pandoc-2.0.2: Conversion between markup formats

CopyrightCopyright (C) 2006-2017 John MacFarlane
LicenseGNU GPL, version 2 or above
MaintainerJohn MacFarlane <jgm@berkeley.edu>
Stabilityalpha
Portabilityportable
Safe HaskellNone
LanguageHaskell98

Text.Pandoc.Parsing

Contents

Description

A utility library with parsers used in pandoc readers.

Synopsis

Documentation

takeWhileP :: Monad m => (Char -> Bool) -> ParserT [Char] st m [Char] Source #

Parse characters while a predicate is true.

takeP :: Monad m => Int -> ParserT [Char] st m [Char] Source #

anyLine :: Monad m => ParserT [Char] st m [Char] Source #

Parse any line of text

anyLineNewline :: Monad m => ParserT [Char] st m [Char] Source #

Parse any line, include the final newline in the output

indentWith :: Stream s m Char => HasReaderOptions st => Int -> ParserT s st m [Char] Source #

Parse indent by specified number of spaces (or equiv. tabs)

many1Till :: (Show end, Stream s m t) => ParserT s st m a -> ParserT s st m end -> ParserT s st m [a] Source #

Like manyTill, but reads at least one item.

notFollowedBy' :: (Show b, Stream s m a) => ParserT s st m b -> ParserT s st m () Source #

A more general form of notFollowedBy. This one allows any type of parser to be specified, and succeeds only if that parser fails. It does not consume any input.

oneOfStrings :: Stream s m Char => [String] -> ParserT s st m String Source #

Parses one of a list of strings. If the list contains two strings one of which is a prefix of the other, the longer string will be matched if possible.

oneOfStringsCI :: Stream s m Char => [String] -> ParserT s st m String Source #

Parses one of a list of strings (tried in order), case insensitive.

spaceChar :: Stream s m Char => ParserT s st m Char Source #

Parses a space or tab.

nonspaceChar :: Stream s m Char => ParserT s st m Char Source #

Parses a nonspace, nonnewline character.

skipSpaces :: Stream s m Char => ParserT s st m () Source #

Skips zero or more spaces or tabs.

blankline :: Stream s m Char => ParserT s st m Char Source #

Skips zero or more spaces or tabs, then reads a newline.

blanklines :: Stream s m Char => ParserT s st m [Char] Source #

Parses one or more blank lines and returns a string of newlines.

gobbleSpaces :: (HasReaderOptions st, Monad m) => Int -> ParserT [Char] st m () Source #

Gobble n spaces; if tabs are encountered, expand them and gobble some or all of their spaces, leaving the rest.

gobbleAtMostSpaces :: (HasReaderOptions st, Monad m) => Int -> ParserT [Char] st m Int Source #

Gobble up to n spaces; if tabs are encountered, expand them and gobble some or all of their spaces, leaving the rest.

enclosed Source #

Arguments

:: (Show end, Stream s m Char) 
=> ParserT s st m t

start parser

-> ParserT s st m end

end parser

-> ParserT s st m a

content parser (to be used repeatedly)

-> ParserT s st m [a] 

Parses material enclosed between start and end parsers.

stringAnyCase :: Stream s m Char => [Char] -> ParserT s st m String Source #

Parse string, case insensitive.

parseFromString :: Monad m => ParserT [Char] st m a -> String -> ParserT [Char] st m a Source #

Parse contents of str using parser and return result.

parseFromString' :: Monad m => ParserT String ParserState m a -> String -> ParserT String ParserState m a Source #

Like parseFromString but specialized for ParserState. This resets stateLastStrPos, which is almost always what we want.

lineClump :: Monad m => ParserT [Char] st m String Source #

Parse raw line block up to and including blank lines.

charsInBalanced :: Stream s m Char => Char -> Char -> ParserT s st m Char -> ParserT s st m String Source #

Parse a string of characters between an open character and a close character, including text between balanced pairs of open and close, which must be different. For example, charsInBalanced '(' ')' anyChar will parse "(hello (there))" and return "hello (there)".

