Class: MatchData
Overview
MatchData
encapsulates the result of matching a ::Regexp
against string. It is returned by Regexp#match and String#match, and also stored in a global variable returned by Regexp.last_match.
Usage:
url = 'https://docs.ruby-lang.org/en/2.5.0/MatchData.html'
m = url.match(/(\d\.?)+/) # => #<MatchData "2.5.0" 1:"0">
m.string # => "https://docs.ruby-lang.org/en/2.5.0/MatchData.html"
m.regexp # => /(\d\.?)+/
# entire matched substring:
m[0] # => "2.5.0"
# Working with unnamed captures
m = url.match(%r{([^/])/([^/])\.html$})
m.captures # => ["2.5.0", "MatchData"]
m[1] # => "2.5.0"
m.values_at(1, 2) # => ["2.5.0", "MatchData"]
# Working with named captures
m = url.match(%r{(?<version>[^/])/(?<module>[^/])\.html$})
m.captures # => ["2.5.0", "MatchData"]
m.named_captures # => {"version"=>"2.5.0", "module"=>"MatchData"}
m[:version] # => "2.5.0"
m.values_at(:version, :module)
# => ["2.5.0", "MatchData"]
# Numerical indexes are working, too
m[1] # => "2.5.0"
m.values_at(1, 2) # => ["2.5.0", "MatchData"]
Global variables equivalence
Parts of last MatchData
(returned by Regexp.last_match) are also aliased as global variables:
-
$~
isRegexp.last_match;
-
$&
is Regexp.last_match[ 0 ]
; -
$1
,$2
, and so on are Regexp.last_match[ i ]
(captures by number); -
$`
is Regexp.last_match.pre_match
; -
$'
is Regexp.last_match.post_match
; -
$+
is Regexp.last_match[ -1 ]
(the last capture).
See also “Special global variables” section in ::Regexp
documentation.
Instance Method Summary
-
#==(object) ⇒ Boolean
(also: #eql?)
Returns
true
ifobject
is another MatchData object whose target string, regexp, match, and captures are the same asself
,false
otherwise. - #[](index) ⇒ String?
-
#begin(n) ⇒ Integer
Returns the offset (in characters) of the beginning of the specified match.
-
#byteoffset(n) ⇒ Array
Returns a two-element array containing the beginning and ending byte-based offsets of the nth match.
-
#captures ⇒ Array
(also: #deconstruct)
Returns the array of captures, which are all matches except
m[0]
: -
#deconstruct ⇒ Array
Alias for #captures.
-
#deconstruct_keys(array_of_names) ⇒ Hash
Returns a hash of the named captures for the given names.
-
#end(n) ⇒ Integer
Returns the offset (in characters) of the end of the specified match.
-
#eql?(object) ⇒ Boolean
Alias for #==.
-
#hash ⇒ Integer
Returns the integer hash value for
self
, based on the target string, regexp, match, and captures. -
#inspect ⇒ String
Returns a string representation of
self
: -
#length ⇒ Integer
(also: #size)
Returns size of the match array:
-
#match(n) ⇒ String?
Returns the matched substring corresponding to the given argument.
-
#match_length(n) ⇒ Integer?
Returns the length (in characters) of the matched substring corresponding to the given argument.
-
#named_captures(symbolize_names: false) ⇒ Hash
Returns a hash of the named captures; each key is a capture name; each value is its captured string or
nil
: -
#names ⇒ array_of_names
Returns an array of the capture names (see
Named Captures
): -
#offset(n) ⇒ Array, end_offset
Returns a 2-element array containing the beginning and ending offsets (in characters) of the specified match.
-
#post_match ⇒ String
Returns the substring of the target string from the end of the first match in
self
(that is,self[0]
) to the end of the string; equivalent to regexp global variable$'
: -
#pre_match ⇒ String
Returns the substring of the target string from its beginning up to the first match in
self
(that is,self[0]
); equivalent to regexp global variable$`
: -
#regexp ⇒ Regexp
Returns the regexp that produced the match:
-
#size ⇒ Integer
Alias for #length.
