Internet-Draft | RSVP YANG Data Model | January 2022 |
Beeram, et al. | Expires 13 July 2022 | [Page] |
This document defines a YANG data model for the configuration and management of the RSVP protocol. The YANG data model covers the building blocks that may be augmented by other RSVP extension data models such as RSVP Traffic-Engineering (RSVP-TE). It is divided into two modules that cover the basic and extended RSVP features.¶
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YANG [RFC6020] and [RFC7950] is a data modeling language that was introduced to define the contents of a conceptual data store that allows networked devices to be managed using NETCONF [RFC6241]. YANG has proved relevant beyond its initial confines, as bindings to other interfaces (e.g. RESTCONF [RFC8040]) and encoding other than XML (e.g. JSON) are being defined. Furthermore, YANG data models can be used as the basis of implementation for other interfaces, such as CLI and programmatic APIs.¶
This document defines a YANG data model for the configuration and management of the RSVP protocol [RFC2205]. The data model is divided into two modules: a base and extended RSVP YANG modules. The RSVP base YANG 'ietf-rsvp' module covers the data that is core to the function of the RSVP protocol and MUST be supported by vendors that support RSVP protocol [RFC2205]. The RSVP extended 'ietf-rsvp-extended' module covers the data that is optional, or provides ability to tune RSVP protocol base functionality. The support for RSVP extended module features by vendors is considered optional.¶
The RSVP YANG model provides the building blocks needed to allow augmentation by other models that extend the RSVP protocol- such as using RSVP extensions to signal Label Switched Paths (LSPs) as defined in [RFC3209].¶
The YANG module(s) defined in this document are compatible with the Network Management Datastore Architecture (NMDA) [RFC7950].¶
The key words "MUST", "MUST NOT", "REQUIRED", "SHALL", "SHALL NOT", "SHOULD", "SHOULD NOT", "RECOMMENDED", "NOT RECOMMENDED", "MAY", and "OPTIONAL" in this document are to be interpreted as described in BCP 14 [RFC2119] [RFC8174] when, and only when, they appear in all capitals, as shown here.¶
The terminology for describing YANG data models is found in [RFC7950].¶
In this document, names of data nodes and other data model objects are prefixed using the standard prefix associated with the corresponding YANG imported modules, as shown in Table 1.¶
A full tree diagram of the module(s) defined in this document is given in subsequent sections as per the syntax defined in [RFC8340].¶
The RSVP YANG module augments the "control-plane-protocol" entry from the 'ietf-routing' module defined in [RFC8349]. It also defines the identity "rsvp" of base type "rt:routing-protocol" to identify the RSVP routing protocol.¶
The 'ietf-rsvp' model defines a single instance of the RSVP protocol. The top 'rsvp' container encompases data for one such RSVP protocol instance. Multiple instances can be defined as multiple control-plane protocols instances as described in [RFC8349].¶
The YANG data model defined has the common building blocks for the operation of the base RSVP protocol for the session type defined in [RFC2205]. The augmentation of this model by other models (e.g. to support RSVP Traffic Engineering (TE) extensions for signaling Label Switched Paths (LSPs)) are outside the scope of this document and are discussed in separate document(s).¶
This RSVP YANG data model defined in this document is divided into two modules: a base and extended modules. The RSVP data covered in 'ietf-rsvp' module are categorized as core to the function of the protocol and MUST be supported by vendors claiming the support for RSVP protocol [RFC2205].¶
The RSVP extended features that are covered in 'ietf-rsvp-extended' module are categorized as either optional or providing ability to better tune the basic functionality of the RSVP protocol. The support for RSVP extended features by all vendors is considered optional.¶
The relationship between the base and RSVP extended YANG modules and the IETF routing YANG model is shown in Figure 1.¶
The RSVP data covered in the 'ietf-rsvp' YANG module provides the common building blocks that are required to configure, operate and manage the RSVP protocol and MUST be supported by vendors that claim the support for base RSVP protocol defined in [RFC2205].¶