romanNumeral Source #

Arguments

:: Stream s m Char 
=> Bool

Uppercase if true

-> ParserT s st m Int 

Parses a roman numeral (uppercase or lowercase), returns number.

emailAddress :: Stream s m Char => ParserT s st m (String, String) Source #

Parses an email address; returns original and corresponding escaped mailto: URI.

uri :: Monad m => ParserT [Char] st m (String, String) Source #

Parses a URI. Returns pair of original and URI-escaped version.

withHorizDisplacement Source #

Arguments

:: Stream s m Char 
=> ParserT s st m a

Parser to apply

-> ParserT s st m (a, Int)

(result, displacement)

Applies a parser, returns tuple of its results and its horizontal displacement (the difference between the source column at the end and the source column at the beginning). Vertical displacement (source row) is ignored.

withRaw :: Monad m => ParsecT [Char] st m a -> ParsecT [Char] st m (a, [Char]) Source #

Applies a parser and returns the raw string that was parsed, along with the value produced by the parser.

escaped Source #

Arguments

:: Stream s m Char 
=> ParserT s st m Char

Parser for character to escape

-> ParserT s st m Char 

Parses backslash, then applies character parser.

characterReference :: Stream s m Char => ParserT s st m Char Source #

Parse character entity.

anyOrderedListMarker :: Stream s m Char => ParserT s ParserState m ListAttributes Source #

Parses an ordered list marker and returns list attributes.

orderedListMarker :: Stream s m Char => ListNumberStyle -> ListNumberDelim -> ParserT s ParserState m Int Source #

Parses an ordered list marker with a given style and delimiter, returns number.

charRef :: Stream s m Char => ParserT s st m Inline Source #

Parses a character reference and returns a Str element.

lineBlockLines :: Monad m => ParserT [Char] st m [String] Source #

Parses an RST-style line block and returns a list of strings.

tableWith :: (Stream s m Char, HasReaderOptions st, Functor mf, Applicative mf, Monad mf) => ParserT s st m (mf [Blocks], [Alignment], [Int]) -> ([Int] -> ParserT s st m (mf [Blocks])) -> ParserT s st m sep -> ParserT s st m end -> ParserT s st m (mf Blocks) Source #

Parse a table using headerParser, rowParser, lineParser, and footerParser.

gridTableWith Source #

Arguments

:: (Monad m, HasReaderOptions st, Functor mf, Applicative mf, Monad mf) 
=> ParserT [Char] st m (mf Blocks)

Block list parser

-> Bool

Headerless table

-> ParserT [Char] st m (mf Blocks) 

gridTableWith' Source #

Arguments

:: (Monad m, HasReaderOptions st, Functor mf, Applicative mf, Monad mf) 
=> ParserT [Char] st m (mf Blocks)

Block list parser

-> Bool

Headerless table

-> ParserT [Char] st m (TableComponents mf) 

readWith :: Parser [Char] st a -> st -> String -> Either PandocError a Source #

Parse a string with a given parser and state

readWithM Source #

Arguments

:: Monad m 
=> ParserT [Char] st m a

parser

-> st

initial state

-> String

input

-> m (Either PandocError a) 

Removes the ParsecT layer from the monad transformer stack

testStringWith :: Show a => ParserT [Char] ParserState Identity a -> [Char] -> IO () Source #

Parse a string with parser (for testing).

guardEnabled :: (Stream s m a, HasReaderOptions st) => Extension -> ParserT s st m () Source #

Succeed only if the extension is enabled.

guardDisabled :: (Stream s m a, HasReaderOptions st) => Extension -> ParserT s st m () Source #

Succeed only if the extension is disabled.

updateLastStrPos :: (Stream s m a, HasLastStrPosition st) => ParserT s st m () Source #

Update the position on which the last string ended.

notAfterString :: (Stream s m a, HasLastStrPosition st) => ParserT s st m Bool Source #

Whether we are right after the end of a string.

logMessage :: (Stream s m a, HasLogMessages st) => LogMessage -> ParserT s st m () Source #

Add a log message.

reportLogMessages :: (PandocMonad m, HasLogMessages st) => ParserT s st m () Source #

Report all the accumulated log messages, according to verbosity level.

data ParserState Source #

Parsing options.

Constructors

ParserState 

Fields

Instances

Default ParserState Source # 

Methods

def :: ParserState #

HasMeta ParserState Source # 
HasIncludeFiles ParserState Source # 
HasLogMessages ParserState Source # 
HasLastStrPosition ParserState Source # 
HasMacros ParserState Source # 
HasIdentifierList ParserState Source # 
HasHeaderMap ParserState Source # 
HasReaderOptions ParserState Source # 
Monad m => HasQuoteContext ParserState m Source # 

data HeaderType Source #

Constructors

SingleHeader Char

Single line of characters underneath

DoubleHeader Char

Lines of characters above and below

data ParserContext Source #

Constructors

ListItemState

Used when running parser on list item contents

NullState

Default state

data QuoteContext Source #

Constructors

InSingleQuote

Used when parsing inside single quotes

InDoubleQuote

Used when parsing inside double quotes

NoQuote

Used when not parsing inside quotes

newtype Key Source #

Constructors

Key String 

Instances

Eq Key Source # 

Methods

(==) :: Key -> Key -> Bool #

(/=) :: Key -> Key -> Bool #

Ord Key Source # 

Methods

compare :: Key -> Key -> Ordering #

(<) :: Key -> Key -> Bool #

(<=) :: Key -> Key -> Bool #

(>) :: Key -> Key -> Bool #

(>=) :: Key -> Key -> Bool #

max :: Key -> Key -> Key #

min :: Key -> Key -> Key #

Read Key Source # 
Show Key Source # 

Methods

showsPrec :: Int -> Key -> ShowS #

show :: Key -> String #

showList :: [Key] -> ShowS #

type Parser t s = Parsec t s Source #

newtype Future s a Source #

Reader monad wrapping the parser state. This is used to possibly delay evaluation until all relevant information has been parsed and made available in the parser state.

Constructors

Future 

Fields

Instances

Monad (Future s) Source # 

Methods

(>>=) :: Future s a -> (a -> Future s b) -> Future s b #

(>>) :: Future s a -> Future s b -> Future s b #

return :: a -> Future s a #

fail :: String -> Future s a #

Functor (Future s) Source # 

Methods

fmap :: (a -> b) -> Future s a -> Future s b #

(<$) :: a -> Future s b -> Future s a #

Applicative (Future s) Source # 

Methods

pure :: a -> Future s a #

(<*>) :: Future s (a -> b) -> Future s a -> Future s b #

(*>) :: Future s a -> Future s b -> Future s b #

(<*) :: Future s a -> Future s b -> Future s a #

Monoid a => Monoid (Future s a) Source # 

Methods

mempty :: Future s a #

mappend :: Future s a -> Future s a -> Future s a #

mconcat :: [Future s a] -> Future s a #

runF :: Future s a -> s -> a Source #

asksF :: (s -> a) -> Future s a Source #

returnF :: Monad m => a -> m (Future s a) Source #

token :: Stream s m t => (t -> String) -> (t -> SourcePos) -> (t -> Maybe a) -> ParsecT s st m a Source #

(<+?>) :: Monoid a => ParserT s st m a -> ParserT s st m a -> ParserT s st m a infixr 5 Source #

insertIncludedFile :: (PandocMonad m, HasIncludeFiles st) => ParserT [a] st m Blocks -> (String -> [a]) -> [FilePath] -> FilePath -> ParserT [a] st m Blocks Source #

Parse content of include file as blocks. Circular includes result in an PandocParseError.

insertIncludedFileF :: (PandocMonad m, HasIncludeFiles st) => ParserT String st m (Future st Blocks) -> [FilePath] -> FilePath -> ParserT String st m (Future st Blocks) Source #

Parse content of include file as future blocks. Circular includes result in an PandocParseError.

