newtype-0.2.2.0: Control/Newtype.hs
{-# LANGUAGE CPP #-}
{-# LANGUAGE FlexibleInstances #-}
{-# LANGUAGE FunctionalDependencies #-}
{-# LANGUAGE MultiParamTypeClasses #-}
{-# LANGUAGE TypeFamilies #-}
#if __GLASGOW_HASKELL__ >= 704
{-# LANGUAGE DefaultSignatures #-}
#endif
{-# OPTIONS_GHC -fno-warn-unused-imports #-}
{- |
Module : Control.Newtype
SPDX-License-Identifier : BSD-3-Clause
The 'Newtype' typeclass and related functions: 'op', 'ala', 'ala'', 'under'. Primarly pulled from Conor McBride's Epigram work. Some examples:
>>> ala Sum foldMap [1,2,3,4] -- foldMaps the list ala the Sum newtype
10
>>> ala Product foldMap [1,2,3,4] -- foldMaps the list ala the Product newtype
24
>>> ala Endo foldMap [(+1), (+2), (subtract 1), (*2)] 3 -- foldMaps the list ala the Endo newtype
8
NB: 'Data.Foldable.foldMap' is a generalized @mconcatMap@ which is a generalized 'concatMap'.
This package includes 'Newtype' instances for all the (non-GHC\/foreign) newtypes in base (as seen in the examples). However, there are neat things you can do with this with /any/ @newtype@ and you should definitely define your own 'Newtype' instances for the power of this library. For example, see \"@'ala' Cont 'traverse'@\", with the proper 'Newtype' instance for @Cont@.
-}
module Control.Newtype
( Newtype(..)
, op
, ala
, ala'
, under
, over
, underF
, overF
) where
import Control.Applicative
import Control.Arrow
import Data.Fixed
import Data.Functor.Compose
import Data.Functor.Identity
import Data.Monoid
import Data.Ord
#if !MIN_VERSION_base(4,7,0)
-- necessary evil for 'Newtype Fixed'
import Unsafe.Coerce (unsafeCoerce)
#else
import Data.Coerce
#endif
-- | Given a @newtype@ @n@, we will always have the same unwrapped type @o@, meaning we can represent this with a fundep @n -> o@.
--
-- Any instance of this class just needs to let 'pack' equal to the newtype's constructor, and let 'unpack' destruct the @newtype@ with pattern matching.
--
-- Starting with @newtype-0.2.2.0@, default method implementations are provided using "Data.Coerce" for GHC 7.8 (i.e. @base-4.7.0.0@) and later, i.e.:
--
-- @
-- 'pack' = 'coerce'
-- 'unpack' = 'coerce'
-- @
--
-- When omitting the method definitions with GHC 7.4 and 7.6 a compile error will be triggered.
--
-- Consequently, if your code relies on these default methods make sure to state
--
-- > build-depends: newtype ^>= 0.2.2.0
--
-- In your @.cabal@ package description.
class Newtype n o | n -> o where
pack :: o -> n
unpack :: n -> o
#if __GLASGOW_HASKELL__ >= 704
default pack :: Coercible o n => o -> n
pack = coerce
default unpack :: Coercible n o => n -> o
unpack = coerce
#endif
#if __GLASGOW_HASKELL__ >= 704 && !MIN_VERSION_base(4,7,0)
-- Hack: We define a dummy 'Coercible' class to force a
-- missing-instance compile error when methods are not explicitly
-- defined
class Coercible o n
coerce :: a -> b
coerce = undefined
#endif
{- TODO: for newtype-0.3
This would be nice, but it breaks in odd ways with GHC < 7.
Oh, and it also makes the instances an extra line longer. :(
class Newtype n where
type Orig n
pack :: Orig n -> n
unpack :: n -> Orig n
-}
-- |
-- This function serves two purposes:
--
-- 1. Giving you the unpack of a @newtype@ without you needing to remember the name.
--
-- 2. Showing that the first parameter is /completely ignored/ on the value level, meaning the only reason you pass in the constructor is to provide type information. Typeclasses sure are neat.
op :: Newtype n o => (o -> n) -> n -> o
op _ = unpack
-- | The workhorse of the package. Given a pack and a \"higher order function\", it handles the packing and unpacking, and just sends you back a regular old function, with the type varying based on the /hof/ (higher-order function) you passed.
