Take the 2-minute tour ×
Stack Overflow is a question and answer site for professional and enthusiast programmers. It's 100% free, no registration required.

I have a very simple question: this function:

hola :: (Integral a) => a -> String
hola 1 = "OK"
hola _ = "asdf"

works fine. But this one:

hola :: (Num a) => a -> String
hola 1 = "OK"
hola _ = "asdf"

cant be compiled: "Could not deduce (Eq a) arising from the literal `1'"

I really dont get it. I am reading a tutorial where it is said

"Integral is also a numeric typeclass. Num includes all numbers, including real numbers and integral numbers, Integral includes only integral (whole) numbers. In this typeclass are Int and Integer." http://learnyouahaskell.com/types-and-typeclasses

Why I cant use Num, so? Thanks in advance and sorry for my english (I dont speak English).


share|improve this question
Your english is very good :) –  Cetin Sert Oct 8 '12 at 14:52

3 Answers 3

up vote 19 down vote accepted

It's a recent change proposed and accepted in September/October last year, in the latest version of the base package, Eq and Show are no longer superclasses of Num. Since that change, no new version of the language report has been published, so it's not yet in the report. And since it's recent, it has also not made it yet into many tutorials or books.

"Pattern matching" against a numeric literal is an implicit application of (==), so an Eq instance is required for it to work. That instance can now no longer be inferred from the Num constraint, so the (quite new :D) compiler rejects the code with only a Num constraint.

But Integral is a subclass of Real, which has Ord (and hence Eq) as a superclass, hence that works.

share|improve this answer
Working in the previuous version :) Thank you!! I think this change make this language a bit confusing.. :( –  user1726613 Oct 7 '12 at 12:18
Well, it will certainly cause a lot of confusion (and breakage of packages) in the transition period. But the overall consensus was that the gain is greater than the loss (no more spurious Eq and Show instances for things like functions that can have sensible Num instances except for the old Eq and Show requirements). The same (mutatis mutandis) applies to the removal of the Num superclass from Bits. Fortunately, the breakages are backward-compatibly fixed by adding the constraints. –  Daniel Fischer Oct 7 '12 at 12:24
Thank you very much Daniel, your answers were very useful. So with the new compiler I have to ensure that the constraint includes a Eq instance at least in order to make the comparison. –  user1726613 Oct 7 '12 at 12:41
Yes, since Eq and Show are no longer implied by Num, with the new compiler, you have to explicitly (for values of "explicitly" that include "implicitly through other constraints") add them where you use them. –  Daniel Fischer Oct 7 '12 at 12:46

As Daniel Fischer said, it used to work but it now doesn't work because Num and Eq were split so Num a does not implies Eq a anymore. To fix your code just make Eq a explicit:

hola :: (Num a, Eq a) => a -> String
hola 1 = "OK"
hola _ = "asdf"
share|improve this answer

Num a is too general. Num a implies that a could be Fractional or maybe a Rational or any other Typeclass that inherits from, or Type that that is instance of Num. You can match 1 trivially against any Integral, but not necessarily against any Num.

(Don't be confused - of course any Num implements fromInteger, but e.g. Fractional doesn't support pattern matching against literals at all).

share|improve this answer
Fractional does support pattern matching against literals, it just requires Eq (as does Integral, but Eq is implied by Integral). E.g. f :: (Num a, Eq a) => a -> Bool; f 0 = True; f _ = False is perfectly valid and works on Doubles as well as Integers. –  dbaupp Oct 7 '12 at 12:12
Yeah, unfortunate wording on my side there. Thanks. –  Cubic Oct 7 '12 at 12:19

Your Answer


By posting your answer, you agree to the privacy policy and terms of service.

Not the answer you're looking for? Browse other questions tagged or ask your own question.