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I am testing a simple code which calculates Mandelbrot fractal. I have been checking it's performance depending on the number of iterations in the function that checks if a point belongs to the Mandelbrot set or not. The surprising thing is that I am getting a big difference in times after adding the -fPIC flag. From what I read the overhead is usually negligible and the highest overhead I came across was about 6%. My is around 30%. Any advice will be appreciated!

Details of my project

I use the -O3 flag, gcc 4.7.2, Ubuntu 12.04.2, x86_64. The results look as follow

    #iter     C (fPIC)  C       C/C(fPIC)
    1         0.01      0.01    1.00 
    100       0.04      0.03    0.75 
    200       0.06      0.04    0.67 
    500       0.15      0.1     0.67 
    1000      0.28      0.19    0.68
    2000      0.56      0.37    0.66 
    4000      1.11      0.72    0.65 
    8000      2.21      1.47    0.67
   16000      4.42      2.88    0.65 
   32000      8.8       5.77    0.66 
   64000      17.6      11.53   0.66

Commands I use:

gcc -O3 -fPIC fractalMain.c fractal.c -o ffpic
gcc -O3 fractalMain.c fractal.c -o f

Code: fractalMain.c

#include <time.h>
#include <stdio.h>
#include <stdbool.h>
#include "fractal.h"

int main()
    int iterNumber[] = {1, 100, 200, 500, 1000, 2000, 4000, 8000, 16000, 32000, 64000};
    int it;
    for(it = 0; it < 11; ++it)
        clock_t start = clock();
        clock_t end = clock();
        double millis = (end - start)*1000 / CLOCKS_PER_SEC/(double)1000;
        printf("Iter: %d, time: %lf \n", iterNumber[it], millis);
    return 0;

Code: fractal.h

#ifndef FRACTAL_H
#define FRACTAL_H
    void fractal(int iter);

Code: fractal.c

#include <stdio.h>
#include <stdbool.h>
#include "fractal.h"

void multiplyComplex(double a_re, double a_im, double b_re, double b_im, double* res_re, double* res_im)
    *res_re = a_re*b_re - a_im*b_im;
    *res_im = a_re*b_im + a_im*b_re;

void sqComplex(double a_re, double a_im, double* res_re, double* res_im)
    multiplyComplex(a_re, a_im, a_re, a_im, res_re, res_im);

bool isInSet(double P_re, double P_im, double C_re, double C_im, int iter)
    double zPrev_re = P_re;
    double zPrev_im = P_im;
    double zNext_re = 0;
    double zNext_im = 0;
    double* p_zNext_re = &zNext_re;
    double* p_zNext_im = &zNext_im;
    int i;  
    for(i = 1; i <= iter; ++i)
        sqComplex(zPrev_re, zPrev_im, p_zNext_re, p_zNext_im);
        zNext_re = zNext_re + C_re;
        zNext_im = zNext_im + C_im;
        if(zNext_re*zNext_re+zNext_im*zNext_im > 4)
            return false;
        zPrev_re = zNext_re;
        zPrev_im = zNext_im;
    return true;

bool isMandelbrot(double P_re, double P_im, int iter)
    return isInSet(0, 0, P_re, P_im, iter);
void fractal(int iter)
    int noIterations = iter;
    double xMin = -1.8;
    double xMax = 1.6;
    double yMin = -1.3;
    double yMax = 0.8;
    int xDim = 512;
    int yDim = 384;
    double P_re, P_im;
    int nop;
    int x, y;

    for(x = 0; x < xDim; ++x)
        for(y = 0; y < yDim; ++y)
            P_re = (double)x*(xMax-xMin)/(double)xDim+xMin;
            P_im = (double)y*(yMax-yMin)/(double)yDim+yMin;
            if(isMandelbrot(P_re, P_im, noIterations))
                nop = x+y;
        printf("%d", nop);

Story behind the comparison

It might look a bit artificial to add the -fPIC flag when building executable (as per one of the comments). So a few words of explanation: first I only compiled the program as executable and wanted to compare to my Lua code, which calls the isMandelbrot function from C. So I created a shared object to call it from lua - and had big time differences. But couldn't understand why they were growing with number of iterations. In the end found out that it was because of the -fPIC. When I create a little c program which calls my lua script (so effectively I do the same thing, only don't need the .so) - the times are very similar to C (without -fPIC). So I have checked it in a few configurations over the last few days and it consistently shows two sets of very similar results: faster without -fPIC and slower with it.

