I have taken the Kernel from the great OpenCL SpMV article for AMD by Bryan Catanzaro. I have given it a toy problem where the input is A= [0 0 0 6 1 3 5 7 2 4 0 0] offsets= [-3 0 2] x= [1 2 3 4] and the output y should be [7 22 15 34]

Here is the kernel:

```
__kernel
void dia_spmv(__global float *A, __const int rows,
__const int diags, __global int *offsets,
__global float *x, __global float *y) {
int row = get_global_id(0);
float accumulator = 0;
for(int diag = 0; diag < diags; diag++) {
int col = row + offsets[diag];
if ((col >= 0) && (col < rows)) {
float m = A[diag*rows + row];
float v = x[col];
accumulator += m * v;
}
}
y[row] = accumulator;
}
```

After loading and writing the input arguments I execute the kernel like this:

```
size_t global_work_size;
global_work_size = 4;
err = clEnqueueNDRangeKernel(cmd_queue, kernel, 1, NULL, &global_work_size,NULL, 0, NULL, NULL);
err = clFinish(cmd_queue);
```

And I get the correct result when I read y back from gpu memory. I.e. I get y = [7 22 15 34]

I am new to OpenCL (and GPGPU in general) so I want to try and understand how to extend the problem correctly for much larger matrices of arbitrary dimension. So lets say I have 1000 000 rows. What should I set global_work_size to be? And should I set local_work_size or should I leave it as NULL?