{-# LANGUAGE PatternGuards #-} {-# LANGUAGE TypeFamilies #-} {-# LANGUAGE CPP #-} #if defined(__GLASGOW_HASKELL__) && __GLASGOW_HASKELL__ >= 702 {-# LANGUAGE Trustworthy #-} #endif ----------------------------------------------------------------------------- -- | -- Module : Data.Stream.Infinite -- Copyright : (C) 2011 Edward Kmett, -- (C) 2007-2010 Wouter Swierstra, Bas van Dijk -- License : BSD-style (see the file LICENSE) -- -- Maintainer : Edward Kmett <ekmett@gmail.com> -- Stability : provisional -- Portability : portable (Haskell 2010) -- ---------------------------------------------------------------------------- module Data.Stream.Infinite ( -- * The type of streams Stream(..) -- * Basic functions , tail -- :: Stream a -> Stream a , inits -- :: Stream a -> Stream [a] , prepend -- :: [a] -> Stream a -> Stream a , concat -- :: Stream [a] -> Stream a -- * Stream transformations , intersperse -- :: a -> Stream a -> Stream , interleave -- :: Stream a -> Stream a -> Stream a , scanl -- :: (b -> a -> b) -> b -> Stream a -> Stream b , scanl' -- :: (b -> a -> b) -> b -> Stream a -> Stream b , scanl1 -- :: (a -> a -> a) -> Stream a -> Stream a , scanl1' -- :: (a -> a -> a) -> Stream a -> Stream a , transpose -- :: Stream (Stream a) -> Stream (Stream a) -- * Building streams , iterate -- :: (a -> a) -> a -> Stream a , cycle -- :: NonEmpty a -> Stream a , unfold -- :: (a -> (b, a)) -> a -> Stream b -- * Extracting sublists , take -- :: Int -> Stream a -> [a] , drop -- :: Int -> Stream a -> Stream a , splitAt -- :: Int -> Stream a -> ([a],Stream a) , takeWhile -- :: (a -> Bool) -> Stream a -> [a] , dropWhile -- :: (a -> Bool) -> Stream a -> Stream a , span -- :: (a -> Bool) -> Stream a -> ([a], Stream a) , break -- :: (a -> Bool) -> Stream a -> ([a], Stream a) , filter -- :: (a -> Bool) -> Stream a -> Stream a , partition -- :: (a -> Bool) -> Stream a -> (Stream a, Stream a) , group -- :: (a -> Bool) -> Stream a -> Stream (NonEmpty a) , groupBy -- :: (a -> a -> Bool) -> Stream a -> Stream (NonEmpty a) -- * Sublist predicates , isPrefixOf -- :: [a] -> Stream a -> Bool -- * Indexing streams , (!!) -- :: Int -> Stream a -> a , elemIndex -- :: Eq a => a -> Stream a -> Int , elemIndices -- :: Eq a => a -> Stream a -> Stream Int , findIndex -- :: (a -> Bool) -> Stream a -> Int , findIndices -- :: (a -> Bool) -> Stream a -> Stream Int -- * Zipping and unzipping streams , zip -- :: Stream a -> Stream b -> Stream (a, b) , zipWith -- :: (a -> b -> c) -> Stream a -> Stream b -> Stream c , unzip -- :: Functor f => f (a, b) -> (f a, f b) -- * Functions on streams of characters , words -- :: Stream Char -> Stream String , unwords -- :: Stream String -> Stream Char , lines -- :: Stream Char -> Stream String , unlines -- :: Stream String -> Stream Char ) where import Prelude hiding ( tail, map, scanr, scanr1, scanl, scanl1 , iterate, take, drop, takeWhile , dropWhile, repeat, cycle, filter , (!!), zip, unzip, zipWith, words , unwords, lines, unlines, break, span , splitAt, foldr, concat ) #if !(MIN_VERSION_base(4,8,0)) import Control.Applicative #endif import Control.Comonad import Data.Char (isSpace) import Data.Data import Data.Functor.Apply import Data.Functor.Extend import Data.Functor.Rep #if !(MIN_VERSION_base(4,8,0)) import Data.Semigroup import Data.Traversable #endif import Data.Foldable hiding (concat) import Data.Distributive import Data.Semigroup.Traversable import Data.Semigroup.Foldable import Data.List.NonEmpty (NonEmpty(..)) data Stream a = a :> Stream a deriving ( Show #ifdef LANGUAGE_DeriveDataTypeable , Data, Typeable #endif ) infixr 5 :> instance Functor Stream where fmap f (a :> as) = f a :> fmap f as b <$ _ = pure b instance Distributive Stream where distribute w = fmap extract w :> distribute (fmap tail w) instance Representable Stream where type Rep Stream = Int tabulate f = unfold (\i -> (,) (f i) $! (i + 1)) 0 index (x :> xs) n | n == 0 = x | n > 0 = xs !! (n - 1) | otherwise = error "Stream.!! negative argument" -- | Extract the sequence following the head of the stream. tail :: Stream a -> Stream a tail (_ :> as) = as {-# INLINE tail #-} instance Extend Stream where duplicated = duplicate extended = extend instance Comonad Stream where duplicate w = w :> duplicate (tail w) extend f w = f w :> extend f (tail w) extract (a :> _) = a instance Apply Stream where (f :> fs) <.