Copyright | (c) Ross Paterson 2002 |
---|---|
License | BSD-style (see the LICENSE file in the distribution) |
Maintainer | libraries@haskell.org |
Stability | provisional |
Portability | portable |
Safe Haskell | Safe |
Language | Haskell2010 |
Basic arrow definitions, based on
- Generalising Monads to Arrows, by John Hughes, Science of Computer Programming 37, pp67-111, May 2000.
plus a couple of definitions (returnA
and loop
) from
- A New Notation for Arrows, by Ross Paterson, in ICFP 2001, Firenze, Italy, pp229-240.
These papers and more information on arrows can be found at http://www.haskell.org/arrows/.
Synopsis
- class Category a => Arrow (a :: Type -> Type -> Type) where
- newtype Kleisli (m :: Type -> Type) a b = Kleisli {
- runKleisli :: a -> m b
- returnA :: Arrow a => a b b
- (^>>) :: Arrow a => (b -> c) -> a c d -> a b d
- (>>^) :: Arrow a => a b c -> (c -> d) -> a b d
- (>>>) :: forall {k} cat (a :: k) (b :: k) (c :: k). Category cat => cat a b -> cat b c -> cat a c
- (<<<) :: forall {k} cat (b :: k) (c :: k) (a :: k). Category cat => cat b c -> cat a b -> cat a c
- (<<^) :: Arrow a => a c d -> (b -> c) -> a b d
- (^<<) :: Arrow a => (c -> d) -> a b c -> a b d
- class Arrow a => ArrowZero (a :: Type -> Type -> Type) where
- zeroArrow :: a b c
- class ArrowZero a => ArrowPlus (a :: Type -> Type -> Type) where
- (<+>) :: a b c -> a b c -> a b c
- class Arrow a => ArrowChoice (a :: Type -> Type -> Type) where
- class Arrow a => ArrowApply (a :: Type -> Type -> Type) where
- app :: a (a b c, b) c
- newtype ArrowMonad (a :: Type -> Type -> Type) b = ArrowMonad (a () b)
- leftApp :: ArrowApply a => a b c -> a (Either b d) (Either c d)
- class Arrow a => ArrowLoop (a :: Type -> Type -> Type) where
- loop :: a (b, d) (c, d) -> a b c
Arrows
class Category a => Arrow (a :: Type -> Type -> Type) where Source #
The basic arrow class.
Instances should satisfy the following laws:
arr
id =id
arr
(f >>> g) =arr
f >>>arr
gfirst
(arr
f) =arr
(first
f)first
(f >>> g) =first
f >>>first
gfirst
f >>>arr
fst
=arr
fst
>>> ffirst
f >>>arr
(id
*** g) =arr
(id
*** g) >>>first
ffirst
(first
f) >>>arr
assoc =arr
assoc >>>first
f
where
assoc ((a,b),c) = (a,(b,c))
The other combinators have sensible default definitions, which may be overridden for efficiency.
arr :: (b -> c) -> a b c Source #
Lift a function to an arrow.
first :: a b c -> a (b, d) (c, d) Source #
Send the first component of the input through the argument arrow, and copy the rest unchanged to the output.
second :: a b c -> a (d, b) (d, c) Source #
A mirror image of first
.
The default definition may be overridden with a more efficient version if desired.
(***) :: a b c -> a b' c' -> a (b, b') (c, c') infixr 3 Source #
Split the input between the two argument arrows and combine their output. Note that this is in general not a functor.
The default definition may be overridden with a more efficient version if desired.
(&&&) :: a b c -> a b c' -> a b (c, c') infixr 3 Source #
Fanout: send the input to both argument arrows and combine their output.
The default definition may be overridden with a more efficient version if desired.
Instances
Monad m => Arrow (Kleisli m) | Since: base-2.1 |
Defined in GHC.Internal.Control.Arrow arr :: (b -> c) -> Kleisli m b c Source # first :: Kleisli m b c -> Kleisli m (b, d) (c, d) Source # second :: Kleisli m b c -> Kleisli m (d, b) (d, c) Source # (***) :: Kleisli m b c -> Kleisli m b' c' -> Kleisli m (b, b') (c, c') Source # (&&&) :: Kleisli m b c -> Kleisli m b c' -> Kleisli m b (c, c') Source # | |
Arrow (->) | Since: base-2.1 |
newtype Kleisli (m :: Type -> Type) a b Source #
Kleisli arrows of a monad.
