module Data.NonEmptyPrivate where
import qualified Data.NonEmpty.Foldable as FoldU
import qualified Data.NonEmpty.Class as C
import qualified Data.Empty as Empty
import qualified Data.Sequence as Seq
import Data.Sequence (Seq, )
import qualified Data.Traversable as Trav
import qualified Data.Foldable as Fold
import qualified Data.List.Match as Match
import qualified Data.List.HT as ListHT
import qualified Data.List as List
import Data.Traversable (Traversable, mapAccumL, mapAccumR)
import Data.Foldable (Foldable, )
import Control.Monad (Monad, return, (=<<), )
import Control.Applicative (Applicative, liftA2, pure, (<*>), )
import Control.DeepSeq (NFData, rnf, )
import Data.Functor (Functor, fmap, )
import Data.Function (flip, const, ($), (.), )
import Data.Maybe (Maybe(Just, Nothing), maybe, mapMaybe, )
import Data.Bool.HT (if', )
import Data.Bool (Bool(True), (&&), )
import Data.Ord (Ord, Ordering(GT), (<=), (>), compare, comparing, )
import Data.Eq ((==), )
import Data.Tuple.HT (mapFst, mapSnd, swap, )
import Data.Tuple (fst, snd, )
import qualified Prelude as P
import Prelude (Eq, Show, Num, Int, uncurry, ($!), )
import qualified Test.QuickCheck as QC
data T f a = Cons { head :: a, tail :: f a }
deriving (Eq, Ord)
instance (C.NFData f, NFData a) => NFData (T f a) where
rnf = C.rnf
instance (C.NFData f) => C.NFData (T f) where
rnf (Cons x xs) = rnf (x, C.rnf xs)
instance (C.Show f, Show a) => Show (T f a) where
showsPrec = C.showsPrec
instance (C.Show f) => C.Show (T f) where
showsPrec p (Cons x xs) =
P.showParen (p>5) $
P.showsPrec 6 x . P.showString "!:" . C.showsPrec 5 xs
infixr 5 !:, `append`, `appendRight`, `appendLeft`
(!:) :: a -> f a -> T f a
(!:) = Cons
force :: T f a -> T f a
force x = Cons (head x) (tail x)
instance Functor f => Functor (T f) where
fmap f (Cons x xs) = f x !: fmap f xs
instance Foldable f => Foldable (T f) where
foldr f y (Cons x xs) = f x $ Fold.foldr f y xs
foldl1 = foldl1
foldr1 f (Cons x xs) =
maybe x (f x) $
Fold.foldr (\y -> Just . maybe y (f y)) Nothing xs
instance Traversable f => Traversable (T f) where
sequenceA (Cons x xs) = liftA2 Cons x $ Trav.sequenceA xs
instance
(Applicative f, C.Empty f, C.Cons f, C.Append f) =>
Applicative (T f) where
pure = singleton
(<*>) = apply
instance (Monad f, C.Empty f, C.Cons f, C.Append f) =>
Monad (T f) where
return = singleton
(>>=) = bind
instance (C.Arbitrary f) => C.Arbitrary (T f) where
arbitrary = arbitrary
shrink = shrink
instance (QC.Arbitrary a, C.Arbitrary f) => QC.Arbitrary (T f a) where
arbitrary = arbitrary
shrink = shrink
arbitrary :: (QC.Arbitrary a, C.Arbitrary f) => QC.Gen (T f a)
arbitrary = liftA2 Cons QC.arbitrary C.arbitrary
shrink :: (QC.Arbitrary a, C.Arbitrary f) => T f a -> [T f a]
shrink (Cons x xs) = fmap (\(y, Aux ys) -> Cons y ys) $ QC.shrink (x, Aux xs)
newtype Aux f a = Aux (f a)
instance (C.Arbitrary f, QC.Arbitrary a) => QC.Arbitrary (Aux f a) where
arbitrary = fmap Aux C.arbitrary
shrink (Aux x) = fmap Aux $ C.shrink x
instance (C.Gen f) => C.Gen (T f) where
genOf gen = liftA2 Cons gen $ C.genOf gen
