Copyright | 2008-2013 Edward Kmett |
---|---|
License | BSD |
Maintainer | Edward Kmett <ekmett@gmail.com> |
Stability | experimental |
Portability | rank 2 types, MPTCs, fundeps |
Safe Haskell | Trustworthy |
Language | Haskell98 |
Synopsis
- class (Functor f, Representable u) => Adjunction f u | f -> u, u -> f where
- unit :: a -> u (f a)
- counit :: f (u a) -> a
- leftAdjunct :: (f a -> b) -> a -> u b
- rightAdjunct :: (a -> u b) -> f a -> b
- adjuncted :: (Adjunction f u, Profunctor p, Functor g) => p (a -> u b) (g (c -> u d)) -> p (f a -> b) (g (f c -> d))
- tabulateAdjunction :: Adjunction f u => (f () -> b) -> u b
- indexAdjunction :: Adjunction f u => u b -> f a -> b
- zapWithAdjunction :: Adjunction f u => (a -> b -> c) -> u a -> f b -> c
- zipR :: Adjunction f u => (u a, u b) -> u (a, b)
- unzipR :: Functor u => u (a, b) -> (u a, u b)
- unabsurdL :: Adjunction f u => f Void -> Void
- absurdL :: Void -> f Void
- cozipL :: Adjunction f u => f (Either a b) -> Either (f a) (f b)
- uncozipL :: Functor f => Either (f a) (f b) -> f (Either a b)
- extractL :: Adjunction f u => f a -> a
- duplicateL :: Adjunction f u => f a -> f (f a)
- splitL :: Adjunction f u => f a -> (a, f ())
- unsplitL :: Functor f => a -> f () -> f a
Documentation
class (Functor f, Representable u) => Adjunction f u | f -> u, u -> f where #
An adjunction between Hask and Hask.
Minimal definition: both unit
and counit
or both leftAdjunct
and rightAdjunct
, subject to the constraints imposed by the
default definitions that the following laws should hold.
unit = leftAdjunct id counit = rightAdjunct id leftAdjunct f = fmap f . unit rightAdjunct f = counit . fmap f
Any implementation is required to ensure that leftAdjunct
and
rightAdjunct
witness an isomorphism from Nat (f a, b)
to
Nat (a, g b)
rightAdjunct unit = id leftAdjunct counit = id
leftAdjunct :: (f a -> b) -> a -> u b #
rightAdjunct :: (a -> u b) -> f a -> b #
Instances
Adjunction Par1 Par1 # | |
Adjunction Identity Identity # | |
Adjunction (V1 :: Type -> Type) (U1 :: Type -> Type) # | |
Adjunction f u => Adjunction (Free f) (Cofree u) # | |
Adjunction ((,) e) ((->) e :: Type -> Type) # | |
Defined in Data.Functor.Adjunction leftAdjunct :: ((e, a) -> b) -> a -> e -> b # rightAdjunct :: (a -> e -> b) -> (e, a) -> b # | |
Adjunction f g => Adjunction (Rec1 f) (Rec1 g) # | |
Adjunction w m => Adjunction (EnvT e w) (ReaderT e m) # | |
Adjunction f g => Adjunction (IdentityT f) (IdentityT g) # | |
Adjunction m w => Adjunction (WriterT s m) (TracedT s w) # | |
(Adjunction f g, Adjunction f' g') => Adjunction (f :+: f') (g :*: g') # | |
(Adjunction f g, Adjunction f' g') => Adjunction (Sum f f') (Product g g') # | |
(Adjunction f g, Adjunction f' g') => Adjunction (f' :.: f) (g :.: g') # | |
(Adjunction f g, Adjunction f' g') => Adjunction (Compose f' f) (Compose g g') # | |
adjuncted :: (Adjunction f u, Profunctor p, Functor g) => p (a -> u b) (g (c -> u d)) -> p (f a -> b) (g (f c -> d)) #
leftAdjunct
and rightAdjunct
form two halves of an isomorphism.
This can be used with the combinators from the lens
package.
adjuncted
::Adjunction
f u =>Iso'
(f a -> b) (a -> u b)
tabulateAdjunction :: Adjunction f u => (f () -> b) -> u b #
Every right adjoint is representable by its left adjoint applied to a unit element
Use this definition and the primitives in Data.Functor.Representable to meet the requirements of the superclasses of Representable.
indexAdjunction :: Adjunction f u => u b -> f a -> b #
This definition admits a default definition for the
index
method of 'Index", one of the superclasses of
Representable.
zapWithAdjunction :: Adjunction f u => (a -> b -> c) -> u a -> f b -> c #
zipR :: Adjunction f u => (u a, u b) -> u (a, b) #
A right adjoint functor admits an intrinsic notion of zipping
unabsurdL :: Adjunction f u => f Void -> Void #
A left adjoint must be inhabited, or we can derive bottom.
cozipL :: Adjunction f u => f (Either a b) -> Either (f a) (f b) #
And a left adjoint must be inhabited by exactly one element
uncozipL :: Functor f => Either (f a) (f b) -> f (Either a b) #
Every functor in Haskell permits uncozipping
extractL :: Adjunction f u => f a -> a #
duplicateL :: Adjunction f u => f a -> f (f a) #
splitL :: Adjunction f u => f a -> (a, f ()) #