*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.

## Problem statement

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*.

## Results

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.

## Further discussion

- 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?

`listToTree`

can be written`uncurry Node $ splitAt (length xs `div` 2) xs`

. – hammar Jun 9 '11 at 21:46`mergeSort in1 in2 `seq` putStrLn "done"`

? Because you probably want`deepSeq`

so that it actually does all the work down the entire result list – Lambdageek Jun 9 '11 at 21:54`splitAt`

will only traverse the list once. – hammar Jun 9 '11 at 23:20`rpar`

for the first computation, but`rseq`

for the second. When you spark both, the evaluation of`merge`

will start right away, and then you have three threads evaluating the`xr`

and`yr`

. – Peter Wortmann Jun 10 '11 at 11:22