混合存储系统的资源分配模型

2015 15th IEEE/ACM International Symposium on Cluster, Cloud and Grid Computing Pub Date : 2015-05-04 DOI:10.1109/CCGrid.2015.132

Hui Wang, P. Varman

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引用次数: 7

摘要

为由固态驱动器(ssd)和硬盘(HDs)组成的混合存储系统提供QoS保证是一个具有挑战性的问题。由于hdd和ssd的IOPS容量差异很大，因此将存储系统视为一个单一的黑盒子是不明智的，相反，一个有用的QoS模型必须区分针对不同设备类型的IOs。传统的存储资源分配模型在很大程度上被设计为为单一资源类型提供QoS，当应用于多个耦合资源时，其利用率和公平性较差。本文提出了一种基于多资源框架的混合存储系统资源分配模型。该模型支持对共享存储系统的客户端进行预留和共享。预留指定客户端必须接收的最小吞吐量(IOPS)，而份额则反映其相对于在同一设备上遇到瓶颈的其他客户端的权重。我们提出了一个正式的多资源分配模型来为客户端分配IOPS，以及一个IO调度算法来最大化系统吞吐量。实验结果验证了模型和算法的正确性。

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A Resource Allocation Model for Hybrid Storage Systems

Providing QoS guarantees for hybrid storage systems made up of both solid-state drives (SSDs) and hard disks (HDs) is a challenging problem. Since HDs and SSDs have widely different IOPS capacities, it is not sensible to treat the storage system as a monolithic black box, instead a useful QoS model must necessarily differentiate the IOs made to different device types. Traditional storage resource allocation models have largely been designed to provide QoS for a single resource type, and result in poor utilization and fairness when applied to multiple coupled resources. In this paper, we present a new resource allocation model for hybrid storage systems using a multi-resource framework. The model supports reservations and shares for clients sharing the storage system. Reservations specify the minimum throughput (IOPS) that a client must receive, while shares reflect its weight relative to other clients that are bottlenecked on the same device. We present a formal multi-resource allocation model to allocate IOPS to clients, together with an IO scheduling algorithm to maximize system throughput. The model and algorithms are validated with empirical results.

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2015 15th IEEE/ACM International Symposium on Cluster, Cloud and Grid Computing

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