{-# LANGUAGE RankNTypes, TypeFamilies, BangPatterns, Trustworthy #-} module Pipes.Text ( -- * Effectful Text -- $intro -- * Lenses -- $lenses -- ** @view@ \/ @(^.)@ -- $view -- ** @over@ \/ @(%~)@ -- $over -- ** @zoom@ -- $zoom -- * Special types: @Producer Text m (Producer Text m r)@ and @FreeT (Producer Text m) m r@ -- $special -- * Producers fromLazy -- * Pipes , map , concatMap , take , drop , takeWhile , dropWhile , filter , scan , pack , unpack , toCaseFold , toLower , toUpper , stripStart -- * Folds , toLazy , toLazyM , foldChars , head , last , null , length , any , all , maximum , minimum , find , index , count -- * Primitive Character Parsers , nextChar , drawChar , unDrawChar , peekChar , isEndOfChars -- * Parsing Lenses , splitAt , span , break , groupBy , group , word , line -- * FreeT Splitters , chunksOf , splitsWith , splits , groupsBy , groups , lines , words -- * Transformations , intersperse , packChars -- * Joiners , intercalate , unlines , unwords -- * Re-exports -- $reexports , module Data.ByteString , module Data.Text , module Data.Profunctor , module Pipes.Parse , module Pipes.Group ) where import Control.Applicative ((<*)) import Control.Monad (liftM, join) import Control.Monad.Trans.State.Strict (StateT(..), modify) import qualified Data.Text as T import Data.Text (Text) import qualified Data.Text.Lazy as TL import Data.ByteString (ByteString) import Data.Functor.Constant (Constant(Constant, getConstant)) import Data.Functor.Identity (Identity) import Data.Profunctor (Profunctor) import qualified Data.Profunctor import Pipes import Pipes.Group (concats, intercalates, FreeT(..), FreeF(..)) import qualified Pipes.Group as PG import qualified Pipes.Parse as PP import Pipes.Parse (Parser) import Pipes.Text.Encoding (Lens'_, Iso'_) import qualified Pipes.Prelude as P import Data.Char (isSpace) import Data.Word (Word8) import Foreign.Storable (sizeOf) import Data.Bits (shiftL) import Prelude hiding ( all, any, break, concat, concatMap, drop, dropWhile, elem, filter, head, last, lines, length, map, maximum, minimum, notElem, null, readFile, span, splitAt, take, takeWhile, unlines, unwords, words, writeFile ) {- $intro This package provides @pipes@ utilities for /text streams/ or /character streams/, realized as streams of 'Text' chunks. The individual chunks are uniformly /strict/, and thus you will generally want @Data.Text@ in scope. But the type @Producer Text m r@ ,as we are using it, is a sort of /pipes/ equivalent of the lazy @Text@ type. This particular module provides many functions equivalent in one way or another to the pure functions in <https://hackage.haskell.org/package/text-1.1.0.0/docs/Data-Text-Lazy.html Data.Text.Lazy>. They transform, divide, group and fold text streams. Though @Producer Text m r@ is the type of \'effectful Text\', the functions in this module are \'pure\' in the sense that they are uniformly monad-independent. Simple /IO/ operations are defined in @Pipes.Text.IO@ -- as lazy IO @Text@ operations are in @Data.Text.Lazy.IO@. Inter-operation with @ByteString@ is provided in @Pipes.Text.Encoding@, which parallels @Data.Text.Lazy.Encoding@. The Text type exported by @Data.Text.Lazy@ is basically that of a lazy list of strict Text: the implementation is arranged so that the individual strict 'Text' chunks are kept to a reasonable size; the user is not aware of the divisions between the connected 'Text' chunks. So also here: the functions in this module are designed to operate on streams that are insensitive to text boundaries. This means that they may freely split text into smaller texts and /discard empty texts/. The objective, though, is that they should /never concatenate texts/ in order to provide strict upper bounds on memory usage. For example, to stream only the first three lines of 'stdin' to 'stdout' you might write: > import Pipes > import qualified Pipes.Text as Text > import qualified Pipes.Text.IO as Text > import Pipes.Group (takes') > import Lens.Family > > main = runEffect $ takeLines 3 Text.stdin >-> Text.stdout > where > takeLines n = Text.unlines . takes' n . view Text.lines The above program will never bring more than one chunk of text (~ 32 KB) into memory, no matter how long the lines are. -} {- $lenses As this example shows, one superficial difference from @Data.Text.Lazy@ is that many of the operations, like 'lines', are \'lensified\'; this has a number of advantages (where it is possible); in particular it facilitates their use with 'Parser's of Text (in the general <http://hackage.haskell.org/package/pipes-parse-3.0.1/docs/Pipes-Parse-Tutorial.html pipes-parse> sense.) The disadvantage, famously, is that the messages you get for type errors can be a little alarming. The remarks that follow in this section are for non-lens adepts. Each lens exported here, e.g. 'lines', 'chunksOf' or 'splitAt', reduces to the intuitively corresponding function when used with @view@ or @(^.)@. Instead of writing: > splitAt 17 producer as we would with the Prelude or Text functions, we write > view (splitAt 17) producer or equivalently > producer ^. splitAt 17 This may seem a little indirect, but note that many equivalents of @Text -> Text@ functions are exported here as 'Pipe's. Here too we recover the intuitively corresponding functions by prefixing them with @(>->)@. Thus something like > stripLines = Text.unlines . Group.maps (>-> Text.stripStart) . view Text.lines would drop the leading white space from each line. The lenses in this library are marked as /improper/; this just means that they don't admit all the operations of an ideal lens, but only /getting/ and /focusing/. Just for this reason, though, the magnificent complexities of the lens libraries are a distraction. The lens combinators to keep in mind, the ones that make sense for our lenses, are @view@ \/ @(^.)@), @over@ \/ @(%~)@ , and @zoom@. One need only keep in mind that if @l@ is a @Lens'_ a b@, then: -} {- $view @view l@ is a function @a -> b@ . Thus @view l a@ (also written @a ^. l@ ) is the corresponding @b@; as was said above, this function will be exactly the function you think it is, given its name. Thus to uppercase the first n characters of a Producer, leaving the rest the same, we could write: > upper n p = do p' <- p ^. Text.splitAt n >-> Text.toUpper > p' -} {- $over @over l@ is a function @(b -> b) -> a -> a@. Thus, given a function that modifies @b@s, the lens lets us modify an @a@ by applying @f :: b -> b@ to the @b@ that we can \"see\" through the lens. So @over l f :: a -> a@ (it can also be written @l %~ f@). For any particular @a@, then, @over l f a@ or @(l %~ f) a@ is a revised @a@. So above we might have written things like these: > stripLines = Text.lines %~ maps (>-> Text.stripStart) > stripLines = over Text.lines (maps (>-> Text.stripStart)) > upper n = Text.splitAt n %~ (>-> Text.toUpper) -} {- $zoom @zoom l@, finally, is a function from a @Parser b m r@ to a @Parser a m r@ (or more generally a @StateT (Producer b m x) m r@). Its use is easiest to see with an decoding lens like 'utf8', which \"sees\" a Text producer hidden inside a ByteString producer: @drawChar@ is a Text parser, returning a @Maybe Char@, @zoom utf8 drawChar@ is a /ByteString/ parser, returning a @Maybe Char@. @drawAll@ is a Parser that returns a list of everything produced from a Producer, leaving only the return value; it would usually be unreasonable to use it. But @zoom (splitAt 17) drawAll@ returns a list of Text chunks containing the first seventeen Chars, and returns the rest of the Text Producer for further parsing. Suppose that we want, inexplicably, to modify the casing of a Text Producer according to any instruction it might contain at the start. Then we might write something like this: > obey :: Monad m => Producer Text m b -> Producer Text m b > obey p = do (ts, p') <- lift $ runStateT (zoom (Text.splitAt 7) drawAll) p > let seven = T.concat ts > case T.toUpper seven of > "TOUPPER" -> p' >-> Text.toUpper > "TOLOWER" -> p' >-> Text.toLower > _ -> do yield seven > p' > >>> let doc = each ["toU","pperTh","is document.