In most of programming languages that support mutable variables, one can easily implement something like this *Java* example:

```
interface Accepter<T> {
void accept(T t);
}
<T> T getFromDoubleAccepter(Accepter<Accepter<T>> acc){
final List<T> l = new ArrayList<T>();
acc.accept(new Accepter<T>(){
@Override
public void accept(T t) {
l.add(t);
}
});
return l.get(0); //Not being called? Exception!
}
```

Just for those do not understand Java, the above code receives something can can be provided a function that takes one parameter, and it supposed to grape this parameter as the final result.

This is not like `callCC`

: there is no control flow alternation. Only the inner function's parameter is concerned.

I think the equivalent type signature in *Haskell* should be

```
getFromDoubleAccepter :: (forall b. (a -> b) -> b) -> a
```

So, if someone can gives you a function `(a -> b) -> b`

for a type of your choice, he MUST already have an `a`

in hand. So your job is to give them a "callback", and than keep whatever they sends you in mind, once they returned to you, return **that** value to your caller.

But I have no idea how to implement this. There are several possible solutions I can think of. Although I don't know how each of them would work, I can rate and order them by prospected difficulties:

`Cont`

or`ContT`

monad. This I consider to be easiest.`RWS`

monad or similar.Any other monads.

*Pure*monads like`Maybe`

I consider harder.Use only standard

*pure*functional features like lazy evaluation, pattern-matching, the fixed point contaminator, etc. This I consider the hardest (or even impossible).

I would like to see answers using any of the above techniques (and prefer harder ways).

**Note:** There should not be any modification of the type signature, and the solution should do the same thing that the *Java* code does.

**UPDATE**

Once I seen somebody commented out `getFromDoubleAccepter f = f id`

I realize that I have made something wrong. Basically I use `forall`

just to make the game easier but it looks like this twist makes it too easy. Actually, the above type signature **forces** the caller to pass back whatever we gave them, so if we choose `a`

as `b`

then that implementation gives the same expected result, but it is just... not expected.

Actually what came up to my mind is a type signature like:

```
getFromDoubleAccepter :: ((a -> ()) -> ()) -> a
```

And this time it is harder.

Another comment writer asks for reasoning. Let's look at a similar function

```
getFunctionFromAccepter :: (((a -> b) -> b) -> b) -> a -> b
```

This one have an naive solution:

```
getFunctionFromAccepter f = \a -> f $ \x -> x a
```

But in the following test code it fails on the third:

```
exeMain = do
print $ getFunctionFromAccepter (\f -> f (\x -> 10)) "Example 1" -- 10
print $ getFunctionFromAccepter (\f -> 20) "Example 2" -- 20
print $ getFunctionFromAccepter (\f -> 10 + f (\x -> 30)) "Example 3" --40, should be 30
```

In the failing case, we pass a function that returns `30`

, and we expect to get that function back. However the final result is in turn `40`

, so it fails. Are there any way to implement doing **Just** that thing I wanted?

If this can be done in Haskell there are a lot of interesting sequences. For example, tuples (or other "algebraic" types) can be defined as functions as well, since we can say something like `type (a,b) = (a->b->())->()`

and implement `fst`

and `snd`

in term of this. And this, is the way I used in a couple of other languages that do not have native "tuple" support but features "closure".

`b`

from an`a`

, but I think that's unlikely to be satisfiable. And then it's meant to produce a type`a`

despite having no way to do so (even if the first parameter was slightly less funky there's no way it can output an`a`

). So I think you need to fix your type signature (which you say should not be modified in the answer) before it can be answered. – Neil Brown Aug 13 '13 at 3:33onlytotal implementation is`getFromDoubleAccepter f = f id`

. – luqui Aug 13 '13 at 3:43with"standard pure functional features like lazy evaluation, pattern-matching" etc. So if it's impossible with these "standard features" then it's also impossible with the monads. I also don't see how you can possibly assess the difficulty of any of those approaches if you don't actually know how to solve the problem with any of them. – Ben Aug 13 '13 at 3:59