Internet-Draft | Framework of OAM for DetNet | October 2022 |
Mirsky, et al. | Expires 9 April 2023 | [Page] |
Deterministic Networking (DetNet), as defined in RFC 8655, is aimed to provide a bounded end-to-end latency on top of the network infrastructure, comprising both Layer 2 bridged and Layer 3 routed segments. This document's primary purpose is to detail the specific requirements of the Operation, Administration, and Maintenance (OAM) recommended to maintain a deterministic network. With the implementation of the OAM framework in DetNet, an operator will have a real-time view of the network infrastructure regarding the network's ability to respect the Service Level Objective, such as packet delay, delay variation, and packet loss ratio, assigned to each DetNet flow.¶
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Deterministic Networking (DetNet) [RFC8655] has proposed to provide a bounded end-to-end latency on top of the network infrastructure, comprising both Layer 2 bridged and Layer 3 routed segments. That work encompasses the data plane, OAM, time synchronization, management, control, and security aspects.¶
Operations, Administration, and Maintenance (OAM) Tools are of primary importance for IP networks [RFC7276]. DetNet OAM should provide a toolset for fault detection, localization, and performance measurement.¶
This document's primary purpose is to detail the specific requirements of the OAM features recommended to maintain a deterministic/reliable network. Specifically, it investigates the requirements for a deterministic network, supporting critical flows.¶
In this document, the term OAM will be used according to its definition specified in [RFC6291]. DetNet expects to implement an OAM framework to maintain a real-time view of the network infrastructure, and its ability to respect the Service Level Objectives (SLO), such as in-order packet delivery, packet delay, delay variation, and packet loss ratio, assigned to each DetNet flow.¶
This document lists the functional requirements toward OAM for DetNet domain. The list can further be used for gap analysis of available OAM tools to identify possible enhancements of existing or whether new OAM tools are required to support proactive and on-demand path monitoring and service validation.¶
This document uses definitions, particularly of a DetNet flow, provided in Section 2.1 [RFC8655]. The following terms are used throughout this document as defined below:¶
OAM: Operations, Administration, and Maintenance¶
DetNet: Deterministic Networking¶
PREOF: Packet Replication, Elimination and Ordering Functions¶
SLO: Service Level Objective¶
The key words "MUST", "MUST NOT", "REQUIRED", "SHALL", "SHALL NOT", "SHOULD", "SHOULD NOT", "RECOMMENDED", "NOT RECOMMENDED", "MAY", and "OPTIONAL" in this document are to be interpreted as described in BCP 14 [RFC2119] and [RFC8174] when, and only when, they appear in all capitals, as shown here. The requirements language is used in Section 6 and applies to future implementations of DetNet OAM.¶
DetNet networks expect to provide communications with predictable low packet delay and packet loss. Most critical applications will define an SLO to be required for the DetNet flows it generates.¶
To respect strict guarantees, DetNet can use an orchestrator able to monitor and maintain the network. Typically, a Software-Defined Network controller places DetNet flows in the deployed network based on their SLO. Thus, resources have to be provisioned a priori for the regular operation of the network. OAM represents the essential elements of the network operation and necessary for OAM resources that need to be accounted for to maintain the network operational.¶
Many legacy OAM tools can be used in DetNet networks, but they are not able to cover all the aspects of deterministic networking. Fulfilling strict guarantees is essential for DetNet flows, resulting in new DetNet specific functionalities that must be covered with OAM. Filling these gaps is inevitable and needs accurate consideration of DetNet specifics. Similar to DetNet flows itself, their OAM needs careful end-to-end engineering as well.¶
For example, appropriate placing of MEPs along the path of a DetNet flow is not always a trivial task and may require proper design together with the design of the service component of a given DetNet flow.¶
There are several DetNet specific challenges for OAM. Bounded network characteristics (e.g., delay, loss) are inseparable service parameters; therefore, PM is a key topic for DetNet. OAM tools are needed to prove the SLO without impacting the DetNet flow characteristics. A further challenge is the strict resource allocation. Resources used by OAM must be considered and allocated to avoid disturbing DetNet flow(s).¶
