{-# LANGUAGE CPP #-} {-# LANGUAGE GADTs #-} {-# LANGUAGE Rank2Types #-} {-# LANGUAGE TypeFamilies #-} {-# LANGUAGE FlexibleContexts #-} {-# LANGUAGE DefaultSignatures #-} {-# LANGUAGE FlexibleInstances #-} {-# LANGUAGE ScopedTypeVariables #-} {-# LANGUAGE MultiParamTypeClasses #-} {-# LANGUAGE UndecidableInstances #-} {-# LANGUAGE TypeOperators #-} #ifdef TRUSTWORTHY {-# LANGUAGE Trustworthy #-} #endif #include "lens-common.h" ----------------------------------------------------------------------------- -- | -- Module : Control.Lens.At -- Copyright : (C) 2012-16 Edward Kmett -- License : BSD-style (see the file LICENSE) -- Maintainer : Edward Kmett -- Stability : experimental -- Portability : non-portable -- ---------------------------------------------------------------------------- module Control.Lens.At ( -- * At At(at) , sans , iat -- * Ixed , Index , IxValue , Ixed(ix) , ixAt , iix -- * Contains , Contains(contains) , icontains ) where import Prelude () import Control.Lens.Each import Control.Lens.Internal.Prelude import Control.Lens.Traversal import Control.Lens.Lens import Control.Lens.Setter import Control.Lens.Indexed import Control.Monad (guard) import Data.Array.IArray as Array import Data.Array.Unboxed import qualified Data.ByteString as StrictB import qualified Data.ByteString.Lazy as LazyB import Data.Complex import Data.Functor (($>)) import Data.Hashable import qualified Data.HashMap.Lazy as HashMap import Data.HashMap.Lazy (HashMap) import qualified Data.HashSet as HashSet import Data.HashSet (HashSet) import Data.Int import qualified Data.IntMap as IntMap import Data.IntMap (IntMap) import qualified Data.IntSet as IntSet import Data.IntSet (IntSet) import qualified Data.Map as Map import Data.Map (Map) import Data.Maybe (isJust) import qualified Data.Set as Set import Data.Set (Set) import qualified Data.Sequence as Seq import Data.Sequence (Seq) import qualified Data.Text as StrictT import qualified Data.Text.Lazy as LazyT import Data.Tree import qualified Data.Vector as Vector import qualified Data.Vector.Primitive as Prim import Data.Vector.Primitive (Prim) import qualified Data.Vector.Storable as Storable import qualified Data.Vector.Unboxed as Unboxed import Data.Vector.Unboxed (Unbox) import Data.Word import Foreign.Storable (Storable) type family Index (s :: *) :: * type instance Index (e -> a) = e type instance Index IntSet = Int type instance Index (Set a) = a type instance Index (HashSet a) = a type instance Index [a] = Int type instance Index (NonEmpty a) = Int type instance Index (Seq a) = Int type instance Index (a,b) = Int type instance Index (a,b,c) = Int type instance Index (a,b,c,d) = Int type instance Index (a,b,c,d,e) = Int type instance Index (a,b,c,d,e,f) = Int type instance Index (a,b,c,d,e,f,g) = Int type instance Index (a,b,c,d,e,f,g,h) = Int type instance Index (a,b,c,d,e,f,g,h,i) = Int type instance Index (IntMap a) = Int type instance Index (Map k a) = k type instance Index (HashMap k a) = k type instance Index (Array.Array i e) = i type instance Index (UArray i e) = i type instance Index (Vector.Vector a) = Int type instance Index (Prim.Vector a) = Int type instance Index (Storable.Vector a) = Int type instance Index (Unboxed.Vector a) = Int type instance Index (Complex a) = Int type instance Index (Identity a) = () type instance Index (Maybe a) = () type instance Index (Tree a) = [Int] type instance