-
#string ⇒ String
Returns the target string if it was frozen; otherwise, returns a frozen copy of the target string:
-
#to_a ⇒ Array
Returns the array of matches:
-
#to_s ⇒ String
Returns the matched string:
-
#values_at(*indexes) ⇒ Array
Returns match and captures at the given
indexes
, which may include any mixture of: - #initialize_copy(orig) Internal use only
Instance Method Details
#==(object) ⇒ Boolean
Also known as: #eql?
Returns true
if object
is another MatchData object whose target string, regexp, match, and captures are the same as self
, false
otherwise.
# File 're.c', line 3535
static VALUE match_equal(VALUE match1, VALUE match2) { const struct re_registers *regs1, *regs2; if (match1 == match2) return Qtrue; if (!RB_TYPE_P(match2, T_MATCH)) return Qfalse; if (!RMATCH(match1)->regexp || !RMATCH(match2)->regexp) return Qfalse; if (!rb_str_equal(RMATCH(match1)->str, RMATCH(match2)->str)) return Qfalse; if (!rb_reg_equal(match_regexp(match1), match_regexp(match2))) return Qfalse; regs1 = RMATCH_REGS(match1); regs2 = RMATCH_REGS(match2); if (regs1->num_regs != regs2->num_regs) return Qfalse; if (memcmp(regs1->beg, regs2->beg, regs1->num_regs * sizeof(*regs1->beg))) return Qfalse; if (memcmp(regs1->end, regs2->end, regs1->num_regs * sizeof(*regs1->end))) return Qfalse; return Qtrue; }
When arguments index
, +start and #length, or range
are given, returns match and captures in the style of Array#[]:
m = /(.)(.)(\d+)(\d)/.match("THX1138.")
# => #<MatchData "HX1138" 1:"H" 2:"X" 3:"113" 4:"8">
m[0] # => "HX1138"
m[1, 2] # => ["H", "X"]
m[1..3] # => ["H", "X", "113"]
m[-3, 2] # => ["X", "113"]
When string or symbol argument name
is given, returns the matched substring for the given name:
m = /(?<foo>.)(.)(?<bar>.+)/.match("hoge")
# => #<MatchData "hoge" foo:"h" bar:"ge">
m['foo'] # => "h"
m[: ] # => "ge"
If multiple captures have the same name, returns the last matched substring.
m = /(?<foo>.)(?<foo>.+)/.match("hoge")
# => #<MatchData "hoge" foo:"h" foo:"oge">
m[:foo] #=> "oge"
m = /\W(?<foo>.)|\w(?<foo>.)|(?<foo>.+)/.match("hoge")
#<MatchData "hoge" foo:nil foo:"oge" foo:nil>
m[:foo] #=> "oge"
# File 're.c', line 2186
static VALUE match_aref(int argc, VALUE *argv, VALUE match) { VALUE idx, length; match_check(match); rb_scan_args(argc, argv, "11", &idx, &length); if (NIL_P(length)) { if (FIXNUM_P(idx)) { return rb_reg_nth_match(FIX2INT(idx), match); } else { int num = namev_to_backref_number(RMATCH_REGS(match), RMATCH(match)->regexp, idx); if (num >= 0) { return rb_reg_nth_match(num, match); } else { return match_ary_aref(match, idx, Qnil); } } } else { long beg = NUM2LONG(idx); long len = NUM2LONG(length); long num_regs = RMATCH_REGS(match)->num_regs; if (len < 0) { return Qnil; } if (beg < 0) { beg += num_regs; if (beg < 0) return Qnil; } else if (beg > num_regs) { return Qnil; } if (beg+len > num_regs) { len = num_regs - beg; } return match_ary_subseq(match, beg, len, Qnil); } }
Returns the offset (in characters) of the beginning of the specified match.
When non-negative integer argument n
is given, returns the offset of the beginning of the n
th match:
m = /(.)(.)(\d+)(\d)/.match("THX1138.")
# => #<MatchData "HX1138" 1:"H" 2:"X" 3:"113" 4:"8">
m[0] # => "HX1138"
m.begin(0) # => 1
m[3] # => "113"
m.begin(3) # => 3
m = /(т)(е)(с)/.match('тест')
# => #<MatchData "тес" 1:"т" 2:"е" 3:"с">
m[0] # => "тес"
m.begin(0) # => 0
m[3] # => "с"
m.begin(3) # => 2
When string or symbol argument name
is given, returns the offset of the beginning for the named match:
m = /(?<foo>.)(.)(?<bar>.)/.match("hoge")
# => #<MatchData "hog" foo:"h" bar:"g">
m[:foo] # => "h"
m.begin('foo') # => 0
m[: ] # => "g"
m.begin(: ) # => 2
Related: #end, #offset, #byteoffset.
