]> Guidelines for Authors and Reviewers of Documents Containing YANG Data Models YumaWorks
USA andy@yumaworks.com
Orange
France mohamed.boucadair@orange.com
Huawei
China bill.wu@huawei.com
Operations and Management Network Modeling NETCONF RESTCONF Automation This document provides guidelines for authors and reviewers of specifications containing YANG data models, including IANA-maintained modules. Recommendations and procedures are defined, which are intended to increase interoperability and usability of Network Configuration Protocol (NETCONF) and RESTCONF Protocol implementations that utilize YANG modules. This document obsoletes RFC 8407. Also, this document updates RFC 8126 by providing additional guidelines for writing the IANA considerations for RFCs that specify IANA-maintained modules. Discussion Venues Discussion of this document takes place on the Network Modeling Working Group mailing list (netmod@ietf.org), which is archived at . Source for this draft and an issue tracker can be found at .
Introduction The standardization of network configuration interfaces for use with network configuration management protocols, such as the Network Configuration Protocol (NETCONF) and the RESTCONF Protocol , requires a modular set of data models that can be reused and extended over time. This document defines a set of guidelines for documents containing YANG 1.1 and YANG 1.0 data models, including IANA-maintained modules. YANG is used to define the data structures, protocol operations, and notification content used within a NETCONF and/or RESTCONF server. YANG is also used to define abstract data structures . A NETCONF or RESTCONF server that supports a particular YANG module will support client NETCONF and/or RESTCONF operation requests, as indicated by the specific content defined in the YANG module. Many YANG constructs are defined as optional to use, such as the "description" statement. However, in order to make YANG modules more readable and interoperable, it is desirable to define a set of descriptive usage guidelines that entails a higher level of compliance than the minimum level defined in the YANG specification . In addition, YANG allows constructs such as infinite length identifiers and string values, or top-level mandatory nodes, that a compliant server is not required to support. Only constructs that all servers are required to support can be used in IETF YANG modules. This document defines usage guidelines related to the NETCONF operations layer and NETCONF content layer, as defined in , and the RESTCONF methods and RESTCONF resources, as defined in . These guidelines are intended to be used by authors and reviewers to improve the readability and interoperability of published YANG data models. These guidelines can be used independent of the IETF publication stream or even by other organizations. YANG 1.0 modules have to conform to while YANG 1.1 modules have to conform to . This document adds usage guidelines in addition to these YANG RFCs. updates by providing guidance for writing the IANA considerations for RFCs that specify IANA-maintained modules. Note that this document is not a YANG tutorial, and the reader is expected to know the YANG data modeling language before implementing the guidance in this document.
  • Note to the RFC Editor: Please replace "AAAA" through the document with the RFC number assigned to this document.
Changes Since RFC 8407 The following changes have been made to the guidelines published in :
  • Implemented errata 5693, 5800, 6899, and 7416.
  • Updated the terminology.
  • Added a note about notation conventions.
  • Updated the URL of the IETF authors guidelines.
  • Updated the guidance so that the "file name" after the <CODE BEGINS> tag is mandatory.
  • Added code markers for the security template.
  • Updated the YANG security considerations template to better insist on the key secure transport features.
  • Added statements that the security template is not required for modules that follow or .
  • Added a statement about how to cite the RFCs that are listed in the security template.
  • Added a template for IANA registrations.
  • Added a note that folding of the examples should be done as per conventions.
  • Added a recommendation about long trees.
  • Fixed a reference bug in .
  • Added a recommendation for the use of meaningful prefix values.
  • Added a note that RFC8792-folding of YANG modules can be used if and only if built-in YANG features (e.g., break line, "+") are not sufficient.
  • Added tool validation checks to ensure that YANG modules fit into the line limits of an I-D.
  • Added tool validation checks of JSON-encoded examples.
  • Added a recommendation to ease extracting and validating examples.
  • Updated many examples to be aligned with the consistent indentation recommendation (internal consistency).
  • Updated the IANA considerations to encourage registration requests to indicate whether a module is maintained by IANA or not.
  • Added guidelines for IANA-maintained modules.
  • Added guidelines about the use of "YANG module" and "YANG data model".
  • Elaborated the guidance for the use of values reserved for documentation in examples.
  • Recommended the use of "example:" for URI examples.
  • Added a new section "Defining Standard Tags" () to echo the guidance in .
  • Recommended against the use of "case + when" construct in some cases.
  • Added a discussion about the prefix pattern to use for example modules.
  • Updated the NMDA guidance in the narrative text to highlight modules that are not NMDA-compliant.
  • Added a new section about YANG module classification.
  • Fixed an inconsistency in Section 4.6.2 where the example mentions identities, but uses them without their prefix as per Section 4.6.4.
  • Fixed an inconsistency in Section 4.6.4 which fails to use "derived-from-or-self()" mentioned back in Section 4.6.2.
  • Added a new section for modeling abstract data structures.
  • Added a discussion about "must + error-message" constructs for state data.
  • Added text about summary of changes in revision statements.
  • Added a template for IANA-maintained modules.
  • Updated the wiki URLs to use the new structure instead of the old trac.
  • Added anydata to the list of statements with mandatory description ().
  • Fixed an error (invalid statements) in Section 4.24.
  • Soften generic I-Ds authorship guidance.
Terminology & Notation Conventions Some of the templates defined in the document use "--" to easily identify specific instructions to the authors. Text prefixed with "--" must not be copied as such when using a template. Note that for YANG templates, "//" is used to convey such instructions. RFC IIII is used to refer to an RFC that defines an initial version of an IANA-maintained module. The following terms are used throughout this document:
IANA-maintained module:
A YANG module that is maintained by IANA and has an IANA registry associated with it (e.g., "iana-tunnel-type" or "iana-pseudowire-types" ).
Once an IANA-maintained module is initialized, new values are not directly added to the module. These values are instead added to the companion registry.
IETF module:
A YANG module that is published by the IETF and that is not maintained by IANA.
published:
A stable release of a module or submodule. For example, the "Request for Comments" described in is considered a stable publication.
unpublished:
An unstable release of a module or submodule. For example the "Internet-Draft" described in is considered an unstable publication that is a work in progress, subject to change at any time.
YANG fragment:
A set of YANG statements that are not intended to represent a complete YANG module or submodule. These statements are not intended for actual use, except to provide an example of YANG statement usage. The invalid syntax "..." is sometimes used to indicate that additional YANG statements would be present in a real YANG module.
YANG tree diagram:
A diagram representing the contents of a YANG module, as defined in . It is also called a "tree diagram".
NETCONF Terms The following terms are defined in and are not redefined here:
  • capabilities
  • client
  • operation
  • server
YANG Terms The following terms are defined in and are not redefined here:
  • data node
  • module
  • namespace
  • submodule
  • version
  • YANG
  • YIN
Note that the term 'module' may be used as a generic term for a YANG module or submodule. When describing properties that are specific to submodules, the term 'submodule' is used instead.
Network Management Datastore Architecture (NMDA) Terms The following terms are defined in and are not redefined here:
  • configuration
  • conventional configuration datastore
  • datastore
  • operational state
  • operational state datastore
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.
YANG Data Model vs. YANG Module Both and make a distinction between the following concepts:
data model:
Describes how data is represented and accessed.
YANG structures data models into modules for ease of use .
module:
Defines hierarchies of schema nodes to make a self-contained and compilable block of YANG definitions and inclusions.
A YANG module is typically a single ".yang" file, starting with a "module" statement.
A YANG module may include any number of submodules that are stored in separate ".yang" files starting with a "submodule" statement. Regardless of the presence of submodules, the module and its submodules are externally viewed as a single YANG module.
A YANG data model can consist (1) of a single YANG module (e.g., ) or (2) multiple YANG modules (e.g., ). Note that the term "YANG model" is sometimes used as an abbreviation of YANG data model. However, that term should be avoided in favor of YANG data model. Likewise, "YANG data module" has no meaning and must be avoided. Even if a YANG data model is structured as a single YANG module, YANG data model term should be used in the title, abstract, and in the body of the document where the overall design is described. "YANG module" should be used when a specific "*.yang" file is referenced. Likewise, "YANG module" should be used when using terms related to YANG module specifications (e.g., augmentation or deviation). However, when extending the concepts embodied in a YANG module, authors should refer to those as an extension to the "YANG data model".
General Documentation Guidelines YANG modules under review are likely to be contained in Internet-Drafts (I-Ds). Guidelines for I-D authors can be found at . These guidelines are not repeated here. The following sections MUST be present in an I-D or RFC containing a YANG module:
  • Narrative sections ()
  • Definitions section ()
Additional YANG-specific considerations MUST be included for the following sections:
  • Security Considerations section ()
  • IANA Considerations section ()
  • References section ()
There are three usage scenarios for YANG that can appear in an I-D or RFC:
  • normative module or submodule
  • example module or submodule
  • example YANG fragment not part of any module or submodule
The guidelines in this document refer mainly to a normative module or submodule but may be applicable to example modules and YANG fragments as well.
Module Copyright The module "description" statement MUST contain a reference to the latest approved IETF Trust Copyright statement, which is available online at: ]]>
Code Components Each normative YANG module or submodule contained within an I-D or RFC is considered to be a code component. The strings "<CODE BEGINS>" and "<CODE ENDS>" MUST be used to identify each code component. The "<CODE BEGINS>" tag MUST be followed by a string identifying the file name specified in . The name string form that includes the revision date SHOULD be used. The revision date MUST match the date used in the most recent revision of the module. The following example is for the "2016-03-20" revision of the "ietf-foo" module: file "ietf-foo@2016-03-20.yang" module ietf-foo { namespace "urn:ietf:params:xml:ns:yang:ietf-foo"; prefix "foo"; organization "..."; contact "..."; description "..."; revision 2016-03-20 { description "Latest revision"; reference "RFC FFFF: Foo Protocol"; } // ... more statements } ]]>
Example Modules Example modules are not code components. The <CODE BEGINS> convention MUST NOT be used for example modules. However, example modules MUST be validated. An example module SHOULD be named using the term "example", followed by a hyphen, followed by a descriptive name, e.g., "example-toaster". See regarding the namespace guidelines for example modules.
Terminology Section A terminology section MUST be present if any terms are defined in the document or if any terms are imported from other documents.
Tree Diagrams YANG tree diagrams provide a concise representation of a YANG module and SHOULD be included to help readers understand YANG module structure. Guidelines on tree diagrams can be found in . Tree diagrams longer than one page SHOULD be included in an appendix, i.e., not in the main body of the document. If YANG tree diagrams are used, then an informative reference to the YANG tree diagrams specification MUST be included in the document. Refer to for an example of such a reference.
Narrative Sections The narrative part MUST include an overview section that describes the scope and field of application of the data model(s) defined by the specification and that specifies the relationship (if any) of these data models to other standards, particularly to standards containing other YANG data models. The narrative part SHOULD include one or more sections to briefly describe the structure of the data models defined in the specification. If the module or modules defined by the specification imports definitions from other modules (except for those defined in or ) or are always implemented in conjunction with other modules, then those facts MUST be noted in the overview section; any special interpretations of definitions in other modules MUST be noted as well. Refer to for an example of this overview section. If the document contains major Network Management Datastore Architecture (NMDA) exceptions or include a temporary non-NMDA module , then the Introduction section SHOULD mention this fact with the reasoning that motivated that design. Refer to for more NMDA-related guidance. Specifically, includes a recommendation for designers to describe and justify any NMDA exceptions in detail as part of the module itself. Consistent indentation SHOULD be used for all examples, including YANG fragments and protocol message instance data. If line wrapping is done for formatting purposes, then this SHOULD be indicated per the guidance in , as shown in the following example: this is a long \ value so the line needs to wrap to stay within 72 characters ]]> Built-in YANG features (e.g., breaking line, "+") SHOULD be used to fit a module into the line limits. Exceptionally, RFC8792-folding of YANG modules MAY be used if and only if built-in YANG features are not sufficient. A similar approach (e.g., use "--tree-line-length 69" or split a tree into subtrees) SHOULD be followed for tree diagrams.
YANG Module Classification The narrative section SHOULD include a mention about the classification of a given model. Such a mention is meant to ease positioning the module in the overall operational ecosystem. Specifically, the following types from and can be used:
Service Model:
Describes a service and the parameters of the service in a portable way that can be used uniformly and independent of the equipment and operating environment.
Examples of service models are the L3VPN Service Model (L3SM) and the L2VPN Service Model (L2SM) .
Network Model:
Describes a network-level abstraction (or a subset of aspects of a network infrastructure), including devices and their subsystems, and relevant protocols operating at the link and network layers across multiple devices. This model corresponds to the network configuration model discussed in .
It can be used by a network operator to allocate resources (e.g., tunnel resource, topology resource) for the service or schedule resources to meet the service requirements defined in a service model.
Examples of network models are the L3VPN Network Model (L3NM) or the L2VPN Network Model (L2NM) .
Device Model:
Refers to the Network Element YANG data model described in or the device configuration model discussed in .
Device models are also used to model a function embedded in a device (e.g., Access Control Lists (ACLs) ).
A comprehensive list of device models is provided in Appendix 4.2 of .
