面向HPC和DC的可重构光互连网络体系结构综述

摘要/Abstract

摘要： 互连网络是高性能计算系统和数据中心的核心组件之一，也是决定其系统整体性能的全局性基础设施。随着高性能计算、云计算和大数据技术的迅速发展，传统的电互连网络在性能、能耗和成本等方面无法满足高性能计算应用和数据中心业务的大规模可扩展通信需求，面临着严峻的挑战。为此，近年来相关研究者提出了多种面向高性能计算和数据中心的可重构的光互连网络结构。首先阐明了光互连网络相对于电互连网络的优势;然后介绍了几种典型的可重构光互连网络体系结构，并对其特点进行了分析比较;最后探讨了可重构光互连网络的发展趋势。

关键词: 光互连网络；可重构；高性能计算；数据中心 ,

Abstract: Interconnection network is one of the core components of high-performance computing systems and data centers, and it is also a global infrastructure that determines the overall performance of the systems. With the rapid development of high-performance computing, cloud computing and big data application technology, in order to meet the large-scale scalable communication requirements of high-performance computing and data center services, traditional electrical interconnection networks face severe challenges in terms of performance, energy consumption and cost. In recent years, researchers have proposed a variety of reconfigurable optical interconnection network architectures for high-performance computing systems and data centers. In this paper, the advantages of optical interconnection network over electrical interconnection network are described. Then, several typical reconfigurable optical interconnect network architectures are introduced, and their characteristics are analyzed and compared. Finally, the development trend of reconfigurable optical interconnect networks is discussed.

Key words: optical interconnection network, reconfigurable, high-performance computing, data center

曹继军. 面向HPC和DC的可重构光互连网络体系结构综述[J]. 计算机工程与科学, 2022, 44(06): 951-963.

CAO Ji-jun. Review of reconfigurable optical interconnection network architecture for HPC and DC[J]. Computer Engineering & Science, 2022, 44(06): 951-963.

