I am implementing an algorithm using raw CUDA kernels, in which every threadblock needs the dense histogram of available data to that threadblock, now the question is that do I have to calculate the dense histogram from the scratch? (is it worth calculating the dense histogram at all, provided that i already have the sparse histogram which is implemented using shared memory)
I have come up with this idea of converting, I will try to elaborate my idea with example (temp and hist both are in shared memory)
0,1,2,3,4,5,6... //array indexes 4,3,0,2,1,0,5... //contents of hist 0,0,2,0,0,5,0... //contents of temp if(hist[x]>0)temp[x]=x; for_every_element //this is sequential part :( if(temp[x]>0) shift elements from index x to 256 4,3,2,1,0,5... //pass 1 of the for loop 4,3,2,1,5... //pass 2 of the for loop //this goes on until all the 0s are compacted
Now I know above is sequential in nature, but the shifting can be done with constant time (and in parallel) because threads_per_block is already set to 256, so shifting is not the main issue, the main issue is how to improve this (or any other suggestion is welcomed).
Edit: i am thinking of another idea, that is as follows
threads_per_block=256 if i can count which of histogram bins are non-zeros (this operation is parallel because each thread is assigned to each bin, i can atomicadd the values generated by each thread) let's say that i can then start a new shared index variable
sindex=0 and each time a thread wants to store the value into
d_hist it can take the latest value from sindex and store it's values to
d_hist[sindex]=hist[treadIdx.x] after that i can atomicAdd the sindex
Now there is only one problem, there is going to be a race condition to getting the value of sindex, so i may have to setup a flag which can be locked or unlocked when a thread is adding any value to
d_hist (but i think there can be a deadlock situation here)
Will this technique work? and is there any other technique better than that?