I have some contrived type:

```
{-# LANGUAGE DeriveFunctor #-}
data T a = T a deriving (Functor)
```

... and that type is the instance of some contrived class:

```
class C t where
toInt :: t -> Int
instance C (T a) where
toInt _ = 0
```

How can I express in a function constraint that `T a`

is an instance of some class for all `a`

?

For example, consider the following function:

```
f t = toInt $ fmap Left t
```

Intuitively, I would expect the above function to work since `toInt`

works on `T a`

for all `a`

, but I cannot express that in the type. This does not work:

```
f :: (Functor t, C (t a)) => t a -> Int
```

... because when we apply `fmap`

the type has become `Either a b`

. I can't fix this using:

```
f :: (Functor t, C (t (Either a b))) => t a -> Int
```

... because `b`

does not represent a universally quantified variable. Nor can I say:

```
f :: (Functor t, C (t x)) => t a -> Int
```

... or use `forall x`

to suggest that the constraint is valid for all `x`

.

So my question is if there is a way to say that a constraint is polymorphic over some of its type variables.

`class C t where toInt :: t a -> Int`

won't work, and you need`C`

to be of kind`* -> Constraint`

? Would kind polymorphism help here? – C. A. McCann Oct 3 '12 at 23:44`Proxy`

from`pipes`

and the concrete class is`Monad`

. I'm type-classing utility functions for proxy-like types, which is why the constraint is there. Following your suggestion, I'd then define a`MonadP`

class specialized to the shape of the`Proxy`

type constructor and use that as a constraint instead. The disadvantage is that if users wanted to write proxy utility functions polymorphic in the proxy-like type, they'd have to rebind do notation to use`MonadP`

instead. – Gabriel Gonzalez Oct 3 '12 at 23:55