/********************************************************************** re.c - $Author: matz $ created at: Mon Aug 9 18:24:49 JST 1993 Copyright (C) 1993-2003 Yukihiro Matsumoto **********************************************************************/ #include "ruby.h" #include "re.h" #include VALUE rb_eRegexpError; #define BEG(no) regs->beg[no] #define END(no) regs->end[no] #if 'a' == 97 /* it's ascii */ static const char casetable[] = { '\000', '\001', '\002', '\003', '\004', '\005', '\006', '\007', '\010', '\011', '\012', '\013', '\014', '\015', '\016', '\017', '\020', '\021', '\022', '\023', '\024', '\025', '\026', '\027', '\030', '\031', '\032', '\033', '\034', '\035', '\036', '\037', /* ' ' '!' '"' '#' '$' '%' '&' ''' */ '\040', '\041', '\042', '\043', '\044', '\045', '\046', '\047', /* '(' ')' '*' '+' ',' '-' '.' '/' */ '\050', '\051', '\052', '\053', '\054', '\055', '\056', '\057', /* '0' '1' '2' '3' '4' '5' '6' '7' */ '\060', '\061', '\062', '\063', '\064', '\065', '\066', '\067', /* '8' '9' ':' ';' '<' '=' '>' '?' */ '\070', '\071', '\072', '\073', '\074', '\075', '\076', '\077', /* '@' 'A' 'B' 'C' 'D' 'E' 'F' 'G' */ '\100', '\141', '\142', '\143', '\144', '\145', '\146', '\147', /* 'H' 'I' 'J' 'K' 'L' 'M' 'N' 'O' */ '\150', '\151', '\152', '\153', '\154', '\155', '\156', '\157', /* 'P' 'Q' 'R' 'S' 'T' 'U' 'V' 'W' */ '\160', '\161', '\162', '\163', '\164', '\165', '\166', '\167', /* 'X' 'Y' 'Z' '[' '\' ']' '^' '_' */ '\170', '\171', '\172', '\133', '\134', '\135', '\136', '\137', /* '`' 'a' 'b' 'c' 'd' 'e' 'f' 'g' */ '\140', '\141', '\142', '\143', '\144', '\145', '\146', '\147', /* 'h' 'i' 'j' 'k' 'l' 'm' 'n' 'o' */ '\150', '\151', '\152', '\153', '\154', '\155', '\156', '\157', /* 'p' 'q' 'r' 's' 't' 'u' 'v' 'w' */ '\160', '\161', '\162', '\163', '\164', '\165', '\166', '\167', /* 'x' 'y' 'z' '{' '|' '}' '~' */ '\170', '\171', '\172', '\173', '\174', '\175', '\176', '\177', '\200', '\201', '\202', '\203', '\204', '\205', '\206', '\207', '\210', '\211', '\212', '\213', '\214', '\215', '\216', '\217', '\220', '\221', '\222', '\223', '\224', '\225', '\226', '\227', '\230', '\231', '\232', '\233', '\234', '\235', '\236', '\237', '\240', '\241', '\242', '\243', '\244', '\245', '\246', '\247', '\250', '\251', '\252', '\253', '\254', '\255', '\256', '\257', '\260', '\261', '\262', '\263', '\264', '\265', '\266', '\267', '\270', '\271', '\272', '\273', '\274', '\275', '\276', '\277', '\300', '\301', '\302', '\303', '\304', '\305', '\306', '\307', '\310', '\311', '\312', '\313', '\314', '\315', '\316', '\317', '\320', '\321', '\322', '\323', '\324', '\325', '\326', '\327', '\330', '\331', '\332', '\333', '\334', '\335', '\336', '\337', '\340', '\341', '\342', '\343', '\344', '\345', '\346', '\347', '\350', '\351', '\352', '\353', '\354', '\355', '\356', '\357', '\360', '\361', '\362', '\363', '\364', '\365', '\366', '\367', '\370', '\371', '\372', '\373', '\374', '\375', '\376', '\377', }; #else # error >>> "You lose. You will need a translation table for your character set." <<< #endif int rb_memcicmp(x, y, len) const void *x, *y; long len; { const unsigned char *p1 = x, *p2 = y; int tmp; while (len--) { if (tmp = casetable[(unsigned)*p1++] - casetable[(unsigned)*p2++]) return tmp; } return 0; } int rb_memcmp(p1, p2, len) const void *p1, *p2; long len; { if (!ruby_ignorecase) { return memcmp(p1, p2, len); } return rb_memcicmp(p1, p2, len); } long rb_memsearch(x0, m, y0, n) const void *x0, *y0; long m, n; { const unsigned char *x = (unsigned char *)x0, *y = (unsigned char *)y0; const unsigned char *s, *e; long i; int d; unsigned long hx, hy; #define KR_REHASH(a, b, h) (((h) << 1) - (((unsigned long)(a))< n) return -1; s = y; e = s + n - m; /* Preprocessing */ /* computes d = 2^(m-1) with the left-shift operator */ d = sizeof(hx) * CHAR_BIT - 1; if (d > m) d = m; if (ruby_ignorecase) { if (n == m) { return rb_memcicmp(x, s, m) == 0 ? 0 : -1; } /* Prepare hash value */ for (hy = hx = i = 0; i < d; ++i) { hx = KR_REHASH(0, casetable[x[i]], hx); hy = KR_REHASH(0, casetable[s[i]], hy); } /* Searching */ while (hx != hy || rb_memcicmp(x, s, m)) { if (s >= e) return -1; hy = KR_REHASH(casetable[*s], casetable[*(s+d)], hy); s++; } } else { if (n == m) { return memcmp(x, s, m) == 0 ? 0 : -1; } /* Prepare hash value */ for (hy = hx = i = 0; i < d; ++i) { hx = KR_REHASH(0, x[i], hx); hy = KR_REHASH(0, s[i], hy); } /* Searching */ while (hx != hy || memcmp(x, s, m)) { if (s >= e) return -1; hy = KR_REHASH(*s, *(s+d), hy); s++; } } return s-y; } #define REG_LITERAL FL_USER5 #define REG_CASESTATE FL_USER0 #define KCODE_NONE 0 #define KCODE_EUC FL_USER1 #define KCODE_SJIS FL_USER2 #define KCODE_UTF8 FL_USER3 #define KCODE_FIXED FL_USER4 #define KCODE_MASK (KCODE_EUC|KCODE_SJIS|KCODE_UTF8) static int reg_kcode = DEFAULT_KCODE; static void kcode_euc(re) struct RRegexp *re; { FL_UNSET(re, KCODE_MASK); FL_SET(re, KCODE_EUC); FL_SET(re, KCODE_FIXED); } static void kcode_sjis(re) struct RRegexp *re; { FL_UNSET(re, KCODE_MASK); FL_SET(re, KCODE_SJIS); FL_SET(re, KCODE_FIXED); } static void kcode_utf8(re) struct RRegexp *re; { FL_UNSET(re, KCODE_MASK); FL_SET(re, KCODE_UTF8); FL_SET(re, KCODE_FIXED); } static void kcode_none(re) struct RRegexp *re; { FL_UNSET(re, KCODE_MASK); FL_SET(re, KCODE_FIXED); } static int curr_kcode; static void kcode_set_option(re) VALUE re; { if (!FL_TEST(re, KCODE_FIXED)) return; curr_kcode = RBASIC(re)->flags & KCODE_MASK; if (reg_kcode == curr_kcode) return; switch (curr_kcode) { case KCODE_NONE: re_mbcinit(MBCTYPE_ASCII); break; case KCODE_EUC: re_mbcinit(MBCTYPE_EUC); break; case