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I would like to create three Haskell functions: a, b, and c.

Each function is to have one argument. The argument is one of the three functions.

I would like function a to have this behavior:

  • if the argument is function a then return function a.
  • if the argument is function b then return function b.
  • if the argument is function c then return function a.

Here's a recap of the behavior I desire for function a:

a a = a
a b = c
a c = a 

And here's the behavior I desire for the other two functions:

b a = a
b b = a
b c = c

c a = c
c b = b
c c = c

Once created, I would like to be able to compose the functions in various ways, for example:

  a (c b)
= a (b)
= c

How do I create these functions?

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2  
You will have to tag the function with some data so you can compare them. That is, you cannot use plain functions. You need to put them in a data type that also has some comparable value. –  Thomas Eding Mar 16 '12 at 22:58
1  
what have you done so far? have you got the signature of the functions? –  Karoly Horvath Mar 16 '12 at 22:59
3  
What are you trying to do by achieving this? –  Marshall Conover Mar 16 '12 at 23:03
    
Try to specify the type of a. (danr gives it the type x -> y, which is cheating in the absolute worst way possible: it's a function that takes something and produces something! unsafeCoerce is an abomination :) –  Dan Burton Mar 17 '12 at 7:24
    
Thanks everyone for the excellent responses. I am trying to implement "the enchanted forest" from pages 73-74 of the book "To Mock a Mockingbird". My Haskell is a bit rusty (obviously). BTW, this is not homework, it is purely for my own interests. –  Roger Costello Mar 17 '12 at 8:56

4 Answers 4

up vote 15 down vote accepted

Since you have given no criteria for how you are going to observe the results, then a = b = c = id satisfies your criteria. But of course that is not what you want. But the idea is important: it doesn't just matter what behavior you want your functions to have, but how you are going to observe that behavior.

There is a most general model if you allow some freedom in the notation, and you get this by using an algebraic data type:

data F = A | B | C
    deriving (Eq, Show) -- ability to compare for equality and print

infixl 1 % 
(%) :: F -> F -> F
A % A = A
A % B = C
A % C = A
B % A = A
...

and so on. Instead of saying a b, you have to say A % B, but that is the only difference. You can compose them:

  A % (C % B)
= A % B
= B

and you can turn them into functions by partially applying (%):

a :: F -> F
a = (A %)

But you cannot compare this a, as ehird says. This model is equivalent to the one you specified, it just looks a little different.

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4  
You can compare that a just fine: instance Eq (F -> F) where f == g = all (\x -> f x == g x) [A, B, C] –  Sjoerd Visscher Mar 17 '12 at 11:10
    
@SjoerdVisscher, oh, right, since it is finite. I always forget about that. –  luqui Mar 17 '12 at 20:10

This is impossible; you can't compare functions to each other, so there's no way to check if your argument is a, b, c or something else.

Indeed, it would be impossible for Haskell to let you check whether two functions are the same: since Haskell is referentially transparent, substituting two different implementations of the same function should have no effect. That is, as long as you give the same input for every output, the exact implementation of a function shouldn't matter, and although proving that \x -> x+x and \x -> x*2 are the same function is easy, it's undecidable in general.

Additionally, there's no possible type that a could have if it's to take itself as an argument (sure, id id types, but id can take anything as its first argument — which means it can't examine it in the way you want to).

If you're trying to achieve something with this (rather than just playing with it out of curiosity — which is fine, of course), then you'll have to do it some other way. It's difficult to say exactly what way that would be without concrete details.

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Well, you can do it like this:

{-# LANGUAGE MagicHash #-}

import GHC.Prim
import Unsafe.Coerce

This function is from ehird's answer here:

equal :: a -> a -> Bool
equal x y = x `seq` y `seq`
              case reallyUnsafePtrEquality# x y of
                 1# -> True
                 _  -> False

Now, let's get to business. Notice that you need to coerce the arguments and the return values as there is no possible type these functions can really have, as ehird pointed out.

a,b,c :: x -> y
a x | unsafeCoerce x `equal` a = unsafeCoerce a
    | unsafeCoerce x `equal` b = unsafeCoerce c
    | unsafeCoerce x `equal` c = unsafeCoerce a

b x | unsafeCoerce x `equal` a = unsafeCoerce a
    | unsafeCoerce x `equal` b = unsafeCoerce a
    | unsafeCoerce x `equal` c = unsafeCoerce c

c x | unsafeCoerce x `equal` a = unsafeCoerce c
    | unsafeCoerce x `equal` b = unsafeCoerce b
    | unsafeCoerce x `equal` c = unsafeCoerce c

Finally, some tests:

test  = a (c b) `equal` c   -- Evaluates to True
test' = a (c b) `equal` a   -- Evaluates to False

Ehh...

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You can do it with 19 nontrivial unsafes, but can you do it with 20?! –  luqui Mar 16 '12 at 23:27
    
@luqui: the 20th unsafeCoerce is hiding here –  danr Mar 16 '12 at 23:34
3  
@luqui Sure! reallyUnsafes count double. –  Daniel Wagner Mar 16 '12 at 23:35
    
What have I wrought?! –  ehird Mar 17 '12 at 0:05
    
Don't forget, this is GHC only, and I don't think reallyUnsafePtrEquality# is even guaranteed to actually work correctly. –  Dan Burton Mar 17 '12 at 7:19

As noted, functions can't be compared for equality. If you simply want functions that satisfy the algebraic laws in your specificiation, making them all equal to the identity function will do nicely.

I hope you are aware that if you post a homework-related question to Stack Overflow, the community expects you to identify it as such.

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2  
Only a very cruel, very ignorant, or very unclear teacher would assign this as a homework problem. –  Dan Burton Mar 17 '12 at 7:21
2  
@DanBurton: agreed. But if it's not homework, then where on Earth does this problem come from? –  Norman Ramsey Mar 17 '12 at 19:31

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