Submodule containing definitions of groupings that are re-used across multiple contexts within the AFT model.
Version: 2024-04-25
submodule openconfig-aft-common { yang-version 1; belongs-to openconfig-aft { prefix oc-aft; } import openconfig-interfaces { prefix oc-if; } import openconfig-extensions { prefix oc-ext; } import openconfig-yang-types { prefix oc-yang; } import openconfig-inet-types { prefix oc-inet; } import openconfig-mpls-types { prefix oc-mplst; } import openconfig-policy-types { prefix oc-pol-types; } import openconfig-aft-types { prefix oc-aftt; } import openconfig-evpn-types { prefix oc-evpn-types; } organization "OpenConfig working group"; contact "OpenConfig working group www.openconfig.net"; description "Submodule containing definitions of groupings that are re-used across multiple contexts within the AFT model."; revision "2024-04-25" { description "Add backup-active to AFT NHG state."; reference "2.6.0"; } revision "2024-01-26" { description "Add gre container under next-hops aft entry state. Add src-ip, dst-ip and ttl under gre aft entry state for telemetry. Updated description for tunnel-src-ip-address properties under next-hops."; reference "2.5.0"; } revision "2023-09-26" { description "Add next-hop-group-name in NHG AFT entry state."; reference "2.4.0"; } revision "2023-04-19" { description "Add atomic attribute to AFT containers."; reference "2.3.0"; } revision "2022-06-16" { description "Add state-synced container under afts."; reference "2.2.0"; } revision "2022-06-15" { description "Add decapsulate-header in NH AFT entry state"; reference "2.1.0"; } revision "2022-05-17" { description "Relocate next-hop-group/next-hop-group-network-instance from openconfig-aft-common to resolve absolute path leafref specific to network-instances"; reference "2.0.0"; } revision "2022-01-27" { description "Add next hop counters and prefix counters."; reference "1.0.0"; } revision "2022-01-26" { description "Add vni-label and tunnel-src-ip-address properties under next-hops"; reference "0.10.0"; } revision "2021-12-09" { description "Add pop-top-label in NH AFT entry state"; reference "0.9.0"; } revision "2021-08-06" { description "Add references to the network instance within which to resolve a next-hop-group; fix defect where NHG could not be an ID defined outside the current NI; add metadata; add IP-in-IP encap."; reference "0.8.0"; } revision "2021-07-15" { description "NHG-ID and NH-ID space management."; reference "0.7.0"; } revision "2020-11-06" { description "Make AFT model read-only."; reference "0.6.0"; } revision "2020-09-09" { description "Remove leafs that are not used as keys from config containers as AFT model is ready-only. * next-hop/interface-ref/config. * all leafs under policy-forwarding-entry/config except index."; reference "0.5.0"; } revision "2019-11-07" { description "Move lsp-name leaf out of aft-common-entry-nexthop-state group."; reference "0.4.1"; } revision "2019-08-02" { description "Add installing protocol for IPv[46] unicast entries. Add the ability to describe conditional next-hop groups outside of the policy forwarding module to allow for efficient handling of CBTS, where many prefixes may share the same next-hop criteria."; reference "0.4.0"; } revision "2019-08-01" { description "Add lsp-name leaf to AFT next-hop."; reference "0.3.3"; } revision "2018-11-21" { description "Add OpenConfig module metadata extensions."; reference "0.3.2"; } revision "2017-08-24" { description "Formatting fixes"; reference "0.3.1"; } revision "2017-05-10" { description "Refactor to provide concretised per-AF schemas per AFT."; reference "0.3.0"; } oc-ext:openconfig-version "2.6.0"; grouping aft-nhop-structural { description "Structural grouping describing a next-hop entry."; container next-hops { description "The list of next-hops that are to be used for entry within the AFT table. The structure of each next-hop is address family independent, such that it is possible to resolve fully how the next-hop is treated. For example: - Where ingress IPv4 unicast packets are to be forwarded via an MPLS LSP, the next-hop list should indicate the MPLS label stack that is used to the next-hop. - Where ingress MPLS labelled packets are to be forwarded to an IPv6 nexthop (for example, a CE within a VPN, then the popped label stack, and IPv6 next-hop address should be indicated)."; list next-hop { oc-ext:telemetry-atomic; key "index"; description "A next-hop associated with the forwarding instance."; leaf index { type leafref { path "../state/index"; } description "A unique index identifying the next-hop entry for the AFT entry"; } container state { config false; description "Operational state parameters relating to the AFT next-hop entry"; uses aft-common-entry-nexthop-state; uses aft-labeled-entry-state; container counters { description "Surrounding container for counters."; uses aft-common-entry-counter-state; } // container counters uses aft-evpn-entry-state; } // container state container ip-in-ip { description "When specified, the packet has an IP-in-IP header applied to it before forwarding to the specified next-hop."; container state { config false; description "State parameters relating to IP-in-IP encapsulation."; uses aft-common-entry-nexthop-ipip-state; } // container state } // container ip-in-ip container gre { description "When