# Is there a way to capture the continuations in a do notation?

Since the following do block:

``````do
x <- foo
y <- bar
return x + y
``````

is desugared to the following form:

``````foo >>= (\x -> bar >>= (\y -> return x + y))
``````

aren't `\x -> ...` and `y -> ...` actually continuations here?

I was wondering if there is a way to capture the continuations in the definition of `bind`, but I can't get the types right. I.e:

``````data Pause a = Pause a | Stop

return x = Stop
m >>= k = Pause k         -- this doesn't work of course
``````

Now I tried muddling around with the types:

``````data Pause a = Pause a (a -> Pause ???) | Stop
------- k ------
``````

But this doesn't work either. Is there no way to capture these implicit continuations?

Btw, I know about the `Cont` monad, I'm just experimenting and trying out stuff.

-
I'm not sure, but maybe you need to think a little harder about what you mean by "capture the continuations". Look at your definition for `>>=`: it throws away the first argument... so what's the first argument doing there? – Owen Jul 5 '12 at 23:05

OK I'm not really sure, but let me put a few thoughts. I'm not quite sure what it ought to mean to capture the continuation. You could, for example, capture the whole `do` block in a structure:

``````{-# LANGUAGE ExistentialQuantification #-}

return x = Return x
f >>= g = Bind f g
``````

For example:

``````block :: MonadExp Int
block = do
x <- return 1
y <- return 2
return \$ x + y

show (Return _) = "Return _"
show (Bind _ _) = "Bind _ _"

print block
>> Bind _ _
``````

And then evaluate the whole thing:

``````finish :: MonadExp a -> a
finish (Return x) = x
finish (Bind f g) = finish \$ g (finish f)

print \$ finish block
>> 3
``````

Or step through it and see the parts

``````step :: MonadExp a -> MonadExp a
step (Return _) = error "At the end"
step (Bind f g) = g \$ finish f

print \$ step block
>> Bind _ _
print \$ step \$ step block
>> Return _
``````

-
This is exactly what I was trying to do - existential types were the missing link. Thanks! – Philip Kamenarsky Jul 9 '12 at 16:53

Well, I don't know if your lambdas are continuations in the strictest sense of the term, but they also look similar to this concept in my eye.

But note that if they are continuations, then the desugared monadic code is already written in continuation passing style (CPS). The usual notion of a control operator that "captures" a continuation is based on direct-style programs; the "captured" continuation is only implicit in the direct-style program, but the CPS transformation makes it explicit.

Since the desugared monadic code is already in CPS or something like it, well, maybe a way to frame your question is whether monadic code can express some of the control flow tricks that CPS code can. Typically, those tricks boil down to the idea that while under the CPS regime it is conventional for a function to finish by invoking its continuation, a function can choose to replace its continuation with another of its choosing. This replacement continuation can be constructed with a reference to the original continuation, so that it can in turn "restore" that original one if it chooses. So for example, coroutines are implemented as a mutual "replace/restore" cycle.

And looked at in this light, I think your answer is mostly no; CPS requires that in `foo >>= bar`, `foo` must be able to choose whether `bar` will be invoked at all, and `foo` must be abble to supply a substitute for `bar`, but `(>>=)` by itself does not offer a mechanism for `foo` to do this, and more importantly, `(>>=)` is in control of the execution flow, not `foo`. Some specific monads implement parts or all of it (for example, the `Maybe` monad allows `foo` to forego execution of `bar` by producing a `Nothing` result), but others don't.

Closest I could get is to forego `(>>=)` and use this instead:

``````-- | Execute action @foo@ with its "continuation" @bar@.
callCC :: Monad m => ((a -> m b) -> m b) -> (a -> m b) -> m b
foo `callCC` bar = foo bar
``````

Here `foo` can choose whether `bar` will be used at all. But notice that this `callCC` is really just `(\$)`!

-