{-# LANGUAGE CPP #-} {-# LANGUAGE ExplicitForAll #-} {-# LANGUAGE FlexibleContexts #-} {-# LANGUAGE FlexibleInstances #-} {-# LANGUAGE GeneralizedNewtypeDeriving #-} {-# LANGUAGE IncoherentInstances #-} {-# LANGUAGE MultiParamTypeClasses #-} {-# LANGUAGE ViewPatterns #-} {-# LANGUAGE OverloadedStrings #-} {- | Module : Text.Pandoc.Parsing Copyright : Copyright (C) 2006-2020 John MacFarlane License : GNU GPL, version 2 or above Maintainer : John MacFarlane Stability : alpha Portability : portable A utility library with parsers used in pandoc readers. -} module Text.Pandoc.Parsing ( take1WhileP, takeP, countChar, textStr, anyLine, anyLineNewline, indentWith, manyChar, many1Char, manyTillChar, many1TillChar, many1Till, manyUntil, manyUntilChar, sepBy1', notFollowedBy', oneOfStrings, oneOfStringsCI, spaceChar, nonspaceChar, skipSpaces, blankline, blanklines, gobbleSpaces, gobbleAtMostSpaces, enclosed, stringAnyCase, parseFromString, parseFromString', lineClump, charsInBalanced, romanNumeral, emailAddress, uri, mathInline, mathDisplay, withHorizDisplacement, withRaw, escaped, characterReference, upperRoman, lowerRoman, decimal, lowerAlpha, upperAlpha, anyOrderedListMarker, orderedListMarker, charRef, lineBlockLines, tableWith, widthsFromIndices, gridTableWith, gridTableWith', readWith, readWithM, testStringWith, guardEnabled, guardDisabled, updateLastStrPos, notAfterString, logMessage, reportLogMessages, ParserState (..), HasReaderOptions (..), HasIdentifierList (..), HasMacros (..), HasLogMessages (..), HasLastStrPosition (..), HasIncludeFiles (..), defaultParserState, HeaderType (..), ParserContext (..), QuoteContext (..), HasQuoteContext (..), NoteTable, NoteTable', KeyTable, SubstTable, Key (..), toKey, registerHeader, smartPunctuation, singleQuoteStart, singleQuoteEnd, doubleQuoteStart, doubleQuoteEnd, ellipses, apostrophe, dash, nested, citeKey, Parser, ParserT, F, Future(..), runF, askF, asksF, returnF, trimInlinesF, token, (<+?>), extractIdClass, insertIncludedFile, insertIncludedFileF, -- * Re-exports from Text.Parsec Stream, runParser, runParserT, parse, tokenPrim, anyToken, getInput, setInput, unexpected, char, letter, digit, alphaNum, skipMany, skipMany1, spaces, space, anyChar, satisfy, newline, string, count, eof, noneOf, oneOf, lookAhead, notFollowedBy, many, many1, manyTill, (<|>), (), choice, try, sepBy, sepBy1, sepEndBy, sepEndBy1, endBy, endBy1, option, optional, optionMaybe, getState, setState, updateState, SourcePos, getPosition, setPosition, sourceColumn, sourceLine, setSourceColumn, setSourceLine, incSourceColumn, newPos, Line, Column ) where import Control.Monad.Identity import Control.Monad.Reader import Data.Char (chr, isAlphaNum, isAscii, isAsciiUpper, isPunctuation, isSpace, ord, toLower, toUpper) import Data.Default import Data.Functor (($>)) import Data.List (intercalate, transpose) import qualified Data.Map as M import Data.Maybe (mapMaybe, fromMaybe) import qualified Data.Set as Set import Data.String import Data.Text (Text) import qualified Data.Text as T import Text.HTML.TagSoup.Entity (lookupEntity) import Text.Pandoc.Asciify (toAsciiChar) import Text.Pandoc.Builder (Blocks, HasMeta (..), Inlines, trimInlines) import qualified Text.Pandoc.Builder as B import Text.Pandoc.Class.PandocMonad (PandocMonad, readFileFromDirs, report) import Text.Pandoc.Definition import Text.Pandoc.Logging import Text.Pandoc.Options import Text.Pandoc.Readers.LaTeX.Types (Macro) import Text.Pandoc.Shared import qualified Text.Pandoc.UTF8 as UTF8 (putStrLn) import Text.Pandoc.XML (fromEntities) import Text.Parsec hiding (token) import Text.Parsec.Pos (initialPos, newPos, updatePosString) import Control.Monad.Except import Text.Pandoc.Error type Parser t s = Parsec t s type ParserT = ParsecT -- | 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. newtype Future s a = Future { runDelayed :: Reader s a } deriving (Monad, Applicative, Functor) type F = Future ParserState runF :: Future s a -> s -> a runF = runReader . runDelayed askF :: Future s s askF = Future ask asksF :: (s -> a) -> Future s a asksF f = Future $ asks f returnF :: Monad m => a -> m (Future s a) returnF = return . return trimInlinesF :: Future s Inlines -> Future s Inlines trimInlinesF = liftM trimInlines instance Semigroup a => Semigroup (Future s a) where (<>) = liftM2 (<>) instance (Semigroup a, Monoid a) => Monoid (Future s a) where mempty = return mempty mappend = (<>) -- | Like @count@, but packs its result countChar :: (Stream s m Char, Monad m) => Int -> ParsecT s st m Char -> ParsecT s st m Text countChar n = fmap T.pack . count n -- | Like @string@, but uses @Text@. textStr :: Stream s m Char => Text -> ParsecT s u m Text textStr t = string (T.unpack t) $> t -- | Parse characters while a predicate is true. take1WhileP :: Monad m => (Char -> Bool) -> ParserT Text st m Text take1WhileP f = do -- needed to persuade parsec that this won't match an empty string: c <- satisfy f inp <- getInput pos <- getPosition let (t, rest) = T.span f inp setInput rest setPosition $ if f '\t' || f '\n' then updatePosString pos $ T.unpack t else incSourceColumn pos (T.length t) return $ T.singleton c <> t -- Parse n characters of input (or the rest of the input if -- there aren't n characters). takeP :: Monad m => Int -> ParserT Text st m Text takeP n = do guard (n > 0) -- faster than 'count n anyChar' inp <- getInput pos <- getPosition let (xs, rest) = T.splitAt n inp -- needed to persuade parsec that this won't match an empty string: anyChar setInput rest setPosition $ updatePosString pos $ T.unpack xs return xs -- | Parse any line of text anyLine :: Monad m => ParserT Text st m Text anyLine = do -- This is much faster than: -- manyTill anyChar newline inp <- getInput pos <- getPosition case T.break (=='\n') inp of (this, T.uncons -> Just ('\n', rest)) -> do -- needed to persuade parsec that this won't match an empty string: anyChar setInput rest setPosition $ incSourceLine (setSourceColumn pos 1) 1 return this _ -> mzero -- | Parse any line, include the final newline in the output anyLineNewline :: Monad m => ParserT Text st m Text anyLineNewline = (<> "\n") <$> anyLine -- | Parse indent by specified number of spaces (or equiv. tabs) indentWith :: Stream s m Char => HasReaderOptions st => Int -> ParserT s st m Text indentWith num = do tabStop <- getOption readerTabStop if num < tabStop then countChar num (char ' ') else choice [ try (countChar num (char ' ')) , try (char '\t' >> indentWith (num - tabStop)) ] -- | Like @many@, but packs its result. manyChar :: Stream s m t => ParserT s st m Char -> ParserT s st m Text manyChar = fmap T.pack . many -- | Like @many1@, but packs its result. many1Char :: Stream s m t => ParserT s st m Char -> ParserT s st m Text many1Char = fmap T.pack . many1 -- | Like @manyTill@, but packs its result. manyTillChar :: Stream s m t => ParserT s st m Char -> ParserT s st m a -> ParserT s st m Text manyTillChar p = fmap T.pack . manyTill p -- | Like @manyTill@, but reads at least one item. many1Till :: (Show end, Stream s m t) => ParserT s st m a -> ParserT s st m end -> ParserT s st m [a] many1Till p end = do notFollowedBy' end first <- p rest <- manyTill p end return (first:rest) -- | Like @many1Till@, but packs its result many1TillChar :: (Show end, Stream s m t) => ParserT s st m Char -> ParserT s st m end -> ParserT s st m Text many1TillChar p = fmap T.pack . many1Till p -- | Like @manyTill@, but also returns the result of end parser. manyUntil :: ParserT s u m a -> ParserT s u m b -> ParserT s u m ([a], b) manyUntil p end = scan where scan = (do e <- end return ([], e) ) <|> (do x <- p (xs, e) <- scan return (x:xs, e)) -- | Like @manyUntil@, but also packs its result. manyUntilChar :: ParserT s u m Char -> ParserT s u m b -> ParserT s u m (Text, b) manyUntilChar p = fmap go . manyUntil p where go (x, y) = (T.pack x, y) -- | Like @sepBy1@ from Parsec, -- but does not fail if it @sep@ succeeds and @p@ fails. sepBy1' :: ParsecT s u m a -> ParsecT s u m sep -> ParsecT s u m [a] sepBy1' p sep = (:) <$> p <*> many (try $ sep >> p) -- | 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. notFollowedBy' :: (Show b, Stream s m a) => ParserT s st m b -> ParserT s st m () notFollowedBy' p = try $ join $ do a <- try p return (unexpected (show a)) <|> return (return ()) -- (This version due to Andrew Pimlott on the Haskell mailing list.) oneOfStrings' :: Stream s m Char => (Char -> Char -> Bool) -> [Text] -> ParserT s st m Text oneOfStrings' f = fmap T.pack . oneOfStrings'' f . fmap T.unpack -- TODO: This should be re-implemented in a Text-aware way oneOfStrings'' :: Stream s m Char => (Char -> Char -> Bool) -> [String] -> ParserT s st m String oneOfStrings'' _ [] = Prelude.fail "no strings" oneOfStrings'' matches strs = try $ do c <- anyChar let strs' = [xs | (x:xs) <- strs, x `matches` c] case strs' of [] -> Prelude.fail "not found" _ -> (c:) <$> oneOfStrings'' matches strs' <|> if "" `elem` strs' then return [c] else Prelude.fail "not found" -- | 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. oneOfStrings :: Stream s m Char => [Text] -> ParserT s st m Text oneOfStrings = oneOfStrings' (==) -- | Parses one of a list of strings (tried in order), case insensitive. -- TODO: This will not be accurate with general Unicode (neither -- Text.toLower nor Text.toCaseFold can be implemented with a map) oneOfStringsCI :: Stream s m Char => [Text] -> ParserT s st m Text oneOfStringsCI = oneOfStrings' ciMatch where ciMatch x y = toLower' x == toLower' y -- this optimizes toLower by checking common ASCII case -- first, before calling the expensive unicode-aware -- function: toLower' c | isAsciiUpper c = chr (ord c + 32) | isAscii c = c | otherwise = toLower c -- | Parses a space or tab. spaceChar :: Stream s m Char => ParserT s st m Char spaceChar = satisfy $ \c -> c == ' ' || c == '\t' -- | Parses a nonspace, nonnewline character. nonspaceChar :: Stream s m Char => ParserT s st m Char nonspaceChar = noneOf ['\t', '\n', ' ', '\r'] -- | Skips zero or more spaces or tabs. skipSpaces :: Stream s m Char => ParserT s st m () skipSpaces = skipMany spaceChar -- | Skips zero or more spaces or tabs, then reads a newline. blankline :: Stream s m Char => ParserT s st m Char blankline = try $ skipSpaces >> newline -- | Parses one or more blank lines and returns a string of newlines. blanklines :: Stream s m Char => ParserT s st m Text blanklines = T.pack <$> many1 blankline -- | Gobble n spaces; if tabs are encountered, expand them -- and gobble some or all of their spaces, leaving the rest. gobbleSpaces :: (HasReaderOptions st, Monad m) => Int -> ParserT Text st m () gobbleSpaces 0 = return () gobbleSpaces n | n < 0 = error "gobbleSpaces called with negative number" | otherwise = try $ do char ' ' <|> eatOneSpaceOfTab gobbleSpaces (n - 1) eatOneSpaceOfTab :: (HasReaderOptions st, Monad m) => ParserT Text st m Char eatOneSpaceOfTab = do char '\t' tabstop <- getOption readerTabStop inp <- getInput setInput $ T.replicate (tabstop - 1) " " <> inp return ' ' -- | Gobble up to 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 Text st m Int gobbleAtMostSpaces 0 = return 0 gobbleAtMostSpaces n | n < 0 = error "gobbleAtMostSpaces called with negative number" | otherwise = option 0 $ do char ' ' <|> eatOneSpaceOfTab (+ 1) <$> gobbleAtMostSpaces (n - 1) -- | Parses material enclosed between start and end parsers. enclosed :: (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] enclosed start end parser = try $ start >> notFollowedBy space >> many1Till parser end -- | Parse string, case insensitive. stringAnyCase :: Stream s m Char => Text -> ParserT s st m Text stringAnyCase = fmap T.pack . stringAnyCase' . T.unpack stringAnyCase' :: Stream s m Char => String -> ParserT s st m String stringAnyCase' [] = string "" stringAnyCase' (x:xs) = do firstChar <- char (toUpper