Use advertise srv6 locator to enable the device to generate routes for a locator in the BGP IPv6 unicast routing table and advertise the routes to BGP peers.

Use undo advertise srv6 locator to delete routes for a locator from the BGP IPv6 unicast routing table.

Syntax

advertise srv6 locator locator-name [ route-policy route-policy-name ]

undo advertise srv6 locator locator-name

Default

The device does not generate routes for a locator in the BGP IPv6 unicast routing table.

Views

BGP IPv6 unicast address family view

Predefined user roles

network-admin

Parameters

locator-name: Specifies a locator by its name, a case-sensitive string of 1 to 31 characters.

route-policy route-policy-name: Specifies a routing policy by its name, a case-sensitive string of 1 to 63 characters. Only routes that match the routing policy can be generated in the BGP IPv6 unicast routing table for the locator. All routes for the locator can be generated in the BGP IPv6 unicast routing table in the following situations:

· You do not specify a routing policy when using this command.

· The specified routing policy does not exist.

· The specified routing policy does not contain if-match clauses.

Usage guidelines

Use this command in an inter-AS BGP network. This command enables the device to use BGP to advertise routes for a locator.

Repeat this command to enable the device to use BGP to advertise routes for multiple locators.

Examples

# Enable the device to generate routes for locator abc in the BGP IPv6 unicast routing table and advertise the routes to BGP peers.

<Sysname> system-view

[Sysname] bgp 100

[Sysname-bgp-default] address-family ipv6

[Sysname-bgp-default-ipv6] advertise srv6 locator abc

Related commands

display segment-routing ipv6 locator

locator

anycast enable

Use anycast enable to enable anycast for an SRv6 locator.

Use undo anycast enable to disable anycast for an SRv6 locator.

Syntax

anycast enable

undo anycast enable

Default

Anycast is disabled for an SRv6 locator.

Views

SRv6 locator view

Predefined user roles

network-admin

Usage guidelines

After you apply a locator to a routing protocol, the routing protocol will advertise the SRv6 SIDs in the locator. By default, the N-bit is set in the Flags field of the Locator TLV in routing protocol packets. The locator belongs to one SRv6 node. If you enable anycast for a locator, the A-bit is set in the Flags field of the Locator TLV in routing protocol packets. The locator is shared by a group of SRv6 nodes.

Examples

# Enable anycast for locator test1.

<Sysname> system-view

[Sysname] segment-routing ipv6

[Sysname-segment-routing-ipv6] locator test1 ipv6-prefix 100:: 64 static 32

[Sysname-segment-routing-ipv6-locator-test1] anycast enable

Related commands

locator

diffserv-mode

Use diffserv-mode to configure the SRv6 DiffServ mode.

Use undo diffserv-mode to restore the default.

Syntax

diffserv-mode { ingress { pipe service-class | short-pipe service-class | uniform } egress { pipe | short-pipe | uniform } | { pipe service-class | short-pipe service-class | uniform } }

undo diffserv-mode

Default

The SRv6 DiffServ mode is pipe in both the inbound and outbound directions. The value for the service-class argument is 0.

Views

SRv6 view

Predefined user roles

network-admin

Parameters

ingress: Specifies the inbound direction.

egress: Specifies the outbound direction.

pipe: Specifies the pipe mode.

short-pipe: Specifies the short-pipe mode.

uniform: Specifies the uniform mode.

service-class: Specifies a traffic class for packets that enters the SRv6 network from the IP network. The value range for the traffic class is 0 to 7. Values 0 to 7 represent traffic classes be, af1, af2, af3, af4, ef, cs6, and cs7, respectively.

Usage guidelines

The following SRv6 DiffServ modes are available:

· Pipe mode—When a packet enters the SRv6 network, the ingress node adds a new IPv6 header to the original packet. The ingress node ignores the IP precedence or DSCP value in the original packet and uses the value specified by using the service-class argument as the traffic class in the new IPv6 header. In the SRv6 network, SRv6 nodes perform QoS scheduling for the packet based on the specified traffic class. When the packet leaves the SRv6 network, the egress node removes the outer IPv6 header from the packet without modifying the IP precedence or DSCP value in the original packet.

· Short-pipe mode—When a packet enters and leaves the SRv6 network, all SRv6 nodes process the packet in the same way as in pipe mode except for the egress node. After the egress node removes the outer IPv6 header from the packet, it performs QoS scheduling as follows:

¡ If no priority trust mode is configured, the egress node performs QoS scheduling for the packet based on the IP precedence or DSCP value in the original packet.

¡ If a priority trust mode is configured, the egress node performs QoS scheduling for the packet based on the trusted priority.

· Uniform mode—When a packet enters the IPv6 network, the ingress node maps the IP precedence or DSCP value in the original IP header to the outer IPv6 header as the traffic class. When the packet leaves the SRv6 network, the egress node maps the traffic class value in the outer IPv6 header to the original packet as the IP precedence or DSCP value.

The accuracy changes when the DSCP value and traffic class value are mapped to each other.

To specify different DiffServ modes for the inbound and outbound directions, use the diffserv-mode command with the ingress and egress keywords. To specify the same DiffServ mode for the inbound and outbound directions, use the diffserv-mode command without the ingress or egress keyword.

If you execute the diffserv-mode command multiple times, the most recent configuration takes effect.

When you configure the SRv6 DiffServ mode on the source and destination nodes of an SRv6 tunnel, follow these restrictions and guidelines:

· The outbound DiffServ mode on the local end must be the same as the inbound DiffServ mode on the peer end.

· The inbound DiffServ mode on the local end must be the same as the outbound DiffServ mode on the peer end.

For more information about IP precedence and DSCP, see priority mapping configuration in QoS Configuration Guide.

Examples

# Configure the SRv6 DiffServ mode as uniform.

<Sysname> system-view

[Sysname] segment-routing ipv6

[Sysname-segment-routing-ipv6] diffserv-mode uniform

display bgp egress-engineering ipv6

Use display bgp egress-engineering ipv6 to display BGP-EPE information for IPv6 peers.

Syntax

display bgp [ instance instance-name ] egress-engineering ipv6 [ ipv6-address ] [ verbose ]

Views

Any view

Predefined user roles

network-admin

network-operator

Parameters

instance instance-name: Specifies a BGP instance by its name, a case-sensitive string of 1 to 31 characters. If you do not specify a BGP instance, this command displays information about the default BGP instance.

ipv6-address: Specifies an IPv6 peer by its IPv6 address. The specified IPv6 peer must already exist. If you do not specify an IPv6 peer, this command displays BGP-EPE information for all IPv6 peers.

verbose: Displays detailed BGP-EPE information. If you do not specify this keyword, the command displays only brief BGP-EPE information.

