/* * * Mini regex-module inspired by Rob Pike's regex code described in: * * http://www.cs.princeton.edu/courses/archive/spr09/cos333/beautiful.html * * * * Supports: * --------- * '.' Dot, matches any character * '^' Start anchor, matches beginning of string * '$' End anchor, matches end of string * '*' Asterisk, match zero or more (greedy) * '+' Plus, match one or more (greedy) * '?' Question, match zero or one (non-greedy) * '[abc]' Character class, match if one of {'a', 'b', 'c'} * '[^abc]' Inverted class, match if NOT one of {'a', 'b', 'c'} -- NOTE: feature is currently broken! * '[a-zA-Z]' Character ranges, the character set of the ranges { a-z | A-Z } * '\s' Whitespace, \t \f \r \n \v and spaces * '\S' Non-whitespace * '\w' Alphanumeric, [a-zA-Z0-9_] * '\W' Non-alphanumeric * '\d' Digits, [0-9] * '\D' Non-digits * * */ #include "re.h" #include #include /* Private function declarations: */ static int matchpattern(regex_t* pattern, const char* text, int* matchlength); static int matchcharclass(char c, const char* str); static int matchstar(regex_t p, regex_t* pattern, const char* text, int* matchlength); static int matchplus(regex_t p, regex_t* pattern, const char* text, int* matchlength); static int matchone(regex_t p, char c); static int matchdigit(char c); static int matchalpha(char c); static int matchwhitespace(char c); static int matchmetachar(char c, const char* str); static int matchrange(char c, const char* str); static int matchdot(char c); static int ismetachar(char c); /* Public functions: */ int re_match(const char* pattern, const char* text, int* matchlength) { return re_matchp(re_compile(pattern), text, matchlength); } int re_matchp(re_t pattern, const char* text, int* matchlength) { int matchlength_; if(NULL == matchlength) { matchlength = &matchlength_; } *matchlength = 0; if (pattern != 0) { if (pattern[0].type == BEGIN) { return ((matchpattern(&pattern[1], text, matchlength)) ? 0 : -1); } else { int idx = -1; do { idx += 1; if (matchpattern(pattern, text, matchlength)) { if (text[0] == '\0') return -1; return idx; } } while (*text++ != '\0'); } } return -1; } re_t re_compile(const char* pattern) { /* The sizes of the two static arrays below substantiates the static RAM usage of this module. MAX_REGEXP_OBJECTS is the max number of symbols in the expression. MAX_CHAR_CLASS_LEN determines the size of buffer for chars in all char-classes in the expression. */ static regex_t re_compiled[MAX_REGEXP_OBJECTS]; static unsigned char ccl_buf[MAX_CHAR_CLASS_LEN]; int ccl_bufidx = 1; char c; /* current char in pattern */ int i = 0; /* index into pattern */ int j = 0; /* index into re_compiled */ while (pattern[i] != '\0' && (j+1 < MAX_REGEXP_OBJECTS)) { c = pattern[i]; switch (c) { /* Meta-characters: */ case '^': { re_compiled[j].type = BEGIN; } break; case '$': { re_compiled[j].type = END; } break; case '.': { re_compiled[j].type = DOT; } break; case '*': { re_compiled[j].type = STAR; } break; case '+': { re_compiled[j].type = PLUS; } break; case '?': { re_compiled[j].type = QUESTIONMARK; } break; /* case '|': { re_compiled[j].type = BRANCH; } break; <-- not working properly */ /* Escaped character-classes (\s \w ...): */ case '\\': { if (pattern[i+1] != '\0') { /* Skip the escape-char '\\' */ i += 1; /* ... and check the next */ switch (pattern[i]) { /* Meta-character: */ case 'd': { re_compiled[j].type = DIGIT; } break; case 'D': { re_compiled[j].type = NOT_DIGIT; } break; case 'w': { re_compiled[j].type = ALPHA; } break; case 'W': { re_compiled[j].type = NOT_ALPHA; } break; case 's': { re_compiled[j].type = WHITESPACE; } break; case 'S': { re_compiled[j].type = NOT_WHITESPACE; } break; /* Escaped character, e.g. '.' or '$' */ default: { re_compiled[j].type = RE_CHAR; re_compiled[j].u.ch = pattern[i]; } break; } } /* '\\' as last char in pattern -> invalid regular expression. */ /* else { re_compiled[j].type = RE_CHAR; re_compiled[j].ch = pattern[i]; } */ } break; /* Character class: */ case '[': { /* Remember where the char-buffer starts. */ int buf_begin = ccl_bufidx; /* Look-ahead to determine if negated */ if (pattern[i+1] == '^') { re_compiled[j].type = INV_CHAR_CLASS; i += 1; /* Increment i to avoid including '^' in the char-buffer */ if (pattern[i+1] == 0) /* incomplete pattern, missing non-zero char after '^' */ { return 0; } } else { re_compiled[j].type = CHAR_CLASS; } /* Copy characters inside [..] to buffer */ while ( (pattern[++i] != ']') && (pattern[i] != '\0')) /* Missing ] */ { if (pattern[i] == '\\') { if (ccl_bufidx >= MAX_CHAR_CLASS_LEN - 1) { //fputs("exceeded internal buffer!\n", stderr); return 0; } if (pattern[i+1] == 0) /* incomplete pattern, missing non-zero char after '\\' */ { return 0; } ccl_buf[ccl_bufidx++] = pattern[i++]; } else if (ccl_bufidx >= MAX_CHAR_CLASS_LEN) { //fputs("exceeded internal buffer!\n", stderr); return 0; } ccl_buf[ccl_bufidx++] = pattern[i]; } if (ccl_bufidx >= MAX_CHAR_CLASS_LEN) { /* Catches cases such as [00000000000000000000000000000000000000][ */ //fputs("exceeded internal buffer!\n", stderr); return 0; } /* Null-terminate string end */ ccl_buf[ccl_bufidx++] = 0; re_compiled[j].u.ccl = &ccl_buf[buf_begin]; } break; /* Other characters: */ default: { re_compiled[j].type = RE_CHAR; re_compiled[j].u.ch = c; } break; } /* no buffer-out-of-bounds access on invalid patterns - see https://github.com/kokke/tiny-regex-c/commit/1a279e04014b70b0695fba559a7c05d55e6ee90b */ if (pattern[i] == 0) { return 0; } i += 1; j += 1; } /* 'UNUSED' is a sentinel used to indicate end-of-pattern */ re_compiled[j].type = UNUSED; return (re_t) re_compiled; } void re_print(regex_t* pattern) { const char* types[] = { "UNUSED", "DOT", "BEGIN", "END", "QUESTIONMARK", "STAR", "PLUS", "RE_CHAR", "CHAR_CLASS", "INV_CHAR_CLASS", "DIGIT", "NOT_DIGIT", "ALPHA", "NOT_ALPHA", "WHITESPACE", "NOT_WHITESPACE", "BRANCH" }; int i; int j; char c; for (i = 0; i < MAX_REGEXP_OBJECTS; ++i) { if (pattern[i].type == UNUSED) { break; } printf("type: %s", types[pattern[i].type]); if (pattern[i].type == CHAR_CLASS || pattern[i].type == INV_CHAR_CLASS) { printf(" ["); for (j = 0; j < MAX_CHAR_CLASS_LEN; ++j) { c = pattern[i].u.ccl[j]; if ((c == '\0') || (c == ']')) { break; } printf("%c", c); } printf("]"); } else if (pattern[i].type == RE_CHAR) { printf(" '%c'", pattern[i].u.ch); } printf("\n"); } } /* Private functions: */ static int matchdigit(char c) { return isdigit(c); } static int matchalpha(char c) { return isalpha(c); } static int matchwhitespace(char c) { return isspace(c); } static int matchalphanum(char c) { return ((c == '_') || matchalpha(c) || matchdigit(c)); } static int matchrange(char c, const char* str) { return ( (c != '-') && (str[0] != '\0') && (str[0] != '-') && (str[1] == '-') && (str[2] != '\0') && ( (c >= str[0]) && (c <= str[2]))); } static int matchdot(char c) { #if defined(RE_DOT_MATCHES_NEWLINE) && (RE_DOT_MATCHES_NEWLINE == 1) (void)c; return 1; #else return c != '\n' && c != '\r'; #endif } static int ismetachar(char c) { return ((c == 's') || (c == 'S') || (c == 'w') || (c == 'W') || (c == 'd') || (c == 'D')); } static int matchmetachar(char c, const char* str) { switch (str[0]) { case 'd': return matchdigit(c); case 'D': return !matchdigit(c); case 'w': return matchalphanum(c); case 'W': return !matchalphanum(c); case 's': return matchwhitespace(c); case 'S': return !matchwhitespace(c); default: return (c == str[0]); } } static int matchcharclass(char c, const char* str) { do { if (matchrange(c, str)) { return 1; } else if (str[0] == '\\') { /* Escape-char: increment str-ptr and match on next char */ str += 1; if (matchmetachar(c, str)) { return 1; } else if ((c == str[0]) && !ismetachar(c)) { return 1; } } else if (c == str[0]) { if (c == '-') { return ((str[-1] == '\0') || (str[1] == '\0')); } else { return 1; } } } while (*str++ != '\0'); return 0; } static int matchone(regex_t p, char c) { switch (p.type) { case DOT: return matchdot(c); case CHAR_CLASS: return matchcharclass(c, (const char*)p.u.ccl); case INV_CHAR_CLASS: return !matchcharclass(c, (const char*)p.u.ccl); case DIGIT: return matchdigit(c); case NOT_DIGIT: return !matchdigit(c); case ALPHA: return matchalphanum(c); case NOT_ALPHA: return !matchalphanum(c); case WHITESPACE: return matchwhitespace(c); case NOT_WHITESPACE: return !matchwhitespace(c); default: return (p.u.ch == c); } } static int matchstar(regex_t p, regex_t* pattern, const char* text, int* matchlength) { int prelen = *matchlength; const char* prepoint = text; while ((text[0] != '\0') && matchone(p, *text)) { text++; (*matchlength)++; } while (text >= prepoint) { if (matchpattern(pattern, text--, matchlength)) return 1; (*matchlength)--; } *matchlength = prelen; return 0; } static int matchplus(regex_t p, regex_t* pattern, const char* text, int* matchlength) { const char* prepoint = text; while ((text[0] != '\0') && matchone(p, *text)) { text++; (*matchlength)++; } while (text > prepoint) { if (matchpattern(pattern, text--, matchlength)) return 1; (*matchlength)--; } return 0; } static int matchquestion(regex_t p, regex_t* pattern, const char* text, int* matchlength) { if (p.type == UNUSED) return 1; if (matchpattern(pattern, text, matchlength)) return 1; if (*text && matchone(p, *text++)) { if (matchpattern(pattern, text, matchlength)) { (*matchlength)++; return 1; } } return 0; } #if 0 /* Recursive matching */ static int matchpattern(regex_t* pattern, const char* text, int *matchlength) { int pre = *matchlength; if ((pattern[0].type == UNUSED) || (pattern[1].type == QUESTIONMARK)) { return matchquestion(pattern[1], &pattern[2], text, matchlength); } else if (pattern[1].type == STAR) { return matchstar(pattern[0], &pattern[2], text, matchlength); } else if (pattern[1].type == PLUS) { return matchplus(pattern[0], &pattern[2], text, matchlength); } else if ((pattern[0].type == END) && pattern[1].type == UNUSED) { return text[0] == '\0'; } else if ((text[0] != '\0') && matchone(pattern[0], text[0])) { (*matchlength)++; return matchpattern(&pattern[1], text+1); } else { *matchlength = pre; return 0; } } #else /* Iterative matching */ static int matchpattern(regex_t* pattern, const char* text, int* matchlength) { int pre = *matchlength; do { if ((pattern[0].type == UNUSED) || (pattern[1].type == QUESTIONMARK)) { return matchquestion(pattern[0], &pattern[2], text, matchlength); } else if (pattern[1].type == STAR) { return matchstar(pattern[0], &pattern[2], text, matchlength); } else if (pattern[1].type == PLUS) { return matchplus(pattern[0], &pattern[2], text, matchlength); } else if ((pattern[0].type == END) && pattern[1].type == UNUSED) { return (text[0] == '\0'); } /* Branching is not working properly else if (pattern[1].type == BRANCH) { return (matchpattern(pattern, text) || matchpattern(&pattern[2], text)); } */ (*matchlength)++; } while ((text[0] != '\0') && matchone(*pattern++, *text++)); *matchlength = pre; return 0; } #endif