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# A Regexp holds a regular expression, used to match a pattern against strings.
# Regexps are created using the `/.../` and `%r{...}` literals, and by the
# Regexp::new constructor.
#
# Regular expressions (*regexp*s) are patterns which describe the contents of a
# string. They're used for testing whether a string contains a given pattern, or
# extracting the portions that match. They are created with the `/`*pat*`/` and
# `%r{`*pat*`}` literals or the `Regexp.new` constructor.
#
# A regexp is usually delimited with forward slashes (`/`). For example:
#
# /hay/ =~ 'haystack' #=> 0
# /y/.match('haystack') #=> #<MatchData "y">
#
# If a string contains the pattern it is said to *match*. A literal string
# matches itself.
#
# Here 'haystack' does not contain the pattern 'needle', so it doesn't match:
#
# /needle/.match('haystack') #=> nil
#
# Here 'haystack' contains the pattern 'hay', so it matches:
#
# /hay/.match('haystack') #=> #<MatchData "hay">
#
# Specifically, `/st/` requires that the string contains the letter *s* followed
# by the letter *t*, so it matches *haystack*, also.
#
# ## `=~` and Regexp#match
#
# Pattern matching may be achieved by using `=~` operator or Regexp#match
# method.
#
# ### `=~` operator
#
# `=~` is Ruby's basic pattern-matching operator. When one operand is a regular
# expression and the other is a string then the regular expression is used as a
# pattern to match against the string. (This operator is equivalently defined
# by Regexp and String so the order of String and Regexp do not matter. Other
# classes may have different implementations of `=~`.) If a match is found, the
# operator returns index of first match in string, otherwise it returns `nil`.
#
# /hay/ =~ 'haystack' #=> 0
# 'haystack' =~ /hay/ #=> 0
# /a/ =~ 'haystack' #=> 1
# /u/ =~ 'haystack' #=> nil
#
# Using `=~` operator with a String and Regexp the `$~` global variable is set
# after a successful match. `$~` holds a MatchData object. Regexp.last_match is
# equivalent to `$~`.
#
# ### Regexp#match method
#
# The #match method returns a MatchData object:
#
# /st/.match('haystack') #=> #<MatchData "st">
#
# ## Metacharacters and Escapes
#
# The following are *metacharacters* `(`, `)`, `[`, `]`, `{`, `}`, `.`, `?`,
# `+`, `*`. They have a specific meaning when appearing in a pattern. To match
# them literally they must be backslash-escaped. To match a backslash literally,
# backslash-escape it: `\\\`.
#
# /1 \+ 2 = 3\?/.match('Does 1 + 2 = 3?') #=> #<MatchData "1 + 2 = 3?">
# /a\\\\b/.match('a\\\\b') #=> #<MatchData "a\\b">
#
# Patterns behave like double-quoted strings and can contain the same backslash
# escapes (the meaning of `\s` is different, however, see
# [below](#label-Character+Classes)).
#
# /\s\u{6771 4eac 90fd}/.match("Go to 東京都")
# #=> #<MatchData " 東京都">
#
# Arbitrary Ruby expressions can be embedded into patterns with the `#{...}`
# construct.
#
# place = "東京都"
# /#{place}/.match("Go to 東京都")
# #=> #<MatchData "東京都">
#
# ## Character Classes
#
# A *character class* is delimited with square brackets (`[`, `]`) and lists
# characters that may appear at that point in the match. `/[ab]/` means *a* or
# *b*, as opposed to `/ab/` which means *a* followed by *b*.
#
# /W[aeiou]rd/.match("Word") #=> #<MatchData "Word">
#
# Within a character class the hyphen (`-`) is a metacharacter denoting an
# inclusive range of characters. `[abcd]` is equivalent to `[a-d]`. A range can
# be followed by another range, so `[abcdwxyz]` is equivalent to `[a-dw-z]`. The
# order in which ranges or individual characters appear inside a character class
# is irrelevant.
#
# /[0-9a-f]/.match('9f') #=> #<MatchData "9">
# /[9f]/.match('9f') #=> #<MatchData "9">
#
# If the first character of a character class is a caret (`^`) the class is
# inverted: it matches any character *except* those named.
#
# /[^a-eg-z]/.match('f') #=> #<MatchData "f">
#
# A character class may contain another character class. By itself this isn't
# useful because `[a-z[0-9]]` describes the same set as `[a-z0-9]`. However,
# character classes also support the `&&` operator which performs set
# intersection on its arguments. The two can be combined as follows:
#
# /[a-w&&[^c-g]z]/ # ([a-w] AND ([^c-g] OR z))
#
# This is equivalent to:
#
# /[abh-w]/
#
# The following metacharacters also behave like character classes:
#
# * `/./` - Any character except a newline.
# * `/./m` - Any character (the `m` modifier enables multiline mode)
# * `/\w/` - A word character (`[a-zA-Z0-9_]`)
# * `/\W/` - A non-word character (`[^a-zA-Z0-9_]`). Please take a look at
# [Bug #4044](https://bugs.ruby-lang.org/issues/4044) if using `/\W/` with
# the `/i` modifier.