Examples

# Display BGP-EPE information for all IPv6 peers.

<Sysname> display bgp egress-engineering ipv6

BGP peering segment type: Node-Adjacency

Peer NodeAdj : 2::9

Local AS number : 100

Remote AS number : 200

Local router ID : 1.1.1.9

Remote router ID : 2.2.2.9

Interface : GE1/0/1

OriginalNextHop : 2::9

RelayNextHop : FE80::28B6:9EFF:FE23:206

Interface : GE1/0/2

OriginalNextHop : 2::9

RelayNextHop : FE80::28B6:9EFF:FE23:208

# Display detailed BGP-EPE information for all IPv6 peers.

<Sysname> display bgp egress-engineering ipv6 verbose

BGP peering segment type: Node-Adjacency

PeerAdj Num : 2

Nexthop : 2::9

Local AS number : 100

Remote AS number : 200

Local router ID : 1.1.1.9

Remote router ID : 2.2.2.9

Local interface address : 10::1

Remote interface address : 10::2

OriginalNextHop : 2::9

RelayNextHop : FE80::28B6:9EFF:FE23:206

SID(no PSP, no USP) : 200::1

SID(PSP) : 200::2

Local interface address : 20::1

Remote interface address : 20::2

OriginalNextHop : 2::9

RelayNextHop : FE80::28B6:9EFF:FE23:208

SID(no PSP, no USP) : 200::1

SID(PSP) : 200::2

BGP peering segment type : Adjacency

PeerAdj : FE80::28B6:9EFF:FE23:206

Local AS number : 100

Remote AS number : 200

Local router ID : 1.1.1.9

Remote router ID : 2.2.2.9

Local interface address : FE80::28B6:9EFF:FE23:D16

Remote interface address : FE80::28B6:9EFF:FE23:206

Interface : GE1/0/1

OriginalNextHop : 2::9

RelayNextHop : FE80::28B6:9EFF:FE23:206

SID(no PSP, no USP) : 200::3

SID(PSP) : 200::4

BGP peering segment type : Adjacency

PeerAdj : FE80::28B6:9EFF:FE23:208

Local AS number : 100

Remote AS number : 200

Local router ID : 1.1.1.9

Remote router ID : 2.2.2.9

Local interface address : FE80::28B6:9EFF:FE23:D18

Remote interface address : FE80::28B6:9EFF:FE23:208

Interface : GE1/0/2

OriginalNextHop : 2::9

RelayNextHop : FE80::28B6:9EFF:FE23:208

SID(no PSP, no USP) : 200::5

SID(PSP) : 200::6

Table 1 Command output

Field	Description
BGP peering segment type	BGP peering segment type of the peer: · Node—Node type. · Adjacency—Adjacency type. · Node-Adjacency—Node and adjacency type.
Peer Node	Address of the node-type peer.
Peer Adj	Address of the adjacency-type peer.
Peer NodeAdj	Address of the node- and adjacency-type peer.
PeerAdj Num	Number of adjacency-type peers.
Interface	Information about the interface used to establish peer relationship.
OriginalNextHop	IP address of the original next hop.
RelayNextHop	IP address of the recursed next hop.
SID(PSP)	End.X SID (PSP type).
SID(no PSP, no USP)	End.X SID (non-PSP and non-USP type).

display bgp egress-engineering srv6 peer-set

Use display bgp egress-engineering srv6 peer-set to display information about BGP-EPE SRv6 peer sets.

Syntax

display bgp [ instance instance-name ] egress-engineering srv6 peer-set [ srv6-peer-set-name ]

Views

Any view

Predefined user roles

network-admin

network-operator

Parameters

instance instance-name: Specifies a BGP instance by its name, a case-sensitive string of 1 to 31 characters. If you do not specify a BGP instance, this command displays BGP-EPE SRv6 peer set information for the default BGP instance.

peer-set-name: Specifies a BGP-EPE SRv6 peer set by its name, a case-sensitive string of 1 to 63 characters. If you do not specify a BGP-EPE SRv6 peer set, this command displays information about all BGP-EPE SRv6 peer sets.

Examples

# Display information about all BGP-EPE SRv6 peer sets.

<Sysname> display bgp egress-engineering srv6 peer-set

BGP egress peering segment srv6 peer-set: abc

StaticSID(PSP) : 210::11

StaticSID(no PSP, no USP): 210::12

SID(PSP) : 101::1:0:0

SID(no PSP, no USP) : 101::1:0:1

Members: 1

Peer: 4:4:4::4

Table 2 Command output

Field	Description
BGP egress peering segment srv6 peer-set	Name of a BGP-EPE SRv6 peer set.
StaticSID(PSP)	Manually configured End.X SID (PSP type).
StaticSID(no PSP, no USP)	Manually configured End.X SID (non-PSP and non-USP type).
SID(PSP)	End.X SID (PSP type).
SID(no PSP, no USP)	End.X SID (non-PSP and non-USP type).
Members	Number of peers in the BGP-EPE SRv6 peer set.
Peer	Peer in the BGP-EPE SRv6 peer set.

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display isis segment-routing ipv6 capability

Use display isis segment-routing ipv6 capability to display IS-IS SRv6 capability information.

Syntax

display isis segment-routing ipv6 capability [ level-1 | level-2 ] [ process-id ]

Views

Any view

Predefined user roles

network-admin

network-operator

Parameters

level-1: Specifies IS-IS Level-1.

level-2: Specifies IS-IS Level-2.

process-id: Specifies an IS-IS process by its ID, in the range of 1 to 65535. If you do not specify a process, this command displays SRv6 capability information for all IS-IS processes.

Usage guidelines

If you do not specify a level, this command displays IS-IS SRv6 capability information for both Level-1 and Level-2.

Examples

# Display SRv6 capability information for IS-IS process 1.

<Sysname> display isis segment-routing ipv6 capability level-1 1

IPv6 segment routing capability information for IS-IS(1)

Level-1 IPv6 segment routing capability

System ID SRv6 capability

0000.1000.0001 Enabled

0000.2000.0001 Enabled

0000.2000.0002 Enabled

0000.2000.0003 Enabled

Table 3 Command output

Field	Description
System ID	Neighbor system ID.
SRv6 capability	Whether SRv6 is enabled.

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display isis segment-routing ipv6 locator

Use display isis segment-routing ipv6 locator to display IS-IS SRv6 locator route information.

Syntax

display isis segment-routing ipv6 locator [ ipv6-address prefix-length ] [ flex-algo flex-algo-id | [ level-1 | level-2 ] | verbose ] * [ process-id ]

Views

Any view

Predefined user roles

network-admin

network-operator

Parameters

ipv6-address prefix-length: Specifies a destination IPv6 address prefix and the prefix length. The value range for the prefix-length argument is 1 to 128.

flex-algo flex-algo-id: Specifies a Flex-Algo by its ID, in the range of 128 to 255. If you do not specify a Flex-Algo, this command displays locator route information calculated by all Flex-Algos.

level-1: Specifies the level-1 area.

level-2: Specifies the level-2 area.

verbose: Displays detailed IS-IS SRv6 locator route information. If you do not specify this keyword, the command displays only brief IS-IS SRv6 locator route information.

process-id: Specifies an IS-IS process by its ID, in the range of 1 to 65535. If you do not specify a process, this command displays IS-IS SRv6 locator route information for all IS-IS processes.

Examples

# Display IS-IS SRv6 locator route information.

<Sysname> display isis segment-routing ipv6 locator

Route information for IS-IS(1)

------------------------------

Level-1 Locator Route Table

---------------------------

Destination : 201:: PrefixLen: 64

Flags : R/-/- Cost : 2

Next hop : FE80::38A5:3DFF:FEE9:218 Interface: GE1/0/1

Destination : 202:: PrefixLen: 64

Flags : R/-/- Cost : 1

Next hop : FE80::38A5:3DFF:FEE9:218 Interface: GE1/0/3

Flags: D-Direct, R-Added to Rib, L-Advertised in LSPs, U-Up/Down Bit Set

Table 4 Command output

Field	Description
Destination	Destination IPv6 prefix.
PrefixLen	Prefix length.
Flag/Flags	Route flags: · D—The route is a direct route. · R—The route has been flushed to the RIB. · L—The route has been advertised in LSPs. · U—Penetration flag. Setting it to UP can prevent an LSP sent from L2 to L1 from being sent back to L2.
Cost	Route cost value.
Next hop	Route next hop.
Interface	Output interface.

