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I was a bit surprised to find out that

head' :: [a] -> b
head' (x:xs) = x

raises an

Couldn't match expected type `b' with actual type `a'
  `b' is a rigid type variable bound by
      the type signature for head' :: [a] -> b at type_test.hs:1:10
  `a' is a rigid type variable bound by
      the type signature for head' :: [a] -> b at type_test.hs:1:10
In the expression: x
In an equation for head': head' (x : xs) = x

Why is that? I'd assume Haskell would allow me to be as lax as I want to be, and would find no problem with [a] -> b.

Thanks

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  • 3
    One way to read polymorphic type signatures is as logical formulas. The signature [a] -> b says “for any a and any b, given a list of as, I can give you a b”, but that’s clearly not true—where would you get a b from? Therefore the only thing that function can do is throw an error or loop infinitely. Furthermore, the signature head :: [a] -> a makes it clear that head must also throw an error, because we can come up with a counterexample for its type—the empty list.
    – Jon Purdy
    Jul 25, 2014 at 20:47
  • It is possible GHC will get partial type signatures that will allow to write [a] -> _ (which means, the _ part will be inferred to be a)
    – sdcvvc
    Jul 26, 2014 at 13:20

4 Answers 4

10

The function type signature is incorrect. Since the input is of type [a], the output will always be of type a. The type signature [a] -> b says that the function will take in any list of things, and return a thing of any (possibly different) type, which is incorrect -- it can only return a thing of the same type a.

5
  • It's only incorrect when a != b. But then again, I think the Haskell tradition and spec indicates that all characters map to unique types.
    – mike3996
    Jul 25, 2014 at 17:31
  • That's the same as saying that if I have a function that will only return, let's say, oranges, I am prohibited to say it will return... fruits. Or that if it might return X, I can't say it may return anything at all. Jul 25, 2014 at 17:32
  • 2
    It's incorrect because that type, [a] -> b is compatible with a type like [Int] -> String while head clearly is not. Jul 25, 2014 at 17:33
  • 2
    @devoured Those phrases are exactly the kinds of things the type system tries to say. It wants to be as general as possible, but no more general. In particular, it seems like you're familiar with type systems that have subtyping so that you could forget, say, an Int into an Any. Haskell does have subtyping, but it is significantly more subtle and designed to keep the types as specific as possible. Jul 25, 2014 at 17:35
  • Yeah, the point of the type system is that the function has to be able to work with any valid assignment of types to its type signature. So type signatures can be more specific than necessary, but not less specific.
    – Ben Kraft
    Jul 25, 2014 at 17:47
4

When you make a polymorphic function like that, there is an implicit forall. You function had type:

forall a b. [a] -> b

This means it can't just work in one case, but all cases. That means your function must, for example, be able to have this type:

[()] -> Float

But your function clearly would not be able to have this type.

2

A function f of type [a] -> b could be used like this:

x :: Integer
x = f ["a", "b", "c"]

Clearly head' can not be used like that. Therefore [a] -> b is not a valid type for head'.

The key thing to realize here is that -> b does not mean "the function could produce any type b, but you do not know which one, so you can only perform operations on it that would work with all types". To express that you'd need existential types. Rather it means "the function can produce any type b that the user requests", that is the function can be used as an expression of any possible type b and it must then be able to produce a value of that type. Clearly head' is not capable of that.

1
  • I think you mean head' instead of max'
    – ThreeFx
    Jul 25, 2014 at 18:52
0

There is nothing wrong with the type signature per se, nor with the code. But the point is that your code needs to be a proof of the proposition that is implied in the type signature.

But your code only shows that you can make a value of some type a from a list of values of the same type a. Nowhere do you show that you can make a value of any unrelated type. Hence the compiler refuses to accept.

One way to prove the type signature would be:

 head xs = error "WTF?"

Because this is non-terminating, you can claim that it is any type the caller might want if and when it returns, without lying.

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