REED: A Reliable Energy-Efficient RAID

2015 44th International Conference on Parallel Processing Pub Date : 2015-09-01 DOI:10.1109/ICPP.2015.74

Shu Yin, Xuewu Li, Kenli Li, Jianzhong Huang, X. Ruan, Xiaomin Zhu, Wei Cao, X. Qin

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引用次数: 11

Abstract

Recent studies indicate that the energy cost and carbon footprint of data centers have become exorbitant. It is a demanding and challenging task to reduce energy consumption in large-scale storage systems in modern data centers. Most energy conservation techniques inevitably have adverse impacts on parallel disk systems. To address the reliability issues of energy-efficient parallel disks, we propose a reliable energy-efficient RAID system called REED, which aims at improving both energy efficiency and reliability of RAID systems by seamlessly integrating HDDs and SSDs. At the heart of REED is a high-performance cache mechanism powered by SSDs, which are serving popular data. Under light workload conditions, REED spins down HDDs into the low-power mode, thereby offering energy conservation. Importantly, during an I/O access turbulence (i.e., I/O load is dynamically and frequently changing), REED is conducive to reducing the number of disk power-state transitions by keeping HDDs in the low-power mode while serving requests with SSDs. We build a model to quantitatively show that REED is capable of improving the reliability of energy-efficient RAIDs. We implement the REED prototype in a real-world RAID-0 system. Our experimental results demonstrate that REED improves the energy-efficiency of conventional RAID-0 by up to 73% while maintaining good reliability.

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里德:可靠的节能RAID

最近的研究表明，数据中心的能源成本和碳足迹已经变得过高。在现代数据中心中，如何降低大型存储系统的能耗是一项艰巨而富有挑战性的任务。大多数节能技术不可避免地对并行磁盘系统产生不利影响。为了解决节能并行磁盘的可靠性问题，我们提出了一种可靠的节能RAID系统，称为REED，旨在通过无缝集成hdd和ssd来提高RAID系统的能效和可靠性。REED的核心是由ssd提供支持的高性能缓存机制，ssd提供流行数据。在轻工作负载条件下，REED将hdd旋转到低功耗模式，从而提供节能。重要的是，在I/O访问动荡期间(即，I/O负载是动态和频繁变化的)，REED有助于通过将hdd保持在低功耗模式，同时使用ssd处理请求，从而减少磁盘电源状态转换的数量。我们建立了一个模型，定量地表明REED能够提高节能raid的可靠性。我们在真实的RAID-0系统中实现了REED原型。我们的实验结果表明，REED在保持良好可靠性的同时，将传统RAID-0的能效提高了73%。

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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2015 44th International Conference on Parallel Processing

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