Definitions Section This section contains the module(s) defined by the specification. These modules SHOULD be written using the YANG 1.1 syntax. YANG 1.0 syntax MAY be used if no YANG 1.1 constructs or semantics are needed in the module. If any of the imported YANG modules are written using YANG 1.1, then the module MUST be written using YANG 1.1. A YIN syntax version () of the module MAY also be present in the document. There MAY also be other types of modules present in the document, such as Structure of Management Information Version 2 (SMIv2), which are not affected by these guidelines. Note that if the module itself is considered normative and not an example module or example YANG fragment, then all YANG statements within a YANG module are considered normative. The use of keywords defined in and apply to YANG "description" statements in normative modules exactly as they would in any other normative section. Example YANG modules and example YANG fragments MUST NOT contain any normative text, including any all-uppercase reserved words from and . Consistent indentation and formatting (e.g., folding) SHOULD be used in all YANG statements within a module. See for guidelines on YANG usage.
Security Considerations Section Each specification that defines one or more modules MUST contain a section that discusses security considerations relevant to those modules. Unless the modules comply with or define YANG extensions (e.g., ), the security section MUST be modeled after the latest approved template (available at <https://wiki.ietf.org/group/ops/yang-security-guidelines>). contains the security considerations template. Authors MUST check the web page at the URL listed above in case there is a more recent version available. In particular:
  • Writable data nodes that could be especially disruptive if abused MUST be explicitly listed by name, and the associated security risks MUST be explained.
  • Readable data nodes that contain especially sensitive information or that raise significant privacy concerns MUST be explicitly listed by name, and the reasons for the sensitivity/privacy concerns MUST be explained.
  • Operations (i.e., YANG "rpc" statements) that are potentially harmful to system behavior or that raise significant privacy concerns MUST be explicitly listed by name, and the reasons for the sensitivity/privacy concerns MUST be explained.
Documents that exclusively define modules that follow the extension in are not required to include the security template in . Likewise, following the template is not required for modules that define YANG extensions such as .
Security Considerations Section Template " YANG module defines a data model that is designed to be accessed via YANG-based management protocols, such as NETCONF [RFC6241] and RESTCONF [RFC8040]. These YANG-based management protocols (1) have to use a secure transport layer (e.g., SSH [RFC4252], TLS [RFC8446], and QUIC [RFC9000]) and (2) have to use mutual authentication. The Network Configuration Access Control Model (NACM) [RFC8341] provides the means to restrict access for particular NETCONF or RESTCONF users to a preconfigured subset of all available NETCONF or RESTCONF protocol operations and content. -- Writable nodes section: -- -- If the data model contains any writable data nodes (those are all -- the "config true" nodes), then include the following text: There are a number of data nodes defined in this YANG module that are writable/creatable/deletable (i.e., "config true", which is the default). All writable data nodes are likely to be sensitive or vulnerable in some network environments. Write operations (e.g., edit-config) and delete operations to these data nodes without proper protection or authentication can have a negative effect on network operations. The following subtrees and data nodes have particular sensitivities/vulnerabilities: -- If the data model contains any particularly sensitive data nodes, -- e.g., ones that are protected by a "nacm:default-deny-write" -- or a "nacm:default-deny-all" extensions statement, then those -- subtrees and data nodes must be listed, with an explanation of the -- associated security risks with a focus on how they can be -- disruptive if abused. Otherwise, state: -- -- "There are no particularly sensitive writable data nodes." -- Readable nodes section: -- -- If the data model contains any readable data nodes (i.e., those -- that are "config false" nodes, but also all other nodes, because -- they can also be read via operations like get or get-config), then -- include the following text: Some of the readable data nodes in this YANG module may be considered sensitive or vulnerable in some network environments. It is thus important to control read access (e.g., via get, get-config, or notification) to these data nodes. Specifically, the following subtrees and data nodes have particular sensitivities/ vulnerabilities: -- You must evaluate whether the data model contains any readable -- data nodes (those are all the "config false" nodes, but also all -- other nodes, because they can also be read via operations like get -- or get-config) are particularly sensitive or vulnerable (e.g., -- if they might reveal customer information or violate personal -- privacy laws). Typically, particularly sensitive readable -- data nodes are ones that are protected by a -- "nacm:default-deny-read" or a "nacm:default-deny-all" extensions -- statement. -- -- Otherwise, state: -- "There are no particularly sensitive readable data nodes." -- RPC/action operations section: -- -- If the data model contains any RPC or action operations, then -- include the following text: Some of the RPC or action operations in this YANG module may be considered sensitive or vulnerable in some network environments. It is thus important to control access to these operations. Specifically, the following operations have particular sensitivities/ vulnerabilities: -- If the data model contains any particularly sensitive RPC -- or action operations, then those operations must be listed -- here, along with an explanation of the associated specific -- sensitivity or vulnerability concerns. -- -- Otherwise, state: -- "There are no particularly sensitive RPC or action operations." -- Reusable groupings from other modules section: -- -- If the data model reuses groupings from other modules and -- the document that specifies these groupings also -- includes those as data nodes, then add this text to remind -- the specific sensitivity or vulnerability of reused nodes. This YANG module uses groupings from other YANG modules that define nodes that may be considered sensitive or vulnerable in network environments. Refer to the Security Considerations of for information as to which nodes may be considered sensitive or vulnerable in network environments. -- No data nodes section: -- -- If the data model does not define any data nodes (i.e., none -- of the above sections or readable/writable data nodes or RPCs -- have been included), then add the following text: The YANG module defines a set of identities, types, and groupings. These nodes are intended to be reused by other YANG modules. The module by itself does not expose any data nodes that are writable, data nodes that contain read-only state, or RPCs. As such, there are no additional security issues related to the YANG module that need to be considered. Modules that use the groupings that are defined in this document should identify the corresponding security considerations. For example, reusing some of these groupings will expose privacy-related information (e.g., 'node-example'). ]]>
Note:
(or a future RFC that replaces it) MUST be listed as a normative reference.
By default, , , , , , and RFC AAAA (or future RFCs that replace any of them) are listed as informative references unless normatively cited in other sections of the document that specifies the YANG module.
IANA Considerations Section Each normative YANG module MUST be registered in both the "IETF XML Registry" and the "YANG Module Names" registry . The registration request in the "YANG Module Names" registry should indicate whether the module is IANA-maintained or not. This applies to new modules and updated modules. An example of an update registration for the "ietf-template" module can be found in . Additional IANA considerations applicable to IANA-maintained modules (including instructions to maintain them) are provided in .
Documents That Create a New Namespace If an I-D defines a new namespace that is to be administered by the IANA, then the document MUST include an IANA Considerations section that specifies how the namespace is to be administered. Specifically, if any YANG module namespace statement value contained in the document is not already registered with IANA, then a new entry in the "ns" registry within the "IETF XML Registry" group MUST be requested from the IANA. A registration template for new YANG modules is provided in .
Documents That Extend an Existing Namespace It is possible to extend an existing namespace using a YANG submodule that belongs to an existing module already administered by IANA. In this case, the document containing the main module MUST be updated to use the latest revision of the submodule.
Registration Templates
IANA Template for Documents Defining New YANG Modules A registration template for a new module is provided below:
IANA Template for Revising YANG Modules A registration template for a revised module is provided below:
References Sections For every import or include statement that appears in a module contained in the specification that identifies a module in a separate document, a corresponding normative reference to that document MUST appear in the Normative References section. The reference MUST correspond to the specific module version actually used within the specification. For every normative reference statement that appears in a module contained in the specification that identifies a separate document, a corresponding normative reference to that document SHOULD appear in the Normative References section. The reference SHOULD correspond to the specific document version actually used within the specification. If the reference statement identifies an informative reference that identifies a separate document, a corresponding informative reference to that document MAY appear in the Informative References section.
Validation Tools All modules need to be validated before submission in an I-D. The 'pyang' YANG compiler is freely available from GitHub: ]]> If the 'pyang' compiler is used to validate a normative module, then the "--ietf" command-line option MUST be used to identify any IETF guideline issues. If the 'pyang' compiler is used to validate an example module, then the "--ietf" command-line option MAY be used to identify any IETF guideline issues. To ensure that a module fits into the line limits of an I-D, the command "pyang -f yang --keep-comments --yang-line-length 69" should be used. The "yanglint" program is also freely available from GitHub. ]]> This tool can be used to validate XPath statements within YANG modules. To check that JSON-encoded examples comply with the target data models, programs such as "yangson" or "yanglint" should be used. Both programs are freely available from GitHub. ]]>
Module Extraction Tools A version of 'rfcstrip' that will extract YANG modules from an I-D or RFC is available. The 'rfcstrip' tool that supports YANG module extraction is freely available at: ]]> This tool can be used to verify that the "<CODE BEGINS>" and "<CODE ENDS>" tags are used correctly and that the normative YANG modules can be extracted correctly. The 'xym' tool is freely available on GitHub and can be used to extract YANG modules from a document. ]]>
Module Usage Examples Each specification that defines one or more modules SHOULD contain usage examples, either throughout the document or in an appendix. This includes example instance document snippets in an appropriate encoding (e.g., XML and/or JSON) to demonstrate the intended usage of the YANG module(s). Examples MUST be validated. Refer to for tools that validate YANG modules and examples. If IP addresses/prefixes are used, then a mix of either IPv4 and IPv6 addresses/prefixes or IPv6 addresses/prefixes exclusively SHOULD be used in the examples. For some types (IP addresses, domain names, etc.), the IETF has reserved values for documentation use. Authors SHOULD use these reserved values in the usage examples if these types are used. Examples of reserved values are listed below:
  • IPv4 and IPv6 addresses/prefixes reserved for documentation are defined in , , and .
  • The Enterprise Number 32473 reserved for documentation use is defined in .
  • Autonomous System Numbers (ASNs) reserved for documentation use are defined in .
  • Reserved domain names for documentation are defined in .
URI examples SHOULD be prefixed with "example:". In order to ease extraction and validation of examples, it is RECOMMENDED to use code markers.
YANG Usage Guidelines Modules in IETF Standards Track specifications MUST comply with all syntactic and semantic requirements of YANG 1.1 . See the exception for YANG 1.0 in Section 3.6. The guidelines in this section are intended to supplement the YANG specification , which is intended to define a minimum set of conformance requirements. In order to promote interoperability and establish a set of practices based on previous experience, the following sections establish usage guidelines for specific YANG constructs. Only guidelines that clarify or restrict the minimum conformance requirements are included here. A template for IETF modules is provided in .
Module Naming Conventions Normative modules contained in Standards Track documents MUST be named according to the guidelines in the IANA Considerations section of . A distinctive word or abbreviation (e.g., protocol name or working group abbreviation) SHOULD be used in the module name. If new definitions are being defined to extend one or more existing modules, then the same word or abbreviation should be reused, instead of creating a new one. All published module names MUST be unique. For a YANG module published in an RFC, this uniqueness is guaranteed by IANA (). For unpublished modules, the authors need to check that no other work in progress is using the same module name. Example modules are non-normative and SHOULD be named with the prefix "example-". It is suggested that a stable module name prefix be selected that represents the entire organization. All normative YANG modules published by the IETF MUST begin with the prefix "ietf-". All IANA-maintained YANG modules MUST begin with the prefix "iana-". Another standards organization, such as the IEEE, might use the prefix "ieee-" for all YANG modules. Once a module name is published, it MUST NOT be reused, even if the RFC containing the module is reclassified to "Historic" status. A module name cannot be changed in YANG, and this would be treated as a new module, not a name change.
Prefixes All YANG definitions are scoped by the module containing the definition being referenced. This allows the same name to be used in multiple modules, even if the names are not unique. In the example below, the identifier "foo" is used in all three modules: YANG defines the following rules for prefix usage:
  • Prefixes are never used for built-in data types and YANG keywords.
  • A prefix MUST be used for any external statement (i.e., a statement defined with the YANG "extension" statement).
  • The proper module prefix MUST be used for all identifiers imported from other modules.
  • The proper module prefix MUST be used for all identifiers included from a submodule.
The following guidelines apply to prefix usage of the current (local) module:
  • The local module prefix SHOULD be used instead of no prefix in all path expressions.
  • The local module prefix MUST be used instead of no prefix in all "default" statements for an "identityref" or "instance-identifier" data type.
  • The local module prefix MAY be used for references to typedefs, groupings, extensions, features, and identities defined in the module.
Consistent with , the prefix defined by a module SHOULD be used when the module is imported, unless there is a conflict. Prefix values SHOULD be short but meaningful to the intended user. Prefix values SHOULD NOT conflict with known modules that have been previously published. For convenience, prefix values of example modules SHOULD be prefixed with "ex" or similar patterns. In doing so, readers of example modules or tree diagrams that mix both example and standard modules can easily identify example parts.
Identifiers All YANG identifiers in published modules MUST be between 1 and 64 characters in length. These include any construct specified as an "identifier-arg-str" token in the ABNF in .
