I'm toying around with zippers, where the current element can have a different type than the left and right lists:

```
data Z a b = Z ([a], b, [a])
```

One can navigate the zipper with `moveLeft`

and `moveRight`

:

```
moveLeft :: (b -> a -> a) -> (a -> b -> b) -> Z a b -> Z a b
moveLeft listF currentF (Z (x:xs, c, ys)) = Z (xs, g x c, ((f c x):ys))
moveRight :: (b -> a -> a) -> (a -> b -> b) -> Z a b -> Z a b
moveRight listF currentF (Z (xs, c, y:ys)) = Z (((f c y):xs), g y c, ys)
```

Here, `listF`

transforms a list element and the current one into a list element to the left or right. `currentF`

transforms the current element and a list element into the current element.

If both the current and the list type are equal, moving is simple:

```
moveLeftSameType :: Z a a -> Z a a
moveLeftSameType = moveLeft const const
```

and everything works as expected, nice!

What I'd like to do now is to generalize the above idea, such that by only implementing the `listF`

and `currentF`

functions for a given `Z a b`

(say `a :: Char`

, `b :: Int`

), `moveLeft`

and `moveRight`

do the right thing automagically. What would be the correct way to do this?

*Remark*

I have tried to implement a class like this:

```
class CPos a where
listF :: c -> d -> d
currentF :: d -> c -> c
moveLeft :: a -> a
moveRight :: a -> a
```

where `moveLeft/Right`

are implemented in terms of `listF`

and `currentF`

, but this fails with

```
The class method `listF' mentions none of the type variables of the class CPos a
```

*Remark 2*

Something I don't like about the above idea in general is the fact that be allowing arbitrary functions `listF`

and `currentF`

it's impossible to guarantee

```
moveLeft . moveRight = id
```

(if the zipper is within the list, on the borders this doesn't hold anyways). Any hints to enforce this?