# Avoiding a bug with mutually recursive default methods in type classes [duplicate]

Possible Duplicate:
Can GHC warn if class instance is a loop?

Consider a type class with two methods which are implementable in terms of each other:

class Num a => Foo a where

foo :: a

bar :: a -> a
bar x = baz x + 1

baz :: a -> a
baz x = bar x - 1


Depending on the type, it might be easier to implement bar or baz, or you might want to give implementations of both of them for efficiency reasons.

Now I go somewhere else and make an instance of this class

instance Foo Integer where
foo = 1


Oops, I forgot to implement either of bar or baz! Never mind, the type system will pick that up for me, won't it?

C:\path\to\file> ghci Foo.hs
GHCi, version 7.4.1: http://www.haskell.org/ghc/  :? for help
[1 of 1] Compiling Main             ( Foo.hs, interpreted )
Ok, modules loaded: Main.


Hmm, apparently not. Now if I try to use my class

*Main> bar 1
<interactive>: out of memory


Uh oh. Cue hours of painful debugging.

Is there a way to let GHC know that each instance needs to specify at least one of bar or baz?

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–  AndrewC Oct 31 '12 at 8:54
@AndrewC Thanks. I've voted to close as a duplicate, but I think there's a subtle difference in my question - I don't want the compiler to always complain about mutually recursive defaults, but I do want the option to tell it to complain for particular classes. –  Chris Taylor Oct 31 '12 at 8:59
I guess it is worth human specification, yes, since asking the compiler to spot where mutual recursion is circular rather than useful is asking a lot! Perhaps a pragma asking it to warn that at least one (sometimes two) of a set of functions is redefined when you make an instance (hard to specify, spread out), or perhaps better, a list of alternative minimal specifications (could be in one large pragma in one place - better). I haven't read the trac ticket closely. –  AndrewC Oct 31 '12 at 10:09
Note that just checking for mutual recursion isn't sufficient; mutually recursive default methods might be perfectly valid, e.g. some and many in Alternative.