软件事务性内存中的能量-性能权衡

2012 IEEE 24th International Symposium on Computer Architecture and High Performance Computing Pub Date : 2012-10-24 DOI:10.1109/SBAC-PAD.2012.19

A. Baldassin, J. P. L. Carvalho, L. A. G. Garcia, R. Azevedo

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引用次数: 9

摘要

事务性内存是一种新的同步机制，旨在简化并行编程，从而帮助程序员释放当前多核处理器的强大功能。尽管从运行时性能的角度对TM (STM)的软件实现进行了广泛的分析，但很少有人注意到几乎所有计算机系统都面临的一个同样重要的约束:能源消耗。在这项工作中，我们对软件事务性内存系统的能量和运行时权衡进行了全面的研究。我们描述了三种最先进的基于锁的STM算法的行为，以及三种不同的冲突解决方案。基于这一特征，我们提出了一种基于dvfs的技术，该技术可以集成到分辨率策略中，从而提高能量延迟积(EDP)。实验结果表明，我们的dvfs增强策略确实有利于高争用级别的应用程序。在这个场景中可以观察到EDP的改进高达59%，在STAMP工作负载中平均EDP减少了16%。

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Energy-Performance Tradeoffs in Software Transactional Memory

Transactional memory (TM) is a new synchronization mechanism devised to simplify parallel programming, thereby helping programmers to unleash the power of current multicore processors. Although software implementations of TM (STM) have been extensively analyzed in terms of runtime performance, little attention has been paid to an equally important constraint faced by nearly all computer systems: energy consumption. In this work we conduct a comprehensive study of energy and runtime tradeoff sin software transactional memory systems. We characterize the behavior of three state-of-the-art lock-based STM algorithms, along with three different conflict resolution schemes. As a result of this characterization, we propose a DVFS-based technique that can be integrated into the resolution policies so as to improve the energy-delay product (EDP). Experimental results show that our DVFS-enhanced policies are indeed beneficial for applications with high contention levels. Improvements of up to 59% in EDP can be observed in this scenario, with an average EDP reduction of 16% across the STAMP workloads.

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

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