This is impossible without using `undefined`

as another commenter mentioned. Let's prove it by counter-example. Assume there were such a function:

```
f :: a -> a
```

When you say that's it not the same as `id`

, that implies that you cannot define:

```
f x = x
```

However, consider the case where `a`

is the type `()`

:

```
f () = ...
```

The only possible result `f`

could return would be `()`

, but that would be the same implementation as `id`

, therefore a contradiction.

The more sophisticated and rigorous answer is to show that the type `a -> a`

must be isomorphic to `()`

. When we say two types `a`

and `b`

are isomorphic, that means that we can define two functions:

```
fw :: a -> b
bw :: b -> a
```

... such that:

```
fw . bw = id
bw . fw = id
```

We can easily do this when the first type is `a -> a`

and the second type is `()`

:

```
fw :: (forall a . a -> a) -> ()
fw f = f ()
bw :: () -> (forall a . a -> a)
bw () x = x
```

We can then prove that:

```
fw . bw
= \() -> fw (bw ())
= \() -> fw (\x -> x)
= \() -> (\x -> x) ()
= \() -> ()
= id
bw . fw
= \f -> bw (fw f)
-- For this to type-check, the type of (fw f) must be ()
-- Therefore, f must be `id`
= \f -> id
= \f -> f
= id
```

When you prove two types are isomorphic, one thing you know is that if one type is inhabited by a finite number of elements, so must the other one. Since the type `()`

is inhabited by exactly one value:

```
data () = ()
```

That means that the type `(forall a . a -> a)`

must also be inhabited by exactly one value, which just so happens to be the implementation for `id`

.

Edit: Some people have commented that the proof of the isomorphism is not sufficiently rigorous, so I'll invoke the Yoneda lemma, which when translated into Haskell, says that for any functor `f`

:

```
(forall b . (a -> b) -> f b) ~ f a
```

Where `~`

means that `(forall b . (a -> b) -> f b)`

is isomorphic to `f a`

. If you choose the `Identity`

functor, this simplifies to:

```
(forall b . (a -> b) -> b) ~ a
```

... and if you choose `a = ()`

, this further simplifies to:

```
(forall b . (() -> b) -> b) ~ ()
```

You can easily prove that `() -> b`

is isomorphic to `b`

:

```
fw :: (() -> b) -> b
fw f = f ()
bw :: b -> (() -> b)
bw b = \() -> b
fw . bw
= \b -> fw (bw b)
= \b -> fw (\() -> b)
= \b -> (\() -> b) ()
= \b -> b
= id
bw . fw
= \f -> bw (fw f)
= \f -> bw (f ())
= \f -> \() -> f ()
= \f -> f
= id
```

So we can then use that to finally specialize the Yoneda isomorphism to:

```
(forall b . b -> b) ~ ()
```

Which says that any function of type `forall b . b -> b`

is isomorphic to `()`

. The Yoneda lemma provides the rigor that my proof was missing.

`myfunction _ = undefined`

is pretty much the only other possible function with that type signature. – dbaupp Sep 1 '12 at 19:41`a -> b`

it's most general signature, but you can restrict it to`a -> a`

. – dbaupp Sep 1 '12 at 20:27`f x = seq x x`

is special because it is strict in`x`

, unlike`f x = id x`

which AFAIK is not.`f x = seq b x`

is more like`f x = id x`

in this case, it is the`seq x x`

which is special. So I see three different functions, without playing with`unsafe`

things: const bottom (`f x = const undefined x`

), lazy identity (`f x = id x`

), and strict identity (`f x = seq x x`

). – CesarB Sep 19 '12 at 0:51