{-# LANGUAGE TypeFamilies #-} {-# OPTIONS_GHC -fno-warn-orphans #-} module Text.Regex.Applicative.Interface where import Control.Applicative hiding (empty) import qualified Control.Applicative import Control.Arrow import Data.Traversable import Data.String import Data.Maybe import Text.Regex.Applicative.Types import Text.Regex.Applicative.Object instance Functor (RE s) where fmap f x = Fmap f x f <$ x = pure f <* x instance Applicative (RE s) where pure x = const x <$> Eps a1 <*> a2 = App a1 a2 a *> b = pure (const id) <*> Void a <*> b a <* b = pure const <*> a <*> Void b instance Alternative (RE s) where a1 <|> a2 = Alt a1 a2 empty = Eps many a = reverse <$> Rep Greedy (flip (:)) [] a some a = (:) <$> a <*> many a instance (char ~ Char, string ~ String) => IsString (RE char string) where fromString = string -- | Match and return a single symbol which satisfies the predicate psym :: (s -> Bool) -> RE s s psym p = Symbol (error "Not numbered symbol") p -- | Match and return the given symbol sym :: Eq s => s -> RE s s sym s = psym (s ==) -- | Match and return any single symbol anySym :: RE s s anySym = psym (const True) -- | Match and return the given sequence of symbols. -- -- Note that there is an 'IsString' instance for regular expression, so -- if you enable the @OverloadedStrings@ language extension, you can write -- @string \"foo\"@ simply as @\"foo\"@. -- -- Example: -- -- >{-# LANGUAGE OverloadedStrings #-} -- >import Text.Regex.Applicative -- > -- >number = "one" *> pure 1 <|> "two" *> pure 2 -- > -- >main = print $ "two" =~ number string :: Eq a => [a] -> RE a [a] string = traverse sym -- | Match zero or more instances of the given expression, which are combined using -- the given folding function. -- -- 'Greediness' argument controls whether this regular expression should match -- as many as possible ('Greedy') or as few as possible ('NonGreedy') instances -- of the underlying expression. reFoldl :: Greediness -> (b -> a -> b) -> b -> RE s a -> RE s b reFoldl g f b a = Rep g f b a -- | Match zero or more instances of the given expression, but as -- few of them as possible (i.e. /non-greedily/). A greedy equivalent of 'few' -- is 'many'. -- -- Examples: -- -- >Text.Regex.Applicative> findFirstPrefix (few anySym <* "b") "ababab" -- >Just ("a","abab") -- >Text.Regex.Applicative> findFirstPrefix (many anySym <* "b") "ababab" -- >Just ("ababa","") few :: RE s a -> RE s [a] few a = reverse <$> Rep NonGreedy (flip (:)) [] a -- | @s =~ a = match a s@ (=~) :: [s] -> RE s a -> Maybe a (=~) = flip match infix 2 =~ -- | Attempt to match a string of symbols against the regular expression. -- Note that the whole string (not just some part of it) should be matched. -- -- Examples: -- -- >Text.Regex.Applicative> match (sym 'a' <|> sym 'b') "a" -- >Just 'a' -- >Text.Regex.Applicative> match (sym 'a' <|> sym 'b') "ab" -- >Nothing -- match :: RE s a -> [s] -> Maybe a match re = let obj = compile re in \str -> listToMaybe $ results $ foldl (flip step) obj str -- | Find a string prefix which is matched by the regular expression. -- -- Of all matching prefixes, pick one using left bias (prefer the left part of -- '<|>' to the right part) and greediness. -- -- This is the match which a backtracking engine (such as Perl's one) would find -- first. -- -- If match is found, the rest of the input is also returned. -- -- Examples: -- -- >Text.Regex.Applicative> findFirstPrefix ("a" <|> "ab") "abc" -- >Just ("a","bc") -- >Text.Regex.Applicative> findFirstPrefix ("ab" <|> "a") "abc" -- >Just ("ab","c") -- >Text.Regex.Applicative> findFirstPrefix "bc" "abc" -- >Nothing findFirstPrefix :: RE s a -> [s] -> Maybe (a, [s]) findFirstPrefix re str = go (compile re) str Nothing where walk obj [] = (obj, Nothing) walk obj (t:ts) = case getResult t of Just r -> (obj, Just r) Nothing -> walk (addThread t obj) ts go obj str resOld = case walk emptyObject $ threads obj of (obj', resThis) -> let res = ((flip (,) str) <$> resThis) <|> resOld in case str of [] -> res _ | failed obj' -> res (s:ss) -> go (step s obj') ss res -- | Find the longest string prefix which is matched by the regular expression. -- -- Submatches are still determined using left bias and greediness, so this is -- different from POSIX semantics. -- -- If match is found, the rest of the input is also returned. -- -- Examples: -- -- >Text.Regex.Applicative Data.Char> let keyword = "if" -- >Text.Regex.Applicative Data.Char> let identifier = many $ psym isAlpha -- >Text.Regex.Applicative Data.Char> let