You may find Data.MemoCombinators useful (in the data-memocombinators package).
You don't say what argument types your
g take --- if they both takes integral values then you would use it like this:
import qualified Data.MemoCombinators as Memo
foo = iterate step (Memo.integral f0, Memo.integral g0)
If required, you could memoise the output of each step as well
step (f,g) = (Memo.integral (newF f g), Memo.integral (newG f g))
I hope you don't see this as ripping the whole program apart.
In reply to your comment:
This is the best I can come up with. It's untested, but should be working along the right lines.
I worry that converting between
Rational is needlessly inefficient --- if there was a
Bits instance for
Double we could use
Memo.bits instead. So this might not ultimately be of any practical use to you.
import Control.Arrow ((&&&))
import Data.Ratio (numerator, denominator, (%))
memoV :: Memo.Memo a -> Memo.Memo (V a)
memoV m f = \(V x y z) -> table x y z
where g x y z = f (V x y z)
table = Memo.memo3 m m m g
memoRealFrac :: RealFrac a => Memo.Memo a
memoRealFrac f = Memo.wrap (fromRational . uncurry (%))
((numerator &&& denominator) . toRational)
A different approach.
step :: (V Double -> V Double, V Double -> V Double)
-> (V Double -> V Double, V Double -> V Double)
How about you change that to
step :: (V Double -> (V Double, V Double))
-> (V Double -> (V Double, V Double))
step h x = (r fx gx, s fx gx)
where (fx, gx) = h x
And also change
foo = (fst . bar, snd . bar)
where bar = iterate step (f0 &&& g0)
Hopefully the shared
gx should result in a bit of a speed-up.