share|improve this question
Cannot reproduce using gcc 4.7.2 on x86_64 (OS/X). – NPE Apr 7 '13 at 11:21
I get: gcc 12.78/18.23 -- clang 13.73 / 13.75 – teppic Apr 7 '13 at 11:41
Take a look at the objdump -d output for each executable. You can see that some optimizations are being excluded in the -fPIC version inside the fractal() function. What exactly are you trying to measure the performance of here? The overhead of calling fractal() when it's compiled with -fPIC? Or are you doing the fractal work in Lua and calling out to the lower level routines? One reason why the non-fPIC version is so much better is because a lot of work is being inlined in fractal(). In the -fPIC version, it's not. Again, you can fix that by making the helpers static. – jszakmeister Apr 7 '13 at 12:06
Stupid question, but you are quite sure that you are compiling as 64-bit code, right? The IA-32 instruction set was not designed for position-independent code and it would be normal to see this kind of difference if you were mistakenly using it. x86_64 was designed to make position-independent code as fast as position-dependent code, and the normal situation is not to have any measurable difference (as NPE and others found) – Pascal Cuoq Apr 7 '13 at 14:53
However, if compiling with gcc-4.8 -flto -O3 -mtune=native with or without -fPIC I am getting only 18.28sec for non PIC and 18.36 for PIC. So I advise to use -flto -mtune=native -O3 with or without -fPIC – Basile Starynkevitch Apr 7 '13 at 15:33
up vote 23 down vote accepted

It turns out that when you compile without the -fPIC option multiplyComplex, sqComplex, isInSet and isMandelbrot are inlined automatically by the compiler. If you define those functions as static you will likely get the same performance when compiling with -fPIC because the compiler will be free to perform inlining.

The reason why the compiler is unable to automatically inline the helper functions has to do with symbol interposition. Position independent code is required to access all global data indirectly, i.e. through the global offset table. The very same constraint applies to function calls, which have to go through the procedure linkage table. Since a symbol might get interposed by another one at runtime (see LD_PRELOAD), the compiler cannot simply assume that it is safe to inline a function with global visibility.

The very same assumption can be made if you compile without -fPIC, i.e. the compiler can safely assume that a global symbol defined in the executable cannot be interposed because the lookup scope begins with the executable itself which is then followed by all other libraries, including the preloaded ones.

For a more thorough understanding have a look at the following paper.

share|improve this answer

As others have discussed in the comment section of your opening post, compiling with -flto should help to reduce the difference in run-times you are seeing for this particular case, since the link time optimisations of gcc will likely figure out that it's actually ok to inline a couple of functions ;)

In general, link time optimisations could lead to massive reductions in code size (~6%) link to paper on link time optimisations in gold, and thus run time as well (more of your program fits in the cache). Also note that -fPIC is mostly viewed as a feature that enables tighter security and is always enabled in android. This question on SO briefly discusses as well. Also, just to let you know, -fpic is the faster version of -fPIC, so if you must use -fPIC try -fpic instead - link to gcc docs. For x86 it might not make a difference, but you need to check this for yourself/ask on gcc-help.

share|improve this answer
Tighter security because it enables address-space layout randomization. I don't think PIC without ASLR gains you anything security-wise. I assume this is why OS X requires position-independent code in executables, not just libraries. (BTW, this explains the first comment on the question saying it's not reproducible on OSX. Either -fPIC doesn't stop inlining, or it can't happen in either case (because OSX does support symbol interposition). TL;DR: static is good! – Peter Cordes Mar 31 at 5:09
Also, your last paragraph is total crap. -fPIC is necessary for shared libraries, and a lot of important code is built as libraries these days. gcc makes code that's as fast as it's possible for it to be, given the requirements imposed on how it has to work (indirection through the GOT or PLT to allow symbol interposition). – Peter Cordes Mar 31 at 5:15
Agner Fog's proposal for an extensible instruction set doesn't support symbol interposition, which removes the overhead of indirection through the GOT even for PIC. In x86-64, most of the overhead of PIC is the indirection, not the relative addressing. RIP-relative addressing is only slightly more expensive than using absolute addressing, and is only needed for accessing global data. Function calls are relative anyway so there's zero overhead. (even in 32bit, the call instruction uses a 32bit relative displacement.) – Peter Cordes Mar 31 at 5:18
I don't know much about this proposal or the specifics of PIC code, but I also suggested that it "might" not be slower for x86. Also, my comment about gcc people not caring about PIC performance still stands - which libraries are you refering to? – baibo Mar 31 at 16:34
No, I haven't talked to gcc people about PIC myself. Are you sure you were interpreting what you heard correctly? Most gcc optimizations apply equally well to PIC and non-PIC, so it's not that performance of PIC code doesn't matter. It sounds more like he meant that optimizations that only help avoid the PIC overhead aren't as high a priority (probably because gcc already does a decent job). It's not like gcc just gives up on important optimizations because nobody bothered to enable them in PIC mode. BTW, database libraries are another good example of perf-critical library code. – Peter Cordes Mar 31 at 19:04

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