I'm building an API between two models. I don't care if it returns a  or Seq or anything Foldable is fine. But if I try to do that, I get errors.
module Main where import Prelude hiding (foldr) import Data.Foldable import Data.Sequence data Struct = Struct main = do print $ foldr (+) 0 $ list Struct print $ foldr (+) 0 $ listFree Struct listFree :: Foldable f => a -> f Int listFree s = singleton 10 class TestClass a where list :: Foldable f => a -> f Int instance TestClass Struct where list s = singleton 10
Both the listFree and the list definitions give the same error:
TestFoldable.hs:19:12: Could not deduce (f ~ ) from the context (Foldable f) bound by the type signature for list :: Foldable f => Struct -> f Int at TestFoldable.hs:19:3-15 `f' is a rigid type variable bound by the type signature for list :: Foldable f => Struct -> f Int at TestFoldable.hs:19:3 In the expression:  In an equation for `list': list s =  In the instance declaration for `TestClass Struct'
Why is that? And what is the "right" way to accomplish what I'm trying to do here?
What I'm trying to accomplish is to hide the implementation from the caller. The actual data structure might be a Seq, IntMap, or anything else and most likely is not a list.
I'm getting responses that say "just return a list". But that means conversion, doesn't it? What if it's a 1,000,000 element structure? Converting it to an intermediate data structure just because of limitations of the API seems a poor solution.
And this is a general problem. How does one have a return value that conforms to some API? To hide the concrete implementation so the implementer is free to choose whatever structure is best for them and can change it without having to change the users of the API.
Another way of putting it is: how can I return an interface instead of a concrete type?
The Haskell community on StackOverflow is (SuperlativeCompliment c => forall c. c)
Existential quantification seems like the general solution to this situation.
Another possibility to consider, which is not a general solution but might have worked for this specific case, that might avoid the extra wrapper value required by existential solution is to return a closure of the fold for the client:
list :: a -> ((Int -> b -> b) -> b -> b) list = \f a0 -> foldr f a0 (singleton 10)