In addition, the following standard RSVP core features are modeled under the 'ietf-rsvp' module:¶
Optional features are beyond the basic configuration, and operation of the RSVP protocol. The decision whether to support these RSVP features on a particular device is left to the vendor that supports the RSVP core features.¶
The following optional features that are covered in the 'ietf-rsvp-extended' YANG module:¶
The RSVP YANG data model defines the 'rsvp' top-level container that contains the configuration and operational state for the RSVP protocol. The presence of this container enables the RSVP protocol functionality.¶
The 'rsvp' top-level container also includes data that has router level scope (i.e. applicable to all objects modeled under rsvp). It also contains configuration and state data about the following types of RSVP objects:¶
The derived state data is contained in "read-only" nodes directly under the intended object as shown in Figure 2.¶
The following¶
'router-level':¶
'interfaces':¶
'neighbors' :¶
'sessions':¶
The defined YANG data model supports configuration inheritance for neighbors, and interfaces. Data nodes defined under the main container (e.g. the container that encompasses the list of interfaces, or neighbors) are assumed to apply equally to all elements of the list, unless overridden explicitly for a certain element (e.g. interface).¶
Modeling notifications data is key in any defined YANG data model. [RFC8639] and [RFC8641] define a subscription and push mechanism for YANG datastores. This mechanism currently allows the user to:¶
The RSVP base module includes the core features and building blocks for modeling the RSVP protocol as described in Section 3.2.¶
Figure 3 shows the YANG tree representation for configuration, state data and RPCs that are covered in 'ietf-rsvp' YANG module:¶
The ietf-rsvp module imports from the following modules:¶
This module also references the following documents: [RFC2205], [RFC5495], [RFC3473], [RFC5063], [RFC2747], [RFC3209], and [RFC2961].¶
<CODE BEGINS> file "ietf-rsvp@2021-12-02.yang" module ietf-rsvp { yang-version 1.1; namespace "urn:ietf:params:xml:ns:yang:ietf-rsvp"; /* Replace with IANA when assigned */ prefix rsvp; import ietf-interfaces { prefix if; reference "RFC8343: A YANG Data Model for Interface Management"; } import ietf-inet-types { prefix inet; reference "RFC6991: Common YANG Data Types"; } import ietf-yang-types { prefix yang; reference "RFC6991: Common YANG Data Types"; } import ietf-routing { prefix rt; reference "RFC8349: A YANG Data Model for Routing Management (NMDA Version)"; } import ietf-key-chain { prefix key-chain; reference "RFC8177: YANG Data Model for Key Chains"; } import ietf-netconf-acm { prefix nacm; reference "RFC8341: Network Configuration Access Control Model"; } organization "IETF Traffic Engineering Architecture and Signaling (TEAS) Working Group"; contact "WG Web: <http://tools.ietf.org/wg/teas/> WG List: <mailto:teas@ietf.org> Editor: Vishnu Pavan Beeram <mailto:vbeeram@juniper.net> Editor: Tarek Saad <mailto:tsaad@juniper.net> Editor: Rakesh Gandhi <mailto:rgandhi@cisco.com> Editor: Xufeng Liu <mailto: xufeng.liu.ietf@gmail.com> Editor: Igor Bryskin <mailto:i_bryskin@yahoo.com>"; description "This module contains the RSVP YANG data model. The model fully conforms to the Network Management Datastore Architecture (NMDA). Copyright (c) 2019 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 Simplified 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). This version of this YANG module is part of RFC XXXX; see the RFC itself for full legal notices."; // RFC Ed.: replace XXXX with actual RFC number and remove this // note. // RFC Ed.: update the date below with the date of RFC publication // and remove this note. revision 2021-12-02 { description "Initial version."; reference "RFCXXXX: A YANG Data Model for Resource Reservation Protocol (RSVP)"; } identity rsvp { base rt:routing-protocol; description "RSVP protocol"; } identity rsvp-session-type { description "Base RSVP session type"; } identity rsvp-session-ip { base rsvp-session-type; description "RSVP IP session type"; } identity