Chris Kuklewicz has developed a regular expression library for Haskell that has been implemented with a variety of backends. Some of these backends are native Haskell implementations, others are not and rely on external C libraries such libpcre. New users may feel overwhelmed with the various options that are available to them. The following table provides an overview of the various features supported by each backend:
|regex-tre||Yes||POSIX||fast||No||No||uses buggy libtre (v0.7.5)|
|regex-tdfa||Yes||POSIX||fast||Yes||Yes||Full Posix compliance|
|regex-dfa||No||Posix||fast||Yes||Yes||old stable version buggy|
Note: speed is something that should be benchmarked by the actual user, since the story changes so much with the task, new GHC, compiler flags, etc. The algorithm used may be a useful thing (backtracking vs NFA/DFA).
All support String, (Seq Char), ByteString, and ByteString.Lazy.
The version of regex-base that comes with ghc 6.6 is version 0.71 The version of regex-base that is in unstable is 0.83 (as of March 5th 2007).
This package exports Text.Regex.Base which re-exports Text.Regex.RegexLike and Text.Regex.Context. These do not provide the ability to do matching, but provide the type classes which all the other regex-* backends use.
The backend packages also import the utility module Text.Regex.Impl to streamline instance declarations.
The 0.71 version has a "tail" bug in one of the instances of RegexLike:
instance (RegexLike a b) => RegexContext a b (MatchResult b) where
which I hope to be fixed in ghc 6.6.1. Getting the unstable version of regex-base also fixes this, though you will have to get and re-compile all the other regex-* modules as well.
The versions of the regex-* backends that come with GHC 6.6 do not re-export the RegexLike classes, so the usage of regex-BACKEND is
import Text.Regex.Base import Text.Regex.BACKEND
The versions in unstable are being upgraded to re-export RegexLike, so the usage will be simplified to
The 0.71 version of regex-base only has Extract instances for [Char] and ByteString. The unstable version also provides instances of ByteString.Lazy and (Seq Char). This Extract support must be accompanied by adding support to each regex-* backend in unstable, and that work is in progress.
The RegexMaker class in v0.71 had no way to gracefully report errors in parsing the regular expression itself. This was a design mistake and has been extended in the unstable version of regex-base to provide monadic version which can fail gracefully.
The RegexLike class only provides support for positions in the source text indexed by Int. I am still considering how to provide Int64 support. The best way is probably going to be another class, which will allow for more generalized index type support. Different backends will, by necessity, have different instances for extended index types.
This exists only in unstable at the moment. It uses a tagged DFA like the TRE c-library to provide efficient Posix matching. It also defaults to true Posix submatch capture (including ambiguous *-operator subpatterns), but this extra effort can be disabled.
The versions from 0.90 and up use mutable ST arrays to keep track of data during matching and have thus have both decent speed and decent memory performance. Previous versions drove the memory use too high, overworking the garbage collector.
By disabling submatch capture this performs nearly as fast as regex-dfa.
The version that comes with GHC 6.6 is 0.71.
This backend provides a Haskell interface for the "posix" c-library that comes with most operating systems, and is provided by include "regex.h". This c-library probably also drives command line utilities such as sed and grep.
I put "posix" in quotes since it is often not fully Posix compliant and may be buggy (as on OS X, where the bug also affects sed).
And the c-library has what I call impossibly-slow performance, as in at least 100x slower than other regex engines.
The goal of regex-tdfa is to create a replacement for regex-posix to accompany a future version of GHC.
The version that comes with ghc 6.6 is v0.71. This takes regex-posix and presents a Text.Regex api that mirrors the one that came with GHC 6.4.x for compatibility.
This wraps the pcre c-library from http://www.pcre.org and gives all the Perl regular expression syntax you might want. This is especially efficient with Data.ByteString.
This wraps the TRE c-library from http://laurikari.net/tre/ which provides Posix regular expressions. The current 0.7.5 version of TRE is buggy, however, so you should avoid this library unless you test your regular expressions to ensure you avoid the bugs.
The author of TRE is currently working to fix these bugs.
Also, the Posix compliance in 0.7.5 fails for *-operators with ambiguous captures.
This is the only LGPL backend, as it is derived from CTKLight. The stable version has had a bad bug on *-operators around patterns that could accept zero characters. The unstable version will have this issue fixed.
This library provides no submatch captures, but is very fast at finding the Posix leftmost longest match.
This backend can either find the left-biased match like Perl or the longest match like Posix. It uses Parsec as a backtracking matching engine and is quite slow.
The submatches returned in longest match mode maximize the length of the captured texts instead of the subpatterns, and this is a divergence from the Posix specification.
Coming soonish. There is also a great tutorial for using (=~) and (=~~) at this blog post.
Release of regex-tdfa
Get it at: Version 0.56, "stable" location at
darcs get --partial darcs.haskell.org:/home/darcs/packages/regex-tdfa
The version that will get updated and broken more often is "unstable" at
darcs get --partial darcs.haskell.org:/home/darcs/packages/regex-unstable/regex-tdfa
Original proposal content of this article
I just came across this article on Thompson Non-Finite Automata which presents an alternative implementation (to the one supposedly used in perl, ruby, python) which is MAAANY times faster.
