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Generic programming time!

If I have a function:

f :: a1 -> a2 -> a3 -> ... -> an

and a value

v :: aX   -- where 1 <= x < n

Without knowing at compile time which of the arguments of f the value v is the right type for (if any), can I partially apply f to v? (using Typeable, Data, TH, or any other trick)

Slightly more solidly, can I construct the function g (below) at run-time? It doesn't actually have to be polymorphic, all my types will be monomorphic!

g :: (a1 -> a2 -> a3 -> a4 -> a5) -> a3 -> (a1 -> a2 -> a4 -> a5)
g f v = \x y z -> f x y v z

I know that, using Typeable (typeRepArgs specifically), v is the 3rd argument of f, but that doesn't mean I have a way to partially apply f.

My code would probably look like:

import Data.Typeable

data Box = forall a. Box (TyRep, a)

mkBox :: Typeable a => a -> Box
mkBox = (typeOf a, a)

g :: Box -> Box -> [Box]
g (Box (ft,f)) (Box (vt,v)) = 
    let argNums = [n | n <- [1..nrArgs], isNthArg n vt ft]
    in map (mkBox . magicApplyFunction f v) argNums

isNthArg :: Int -> TyRep -> TyRep -> Bool
isNthArg n arg func = Just arg == lookup n (zip [1..] (typeRepArgs func))

nrArgs :: TyRep -> Int
nrArgs = (\x -> x - 1) . length . typeRepArgs

Is there anything that can implement the magicApplyFunction?

EDIT: I finally got back to playing with this. The magic apply function is:

buildFunc :: f -> x -> Int -> g
buildFunc f x 0 = unsafeCoerce f x
buildFunc f x i =
        let !res = \y -> (buildFunc (unsafeCoerce f y) x (i-1))
        in unsafeCoerce res
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There is nothing wrong with g, as far as I can see, and polymorphism does not matter either. Just as you can use flip everytime you have a function and the 2nd argument, you know. –  Ingo Apr 21 '11 at 14:21
    
But I don't have`g` at compile time! How can I generate it at runtime? IIRC, I can't pass functions back and forth to/from hint –  Thomas M. DuBuisson Apr 21 '11 at 14:33
    
Writing the function to apply it via th shouldn't be a problem -- the issue is what sort of value you get back (Dynamic/Box) is, as you realize, your only option. –  sclv Apr 21 '11 at 15:08
    
A few design decisions are ambiguous here. What happens when more than one argument has the same type? Should you always pick the first, the last, or should you be required to specify the argument number? The best way, imho, would be partial application fused with python-like keyword args, but that would require a lot more magic. –  Dan Burton Apr 21 '11 at 16:37
    
Dan: If more than one argument has the same type I want all possible functions the result from partially applying f with a single v in each argument placement that is type-correct. If you look at g in my last code snippet you'll see this. –  Thomas M. DuBuisson Apr 21 '11 at 16:46
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2 Answers

up vote 2 down vote accepted

I'm not going to write the whole solution here for now, but I'm sure this can be done purely with Data.Dynamic and Typeable. The source for dynApply and funResultTy should provide the key elements:

dynApply :: Dynamic -> Dynamic -> Maybe Dynamic
dynApply (Dynamic t1 f) (Dynamic t2 x) =
  case funResultTy t1 t2 of
    Just t3 -> Just (Dynamic t3 ((unsafeCoerce f) x))
    Nothing -> Nothing


funResultTy :: TypeRep -> TypeRep -> Maybe TypeRep
funResultTy trFun trArg
  = case splitTyConApp trFun of
      (tc, [t1,t2]) | tc == funTc && t1 == trArg -> Just t2
      _ -> Nothing

To keep things simple, I'd have type Box = (Dynamic, [Either TypeRep Dynamic]). The latter starts out as a list of typereps of arguments. magicApply would look for the first matching TypeRep in the box and substitute the Dynamic of the value. Then you could have an extract that given a Box to which all arguments have been magicapplied, actually performs the dynApply calls to produce the resulting dynamic result.

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Isn't this just dynamically checking that x is the correct type for the first argument of f (no flipping / argument reordering)? If f :: Int -> Double -> Bool and x :: Double then I wish to combine f and x to get h :: Int -> Bool. Did I miss the point of your answer? –  Thomas M. DuBuisson Apr 21 '11 at 15:27
    
@TomMD that's what dynApply and funResultTy do. They're just copy/paste from the library definitions. how they do it shows how to extract the full list of arguments to a function, which in turn can be used to implement the solution I sketched below that code. –  sclv Apr 21 '11 at 15:36
    
Ah, I see your point. I'll play with this a bit - thanks! –  Thomas M. DuBuisson Apr 21 '11 at 15:57
    
Thanks for the pointers. I got around to building an apply function by swinging unsafeCoerce around like a blind woodsman. See the edit if you're interested. –  Thomas M. DuBuisson Apr 27 '11 at 17:25
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Hm.. Typeable only? How about good old OverlappingInstances?

{-# LANGUAGE MultiParamTypeClasses, FlexibleInstances, TypeFamilies,
UndecidableInstances, IncoherentInstances, ScopedTypeVariables #-}

class Magical a b c where
    apply :: a -> b -> c

instance (AreEqual a c e, Magical' e (a -> b) c r) => Magical (a -> b) c r where
    apply f a = apply' (undefined :: e) f a


class Magical' e a b c where
    apply' :: e -> a -> b -> c

instance (r ~ b) => Magical' True (a -> b) a r where
    apply' _ f a = f a

instance (Magical b c d, r ~ (a -> d)) => Magical' False (a -> b) c r where
    apply' _ f c = \a -> apply (f a) c


data True
data False

class AreEqual a b r
instance (r ~ True) => AreEqual a a r
instance (r ~ False) => AreEqual a b r


test :: Int -> Char -> Bool
test i c = True

t1 = apply test (5::Int)
t2 = apply test 'c'
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