Mike Schlansker

CORONET: Fault tolerance for Software Defined Networks

Software Defined Networking, or SDN, based networks are being deployed not only in testbed networks, but also in production networks. Although fault-tolerance is one of the most desirable properties in production networks, there are not much study in providing fault-tolerance to SDN-based networks. The goal of this work is to develop a fault tolerant SDN architecture that can rapidly recover from faults and scale to large network sizes. This paper presents CORONET, a SDN fault-tolerant system that recovers from multiple link failures in the data plane. We describe a prototype implementation based on NOX that demonstrates fault recovery for emulated topologies using Mininet. We also discuss possible extensions to handle control plane and controller faults.

Ensemble routing for datacenter networks

This paper describes Hash-Based Routing (HBR), an architecture that enhances Ethernet to support dynamic management for multipath networks in scalable datacenters. This work enhances HBR to support flow ensemble management for large-scale networks of arbitrary topology. Ensemble routing eliminates measurement and control for individual flows and instead manages using summary data thus providing a unique capability for reactive datacenter-wide network management. HBR provides seamless interoperability with Ethernet and supports the attachment of unmodified L2 hosts and devices including FCoE devices within converged fabrics. Simulation experiments demonstrate efficient multipath routing for a variety of scalable topologies. Optimized routing maintains efficiency in the presence of network faults and implements spatial Quality of Service to dynamically provision physical network hardware among co-hosted tenants or applications.

Killer Fabrics for Scalable Datacenters

Most datacenter networks are based on specialized edge-core topologies, which are costly to build, difficult to maintain and consume too much power. We propose enhancements to layer-two (L2) Ethernet switches to enable multipath L2 routing in scalable datacenters. This replaces an expensive router with commodity switches. Our hash-based routing approach reuses and minimally extends hardware structures in high-volume switches, while exposing a powerful network management inter-face for multipath load balancing, QoS differentiation, and resilience to faults. Simulation results demonstrate near-optimal load balancing for uniform and non-uniform traffic patterns, and effective management of large datacenter networks independent of the number of traffic flows.

Design Challenges for High Performance, Scalable NFV Interconnects

Software-based network functions (NFs) have seen growing interest. Increasingly complex functionality is achieved by having multiple functions chained together to support the required network-resident services. Network Function Virtualization (NFV) platforms need to scale and achieve high performance, potentially utilizing multiple hosts in a cluster. Efficient data movement is crucial, a cornerstone of kernel bypass. Moving packet data involves delivering the packet from the network interface to an NF, moving it across functions on the same host, and finally across yet another network to NFs running on other hosts in a cluster/data center. In this paper we measure the performance characteristics of different approaches for moving data at each of these levels. We also introduce a new high performance inter-host interconnect using InfiniBand. We evaluate the performance of Open vSwitch and the Open Net VM NFV platform, considering a simple forwarding function and Snort, a popular intrusion detection system.

Hash-based routing for scalable datacenters

Most datacenter networks are based on specialized edge-core topologies, which are costly to build, difficult to maintain and consume too much power. We propose enhancements to layer-two (L2) Ethernet switches to enable multipath L2 routing in scalable datacenters. Our hash-based routing approach reuses and minimally extends hardware structures in high-volume switches, while exposing a powerful network management interface for multipath load balancing, QoS differentiation, and resilience to faults.