]> China Unicom

Beijing China tanyx11@chinaunicom.cn

China Unicom

Beijing China zhengyanlei@chinaunicom.cn

Huawei Technologies

italo.busi@huawei.com

Huawei Technologies

China yuchaode@huawei.com

CAICT

China zhaoxing@caict.ac.cn

Routing Common Control and Measurement Plane next generation unicorn sparkling distributed ledger This document defines YANG data models to describe the topology and tunnel information of a fine grain Optical Transport Network. The YANG data models defined in this document are designed to meet the requirements for efficient transmission of sub-1Gbit/s client signals in transport network. About This Document The latest revision of this draft can be found at . Status information for this document may be found at . Discussion of this document takes place on the Common Control and Measurement Plane Working Group mailing list (), which is archived at . Subscribe at . Source for this draft and an issue tracker can be found at .

Introduction Optical Transport Networks (OTN) is a mainstream layer 1 technology for the transport network. Over the years, it has continued to evolve, to improve its transport functions for the emerging requirements. The topology and tunnel information in the OTN has already been defined by generic traffic-engineering models and technology-specific models, including and . In the latest version of OTN, ITU-T G.709/Y.1331 Edition 6.5 , the fine grain OTN (fgOTN) is introduced for the efficient transmission of low rate client signals (e.g., sub-1G). This document presents the control interface requirements of fgOTN, and defines two YANG data models for fgOTN topology and fgOTN tunnel. The topology model can capture topological and resource-related information pertaining to fgOTN. The fgOTN tunnel YANG data model defined in this document is used for the provisioning and management of fgOTN Traffic Engineering (TE) tunnels and Label Switched Paths (LSPs). Furthermore, this document also imports the generic Layer 1 types defined in . The YANG data models defined in this document conform to the Network Management Datastore Architecture (NMDA) defined in .

Terminology and Notations Some of the key terms used in this document are listed as follow.

• fgTS: fine grain Tributary Slot.
• fgODUflex: fine grain Optical channel Data Unit flex.

The following terms are defined in and are not redefined here:

• client
• server
• augment
• data model
• data node

The following terms are defined in and are not redefined here:

• configuration data
• state data

The terminology for describing YANG data models is found in .

Requirements Notation 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 when, and only when, they appear in all capitals, as shown here.

Tree Diagram A simplified graphical representation of the data model is used in of this document. The meaning of the symbols in this diagram is defined in .

Requirements Language 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 when, and only when, they appear in all capitals, as shown here.

Prefixes in Model Names In this documents, names of data nodes and other data model objects are prefixed using the standard prefix associated with the corresponding YANG imported modules, as shown in the following table. Prefixes and corresponding YANG modules

Prefix	Yang Module	Reference
l1-types	ietf-layer1-types	[RFC YYYY]
otnt	ietf-otn-topology	[RFC ZZZZ]
te	ietf-te	[RFC KKKK]
otn-tnl	ietf-otn-tunnel	[RFC JJJJ]
fgotnt	ietf-fgotn-topology	RFC XXXX
fgotn-tnl	ietf-fgotn-tunnel	RFC XXXX

RFC Editor Note: Please replace XXXX with the number assigned to the RFC once this draft becomes an RFC. Please replace YYYY with the RFC numbers assigned to . Please replace ZZZZ with the RFC numbers assigned to . Please replace KKKK with the RFC numbers assigned to . Please replace JJJJ with the RFC numbers assigned to . Please remove this note.

Model Tree Diagrams The tree diagrams extracted from the module(s) defined in this document are given in subsequent sections as per the syntax defined in .

Fine grain Optical Transport Network Scenarios Overview OTN network will cover a larger scope of networks, it may include the backbone network, metro core, metro aggregation, metro access, and even the OTN CPE in the customers' networks . In general, the metro OTN networks support both fgODUflex and ODUk switching. At the boundary nodes (e.g., metro-core nodes) of the metro OTN networks, the fgODUflexes to other metro OTN networks are multiplexed into ODUk of backbone networks. Therefore, the backbone OTN network could only support ODUk switching. The typical scenarios for fgOTN is to provide low bit rate private line or private network services for customers. The interface function requirements of fgOTN mainly include topology resource reporting and service provisioning. Three scenarios that require special consideration are listed based on the characteristics of fgOTN.

