A String object holds and manipulates an arbitrary sequence of bytes, typically representing characters. String objects may be created using ::new or as literals.
Because of aliasing issues, users of strings should be aware of the methods that modify the contents of a String object. Typically, methods with names ending in “!” modify their receiver, while those without a “!” return a new String. However, there are exceptions, such as #[]=.
Returns a new String that is a copy of string
.
With no arguments, returns the empty string with the Encoding ASCII-8BIT
:
s = String.new s # => "" s.encoding # => #<Encoding:ASCII-8BIT>
With the single String argument string
, returns a copy of
string
with the same encoding as string
:
s = String.new("Que veut dire \u{e7}a?") s # => "Que veut dire \u{e7}a?" s.encoding # => #<Encoding:UTF-8>
Literal strings like ""
or here-documents always use
script
encoding, unlike ::new.
With keyword encoding
, returns a copy of str
with
the specified encoding:
s = String.new(encoding: 'ASCII') s.encoding # => #<Encoding:US-ASCII> s = String.new('foo', encoding: 'ASCII') s.encoding # => #<Encoding:US-ASCII>
Note that these are equivalent:
s0 = String.new('foo', encoding: 'ASCII') s1 = 'foo'.force_encoding('ASCII') s0.encoding == s1.encoding # => true
With keyword capacity
, returns a copy of str
; the
given capacity
may set the size of the internal buffer, which
may affect performance:
String.new(capacity: 1) # => "" String.new(capacity: 4096) # => ""
The string
, encoding
, and capacity
arguments may all be used together:
String.new('hello', encoding: 'UTF-8', capacity: 25)
static VALUE rb_str_init(int argc, VALUE *argv, VALUE str) { static ID keyword_ids[2]; VALUE orig, opt, venc, vcapa; VALUE kwargs[2]; rb_encoding *enc = 0; int n; if (!keyword_ids[0]) { keyword_ids[0] = rb_id_encoding(); CONST_ID(keyword_ids[1], "capacity"); } n = rb_scan_args(argc, argv, "01:", &orig, &opt); if (!NIL_P(opt)) { rb_get_kwargs(opt, keyword_ids, 0, 2, kwargs); venc = kwargs[0]; vcapa = kwargs[1]; if (venc != Qundef && !NIL_P(venc)) { enc = rb_to_encoding(venc); } if (vcapa != Qundef && !NIL_P(vcapa)) { long capa = NUM2LONG(vcapa); long len = 0; int termlen = enc ? rb_enc_mbminlen(enc) : 1; if (capa < STR_BUF_MIN_SIZE) { capa = STR_BUF_MIN_SIZE; } if (n == 1) { StringValue(orig); len = RSTRING_LEN(orig); if (capa < len) { capa = len; } if (orig == str) n = 0; } str_modifiable(str); if (STR_EMBED_P(str)) { /* make noembed always */ char *new_ptr = ALLOC_N(char, (size_t)capa + termlen); memcpy(new_ptr, RSTRING(str)->as.ary, RSTRING_EMBED_LEN_MAX + 1); RSTRING(str)->as.heap.ptr = new_ptr; } else if (FL_TEST(str, STR_SHARED|STR_NOFREE)) { const size_t size = (size_t)capa + termlen; const char *const old_ptr = RSTRING_PTR(str); const size_t osize = RSTRING(str)->as.heap.len + TERM_LEN(str); char *new_ptr = ALLOC_N(char, (size_t)capa + termlen); memcpy(new_ptr, old_ptr, osize < size ? osize : size); FL_UNSET_RAW(str, STR_SHARED); RSTRING(str)->as.heap.ptr = new_ptr; } else if (STR_HEAP_SIZE(str) != (size_t)capa + termlen) { SIZED_REALLOC_N(RSTRING(str)->as.heap.ptr, char, (size_t)capa + termlen, STR_HEAP_SIZE(str)); } RSTRING(str)->as.heap.len = len; TERM_FILL(&RSTRING(str)->as.heap.ptr[len], termlen); if (n == 1) { memcpy(RSTRING(str)->as.heap.ptr, RSTRING_PTR(orig), len); rb_enc_cr_str_exact_copy(str, orig); } FL_SET(str, STR_NOEMBED); RSTRING(str)->as.heap.aux.capa = capa; } else if (n == 1) { rb_str_replace(str, orig); } if (enc) { rb_enc_associate(str, enc); ENC_CODERANGE_CLEAR(str); } } else if (n == 1) { rb_str_replace(str, orig); } return str; }
If object
is a String object, returns object
.
Otherwise if object
responds to :to_str
, calls
object.to_str
and returns the result.
Returns nil
if object
does not respond to
:to_str
Raises an exception unless object.to_str
returns a String
object.
static VALUE rb_str_s_try_convert(VALUE dummy, VALUE str) { return rb_check_string_type(str); }
Returns the result of formatting object
into the format
specification self
(see Kernel#sprintf for formatting
details):
"%05d" % 123 # => "00123"
If self
contains multiple substitutions, object
must be an Array or Hash containing the values to be substituted:
"%-5s: %016x" % [ "ID", self.object_id ] # => "ID : 00002b054ec93168" "foo = %{foo}" % {foo: 'bar'} # => "foo = bar" "foo = %{foo}, baz = %{baz}" % {foo: 'bar', baz: 'bat'} # => "foo = bar, baz = bat"
static VALUE rb_str_format_m(VALUE str, VALUE arg) { VALUE tmp = rb_check_array_type(arg); if (!NIL_P(tmp)) { return rb_str_format(RARRAY_LENINT(tmp), RARRAY_CONST_PTR(tmp), str); } return rb_str_format(1, &arg, str); }
Returns a new String containing integer
copies of
self
:
"Ho! " * 3 # => "Ho! Ho! Ho! " "Ho! " * 0 # => ""
VALUE rb_str_times(VALUE str, VALUE times) { VALUE str2; long n, len; char *ptr2; int termlen; if (times == INT2FIX(1)) { return str_duplicate(rb_cString, str); } if (times == INT2FIX(0)) { str2 = str_alloc(rb_cString); rb_enc_copy(str2, str); return str2; } len = NUM2LONG(times); if (len < 0) { rb_raise(rb_eArgError, "negative argument"); } if (RSTRING_LEN(str) == 1 && RSTRING_PTR(str)[0] == 0) { str2 = str_alloc(rb_cString); if (!STR_EMBEDDABLE_P(len, 1)) { RSTRING(str2)->as.heap.aux.capa = len; RSTRING(str2)->as.heap.ptr = ZALLOC_N(char, (size_t)len + 1); STR_SET_NOEMBED(str2); } STR_SET_LEN(str2, len); rb_enc_copy(str2, str); return str2; } if (len && LONG_MAX/len < RSTRING_LEN(str)) { rb_raise(rb_eArgError, "argument too big"); } len *= RSTRING_LEN(str); termlen = TERM_LEN(str); str2 = str_new0(rb_cString, 0, len, termlen); ptr2 = RSTRING_PTR(str2); if (len) { n = RSTRING_LEN(str); memcpy(ptr2, RSTRING_PTR(str), n); while (n <= len/2) { memcpy(ptr2 + n, ptr2, n); n *= 2; } memcpy(ptr2 + n, ptr2, len-n); } STR_SET_LEN(str2, len); TERM_FILL(&ptr2[len], termlen); rb_enc_cr_str_copy_for_substr(str2, str); return str2; }
Returns a new String containing other_string
concatenated to
self
:
"Hello from " + self.to_s # => "Hello from main"
VALUE rb_str_plus(VALUE str1, VALUE str2) { VALUE str3; rb_encoding *enc; char *ptr1, *ptr2, *ptr3; long len1, len2; int termlen; StringValue(str2); enc = rb_enc_check_str(str1, str2); RSTRING_GETMEM(str1, ptr1, len1); RSTRING_GETMEM(str2, ptr2, len2); termlen = rb_enc_mbminlen(enc); if (len1 > LONG_MAX - len2) { rb_raise(rb_eArgError, "string size too big"); } str3 = str_new0(rb_cString, 0, len1+len2, termlen); ptr3 = RSTRING_PTR(str3); memcpy(ptr3, ptr1, len1); memcpy(ptr3+len1, ptr2, len2); TERM_FILL(&ptr3[len1+len2], termlen); ENCODING_CODERANGE_SET(str3, rb_enc_to_index(enc), ENC_CODERANGE_AND(ENC_CODERANGE(str1), ENC_CODERANGE(str2))); RB_GC_GUARD(str1); RB_GC_GUARD(str2); return str3; }
Returns self
if self
is not frozen.
Otherwise. returns self.dup
, which is not frozen.
static VALUE str_uplus(VALUE str) { if (OBJ_FROZEN(str)) { return rb_str_dup(str); } else { return str; } }
Returns a frozen, possibly pre-existing copy of the string.
The returned String will be deduplicated as long as it does not have any instance variables set on it.
static VALUE str_uminus(VALUE str) { if (!BARE_STRING_P(str) && !rb_obj_frozen_p(str)) { str = rb_str_dup(str); } return rb_fstring(str); }
Returns a new String containing the concatenation of self
and
object
:
s = 'foo' s << 'bar' # => "foobar"
If object
is an Integer, the value is considered a codepoint
and converted to a character before concatenation:
s = 'foo' s << 33 # => "foo!"
Related: #concat, which takes multiple arguments.
VALUE rb_str_concat(VALUE str1, VALUE str2) { unsigned int code; rb_encoding *enc = STR_ENC_GET(str1); int encidx; if (RB_INTEGER_TYPE_P(str2)) { if (rb_num_to_uint(str2, &code) == 0) { } else if (FIXNUM_P(str2)) { rb_raise(rb_eRangeError, "%ld out of char range", FIX2LONG(str2)); } else { rb_raise(rb_eRangeError, "bignum out of char range"); } } else { return rb_str_append(str1, str2); } encidx = rb_enc_to_index(enc); if (encidx == ENCINDEX_ASCII || encidx == ENCINDEX_US_ASCII) { /* US-ASCII automatically extended to ASCII-8BIT */ char buf[1]; buf[0] = (char)code; if (code > 0xFF) { rb_raise(rb_eRangeError, "%u out of char range", code); } rb_str_cat(str1, buf, 1); if (encidx == ENCINDEX_US_ASCII && code > 127) { rb_enc_associate_index(str1, ENCINDEX_ASCII); ENC_CODERANGE_SET(str1, ENC_CODERANGE_VALID); } } else { long pos = RSTRING_LEN(str1); int cr = ENC_CODERANGE(str1); int len; char *buf; switch (len = rb_enc_codelen(code, enc)) { case ONIGERR_INVALID_CODE_POINT_VALUE: rb_raise(rb_eRangeError, "invalid codepoint 0x%X in %s", code, rb_enc_name(enc)); break; case ONIGERR_TOO_BIG_WIDE_CHAR_VALUE: case 0: rb_raise(rb_eRangeError, "%u out of char range", code); break; } buf = ALLOCA_N(char, len + 1); rb_enc_mbcput(code, buf, enc); if (rb_enc_precise_mbclen(buf, buf + len + 1, enc) != len) { rb_raise(rb_eRangeError, "invalid codepoint 0x%X in %s", code, rb_enc_name(enc)); } rb_str_resize(str1, pos+len); memcpy(RSTRING_PTR(str1) + pos, buf, len); if (cr == ENC_CODERANGE_7BIT && code > 127) cr = ENC_CODERANGE_VALID; ENC_CODERANGE_SET(str1, cr); } return str1; }
Compares self
and other_string
, returning:
-1 if other_string
is smaller.
0 if the two are equal.
1 if other_string
is larger.
nil
if the two are incomparable.
Examples:
'foo' <=> 'foo' # => 0 'foo' <=> 'food' # => -1 'food' <=> 'foo' # => 1 'FOO' <=> 'foo' # => -1 'foo' <=> 'FOO' # => 1 'foo' <=> 1 # => nil
static VALUE rb_str_cmp_m(VALUE str1, VALUE str2) { int result; VALUE s = rb_check_string_type(str2); if (NIL_P(s)) { return rb_invcmp(str1, str2); } result = rb_str_cmp(str1, s); return INT2FIX(result); }
Returns true
if object
has the same length and
content; as self
; false
otherwise:
s = 'foo' s == 'foo' # => true s == 'food' # => false s == 'FOO' # => false
Returns false
if the two strings’ encodings are not
compatible:
"\u{e4 f6 fc}".encode("ISO-8859-1") == ("\u{c4 d6 dc}") # => false
If object
is not an instance of String but responds to
to_str
, then the two strings are compared using
object.==
.
VALUE rb_str_equal(VALUE str1, VALUE str2) { if (str1 == str2) return Qtrue; if (!RB_TYPE_P(str2, T_STRING)) { if (!rb_respond_to(str2, idTo_str)) { return Qfalse; } return rb_equal(str2, str1); } return rb_str_eql_internal(str1, str2); }
Returns true
if object
has the same length and
content; as self
; false
otherwise:
s = 'foo' s == 'foo' # => true s == 'food' # => false s == 'FOO' # => false
Returns false
if the two strings’ encodings are not
compatible:
"\u{e4 f6 fc}".encode("ISO-8859-1") == ("\u{c4 d6 dc}") # => false
If object
is not an instance of String but responds to
to_str
, then the two strings are compared using
object.==
.
VALUE rb_str_equal(VALUE str1, VALUE str2) { if (str1 == str2) return Qtrue; if (!RB_TYPE_P(str2, T_STRING)) { if (!rb_respond_to(str2, idTo_str)) { return Qfalse; } return rb_equal(str2, str1); } return rb_str_eql_internal(str1, str2); }
Returns the Integer index of the first substring that matches the given
regexp
, or nil
if no match found:
'foo' =~ /f/ # => 0 'foo' =~ /o/ # => 1 'foo' =~ /x/ # => nil
Note: also updates Regexp-related global variables.
If the given object
is not a Regexp, returns the value
returned by object =~ self
.
Note that string =~ regexp
is different from regexp =~
string
(see Regexp#=~):
number= nil "no. 9" =~ /(?<number>\d+)/ number # => nil (not assigned) /(?<number>\d+)/ =~ "no. 9" number #=> "9"
static VALUE rb_str_match(VALUE x, VALUE y) { switch (OBJ_BUILTIN_TYPE(y)) { case T_STRING: rb_raise(rb_eTypeError, "type mismatch: String given"); case T_REGEXP: return rb_reg_match(y, x); default: return rb_funcall(y, idEqTilde, 1, x); } }
Returns the substring of self
specified by the arguments.
When the single Integer argument index
is given, returns the
1-character substring found in self
at offset
index
:
'bar'[2] # => "r"
Counts backward from the end of self
if index
is
negative:
'foo'[-3] # => "f"
Returns nil
if index
is out of range:
'foo'[3] # => nil 'foo'[-4] # => nil
When the two Integer arguments start
and length
are given, returns the substring of the given length
found in
self
at offset start
:
'foo'[0, 2] # => "fo" 'foo'[0, 0] # => ""
Counts backward from the end of self
if start
is
negative:
'foo'[-2, 2] # => "oo"
Special case: returns a new empty String if start
is equal to
the length of self
:
'foo'[3, 2] # => ""
Returns nil
if start
is out of range:
'foo'[4, 2] # => nil 'foo'[-4, 2] # => nil
Returns the trailing substring of self
if length
is large:
'foo'[1, 50] # => "oo"
Returns nil
if length
is negative:
'foo'[0, -1] # => nil
When the single Range argument range
is given, derives
start
and length
values from the given
range
, and returns values as above:
'foo'[0..1]
is equivalent to 'foo'[0, 2]
.
'foo'[0...1]
is equivalent to 'foo'[0, 1]
.
When the Regexp argument regexp
is given, and the
capture
argument is 0
, returns the first matching
substring found in self
, or nil
if none found:
'foo'[/o/] # => "o" 'foo'[/x/] # => nil s = 'hello there' s[/[aeiou](.)\1/] # => "ell" s[/[aeiou](.)\1/, 0] # => "ell"
If argument capture
is given and not 0
, it should
be either an Integer capture group index or a String or Symbol capture
group name; the method call returns only the specified capture (see Regexp Capturing):
s = 'hello there' s[/[aeiou](.)\1/, 1] # => "l" s[/(?<vowel>[aeiou])(?<non_vowel>[^aeiou])/, "non_vowel"] # => "l" s[/(?<vowel>[aeiou])(?<non_vowel>[^aeiou])/, :vowel] # => "e"
If an invalid capture group index is given, nil
is returned.
If an invalid capture group name is given, IndexError
is
raised.
