A scalable parallel algorithm for dynamic range-limited n-tuple computation in many-body molecular dynamics simulation

2013 SC - International Conference for High Performance Computing, Networking, Storage and Analysis (SC) Pub Date : 2013-11-17 DOI:10.1145/2503210.2503235

Manaschai Kunaseth, R. Kalia, A. Nakano, K. Nomura, P. Vashishta

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引用次数: 12

Abstract

Recent advancements in reactive molecular dynamics (MD) simulations based on many-body interatomic potentials necessitate efficient dynamic n-tuple computation, where a set of atomic n-tuples within a given spatial range is constructed at every time step. Here, we develop a computation-pattern algebraic framework to mathematically formulate general n-tuple computation. Based on translation/reflection-invariant properties of computation patterns within this framework, we design a shift-collapse (SC) algorithm for cell-based parallel MD. Theoretical analysis quantifies the compact n-tuple search space and small communication cost of SC-MD for arbitrary n, which are reduced to those in best pair-computation approaches (e.g. eighth-shell method) for n = 2. Benchmark tests show that SC-MD outperforms our production MD code at the finest grain, with 9.7-and 5.1-fold speedups on Intel-Xeon and BlueGene/Q clusters. SC-MD also exhibits excellent strong scalability.

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多体分子动力学模拟中动态范围有限n元组计算的可扩展并行算法

基于多体原子间势的反应分子动力学(MD)模拟的最新进展需要高效的动态n元组计算，其中在每个时间步长构建给定空间范围内的一组原子n元组。在这里，我们开发了一个计算模式代数框架，以数学方式表述一般的n元组计算。基于该框架内计算模式的平移/反射不变特性，我们设计了一种基于cell的并行MD的shift-collapse (SC)算法。理论分析量化了任意n下SC-MD的紧凑n元组搜索空间和较小的通信开销，并将其简化为n = 2时的最佳对计算方法(如八壳法)。基准测试表明，SC-MD在最细粒度上优于我们的生产MD代码，在Intel-Xeon和BlueGene/Q集群上的速度提高了9.7倍和5.1倍。SC-MD还具有很强的可扩展性。

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2013 SC - International Conference for High Performance Computing, Networking, Storage and Analysis (SC)

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