4

This problem actually emerged from attempt to implement few mathematical groups as types.

Cyclic groups have no problem (instance of Data.Group defined elsewhere):

newtype Cyclic (n :: Nat) = Cyclic {cIndex :: Integer} deriving (Eq, Ord)

cyclic :: forall n. KnownNat n => Integer -> Cyclic n
cyclic x = Cyclic $ x `mod` toInteger (natVal (Proxy :: Proxy n))

But symmetric groups have some problem on defining some instances (implementation via factorial number system):

infixr 6 :.

data Symmetric (n :: Nat) where
    S1 :: Symmetric 1
    (:.) :: (KnownNat n, 2 <= n) => Cyclic n -> Symmetric (n-1) -> Symmetric n

instance {-# OVERLAPPING #-} Enum (Symmetric 1) where
    toEnum _ = S1
    fromEnum S1 = 0

instance (KnownNat n, 2 <= n) => Enum (Symmetric n) where
    toEnum n = let
        (q,r) = divMod n (1 + fromEnum (maxBound :: Symmetric (n-1)))
        in toEnum q :. toEnum r
    fromEnum (x :. y) = fromInteger (cIndex x) * (1 + fromEnum (maxBound `asTypeOf` y)) + fromEnum y

instance {-# OVERLAPPING #-} Bounded (Symmetric 1) where
    minBound = S1
    maxBound = S1

instance (KnownNat n, 2 <= n) => Bounded (Symmetric n) where
    minBound = minBound :. minBound
    maxBound = maxBound :. maxBound

Error message from ghci (only briefly):

Overlapping instances for Enum (Symmetric (n - 1))
Overlapping instances for Bounded (Symmetric (n - 1))

So how can GHC know whether n-1 equals to 1 or not? I'd also like to know whether the solution can be written without FlexibleInstances.

3

Add Bounded (Symmetric (n-1)) and Enum (Symmetric (n-1)) as constraints, because fully resolving those constraints would require knowing the exact value of n.

instance (KnownNat n, 2 <= n, Bounded (Symmetric (n-1)), Enum (Symmetric (n-1))) =>
  Enum (Symmetric n) where
  ...

instance (KnownNat n, 2 <= n, Bounded (Symmetric (n-1))) =>
  Bounded (Symmetric n) where
  ...

To avoid FlexibleInstances (which is not worth it IMO, FlexibleInstances is a benign extension), use Peano numbers data Nat = Z | S Nat instead of GHC's primitive representation. First replace the instance head Bounded (Symmetric n) with Bounded (Symmetric (S (S n'))) (this plays the role of the constraint 2 <= n), and then break up the instance with an auxiliary class (possibly more) to satisfy the standard requirement on instance heads. It might look like this:

instance Bounded_Symmetric n => Bounded (Symmetric n) where ...
instance Bounded_Symmetric O where ...
instance Bounded_Symmetric n => Bounded_Symmetric (S n) where ...

Your Answer

By clicking “Post Your Answer”, you agree to our terms of service, privacy policy and cookie policy

Not the answer you're looking for? Browse other questions tagged or ask your own question.