Latency and Backlog Bounds in Time-Sensitive Networking with Credit Based Shapers and Asynchronous Traffic Shaping

We compute bounds on end-to-end worst-case latency and on nodal backlog size for a per-class deterministic network that implements Credit Based Shaper (CBS) and Asynchronous Traffic Shaping (ATS), as proposed by the Time-Sensitive Networking (TSN) standardization group. ATS is an implementation of the Interleaved Regulator, which reshapes traffic in the network before admitting it into a CBS buffer, thus avoiding burstiness cascades. Due to the interleaved regulator, traffic is reshaped at every switch, which allows for the computation of explicit delay and backlog bounds. Furthermore, we obtain a novel, tight per-flow bound for the response time of CBS, when the input is regulated, which is smaller than existing network calculus bounds. We also compute a per-flow bound on the response time of the interleaved regulator. Based on all the above results, we compute bounds on the per-class backlogs. Then, we use the newly computed delay bounds along with recent results on interleaved regulators from literature to derive tight end-to-end latency bounds and show that these are less than the sums of per-switch delay bounds.

On Time Synchronization Issues in Time-Sensitive Networks with Regulators and Nonideal Clocks

Jean-Yves Le Boudec, Ludovic Bernard Gérard Thomas

Flow reshaping is used in time-sensitive networks (as in the context of IEEE TSN and IETF Detnet) in order to reduce burstiness inside the network and to support the computation of guaranteed latency bounds. This is performed using per-flow regulators (such as the Token Bucket Filter) or interleaved regulators (as with IEEE TSN Asynchronous Traffic Shaping, ATS). The former use one FIFO queue per flow, whereas the latter use one FIFO queue per input port. Both types of regulators are beneficial as they cancel the increase of burstiness due to multiplexing inside the network. It was demonstrated, by using network calculus, that they do not increase the worst-case latency. However, the properties of regulators were established assuming that time is perfect in all network nodes. In reality, nodes use local, imperfect clocks. Time-sensitive networks exist in two flavours: (1) in non-synchronized networks, local clocks run independently at every node and their deviations are not controlled and (2) in synchronized networks, the deviations of local clocks are kept within very small bounds using for example a synchronization protocol (such as PTP) or a satellite based geo-positioning system (such as GPS). We revisit the properties of regulators in both cases. In non-synchronized networks, we show that ignoring the timing inaccuracies can lead to network instability due to unbounded delay in per-flow or interleaved regulators. We propose and analyze two methods (rate and burst cascade, and asynchronous dual arrival-curve method) for avoiding this problem. In synchronized networks, we show that there is no instability with per-flow regulators but, surprisingly, interleaved regulators can lead to instability. To establish these results, we develop a new framework that captures industrial requirements on clocks in both non-synchronized and synchronized networks, and we develop a toolbox that extends network calculus to account for clock imperfections.

Association for Computing Machinery2020

Simplifying Development and Management of Software-Defined Networks

Peter Peresini

Computer networks are an important part of our life. Yet, they are traditionally hard to manage and operate. The recent shift to Software-Defined Networking (SDN) is promised to change the way in which the networks are run by their operators. However, SDN is still in its initial stage and as such it lags behind traditional networks in terms of correctness and reliability; both the properties being vitally important for the network operators. Meanwhile, general purpose computers were following Moore's law for years and as a result, together with algorithmic improvements, the costs of computing have been declining --- we have more processing power available to us than anytime before. In this dissertation I strive to reduce the correctness and reliability gap of SDN and help speed up the adoption of SDN by providing tools that help programmers and operators gain confidence in their networks. These tools leverage the today's trend in the increasing availability of vast amounts of computing power and combine it with the past research on systematic validation, optimization and satisfiability solving. The first tool this thesis introduces, NICE, focuses on debugging of an SDN controller. In particular, while SDN is conceptually a centralized system with the controller in the command, SDN is still a distributed system. As such, programmers might miss various event interleavings and race conditions that lead to a buggy behavior. NICE uncovers such insidious bugs by systematically exploring possible network states by a novel combination of two techniques -- symbolic execution and model checking. The combination of the two techniques and SDN-related heuristics let NICE explore possible scenarios deeper than any existing technique alone. This thesis also introduces Monocle, a tool aimed at ensuring reliability of SDN switches. Specifically, Monocle continuously verifies that a switch data plane processes packets as configured by the SDN controller. Such monitoring is important in the presence of silent errors ranging from switch firmware bugs, through memory corruption, to transient inconsistencies. To verify that the switch data plane works as intended, Monocle constructs data plane packets and injects them into the network. Such packet construction is, however, a rather intricate problem when considering a complicated nature of the switch packet matching mechanism in the presence of multiple overlapping rules. In the thesis I formally describe the constraints that the generated packets need to satisfy, and I leverage an off-the-shelf satisfiability solver to solve them. Finally, this thesis introduces ESPRES, a tool focused on scheduling network updates. I first observe that big network updates such as traffic engineering or failure re-routing usually contain many subupdates that are independent (e.g, updates of different flows). Then I conjecture that while the length of the total update is bottlenecked by the slowest switch, the time when an individual subupdate finishes can be greatly improved for a majority of them. To achieve this goal in an online fashion, ESPRES uses a greedy mechanism to reorder individual switch commands according to the current situation on different switches.

EPFL2016

On Time Synchronization Issues in Time-Sensitive Networks with Regulators and Nonideal Clocks

Jean-Yves Le Boudec, Ludovic Bernard Gérard Thomas

Association for Computing Machinery2020

Simplifying Development and Management of Software-Defined Networks

Peter Peresini

EPFL2016