# * `/\d/` - A digit character (`[0-9]`)
# * `/\D/` - A non-digit character (`[^0-9]`)
# * `/\h/` - A hexdigit character (`[0-9a-fA-F]`)
# * `/\H/` - A non-hexdigit character (`[^0-9a-fA-F]`)
# * `/\s/` - A whitespace character: `/[ \t\r\n\f\v]/`
# * `/\S/` - A non-whitespace character: `/[^ \t\r\n\f\v]/`
# * `/\R/` - A linebreak: `\n`, `\v`, `\f`, `\r` `\u0085` (NEXT LINE),
# `\u2028` (LINE SEPARATOR), `\u2029` (PARAGRAPH SEPARATOR) or `\r\n`.
#
#
# POSIX *bracket expressions* are also similar to character classes. They
# provide a portable alternative to the above, with the added benefit that they
# encompass non-ASCII characters. For instance, `/\d/` matches only the ASCII
# decimal digits (0-9); whereas `/[[:digit:]]/` matches any character in the
# Unicode *Nd* category.
#
# * `/[[:alnum:]]/` - Alphabetic and numeric character
# * `/[[:alpha:]]/` - Alphabetic character
# * `/[[:blank:]]/` - Space or tab
# * `/[[:cntrl:]]/` - Control character
# * `/[[:digit:]]/` - Digit
# * `/[[:graph:]]/` - Non-blank character (excludes spaces, control
# characters, and similar)
# * `/[[:lower:]]/` - Lowercase alphabetical character
# * `/[[:print:]]/` - Like [:graph:], but includes the space character
# * `/[[:punct:]]/` - Punctuation character
# * `/[[:space:]]/` - Whitespace character (`[:blank:]`, newline, carriage
# return, etc.)
# * `/[[:upper:]]/` - Uppercase alphabetical
# * `/[[:xdigit:]]/` - Digit allowed in a hexadecimal number (i.e., 0-9a-fA-F)
#
#
# Ruby also supports the following non-POSIX character classes:
#
# * `/[[:word:]]/` - A character in one of the following Unicode general
# categories *Letter*, *Mark*, *Number*, *Connector_Punctuation*
# * `/[[:ascii:]]/` - A character in the ASCII character set
#
# # U+06F2 is "EXTENDED ARABIC-INDIC DIGIT TWO"
# /[[:digit:]]/.match("\u06F2") #=> #<MatchData "\u{06F2}">
# /[[:upper:]][[:lower:]]/.match("Hello") #=> #<MatchData "He">
# /[[:xdigit:]][[:xdigit:]]/.match("A6") #=> #<MatchData "A6">
#
#
# ## Repetition
#
# The constructs described so far match a single character. They can be followed
# by a repetition metacharacter to specify how many times they need to occur.
# Such metacharacters are called *quantifiers*.
#
# * `*` - Zero or more times
# * `+` - One or more times
# * `?` - Zero or one times (optional)
# * `{`*n*`}` - Exactly *n* times
# * `{`*n*`,}` - *n* or more times
# * `{,`*m*`}` - *m* or less times
# * `{`*n*`,`*m*`}` - At least *n* and at most *m* times
#
#
# At least one uppercase character ('H'), at least one lowercase character
# ('e'), two 'l' characters, then one 'o':
#
# "Hello".match(/[[:upper:]]+[[:lower:]]+l{2}o/) #=> #<MatchData "Hello">
#
# Repetition is *greedy* by default: as many occurrences as possible are matched
# while still allowing the overall match to succeed. By contrast, *lazy*
# matching makes the minimal amount of matches necessary for overall success.
# Most greedy metacharacters can be made lazy by following them with `?`. For
# the `{n}` pattern, because it specifies an exact number of characters to match
# and not a variable number of characters, the `?` metacharacter instead makes
# the repeated pattern optional.
#
# Both patterns below match the string. The first uses a greedy quantifier so
# '.+' matches '<a><b>'; the second uses a lazy quantifier so '.+?' matches
# '<a>':
#
# /<.+>/.match("<a><b>") #=> #<MatchData "<a><b>">
# /<.+?>/.match("<a><b>") #=> #<MatchData "<a>">
#
# A quantifier followed by `+` matches *possessively*: once it has matched it
# does not backtrack. They behave like greedy quantifiers, but having matched
# they refuse to "give up" their match even if this jeopardises the overall
# match.
#
# ## Capturing
#
# Parentheses can be used for *capturing*. The text enclosed by the
# *n*<sup>th</sup> group of parentheses can be subsequently referred to with
# *n*. Within a pattern use the *backreference* `\n`; outside of the pattern use
# `MatchData[n]`.
#
# 'at' is captured by the first group of parentheses, then referred to later
# with `\1`:
#
# /[csh](..) [csh]\1 in/.match("The cat sat in the hat")
# #=> #<MatchData "cat sat in" 1:"at">
#
# Regexp#match returns a MatchData object which makes the captured text
# available with its #[] method:
#
# /[csh](..) [csh]\1 in/.match("The cat sat in the hat")[1] #=> 'at'
#
# Capture groups can be referred to by name when defined with the
# `(?<`*name*`>)` or `(?'`*name*`')` constructs.
#
# /\$(?<dollars>\d+)\.(?<cents>\d+)/.match("$3.67")
# #=> #<MatchData "$3.67" dollars:"3" cents:"67">
# /\$(?<dollars>\d+)\.(?<cents>\d+)/.match("$3.67")[:dollars] #=> "3"
#
# Named groups can be backreferenced with `\k<`*name*`>`, where *name* is the
# group name.
#
# /(?<vowel>[aeiou]).\k<vowel>.\k<vowel>/.match('ototomy')
# #=> #<MatchData "ototo" vowel:"o">
#
# **Note**: A regexp can't use named backreferences and numbered backreferences
# simultaneously. Also, if a named capture is used in a regexp, then parentheses
# used for grouping which would otherwise result in a unnamed capture are
# treated as non-capturing.
