((unsigned)(lo) & 0x3ff) << 0))) static unsigned md_decode_utf16le__(const CHAR* str, SZ str_size, SZ* p_size) { if(IS_UTF16_SURROGATE_HI(str[0])) { if(1 < str_size && IS_UTF16_SURROGATE_LO(str[1])) { if(p_size != NULL) *p_size = 2; return UTF16_DECODE_SURROGATE(str[0], str[1]); } } if(p_size != NULL) *p_size = 1; return str[0]; } static unsigned md_decode_utf16le_before__(MD_CTX* ctx, OFF off) { if(off > 2 && IS_UTF16_SURROGATE_HI(CH(off-2)) && IS_UTF16_SURROGATE_LO(CH(off-1))) return UTF16_DECODE_SURROGATE(CH(off-2), CH(off-1)); return CH(off); } /* No whitespace uses surrogates, so no decoding needed here. */ #define ISUNICODEWHITESPACE_(codepoint) md_is_unicode_whitespace__(codepoint) #define ISUNICODEWHITESPACE(off) md_is_unicode_whitespace__(CH(off)) #define ISUNICODEWHITESPACEBEFORE(off) md_is_unicode_whitespace__(CH((off)-1)) #define ISUNICODEPUNCT(off) md_is_unicode_punct__(md_decode_utf16le__(STR(off), ctx->size - (off), NULL)) #define ISUNICODEPUNCTBEFORE(off) md_is_unicode_punct__(md_decode_utf16le_before__(ctx, off)) static inline int md_decode_unicode(const CHAR* str, OFF off, SZ str_size, SZ* p_char_size) { return md_decode_utf16le__(str+off, str_size-off, p_char_size); } #elif defined MD4C_USE_UTF8 #define IS_UTF8_LEAD1(byte) ((unsigned char)(byte) <= 0x7f) #define IS_UTF8_LEAD2(byte) (((unsigned char)(byte) & 0xe0) == 0xc0) #define IS_UTF8_LEAD3(byte) (((unsigned char)(byte) & 0xf0) == 0xe0) #define IS_UTF8_LEAD4(byte) (((unsigned char)(byte) & 0xf8) == 0xf0) #define IS_UTF8_TAIL(byte) (((unsigned char)(byte) & 0xc0) == 0x80) static unsigned md_decode_utf8__(const CHAR* str, SZ str_size, SZ* p_size) { if(!IS_UTF8_LEAD1(str[0])) { if(IS_UTF8_LEAD2(str[0])) { if(1 < str_size && IS_UTF8_TAIL(str[1])) { if(p_size != NULL) *p_size = 2; return (((unsigned int)str[0] & 0x1f) << 6) | (((unsigned int)str[1] & 0x3f) << 0); } } else if(IS_UTF8_LEAD3(str[0])) { if(2 < str_size && IS_UTF8_TAIL(str[1]) && IS_UTF8_TAIL(str[2])) { if(p_size != NULL) *p_size = 3; return (((unsigned int)str[0] & 0x0f) << 12) | (((unsigned int)str[1] & 0x3f) << 6) | (((unsigned int)str[2] & 0x3f) << 0); } } else if(IS_UTF8_LEAD4(str[0])) { if(3 < str_size && IS_UTF8_TAIL(str[1]) && IS_UTF8_TAIL(str[2]) && IS_UTF8_TAIL(str[3])) { if(p_size != NULL) *p_size = 4; return (((unsigned int)str[0] & 0x07) << 18) | (((unsigned int)str[1] & 0x3f) << 12) | (((unsigned int)str[2] & 0x3f) << 6) | (((unsigned int)str[3] & 0x3f) << 0); } } } if(p_size != NULL) *p_size = 1; return (unsigned) str[0]; } static unsigned md_decode_utf8_before__(MD_CTX* ctx, OFF off) { if(!IS_UTF8_LEAD1(CH(off-1))) { if(off > 1 && IS_UTF8_LEAD2(CH(off-2)) && IS_UTF8_TAIL(CH(off-1))) return (((unsigned int)CH(off-2) & 0x1f) << 6) | (((unsigned int)CH(off-1) & 0x3f) << 0); if(off > 2 && IS_UTF8_LEAD3(CH(off-3)) && IS_UTF8_TAIL(CH(off-2)) && IS_UTF8_TAIL(CH(off-1))) return (((unsigned int)CH(off-3) & 0x0f) << 12) | (((unsigned int)CH(off-2) & 0x3f) << 6) | (((unsigned int)CH(off-1) & 0x3f) << 0); if(off > 3 && IS_UTF8_LEAD4(CH(off-4)) && IS_UTF8_TAIL(CH(off-3)) && IS_UTF8_TAIL(CH(off-2)) && IS_UTF8_TAIL(CH(off-1))) return (((unsigned int)CH(off-4) & 0x07) << 18) | (((unsigned int)CH(off-3) & 0x3f) << 12) | (((unsigned int)CH(off-2) & 0x3f) << 6) | (((unsigned int)CH(off-1) & 0x3f) << 0); } return (unsigned) CH(off-1); } #define ISUNICODEWHITESPACE_(codepoint) md_is_unicode_whitespace__(codepoint) #define ISUNICODEWHITESPACE(off) md_is_unicode_whitespace__(md_decode_utf8__(STR(off), ctx->size - (off), NULL)) #define ISUNICODEWHITESPACEBEFORE(off) md_is_unicode_whitespace__(md_decode_utf8_before__(ctx, off)) #define ISUNICODEPUNCT(off) md_is_unicode_punct__(md_decode_utf8__(STR(off), ctx->size - (off), NULL)) #define ISUNICODEPUNCTBEFORE(off) md_is_unicode_punct__(md_decode_utf8_before__(ctx, off)) static inline unsigned md_decode_unicode(const CHAR* str, OFF off, SZ str_size, SZ* p_char_size) { return md_decode_utf8__(str+off, str_size-off, p_char_size); } #else #define ISUNICODEWHITESPACE_(codepoint) ISWHITESPACE_(codepoint) #define ISUNICODEWHITESPACE(off) ISWHITESPACE(off) #define ISUNICODEWHITESPACEBEFORE(off) ISWHITESPACE((off)-1) #define ISUNICODEPUNCT(off) ISPUNCT(off) #define ISUNICODEPUNCTBEFORE(off) ISPUNCT((off)-1) static inline void md_get_unicode_fold_info(unsigned codepoint, MD_UNICODE_FOLD_INFO* info) { info->codepoints[0] = codepoint; if(ISUPPER_(codepoint)) info->codepoints[0] += 'a' - 'A'; info->n_codepoints = 1; } static inline unsigned md_decode_unicode(const CHAR* str, OFF off, SZ str_size, SZ* p_size) { *p_size = 1; return (unsigned) str[off]; } #endif /************************************* *** Helper string manipulations *** *************************************/ /* Fill buffer with copy of the string between 'beg' and 'end' but replace any * line breaks with given replacement character. * * NOTE: Caller is responsible to make sure the buffer is large enough. * (Given the output is always shorter then input, (end - beg) is good idea * what the caller should allocate.) */ static void md_merge_lines(MD_CTX* ctx, OFF beg, OFF end, const MD_LINE* lines, int n_lines, CHAR line_break_replacement_char, CHAR* buffer, SZ* p_size) { CHAR* ptr = buffer; int line_index = 0; OFF off = beg; while(1) { const MD_LINE* line = &lines[line_index]; OFF line_end = line->end; if(end < line_end) line_end = end; while(off < line_end) { *ptr = CH(off); ptr++; off++; } if(off >= end) { *p_size = ptr - buffer; return; } *ptr = line_break_replacement_char; ptr++; line_index++; off = lines[line_index].beg; } } /* Wrapper of md_merge_lines() which allocates new buffer for the output string. */ static int md_merge_lines_alloc(MD_CTX* ctx, OFF beg, OFF end, const MD_LINE* lines, int n_lines, CHAR line_break_replacement_char, CHAR** p_str, SZ* p_size) { CHAR* buffer; buffer = (CHAR*) malloc(sizeof(CHAR) * (end - beg)); if(buffer == NULL) { MD_LOG("malloc() failed."); return -1; } md_merge_lines(ctx, beg, end, lines, n_lines, line_break_replacement_char, buffer, p_size); *p_str = buffer; return 0; } static OFF md_skip_unicode_whitespace(const CHAR* label, OFF off, SZ size) { SZ char_size; unsigned codepoint; while(off < size) { codepoint = md_decode_unicode(label, off, size, &char_size); if(!ISUNICODEWHITESPACE_(codepoint) && !ISNEWLINE_(label[off])) break; off += char_size; } return off; } /****************************** *** Recognizing raw HTML *** ******************************/ /* md_is_html_tag() may be called when processing inlines (inline raw HTML) * or when breaking document to blocks (checking for start of HTML block type 7). * * When breaking document to blocks, we do not yet know line boundaries, but * in that case the whole tag has to live on a single line. We distinguish this * by n_lines == 0. */ static int md_is_html_tag(MD_CTX* ctx, const MD_LINE* lines, int n_lines, OFF beg, OFF max_end, OFF* p_end) { int attr_state; OFF off = beg; OFF line_end = (n_lines > 0) ? lines[0].end : ctx->size; int i = 0; MD_ASSERT(CH(beg) == _T('<')); if(off + 1 >= line_end) return FALSE; off++; /* For parsing attributes, we need a little state automaton below. * State -1: no attributes are allowed. * State 0: attribute could follow after some whitespace. * State 1: after a whitespace (attribute name may follow). * State 2: after attribute name ('=' MAY follow). * State 3: after '=' (value specification MUST follow). * State 41: in middle of unquoted attribute value. * State 42: in middle of single-quoted attribute value. * State 43: in middle of double-quoted attribute value. */ attr_state = 0; if(CH(off) == _T('/')) { /* Closer tag "". No attributes may be present. */ attr_state = -1; off++; } /* Tag name */ if(off >= line_end || !ISALPHA(off)) return FALSE; off++; while(off < line_end && (ISALNUM(off) || CH(off) == _T('-'))) off++; /* (Optional) attributes (if not closer), (optional) '/' (if not closer) * and final '>'. */ while(1) { while(off < line_end && !ISNEWLINE(off)) { if(attr_state > 40) { if(attr_state == 41 && (ISBLANK(off) || ISANYOF(off, _T("\"'=<>`")))) { attr_state = 0; off--; /* Put the char back for re-inspection in the new state. */ } else if(attr_state == 42 && CH(off) == _T('\'')) { attr_state = 0; } else if(attr_state == 43 && CH(off) == _T('"')) { attr_state = 0; } off++; } else if(ISWHITESPACE(off)) { if(attr_state == 0) attr_state = 1; off++; } else if(attr_state <= 2 && CH(off) == _T('>')) { /* End. */ goto done; } else if(attr_state <= 2 && CH(off) == _T('/') && off+1 < line_end && CH(off+1) == _T('>')) { /* End with digraph '/>' */ off++; goto done; } else if((attr_state == 1 || attr_state == 2) && (ISALPHA(off) || CH(off) == _T('_') || CH(off) == _T(':'))) { off++; /* Attribute name */ while(off < line_end && (ISALNUM(off) || ISANYOF(off, _T("_.:-")))) off++; attr_state = 2; } else if(attr_state == 2 && CH(off) == _T('=')) { /* Attribute assignment sign */ off++; attr_state = 3; } else if(attr_state == 3) { /* Expecting start of attribute value. */ if(CH(off) == _T('"')) attr_state = 43; else if(CH(off) == _T('\'')) attr_state = 42; else if(!ISANYOF(off, _T("\"'=<>`")) && !ISNEWLINE(off)) attr_state = 41; else return FALSE; off++; } else { /* Anything unexpected. */ return FALSE; } } /* We have to be on a single line. See definition of start condition * of HTML block, type 7. */ if(n_lines == 0) return FALSE; i++; if(i >= n_lines) return FALSE; off = lines[i].beg; line_end = lines[i].end; if(attr_state == 0 || attr_state == 41) attr_state = 1; if(off >= max_end) return FALSE; } done: if(off >= max_end) return FALSE; *p_end = off+1; return TRUE; } static int md_scan_for_html_closer(MD_CTX* ctx, const MD_CHAR* str, MD_SIZE len, const MD_LINE* lines, int n_lines, OFF beg, OFF max_end, OFF* p_end, OFF* p_scan_horizon) { OFF off = beg; int i = 0; if(off < *p_scan_horizon && *p_scan_horizon >= max_end - len) { /* We have already scanned the range up to the max_end so we know * there is nothing to see. */ return FALSE; } while(TRUE) { while(off + len <= lines[i].end && off + len <= max_end) { if(md_ascii_eq(STR(off), str, len)) { /* Success. */ *p_end = off + len; return TRUE; } off++; } i++; if(off >= max_end || i >= n_lines) { /* Failure. */ *p_scan_horizon = off; return FALSE; } off = lines[i].beg; } } static int md_is_html_comment(MD_CTX* ctx, const MD_LINE* lines, int n_lines, OFF beg, OFF max_end, OFF* p_end) { OFF off = beg; MD_ASSERT(CH(beg) == _T('<')); if(off + 4 >= lines[0].end) return FALSE; if(CH(off+1) != _T('!') || CH(off+2) != _T('-') || CH(off+3) != _T('-')) return FALSE; off += 4; /* ">" and "->" must not follow the opening. */ if(off < lines[0].end && CH(off) == _T('>')) return FALSE; if(off+1 < lines[0].end && CH(off) == _T('-') && CH(off+1) == _T('>')) return FALSE; /* HTML comment must not contain "--", so we scan just for "--" instead * of "-->" and verify manually that '>' follows. */ if(md_scan_for_html_closer(ctx, _T("--"), 2, lines, n_lines, off, max_end, p_end, &ctx->html_comment_horizon)) { if(*p_end < max_end && CH(*p_end) == _T('>')) { *p_end = *p_end + 1; return TRUE; } } return FALSE; } static int md_is_html_processing_instruction(MD_CTX* ctx, const MD_LINE* lines, int n_lines, OFF beg, OFF max_end, OFF* p_end) { OFF off = beg; if(off + 2 >= lines[0].end) return FALSE; if(CH(off+1) != _T('?')) return FALSE; off += 2; return md_scan_for_html_closer(ctx, _T("?>"), 2, lines, n_lines, off, max_end, p_end, &ctx->html_proc_instr_horizon); } static int md_is_html_declaration(MD_CTX* ctx, const MD_LINE* lines, int n_lines, OFF beg, OFF max_end, OFF* p_end) { OFF off = beg; if(off + 2 >= lines[0].end) return FALSE; if(CH(off+1) != _T('!')) return FALSE; off += 2; /* Declaration name. */ if(off >= lines[0].end || !ISALPHA(off)) return FALSE; off++; while(off < lines[0].end && ISALPHA(off)) off++; if(off < lines[0].end && !ISWHITESPACE(off)) return FALSE; return md_scan_for_html_closer(ctx, _T(">"), 1, lines, n_lines, off, max_end, p_end, &ctx->html_decl_horizon); } static int md_is_html_cdata(MD_CTX* ctx, const MD_LINE* lines, int n_lines, OFF beg, OFF max_end, OFF* p_end) { static const CHAR open_str[] = _T("= lines[0].end) return FALSE; if(memcmp(STR(off), open_str, open_size) != 0) return FALSE; off += open_size; if(lines[n_lines-1].end < max_end) max_end = lines[n_lines-1].end - 2; return md_scan_for_html_closer(ctx, _T("]]>"), 3, lines, n_lines, off, max_end, p_end, &ctx->html_cdata_horizon); } static int md_is_html_any(MD_CTX* ctx, const MD_LINE* lines, int n_lines, OFF beg, OFF max_end, OFF* p_end) { MD_ASSERT(CH(beg) == _T('<')); return (md_is_html_tag(ctx, lines, n_lines, beg, max_end, p_end) || md_is_html_comment(ctx, lines, n_lines, beg, max_end, p_end) || md_is_html_processing_instruction(ctx, lines, n_lines, beg, max_end, p_end) || md_is_html_declaration(ctx, lines, n_lines, beg, max_end, p_end) || md_is_html_cdata(ctx, lines, n_lines, beg, max_end, p_end)); } /**************************** *** Recognizing Entity *** ****************************/ static int md_is_hex_entity_contents(MD_CTX* ctx, const CHAR* text, OFF beg, OFF max_end, OFF* p_end) { OFF off = beg; while(off < max_end && ISXDIGIT_(text[off]) && off - beg <= 8) off++; if(1 <= off - beg && off - beg <= 6) { *p_end = off; return TRUE; } else { return FALSE; } } static int md_is_dec_entity_contents(MD_CTX* ctx, const CHAR* text, OFF beg, OFF max_end, OFF* p_end) { OFF off = beg; while(off < max_end && ISDIGIT_(text[off]) && off - beg <= 8) off++; if(1 <= off - beg && off - beg <= 7) { *p_end = off; return TRUE; } else { return FALSE; } } static int md_is_named_entity_contents(MD_CTX* ctx, const CHAR* text, OFF beg, OFF max_end, OFF* p_end) { OFF off = beg; if(off < max_end && ISALPHA_(text[off])) off++; else return FALSE; while(off < max_end && ISALNUM_(text[off]) && off - beg <= 48) off++; if(2 <= off - beg && off - beg <= 48) { *p_end = off; return TRUE; } else { return FALSE; } } static int md_is_entity_str(MD_CTX* ctx, const CHAR* text, OFF beg, OFF max_end, OFF* p_end) { int is_contents; OFF off = beg; MD_ASSERT(text[off] == _T('&')); off++; if(off+2 < max_end && text[off] == _T('#') && (text[off+1] == _T('x') || text[off+1] == _T('X'))) is_contents = md_is_hex_entity_contents(ctx, text, off+2, max_end, &off); else if(off+1 < max_end && text[off] == _T('#')) is_contents = md_is_dec_entity_contents(ctx, text, off+1, max_end, &off); else is_contents = md_is_named_entity_contents(ctx, text, off, max_end, &off); if(is_contents && off < max_end && text[off] == _T(';')) { *p_end = off+1; return TRUE; } else { return FALSE; } } static inline int md_is_entity(MD_CTX* ctx, OFF beg, OFF max_end, OFF* p_end) { return md_is_entity_str(ctx, ctx->text, beg, max_end, p_end); } /****************************** *** Attribute Management *** ******************************/ typedef struct MD_ATTRIBUTE_BUILD_tag MD_ATTRIBUTE_BUILD; struct MD_ATTRIBUTE_BUILD_tag { CHAR* text; MD_TEXTTYPE* substr_types; OFF* substr_offsets; int substr_count; int substr_alloc; MD_TEXTTYPE trivial_types[1]; OFF trivial_offsets[2]; }; #define MD_BUILD_ATTR_NO_ESCAPES 0x0001 static int md_build_attr_append_substr(MD_CTX* ctx, MD_ATTRIBUTE_BUILD* build, MD_TEXTTYPE type, OFF off) { if(build->substr_count >= build->substr_alloc) { MD_TEXTTYPE* new_substr_types; OFF* new_substr_offsets; build->substr_alloc = (build->substr_alloc == 0 ? 8 : build->substr_alloc * 2); new_substr_types = (MD_TEXTTYPE*) realloc(build->substr_types, build->substr_alloc * sizeof(MD_TEXTTYPE)); if(new_substr_types == NULL) { MD_LOG("realloc() failed."); return -1; } /* Note +1 to reserve space for final offset (== raw_size). */ new_substr_offsets = (OFF*) realloc(build->substr_offsets, (build->substr_alloc+1) * sizeof(OFF)); if(new_substr_offsets == NULL) { MD_LOG("realloc() failed."); free(new_substr_types); return -1; } build->substr_types = new_substr_types; build->substr_offsets = new_substr_offsets; } build->substr_types[build->substr_count] = type; build->substr_offsets[build->substr_count] = off; build->substr_count++; return 0; } static void md_free_attribute(MD_CTX* ctx, MD_ATTRIBUTE_BUILD* build) { if(build->substr_alloc > 0) { free(build->text); free(build->substr_types); free(build->substr_offsets); } } static int md_build_attribute(MD_CTX* ctx, const CHAR* raw_text, SZ raw_size, unsigned flags, MD_ATTRIBUTE* attr, MD_ATTRIBUTE_BUILD* build) { OFF raw_off, off; int is_trivial; int ret = 0; memset(build, 0, sizeof(MD_ATTRIBUTE_BUILD)); /* If there is no backslash and no ampersand, build trivial attribute * without any malloc(). */ is_trivial = TRUE; for(raw_off = 0; raw_off < raw_size; raw_off++) { if(ISANYOF3_(raw_text[raw_off], _T('\\'), _T('&'), _T('\0'))) { is_trivial = FALSE; break; } } if(is_trivial) { build->text = (CHAR*) (raw_size ? raw_text : NULL); build->substr_types = build->trivial_types; build->substr_offsets = build->trivial_offsets; build->substr_count = 1; build->substr_alloc = 0; build->trivial_types[0] = MD_TEXT_NORMAL; build->trivial_offsets[0] = 0; build->trivial_offsets[1] = raw_size; off = raw_size; } else { build->text = (CHAR*) malloc(raw_size * sizeof(CHAR)); if(build->text == NULL) { MD_LOG("malloc() failed."); goto abort; } raw_off = 0; off = 0; while(raw_off < raw_size) { if(raw_text[raw_off] == _T('\0')) { MD_CHECK(md_build_attr_append_substr(ctx, build, MD_TEXT_NULLCHAR, off)); memcpy(build->text + off, raw_text + raw_off, 1); off++; raw_off++; continue; } if(raw_text[raw_off] == _T('&')) { OFF ent_end; if(md_is_entity_str(ctx, raw_text, raw_off, raw_size, &ent_end)) { MD_CHECK(md_build_attr_append_substr(ctx, build, MD_TEXT_ENTITY, off)); memcpy(build->text + off, raw_text + raw_off, ent_end - raw_off); off += ent_end - raw_off; raw_off = ent_end; continue; } } if(build->substr_count == 0 || build->substr_types[build->substr_count-1] != MD_TEXT_NORMAL) MD_CHECK(md_build_attr_append_substr(ctx, build, MD_TEXT_NORMAL, off)); if(!