# my CPS is right?

in "The Scheme Programming Language 4th Edition", there is a example as below:

``````
(define product
(lambda (ls)
(call/cc
(lambda (break)
(let f ([ls ls])
(cond
[(null? ls) 1]
[(= (car ls) 0) (break 0)]
[else (* (car ls) (f (cdr ls)))]))))))
``````
(product '(1 2 3 4 5)) => 120

(product '(7 3 8 0 1 9 5)) => 0

later it is converted into CPS in 3.3 as below

``````
(define product
(lambda (ls k)
(let ([break k])
(let f ([ls ls] [k k])
(cond
[(null? ls) (k 1)]
[(= (car ls) 0) (break 0)]
[else (f (cdr ls)
(lambda (x)
(k (* (car ls) x))))])))))
``````
(product '(1 2 3 4 5) (lambda (x) x)) => 120

(product '(7 3 8 0 1 9 5) (lambda (x) x)) => 0

I want to do it myself, The corresponding CPS is below

``````
(define (product ls prod break)
(cond
((null? ls)
(break prod))
((= (car ls) 0)
(break 0))
(else
(product (cdr ls) (* prod (car ls)) break))))
``````
(product '(1 2 3 4 5) 1 (lambda (x) x)) => 120

(product '(1 2 0 4 5) 1 (lambda (x) x)) => 0

I want to ask my CPS is right? T Thanks in advance!

BEST REGARDS

-
Where are your test cases? This is not meant to be a flippant question. If you don't know how to call a CPS'ed function, you've missed something important. –  dyoo Jul 5 '12 at 3:00
Also, you should note that the function that you've CPSed is not the original "product" function, but one that's written with a standard accumulator. (define (p l acc) (if (null? l) acc (p (cdr l) (* acc (car l)))) is not exactly the function you transformed, but it's close. (My definition of f just omits the early escape when we hit a zero.) In any event, the function that you transformed exhibited iterative recursion, and you can see this because your CPSed version of it doesn't need to construct new continuations. –  dyoo Jul 5 '12 at 3:10
the original case is here :scheme.com/tspl4/further.html#./further:h4 –  abelard20008 Jul 9 '12 at 2:35

I think this is the correct implementation :

``````(define inside-product #f)  ;; to demonstrate the continuation

(define (product ls prod break)
(cond
((null? ls)
(begin
(set! inside-product prod)
(prod 1)))
((= (car ls) 0)
(break 0))
(else
(product (cdr ls) (lambda (x) (prod (* (car ls) x))) break))))

(define identity (lambda (x) x))
``````

The idea of CPS is to keep a track of the recursion.

``````> (product (list 1 2 3) identity identity)
6
> (inside-product 4)
24
``````
-
Unfortunately, I have to -1 this: there's not a use of set! in the original code, and the use of mutation here confuses issues. –  dyoo Jul 5 '12 at 2:59
I used the set! on purpose, in order to demonstrate the continuation. When the end of the list is reached, the value of inside-product is set to the continuation. So, once the product procedure is executed as shown in the example, the value of inside-product is set to (lambda (x) ((lambda (x) ((lambda (x) (identity (* 1 x))) (* 2 x))) (* 3 x))) –  Rajesh Bhat Jul 5 '12 at 12:43
Hmmm... Ok. The question that the original questioner asked is still ambiguous, as he or she needs to say what function was transformed to CPS. From what I can tell, prod is supposed to be an accumulator in the original question. Yet there's no original source code pre-CPS-transform in the question that corresponds to a use of prod this way. So something is missing from the question. –  dyoo Jul 6 '12 at 23:20
In my original question, prod is a number 1, so, I can call "product" like this : (product '(1 2 3 4 5) 1 (lambda (x) x)) => 120, maybe, my understanding about CPS is wrong, Where I can study CPS step by step, Thanks in advance! –  abelard20008 Jul 9 '12 at 2:46
You can look at textbooks such as Programming Languages: Application and Interpretation, as well as Essentials of Programming Languages. Both have chapters on CPS, if I'm remembering right. Google for "PLAI" and you should find the first textbook online. –  dyoo Jul 9 '12 at 13:57
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