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)
```

The type `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 `Nat`

into `T`

```
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
```

with

```
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**.