(flags & MD_BUILD_ATTR_NO_ESCAPES) && raw_text[raw_off] == _T('\\') && raw_off+1 < raw_size && (ISPUNCT_(raw_text[raw_off+1]) || ISNEWLINE_(raw_text[raw_off+1]))) raw_off++; build->text[off++] = raw_text[raw_off++]; } build->substr_offsets[build->substr_count] = off; } attr->text = build->text; attr->size = off; attr->substr_offsets = build->substr_offsets; attr->substr_types = build->substr_types; return 0; abort: md_free_attribute(ctx, build); return -1; } /********************************************* *** Dictionary of Reference Definitions *** *********************************************/ #define MD_FNV1A_BASE 2166136261 #define MD_FNV1A_PRIME 16777619 static inline unsigned md_fnv1a(unsigned base, const void* data, size_t n) { const unsigned char* buf = (const unsigned char*) data; unsigned hash = base; size_t i; for(i = 0; i < n; i++) { hash ^= buf[i]; hash *= MD_FNV1A_PRIME; } return hash; } struct MD_REF_DEF_tag { CHAR* label; CHAR* title; unsigned hash; SZ label_size : 24; unsigned label_needs_free : 1; unsigned title_needs_free : 1; SZ title_size; OFF dest_beg; OFF dest_end; }; /* Label equivalence is quite complicated with regards to whitespace and case * folding. This complicates computing a hash of it as well as direct comparison * of two labels. */ static unsigned md_link_label_hash(const CHAR* label, SZ size) { unsigned hash = MD_FNV1A_BASE; OFF off; unsigned codepoint; int is_whitespace = FALSE; off = md_skip_unicode_whitespace(label, 0, size); while(off < size) { SZ char_size; codepoint = md_decode_unicode(label, off, size, &char_size); is_whitespace = ISUNICODEWHITESPACE_(codepoint) || ISNEWLINE_(label[off]); if(is_whitespace) { codepoint = ' '; hash = md_fnv1a(hash, &codepoint, sizeof(unsigned)); off = md_skip_unicode_whitespace(label, off, size); } else { MD_UNICODE_FOLD_INFO fold_info; md_get_unicode_fold_info(codepoint, &fold_info); hash = md_fnv1a(hash, fold_info.codepoints, fold_info.n_codepoints * sizeof(unsigned)); off += char_size; } } return hash; } static OFF md_link_label_cmp_load_fold_info(const CHAR* label, OFF off, SZ size, MD_UNICODE_FOLD_INFO* fold_info) { unsigned codepoint; SZ char_size; if(off >= size) { /* Treat end of link label as a whitespace. */ goto whitespace; } if(ISNEWLINE_(label[off])) { /* Treat new lines as a whitespace. */ off++; goto whitespace; } codepoint = md_decode_unicode(label, off, size, &char_size); off += char_size; if(ISUNICODEWHITESPACE_(codepoint)) { /* Treat all whitespace as equivalent */ goto whitespace; } /* Get real folding info. */ md_get_unicode_fold_info(codepoint, fold_info); return off; whitespace: fold_info->codepoints[0] = _T(' '); fold_info->n_codepoints = 1; return off; } static int md_link_label_cmp(const CHAR* a_label, SZ a_size, const CHAR* b_label, SZ b_size) { OFF a_off; OFF b_off; int a_reached_end = FALSE; int b_reached_end = FALSE; MD_UNICODE_FOLD_INFO a_fi = { 0 }; MD_UNICODE_FOLD_INFO b_fi = { 0 }; OFF a_fi_off = 0; OFF b_fi_off = 0; int cmp; a_off = md_skip_unicode_whitespace(a_label, 0, a_size); b_off = md_skip_unicode_whitespace(b_label, 0, b_size); while(!a_reached_end && !b_reached_end) { /* If needed, load fold info for next char. */ if(a_fi_off >= a_fi.n_codepoints) { a_fi_off = 0; a_off = md_link_label_cmp_load_fold_info(a_label, a_off, a_size, &a_fi); a_reached_end = (a_off >= a_size); } if(b_fi_off >= b_fi.n_codepoints) { b_fi_off = 0; b_off = md_link_label_cmp_load_fold_info(b_label, b_off, b_size, &b_fi); b_reached_end = (b_off >= b_size); } cmp = b_fi.codepoints[b_fi_off] - a_fi.codepoints[a_fi_off]; if(cmp != 0) return cmp; a_fi_off++; b_fi_off++; } return 0; } typedef struct MD_REF_DEF_LIST_tag MD_REF_DEF_LIST; struct MD_REF_DEF_LIST_tag { int n_ref_defs; int alloc_ref_defs; MD_REF_DEF* ref_defs[]; /* Valid items always point into ctx->ref_defs[] */ }; static int md_ref_def_cmp(const void* a, const void* b) { const MD_REF_DEF* a_ref = *(const MD_REF_DEF**)a; const MD_REF_DEF* b_ref = *(const MD_REF_DEF**)b; if(a_ref->hash < b_ref->hash) return -1; else if(a_ref->hash > b_ref->hash) return +1; else return md_link_label_cmp(a_ref->label, a_ref->label_size, b_ref->label, b_ref->label_size); } static int md_ref_def_cmp_stable(const void* a, const void* b) { int cmp; cmp = md_ref_def_cmp(a, b); /* Ensure stability of the sorting. */ if(cmp == 0) { const MD_REF_DEF* a_ref = *(const MD_REF_DEF**)a; const MD_REF_DEF* b_ref = *(const MD_REF_DEF**)b; if(a_ref < b_ref) cmp = -1; else if(a_ref > b_ref) cmp = +1; else cmp = 0; } return cmp; } static int md_build_ref_def_hashtable(MD_CTX* ctx) { int i, j; if(ctx->n_ref_defs == 0) return 0; ctx->ref_def_hashtable_size = (ctx->n_ref_defs * 5) / 4; ctx->ref_def_hashtable = malloc(ctx->ref_def_hashtable_size * sizeof(void*)); if(ctx->ref_def_hashtable == NULL) { MD_LOG("malloc() failed."); goto abort; } memset(ctx->ref_def_hashtable, 0, ctx->ref_def_hashtable_size * sizeof(void*)); /* Each member of ctx->ref_def_hashtable[] can be: * -- NULL, * -- pointer to the MD_REF_DEF in ctx->ref_defs[], or * -- pointer to a MD_REF_DEF_LIST, which holds multiple pointers to * such MD_REF_DEFs. */ for(i = 0; i < ctx->n_ref_defs; i++) { MD_REF_DEF* def = &ctx->ref_defs[i]; void* bucket; MD_REF_DEF_LIST* list; def->hash = md_link_label_hash(def->label, def->label_size); bucket = ctx->ref_def_hashtable[def->hash % ctx->ref_def_hashtable_size]; if(bucket == NULL) { ctx->ref_def_hashtable[def->hash % ctx->ref_def_hashtable_size] = def; continue; } if(ctx->ref_defs <= (MD_REF_DEF*) bucket && (MD_REF_DEF*) bucket < ctx->ref_defs + ctx->n_ref_defs) { /* The bucket already contains one ref. def. Lets see whether it * is the same label (ref. def. duplicate) or different one * (hash conflict). */ MD_REF_DEF* old_def = (MD_REF_DEF*) bucket; if(md_link_label_cmp(def->label, def->label_size, old_def->label, old_def->label_size) == 0) { /* Ignore this ref. def. */ continue; } /* Make the bucket capable of holding more ref. defs. */ list = (MD_REF_DEF_LIST*) malloc(sizeof(MD_REF_DEF_LIST) + 4 * sizeof(MD_REF_DEF*)); if(list == NULL) { MD_LOG("malloc() failed."); goto abort; } list->ref_defs[0] = old_def; list->ref_defs[1] = def; list->n_ref_defs = 2; list->alloc_ref_defs = 4; ctx->ref_def_hashtable[def->hash % ctx->ref_def_hashtable_size] = list; continue; } /* Append the def to the bucket list. */ list = (MD_REF_DEF_LIST*) bucket; if(list->n_ref_defs >= list->alloc_ref_defs) { MD_REF_DEF_LIST* list_tmp = (MD_REF_DEF_LIST*) realloc(list, sizeof(MD_REF_DEF_LIST) + 2 * list->alloc_ref_defs * sizeof(MD_REF_DEF*)); if(list_tmp == NULL) { MD_LOG("realloc() failed."); goto abort; } list = list_tmp; list->alloc_ref_defs *= 2; ctx->ref_def_hashtable[def->hash % ctx->ref_def_hashtable_size] = list; } list->ref_defs[list->n_ref_defs] = def; list->n_ref_defs++; } /* Sort the complex buckets so we can use bsearch() with them. */ for(i = 0; i < ctx->ref_def_hashtable_size; i++) { void* bucket = ctx->ref_def_hashtable[i]; MD_REF_DEF_LIST* list; if(bucket == NULL) continue; if(ctx->ref_defs <= (MD_REF_DEF*) bucket && (MD_REF_DEF*) bucket < ctx->ref_defs + ctx->n_ref_defs) continue; list = (MD_REF_DEF_LIST*) bucket; qsort(list->ref_defs, list->n_ref_defs, sizeof(MD_REF_DEF*), md_ref_def_cmp_stable); /* Disable duplicates. */ for(j = 1; j < list->n_ref_defs; j++) { if(md_ref_def_cmp(&list->ref_defs[j-1], &list->ref_defs[j]) == 0) list->ref_defs[j] = list->ref_defs[j-1]; } } return 0; abort: return -1; } static void md_free_ref_def_hashtable(MD_CTX* ctx) { if(ctx->ref_def_hashtable != NULL) { int i; for(i = 0; i < ctx->ref_def_hashtable_size; i++) { void* bucket = ctx->ref_def_hashtable[i]; if(bucket == NULL) continue; if(ctx->ref_defs <= (MD_REF_DEF*) bucket && (MD_REF_DEF*) bucket < ctx->ref_defs + ctx->n_ref_defs) continue; free(bucket); } free(ctx->ref_def_hashtable); } } static const MD_REF_DEF* md_lookup_ref_def(MD_CTX* ctx, const CHAR* label, SZ label_size) { unsigned hash; void* bucket; if(ctx->ref_def_hashtable_size == 0) return NULL; hash = md_link_label_hash(label, label_size); bucket = ctx->ref_def_hashtable[hash % ctx->ref_def_hashtable_size]; if(bucket == NULL) { return NULL; } else if(ctx->ref_defs <= (MD_REF_DEF*) bucket && (MD_REF_DEF*) bucket < ctx->ref_defs + ctx->n_ref_defs) { const MD_REF_DEF* def = (MD_REF_DEF*) bucket; if(md_link_label_cmp(def->label, def->label_size, label, label_size) == 0) return def; else return NULL; } else { MD_REF_DEF_LIST* list = (MD_REF_DEF_LIST*) bucket; MD_REF_DEF key_buf; const MD_REF_DEF* key = &key_buf; const MD_REF_DEF** ret; key_buf.label = (CHAR*) label; key_buf.label_size = label_size; key_buf.hash = md_link_label_hash(key_buf.label, key_buf.label_size); ret = (const MD_REF_DEF**) bsearch(&key, list->ref_defs, list->n_ref_defs, sizeof(MD_REF_DEF*), md_ref_def_cmp); if(ret != NULL) return *ret; else return NULL; } } /*************************** *** Recognizing Links *** ***************************/ /* Note this code is partially shared between processing inlines and blocks * as reference definitions and links share some helper parser functions. */ typedef struct MD_LINK_ATTR_tag MD_LINK_ATTR; struct MD_LINK_ATTR_tag { OFF dest_beg; OFF dest_end; CHAR* title; SZ title_size; int title_needs_free; }; static int md_is_link_label(MD_CTX* ctx, const MD_LINE* lines, int n_lines, OFF beg, OFF* p_end, int* p_beg_line_index, int* p_end_line_index, OFF* p_contents_beg, OFF* p_contents_end) { OFF off = beg; OFF contents_beg = 0; OFF contents_end = 0; int line_index = 0; int len = 0; if(CH(off) != _T('[')) return FALSE; off++; while(1) { OFF line_end = lines[line_index].end; while(off < line_end) { if(CH(off) == _T('\\') && off+1 < ctx->size && (ISPUNCT(off+1) || ISNEWLINE(off+1))) { if(contents_end == 0) { contents_beg = off; *p_beg_line_index = line_index; } contents_end = off + 2; off += 2; } else if(CH(off) == _T('[')) { return FALSE; } else if(CH(off) == _T(']')) { if(contents_beg < contents_end) { /* Success. */ *p_contents_beg = contents_beg; *p_contents_end = contents_end; *p_end = off+1; *p_end_line_index = line_index; return TRUE; } else { /* Link label must have some non-whitespace contents. */ return FALSE; } } else { unsigned codepoint; SZ char_size; codepoint = md_decode_unicode(ctx->text, off, ctx->size, &char_size); if(!ISUNICODEWHITESPACE_(codepoint)) { if(contents_end == 0) { contents_beg = off; *p_beg_line_index = line_index; } contents_end = off + char_size; } off += char_size; } len++; if(len > 999) return FALSE; } line_index++; len++; if(line_index < n_lines) off = lines[line_index].beg; else break; } return FALSE; } static int md_is_link_destination_A(MD_CTX* ctx, OFF beg, OFF max_end, OFF* p_end, OFF* p_contents_beg, OFF* p_contents_end) { OFF off = beg; if(off >= max_end || CH(off) != _T('<')) return FALSE; off++; while(off < max_end) { if(CH(off) == _T('\\') && off+1 < max_end && ISPUNCT(off+1)) { off += 2; continue; } if(ISNEWLINE(off) || CH(off) == _T('<')) return FALSE; if(CH(off) == _T('>')) { /* Success. */ *p_contents_beg = beg+1; *p_contents_end = off; *p_end = off+1; return TRUE; } off++; } return FALSE; } static int md_is_link_destination_B(MD_CTX* ctx, OFF beg, OFF max_end, OFF* p_end, OFF* p_contents_beg, OFF* p_contents_end) { OFF off = beg; int parenthesis_level = 0; while(off < max_end) { if(CH(off) == _T('\\') && off+1 < max_end && ISPUNCT(off+1)) { off += 2; continue; } if(ISWHITESPACE(off) || ISCNTRL(off)) break; /* Link destination may include balanced pairs of unescaped '(' ')'. * Note we limit the maximal nesting level by 32 to protect us from * https://github.com/jgm/cmark/issues/214 */ if(CH(off) == _T('(')) { parenthesis_level++; if(parenthesis_level > 32) return FALSE; } else if(CH(off) == _T(')')) { if(parenthesis_level == 0) break; parenthesis_level--; } off++; } if(parenthesis_level != 0 || off == beg) return FALSE; /* Success. */ *p_contents_beg = beg; *p_contents_end = off; *p_end = off; return TRUE; } static inline int md_is_link_destination(MD_CTX* ctx, OFF beg, OFF max_end, OFF* p_end, OFF* p_contents_beg, OFF* p_contents_end) { if(CH(beg) == _T('<')) return md_is_link_destination_A(ctx, beg, max_end, p_end, p_contents_beg, p_contents_end); else return md_is_link_destination_B(ctx, beg, max_end, p_end, p_contents_beg, p_contents_end); } static int md_is_link_title(MD_CTX* ctx, const MD_LINE* lines, int n_lines, OFF beg, OFF* p_end, int* p_beg_line_index, int* p_end_line_index, OFF* p_contents_beg, OFF* p_contents_end) { OFF off = beg; CHAR closer_char; int line_index = 0; /* White space with up to one line break. */ while(off < lines[line_index].end && ISWHITESPACE(off)) off++; if(off >= lines[line_index].end) { line_index++; if(line_index >= n_lines) return FALSE; off = lines[line_index].beg; } if(off == beg) return FALSE; *p_beg_line_index = line_index; /* First char determines how to detect end of it. */ switch(CH(off)) { case _T('"'): closer_char = _T('"'); break; case _T('\''): closer_char = _T('\''); break; case _T('('): closer_char = _T(')'); break; default: return FALSE; } off++; *p_contents_beg = off; while(line_index < n_lines) { OFF line_end = lines[line_index].end; while(off < line_end) { if(CH(off) == _T('\\') && off+1 < ctx->size && (ISPUNCT(off+1) || ISNEWLINE(off+1))) { off++; } else if(CH(off) == closer_char) { /* Success. */ *p_contents_end = off; *p_end = off+1; *p_end_line_index = line_index; return TRUE; } else if(closer_char == _T(')') && CH(off) == _T('(')) { /* ()-style title cannot contain (unescaped '(')) */ return FALSE; } off++; } line_index++; } return FALSE; } /* Returns 0 if it is not a reference definition. * * Returns N > 0 if it is a reference definition. N then corresponds to the * number of lines forming it). In this case the definition is stored for * resolving any links referring to it. * * Returns -1 in case of an error (out of memory). */ static int md_is_link_reference_definition(MD_CTX* ctx, const MD_LINE* lines, int n_lines) { OFF label_contents_beg; OFF label_contents_end; int label_contents_line_index = -1; int label_is_multiline; CHAR* label; SZ label_size; int label_needs_free = FALSE; OFF dest_contents_beg; OFF dest_contents_end; OFF title_contents_beg; OFF title_contents_end; int title_contents_line_index; int title_is_multiline; OFF off; int line_index = 0; int tmp_line_index; MD_REF_DEF* def; int ret; /* Link label. */ if(!md_is_link_label(ctx, lines, n_lines, lines[0].beg, &off, &label_contents_line_index, &line_index, &label_contents_beg, &label_contents_end)) return FALSE; label_is_multiline = (label_contents_line_index != line_index); /* Colon. */ if(off >= lines[line_index].end || CH(off) != _T(':')) return FALSE; off++; /* Optional white space with up to one line break. */ while(off < lines[line_index].end && ISWHITESPACE(off)) off++; if(off >= lines[line_index].end) { line_index++; if(line_index >= n_lines) return FALSE; off = lines[line_index].beg; } /* Link destination. */ if(!md_is_link_destination(ctx, off, lines[line_index].end, &off, &dest_contents_beg, &dest_contents_end)) return FALSE; /* (Optional) title. Note we interpret it as an title only if nothing * more follows on its last line. */ if(md_is_link_title(ctx, lines + line_index, n_lines - line_index, off, &off, &title_contents_line_index, &tmp_line_index, &title_contents_beg, &title_contents_end) && off >= lines[line_index + tmp_line_index].end) { title_is_multiline = (tmp_line_index != title_contents_line_index); title_contents_line_index += line_index; line_index += tmp_line_index; } else { /* Not a title. */ title_is_multiline = FALSE; title_contents_beg = off; title_contents_end = off; title_contents_line_index = 0; } /* Nothing more can follow on the last line. */ if(off < lines[line_index].end) return FALSE; /* Construct label. */ if(!label_is_multiline) { label = (CHAR*) STR(label_contents_beg); label_size = label_contents_end - label_contents_beg; label_needs_free = FALSE; } else { MD_CHECK(md_merge_lines_alloc(ctx, label_contents_beg, label_contents_end, lines + label_contents_line_index, n_lines - label_contents_line_index, _T(' '), &label, &label_size)); label_needs_free = TRUE; } /* Store the reference definition. */ if(ctx->n_ref_defs >= ctx->alloc_ref_defs) { MD_REF_DEF* new_defs; ctx->alloc_ref_defs = (ctx->alloc_ref_defs > 0 ? ctx->alloc_ref_defs * 2 : 16); new_defs = (MD_REF_DEF*) realloc(ctx->ref_defs, ctx->alloc_ref_defs * sizeof(MD_REF_DEF)); if(new_defs == NULL) { MD_LOG("realloc() failed."); ret = -1; goto abort; } ctx->ref_defs = new_defs; } def = &ctx->ref_defs[ctx->n_ref_defs]; memset(def, 0, sizeof(MD_REF_DEF)); def->label = label; def->label_size = label_size; def->label_needs_free = label_needs_free; def->dest_beg = dest_contents_beg; def->dest_end = dest_contents_end; if(title_contents_beg >= title_contents_end) { def->title = NULL; def->title_size = 0; } else if(!title_is_multiline) { def->title = (CHAR*) STR(title_contents_beg); def->title_size = title_contents_end - title_contents_beg; } else { MD_CHECK(md_merge_lines_alloc(ctx, title_contents_beg, title_contents_end, lines + title_contents_line_index, n_lines - title_contents_line_index, _T('\n'), &def->title, &def->title_size)); def->title_needs_free = TRUE; } /* Success. */ ctx->n_ref_defs++; return line_index + 1; abort: /* Failure. */ if(label_needs_free) free(label); return -1; } static int md_is_link_reference(MD_CTX* ctx, const MD_LINE* lines, int n_lines, OFF beg, OFF end, MD_LINK_ATTR* attr) { const MD_REF_DEF* def; const MD_LINE* beg_line; const MD_LINE* end_line; CHAR* label; SZ label_size; int ret; MD_ASSERT(CH(beg) == _T('[') || CH(beg) == _T('!')); MD_ASSERT(CH(end-1) == _T(']')); beg += (CH(beg) == _T('!') ? 