# File 're.c', line 1308
static VALUE match_begin(VALUE match, VALUE n) { int i = match_backref_number(match, n); struct re_registers *regs = RMATCH_REGS(match); match_check(match); backref_number_check(regs, i); if (BEG(i) < 0) return Qnil; update_char_offset(match); return LONG2NUM(RMATCH_EXT(match)->char_offset[i].beg); }
#byteoffset(n) ⇒ Array
Returns a two-element array containing the beginning and ending byte-based offsets of the nth match. n can be a string or symbol to reference a named capture.
m = /(.)(.)(\d+)(\d)/.match("THX1138.")
m.byteoffset(0) #=> [1, 7]
m.byteoffset(4) #=> [6, 7]
m = /(?<foo>.)(.)(?<bar>.)/.match("hoge")
p m.byteoffset(:foo) #=> [0, 1]
p m.byteoffset(: ) #=> [2, 3]
# File 're.c', line 1284
static VALUE match_byteoffset(VALUE match, VALUE n) { int i = match_backref_number(match, n); struct re_registers *regs = RMATCH_REGS(match); match_check(match); backref_number_check(regs, i); if (BEG(i) < 0) return rb_assoc_new(Qnil, Qnil); return rb_assoc_new(LONG2NUM(BEG(i)), LONG2NUM(END(i))); }
#captures ⇒ Array Also known as: #deconstruct
# File 're.c', line 2074
static VALUE match_captures(VALUE match) { return match_array(match, 1); }
Alias for #captures.
#deconstruct_keys(array_of_names) ⇒ Hash
Returns a hash of the named captures for the given names.
m = /(?<hours>\d{2}):(?<minutes>\d{2}):(?<seconds>\d{2})/.match("18:37:22")
m.deconstruct_keys([:hours, :minutes]) # => {:hours => "18", :minutes => "37"}
m.deconstruct_keys(nil) # => {:hours => "18", :minutes => "37", :seconds => "22"}
Returns an empty hash if no named captures were defined:
m = /(\d{2}):(\d{2}):(\d{2})/.match("18:37:22")
m.deconstruct_keys(nil) # => {}
# File 're.c', line 2429
static VALUE match_deconstruct_keys(VALUE match, VALUE keys) { VALUE h; long i; match_check(match); if (NIL_P(RMATCH(match)->regexp)) { return rb_hash_new_with_size(0); } if (NIL_P(keys)) { h = rb_hash_new_with_size(onig_number_of_names(RREGEXP_PTR(RMATCH(match)->regexp))); struct MEMO *memo; memo = MEMO_NEW(h, match, 1); onig_foreach_name(RREGEXP_PTR(RMATCH(match)->regexp), match_named_captures_iter, (void*)memo); return h; } Check_Type(keys, T_ARRAY); if (onig_number_of_names(RREGEXP_PTR(RMATCH(match)->regexp)) < RARRAY_LEN(keys)) { return rb_hash_new_with_size(0); } h = rb_hash_new_with_size(RARRAY_LEN(keys)); for (i=0; i<RARRAY_LEN(keys); i++) { VALUE key = RARRAY_AREF(keys, i); VALUE name; Check_Type(key, T_SYMBOL); name = rb_sym2str(key); int num = NAME_TO_NUMBER(RMATCH_REGS(match), RMATCH(match)->regexp, RMATCH(match)->regexp, RSTRING_PTR(name), RSTRING_END(name)); if (num >= 0) { rb_hash_aset(h, key, rb_reg_nth_match(num, match)); } else { return h; } } return h; }
Returns the offset (in characters) of the end of the specified match.
When non-negative integer argument n
is given, returns the offset of the end of the n
th match:
m = /(.)(.)(\d+)(\d)/.match("THX1138.")
