I think I may have asked this on Haskell-Cafe at some point, but damned if I can find the answer now... So I'm asking it again here, so hopefully in future I can *find* the answer!

Haskell is *fantastic* at dealing with parametric polymorphism. But the trouble is that not everything is parametric. As a trivial example, suppose we want to fetch the first element of data out of a container. For a parametric type, that's trivial:

class HasFirst c where first :: c x -> Maybe x instance HasFirst [] where first [] = Nothing first (x:_) = Just x

Now try and write an instance for `ByteString`

. You can't. Its type doesn't mention the element type. You also cannot write an instance for `Set`

, because it requires an `Ord`

constraint - but the class head doesn't mention the element type, so you cannot constrain it.

Associated types provide a neat way to completely fix these problems:

class HasFirst c where type Element c :: * first :: c -> Maybe (Element c) instance HasFirst [x] where type Element [x] = x first [] = Nothing first (x:_) = Just x instance HasFirst ByteString where type Element ByteString = Word8 first b = b ! 0 instance Ord x => HasFirst (Set x) where type Element (Set x) = x first s = findMin s

We now have a new problem, however. Consider trying to "fix" `Functor`

so that it works for all container types:

class Functor f where type Element f :: * fmap :: (Functor f2) => (Element f -> Element f2) -> f -> f2

This doesn't work at all. It says that if we have a function from the element type of `f`

to the element type of `f2`

, then we can turn an `f`

into an `f2`

. So far so good. However, there is apparently *no way* to demand that `f`

and `f2`

are *the same sort of container!*

Under the existing `Functor`

definition, we have

fmap :: (x -> y) -> [x] -> [y] fmap :: (x -> y) -> Seq x -> Seq y fmap :: (x -> y) -> IO x -> IO y

But we do *not* have `fmap :: (x -> y) -> IO x -> [y]`

. That is quite impossible. But the class definition above allows it.

Does anybody know how to explain to the type system what I *actually* meant?

**Edit**

The above works by defining a way to compute an element type from a container type. What happens if you try to do it the other way around? Define a function to compute a container type from an element type? Does that work out any easier?