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Hey I've seen on a website this example kernel

 __global__ void loop1( int N, float alpha, float* x, float* y ) {
   int i;
   int i0 = blockIdx.x*blockDim.x + threadIdx.x;

   for(i=i0;i<N;i+=blockDim.x*gridDim.x) {
      y[i] = alpha*x[i] + y[i];

To compute this function in C

   for(i=0;i<N;i++) {
      y[i] = alpha*x[i] + y[i];

Surely the for loop inside the kernel isn't necessary? and you can just do y[i0] = alpha*x[i0] + y[i0] and remove the for loop altogether.

I'm just curious as to why it's there and what it's purpose is. This is assuming a kernel call such as loop1<<<64,256>>>> so presumably gridDim.x = 1

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Actually using such kernel execution configuration <<<64, 256>>>> gridDim.x value is 64, not 1, because gridDim buit-in dim3 variable contains the dimensions of the grid and this grid has 64 thread blocks using one dimension. –  Grzegorz Szpetkowski Mar 16 '11 at 21:30

3 Answers 3

up vote 4 down vote accepted

You need the for loop in the kernel if your vector has more entrys than you have started threads. If it's possible it is of course more efficent to start enough threads.

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Ah I see, so it is needed if N is larger than 64*256 in this case? Thanks very much –  user660414 Mar 16 '11 at 20:55

Interesting kernel. The loop inside the kernel is necessary, because N is greater than total number of threads, which is 16 384 (blockDim.x*gridDim.x), but I think it's not good practice to do it (the whole point of CUDA is to use SIMT concept). According to CUDA Programming Guide you can have at most 65535 thread blocks with one kernel. Futhermore starting from Compute Capability 2.x (Fermi) you can have at most 1024 threads per one block (512 before Fermi) Also you can (if possible) separate code into multiple (sequential) kernels.

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sometimes it is better to have a for loop that is easily unrollable (which is true in this case), than to launch too many blocks and keep switching them. The optimal number can be found empirically for a given problem. –  Pavan Yalamanchili Mar 17 '11 at 17:25
@Pavan ok, but I think that also (global) memory access could be optimized in for loop. In above example y[i] = alpha*x[i] + y[i]; iterations are very scattered (i0, i0 + numberOfThreads, i0+2*numberOfThreads, ..). –  Grzegorz Szpetkowski Mar 17 '11 at 20:07
Szepetkowski, You are right. I usually access contiguous blocks of data with for loops, so I never really thought of it that way :) –  Pavan Yalamanchili Mar 18 '11 at 6:22

Much as we would like to believe that CUDA GPUs have infinite execution resources, they do not, and authors of highly optimized code are finding that unrolled for loops, often with fixed numbers of blocks, give the best performance. Makes for painful coding, but optimized CPU code is also pretty painful.

btw a commenter mentioned that this code would have coalescing problems, and I don't see why. If the base addresses are correctly aligned (64B since those are floats), all of the memory transactions by this code will be coalesced, provided the threads/block is also divisible by 64.

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