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I'm looking for a way to find the pseudo-inverse of a matrix so it can be done on the GPU. SVD/QR are difficult to parallelize and are not supported but MATLAB's GPU, but it seems that LU, though can be run in parallel is not supported by MATLAB's GPU as well. I compared performance and it seems to be slower than running on a single core CPU.

I am looking for a pseudo inverse (or even a regular inverse for square matrices) that I can use. According to Matlab, using mldivide () performs Gauss elimination which is applicable for GPUs.

I tried using A\I but unfortunately it does not run efficiently on GPUs.

Does anyone can direct me to an optimized code for parallel LU or Gaussian elimination?

I heard of the MAGMA package, but it seems a lot of work to install and to compile and I really need this simple thing.

A C++ code is also welcome.

Thanks, Gil

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closed as off-topic by Eitan T, Balog Pal, skuntsel, Mario, Vamsi Jul 1 '13 at 2:36

This question appears to be off-topic. The users who voted to close gave this specific reason:

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Your question sounds confusing... A \ eye(size(A, 1)) is in general not the Moore Penrose pseudo inverse of A; moreover MATLAB has some support for SVD on gpu. In order to give you a sensible answer we will need more information: size, rank, and other properties of A, and exactly what type of generalized inverse you are interested in. Generalized inverses are seldom used in linear algebra: stating tha actual problem you are trying to solve by the computation of a generalized inverse of A could also be useful. –  Stefano M Jun 22 '13 at 14:06
afaik, MATLAB uses the MAGMA package for some of its operations on the GPU. Here is a list of the functions that gpuArray supports: mathworks.com/help/distcomp/using-gpuarray.html#bsloua3-1 –  Amro Jun 22 '13 at 20:26
@Gil: pinv(A) is similar to V*diag(1./diag(S))*U' where [U,S,V] = svd(A). But as was said, you rarely need the inverse of a matrix itself, mldivide/mrdivide are usually what you use. –  Amro Jun 26 '13 at 17:21

2 Answers 2

In MATLAB R2013a, LU, QR and SVD are all supported on the gpu through gpuArray. There's a list of supported functions here: http://www.mathworks.co.uk/help/distcomp/using-gpuarray.html#bsloua3-1 . The linear algebra functions of gpuArray are all implemented using MAGMA.

A\b can run efficiently on the GPU, see this example: http://www.mathworks.co.uk/help/distcomp/examples/benchmarking-a-b-on-the-gpu.html . As the problem size increases, you can expect a decently powerful GPU (e.g. Tesla) to run up to 5 times faster than the CPU.

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Thanks. I tried A\eye on GPU and it was actually slower. Perhaps it was because I'm using 2012b. Thanks! –  Gil Jun 24 '13 at 11:30
I wouldn't expect a large performance difference for A\b between R2012b and R2013a - your problem size / GPU hardware are much more likely to be important. –  Edric Jun 24 '13 at 12:07


ABSTRACT In this project several mathematic algorithms are developed to obtain a matrix inversion method - that combines CUDA’s parallel architecture and MATLAB – which is actually faster than MATLAB’s built in inverse matrix function. This matrix inversion method is intended to be used for image reconstruction as a faster alternative to iterative methods with a comparable quality. The algorithms developed in this project are Gauss-Jordan elimination, Cholesky decomposition, Gaussian elimination and matrix multiplication.

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