Regular and Irregular Expressions

Regular expression is a powerful form of declarative programming languages, mainly used for pattern-matching within strings. Its corresponding machine model is the finite automaton.

There are many different dialects (also called flavors) of regular expressions, all subtly different. Therefore, when asking questions, always include the tag for the specific programming language or tool (e.g., Perl, Ruby, Python, Java, JavaScript, vi, Emacs, sed, Lex, grep, etc.) you are using. Otherwise, you may get answers that won't work for you. See below for a short outline of different dialects.

Depending on which flavor you’re using, modern regular expression engines can support advanced features like backreferences, conditional subpatterns, regular expression subroutines, code callouts, positive and negative lookahead/lookbehind assertions, and even recursion. This rich feature-set allows them to parse far more than the strictly regular languages for which they were originally named.

Today, we still call these pattern-matching languages regular expressions (or regexes for short), even if they may no longer be regular in the computer scientific sense.

Regular expressions are used for two purposes: input validation and data extraction. Regular expressions for input validation must accept all input allowed by the standard (if any) or requirement and reject everything else, and it must do so correctly on arbitrary input string, without any assumption. Such regular expressions can be very complex, but their strictness makes them full-fledged parsers capable of extracting data. On the other hand, regular expression for data extraction only needs to work correctly in a certain input domain, which may or may not be well-defined. Such regular expression usually comes with assumptions on certain features of the data, which makes it fragile and subject to breakage on unexpected change in the input domain.

Fools Rush in Where Angels Fear to Tread

The tremendous power and expressiveness of modern regular expressions can seduce the gullible — or the foolhardy — into trying to use regular expressions on every string-related task they come across. This is a bad idea in general, and a very bad idea in one particular area. Although it is perfectly appropriate to use regular expressions on specific XML or HTML of known characteristics, attempting to fully and correctly parse arbitrary XML or HTML using regular expressions alone has been known to induce madness in those attempting this Herculean and Sisyphean task.

For general parsing of arbitrary XML or HTML, it is therefore always better to use a dedicated parser — like an event-driven SAX parser or a DOM parser — than it is to use regular expressions.

How to ask regex-based questions

  • Different languages have different regex implementations. So it's wise to mention the language in which you want your regex to work. If you are not specific about the language, do mention it.

  • Regex questions are better explained with examples than elaborate sentences. Give us examples of what needs to be matched and what shouldn't.

  • Even if you are not well versed in regexes, it's better to show us what you've tried than simply asking the community to solve your problem.

  • Use online tools like Regex101, RegExr, and RegexPal to verify your regex patterns. You can even paste links from these sites to show us what you tried and what are the results. See below for more sites you can try.

  • Ensure your question is a regular expression and not a filename expansion (tag: ) often used on command lines to match files to pass as parameters to a command.

Regular Expression Patterns

The examples below use slashes as delimiters around the regular expressions. This is a moderately common convention, and some languages (like JavaScript) use it to delimit regex literals, but not part of the regular expression syntax proper.


  • \ Escapes special characters to literal and literal characters to special.

e.g.: /\[\.\]/ matches the literal string "[.]", whereas without the middle backslash, it would match any character between square brackets, and without any backslashes, it would only match exactly one literal dot.

e.g.: /\(s\)/ matches '(s)' while /(\s)/ matches any whitespace and captures the match... in some dialects.


Quantifiers match the preceding sub-pattern a certain number of times. The sub-pattern can be a single character, an escape sequence, a pattern enclosed by parentheses or a character set.

  • {n} matches exactly n times.
  • {n,} matches n or more times.
  • {n,m} matches n to m times.
  • * is short for {0,}. Matches zero or more times.
  • + is short for {1,}. Matches one or more times.
  • ? is short for {0,1}. Matches zero or one time.

e.g.: /o{1,3}/ matches 'oo' in "tooth" and 'o' in "nose".

* is universally supported. Traditional grep did not support the other quantifiers; they were introduced with extended regular expressions (i.e. egrep).

Pattern delimiters

Matches entire contained pattern.

  • (pattern) captures match.
  • (?:pattern) doesn't capture match

e.g.: /(d).\1/ matches 'dad' and captures 'd' in "abcdadef" while /(?:.d){2}/ matches but doesn't capture 'cdad'.

Traditional grep did not support grouping or capturing; it was introduced with extended regular expressions (i.e. egrep).

Non-capturing matches were introduced in Perl 5 and are only supported in relatively modern regular expression implementations.


A lookahead matches only if the preceding subexpression is followed by the pattern, but the pattern is not part of the match. The subexpression is the part of the regular expression which will be matched.

  • (?=pattern) matches only if there is a following pattern in input.
  • (?!pattern) matches only if there is not a following pattern in input.

e.g.: /Win(?=98)/ matches 'Win' only if 'Win' is followed by '98'.

Lookaheads were introduced in Perl 5 and are only supported in relatively modern regular expression implementations.


  • | Alternation matches content on either side of the alternation character.

e.g.: /(a|b)a/ matches 'aa' in "dseaas" and 'ba' in "acbab".

Basic regular expression (BRE) does not support alternation; it was introduced with extended regular expressions (ERE).

Character classes

Matches any one of the contained characters. A range of characters may be defined by using a hyphen.

