Thin servers with smart pipes: designing SoC accelerators for memcached

Kevin T. Lim, David Meisner, A. Saidi, Parthasarathy Ranganathan, T. Wenisch
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引用次数: 197

Abstract

Distributed in-memory key-value stores, such as memcached, are central to the scalability of modern internet services. Current deployments use commodity servers with high-end processors. However, given the cost-sensitivity of internet services and the recent proliferation of volume low-power System-on-Chip (SoC) designs, we see an opportunity for alternative architectures. We undertake a detailed characterization of memcached to reveal performance and power inefficiencies. Our study considers both high-performance and low-power CPUs and NICs across a variety of carefully-designed benchmarks that exercise the range of memcached behavior. We discover that, regardless of CPU microarchitecture, memcached execution is remarkably inefficient, saturating neither network links nor available memory bandwidth. Instead, we find performance is typically limited by the per-packet processing overheads in the NIC and OS kernel---long code paths limit CPU performance due to poor branch predictability and instruction fetch bottlenecks. Our insights suggest that neither high-performance nor low-power cores provide a satisfactory power-performance trade-off, and point to a need for tighter integration of the network interface. Hence, we argue for an alternate architecture---Thin Servers with Smart Pipes (TSSP)---for cost-effective high-performance memcached deployment. TSSP couples an embedded-class low-power core to a memcached accelerator that can process GET requests entirely in hardware, offloading both network handling and data look up. We demonstrate the potential benefits of our TSSP architecture through an FPGA prototyping platform, and show the potential for a 6X-16X power-performance improvement over conventional server baselines.
具有智能管道的瘦服务器:为memcached设计SoC加速器
分布式内存中的键值存储(如memcached)是现代互联网服务可伸缩性的核心。当前的部署使用带有高端处理器的商品服务器。然而,考虑到互联网服务的成本敏感性和最近批量低功耗片上系统(SoC)设计的激增,我们看到了替代架构的机会。我们对memcached进行了详细的表征,以揭示性能和功耗方面的低效率。我们的研究考虑了高性能和低功耗cpu和nic,这些cpu和nic都是经过精心设计的,可以测试memcached行为的范围。我们发现,无论CPU微架构如何,memcached的执行效率都非常低,既不会使网络链路饱和,也不会使可用的内存带宽饱和。相反,我们发现性能通常受到网卡和操作系统内核中每包处理开销的限制——由于分支可预测性差和指令获取瓶颈,较长的代码路径限制了CPU性能。我们的见解表明,高性能和低功耗内核都不能提供令人满意的功率性能权衡,并指出需要更紧密地集成网络接口。因此,我们主张采用另一种架构——带智能管道的瘦服务器(TSSP)——以实现经济高效的高性能memcached部署。TSSP将嵌入式低功耗核心与memcached加速器结合在一起,memcached加速器可以完全在硬件中处理GET请求,从而卸载网络处理和数据查找。我们通过FPGA原型平台展示了我们的TSSP架构的潜在优势,并展示了比传统服务器基准提高6X-16X功率性能的潜力。
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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