\n"] > >>> runEffect $ obey doc >-> Text.stdout > THIS DOCUMENT. The purpose of exporting lenses is the mental economy achieved with this three-way applicability. That one expression, e.g. @lines@ or @splitAt 17@ can have these three uses is no more surprising than that a pipe can act as a function modifying the output of a producer, namely by using @>->@ to its left: @producer >-> pipe@ -- but can /also/ modify the inputs to a consumer by using @>->@ to its right: @pipe >-> consumer@ The three functions, @view@ \/ @(^.)@, @over@ \/ @(%~)@ and @zoom@ are supplied by both <http://hackage.haskell.org/package/lens lens> and <http://hackage.haskell.org/package/lens-family lens-family> The use of 'zoom' is explained in <http://hackage.haskell.org/package/pipes-parse-3.0.1/docs/Pipes-Parse-Tutorial.html Pipes.Parse.Tutorial> and to some extent in the @Pipes.Text.Encoding@ module here. -} {- $special These simple 'lines' examples reveal a more important difference from @Data.Text.Lazy@ . This is in the types that are most closely associated with our central text type, @Producer Text m r@. In @Data.Text@ and @Data.Text.Lazy@ we find functions like > splitAt :: Int -> Text -> (Text, Text) > lines :: Text -> [Text] > chunksOf :: Int -> Text -> [Text] which relate a Text with a pair of Texts or a list of Texts. The corresponding functions here (taking account of \'lensification\') are > view . splitAt :: (Monad m, Integral n) => n -> Producer Text m r -> Producer Text m (Producer Text m r) > view lines :: Monad m => Producer Text m r -> FreeT (Producer Text m) m r > view . chunksOf :: (Monad m, Integral n) => n -> Producer Text m r -> FreeT (Producer Text m) m r Some of the types may be more readable if you imagine that we have introduced our own type synonyms > type Text m r = Producer T.Text m r > type Texts m r = FreeT (Producer T.Text m) m r Then we would think of the types above as > view . splitAt :: (Monad m, Integral n) => n -> Text m r -> Text m (Text m r) > view lines :: (Monad m) => Text m r -> Texts m r > view . chunksOf :: (Monad m, Integral n) => n -> Text m r -> Texts m r which brings one closer to the types of the similar functions in @Data.Text.Lazy@ In the type @Producer Text m (Producer Text m r)@ the second element of the \'pair\' of effectful Texts cannot simply be retrieved with something like 'snd'. This is an \'effectful\' pair, and one must work through the effects of the first element to arrive at the second Text stream, even if you are proposing to throw the Text in the first element away. Note that we use Control.Monad.join to fuse the pair back together, since it specializes to > join :: Monad m => Producer Text m (Producer m r) -> Producer m r The return type of 'lines', 'words', 'chunksOf' and the other /splitter/ functions, @FreeT (Producer m Text) m r@ -- our @Texts m r@ -- is the type of (effectful) lists of (effectful) texts. The type @([Text],r)@ might be seen to gather together things of the forms: > r > (Text,r) > (Text, (Text, r)) > (Text, (Text, (Text, r))) > (Text, (Text, (Text, (Text, r)))) > ... (We might also have identified the sum of those types with @Free ((,) Text) r@ -- or, more absurdly, @FreeT ((,) Text) Identity r@.) Similarly, our type @Texts m r@, or @FreeT (Text m) m r@ -- in fact called @FreeT (Producer Text m) m r@ here -- encompasses all the members of the sequence: > m r > Text m r > Text m (Text m r) > Text m (Text m (Text m r)) > Text m (Text m (Text m (Text m r))) > ... We might have used a more specialized type in place of @FreeT (Producer a m) m r@, or indeed of @FreeT (Producer Text m) m r@, but it is clear that the correct result type of 'lines' will be isomorphic to @FreeT (Producer Text m) m r@ . One might think that > lines :: Monad m => Lens'_ (Producer Text m r) (FreeT (Producer Text m) m r) > view . lines :: Monad m => Producer Text m r -> FreeT (Producer Text m) m r should really have the type > lines :: Monad m => Pipe Text Text m r as e.g. 