reservation-style { description "Base identity for reservation style."; } identity reservation-wildcard-filter { base reservation-style; description "Wildcard-Filter (WF) Style."; reference "RFC2205"; } identity reservation-fixed-filter { base reservation-style; description "Fixed-Filter (FF) Style."; reference "RFC2205"; } identity reservation-shared-explicit { base reservation-style; description "Shared Explicit (SE) Style."; reference "RFC2205"; } grouping graceful-restart { description "RSVP graceful restart local parameters grouping."; container graceful-restart { description "Graceful restart local information."; leaf enabled { type boolean; default "false"; description "'true' if RSVP Graceful Restart is enabled. 'false' if RSVP Graceful Restart is disabled."; reference "RFC5495"; } leaf local-restart-time { type uint32; units "seconds"; default "120"; description "Time it takes the local node to restart its RSVP-TE component (to the point where it can exchange RSVP Hello with its neighbors). A value of 0xffffffff indicates that the restart of the neighbor's control plane may occur over an indeterminate interval and that the operation of its data plane is unaffected by control plane failures."; reference "RFC3473"; } leaf local-recovery-time { type uint32; units "seconds"; default "120"; description "The period of time, in seconds, that the local node requires to re-synchronize RSVP and MPLS forwarding state with its neighbor. A value of zero (0) indicates that MPLS forwarding state was not preserved across a particular reboot."; reference "RFC3473"; } container helper-mode { description "Helper mode information. In this mode, the node resynchronize its stored states with a neighbor whose control plane has restarted. The helper mode term is borrowed from RFC3623 and adopted by several vendors vendors in their implementation of RSVP graceful restart."; leaf enabled { type boolean; default "true"; description "'true' if helper mode is enabled."; } leaf max-helper-restart-time { type uint32; units "seconds"; default "20"; description "The maximum time the router or switch waits after it discovers that the neighboring router has gone down before it declares the neighbor down."; reference "RFC5063"; } leaf max-helper-recovery-time { type uint32; units "seconds"; default "180"; description "The maximum amount of time the router retains the state of its RSVP neighbors while they undergo a graceful restart."; reference "RFC5063"; } } } } grouping neighbor-graceful-restart { description "RSVP graceful restart neighbor parameters grouping."; container graceful-restart { description "Graceful restart information."; leaf neighbor-restart-time { type uint32; units "seconds"; default "120"; config false; description "Time it takes the neighbor node to restart its RSVP-TE component (to the point where it can exchange RSVP Hello with its neighbors). A value of 0xffffffff indicates that the restart of the neighbor's control plane may occur over an indeterminate interval and that the operation of its data plane is unaffected by control plane failures."; reference "RFC3473"; } leaf neighbor-recovery-time { type uint32; units "seconds"; default "120"; config false; description "The period of time, in milliseconds, that the neighbor node requires to re-synchronize RSVP and MPLS forwarding state with its neighbor. A value of zero (0) indicates that MPLS forwarding state was not preserved across a particular reboot."; reference "RFC3473"; } container helper-mode { description "Helper mode information."; leaf neighbor-restart-time-remaining { type uint32; units "seconds"; config false; description "Number of seconds remaining for neighbor to send Hello message after restart."; reference "RFC5063"; } leaf neighbor-recovery-time-remaining { type uint32; units "seconds"; config false; description "Number of seconds remaining for neighbor to refresh."; reference "RFC5063"; } } // helper-mode } } grouping refresh-reduction { description "Top level grouping for RSVP refresh reduction parameters."; container refresh-reduction { description "Top level container for RSVP refresh reduction parameters."; leaf enabled { type boolean; default "true"; description "'true' if RSVP Refresh Reduction is enabled. 