A P4-based 5G User Plane Function

Proceedings of the ACM SIGCOMM Symposium on SDN Research (SOSR) Pub Date : 2021-10-11 DOI:10.1145/3482898.3483358

Robert MacDavid, C. Cascone, Pingping Lin, Badhrinath Padmanabhan, A. Thakur, Larry L. Peterson, J. Rexford, M. O. Sunay

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引用次数: 29

Abstract

The demands on mobile networks are constantly evolving, but designing and integrating new high-speed packet processing remains a challenge due to the complexity of requirements and opacity of protocol specifications. 5G data planes should be implemented in programmable hardware for both speed and flexibility, and extending or replacing these data planes should be painless. In this paper we implement the 5G data plane using two P4 programs: one that acts as a open-source model data plane to simplify the interface with the control plane, and one to run efficiently on hardware switches to minimize latency and maximize bandwidth. The model data plane enables testing changes made to the control plane before integrating with a performant data plane, and vice versa. The hardware data plane implements the fast path for device traffic, and makes use of microservices to implement functions that highspeed switch hardware cannot do. Our data plane implementation is currently in limited deployment on three university campuses where it is enabling new research on mobile networks.

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基于p4的5G用户平面功能

移动网络的需求在不断变化，但由于需求的复杂性和协议规范的不透明性，设计和集成新的高速分组处理仍然是一个挑战。5G数据平面应该在可编程硬件中实现，以实现速度和灵活性，扩展或替换这些数据平面应该是无痛的。在本文中，我们使用两个P4程序来实现5G数据平面:一个作为开源模型数据平面，以简化与控制平面的接口，另一个在硬件交换机上高效运行，以最小化延迟和最大化带宽。模型数据平面允许在与高性能数据平面集成之前测试对控制平面所做的更改，反之亦然。硬件数据平面实现了设备流量的快速通道，并利用微服务实现了高速交换机硬件无法实现的功能。我们的数据平面实现目前正在三个大学校园进行有限的部署，在那里它可以对移动网络进行新的研究。

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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Proceedings of the ACM SIGCOMM Symposium on SDN Research (SOSR)

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