"Implementing `call/cc`

" doesn't really make sense at the layer you're working in; if you can implement `call/cc`

in a language, that just means it has a built-in construct at least as powerful as `call/cc`

. At the level of the language itself, `call/cc`

is basically a primitive control flow operator, just like some form of branching must be.

Of course, you can implement a language with `call/cc`

in a language without it; this is because it's at a lower level. You're translating the language's constructs in a specific manner, and you arrange this translation so that you can implement `call/cc`

; i.e., generally, continuation-passing style (although for non-portable implementation in C, you can also just copy the stack directly; I'll cover continuation-passing style in more depth later). This does not really give any great insight into `call/cc`

*itself* — the insight is into the model with which you make it possible. On top of that, `call/cc`

is just a wrapper.

Now, Haskell does not expose a notion of a continuation; it would break referential transparency, and limit possible implementation strategies. `Cont`

is implemented in Haskell, just like every other monad, and you can think of it as a model of a language with continuations using continuation-passing style, just like the list monad models nondeterminism.

Technically, that definition of `callCC`

does type if you just remove the applications of `Cont`

and `runCont`

. But that won't help you understand how it works in the context of the `Cont`

monad, so let's look at its definition instead. (This definition isn't the one used in the current Monad Transformer Library, because all of the monads in it are built on top of their transformer versions, but it matches the snippet's use of `Cont`

(which only works with the older version), and simplifies things dramatically.)

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

OK, so `Cont r a`

is just `(a -> r) -> r`

, and `runCont`

lets us get this function out of a `Cont r a`

value. Simple enough. But what does it mean?

`Cont r a`

is a continuation-passing computation with final result `r`

, and result `a`

. What does final result mean? Well, let's write the type of `runCont`

out more explicitly:

```
runCont :: Cont r a -> (a -> r) -> r
```

So, as we can see, the "final result" is the value we get out of `runCont`

at the end. Now, how can we build up computations with `Cont`

? The monad instance is enlightening:

```
instance Monad (Cont r) where
return a = Cont (\k -> k a)
m >>= f = Cont (\k -> runCont m (\result -> runCont (f result) k))
```

Well, okay, it's enlightening if you already know what it means. The key thing is that when you write `Cont (\k -> ...)`

, `k`

is *the rest of the computation* — it's expecting you to give it a value `a`

, and will then give you the final result of the computation (of type `r`

, remember) back, which you can then use as your own return value because your return type is `r`

too. Whew! And when we run a `Cont`

computation with `runCont`

, we're simply specifying the final `k`

— the "top level" of the computation that produces the final result.

What's this "rest of the computation" called? A *continuation,* because it's the *continuation* of the computation!

`(>>=)`

is actually quite simple: we run the computation on the left, giving it our *own* rest-of-computation. This rest-of-computation just feeds the value into `f`

, which produces its own computation. We run that computation, feeding it into the rest-of-computation that our combined action has been given. In this way, we can thread together computations in `Cont`

:

```
computeFirst >>= \a ->
computeSecond >>= \b ->
return (a + b)
```

or, in the more familiar `do`

notation:

```
do a <- computeFirst
b <- computeSecond
return (a + b)
```

We can then run these computations with `runCont`

— most of the time, something like `runCont foo id`

will work just fine, turning a `foo`

with the same result and final result type into its result.

So far, so good. Now let's make things confusing.

```
wtf :: Cont String Int
wtf = Cont (\k -> "eek!")
aargh :: Cont String Int
aargh = do
a <- return 1
b <- wtf
c <- return 2
return (a + b + c)
```

What's going on here?! `wtf`

is a `Cont`

computation with final result `String`

and result `Int`

, but there's no `Int`

in sight.

What happens when we run `aargh`

, say with `runCont aargh show`

— i.e., run the computation, and `show`

its `Int`

result as a `String`

to produce the final result?

We get `"eek!"`

back.

Remember how `k`

is the "rest of the computation"? What we've done in `wtf`

is cunningly *not* call it, and instead supply our own final result — which then becomes, well, final!

This is just the first thing continuations can do. Something like `Cont (\k -> k 1 + k 2)`

runs the rest of the computation as if it returned 1, *and again* as if it returned 2, and adds the two final results together! Continuations basically allow expressing *arbitrarily complex non-local control flow,* making them as powerful as they are confusing. Indeed, continuations are so general that, in a sense, every monad is a special case of `Cont`

. Indeed, you can think of `(>>=)`

in general as using a kind of continuation-passing style:

```
(>>=) :: (Monad m) => m a -> (a -> m b) -> m b
```

The second argument is a continuation taking the result of the first computation and returning the rest of the computation to be run.

But I still haven't answered the question: what's going on with that `callCC`

? Well, it calls the function you give with the current continuation. But hang on a second, isn't that what we were doing with `Cont`

already? Yes, but compare the types:

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

Huh. You see, the problem with `Cont`

is that we can't sequence actions from *inside* of the function we pass — we're just producing an `r`

result in a pure manner. `callCC`

lets the continuation be accessed, passed around, and just generally be messed around with from *inside* `Cont`

computations. When we have

```
do a <- callCC (\cc -> ...)
foo ...
```

You can imagine `cc`

being a function we can call with any value inside the function to make that the return value of `callCC (\cc -> ...)`

computation *itself*. Or, of course, we could just return a value normally, but then calling `callCC`

in the first place would be a little pointless :)

As for the mysterious `b`

there, it's just because you can use `cc foo`

to stand in for a computation of *any* type you want, since it *escapes* the normal control flow and, like I said, immediately uses that as the result of the entire `callCC (\cc -> ...)`

. So since it never has to actually produce a value, it can get away with returning a value of any type it wants. Sneaky!

Which brings us to the actual implementation:

```
callCC f = Cont (\k -> runCont (f (\a -> Cont (\_ -> k a))) k)
```

First, we get the entire rest of the computation, and call it `k`

. But what's this `f (\a -> Cont (\_ -> k a))`

part about? Well, we know that `f`

takes a value of type `(a -> Cont r b)`

, and that's what the lambda is — a function that takes a value to use as the result of the `callCC f`

, and returns a `Cont`

computation that ignores its continuation and just returns that value through `k`

— the "rest of the computation" from the perspective of `callCC f`

. OK, so the result of that `f`

call is another `Cont`

computation, which we'll need to supply a continuation to in order to run. We just pass the same continuation again since, if everything goes normally, we want whatever the computation returns to be our return value and continue on normally. (Indeed, passing another value wouldn't make *sense* — it's "call with *current* continuation", not "call with a continuation other than the one you're actually running me with".)

All in all, I hope you found this as enlightening as it is long. Continuations are very powerful, but it can take a lot of time to get an intuition for how they work. I suggest playing around with `Cont`

(which you'll have to call `cont`

to get things working with the current mtl) and working out how you get the results you do to get a feel for the control flow.

Recommended further reading on continuations: