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Can anyone give an example or a link to an example which uses __builtin_prefetch in GCC (or just the asm instruction prefetcht0 in general) to gain a substantial performance advantage? In particular, I'd like the example to meet the following criteria:

  1. It is a simple, small, self-contained example.
  2. Removing the __builtin_prefetch instruction results in performance degradation.
  3. Replacing the __builtin_prefetch instruction with the corresponding memory access results in performance degradation.

That is, I want the shortest example showing __builtin_prefetch performing an optimization that couldn't be managed without it.

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3 Answers 3

up vote 38 down vote accepted

Here's an actual piece of code that I've pulled out of a larger project. (Sorry, it's the shortest one I can find that had a noticable speedup from prefetching.) This code performs a very large data transpose.

This example uses the SSE prefetch instructions, which may be the same as the one that GCC emits.

To run this example, you will need to compile this for x64 and have more than 4GB of memory. You can run it with a smaller datasize, but it will be too fast to time.

#include <iostream>
using std::cout;
using std::endl;

#include <emmintrin.h>
#include <malloc.h>
#include <time.h>
#include <string.h>


#define f_vector    __m128d
#define i_ptr       size_t
inline void swap_block(f_vector *A,f_vector *B,i_ptr L){
    //  To be super-optimized later.

    f_vector *stop = A + L;

        f_vector tmpA = *A;
        f_vector tmpB = *B;
        *A++ = tmpB;
        *B++ = tmpA;
    }while (A < stop);
void transpose_even(f_vector *T,i_ptr block,i_ptr x){
    //  Transposes T.
    //  T contains x columns and x rows.
    //  Each unit is of size (block * sizeof(f_vector)) bytes.

    //  - 0 < block
    //  - 1 < x

    i_ptr row_size = block * x;
    i_ptr iter_size = row_size + block;

    //  End of entire matrix.
    f_vector *stop_T = T + row_size * x;
    f_vector *end = stop_T - row_size;

    //  Iterate each row.
    f_vector *y_iter = T;
        //  Iterate each column.
        f_vector *ptr_x = y_iter + block;
        f_vector *ptr_y = y_iter + row_size;


            _mm_prefetch((char*)(ptr_y + row_size),_MM_HINT_T0);


            ptr_x += block;
            ptr_y += row_size;
        }while (ptr_y < stop_T);

        y_iter += iter_size;
    }while (y_iter < end);
int main(){

    i_ptr dimension = 4096;
    i_ptr block = 16;

    i_ptr words = block * dimension * dimension;
    i_ptr bytes = words * sizeof(f_vector);

    cout << "bytes = " << bytes << endl;
//    system("pause");

    f_vector *T = (f_vector*)_mm_malloc(bytes,16);
    if (T == NULL){
        cout << "Memory Allocation Failure" << endl;

    //  Perform in-place data transpose
    cout << "Starting Data Transpose...   ";
    clock_t start = clock();
    clock_t end = clock();

    cout << "Done" << endl;
    cout << "Time: " << (double)(end - start) / CLOCKS_PER_SEC << " seconds" << endl;


When I run it with ENABLE_PREFETCH enabled, this is the output:

bytes = 4294967296
Starting Data Transpose...   Done
Time: 0.725 seconds
Press any key to continue . . .

When I run it with ENABLE_PREFETCH disabled, this is the output:

bytes = 4294967296
Starting Data Transpose...   Done
Time: 0.822 seconds
Press any key to continue . . .

So there's a 13% speedup from prefetching.


Here's some more results:

Operating System: Windows 7 Professional/Ultimate
Compiler: Visual Studio 2010 SP1
Compile Mode: x64 Release

Intel Core i7 860 @ 2.8 GHz, 8 GB DDR3 @ 1333 MHz
Prefetch   : 0.868
No Prefetch: 0.960

Intel Core i7 920 @ 3.5 GHz, 12 GB DDR3 @ 1333 MHz
Prefetch   : 0.725
No Prefetch: 0.822

Intel Core i7 2600K @ 4.6 GHz, 16 GB DDR3 @ 1333 MHz
Prefetch   : 0.718
No Prefetch: 0.796