> (a :> as) = f a :> (fs <.> as) as <. _ = as _ .> bs = bs instance ComonadApply Stream where (f :> fs) <@> (a :> as) = f a :> (fs <@> as) as <@ _ = as _ @> bs = bs instance Applicative Stream where pure a = as where as = a :> as (<*>) = (<.>) (<* ) = (<. ) ( *>) = ( .>) instance Foldable Stream where fold (m :> ms) = m `mappend` fold ms foldMap f (a :> as) = f a `mappend` foldMap f as foldr f0 _ = go f0 where go f (a :> as) = f a (go f as) #if __GLASGOW_HASKELL__ > 710 length _ = error "infinite length" null _ = False #endif instance Traversable Stream where traverse f ~(a :> as) = (:>) <$> f a <*> traverse f as instance Foldable1 Stream instance Traversable1 Stream where traverse1 f ~(a :> as) = (:>) <$> f a <.> traverse1 f as sequence1 ~(a :> as) = (:>) <$> a <.> sequence1 as -- | The unfold function is similar to the unfold for lists. Note -- there is no base case: all streams must be infinite. unfold :: (a -> (b, a)) -> a -> Stream b unfold f c | (x, d) <- f c = x :> unfold f d instance Monad Stream where return = pure m >>= f = unfold (\(bs :> bss) -> (extract bs, tail <$> bss)) (fmap f m) _ >> bs = bs -- | Interleave two Streams @xs@ and @ys@, alternating elements -- from each list. -- -- > [x1,x2,...] `interleave` [y1,y2,...] == [x1,y1,x2,y2,...] interleave :: Stream a -> Stream a -> Stream a interleave ~(x :> xs) ys = x :> interleave ys xs -- | The 'inits' function takes a stream @xs@ and returns all the -- finite prefixes of @xs@. -- -- Note that this 'inits' is lazier then @Data.List.inits@: -- -- > inits _|_ = [] ::: _|_ -- -- while for @Data.List.inits@: -- -- > inits _|_ = _|_ inits :: Stream a -> Stream [a] inits xs = [] :> ((extract xs :) <$> inits (tail xs)) -- | Prepend a list to a stream. prepend :: Foldable f => f a -> Stream a -> Stream a prepend xs ys = foldr (:>) ys xs -- | Flatten a stream of lists into a stream. concat :: Foldable f => Stream (f a) -> Stream a concat = foldr prepend undefined -- | @'intersperse' y xs@ creates an alternating stream of -- elements from @xs@ and @y@. intersperse :: a -> Stream a -> Stream a intersperse y ~(x :> xs) = x :> y :> intersperse y xs -- | 'scanl' yields a stream of successive reduced values from: -- -- > scanl f z [x1, x2, ...] == [z, z `f` x1, (z `f` x1) `f` x2, ...] scanl :: (a -> b -> a) -> a -> Stream b -> Stream a scanl f z ~(x :> xs) = z :> scanl f (f z x) xs -- | 'scanl' yields a stream of successive reduced values from: -- -- > scanl f z [x1, x2, ...] == [z, z `f` x1, (z `f` x1) `f` x2, ...] scanl' :: (a -> b -> a) -> a -> Stream b -> Stream a scanl' f z ~(x :> xs) = z :> (scanl' f $! f z x) xs -- | 'scanl1' is a variant of 'scanl' that has no starting value argument: -- -- > scanl1 f [x1, x2, ...] == [x1, x1 `f` x2, ...] scanl1 :: (a -> a -> a) -> Stream a -> Stream a scanl1 f ~(x :> xs) = scanl f x xs -- | @scanl1'@ is a strict 'scanl' that has no starting value. scanl1' :: (a -> a -> a) -> Stream a -> Stream a scanl1' f ~(x :> xs) = scanl' f x xs -- | 'transpose' computes the transposition of a stream of streams. transpose :: Stream (Stream a) -> Stream (Stream a) transpose ~((x :> xs) :> yss) = (x :> (extract <$> yss)) :> transpose (xs :> (tail <$> yss)) -- | @'iterate' f x@ produces the infinite sequence -- of repeated applications of @f@ to @x@. -- -- > iterate f x = [x, f x, f (f x), ..] iterate :: (a -> a) -> a -> Stream a iterate f x = x :> iterate f (f x) -- | @'cycle' xs@ returns the infinite repetition of @xs@: -- -- > cycle [1,2,3] = Cons 1 (Cons 2 (Cons 3 (Cons 1 (Cons 2 ... cycle :: NonEmpty a -> Stream a cycle xs = ys where ys = foldr (:>) ys xs -- | @'take' n xs@ returns the first @n@ elements of @xs@. -- -- /Beware/: passing a negative integer as the first argument will -- cause an error. take :: Int -> Stream a -> [a] take n ~(x :> xs) | n == 0 = [] | n > 0 = x : take (n - 1) xs | otherwise = error "Stream.take: negative argument" -- | @'drop' n xs@ drops the first @n@ elements off the front of -- the sequence @xs@. -- -- /Beware/: passing a negative integer as the first argument will -- cause an error. drop :: Int -> Stream a -> Stream a drop n xs | n == 0 = xs | n > 0 = drop (n - 1) (tail xs) | otherwise = error "Stream.drop: negative argument" -- | @'splitAt' n xs@ returns a pair consisting of the prefix of -- @xs@ of length @n@ and the remaining stream immediately following -- this prefix. -- -- /Beware/: passing a negative integer as the first argument will -- cause an error. splitAt :: Int -> Stream a -> ([a],Stream a) splitAt n xs | n == 0 = ([],xs) | n > 0, (prefix, rest) <- splitAt (n - 1) (tail xs) = (extract xs : prefix, rest) | otherwise = error "Stream.splitAt: negative argument" -- | @'takeWhile' p xs@ returns the longest prefix of the stream -- @xs@ for which the predicate @p@ holds. takeWhile :: (a -> Bool) -> Stream a -> [a] takeWhile p (x :> xs) | p x = x : takeWhile p xs | otherwise = [] -- | @'dropWhile' p xs@ returns the suffix remaining after -- @'takeWhile' p xs@. -- -- /Beware/: this function may diverge if every element of @xs@ -- satisfies @p@, e.g. @dropWhile even (repeat 0)@ will loop. dropWhile :: (a -> Bool) -> Stream a -> Stream a dropWhile p ~(x :> xs) | p x = dropWhile p xs | otherwise = x :> xs -- | @'span' p xs@ returns the longest prefix of @xs@ that satisfies -- @p@, together with the remainder of the stream. span :: (a -> Bool) -> Stream a -> ([a], Stream a) span p xxs@(x :> xs) | p x, (ts, fs) <- span p xs = (x : ts, fs) | otherwise = ([], xxs) -- | The 'break' @p@ function is equivalent to 'span' @not . p@. break :: (a -> Bool) -> Stream a -> ([a], Stream a) break p = span (not . p) -- | @'filter' p xs@, removes any elements from @xs@ that do not satisfy @p@. -- -- /Beware/: this function may diverge if there is no element of -- @xs@ that satisfies @p@, e.g. @filter odd (repeat 0)@ will loop. filter :: (a -> Bool) -> Stream a -> Stream a filter p ~(x :> xs) | p x = x :> filter p xs | otherwise = filter p xs -- | The 'partition' function takes a predicate @p@ and a stream -- @xs@, and returns a pair of streams. The first stream corresponds -- to the elements of @xs@ for which @p@ holds; the second stream -- corresponds to the elements of @xs@ for which @p@ does not hold. -- -- /Beware/: One of the elements of the tuple may be undefined. For -- example, @fst (partition even (repeat 0)) == repeat 0@; on the -- other hand @snd (partition even (repeat 0))@ is undefined. partition :: (a -> Bool) -> Stream a -> (Stream a, Stream a) partition p ~(x :> xs) | p x = (x :> ts, fs) | otherwise = (ts, x :> fs) where (ts, fs) = partition p xs -- | The 'group' function takes a stream and returns a stream of -- lists such that flattening the resulting stream is equal to the -- argument. Moreover, each sublist in the resulting stream -- contains only equal elements. For example, -- -- > group $ cycle "Mississippi" = "M" ::: "i" ::: "ss" ::: "i" ::: "ss" ::: "i" ::: "pp" ::: "i" ::: "M" ::: "i" ::: ... group :: Eq a => Stream a -> Stream (NonEmpty a) group = groupBy (==) groupBy :: (a -> a -> Bool) -> Stream a -> Stream (NonEmpty a) groupBy eq ~(x :> ys) | (xs, zs) <- span (eq x) ys = (x :| xs) :> groupBy eq zs -- | The 'isPrefix' function returns @True@ if the first argument is -- a prefix of the second. isPrefixOf :: Eq a => [a] -> Stream a -> Bool isPrefixOf [] _ = True isPrefixOf (y:ys) (x :> xs) | y == x = isPrefixOf ys xs | otherwise = False -- | @xs !! n@ returns the element of the stream @xs@ at index -- @n@. Note that the head of the stream has index 0. -- -- /Beware/: passing a negative integer as the first argument will cause -- an error. (!!) :: Stream a -> Int -> a (!!) = index -- | The 'elemIndex' function returns the index of the first element -- in the given stream which is equal (by '==') to the query element, -- -- /Beware/: @'elemIndex' x xs@ will diverge if none of the elements -- of @xs@ equal @x@. elemIndex :: Eq a => a -> Stream a -> Int elemIndex x = findIndex (\y -> x == y) -- | The 'elemIndices' function extends 'elemIndex', by returning the -- indices of all elements equal to the query element, in ascending order. -- -- /Beware/: 'elemIndices' @x@ @xs@ will diverge if any suffix of -- @xs@ does not contain @x@. elemIndices :: Eq a => a -> Stream a -> Stream Int elemIndices x = findIndices (x==) -- | The 'findIndex' function takes a predicate and a stream and returns -- the index of the first element in the stream that satisfies the predicate, -- -- /Beware/: 'findIndex' @p@ @xs@ will diverge if none of the elements of -- @xs@ satisfy @p@. findIndex :: (a -> Bool) -> Stream a -> Int findIndex p = indexFrom 0 where indexFrom ix (x :> xs) | p x = ix | otherwise = (indexFrom $! (ix + 1)) xs -- | The 'findIndices' function extends 'findIndex', by returning the -- indices of all elements satisfying the predicate, in ascending -- order. -- -- /Beware/: 'findIndices' @p@ @xs@ will diverge if all the elements -- of any suffix of @xs@ fails to satisfy @p@. findIndices :: (a -> Bool) -> Stream a -> Stream Int findIndices p = indicesFrom 0 where indicesFrom ix (x :> xs) | p x = ix :> ixs | otherwise = ixs where ixs = (indicesFrom $! (ix+1)) xs -- | The 'zip' function takes two streams and returns a list of -- corresponding pairs. zip :: Stream a -> Stream b -> Stream (a,b) zip ~(x :> xs) ~(y :> ys) = (x,y) :> zip xs ys -- | The 'zipWith' function generalizes 'zip'. Rather than tupling -- the functions, the elements are combined using the function -- passed as the first argument to 'zipWith'. zipWith :: (a -> b -> c) -> Stream a -> Stream b -> Stream c zipWith f ~(x :> xs) ~(y :> ys) = f x y :> zipWith f xs ys -- | The 'unzip' function is the inverse of the 'zip' function. unzip :: Stream (a,b) -> (Stream a, Stream b) unzip xs = (fst <$> xs, snd <$> xs) -- | The 'words' function breaks a stream of characters into a -- stream of words, which were delimited by white space. -- -- /Beware/: if the stream of characters @xs@ does not contain white -- space, accessing the tail of @words xs@ will loop. words :: Stream Char -> Stream String words xs | (w, ys) <- break isSpace xs = w :> words ys -- | The 'unwords' function is an inverse operation to 'words'. It -- joins words with separating spaces. unwords :: Stream String -> Stream Char unwords ~(x :> xs) = foldr (:>) (' ' :> unwords xs) x -- | The 'lines' function breaks a stream of characters into a list -- of strings at newline characters. The resulting strings do not -- contain newlines. -- -- /Beware/: if the stream of characters @xs@ does not contain -- newline characters, accessing the tail of @lines xs@ will loop. lines :: Stream Char -> Stream String lines xs | (l, ys) <- break (== '\n') xs = l :> lines (tail ys) -- | The 'unlines' function is an inverse operation to 'lines'. It -- joins lines, after appending a terminating newline to each. unlines :: Stream String -> Stream Char unlines ~(x :> xs) = foldr (:>) ('\n' :> unlines xs) x