When the single String argument substring
is given, returns
the substring from self
if found, otherwise nil
:
'foo'['oo'] # => "oo" 'foo'['xx'] # => nil
static VALUE rb_str_aref_m(int argc, VALUE *argv, VALUE str) { if (argc == 2) { if (RB_TYPE_P(argv[0], T_REGEXP)) { return rb_str_subpat(str, argv[0], argv[1]); } else { long beg = NUM2LONG(argv[0]); long len = NUM2LONG(argv[1]); return rb_str_substr(str, beg, len); } } rb_check_arity(argc, 1, 2); return rb_str_aref(str, argv[0]); }
Element Assignment—Replaces some or all of the content of str. The portion of the string affected is determined using the same criteria as #[]. If the replacement string is not the same length as the text it is replacing, the string will be adjusted accordingly. If the regular expression or string is used as the index doesn’t match a position in the string, IndexError is raised. If the regular expression form is used, the optional second Integer allows you to specify which portion of the match to replace (effectively using the MatchData indexing rules. The forms that take an Integer will raise an IndexError if the value is out of range; the Range form will raise a RangeError, and the Regexp and String will raise an IndexError on negative match.
static VALUE rb_str_aset_m(int argc, VALUE *argv, VALUE str) { if (argc == 3) { if (RB_TYPE_P(argv[0], T_REGEXP)) { rb_str_subpat_set(str, argv[0], argv[1], argv[2]); } else { rb_str_splice(str, NUM2LONG(argv[0]), NUM2LONG(argv[1]), argv[2]); } return argv[2]; } rb_check_arity(argc, 2, 3); return rb_str_aset(str, argv[0], argv[1]); }
Returns true for a string which has only ASCII characters.
"abc".force_encoding("UTF-8").ascii_only? #=> true "abc\u{6666}".force_encoding("UTF-8").ascii_only? #=> false
static VALUE rb_str_is_ascii_only_p(VALUE str) { int cr = rb_enc_str_coderange(str); return cr == ENC_CODERANGE_7BIT ? Qtrue : Qfalse; }
Returns a copied string whose encoding is ASCII-8BIT.
static VALUE rb_str_b(VALUE str) { VALUE str2 = str_alloc(rb_cString); str_replace_shared_without_enc(str2, str); ENC_CODERANGE_CLEAR(str2); return str2; }
Returns an array of bytes in str. This is a shorthand for
str.each_byte.to_a
.
If a block is given, which is a deprecated form, works the same as
each_byte
.
static VALUE rb_str_bytes(VALUE str) { VALUE ary = WANTARRAY("bytes", RSTRING_LEN(str)); return rb_str_enumerate_bytes(str, ary); }
Returns the count of bytes in self
:
"\x80\u3042".bytesize # => 4 "hello".bytesize # => 5
Related: #length.
static VALUE rb_str_bytesize(VALUE str) { return LONG2NUM(RSTRING_LEN(str)); }
Byte Reference—If passed a single Integer,
returns a substring of one byte at that position. If passed two Integer objects, returns a substring starting at
the offset given by the first, and a length given by the second. If given a
Range, a substring containing bytes at offsets
given by the range is returned. In all three cases, if an offset is
negative, it is counted from the end of str. Returns
nil
if the initial offset falls outside the string, the length
is negative, or the beginning of the range is greater than the end. The
encoding of the resulted string keeps original encoding.
"hello".byteslice(1) #=> "e" "hello".byteslice(-1) #=> "o" "hello".byteslice(1, 2) #=> "el" "\x80\u3042".byteslice(1, 3) #=> "\u3042" "\x03\u3042\xff".byteslice(1..3) #=> "\u3042"
static VALUE rb_str_byteslice(int argc, VALUE *argv, VALUE str) { if (argc == 2) { long beg = NUM2LONG(argv[0]); long end = NUM2LONG(argv[1]); return str_byte_substr(str, beg, end, TRUE); } rb_check_arity(argc, 1, 2); return str_byte_aref(str, argv[0]); }
Returns a copy of str with the first character converted to uppercase and the remainder to lowercase.
See #downcase for meaning of
options
and use with different encodings.
"hello".capitalize #=> "Hello" "HELLO".capitalize #=> "Hello" "123ABC".capitalize #=> "123abc"
static VALUE rb_str_capitalize(int argc, VALUE *argv, VALUE str) { rb_encoding *enc; OnigCaseFoldType flags = ONIGENC_CASE_UPCASE | ONIGENC_CASE_TITLECASE; VALUE ret; flags = check_case_options(argc, argv, flags); enc = str_true_enc(str); if (RSTRING_LEN(str) == 0 || !RSTRING_PTR(str)) return str; if (flags&ONIGENC_CASE_ASCII_ONLY) { ret = rb_str_new(0, RSTRING_LEN(str)); rb_str_ascii_casemap(str, ret, &flags, enc); } else { ret = rb_str_casemap(str, &flags, enc); } return ret; }
Modifies str by converting the first character to uppercase and
the remainder to lowercase. Returns nil
if no changes are
made. There is an exception for modern Georgian (mkhedruli/MTAVRULI), where
the result is the same as for #downcase, to avoid mixed case.
See #downcase for meaning of
options
and use with different encodings.
a = "hello" a.capitalize! #=> "Hello" a #=> "Hello" a.capitalize! #=> nil
static VALUE rb_str_capitalize_bang(int argc, VALUE *argv, VALUE str) { rb_encoding *enc; OnigCaseFoldType flags = ONIGENC_CASE_UPCASE | ONIGENC_CASE_TITLECASE; flags = check_case_options(argc, argv, flags); str_modify_keep_cr(str); enc = str_true_enc(str); if (RSTRING_LEN(str) == 0 || !RSTRING_PTR(str)) return Qnil; if (flags&ONIGENC_CASE_ASCII_ONLY) rb_str_ascii_casemap(str, str, &flags, enc); else str_shared_replace(str, rb_str_casemap(str, &flags, enc)); if (ONIGENC_CASE_MODIFIED&flags) return str; return Qnil; }
Compares self
and other_string
, ignoring case,
and returning:
-1 if other_string
is smaller.
0 if the two are equal.
1 if other_string
is larger.
nil
if the two are incomparable.
Examples:
'foo'.casecmp('foo') # => 0 'foo'.casecmp('food') # => -1 'food'.casecmp('foo') # => 1 'FOO'.casecmp('foo') # => 0 'foo'.casecmp('FOO') # => 0 'foo'.casecmp(1) # => nil
static VALUE rb_str_casecmp(VALUE str1, VALUE str2) { VALUE s = rb_check_string_type(str2); if (NIL_P(s)) { return Qnil; } return str_casecmp(str1, s); }
Returns true
if self
and
other_string
are equal after Unicode case folding, otherwise
false
:
'foo'.casecmp?('foo') # => true 'foo'.casecmp?('food') # => false 'food'.casecmp?('foo') # => true 'FOO'.casecmp?('foo') # => true 'foo'.casecmp?('FOO') # => true
Returns nil
if the two values are incomparable:
'foo'.casecmp?(1) # => nil
static VALUE rb_str_casecmp_p(VALUE str1, VALUE str2) { VALUE s = rb_check_string_type(str2); if (NIL_P(s)) { return Qnil; } return str_casecmp_p(str1, s); }
Centers str
in width
. If width
is
greater than the length of str
, returns a new String of length width
with
str
centered and padded with padstr
; otherwise,
returns str
.
"hello".center(4) #=> "hello" "hello".center(20) #=> " hello " "hello".center(20, '123') #=> "1231231hello12312312"
static VALUE rb_str_center(int argc, VALUE *argv, VALUE str) { return rb_str_justify(argc, argv, str, 'c'); }
Returns an array of characters in str. This is a shorthand for
str.each_char.to_a
.
If a block is given, which is a deprecated form, works the same as
each_char
.
static VALUE rb_str_chars(VALUE str) { VALUE ary = WANTARRAY("chars", rb_str_strlen(str)); return rb_str_enumerate_chars(str, ary); }
Returns a new String with the given record
separator removed from the end of str (if present). If
$/
has not been changed from the default Ruby record
separator, then chomp
also removes carriage return characters
(that is it will remove \n
, \r
, and
\r\n
). If $/
is an empty string, it will remove
all trailing newlines from the string.
"hello".chomp #=> "hello" "hello\n".chomp #=> "hello" "hello\r\n".chomp #=> "hello" "hello\n\r".chomp #=> "hello\n" "hello\r".chomp #=> "hello" "hello \n there".chomp #=> "hello \n there" "hello".chomp("llo") #=> "he" "hello\r\n\r\n".chomp('') #=> "hello" "hello\r\n\r\r\n".chomp('') #=> "hello\r\n\r"
static VALUE rb_str_chomp(int argc, VALUE *argv, VALUE str) { VALUE rs = chomp_rs(argc, argv); if (NIL_P(rs)) return str_duplicate(rb_cString, str); return rb_str_subseq(str, 0, chompped_length(str, rs)); }
Modifies str in place as described for #chomp, returning str, or
nil
if no modifications were made.
static VALUE rb_str_chomp_bang(int argc, VALUE *argv, VALUE str) { VALUE rs; str_modifiable(str); if (RSTRING_LEN(str) == 0) return Qnil; rs = chomp_rs(argc, argv); if (NIL_P(rs)) return Qnil; return rb_str_chomp_string(str, rs); }
Returns a new String with the last character
removed. If the string ends with \r\n
, both characters are
removed. Applying chop
to an empty string returns an empty
string. #chomp is often a safer
alternative, as it leaves the string unchanged if it doesn’t end in a
record separator.
"string\r\n".chop #=> "string" "string\n\r".chop #=> "string\n" "string\n".chop #=> "string" "string".chop #=> "strin" "x".chop.chop #=> ""
static VALUE rb_str_chop(VALUE str) { return rb_str_subseq(str, 0, chopped_length(str)); }
Processes str as for #chop, returning str, or
nil
if str is the empty string. See also #chomp!.
static VALUE rb_str_chop_bang(VALUE str) { str_modify_keep_cr(str); if (RSTRING_LEN(str) > 0) { long len; len = chopped_length(str); STR_SET_LEN(str, len); TERM_FILL(&RSTRING_PTR(str)[len], TERM_LEN(str)); if (ENC_CODERANGE(str) != ENC_CODERANGE_7BIT) { ENC_CODERANGE_CLEAR(str); } return str; } return Qnil; }
Returns a one-character string at the beginning of the string.
a = "abcde" a.chr #=> "a"
static VALUE rb_str_chr(VALUE str) { return rb_str_substr(str, 0, 1); }
Makes string empty.
a = "abcde" a.clear #=> ""
static VALUE rb_str_clear(VALUE str) { str_discard(str); STR_SET_EMBED(str); STR_SET_EMBED_LEN(str, 0); RSTRING_PTR(str)[0] = 0; if (rb_enc_asciicompat(STR_ENC_GET(str))) ENC_CODERANGE_SET(str, ENC_CODERANGE_7BIT); else ENC_CODERANGE_SET(str, ENC_CODERANGE_VALID); return str; }
Returns an array of the Integer ordinals of the
characters in str. This is a shorthand for
str.each_codepoint.to_a
.
If a block is given, which is a deprecated form, works the same as
each_codepoint
.
static VALUE rb_str_codepoints(VALUE str) { VALUE ary = WANTARRAY("codepoints", rb_str_strlen(str)); return rb_str_enumerate_codepoints(str, ary); }
Returns a new String containing the concatenation of self
and
all objects in objects
:
s = 'foo' s.concat('bar', 'baz') # => "foobarbaz"
For each given object object
that is an Integer, the value is
considered a codepoint and converted to a character before concatenation:
s = 'foo' s.concat(32, 'bar', 32, 'baz') # => "foo bar baz"
Related: #<<, which takes a single argument.
static VALUE rb_str_concat_multi(int argc, VALUE *argv, VALUE str) { str_modifiable(str); if (argc == 1) { return rb_str_concat(str, argv[0]); } else if (argc > 1) { int i; VALUE arg_str = rb_str_tmp_new(0); rb_enc_copy(arg_str, str); for (i = 0; i < argc; i++) { rb_str_concat(arg_str, argv[i]); } rb_str_buf_append(str, arg_str); } return str; }
Each other_str
parameter defines a set of characters to count.
The intersection of these sets defines the characters to count in
str
. Any other_str
that starts with a caret
^
is negated. The sequence c1-c2
means all
characters between c1 and c2. The backslash character \
can
be used to escape ^
or -
and is otherwise ignored
unless it appears at the end of a sequence or the end of a
other_str
.
a = "hello world" a.count "lo" #=> 5 a.count "lo", "o" #=> 2 a.count "hello", "^l" #=> 4 a.count "ej-m" #=> 4 "hello^world".count "\\^aeiou" #=> 4 "hello-world".count "a\\-eo" #=> 4 c = "hello world\\r\\n" c.count "\\" #=> 2 c.count "\\A" #=> 0 c.count "X-\\w" #=> 3
static VALUE rb_str_count(int argc, VALUE *argv, VALUE str) { char table[TR_TABLE_SIZE]; rb_encoding *enc = 0; VALUE del = 0, nodel = 0, tstr; char *s, *send; int i; int ascompat; rb_check_arity(argc, 1, UNLIMITED_ARGUMENTS); tstr = argv[0]; StringValue(tstr); enc = rb_enc_check(str, tstr); if (argc == 1) { const char *ptstr; if (RSTRING_LEN(tstr) == 1 && rb_enc_asciicompat(enc) && (ptstr = RSTRING_PTR(tstr), ONIGENC_IS_ALLOWED_REVERSE_MATCH(enc, (const unsigned char *)ptstr, (const unsigned char *)ptstr+1)) && !is_broken_string(str)) { int n = 0; int clen; unsigned char c = rb_enc_codepoint_len(ptstr, ptstr+1, &clen, enc); s = RSTRING_PTR(str); if (!s || RSTRING_LEN(str) == 0) return INT2FIX(0); send = RSTRING_END(str); while (s < send) { if (*(unsigned char*)s++ == c) n++; } return INT2NUM(n); } } tr_setup_table(tstr, table, TRUE, &del, &nodel, enc); for (i=1; i<argc; i++) { tstr = argv[i]; StringValue(tstr); enc = rb_enc_check(str, tstr); tr_setup_table(tstr, table, FALSE, &del, &nodel, enc); } s = RSTRING_PTR(str); if (!s || RSTRING_LEN(str) == 0) return INT2FIX(0); send = RSTRING_END(str); ascompat = rb_enc_asciicompat(enc); i = 0; while (s < send) { unsigned int c; if (ascompat && (c = *(unsigned char*)s) < 0x80) { if (table[c]) { i++; } s++; } else { int clen; c = rb_enc_codepoint_len(s, send, &clen, enc); if (tr_find(c, table, del, nodel)) { i++; } s += clen; } } return INT2NUM(i); }
Returns the string generated by calling crypt(3)
standard
library function with str
and salt_str
, in this
order, as its arguments. Please do not use this method any longer. It is
legacy; provided only for backward compatibility with ruby scripts in
earlier days. It is bad to use in contemporary programs for several
reasons:
Behaviour of C’s crypt(3)
depends on the OS it is run. The
generated string lacks data portability.
On some OSes such as Mac OS, crypt(3)
never fails (i.e.
silently ends up in unexpected results).
On some OSes such as Mac OS, crypt(3)
is not thread safe.
So-called “traditional” usage of crypt(3)
is very very very
weak. According to its manpage, Linux’s traditional crypt(3)
output has only 2**56 variations; too easy to brute force today. And this
is the default behaviour.
In order to make things robust some OSes implement so-called “modular”
usage. To go through, you have to do a complex build-up of the
salt_str
parameter, by hand. Failure in generation of a proper
salt string tends not to yield any errors; typos in parameters are normally
not detectable.
For instance, in the following example, the second invocation of #crypt is wrong; it has a typo in “round=” (lacks “s”). However the call does not fail and something unexpected is generated.
"foo".crypt("$5$rounds=1000$salt$") # OK, proper usage "foo".crypt("$5$round=1000$salt$") # Typo not detected
Even in the “modular” mode, some hash functions are considered archaic and
no longer recommended at all; for instance module $1$
is
officially abandoned by its author: see phk.freebsd.dk/sagas/md5crypt_eol.html
. For another instance module $3$
is considered completely
broken: see the manpage of FreeBSD.
On some OS such as Mac OS, there is no modular mode. Yet, as written above,
crypt(3)
on Mac OS never fails. This means even if you build
up a proper salt string it generates a traditional DES hash anyways, and
there is no way for you to be aware of.
"foo".crypt("$5$rounds=1000$salt$") # => "$5fNPQMxC5j6."
If for some reason you cannot migrate to other secure contemporary password
hashing algorithms, install the string-crypt gem and require
'string/crypt'
to continue using it.
static VALUE rb_str_crypt(VALUE str, VALUE salt) { #ifdef HAVE_CRYPT_R VALUE databuf; struct crypt_data *data; # define CRYPT_END() ALLOCV_END(databuf) #else extern char *crypt(const char *, const char *); # define CRYPT_END() (void)0 #endif VALUE result; const char *s, *saltp; char *res; #ifdef BROKEN_CRYPT char salt_8bit_clean[3]; #endif StringValue(salt); mustnot_wchar(str); mustnot_wchar(salt); if (RSTRING_LEN(salt) < 2) { goto short_salt; } s = StringValueCStr(str); saltp = RSTRING_PTR(salt); if (!saltp[0] || !saltp[1]) goto short_salt; #ifdef BROKEN_CRYPT if (!ISASCII((unsigned char)saltp[0]) || !ISASCII((unsigned char)saltp[1])) { salt_8bit_clean[0] = saltp[0] & 0x7f; salt_8bit_clean[1] = saltp[1] & 0x7f; salt_8bit_clean[2] = '\0'; saltp = salt_8bit_clean; } #endif #ifdef HAVE_CRYPT_R data = ALLOCV(databuf, sizeof(struct crypt_data)); # ifdef HAVE_STRUCT_CRYPT_DATA_INITIALIZED data->initialized = 0; # endif res = crypt_r(s, saltp, data); #else res = crypt(s, saltp); #endif if (!res) { int err = errno; CRYPT_END(); rb_syserr_fail(err, "crypt"); } result = rb_str_new_cstr(res); CRYPT_END(); return result; short_salt: rb_raise(rb_eArgError, "salt too short (need >=2 bytes)"); UNREACHABLE_RETURN(Qundef); }
Returns a copy of str with all characters in the intersection of its arguments deleted. Uses the same rules for building the set of characters as #count.
