# Why does Haskell perform so poorly when executing C-like codes? (in this instance at least)

I am trying to figure out some performance issues I have been having with Haskell. As part of that, I have written a small comparison program to compare C and Haskell. Specifically, I translated the C program to Haskell with as few changes as I could. The speed-measured part of the Haskell program is then written in a very imperative style.

The program makes two list of random numbers in some range, and then calculates the integral of the graph formed by simply connecting those points, with one list being x-values and one list being y-values. Essentially, it is the trapezoidal rule.

Here are the two codes:

main.c

``````#include <stdio.h>
#include <stdlib.h>
#include <time.h>

#define N 5000000
#define maxY 1e5f/N
#define maxXgap 1

int main(){
int i;
float *y, *x;
float xaccum, area;
clock_t begin, end;
double time_spent;

y = (float*)malloc(sizeof(float)*N);
x = (float*)malloc(sizeof(float)*N);

srand(50546345); // change seed for different numbers

//populate y and x fields with random points
for(i = 0; i < N; i++){
y[i] = ((float)rand())/((float)RAND_MAX)*maxY;
}
xaccum = 0;
for(i = 0; i < N; i++){
x[i] = xaccum;
xaccum += ((float)rand())/((float)RAND_MAX)*maxXgap;
}
begin = clock();
//perform a trapezoidal integration using the x y coordinates
area = 0;
for(i = 0; i < N-1; i++){
area += (y[i+1]+y[i])/2*(x[i+1]-x[i]);
}
end = clock();
time_spent = (double)(end - begin) / CLOCKS_PER_SEC * 1000;
printf("%i points\n%f area\n%f ms\n", N, area, time_spent);
}
``````

Main.hs

``````{-# LANGUAGE BangPatterns #-}
module Main where

import Data.Array.Unboxed
import Data.Array.IO
import Data.List
import System.Random
import System.CPUTime
import Text.Printf
import Control.Exception

main :: IO ()
main = do
(x,y) <- initArrays
area <- time \$ integrate x y
print area

n :: Int
n = 5000000

maxY :: Float
maxY = 100000.0/(fromIntegral n)

maxXgap :: Float
maxXgap = 1

--initialize arrays with random floats
--this part is not measured in the running time (very slow)
initArrays :: IO (IOUArray Int Float, IOUArray Int Float)
initArrays = do
y <- newListArray (0,n-1) (randomList maxY n (mkStdGen 23432))
x <- newListArray (0,n-1) (scanl1 (+) \$ randomList maxXgap n (mkStdGen 5462))
return (x,y)

randomList :: Float -> Int -> StdGen -> [Float]
randomList max n gen = map (abs . ((*) max)) (take n . unfoldr (Just . random) \$ gen)

integrate :: IOUArray Int Float -> IOUArray Int Float -> IO Float
integrate x y = iterative x y 0 0

iterative :: IOUArray Int Float -> IOUArray Int Float -> Int -> Float -> IO Float
iterative x y !i !accum = do if i == n-1
then return accum
else do x1 <- readArray x i
iterative x y (i+1) (accum + (y2+y1)/2*(x2-x1))

time :: IO t -> IO t
time a = do
start <- getCPUTime
v <- a
end <- getCPUTime
let diff = (fromIntegral (end-start)) / (10^9)
printf "Computation time %0.5f ms\n" (diff :: Double)
return v
``````

The C integration runs in about 7 ms and the Haskell integration in about 60 ms on my system. Of course the Haskell version will be slower, but I am wondering why it is this much slower. Obviously there is a lot of inefficiency in the Haskell code.

Why is the Haskell code so much slower? How could one fix it?

-

Out of curiosity, I ran this with llvm:

ghc Test.hs -O2 -XBangPatterns -fllvm -optlo-O3

and it took it down from 60ms to 24ms. Still not ideal.

So, one of the first things I'll do when I want to know why a benchmark like this is so slow, is dump the prepared core. That is, the core after optimisations.

ghc Test.hs -O2 -ddump-prep -dsuppress-all -XBangPatterns > Test.hscore

After looking through the core, I eventually found \$wa, where the iterative loop is defined. It turns out it's making surprisingly many index bound checks. See, I usually use Data.Vector.Unboxed, which has "unsafeRead" and "unsafeIndex" functions, to remove bounds checks. These would be useful here. Personally, I think the vector package is superior.

If you look at \$wa, you'll notice it's unboxing the arguments at the start:

``````case w_s3o9 of _ { STUArray l_s3of u_s3oi ds1_s3ol ds2_s3oH ->
case l_s3of of wild2_s3os { I# m_s3oo ->
case u_s3oi of wild3_s3ot { I# n1_s3ov ->
case ds1_s3ol of wild4_s3oC { I# y1_s3oE ->
``````

this looks bad, but it turns out in the recursive call it's using a specialised version, integrate_\$s\$wa, with unboxed integers etc. This is good.

In summary, I think you should get a good improvement by using vector with unsafe indexing.

Edit: here is a modified version with Data.Vector. It runs in about 7ms. For good vector code, I think the only slowness compared to C should be due to incomplete alias analysis. https://gist.github.com/amosr/6026995

-
The `array` package has `unsafeRead` and `unsafeWrite` too, there's no need to switch to `vector` for that. –  Daniel Fischer Jul 18 '13 at 12:43
Oh, okay. I had a quick look but couldn't see them. Obviously too quick –  Amos Robinson Jul 18 '13 at 14:31
@DanielFischer I do not see those methods in the MArray interface. Can they really be implemented when the arrays can be indexed by any element implementing `Ix`? –  Eric Thoma Jul 19 '13 at 17:43
@EricThoma They're available from `Data.Array.Base`. For some unfathomable reason, somebody decided not to have Haddock docs for that, and not to export them from another, documented, module. I tend to forget that they're not documented, because I use them all the time. They both take `Int` indices (0-based). –  Daniel Fischer Jul 19 '13 at 17:49

First, I tried your code to reproduce your findings (using GHC 7.6.3 -O2 -fllvm and gcc 4.7.2 and -O3)

``````\$ ./theHaskellVersion-rev1
Computation time 24.00000 ms
25008.195
[tommd@Vodka Test]\$ ./theCVersion
5000000 points
25013.105469 area
10.000000 ms
``````

So we are aiming for 10ms if the goal is to perform on par (a 60% reduction in runtime). Looking at your code I see:

• `Array`s are used, which are ancient and cludgy. I switched to `Vector`.
• There is no worker/wrapper transformation on `iterative`. The change is just to make an auxillary function in a where clause that doesn't require `x` and `y` as parameters.
• `Float` is used even though `Double` often performs surprisingly better (this probably doesn't matter here).

The end result is on-par with what you posted in C:

``````\$ ghc -O2 so.hs -hide-package random && ./so
Computation time 11.00000 ms
24999.048783785303
``````
-
A few minor points: the worker/wrapper on iterative doesn't matter much, since I suspect SpecConstr (a generalisation of w/w) will do that anyway. I also think you need a seq in iterative in order to calculate the timing correctly –  Amos Robinson Jul 18 '13 at 6:15
How silly of me, teaches me to forget `\$!`. –  Thomas M. DuBuisson Jul 18 '13 at 6:20
Although you're right - writing it in a way that assures w/w will occur is probably better than praying for SpecConstr and other optimisations to do the right thing –  Amos Robinson Jul 18 '13 at 6:22