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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.

  1. Is it possible to explain why this runs so much slower on several CPUs than on one?
  2. 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
share|improve this question
1  
Note that this is really an implementation of quicksort: stackoverflow.com/questions/7717691/… –  user5402 Nov 3 '13 at 14:11
1  
At least I can't get it to perform better with pseq, even when purging down any possible thunks with sum. Perhaps there's an entirely different problem involved. — As I have now deleted by answer, here again as a comment: 1. naming that function just quicksort might confuse since you wouldn't expect such a function to accept an extra parallelism argument; 2. Use type signatures, just always for top-level functions and even more so when they might work slightly different than what the name suggests; 3. use library functions such as partition if possible. — Good question, BTW. –  leftaroundabout Nov 3 '13 at 14:58
3  
I don't have enough time to post a full answer, but I guess there are two possible issues: (1) You should rather use l `par` u `pseq` (u ++ l). (2) While you run sub-computations in parallel, they're not really evaluated until needed. So you should force each sub-list to NF (or at least its full structure), something like forceList l `par` forceList u `pseq` (u ++ l) where forceList is (your own) function that forces evaluation of a list. Also for proper benchmarking I suggest to use criterion. –  Petr Pudlák Nov 3 '13 at 20:44
    
If you want a quick and easy way to see how your sparks are doing, you can compile with the -rtsopts flag, and add the -sstderr flag when you then run the program. –  ollanta Nov 3 '13 at 20:52
1  
Actually, the mergesort implementation performs with almost constant speed on my machine as long as I don't use more threads than I have cores. I'm beginning to think the main problem we have is to do with memory/cache; lists just aren't great in that regard. If all cores wait most of the time fetching memory pages, little can be gained with parallelism. In the quicksort this is apparently more critical than in mergesort. –  leftaroundabout Nov 4 '13 at 9:32

2 Answers 2

I'm not sure how well it can work for the idiomatic quicksort, but it can work (to a somewhat weak extent) for the true imperative quicksort as shown by Roman in Sparking Imperatives.

He never did get good speedup, though. This really needs a real work-stealing deque that doesn't overflow like the spark queue to optimize properly.

share|improve this answer
    
Am I hitting a wall in the spark queue? I am only using par 16 times to subdivide the problem down to my 16 capabilities. After that the algorithm is sequential. Maybe I am not understanding something fundamental about the nature of par, pseq and sparks? –  lysgaard Nov 4 '13 at 9:46

You won't get any noticeable improvement since your pseudo-quicksort involves list concatenation, which cannot be parallelized and requires quadratic time (total time for all concatenations). I'd recommend you to try working with a mergesort, which is O(n log n) on linked lists.

Also, to run the program with large number of threads you should compile it with -rtsopts.

share|improve this answer
    
I have added a merge sort implementation. I have taken care to make the algorithm only traverse lists once during splitting and merging which should be optimal. It shows the same symptoms as the quick sort however. Slower the more capabilities you throw at it. -rtsopts is only needed for more than 24 capabilities. –  lysgaard Nov 4 '13 at 9:29
    
How is list concatenation quadratic in time? –  leftaroundabout Nov 4 '13 at 9:30
    
I mean, total time for all concatenations is quadratic –  tempestadept Nov 4 '13 at 9:45

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