#
# /(\w)(\w)/.match("ab").captures # => ["a", "b"]
# /(\w)(\w)/.match("ab").named_captures # => {}
#
# /(?<c>\w)(\w)/.match("ab").captures # => ["a"]
# /(?<c>\w)(\w)/.match("ab").named_captures # => {"c"=>"a"}
#
# When named capture groups are used with a literal regexp on the left-hand side
# of an expression and the `=~` operator, the captured text is also assigned to
# local variables with corresponding names.
#
# /\$(?<dollars>\d+)\.(?<cents>\d+)/ =~ "$3.67" #=> 0
# dollars #=> "3"
#
# ## Grouping
#
# Parentheses also *group* the terms they enclose, allowing them to be
# quantified as one *atomic* whole.
#
# The pattern below matches a vowel followed by 2 word characters:
#
# /[aeiou]\w{2}/.match("Caenorhabditis elegans") #=> #<MatchData "aen">
#
# Whereas the following pattern matches a vowel followed by a word character,
# twice, i.e. `[aeiou]\w[aeiou]\w`: 'enor'.
#
# /([aeiou]\w){2}/.match("Caenorhabditis elegans")
# #=> #<MatchData "enor" 1:"or">
#
# The `(?:`...`)` construct provides grouping without capturing. That is, it
# combines the terms it contains into an atomic whole without creating a
# backreference. This benefits performance at the slight expense of readability.
#
# The first group of parentheses captures 'n' and the second 'ti'. The second
# group is referred to later with the backreference `\2`:
#
# /I(n)ves(ti)ga\2ons/.match("Investigations")
# #=> #<MatchData "Investigations" 1:"n" 2:"ti">
#
# The first group of parentheses is now made non-capturing with '?:', so it
# still matches 'n', but doesn't create the backreference. Thus, the
# backreference `\1` now refers to 'ti'.
#
# /I(?:n)ves(ti)ga\1ons/.match("Investigations")
# #=> #<MatchData "Investigations" 1:"ti">
#
# ### Atomic Grouping
#
# Grouping can be made *atomic* with `(?>`*pat*`)`. This causes the
# subexpression *pat* to be matched independently of the rest of the expression
# such that what it matches becomes fixed for the remainder of the match, unless
# the entire subexpression must be abandoned and subsequently revisited. In this
# way *pat* is treated as a non-divisible whole. Atomic grouping is typically
# used to optimise patterns so as to prevent the regular expression engine from
# backtracking needlessly.
#
# The `"` in the pattern below matches the first character of the string, then
# `.*` matches *Quote"*. This causes the overall match to fail, so the text
# matched by `.*` is backtracked by one position, which leaves the final
# character of the string available to match `"`
#
# /".*"/.match('"Quote"') #=> #<MatchData "\"Quote\"">
#
# If `.*` is grouped atomically, it refuses to backtrack *Quote"*, even though
# this means that the overall match fails
#
# /"(?>.*)"/.match('"Quote"') #=> nil
#
# ## Subexpression Calls
#
# The `\g<`*name*`>` syntax matches the previous subexpression named *name*,
# which can be a group name or number, again. This differs from backreferences
# in that it re-executes the group rather than simply trying to re-match the
# same text.
#
# This pattern matches a *(* character and assigns it to the `paren` group,
# tries to call that the `paren` sub-expression again but fails, then matches a
# literal *)*:
#
# /\A(?<paren>\(\g<paren>*\))*\z/ =~ '()'
#
# /\A(?<paren>\(\g<paren>*\))*\z/ =~ '(())' #=> 0
# # ^1
# # ^2
# # ^3
# # ^4
# # ^5
# # ^6
# # ^7
# # ^8
# # ^9
# # ^10
#
# 1. Matches at the beginning of the string, i.e. before the first character.
# 2. Enters a named capture group called `paren`
# 3. Matches a literal *(*, the first character in the string
# 4. Calls the `paren` group again, i.e. recurses back to the second step
# 5. Re-enters the `paren` group
# 6. Matches a literal *(*, the second character in the string
# 7. Try to call `paren` a third time, but fail because doing so would prevent
# an overall successful match
# 8. Match a literal *)*, the third character in the string. Marks the end of
# the second recursive call
# 9. Match a literal *)*, the fourth character in the string
# 10. Match the end of the string
#
#
# ## Alternation
#
# The vertical bar metacharacter (`|`) combines two expressions into a single
# one that matches either of the expressions. Each expression is an
# *alternative*.
#
# /\w(and|or)\w/.match("Feliformia") #=> #<MatchData "form" 1:"or">
# /\w(and|or)\w/.match("furandi") #=> #<MatchData "randi" 1:"and">
# /\w(and|or)\w/.match("dissemblance") #=> nil
#
# ## Character Properties
#
# The `\p{}` construct matches characters with the named property, much like
# POSIX bracket classes.
#
# * `/\p{Alnum}/` - Alphabetic and numeric character
# * `/\p{Alpha}/` - Alphabetic character
# * `/\p{Blank}/` - Space or tab
# * `/\p{Cntrl}/` - Control character
# * `/\p{Digit}/` - Digit
# * `/\p{Graph}/` - Non-blank character (excludes spaces, control characters,
# and similar)
# * `/\p{Lower}/` - Lowercase alphabetical character
# * `/\p{Print}/` - Like `\p{Graph}`, but includes the space character
# * `/\p{Punct}/` - Punctuation character
# * `/\p{Space}/` - Whitespace character (`[:blank:]`, newline, carriage
# return, etc.)