KCODE_SJIS: re_mbcinit(MBCTYPE_SJIS); break; case KCODE_UTF8: re_mbcinit(MBCTYPE_UTF8); break; } } static void kcode_reset_option() { if (reg_kcode == curr_kcode) return; switch (reg_kcode) { case KCODE_NONE: re_mbcinit(MBCTYPE_ASCII); break; case KCODE_EUC: re_mbcinit(MBCTYPE_EUC); break; case KCODE_SJIS: re_mbcinit(MBCTYPE_SJIS); break; case KCODE_UTF8: re_mbcinit(MBCTYPE_UTF8); break; } } int rb_reg_mbclen2(c, re) unsigned int c; VALUE re; { int len; if (!FL_TEST(re, KCODE_FIXED)) return mbclen(c); kcode_set_option(re); len = mbclen(c); kcode_reset_option(); return len; } static void rb_reg_check(re) VALUE re; { if (!RREGEXP(re)->ptr || !RREGEXP(re)->str) { rb_raise(rb_eTypeError, "uninitialized Regexp"); } } extern int ruby_in_compile; static void rb_reg_expr_str(str, s, len) VALUE str; const char *s; long len; { const char *p, *pend; int need_escape = 0; p = s; pend = p + len; while (pptr->options & RE_OPTION_MULTILINE) rb_str_buf_cat2(str, "m"); if (RREGEXP(re)->ptr->options & RE_OPTION_IGNORECASE) rb_str_buf_cat2(str, "i"); if (RREGEXP(re)->ptr->options & RE_OPTION_EXTENDED) rb_str_buf_cat2(str, "x"); if (FL_TEST(re, KCODE_FIXED)) { switch ((RBASIC(re)->flags & KCODE_MASK)) { case KCODE_NONE: rb_str_buf_cat2(str, "n"); break; case KCODE_EUC: rb_str_buf_cat2(str, "e"); break; case KCODE_SJIS: rb_str_buf_cat2(str, "s"); break; case KCODE_UTF8: rb_str_buf_cat2(str, "u"); break; } } } OBJ_INFECT(str, re); return str; } /* * call-seq: * rxp.source => str * * Returns the original string of the pattern. * * /ab+c/ix.source #=> "ab+c" */ static VALUE rb_reg_source(re) VALUE re; { VALUE str; rb_reg_check(re); str = rb_str_new(RREGEXP(re)->str,RREGEXP(re)->len); if (OBJ_TAINTED(re)) OBJ_TAINT(str); return str; } /* * call-seq: * rxp.inspect => string * * Produce a nicely formatted string-version of _rxp_. Perhaps surprisingly, * #inspect actually produces the more natural version of * the string than #to_s. * * /ab+c/ix.to_s #=> /ab+c/ix */ static VALUE rb_reg_inspect(re) VALUE re; { rb_reg_check(re); return rb_reg_desc(RREGEXP(re)->str, RREGEXP(re)->len, re); } /* * call-seq: * rxp.to_s => str * * Returns a string containing the regular expression and its options (using the * (?xxx:yyy) notation. This string can be fed back in to * Regexp::new to a regular expression with the same semantics as * the original. (However, Regexp#== may not return true when * comparing the two, as the source of the regular expression itself may * differ, as the example shows). Regexp#inspect produces a * generally more readable version of rxp. * * r1 = /ab+c/ix #=> /ab+c/ix * s1 = r1.to_s #=> "(?ix-m:ab+c)" * r2 = Regexp.new(s1) #=> /(?ix-m:ab+c)/ * r1 == r2 #=> false * r1.source #=> "ab+c" * r2.source #=> "(?ix-m:ab+c)" */ static VALUE rb_reg_to_s(re) VALUE re; { int options; const int embeddable = RE_OPTION_MULTILINE|RE_OPTION_IGNORECASE|RE_OPTION_EXTENDED; long len; const char* ptr; VALUE str = rb_str_buf_new2("(?"); rb_reg_check(re); options = RREGEXP(re)->ptr->options; ptr = RREGEXP(re)->str; len = RREGEXP(re)->len; again: if (len >= 4 && ptr[0] == '(' && ptr[1] == '?') { int err = 1; ptr += 2; if ((len -= 2) > 0) { do { if (*ptr == 'm') { options |= RE_OPTION_MULTILINE; } else if (*ptr == 'i') { options |= RE_OPTION_IGNORECASE; } else if (*ptr == 'x') { options |= RE_OPTION_EXTENDED; } else break; ++ptr; } while (--len > 0); } if (len > 1 && *ptr == '-') { ++ptr; --len; do { if (*ptr == 'm') { options &= ~RE_OPTION_MULTILINE; } else if (*ptr == 'i') { options &= ~RE_OPTION_IGNORECASE; } else if (*ptr == 'x') { options &= ~RE_OPTION_EXTENDED; } else break; ++ptr; } while (--len > 0); } if (*ptr == ')') { --len; ++ptr; goto again; } if (*ptr == ':' && ptr[len-1] == ')') { Regexp *rp; kcode_set_option(re); rp = ALLOC(Regexp); MEMZERO((char *)rp, Regexp, 1); err = re_compile_pattern(++ptr, len -= 2, rp) != 0; kcode_reset_option(); re_free_pattern(rp); } if (err) { options = RREGEXP(re)->ptr->options; ptr = RREGEXP(re)->str; len = RREGEXP(re)->len; } } if (options & RE_OPTION_MULTILINE) rb_str_buf_cat2(str, "m"); if (options & RE_OPTION_IGNORECASE) rb_str_buf_cat2(str, "i"); if (options & RE_OPTION_EXTENDED) rb_str_buf_cat2(str, "x"); if ((options & embeddable) != embeddable) { rb_str_buf_cat2(str, "-"); if (!(options & RE_OPTION_MULTILINE)) rb_str_buf_cat2(str, "m"); if (!(options & RE_OPTION_IGNORECASE)) rb_str_buf_cat2(str, "i"); if (!(options & RE_OPTION_EXTENDED)) rb_str_buf_cat2(str, "x"); } rb_str_buf_cat2(str, ":"); rb_reg_expr_str(str, ptr, len); rb_str_buf_cat2(str, ")"); OBJ_INFECT(str, re); return str; } static void rb_reg_raise(s, len, err, re) const char *s; long len; const char *err; VALUE re; { VALUE desc = rb_reg_desc(s, len, re); if (ruby_in_compile) rb_compile_error("%s: %s", err, RSTRING(desc)->ptr); else rb_raise(rb_eRegexpError, "%s: %s", err, RSTRING(desc)->ptr); } /* * call-seq: * rxp.casefold? => true or false * * Returns the value of the case-insensitive flag. */ static VALUE rb_reg_casefold_p(re) VALUE re; { rb_reg_check(re); if (RREGEXP(re)->ptr->options & RE_OPTION_IGNORECASE) return Qtrue; return Qfalse; } /* * call-seq: * rxp.options => fixnum * * Returns the set of bits corresponding to the options used when creating this * Regexp (see Regexp::new for details. Note that additional bits * may be set in the returned options: these are used internally by the regular * expression code. These extra bits are ignored if the options are passed to * Regexp::new. * * Regexp::IGNORECASE #=> 1 * Regexp::EXTENDED #=> 2 * Regexp::MULTILINE #=> 4 * * /cat/.options #=> 128 * /cat/ix.options #=> 131 * Regexp.new('cat', true).options #=> 129 * Regexp.new('cat', 0, 's').options #=> 384 * * r = /cat/ix * Regexp.new(r.source, r.options) #=> /cat/ix */ static VALUE rb_reg_options_m(re) VALUE re; { int options = rb_reg_options(re); return INT2NUM(options); } /* * call-seq: * rxp.kcode => str * * Returns the character set code for the regexp. */ static VALUE rb_reg_kcode_m(re) VALUE re; { char *kcode; if (FL_TEST(re, KCODE_FIXED)) { switch (RBASIC(re)->flags & KCODE_MASK) { case KCODE_NONE: kcode = "none"; break; case KCODE_EUC: kcode = "euc"; break; case KCODE_SJIS: kcode = "sjis"; break; case KCODE_UTF8: kcode = "utf8"; break; default: rb_bug("unknown kcode - should not happen"); break; } return rb_str_new2(kcode); } return Qnil; } static Regexp* make_regexp(s, len, flags) const char *s; long len; int flags; { Regexp *rp; char *err; /* Handle escaped characters first. */ /* Build a copy of the string (in dest) with the escaped characters translated, and generate the regex from that. */ rp = ALLOC(Regexp); MEMZERO((char *)rp, Regexp, 1); rp->buffer = ALLOC_N(char, 16); rp->allocated = 16; rp->fastmap = ALLOC_N(char, 256); if (flags) { rp->options = flags; } err = re_compile_pattern(s, len, rp); if (err != NULL) { re_free_pattern(rp); rb_reg_raise(s, len, err, 0); return 0; } return rp; } /* * Document-class: MatchData * * MatchData is the type of the special variable $~, * and is the type of the object returned by Regexp#match and * Regexp#last_match. It encapsulates all the results of a pattern * match, results normally accessed through the special variables * $&, $', $`, $1, * $2, and so on. Matchdata is also known as * MatchingData. * */ VALUE rb_cMatch; static VALUE match_alloc _((VALUE)); static VALUE match_alloc(klass) VALUE klass; { NEWOBJ(match, struct RMatch); OBJSETUP(match, klass, T_MATCH); match->str = 0; match->regs = 0; match->regs = ALLOC(struct re_registers); MEMZERO(match->regs, struct re_registers, 1); return (VALUE)match; } /* :nodoc: */ static VALUE match_init_copy(obj, orig) VALUE obj, orig; { if (obj == orig) return obj; if (!rb_obj_is_instance_of(orig, rb_obj_class(obj))) { rb_raise(rb_eTypeError, "wrong argument class"); } RMATCH(obj)->str = RMATCH(orig)->str; re_free_registers(RMATCH(obj)->regs); RMATCH(obj)->regs->allocated = 0; re_copy_registers(RMATCH(obj)->regs, RMATCH(orig)->regs); return obj; } /* * call-seq: * mtch.length => integer * mtch.size => integer * * Returns the number of elements in the match array. * * m = /(.)(.)(\d+)(\d)/.match("THX1138.") * m.length #=> 5 * m.size #=> 5 */ static VALUE match_size(match) VALUE match; { return INT2FIX(RMATCH(match)->regs->num_regs); } /* * call-seq: * mtch.offset(n) => array * * Returns a two-element array containing the beginning and ending offsets of * the nth match. * * m = /(.)(.)(\d+)(\d)/.match("THX1138.") * m.offset(0) #=> [1, 7] * m.offset(4) #=> [6, 7] */ static VALUE match_offset(match, n) VALUE match, n; { int i = NUM2INT(n); if (i < 0 || RMATCH(match)->regs->num_regs <= i) rb_raise(rb_eIndexError, "index %d out of matches", i); if (RMATCH(match)->regs->beg[i] < 0) return rb_assoc_new(Qnil, Qnil); return rb_assoc_new(INT2FIX(RMATCH(match)->regs->beg[i]), INT2FIX(RMATCH(match)->regs->end[i])); } /* * call-seq: * mtch.begin(n) => integer * * Returns the offset of the start of the nth element of the match * array in the string. * * m = /(.)(.)(\d+)(\d)/.match("THX1138.") * m.begin(0) #=> 1 * m.begin(2) #=> 2 */ static VALUE match_begin(match, n) VALUE match, n; { int i = NUM2INT(n); if (i < 0 || RMATCH(match)->regs->num_regs <= i) rb_raise(rb_eIndexError, "index %d out of matches", i); if (RMATCH(match)->regs->beg[i] < 0) return Qnil; return INT2FIX(RMATCH(match)->regs->beg[i]); } /* * call-seq: * mtch.end(n) => integer * * Returns the offset of the character immediately following the end of the * nth element of the match array in the string. * * m = /(.)(.)(\d+)(\d)/.match("THX1138.") * m.end(0) #=> 7 * m.end(2) #=> 3 */ static VALUE match_end(match, n) VALUE match, n; { int i = NUM2INT(n); if (i < 0 || RMATCH(match)->regs->num_regs <= i) rb_raise(rb_eIndexError, "index %d out of matches", i); if (RMATCH(match)->regs->beg[i] < 0) return Qnil; return INT2FIX(RMATCH(match)->regs->end[i]); } #define MATCH_BUSY FL_USER2 void rb_match_busy(match) VALUE match; { FL_SET(match, MATCH_BUSY); } int ruby_ignorecase; static int may_need_recompile; static void rb_reg_prepare_re(re) VALUE re; { int need_recompile = 0; int state; rb_reg_check(re); state = FL_TEST(re, REG_CASESTATE); /* ignorecase status */ if (ruby_ignorecase && !state) { FL_SET(re, REG_CASESTATE); RREGEXP(re)->ptr->options |= RE_OPTION_IGNORECASE; need_recompile = 1; } if (!ruby_ignorecase && state) { FL_UNSET(re, REG_CASESTATE); RREGEXP(re)->ptr->options &= ~RE_OPTION_IGNORECASE; need_recompile = 1; } if (!FL_TEST(re, KCODE_FIXED) && (RBASIC(re)->flags & KCODE_MASK) != reg_kcode) { need_recompile = 1; RBASIC(re)->flags &= ~KCODE_MASK; RBASIC(re)->flags |= reg_kcode; } if (need_recompile) { char *err; if (FL_TEST(re, KCODE_FIXED)) kcode_set_option(re); rb_reg_check(re); RREGEXP(re)->ptr->fastmap_accurate = 0; err = re_compile_pattern(RREGEXP(re)->str, RREGEXP(re)->len, RREGEXP(re)->ptr); if (err != NULL) { rb_reg_raise(RREGEXP(re)->str, RREGEXP(re)->len, err, re); } } } long rb_reg_adjust_startpos(re, str, pos, reverse) VALUE re, str; long pos, reverse; { long range; rb_reg_check(re); if (may_need_recompile) rb_reg_prepare_re(re); if (FL_TEST(re, KCODE_FIXED)) kcode_set_option(re); else if (reg_kcode != curr_kcode) kcode_reset_option(); if (reverse) { range = -pos; } else { range = RSTRING(str)->len - pos; } return re_adjust_startpos(RREGEXP(re)->ptr, RSTRING(str)->ptr, RSTRING(str)->len, pos, range); } long rb_reg_search(re, str, pos, reverse) VALUE re, str; long pos, reverse; { long result; VALUE match; static struct re_registers regs; long range; if (pos > RSTRING(str)->len || pos < 0) { rb_backref_set(Qnil); return -1; } rb_reg_check(re); if (may_need_recompile) rb_reg_prepare_re(re); if (FL_TEST(re, KCODE_FIXED)) kcode_set_option(re); else if (reg_kcode != curr_kcode) kcode_reset_option(); if (reverse) { range = -pos; } else { range = RSTRING(str)->len - pos; } result = re_search(RREGEXP(re)->ptr,RSTRING(str)->ptr,RSTRING(str)->len, pos, range, ®s); if (FL_TEST(re, KCODE_FIXED)) kcode_reset_option(); if (result == -2) { rb_reg_raise(RREGEXP(re)->str, RREGEXP(re)->len, "Stack overflow in regexp matcher", re); } if (result < 0) { rb_backref_set(Qnil); return result; } match = rb_backref_get(); if (NIL_P(match) || FL_TEST(match, MATCH_BUSY)) { match = match_alloc(rb_cMatch); } else { if (rb_safe_level() >= 3) OBJ_TAINT(match); else FL_UNSET(match, FL_TAINT); } re_copy_registers(RMATCH(match)->regs, ®s); RMATCH(match)->str = rb_str_new4(str); rb_backref_set(match); OBJ_INFECT(match, re); OBJ_INFECT(match, str); return result; } VALUE rb_reg_nth_defined(nth, match) int nth; VALUE match; { if (NIL_P(match)) return Qnil; if (nth >= RMATCH(match)->regs->num_regs) { return Qnil; } if (nth < 0) { nth += RMATCH(match)->regs->num_regs; if (nth <= 0) return Qnil; } if (RMATCH(match)->BEG(nth) == -1) return Qfalse; return Qtrue; } VALUE rb_reg_nth_match(nth, match) int nth; VALUE match; { VALUE str; long start, end, len; if (NIL_P(match)) return Qnil; if (nth >= RMATCH(match)->regs->num_regs) { return Qnil; } if (nth < 0) { nth += RMATCH(match)->regs->num_regs; if (nth <= 0) return Qnil; } start = RMATCH(match)->BEG(nth); if (start == -1) return Qnil; end = RMATCH(match)->END(nth); len = end - start; str = rb_str_substr(RMATCH(match)->str, start, len); OBJ_INFECT(str, match); return str; } VALUE rb_reg_last_match(match) VALUE match; { return rb_reg_nth_match(0, match); } /* * call-seq: * mtch.pre_match => str * * Returns the portion of the original string before the current match. * Equivalent to the special variable $`. * * m = /(.)(.)(\d+)(\d)/.match("THX1138.") * m.pre_match #=> "T" */ VALUE rb_reg_match_pre(match) VALUE match; { VALUE str; if (NIL_P(match)) return Qnil; if (RMATCH(match)->BEG(0) == -1) return Qnil; str = rb_str_substr(RMATCH(match)->str, 0, RMATCH(match)->BEG(0)); if (OBJ_TAINTED(match)) OBJ_TAINT(str); return str; } /* * call-seq: * mtch.post_match => str * * Returns the portion of the original string after the current match. * Equivalent to the special variable $'. * * m = /(.)(.)(\d+)(\d)/.match("THX1138: The Movie") * m.post_match #=> ": The Movie" */ VALUE rb_reg_match_post(match) VALUE match; { VALUE str; long pos; if (NIL_P(match)) return Qnil; if (RMATCH(match)->BEG(0) == -1) return Qnil; str = RMATCH(match)->str; pos = RMATCH(match)->END(0); str = rb_str_substr(str, pos, RSTRING(str)->len - pos); if (OBJ_TAINTED(match)) OBJ_TAINT(str); return str; } VALUE rb_reg_match_last(match) VALUE match; { int i; if (NIL_P(match)) return Qnil; if (RMATCH(match)->BEG(0) == -1) return Qnil; for (i=RMATCH(match)->regs->num_regs-1; RMATCH(match)->BEG(i) == -1 && i > 0; i--) ; if (i == 0) return Qnil; return rb_reg_nth_match(i, match); } static VALUE last_match_getter() { return rb_reg_last_match(rb_backref_get()); } static VALUE prematch_getter() { return rb_reg_match_pre(rb_backref_get()); } static VALUE postmatch_getter() { return rb_reg_match_post(rb_backref_get()); } static VALUE last_paren_match_getter() { return rb_reg_match_last(rb_backref_get()); } static VALUE match_array(match, start) VALUE match; int start; { struct re_registers *regs = RMATCH(match)->regs; VALUE ary = rb_ary_new2(regs->num_regs); VALUE target = RMATCH(match)->str; int i; int taint = OBJ_TAINTED(match); for (i=start; inum_regs; i++) { if (regs->beg[i] == -1) { rb_ary_push(ary, Qnil); } else { VALUE str = rb_str_substr(target, regs->beg[i], regs->end[i]-regs->beg[i]); if (taint) OBJ_TAINT(str); rb_ary_push(ary, str); } } return ary; } /* [MG]:FIXME: I put parens around the /.../.match() in the first line of the second example to prevent the '*' followed by a '/' from ending the comment. */ /* * call-seq: * mtch.to_a => anArray * * Returns the array of matches. * * m = /(.)(.)(\d+)(\d)/.match("THX1138.") * m.to_a #=> ["HX1138", "H", "X", "113", "8"] * * Because to_a is called when expanding * *variable, there's a useful assignment * shortcut for extracting matched fields. This is slightly slower than * accessing the fields directly (as an intermediate array is * generated). * * all,f1,f2,f3 = *(/(.)(.)(\d+)(\d)/.match("THX1138.")) * all #=> "HX1138" * f1 #=> "H" * f2 #=> "X" * f3 #=> "113" */ static VALUE match_to_a(match) VALUE match; { return match_array(match, 0); } /* * call-seq: * mtch.captures => array * * Returns the array of captures; equivalent to mtch.to_a[1..-1]. * * f1,f2,f3,f4 = /(.)(.)(\d+)(\d)/.match("THX1138.").captures * f1 #=> "H" * f2 #=> "X" * f3 #=> "113" * f4 #=> "8" */ static VALUE match_captures(match) VALUE match; { return match_array(match, 1); } /* * call-seq: * mtch[i] => obj * mtch[start, length] => array * mtch[range] => array * * Match Reference---MatchData acts as an array, and may be * accessed using the normal array indexing techniques. mtch[0] is * equivalent to the special variable $&, and returns the entire * matched string. mtch[1], mtch[2], and so on return the values * of the matched backreferences (portions of the pattern between parentheses). * * m = /(.)