Safe Haskell | None |
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- newtype Parser s t a = P (Parser s t a)
- data Result z a
- runParser :: Parser s t a -> s -> [t] -> (a, s, [t])
- next :: Parser s t t
- eof :: Parser s t ()
- satisfy :: (t -> Bool) -> Parser s t t
- onFail :: Parser s t a -> Parser s t a -> Parser s t a
- manyFinally :: Parser s t a -> Parser s t z -> Parser s t [a]
- stUpdate :: (s -> s) -> Parser s t ()
- stQuery :: (s -> a) -> Parser s t a
- stGet :: Parser s t s
- reparse :: [t] -> Parser s t ()
- module Text.ParserCombinators.Poly.Base
- module Control.Applicative
The Parser datatype
The only differences between a State and a StateLazy parser are the instance of Applicative, and the type (and implementation) of runParser. We therefore need to newtype the original Parser type, to allow it to have a different instance.
Monad (Parser s t) | |
Functor (Parser s t) | |
Applicative (Parser s t) | |
Alternative (Parser s t) | |
PolyParse (Parser s t) | |
Commitment (Parser s t) |
A return type like Either, that distinguishes not only between right and wrong answers, but also has commitment, so that a failure cannot be undone. This should only be used for writing very primitive parsers - really it is an internal detail of the library. The z type is the remaining unconsumed input.
runParser :: Parser s t a -> s -> [t] -> (a, s, [t])Source
Apply a parser to an input token sequence.
Basic parsers
satisfy :: (t -> Bool) -> Parser s t tSource
Return the next token if it satisfies the given predicate.
onFail :: Parser s t a -> Parser s t a -> Parser s t aSource
p
means parse p, unless p fails, in which case
parse q instead.
Can be chained together to give multiple attempts to parse something.
(Note that q could itself be a failing parser, e.g. to change the error
message from that defined in p to something different.)
However, a severe failure in p cannot be ignored.
onFail
q
manyFinally :: Parser s t a -> Parser s t z -> Parser s t [a]Source
State-handling
Re-parsing
reparse :: [t] -> Parser s t ()Source
Push some tokens back onto the front of the input stream and reparse. This is useful e.g. for recursively expanding macros. When the user-parser recognises a macro use, it can lookup the macro expansion from the parse state, lex it, and then stuff the lexed expansion back down into the parser.
Re-export all more general combinators
module Control.Applicative