There is a well known issue that we cannot use `forall`

types in the `Cont`

return type.

However it should be OK to have the following definition:

```
class Monad m => MonadCont' m where
callCC' :: ((a -> forall b. m b) -> m a) -> m a
shift :: (forall r.(a -> m r) -> m r) -> m a
reset :: m a -> m a
```

and then find an instance that makes sense. In this paper the author claimed that we can implement `MonadFix`

on top of `ContT r m`

providing that `m`

implemented `MonadFix`

and `MonadRef`

. But I think if we do have a `MonadRef`

we can actually implement `callCC'`

above like the following:

```
--satisfy law: mzero >>= f === mzero
class Monad m => MonadZero m where
mzero :: m a
instance (MonadZero m, MonadRef r m) => MonadCont' m where
callCC' k = do
ref <- newRef Nothing
v <- k (\a -> writeRef ref (Just a) >> mzero)
r <- readRef ref
return $ maybe v id r
shift = ...
reset = ...
```

(Unfortunately I am not familiar with the semantic of `shift`

and `reset`

so I didn't provide implementations for them)

This implementation seems OK for me. Intuitively, when `callCC'`

being called, we feed `k`

which a function that its own effect is always fail (although we are not able to provide a value of arbitrary type `b`

, but we can always provide `mzero`

of type `m b`

and according to the law it should effectively stop all further effects being computed), and it captures the received value as the final result of `callCC'`

.

So my question is:

Is this implementation works as expected for an ideal `callCC`

? Can we implement `shift`

and `reset`

with proper semantic as well?

In addition to the above, I want to know:

To ensure the proper behaviour we have to assume some property of `MonadRef`

. So what would the laws a `MonadRef`

to have in order to make the above implementation behave as expected?

**UPDATE**

It turn out that the above naive implementation is not good enough. To make it satisfy "Continuation current"

```
callCC $\k -> k m === callCC $ const m === m
```

We have to adjust the implementation to

```
instance (MonadPlus m, MonadRef r m) => MonadCont' m where
callCC' k = do
ref <- newRef mzero
mplus (k $ \a -> writeRef ref (return a) >> mzero) (join (readRef ref))
```

In other words, the original `MonadZero`

is not enough, we have to be able to combind a `mzero`

value with a normal computation without cancelling the whole computation.

**The above does not answer the question, it is just adjusted as the original attempt was falsified to be a candidate. But for the updated version, the original questions are still questions. Especially, reset and shift are still up to be implemented.**