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)
```

`prune`

looks likely to have thunk leaks. And your`Table Edge`

could be an unboxed vector, which should give you some additional boost. – jberryman Jun 23 '14 at 17:12canbe expected to run, but I could try to improve your code if I knew how fast it is now. – user2407038 Jun 23 '14 at 21:54