Seing how badly we did in the shootout initially, wouldn't it be grand if "we" implemented this algorithm and could then outrun every other language WRT regular expressions, with a native haskell library...
The above article is slightly incomplete advocacy. I will explain in the (apples|oranges) section below ChrisKuklewicz 15:56, 30 January 2007 (UTC)
As Haskell is all about making data more strongly typed, I want to make the point that there are two popular Types of regular expressions in existence. Just as all String's are not the same Type, such as some may be escaped or encoded versions or hold data printed in different formats, a regular expressions like "a?a" means two different things depending on its actual Type.
And this difference is very close to another thing that Haskell and functional programming emphasize : declarative programming (what) as opposed to imperative programming (how).
I will call the two Types of regular expressions Posix and Perl.
- Posix Regular Expressions
- This is the declarative approach to regular expressions. The correct match of a regexp to a string of text starts at the leftmost possible position; there are no valid matches that can start before it. Of the possible matches that start at this leftmost position, the one that matches the longest substring is the correct match.
- How this match is found is immaterial to this definition of the correct match.
- Here and for the rest for the rest of this page I mean Posix to be modern "Posix Extended Regular Expressions" and never the older "Posix Basic Regular Expressions".
- Perl Regular Expressions
- This is the imperative approach to regular expressions. The correct match of a regexp to a string of text starts at the leftmost possible position; there are no valid matches that can start before it. To choose the correct match that starts at this position match parts of the regexp against the text until the first match is found. Specifically you must try left branches of '|' before right branches, and treat '?' '*' and '+' as greedy. Greedy means to match as many iterations, and only backing off the number of repetitions if no complete match is possible.
- The first match found may not be the longest, and it may not be the shortest. It is the left-biased choice.
- This definition of a correct match is identical description of how a backtracking implementation would operate.
To find a Perl match you usually do what Perl (and Python, and Java, etc.) do, which is try the left branches and greedy repetition first, then backtrack until the first answer is found. The number of path is the multiplication of alternatives. So "a?" repeated 'n' times has 2n paths.
To find a Posix match you must try all possible matches from a starting point and pick the longest, moving on the next starting point if there was not match. If you must backtrack and check each path separately this will take exponential time. To avoid this you construct an automata (NFA or DFA) and then you can check "a?" repeated n times in polynomial time (I think it is O(n2) for NFA, O(n) for DFA). You don't have to use an automata; you can write a (slow) Posix engine using backtracking.
Perl has an obvious and easy to implement "right-bias" variant that is the mirror image. And Posix has an obvious and easy to implement "shortest match".
In Posix, declaring you want to match "a|b" is always exactly the same as "b|a". Where in Perl these can be very different instructions.
When writing a Perl regexp you may want more imperative control. So there are lazy variants '??' and '+?' and '*?' which are non-greedy and try the fewest number of repetitions first. And at least Java add posessive variants '?+' and '++' and '*+' that try the largest number of iterations that locally match, but will not backtrack to fewer repetitions; thus removing many possible paths to try from the search space. And Perl introduced lookahead assertions, where the engine checks if the future text a point matches or fails to match a nested regular expression. After a while these extensions comprise a whole imperative parsing language expressed in the form a single complicated string. So to make it easier to read Perl introduced comments and a whitespace ignoring mode that let you write better documented regular expressions. And it lets you (especially in Perl 6) embed fragments of Perl into the regular expressions. So Perl regexps give you a tremendous amount of power in how to find the match, which translates into power (for the expert) in defining what the match will be.
With Perl there is a unique first match, so knowing what the parenthesized subgroups matched is easy. In Posix there can several ambiguous ways to match the same longest answer. Two examples:
- "12" =~ "(..)|(.)(.)" could match
- \0 = "12", \1 = "12", \1 = no match, \2 = no match
- \0 = "12", \1 = no match, \1="1", \2 = "2"
- "12" =~ "(.?)*" could match
- \0 = "12", \1 = "" (empty match)
- \0 = "12", \1 = "2"
And the Posix standard requires a left bias in the first example and the non-empty final iteration in the second example. So "a|b" and "b|a" are distinguishable if there are ambiguous ways to match and these ambiguities affect the captured subgroups.
About the paper in the above section: It never mentions the difference between longest versus leftmost meaning of regular expressions. Replacing the Perl engine with a Posix DFA will simply break many carefully crafted regular expressions. I do not know if the engine Russ Cox touts that was written 20 years ago by Pike implements Posix or Perl semantics. If it finds the longest match (Posix) then it is no help in replacing the default engine in a language like Perl. If it does efficiently find the left-biased match then it would be possible. The comparison to Ville Laurikari's work is not encouraging in this regard since Ville's system finds the longest match and not the left-biased one.