No, you can't. First off, there's a slight terminological confusion: what you have there are *lists*, not arrays (which Haskell also has) , although the point stands either way. So then, as with all things Haskell, you must ask yourself: *what would the type of *`aList = [aList, 1]`

be?

Let's consider the simpler case of `aList = [aList]`

. We know that `aList`

must be a list of *something*, so `aList :: [`*α*]

for some type *α*

. What's *α*

? As the type of the list elements, we know that *α*

must be the type of `aList`

; that is, *α* ~ [*α*]

, where `~`

represents type equality. So *α* ~ [*α*] ~ [[*α*]] ~ [[[*α*]]] ~ ⋯ ~ [⋯[*α*]⋯] ~ ⋯

. This is, indeed, an infinite type, and Haskell forbids such things.

In the case of the value `aList = [aList, 1]`

, you also have the restriction that `1 :: `*α*

, but all that that lets us conclude is that there must be a `Num `*α*

constraint (`Num `*α* => [⋯[*α*]⋯]

), which doesn't change anything.

The obvious next three questions are:

- Why do Haskell lists only contain one type of element?
- Why does Haskell forbid infinite types?
- What can I do about this?

Let's tackle those in order.

Number one: Why do Haskell lists only contain one type of element? This is because of Haskell's type system. Suppose you have a list of values of different types: `[False,1,2.0,'c']`

. What's the type of the function `someElement n = [False,1,2.0,'c'] !! n`

? There isn't one, because you couldn't know what type you'd get back. So what could you do with that value, anyway? You don't know anything about it, after all!

Number two: Why does Haskell forbid infinite types? The problem with infinite types is that they don't add many capabilities (you can always wrap them in a new type; see below), and they make some genuine bugs type-check. For example, in the question "Why does this Haskell code produce the ‘infinite type’ error?", the non-existence of infinite types precluded a buggy implementation of `intersperse`

(and would have even without the explicit type signature).

Number three: What can I do about this? If you want to fake an infinite type in Haskell, you must use a *recursive data type*. The data type prevents the type from having a truly infinite expansion, and the explicitness avoids the accidental bugs mentioned above. So we can define a newtype for an infinitely nested list as follows:

```
Prelude> newtype INL a = MkINL [INL a] deriving Show
Prelude> let aList = MkINL [aList]
Prelude> :t aList
aList :: INL a
Prelude> aList
MkINL [MkINL [MkINL [MkINL ^CInterrupted.
```

This got us our infinitely-nested list that we wanted—printing it out is never going to terminate—but none of the *types* were infinite. (`INL a`

is *isomorphic* to `[INL a]`

, but it's not *equal* to it. If you're curious about this, the difference is between isorecursive types (what Haskell has) and equirecursive types (which allow infinite types).)

But note that this type isn't very useful; the only lists it contains are either infinitely nested things like `aList`

, or variously nested collections of the empty list. There's no way to get a base case of a value of type `a`

into one of the lists:

```
Prelude> MkINL [()]
<interactive>:15:8:
Couldn't match expected type `INL a0' with actual type `()'
In the expression: ()
In the first argument of `MkINL', namely `[()]'
In the expression: MkINL [()]
```

So the list you want is an *arbitrarily* nested list. The 99 Haskell Problems has a question about these, which requires defining a new data type:

```
data NestedList a = Elem a | List [NestedList a]
```

Every element of `NestedList a`

is either a plain value of type `a`

, or a list of more `NestedList a`

s. (This is the same thing as an arbitrarily-branching tree which only stores data in its leaves.) Then you have

```
Prelude> data NestedList a = Elem a | List [NestedList a] deriving Show
Prelude> let aList = List [aList, Elem 1]
Prelude> :t aList
aList :: NestedList Integer
Prelude> aList
List [List [List [List ^CInterrupted.
```

You'll have to define your own lookup function now, and note that it will probably have type `NestedList a -> Int -> Maybe (NestedList a)`

—the `Maybe`

is for dealing with out-of-range integers, but the important part is that it can't just return an `a`

. After all, `aList ! 0`

is not an integer!

`anArray!!0!!1`

would be equivalent to`anArray!!0!!0!!1`

or`anArray!!0!!0!!0!!1`

. A recursively defined array is not the same as a 2-dimensional array. – Anderson Green Sep 10 '13 at 23:36