{-# LANGUAGE CPP #-} {-# LANGUAGE FlexibleContexts #-} {-# LANGUAGE FlexibleInstances #-} {-# LANGUAGE MultiParamTypeClasses #-} {-# LANGUAGE FunctionalDependencies #-} #ifdef TRUSTWORTHY {-# LANGUAGE Trustworthy #-} #endif ----------------------------------------------------------------------------- -- | -- Module : Control.Lens.Cons -- Copyright : (C) 2012-13 Edward Kmett -- License : BSD-style (see the file LICENSE) -- Maintainer : Edward Kmett <ekmett@gmail.com> -- Stability : experimental -- Portability : non-portable -- ----------------------------------------------------------------------------- module Control.Lens.Cons ( -- * Cons Cons(..) , (<|) , cons , uncons , _head, _tail -- * Snoc , Snoc(..) , (|>) , snoc , unsnoc , _init, _last ) where import Control.Applicative import Control.Lens.Equality (simply) import Control.Lens.Fold import Control.Lens.Internal.Getter import Control.Lens.Internal.Review import Control.Lens.Prism import Control.Lens.Review import Control.Lens.Tuple import Control.Lens.Type import qualified Data.ByteString as StrictB import qualified Data.ByteString.Lazy as LazyB import Data.Functor.Identity import Data.Monoid import Data.Profunctor import qualified Data.Sequence as Seq import Data.Sequence hiding ((<|), (|>)) import qualified Data.Text as StrictT import qualified Data.Text.Lazy as LazyT import Data.Vector (Vector) import qualified Data.Vector as Vector import Data.Vector.Storable (Storable) import qualified Data.Vector.Storable as Storable import Data.Vector.Primitive (Prim) import qualified Data.Vector.Primitive as Prim import Data.Vector.Unboxed (Unbox) import qualified Data.Vector.Unboxed as Unbox import Data.Word -- $setup -- >>> :set -XNoOverloadedStrings -- >>> import Control.Lens -- >>> 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 infixr 5 <|, `cons` infixl 5 |>, `snoc` ------------------------------------------------------------------------------ -- Cons ------------------------------------------------------------------------------ -- | This class provides a way to attach or detach elements on the left -- side of a structure in a flexible manner. class (Profunctor p, Functor f) => Cons p f s t a b | s -> a, t -> b, s b -> t, t a -> s where -- | Most of the time this is a 'Prism'. -- -- @ -- '_Cons' :: 'Prism' [a] [b] (a, [a]) (b, [b]) -- '_Cons' :: 'Prism' ('Seq' a) ('Seq' b) (a, 'Seq' a) (b, 'Seq' b) -- '_Cons' :: 'Prism' ('Vector' a) ('Vector' b) (a, 'Vector' a) (b, 'Vector' b) -- '_Cons' :: 'Prism'' 'String' ('Char', 'String') -- '_Cons' :: 'Prism'' 'StrictT.Text' ('Char', 'StrictT.Text') -- '_Cons' :: 'Prism'' 'StrictB.ByteString' ('Word8', 'StrictB.ByteString') -- @ -- -- However, by including @p@ and @f@ in the class you can write instances that only permit 'uncons' -- or which only permit 'cons', or where '_head' and '_tail' are lenses and not traversals. _Cons :: Overloaded p f s t (a,s) (b,t) instance (Choice p, Applicative f) => Cons p f [a] [b] a b where _Cons = prism (uncurry (:)) $ \ aas -> case aas of (a:as) -> Right (a, as) [] -> Left [] {-# INLINE _Cons #-} instance (Choice p, Applicative f) => Cons p f (Seq a) (Seq b) a b where _Cons = prism (uncurry (Seq.