Cédric Courtaud, Julien Sopena, Gilles Muller, D. G. Pérez
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引用次数: 10
摘要
内存干扰可能会导致运行在COTS多核处理器上的应用程序严重减速。它们是由并发访问内存系统的共享硬件资源引起的。由于引起的延迟难以预测,内存干扰成为实时系统中采用COTS多核处理器的主要障碍。在本文中,我们提出了一个实验表征应用程序的内存消耗,以确定它们对内存干扰的敏感性。由于一组新的微基准测试,我们证明了纯定量表征缺乏精度。为了提高准确性,我们定义了量化内存消耗的定性方面的新指标,并使用V ALGRIND框架实现了一个分析工具。此外,我们的分析工具产生高分辨率的分析,使我们能够清楚地区分应用程序行为的各个阶段。使用我们的微基准和我们的新特征,我们训练了一个最先进的回归器。对M I B ENCH和PARSEC套件应用程序的验证表明,与纯粹的定量表征相比,预测精度有显着提高。
Improving Prediction Accuracy of Memory Interferences for Multicore Platforms
Memory interferences may introduce important slowdowns in applications running on COTS multi-core processors. They are caused by concurrent accesses to shared hardware resources of the memory system. The induced delays are difficult to predict, making memory interferences a major obstacle to the adoption of COTS multi-core processors in real-time systems. In this article, we propose an experimental characterization of applications' memory consumption to determine their sensitivity to memory interferences. Thanks to a new set of microbenchmarks, we show the lack of precision of a purely quantitative characterization. To improve accuracy, we define new metrics quantifying qualitative aspects of memory consumption and implement a profiling tool using the V ALGRIND framework. In addition, our profiling tool produces high resolution profiles allowing us to clearly distinguish the various phases in applications' behavior. Using our microbenchmarks and our new characterization, we train a state-of-the-art regressor. The validation on applications from the M I B ENCH and the PARSEC suites indicates significant gain in prediction accuracy compared to a purely quantitative characterization.
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