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I need to square root each element of a matrix (which is basically a vector of float values once in memory) using CUDA.

Matrix dimensions are not known 'a priori' and may vary [2-20.000].

I was wondering: I might use (as Jonathan suggested here) one block dimension like this:

int thread_id = blockDim.x * block_id + threadIdx.x;

and check for thread_id lower than rows*columns... that's pretty simple and straight.

But is there any particular performance reason why should I use two (or even three) block grid dimensions to perform such a calculation (keeping in mind that I have a matrix afterall) instead of just one?

I'm thinking at coalescence problems, like making all threads reading values sequentially

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up vote 6 down vote accepted

The dimensions only exist for convenience, internally everything is linear, so there would be no advantage in terms of efficiency either way. Avoiding the computation of the (contrived) linear index as you've shown above would seem to be a bit faster, but there wouldn't be any difference in how the threads coalesce.

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Thank you, considering the matrix may be of a non-32-multiple size (e.g. 1033x2977), the tiling approach (2 dimensions) seems to me just complicated as the above, but I might be wrong – Marco A. Mar 28 '11 at 19:55
Thank you ashwin, a question: the second approach of your page maximizes coalescence if I choose a thread number multiple of the semiwarp, right? – Marco A. Mar 29 '11 at 9:37
@Paul: It's always a good idea to choose a block-size (threads per block) that is divisible by warp-size (threads per warp), because there will be no somewhat-empty warps anyway. – LumpN Mar 30 '11 at 16:20
@Paul The link for work allocation strategies: – Ashwin Nanjappa Sep 11 '15 at 1:02

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