The key is to come up with the correct type.
If you want something like
[1, [2, [3, ]]], then doing exactly that won't work, because all list elements must be the same type.
This makes sense, because when I grab an element out of the list, I need to know what type it is before I can do anything with it (this is sort of the whole point of types, they tell you what you can and can't do with a thing).
But since Haskell's type system is static, I need to know what type it is even without knowing which element of the list it is, because which list index I'm grabbing might not be known until the program runs. So I pretty much have to get the same type of thing whatever index I use.
However, it's possible to do something very much like what you want: you want a data type that might be an integer, or might be a list:
type IntegerOrList a = Either Integer [a]
If you're not familiar with the
Either type, a value of
Either l r can either be
Left x for some
x :: l, or
Right y for some
y :: r. So
IntegerOrList a is a type whose values are either an integer or a list of something. So we can make a list of those things: the following is a value of type
[Left 7, Left 4, Right [True, False], Left 8, Right , Right [False]]
Okay, so that's one level of lists inside lists, but we can't put lists inside lists inside lists yet – the inner lists contain
Bools, which can't be lists. If we instead had
[IntegerOrList (IntegerOrList Bool)], we'd be able to have lists inside lists inside lists, but we'd still get no further. In our example, we had a list which contained values which were either integers or lists, and the lists were lists which contained values which were either integers or lists, and... what we really want is something like
IntegerOrList (IntegerOrList (IntegerOrList ..., or more simply, something like:
type IntegerOrLists = Either Integer [IntegerOrLists]
But that's not allowed – type synonyms can't be recursive, because that would produce an infinitely large type, which is confusing for the poor compiler. However, proper data types can be recursive:
data IntegerOrLists = I Integer | L [IntegerOrLists]
Now you can build lists like these, mixing integers and lists of your type:
L [I 1, L [I 2, L [I 3, L [I 4]]]]
The key is that whether each item is an integer or a list has to be flagged by using the
L constructors. Now each element of the list is of type
IntegerOrLists, and we can distinguish which it is by looking at that constructor. So the typechecker is happy at last.