Copyright | Bryan O'Sullivan 2007-2015 |
---|---|
License | BSD3 |
Maintainer | bos@serpentine.com |
Stability | experimental |
Portability | unknown |
Safe Haskell | Trustworthy |
Language | Haskell2010 |
Simple, efficient combinator parsing for Text
strings,
loosely based on the Parsec library.
Synopsis
- type Parser = Parser Text
- type Result = IResult Text
- data IResult i r
- compareResults :: (Eq i, Eq r) => IResult i r -> IResult i r -> Maybe Bool
- parse :: Parser a -> Text -> Result a
- feed :: Monoid i => IResult i r -> i -> IResult i r
- parseOnly :: Parser a -> Text -> Either String a
- parseWith :: Monad m => m Text -> Parser a -> Text -> m (Result a)
- parseTest :: Show a => Parser a -> Text -> IO ()
- maybeResult :: Result r -> Maybe r
- eitherResult :: Result r -> Either String r
- char :: Char -> Parser Char
- anyChar :: Parser Char
- notChar :: Char -> Parser Char
- satisfy :: (Char -> Bool) -> Parser Char
- satisfyWith :: (Char -> a) -> (a -> Bool) -> Parser a
- skip :: (Char -> Bool) -> Parser ()
- peekChar :: Parser (Maybe Char)
- peekChar' :: Parser Char
- digit :: Parser Char
- letter :: Parser Char
- space :: Parser Char
- inClass :: String -> Char -> Bool
- notInClass :: String -> Char -> Bool
- string :: Text -> Parser Text
- stringCI :: Text -> Parser Text
- asciiCI :: Text -> Parser Text
- skipSpace :: Parser ()
- skipWhile :: (Char -> Bool) -> Parser ()
- scan :: s -> (s -> Char -> Maybe s) -> Parser Text
- runScanner :: s -> (s -> Char -> Maybe s) -> Parser (Text, s)
- take :: Int -> Parser Text
- takeWhile :: (Char -> Bool) -> Parser Text
- takeWhile1 :: (Char -> Bool) -> Parser Text
- takeTill :: (Char -> Bool) -> Parser Text
- (.*>) :: Text -> Parser a -> Parser a
- (<*.) :: Parser a -> Text -> Parser a
- takeText :: Parser Text
- takeLazyText :: Parser Text
- endOfLine :: Parser ()
- isEndOfLine :: Char -> Bool
- isHorizontalSpace :: Char -> Bool
- decimal :: Integral a => Parser a
- hexadecimal :: (Integral a, Bits a) => Parser a
- signed :: Num a => Parser a -> Parser a
- double :: Parser Double
- data Number
- number :: Parser Number
- rational :: Fractional a => Parser a
- scientific :: Parser Scientific
- try :: Parser i a -> Parser i a
- (<?>) :: Parser i a -> String -> Parser i a
- choice :: Alternative f => [f a] -> f a
- count :: Monad m => Int -> m a -> m [a]
- option :: Alternative f => a -> f a -> f a
- many' :: MonadPlus m => m a -> m [a]
- many1 :: Alternative f => f a -> f [a]
- many1' :: MonadPlus m => m a -> m [a]
- manyTill :: Alternative f => f a -> f b -> f [a]
- manyTill' :: MonadPlus m => m a -> m b -> m [a]
- sepBy :: Alternative f => f a -> f s -> f [a]
- sepBy' :: MonadPlus m => m a -> m s -> m [a]
- sepBy1 :: Alternative f => f a -> f s -> f [a]
- sepBy1' :: MonadPlus m => m a -> m s -> m [a]
- skipMany :: Alternative f => f a -> f ()
- skipMany1 :: Alternative f => f a -> f ()
- eitherP :: Alternative f => f a -> f b -> f (Either a b)
- match :: Parser a -> Parser (Text, a)
- endOfInput :: forall t. Chunk t => Parser t ()
- atEnd :: Chunk t => Parser t Bool
Differences from Parsec
Compared to Parsec 3, attoparsec makes several tradeoffs. It is not intended for, or ideal for, all possible uses.
