9c9f7d4e08
Currently, the errorItemLength function implicitly assumes that every token spans exactly one character. That assumption is correct for the Stream instances for the basic string types (String/Text/ByteString) included in Megaparsec. It does not necessarily hold for custom token types however, in particular if using a separate lexer pass. This commit adds a new tokensLength function that allows the Stream instance to give a custom width for a non-empty token stream. In practice, parse errors concerning a token with a width greater than 1 are currently rendered incorrectly (only one caret is displayed below the offending token). |
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bench | ||
megaparsec-tests | ||
nix | ||
parsers-bench | ||
Text | ||
.gitignore | ||
.travis.yml | ||
cabal.project | ||
CHANGELOG.md | ||
default.nix | ||
HACKING.md | ||
LICENSE.md | ||
megaparsec.cabal | ||
README.md | ||
Setup.hs | ||
shell.nix |
Megaparsec
- Features
- Documentation
- Tutorials
- Performance
- Comparison with other solutions
- Related packages
- Prominent projects that use Megaparsec
- Links to announcements and blog posts
- Contribution
- License
This is an industrial-strength monadic parser combinator library. Megaparsec is a feature-rich package that tries to find a nice balance between speed, flexibility, and quality of parse errors.
Features
The project provides flexible solutions to satisfy common parsing needs. The section describes them shortly. If you're looking for comprehensive documentation, see the section about documentation.
Core features
The package is built around MonadParsec
, an MTL-style monad transformer.
Most features work with all instances of MonadParsec
. One can achieve
various effects combining monad transformers, i.e. building a monadic stack.
Since the common monad transformers like WriterT
, StateT
, ReaderT
and
others are instances of the MonadParsec
type class, one can also wrap
ParsecT
in these monads, achieving, for example, backtracking state.
On the other hand ParsecT
is an instance of many type classes as well. The
most useful ones are Monad
, Applicative
, Alternative
, and
MonadParsec
.
Megaparsec includes all functionality that is typically available in Parsec-like libraries and also features some special combinators:
failure
allows us to report a parse error with unexpected and expected items.fancyFailure
provides a way to report custom parse errors.withRecovery
can be used to recover from parse errors “on-the-fly” and continue parsing. Once parsing is finished, several parse errors may be reported or ignored altogether.observing
makes it possible to “observe” parse errors without ending parsing (they are returned inLeft
, while normal results are wrapped inRight
).
In addition to that, Megaparsec features high-performance combinators similar to those found in Attoparsec:
tokens
makes it easy to parse several tokens in a row (string
andstring'
are built on top of this primitive). This is about 100 times faster than matching a string token by token.tokens
returns “chunk” of original input, meaning that if you parseText
, it'll returnText
without repacking.takeWhile
andtakeWhile1
are about 150 times faster than approaches involvingmany
,manyTill
and other similar combinators.takeP
allows us to grab n tokens from the stream and returns them as a “chunk” of the stream.
Megaparsec is about as fast as Attoparsec if you write your parser carefully (see also the section about performance).
The library can currently work with the following types of input stream out-of-the-box:
String = [Char]
ByteString
(strict and lazy)Text
(strict and lazy)
It's also possible to make it work with custom token streams by making them
an instance of the Stream
type class.
Error messages
Megaparsec has typed error messages and the ability to signal custom parse errors that better suit user's domain of interest.
Megaparsec 7 introduced the ParseErrorBundle
data type that helps to
manage multi-error messages and pretty-print them easily and efficiently.
That version of the library also made the practice of displaying offending
lines the default, similar to how recent versions of GHC do it.
Alex support
Megaparsec works well with streams of tokens produced by tools like Alex.
The design of the Stream
type class has been changed significantly in
versions 6 and 7, but user can still work with custom streams of tokens.
Character and binary parsing
Megaparsec has decent support for Unicode-aware character parsing. Functions
for character parsing live in the Text.Megaparsec.Char
module.
Similarly, there is Text.Megaparsec.Byte
module for parsing
streams of bytes.
Lexer
Text.Megaparsec.Char.Lexer
is a module that should help
you write your lexer. If you have used Parsec
in the past, this module
“fixes” its particularly inflexible Text.Parsec.Token
.
Text.Megaparsec.Char.Lexer
is intended to be imported
using a qualified import, it's not included in Text.Megaparsec
. The
module doesn't impose how you should write your parser, but certain
approaches may be more elegant than others. An especially important theme is
parsing of white space, comments, and indentation.
The design of the module allows one quickly solve simple tasks and doesn't get in the way when the need to implement something less standard arises.
Text.Megaparsec.Byte.Lexer
is also available for users
who wish to parse binary data.
Documentation
Megaparsec is well-documented. See the current version of Megaparsec documentation on Hackage.
Tutorials
You can find Megaparsec tutorials here. They should provide sufficient guidance to help you start with your parsing tasks. The site also has instructions and tips for Parsec users who decide to migrate to Megaparsec.