‌

# Display detailed IS-IS SRv6 locator route information.

<Sysname> display isis segment-routing ipv6 locator verbose

Route information for IS-IS(1)

------------------------------

Level-1 Locator Route Table

---------------------------

IPv6 dest : 5000::/64

Flag : D/L/- Cost : 0

Admin tag : - Src count : 1

Algorithm : 0

Priority : Low

Nexthop : Direct

NxthopFlag : -

Interface : NULL0 Delay Flag : N/A

Nib ID : 0x0

Flags: D-Direct, R-Added to Rib, L-Advertised in LSPs, U-Up/Down Bit Set

Level-2 Locator Route Table

---------------------------

IPv6 dest : 5000::/64

Flag : D/L/- Cost : 0

Admin tag : - Src count : 4

Algorithm : 0

Priority : Low

Nexthop : Direct

NxthopFlag : -

Interface : NULL0 Delay Flag : N/A

Nib ID : 0x0

Flags: D-Direct, R-Added to Rib, L-Advertised in LSPs, U-Up/Down Bit Set

Table 5 Command output

Field	Description
Route information for IS-IS(1)	Locator route information about the IS-IS proces.
Level-1 Locator Route Table	IS-IS Level-1 locator route information.
Level-2 Locator Route Table	IS-IS Level-2 locator route information.
IPv6 dest	Destination IPv6 prefix
Flag	Route state flag: · D—Direct route. · R—The route has been added into the routing table. · L—The route has been advertised in an LSP. · U—Route leaking flag, indicating that the Level-1 route is from Level-2. U means that the route will not be returned to Level-2.
Cost	Route cost.
Admin tag	Administrative tag.
Src count	Number of advertisement sources.
Algorithm	Flexible algorithm ID.
Priority	Route convergence priority: · Critical. · High. · Medium. · Low.
Next hop	Next hop. If the route is a direct route, this field displays Direct.
NxthopFlag	Next hop flag. Value D indicates that the next hop is the direct next hop of the advertisement source.
Interface	Output interface.
Delay Flag	Microloop avoidance delay flag: · D—Microloop avoidance is configured. Route convergence is delayed. · N/A—Microloop avoidance is not configured or the microloop avoidance delay timer has expired. Route convergence is in progress.
Nib ID	Next hop index assigned by the routing management module.

‌

display segment-routing ipv6 remote-locator

Use display segment-routing ipv6 remote-locator to display remote SRv6 locator information.

Syntax

display segment-routing ipv6 remote-locator [ remote-locator-name ]

Views

Any view

Predefined user roles

network-admin

network-operator

Parameters

remote-locator-name: Specifies a remote locator by its name, a case-sensitive string of 1 to 31 characters. If you do not specify a remote locator, this command displays information about all remote locators.

Examples

# Display information about all remote locators.

<Sysname> display segment-routing ipv6 remote-locator

Remote locator configuration table

Remote locator name : abc

IPv6 prefix : 100:1:: Prefix length : 64

Static length : 8 Args length : 8

Auto remote SID start : 100:1::1:0

Auto remote SID end : 100:1::FFFF:FFFF:FFFF:FF00

Static remote SID start : 100:1::100

Static remote SID end : 100:1::FF00

Table 6 Command output

Field	Description
IPv6 prefix	IPv6 address prefix of the remote locator.
Prefix length	Prefix length of the remote locator.
Static length	Static length of the remote locator.
Args length	Argument length.
Auto remote SID start	Start dynamic SRv6 SID. If no dynamic SRv6 SIDs exist, this field displays N/A.
Auto remote SID end	End dynamic SRv6 SID. If no dynamic SRv6 SIDs exist, this field displays N/A.
Static remote SID start	Start static SRv6 SID. If no static SRv6 SIDs exist, this field displays N/A.
Static remote SID end	End static SRv6 SID. If no static SRv6 SIDs exist, this field displays N/A.

‌

display segment-routing ipv6 remote-sid

Use display segment-routing ipv6 remote-sid to display remote SRv6 SID information .

Syntax

display segment-routing ipv6 remote-sid { end-dx2 | end-dx2l } [ sid ]

Views

Any view

Predefined user roles

network-admin

network-operator

Parameters

end-dx2: Specifies End.DX2 SIDs.

end-dx2l: Specifies End.DX2L SIDs.

sid: Specifies an SRv6 SID. If you do not specify an SRv6 SID, this command displays information about all remote SRv6 SIDs of the specified type.

Examples

# Display information about all remote SRv6 SIDs of the End.DX2 type.

<Sysname> display segment-routing ipv6 remote-sid end-dx2

Remote SID forwarding table (End.DX2)

Total remote SIDs: 1

SID : 100:1::100/64

Function type : End.DX2 Flavor : PSP

Xconnect-group: abc Connection : abc

VSI name : Service ID : 0

Interface :

Remote locator name: abc Allocation type: Static

Owner : L2VPN State : Active

Create Time : Jan 27 09:59:34.541 2022

# Display information about all remote SRv6 SIDs of the End.DX2L type.

<Sysname> display segment-routing ipv6 remote-sid end-dx2l

Remote SID forwarding table (End.DX2L)

Total remote SIDs: 1

SID : 200:1::100/64

Function type : End.DX2L Flavor : PSP

Xconnect-group: vpna Connection : a

VSI name : Service ID : 0

Interface :

Remote locator name: bbb Allocation type: Static

Owner : L2VPN State : Active

Create Time : Nov 15 20:36:04.528 2021

Table 7 Command output

Field	Description
SID	SRv6 SID.
Function type	SRv6 SID type: · End.DX2. · End.DX2L.
Flavor	SRv6 SID flavor type: · PSP—The penultimate SRv6 node removes the SRH. · NOPSP—The penultimate SRv6 node does not remove the SRH.
Xconnect group	Cross-connect group name.
Connection	Cross-connect name.
VSI name	VSI name.
Service ID	Ethernet service instance ID. If no Ethernet service instance ID exists, this field displays 0.
Interface	Output interface. If no output interface exists, this field displays 0.
Allocation type	SID allocation type: · Static—Manually configured. · Dynamic—Dynamically allocated.
Owner	Protocol that applies for the SID: L2VPN.
State	SID state: · Active. · Inactive.
Create Time	SID creation time.

‌

display isis segment-routing ipv6 sid-info conflict

Use display isis segment-routing ipv6 sid-info conflict to display information about conflicting SRv6 SIDs.

Syntax

display isis segment-routing ipv6 sid-info conflict [ sid-value ] [ level-1 | level-2 ] [ process-id ]

Views

Any view

Predefined user roles

network-admin

network-operator

Parameters

sid-value: Specifies an SRv6 SID.

level-1: Specifies the level-1 area.

level-2: Specifies the level-2 area.

process-id: Specifies an IS-IS process by its process ID in the range of 1 to 65535. If you do not specify an IS-IS process, this command displays information about conflicting SRv6 SIDs for all IS-IS processes.

Usage guidelines

If you do not specify any parameters, this command displays information about all conflicting SRv6 SIDs.

Examples

# Display information about all conflicting SRv6 SIDs.

<Sysname> display isis segment ipv6 sid-info conflict

Segment Routing IPv6 SID Conflict Information For IS-IS(1)

----------------------------------------------------------

Level-1 SID Conflict Information

--------------------------------

SID: 6:5::100

System ID=3333.3333.3333.00, Flag(A)=0, Function type=End with PSP

System ID=4444.4444.4444.00, Flag(A)=0, Function type=End with PSP

SID: 6:5::101

System ID=3333.3333.3333.00, Flag(A)=0, Function type=End (no PSP, no USP)

System ID=4444.4444.4444.00, Flag(A)=0, Function type=End (no PSP, no USP)

SID: 6:5::103

System ID=3333.3333.3333.00, Flag(A)=0, Function type=End.X (no PSP, no USP)

System ID=4444.4444.4444.00, Flag(A)=0, Function type=End.X (no PSP, no USP)

Table 8 Command output

Field	Description
SID	Conflicting SRv6 SID.
System ID	ID of the system that advertised the SID.
Flag (A)	Anycast flag (A flag). The value is 1 if this flag is set, which indicates that the SID is an anycast SID.
Function type	SID function type: · End (no PSP, no USP)—End SID, which is not removed on the penultimate segment or the ultimate segment. · End with PSP—End SID, which is removed on the penultimate segment. · End with USP—End SID, which is removed on the ultimate segment. · End with PSP&USP—End SID, which is removed on the penultimate segment and the ultimate segment. · End.X (no PSP, no USP)—End.X SID, which is not removed on the penultimate segment or the ultimate segment. · End.X with PSP—End.X SID, which is removed on the penultimate segment. · End.X with USP—End.X SID, which is removed on the ultimate segment. · End.X with PSP&USP—End.T SID, which is removed on the penultimate segment and the ultimate segment. · End.DT4—End.DT4 SID. · End.DT6—End.DT6 SID. · End.DT46—End.DT46 SID. · End with COC—End SID. · End with PSP&COC—End SID. · End with PSP&USP&COC—End SID. · End.X with COC—End.X SID. · End.X with PSP&COC—End.X SID. · End.X with PSP&USP&COC—End.X SID. · End with PSP&USD&COC—End SID. · End with PSP&USP&USD&COC—End SID. · End.X with PSP&USD&COC—End.X SID. · End.X with PSP&USP&USD&COC—End.X SID.