Re-exports from Text.Pandoc.Parsec

class Monad m => Stream s m t | s -> t #

An instance of Stream has stream type s, underlying monad m and token type t determined by the stream

Some rough guidelines for a "correct" instance of Stream:

  • unfoldM uncons gives the [t] corresponding to the stream
  • A Stream instance is responsible for maintaining the "position within the stream" in the stream state s. This is trivial unless you are using the monad in a non-trivial way.

Minimal complete definition

uncons

Instances

Monad m => Stream ByteString m Char 

Methods

uncons :: ByteString -> m (Maybe (Char, ByteString)) #

Monad m => Stream ByteString m Char 

Methods

uncons :: ByteString -> m (Maybe (Char, ByteString)) #

Monad m => Stream Text m Char 

Methods

uncons :: Text -> m (Maybe (Char, Text)) #

Monad m => Stream Text m Char 

Methods

uncons :: Text -> m (Maybe (Char, Text)) #

Monad m => Stream [tok] m tok 

Methods

uncons :: [tok] -> m (Maybe (tok, [tok])) #

runParser :: Stream s Identity t => Parsec s u a -> u -> SourceName -> s -> Either ParseError a #

The most general way to run a parser over the Identity monad. runParser p state filePath input runs parser p on the input list of tokens input, obtained from source filePath with the initial user state st. The filePath is only used in error messages and may be the empty string. Returns either a ParseError (Left) or a value of type a (Right).

 parseFromFile p fname
   = do{ input <- readFile fname
       ; return (runParser p () fname input)
       }

runParserT :: Stream s m t => ParsecT s u m a -> u -> SourceName -> s -> m (Either ParseError a) #

The most general way to run a parser. runParserT p state filePath input runs parser p on the input list of tokens input, obtained from source filePath with the initial user state st. The filePath is only used in error messages and may be the empty string. Returns a computation in the underlying monad m that return either a ParseError (Left) or a value of type a (Right).

parse :: Stream s Identity t => Parsec s () a -> SourceName -> s -> Either ParseError a #

parse p filePath input runs a parser p over Identity without user state. The filePath is only used in error messages and may be the empty string. Returns either a ParseError (Left) or a value of type a (Right).

 main    = case (parse numbers "" "11, 2, 43") of
            Left err  -> print err
            Right xs  -> print (sum xs)

 numbers = commaSep integer

tokenPrim #

Arguments

:: Stream s m t 
=> (t -> String)

Token pretty-printing function.

-> (SourcePos -> t -> s -> SourcePos)

Next position calculating function.

-> (t -> Maybe a)

Matching function for the token to parse.

-> ParsecT s u m a 

The parser tokenPrim showTok nextPos testTok accepts a token t with result x when the function testTok t returns Just x. The token can be shown using showTok t. The position of the next token should be returned when nextPos is called with the current source position pos, the current token t and the rest of the tokens toks, nextPos pos t toks.

This is the most primitive combinator for accepting tokens. For example, the char parser could be implemented as:

 char c
   = tokenPrim showChar nextPos testChar
   where
     showChar x        = "'" ++ x ++ "'"
     testChar x        = if x == c then Just x else Nothing
     nextPos pos x xs  = updatePosChar pos x

anyToken :: (Stream s m t, Show t) => ParsecT s u m t #

The parser anyToken accepts any kind of token. It is for example used to implement eof. Returns the accepted token.

getInput :: Monad m => ParsecT s u m s #

Returns the current input

setInput :: Monad m => s -> ParsecT s u m () #

setInput input continues parsing with input. The getInput and setInput functions can for example be used to deal with #include files.

unexpected :: Stream s m t => String -> ParsecT s u m a #

The parser unexpected msg always fails with an unexpected error message msg without consuming any input.

