{-# LANGUAGE BangPatterns #-} {-# LANGUAGE CPP #-} {-# LANGUAGE FlexibleInstances #-} {-# LANGUAGE GeneralizedNewtypeDeriving #-} {-# LANGUAGE NoImplicitPrelude #-} {-# LANGUAGE ScopedTypeVariables #-} {-# LANGUAGE StandaloneDeriving #-} {-# LANGUAGE TypeOperators #-} #if __GLASGOW_HASKELL__ >=706 {-# LANGUAGE PolyKinds #-} #endif #if __GLASGOW_HASKELL__ >=702 {-# LANGUAGE Trustworthy #-} #endif -- | A class of non-empty data structures that can be folded to a summary value. module Data.Foldable1 ( Foldable1(..), foldr1, foldr1', foldl1, foldl1', intercalate1, foldrM1, foldlM1, foldrMapM1, foldlMapM1, maximumBy, minimumBy, ) where import Data.Foldable (Foldable, foldlM, foldr) import Data.List (foldl, foldl') import Data.List.NonEmpty (NonEmpty (..)) import Data.Semigroup (Dual (..), First (..), Last (..), Max (..), Min (..), Product (..), Semigroup (..), Sum (..)) import Prelude (Maybe (..), Monad (..), Ord, Ordering (..), id, seq, ($!), ($), (.), (=<<), flip, const, error) import qualified Data.List.NonEmpty as NE #if MIN_VERSION_base(4,4,0) import Data.Complex (Complex (..)) import GHC.Generics (M1 (..), Par1 (..), Rec1 (..), V1, (:*:) (..), (:+:) (..), (:.:) (..)) #else import Generics.Deriving (M1 (..), Par1 (..), Rec1 (..), V1, (:*:) (..), (:+:) (..), (:.:) (..)) #endif #if MIN_VERSION_base(4,6,0) import Data.Ord (Down (..)) #endif #if MIN_VERSION_base(4,8,0) import qualified Data.Monoid as Mon #endif #if !MIN_VERSION_base(4,12,0) import Data.Orphans () #endif #ifdef MIN_VERSION_tagged import Data.Tagged (Tagged (..)) #endif #ifdef MIN_VERSION_ghc_prim #if MIN_VERSION_ghc_prim(0,7,0) import GHC.Tuple (Solo (..)) #endif #endif -- Instances import Control.Applicative.Backwards (Backwards (..)) import Control.Applicative.Lift (Lift (..)) import Control.Monad.Trans.Identity (IdentityT (..)) import Data.Functor.Compose (Compose (..)) import Data.Functor.Identity (Identity (..)) import Data.Functor.Reverse (Reverse (..)) import Data.Tree (Tree (..)) import qualified Data.Functor.Product as Functor import qualified Data.Functor.Sum as Functor -- coerce #if __GLASGOW_HASKELL__ <708 import Unsafe.Coerce (unsafeCoerce) #else import Data.Coerce (Coercible, coerce) #endif -- $setup -- >>> import Prelude hiding (foldr1, foldl1, head, last, minimum, maximum) ------------------------------------------------------------------------------- -- Foldable1 type class ------------------------------------------------------------------------------- -- | Non-empty data structures that can be folded. class Foldable t => Foldable1 t where #if __GLASGOW_HASKELL__ >= 708 {-# MINIMAL foldMap1 | foldrMap1 #-} #endif -- At some point during design it was possible to define this class using -- only 'toNonEmpty'. But it seems a bad idea in general. -- -- So currently we require either foldMap1 or foldrMap1 -- -- * foldMap1 defined using foldrMap1 -- * foldrMap1 defined using foldMap1 -- -- One can alsays define instance using following pattern: -- -- toNonEmpty = ... -- foldMap f = foldMap f . toNonEmpty -- foldrMap1 f g = foldrMap1 f g . toNonEmpty -- | Combine the elements of a structure using a semigroup. fold1 :: Semigroup m => t m -> m fold1 = foldMap1 id -- | Map each element of the structure to a semigroup, -- and combine the results. -- -- >>> foldMap1 Sum (1 :| [2, 3, 4]) -- Sum {getSum = 10} -- foldMap1 :: Semigroup m => (a -> m) -> t a -> m foldMap1 f = foldrMap1 f (\a m -> f a <> m) -- | A variant of 'foldMap1' that is strict in the accumulator. -- -- >>> foldMap1' Sum (1 :| [2, 3, 4]) -- Sum {getSum = 10} -- foldMap1' :: Semigroup m => (a -> m) -> t a -> m foldMap1' f = foldlMap1' f (\m a -> m <> f a) -- | List of elements