'toUpper' does. But this would spoil the control we are attempting to maintain over the size of chunks. It is in fact just as unreasonable to want such a pipe as to want > Data.Text.Lazy.lines :: Text -> Text to 'rechunk' the strict Text chunks inside the lazy Text to respect line boundaries. In fact we have > Data.Text.Lazy.lines :: Text -> [Text] > Prelude.lines :: String -> [String] where the elements of the list are themselves lazy Texts or Strings; the use of @FreeT (Producer Text m) m r@ is simply the 'effectful' version of this. The @Pipes.Group@ module, which can generally be imported without qualification, provides many functions for working with things of type @FreeT (Producer a m) m r@. In particular it conveniently exports the constructors for @FreeT@ and the associated @FreeF@ type -- a fancy form of @Either@, namely > data FreeF f a b = Pure a | Free (f b) for pattern-matching. Consider the implementation of the 'words' function, or of the part of the lens that takes us to the words; it is compact but exhibits many of the points under discussion, including explicit handling of the @FreeT@ and @FreeF@ constuctors. Keep in mind that > newtype FreeT f m a = FreeT (m (FreeF f a (FreeT f m a))) > next :: Monad m => Producer a m r -> m (Either r (a, Producer a m r)) Thus the @do@ block after the @FreeT@ constructor is in the base monad, e.g. 'IO' or 'Identity'; the later subordinate block, opened by the @Free@ constructor, is in the @Producer@ monad: > words :: Monad m => Producer Text m r -> FreeT (Producer Text m) m r > words p = FreeT $ do -- With 'next' we will inspect p's first chunk, excluding spaces; > x <- next (p >-> dropWhile isSpace) -- note that 'dropWhile isSpace' is a pipe, and is thus *applied* with '>->'. > return $ case x of -- We use 'return' and so need something of type 'FreeF (Text m) r (Texts m r)' > Left r -> Pure r -- 'Left' means we got no Text chunk, but only the return value; so we are done. > Right (txt, p') -> Free $ do -- If we get a chunk and the rest of the producer, p', we enter the 'Producer' monad > p'' <- view (break isSpace) -- When we apply 'break isSpace', we get a Producer that returns a Producer; > (yield txt >> p') -- so here we yield everything up to the next space, and get the rest back. > return (words p'') -- We then carry on with the rest, which is likely to begin with space. -} -- | Convert a lazy 'TL.Text' into a 'Producer' of strict 'Text's fromLazy :: (Monad m) => TL.Text -> Producer' Text m () fromLazy = TL.foldrChunks (\e a -> yield e >> a) (return ()) {-# INLINE fromLazy #-} (^.) :: a -> ((b -> Constant b b) -> (a -> Constant b a)) -> b a ^. lens = getConstant (lens Constant a) -- | Apply a transformation to each 'Char' in the stream map :: (Monad m) => (Char -> Char) -> Pipe Text Text m r map f = P.map (T.map f) {-# INLINABLE map #-} {-# RULES "p >-> map f" forall p f . p >-> map f = for p (\txt -> yield (T.map f txt)) #-} -- | Map a function over the characters of a text stream and concatenate the results concatMap :: (Monad m) => (Char -> Text) -> Pipe Text Text m r concatMap f = P.map (T.concatMap f) {-# INLINABLE concatMap #-} {-# RULES "p >-> concatMap f" forall p f . p >-> concatMap f = for p (\txt -> yield (T.concatMap f txt)) #-} -- | Transform a Pipe of 'String's into one of 'Text' chunks pack :: Monad m => Pipe String Text m r pack = P.map T.pack {-# INLINEABLE pack #-} {-# RULES "p >-> pack" forall p . p >-> pack = for p (\txt -> yield (T.pack txt)) #-} -- | Transform a Pipes of 'Text' chunks into one of 'String's unpack :: Monad m => Pipe Text String m r unpack = for cat (\t -> yield (T.unpack t)) {-# INLINEABLE unpack #-} {-# RULES "p >-> unpack" forall p . p >-> unpack = for p (\txt -> yield (T.unpack txt)) #-} -- | @toCaseFold@, @toLower@, @toUpper@ and @stripStart@ are standard 'Text' utilities, -- here acting as 'Text' pipes, rather as they would on a lazy text toCaseFold :: Monad m => Pipe Text Text m r toCaseFold = P.map T.toCaseFold {-# INLINEABLE toCaseFold #-} {-# RULES "p >-> toCaseFold" forall p . p >-> toCaseFold = for p (\txt -> yield (T.toCaseFold txt)) #-} -- | lowercase incoming 'Text' toLower :: Monad m => Pipe Text Text m r toLower = P.map T.toLower {-# INLINEABLE toLower #-} {-# RULES "p >-> toLower" forall p . p >-> toLower = for p (\txt -> yield (T.toLower txt)) #-} -- | uppercase incoming 'Text' toUpper :: Monad m => Pipe Text Text m r toUpper = P.map T.toUpper {-# INLINEABLE toUpper #-} {-# RULES "p >-> toUpper" forall p . p >-> toUpper = for p (\txt -> yield (T.toUpper txt)) #-} -- | Remove leading white space from an incoming succession of 'Text's stripStart :: Monad m => Pipe Text Text m r stripStart = do chunk <- await let text = T.stripStart chunk if T.null text then stripStart else do yield text cat {-# INLINEABLE stripStart #-} -- | @(take n)@ only allows @n@ individual characters to pass; -- contrast @Pipes.Prelude.take@ which would let @n@ chunks pass. take :: (Monad m, Integral a) => a -> Pipe Text Text m () take n0 = go n0 where go n | n <= 0 = return () | otherwise = do txt <- await let len = fromIntegral (T.length txt) if (len > n) then yield (T.take (fromIntegral n) txt) else do yield txt go (n - len) {-# INLINABLE take #-} -- | @(drop n)@ drops the first @n@ characters drop :: (Monad m, Integral a) => a -> Pipe Text Text m r drop n0 = go n0 where go n | n <= 0 = cat | otherwise = do txt <- await let len = fromIntegral (T.length txt) if (len >= n) then do yield (T.drop (fromIntegral n) txt) cat else go (n - len) {-# INLINABLE drop #-} -- | Take characters until they fail the predicate takeWhile :: (Monad m) => (Char -> Bool) -> Pipe Text Text m () takeWhile predicate = go where go = do txt <- await let (prefix, suffix) = T.span predicate txt if (T.null suffix) then do yield txt go else yield prefix {-# INLINABLE takeWhile #-} -- | Drop characters until they fail the predicate dropWhile :: (Monad m) => (Char -> Bool) -> Pipe Text Text m r dropWhile predicate = go where go = do txt <- await case T.findIndex (not . predicate) txt of Nothing -> go Just i -> do yield (T.drop i txt) cat {-# INLINABLE dropWhile #-} -- | Only allows 'Char's to pass if they satisfy the predicate filter :: (Monad m) => (Char -> Bool) -> Pipe Text Text m r filter predicate = P.map (T.filter predicate) {-# INLINABLE filter #-} {-# RULES "p >-> filter q" forall p q . p >-> filter q = for p (\txt -> yield (T.filter q txt)) #-} -- | Strict left scan over the characters scan :: (Monad m) => (Char -> Char -> Char) -> Char -> Pipe Text Text m r scan step begin = do yield (T.singleton begin) go begin where go c = do txt <- await let txt' = T.scanl step c txt c' = T.last txt' yield (T.tail txt') go c' {-# INLINABLE scan #-} {-| Fold a pure 'Producer' of strict 'Text's into a lazy 'TL.Text' -} toLazy :: Producer Text Identity () -> TL.Text toLazy = TL.fromChunks . P.toList {-# INLINABLE toLazy #-} {-| Fold an effectful 'Producer' of strict 'Text's into a lazy 'TL.Text' Note: 'toLazyM' is not an idiomatic use of @pipes@, but I provide it for simple testing purposes. Idiomatic @pipes@ style consumes the chunks immediately as they are generated instead of loading them all into memory. -} toLazyM :: (Monad m) => Producer Text m () -> m TL.Text toLazyM = liftM TL.fromChunks . P.toListM {-# INLINABLE toLazyM #-} -- | Reduce the text stream using a strict left fold over characters foldChars :: Monad m => (x -> Char -> x) -> x -> (x -> r) -> Producer Text m () -> m r foldChars step begin done = P.fold (T.foldl' step) begin done {-# INLINABLE foldChars #-} -- | Retrieve the first 'Char' head :: (Monad m) => Producer Text m () -> m (Maybe Char) head = go where go p = do x <- nextChar p case x of Left _ -> return Nothing Right (c, _) -> return (Just c) {-# INLINABLE