The parsers fail, (<?>) and unexpected are the three parsers used to generate error messages. Of these, only (<?>) is commonly used. For an example of the use of unexpected, see the definition of notFollowedBy.

char :: Stream s m Char => Char -> ParsecT s u m Char #

char c parses a single character c. Returns the parsed character (i.e. c).

 semiColon  = char ';'

letter :: Stream s m Char => ParsecT s u m Char #

Parses a letter (an upper case or lower case character). Returns the parsed character.

digit :: Stream s m Char => ParsecT s u m Char #

Parses a digit. Returns the parsed character.

alphaNum :: Stream s m Char => ParsecT s u m Char #

Parses a letter or digit (a character between '0' and '9'). Returns the parsed character.

skipMany :: ParsecT s u m a -> ParsecT s u m () #

skipMany p applies the parser p zero or more times, skipping its result.

 spaces  = skipMany space

skipMany1 :: Stream s m t => ParsecT s u m a -> ParsecT s u m () #

skipMany1 p applies the parser p one or more times, skipping its result.

spaces :: Stream s m Char => ParsecT s u m () #

Skips zero or more white space characters. See also skipMany.

space :: Stream s m Char => ParsecT s u m Char #

Parses a white space character (any character which satisfies isSpace) Returns the parsed character.

anyChar :: Stream s m Char => ParsecT s u m Char #

This parser succeeds for any character. Returns the parsed character.

satisfy :: Stream s m Char => (Char -> Bool) -> ParsecT s u m Char #

The parser satisfy f succeeds for any character for which the supplied function f returns True. Returns the character that is actually parsed.

newline :: Stream s m Char => ParsecT s u m Char #

Parses a newline character ('\n'). Returns a newline character.

string :: Stream s m Char => String -> ParsecT s u m String #

string s parses a sequence of characters given by s. Returns the parsed string (i.e. s).

 divOrMod    =   string "div" 
             <|> string "mod"

count :: Stream s m t => Int -> ParsecT s u m a -> ParsecT s u m [a] #

count n p parses n occurrences of p. If n is smaller or equal to zero, the parser equals to return []. Returns a list of n values returned by p.

eof :: (Stream s m t, Show t) => ParsecT s u m () #

This parser only succeeds at the end of the input. This is not a primitive parser but it is defined using notFollowedBy.

 eof  = notFollowedBy anyToken <?> "end of input"

noneOf :: Stream s m Char => [Char] -> ParsecT s u m Char #

As the dual of oneOf, noneOf cs succeeds if the current character not in the supplied list of characters cs. Returns the parsed character.

 consonant = noneOf "aeiou"

oneOf :: Stream s m Char => [Char] -> ParsecT s u m Char #

oneOf cs succeeds if the current character is in the supplied list of characters cs. Returns the parsed character. See also satisfy.

  vowel  = oneOf "aeiou"

lookAhead :: Stream s m t => ParsecT s u m a -> ParsecT s u m a #

lookAhead p parses p without consuming any input.

If p fails and consumes some input, so does lookAhead. Combine with try if this is undesirable.

notFollowedBy :: (Stream s m t, Show a) => ParsecT s u m a -> ParsecT s u m () #

notFollowedBy p only succeeds when parser p fails. This parser does not consume any input. This parser can be used to implement the 'longest match' rule. For example, when recognizing keywords (for example let), we want to make sure that a keyword is not followed by a legal identifier character, in which case the keyword is actually an identifier (for example lets). We can program this behaviour as follows:

 keywordLet  = try (do{ string "let"
                      ; notFollowedBy alphaNum
                      })

many :: ParsecT s u m a -> ParsecT s u m [a] #

many p applies the parser p zero or more times. Returns a list of the returned values of p.

 identifier  = do{ c  <- letter
                 ; cs <- many (alphaNum <|> char '_')
                 ; return (c:cs)
                 }

many1 :: Stream s m t => ParsecT s u m a -> ParsecT s u m [a] #

many1 p applies the parser p one or more times. Returns a list of the returned values of p.

 word  = many1 letter

manyTill :: Stream s m t => ParsecT s u m a -> ParsecT s u m end -> ParsecT s u m [a] #

manyTill p end applies parser p zero or more times until parser end succeeds. Returns the list of values returned by p. This parser can be used to scan comments:

 simpleComment   = do{ string "<!--"
                     ; manyTill anyChar (try (string "-->"))
                     }

Note the overlapping parsers anyChar and string "-->", and therefore the use of the try combinator.

