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I have a collection of records spread across a number of types in a large Haskell application that reference each other. All of the types involved implement a common typeclass. The typeclass contains functions that work over a variable and all of its children, very much like uniplate's para function.

This is a simplified code sample of what I'd like to build. Is it possible (and reasonable) to get generic functionality to fold over record fields that implement a given typeclass in GHC...

{-# LANGUAGE RankNTypes #-}

myPara :: forall a r . (Data a, Foo a)
       => (forall b . Foo b => b -> [r] -> r)
       -> a
       -> r

-- or as a fold
myFold :: forall a r . (Data a, Foo a)
       => (forall b . Foo b => r -> b -> r)
       -> r
       -> b
       -> r

But generic enough to work with an arbitrary typeclass?

{-# LANGUAGE ExistentialQuantification #-}
{-# LANGUAGE DeriveDataTypeable #-}

import Data.Data
import Data.Generics.Uniplate.Data

class Foo a where 
  fooConst :: a -> Int

data Bar = Bar {barBaz :: Baz} deriving (Typeable, Data)

instance Foo Bar where
  fooConst _ = 2

data Baz = Baz {barBar :: Bar} deriving (Typeable, Data)

instance Foo Baz where
  fooConst _ = 3

func :: Int
func = foldl (\ x y -> x + fooConst y) 0 instances where
  instances :: forall a . (Data a, Foo a) => [a]
  instances = universeBi bar
  bar = Bar{barBaz = baz}
  baz = Baz{barBar = bar}

Compiling this with GHC 7.2.1 (obviously) fails:

    Ambiguous type variable `a0' in the constraints:
      (Data a0) arising from a use of `instances' at Repro.hs:21:42-50
      (Foo a0) arising from a use of `instances' at Repro.hs:21:42-50
    Probable fix: add a type signature that fixes these type variable(s)
    In the third argument of `foldl', namely `instances'
    In the expression: foldl (\ x y -> x + fooConst y) 0 instances
    In an equation for `func':
          = foldl (\ x y -> x + fooConst y) 0 instances
              instances :: forall a. (Data a, Foo a) => [a]
              instances = universeBi bar
              bar = Bar {barBaz = baz}
              baz = Baz {barBar = bar}
share|improve this question
By my reading of the uniplate documentation, the type of instances ought to be just [Baz], no? – Daniel Wagner Oct 13 '11 at 20:57
Yes, it's more a theoretical question than anything. – Nathan Howell Oct 13 '11 at 21:52
I'm not sure I understand what the theoretical question is. Could you make that a bit more precise in your text? (When you ask, "Is it possible to get generic functionality like this?", what does "like this" mean?) – Daniel Wagner Oct 13 '11 at 21:57
You are beginning to abstract over typeclasses, which Haskell is pretty bad at. Make the class concrete: eg. for Eq, use data Eq a = Eq { eq :: a -> a -> Bool }, then pass it as a parameter. Typeclasses are mainly for notational convenience, let functions do the heavy lifting. – luqui Oct 13 '11 at 23:52
Looks like it might be possible with ConstraintKinds in GHC 7.4 – Nathan Howell Oct 14 '11 at 16:17

2 Answers 2

been a while..

Have you tried existentially quantified data constructors?

data Foo = forall a. MyTypeClass a => Bar [a]

func (Bar l) = map typeClassMember a

now, func will work with anything of type Foo, which hides the inner type.

share|improve this answer
What I want is a generic function, similar to universeBi (from uniplate) that abstracts over typeclasses instead of types. I have functions like the one you're recommending already, but I have a lot of them and I'm trying to simplify a very large chunk of code. – Nathan Howell Nov 29 '11 at 7:01

You've hit the Existential Antipattern. You shouldn't be using typeclasses for anything except cases when you need compiler to guess the type for you. List of values of type x will stay the list of values of type x no matter what typeclasses you will implement, and you can't break the type system here.

You can:

  1. Use an ad-hoc box type as suggested above. This is just plain ugly.

  2. Implement generic interfaces with message-passing.

    data Foo = Foo { fooConst :: Int }

    bar = Foo 2

    baz = Foo 3

share|improve this answer

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