apply ::
(Applicative f, C.Cons f, C.Append f) =>
T f (a -> b) -> T f a -> T f b
apply (Cons f fs) (Cons x xs) =
Cons (f x) (fmap f xs `C.append` (fs <*> C.cons x xs))
bind ::
(Monad f, C.Cons f, C.Append f) =>
T f a -> (a -> T f b) -> T f b
bind (Cons x xs) k =
appendRight (k x) (flatten . k =<< xs)
toList :: Foldable f => T f a -> [a]
toList (Cons x xs) = x : Fold.toList xs
flatten :: C.Cons f => T f a -> f a
flatten (Cons x xs) = C.cons x xs
fetch :: C.ViewL f => f a -> Maybe (T f a)
fetch = fmap (uncurry Cons) . C.viewL
instance C.ViewL f => C.ViewL (T f) where
viewL (Cons x xs) = fmap ((,) x) $ fetch xs
instance C.Cons f => C.Cons (T f) where
cons x0 (Cons x1 xs) = x0 !: C.cons x1 xs
instance C.Snoc f => C.Snoc (T f) where
snoc (Cons x0 xs) x1 = x0 !: C.snoc xs x1
cons :: a -> f a -> T f a
cons = Cons
snoc :: Traversable f => f a -> a -> T f a
snoc xs x =
uncurry Cons $ mapAccumR (flip (,)) x xs
snocAlt :: (C.Cons f, Traversable f) => f a -> a -> f a
snocAlt xs x = flatten $ snoc xs x
instance C.Empty f => C.Singleton (T f) where
singleton = singleton
singleton :: C.Empty f => a -> T f a
singleton x = x !: C.empty
viewL :: T f a -> (a, f a)
viewL (Cons x xs) = (x, xs)
viewR :: (Traversable f) => T f a -> (f a, a)
viewR (Cons x xs) = swap $ mapAccumL (flip (,)) x xs
mapHead :: (a -> a) -> T f a -> T f a
mapHead f (Cons x xs) = f x !: xs
mapTail :: (f a -> g a) -> T f a -> T g a
mapTail f (Cons x xs) = x !: f xs
init :: (Traversable f) => T f a -> f a
init = fst . viewR
last :: (Foldable f) => T f a -> a
last = foldl1 (flip const)
foldl1 :: (Foldable f) => (a -> a -> a) -> T f a -> a
foldl1 f (Cons x xs) = Fold.foldl f x xs
foldl1Map :: (Foldable f) => (b -> b -> b) -> (a -> b) -> T f a -> b
foldl1Map f g (Cons x xs) = Fold.foldl (\b a -> f b (g a)) (g x) xs
foldBalanced :: (a -> a -> a) -> T [] a -> a
foldBalanced = foldBalancedGen (:)
foldBalancedStrict :: (a -> a -> a) -> T [] a -> a
foldBalancedStrict = foldBalancedGen (\x -> ((:) $! x))
foldBalancedGen :: (a -> [a] -> [a]) -> (a -> a -> a) -> T [] a -> a
foldBalancedGen listCons f xs@(Cons _ rs) =
let reduce (z0:z1:zs) = listCons (f z0 z1) (reduce zs)
reduce zs = zs
ys = appendRight xs $ Match.take rs $ reduce $ flatten ys
in last ys
maximum :: (Ord a, Foldable f) => T f a -> a
maximum = foldl1 P.max
minimum :: (Ord a, Foldable f) => T f a -> a
minimum = foldl1 P.min
maximumBy :: (Foldable f) => (a -> a -> Ordering) -> T f a -> a
maximumBy f = foldl1 (\x y -> case f x y of P.LT -> y; _ -> x)
minimumBy :: (Foldable f) => (a -> a -> Ordering) -> T f a -> a
minimumBy f = foldl1 (\x y -> case f x y of P.GT -> y; _ -> x)
maximumKey :: (Ord b, Foldable f) => (a -> b) -> T f a -> a
maximumKey f =
snd . Fold.maximumBy (comparing fst) . FoldU.Mapped (attachKey f)
minimumKey :: (Ord b, Foldable f) => (a -> b) -> T f a -> a
minimumKey f =
snd . Fold.minimumBy (comparing fst) . FoldU.Mapped (attachKey f)
_maximumKey :: (Ord b, Foldable f, Functor f) => (a -> b) -> T f a -> a
_maximumKey f =
snd . maximumBy (comparing fst) . fmap (attachKey f)