"hello".delete "l","lo" #=> "heo" "hello".delete "lo" #=> "he" "hello".delete "aeiou", "^e" #=> "hell" "hello".delete "ej-m" #=> "ho"
static VALUE rb_str_delete(int argc, VALUE *argv, VALUE str) { str = str_duplicate(rb_cString, str); rb_str_delete_bang(argc, argv, str); return str; }
Performs a delete
operation in place, returning str,
or nil
if str was not modified.
static VALUE rb_str_delete_bang(int argc, VALUE *argv, VALUE str) { char squeez[TR_TABLE_SIZE]; rb_encoding *enc = 0; char *s, *send, *t; VALUE del = 0, nodel = 0; int modify = 0; int i, ascompat, cr; if (RSTRING_LEN(str) == 0 || !RSTRING_PTR(str)) return Qnil; rb_check_arity(argc, 1, UNLIMITED_ARGUMENTS); for (i=0; i<argc; i++) { VALUE s = argv[i]; StringValue(s); enc = rb_enc_check(str, s); tr_setup_table(s, squeez, i==0, &del, &nodel, enc); } str_modify_keep_cr(str); ascompat = rb_enc_asciicompat(enc); s = t = RSTRING_PTR(str); send = RSTRING_END(str); cr = ascompat ? ENC_CODERANGE_7BIT : ENC_CODERANGE_VALID; while (s < send) { unsigned int c; int clen; if (ascompat && (c = *(unsigned char*)s) < 0x80) { if (squeez[c]) { modify = 1; } else { if (t != s) *t = c; t++; } s++; } else { c = rb_enc_codepoint_len(s, send, &clen, enc); if (tr_find(c, squeez, del, nodel)) { modify = 1; } else { if (t != s) rb_enc_mbcput(c, t, enc); t += clen; if (cr == ENC_CODERANGE_7BIT) cr = ENC_CODERANGE_VALID; } s += clen; } } TERM_FILL(t, TERM_LEN(str)); STR_SET_LEN(str, t - RSTRING_PTR(str)); ENC_CODERANGE_SET(str, cr); if (modify) return str; return Qnil; }
Returns a copy of str with leading prefix
deleted.
"hello".delete_prefix("hel") #=> "lo" "hello".delete_prefix("llo") #=> "hello"
static VALUE rb_str_delete_prefix(VALUE str, VALUE prefix) { long prefixlen; prefixlen = deleted_prefix_length(str, prefix); if (prefixlen <= 0) return str_duplicate(rb_cString, str); return rb_str_subseq(str, prefixlen, RSTRING_LEN(str) - prefixlen); }
Deletes leading prefix
from str, returning
nil
if no change was made.
"hello".delete_prefix!("hel") #=> "lo" "hello".delete_prefix!("llo") #=> nil
static VALUE rb_str_delete_prefix_bang(VALUE str, VALUE prefix) { long prefixlen; str_modify_keep_cr(str); prefixlen = deleted_prefix_length(str, prefix); if (prefixlen <= 0) return Qnil; return rb_str_drop_bytes(str, prefixlen); }
Returns a copy of str with trailing suffix
deleted.
"hello".delete_suffix("llo") #=> "he" "hello".delete_suffix("hel") #=> "hello"
static VALUE rb_str_delete_suffix(VALUE str, VALUE suffix) { long suffixlen; suffixlen = deleted_suffix_length(str, suffix); if (suffixlen <= 0) return str_duplicate(rb_cString, str); return rb_str_subseq(str, 0, RSTRING_LEN(str) - suffixlen); }
Deletes trailing suffix
from str, returning
nil
if no change was made.
"hello".delete_suffix!("llo") #=> "he" "hello".delete_suffix!("hel") #=> nil
static VALUE rb_str_delete_suffix_bang(VALUE str, VALUE suffix) { long olen, suffixlen, len; str_modifiable(str); suffixlen = deleted_suffix_length(str, suffix); if (suffixlen <= 0) return Qnil; olen = RSTRING_LEN(str); str_modify_keep_cr(str); len = olen - suffixlen; STR_SET_LEN(str, len); TERM_FILL(&RSTRING_PTR(str)[len], TERM_LEN(str)); if (ENC_CODERANGE(str) != ENC_CODERANGE_7BIT) { ENC_CODERANGE_CLEAR(str); } return str; }
Returns a copy of str with all uppercase letters replaced with
their lowercase counterparts. Which letters exactly are replaced, and by
which other letters, depends on the presence or absence of options, and on
the encoding
of the string.
The meaning of the options
is as follows:
Full Unicode case mapping, suitable for most languages (see :turkic and :lithuanian options below for exceptions). Context-dependent case mapping as described in Table 3-14 of the Unicode standard is currently not supported.
Only the ASCII region, i.e. the characters “A” to “Z” and “a” to “z”, are affected. This option cannot be combined with any other option.
Full Unicode case mapping, adapted for Turkic languages (Turkish, Azerbaijani, …). This means that upper case I is mapped to lower case dotless i, and so on.
Currently, just full Unicode case mapping. In the future, full Unicode case mapping adapted for Lithuanian (keeping the dot on the lower case i even if there is an accent on top).
Only available on downcase
and downcase!
. Unicode
case folding, which is more far-reaching than Unicode case
mapping. This option currently cannot be combined with any other option
(i.e. there is currently no variant for turkic languages).
Please note that several assumptions that are valid for ASCII-only case conversions do not hold for more general case conversions. For example, the length of the result may not be the same as the length of the input (neither in characters nor in bytes), some roundtrip assumptions (e.g. str.downcase == str.upcase.downcase) may not apply, and Unicode normalization (i.e. #unicode_normalize) is not necessarily maintained by case mapping operations.
Non-ASCII case mapping/folding is currently supported for UTF-8, UTF-16BE/LE, UTF-32BE/LE, and ISO-8859-1~16 Strings/Symbols. This support will be extended to other encodings.
"hEllO".downcase #=> "hello"
static VALUE rb_str_downcase(int argc, VALUE *argv, VALUE str) { rb_encoding *enc; OnigCaseFoldType flags = ONIGENC_CASE_DOWNCASE; VALUE ret; flags = check_case_options(argc, argv, flags); enc = str_true_enc(str); if (case_option_single_p(flags, enc, str)) { ret = rb_str_new(RSTRING_PTR(str), RSTRING_LEN(str)); str_enc_copy(ret, str); downcase_single(ret); } else if (flags&ONIGENC_CASE_ASCII_ONLY) { ret = rb_str_new(0, RSTRING_LEN(str)); rb_str_ascii_casemap(str, ret, &flags, enc); } else { ret = rb_str_casemap(str, &flags, enc); } return ret; }
Downcases the contents of str, returning nil
if no
changes were made.
See #downcase for meaning of
options
and use with different encodings.
static VALUE rb_str_downcase_bang(int argc, VALUE *argv, VALUE str) { rb_encoding *enc; OnigCaseFoldType flags = ONIGENC_CASE_DOWNCASE; flags = check_case_options(argc, argv, flags); str_modify_keep_cr(str); enc = str_true_enc(str); if (case_option_single_p(flags, enc, str)) { if (downcase_single(str)) flags |= ONIGENC_CASE_MODIFIED; } else if (flags&ONIGENC_CASE_ASCII_ONLY) rb_str_ascii_casemap(str, str, &flags, enc); else str_shared_replace(str, rb_str_casemap(str, &flags, enc)); if (ONIGENC_CASE_MODIFIED&flags) return str; return Qnil; }
Returns a quoted version of the string with all non-printing characters
replaced by \xHH
notation and all special characters escaped.
This method can be used for round-trip: if the resulting
new_str
is eval’ed, it will produce the original string.
"hello \n ''".dump #=> "\"hello \\n ''\"" "\f\x00\xff\\\"".dump #=> "\"\\f\\x00\\xFF\\\\\\\"\""
See also #undump.
VALUE rb_str_dump(VALUE str) { int encidx = rb_enc_get_index(str); rb_encoding *enc = rb_enc_from_index(encidx); long len; const char *p, *pend; char *q, *qend; VALUE result; int u8 = (encidx == rb_utf8_encindex()); static const char nonascii_suffix[] = ".dup.force_encoding(\"%s\")"; len = 2; /* "" */ if (!rb_enc_asciicompat(enc)) { len += strlen(nonascii_suffix) - rb_strlen_lit("%s"); len += strlen(enc->name); } p = RSTRING_PTR(str); pend = p + RSTRING_LEN(str); while (p < pend) { int clen; unsigned char c = *p++; switch (c) { case '"': case '\\': case '\n': case '\r': case '\t': case '\f': case '\013': case '\010': case '\007': case '\033': clen = 2; break; case '#': clen = IS_EVSTR(p, pend) ? 2 : 1; break; default: if (ISPRINT(c)) { clen = 1; } else { if (u8 && c > 0x7F) { /* \u notation */ int n = rb_enc_precise_mbclen(p-1, pend, enc); if (MBCLEN_CHARFOUND_P(n)) { unsigned int cc = rb_enc_mbc_to_codepoint(p-1, pend, enc); if (cc <= 0xFFFF) clen = 6; /* \uXXXX */ else if (cc <= 0xFFFFF) clen = 9; /* \u{XXXXX} */ else clen = 10; /* \u{XXXXXX} */ p += MBCLEN_CHARFOUND_LEN(n)-1; break; } } clen = 4; /* \xNN */ } break; } if (clen > LONG_MAX - len) { rb_raise(rb_eRuntimeError, "string size too big"); } len += clen; } result = rb_str_new(0, len); p = RSTRING_PTR(str); pend = p + RSTRING_LEN(str); q = RSTRING_PTR(result); qend = q + len + 1; *q++ = '"'; while (p < pend) { unsigned char c = *p++; if (c == '"' || c == '\\') { *q++ = '\\'; *q++ = c; } else if (c == '#') { if (IS_EVSTR(p, pend)) *q++ = '\\'; *q++ = '#'; } else if (c == '\n') { *q++ = '\\'; *q++ = 'n'; } else if (c == '\r') { *q++ = '\\'; *q++ = 'r'; } else if (c == '\t') { *q++ = '\\'; *q++ = 't'; } else if (c == '\f') { *q++ = '\\'; *q++ = 'f'; } else if (c == '\013') { *q++ = '\\'; *q++ = 'v'; } else if (c == '\010') { *q++ = '\\'; *q++ = 'b'; } else if (c == '\007') { *q++ = '\\'; *q++ = 'a'; } else if (c == '\033') { *q++ = '\\'; *q++ = 'e'; } else if (ISPRINT(c)) { *q++ = c; } else { *q++ = '\\'; if (u8) { int n = rb_enc_precise_mbclen(p-1, pend, enc) - 1; if (MBCLEN_CHARFOUND_P(n)) { int cc = rb_enc_mbc_to_codepoint(p-1, pend, enc); p += n; if (cc <= 0xFFFF) snprintf(q, qend-q, "u%04X", cc); /* \uXXXX */ else snprintf(q, qend-q, "u{%X}", cc); /* \u{XXXXX} or \u{XXXXXX} */ q += strlen(q); continue; } } snprintf(q, qend-q, "x%02X", c); q += 3; } } *q++ = '"'; *q = '\0'; if (!rb_enc_asciicompat(enc)) { snprintf(q, qend-q, nonascii_suffix, enc->name); encidx = rb_ascii8bit_encindex(); } /* result from dump is ASCII */ rb_enc_associate_index(result, encidx); ENC_CODERANGE_SET(result, ENC_CODERANGE_7BIT); return result; }
Passes each byte in str to the given block, or returns an enumerator if no block is given.
"hello".each_byte {|c| print c, ' ' }
produces:
104 101 108 108 111
static VALUE rb_str_each_byte(VALUE str) { RETURN_SIZED_ENUMERATOR(str, 0, 0, rb_str_each_byte_size); return rb_str_enumerate_bytes(str, 0); }
Passes each character in str to the given block, or returns an enumerator if no block is given.
"hello".each_char {|c| print c, ' ' }
produces:
h e l l o
static VALUE rb_str_each_char(VALUE str) { RETURN_SIZED_ENUMERATOR(str, 0, 0, rb_str_each_char_size); return rb_str_enumerate_chars(str, 0); }
Passes the Integer ordinal of each character in str, also known as a codepoint when applied to Unicode strings to the given block. For encodings other than UTF-8/UTF-16(BE|LE)/UTF-32(BE|LE), values are directly derived from the binary representation of each character.
If no block is given, an enumerator is returned instead.
"hello\u0639".each_codepoint {|c| print c, ' ' }
produces:
104 101 108 108 111 1593
static VALUE rb_str_each_codepoint(VALUE str) { RETURN_SIZED_ENUMERATOR(str, 0, 0, rb_str_each_char_size); return rb_str_enumerate_codepoints(str, 0); }
Passes each grapheme cluster in str to the given block, or returns an enumerator if no block is given. Unlike #each_char, this enumerates by grapheme clusters defined by Unicode Standard Annex #29 unicode.org/reports/tr29/
"a\u0300".each_char.to_a.size #=> 2 "a\u0300".each_grapheme_cluster.to_a.size #=> 1
static VALUE rb_str_each_grapheme_cluster(VALUE str) { RETURN_SIZED_ENUMERATOR(str, 0, 0, rb_str_each_grapheme_cluster_size); return rb_str_enumerate_grapheme_clusters(str, 0); }
Splits str using the supplied parameter as the record separator
($/
by default), passing each substring in turn to the
supplied block. If a zero-length record separator is supplied, the string
is split into paragraphs delimited by multiple successive newlines.
If chomp
is true
, separator
will be
removed from the end of each line.
If no block is given, an enumerator is returned instead.
"hello\nworld".each_line {|s| p s} # prints: # "hello\n" # "world" "hello\nworld".each_line('l') {|s| p s} # prints: # "hel" # "l" # "o\nworl" # "d" "hello\n\n\nworld".each_line('') {|s| p s} # prints # "hello\n\n" # "world" "hello\nworld".each_line(chomp: true) {|s| p s} # prints: # "hello" # "world" "hello\nworld".each_line('l', chomp: true) {|s| p s} # prints: # "he" # "" # "o\nwor" # "d"
static VALUE rb_str_each_line(int argc, VALUE *argv, VALUE str) { RETURN_SIZED_ENUMERATOR(str, argc, argv, 0); return rb_str_enumerate_lines(argc, argv, str, 0); }
Returns true
if the length of self
is zero,
false
otherwise:
"hello".empty? # => false " ".empty? # => false "".empty? # => true
static VALUE rb_str_empty(VALUE str) { if (RSTRING_LEN(str) == 0) return Qtrue; return Qfalse; }
The first form returns a copy of str
transcoded to encoding
encoding
. The second form returns a copy of str
transcoded from src_encoding to dst_encoding. The last form returns a copy
of str
transcoded to Encoding.default_internal
.
By default, the first and second form raise Encoding::UndefinedConversionError for characters that are undefined in the destination encoding, and Encoding::InvalidByteSequenceError for invalid byte sequences in the source encoding. The last form by default does not raise exceptions but uses replacement strings.
The options
keyword arguments give details for conversion. The
arguments are:
If the value is :replace
, encode replaces invalid byte
sequences in str
with the replacement character. The default
is to raise the Encoding::InvalidByteSequenceError
exception
If the value is :replace
, encode replaces characters which are
undefined in the destination encoding with the replacement character. The
default is to raise the Encoding::UndefinedConversionError.
Sets the replacement string to the given value. The default replacement string is “uFFFD” for Unicode encoding forms, and “?” otherwise.
Sets the replacement string by the given object for undefined character. The object should be a Hash, a Proc, a Method, or an object which has [] method. Its key is an undefined character encoded in the source encoding of current transcoder. Its value can be any encoding until it can be converted into the destination encoding of the transcoder.
The value must be :text
or :attr
. If the value is
:text
encode
replaces undefined characters with their (upper-case hexadecimal) numeric
character references. ‘&’, ‘<’, and ‘>’ are converted to
“&”, “<”, and “>”, respectively. If the value is
:attr
, encode also
quotes the replacement result (using ‘“’), and replaces ‘”’ with
“"”.
Replaces LF (“n”) with CR (“r”) if value is true.
Replaces LF (“n”) with CRLF (“rn”) if value is true.
