Applying the swept rule for solving explicit partial differential equations on heterogeneous computing systems

Applications that exploit the architectural details of high-performance computing (HPC) systems have become increasingly invaluable in academia and industry over the past two decades. The most important hardware development of the last decade in HPC has been the general purpose graphics processing u...

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Bibliographic Details
Published inThe Journal of supercomputing Vol. 77; no. 2; pp. 1976 - 1997
Main Authors Magee, Daniel J., Walker, Anthony S., Niemeyer, Kyle E.
Format Journal Article
LanguageEnglish
Published New York Springer US 01.02.2021
Springer Nature B.V
Subjects
Compilers
Computation
Computer Science
Costs
Decomposition
Euler-Lagrange equation
Graphics processing units
Interpreters
Mathematical analysis
Partial differential equations
Processor Architectures
Programming Languages
Supercomputers
Thermodynamics
Partial differential equations
Computational fluid dynamics
Heterogeneous computing
Domain decomposition
Communication-avoiding algorithms
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Summary:Applications that exploit the architectural details of high-performance computing (HPC) systems have become increasingly invaluable in academia and industry over the past two decades. The most important hardware development of the last decade in HPC has been the general purpose graphics processing unit (GPGPU), a class of massively parallel devices that now contributes the majority of computational power in the top 500 supercomputers. As these systems grow, small costs such as latency—due to the fixed cost of memory accesses and communication—accumulate in a large simulation and become a significant barrier to performance. The swept time-space decomposition rule is a communication-avoiding technique for time-stepping stencil update formulas that attempts to reduce latency costs. This work extends the swept rule by targeting heterogeneous, CPU/GPU architectures representing current and future HPC systems. We compare our approach to a naive decomposition scheme with two test equations using an MPI+CUDA pattern on 40 processes over two nodes containing one GPU. The swept rule produces a factor of 1.9 to 23 speedup for the heat equation and a factor of 1.1 to 2.0 speedup for the Euler equations, using the same processors and work distribution, and with the best possible configurations. These results show the potential effectiveness of the swept rule for different equations and numerical schemes on massively parallel compute systems that incur substantial latency costs.
ISSN:0920-8542
1573-0484
DOI:10.1007/s11227-020-03340-9