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I have an implementation of Conway's Game of Life. I want to speed it up if possible by using parallelism.

life :: [(Int, Int)] -> [(Int, Int)]
life cells = map snd . filter rules . freq $ concatMap neighbours cells
    where rules (n, c) = n == 3 || (n == 2 && c `elem` cells)
          freq = map (length &&& head) . group . sort

parLife :: [(Int, Int)] -> [(Int, Int)]
parLife cells = parMap rseq snd . filter rules . freq . concat $ parMap rseq neighbours cells
    where rules (n, c) = n == 3 || (n == 2 && c `elem` cells)
          freq = map (length &&& head) . group . sort

neigbours :: (Int, Int) -> [(Int, Int)]
neighbours (x, y) = [(x + dx, y + dy) | dx <- [-1..1], dy <- [-1..1], dx /= 0 || dy /= 0]

in profiling, neighbours accounts for 6.3% of the time spent, so while small I expected a noticable speedup by mapping it in parallel.

I tested with a simple function

main = print $ last $ take 200 $ iterate life fPent
    where fPent = [(1, 2), (2, 2), (2, 1), (2, 3), (3, 3)]

and compiled the parallel version as

ghc --make -O2 -threaded life.hs

and ran it as

./life +RTS -N3

it turns out that the parallel version is slower. Am I using parMap incorrectly here? is this even a case where parallelism can be used?

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Firstly, do you have at least 3 cores in your computer? Secondly, parallelism always comes with some overhead, so if the work being done by each thread is very small, the extra overhead will outweigh any speed-ups. –  dbaupp Sep 1 '12 at 8:24
    
i have an i5-2500k, so there is definitely up to 4 cores avaliable –  cdk Sep 1 '12 at 13:34
    
Note that you can get much larger speedups from improving the algorithm than from parallelising. The bulk of the time is spent in sort and elem. Using the fact that the list of cells is sorted (and changing fPent so that it is sorted) you can roughly halve the time. –  Daniel Fischer Sep 1 '12 at 14:22
    
@DanielFischer: the list is not necessarily sorted if fPent is sorted. freq takes the list of every cell neighbouring a live cell as its input, and the same cell could be the neigbour of many different live cells and appear scattered throughout the list. If there was a way to be able to find the total number of occurences of each unique element in the list faster than sorting, that would indeed improve the algorithm –  cdk Sep 7 '12 at 23:14
    
Chris, you sort the list in the step: freq = map (length &&& head) . group . sort, so the cells for the next generation are always sorted. –  Daniel Fischer Sep 8 '12 at 16:11
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1 Answer

up vote 2 down vote accepted

I don't think you're measuring right. Your parLife is indeed a bit faster than life. In fact, on my machine (Phenom X4, 4 core,) the former only takes about 92.5% of the time the latter does, which considering you're saying you're expecting only a 6% improvement is quite good.

What is your benchmarking setup? Have you tried using criterion? Here's what I did:

import Criterion
import Criterion.Main

-- your code, minus main

runGame f n = last $ take n $ iterate f fPent
    where fPent = [(1, 2), (2, 2), (2, 1), (2, 3), (3, 3)]

main = defaultMain
    [ bench "No parallelism 200" $ whnf (runGame life)    200
    , bench "Parallelism 200"    $ whnf (runGame parLife) 200 ]

Compiled with ghc --make -O2 -o bench and ran with ./bench -o bencht.hmtl +RTS -N3.

Here's the detailed result of the report.

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Hmm, strange. I also get the result that parLife is faster from criterion, but when I run the thing standalone, parLife is consistently significantly slower than life. –  Daniel Fischer Sep 1 '12 at 14:11
    
Ah, only with the threaded runtime, not with the nonthreaded! –  Daniel Fischer Sep 1 '12 at 14:15
    
I think it has something to do with the longevity of the process… I.e. initializing the thread pool etc. is more expensive than the (admittedly minor) gains we get from parallelizing. –  Aleksandar Dimitrov Sep 1 '12 at 14:18
    
Possibly. But I ran with 500 iterations to get more reliable timings. That's long enough that initialising the thread pool etc. shouldn't matter. Probably the threaded runtime has higher overhead for sparking. –  Daniel Fischer Sep 1 '12 at 14:27
    
Oh, but wait! The non-threaded runtime doesn't even support parallelism, no sparks there! –  Daniel Fischer Sep 1 '12 at 14:38
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