-- | -- Module : Replace.Megaparsec -- -- __Replace.Megaparsec__ is for finding text patterns, and also editing and -- replacing the found patterns. -- This activity is traditionally done with regular expressions, -- but __Replace.Megaparsec__ uses "Text.Megaparsec" parsers instead for -- the pattern matching. -- -- __Replace.Megaparsec__ can be used in the same sort of “pattern capture” -- or “find all” situations in which one would use Python -- <https://docs.python.org/3/library/re.html#re.findall re.findall>, -- or Perl -- <https://perldoc.perl.org/functions/m.html m//>, -- or Unix -- <https://www.gnu.org/software/grep/ grep>. -- -- __Replace.Megaparsec__ can be used in the same sort of “stream editing” -- or “search-and-replace” situations in which one would use Python -- <https://docs.python.org/3/library/re.html#re.sub re.sub>, -- or Perl -- <https://perldoc.perl.org/functions/s.html s///>, -- or Unix -- <https://www.gnu.org/software/sed/manual/html_node/The-_0022s_0022-Command.html sed>, -- or -- <https://www.gnu.org/software/gawk/manual/gawk.html awk>. -- -- See the __replace-megaparsec__ package README for usage examples. {-# LANGUAGE LambdaCase #-} {-# LANGUAGE RankNTypes #-} {-# LANGUAGE TypeFamilies #-} {-# LANGUAGE FlexibleContexts #-} {-# LANGUAGE ScopedTypeVariables #-} module Replace.Megaparsec ( -- * Parser combinator sepCap , findAll , findAllCap -- * Running parser , streamEditT , streamEdit ) where import Data.Void import Data.Maybe import Data.Bifunctor import Data.Functor.Identity import Data.Proxy import Data.Foldable import Control.Exception (throw) import Data.Typeable import Control.Monad import Text.Megaparsec -- | -- == Separate and capture -- -- Parser combinator to find all of the non-overlapping ocurrences -- of the pattern @sep@ in a text stream. Separate the stream into sections: -- -- * sections which can parsed by the pattern @sep@ will be captured as -- matching sections in 'Right' -- * non-matching sections of the stream will be captured in 'Left'. -- -- This parser will always consume its entire input and can never fail. -- If there are no pattern matches, then the entire input stream will be -- returned as a non-matching 'Left' section. -- -- The pattern matching parser @sep@ will not be allowed to succeed without -- consuming any input. If we allow the parser to match a zero-width pattern, -- then it can match the same zero-width pattern again at the same position -- on the next iteration, which would result in an infinite number of -- overlapping pattern matches. So, for example, the -- pattern @many digitChar@, which can match zero occurences of a digit, -- will be treated by @sepCap@ as @some digitChar@, and required to match -- at least one digit. -- -- This @sepCap@ parser combinator is the basis for all of the other -- features of this module. It is similar to the @sep*@ family of functions -- found in -- <http://hackage.haskell.org/package/parser-combinators/docs/Control-Monad-Combinators.html parser-combinators> -- and -- <http://hackage.haskell.org/package/parsers/docs/Text-Parser-Combinators.html parsers> -- but, importantly, it returns the parsed result of the @sep@ parser instead -- of throwing it away. -- sepCap :: forall e s m a. (MonadParsec e s m) => m a -- ^ The pattern matching parser @sep@ -> m [Either (Tokens s) a] sepCap sep = (fmap.fmap) (first $ tokensToChunk (Proxy::Proxy s)) $ fmap sequenceLeft $ many $ fmap Right (try $ consumeSome sep) <|> fmap Left anySingle where sequenceLeft :: [Either l r] -> [Either [l] r] sequenceLeft = foldr consLeft [] where consLeft :: Either l r -> [Either [l] r] -> [Either [l] r] consLeft (Left l) ((Left ls):xs) = (Left (l:ls)):xs consLeft (Left l) xs = (Left [l]):xs consLeft (Right r) xs = (Right r):xs -- If sep succeeds and consumes 0 input tokens, we must force it to fail, -- otherwise infinite loop consumeSome p = do offset1 <- getOffset x <- p offset2 <- getOffset when (offset1 == offset2) empty return x -- | -- == Find all occurences, parse and capture