I wrote a small state space explorer for an exhaustive search problem. Given a start state, a transition relation computes a set of successor states, until all states have been seen (I know that the search space is finite). For my problem at hand, it yields 2*n successor states tops. For all states, I also check if they satisfy some property
dlCheck (here, there's only ONE matching state in the whole state space).
As I keep the
Data.Set of seen states around, I'm expecting big-time memory consumption already. However, the heap profile has me puzzling (ATest contains the code below, the property check and transition are in another module):
If I would guess, I'd say that lower bound on
Set is the size of the already explored state space. I am wondering where the periodic contraction is coming from. Do you spot anything funny in the exploration below? The main call is into the final
dlsStreamHist at the bottom.
Given that the whole program is too large to post, and I have some idea on the performance of the transition relation and the property check, I'm assuming the problem is somewhere here. Am I maybe looking for strict set-operations, very much like
foldl'? It could be that somehow first all successor states are calculated, before comparing them to the
seen set, instead of doing it on the fly.
-- 'test' applies a step to each process in the state (individually), yielding a set of successor states -- ...or not, if a process blocks. Already seen states are in the first component -- so that we don't explore them again, -- blocked configs go into the second, and new successor states go into the third component. -- We produce a potentially infinite stream of sets of blocked/enabled configurations. -- This method generates our search space; the transition relation 'step' is in here. testHistory :: State a => Set a -> Set a -> [(Set a, Set a, Set a)] testHistory seen ps | null ps =  | otherwise = let (ls,rs) = fold (\s lr -> fold (\x (l,r) -> maybe (insert s l,r) (\c -> (l,insert c r)) x) lr (step s)) (empty,empty) ps newSeen = seen `union` ps new = rs `difference` newSeen in (newSeen,ls,new):(testHistory newSeen new) -- Take a program, and run it (to infinity). For each blocked configuration, collect all deadlocks (if any). -- For infinite streams, you might want to 'nub' the result. dlsStreamT :: State a => (Set a -> [(Set a, c)]) -> a -> [Set (Process,Lock,Int)] dlsStreamT testF p = concatMap (Data.Set.toList . (fold (union) empty) . (filter (not . null)) . (Data.Set.map (filter (not . null)))) $ map ((filter (not . null)) . (Data.Set.map dlCheck) . fst) (testF (singleton p)) dlsStreamHist :: State a => a -> [Set (Process,Lock,Int)] dlsStreamHist = dlsStreamT (map (\(_,x,y)->(x,y)) . testHistory empty)