I have got this seemingly trivial parallel quicksort implementation, the code is as follows:
import System.Random import Control.Parallel import Data.List quicksort :: [a] -> [a] quicksort xs = pQuicksort 16 xs -- 16 is the number of sparks used to sort -- pQuicksort, parallelQuicksort -- As long as n > 0 evaluates the lower and upper part of the list in parallel, -- when we have recursed deep enough, n==0, this turns into a serial quicksort. pQuicksort :: Int -> [a] -> [a] pQuicksort _  =  pQuicksort 0 (x:xs) = let (lower, upper) = partition (< x) xs in pQuicksort 0 lower ++ [x] ++ pQuicksort 0 upper pQuicksort n (x:xs) = let (lower, upper) = partition (< x) xs l = pQuicksort (n `div` 2) lower u = [x] ++ pQuicksort (n `div` 2) upper in (par u l) ++ u main :: IO () main = do gen <- getStdGen let randints = (take 5000000) $ randoms gen :: [Int] putStrLn . show . sum $ (quicksort randints)
I compile with
ghc --make -threaded -O2 quicksort.hs
and run with
./quicksort +RTS -N16 -RTS
No matter what I do I can not get this to run faster than a simple sequential implementation running on one cpu.
- Is it possible to explain why this runs so much slower on several CPUs than on one?
- Is it possible to make this scale, at least sub linearly, with the number of CPUs by doing some trick?
EDIT: @tempestadept hinted that quick sort it self is the problem. To check this I implemented a simple merge sort in the same spirit as the example above. It has the same behaviour, performs slower the more capabilities you add.
import System.Random import Control.Parallel splitList :: [a] -> ([a], [a]) splitList = helper True   where helper _ left right  = (left, right) helper True left right (x:xs) = helper False (x:left) right xs helper False left right (x:xs) = helper True left (x:right) xs merge :: (Ord a) => [a] -> [a] -> [a] merge xs  = xs merge  ys = ys merge (x:xs) (y:ys) = case x<y of True -> x : merge xs (y:ys) False -> y : merge (x:xs) ys mergeSort :: (Ord a) => [a] -> [a] mergeSort xs = pMergeSort 16 xs -- we use 16 sparks -- pMergeSort, parallel merge sort. Takes an extra argument -- telling how many sparks to create. In our simple test it is -- set to 16 pMergeSort :: (Ord a) => Int -> [a] -> [a] pMergeSort _  =  pMergeSort _ [a] = [a] pMergeSort 0 xs = let (left, right) = splitList xs in merge (pMergeSort 0 left) (pMergeSort 0 right) pMergeSort n xs = let (left, right) = splitList xs l = pMergeSort (n `div` 2) left r = pMergeSort (n `div` 2) right in (r `par` l) `pseq` (merge l r) ris :: Int -> IO [Int] ris n = do gen <- getStdGen return . (take n) $ randoms gen main = do r <- ris 100000 putStrLn . show . sum $ mergeSort r