2 : 1); end--; /* Find lines corresponding to the beg and end positions. */ MD_ASSERT(lines[0].beg <= beg); beg_line = lines; while(beg >= beg_line->end) beg_line++; MD_ASSERT(end <= lines[n_lines-1].end); end_line = beg_line; while(end >= end_line->end) end_line++; if(beg_line != end_line) { MD_CHECK(md_merge_lines_alloc(ctx, beg, end, beg_line, n_lines - (beg_line - lines), _T(' '), &label, &label_size)); } else { label = (CHAR*) STR(beg); label_size = end - beg; } def = md_lookup_ref_def(ctx, label, label_size); if(def != NULL) { attr->dest_beg = def->dest_beg; attr->dest_end = def->dest_end; attr->title = def->title; attr->title_size = def->title_size; attr->title_needs_free = FALSE; } if(beg_line != end_line) free(label); ret = (def != NULL); abort: return ret; } static int md_is_inline_link_spec(MD_CTX* ctx, const MD_LINE* lines, int n_lines, OFF beg, OFF* p_end, MD_LINK_ATTR* attr) { int line_index = 0; int tmp_line_index; OFF title_contents_beg; OFF title_contents_end; int title_contents_line_index; int title_is_multiline; OFF off = beg; int ret = FALSE; while(off >= lines[line_index].end) line_index++; MD_ASSERT(CH(off) == _T('(')); off++; /* Optional white space with up to one line break. */ while(off < lines[line_index].end && ISWHITESPACE(off)) off++; if(off >= lines[line_index].end && ISNEWLINE(off)) { line_index++; if(line_index >= n_lines) return FALSE; off = lines[line_index].beg; } /* Link destination may be omitted, but only when not also having a title. */ if(off < ctx->size && CH(off) == _T(')')) { attr->dest_beg = off; attr->dest_end = off; attr->title = NULL; attr->title_size = 0; attr->title_needs_free = FALSE; off++; *p_end = off; return TRUE; } /* Link destination. */ if(!md_is_link_destination(ctx, off, lines[line_index].end, &off, &attr->dest_beg, &attr->dest_end)) return FALSE; /* (Optional) title. */ if(md_is_link_title(ctx, lines + line_index, n_lines - line_index, off, &off, &title_contents_line_index, &tmp_line_index, &title_contents_beg, &title_contents_end)) { title_is_multiline = (tmp_line_index != title_contents_line_index); title_contents_line_index += line_index; line_index += tmp_line_index; } else { /* Not a title. */ title_is_multiline = FALSE; title_contents_beg = off; title_contents_end = off; title_contents_line_index = 0; } /* Optional whitespace followed with final ')'. */ while(off < lines[line_index].end && ISWHITESPACE(off)) off++; if(off >= lines[line_index].end && ISNEWLINE(off)) { line_index++; if(line_index >= n_lines) return FALSE; off = lines[line_index].beg; } if(CH(off) != _T(')')) goto abort; off++; if(title_contents_beg >= title_contents_end) { attr->title = NULL; attr->title_size = 0; attr->title_needs_free = FALSE; } else if(!title_is_multiline) { attr->title = (CHAR*) STR(title_contents_beg); attr->title_size = title_contents_end - title_contents_beg; attr->title_needs_free = FALSE; } else { MD_CHECK(md_merge_lines_alloc(ctx, title_contents_beg, title_contents_end, lines + title_contents_line_index, n_lines - title_contents_line_index, _T('\n'), &attr->title, &attr->title_size)); attr->title_needs_free = TRUE; } *p_end = off; ret = TRUE; abort: return ret; } static void md_free_ref_defs(MD_CTX* ctx) { int i; for(i = 0; i < ctx->n_ref_defs; i++) { MD_REF_DEF* def = &ctx->ref_defs[i]; if(def->label_needs_free) free(def->label); if(def->title_needs_free) free(def->title); } free(ctx->ref_defs); } /****************************************** *** Processing Inlines (a.k.a Spans) *** ******************************************/ /* We process inlines in few phases: * * (1) We go through the block text and collect all significant characters * which may start/end a span or some other significant position into * ctx->marks[]. Core of this is what md_collect_marks() does. * * We also do some very brief preliminary context-less analysis, whether * it might be opener or closer (e.g. of an emphasis span). * * This speeds the other steps as we do not need to re-iterate over all * characters anymore. * * (2) We analyze each potential mark types, in order by their precedence. * * In each md_analyze_XXX() function, we re-iterate list of the marks, * skipping already resolved regions (in preceding precedences) and try to * resolve them. * * (2.1) For trivial marks, which are single (e.g. HTML entity), we just mark * them as resolved. * * (2.2) For range-type marks, we analyze whether the mark could be closer * and, if yes, whether there is some preceding opener it could satisfy. * * If not we check whether it could be really an opener and if yes, we * remember it so subsequent closers may resolve it. * * (3) Finally, when all marks were analyzed, we render the block contents * by calling MD_RENDERER::text() callback, interrupting by ::enter_span() * or ::close_span() whenever we reach a resolved mark. */ /* The mark structure. * * '\\': Maybe escape sequence. * '\0': NULL char. * '*': Maybe (strong) emphasis start/end. * '_': Maybe (strong) emphasis start/end. * '~': Maybe strikethrough start/end (needs MD_FLAG_STRIKETHROUGH). * '`': Maybe code span start/end. * '&': Maybe start of entity. * ';': Maybe end of entity. * '<': Maybe start of raw HTML or autolink. * '>': Maybe end of raw HTML or autolink. * '[': Maybe start of link label or link text. * '!': Equivalent of '[' for image. * ']': Maybe end of link label or link text. * '@': Maybe permissive e-mail auto-link (needs MD_FLAG_PERMISSIVEEMAILAUTOLINKS). * ':': Maybe permissive URL auto-link (needs MD_FLAG_PERMISSIVEURLAUTOLINKS). * '.': Maybe permissive WWW auto-link (needs MD_FLAG_PERMISSIVEWWWAUTOLINKS). * 'D': Dummy mark, it reserves a space for splitting a previous mark * (e.g. emphasis) or to make more space for storing some special data * related to the preceding mark (e.g. link). * * Note that not all instances of these chars in the text imply creation of the * structure. Only those which have (or may have, after we see more context) * the special meaning. * * (Keep this struct as small as possible to fit as much of them into CPU * cache line.) */ struct MD_MARK_tag { OFF beg; OFF end; /* For unresolved openers, 'prev' and 'next' form the chain of open openers * of given type 'ch'. * * During resolving, we disconnect from the chain and point to the * corresponding counterpart so opener points to its closer and vice versa. */ int prev; int next; CHAR ch; unsigned char flags; }; /* Mark flags (these apply to ALL mark types). */ #define MD_MARK_POTENTIAL_OPENER 0x01 /* Maybe opener. */ #define MD_MARK_POTENTIAL_CLOSER 0x02 /* Maybe closer. */ #define MD_MARK_OPENER 0x04 /* Definitely opener. */ #define MD_MARK_CLOSER 0x08 /* Definitely closer. */ #define MD_MARK_RESOLVED 0x10 /* Resolved in any definite way. */ /* Mark flags specific for various mark types (so they can share bits). */ #define MD_MARK_EMPH_INTRAWORD 0x20 /* Helper for the "rule of 3". */ #define MD_MARK_EMPH_MOD3_0 0x40 #define MD_MARK_EMPH_MOD3_1 0x80 #define MD_MARK_EMPH_MOD3_2 (0x40 | 0x80) #define MD_MARK_EMPH_MOD3_MASK (0x40 | 0x80) #define MD_MARK_AUTOLINK 0x20 /* Distinguisher for '<', '>'. */ #define MD_MARK_VALIDPERMISSIVEAUTOLINK 0x20 /* For permissive autolinks. */ static MD_MARKCHAIN* md_asterisk_chain(MD_CTX* ctx, unsigned flags) { switch(flags & (MD_MARK_EMPH_INTRAWORD | MD_MARK_EMPH_MOD3_MASK)) { case MD_MARK_EMPH_INTRAWORD | MD_MARK_EMPH_MOD3_0: return &ASTERISK_OPENERS_intraword_mod3_0; case MD_MARK_EMPH_INTRAWORD | MD_MARK_EMPH_MOD3_1: return &ASTERISK_OPENERS_intraword_mod3_1; case MD_MARK_EMPH_INTRAWORD | MD_MARK_EMPH_MOD3_2: return &ASTERISK_OPENERS_intraword_mod3_2; case MD_MARK_EMPH_MOD3_0: return &ASTERISK_OPENERS_extraword_mod3_0; case MD_MARK_EMPH_MOD3_1: return &ASTERISK_OPENERS_extraword_mod3_1; case MD_MARK_EMPH_MOD3_2: return &ASTERISK_OPENERS_extraword_mod3_2; default: MD_UNREACHABLE(); } return NULL; } static MD_MARKCHAIN* md_mark_chain(MD_CTX* ctx, int mark_index) { MD_MARK* mark = &ctx->marks[mark_index]; switch(mark->ch) { case _T('*'): return md_asterisk_chain(ctx, mark->flags); case _T('_'): return &UNDERSCORE_OPENERS; case _T('~'): return &TILDE_OPENERS; case _T('['): return &BRACKET_OPENERS; case _T('|'): return &TABLECELLBOUNDARIES; default: return NULL; } } static MD_MARK* md_push_mark(MD_CTX* ctx) { if(ctx->n_marks >= ctx->alloc_marks) { MD_MARK* new_marks; ctx->alloc_marks = (ctx->alloc_marks > 0 ? ctx->alloc_marks * 2 : 64); new_marks = realloc(ctx->marks, ctx->alloc_marks * sizeof(MD_MARK)); if(new_marks == NULL) { MD_LOG("realloc() failed."); return NULL; } ctx->marks = new_marks; } return &ctx->marks[ctx->n_marks++]; } #define PUSH_MARK_() \ do { \ mark = md_push_mark(ctx); \ if(mark == NULL) { \ ret = -1; \ goto abort; \ } \ } while(0) #define PUSH_MARK(ch_, beg_, end_, flags_) \ do { \ PUSH_MARK_(); \ mark->beg = (beg_); \ mark->end = (end_); \ mark->prev = -1; \ mark->next = -1; \ mark->ch = (char)(ch_); \ mark->flags = (flags_); \ } while(0) static void md_mark_chain_append(MD_CTX* ctx, MD_MARKCHAIN* chain, int mark_index) { if(chain->tail >= 0) ctx->marks[chain->tail].next = mark_index; else chain->head = mark_index; ctx->marks[mark_index].prev = chain->tail; chain->tail = mark_index; } /* Sometimes, we need to store a pointer into the mark. It is quite rare * so we do not bother to make MD_MARK use union, and it can only happen * for dummy marks. */ static inline void md_mark_store_ptr(MD_CTX* ctx, int mark_index, void* ptr) { MD_MARK* mark = &ctx->marks[mark_index]; MD_ASSERT(mark->ch == 'D'); /* Check only members beg and end are misused for this. */ MD_ASSERT(sizeof(void*) <= 2 * sizeof(OFF)); memcpy(mark, &ptr, sizeof(void*)); } static inline void* md_mark_get_ptr(MD_CTX* ctx, int mark_index) { void* ptr; MD_MARK* mark = &ctx->marks[mark_index]; MD_ASSERT(mark->ch == 'D'); memcpy(&ptr, mark, sizeof(void*)); return ptr; } static void md_resolve_range(MD_CTX* ctx, MD_MARKCHAIN* chain, int opener_index, int closer_index) { MD_MARK* opener = &ctx->marks[opener_index]; MD_MARK* closer = &ctx->marks[closer_index]; /* Remove opener from the list of openers. */ if(chain != NULL) { if(opener->prev >= 0) ctx->marks[opener->prev].next = opener->next; else chain->head = opener->next; if(opener->next >= 0) ctx->marks[opener->next].prev = opener->prev; else chain->tail = opener->prev; } /* Interconnect opener and closer and mark both as resolved. */ opener->next = closer_index; opener->flags |= MD_MARK_OPENER | MD_MARK_RESOLVED; closer->prev = opener_index; closer->flags |= MD_MARK_CLOSER | MD_MARK_RESOLVED; } #define MD_ROLLBACK_ALL 0 #define MD_ROLLBACK_CROSSING 1 /* In the range ctx->marks[opener_index] ... [closer_index], undo some or all * resolvings accordingly to these rules: * * (1) All openers BEFORE the range corresponding to any closer inside the * range are un-resolved and they are re-added to their respective chains * of unresolved openers. This ensures we can reuse the opener for closers * AFTER the range. * * (2) If 'how' is MD_ROLLBACK_ALL, then ALL resolved marks inside the range * are discarded. * * (3) If 'how' is MD_ROLLBACK_CROSSING, only closers with openers handled * in (1) are discarded. I.e. pairs of openers and closers which are both * inside the range are retained as well as any unpaired marks. */ static void md_rollback(MD_CTX* ctx, int opener_index, int closer_index, int how) { int i; int mark_index; /* Cut all unresolved openers at the mark index. */ for(i = OPENERS_CHAIN_FIRST; i < OPENERS_CHAIN_LAST+1; i++) { MD_MARKCHAIN* chain = &ctx->mark_chains[i]; while(chain->tail >= opener_index) chain->tail = ctx->marks[chain->tail].prev; if(chain->tail >= 0) ctx->marks[chain->tail].next = -1; else chain->head = -1; } /* Go backwards so that un-resolved openers are re-added into their * respective chains, in the right order. */ mark_index = closer_index - 1; while(mark_index > opener_index) { MD_MARK* mark = &ctx->marks[mark_index]; int mark_flags = mark->flags; int discard_flag = (how == MD_ROLLBACK_ALL); if(mark->flags & MD_MARK_CLOSER) { int mark_opener_index = mark->prev; /* Undo opener BEFORE the range. */ if(mark_opener_index < opener_index) { MD_MARK* mark_opener = &ctx->marks[mark_opener_index]; MD_MARKCHAIN* chain; mark_opener->flags &= ~(MD_MARK_OPENER | MD_MARK_CLOSER | MD_MARK_RESOLVED); chain = md_mark_chain(ctx, opener_index); if(chain != NULL) { md_mark_chain_append(ctx, chain, mark_opener_index); discard_flag = 1; } } } /* And reset our flags. */ if(discard_flag) mark->flags &= ~(MD_MARK_OPENER | MD_MARK_CLOSER | MD_MARK_RESOLVED); /* Jump as far as we can over unresolved or non-interesting marks. */ switch(how) { case MD_ROLLBACK_CROSSING: if((mark_flags & MD_MARK_CLOSER) && mark->prev > opener_index) { /* If we are closer with opener INSIDE the range, there may * not be any other crosser inside the subrange. */ mark_index = mark->prev; break; } /* Pass through. */ default: mark_index--; break; } } } static void md_build_mark_char_map(MD_CTX* ctx) { memset(ctx->mark_char_map, 0, sizeof(ctx->mark_char_map)); ctx->mark_char_map['\\'] = 1; ctx->mark_char_map['*'] = 1; ctx->mark_char_map['_'] = 1; ctx->mark_char_map['`'] = 1; ctx->mark_char_map['&'] = 1; ctx->mark_char_map[';'] = 1; ctx->mark_char_map['<'] = 1; ctx->mark_char_map['>'] = 1; ctx->mark_char_map['['] = 1; ctx->mark_char_map['!'] = 1; ctx->mark_char_map[']'] = 1; ctx->mark_char_map['\0'] = 1; if(ctx->parser.flags & MD_FLAG_STRIKETHROUGH) ctx->mark_char_map['~'] = 1; if(ctx->parser.flags & MD_FLAG_LATEXMATHSPANS) ctx->mark_char_map['$'] = 1; if(ctx->parser.flags & MD_FLAG_PERMISSIVEEMAILAUTOLINKS) ctx->mark_char_map['@'] = 1; if(ctx->parser.flags & MD_FLAG_PERMISSIVEURLAUTOLINKS) ctx->mark_char_map[':'] = 1; if(ctx->parser.flags & MD_FLAG_PERMISSIVEWWWAUTOLINKS) ctx->mark_char_map['.'] = 1; if(ctx->parser.flags & MD_FLAG_TABLES) ctx->mark_char_map['|'] = 1; if(ctx->parser.flags & MD_FLAG_COLLAPSEWHITESPACE) { int i; for(i = 0; i < (int) sizeof(ctx->mark_char_map); i++) { if(ISWHITESPACE_(i)) ctx->mark_char_map[i] = 1; } } } /* We limit code span marks to lower then 32 backticks. This solves the * pathologic case of too many openers, each of different length: Their * resolving would be then O(n^2). */ #define CODESPAN_MARK_MAXLEN 32 static int md_is_code_span(MD_CTX* ctx, const MD_LINE* lines, int n_lines, OFF beg, OFF* p_opener_beg, OFF* p_opener_end, OFF* p_closer_beg, OFF* p_closer_end, OFF last_potential_closers[CODESPAN_MARK_MAXLEN], int* p_reached_paragraph_end) { OFF opener_beg = beg; OFF opener_end; OFF closer_beg; OFF closer_end; SZ mark_len; OFF line_end; int has_space_after_opener = FALSE; int has_eol_after_opener = FALSE; int has_space_before_closer = FALSE; int has_eol_before_closer = FALSE; int has_only_space = TRUE; int line_index = 0; line_end = lines[0].end; opener_end = opener_beg; while(opener_end < line_end && CH(opener_end) == _T('`')) opener_end++; has_space_after_opener = (opener_end < line_end && CH(opener_end) == _T(' ')); has_eol_after_opener = (opener_end == line_end); /* The caller needs to know end of the opening mark even if we fail. */ *p_opener_end = opener_end; mark_len = opener_end - opener_beg; if(mark_len > CODESPAN_MARK_MAXLEN) return FALSE; /* Check whether we already know there is no closer of this length. * If so, re-scan does no sense. This fixes issue #59. */ if(last_potential_closers[mark_len-1] >= lines[n_lines-1].end || (*p_reached_paragraph_end && last_potential_closers[mark_len-1] < opener_end)) return FALSE; closer_beg = opener_end; closer_end = opener_end; /* Find closer mark. */ while(TRUE) { while(closer_beg < line_end && CH(closer_beg) != _T('`')) { if(CH(closer_beg) != _T(' ')) has_only_space = FALSE; closer_beg++; } closer_end = closer_beg; while(closer_end < line_end && CH(closer_end) == _T('`')) closer_end++; if(closer_end - closer_beg == mark_len) { /* Success. */ has_space_before_closer = (closer_beg > lines[line_index].beg && CH(closer_beg-1) == _T(' ')); has_eol_before_closer = (closer_beg == lines[line_index].beg); break; } if(closer_end - closer_beg > 0) { /* We have found a back-tick which is not part of the closer. */ has_only_space = FALSE; /* But if we eventually fail, remember it as a potential closer * of its own length for future attempts. This mitigates needs for * rescans. */ if(closer_end - closer_beg < CODESPAN_MARK_MAXLEN) { if(closer_beg > last_potential_closers[closer_end - closer_beg - 1]) last_potential_closers[closer_end - closer_beg - 1] = closer_beg; } } if(closer_end >= line_end) { line_index++; if(line_index >= n_lines) { /* Reached end of the paragraph and still nothing. */ *p_reached_paragraph_end = TRUE; return FALSE; } /* Try on the next line. */ line_end = lines[line_index].end; closer_beg = lines[line_index].beg; } else { closer_beg = closer_end; } } /* If there is a space or a new line both after and before the opener * (and if the code span is not made of spaces only), consume one initial * and one trailing space as part of the marks. */ if(!has_only_space && (has_space_after_opener || has_eol_after_opener) && (has_space_before_closer || has_eol_before_closer)) { if(has_space_after_opener) opener_end++; else opener_end = lines[1].beg; if(has_space_before_closer) closer_beg--; else { closer_beg = lines[line_index-1].end; /* We need to eat the preceding "\r\n" but not any line trailing * spaces. */ while(closer_beg < ctx->size && ISBLANK(closer_beg)) closer_beg++; } } *p_opener_beg = opener_beg; *p_opener_end = opener_end; *p_closer_beg = closer_beg; *p_closer_end = closer_end; return TRUE; } static int md_is_autolink_uri(MD_CTX* ctx, OFF beg, OFF max_end, OFF* p_end) { OFF off = beg+1; MD_ASSERT(CH(beg) == _T('<')); /* Check for scheme. */ if(off >= max_end || !ISASCII(off)) return FALSE; off++; while(1) { if(off >= max_end) return FALSE; if(off - beg > 32) return FALSE; if(CH(off) == _T(':') && off - beg >= 3) break; if(!ISALNUM(off) && CH(off) != _T('+') && CH(off) != _T('-') && CH(off) != _T('.')) return FALSE; off++; } /* Check the path after the scheme. */ while(off < max_end && CH(off) != _T('>')) { if(ISWHITESPACE(off) || ISCNTRL(off) || CH(off) == _T('<')) return FALSE; off++; } if(off >= max_end) return FALSE; MD_ASSERT(CH(off) == _T('>')); *p_end = off+1; return TRUE; } static int md_is_autolink_email(MD_CTX* ctx, OFF beg, OFF max_end, OFF* p_end) { OFF off = beg + 1; int label_len; MD_ASSERT(CH(beg) == _T('<')); /* The code should correspond to this regexp: /^[a-zA-Z0-9.!#$%&'*+\/=?^_`{|}~-]+ @[a-zA-Z0-9](?:[a-zA-Z0-9-]{0,61}[a-zA-Z0-9])? (?:\.[a-zA-Z0-9](?:[a-zA-Z0-9-]{0,61}[a-zA-Z0-9])?)*$/ */ /* Username (before '@'). */ while(off < max_end && (ISALNUM(off) || ISANYOF(off, _T(".!#$%&'*+/=?^_`{|}~-")))) off++; if(off <= beg+1) return FALSE; /* '@' */ if(off >= max_end || CH(off) != _T('@')) return FALSE; off++; /* Labels delimited with '.'; each label is sequence of 1 - 62 alnum * characters or '-', but '-' is not allowed as first or last char. */ label_len = 0; while(off < max_end) { if(ISALNUM(off)) label_len++; else if(CH(off) == _T('-') && label_len > 0) label_len++; else if(CH(off) == _T('.') && label_len > 0 && CH(off-1) != _T('-')) label_len = 0; else break; if(label_len > 62) return FALSE; off++; } if(label_len <= 0 || off >= max_end || CH(off) != _T('>') || CH(off-1) == _T('-')) return FALSE; *p_end = off+1; return TRUE; } static int md_is_autolink(MD_CTX* ctx, OFF beg, OFF max_end, OFF* p_end, int* p_missing_mailto) { if(md_is_autolink_uri(ctx, beg, max_end, p_end)) { *p_missing_mailto = FALSE; return TRUE; } if(md_is_autolink_email(ctx, beg, max_end, p_end)) { *p_missing_mailto = TRUE; return TRUE; } return FALSE; } static int md_collect_marks(MD_CTX* ctx, const MD_LINE* lines, int n_lines, int table_mode) { int i; int ret = 0; MD_MARK* mark; OFF codespan_last_potential_closers[CODESPAN_MARK_MAXLEN] = { 0 }; int codespan_scanned_till_paragraph_end = FALSE; for(i = 0; i < n_lines; i++) { const MD_LINE* line = &lines[i]; OFF off = line->beg; OFF line_end = line->end; while(TRUE) { CHAR ch; #ifdef MD4C_USE_UTF16 /* For UTF-16, mark_char_map[] covers only ASCII. */ #define IS_MARK_CHAR(off) ((CH(off) < SIZEOF_ARRAY(ctx->mark_char_map)) && \ (ctx->mark_char_map[(unsigned char) CH(off)])) #else /* For 8-bit encodings, mark_char_map[] covers all 256 elements. */ #define IS_MARK_CHAR(off) (ctx->mark_char_map[(unsigned char) CH(off)]) #endif /* Optimization: Use some loop unrolling. */ while(off + 3 < line_end && !IS_MARK_CHAR(off+0) && !IS_MARK_CHAR(off+1) && !IS_MARK_CHAR(off+2) && !IS_MARK_CHAR(off+3)) off += 4; while(off < line_end && !IS_MARK_CHAR(off+0)) off++; if(off >= line_end) break; ch = CH(off); /* A backslash escape. * It can go beyond line->end as it may involve escaped new * line to form a hard break. */ if(ch == _T('\\') && off+1 < ctx->size && (ISPUNCT(off+1) || ISNEWLINE(off+1))) { /* Hard-break cannot be on the last line of the block. */ if(!ISNEWLINE(off+1) || i+1 < n_lines) PUSH_MARK(ch, off, off+2, MD_MARK_RESOLVED); off += 2; continue; } /* A potential (string) emphasis start/end. */ if(ch == _T('*') || ch == _T('_')) { OFF tmp = off+1; int left_level; /* What precedes: 0 = whitespace; 1 = punctuation; 2 = other char. */ int right_level; /* What follows: 0 = whitespace; 1 = punctuation; 2 = other char. */ while(tmp < line_end && CH(tmp) == ch) tmp++; if(off == line->beg || ISUNICODEWHITESPACEBEFORE(off)) left_level = 0; else if(ISUNICODEPUNCTBEFORE(off)) left_level = 1; else left_level = 2; if(tmp == line_end || ISUNICODEWHITESPACE(tmp)) right_level = 0; else if(ISUNICODEPUNCT(tmp)) right_level = 1; else right_level = 2; /* Intra-word underscore doesn't have special meaning. */ if(ch == _T('_') && left_level == 2 && right_level == 2) { left_level = 0; right_level = 0; } if(left_level != 0 || right_level != 0) { unsigned flags = 0; if(left_level > 0 && left_level >= right_level) flags |= MD_MARK_POTENTIAL_CLOSER; if(right_level > 0 && right_level >= left_level) flags |= MD_MARK_POTENTIAL_OPENER; if(left_level == 2 && right_level == 2) flags |= MD_MARK_EMPH_INTRAWORD; /* For "the rule of three" we need to remember the original * size of the mark (modulo three), before we potentially * split the mark when being later resolved partially by some * shorter closer. */ switch((tmp - off) % 3) { case 0: flags |= MD_MARK_EMPH_MOD3_0; break; case 1: flags |= MD_MARK_EMPH_MOD3_1; break; case 2: flags |= MD_MARK_EMPH_MOD3_2; break; } PUSH_MARK(ch, off, tmp, flags); /* During resolving, multiple asterisks may have to be * split into independent span start/ends. Consider e.g. * "**foo* bar*". Therefore we push also some empty dummy * marks to have enough space for that. */ off++; while(off < tmp) { PUSH_MARK('D', off, off, 0); off++; } continue; } off = tmp; continue; } /* A potential code span start/end. */ if(ch == _T('`')) { OFF opener_beg, opener_end; OFF closer_beg, closer_end; int is_code_span; is_code_span = md_is_code_span(ctx, lines + i, n_lines - i, off, &opener_beg, &opener_end, &closer_beg, &closer_end, codespan_last_potential_closers, &codespan_scanned_till_paragraph_end); if(is_code_span) { PUSH_MARK(_T('`'), opener_beg, opener_end, MD_MARK_OPENER | MD_MARK_RESOLVED); PUSH_MARK(_T('`'), closer_beg, closer_end, MD_MARK_CLOSER | MD_MARK_RESOLVED); ctx->marks[ctx->n_marks-2].next = ctx->n_marks-1; ctx->marks[ctx->n_marks-1].prev = ctx->n_marks-2; off = closer_end; /* Advance the current line accordingly. */ while(off > line_end) { i++; line++; line_end = line->end; } continue; } off = opener_end; continue; } /* A potential entity start. */ if(ch == _T('&')) { PUSH_MARK(ch, off, off+1, MD_MARK_POTENTIAL_OPENER); off++; continue; } /* A potential entity end. */ if(ch == _T(';')) { /* We surely cannot be entity unless the previous mark is '&'. */ if(ctx->n_marks > 0 && ctx->marks[ctx->n_marks-1].ch == _T('&')) PUSH_MARK(ch, off, off+1, MD_MARK_POTENTIAL_CLOSER); off++; continue; } /* A potential autolink or raw HTML start/end. */ if(ch == _T('<')) { int is_autolink; OFF autolink_end; int missing_mailto; if(!(ctx->parser.flags & MD_FLAG_NOHTMLSPANS)) { int is_html; OFF html_end; /* Given the nature of the raw HTML, we have to recognize * it here. Doing so later in md_analyze_lt_gt() could * open can of worms of quadratic complexity. */ is_html = md_is_html_any(ctx, lines + i, n_lines - i, off, lines[n_lines-1].end, &html_end); if(is_html) { PUSH_MARK(_T('<'), off, off, MD_MARK_OPENER | MD_MARK_RESOLVED); PUSH_MARK(_T('>'), html_end, html_end, MD_MARK_CLOSER | MD_MARK_RESOLVED); ctx->marks[ctx->n_marks-2].next = ctx->n_marks-1; ctx->marks[ctx->n_marks-1].prev = ctx->n_marks-2; off = html_end; /* Advance the current line accordingly. */ while(off > line_end) { i++; line++; line_end = line->end; } continue; } } is_autolink = md_is_autolink(ctx, off, lines[n_lines-1].end, &autolink_end, &missing_mailto); if(is_autolink) { PUSH_MARK((missing_mailto ? _T('@') : _T('<')), off, off+1, MD_MARK_OPENER | MD_MARK_RESOLVED | MD_MARK_AUTOLINK); PUSH_MARK(_T('>'), autolink_end-1, autolink_end, MD_MARK_CLOSER | MD_MARK_RESOLVED | MD_MARK_AUTOLINK); ctx->marks[ctx->n_marks-2].next = ctx->n_marks-1; ctx->marks[ctx->n_marks-1].prev = ctx->n_marks-2; off = autolink_end; continue; } off++; continue; } /* A potential link or its part. */ if(ch == _T('[') || (ch == _T('!') && off+1 < line_end && CH(off+1) == _T('['))) { OFF tmp = (ch == _T('[') ? off+1 : off+2); PUSH_MARK(ch, off, tmp, MD_MARK_POTENTIAL_OPENER); off = tmp; /* Two dummies to make enough place for data we need if it is * a link. */ PUSH_MARK('D', off, off, 0); PUSH_MARK('D', off, off, 0); continue; } if(ch == _T(']')) { PUSH_MARK(ch, off, off+1, MD_MARK_POTENTIAL_CLOSER); off++; continue; } /* A potential permissive e-mail autolink. */ if(ch == _T('@')) { if(line->beg + 1 <= off && ISALNUM(off-1) && off + 3 < line->end && ISALNUM(off+1)) { PUSH_MARK(ch, off, off+1, MD_MARK_POTENTIAL_OPENER); /* Push a dummy as a reserve for a closer. */ PUSH_MARK('D', off, off, 0); } off++; continue; } /* A potential permissive URL autolink. */ if(ch == _T(':')) { static struct { const CHAR* scheme; SZ scheme_size; const CHAR* suffix; SZ suffix_size; } scheme_map[] = { /* In the order from the most frequently used, arguably. */ { _T("http"), 4, _T("//"), 2 }, { _T("https"), 5, _T("//"), 2 }, { _T("ftp"), 3, _T("//"), 2 } }; int scheme_index; for(scheme_index = 0; scheme_index < (int) SIZEOF_ARRAY(scheme_map); scheme_index++) { const CHAR* scheme = scheme_map[scheme_index].scheme; const SZ scheme_size = scheme_map[scheme_index].scheme_size; const CHAR* suffix = scheme_map[scheme_index].suffix; const SZ suffix_size = scheme_map[scheme_index].suffix_size; if(line->beg + scheme_size <= off && md_ascii_eq(STR(off-scheme_size), scheme, scheme_size) && (line->beg + scheme_size == off || ISWHITESPACE(off-scheme_size-1) || ISANYOF(off-scheme_size-1, _T("*_~(["))) && off + 1 + suffix_size < line->end && md_ascii_eq(STR(off+1), suffix, suffix_size)) { PUSH_MARK(ch, off-scheme_size, off+1+suffix_size, MD_MARK_POTENTIAL_OPENER); /* Push a dummy as a reserve for a closer. */ PUSH_MARK('D', off, off, 0); off += 1 + suffix_size; continue; } } off++; continue; } /* A potential permissive WWW autolink. */ if(ch == _T('.')) { if(line->beg + 3 <= off && md_ascii_eq(STR(off-3), _T("www"), 3) && (line->beg + 3 == off || ISWHITESPACE(off-4) || ISANYOF(off-4, _T("*_~(["))) && off + 1 < line_end) { PUSH_MARK(ch, off-3, off+1, MD_MARK_POTENTIAL_OPENER); /* Push a dummy as a reserve for a closer. */ PUSH_MARK('D', off, off, 0); off++; continue; } off++; continue; } /* A potential table cell boundary. */ if(table_mode && ch == _T('|')) { PUSH_MARK(ch, off, off+1, 0); off++; continue; } /* A potential strikethrough start/end. */ if(ch == _T('~')) { OFF tmp = off+1; while(tmp < line_end && CH(tmp) == _T('~')) tmp++; PUSH_MARK(ch, off, tmp, MD_MARK_POTENTIAL_OPENER | MD_MARK_POTENTIAL_CLOSER); off = tmp; continue; } /* A potential equation start/end */ if(ch == _T('$')) { /* We can have at most two consecutive $ signs, * where two dollar signs signify a display equation. */ OFF tmp = off+1; while(tmp < line_end && CH(tmp) == _T('$')) tmp++; if (tmp - off <= 2) PUSH_MARK(ch, off, tmp, MD_MARK_POTENTIAL_OPENER | MD_MARK_POTENTIAL_CLOSER); off = tmp; continue; } /* Turn non-trivial whitespace into single space. */ if(ISWHITESPACE_(ch)) { OFF tmp = off+1; while(tmp < line_end && ISWHITESPACE(tmp)) tmp++; if(tmp - off > 1 || ch != _T(' ')) PUSH_MARK(ch, off, tmp, MD_MARK_RESOLVED); off = tmp; continue; } /* NULL character. */ if(ch == _T('\0')) { PUSH_MARK(ch, off, off+1, MD_MARK_RESOLVED); off++; continue; } off++; } } /* Add a dummy mark at the end of the mark vector to simplify * process_inlines(). */ PUSH_MARK(127, ctx->size, ctx->size, MD_MARK_RESOLVED); abort: return ret; } static void md_analyze_bracket(MD_CTX* ctx, int mark_index) { /* We cannot really resolve links here as for that we would need * more context. E.g. a following pair of brackets (reference link), * or enclosing pair of brackets (if the inner is the link, the outer * one cannot be.) * * Therefore we here only construct a list of resolved '[' ']' pairs * ordered by position of the closer. This allows ur to analyze what is * or is not link in the right order, from inside to outside in case * of nested brackets. * * The resolving itself is deferred into md_resolve_links(). */ MD_MARK* mark = &ctx->marks[mark_index]; if(mark->flags & MD_MARK_POTENTIAL_OPENER) { md_mark_chain_append(ctx, &BRACKET_OPENERS, mark_index); return; } if(BRACKET_OPENERS.tail >= 0) { /* Pop the opener from the chain. */ int opener_index = BRACKET_OPENERS.tail; MD_MARK* opener = &ctx->marks[opener_index]; if(opener->prev >= 0) ctx->marks[opener->prev].next = -1; else BRACKET_OPENERS.head = -1; BRACKET_OPENERS.tail = opener->prev; /* Interconnect the opener and closer. */ opener->next = mark_index; mark->prev = opener_index; /* Add the pair into chain of potential links for md_resolve_links(). * Note we misuse opener->prev for this as opener->next points to its * closer. */ if(ctx->unresolved_link_tail >= 0) ctx->marks[ctx->unresolved_link_tail].prev = opener_index; else ctx->unresolved_link_head = opener_index; ctx->unresolved_link_tail = opener_index; opener->prev = -1; } } /* Forward declaration. */ static void md_analyze_link_contents(MD_CTX* ctx, const MD_LINE* lines, int n_lines, int mark_beg, int mark_end); static int md_resolve_links(MD_CTX* ctx, const MD_LINE* lines, int n_lines) { int opener_index = ctx->unresolved_link_head; OFF last_link_beg = 0; OFF last_link_end = 0; OFF last_img_beg = 0; OFF last_img_end = 0; while(opener_index >= 0) { MD_MARK* opener = &ctx->marks[opener_index]; int closer_index = opener->next; MD_MARK* closer = &ctx->marks[closer_index]; int next_index = opener->prev; MD_MARK* next_opener; MD_MARK* next_closer; MD_LINK_ATTR attr; int is_link = FALSE; if(next_index >= 0) { next_opener = &ctx->marks[next_index]; next_closer = &ctx->marks[next_opener->next]; } else { next_opener = NULL; next_closer = NULL; } /* If nested ("[ [ ] ]"), we need to make sure that: * - The outer does not end inside of (...) belonging to the inner. * - The outer cannot be link if the inner is link (i.e. not image). * * (Note we here analyze from inner to outer as the marks are ordered * by closer->beg.) */ if((opener->beg < last_link_beg && closer->end < last_link_end) || (opener->beg < last_img_beg && closer->end < last_img_end) || (opener->beg < last_link_end && opener->ch == '[')) { opener_index = next_index; continue; } if(next_opener != NULL && next_opener->beg == closer->end) { if(next_closer->beg > closer->end + 1) { /* Might be full reference link. */ is_link = md_is_link_reference(ctx, lines, n_lines, next_opener->beg, next_closer->end, &attr); } else { /* Might be shortcut reference link. */ is_link = md_is_link_reference(ctx, lines, n_lines, opener->beg, closer->end, &attr); } if(is_link < 0) return -1; if(is_link) { /* Eat the 2nd "[...]". */ closer->end = next_closer->end; } } else { if(closer->end < ctx->size && CH(closer->end) == _T('(')) { /* Might be inline link. */ OFF inline_link_end = UINT_MAX; is_link = md_is_inline_link_spec(ctx, lines, n_lines, closer->end, &inline_link_end, &attr); if(is_link < 0) return -1; /* Check the closing ')' is not inside an already resolved range * (i.e. a range with a higher priority), e.g. a code span. */ if(is_link) { int i = closer_index + 1; while(i < ctx->n_marks) { MD_MARK* mark = &ctx->marks[i]; if(mark->beg >= inline_link_end) break; if((mark->flags & (MD_MARK_OPENER | MD_MARK_RESOLVED)) == (MD_MARK_OPENER | MD_MARK_RESOLVED)) { if(ctx->marks[mark->next].beg >= inline_link_end) { /* Cancel the link status. */ if(attr.title_needs_free) free(attr.title); is_link = FALSE; break; } i = mark->next + 1; } else { i++; } } } if(is_link) { /* Eat the "(...)" */ closer->end = inline_link_end; } } if(!is_link) { /* Might be collapsed reference link. */ is_link = md_is_link_reference(ctx, lines, n_lines, opener->beg, closer->end, &attr); if(is_link < 0) return -1; } } if(is_link) { /* Resolve the brackets as a link. */ opener->flags |= MD_MARK_OPENER | MD_MARK_RESOLVED; closer->flags |= MD_MARK_CLOSER | MD_MARK_RESOLVED; /* If it is a link, we store the destination and title in the two * dummy marks after the opener. */ MD_ASSERT(ctx->marks[opener_index+1].ch == 'D'); ctx->marks[opener_index+1].beg = attr.dest_beg; ctx->marks[opener_index+1].end = attr.dest_end; MD_ASSERT(ctx->marks[opener_index+2].ch == 'D'); md_mark_store_ptr(ctx, opener_index+2, attr.title); if(attr.title_needs_free) md_mark_chain_append(ctx, &PTR_CHAIN, opener_index+2); ctx->marks[opener_index+2].prev = attr.title_size; if(opener->ch == '[') { last_link_beg = opener->beg; last_link_end = closer->end; } else { last_img_beg = opener->beg; last_img_end = closer->end; } md_analyze_link_contents(ctx, lines, n_lines, opener_index+1, closer_index); } opener_index = next_index; } return 0; } /* Analyze whether the mark '&' starts a HTML entity. * If so, update its flags as well as flags of corresponding closer ';'. */ static void md_analyze_entity(MD_CTX* ctx, int mark_index) { MD_MARK* opener = &ctx->marks[mark_index]; MD_MARK* closer; OFF off; /* Cannot be entity if there is no closer as the next mark. * (Any other mark between would mean strange character which cannot be * part of the entity. * * So we can do all the work on '&' and do not call this later for the * closing mark ';'. */ if(mark_index + 1 >= ctx->n_marks) return; closer = &ctx->marks[mark_index+1]; if(closer->ch != ';') return; if(md_is_entity(ctx, opener->beg, closer->end, &off)) { MD_ASSERT(off == closer->end); md_resolve_range(ctx, NULL, mark_index, mark_index+1); opener->end = closer->end; } } static void md_analyze_table_cell_boundary(MD_CTX* ctx, int mark_index) { MD_MARK* mark = &ctx->marks[mark_index]; mark->flags |= MD_MARK_RESOLVED; md_mark_chain_append(ctx, &TABLECELLBOUNDARIES, mark_index); ctx->n_table_cell_boundaries++; } /* Split a longer mark into two. The new mark takes the given count of * characters. May only be called if an adequate number of dummy 'D' marks * follows. */ static int md_split_emph_mark(MD_CTX* ctx, int mark_index, SZ n) { MD_MARK* mark = &ctx->marks[mark_index]; int new_mark_index = mark_index + (mark->end - mark->beg - n); MD_MARK* dummy = &ctx->marks[new_mark_index]; MD_ASSERT(mark->end - mark->beg > n); MD_ASSERT(dummy->ch == 'D'); memcpy(dummy, mark, sizeof(MD_MARK)); mark->end -= n; dummy->beg = mark->end; return new_mark_index; } static void md_analyze_emph(MD_CTX* ctx, int mark_index) { MD_MARK* mark = &ctx->marks[mark_index]; MD_MARKCHAIN* chain = md_mark_chain(ctx, mark_index); /* If we can be a closer, try to resolve with the preceding opener. */ if(mark->flags & MD_MARK_POTENTIAL_CLOSER) { MD_MARK* opener = NULL; int opener_index; if(mark->ch == _T('*')) { MD_MARKCHAIN* opener_chains[6]; int i, n_opener_chains; unsigned flags = mark->flags; /* Apply "rule of three". (This is why we break asterisk opener * marks into multiple chains.) */ n_opener_chains = 0; opener_chains[n_opener_chains++] = &ASTERISK_OPENERS_intraword_mod3_0; if((flags & MD_MARK_EMPH_MOD3_MASK) != MD_MARK_EMPH_MOD3_2) opener_chains[n_opener_chains++] = &ASTERISK_OPENERS_intraword_mod3_1; if((flags & MD_MARK_EMPH_MOD3_MASK) != MD_MARK_EMPH_MOD3_1) opener_chains[n_opener_chains++] = &ASTERISK_OPENERS_intraword_mod3_2; opener_chains[n_opener_chains++] = &ASTERISK_OPENERS_extraword_mod3_0; if(!(flags & MD_MARK_EMPH_INTRAWORD) || (flags & MD_MARK_EMPH_MOD3_MASK) != MD_MARK_EMPH_MOD3_2) opener_chains[n_opener_chains++] = &ASTERISK_OPENERS_extraword_mod3_1; if(!(flags & MD_MARK_EMPH_INTRAWORD) || (flags & MD_MARK_EMPH_MOD3_MASK) != MD_MARK_EMPH_MOD3_1) opener_chains[n_opener_chains++] = &ASTERISK_OPENERS_extraword_mod3_2; /* Opener is the most recent mark from the allowed chains. */ for(i = 0; i < n_opener_chains; i++) { if(opener_chains[i]->tail >= 0) { int tmp_index = opener_chains[i]->tail; MD_MARK* tmp_mark = &ctx->marks[tmp_index]; if(opener == NULL || tmp_mark->end > opener->end) { opener_index = tmp_index; opener = tmp_mark; } } } } else { /* Simple emph. mark */ if(chain->tail >= 0) { opener_index = chain->tail; opener = &ctx->marks[opener_index]; } } /* Resolve, if we have found matching opener. */ if(opener != NULL) { SZ opener_size = opener->end - opener->beg; SZ closer_size = mark->end - mark->beg; if(opener_size > closer_size) { opener_index = md_split_emph_mark(ctx, opener_index, closer_size); md_mark_chain_append(ctx, md_mark_chain(ctx, opener_index), opener_index); } else if(opener_size < closer_size) { md_split_emph_mark(ctx, mark_index, closer_size - opener_size); } md_rollback(ctx, opener_index, mark_index, MD_ROLLBACK_CROSSING); md_resolve_range(ctx, chain, opener_index, mark_index); return; } } /* If we could not resolve as closer, we may be yet be an opener. */ if(mark->flags & MD_MARK_POTENTIAL_OPENER) md_mark_chain_append(ctx, chain, mark_index); } static void md_analyze_tilde(MD_CTX* ctx, int mark_index) { /* We attempt to be Github Flavored Markdown compatible here. GFM says * that length of the tilde sequence is not important at all. Note that * implies the TILDE_OPENERS chain can have at most one item. */ if(TILDE_OPENERS.head >= 0) { /* The chain already contains an opener, so we may resolve the span. */ int opener_index = TILDE_OPENERS.head; md_rollback(ctx, opener_index, mark_index, MD_ROLLBACK_CROSSING); md_resolve_range(ctx, &TILDE_OPENERS, opener_index, mark_index); } else { /* We can only be opener. */ md_mark_chain_append(ctx, &TILDE_OPENERS, mark_index); } } static void md_analyze_dollar(MD_CTX* ctx, int mark_index) { /* This should mimic the way inline equations work in LaTeX, so there * can only ever be one item in the chain (i.e. the dollars can't be * nested). This is basically the same as the md_analyze_tilde function, * except that we require matching openers and closers to be of the same * length. * * E.g.: $abc$$def$$ => abc (display equation) def (end equation) */ if(DOLLAR_OPENERS.head >= 0) { /* If the potential closer has a non-matching number of $, discard */ MD_MARK* open = &ctx->marks[DOLLAR_OPENERS.head]; MD_MARK* close = &ctx->marks[mark_index]; int opener_index = DOLLAR_OPENERS.head; md_rollback(ctx, opener_index, mark_index, MD_ROLLBACK_ALL); if (open->end - open->beg == close->end - close->beg) { /* We are the matching closer */ md_resolve_range(ctx, &DOLLAR_OPENERS, opener_index, mark_index); } else { /* We don't match the opener, so discard old opener and insert as opener */ md_mark_chain_append(ctx, &DOLLAR_OPENERS, mark_index); } } else { /* No unmatched openers, so we are opener */ md_mark_chain_append(ctx, &DOLLAR_OPENERS, mark_index); } } static void md_analyze_permissive_url_autolink(MD_CTX* ctx, int mark_index) { MD_MARK* opener = &ctx->marks[mark_index]; int closer_index = mark_index + 1; MD_MARK* closer = &ctx->marks[closer_index]; MD_MARK* next_resolved_mark; OFF off = opener->end; int n_dots = FALSE; int has_underscore_in_last_seg = FALSE; int has_underscore_in_next_to_last_seg = FALSE; int n_opened_parenthesis = 0; /* Check for domain. */ while(off < ctx->size) { if(ISALNUM(off) || CH(off) == _T('-')) { off++; } else if(CH(off) == _T('.')) { /* We must see at least one period. */ n_dots++; has_underscore_in_next_to_last_seg = has_underscore_in_last_seg; has_underscore_in_last_seg = FALSE; off++; } else if(CH(off) == _T('_')) { /* No underscore may be present in the last two domain segments. */ has_underscore_in_last_seg = TRUE; off++; } else { break; } } if(off > opener->end && CH(off-1) == _T('.')) { off--; n_dots--; } if(off <= opener->end || n_dots == 0 || has_underscore_in_next_to_last_seg || has_underscore_in_last_seg) return; /* Check for path. */ next_resolved_mark = closer + 1; while(next_resolved_mark->ch == 'D' || !(next_resolved_mark->flags & MD_MARK_RESOLVED)) next_resolved_mark++; while(off < next_resolved_mark->beg && CH(off) != _T('<') && !ISWHITESPACE(off) && !ISNEWLINE(off)) { /* Parenthesis must be balanced. */ if(CH(off) == _T('(')) { n_opened_parenthesis++; } else if(CH(off) == _T(')')) { if(n_opened_parenthesis > 0) n_opened_parenthesis--; else break; } off++; } /* These cannot be last char In such case they are more likely normal * punctuation. */ if(ISANYOF(off-1, _T("?!.,:*_~"))) off--; /* Ok. Lets call it auto-link. Adapt opener and create closer to zero * length so all the contents becomes the link text. */ MD_ASSERT(closer->ch == 'D'); opener->end = opener->beg; closer->ch = opener->ch; closer->beg = off; closer->end = off; md_resolve_range(ctx, NULL, mark_index, closer_index); } /* The permissive autolinks do not have to be enclosed in '<' '>' but we * instead impose stricter rules what is understood as an e-mail address * here. Actually any non-alphanumeric characters with exception of '.' * are prohibited both in username and after '@'. */ static void md_analyze_permissive_email_autolink(MD_CTX* ctx, int mark_index) { MD_MARK* opener = &ctx->marks[mark_index]; int closer_index; MD_MARK* closer; OFF beg = opener->beg; OFF end = opener->end; int dot_count = 0; MD_ASSERT(CH(beg) == _T('@')); /* Scan for name before '@'. */ while(beg > 0 && (ISALNUM(beg-1) || ISANYOF(beg-1, _T(".-_+")))) beg--; /* Scan for domain after '@'. */ while(end < ctx->size && (ISALNUM(end) || ISANYOF(end, _T(".-_")))) { if(CH(end) == _T('.')) dot_count++; end++; } if(CH(end-1) == _T('.')) { /* Final '.' not part of it. */ dot_count--; end--; } else if(ISANYOF2(end-1, _T('-'), _T('_'))) /* These are forbidden at the end. */ return; if(CH(end-1) == _T('@') || dot_count == 0) return; /* Ok. Lets call it auto-link. Adapt opener and create closer to zero * length so all the contents becomes the link text. */ closer_index = mark_index + 1; closer = &ctx->marks[closer_index]; MD_ASSERT(closer->ch == 'D'); opener->beg = beg; opener->end = beg; closer->ch = opener->ch; closer->beg = end; closer->end = end; md_resolve_range(ctx, NULL, mark_index, closer_index); } static inline void md_analyze_marks(MD_CTX* ctx, const MD_LINE* lines, int n_lines, int mark_beg, int mark_end, const CHAR* mark_chars) { int i = mark_beg; while(i < mark_end) { MD_MARK* mark = &ctx->marks[i]; /* Skip resolved spans. */ if(mark->flags & MD_MARK_RESOLVED) { if(mark->flags & MD_MARK_OPENER) { MD_ASSERT(i < mark->next); i = mark->next + 1; } else { i++; } continue; } /* Skip marks we do not want to deal with. */ if(!ISANYOF_(mark->ch, mark_chars)) { i++; continue; } /* Analyze the mark. */ switch(mark->ch) { case '[': /* Pass through. */ case '!': /* Pass through. */ case ']': md_analyze_bracket(ctx, i); break; case '&': md_analyze_entity(ctx, i); break; case '|': md_analyze_table_cell_boundary(ctx, i); break; case '_': /* Pass through. */ case '*': md_analyze_emph(ctx, i); break; case '~': md_analyze_tilde(ctx, i); break; case '$': md_analyze_dollar(ctx, i); break; case '.': /* Pass through. */ case ':': md_analyze_permissive_url_autolink(ctx, i); break; case '@': md_analyze_permissive_email_autolink(ctx, i); break; } i++; } } /* Analyze marks (build ctx->marks). */ static int md_analyze_inlines(MD_CTX* ctx, const MD_LINE* lines, int n_lines, int table_mode) { int ret; /* Reset the previously collected stack of marks. */ ctx->n_marks = 0; /* Collect all marks. */ MD_CHECK(md_collect_marks(ctx, lines, n_lines, table_mode)); /* We analyze marks in few groups to handle their precedence. */ /* (1) Entities; code spans; autolinks; raw HTML. */ md_analyze_marks(ctx, lines, n_lines, 0, ctx->n_marks, _T("&")); if(table_mode) { /* (2) Analyze table cell boundaries. * Note we reset TABLECELLBOUNDARIES chain prior to the call md_analyze_marks(), * not after, because caller may need it. */ MD_ASSERT(n_lines == 1); TABLECELLBOUNDARIES.head = -1; TABLECELLBOUNDARIES.tail = -1; ctx->n_table_cell_boundaries = 0; md_analyze_marks(ctx, lines, n_lines, 0, ctx->n_marks, _T("|")); return ret; } /* (3) Links. */ md_analyze_marks(ctx, lines, n_lines, 0, ctx->n_marks, _T("[]!")); MD_CHECK(md_resolve_links(ctx, lines, n_lines)); BRACKET_OPENERS.head = -1; BRACKET_OPENERS.tail = -1; ctx->unresolved_link_head = -1; ctx->unresolved_link_tail = -1; /* (4) Emphasis and strong emphasis; permissive autolinks. */ md_analyze_link_contents(ctx, lines, n_lines, 0, ctx->n_marks); abort: return ret; } static void md_analyze_link_contents(MD_CTX* ctx, const MD_LINE* lines, int n_lines, int mark_beg, int mark_end) { md_analyze_marks(ctx, lines, n_lines, mark_beg, mark_end, _T("*_~$@:.")); ASTERISK_OPENERS_extraword_mod3_0.head = -1; ASTERISK_OPENERS_extraword_mod3_0.tail = -1; ASTERISK_OPENERS_extraword_mod3_1.head = -1; ASTERISK_OPENERS_extraword_mod3_1.tail = -1; ASTERISK_OPENERS_extraword_mod3_2.head = -1; ASTERISK_OPENERS_extraword_mod3_2.tail = -1; ASTERISK_OPENERS_intraword_mod3_0.head = -1; ASTERISK_OPENERS_intraword_mod3_0.tail = -1; ASTERISK_OPENERS_intraword_mod3_1.head = -1; ASTERISK_OPENERS_intraword_mod3_1.tail = -1; ASTERISK_OPENERS_intraword_mod3_2.head = -1; ASTERISK_OPENERS_intraword_mod3_2.tail = -1; UNDERSCORE_OPENERS.head = -1; UNDERSCORE_OPENERS.tail = -1; TILDE_OPENERS.head = -1; TILDE_OPENERS.tail = -1; DOLLAR_OPENERS.head = -1; DOLLAR_OPENERS.tail = -1; } static int md_enter_leave_span_a(MD_CTX* ctx, int enter, MD_SPANTYPE type, const CHAR* dest, SZ dest_size, int prohibit_escapes_in_dest, const CHAR* title, SZ title_size) { MD_ATTRIBUTE_BUILD href_build = { 0 }; MD_ATTRIBUTE_BUILD title_build = { 0 }; MD_SPAN_A_DETAIL det; int ret = 0; /* Note we here rely on fact that MD_SPAN_A_DETAIL and * MD_SPAN_IMG_DETAIL are binary-compatible. */ memset(&det, 0, sizeof(MD_SPAN_A_DETAIL)); MD_CHECK(md_build_attribute(ctx, dest, dest_size, (prohibit_escapes_in_dest ? MD_BUILD_ATTR_NO_ESCAPES : 0), &det.href, &href_build)); MD_CHECK(md_build_attribute(ctx, title, title_size, 0, &det.title, &title_build)); if(enter) MD_ENTER_SPAN(type, &det); else MD_LEAVE_SPAN(type, &det); abort: md_free_attribute(ctx, &href_build); md_free_attribute(ctx, &title_build); return ret; } /* Render the output, accordingly to the analyzed ctx->marks. */ static int md_process_inlines(MD_CTX* ctx, const MD_LINE* lines, int n_lines) { MD_TEXTTYPE text_type; const MD_LINE* line = lines; MD_MARK* prev_mark = NULL; MD_MARK* mark; OFF off = lines[0].beg; OFF end = lines[n_lines-1].end; int enforce_hardbreak = 0; int ret = 0; /* Find first resolved mark. Note there is always at least one resolved * mark, the dummy last one after the end of the latest line we actually * never really reach. This saves us of a lot of special checks and cases * in this function. */ mark = ctx->marks; while(!