参考文献［14］

［1］	Zhou Xi-min,Li Gen-guo, Dai Song-jun,et al.2019 annual report of Shanghai supercomputer center［EB/OL］.［2019-12-15］.http://www.ssc.net.cn/file/report/2019.pdf.(in Chinese)
［2］	TOP500 Org. TOP500 list of November 2020［EB/OL］.［2021-03-15］.http://top500.org/lists/top500/list/2020/11.
［3］	Zhao X, Vusirikala V,Koley B,et al.The prospect of inter data center optical networks ［J］.IEEE Communications Magazine,2013,51(9):32-38.
［4］	Phumla D, Isoe G, Boiyo D, et al. All-optical VCSEL-to- VCSEL injection based on cross gain modulation for routing in multimode flexible spectrum optimization in optical fibre transmission links ［J］.International Journal of Optics,2019(3):1-11.
［5］	Cheung S, Su T, Okamoto K,et al. Ultra-compact Silicon Photonic 512×512 25 GHz arrayed waveguid grating router［J］.IEEE Journal on Selected Topics in Quantum Electronics,2014,20:310-316.
［6］	ACM SIGCOMM Org.SIGCOMM homepage ［EB/OL］.［2021-02-13］.http://www.sigcomm.org.
［7］	Wang G,Andersen D G,Kaminsky M,et al.c-Through:Part-time optics in data centers ［J］.ACM SIGCOMM Computer Communication Review,2011,41(4):327-338.
［8］	Chen K,Singla A,Singh A,et al.OSA:An optical switching architecture for data center networks with unprecedented flexibility［J］. IEEE/ACM Transaction on Networking,2014,22(2):498-511.
［9］	Nathan F,Porter G,Radhakrishnan S,et al.Helios:A hybrid electrical/optical switch architecture for modular data centers ［J］. ACM SIGCOMM Computer Communication Review,2011,41(4):339-350.
［10］	Porter G,Strong R,Farrington N,et al.Integrating microsecond circuit switching into the data center［J］. ACM SIGCOMM Computer Communication Review,2013,43(4):447-458.
［11］	Hamedazimi N,Qazi Z,Gupta H,et al.Firefly:A reconfigurable wireless data center fabric using free-space optics［C］∥Proc of 2014 ACM SIGCOMM Conference,2014:319-330.
［12］	Ghobadi M,Mahajan R,Phanishayee A,et al.ProjecToR:Agile reconfigurable data center interconnect［C］∥Proc of 2016 ACM SIGCOMM Conference,2016:216-229.
［13］	Samadi P,Wen K, Xu J J,et al.Reconfigurable optical dragonfly architecture for high performance computing［C］∥Proc of IEEE Optical Fiber Communication Conference & Exhibition (OFC),2016:paper Th2A.60.
［14］	Zang Da-wei, Cao Zheng,Wang Zhan,et al.AWGR-baseed OCS/EPS hybrid datacenter network［J］.Chinese Journal of Computers,2016,39(9):1868-1882.(in Chinese)
［15］	Mellette W M, McGuinness R,Roy A,et al.RotorNet:A scalable,low-complexity,optical datacenter network［C］∥Proc of the 7th Conference on the Special Interest Group on Data Communication,2017:267-280.
［16］	Ballani H, Costa P,Behrendt R,et al.Sirius:A flat datacenter network with nanosecond optical switching［C］∥Proc of the Annual Conference on the ACM Special Interest Group on Data Communication on the Applications, Technologies,Architectures, and Protocol for Computer Communication,2020:782-797.
［17］	Edmonds J Paths.Trees and flowers ［J］.Canadian Journal on Mathematics,2012,17(3):361-379.
［18］	Hamiton J. An architecture for modular data centers［C］∥Proc of the 3rd Biennial Conference on Innovative Data Systems Research (CIDR),2007:1-8.
［19］	Singla A,Singh A,Ramachandran K,et al.Proteus:A topology malleable data center network［C］∥Proc of ACM SIGCOMM Workshop on Hot Topics in Networks (HotNets),2010:1-6.
［20］	Müller-Hannemann M,Schwartz A.Implementing weighted b-matching algorithms:Insights from a computational study［C］∥Proc of International Workshop on Algorithm Engineering and Experimentation,1999:18-36.
［21］	Kim J,Dally W J,Scott S,et al.Technology-driven,highly scalable dragonfly topology［J］.ACM SIGARCH Computer Architecture News,2008,36(3):77-88.
［22］	Faanes G, Bataineh A,Roweth D,et al.Cray Cascade:A scalable HPC system based on a Dragonfly network［C］∥Proc of 2012 International Conference for High Performance Computing,Networking,Storage and Analysis,2012:1-9.
［23］	Rajamony R,Arimilli L B,Gildea K.PERCS:The IBM Power7-IH high-performance computing system ［J］.IBM Journal of Research and Development,2011,55(3):233-244.
［24］	Sinkhorn R.A relationship between arbitrary positive matrices and doubly stochastic matrices［J］.The Annals of Mathematical Statistics,1964,35(2):876-879.
［25］	von Neumann J. A certain zero-sum two-person game equivalent to the optimal assignment problem［M］∥Contributions to the Theory of Games,Princeton:Princeton University Press,1953,2:5-12.
［26］	Kent optronics homepage ［EB/OL］.［2021-02-13］.http://kentoptronics.com/switchable.html.
［27］	THORLABS homepage ［EB/OL］.［2021-02-13］.http://www.thorlabs.us/navigation.cfg?guide_id=1.
［28］	Chang C S, Lee D S, Jou Y S. Load balanced birkhoff-von neumann switches,Part I:One-stage buffering［J］.Computer Communications,2002,25(6):611-622.
［29］	Christodoulopoulos K, Katrinis K, Ruffini M, et al. Accelerating HPC workloads with dynamic adaptation of a software-defined hybrid electronic/optical interconnect［C］∥Proc of IEEE Optical Fiber Communication Conference & Exhibition (OFC),2014:paper Th2A.11.
［30］	Zang D W,Chen M Y,Sun N H,et al.OpticV:An energy-efficient datacenter network architecture by MEMS-basedall-optical bypassing［C］∥Proc of IEEE Optical Intercon-nects Conference (OI),2016:70-71.
［31］	Bao J Z,Dong D Z,Zhao B K,et al.FlyCast:Free-space optics accelerating multicast communications in physical layer［J］.ACM SIGCOMM Computer Communication Review,2015,45(4):97-98.
	附中文参考文献：
［1］	周曦民,李根国,戴松筠,等.上海超级计算中心2019年度报告［EB/OL］.［2019-12-15］.http://www.ssc.net.cn/file/report/2019.pdf.
［14］	藏大伟,曹政,王展,等.基于AWGR的OCS/EPS数据中心光电混合网络［J］.计算机学报,2016,39(9):1868-1882.

