I've noticed that my code runs on 64 bit Linux much slower than on 32 bit Linux or 64 bit Window or 64 bit Mac. This is minimal test case.

#include <stdlib.h>

typedef unsigned char UINT8;

stretch(UINT8 * lineOut, UINT8 * lineIn, int xsize, float *kk)
    int xx, x;

    for (xx = 0; xx < xsize; xx++) {
        float ss = 0.0;
        for (x = 0; x < xsize; x++) {
            ss += lineIn[x] * kk[x];
        lineOut[xx] = (UINT8) ss;

main( int argc, char** argv )
    int i;
    int xsize = 2048;

    UINT8 *lineIn = calloc(xsize, sizeof(UINT8));
    UINT8 *lineOut = calloc(xsize, sizeof(UINT8));
    float *kk = calloc(xsize, sizeof(float));

    for (i = 0; i < 1024; i++) {
        stretch(lineOut, lineIn, xsize, kk);

    return 0;

And there is how it runs:

$ cc --version
cc (Ubuntu 4.8.2-19ubuntu1) 4.8.2
$ cc -O2 -Wall -m64 ./tt.c -o ./tt && time ./tt
user  14.166s
$ cc -O2 -Wall -m32 ./tt.c -o ./tt && time ./tt
user  5.018s

As you can see, 32 bit version runs almost 3 times faster (I've tested both on 32bit and 64bit Ubuntu, result the same). And even more strange what performance depends on C standard:

$ cc -O2 -Wall -std=c99 -m32 ./tt.c -o ./tt && time ./tt
user  15.825s
$ cc -O2 -Wall -std=gnu99 -m32 ./tt.c -o ./tt && time ./tt
user  5.090s

How can it be? How can I workaround this to speed up 64 bit version generated by GCC.

Update 1

I've compared assembler produced by fast 32 bit (default and gnu99) and slow (c99) and found following:

  movzbl    (%ebx,%eax), %edx   # MEM[base: lineIn_10(D), index: _72, offset: 0B], D.1543
  movl  %edx, (%esp)    # D.1543,
  fildl (%esp)  #
  fmuls (%esi,%eax,4)   # MEM[base: kk_18(D), index: _72, step: 4, offset: 0B]
  addl  $1, %eax    #, x
  cmpl  %ecx, %eax  # xsize, x
  faddp %st, %st(1) #,
  fstps 12(%esp)    #
  flds  12(%esp)    #
  jne   .L5 #,

There is no fstps and flds commands in fast case. So GCC stores and loads value from memory on each step. I've tried register float type, but this doesn't help.

Update 2

I've tested on gcc-4.9 and looks like it generates optimal code for 64 bit. And -ffast-math (suggested by @jch) fixes -m32 -std=c99 for both GCC versions. I'm still looking for solution for 64 bit on gcc-4.8, because it is more common version for now that 4.9.

  • A factor of 3 hints at auto-vectorization failing. Have a look at the -S assembly listing. – Hans Passant Oct 27 '14 at 11:04
  • @HansPassant No, "Vectorization is enabled by the flag -ftree-vectorize and by default at -O3". – homm Oct 27 '14 at 11:09
  • when running the program without gcc optimization, i got ~ execution time (user:0m14.349s(x86) VS 0m14.723s (x86_64)). GCC optimization failing?! – Bechir Oct 27 '14 at 11:11
  • Not relevant to the problem, but in the interest of being informational: you can't define a function called stretch(), all public function names starting with str are reserved. – unwind Oct 27 '14 at 11:25
  • 1
    Have you checked that the version of libc6, as compiled for a 64 bit architecture, is being used for the 64bit versions of the compile? – user3629249 Oct 28 '14 at 1:23

There is a partial dependency stall in the code generated by older versions of GCC.

movzbl (%rsi,%rax), %r8d
cvtsi2ss %r8d, %xmm0  ;; all upper bits in %xmm0 are false dependency

The dependency can be broken by xorps.