# * `/\p{Upper}/` - Uppercase alphabetical
# * `/\p{XDigit}/` - Digit allowed in a hexadecimal number (i.e., 0-9a-fA-F)
# * `/\p{Word}/` - A member of one of the following Unicode general category
# *Letter*, *Mark*, *Number*, *Connector_Punctuation*
# * `/\p{ASCII}/` - A character in the ASCII character set
# * `/\p{Any}/` - Any Unicode character (including unassigned characters)
# * `/\p{Assigned}/` - An assigned character
#
#
# A Unicode character's *General Category* value can also be matched with
# `\p{`*Ab*`}` where *Ab* is the category's abbreviation as described below:
#
# * `/\p{L}/` - 'Letter'
# * `/\p{Ll}/` - 'Letter: Lowercase'
# * `/\p{Lm}/` - 'Letter: Mark'
# * `/\p{Lo}/` - 'Letter: Other'
# * `/\p{Lt}/` - 'Letter: Titlecase'
# * `/\p{Lu}/` - 'Letter: Uppercase
# * `/\p{Lo}/` - 'Letter: Other'
# * `/\p{M}/` - 'Mark'
# * `/\p{Mn}/` - 'Mark: Nonspacing'
# * `/\p{Mc}/` - 'Mark: Spacing Combining'
# * `/\p{Me}/` - 'Mark: Enclosing'
# * `/\p{N}/` - 'Number'
# * `/\p{Nd}/` - 'Number: Decimal Digit'
# * `/\p{Nl}/` - 'Number: Letter'
# * `/\p{No}/` - 'Number: Other'
# * `/\p{P}/` - 'Punctuation'
# * `/\p{Pc}/` - 'Punctuation: Connector'
# * `/\p{Pd}/` - 'Punctuation: Dash'
# * `/\p{Ps}/` - 'Punctuation: Open'
# * `/\p{Pe}/` - 'Punctuation: Close'
# * `/\p{Pi}/` - 'Punctuation: Initial Quote'
# * `/\p{Pf}/` - 'Punctuation: Final Quote'
# * `/\p{Po}/` - 'Punctuation: Other'
# * `/\p{S}/` - 'Symbol'
# * `/\p{Sm}/` - 'Symbol: Math'
# * `/\p{Sc}/` - 'Symbol: Currency'
# * `/\p{Sc}/` - 'Symbol: Currency'
# * `/\p{Sk}/` - 'Symbol: Modifier'
# * `/\p{So}/` - 'Symbol: Other'
# * `/\p{Z}/` - 'Separator'
# * `/\p{Zs}/` - 'Separator: Space'
# * `/\p{Zl}/` - 'Separator: Line'
# * `/\p{Zp}/` - 'Separator: Paragraph'
# * `/\p{C}/` - 'Other'
# * `/\p{Cc}/` - 'Other: Control'
# * `/\p{Cf}/` - 'Other: Format'
# * `/\p{Cn}/` - 'Other: Not Assigned'
# * `/\p{Co}/` - 'Other: Private Use'
# * `/\p{Cs}/` - 'Other: Surrogate'
#
#
# Lastly, `\p{}` matches a character's Unicode *script*. The following scripts
# are supported: *Arabic*, *Armenian*, *Balinese*, *Bengali*, *Bopomofo*,
# *Braille*, *Buginese*, *Buhid*, *Canadian_Aboriginal*, *Carian*, *Cham*,
# *Cherokee*, *Common*, *Coptic*, *Cuneiform*, *Cypriot*, *Cyrillic*, *Deseret*,
# *Devanagari*, *Ethiopic*, *Georgian*, *Glagolitic*, *Gothic*, *Greek*,
# *Gujarati*, *Gurmukhi*, *Han*, *Hangul*, *Hanunoo*, *Hebrew*, *Hiragana*,
# *Inherited*, *Kannada*, *Katakana*, *Kayah_Li*, *Kharoshthi*, *Khmer*, *Lao*,
# *Latin*, *Lepcha*, *Limbu*, *Linear_B*, *Lycian*, *Lydian*, *Malayalam*,
# *Mongolian*, *Myanmar*, *New_Tai_Lue*, *Nko*, *Ogham*, *Ol_Chiki*,
# *Old_Italic*, *Old_Persian*, *Oriya*, *Osmanya*, *Phags_Pa*, *Phoenician*,
# *Rejang*, *Runic*, *Saurashtra*, *Shavian*, *Sinhala*, *Sundanese*,
# *Syloti_Nagri*, *Syriac*, *Tagalog*, *Tagbanwa*, *Tai_Le*, *Tamil*, *Telugu*,
# *Thaana*, *Thai*, *Tibetan*, *Tifinagh*, *Ugaritic*, *Vai*, and *Yi*.
#
# Unicode codepoint U+06E9 is named "ARABIC PLACE OF SAJDAH" and belongs to the
# Arabic script:
#
# /\p{Arabic}/.match("\u06E9") #=> #<MatchData "\u06E9">
#
# All character properties can be inverted by prefixing their name with a caret
# (`^`).
#
# Letter 'A' is not in the Unicode Ll (Letter; Lowercase) category, so this
# match succeeds:
#
# /\p{^Ll}/.match("A") #=> #<MatchData "A">
#
# ## Anchors
#
# Anchors are metacharacter that match the zero-width positions between
# characters, *anchoring* the match to a specific position.
#
# * `^` - Matches beginning of line
# * `$` - Matches end of line
# * `\A` - Matches beginning of string.
# * `\Z` - Matches end of string. If string ends with a newline, it matches
# just before newline
# * `\z` - Matches end of string
# * `\G` - Matches first matching position:
#
# In methods like `String#gsub` and `String#scan`, it changes on each
# iteration. It initially matches the beginning of subject, and in each
# following iteration it matches where the last match finished.
#
# " a b c".gsub(/ /, '_') #=> "____a_b_c"
# " a b c".gsub(/\G /, '_') #=> "____a b c"
#
# In methods like `Regexp#match` and `String#match` that take an (optional)
# offset, it matches where the search begins.
#
# "hello, world".match(/,/, 3) #=> #<MatchData ",">
# "hello, world".match(/\G,/, 3) #=> nil
#
# * `\b` - Matches word boundaries when outside brackets; backspace (0x08)
# when inside brackets
# * `\B` - Matches non-word boundaries
# * `(?=`*pat*`)` - *Positive lookahead* assertion: ensures that the following
# characters match *pat*, but doesn't include those characters in the
# matched text
# * `(?!