specified, the packet has an GRE (Generic Routing Encapsulation)header applied to it before forwarding to the specified next-hop. encapsulate-header leaf should be set to GRE for this to apply"; container state { config false; description "State parameters relating to GRE encapsulation."; uses aft-common-entry-nexthop-gre-state; } // container state } // container gre uses oc-if:interface-ref-state; } // list next-hop } // container next-hops } // grouping aft-nhop-structural grouping aft-common-entry-state { description "Operational state parameters relating to a forwarding entry"; container counters { config false; description "Surrounding container for counters."; uses aft-common-entry-counter-state; } // container counters leaf entry-metadata { type binary { length "0..8"; } description "Metadata persistently stored with the entry."; } } // grouping aft-common-entry-state grouping aft-labeled-entry-state { description "Operational state for LSP name in forwarding entry"; leaf lsp-name { type string; description "Where applicable, the protocol name for the next-hop labelled forwarding entry. This leaf is applicable only to next-hops which include MPLS label information, and its value typically corresponds to the RSVP-TE LSP name."; } } // grouping aft-labeled-entry-state grouping aft-evpn-entry-state { description "Operational state for evpn related information in forwarding entry"; leaf vni-label { type oc-evpn-types:evi-id; description "Where applicable, the next hop label representing the virtual network identifier (VNI) for the forwarding entry. This leaf is applicable only to next-hops which include VXLAN encapsulation header information"; } leaf tunnel-src-ip-address { type oc-inet:ip-address; description "Where applicable this represents the vxlan tunnel source ip address. For VXLAN this represents the source VTEP ip address"; } } // grouping aft-evpn-entry-state grouping aft-common-entry-nexthop-state { description "Parameters relating to a next-hop."; leaf index { type uint64; description "A unique entry for the next-hop."; } leaf programmed-index { type uint64; description "In some routing protocols, or route injection mechanisms it is possible to set the index of the next-hop via configuration or the protocol itself. In some systems it may not be possible to maintain the index provided by an external client when advertising the same entry via telemetry. This leaf reflects the configured or client-supplied index of the next-hop. This allows a client to create an assocation or mapping back to the original index pushed by the client, and the ID used as a key in the next-hop AFT list."; } leaf ip-address { type oc-inet:ip-address; description "The IP address of the next-hop system."; } leaf mac-address { type oc-yang:mac-address; description "The MAC address of the next-hop if resolved by the local network instance."; } leaf pop-top-label { type boolean; default 'false'; description "Flag that controls pop action, i.e., the top-most MPLS label should be popped from the packet when switched by the system. The top-most MPLS label associated with pop action is equal to the label key used in 'mpls' AFT 'label-entry' list."; } leaf-list pushed-mpls-label-stack { type oc-mplst:mpls-label; ordered-by user; description "The MPLS label stack imposed when forwarding packets to the next-hop - the stack is encoded as a leaf list whereby the order of the entries is such that the first entry in the list is the label at the bottom of the stack to be pushed. To this end, a packet which is to forwarded to a device using a service label of 42, and a transport label of 8072 will be represented with a label stack list of [42, 8072]. The MPLS label stack list is ordered by the user, such that no system re-ordering of leaves is permitted by the system. A swap operation is reflected by entries in the popped-mpls-label-stack and pushed-mpls-label-stack nodes."; } leaf encapsulate-header { type oc-aftt:encapsulation-header-type; description "When forwarding a packet to the specified next-hop the local system performs an encapsulation of the packet - adding the specified header type."; } leaf decapsulate-header { type oc-aftt:encapsulation-header-type; description "When forwarding a packet to the specified next-hop, the local system performs a decapsulation of the packet - removing the specified header type. In the case that no next-hop is specified, the packet header is removed, and a subsequent forwarding lookup is performed on the packet encapsulated within the header, matched within the relevant AFT within the specified network-instance."; } uses aft-common-install-protocol; } // grouping aft-common-entry-nexthop-state grouping aft-common-entry-nexthop-ipip-state { description "IP-in-IP encapsulation applied on a next-hop"; leaf src-ip { type oc-inet:ip-address; description "Source IP address to use for the encapsulated packet."; } leaf dst-ip { type oc-inet:ip-address; description "Destination IP address to use for the encapsulated packet."; } } // grouping aft-common-entry-nexthop-ipip-state grouping aft-common-entry-nexthop-gre-state { description "GRE encapsulation applied on a IPv4 and IPv6 next-hop."; leaf src-ip { type oc-inet:ip-address; description "The source IP address for the GRE encapsulation may be expressed using this leaf (src-ip) or if may be derived from '../../interface-ref/state/subinterface'"; } leaf dst-ip { type oc-inet:ip-address; description "Destination IP address to use for the encapsulated packet."; } leaf ttl { type uint8; description "This leaf reflects the configured/default TTL value that is used in the outer header during packet encapsulation. When this leaf is not set, the TTL value of the inner packet is copied over as the outer packet's TTL value during encapsulation."; } } // grouping aft-common-entry-nexthop-gre-state grouping aft-common-install-protocol { description "Grouping for a common reference to the protocol which installed an entry."; leaf origin-protocol { type identityref { base oc-pol-types:INSTALL_PROTOCOL_TYPE; } description "The protocol from which the AFT entry was learned."; } } // grouping aft-common-install-protocol grouping aft-common-ip-state { description "Common parameters across IP address families"; uses aft-common-install-protocol; leaf decapsulate-header { type oc-aftt:encapsulation-header-type; description "When forwarding a packet to the specified next-hop, the local system performs a decapsulation of the packet - removing the specified header type. In the case that no next-hop is specified, the packet header is removed, and a subsequent forwarding lookup is performed on the packet encapsulated within the header, matched within the relevant AFT within the specified network-instance."; } } // grouping aft-common-ip-state grouping aft-next-hop-groups-structural { description "Logical grouping for groups of next-hops."; container next-hop-groups { description "Surrounding container for groups of next-hops."; list next-hop-group { oc-ext:telemetry-atomic; key "id"; description "An individual set of next-hops grouped into a common group. Each entry within an abstract forwarding table points to a next-hop-group. Entries in the next-hop-group are forwarded to according to the weights specified for each next-hop group. If an entry within the next-hop group becomes unusable, for example due to an interface failure, the remaining entries are used until all entries become unusable - at which point the backup next-hop-group (if specified) is used."; leaf id { type leafref { path "../state/id"; } description "A reference to a unique identifier for the next-hop-group."; } container state { config false; description "Operational state parameters relating to next-hop-groups."; uses aft-nhg-state; } // container state container next-hops { description "Surrounding container for the list of next-hops within the next-hop-group."; list next-hop { key "index"; description "An individual next-hop within the next-hop-group. Each next-hop is a reference to an entry within the next-hop list."; leaf index { type leafref { path "../state/index"; } description "A reference to the index for the next-hop within the the next-hop-group."; } container state { config false; description "Operational state parameters related to a next-hop within the next-hop-group."; uses aft-nhg-nh-state; } // container state } // list next-hop } // container next-hops container conditional { description "When a system selects a next-hop-group based on conditions in addition to those specified in the referencing table entries (for example, DSCP is used in addition to the IPv4 destination prefix), these conditions are specified in the conditions list. Where such conditions exist, the next-hop-group MUST only specify next-hop-groups under the conditional list, and therefore MUST NOT specify any corresponding next-hops. The next-hop-groups that are referenced by any conditions MUST reference only next-hops and therefore MUST NOT be conditional themselves."; list condition { key "id"; description "A conditional next-hop-group that is used by the AFT entry. The conditions that are specified within the group are logically ANDed together. If a condition is a leaf-list field its contents are logically ORed."; leaf id { type leafref { path "../state/id"; } description "A reference to the identifier for the condition."; } container state { config false; description "Operational state parameters related to the conditional next-hop selection."; uses aft-nhg-conditional-state; } // container state container input-interfaces { description "The set of input interfaces that are required to be matched for the next-hop-group condition to be met. Each non-interface condition is logically ANDed with each member of the list -- i.e., interfaces in the list are logically ORed. If the input-interface list is empty, the condition applies to ALL input interfaces."; list input-interface { key "id"; description "The input interface that must be matched for the condition to be met."; leaf id { type leafref { path "../state/id"; } description "Reference to the unique ID assigned to the input interface within the conditions list."; } container state { config false; description "Operational state parameters that relate to the input interface."; uses aft-nhg-conditional-interface-state; } // container state } // list input-interface } // container input-interfaces } // list condition } // container conditional } // list next-hop-group } // container next-hop-groups } // grouping aft-next-hop-groups-structural grouping aft-nhg-state { description "Operational state parameters related to a next-hop-group."; leaf id { type uint64; description "A