#ifdef __SSE__
float __attribute__((always_inline)) i2f(int v) {
    float x;
    __asm__("xorps %0, %0; cvtsi2ss %1, %0" : "=x"(x) : "r"(v) );
    return x;
float __attribute__((always_inline)) i2f(int v) { return (float) v; }

void stretch(UINT8* lineOut, UINT8* lineIn, int xsize, float *kk)
    int xx, x;

    for (xx = 0; xx < xsize; xx++) {
        float ss = 0.0;
        for (x = 0; x < xsize; x++) {
            ss += i2f(lineIn[x]) * kk[x];
        lineOut[xx] = (UINT8) ss;


$ cc -O2 -Wall -m64 ./test.c -o ./test64 && time ./test64
./test64  4.07s user 0.00s system 99% cpu 4.070 total
$ cc -O2 -Wall -m32 ./test.c -o ./test32 && time ./test32
./test32  3.94s user 0.00s system 99% cpu 3.938 total
  • Wow, this works in my project, not only in test case. Only question is: how is this code cross-platform? Can always_inline break any compillers? Is all x86 64 bit target CPUs has __SSE__ flag during compilation? Also I've noticed that i2f should be static. – homm Oct 27 '14 at 13:20
  • @homm well, I guess if you guard it with right ifdefs (which I unfortunately can't tell you from the top of my head) it will be crossplatform :) I expect this already to build just fine on Mac/Linux with GCC and clang (even though clang does not really need this hack, it breaks dependency by itself). You will need to change __attribute__ in #else-branch to __forceinline for MSVC but otherwise it should still work because MSVC does not define __SSE__. – Vyacheslav Egorov Oct 27 '14 at 13:28
  • If I were to include this code into my project I'd probably write it like this #if (GCC_VERSION < 40900) && defined(__SSE__) – Vyacheslav Egorov Oct 27 '14 at 13:31
  • Note that on systems that have an older gcc, there may also be an assembler that doesn't know about these instructions. I got libImaging/ImagingUtils.h:40: Error: operand type mismatch for 'xorps' libImaging/ImagingUtils.h:40: Error: operand type mismatch for 'cvtsi2ss' for code in the py-Pillow package that apparently picked up this trick. – Rhialto supports Monica Jan 13 '18 at 15:15
  • the original code contained mistake, which caused the error you have seen @Rhialto, instead of =X it should have said =x. wrong register contraint. – Vyacheslav Egorov Apr 2 '18 at 13:46

Here is what I tried: I declared ss as volatile. This prevented the compiler from doing optimizations on it. I got similar times for both 32 and 64 bit versions.

64bit was slightly slower but this is normal because 64bit code is larger and the uCode cache has a finite size. So in general 64bit should be very slightly slower than 32 (<3-4%).

Getting back to the problem, I think that in 32bit mode the compiler makes more aggressive optimizations on ss.

Update 1:

Looking at the 64bit code, it generates a CVTTSS2SI instruction, paired with a CVTSI2SS instruction for float to integer conversion. This has a higher latency. The 32bit code just uses a FMULS instruction, operating directly on floats. Need to look for a compiler option to prevent these conversions.

  • I can't declare it as int, I need float there. – homm Oct 27 '14 at 11:39

In 32 bit mode, the compiler is making extra efforts to preserve strict IEEE 754 floating point semantics. You can avoid this by compiling with -ffast-math:

$ gcc -m32 -O2 -std=c99 test.c && time ./a.out 

real    0m13.869s
user    0m13.884s
sys     0m0.000s
$ gcc -m32 -O2 -std=c99 -ffast-math test.c && time ./a.out 

real    0m4.477s
user    0m4.480s
sys     0m0.000s

I cannot reproduce your results in 64-bit mode, but I'm pretty confident that -ffast-math will solve your issues. More generally, unless you really need reproducible IEEE 754 rounding behaviour, -ffast-math is what you want.

  • I suppose you're on gcc-4.9, looks like it generates fast code for 64 bit, but still slow for -std=c99 without -ffast-math. On gcc-4.8 fast math doesn't help for -m64. But your answer is still most helpful. Thanks! – homm Oct 27 '14 at 12:36
  • Yes, you're right. I can reproduce your results with gcc-4.8, and indeed, neither -ffast-math nor -march=corei7 solves the issue. – jch Oct 27 '14 at 12:40

Looks like a case for restrict. The three arrays can't overlap, can they?


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