- While attoparsec can consume input incrementally, Parsec cannot. Incremental input is a huge deal for efficient and secure network and system programming, since it gives much more control to users of the library over matters such as resource usage and the I/O model to use.
- Much of the performance advantage of attoparsec is gained via
high-performance parsers such as
takeWhile
andstring
. If you use complicated combinators that return lists of characters, there is less performance difference between the two libraries. - Unlike Parsec 3, attoparsec does not support being used as a monad transformer.
- attoparsec is specialised to deal only with strict
Text
input. Efficiency concerns rule out both lists and lazy text. The usual use for lazy text would be to allow consumption of very large input without a large footprint. For this need, attoparsec's incremental input provides an excellent substitute, with much more control over when input takes place. If you must use lazy text, see theLazy
module, which feeds lazy chunks to a regular parser. - Parsec parsers can produce more helpful error messages than attoparsec parsers. This is a matter of focus: attoparsec avoids the extra book-keeping in favour of higher performance.
Incremental input
attoparsec supports incremental input, meaning that you can feed it
a Text
that represents only part of the expected total amount
of data to parse. If your parser reaches the end of a fragment of
input and could consume more input, it will suspend parsing and
return a Partial
continuation.
Supplying the Partial
continuation with another string will
resume parsing at the point where it was suspended, with the string
you supplied used as new input at the end of the existing
input. You must be prepared for the result of the resumed parse to
be another Partial
continuation.
To indicate that you have no more input, supply the Partial
continuation with an empty
Text
.
Remember that some parsing combinators will not return a result
until they reach the end of input. They may thus cause Partial
results to be returned.
If you do not need support for incremental input, consider using
the parseOnly
function to run your parser. It will never
prompt for more input.
Note: incremental input does not imply that attoparsec will
release portions of its internal state for garbage collection as it
proceeds. Its internal representation is equivalent to a single
Text
: if you feed incremental input to an a parser, it will
require memory proportional to the amount of input you supply.
(This is necessary to support arbitrary backtracking.)
Performance considerations
If you write an attoparsec-based parser carefully, it can be realistic to expect it to perform similarly to a hand-rolled C parser (measuring megabytes parsed per second).
To actually achieve high performance, there are a few guidelines that it is useful to follow.
Use the Text
-oriented parsers whenever possible,
e.g. takeWhile1
instead of many1
anyChar
. There is
about a factor of 100 difference in performance between the two
kinds of parser.
For very simple character-testing predicates, write them by hand
instead of using inClass
or notInClass
. For instance, both
of these predicates test for an end-of-line character, but the
first is much faster than the second:
endOfLine_fast c = c == '\r' || c == '\n' endOfLine_slow = inClass "\r\n"
Make active use of benchmarking and profiling tools to measure, find the problems with, and improve the performance of your parser.
Parser types
The result of a parse. This is parameterised over the type i
of string that was processed.
This type is an instance of Functor
, where fmap
transforms the
value in a Done
result.
Fail i [String] String | The parse failed. The |
Partial (i -> IResult i r) | Supply this continuation with more input so that the parser can resume. To indicate that no more input is available, pass an empty string to the continuation. Note: if you get a |
Done i r | The parse succeeded. The |
Running parsers
feed :: Monoid i => IResult i r -> i -> IResult i r #
If a parser has returned a Partial
result, supply it with more
input.
parseOnly :: Parser a -> Text -> Either String a #
Run a parser that cannot be resupplied via a Partial
result.
This function does not force a parser to consume all of its input. Instead, any residual input will be discarded. To force a parser to consume all of its input, use something like this:
parseOnly
(myParser<*
endOfInput
)
:: Monad m | |
=> m Text | An action that will be executed to provide the parser
with more input, if necessary. The action must return an
|
-> Parser a | |
-> Text | Initial input for the parser. |
-> m (Result a) |
Run a parser with an initial input string, and a monadic action that can supply more input if needed.
parseTest :: Show a => Parser a -> Text -> IO () #
Run a parser and print its result to standard output.
