This function is incorrect and won't compile:

checkIsZero :: (Num a) => a -> String
checkIsZero a = if a == 0
                  then "Zero"
                  else "Not zero"

This doesn't work because of the comparison between a Num and 0 in the expression a == 0. Changing Num to Integral makes this a valid function.

What is this wicked sorcery that doesn't let me compare my numbers to 0?!

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  • in ghci it seems to work for Num; are you using ghc? what is the error message? – jev Sep 4 '13 at 21:23
  • I put the above function into functions.hs then do :l functions.hs in ghci and get the error Could not deduce (Eq a) arising from a use of '==' – Cory Klein Sep 4 '13 at 21:27
  • 3
    @jev Since GHC 7.4, it shouldn't work, at least not with that type signature. Eq is no longer implied by Num. – user824425 Sep 4 '13 at 21:27

Num requires instances to implement +, *, abs, signum, and fromInteger. Note that == isn't on the list! It's instances of the Eq typeclass that must implement ==.

So, the Num constraint is not sufficient - you need an Eq constraint too. The following will compile.

checkIsZero :: (Eq a, Num a) => a -> String
checkIsZero a | a == 0    = "Zero"
              | otherwise = "Not zero"

Integral works because something which is an instance of Integral must itself be an instance of Ord, which in turn must be an instance of Eq.

You can check all this stuff by using hoogle and digging into the source.

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  • Quick comment - I think the Integral class is another example of Haskell's numeric type classes being broken. The notion it tries to capture is "operations that can be divided with remainder". In mathematics we call that a 'Euclidean domain' and it includes objects like the gaussian integers, polynomial rings and power series, which don't necessarily have a sensible Ord instance and don't admit an embedding into the integers (as is required by toInteger). I'd rather see a EuclideanDomain class and a separate Integral class that could encompass e.g. integers Z, and Z/pZ for p prime. – Chris Taylor Sep 7 '13 at 9:11

The reason for not requiring an Eq instance to define a Num instance is that it would rule out useful instances like

instance Num b => Num (a -> b) where
    f + g    = \x -> f x + g x
    f - g    = \x -> f x - g x
    f * x    = \x -> f x * g x
    abs f    = \x -> abs (f x)
    signum f = \x -> signum (f x)
    fromInteger = const . fromInteger

because you can't write an Eq instance for a function.

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  • 4
    This applies not only to such function instances but also to symbolic algebra types, infinite-precision reals, automatic-derivative types... – leftaroundabout Sep 4 '13 at 22:36
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    I think some people would argue with your description of the given instance as "useful"! – Ben Millwood Sep 4 '13 at 23:09
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    @BenMillwood I'd say those people are not imaginative enough. For an example use case, see this paper which details a simple way to implement Automatic Differentiation in Haskell, which includes lines like cos = cos >< negate sin (derivative of cos(x) is -sin(x)) and log = log >< recip (derivative of log(x) is the reciprocal of x). – Chris Taylor Sep 5 '13 at 6:08
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    @BenMillwood - Mathematicians have been using this very notation for hundreds of years. It only looks weird in Haskell since we mistakenly created a typeclass called Num instead of ones called LinearSpace, Field, Algebra, and so on. – Fixnum Sep 5 '13 at 15:16
  • @Fixnum: I know what mathematicians do, this does not make it a good idea :) I say this as a recent maths graduate: I love mathematics, but it's often poorly-typed and only parseable by a human with intelligence, intuition, and understanding of the concepts in play. Your instance makes it easy to write statements that look like they mean one thing but mean another, or type check when they are clearly an error. Consider 2 (x + y) = 2. I'm aware that you can add functions, but to use + to refer to addition of numbers and functions simultaneously in the same context is just bad practice. – Ben Millwood Sep 5 '13 at 21:57

If data is an instance of Num a, it is not a grantee , that this data is an instance of Eq a.

Integer (and Int, Double) has both instances: instance Num Integer and instance Eq Integer, and program is valid

Integral is defined as

class (Real a, Enum a)=> Integral a where ...
class (Num a, Ord a)=> Real a where ...
class Eq a => Ord a where ...

 ~= class (Num a, Eq a, Enum a)=> Integral a where ... --means
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  • My ghci says that Ord not Eq is a superclass of Real. – Ben Millwood Sep 4 '13 at 23:10

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