时间扭曲:事务性内存中的有效中断减少

Pub Date : 2015-07-08 DOI:10.1145/2775435
Nuno Diegues, P. Romano
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引用次数: 6

摘要

十年前发生的多核革命已经使并行编程成为主流软件开发行业的主要关注点。在这种情况下,事务性内存(Transactional Memory, TM)作为一种比基于锁的同步更简单、更有吸引力的选择而出现,锁的同步的复杂性和易出错性已得到广泛认可。在TM中,允许的概念转换为只有在保证目标正确性标准的任何历史中不能接受事务时才终止事务。这个理论上强大的属性经常被最先进的TMs所忽略,因为它会带来相当大的算法成本。相反,这些tm选择通过在过于保守的条件下终止事务来最大化其实现的效率。因此,他们冒着拒绝大量安全处决的风险。在本文中,我们试图通过引入时间扭曲多版本(Time-Warp Multiversion, TWM)算法来确定容忍度和效率之间的平衡点。TWM的关键思想是允许执行过时读取(即错过并发提交事务的写操作)的更新事务通过“在过去提交”来序列化,我们称之为时间扭曲提交。在其核心,TWM使用了一种新颖的轻量级验证机制,计算开销很小。TWM还保证只读事务永远不会被终止。此外,TWM保证了虚拟世界的一致性,这是一个被认为与TM特别相关的安全属性。我们通过广泛的实验研究证明了这种方法的实用性:我们将TWM与其他五种典型替代设计选择的tm进行比较,并在各种基准上进行比较。该研究显示,在高并发场景中,所有考虑的工作负载和TMs的平均性能提高了65%,在最有利的基准测试中,收益可扩展到9倍。这些结果是由于TWM能够在非最小争用场景中大幅减少中断,同时在最坏情况下引入很少的开销(大约10%),综合设计的场景(即没有不能使用TWM优化的争用或争用模式)。
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Time-Warp: Efficient Abort Reduction in Transactional Memory
The multicore revolution that took place one decade ago has turned parallel programming into a major concern for the mainstream software development industry. In this context, Transactional Memory (TM) has emerged as a simpler and attractive alternative to that of lock-based synchronization, whose complexity and error-proneness are widely recognized. The notion of permissiveness in TM translates to only aborting a transaction when it cannot be accepted in any history that guarantees a target correctness criterion. This theoretically powerful property is often neglected by state-of-the-art TMs because it imposes considerable algorithmic costs. Instead, these TMs opt to maximize their implementation’s efficiency by aborting transactions under overly conservative conditions. As a result, they risk rejecting a significant number of safe executions. In this article, we seek to identify a sweet spot between permissiveness and efficiency by introducing the Time-Warp Multiversion (TWM) algorithm. TWM is based on the key idea of allowing an update transaction that has performed stale reads (i.e., missed the writes of concurrently committed transactions) to be serialized by “committing it in the past,” which we call a time-warp commit. At its core, TWM uses a novel, lightweight validation mechanism with little computational overhead. TWM also guarantees that read-only transactions can never be aborted. Further, TWM guarantees Virtual World Consistency, a safety property that is deemed as particularly relevant in the context of TM. We demonstrate the practicality of this approach through an extensive experimental study: we compare TWM with five other TMs, representative of typical alternative design choices, and on a wide variety of benchmarks. This study shows an average performance improvement across all considered workloads and TMs of 65% in high concurrency scenarios, with gains extending up to 9 × with the most favorable benchmarks. These results are a consequence of TWM’s ability to achieve drastic reduction of aborts in scenarios of nonminimal contention, while introducing little overhead (approximately 10%) in worst-case, synthetically designed scenarios (i.e., no contention or contention patterns that cannot be optimized using TWM).
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