# Scheme evolution

## Regular Scheme program:

```
(define factorial
(lambda (n)
(if (= n 0)
1
(* n (factorial (- n 1))))))
```

Should work, but notice that calling this function on large numbers will extend the stack on every recursion, which is bad in languages like C and Java.

## Continuation-passing style

```
(define factorial
(lambda (n)
(factorial_cps n (lambda (k) k))))
(define factorial_cps
(lambda (n k)
(if (zero? n)
(k 1)
(factorial (- n 1) (lambda (v)
(k (* n v)))))))
```

Ah, this way, we don't grow our stack every recursion because we can extend a continuation instead. However, C doesn't have continuations.

## Representation-independent CPS

```
(define factorial
(lambda (n)
(factorial_cps n (k_))))
(define factorial_cps
(lambda (n k)
(if (zero? n)
(apply_k 1)
(factorial (- n 1) (k_extend n k))))
(define apply_k
(lambda (ko v)
(ko v)))
(define kt_empty
(lambda ()
(lambda (v) v)))
(define kt_extend
(lambda ()
(lambda (v)
(apply_k k (* n v)))))
```

Notice that responsibility for representation of the continuations used in the original CPS program has been shifted to the `kt_`

helper procedures.

## Representation-independent CPS using ParentheC unions

Since representation of the continuations is in the helper procedures, we can switch to using ParentheC instead, with `kt_`

being a type designator.

```
(define factorial
(lambda (n)
(factorial_cps n (kt_empty))))
(define factorial_cps
(lambda (n k)
(if (zero? n)
(apply_k 1)
(factorial (- n 1) (kt_extend n k))))
(define-union kt
(empty)
(extend n k))
(define apply_k
(lambda ()
(union-case kh kt
[(empty) v]
[(extend n k) (begin
(set! kh k)
(set! v (* n v))
(apply_k))])))
```

## Trampolined, registerized ParentheC program

That's not enough. We now replace all function calls by instead setting global variables and a program counter. Procedures are now labels suitable for GOTO statements.

```
(define-registers n k kh v)
(define-program-counter pc)
(define-label main
(begin
(set! n 5) ; what is the factorial of 5??
(set! pc factorial_cps)
(mount-trampoline kt_empty k pc)
(printf "Factorial of 5: ~d\n" v)))
(define-label factorial_cps
(if (zero? n)
(begin
(set! kh k)
(set! v 1)
(set! pc apply_k))
(begin
(set! k (kt_extend n k))
(set! n (- n 1))
(set! pc factorial_cps))))
(define-union kt
(empty dismount) ; get off the trampoline!
(extend n k))
(define-label apply_k
(union-case kh kt
[(empty dismount) (dismount-trampoline dismount)]
[(extend n k) (begin
(set! kh k)
(set! v (* n v))
(set! pc apply_k))]))
```

Oh look, we have a `main`

procedure now too. Now all that's left to do is save this file as `fact5.pc`

and run it through ParentheC's pc2c:

```
> (load "pc2c.ss")
> (pc2c "fact5.pc" "fact5.c" "fact5.h")
```

Could it be? We got `fact5.c`

and `fact5.h`

. Let's see...

```
$ gcc fact5.c -o fact5
$ ./fact5
Factorial of 5: 120
```

Success! We have converted a recursive Scheme program into a non-recursive C program! And it only took several hours and many forehead-shaped impressions in the wall to do it! For convenience, fact5.c and
and fact5.h.