‌

display isis segment-routing ipv6 sid-info locator

Use display isis segment-routing ipv6 sid-info locator to display information about SRv6 SIDs advertised by IS-IS in a locator or all locators.

Syntax

Views

Any view

Predefined user roles

network-admin

network-operator

Parameters

ipv6-prefix prefix-length: Specifies a locator by its IPv6 prefix. The ipv6-prefix argument represents the IPv6 prefix address. The prefix-length argument represents the prefix length, in the range of 32 to 120.

end: Specifies End SIDs.

end-dt4: Specifies End.DT4 SIDs.

end-dt46: Specifies End.DT46 SIDs.

end-dt6: Specifies End.DT6 SIDs.

end-m: Specifies End.M SIDs.

end-x: Specifies End.X SIDs.

level-1: Specifies the level-1 area.

level-2: Specifies the level-2 area.

process-id: Specifies an IS-IS process by its process ID in the range of 1 to 65535. If you do not specify an IS-IS process, this command displays information about SRv6 SIDs in the specified locator for all IS-IS processes.

Usage guidelines

If you do not specify any parameters, this command displays information about SRv6 SIDs advertised by IS-IS in all locators.

Examples

# Display information about SRv6 SIDs advertised by level-1 IS-IS in all locators.

<Sysname> display isis segment ipv6 sid-info locator level-1

Segment Routing IPv6 SID Locator Information For IS-IS(1)

---------------------------------------------------------

Level-1 SID Information

-----------------------

Locator: 1:2::/96

System ID: 1111.1111.1111.00

Locator Info: Cost=0, Flag(D)=0, Flag(A)=0, Algorithm=0

SID: 1:2::1

Function Type: End.DT4

Neighbor ID: --

SID: 1:2::2

Function Type: End.DT6

Neighbor ID: --

SID: 1:2::3

Function Type: End.DT46

Neighbor ID: --

SID: 1:2::104

Function Type: End with PSP

Neighbor ID: --

SID: 1:2::105

Function Type: End (no PSP, no USP)

Neighbor ID: --

SID: 1:2::106

Function Type: End.X (no PSP, no USP)

Neighbor ID: 2222.2222.2222.00

SID: 1:2::107

Function Type: End.X with PSP

Neighbor ID: 2222.2222.2222.00

Table 9 Command output

Field	Description
System ID	ID of the system that advertised an SRv6 SID.
SID	SRv6 SID.
Locator Info	Locator information.
Cost	Locator TLV cost.
Flag (D)	Leaking flag (D flag). The value is 1 if this flag is set, which indicates that locator TLVs cannot be leaked from Level-1 to Level-2.
Flag (A)	Anycast locator flag (A flag). The value is 1 if this flag is set, which indicates that the locator is an anycast locator.
Algorithm	ID of the algorithm associated with the SRv6 locator: · 0—SPF algorithm. · 128 to 255—Flex-Algo algorithm.
Function type	SID function type: · End (no PSP, no USP)—End SID, which is not removed on the penultimate segment or the ultimate segment. · End with PSP—End SID, which is removed on the penultimate segment. · End with USP—End SID, which is removed on the ultimate segment. · End with PSP&USP—End SID, which is removed on the penultimate segment and the ultimate segment. · End.X (no PSP, no USP)—End.X SID, which is not removed on the penultimate segment or the ultimate segment. · End.X with PSP—End.X SID, which is removed on the penultimate segment. · End.X with USP—End.X SID, which is removed on the ultimate segment. · End.X with PSP&USP—End.T SID, which is removed on the penultimate segment and the ultimate segment. · End.DT4—End.DT4 SID. · End.DT6—End.DT6 SID. · End.DT46—End.DT46 SID. · End with COC—End SID. · End with PSP&COC—End SID. · End with PSP&USP&COC—End SID. · End.X with COC—End.X SID. · End.X with PSP&COC—End.X SID. · End.X with PSP&USP&COC—End.X SID. · End with PSP&USD&COC—End SID. · End with PSP&USP&USD&COC—End SID. · End.X with PSP&USD&COC—End.X SID. · End.X with PSP&USP&USD&COC—End.X SID.
Neighbor ID	Neighbor ID. This field displays a value only for an End.X SID. For other SRv6 SIDs, this field displays two hyphens (--).

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display isis segment-routing ipv6 sid-info sid

Use display isis segment-routing ipv6 sid-info sid to display information about SRv6 SIDs advertised by IS-IS.

Syntax

Views

Any view

Predefined user roles

network-admin

network-operator

Parameters

sid-value: Specifies an SRv6 SID.

end: Specifies End SIDs.

end-dt4: Specifies End.DT4 SIDs.

end-dt46: Specifies End.DT46 SIDs.

end-dt6: Specifies End.DT6 SIDs.

end-m: Specifies End.M SIDs

end-x: Specifies End.X SIDs.

level-1: Specifies the level-1 area.

level-2: Specifies the level-2 area.

process-id: Specifies an IS-IS process by its process ID in the range of 1 to 65535. If you do not specify an IS-IS process, this command displays information about SRv6 SIDs for all IS-IS processes.

Usage guidelines

If you do not specify any parameters, this command displays information about all SRv6 SIDs advertised by IS-IS.

Examples

# Display information about all SRv6 SIDs advertised by level-1 IS-IS.

<Sysname> display isis segment-routing ipv6 sid-info sid level-1

Segment Routing IPv6 SID Information For IS-IS(1)

-------------------------------------------------

Level-1 SID Information

-----------------------

SID: 1:2::1

Flag(A): 0

Function Type: End.DT4

System ID: 1111.1111.1111.00

Neighbor ID: --

SID: 1:2::2

Flag(A): 0, Function Type: End.DT6

System ID: 1111.1111.1111.00

Neighbor ID: --

SID: 1:2::3

Flag(A): 0, Function Type: End.DT46

System ID: 1111.1111.1111.00

Neighbor ID: --

SID: 1:2::105

Flag(A): 0, Function Type: End (no PSP, no USP)

System ID: 1111.1111.1111.00

Neighbor ID: --

SID: 1:2::106

Flag(A): 0, Function Type: End.X (no PSP, no USP)

System ID: 1111.1111.1111.00

Neighbor ID: 2222.2222.2222.00

Table 10 Command output

Field	Description
SID	SRv6 SID advertised by IS-IS
Flag (A)	Anycast locator flag (A flag). The value is 1 if this flag is set, which indicates that the locator is an anycast locator.
Function type	SID function type: · End (no PSP, no USP)—End SID, which is not removed on the penultimate segment or the ultimate segment. · End with PSP—End SID, which is removed on the penultimate segment. · End with USP—End SID, which is removed on the ultimate segment. · End with PSP&USP—End SID, which is removed on the penultimate segment and the ultimate segment. · End.X (no PSP, no USP)—End.X SID, which is not removed on the penultimate segment or the ultimate segment. · End.X with PSP—End.X SID, which is removed on the penultimate segment. · End.X with USP—End.X SID, which is removed on the ultimate segment. · End.X with PSP&USP—End.T SID, which is removed on the penultimate segment and the ultimate segment. · End.DT4—End.DT4 SID. · End.DT6—End.DT6 SID. · End.DT46—End.DT46 SID. · End with COC—End SID. · End with PSP&COC—End SID. · End with PSP&USP&COC—End SID. · End.X with COC—End.X SID. · End.X with PSP&COC—End.X SID. · End.X with PSP&USP&COC—End.X SID. · End with PSP&USD&COC—End SID. · End with PSP&USP&USD&COC—End SID. · End.X with PSP&USD&COC—End.X SID. · End.X with PSP&USP&USD&COC—End.X SID.
System ID	ID of the system that advertised the SRv6 SID.
Neighbor ID	Neighbor ID. This field displays a value only for an End.X SID. For other SRv6 SIDs, this field displays two hyphens (--).