lexeme = (Left <$> keyword) <|> (Right <$> identifier) -- >Text.Regex.Applicative Data.Char> findLongestPrefix lexeme "if foo" -- >Just (Left "if"," foo") -- >Text.Regex.Applicative Data.Char> findLongestPrefix lexeme "iffoo" -- >Just (Right "iffoo","") findLongestPrefix :: RE s a -> [s] -> Maybe (a, [s]) findLongestPrefix re str = go (compile re) str Nothing where go obj str resOld = let res = (fmap (flip (,) str) $ listToMaybe $ results obj) <|> resOld in case str of [] -> res _ | failed obj -> res (s:ss) -> go (step s obj) ss res -- | Find the shortest prefix (analogous to 'findLongestPrefix') findShortestPrefix :: RE s a -> [s] -> Maybe (a, [s]) findShortestPrefix re str = go (compile re) str where go obj str = case results obj of r : _ -> Just (r, str) [] -> case str of [] -> Nothing _ | failed obj -> Nothing s:ss -> go (step s obj) ss -- | Find the leftmost substring that is matched by the regular expression. -- Otherwise behaves like 'findFirstPrefix'. Returns the result together with -- the prefix and suffix of the string surrounding the match. findFirstInfix :: RE s a -> [s] -> Maybe ([s], a, [s]) findFirstInfix re str = fmap (\((first, res), last) -> (first, res, last)) $ findFirstPrefix ((,) <$> few anySym <*> re) str -- Auxiliary function for findExtremeInfix prefixCounter :: RE s (Int, [s]) prefixCounter = second reverse <$> reFoldl NonGreedy f (0, []) anySym where f (i, prefix) s = ((,) $! (i+1)) $ s:prefix data InfixMatchingState s a = GotResult { prefixLen :: !Int , prefixStr :: [s] , result :: a , postfixStr :: [s] } | NoResult -- a `preferOver` b chooses one of a and b, giving preference to a preferOver :: InfixMatchingState s a -> InfixMatchingState s a -> InfixMatchingState s a preferOver NoResult b = b preferOver b NoResult = b preferOver a b = case prefixLen a `compare` prefixLen b of GT -> b -- prefer b when it has smaller prefix _ -> a -- otherwise, prefer a mkInfixMatchingState :: [s] -- rest of input -> Thread s ((Int, [s]), a) -> InfixMatchingState s a mkInfixMatchingState rest thread = case getResult thread of Just ((pLen, pStr), res) -> GotResult { prefixLen = pLen , prefixStr = pStr , result = res , postfixStr = rest } Nothing -> NoResult gotResult :: InfixMatchingState s a -> Bool gotResult GotResult {} = True gotResult _ = False -- Algorithm for finding leftmost longest infix match: -- -- 1. Add a thread /.*?/ to the begginning of the regexp -- 2. As soon as we get first accept, we delete that thread -- 3. When we get more than one accept, we choose one by the following criteria: -- 3.1. Compare by the length of prefix (since we are looking for the leftmost -- match) -- 3.2. If they are produced on the same step, choose the first one (left-biased -- choice) -- 3.3. If they are produced on the different steps, choose the later one (since -- they have the same prefixes, later means longer) findExtremalInfix :: -- function to combine a later result (first arg) to an earlier one (second -- arg) (InfixMatchingState s a -> InfixMatchingState s a -> InfixMatchingState s a) -> RE s a -> [s] -> Maybe ([s], a, [s]) findExtremalInfix newOrOld re str = case go (compile $ (,) <$> prefixCounter <*> re) str NoResult of NoResult -> Nothing r@GotResult{} -> Just (prefixStr r, result r, postfixStr r) where {- go :: ReObject s ((Int, [s]), a) -> [s] -> InfixMatchingState s a -> InfixMatchingState s a -} go obj str resOld = let resThis = foldl (\acc t -> acc `preferOver` mkInfixMatchingState str t) NoResult $ threads obj res = resThis `newOrOld` resOld obj' = -- If we just found the first result, kill the "prefixCounter" thread. -- We rely on the fact that it is the last thread of the object. if gotResult resThis && not (gotResult resOld) then fromThreads $ init $ threads obj else obj in case str of [] -> res _ | failed obj -> res (s:ss) -> go (step s obj') ss res -- | Find the leftmost substring that is matched by the regular expression. -- Otherwise behaves like 'findLongestPrefix'. Returns the result together with -- the prefix and suffix of the string surrounding the match. findLongestInfix :: RE s a -> [s] -> Maybe ([s], a, [s]) findLongestInfix = findExtremalInfix preferOver -- | Find the leftmost substring that is matched by the regular expression. -- Otherwise behaves like 'findShortestPrefix'. Returns the result together with -- the prefix and suffix of the string surrounding the match. findShortestInfix :: RE s a -> [s] -> Maybe ([s], a, [s]) findShortestInfix = findExtremalInfix $ flip preferOver