基于记忆的大内存系统分子动力学模拟

Zhen Xie, Wenqian Dong, Jie Liu, I. Peng, Yanbao Ma, Dong Li
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引用次数: 17

摘要

分子动力学(MD)模拟是模拟粒子系综的基本方法。在本文中,我们介绍了一种利用新兴的tb级大存储系统来提高MD性能的新方法。特别是,我们用内存容量换取计算能力,通过基于查找表的记忆技术来提高MD的性能。传统的记忆技术用于MD模拟使用相对较小的DRAM,基于次优数据结构,并取代成对计算,这导致大内存系统的性能优势有限。我们介绍了MD- hm,一个为大存储系统定制的基于记忆的MD仿真框架。MD-HM将仿真场划分为子网格,并基于轻量级模式匹配算法将每个子网格中的计算作为一个整体替换,以识别子网格中的计算。MD-HM使用新的两阶段lsm树来优化读/写性能。通过9次MD模拟评估,我们发现MD- hm在基于Intel optane的大内存系统上的平均加速速度为7.6倍,优于最先进的LAMMPS模拟框架。
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MD-HM: memoization-based molecular dynamics simulations on big memory system
Molecular dynamics (MD) simulation is a fundamental method for modeling ensembles of particles. In this paper, we introduce a new method to improve the performance of MD by leveraging the emerging TB-scale big memory system. In particular, we trade memory capacity for computation capability to improve MD performance by the lookup table-based memoization technique. The traditional memoization technique for the MD simulation uses relatively small DRAM, bases on a suboptimal data structure, and replaces pair-wise computation, which leads to limited performance benefit in the big memory system. We introduce MD-HM, a memoization-based MD simulation framework customized for the big memory system. MD-HM partitions the simulation field into subgrids, and replaces computation in each subgrid as a whole based on a lightweight pattern-match algorithm to recognize computation in the subgrid. MD-HM uses a new two-phase LSM-tree to optimize read/write performance. Evaluating with nine MD simulations, we show that MD-HM outperforms the state-of-the-art LAMMPS simulation framework with an average speedup of 7.6x based on the Intel Optane-based big memory system.
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