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I'm trying to flatten an arbitrary number of lists inside lists in Haskell. I know this question has been posted up on Stack before, but the answers on there are either too complicated for me (I'm new to Haskell), or not an answer satisfying my needs (e.g. concat won't work for me because I have to actually write this flatten function myself for an exam study guide). I'm also writing my own flatten function in Haskell to understand maybe why the top solutions uses Modules.

Here's what I have so far.

flatten :: [[a]] -> [a]
flatten [] = []
flatten (x:xs) = flatten x:flatten xs

However, I get an error:

Inferred type is not general enough
*** Expression    : flatten
*** Expected type : [[a]] -> [a]
*** Inferred type : [[[a]]] -> [[a]]

EDIT: Sorry! I misunderstood my exam study question. All elements of the list actually have to be lists. For example, [[[1,2,3], [4,5,6]], [7,8,9]] and not [1, [2,3,4]].

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Try to define the type of your function. Your above definition has conflicts in the types. – Bryan Olivier Mar 21 '13 at 23:14
Hmm, so I defined it as flatten :: [a] -> [a] but it's complaining that [a] -> [[a]] does not match [a] -> [a] and still, unification would give infinite type. Why is this? – dtgee Mar 21 '13 at 23:24
I'm afraid you like to flatten a list like [1,[2,3]] which is not a correctly typed list in the first place. It is really a tree and you would need a datatype to define it. – Bryan Olivier Mar 21 '13 at 23:32
If your exam study guide is specific to Haskell, I'm afraid you are still misunderstanding it. You can't make a Haskell list like the ones you describe in your EDIT -- every element of the list must be the same type, and a list-of-integers is not the same type as a list-of-list-of-integers. – comingstorm Mar 21 '13 at 23:40
@comingstorm That actually makes sense. Now I have no idea where to start approaching this problem.. – dtgee Mar 21 '13 at 23:42

Step 1: define your data. You need a datatype that supports arbitrary nesting. [a] does not, so you will not be able to solve the problem that way.

So what will the data look like? How about some Lisp notation:

(a b c)
((a b) c d)
(a (b c) d (e (f)))

Looks like an element can either be an atom, or a list. So let's say the previous sentence in Haskell:

data Element t = -- "an element is either ..."
    = Atom t     -- "an atom ..."
    | List [Element t]  -- "or a list of elements"
  deriving (Show)       -- "and please print things for me too, okay?"

Step 2: traversing the data. Now you need to write a function that flattens an Element t into a list. What's the type signature going to look like?

I'd suggest flatten :: Element t -> [t]. To implement it, it's going to need two cases -- one for Atoms, and one for Lists:

flatten :: Element t -> [t]
flatten (Atom x) = ....
flatten (List xs) = .....

Remember that each equation has to evaluate to a [t]. Good luck!

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I'm still new to Haskell, and I'm not sure what an atom is. I couldn't find any relevant information online, either. – dtgee Mar 22 '13 at 0:58
@user1831442 it's a Lisp term. It just means a datum that's not a list. – Matt Fenwick Mar 22 '13 at 3:06
I don't think I have anymore time to figure out how to implement this, could you please just give me a quick and dirty implementation of this? – dtgee Mar 22 '13 at 5:11
@user1831442 sorry, no. That's not what StackOverflow is for. But a hint: check out ++. – Matt Fenwick Mar 22 '13 at 11:22

Let's work out the type of your function: if you have a list of lists, this is written [[a]]. You want to flatten this to just a list, [a], so the type of flatten should be [[a]] -> [a]. You could also cheat and lookup the type of concat, since you know you are re-implementing that.

Now lets look at the implementation. The first case matches [] and returns []. Does this conform to [[a]] -> [a]? Yes, because the parameter [] is an empty list of type [something] where something can have the type [a]. The return value also conforms to our type because it's an empty list of type [whatever] where whatever can have type a.

Now lets look at the second case, does it match the type [[a]] -> [a]? Pattern matching with (x:xs) means x has the type [a] and xs has the type [[a]], this is fine. The problem is your recursive calls: the first one calls flatten with x which has type [a]. But we know flatten's parameter must be of type [[a]].

By the way, you will often get clearer or more precise type error messages if you declare the type of your function first. This is because the compiler can immediately stop once it finds a contradiction with what you declared. If you elide the signature, the compiler only checks that the definition is consistent with itself. When I declare the type GHC tells me:

    Couldn't match type `a' with `[a0]'
      `a' is a rigid type variable bound by
          the type signature for flatten :: [[a]] -> [a] at x.hs:20:1
    Expected type: [[a0]]
      Actual type: [a]
    In the first argument of `flatten', namely `x'
    In the first argument of `(:)', namely `flatten x'

This is exactly what we found checking the type ourselves, manually. The argument we passed to flatten should have type [[a]] but we were actually passing a value of type [a].

