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I am very new to parallel programming and stack overflow. I am working on a matrix multiplication implementation using CUDA. I am using column order float arrays as matrix representations.

The algorithm I developed is a bit unique and goes as follows. Given a matrix an n x m matrix A and an m x k matrix B, I launch an n x k blocks with m threads in each block. Essentially, I launch a block for every entry in the resulting matrix, with each thread computing one multiplication for that entry. For example,

1 0 0     0 1 2  
0 1 0  *  3 4 5  
0 0 1     6 7 8

For the first entry in the resulting matrix I would launch each thread with

thread 0 computing 1 * 3 thread 1 computing 0 * 0 thread 2 computing 0 * 1

With each thread adding to a 0-initialized matrix. Right now, I am not getting a correct answer. I am getting this over and over again

0 0 2
0 0 5
0 0 8

My kernel function is below. Could this be a thread synchronization problem or am I screwing up array indexing or something?

    /*@param d_A: Column order matrix 
     *@param d_B: Column order matrix
     *@param d_result: 0-initialized matrix that kernels write to
     *@param dim_A: dimensionality of A (number of rows)
     *@param dim_B: dimensionality of B (number of rows)
    __global__ void dot(float *d_A, float *d_B, float *d_result, int dim_A, int dim_B) {
        int n = blockIdx.x;
        int k = blockIdx.y;
        int m = threadIdx.x;

       float a = d_A[(m * dim_A) + n];
       float b = d_B[(k * dim_B) + m];
       //d_result[(k * dim_A) + n] += (a * b);

       float temp = d_result[(k*dim_A) + n];
       temp = temp + (a * b);
       d_result[(k*dim_A) + n] = temp;
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In d_result[(k*dim_A) + n] = temp; each thread in the block is writing to the same location overwriting each others result. –  RoBiK Jun 28 '13 at 15:04

1 Answer 1

The whole idea of using syncthreads() is wrong in this case. This API call has a block scope.

   1. syncthreads();
   2. float temp = d_result[(k*dim_A) + n];
   3. syncthreads();
   4. temp = temp + (a * b);
   5. syncthreads();
   6. d_result[(k*dim_A) + n] = temp;
   7. syncthreads();

The local variable float temp; has thread scope and using this synchronization barrier is senseless. The pointer d_result is global memory pointer and using this synchronization barrier is also senseless. Note that there isn't available yet (maybe there will never be available) a barrier which synchronizes threads globally.

Typically the usage of syncthreads() is required when shared memory is used for computation. In this case you may want to use shared memory. Here you could see an example of how to use shared memory and syncthreads() properly. Here you have an example of matrix multiplication with shared memory.

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