# => #<MatchData "HX1138" 1:"H" 2:"X" 3:"113" 4:"8">
m[0] # => "HX1138"
m.end(0) # => 7
m[3] # => "113"
m.end(3) # => 6
m = /(т)(е)(с)/.match('тест')
# => #<MatchData "тес" 1:"т" 2:"е" 3:"с">
m[0] # => "тес"
m.end(0) # => 3
m[3] # => "с"
m.end(3) # => 3
When string or symbol argument name
is given, returns the offset of the end for the named match:
m = /(?<foo>.)(.)(?<bar>.)/.match("hoge")
# => #<MatchData "hog" foo:"h" bar:"g">
m[:foo] # => "h"
m.end('foo') # => 1
m[: ] # => "g"
m.end(: ) # => 3
Related: #begin, #offset, #byteoffset.
# File 're.c', line 1334
static VALUE match_end(VALUE match, VALUE n) { int i = match_backref_number(match, n); struct re_registers *regs = RMATCH_REGS(match); match_check(match); backref_number_check(regs, i); if (BEG(i) < 0) return Qnil; update_char_offset(match); return LONG2NUM(RMATCH_EXT(match)->char_offset[i].end); }
#==(object) ⇒ Boolean
#eql?(object) ⇒ Boolean
Boolean
#eql?(object) ⇒ Boolean
Alias for #==.
#hash ⇒ Integer
Returns the integer hash value for self
, based on the target string, regexp, match, and captures.
See also Object#hash.
# File 're.c', line 3509
static VALUE match_hash(VALUE match) { const struct re_registers *regs; st_index_t hashval; match_check(match); hashval = rb_hash_start(rb_str_hash(RMATCH(match)->str)); hashval = rb_hash_uint(hashval, reg_hash(match_regexp(match))); regs = RMATCH_REGS(match); hashval = rb_hash_uint(hashval, regs->num_regs); hashval = rb_hash_uint(hashval, rb_memhash(regs->beg, regs->num_regs * sizeof(*regs->beg))); hashval = rb_hash_uint(hashval, rb_memhash(regs->end, regs->num_regs * sizeof(*regs->end))); hashval = rb_hash_end(hashval); return ST2FIX(hashval); }
#initialize_copy(orig)
# File 're.c', line 1088
static VALUE match_init_copy(VALUE obj, VALUE orig) { rb_matchext_t *rm; if (!OBJ_INIT_COPY(obj, orig)) return obj; RB_OBJ_WRITE(obj, &RMATCH(obj)->str, RMATCH(orig)->str); RB_OBJ_WRITE(obj, &RMATCH(obj)->regexp, RMATCH(orig)->regexp); rm = RMATCH_EXT(obj); if (rb_reg_region_copy(&rm->regs, RMATCH_REGS(orig))) rb_memerror(); if (RMATCH_EXT(orig)->char_offset_num_allocated) { if (rm->char_offset_num_allocated < rm->regs.num_regs) { REALLOC_N(rm->char_offset, struct rmatch_offset, rm->regs.num_regs); rm->char_offset_num_allocated = rm->regs.num_regs; } MEMCPY(rm->char_offset, RMATCH_EXT(orig)->char_offset, struct rmatch_offset, rm->regs.num_regs); RB_GC_GUARD(orig); } return obj; }
#inspect ⇒ String
Returns a string representation of self
:
m = /.$/.match("foo")
# => #<MatchData "o">
m.inspect # => "#<MatchData \"o\">"
m = /(.)(.)(.)/.match("foo")
# => #<MatchData "foo" 1:"f" 2:"o" 3:"o">
m.inspect # => "#<MatchData \"foo\" 1:\"f\" 2:\"o\
m = /(.)(.)?(.)/.match("fo")
# => #<MatchData "fo" 1:"f" 2:nil 3:"o">
m.inspect # => "#<MatchData \"fo\" 1:\"f\" 2:nil 3:\"o\">"
Related: #to_s.
