Can anyone provide me with a parallel algorithm for calculating the sparse Cholesky factorization? It must be suitable for execution on a GPU. Any answers in CUDA, OpenCL, or even pseudocode would be much appreciated.
closed as offtopic by Christian Rau, sashkello, glts, wudzik, Drew Sep 14 '13 at 15:30This question appears to be offtopic. The users who voted to close gave these specific reasons:



Generally speaking, direct sparse methods are not a great fit for the GPU. While the best direct solvers (thinking about packages like CHOLMOD, SuperLU, MUMPS here) use strategies to generate dense sub blocks which can be processed using L3 BLAS, the size and shape of the blocks don't tend to profit from using a GPU BLAS for acceleration. It doesn't mean it can't be done, just that the performance improvements may not be worth the effort. Seeing as you are asking about a sparse Cholesky factorization, I assumed the matrix is symmetric positive definite. In that case you might consider using an iterative solver  there are a number of good implementations of Conjugate Gradient and other Krylov subspace methods with simple preconditioners which might be of some use. The Cusp library for CUDA might be worth investigating if your problem is amenable to iterative methods. The ViennaCL library offers something similar if you are looking for OpenCL. 


See UHM  Unassembled Hyper Matrix solver. It can calculates sparse Cholesky factorization using multiple GPU on one host. 


Sparse Cholesky factorizations on a GPU is an open problem. Even the Linear Programming paper mentioned previously uses a dense algorithm while most problems are sparse. The commercial LP solver market is very competitive, but nobody has a product that makes much use of the GPU yet. 


The multifrontal algorithm seems to be a popular choice for parallel sparse factorisation. Check out the As I understand it, the code makes extensive use of level 3 Contrary to dense factorisation, sparse methods always include a nonnegligible amount of integer work in addition to the floatingpoint work done (though the floatingpoint is still dominant). I'm no expert on Hope this helps. 


Check out these articles, courtesy of the ACM (SC'08 and PPoPP '09 are excellent conferences). V. Volkov, J. W. Demmel. Benchmarking GPUs to tune dense linear algebra. SC'08. Jung, J.H., O’Leary, D.P. Cholesky Decomposition and Linear Programming on a GPU. Scholarly Paper, University of Maryland, 2006. G. QuintanaOrti, F. D. Igual, E. S. QuintanaOrti, R. A. van de Geijn. Solving dense linear systems on platforms with multiple hardware accelerators. PPoPP '09. If you don't have access to these through the ACM Portal/DL, they might be online somewhere. Otherwise... I can probably quote some of the most relevant sections, with citations, and have it be fair use. EDIT: Check this out maybe? EDIT2: Missed the part about "sparse". Looking around online and at the ACM/IEEE, I don't see a lot that jumps out at me. What I do see doesn't sound promising... this might not be a computation where you see a lot of benefit from using the GPU. 

