# OpenCL Index operations: algorithmic vs constant index buffer

So I'm writing a neural network library using Aparapi (which generates OpenCL from Java code). Anyway there are many situations where I need to do complex index operations to find the source/destination node for a given weight when doing forward passes and backpropagation.

In many cases this is very simple 1D to 2D formula, but in some cases, such as for convolution nets, I need to do a somewhat more complex operation to find the index (often something like 3D to 1D to 3D).

I have been sticking with algorthims to compute these indices. The alternative would be to simple store the source and destination indices for each weight in a constant int array. I have avoided this as this would almost double the amount of memory storage.

I was wondering what the speed differences would be for computing indices vs reading them from a constant array? Am I losing speed in exchange for memory? Is the difference significant?

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Have you tried to benchmark it? Memory access speeds and latencies vary a lot from device to device, especially between GPU's and CPU's, so it really depends on your hardware, your specific algorithm, and so on. –  Thomas Aug 18 '13 at 5:47
If indices are like a[gid*3+x*15], striding can stop using some memory banks, computing indices qouldnt be a problem near this thing. –  huseyin tugrul buyukisik Aug 18 '13 at 5:51
@Thomas:I haven't tested it with a constant index buffer, but I am trying to design the software to be rather portable, so I'm more interested general performance than performance on my hardware. –  technotheist Aug 18 '13 at 6:04
Although, that being said, I am designing it for use on GPU/APU –  technotheist Aug 18 '13 at 6:09
If I was to use an index buffer, it would have to look something like this: `float[] nodes; float[] weights; int inputsPerNode; int[] weightSrc; fwd() { float sum = 0; int i0 = gid() * inputsPerNode; for(int i = 0; i < inputPerNode; i++) { sum += weights[i0 + i] * nodes[weightSrc[i0 + i]]; } nodes[gid()] = f(sum); } –  technotheist Aug 18 '13 at 6:15