_minimumKey :: (Ord b, Foldable f, Functor f) => (a -> b) -> T f a -> a
_minimumKey f =
snd . minimumBy (comparing fst) . fmap (attachKey f)
attachKey :: (a -> b) -> a -> (b, a)
attachKey f a = (f a, a)
sum :: (Num a, Foldable f) => T f a -> a
sum = foldl1 (P.+)
product :: (Num a, Foldable f) => T f a -> a
product = foldl1 (P.*)
instance (C.Cons f, C.Append f) => C.Append (T f) where
append xs ys = appendRight xs (flatten ys)
append :: (C.Append f, Traversable f) => T f a -> T f a -> T (T f) a
append xs ys =
mapTail (flip appendLeft ys) xs
appendRight :: (C.Append f) => T f a -> f a -> T f a
appendRight (Cons x xs) ys = Cons x (C.append xs ys)
appendLeft ::
(C.Append f, Traversable f) =>
f a -> T f a -> T f a
appendLeft xt (Cons y ys) =
mapTail (flip C.append ys) $ snoc xt y
cycle :: (C.Cons f, C.Append f) => T f a -> T f a
cycle x =
let y = C.append x y
in y
instance (C.Zip f) => C.Zip (T f) where
zipWith = zipWith
zipWith :: (C.Zip f) => (a -> b -> c) -> T f a -> T f b -> T f c
zipWith f (Cons a as) (Cons b bs) = Cons (f a b) (C.zipWith f as bs)
instance (C.Repeat f) => C.Repeat (T f) where
repeat a = Cons a $ C.repeat a
instance (C.Iterate f) => C.Iterate (T f) where
iterate f a = Cons a $ C.iterate f (f a)
reverse :: (Traversable f, C.Reverse f) => T f a -> T f a
reverse (Cons x xs) = snoc (C.reverse xs) x
instance (Traversable f, C.Reverse f) => C.Reverse (T f) where
reverse = reverse
instance (C.Sort f, InsertBy f) => C.Sort (T f) where
sort (Cons x xs) = insert x $ C.sort xs
instance (C.SortBy f, InsertBy f) => C.SortBy (T f) where
sortBy f (Cons x xs) = insertBy f x $ C.sortBy f xs
class Insert f where
insert :: (Ord a) => a -> f a -> T f a
instance (Insert f) => Insert (T f) where
insert y xt@(Cons x xs) =
uncurry Cons $
case compare y x of
GT -> (x, insert y xs)
_ -> (y, xt)
instance Insert Empty.T where
insert = insertDefault
instance Insert [] where
insert = insertDefault
instance Insert Maybe where
insert = insertDefault
instance Insert Seq where
insert = insertDefault
insertDefault :: (Ord a, InsertBy f, C.SortBy f) => a -> f a -> T f a
insertDefault = insertBy compare
class Insert f => InsertBy f where
insertBy :: (a -> a -> Ordering) -> a -> f a -> T f a
instance (InsertBy f) => InsertBy (T f) where
insertBy f y xt@(Cons x xs) =
uncurry Cons $
case f y x of
GT -> (x, insertBy f y xs)
_ -> (y, xt)
instance InsertBy Empty.T where
insertBy _ x Empty.Cons = Cons x Empty.Cons
instance InsertBy [] where
insertBy f y xt =
uncurry Cons $
case xt of
[] -> (y, xt)
x:xs ->
case f y x of
GT -> (x, List.insertBy f y xs)
_ -> (y, xt)
instance InsertBy Maybe where
insertBy f y mx =
uncurry Cons $
case mx of
Nothing -> (y, Nothing)
Just x ->
mapSnd Just $
case f y x of
GT -> (x, y)
_ -> (y, x)
instance InsertBy Seq where
insertBy f y xt =
uncurry Cons $
case Seq.spanl ((GT ==) . f y) xt of
(ys,zs) ->
case Seq.viewl ys of
Seq.EmptyL -> (y, xt)
w Seq.:< ws -> (w, ws Seq.>< y Seq.<| zs)
insertByTraversable ::
(Traversable f) =>
(a -> a -> Ordering) -> a -> f a -> T f a
insertByTraversable cmp y0 =
uncurry (flip snoc . snd) .