Performance
Despite being flexible, Megaparsec is also fast. Here is how Megaparsec 7.0.0 compares to Attoparsec 0.13.2.2 (the fastest widely used parsing library in the Haskell ecosystem):
Test case | Execution time | Allocated | Max residency |
---|---|---|---|
CSV (Attoparsec) | 76.50 μs | 397,784 | 10,544 |
CSV (Megaparsec) | 64.69 μs | 352,408 | 9,104 |
Log (Attoparsec) | 302.8 μs | 1,150,032 | 10,912 |
Log (Megaparsec) | 337.8 μs | 1,246,496 | 10,912 |
JSON (Attoparsec) | 18.20 μs | 128,368 | 9,032 |
JSON (Megaparsec) | 25.45 μs | 203,824 | 9,176 |
The benchmarks were created to guide development of Megaparsec 6 and can be found here.
If you think your Megaparsec parser is not efficient enough, take a look at these instructions.
Comparison with other solutions
There are quite a few libraries that can be used for parsing in Haskell, let's compare Megaparsec with some of them.
Megaparsec vs Attoparsec
Attoparsec is another prominent Haskell library for parsing. Although both libraries deal with parsing, it's usually easy to decide which you will need in particular project:
-
Attoparsec is sometimes faster but not that feature-rich. It should be used when you want to process large amounts of data where performance matters more than quality of error messages.
-
Megaparsec is good for parsing of source code or other human-readable texts. It has better error messages and it's implemented as monad transformer.
So, if you work with something human-readable where size of input data is moderate, just go with Megaparsec, otherwise Attoparsec may be a better choice.
Megaparsec vs Parsec
Since Megaparsec is a fork of Parsec, we are bound to list the main differences between the two libraries:
-
Better error messages. Megaparsec has well-typed error messages and custom error messages.
-
Megaparsec can show the line on which parse error happened as part of parse error. This makes it a lot easier to figure out where the error happened.
-
Some quirks and bugs of Parsec are fixed.
-
Better support for Unicode parsing in
Text.Megaparsec.Char
. -
Megaparsec has more powerful combinators and can parse languages where indentation matters out-of-the-box.
-
Better documentation.
-
Megaparsec can recover from parse errors “on the fly” and continue parsing.
-
Megaparsec allows us to conditionally process parse errors inside your parser before parsing is finished. In particular, it's possible to define regions in which parse errors, should they happen, will get a “context tag”, e.g. we could build a context stack like “in function definition foo”, “in expression x”, etc. This is not possible with Parsec.
-
Megaparsec is faster and supports efficient operations
tokens
,takeWhileP
,takeWhile1P
,takeP
, like Attoparsec.
If you want to see a detailed change log, CHANGELOG.md
may be helpful.
Also see this original announcement for another
comparison.
Megaparsec vs Trifecta
Trifecta is another Haskell library featuring good error messages. These are the common reasons why Trifecta may be problematic to use:
-
Complicated, doesn't have any tutorials available, and documentation doesn't help at all.
-
Trifecta can parse
String
andByteString
natively, but notText
. -
Depends on
lens
, which is a very heavy dependency. If you're not intolens
and would like to keep your code “vanilla”, you may not like the API.
Idris has switched from Trifecta to Megaparsec which allowed it to have better error messages and fewer dependencies.
Megaparsec vs Earley
Earley is a newer library that allows us to safely parse context-free grammars (CFG). Megaparsec is a lower-level library compared to Earley, but there are still enough reasons to choose it:
-
Megaparsec is faster.
-
Your grammar may be not context-free or you may want introduce some sort of state to the parsing process. Almost all non-trivial parsers require state. Even if your grammar is context-free, state may allow for additional niceties. Earley does not support that.
-
Megaparsec's error messages are more flexible allowing to include arbitrary data in them, return multiple error messages, mark regions that affect any error that happens in those regions, etc.
In other words, Megaparsec is less safe but also more powerful.
Related packages
The following packages are designed to be used with Megaparsec (open a PR if you want to add something to the list):
hspec-megaparsec
—utilities for testing Megaparsec parsers with with Hspec.cassava-megaparsec
—Megaparsec parser of CSV files that plays nicely with Cassava.tagsoup-megaparsec
—a library for easily using TagSoup as a token type in Megaparsec.replace-megaparsec
—Stream editing and find-and-replace with Megaparsec.
Prominent projects that use Megaparsec
Some prominent projects that use Megaparsec:
- Idris—a general-purpose functional programming language with dependent types
- Dhall—an advanced configuration language
- hnix—re-implementation of the Nix language in Haskell
- Hledger—an accounting tool
- MMark—strict markdown processor for writers
Links to announcements and blog posts
Here are some blog posts mainly announcing new features of the project and describing what sort of things are now possible:
- Megaparsec 7
- Evolution of error messages
- A major upgrade to Megaparsec: more speed, more power
- Latest additions to Megaparsec
- Announcing Megaparsec 5
- Megaparsec 4 and 5
- The original Megaparsec 4.0.0 announcement
Contribution
Issues (bugs, feature requests or otherwise feedback) may be reported in the GitHub issue tracker for this project.
Pull requests are also welcome.
License
Copyright © 2015–present Megaparsec contributors
Copyright © 2007 Paolo Martini
Copyright © 1999–2000 Daan Leijen
Distributed under FreeBSD license.