(mark->flags & MD_MARK_RESOLVED)) mark++; text_type = MD_TEXT_NORMAL; while(1) { /* Process the text up to the next mark or end-of-line. */ OFF tmp = (line->end < mark->beg ? line->end : mark->beg); if(tmp > off) { MD_TEXT(text_type, STR(off), tmp - off); off = tmp; } /* If reached the mark, process it and move to next one. */ if(off >= mark->beg) { switch(mark->ch) { case '\\': /* Backslash escape. */ if(ISNEWLINE(mark->beg+1)) enforce_hardbreak = 1; else MD_TEXT(text_type, STR(mark->beg+1), 1); break; case ' ': /* Non-trivial space. */ MD_TEXT(text_type, _T(" "), 1); break; case '`': /* Code span. */ if(mark->flags & MD_MARK_OPENER) { MD_ENTER_SPAN(MD_SPAN_CODE, NULL); text_type = MD_TEXT_CODE; } else { MD_LEAVE_SPAN(MD_SPAN_CODE, NULL); text_type = MD_TEXT_NORMAL; } break; case '_': case '*': /* Emphasis, strong emphasis. */ if(mark->flags & MD_MARK_OPENER) { if((mark->end - off) % 2) { MD_ENTER_SPAN(MD_SPAN_EM, NULL); off++; } while(off + 1 < mark->end) { MD_ENTER_SPAN(MD_SPAN_STRONG, NULL); off += 2; } } else { while(off + 1 < mark->end) { MD_LEAVE_SPAN(MD_SPAN_STRONG, NULL); off += 2; } if((mark->end - off) % 2) { MD_LEAVE_SPAN(MD_SPAN_EM, NULL); off++; } } break; case '~': if(mark->flags & MD_MARK_OPENER) MD_ENTER_SPAN(MD_SPAN_DEL, NULL); else MD_LEAVE_SPAN(MD_SPAN_DEL, NULL); break; case '$': if(mark->flags & MD_MARK_OPENER) { MD_ENTER_SPAN((mark->end - off) % 2 ? MD_SPAN_LATEXMATH : MD_SPAN_LATEXMATH_DISPLAY, NULL); text_type = MD_TEXT_LATEXMATH; } else { MD_LEAVE_SPAN((mark->end - off) % 2 ? MD_SPAN_LATEXMATH : MD_SPAN_LATEXMATH_DISPLAY, NULL); text_type = MD_TEXT_NORMAL; } break; case '[': /* Link, image. */ case '!': case ']': { const MD_MARK* opener = (mark->ch != ']' ? mark : &ctx->marks[mark->prev]); const MD_MARK* dest_mark = opener+1; const MD_MARK* title_mark = opener+2; MD_ASSERT(dest_mark->ch == 'D'); MD_ASSERT(title_mark->ch == 'D'); MD_CHECK(md_enter_leave_span_a(ctx, (mark->ch != ']'), (opener->ch == '!' ? MD_SPAN_IMG : MD_SPAN_A), STR(dest_mark->beg), dest_mark->end - dest_mark->beg, FALSE, md_mark_get_ptr(ctx, title_mark - ctx->marks), title_mark->prev)); /* link/image closer may span multiple lines. */ if(mark->ch == ']') { while(mark->end > line->end) line++; } break; } case '<': case '>': /* Autolink or raw HTML. */ if(!(mark->flags & MD_MARK_AUTOLINK)) { /* Raw HTML. */ if(mark->flags & MD_MARK_OPENER) text_type = MD_TEXT_HTML; else text_type = MD_TEXT_NORMAL; break; } /* Pass through, if auto-link. */ case '@': /* Permissive e-mail autolink. */ case ':': /* Permissive URL autolink. */ case '.': /* Permissive WWW autolink. */ { MD_MARK* opener = ((mark->flags & MD_MARK_OPENER) ? mark : &ctx->marks[mark->prev]); MD_MARK* closer = &ctx->marks[opener->next]; const CHAR* dest = STR(opener->end); SZ dest_size = closer->beg - opener->end; /* For permissive auto-links we do not know closer mark * position at the time of md_collect_marks(), therefore * it can be out-of-order in ctx->marks[]. * * With this flag, we make sure that we output the closer * only if we processed the opener. */ if(mark->flags & MD_MARK_OPENER) closer->flags |= MD_MARK_VALIDPERMISSIVEAUTOLINK; if(opener->ch == '@' || opener->ch == '.') { dest_size += 7; MD_TEMP_BUFFER(dest_size * sizeof(CHAR)); memcpy(ctx->buffer, (opener->ch == '@' ? _T("mailto:") : _T("http://")), 7 * sizeof(CHAR)); memcpy(ctx->buffer + 7, dest, (dest_size-7) * sizeof(CHAR)); dest = ctx->buffer; } if(closer->flags & MD_MARK_VALIDPERMISSIVEAUTOLINK) MD_CHECK(md_enter_leave_span_a(ctx, (mark->flags & MD_MARK_OPENER), MD_SPAN_A, dest, dest_size, TRUE, NULL, 0)); break; } case '&': /* Entity. */ MD_TEXT(MD_TEXT_ENTITY, STR(mark->beg), mark->end - mark->beg); break; case '\0': MD_TEXT(MD_TEXT_NULLCHAR, _T(""), 1); break; case 127: goto abort; } off = mark->end; /* Move to next resolved mark. */ prev_mark = mark; mark++; while(!(mark->flags & MD_MARK_RESOLVED) || mark->beg < off) mark++; } /* If reached end of line, move to next one. */ if(off >= line->end) { /* If it is the last line, we are done. */ if(off >= end) break; if(text_type == MD_TEXT_CODE || text_type == MD_TEXT_LATEXMATH) { OFF tmp; MD_ASSERT(prev_mark != NULL); MD_ASSERT(ISANYOF2_(prev_mark->ch, '`', '$') && (prev_mark->flags & MD_MARK_OPENER)); MD_ASSERT(ISANYOF2_(mark->ch, '`', '$') && (mark->flags & MD_MARK_CLOSER)); /* Inside a code span, trailing line whitespace has to be * outputted. */ tmp = off; while(off < ctx->size && ISBLANK(off)) off++; if(off > tmp) MD_TEXT(text_type, STR(tmp), off-tmp); /* and new lines are transformed into single spaces. */ if(prev_mark->end < off && off < mark->beg) MD_TEXT(text_type, _T(" "), 1); } else if(text_type == MD_TEXT_HTML) { /* Inside raw HTML, we output the new line verbatim, including * any trailing spaces. */ OFF tmp = off; while(tmp < end && ISBLANK(tmp)) tmp++; if(tmp > off) MD_TEXT(MD_TEXT_HTML, STR(off), tmp - off); MD_TEXT(MD_TEXT_HTML, _T("\n"), 1); } else { /* Output soft or hard line break. */ MD_TEXTTYPE break_type = MD_TEXT_SOFTBR; if(text_type == MD_TEXT_NORMAL) { if(enforce_hardbreak) break_type = MD_TEXT_BR; else if((CH(line->end) == _T(' ') && CH(line->end+1) == _T(' '))) break_type = MD_TEXT_BR; } MD_TEXT(break_type, _T("\n"), 1); } /* Move to the next line. */ line++; off = line->beg; enforce_hardbreak = 0; } } abort: return ret; } /*************************** *** Processing Tables *** ***************************/ static void md_analyze_table_alignment(MD_CTX* ctx, OFF beg, OFF end, MD_ALIGN* align, int n_align) { static const MD_ALIGN align_map[] = { MD_ALIGN_DEFAULT, MD_ALIGN_LEFT, MD_ALIGN_RIGHT, MD_ALIGN_CENTER }; OFF off = beg; while(n_align > 0) { int index = 0; /* index into align_map[] */ while(CH(off) != _T('-')) off++; if(off > beg && CH(off-1) == _T(':')) index |= 1; while(off < end && CH(off) == _T('-')) off++; if(off < end && CH(off) == _T(':')) index |= 2; *align = align_map[index]; align++; n_align--; } } /* Forward declaration. */ static int md_process_normal_block_contents(MD_CTX* ctx, const MD_LINE* lines, int n_lines); static int md_process_table_cell(MD_CTX* ctx, MD_BLOCKTYPE cell_type, MD_ALIGN align, OFF beg, OFF end) { MD_LINE line; MD_BLOCK_TD_DETAIL det; int ret = 0; while(beg < end && ISWHITESPACE(beg)) beg++; while(end > beg && ISWHITESPACE(end-1)) end--; det.align = align; line.beg = beg; line.end = end; MD_ENTER_BLOCK(cell_type, &det); MD_CHECK(md_process_normal_block_contents(ctx, &line, 1)); MD_LEAVE_BLOCK(cell_type, &det); abort: return ret; } static int md_process_table_row(MD_CTX* ctx, MD_BLOCKTYPE cell_type, OFF beg, OFF end, const MD_ALIGN* align, int col_count) { MD_LINE line; OFF* pipe_offs = NULL; int i, j, n; int ret = 0; line.beg = beg; line.end = end; /* Break the line into table cells by identifying pipe characters who * form the cell boundary. */ MD_CHECK(md_analyze_inlines(ctx, &line, 1, TRUE)); /* We have to remember the cell boundaries in local buffer because * ctx->marks[] shall be reused during cell contents processing. */ n = ctx->n_table_cell_boundaries; pipe_offs = (OFF*) malloc(n * sizeof(OFF)); if(pipe_offs == NULL) { MD_LOG("malloc() failed."); ret = -1; goto abort; } for(i = TABLECELLBOUNDARIES.head, j = 0; i >= 0; i = ctx->marks[i].next) { MD_MARK* mark = &ctx->marks[i]; pipe_offs[j++] = mark->beg; } /* Process cells. */ MD_ENTER_BLOCK(MD_BLOCK_TR, NULL); j = 0; if(beg < pipe_offs[0] && j < col_count) MD_CHECK(md_process_table_cell(ctx, cell_type, align[j++], beg, pipe_offs[0])); for(i = 0; i < n-1 && j < col_count; i++) MD_CHECK(md_process_table_cell(ctx, cell_type, align[j++], pipe_offs[i]+1, pipe_offs[i+1])); if(pipe_offs[n-1] < end-1 && j < col_count) MD_CHECK(md_process_table_cell(ctx, cell_type, align[j++], pipe_offs[n-1]+1, end)); /* Make sure we call enough table cells even if the current table contains * too few of them. */ while(j < col_count) MD_CHECK(md_process_table_cell(ctx, cell_type, align[j++], 0, 0)); MD_LEAVE_BLOCK(MD_BLOCK_TR, NULL); abort: free(pipe_offs); /* Free any temporary memory blocks stored within some dummy marks. */ for(i = PTR_CHAIN.head; i >= 0; i = ctx->marks[i].next) free(md_mark_get_ptr(ctx, i)); PTR_CHAIN.head = -1; PTR_CHAIN.tail = -1; return ret; } static int md_process_table_block_contents(MD_CTX* ctx, int col_count, const MD_LINE* lines, int n_lines) { MD_ALIGN* align; int i; int ret = 0; /* At least two lines have to be present: The column headers and the line * with the underlines. */ MD_ASSERT(n_lines >= 2); align = malloc(col_count * sizeof(MD_ALIGN)); if(align == NULL) { MD_LOG("malloc() failed."); ret = -1; goto abort; } md_analyze_table_alignment(ctx, lines[1].beg, lines[1].end, align, col_count); MD_ENTER_BLOCK(MD_BLOCK_THEAD, NULL); MD_CHECK(md_process_table_row(ctx, MD_BLOCK_TH, lines[0].beg, lines[0].end, align, col_count)); MD_LEAVE_BLOCK(MD_BLOCK_THEAD, NULL); MD_ENTER_BLOCK(MD_BLOCK_TBODY, NULL); for(i = 2; i < n_lines; i++) { MD_CHECK(md_process_table_row(ctx, MD_BLOCK_TD, lines[i].beg, lines[i].end, align, col_count)); } MD_LEAVE_BLOCK(MD_BLOCK_TBODY, NULL); abort: free(align); return ret; } static int md_is_table_row(MD_CTX* ctx, OFF beg, OFF* p_end) { MD_LINE line; int i; int ret = FALSE; line.beg = beg; line.end = beg; /* Find end of line. */ while(line.end < ctx->size && !ISNEWLINE(line.end)) line.end++; MD_CHECK(md_analyze_inlines(ctx, &line, 1, TRUE)); if(TABLECELLBOUNDARIES.head >= 0) { if(p_end != NULL) *p_end = line.end; ret = TRUE; } abort: /* Free any temporary memory blocks stored within some dummy marks. */ for(i = PTR_CHAIN.head; i >= 0; i = ctx->marks[i].next) free(md_mark_get_ptr(ctx, i)); PTR_CHAIN.head = -1; PTR_CHAIN.tail = -1; return ret; } /************************** *** Processing Block *** **************************/ #define MD_BLOCK_CONTAINER_OPENER 0x01 #define MD_BLOCK_CONTAINER_CLOSER 0x02 #define MD_BLOCK_CONTAINER (MD_BLOCK_CONTAINER_OPENER | MD_BLOCK_CONTAINER_CLOSER) #define MD_BLOCK_LOOSE_LIST 0x04 #define MD_BLOCK_SETEXT_HEADER 0x08 struct MD_BLOCK_tag { MD_BLOCKTYPE type : 8; unsigned flags : 8; /* MD_BLOCK_H: Header level (1 - 6) * MD_BLOCK_CODE: Non-zero if fenced, zero if indented. * MD_BLOCK_LI: Task mark character (0 if not task list item, 'x', 'X' or ' '). * MD_BLOCK_TABLE: Column count (as determined by the table underline). */ unsigned data : 16; /* Leaf blocks: Count of lines (MD_LINE or MD_VERBATIMLINE) on the block. * MD_BLOCK_LI: Task mark offset in the input doc. * MD_BLOCK_OL: Start item number. */ unsigned n_lines; }; struct MD_CONTAINER_tag { CHAR ch; unsigned is_loose : 8; unsigned is_task : 8; unsigned start; unsigned mark_indent; unsigned contents_indent; OFF block_byte_off; OFF task_mark_off; }; static int md_process_normal_block_contents(MD_CTX* ctx, const MD_LINE* lines, int n_lines) { int i; int ret; MD_CHECK(md_analyze_inlines(ctx, lines, n_lines, FALSE)); MD_CHECK(md_process_inlines(ctx, lines, n_lines)); abort: /* Free any temporary memory blocks stored within some dummy marks. */ for(i = PTR_CHAIN.head; i >= 0; i = ctx->marks[i].next) free(md_mark_get_ptr(ctx, i)); PTR_CHAIN.head = -1; PTR_CHAIN.tail = -1; return ret; } static int md_process_verbatim_block_contents(MD_CTX* ctx, MD_TEXTTYPE text_type, const MD_VERBATIMLINE* lines, int n_lines) { static const CHAR indent_chunk_str[] = _T(" "); static const SZ indent_chunk_size = SIZEOF_ARRAY(indent_chunk_str) - 1; int i; int ret = 0; for(i = 0; i < n_lines; i++) { const MD_VERBATIMLINE* line = &lines[i]; int indent = line->indent; MD_ASSERT(indent >= 0); /* Output code indentation. */ while(indent > (int) SIZEOF_ARRAY(indent_chunk_str)) { MD_TEXT(text_type, indent_chunk_str, indent_chunk_size); indent -= SIZEOF_ARRAY(indent_chunk_str); } if(indent > 0) MD_TEXT(text_type, indent_chunk_str, indent); /* Output the code line itself. */ MD_TEXT_INSECURE(text_type, STR(line->beg), line->end - line->beg); /* Enforce end-of-line. */ MD_TEXT(text_type, _T("\n"), 1); } abort: return ret; } static int md_process_code_block_contents(MD_CTX* ctx, int is_fenced, const MD_VERBATIMLINE* lines, int n_lines) { if(is_fenced) { /* Skip the first line in case of fenced code: It is the fence. * (Only the starting fence is present due to logic in md_analyze_line().) */ lines++; n_lines--; } else { /* Ignore blank lines at start/end of indented code block. */ while(n_lines > 0 && lines[0].beg == lines[0].end) { lines++; n_lines--; } while(n_lines > 0 && lines[n_lines-1].beg == lines[n_lines-1].end) { n_lines--; } } if(n_lines == 0) return 0; return md_process_verbatim_block_contents(ctx, MD_TEXT_CODE, lines, n_lines); } static int md_setup_fenced_code_detail(MD_CTX* ctx, const MD_BLOCK* block, MD_BLOCK_CODE_DETAIL* det, MD_ATTRIBUTE_BUILD* info_build, MD_ATTRIBUTE_BUILD* lang_build) { const MD_VERBATIMLINE* fence_line = (const MD_VERBATIMLINE*)(block + 1); OFF beg = fence_line->beg; OFF end = fence_line->end; OFF lang_end; CHAR fence_ch = CH(fence_line->beg); int ret = 0; /* Skip the fence itself. */ while(beg < ctx->size && CH(beg) == fence_ch) beg++; /* Trim initial spaces. */ while(beg < ctx->size && CH(beg) == _T(' ')) beg++; /* Trim trailing spaces. */ while(end > beg && CH(end-1) == _T(' ')) end--; /* Build info string attribute. */ MD_CHECK(md_build_attribute(ctx, STR(beg), end - beg, 0, &det->info, info_build)); /* Build info string attribute. */ lang_end = beg; while(lang_end < end && !ISWHITESPACE(lang_end)) lang_end++; MD_CHECK(md_build_attribute(ctx, STR(beg), lang_end - beg, 0, &det->lang, lang_build)); det->fence_char = fence_ch; abort: return ret; } static int md_process_leaf_block(MD_CTX* ctx, const MD_BLOCK* block) { union { MD_BLOCK_H_DETAIL header; MD_BLOCK_CODE_DETAIL code; } det; MD_ATTRIBUTE_BUILD info_build; MD_ATTRIBUTE_BUILD lang_build; int is_in_tight_list; int clean_fence_code_detail = FALSE; int ret = 0; memset(&det, 0, sizeof(det)); if(ctx->n_containers == 0) is_in_tight_list = FALSE; else is_in_tight_list = !ctx->containers[ctx->n_containers-1].is_loose; switch(block->type) { case MD_BLOCK_H: det.header.level = block->data; break; case MD_BLOCK_CODE: /* For fenced code block, we may need to set the info string. */ if(block->data != 0) { memset(&det.code, 0, sizeof(MD_BLOCK_CODE_DETAIL)); clean_fence_code_detail = TRUE; MD_CHECK(md_setup_fenced_code_detail(ctx, block, &det.code, &info_build, &lang_build)); } break; default: /* Noop. */ break; } if(!is_in_tight_list || block->type != MD_BLOCK_P) MD_ENTER_BLOCK(block->type, (void*) &det); /* Process the block contents accordingly to is type. */ switch(block->type) { case MD_BLOCK_HR: /* noop */ break; case MD_BLOCK_CODE: MD_CHECK(md_process_code_block_contents(ctx, (block->data != 0), (const MD_VERBATIMLINE*)(block + 1), block->n_lines)); break; case MD_BLOCK_HTML: MD_CHECK(md_process_verbatim_block_contents(ctx, MD_TEXT_HTML, (const MD_VERBATIMLINE*)(block + 1), block->n_lines)); break; case MD_BLOCK_TABLE: MD_CHECK(md_process_table_block_contents(ctx, block->data, (const MD_LINE*)(block + 1), block->n_lines)); break; default: MD_CHECK(md_process_normal_block_contents(ctx, (const MD_LINE*)(block + 1), block->n_lines)); break; } if(!is_in_tight_list || block->type != MD_BLOCK_P) MD_LEAVE_BLOCK(block->type, (void*) &det); abort: if(clean_fence_code_detail) { md_free_attribute(ctx, &info_build); md_free_attribute(ctx, &lang_build); } return ret; } static int md_process_all_blocks(MD_CTX* ctx) { int byte_off = 0; int ret = 0; /* ctx->containers now is not needed for detection of lists and list items * so we reuse it for tracking what lists are loose or tight. We rely * on the fact the vector is large enough to hold the deepest nesting * level of lists. */ ctx->n_containers = 0; while(byte_off < ctx->n_block_bytes) { MD_BLOCK* block = (MD_BLOCK*)((char*)ctx->block_bytes + byte_off); union { MD_BLOCK_UL_DETAIL ul; MD_BLOCK_OL_DETAIL ol; MD_BLOCK_LI_DETAIL li; } det; switch(block->type) { case MD_BLOCK_UL: det.ul.is_tight = (block->flags & MD_BLOCK_LOOSE_LIST) ? FALSE : TRUE; det.ul.mark = (CHAR) block->data; break; case MD_BLOCK_OL: det.ol.start = block->n_lines; det.ol.is_tight = (block->flags & MD_BLOCK_LOOSE_LIST) ? FALSE : TRUE; det.ol.mark_delimiter = (CHAR) block->data; break; case MD_BLOCK_LI: det.li.is_task = (block->data != 0); det.li.task_mark = (CHAR) block->data; det.li.task_mark_offset = (OFF) block->n_lines; break; default: /* noop */ break; } if(block->flags & MD_BLOCK_CONTAINER) { if(block->flags & MD_BLOCK_CONTAINER_CLOSER) { MD_LEAVE_BLOCK(block->type, &det); if(block->type == MD_BLOCK_UL || block->type == MD_BLOCK_OL || block->type == MD_BLOCK_QUOTE) ctx->n_containers--; } if(block->flags & MD_BLOCK_CONTAINER_OPENER) { MD_ENTER_BLOCK(block->type, &det); if(block->type == MD_BLOCK_UL || block->type == MD_BLOCK_OL) { ctx->containers[ctx->n_containers].is_loose = (block->flags & MD_BLOCK_LOOSE_LIST); ctx->n_containers++; } else if(block->type == MD_BLOCK_QUOTE) { /* This causes that any text in a block quote, even if * nested inside a tight list item, is wrapped with *

...

