(Sorry about the length—I go a little bit far afield/in excessive depth. The CliffsNotes version is "No, you can't really do what you want because types aren't values and we can't give your function a sensible type; use your own data type.". The first and the fifth paragraph, not counting this one or the code block, explain the core of what I mean by that first part, and the rest of the answer should provide some clarification/detail.)

Roughly speaking, no, this is not possible, for two reasons. The first is the type-dispatch issue. The `:t`

command is a feature (an enormously useful one) of GHCi, and isn't a Haskell function. Think about why: what type would it have? `:t :: a -> ?`

? Types themselves aren't values, and thus don't have a type. It's two different worlds. So the way you're trying to do this isn't possible. Also note that you have a random `do`

. This is bad—`do`

notation is a syntactic sugar for monadic computation, and you aren't doing any of that. Get rid of it!

Why is this? Haskell has two kinds polymorphism, and the one we're concerned with at the moment is parametric polymorphism. This is what you see when you have a type like `concat :: [[a]] -> a`

. That `a`

says that one single definition of `concat`

must be usable for every possible `a`

from now until the end of time. How on earth would you type `flatten`

using this scheme? It's just not possible.

You're trying to call a different function, defined ad-hoc, for different kinds of data. This is called, shockingly, ad-hoc polymorphism. For instance, in C++, you could define the following function:

```
template <typename T>
void flatten(vector<T>& v) { ... }
template <typename T>
void flatten(vector< vector<T> >& v) { ... }
```

This would allow you do different things for different types. You could even have `template <> void flatten(int) { ... }`

! You *can* accomplish this in Haskell by using type classes such as `Num`

or `Show`

; the whole point of a type signature like `Show a => a -> String`

is that a different function can be called for different `a`

s. And in fact, you can take advantage of this to get a partial solution to your problem…but before we do, let's look at the second problem.

This issue is with the list you are trying to feed in. Haskell's list type is defined as (roughly) `data [a] = [] | a : [a]`

. In other words, every element of a list must have the same type; a list of ints, `[Int]`

, contains only ints, `Int`

; and a list of lists of ints, `[[Int]]`

, contains only lists of ints, `[Int]`

. The structure `[1,2,[3,4],5]`

is illegal! Reading your code, I think you understand this; however, there's another ramification. For similar reasons, you can't write a fully-generic flatten function of type `flatten :: [...[a]...] -> [a]`

. Your *function* also has to be able to deal with arbitrary nesting *depth*, which still isn't possible with a list. You need `[a]`

, `[[a]]`

, and so on to all be the same type!

Thus, to get all of the necessary properties, you want a different type. The type you want has a different property: it contains either nothing, a single element followed by the rest of the value, or a nested list of elements followed by the rest of the value. In other words, something like

```
data NList a = Nil
| a :> NList a
| (NList a) :>> NList a
deriving (Eq, Show)
infixr 5 :>, :>>
```

Then, instead of the list `[1,2,3] == 1 : 2 : 3 : []`

, you would write `1 :> 2 :> 3 :> Nil`

; instead of Lisp's `(1 (2 3) 4 ())`

, you would write
`1 :> (2 :> 3 :> Nil) :>> 4 :> Nil :>> Nil`

. You can even begin to define functions to manipulate it:

```
nhead :: NList a -> Either a [a]
nhead Nil = error "nhead: Empty NList."
nhead (h :> _) = Left a
nhead (h :>> _) = Right a
ntail :: NList a -> NList a
ntail Nil = error "nhead: Empty NList."
ntail (_ :> t) = t
ntail (_ :>> t) = t
```

Admittedly, you might find this a bit clunky (or perhaps not), so you might try to think about your type differently. Another option, which the Haskell translation of the 99 problems uses, is to realize that everything in a nested list is either a single item or a list of nested lists. This translation gives you

```
data NestedList a = Elem a
| List [NestedList a]
deriving (Eq, Show)
```

The two above lists then become `List [Elem 1, Elem 2, Elem 3]`

and `List [Elem 1, List [Elem 2, Elem 3], Elem 4, List []]`

. As for how to flatten them—since you're trying to learn from the 99 problems, that I won't say :) And after all, you seem to have a handle on that part of the problem.

Now, let's return to type classes. I lied a bit when I said that you couldn't write something which took an arbitrarily-nested list—you can, in fact, using type classes and some GHC extensions. Now, before I continue, I should say: **don't use this!** Seriously. The other technique is almost definitely a better choice. However, this technique is cool, and so I will present it here. Consider the following code:

```
{-# LANGUAGE MultiParamTypeClasses, FlexibleInstances, UndecidableInstances #-}
class Flattenable f e where
flatten :: f -> [e]
instance Flattenable a a where
flatten = return
instance Flattenable f e => Flattenable [f] e where
flatten = concatMap flatten
```

We are creating a *type class* whose instances are the things we can flatten. If we have `Flattenable f e`

, then `f`

should be a collection, in this case a list, whose elements are ultimately of type `e`

. Any single object is such a collection, and its element type is itself; thus, the first instance declaration allows us to flatten anything into a singleton list. The second instance declaration says that if we can flatten an `f`

into a list of `e`

s, then we can also flatten a list of `f`

s into a list of `e`

s by flattening each `f`

and sticking the resulting lists together. This recursive class definition defines the function recursively for the nested list types, giving you the ability to flatten a list of any nesting with the single function `flatten`

: `[1,2,3]`

, `[[4,5],[6]]`

, `[[[7,8],[9]],[[10]],[[11],[12]]]`

, and so on.

However, because of the multiple instances and such, it does require a single type annotation: you will need to write, for instance, `flatten [[True,False],[True]] :: [Bool]`

. If you have something that's type class-polymorphic within your lists, then things are a little stricter; you need to write `flatten [[1],[2,3 :: Int]] :: [Int]`

, and as far as I can tell, the resulting list cannot be polymorphic itself. (However, I could well be wrong about this last part, as I haven't tried everything by any means.) For a similar reason, this is too open—you could declare `instance Flattenable [f] () where flatten = [()]`

if you wanted too. I tried to get things to work with type families/functional dependencies in order to remove some of these problems, but thanks to the recursive structure, couldn't get it to work (I had no `e`

and a declaration along the lines of `type Elem a = a`

and `type Elem [f] = Elem f`

, but these conflicted since `[f]`

matches `a`

). If anyone knows how, I'd very much like to see it!

Again, sorry about the length—I tend to start blathering when I get tired. Still, I hope this is helpful!

`do`

in your function definition is superfluous. – sepp2k Jun 4 '10 at 13:06