I need to decode an RLE in CUDA and I have been trying to think about the most efficient way of expanding the RLE into a list with all my values. So Say my values are 2, 3, 4 and my runs are 3, 3 , 1 I want to expand that to 2, 2, 2, 3, 3, 3, 4.

At first I thought I could use cudaMemset but I am pretty sure now that launches a Kernel and I have CUDA Compute Capability 3.0 so even if it were not probably inefficient to launch a new kernel for each value / run pair I do not have dynamic parallelism available to do this.

So I want to know if this solution is sound before I go and implement it since there are so many things that end up not working well on CUDA if you aren't being clever. Would it be reasonable to make a kernel that will call cudaMalloc then cudaMemCpy to the destination? I can easily compute the prefix sums to know where to copy the memory to and from and make all my reading at least coalesced. What I am worried about is calling cudaMalloc and cudaMemCpy so many times.

Another potential option is writing these values to shared memory and then copying those to global memory. I want to know if my first solution should work and be efficient or if I have to do the latter.


You don't want to think about doing a separate operation (e.g. cudaMalloc, or cudaMemset) for each value/run pair.

After computing the prefix sum on the run sequence, the last value in the prefix sum will be the total allocation size. Use that for a single cudaMalloc operation for the entire final expanded sequence.

Once you have the necessary space allocated, and the prefix sum computed, the actual expansion is pretty straightforward.

thrust can make this pretty easy if you want a fast prototype. There is an example code for it.

  • Robert you are one of the most awesome people around. You have solved every problem I have ever run into on CUDA. Thank you! – flips Apr 18 '16 at 15:37

@RobertCrovella is of course correct, but you can go even further in terms of efficiency if you have the leeway to slightly tweak your compression sceheme.

Sorry for the self-plugging, but you might be interested in my own implementation of a variant of Run-Length Encoding, with the addition of anchoring of output positions into the input (e.g.. "in which offset in which run do we have the 2048th element?"); this allows for a more equitable assignment of work to thread blocks and avoids the need for a full-blown prefix sum. It's still a work-in-progress, so I only get ~34 GB/sec on a 336 GB/sec memory bandwidth card (Titan X) at the time of writing, but it's quite usable.

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