The DetNet Working Group has defined two sub-layers:¶
OAM mechanisms exist for the DetNet forwarding sub-layer, nonetheless, OAM for the service sub-layer requires new OAM procedures. These new OAM functions must allow, for example, to recognize/discover DetNet relay nodes, to get information about their configuration, and to check their operation or status.¶
DetNet service sub-layer functions using a sequence number. That creates a challenge for inserting OAM packets in the DetNet flow.¶
Fault tolerance also assumes that multiple paths could be provisioned to maintain an end-to-end circuit by adapting to the existing conditions. The DetNet Controller Plane, e.g., central controller/orchestrator, controls the PREOF on a node. OAM is expected to support monitoring and troubleshooting PREOF on a particular node and within the domain.¶
Note that a distributed architecture of of the DetNet Control Plane can also control PREOF in those scenarios where DetNet solutions involve more than one single central controller.¶
DetNet forwarding sub-layer is based on legacy technologies and has a much better coverage regarding OAM. However, the forwarding sub-layer is terminated at DetNet relay nodes, so the end-to-end OAM state of forwarding may be created only based on the status of multiple forwarding sub-layer segments serving a given DetNet flow (e.g., in case of DetNet MPLS, there may be no end-to-end LSP below the DetNet PW).¶
OAM features will enable DetNet with robust operation both for forwarding and routing purposes.¶
It is worth noting that the test and data packets are expected to follow the same path, i.e., the connectivity verification has to be conducted in-band without impacting the data traffic. It is expected that test packets share fate with the monitored data traffic without introducing congestion in normal network conditions.¶
Information about the state of the network can be collected using several mechanisms. Some protocols, e.g., Simple Network Management Protocol, send queries. Others, e.g., YANG-based data models, generate notifications based on the publish-subscribe method. In either way, information is collected and sent using the DetNet Controller Plane.¶
Also, we can characterize methods of transporting OAM information relative to the path of data. For instance, OAM information may be transported in-band or out-of-band relative to the DetNet flow. In case of the former, the telemetry information uses resources allocated for the monitored DetNet flow. If an in-band method of transporting telemetry is used, the amount of generated information needs to be carefully analyzed, and additional resources must be reserved. [RFC9197] defines the in-band transport mechanism where telemetry information is collected in the data packet on which information is generated. Two tracing methods are described - end-to-end, i.e., from the ingress and egress nodes, and hop-by-hop, i.e., like end-to-end with additional information from transit nodes. [I-D.ietf-ippm-ioam-direct-export] and [I-D.mirsky-ippm-hybrid-two-step] are examples of out-of-band telemetry transport. In the former case, information is transported by each node traversed by the data packet of the monitored DetNet flow in a specially constructed packet. In the latter, information is collected in a sequence of follow-up packets that traverse the same path as the data packet of the monitored DetNet flow. In both methods, transport of the telemetry can avoid using resources allocated for the DetNet domain.¶
Continuity check is used to monitor the continuity of a path, i.e., that there exists a way to deliver the packets between two MEP A and MEP B. The continuity check detects a network failure in one direction, from the MEP transmitting test packets to the remote egress MEP.¶
In addition to the Continuity Check, DetNet solutions have to verify the connectivity. This verification considers additional constraints, i.e., the absence of misconnection. The misconnection error state is entered after several consecutive test packets from other DetNet flows are received. The definition of the conditions of entry and exit for misconnection error state is outside the scope of this document.¶
Ping and traceroute are two ubiquitous tools that help localize and characterize a failure in the network. They help to identify a subset of the list of routers in the route. However, to be predictable, resources are reserved per flow in DetNet. Thus, DetNet needs to define route tracing tools able to track the route for a specific flow. Also, tracing can be used for the discovery of the Path Maximum Transmission Unit or location of elements of PREOF for the particular route in the DetNet domain.¶
