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I'm learning Haskell. My interest is to use it for personal computer experimentation. Right now, I'm trying to see how fast Haskell can get. Many claim parity with C(++), and if that is true, I would be very happy (I should note that I will be using Haskell whether or not it's fast, but fast is still a good thing).

My test program implements π(x) with a very simple algorithm: Primes numbers add 1 to the result. Prime numbers have no integer divisors between 1 and √x. This is not an algorithm battle, this is purely for compiler performance.

Haskell seems to be about 6x slower on my computer, which is fine (still 100x faster than pure Python), but that could be just because I'm a Haskell newbie.

Now, my question: How, without changing the algorithm, can I optimize the Haskell implementation? Is Haskell really on performance parity with C?

Here is my Haskell code:

import System.Environment

-- a simple integer square root
isqrt :: Int -> Int
isqrt = floor . sqrt . fromIntegral

-- primality test        
prime :: Int -> Bool
prime x = null [x | q <- [3, 5..isqrt x], rem x q == 0]

main = do
  n <- fmap (read . head) getArgs
  print $ length $ filter prime (2:[3, 5..n])

Here is my C++ code:

#include <iostream>
#include <cmath>
#include <cstdlib>
using namespace std;

bool isPrime(int);

int main(int argc, char* argv[]) {
    int primes = 10000, count = 0;
    if (argc > 1) {
        primes = atoi(argv[1]);
    }
    if (isPrime(2)) {
        count++;
    }
    for (int i = 3; i <= primes; i+=2) {
        if (isPrime(i)){
            count++;
        }
    }
    cout << count << endl;
    return 0;
}

bool isPrime(int x){
    for (int i = 2; i <= floor(sqrt(x)); i++) {
        if (x % i == 0) {
            return false;
        }
    }
    return true;
}
  • Did you compile your code with optimizations on? – bheklilr Feb 19 '14 at 22:49
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    You'll want to use -O2 when compiling with GHC. The LLVM bit shouldn't have much to do with it (not entirely sure, I've never used it being primarily a windows dev). – bheklilr Feb 19 '14 at 22:52
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    So you're comparing a functional programming system to an imperative one with explicit memory management, by running a program with no data structures or even any unpredictable branches. By the way, don't forget -fprofile-generate and -fprofile-use. – Potatoswatter Feb 19 '14 at 23:51
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    By the way, my eyes hurt when I see those sqrt/floor computations. To check if q <= sqrt(x) can be expressed q*q <= x So there you have it: one integer multiplication vs. several floaing point instructions. – Ingo Feb 20 '14 at 0:47
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    @Ingo: ... of which one is totally unnecessary (i <= floor (sqrt (x)) if and only if i <= sqrt (x)), and one is very expensive. And once x ≥ 2^53, things will go wrong. – gnasher729 Mar 30 '15 at 11:11
31

Your Haskell version is constructing a lazy list in prime only to test if it is null. This seems to indeed be a bottle neck. The following version runs just as fast as the C++ version on my machine:

prime :: Int -> Bool
prime x = go 3
  where
    go q | q <= isqrt x = if rem x q == 0 then False else go (q+2)
    go _  = True

3.31s when compiled with -O2 vs. 3.18s for C++ with gcc 4.8 and -O3 for n=5000000.

Of course, 'guessing' where the program is slow to optimize it is not a very good approach. Fortunately, Haskell has good profiling tools on board.

Compiling and running with

$ ghc --make primes.hs -O2 -prof -auto-all -fforce-recomp && ./primes 5000000 +RTS -p

gives

# primes.prof
  Thu Feb 20 00:49 2014 Time and Allocation Profiling Report  (Final)

     primes +RTS -p -RTS 5000000

  total time  =        5.71 secs   (5710 ticks @ 1000 us, 1 processor)
  total alloc = 259,580,976 bytes  (excludes profiling overheads)

COST CENTRE MODULE  %time %alloc

prime.go    Main     96.4    0.0
main        Main      2.0   84.6
isqrt       Main      0.9   15.4

                                                      individual     inherited
COST CENTRE MODULE                  no.     entries  %time %alloc   %time %alloc

MAIN        MAIN                     45           0    0.0    0.0   100.0  100.0
 main       Main                     91           0    2.0   84.6   100.0  100.0
  prime     Main                     92     2500000    0.7    0.0    98.0   15.4
   prime.go Main                     93   326103491   96.4    0.0    97.3   15.4
    isqrt   Main                     95           0    0.9   15.4     0.9   15.4

--- >8 ---

which clearly shows that prime is where things get hot. For more information on profiling, I'll refer you to Real World Haskell, Chap 25.

