Relaxed Schedulers Can Efficiently Parallelize Iterative Algorithms

Dan Alistarh, Trevor Brown, Justin Kopinsky, Giorgi Nadiradze
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引用次数: 9

Abstract

There has been significant progress in understanding the parallelism inherent to iterative sequential algorithms: for many classic algorithms, the depth of the dependence structure is now well understood, and scheduling techniques have been developed to exploit this shallow dependence structure for efficient parallel implementations. A related, applied research strand has studied methods by which certain iterative task-based algorithms can be efficiently parallelized via relaxed concurrent priority schedulers. These allow for high concurrency when inserting and removing tasks, at the cost of executing superfluous work due to the relaxed semantics of the scheduler. In this work, we take a step towards unifying these two research directions, by showing that there exists a family of relaxed priority schedulers that can efficiently and deterministically execute classic iterative algorithms such as greedy maximal independent set (MIS) and matching. Our primary result shows that, given a randomized scheduler with an expected relaxation factor of k in terms of the maximum allowed priority inversions on a task, and any graph on n vertices, the scheduler is able to execute greedy MIS with only an additive factor of \poly(k) expected additional iterations compared to an exact (but not scalable) scheduler. This counter-intuitive result demonstrates that the overhead of relaxation when computing MIS is not dependent on the input size or structure of the input graph. Experimental results show that this overhead can be clearly offset by the gain in performance due to the highly scalable scheduler. In sum, we present an efficient method to deterministically parallelize iterative sequential algorithms, with provable runtime guarantees in terms of the number of executed tasks to completion.
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放松调度可以有效地并行化迭代算法
在理解迭代顺序算法固有的并行性方面已经取得了重大进展:对于许多经典算法,现在已经很好地理解了依赖结构的深度,并且已经开发了调度技术来利用这种浅层依赖结构来实现高效的并行。一个相关的应用研究链研究了一些基于迭代任务的算法可以通过放松的并发优先级调度来有效地并行化的方法。这允许在插入和删除任务时实现高并发性,但代价是由于调度器的宽松语义而导致执行多余的工作。在这项工作中,我们向统一这两个研究方向迈出了一步,通过证明存在一组放松优先级调度程序,它们可以有效地和确定性地执行经典的迭代算法,如贪婪最大独立集(MIS)和匹配。我们的主要结果表明,给定一个随机调度器,其预期松弛因子为k(就任务上允许的最大优先级反转而言),以及n个顶点上的任何图,与精确(但不可伸缩)调度器相比,该调度器能够执行贪婪MIS,其附加因子为\poly(k),预期额外迭代。这个反直觉的结果表明,计算MIS时的松弛开销不依赖于输入图的大小或结构。实验结果表明,由于高度可伸缩的调度器,这种开销可以明显地被性能增益所抵消。总之,我们提出了一种有效的方法来确定并行化迭代顺序算法,在执行任务完成的数量方面具有可证明的运行时间保证。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
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