Identifier Naming Conventions Identifiers SHOULD follow a consistent naming pattern throughout the module. Only lowercase letters, numbers, and dashes SHOULD be used in identifier names. Uppercase characters, the period character, and the underscore character MAY be used if the identifier represents a well-known value that uses these characters. YANG does not permit any other characters in YANG identifiers. Identifiers SHOULD include complete words and/or well-known acronyms or abbreviations. Child nodes within a container or list SHOULD NOT replicate the parent identifier. YANG identifiers are hierarchical and are only meant to be unique within the set of sibling nodes defined in the same module namespace. List identifiers SHOULD be singular with the surrounding container name plural. Similarly, "leaf-list" identifiers SHOULD be singular. It is permissible to use common identifiers such as "name" or "id" in data definition statements, especially if these data nodes share a common data type. Identifiers SHOULD NOT carry any special semantics that identify data modeling properties. Only YANG statements and YANG extension statements are designed to convey machine-readable data modeling properties. For example, naming an object "config" or "state" does not change whether it is configuration data or state data. Only defined YANG statements or YANG extension statements can be used to assign semantics in a machine-readable format in YANG.
Defaults In general, it is suggested that substatements containing very common default values SHOULD NOT be present. The substatements listed in are commonly used with the default value, which would make the module difficult to read if used everywhere they are allowed. Statement Defaults
Statement Default Value
config true
mandatory false
max-elements unbounded
min-elements 0
ordered-by system
status current
yin-element false
Conditional Statements A module may be conceptually partitioned in several ways, using the "if-feature" and/or "when" statements. Data model designers need to carefully consider all modularity aspects, including the use of YANG conditional statements. If a data definition is optional, depending on server support for a NETCONF or RESTCONF protocol capability, then a YANG "feature" statement SHOULD be defined. The defined "feature" statement SHOULD then be used in the conditional "if-feature" statement referencing the optional data definition. If any notification data, or any data definition, for a non- configuration data node is not mandatory, then the server may or may not be required to return an instance of this data node. If any conditional requirements exist for returning the data node in a notification payload or retrieval request, they MUST be documented somewhere. For example, a "when" or "if-feature" statement could apply to the data node, or the conditional requirements could be explained in a "description" statement within the data node or one of its ancestors (if any). If any "if-feature" statements apply to a list node, then the same "if-feature" statements MUST apply to any key leaf nodes for the list. There MUST NOT be any "if-feature" statements applied to any key leafs that do not also apply to the parent list node. There SHOULD NOT be any "when" statements applied to a key leaf node. It is possible that a "when" statement for an ancestor node of a key leaf will have the exact node-set result as the key leaf. In such a case, the "when" statement for the key leaf is redundant and SHOULD be avoided. Some modules use "case + when" construct but provide duplicated information (e.g., the "when" statements are constraining a single case in the choice as shown in the example below). Such constructs with duplicated information SHOULD NOT be used. The following example removes the duplicated information: Note that the use of "case + when" is still useful in cases where complementary modelling constraints should be expressed. See the example provided below. includes provisions for defining constraints on state data and specifies that a constraint must be true in a valid state data tree. However, softens that behavior by allowing semantic constraints to be violated under some circumstances to help to detect anomalies. Relaxing validation constraints on state data is meant to reveal deviations of the observed behavior vs. intended behavior of a managed entity and hopefully trigger corrective actions by a management system. From that perspective, it is RECOMMENDED to avoid defining constraints on state data that would hinder the detection by a management system of abnormal behaviors of a managed entity.
XPath Usage This section describes guidelines for using the XML Path Language (XPath) within YANG modules.
XPath Evaluation Contexts YANG defines five separate contexts for evaluation of XPath statements:
  1. The "running" datastore: collection of all YANG configuration data nodes. The document root is the conceptual container (e.g., "config" in the "edit-config" operation), which is the parent of all top-level data definition statements with a "config" statement value of "true".
  2. State data + the "running" datastore: collection of all YANG data nodes. The document root is the conceptual container, parent of all top-level data definition statements.
  3. Notification: an event notification document. The document root is the notification element.
  4. RPC Input: The document root is the conceptual "input" node, which is the parent of all RPC input parameter definitions.
  5. RPC Output: The document root is the conceptual "output" node, which is the parent of all RPC output parameter definitions.
Note that these XPath contexts cannot be mixed. For example, a "when" statement in a notification context cannot reference configuration data. It is especially important to consider the XPath evaluation context for XPath expressions defined in groupings. An XPath expression defined in a grouping may not be portable, meaning it cannot be used in multiple contexts and produce proper results. If the XPath expressions defined in a grouping are intended for a particular context, then this context SHOULD be identified in the "description" statement for the grouping.
Function Library The "position" and "last" functions SHOULD NOT be used. This applies to implicit use of the "position" function as well (e.g., '//chapter[42]'). A server is only required to maintain the relative XML document order of all instances of a particular user-ordered list or leaf-list. The "position" and "last" functions MAY be used if they are evaluated in a context where the context node is a user- ordered "list" or "leaf-list". The "id" function SHOULD NOT be used. The "ID" attribute is not present in YANG documents, so this function has no meaning. The XPath execution environment SHOULD return an empty string for this function. The "namespace-uri" and "name" functions SHOULD NOT be used. Expanded names in XPath are different than YANG. A specific canonical representation of a YANG-expanded name does not exist. The "lang" function SHOULD NOT be used. This function does not apply to YANG because there is no "lang" attribute set with the document. The XPath execution environment SHOULD return "false" for this function. The "local-name", "namespace-uri", "name", "string", and "number" functions SHOULD NOT be used if the argument is a node-set. If so, the function result will be determined by the document order of the node-set. Since this order can be different on each server, the function results can also be different. Any function call that implicitly converts a node-set to a string will also have this issue. The "local-name" function SHOULD NOT be used to reference local names outside of the YANG module that defines the must or when expression containing the "local-name" function. Example of a "local-name" function that should not be used: The "derived-from-or-self" function SHOULD be used instead of an equality expression for identityref values. This allows the identities to be conceptually augmented. Example:
Axes The "attribute" and "namespace" axes are not supported in YANG and MAY be empty in a NETCONF or RESTCONF server implementation. The "preceding" and "following" axes SHOULD NOT be used. These constructs rely on XML document order within a NETCONF or RESTCONF server configuration database, which may not be supported consistently or produce reliable results across implementations. Predicate expressions based on static node properties (e.g., element name or value, and "ancestor" or "descendant" axes) SHOULD be used instead. The "preceding" and "following" axes MAY be used if document order is not relevant to the outcome of the expression (e.g., check for global uniqueness of a parameter value). The "preceding-sibling" and "following-sibling" axes SHOULD NOT be used; however, they MAY be used if document order is not relevant to the outcome of the expression. A server is only required to maintain the relative XML document order of all instances of a particular user-ordered list or leaf-list. The "preceding-sibling" and "following-sibling" axes MAY be used if they are evaluated in a context where the context node is a user-ordered "list" or "leaf-list".
Types Data nodes that use the "int64" and "uint64" built-in type SHOULD NOT be used within numeric or boolean expressions. There are boundary conditions in which the translation from the YANG 64-bit type to an XPath number can cause incorrect results. Specifically, an XPath "double" precision floating-point number cannot represent very large positive or negative 64-bit numbers because it only provides a total precision of 53 bits. The "int64" and "uint64" data types MAY be used in numeric expressions if the value can be represented with no more than 53 bits of precision. Data modelers need to be careful not to confuse the YANG value space and the XPath value space. The data types are not the same in both, and conversion between YANG and XPath data types SHOULD be considered carefully. Explicit XPath data type conversions MAY be used (e.g., "string", "boolean", or "number" functions), instead of implicit XPath data type conversions. XPath expressions that contain a literal value representing a YANG identity SHOULD always include the declared prefix of the module where the identity is defined. XPath expressions for "when" statements SHOULD NOT reference the context node or any descendant nodes of the context node. They MAY reference descendant nodes if the "when" statement is contained within an "augment" statement, and the referenced nodes are not defined within the "augment" statement. Example:
Wildcards It is possible to construct XPath expressions that will evaluate differently when combined with several modules within a server implementation rather than when evaluated within the single module. This is due to augmenting nodes from other modules. Wildcard expansion is done within a server against all the nodes from all namespaces, so it is possible for a "must" or "when" expression that uses the '*' operator to always evaluate to false if processed within a single YANG module. In such cases, the "description" statement SHOULD clarify that augmenting objects are expected to match the wildcard expansion.
Boolean Expressions The YANG "must" and "when" statements use an XPath boolean expression to define the test condition for the statement. It is important to specify these expressions in a way that will not cause inadvertent changes in the result if the objects referenced in the expression are updated in future revisions of the module. For example, the leaf "foo2" must exist if the leaf "foo1" is equal to "one" or "three": In the next revision of the module, leaf "foo1" is extended with a new enum named "four": Now the first XPath expression will allow the enum "four" to be accepted in addition to the "one" and "three" enum values.
YANG Definition Lifecycle Management The YANG status statement MUST be present within a definition if its value is "deprecated" or "obsolete". The status SHOULD NOT be changed from "current" directly to "obsolete". An object SHOULD be available for at least one year after the publication date with a "deprecated" status before it is changed to "obsolete". The module or submodule name MUST NOT be changed, once the document containing the module or submodule is published. The module namespace URI value MUST NOT be changed, once the document containing the module is published. The revision date substatement within the import statement SHOULD be present if any groupings are used from the external module. The revision date substatement within the include statement SHOULD be present if any groupings are used from the external submodule. If an import statement is for a module from a stable source (e.g., an RFC for an IETF module), then a reference-stmt SHOULD be present within an import statement. If submodules are used, then the document containing the main module MUST be updated so that the main module revision date is equal to or more recent than the revision date of any submodule that is (directly or indirectly) included by the main module. Definitions for future use SHOULD NOT be specified in a module. Do not specify placeholder objects like the "reserved" example below:
Module Header, Meta, and Revision Statements For published modules, the namespace MUST be a globally unique URI, as defined in . This value is usually assigned by the IANA. The "organization" statement MUST be present. If the module is contained in a document intended for IETF Standards Track status, then the organization SHOULD be the IETF working group (WG) chartered to write the document. Exceptions may be example modules, IANA-maintained modules, or modules contained in AD-sponsored documents. For other standards organizations, a similar approach is also suggested. The "contact" statement MUST be present. If the module is contained in a document intended for Standards Track status, then the WG web and mailing information SHOULD be present, and the main document author or editor contact information SHOULD be present. If additional authors or editors exist, their contact information MAY be present. There is no need to include the contact information for WG Chairs. The "description" statement MUST be present. For modules published within IETF documents, the appropriate IETF Trust Copyright text MUST be present, as described in Section 3.1 and contain the following statement:
  • All revisions of IETF and IANA published modules can be found at the YANG Parameters registry: https://www.iana.org/assignments/yang-parameters.
If the module relies on information contained in other documents, which are not the same documents implied by the import statements present in the module, then these documents MUST be identified in the reference statement. A "revision" statement MUST be present for each published version of the module. The "revision" statement MUST have a "reference" substatement. It MUST identify the published document that contains the module. Modules are often extracted from their original documents, and it is useful for developers and operators to know how to find the original source document in a consistent manner. The "revision" statement MAY have a "description" substatement. For convenience, the description text of a new published revision may summarize any changes made to a module compared to the previous published revision. Typically, that list is a YANG-specific subset of the summary of changes listing any changes made from the RFC being updated or obsoleted as per . The following example shows the revision statement for a published YANG module: The following example shows the revision statements for a published YANG module that updates a published module. The new revision statement summarizes the changes compared to the previous published revision. For an unpublished module, a complete history of each unpublished module revision is not required. That is, within a sequence of draft versions, only the most recent revision need be recorded in the module. Do not remove or reuse a revision statement for a published module. A new revision date is not required unless the module contents have changed. If the module contents have changed, then the revision date of that new module version MUST be updated to a date later than that of the previous version. The following example shows the revision statements for an unpublished update to a published YANG module. The latest revision statement of the unpublished module summarizes the changes compared to the previous revision.
Namespace Assignments It is RECOMMENDED that only valid YANG modules be included in documents, whether or not the modules are published yet. This allows:
  • the module to compile correctly instead of generating disruptive fatal errors.
  • early implementors to use the modules without picking a random value for the XML namespace.
  • early interoperability testing since independent implementations will use the same XML namespace value.
Until a URI is assigned by the IANA, a proposed namespace URI MUST be provided for the namespace statement in a YANG module. A value SHOULD be selected that is not likely to collide with other YANG namespaces. Standard module names, prefixes, and URI strings already listed in the "YANG Module Names" registry group MUST NOT be used. A standard namespace statement value SHOULD have the following form: : ]]> The following URN prefix string SHOULD be used for published and unpublished YANG modules: The following example URNs would be valid namespace statement values for Standards Track modules: Note that a different URN prefix string SHOULD be used for modules that are not Standards Track. The string SHOULD be selected according to the guidelines in . The following URIs exemplify what might be used by modules that are not Standards Track. Note that the domain "example.com" SHOULD be used by example modules in IETF I-Ds. These URIs are not intended to be dereferenced. They are used for module namespace identification only. Example URIs using URLs per : Example URIs using tags per :
Top-Level Data Definitions The top-level data organization SHOULD be considered carefully, in advance. Data model designers need to consider how the functionality for a given protocol or protocol family will grow over time. The separation of configuration data and operational state SHOULD be considered carefully. It is sometimes useful to define separate top- level containers for configuration and non-configuration data. For some existing top-level data nodes, configuration data was not in scope, so only one container representing operational state was created. Refer to NMDA for details. The number of top-level data nodes within a module SHOULD be minimized. It is often useful to retrieve related information within a single subtree. If data is too distributed, it becomes difficult to retrieve all at once. The names and data organization SHOULD reflect persistent information, such as the name of a protocol. The name of the working group SHOULD NOT be used because this may change over time. A mandatory database data definition is defined as a node that a client must provide for the database to be valid. The server is not required to provide a value. Top-level database data definitions MUST NOT be mandatory. If a mandatory node appears at the top level, it will immediately cause the database to be invalid. This can occur when the server boots or when a module is loaded dynamically at runtime.
Data Types Selection of an appropriate data type (i.e., built-in type, existing derived type, or new derived type) is very subjective; therefore, few requirements can be specified on that subject. Data model designers SHOULD use the most appropriate built-in data type for the particular application. The signed numeric data types (i.e., "int8", "int16", "int32", and "int64") SHOULD NOT be used unless negative values are allowed for the desired semantics.
Fixed-Value Extensibility If the set of values is fixed and the data type contents are controlled by a single naming authority (e.g., IANA), then an enumeration data type SHOULD be used. If distributed extensibility or hierarchical organization of enumerated values is required, then the "identityref" data type SHOULD be used instead of an enumeration or other built-in type. Note that any module can declare an identity with base "foo-type" that is valid for the "foo" leaf. Identityref values are considered to be qualified names.
Patterns and Ranges For string data types, if a machine-readable pattern can be defined for the desired semantics, then one or more pattern statements SHOULD be present. A single-quoted string SHOULD be used to specify the pattern, since a double-quoted string can modify the content. If the patterns used in a type definition have known limitations such as false negative or false positive matches, then these limitations SHOULD be documented within the typedef or data definition. The following typedef from demonstrates the proper use of the "pattern" statement: For string data types, if the length of the string is required to be bounded in all implementations, then a length statement MUST be present. The following typedef from demonstrates the proper use of the "length" statement: For numeric data types, if the values allowed by the intended semantics are different than those allowed by the unbounded intrinsic data type (e.g., "int32"), then a range statement SHOULD be present. The following typedef from demonstrates the proper use of the "range" statement:
Enumerations and Bits For "enumeration" or "bits" data types, the semantics for each "enum" or "bit" SHOULD be documented. A separate "description" statement (within each "enum" or "bit" statement) SHOULD be present.
Union Types The YANG "union" type is evaluated by testing a value against each member type in the union. The first type definition that accepts a value as valid is the member type used. In general, member types SHOULD be ordered from most restrictive to least restrictive types. In the following example, the "enumeration" type will never be matched because the preceding "string" type will match everything. Incorrect: Correct: It is possible for different member types to match, depending on the input encoding format. In XML, all values are passed as string nodes; but in JSON, there are different value types for numbers, booleans, and strings. In the following example, a JSON numeric value will always be matched by the "int32" type, but in XML the string value representing a number will be matched by the "string" type. The second version will match the "int32" member type no matter how the input is encoded. Incorrect: Correct:
Empty and Boolean YANG provides an "empty" data type, which has one value (i.e., present). The default is "not present", which is not actually a value. When used within a list key, only one value can (and must) exist for this key leaf. The type "empty" SHOULD NOT be used for a key leaf since it is pointless. There is really no difference between a leaf of type "empty" and a leaf-list of type "empty". Both are limited to one instance. The type "empty" SHOULD NOT be used for a leaf-list. The advantage of using type "empty" instead of type "boolean" is that the default (not present) does not take up any bytes in a representation. The disadvantage is that the client may not be sure if an empty leaf is missing because it was filtered somehow or not implemented. The client may not have a complete and accurate schema for the data returned by the server and may not be aware of the missing leaf. The YANG "boolean" data type provides two values ("true" and "false"). When used within a list key, two entries can exist for this key leaf. Default values are ignored for key leafs, but a default statement is often used for plain boolean leafs. The advantage of the "boolean" type is that the leaf or leaf-list has a clear representation for both values. The default value is usually not returned unless explicitly requested by the client, so no bytes are used in a typical representation. In general, the "boolean" data type SHOULD be used instead of the "empty" data type, as shown in the example below: Incorrect: Correct:
Reusable Type Definitions If an appropriate derived type exists in any standard module, such as , then it SHOULD be used instead of defining a new derived type. If an appropriate units identifier can be associated with the desired semantics, then a units statement SHOULD be present. If an appropriate default value can be associated with the desired semantics, then a default statement SHOULD be present. If a significant number of derived types are defined, and it is anticipated that these data types will be reused by multiple modules, then these derived types SHOULD be contained in a separate module or submodule, to allow easier reuse without unnecessary coupling. The "description" statement MUST be present. If the type definition semantics are defined in an external document (other than another YANG module indicated by an import statement), then the reference statement MUST be present.
Reusable Groupings A reusable grouping is a YANG grouping that can be imported by another module and is intended for use by other modules. This is not the same as a grouping that is used within the module in which it is defined, but it happens to be exportable to another module because it is defined at the top level of the YANG module. The following guidelines apply to reusable groupings, in order to make them as robust as possible:
  • Clearly identify the purpose of the grouping in the "description" statement.
  • There are five different XPath contexts in YANG (rpc/input, rpc/output, notification, "config true" data nodes, and all data nodes). Clearly identify which XPath contexts are applicable or excluded for the grouping.
  • Do not reference data outside the grouping in any "path", "must", or "when" statements.
  • Do not include a "default" substatement on a leaf or choice unless the value applies on all possible contexts.
  • Do not include a "config" substatement on a data node unless the value applies on all possible contexts.
  • Clearly identify any external dependencies in the grouping "description" statement, such as nodes referenced by an absolute path from a "path", "must", or "when" statement.
Data Definitions The "description" statement MUST be present in the following YANG statements:
  • anydata
  • anyxml
  • augment
  • choice
  • container
  • extension
  • feature
  • grouping
  • identity
  • leaf
  • leaf-list
  • list
  • notification
  • rpc
  • typedef
If the data definition semantics are defined in an external document, (other than another YANG module indicated by an import statement), then a reference statement MUST be present. The "anyxml" construct may be useful to represent an HTML banner containing markup elements, such as "<b>" and "</b>", and MAY be used in such cases. However, this construct SHOULD NOT be used if other YANG data node types can be used instead to represent the desired syntax and semantics. It has been found that the "anyxml" statement is not implemented consistently across all servers. It is possible that mixed-mode XML will not be supported or that configuration anyxml nodes will not be supported. If there are referential integrity constraints associated with the desired semantics that can be represented with XPath, then one or more "must" statements SHOULD be present. For list and leaf-list data definitions, if the number of possible instances is required to be bounded for all implementations, then the max-elements statements SHOULD be present. If any "must" or "when" statements are used within the data definition, then the data definition "description" statement SHOULD describe the purpose of each one. The "choice" statement is allowed to be directly present within a "case" statement in YANG 1.1. This needs to be considered carefully. Consider simply including the nested "choice" as additional "case" statements within the parent "choice" statement. Note that the "mandatory" and "default" statements within a nested "choice" statement only apply if the "case" containing the nested "choice" statement is first selected. If a list defines any key leafs, then these leafs SHOULD be defined in order, as the first child nodes within the list. The key leafs MAY be in a different order in some cases, e.g., they are defined in a grouping, and not inline in the list statement.
Non-Presence Containers A non-presence container is used to organize data into specific subtrees. It is not intended to have semantics within the data model beyond this purpose, although YANG allows it (e.g., a "must" statement within the non-presence container). Example using container wrappers: Example without container wrappers: Use of non-presence containers to organize data is a subjective matter similar to use of subdirectories in a file system. Although these containers do not have any semantics, they can impact protocol operations for the descendant data nodes within a non-presence container, so use of these containers SHOULD be considered carefully. The NETCONF and RESTCONF protocols do not currently support the ability to delete all list (or leaf-list) entries at once. This deficiency is sometimes avoided by use of a parent container (i.e., deleting the container also removes all child entries).
Top-Level Data Nodes Use of top-level objects needs to be considered carefully:
  • top-level siblings are not ordered
  • top-level siblings are not static and depend on the modules that are loaded
  • for subtree filtering, retrieval of a top-level leaf-list will be treated as a content-match node for all top-level-siblings
  • a top-level list with many instances may impact performance
Operation Definitions If the operation semantics are defined in an external document (other than another YANG module indicated by an import statement), then a reference statement MUST be present. If the operation impacts system behavior in some way, it SHOULD be mentioned in the "description" statement. If the operation is potentially harmful to system behavior in some way, it MUST be mentioned in the Security Considerations section of the document.
Notification Definitions The "description" statement MUST be present. If the notification semantics are defined in an external document (other than another YANG module indicated by an import statement), then a reference statement MUST be present. If the notification refers to a specific resource instance, then this instance SHOULD be identified in the notification data. This is usually done by including "leafref" leaf nodes with the key leaf values for the resource instance. For example: Note that there are no formal YANG statements to identify any data node resources associated with a notification. The "description" statement for the notification SHOULD specify if and how the notification identifies any data node resources associated with the specific event.
Feature Definitions The YANG "feature" statement is used to define a label for a set of optional functionality within a module. The "if-feature" statement is used in the YANG statements associated with a feature. The description-stmt within a feature-stmt MUST specify any interactions with other features. The set of YANG features defined in a module should be considered carefully. Very fine granular features increase interoperability complexity and should be avoided. A likely misuse of the feature mechanism is the tagging of individual leafs (e.g., counters) with separate features. If there is a large set of objects associated with a YANG feature, then consider moving those objects to a separate module, instead of using a YANG feature. Note that the set of features within a module is easily discovered by the reader, but the set of related modules within the entire YANG library is not as easy to identify. Module names with a common prefix can help readers identify the set of related modules, but this assumes the reader will have discovered and installed all the relevant modules. Another consideration for deciding whether to create a new module or add a YANG feature is the stability of the module in question. It may be desirable to have a stable base module that is not changed frequently. If new functionality is placed in a separate module, then the base module does not need to be republished. If it is designed as a YANG feature, then the module will need to be republished. If one feature requires implementation of another feature, then an "if-feature" statement SHOULD be used in the dependent "feature" statement. For example, feature2 requires implementation of feature1:
YANG Data Node Constraints
Controlling Quantity The "min-elements" and "max-elements" statements can be used to control how many list or leaf-list instances are required for a particular data node. YANG constraint statements SHOULD be used to identify conditions that apply to all implementations of the data model. If platform-specific limitations (e.g., the "max-elements" supported for a particular list) are relevant to operations, then a data model definition statement (e.g., "max-ports" leaf) SHOULD be used to identify the limit.
"must" versus "when" "must" and "when" YANG statements are used to provide cross-object referential tests. They have very different behavior. The "when" statement causes data node instances to be silently deleted as soon as the condition becomes false. A false "when" expression is not considered to be an error. The "when" statement SHOULD be used together with "augment" or "uses" statements to achieve conditional model composition. The condition SHOULD be based on static properties of the augmented entry (e.g., list key leafs). The "must" statement causes a datastore validation error if the condition is false. This statement SHOULD be used for enforcing parameter value restrictions that involve more than one data node (e.g., end-time parameter must be after the start-time parameter).
"augment" Statements The YANG "augment" statement is used to define a set of data definition statements that will be added as child nodes of a target data node. The module namespace for these data nodes will be the augmenting module, not the augmented module. A top-level "augment" statement SHOULD NOT be used if the target data node is in the same module or submodule as the evaluated "augment" statement. The data definition statements SHOULD be added inline instead.
Conditional Augment Statements The "augment" statement is often used together with the "when" statement and/or "if-feature" statement to make the augmentation conditional on some portion of the data model. The following example from shows how a conditional container called "ethernet" is added to the "interface" list only for entries of the type "ethernetCsmacd".
Conditionally Mandatory Data Definition Statements YANG has very specific rules about how configuration data can be updated in new releases of a module. These rules allow an "old client" to continue interoperating with a "new server". If data nodes are added to an existing entry, the old client MUST NOT be required to provide any mandatory parameters that were not in the original module definition. It is possible to add conditional "augment" statements such that the old client would not know about the new condition and would not specify the new condition. The conditional "augment" statement can contain mandatory objects only if the condition is false, unless explicitly requested by the client. Only a conditional "augment" statement that uses the "when" statement form of a condition can be used in this manner. The YANG features enabled on the server cannot be controlled by the client in any way, so it is not safe to add mandatory augmenting data nodes based on the "if-feature" statement. The XPath "when" statement condition MUST NOT reference data outside of the target data node because the client does not have any control over this external data. In the following sample, it is okay to augment the "interface" entry with "mandatory-leaf" because the augmentation depends on support for "some-new-iftype". The old client does not know about this type, so it would never select this type; therefore, it would not add a mandatory data node. Note that this practice is safe only for creating data resources. It is not safe for replacing or modifying resources if the client does not know about the new condition. The YANG data model MUST be packaged in a way that requires the client to be aware of the mandatory data nodes if it is aware of the condition for this data. In the example above, the "some-new-iftype" identity is defined in the same module as the "mandatory-leaf" data definition statement. This practice is not safe for identities defined in a common module such as "iana-if-type" because the client is not required to know about "my-module" just because it knows about the "iana-if-type" module.