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display isis segment-routing ipv6 sid-info statistics

Use display isis segment-routing ipv6 sid-info statistics to display SRv6 SID statistics.

Syntax

display isis segment-routing ipv6 sid-info statistics [ system-id system-id ] [ level-1 | level-2 ] [ process-id ]

Views

Any view

Predefined user roles

network-admin

network-operator

Parameters

system-id system-id: Specifies an advertisement source by its system ID.

level-1: Specifies the level-1 area.

level-2: Specifies the level-2 area.

process-id: Specifies an IS-IS process by its process ID in the range of 1 to 65535. If you do not specify an IS-IS process, this command displays SRv6 SID statistics for all IS-IS processes.

Usage guidelines

If you do not specify any parameters, this command displays all SRv6 SID statistics.

Examples

# Display all SRv6 SID statistics.

<Sysname> display isis segment-routing ipv6 sid-info statistics

Segment Routing IPv6 SID Statistic Information For IS-IS(1)

-----------------------------------------------------------

Level-1 SID Statistic Information

---------------------------------

System ID: 3333.3333.3333.00

Locator: 6:5::/96

End=2, End.X=0, End.M=0, End.DT4=0, End.DT6=0, End.DT46=0

Total advertised SIDs:

End=2, End.X=0, End.M=0, End.DT4=0, End.DT6=0, End.DT46=0

System ID: 1111.1111.1111.00

Locator: 1:2::/96

End=2, End.X=2, End.M=0, End.DT4=3, End.DT6=3, End.DT46=1

Total advertised SIDs:

End=2, End.X=2, End.M=0, End.DT4=3, End.DT6=3, End.DT46=1

Table 11 Command output

Field	Description
System ID	ID of the system that advertised SRv6 SIDs.
Locator	Locator of the SRv6 SIDs.
End	Number of advertised End SIDs.
End.X	Number of advertised End.X SIDs.
End.M	Number of advertised End.M SIDs.
End.DT4	Number of advertised End.DT4 SIDs.
End.DT6	Number of advertised End.DT6 SIDs.
End.DT46	Number of advertised End.DT46 SIDs.
Total advertised SIDs	Total number of advertised SRv6 SIDs.

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display isis segment-routing ipv6 sid-info system-id

Use display isis segment-routing ipv6 sid-info system-id to display information about SRv6 SIDs advertised from an advertisement source or all advertisement sources.

Syntax

Views

Any view

Predefined user roles

network-admin

network-operator

Parameters

system-id: Specifies an advertisement source by its system ID.

end: Specifies End SIDs.

end-dt4: Specifies End.DT4 SIDs.

end-dt46: Specifies End.DT46 SIDs.

end-dt6: Specifies End.DT6 SIDs

end-m: Specifies End.M SIDs.

end-x: Specifies End.X SIDs.

level-1: Specifies the level-1 area.

level-2: Specifies the level-2 area.

process-id: Specifies an IS-IS process by its process ID in the range of 1 to 65535. If you do not specify an IS-IS process, this command displays information about SRv6 SIDs advertised from the specified advertisement source for all IS-IS processes.

is-name isname: Specifies a host by its name, a case-insensitive string of 1 to 64 characters.

Usage guidelines

If you do not specify any parameters, this command displays information about SRv6 SIDs advertised from all advertisement sources.

Examples

# Display information about SRv6 SIDs advertised from 0000.0000.0001.

<Sysname> display isis segment ipv6 sid-info system-id 0000.0000.0001

Segment Routing IPv6 SID System ID Information For IS-IS(1)

-----------------------------------------------------------

Level-1 SID Information

-----------------------

System id: 0000.0000.0001

Locator: 1:2::/96

Cost=0, Flag(D)=0,Flag(A)=0, Algorithm=0

SID: 1:2::1

Function Type: End.DT4

Neighbors ID: --

SID: 1:2::2

Function Type: End.DT6

Neighbors ID: --

SID: 1:2::3

Function Type: End.DT46

Neighbors ID: --

SID: 1:2::104

Function Type: End with PSP

Neighbors ID: --

SID: 1:2::105

Function Type: End (no PSP, no USP)

Neighbors ID: --

SID: 1:2::106

Function Type: End.X (no PSP, no USP)

Neighbors ID: 2222.2222.2222.00

SID: 1:2::107

Function Type: End.X with PSP

Neighbors ID: 2222.2222.2222.00

Table 12 Command output

Field	Description
Cost	Locator TLV cost.
Flag (D)	Leaking flag (D flag). The value is 1 if this flag is set, which indicates that locator TLVs cannot be leaked from Level-1 to Level-2.
Flag (A)	Anycast locator flag (A flag). The value is 1 if this flag is set, which indicates that the locator is an anycast locator.
Algorithm	ID of the algorithm associated with the SRv6 locator: · 0—SPF algorithm. · 128 to 255—Flex-Algo algorithm.
SID	SRv6 SID.
Function type	SID function type: · End (no PSP, no USP)—End SID, which is not removed on the penultimate segment or the ultimate segment. · End with PSP—End SID, which is removed on the penultimate segment. · End with USP—End SID, which is removed on the ultimate segment. · End with PSP&USP—End SID, which is removed on the penultimate segment and the ultimate segment. · End.X (no PSP, no USP)—End.X SID, which is not removed on the penultimate segment or the ultimate segment. · End.X with PSP—End.X SID, which is removed on the penultimate segment. · End.X with USP—End.X SID, which is removed on the ultimate segment. · End.X with PSP&USP—End.T SID, which is removed on the penultimate segment and the ultimate segment. · End.DT4—End.DT4 SID. · End.DT6—End.DT6 SID. · End.DT46—End.DT46 SID. · End with COC—End SID. · End with PSP&COC—End SID. · End with PSP&USP&COC—End SID. · End.X with COC—End.X SID. · End.X with PSP&COC—End.X SID. · End.X with PSP&USP&COC—End.X SID. · End with PSP&USD&COC—End SID. · End with PSP&USP&USD&COC—End SID. · End.X with PSP&USD&COC—End.X SID. · End.X with PSP&USP&USD&COC—End.X SID.
Neighbor ID	Neighbor ID. This field displays a value only for an End.X SID. For other SRv6 SIDs, this field displays two hyphens (--).

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display ospfv3 segment-routing ipv6 capability

Use display ospfv3 segment-routing ipv6 capability to display OSPFv3 SRv6 capability information.

Syntax

display ospfv3 [ process-id ] segment-routing ipv6 capability

Views

Any view

Predefined user roles

network-admin

network-operator

Parameters

process-id: Specifies an OSPFv3 process by its ID, in the range of 1 to 65535. If you do not specify a process, this command displays SRv6 capability information for all OSPFv3 processes.

