I've been learning some Haskell by implementing a feature selection algorithm.
I've gotten the performance from 20s on a benchmark dataset down to 5s, where the C program handles the same dataset in 0.5s. The dataset can be found here. To run, call the compiled binary like so:
./Mrmr 10 test_nci9_s3.csv.
The code is here, and I'm interested in optimizing mutualInfoInnerLoop:
mutualInfoInnerLoop :: Double -> Data.Vector.Unboxed.Vector (Int, Int) -> Double -> (Int, Int, Double) -> Double mutualInfoInnerLoop n xys !acc (!i, !j, !px_py) | n == 0 || px_py == 0 || pxy == 0 = acc | otherwise = pxy * logBase 2 ( pxy / px_py ) + acc where pxy = ( fromIntegral . U.foldl' accumEq2 0 $ xys ) / n accumEq2 :: Int -> (Int, Int) -> Int accumEq2 !acc (!i', !j') | i' == i && j' == j = acc + 1 | otherwise = acc
The profiler says:
COST CENTRE MODULE %time %alloc mutualInfoInnerLoop Main 75.0 47.9 mutualInfo Main 14.7 32.1 parseCsv Main 5.9 13.1 CAF GHC.Float 1.5 0.0 readInt Main 1.5 1.2 doMrmr Main 1.5 4.0
Which shows mutualInfoInnerLoop as making 50% of the allocations, with 75% of the runtime in the program. The allocations are disconcerting.
Also, the Core for that function has a signature:
mutualInfoInnerLoop_rXG :: GHC.Types.Double -> Data.Vector.Unboxed.Base.Vector (GHC.Types.Int, GHC.Types.Int) -> GHC.Types.Double -> (GHC.Types.Int, GHC.Types.Int, GHC.Types.Double) -> GHC.Types.Double [GblId, Arity=4, Caf=NoCafRefs, Str=DmdType U(L)LU(L)U(U(L)U(L)U(L))m]
Showing most of the parameters as being Lazily evaluated and boxed (as opposed to strict and unboxed).
I've tried BangPatterns, I've tried MagicHash, and I can't seem to make it go faster.
Anyone have any suggestions?