<|)) $ \aas -> case viewl aas of a :< as -> Right (a, as) EmptyL -> Left mempty {-# INLINE _Cons #-} instance (Choice p, Applicative f) => Cons p f StrictB.ByteString StrictB.ByteString Word8 Word8 where _Cons = prism' (uncurry StrictB.cons) StrictB.uncons instance (Choice p, Applicative f) => Cons p f LazyB.ByteString LazyB.ByteString Word8 Word8 where _Cons = prism' (uncurry LazyB.cons) LazyB.uncons instance (Choice p, Applicative f) => Cons p f StrictT.Text StrictT.Text Char Char where _Cons = prism' (uncurry StrictT.cons) StrictT.uncons instance (Choice p, Applicative f) => Cons p f LazyT.Text LazyT.Text Char Char where _Cons = prism' (uncurry LazyT.cons) LazyT.uncons instance (Choice p, Applicative f) => Cons p f (Vector a) (Vector b) a b where _Cons = prism (uncurry Vector.cons) $ \v -> if Vector.null v then Left Vector.empty else Right (Vector.unsafeHead v, Vector.unsafeTail v) {-# INLINE _Cons #-} instance (Choice p, Applicative f, Prim a, Prim b) => Cons p f (Prim.Vector a) (Prim.Vector b) a b where _Cons = prism (uncurry Prim.cons) $ \v -> if Prim.null v then Left Prim.empty else Right (Prim.unsafeHead v, Prim.unsafeTail v) {-# INLINE _Cons #-} instance (Choice p, Applicative f, Storable a, Storable b) => Cons p f (Storable.Vector a) (Storable.Vector b) a b where _Cons = prism (uncurry Storable.cons) $ \v -> if Storable.null v then Left Storable.empty else Right (Storable.unsafeHead v, Storable.unsafeTail v) {-# INLINE _Cons #-} instance (Choice p, Applicative f, Unbox a, Unbox b) => Cons p f (Unbox.Vector a) (Unbox.Vector b) a b where _Cons = prism (uncurry Unbox.cons) $ \v -> if Unbox.null v then Left Unbox.empty else Right (Unbox.unsafeHead v, Unbox.unsafeTail v) {-# INLINE _Cons #-} -- | 'cons' an element onto a container. -- -- This is an infix alias for 'cons'. (<|) :: Cons Reviewed Identity s s a a => a -> s -> s (<|) = curry (simply review _Cons) {-# INLINE (<|) #-} -- | 'cons' an element onto a container. cons :: Cons Reviewed Identity s s a a => a -> s -> s cons = curry (simply review _Cons) {-# INLINE cons #-} -- | Attempt to extract the left-most element from a container, and a version of the container without that element. uncons :: Cons (->) (Accessor (First (a, s))) s s a a => s -> Maybe (a, s) uncons = simply preview _Cons {-# INLINE uncons #-} -- | A 'Traversal' reading and writing to the 'head' of a /non-empty/ container. -- -- >>> [a,b,c]^? _head -- Just a -- -- >>> [a,b,c] & _head .~ d -- [d,b,c] -- -- >>> [a,b,c] & _head %~ f -- [f a,b,c] -- -- >>> [] & _head %~ f -- [] -- -- >>> [1,2,3]^?!_head -- 1 -- -- >>> []^?_head -- Nothing -- -- >>> [1,2]^?_head -- Just 1 -- -- >>> [] & _head .~ 1 -- [] -- -- >>> [0] & _head .~ 2 -- [2] -- -- >>> [0,1] & _head .~ 2 -- [2,1] -- -- This isn't limited to lists. -- -- For instance you can also 'Data.Traversable.traverse' the head of a 'Seq': -- -- >>> Seq.fromList [a,b,c,d] & _head %~ f -- fromList [f a,b,c,d] -- -- >>> Seq.fromList [] ^? _head -- Nothing -- -- >>> Seq.fromList [a,b,c,d] ^? _head -- Just a -- -- @ -- '_head' :: 'Traversal'' [a] a -- '_head' :: 'Traversal'' ('Seq' a) a -- '_head' :: 'Traversal'' ('Vector' a) a -- @ _head :: Cons (->) f s s a a => LensLike' f s a _head = _Cons._1 {-# INLINE _head #-} -- | A 'Traversal' reading and writing to the 'tail' of a /non-empty/ container. -- -- >>> [a,b] & _tail .