Set, similarly to
 has a perfectly defined monadic operations. The problem is that they require that the values satisfy
Ord constraint, and so it's impossible to define
>>= without any constraints. The same problem applies to many other data structures that require some kind of constraints on possible values.
The standard trick (suggested to me in a haskell-cafe post) is to wrap
Set into the continuation monad.
ContT doesn't care if the underlying type functor has any constraints. The constraints become only needed when wrapping/unwrapping
Sets into/from continuations:
import Control.Monad.Cont import Data.Foldable (foldrM) import Data.Set setReturn :: a -> Set a setReturn = singleton setBind :: (Ord b) => Set a -> (a -> Set b) -> Set b setBind set f = foldl' (\s -> union s . f) empty set type SetM r a = ContT r Set a fromSet :: (Ord r) => Set a -> SetM r a fromSet = ContT . setBind toSet :: SetM r r -> Set r toSet c = runContT c setReturn
This works as needed. For example, we can simulate a non-deterministic function that either increases its argument by 1 or leaves it intact:
step :: (Ord r) => Int -> SetM r Int step i = fromSet $ fromList [i, i + 1] -- repeated application of step: stepN :: Int -> Int -> Set Int stepN times start = toSet $ foldrM ($) start (replicate times step)
stepN 5 0 yields
fromList [0,1,2,3,4,5]. If we used
 monad instead, we would get
The problem is efficiency. If we call
stepN 20 0 the output takes a few seconds and
stepN 30 0 doesn't finish within a reasonable amount of time. It turns out that all
Set.union operations are performed at the end, instead of performing them after each monadic computation. The result is that exponentially many
Sets are constructed and
unioned only at the end, which is unacceptable for most tasks.
Is there any way around it, to make this construction efficient? I tried but without success.
(I even suspect that there could be some kinds of theoretical limits following from Curry-Howard isomorphism and Glivenko's theorem. Glivenko's theorem says that for any propositional tautology φ the formula ¬¬φ can be proved in intuitionistic logic. However, I suspect that the length of the proof (in normal form) can be exponentially long. So, perhaps, there could be cases when wrapping a computation into the continuation monad will make it exponentially longer?)