Internet-Draft MNA Usecases May 2022
Saad, et al. Expires 20 November 2022 [Page]
MPLS Working Group
Intended Status:
T. Saad
Juniper Networks
K. Makhijani
Futurewei Technologies
H. Song
Futurewei Technologies
G. Mirsky

Use Cases for MPLS Network Action Indicators and MPLS Ancillary Data


This document presents a number of use cases that have a common need for encoding network action indicators and associated ancillary data inside MPLS packets. There has been significant recent interest in extending the MPLS data plane to carry such indicators and ancillary data to address a number of use cases that are described in this document.

The use cases described in this document are not an exhaustive set, but rather the ones that are actively discussed by members of the IETF MPLS, PALS and DETNET working groups participating in the MPLS Open Design Team.

Status of This Memo

This Internet-Draft is submitted in full conformance with the provisions of BCP 78 and BCP 79.

Internet-Drafts are working documents of the Internet Engineering Task Force (IETF). Note that other groups may also distribute working documents as Internet-Drafts. The list of current Internet-Drafts is at

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This Internet-Draft will expire on 20 November 2022.

Table of Contents

1. Introduction

This document describes important cases that require carrying additional ancillary data within the MPLS packets, as well as means to indicate the ancillary data is present, and a specific action needs to be performed on the packet.

These use cases have been identified by the MPLS Working Group Open Design Team working on defining MPLS Network Actions for the MPLS data plane. The MPLS Ancillary Data (AD) can be classified as:

The use cases described in this document will be used to assist in identifying requirements and issues to be considered for future resolution by the working group.

1.1. Terminology

The following terminology is used in the document:

IETF Network Slice:
a well-defined composite of a set of endpoints, the connectivity requirements between subsets of these endpoints, and associated requirements; the term 'network slice' in this document refers to 'IETF network slice' as defined in [I-D.ietf-teas-ietf-network-slices].
Time-Bound Networking:
Networks that transport time-bounded traffic.

1.2. Acronyms and Abbreviations

  • ISD: In-stack data
  • PSD: Post-stack data
  • MNA: MPLS Network Action
  • NAI: Network Action Indicator
  • AD: Ancillary Data

2. Use Cases

2.1. No Further Fastreroute

MPLS Fast Reroute (FRR) [RFC4090], [RFC5286] and [RFC7490] is a useful and widely deployed tool for minimizing packet loss in the case of a link or node failure.

Several cases exist where, once FRR has taken place in an MPLS network and resulted in rerouting a packet away from the failure, a second FRR that impacts the same packet to rerouting is not helpful, and may even be disruptive.

For example, in such a case, the packet may continue to loop until its TTL expires. This can lead to link congestion and further packet loss. Thus, the attempt to prevent a packet from being dropped may instead affect many other packets. A proposal to address this is presented in [I-D.kompella-mpls-nffrr].

2.2. In-situ OAM

In-situ Operations, Administration, and Maintenance (IOAM) may record operational and telemetry information within the packet while the packet traverses a particular path in a network domain.

The term "in-situ" refers to the fact that the IOAM data fields are added to the data packets rather than being sent within the probe packets specifically dedicated to OAM or Performance Measurement (PM).

IOAM can run in two modes Edge-to-Edge (E2E) and Hop-by-Hop (HbH). In E2E mode, only the encapsulating and decapsulating nodes will process IOAM data fields. In HbH mode, the encapsulating and decapsulating nodes as well as intermediate IOAM-capable nodes process IOAM data fields.

The IOAM data fields are defined in [I-D.ietf-ippm-ioam-data], and can be used for various use-cases of OAM and PM.

[I-D.gandhi-mpls-ioam-sr] defines how IOAM data fields are transported using the MPLS data plane encapsulations, including Segment Routing (SR) with MPLS data plane (SR-MPLS).

The IOAM data may be added after the bottom of the MPLS label stack. The IOAM data fields can be of fixed or incremental size as defined in [I-D.ietf-ippm-ioam-data]. [I-D.gandhi-mpls-ioam] describes the applicability of IOAM to MPLS dataplane. The encapsulating MPLS node needs to know if the decapsulating MPLS node can process the IOAM data before adding it in the packet. In HbH IOAM mode, nodes that are capable of processing IOAM will intercept and process the IOAM data accordingly. The presence of IOAM header and optional IOAM data will betransparent to nodes that do not support or do not participate in the IOAM process.

