# Haskell could not unify type instance equations

I am trying to tag canonical Nat datatype with (Even/Odd) Parity kind to see if we can get any free theorems. Here is the code:

``````{-# LANGUAGE GADTs #-}
{-# LANGUAGE TypeFamilies #-}
{-# LANGUAGE DataKinds #-}

-- Use DataKind promotion with type function for even-odd

module EvenOdd where

data Parity = Even | Odd
-- Parity is promoted to kind level Parity.
-- Even & Odd to type level 'Even & 'Odd of kind Parity

-- We define type-function opp to establish the relation that
-- type 'Even is opposite of 'Odd, and vice-versa
type family Opp (n :: Parity) :: Parity
type instance Opp 'Even = 'Odd
type instance Opp 'Odd = 'Even

-- We tag natural number with the type of its parity
data Nat :: Parity -> * where
Zero :: Nat 'Even
Succ :: Nat p -> Nat (Opp p)

-- Now we (should) get free theorems.
-- 1. Plus of two even numbers is even
evenPlus :: Nat 'Even -> Nat 'Even -> Nat 'Even
evenPlus Zero n2 = n2  -- Line 31
evenPlus (Succ (Succ n1)) n2 = Succ (Succ (evenPlus n1 n2))
``````

However, GHC throws type error:

``````Could not deduce (p1 ~ 'Even)
from the context ('Even ~ Opp p)
bound by a pattern with constructor
Succ :: forall (p :: Parity). Nat p -> Nat (Opp p),
in an equation for `evenPlus'
at even-odd.hs:31:13-26
or from (p ~ Opp p1)
bound by a pattern with constructor
Succ :: forall (p :: Parity). Nat p -> Nat (Opp p),
in an equation for `evenPlus'
at even-odd.hs:31:19-25
`p1' is a rigid type variable bound by
a pattern with constructor
Succ :: forall (p :: Parity). Nat p -> Nat (Opp p),
in an equation for `evenPlus'
at even-odd.hs:31:19
Expected type: Nat 'Even
Actual type: Nat p
In the first argument of `evenPlus', namely `n1'
In the first argument of `Succ', namely `(evenPlus n1 n2)'
``````

As I understand it, the gist of the above error is that GHC was unable to deduce (p1 ~ 'Even), when the context has the equation: ((Opp (Opp p1)) ~ 'Even).

Why does this happen? Is there something wrong with my approach?

-

I don't think GADT pattern match refinement works this way round. You have `Opp p` as the result type of a constructor. So if you write something like

``````f :: Nat 'Even -> ...
f (Succ n) = ...
``````

then the type checker knows that `Nat (Opp t) ~ Nat 'Even` and therefore `Opp t ~ 'Even`. But to solve this, the type checker has to invert the function `Opp`, which is asking a lot.

I suggest you change the definition of `Nat` to say:

``````data Nat :: Parity -> * where
Zero :: Nat 'Even
Succ :: Nat (Opp p) -> Nat p
``````

This should just work.

### Edit

Actually, let me expand slightly.

The suggestion above is not without a (minor) price. You lose a bit of type inference. For example, the type of `Succ Zero` is now `Succ Zero :: Opp p ~ 'Even => Nat p` and not `Nat 'Odd`. With an explicit type annotation, it resolves ok.

You can improve on this by adding a constraint to `Succ` that requires that `Opp` is self-inverse. The only two elements of `Parity` are `Even` and `Odd`, and for these the constraint holds, so it should never cause any problems:

``````data Nat :: Parity -> * where
Zero :: Nat 'Even
Succ :: (Opp (Opp p) ~ p) => Nat (Opp p) -> Nat p
``````

Now `Succ Zero` is inferred to be of type `Nat 'Odd`, and the pattern match still works.

-
This works, thank you. I see that there is difference between both approaches in terms of type constraints they generate. –  Gowtham Kaki Dec 3 '13 at 17:31
@GowthamKaki I added a bit more detail to my answer. –  kosmikus Dec 3 '13 at 18:12