Full-system chip multiprocessor power evaluations using FPGA-based emulation

Proceeding of the 13th international symposium on Low power electronics and design (ISLPED '08) Pub Date : 2008-08-11 DOI:10.1145/1393921.1394010

A. Bhattacharjee, Gilberto Contreras, M. Martonosi

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引用次数: 49

Abstract

The design process for chip multiprocessors (CMPs) requires extremely long simulation times to explore performance, power, and thermal issues, particularly when operating system (OS) effects are included. In response, our novel FPGA-based emulation methodology models a full CMP design including applications and an OS. Activity counters programmed into the cores feed per-component microarchitectural power models. These models achieve under 10% error compared to detailed gate-level simulations. Our method retains software flexibility, but offers up to 35x speedup compared to corresponding full-system software simulations. We present our approach by emulating a 2-core Leon3 cache-coherent multiprocessor running Linux and parallel benchmarks. In an example case study, our emulated system uses activity counts (a proxy for temperature) to guide process migration between the CMP cores. Overall, this paper's methodology makes possible detailed power and thermal studies of CMPs and their operating systems.

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基于fpga仿真的全系统芯片多处理器功耗评估

芯片多处理器(cmp)的设计过程需要非常长的模拟时间来探索性能、电源和热问题，特别是在包括操作系统(OS)影响时。作为回应，我们新颖的基于fpga的仿真方法模拟了一个完整的CMP设计，包括应用程序和操作系统。编程到核心中的活动计数器提供每个组件的微架构功率模型。与详细的门级模拟相比，这些模型的误差低于10%。我们的方法保留了软件的灵活性，但与相应的全系统软件模拟相比，提供了高达35倍的加速。我们通过模拟运行Linux和并行基准测试的2核Leon3缓存一致多处理器来展示我们的方法。在一个示例案例研究中，我们的仿真系统使用活动计数(温度的代理)来指导CMP核心之间的进程迁移。总体而言，本文的方法使得cmp及其操作系统的详细功率和热研究成为可能。

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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Proceeding of the 13th international symposium on Low power electronics and design (ISLPED '08)

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