Deviation Statements Per , the YANG "deviation" statement is not allowed to appear in IETF YANG modules, but it can be useful for documenting server capabilities. Deviation statements are not reusable and typically not shared across all platforms. There are several reasons that deviations might be needed in an implementation, e.g., an object cannot be supported on all platforms, or feature delivery is done in multiple development phases. Deviation statements can also be used to add annotations to a module, which does not affect the conformance requirements for the module. It is suggested that deviation statements be defined in separate modules from regular YANG definitions. This allows the deviations to be platform specific and/or temporary. The order that deviation statements are evaluated can affect the result. Therefore, multiple deviation statements in the same module, for the same target object, SHOULD NOT be used. The "max-elements" statement is intended to describe an architectural limit to the number of list entries. It is not intended to describe platform limitations. It is better to use a "deviation" statement for the platforms that have a hard resource limit. Example documenting platform resource limits:
Extension Statements The YANG "extension" statement is used to specify external definitions. This appears in the YANG syntax as an "unknown-statement". Usage of extension statements in a published module needs to be considered carefully. The following guidelines apply to the usage of YANG extensions:
  • The semantics of the extension MUST NOT contradict any YANG statements. Extensions can add semantics not covered by the normal YANG statements.
  • The module containing the extension statement MUST clearly identify the conformance requirements for the extension. It should be clear whether all implementations of the YANG module containing the extension need to also implement the extension. If not, identify what conditions apply that would require implementation of the extension.
  • The extension MUST clearly identify where it can be used within other YANG statements.
  • The extension MUST clearly identify if YANG statements or other extensions are allowed or required within the extension as substatements.
Data Correlation Data can be correlated in various ways, using common data types, common data naming, and common data organization. There are several ways to extend the functionality of a module, based on the degree of coupling between the old and new functionality:
inline:
update the module with new protocol-accessible objects. The naming and data organization of the original objects is used. The new objects are in the original module namespace.
augment:
create a new module with new protocol-accessible objects that augment the original data structure. The naming and data organization of the original objects is used. The new objects are in the new module namespace.
mirror:
create new objects in a new module or the original module, except use a new naming scheme and data location. The naming can be coupled in different ways. Tight coupling is achieved with a "leafref" data type, with the "require-instance" substatement set to "true". This method SHOULD be used.
If the new data instances are not limited to the values in use in the original data structure, then the "require-instance" substatement MUST be set to "false". Loose coupling is achieved by using key leafs with the same data type as the original data structure. This has the same semantics as setting the "require-instance" substatement to "false". The relationship between configuration and operational state has been clarified in NMDA .
Use of "leafref" for Key Correlation Sometimes it is not practical to augment a data structure. For example, the correlated data could have different keys or contain mandatory nodes. The following example shows the use of the "leafref" data type for data correlation purposes: Not preferred: Preferred:
Operational State The modeling of operational state with YANG has been refined over time. At first, only data that has a "config" statement value of "false" was considered to be operational state. This data was not considered to be part of any datastore, which made the YANG XPath definition much more complicated. Operational state is now modeled using YANG according to the NMDA and conceptually contained in the operational state datastore, which also includes the operational values of configuration data. There is no longer any need to duplicate data structures to provide separate configuration and operational state sections. This section describes some data modeling issues related to operational state and guidelines for transitioning YANG data model design to be NMDA compatible.
Combining Operational State and Configuration Data If possible, operational state SHOULD be combined with its associated configuration data. This prevents duplication of key leafs and ancestor nodes. It also prevents race conditions for retrieval of dynamic entries and allows configuration and operational state to be retrieved together with minimal message overhead.
Representing Operational Values of Configuration Data If possible, the same data type SHOULD be used to represent the configured value and the operational value, for a given leaf or leaf- list object. Sometimes the configured value set is different than the operational value set for that object, for example, the "admin-status" and "oper-status" leafs in . In this case, a separate object MAY be used to represent the configured and operational values. Sometimes the list keys are not identical for configuration data and the corresponding operational state. In this case, separate lists MAY be used to represent the configured and operational values. If it is not possible to combine configuration and operational state, then the keys used to represent list entries SHOULD be the same type. The "leafref" data type SHOULD be used in operational state for key leafs that have corresponding configuration instances. The "require-instance" statement MAY be set to "false" (in YANG 1.1 modules only) to indicate instances are allowed in the operational state that do not exist in the associated configuration data. The need to replicate objects or define different operational state objects depends on the data model. It is not possible to define one approach that will be optimal for all data models. Designers SHOULD describe and justify any NMDA exceptions in detail, such as the use of separate subtrees and/or separate leafs. The "description" statements for both the configuration and the operational state SHOULD be used for this purpose.
NMDA Transition Guidelines YANG modules SHOULD be designed with the assumption that they will be used on servers supporting the operational state datastore. With this in mind, YANG modules SHOULD define "config false" nodes wherever they make sense to the data model. "Config false" nodes SHOULD NOT be defined to provide the operational value for configuration nodes, except when the value space of a configured and operational value may differ, in which case a distinct "config false" node SHOULD be defined to hold the operational value for the configured node. The following guidelines are meant to help modelers develop YANG modules that will maximize the utility of the model with both current and new implementations. New modules and modules that are not concerned with the operational state of configuration information SHOULD immediately be structured to be NMDA compatible, as described in Section 4.23.1. This transition MAY be deferred if the module does not contain any configuration datastore objects. The remaining are options that MAY be followed during the time that NMDA mechanisms are being defined.
  1. Modules that require immediate support for the NMDA features SHOULD be structured for NMDA. A temporary non-NMDA version of this type of module MAY exist, as either an existing model or a model created by hand or with suitable tools that mirror the current modeling strategies. Both the NMDA and the non-NMDA modules SHOULD be published in the same document, with NMDA modules in the document main body and the non-NMDA modules in a non-normative appendix. The use of the non-NMDA module will allow temporary bridging of the time period until NMDA implementations are available.
  2. For published models, the model should be republished with an NMDA-compatible structure, deprecating non-NMDA constructs. For example, the "ietf-interfaces" model in has been restructured as an NMDA-compatible model in . The "/interfaces-state" hierarchy has been marked "status deprecated". Models that mark their "/foo-state" hierarchy with "status deprecated" will allow NMDA-capable implementations to avoid the cost of duplicating the state nodes, while enabling non-NMDA-capable implementations to utilize them for access to the operational values.
  3. For models that augment models that have not been structured with the NMDA, the modeler will have to consider the structure of the base model and the guidelines listed above. Where possible, such models should move to new revisions of the base model that are NMDA compatible. When that is not possible, augmenting "state" containers SHOULD be avoided, with the expectation that the base model will be re-released with the state containers marked as deprecated. It is RECOMMENDED to augment only the "/foo" hierarchy of the base model. Where this recommendation cannot be followed, then any new "state" elements SHOULD be included in their own module.
Temporary Non-NMDA Modules A temporary non-NMDA module allows a non-NMDA-aware client to access operational state from an NMDA-compliant server. It contains the top-level "config false" data nodes that would have been defined in a legacy YANG module (before NMDA). A server that needs to support both NMDA and non-NMDA clients can advertise both the new NMDA module and the temporary non-NMDA module. A non-NMDA client can use separate "foo" and "foo-state" subtrees, except the "foo-state" subtree is located in a different (temporary) module. The NMDA module can be used by a non-NMDA client to access the conventional configuration datastores and the deprecated <get> operation to access nested "config false" data nodes. To create the temporary non-NMDA model from an NMDA model, the following steps can be taken:
  • Change the module name by appending "-state" to the original module name
  • Change the namespace by appending "-state" to the original namespace value
  • Change the prefix by appending "-s" to the original prefix value
  • Add an import to the original module (e.g., for typedef definitions)
  • Retain or create only the top-level nodes that have a "config" statement value "false". These subtrees represent "config false" data nodes that were combined into the configuration subtree; therefore, they are not available to non-NMDA aware clients. Set the "status" statement to "deprecated" for each new node.
  • The module description SHOULD clearly identify the module as a temporary non-NMDA module
Example: Create a New NMDA Module Create an NMDA-compliant module, using combined configuration and state subtrees, whenever possible.
Example: Convert an Old Non-NMDA Module Do not remove non-compliant objects from existing modules. Instead, change the status to "deprecated". At some point, usually after 1 year, the status MAY be changed to "obsolete". Old Module:
Example: Create a Temporary NMDA Module Create a new module that contains the top-level operational state data nodes that would have been available before they were combined with configuration data nodes (to be NMDA compliant).
Performance Considerations It is generally likely that certain YANG statements require more runtime resources than other statements. Although there are no performance requirements for YANG validation, the following information MAY be considered when designing YANG data models:
  • Lists are generally more expensive than containers
  • "when" statement evaluation is generally more expensive than "if-feature" or "choice" statements
  • "must" statements are generally more expensive than "min-elements", "max-elements", "mandatory", or "unique" statements
  • "identityref" leafs are generally more expensive than "enumeration" leafs
  • "leafref" and "instance-identifier" types with "require-instance" set to "true" are generally more expensive than if "require-instance" is set to "false"
Open Systems Considerations Only the modules imported by a particular module can be assumed to be present in an implementation. An open system MAY include any combination of YANG modules.
Guidelines for Constructs Specific to YANG 1.1 The set of guidelines for YANG 1.1 will grow as operational experience is gained with the new language features. This section contains an initial set of guidelines for new YANG 1.1 language features.
Importing Multiple Revisions Standard modules SHOULD NOT import multiple revisions of the same module into a module. This MAY be done if independent definitions (e.g., enumeration typedefs) from specific revisions are needed in the importing module.
Using Feature Logic The YANG 1.1 feature logic is much more expressive than YANG 1.0. A "description" statement SHOULD describe the "if-feature" logic in text, to help readers understand the module. YANG features SHOULD be used instead of the "when" statement, if possible. Features are advertised by the server, and objects conditional by the "if-feature" statement are conceptually grouped together. There is no such commonality supported for "when" statements. Features generally require less server implementation complexity and runtime resources than objects that use "when" statements. Features are generally static (i.e., set when a module is loaded and not changed at runtime). However, every client edit might cause a "when" statement result to change.
"anyxml" versus "anydata" The "anyxml" statement MUST NOT be used to represent a conceptual subtree of YANG data nodes. The "anydata" statement MUST be used for this purpose.
"action" versus "rpc" The use of "action" statements or "rpc" statements is a subjective design decision. RPC operations are not associated with any particular data node. Actions are associated with a specific data node definition. An "action" statement SHOULD be used if the protocol operation is specific to a subset of all data nodes instead of all possible data nodes. The same action name MAY be used in different definitions within different data node. For example, a "reset" action defined with a data node definition for an interface might have different parameters than for a power supply or a VLAN. The same action name SHOULD be used to represent similar semantics. The NETCONF Access Control Model (NACM) does not support parameter-based access control for RPC operations. The user is given permission (or not) to invoke the RPC operation with any parameters. For example, if each client is only allowed to reset their own interface, then NACM cannot be used. For example, NACM cannot enforce access control based on the value of the "interface" parameter, only the "reset" operation itself: However, NACM can enforce access control for individual interface instances, using a "reset" action. If the user does not have read access to the specific "interface" instance, then it cannot invoke the "reset" action for that interface instance:
Updating YANG Modules (Published versus Unpublished) YANG modules can change over time. Typically, new data model definitions are needed to support new features. YANG update rules defined in MUST be followed for published modules. They MAY be followed for unpublished modules. The YANG update rules only apply to published module revisions. Each organization will have their own way to identify published work that is considered to be stable and unpublished work that is considered to be unstable. For example, in the IETF, the RFC document is used for published work, and the I-D is used for unpublished work.
Defining Standard Tags specifies a method for associating tags with YANG modules. Tags may be defined and associated at module design time, at implementation time, or via user administrative control. Design-time tags are indicated using the module-tag extension statement. A module MAY indicate, using module-tag extension statements, a set of tags that are to be automatically associated with it (i.e., not added through configuration). Authors can use existing standard tags or use new tags defined in the model definition, as appropriate. For IETF modules, new tags MUST be assigned in the IANA "IETF YANG Module Tags" registry within the "YANG Module Tags" registry .
Modeling Abstract Data Structures For contexts where YANG is used to model abstract data structures (e.g., protocol messages), the use of the "structure" extension statement is RECOMMENDED compared to the "yang-data" extension statement .
  • Examples of modules that rely upon the "structure" extension statement are or .
Abstract data structures can be augmented using the "augment-structure" statement .
  • Examples of modules that augment abstract data structures are and .
