Parametricity is about the values of types with variables.
T has no variables, so parametricity does not apply. Infact, T has many inhabitants
ap :: T -> T -> T
ap (MkT f) t = f t
idT :: T
idT = MkT id
constT :: T
constT = MkT $ \t -> MkT $ \_ -> t
axiom_sT :: T
axiom_sT = MkT $ \f -> MkT $ \g -> MkT $ \a -> (g `ap` a) `ap` (f `ap` a)
T is an implementation of the Untyped Lambda Calculus, a universal formal system equivalent in power to a Turing machine. The three functions above (plus
ap) form the SKI calculus, an equivalent formal system.
It is possible to encode any Haskell datatype into
T. Consider the type for natural numbers
data Nat = Zero | Succ Nat
we can encode
church :: Nat -> T
church Zero = MkT $ \f -> MkT $ \x -> x
church (Succ n) = MkT $ \f -> MkT $ \x -> f `ap` (church n)
now, you are partially correct though. There is no way in Haskell to write the inverse function of this (so far as I know). Which is really a shame. Although you can write a sort of psuedo inverse with the type
T -> IO Nat. Also, my understanding is the GHCs optimizer can die on recursive
newtypes (someone please correct me if I am wrong about this, because I would like to go back to using them).
Instead, the type
data T = MkT (T -> T) | Failed String
ap (MkT f) a = f a
ap (Failed s) _ = Failed s
which is the lambda calculus with exceptions, can be used in a fully invertable way.
In conclusion, in one sense
T is not a useful type at all, but in another sense it is the most useful type of all.