能量和热感知缓冲区缓存替换算法

Jianhui Yue, Yifeng Zhu, Zhao Cai, Lin Lin
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引用次数: 12

摘要

功耗是数据服务器日益关注的问题,因为它直接影响运行成本和系统可靠性。先前的研究表明,数据服务器上的大部分内存空间用于缓冲缓存,因此缓存替换变得至关重要。暂时地将内存访问集中到一组较小的内存芯片上,增加了通过DMA重叠搭便车的机会,也增加了其他队列断电的机会。提出了一种功率和热感知的缓存替换算法。它推测持有最多冷块的内存等级很可能在不久的将来被访问。从这个等级中选择受害块可以帮助减少同时活动的内存等级的数量。我们使用三个真实的I/O服务器跟踪,包括TPC-C, LM-TBF和MSN-BEFS来评估我们的算法。实验结果表明,该算法可以比LRU节省27%的能量,并在性能几乎没有下降的情况下将内存温度降低到5.45°C。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Energy and thermal aware buffer cache replacement algorithm
Power consumption is an increasingly impressing concern for data servers as it directly affects running costs and system reliability. Prior studies have shown most memory space on data servers are used for buffer caching and thus cache replacement becomes critical. Temporally concentrating memory accesses to a smaller set of memory chips increases the chances of free riding through DMA overlapping and also enlarges the opportunities for other ranks to power down. This paper proposes a power and thermal-aware buffer cache replacement algorithm. It conjectures that the memory rank that holds the most amount of cold blocks are very likely to be accessed in the near future. Choosing the victim block from this rank can help reduce the number of memory ranks that are active simultaneously. We use three real-world I/O server traces, including TPC-C, LM-TBF and MSN-BEFS to evaluate our algorithm. Experimental results show that our algorithm can save up to 27% energy than LRU and reduce the temperature of memory up to 5.45°C with little or no performance degradation.
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