(.)(\d+)(\d)/.match("THX1138.") * m[0] #=> "HX1138" * m[1, 2] #=> ["H", "X"] * m[1..3] #=> ["H", "X", "113"] * m[-3, 2] #=> ["X", "113"] */ static VALUE match_aref(argc, argv, match) int argc; VALUE *argv; VALUE match; { VALUE idx, rest; rb_scan_args(argc, argv, "11", &idx, &rest); if (!NIL_P(rest) || !FIXNUM_P(idx) || FIX2INT(idx) < 0) { return rb_ary_aref(argc, argv, match_to_a(match)); } return rb_reg_nth_match(FIX2INT(idx), match); } static VALUE match_entry _((VALUE, long)); static VALUE match_entry(match, n) VALUE match; long n; { return rb_reg_nth_match(n, match); } /* * call-seq: * mtch.select([index]*) => array * * Uses each index to access the matching values, returning an array of * the corresponding matches. * * m = /(.)(.)(\d+)(\d)/.match("THX1138: The Movie") * m.to_a #=> ["HX1138", "H", "X", "113", "8"] * m.select(0, 2, -2) #=> ["HX1138", "X", "113"] */ static VALUE match_values_at(argc, argv, match) int argc; VALUE *argv; VALUE match; { return rb_values_at(match, RMATCH(match)->regs->num_regs, argc, argv, match_entry); } /* * call-seq: * mtch.select([index]*) => array * * Uses each index to access the matching values, returning an * array of the corresponding matches. * * m = /(.)(.)(\d+)(\d)/.match("THX1138: The Movie") * m.to_a #=> ["HX1138", "H", "X", "113", "8"] * m.select(0, 2, -2) #=> ["HX1138", "X", "113"] */ static VALUE match_select(argc, argv, match) int argc; VALUE *argv; VALUE match; { if (argc > 0) { rb_raise(rb_eArgError, "wrong number of arguments (%d for 0)", argc); } else { struct re_registers *regs = RMATCH(match)->regs; VALUE target = RMATCH(match)->str; VALUE result = rb_ary_new(); int i; int taint = OBJ_TAINTED(match); for (i=0; inum_regs; i++) { VALUE str = rb_str_substr(target, regs->beg[i], regs->end[i]-regs->beg[i]); if (taint) OBJ_TAINT(str); if (RTEST(rb_yield(str))) { rb_ary_push(result, str); } } return result; } } /* * call-seq: * mtch.to_s => str * * Returns the entire matched string. * * m = /(.)(.)(\d+)(\d)/.match("THX1138.") * m.to_s #=> "HX1138" */ static VALUE match_to_s(match) VALUE match; { VALUE str = rb_reg_last_match(match); if (NIL_P(str)) str = rb_str_new(0,0); if (OBJ_TAINTED(match)) OBJ_TAINT(str); if (OBJ_TAINTED(RMATCH(match)->str)) OBJ_TAINT(str); return str; } /* * call-seq: * mtch.string => str * * Returns a frozen copy of the string passed in to match. * * m = /(.)(.)(\d+)(\d)/.match("THX1138.") * m.string #=> "THX1138." */ static VALUE match_string(match) VALUE match; { return RMATCH(match)->str; /* str is frozen */ } VALUE rb_cRegexp; static void rb_reg_initialize(obj, s, len, options) VALUE obj; const char *s; long len; int options; /* CASEFOLD = 1 */ /* EXTENDED = 2 */ /* MULTILINE = 4 */ /* CODE_NONE = 16 */ /* CODE_EUC = 32 */ /* CODE_SJIS = 48 */ /* CODE_UTF8 = 64 */ { struct RRegexp *re = RREGEXP(obj); if (!OBJ_TAINTED(obj) && rb_safe_level() >= 4) rb_raise(rb_eSecurityError, "Insecure: can't modify regexp"); rb_check_frozen(obj); if (FL_TEST(obj, REG_LITERAL)) rb_raise(rb_eSecurityError, "can't modify literal regexp"); if (re->ptr) re_free_pattern(re->ptr); if (re->str) free(re->str); re->ptr = 0; re->str = 0; switch (options & ~0xf) { case 0: default: FL_SET(re, reg_kcode); break; case 16: kcode_none(re); break; case 32: kcode_euc(re); break; case 48: kcode_sjis(re); break; case 64: kcode_utf8(re); break; } if (options & ~0xf) { kcode_set_option((VALUE)re); } if (ruby_ignorecase) { options |= RE_OPTION_IGNORECASE; FL_SET(re, REG_CASESTATE); } re->ptr = make_regexp(s, len, options & 0xf); re->str = ALLOC_N(char, len+1); memcpy(re->str, s, len); re->str[len] = '\0'; re->len = len; if (options & ~0xf) { kcode_reset_option(); } if (ruby_in_compile) FL_SET(obj, REG_LITERAL); } static VALUE rb_reg_s_alloc _((VALUE)); static VALUE rb_reg_s_alloc(klass) VALUE klass; { NEWOBJ(re, struct RRegexp); OBJSETUP(re, klass, T_REGEXP); re->ptr = 0; re->len = 0; re->str = 0; return (VALUE)re; } VALUE rb_reg_new(s, len, options) const char *s; long len; int options; { VALUE re = rb_reg_s_alloc(rb_cRegexp); rb_reg_initialize(re, s, len, options); return (VALUE)re; } static int case_cache; static int kcode_cache; static VALUE reg_cache; VALUE rb_reg_regcomp(str) VALUE str; { volatile VALUE save_str = str; if (reg_cache && RREGEXP(reg_cache)->len == RSTRING(str)->len && case_cache == ruby_ignorecase && kcode_cache == reg_kcode && memcmp(RREGEXP(reg_cache)->str, RSTRING(str)->ptr, RSTRING(str)->len) == 0) return reg_cache; case_cache = ruby_ignorecase; kcode_cache = reg_kcode; return reg_cache = rb_reg_new(RSTRING(str)->ptr, RSTRING(str)->len, ruby_ignorecase); } static int rb_reg_cur_kcode(re) VALUE re; { if (FL_TEST(re, KCODE_FIXED)) { return RBASIC(re)->flags & KCODE_MASK; } return 0; } /* * call-seq: * rxp.hash => fixnum * * Produce a hash based on the text and options of this regular expression. */ static VALUE rb_reg_hash(re) VALUE re; { int hashval, len; char *p; rb_reg_check(re); hashval = RREGEXP(re)->ptr->options; len = RREGEXP(re)->len; p = RREGEXP(re)->str; while (len--) { hashval = hashval * 33 + *p++; } hashval = hashval + (hashval>>5); return INT2FIX(hashval); } /* * call-seq: * rxp == other_rxp => true or false * rxp.eql?