基于gpu异步调度的蒙特卡罗中子传输散度减小

IF 0.7 4区 计算机科学 Q4 COMPUTER SCIENCE, INTERDISCIPLINARY APPLICATIONS
Braxton Cuneo, Mike Bailey
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引用次数: 0

摘要

虽然蒙特卡罗中子输运(MCNT)几乎是令人尴尬的并行,但在gpu上评估MCNT时,中子的有效不可预测的寿命可能导致分歧。发散是指经纱中相邻线程执行不同控制流路径的现象;在gpu上,它会降低性能,因为每个工作组一次只能执行一条路径。线程数据重新映射(TDR)过程通过在硬件之间移动数据来解决这些差异,从而使相同warp中的数据通过相似的路径进行处理。TDR以前实现中的一个常见问题是其重新映射和处理周期的同步性,这将对先前处理过程产生的数据进行彻底排序,并对排序后的数据进行彻底评估。在另一篇论文中,我们定义了一种通过异步调度程序重新映射数据的方法,该方法允许将工作存储在共享内存中并任意延迟,直到该工作成为低发散评估的可行选择。本文调查了一组更广泛的案例,目的是通过一组更全面的参数来描述性能趋势。这些参数包括散射/捕获/裂变的横截面、隐式捕获的使用、源中子计数、模拟时间跨度和调优内存分配。在这些情况下,我们记录了最小和平均执行时间,以及针对同步和异步调度的启发式调整的接近最佳的内存分配大小。通过收集的数据可以看出,异步方法在大多数情况下更快,内存效率更高,并且需要更少的调优来实现具有竞争力的性能。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Divergence Reduction in Monte Carlo Neutron Transport with On-GPU Asynchronous Scheduling
While Monte Carlo Neutron Transport (MCNT) is near-embarrasingly parallel, the effectively unpredictable lifetime of neutrons can lead to divergence when MCNT is evaluated on GPUs. Divergence is the phenomenon of adjacent threads in a warp executing different control flow paths; on GPUS, it reduces performance because each work group may only execute one path at a time. The process of Thread Data Remapping (TDR) resolves these discrepancies by moving data across hardware such that data in the same warp will be processed through similar paths. A common issue among prior implementations of TDR is the synchronous nature of its remapping and processing cycles, which exhaustively sort data produced by prior processing passes and exhaustively evaluate the sorted data. In another paper, we defined a method of remapping data through an asynchronous scheduler which allows for work to be stored in shared memory and deferred arbitrarily until that work is a viable option for low-divergence evaluation. This paper surveys a wider set of cases, with the goal of characterizing performance trends across a more comprehensive set of parameters. These parameters include cross sections of scattering/capturing/fission, use of implicit capture, source neutron counts, simulation time spans, and tuned memory allocations. Across these cases, we have recorded minimum and average execution times, as well as a heuristically-tuned near-optimal memory allocation size for both synchronous and asynchronous scheduling. Across the collected data, it is shown that the asynchronous method is faster and more memory efficient in the majority of cases, and that it requires less tuning to achieve competitive performance.
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来源期刊
ACM Transactions on Modeling and Computer Simulation
ACM Transactions on Modeling and Computer Simulation 工程技术-计算机:跨学科应用
CiteScore
2.50
自引率
22.20%
发文量
29
审稿时长
>12 weeks
期刊介绍: The ACM Transactions on Modeling and Computer Simulation (TOMACS) provides a single archival source for the publication of high-quality research and developmental results referring to all phases of the modeling and simulation life cycle. The subjects of emphasis are discrete event simulation, combined discrete and continuous simulation, as well as Monte Carlo methods. The use of simulation techniques is pervasive, extending to virtually all the sciences. TOMACS serves to enhance the understanding, improve the practice, and increase the utilization of computer simulation. Submissions should contribute to the realization of these objectives, and papers treating applications should stress their contributions vis-á-vis these objectives.
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