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Has anyone seen any numbers / analysis on whether or not use of the C / C++ restrict keyword in gcc / g++ actual provides any significant performance boost in reality ( and not just in theory )?

I've read various articles recommending / disparaging it's use, but I haven't ran across any real numbers practically demonstrating either sides arguments.


I know that restrict is not officially part of C++, but it is supported by some compilers and I've read a paper by Christer Ericson which strongly recommends it's usage.

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Aliasing issues are commonly considered the #1 reason why C/C++ are less efficient at many computational tasks than Fortran. So I'd say any feature which helps avoid aliasing can make a big difference. –  jalf Dec 27 '09 at 23:58

4 Answers 4

up vote 31 down vote accepted

The restrict keyword does a difference.

I've seen improvements of factor 2 and more in some situations (image processing). Most of the time the difference is not that large though. About 10%.

Here is a little example that illustrate the difference. I've written a very basic 4x4 vector * matrix transform as a test. Note that I have to force the function not to be inlined. Otherwise GCC detects that there aren't any aliasing pointers in my benchmark code and restrict wouldn't make a difference due to inlining.

I could have moved the transform function to a different file as well.

#include <math.h>

#define __restrict

void transform (float * __restrict dest, float * __restrict src, 
                float * __restrict matrix, int n) __attribute__ ((noinline));

void transform (float * __restrict dest, float * __restrict src, 
                float * __restrict matrix, int n)
  int i;

  // simple transform loop.

  // written with aliasing in mind. dest, src and matrix 
  // are potentially aliasing, so the compiler is forced to reload
  // the values of matrix and src for each iteration.

  for (i=0; i<n; i++)
    dest[0] = src[0] * matrix[0] + src[1] * matrix[1] + 
              src[2] * matrix[2] + src[3] * matrix[3];

    dest[1] = src[0] * matrix[4] + src[1] * matrix[5] + 
              src[2] * matrix[6] + src[3] * matrix[7];

    dest[2] = src[0] * matrix[8] + src[1] * matrix[9] + 
              src[2] * matrix[10] + src[3] * matrix[11];

    dest[3] = src[0] * matrix[12] + src[1] * matrix[13] + 
              src[2] * matrix[14] + src[3] * matrix[15];

    src  += 4;
    dest += 4;

float srcdata[4*10000];
float dstdata[4*10000];

int main (int argc, char**args)
  int i,j;
  float matrix[16];

  // init all source-data, so we don't get NANs  
  for (i=0; i<16; i++)   matrix[i] = 1;
  for (i=0; i<4*10000; i++) srcdata[i] = i;

  // do a bunch of tests for benchmarking. 
  for (j=0; j<10000; j++)
    transform (dstdata, srcdata, matrix, 10000);

Results: (on my 2 Ghz Core Duo)

nils@doofnase:~$ gcc -O3 test.c
nils@doofnase:~$ time ./a.out

real    0m2.517s
user    0m2.516s
sys     0m0.004s

nils@doofnase:~$ gcc -O3 -DUSE_RESTRICT test.c
nils@doofnase:~$ time ./a.out

real    0m2.034s
user    0m2.028s
sys     0m0.000s

Over the thumb 20% faster execution, on that system.

To show how much it depends on the architecture I've let the same code run on a Cortex-A8 embedded CPU (adjusted the loop count a bit cause I don't want to wait that long):

root@beagleboard:~# gcc -O3 -mcpu=cortex-a8 -mfpu=neon -mfloat-abi=softfp test.c
root@beagleboard:~# time ./a.out

real    0m 7.64s
user    0m 7.62s
sys     0m 0.00s

root@beagleboard:~# gcc -O3 -mcpu=cortex-a8 -mfpu=neon -mfloat-abi=softfp -DUSE_RESTRICT test.c 
root@beagleboard:~# time ./a.out

real    0m 7.00s
user    0m 6.98s
sys     0m 0.00s

Here the difference is just 9% (same compiler btw.)

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Nice work. There is an article on the use of restrict on a Cell processor here: cellperformance.beyond3d.com/articles/2006/05/… that may be relevant to the discussion architecture specific benefits. –  Clifford Dec 27 '09 at 20:31
@Nils Pipenbrinck: Why do you have to disable inlining for the function? It seems like an awfully big function for the compiler to automatically inline. –  Robert S. Barnes Dec 28 '09 at 7:40
@Nils Pipenbrinck: By the way Ulrich Drepper posted code for a superoptimized matrix multiply as part of his discussion of optimizing cache and memory usage. It's here: lwn.net/Articles/258188 . His discussion of each step he went through to arrive at that solution is here: lwn.net/Articles/255364 . He was able to reduce the execution time by 90% over a standard MM. –  Robert S. Barnes Dec 28 '09 at 7:45
@Nils Pipenbrinck: I ran your test. When I compiled with -O3 I got the same result as you, about a 20% speed increase. But when I compiled without any optimization flag the two runs where identical. This is interesting: No Op flag = 0m5.022s for both, -O3 0m3.186s & 0m2.583s, -Os 0m2.391s & 0m2.314s. Optimizing for size gives the best result. Adding restrict in this case only bought an extra 3.2% performance. Wonder why that is? –  Robert S. Barnes Dec 28 '09 at 7:58

The article Demystifying The Restrict Keyword refers to the paper Why Programmer-specified Aliasing is a Bad Idea (pdf) which says it generally doesn't help and provides measurements to back this up.

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Note that C++ compilers that allow the restrict keyword may still ignore it. That is the case for example here.

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Actually, if you read down the page you'll notice that while restrict is ignored in C++ because of a potential conflict with user variables of the same name, __restrict__ is supported for C++. –  Robert S. Barnes Dec 27 '09 at 9:59
@Robert: And ignored. The difference is only that identifiers with a double underscore are reserved for system usage. Thus a __restrict__ should not clash with any user declared identifiers. –  Loki Astari Dec 27 '09 at 20:02
@Martin: How do you know it's ignored? It's not completely clear from the documentation - seems like you could read it either way. –  Robert S. Barnes Dec 28 '09 at 7:35
I agree that it is not clear, but it would seem inconsistent to ignore restrict but not __restrict__. Either way, it remains non-portable, and beneficial in very specific cases. I suggest that if you know it is beneficial in a particular situation, and you need that benefit to achieve success, then use it; otherwise why make the code gratuitously non-portable? I would not use it habitually, but as a last resort and after testing the actual benefit. –  Clifford Dec 28 '09 at 9:32
@Clifford: Of course, but it's like that with pretty much any optimization - test this way and that way and then use what works. –  Robert S. Barnes Dec 28 '09 at 11:17

I tested this C-Program. Without restrict it took 12.640 seconds to complete, with restrict 12.516. Looks like it can save some time.

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That kind of difference is in the measurement noise... –  Drew Hall Dec 27 '09 at 9:36
That difference is almost certainly insignificant, however, you should also declare c as restricted since each time c is written to at the moment the compiler may be considering that *a *b and *inc might have been changed. –  James Dec 27 '09 at 16:17
In your example the optimizer can detect that the parameters don't have aliasing. Try to disable inlining and you'll see a bigger difference. –  Nils Pipenbrinck Dec 27 '09 at 18:41
But if you disable inlining, you're artificially crippling the compiler, so you no longer get an accurate picture of how much restricthelps on real-world code. –  jalf Dec 28 '09 at 0:00
@raphaelr: It seems like you need to use optimization flags for restrict to be useful. Try either -O3 or -Os. –  Robert S. Barnes Dec 28 '09 at 8:11

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