`*pat*`)` - *Negative lookahead* assertion: ensures that the following
# characters do not match *pat*, but doesn't include those characters in the
# matched text
# * `(?<=`*pat*`)` - *Positive lookbehind* assertion: ensures that the
# preceding characters match *pat*, but doesn't include those characters in
# the matched text
# * `(?<!`*pat*`)` - *Negative lookbehind* assertion: ensures that the
# preceding characters do not match *pat*, but doesn't include those
# characters in the matched text
#
#
# If a pattern isn't anchored it can begin at any point in the string:
#
# /real/.match("surrealist") #=> #<MatchData "real">
#
# Anchoring the pattern to the beginning of the string forces the match to start
# there. 'real' doesn't occur at the beginning of the string, so now the match
# fails:
#
# /\Areal/.match("surrealist") #=> nil
#
# The match below fails because although 'Demand' contains 'and', the pattern
# does not occur at a word boundary.
#
# /\band/.match("Demand")
#
# Whereas in the following example 'and' has been anchored to a non-word
# boundary so instead of matching the first 'and' it matches from the fourth
# letter of 'demand' instead:
#
# /\Band.+/.match("Supply and demand curve") #=> #<MatchData "and curve">
#
# The pattern below uses positive lookahead and positive lookbehind to match
# text appearing in tags without including the tags in the match:
#
# /(?<=<b>)\w+(?=<\/b>)/.match("Fortune favours the <b>bold</b>")
# #=> #<MatchData "bold">
#
# ## Options
#
# The end delimiter for a regexp can be followed by one or more single-letter
# options which control how the pattern can match.
#
# * `/pat/i` - Ignore case
# * `/pat/m` - Treat a newline as a character matched by `.`
# * `/pat/x` - Ignore whitespace and comments in the pattern
# * `/pat/o` - Perform `#{}` interpolation only once
#
#
# `i`, `m`, and `x` can also be applied on the subexpression level with the
# `(?`*on*`-`*off*`)` construct, which enables options *on*, and disables
# options *off* for the expression enclosed by the parentheses:
#
# /a(?i:b)c/.match('aBc') #=> #<MatchData "aBc">
# /a(?-i:b)c/i.match('ABC') #=> nil
#
# Additionally, these options can also be toggled for the remainder of the
# pattern:
#
# /a(?i)bc/.match('abC') #=> #<MatchData "abC">
#
# Options may also be used with `Regexp.new`:
#
# Regexp.new("abc", Regexp::IGNORECASE) #=> /abc/i
# Regexp.new("abc", Regexp::MULTILINE) #=> /abc/m
# Regexp.new("abc # Comment", Regexp::EXTENDED) #=> /abc # Comment/x
# Regexp.new("abc", Regexp::IGNORECASE | Regexp::MULTILINE) #=> /abc/mi
#
# ## Free-Spacing Mode and Comments
#
# As mentioned above, the `x` option enables *free-spacing* mode. Literal white
# space inside the pattern is ignored, and the octothorpe (`#`) character
# introduces a comment until the end of the line. This allows the components of
# the pattern to be organized in a potentially more readable fashion.
#
# A contrived pattern to match a number with optional decimal places:
#
# float_pat = /\A
# [[:digit:]]+ # 1 or more digits before the decimal point
# (\. # Decimal point
# [[:digit:]]+ # 1 or more digits after the decimal point
# )? # The decimal point and following digits are optional
# \Z/x
# float_pat.match('3.14') #=> #<MatchData "3.14" 1:".14">
#
# There are a number of strategies for matching whitespace:
#
# * Use a pattern such as `\s` or `\p{Space}`.
# * Use escaped whitespace such as `\ `, i.e. a space preceded by a backslash.
# * Use a character class such as `[ ]`.
#
#
# Comments can be included in a non-`x` pattern with the `(?#`*comment*`)`
# construct, where *comment* is arbitrary text ignored by the regexp engine.
#
# Comments in regexp literals cannot include unescaped terminator characters.
#
# ## Encoding
#
# Regular expressions are assumed to use the source encoding. This can be
# overridden with one of the following modifiers.
#
# * `/`*pat*`/u` - UTF-8
# * `/`*pat*`/e` - EUC-JP
# * `/`*pat*`/s` - Windows-31J
# * `/`*pat*`/n` - ASCII-8BIT
#
#
# A regexp can be matched against a string when they either share an encoding,
# or the regexp's encoding is *US-ASCII* and the string's encoding is
# ASCII-compatible.
#
# If a match between incompatible encodings is attempted an
# `Encoding::CompatibilityError` exception is raised.
#
# The `Regexp#fixed_encoding?` predicate indicates whether the regexp has a
# *fixed* encoding, that is one incompatible with ASCII. A regexp's encoding can
# be explicitly fixed by supplying `Regexp::FIXEDENCODING` as the second
# argument of `Regexp.new`:
#
# r = Regexp.new("a".force_encoding("iso-8859-1"),Regexp::FIXEDENCODING)
# r =~ "a\u3042"
# # raises Encoding::CompatibilityError: incompatible encoding regexp match
# # (ISO-8859-1 regexp with UTF-8 string)
#
# ## Special global variables
#
# Pattern matching sets some global variables :
# * `$~` is equivalent to Regexp.last_match;
# * `$&` contains the complete matched text;
# * `$`` contains string before match;
# * `$'` contains string after match;
# * `$1`, `$2` and so on contain text matching first, second, etc capture
# group;
# * `$+` contains last capture group.
