RIFL: A Reliable Link Layer Network Protocol for FPGA-to-FPGA Communication

The 2021 ACM/SIGDA International Symposium on Field-Programmable Gate Arrays Pub Date : 2021-02-17 DOI:10.1145/3431920.3439467

Q. Shen, Jun Zheng, P. Chow

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引用次数: 1

Abstract

More and more latency-sensitive applications are being introduced into the data center. Performance of such applications can be limited by the high latency of the network interconnect. Because the conventional network stack is designed not only for LAN, but also for WAN, it carries a great amount of redundancy that is not required in a data center network. This paper introduces the concept of a three-layer protocol stack that can replace the conventional network stack and fulfill the exact demands of data center network communications. The detailed design and implementation of the first layer of the stack, which we call RIFL, is presented. A novel low latency in-band hop-by-hop re-transmission protocol is proposed and adopted in RIFL, which guarantees lossless transmission for links whose longest wire segment is no more than 150 meters. Experimental results show that RIFL achieves 218 nanoseconds round-trip latency on 3 meter zero-hop links, at a throughput of 104.7 Gbps. RIFL is a multi-lane protocol with scalable throughput from 500 Mbps to above 200 Gbps. It is portable to most of the recent FPGAs. It can be the enabler of low latency, high throughput, flexible, scalable, and lossless data center networks.

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用于fpga到fpga通信的可靠链路层网络协议

越来越多对延迟敏感的应用程序被引入数据中心。这种应用程序的性能可能受到网络互连的高延迟的限制。由于传统的网络堆栈不仅是为局域网设计的，而且也是为广域网设计的，因此它承载了大量的冗余，而这在数据中心网络中是不需要的。本文提出了三层协议栈的概念，可以代替传统的网络协议栈，满足数据中心网络通信的要求。给出了栈的第一层(我们称之为RIFL)的详细设计和实现。提出并采用了一种新颖的低时延带内逐跳重传协议，保证了最长线段不超过150米的链路无损传输。实验结果表明，在3米零跳链路上，RIFL实现了218纳秒的往返延迟，吞吐量为104.7 Gbps。RIFL是一种多通道协议，吞吐量可从500 Mbps扩展到200 Gbps以上。它可移植到大多数最新的fpga。它可以实现低延迟、高吞吐量、灵活、可扩展和无损的数据中心网络。

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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The 2021 ACM/SIGDA International Symposium on Field-Programmable Gate Arrays

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