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I'm currently learning Haskell using the project Euler problems as my playground. I was astound by how slow my Haskell programs turned out to be compared to similar programs written in other languages. I'm wondering if I've forseen something, or if this is the kind of performance penalties one has to expect when using Haskell.

The following program in inspired by Problem 331, but I've changed it before posting so I don't spoil anything for other people. It computes the arc length of a discrete circle drawn on a 2^30 x 2^30 grid. It is a simple tail recursive implementation and I make sure that the updates of the accumulation variable keeping track of the arc length is strict. Yet it takes almost one and a half minute to complete (compiled with the -O flag with ghc).

import Data.Int

arcLength :: Int64->Int64
arcLength n = arcLength' 0 (n-1) 0 0 where
    arcLength' x y norm2 acc
        | x > y = acc
        | norm2 < 0 = arcLength' (x + 1) y (norm2 + 2*x +1) acc
        | norm2 > 2*(n-1) = arcLength' (x - 1) (y-1) (norm2 - 2*(x + y) + 2) acc
        | otherwise = arcLength' (x + 1) y (norm2 + 2*x + 1) $! (acc + 1)

main = print $ arcLength (2^30)

Here is a corresponding implementation in Java. It takes about 4.5 seconds to complete.

public class ArcLength {
public static void main(String args[]) {
    long n = 1 << 30;
    long x = 0;
    long y = n-1;
    long acc = 0;
    long norm2 = 0;
    long time = System.currentTimeMillis();

    while(x <= y) {
        if (norm2 < 0) {
            norm2 += 2*x + 1;
        } else if (norm2 > 2*(n-1)) {
            norm2 += 2 - 2*(x+y);
        } else {
            norm2 += 2*x + 1;

    time = System.currentTimeMillis() - time;


EDIT: After the discussions in the comments I made som modifications in the Haskell code and did some performance tests. First I changed n to 2^29 to avoid overflows. Then I tried 6 different version: With Int64 or Int and with bangs before either norm2 or both and norm2 and acc in the declaration arcLength' x y !norm2 !acc. All are compiled with

ghc -O3 -prof -rtsopts -fforce-recomp -XBangPatterns arctest.hs

Here are the results:

(Int !norm2 !acc)
total time  =        3.00 secs   (150 ticks @ 20 ms)
total alloc =       2,892 bytes  (excludes profiling overheads)

(Int norm2 !acc)
total time  =        3.56 secs   (178 ticks @ 20 ms)
total alloc =       2,892 bytes  (excludes profiling overheads)

(Int norm2 acc)
total time  =        3.56 secs   (178 ticks @ 20 ms)
total alloc =       2,892 bytes  (excludes profiling overheads)

(Int64 norm2 acc)
arctest.exe: out of memory

(Int64 norm2 !acc)
total time  =       48.46 secs   (2423 ticks @ 20 ms)
total alloc = 26,246,173,228 bytes  (excludes profiling overheads)

(Int64 !norm2 !acc)
total time  =       31.46 secs   (1573 ticks @ 20 ms)
total alloc =       3,032 bytes  (excludes profiling overheads)

I'm using GHC 7.0.2 under a 64-bit Windows 7 (The Haskell platform binary distribution). According to the comments, the problem does not occur when compiling under other configurations. This makes me think that the Int64 type is broken in the Windows release.

share|improve this question
Did you tried a bang pattern? arcLength' x y !norm2 !acc? norm2 and acc are not always passed stricly because they might not needed when the first branch is taken. BTW, it takes only 6 secs on my machine. –  FUZxxl Apr 30 '11 at 12:14
Generally, Haskell can be one of the faster languages around. There's propably something in your Haskell code that causes worse complexity or doesn't play nice with GHC's optimizations. –  delnan Apr 30 '11 at 12:15
-O2 is the typical flag for GHC optimization. -O doesn't do too much, iirc. –  Thomas M. DuBuisson Apr 30 '11 at 15:10
The comments seem to suggest this is a bug related to GHC 7.0.2 and 64 bit GMP (where the Int64 type comes from) on 32 bit Windows. Can you either upgrade the libgmp, upgrade GHC to 7.0.3 or test on 64 bit Windows? –  Don Stewart Apr 30 '11 at 16:32
I get the same behaviour on GHC 7.0.3. I'm also running on 64 bit Windows. But I suspect that the binary distribution of the Haskell platform is 32-bit. There weren't any 64-downloads. –  dbergh Apr 30 '11 at 17:01