Retrieve Server Tunnels Scenario of fgOTN below shows an example of scenario to retrieve server tunnels for multi-domain fgOTN service. In this example, some small bandwidth fgOTN service are aggregated by the access ring (10G), and then aggregated into a bigger bandwidth in metro ring (100G). The allocation of TS to support fgOTN switching maybe different in access ring and metro ring. All link bandwidth information that supports fgOTN should be reported to MDSC by the PNC controller. E.g. there could be three ODU0 allocated in the access ring while there could be two ODU2 are allocated in the metro ring to support fgOTN switching. In this example, the server layer ODUk tunnel for fgOTN tunnel from node A to node E is ODU0, and the server layer tunnel from node E to node G is ODU2. The server layer tunnel for fgOTN tunnel will include one ODU0 tunnel and one ODU2 tunnel.

The Scenario to Retrieve Server Tunnels

Multi-layer Path Splicing Scenario of fgOTN Some operators that would like to provide the paths when there could be different switching capabilities of nodes in their LSP, so that the MDSC coordinator can clearly display multi-layer paths and the relationship between primary-path and secondary-path. In the current network, not all nodes in the operator network support fgOTN, as shown in figure 2, node f1, f2, f3 and f4 support fgOTN, node N-f5 and node N-f6 do not support fgOTN. To present the end-to-end multi-layer primary-path and secondary-path of the services on the client side, it is necessary to complete the end-to-end path splicing based on the the ODU tunnel information associated with the fgotn tunnel. In , assuming that the server layer ODUk tunnel for the fgOTN primary tunnel from node f1 to node f2 is ODU0, the server layer tunnel from node f2 to node f3 is ODU2, and the server layer tunnel from node f3 to node f4 is ODU1. Assuming the server layer ODUk tunnel for the fgOTN secondary tunnel from node f1 to node f2 is ODU2. We need to setup four server layer ODUk tunnels before setting up an fgODUflex tunnel with a primary path and a secondary path to provide protection. To support multi-layer path splicing, we should make some extension on the dependency tunnel structure or on the path element, such as extending the working roles and index of the tunnels.

Multi-layer Path Splicing Scenario of fgOTN

Hitless Bandwidth Adjustment Scenario of fgOTN defines the data plane procedure to support fgODUflex hitless resizing. The support of management of hitless resizing of fgODUflex needs to be carefully considered. The range of fgOTN service's Bandwidth on Demand (BoD) cannot exceed its server layer's bandwidth. The client needs to know how many bandwidth of a link is allocated for fgOTN. When performs hitless resizing, the client sends the fgODUflex identifier and the target bandwidth to the source node controller. After receiving the network management configuration information, the source node triggers the bandwidth adjustment. During the hitless bandwidth adjustment process, it is necessary to reserve or mark the corresponding bandwidth resources first, and then trigger the the bandwidth adjustment actions. Another point to note is that when performing bidirectional hitless resizing for fgODUflex service, the adjustment should be initiated by the client side to a single network management system. Specifically, the adjustment is first performed in the Node 1 to Node 6 direction, and then the reverse direction (Node 6 to Node 1) is automatically triggered for adjustment. Both single domain and multi-domain hitless resizing should be supported. For single domain and multi-domain hitless resizing scenario, the source controller alone report the bandwidth adjustment status to the MDSC coordinator upon completion.

Hitless Resizing Scenario of fgOTN +------+ +------+ +------+ +------+ +------+ +------+ | node |-------| node |-------| node |-------| node |-------| node |-------| node | | 1 |-------| 2 |-------| 3 |-------| 4 |-------| 5 |-------| 6 | +------+ +------+ | +------+ +------+ | +------+ +------+ source | | destination Domain 1 | Domain 2 | Domain 3 | | ]]>

YANG Data Model for fine grain Optical Transport Network Overview In order to provide fgOTN capabilities, this document defines two extension YANG data models augmenting to OTN topology and OTN tunnel YANG model, as defined in and . As defined in Annex M of , fgOTN is defining a new path layer network which complements the existing OTN. Therefore:

• A single network topology instance is used to report both OTN and fgOTN topology information: fgOTN technology-specific attributes are therefore defined in the fgOTN topology model as augmentations of the OTN topology model, but without defining a new network type for fgOTN.
• The OTN tunnel model can be used to setup either an OTN or an fgOTN tunnel: fgOTN technology-specific attributes are therefore defined in the fgOTN tunnel model as augmentations of the OTN tunnel model, which are applicable only when the OTN tunnel is an fgOTN tunnel.

