Parallel-algorithm extension for tsunami and earthquake-cycle simulators for massively parallel execution on the K computer-Reference-Cited by-同舟云学术

Parallel-algorithm extension for tsunami and earthquake-cycle simulators for massively parallel execution on the K computer

Published:2016-07-27 Issue:4 Volume:30 Page:454-468
ISSN:1094-3420
Container-title:The International Journal of High Performance Computing Applications
language:en
Short-container-title:The International Journal of High Performance Computing Applications

Author:

Ando Kazuto¹,Hyodo Mamoru²,Baba Toshitaka³,Hori Takane²,Kato Toshihiro⁴,Watanabe Masaru⁵,Ichikawa Shin-ichi⁵,Kitahara Hisakuni⁶,Uehara Hitoshi¹,Inoue Hikaru⁵

Affiliation:

1. Center for Earth Information Science and Technology, Japan Agency for Marine-Earth Science and Technology, Yokohama, Japan

2. Research and Development Center for Earthquake and Tsunami, Japan Agency for Marine-Earth Science and Technology, Yokohama, Japan

3. Institute of Technology and Science, University of Tokushima, Tokushima, Japan

4. 1st Government and Public Solution Division, NEC Corporation, Tokyo, Japan

5. HPC Application Solutions Division, Technical Computing Solutions Unit, Fujitsu Ltd, Chiba, Japan

6. Integration Business Division, Fujitsu Social Science Laboratory Ltd, Kawasaki, Japan

Abstract

This article presents a case study on the extension of parallel algorithms in tsunami and earthquake-cycle simulators for massively parallel execution on the K computer. We use two target applications: a tsunami-simulation program, “JAGURS,” and an earthquake-cycle program, “RSGDX.” Our optimization strategy for collective communication is to split the Message Passing Interface (MPI) communicator and perform multistage localized communication to minimize the communication frequency, transferred data size, and network congestion. Moreover, in the case of severe load imbalances, we apply cyclic distribution and extend the axes for parallelization. For each application, we conduct a performance evaluation with massively parallel execution on the K computer. It is shown that our optimized code enables JAGURS to attain a 21.8× speedup for collective communication and a 7.9× speedup for the time-step loop on 8748 nodes (69,984 cores). RSGDX attains a 4.25× speedup for collective communication and an 18.7× speedup for the time-step loop on 8192 nodes (65,536 cores).

Publisher

SAGE Publications

Subject

Hardware and Architecture,Theoretical Computer Science,Software

Link

http://journals.sagepub.com/doi/pdf/10.1177/1094342016636670

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