L. Gan, Jingheng Xu, Xin Wang, Sihai Wu, Xiaohui Duan, Yuxuan Li, H. Fu, Guangwen Yang
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引用次数: 3
摘要
偏移算法是地震应用中最重要的地下地质成像方法之一,可以帮助地球物理勘探工作者更好地了解地球系统。然而,由于迁移算法需要覆盖更大的区域和获得更好的分辨率,对于当前最先进的计算系统来说,必须解决许多棘手的挑战。本工作将弹性迁移算法优化并扩展到世界上最强大的系统之一神威太湖之光超级计算机上。针对主要进程,提出了一套算法级、进程级和线程级优化的逆时间迁移(reverse time migration, RTM)算法,以显著提高神威CPU的性能(最快可达163倍的求解时间加速)。我们的设计在神威太湖之光超级计算机上成功地扩展到200多万核(总共2662400核),具有近乎理想的弱缩放效率。最大的运行能够实现每秒处理超过8590亿个单元的可持续性能。
Million-Core-Scalable Simulation of the Elastic Migration Algorithm on Sunway TaihuLight Supercomputer
Migration algorithm is one of the most essential methods in seismic application to image the underground geology, and to help scientists and researchers in geophysics exploration better understand the earth system. However, due to the desire in migration algorithm for covering lager region and acquiring better resolution, many tough challenges have to be tackled for current state-of-the-art computing systems. This work optimized and scaled the elastic migration algorithm onto the Sunway TaihuLight supercomputer, one of the most powerful systems of the world. Targeting at the major process, the reverse time migration (RTM) algorithm, a set of algorithmic, process-level, and thread-level optimizations is proposed, to significantly improve the performance (up to 163× speedup in time-to-solution) on Sunway CPU. Our design is successfully scaled to over two million cores (2,662,400 cores in total) on the Sunway TaihuLight supercomputer, with nearly ideal weak-scaling efficiency. The largest run is able to achieve a sustainable performance of processing over 859 billion cells per second.
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