'false' if RSVP Refresh Reduction is disabled."; } reference "RFC2961 RSVP Refresh Overhead Reduction Extensions"; } } grouping authentication { description "Top level grouping for RSVP authentication parameters."; container authentication { description "Top level container for RSVP authentication parameters."; leaf enabled { type boolean; default "false"; description "'true' if RSVP Authentication is enabled. 'false' if RSVP Authentication is disabled."; } leaf authentication-key { type string; default ""; description "An authentication key string."; reference "RFC2747: RSVP Cryptographic Authentication"; } leaf crypto-algorithm { type identityref { base key-chain:crypto-algorithm; } mandatory true; description "Cryptographic algorithm associated with key."; } } } grouping hellos { description "Top level grouping for RSVP hellos parameters."; container hellos { description "Top level container for RSVP hello parameters."; leaf enabled { type boolean; default "true"; description "'true' if RSVP Hello is enabled. 'false' if RSVP Hello is disabled."; reference "RFC3209: RSVP-TE: Extensions to RSVP for LSP Tunnels. RFC5495: Description of the Resource Reservation Protocol - Traffic-Engineered (RSVP-TE) Graceful Restart Procedures."; } } } grouping session-attributes { description "Top level grouping for RSVP session properties."; leaf destination-port { type uint16; description "RSVP destination port."; reference "RFC2205"; } leaf protocol-id { type uint8; description "The IP protocol ID."; reference "RFC2205, section 3.2"; } leaf source { type inet:ip-address; description "RSVP source address."; reference "RFC2205"; } leaf destination { type inet:ip-address; description "RSVP destination address."; reference "RFC2205"; } leaf session-name { type string; default ""; description "The signaled name of this RSVP session."; } leaf session-status { type enumeration { enum up { description "RSVP session is up."; } enum down { description "RSVP session is down."; } } default "down"; description "Enumeration of RSVP session states."; } leaf session-type { type identityref { base rsvp-session-type; } mandatory "true"; description "RSVP session type."; } container psbs { description "Path State Block (PSB) container."; list psb { description "List of Path State Blocks."; leaf source-port { type inet:port-number; description "RSVP source port."; reference "RFC2205"; } leaf expires-in { type uint32; units "seconds"; default "180"; description "Time to expiry (in seconds)."; } } } container rsbs { description "Reservation State Block (RSB) container."; list rsb { description "List of Reservation State Blocks."; leaf source-port { type inet:port-number; description "RSVP source port."; reference "RFC2205"; } leaf reservation-style { type identityref { base reservation-style; } mandatory "true"; description "RSVP reservation style."; } leaf expires-in { type uint32; units "seconds"; default "180"; description "Time to expiry (in seconds)."; } } } } grouping neighbor-attributes { description "Top level grouping for RSVP neighbor properties."; leaf address { type inet:ip-address; description "Address of the RSVP neighbor."; } leaf epoch { type uint32; default "0"; description "Neighbor epoch."; reference "RFC5063"; } leaf expiry-time { type uint32; units "seconds"; default "180"; description "Neighbor expiry time after which the neighbor state is purged if no states associated with it."; } uses neighbor-graceful-restart { description "Allows configuration applicable to all neighbors"; } leaf hello-status { type enumeration { enum enabled { description "RSVP Hellos enabled."; } enum disabled { description "RSVP Hellos disabled."; } enum restarting { description "RSVP restarting."; } } config false; description "RSVP Hello status."; } leaf interface { type if:interface-ref; description "Interface where RSVP neighbor was detected."; } leaf neighbor-status { type enumeration { enum up { description "Neighbor state up."; } enum down { description "Neighbor state down."; } enum hello-disable { description "RSVP Hellos disabled."; } enum restarting { description "RSVP neighbor restarting."; } } config false; description "RSVP neighbor state."; } leaf refresh-reduction-capable { type boolean; default "true"; description "Enables all RSVP refresh reduction message bundling, RSVP