pattern matches -- -- Parser combinator for finding all occurences of a pattern in a stream. -- -- Will call 'sepCap' with the 'Text.Megaparsec.match' combinator so that -- the text which matched the pattern parser @sep@ will be returned in -- the 'Right' sections, along with the result of the parse of @sep@. -- -- @ -- findAllCap sep = 'sepCap' ('Text.Megaparsec.match' sep) -- @ findAllCap :: MonadParsec e s m => m a -- ^ The pattern matching parser @sep@ -> m [Either (Tokens s) (Tokens s, a)] findAllCap sep = sepCap (match sep) -- | -- == Find all occurences -- -- Parser combinator for finding all occurences of a pattern in a stream. -- -- Will call 'sepCap' with the 'Text.Megaparsec.match' combinator and -- return the text which matched the pattern parser @sep@ in -- the 'Right' sections. -- -- @ -- findAll sep = (fmap.fmap) ('Data.Bifunctor.second' fst) $ 'sepCap' ('Text.Megaparsec.match' sep) -- @ findAll :: MonadParsec e s m => m a -- ^ The pattern matching parser @sep@ -> m [Either (Tokens s) (Tokens s)] findAll sep = (fmap.fmap) (second fst) $ sepCap (match sep) -- | -- == Stream editor -- -- Also can be considered “find-and-replace”. Finds all -- of the sections of the stream which match the pattern @sep@, and replaces -- them with the result of the @editor@ function. -- -- This function is not a “parser combinator,” it is -- a “way to run a parser”, like 'Text.Megaparsec.parse' -- or 'Text.Megaparsec.runParserT'. -- -- === Access the matched section of text in the editor -- -- If you want access to the matched string in the @editor@ function, -- then combine the pattern parser @sep@ with 'Text.Megaparsec.match', like -- -- @ -- let editor (matchString,parseResult) = return matchString -- in streamEditT ('Text.Megaparsec.match' sep) editor inputstring -- @ -- -- === Type constraints -- -- The type of the stream of text that is input must -- be @Stream s@ such that @Tokens s ~ s@, because we want -- to output the same type of stream that was input. That requirement is -- satisfied for all the 'Text.Megaparsec.Stream' instances included -- with "Text.Megaparsec": -- "Data.Text", -- "Data.Text.Lazy", -- "Data.Bytestring", -- "Data.Bytestring.Lazy", -- and "Data.String". -- -- We need the @Monoid s@ instance so that we can @mappend@ the output -- stream. -- -- We need @Typeable s@ and @Show s@ for 'Control.Exception.throw'. In theory -- this function should never throw an exception, because it only throws -- when the 'sepCap' parser fails, and the 'sepCap' parser -- can never fail. If this function ever throws, please report that as a bug. -- -- === Underlying monad context -- -- Both the parser @sep@ and the @editor@ function are run in the underlying -- monad context. -- -- If you want to do 'IO' operations in the @editor@ function or the -- parser @sep@, then run this in 'IO'. -- -- If you want the @editor@ function or the parser @sep@ to remember some state, -- then run this in a stateful monad. streamEditT :: forall s m a. (Stream s, Monad m, Monoid s, Tokens s ~ s, Show s, Show (Token s), Typeable s) => ParsecT Void s m a -- ^ The parser @sep@ for the pattern of interest. -> (a -> m s) -- ^ The @editor@ function. Takes a parsed result of @sep@ -- and returns a new stream section for the replacement. -> s -- ^ The input stream of text to be edited. -> m s streamEditT sep editor input = do runParserT (sepCap sep) "" input >>= \case (Left err) -> throw err -- sepCap can never fail, but if it does, throw (Right r) -> fmap fold $ traverse (either return editor) r -- | -- == Pure stream editor -- -- Pure version of 'streamEditT'. streamEdit :: forall s a. (Stream s, Monoid s, Tokens s ~ s, Show s, Show (Token s), Typeable s) => Parsec Void s a -- ^ The parser @sep@ for the pattern of interest. -> (a -> s) -- ^ The @editor@ function. Takes a parsed result of @sep@ -- and returns a new stream section for the replacement. -> s -- ^ The input stream of text to be edited. -> s streamEdit sep editor = runIdentity . streamEditT sep (Identity . editor)