(other_rxp) => true or false * * Equality---Two regexps are equal if their patterns are identical, they have * the same character set code, and their casefold? values are the * same. * * /abc/ == /abc/x #=> false * /abc/ == /abc/i #=> false * /abc/u == /abc/n #=> false */ static VALUE rb_reg_equal(re1, re2) VALUE re1, re2; { if (re1 == re2) return Qtrue; if (TYPE(re2) != T_REGEXP) return Qfalse; rb_reg_check(re1); rb_reg_check(re2); if (RREGEXP(re1)->len != RREGEXP(re2)->len) return Qfalse; if (memcmp(RREGEXP(re1)->str, RREGEXP(re2)->str, RREGEXP(re1)->len) == 0 && rb_reg_cur_kcode(re1) == rb_reg_cur_kcode(re2) && RREGEXP(re1)->ptr->options == RREGEXP(re2)->ptr->options) { return Qtrue; } return Qfalse; } /* * call-seq: * rxp.match(str) => matchdata or nil * * Returns a MatchData object describing the match, or * nil if there was no match. This is equivalent to retrieving the * value of the special variable $~ following a normal match. * * /(.)(.)(.)/.match("abc")[2] #=> "b" */ VALUE rb_reg_match(re, str) VALUE re, str; { long start; if (NIL_P(str)) { rb_backref_set(Qnil); return Qnil; } StringValue(str); start = rb_reg_search(re, str, 0, 0); if (start < 0) { return Qnil; } return LONG2FIX(start); } /* * call-seq: * rxp === str => true or false * * Case Equality---Synonym for Regexp#=~ used in case statements. * * a = "HELLO" * case a * when /^[a-z]*$/; print "Lower case\n" * when /^[A-Z]*$/; print "Upper case\n" * else; print "Mixed case\n" * end * * produces: * * Upper case */ VALUE rb_reg_eqq(re, str) VALUE re, str; { long start; if (TYPE(str) != T_STRING) { str = rb_check_string_type(str); if (NIL_P(str)) { rb_backref_set(Qnil); return Qfalse; } } StringValue(str); start = rb_reg_search(re, str, 0, 0); if (start < 0) { return Qfalse; } return Qtrue; } /* * call-seq: * ~ rxp => integer or nil * * Match---Matches rxp against the contents of $_. * Equivalent to rxp =~ $_. * * $_ = "input data" * ~ /at/ #=> 7 */ VALUE rb_reg_match2(re) VALUE re; { long start; VALUE line = rb_lastline_get(); if (TYPE(line) != T_STRING) { rb_backref_set(Qnil); return Qnil; } start = rb_reg_search(re, line, 0, 0); if (start < 0) { return Qnil; } return LONG2FIX(start); } /* * call-seq: * rxp.match(str) => matchdata or nil * * Returns a MatchData object describing the match, or * nil if there was no match. This is equivalent to retrieving the * value of the special variable $~ following a normal match. * * /(.)(.)(.)/.match("abc")[2] #=> "b" */ static VALUE rb_reg_match_m(re, str) VALUE re, str; { VALUE result = rb_reg_match(re, str); if (NIL_P(result)) return Qnil; result = rb_backref_get(); rb_match_busy(result); return result; } /* * Document-method: compile * * Synonym for Regexp.new */ /* * call-seq: * Regexp.new(string [, options [, lang]]) => regexp * Regexp.new(regexp) => regexp * Regexp.compile(string [, options [, lang]]) => regexp * Regexp.compile(regexp) => regexp * * Constructs a new regular expression from pattern, which can be either * a String or a Regexp (in which case that regexp's * options are propagated, and new options may not be specified (a change as of * Ruby 1.8). If options is a Fixnum, it should be one or * more of the constants Regexp::EXTENDED, * Regexp::IGNORECASE, and Regexp::MULTILINE, * or-ed together. Otherwise, if options is not * nil, the regexp will be case insensitive. The lang * parameter enables multibyte support for the regexp: `n', `N' = none, `e', * `E' = EUC, `s', `S' = SJIS, `u', `U' = UTF-8. * * r1 = Regexp.new('^a-z+:\\s+\w+') #=> /^a-z+:\s+\w+/ * r2 = Regexp.new('cat', true) #=> /cat/i * r3 = Regexp.new('dog', Regexp::EXTENDED) #=> /dog/x * r4 = Regexp.new(r2) #=> /cat/i */ static VALUE rb_reg_initialize_m(argc, argv, self) int argc; VALUE *argv; VALUE self; { const char *s; long len; int flags = 0; if (argc == 0 || argc > 3) { rb_raise(rb_eArgError, "wrong number of arguments"); } if (TYPE(argv[0]) == T_REGEXP) { if (argc > 1) { rb_warn("flags%s ignored", (argc == 3) ? " and encoding": ""); } rb_reg_check(argv[0]); flags = RREGEXP(argv[0])->ptr->options & 0xf; if (FL_TEST(argv[0], KCODE_FIXED)) { switch (RBASIC(argv[0])->flags & KCODE_MASK) { case KCODE_NONE: flags |= 16; break; case KCODE_EUC: flags |= 32; break; case KCODE_SJIS: flags |= 48; break; case KCODE_UTF8: flags |= 64; break; default: break; } } s = RREGEXP(argv[0])->str; len = RREGEXP(argv[0])->len; } else { if (argc >= 2) { if (FIXNUM_P(argv[1])) flags = FIX2INT(argv[1]); else if (RTEST(argv[1])) flags = RE_OPTION_IGNORECASE; } if (argc == 3 && !NIL_P(argv[2])) { char *kcode = StringValuePtr(argv[2]); flags &= ~0x70; switch (kcode[0]) { case 'n': case 'N': flags |= 16; break; case 'e': case 'E': flags |= 32; break; case 's': case 'S': flags |= 48; break; case 'u': case 'U': flags |= 64; break; default: break; } } s = StringValuePtr(argv[0]); len = RSTRING(argv[0])->len; } rb_reg_initialize(self, s, len, flags); return self; } VALUE rb_reg_quote(str) VALUE str; { char *s, *send, *t; VALUE tmp; int c; s = RSTRING(str)->ptr; send = s + RSTRING(str)->len; for (; s < send; s++) { c = *s; if (ismbchar(c)) { int n = mbclen(c); while (n-- && s < send) s++; s--; continue; } switch (c) { case '[': case ']': case '{': case '}': case '(': case ')': case '|': case '-': case '*': case '.': case '\\': case '?': case '+': case '^': case '$': case ' ': case '#': case '\t': case '\f': case '\n': case '\r': goto meta_found; } } return str; meta_found: tmp = rb_str_new(0, RSTRING(str)->len*2); t = RSTRING(tmp)->ptr; /* copy upto metacharacter */ memcpy(t, RSTRING(str)->ptr, s - RSTRING(str)->ptr); t += s - RSTRING(str)->ptr; for (; s < send; s++) { c = *s; if (ismbchar(c)) { int n = mbclen(c); while (n-- && s < send) *t++ = *s++; s--; continue; } switch (c) { case '[': case ']': case '{': case '}': case '(': case ')': case '|': case '-': case '*': case '.': case '\\': case '?': case '+': case '^': case '$': case '#': *t++ = '\\'; break; case ' ': *t++ = '\\'; *t++ = ' '; continue; case '\t': *t++ = '\\'; *t++ = 't'; continue; case '\n': *t++ = '\\'; *t++ = 'n'; continue; case '\r': *t++ = '\\'; *t++ = 'r'; continue; case '\f': *t++ = '\\'; *t++ = 'f'; continue; } *t++ = c; } rb_str_resize(tmp, t - RSTRING(tmp)->ptr); OBJ_INFECT(tmp, str); return tmp; } /* * call-seq: * Regexp.escape(str) => a_str * Regexp.quote(str) => a_str * * Escapes any characters that would have special meaning in a regular * expression. Returns a new escaped string, or self if no characters are * escaped. For any string, * Regexp.escape(str)=~str will be true. * * Regexp.escape('\\*?