I'm a graduate student in biophysics, trying to program a protein aggregation model using PyCUDA and Scipy's
ODEInt. Within the past two weeks, I've gotten the code running, but it's very slow. Let me see if I can explain what my code does.
I have an
np array of
N concentrations with each element being the concentration of the
i+1 length polymer. I have a function that calculates the rate of change of the polymer concentrations using
CUDA where each kernel calculates the rate of change of one specific length polymer. During this calculation, an
(N-i-1) length array needs to be summed by the thread, drastically slowing down my code.
Doing a little reading and Googling, I've come across parallel reduction as a way of invoking parallelism to make a serial calculation like an array sum go much faster. Of course I'm referring to Mark Harris' powerpoint slides. These were a great read and this looks like a potential way to drastically speed up my code, but I have a few questions :
If the number of polymer species, N, needs to be ~ 8700-9000, is it conceivable to use CUDA to reduce these N arrays at the same time? Doing a quick calculation (again possible thanks to SO's great explanation of how to calculate the maximum number of concurrent threads), I get for my GTX Titan that I can have 15 * 64 * 32 = 30720 threads running at once. If I invoke my kernel on ~8960 kernels at a time, I should only have 21760 threads left to use, correct? Since it seems that you need at least (length of the array/2) threads to properly reduce it, then I'm doomed.
I was thinking that perhaps I could use the remaining threads by dividing them up and reducing a few of the big arrays at a time in serial.
I don't know...I'm just a physics grad student. I thought I'd ask the professionals before I embarked on a long journey in the wrong direction. Is it possible to easily and efficiently tell a kernel to reduce something?
Thank you, Karsten
Here's a representation of what I'm trying to do.
fluxes and concs are np.arrays dcdt(concs, t) Call CUDA to calculate fluxes Thread 0 fluxes[i] = stuff + sum(concs[n] for n from 1 to 9000) 1 fluxes[i] = stuff + sum(concs[n] for n from 2 to 9000) 2 fluxes[i] = stuff + sum(concs[n] for n from 3 to 9000) ... N fluxes[i] = stuff
You'll notice that the sum of the arrays that we've been talking about is basically a smaller version of the same array for each of the threads. This makes me wonder if this is something I should just do on the host.