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Woops, had to change the question around a bit. Please see my edited post. – dtgee Mar 21 '13 at 23:40
Now that you have settled on the type of your function, carefully examine the types of your function definitions. You will find that both the first and third clause of your function do not comply. – Bryan Olivier Mar 21 '13 at 23:45
I think I see now. You can't write this function this way because the arguments keep changing. – dtgee Mar 22 '13 at 0:50

Well, in Haskell all nested lists have a uniform nesting depth for all elements. This is a consequence of the type system, which requires all of the elements of a list to be of the same type.

Something like the following definition could never typecheck:

example = [1, [2, 3, 4], [[5, 6], [7]]]

The first element is 1 :: Integer, second one is [2, 3, 4] :: [Integer], and so on.

The same problem applies to your edited example:

[[[1,2,3], [4,5,6]], [7,8,9]]

The first element of this list would have a type like [[Integer]], while the second one would have something like [Integer]. But this is not allowed.

Second thing: it's not just that the lists can't have a non-uniform depth, there also cannot exist a function that will "look" at different nested lists at different depths. A function of a type like [[a]] -> [a] will "peel" one level of nesting off its input list, but will treat a as an opaque type—it doesn't know what type a is, so if you pass an [[[Integer]]] argument, flatten cannot exploit the fact that a is [Integer] for that one argument you gave it—a could be anything!

So the only list flattening that can be done in Haskell is to remove nesting at some depth fixed by the function's type. So for example, flatten peels off just one level of nesting, and using function composition we can peel off two or more: flatten . flatten :: [[[a]]] -> [a], flatten . flatten . flatten :: [[[[a]]]] -> [a], and so on.

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[[[1,2,3], [4,5,6]], [7,8,9]] is not a valid Haskell list either. It contains two elements; the first is [[1,2,3], [4,5,6]] which is a [[Int]], and the second is just [7,8,9], which is just [Int].

A list in Haskell is always of type [a], for some a which has to be the same for all elements of the list. This means that if you're dealing with nested lists, every element must have the same degree of nesting.

It seems unlikely that a basic Haskell exam would ask you to flatten arbitrary levels of nesting. It almost certainly just wants to you to implement flatten :: [[a]] -> [a], which you can tell from the type only removes one "level" of list. You can call it on lists like [[[1], [[2]], [[3]]], which is of type [[[Int]], but the type clearly says that the result will be [[Int]], i.e. it will return [[1], [2], [3]], not [1, 2, 3].

The problem with what you're trying to do is that when your flatten receives its argument of type [[a]] and splits it into (x:xs) (unless it was empty), the x will be an element of that [[a]] list, so it will have type [a]. You're then trying to call flatten on it so you that you can flatten "all the way down", but flatten takes an argument of type [[a]] and x is of type [a].

Another way to think about why this couldn't work is that if it did work, you'd eventually get to the last "level" of list, and x wouldn't even be a list type at all. But you'd then pass it to flatten again, which would try to match it against either of the patterns [] or (x:xs), and have to fail. The type errors you're getting are what prevents this from occurring.

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You can write a function which can flatten arbitrary deep nested lists, but the nesting level must be consistent (at least if you want to stay with lists):

{-# LANGUAGE FlexibleInstances
  , OverlappingInstances
  , IncoherentInstances  #-}

class Nested a where
  flatten :: [a] -> [Int]

instance Nested Int where
  flatten = id

instance (Nested a) => Nested [a] where
  flatten xss = concatMap flatten xss

-- e.g. now this works ...
flatten [[1 :: Int,2,3],[2,3,4]]   
-- ... and this too ...
flatten [[[1 :: Int,2,3],[2,3,4]],[[25]]]   
-- ... but this won't work
-- flatten [[[1 :: Int,2,3],[2,3,4]],25]   

If you want to allow arbitrary nesting, you have to wrap your types:

{-# LANGUAGE ExistentialQuantification }

class Foo a

instance Foo Int

instance Foo [a]

data F = forall a. Foo a => F a

test = F [F (1 :: Int), F [F (2 :: Int), F [F (3 :: Int), F [F (4 :: Int)]]]] 

Now you could write a flatten for such a type.

However, I wouldn't recommend to explore this as a beginner. First you need a better understanding concerning how types actually should work. This stuff just isn't trivial, it goes against the grain of Haskell's type system, so every explanation will confuse you. Try to use the types in a way they are intended to use, and come back to such questions when you are really comfortable with the common use cases.

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