Replaces CRLF (“rn”) and CR (“r”) with LF (“n”) if value is true.
static VALUE str_encode(int argc, VALUE *argv, VALUE str) { VALUE newstr = str; int encidx = str_transcode(argc, argv, &newstr); return encoded_dup(newstr, str, encidx); }
The first form transcodes the contents of str from str.encoding to
encoding
. The second form transcodes the contents of
str from src_encoding to dst_encoding. The options
keyword arguments give details for conversion. See #encode for details. Returns the
string even if no changes were made.
static VALUE str_encode_bang(int argc, VALUE *argv, VALUE str) { VALUE newstr; int encidx; rb_check_frozen(str); newstr = str; encidx = str_transcode(argc, argv, &newstr); if (encidx < 0) return str; if (newstr == str) { rb_enc_associate_index(str, encidx); return str; } rb_str_shared_replace(str, newstr); return str_encode_associate(str, encidx); }
Returns the Encoding object that represents the encoding of obj.
VALUE rb_obj_encoding(VALUE obj) { int idx = rb_enc_get_index(obj); if (idx < 0) { rb_raise(rb_eTypeError, "unknown encoding"); } return rb_enc_from_encoding_index(idx & ENC_INDEX_MASK); }
Returns true if str
ends with one of the suffixes
given.
"hello".end_with?("ello") #=> true # returns true if one of the +suffixes+ matches. "hello".end_with?("heaven", "ello") #=> true "hello".end_with?("heaven", "paradise") #=> false
static VALUE rb_str_end_with(int argc, VALUE *argv, VALUE str) { int i; char *p, *s, *e; rb_encoding *enc; for (i=0; i<argc; i++) { VALUE tmp = argv[i]; StringValue(tmp); enc = rb_enc_check(str, tmp); if (RSTRING_LEN(str) < RSTRING_LEN(tmp)) continue; p = RSTRING_PTR(str); e = p + RSTRING_LEN(str); s = e - RSTRING_LEN(tmp); if (rb_enc_left_char_head(p, s, e, enc) != s) continue; if (memcmp(s, RSTRING_PTR(tmp), RSTRING_LEN(tmp)) == 0) return Qtrue; } return Qfalse; }
Returns true
if object
has the same length and
content; as self
; false
otherwise:
s = 'foo' s.eql?('foo') # => true s.eql?('food') # => false s.eql?('FOO') # => false
Returns false
if the two strings’ encodings are not
compatible:
"\u{e4 f6 fc}".encode("ISO-8859-1").eql?("\u{c4 d6 dc}") # => false
MJIT_FUNC_EXPORTED VALUE rb_str_eql(VALUE str1, VALUE str2) { if (str1 == str2) return Qtrue; if (!RB_TYPE_P(str2, T_STRING)) return Qfalse; return rb_str_eql_internal(str1, str2); }
Changes the encoding to encoding
and returns self.
static VALUE rb_str_force_encoding(VALUE str, VALUE enc) { str_modifiable(str); rb_enc_associate(str, rb_to_encoding(enc)); ENC_CODERANGE_CLEAR(str); return str; }
VALUE rb_str_freeze(VALUE str) { if (OBJ_FROZEN(str)) return str; rb_str_resize(str, RSTRING_LEN(str)); return rb_obj_freeze(str); }
returns the indexth byte as an integer.
static VALUE rb_str_getbyte(VALUE str, VALUE index) { long pos = NUM2LONG(index); if (pos < 0) pos += RSTRING_LEN(str); if (pos < 0 || RSTRING_LEN(str) <= pos) return Qnil; return INT2FIX((unsigned char)RSTRING_PTR(str)[pos]); }
Returns an array of grapheme clusters in str. This is a shorthand
for str.each_grapheme_cluster.to_a
.
If a block is given, which is a deprecated form, works the same as
each_grapheme_cluster
.
static VALUE rb_str_grapheme_clusters(VALUE str) { VALUE ary = WANTARRAY("grapheme_clusters", rb_str_strlen(str)); return rb_str_enumerate_grapheme_clusters(str, ary); }
Returns a copy of str with all occurrences of
pattern substituted for the second argument. The pattern
is typically a Regexp; if given as a String, any regular expression metacharacters it
contains will be interpreted literally, e.g. \d
will match a
backslash followed by ‘d’, instead of a digit.
If replacement
is a String it will
be substituted for the matched text. It may contain back-references to the
pattern’s capture groups of the form \d
, where d is a
group number, or \k<n>
, where n is a group
name. Similarly, \&
, \'
, \`
, and
+
correspond to special variables, $&
,
$'
, $`
, and $+
, respectively. (See
regexp.rdoc for details.) \0
is the same as
\&
. \\
is interpreted as an escape, i.e., a
single backslash. Note that, within replacement
the special
match variables, such as $&
, will not refer to the current
match.
If the second argument is a Hash, and the matched text is one of its keys, the corresponding value is the replacement string.
In the block form, the current match string is passed in as a parameter,
and variables such as $1
, $2
, $`
,
$&
, and $'
will be set appropriately. (See
regexp.rdoc for details.) The value returned by the block will be
substituted for the match on each call.
When neither a block nor a second argument is supplied, an Enumerator is returned.
"hello".gsub(/[aeiou]/, '*') #=> "h*ll*" "hello".gsub(/([aeiou])/, '<\1>') #=> "h<e>ll<o>" "hello".gsub(/./) {|s| s.ord.to_s + ' '} #=> "104 101 108 108 111 " "hello".gsub(/(?<foo>[aeiou])/, '{\k<foo>}') #=> "h{e}ll{o}" 'hello'.gsub(/[eo]/, 'e' => 3, 'o' => '*') #=> "h3ll*"
Note that a string literal consumes backslashes. (See syntax/literals.rdoc
for details on string literals.) Back-references are typically preceded by
an additional backslash. For example, if you want to write a back-reference
\&
in replacement
with a double-quoted string
literal, you need to write: "..\\&.."
. If you
want to write a non-back-reference string \&
in
replacement
, you need first to escape the backslash to prevent
this method from interpreting it as a back-reference, and then you need to
escape the backslashes again to prevent a string literal from consuming
them: "..\\\\&.."
. You may want to use the block
form to avoid a lot of backslashes.
static VALUE rb_str_gsub(int argc, VALUE *argv, VALUE str) { return str_gsub(argc, argv, str, 0); }
Performs the substitutions of #gsub
in place, returning str, or nil
if no substitutions
were performed. If no block and no replacement is given, an
enumerator is returned instead.
static VALUE rb_str_gsub_bang(int argc, VALUE *argv, VALUE str) { str_modify_keep_cr(str); return str_gsub(argc, argv, str, 1); }
Returns the integer hash value for self
. The value is based on
the length, content and encoding of self
.
static VALUE rb_str_hash_m(VALUE str) { st_index_t hval = rb_str_hash(str); return ST2FIX(hval); }
Treats leading characters from str as a string of hexadecimal
digits (with an optional sign and an optional 0x
) and returns
the corresponding number. Zero is returned on error.
"0x0a".hex #=> 10 "-1234".hex #=> -4660 "0".hex #=> 0 "wombat".hex #=> 0
static VALUE rb_str_hex(VALUE str) { return rb_str_to_inum(str, 16, FALSE); }
Returns true
if str contains the given string or
character.
"hello".include? "lo" #=> true "hello".include? "ol" #=> false "hello".include? ?h #=> true
static VALUE rb_str_include(VALUE str, VALUE arg) { long i; StringValue(arg); i = rb_str_index(str, arg, 0); if (i == -1) return Qfalse; return Qtrue; }
Returns the Integer index of the first occurrence of the given
substring
, or nil
if none found:
'foo'.index('f') # => 0 'foo'.index('o') # => 1 'foo'.index('oo') # => 1 'foo'.index('ooo') # => nil
Returns the Integer index of the first match for the given Regexp
regexp
, or nil
if none found:
'foo'.index(/f/) # => 0 'foo'.index(/o/) # => 1 'foo'.index(/oo/) # => 1 'foo'.index(/ooo/) # => nil
Integer argument offset
, if given, specifies the position in
the string to begin the search:
'foo'.index('o', 1) # => 1 'foo'.index('o', 2) # => 2 'foo'.index('o', 3) # => nil
If offset
is negative, counts backward from the end of
self
:
'foo'.index('o', -1) # => 2 'foo'.index('o', -2) # => 1 'foo'.index('o', -3) # => 1 'foo'.index('o', -4) # => nil
Related: #rindex
static VALUE rb_str_index_m(int argc, VALUE *argv, VALUE str) { VALUE sub; VALUE initpos; long pos; if (rb_scan_args(argc, argv, "11", &sub, &initpos) == 2) { pos = NUM2LONG(initpos); } else { pos = 0; } if (pos < 0) { pos += str_strlen(str, NULL); if (pos < 0) { if (RB_TYPE_P(sub, T_REGEXP)) { rb_backref_set(Qnil); } return Qnil; } } if (RB_TYPE_P(sub, T_REGEXP)) { if (pos > str_strlen(str, NULL)) return Qnil; pos = str_offset(RSTRING_PTR(str), RSTRING_END(str), pos, rb_enc_check(str, sub), single_byte_optimizable(str)); if (rb_reg_search(sub, str, pos, 0) < 0) { return Qnil; } else { VALUE match = rb_backref_get(); struct re_registers *regs = RMATCH_REGS(match); pos = rb_str_sublen(str, BEG(0)); return LONG2NUM(pos); } } else { StringValue(sub); pos = rb_str_index(str, sub, pos); pos = rb_str_sublen(str, pos); } if (pos == -1) return Qnil; return LONG2NUM(pos); }
Replaces the contents of str with the corresponding values in other_str.
s = "hello" #=> "hello" s.replace "world" #=> "world"
VALUE rb_str_replace(VALUE str, VALUE str2) { str_modifiable(str); if (str == str2) return str; StringValue(str2); str_discard(str); return str_replace(str, str2); }
Inserts the given other_string
into self
; returns
self
.
If the Integer index
is positive, inserts
other_string
at offset index
:
'foo'.insert(1, 'bar') # => "fbaroo"
If the Integer index
is negative, counts backward from the end
of self
and inserts other_string
at offset
index+1
(that is, after self[index]
):
'foo'.insert(-2, 'bar') # => "fobaro"
static VALUE rb_str_insert(VALUE str, VALUE idx, VALUE str2) { long pos = NUM2LONG(idx); if (pos == -1) { return rb_str_append(str, str2); } else if (pos < 0) { pos++; } rb_str_splice(str, pos, 0, str2); return str; }
Returns a printable version of str, surrounded by quote marks, with special characters escaped.
str = "hello" str[3] = "\b" str.inspect #=> "\"hel\\bo\""
VALUE rb_str_inspect(VALUE str) { int encidx = ENCODING_GET(str); rb_encoding *enc = rb_enc_from_index(encidx), *actenc; const char *p, *pend, *prev; char buf[CHAR_ESC_LEN + 1]; VALUE result = rb_str_buf_new(0); rb_encoding *resenc = rb_default_internal_encoding(); int unicode_p = rb_enc_unicode_p(enc); int asciicompat = rb_enc_asciicompat(enc); if (resenc == NULL) resenc = rb_default_external_encoding(); if (!rb_enc_asciicompat(resenc)) resenc = rb_usascii_encoding(); rb_enc_associate(result, resenc); str_buf_cat2(result, "\""); p = RSTRING_PTR(str); pend = RSTRING_END(str); prev = p; actenc = get_actual_encoding(encidx, str); if (actenc != enc) { enc = actenc; if (unicode_p) unicode_p = rb_enc_unicode_p(enc); } while (p < pend) { unsigned int c, cc; int n; n = rb_enc_precise_mbclen(p, pend, enc); if (!MBCLEN_CHARFOUND_P(n)) { if (p > prev) str_buf_cat(result, prev, p - prev); n = rb_enc_mbminlen(enc); if (pend < p + n) n = (int)(pend - p); while (n--) { snprintf(buf, CHAR_ESC_LEN, "\\x%02X", *p & 0377); str_buf_cat(result, buf, strlen(buf)); prev = ++p; } continue; } n = MBCLEN_CHARFOUND_LEN(n); c = rb_enc_mbc_to_codepoint(p, pend, enc); p += n; if ((asciicompat || unicode_p) && (c == '"'|| c == '\\' || (c == '#' && p < pend && MBCLEN_CHARFOUND_P(rb_enc_precise_mbclen(p,pend,enc)) && (cc = rb_enc_codepoint(p,pend,enc), (cc == '$' || cc == '@' || cc == '{'))))) { if (p - n > prev) str_buf_cat(result, prev, p - n - prev); str_buf_cat2(result, "\\"); if (asciicompat || enc == resenc) { prev = p - n; continue; } } switch (c) { case '\n': cc = 'n'; break; case '\r': cc = 'r'; break; case '\t': cc = 't'; break; case '\f': cc = 'f'; break; case '\013': cc = 'v'; break; case '\010': cc = 'b'; break; case '\007': cc = 'a'; break; case 033: cc = 'e'; break; default: cc = 0; break; } if (cc) { if (p - n > prev) str_buf_cat(result, prev, p - n - prev); buf[0] = '\\'; buf[1] = (char)cc; str_buf_cat(result, buf, 2); prev = p; continue; } if ((enc == resenc && rb_enc_isprint(c, enc)) || (asciicompat && rb_enc_isascii(c, enc) && ISPRINT(c))) { continue; } else { if (p - n > prev) str_buf_cat(result, prev, p - n - prev); rb_str_buf_cat_escaped_char(result, c, unicode_p); prev = p; continue; } } if (p > prev) str_buf_cat(result, prev, p - prev); str_buf_cat2(result, "\""); return result; }
Returns the Symbol corresponding to str, creating the symbol if it did not previously exist. See Symbol#id2name.
"Koala".intern #=> :Koala s = 'cat'.to_sym #=> :cat s == :cat #=> true s = '@cat'.to_sym #=> :@cat s == :@cat #=> true
This can also be used to create symbols that cannot be represented using
the :xxx
notation.
'cat and dog'.to_sym #=> :"cat and dog"
VALUE rb_str_intern(VALUE str) { VALUE sym; #if USE_SYMBOL_GC rb_encoding *enc, *ascii; int type; #else ID id; #endif GLOBAL_SYMBOLS_ENTER(symbols); { sym = lookup_str_sym_with_lock(symbols, str); if (sym) { // ok } else { #if USE_SYMBOL_GC enc = rb_enc_get(str); ascii = rb_usascii_encoding(); if (enc != ascii && sym_check_asciionly(str)) { str = rb_str_dup(str); rb_enc_associate(str, ascii); OBJ_FREEZE(str); enc = ascii; } else { str = rb_str_dup(str); OBJ_FREEZE(str); } str = rb_fstring(str); type = rb_str_symname_type(str, IDSET_ATTRSET_FOR_INTERN); if (type < 0) type = ID_JUNK; sym = dsymbol_alloc(symbols, rb_cSymbol, str, enc, type); #else id = intern_str(str, 0); sym = ID2SYM(id); #endif } } GLOBAL_SYMBOLS_LEAVE(); return sym; }
Returns an array of lines in str split using the supplied record
separator ($/
by default). This is a shorthand for
str.each_line(separator, getline_args).to_a
.
If chomp
is true
, separator
will be
removed from the end of each line.
"hello\nworld\n".lines #=> ["hello\n", "world\n"] "hello world".lines(' ') #=> ["hello ", " ", "world"] "hello\nworld\n".lines(chomp: true) #=> ["hello", "world"]
If a block is given, which is a deprecated form, works the same as
each_line
.
static VALUE rb_str_lines(int argc, VALUE *argv, VALUE str) { VALUE ary = WANTARRAY("lines", 0); return rb_str_enumerate_lines(argc, argv, str, ary); }
If integer is greater than the length of str, returns a new String of length integer with str left justified and padded with padstr; otherwise, returns str.
"hello".ljust(4) #=> "hello" "hello".ljust(20) #=> "hello " "hello".ljust(20, '1234') #=> "hello123412341234123"
static VALUE rb_str_ljust(int argc, VALUE *argv, VALUE str) { return rb_str_justify(argc, argv, str, 'l'); }
Returns a copy of the receiver with leading whitespace removed. See also #rstrip and #strip.
Refer to #strip for the definition of whitespace.
" hello ".lstrip #=> "hello " "hello".lstrip #=> "hello"
static VALUE rb_str_lstrip(VALUE str) { char *start; long len, loffset; RSTRING_GETMEM(str, start, len); loffset = lstrip_offset(str, start, start+len, STR_ENC_GET(str)); if (loffset <= 0) return str_duplicate(rb_cString, str); return rb_str_subseq(str, loffset, len - loffset); }
Removes leading whitespace from the receiver. Returns the altered receiver,
or nil
if no change was made. See also #rstrip! and #strip!.
Refer to #strip for the definition of whitespace.
" hello ".lstrip! #=> "hello " "hello ".lstrip! #=> nil "hello".lstrip! #=> nil
static VALUE rb_str_lstrip_bang(VALUE str) { rb_encoding *enc; char *start, *s; long olen, loffset; str_modify_keep_cr(str); enc = STR_ENC_GET(str); RSTRING_GETMEM(str, start, olen); loffset = lstrip_offset(str, start, start+olen, enc); if (loffset > 0) { long len = olen-loffset; s = start + loffset; memmove(start, s, len); STR_SET_LEN(str, len); #if !SHARABLE_MIDDLE_SUBSTRING TERM_FILL(start+len, rb_enc_mbminlen(enc)); #endif return str; } return Qnil; }
Returns a Matchdata object (or nil
) based on self
and the given pattern
.
