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.

Is it possible to remove the duplicates (as in nub) from a list of functions in Haskell? Basically, is it possible to add an instance for (Eq (Integer -> Integer))

In ghci:

let fs = [(+2), (*2), (^2)]
let cs = concat $ map subsequences $ permutations fs
nub cs

<interactive>:31:1:
No instance for (Eq (Integer -> Integer))
  arising from a use of `nub'
Possible fix:
  add an instance declaration for (Eq (Integer -> Integer))
In the expression: nub cs
In an equation for `it': it = nub cs

Thanks in advance.

...

Further, based on larsmans' answer, I am now able to do this

> let fs = [AddTwo, Double, Square]
> let css = nub $ concat $ map subsequences $ permutations fs

in order to get this

> css

[[],[AddTwo],[Double],[AddTwo,Double],[Square],[AddTwo,Square],[Double,Square],[AddTwo,Double,Square],[Double,AddTwo],[Double,AddTwo,Square],[Square,Double],[Square,AddTwo],[Square,Double,AddTwo],[Double,Square,AddTwo],[Square,AddTwo,Double],[AddTwo,Square,Double]]

and then this

> map (\cs-> call <$> cs <*> [3,4]) css

[[],[5,6],[6,8],[5,6,6,8],[9,16],[5,6,9,16],[6,8,9,16],[5,6,6,8,9,16],[6,8,5,6],[6,8,5,6,9,16],[9,16,6,8],[9,16,5,6],[9,16,6,8,5,6],[6,8,9,16,5,6],[9,16,5,6,6,8],[5,6,9,16,6,8]]

, which was my original intent.

share|improve this question

2 Answers 2

up vote 8 down vote accepted

No, this is not possible. Functions cannot be compared for equality.

The reason for this is:

  1. Pointer comparison makes very little sense for Haskell functions, since then the equality of id and \x -> id x would change based on whether the latter form is optimized into id.
  2. Extensional comparison of functions is impossible, since it would require a positive solution to the halting problem (both functions having the same halting behavior is a necessary requirement for equality).

The workaround is to represent functions as data:

data Function = AddTwo | Double | Square deriving Eq

call AddTwo  =  (+2)
call Double  =  (*2)
call Square  =  (^2)
share|improve this answer

No, it's not possible to do this for Integer -> Integer functions.

However, it is possible if you're also ok with a more general type signature Num a => a -> a, as your example indicates! One naïve way (not safe), would go like

{-# LANGUAGE FlexibleInstances           #-}
{-# LANGUAGE NoMonomorphismRestriction   #-}

data NumResLog a = NRL { runNumRes :: a, runNumResLog :: String }
             deriving (Eq, Show)

instance (Num a) => Num (NumResLog a) where
  fromInteger n = NRL (fromInteger n) (show n)
  NRL a alog + NRL b blog
            = NRL (a+b) ( "("++alog++ ")+(" ++blog++")" )
  NRL a alog * NRL b blog
            = NRL (a*b) ( "("++alog++ ")*(" ++blog++")" )
  ...


instance (Num a) => Eq (NumResLog a -> NumResLog a) where
  f == g  = runNumResLog (f arg) == runNumResLog (g arg)
     where arg = NRL 0 "THE ARGUMENT"

unlogNumFn :: (NumResLog a -> NumResLog c) -> (a->c)
unlogNumFn f = runNumRes . f . (`NRL`"")

which works basically by comparing a "normalised" version of the functions' source code. Of course this fails when you compare e.g. (+1) == (1+), which are equivalent numerically but yield "(THE ARGUMENT)+(1)" vs. "(1)+(THE ARGUMENT)" and thus are indicated as non-equal. However, since functions Num a => a->a are essentially constricted to be polynomials (yeah, abs and signum make it a bit more difficult, but it's still doable), you can find a data type that properly handles those equivalencies.

The stuff can be used like this:

> let fs = [(+2), (*2), (^2)]
> let cs = concat $ map subsequences $ permutations fs
> let ncs = map (map unlogNumFn) $ nub cs
> map (map ($ 1)) ncs
[[],[3],[2],[3,2],[1],[3,1],[2,1],[3,2,1],[2,3],[2,3,1],[1,2],[1,3],[1,2,3],[2,1,3],[1,3,2],[3,1,2]]
share|improve this answer

Your Answer

 
discard

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.