Named data networking (NDN) is a content-centric future Internet architecture that uses routable content names instead of IP addresses to achieve location-independent forwarding. Nevertheless, NDN's design is limited to offering hosted applications a simple content pull mechanism. As a result, increased complexity is needed in developing applications that require more sophisticated content delivery functionalities (e.g., push, publish/subscribe, streaming, generalized forwarding, and dynamic content naming). This thesis introduces a novel Enhanced NDN (ENDN) architecture that offers an extensible catalog of content delivery services (e.g., adaptive forwarding, customized monitoring, and in-network caching control). More precisely, the proposed architecture allows hosted applications to associate their content namespaces with a set of services offered by ENDN.
The design of ENDN starts from the current NDN architecture that is gradually modified to meet the evolving needs of novel applications. NDN switches use several forwarding tables in the packet processing pipeline, the most important one being the Forwarding Information Base (FIB). The NDN FIBs face stringent performance requirements, especially in Internet-scale deployments. Hence, to increase the NDN data plane scalability and flexibility, we first propose FCTree, a novel FIB data structure. FCTree is a compressed FIB data structure that significantly reduces the required storage space within the NDN routers while providing fast lookup and modification operations. FCTree also offers additional lookup types that can be used as building blocks to novel network services (e.g., in-network search engine).
Second, we design a novel programmable data plane for ENDN using P4, a prominent data plane programming language. Our proposed data plane allows content namespaces to be processed by P4 functions implementing complex stateful forwarding behaviors. We thus extend existing P4 models to overcome their limitations with respect to processing string-based content names. Our proposed data plane also allows running independent P4 functions in isolation, thus enabling P4 code run-time pluggability. We further enhance our proposed data plane by making it protocol-independent using programmable parsers to allow interfacing with IP networks.
Finally, we introduce a new control plane architecture that allows the applications to express their network requirements using intents. We employ Event-B machine (EBM) language modeling and tools to represent these intents and their semantics on an abstract model of the network. The resulting EBMs are then gradually refined to represent configurations at the programmable data plane. The Event-B method formally ensures the consistency of the different application requirements using proof obligations and verifies that the requirements of different intents do not contradict each other. Thus, the desired properties of the network or its services, as defined by the intent, are guaranteed to be satisfied by the refined EBM representing the final data-plane configurations. Experimental evaluation results demonstrate the feasibility and efficiency of our proposed architecture.
Identifer | oai:union.ndltd.org:uottawa.ca/oai:ruor.uottawa.ca:10393/43584 |
Date | 11 May 2022 |
Creators | Karrakchou, Ouassim |
Contributors | Karmouch, Ahmed, Samaan, Nancy |
Publisher | Université d'Ottawa / University of Ottawa |
Source Sets | Université d’Ottawa |
Language | English |
Detected Language | English |
Type | Thesis |
Format | application/pdf |
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