Note: also updates Regexp-related global variables.
Computes regexp
by converting pattern
(if not
already a Regexp).
regexp = Regexp.new(pattern)
Computes matchdata
, which will be either a MatchData object or
nil
(see Regexp#match):
matchdata = <tt>regexp.match(self)
With no block given, returns the computed matchdata
:
'foo'.match('f') # => #<MatchData "f"> 'foo'.match('o') # => #<MatchData "o"> 'foo'.match('x') # => nil
If Integer argument offset
is given, the search begins at
index offset
:
'foo'.match('f', 1) # => nil 'foo'.match('o', 1) # => #<MatchData "o">
With a block given, calls the block with the computed
matchdata
and returns the block’s return value:
'foo'.match(/o/) {|matchdata| matchdata } # => #<MatchData "o"> 'foo'.match(/x/) {|matchdata| matchdata } # => nil 'foo'.match(/f/, 1) {|matchdata| matchdata } # => nil
static VALUE rb_str_match_m(int argc, VALUE *argv, VALUE str) { VALUE re, result; if (argc < 1) rb_check_arity(argc, 1, 2); re = argv[0]; argv[0] = str; result = rb_funcallv(get_pat(re), rb_intern("match"), argc, argv); if (!NIL_P(result) && rb_block_given_p()) { return rb_yield(result); } return result; }
Returns true
or false
based on whether a match is
found for self
and pattern
.
Note: does not update Regexp-related global variables.
Computes regexp
by converting pattern
(if not
already a Regexp).
regexp = Regexp.new(pattern)
Returns true
if self+.match(regexp)
returns a
Matchdata object, false
otherwise:
'foo'.match?(/o/) # => true 'foo'.match?('o') # => true 'foo'.match?(/x/) # => false
If Integer argument offset
is given, the search begins at
index offset
:
'foo'.match?('f', 1) # => false 'foo'.match?('o', 1) # => true
static VALUE rb_str_match_m_p(int argc, VALUE *argv, VALUE str) { VALUE re; rb_check_arity(argc, 1, 2); re = get_pat(argv[0]); return rb_reg_match_p(re, str, argc > 1 ? NUM2LONG(argv[1]) : 0); }
Returns the successor to self
. The successor is calculated by
incrementing characters.
The first character to be incremented is the rightmost alphanumeric: or, if no alphanumerics, the rightmost character:
'THX1138'.succ # => "THX1139" '<<koala>>'.succ # => "<<koalb>>" '***'.succ # => '**+'
The successor to a digit is another digit, “carrying” to the next-left character for a “rollover” from 9 to 0, and prepending another digit if necessary:
'00'.succ # => "01" '09'.succ # => "10" '99'.succ # => "100"
The successor to a letter is another letter of the same case, carrying to the next-left character for a rollover, and prepending another same-case letter if necessary:
'aa'.succ # => "ab" 'az'.succ # => "ba" 'zz'.succ # => "aaa" 'AA'.succ # => "AB" 'AZ'.succ # => "BA" 'ZZ'.succ # => "AAA"
The successor to a non-alphanumeric character is the next character in the underlying character set’s collating sequence, carrying to the next-left character for a rollover, and prepending another character if necessary:
s = 0.chr * 3 s # => "\x00\x00\x00" s.succ # => "\x00\x00\x01" s = 255.chr * 3 s # => "\xFF\xFF\xFF" s.succ # => "\x01\x00\x00\x00"
Carrying can occur between and among mixtures of alphanumeric characters:
s = 'zz99zz99' s.succ # => "aaa00aa00" s = '99zz99zz' s.succ # => "100aa00aa"
The successor to an empty String is a new empty String:
''.succ # => ""
VALUE rb_str_succ(VALUE orig) { VALUE str; str = rb_str_new(RSTRING_PTR(orig), RSTRING_LEN(orig)); rb_enc_cr_str_copy_for_substr(str, orig); return str_succ(str); }
Treats leading characters of str as a string of octal digits (with an optional sign) and returns the corresponding number. Returns 0 if the conversion fails.
"123".oct #=> 83 "-377".oct #=> -255 "bad".oct #=> 0 "0377bad".oct #=> 255
If str
starts with 0
, radix indicators are
honored. See Kernel#Integer.
static VALUE rb_str_oct(VALUE str) { return rb_str_to_inum(str, -8, FALSE); }
Returns the Integer ordinal of a one-character string.
"a".ord #=> 97
static VALUE rb_str_ord(VALUE s) { unsigned int c; c = rb_enc_codepoint(RSTRING_PTR(s), RSTRING_END(s), STR_ENC_GET(s)); return UINT2NUM(c); }
Searches sep or pattern (regexp) in the string and returns the part before it, the match, and the part after it. If it is not found, returns two empty strings and str.
"hello".partition("l") #=> ["he", "l", "lo"] "hello".partition("x") #=> ["hello", "", ""] "hello".partition(/.l/) #=> ["h", "el", "lo"]
static VALUE rb_str_partition(VALUE str, VALUE sep) { long pos; sep = get_pat_quoted(sep, 0); if (RB_TYPE_P(sep, T_REGEXP)) { if (rb_reg_search(sep, str, 0, 0) < 0) { goto failed; } VALUE match = rb_backref_get(); struct re_registers *regs = RMATCH_REGS(match); pos = BEG(0); sep = rb_str_subseq(str, pos, END(0) - pos); } else { pos = rb_str_index(str, sep, 0); if (pos < 0) goto failed; } return rb_ary_new3(3, rb_str_subseq(str, 0, pos), sep, rb_str_subseq(str, pos+RSTRING_LEN(sep), RSTRING_LEN(str)-pos-RSTRING_LEN(sep))); failed: return rb_ary_new3(3, str_duplicate(rb_cString, str), str_new_empty_String(str), str_new_empty_String(str)); }
Returns a new String containing the concatenation of all given
other_strings
and self
:
s = 'foo' s.prepend('bar', 'baz') # => "barbazfoo"
Related: #concat.
static VALUE rb_str_prepend_multi(int argc, VALUE *argv, VALUE str) { str_modifiable(str); if (argc == 1) { rb_str_update(str, 0L, 0L, argv[0]); } else if (argc > 1) { int i; VALUE arg_str = rb_str_tmp_new(0); rb_enc_copy(arg_str, str); for (i = 0; i < argc; i++) { rb_str_append(arg_str, argv[i]); } rb_str_update(str, 0L, 0L, arg_str); } return str; }
Replaces the contents of str with the corresponding values in other_str.
s = "hello" #=> "hello" s.replace "world" #=> "world"
VALUE rb_str_replace(VALUE str, VALUE str2) { str_modifiable(str); if (str == str2) return str; StringValue(str2); str_discard(str); return str_replace(str, str2); }
Returns a new string with the characters from str in reverse order.
"stressed".reverse #=> "desserts"
static VALUE rb_str_reverse(VALUE str) { rb_encoding *enc; VALUE rev; char *s, *e, *p; int cr; if (RSTRING_LEN(str) <= 1) return str_duplicate(rb_cString, str); enc = STR_ENC_GET(str); rev = rb_str_new(0, RSTRING_LEN(str)); s = RSTRING_PTR(str); e = RSTRING_END(str); p = RSTRING_END(rev); cr = ENC_CODERANGE(str); if (RSTRING_LEN(str) > 1) { if (single_byte_optimizable(str)) { while (s < e) { *--p = *s++; } } else if (cr == ENC_CODERANGE_VALID) { while (s < e) { int clen = rb_enc_fast_mbclen(s, e, enc); p -= clen; memcpy(p, s, clen); s += clen; } } else { cr = rb_enc_asciicompat(enc) ? ENC_CODERANGE_7BIT : ENC_CODERANGE_VALID; while (s < e) { int clen = rb_enc_mbclen(s, e, enc); if (clen > 1 || (*s & 0x80)) cr = ENC_CODERANGE_UNKNOWN; p -= clen; memcpy(p, s, clen); s += clen; } } } STR_SET_LEN(rev, RSTRING_LEN(str)); str_enc_copy(rev, str); ENC_CODERANGE_SET(rev, cr); return rev; }
Reverses str in place.
static VALUE rb_str_reverse_bang(VALUE str) { if (RSTRING_LEN(str) > 1) { if (single_byte_optimizable(str)) { char *s, *e, c; str_modify_keep_cr(str); s = RSTRING_PTR(str); e = RSTRING_END(str) - 1; while (s < e) { c = *s; *s++ = *e; *e-- = c; } } else { str_shared_replace(str, rb_str_reverse(str)); } } else { str_modify_keep_cr(str); } return str; }
Returns the Integer index of the last occurrence of the given
substring
, or nil
if none found:
'foo'.rindex('f') # => 0 'foo'.rindex('o') # => 2 'foo'.rindex('oo') # => 1 'foo'.rindex('ooo') # => nil
Returns the Integer index of the last match for the given Regexp
regexp
, or nil
if none found:
'foo'.rindex(/f/) # => 0 'foo'.rindex(/o/) # => 2 'foo'.rindex(/oo/) # => 1 'foo'.rindex(/ooo/) # => nil
Integer argument offset
, if given and non-negative, specifies
the maximum starting position in the
string to _end_ the search: 'foo'.rindex('o', 0) # => nil 'foo'.rindex('o', 1) # => 1 'foo'.rindex('o', 2) # => 2 'foo'.rindex('o', 3) # => 2
If offset
is a negative Integer, the maximum starting position
in the string to end the search is the sum of the string’s length
and offset
:
'foo'.rindex('o', -1) # => 2 'foo'.rindex('o', -2) # => 1 'foo'.rindex('o', -3) # => nil 'foo'.rindex('o', -4) # => nil
Related: #index
static VALUE rb_str_rindex_m(int argc, VALUE *argv, VALUE str) { VALUE sub; VALUE vpos; rb_encoding *enc = STR_ENC_GET(str); long pos, len = str_strlen(str, enc); /* str's enc */ if (rb_scan_args(argc, argv, "11", &sub, &vpos) == 2) { pos = NUM2LONG(vpos); if (pos < 0) { pos += len; if (pos < 0) { if (RB_TYPE_P(sub, T_REGEXP)) { rb_backref_set(Qnil); } return Qnil; } } if (pos > len) pos = len; } else { pos = len; } if (RB_TYPE_P(sub, T_REGEXP)) { /* enc = rb_get_check(str, sub); */ pos = str_offset(RSTRING_PTR(str), RSTRING_END(str), pos, enc, single_byte_optimizable(str)); if (rb_reg_search(sub, str, pos, 1) >= 0) { VALUE match = rb_backref_get(); struct re_registers *regs = RMATCH_REGS(match); pos = rb_str_sublen(str, BEG(0)); return LONG2NUM(pos); } } else { StringValue(sub); pos = rb_str_rindex(str, sub, pos); if (pos >= 0) return LONG2NUM(pos); } return Qnil; }
If integer is greater than the length of str, returns a new String of length integer with str right justified and padded with padstr; otherwise, returns str.
"hello".rjust(4) #=> "hello" "hello".rjust(20) #=> " hello" "hello".rjust(20, '1234') #=> "123412341234123hello"
static VALUE rb_str_rjust(int argc, VALUE *argv, VALUE str) { return rb_str_justify(argc, argv, str, 'r'); }
Searches sep or pattern (regexp) in the string from the end of the string, and returns the part before it, the match, and the part after it. If it is not found, returns two empty strings and str.
"hello".rpartition("l") #=> ["hel", "l", "o"] "hello".rpartition("x") #=> ["", "", "hello"] "hello".rpartition(/.l/) #=> ["he", "ll", "o"]
static VALUE rb_str_rpartition(VALUE str, VALUE sep) { long pos = RSTRING_LEN(str); sep = get_pat_quoted(sep, 0); if (RB_TYPE_P(sep, T_REGEXP)) { if (rb_reg_search(sep, str, pos, 1) < 0) { goto failed; } VALUE match = rb_backref_get(); struct re_registers *regs = RMATCH_REGS(match); pos = BEG(0); sep = rb_str_subseq(str, pos, END(0) - pos); } else { pos = rb_str_sublen(str, pos); pos = rb_str_rindex(str, sep, pos); if(pos < 0) { goto failed; } pos = rb_str_offset(str, pos); } return rb_ary_new3(3, rb_str_subseq(str, 0, pos), sep, rb_str_subseq(str, pos+RSTRING_LEN(sep), RSTRING_LEN(str)-pos-RSTRING_LEN(sep))); failed: return rb_ary_new3(3, str_new_empty_String(str), str_new_empty_String(str), str_duplicate(rb_cString, str)); }
Returns a copy of the receiver with trailing whitespace removed. See also #lstrip and #strip.
Refer to #strip for the definition of whitespace.
" hello ".rstrip #=> " hello" "hello".rstrip #=> "hello"
static VALUE rb_str_rstrip(VALUE str) { rb_encoding *enc; char *start; long olen, roffset; enc = STR_ENC_GET(str); RSTRING_GETMEM(str, start, olen); roffset = rstrip_offset(str, start, start+olen, enc); if (roffset <= 0) return str_duplicate(rb_cString, str); return rb_str_subseq(str, 0, olen-roffset); }
Removes trailing whitespace from the receiver. Returns the altered
receiver, or nil
if no change was made. See also #lstrip! and #strip!.
Refer to #strip for the definition of whitespace.
" hello ".rstrip! #=> " hello" " hello".rstrip! #=> nil "hello".rstrip! #=> nil
static VALUE rb_str_rstrip_bang(VALUE str) { rb_encoding *enc; char *start; long olen, roffset; str_modify_keep_cr(str); enc = STR_ENC_GET(str); RSTRING_GETMEM(str, start, olen); roffset = rstrip_offset(str, start, start+olen, enc); if (roffset > 0) { long len = olen - roffset; STR_SET_LEN(str, len); #if !SHARABLE_MIDDLE_SUBSTRING TERM_FILL(start+len, rb_enc_mbminlen(enc)); #endif return str; } return Qnil; }
Both forms iterate through str, matching the pattern (which may be
a Regexp or a String).
For each match, a result is generated and either added to the result array
or passed to the block. If the pattern contains no groups, each individual
result consists of the matched string, $&
. If the pattern
contains groups, each individual result is itself an array containing one
entry per group.
a = "cruel world" a.scan(/\w+/) #=> ["cruel", "world"] a.scan(/.../) #=> ["cru", "el ", "wor"] a.scan(/(...)/) #=> [["cru"], ["el "], ["wor"]] a.scan(/(..)(..)/) #=> [["cr", "ue"], ["l ", "wo"]]
And the block form:
a.scan(/\w+/) {|w| print "<<#{w}>> " } print "\n" a.scan(/(.)(.)/) {|x,y| print y, x } print "\n"
produces:
<<cruel>> <<world>> rceu lowlr
static VALUE rb_str_scan(VALUE str, VALUE pat) { VALUE result; long start = 0; long last = -1, prev = 0; char *p = RSTRING_PTR(str); long len = RSTRING_LEN(str); pat = get_pat_quoted(pat, 1); mustnot_broken(str); if (!rb_block_given_p()) { VALUE ary = rb_ary_new(); while (!NIL_P(result = scan_once(str, pat, &start, 0))) { last = prev; prev = start; rb_ary_push(ary, result); } if (last >= 0) rb_pat_search(pat, str, last, 1); else rb_backref_set(Qnil); return ary; } while (!NIL_P(result = scan_once(str, pat, &start, 1))) { last = prev; prev = start; rb_yield(result); str_mod_check(str, p, len); } if (last >= 0) rb_pat_search(pat, str, last, 1); return str; }
If the string is invalid byte sequence then replace invalid bytes with given replacement character, else returns self. If block is given, replace invalid bytes with returned value of the block.
"abc\u3042\x81".scrub #=> "abc\u3042\uFFFD" "abc\u3042\x81".scrub("*") #=> "abc\u3042*" "abc\u3042\xE3\x80".scrub{|bytes| '<'+bytes.unpack('H*')[0]+'>' } #=> "abc\u3042<e380>"
static VALUE str_scrub(int argc, VALUE *argv, VALUE str) { VALUE repl = argc ? (rb_check_arity(argc, 0, 1), argv[0]) : Qnil; VALUE new = rb_str_scrub(str, repl); return NIL_P(new) ? str_duplicate(rb_cString, str): new; }
If the string is invalid byte sequence then replace invalid bytes with given replacement character, else returns self. If block is given, replace invalid bytes with returned value of the block.
