A monadic parser combinator library based on Haskell’s Parsec.
Install parsing
with Spago:
$ spago install parsing
Here is a basic tutorial introduction to monadic parsing with this package.
A parser turns a string into a data structure. Parsers in this library have the type Parser s a
, where s
is the type of the input string, and a
is the type of the data which the parser will produce on success. Parser s
is a monad. It’s defined in the module Parsing
.
Monads can be used to provide context for a computation, and that’s how we use them in monadic parsing.
The context provided by the Parser s
monad is the parser’s current location in the input string.
Parsing starts at the beginning of the input string.
Parsing requires two more capabilities: alternative and failure.
We need alternative to be able to choose what kind of thing we’re parsing depending
on the input which we encounter. This is provided by the <|>
“alt”
operator of the Alt
typeclass instance of the Parser s
monad.
The expression p_left <|> p_right
will first try the p_left
parser and if that fails
and consumes no input then it will try the p_right
parser.
We need failure in case the input stream is not parseable. This is provided by the fail
function, which calls the throwError
function of the MonadThrow
typeclass instance of
the Parser s
monad.
To run a parser, call the function runParser :: s -> Parser s a -> Either ParseError a
in
the Parsing
module, and supply it with an input string and a parser.
If the parse succeeds then the result is Right a
and if the parse fails then the
result is Left ParseError
.
Each type of input string needs primitive parsers.
Primitive parsers for input string type String
are in the Parsing.String
module.
For example, the primitive char :: Char -> Parser String Char
parser will exactly match
one literal character and then advance by one position in the input string.
We can use these primitive parsers to write other String
parsers.
Here is a parser ayebee :: Parser String Boolean
which will accept only two input
strings: "ab"
or "aB"
.
It will return true
if the b
character is uppercase.
It will return false
if the b
character is lowercase.
It will fail with a ParseError
if the input string is anything else.
ayebee :: Parser String Boolean
ayebee = do
_ <- char 'a'
b <- char 'b' <|> char 'B'
pure (b == 'B')
We can run the parser ayebee
like so
runParser "aB" ayebee
and then the parser will succeed and return Right true
.
There are other String
parsers in the module Parsing.String.Basic
, for example the parser letter :: Parser String Char
which will accept any single alphabetic letter.
Parser combinators are in this package in the module Parsing.Combinators
.
A parser combinator is a function which takes a parser as an argument and returns a new parser. The many
combinator, for example, will repeat a parser as many times as it can. So the parser many letter
will have type Parser String (Array Char)
.
Running the parser
runParser "aBabaB" (many ayebee)
will return Right [true, false, true]
.
Starting with v9.0.0, all parsers and combinators in this package are always stack-safe.
For the most part, we can just write recursive parsers (parsers defined in terms of themselves) and they will work as we expect.
In some cases like this:
aye :: Parser String Char
aye = char 'a' *> aye
we might get a compile-time CycleInDeclaration error which looks like this:
The value of aye is undefined here, so this reference is not allowed.
See https://github.com/purescript/documentation/blob/master/errors/CycleInDeclaration.md for more information,
or to contribute content related to this error.
This is happening because we tried to call aye
recursively “at a point
where such a reference would be unavailable because of strict evaluation.”
The
best way to solve
this is to stick a
Control.Lazy.defer
in front of the parser to break the cycle.
aye :: Parser String Char
aye = defer \_ -> char 'a' *> aye
-
Monadic Parsers at the Input Boundary (YouTube) by James Brock is an introductory tutorial to monadic parser combinators with this package.
-
Monadic Parser Combinators by Graham Hutton and Erik Meijer 1996.
-
The original short classic FUNCTIONAL PEARLS Monadic Parsing in Haskell by Graham Hutton and Erik Meijer 1998.
-
Parsec: Direct Style Monadic Parser Combinators For The Real World by Daan Leijen and Erik Meijer 2001.
-
Parse, don't validate by Alexis King is about what it means to “parse” something, without any mention of monads.
-
Revisiting Monadic Parsing in Haskell by Vaibhav Sagar is a reflection on the Hutton, Meijer FUNCTIONAL PEARL.
-
Parsec: “try a <|> b” considered harmful by Edward Z. Yang is about how to decide when to backtrack from a failed alternative.
-
Parser Combinators in Haskell by Heitor Toledo Lassarote de Paula.
There are lots of other great monadic parsing tutorials on the internet.
parsing-dataview
primitive parsers for binary parsing ofArrayBuffer
.datetime-parsing
parsers for dates and times.formatters
parsers for dates and times and various other things.
parsing
documentation is stored in a few places:
- Module documentation is published on Pursuit.
- Written documentation is kept in the docs directory.
- Usage examples can be found in the test suite.
If you get stuck, there are several ways to get help:
- Open an issue if you have encountered a bug or problem.
- Ask general questions on the PureScript Discourse forum or the PureScript Discord chat.
You can contribute to parsing
in several ways:
-
If you encounter a problem or have a question, please open an issue. We'll do our best to work with you to resolve or answer it.
-
If you would like to contribute code, tests, or documentation, please read the contributor guide. It's a short, helpful introduction to contributing to this library, including development instructions.
-
If you have written a library, tutorial, guide, or other resource based on this package, please share it on the PureScript Discourse! Writing libraries and learning resources are a great way to help this library succeed.