BTL: A Framework for Measuring and Modeling Energy in Memory Hierarchies

2012 IEEE 24th International Symposium on Computer Architecture and High Performance Computing Pub Date : 2012-10-24 DOI:10.1109/SBAC-PAD.2012.38

I. Manousakis, Dimitrios S. Nikolopoulos

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引用次数: 14

Abstract

Understanding the energy efficiency of computing systems is paramount. Although processors remain dominant energy consumers and the focal target of energy-aware optimization in computing systems, the memory subsystem dissipates substantial amounts of power, which at high densities may exceed50% of total system power. The failure of DRAM to keep up with increasing processor speeds, creates a two-pronged bottleneck for overall system energy efficiency. This paper presents a high-performance, autonomic power instrumentation setup to measure energy consumption in computing systems and accurately attribute energy to processors and components of the memory hierarchy. We provide a set of carefully engineered micro benchmarks that reveal the energy efficiency under different memory access patterns and stress the importance of minimizing costly data transfers that involve multiple levels of the system's memory hierarchy. Lastly, we present BTL (Bottom line), a processor specific model for deriving lower bounds of energy consumption. BTL predicts the minimum dynamic energy consumption for any workload, thus uncovering opportunities for energy optimization.

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内存层次中能量测量和建模的框架

了解计算系统的能源效率是至关重要的。尽管处理器仍然是主要的能源消耗者和计算系统中能源感知优化的焦点目标，但内存子系统消耗了大量的功率，在高密度时可能超过系统总功率的50%。DRAM无法跟上不断增长的处理器速度，会给整个系统的能源效率造成双重瓶颈。本文提出了一种高性能、自主的功率测量装置，用于测量计算系统中的能量消耗，并准确地将能量分配给处理器和内存层次结构的组件。我们提供了一组精心设计的微基准测试，揭示了不同内存访问模式下的能源效率，并强调了最小化涉及系统内存层次结构多个级别的昂贵数据传输的重要性。最后，我们提出了BTL(底线)，这是一个特定于处理器的模型，用于推导能量消耗的下界。BTL预测任何工作负载的最小动态能耗，从而发现能源优化的机会。

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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2012 IEEE 24th International Symposium on Computer Architecture and High Performance Computing

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