Similar to the case of
Monad, where it is possible to basically implement
liftM :: Monad m => (a->b) -> m a -> m b liftM f q = return . f =<< q
we could also emulate
foldLiftT :: (Traversable t, Monoid m) => (a -> m) -> t a -> m foldLiftT f = fst . traverse (f >>> \x -> (x,x)) -- or: . sequenceA . fmap (f >>> \x -> (x, x))
Monoid m => (,) m monad. So the combination of superclass and methods bears in both cases a certain redundancy.
In case of monads, it can be argued that a "better" definition of the type class would be (I'll skip applicative / monoidal)
class (Functor m) => Monad m where return :: a -> m a join :: m (m a) -> m a
at least that's what's used in category theory. This definition does, without using the
Functor superclass, not permit
liftM, so it is without this redundancy.
Is a similar transformation possible for the
To clarify: what I'm after is a re-definition, let's call it,
class (Functor t, Foldable t) => Traversable t where skim :: ???
such that we could make the actual
Traverse methods top-level functions
sequenceA :: (Traversable t, Applicative f) => t (f a) -> f (t a)
but it would not be possible to make generically
instance (Traversable t) => Foldable t where foldMap = ... skim ... data T instance Traversable T where skim = ...
This is not because I need this for something particular, but a conceptual question so as to better understand the difference between
Traversable. Again much like
>>= is much more convenient than
join for everyday Haskell programming (because you usually need precisely this combination of
join), the latter makes it simpler to grasp what a monad is about.