Optimizing for caches is not a trivial matter. So such trivialized generalization as this:
From whatever I have read till now, global memory is slower than surface memory. So use of surface memory should take less time.
are simply so broad as to be incorrect, in my opinion. It will be frequently true, but not always true. The specifics matter, and proper programming practice matters, too.
Surface memory is nothing more than global memory with an intervening cache. But global memory (on all GPUs supported by current CUDA versions) already has support from L2 (and in some cases L1) cache(s).
The code you have proposed for test/comparison has a number of issues that I would point out:
Your timing methodology is incorrect. This:
t1 = clock();
mul <<<dimGrid, dimBlock>>> (N);
t2 = clock();
will time the duration of the kernel launch not the duration of the kernel execution. So this is almost never the correct way to time things. We can fix this by putting a cudaDeviceSynchronize(); call in the timing region, to force completion of the kernel before timing closure.
This is a particularly bad construct if you are interested in performance:
dim3 dimBlock(1, 1);
because 31 out of every 32 threads in every GPU warp will be inactive, you are leaving 31/32 of the performance of the GPU unused. This has wide-ranging implications. I have no interest in studying the performance of such a scenario, and you shouldn't either (as it is not reflective of real-world performance on well-written codes), unless you are interested in microbenchmarking (not comparative benchmarking). So your code should be fixed to handle at least 32, and ideally 256 or more threads per block.
You've provided no "global memory" comparison case. So I shall provide one.
You've not stated many other factors important for comparative benchmarking, or perf analysis, such as the GPU and platform you are running on, as well as the compile command.
In my opinion, the problem size is too small. A matrix multiply of 100x100 matrices is on the edge of a code that could reasonably occupy the GPU, or test it's performance limits. So I shall make the problem size larger.
With respect to the problem size argument, this is important for the cache discussion. First of all, the surface cache tends to be a spatially-optimized cache, whereas the ordinary L1 and L2 caches are linearly (cache-line) optimized. For very large 2D problems, the surface cache might give better behavior than the L2. But for very small problems, the difference will be less pronounced. Secondly, the surface cache is in addition to the L1 and L2 caches, so a good optimization strategy is to funnel some data through L1 and L2, and other data through surface, to maximize the available cache lines. In fact, since your input matrices are read-only, a further optimization might be to use textures rather than surface for those. But from a contrary point of view, if my problem is so small as to completely fit in the L2 cache, then the surface cache is not likely to give a significant improvement. Your original problem size included 3 matrices of 100x100 int quantities, so about 40Kbytes each, or 120K bytes total. This problem size will fit in the L2 cache of most GPUs. By increasing the problem size (as we shall see - to about 12MB total) we can severely handicap the global-memory-only case.
Here's a code and fully worked example, that has been modified to address most of the above issues. When I run this code on my Quadro5000 GPU on CUDA 7.5/Fedora 20, I observe the surface case to be about 8x faster than the global memory case:
$ cat t1129.cu
#include <stdio.h>
#include <iostream>
typedef int mytype;
const int blk_dim=16;
#define my_N 1000
#define A_VAL 1
#define B_VAL 2
surface < void, 2 > a_surf;
surface < void, 2 > b_surf;
surface < void, 2 > c_surf;