# File 're.c', line 2542
static VALUE match_inspect(VALUE match) { VALUE cname = rb_class_path(rb_obj_class(match)); VALUE str; int i; struct re_registers *regs = RMATCH_REGS(match); int num_regs = regs->num_regs; struct backref_name_tag *names; VALUE regexp = RMATCH(match)->regexp; if (regexp == 0) { return rb_sprintf("#<%"PRIsVALUE":%p>", cname, (void*)match); } else if (NIL_P(regexp)) { return rb_sprintf("#<%"PRIsVALUE": %"PRIsVALUE">", cname, rb_reg_nth_match(0, match)); } names = ALLOCA_N(struct backref_name_tag, num_regs); MEMZERO(names, struct backref_name_tag, num_regs); onig_foreach_name(RREGEXP_PTR(regexp), match_inspect_name_iter, names); str = rb_str_buf_new2("#<"); rb_str_append(str, cname); for (i = 0; i < num_regs; i++) { VALUE v; rb_str_buf_cat2(str, " "); if (0 < i) { if (names[i].name) rb_str_buf_cat(str, (const char *)names[i].name, names[i].len); else { rb_str_catf(str, "%d", i); } rb_str_buf_cat2(str, ":"); } v = rb_reg_nth_match(i, match); if (NIL_P(v)) rb_str_buf_cat2(str, "nil"); else rb_str_buf_append(str, rb_str_inspect(v)); } rb_str_buf_cat2(str, ">"); return str; }
#length ⇒ Integer Also known as: #size
# File 're.c', line 1183
static VALUE match_size(VALUE match) { match_check(match); return INT2FIX(RMATCH_REGS(match)->num_regs); }
Returns the matched substring corresponding to the given argument.
When non-negative argument n
is given, returns the matched substring for the n
th match:
m = /(.)(.)(\d+)(\d)(\w)?/.match("THX1138.")
# => #<MatchData "HX1138" 1:"H" 2:"X" 3:"113" 4:"8" 5:nil>
m.match(0) # => "HX1138"
m.match(4) # => "8"
m.match(5) # => nil
When string or symbol argument name
is given, returns the matched substring for the given name:
m = /(?<foo>.)(.)(?<bar>.+)/.match("hoge")
# => #<MatchData "hoge" foo:"h" bar:"ge">
m.match('foo') # => "h"
m.match(: ) # => "ge"
# File 're.c', line 1376
static VALUE match_nth(VALUE match, VALUE n) { int i = match_backref_number(match, n); struct re_registers *regs = RMATCH_REGS(match); backref_number_check(regs, i); long start = BEG(i), end = END(i); if (start < 0) return Qnil; return rb_str_subseq(RMATCH(match)->str, start, end - start); }
Returns the length (in characters) of the matched substring corresponding to the given argument.
When non-negative argument n
is given, returns the length of the matched substring for the n
th match:
m = /(.)(.)(\d+)(\d)(\w)?/.match("THX1138.")
# => #<MatchData "HX1138" 1:"H" 2:"X" 3:"113" 4:"8" 5:nil>
m.match_length(0) # => 6
m.match_length(4) # => 1
m.match_length(5) # => nil
When string or symbol argument name
is given, returns the length of the matched substring for the named match:
m = /(?<foo>.)(.)(?<bar>.+)/.match("hoge")
# => #<MatchData "hoge" foo:"h" bar:"ge">
m.match_length('foo') # => 1
m.match_length(: ) # => 2
# File 're.c', line 1420
static VALUE match_nth_length(VALUE match, VALUE n) { int i = match_backref_number(match, n); struct re_registers *regs = RMATCH_REGS(match); match_check(match); backref_number_check(regs, i); if (BEG(i) < 0) return Qnil; update_char_offset(match); const struct rmatch_offset *const ofs = &RMATCH_EXT(match)->char_offset[i]; return LONG2NUM(ofs->end - ofs->beg); }
#named_captures(symbolize_names: false) ⇒ Hash
Returns a hash of the named captures; each key is a capture name; each value is its captured string or nil
:
m = /(?<foo>.)(.)(?<bar>.+)/.match("hoge")
# => #<MatchData "hoge" foo:"h" bar:"ge">
m.named_captures # => {"foo"=>"h", "bar"=>"ge"}
m = /(?<a>.)(?<b>.)/.match("01")
