Can we solve this equation for X ?
Applicative is to monad what X is to comonad
After giving it some thought, I think this is actually a backward question. One might think that
ComonadApply is to
Applicative is to
Monad, but that is not the case. But to see this, let us use PureScript's typeclass hierarchy:
class Functor f where fmap :: (a -> b) -> f a -> f b class Functor f => Apply f where apply :: f (a -> b) -> f a -> f b -- (<*>) class Apply f => Applicative f where pure :: a -> f a class Applicative m => Monad m where bind :: m a -> (a -> m b) -> m b -- (>>=) -- join :: m (m a) -> m a -- join = flip bind id
As you can see,
ComonadApply is merely
(Apply w, Comonad w) => w. However,
Applicative's ability to inject values into the functor with
pure is the real difference.
The definition of a
Comonad as the categorical dual consists of
extend (or the alternative definiton via
class Functor w => Comonad w where extract :: w a -> a extend :: (w a -> b) -> w a -> w b -- extend f = fmap f . duplicate k -- duplicate :: w a -> w (w a) -- duplicate = extend id
So if we look at the step from
Monad, the logical step between would be a typeclass with
class Apply w => Extract w where extract :: w a -> a class Extract w => Comonad w where extend :: (w a -> b) -> w a -> w b
Note that we cannot define
extract in terms of
duplicate, and neither can we define
return in terms of
join, so this seems like the "logical" step.
apply is mostly irrelevant here; it can be defined for either
Monad, as long as their laws hold:
applyC f = fmap $ extract f -- Comonad variant; needs only Extract actually (*) applyM f = bind f . flip fmap -- Monad variant; we need join or bind
Extract (getting values out) is to
Applicative (getting values in) is to
Apply is more or less a happy little accident along the way. It would be interesting whether there are types in Hask that have
Extract, but not
Extend but not
Comonad, see below), but I guess those are rather rare.
Extract doesn't exist—yet. But neither did
Applicative in the 2010 report. Also, any type that is both an instance of
Applicative automatically is both a
Monad and a
Comonad, since you can define
extend in terms of
bindC :: Extract w => w a -> (a -> w b) -> w b bindC k f = f $ extract k extendM :: Applicative w => (w a -> b) -> w a -> w b extendM f k = pure $ f k
* Being able to define
apply in terms of
extract is a sign that
class Extend w => Comonad w could be more feasible, but one could have split
class (Applicative f, Bind f) => Monad f and therefore
(Extend w, Extract w) => Comonad w, so it's more or less splitting hair.
To me it seems that
Apply class should not be a part of the picture at all.
For example the definition of
apply in @Zeta's answer does not seem to be well-behaved. In particular, it always discards the context of the first argument and only uses the context of the second argument.
Intuitively, it seems that comonad is about "splitting" the context instead of combining, and so "co-applicative" should be the same.
This question seems to have better answers: Is there a concept of something like co-applicative functors sitting between comonads and functors?.