Applications Know Best: Performance-Driven Memory Overcommit with Ginkgo

2011 IEEE Third International Conference on Cloud Computing Technology and Science Pub Date : 2011-11-29 DOI:10.1109/CloudCom.2011.27

M. R. Hines, Abel Gordon, Márcio Silva, D. D. Silva, K. D. Ryu, Muli Ben-Yehuda

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引用次数: 72

Abstract

Memory over commitment enables cloud providers to host more virtual machines on a single physical server, exploiting spare CPU and I/O capacity when physical memory becomes the bottleneck for virtual machine deployment. However, over commiting memory can also cause noticeable application performance degradation. We present Ginkgo, a policy framework for over omitting memory in an informed and automated fashion. By directly correlating application-level performance to memory, Ginkgo automates the redistribution of scarce memory across all virtual machines, satisfying performance and capacity constraints. Ginkgo also achieves memory gains for traditionally fixed-size Java applications by coordinating the redistribution of available memory with the activities of the Java Virtual Machine heap. When compared to a non-over commited system, Ginkgo runs the Day Trader 2.0 and SPEC Web 2009 benchmarks with the same number of virtual machines while saving up to 73% (50% omitting free space) of a physical server's memory while keeping application performance degradation within 7%.

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应用程序知道最好的:性能驱动的内存过度使用银杏

内存超过承诺使云提供商能够在单个物理服务器上托管更多虚拟机，当物理内存成为虚拟机部署的瓶颈时，可以利用空闲的CPU和I/O容量。但是，过度使用内存也会导致明显的应用程序性能下降。我们提出银杏，在一个知情和自动化的方式过度省略记忆的政策框架。通过直接将应用程序级性能与内存相关联，Ginkgo在所有虚拟机之间自动重新分配稀缺内存，从而满足性能和容量限制。Ginkgo还通过与Java虚拟机堆的活动协调可用内存的重新分配，为传统的固定大小的Java应用程序实现内存增益。与非过度承诺的系统相比，Ginkgo在运行Day Trader 2.0和SPEC Web 2009基准测试时使用相同数量的虚拟机，同时节省了物理服务器内存的73%(50%省略了可用空间)，同时将应用程序性能降低在7%以内。

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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2011 IEEE Third International Conference on Cloud Computing Technology and Science

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