(<|>) :: ParsecT s u m a -> ParsecT s u m a -> ParsecT s u m a infixr 1 #

This combinator implements choice. The parser p <|> q first applies p. If it succeeds, the value of p is returned. If p fails without consuming any input, parser q is tried. This combinator is defined equal to the mplus member of the MonadPlus class and the (<|>) member of Alternative.

The parser is called predictive since q is only tried when parser p didn't consume any input (i.e.. the look ahead is 1). This non-backtracking behaviour allows for both an efficient implementation of the parser combinators and the generation of good error messages.

(<?>) :: ParsecT s u m a -> String -> ParsecT s u m a infix 0 #

The parser p <?> msg behaves as parser p, but whenever the parser p fails without consuming any input, it replaces expect error messages with the expect error message msg.

This is normally used at the end of a set alternatives where we want to return an error message in terms of a higher level construct rather than returning all possible characters. For example, if the expr parser from the try example would fail, the error message is: '...: expecting expression'. Without the (<?>) combinator, the message would be like '...: expecting "let" or letter', which is less friendly.

choice :: Stream s m t => [ParsecT s u m a] -> ParsecT s u m a #

choice ps tries to apply the parsers in the list ps in order, until one of them succeeds. Returns the value of the succeeding parser.

try :: ParsecT s u m a -> ParsecT s u m a #

The parser try p behaves like parser p, except that it pretends that it hasn't consumed any input when an error occurs.

This combinator is used whenever arbitrary look ahead is needed. Since it pretends that it hasn't consumed any input when p fails, the (<|>) combinator will try its second alternative even when the first parser failed while consuming input.

The try combinator can for example be used to distinguish identifiers and reserved words. Both reserved words and identifiers are a sequence of letters. Whenever we expect a certain reserved word where we can also expect an identifier we have to use the try combinator. Suppose we write:

 expr        = letExpr <|> identifier <?> "expression"

 letExpr     = do{ string "let"; ... }
 identifier  = many1 letter

If the user writes "lexical", the parser fails with: unexpected 'x', expecting 't' in "let". Indeed, since the (<|>) combinator only tries alternatives when the first alternative hasn't consumed input, the identifier parser is never tried (because the prefix "le" of the string "let" parser is already consumed). The right behaviour can be obtained by adding the try combinator:

 expr        = letExpr <|> identifier <?> "expression"

 letExpr     = do{ try (string "let"); ... }
 identifier  = many1 letter

sepBy :: Stream s m t => ParsecT s u m a -> ParsecT s u m sep -> ParsecT s u m [a] #

sepBy p sep parses zero or more occurrences of p, separated by sep. Returns a list of values returned by p.

 commaSep p  = p `sepBy` (symbol ",")

sepBy1 :: Stream s m t => ParsecT s u m a -> ParsecT s u m sep -> ParsecT s u m [a] #

sepBy1 p sep parses one or more occurrences of p, separated by sep. Returns a list of values returned by p.

sepEndBy :: Stream s m t => ParsecT s u m a -> ParsecT s u m sep -> ParsecT s u m [a] #

sepEndBy p sep parses zero or more occurrences of p, separated and optionally ended by sep, ie. haskell style statements. Returns a list of values returned by p.

 haskellStatements  = haskellStatement `sepEndBy` semi

sepEndBy1 :: Stream s m t => ParsecT s u m a -> ParsecT s u m sep -> ParsecT s u m [a] #

sepEndBy1 p sep parses one or more occurrences of p, separated and optionally ended by sep. Returns a list of values returned by p.