"abc\u3042\x81".scrub! #=> "abc\u3042\uFFFD" "abc\u3042\x81".scrub!("*") #=> "abc\u3042*" "abc\u3042\xE3\x80".scrub!{|bytes| '<'+bytes.unpack('H*')[0]+'>' } #=> "abc\u3042<e380>"
static VALUE str_scrub_bang(int argc, VALUE *argv, VALUE str) { VALUE repl = argc ? (rb_check_arity(argc, 0, 1), argv[0]) : Qnil; VALUE new = rb_str_scrub(str, repl); if (!NIL_P(new)) rb_str_replace(str, new); return str; }
modifies the indexth byte as integer.
static VALUE rb_str_setbyte(VALUE str, VALUE index, VALUE value) { long pos = NUM2LONG(index); long len = RSTRING_LEN(str); char *head, *left = 0; unsigned char *ptr; rb_encoding *enc; int cr = ENC_CODERANGE_UNKNOWN, width, nlen; if (pos < -len || len <= pos) rb_raise(rb_eIndexError, "index %ld out of string", pos); if (pos < 0) pos += len; VALUE v = rb_to_int(value); VALUE w = rb_int_and(v, INT2FIX(0xff)); unsigned char byte = NUM2INT(w) & 0xFF; if (!str_independent(str)) str_make_independent(str); enc = STR_ENC_GET(str); head = RSTRING_PTR(str); ptr = (unsigned char *)&head[pos]; if (!STR_EMBED_P(str)) { cr = ENC_CODERANGE(str); switch (cr) { case ENC_CODERANGE_7BIT: left = (char *)ptr; *ptr = byte; if (ISASCII(byte)) goto end; nlen = rb_enc_precise_mbclen(left, head+len, enc); if (!MBCLEN_CHARFOUND_P(nlen)) ENC_CODERANGE_SET(str, ENC_CODERANGE_BROKEN); else ENC_CODERANGE_SET(str, ENC_CODERANGE_VALID); goto end; case ENC_CODERANGE_VALID: left = rb_enc_left_char_head(head, ptr, head+len, enc); width = rb_enc_precise_mbclen(left, head+len, enc); *ptr = byte; nlen = rb_enc_precise_mbclen(left, head+len, enc); if (!MBCLEN_CHARFOUND_P(nlen)) ENC_CODERANGE_SET(str, ENC_CODERANGE_BROKEN); else if (MBCLEN_CHARFOUND_LEN(nlen) != width || ISASCII(byte)) ENC_CODERANGE_CLEAR(str); goto end; } } ENC_CODERANGE_CLEAR(str); *ptr = byte; end: return value; }
Returns the substring of self
specified by the arguments.
When the single Integer argument index
is given, returns the
1-character substring found in self
at offset
index
:
'bar'[2] # => "r"
Counts backward from the end of self
if index
is
negative:
'foo'[-3] # => "f"
Returns nil
if index
is out of range:
'foo'[3] # => nil 'foo'[-4] # => nil
When the two Integer arguments start
and length
are given, returns the substring of the given length
found in
self
at offset start
:
'foo'[0, 2] # => "fo" 'foo'[0, 0] # => ""
Counts backward from the end of self
if start
is
negative:
'foo'[-2, 2] # => "oo"
Special case: returns a new empty String if start
is equal to
the length of self
:
'foo'[3, 2] # => ""
Returns nil
if start
is out of range:
'foo'[4, 2] # => nil 'foo'[-4, 2] # => nil
Returns the trailing substring of self
if length
is large:
'foo'[1, 50] # => "oo"
Returns nil
if length
is negative:
'foo'[0, -1] # => nil
When the single Range argument range
is given, derives
start
and length
values from the given
range
, and returns values as above:
'foo'[0..1]
is equivalent to 'foo'[0, 2]
.
'foo'[0...1]
is equivalent to 'foo'[0, 1]
.
When the Regexp argument regexp
is given, and the
capture
argument is 0
, returns the first matching
substring found in self
, or nil
if none found:
'foo'[/o/] # => "o" 'foo'[/x/] # => nil s = 'hello there' s[/[aeiou](.)\1/] # => "ell" s[/[aeiou](.)\1/, 0] # => "ell"
If argument capture
is given and not 0
, it should
be either an Integer capture group index or a String or Symbol capture
group name; the method call returns only the specified capture (see Regexp Capturing):
s = 'hello there' s[/[aeiou](.)\1/, 1] # => "l" s[/(?<vowel>[aeiou])(?<non_vowel>[^aeiou])/, "non_vowel"] # => "l" s[/(?<vowel>[aeiou])(?<non_vowel>[^aeiou])/, :vowel] # => "e"
If an invalid capture group index is given, nil
is returned.
If an invalid capture group name is given, IndexError
is
raised.
When the single String argument substring
is given, returns
the substring from self
if found, otherwise nil
:
'foo'['oo'] # => "oo" 'foo'['xx'] # => nil
static VALUE rb_str_aref_m(int argc, VALUE *argv, VALUE str) { if (argc == 2) { if (RB_TYPE_P(argv[0], T_REGEXP)) { return rb_str_subpat(str, argv[0], argv[1]); } else { long beg = NUM2LONG(argv[0]); long len = NUM2LONG(argv[1]); return rb_str_substr(str, beg, len); } } rb_check_arity(argc, 1, 2); return rb_str_aref(str, argv[0]); }
Deletes the specified portion from str, and returns the portion deleted.
string = "this is a string" string.slice!(2) #=> "i" string.slice!(3..6) #=> " is " string.slice!(/s.*t/) #=> "sa st" string.slice!("r") #=> "r" string #=> "thing"
static VALUE rb_str_slice_bang(int argc, VALUE *argv, VALUE str) { VALUE result = Qnil; VALUE indx; long beg, len = 1; char *p; rb_check_arity(argc, 1, 2); str_modify_keep_cr(str); indx = argv[0]; if (RB_TYPE_P(indx, T_REGEXP)) { if (rb_reg_search(indx, str, 0, 0) < 0) return Qnil; VALUE match = rb_backref_get(); struct re_registers *regs = RMATCH_REGS(match); int nth = 0; if (argc > 1 && (nth = rb_reg_backref_number(match, argv[1])) < 0) { if ((nth += regs->num_regs) <= 0) return Qnil; } else if (nth >= regs->num_regs) return Qnil; beg = BEG(nth); len = END(nth) - beg; goto subseq; } else if (argc == 2) { beg = NUM2LONG(indx); len = NUM2LONG(argv[1]); goto num_index; } else if (FIXNUM_P(indx)) { beg = FIX2LONG(indx); if (!(p = rb_str_subpos(str, beg, &len))) return Qnil; if (!len) return Qnil; beg = p - RSTRING_PTR(str); goto subseq; } else if (RB_TYPE_P(indx, T_STRING)) { beg = rb_str_index(str, indx, 0); if (beg == -1) return Qnil; len = RSTRING_LEN(indx); result = str_duplicate(rb_cString, indx); goto squash; } else { switch (rb_range_beg_len(indx, &beg, &len, str_strlen(str, NULL), 0)) { case Qnil: return Qnil; case Qfalse: beg = NUM2LONG(indx); if (!(p = rb_str_subpos(str, beg, &len))) return Qnil; if (!len) return Qnil; beg = p - RSTRING_PTR(str); goto subseq; default: goto num_index; } } num_index: if (!(p = rb_str_subpos(str, beg, &len))) return Qnil; beg = p - RSTRING_PTR(str); subseq: result = rb_str_new(RSTRING_PTR(str)+beg, len); rb_enc_cr_str_copy_for_substr(result, str); squash: if (len > 0) { if (beg == 0) { rb_str_drop_bytes(str, len); } else { char *sptr = RSTRING_PTR(str); long slen = RSTRING_LEN(str); if (beg + len > slen) /* pathological check */ len = slen - beg; memmove(sptr + beg, sptr + beg + len, slen - (beg + len)); slen -= len; STR_SET_LEN(str, slen); TERM_FILL(&sptr[slen], TERM_LEN(str)); } } return result; }
Divides str into substrings based on a delimiter, returning an array of these substrings.
If pattern is a String, then its contents are used as the delimiter when splitting str. If pattern is a single space, str is split on whitespace, with leading and trailing whitespace and runs of contiguous whitespace characters ignored.
If pattern is a Regexp, str is divided where the pattern matches. Whenever the pattern matches a zero-length string, str is split into individual characters. If pattern contains groups, the respective matches will be returned in the array as well.
If pattern is nil
, the value of $;
is
used. If $;
is nil
(which is the default),
str is split on whitespace as if ‘ ’ were specified.
If the limit parameter is omitted, trailing null fields are
suppressed. If limit is a positive number, at most that number of
split substrings will be returned (captured groups will be returned as
well, but are not counted towards the limit). If limit is
1
, the entire string is returned as the only entry in an
array. If negative, there is no limit to the number of fields returned, and
trailing null fields are not suppressed.
When the input str
is empty an empty Array is returned as the string is considered to have
no fields to split.
" now's the time ".split #=> ["now's", "the", "time"] " now's the time ".split(' ') #=> ["now's", "the", "time"] " now's the time".split(/ /) #=> ["", "now's", "", "the", "time"] "1, 2.34,56, 7".split(%r{,\s*}) #=> ["1", "2.34", "56", "7"] "hello".split(//) #=> ["h", "e", "l", "l", "o"] "hello".split(//, 3) #=> ["h", "e", "llo"] "hi mom".split(%r{\s*}) #=> ["h", "i", "m", "o", "m"] "mellow yellow".split("ello") #=> ["m", "w y", "w"] "1,2,,3,4,,".split(',') #=> ["1", "2", "", "3", "4"] "1,2,,3,4,,".split(',', 4) #=> ["1", "2", "", "3,4,,"] "1,2,,3,4,,".split(',', -4) #=> ["1", "2", "", "3", "4", "", ""] "1:2:3".split(/(:)()()/, 2) #=> ["1", ":", "", "", "2:3"] "".split(',', -1) #=> []
If a block is given, invoke the block with each split substring.
static VALUE rb_str_split_m(int argc, VALUE *argv, VALUE str) { rb_encoding *enc; VALUE spat; VALUE limit; split_type_t split_type; long beg, end, i = 0, empty_count = -1; int lim = 0; VALUE result, tmp; result = rb_block_given_p() ? Qfalse : Qnil; if (rb_scan_args(argc, argv, "02", &spat, &limit) == 2) { lim = NUM2INT(limit); if (lim <= 0) limit = Qnil; else if (lim == 1) { if (RSTRING_LEN(str) == 0) return result ? rb_ary_new2(0) : str; tmp = str_duplicate(rb_cString, str); if (!result) { rb_yield(tmp); return str; } return rb_ary_new3(1, tmp); } i = 1; } if (NIL_P(limit) && !lim) empty_count = 0; enc = STR_ENC_GET(str); split_type = SPLIT_TYPE_REGEXP; if (!NIL_P(spat)) { spat = get_pat_quoted(spat, 0); } else if (NIL_P(spat = rb_fs)) { split_type = SPLIT_TYPE_AWK; } else if (!(spat = rb_fs_check(spat))) { rb_raise(rb_eTypeError, "value of $; must be String or Regexp"); } else { rb_category_warn(RB_WARN_CATEGORY_DEPRECATED, "$; is set to non-nil value"); } if (split_type != SPLIT_TYPE_AWK) { switch (BUILTIN_TYPE(spat)) { case T_REGEXP: rb_reg_options(spat); /* check if uninitialized */ tmp = RREGEXP_SRC(spat); split_type = literal_split_pattern(tmp, SPLIT_TYPE_REGEXP); if (split_type == SPLIT_TYPE_AWK) { spat = tmp; split_type = SPLIT_TYPE_STRING; } break; case T_STRING: mustnot_broken(spat); split_type = literal_split_pattern(spat, SPLIT_TYPE_STRING); break; default: UNREACHABLE_RETURN(Qnil); } } #define SPLIT_STR(beg, len) (empty_count = split_string(result, str, beg, len, empty_count)) if (result) result = rb_ary_new(); beg = 0; char *ptr = RSTRING_PTR(str); char *eptr = RSTRING_END(str); if (split_type == SPLIT_TYPE_AWK) { char *bptr = ptr; int skip = 1; unsigned int c; end = beg; if (is_ascii_string(str)) { while (ptr < eptr) { c = (unsigned char)*ptr++; if (skip) { if (ascii_isspace(c)) { beg = ptr - bptr; } else { end = ptr - bptr; skip = 0; if (!NIL_P(limit) && lim <= i) break; } } else if (ascii_isspace(c)) { SPLIT_STR(beg, end-beg); skip = 1; beg = ptr - bptr; if (!NIL_P(limit)) ++i; } else { end = ptr - bptr; } } } else { while (ptr < eptr) { int n; c = rb_enc_codepoint_len(ptr, eptr, &n, enc); ptr += n; if (skip) { if (rb_isspace(c)) { beg = ptr - bptr; } else { end = ptr - bptr; skip = 0; if (!NIL_P(limit) && lim <= i) break; } } else if (rb_isspace(c)) { SPLIT_STR(beg, end-beg); skip = 1; beg = ptr - bptr; if (!NIL_P(limit)) ++i; } else { end = ptr - bptr; } } } } else if (split_type == SPLIT_TYPE_STRING) { char *str_start = ptr; char *substr_start = ptr; char *sptr = RSTRING_PTR(spat); long slen = RSTRING_LEN(spat); mustnot_broken(str); enc = rb_enc_check(str, spat); while (ptr < eptr && (end = rb_memsearch(sptr, slen, ptr, eptr - ptr, enc)) >= 0) { /* Check we are at the start of a char */ char *t = rb_enc_right_char_head(ptr, ptr + end, eptr, enc); if (t != ptr + end) { ptr = t; continue; } SPLIT_STR(substr_start - str_start, (ptr+end) - substr_start); ptr += end + slen; substr_start = ptr; if (!NIL_P(limit) && lim <= ++i) break; } beg = ptr - str_start; } else if (split_type == SPLIT_TYPE_CHARS) { char *str_start = ptr; int n; mustnot_broken(str); enc = rb_enc_get(str); while (ptr < eptr && (n = rb_enc_precise_mbclen(ptr, eptr, enc)) > 0) { SPLIT_STR(ptr - str_start, n); ptr += n; if (!NIL_P(limit) && lim <= ++i) break; } beg = ptr - str_start; } else { long len = RSTRING_LEN(str); long start = beg; long idx; int last_null = 0; struct re_registers *regs; VALUE match = 0; for (; rb_reg_search(spat, str, start, 0) >= 0; (match ? (rb_match_unbusy(match), rb_backref_set(match)) : (void)0)) { match = rb_backref_get(); if (!result) rb_match_busy(match); regs = RMATCH_REGS(match); end = BEG(0); if (start == end && BEG(0) == END(0)) { if (!ptr) { SPLIT_STR(0, 0); break; } else if (last_null == 1) { SPLIT_STR(beg, rb_enc_fast_mbclen(ptr+beg, eptr, enc)); beg = start; } else { if (start == len) start++; else start += rb_enc_fast_mbclen(ptr+start,eptr,enc); last_null = 1; continue; } } else { SPLIT_STR(beg, end-beg); beg = start = END(0); } last_null = 0; for (idx=1; idx < regs->num_regs; idx++) { if (BEG(idx) == -1) continue; SPLIT_STR(BEG(idx), END(idx)-BEG(idx)); } if (!NIL_P(limit) && lim <= ++i) break; } if (match) rb_match_unbusy(match); } if (RSTRING_LEN(str) > 0 && (!NIL_P(limit) || RSTRING_LEN(str) > beg || lim < 0)) { SPLIT_STR(beg, RSTRING_LEN(str)-beg); } return result ? result : str; }
Builds a set of characters from the other_str parameter(s) using the procedure described for #count. Returns a new string where runs of the same character that occur in this set are replaced by a single character. If no arguments are given, all runs of identical characters are replaced by a single character.
"yellow moon".squeeze #=> "yelow mon" " now is the".squeeze(" ") #=> " now is the" "putters shoot balls".squeeze("m-z") #=> "puters shot balls"
static VALUE rb_str_squeeze(int argc, VALUE *argv, VALUE str) { str = str_duplicate(rb_cString, str); rb_str_squeeze_bang(argc, argv, str); return str; }
Squeezes str in place, returning either str, or
nil
if no changes were made.
static VALUE rb_str_squeeze_bang(int argc, VALUE *argv, VALUE str) { char squeez[TR_TABLE_SIZE]; rb_encoding *enc = 0; VALUE del = 0, nodel = 0; unsigned char *s, *send, *t; int i, modify = 0; int ascompat, singlebyte = single_byte_optimizable(str); unsigned int save; if (argc == 0) { enc = STR_ENC_GET(str); } else { for (i=0; i<argc; i++) { VALUE s = argv[i]; StringValue(s); enc = rb_enc_check(str, s); if (singlebyte && !single_byte_optimizable(s)) singlebyte = 0; tr_setup_table(s, squeez, i==0, &del, &nodel, enc); } } str_modify_keep_cr(str); s = t = (unsigned char *)RSTRING_PTR(str); if (!s || RSTRING_LEN(str) == 0) return Qnil; send = (unsigned char *)RSTRING_END(str); save = -1; ascompat = rb_enc_asciicompat(enc); if (singlebyte) { while (s < send) { unsigned int c = *s++; if (c != save || (argc > 0 && !squeez[c])) { *t++ = save = c; } } } else { while (s < send) { unsigned int c; int clen; if (ascompat && (c = *s) < 0x80) { if (c != save || (argc > 0 && !squeez[c])) { *t++ = save = c; } s++; } else { c = rb_enc_codepoint_len((char *)s, (char *)send, &clen, enc); if (c != save || (argc > 0 && !tr_find(c, squeez, del, nodel))) { if (t != s) rb_enc_mbcput(c, t, enc); save = c; t += clen; } s += clen; } } } TERM_FILL((char *)t, TERM_LEN(str)); if ((char *)t - RSTRING_PTR(str) != RSTRING_LEN(str)) { STR_SET_LEN(str, (char *)t - RSTRING_PTR(str)); modify = 1; } if (modify) return str; return Qnil; }
Returns true if str
starts with one of the
prefixes
given. Each of the prefixes
should be a
String or a Regexp.