Index StrictT.Text = Int type instance Index LazyT.Text = Int64 type instance Index StrictB.ByteString = Int type instance Index LazyB.ByteString = Int64 -- $setup -- >>> :set -XNoOverloadedStrings -- >>> import Control.Lens -- >>> import qualified Data.IntSet as IntSet -- >>> import qualified Data.Sequence as Seq -- >>> import qualified Data.Map as Map -- >>> import Debug.SimpleReflect.Expr -- >>> import Debug.SimpleReflect.Vars as Vars hiding (f,g) -- >>> let f :: Expr -> Expr; f = Debug.SimpleReflect.Vars.f -- >>> let g :: Expr -> Expr; g = Debug.SimpleReflect.Vars.g -- >>> let f' :: Int -> Expr -> Expr; f' = Debug.SimpleReflect.Vars.f' -- >>> let h :: Int -> Expr; h = Debug.SimpleReflect.Vars.h -- | -- This class provides a simple 'Lens' that lets you view (and modify) -- information about whether or not a container contains a given 'Index'. class Contains m where -- | -- >>> IntSet.fromList [1,2,3,4] ^. contains 3 -- True -- -- >>> IntSet.fromList [1,2,3,4] ^. contains 5 -- False -- -- >>> IntSet.fromList [1,2,3,4] & contains 3 .~ False -- fromList [1,2,4] contains :: Index m -> Lens' m Bool -- | An indexed version of 'contains'. -- -- >>> IntSet.fromList [1,2,3,4] ^@. icontains 3 -- (3,True) -- -- >>> IntSet.fromList [1,2,3,4] ^@. icontains 5 -- (5,False) -- -- >>> IntSet.fromList [1,2,3,4] & icontains 3 %@~ \i x -> if odd i then not x else x -- fromList [1,2,4] -- -- >>> IntSet.fromList [1,2,3,4] & icontains 3 %@~ \i x -> if even i then not x else x -- fromList [1,2,3,4] icontains :: Contains m => Index m -> IndexedLens' (Index m) m Bool icontains i f = contains i (indexed f i) {-# INLINE icontains #-} instance Contains IntSet where #if MIN_VERSION_containers(0,6,3) contains k f = IntSet.alterF f k #else -- This is a flipped copy of the implementation of `IntSet.alterF`. Unlike a -- `Set`, we don't have to worry about expensive comparisons from descending -- multiple times into an `IntSet`. We are careful to share the results of -- insertion or deletion across multiple positions in the `Functor`. contains k f s = fmap choose (f member_) where member_ = IntSet.member k s (inserted, deleted) | member_ = (s, IntSet.delete k s) | otherwise = (IntSet.insert k s, s) choose True = inserted choose False = deleted #endif {-# INLINE contains #-} instance Ord a => Contains (Set a) where #if MIN_VERSION_containers(0,6,3) contains k f = Set.alterF f k #else contains k f s = f (Set.member k s) <&> \b -> if b then Set.insert k s else Set.delete k s #endif {-# INLINE contains #-} instance (Eq a, Hashable a) => Contains (HashSet a) where contains k f s = HashSet.fromMap <$> HashMap.alterF (fmap guard . f . isJust) k (HashSet.toMap s) {-# INLINE contains #-} -- | This provides a common notion of a value at an index that is shared by both 'Ixed' and 'At'. type family IxValue (m :: *) :: * -- | Provides a simple 'Traversal' lets you 'traverse' the value at a given -- key in a 'Map' or element at an ordinal position in a list or 'Seq'. class Ixed m where -- | -- /NB:/ Setting the value of this 'Traversal' will only set the value in -- 'at' if it is already present. -- -- If you want to be able to insert /missing/ values, you want 'at'. -- -- >>> Seq.fromList [a,b,c,d] & ix 2 %~ f -- fromList [a,b,f c,d] -- -- >>> Seq.fromList [a,b,c,d] & ix 2 .