Kleisli | |
|
Instances
Monad m => Category (Kleisli m :: Type -> Type -> Type) | Since: base-3.0 | ||||
Generic1 (Kleisli m a :: Type -> Type) | |||||
Defined in GHC.Internal.Control.Arrow
| |||||
Monad m => Arrow (Kleisli m) | Since: base-2.1 | ||||
Defined in GHC.Internal.Control.Arrow arr :: (b -> c) -> Kleisli m b c Source # first :: Kleisli m b c -> Kleisli m (b, d) (c, d) Source # second :: Kleisli m b c -> Kleisli m (d, b) (d, c) Source # (***) :: Kleisli m b c -> Kleisli m b' c' -> Kleisli m (b, b') (c, c') Source # (&&&) :: Kleisli m b c -> Kleisli m b c' -> Kleisli m b (c, c') Source # | |||||
Monad m => ArrowApply (Kleisli m) | Since: base-2.1 | ||||
Monad m => ArrowChoice (Kleisli m) | Since: base-2.1 | ||||
Defined in GHC.Internal.Control.Arrow left :: Kleisli m b c -> Kleisli m (Either b d) (Either c d) Source # right :: Kleisli m b c -> Kleisli m (Either d b) (Either d c) Source # (+++) :: Kleisli m b c -> Kleisli m b' c' -> Kleisli m (Either b b') (Either c c') Source # (|||) :: Kleisli m b d -> Kleisli m c d -> Kleisli m (Either b c) d Source # | |||||
MonadFix m => ArrowLoop (Kleisli m) | Beware that for many monads (those for which the Since: base-2.1 | ||||
MonadPlus m => ArrowPlus (Kleisli m) | Since: base-2.1 | ||||
MonadPlus m => ArrowZero (Kleisli m) | Since: base-2.1 | ||||
Defined in GHC.Internal.Control.Arrow | |||||
Alternative m => Alternative (Kleisli m a) | Since: base-4.14.0.0 | ||||
Applicative m => Applicative (Kleisli m a) | Since: base-4.14.0.0 | ||||
Defined in GHC.Internal.Control.Arrow pure :: a0 -> Kleisli m a a0 Source # (<*>) :: Kleisli m a (a0 -> b) -> Kleisli m a a0 -> Kleisli m a b Source # liftA2 :: (a0 -> b -> c) -> Kleisli m a a0 -> Kleisli m a b -> Kleisli m a c Source # (*>) :: Kleisli m a a0 -> Kleisli m a b -> Kleisli m a b Source # (<*) :: Kleisli m a a0 -> Kleisli m a b -> Kleisli m a a0 Source # | |||||
Functor m => Functor (Kleisli m a) | Since: base-4.14.0.0 | ||||
Monad m => Monad (Kleisli m a) | Since: base-4.14.0.0 | ||||
MonadPlus m => MonadPlus (Kleisli m a) | Since: base-4.14.0.0 | ||||
Generic (Kleisli m a b) | |||||
Defined in GHC.Internal.Control.Arrow
| |||||
type Rep1 (Kleisli m a :: Type -> Type) | Since: base-4.14.0.0 | ||||
Defined in GHC.Internal.Control.Arrow | |||||
type Rep (Kleisli m a b) | Since: base-4.14.0.0 | ||||
Defined in GHC.Internal.Control.Arrow |
Derived combinators
returnA :: Arrow a => a b b Source #
The identity arrow, which plays the role of return
in arrow notation.
(^>>) :: Arrow a => (b -> c) -> a c d -> a b d infixr 1 Source #
Precomposition with a pure function.
(>>^) :: Arrow a => a b c -> (c -> d) -> a b d infixr 1 Source #
Postcomposition with a pure function.
(>>>) :: forall {k} cat (a :: k) (b :: k) (c :: k). Category cat => cat a b -> cat b c -> cat a c infixr 1 Source #
Left-to-right composition
(<<<) :: forall {k} cat (b :: k) (c :: k) (a :: k). Category cat => cat b c -> cat a b -> cat a c infixr 1 Source #
Right-to-left composition
Right-to-left variants
(<<^) :: Arrow a => a c d -> (b -> c) -> a b d infixr 1 Source #
Precomposition with a pure function (right-to-left variant).
