# Scheme: how does a nested call/cc work for a coroutine?

I am looking at the following example for a coroutine from http://community.schemewiki.org/?call-with-current-continuation:

`````` (define (hefty-computation do-other-stuff)
(let loop ((n 5))
(display "Hefty computation: ")
(display n)
(newline)
(set! do-other-stuff (call/cc do-other-stuff)) ; point A
(display "Hefty computation (b)")
(newline)
(set! do-other-stuff (call/cc do-other-stuff))
(display "Hefty computation (c)")
(newline)
(set! do-other-stuff (call/cc do-other-stuff))
(if (> n 0)
(loop (- n 1)))))
``````

superfluous work:

`````` ;; notionally displays a clock
(define (superfluous-computation do-other-stuff)
(let loop ()
(for-each (lambda (graphic)
(display graphic)
(newline)
(set! do-other-stuff (call/cc do-other-stuff)))
'("Straight up." "Quarter after." "Half past."  "Quarter til.")) ; point B
(loop)))

(hefty-computation superfluous-computation)
``````

For the first usage of call/cc, what is the context supposed to be? When I say context, I mean where are we supposed to "return to" as a result of callcc's jump?

From what I understand, the first time you call call/cc, do-other-stuff essentially becomes a procedure that executes the code of superfluous-computation and then jumps to the point right after the set! (point A). The second time, it will wrap its "jump to point B" behavior around the "jump to point A and execute the context, or whatever code follows point A". Is this correct?

It doesn't seem like this code would work if the set! actually happened. Or is the set! necessary for this code to work?

A visual representation of what's going on would really help.

The context of `call/cc` is where ever `call/cc` is being called from. You can almost think of a `call/cc` like `goto` that jumps the code right back to where you were before and substitutes `(call/cc whatever)` with the return value.

`call/cc` basically says, "let's go do this function and give it away to jump right back here and forget about whatever else it was doing"

Ok when I was trying to understand `call/cc` for the first time, I found this code confusing in the extreme so let's look at a simplified coroutine example:

``````(define r1
(lambda (cont)
(display "I'm in r1!")
(newline)
(r1 (call/cc cont))))

(define r2
(lambda (cont2)
(display "I'm in r2!")
(newline)
(r2 (call/cc cont2))))
``````

Ok this is exactly the same concept as your code. But it's much simpler.

In this case, if we call `(r1 r2)` this prints

``````I'm in r1
I'm in r2
I'm in r1
I'm in r2
I'm in r1
I'm in r2
I'm in r1
I'm in r2
...
``````

Why? Because `r1` first takes in r2 as `cont` so it announces to us that it's in r1. And then it recurses on itself with the result of `(call/cc cont)` aka `(call/cc r2)`.

Ok so what's the return of this? well `(call/cc r2)` will start executing r2 and announce that it's in r2 and then recurse on itself with the result of `(call/cc cont2)`. Ok so what was `cont2` again? `cont2` was a continuation to that expression before in `r1`. So when we call it here, we pass back a continuation to the spot we're currently at. Then we forget anything about what we were doing in r2 and hop back into executing r1.

This repeats in `r1` now. We announce stuff and then jump back to where we where before in r2 with and our expression from before, `(call/cc cont2)` returns a continuation to where we were in `r1` and then we continue in our merry infinite loop.

In your code the concept is exactly the same. In fact `superfluous-computation` is almost identical to the above functions when you stop and think about it. So what's up with the `set!`s? In this code all they do is change the value of `do-other-work` to the newest continuation. That's it. In my example I used recursion. In this example they use `set!`.
• When you say "cont2 was a continuation to that expression before in r1", are you saying that cont2 is a procedure that jumps back to the line `r1 (call/cc cont)`, except `(call/cc cont)` is replaced with a procedure that jumps to where r2 is about to recurse? I'm having trouble understanding what the `call/cc cont` finally ends up evaluating to before you actually finish the result of `r1 (call/cont)`. – hxngsun Nov 12 '12 at 6:14
• saying `(cont2 val)` is akin to saying jump back to `r1 (call/cc cont)` and replacing `(call/cc cont)` with val – Daniel Gratzer Nov 12 '12 at 6:18
• Really when I say replace, I mean that `(call/cc cont)` evaluates to val. You can think of it like a replacement if it helps – Daniel Gratzer Nov 12 '12 at 6:19