x) <|> char (toLower x) rest <- stringAnyCase' xs return (firstChar:rest) -- | Parse contents of 'str' using 'parser' and return result. parseFromString :: (Stream s m Char, IsString s) => ParserT s st m r -> Text -> ParserT s st m r parseFromString parser str = do oldPos <- getPosition setPosition $ initialPos "chunk" oldInput <- getInput setInput $ fromString $ T.unpack str result <- parser spaces eof setInput oldInput setPosition oldPos return result -- | Like 'parseFromString' but specialized for 'ParserState'. -- This resets 'stateLastStrPos', which is almost always what we want. parseFromString' :: (Stream s m Char, IsString s, HasLastStrPosition u) => ParserT s u m a -> Text -> ParserT s u m a parseFromString' parser str = do oldLastStrPos <- getLastStrPos <$> getState updateState $ setLastStrPos Nothing res <- parseFromString parser str updateState $ setLastStrPos oldLastStrPos return res -- | Parse raw line block up to and including blank lines. lineClump :: Monad m => ParserT Text st m Text lineClump = blanklines <|> (T.unlines <$> many1 (notFollowedBy blankline >> anyLine)) -- | 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)". charsInBalanced :: Stream s m Char => Char -> Char -> ParserT s st m Char -> ParserT s st m Text charsInBalanced open close parser = try $ do char open let isDelim c = c == open || c == close raw <- many $ T.pack <$> many1 (notFollowedBy (satisfy isDelim) >> parser) <|> (do res <- charsInBalanced open close parser return $ T.singleton open <> res <> T.singleton close) char close return $ T.concat raw -- old charsInBalanced would be: -- charsInBalanced open close (noneOf "\n" <|> char '\n' >> notFollowedBy blankline) -- old charsInBalanced' would be: -- charsInBalanced open close anyChar -- Auxiliary functions for romanNumeral: -- | Parses a roman numeral (uppercase or lowercase), returns number. romanNumeral :: Stream s m Char => Bool -- ^ Uppercase if true -> ParserT s st m Int romanNumeral upperCase = do let rchar uc = char $ if upperCase then uc else toLower uc let one = rchar 'I' let five = rchar 'V' let ten = rchar 'X' let fifty = rchar 'L' let hundred = rchar 'C' let fivehundred = rchar 'D' let thousand = rchar 'M' lookAhead $ choice [one, five, ten, fifty, hundred, fivehundred, thousand] thousands <- ((1000 *) . length) <$> many thousand ninehundreds <- option 0 $ try $ hundred >> thousand >> return 900 fivehundreds <- option 0 $ 500 <$ fivehundred fourhundreds <- option 0 $ try $ hundred >> fivehundred >> return 400 hundreds <- ((100 *) . length) <$> many hundred nineties <- option 0 $ try $ ten >> hundred >> return 90 fifties <- option 0 (50 <$ fifty) forties <- option 0 $ try $ ten >> fifty >> return 40 tens <- ((10 *) . length) <$> many ten nines <- option 0 $ try $ one >> ten >> return 9 fives <- option 0 (5 <$ five) fours <- option 0 $ try $ one >> five >> return 4 ones <- length <$> many one let total = thousands + ninehundreds + fivehundreds + fourhundreds + hundreds + nineties + fifties + forties + tens + nines + fives + fours + ones if total == 0 then Prelude.fail "not a roman numeral" else return total -- Parsers for email addresses and URIs -- | Parses an email address; returns original and corresponding -- escaped mailto: URI. emailAddress :: Stream s m Char => ParserT s st m (Text, Text) emailAddress = try $ toResult <$> mailbox <*> (char '@' *> domain) where toResult mbox dom = let full = fromEntities $ T.pack $ mbox ++ '@':dom in (full, escapeURI $ "mailto:" <> full) mailbox = intercalate "." <$> (emailWord `sepBy1'` dot) domain = intercalate "." <$> (subdomain `sepBy1'` dot) dot = char '.' subdomain = many1 $ alphaNum <|> innerPunct -- this excludes some valid email addresses, since an -- email could contain e.g. '__', but gives better results -- for our purposes, when combined with markdown parsing: innerPunct = try (satisfy (\c -> isEmailPunct c || c == '@') <* notFollowedBy space <* notFollowedBy (satisfy isPunctuation)) -- technically an email address could begin with a symbol, -- but allowing this creates too many problems. -- See e.g. https://github.com/jgm/pandoc/issues/2940 emailWord = do x <- satisfy isAlphaNum xs <- many (satisfy isEmailChar) return (x:xs) isEmailChar c = isAlphaNum c || isEmailPunct c isEmailPunct c = T.any (== c) "!\"#$%&'*+-/=?^_{|}~;" uriScheme :: Stream s m Char => ParserT s st m Text uriScheme = oneOfStringsCI (Set.toList schemes) -- | Parses a URI. Returns pair of original and URI-escaped version. uri :: Stream s m Char => ParserT s st m (Text, Text) uri = try $ do scheme <- uriScheme char ':' -- Avoid parsing e.g. "**Notes:**" as a raw URI: notFollowedBy (oneOf "*_]") -- We allow sentence punctuation except at the end, since -- we don't want the trailing '.' in 'http://google.com.' We want to allow -- http://en.wikipedia.org/wiki/State_of_emergency_(disambiguation) -- as a URL, while NOT picking up the closing paren in -- (http://wikipedia.org). So we include balanced parens in the URL. str <- T.concat <$> many1 (uriChunkBetween '(' ')' <|> uriChunkBetween '{' '}' <|> uriChunkBetween '[' ']' <|> T.pack <$> uriChunk) str' <- option str $ char '/' >> return (str <> "/") let uri' = scheme <> ":" <> fromEntities str' return (uri', escapeURI uri') where wordChar = alphaNum <|> oneOf "#$%+/@\\_-&=" percentEscaped = try $ (:) <$> char '%' <*> many1 hexDigit entity = try $ pure <$> characterReference punct = try $ many1 (char ',') <|> fmap pure (satisfy (\c -> not (isSpace c) && c /= '<' && c /= '>')) uriChunk = many1 wordChar <|> percentEscaped <|> entity <|> try (punct <* lookAhead (void wordChar <|> void percentEscaped)) uriChunkBetween l r = try $ do chunk <- between (char l) (char r) uriChunk return (T.pack $ [l] ++ chunk ++ [r]) mathInlineWith :: Stream s m Char => Text -> Text -> ParserT s st m Text mathInlineWith op cl = try $ do textStr op when (op == "$") $ notFollowedBy space words' <- many1Till (countChar 1 (noneOf " \t\n\\") <|> (char '\\' >> -- This next clause is needed because \text{..