Agile, efficient virtualization power management with low-latency server power states

C. Isci, S. McIntosh, J. Kephart, R. Das, James E. Hanson, Scott Piper, Robert R. Wolford, Tom Brey, Robert Kantner, Allen Ng, J. Norris, Abdoulaye Traore, M. Frissora
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引用次数: 49

Abstract

One of the main driving forces of the growing adoption of virtualization is its dramatic simplification of the provisioning and dynamic management of IT resources. By decoupling running entities from the underlying physical resources, and by providing easy-to-use controls to allocate, deallocate and migrate virtual machines (VMs) across physical boundaries, virtualization opens up new opportunities for improving overall system resource use and power efficiency. While a range of techniques for dynamic, distributed resource management of virtualized systems have been proposed and have seen their widespread adoption in enterprise systems, similar techniques for dynamic power management have seen limited acceptance. The main barrier to dynamic, power-aware virtualization management stems not from the limitations of virtualization, but rather from the underlying physical systems; and in particular, the high latency and energy cost of power state change actions suited for virtualization power management. In this work, we first explore the feasibility of low-latency power states for enterprise server systems and demonstrate, with real prototypes, their quantitative energy-performance trade offs compared to traditional server power states. Then, we demonstrate an end-to-end power-aware virtualization management solution leveraging these states, and evaluate the dramatically-favorable power-performance characteristics achievable with such systems. We present, via both real system implementations and scale-out simulations, that virtualization power management with low-latency server power states can achieve comparable overheads as base distributed resource management in virtualized systems, and thus can benefit from the same level of adoption, while delivering close to energy-proportional power efficiency.
具有低延迟服务器电源状态的敏捷、高效的虚拟化电源管理
越来越多地采用虚拟化的主要驱动力之一是它极大地简化了IT资源的供应和动态管理。通过将运行的实体与底层物理资源解耦,并提供易于使用的控件来跨物理边界分配、释放和迁移虚拟机,虚拟化为改进整体系统资源使用和能效开辟了新的机会。虽然已经提出了一系列用于虚拟系统的动态、分布式资源管理的技术,并在企业系统中得到了广泛采用,但用于动态电源管理的类似技术的接受程度有限。动态的、功率感知的虚拟化管理的主要障碍不是来自虚拟化的限制,而是来自底层物理系统;特别是,电源状态更改操作的高延迟和能源成本适合于虚拟化电源管理。在这项工作中,我们首先探索了企业服务器系统的低延迟电源状态的可行性,并通过真实的原型演示了与传统服务器电源状态相比,它们的定量能源性能权衡。然后,我们将演示利用这些状态的端到端电源感知虚拟化管理解决方案,并评估使用此类系统可实现的非常有利的电源性能特征。我们通过实际系统实现和向外扩展模拟表明,具有低延迟服务器电源状态的虚拟化电源管理可以实现与虚拟化系统中的基本分布式资源管理相当的开销,因此可以从相同级别的采用中受益,同时提供接近能量比例的电源效率。
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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