Title :
Scaling lattice QCD beyond 100 GPUs
Author :
Babich, R. ; Clark, M.A. ; Joo, Balint ; Shi, Guangming ; Brower, R.C. ; Gottlieb, S.
Author_Institution :
Center for Comput. Sci., Boston Univ., Boston, MA, USA
Abstract :
Over the past five years, graphics processing units (GPUs) have had a transformational effect on numerical lattice quantum chromodynamics (LQCD) calculations in nuclear and particle physics. While GPUs have been applied with great success to the post-Monte Carlo "analysis" phase which accounts for a substantial fraction of the workload in a typical LQCD calculation, the initial Monte Carlo "gauge field generation" phase requires capability-level supercomputing, corresponding to O(100) GPUs or more. Such strong scaling has not been previously achieved. In this contribution, we demonstrate that using a multi-dimensional parallelization strategy and a domain-decomposed preconditioner allows us to scale into this regime. We present results for two popular discretizations of the Dirac operator, Wilson-clover and improved staggered, employing up to 256 GPUs on the Edge cluster at Lawrence Livermore National Laboratory.
Keywords :
Monte Carlo methods; graphics processing units; Dirac operator; Edge cluster; GPU; Lawrence Livermore National Laboratory; Monte Carlo gauge field generation phase; Wilson-clover; capability-level supercomputing; domain-decomposed preconditioner; graphics processing unit; multidimensional parallelization strategy; nuclear physics; numerical lattice quantum chromodynamics calculation; particle physics; post-Monte Carlo analysis phase; scaling lattice QCD; substantial fraction; Color; Equations; Graphics processing unit; Lattices; Libraries; Mathematical model; Physics; GPU; Krylov solvers; Lattice QCD; domain decomposition;
Conference_Titel :
High Performance Computing, Networking, Storage and Analysis (SC), 2011 International Conference for
Conference_Location :
Seatle, WA
Electronic_ISBN :
978-1-4503-0771-0