. */ ctx->containers[ctx->n_containers].is_loose = TRUE; ctx->n_containers++; } } } else { MD_CHECK(md_process_leaf_block(ctx, block)); if(block->type == MD_BLOCK_CODE || block->type == MD_BLOCK_HTML) byte_off += block->n_lines * sizeof(MD_VERBATIMLINE); else byte_off += block->n_lines * sizeof(MD_LINE); } byte_off += sizeof(MD_BLOCK); } ctx->n_block_bytes = 0; abort: return ret; } /************************************ *** Grouping Lines into Blocks *** ************************************/ static void* md_push_block_bytes(MD_CTX* ctx, int n_bytes) { void* ptr; if(ctx->n_block_bytes + n_bytes > ctx->alloc_block_bytes) { void* new_block_bytes; ctx->alloc_block_bytes = (ctx->alloc_block_bytes > 0 ? ctx->alloc_block_bytes * 2 : 512); new_block_bytes = realloc(ctx->block_bytes, ctx->alloc_block_bytes); if(new_block_bytes == NULL) { MD_LOG("realloc() failed."); return NULL; } /* Fix the ->current_block after the reallocation. */ if(ctx->current_block != NULL) { OFF off_current_block = (char*) ctx->current_block - (char*) ctx->block_bytes; ctx->current_block = (MD_BLOCK*) ((char*) new_block_bytes + off_current_block); } ctx->block_bytes = new_block_bytes; } ptr = (char*)ctx->block_bytes + ctx->n_block_bytes; ctx->n_block_bytes += n_bytes; return ptr; } static int md_start_new_block(MD_CTX* ctx, const MD_LINE_ANALYSIS* line) { MD_BLOCK* block; MD_ASSERT(ctx->current_block == NULL); block = (MD_BLOCK*) md_push_block_bytes(ctx, sizeof(MD_BLOCK)); if(block == NULL) return -1; switch(line->type) { case MD_LINE_HR: block->type = MD_BLOCK_HR; break; case MD_LINE_ATXHEADER: case MD_LINE_SETEXTHEADER: block->type = MD_BLOCK_H; break; case MD_LINE_FENCEDCODE: case MD_LINE_INDENTEDCODE: block->type = MD_BLOCK_CODE; break; case MD_LINE_TEXT: block->type = MD_BLOCK_P; break; case MD_LINE_HTML: block->type = MD_BLOCK_HTML; break; case MD_LINE_BLANK: case MD_LINE_SETEXTUNDERLINE: case MD_LINE_TABLEUNDERLINE: default: MD_UNREACHABLE(); break; } block->flags = 0; block->data = line->data; block->n_lines = 0; ctx->current_block = block; return 0; } /* Eat from start of current (textual) block any reference definitions and * remember them so we can resolve any links referring to them. * * (Reference definitions can only be at start of it as they cannot break * a paragraph.) */ static int md_consume_link_reference_definitions(MD_CTX* ctx) { MD_LINE* lines = (MD_LINE*) (ctx->current_block + 1); int n_lines = ctx->current_block->n_lines; int n = 0; /* Compute how many lines at the start of the block form one or more * reference definitions. */ while(n < n_lines) { int n_link_ref_lines; n_link_ref_lines = md_is_link_reference_definition(ctx, lines + n, n_lines - n); /* Not a reference definition? */ if(n_link_ref_lines == 0) break; /* We fail if it is the ref. def. but it could not be stored due * a memory allocation error. */ if(n_link_ref_lines < 0) return -1; n += n_link_ref_lines; } /* If there was at least one reference definition, we need to remove * its lines from the block, or perhaps even the whole block. */ if(n > 0) { if(n == n_lines) { /* Remove complete block. */ ctx->n_block_bytes -= n * sizeof(MD_LINE); ctx->n_block_bytes -= sizeof(MD_BLOCK); ctx->current_block = NULL; } else { /* Remove just some initial lines from the block. */ memmove(lines, lines + n, (n_lines - n) * sizeof(MD_LINE)); ctx->current_block->n_lines -= n; ctx->n_block_bytes -= n * sizeof(MD_LINE); } } return 0; } static int md_end_current_block(MD_CTX* ctx) { int ret = 0; if(ctx->current_block == NULL) return ret; /* Check whether there is a reference definition. (We do this here instead * of in md_analyze_line() because reference definition can take multiple * lines.) */ if(ctx->current_block->type == MD_BLOCK_P || (ctx->current_block->type == MD_BLOCK_H && (ctx->current_block->flags & MD_BLOCK_SETEXT_HEADER))) { MD_LINE* lines = (MD_LINE*) (ctx->current_block + 1); if(CH(lines[0].beg) == _T('[')) { MD_CHECK(md_consume_link_reference_definitions(ctx)); if(ctx->current_block == NULL) return ret; } } if(ctx->current_block->type == MD_BLOCK_H && (ctx->current_block->flags & MD_BLOCK_SETEXT_HEADER)) { int n_lines = ctx->current_block->n_lines; if(n_lines > 1) { /* Get rid of the underline. */ ctx->current_block->n_lines--; ctx->n_block_bytes -= sizeof(MD_LINE); } else { /* Only the underline has left after eating the ref. defs. * Keep the line as beginning of a new ordinary paragraph. */ ctx->current_block->type = MD_BLOCK_P; return 0; } } /* Mark we are not building any block anymore. */ ctx->current_block = NULL; abort: return ret; } static int md_add_line_into_current_block(MD_CTX* ctx, const MD_LINE_ANALYSIS* analysis) { MD_ASSERT(ctx->current_block != NULL); if(ctx->current_block->type == MD_BLOCK_CODE || ctx->current_block->type == MD_BLOCK_HTML) { MD_VERBATIMLINE* line; line = (MD_VERBATIMLINE*) md_push_block_bytes(ctx, sizeof(MD_VERBATIMLINE)); if(line == NULL) return -1; line->indent = analysis->indent; line->beg = analysis->beg; line->end = analysis->end; } else { MD_LINE* line; line = (MD_LINE*) md_push_block_bytes(ctx, sizeof(MD_LINE)); if(line == NULL) return -1; line->beg = analysis->beg; line->end = analysis->end; } ctx->current_block->n_lines++; return 0; } static int md_push_container_bytes(MD_CTX* ctx, MD_BLOCKTYPE type, unsigned start, unsigned data, unsigned flags) { MD_BLOCK* block; int ret = 0; MD_CHECK(md_end_current_block(ctx)); block = (MD_BLOCK*) md_push_block_bytes(ctx, sizeof(MD_BLOCK)); if(block == NULL) return -1; block->type = type; block->flags = flags; block->data = data; block->n_lines = start; abort: return ret; } /*********************** *** Line Analysis *** ***********************/ static int md_is_hr_line(MD_CTX* ctx, OFF beg, OFF* p_end, OFF* p_killer) { OFF off = beg + 1; int n = 1; while(off < ctx->size && (CH(off) == CH(beg) || CH(off) == _T(' ') || CH(off) == _T('\t'))) { if(CH(off) == CH(beg)) n++; off++; } if(n < 3) { *p_killer = off; return FALSE; } /* Nothing else can be present on the line. */ if(off < ctx->size && !ISNEWLINE(off)) { *p_killer = off; return FALSE; } *p_end = off; return TRUE; } static int md_is_atxheader_line(MD_CTX* ctx, OFF beg, OFF* p_beg, OFF* p_end, unsigned* p_level) { int n; OFF off = beg + 1; while(off < ctx->size && CH(off) == _T('#') && off - beg < 7) off++; n = off - beg; if(n > 6) return FALSE; *p_level = n; if(!(ctx->parser.flags & MD_FLAG_PERMISSIVEATXHEADERS) && off < ctx->size && CH(off) != _T(' ') && CH(off) != _T('\t') && !ISNEWLINE(off)) return FALSE; while(off < ctx->size && CH(off) == _T(' ')) off++; *p_beg = off; *p_end = off; return TRUE; } static int md_is_setext_underline(MD_CTX* ctx, OFF beg, OFF* p_end, unsigned* p_level) { OFF off = beg + 1; while(off < ctx->size && CH(off) == CH(beg)) off++; /* Optionally, space(s) can follow. */ while(off < ctx->size && CH(off) == _T(' ')) off++; /* But nothing more is allowed on the line. */ if(off < ctx->size && !ISNEWLINE(off)) return FALSE; *p_level = (CH(beg) == _T('=') ? 1 : 2); *p_end = off; return TRUE; } static int md_is_table_underline(MD_CTX* ctx, OFF beg, OFF* p_end, unsigned* p_col_count) { OFF off = beg; int found_pipe = FALSE; unsigned col_count = 0; if(off < ctx->size && CH(off) == _T('|')) { found_pipe = TRUE; off++; while(off < ctx->size && ISWHITESPACE(off)) off++; } while(1) { OFF cell_beg; int delimited = FALSE; /* Cell underline ("-----", ":----", "----:" or ":----:") */ cell_beg = off; if(off < ctx->size && CH(off) == _T(':')) off++; while(off < ctx->size && CH(off) == _T('-')) off++; if(off < ctx->size && CH(off) == _T(':')) off++; if(off - cell_beg < 3) return FALSE; col_count++; /* Pipe delimiter (optional at the end of line). */ while(off < ctx->size && ISWHITESPACE(off)) off++; if(off < ctx->size && CH(off) == _T('|')) { delimited = TRUE; found_pipe = TRUE; off++; while(off < ctx->size && ISWHITESPACE(off)) off++; } /* Success, if we reach end of line. */ if(off >= ctx->size || ISNEWLINE(off)) break; if(!delimited) return FALSE; } if(!found_pipe) return FALSE; *p_end = off; *p_col_count = col_count; return TRUE; } static int md_is_opening_code_fence(MD_CTX* ctx, OFF beg, OFF* p_end) { OFF off = beg; while(off < ctx->size && CH(off) == CH(beg)) off++; /* Fence must have at least three characters. */ if(off - beg < 3) return FALSE; ctx->code_fence_length = off - beg; /* Optionally, space(s) can follow. */ while(off < ctx->size && CH(off) == _T(' ')) off++; /* Optionally, an info string can follow. */ while(off < ctx->size && !ISNEWLINE(off)) { /* Backtick-based fence must not contain '`' in the info string. */ if(CH(beg) == _T('`') && CH(off) == _T('`')) return FALSE; off++; } *p_end = off; return TRUE; } static int md_is_closing_code_fence(MD_CTX* ctx, CHAR ch, OFF beg, OFF* p_end) { OFF off = beg; int ret = FALSE; /* Closing fence must have at least the same length and use same char as * opening one. */ while(off < ctx->size && CH(off) == ch) off++; if(off - beg < ctx->code_fence_length) goto out; /* Optionally, space(s) can follow */ while(off < ctx->size && CH(off) == _T(' ')) off++; /* But nothing more is allowed on the line. */ if(off < ctx->size && !ISNEWLINE(off)) goto out; ret = TRUE; out: /* Note we set *p_end even on failure: If we are not closing fence, caller * would eat the line anyway without any parsing. */ *p_end = off; return ret; } /* Returns type of the raw HTML block, or FALSE if it is not HTML block. * (Refer to CommonMark specification for details about the types.) */ static int md_is_html_block_start_condition(MD_CTX* ctx, OFF beg) { typedef struct TAG_tag TAG; struct TAG_tag { const CHAR* name; unsigned len : 8; }; /* Type 6 is started by a long list of allowed tags. We use two-level * tree to speed-up the search. */ #ifdef X #undef X #endif #define X(name) { _T(name), sizeof(name)-1 } #define Xend { NULL, 0 } static const TAG t1[] = { X("script"), X("pre"), X("style"), Xend }; static const TAG a6[] = { X("address"), X("article"), X("aside"), Xend }; static const TAG b6[] = { X("base"), X("basefont"), X("blockquote"), X("body"), Xend }; static const TAG c6[] = { X("caption"), X("center"), X("col"), X("colgroup"), Xend }; static const TAG d6[] = { X("dd"), X("details"), X("dialog"), X("dir"), X("div"), X("dl"), X("dt"), Xend }; static const TAG f6[] = { X("fieldset"), X("figcaption"), X("figure"), X("footer"), X("form"), X("frame"), X("frameset"), Xend }; static const TAG h6[] = { X("h1"), X("head"), X("header"), X("hr"), X("html"), Xend }; static const TAG i6[] = { X("iframe"), Xend }; static const TAG l6[] = { X("legend"), X("li"), X("link"), Xend }; static const TAG m6[] = { X("main"), X("menu"), X("menuitem"), Xend }; static const TAG n6[] = { X("nav"), X("noframes"), Xend }; static const TAG o6[] = { X("ol"), X("optgroup"), X("option"), Xend }; static const TAG p6[] = { X("p"), X("param"), Xend }; static const TAG s6[] = { X("section"), X("source"), X("summary"), Xend }; static const TAG t6[] = { X("table"), X("tbody"), X("td"), X("tfoot"), X("th"), X("thead"), X("title"), X("tr"), X("track"), Xend }; static const TAG u6[] = { X("ul"), Xend }; static const TAG xx[] = { Xend }; #undef X static const TAG* map6[26] = { a6, b6, c6, d6, xx, f6, xx, h6, i6, xx, xx, l6, m6, n6, o6, p6, xx, xx, s6, t6, u6, xx, xx, xx, xx, xx }; OFF off = beg + 1; int i; /* Check for type 1: size) { if(md_ascii_case_eq(STR(off), t1[i].name, t1[i].len)) return 1; } } /* Check for type 2: "), 3, p_end) ? 2 : FALSE); case 3: return (md_line_contains(ctx, beg, _T("?>"), 2, p_end) ? 3 : FALSE); case 4: return (md_line_contains(ctx, beg, _T(">"), 1, p_end) ? 4 : FALSE); case 5: return (md_line_contains(ctx, beg, _T("]]>"), 3, p_end) ? 5 : FALSE); case 6: /* Pass through */ case 7: *p_end = beg; return (ISNEWLINE(beg) ? ctx->html_block_type : FALSE); default: MD_UNREACHABLE(); } return FALSE; } static int md_is_container_compatible(const MD_CONTAINER* pivot, const MD_CONTAINER* container) { /* Block quote has no "items" like lists. */ if(container->ch == _T('>')) return FALSE; if(container->ch != pivot->ch) return FALSE; if(container->mark_indent > pivot->contents_indent) return FALSE; return TRUE; } static int md_push_container(MD_CTX* ctx, const MD_CONTAINER* container) { if(ctx->n_containers >= ctx->alloc_containers) { MD_CONTAINER* new_containers; ctx->alloc_containers = (ctx->alloc_containers > 0 ? ctx->alloc_containers * 2 : 16); new_containers = realloc(ctx->containers, ctx->alloc_containers * sizeof(MD_CONTAINER)); if(new_containers == NULL) { MD_LOG("realloc() failed."); return -1; } ctx->containers = new_containers; } memcpy(&ctx->containers[ctx->n_containers++], container, sizeof(MD_CONTAINER)); return 0; } static int md_enter_child_containers(MD_CTX* ctx, int n_children, unsigned data) { int i; int ret = 0; for(i = ctx->n_containers - n_children; i < ctx->n_containers; i++) { MD_CONTAINER* c = &ctx->containers[i]; int is_ordered_list = FALSE; switch(c->ch) { case _T(')'): case _T('.'): is_ordered_list = TRUE; /* Pass through */ case _T('-'): case _T('+'): case _T('*'): /* Remember offset in ctx->block_bytes so we can revisit the * block if we detect it is a loose list. */ md_end_current_block(ctx); c->block_byte_off = ctx->n_block_bytes; MD_CHECK(md_push_container_bytes(ctx, (is_ordered_list ? MD_BLOCK_OL : MD_BLOCK_UL), c->start, data, MD_BLOCK_CONTAINER_OPENER)); MD_CHECK(md_push_container_bytes(ctx, MD_BLOCK_LI, c->task_mark_off, (c->is_task ? CH(c->task_mark_off) : 0), MD_BLOCK_CONTAINER_OPENER)); break; case _T('>'): MD_CHECK(md_push_container_bytes(ctx, MD_BLOCK_QUOTE, 0, 0, MD_BLOCK_CONTAINER_OPENER)); break; default: MD_UNREACHABLE(); break; } } abort: return ret; } static int md_leave_child_containers(MD_CTX* ctx, int n_keep) { int ret = 0; while(ctx->n_containers > n_keep) { MD_CONTAINER* c = &ctx->containers[ctx->n_containers-1]; int is_ordered_list = FALSE; switch(c->ch) { case _T(')'): case _T('.'): is_ordered_list = TRUE; /* Pass through */ case _T('-'): case _T('+'): case _T('*'): MD_CHECK(md_push_container_bytes(ctx, MD_BLOCK_LI, c->task_mark_off, (c->is_task ? CH(c->task_mark_off) : 0), MD_BLOCK_CONTAINER_CLOSER)); MD_CHECK(md_push_container_bytes(ctx, (is_ordered_list ? MD_BLOCK_OL : MD_BLOCK_UL), 0, c->ch, MD_BLOCK_CONTAINER_CLOSER)); break; case _T('>'): MD_CHECK(md_push_container_bytes(ctx, MD_BLOCK_QUOTE, 0, 0, MD_BLOCK_CONTAINER_CLOSER)); break; default: MD_UNREACHABLE(); break; } ctx->n_containers--; } abort: return ret; } static int md_is_container_mark(MD_CTX* ctx, unsigned indent, OFF beg, OFF* p_end, MD_CONTAINER* p_container) { OFF off = beg; OFF max_end; if(indent >= ctx->code_indent_offset) return FALSE; /* Check for block quote mark. */ if(off < ctx->size && CH(off) == _T('>')) { off++; p_container->ch = _T('>'); p_container->is_loose = FALSE; p_container->is_task = FALSE; p_container->mark_indent = indent; p_container->contents_indent = indent + 1; *p_end = off; return TRUE; } /* Check for list item bullet mark. */ if(off+1 < ctx->size && ISANYOF(off, _T("-+*")) && (ISBLANK(off+1) || ISNEWLINE(off+1))) { p_container->ch = CH(off); p_container->is_loose = FALSE; p_container->is_task = FALSE; p_container->mark_indent = indent; p_container->contents_indent = indent + 1; *p_end = off + 1; return TRUE; } /* Check for ordered list item marks. */ max_end = off + 9; if(max_end > ctx->size) max_end = ctx->size; p_container->start = 0; while(off < max_end && ISDIGIT(off)) { p_container->start = p_container->start * 10 + CH(off) - _T('0'); off++; } if(off > beg && off+1 < ctx->size && (CH(off) == _T('.') || CH(off) == _T(')')) && (ISBLANK(off+1) || ISNEWLINE(off+1))) { p_container->ch = CH(off); p_container->is_loose = FALSE; p_container->is_task = FALSE; p_container->mark_indent = indent; p_container->contents_indent = indent + off - beg + 1; *p_end = off + 1; return TRUE; } return FALSE; } static unsigned md_line_indentation(MD_CTX* ctx, unsigned total_indent, OFF beg, OFF* p_end) { OFF off = beg; unsigned indent = total_indent; while(off < ctx->size && ISBLANK(off)) { if(CH(off) == _T('\t')) indent = (indent + 4) & ~3; else indent++; off++; } *p_end = off; return indent - total_indent; } static const MD_LINE_ANALYSIS md_dummy_blank_line = { MD_LINE_BLANK, 0 }; /* Analyze type of the line and find some its properties. This serves as a * main input for determining type and boundaries of a block. */ static int md_analyze_line(MD_CTX* ctx, OFF beg, OFF* p_end, const MD_LINE_ANALYSIS* pivot_line, MD_LINE_ANALYSIS* line) { unsigned total_indent = 0; int n_parents = 0; int n_brothers = 0; int n_children = 0; MD_CONTAINER container = { 0 }; int prev_line_has_list_loosening_effect = ctx->last_line_has_list_loosening_effect; OFF off = beg; OFF hr_killer = 0; int ret = 0; line->indent = md_line_indentation(ctx, total_indent, off, &off); total_indent += line->indent; line->beg = off; /* Given the indentation and block quote marks '>', determine how many of * the current containers are our parents. */ while(n_parents < ctx->n_containers) { MD_CONTAINER* c = &ctx->containers[n_parents]; if(c->ch == _T('>') && line->indent < ctx->code_indent_offset && off < ctx->size && CH(off) == _T('>')) { /* Block quote mark. */ off++; total_indent++; line->indent = md_line_indentation(ctx, total_indent, off, &off); total_indent += line->indent; /* The optional 1st space after '>' is part of the block quote mark. */ if(line->indent > 0) line->indent--; line->beg = off; } else if(c->ch != _T('>') && line->indent >= c->contents_indent) { /* List. */ line->indent -= c->contents_indent; } else { break; } n_parents++; } if(off >= ctx->size || ISNEWLINE(off)) { /* Blank line does not need any real indentation to be nested inside * a list. */ if(n_brothers + n_children == 0) { while(n_parents < ctx->n_containers && ctx->containers[n_parents].ch != _T('>')) n_parents++; } } while(TRUE) { /* Check whether we are fenced code continuation. */ if(pivot_line->type == MD_LINE_FENCEDCODE) { line->beg = off; /* We are another MD_LINE_FENCEDCODE unless we are closing fence * which we transform into MD_LINE_BLANK. */ if(line->indent < ctx->code_indent_offset) { if(md_is_closing_code_fence(ctx, CH(pivot_line->beg), off, &off)) { line->type = MD_LINE_BLANK; ctx->last_line_has_list_loosening_effect = FALSE; break; } } /* Change indentation accordingly to the initial code fence. */ if(n_parents == ctx->n_containers) { if(line->indent > pivot_line->indent) line->indent -= pivot_line->indent; else line->indent = 0; line->type = MD_LINE_FENCEDCODE; break; } } /* Check whether we are HTML block continuation. */ if(pivot_line->type == MD_LINE_HTML && ctx->html_block_type > 0) { int html_block_type; html_block_type = md_is_html_block_end_condition(ctx, off, &off); if(html_block_type > 0) { MD_ASSERT(html_block_type == ctx->html_block_type); /* Make sure this is the last line of the block. */ ctx->html_block_type = 0; /* Some end conditions serve as blank lines at the same time. */ if(html_block_type == 6 || html_block_type == 7) { line->type = MD_LINE_BLANK; line->indent = 0; break; } } if(n_parents == ctx->n_containers) { line->type = MD_LINE_HTML; break; } } /* Check for blank line. */ if(off >= ctx->size || ISNEWLINE(off)) { if(pivot_line->type == MD_LINE_INDENTEDCODE && n_parents == ctx->n_containers) { line->type = MD_LINE_INDENTEDCODE; if(line->indent > ctx->code_indent_offset) line->indent -= ctx->code_indent_offset; else line->indent = 0; ctx->last_line_has_list_loosening_effect = FALSE; } else { line->type = MD_LINE_BLANK; ctx->last_line_has_list_loosening_effect = (n_parents > 0 && n_brothers + n_children == 0 && ctx->containers[n_parents-1].ch != _T('>')); #if 1 /* See https://github.com/mity/md4c/issues/6 * * This ugly checking tests we are in (yet empty) list item but not * its very first line (with the list item mark). * * If we are such blank line, then any following non-blank line * which would be part of this list item actually ends the list * because "a list item can begin with at most one blank line." */ if(n_parents > 0 && ctx->containers[n_parents-1].ch != _T('>') && n_brothers + n_children == 0 && ctx->current_block == NULL && ctx->n_block_bytes > (int) sizeof(MD_BLOCK)) { MD_BLOCK* top_block = (MD_BLOCK*) ((char*)ctx->block_bytes + ctx->n_block_bytes - sizeof(MD_BLOCK)); if(top_block->type == MD_BLOCK_LI) ctx->last_list_item_starts_with_two_blank_lines = TRUE; } #endif } break; } else { #if 1 /* This is 2nd half of the hack. If the flag is set (that is there * were 2nd blank line at the start of the list item) and we would also * belonging to such list item, then interrupt the list. */ ctx->last_line_has_list_loosening_effect = FALSE; if(ctx->last_list_item_starts_with_two_blank_lines) { if(n_parents > 0 && ctx->containers[n_parents-1].ch != _T('>') && n_brothers + n_children == 0 && ctx->current_block == NULL && ctx->n_block_bytes > (int) sizeof(MD_BLOCK)) { MD_BLOCK* top_block = (MD_BLOCK*) ((char*)ctx->block_bytes + ctx->n_block_bytes - sizeof(MD_BLOCK)); if(top_block->type == MD_BLOCK_LI) n_parents--; } ctx->last_list_item_starts_with_two_blank_lines = FALSE; } #endif } /* Check whether we are Setext underline. */ if(line->indent < ctx->code_indent_offset && pivot_line->type == MD_LINE_TEXT && (CH(off) == _T('=') || CH(off) == _T('-')) && (n_parents == ctx->n_containers)) { unsigned level; if(md_is_setext_underline(ctx, off, &off, &level)) { line->type = MD_LINE_SETEXTUNDERLINE; line->data = level; break; } } /* Check for thematic break line. */ if(line->indent < ctx->code_indent_offset && ISANYOF(off, _T("-_*")) && off >= hr_killer) { if(md_is_hr_line(ctx, off, &off, &hr_killer)) { line->type = MD_LINE_HR; break; } } /* Check for "brother" container. I.e. whether we are another list item * in already started list. */ if(n_parents < ctx->n_containers && n_brothers + n_children == 0) { OFF tmp; if(md_is_container_mark(ctx, line->indent, off, &tmp, &container) && md_is_container_compatible(&ctx->containers[n_parents], &container)) { pivot_line = &md_dummy_blank_line; off = tmp; total_indent += container.contents_indent - container.mark_indent; line->indent = md_line_indentation(ctx, total_indent, off, &off); total_indent += line->indent; line->beg = off; /* Some of the following whitespace actually still belongs to the mark. */ if(off >= ctx->size || ISNEWLINE(off)) { container.contents_indent++; } else if(line->indent <= ctx->code_indent_offset) { container.contents_indent += line->indent; line->indent = 0; } else { container.contents_indent += 1; line->indent--; } ctx->containers[n_parents].mark_indent = container.mark_indent; ctx->containers[n_parents].contents_indent = container.contents_indent; n_brothers++; continue; } } /* Check for indented code. * Note indented code block cannot interrupt a paragraph. */ if(line->indent >= ctx->code_indent_offset && (pivot_line->type == MD_LINE_BLANK || pivot_line->type == MD_LINE_INDENTEDCODE)) { line->type = MD_LINE_INDENTEDCODE; MD_ASSERT(line->indent >= ctx->code_indent_offset); line->indent -= ctx->code_indent_offset; line->data = 0; break; } /* Check for start of a new container block. */ if(line->indent < ctx->code_indent_offset && md_is_container_mark(ctx, line->indent, off, &off, &container)) { if(pivot_line->type == MD_LINE_TEXT && n_parents == ctx->n_containers && (off >= ctx->size || ISNEWLINE(off)) && container.ch != _T('>')) { /* Noop. List mark followed by a blank line cannot interrupt a paragraph. */ } else if(pivot_line->type == MD_LINE_TEXT && n_parents == ctx->n_containers && (container.ch == _T('.') || container.ch == _T(')')) && container.start != 1) { /* Noop. Ordered list cannot interrupt a paragraph unless the start index is 1. */ } else { total_indent += container.contents_indent - container.mark_indent; line->indent = md_line_indentation(ctx, total_indent, off, &off); total_indent += line->indent; line->beg = off; line->data = container.ch; /* Some of the following whitespace actually still belongs to the mark. */ if(off >= ctx->size || ISNEWLINE(off)) { container.contents_indent++; } else if(line->indent <= ctx->code_indent_offset) { container.contents_indent += line->indent; line->indent = 0; } else { container.contents_indent += 1; line->indent--; } if(n_brothers + n_children == 0) pivot_line = &md_dummy_blank_line; if(n_children == 0) MD_CHECK(md_leave_child_containers(ctx, n_parents + n_brothers)); n_children++; MD_CHECK(md_push_container(ctx, &container)); continue; } } /* Check whether we are table continuation. */ if(pivot_line->type == MD_LINE_TABLE && md_is_table_row(ctx, off, &off) && n_parents == ctx->n_containers) { line->type = MD_LINE_TABLE; break; } /* Check for ATX header. */ if(line->indent < ctx->code_indent_offset && CH(off) == _T('#')) { unsigned level; if(md_is_atxheader_line(ctx, off, &line->beg, &off, &level)) { line->type = MD_LINE_ATXHEADER; line->data = level; break; } } /* Check whether we are starting code fence. */ if(CH(off) == _T('`') || CH(off) == _T('~')) { if(md_is_opening_code_fence(ctx, off, &off)) { line->type = MD_LINE_FENCEDCODE; line->data = 1; break; } } /* Check for start of raw HTML block. */ if(CH(off) == _T('<') && !(ctx->parser.flags & MD_FLAG_NOHTMLBLOCKS)) { ctx->html_block_type = md_is_html_block_start_condition(ctx, off); /* HTML block type 7 cannot interrupt paragraph. */ if(ctx->html_block_type == 7 && pivot_line->type == MD_LINE_TEXT) ctx->html_block_type = 0; if(ctx->html_block_type > 0) { /* The line itself also may immediately close the block. */ if(md_is_html_block_end_condition(ctx, off, &off) == ctx->html_block_type) { /* Make sure this is the last line of the block. */ ctx->html_block_type = 0; } line->type = MD_LINE_HTML; break; } } /* Check for table underline. */ if((ctx->parser.flags & MD_FLAG_TABLES) && pivot_line->type == MD_LINE_TEXT && (CH(off) == _T('|') || CH(off) == _T('-') || CH(off) == _T(':')) && n_parents == ctx->n_containers) { unsigned col_count; if(ctx->current_block != NULL && ctx->current_block->n_lines == 1 && md_is_table_underline(ctx, off, &off, &col_count) && md_is_table_row(ctx, pivot_line->beg, NULL)) { line->data = col_count; line->type = MD_LINE_TABLEUNDERLINE; break; } } /* By default, we are normal text line. */ line->type = MD_LINE_TEXT; if(pivot_line->type == MD_LINE_TEXT && n_brothers + n_children == 0) { /* Lazy continuation. */ n_parents = ctx->n_containers; } /* Check for task mark. */ if((ctx->parser.flags & MD_FLAG_TASKLISTS) && n_brothers + n_children > 0 && ISANYOF_(ctx->containers[ctx->n_containers-1].ch, _T("-+*.)"))) { OFF tmp = off; while(tmp < ctx->size && tmp < off + 3 && ISBLANK(tmp)) tmp++; if(tmp + 2 < ctx->size && CH(tmp) == _T('[') && ISANYOF(tmp+1, _T("xX ")) && CH(tmp+2) == _T(']') && (tmp + 3 == ctx->size || ISBLANK(tmp+3) || ISNEWLINE(tmp+3))) { MD_CONTAINER* task_container = (n_children > 0 ? &ctx->containers[ctx->n_containers-1] : &container); task_container->is_task = TRUE; task_container->task_mark_off = tmp + 1; off = tmp + 3; while(ISWHITESPACE(off)) off++; line->beg = off; } } break; } /* Scan for end of the line. * * Note this is quite a bottleneck of the parsing as we here iterate almost * over compete document. */ #if defined __linux__ && !defined MD4C_USE_UTF16 /* Recent glibc versions have superbly optimized strcspn(), even using * vectorization if available. */ if(ctx->doc_ends_with_newline && off < ctx->size) { while(TRUE) { off += (OFF) strcspn(STR(off), "\r\n"); /* strcspn() can stop on zero terminator; but that can appear * anywhere in the Markfown input... */ if(CH(off) == _T('\0')) off++; else break; } } else #endif { /* Optimization: Use some loop unrolling. */ while(off + 3 < ctx->size && !ISNEWLINE(off+0) && !ISNEWLINE(off+1) && !ISNEWLINE(off+2) && !ISNEWLINE(off+3)) off += 4; while(off < ctx->size && !ISNEWLINE(off)) off++; } /* Set end of the line. */ line->end = off; /* But for ATX header, we should exclude the optional trailing mark. */ if(line->type == MD_LINE_ATXHEADER) { OFF tmp = line->end; while(tmp > line->beg && CH(tmp-1) == _T(' ')) tmp--; while(tmp > line->beg && CH(tmp-1) == _T('#')) tmp--; if(tmp == line->beg || CH(tmp-1) == _T(' ') || (ctx->parser.flags & MD_FLAG_PERMISSIVEATXHEADERS)) line->end = tmp; } /* Trim trailing spaces. */ if(line->type != MD_LINE_INDENTEDCODE && line->type != MD_LINE_FENCEDCODE) { while(line->end > line->beg && CH(line->end-1) == _T(' ')) line->end--; } /* Eat also the new line. */ if(off < ctx->size && CH(off) == _T('\r')) off++; if(off < ctx->size && CH(off) == _T('\n')) off++; *p_end = off; /* If we belong to a list after seeing a blank line, the list is loose. */ if(prev_line_has_list_loosening_effect && line->type != MD_LINE_BLANK && n_parents + n_brothers > 0) { MD_CONTAINER* c = &ctx->containers[n_parents + n_brothers - 1]; if(c->ch != _T('>')) { MD_BLOCK* block = (MD_BLOCK*) (((char*)ctx->block_bytes) + c->block_byte_off); block->flags |= MD_BLOCK_LOOSE_LIST; } } /* Leave any containers we are not part of anymore. */ if(n_children == 0 && n_parents + n_brothers < ctx->n_containers) MD_CHECK(md_leave_child_containers(ctx, n_parents + n_brothers)); /* Enter any container we found a mark for. */ if(n_brothers > 0) { MD_ASSERT(n_brothers == 1); MD_CHECK(md_push_container_bytes(ctx, MD_BLOCK_LI, ctx->containers[n_parents].task_mark_off, (ctx->containers[n_parents].is_task ? CH(ctx->containers[n_parents].task_mark_off) : 0), MD_BLOCK_CONTAINER_CLOSER)); MD_CHECK(md_push_container_bytes(ctx, MD_BLOCK_LI, container.task_mark_off, (container.is_task ? CH(container.task_mark_off) : 0), MD_BLOCK_CONTAINER_OPENER)); ctx->containers[n_parents].is_task = container.is_task; ctx->containers[n_parents].task_mark_off = container.task_mark_off; } if(n_children > 0) MD_CHECK(md_enter_child_containers(ctx, n_children, line->data)); abort: return ret; } static int md_process_line(MD_CTX* ctx, const MD_LINE_ANALYSIS** p_pivot_line, MD_LINE_ANALYSIS* line) { const MD_LINE_ANALYSIS* pivot_line = *p_pivot_line; int ret = 0; /* Blank line ends current leaf block. */ if(line->type == MD_LINE_BLANK) { MD_CHECK(md_end_current_block(ctx)); *p_pivot_line = &md_dummy_blank_line; return 0; } /* Some line types form block on their own. */ if(line->type == MD_LINE_HR || line->type == MD_LINE_ATXHEADER) { MD_CHECK(md_end_current_block(ctx)); /* Add our single-line block. */ MD_CHECK(md_start_new_block(ctx, line)); MD_CHECK(md_add_line_into_current_block(ctx, line)); MD_CHECK(md_end_current_block(ctx)); *p_pivot_line = &md_dummy_blank_line; return 0; } /* MD_LINE_SETEXTUNDERLINE changes meaning of the current block and ends it. */ if(line->type == MD_LINE_SETEXTUNDERLINE) { MD_ASSERT(ctx->current_block != NULL); ctx->current_block->type = MD_BLOCK_H; ctx->current_block->data = line->data; ctx->current_block->flags |= MD_BLOCK_SETEXT_HEADER; MD_CHECK(md_add_line_into_current_block(ctx, line)); MD_CHECK(md_end_current_block(ctx)); if(ctx->current_block == NULL) { *p_pivot_line = &md_dummy_blank_line; } else { /* This happens if we have consumed all the body as link ref. defs. * and downgraded the underline into start of a new paragraph block. */ line->type = MD_LINE_TEXT; *p_pivot_line = line; } return 0; } /* MD_LINE_TABLEUNDERLINE changes meaning of the current block. */ if(line->type == MD_LINE_TABLEUNDERLINE) { MD_ASSERT(ctx->current_block != NULL); MD_ASSERT(ctx->current_block->n_lines == 1); ctx->current_block->type = MD_BLOCK_TABLE; ctx->current_block->data = line->data; MD_ASSERT(pivot_line != &md_dummy_blank_line); ((MD_LINE_ANALYSIS*)pivot_line)->type = MD_LINE_TABLE; MD_CHECK(md_add_line_into_current_block(ctx, line)); return 0; } /* The current block also ends if the line has different type. */ if(line->type != pivot_line->type) MD_CHECK(md_end_current_block(ctx)); /* The current line may start a new block. */ if(ctx->current_block == NULL) { MD_CHECK(md_start_new_block(ctx, line)); *p_pivot_line = line; } /* In all other cases the line is just a continuation of the current block. */ MD_CHECK(md_add_line_into_current_block(ctx, line)); abort: return ret; } static int md_process_doc(MD_CTX *ctx) { const MD_LINE_ANALYSIS* pivot_line = &md_dummy_blank_line; MD_LINE_ANALYSIS line_buf[2]; MD_LINE_ANALYSIS* line = &line_buf[0]; OFF off = 0; int ret = 0; MD_ENTER_BLOCK(MD_BLOCK_DOC, NULL); while(off < ctx->size) { if(line == pivot_line) line = (line == &line_buf[0] ? &line_buf[1] : &line_buf[0]); MD_CHECK(md_analyze_line(ctx, off, &off, pivot_line, line)); MD_CHECK(md_process_line(ctx, &pivot_line, line)); } md_end_current_block(ctx); MD_CHECK(md_build_ref_def_hashtable(ctx)); /* Process all blocks. */ MD_CHECK(md_leave_child_containers(ctx, 0)); MD_CHECK(md_process_all_blocks(ctx)); MD_LEAVE_BLOCK(MD_BLOCK_DOC, NULL); abort: #if 0 /* Output some memory consumption statistics. */ { char buffer[256]; sprintf(buffer, "Alloced %u bytes for block buffer.", (unsigned)(ctx->alloc_block_bytes)); MD_LOG(buffer); sprintf(buffer, "Alloced %u bytes for containers buffer.", (unsigned)(ctx->alloc_containers * sizeof(MD_CONTAINER))); MD_LOG(buffer); sprintf(buffer, "Alloced %u bytes for marks buffer.", (unsigned)(ctx->alloc_marks * sizeof(MD_MARK))); MD_LOG(buffer); sprintf(buffer, "Alloced %u bytes for aux. buffer.", (unsigned)(ctx->alloc_buffer * sizeof(MD_CHAR))); MD_LOG(buffer); } #endif return ret; } /******************** *** Public API *** ********************/ int md_parse(const MD_CHAR* text, MD_SIZE size, const MD_PARSER* parser, void* userdata) { MD_CTX ctx; int i; int ret; if(parser->abi_version != 0) { if(parser->debug_log != NULL) parser->debug_log("Unsupported abi_version.", userdata); return -1; } /* Setup context structure. */ memset(&ctx, 0, sizeof(MD_CTX)); ctx.text = text; ctx.size = size; memcpy(&ctx.parser, parser, sizeof(MD_PARSER)); ctx.userdata = userdata; ctx.code_indent_offset = (ctx.parser.flags & MD_FLAG_NOINDENTEDCODEBLOCKS) ? (OFF)(-1) : 4; md_build_mark_char_map(&ctx); ctx.doc_ends_with_newline = (size > 0 && ISNEWLINE_(text[size-1])); /* Reset all unresolved opener mark chains. */ for(i = 0; i < (int) SIZEOF_ARRAY(ctx.mark_chains); i++) { ctx.mark_chains[i].head = -1; ctx.mark_chains[i].tail = -1; } ctx.unresolved_link_head = -1; ctx.unresolved_link_tail = -1; /* All the work. */ ret = md_process_doc(&ctx); /* Clean-up. */ md_free_ref_defs(&ctx); md_free_ref_def_hashtable(&ctx); free(ctx.buffer); free(ctx.marks); free(ctx.block_bytes); free(ctx.containers); return ret; }