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I'm attempting to optimise an application in realtime 3D modelling. The compute part of the application runs almost entirely on the GPU in CUDA. The application requires the solution of a small (6x6) double precision symmetric positive definite linear system Ax = b 500+ times per second. Currently this is being done with an efficient CPU based Linear Algebra library using Cholesky but necessitates the copying of data from the CPU - GPU and back to GPU hundreds of times per second and the overhead of kernel launches each time etc.

How can I calculate the solution to the linear system on the GPU solely without having to take the data onto the CPU at all? I've read a little about the MAGMA library but it seems to use hybrid algorithms rather than GPU only algorithms.

I'm prepared for the fact that the solution of an individual linear system on the GPU is going to be a lot slower than with the existing CPU based library but I want to see if that can be made up for by removing the data communication between the host and device and the overhead of kernel launches etc hundreds of times per second. If there is no GPU only LAPACK-like alternative out there how would I go about implementing something to solve this particular 6x6 case on the GPU only? Could it be done without a huge time investment with GPU BLAS libraries for example?

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  • A 6x6 linear system is so small, that you could write the equations yourself inside CUDA code... Obviously for such a small system it would be very hard to get any benefit from the parallel nature of CUDA, but getting rid of the GPU-CPU communication would give a huge benefit indeed. Would it be possible, that you parallelize in a different way? Solve the system on a single GPU core and then use multiple cores achive 500+ solutions / s. That would be the best, unless you need results from the previous system to start working on the next one.
    – Eiver
    Jul 29, 2012 at 17:35
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    @Eiver is on the money. can you do those 500 in parallel or are they dependent on each other? for 6x6 this approach en.wikipedia.org/wiki/Cholesky_decomposition#Block_variant looks hand-codable... Jul 29, 2012 at 18:12

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NVIDIA posted code for a batched Ax=b solver to the registered developer website last fall. This code works for generic matrices, and should work well enough for your needs provided you can expand the symmetric matrices to full matrices (that should not be an issue for a 6x6?). As the code performs pivoting, which is unnecessary for positive definite matrices, it is not optimal for your case, but you may be able to modify it for your purposes as the code is under a BSD license.

NVIDIA's standard developer website is experiencing some issues at the moment. Here is how you can download the batched solver code at this time:

(1) Go to http://www.nvidia.com/content/cuda/cuda-toolkit.html

(2) If you have an existing NVdeveloper account (e.g. via partners.nvidia.com) click on the green "Login to nvdeveloper" link on the right half of the screen. Otherwise click on "Join nvdeveloper" to apply for a new account; requests for new accounts are typically approved within one business day.

(3) Log in at the prompt with your email address and password

(4) There is a section on the right hand side titled "Newest Downloads". The fifth item from the top is "Batched Solver". Click on that and it will bring you to the download page for the code.

(5) Click on the "download" link, then click "Accept" to accept the license terms. Your download should start.

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  • Thank you very much, from an initial look at the Batched Solver it looks like it will do what I'm looking for. Jul 31, 2012 at 14:28
  • I just asked another question about linear algebra and GPUs which you might know something about! stackoverflow.com/questions/11778981/… Aug 2, 2012 at 13:58

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