2.3. Network Slicing

[I-D.ietf-teas-ietf-network-slices] specifies the definition of an IETF Network Slice. It further discusses the general framework for requesting and operating IETF Network Slices, their characteristics, and the necessary system components and interfaces.

Multiple network slices can be realized on top of a single physical network.

In order to overcome scale challenges, IETF Network Slices may be aggregated into groups according to similar characteristics. The slice aggregate [I-D.bestbar-teas-ns-packet] is a construct that comprises of the traffic flows of one or more IETF Network Slices of similar characteristics.

A router that requires forwarding of a packet that belongs to a slice aggregate may have to decide on the forwarding action to take based on selected next-hop(s), and the forwarding treatment (e.g., scheduling and drop policy) to enforce based on the associated per-hop behavior.

The routers in the network that forward traffic over links that are shared by multiple slice aggregates need to identify the slice aggregate packets in order to enforce the associated forwarding action and treatment.

An IETF network slice MAY support the following key features:

  1. A Slice Selector
  2. A Network Resource Partition associated with a slice aggregate.
  3. A Path selection criteria
  4. Verification that per slice Slice Level Objectives (SLOs) are being met. This may be done by active measurements (inferred) or by using hybrid measurement methods, e.g., IOAM.
  5. Additionally, there is an on-going discussion on using Service Functions (SFs) with network slices. This may require insertion of an NSH.
  6. For multi-domain scenarios, a packet that traverses multiple domains may encode different identifiers within each domain.

2.3.1. Global Identifier as Flow-Aggregate Selector

A Global Identifier as a Flow-Aggregate Selector (G-FAS) can be encoded in the MPLS packet as defined in [I-D.kompella-mpls-mspl4fa], [], and [I-D.decraene-mpls-slid-encoded-entropy-label-id]. The G-FAS is used to associate the packets belonging to Slice-Flow Aggregate to the underlying Network Resource Partition (NRP) as described in [I-D.bestbar-teas-ns-packet].

The G-FAS can be encoded within an MPLS label carried in the packet's MPLS label stack. All packets that belong to the same flow aggregate MAY carry the same FAS in the MPLS label stack.

When MPLS packets carry a G-FAS, MPLS LSRs use the forwarding label to select the forwarding next-hop(s), and use the G-FAS in the MPLS packet to infer the specific forwarding treatment that needs to be applied on the packet.

2.3.2. Forwarding Label as a Flow-Aggregate Selector

[RFC3031] states in Section 2.1 that: 'Some routers analyze a packet's network layer header not merely to choose the packet's next hop, but also to determine a packet's "precedence" or "class of service"'.

It is possible by assigning a unique MPLS forwarding label to each flow aggregate (FEC) to distinguish the packets forwarded to the same destination. from other flow aggregates. In this case, LSRs can use the top forwarding label to infer both the forwarding action and the forwarding treatment to be invoked on the packets.

2.4. Delay Budgets for Time-Bound Applications

The routers in a network can perform two distinct functions on incoming packets, namely forwarding (where the packet should be sent) and scheduling (when the packet should be sent). IEEE-802.1 Time Sensitive Networking (TSN) and Deterministic Networking provide several mechanisms for scheduling under the assumption that routers are time-synchronized. The most effective mechanisms for delay minimization involve per-flow resource allocation.

Segment Routing (SR) is a forwarding paradigm that allows encoding forwarding instructions in the packet in a stack data structure, rather than being programmed into the routers. The SR instructions are contained within a packet in the form of a First-in First-out stack dictating the forwarding decisions of successive routers. Segment routing may be used to choose a path sufficiently short to be capable of providing a bounded end-to-end latency but does not influence the queueing of individual packets in each router along that path.

When carried over the MPLS data plane, a solution is required to enable the delivery of such packets that can be delivered to their final destination by a given time budget.