# => #<MatchData "01" a:"0" b:"1">
m.named_captures #=> {"a" => "0", "b" => "1"}
m = /(?<a>.)(?<b>.)?/.match("0")
# => #<MatchData "0" a:"0" b:nil>
m.named_captures #=> {"a" => "0", "b" => nil}
m = /(?<a>.)(?<a>.)/.match("01")
# => #<MatchData "01" a:"0" a:"1">
m.named_captures #=> {"a" => "1"}
If keyword argument symbolize_names
is given a true value, the keys in the resulting hash are Symbols:
m = /(?<a>.)(?<a>.)/.match("01")
# => #<MatchData "01" a:"0" a:"1">
m.named_captures(symbolize_names: true) #=> {:a => "1"}
# File 're.c', line 2376
static VALUE match_named_captures(int argc, VALUE *argv, VALUE match) { VALUE hash; struct MEMO *memo; match_check(match); if (NIL_P(RMATCH(match)->regexp)) return rb_hash_new(); VALUE opt; VALUE symbolize_names = 0; rb_scan_args(argc, argv, "0:", &opt); if (!NIL_P(opt)) { static ID keyword_ids[1]; VALUE symbolize_names_val; if (!keyword_ids[0]) { keyword_ids[0] = rb_intern_const("symbolize_names"); } rb_get_kwargs(opt, keyword_ids, 0, 1, &symbolize_names_val); if (!UNDEF_P(symbolize_names_val) && RTEST(symbolize_names_val)) { symbolize_names = 1; } } hash = rb_hash_new(); memo = MEMO_NEW(hash, match, symbolize_names); onig_foreach_name(RREGEXP(RMATCH(match)->regexp)->ptr, match_named_captures_iter, (void*)memo); return hash; }
#names ⇒ array_of_names
Returns an array of the capture names (see Named Captures
):
m = /(?<foo>.)(?<bar>.)(?<baz>.)/.match("hoge")
# => #<MatchData "hog" foo:"h" bar:"o" baz:"g">
m.names # => ["foo", "bar", "baz"]
m = /foo/.match('foo') # => #<MatchData "foo">
m.names # => [] # No named captures.
Equivalent to:
m = /(?<foo>.)(?<bar>.)(?<baz>.)/.match("hoge")
m.regexp.names # => ["foo", "bar", "baz"]
# File 're.c', line 1162
static VALUE match_names(VALUE match) { match_check(match); if (NIL_P(RMATCH(match)->regexp)) return rb_ary_new_capa(0); return rb_reg_names(RMATCH(match)->regexp); }
Returns a 2-element array containing the beginning and ending offsets (in characters) of the specified match.
When non-negative integer argument n
is given, returns the starting and ending offsets of the n
th match:
m = /(.)(.)(\d+)(\d)/.match("THX1138.")
# => #<MatchData "HX1138" 1:"H" 2:"X" 3:"113" 4:"8">
m[0] # => "HX1138"
m.offset(0) # => [1, 7]
m[3] # => "113"
m.offset(3) # => [3, 6]
m = /(т)(е)(с)/.match('тест')
# => #<MatchData "тес" 1:"т" 2:"е" 3:"с">
m[0] # => "тес"
m.offset(0) # => [0, 3]
m[3] # => "с"
m.offset(3) # => [2, 3]
When string or symbol argument name
is given, returns the starting and ending offsets for the named match:
m = /(?<foo>.)(.)(?<bar>.)/.match("hoge")
# => #<MatchData "hog" foo:"h" bar:"g">
m[:foo] # => "h"
m.offset('foo') # => [0, 1]
m[: ] # => "g"
m.offset(: ) # => [2, 3]
Related: #byteoffset, #begin, #end.
# File 're.c', line 1249
static VALUE match_offset(VALUE match, VALUE n) { int i = match_backref_number(match, n); struct re_registers *regs = RMATCH_REGS(match); match_check(match); backref_number_check(regs, i); if (BEG(i) < 0) return rb_assoc_new(Qnil, Qnil); update_char_offset(match); return rb_assoc_new(LONG2NUM(RMATCH_EXT(match)->char_offset[i].beg), LONG2NUM(RMATCH_EXT(match)->char_offset[i].end)); }
#post_match ⇒ String
Returns the substring of the target string from the end of the first match in self
(that is, self[0]
) to the end of the string; equivalent to regexp global variable $'
:
m = /(.)(.)(\d+)(\d)/.match("THX1138: The Movie")
# => #<MatchData "HX1138" 1:"H" 2:"X" 3:"113" 4:"8">
m[0] # => "HX1138"
m.post_match # => ": The Movie"\
Related: #pre_match.