IANA-Maintained Modules
Context IANA maintains a set of registries that are key for interoperability. The content of these registries are usually available using various formats (e.g., plain text, XML). However, there were some confusion in the past about whether the content of some registries is dependent on a specific representation format. For example, Section 5 of was published to clarify that MIB and YANG modules are merely additional formats in which the "Interface Types (ifType)" and "Tunnel Types (tunnelType)" registries are available. The MIB and YANG modules are not separate registries, and the same values are always present in all formats of the same registry. Also, some YANG modules include parameters and values directly in a module that is not maintained by IANA while these are populated in an IANA registry. Such a design is suboptimal as it creates another source of information that may deviate from the IANA registry as new values are assigned or some values are deprecated. For the sake of consistency and ability to support new values while maintaining IANA registries as the unique authoritative source of information, this document encourages the use of IANA-maintained modules as the single source of information. The following section provides a set of guidelines for YANG module authors related to the design of IANA-maintained modules. These guidelines are meant to leverage existing IANA registries and use YANG as another format to present the content of these registries when appropriate.
Guidelines for IANA-Maintained Modules When designing a YANG module for a functionality governed by a protocol for which IANA maintains a registry, it is RECOMMENDED to specify an IANA-maintained module that echoes the content of that registry. This is superior to including that content in an IETF-maintained module. When one or multiple registries are available under the same registry group, it is RECOMMENDED to define an IANA-maintained module for each registry. However, module designers MAY consider defining one single IANA-maintained module that covers all registries if maintaining that single module is manageable (e.g., very few values are present or expected to be present for each registry). An example of such a module is documented in . An IANA-maintained module may use the "identityref" data type (e.g., ) or an enumeration data type (e.g., ). See for a guidance on which data type to use. The decision about which type to use should be made based upon specifics related to the intended use of the IANA-maintained module. For example, identities are useful if the registry entries are organized hierarchically, possibly including multiple inheritances. It is RECOMMENDED that the reasoning for the design choice is documented in the companion specification that registers an IANA-maintained module. For example, defines an IANA-maintained module that uses enumerations for the following reason:
The DOTS telemetry module (Section 11.1) uses "enumerations" rather than "identities" to define units, samples, and intervals because otherwise the namespace identifier "ietf-dots-telemetry" must be included when a telemetry attribute is included (e.g., in a mitigation efficacy update). The use of "identities" is thus suboptimal from the standpoint of message compactness, as message compactness is one of the key requirements for DOTS signal channel messages.
Designers of IANA-maintained modules MAY supply the full initial version of the module in a specification document that registers the module or only a script to be used (including by IANA) for generating the module (e.g., an XSLT stylesheet as in Appendix A of or a Python script as in ). For both cases, the document that defines an IANA-maintained module MUST include a note indicating that the document is only documenting the initial version of the module and that the authoritative version is to be retrieved from the IANA registry. Also, the IANA-maintained module MUST include the following note indicating the RFC that registered the initial version of the IANA-maintained module:
  • The initial version of this YANG module is part of RFC IIII; see the RFC itself for full legal notices.
It is RECOMMENDED to include the URL from where to retrieve the recent version of the module. When a script is used, the Internet-Draft that defines an IANA-maintained module have to include an appendix with the full script and SHOULD include an appendix with the initial full version of the module. Including such an appendix in pre-RFC versions is meant to assess the correctness of the outcome of the supplied script. The authors MUST include a note to the RFC Editor requesting that the appendix with the initial version of the module be removed before publication as RFC and that RFC IIII is replaced with the RFC number that is assigned to the document. Initial versions of IANA-maintained modules that are published in RFCs may be misused despite the appropriate language to refer to the IANA registry to retrieve the up-to-date module. This is problematic for interoperability, e.g., when values are deprecated or are associated with a new meaning. If an IANA-maintained module is imported by another module, a normative reference with the IANA URL from where to retrieve the IANA-maintained module SHOULD be included. Although not encouraged, referencing the RFC that defines the initial version of the IANA module is acceptable in specific cases (e.g., the imported version is specifically the initial version, the RFC includes useful description about the usage of the module). Examples of IANA URLs from where to retrieve the latest version of an IANA-maintained module are: , , and . "IANA_FOO_URL" is used in the following to refer to such URLs. These URLs are expected to be sufficiently permanent and stable. Whenever referencing a specific version of an IANA-maintained module is needed, then URLs such as are used. "IANA_FOO_URL_With_REV" is used in the following to refer to such URLs. A template for IANA-maintained modules is provided in .
Guidance for Writing the IANA Considerations for RFCs Defining IANA-Maintained Modules In addition to the IANA considerations in , the IANA Considerations Section of an RFC that includes an IANA-maintained module MUST provide the required instructions for IANA to automatically perform the maintenance of that IANA module. These instructions describe how to proceed with updates to the IANA-maintained module that are triggered by a change to the authoritative registry. Concretely, the IANA Considerations Section SHALL at least provide the following information:
  • A request to IANA to add a note to the page displaying the information about the IANA-maintained module that new values must not be directly added to the module. These values should be added to an authoritative IANA registry.
  • A request to IANA to add a note to the authoritative IANA registry to indicate that any change to the registry must be reflected into the corresponding IANA-maintained module. That is, any changes to the registry must be accompanied by an update to the corresponding IANA-maintained module.
  • Details about the required actions (e.g., add a new "identity" or "enum" statement) to update the IANA-maintained module to reflect changes to an authoritative IANA registry. Typically, these details have to include the procedure to create a new "identity" statement name and substatements ("base", "status", "description", and "reference") or a new "enum" statement and sub-statements ("value", "status", "description", and "reference").
    • When creating a new "identity" statement name or a new "enum" statement, it is RECOMMENDED to mirror the name (if present) as recorded in the IANA registry.
    • If the name in the IANA registry does not comply with the naming conventions listed in , the procedure MUST detail how IANA can generate legal identifiers from such a name. Specifically, if the name begins with a number, it is RECOMMENDED to spell out the number when used as an identifier. IANA should be provided with instructions to perform such task. For example, authors of a module with such identifiers have to indicate whether:
      • "3des-cbc" should be "three-des-cbc" or rather "triple-des-cbc" to be consistent with .
      • "6to4" should be "sixToFour" as in or "sixtofour" as in .
    • If a new registration uses an identifier that does not comply with the naming conventions listed in , IANA should check if a guidance to generate legal identifiers was supplied in the RFC that specified the initial version of the module. If no such guidance is available, IANA should check the latest revision of the IANA-maintained module for similar patterns. If all else failed, IANA should seek advice from relevant registry experts (e.g., designated experts for a registry with Expert Review policy () or responsible Area Director).
  • A note that unassigned or reserved values must not be present in the IANA-maintained module.
  • An instruction whether experimental values should be included in the IANA-maintained module. If no instruction is provided, experimental values MUST NOT be listed in the IANA-maintained module.
  • An instruction about how to generate the "revision" statement.
A template for the IANA Considerations is provided in for IANA-maintained modules with identities and for IANA-maintained modules with enumerations. Authors may modify the template to reflect specifics of their modules (e.g., multiple registries can be listed for a single IANA-maintained module, no explicit description (or name) field is listed under the authoritative IANA registry, or the name does not comply with YANG naming conventions ()). An example of "revision" statements that are generated following the guidance in is provided below: Duplicating the same reference at the high level and at the level of a new addition might be redundant. For example, the following does not provide access to a specific (OLD) revision of the module when future revisions are made : The following example shows how to generate the "revision" statements following the guidance in : The following templates are to be considered in addition to the required information that is provided in .
Template for IANA-Maintained Modules with Identities ". The "reference" substatement points specifically to the published module (i.e., IANA_FOO_URL_With_REV). It may also point to an authoritative event triggering the update to the YANG module. In all cases, this event is cited from the underlying IANA registry. If the update is triggered by an RFC, that RFC must also be included in the "reference" substatement. -- If a name in the IANA registry does not comply with the -- YANG naming conventions, add details how IANA can generate -- legal identifiers. For example, if the name begins with -- a number, indicate a preference to spell out the number when -- used as an identifier. IANA is requested to add this note to [reference-to-the-iana-foo- registry]: When this registry is modified, the YANG module "iana-foo" [IANA_FOO_URL] must be updated as defined in RFC IIII. ]]>
Template for IANA-Maintained Modules with Enumerations ". The "reference" substatement points specifically to the published module (i.e., IANA_FOO_URL_With_REV). It may also point to an authoritative event triggering the update to the YANG module. In all cases, this event is cited from the underlying IANA registry. If the update is triggered by an RFC, that RFC must also be included in the "reference" substatement. -- If a name in the IANA registry does not comply with the -- YANG naming conventions, add details how IANA can generate -- legal identifiers. For example, if the name begins with -- a number, indicate a preference to spell out the number when -- used as an identifier. IANA is requested to add this note to [reference-to-the-iana-foo- registry]: When this registry is modified, the YANG module "iana-foo" [IANA_FOO_URL] must be updated as defined in RFC IIII. ]]>
IANA Considerations
YANG Modules The following registration in the "ns" registry of the "IETF XML Registry" was detailed in . This document requests IANA to update this registration to reference this document. IANA is requested to register the following URI in the "ns" registry within the "IETF XML Registry" group : This document requests IANA to register the following YANG modules in the "YANG Module Names" registry within the "YANG Parameters" registry group.
Update YANG Parameters Registry Also, this document requests IANA to update the RFC8407 reference for the "YANG Module Names" registry under the "YANG Parameters" registry group to point to the RFC number that will be assigned to this document as it contains the template necessary for registration in Appendix B.
IANA-Maintained Modules IANA should refer to for information necessary to populate "revision" statements and "identity" and "enum" substatements in IANA-maintained modules. These considerations cover both the creation and maintenance of an IANA-mainatined module. In particular, the following should be noted:
  • When an underlying registration is deprecated or obsoleted, a corresponding "status" substatement should be added to the identity or enumeration statement.
  • The "reference" substatement should point specifically to the published module (i.e., IANA_FOO_URL_With_REV). When the registration is triggered by an RFC, that RFC must also be included in the "reference" substatement. It may also point to an authoritative event triggering the update to the YANG module. In all cases, the event is cited from the underlying IANA registry.
In addition, when the module is published, IANA must add the following notes to:
The YANG Module Names registry:
New values must not be directly added to the "iana-foo" YANG module. They must instead be added to the "foo" registry.
The underlying registry:
When this registry is modified, the YANG module "iana-foo" [IANA_FOO_URL] must be updated as defined in RFC IIII.
Operations and Manageability Considerations Although the document focuses on YANG data modeling language guidance, the document does not define a protocol or a protocol extension. As such, there are no new operations or manageability requirements introduced by this document.
Security Considerations This document defines guidelines for NETCONF or RESTCONF content defined with the YANG data modeling language. It does not introduce any new or increased security risks.
