Rank-N types
The GHC Users Guide has an Arbitrary Rank Polymorphism section.
About
Normal Haskell '98 types are considered Rank-1 types. A Haskell '98 type signature such as
a -> b -> a
implies that the type variables are universally quantified like so:
forall a b. a -> b -> a
forall can be floated out of the right-hand side of -> if it appears there, so:
forall a. a -> (forall b. b -> a)
is also a Rank-1 type because it is equivalent to the previous signature.
However, a forall appearing within the left-hand side of (->) cannot be moved up, and therefore forms another level or rank. The type is labeled "Rank-N" where N is the number of foralls which are nested and cannot be merged with a previous one. For example:
(forall a. a -> a) -> (forall b. b -> b)
is a Rank-2 type because the latter forall can be moved to the start but the former one cannot. Therefore, there are two levels of universal quantification.
Rank-N type reconstruction is undecidable in general, and some explicit type annotations are required in their presence.
Rank-2 or Rank-N types may be specifically enabled by the language extensions
{-# LANGUAGE Rank2Types #-} or {-# LANGUAGE RankNTypes #-}.
Church-encoded Lists
Church-encoded lists use RankNTypes too, as seen in a StackOverflow answer by sacundim:
-- | Laws:
--
-- > runList (fromList xs) cons nil == xs
-- > runList (fromList xs) f z == foldr f z xs
-- > foldr f z (toList xs) == runList xs f z
newtype ChurchList a =
ChurchList { runList :: forall r. (a -> r -> r) -> r -> r }
-- | Make a 'ChurchList' out of a regular list.
fromList :: [a] -> ChurchList a
fromList xs = ChurchList $ \k z -> foldr k z xs
-- | Turn a 'ChurchList' into a regular list.
toList :: ChurchList a -> [a]
toList xs = runList xs (:) []
-- | The 'ChurchList' counterpart to '(:)'. Unlike 'DList', whose
-- implementation uses the regular list type, 'ChurchList' abstracts
-- over it as well.
cons :: a -> ChurchList a -> ChurchList a
cons x xs = ChurchList $ \k z -> k x (runList xs k z)
-- | Append two 'ChurchList's. This runs in O(1) time. Note that
-- there is no need to materialize the lists as @[a]@.
append :: ChurchList a -> ChurchList a -> ChurchList a
append xs ys = ChurchList $ \k z -> runList xs k (runList ys k z)
-- i.e.,
nil = {- fromList [] = ChurchList $ \k z -> foldr k z []
= -} ChurchList $ \k z -> z
singleton x = {- cons x nil = ChurchList $ \k z -> k x (runList nil k z)
= -} ChurchList $ \k z -> k x z
snoc xs x = {- append xs $ singleton x
= ChurchList $ \k z -> runList xs k (runList (singleton x) k z)
= -} ChurchList $ \k z -> runList xs k (k x z)
Relation to Existentials
In order to unpack an existential type, you need a polymorphic function that works on any type that could be stored in the existential. This leads to a natural relation between higher-rank types and existentials; and an encoding of existentials in terms of higher rank types in continuation-passing style.
In general, you can replace
data T a1 .. ai = forall t1 .. tj. constraints => Constructor e1 .. ek
(where e1..ek are types in terms of a1..ai and t1..tj)
Constructor exp1 .. expk -- application of the constructor
case e of (Constructor pat1 .. patk) -> res
with
data T' a1 .. ai = Constructor' (forall b. (forall t1..tj. constraints => e1 -> e2 -> ... -> ek -> b) -> b)
Constructor' (\f -> f exp1 .. expk)
case e of (Constructor' f) -> let k pat1 .. patk = res in f k
See also
- Rank-N types on the Haskell' website.
- The GHC Users Guide has a section on Arbitrary Rank Polymorphism.