6 Answers 6

up vote 9 down vote accepted

Hm, I installed a fresh Haskell platform with 7.0.3, and get roughly the following core for your program (-ddump-simpl):

Main.$warcLength' =
  \ (ww_s1my :: GHC.Prim.Int64#) (ww1_s1mC :: GHC.Prim.Int64#)
    (ww2_s1mG :: GHC.Prim.Int64#) (ww3_s1mK :: GHC.Prim.Int64#) ->
    case {__pkg_ccall ghc-prim hs_gtInt64 [...]
           ww_s1my ww1_s1mC GHC.Prim.realWorld#

So GHC has realized that it can unpack your integers, which is good. But this hs_getInt64 call looks suspiciously like a C call. Looking at the assembler output (-ddump-asm), we see stuff like:

pushl %eax
movl 76(%esp),%eax
pushl %eax
call _hs_gtInt64
addl $16,%esp

So this looks very much like every operation on the Int64 get turned into a full-blown C call in the backend. Which is slow, obviously.

The source code of GHC.IntWord64 seems to verify that: In a 32-bit build (like the one currently shipped with the platform), you will have only emulation via the FFI interface.

share|improve this answer
That's right. On a 32 bit machine Int64 is implemented via the C GMP library. It will have some performance overhead. On a 64 bit machine, no such problems. –  Don Stewart Apr 30 '11 at 17:15
I guess that settles it. Thanks! I also guess it isn't enough to have a 64-bit machine if you have Windows, since there is no 64-bit GHC for windows (hackage.haskell.org/trac/ghc/wiki/WindowsGhc). –  dbergh Apr 30 '11 at 17:38
And you will get the same degradation using Integer instead (which is also implemented as a C call into libgmp). –  Don Stewart Apr 30 '11 at 18:45

Hmm, this is interesting. So I just compiled both of your programs, and tried them out:

% java -version                                                                                          
java version "1.6.0_18"
OpenJDK Runtime Environment (IcedTea6 1.8.7) (6b18-1.8.7-2~squeeze1)
OpenJDK 64-Bit Server VM (build 14.0-b16, mixed mode)
% javac ArcLength.java                                                                                   
% java ArcLength                                                                                         

So about 6.6 seconds for the Java solution. Next is ghc with some optimization:

% ghc --version                                                                                          
The Glorious Glasgow Haskell Compilation System, version 6.12.1
% ghc --make -O arc.hs
% time ./arc                                                                                             
./arc  12.68s user 0.04s system 99% cpu 12.718 total

Just under 13 seconds for ghc -O

Trying with some further optimization:

% ghc --make -O3
% time ./arc                                                                                             [13:16]
./arc  5.75s user 0.00s system 99% cpu 5.754 total

With further optimization flags, the haskell solution took under 6 seconds

It would be interesting to know what version compiler you are using.

share|improve this answer
Same for me. Things got faster when I changed Int64 to Int and added an explicit type signature to the inner worker. I am on x64, ghc 7.0.3 –  FUZxxl Apr 30 '11 at 12:35
I use ghc under windows. ghc --version The Glorious Glasgow Haskell Compilation System, version 7.0.2 –  dbergh Apr 30 '11 at 12:55
I see the same slowness with Int64 when compiled by 32 bit version of GHC 7.0.2 and the same <5 sec time when compiled with x64 version (7.0.3 though). Btw -fllvm option seems to speed up 32 bit version of this (not sure how it would behave with x64 since it ignores -fllvm in x64 GHC on MacOS) –  Ed'ka Apr 30 '11 at 14:38
Hmm, when compiled without -O3 I had killed it after a minute or so, so the optimization done by -O3 here is HUGE. –  Palmik Apr 30 '11 at 15:12
Hmmm, I find it kind of disappointing that randomly cluttering the code with exclamaition marks have such a big impact. But to me it seems that the real issue is that the implementation of the 64-bit arithmetic is bad... According to my timings, using 64-bit integers almost increases the execution time by a factor 10. –  dbergh Apr 30 '11 at 16:42

There's a couple of interesting things in your question.

You should be using -O2 primarily. It will just do a better job (in this case, identifying and removing laziness that was still present in the -O version).

Secondly, your Haskell isn't quite the same as the Java (it does different tests and branches). As with others, running your code on my Linux box results in around 6s runtime. It seems fine.

