Note: This post was completely rewritten 2011-06-10; thanks to Peter for helping me out. Also, please don't be offended if I don't accept one answer, since this question seems to be rather open-ended. (But, if you solve it, you get the check mark, of course).
Another user had posted a question about parallelizing a merge sort. I thought I'd write a simple solution, but alas, it is not much faster than the sequential version.
Merge sort is a divide-and-conquer algorithm, where the leaves of computation can be parallelized.
The code works as follows: the list is converted into a tree, representing computation nodes. Then, the merging step returns a list for each node. Theoretically, we should see some significant performanc gains, since we're going from an O(n log n) algorithm to an O(n) algorithm with infinite processors.
The first steps of the computation are parallelized, when parameter l (level) is greater than zero below. This is done by [via variable strat] selecting the rpar strategy, which will make sub-computation mergeSort' x occur in parallel with mergeSort' y. Then, we merge the results, and force its evaluation with rdeepseq.
data Tree a = Leaf a | Node (Tree a) (Tree a) deriving (Show) instance NFData a => NFData (Tree a) where rnf (Leaf v) = deepseq v () rnf (Node x y) = deepseq (x, y) () listToTree  = error "listToTree -- empty list" listToTree [x] = Leaf x listToTree xs = uncurry Node $ listToTree *** listToTree $ splitAt (length xs `div` 2) xs -- mergeSort' :: Ord a => Tree a -> Eval [a] mergeSort' l (Leaf v) = return [v] mergeSort' l (Node x y) = do xr <- strat $ runEval $ mergeSort' (l - 1) x yr <- rseq $ runEval $ mergeSort' (l - 1) y rdeepseq (merge xr yr) where merge  y = y merge x  = x merge (x:xs) (y:ys) | x < y = x : merge xs (y:ys) | otherwise = y : merge (x:xs) ys strat | l > 0 = rpar | otherwise = rseq mergeSort = runEval . mergeSort' 10
By only evaluating a few levels of the computation, we should have decent parallel communication complexity as well -- some constant factor order of n.
Obtain the 4th version source code here [ http://pastebin.com/DxYneAaC ], and run it with the following to inspect thread usage, or subsequent command lines for benchmarking,
rm -f ParallelMergeSort; ghc -O2 -O3 -optc-O3 -optc-ffast-math -eventlog --make -rtsopts -threaded ParallelMergeSort.hs ./ParallelMergeSort +RTS -H512m -K512m -ls -N threadscope ParallelMergeSort.eventlog
Results on a 24-core X5680 @ 3.33GHz show little improvement
> ./ParallelMergeSort initialization: 10.461204s sec. sorting: 6.383197s sec. > ./ParallelMergeSort +RTS -H512m -K512m -N initialization: 27.94877s sec. sorting: 5.228463s sec.
and on my own machine, a quad-core Phenom II,
> ./ParallelMergeSort initialization: 18.943919s sec. sorting: 10.465077s sec. > ./ParallelMergeSort +RTS -H512m -K512m -ls -N initialization: 22.92075s sec. sorting: 7.431716s sec.
Inspecting the result in threadscope shows good utilization for small amounts of data. (though, sadly, no perceptible speedup). However, when I try to run it on larger lists, like the above, it uses about 2 cpus half the time. It seems like a lot of sparks are getting pruned. It's also sensitive to the memory parameters, where 256mb is the sweet spot, 128mb gives 9 seconds, 512 gives 8.4, and 1024 gives 12.3!
Solutions I'm looking for
Finally, if anyone knows some high-power tools to throw at this, I'd appreciate it. (Eden?). My primary interest in Haskell parallelism is to be able to write small supportive tools for research projects, which I can throw on a 24 or 80 core server in our lab's cluster. Since they're not the main point of our group's research, I don't want to spend much time on the parallelization efficiency. So, for me, simpler is better, even if I only end up getting 20% usage.
- I notice that the second bar in threadscope is sometimes green (c.f. its homepage, where the second bar seems to always be garbage collection). What does this mean?
- Is there any way to sidestep garbage collection? It seems to be taking a lot of time. For example, why can't a subcomputation be forked, return the result in shared memory, and then die?
- Is there a better way (arrows, applicative) to express parallelism?