} can -- contain $, \(\), etc. (try (string "text" >> (("\\text" <>) <$> inBalancedBraces 0 "")) <|> (\c -> T.pack ['\\',c]) <$> anyChar)) <|> do (blankline <* notFollowedBy' blankline) <|> (oneOf " \t" <* skipMany (oneOf " \t")) notFollowedBy (char '$') return " " ) (try $ textStr cl) notFollowedBy digit -- to prevent capture of $5 return $ trimMath $ T.concat words' where inBalancedBraces :: Stream s m Char => Int -> Text -> ParserT s st m Text inBalancedBraces n = fmap T.pack . inBalancedBraces' n . T.unpack inBalancedBraces' :: Stream s m Char => Int -> String -> ParserT s st m String inBalancedBraces' 0 "" = do c <- anyChar if c == '{' then inBalancedBraces' 1 "{" else mzero inBalancedBraces' 0 s = return $ reverse s inBalancedBraces' numOpen ('\\':xs) = do c <- anyChar inBalancedBraces' numOpen (c:'\\':xs) inBalancedBraces' numOpen xs = do c <- anyChar case c of '}' -> inBalancedBraces' (numOpen - 1) (c:xs) '{' -> inBalancedBraces' (numOpen + 1) (c:xs) _ -> inBalancedBraces' numOpen (c:xs) mathDisplayWith :: Stream s m Char => Text -> Text -> ParserT s st m Text mathDisplayWith op cl = try $ fmap T.pack $ do textStr op many1Till (noneOf "\n" <|> (newline <* notFollowedBy' blankline)) (try $ textStr cl) mathDisplay :: (HasReaderOptions st, Stream s m Char) => ParserT s st m Text mathDisplay = (guardEnabled Ext_tex_math_dollars >> mathDisplayWith "$$" "$$") <|> (guardEnabled Ext_tex_math_single_backslash >> mathDisplayWith "\\[" "\\]") <|> (guardEnabled Ext_tex_math_double_backslash >> mathDisplayWith "\\\\[" "\\\\]") mathInline :: (HasReaderOptions st , Stream s m Char) => ParserT s st m Text mathInline = (guardEnabled Ext_tex_math_dollars >> mathInlineWith "$" "$") <|> (guardEnabled Ext_tex_math_single_backslash >> mathInlineWith "\\(" "\\)") <|> (guardEnabled Ext_tex_math_double_backslash >> mathInlineWith "\\\\(" "\\\\)") -- | 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. withHorizDisplacement :: Stream s m Char => ParserT s st m a -- ^ Parser to apply -> ParserT s st m (a, Int) -- ^ (result, displacement) withHorizDisplacement parser = do pos1 <- getPosition result <- parser pos2 <- getPosition return (result, sourceColumn pos2 - sourceColumn pos1) -- | Applies a parser and returns the raw string that was parsed, -- along with the value produced by the parser. withRaw :: Monad m => ParsecT Text st m a -> ParsecT Text st m (a, Text) withRaw parser = do pos1 <- getPosition inp <- getInput result <- parser pos2 <- getPosition let (l1,c1) = (sourceLine pos1, sourceColumn pos1) let (l2,c2) = (sourceLine pos2, sourceColumn pos2) let inplines = take ((l2 - l1) + 1) $ T.lines inp let raw = case inplines of [] -> "" [l] -> T.take (c2 - c1) l ls -> T.unlines (init ls) <> T.take (c2 - 1) (last ls) return (result, raw) -- | Parses backslash, then applies character parser. escaped :: Stream s m Char => ParserT s st m Char -- ^ Parser for character to escape -> ParserT s st m Char escaped parser = try $ char '\\' >> parser -- | Parse character entity. characterReference :: Stream s m Char => ParserT s st m Char characterReference = try $ do char '&' ent <- many1Till nonspaceChar (char ';') let ent' = case ent of '#':'X':xs -> '#':'x':xs -- workaround tagsoup bug '#':_ -> ent _ -> ent ++ ";" case lookupEntity ent' of Just (c : _) -> return c _ -> Prelude.fail "entity not found" -- | Parses an uppercase roman numeral and returns (UpperRoman, number). upperRoman :: Stream s m Char => ParserT s st m (ListNumberStyle, Int) upperRoman = do num <- romanNumeral True return (UpperRoman, num) -- | Parses a lowercase roman numeral and returns (LowerRoman, number). lowerRoman :: Stream s m Char => ParserT s st m (ListNumberStyle, Int) lowerRoman = do num <- romanNumeral False return (LowerRoman, num) -- | Parses a decimal numeral and returns (Decimal, number). decimal :: Stream s m Char => ParserT s st m (ListNumberStyle, Int) decimal = do num <- many1 digit return (Decimal, fromMaybe 1 $ safeRead $ T.pack num) -- | Parses a '@' and optional label and -- returns (DefaultStyle, [next example number]). The next -- example number is incremented in parser state, and the label -- (if present) is added to the label table. exampleNum :: Stream s m Char => ParserT s ParserState m (ListNumberStyle, Int) exampleNum = do char '@' lab <- T.pack <$> many (alphaNum <|> satisfy (\c -> c == '_' || c == '-')) st <- getState let num = stateNextExample st let newlabels = if T.null lab then stateExamples st else M.insert lab num $ stateExamples st updateState $ \s -> s{ stateNextExample = num + 1 , stateExamples = newlabels } return (Example, num) -- | Parses a '#' returns (DefaultStyle, 1). defaultNum :: Stream s m Char => ParserT s st m (ListNumberStyle, Int) defaultNum = do char '#' return (DefaultStyle, 1) -- | Parses a lowercase letter and returns (LowerAlpha, number). lowerAlpha :: Stream s m Char => ParserT s st m (ListNumberStyle, Int) lowerAlpha = do ch <- oneOf ['a'..'z'] return (LowerAlpha, ord ch - ord 'a' + 1) -- | Parses an uppercase letter and returns (UpperAlpha, number). upperAlpha :: Stream s m Char => ParserT s st m (ListNumberStyle, Int) upperAlpha = do ch <- oneOf ['A'..'Z'] return (UpperAlpha, ord ch - ord 'A' + 1) -- | Parses a roman numeral i or I romanOne :: Stream s m Char => ParserT s st m (ListNumberStyle, Int) romanOne = (char 'i' >> return (LowerRoman, 1)) <|> (char 'I' >> return (UpperRoman, 1)) -- | Parses an ordered list marker and returns list attributes. anyOrderedListMarker :: Stream s m Char => ParserT s ParserState m ListAttributes anyOrderedListMarker = choice [delimParser numParser | delimParser <- [inPeriod, inOneParen, inTwoParens], numParser <- [decimal, exampleNum, defaultNum, romanOne, lowerAlpha, lowerRoman, upperAlpha, upperRoman]] -- | Parses a list number (num) followed by a period, returns list attributes. inPeriod :: Stream s