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.