不规则应用程序的压力驱动硬件管理线程并发

Proceedings of the Seventh Workshop on Irregular Applications: Architectures and Algorithms Pub Date : 2017-11-12 DOI:10.1145/3149704.3149705

John D. Leidel, Xi Wang, Yong Chen

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引用次数: 3

摘要

鉴于高效数据密集型计算的重要性日益增加，我们发现现代处理器设计并不适合这些算法中发现的不规则内存访问模式。本研究的重点是将编译器的指令成本调度逻辑映射到硬件管理的并发控制，以最大限度地减少管道停滞。通过这种方式，现代编译器可以直接理解管理低延迟线程并发性的硬件模块。我们引入了一种线程上下文切换方法，该方法通过一组与编译器指令调度程序耦合的基于硬件的机制直接管理。当线程中的单个指令执行时，它们各自的开销会累积到控制寄存器中。一旦寄存器达到预先确定的饱和点，线程就被迫进行上下文切换。我们使用一系列24个基准测试来评估我们的方法的性能优势，这些基准测试显示性能加速高达14.6倍。

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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Pressure-Driven Hardware Managed Thread Concurrency for Irregular Applications

Given the increasing importance of efficient data intensive computing, we find that modern processor designs are not well suited to the irregular memory access patterns found in these algorithms. This research focuses on mapping the compiler's instruction cost scheduling logic to hardware managed concurrency controls in order to minimize pipeline stalls. In this manner, the hardware modules managing the low-latency thread concurrency can be directly understood by modern compilers. We introduce a thread context switching method that is managed directly via a set of hardware-based mechanisms that are coupled to the compiler instruction scheduler. As individual instructions from a thread execute, their respective cost is accumulated into a control register. Once the register reaches a pre-determined saturation point, the thread is forced to context switch. We evaluate the performance benefits of our approach using a series of 24 benchmarks that exhibit performance acceleration of up to 14.6X.

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Proceedings of the Seventh Workshop on Irregular Applications: Architectures and Algorithms

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