~ e -- fromList [a,b,e,d] -- -- >>> Seq.fromList [a,b,c,d] ^? ix 2 -- Just c -- -- >>> Seq.fromList [] ^? ix 2 -- Nothing ix :: Index m -> Traversal' m (IxValue m) default ix :: At m => Index m -> Traversal' m (IxValue m) ix = ixAt {-# INLINE ix #-} -- | An indexed version of 'ix'. -- -- >>> Seq.fromList [a,b,c,d] & iix 2 %@~ f' -- fromList [a,b,f' 2 c,d] -- -- >>> Seq.fromList [a,b,c,d] & iix 2 .@~ h -- fromList [a,b,h 2,d] -- -- >>> Seq.fromList [a,b,c,d] ^@? iix 2 -- Just (2,c) -- -- >>> Seq.fromList [] ^@? iix 2 -- Nothing iix :: Ixed m => Index m -> IndexedTraversal' (Index m) m (IxValue m) iix i f = ix i (indexed f i) {-# INLINE iix #-} -- | A definition of 'ix' for types with an 'At' instance. This is the default -- if you don't specify a definition for 'ix'. ixAt :: At m => Index m -> Traversal' m (IxValue m) ixAt i = at i . traverse {-# INLINE ixAt #-} type instance IxValue (e -> a) = a instance Eq e => Ixed (e -> a) where ix e p f = p (f e) <&> \a e' -> if e == e' then a else f e' {-# INLINE ix #-} type instance IxValue (Maybe a) = a instance Ixed (Maybe a) where ix ~() f (Just a) = Just <$> f a ix ~() _ Nothing = pure Nothing {-# INLINE ix #-} type instance IxValue [a] = a instance Ixed [a] where ix k f xs0 | k < 0 = pure xs0 | otherwise = go xs0 k where go [] _ = pure [] go (a:as) 0 = f a <&> (:as) go (a:as) i = (a:) <$> (go as $! i - 1) {-# INLINE ix #-} type instance IxValue (NonEmpty a) = a instance Ixed (NonEmpty a) where ix k f xs0 | k < 0 = pure xs0 | otherwise = go xs0 k where go (a:|as) 0 = f a <&> (:|as) go (a:|as) i = (a:|) <$> ix (i - 1) f as {-# INLINE ix #-} type instance IxValue (Identity a) = a instance Ixed (Identity a) where ix ~() f (Identity a) = Identity <$> f a {-# INLINE ix #-} type instance IxValue (Tree a) = a instance Ixed (Tree a) where ix xs0 f = go xs0 where go [] (Node a as) = f a <&> \a' -> Node a' as go (i:is) t@(Node a as) | i < 0 = pure t | otherwise = Node a <$> ix i (go is) as {-# INLINE ix #-} type instance IxValue (Seq a) = a instance Ixed (Seq a) where ix i f m | 0 <= i && i < Seq.length m = f (Seq.index m i) <&> \a -> Seq.update i a m | otherwise = pure m {-# INLINE ix #-} type instance IxValue (IntMap a) = a instance Ixed (IntMap a) where ix k f m = case IntMap.lookup k m of Just v -> f v <&> \v' -> IntMap.insert k v' m Nothing -> pure m {-# INLINE ix #-} type instance IxValue (Map k a) = a instance Ord k => Ixed (Map k a) where ix k f m = case Map.lookup k m of Just v -> f v <&> \v' -> Map.insert k v' m Nothing -> pure m {-# INLINE ix #-} type instance IxValue (HashMap k a) = a instance (Eq k, Hashable k) => Ixed (HashMap k a) where ix k f m = case HashMap.lookup k m of Just v -> f v <&> \v' -> HashMap.insert k v' m Nothing -> pure m {-# INLINE ix #-} type instance IxValue (Set k) = () instance Ord k => Ixed (Set k) where ix k f m = if Set.member k m then f () $> m else pure m {-# INLINE ix #-} type instance IxValue IntSet = () instance Ixed IntSet where ix k f m = if IntSet.member k m then f () $> m else pure m {-# INLINE ix #-} type instance IxValue (HashSet k) = () instance (Eq k, Hashable k) => Ixed (HashSet k) where ix k f m = if HashSet.member k m then f () $> m else pure m {-# INLINE ix #-} type instance IxValue (Array.Array i e) = e -- | -- @ -- arr '!' i ≡ arr 'Control.Lens.Getter.^.' 'ix' i -- arr '//' [(i,e)] ≡ 'ix' i 'Control.Lens.Setter..~' e '$' arr -- @ instance Ix i => Ixed (Array.Array i e) where ix i f arr | inRange (bounds arr) i = f (arr Array.! i) <&> \e -> arr Array.