# how to understand this continuation?

``````(let ([x (call/cc (lambda (k) k))])
(x (lambda (ignore) "hi")))  => "hi"
``````

How can I write the executing steps of this continuation?

-

The `call/cc` operator is used to call a given procedure with the current continuation (hence the name `call-with-current-continuation`). So to understand how it works, we need to know what the current continuation is.

In your program, at the point that the `call/cc` is executed, the continuation looks like this:

``````CONT = (let ([x HOLE])
(x (lambda (ignore) "hi")))
``````

where `HOLE` is a placeholder for a value to plug in. In other words, the continuation is the remaining computation. You can stick a value into the continuation if you want to progress.

Now, `call/cc` captures this continuation and passes it to the procedure `(lambda (k) k)`. You can see that this procedure just immediately returns the continuation. So the program reduces to:

``````(let ([x CONT])
(x (lambda (ignore) "hi")))
``````

Applying a continuation captured by `call/cc` replaces the current computation with that continuation plugged with the value you give it. So the application `(x (lambda (ignore) "hi"))` turns into:

``````(let ([x (lambda (ignore) "hi")])
(x (lambda (ignore) "hi")))
``````

-

In the first line `[x (call/cc (lambda (k) k))]` we're creating a new continuation which is bound to the `k` parameter in the received `lambda`. That `k` is returned and in turn bound to the `x` local variable - therefore, `x` is a continuation.

In the second line, `x` is called with a single-argument `lambda`; the argument is ignored and the result of invoking `(lambda (ignore) "hi")` is `"hi"`, which is finally returned as the result of the continuation. This is equivalent to simply calling:

``````(call/cc
(lambda (k)
(k "hi")))
``````
-

Why does this expression evaluate to "hi" ?

``````(let ([x (call/cc (lambda (k) k))])
(x (lambda (ignore) "hi")))
``````

The first step is to decide what `k` looks like:

``````(define k
(lambda (value)
(let ((x value))
(x (lambda (ignore) "hi")))))
``````

We see immediately that this is the same as

``````(define k
(lambda (x)
(x (lambda (ignore) "hi"))))
``````

But, I failed to mention one little detail. If `k` is ever invoked, it is as if it were invoked in tail position.

So `(f (k 3))` for all continuations `k` built by `call/cc` is the same as `(k 3)`. That is always a little bit tricky.

So, let's use `lambda^` to mean that the function it introduces is to be invoked as if it were in tail position.

``````(define k
(lambda^ (x)
(x (lambda (ignore) "hi"))))
``````

Now we know what `k` is, we also need to know that returning out of `(call/cc (lambda (k) k))` is really using a default.

It should have been written correctly as

``````(call/cc (lambda (k) (k k))).
``````

There is always an implied invocation of k at the top of the body of the lambda expression passed to `call/cc`.

We know what `k` is.

So, we know that this must be the same as, (for ease of reading let's turn the `x`'s in the argument position into `y`'s.)

``````((lambda^ (x) (x (lambda (ignore) "hi")))
(lambda^ (y) (y (lambda (ignore) "hi"))))
``````

So, we evaluate both positions to functions.

Once we invoke the function in function position, we are done, since it is headed by `lambda^` So, we need to know that

``````((lambda^ (x) (x (lambda (ignore) "hi")))
(lambda^ (y) (y (lambda (ignore) "hi"))))
``````

evaluates to, substituting for `x`

``````((lambda^ (y) (y (lambda (ignore) "hi")))
(lambda (ignore) "hi"))
``````

and one more step, substituting for `y`

`((lambda (ignore) "hi") (lambda (ignore) "hi"))`, which ignores its argument and returns "hi"