I'm trying to write an arrow transformer that takes regular functions, and turns them into computations on abstract values. If we have a "source" arrow,
f :: Int -> Int f x = x + 1
then the goal would be to have f work on lifted [sic?] abstract value types, in this example
f' :: AV Int -> AV Int f' (Const x) = Const (f x) -- pass along errors, since AV computation isn't always defined -- or computable in the case of errors f' (Error s) = Error s -- avRep = "abstract representation". Think of symbolic math manipulation or ASTs. f' (Abstract avRep) = AVRepPlus avRep (AVRepConst 1)
However, in order to implement this arrow successfully, one needs to lift a few types, so that one has heterogeneous data structures with some concrete and some abstract values, at arbitrary depth. What I've ended up doing is adding special types for regular haskell constructors, e.g. if
g = uncurry (+) -- i.e. g (x, y) = x + y
then I add an abstract representation for (,), the tuple constructor,
AVTuple :: AV a -> AV b -> AV (a, b)
and the code for g is lifted to [unrolled a little],
g' (AVTuple (AVConst a) (AVConst b)) = (AVConst (g (a, b))) g' (AVTuple (AVError e) _) = (AVError e) -- symmetric case here, i.e. AVTuple _ (AVError e) g' (AVTuple a@(AVTuple _ _) b) = -- recursive code here
The same needs to be done with AVEither. This is going to end up being a lot of cases. Is there a nice way around this?
I am a Haskell newbie, so please send me references or semi-detailed explanation; probably the closest thing I've read is the SYBR paper (scrap your boilerplate revolutions) sections 1-3.
Thank you very very much!