// [(i,e)] | otherwise = pure arr {-# INLINE ix #-} type instance IxValue (UArray i e) = e -- | -- @ -- arr '!' i ≡ arr 'Control.Lens.Getter.^.' 'ix' i -- arr '//' [(i,e)] ≡ 'ix' i 'Control.Lens.Setter..~' e '$' arr -- @ instance (IArray UArray e, Ix i) => Ixed (UArray i e) where ix i f arr | inRange (bounds arr) i = f (arr Array.! i) <&> \e -> arr Array.// [(i,e)] | otherwise = pure arr {-# INLINE ix #-} type instance IxValue (Vector.Vector a) = a instance Ixed (Vector.Vector a) where ix i f v | 0 <= i && i < Vector.length v = f (v Vector.! i) <&> \a -> v Vector.// [(i, a)] | otherwise = pure v {-# INLINE ix #-} type instance IxValue (Prim.Vector a) = a instance Prim a => Ixed (Prim.Vector a) where ix i f v | 0 <= i && i < Prim.length v = f (v Prim.! i) <&> \a -> v Prim.// [(i, a)] | otherwise = pure v {-# INLINE ix #-} type instance IxValue (Storable.Vector a) = a instance Storable a => Ixed (Storable.Vector a) where ix i f v | 0 <= i && i < Storable.length v = f (v Storable.! i) <&> \a -> v Storable.// [(i, a)] | otherwise = pure v {-# INLINE ix #-} type instance IxValue (Unboxed.Vector a) = a instance Unbox a => Ixed (Unboxed.Vector a) where ix i f v | 0 <= i && i < Unboxed.length v = f (v Unboxed.! i) <&> \a -> v Unboxed.// [(i, a)] | otherwise = pure v {-# INLINE ix #-} type instance IxValue StrictT.Text = Char instance Ixed StrictT.Text where ix e f s = case StrictT.splitAt e s of (l, mr) -> case StrictT.uncons mr of Nothing -> pure s Just (c, xs) -> f c <&> \d -> StrictT.concat [l, StrictT.singleton d, xs] {-# INLINE ix #-} type instance IxValue LazyT.Text = Char instance Ixed LazyT.Text where ix e f s = case LazyT.splitAt e s of (l, mr) -> case LazyT.uncons mr of Nothing -> pure s Just (c, xs) -> f c <&> \d -> LazyT.append l (LazyT.cons d xs) {-# INLINE ix #-} type instance IxValue StrictB.ByteString = Word8 instance Ixed StrictB.ByteString where ix e f s = case StrictB.splitAt e s of (l, mr) -> case StrictB.uncons mr of Nothing -> pure s Just (c, xs) -> f c <&> \d -> StrictB.concat [l, StrictB.singleton d, xs] {-# INLINE ix #-} type instance IxValue LazyB.ByteString = Word8 instance Ixed LazyB.ByteString where -- TODO: we could be lazier, returning each chunk as it is passed ix e f s = case LazyB.splitAt e s of (l, mr) -> case LazyB.uncons mr of Nothing -> pure s Just (c, xs) -> f c <&> \d -> LazyB.append l (LazyB.cons d xs) {-# INLINE ix #-} -- | 'At' provides a 'Lens' that can be used to read, -- write or delete the value associated with a key in a 'Map'-like -- container on an ad hoc basis. -- -- An instance of 'At' should satisfy: -- -- @ -- 'ix' k ≡ 'at' k '.' 'traverse' -- @ class Ixed m => At m where -- | -- >>> Map.fromList [(1,"world")] ^.at 1 -- Just "world" -- -- >>> at 1 ?~ "hello" $ Map.empty -- fromList [(1,"hello")] -- -- /Note:/ 'Map'-like containers form a reasonable instance, but not 'Array'-like ones, where -- you cannot satisfy the 'Lens' laws. at :: Index m -> Lens' m (Maybe (IxValue m)) -- | Delete the value associated with a key in a 'Map'-like container -- -- @ -- 'sans' k = 'at' k .~ Nothing -- @ sans :: At m => Index m -> m -> m sans k m = m & at k .