message ID, reliable message delivery and Srefresh messages."; reference "RFC2961 RSVP Refresh Overhead Reduction Extensions"; } leaf restart-count { type yang:counter32; config false; description "Number of times this RSVP neighbor has restarted."; } leaf restart-time { type yang:date-and-time; config false; description "Last restart time of the RSVP neighbor."; reference "RFC3473"; } } grouping packet-statistics { description "Packet statistics grouping."; container packets { description "Packet statistics container."; leaf sent { type yang:counter64; description "RSVP packet sent count."; } leaf received { type yang:counter64; description "RSVP packet received count."; } } } grouping message-statistics { description "RSVP protocol statistics grouping."; container messages { description "RSVP protocol statistics container."; leaf ack-sent { type yang:counter64; description "RSVP Hello sent count."; } leaf ack-received { type yang:counter64; description "RSVP Hello received count."; } leaf bundle-sent { type yang:counter64; description "RSVP Bundle message sent count."; } leaf bundle-received { type yang:counter64; description "RSVP Bundle message received count."; } leaf hello-sent { type yang:counter64; description "RSVP Hello message sent count."; } leaf hello-received { type yang:counter64; description "RSVP Hello message received count."; } leaf integrity-challenge-sent { type yang:counter64; description "RSVP Integrity Challenge message sent count."; } leaf integrity-challenge-received { type yang:counter64; description "RSVP Integrity Challenge message received count."; } leaf integrity-response-sent { type yang:counter64; description "RSVP Integrity Response message sent count."; } leaf integrity-response-received { type yang:counter64; description "RSVP Integrity Response message received count."; } leaf notify-sent { type yang:counter64; description "RSVP Notify message sent count."; } leaf notify-received { type yang:counter64; description "RSVP Notify message received count."; } leaf path-sent { type yang:counter64; description "RSVP Path message sent count."; } leaf path-received { type yang:counter64; description "RSVP Path message received count."; } leaf path-err-sent { type yang:counter64; description "RSVP Path error message sent count."; } leaf path-err-received { type yang:counter64; description "RSVP Path error message received count."; } leaf path-tear-sent { type yang:counter64; description "RSVP Path tear message sent count."; } leaf path-tear-received { type yang:counter64; description "RSVP Path tear message received count."; } leaf resv-sent { type yang:counter64; description "RSVP Resv message sent count."; } leaf resv-received { type yang:counter64; description "RSVP Resv message received count."; } leaf resv-confirm-sent { type yang:counter64; description "RSVP Confirm message sent count."; } leaf resv-confirm-received { type yang:counter64; description "RSVP Confirm message received count."; } leaf resv-err-sent { type yang:counter64; description "RSVP Resv error message sent count."; } leaf resv-err-received { type yang:counter64; description "RSVP Resv error message received count."; } leaf resv-tear-sent { type yang:counter64; description "RSVP Resv tear message sent count."; } leaf resv-tear-received { type yang:counter64; description "RSVP Resv tear message received count."; } leaf srefresh-sent { type yang:counter64; description "RSVP Srefresh message sent count."; } leaf srefresh-received { type yang:counter64; description "RSVP Srefresh message received count."; } leaf unknown-messages-received { type yang:counter64; description "Unknown messages received count."; } } } grouping errors-statistics { description "Error statistics grouping."; container errors { description "Error statistics container."; leaf authenticate { type yang:counter64; description "The total number of RSVP packets received with an authentication failure."; } leaf checksum { type yang:counter64; description "The total number of RSVP packets received with an invalid checksum value."; } leaf packet-length { type yang:counter64; description "The total number of packets received with an invalid packet length."; } } } grouping statistics { description "RSVP statistic attributes."; container statistics { config