void CUDA_SAFE_CALL(cudaError_t call, int line) {
switch (call) {
case cudaSuccess:
break;
default:
printf("ERROR at line :%i.%d' ' %s\n",
line, call, cudaGetErrorString(call));
exit(-1);
break;
}
}
#ifdef USE_GLOBAL
__global__ void mul(const mytype * __restrict__ d_a, const mytype * __restrict__ d_b, mytype * __restrict__ d_c, const int N)
#else
__global__ void mul(const int N)
#endif
{
mytype a, b, c, temp;
int i;
unsigned int x = blockIdx.x * blockDim.x + (threadIdx.x);
unsigned int y = blockIdx.y * blockDim.y + (threadIdx.y);
if (x < N && y < N) {
temp = 0;
for (i = 0; i < N; i++) {
#ifdef USE_GLOBAL
a = d_a[x*N+i];
b = d_b[i*N+y];
#else
surf2Dread( & a, a_surf, (x) * sizeof(mytype), i);
surf2Dread( & b, b_surf, (i) * sizeof(mytype), y);
#endif
temp += a * b;
}
c = temp;
#ifdef USE_GLOBAL
d_c[x*N+y] = c;
#else
// Write to output surface
surf2Dwrite(c, c_surf, x * sizeof(mytype), y);
#endif
}
}
int main() {
const int N = my_N;
mytype *a, *b, *c, *d_a, *d_b, *d_c;
int i, j;
clock_t t1, t2;
cudaArray * da, * db, * dc;
cudaChannelFormatDesc channelDesc = cudaCreateChannelDesc < mytype > ();
dim3 dimBlock(blk_dim, blk_dim);
dim3 dimGrid((N+dimBlock.x-1)/dimBlock.x, (N+dimBlock.y-1)/dimBlock.y);
int s = N * N * sizeof(mytype);
a = (mytype *)malloc(s);
b = (mytype *)malloc(s);
c = (mytype *)malloc(s);
CUDA_SAFE_CALL(cudaMalloc(&d_a, s), __LINE__);
CUDA_SAFE_CALL(cudaMalloc(&d_b, s), __LINE__);
CUDA_SAFE_CALL(cudaMalloc(&d_c, s), __LINE__);
for (i = 0; i < N; i++)
for (j = 0; j < N; j++)
a[i*N+j] = A_VAL;
for (i = 0; i < N; i++)
for (j = 0; j < N; j++)
b[i*N+j] = B_VAL;
CUDA_SAFE_CALL(cudaMallocArray( & da, & channelDesc, N, N, cudaArraySurfaceLoadStore), __LINE__);
CUDA_SAFE_CALL(cudaMallocArray( & db, & channelDesc, N, N, cudaArraySurfaceLoadStore), __LINE__);
CUDA_SAFE_CALL(cudaMallocArray( & dc, & channelDesc, N, N, cudaArraySurfaceLoadStore), __LINE__);
CUDA_SAFE_CALL(cudaMemcpyToArray(da, 0, 0, a, s, cudaMemcpyHostToDevice), __LINE__);
CUDA_SAFE_CALL(cudaMemcpyToArray(db, 0, 0, b, s, cudaMemcpyHostToDevice), __LINE__);
CUDA_SAFE_CALL(cudaBindSurfaceToArray(a_surf, da), __LINE__);
CUDA_SAFE_CALL(cudaBindSurfaceToArray(b_surf, db), __LINE__);
CUDA_SAFE_CALL(cudaBindSurfaceToArray(c_surf, dc), __LINE__);
#ifdef USE_GLOBAL
CUDA_SAFE_CALL(cudaMemcpy(d_a, a, s, cudaMemcpyHostToDevice), __LINE__);
CUDA_SAFE_CALL(cudaMemcpy(d_b, b, s, cudaMemcpyHostToDevice), __LINE__);
#endif
t1 = clock();
#ifdef USE_GLOBAL
mul <<<dimGrid, dimBlock>>> (d_a, d_b, d_c, N);
#else
mul <<<dimGrid, dimBlock>>> (N);
#endif
cudaDeviceSynchronize();
t2 = clock();
CUDA_SAFE_CALL(cudaMemcpyFromArray(c, dc, 0, 0, s, cudaMemcpyDeviceToHost), __LINE__);
#ifdef USE_GLOBAL
CUDA_SAFE_CALL(cudaMemcpy(c, d_c, s, cudaMemcpyDeviceToHost), __LINE__);
#endif
double t3 = (double) t2 - (double) t1;
t3 = t3 / CLOCKS_PER_SEC;
printf("\n CUDA time :%lf\n", t3);
for (i=0; i < N*N; i++)
if(c[i] != A_VAL*B_VAL*N) {std::cout << "mismatch at: " << i << ", was: " << c[i] << " should be: " << A_VAL*B_VAL*N << std::endl; return 1;}
CUDA_SAFE_CALL(cudaFreeArray(da), __LINE__);
CUDA_SAFE_CALL(cudaFreeArray(db), __LINE__);
CUDA_SAFE_CALL(cudaFreeArray(dc), __LINE__);
std::cout << "Success!" << std::endl;
return 0;
}
[bob@cluster1 misc]$ nvcc -O3 -o t1129 t1129.cu
[bob@cluster1 misc]$ ./t1129
CUDA time :0.028771
Success!
$ nvcc -O3 -DUSE_GLOBAL -o t1129 t1129.cu
$ ./t1129
CUDA time :0.243635
Success!
$
As a final note, there are many other optimizations we could talk about, which would probably shift the comparison one way or the other. But if you actually want to do fast matrix multiply operations, you should use CUBLAS. You should not write your own matrix multiply routines.
dim3 dimBlock(1, 1);That "threading scheme" you have chosen will leave approximately 97% of the GPU horsepower unused. Your optimization priorities are incorrect.