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?

`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`freq = map (length &&& head) . group . sort`

, so the`cells`

for the next generation are always sorted. – Daniel Fischer Sep 8 '12 at 16:11