CMU-CS-10-149
Computer Science Department
School of Computer Science, Carnegie Mellon University



CMU-CS-10-149

A Practical System for Centralized Network Control

Hong Yan

November 2010

Ph.D. Thesis

CMU-CS-10-149.pdf


Keywords: Centralized Network Control, Clean-slate Network Design, Network Dissemination Plane, Network Management

IP networking is a spectacular success, catalyzing the diffusion of data networking across academic institutions, governments, businesses, and homes worldwide. Yet, despite the fundamental importance of this infrastructure, today's networks are surprisingly fragile and increasingly difficult to configure, control, and maintain. As our dependence on data networking grows, so do the risks of security breaches, large-scale outages, and service disruptions.

We believe that the root of these problems lies in the complexity of the control and management planes – the software and protocols coordinating network elements – and particularly the way the decision logic and the distributed-systems issues are inexorably intertwined. The research community advocates a complete refactoring of the functionality and proposes a new architecture which they call "4D," after the architecture's four planes: decision, dissemination, discovery, and data. The 4D architecture pulls decision-making logic out of the network elements to create a logically centralized decision plane, where network-level objectives and policies are specified and enforced by direct configuration of state on individual network elements.

While the 4D vision is conceptually appealing, it has raised a wide range of practical concerns related to robustness, flexibility, scalability, and security. Our thesis is that "it is actually possible to build a 4D network that is as scalable and robust as traditional IP networks but greatly simplifies network control and management". To prove this thesis, we must address the following technical challenges:

1. What kind of decision-plane framework will enable the centralization and composition of multiple network control functions for sophisticated network control?
2. How can we provide reliable connectivity to remotely manage distributed network elements without relying on the communication services that are being managed?
3. Is there an efficient way to disseminate control messages from central decision servers to a large number of network elements?

We believe that answering the above questions is key to the successful deployment of 4D networks. In this dissertation, we tackle those challenges by building a 4D network control platform called Tesseract and demonstrating that Tesseract enables both simpler protocols that do not have to embed decision-making logic, and more powerful decision algorithms for implementing sophisticated goals. The main target of our work is to turn the revolutionary 4D concept into a practical working system.

133 pages


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