I've got a problem that I want to split across multiple CUDA devices, but I suspect my current system architecture is holding me back;

What I've set up is a GPU class, with functions that perform operations on the GPU (strange that). These operations are of the style

for iteration in range(maxval):

I'd imagined that there would be N gpuinstances for N devices, but I don't know enough about multiprocessing to see the simplest way of applying this so that each device is asynchronously assigned, and strangely few of the examples that I came across gave concrete demonstrations of collating results after processing.

Can anyone give me any pointers in this area?

UPDATE Thank you Kaloyan for your guidance in terms of the multiprocessing area; if CUDA wasn't specifically the sticking point I'd be marking you as answered. Sorry.

Perviously to playing with this implementation, the gpuinstance class initiated the CUDA device with import pycuda.autoinit But that didn't appear to work, throwing invalid context errors as soon as each (correctly scoped) thread met a cuda command. I then tried manual initialisation in the __init__ constructor of the class with...

self.mydev=pycuda.driver.Device(devid) #this is passed at instantiation of class

My assumption here is that the context is preserved between the list of gpuinstances is created and when the threads use them, so each device is sitting pretty in its own context.

(I also implemented a destructor to take care of pop/detach cleanup)

Problem is, invalid context exceptions are still appearing as soon as the thread tries to touch CUDA.

Any ideas folks? And Thanks to getting this far. Automatic upvotes for people working 'banana' into their answer! :P

  • Is the gpuinstance.gpufunction(arguments,iteration) asynchronous or does it block execution?
    – ktdrv
    Commented May 5, 2011 at 22:41

2 Answers 2


You need to get all your bananas lined up on the CUDA side of things first, then think about the best way to get this done in Python [shameless rep whoring, I know].

The CUDA multi-GPU model is pretty straightforward pre 4.0 - each GPU has its own context, and each context must be established by a different host thread. So the idea in pseudocode is:

  1. Application starts, process uses the API to determine the number of usable GPUS (beware things like compute mode in Linux)
  2. Application launches a new host thread per GPU, passing a GPU id. Each thread implicitly/explicitly calls equivalent of cuCtxCreate() passing the GPU id it has been assigned
  3. Profit!

In Python, this might look something like this:

import threading
from pycuda import driver

class gpuThread(threading.Thread):
    def __init__(self, gpuid):
        self.ctx  = driver.Device(gpuid).make_context()
        self.device = self.ctx.get_device()

    def run(self):
        print "%s has device %s, api version %s"  \
             % (self.getName(), self.device.name(), self.ctx.get_api_version())
        # Profit!

    def join(self):

ngpus = driver.Device.count()
for i in range(ngpus):
    t = gpuThread(i)

This assumes it is safe to just establish a context without any checking of the device beforehand. Ideally you would check the compute mode to make sure it is safe to try, then use an exception handler in case a device is busy. But hopefully this gives the basic idea.

  • 1
    @talonmies as always, thanks, but quick query: If I understand this correctly, each thread is 'instantiated', executed, and joined in line. Does this not cause execution to run serially? I assume that the easy fix is to break the t.join()s into a separate loop.
    – Bolster
    Commented May 6, 2011 at 15:54
  • @Andrew Bolter: Yeah, I guess the start methods should be all called in a loop, and the joins all called later. I was wondering a little about the global interpreter lock in that situation too... I must confess I used mpi4py for my python multi-gpu, I have a pthreads framework I use for multi-gpu as well, but usually only with C/C++ and Fortran.
    – talonmies
    Commented May 6, 2011 at 16:10
  • @Andrew Bolter: I just added a little bit of instrumentation to a modified version of that code I posted and I am beginning to wonder at the sanity of using python threading for this. I would not like to bet on the correctness of what I posted at this point....
    – talonmies
    Commented May 6, 2011 at 16:58
  • I suspect I'm going to refactor the problem with an aim to MPI, but it strikes me that this should be more trivial. Also, to circle around the threading deficiencies I've also been looking at multiprocessing instead.
    – Bolster
    Commented May 6, 2011 at 17:33
  • Also, I don't quite understand your 'pre-4.0' comment, as I understood it the previous context relevant multi-device operation was still supported?
    – Bolster
    Commented May 6, 2011 at 18:23

What you need is a multi-threaded implementation of the map built-in function. Here is one implementation. That, with a little modification to suit your particular needs, you get:

import threading

def cuda_map(args_list, gpu_instances):

    result = [None] * len(args_list)

    def task_wrapper(gpu_instance, task_indices):
        for i in task_indices:
            result[i] = gpu_instance.gpufunction(args_list[i])

    threads = [threading.Thread(
                    args=(gpu_i, list(xrange(len(args_list)))[i::len(gpu_instances)])
              ) for i, gpu_i in enumerate(gpu_instances)]
    for t in threads:
    for t in threads:

    return result

It is more or less the same as what you have above, with the big difference being that you don't spend time waiting for each single completion of the gpufunction.

  • Thank you for your comment, and its guided me towards a solution, but its come up against CUDA-related issues regarding device contexts. Updating question to reflect this now
    – Bolster
    Commented May 6, 2011 at 1:45

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