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I am attempting to implement a shared memory based matrix multiplication kernel as outlined in the CUDA C Programming Guide. The following is the kernel:

 __global__ void matrixMultiplyShared(float * A, float * B, float * C,
                     int ARows, int AColumns,
                     int BRows, int BColumns,
                     int CRows, int CColumns) {
     float * CSub = &C[CColumns * 16 * blockIdx.y + 16 * blockIdx.x];
     float CValue = 0;
 for (int k = 0; k < (AColumns / 16); ++k) {
         float * ASub =  &A[AColumns * 16 * blockIdx.y + 16 * k];
         float * BSub = &B[AColumns*16*k + 16*blockIdx.y];
         __shared__ float As[16][16];
         __shared__ float Bs[16][16];
         As[threadIdx.y][threadIdx.x] = ASub[threadIdx.y*AColumns+threadIdx.x];
         Bs[threadIdx.y][threadIdx.x] = BSub[threadIdx.y*AColumns+threadIdx.x];
         __syncthreads();
         for (int n = 0; n < 16; ++n)
        CValue += As[threadIdx.y][n] * Bs[n][threadIdx.x];
         __syncthreads();
     }
     CSub[threadIdx.x*CColumns+threadIdx.y]=CValue;
 }

While the following is the call to the kernel:

 dim3 dimBlock(16, 16, 1);
 dim3 dimGrid;
 dimGrid.x = (CColumns + dimBlock.x - 1)/dimBlock.x;
 dimGrid.y = (CRows + dimBlock.y - 1)/dimBlock.y;
 matrixMultiplyShared<<<dimGrid , dimBlock>>>(deviceA , deviceB , deviceC , ARows , AColumns, BRows ,BColumns , CRows , CColumns);

Unfortunately this seems to produce incorrect results.

Any assistance/explanations would be greatly appreciated.

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Does it work if you remove all the 16's (make all those 16 into a named constant - that way, you easily change it to, say 1, and it will also help if you want to check if it's faster with 16, 32, 64, 128 or whatever) –  Mats Petersson Dec 29 '12 at 0:34
    
Why would you ever want to initialise the block dimensions using floating point numbers? It is an integer structure. In this case 16 is exactly representable as a floating point quantity, but in other cases you won't be so lucky –  talonmies Dec 29 '12 at 4:38
    
Fixed it to be integer, tried moving it into a named constant - to no effect. –  Abraham P Dec 30 '12 at 21:27
    
Are you trying to multiply two matrices using grid dimension as (1,1,1) ? –  Recker Jan 2 '13 at 23:38
    
I guess a bunch of folks are taking the same class. Take a look at this question. –  Robert Crovella Jan 3 '13 at 17:00

1 Answer 1

up vote 4 down vote accepted

There are at least 2 basic errors in your kernel, both relatively trivial. Where you have this:

     float * BSub = &B[AColumns*16*k + 16*blockIdx.y];

You should use this:

     float * BSub = &B[AColumns*16*k + 16*blockIdx.x];

And where you have this:

 CSub[threadIdx.x*CColumns+threadIdx.y]=CValue;

You should use this:

 CSub[threadIdx.y*CColumns+threadIdx.x]=CValue;

This should allow you to get basic correctness under the following conditions:

  1. square matrices
  2. matrix dimensions evenly divisible by tile dimension

Fixing the square matrix limitation is not difficult. Fixing the dimension limitation on the tile dimension involves considerable changes to the kernel, in order to:

  1. not process out-of-range elements
  2. properly populate your shared memory area with values that are appropriate in the "border" regions

Since your code doesn't comprehend any of this, I wasn't sure if you're asking about it and chose not to address those issues specifically.

I was able to get the following adaptation of your code working as a basic example: (note that for the benefit of reduced code size to look at, I have dispensed with usual CUDA error checking. Please don't use this as a representative example of good coding. Do proper error checking. The point of my answer is not to explain good CUDA error checking but to show an algorithmically correct example.)

