# polymorphic function on existential type

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

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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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
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
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
Although, I note that `Int -> ScaleValue` might be best represented as `[ScaleValue]` or `Stream ScaleValue`. –  ehird Dec 17 '11 at 6:38
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