Result conversion
maybeResult :: Result r -> Maybe r #
eitherResult :: Result r -> Either String r #
Parsing individual characters
satisfy :: (Char -> Bool) -> Parser Char #
The parser satisfy p
succeeds for any character for which the
predicate p
returns True
. Returns the character that is
actually parsed.
digit = satisfy isDigit where isDigit c = c >= '0' && c <= '9'
satisfyWith :: (Char -> a) -> (a -> Bool) -> Parser a #
The parser satisfyWith f p
transforms a character, and succeeds
if the predicate p
returns True
on the transformed value. The
parser returns the transformed character that was parsed.
skip :: (Char -> Bool) -> Parser () #
The parser skip p
succeeds for any character for which the
predicate p
returns True
.
skipDigit = skip isDigit where isDigit c = c >= '0' && c <= '9'
Lookahead
peekChar :: Parser (Maybe Char) #
Match any character, to perform lookahead. Returns Nothing
if
end of input has been reached. Does not consume any input.
Note: Because this parser does not fail, do not use it with
combinators such as many
, because such
parsers loop until a failure occurs. Careless use will thus result
in an infinite loop.
Match any character, to perform lookahead. Does not consume any input, but will fail if end of input has been reached.
Special character parsers
Character classes
inClass :: String -> Char -> Bool #
Match any character in a set.
vowel = inClass "aeiou"
Range notation is supported.
halfAlphabet = inClass "a-nA-N"
To add a literal '-'
to a set, place it at the beginning or end
of the string.
notInClass :: String -> Char -> Bool #
Match any character not in a set.
Efficient string handling
string :: Text -> Parser Text #
string s
parses a sequence of characters that identically match
s
. Returns the parsed string (i.e. s
). This parser consumes no
input if it fails (even if a partial match).
Note: The behaviour of this parser is different to that of the
similarly-named parser in Parsec, as this one is all-or-nothing.
To illustrate the difference, the following parser will fail under
Parsec given an input of "for"
:
string "foo" <|> string "for"
The reason for its failure is that the first branch is a
partial match, and will consume the letters 'f'
and 'o'
before failing. In attoparsec, the above parser will succeed on
that input, because the failed first branch will consume nothing.
stringCI :: Text -> Parser Text #
Deprecated: this is very inefficient, use asciiCI instead
Satisfy a literal string, ignoring case.
Note: this function is currently quite inefficient. Unicode case folding can change the length of a string ("ß" becomes "ss"), which makes a simple, efficient implementation tricky. We have (for now) chosen simplicity over efficiency.
asciiCI :: Text -> Parser Text #
Satisfy a literal string, ignoring case for characters in the ASCII range.
skipWhile :: (Char -> Bool) -> Parser () #
Skip past input for as long as the predicate returns True
.
scan :: s -> (s -> Char -> Maybe s) -> Parser Text #
A stateful scanner. The predicate consumes and transforms a
state argument, and each transformed state is passed to successive
invocations of the predicate on each character of the input until one
returns Nothing
or the input ends.
This parser does not fail. It will return an empty string if the
predicate returns Nothing
on the first character of input.
Note: Because this parser does not fail, do not use it with
combinators such as many
, because such
parsers loop until a failure occurs. Careless use will thus result
in an infinite loop.
runScanner :: s -> (s -> Char -> Maybe s) -> Parser (Text, s) #
Like scan
, but generalized to return the final state of the
scanner.
takeWhile :: (Char -> Bool) -> Parser Text #
Consume input as long as the predicate returns True
, and return
the consumed input.
This parser does not fail. It will return an empty string if the
predicate returns False
on the first character of input.
Note: Because this parser does not fail, do not use it with
combinators such as many
, because such
parsers loop until a failure occurs. Careless use will thus result
in an infinite loop.
takeTill :: (Char -> Bool) -> Parser Text #
Consume input as long as the predicate returns False
(i.e. until it returns True
), and return the consumed input.
This parser does not fail. It will return an empty string if the
predicate returns True
on the first character of input.
Note: Because this parser does not fail, do not use it with
combinators such as many
, because such
parsers loop until a failure occurs. Careless use will thus result
in an infinite loop.
String combinators
If you enable the OverloadedStrings
language extension, you can
use the *>
and <*
combinators to simplify the common task of
matching a statically known string, then immediately parsing
something else.
