# Lambda calculus in Haskell: Is there some way to make Church numerals type check?

I'm playing with some lambda calculus stuff in Haskell, specifically church numerals. I have the following defined:

``````let zero = (\f z -> z)
let one = (\f z -> f z)
let two = (\f z -> f (f z))
let iszero = (\n -> n (\x -> (\x y -> y)) (\x y -> x))
let mult = (\m n -> (\s z -> m (\x -> n s x) z))
``````

This works:

``````:t (\n -> (iszero n) one (mult one one))
``````

This fails with an occurs check:

``````:t (\n -> (iszero n) one (mult n one))
``````

I have played with `iszero` and `mult` with my constants and they seem to be correct. Is there some way to make this typeable? I didn't think what I was doing was too crazy, but maybe I'm doing something wrong?

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Your definitions are correct, as are their types, when seen at top-level. The problem is that, in the second example, you're using `n` in two different ways that don't have the same type--or rather, their types can't be unified, and attempting to do so would produce an infinite type. Similar uses of `one` work correctly because each use is independently specialized to different types.

To make this work in a straightforward way you need higher-rank polymorphism. The correct type for a church numeral is `(forall a. (a -> a) -> a -> a)`, but higher-rank types can't be inferred, and require a GHC extension such as `RankNTypes`. If you enable an appropriate extension (you only need rank-2 in this case, I think) and give explicit types for your definitions, they should work without changing the actual implementation.

Note that there are (or at least were) some restrictions on the use of higher-rank polymorphic types. You can, however, wrap your church numerals in something like `newtype ChurchNum = ChurchNum (forall a. (a -> a) -> a -> a)`, which would allow giving them a `Num` instance as well.

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Wow, you're right. I did not expect something so fundamental to require higher-rank polymorphism but I guess that's what comes from the lambda calculus being untyped. –  singpolyma Oct 17 '12 at 20:22
@singpolyma: One could argue that higher-rank polymorphism is itself fundamental to a polymorphic typed lambda calculus, not the extra limitations necessary to allow full type inference. –  C. A. McCann Oct 17 '12 at 20:49
@singpolyma: BTW,the mentioned above restrictions will come into play when you try to implement something like `mult m n = m (plus n) zero` which is a valid expression in untyped lambda but requires impredicative polymorphism in typed. Here is Oleg's workaround for that: okmij.org/ftp/Haskell/types.html#some-impredicativity –  Ed'ka Oct 18 '12 at 0:42

``````type Nat a = (a -> a) -> a -> a

zero :: Nat a
zero = (\f z -> z)

one :: Nat a
one = (\f z -> f z)

two :: Nat a
two = (\f z -> f (f z))

iszero :: Nat (a -> a -> a) -> a -> a -> a
iszero = (\n -> n (\x -> (\x y -> y)) (\x y -> x))

mult :: Nat a -> Nat a -> Nat a
mult = (\m n -> (\s z -> m (\x -> n s x) z))
``````

As you can see, everything seems pretty normal except for the type of `iszero`.

Let's see what happens with your expression:

``````*Main> :t (\n -> (iszero n) one n)
<interactive>:1:23:
Occurs check: cannot construct the infinite type:
a0
=
((a0 -> a0) -> a0 -> a0)
-> ((a0 -> a0) -> a0 -> a0) -> (a0 -> a0) -> a0 -> a0
Expected type: Nat a0
Actual type: Nat (Nat a0 -> Nat a0 -> Nat a0)
In the third argument of `iszero', namely `(mult n one)'
In the expression: (iszero n) one (mult n one)
``````

See how the error uses our `Nat` alias!

We can actually get a similar error with the simpler expression `\n -> (iszero n) one n`. Here's what's wrong. Since we are calling `iszero n`, we must have `n :: Nat (b -> b -> b)`. Also, because of `iszero`s type the second and third arguments, `n` and `one`, must have the type `b`. Now we have two equations for the type of `n`:

``````n :: Nat (b -> b -> b)
n :: b
``````

Which can't be reconciled. Bummer.

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