(^<<) :: Arrow a => (c -> d) -> a b c -> a b d infixr 1 Source #
Postcomposition with a pure function (right-to-left variant).
Monoid operations
Conditionals
class Arrow a => ArrowChoice (a :: Type -> Type -> Type) where Source #
Choice, for arrows that support it. This class underlies the
if
and case
constructs in arrow notation.
Instances should satisfy the following laws:
left
(arr
f) =arr
(left
f)left
(f >>> g) =left
f >>>left
gf >>>
arr
Left
=arr
Left
>>>left
fleft
f >>>arr
(id
+++ g) =arr
(id
+++ g) >>>left
fleft
(left
f) >>>arr
assocsum =arr
assocsum >>>left
f
where
assocsum (Left (Left x)) = Left x assocsum (Left (Right y)) = Right (Left y) assocsum (Right z) = Right (Right z)
The other combinators have sensible default definitions, which may be overridden for efficiency.
left :: a b c -> a (Either b d) (Either c d) Source #
Feed marked inputs through the argument arrow, passing the rest through unchanged to the output.
right :: a b c -> a (Either d b) (Either d c) Source #
A mirror image of left
.
The default definition may be overridden with a more efficient version if desired.
(+++) :: a b c -> a b' c' -> a (Either b b') (Either c c') infixr 2 Source #
Split the input between the two argument arrows, retagging and merging their outputs. Note that this is in general not a functor.
The default definition may be overridden with a more efficient version if desired.
(|||) :: a b d -> a c d -> a (Either b c) d infixr 2 Source #
Fanin: Split the input between the two argument arrows and merge their outputs.
The default definition may be overridden with a more efficient version if desired.
Instances
Monad m => ArrowChoice (Kleisli m) | Since: base-2.1 |
Defined in GHC.Internal.Control.Arrow left :: Kleisli m b c -> Kleisli m (Either b d) (Either c d) Source # right :: Kleisli m b c -> Kleisli m (Either d b) (Either d c) Source # (+++) :: Kleisli m b c -> Kleisli m b' c' -> Kleisli m (Either b b') (Either c c') Source # (|||) :: Kleisli m b d -> Kleisli m c d -> Kleisli m (Either b c) d Source # | |
ArrowChoice (->) | Since: base-2.1 |
Arrow application
class Arrow a => ArrowApply (a :: Type -> Type -> Type) where Source #
Some arrows allow application of arrow inputs to other inputs. Instances should satisfy the following laws:
first
(arr
(\x ->arr
(\y -> (x,y)))) >>>app
=id
first
(arr
(g >>>)) >>>app
=second
g >>>app
first
(arr
(>>> h)) >>>app
=app
>>> h
Such arrows are equivalent to monads (see ArrowMonad
).
Instances
Monad m => ArrowApply (Kleisli m) | Since: base-2.1 |
ArrowApply (->) | Since: base-2.1 |
Defined in GHC.Internal.Control.Arrow |
newtype ArrowMonad (a :: Type -> Type -> Type) b Source #
The ArrowApply
class is equivalent to Monad
: any monad gives rise
to a Kleisli
arrow, and any instance of ArrowApply
defines a monad.
ArrowMonad (a () b) |
Instances
leftApp :: ArrowApply a => a b c -> a (Either b d) (Either c d) Source #
Any instance of ArrowApply
can be made into an instance of
ArrowChoice
by defining left
= leftApp
.
Feedback
class Arrow a => ArrowLoop (a :: Type -> Type -> Type) where Source #
The loop
operator expresses computations in which an output value
is fed back as input, although the computation occurs only once.
It underlies the rec
value recursion construct in arrow notation.
loop
should satisfy the following laws:
- extension
loop
(arr
f) =arr
(\ b ->fst
(fix
(\ (c,d) -> f (b,d))))- left tightening
loop
(first
h >>> f) = h >>>loop
f- right tightening
loop
(f >>>first
h) =loop
f >>> h- sliding
loop
(f >>>arr
(id
*** k)) =loop
(arr
(id
*** k) >>> f)- vanishing
loop
(loop
f) =loop
(arr
unassoc >>> f >>>arr
assoc)- superposing
second
(loop
f) =loop
(arr
assoc >>>second
f >>>arr
unassoc)
where
assoc ((a,b),c) = (a,(b,c)) unassoc (a,(b,c)) = ((a,b),c)