Let's set aside `at`

, and just think about your first four functions for the moment. You haven't given them type signatures, so let's look at those; they'll make things much clearer. The types are

```
cons :: a -> (a, ())
prepend :: a -> b -> (a, b)
head :: (a, b) -> a
tail :: (a, b) -> b
```

Hmmm. Compare these to the types of the corresponding Prelude functions^{1}:

```
return :: a -> [a]
(:) :: a -> [a] -> [a]
head :: [a] -> a
tail :: [a] -> [a]
```

The big difference is that, in your code, there's nothing that corresponds to the list type, `[]`

. What would such a type be? Well, let's compare, function by function.

`cons`

/`return`

: here, `(a,())`

corresponds to `[a]`

`prepend`

/`(:)`

: here, both `b`

and `(a,b)`

correspond to `[a]`

`head`

: here, `(a,b)`

corresponds to `[a]`

`tail`

: here, `(a,b)`

corresponds to `[a]`

It's clear, then, that what you're trying to say is that a list is a pair. And `prepend`

indicates that you then expect the tail of the list to be another list. So what would that make the list type? You'd want to write `type List a = (a,List a)`

(although this would leave out `()`

, your empty list, but I'll get to that later), but you can't do this—type synonyms can't be recursive. After all, think about what the type of `at`

/`!!`

would be. In the prelude, you have `(!!) :: [a] -> Int -> a`

. Here, you might try `at :: (a,b) -> Int -> a`

, but this won't work; you have no way to convert a `b`

into an `a`

. So you really ought to have `at :: (a,(a,b)) -> Int -> a`

, but of course this won't work either. You'll never be able to work with the structure of the list (neatly), because you'd need an infinite type. Now, you might argue that your type *does* stop, because `()`

will finish a list. But then you run into a related problem: now, a length-zero list has type `()`

, a length-one list has type `(a,())`

, a length-two list has type `(a,(a,()))`

, etc. This is the problem: there *is* no single "list type" in your implementation, and so `at`

can't have a well-typed first parameter.

You have hit on something, though; consider the definition of lists:

```
data List a = []
| a : [a]
```

Here, `[] :: [a]`

, and `(:) :: a -> [a] -> [a]`

. In other words, a list is isomorphic to something which is either a singleton value, or a pair of a value and a list:

```
newtype List' a = List' (Either () (a,List' a))
```

You were trying to use the same trick without creating a type, but it's this creation of a new type which allows you to get the recursion. And it's exactly your missing recursion which allows lists to have a single type.

**1:** On a related note, `cons`

should be called something like `singleton`

, and `prepend`

should be `cons`

, but that's not important right now.

recursivenature of a list type. We have to use Haskell's features to create recursive data types, because the Hindley-Milner type system cannot infer recursive types on the fly. – luqui Jul 15 '11 at 18:06