#
#
# Example:
#
# m = /s(\w{2}).*(c)/.match('haystack') #=> #<MatchData "stac" 1:"ta" 2:"c">
# $~ #=> #<MatchData "stac" 1:"ta" 2:"c">
# Regexp.last_match #=> #<MatchData "stac" 1:"ta" 2:"c">
#
# $& #=> "stac"
# # same as m[0]
# $` #=> "hay"
# # same as m.pre_match
# $' #=> "k"
# # same as m.post_match
# $1 #=> "ta"
# # same as m[1]
# $2 #=> "c"
# # same as m[2]
# $3 #=> nil
# # no third group in pattern
# $+ #=> "c"
# # same as m[-1]
#
# These global variables are thread-local and method-local variables.
#
# ## Performance
#
# Certain pathological combinations of constructs can lead to abysmally bad
# performance.
#
# Consider a string of 25 *a*s, a *d*, 4 *a*s, and a *c*.
#
# s = 'a' * 25 + 'd' + 'a' * 4 + 'c'
# #=> "aaaaaaaaaaaaaaaaaaaaaaaaadaaaac"
#
# The following patterns match instantly as you would expect:
#
# /(b|a)/ =~ s #=> 0
# /(b|a+)/ =~ s #=> 0
# /(b|a+)*/ =~ s #=> 0
#
# However, the following pattern takes appreciably longer:
#
# /(b|a+)*c/ =~ s #=> 26
#
# This happens because an atom in the regexp is quantified by both an immediate
# `+` and an enclosing `*` with nothing to differentiate which is in control of
# any particular character. The nondeterminism that results produces
# super-linear performance. (Consult *Mastering Regular Expressions* (3rd ed.),
# pp 222, by *Jeffery Friedl*, for an in-depth analysis). This particular case
# can be fixed by use of atomic grouping, which prevents the unnecessary
# backtracking:
#
# (start = Time.now) && /(b|a+)*c/ =~ s && (Time.now - start)
# #=> 24.702736882
# (start = Time.now) && /(?>b|a+)*c/ =~ s && (Time.now - start)
# #=> 0.000166571
#
# A similar case is typified by the following example, which takes approximately
# 60 seconds to execute for me:
#
# Match a string of 29 *a*s against a pattern of 29 optional *a*s followed by 29
# mandatory *a*s:
#
# Regexp.new('a?' * 29 + 'a' * 29) =~ 'a' * 29
#
# The 29 optional *a*s match the string, but this prevents the 29 mandatory *a*s
# that follow from matching. Ruby must then backtrack repeatedly so as to
# satisfy as many of the optional matches as it can while still matching the
# mandatory 29. It is plain to us that none of the optional matches can succeed,
# but this fact unfortunately eludes Ruby.
#
# The best way to improve performance is to significantly reduce the amount of
# backtracking needed. For this case, instead of individually matching 29
# optional *a*s, a range of optional *a*s can be matched all at once with
# *a{0,29}*:
#
# Regexp.new('a{0,29}' + 'a' * 29) =~ 'a' * 29
#
class Regexp
# Constructs a new regular expression from `pattern`, which can be either a
# String or a Regexp (in which case that regexp's options are propagated), and
# new options may not be specified (a change as of Ruby 1.8).
#
# If `options` is an Integer, it should be one or more of the constants
# Regexp::EXTENDED, Regexp::IGNORECASE, and Regexp::MULTILINE, *or*-ed together.
# Otherwise, if `options` is not `nil` or `false`, the regexp will be case
# insensitive.
#
# r1 = Regexp.new('^a-z+:\\s+\w+') #=> /^a-z+:\s+\w+/
# r2 = Regexp.new('cat', true) #=> /cat/i
# r3 = Regexp.new(r2) #=> /cat/i
# r4 = Regexp.new('dog', Regexp::EXTENDED | Regexp::IGNORECASE) #=> /dog/ix
#
def initialize: (String string, ?untyped options, ?String kcode) -> Object
| (Regexp regexp) -> void
# Alias for Regexp.new
#
def self.compile: (String string, ?untyped options, ?String kcode) -> Regexp
| (Regexp regexp) -> Regexp
# Escapes any characters that would have special meaning in a regular
# expression. Returns a new escaped string with the same or compatible encoding.
# For any string, `Regexp.new(Regexp.escape(*str*))=~*str`* will be true.
#
# Regexp.escape('\*?{}.') #=> \\\*\?\{\}\.
#
def self.escape: (String | Symbol str) -> String
# The first form returns the MatchData object generated by the last successful
# pattern match. Equivalent to reading the special global variable `$~` (see
# Special global variables in Regexp for details).
#
# The second form returns the *n*th field in this MatchData object. *n* can be a
# string or symbol to reference a named capture.
#
# Note that the last_match is local to the thread and method scope of the method
# that did the pattern match.
#
# /c(.)t/ =~ 'cat' #=> 0
# Regexp.last_match #=> #<MatchData "cat" 1:"a">
# Regexp.last_match(0) #=> "cat"
# Regexp.last_match(1) #=> "a"
# Regexp.last_match(2) #=> nil
#
# /(?<lhs>\w+)\s*=\s*(?<rhs>\w+)/ =~ "var = val"
# Regexp.last_match #=> #<MatchData "var = val" lhs:"var" rhs:"val">
# Regexp.last_match(:lhs) #=> "var"
# Regexp.last_match(:rhs) #=> "val"
#
def self.last_match: () -> MatchData?
| (Integer n) -> String?
| (Symbol | String n) -> String?
