It does work very much like Scheme's call/cc. You need to take into account that it is in Cont monad.

The actual function is defined using ContT. ContT is a monad transformer that allows to add continuations into other monads, but let's see how this works with Identity monad first, and limit ourselves to Cont.

```
Cont r a = Cont {runCont :: (a->r)->r}
```

Here, `Cont r a`

represents a function that can compute some value of type `a`

, since given a function of type `a->r`

it can compute a value of type `r`

.

It is clearly a monad:

```
return x = Cont $ \f -> f x
```

(a trivial "computation" of a value of type `a`

)

```
ma >>= h = Cont $ \f -> runCont ma $ \a -> runCont (h a) f
```

(here `ma :: Cont r a`

, and `h :: a -> Cont r b`

)

(a computation of value of type `a`

, ma, can turn into a computation of a value of type `b`

- `runCont ma`

is given `h`

, which, given a value of type `a`

, "knows" how to produce a computation of a value of type `b`

- which can be supplied with function `f :: b -> r`

to compute a value of type `r`

)

In essence, `h`

is the **continuation** of `ma`

, and `>>=`

binds `ma`

and its continuation to produce the continuation of the function composition (the function "hidden" inside `ma`

to produce `a`

and the function "hidden" inside `h`

to produce `b`

). This is the "stack" you were looking for.

Let's start with the simplified type (not using `ContT`

):

```
callCC :: ((a -> Cont r b) -> Cont r a) -> Cont r a
```

Here, callCC uses a function that constructs a continuation given a continuation.

There is a important point that you seem to be missing, too. `callCC`

only makes sense if there is a continuation after `callCC`

- i.e. there is a continuation to pass. Let's consider it is the last line of a `do`

-block, which is the same as to say it must have something bound to it with `>>=`

:

```
callCC f >>= return "blah"
```

will do. The important bit here is that the operation of `callCC`

can be understood easier when you see this context, when you see it is on the left hand side of `>>=`

.

Knowing how `>>=`

works, and taking into account right-associativity of `>>=`

, you can see that `h`

in `callCC f = cont $ \h -> runCont (f (\a -> cont $ \_ -> h a)) h`

is in fact built using current continuation - it is built using the `h`

appearing on the right of `>>=`

- the entire `do`

-block from the line following callCC to the end:

```
(callCC f) >>= h =
Cont $ \g -> runCont
(cont $ \h -> runCont (f (\a -> cont $ \_ -> h a)) h) $
\a -> runCont (h a) g =
[reduction step: runCont (Cont x) => x]
Cont $ \g -> (\h -> runCont (f (\a -> Cont $ \_ -> h a)) h) $
\a -> runCont (h a) g =
[(\h -> f) (\a -> ...) => f [h/(\a -> ...)] -- replace
occurrences of h with (\a -> ...)]
Cont $ \g -> runCont (f (\a -> Cont $ \_ -> (\b -> runCont (h b) g) a)) $
\a -> runCont (h a) g =
[(\b -> runCont (h b) g) a => runCont (h a) g]
Cont $ \g -> runCont (f (\a -> Cont $ \_ -> runCont (h a) g)) $
\a -> runCont (h a) g
```

You can see here how `\_ -> runCont (h a) g`

in essence will ignore the continuation following the invocation of the function passed to `f`

- and "switch the stack", switch to the current continuation `h`

of the place where `callCC`

is invoked.

(Similar reasoning can be applied if `callCC`

is the last in the chain, albeit it is less clear that the "current continuation" in that case is the function passed to `runCont`

)

The last point is that `runCont (f...) h`

does not really use this last `h`

, if the actual invocation of `h`

occurs from inside the continuation computed by `f`

, if that ever happens.