head #-} -- | Retrieve the last 'Char' last :: (Monad m) => Producer Text m () -> m (Maybe Char) last = go Nothing where go r p = do x <- next p case x of Left () -> return r Right (txt, p') -> if (T.null txt) then go r p' else go (Just $ T.last txt) p' {-# INLINABLE last #-} -- | Determine if the stream is empty null :: (Monad m) => Producer Text m () -> m Bool null = P.all T.null {-# INLINABLE null #-} -- | Count the number of characters in the stream length :: (Monad m, Num n) => Producer Text m () -> m n length = P.fold (\n txt -> n + fromIntegral (T.length txt)) 0 id {-# INLINABLE length #-} -- | Fold that returns whether 'M.Any' received 'Char's satisfy the predicate any :: (Monad m) => (Char -> Bool) -> Producer Text m () -> m Bool any predicate = P.any (T.any predicate) {-# INLINABLE any #-} -- | Fold that returns whether 'M.All' received 'Char's satisfy the predicate all :: (Monad m) => (Char -> Bool) -> Producer Text m () -> m Bool all predicate = P.all (T.all predicate) {-# INLINABLE all #-} -- | Return the maximum 'Char' within a text stream maximum :: (Monad m) => Producer Text m () -> m (Maybe Char) maximum = P.fold step Nothing id where step mc txt = if (T.null txt) then mc else Just $ case mc of Nothing -> T.maximum txt Just c -> max c (T.maximum txt) {-# INLINABLE maximum #-} -- | Return the minimum 'Char' within a text stream (surely very useful!) minimum :: (Monad m) => Producer Text m () -> m (Maybe Char) minimum = P.fold step Nothing id where step mc txt = if (T.null txt) then mc else case mc of Nothing -> Just (T.minimum txt) Just c -> Just (min c (T.minimum txt)) {-# INLINABLE minimum #-} -- | Find the first element in the stream that matches the predicate find :: (Monad m) => (Char -> Bool) -> Producer Text m () -> m (Maybe Char) find predicate p = head (p >-> filter predicate) {-# INLINABLE find #-} -- | Index into a text stream index :: (Monad m, Integral a) => a-> Producer Text m () -> m (Maybe Char) index n p = head (p >-> drop n) {-# INLINABLE index #-} -- | Store a tally of how many segments match the given 'Text' count :: (Monad m, Num n) => Text -> Producer Text m () -> m n count c p = P.fold (+) 0 id (p >-> P.map (fromIntegral . T.count c)) {-# INLINABLE count #-} -- | Consume the first character from a stream of 'Text' -- -- 'next' either fails with a 'Left' if the 'Producer' has no more characters or -- succeeds with a 'Right' providing the next character and the remainder of the -- 'Producer'. nextChar :: (Monad m) => Producer Text m r -> m (Either r (Char, Producer Text m r)) nextChar = go where go p = do x <- next p case x of Left r -> return (Left r) Right (txt, p') -> case (T.uncons txt) of Nothing -> go p' Just (c, txt') -> return (Right (c, yield txt' >> p')) {-# INLINABLE nextChar #-} -- | Draw one 'Char' from a stream of 'Text', returning 'Left' if the 'Producer' is empty drawChar :: (Monad m) => Parser Text m (Maybe Char) drawChar = do x <- PP.draw case x of Nothing -> return Nothing Just txt -> case (T.uncons txt) of Nothing -> drawChar Just (c, txt') -> do PP.unDraw txt' return (Just c) {-# INLINABLE drawChar #-} -- | Push back a 'Char' onto the underlying 'Producer' unDrawChar :: (Monad m) => Char -> Parser Text m () unDrawChar c = modify (yield (T.singleton c) >>) {-# INLINABLE unDrawChar #-} {-| 'peekChar' checks the first 'Char' in the stream, but uses 'unDrawChar' to push the 'Char' back > peekChar = do > x <- drawChar > case x of > Left _ -> return () > Right c -> unDrawChar c > return x -} peekChar :: (Monad m) => Parser Text m (Maybe Char) peekChar = do x <- drawChar case x of Nothing -> return () Just c -> unDrawChar c return x {-# INLINABLE peekChar #-} {-| Check if the underlying 'Producer' has no more characters Note that this will skip over empty 'Text' chunks, unlike 'PP.isEndOfInput' from @pipes-parse@, which would consider an empty 'Text' a valid bit of input. > isEndOfChars = liftM isLeft peekChar -} isEndOfChars :: (Monad m) => Parser