~ Nothing {-# INLINE sans #-} -- | An indexed version of 'at'. -- -- >>> Map.fromList [(1,"world")] ^@. iat 1 -- (1,Just "world") -- -- >>> iat 1 %@~ (\i x -> if odd i then Just "hello" else Nothing) $ Map.empty -- fromList [(1,"hello")] -- -- >>> iat 2 %@~ (\i x -> if odd i then Just "hello" else Nothing) $ Map.empty -- fromList [] -- iat :: At m => Index m -> IndexedLens' (Index m) m (Maybe (IxValue m)) iat i f = at i (indexed f i) {-# INLINE iat #-} instance At (Maybe a) where at ~() f = f {-# INLINE at #-} instance At (IntMap a) where #if MIN_VERSION_containers(0,5,8) at k f = IntMap.alterF f k #else at k f m = f mv <&> \r -> case r of Nothing -> maybe m (const (IntMap.delete k m)) mv Just v' -> IntMap.insert k v' m where mv = IntMap.lookup k m #endif {-# INLINE at #-} instance Ord k => At (Map k a) where #if MIN_VERSION_containers(0,5,8) at k f = Map.alterF f k #else at k f m = f mv <&> \r -> case r of Nothing -> maybe m (const (Map.delete k m)) mv Just v' -> Map.insert k v' m where mv = Map.lookup k m #endif {-# INLINE at #-} instance (Eq k, Hashable k) => At (HashMap k a) where at k f = HashMap.alterF f k {-# INLINE at #-} instance At IntSet where -- This is a gently modified copy of the implementation of `IntSet.alterF`. -- Unlike a `Set`, we don't have to worry about expensive comparisons from -- descending multiple times into an `IntSet`. We are careful to share the -- results of insertion or deletion across multiple positions in the -- `Functor`. at k f s = fmap choose (f (guard member_)) where member_ = IntSet.member k s (inserted, deleted) | member_ = (s, IntSet.delete k s) | otherwise = (IntSet.insert k s, s) choose (Just ~()) = inserted choose Nothing = deleted {-# INLINE at #-} instance Ord k => At (Set k) where #if MIN_VERSION_containers(0,6,3) at k f = Set.alterF (fmap isJust . f . guard) k #else at k f m = f mv <&> \r -> case r of Nothing -> maybe m (const (Set.delete k m)) mv Just ~() -> maybe (Set.insert k m) (const m) mv where mv = if Set.member k m then Just () else Nothing #endif {-# INLINE at #-} instance (Eq k, Hashable k) => At (HashSet k) where at k f s = HashSet.fromMap <$> HashMap.alterF f k (HashSet.toMap s) {-# INLINE at #-} -- | @'ix' :: 'Int' -> 'Traversal'' (a,a) a@ type instance IxValue (a,a2) = a instance (a~a2) => Ixed (a,a2) where ix p = elementOf each p -- | @'ix' :: 'Int' -> 'Traversal'' (a,a,a) a@ type instance IxValue (a,a2,a3) = a instance (a~a2, a~a3) => Ixed (a,a2,a3) where ix p = elementOf each p -- | @'ix' :: 'Int' -> 'Traversal'' (a,a,a,a) a@ type instance IxValue (a,a2,a3,a4) = a instance (a~a2, a~a3, a~a4) => Ixed (a,a2,a3,a4) where ix p = elementOf each p -- | @'ix' :: 'Int' -> 'Traversal'' (a,a,a,a,a) a@ type instance IxValue (a,a2,a3,a4,a5) = a instance (a~a2, a~a3, a~a4, a~a5) => Ixed (a,a2,a3,a4,a5) where ix p = elementOf each p -- | @'ix' :: 'Int' -> 'Traversal'' (a,a,a,a,a,a) a@ type instance IxValue (a,a2,a3,a4,a5,a6) = a instance (a~a2, a~a3, a~a4, a~a5, a~a6) => Ixed (a,a2,a3,a4,a5,a6) where ix p = elementOf each p -- | @'ix' :: 'Int' -> 'Traversal'' (a,a,a,a,a,a,a) a@ type instance IxValue (a,a2,a3,a4,a5,a6,a7) = a instance (a~a2, a~a3, a~a4, a~a5, a~a6, a~a7) => Ixed (a,a2,a3,a4,a5,a6,a7) where ix p = elementOf each p -- | @'ix' :: 'Int' -> 'Traversal'' (a,a,a,a,a,a,a,a) a@ type instance IxValue (a,a2,a3,a4,a5,a6,a7,a8) = a instance (a~a2, a~a3, a~a4, a~a5, a~a6, a~a7, a~a8) => Ixed (a,a2,a3,a4,a5,a6,a7,a8) where ix p = elementOf each p -- | @'ix' :: 'Int' -> 'Traversal'' (a,a,a,a,a,a,a,a,a) a@ type instance IxValue (a,a2,a3,a4,a5,a6,a7,a8,a9) = a instance (a~a2, a~a3, a~a4, a~a5, a~a6, a~a7, a~a8, a~a9) => Ixed (a,a2,a3,a4,a5,a6,a7,a8,a9) where ix p = elementOf each p