{-# LANGUAGE Rank2Types #-} ----------------------------------------------------------------------------- -- | -- Module : Control.Lens.Getter -- Copyright : (C) 2012 Edward Kmett -- License : BSD-style (see the file LICENSE) -- Maintainer : Edward Kmett <ekmett@gmail.com> -- Stability : provisional -- Portability : Rank2Types -- -- -- A @'Getter' a c@ is just any function @(a -> c)@, which we've flipped into continuation -- passing style, @(c -> r) -> a -> r@ and decorated with 'Accessor' to obtain -- -- @type 'Getting' r a c = (c -> 'Accessor' r c) -> a -> 'Accessor' r a@ -- -- If we restrict access to knowledge about the type 'r' and can work for any d and b, we could get: -- -- @type 'Getter' a c = forall r. 'Getting' r a c@ -- -- But we actually hide the use of 'Accessor' behind a class 'Gettable' to error messages from -- type class resolution rather than at unification time, where they are much uglier. -- -- @type 'Getter' a c = forall f. 'Gettable' f => (c -> f c) -> a -> f a@ -- -- Everything you can do with a function, you can do with a 'Getter', but note that because of the -- continuation passing style ('.') composes them in the opposite order. -- -- Since it is only a function, every 'Getter' obviously only retrieves a single value for a given -- input. -- ---------------------------------------------------------------------------- module Control.Lens.Getter ( -- * Getters Getter , Getting , Gettable(..) , Accessor(..) -- * Building Getters , to -- * Combinators for Getters and Folds , (^.), (^$) , view , views , use , uses , query , queries ) where import Control.Applicative import Control.Applicative.Backwards import Control.Lens.Internal import Control.Monad.Reader.Class as Reader import Control.Monad.State.Class as State import Data.Functor.Compose import Data.Monoid infixl 8 ^. infixr 0 ^$ --------------- -- Getters --------------- -- | A 'Getter' describes how to retrieve a single value in a way that can be composed with -- other lens-like constructions. -- -- Unlike a 'Control.Lens.Type.Lens' a 'Getter' is read-only. Since a 'Getter' cannot be used to write back -- there are no lens laws that can be applied to it. In fact, it is isomorphic to an arbitrary function from @(a -> c)@. -- -- Moreover, a 'Getter' can be used directly as a 'Control.Lens.Fold.Fold', since it just ignores the 'Applicative'. type Getter a c = forall f. Gettable f => (c -> f c) -> a -> f a -- | Build a 'Getter' from an arbitrary Haskell function. -- -- @'to' f . 'to' g = 'to' (g . f)@ -- -- @a '^.' 'to' f = f a@ -- -- >>> import Control.Lens -- >>> (0, -5)^._2.to abs -- 5 to :: (a -> c) -> Getter a c to f g = coerce . g . f {-# INLINE to #-} -- | -- Most 'Getter' combinators are able to be used with both a 'Getter' or a 'Control.Lens.Fold.Fold' in -- limited situations, to do so, they need to be monomorphic in what we are going to -- extract with 'Const'. To be compatible with 'Control.Lens.Type.Lens', 'Control.Lens.Traversal.Traversal' and 'Control.Lens.Iso.Iso' we also -- restricted choices of the irrelevant b and d parameters. -- -- If a function accepts a @'Getting' r a c@, then when @r@ is a 'Monoid', then you can pass a 'Control.Lens.Fold.Fold' (or 'Control.Lens.Traversal.Traversal'), otherwise you can only pass this a -- 'Getter' or 'Control.Lens.Type.Lens'. type Getting r a c = (c -> Accessor r c) -> a -> Accessor r a ----------------------------------------------------------------------------- -- Gettables & Accessors ----------------------------------------------------------------------------- -- | Generalizing 'Const' so we can apply simple 'Applicative' transformations to it -- and so we can get nicer error messages -- -- A 'Gettable' 'Functor' ignores its argument, which it carries solely as a phantom -- type parameter. -- -- To ensure this, an instance of 'Gettable' is required to satisfy: -- -- @'id' = 'fmap' f = 'coerce'@ class Functor f => Gettable f where -- | Replace the phantom type argument. coerce :: f a -> f b instance Gettable (Const r) where coerce (Const m) = Const m instance Gettable f => Gettable (Backwards f) where coerce = Backwards . coerce . forwards instance (Functor f, Gettable g) => Gettable (Compose f g) where coerce = Compose . fmap coerce . getCompose -- | This instance is a lie, but it is a useful lie. instance Gettable f => Gettable (ElementOf f) where coerce (ElementOf m) = ElementOf $ \i -> case m i of Searching _ _ -> NotFound "coerced while searching" -- er... Found j as -> Found j (coerce as) NotFound s -> NotFound s -- | Used instead of 'Const' to report -- -- @No instance of ('Control.Lens.Setter.Settable' 'Accessor')@ -- -- when the user attempts to misuse a 'Control.Lens.Setter.Setter' as a 'Getter', -- rather than a monolithic unification error. newtype Accessor r a = Accessor { runAccessor :: r } instance Functor (Accessor r) where fmap _ (Accessor m) = Accessor m instance Gettable (Accessor r) where coerce (Accessor m) = Accessor m instance Monoid r => Applicative (Accessor r) where pure _ = Accessor mempty Accessor a <*> Accessor b = Accessor (mappend a b) ------------------------------- -- Getting Values ------------------------------- -- | View the value pointed to by a 'Getter', 'Control.Lens.Iso.Iso' or 'Control.Lens.Type.Lens' or the result of folding over -- all the results of a 'Control.Lens.Fold.Fold' or 'Control.Lens.Traversal.Traversal' that points at a monoidal values. -- -- It may be useful to think of 'view' as having these more restrictive signatures: -- -- @'view' . 'to' = 'id'@ -- -- >>> import Control.Lens -- >>> view _2 (1,"hello") -- "hello" -- -- @ -- view :: 'Getter' a c -> a -> c -- view :: 'Monoid' m => 'Control.Lens.Fold.Fold' a m -> a -> m -- view :: 'Control.Lens.Type.Simple' 'Control.Lens.Iso.Iso' a c -> a -> c -- view :: 'Control.Lens.Type.Simple' 'Control.Lens.Type.Lens' a c -> a -> c -- view :: 'Monoid' m => 'Control.Lens.Type.Simple' 'Control.Lens.Traversal.Traversal' a m -> a -> m -- @ view :: Getting c a c -> a -> c view l = runAccessor . l Accessor {-# INLINE view #-} -- | View the value of a 'Getter', 'Control.Lens.Iso.Iso', 'Control.Lens.Type.Lens' or the result of folding over the -- result of mapping the targets of a 'Control.Lens.Fold.Fold' or 'Control.Lens.Traversal.Traversal'. -- -- It may be useful to think of 'views' as having these more restrictive signatures: -- -- >>> import Control.Lens -- >>> views _2 length (1,"hello") -- 5 -- -- @ -- views :: 'Getter' a c -> (c -> d) -> a -> d -- views :: 'Monoid' m => 'Control.Lens.Fold.Fold' a c -> (c -> m) -> a -> m -- views :: 'Control.Lens.Type.Simple' 'Control.Lens.Iso.Iso' a c -> (c -> d) -> a -> d -- views :: 'Control.Lens.Type.Simple' 'Control.Lens.Type.Lens' a c -> (c -> d) -> a -> d -- views :: 'Monoid' m => 'Control.Lens.Type.Simple' 'Control.Lens.Traversal.Traversal' a c -> (c -> m) -> a -> m -- @ views :: Getting m a c -> (c -> m) -> a -> m views l f = runAccessor . l (Accessor . f) {-# INLINE views #-} -- | View the value pointed to by a 'Getter', 'Control.Lens.Iso.Iso' or 'Control.Lens.Type.Lens' or the result of folding over -- all the results of a 'Control.Lens.Fold.Fold' or 'Control.Lens.Traversal.Traversal' that points at a monoidal values. -- -- This is the same operation as 'view', only infix. -- -- >>> import Control.Lens -- >>> _2 ^$ (1, "hello") -- "hello" -- -- @ -- (^$) :: 'Getter' a c -> a -> c -- (^$) :: 'Monoid' m => 'Control.Lens.Fold.Fold' a m -> a -> m -- (^$) :: 'Control.Lens.Type.Simple' 'Control.Lens.Iso.Iso' a c -> a -> c -- (^$) :: 'Control.Lens.Type.Simple' 'Control.Lens.Type.Lens' a c -> a -> c -- (^$) :: 'Monoid' m => 'Control.Lens.Type.Simple' 'Control.Lens.Traversal.Traversal' a m -> a -> m -- @ (^$) :: Getting c a c -> a -> c l ^$ a = runAccessor (l Accessor a) {-# INLINE (^$) #-} -- | View the value pointed to by a 'Getter' or 'Control.Lens.Type.Lens' or the result of folding over -- all the results of a 'Control.Lens.Fold.Fold' or 'Control.Lens.Traversal.Traversal' that points at a monoidal values. -- -- This is the same operation as 'view' with the arguments flipped. -- -- The fixity and semantics are such that subsequent field accesses can be -- performed with ('Prelude..') -- -- >>> :m + Data.Complex Control.Lens -- >>> ((0, 1 :+ 2), 