~ [c,d,e] -- [a,c,d,e] -- -- >>> [] & _tail .~ [a,b] -- [] -- -- >>> [a,b,c,d,e] & _tail.traverse %~ f -- [a,f b,f c,f d,f e] -- -- >>> [1,2] & _tail .~ [3,4,5] -- [1,3,4,5] -- -- >>> [] & _tail .~ [1,2] -- [] -- -- >>> [a,b,c]^?_tail -- Just [b,c] -- -- >>> [1,2]^?!_tail -- [2] -- -- >>> "hello"^._tail -- "ello" -- -- >>> ""^._tail -- "" -- -- This isn't limited to lists. For instance you can also 'Control.Traversable.traverse' the tail of a 'Seq'. -- -- >>> Seq.fromList [a,b] & _tail .~ Seq.fromList [c,d,e] -- fromList [a,c,d,e] -- -- >>> Seq.fromList [a,b,c] ^? _tail -- Just (fromList [b,c]) -- -- >>> Seq.fromList [] ^? _tail -- Nothing -- -- @ -- '_tail' :: 'Traversal'' [a] [a] -- '_tail' :: 'Traversal'' ('Seq' a) ('Seq' a) -- '_tail' :: 'Traversal'' ('Vector' a) ('Vector' a) -- @ _tail :: Cons (->) f s s a a => LensLike' f s s _tail = _Cons._2 {-# INLINE _tail #-} ------------------------------------------------------------------------------ -- Snoc ------------------------------------------------------------------------------ -- | This class provides a way to attach or detach elements on the right -- side of a structure in a flexible manner. class (Profunctor p, Functor f) => Snoc p f s t a b | s -> a, t -> b, s b -> t, t a -> s where -- | Most of the time this is a 'Prism'. -- -- @ -- '_Snoc' :: 'Prism' [a] [b] ([a], a) ([b], b) -- '_Snoc' :: 'Prism' ('Seq' a) ('Seq' b) ('Seq' a, a) ('Seq' b, b) -- '_Snoc' :: 'Prism' ('Vector' a) ('Vector' b) ('Vector' a, a) ('Vector' b, b) -- '_Snoc' :: 'Prism'' 'String' ('String', 'Char') -- '_Snoc' :: 'Prism'' 'StrictT.Text' ('StrictT.Text', 'Char') -- '_Snoc' :: 'Prism'' 'StrictB.ByteString' ('StrictB.ByteString', 'Word8') -- @ -- -- However, by including @p@ and @f@ in the class you can write instances that only permit 'unsnoc' -- or which only permit 'snoc' or where '_init' and '_last' are lenses and not traversals. _Snoc :: Overloaded p f s t (s,a) (t,b) instance (Choice p, Applicative f) => Snoc p f [a] [b] a b where _Snoc = prism (\(as,a) -> as Prelude.++ [a]) $ \aas -> if Prelude.null aas then Left [] else Right (Prelude.init aas, Prelude.last aas) {-# INLINE _Snoc #-} instance (Choice p, Applicative f) => Snoc p f (Seq a) (Seq b) a b where _Snoc = prism (uncurry (Seq.|>)) $ \aas -> case viewr aas of as :> a -> Right (as, a) EmptyR -> Left mempty {-# INLINE _Snoc #-} instance (Choice p, Applicative f) => Snoc p f (Vector a) (Vector b) a b where _Snoc = prism (uncurry Vector.snoc) $ \v -> if Vector.null v then Left Vector.empty else Right (Vector.unsafeInit v, Vector.unsafeLast v) {-# INLINE _Snoc #-} instance (Choice p, Applicative f, Prim a, Prim b) => Snoc p f (Prim.Vector a) (Prim.Vector b) a b where _Snoc = prism (uncurry Prim.snoc) $ \v -> if Prim.null v then Left Prim.empty else Right (Prim.unsafeInit v, Prim.unsafeLast v) {-# INLINE _Snoc #-} instance (Choice p, Applicative f, Storable a, Storable b) => Snoc p f (Storable.Vector a) (Storable.Vector b) a b where _Snoc = prism (uncurry Storable.snoc) $ \v -> if Storable.null v then Left Storable.empty else Right (Storable.unsafeInit v, Storable.unsafeLast v) {-# INLINE _Snoc #-} instance (Choice p, Applicative f, Unbox a, Unbox b) => Snoc p f (Unbox.Vector a) (Unbox.Vector