[1]	赵振宇, 杨天豪, 蒋汶乘, 张书政. 基于机器学习的多压多温多参标准单元延迟快速计算方法[J]. 计算机工程与科学, 2023, 45(08): 1331-1338.
[2]	熊国杰, 张津铭, 贺光辉. 一种面向Chiplet互连的高效传输协议设计与实现[J]. 计算机工程与科学, 2023, 45(08): 1339-1346.
[3]	孙彩霞, 隋兵才, 邓全, 郑重, 倪晓强, 王永文. 应用级兼容RISC-V的混合指令集处理器[J]. 计算机工程与科学, 2023, 45(08): 1347-1353.
[4]	马思远, 焦佳辉, 任晟岐, 宋伟. 基于注意力机制的城市多元空气质量数据缺失值填充[J]. 计算机工程与科学, 2023, 45(08): 1354-1364.
[5]	史明川, 龙巧洲, 邹鸿基, 李暾. 基于Surrogate模型的断言覆盖技术研究[J]. 计算机工程与科学, 2023, 45(08): 1365-1375.
[6]	高文才, 陈小文. 一种基于混合加固的容软错误NoC路由器[J]. 计算机工程与科学, 2023, 45(08): 1376-1382.
[7]	王星苏, 熊文, 张瑞. 海量地铁乘客轨迹相似性连接方法：以深圳地铁为例[J]. 计算机工程与科学, 2023, 45(08): 1383-1392.
[8]	夏戈明, 虞朝栋, 陈健. 边缘计算中的信任问题：挑战与评论[J]. 计算机工程与科学, 2023, 45(08): 1393-1404.
[9]	尹春勇, 冯梦雪. 基于注意力机制的半监督日志异常检测方法[J]. 计算机工程与科学, 2023, 45(08): 1405-1415.
[10]	余子丞, 凌捷. 基于Transformer和多特征融合的DGA域名检测方法[J]. 计算机工程与科学, 2023, 45(08): 1416-1423.
[11]	侯占伟, 李鑫, 王辉, 申自浩, 刘琨, 刘沛骞. 面向路网的空间众包隐私保护任务分配算法[J]. 计算机工程与科学, 2023, 45(08): 1424-1432.
[12]	印杰, 黄肖宇, 刘家银, 牛博威, 谢文伟, . 基于预训练语言模型的安卓恶意软件检测方法[J]. 计算机工程与科学, 2023, 45(08): 1433-1442.
[13]	谷文俊, 张晟恺, 邱晓梦, 李亚康, 宋伟. 基于双模态的小角散射图像结构表征技术研究[J]. 计算机工程与科学, 2023, 45(08): 1443-1452.
[14]	唐剑, 车文刚, 高盛祥. 融入注意力机制的多尺度卷积图像去雾方法[J]. 计算机工程与科学, 2023, 45(08): 1453-1462.
[15]	吴栋梁, 刘知贵, . 基于轻量化YOLOX的电子元器件缺陷检测方法研究[J]. 计算机工程与科学, 2023, 45(08): 1463-1471.