# Escapes any characters that would have special meaning in a regular
# expression. Returns a new escaped string with the same or compatible encoding.
# For any string, `Regexp.new(Regexp.escape(*str*))=~*str`* will be true.
#
# Regexp.escape('\*?{}.') #=> \\\*\?\{\}\.
#
def self.quote: (String | Symbol str) -> String
# Try to convert *obj* into a Regexp, using to_regexp method. Returns converted
# regexp or nil if *obj* cannot be converted for any reason.
#
# Regexp.try_convert(/re/) #=> /re/
# Regexp.try_convert("re") #=> nil
#
# o = Object.new
# Regexp.try_convert(o) #=> nil
# def o.to_regexp() /foo/ end
# Regexp.try_convert(o) #=> /foo/
#
def self.try_convert: (untyped obj) -> Regexp?
# Return a Regexp object that is the union of the given *pattern*s, i.e., will
# match any of its parts. The *pattern*s can be Regexp objects, in which case
# their options will be preserved, or Strings. If no patterns are given, returns
# `/(?!)/`. The behavior is unspecified if any given *pattern* contains
# capture.
#
# Regexp.union #=> /(?!)/
# Regexp.union("penzance") #=> /penzance/
# Regexp.union("a+b*c") #=> /a\+b\*c/
# Regexp.union("skiing", "sledding") #=> /skiing|sledding/
# Regexp.union(["skiing", "sledding"]) #=> /skiing|sledding/
# Regexp.union(/dogs/, /cats/i) #=> /(?-mix:dogs)|(?i-mx:cats)/
#
# Note: the arguments for ::union will try to be converted into a regular
# expression literal via #to_regexp.
#
def self.union: () -> Regexp
| (String | Regexp pat1, *String | Regexp pat2) -> Regexp
| (::Array[String | Regexp]) -> Regexp
public
# Equality---Two regexps are equal if their patterns are identical, they have
# the same character set code, and their `casefold?` values are the same.
#
# /abc/ == /abc/x #=> false
# /abc/ == /abc/i #=> false
# /abc/ == /abc/u #=> false
# /abc/u == /abc/n #=> false
#
def ==: (untyped other) -> bool
# Case Equality---Used in case statements.
#
# a = "HELLO"
# case a
# when /\A[a-z]*\z/; print "Lower case\n"
# when /\A[A-Z]*\z/; print "Upper case\n"
# else; print "Mixed case\n"
# end
# #=> "Upper case"
#
# Following a regular expression literal with the #=== operator allows you to
# compare against a String.
#
# /^[a-z]*$/ === "HELLO" #=> false
# /^[A-Z]*$/ === "HELLO" #=> true
#
def ===: (untyped other) -> bool
# Match---Matches *rxp* against *str*.
#
# /at/ =~ "input data" #=> 7
# /ax/ =~ "input data" #=> nil
#
# If `=~` is used with a regexp literal with named captures, captured strings
# (or nil) is assigned to local variables named by the capture names.
#
# /(?<lhs>\w+)\s*=\s*(?<rhs>\w+)/ =~ " x = y "
# p lhs #=> "x"
# p rhs #=> "y"
#
# If it is not matched, nil is assigned for the variables.
#
# /(?<lhs>\w+)\s*=\s*(?<rhs>\w+)/ =~ " x = "
# p lhs #=> nil
# p rhs #=> nil
#
# This assignment is implemented in the Ruby parser. The parser detects
# 'regexp-literal =~ expression' for the assignment. The regexp must be a
# literal without interpolation and placed at left hand side.
#
# The assignment does not occur if the regexp is not a literal.
#
# re = /(?<lhs>\w+)\s*=\s*(?<rhs>\w+)/
# re =~ " x = y "
# p lhs # undefined local variable
# p rhs # undefined local variable
#
# A regexp interpolation, `#{}`, also disables the assignment.
#
# rhs_pat = /(?<rhs>\w+)/
# /(?<lhs>\w+)\s*=\s*#{rhs_pat}/ =~ "x = y"
# p lhs # undefined local variable
#
# The assignment does not occur if the regexp is placed at the right hand side.
#
# " x = y " =~ /(?<lhs>\w+)\s*=\s*(?<rhs>\w+)/
# p lhs, rhs # undefined local variable
#
def =~: (String? str) -> Integer?