YANG Data Model for fgOTN Topology

Fine Grain OTN Topology Data Model Overview This document aims to describe the data model for fine grain OTN topology. The YANG module presented in this document augments from OTN topology data model, i.e., the ietf-otn-topology, as specified in . In section 6 of , the guideline for augmenting OTN topology model was provided, and in this draft, we augment the OTN topology model to describe the topology characteristics of fgOTN. Common types, identities and groupings defined in is reused in this document. defines an abstract (generic, or base) YANG data model for network/service topologies and inventories, and provides the fundamental model for . OTN topology module in augments from the TE topology YANG model defined in . shows the augmentation relationship.

Relationship between fgOTN topology and OTN topology model

The entities, TE attributes and OTN attributes, such as nodes, termination points and links, are still applicable for describing an fgOTN topology and the model presented in this document only specifies technology-specific attributes/information. The fgOTN-specific attributes including the fgTS, can be used to represent the bandwidth and label information. At the same time, it is necessary to extend the encoding and switching-capability enumeration values in to identify that the current Tunnel Termination Point (TTP) is a termination point of an fgOTN tunnel.

Bandwidth Augmentation Based on the OTN topology model, we augment the bandwidth information of fgOTN, including the max-link-bandwidth and unreserved-bandwidth. The augmented parameter fgotn-bandwidth is used to indicate how much of the bandwidth has been allocated for the usage of fgOTN. For example, if 2 ODU0s are allocated to support fgOTN switching switching, the fgotn-bandwidth is 2500, and the unit is Mbps. The augmented fgotnlist structure is used to describe the unreserved TE bandwidth of fgOTN in the server ODUk. The odu-ts-number is used to indicate the index of server ODUk channel.

Label Augmentation The model augments the label-restriction list with fgOTN technology-specific label information using the otn-label-range-info grouping defined in . The fgts-range list is used to describe the availability of fgOTN timeslot in the server ODUk, including the fgts-reserved and fgts-unreserved. The odu-ts-number is used to indicate the index of server ODUk channel.

YANG Data Model for fgOTN Tunnel

Fine Grain OTN Tunnel Data Model Overview This document aims to describe the data model for fgOTN tunnel. The fgOTN tunnel model augments to OTN tunnel with fgOTN-specific parameters, including the bandwidth information and label information. shows the augmentation relationship.

Relationship between fgOTN and OTN tunnel model

It's also worth noting that the fgOTN tunnel provisioning is usually based on the fgOTN topology. Therefore the fgOTN tunnel model is usually used together with fgOTN topology model specified in this document. The OTN tunnel model also imports a few type modules, including ietf-layer1-types and ietf-te-types. A new identity based on odu-type should be defined for fgODUflex in an updated version of to indicate the bandwidth of fgotn tunnel.

Bandwidth Augmentation The model augment TE bandwidth information of fgOTN tunnel. The string value fgoduflex-bandwidth is used to indicate the bandwidth of this fgOTN tunnel.

Label Augmentation The module augments TE label-hop for the explicit route objects included or excluded by the path computation of the primary-paths and secondary-paths using the fgts-numbers. The fgts-numbers is used to specify fgTS information on inter-domain ports of the routing path. When specifying the fgotn time slot in the routing constraint information, the ODU time slot must also be specified. We also augment the TE label-hop for the record route of the LSP using the fgts-numbers.

YANG Data Model for fgOTN types

fgOTN types YANG module

YANG Tree for fgOTN topology below shows the tree diagram of the YANG data model defined in module "ietf-fgotn-topology" ().

YANG Data Model for fgOTN topology

fgOTN topology YANG module

YANG Tree for fgOTN tunnel below shows the tree diagram of the YANG data model defined in module "ietf-fgotn-tunnel" ().