3)^._1._2.to magnitude -- 2.23606797749979 -- -- @ -- (^.) :: a -> 'Getter' a c -> c -- (^.) :: 'Monoid' m => a -> 'Control.Lens.Fold.Fold' a m -> m -- (^.) :: a -> 'Control.Lens.Type.Simple' 'Control.Lens.Iso.Iso' a c -> c -- (^.) :: a -> 'Control.Lens.Type.Simple' 'Control.Lens.Type.Lens' a c -> c -- (^.) :: 'Monoid' m => a -> 'Control.Lens.Type.Simple' 'Control.Lens.Traversal.Traversal' a m -> m -- @ (^.) :: a -> Getting c a c -> c a ^. l = runAccessor (l Accessor a) {-# INLINE (^.) #-} ------------------------------------------------------------------------------ -- MonadReader ------------------------------------------------------------------------------ -- | -- Query the target of a 'Control.Lens.Type.Lens', 'Control.Lens.Iso.Iso' or 'Getter' in the current state, or use a -- summary of a 'Control.Lens.Fold.Fold' or 'Control.Lens.Traversal.Traversal' that points to a monoidal value. -- -- @ -- query :: 'MonadReader' a m => 'Getter' a c -> m c -- query :: ('MonadReader' a m, 'Monoid' c) => 'Control.Lens.Fold.Fold' a c -> m c -- query :: 'MonadReader' a m => 'Control.Lens.Type.Simple' 'Control.Lens.Iso.Iso' a c -> m c -- query :: 'MonadReader' a m => 'Control.Lens.Type.Simple' 'Control.Lens.Type.Lens' a c -> m c -- query :: ('MonadReader' a m, 'Monoid' c) => 'Control.Lens.Type.Simple' 'Control.Lens.Traversal.Traversal' a c -> m c -- @ query :: MonadReader a m => Getting c a c -> m c query l = Reader.asks (^.l) {-# INLINE query #-} -- | -- Use the target of a 'Control.Lens.Type.Lens', 'Control.Lens.Iso.Iso' or 'Getter' in the current state, or use a -- summary of a 'Control.Lens.Fold.Fold' or 'Control.Lens.Traversal.Traversal' that points to a monoidal value. -- -- @ -- queries :: 'MonadReader' a m => 'Getter' a c -> (c -> e) -> m e -- queries :: ('MonadReader' a m, 'Monoid' c) => 'Control.Lens.Fold.Fold' a c -> (c -> e) -> m e -- queries :: 'MonadReader' a m => 'Control.Lens.Type.Simple' 'Control.Lens.Iso.Iso' a c -> (c -> e) -> m e -- queries :: 'MonadReader' a m => 'Control.Lens.Type.Simple' 'Control.Lens.Type.Lens' a c -> (c -> e) -> m e -- queries :: ('MonadReader' a m, 'Monoid' c) => 'Control.Lens.Type.Simple' 'Control.Lens.Traversal.Traversal' a c -> (c -> e) -> m e -- @ queries :: MonadReader a m => Getting e a c -> (c -> e) -> m e queries l f = Reader.asks (views l f) {-# INLINE queries #-} ------------------------------------------------------------------------------ -- MonadState ------------------------------------------------------------------------------ -- | -- Use the target of a 'Control.Lens.Type.Lens', 'Control.Lens.Iso.Iso', or 'Getter' in the current state, or use a -- summary of a 'Control.Lens.Fold.Fold' or 'Control.Lens.Traversal.Traversal' that points to a monoidal value. -- -- @ -- use :: 'MonadState' a m => 'Getter' a c -> m c -- use :: ('MonadState' a m, 'Monoid' r) => 'Control.Lens.Fold.Fold' a r -> m r -- use :: 'MonadState' a m => 'Control.Lens.Type.Simple' 'Control.Lens.Iso.Iso' a c -> m c -- use :: 'MonadState' a m => 'Control.Lens.Type.Simple' 'Control.Lens.Type.Lens' a c -> m c -- use :: ('MonadState' a m, 'Monoid' r) => 'Control.Lens.Type.Simple' 'Control.Lens.Traversal.Traversal' a r -> m r -- @ use :: MonadState a m => Getting c a c -> m c use l = State.gets (view l) {-# INLINE use #-} -- | -- Use the target of a 'Control.Lens.Type.Lens', 'Control.Lens.Iso.Iso' or 'Getter' in the current state, or use a -- summary of a 'Control.Lens.Fold.Fold' or 'Control.Lens.Traversal.Traversal' that points to a monoidal value. -- -- @ -- uses :: 'MonadState' a m => 'Getter' a c -> (c -> e) -> m e -- uses :: ('MonadState' a m, 'Monoid' r) => 'Control.Lens.Fold.Fold' a c -> (c -> r) -> m r -- uses :: 'MonadState' a m => 'Control.Lens.Type.Simple' 'Control.Lens.Type.Lens' a c -> (c -> e) -> m e -- uses :: 'MonadState' a m => 'Control.Lens.Type.Simple' 'Control.Lens.Iso.Iso' a c -> (c -> e) -> m e -- uses :: ('MonadState' a m, 'Monoid' r) => 'Control.Lens.Type.Simple' 'Control.Lens.Traversal.Traversal' a c -> (c -> r) -> m r -- @ uses :: MonadState a m => Getting e a c -> (c -> e) -> m e uses l f = State.gets (views l f) {-# INLINE uses #-}