Make sure it is the same as the Java

One idea: let's do a literal transcription of your Java, with the same control flow, operations and types.

import Data.Bits
import Data.Int

loop :: Int -> Int
loop n = go 0 (n-1) 0 0
        go :: Int -> Int -> Int -> Int -> Int
        go x y acc norm2
            | x <= y        = case () of { _
                | norm2 < 0         -> go (x+1) y     acc     (norm2 + 2*x + 1)
                | norm2 > 2 * (n-1) -> go (x-1) (y-1) acc     (norm2 + 2 - 2 * (x+y))
                | otherwise         -> go (x+1) y     (acc+1) (norm2 + 2*x + 1)
            | otherwise     = acc

main = print $ loop (1 `shiftL` 30)

Peek at the core

We'll take a quick peek at the Core, using ghc-core, and it shows a very nice loop of unboxed type:

  :: Int#
     -> Int#
     -> Int#
     -> Int#
     -> Int#

main_$s$wgo =
  \ (sc_sQa :: Int#)
    (sc1_sQb :: Int#)
    (sc2_sQc :: Int#)
    (sc3_sQd :: Int#) ->
    case <=# sc3_sQd sc2_sQc of _ {
      False -> sc1_sQb;
      True ->
        case <# sc_sQa 0 of _ {
          False ->
            case ># sc_sQa 2147483646 of _ {
              False ->
                  (+# (+# sc_sQa (*# 2 sc3_sQd)) 1)
                  (+# sc1_sQb 1)
                      (+# sc3_sQd 1);
              True ->
                     (+# sc_sQa 2)
                     (*# 2 (+# sc3_sQd sc2_sQc)))
                  (-# sc2_sQc 1)
                  (-# sc3_sQd 1)
          True ->
              (+# (+# sc_sQa (*# 2 sc3_sQd)) 1)
              (+# sc3_sQd 1)

that is, all unboxed into registers. That loop looks great!

And performs just fine (Linux/x86-64/GHC 7.03):

./A  5.95s user 0.01s system 99% cpu 5.980 total

Checking the asm

We get reasonable assembly too, as a nice loop:

        cmpq    %rdi, %r8
        jg      .L8
        testq   %r14, %r14
        movq    %r14, %rdx
        js      .L4
        cmpq    $2147483646, %r14
        jle     .L9
        leaq    (%rdi,%r8), %r10
        addq    $2, %rdx
        leaq    -1(%rdi), %rdi
        addq    %r10, %r10
        movq    %rdx, %r14
        leaq    -1(%r8), %r8
        subq    %r10, %r14
        jmp     Main_mainzuzdszdwgo_info
        leaq    1(%r14,%r8,2), %r14
        addq    $1, %rsi
        leaq    1(%r8), %r8
        jmp     Main_mainzuzdszdwgo_info
        movq    %rsi, %rbx
        jmp     *0(%rbp)
        leaq    1(%r14,%r8,2), %r14
        leaq    1(%r8), %r8
        jmp     Main_mainzuzdszdwgo_info

Using the -fvia-C backend.

So this looks fine!

My suspicion, as mentioned in the comment above, is something to do with the version of libgmp you have on 32 bit Windows generating poor code for 64 bit ints. First try upgrading to GHC 7.0.3, and then try some of the other code generator backends, then if you still have an issue with Int64, file a bug report to GHC trac.

Broadly confirming that it is indeed the cost of making those C calls in the 32 bit emulation of 64 bit ints, we can replace Int64 with Integer, which is implemented with C calls to GMP on every machine, and indeed, runtime goes from 3s to well over a minute.

Lesson: use hardware 64 bits if at all possible.

share|improve this answer
Not always possible. Haskell can't compile to 64bit code under windows, so this is not always an option. –  FUZxxl Apr 30 '11 at 21:17
How do you get such clean core output? –  FUZxxl Apr 30 '11 at 22:38
Using ghc-core, which you can get here: hackage.haskell.org/package/ghc-core –  Don Stewart Apr 30 '11 at 22:38
What does this program? –  FUZxxl Apr 30 '11 at 22:40

The normal optimization flag for performance concerned code is -O2. What you used, -O, does very little. -O3 doesn't do much (any?) more than -O2 - it even used to include experimental "optimizations" that often made programs notably slower.