Instead of writing something like this:
string
"foo"*>
wibble
Using OverloadedStrings
, you can omit the explicit use of
string
, and write a more compact version:
"foo" *>
wibble
(Note: the .*>
and <*.
combinators that were originally
provided for this purpose are obsolete and unnecessary, and will be
removed in the next major version.)
Consume all remaining input
takeLazyText :: Parser Text #
Consume all remaining input and return it as a single string.
Text parsing
Match either a single newline character '\n'
, or a carriage
return followed by a newline character "\r\n"
.
isEndOfLine :: Char -> Bool #
A predicate that matches either a carriage return '\r'
or
newline '\n'
character.
isHorizontalSpace :: Char -> Bool #
A predicate that matches either a space ' '
or horizontal tab
'\t'
character.
Numeric parsers
hexadecimal :: (Integral a, Bits a) => Parser a #
Parse and decode an unsigned hexadecimal number. The hex digits
'a'
through 'f'
may be upper or lower case.
This parser does not accept a leading "0x"
string.
signed :: Num a => Parser a -> Parser a #
Parse a number with an optional leading '+'
or '-'
sign
character.
Parse a rational number.
This parser accepts an optional leading sign character, followed by
at least one decimal digit. The syntax similar to that accepted by
the read
function, with the exception that a trailing '.'
or
'e'
not followed by a number is not consumed.
Examples with behaviour identical to read
, if you feed an empty
continuation to the first result:
rational "3" == Done 3.0 "" rational "3.1" == Done 3.1 "" rational "3e4" == Done 30000.0 "" rational "3.1e4" == Done 31000.0, ""
Examples with behaviour identical to read
:
rational ".3" == Fail "input does not start with a digit" rational "e3" == Fail "input does not start with a digit"
Examples of differences from read
:
rational "3.foo" == Done 3.0 ".foo" rational "3e" == Done 3.0 "e"
This function does not accept string representations of "NaN" or "Infinity".
A numeric type that can represent integers accurately, and
floating point numbers to the precision of a Double
.
Note: this type is deprecated, and will be removed in the next
major release. Use the Scientific
type instead.
Instances
Eq Number # | |
Fractional Number # | |
Data Number # | |
Defined in Data.Attoparsec.Number gfoldl :: (forall d b. Data d => c (d -> b) -> d -> c b) -> (forall g. g -> c g) -> Number -> c Number # gunfold :: (forall b r. Data b => c (b -> r) -> c r) -> (forall r. r -> c r) -> Constr -> c Number # toConstr :: Number -> Constr # dataTypeOf :: Number -> DataType # dataCast1 :: Typeable t => (forall d. Data d => c (t d)) -> Maybe (c Number) # dataCast2 :: Typeable t => (forall d e. (Data d, Data e) => c (t d e)) -> Maybe (c Number) # gmapT :: (forall b. Data b => b -> b) -> Number -> Number # gmapQl :: (r -> r' -> r) -> r -> (forall d. Data d => d -> r') -> Number -> r # gmapQr :: forall r r'. (r' -> r -> r) -> r -> (forall d. Data d => d -> r') -> Number -> r # gmapQ :: (forall d. Data d => d -> u) -> Number -> [u] # gmapQi :: Int -> (forall d. Data d => d -> u) -> Number -> u # gmapM :: Monad m => (forall d. Data d => d -> m d) -> Number -> m Number # gmapMp :: MonadPlus m => (forall d. Data d => d -> m d) -> Number -> m Number # gmapMo :: MonadPlus m => (forall d. Data d => d -> m d) -> Number -> m Number # | |
Num Number # | |
Ord Number # | |
Real Number # | |
Defined in Data.Attoparsec.Number toRational :: Number -> Rational # | |
RealFrac Number # | |
Show Number # | |
NFData Number # | |
Defined in Data.Attoparsec.Number |
Deprecated: Use scientific
instead.
Parse a number, attempting to preserve both speed and precision.
The syntax accepted by this parser is the same as for double
.
This function does not accept string representations of "NaN" or "Infinity".
rational :: Fractional a => Parser a #
Parse a rational number.
