I'm writing a type class for my
pipes library to define an abstract interface to
Proxy-like types. The type class looks something like:
class ProxyC p where idT :: (Monad m) => b' -> p a' a b' b m r (<-<) :: (Monad m) => (c' -> p b' b c' c m r) -> (b' -> p a' a b' b m r) -> (c' -> p a' a c' c m r) ... -- other methods
I'm also writing extensions for the
Proxy type that are of the form:
instance (ProxyC p) => ProxyC (SomeExtension p) where ....
... and I'd like these instances to be able to impose an additional constraint that if
m is a
p a' a b' b m is a
Monad for all
However, I have no clue how to cleanly encode that as a constraint either for the
ProxyC class or for the instances. The only solution I currently know of is to do something like encoding it in the method signatures of the class:
(<-<) :: (Monad m, Monad (p b' b c' c m), Monad (p a' a b' b m)) => (c' -> p b' b c' c m r) -> (b' -> p a' a b' b m r) -> (c' -> p a' a c' c m r)
... but I was hoping there would be a simpler and more elegant solution.
Edit: And not even that last solution works, since the compiler does not deduce that
(Monad (SomeExtension p a' a b' b m)) implies
(Monad (p a' a b' b m)) for a specific choice of variables, even when given the following instance:
instance (Monad (p a b m)) => Monad (SomeExtension p a b m) where ...
Edit #2: The next solution I'm considering is just duplicating the methods for the
Monad class within the
class ProxyC p where return' :: (Monad m) => r -> p a' a b' b m r (!>=) :: (Monad m) => ...
... and then instantiating them with each
ProxyC instance. This seems okay for my purposes since the
Monad methods only need to be used internally for extension writing and the original type still has a proper
Monad instance for the downstream user. All this does is just expose the
Monad methods to the instance writer.