Portability | portable |
---|---|
Stability | provisional |
Maintainer | Edward Kmett <ekmett@gmail.com> |
Safe Haskell | Trustworthy |
- class Functor w => Comonad w where
- liftW :: Comonad w => (a -> b) -> w a -> w b
- wfix :: Comonad w => w (w a -> a) -> a
- cfix :: Comonad w => (w a -> a) -> w a
- (=>=) :: Comonad w => (w a -> b) -> (w b -> c) -> w a -> c
- (=<=) :: Comonad w => (w b -> c) -> (w a -> b) -> w a -> c
- (<<=) :: Comonad w => (w a -> b) -> w a -> w b
- (=>>) :: Comonad w => w a -> (w a -> b) -> w b
- class Comonad w => ComonadApply w where
- (<@@>) :: ComonadApply w => w a -> w (a -> b) -> w b
- liftW2 :: ComonadApply w => (a -> b -> c) -> w a -> w b -> w c
- liftW3 :: ComonadApply w => (a -> b -> c -> d) -> w a -> w b -> w c -> w d
- newtype Cokleisli w a b = Cokleisli {
- runCokleisli :: w a -> b
- class Functor f where
- (<$>) :: Functor f => (a -> b) -> f a -> f b
- ($>) :: Functor f => f a -> b -> f b
Comonads
class Functor w => Comonad w whereSource
There are two ways to define a comonad:
I. Provide definitions for extract
and extend
satisfying these laws:
extend
extract
=id
extract
.extend
f = fextend
f .extend
g =extend
(f .extend
g)
In this case, you may simply set fmap
= liftW
.
These laws are directly analogous to the laws for monads and perhaps can be made clearer by viewing them as laws stating that Cokleisli composition must be associative, and has extract for a unit:
f=>=
extract
= fextract
=>=
f = f (f=>=
g)=>=
h = f=>=
(g=>=
h)
II. Alternately, you may choose to provide definitions for fmap
,
extract
, and duplicate
satisfying these laws:
extract
.duplicate
=id
fmap
extract
.duplicate
=id
duplicate
.duplicate
=fmap
duplicate
.duplicate
In this case you may not rely on the ability to define fmap
in
terms of liftW
.
You may of course, choose to define both duplicate
and extend
.
In that case you must also satisfy these laws:
extend
f =fmap
f .duplicate
duplicate
=extend
idfmap
f =extend
(f .extract
)
These are the default definitions of extend
and duplicate
and
the definition of liftW
respectively.
Comonad Tree | |
Comonad Identity | |
Comonad NonEmpty | |
Monoid m => Comonad ((->) m) | |
Comonad ((,) e) | |
Comonad w => Comonad (IdentityT w) | |
Comonad (Tagged * s) | |
Comonad w => Comonad (EnvT e w) | |
Comonad w => Comonad (StoreT s w) | |
(Comonad w, Monoid m) => Comonad (TracedT m w) | |
(Comonad f, Comonad g) => Comonad (Coproduct f g) |
Combining Comonads
class Comonad w => ComonadApply w whereSource
ComonadApply
is to Comonad
like Applicative
is to Monad
.
Mathematically, it is a strong lax symmetric semi-monoidal comonad on the
category Hask
of Haskell types. That it to say that w
is a strong lax
symmetric semi-monoidal functor on Hask, where both extract
and duplicate
are
symmetric monoidal natural transformations.
Laws:
(.
)<$>
u<@>
v<@>
w = u<@>
(v<@>
w)extract
(p<@>
q) =extract
p (extract
q)duplicate
(p<@>
q) = (<@>
)<$>
duplicate
p<@>
duplicate
q
If our type is both a ComonadApply
and Applicative
we further require
(<*>
) = (<@>
)
Finally, if you choose to define (<@
) and (@>
), the results of your
definitions should match the following laws:
a@>
b =const
id
<$>
a<@>
b a<@
b =const
<$>
a<@>
b
ComonadApply Tree | |
ComonadApply Identity | |
ComonadApply NonEmpty | |
Monoid m => ComonadApply ((->) m) | |
Semigroup m => ComonadApply ((,) m) | |
ComonadApply w => ComonadApply (IdentityT w) | |
(Semigroup e, ComonadApply w) => ComonadApply (EnvT e w) | |
(ComonadApply w, Semigroup s) => ComonadApply (StoreT s w) | |
(ComonadApply w, Monoid m) => ComonadApply (TracedT m w) |
(<@@>) :: ComonadApply w => w a -> w (a -> b) -> w bSource
A variant of <@>
with the arguments reversed.
liftW2 :: ComonadApply w => (a -> b -> c) -> w a -> w b -> w cSource
Lift a binary function into a Comonad
with zipping
liftW3 :: ComonadApply w => (a -> b -> c -> d) -> w a -> w b -> w c -> w dSource
Lift a ternary function into a Comonad
with zipping
Cokleisli Arrows
newtype Cokleisli w a b Source
Cokleisli | |
|
Typeable1 w => Typeable2 (Cokleisli w) | |
Comonad w => Arrow (Cokleisli w) | |
Comonad w => ArrowChoice (Cokleisli w) | |
Comonad w => ArrowApply (Cokleisli w) | |
ComonadApply w => ArrowLoop (Cokleisli w) | |
Comonad w => Category (Cokleisli w) | |
Monad (Cokleisli w a) | |
Functor (Cokleisli w a) | |
Applicative (Cokleisli w a) |
Functors
class Functor f where
The Functor
class is used for types that can be mapped over.
Instances of Functor
should satisfy the following laws:
fmap id == id fmap (f . g) == fmap f . fmap g
The instances of Functor
for lists, Maybe
and IO
satisfy these laws.
Functor [] | |
Functor IO | |
Functor Id | |
Functor ZipList | |
Functor ReadPrec | |
Functor ReadP | |
Functor Maybe | |
Functor Tree | |
Functor Identity | |
Functor Min | |
Functor Max | |
Functor First | |
Functor Last | |
Functor Option | |
Functor NonEmpty | |
Functor ((->) r) | |
Functor (Either a) | |
Functor ((,) a) | |
Ix i => Functor (Array i) | |
Functor (StateL s) | |
Functor (StateR s) | |
Functor (Const m) | |
Monad m => Functor (WrappedMonad m) | |
Arrow a => Functor (ArrowMonad a) | |
Functor m => Functor (IdentityT m) | |
Arrow a => Functor (WrappedArrow a b) | |
Functor (Tagged k s) | |
(Functor f, Functor g) => Functor (Compose f g) | |
Functor (Cokleisli w a) | |
Functor w => Functor (EnvT e w) | |
Functor w => Functor (StoreT s w) | |
Functor w => Functor (TracedT m w) | |
(Functor f, Functor g) => Functor (Coproduct f g) |