  • [characters] matches any one of the contained characters.
  • [^characters] negates the character set and matches one character which is not one of the contained characters.

e.g.: /[abcd]/ matches one character which can be any of the characters 'a', 'b', 'c', or 'd' and may be abbreviated to /[a-d]/. Ranges must be in ascending order, otherwise they will throw an error. (e.g.: /[d-a]/ will throw an error.) /[^0-9]/ matches all characters but digits.

Note: Most special characters are automatically escaped to their literal meaning in character sets.

Special characters

Special characters are characters that match something else than what they appear as.

  • ^ matches beginning of input (or new line with m flag).
  • $ matches end of input (or end of line with m flag).
  • . matches any character except line separator (please check your documentation for exact list, line separator always includes newline character).
  • ? directly following a quantifier makes the quantifier non-greedy (makes it match minimum instead of maximum of the interval defined).

e.g.: /(.)*?/ matches nothing or '' in all strings.

note: Non-greedy matches are not supported in older browsers such as Netscape Navigator 4 or Microsoft Internet Explorer 5.0.

Non-greedy matching was introduced in Perl 5 and is only supported in relatively modern regular expression implementations.

Literal characters

All characters except those with special meaning. Mapped directly to the corresponding character.

e.g.: /a/ matches 'a' in Any ancestor.

Back references

  • \n Back references matches the same thing as a previously captured match. n is a positive nonzero integer indicating which captured group to reference to.

  • /(\S)\1(\1)+/g matches all occurrences of three or more consecutive identical non-whitespace characters.

  • /<(\S+).*>(.*)<\/\1>/ matches any tag.

e.g.: /<(\S+).*>(.*)<\/\1>/ matches <div id="me">text</div> in text <div id=\"me\">text</div>.

Character Escapes

  • \f matches form-feed.
  • \r matches carriage return.
  • \n matches linefeed.
  • \t matches horizontal tab.
  • \v matches vertical tab.
  • \0 matches NUL character.
  • [\b] matches backspace.
  • \s matches whitespace (please check your documentation for exact list, most engines include at least [ \t\f\r\n]).
  • \S matches anything but a whitespace (shorthand negated character class of \s).
  • \w matches any alphanumerical character (word characters) including underscore (please check your documentation for exact list, usually defined as [a-zA-Z0-9_]).
  • \W matches any non-word characters (shorthand negated character class of \w).
  • \d matches any digit (please check your documentation for exact list, usually defined as [0-9]).
  • \D matches any non-digit (shorthand negated character class of \d).
  • \b matches a word boundary (the position between a word and a non-word character, usually syncs with definition of \w).
  • \B matches a non-word boundary (any position not matched by \b).
  • \cX matches a control character. (eg: \cm matches control-M).
  • \xhh matches the character with two characters of hexadecimal code hh.
  • \uhhhh matches the Unicode character with four characters of hexadecimal code hhhh.

Many of these escapes were introduced in Perl and are only available in relatively modern regular expression implementations.

Main Dialects

The first implementation of regular expressions was Ken Thompson's for ed and then grep in 1968. This basically only implemented character classes, ^, $, ., and * as well as backslash escapes.

This was later formalized into POSIX Basic Regular Expressions (BRE) with numerous additions, many of which -- somewhat bewilderingly, for reasons of backwards compatibility -- use the backslash to produce a metacharacter out of a regular character, rather than the other way around.

Later, an extended grep aka egrep was introduced by Alfred V. Aho which significantly expanded the repertoire of metacharacters. Although many additions were mere convenience, the extensions included grouping, alteration, and back references, which significantly extend the expressive power of the formalism.

These extensions were later formalized into POSIX Extended Regular Expressions.

POSIX also unified the tool, specifying that plain grep accepts basic regular expressions, while grep -E accepts extended regular expressions. Also, grep -F is provided as a replacement for fgrep, also originally by Aho, which performs search on literal strings, not regular expressions.

The Perl programming language featured a significantly modified and enhanced version of Henry Spencer's regular expression library. With the release of Perl v5, further enhancements including lookaheads, lookbehinds, non-committing matches, non-capturing groups etc. were introduced. Through Philip Hazel's library reimplementation PCRE, these capabilities were made available in many other programming languages, including, but not limited to, PHP, Python, and R. Hence, Perl-Compatible Regular Expressions are the third main dialect of regular expressions in widespread use.

Many tools have their own regular expression implementations which fall between these categories. For example many text editors implement their own dialects. JavaScript also does this, and codifies its own dialect as part of the ECMA-262 standard.

Useful links

Learning regular expressions

Documentation for JavaScript

Online sandboxes (for testing and publishing regexes online)

  • RegexPlanet (supports a variety of flavors to choose from)
  • Regexpal (ECMAScript flavor, as implemented by JavaScript)
  • Regexhero (.NET flavor)
  • RegExr v2.0 (in JavaScript)
  • RegExr v1.0 (ECMAScript flavor, as implemented by Adobe Flash)
  • reFiddle (in JavaScript, à la jsFiddle)
  • Rubular (Ruby flavor)
  • myregexp.com (Java-applet with source code)
  • regexe.com (German; probably Java flavor)
  • regex101 (in JavaScript, Python, PCRE 16-bit, generates explanation of pattern)
  • regexper.com (generates graphical representation for ECMAScript flavor)
  • debuggex (generates graphical representation and shows processing of pattern – JavaScript, Python, and PCRE-compatible)
  • pyregex.com (web validator for Python regular expressions)
  • regviz.org (Visual debugging of regular expressions for JavaScript)

Other links

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