5

I learned that you can redefine ContT from transformers such that the r type parameter is made implicit (and may be specified explicitly using TypeApplications), viz.:

-- | Same as `ContT` but with the `r` made implicit
type ContT ::
  forall (r :: Type).
  (Type -> Type) ->
  Type ->
  Type
data ContT m a where
  ContT ::
    forall r m a.
    {runContT :: (a -> m r) -> m r} ->
    ContT @r m a

type ContVoid :: (Type -> Type) -> Type -> Type
type ContVoid = ContT @()

I hadn't realized this was possible in GHC. What is the larger feature called to refer to this way of defining a family of types with implicit type parameters, that is specified using forall in type definition (referring, in the example above, to the outer forall - rather than the inner forall which simply unifies the r)?

1 Answer 1

5

Nobody uses this (invisible dependent quantification) for this purpose (where the dependency is not used) but it is the same as giving a Type -> .. parameter, implicitly.

type EITHER :: forall (a :: Type) (b :: Type). Type
data EITHER where
 LEFT  :: a -> EITHER @a @b
 RIGHT :: b -> EITHER @a @b

eITHER :: (a -> res) -> (b -> res) -> (EITHER @a @b -> res)
eITHER left right = \case
 LEFT  a -> left  a
 RIGHT b -> right b

You can also use "visible dependent quantification" where forall-> is the visible counterpart to forall., so forall (a :: Type) -> .. is properly like Type -> .. where a does not appear in ..:

type EITHER :: forall (a :: Type) -> forall (b :: Type) -> Type
data EITHER a b where
 LEFT  :: a -> EITHER a b
 RIGHT :: b -> EITHER a b

eITHER :: (a -> res) -> (b -> res) -> (EITHER a b -> res)
eITHER left right = \case
 LEFT  a -> left  a
 RIGHT b -> right b
4
  • 1
    Can you point to the GHC user guide where these are explained?
    – pedrofurla
    Feb 1, 2022 at 20:38
  • 3
    This explains {in,}visible arguments, but this is ultimately regular kind polymorphism where the quantification is "not used". This is unusual, normally the quantifiee k appears in the rest of the kind Proxy :: forall (k :: Type). k -> Type. If it doesn't, it is like in type theory where a function arrow A -> B is a special case of a dependent function pi (a :: A) -> B if a does not appear in B Feb 1, 2022 at 21:21
  • 1
    I don't know of any use of this. Let me know if you find any. I remember playing around with this, the invisible case forall (a :: Type). Type was pretty unsuable and I think forall (a :: Type) -> Type was not the same as Type -> Type but it's been a while Feb 1, 2022 at 21:22
  • 1
    @Iceland_jack Here is a real-world use; backwards compatibility, basically. Feb 1, 2022 at 21:48

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