unique identifier for the next-hop-group. This index is not expected to be consistent across reboots, or reprogramming of the next-hop-group. When updating a next-hop-group, if the group is removed by the system or assigned an alternate identifier, the system should send telemetry notifications deleting the previous identifier. If the identifier of the next-hop-group is changed, all AFT entries that reference it must also be updated."; } leaf next-hop-group-name { type string; description "Where applicable, this leaf is a unique identifier string for the next-hop-group. It is an arbitrary name for the group, that is supported by vendors and is exposed for telemetry."; } leaf programmed-id { type uint64; description "In some routing protocols or route injection mechanisms it is possible to supply the ID of the next-hop-group via configuration or the protocol itself. In some systems, it may not be possible to use this same ID when returning the NHG via telemetry. This leaf reflects the ID of the next-hop group that was used by the original programming mechanism. This leaf allows a client to create an association between a programmed next-hop's original ID, and the ID that is extracted via telemetry as a key in the next-hop-group AFT list."; } leaf color { type uint64; description "An arbitrary colour that is used as an identifier for the next-hop group. Some next-hop resolutions may utilise the colour to select the particular next-hop-group that a routing entry should be resolved to. In this case, next-hop-group selection may be based on colour matches rather than the protocol specified next-hop. Regardless of whether the next-hop-group's specified colour is used to select an AFT's active forwarding entry, the next-hop-group referenced by an entry should be the currently active value. Next-hop-groups that are installed on the system through a protocol that allows injection of such entries (e.g., BGP using the SR-TE Policy SAFI, or gRPC-based RIB programming) should have the colour specified in the injecting protocol within this leaf."; } leaf backup-next-hop-group { type leafref { path "../../../next-hop-group/state/id"; } description "The backup next-hop-group for the current group. When all entries within the next-hop group become unusable, the backup next-hop group is used if specified."; } leaf backup-active { type boolean; default 'false'; description "Set to true if and only if the device no longer forwards traffic using the primary NextHops of this NextHopGroup and instead uses the specified backup-next-hop-group. This leaf should be set to false if the backup-next-hop-group is either unspecified or unused by the device."; } } // grouping aft-nhg-state grouping aft-nhg-nh-state { description "Operational state parameters relating to an individual next-hop within the next-hop-group."; leaf index { type leafref { path "../../../../../../next-hops/next-hop/state/index"; } description "A reference to the identifier for the next-hop to which the entry in the next-hop group corresponds."; } leaf weight { type uint64; description "The weight applied to the next-hop within the group. Traffic is balanced across the next-hops within the group in the proportion of weight/(sum of weights of the next-hops within the next-hop group)."; } } // grouping aft-nhg-nh-state grouping aft-nhg-conditional-state { description "Operational state parameters relating to the conditional selection of a next-hop group for an AFT entry."; leaf id { type uint64; description "A unique identifier for the conditional criteria."; } leaf-list dscp { type oc-inet:dscp; description "A set of DSCP values that must be matched by an input packet for the next-hop-group specified to be selected. A logical OR is applied across the DSCP values."; } leaf next-hop-group { type leafref { path "../../../../../next-hop-group/state/id"; } description "The next-hop-group that is used by the system for packets that match the criteria specified."; } } // grouping aft-nhg-conditional-state grouping aft-nhg-conditional-interface-state { description "Operational state parameters relating to the input-interface condition for a next-hop-group."; leaf id { type string; description "A unique reference for the input interface."; } uses oc-if:interface-ref-common; } // grouping aft-nhg-conditional-interface-state grouping aft-common-entry-counter-state { description "Counters relating to a forwarding entry"; leaf packets-forwarded { type oc-yang:counter64; description "The number of packets which have matched, and been forwarded, based on the AFT entry."; } leaf octets-forwarded { type oc-yang:counter64; description "The number of octets which have matched, and been forwarded, based on the AFT entry"; } } // grouping aft-common-entry-counter-state grouping aft-common-backup-entry-counter-state { description "Counters relating to a backup forwarding entry"; leaf packets-forwarded-backup { type oc-yang:counter64; description "The number of packets which have matched, and been forwarded, based on the AFT backup entry."; } leaf octets-forwarded-backup { type oc-yang:counter64; description "The number of octets which have matched, and been forwarded, based on the AFT backup entry"; } } // grouping aft-common-backup-entry-counter-state } // submodule openconfig-aft-common
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