#include <stdio.h>
#include <math.h>
#define TILE_DIM 16
#define DIMX 256
#define DIMY 256
#define RES 0.1

__global__ void matrixMultiplyShared(float * A, float * B, float * C,
                     int ARows, int AColumns,
                     int BRows, int BColumns,
                     int CRows, int CColumns) {
     float CValue = 0;
     if (((blockIdx.y * blockDim.y + threadIdx.y)< CRows) && ((blockIdx.x * blockDim.x + threadIdx.x) < CColumns)) {
       for (int k = 0; k < (AColumns / TILE_DIM); ++k) {
         float * ASub =  &A[AColumns * TILE_DIM * blockIdx.y + TILE_DIM * k];
         float * BSub = &B[AColumns*TILE_DIM*k + TILE_DIM*blockIdx.x];
         __shared__ float As[TILE_DIM][TILE_DIM];
         __shared__ float Bs[TILE_DIM][TILE_DIM];
         As[threadIdx.y][threadIdx.x] = ASub[threadIdx.y*AColumns+threadIdx.x];
         Bs[threadIdx.y][threadIdx.x] = BSub[threadIdx.y*AColumns+threadIdx.x];
         __syncthreads();
         for (int n = 0; n < TILE_DIM; ++n)
         CValue += As[threadIdx.y][n] * Bs[n][threadIdx.x];
         __syncthreads();
       }
       C[((blockIdx.y * blockDim.y + threadIdx.y)*CColumns)+(blockIdx.x*blockDim.x)+threadIdx.x]=CValue;
     }
 }


void matrixMultiplyCPU(float * A, float * B, float * C,
                     int ARows, int AColumns,
                     int BRows, int BColumns,
                     int CRows, int CColumns) {
  for (int i = 0; i<ARows; i++)
    for (int j=0; j<BColumns; j++){
      float Ctemp = 0.0;
      for (int k=0; k<AColumns; k++)
        Ctemp += A[i*AColumns + k] * B[k*BColumns+j];
      C[i*CColumns+j] = Ctemp;
      }

}
int main(){
 int CColumns = DIMY, CRows=DIMX, AColumns=DIMY, ARows=DIMX, BColumns=DIMY, BRows=DIMX;
 dim3 dimBlock(TILE_DIM, TILE_DIM, 1);
 dim3 dimGrid;
 dimGrid.x = (CColumns + dimBlock.x - 1)/dimBlock.x;
 dimGrid.y = (CRows + dimBlock.y - 1)/dimBlock.y;
 float *deviceA, *deviceB, *deviceC;
 float hostA[DIMY][DIMX];
 float hostB[DIMY][DIMX];
 float hostC[DIMY][DIMX];
 float hostCp[DIMY][DIMX];
 for (int x = 0; x<DIMX; x++)
   for (int y = 0; y<DIMY; y++) {
     hostA[y][x] = rand()/(float)RAND_MAX;
     hostB[y][x] = rand()/(float)RAND_MAX;
     }
  cudaMalloc((void **)&deviceA, DIMX*DIMY*sizeof(float));
  cudaMalloc((void **)&deviceB, DIMX*DIMY*sizeof(float));
  cudaMalloc((void **)&deviceC, DIMX*DIMY*sizeof(float));
  cudaMemcpy(deviceA, hostA, DIMX*DIMY*sizeof(float), cudaMemcpyHostToDevice);
  cudaMemcpy(deviceB, hostB, DIMX*DIMY*sizeof(float), cudaMemcpyHostToDevice);
  matrixMultiplyShared<<<dimGrid , dimBlock>>>(deviceA , deviceB , deviceC , ARows , AColumns, BRows ,BColumns , CRows , CColumns);
  cudaMemcpy(hostC, deviceC, DIMX*DIMY*sizeof(float), cudaMemcpyDeviceToHost);
  matrixMultiplyCPU(&(hostA[0][0]) , &(hostB[0][0]) , &(hostCp[0][0]) , ARows , AColumns, BRows ,BColumns , CRows , CColumns);

 for (int y = 0; y<DIMY; y++)
   for (int x = 0; x<DIMX; x++)
     if (fabs(hostCp[y][x] - hostC[y][x]) > RES)
       {
       printf("Error at offset y=%d,x=%d, CPU = %f, GPU = %f\n", y, x, hostCp[y][x], hostC[y][x]);
       return 1;
       }
 printf("Finished!\n");
 return 0;
}
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