What does it really mean in the context of types?
It means the type system has enough features in it to represent arbitrary computations. As a very short proof, I present below a type-level implementation of the SK
calculus; there are many places that discuss the Turing-completeness of this calculus and what it means, so I won't rehash that here.
{-# LANGUAGE DataKinds #-}
{-# LANGUAGE TypeFamilies #-}
{-# LANGUAGE UndecidableInstances #-}
{-# LANGUAGE TypeOperators #-}
infixl 1 `App`
data Term = S | K | App Term Term
type family Reduce t where
Reduce S = S
Reduce K = K
Reduce (S `App` x `App` y `App` z) = Reduce (x `App` z `App` (y `App` z))
Reduce (K `App` x `App` y) = Reduce x
Reduce (x `App` y) = Reduce (Reduce x `App` y)
You can see this in action at a ghci prompt; for example, in the SK
calculus, the term SKSK
reduces (eventually) to just K
:
> :kind! Reduce (S `App` K `App` S `App` K)
Reduce (S `App` K `App` S `App` K) :: Term
= 'K
Here's a fun one to try as well:
> type I = S `App` K `App` K
> type Rep = S `App` I `App` I
> :kind! Reduce (Rep `App` Rep)
I won't spoil the fun -- try it yourself. But know how to terminate programs with extreme prejudice first.
Could some one give an example how a programmer can benefit from it?
Arbitrary type-level computation allows you to express arbitrary invariants on your types, and have the compiler verify (at compile-time) that they are preserved. Want a red-black tree? How about a red-black tree that the compiler can check preserves the red-black-tree invariants? That would be handy, right, since that rules out a whole class of implementation bugs? How about a type for XML values that is statically known to match a particular schema? In fact, why not go a step further and write down a parameterized type whose parameter represents a schema? Then you could read in a schema at runtime, and have your compile-time checks guarantee that your parameterized value can only represent well-formed values in that schema. Nice!
Or, perhaps a more prosaic example: what if you wanted your compiler to check that you never indexed your dictionary with a key that wasn't there? With a sufficiently advanced type system, you can.
Of course, there's always a price. In Haskell (and probably Scala?), the price of a very exciting compile-time check is spending a great deal of programmer time and effort convincing the compiler that the thing you're checking is true -- and this is often both a high up-front cost as well as a high ongoing maintenance cost.