Portability	portable
Stability	provisional
Maintainer	Edward Kmett <ekmett@gmail.com>
Safe Haskell	Unsafe

Data.Profunctor.Unsafe

Contents

Profunctors

Description

For a good explanation of profunctors in Haskell see Dan Piponi's article:

http://blog.sigfpe.com/2011/07/profunctors-in-haskell.html

This module includes unsafe composition operators that are useful in practice when it comes to generating optimal core in GHC.

If you import this module you are taking upon yourself the obligation that you will only call the operators with # in their names with functions that are operationally identity such as newtype constructors or the field accessor of a newtype.

If you are ever in doubt, use rmap or lmap.

Synopsis

Profunctors

class Profunctor p whereSource

Formally, the class Profunctor represents a profunctor from Hask -> Hask.

Intuitively it is a bifunctor where the first argument is contravariant and the second argument is covariant.

You can define a Profunctor by either defining dimap or by defining both lmap and rmap.

If you supply dimap, you should ensure that:

dimap id id ≡ id

If you supply lmap and rmap, ensure:

 lmap id ≡ id
 rmap id ≡ id

If you supply both, you should also ensure:

dimap f g ≡ lmap f . rmap g

These ensure by parametricity:

 dimap (f . g) (h . i) ≡ dimap g h . dimap f i
 lmap (f . g) ≡ lmap g . lmap f
 rmap (f . g) ≡ rmap f . rmap g

Methods

dimap :: (a -> b) -> (c -> d) -> p b c -> p a dSource

Map over both arguments at the same time.

dimap f g ≡ lmap f . rmap g

lmap :: (a -> b) -> p b c -> p a cSource

Map the first argument contravariantly.

lmap f ≡ dimap f id

rmap :: (b -> c) -> p a b -> p a cSource

Map the second argument covariantly.

rmap ≡ dimap id

(#.) :: (b -> c) -> p a b -> p a cSource

Strictly map the second argument argument covariantly with a function that is assumed operationally to be a cast, such as a newtype constructor.

Note: This operation is explicitly unsafe since an implementation may choose to use unsafeCoerce to implement this combinator and it has no way to validate that your function meets the requirements.

If you implement this combinator with unsafeCoerce, then you are taking upon yourself the obligation that you don't use GADT-like tricks to distinguish values.

If you import Data.Profunctor.Unsafe you are taking upon yourself the obligation that you will only call this with a first argument that is operationally identity.

The semantics of this function with respect to bottoms should match the default definition:

(#.) ≡ \f -> \p -> p `seq` rmap f p

(.#) :: p b c -> (a -> b) -> p a cSource

Strictly map the first argument argument contravariantly with a function that is assumed operationally to be a cast, such as a newtype constructor.

Note: This operation is explicitly unsafe since an implementation may choose to use unsafeCoerce to implement this combinator and it has no way to validate that your function meets the requirements.

If you implement this combinator with unsafeCoerce, then you are taking upon yourself the obligation that you don't use GADT-like tricks to distinguish values.

If you import Data.Profunctor.Unsafe you are taking upon yourself the obligation that you will only call this with a second argument that is operationally identity.

(.#) ≡ \p -> p `seq` \f -> lmap f p

Instances

Profunctor (->)
Monad m => Profunctor (Kleisli m)
Functor w => Profunctor (Cokleisli w)
Profunctor (Tagged *)
Profunctor (Forget r)
Arrow p => Profunctor (WrappedArrow p)
Functor f => Profunctor (DownStar f)
Functor f => Profunctor (UpStar f)
(Profunctor p, Profunctor q) => Profunctor (Procompose p q)
(Profunctor p, Profunctor q) => Profunctor (Rift p q)