Consider the following code:

```
class Foo f
class Bar b
newtype D d = D
call :: Proxy c -> (forall a . c a => a -> Bool) -> x -> Bool
call g x = g x
-- this function is Testable, and can be used by QuickCheck
f :: (Foo (D d), Bar d) => D d -> Bool
f = error ""
//assume the type FConstraint has kind (* -> Constraint)
main = print $ call (Proxy::Proxy FConstraint) (unsafeCoerce f) (D::D 17)
```

The intent of such a strange function is to be able to easily test polymorphic functions (such as `f`

) using QuickCheck: `call`

would be iterated over a type list of monomorphic types, and this list could be used for several different properties (all taking a single argument) without explicitly writing out type signatures each time. Since this is only appearing in test code, I'm willing to use `unsafeCoerce`

(though I'm not sure it will do what I want at this point. I need to solve the question below first).

I'm certainly open to better/alternate designs for `call`

, but here's my question about the solution I came up with above: I need a type `FConstraint`

with kind `(* -> Constraint)`

which can be used for the first argument to `call`

.

Here's what I've tried:

```
type FConstraint x = (Foo x, Bar ??)
type FConstraint (D d) = (Foo (D d), Bar d)
```

Neither type synonym works, since I need to *pattern match on the type* to get all of the constraints, and also need to *partially apply* `FConstraint`

, neither of which type synonyms allow.

I've also tried a type family:

```
type family FConstraint x
type instance FConstraint (D d) = (Foo (D d), Bar d)
```

but I still can't partially apply this (nor can I with a closed type family).

Thus I need a type of kind `(* -> Constraint)`

which

- Pattern matches on the type of kind
`*`

- Can be partially applied

**UPDATE**

Here's an almost-compiling example using the idea in the answer below:

```
{-# LANGUAGE RankNTypes, ScopedTypeVariables, ConstraintKinds, TypeOperators,
MultiParamTypeClasses, DataKinds, PolyKinds, FlexibleInstances,
UndecidableInstances, FlexibleContexts, TypeFamilies,
FunctionalDependencies #-}
import Control.Monad
import Data.Proxy
import GHC.Prim
import GHC.TypeLits
import Test.QuickCheck
import Test.Framework
import Test.Framework.Providers.QuickCheck2
import Unsafe.Coerce
newtype Zq q = Zq Integer deriving (Show, Eq)
instance (KnownNat q) => Arbitrary (Zq q) where
arbitrary = liftM (\i -> Zq $ (i `mod` (natVal (Proxy::Proxy q)))) arbitrary
instance (KnownNat q) => Num (Zq q) where
(Zq a) + (Zq b) = Zq $ (a + b) `mod` (natVal (Proxy::Proxy q))
(Zq a) * (Zq b) = Zq $ (a * b) `mod` (natVal (Proxy::Proxy q))
negate (Zq 0) = (Zq 0)
negate (Zq a) = Zq $ (natVal (Proxy::Proxy q)) - a
fromInteger x = Zq $ x `mod` (natVal (Proxy::Proxy q))
f :: (KnownNat q) => Zq q -> Zq q
f x = x + 1
finv :: (KnownNat q) => Zq q -> Zq q
finv x = x - 1
prop_f :: forall q . (KnownNat q) => Zq q -> Bool
prop_f x = (finv . f) x == x
call :: (c x) => Proxy (c :: * -> Constraint) ->
(forall a . c a => a -> Bool) ->
x ->
Bool
call _ f = f
class UnZq zq q | zq -> q
instance UnZq (Zq q) q
class FConstraint x
instance (KnownNat q, UnZq zq q) => FConstraint zq
main = defaultMain $ [testProperty "zq_f_id" $ property $
(call (Proxy::Proxy FConstraint) $ unsafeCoerce prop_f :: Zq 3 -> Bool)]
```

I get the error:

```
Could not deduce (KnownNat q0) arising from a use of ‘prop_f’
from the context (FConstraint a)
```

I'm hoping this is a simple scoping issue...

Here's more code for a use case:

```
type MyTypes = '[ Zq 3, Zq 5, Zq 7, Zq 11 ]
class TypesToProps xs c where
tmap :: Proxy xs -> Proxy c -> (forall a . c a => a -> Bool) -> [Property]
instance TypesToProps '[] c where
tmap _ _ _ = []
instance (c x, TypesToProps xs c, Arbitrary x, Show x)
=> TypesToProps (x ': xs) c where
tmap _ c f = (property (call c f :: x -> Bool)) : (tmap (Proxy::Proxy xs) c f)
-- results in same error as the `main` above
main = defaultMain $ map (testProperty "zq_f_id") $
tmap (Proxy::Proxy MyTypes)
(Proxy::Proxy FConstraint)
(unsafeCoerce prop_f)
```