of a structure, from left to right. -- -- >>> toNonEmpty (Identity 2) -- 2 :| [] -- toNonEmpty :: t a -> NonEmpty a toNonEmpty = runNonEmptyDList . foldMap1 singleton -- | The largest element of a non-empty structure. -- -- >>> maximum (32 :| [64, 8, 128, 16]) -- 128 -- maximum :: Ord a => t a -> a maximum = getMax #. foldMap1' Max -- | The least element of a non-empty structure. -- -- >>> minimum (32 :| [64, 8, 128, 16]) -- 8 -- minimum :: Ord a => t a -> a minimum = getMin #. foldMap1' Min -- | The first element of a non-empty structure. -- -- >>> head (1 :| [2, 3, 4]) -- 1 -- head :: t a -> a head = getFirst #. foldMap1 First -- | The last element of a non-empty structure. -- -- >>> last (1 :| [2, 3, 4]) -- 4 -- last :: t a -> a last = getLast #. foldMap1 Last -- | Generalized 'foldr1'. foldrMap1 :: (a -> b) -> (a -> b -> b) -> t a -> b foldrMap1 f g xs = appFromMaybe (foldMap1 (FromMaybe #. h) xs) Nothing where h a Nothing = f a h a (Just b) = g a b -- | Generalized 'foldl1''. foldlMap1' :: (a -> b) -> (b -> a -> b) -> t a -> b foldlMap1' f g xs = foldrMap1 f' g' xs SNothing where -- f' :: a -> SMaybe b -> b f' a SNothing = f a f' a (SJust b) = g b a -- g' :: a -> (SMaybe b -> b) -> SMaybe b -> b g' a x SNothing = x $! SJust (f a) g' a x (SJust b) = x $! SJust (g b a) -- | Generalized 'foldl1'. foldlMap1 :: (a -> b) -> (b -> a -> b) -> t a -> b foldlMap1 f g xs = appFromMaybe (getDual (foldMap1 ((Dual . FromMaybe) #. h) xs)) Nothing where h a Nothing = f a h a (Just b) = g b a -- | Generalized 'foldr1''. foldrMap1' :: (a -> b) -> (a -> b -> b) -> t a -> b foldrMap1' f g xs = foldlMap1 f' g' xs SNothing where f' a SNothing = f a f' a (SJust b) = g a b g' bb a SNothing = bb $! SJust (f a) g' bb a (SJust b) = bb $! SJust (g a b) ------------------------------------------------------------------------------- -- Combinators ------------------------------------------------------------------------------- -- | Right-associative fold of a structure. -- -- In the case of lists, 'foldr1', when applied to a binary operator, -- and a list, reduces the list using the binary operator, -- from right to left: -- -- > foldr1 f [x1, x2, ..., xn] == x1 `f` (x2 `f` ... (xn1 `f` xn )...) -- -- Note that, since the head of the resulting expression is produced by -- an application of the operator to the first element of the list, -- 'foldr1' can produce a terminating expression from an infinite list. -- -- For a general 'Foldable1' structure this should be semantically identical -- to, -- -- @foldr1 f = foldr1 f . 'toNonEmpty'@ -- foldr1 :: Foldable1 t => (a -> a -> a) -> t a -> a foldr1 = foldrMap1 id {-# INLINE foldr1 #-} -- | Right-associative fold of a structure, but with strict application of -- the operator. -- foldr1' :: Foldable1 t => (a -> a -> a) -> t a -> a foldr1' = foldrMap1' id {-# INLINE foldr1' #-} -- | Left-associative fold of a structure. -- -- In the case of lists, 'foldl1', when applied to a binary -- operator, and a list, reduces the list using the binary operator, -- from left to right: -- -- > foldl1 f [x1, x2, ..., xn] == (...((x1 `f` x2) `f`...) `f` xn -- -- Note that to produce the outermost application of the operator the -- entire input list must be traversed. This means that 'foldl1' will -- diverge if given an infinite list. -- -- Also note that if you want an efficient left-fold, you probably want to -- use 'foldl1'' instead of 'foldl1'. The reason for this is that latter does -- not force the "inner" results (e.g. @x1 \`f\` x2@ in the above example) -- before applying them to the operator (e.g. to @(\`f\` x3)@). This results -- in a thunk chain \(\mathcal{O}(n)\) elements long, which then must be -- evaluated from the outside-in. -- -- For a general 'Foldable1' structure this should be semantically identical -- to, -- -- @foldl1 f z = foldl1 f . 