Examples

# Display SRv6 capability information for all OSPFv3 processes.

<Sysname> display ospfv3 segment-routing ipv6 capability

OSPFv3 Process 1 with Router ID 1.1.1.1

Area 0.0.0.0

------------------------------------------------------------------------

Router ID SRv6 capability

2.2.2.2 Enabled

Table 13 Command output

Field	Description
Router ID	Device router ID.
SRv6 capability	Whether SRv6 is enabled. The value can only be Enabled.

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display ospfv3 segment-routing ipv6 locator

Use display ospfv3 segment-routing ipv6 locator to display OSPFv3 SRv6 locator information.

Syntax

display ospfv3 [ process-id ] segment-routing ipv6 locator [ ipv6-address prefix-length ]

Views

Any view

Predefined user roles

network-admin

network-operator

Parameters

process-id: Specifies an OSPFv3 process by its ID, in the range of 1 to 65535. If you do not specify an OSPFv3 process, this command displays locator information for all OSPFv3 processes.

ipv6-address prefix-length: Specifies an IPv6 address prefix and the prefix length. The ipv6-address argument represents the IPv6 address prefix. The prefix-length argument represents the prefix length, in the range of 32 to 120. If you do not specify this option, the command displays locator information for all IPv6 prefixes.

Examples

# Display locator information for all OSPFv3 processes.

<Sysname> display ospfv3 segment-routing ipv6 locator

OSPFv3 Process 1 with Router ID 1.1.1.1

-------------------------------------------------------------------------

I - Intra area route, E1 - Type 1 external route, N1 - Type 1 NSSA route

IA - Inter area route, E2 - Type 2 external route, N2 - Type 2 NSSA route

* - Selected route

*Destination: 192:168::12:0/120

Type : I Area : 0.0.0.0

AdvRouter : 2.2.2.2 Preference : 10

NibID : 0x23000002 Cost : 10

Interface : GE1/0/1 BkInterface: N/A

Nexthop : ::

BkNexthop : N/A

Status : Direct

Table 14 Command output

Field	Description
Destination	Destination network.
Type	Route type.
Area	Area ID.
AdvRouter	ID of the router that advertises LSAs.
Preference	Route preference.
NibID	ID of the next hop information in the route.
Cost	Route cost.
Interface	Output interface.
BkInterface	Backup output interface.
Nexthop	Next hop address.
BkNexthop	Backup next hop address.
Status	Route state: · Local—The route is a local route and has not been sent to the route management module. · Invalid—The next hop of the route is invalid. · Stale—The next hop of the route is stale. · Normal—The route is usable. · Delete—The route is deleted. · Direct—The route is a direct route. · Rely—The route is recursed by another route.

display segment-routing ipv6 available-static-sid

Use display segment-routing ipv6 available-static-sid to display available static SRv6 SIDs in a locator.

Syntax

display segment-routing ipv6 available-static-sid locator locator-name [ from begin-value ]

Views

Any view

Predefined user roles

network-admin

network-operator

Parameters

locator locator-name: Specifies a locator by its name, a case-sensitive string of 1 to 31 characters.

from begin-value: Specifies available static SRv6 SIDs that start from the specified value. The begin-value argument represents the start value in IPv6 address format. If you do not specify a start value, this command displays available static SRv6 SIDs starting from the smallest available one.

Usage guidelines

If you specify a static length when configuring an SRv6 locator, the device can allocate static SRv6 SIDs from the locator. Use this command to display a maximum of 10 available static SRv6 SIDs in the locator.

To specify the from begin-value option, you must first identify the static SID range of the locator. For this purpose, use the display segment-routing ipv6 locator command.

Examples

# Display available static SRv6 SIDs in COC-both locator test3.

<Sysname> display segment-routing ipv6 available-static-sid locator test3

Available static SRv6 SID table

300:F8:4A::100

300:F8:4A::200

300:F8:4A::300

300:F8:4A::400

300:F8:4A::500

300:F8:4A::600

300:F8:4A::700

300:F8:4A::800

300:F8:4A::900

300:F8:4A::A00

Available static SRv6 CSID table

300:F8:4A:0:1::

300:F8:4A:0:2::

300:F8:4A:0:3::

300:F8:4A:0:4::

300:F8:4A:0:5::

300:F8:4A:0:6::

300:F8:4A:0:7::

300:F8:4A:0:8::

300:F8:4A:0:9::

300:F8:4A:0:A::

Table 15 Command output

Field	Description
Available static SRv6 SID table	Available static SRv6 SIDs.
Available static SRv6 CSID table	Available static compressible SRv6 SIDs.
N/A	No static SRv6 SIDs are available.

Related commands

display segment-routing ipv6 locator

display segment-routing ipv6 brief

Use display segment-routing ipv6 brief to display brief SRv6 information.

Syntax

display segment-routing ipv6 brief

Views

Any view

Predefined user roles

network-admin

network-operator

Examples

# Display brief SRv6 information.

<Sysname> display segment-routing ipv6 brief

Current SRv6 info:

Flavor mode: NO-PSP

SRv6 info at next reboot:

Flavor mode: NO-PSP

SRv6 TE FRR: Disabled

SRH flag check: Disabled

Encapsulation source-address: -

TTL mode: pipe

Path MTU: 1500

Path MTU reserved: 0

SRv6 compression: Disabled

Diffserv mode info:

Ingress mode: -

Engress mode: -

Service class: 0

SRv6 SBFD: Disabled

End.X update-delay time: 100 ms

Table 16 Command output

Field	Description
Current SRv6 info	Current effective SRv6 information.
SRv6 info at the next reboot	SRv6 information that will take effect at the next startup.
Flavor mode	SRv6 SID flavor: · PSP—The penultimate SRv6 node removes the SRH. · NO-PSP—The penultimate SRv6 node does not remove the SRH.
SRv6 TE FRR	SRv6 TEE FRR status: · Disabled. · Enabled. · Downgrade—Switched to SRv6 BE FRR.
SRH flag check	SRH flag check status: · Disabled. · Enabled.
Encapsulated source address	Source IP address in the IPv6 header encapsulated by SRv6.
IP TTL	TTL value in the IPv6 header encapsulated by SRv6.
TTL mode	TTL handling mode of the SRv6 TE policy: · pipe—Pipe mode. · uniform—Uniform mode.
Path MTU	Path MTU value for SRv6.
Path MTU reserved	Global reserved path MTU for SRv6.
SRv6 compression	SRv6 compression status: · Disabled. · Enabled.
Diffserv mode info	SRv6 DiffServ mode.
Ingress mode	SRv6 DiffServ mode in the inbound direction: · pipe—Pipe mode. · short-pipe—Short-pipe mode. · uniform—Uniform mode. If SRv6 DiffServ mode in the inbound direction is not configured, this field displays a hyphen (-).
Engress mode	SRv6 DiffServ mode in the outbound direction: · pipe—Pipe mode. · short-pipe—Short-pipe mode. · uniform—Uniform mode. If SRv6 DiffServ mode in the outbound direction is not configured, this field displays a hyphen (-).
Service class	Traffic class for packets entering the SRv6 network from a common IP network.
SRv6 SBFD	SBFD status for SRv6: · Disabled. · Enabled.
End.X update-delay time	Delay time to flush static End.X SIDs to the FIB, in milliseconds.

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display segment-routing ipv6 forwarding

Use display segment-routing ipv6 forwarding to display SRv6 forwarding entry information.

