I want to write a parallel map function in Haskell that's as efficient as possible. My initial attempt, which seems to be currently best, is to simply write,

```
pmap :: (a -> b) -> [a] -> [b]
pmap f = runEval . parList rseq . map f
```

I'm not seeing perfect CPU division, however. If this is possibly related to the number of sparks, could I write a pmap that divides the list into *# of cpus* segments, so there are minimal sparks created? I tried the following, but the peformance (and number of sparks) is much worse,

```
pmap :: (a -> b) -> [a] -> [b]
pmap f xs = concat $ runEval $ parList rseq $ map (map f) (chunk xs) where
-- the (len / 4) argument represents the size of the sublists
chunk xs = chunk' ((length xs) `div` 4) xs
chunk' n xs | length xs <= n = [xs]
| otherwise = take n xs : chunk (drop n xs)
```

The worse performance may be correlated with the higher memory use. The original pmap does scale somewhat on 24-core systems, so it's not that I don't have enough data. (The number of CPU's on my desktop is 4, so I just hardcoded that).

### Edit 1

Some performance data using `+RTS -H512m -N -sstderr -RTS`

is here:

`parMap`

to spark once for each core isn't a sure way to go - each element might take a different amount of work to compute. For example, in the trivial`fib`

implementation, the work increases significantly for each successive element, so placing the last`n`

elements in the same spark will result in very little parallelism. – Thomas M. DuBuisson May 11 '11 at 20:24