To really understand what is going on, you can look at (one of) GHC's intermediate languages Core, which will show you how the code looks like after optimization. Some good info is at the Haskell wiki. I would not recommend to do that unless necessary, but it is good to know that the possibility exists.

To your other questions:

1) How, without changing the algorithm, can I optimize the Haskell implementation?

Profile, and try to write inner loops so that they don't do any memory allocations and can be made strict by the compiler. Doing so can take some practice and experience.

2) Is Haskell really on performance parity with C?

That depends. GHC is amazing and can often optimize your program very well. If you know what you're doing you can usually get close to the performance of optimized C (100% - 200% of C's speed). That said, these optimizations are not always easy or pretty to the eye and high level Haskell can be slower. But don't forget that you're gaining amazing expressiveness and high level abstractions when using Haskell. It will usually be fast enough for all but the most performance critical applications and even then you can often get pretty close to C with some profiling and performance optimizations.

  • wow! Thanks for all of the information. (Esp. the profiling part). I did try a tail-recursive version, but it was really slow for some reason or other (I use multiple arguments to carry around variables). Is my C++ (4.8.2) just really fast? It's still a hair faster than 1.5x the speed of Haskell, though I'm pretty happy myself. I'm not giving up the expressiveness any time soon, I just wanted to see how much it hurt. :) I'll see if anyone else has anything to add... If not, yours is the accepted answer. – PythonNut Feb 20 '14 at 0:13
  • @PythonNut: If you run it with profiling enabled it will be slower of course. In my experience you can get pretty close (+50-100%), but parity can sometimes be hard / impossible to achieve. Depends on your experience, I am not the absolute expert here. What will stand between you and performance though is that these expressive languages can make it really tempting to use high level constructs that will not be as fast as a bare-bones loop. The lazy list is a case in point. Still, most of the time it doesn't matter and you're still getting good speed. – Paul Feb 20 '14 at 0:19
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    I think the issue with prime isn't the laziness as much as it is unboxing. With @Paul's prime, ghc produces an unboxed inner loop. With a lazy list the inner loop is very nice, but it works on boxed integers and therefore has to unbox them at each step. Incidentally, I get the same performance as the recursive prime by changing the original prime definition to use unboxed vectors instead of lists. – John L Feb 20 '14 at 0:26
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    Did you try V.null $ V.filter (\q -> rem x q == 0) $ V.iterateN (quot (isqrt x) 2) (+2) $ 3 instead ? seems you might win a little bit over generate. – Jedai Feb 22 '14 at 13:11
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    Checking with Criterion, the version with iterateN and the right number of element is as fast as the loop so V.null . V.filter ((== 0) . (rem x)) . V.iterateN ((isqrt x - 1) `quot` 2) (+2) $ 3 . – Jedai Feb 22 '14 at 15:23
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I dont think that the Haskell version (original and improved by first answer) are equivalent with the C++ version. The reason is this: Both only consider every second element (in the prime function), while the C++ version scans every element (only i++ in the isPrime() function.

When i fix this (change i++ to i+=2 in the isPrime() function for C++) i get down to almost 1/3 of the runtime of the optimized Haskell version (2.1s C++ vs 6s Haskell).

The output remains the same for both (of course). Note that this is no specific opimization of the C++ version ,just an adaptation of the trick already applied in the Haskell version.

  • Also i has to start from 3, same as in both Hasell versions. – Lazarus535 Mar 30 '15 at 10:20

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