m Char => ParserT s st m (ListNumberStyle, Int) -> ParserT s st m ListAttributes inPeriod num = try $ do (style, start) <- num char '.' let delim = if style == DefaultStyle then DefaultDelim else Period return (start, style, delim) -- | Parses a list number (num) followed by a paren, returns list attributes. inOneParen :: Stream s m Char => ParserT s st m (ListNumberStyle, Int) -> ParserT s st m ListAttributes inOneParen num = try $ do (style, start) <- num char ')' return (start, style, OneParen) -- | Parses a list number (num) enclosed in parens, returns list attributes. inTwoParens :: Stream s m Char => ParserT s st m (ListNumberStyle, Int) -> ParserT s st m ListAttributes inTwoParens num = try $ do char '(' (style, start) <- num char ')' return (start, style, TwoParens) -- | Parses an ordered list marker with a given style and delimiter, -- returns number. orderedListMarker :: Stream s m Char => ListNumberStyle -> ListNumberDelim -> ParserT s ParserState m Int orderedListMarker style delim = do let num = defaultNum <|> -- # can continue any kind of list case style of DefaultStyle -> decimal Example -> exampleNum Decimal -> decimal UpperRoman -> upperRoman LowerRoman -> lowerRoman UpperAlpha -> upperAlpha LowerAlpha -> lowerAlpha let context = case delim of DefaultDelim -> inPeriod Period -> inPeriod OneParen -> inOneParen TwoParens -> inTwoParens (start, _, _) <- context num return start -- | Parses a character reference and returns a Str element. charRef :: Stream s m Char => ParserT s st m Inline charRef = Str . T.singleton <$> characterReference lineBlockLine :: Monad m => ParserT Text st m Text lineBlockLine = try $ do char '|' char ' ' white <- T.pack <$> many (spaceChar >> return '\160') notFollowedBy newline line <- anyLine continuations <- many (try $ char ' ' >> anyLine) return $ white <> T.unwords (line : continuations) blankLineBlockLine :: Stream s m Char => ParserT s st m Char blankLineBlockLine = try (char '|' >> blankline) -- | Parses an RST-style line block and returns a list of strings. lineBlockLines :: Monad m => ParserT Text st m [Text] lineBlockLines = try $ do lines' <- many1 (lineBlockLine <|> (T.singleton <$> blankLineBlockLine)) skipMany blankline return lines' -- | Parse a table using 'headerParser', 'rowParser', -- 'lineParser', and 'footerParser'. tableWith :: (Stream s m Char, HasReaderOptions st, 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) tableWith headerParser rowParser lineParser footerParser = try $ do (aligns, widths, heads, rows) <- tableWith' headerParser rowParser lineParser footerParser let th = TableHead nullAttr <$> heads tb = (:[]) . TableBody nullAttr 0 [] <$> rows tf = pure $ TableFoot nullAttr [] return $ B.table B.emptyCaption (zip aligns (map fromWidth widths)) <$> th <*> tb <*> tf where fromWidth n | n > 0 = ColWidth n | otherwise = ColWidthDefault type TableComponents mf = ([Alignment], [Double], mf [Row], mf [Row]) tableWith' :: (Stream s m Char, HasReaderOptions st, 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 (TableComponents mf) tableWith' headerParser rowParser lineParser footerParser = try $ do (heads, aligns, indices) <- headerParser lines' <- sequence <$> rowParser indices `sepEndBy1` lineParser footerParser numColumns <- getOption readerColumns let widths = if null indices then replicate (length aligns) 0.0 else widthsFromIndices numColumns indices let toRow = Row nullAttr . map B.simpleCell toHeaderRow l = if null l then [] else [toRow l] return (aligns, widths, toHeaderRow <$> heads, map toRow <$> lines') -- Calculate relative widths of table columns, based on indices widthsFromIndices :: Int -- Number of columns on terminal -> [Int] -- Indices -> [Double] -- Fractional relative sizes of columns widthsFromIndices _ [] = [] widthsFromIndices numColumns' indices = let numColumns = max numColumns' (if null indices then 0 else last indices) lengths' = zipWith (-) indices (0:indices) lengths = reverse $ case reverse lengths' of [] -> [] [x] -> [x] -- compensate for the fact that intercolumn -- spaces are counted in widths of all columns -- but the last... (x:y:zs) -> if x < y && y - x <= 2 then y:y:zs else x:y:zs totLength = sum lengths quotient = if totLength > numColumns then fromIntegral totLength else fromIntegral numColumns fracs = map (\l -> fromIntegral l / quotient) lengths in tail fracs --- -- Parse a grid table: starts with row of '-' on top, then header -- (which may be grid), then the rows, -- which may be grid, separated by blank lines, and -- ending with a footer (dashed line followed by blank line). gridTableWith :: (Stream s m Char, HasReaderOptions st, HasLastStrPosition st, Monad mf, IsString s) => ParserT s st m (mf Blocks) -- ^ Block list parser -> Bool -- ^ Headerless table -> ParserT s st m (mf Blocks) gridTableWith blocks headless = tableWith (gridTableHeader headless blocks) (gridTableRow blocks) (gridTableSep '-') gridTableFooter gridTableWith' :: (Stream s m Char, HasReaderOptions st, HasLastStrPosition st, Monad mf, IsString s) => ParserT s st m (mf Blocks) -- ^ Block list parser -> Bool -- ^ Headerless table -> ParserT s st m (TableComponents mf) gridTableWith' blocks headless = tableWith' (gridTableHeader headless blocks) (gridTableRow blocks) (gridTableSep '-') gridTableFooter gridTableSplitLine :: [Int] -> Text -> [Text] gridTableSplitLine indices line = map removeFinalBar $ tail $ splitTextByIndices (init indices) $ trimr line gridPart :: Stream s m Char => Char -> ParserT s st m ((Int, Int), Alignment) gridPart ch = do leftColon <- option False (True <$ char ':') dashes <- many1 (char ch) rightColon <- option False (True <$ char ':') char '+' let lengthDashes = length dashes + (if leftColon then 1 else 0) + (if rightColon then 1 else 0) let alignment = case (leftColon, rightColon) of (True, True) -> AlignCenter (True, False) -> AlignLeft (False, True) -> AlignRight (False, False) -> AlignDefault return ((lengthDashes, lengthDashes + 1), alignment) gridDashedLines :: Stream s m Char => Char -> ParserT s st m [((Int, Int), Alignment)] gridDashedLines ch = try $ char '+' >> many1 (gridPart ch) <* blankline removeFinalBar :: Text -> Text removeFinalBar = T.dropWhileEnd go . T.dropWhileEnd (=='|') where go c = T.any (== c) " \t" -- | Separator between rows of grid table. gridTableSep :: Stream s m Char => Char -> ParserT s st m Char gridTableSep ch = try $ gridDashedLines ch >> return '\n' -- | Parse header for a grid table. gridTableHeader :: (Stream s m Char, Monad mf, IsString s, HasLastStrPosition st) => Bool -- ^ Headerless table -> ParserT s st m (mf Blocks) -> ParserT s st m (mf [Blocks], [Alignment], [Int]) gridTableHeader headless blocks = try $ do optional blanklines dashes <- gridDashedLines '-' rawContent <- if headless then return $ repeat "" else many1 (notFollowedBy (gridTableSep '=') >> char '|' >> T.pack <$> many1Till anyChar newline) underDashes <- if headless then return dashes else gridDashedLines '=' guard $ length dashes == length underDashes let lines' = map (snd . fst) underDashes let indices = scanl (+) 0 lines' let aligns = map snd underDashes let rawHeads = if headless then replicate (length underDashes) "" else map (T.unlines . map trim) $ transpose $ map (gridTableSplitLine indices) rawContent heads <- sequence <$> mapM (parseFromString' blocks . trim) rawHeads return (heads, aligns, indices) gridTableRawLine :: Stream s m Char => [Int] -> ParserT s st m [Text] gridTableRawLine indices = do char '|' line <- many1Till anyChar newline return (gridTableSplitLine indices $ T.pack line) -- | Parse row of grid table. gridTableRow :: (Stream s m Char, Monad mf, IsString s, HasLastStrPosition st) => ParserT s st m (mf Blocks) -> [Int] -> ParserT s st m (mf [Blocks]) gridTableRow blocks indices = do colLines <- many1 (gridTableRawLine indices) let cols = map ((<> "\n") . T.unlines . removeOneLeadingSpace) $ transpose colLines compactifyCell bs = case compactify [bs] of [] -> mempty x:_ -> x cells <- sequence <$> mapM (parseFromString' blocks) cols return $ fmap (map compactifyCell) cells removeOneLeadingSpace :: [Text] -> [Text] removeOneLeadingSpace xs = if all startsWithSpace xs then map (T.drop 1) xs else xs where startsWithSpace t = case T.uncons t of Nothing -> True Just (c, _) -> c == ' ' -- | Parse footer for a grid table. gridTableFooter :: Stream s m Char => ParserT s st m () gridTableFooter = optional blanklines --- -- | Removes the ParsecT layer from the monad transformer stack readWithM :: (Stream s m Char, ToText s) => ParserT s st m a -- ^ parser -> st -- ^ initial state -> s -- ^ input -> m (Either PandocError a) readWithM parser state input = mapLeft (PandocParsecError $ toText input) `liftM` runParserT parser state "source" input -- | Parse a string with a given parser and state readWith :: Parser Text st a -> st -> Text -> Either PandocError a readWith p t inp = runIdentity $ readWithM p t inp -- | Parse a string with @parser@ (for testing). testStringWith :: Show a => ParserT Text ParserState Identity a -> Text -> IO () testStringWith parser str = UTF8.putStrLn $ show $ readWith parser defaultParserState str -- | Parsing options. data ParserState = ParserState { stateOptions :: ReaderOptions, -- ^ User options stateParserContext :: ParserContext, -- ^ Inside list? stateQuoteContext :: QuoteContext, -- ^ Inside quoted environment? stateAllowLinks :: Bool, -- ^ Allow parsing of links stateAllowLineBreaks :: Bool, -- ^ Allow parsing of line breaks stateMaxNestingLevel :: Int, -- ^ Max # of nested Strong/Emph stateLastStrPos :: Maybe SourcePos, -- ^ Position after last str parsed stateKeys :: KeyTable, -- ^ List of reference keys stateHeaderKeys :: KeyTable, -- ^ List of implicit header ref keys stateSubstitutions :: SubstTable, -- ^ List of substitution references stateNotes :: NoteTable, -- ^ List of notes (raw bodies) stateNotes' :: NoteTable', -- ^ List of notes (parsed bodies) stateNoteRefs :: Set.Set Text, -- ^ List of note references used stateMeta :: Meta, -- ^ Document metadata stateMeta' :: F Meta, -- ^ Document metadata stateCitations :: M.Map Text Text, -- ^ RST-style citations stateHeaderTable :: [HeaderType], -- ^ Ordered list of header types used stateIdentifiers :: Set.Set Text, -- ^ Header identifiers used stateNextExample :: Int, -- ^ Number of next example stateExamples :: M.Map Text Int, -- ^ Map from example labels to numbers stateMacros :: M.Map Text Macro, -- ^ Table of macros defined so far stateRstDefaultRole :: Text, -- ^ Current rST default interpreted text role stateRstHighlight :: Maybe Text, -- ^ Current rST literal block language stateRstCustomRoles :: M.Map Text (Text, Maybe Text, Attr), -- ^ Current rST custom text roles -- Triple represents: 1) Base role, 2) Optional format (only for :raw: -- roles), 3) Additional classes (rest of Attr is unused)). stateCaption :: Maybe Inlines, -- ^ Caption in current environment stateInHtmlBlock :: Maybe Text, -- ^ Tag type of HTML block being parsed stateFencedDivLevel :: Int, -- ^ Depth of fenced div stateContainers :: [Text], -- ^ parent include files stateLogMessages :: [LogMessage], -- ^ log messages stateMarkdownAttribute :: Bool -- ^ True if in markdown=1 context } instance Default ParserState where def = defaultParserState instance HasMeta ParserState where setMeta field val st = st{ stateMeta = setMeta field val $ stateMeta st } deleteMeta field st = st{ stateMeta = deleteMeta field $ stateMeta st } class HasReaderOptions st where extractReaderOptions :: st -> ReaderOptions getOption :: (Stream s m t) => (ReaderOptions -> b) -> ParserT s st m b -- default getOption f = (f . extractReaderOptions) <$> getState instance HasReaderOptions ParserState where extractReaderOptions = stateOptions class HasQuoteContext st m where getQuoteContext :: (Stream s m t) => ParsecT s st m QuoteContext withQuoteContext :: QuoteContext -> ParsecT s st m a -> ParsecT s st m a instance Monad m => HasQuoteContext ParserState m where getQuoteContext = stateQuoteContext <$> getState withQuoteContext context parser = do oldState <- getState let oldQuoteContext = stateQuoteContext oldState setState oldState { stateQuoteContext = context } result <- parser newState <- getState setState newState { stateQuoteContext = oldQuoteContext } return result class HasIdentifierList st where extractIdentifierList :: st -> Set.Set Text updateIdentifierList :: (Set.Set Text -> Set.Set Text) -> st -> st instance HasIdentifierList ParserState where extractIdentifierList = stateIdentifiers updateIdentifierList f st = st{ stateIdentifiers = f $ stateIdentifiers st } class HasMacros st where extractMacros :: st -> M.Map Text Macro updateMacros :: (M.Map Text Macro -> M.Map Text Macro) -> st -> st instance HasMacros ParserState where extractMacros = stateMacros updateMacros f st = st{ stateMacros = f $ stateMacros st } class HasLastStrPosition st where setLastStrPos :: Maybe SourcePos -> st -> st getLastStrPos :: st -> Maybe SourcePos instance HasLastStrPosition ParserState where setLastStrPos pos st = st{ stateLastStrPos = pos } getLastStrPos st = stateLastStrPos st class HasLogMessages st where addLogMessage :: LogMessage -> st -> st getLogMessages :: st -> [LogMessage] instance HasLogMessages ParserState where addLogMessage msg st = st{ stateLogMessages = msg : stateLogMessages st } getLogMessages st = reverse $ stateLogMessages st class HasIncludeFiles st where getIncludeFiles :: st -> [Text] addIncludeFile :: Text -> st -> st dropLatestIncludeFile :: st -> st instance HasIncludeFiles ParserState where getIncludeFiles = stateContainers addIncludeFile f s = s{ stateContainers = f : stateContainers s } dropLatestIncludeFile s = s { stateContainers = drop 1 $ stateContainers s } defaultParserState :: ParserState defaultParserState = ParserState { stateOptions = def, stateParserContext = NullState, stateQuoteContext = NoQuote, stateAllowLinks = True, stateAllowLineBreaks = True, stateMaxNestingLevel = 6, stateLastStrPos = Nothing, stateKeys = M.empty, stateHeaderKeys = M.empty, stateSubstitutions = M.empty, stateNotes = [], stateNotes' = M.empty, stateNoteRefs = Set.empty, stateMeta = nullMeta, stateMeta' = return nullMeta, stateCitations = M.empty, stateHeaderTable = [], stateIdentifiers = Set.empty, stateNextExample = 1, stateExamples = M.empty, stateMacros = M.empty, stateRstDefaultRole = "title-reference", stateRstHighlight = Nothing, stateRstCustomRoles = M.empty, stateCaption = Nothing, stateInHtmlBlock = Nothing, stateFencedDivLevel = 0, stateContainers = [], stateLogMessages = [], stateMarkdownAttribute = False } -- | Add a log message. logMessage :: (Stream s m a, HasLogMessages st) => LogMessage -> ParserT s st m () logMessage msg = updateState (addLogMessage msg) -- | Report all the accumulated log messages, according to verbosity level. reportLogMessages :: (PandocMonad m, HasLogMessages st) => ParserT s st m () reportLogMessages = do msgs <- getLogMessages <$> getState mapM_ report msgs -- | Succeed only if the extension is enabled. guardEnabled :: (Stream s m a, HasReaderOptions st) => Extension -> ParserT s st m () guardEnabled ext = getOption readerExtensions >>= guard . extensionEnabled ext -- | Succeed only if the extension is disabled. guardDisabled :: (Stream s m a, HasReaderOptions st) => Extension -> ParserT s st m () guardDisabled ext = getOption readerExtensions >>= guard . not . extensionEnabled ext -- | Update the position on which the last string ended. updateLastStrPos :: (Stream s m a, HasLastStrPosition st) => ParserT s st m () updateLastStrPos = getPosition >>= updateState . setLastStrPos . Just -- | Whether we are right after the end of a string. notAfterString :: (Stream s m a, HasLastStrPosition st) => ParserT s st m Bool notAfterString = do pos <- getPosition st <- getState return $ getLastStrPos st /= Just pos data HeaderType = SingleHeader Char -- ^ Single line of characters underneath | DoubleHeader Char -- ^ Lines of characters above and below deriving (Eq, Show) data ParserContext = ListItemState -- ^ Used when running parser on list item contents | NullState -- ^ Default state deriving (Eq, Show) data QuoteContext = InSingleQuote -- ^ Used when parsing inside single quotes | InDoubleQuote -- ^ Used when parsing inside double quotes | NoQuote -- ^ Used when not parsing inside quotes deriving (Eq, Show) type NoteTable = [(Text, Text)] type NoteTable' = M.Map Text (SourcePos, F Blocks) -- used in markdown reader newtype Key = Key Text deriving (Show, Read, Eq, Ord) toKey :: Text -> Key toKey = Key . T.toLower . T.unwords . T.words . unbracket where unbracket t | Just ('[', t') <- T.uncons t , Just (t'', ']') <- T.unsnoc t' = t'' | otherwise = t type KeyTable = M.Map Key (Target, Attr) type SubstTable = M.Map Key Inlines -- | Add header to the list of headers in state, together -- with its associated identifier. If the identifier is null -- and the auto_identifiers extension is set, generate a new -- unique identifier, and update the list of identifiers -- in state. Issue a warning if an explicit identifier -- is encountered that duplicates an earlier identifier -- (explicit or automatically generated). registerHeader :: (Stream s m a, HasReaderOptions st, HasLogMessages st, HasIdentifierList st) => Attr -> Inlines -> ParserT s st m Attr registerHeader (ident,classes,kvs) header' = do ids <- extractIdentifierList <$> getState exts <- getOption readerExtensions if T.null ident && Ext_auto_identifiers `extensionEnabled` exts then do let id' = uniqueIdent exts (B.toList header') ids let id'' = if Ext_ascii_identifiers `extensionEnabled` exts then T.pack $ mapMaybe toAsciiChar $ T.unpack id' else id' updateState $ updateIdentifierList $ Set.insert id' updateState $ updateIdentifierList $ Set.insert id'' return (id'',classes,kvs) else do unless (T.null ident) $ do when (ident `Set.member` ids) $ do pos <- getPosition logMessage $ DuplicateIdentifier ident pos updateState $ updateIdentifierList $ Set.insert ident return (ident,classes,kvs) smartPunctuation :: (HasReaderOptions st, HasLastStrPosition st, HasQuoteContext st m, Stream s m Char) => ParserT s st m Inlines -> ParserT s st m Inlines smartPunctuation inlineParser = do guardEnabled Ext_smart choice [ quoted inlineParser, apostrophe, dash, ellipses ] apostrophe :: Stream s m Char => ParserT s st m Inlines apostrophe = (char '\'' <|> char '\8217') >> return (B.str "\x2019") quoted :: (HasLastStrPosition st, HasQuoteContext st m, Stream s m Char) => ParserT s st m Inlines -> ParserT s st m Inlines quoted inlineParser = doubleQuoted inlineParser <|> singleQuoted inlineParser singleQuoted :: (HasLastStrPosition st, HasQuoteContext st m, Stream s m Char) => ParserT s st m Inlines -> ParserT s st m Inlines singleQuoted inlineParser = try $ B.singleQuoted . mconcat <$ singleQuoteStart <*> withQuoteContext InSingleQuote (many1Till inlineParser singleQuoteEnd) doubleQuoted :: (HasQuoteContext st m, Stream s m Char) => ParserT s st m Inlines -> ParserT s st m Inlines doubleQuoted inlineParser = try $ B.doubleQuoted . mconcat <$ doubleQuoteStart <*> withQuoteContext InDoubleQuote (manyTill inlineParser doubleQuoteEnd) failIfInQuoteContext :: (HasQuoteContext st m, Stream s m t) => QuoteContext -> ParserT s st m () failIfInQuoteContext context = do context' <- getQuoteContext when (context' == context) $ Prelude.fail "already inside quotes" charOrRef :: Stream s m Char => [Char] -> ParserT s st m Char charOrRef cs = oneOf cs <|> try (do c <- characterReference guard (c `elem` cs) return c) singleQuoteStart :: (HasLastStrPosition st, HasQuoteContext st m, Stream s m Char) => ParserT s st m () singleQuoteStart = do failIfInQuoteContext InSingleQuote -- single quote start can't be right after str guard =<< notAfterString try $ do charOrRef "'\8216\145" notFollowedBy (oneOf [' ', '\t', '\n']) singleQuoteEnd :: Stream s m Char => ParserT s st m () singleQuoteEnd = try $ do charOrRef "'\8217\146" notFollowedBy alphaNum doubleQuoteStart :: (HasQuoteContext st m, Stream s m Char) => ParserT s st m () doubleQuoteStart = do failIfInQuoteContext InDoubleQuote try $ do charOrRef "\"\8220\147" notFollowedBy (oneOf [' ', '\t', '\n']) doubleQuoteEnd :: Stream s m Char => ParserT s st m () doubleQuoteEnd = void (charOrRef "\"\8221\148") ellipses :: Stream s m Char => ParserT s st m Inlines ellipses = try (string "..." >> return (B.str "\8230")) dash :: (HasReaderOptions st, Stream s m Char) => ParserT s st m Inlines dash = try $ do oldDashes <- extensionEnabled Ext_old_dashes <$> getOption readerExtensions if oldDashes then do char '-' (char '-' >> return (B.str "\8212")) <|> (lookAhead digit >> return (B.str "\8211")) else do string "--" (char '-' >> return (B.str "\8212")) <|> return (B.str "\8211") -- This is used to prevent exponential blowups for things like: -- a**a*a**a*a**a*a**a*a**a*a**a*a** nested :: Stream s m a => ParserT s ParserState m a -> ParserT s ParserState m a nested p = do nestlevel <- stateMaxNestingLevel <$> getState guard $ nestlevel > 0 updateState $ \st -> st{ stateMaxNestingLevel = stateMaxNestingLevel st - 1 } res <- p updateState $ \st -> st{ stateMaxNestingLevel = nestlevel } return res citeKey :: (Stream s m Char, HasLastStrPosition st) => ParserT s st m (Bool, Text) citeKey = try $ do guard =<< notAfterString suppress_author <- option False (True <$ char '-') char '@' firstChar <- alphaNum <|> char '_' <|> char '*' -- @* for wildcard in nocite let regchar = satisfy (\c -> isAlphaNum c || c == '_') let internal p = try $ p <* lookAhead regchar rest <- many $ regchar <|> internal (oneOf ":.#$%&-+?<>~/") <|> try (oneOf ":/" <* lookAhead (char '/')) let key = firstChar:rest return (suppress_author, T.pack key) token :: (Stream s m t) => (t -> Text) -> (t -> SourcePos) -> (t -> Maybe a) -> ParsecT s st m a token pp pos match = tokenPrim (T.unpack . pp) (\_ t _ -> pos t) match infixr 5 <+?> (<+?>) :: (Monoid a) => ParserT s st m a -> ParserT s st m a -> ParserT s st m a a <+?> b = a >>= flip fmap (try b <|> return mempty) . mappend extractIdClass :: Attr -> Attr extractIdClass (ident, cls, kvs) = (ident', cls', kvs') where ident' = fromMaybe ident (lookup "id" kvs) cls' = case lookup "class" kvs of Just cl -> T.words cl Nothing -> cls kvs' = filter (\(k,_) -> k /= "id" || k /= "class") kvs insertIncludedFile' :: (PandocMonad m, HasIncludeFiles st) => ParserT a st m (mf Blocks) -> (Text -> a) -> [FilePath] -> FilePath -> ParserT a st m (mf Blocks) insertIncludedFile' blocks totoks dirs f = do oldPos <- getPosition oldInput <- getInput containers <- getIncludeFiles <$> getState when (T.pack f `elem` containers) $ throwError $ PandocParseError $ T.pack $ "Include file loop at " ++ show oldPos updateState $ addIncludeFile $ T.pack f mbcontents <- readFileFromDirs dirs f contents <- case mbcontents of Just s -> return s Nothing -> do report $ CouldNotLoadIncludeFile (T.pack f) oldPos return "" setPosition $ newPos f 1 1 setInput $ totoks contents bs <- blocks setInput oldInput setPosition oldPos updateState dropLatestIncludeFile return bs -- | Parse content of include file as blocks. Circular includes result in an -- @PandocParseError@. insertIncludedFile :: (PandocMonad m, HasIncludeFiles st) => ParserT [a] st m Blocks -> (Text -> [a]) -> [FilePath] -> FilePath -> ParserT [a] st m Blocks insertIncludedFile blocks totoks dirs f = runIdentity <$> insertIncludedFile' (Identity <$> blocks) totoks dirs f -- | Parse content of include file as future blocks. Circular includes result in -- an @PandocParseError@. insertIncludedFileF :: (PandocMonad m, HasIncludeFiles st) => ParserT Text st m (Future st Blocks) -> [FilePath] -> FilePath -> ParserT Text st m (Future st Blocks) insertIncludedFileF p = insertIncludedFile' p id