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So say I have a class:

class C a where
  reduce :: a -> Int

Now I want to pack it up in a data type:

data Signal = forall a. (C a) => Signal [(Double, a)]

Thanks to the existential quantification, I can call C methods on Signals, but Signals don't expose a type parameter:

reduceSig :: Signal -> [(Double, Int)]
reduceSig (Signal sig) = map (second reduce) sig

Now since C has a number of methods my natural next step is to pull out the 'reduce' function so I can substitute any method:

mapsig :: (C a) => (a -> a) -> Signal -> Signal
mapsig f (Signal sig) = Signal (map (second f) sig)

Type error! Could not deduce (a1 ~ a). On further thought, I think what it's saying is that 'f' is a function on some instance of C, but I can't guarantee it's the same instance of C as in the Signals, because the type parameters are concealed! I wanted it, I got it.

So does this mean it's impossible to generalize reduceSig? I can live with this, but I'm so used to freely factoring out functions in haskell it feels strange to be obliged to write the boilerplate. On the other hand, I can't think of any way to express that a type is equal to the type inside of Signal, short of giving Signal a type parameter.

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By the way, unless C contains more than you have here, your Signal type is equivalent to data Signal = Signal [(Double, Int)]! So there's no advantage to using an existential type here, unless this is a simplified problem (see also: 1, 2, although the situations they address aren't completely analogous). –  ehird Dec 17 '11 at 5:43
    
Yeah, C has a bunch of methods, I was just trying to simplify for the example. But as you point out, simplify too much and the whole rationale goes away :) –  Evan Laforge Dec 17 '11 at 5:48

1 Answer 1

up vote 15 down vote accepted

What you need to express is that f, like reduce used in reduceSig, can be applied to any type that is an instance of C, as opposed to the current type, where f works on a single type that is an instance of C. This can be done like so:

mapsig :: (forall a. (C a) => a -> a) -> Signal -> Signal
mapsig f (Signal sig) = Signal (map (second f) sig)

You'll need the RankNTypes extension, as you often do when using existential types; note that the implementation of mapsig is the same, the type has just been generalised.

Basically, with this type, mapsig gets to decide which a the function is called on; with your previous type, the caller of mapsig gets to decide that, which doesn't work, because only mapsig knows the correct a, i.e. the one inside the Signal.

However, mapsig reduce does not work, for the obvious reason that reduce :: (C a) => a -> Int, and you don't know that a is Int! You need to give mapsig a more general type (with the same implementation):

mapsig :: (C b) => (forall a. (C a) => a -> b) -> Signal -> Signal

i.e., f is a function taking any type that is an instance of C, and producing a type that is an instance of C (that type is fixed at the time of the mapsig call and chosen by the caller; i.e. while the value mapsig f can be called on any Signal, it will always produce a Signal with the same a as a result (not that you can inspect this from outside).)

Existentials and rank-N types are very tricky indeed, so this might take a bit of time to digest. :)


As an addendum, it's worth pointing out that if all the functions in C look like a -> r for some r, then you would be better off creating a record instead, i.e. turning

class C a where
  reduce :: a -> Int
  foo :: a -> (String, Double)
  bar :: a -> ByteString -> Magic

data Signal = forall a. (C a) => Signal [(Double, a)]

mapsig :: (C b) => (forall a. (C a) => a -> b) -> Signal -> Signal

into

data C = C
  { reduce :: Int
  , foo :: (String, Double)
  , bar :: ByteString -> Magic
  }

data Signal = Signal [(Double, C)]

mapsig :: (C -> C) -> Signal -> Signal

These two Signal types are actually equivalent! The benefits of the former solution only appear when you have other data types that use C without existentially quantifying it, so that you can have code that uses special knowledge and operations of the specific instance of C it's using. If your primary use-cases of this class are through existential quantification, you probably don't want it in the first place. But I don't know what your program looks like :)

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1  
Aha, I thought it would involve RankNTypes somehow, but I didn't know that it would select a type for 'a' to agree with the type hidden inside Signal. That's pretty cool. Actually, it turns out I slightly misstated my problem, 'C a' has various 'a->a' functions, and those are happy with the first mapsig. You're right, the second is a little magical seeming and I'll have to put some more thought into that one. Thanks for the enlightenment! –  Evan Laforge Dec 17 '11 at 6:25
1  
Right, I agree about the record, and I usually prefer records to classes. But here's the real class declaration: class Scale d where transpose_chromatic :: Int -> d -> d; transpose_diatonic :: Int -> d -> d; reduce :: Degree d -> Frequency. Given that, I could put the functions in a record, but I'd still need a polymorphic 'd' since notes of different scales will require different amounts of data to represent them. I suppose the functions could all be pre-partially-applied to the appropriate data... hmm, I'll have to think more on it. –  Evan Laforge Dec 17 '11 at 6:28
1  
Well, transpose_chromatic and transpose_diatonic are easily represented as Int -> ScaleValue fields (where the data type is ScaleValue), but you'd have to change the definition of Degree. I think it should be fairly easy, assuming Degree isn't a type family, but if you don't use this class solely through existential quantification, then I agree it probably isn't worth it. It's another question entirely, anyway :) Good luck with your design! –  ehird Dec 17 '11 at 6:36
1  
Although, I note that Int -> ScaleValue might be best represented as [ScaleValue] or Stream ScaleValue. –  ehird Dec 17 '11 at 6:38
1  
Ah, I suppose you mean pre-apply transpose to [1..] and let laziness do its thing. Assuming that transpositions are small numbers, I can see how this is mostly equivalent. Of course, I'd need two, one for positive and one for negative. I wonder what other reasons there are to prefer one over the other? –  Evan Laforge Dec 17 '11 at 19:42

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