b) a b where _Snoc = prism (uncurry Unbox.snoc) $ \v -> if Unbox.null v then Left Unbox.empty else Right (Unbox.unsafeInit v, Unbox.unsafeLast v) {-# INLINE _Snoc #-} instance (Choice p, Applicative f) => Snoc p f StrictB.ByteString StrictB.ByteString Word8 Word8 where _Snoc = prism (uncurry StrictB.snoc) $ \v -> if StrictB.null v then Left StrictB.empty else Right (StrictB.init v, StrictB.last v) {-# INLINE _Snoc #-} instance (Choice p, Applicative f) => Snoc p f LazyB.ByteString LazyB.ByteString Word8 Word8 where _Snoc = prism (uncurry LazyB.snoc) $ \v -> if LazyB.null v then Left LazyB.empty else Right (LazyB.init v, LazyB.last v) {-# INLINE _Snoc #-} instance (Choice p, Applicative f) => Snoc p f StrictT.Text StrictT.Text Char Char where _Snoc = prism (uncurry StrictT.snoc) $ \v -> if StrictT.null v then Left StrictT.empty else Right (StrictT.init v, StrictT.last v) {-# INLINE _Snoc #-} instance (Choice p, Applicative f) => Snoc p f LazyT.Text LazyT.Text Char Char where _Snoc = prism (uncurry LazyT.snoc) $ \v -> if LazyT.null v then Left LazyT.empty else Right (LazyT.init v, LazyT.last v) {-# INLINE _Snoc #-} -- | A 'Traversal' reading and replacing all but the a last element of a /non-empty/ container. -- -- >>> [a,b,c,d]^?_init -- Just [a,b,c] -- -- >>> []^?_init -- Nothing -- -- >>> [a,b] & _init .~ [c,d,e] -- [c,d,e,b] -- -- >>> [] & _init .~ [a,b] -- [] -- -- >>> [a,b,c,d] & _init.traverse %~ f -- [f a,f b,f c,d] -- -- >>> [1,2,3]^?_init -- Just [1,2] -- -- >>> [1,2,3,4]^?!_init -- [1,2,3] -- -- >>> "hello"^._init -- "hell" -- -- >>> ""^._init -- "" -- -- @ -- '_init' :: 'Traversal'' [a] [a] -- '_init' :: 'Traversal'' ('Seq' a) ('Seq' a) -- '_init' :: 'Traversal'' ('Vector' a) ('Vector' a) -- @ _init :: Snoc (->) f s s a a => LensLike' f s s _init = _Snoc._1 {-# INLINE _init #-} -- | A 'Traversal' reading and writing to the last element of a /non-empty/ container. -- -- >>> [a,b,c]^?!_last -- c -- -- >>> []^?_last -- Nothing -- -- >>> [a,b,c] & _last %~ f -- [a,b,f c] -- -- >>> [1,2]^?_last -- Just 2 -- -- >>> [] & _last .~ 1 -- [] -- -- >>> [0] & _last .~ 2 -- [2] -- -- >>> [0,1] & _last .~ 2 -- [0,2] -- -- This 'Traversal' is not limited to lists, however. We can also work with other containers, such as a 'Vector'. -- -- >>> Vector.fromList "abcde" ^? _last -- Just 'e' -- -- >>> Vector.empty ^? _last -- Nothing -- -- >>> Vector.fromList "abcde" & _last .~ 'Q' -- fromList "abcdQ" -- -- @ -- '_last' :: 'Traversal'' [a] a -- '_last' :: 'Traversal'' ('Seq' a) a -- '_last' :: 'Traversal'' ('Vector' a) a -- @ _last :: Snoc (->) f s s a a => LensLike' f s a _last = _Snoc._2 {-# INLINE _last #-} -- | 'snoc' an element onto the end of a container. -- -- This is an infix alias for 'snoc'. (|>) :: Snoc Reviewed Identity s s a a => s -> a -> s (|>) = curry (simply review _Snoc) {-# INLINE (|>) #-} -- | 'snoc' an element onto the end of a container. snoc :: Snoc Reviewed Identity s s a a => s -> a -> s snoc = curry (simply review _Snoc) {-# INLINE snoc #-} -- | Attempt to extract the right-most element from a container, and a version of the container without that element. unsnoc :: Snoc (->) (Accessor (First (s, a))) s s a a => s -> Maybe (s, a) unsnoc s = simply preview _Snoc s {-# INLINE unsnoc #-}