Flexible Software-defined Packet Processing using Low-area Hardware

Computer networks are in the Software Defined Networking (SDN) and Network Function Virtualization (NFV) era. SDN brings a whole new set of flexibility and possibilities into the network. The data plane of forwarding devices can be programmed to provide functionality for any protocol, and to perform novel network testing, diagnostics, and troubleshooting. One of the most dominant hardware architectures for implementing the programmable data plane is the Reconfigurable Match Tables (RMT) architecture. RMT's innovative programmable architecture enables support of novel networking protocols. However, there are certain shortcomings associated with its architecture that limit its scalability and lead to an unnecessarily complex architecture. In this paper, we present the details of an alternative packet parser and MatchAction pipeline. The parser sustains tenfold throughput at an area increase of only 32 percent. The pipeline supports unlimited combination of tables at minimum possible cost and provides a new level of flexibility to programmable Match-Action packet processing by allowing custom depth for actions. In addition, it has more advanced field-referencing mechanisms. Despite these architectural enhancements, it has 31 percent less area compared to RMT architecture

Reducing crossbar costs in the match-action pipeline

Software Defined Networking (SDN) is a new networking paradigm in which the control plane and data plane are decoupled. Throughout the recent years, a number of architectures have emerged for protocol-independent packet processing. One such architecture is the Protocol Independent Switch Architecture (PISA). It is a programmable and protocol-independent architecture composed of a number of Match and Action stages. Inside each of these stages is a crossbar to generate the search key and another crossbar to provide the input to the Action Units. In this paper, we design and explore alternative interconnection schemes with the aim of finding the most area- and power-efficient interconnection structure. Moreover, we propose further modifications to the interconnection structure, as a result of which the on-chip area of both match and action crossbars will be reduced by more than 70 % and power dissipation will be reduced by 25.8 % and 23.1 % for match and action crossbars respectively

Reducing crossbar costs in the match-action pipeline

Software Defined Networking (SDN) is a new networking paradigm in which the control plane and data plane are decoupled. Throughout the recent years, a number of architectures have emerged for protocol-independent packet processing. One such architecture is the Protocol Independent Switch Architecture (PISA). It is a programmable and protocol-independent architecture composed of a number of Match and Action stages. Inside each of these stages is a crossbar to generate the search key and another crossbar to provide the input to the Action Units. In this paper, we design and explore alternative interconnection schemes with the aim of finding the most area- and power-efficient interconnection structure. Moreover, we propose further modifications to the interconnection structure, as a result of which the on-chip area of both match and action crossbars will be reduced by more than 70 % and power dissipation will be reduced by 25.8 % and 23.1 % for match and action crossbars respectively.acceptedVersionPeer reviewe