--
-- The reason for the signature of the hof is due to 'ala' not caring about structure. To illustrate why this is important, another function in this package is 'under'. It is not extremely useful; @under2@ might be more useful (with e.g., 'mappend'), but then we already digging the trench of \"What about @under3@? @under4@?\". The solution utilized here is to just hand off the \"packer\" to the hof. That way your structure can be imposed in the hof, whatever you may want it to be (e.g., List, Traversable).
ala :: (Newtype n o, Newtype n' o') => (o -> n) -> ((o -> n) -> b -> n') -> (b -> o')
ala pa hof = ala' pa hof id
-- | This is the original function seen in Conor McBride's work. The way it differs from the 'ala' function in this package, is that it provides an extra hook into the \"packer\" passed to the hof. However, this normally ends up being 'id', so 'ala' wraps this function and passes 'id' as the final parameter by default. If you want the convenience of being able to hook right into the hof, you may use this function.
ala' :: (Newtype n o, Newtype n' o') => (o -> n) -> ((a -> n) -> b -> n') -> (a -> o) -> (b -> o')
ala' _ hof f = unpack . hof (pack . f)
-- | A very simple operation involving running the function \"under\" the newtype. Suffers from the problems mentioned in the 'ala' function's documentation.
under :: (Newtype n o, Newtype n' o') => (o -> n) -> (n -> n') -> (o -> o')
under _ f = unpack . f . pack
-- | The opposite of 'under'. I.e., take a function which works on the underlying types, and switch it to a function that works on the newtypes.
--
-- @since 0.2
over :: (Newtype n o, Newtype n' o') => (o -> n) -> (o -> o') -> (n -> n')
over _ f = pack . f . unpack
-- | 'under' lifted into a 'Functor'.
--
-- @since 0.2
underF :: (Newtype n o, Newtype n' o', Functor f) => (o -> n) -> (f n -> f n') -> (f o -> f o')
underF _ f = fmap unpack . f . fmap pack
-- | 'over' lifted into a 'Functor'.
--
-- @since 0.2
overF :: (Newtype n o, Newtype n' o', Functor f) => (o -> n) -> (f o -> f o') -> (f n -> f n')
overF _ f = fmap pack . f . fmap unpack
instance Newtype All Bool where
pack = All
unpack (All a) = a
instance Newtype Any Bool where
pack = Any
unpack (Any a) = a
instance Newtype (Sum a) a where
pack = Sum
unpack (Sum a) = a
instance Newtype (Product a) a where
pack = Product
unpack (Product a) = a
-- | @since 0.2
instance Newtype (Kleisli m a b) (a -> m b) where
pack = Kleisli
unpack (Kleisli a) = a
instance Newtype (WrappedMonad m a) (m a) where
pack = WrapMonad
unpack (WrapMonad a) = a
instance Newtype (WrappedArrow a b c) (a b c) where
pack = WrapArrow
unpack (WrapArrow a) = a
instance Newtype (ZipList a) [a] where
pack = ZipList
unpack (ZipList a) = a
instance Newtype (Const a x) a where
pack = Const
unpack (Const a) = a
instance Newtype (Endo a) (a -> a) where
pack = Endo
unpack (Endo a) = a
instance Newtype (First a) (Maybe a) where
pack = First
unpack (First a) = a
instance Newtype (Last a) (Maybe a) where
pack = Last
unpack (Last a) = a
instance ArrowApply a => Newtype (ArrowMonad a b) (a () b) where
pack = ArrowMonad
unpack (ArrowMonad a) = a
-- | @since 0.2.1.0
instance Newtype (Fixed a) Integer where
#if MIN_VERSION_base(4,7,0)
pack = MkFixed
unpack (MkFixed x) = x
#else
-- 'Fixed' is a newtype, but its constructor wasn't exported before base-4.7.0
pack = unsafeCoerce
unpack = unsafeCoerce
#endif
-- | @since 0.2.1.0
instance Newtype (Dual a) a where
pack = Dual
unpack (Dual a) = a
#if MIN_VERSION_base(4,8,0)
-- | __NOTE__: Type & instance only available with @base ≥ 4.8.0@
--
-- @since 0.2.1.0
instance Newtype (Alt f a) (f a) where
pack = Alt
unpack (Alt x) = x
#endif
#if MIN_VERSION_base(4,6,0)
-- | __NOTE__: Type & instance only available with @base ≥ 4.6.0@
--
-- @since 0.2.1.0
instance Newtype (Down a) a where
pack = Down
unpack (Down a) = a
#endif
-- | @since 0.2.1.0
instance Newtype (Identity a) a where
pack = Identity
unpack (Identity a) = a
-- | @since 0.2.1.0
instance Newtype (Compose f g a) (f (g a)) where
pack = Compose
unpack (Compose x) = x
#if MIN_VERSION_base(4,12,0)
-- | __NOTE__: Type & instance only available with @base ≥ 4.12.0@
--
-- @since 0.2.1.0
instance Newtype (Ap f a) (f a) where
pack = Ap
unpack (Ap x) = x
#endif
-- TODO
-- Data.Semigroup
-- Data.Functor.Contravariant