Syntax

display segment-routing ipv6 forwarding [ entry-id [ relation ] | forwarding-type { srv6be | srv6pcpath | srv6pgroup | srv6policy | srv6sfc | srv6sidlist | srv6sids } ] [ slot slot-number ]

Views

Any view

Predefined user roles

network-admin

network-operator

Parameters

entry-id: Specifies an SRv6 forwarding entry by its ID. The value range for this argument is 0 to 4294967294.If you do not specify an SRv6 forwarding entry ID, this command displays information about all SRv6 forwarding entries.

relation: Displays information about entries associated with the specified entry.

forwarding-type: Specifies a forwarding type. If you do not specify a forwarding type, this command displays SRv6 forwarding information for all forwarding types.

srv6be: Specifies tunnels in SRv6 BE paths.

srv6pcpath: Specifies tunnels in SRv6 TE policy candidate paths.

srv6pgroup: Specifies tunnels in SRv6 TE policy groups.

srv6policy: Specifies tunnels in SRv6 TE policies.

srv6sfc: Specifies tunnels in SRv6 SFCs.

srv6psidlist: Specifies tunnels defined by SID lists in SRv6 TE policies.

srv6sids: Specifies tunnels matching SRv6 SIDs.

slot slot-number: Specifies a card by its slot number. If you do not specify a card, this command displays SRv6 forwarding entries on the active MPU.

Examples

# Display all SRv6 forwarding entries.

<Sysname> display segment-routing ipv6 forwarding

Total SRv6 forwarding entries: 4

Flags: T – Forwarded through a tunnel

N – Forwarded through the outgoing interface to the nexthop IP address

A - Active forwarding information

B – Backup forwarding information

ID FWD-Type Flags Forwarding info

Attri-Val Attri-Val

--------------------------------------------------------------------------------

2148532225 SRv6PSIDList NA GE1/0/1

FE80::54CB:70FF:FE86:316

{6000::1, 7000::1, 8000::1}

2149580801 SRv6PCPath TA 2148532225

2150629377 SRv6Policy TA 2149580801

Policy10

2153775105 SRv6SFC NA GE1/0/1

FE80::54CB:70FF:FE86:316

{6000::1, 7000::1, 8000::1}

Table 17 Command output

Field	Description
FWD-Type	Tunnel forwarding type: · SRv6PSIDs—Tunnel established based on SRv6 SIDs. · SRv6PSIDList—Tunnel established based on the SID list in an SRv6 TE policy. · SRv6PCPath—Tunnel established on the candidate path selected by an SRv6 TE policy. · SRv6Policy—SRv6 TE policy tunnel. · SRv6PGroup—SRv6 TE policy group tunnel. · SRv6BE—Tunnel corresponding to the next hop in an SRv6 multi-level primary and secondary scenario or a multiple-primary and one-secondary scenario. · SRv6SFC—SRv6 service chain static proxy tunnel.
Flags	Forwarding flags: · T—Tunnel forwarding. · N—Output interface or next hop forwarding. · A—Active forwarding information. · B—Backup forwarding information. · S—Secondary backup forwarding information.
Forwarding info	SRv6 forwarding information. · For the N forwarding flag, the forwarding information includes the output interface, next hop, and SID list. A SID in [xx:xx, xx:xx, xx:xx, xx:xx], [xx:xx, xx:xx, xx:xx], [xx:xx, xx:xx], or [xx:xx] format is composed of G-SIDs, where xx:xx represents a G-SID. Only the 32-bit G-SID compression mode (cos32) is supported, so such a SID can contain a maximum of four G-SIDs, listed in ascending order by SI. · For the T forwarding flag, the forwarding information is the SRv6 forwarding entry ID.
Attri-Val	Forwarding attribute. In the current software version, the value is an SRv6 TE policy name. This field is available only when the value for the FWD-Type field is SRv6Policy or SRv6PGroup.

‌

display segment-routing ipv6 local-sid

Use display segment-routing ipv6 local-sid to display information about the SRv6 local SID forwarding table.

Syntax

display segment-routing ipv6 local-sid [ locator locator-name ] [ end-x | end-x-coc-none | end-x-coc32 ] [ sid | interface interface-type interface-number [ nexthop nexthop-ipv6-address ] ] [ owner owner ]

Views

Any view

Predefined user roles

network-admin

network-operator

Parameters

locator locator-name: Specifies a locator by its name, a case-sensitive string of 1 to 31 characters. If you do not specify a locator, this command displays information about the SRv6 local SID forwarding table for all locators.

end: Specifies End SIDs.

end-am: Specifies End.AM SIDs.

end-as: Specifies End.AS SIDs.

end-b6encaps: Specifies End.B6ENCAPS SIDs.

end-b6encapsred: Specifies End.B6ENCAPSRED SIDs.

end-b6insert: Specifies End.B6INSERT SIDs.

end-b6insertred: Specifies End.B6INSERTRED SIDs.

end-coc-none: Specifies End (COCNONE) SIDs.

end-coc32: Specifies End (COC32) SIDs.

end-dt2m: Specifies End.DT2M SIDs.

end-dt2u: Specifies End.DT2U SIDs.

end-dt2ul: Specifies End.DT2UL SIDs.

end-dt4: Specifies End.DT4 SIDs.

end-dt46: Specifies End.DT46 SIDs.

end-dt6: Specifies End.DT6 SIDs.

end-dx2: Specifies End.DX2 SIDs.

end-dx2l: Specifies End.DX2L SIDs.

end-dx4: Specifies End.DX4 SIDs.

end-dx6: Specifies End.DX6 SIDs.

end-m: Specifies End.M SIDs.

end-op: Specifies End.OP SIDs.

end-t: Specifies End.T SIDs.

end-x: Specifies End.X SIDs.

end-x-coc-none: Specifies End.X (COCNONE) SIDs.

end-x-coc32: Specifies End.X (COC32) SIDs.

sid: Specifies an SRv6 SID. If you do not specify an SRv6 SID, this command displays SRv6 local forwarding table information for all SRv6 SIDs of the specified type.

vpn-instance vpn-instance-name: Specifies the MPLS L3VPN instance to which the SRv6 SIDs belong. The vpn-instance-name argument is a case-sensitive string of 1 to 31 characters. If you do not specify this option, the command displays SRv6 local SID forwarding table information in the public network.

interface interface-type interface-number: Specifies an output interface by its type and number. If you do not specify an output interface, the command displays SRv6 local SID forwarding table information for all End.X SIDs.

nexthop nexthop-ipv6-address: Specifies the IPv6 address of a next hop. If you do not specify a next hop, the command displays SRv6 local SID forwarding table information for all IPv6 next hops.

owner owner: Specifies a protocol. The value for the owner argument is case insensitive. The supported values include SIDMGR, BGP, SRPolicy, IS-IS, OSPFv3, and L2VPN. If you do not specify a protocol, this command displays information about the SRv6 local SID forwarding table for all protocols.

Examples

# Display SRv6 local forwarding table information for all End SIDs.

<Sysname> display segment-routing ipv6 local-sid end

Local SID forwarding table (End)

Total SIDs: 1

SID : 100::64/96

Function type : End Flavor : NO-FLAVOR

Locator name : abc Allocation type: Static

Owner : SIDMGR State : Active

Flags : F

Create Time : May 19 17:21:15.687 2020

# Display SRv6 local forwarding table information for all End.X SIDs.

<Sysname> display segment-routing ipv6 local-sid end-x

Local SID forwarding table (End.X)

Total SIDs: 1

SID : 1000:0:0:15::/32

Function type : End.X Flavor : NO-FLAVOR

Interface : GE1/0/1 Interface index: 0x102

Next hop : FE80::1 Allocation type: Static

Locator name : abc

Owner : SIDMGR State : Active

Flags : F

Create Time : May 19 17:21:46.740 2020

# Display SRv6 local forwarding table information for all End.X SIDs. (With different output interfaces and nexthops for the same opcode.)