'toNonEmpty'@ -- foldl1 :: Foldable1 t => (a -> a -> a) -> t a -> a foldl1 = foldlMap1 id {-# INLINE foldl1 #-} -- | Left-associative fold of a structure but with strict application of -- the operator. -- -- This ensures that each step of the fold is forced to weak head normal -- form before being applied, avoiding the collection of thunks that would -- otherwise occur. This is often what you want to strictly reduce a finite -- list to a single, monolithic result (e.g. 'length'). -- -- For a general 'Foldable1' structure this should be semantically identical -- to, -- -- @foldl1' f z = foldl1 f . 'toNonEmpty'@ -- foldl1' :: Foldable1 t => (a -> a -> a) -> t a -> a foldl1' = foldlMap1' id {-# INLINE foldl1' #-} -- | Insert an @m@ between each pair of @t m@. -- -- >>> intercalate1 ", " $ "hello" :| ["how", "are", "you"] -- "hello, how, are, you" -- -- >>> intercalate1 ", " $ "hello" :| [] -- "hello" -- -- >>> intercalate1 mempty $ "I" :| ["Am", "Fine", "You?"] -- "IAmFineYou?" -- intercalate1 :: (Foldable1 t, Semigroup m) => m -> t m -> m intercalate1 = flip intercalateMap1 id intercalateMap1 :: (Foldable1 t, Semigroup m) => m -> (a -> m) -> t a -> m intercalateMap1 j f = flip joinee j . foldMap1 (JoinWith . const . f) -- | Monadic fold over the elements of a non-empty structure, -- associating to the right, i.e. from right to left. foldrM1 :: (Foldable1 t, Monad m) => (a -> a -> m a) -> t a -> m a foldrM1 = foldrMapM1 return -- | Map variant of 'foldrM1'. foldrMapM1 :: (Foldable1 t, Monad m) => (a -> m b) -> (a -> b -> m b) -> t a -> m b foldrMapM1 g f = go . toNonEmpty where go (e:|es) = case es of [] -> g e x:xs -> f e =<< go (x:|xs) -- | Monadic fold over the elements of a non-empty structure, -- associating to the left, i.e. from left to right. foldlM1 :: (Foldable1 t, Monad m) => (a -> a -> m a) -> t a -> m a foldlM1 = foldlMapM1 return -- | Map variant of 'foldlM1'. foldlMapM1 :: (Foldable1 t, Monad m) => (a -> m b) -> (b -> a -> m b) -> t a -> m b foldlMapM1 g f t = g x >>= \y -> foldlM f y xs where x:|xs = toNonEmpty t -- | The largest element of a non-empty structure with respect to the -- given comparison function. -- See Note [maximumBy/minimumBy space usage] maximumBy :: Foldable1 t => (a -> a -> Ordering) -> t a -> a maximumBy cmp = foldl1' max' where max' x y = case cmp x y of GT -> x _ -> y -- | The least element of a non-empty structure with respect to the -- given comparison function. -- See Note [maximumBy/minimumBy space usage] minimumBy :: Foldable1 t => (a -> a -> Ordering) -> t a -> a minimumBy cmp = foldl1' min' where min' x y = case cmp x y of GT -> y _ -> x ------------------------------------------------------------------------------- -- Auxiliary types ------------------------------------------------------------------------------- -- | Used for default toNonEmpty implementation. newtype NonEmptyDList a = NEDL { unNEDL :: [a] -> NonEmpty a } instance Semigroup (NonEmptyDList a) where xs <> ys = NEDL (unNEDL xs . NE.toList . unNEDL ys) {-# INLINE (<>) #-} -- | Create dlist with a single element singleton :: a -> NonEmptyDList a singleton = NEDL #. (:|) -- | Convert a dlist to a non-empty list runNonEmptyDList :: NonEmptyDList a -> NonEmpty a runNonEmptyDList = ($ []) . unNEDL {-# INLINE runNonEmptyDList #-} -- | Used for foldrMap1 and foldlMap1 definitions newtype FromMaybe b = FromMaybe { appFromMaybe :: Maybe b -> b } instance Semigroup (FromMaybe b) where FromMaybe f <> FromMaybe g = FromMaybe (f . Just . g) -- | Strict maybe, used