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# CUDA how to get grid, block, thread size and parallalize non square matrix calculation

I am new to CUDA and need help understanding some things. I need help parallelizing these two for loops. Specifically how to setup the dimBlock and dimGrid to make this run faster. I know this looks like the vector add example in the sdk but that example is only for square matrices and when I try to modify that code for my 128 x 1024 matrix it doesn't work properly.

``````__global__ void mAdd(float* A, float* B, float* C)
{
for(int i = 0; i < 128; i++)
{
for(int i = 0; i < 1024; i++)
{
C[i * 1024 + j] = A[i * 1024 + j] + B[i * 1024 + j];
}
}
}
``````

This code is part of a larger loop and is the simplest portion of the code, so I decided to try to paralleize thia and learn CUDA at same time. I have read the guides but still do not understand how to get the proper no. of grids/block/threads going and use them effectively.

-
In pycuda it is just `C[i] = A[i] + B[i]` demo.py – J.F. Sebastian Apr 13 '11 at 2:06

As you have written it, that kernel is completely serial. Every thread launched to execute it is going to performing the same work.

The main idea behind CUDA (and OpenCL and other similar "single program, multiple data" type programming models) is that you take a "data parallel" operation - so one where the same, largely independent, operation must be performed many times - and write a kernel which performs that operation. A large number of (semi)autonomous threads are then launched to perform that operation across the input data set.

``````C[k] = A[k] + B[k];
``````

for all k between 0 and 128 * 1024. Each addition operation is completely independent and has no ordering requirements, and therefore can be performed by a different thread. To express this in CUDA, one might write the kernel like this:

``````__global__ void mAdd(float* A, float* B, float* C, int n)
{
int k = threadIdx.x + blockIdx.x * blockDim.x;

if (k < n)
C[k] = A[k] + B[k];
}
``````

[disclaimer: code written in browser, not tested, use at own risk]

Here, the inner and outer loop from the serial code are replaced by one CUDA thread per operation, and I have added a limit check in the code so that in cases where more threads are launched than required operations, no buffer overflow can occur. If the kernel is then launched like this:

``````const int n = 128 * 1024;
int blocksize = 512; // value usually chosen by tuning and hardware constraints
int nblocks = n / nthreads; // value determine by block size and total work