Playing around with some code:

{-# LANGUAGE FlexibleInstances, OverlappingInstances #-}

class Arity f where
  arity :: f -> Int

instance Arity x where
  arity _ = 0

instance Arity f => Arity ((->) a f) where
  arity f = 1 + arity (f undefined)

Without IncoherentInstances:

ghci> arity foldr
blah blah ambiguous blah blah possible fix blah
ghci> arity (foldr :: (a -> Int -> Int) -> Int -> [a] -> Int)
ghci> let f x y = 3 in arity f
ghci> arity $ \x y -> 3

If we add IncoherentInstances to the list of pragmas, then it can handle foldr without needing a monomorphic type signature, but it gets the wrong answer on lambdas:

ghci> arity foldr
ghci> let f x y = 3 in arity f
ghci> arity $ \x y -> 3 -- should be 2

What is the black magic behind Incoherent Instances? Why does it do what it does here?

up vote 28 down vote accepted

Well this is quite complicated. Lets start with the ambiguous error:

    Ambiguous type variable `b0' in the constraint:
      (Arity b0) arising from a use of `arity'
    Probable fix: add a type signature that fixes these type variable(s)
    In the expression: arity foldr
    In an equation for `it': it = arity foldr

Normally, without overlapping instances, when attempting to match a type against a class, it will compare the type against all instances for that class. If there is exactly one match, it will use that instance. Overwise you will either get a no instance error (eg with show (*)), or an overlapping instances error. For example, if you remove the OverlappingInstances language feature from the above program, you will get this error with arity (&&):

    Overlapping instances for Arity (Bool -> Bool -> Bool)
      arising from a use of `arity'
    Matching instances:
      instance Arity f => Arity (a -> f)
        -- Defined at tmp/test.hs:9:10-36
      instance Arity x -- Defined at tmp/test.hs:12:10-16
    In the expression: arity (&&)
    In an equation for `it': it = arity (&&)

It matches Arity (a -> f), as a can be Bool and f can be Bool -> Bool. It also matches Arity x, as x can be Bool -> Bool -> Bool.

With OverlappingInstances, when faced with a situation when two or more instances can match, if there is a most specific one it will be chosen. An instance X is more specific than an instance Y if X could match Y, but not vice versa.

In this case, (a -> f) matches x, but x does not match (a -> f) (eg consider x being Int). So Arity (a -> f) is more specific than Arity x, so if both match the former will be chosen.

Using these rules, arity (&&) will firstly match Arity ((->) a f), with a being Bool, and f being Bool -> Bool. The next match will have a being Bool and f being bool. Finally it will end matching Arity x, with x being Bool.

Note with the above function, (&&) result is a concrete type Bool. What happens though, when the type is not concrete? For example, lets look at the result of arity undefined. undefined has the type a, so it isn't a concrete type:

    Ambiguous type variable `f0' in the constraint:
      (Arity f0) arising from a use of `arity'
    Probable fix: add a type signature that fixes these type variable(s)
    In the expression: arity undefined
    In an equation for `it': it = arity undefined

You get an abiguous type variable error, just like the one for foldr. Why does this happen? It is because depending on what a is, a different instance would be required. If a was Int, then the Arity x instance should be matched. If a was Int -> Int, then the Arity ((->) a f) instance should be matched. Due to this, ghc refuses to compile the program.

If you note the type of foldr: foldr :: forall a b. (a -> b -> b) -> b -> [a] -> b, you will notice the same problem: the result is not a concrete variable.

Here is where IncoherentInstances comes in: with that language feature enabled, it will ignore the above problem, and just choose an instance that will always match the variable. Eg with arity undefined, Arity x will always match a, so the result will be 0. A similar thing is done at for foldr.

Now for the second problem, why does arity $ \x y -> 3 return 0 when IncoherentInstaces is enabled?

This is very weird behaviour. This following ghci session will show how weird it is:

*Main> let f a b = 3
*Main> arity f
*Main> arity (\a b -> 3)

This leads me to think that there is a bug in ghc, where \a b -> 3 is seen by IncoherentInstances to have the type x instead of a -> b -> Int. I can't think of any reason why those two expressions should not be exactly the same.

  • 5
    arity (\a b -> a + b) gives the correct result, I think it's an issue with the optimizer nuking dead variables (analysis is marking them as dead at least) when it probably shouldn't be. – Nathan Howell Dec 4 '11 at 0:57
  • 1
    @NathanHowell - interesting. arity $ \a b -> const a b yields 2, but arity $ \a b -> a yields 0. – Dan Burton Dec 4 '11 at 1:09
  • 3
    +1 thanks for the good explanation of OverlappingInstances and IncoherentInstances. – Dan Burton Dec 4 '11 at 1:10
  • 2
    @NathanHowell does an optimizer play any role here, though, since this is in a GHCi session? – acfoltzer Dec 4 '11 at 4:31
  • 2
    Seems like the "How" should be dropped from the question, then? :) My impression is that there are many people who believe IncoherentInstances is a bad idea and would not be sorry to see it gone altogether. – Ben Millwood Dec 12 '11 at 3:04

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