One of the problems here is that category theory, a.k.a. general abstract nonsense, is a theory that you can use to talk about almost anything in mathematics. So everything that we are talking about can be expressed using the language of category theory, but we might not produce any interesting results.
Does every every typeclass in Haskell whose members are of kind
* -> * correspond to some function between categories?
No. This question contains a type error! A function maps sets to sets, but a category is not a set. (Put another way, functions are morphisms in the category Set.) Categories are formulated using classes, often proper classes, so you cannot feed a category to a function.
We would call objects in
* -> * morphisms in the category of Haskell types. A subcategory of this category is the category of functors between Haskell types, which is called
Does every typeclass in Haskell whose members are of kind
* correspond to some category (technically: some subcategory of Hask)?
Yes. This is true, but it's not terribly interesting. Just remove every object from Hask that is not in your typeclass, and remove any morphism in Hask that does not consume and produce elements from your typeclass, and you are left with a subcategory of Hask. This category should have at least one object,
⊥, and at least one morphism,
Do typeclasses of kind equal to or higher than
* -> * -> * correspond to some category theoretic notion?
Yes. Again, this won't be very interesting. Let's take a typeclass
X with kind
* -> * -> *.
X an object in a category of typeclasses with the same kind? Well, yes. But this category isn't very interesting, because it's hard to imagine any nontrivial morphisms.
X a morphism in some category? No, because it cannot be composed.
X a functor mapping a subcategory of types in Hask to a subcategory of morphisms on types in Hask? Sure, but we would have to have some special knowledge that both
X Y a b and
X Z a b are permissible for the same
a b before we allow morphisms into our starting subcategory on types of Hask.
This doesn't seem to me like it will produce any useful insights, which is not really surprising because we don't really know anything about
Category theory is one of those tools that is really quite easy to overthink and overapply. If you are not interested in category theory as a subject of study in and of itself, my recommendation is to find concrete motivations to use it. Specific typeclasses (functors, lenses, monads, comonads, etc) will sometimes provide you with enough structure or "raw mathematical material" from which you can construct an interesting proof in category theory. But the study of typeclasses in general may be a bit more abstract than it is useful.