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Recently I took a look at Haskell, using LYAH.

I was messing around with type classes and wrote this quick test function:

foo :: (Num x) => x -> String
foo x = show x ++ "!"

But that produces this error:

test.hs:2:9:
    Could not deduce (Show x) arising from a use of `show'
    from the context (Num x)
    bound by the type signature for foo :: Num x => x -> String
    at test.hs:1:8-29
    Possible fix:
      add (Show x) to the context of
        the type signature for foo :: Num x => x -> String

But according to LYAH:

To join Num, a type must already be friends with Show and Eq.

So if everything in Num is a subset of Show and Eq, why do I need to change the type signature to foo :: (Num x, Show x) => x -> String for this to work? Shouldn't it be possible to infer that a Num is also Show-able?

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up vote 16 down vote accepted

The information in LYAH is old. The release notes for GHC 7.4.1 say that:

The Num class no longer has Eq or Show superclasses.

You will need to write,

foo :: (Num x, Show x) => x -> String

(In fact, the foo you wrote doesn't require Num x, so you can omit that to avoid an unnecessary constraint.)

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1  
So what subclasses of Num don't have Eq or Show anymore? I don't see any listings of what gained those (Or why it was changed at all, actually.) – charmlessCoin Oct 11 '13 at 22:32
6  
It used to be class (Eq a, Show a) => Num a where {...}, now it's just class Num a where {...}. There was no need to have Eq and Show as a superclass: a Num instance does not imply an instance of either of those classes (like Ord implies Eq), nor does it depend on them (Num has no laws, and the default definitions for its 'methods' don't refer to Eq or Show). I think that's why Num became a stand-alone class. Less requirements means that the class allows for more instances, such as Num b => Num (a -> b). – Rhymoid Oct 11 '13 at 23:44
2  
It's important to note that this is a GHC change; the Haskell standard still demands Show and Eq superclasses. In the strict sense, this makes GHC a non-Haskell-compliant compiler; however, this change will most likely make its way into the next standard anyway, much like soon Applicative will be a superclass of Monad. – David Jul 13 '14 at 17:31

It used to be that an instance of Num was also an instance of Show and Eq , but that's no longer the case.

You'll need to add a Show constraint as well.

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Haskell, both 98 and 2010 both require all instances of Num to also be instances on Show and Eq. This is largely an accident of history.

GHC, the most popular Haskell compiler, diverges from the standard here without requiring any pragma. This was done to allow applicative functors to be instances of Num and enjoy the benefits of overloaded syntax.

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Shouldn't you write:

(Num x) => x -> String

Instead of

(Num x) x -> String

And as far as I know this inheritance is at least outdated.

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