DetNet is not expected to use Equal-Cost Multipath (ECMP) [RFC8939]. As the result, DetNet OAM in ECMP environment is outside the scope of this document.¶
DetNet expects to operate fault-tolerant networks. Thus, mechanisms able to detect faults before they impact the network performance are needed.¶
The network has to detect when a fault occurred, i.e., the network has deviated from its expected behavior. While the network must report an alarm, the cause may not be identified precisely. For instance, the end-to-end reliability has decreased significantly, or a buffer overflow occurs.¶
An ability to localize the network defect and provide its characterization are necessary elements of network operation.¶
Hybrid OAM methods are used in performance monitoring and defined in [RFC7799] as:¶
A hybrid measurement method may produce metrics as close to passive, but it still alters something in a data packet even if that is the value of a designated field in the packet encapsulation. One example of such a hybrid measurement method is the Alternate Marking method (AMM) described in [RFC8321]. As with all on-path telemetry methods, AMM in a DetNet domain with the IP data plane is natively in-band in respect to the monitored DetNet flow. Because the marking is applied to a data flow, measured metrics are directly applicable to the DetNet flow. AMM minimizes the additional load on the DetNet domain by using nodal collection and computation of performance metrics in combination with optionally using out-of-band telemetry collection for further network analysis.¶
The ability to expose a collection of metrics to support an operator making proper decisions is essential. Following perfromence metris are useful:¶
The optimization of the number of statistics / measurements to collected, frequency of collecting using a distributed and/or centralized mechanisms is an important operational function. Periodic and event-triggered collection information characterizing the state of a network is an example of of of mechanisms to achieve the optimization.¶
DetNet aims to enable real-time communications on top of a heterogeneous multi-hop architecture. To make correct decisions, the DetNet Controller Plane [RFC8655] needs timely information about packet losses/delays for each flow, and each hop of the paths. In other words, just the average end-to-end statistics are not enough. The collected information must be sufficient to allow a systemto predict the worst-case scenario.¶
Service protection (provided by the DetNet Service sub-layer) is designed to cope with simple network failures and mitigates the DetNet Controller Plane's immediate reaction to network events. In the face of events that impact the network operation (e.g., link up/down, device crash/reboot, flows starting and ending), the DetNet Controller Plane needs to perform repair and re-optimization actions in order to permanently ensure the SLO of all active flows with minimal waste of resources. The Controller Plane is expected to be able to continuously retrieve the state of the network, to evaluate conditions and trends about the relevance of a reconfiguration, quantifying:¶
Thus, reconfiguration may only be triggered if the gain is significant.¶
When multiple paths are reserved between two MEPs, packet replication may be used to introduce redundancy and alleviate transmission errors and collisions. For instance, in Figure 1, the source device S is transmitting a packet to devices A and B.¶
Because the quality of service criteria associated with a path may degrade, the network has to provision additional resources along the path.¶
According to [RFC8655], DetNet functionality is divided into forwarding and service sub-layers. The DetNet forwarding sub-layer includes DetNet transit nodes and may allocate resources for a DetNet flow over paths provided by the underlay network. The DetNet service sub-layer includes DetNet relay nodes and provides a DetNet service (e.g., service protection). This section lists general requirements for DetNet OAM as well as requirements in each of the DetNet sub-layers of a DetNet domain.¶
The OAM functions for the DetNet service sub-layer allow, for example, to recognize/discover DetNet relay nodes, to get information about their configuration, and to check their operation or status.¶
The requirements on OAM for a DetNet relay node are:¶
This document has no actionable requirements for IANA. This section can be removed before the publication.¶
This document lists the OAM requirements for a DetNet domain and does not raise any security concerns or issues in addition to ones common to networking and those specific to a DetNet discussed in [RFC9055].¶
The authors express their appreciation and gratitude to Pascal Thubert for the review, insightful questions, and helpful comments.¶