to implement default foldlMap1' etc. data SMaybe a = SNothing | SJust !a -- | Used to implement intercalate1/Map newtype JoinWith a = JoinWith {joinee :: (a -> a)} instance Semigroup a => Semigroup (JoinWith a) where JoinWith a <> JoinWith b = JoinWith $ \j -> a j <> j <> b j ------------------------------------------------------------------------------- -- Instances for misc base types ------------------------------------------------------------------------------- instance Foldable1 NonEmpty where foldMap1 f (x :| xs) = go (f x) xs where go y [] = y go y (z : zs) = y <> go (f z) zs foldMap1' f (x :| xs) = foldl' (\m y -> m <> f y) (f x) xs toNonEmpty = id foldrMap1 g f (x :| xs) = go x xs where go y [] = g y go y (z : zs) = f y (go z zs) foldlMap1 g f (x :| xs) = foldl f (g x) xs foldlMap1' g f (x :| xs) = let gx = g x in gx `seq` foldl' f gx xs head = NE.head last = NE.last #if MIN_VERSION_base(4,6,0) instance Foldable1 Down where foldMap1 = coerce #endif #if MIN_VERSION_base(4,4,0) instance Foldable1 Complex where foldMap1 f (x :+ y) = f x <> f y toNonEmpty (x :+ y) = x :| y : [] #endif ------------------------------------------------------------------------------- -- Instances for tuples ------------------------------------------------------------------------------- -- 3+ tuples are not Foldable/Traversable instance Foldable1 ((,) a) where foldMap1 f (_, y) = f y toNonEmpty (_, x) = x :| [] minimum (_, x) = x maximum (_, x) = x head (_, x) = x last (_, x) = x ------------------------------------------------------------------------------- -- Monoid / Semigroup instances ------------------------------------------------------------------------------- instance Foldable1 Dual where foldMap1 = coerce instance Foldable1 Sum where foldMap1 = coerce instance Foldable1 Product where foldMap1 = coerce instance Foldable1 Min where foldMap1 = coerce instance Foldable1 Max where foldMap1 = coerce instance Foldable1 First where foldMap1 = coerce instance Foldable1 Last where foldMap1 = coerce #if MIN_VERSION_base(4,8,0) deriving instance (Foldable1 f) => Foldable1 (Mon.Alt f) #endif #if MIN_VERSION_base(4,12,0) deriving instance (Foldable1 f) => Foldable1 (Mon.Ap f) #endif ------------------------------------------------------------------------------- -- GHC.Generics instances ------------------------------------------------------------------------------- instance Foldable1 V1 where foldMap1 _ x = x `seq` error "foldMap1 @V1" instance Foldable1 Par1 where foldMap1 = coerce deriving instance Foldable1 f => Foldable1 (Rec1 f) deriving instance Foldable1 f => Foldable1 (M1 i c f) instance (Foldable1 f, Foldable1 g) => Foldable1 (f :+: g) where foldMap1 f (L1 x) = foldMap1 f x foldMap1 f (R1 y) = foldMap1 f y instance (Foldable1 f, Foldable1 g) => Foldable1 (f :*: g) where foldMap1 f (x :*: y) = foldMap1 f x <> foldMap1 f y instance (Foldable1 f, Foldable1 g) => Foldable1 (f :.: g) where foldMap1 f = foldMap1 (foldMap1 f) . unComp1 ------------------------------------------------------------------------------- -- Extra instances ------------------------------------------------------------------------------- instance Foldable1 Identity where foldMap1 = coerce foldrMap1 g _ = coerce g foldrMap1' g _ = coerce g foldlMap1 g _ = coerce g foldlMap1' g _ = coerce g toNonEmpty (Identity x) = x :| [] last = coerce head = coerce minimum = coerce maximum = coerce -- | It would be enough for either half of a product to be 'Foldable1'. -- Other could be 'Foldable'. instance (Foldable1 f, Foldable1 g) => Foldable1 (Functor.Product f g) where foldMap1 f (Functor.Pair x y) = foldMap1 f x <> foldMap1 f y foldrMap1 g f (Functor.Pair x