CACTI-P: Architecture-level modeling for SRAM-based structures with advanced leakage reduction techniques

2011 IEEE/ACM International Conference on Computer-Aided Design (ICCAD) Pub Date : 2011-11-07 DOI:10.1109/ICCAD.2011.6105405

Sheng Li, Ke Chen, Jung Ho Ahn, J. Brockman, N. Jouppi

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引用次数: 227

Abstract

This paper introduces CACTI-P, the first architecture-level integrated power, area, and timing modeling framework for SRAM-based structures with advanced leakage power reduction techniques. CACTI-P supports modeling of major leakage power reduction approaches including power-gating, long channel devices, and Hi-k metal gate devices. Because it accounts for implementation overheads, CACTI-P enables in-depth study of architecture-level tradeoffs for advanced leakage power management schemes. We illustrate the potential applicability of CACTI-P in the design and analysis of leakage power reduction techniques of future manycore processors by applying nanosecond scale power-gating to different levels of cache for a 64 core multithreaded architecture at the 22nm technology. Combining results from CACTI-P and a performance simulator, we find that although nanosecond scale power-gating is a powerful way to minimize leakage power for all levels of caches, its severe impacts on processor performance and energy when being used for L1 data caches make nanosecond scale power-gating a better fit for caches closer to main memory.

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caci - p:基于sram的结构的架构级建模，具有先进的减少泄漏技术

本文介绍了caci - p，这是基于sram的结构的第一个架构级集成功率，面积和时序建模框架，具有先进的泄漏功率降低技术。caci - p支持主要泄漏功率降低方法的建模，包括功率门控、长通道器件和Hi-k金属栅极器件。由于caci - p考虑了实现开销，因此可以对高级泄漏电源管理方案的架构级权衡进行深入研究。我们通过在22nm技术下对64核多线程架构的不同级别缓存应用纳秒级功率门控，说明了caci - p在未来多核处理器的泄漏功耗降低技术设计和分析中的潜在应用。结合caci - p和性能模拟器的结果，我们发现尽管纳秒级功率门控是最小化所有级别缓存泄漏功率的强大方法，但当用于L1数据缓存时，它对处理器性能和能量的严重影响使得纳秒级功率门控更适合靠近主存储器的缓存。

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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2011 IEEE/ACM International Conference on Computer-Aided Design (ICCAD)

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