Note: This answer is available as a literate Haskell file at Gist.

I quite enjoyed this exercise. I tried to do it without looking at the answers, and it was worth it. It took me considerable time, but the result is surprisingly close to two of the other answers, as well as to monad-coroutine library. So I guess this is somewhat natural solution to this problem. Without this exercise, I wouldn't understand how *monad-coroutine* really works.

To add some additional value, I'll explain the steps that eventually led me to the solution.

**Recognizing the state monad**

Since we're dealing with states, it we look for patterns that can be effectively described by the state monad. In particular, `s - s`

is isomorphic to `s -> (s, ())`

, so it could be replaced by `State s ()`

. And function of type `s -> x -> (s, y)`

can be flipped to `x -> (s -> (s, y))`

, which is actually `x -> State s y`

. This leads us to updated signatures

```
mutate :: State s () - Pause s ()
step :: Pause s () - State s (Maybe (Pause s ()))
```

**Generalization**

Our `Pause`

monad is currently parametrized by the state. However, now we see that we don't really need the state for anything, nor we use any specifics of the state monad. So we could try to make a more general solution that is parametrized by any monad:

```
mutate :: (Monad m) = m () -> Pause m ()
yield :: (Monad m) = Pause m ()
step :: (Monad m) = Pause m () -> m (Maybe (Pause m ()))
```

Also, we could try to make `mutate`

and `step`

more general by allowing any kind of value, not just `()`

. And by realizing that `Maybe a`

is isomorphic to `Either a ()`

we can finally generalize our signatures to

```
mutate :: (Monad m) = m a -> Pause m a
yield :: (Monad m) = Pause m ()
step :: (Monad m) = Pause m a -> m (Either (Pause m a) a)
```

so that `step`

returns the intermediate value of the computation.

**Monad transformer**

Now, we see that we're actually trying to make a monad from a monad - add some additional functionality. This is what is usually called a monad transformer. Moreover, `mutate`

's signature is exactly the same as lift from `MonadTrans`

. Most likely, we're on the right track.

**The final monad**

The `step`

function seems to be the most important part of our monad, it defines just what we need. Perhaps, this could be the new data structure? Let's try:

```
import Control.Monad
import Control.Monad.Cont
import Control.Monad.State
import Control.Monad.Trans
data Pause m a
= Pause { step :: m (Either (Pause m a) a) }
```

If the `Either`

part is `Right`

, it's just a monadic value, without any
suspensions. This leads us how to implement the easist thing - the `lift`

function from `MonadTrans`

:

```
instance MonadTrans Pause where
lift k = Pause (liftM Right k)
```

and `mutate`

is simply a specialization:

```
mutate :: (Monad m) => m () -> Pause m ()
mutate = lift
```

If the `Either`

part is `Left`

, it represents the continued computation after a suspension. So let's create a function for that:

```
suspend :: (Monad m) => Pause m a -> Pause m a
suspend = Pause . return . Left
```

Now `yield`

ing a computation is simple, we just suspend with an empty
computation:

```
yield :: (Monad m) => Pause m ()
yield = suspend (return ())
```

Still, we're missing the most important part. The `Monad`

instance. Let's fix
it. Implementing `return`

is simple, we just lift the inner monad. Implementing `>>=`

is a bit trickier. If the original `Pause`

value was only a simple value (`Right y`

), then we just wrap `f y`

as the result. If it is a paused computation that can be continued (`Left p`

), we recursively descend into it.

```
instance (Monad m) => Monad (Pause m) where
return x = lift (return x) -- Pause (return (Right x))
(Pause s) >>= f
= Pause $ s >>= \x -> case x of
Right y -> step (f y)
Left p -> return (Left (p >>= f))
```

**Testing**

Let's try to make some model function that uses and updates state, yielding
while inside the computation:

```
test1 :: Int -> Pause (State Int) Int
test1 y = do
x <- lift get
lift $ put (x * 2)
yield
return (y + x)
```

And a helper function that debugs the monad - prints its intermediate steps to
the console:

```
debug :: Show s => s -> Pause (State s) a -> IO (s, a)
debug s p = case runState (step p) s of
(Left next, s') -> print s' >> debug s' next
(Right r, s') -> return (s', r)
main :: IO ()
main = do
debug 1000 (test1 1 >>= test1 >>= test1) >>= print
```

The result is

```
2000
4000
8000
(8000,7001)
```

as expected.

**Coroutines and ***monad-coroutine*

What we have implemented is a quite general monadic solution that implements Coroutines. Perhaps not surprisingly, someone had the idea before :-), and created the monad-coroutine package. Less surprisingly, it's quite similar to what we created.

The package generalizes the idea even further. The continuing computation is stored inside an arbitrary functor. This allows suspend many variations how to work with suspended computations. For example, to pass a value to the caller of resume (which we called `step`

), or to wait for a value to be provided to continue, etc.

`Cont`

instance, I'd think; poke at`callCC`

. – geekosaur Apr 19 '12 at 21:21resume(ResumeT) but for some reason it disappeared around version 6.8 I think. – stephen tetley Apr 19 '12 at 21:50