The syntax accepted by this parser is the same as for double
.
Note: this parser is not safe for use with inputs from untrusted
sources. An input with a suitably large exponent such as
"1e1000000000"
will cause a huge Integer
to be allocated,
resulting in what is effectively a denial-of-service attack.
In most cases, it is better to use double
or scientific
instead.
scientific :: Parser Scientific #
Parse a scientific number.
The syntax accepted by this parser is the same as for double
.
Combinators
try :: Parser i a -> Parser i a #
Attempt a parse, and if it fails, rewind the input so that no input appears to have been consumed.
This combinator is provided for compatibility with Parsec. attoparsec parsers always backtrack on failure.
Name the parser, in case failure occurs.
choice :: Alternative f => [f a] -> f a #
choice ps
tries to apply the actions in the list ps
in order,
until one of them succeeds. Returns the value of the succeeding
action.
option :: Alternative f => a -> f a -> f a #
option x p
tries to apply action p
. If p
fails without
consuming input, it returns the value x
, otherwise the value
returned by p
.
priority = option 0 (digitToInt <$> digit)
many' :: MonadPlus m => m a -> m [a] #
many' p
applies the action p
zero or more times. Returns a
list of the returned values of p
. The value returned by p
is
forced to WHNF.
word = many' letter
many1 :: Alternative f => f a -> f [a] #
many1 p
applies the action p
one or more times. Returns a
list of the returned values of p
.
word = many1 letter
many1' :: MonadPlus m => m a -> m [a] #
many1' p
applies the action p
one or more times. Returns a
list of the returned values of p
. The value returned by p
is
forced to WHNF.
word = many1' letter
manyTill :: Alternative f => f a -> f b -> f [a] #
manyTill p end
applies action p
zero or more times until
action end
succeeds, and returns the list of values returned by
p
. This can be used to scan comments:
simpleComment = string "<!--" *> manyTill anyChar (string "-->")
(Note the overlapping parsers anyChar
and string "-->"
.
While this will work, it is not very efficient, as it will cause a
lot of backtracking.)
manyTill' :: MonadPlus m => m a -> m b -> m [a] #
manyTill' p end
applies action p
zero or more times until
action end
succeeds, and returns the list of values returned by
p
. This can be used to scan comments:
simpleComment = string "<!--" *> manyTill' anyChar (string "-->")
(Note the overlapping parsers anyChar
and string "-->"
.
While this will work, it is not very efficient, as it will cause a
lot of backtracking.)
The value returned by p
is forced to WHNF.
sepBy :: Alternative f => f a -> f s -> f [a] #
sepBy p sep
applies zero or more occurrences of p
, separated
by sep
. Returns a list of the values returned by p
.
commaSep p = p `sepBy` (char ',')
sepBy' :: MonadPlus m => m a -> m s -> m [a] #
sepBy' p sep
applies zero or more occurrences of p
, separated
by sep
. Returns a list of the values returned by p
. The value
returned by p
is forced to WHNF.
commaSep p = p `sepBy'` (char ',')
sepBy1 :: Alternative f => f a -> f s -> f [a] #
sepBy1 p sep
applies one or more occurrences of p
, separated
by sep
. Returns a list of the values returned by p
.
commaSep p = p `sepBy1` (char ',')
sepBy1' :: MonadPlus m => m a -> m s -> m [a] #
sepBy1' p sep
applies one or more occurrences of p
, separated
by sep
. Returns a list of the values returned by p
. The value
returned by p
is forced to WHNF.
commaSep p = p `sepBy1'` (char ',')
skipMany :: Alternative f => f a -> f () #
Skip zero or more instances of an action.
skipMany1 :: Alternative f => f a -> f () #
Skip one or more instances of an action.
eitherP :: Alternative f => f a -> f b -> f (Either a b) #
Combine two alternatives.
match :: Parser a -> Parser (Text, a) #
Return both the result of a parse and the portion of the input that was consumed while it was being parsed.
State observation and manipulation functions
endOfInput :: forall t. Chunk t => Parser t () #
Match only if all input has been consumed.