false; description "RSVP statistics container."; uses message-statistics; uses packet-statistics; uses errors-statistics; } } grouping intf-attributes { description "Top level grouping for RSVP interface properties."; uses refresh-reduction; uses hellos; uses authentication; uses statistics; } augment "/rt:routing/rt:control-plane-protocols/" + "rt:control-plane-protocol" { when "rt:type = 'rsvp:rsvp'" { description "This augment is only valid when routing protocol instance type is RSVP."; } description "RSVP protocol augmentation."; container rsvp { presence "Enable RSVP feature"; description "RSVP feature container"; container interfaces { description "RSVP interfaces container."; uses intf-attributes; list interface { key "name"; description "RSVP interfaces."; leaf name { type if:interface-ref; description "RSVP interface."; } uses intf-attributes; } } container sessions { description "RSVP sessions container."; list session-ip { key "destination protocol-id destination-port"; config false; description "List of RSVP sessions."; uses session-attributes; } } container neighbors { description "RSVP neighbors container"; list neighbor { key "address"; description "List of RSVP neighbors"; uses neighbor-attributes; } } uses graceful-restart; } } grouping session-ref { description "Session reference information"; leaf destination { type leafref { path "/rt:routing/rt:control-plane-protocols" + "/rt:control-plane-protocol/rsvp:rsvp" + "/rsvp:sessions/rsvp:session-ip/destination"; } mandatory true; description "The RSVP session destination."; } leaf protocol-id { type uint8; mandatory true; description "The RSVP session protocol ID."; } leaf destination-port { type inet:ip-address; mandatory true; description "The RSVP session destination port."; } } rpc clear-session { nacm:default-deny-all; description "Clears RSVP sessions RPC"; input { leaf routing-protocol-instance-name { type leafref { path "/rt:routing/rt:control-plane-protocols/" + "rt:control-plane-protocol/rt:name"; } mandatory true; description "Name of the RSVP protocol instance whose session is being cleared. If the corresponding RSVP instance doesn't exist, then the operation will fail with an error-tag of 'data-missing' and an error-app-tag of 'routing-protocol-instance-not-found'."; } choice filter-type { mandatory true; description "Filter choice"; case match-all { leaf all { type empty; mandatory true; description "Match all RSVP sessions."; } } case match-one { container session-info { description "Specifies the specific session to invoke the operation on."; choice session-type { mandatory true; description "The RSVP session type."; case rsvp-session-ip { uses session-ref; } } } } } } } rpc clear-neighbor { nacm:default-deny-all; description "RPC to clear the RSVP Hello session to a neighbor."; input { leaf routing-protocol-instance-name { type leafref { path "/rt:routing/rt:control-plane-protocols/" + "rt:control-plane-protocol/rt:name"; } mandatory true; description "Name of the RSVP protocol instance whose session is being cleared. If the corresponding RSVP instance doesn't exist, then the operation will fail with an error-tag of 'data-missing' and an error-app-tag of 'routing-protocol-instance-not-found'."; } choice filter-type { mandatory true; description "The Filter choice."; case match-all { leaf all { type empty; mandatory true; description "Match all RSVP neighbor sessions."; } } case match-one { leaf neighbor-address { type leafref { path "/rt:routing/rt:control-plane-protocols" + "/rt:control-plane-protocol/rsvp:rsvp" + "/rsvp:neighbors/rsvp:neighbor/address"; } mandatory true; description "Match the specific RSVP neighbor session."; } } } } } rpc clear-authentication { nacm:default-deny-all; description "Clears the RSVP Security Association (SA) before the lifetime expires."; input { leaf routing-protocol-instance-name { type leafref { path "/rt:routing/rt:control-plane-protocols/" + "rt:control-plane-protocol/rt:name"; } mandatory true; description "Name of the RSVP protocol instance whose session is being cleared. If the corresponding RSVP instance doesn't exist, then the operation will fail with an error-tag of 'data-missing' and an error-app-tag of 'routing-protocol-instance-not-found'."; } choice filter-type { mandatory true; description "Filter choice"; case match-all { leaf all { type empty; mandatory true; description "Match all RSVP security associations."; } } case match-one-interface { leaf interface { type if:interface-ref; description "Interface where RSVP security association(s) to be detected."; } } } } } } <CODE ENDS>¶