YANG Data Model for fgOTN tunnel

fgOTN tunnel YANG module

Manageability Considerations <Add any manageability considerations>

Security Considerations <Add any security considerations>

IANA Considerations <Add any IANA considerations>

References Normative References International Telecommunication Union International Telecommunication Union Huawei Technologies Huawei Technologies Alef Edge Nokia Telefonica This document defines a YANG data model for representing, retrieving, and manipulating Optical Transport Network (OTN) topologies. It is independent of control plane protocols and captures topological and resource-related information pertaining to OTN. Huawei Technologies Huawei Technologies Nokia Nokia CAICT This document describes the YANG data model for tunnels in OTN TE networks. The model can be used to do the configuration in order to establish the tunnel in OTN network. This work is independent with the control plane protocols. Huawei Technologies Huawei Technologies This document defines a collection of common common data types, identities, and groupings in the YANG data modeling language. These derived common common data types, identities, and groupings are intended to be imported by modules that model Layer 1 configuration and state capabilities. The Layer 1 types are representative of Layer 1 client signals applicable to transport networks, such as Optical Transport Networks (OTN). The Optical Transport Network (OTN) data structures are included in this document as Layer 1 types. Datastores are a fundamental concept binding the data models written in the YANG data modeling language to network management protocols such as the Network Configuration Protocol (NETCONF) and RESTCONF. This document defines an architectural framework for datastores based on the experience gained with the initial simpler model, addressing requirements that were not well supported in the initial model. This document updates RFC 7950. YANG is a data modeling language used to model configuration data, state data, Remote Procedure Calls, and notifications for network management protocols. This document describes the syntax and semantics of version 1.1 of the YANG language. YANG version 1.1 is a maintenance release of the YANG language, addressing ambiguities and defects in the original specification. There are a small number of backward incompatibilities from YANG version 1. This document also specifies the YANG mappings to the Network Configuration Protocol (NETCONF). The Network Configuration Protocol (NETCONF) defined in this document provides mechanisms to install, manipulate, and delete the configuration of network devices. It uses an Extensible Markup Language (XML)-based data encoding for the configuration data as well as the protocol messages. The NETCONF protocol operations are realized as remote procedure calls (RPCs). This document obsoletes RFC 4741. [STANDARDS-TRACK] In many standards track documents several words are used to signify the requirements in the specification. These words are often capitalized. This document defines these words as they should be interpreted in IETF documents. This document specifies an Internet Best Current Practices for the Internet Community, and requests discussion and suggestions for improvements. RFC 2119 specifies common key words that may be used in protocol specifications. This document aims to reduce the ambiguity by clarifying that only UPPERCASE usage of the key words have the defined special meanings. This document captures the current syntax used in YANG module tree diagrams. The purpose of this document is to provide a single location for this definition. This syntax may be updated from time to time based on the evolution of the YANG language. Cisco Systems Inc Cisco Systems Inc Alef Edge Juniper Networks Individual This document defines a YANG data model for the provisioning and management of Traffic Engineering (TE) tunnels, Label Switched Paths (LSPs), and interfaces. The model covers data that is independent of any technology or dataplane encapsulation and is divided into two YANG modules that cover device-specific, and device independent data. This model covers data for configuration, operational state, remote procedural calls, and event notifications. Informative References This document defines an abstract (generic, or base) YANG data model for network/service topologies and inventories. The data model serves as a base model that is augmented with technology-specific details in other, more specific topology and inventory data models. This document defines a YANG data model for representing, retrieving, and manipulating Traffic Engineering (TE) Topologies. The model serves as a base model that other technology-specific TE topology models can augment. Huawei Futurewei Technologies Alef Edge Cisco Systems Inc. Individual This document defines a collection of common data types, identities, and groupings in YANG data modeling language. These derived common data types, identities and groupings are intended to be imported by other modules, e.g., those which model the Traffic Engineering (TE) configuration and state capabilities. This document obsoletes RFC 8776.

Multi-domain fgOTN Hitless Resizing Process The process of multi-domain fgOTN hitless resizing include five steps. The source controller alone report the hitless bandwidth adjustment status to the MDSC coordinator. To be noted that, the resizing process is divided into two directions, and the resizing is considered successful when both directions have been adjusted. Step 1: The MDSC coordinator sends an resizing command to the source node (Node1) via Controller 1. Step 2: Controller 1 will report a bandwidth adjustment starting status notification, e.g. ietf-te-types:lsp-bandwidth-modifying, to the MDSC. Step 3: Node 1 to node 6 will modify their configuration in the forward direction through data plane node by node. The detail of this process can reference to Annex O.2 of . Step 4: At the same time, the reverse direction bandwidth resizing will be triggered auotmatically by the data plane in node 6. Controller 3 needs to report an bandwidth adjustment starting status notification, ietf-te-types:lsp-bandwidth-modifying, to the MDSC. Step 5: After the reverse direction (Node 6 to Node 1) resizing is completed, Controller 1 will report an ending status notification, ietf-te-types:lsp-bandwidth-modified-ok, to the MDSC. If the hitless resizing fails, the source controller (i.e., Controller 1) needs to report an bandwidth adjustment failure status notification, ietf-te-types:lsp-bandwidth-modify-failed, to the MDSC coordinator. During the whole process, all domain controllers, including the intermediate domain Controller 2, need to report the notifications of topology and tunnel resource changes to the MDSC.

Acknowledgments

Contributors China Unicom

Beijing China wangzl172@chinaunicom.cn

Fiberhome Telecommunication Technologies Co.,LTD

lich@fiberhome.com