This is a follow up to this post, with code now based on Structuring Depth-First Search Algorithms in Haskell to do depth first search, by King and Launchbury in the 1990s. That paper suggests a generate and prune strategy, but uses a mutable array with a State Monad (with some grammar that I suspect has since been deprecated). The authors hint that a set could be used for remembering nodes visited, as the cost of an additional O(log n). I tried to implement with a set (we have better machines now than they did in the 1990s!), to use modern State Monad syntax, and to use Vectors rather than arrays (as I read that that is normally better).
As before, my code runs on small data sets, but fails to return on the 5m edge graph I need to analyse, and I'm looking for hints only as to the weakness operating at scale. What I do know is that the code operates comfortably within memory, so that is not the problem, but have I inadvertently slipped to O(n2)? (By contrast, the official implementation of this paper in the Data.Graph library (which I have lately also borrowed some code from) uses a mutable Array but fails on the big data set with a ... Stack Overflow!!!)
So now I have a Vector data store with IntSet State that does not complete and an Array with ST Monad Array 'official' one that crashes! Haskell should be able to do better than this?
import Data.Vector (Vector) import qualified Data.IntSet as IS import qualified Data.Vector as V import qualified Data.ByteString.Char8 as BS import Control.Monad.State type Vertex = Int type Table a = Vector a type Graph = Table [Vertex] type Edge = (Vertex, Vertex) data Tree a = Node a (Forest a) deriving (Show,Eq) type Forest a = [Tree a] -- ghc -O2 -threaded --make -- +RTS -Nx generate :: Graph -> Vertex -> Tree Vertex generate g v = Node v $ map (generate g) (g V.! v) chop :: Forest Vertex -> State IS.IntSet (Forest Vertex) chop  = return  chop (Node x ts:us) = do visited <- contains x if visited then chop us else do include x x1 <- chop ts x2 <- chop us return (Node x x1:x2) prune :: Forest Vertex -> State IS.IntSet (Forest Vertex) prune vs = chop vs main = do --edges <- V.fromList `fmap` getEdges "testdata.txt" edges <- V.fromList `fmap` getEdges "SCC.txt" let -- calculate size of five largest SCC maxIndex = fst $ V.last edges gr = buildG maxIndex edges sccRes = scc gr big5 = take 5 sccRes big5' = map (\l -> length $ postorder l) big5 putStrLn $ show $ big5' contains :: Vertex -> State IS.IntSet Bool contains v = state $ \visited -> (v `IS.member` visited, visited) include :: Vertex -> State IS.IntSet () include v = state $ \visited -> ((), IS.insert v visited) getEdges :: String -> IO [Edge] getEdges path = do lines <- (map BS.words . BS.lines) `fmap` BS.readFile path let pairs = (map . map) (maybe (error "can't read Int") fst . BS.readInt) lines return [(a, b) | [a, b] <- pairs] vertices :: Graph -> [Vertex] vertices gr = [1.. (V.length gr - 1)] edges :: Graph -> [Edge] edges g = [(u,v) | u <- vertices g, v <- g V.! u] -- accumulate :: (a -> b -> a) -> Vector a-> Vector (Int, b)--> Vector a -- accumulating function f -- initial vector (of length m) -- vector of index/value pairs (of length n) buildG :: Int -> Table Edge -> Graph buildG maxIndex edges = graph' where graph = V.replicate (maxIndex + 1)  --graph' = V.accumulate (\existing new -> new:existing) graph edges -- flip f takes its (first) two arguments in the reverse order of f graph' = V.accumulate (flip (:)) graph edges mapT :: Ord a => (Vertex -> a -> b) -> Table a -> Table b mapT = V.imap outDegree :: Graph -> Table Int outDegree g = mapT numEdges g where numEdges v es = length es indegree :: Graph -> Table Int indegree g = outDegree $ transposeG g transposeG :: Graph -> Graph transposeG g = buildG (V.length g - 1) (reverseE g) reverseE :: Graph -> Table Edge reverseE g = V.fromList [(w, v) | (v,w) <- edges g] -- -------------------------------------------------------------- postorder :: Tree a -> [a] postorder (Node a ts) = postorderF ts ++ [a] postorderF :: Forest a -> [a] postorderF ts = concat (map postorder ts) postOrd :: Graph -> [Vertex] postOrd g = postorderF (dff g) dfs :: Graph -> [Vertex] -> Forest Vertex dfs g vs = map (generate g) vs dfs' :: Graph -> [Vertex] -> Forest Vertex dfs' g vs = fst $ runState (prune d) $ IS.fromList  where d = dfs g vs dff :: Graph -> Forest Vertex dff g = dfs' g $ reverse (vertices g) scc :: Graph -> Forest Vertex scc g = dfs' g $ reverse $ postOrd (transposeG g)