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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
        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:

  :: 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
 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?

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I guess you have tried ghc -O2 already? –  J Fritsch Dec 11 '11 at 18:05
Yes, I have. The source is also annotated with {-# LANGUAGE BangPatterns #-} and {-# OPTIONS_GHC -O2 -fexcess-precision -funbox-strict-fields #-} –  LanceH Dec 11 '11 at 18:11
Can you provide the Int and file you use for benchmarking? –  Thomas M. DuBuisson Dec 11 '11 at 18:29
The core is unsurprising. You've annotated mutualInfoInnerLoop as NOINLINE, so GHC won't inline it. As a consequence, none of the arguments can be unboxed. What happens if you change that NOINLINE to INLINE? –  John L Dec 11 '11 at 19:17
If the idea is to meet or beat the C code then we need that too. –  Thomas M. DuBuisson Dec 11 '11 at 23:02

1 Answer 1

I'm by far no expert at this, but I do see one small improvement. In your source I see this:

mutualInfo n ... = foldl' (mutualInfoInnerLoop n $ U.zip xs ys) ...

You don't need to check n == 0 every single time the function is invoked, since you never change the n argument when you invoke it. The xys argument doesn't change, either, meaning that pxy does not change across invocations, since it depends solely on xys and n. Let's take advantage of these things to make sure a closure is created which evaluates these things only once.

mutualInfoInnerLoop n xys
  | n == 0 || pxy == 0 = const
  | otherwise          = go
  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
        go !acc (!i, !j, !px_py)
          | px_py == 0 = acc
          | otherwise  = pxy * logBase 2 ( pxy / px_py ) + acc

I'm not sure if GHC is smart enough to perform this optimization on its own, nor am I sure this saves much time/space, but it's the best I've got. With those bang patterns sprinkled all over, I wonder if this is a case of too much strictness.

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Excellent suggestion! I actually ended up moving the n == 0 into doMrmr, seemed like a good idea. As for this construction though, without unpacking i or j we can't construct accumEq2 -- which makes me wonder if the dynamically-constructed nature of accumEq2 is the problem. –  LanceH Dec 11 '11 at 23:58
Actually, all those bang patterns seem to help, shave off a half-second (we're actually at around 4s). –  LanceH Dec 12 '11 at 0:11
Oh I forgot i and j are used in accumEq2. My bad. –  Dan Burton Dec 12 '11 at 0:19

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