Text m Bool isEndOfChars = do x <- peekChar return (case x of Nothing -> True Just _-> False ) {-# INLINABLE isEndOfChars #-} -- | Splits a 'Producer' after the given number of characters splitAt :: (Monad m, Integral n) => n -> Lens'_ (Producer Text m r) (Producer Text m (Producer Text m r)) splitAt n0 k p0 = fmap join (k (go n0 p0)) where go 0 p = return p go n p = do x <- lift (next p) case x of Left r -> return (return r) Right (txt, p') -> do let len = fromIntegral (T.length txt) if (len <= n) then do yield txt go (n - len) p' else do let (prefix, suffix) = T.splitAt (fromIntegral n) txt yield prefix return (yield suffix >> p') {-# INLINABLE splitAt #-} -- | Split a text stream in two, producing the longest -- consecutive group of characters that satisfies the predicate -- and returning the rest span :: (Monad m) => (Char -> Bool) -> Lens'_ (Producer Text m r) (Producer Text m (Producer Text m r)) span predicate k p0 = fmap join (k (go p0)) where go p = do x <- lift (next p) case x of Left r -> return (return r) Right (txt, p') -> do let (prefix, suffix) = T.span predicate txt if (T.null suffix) then do yield txt go p' else do yield prefix return (yield suffix >> p') {-# INLINABLE span #-} {-| Split a text stream in two, producing the longest consecutive group of characters that don't satisfy the predicate -} break :: (Monad m) => (Char -> Bool) -> Lens'_ (Producer Text m r) (Producer Text m (Producer Text m r)) break predicate = span (not . predicate) {-# INLINABLE break #-} {-| Improper lens that splits after the first group of equivalent Chars, as defined by the given equivalence relation -} groupBy :: (Monad m) => (Char -> Char -> Bool) -> Lens'_ (Producer Text m r) (Producer Text m (Producer Text m r)) groupBy equals k p0 = fmap join (k ((go p0))) where go p = do x <- lift (next p) case x of Left r -> return (return r) Right (txt, p') -> case T.uncons txt of Nothing -> go p' Just (c, _) -> (yield txt >> p') ^. span (equals c) {-# INLINABLE groupBy #-} -- | Improper lens that splits after the first succession of identical 'Char' s group :: Monad m => Lens'_ (Producer Text m r) (Producer Text m (Producer Text m r)) group = groupBy (==) {-# INLINABLE group #-} {-| Improper lens that splits a 'Producer' after the first word Unlike 'words', this does not drop leading whitespace -} word :: (Monad m) => Lens'_ (Producer Text m r) (Producer Text m (Producer Text m r)) word k p0 = fmap join (k (to p0)) where to p = do p' <- p^.span isSpace p'^.break isSpace {-# INLINABLE word #-} line :: (Monad m) => Lens'_ (Producer Text m r) (Producer Text m (Producer Text m r)) line = break (== '\n') {-# INLINABLE line #-} -- | Intersperse a 'Char' in between the characters of stream of 'Text' intersperse :: (Monad m) => Char -> Producer Text m r -> Producer Text m r intersperse c = go0 where go0 p = do x <- lift (next p) case x of Left r -> return r Right (txt, p') -> do yield (T.intersperse c txt) go1 p' go1 p = do x <- lift (next p) case x of Left r -> return r Right (txt, p') -> do yield (T.singleton c) yield (T.intersperse c txt) go1 p' {-# INLINABLE intersperse #-} -- | Improper isomorphism between a 'Producer' of 'ByteString's and 'Word8's packChars :: Monad m => Iso'_ (Producer Char m x) (Producer Text m x) packChars = Data.Profunctor.dimap to (fmap from) where -- to :: Monad m => Producer Char m x -> Producer Text m x to p = PG.folds step id done (p^.PG.chunksOf defaultChunkSize) step diffAs c = diffAs . (c:) done diffAs = T.pack (diffAs []) -- from :: Monad m => Producer Text m x -> Producer Char m x from p = for p (each . T.unpack) {-# INLINABLE packChars #-} defaultChunkSize :: Int defaultChunkSize = 16384 - (sizeOf (undefined :: Int) `shiftL` 1) -- | Split a text stream into 'FreeT'-delimited text streams of fixed size chunksOf :: (Monad m, Integral n) => n -> Lens'_ (Producer Text m r) (FreeT (Producer Text m) m r) chunksOf n k p0 = fmap concats (k (FreeT (go p0))) where go p = do x <- next