References Normative References XML Path Language (XPath) Version 1.0 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] RESTCONF Protocol This document describes an HTTP-based protocol that provides a programmatic interface for accessing data defined in YANG, using the datastore concepts defined in the Network Configuration Protocol (NETCONF). The YANG 1.1 Data Modeling Language 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). YANG - A Data Modeling Language for the Network Configuration Protocol (NETCONF) YANG is a data modeling language used to model configuration and state data manipulated by the Network Configuration Protocol (NETCONF), NETCONF remote procedure calls, and NETCONF notifications. [STANDARDS-TRACK] YANG Data Structure Extensions This document describes YANG mechanisms for defining abstract data structures with YANG. Guidelines for Writing an IANA Considerations Section in RFCs Many protocols make use of points of extensibility that use constants to identify various protocol parameters. To ensure that the values in these fields do not have conflicting uses and to promote interoperability, their allocations are often coordinated by a central record keeper. For IETF protocols, that role is filled by the Internet Assigned Numbers Authority (IANA). To make assignments in a given registry prudently, guidance describing the conditions under which new values should be assigned, as well as when and how modifications to existing values can be made, is needed. This document defines a framework for the documentation of these guidelines by specification authors, in order to assure that the provided guidance for the IANA Considerations is clear and addresses the various issues that are likely in the operation of a registry. This is the third edition of this document; it obsoletes RFC 5226. Defining and Using Metadata with YANG This document defines a YANG extension that allows for defining metadata annotations in YANG modules. The document also specifies XML and JSON encoding of annotations and other rules for annotating instances of YANG data nodes. Handling Long Lines in Content of Internet-Drafts and RFCs This document defines two strategies for handling long lines in width-bounded text content. One strategy, called the "single backslash" strategy, is based on the historical use of a single backslash ('\') character to indicate where line-folding has occurred, with the continuation occurring with the first character that is not a space character (' ') on the next line. The second strategy, called the "double backslash" strategy, extends the first strategy by adding a second backslash character to identify where the continuation begins and is thereby able to handle cases not supported by the first strategy. Both strategies use a self-describing header enabling automated reconstitution of the original content. YANG Module Tags This document provides for the association of tags with YANG modules. The expectation is for such tags to be used to help classify and organize modules. A method for defining, reading, and writing modules tags is provided. Tags may be registered and assigned during module definition, assigned by implementations, or dynamically defined and set by users. This document also provides guidance to future model writers; as such, this document updates RFC 8407. Network Management Datastore Architecture (NMDA) 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. Key words for use in RFCs to Indicate Requirement Levels 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. Ambiguity of Uppercase vs Lowercase in RFC 2119 Key Words 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. Network Configuration Access Control Model The standardization of network configuration interfaces for use with the Network Configuration Protocol (NETCONF) or the RESTCONF protocol requires a structured and secure operating environment that promotes human usability and multi-vendor interoperability. There is a need for standard mechanisms to restrict NETCONF or RESTCONF protocol access for particular users to a preconfigured subset of all available NETCONF or RESTCONF protocol operations and content. This document defines such an access control model. This document obsoletes RFC 6536. The IETF XML Registry This document describes an IANA maintained registry for IETF standards which use Extensible Markup Language (XML) related items such as Namespaces, Document Type Declarations (DTDs), Schemas, and Resource Description Framework (RDF) Schemas. Uniform Resource Identifier (URI): Generic Syntax A Uniform Resource Identifier (URI) is a compact sequence of characters that identifies an abstract or physical resource. This specification defines the generic URI syntax and a process for resolving URI references that might be in relative form, along with guidelines and security considerations for the use of URIs on the Internet. The URI syntax defines a grammar that is a superset of all valid URIs, allowing an implementation to parse the common components of a URI reference without knowing the scheme-specific requirements of every possible identifier. This specification does not define a generative grammar for URIs; that task is performed by the individual specifications of each URI scheme. [STANDARDS-TRACK] Rights Contributors Provide to the IETF Trust The IETF policies about rights in Contributions to the IETF are designed to ensure that such Contributions can be made available to the IETF and Internet communities while permitting the authors to retain as many rights as possible. This memo details the IETF policies on rights in Contributions to the IETF. It also describes the objectives that the policies are designed to meet. This memo obsoletes RFCs 3978 and 4748 and, with BCP 79 and RFC 5377, replaces Section 10 of RFC 2026. This document specifies an Internet Best Current Practices for the Internet Community, and requests discussion and suggestions for improvements. Informative References YANG Module Names IANA IETF XML Registry IANA Style Guide RFC Editor iana-bfd-types YANG Module IANA iana-bgp-l2-encaps YANG Module IANA iana-bfd-types@2021-10-21.yang IANA iana-pseudowire-types YANG Module IANA IANA YANG n.d. YANG Parameters n.d. YANG Module Tags IANA iana-tunnel-type YANG Module IANA Guidelines to Authors of Internet-Drafts IETF n.d. Guidelines for Authors and Reviewers of Documents Containing YANG Data Models This memo provides guidelines for authors and reviewers of specifications containing YANG modules. Recommendations and procedures are defined, which are intended to increase interoperability and usability of Network Configuration Protocol (NETCONF) and RESTCONF protocol implementations that utilize YANG modules. This document obsoletes RFC 6087. A YANG Data Model for Tunnel Interface Types This document specifies the initial version of a YANG module "iana-tunnel-type", which contains a collection of IANA-maintained YANG identities used as interface types for tunnel interfaces. The module reflects the "tunnelType" registry maintained by IANA. The latest revision of this YANG module can be obtained from the IANA website. Tunnel type values are not directly added to the Tunnel Interface Types YANG module; they must instead be added to the "tunnelType" IANA registry. Once a new tunnel type registration is made by IANA for a new tunneling scheme or even an existing one that is not already listed in the current registry (e.g., LISP, NSH), IANA will update the Tunnel Interface Types YANG module accordingly. Some of the IETF-defined tunneling techniques are not listed in the current IANA registry. It is not the intent of this document to update the existing IANA registry with a comprehensive list of tunnel technologies. Registrants must follow the IETF registration procedure for interface types whenever a new tunnel type is needed. A YANG Network Data Model for Layer 2 VPNs This document defines an L2VPN Network Model (L2NM) that can be used to manage the provisioning of Layer 2 Virtual Private Network (L2VPN) services within a network (e.g., a service provider network). The L2NM complements the L2VPN Service Model (L2SM) by providing a network-centric view of the service that is internal to a service provider. The L2NM is particularly meant to be used by a network controller to derive the configuration information that will be sent to relevant network devices. Also, this document defines a YANG module to manage Ethernet segments and the initial versions of two IANA-maintained modules that include a set of identities of BGP Layer 2 encapsulation types and pseudowire types. The Internet Standards Process -- Revision 3 This memo documents the process used by the Internet community for the standardization of protocols and procedures. It defines the stages in the standardization process, the requirements for moving a document between stages and the types of documents used during this process. This document specifies an Internet Best Current Practices for the Internet Community, and requests discussion and suggestions for improvements. YANG Tree Diagrams 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. Service Models Explained The IETF has produced many modules in the YANG modeling language. The majority of these modules are used to construct data models to model devices or monolithic functions. A small number of YANG modules have been defined to model services (for example, the Layer 3 Virtual Private Network Service Model (L3SM) produced by the L3SM working group and documented in RFC 8049). This document describes service models as used within the IETF and also shows where a service model might fit into a software-defined networking architecture. Note that service models do not make any assumption of how a service is actually engineered and delivered for a customer; details of how network protocols and devices are engineered to deliver a service are captured in other modules that are not exposed through the interface between the customer and the provider. YANG Data Model for the OSPF Protocol This document defines a YANG data model that can be used to configure and manage OSPF. The model is based on YANG 1.1 as defined in RFC 7950 and conforms to the Network Management Datastore Architecture (NMDA) as described in RFC 8342. A YANG Data Model for SNMP Configuration This document defines a collection of YANG definitions for configuring SNMP engines. A YANG Data Model for Routing Management (NMDA Version) This document specifies three YANG modules and one submodule. Together, they form the core routing data model that serves as a framework for configuring and managing a routing subsystem. It is expected that these modules will be augmented by additional YANG modules defining data models for control-plane protocols, route filters, and other functions. The core routing data model provides common building blocks for such extensions -- routes, Routing Information Bases (RIBs), and control-plane protocols. The YANG modules in this document conform to the Network Management Datastore Architecture (NMDA). This document obsoletes RFC 8022. Common YANG Data Types This document introduces a collection of common data types to be used with the YANG data modeling language. This document obsoletes RFC 6021. A Framework for Automating Service and Network Management with YANG Data models provide a programmatic approach to represent services and networks. Concretely, they can be used to derive configuration information for network and service components, and state information that will be monitored and tracked. Data models can be used during the service and network management life cycle (e.g., service instantiation, service provisioning, service optimization, service monitoring, service diagnosing, and service assurance). Data models are also instrumental in the automation of network management, and they can provide closed-loop control for adaptive and deterministic service creation, delivery, and maintenance. This document describes a framework for service and network management automation that takes advantage of YANG modeling technologies. This framework is drawn from a network operator perspective irrespective of the origin of a data model; thus, it can accommodate YANG modules that are developed outside the IETF. YANG Data Model for L3VPN Service Delivery This document defines a YANG data model that can be used for communication between customers and network operators and to deliver a Layer 3 provider-provisioned VPN service. This document is limited to BGP PE-based VPNs as described in RFCs 4026, 4110, and 4364. This model is intended to be instantiated at the management system to deliver the overall service. It is not a configuration model to be used directly on network elements. This model provides an abstracted view of the Layer 3 IP VPN service configuration components. It will be up to the management system to take this model as input and use specific configuration models to configure the different network elements to deliver the service. How the configuration of network elements is done is out of scope for this document. This document obsoletes RFC 8049; it replaces the unimplementable module in that RFC with a new module with the same name that is not backward compatible. The changes are a series of small fixes to the YANG module and some clarifications to the text. A YANG Data Model for Layer 2 Virtual Private Network (L2VPN) Service Delivery This document defines a YANG data model that can be used to configure a Layer 2 provider-provisioned VPN service. It is up to a management system to take this as an input and generate specific configuration models to configure the different network elements to deliver the service. How this configuration of network elements is done is out of scope for this document. The YANG data model defined in this document includes support for point-to-point Virtual Private Wire Services (VPWSs) and multipoint Virtual Private LAN Services (VPLSs) that use Pseudowires signaled using the Label Distribution Protocol (LDP) and the Border Gateway Protocol (BGP) as described in RFCs 4761 and 6624. The YANG data model defined in this document conforms to the Network Management Datastore Architecture defined in RFC 8342. A YANG Network Data Model for Layer 3 VPNs As a complement to the Layer 3 Virtual Private Network Service Model (L3SM), which is used for communication between customers and service providers, this document defines an L3VPN Network Model (L3NM) that can be used for the provisioning of Layer 3 Virtual Private Network (L3VPN) services within a service provider network. The model provides a network-centric view of L3VPN services. The L3NM is meant to be used by a network controller to derive the configuration information that will be sent to relevant network devices. The model can also facilitate communication between a service orchestrator and a network controller/orchestrator. YANG Module Classification The YANG data modeling language is currently being considered for a wide variety of applications throughout the networking industry at large. Many standards development organizations (SDOs), open-source software projects, vendors, and users are using YANG to develop and publish YANG modules for a wide variety of applications. At the same time, there is currently no well-known terminology to categorize various types of YANG modules. A consistent terminology would help with the categorization of YANG modules, assist in the analysis of the YANG data modeling efforts in the IETF and other organizations, and bring clarity to the YANG- related discussions between the different groups. This document describes a set of concepts and associated terms to support consistent classification of YANG modules. YANG Data Model for Network Access Control Lists (ACLs) This document defines a data model for Access Control Lists (ACLs). An ACL is a user-ordered set of rules used to configure the forwarding behavior in a device. Each rule is used to find a match on a packet and define actions that will be performed on the packet. The Secure Shell (SSH) Authentication Protocol The Secure Shell Protocol (SSH) is a protocol for secure remote login and other secure network services over an insecure network. This document describes the SSH authentication protocol framework and public key, password, and host-based client authentication methods. Additional authentication methods are described in separate documents. The SSH authentication protocol runs on top of the SSH transport layer protocol and provides a single authenticated tunnel for the SSH connection protocol. [STANDARDS-TRACK] The Transport Layer Security (TLS) Protocol Version 1.3 This document specifies version 1.3 of the Transport Layer Security (TLS) protocol. TLS allows client/server applications to communicate over the Internet in a way that is designed to prevent eavesdropping, tampering, and message forgery. This document updates RFCs 5705 and 6066, and obsoletes RFCs 5077, 5246, and 6961. This document also specifies new requirements for TLS 1.2 implementations. QUIC: A UDP-Based Multiplexed and Secure Transport This document defines the core of the QUIC transport protocol. QUIC provides applications with flow-controlled streams for structured communication, low-latency connection establishment, and network path migration. QUIC includes security measures that ensure confidentiality, integrity, and availability in a range of deployment circumstances. Accompanying documents describe the integration of TLS for key negotiation, loss detection, and an exemplary congestion control algorithm. JSON Encoding of Data Modeled with YANG This document defines encoding rules for representing configuration data, state data, parameters of Remote Procedure Call (RPC) operations or actions, and notifications defined using YANG as JavaScript Object Notation (JSON) text. IPv4 Address Blocks Reserved for Documentation Three IPv4 unicast address blocks are reserved for use in examples in specifications and other documents. This document describes the use of these blocks. This document is not an Internet Standards Track specification; it is published for informational purposes. IPv6 Address Prefix Reserved for Documentation To reduce the likelihood of conflict and confusion when relating documented examples to deployed systems, an IPv6 unicast address prefix is reserved for use in examples in RFCs, books, documentation, and the like. Since site-local and link-local unicast addresses have special meaning in IPv6, these addresses cannot be used in many example situations. The document describes the use of the