"hello".start_with?("hell") #=> true "hello".start_with?(/H/i) #=> true # returns true if one of the prefixes matches. "hello".start_with?("heaven", "hell") #=> true "hello".start_with?("heaven", "paradise") #=> false
static VALUE rb_str_start_with(int argc, VALUE *argv, VALUE str) { int i; for (i=0; i<argc; i++) { VALUE tmp = argv[i]; if (RB_TYPE_P(tmp, T_REGEXP)) { if (rb_reg_start_with_p(tmp, str)) return Qtrue; } else { StringValue(tmp); rb_enc_check(str, tmp); if (RSTRING_LEN(str) < RSTRING_LEN(tmp)) continue; if (memcmp(RSTRING_PTR(str), RSTRING_PTR(tmp), RSTRING_LEN(tmp)) == 0) return Qtrue; } } return Qfalse; }
Returns a copy of the receiver with leading and trailing whitespace removed.
Whitespace is defined as any of the following characters: null, horizontal tab, line feed, vertical tab, form feed, carriage return, space.
" hello ".strip #=> "hello" "\tgoodbye\r\n".strip #=> "goodbye" "\x00\t\n\v\f\r ".strip #=> "" "hello".strip #=> "hello"
static VALUE rb_str_strip(VALUE str) { char *start; long olen, loffset, roffset; rb_encoding *enc = STR_ENC_GET(str); RSTRING_GETMEM(str, start, olen); loffset = lstrip_offset(str, start, start+olen, enc); roffset = rstrip_offset(str, start+loffset, start+olen, enc); if (loffset <= 0 && roffset <= 0) return str_duplicate(rb_cString, str); return rb_str_subseq(str, loffset, olen-loffset-roffset); }
Removes leading and trailing whitespace from the receiver. Returns the
altered receiver, or nil
if there was no change.
Refer to #strip for the definition of whitespace.
" hello ".strip! #=> "hello" "hello".strip! #=> nil
static VALUE rb_str_strip_bang(VALUE str) { char *start; long olen, loffset, roffset; rb_encoding *enc; str_modify_keep_cr(str); enc = STR_ENC_GET(str); RSTRING_GETMEM(str, start, olen); loffset = lstrip_offset(str, start, start+olen, enc); roffset = rstrip_offset(str, start+loffset, start+olen, enc); if (loffset > 0 || roffset > 0) { long len = olen-roffset; if (loffset > 0) { len -= loffset; memmove(start, start + loffset, len); } STR_SET_LEN(str, len); #if !SHARABLE_MIDDLE_SUBSTRING TERM_FILL(start+len, rb_enc_mbminlen(enc)); #endif return str; } return Qnil; }
Returns a copy of str
with the first occurrence of
pattern
replaced by the second argument. The
pattern
is typically a Regexp; if
given as a String, any regular expression
metacharacters it contains will be interpreted literally, e.g.
\d
will match a backslash followed by ‘d’, instead of a digit.
If replacement
is a String it will
be substituted for the matched text. It may contain back-references to the
pattern’s capture groups of the form \d
, where d is a
group number, or \k<n>
, where n is a group
name. Similarly, \&
, \'
, \`
, and
+
correspond to special variables, $&
,
$'
, $`
, and $+
, respectively. (See
regexp.rdoc for details.) \0
is the same as
\&
. \\
is interpreted as an escape, i.e., a
single backslash. Note that, within replacement
the special
match variables, such as $&
, will not refer to the current
match.
If the second argument is a Hash, and the matched text is one of its keys, the corresponding value is the replacement string.
In the block form, the current match string is passed in as a parameter,
and variables such as $1
, $2
, $`
,
$&
, and $'
will be set appropriately. (See
regexp.rdoc for details.) The value returned by the block will be
substituted for the match on each call.
"hello".sub(/[aeiou]/, '*') #=> "h*llo" "hello".sub(/([aeiou])/, '<\1>') #=> "h<e>llo" "hello".sub(/./) {|s| s.ord.to_s + ' ' } #=> "104 ello" "hello".sub(/(?<foo>[aeiou])/, '*\k<foo>*') #=> "h*e*llo" 'Is SHELL your preferred shell?'.sub(/[[:upper:]]{2,}/, ENV) #=> "Is /bin/bash your preferred shell?"
Note that a string literal consumes backslashes. (See syntax/literals.rdoc
for details about string literals.) Back-references are typically preceded
by an additional backslash. For example, if you want to write a
back-reference \&
in replacement
with a
double-quoted string literal, you need to write:
"..\\&.."
. If you want to write a
non-back-reference string \&
in replacement
,
you need first to escape the backslash to prevent this method from
interpreting it as a back-reference, and then you need to escape the
backslashes again to prevent a string literal from consuming them:
"..\\\\&.."
. You may want to use the block form
to avoid a lot of backslashes.
static VALUE rb_str_sub(int argc, VALUE *argv, VALUE str) { str = str_duplicate(rb_cString, str); rb_str_sub_bang(argc, argv, str); return str; }
Performs the same substitution as #sub in-place.
Returns str
if a substitution was performed or
nil
if no substitution was performed.
static VALUE rb_str_sub_bang(int argc, VALUE *argv, VALUE str) { VALUE pat, repl, hash = Qnil; int iter = 0; long plen; int min_arity = rb_block_given_p() ? 1 : 2; long beg; rb_check_arity(argc, min_arity, 2); if (argc == 1) { iter = 1; } else { repl = argv[1]; hash = rb_check_hash_type(argv[1]); if (NIL_P(hash)) { StringValue(repl); } } pat = get_pat_quoted(argv[0], 1); str_modifiable(str); beg = rb_pat_search(pat, str, 0, 1); if (beg >= 0) { rb_encoding *enc; int cr = ENC_CODERANGE(str); long beg0, end0; VALUE match, match0 = Qnil; struct re_registers *regs; char *p, *rp; long len, rlen; match = rb_backref_get(); regs = RMATCH_REGS(match); if (RB_TYPE_P(pat, T_STRING)) { beg0 = beg; end0 = beg0 + RSTRING_LEN(pat); match0 = pat; } else { beg0 = BEG(0); end0 = END(0); if (iter) match0 = rb_reg_nth_match(0, match); } if (iter || !NIL_P(hash)) { p = RSTRING_PTR(str); len = RSTRING_LEN(str); if (iter) { repl = rb_obj_as_string(rb_yield(match0)); } else { repl = rb_hash_aref(hash, rb_str_subseq(str, beg0, end0 - beg0)); repl = rb_obj_as_string(repl); } str_mod_check(str, p, len); rb_check_frozen(str); } else { repl = rb_reg_regsub(repl, str, regs, RB_TYPE_P(pat, T_STRING) ? Qnil : pat); } enc = rb_enc_compatible(str, repl); if (!enc) { rb_encoding *str_enc = STR_ENC_GET(str); p = RSTRING_PTR(str); len = RSTRING_LEN(str); if (coderange_scan(p, beg0, str_enc) != ENC_CODERANGE_7BIT || coderange_scan(p+end0, len-end0, str_enc) != ENC_CODERANGE_7BIT) { rb_raise(rb_eEncCompatError, "incompatible character encodings: %s and %s", rb_enc_name(str_enc), rb_enc_name(STR_ENC_GET(repl))); } enc = STR_ENC_GET(repl); } rb_str_modify(str); rb_enc_associate(str, enc); if (ENC_CODERANGE_UNKNOWN < cr && cr < ENC_CODERANGE_BROKEN) { int cr2 = ENC_CODERANGE(repl); if (cr2 == ENC_CODERANGE_BROKEN || (cr == ENC_CODERANGE_VALID && cr2 == ENC_CODERANGE_7BIT)) cr = ENC_CODERANGE_UNKNOWN; else cr = cr2; } plen = end0 - beg0; rlen = RSTRING_LEN(repl); len = RSTRING_LEN(str); if (rlen > plen) { RESIZE_CAPA(str, len + rlen - plen); } p = RSTRING_PTR(str); if (rlen != plen) { memmove(p + beg0 + rlen, p + beg0 + plen, len - beg0 - plen); } rp = RSTRING_PTR(repl); memmove(p + beg0, rp, rlen); len += rlen - plen; STR_SET_LEN(str, len); TERM_FILL(&RSTRING_PTR(str)[len], TERM_LEN(str)); ENC_CODERANGE_SET(str, cr); return str; } return Qnil; }
Returns the successor to self
. The successor is calculated by
incrementing characters.
The first character to be incremented is the rightmost alphanumeric: or, if no alphanumerics, the rightmost character:
'THX1138'.succ # => "THX1139" '<<koala>>'.succ # => "<<koalb>>" '***'.succ # => '**+'
The successor to a digit is another digit, “carrying” to the next-left character for a “rollover” from 9 to 0, and prepending another digit if necessary:
'00'.succ # => "01" '09'.succ # => "10" '99'.succ # => "100"
The successor to a letter is another letter of the same case, carrying to the next-left character for a rollover, and prepending another same-case letter if necessary:
'aa'.succ # => "ab" 'az'.succ # => "ba" 'zz'.succ # => "aaa" 'AA'.succ # => "AB" 'AZ'.succ # => "BA" 'ZZ'.succ # => "AAA"
The successor to a non-alphanumeric character is the next character in the underlying character set’s collating sequence, carrying to the next-left character for a rollover, and prepending another character if necessary:
s = 0.chr * 3 s # => "\x00\x00\x00" s.succ # => "\x00\x00\x01" s = 255.chr * 3 s # => "\xFF\xFF\xFF" s.succ # => "\x01\x00\x00\x00"
Carrying can occur between and among mixtures of alphanumeric characters:
s = 'zz99zz99' s.succ # => "aaa00aa00" s = '99zz99zz' s.succ # => "100aa00aa"
The successor to an empty String is a new empty String:
''.succ # => ""
VALUE rb_str_succ(VALUE orig) { VALUE str; str = rb_str_new(RSTRING_PTR(orig), RSTRING_LEN(orig)); rb_enc_cr_str_copy_for_substr(str, orig); return str_succ(str); }
Returns a basic n-bit checksum of the characters in str,
where n is the optional Integer
parameter, defaulting to 16. The result is simply the sum of the binary
value of each byte in str modulo 2**n - 1
. This is
not a particularly good checksum.
static VALUE rb_str_sum(int argc, VALUE *argv, VALUE str) { int bits = 16; char *ptr, *p, *pend; long len; VALUE sum = INT2FIX(0); unsigned long sum0 = 0; if (rb_check_arity(argc, 0, 1) && (bits = NUM2INT(argv[0])) < 0) { bits = 0; } ptr = p = RSTRING_PTR(str); len = RSTRING_LEN(str); pend = p + len; while (p < pend) { if (FIXNUM_MAX - UCHAR_MAX < sum0) { sum = rb_funcall(sum, '+', 1, LONG2FIX(sum0)); str_mod_check(str, ptr, len); sum0 = 0; } sum0 += (unsigned char)*p; p++; } if (bits == 0) { if (sum0) { sum = rb_funcall(sum, '+', 1, LONG2FIX(sum0)); } } else { if (sum == INT2FIX(0)) { if (bits < (int)sizeof(long)*CHAR_BIT) { sum0 &= (((unsigned long)1)<<bits)-1; } sum = LONG2FIX(sum0); } else { VALUE mod; if (sum0) { sum = rb_funcall(sum, '+', 1, LONG2FIX(sum0)); } mod = rb_funcall(INT2FIX(1), idLTLT, 1, INT2FIX(bits)); mod = rb_funcall(mod, '-', 1, INT2FIX(1)); sum = rb_funcall(sum, '&', 1, mod); } } return sum; }
Returns a copy of str with uppercase alphabetic characters converted to lowercase and lowercase characters converted to uppercase.
See #downcase for meaning of
options
and use with different encodings.
"Hello".swapcase #=> "hELLO" "cYbEr_PuNk11".swapcase #=> "CyBeR_pUnK11"
static VALUE rb_str_swapcase(int argc, VALUE *argv, VALUE str) { rb_encoding *enc; OnigCaseFoldType flags = ONIGENC_CASE_UPCASE | ONIGENC_CASE_DOWNCASE; VALUE ret; flags = check_case_options(argc, argv, flags); enc = str_true_enc(str); if (RSTRING_LEN(str) == 0 || !RSTRING_PTR(str)) return str_duplicate(rb_cString, str); if (flags&ONIGENC_CASE_ASCII_ONLY) { ret = rb_str_new(0, RSTRING_LEN(str)); rb_str_ascii_casemap(str, ret, &flags, enc); } else { ret = rb_str_casemap(str, &flags, enc); } return ret; }
Equivalent to #swapcase, but
modifies the receiver in place, returning str, or nil
if no changes were made.
See #downcase for meaning of
options
and use with different encodings.
static VALUE rb_str_swapcase_bang(int argc, VALUE *argv, VALUE str) { rb_encoding *enc; OnigCaseFoldType flags = ONIGENC_CASE_UPCASE | ONIGENC_CASE_DOWNCASE; flags = check_case_options(argc, argv, flags); str_modify_keep_cr(str); enc = str_true_enc(str); if (flags&ONIGENC_CASE_ASCII_ONLY) rb_str_ascii_casemap(str, str, &flags, enc); else str_shared_replace(str, rb_str_casemap(str, &flags, enc)); if (ONIGENC_CASE_MODIFIED&flags) return str; return Qnil; }
Returns a complex which denotes the string form. The parser ignores leading whitespaces and trailing garbage. Any digit sequences can be separated by an underscore. Returns zero for null or garbage string.
'9'.to_c #=> (9+0i) '2.5'.to_c #=> (2.5+0i) '2.5/1'.to_c #=> ((5/2)+0i) '-3/2'.to_c #=> ((-3/2)+0i) '-i'.to_c #=> (0-1i) '45i'.to_c #=> (0+45i) '3-4i'.to_c #=> (3-4i) '-4e2-4e-2i'.to_c #=> (-400.0-0.04i) '-0.0-0.0i'.to_c #=> (-0.0-0.0i) '1/2+3/4i'.to_c #=> ((1/2)+(3/4)*i) 'ruby'.to_c #=> (0+0i)
See Kernel.Complex.
static VALUE string_to_c(VALUE self) { char *s; VALUE num; rb_must_asciicompat(self); s = RSTRING_PTR(self); if (s && s[RSTRING_LEN(self)]) { rb_str_modify(self); s = RSTRING_PTR(self); s[RSTRING_LEN(self)] = '\0'; } if (!s) s = (char *)""; (void)parse_comp(s, 0, &num); return num; }
Returns the result of interpreting leading characters in str as a
floating point number. Extraneous characters past the end of a valid number
are ignored. If there is not a valid number at the start of str,
0.0
is returned. This method never raises an exception.
"123.45e1".to_f #=> 1234.5 "45.67 degrees".to_f #=> 45.67 "thx1138".to_f #=> 0.0
static VALUE rb_str_to_f(VALUE str) { return DBL2NUM(rb_str_to_dbl(str, FALSE)); }
Returns the result of interpreting leading characters in str as an
integer base base (between 2 and 36). Extraneous characters past
the end of a valid number are ignored. If there is not a valid number at
the start of str, 0
is returned. This method never
raises an exception when base is valid.
"12345".to_i #=> 12345 "99 red balloons".to_i #=> 99 "0a".to_i #=> 0 "0a".to_i(16) #=> 10 "hello".to_i #=> 0 "1100101".to_i(2) #=> 101 "1100101".to_i(8) #=> 294977 "1100101".to_i(10) #=> 1100101 "1100101".to_i(16) #=> 17826049
static VALUE rb_str_to_i(int argc, VALUE *argv, VALUE str) { int base = 10; if (rb_check_arity(argc, 0, 1) && (base = NUM2INT(argv[0])) < 0) { rb_raise(rb_eArgError, "invalid radix %d", base); } return rb_str_to_inum(str, base, FALSE); }
Returns the result of interpreting leading characters in str
as a rational. Leading whitespace and extraneous characters past the end
of a valid number are ignored. Digit sequences can be separated by an
underscore. If there is not a valid number at the start of
str
, zero is returned. This method never raises an exception.
' 2 '.to_r #=> (2/1) '300/2'.to_r #=> (150/1) '-9.2'.to_r #=> (-46/5) '-9.2e2'.to_r #=> (-920/1) '1_234_567'.to_r #=> (1234567/1) '21 June 09'.to_r #=> (21/1) '21/06/09'.to_r #=> (7/2) 'BWV 1079'.to_r #=> (0/1)
NOTE: “0.3”.to_r isn’t the same as 0.3.to_r. The former is equivalent to “3/10”.to_r, but the latter isn’t so.
"0.3".to_r == 3/10r #=> true 0.3.to_r == 3/10r #=> false
See also Kernel#Rational.
static VALUE string_to_r(VALUE self) { VALUE num; rb_must_asciicompat(self); num = parse_rat(RSTRING_PTR(self), RSTRING_END(self), 0, TRUE); if (RB_FLOAT_TYPE_P(num) && !FLOAT_ZERO_P(num)) rb_raise(rb_eFloatDomainError, "Infinity"); return num; }
Returns the Symbol corresponding to str, creating the symbol if it did not previously exist. See Symbol#id2name.