p return $ case x of Left r -> Pure r Right (txt, p') -> Free $ do p'' <- (yield txt >> p') ^. splitAt n return $ FreeT (go p'') {-# INLINABLE chunksOf #-} {-| Split a text stream into sub-streams delimited by characters that satisfy the predicate -} splitsWith :: (Monad m) => (Char -> Bool) -> Producer Text m r -> FreeT (Producer Text m) m r splitsWith predicate p0 = FreeT (go0 p0) where go0 p = do x <- next p case x of Left r -> return (Pure r) Right (txt, p') -> if (T.null txt) then go0 p' else return $ Free $ do p'' <- (yield txt >> p') ^. span (not . predicate) return $ FreeT (go1 p'') go1 p = do x <- nextChar p return $ case x of Left r -> Pure r Right (_, p') -> Free $ do p'' <- p' ^. span (not . predicate) return $ FreeT (go1 p'') {-# INLINABLE splitsWith #-} -- | Split a text stream using the given 'Char' as the delimiter splits :: (Monad m) => Char -> Lens'_ (Producer Text m r) (FreeT (Producer Text m) m r) splits c k p = fmap (PG.intercalates (yield (T.singleton c))) (k (splitsWith (c ==) p)) {-# INLINABLE splits #-} {-| Isomorphism between a stream of 'Text' and groups of equivalent 'Char's , using the given equivalence relation -} groupsBy :: Monad m => (Char -> Char -> Bool) -> Lens'_ (Producer Text m x) (FreeT (Producer Text m) m x) groupsBy equals k p0 = fmap concats (k (FreeT (go p0))) where go p = do x <- next p case x of Left r -> return (Pure r) Right (bs, p') -> case T.uncons bs of Nothing -> go p' Just (c, _) -> do return $ Free $ do p'' <- (yield bs >> p')^.span (equals c) return $ FreeT (go p'') {-# INLINABLE groupsBy #-} -- | Like 'groupsBy', where the equality predicate is ('==') groups :: Monad m => Lens'_ (Producer Text m x) (FreeT (Producer Text m) m x) groups = groupsBy (==) {-# INLINABLE groups #-} {-| Split a text stream into 'FreeT'-delimited lines -} lines :: (Monad m) => Iso'_ (Producer Text m r) (FreeT (Producer Text m) m r) lines = Data.Profunctor.dimap _lines (fmap _unlines) where _lines p0 = FreeT (go0 p0) where go0 p = do x <- next p case x of Left r -> return (Pure r) Right (txt, p') -> if (T.null txt) then go0 p' else return $ Free $ go1 (yield txt >> p') go1 p = do p' <- p ^. break ('\n' ==) return $ FreeT $ do x <- nextChar p' case x of Left r -> return $ Pure r Right (_, p'') -> go0 p'' -- _unlines -- :: Monad m -- => FreeT (Producer Text m) m x -> Producer Text m x _unlines = concats . PG.maps (<* yield (T.singleton '\n')) {-# INLINABLE lines #-} -- | Split a text stream into 'FreeT'-delimited words words :: (Monad m) => Iso'_ (Producer Text m r) (FreeT (Producer Text m) m r) words = Data.Profunctor.dimap go (fmap _unwords) where go p = FreeT $ do x <- next (p >-> dropWhile isSpace) return $ case x of Left r -> Pure r Right (bs, p') -> Free $ do p'' <- (yield bs >> p') ^. break isSpace return (go p'') _unwords = PG.intercalates (yield $ T.singleton ' ') {-# INLINABLE words #-} {-| 'intercalate' concatenates the 'FreeT'-delimited text streams after interspersing a text stream in between them -} intercalate :: (Monad m) => Producer Text m () -> FreeT (Producer Text m) m r -> Producer Text m r intercalate p0 = go0 where go0 f = do x <- lift (runFreeT f) case x of Pure r -> return r Free p -> do f' <- p go1 f' go1 f = do x <- lift (runFreeT f) case x of Pure r -> return r Free p -> do p0 f' <- p go1 f' {-# INLINABLE intercalate #-} {-| Join 'FreeT'-delimited lines into a text stream -} unlines :: (Monad m) => FreeT (Producer Text m) m r -> Producer Text m r unlines = go where go f = do x <- lift (runFreeT f) case x of Pure r -> return r Free p -> do f' <- p yield $ T.singleton '\n' go f' {-# INLINABLE unlines #-} {-| Join 'FreeT'-delimited words into a text stream -} unwords :: (Monad m) => FreeT (Producer Text m) m r -> Producer Text m r unwords = intercalate (yield $ T.singleton ' ') {-# INLINABLE unwords #-} {- $reexports @Data.Text@ re-exports the 'Text' type. @Pipes.Parse@ re-exports 'input', 'concat', 'FreeT' (the type) and the 'Parse' synonym. -}