The RSVP extended module augments the RSVP base module with optional feature data as described in Section 3.3.¶
Figure 4 shows the YANG tree representation for configuration and state data that are covered in 'ietf-rsvp-extended' YANG module:¶
The 'ietf-rsvp-extended' module imports from the following modules:¶
Figure 5 shows the RSVP extended YANG module:¶
This module also references the following documents: [RFC3473], [RFC2747], [RFC3209], [RFC2205], [RFC2961], and [RFC5495].¶
This document registers the following URIs in the IETF XML registry [RFC3688]. Following the format in [RFC3688], the following registration is requested to be made.¶
URI: urn:ietf:params:xml:ns:yang:ietf-rsvp Registrant Contact: The IESG. XML: N/A, the requested URI is an XML namespace. URI: urn:ietf:params:xml:ns:yang:ietf-rsvp-extended Registrant Contact: The IESG. XML: N/A, the requested URI is an XML namespace.¶
This document registers two YANG modules in the YANG Module Names registry [RFC6020].¶
name: ietf-rsvp namespace: urn:ietf:params:xml:ns:yang:ietf-rsvp prefix: rsvp reference: RFCXXXX name: ietf-rsvp-extended namespace: urn:ietf:params:xml:ns:yang:ietf-rsvp-extended prefix: rsvp-extended reference: RFCXXXX¶
The YANG module specified in this document defines a schema for data that is designed to be accessed via network management protocols such as NETCONF [RFC6241] or RESTCONF [RFC8040]. The lowest NETCONF layer is the secure transport layer, and the mandatory-to-implement secure transport is Secure Shell (SSH) [RFC6242]. The lowest RESTCONF layer is HTTPS, and the mandatory-to-implement secure transport is TLS [RFC8446].¶
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.¶
There are a number of data nodes defined in the YANG module(s) defined in this document that are writable/creatable/deletable (i.e., config true, which is the default). These data nodes may be considered sensitive or vulnerable in some network environments. Write operations (e.g., <edit-config>) to these data nodes without proper protection can have a negative effect on network operations. These are the subtrees and data nodes and their sensitivity/vulnerability:¶
/rt:routing/rt:control-plane-protocols/rt:control-plane-protocol/rsvp:rsvp/ /rsvp:globals /rsvp:interfaces /rsvp:sessions¶
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. These are the subtrees and data nodes and their sensitivity/vulnerability:¶
/rt:routing/rt:control-plane-protocols/rt:control-plane-protocol/rsvp:rsvp/ /rsvp:globals /rsvp:interfaces /rsvp:sessions¶
For RSVP authentication, the configuration supported is via the specification of key-chains [RFC8177] or the direct specification of key and authentication algorithm, and hence security considerations of [RFC8177] are inherited. This includes the considerations with respect to the local storage and handling of authentication keys.¶
Some of the RPC operations defined in this YANG module may be considered sensitive or vulnerable in some network environments. It is thus important to control access to these operations. The RSVP YANG module support the "clear-session" and "clear-neighbor" RPCs. If access to either of these is compromised, they can result in temporary network outages be employed to mount DoS attacks.¶
The security considerations spelled out in the YANG 1.1 specification [RFC7950] apply for this document as well.¶
The authors would like to thank Tom Petch for reviewing and providing useful feedback about the document. The authors would also like to thank Lou Berger for reviewing and providing valuable feedback on this document.¶
A simple network setup is shown in {fig-example title}. R1 runs the RSVP routing protocol on both interfaces 'ge0/0/0/1', and 'ge0/0/0/2'.¶
The instance data tree could then be as follows:¶
Himanshu Shah Ciena Email: hshah@ciena.com Xia Chen Huawei Technologies Email: jescia.chenxia@huawei.com Raqib Jones Brocade Email: raqib@Brocade.com Bin Wen Comcast Email: Bin_Wen@cable.comcast.com¶