"Koala".intern #=> :Koala s = 'cat'.to_sym #=> :cat s == :cat #=> true s = '@cat'.to_sym #=> :@cat s == :@cat #=> true
This can also be used to create symbols that cannot be represented using
the :xxx
notation.
'cat and dog'.to_sym #=> :"cat and dog"
VALUE rb_str_intern(VALUE str) { VALUE sym; #if USE_SYMBOL_GC rb_encoding *enc, *ascii; int type; #else ID id; #endif GLOBAL_SYMBOLS_ENTER(symbols); { sym = lookup_str_sym_with_lock(symbols, str); if (sym) { // ok } else { #if USE_SYMBOL_GC enc = rb_enc_get(str); ascii = rb_usascii_encoding(); if (enc != ascii && sym_check_asciionly(str)) { str = rb_str_dup(str); rb_enc_associate(str, ascii); OBJ_FREEZE(str); enc = ascii; } else { str = rb_str_dup(str); OBJ_FREEZE(str); } str = rb_fstring(str); type = rb_str_symname_type(str, IDSET_ATTRSET_FOR_INTERN); if (type < 0) type = ID_JUNK; sym = dsymbol_alloc(symbols, rb_cSymbol, str, enc, type); #else id = intern_str(str, 0); sym = ID2SYM(id); #endif } } GLOBAL_SYMBOLS_LEAVE(); return sym; }
Returns a copy of str
with the characters in
from_str
replaced by the corresponding characters in
to_str
. If to_str
is shorter than
from_str
, it is padded with its last character in order to
maintain the correspondence.
"hello".tr('el', 'ip') #=> "hippo" "hello".tr('aeiou', '*') #=> "h*ll*" "hello".tr('aeiou', 'AA*') #=> "hAll*"
Both strings may use the c1-c2
notation to denote ranges of
characters, and from_str
may start with a ^
,
which denotes all characters except those listed.
"hello".tr('a-y', 'b-z') #=> "ifmmp" "hello".tr('^aeiou', '*') #=> "*e**o"
The backslash character \
can be used to escape ^
or -
and is otherwise ignored unless it appears at the end of
a range or the end of the from_str
or to_str
:
"hello^world".tr("\\^aeiou", "*") #=> "h*ll**w*rld" "hello-world".tr("a\\-eo", "*") #=> "h*ll**w*rld" "hello\r\nworld".tr("\r", "") #=> "hello\nworld" "hello\r\nworld".tr("\\r", "") #=> "hello\r\nwold" "hello\r\nworld".tr("\\\r", "") #=> "hello\nworld" "X['\\b']".tr("X\\", "") #=> "['b']" "X['\\b']".tr("X-\\]", "") #=> "'b'"
static VALUE rb_str_tr(VALUE str, VALUE src, VALUE repl) { str = str_duplicate(rb_cString, str); tr_trans(str, src, repl, 0); return str; }
Translates str in place, using the same rules as #tr. Returns str, or
nil
if no changes were made.
static VALUE rb_str_tr_bang(VALUE str, VALUE src, VALUE repl) { return tr_trans(str, src, repl, 0); }
Processes a copy of str as described under #tr, then removes duplicate characters in regions that were affected by the translation.
"hello".tr_s('l', 'r') #=> "hero" "hello".tr_s('el', '*') #=> "h*o" "hello".tr_s('el', 'hx') #=> "hhxo"
static VALUE rb_str_tr_s(VALUE str, VALUE src, VALUE repl) { str = str_duplicate(rb_cString, str); tr_trans(str, src, repl, 1); return str; }
Performs #tr_s processing on
str in place, returning str, or nil
if no
changes were made.
static VALUE rb_str_tr_s_bang(VALUE str, VALUE src, VALUE repl) { return tr_trans(str, src, repl, 1); }
Returns an unescaped version of the string. This does the inverse of #dump.
"\"hello \\n ''\"".undump #=> "hello \n ''"
static VALUE str_undump(VALUE str) { const char *s = RSTRING_PTR(str); const char *s_end = RSTRING_END(str); rb_encoding *enc = rb_enc_get(str); VALUE undumped = rb_enc_str_new(s, 0L, enc); bool utf8 = false; bool binary = false; int w; rb_must_asciicompat(str); if (rb_str_is_ascii_only_p(str) == Qfalse) { rb_raise(rb_eRuntimeError, "non-ASCII character detected"); } if (!str_null_check(str, &w)) { rb_raise(rb_eRuntimeError, "string contains null byte"); } if (RSTRING_LEN(str) < 2) goto invalid_format; if (*s != '"') goto invalid_format; /* strip '"' at the start */ s++; for (;;) { if (s >= s_end) { rb_raise(rb_eRuntimeError, "unterminated dumped string"); } if (*s == '"') { /* epilogue */ s++; if (s == s_end) { /* ascii compatible dumped string */ break; } else { static const char force_encoding_suffix[] = ".force_encoding(\""; /* "\")" */ static const char dup_suffix[] = ".dup"; const char *encname; int encidx; ptrdiff_t size; /* check separately for strings dumped by older versions */ size = sizeof(dup_suffix) - 1; if (s_end - s > size && memcmp(s, dup_suffix, size) == 0) s += size; size = sizeof(force_encoding_suffix) - 1; if (s_end - s <= size) goto invalid_format; if (memcmp(s, force_encoding_suffix, size) != 0) goto invalid_format; s += size; if (utf8) { rb_raise(rb_eRuntimeError, "dumped string contained Unicode escape but used force_encoding"); } encname = s; s = memchr(s, '"', s_end-s); size = s - encname; if (!s) goto invalid_format; if (s_end - s != 2) goto invalid_format; if (s[0] != '"' || s[1] != ')') goto invalid_format; encidx = rb_enc_find_index2(encname, (long)size); if (encidx < 0) { rb_raise(rb_eRuntimeError, "dumped string has unknown encoding name"); } rb_enc_associate_index(undumped, encidx); } break; } if (*s == '\\') { s++; if (s >= s_end) { rb_raise(rb_eRuntimeError, "invalid escape"); } undump_after_backslash(undumped, &s, s_end, &enc, &utf8, &binary); } else { rb_str_cat(undumped, s++, 1); } } return undumped; invalid_format: rb_raise(rb_eRuntimeError, "invalid dumped string; not wrapped with '\"' nor '\"...\".force_encoding(\"...\")' form"); }
Unicode Normalization—Returns a normalized form of str
, using
Unicode normalizations NFC, NFD, NFKC, or NFKD. The normalization form used
is determined by form
, which can be any of the four values
:nfc
, :nfd
, :nfkc
, or
:nfkd
. The default is :nfc
.
If the string is not in a Unicode Encoding, then an Exception is raised. In this context, ‘Unicode Encoding’ means any of UTF-8, UTF-16BE/LE, and UTF-32BE/LE, as well as GB18030, UCS_2BE, and UCS_4BE. Anything other than UTF-8 is implemented by converting to UTF-8, which makes it slower than UTF-8.
"a\u0300".unicode_normalize #=> "\u00E0" "a\u0300".unicode_normalize(:nfc) #=> "\u00E0" "\u00E0".unicode_normalize(:nfd) #=> "a\u0300" "\xE0".force_encoding('ISO-8859-1').unicode_normalize(:nfd) #=> Encoding::CompatibilityError raised
static VALUE rb_str_unicode_normalize(int argc, VALUE *argv, VALUE str) { return unicode_normalize_common(argc, argv, str, id_normalize); }
Destructive version of #unicode_normalize, doing Unicode normalization in place.
static VALUE rb_str_unicode_normalize_bang(int argc, VALUE *argv, VALUE str) { return rb_str_replace(str, unicode_normalize_common(argc, argv, str, id_normalize)); }
Checks whether str
is in Unicode normalization form
form
, which can be any of the four values :nfc
,
:nfd
, :nfkc
, or :nfkd
. The default
is :nfc
.
If the string is not in a Unicode Encoding, then an Exception is raised. For details, see #unicode_normalize.
"a\u0300".unicode_normalized? #=> false "a\u0300".unicode_normalized?(:nfd) #=> true "\u00E0".unicode_normalized? #=> true "\u00E0".unicode_normalized?(:nfd) #=> false "\xE0".force_encoding('ISO-8859-1').unicode_normalized? #=> Encoding::CompatibilityError raised
static VALUE rb_str_unicode_normalized_p(int argc, VALUE *argv, VALUE str) { return unicode_normalize_common(argc, argv, str, id_normalized_p); }
Decodes str (which may contain binary data) according to the
format string, returning an array of each value extracted. The format
string consists of a sequence of single-character directives, summarized in
the table at the end of this entry. Each directive may be followed by a
number, indicating the number of times to repeat with this directive. An
asterisk (“*
”) will use up all remaining elements. The
directives sSiIlL
may each be followed by an underscore
(“_
”) or exclamation mark (“!
”) to use the
underlying platform’s native size for the specified type; otherwise, it
uses a platform-independent consistent size. Spaces are ignored in the
format string. See also #unpack1, Array#pack.
"abc \0\0abc \0\0".unpack('A6Z6') #=> ["abc", "abc "] "abc \0\0".unpack('a3a3') #=> ["abc", " \000\000"] "abc \0abc \0".unpack('Z*Z*') #=> ["abc ", "abc "] "aa".unpack('b8B8') #=> ["10000110", "01100001"] "aaa".unpack('h2H2c') #=> ["16", "61", 97] "\xfe\xff\xfe\xff".unpack('sS') #=> [-2, 65534] "now=20is".unpack('M*') #=> ["now is"] "whole".unpack('xax2aX2aX1aX2a') #=> ["h", "e", "l", "l", "o"]
This table summarizes the various formats and the Ruby classes returned by each.
Integer | | Directive | Returns | Meaning ------------------------------------------------------------------ C | Integer | 8-bit unsigned (unsigned char) S | Integer | 16-bit unsigned, native endian (uint16_t) L | Integer | 32-bit unsigned, native endian (uint32_t) Q | Integer | 64-bit unsigned, native endian (uint64_t) J | Integer | pointer width unsigned, native endian (uintptr_t) | | c | Integer | 8-bit signed (signed char) s | Integer | 16-bit signed, native endian (int16_t) l | Integer | 32-bit signed, native endian (int32_t) q | Integer | 64-bit signed, native endian (int64_t) j | Integer | pointer width signed, native endian (intptr_t) | | S_ S! | Integer | unsigned short, native endian I I_ I! | Integer | unsigned int, native endian L_ L! | Integer | unsigned long, native endian Q_ Q! | Integer | unsigned long long, native endian (ArgumentError | | if the platform has no long long type.) J! | Integer | uintptr_t, native endian (same with J) | | s_ s! | Integer | signed short, native endian i i_ i! | Integer | signed int, native endian l_ l! | Integer | signed long, native endian q_ q! | Integer | signed long long, native endian (ArgumentError | | if the platform has no long long type.) j! | Integer | intptr_t, native endian (same with j) | | S> s> S!> s!> | Integer | same as the directives without ">" except L> l> L!> l!> | | big endian I!> i!> | | Q> q> Q!> q!> | | "S>" is same as "n" J> j> J!> j!> | | "L>" is same as "N" | | S< s< S!< s!< | Integer | same as the directives without "<" except L< l< L!< l!< | | little endian I!< i!< | | Q< q< Q!< q!< | | "S<" is same as "v" J< j< J!< j!< | | "L<" is same as "V" | | n | Integer | 16-bit unsigned, network (big-endian) byte order N | Integer | 32-bit unsigned, network (big-endian) byte order v | Integer | 16-bit unsigned, VAX (little-endian) byte order V | Integer | 32-bit unsigned, VAX (little-endian) byte order | | U | Integer | UTF-8 character w | Integer | BER-compressed integer (see Array#pack) Float | | Directive | Returns | Meaning ----------------------------------------------------------------- D d | Float | double-precision, native format F f | Float | single-precision, native format E | Float | double-precision, little-endian byte order e | Float | single-precision, little-endian byte order G | Float | double-precision, network (big-endian) byte order g | Float | single-precision, network (big-endian) byte order String | | Directive | Returns | Meaning ----------------------------------------------------------------- A | String | arbitrary binary string (remove trailing nulls and ASCII spaces) a | String | arbitrary binary string Z | String | null-terminated string B | String | bit string (MSB first) b | String | bit string (LSB first) H | String | hex string (high nibble first) h | String | hex string (low nibble first) u | String | UU-encoded string M | String | quoted-printable, MIME encoding (see RFC2045) m | String | base64 encoded string (RFC 2045) (default) | | base64 encoded string (RFC 4648) if followed by 0 P | String | pointer to a structure (fixed-length string) p | String | pointer to a null-terminated string Misc. | | Directive | Returns | Meaning ----------------------------------------------------------------- @ | --- | skip to the offset given by the length argument X | --- | skip backward one byte x | --- | skip forward one byte
HISTORY
J, J! j, and j! are available since Ruby 2.3.
Q_, Q!, q_, and q! are available since Ruby 2.1.
I!<, i!<, I!>, and i!> are available since Ruby 1.9.3.
# File pack.rb, line 256 def unpack(fmt) Primitive.pack_unpack(fmt) end
Decodes str (which may contain binary data) according to the format string, returning the first value extracted. See also #unpack, Array#pack.
Contrast with #unpack:
"abc \0\0abc \0\0".unpack('A6Z6') #=> ["abc", "abc "] "abc \0\0abc \0\0".unpack1('A6Z6') #=> "abc"
In that case data would be lost but often it’s the case that the array only holds one value, especially when unpacking binary data. For instance:
“xffx00x00x00”.unpack(“l”) #=> [255] “xffx00x00x00”.unpack1(“l”) #=> 255
Thus unpack1 is convenient, makes clear the intention and signals the expected return value to those reading the code.
# File pack.rb, line 280 def unpack1(fmt) Primitive.pack_unpack1(fmt) end
Returns a copy of str with all lowercase letters replaced with their uppercase counterparts.
See #downcase for meaning of
options
and use with different encodings.
"hEllO".upcase #=> "HELLO"
static VALUE rb_str_upcase(int argc, VALUE *argv, VALUE str) { rb_encoding *enc; OnigCaseFoldType flags = ONIGENC_CASE_UPCASE; VALUE ret; flags = check_case_options(argc, argv, flags); enc = str_true_enc(str); if (case_option_single_p(flags, enc, str)) { ret = rb_str_new(RSTRING_PTR(str), RSTRING_LEN(str)); str_enc_copy(ret, str); upcase_single(ret); } else if (flags&ONIGENC_CASE_ASCII_ONLY) { ret = rb_str_new(0, RSTRING_LEN(str)); rb_str_ascii_casemap(str, ret, &flags, enc); } else { ret = rb_str_casemap(str, &flags, enc); } return ret; }
Upcases the contents of str, returning nil
if no
changes were made.
See #downcase for meaning of
options
and use with different encodings.
static VALUE rb_str_upcase_bang(int argc, VALUE *argv, VALUE str) { rb_encoding *enc; OnigCaseFoldType flags = ONIGENC_CASE_UPCASE; flags = check_case_options(argc, argv, flags); str_modify_keep_cr(str); enc = str_true_enc(str); if (case_option_single_p(flags, enc, str)) { if (upcase_single(str)) flags |= ONIGENC_CASE_MODIFIED; } else if (flags&ONIGENC_CASE_ASCII_ONLY) rb_str_ascii_casemap(str, str, &flags, enc); else str_shared_replace(str, rb_str_casemap(str, &flags, enc)); if (ONIGENC_CASE_MODIFIED&flags) return str; return Qnil; }
With a block given, calls the block with each String value returned by
successive calls to #succ; the
first value is self
, the next is self.succ
, and
so on; the sequence terminates when value other_string
is
reached; returns self
:
'a8'.upto('b6') {|s| print s, ' ' } # => "a8"
Output:
a8 a9 b0 b1 b2 b3 b4 b5 b6
If argument exclusive
is given as a truthy object, the last
value is omitted:
'a8'.upto('b6', true) {|s| print s, ' ' } # => "a8"
Output:
a8 a9 b0 b1 b2 b3 b4 b5
If other_string
would not be reached, does not call the block:
'25'.upto('5') {|s| fail s } 'aa'.upto('a') {|s| fail s }
With no block given, returns a new Enumerator:
'a8'.upto('b6') # => #<Enumerator: "a8":upto("b6")>
static VALUE rb_str_upto(int argc, VALUE *argv, VALUE beg) { VALUE end, exclusive; rb_scan_args(argc, argv, "11", &end, &exclusive); RETURN_ENUMERATOR(beg, argc, argv); return rb_str_upto_each(beg, end, RTEST(exclusive), str_upto_i, Qnil); }
Returns true for a string which is encoded correctly.
"\xc2\xa1".force_encoding("UTF-8").valid_encoding? #=> true "\xc2".force_encoding("UTF-8").valid_encoding? #=> false "\x80".force_encoding("UTF-8").valid_encoding? #=> false
static VALUE rb_str_valid_encoding_p(VALUE str) { int cr = rb_enc_str_coderange(str); return cr == ENC_CODERANGE_BROKEN ? Qfalse : Qtrue; }