IPv6 address prefix 2001:DB8::/32 as a reserved prefix for use in documentation. This memo provides information for the Internet community. Expanding the IPv6 Documentation Space The document describes the reservation of an additional IPv6 address prefix for use in documentation. This update to RFC 3849 expands on the existing 2001:db8::/32 address block with the reservation of an additional, larger prefix. The addition of a /20 prefix allows documented examples to more closely reflect a broader range of realistic, current deployment scenarios and more closely aligns with contemporary allocation models for large networks. Enterprise Number for Documentation Use This document describes an Enterprise Number (also known as SMI Network Management Private Enterprise Code) for use in documentation. This memo provides information for the Internet community. Autonomous System (AS) Number Reservation for Documentation Use To reduce the likelihood of conflict and confusion when relating documented examples to deployed systems, two blocks of Autonomous System numbers (ASNs) are reserved for use in examples in RFCs, books, documentation, and the like. This document describes the reservation of two blocks of ASNs as reserved numbers for use in documentation. This memo provides information for the Internet community. Reserved Top Level DNS Names To reduce the likelihood of conflict and confusion, a few top level domain names are reserved for use in private testing, as examples in documentation, and the like. In addition, a few second level domain names reserved for use as examples are documented. This document specifies an Internet Best Current Practices for the Internet Community, and requests discussion and suggestions for improvements. The 'tag' URI Scheme This document describes the "tag" Uniform Resource Identifier (URI) scheme. Tag URIs (also known as "tags") are designed to be unique across space and time while being tractable to humans. They are distinct from most other URIs in that they have no authoritative resolution mechanism. A tag may be used purely as an entity identifier. Furthermore, using tags has some advantages over the common practice of using "http" URIs as identifiers for non-HTTP-accessible resources. This memo provides information for the Internet community. A YANG Data Model for Interface Management This document defines a YANG data model for the management of network interfaces. It is expected that interface-type-specific data models augment the generic interfaces data model defined in this document. The data model includes definitions for configuration and system state (status information and counters for the collection of statistics). The YANG data model in this document conforms to the Network Management Datastore Architecture (NMDA) defined in RFC 8342. This document obsoletes RFC 7223. A YANG Data Model for Interface Management This document defines a YANG data model for the management of network interfaces. It is expected that interface-type-specific data models augment the generic interfaces data model defined in this document. The data model includes configuration data and state data (status information and counters for the collection of statistics). Distributed Denial-of-Service Open Threat Signaling (DOTS) Signal Channel Specification This document specifies the Distributed Denial-of-Service Open Threat Signaling (DOTS) signal channel, a protocol for signaling the need for protection against Distributed Denial-of-Service (DDoS) attacks to a server capable of enabling network traffic mitigation on behalf of the requesting client. A companion document defines the DOTS data channel, a separate reliable communication layer for DOTS management and configuration purposes. This document obsoletes RFC 8782. A File Format for YANG Instance Data There is a need to document data defined in YANG models at design time, implementation time, or when a live server is unavailable. This document specifies a standard file format for YANG instance data, which follows the syntax and semantics of existing YANG models and annotates it with metadata. Distributed Denial-of-Service Open Threat Signaling (DOTS) Telemetry This document aims to enrich the Distributed Denial-of-Service Open Threat Signaling (DOTS) signal channel protocol with various telemetry attributes, allowing for optimal Distributed Denial-of-Service (DDoS) attack mitigation. It specifies the normal traffic baseline and attack traffic telemetry attributes a DOTS client can convey to its DOTS server in the mitigation request, the mitigation status telemetry attributes a DOTS server can communicate to a DOTS client, and the mitigation efficacy telemetry attributes a DOTS client can communicate to a DOTS server. The telemetry attributes can assist the mitigator in choosing the DDoS mitigation techniques and performing optimal DDoS attack mitigation. This document specifies two YANG modules: one for representing DOTS telemetry message types and one for sharing the attack mapping details over the DOTS data channel. Distributed Denial-of-Service Open Threat Signaling (DOTS) Signal Channel Configuration Attributes for Robust Block Transmission This document specifies new DDoS Open Threat Signaling (DOTS) signal channel configuration parameters that can be negotiated between DOTS peers to enable the use of Q-Block1 and Q-Block2 Constrained Application Protocol (CoAP) options. These options enable robust and faster transmission rates for large amounts of data with less packet interchanges as well as support for faster recovery should any of the blocks get lost in transmission (especially during DDoS attacks). Also, this document defines a YANG data model for representing these new DOTS signal channel configuration parameters. This model augments the DOTS signal YANG module ("ietf-dots-signal-channel") defined in RFC 9132. Guidelines and Registration Procedures for Interface Types and Tunnel Types This document provides guidelines and procedures for those who are defining, registering, or evaluating definitions of new interface types ("ifType" values) and tunnel types. The original definition of the IANA interface type registry predated the use of IANA Considerations sections and YANG modules, so some confusion arose over time. Tunnel types were added later, with the same requirements and allocation policy as interface types. This document updates RFC 2863 and provides updated guidance for these registries. The Interfaces Group MIB This memo discusses the 'interfaces' group of MIB-II, especially the experience gained from the definition of numerous media-specific MIB modules for use in conjunction with the 'interfaces' group for managing various sub-layers beneath the internetwork-layer. It specifies clarifications to, and extensions of, the architectural issues within the MIB-II model of the 'interfaces' group. [STANDARDS-TRACK] IANA Interface Type YANG Module This document defines the initial version of the iana-if-type YANG module. YANG Types for DNS Classes and Resource Record Types This document introduces the YANG module "iana-dns-class-rr-type", which contains derived types reflecting two IANA registries: DNS CLASSes and Resource Record (RR) TYPEs. These YANG types are intended as the minimum basis for future data modeling work. YANG Groupings for TLS Clients and TLS Servers This document presents four YANG 1.1 modules -- three IETF modules and one supporting IANA module. The three IETF modules are "ietf-tls-common", "ietf-tls-client", and "ietf-tls-server". The "ietf-tls-client" and "ietf-tls-server" modules are the primary productions of this work, supporting the configuration and monitoring of TLS clients and servers. The IANA module is "iana-tls-cipher-suite-algs". This module defines YANG enumerations that provide support for an IANA-maintained algorithm registry. The Secure Shell (SSH) Transport Layer Protocol The Secure Shell (SSH) is a protocol for secure remote login and other secure network services over an insecure network. This document describes the SSH transport layer protocol, which typically runs on top of TCP/IP. The protocol can be used as a basis for a number of secure network services. It provides strong encryption, server authentication, and integrity protection. It may also provide compression. Key exchange method, public key algorithm, symmetric encryption algorithm, message authentication algorithm, and hash algorithm are all negotiated. This document also describes the Diffie-Hellman key exchange method and the minimal set of algorithms that are needed to implement the SSH transport layer protocol. [STANDARDS-TRACK] Guidelines for Authors and Reviewers of MIB Documents This memo provides guidelines for authors and reviewers of IETF standards-track specifications containing MIB modules. Applicable portions may be used as a basis for reviews of other MIB documents. This document specifies an Internet Best Current Practices for the Internet Community, and requests discussion and suggestions for improvements.
Module Review Checklist This section is adapted from . The purpose of a YANG module review is to review the YANG module for both technical correctness and adherence to IETF documentation requirements. The following checklist may be helpful when reviewing an I-D:
  • I-D Boilerplate -- verify that the document contains the required I-D boilerplate (see <https://www.ietf.org/id-info/guidelines.html>), including the appropriate statement to permit publication as an RFC, and that the I-D boilerplate does not contain references or section numbers.
  • Abstract -- verify that the abstract does not contain references, that it does not have a section number, and that its content follows the guidelines in <https://www.ietf.org/id-info/guidelines.html>.
  • Copyright Notice -- verify that the document has the appropriate text regarding the rights that document contributors provide to the IETF Trust . Verify that it contains the full IETF Trust copyright notice at the beginning of the document. The IETF Trust Legal Provisions (TLP) can be found at: <https://trustee.ietf.org/license-info/>
  • Security Considerations section -- If none of the modules in the document falls under the exceptions in (e.g., use YANG data structure), verify that the section is modeled after the latest approved template from the Operations and Management (OPS) area website (see <https://wiki.ietf.org/group/ops/yang-security-guidelines>) and that the guidelines therein have been followed.
  • IANA Considerations section -- this section must always be present. For each module within the document, ensure that the IANA Considerations section contains entries for the following IANA registries:
    XML Namespace Registry:
    Register the YANG module namespace.
    YANG Module Registry:
    Register the YANG module name, prefix, namespace, and RFC number, according to the rules specified in .
  • References -- verify that the references are properly divided between normative and informative references, that RFCs 2119 and 8174 are included as normative references if the terminology defined therein is used in the document, that all references required by the boilerplate are present, that all YANG modules containing imported items are cited as normative references, and that all citations point to the most current RFCs, unless there is a valid reason to do otherwise (for example, it is okay to include an informative reference to a previous version of a specification to help explain a feature included for backward compatibility). Be sure citations for all imported modules are present somewhere in the document text (outside the YANG module). If a YANG module contains reference or "description" statements that refer to an I-D, then the I-D is included as an informative reference.
  • License -- verify that the document contains the Revised BSD License in each YANG module or submodule. Some guidelines related to this requirement are described in Section 3.1. Make sure that the correct year is used in all copyright dates. Use the approved text from the latest TLP document, which can be found at: <https://trustee.ietf.org/license-info/>
  • Other Issues -- check for any issues mentioned in <https://www.ietf.org/id-info/checklist.html> that are not covered elsewhere.
  • Technical Content -- review the actual technical content for compliance with the guidelines in this document. The use of a YANG module compiler is recommended when checking for syntax errors. A list of freely available tools and other information, including formatting advice, can be found at: <https://wiki.ietf.org/group/netconf> and <https://wiki.ietf.org/group/netmod> Checking for correct syntax, however, is only part of the job. It is just as important to actually read the YANG module document from the point of view of a potential implementor. It is particularly important to check that "description" statements are sufficiently clear and unambiguous to allow interoperable implementations to be created.
Template for IETF Modules WG List: Editor: your-name "; // replace the first sentence in this description statement. // replace the copyright notice with the most recent // version, if it has been updated since the publication // of this document description "This module defines a template for other YANG modules. Copyright (c) IETF Trust and the persons identified as authors of the code. All rights reserved. Redistribution and use in source and binary forms, with or without modification, is permitted pursuant to, and subject to the license terms contained in, the Revised BSD License set forth in Section 4.c of the IETF Trust's Legal Provisions Relating to IETF Documents (https://trustee.ietf.org/license-info). All revisions of IETF and IANA published modules can be found at the YANG Parameters registry group (https://www.iana.org/assignments/yang-parameters). This version of this YANG module is part of RFC XXXX; see the RFC itself for full legal notices."; // RFC Ed.: replace XXXX/YYYY with actual RFC number and remove // this note // replace 'date-revision' with the module publication date // the format is (YYYY-MM-DD) revision date-revision { description "What changed in this revision."; reference "RFC XXXX: "; } // RFC Ed.: Update with the RFC number and title // of the RFC that defined the initial version of // the module and remove this note revision date-initial { description "Initial version"; reference "RFC YYYY: "; } // extension statements // feature statements // identity statements // typedef statements // grouping statements // data definition statements // augment statements // rpc statements // notification statements // DO NOT put deviation statements in a published module } ]]>
Template for IANA-Maintained Modules "; description "This module defines a template for IANA-maintained modules. Copyright (c) IETF Trust and the persons identified as authors of the code. All rights reserved. Redistribution and use in source and binary forms, with or without modification, is permitted pursuant to, and subject to the license terms contained in, the Revised BSD License set forth in Section 4.c of the IETF Trust's Legal Provisions Relating to IETF Documents (https://trustee.ietf.org/license-info). All revisions of IETF and IANA published modules can be found at the YANG Parameters registry group (https://www.iana.org/assignments/yang-parameters). The initial version of this YANG module is part of RFC IIII; see the RFC itself for full legal notices. // RFC Ed.: replace IIII with actual RFC number and remove // this note // If a script is used, complete with the script information This version of this YANG module was generated from the corresponding IANA registry using a . // RFC Ed.: replace the IANA_FOO_URL and remove this note The latest version of this YANG module is available at ."; // replace with the registry name and the URL of the IANA registry reference "Registry Name (URL)"; // replace 'date-revision' with the module publication date // the format is (YYYY-MM-DD) revision date-revision { description "Indicates the list of changes per Section 4.30.3 of RFCAAAA."; reference "URL of the latest version of the module (if any) list the authoritative event (e.g., RFC) that triggered the update to the YANG module"; } // replace 'date-initial' with the module publication date // the format is (YYYY-MM-DD) revision date-initial { description "Initial version"; reference "URL of the published initial version of the module RFC IIII: RFC Title"; // RFC Ed.: Update with the RFC number and title // of the RFC that defined the initial version of // the module and remove this note } // identity statements // typedef statements } ]]>
Acknowledgments Thanks to Jürgen Schönwälder and Ladislav Lhotka for the discussion and valuable comments. Special thanks to Ladislav Lhotka for sharing more context that led to the design documented in . Thanks to Italo Busi, Benoît Claise, Tom Petch, Randy Presuhn, Martin Björklund, Acee Lindem, Dale R. Worley, Kent Watsen, Jan Lindblad, Qiufang Ma, Mahesh Jethanandani, Robert Wilton, and Thomas Fossati for the comments. Lou Berger suggested to include more details about IANA considerations. is inspired from . Michal Vaško reported an inconsistency in Sections and of . Thanks to Xufeng Liu for reviewing the document, including providing YANGDOCTORS reviews. Italo Busi provided the examples of "case + when" construct. Thanks to Rich Salz and Michael Richardson for the SAAG review. Kent Watsen contributed text to the security and IANA-maintained module templates. Special thanks to Amanda Baber for the thoughtful and careful review of the document. Thanks to Qiufang Ma for the careful shepherd review. Thanks to Acee Lindem for triggering the discussion on data model vs. module. Thanks to Mahesh Jethanandani for the thoughtful AD review. Thanks to Christer Holmberg for the genart review, Jean Mahoney for the check on RPC implications, Ralf Weber for the dnsdir, Giuseppe Fioccola for the opsdir review, Joseph Touch for the tsvart review, and Yoav Nir for the secdir review. Thanks Éric Vyncke, Mike Bishop, Roman Danyliw, Orie Steele, Ketan Talaulikar, and Deb Cooley for the IESG review.
The author of RFC 8407:
Andy Bierman
YumaWorks
email: andy@yumaworks.com
Acknowledgments from RFC 8407:
The structure and contents of this document are adapted from "Guidelines for Authors and Reviewers of MIB Documents" , by C. M. Heard.
The working group thanks Martin Bjorklund, Juergen Schoenwaelder, Ladislav Lhotka, Jernej Tuljak, Lou Berger, Robert Wilton, Kent Watsen, and William Lupton for their extensive reviews and contributions to this document.