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I am learning Haskell and I don't understand why I can do this:

f :: [Int] -> Bool
f l  
    | l==l = True
    | otherwise = False

But I can't do this.

f :: [a] -> Bool
f l  
    | l==l = True
    | otherwise = False

What's going on under the hood?

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I'm not 100% sure on this, but it could be because of object types. Eq class has Char, Int, Float, Double etc..., but what if you had some object like House, it wouldn't know how to compare those unless you define it. Hopefully that helps. Really it seems like it would come down to the Eq class which defines == for just those types. –  Matt Dec 25 '11 at 7:11
@Matt: In Haskell there is no concept called object type or object. –  jmg Dec 25 '11 at 8:55
In any event, I'm confused about the details. Shouldn't it take two arguments ([a]->[a]->Bool)? Isn't l==l always true (for any Eq)? –  Andrew Jaffe Dec 25 '11 at 11:20
@AndrewJaffe It depends on the Eq instance. It is true, that for all auto generated Eq instances l == l holds, but technically nothing prevents you from writing the following instance: instance Eq T where { _ == _ = False }. –  jmg Dec 27 '11 at 9:55
@jmg: technically nothing prevents this. Nothing prevents you from designing a monad that violates the monad laws, either. But you definitely should never do something like that, anyone should be able to rely on these laws, == should always be an equivalence relation. –  leftaroundabout Dec 27 '11 at 10:32

2 Answers 2

up vote 23 down vote accepted

Given two values of an arbitrary type, Haskell does not necessarily know how to compare them for equality. == is only defined for types that are part of the Eq class.

For example, determining if two functions are equal is undecidable in general (I think).

You can compare two lists by checking if each element is equal to its corresponding element in the other list. However, this only makes sense if you can compare the elements for equality, so you have to add a constraint:

f :: Eq a => [a] -> Bool
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If you consider functions to be equal if they produce the same results for all inputs, and allow that to include non-termination as a possible result, then function equality reduces to the halting problem. So yeah, undecidable. –  C. A. McCann Dec 25 '11 at 7:20
Something reducing to the halting problem does not by itself make it undecidable. The halting problem reducing to something does make it undecidable. –  Prateek Dec 25 '11 at 9:32
@Prateek: Right, sorry. I misspoke. In this case both can be reduced to the other, anyway. –  C. A. McCann Dec 25 '11 at 21:53

I'd point you at the chapter on typeclasses in Real World Haskell


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