2 x Intel Xeon X5482 @ 3.2 GHz, 64 GB DDR2 @ 800 MHz
Prefetch   : 2.273
No Prefetch: 2.666
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Interesting. Unfortunately on the two machines I tested (Macbook Pro with "Core 2 Duo" and a Linux machine with a "Quad-Core AMD Opteron Processor 2376") I didn't get a significant difference between the two versions. I suspect it has to do with cache size -- it looks you have a better machine than those two. What do you think? –  Shaun Harker Sep 7 '11 at 3:24
My machine is a Core i7 920 @ 3.5 GHz. 8MB L3 cache. This 10% speedup is more or less consistent on 3 other machines that I've tested: Core i7 2600K @ 4.6 GHz, and 2 x Xeon X5482 @ 3.2 GHz. But I'll admit that I've never tested it on a laptop or an AMD machine. –  Mysticial Sep 7 '11 at 3:39
I just edited my answer with the benchmarks on all 4 machines that I tested. They're all Intel desktops/workstations. So that could be the reason. I didn't test if your 3rd point holds. It could be that substituting it with a memory access could produce the same result. –  Mysticial Sep 7 '11 at 3:49
The third point is tricky to test due to the out-of-order execution. In order for the third point to hold, you will need to have some 100 - 200 instructions between the load to when it's actually used. A stalled load will block the pipeline after the re-order buffer is filled up. But a prefetch won't. The only time you'll see the penalty of the stalled load is when you actually have enough instructions to overflow the re-order buffer... If you just replace my prefetch with a normal load, the compiler will probably optimize out the load as dead code... (which satisfies your last point, lol) –  Mysticial Sep 9 '11 at 6:18
Yes, you'd have to add some sort of "dummy" thing to take in the memory access and then print its value so it wouldn't be optimized away -- that's what i have been doing. Can you give me a link to information regarding what you are discussing about stalled loads and re-order buffers? I think that might do me a world of good. –  Shaun Harker Sep 10 '11 at 5:07

From the documentation:

      for (i = 0; i < n; i++)
          a[i] = a[i] + b[i];
          __builtin_prefetch (&a[i+j], 1, 1);
          __builtin_prefetch (&b[i+j], 0, 1);
          /* ... */
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I expect that the CPU's hardware prefetcher, would have prefetched this anyway. This is usually the cause of people discovering that "prefetch does nothing" - it really requires that the access pattern is something that a reasonably simple piece of logic, analyzing access patterns cannot predict. –  Crowley9 Sep 8 '11 at 1:48
@Crowley9 I disagree that this is a bad answer. The OP wanted a simple example (probably to know how to use it), this answers on that. –  a3mlord Mar 11 at 19:21
Older CPUs with less smart hardware prefetching benefited from software prefetching in more cases. I think even P4 would have been smart enough to HW prefetch sequential accesses to contiguous data, though. This is a terrible example because it's a case where the extra prefetch instructions just slow things down. @a3mlord: The OP wanted a performance win, not just the syntax. –  Peter Cordes 2 hours ago

Binary search is a simple example that could benefit from explicit prefetching. The access pattern in a binary search looks pretty much random to the hardware prefetcher, so there is little chance that it will accurately predict what to fetch.

In this example, I prefetch the two possible 'middle' locations of the next loop iteration in the current iteration. One of the prefetches will probably never be used, but the other will (unless this is the final iteration).

 #include <time.h>
 #include <stdio.h>
 #include <stdlib.h>

 int binarySearch(int *array, int number_of_elements, int key) {
         int low = 0, high = number_of_elements-1, mid;
         while(low <= high) {
                 mid = (low + high)/2;
            #ifdef DO_PREFETCH
            // low path
            __builtin_prefetch (&array[(mid + 1 + high)/2], 0, 1);
            // high path
            __builtin_prefetch (&array[(low + mid - 1)/2], 0, 1);

                 if(array[mid] < key)
                         low = mid + 1; 
                 else if(array[mid] == key)
                         return mid;
                 else if(array[mid] > key)
                         high = mid-1;
         return -1;
 int main() {
     int SIZE = 1024*1024*512;
     int *array =  malloc(SIZE*sizeof(int));
     for (int i=0;i<SIZE;i++){
       array[i] = i;
     int NUM_LOOKUPS = 1024*1024*8;
     int *lookups = malloc(NUM_LOOKUPS * sizeof(int));
     for (int i=0;i<NUM_LOOKUPS;i++){
       lookups[i] = rand() % SIZE;
     for (int i=0;i<NUM_LOOKUPS;i++){
       int result = binarySearch(array, SIZE, lookups[i]);

When I compile and run this example with DO_PREFETCH enabled, I see a 20% reduction in runtime:

 $ gcc c-binarysearch.c -DDO_PREFETCH -o with-prefetch -std=c11 -O3
 $ gcc c-binarysearch.c -o no-prefetch -std=c11 -O3

 $ perf stat -e L1-dcache-load-misses,L1-dcache-loads ./with-prefetch 

  Performance counter stats for './with-prefetch':

    356,675,702      L1-dcache-load-misses     #   41.39% of all L1-dcache hits  
   861,807,382      L1-dcache-loads                                             

   8.787467487 seconds time elapsed

 $ perf stat -e L1-dcache-load-misses,L1-dcache-loads ./no-prefetch 

 Performance counter stats for './no-prefetch':

   382,423,177      L1-dcache-load-misses     #   97.36% of all L1-dcache hits  
   392,799,791      L1-dcache-loads                                             

  11.376439030 seconds time elapsed

Notice that we are doing twice as many L1 cache loads in the prefetch version. We're actually doing a lot more work but the memory access pattern is more friendly to the pipeline. This also shows the tradeoff. While this block of code runs faster in isolation, we have loaded a lot of junk into the caches and this may put more pressure on other parts of the application.

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