As others have identified, the key to the problem is the existentially quantified
tag in the type of
Con3. When you're trying to define
Con3 s == Con3 t = ???
there's no reason why
t should be expressions with the same
But perhaps you don't care? You can perfectly well define the heterogeneous equality test which is happy to compare
Exprs structurally, regardless of tags.
instance Eq (Expr tag) where
(==) = heq where
heq :: Expr a -> Expr b -> Bool
heq (Con1 i) (Con1 j) = i == j
heq (Con2 s) (Con2 t) = heq s t
heq (Con3 s) (Con3 t) = heq s t
If you do care, then you might be well advised to equip
Con3 with a run-time witness to the existentially quantified
tag. The standard way to do this is with the singleton construction.
data SingExprTag (tag :: ExprTag) where
SingTag1 :: SingExprTag Tag1
SingTag2 :: SingExprTag Tag2
Case analysis on a value in
SingExprTag tag will exactly determine what
tag is. We can slip this extra piece of information into
Con3 as follows:
data Expr' (tag :: ExprTag) where
Con1' :: Int -> Expr' tag
Con2' :: Expr' tag -> Expr' tag
Con3' :: SingExprTag tag -> Expr' tag -> Expr' Tag2
Now we can check whether the tags match. We could write a heterogeneous equality for tag singletons like this...
heqTagBoo :: SingExprTag a -> SingExprTag b -> Bool
heqTagBoo SingTag1 SingTag1 = True
heqTagBoo SingTag2 SingTag2 = True
heqTagBoo _ _ = False
...but to do so would be perfectly useless, as it only gives us a value of type
Bool, with no idea what that value means nor to what its truth might entitle us. Knowing that
heqTagBoo a b = True does not tell the typechecker anything useful about the tags which
b witness. A Boolean is a bit uninformative.
We can write essentially the same test, but delivering in the positive case some evidence that the tags are equal.
data x :=: y where
Refl :: x :=: x
singExprTagEq :: SingExprTag a -> SingExprTag b -> Maybe (a :=: b)
singExprTagEq SingTag1 SingTag1 = Just Refl
singExprTagEq SingTag2 SingTag2 = Just Refl
singExprTagEq _ _ = Nothing
Now we're cooking with gas! We can implement an instance of
Expr' which uses
ExprTag comparison to justify a recursive call on two
Con3' children when the tags have been shown to match.
instance Eq (Expr' tag) where
Con1' i == Con1' j = i == j
Con2' s == Con2' t = s == t
Con3' a s == Con3' b t = case singExprTagEq a b of
Just Refl -> s == t
Nothing -> False
The general situation is that promoted types need their associated singleton types (at least until we get proper ∏-types), and we need evidence-producing heterogeneous equality tests for those singleton families, so that we can compare two singletons and gain type-level knowledge when they witness the same type-level values. Then as long as your GADTs carry singleton witnesses for any existentials, you can test equality homogeneously, ensuring that positive results from singleton tests give the bonus of unifying types for the other tests.