Persistency for synchronization-free regions

Q1 Computer Science ACM Sigplan Notices Pub Date : 2018-06-11 DOI:10.1145/3296979.3192367

V. Gogte, S. Diestelhorst, William Wang, S. Narayanasamy, Peter M. Chen, T. Wenisch

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引用次数: 80

Abstract

Nascent persistent memory (PM) technologies promise the performance of DRAM with the durability of disk, but how best to integrate them into programming systems remains an open question. Recent work extends language memory models with a persistency model prescribing semantics for updates to PM. These semantics enable programmers to design data structures in PM that are accessed like memory and yet are recoverable upon crash or failure. Alas, we find the semantics and performance of existing approaches unsatisfying. Existing approaches require high-overhead mechanisms, are restricted to certain synchronization constructs, provide incomplete semantics, and/or may recover to state that cannot arise in fault-free execution. We propose persistency semantics that guarantee failure atomicity of synchronization-free regions (SFRs) - program regions delimited by synchronization operations. Our approach provides clear semantics for the PM state recovery code may observe and extends C++11's "sequential consistency for data-race-free" guarantee to post-failure recovery code. We investigate two designs for failure-atomic SFRs that vary in performance and the degree to which commit of persistent state may lag execution. We demonstrate both approaches in LLVM v3.6.0 and compare to a state-of-the-art baseline to show performance improvement up to 87.5% (65.5% avg).

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无同步区域的持久性

新生的持久内存(PM)技术保证了DRAM的性能和磁盘的耐用性，但是如何最好地将它们集成到编程系统中仍然是一个悬而未决的问题。最近的工作扩展了语言记忆模型，使用持久性模型规定了更新到PM的语义。这些语义使程序员能够在PM中设计数据结构，这些数据结构可以像内存一样访问，并且在崩溃或故障时可以恢复。遗憾的是，我们发现现有方法的语义和性能都不令人满意。现有的方法需要高开销的机制，受限于某些同步构造，提供不完整的语义，和/或可能恢复到在无故障执行中无法出现的状态。我们提出了保证无同步区(SFRs)——由同步操作划分的程序区域的故障原子性的持久性语义。我们的方法为PM状态恢复代码提供了清晰的语义，可以将c++ 11的“无数据竞争的顺序一致性”保证扩展到故障后恢复代码。我们研究了两种故障原子sfr的设计，它们在性能和持久状态提交可能延迟执行的程度上有所不同。我们在LLVM v3.6.0中演示了这两种方法，并与最先进的基线进行了比较，显示性能提高高达87.5%(平均65.5%)。

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来源期刊

ACM Sigplan Notices 工程技术-计算机：软件工程

CiteScore

4.90

自引率

0.00%

发文量

审稿时长

2-4 weeks

期刊介绍： The ACM Special Interest Group on Programming Languages explores programming language concepts and tools, focusing on design, implementation, practice, and theory. Its members are programming language developers, educators, implementers, researchers, theoreticians, and users. SIGPLAN sponsors several major annual conferences, including the Symposium on Principles of Programming Languages (POPL), the Symposium on Principles and Practice of Parallel Programming (PPoPP), the Conference on Programming Language Design and Implementation (PLDI), the International Conference on Functional Programming (ICFP), the International Conference on Object-Oriented Programming, Systems, Languages, and Applications (OOPSLA), as well as more than a dozen other events of either smaller size or in-cooperation with other SIGs. The monthly "ACM SIGPLAN Notices" publishes proceedings of selected sponsored events and an annual report on SIGPLAN activities. Members receive discounts on conference registrations and free access to ACM SIGPLAN publications in the ACM Digital Library. SIGPLAN recognizes significant research and service contributions of individuals with a variety of awards, supports current members through the Professional Activities Committee, and encourages future programming language enthusiasts with frequent Programming Languages Mentoring Workshops (PLMW).