# What distinguishes a continuation from a function?

Continuation describes what happens next with some value, right? Isn't that just a function that takes a value and does some computation?

``````(+ (* 2 3) 5)
``````

the continuation of `(* 2 3)` is `(+ _ 5)`

``````(define k (lambda (v) (+ v 5)))
``````

What is the point of using `call/cc` in here and not using the function `k` ?

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You don't use `call/cc` whose argument is taking the current continuation (as a function). Edit your question to use `call/cc`! Read wikipage on continuation –  Basile Starynkevitch Aug 29 '13 at 22:40
I'm not using call/cc, I'm using an equivalent function represents the continuation? –  ayhid Aug 29 '13 at 22:47
Continuation is syntactically a function but it represents a control transfer. Its call protocol is different than a function's - it's supposed never to return. –  Will Ness Aug 31 '13 at 17:03

## 3 Answers

True. All programs have continuations until it halts. One continuation is usually one step in the calculation done by the underlying implementation.

Your example:

``````(+ (* 2 3) 5)
``````

The combination + is dependent on the combination * to finish first. Thus `(+ result 5)` is indeed the continuation of `(* 2 3)`. It's not a procedure in this context though. The usefulness of `call/cc` is when you have an continuation you regret and want to do something else instead or you want to come back to this at a later time. Lets do the first:

``````(define g 0)
(call/cc
(lambda (exit)
(/ 10 (if (= g 0) (exit +Inf.0) g))))
``````

Clearly, there is a division which is the continuation when the result of the if is done, but since `exit` is run the whole thing gets short circuited to return +Inf.0.

How would you do that with a procedure without getting it to do the division afterward? In this style, you can't.

It isn't really magic since Scheme converts your code to Continuation Passing Style(=CPS) and in CPS call/cc is no special. It's not trivial writing code in CPS.

Here's the CPS definition of `call/cc`

``````(define (kcall/cc k consumer)
(consumer k (lambda (ignore v) (k v))))
``````
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A 'continuation' is the entire future of a computation. Every point in a computation has a continuation which, in naive terms, you can think of as the current program-counter and current stack. The Scheme `call/cc` function conveniently captures the current configuration and packages it up into a function. When you invoke that function you revert back to that point in the computation. Thus, a continuation is very different from a function (but the continuation function is, well, a function).

There are two common cases where one typically sees `call/cc` applied:

1. non-local exit. You establish a continuation, do some computation, to abruptly end the computation you invoke the continuation.

2. restart/reenter a computation. In this case you save the continuation and then call it again as you please.

Here is an example for case #1:

``````(begin
;; do stuff
(call/cc (lambda (k)
;; do more

;; oops, must 'abort'
(k 'ignore)))
;; continue on
)
``````

And here is an example for case #2:

``````> (define c #f)
> (let ((x 10))
(display (list (+ 1 (call/cc (lambda (k) (set! c k) x))) 111))
(display " more"))
(11 111) more
> (c 20)
(21 111) more
> (c 90)
(91 111) more
``````

For this case #2 is it worth noting that the continuation brings you back to the top-level read-eval-print loop - which gives you a chance to re-invoke the continuation in this example!

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Congratulations! You've just invented continuation-passing style! The only difference between what you've done and `call/cc` is that `call/cc` does it automatically, and doesn't require you to restructure your code.

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