2.4.1. Stack Based Methods for Latency Control

One efficient data structure for inserting local deadlines into the headers is a "stack", similar to that used in Segment Routing to carry forwarding instructions. The number of deadline values in the stack equals the number of routers the packet needs to traverse in the network, and each deadline value corresponds to a specific router. The Top-of-Stack (ToS) corresponds to the first router's deadline while the Bottom-of-Stack (BoS) refers to the last's. All local deadlines in the stack are later or equal to the current time (upon which all routers agree), and times closer to the ToS are always earlier or equal to times closer to the BoS.

The ingress router inserts the deadline stack into the packet headers; no other router needs to be aware of the requirements of the time-bound flows. Hence admitting a new flow only requires updating the information base of the ingress router.

MPLS LSRs that expose the Top of Stack (ToS) label can also inspect the associated "deadline" carried in the packet (either in MPLS stack as ISD or after BoS as PSD).

2.5. NSH-based Service Function Chaining

[RFC8595] describes how Service Function Chaining (SFC) can be realized in an MPLS network by emulating the NSH by using only MPLS label stack elements.

The approach in [RFC8595] introduces some limitations that are discussed in [I-D.lm-mpls-sfc-path-verification]. This approach, however, can benefit from the framework introduced with MNA [I-D.andersson-mpls-mna-fwk].

For example, it may be possible to extend NSH emulation using MPLS labels [RFC8595] to support the functionality of NSH Context Headers, whether fixed or variable-length. One of the use cases could support Flow ID [I-D.ietf-sfc-nsh-tlv] that may be used for load-balancing among Service Function Forwarders (SFFs) and/or the Service Function (SF) within the same SFP.

2.6. Network Programming

In SR, an ingress node steers a packet through an ordered list of instructions, called "segments". Each one of these instructions represents a function to be called at a specific location in the network. A function is locally defined on the node where it is executed and may range from simply moving forward in the segment list to any complex user-defined behavior.

Network Programming combines Segment Routing (SR) functions to achieve a networking objective that goes beyond mere packet routing.

It may be desirable to encode a pointer to function and its arguments within an MPLS packet transport header. For example, in MPLS we can encode the FUNC::ARGs within the label stack or after the Bottom of Stack to support the equivalent of FUNC::ARG in SRv6 as described in [RFC8986].

2.7. Application Aware Networking

Application-aware Networking (APN) as described in [] allows application-aware information (i.e., APN attributes) including APN identification (ID) and/or APN parameters (e.g. network performance requirements) to be encapsulated at network edge devices and carried in packets traversing an APN domain.

The APN data is carried in packets to facilitate service provisioning, and be used to perform fine-granularity traffic steering and network resource adjustment. To support APN in MPLS networks, mechanisms are needed to carry such APN data in MPLS encapsulated packets.

3. Co-existence of Usecases

Two or more of the aforementioned use cases MAY co-exist in the same packet. This may require the presence of multiple ancilary data (whether In-stack or Post-stack ancillary data) to be present in the same MPLS packet.

For example, IOAM may provide key functions along with network slicing to help ensure that critical network slice SLOs are being met by the network provider. In this case, IOAM is able to collect key performance measurement parameters of network slice traffic flows as it traverses the transport network.

4. IANA Considerations

This document has no IANA actions.

5. Security Considerations

This document introduces no new security considerations.

6. Acknowledgement

The authors gratefully acknowledge the input of the members of the MPLS Open Design Team.

7. Contributors

The following individuals contributed to this document:

   Loa Andersson
   Bronze Dragon Consulting

8. Informative References

Andersson, L., Bryant, S., Bocci, M., and T. Li, "MPLS Network Actions Framework", Work in Progress, Internet-Draft, draft-andersson-mpls-mna-fwk-01, , <>.
Saad, T., Beeram, V. P., Dong, J., Wen, B., Ceccarelli, D., Halpern, J., Peng, S., Chen, R., Liu, X., Contreras, L. M., Rokui, R., and L. Jalil, "Realizing Network Slices in IP/MPLS Networks", Work in Progress, Internet-Draft, draft-bestbar-teas-ns-packet-10, , <>.
Decraene, B., Filsfils, C., Henderickx, W., Saad, T., Beeram, V. P., and L. Jalil, "Using Entropy Label for Network Slice Identification in MPLS networks.", Work in Progress, Internet-Draft, draft-decraene-mpls-slid-encoded-entropy-label-id-03, , <>.
Gandhi, R., Ali, Z., Brockners, F., Wen, B., Decraene, B., and V. Kozak, "MPLS Data Plane Encapsulation for In-situ OAM Data", Work in Progress, Internet-Draft, draft-gandhi-mpls-ioam-04, , <>.
Gandhi, R., Ali, Z., Filsfils, C., Brockners, F., Wen, B., and V. Kozak, "MPLS Data Plane Encapsulation for In-situ OAM Data", Work in Progress, Internet-Draft, draft-gandhi-mpls-ioam-sr-06, , <>.
Brockners, F., Bhandari, S., and T. Mizrahi, "Data Fields for In-situ OAM", Work in Progress, Internet-Draft, draft-ietf-ippm-ioam-data-17, , <>.
Wei, Y., Elzur, U., Majee, S., Pignataro, C., and D. E. Eastlake, "Network Service Header (NSH) Metadata Type 2 Variable-Length Context Headers", Work in Progress, Internet-Draft, draft-ietf-sfc-nsh-tlv-15, , <>.
Farrel, A., Drake, J., Rokui, R., Homma, S., Makhijani, K., Contreras, L. M., and J. Tantsura, "Framework for IETF Network Slices", Work in Progress, Internet-Draft, draft-ietf-teas-ietf-network-slices-10, , <>.
Kompella, K., Beeram, V. P., Saad, T., and I. Meilik, "Multi-purpose Special Purpose Label for Forwarding Actions", Work in Progress, Internet-Draft, draft-kompella-mpls-mspl4fa-02, , <>.
Kompella, K. and W. Lin, "No Further Fast Reroute", Work in Progress, Internet-Draft, draft-kompella-mpls-nffrr-02, , <>.
Li, Z., Peng, S., Voyer, D., Xie, C., Liu, P., Qin, Z., and G. Mishra, "Problem Statement and Use Cases of Application-aware Networking (APN)", Work in Progress, Internet-Draft, draft-li-apn-problem-statement-usecases-06, , <>.
Li, Z. and J. Dong, "Carrying Virtual Transport Network Identifier in MPLS Packet", Work in Progress, Internet-Draft, draft-li-mpls-enhanced-vpn-vtn-id-02, , <>.
Yao, L. and G. Mirsky, "MPLS-based Service Function Path(SFP) Consistency Verification", Work in Progress, Internet-Draft, draft-lm-mpls-sfc-path-verification-02, , <>.
Rosen, E., Viswanathan, A., and R. Callon, "Multiprotocol Label Switching Architecture", RFC 3031, DOI 10.17487/RFC3031, , <>.
Pan, P., Ed., Swallow, G., Ed., and A. Atlas, Ed., "Fast Reroute Extensions to RSVP-TE for LSP Tunnels", RFC 4090, DOI 10.17487/RFC4090, , <>.
Atlas, A., Ed. and A. Zinin, Ed., "Basic Specification for IP Fast Reroute: Loop-Free Alternates", RFC 5286, DOI 10.17487/RFC5286, , <>.
Bryant, S., Filsfils, C., Previdi, S., Shand, M., and N. So, "Remote Loop-Free Alternate (LFA) Fast Reroute (FRR)", RFC 7490, DOI 10.17487/RFC7490, , <>.
Farrel, A., Bryant, S., and J. Drake, "An MPLS-Based Forwarding Plane for Service Function Chaining", RFC 8595, DOI 10.17487/RFC8595, , <>.
Filsfils, C., Ed., Camarillo, P., Ed., Leddy, J., Voyer, D., Matsushima, S., and Z. Li, "Segment Routing over IPv6 (SRv6) Network Programming", RFC 8986, DOI 10.17487/RFC8986, , <>.

Authors' Addresses

Tarek Saad
Juniper Networks
Kiran Makhijani
Futurewei Technologies
Haoyu Song
Futurewei Technologies
Greg Mirsky