# Returns the value of the case-insensitive flag.
#
# /a/.casefold? #=> false
# /a/i.casefold? #=> true
# /(?i:a)/.casefold? #=> false
#
def casefold?: () -> bool
# Returns the Encoding object that represents the encoding of obj.
#
def encoding: () -> Encoding
# Equality---Two regexps are equal if their patterns are identical, they have
# the same character set code, and their `casefold?` values are the same.
#
# /abc/ == /abc/x #=> false
# /abc/ == /abc/i #=> false
# /abc/ == /abc/u #=> false
# /abc/u == /abc/n #=> false
#
def eql?: (untyped other) -> bool
# Returns false if rxp is applicable to a string with any ASCII compatible
# encoding. Returns true otherwise.
#
# r = /a/
# r.fixed_encoding? #=> false
# r =~ "\u{6666} a" #=> 2
# r =~ "\xa1\xa2 a".force_encoding("euc-jp") #=> 2
# r =~ "abc".force_encoding("euc-jp") #=> 0
#
# r = /a/u
# r.fixed_encoding? #=> true
# r.encoding #=> #<Encoding:UTF-8>
# r =~ "\u{6666} a" #=> 2
# r =~ "\xa1\xa2".force_encoding("euc-jp") #=> Encoding::CompatibilityError
# r =~ "abc".force_encoding("euc-jp") #=> 0
#
# r = /\u{6666}/
# r.fixed_encoding? #=> true
# r.encoding #=> #<Encoding:UTF-8>
# r =~ "\u{6666} a" #=> 0
# r =~ "\xa1\xa2".force_encoding("euc-jp") #=> Encoding::CompatibilityError
# r =~ "abc".force_encoding("euc-jp") #=> nil
#
def fixed_encoding?: () -> bool
# Produce a hash based on the text and options of this regular expression.
#
# See also Object#hash.
#
def hash: () -> Integer
# Produce a nicely formatted string-version of *rxp*. Perhaps surprisingly,
# `#inspect` actually produces the more natural version of the string than
# `#to_s`.
#
# /ab+c/ix.inspect #=> "/ab+c/ix"
#
def inspect: () -> String
# Returns a MatchData object describing the match, or `nil` if there was no
# match. This is equivalent to retrieving the value of the special variable `$~`
# following a normal match. If the second parameter is present, it specifies
# the position in the string to begin the search.
#
# /(.)(.)(.)/.match("abc")[2] #=> "b"
# /(.)(.)/.match("abc", 1)[2] #=> "c"
#
# If a block is given, invoke the block with MatchData if match succeed, so that
# you can write
#
# /M(.*)/.match("Matz") do |m|
# puts m[0]
# puts m[1]
# end
#
# instead of
#
# if m = /M(.*)/.match("Matz")
# puts m[0]
# puts m[1]
# end
#
# The return value is a value from block execution in this case.
#
def match: (String? | Symbol | _ToStr str, ?Integer pos) -> MatchData?
| [T] (String? | Symbol | _ToStr str, ?Integer pos) { (MatchData) -> T } -> T?
# Returns a `true` or `false` indicates whether the regexp is matched or not
# without updating $~ and other related variables. If the second parameter is
# present, it specifies the position in the string to begin the search.
#
# /R.../.match?("Ruby") #=> true
# /R.../.match?("Ruby", 1) #=> false
# /P.../.match?("Ruby") #=> false
# $& #=> nil
#
def match?: (String? | Symbol | _ToStr str, ?Integer pos) -> bool
# Returns a hash representing information about named captures of *rxp*.
#
# A key of the hash is a name of the named captures. A value of the hash is an
# array which is list of indexes of corresponding named captures.
#
# /(?<foo>.)(?<bar>.)/.named_captures
# #=> {"foo"=>[1], "bar"=>[2]}
#
# /(?<foo>.)(?<foo>.)/.named_captures
# #=> {"foo"=>[1, 2]}
#
# If there are no named captures, an empty hash is returned.
#
# /(.)(.)/.named_captures
# #=> {}
#
def named_captures: () -> ::Hash[String, ::Array[Integer]]
# Returns a list of names of captures as an array of strings.
#
# /(?<foo>.)(?<bar>.)(?<baz>.)/.names
# #=> ["foo", "bar", "baz"]
#
# /(?<foo>.)(?<foo>.)/.names
# #=> ["foo"]
#
# /(.)(.)/.names
# #=> []
#
def names: () -> ::Array[String]
# Returns the set of bits corresponding to the options used when creating this
# Regexp (see Regexp::new for details. Note that additional bits may be set in
# the returned options: these are used internally by the regular expression
# code. These extra bits are ignored if the options are passed to Regexp::new.
#
# Regexp::IGNORECASE #=> 1
# Regexp::EXTENDED #=> 2
# Regexp::MULTILINE #=> 4
#
# /cat/.options #=> 0
# /cat/ix.options #=> 3
# Regexp.new('cat', true).options #=> 1
# /\xa1\xa2/e.options #=> 16
#
# r = /cat/ix
# Regexp.new(r.source, r.options) #=> /cat/ix
#
def options: () -> Integer
# Returns the original string of the pattern.
#
# /ab+c/ix.source #=> "ab+c"
#
# Note that escape sequences are retained as is.
#
# /\x20\+/.source #=> "\\x20\\+"
#
def source: () -> String
# Returns a string containing the regular expression and its options (using the
# `(?opts:source)` notation. This string can be fed back in to Regexp::new to a
# regular expression with the same semantics as the original. (However,
# `Regexp#==` may not return true when comparing the two, as the source of the
# regular expression itself may differ, as the example shows). Regexp#inspect
# produces a generally more readable version of *rxp*.
#
# r1 = /ab+c/ix #=> /ab+c/ix
# s1 = r1.to_s #=> "(?ix-m:ab+c)"
# r2 = Regexp.new(s1) #=> /(?ix-m:ab+c)/
# r1 == r2 #=> false
# r1.source #=> "ab+c"
# r2.source #=> "(?ix-m:ab+c)"
#
def to_s: () -> String
# Match---Matches *rxp* against the contents of `$_`. Equivalent to *`rxp* =~
# $_`.
#
# $_ = "input data"
# ~ /at/ #=> 7
#
def ~: () -> Integer?
private
def initialize_copy: (self object) -> self
end
# see Regexp.options and Regexp.new
#
#
Regexp::EXTENDED: Integer
# see Regexp.options and Regexp.new
#
#
Regexp::FIXEDENCODING: Integer
# see Regexp.options and Regexp.new
#
#
Regexp::IGNORECASE: Integer
# see Regexp.options and Regexp.new
#
#
Regexp::MULTILINE: Integer
# see Regexp.options and Regexp.new
#
#
Regexp::NOENCODING: Integer
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