VirtualPower: coordinated power management in virtualized enterprise systems

Ripal Nathuji, K. Schwan
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引用次数: 763

Abstract

Power management has become increasingly necessary in large-scale datacenters to address costs and limitations in cooling or power delivery. This paper explores how to integrate power management mechanisms and policies with the virtualization technologies being actively deployed in these environments. The goals of the proposed VirtualPower approach to online power management are (i) to support the isolated and independent operation assumed by guest virtual machines (VMs) running on virtualized platforms and (ii) to make it possible to control and globally coordinate the effects of the diverse power management policies applied by these VMs to virtualized resources. To attain these goals, VirtualPower extends to guest VMs `soft' versions of the hardware power states for which their policies are designed. The resulting technical challenge is to appropriately map VM-level updates made to soft power states to actual changes in the states or in the allocation of underlying virtualized hardware. An implementation of VirtualPower Management (VPM) for the Xen hypervisor addresses this challenge by provision of multiple system-level abstractions including VPM states, channels, mechanisms, and rules. Experimental evaluations on modern multicore platforms highlight resulting improvements in online power management capabilities, including minimization of power consumption with little or no performance penalties and the ability to throttle power consumption while still meeting application requirements. Finally, coordination of online methods for server consolidation with VPM management techniques in heterogeneous server systems is shown to provide up to 34% improvements in power consumption.
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VirtualPower:虚拟化企业系统中的协同电源管理
在大型数据中心中,电源管理变得越来越必要,以解决冷却或供电方面的成本和限制。本文探讨了如何将电源管理机制和策略与这些环境中正在积极部署的虚拟化技术集成在一起。提出的VirtualPower在线电源管理方法的目标是:(i)支持运行在虚拟化平台上的来宾虚拟机(vm)所假定的隔离和独立操作;(ii)使这些虚拟机对虚拟化资源应用的各种电源管理策略的影响能够得到控制和全局协调。为了实现这些目标,VirtualPower扩展到客户虚拟机的硬件电源状态的“软”版本,它们的策略是针对这些状态设计的。由此产生的技术挑战是将对软实力状态所做的vm级更新适当地映射到状态或底层虚拟化硬件分配中的实际更改。Xen管理程序的虚拟电源管理(VirtualPower Management, VPM)实现通过提供多个系统级抽象(包括VPM状态、通道、机制和规则)来解决这一挑战。在现代多核平台上的实验评估强调了在线电源管理能力的改进,包括在很少或没有性能损失的情况下最小化功耗,以及在满足应用需求的同时限制功耗的能力。最后,在异构服务器系统中,将服务器整合的在线方法与VPM管理技术相协调,可以将功耗提高34%。
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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