I'm trying to find a more elegant way to write the following code.
class C c where type E c :: * -> * class C c => A c where g :: E c a -> E c a class (C c, A c) => D c where f :: E c a -> E c a instance A c => D c where f = g
This produces an error.
Test.hs:58:9: Could not deduce (E c0 ~ E c) from the context (A c) bound by the instance declaration at Test.hs:57:10-19 NB: `E' is a type function, and may not be injective Expected type: E c a Actual type: E c0 a Expected type: E c a -> E c a Actual type: E c0 a -> E c0 a In the expression: g In an equation for `f': f = g Failed, modules loaded: none.
My current solution is to add a dummy variable, from which it can derive which particular C is in use.
class C c where type E c :: * -> * class C c => A c where g_inner :: c -> E c a -> E c a g = g_inner undefined class (C c, A c) => D c where f_inner :: c -> E c a -> E c a f = f_inner undefined instance A c => D c where f_inner = g_inner
I know this is another instance of associated types not being injective, but I can't quite figure it out. Sure, E might not be injective, but it seems somewhere the information that g will work on the particular (E c) referenced in class D has been lost.
Any explanation, and more importantly better workarounds would be much appreciated. Thanks!
Okay, I see switching
data makes the code work.
I'm trying to sound out how this might work. Each
c creates a new data type
E c. In the instance context, we have to match
forall a. ((E) c) a -> ((E) c) a with
forall a. ((E) c) a -> ((E) c) a. Denoting
F = E c, we are then matching
forall a. F a -> F a with itself.
I'm having trouble seeing where things break with the type synonyms (associated types) case. Sure, one could define two instances of
A which both have signature
(E c) a -> (E c) a. But, why would it be wrong to use the definition from the instance
A c which is in scope?