In this recent answer of mine, I happened to crack open this old chestnut (a program so old, half of it was written in the seventeenth century by Leibniz and written on a computer in the seventies by my dad). I'll leave out the modern bit to save space.
class Differentiable f where type D f :: * -> * newtype K a x = K a newtype I x = I x data (f :+: g) x = L (f x) | R (g x) data (f :*: g) x = f x :&: g x instance Differentiable (K a) where type D (K a) = K Void instance Differentiable I where type D I = K () instance (Differentiable f, Differentiable g) => Differentiable (f :+: g) where type D (f :+: g) = D f :+: D g instance (Differentiable f, Differentiable g) => Differentiable (f :*: g) where type D (f :*: g) = (D f :*: g) :+: (f :*: D g)
Now, here's the frustrating thing. I don't know how to stipulate that
D f must itself be differentiable. Certainly, these instances respect that property, and there might well be fun programs you can write which make use of the ability to keep differentiating a functor, shooting holes in more and more places: Taylor expansions, that sort of thing.
I'd like to be able to say something like
class Differentiable f where type D f instance Differentiable (D f)
and require a check that instance declarations have
type definitions for which the necessary instances exist.
Maybe more mundane stuff like
class SortContainer c where type WhatsIn c instance Ord (WhatsIn c) ...
would also be nice. That, of course, has the fundep workaround
class Ord w => SortContainer c w | c -> w where ...
but to attempt the same trick for
Differentiable seems... well... involuted.
So, is there a nifty workaround that gets me repeatable differentiability? (I guess I could build a representation GADT and and and... but is there a way that works with classes?)
And are there any obvious snags with the suggestion that we should be able to demand constraints on type (and, I suppose, data) families when we declare them, then check that the instances satisfy them?