y) = foldr f (foldrMap1 g f y) x head (Functor.Pair x _) = head x last (Functor.Pair _ y) = last y instance (Foldable1 f, Foldable1 g) => Foldable1 (Functor.Sum f g) where foldMap1 f (Functor.InL x) = foldMap1 f x foldMap1 f (Functor.InR y) = foldMap1 f y foldrMap1 g f (Functor.InL x) = foldrMap1 g f x foldrMap1 g f (Functor.InR y) = foldrMap1 g f y toNonEmpty (Functor.InL x) = toNonEmpty x toNonEmpty (Functor.InR y) = toNonEmpty y head (Functor.InL x) = head x head (Functor.InR y) = head y last (Functor.InL x) = last x last (Functor.InR y) = last y minimum (Functor.InL x) = minimum x minimum (Functor.InR y) = minimum y maximum (Functor.InL x) = maximum x maximum (Functor.InR y) = maximum y instance (Foldable1 f, Foldable1 g) => Foldable1 (Compose f g) where foldMap1 f = foldMap1 (foldMap1 f) . getCompose foldrMap1 f g = foldrMap1 (foldrMap1 f g) (\xs x -> foldr g x xs) . getCompose head = head . head . getCompose last = last . last . getCompose ------------------------------------------------------------------------------- -- containers ------------------------------------------------------------------------------- instance Foldable1 Tree where foldMap1 f (Node x []) = f x foldMap1 f (Node x (y : ys)) = f x <> foldMap1 (foldMap1 f) (y :| ys) foldMap1' f = go where go (Node x ys) = foldl' (\m zs -> let gozs = go zs in gozs `seq` m <> gozs) (f x) ys foldlMap1 f g (Node x xs) = goForest (f x) xs where goForest = foldl' go go y (Node z zs) = goForest (g y z) zs foldlMap1' f g (Node x xs) = goForest (f x) xs where goForest !y = foldl' go y go !y (Node z zs) = goForest (g y z) zs head (Node x _) = x ------------------------------------------------------------------------------- -- transformers ------------------------------------------------------------------------------- instance Foldable1 f => Foldable1 (Reverse f) where foldMap1 f = getDual . foldMap1 (Dual . f) . getReverse foldrMap1 f g (Reverse xs) = foldlMap1 f (flip g) xs foldlMap1 f g (Reverse xs) = foldrMap1 f (flip g) xs foldrMap1' f g (Reverse xs) = foldlMap1' f (flip g) xs foldlMap1' f g (Reverse xs) = foldrMap1' f (flip g) xs head = last . getReverse last = head . getReverse deriving instance Foldable1 f => Foldable1 (IdentityT f) instance Foldable1 f => Foldable1 (Backwards f) where foldMap1 f = foldMap1 f . forwards instance Foldable1 f => Foldable1 (Lift f) where foldMap1 f (Pure x) = f x foldMap1 f (Other y) = foldMap1 f y ------------------------------------------------------------------------------- -- tagged ------------------------------------------------------------------------------- #ifdef MIN_VERSION_tagged instance Foldable1 (Tagged b) where foldMap1 = coerce foldrMap1 g _ = coerce g foldrMap1' g _ = coerce g foldlMap1 g _ = coerce g foldlMap1' g _ = coerce g toNonEmpty x = coerce x :| [] last = coerce head = coerce minimum = coerce maximum = coerce #endif ------------------------------------------------------------------------------- -- ghc-prim ------------------------------------------------------------------------------- #ifdef MIN_VERSION_ghc_prim #if MIN_VERSION_ghc_prim(0,7,0) instance Foldable1 Solo where foldMap1 f (Solo y) = f y toNonEmpty (Solo x) = x :| [] minimum (Solo x) = x maximum (Solo x) = x head (Solo x) = x last (Solo x) = x #endif #endif ------------------------------------------------------------------------------- -- coerce shim ------------------------------------------------------------------------------- #if __GLASGOW_HASKELL__ <708 coerce :: a -> b coerce = unsafeCoerce (#.) :: (b -> c) -> (a -> b) -> a -> c (#.) _f = coerce #else (#.) :: Coercible b c => (b -> c) -> (a -> b) -> a -> c (#.) _f = coerce #endif