With -O2 I get performance competitive with Java:

tommd@Mavlo:Test$ uname -r -m
2.6.37 x86_64
tommd@Mavlo:Test$ ghc --version
The Glorious Glasgow Haskell Compilation System, version 7.0.3

tommd@Mavlo:Test$ ghc -O2 so.hs
[1 of 1] Compiling Main             ( so.hs, so.o )
Linking so ...
tommd@Mavlo:Test$ time ./so

real    0m4.948s
user    0m4.896s
sys     0m0.000s

And Java is about 1 second faster (20%):

tommd@Mavlo:Test$ time java ArcLength

real    0m3.961s
user    0m3.936s
sys     0m0.024s

But an interesting thing about GHC is it has many different backends. By default it uses the native code generator (NCG), which we timed above. There's also an LLVM backend that often does better... but not here:

tommd@Mavlo:Test$ ghc -O2 so.hs -fllvm -fforce-recomp
[1 of 1] Compiling Main             ( so.hs, so.o )
Linking so ...
tommd@Mavlo:Test$ time ./so

real    0m5.973s
user    0m5.968s
sys     0m0.000s

But, as FUZxxl mentioned in the comments, LLVM does much better when you add a few strictness annotations:

$ ghc -O2 -fllvm -fforce-recomp so.hs
[1 of 1] Compiling Main             ( so.hs, so.o )
Linking so ...
tommd@Mavlo:Test$ time ./so

real    0m4.099s
user    0m4.088s
sys     0m0.000s

There's also an old "via-c" generator that uses C as an intermediate language. It does well in this case:

tommd@Mavlo:Test$ ghc -O2 so.hs -fvia-c -fforce-recomp
[1 of 1] Compiling Main             ( so.hs, so.o )

on the commandline:
    Warning: The -fvia-c flag will be removed in a future GHC release
Linking so ...
ttommd@Mavlo:Test$ ti
tommd@Mavlo:Test$ time ./so

real    0m3.982s
user    0m3.972s
sys     0m0.000s

Hopefully the NCG will be improved to match via-c for this case before they remove this backend.

share|improve this answer
When you add a bang patterns at the parameter norm2 in arcLength', the llvm backend does a much better job, because norm2 is not strict by default. –  FUZxxl Apr 30 '11 at 16:18
Ah! And you have to add a bang at arcLength !n, too. –  FUZxxl Apr 30 '11 at 16:25
Right you are! I'll edit the answer. –  Thomas M. DuBuisson Apr 30 '11 at 16:49

dberg, I feel like all of this got off to a bad start with the unfortunate -O flag. Just to emphasize a point made by others, for run-of-the-mill compilation and testing, do like me and paste this into your .bashrc or whatever:

alias ggg="ghc --make -O2"
alias gggg="echo 'Glorious Glasgow for Great Good!' && ghc --make -O2 --fforce-recomp"
share|improve this answer

I've played with the code a little and this version seems to run faster than Java version on my laptop (3.55s vs 4.63s):

{-# LANGUAGE BangPatterns #-}

arcLength :: Int->Int
arcLength n = arcLength' 0 (n-1) 0 0 where
    arcLength' :: Int -> Int -> Int -> Int -> Int
    arcLength' !x !y !norm2 !acc
        | x > y = acc
        | norm2 > 2*(n-1) = arcLength' (x - 1) (y - 1) (norm2 - 2*(x + y) + 2) acc
        | norm2 < 0 = arcLength' (succ x) y (norm2 + x*2 + 1) acc
        | otherwise = arcLength' (succ x) y (norm2 + 2*x + 1) (acc + 1)      

main = print $ arcLength (2^30)


$ ghc -O2 tmp1.hs -fforce-recomp
[1 of 1] Compiling Main             ( tmp1.hs, tmp1.o )
Linking tmp1 ...

$ time ./tmp1

real    0m3.553s
user    0m3.539s
sys 0m0.006s
share|improve this answer
I compiled the Java version with gcj on my machine and it run in 3.5 secs as opposed to haskell, which runs in 6 secs. The JVM makes the code slower. –  FUZxxl Apr 30 '11 at 21:15
@FUZxxl I can't try gcj, but c++ (gcc -O3) version runs here in 2.1s ( vs my ghc's 3.5s - not that bad). Not sure why you're getting 6s with my version, nor can I explain why changing x+1 to succ x makes such a big difference here (5.3s vs 3.6). –  Ed'ka May 1 '11 at 1:12
Me too. Mybe my machine is less powerful. On my machine, I got about 2.8 secs for plain C, and 3.5 secs for Java. –  FUZxxl May 1 '11 at 9:18

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