How does `undefined`

work? Well, the best answer, IMHO, is that **it doesn't work**. But to understand that answer, we have to work through its consequences, which are not obvious to a newcomer.

Basically, if we have `undefined :: a`

, what that means for the type system is that `undefined`

can appear anywhere. Why? Because in Haskell, whenever you see an expression that has some type, you can *specialize* the type by consistently substituting all instances of any of its type variables for any other type. Familiar examples would be things like this:

```
map :: (a -> b) -> [a] -> [b]
-- Substitute b := b -> x
map :: (a -> b -> c) -> [a] -> [b -> c]
-- Substitute a := Int
map :: (Int -> b -> c) -> [Int] -> [b -> c]
-- etc.
```

In the case of `map`

, how does this work? Well, it comes down to the fact that `map`

's arguments provide everything that's necessary to produce an answer, no matter what substitutions and specializations we make for its type variables. If you have a list and a function that consumes values of the same type as the list's elements, you can do what map does, period.

But in the case of `undefined :: a`

, what this signature would mean is that no matter what type `a`

may get specialized to, `undefined`

is able to produce a value of that type. How can it do it? Well, actually, it can't, so if a program actually reaches a step where the value of `undefined`

is needed, there is no way to continue. The only thing the program can do at that point is to fail

The story behind this other case is similar but different:

```
loop :: a
loop = loop
```

Here, we can prove that `loop`

has type `a`

by this crazy-sounding argument: suppose that `loop`

has type `a`

. It needs to produce a value of type `a`

. How can it do it? Easy, it just calls `loop`

. Presto!

That sounds crazy, right? Well, the thing is that it's really no different from what's going on in the second equation of this definition of `map`

:

```
map :: (a -> b) -> [a] -> [b]
map f [] = []
map f (x:xs) = f x : map f xs
```

In that second equation, `f x`

has type `b`

, and `(f x:)`

has type `[b] -> [b]`

; now to conclude our proof that `map`

indeed has the type our signature claims, we need to produce a `[b]`

. So how are we doing it? By assuming that `map`

has the type we're trying to prove it has!

The way Haskell's type inference algorithm works is that it first guesses that the expression's type is `a`

, and then it only changes its guess when it finds something that contradicts that assumption. `undefined`

typechecks to `a`

because it's a flat-out lie. `loop`

typechecks to `a`

because recursion is allowed, and all `loop`

does is recurse.

**EDIT:** What the heck, I might as well spell out one example. Here's an informal demonstration of how to infer the type of `map`

from this definition:

```
map f [] = []
map f (x:xs) = f x : map f xs
```

It goes like this:

- We start by provisionally assuming that
`map :: a`

.
- But map takes two arguments, so
`a`

can't be the type. We revise our assumption to this: `map :: a -> b -> c; f :: a`

.
- But as we can see in the first equation, the second argument is a list:
`map :: a -> [b] -> c; f :: a`

.
- But as we can also see in the first equation, the result is also a list:
`map :: a -> [b] -> [c]; f :: a`

.
- In the second equation, we're pattern matching the second argument against the constructor
`(:) :: b -> [b] -> [b]`

. This means that in that equation, `x :: b`

and `xs :: [b]`

.
- Consider the right hand side of the second equation. Since the result of
`map f (x:xs)`

must be of type `[c]`

, that means `f x : map f xs`

must also be of type `[c]`

.
- Given the type of the constructor
`(:) :: c -> [c] -> [c]`

, that means that `f x :: c`

and `map f xs :: [c]`

.
- In (7) we concluded that
`map f xs :: [c]`

. We had assumed that in (6), and if we had concluded otherwise in (7) this would have been a type error. We can also now dive into this expression and see what types this requires `f`

and `xs`

to have, but to make a longer story short, everything's going to check out.
- Since
`f x :: c`

and `x :: b`

, we must conclude that `f :: b -> c`

. So now we get `map :: (b -> c) -> [b] -> [c]`

.
- We're done.

The same process, but for `loop = loop`

:

- We provisionally assume that
`loop :: a`

.
`loop`

takes no arguments, so its type is consistent with `a`

so far.
- The right hand side of
`loop`

is `loop`

, which we've provisionally assigned type `a`

, so that checks out.
- There's nothing more to consider; we're done.
`loop`

has type `a`

.

`let undef = undef`

`let f x = x + undef`

`let f x = head undef`

, etc... and from the type of`undef`

which is`t`

we can see that it can be replaced by any type, hence it can be used anywhere anything of some type is expected. – Wes May 25 '13 at 10:26