系统级最大功率(SYMPO)——一种使用综合基准提高系统级功耗的系统方法

K. Ganesan, Jungho Jo, W. Bircher, Dimitris Kaseridis, Zhibin Yu, L. John
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引用次数: 38

摘要

为了有效地为最坏的功耗场景设计计算机系统,系统架构师通常在汇编语言级别使用手工制作的最大功耗基准。这些压力标记,也称为权力病毒,生成起来非常繁琐,需要大量的领域知识。本文提出了一个系统级最大功率病毒自动生成框架SYMPO,该框架采用遗传算法和抽象工作负载生成框架,最大限度地提高了CPU和内存系统的功耗。对于一组三个isa,我们通过比较使用SYMPO生成的功率病毒的功耗与业界广泛用于测试系统稳定性的MPrime折磨测试的功耗来显示功率病毒的有效性。我们的结果表明,与SPARC ISA上的MPrime相比,使用SYMPO会导致生成功耗病毒,其功耗高出14-41%。当使用完整的系统模拟器时,遗传算法在11到15小时内实现了大约70到90代的结果。我们还表明,与之前的压力标记生成方法相比,在Alpha ISA中生成的功率病毒消耗的功率多9-24%。我们通过测量四核AMD飞鸿II X4系统来测量和提供这些基准测试在硬件上的功耗。与x86硬件上的各种工业级电源病毒相比,SYMPO电源病毒消耗更多的电源。我们还提供了各种行业标准电源病毒的微架构独立表征。
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System-level Max POwer (SYMPO) - a systematic approach for escalating system-level power consumption using synthetic benchmarks
To effectively design a computer system for the worst case power consumption scenario, system architects often use hand-crafted maximum power consuming benchmarks at the assembly language level. These stressmarks, also called power viruses, are very tedious to generate and require significant domain knowledge. In this paper, we propose SYMPO, an automatic SYstem level Max POwer virus generation framework, which maximizes the power consumption of the CPU and the memory system using genetic algorithm and an abstract workload generation framework. For a set of three ISAs, we show the efficacy of the power viruses generated using SYMPO by comparing the power consumption with that of MPrime torture test, which is widely used by industry to test system stability. Our results show that the usage of SYMPO results in the generation of power viruses that consume 14–41% more power compared to MPrime on SPARC ISA. The genetic algorithm achieved this result in about 70 to 90 generations in 11 to 15 hours when using a full system simulator. We also show that the power viruses generated in the Alpha ISA consume 9–24% more power compared to the previous approach of stressmark generation. We measure and provide the power consumption of these benchmarks on hardware by instrumenting a quad-core AMD Phenom II X4 system. The SYMPO power virus consumes more power compared to various industry grade power viruses on x86 hardware. We also provide a microarchitecture independent characterization of various industry standard power viruses.
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