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.

`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`takeJusts maxJusts f = take maxJusts . catMaybes . map f`

except it evaluates the`f`

calls in parallel? – hammar Oct 18 '12 at 17:20