{}.') #=> \\\\\*\?\{\}\. */ static VALUE rb_reg_s_quote(argc, argv) int argc; VALUE *argv; { VALUE str, kcode; int kcode_saved = reg_kcode; rb_scan_args(argc, argv, "11", &str, &kcode); if (!NIL_P(kcode)) { rb_set_kcode(StringValuePtr(kcode)); curr_kcode = reg_kcode; reg_kcode = kcode_saved; } StringValue(str); str = rb_reg_quote(str); kcode_reset_option(); return str; } int rb_kcode() { switch (reg_kcode) { case KCODE_EUC: return MBCTYPE_EUC; case KCODE_SJIS: return MBCTYPE_SJIS; case KCODE_UTF8: return MBCTYPE_UTF8; case KCODE_NONE: return MBCTYPE_ASCII; } rb_bug("wrong reg_kcode value (0x%x)", reg_kcode); } static int rb_reg_get_kcode(re) VALUE re; { switch (RBASIC(re)->flags & KCODE_MASK) { case KCODE_NONE: return 16; case KCODE_EUC: return 32; case KCODE_SJIS: return 48; case KCODE_UTF8: return 64; default: return 0; } } int rb_reg_options(re) VALUE re; { int options; rb_reg_check(re); options = RREGEXP(re)->ptr->options & (RE_OPTION_IGNORECASE|RE_OPTION_MULTILINE|RE_OPTION_EXTENDED); if (FL_TEST(re, KCODE_FIXED)) { options |= rb_reg_get_kcode(re); } return options; } /* * call-seq: * Regexp.union([pattern]*) => new_str * * Return a Regexp object that is the union of the given * patterns, i.e., will match any of its parts. The patterns * can be Regexp objects, in which case their options will be preserved, or * Strings. If no arguments are given, returns /(?!)/. * * Regexp.union #=> /(?!)/ * Regexp.union("penzance") #=> /penzance/ * Regexp.union("skiing", "sledding") #=> /skiing|sledding/ * Regexp.union(/dogs/, /cats/i) #=> /(?-mix:dogs)|(?i-mx:cats)/ */ static VALUE rb_reg_s_union(argc, argv) int argc; VALUE *argv; { if (argc == 0) { VALUE args[1]; args[0] = rb_str_new2("(?!)"); return rb_class_new_instance(1, args, rb_cRegexp); } else if (argc == 1) { VALUE v; v = rb_check_convert_type(argv[0], T_REGEXP, "Regexp", "to_regexp"); if (!NIL_P(v)) return v; else { VALUE args[1]; args[0] = rb_reg_s_quote(argc, argv); return rb_class_new_instance(1, args, rb_cRegexp); } } else { int i, kcode = -1; VALUE kcode_re = Qnil; VALUE source = rb_str_buf_new(0); VALUE args[3]; for (i = 0; i < argc; i++) { volatile VALUE v; if (0 < i) rb_str_buf_cat2(source, "|"); v = rb_check_convert_type(argv[i], T_REGEXP, "Regexp", "to_regexp"); if (!NIL_P(v)) { if (FL_TEST(v, KCODE_FIXED)) { if (kcode == -1) { kcode_re = v; kcode = RBASIC(v)->flags & KCODE_MASK; } else if ((RBASIC(v)->flags & KCODE_MASK) != kcode) { volatile VALUE str1, str2; str1 = rb_inspect(kcode_re); str2 = rb_inspect(v); rb_raise(rb_eArgError, "mixed kcode: %s and %s", RSTRING(str1)->ptr, RSTRING(str2)->ptr); } } v = rb_reg_to_s(v); } else { args[0] = argv[i]; v = rb_reg_s_quote(1, args); } rb_str_buf_append(source, v); } args[0] = source; args[1] = Qnil; switch (kcode) { case -1: args[2] = Qnil; break; case KCODE_NONE: args[2] = rb_str_new2("n"); break; case KCODE_EUC: args[2] = rb_str_new2("e"); break; case KCODE_SJIS: args[2] = rb_str_new2("s"); break; case KCODE_UTF8: args[2] = rb_str_new2("u"); break; } return rb_class_new_instance(3, args, rb_cRegexp); } } /* :nodoc: */ static VALUE rb_reg_init_copy(copy, re) VALUE copy, re; { if (copy == re) return copy; rb_check_frozen(copy); /* need better argument type check */ if (!rb_obj_is_instance_of(re, rb_obj_class(copy))) { rb_raise(rb_eTypeError, "wrong argument type"); } rb_reg_check(re); rb_reg_initialize(copy, RREGEXP(re)->str, RREGEXP(re)->len, rb_reg_options(re)); return copy; } VALUE rb_reg_regsub(str, src, regs) VALUE str, src; struct re_registers *regs; { VALUE val = 0; char *p, *s, *e, c; int no; p = s = RSTRING(str)->ptr; e = s + RSTRING(str)->len; while (s < e) { char *ss = s; c = *s++; if (ismbchar(c)) { s += mbclen(c) - 1; continue; } if (c != '\\' || s == e) continue; if (!val) { val = rb_str_buf_new(ss-p); rb_str_buf_cat(val, p, ss-p); } else { rb_str_buf_cat(val, p, ss-p); } c = *s++; p = s; switch (c) { case '0': case '1': case '2': case '3': case '4': case '5': case '6': case '7': case '8': case '9': no = c - '0'; break; case '&': no = 0; break; case '`': rb_str_buf_cat(val, RSTRING(src)->ptr, BEG(0)); continue; case '\'': rb_str_buf_cat(val, RSTRING(src)->ptr+END(0), RSTRING(src)->len-END(0)); continue; case '+': no = regs->num_regs-1; while (BEG(no) == -1 && no > 0) no--; if (no == 0) continue; break; case '\\': rb_str_buf_cat(val, s-1, 1); continue; default: rb_str_buf_cat(val, s-2, 2); continue; } if (no >= 0) { if (no >= regs->num_regs) continue; if (BEG(no) == -1) continue; rb_str_buf_cat(val, RSTRING(src)->ptr+BEG(no), END(no)-BEG(no)); } } if (p < e) { if (!val) { val = rb_str_buf_new(e-p); rb_str_buf_cat(val, p, e-p); } else { rb_str_buf_cat(val, p, e-p); } } if (!val) return str; return val; } const char* rb_get_kcode() { switch (reg_kcode) { case KCODE_SJIS: return "SJIS"; case KCODE_EUC: return "EUC"; case KCODE_UTF8: return "UTF8"; default: return "NONE"; } } static VALUE kcode_getter() { return rb_str_new2(rb_get_kcode()); } void rb_set_kcode(code) const char *code; { if (code == 0) goto set_no_conversion; switch (code[0]) { case 'E': case 'e': reg_kcode = KCODE_EUC; re_mbcinit(MBCTYPE_EUC); break; case 'S': case 's': reg_kcode = KCODE_SJIS; re_mbcinit(MBCTYPE_SJIS); break; case 'U': case 'u': reg_kcode = KCODE_UTF8; re_mbcinit(MBCTYPE_UTF8); break; default: case 'N': case 'n': case 'A': case 'a': set_no_conversion: reg_kcode = KCODE_NONE; re_mbcinit(MBCTYPE_ASCII); break; } } static void kcode_setter(val) VALUE val; { may_need_recompile = 1; rb_set_kcode(StringValuePtr(val)); } static VALUE ignorecase_getter() { return ruby_ignorecase?Qtrue:Qfalse; } static void ignorecase_setter(val, id) VALUE val; ID id; { rb_warn("modifying %s is deprecated", rb_id2name(id)); may_need_recompile = 1; ruby_ignorecase = RTEST(val); } static VALUE match_getter() { VALUE match = rb_backref_get(); if (NIL_P(match)) return Qnil; rb_match_busy(match); return match; } static void match_setter(val) VALUE val; { if (!NIL_P(val)) { Check_Type(val, T_MATCH); } rb_backref_set(val); } /* * call-seq: * Regexp.last_match => matchdata * Regexp.last_match(fixnum) => str * * The first form returns the MatchData object generated by the * last successful pattern match. Equivalent to reading the global variable * $~. The second form returns the nth field in this * MatchData object. * * /c(.)t/ =~ 'cat' #=> 0 * Regexp.last_match #=> # * Regexp.last_match(0) #=> "cat" * Regexp.last_match(1) #=> "a" * Regexp.last_match(2) #=> nil */ static VALUE rb_reg_s_last_match(argc, argv) int argc; VALUE *argv; { VALUE nth; if (rb_scan_args(argc, argv, "01", &nth) == 1) { return rb_reg_nth_match(NUM2INT(nth), rb_backref_get()); } return match_getter(); } /* * Document-class: Regexp * * A Regexp holds a regular expression, used to match a pattern * against strings. Regexps are created using the /.../ and * %r{...} literals, and by the Regexp::new * constructor. * */ void Init_Regexp() { rb_eRegexpError = rb_define_class("RegexpError", rb_eStandardError); re_set_casetable(casetable); #if DEFAULT_KCODE == KCODE_EUC re_mbcinit(MBCTYPE_EUC); #else #if DEFAULT_KCODE == KCODE_SJIS re_mbcinit(MBCTYPE_SJIS); #else #if DEFAULT_KCODE == KCODE_UTF8 re_mbcinit(MBCTYPE_UTF8); #else re_mbcinit(MBCTYPE_ASCII); #endif #endif #endif rb_define_virtual_variable("$~", match_getter, match_setter); rb_define_virtual_variable("$&", last_match_getter, 0); rb_define_virtual_variable("$`", prematch_getter, 0); rb_define_virtual_variable("$'", postmatch_getter, 0); rb_define_virtual_variable("$+", last_paren_match_getter, 0); rb_define_virtual_variable("$=", ignorecase_getter, ignorecase_setter); rb_define_virtual_variable("$KCODE", kcode_getter, kcode_setter); rb_define_virtual_variable("$-K", kcode_getter, kcode_setter); rb_cRegexp = rb_define_class("Regexp", rb_cObject); rb_define_alloc_func(rb_cRegexp, rb_reg_s_alloc); rb_define_singleton_method(rb_cRegexp, "compile", rb_class_new_instance, -1); rb_define_singleton_method(rb_cRegexp, "quote", rb_reg_s_quote, -1); rb_define_singleton_method(rb_cRegexp, "escape", rb_reg_s_quote, -1); rb_define_singleton_method(rb_cRegexp, "union", rb_reg_s_union, -1); rb_define_singleton_method(rb_cRegexp, "last_match", rb_reg_s_last_match, -1); rb_define_method(rb_cRegexp, "initialize", rb_reg_initialize_m, -1); rb_define_method(rb_cRegexp, "initialize_copy", rb_reg_init_copy, 1); rb_define_method(rb_cRegexp, "hash", rb_reg_hash, 0); rb_define_method(rb_cRegexp, "eql?", rb_reg_equal, 1); rb_define_method(rb_cRegexp, "==", rb_reg_equal, 1); rb_define_method(rb_cRegexp, "=~", rb_reg_match, 1); rb_define_method(rb_cRegexp, "===", rb_reg_eqq, 1); rb_define_method(rb_cRegexp, "~", rb_reg_match2, 0); rb_define_method(rb_cRegexp, "match", rb_reg_match_m, 1); rb_define_method(rb_cRegexp, "to_s", rb_reg_to_s, 0); rb_define_method(rb_cRegexp, "inspect", rb_reg_inspect, 0); rb_define_method(rb_cRegexp, "source", rb_reg_source, 0); rb_define_method(rb_cRegexp, "casefold?", rb_reg_casefold_p, 0); rb_define_method(rb_cRegexp, "options", rb_reg_options_m, 0); rb_define_method(rb_cRegexp, "kcode", rb_reg_kcode_m, 0); rb_define_const(rb_cRegexp, "IGNORECASE", INT2FIX(RE_OPTION_IGNORECASE)); rb_define_const(rb_cRegexp, "EXTENDED", INT2FIX(RE_OPTION_EXTENDED)); rb_define_const(rb_cRegexp, "MULTILINE", INT2FIX(RE_OPTION_MULTILINE)); rb_global_variable(®_cache); rb_cMatch = rb_define_class("MatchData", rb_cObject); rb_define_global_const("MatchingData", rb_cMatch); rb_define_alloc_func(rb_cMatch, match_alloc); rb_undef_method(CLASS_OF(rb_cMatch), "new"); rb_define_method(rb_cMatch, "initialize_copy", match_init_copy, 1); rb_define_method(rb_cMatch, "size", match_size, 0); rb_define_method(rb_cMatch, "length", match_size, 0); rb_define_method(rb_cMatch, "offset", match_offset, 1); rb_define_method(rb_cMatch, "begin", match_begin, 1); rb_define_method(rb_cMatch, "end", match_end, 1); rb_define_method(rb_cMatch, "to_a", match_to_a, 0); rb_define_method(rb_cMatch, "[]", match_aref, -1); rb_define_method(rb_cMatch, "captures", match_captures, 0); rb_define_method(rb_cMatch, "select", match_select, -1); rb_define_method(rb_cMatch, "values_at", match_values_at, -1); rb_define_method(rb_cMatch, "pre_match", rb_reg_match_pre, 0); rb_define_method(rb_cMatch, "post_match", rb_reg_match_post, 0); rb_define_method(rb_cMatch, "to_s", match_to_s, 0); rb_define_method(rb_cMatch, "inspect", rb_any_to_s, 0); /* in object.c */ rb_define_method(rb_cMatch, "string", match_string, 0); }