mapAccumL
(\(searching,y) x ->
let stillSearching = searching && cmp y x == GT
in mapFst ((,) stillSearching) $ if' stillSearching (y,x) (x,y))
(True, y0)
mapWithIndex :: (Traversable f) => (Int -> a -> b) -> Int -> f a -> f b
mapWithIndex f n = snd . mapAccumL (\k x -> (P.succ k, f k x)) n
removeAt :: (Traversable f) => Int -> T f a -> (a, f a)
removeAt n (Cons x0 xs) =
mapAccumL (\x (k,y) -> if k<=n then (y,x) else (x,y)) x0 $
mapWithIndex (,) 1 xs
removeEach :: (Traversable f) => T f a -> T f (a, f a)
removeEach xs = mapWithIndex (\n _ -> removeAt n xs) 0 xs
tails :: (Traversable f, C.Cons g, C.Empty g) => f a -> T f (g a)
tails = scanr C.cons C.empty
inits :: (Traversable f, C.Snoc g, C.Empty g) => f a -> T f (g a)
inits = scanl C.snoc C.empty
initsRev ::
(Traversable f, C.Cons g, C.Empty g, C.Reverse g) =>
f a -> T f (g a)
initsRev = fmap C.reverse . scanl (flip C.cons) C.empty
class TransposeOuter f where
transpose :: TransposeInner g => f (g a) -> g (f a)
instance TransposeOuter [] where
transpose =
let go [] = transposeStart
go (xs : xss) = zipHeadTail xs $ go xss
in go
class TransposeInner g where
transposeStart :: g a
zipHeadTail :: (C.Singleton f, C.Cons f) => g a -> g (f a) -> g (f a)
instance TransposeInner [] where
transposeStart = []
zipHeadTail =
let go (x:xs) (ys:yss) = C.cons x ys : go xs yss
go [] yss = yss
go xs [] = fmap C.singleton xs
in go
transposePrelude :: [[a]] -> [[a]]
transposePrelude =
let go [] = []
go ([] : xss) = go xss
go ((x:xs) : xss) =
case ListHT.unzip $ mapMaybe ListHT.viewL xss of
(ys, yss) -> (x : ys) : go (xs : yss)
in go
propTranspose :: [[P.Int]] -> P.Bool
propTranspose xs =
List.transpose xs P.== transpose xs
propTransposePrelude :: [[P.Int]] -> P.Bool
propTransposePrelude xs =
List.transpose xs P.== transposePrelude xs
scanl :: Traversable f => (b -> a -> b) -> b -> f a -> T f b
scanl f b =
Cons b . snd .
mapAccumL (\b0 -> (\b1 -> (b1,b1)) . f b0) b
scanr :: Traversable f => (a -> b -> b) -> b -> f a -> T f b
scanr f b =
uncurry Cons .
mapAccumR (\b0 -> flip (,) b0 . flip f b0) b
mapAdjacent ::
(Traversable f) => (a -> a -> b) -> T f a -> f b
mapAdjacent f (Cons x xs) =
snd $ mapAccumL (\a0 a1 -> (a1, f a0 a1)) x xs
mapAdjacent1 :: (Traversable f) => (a -> a -> b -> c) -> a -> f (a,b) -> f c
mapAdjacent1 f = (snd.) . mapAccumL (\a0 (a1,b) -> (a1, f a0 a1 b))