# Encoding the dynamicaly-typed lambda calculus in Haskell using recursive types

I'm reading Pierce's Types and Programming Languages book and in the chapter about recursive types he mentions that they can be used to encode the dynamic lambda calculus in a typed language. As an exercise, I'm trying to write that encoding in Haskell but I can't get it to pass the typechecker:

``````{-# LANGUAGE RankNTypes, ScopedTypeVariables #-}

data D = D (forall x . x -> x )

lam :: (D -> D) -> D
--lam f = D f
lam = undefined

ap :: D -> D -> D
ap (D f) x = f x

--Some examples:
myConst :: D
myConst = lam (\x -> lam (\y -> x))

flippedAp :: D
flippedAp = lam (\x -> lam (\f -> ap f x))
``````

Right now, this code gives me the following error message (that I don't really understand):

``````dyn.hs:6:11:
Couldn't match type `x' with `D'
`x' is a rigid type variable bound by
a type expected by the context: x -> x at dyn.hs:6:9
Expected type: x -> x
Actual type: D -> D
In the first argument of `D', namely `f'
In the expression: D f
In an equation for `lam': lam f = D f
``````

Changing the definition of `lam` to undefined (the commented-out line) gets the code to compile so I suspect that whatever I did wrong is either on lam's definition or in the original definition for the D datatype.

-

The reason this doesn't work is because `f :: D -> D`. `D` wants a function which can take in any type `x` and return `x`. This is equivalent to

``````d :: forall a. a -> a
``````

As you can see, the only sane implementation for this is `id`. Try

`````` data D = D (D -> D)
...
unit = D id
``````

Perhaps for better printing:

`````` data D = DFunc (D -> D) | DNumber Int
``````
-
Damn its so obvious now. In Haskell the recursive type quantifier is implicit so I didn't need to try to write it down like I did. –  missingno Sep 21 at 3:49
`data D = D (D -> D)` has plenty of non-bottom inhabitants... –  Daniel Wagner Sep 21 at 18:43
@DanielWagner Gah, you're right, updated.. –  jozefg Sep 21 at 21:18
The issue is that your `f` has type `D -> D` (according to your type signature for `lam`), but the `D` constructor expects an argument of type `forall x . x -> x`. Those are not the same type, so the compiler complains