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The Question

I have a finite list of values:

values :: [A]

... and an expensive, but pure, function on those values:

expensiveFunction :: A -> Maybe B

How do I run that function on each value in parallel and only return the first n results that complete with a Just and stop computation of the unfinished results?

takeJustsPar :: (NFData b) => Int -> (a -> Maybe b) -> [a] -> [b]
takeJustsPar maxJusts f as = ???

The Motivation

I know how I would do this using Control.Concurrent, but I wanted to experiment using Haskell's parallelism features. Also, the (scant) literature I could find seems to indicate that Haskell's parallelism features make it cheaper to spawn parallel computations and adapt the workload among the number of capabilities.

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@hammar Thanks for pointing out the obvious flaw in my question. I updated the question to reflect the fact that the results are still ordered, but a simple take of the original list will not work since the criterion for inclusion in the output is the result of the computation (a Just if it succeeds and Nothing if it failed). –  Gabriel Gonzalez Oct 18 '12 at 17:11
Ok, so the function you want is equivalent to takeJusts maxJusts f = take maxJusts . catMaybes . map f except it evaluates the f calls in parallel? –  hammar Oct 18 '12 at 17:20
@hammar That's right. –  Gabriel Gonzalez Oct 18 '12 at 17:21
You probably also want to prioritize the earlier computations then, since those are more likely to make it into the result. –  hammar Oct 18 '12 at 17:28
@hammar So perhaps I should just chunk the list and compute in parallel each chunk, then update the accumulator after each chunk to reflect how many result I still need and keep going if it's non-zero. I think I can figure out the rest from here and answer my own question. –  Gabriel Gonzalez Oct 18 '12 at 17:30

1 Answer 1

up vote 4 down vote accepted

I attempted two solutions. The first uses the Par monad (i.e. Control.Monad.Par):

import Control.Monad.Par (Par, NFData)
import Control.Monad.Par.Combinator (parMap)
import Data.Maybe (catMaybes)
import Data.List.Split (chunksOf)

takeJustsPar :: (NFData b) => Int -> Int -> (a -> Maybe b) -> [a] -> Par [b]
takeJustsPar n chunkSize f as = go n (chunksOf chunkSize as) where
    go _ [] = return []
    go 0 _  = return []
    go numNeeded (chunk:chunks) = do
        evaluatedChunk <- parMap f chunk
        let results      = catMaybes evaluatedChunk
            numFound     = length results
            numRemaining = numNeeded - numFound
        fmap (results ++) $ go numRemaining chunks

The second attempt used Control.Parallel.Strategies:

import Control.Parallel.Strategies
import Data.List.Split (chunksOf)

chunkPar :: (NFData a) => Int -> Int -> [a] -> [a]
chunkPar innerSize outerSize as
  = concat ((chunksOf innerSize as) `using` (parBuffer outerSize rdeepseq))

The latter one ended up being MUCH more composable, since I could just write:

take n $ catMaybes $ chunkPar 1000 10 $ map expensiveFunction xs

... rather than baking in the take and catMaybes behavior into the parallelism strategy.

The latter solution also gives nearly perfect utilization. On the embarrassingly parallel problem I tested it on, it gave 99% utilization for 8 cores. I didn't test the utilization of the Par monad because I was borrowing a colleague's computer and didn't want to waste their time when I was satisfied with the performance of Control.Parallel.Strategies.

So the answer is to use Control.Parallel.Strategies, which gives much more composable behavior and great multi-core utilization.

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