I first wrote the solution in the untyped lambda calculus, using top-level definitions for things like *zero?*, *true*, *false*, etc, defined using Church encodings. This implementation assumes that multi-argument functions are curried and that functions are partially applied (like Haskell).

Church encoding natural numbers looks like:

```
(define 0 λf x. x)
(define 1 λf x. f x)
(define 2 λf x. f (f x))
(define 3 λf x. f (f (f x)))
```

Church booleans `true`

and `false`

are defined below

```
(define const λx y. x)
(define U λf. f f)
(define true λt f. t)
(define false λt f. f)
(define succ λn f x. f (n f x))
(define 0 λf x. x)
(define * λm n f x. m (n f) x)
(define zero? λn. n (const false) true)
(define pred λn f x. n (λg h. h (g f)) (const x) id)
```

With those pre-requisites defined, now we define the factorial function using self-application for recursion. This definition is tail-recursive.

```
(define !
U (lambda loop acc n.
zero? n -- branches wrapped in lambdas
-- to accomodate call-by-value
(lambda _. acc)
(lambda _. (loop loop (* n acc) (pred n))))
n) -- dummy argument to evaluate selected branch
1)
```

From here, I cheated and performed normal order evaluation on `!`

; this is essentially partial evaluation. For this to work, I had to remove the definition of `U`

to prevent divergence, then add it back in after.

Here's the resulting term. It is fairly cryptic (though I would've had difficulty writing anything this short by hand, without an interpreter) so I've added comments identifying the parts I can still recognize.

```
(λx. x x) -- self application
(λloop acc n.
n (λy t f. f) -- const false
(λt f. t) -- true
(λ_. acc) -- zero? branch
(λ_. loop loop -- other branch
(λf. n (acc f))
(λf x. n (λg h. h (g f)) (λy. x) (λx. x))) -- pred
n) -- dummy argument
(λf. f) -- 1
```

The multiplication might be hard to spot, but it's there. Now, to test it I evaluated the term applied to 3, or `(λf x. f (f (f x)))`

. Hybrid applicative and hybrid normal evaluation both reduce to a normal term without diverging, yielding `λf x. f (f (f (f (f (f x)))))`

, or 6. Other reduction strategies either diverge (due to the self application) or don't reduce to normal form.

`if`

or`cond`

)? – Jeremiah Willcock Mar 5 '11 at 19:42`let`

and/or`let*`

just as an abbreviation for the`((lambda`

idiom? That would not simplify the problem any, but it would make the resulting code cleaner. – Jeremiah Willcock Mar 5 '11 at 20:05`let`

s and`define`

s translated to`lambda`

s? – Tim Mar 5 '11 at 20:48