Network Protocol Virtualization or Network Protocol Stack Virtualization is a concept of providing network connections as a service, without concerning application developer to decide the exact communication stack composition.
Concept
editNetwork Protocol Virtualization (NPV) was firstly proposed by Heuschkel et al. in 2015 as a rough sketch as part of a transition concept for network protocol stacks.[1] The concept evolved and was published in a deployable state in 2018.[2]
The key idea is to decouple applications from their communication stacks. Today the socket API requires application developer to compose the communication stack by hand by choosing between IPv4/IPv6 and UDP/TCP. NPV proposes the network protocol stack should be tailored to the observed network environment (e.g. link layer technology, or current network performance). Thus, the network stack should not be composed at development time, but at runtime and it needs the possibility to be adapted if needed.
Additionally, the decoupling relaxes the chains of the ISO OSI network layer model, and thus enables alternative concepts of communication stacks. Heuschkel et al. proposes the concept of Application layer middleboxes as an example to add additional layers to the communication stack to enrich the communication with useful services (e.g. HTTP optimizations[3])
The Figure illustrates the data flow. Applications interface to the NPV software through some kind of API. Heuschkel et al. proposed socket API equivalent replacements but envisioned more sophisticated interfaces for future applications. A scheduler assigns the application payload to one (of potentially many) communication stack to get processed to network packets, that get sent using networking hardware. A management component decides how communication stacks get composed and the scheduling scheme. To support decisions a management interface is provided to integrate the management system in software-defined networking contexts.
NPV has been further investigated as a central element of LPWAN Internet of Things (IoT) scenarios. Specifically, the deployment of applications that are agnostic to the underlying transport, network, link and physical layers was explored by Rolando Herrero in 2020.[4] In this context, NPV becomes a very successful and flexible tool to accomplish the deployment and management of constrained sensors, actuators and controllers in massive IoT access networks.[5]
Implementations
editCurrently there is just one academic implementation available to demonstrate the concept. Heuschkel et al. published this implementation as demonstrator in 2016.[6] The last iteration of this code is available under AGPLv3 on Github.
See also
editReferences
edit- ^ Heuschkel, Jens; Schweizer, Immanuel; Zimmermann, Thorsten; Wehrle, Klaus; Mühlhäuser, Max (2015). "Protocol Virtualization through Dynamic Network Stacks". Proceedings of 1st Workshop on Software-Defined Networking and Network Function Virtualization for Flexible Network Management (SDNFlex).
- ^ Heuschkel, Jens; Wang, Lin; Fleckstein, Erik; Ofenloch, Michael; Blöcher, Marcel; Crowcroft, Jon; Mühlhäuser, Max (2015). "VirtualStack: Flexible Cross-layer Optimization via Network Protocol Virtualization". Proceedings of 43rd Local Computer Networks (LCN) IEEE.
- ^ Heuschkel, Jens; Forstmann, Jens; Wang, Lin; Mühlhäuser, Max (2018). "Identifying the Performance Impairment of HTTP". Proceedings of 42rd Local Computer Networks (LCN) IEEE.
- ^ Herrero, Rolando (2021). "Protocol stack virtualization support in IoT". Transactions on Emerging Telecommunications Technologies. 32 (11). doi:10.1002/ett.4340. S2CID 238717271.
- ^ Herrero, Rolando (2021). "Towards protocol stack virtualization in massive IoT deployments". Internet of Things. 14: 100396. doi:10.1016/j.iot.2021.100396. S2CID 233522611.
- ^ Heuschkel, Jens; Stein, Michael; Mühlhäuser, Max (2016). "VirtualStack: SDN-controlled Transparent Protocol Transitions At the Edge". Proceedings of 41rd Local Computer Networks (LCN) IEEE.