endBy :: Stream s m t => ParsecT s u m a -> ParsecT s u m sep -> ParsecT s u m [a] #

endBy p sep parses zero or more occurrences of p, separated and ended by sep. Returns a list of values returned by p.

  cStatements  = cStatement `endBy` semi

endBy1 :: Stream s m t => ParsecT s u m a -> ParsecT s u m sep -> ParsecT s u m [a] #

endBy1 p sep parses one or more occurrences of p, separated and ended by sep. Returns a list of values returned by p.

option :: Stream s m t => a -> ParsecT s u m a -> ParsecT s u m a #

option x p tries to apply parser p. If p fails without consuming input, it returns the value x, otherwise the value returned by p.

 priority  = option 0 (do{ d <- digit
                         ; return (digitToInt d) 
                         })

optional :: Stream s m t => ParsecT s u m a -> ParsecT s u m () #

optional p tries to apply parser p. It will parse p or nothing. It only fails if p fails after consuming input. It discards the result of p.

optionMaybe :: Stream s m t => ParsecT s u m a -> ParsecT s u m (Maybe a) #

optionMaybe p tries to apply parser p. If p fails without consuming input, it return Nothing, otherwise it returns Just the value returned by p.

getState :: Monad m => ParsecT s u m u #

Returns the current user state.

setState :: Monad m => u -> ParsecT s u m () #

An alias for putState for backwards compatibility.

updateState :: Monad m => (u -> u) -> ParsecT s u m () #

An alias for modifyState for backwards compatibility.

data SourcePos :: * #

The abstract data type SourcePos represents source positions. It contains the name of the source (i.e. file name), a line number and a column number. SourcePos is an instance of the Show, Eq and Ord class.

Instances

Eq SourcePos 
Data SourcePos 

Methods

gfoldl :: (forall d b. Data d => c (d -> b) -> d -> c b) -> (forall g. g -> c g) -> SourcePos -> c SourcePos #

gunfold :: (forall b r. Data b => c (b -> r) -> c r) -> (forall r. r -> c r) -> Constr -> c SourcePos #

toConstr :: SourcePos -> Constr #

dataTypeOf :: SourcePos -> DataType #

dataCast1 :: Typeable (* -> *) t => (forall d. Data d => c (t d)) -> Maybe (c SourcePos) #

dataCast2 :: Typeable (* -> * -> *) t => (forall d e. (Data d, Data e) => c (t d e)) -> Maybe (c SourcePos) #

gmapT :: (forall b. Data b => b -> b) -> SourcePos -> SourcePos #

gmapQl :: (r -> r' -> r) -> r -> (forall d. Data d => d -> r') -> SourcePos -> r #

gmapQr :: (r' -> r -> r) -> r -> (forall d. Data d => d -> r') -> SourcePos -> r #

gmapQ :: (forall d. Data d => d -> u) -> SourcePos -> [u] #

gmapQi :: Int -> (forall d. Data d => d -> u) -> SourcePos -> u #

gmapM :: Monad m => (forall d. Data d => d -> m d) -> SourcePos -> m SourcePos #

gmapMp :: MonadPlus m => (forall d. Data d => d -> m d) -> SourcePos -> m SourcePos #

gmapMo :: MonadPlus m => (forall d. Data d => d -> m d) -> SourcePos -> m SourcePos #

Ord SourcePos 
Show SourcePos 

getPosition :: Monad m => ParsecT s u m SourcePos #

Returns the current source position. See also SourcePos.

setPosition :: Monad m => SourcePos -> ParsecT s u m () #

setPosition pos sets the current source position to pos.

sourceColumn :: SourcePos -> Column #

Extracts the column number from a source position.

sourceLine :: SourcePos -> Line #

Extracts the line number from a source position.

setSourceColumn :: SourcePos -> Column -> SourcePos #

Set the column number of a source position.

setSourceLine :: SourcePos -> Line -> SourcePos #

Set the line number of a source position.

newPos :: SourceName -> Line -> Column -> SourcePos #

Create a new SourcePos with the given source name, line number and column number.

type Line = Int #

type Column = Int #