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I'm reading code of the HList library. There is an HBetween class which is a type level function taking a HNat n and return a list of HNats forming a range [HZero, n). I want to implement an other class HRange, it has an overload function hRange :: l -> u -> r which take a low bound l and a upper bound u and return a range [l, u). My code is below(to make the code more clear, the result of hRange is in reversed order, say (u, l] )

{-# LANGUAGE MultiParamTypeClasses, FunctionalDependencies, 
    FlexibleInstances, FlexibleContexts, UndecidableInstances #-}
module Data.HList.HNats where
import Data.HList.CommonMain
class (HNat l, HNat u) => HRange l u r | l u -> r where
  hRange :: l -> u -> r
instance HNat l => HRange l (HSucc l) (HCons l HNil) where
  hRange _ _ = undefined
instance HRange l u r => HRange l (HSucc u) (HCons u r) where
  hRange _ _ = undefined

I tried this code in ghci, something unexpected happened:

*Data.HList.HNats Data.HList> :load Data/HList/HNats
[1 of 1] Compiling Data.HList.HNats ( Data/HList/HNats.hs, interpreted )
Ok, modules loaded: Data.HList.HNats.
*Data.HList.HNats Data.HList> hRange hZero (hSucc hZero )

    Overlapping instances for HRange
                                HZero (HSucc HZero) (HCons HZero HNil)
      arising from a use of `hRange'
    Matching instances:
      instance HNat l => HRange l (HSucc l) (HCons l HNil)
        -- Defined at Data/HList/HNats.hs:14:10
      instance HRange l u r => HRange l (HSucc u) (HCons u r)
        -- Defined at Data/HList/HNats.hs:20:10
    In the expression: hRange hZero (hSucc hZero)
    In an equation for `it': it = hRange hZero (hSucc hZero)
*Data.HList.HNats Data.HList> 

I don't know why hRange hZero (hSucc hZero ) could match instance instance HRange l u r => HRange l (HSucc u) (HCons u r). Any explanation is appreciated!

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1 Answer 1

Note that GHC gives the type of hRange hZero (hSucc hZero) as HRange HZero (HSucc HZero) (HCons Zero HNil). Because the GHC instance matcher does not consider constraints before selecting matches, it just checks against HRange l (HSucc u) (HCons u r). l can match anything, so matches HZero; HSucc u clearly matches HSucc HZero, as do HCons u r and HCons HZero HNil.

In general, as far as GHC is concerned, your second instance is a strict superset of the first, since the only difference in the right sides (thus ignoring the constraints HNat l and HRange l u r), when selecting an instance the first is the second with r restricted to be HNil. The normal approach to this problem is to throw in a phantom type or class to differentiate the right sides, although off the top of my head I do not see how to do that here.

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thank you very much, I'm seeking some other method :) –  pysuxing May 13 '13 at 1:52

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