# File 're.c', line 1938
VALUE rb_reg_match_post(VALUE match) { VALUE str; long pos; struct re_registers *regs; if (NIL_P(match)) return Qnil; match_check(match); regs = RMATCH_REGS(match); if (BEG(0) == -1) return Qnil; str = RMATCH(match)->str; pos = END(0); str = rb_str_subseq(str, pos, RSTRING_LEN(str) - pos); return str; }
#pre_match ⇒ String
Returns the substring of the target string from its beginning up to the first match in self
(that is, self[0]
); equivalent to regexp global variable $`
:
m = /(.)(.)(\d+)(\d)/.match("THX1138.")
# => #<MatchData "HX1138" 1:"H" 2:"X" 3:"113" 4:"8">
m[0] # => "HX1138"
m.pre_match # => "T"
Related: #post_match.
# File 're.c', line 1905
VALUE rb_reg_match_pre(VALUE match) { VALUE str; struct re_registers *regs; if (NIL_P(match)) return Qnil; match_check(match); regs = RMATCH_REGS(match); if (BEG(0) == -1) return Qnil; str = rb_str_subseq(RMATCH(match)->str, 0, BEG(0)); return str; }
#regexp ⇒ Regexp
Returns the regexp that produced the match:
m = /a.*b/.match("abc") # => #<MatchData "ab">
m.regexp # => /a.*b/
# File 're.c', line 1127
static VALUE match_regexp(VALUE match) { VALUE regexp; match_check(match); regexp = RMATCH(match)->regexp; if (NIL_P(regexp)) { VALUE str = rb_reg_nth_match(0, match); regexp = rb_reg_regcomp(rb_reg_quote(str)); RB_OBJ_WRITE(match, &RMATCH(match)->regexp, regexp); } return regexp; }
Alias for #length.
#string ⇒ String
Returns the target string if it was frozen; otherwise, returns a frozen copy of the target string:
m = /(.)(.)(\d+)(\d)/.match("THX1138.")
# => #<MatchData "HX1138" 1:"H" 2:"X" 3:"113" 4:"8">
m.string # => "THX1138."
# File 're.c', line 2495
static VALUE match_string(VALUE match) { match_check(match); return RMATCH(match)->str; /* str is frozen */ }
#to_a ⇒ Array
# File 're.c', line 2052
static VALUE match_to_a(VALUE match) { return match_array(match, 0); }
#to_s ⇒ String
# File 're.c', line 2300
static VALUE match_to_s(VALUE match) { VALUE str = rb_reg_last_match(match_check(match)); if (NIL_P(str)) str = rb_str_new(0,0); return str; }
#values_at(*indexes) ⇒ Array
Returns match and captures at the given indexes
, which may include any mixture of:
-
Integers.
-
Ranges.
-
Names (strings and symbols).
Examples:
m = /(.)(.)(\d+)(\d)/.match("THX1138: The Movie")
# => #<MatchData "HX1138" 1:"H" 2:"X" 3:"113" 4:"8">
m.values_at(0, 2, -2) # => ["HX1138", "X", "113"]
m.values_at(1..2, -1) # => ["H", "X", "8"]
m = /(?<a>\d+) *(?<op>[+\-*\/]) *(?<b>\d+)/.match("1 + 2")
# => #<MatchData "1 + 2" a:"1" op:"+" b:"2">
m.values_at(0, 1..2, :a, :b, :op)
# => ["1 + 2", "1", "+", "1", "2", "+"]
# File 're.c', line 2255
static VALUE match_values_at(int argc, VALUE *argv, VALUE match) { VALUE result; int i; match_check(match); result = rb_ary_new2(argc); for (i=0; i<argc; i++) { if (FIXNUM_P(argv[i])) { rb_ary_push(result, rb_reg_nth_match(FIX2INT(argv[i]), match)); } else { int num = namev_to_backref_number(RMATCH_REGS(match), RMATCH(match)->regexp, argv[i]); if (num >= 0) { rb_ary_push(result, rb_reg_nth_match(num, match)); } else { match_ary_aref(match, argv[i], result); } } } return result; }