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Main Authors: Ichimura, Tsuyoshi, Fujita, Kohei, Hori, Muneo, Maddegedara, Lalith, Wells, Jack, Gray, Alan, Karlin, Ian, Linford, John
Format: Preprint
Published: 2024
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Online Access:https://arxiv.org/abs/2409.20380
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author Ichimura, Tsuyoshi
Fujita, Kohei
Hori, Muneo
Maddegedara, Lalith
Wells, Jack
Gray, Alan
Karlin, Ian
Linford, John
author_facet Ichimura, Tsuyoshi
Fujita, Kohei
Hori, Muneo
Maddegedara, Lalith
Wells, Jack
Gray, Alan
Karlin, Ian
Linford, John
contents We propose a CPU-GPU heterogeneous computing method for solving time-evolution partial differential equation problems many times with guaranteed accuracy, in short time-to-solution and low energy-to-solution. On a single-GH200 node, the proposed method improved the computation speed by 86.4 and 8.67 times compared to the conventional method run only on CPU and only on GPU, respectively. Furthermore, the energy-to-solution was reduced by 32.2-fold (from 9944 J to 309 J) and 7.01-fold (from 2163 J to 309 J) when compared to using only the CPU and GPU, respectively. Using the proposed method on the Alps supercomputer, a 51.6-fold and 6.98-fold speedup was attained when compared to using only the CPU and GPU, respectively, and a high weak scaling efficiency of 94.3% was obtained up to 1,920 compute nodes. These implementations were realized using directive-based parallel programming models while enabling portability, indicating that directives are highly effective in analyses in heterogeneous computing environments.
format Preprint
id arxiv_https___arxiv_org_abs_2409_20380
institution arXiv
publishDate 2024
record_format arxiv
spellingShingle Heterogeneous computing in a strongly-connected CPU-GPU environment: fast multiple time-evolution equation-based modeling accelerated using data-driven approach
Ichimura, Tsuyoshi
Fujita, Kohei
Hori, Muneo
Maddegedara, Lalith
Wells, Jack
Gray, Alan
Karlin, Ian
Linford, John
Computational Engineering, Finance, and Science
We propose a CPU-GPU heterogeneous computing method for solving time-evolution partial differential equation problems many times with guaranteed accuracy, in short time-to-solution and low energy-to-solution. On a single-GH200 node, the proposed method improved the computation speed by 86.4 and 8.67 times compared to the conventional method run only on CPU and only on GPU, respectively. Furthermore, the energy-to-solution was reduced by 32.2-fold (from 9944 J to 309 J) and 7.01-fold (from 2163 J to 309 J) when compared to using only the CPU and GPU, respectively. Using the proposed method on the Alps supercomputer, a 51.6-fold and 6.98-fold speedup was attained when compared to using only the CPU and GPU, respectively, and a high weak scaling efficiency of 94.3% was obtained up to 1,920 compute nodes. These implementations were realized using directive-based parallel programming models while enabling portability, indicating that directives are highly effective in analyses in heterogeneous computing environments.
title Heterogeneous computing in a strongly-connected CPU-GPU environment: fast multiple time-evolution equation-based modeling accelerated using data-driven approach
topic Computational Engineering, Finance, and Science
url https://arxiv.org/abs/2409.20380