<Sysname> display segment-routing ipv6 local-sid end-x

Local SID forwarding table (End.X)

Total SIDs: 1

SID : 100:1::A/80

Function type : End.X Flavor : PSP

Locator name : abc Allocation type: Static

Flag : - State : Active

Owner : SIDMGR Paths : 2

Path Index : 1

Interface : GE1/0/1 Interface index: 0x1

Next hop : 1::1 Weight : 1

Create Time : May 20 07:23:47.355 2022

Path Index : 2

Interface : GE1/0/2 Interface index: 0x2

Next hop : 2::2 Weight : 1

Create Time : May 20 07:23:58.697 2022

# Display SRv6 local forwarding table information for all End.DT4 SIDs.

<Sysname> display segment-routing ipv6 local-sid end-dt4

Local SID forwarding table (End.DT4)

Total SIDs: 1

SID : 6:5::1:1/120

Function type : End.DT4 Flavor : PSP

VPN instance : vpn1 Allocation type: Static

Network type : MPLS L3VPN

Locator name : abc

Owner : SIDMGR State : Active

Flags : F

Create Time : May 19 17:22:27.356 2020

# Display SRv6 local forwarding table information for all End.DT6 SIDs.

<Sysname> display segment-routing ipv6 local-sid end-dt6

Local SID forwarding table (End.DT6)

Total SIDs: 1

SID : 1:2::2:2/120

Function type : End.DT6 Flavor : PSP

VPN instance : vpn1 Allocation type: Static

Network type : MPLS L3VPN

Locator name : abc

Owner : SIDMGR State : Active

Flags : F

Create Time : May 19 17:22:27.356 2020

# Display SRv6 local forwarding table information for all End.OP SIDs.

<Sysname> display segment-routing ipv6 local-sid end-op

Local SID forwarding table (End.OP)

Total SIDs: 1

SID : 100::190/96

Function type : End.OP

Locator name : abc

Owner : SIDMGR State : Active

Flags : F

Create Time : May 19 17:23:40.248 2020

# Display SRv6 local forwarding table information for all End.DX2 SIDs.

<Sysname> display segment-routing ipv6 local-sid end-dx2

Local SID forwarding table (End.DX2)

Total SIDs: 1

SID : 100:1:2:3::6400/96

Function type : End.DX2 Flavor : PSP

Xconnect-group: abc Connection : test

VSI name : Service ID : 0

Interface :

Locator name : abc Allocation type: Static

Owner : SIDMGR State : Active

Flags : F

Create Time : May 20 09:17:58.995 2020

# Display SRv6 local forwarding table information for all End.DT2U SIDs.

<Sysname> display segment-routing ipv6 local-sid end-dt2u

Local SID forwarding table (End.DT2U)

Total SIDs: 1

SID : 100:1:2:3::C800/96

Function type : End.DT2U Flavor : PSP

VSI name : abc Allocation type: Static

Locator name : abc

Owner : SIDMGR State : Active

Flags : F

Create Time : May 20 09:18:14.504 2020

# Display SRv6 local forwarding table information for End.AS SIDs in Layer 2 encapsulation forwarding scenario.

<Sysname> display segment-routing ipv6 local-sid end-as

Local SID forwarding table (End.AS)

Total SIDs: 1

SID : 100:1:2:3::C800/96

Function type : End.AS Allocation type: Static

Locator name : abc Forward type : L2

Inner type : IPv4 Source address : 2::60

Backup SID : 1::AA Peer SID : 300::3

Bypass : Enabled Bypass SID : 5::9

TTL mode : Uniform TTL value : -

Diffserv mode : Uniform Service class : -

Color : - Cache SL : 2

Cache list :

4::3

7::8

8::9

1::16::9

Encapsulation count: 2

Out-interface: GE1/0/1 In-interface : GE1/0/1

Out-S-VLAN : 100 Out-C-VLAN : -

In-S-VLAN : 200 In-C-VLAN : -

Dest MAC : 0056-00aa-00cb

Out-interface: GE1/0/2 In-interface : GE1/0/1

Out-S-VLAN : 101 Out-C-VLAN : -

In-S-VLAN : 201 In-C-VLAN : -

Dest MAC : 0056-00aa-00cd

Owner : SIDMGR State : Active

Flags : F

Create Time : May 19 17:21:15.687 2020

# Display SRv6 local forwarding table information for End.AS SIDs in Layer 3 encapsulation forwarding scenario.

<Sysname> display segment-routing ipv6 local-sid end-as

Local SID forwarding table (End.AS)

Total SIDs: 1

SID : 100:1:2:3::C800/96

Function type : End.AS Allocation type: Static

Locator name : abc Forward type : L3

Inner type : IPv4 Source address : 2::60

Backup SID : 1::AA Peer SID : 300::3

Bypass : Enabled Bypass SID : 5::9

TTL mode : Uniform TTL value : -

Diffserv mode : Uniform Service class : -

Color : - Cache-SL : 2

Cache list :

4::3

7::8

8::9

1::16::9

Encapsulation count: 2

Next hop : 10.1.1.2 Out-interface : GE1/0/2

In-interface : GE1/0/2 Symmetric-index: 1

Next hop : 10.1.1.3 Out-interface : GE1/0/1

In-interface : GE1/0/1 Symmetric-index: 2

Owner : SIDMGR State : Active

Flags : F

Create Time : May 19 17:21:15.687 2020

# Display SRv6 local forwarding table information for End.AS SIDs in Layer 3 encapsulation forwarding scenario.

<Sysname> display segment-routing ipv6 local-sid end-as

Local SID forwarding table (End.AS)

Total SIDs: 1

SID : 100:1:2:3::C800/96

Function type : End.AS Allocation type: Static

Locator name : abc Forward type : L3

Inner type : IPv4 Source address : 2::60

Backup SID : 1::AA Peer SID : 300::3

Bypass : Enabled Bypass SID : 5::9

TTL mode : Uniform TTL value : -

Diffserv mode : Uniform Service class : -

Color : - Cache-SL : 2

Cache list :

4::3

7::8

8::9

1::16::9

Encapsulation count: 2

Next hop : 10.1.1.2 Out-interface : Vlan20

In-interface : Vlan20 Symmetric-index: 1

Next hop : 10.1.1.3 Out-interface : Vlan10

In-interface : Vlan10 Symmetric-index: 2

Owner : SIDMGR State : Active

Flags : F

Create Time : May 19 17:21:15.687 2020

# Display SRv6 local forwarding table information for End.AM SIDs in Layer 3 encapsulation forwarding scenario.

<Sysname> display segment-routing ipv6 local-sid end-am

Local SID forwarding table (End.AM)

Total SIDs: 1

SID : 100:1:2:3::C800/96

Function type : End.AM Allocation type: Static

Locator name : abc Forward type : L3

Encapsulation count: 2

Next hop : 1::1 Out-interface : GE1/0/2

In-interface : GE1/0/2

Next hop : 1::2 Out-interface : GE1/0/1

In-interface : GE1/0/1

Owner : SIDMGR State : Active

Flags : F

Create Time : May 19 17:21:15.687 2020

# Display SRv6 local forwarding table information for End.AM SIDs in Layer 3 encapsulation forwarding scenario.

<Sysname> display segment-routing ipv6 local-sid end-am

Local SID forwarding table (End.AM)

Total SIDs: 1

SID : 100:1:2:3::C800/96

Function type : End.AM Allocation type: Static

Locator name : abc Forward type : L3

Encapsulation count: 2

Next hop : 1::1 Out-interface : Vlan20

In-interface : Vlan20

Next hop : 1::2 Out-interface : Vlan10

In-interface : Vlan10

Owner : SIDMGR State : Active

Flags : F

Create Time : May 19 17:21:15.687 2020

# Display SRv6 local forwarding table information for End.AM SIDs in Layer 2 encapsulation forwarding scenario.

<Sysname> display segment-routing ipv6 local-sid end-am

Local SID forwarding table (End.AM)

Total SIDs: 1

SID : 100:1:2:3::C800/96

Function type : End.AM Allocation type: Static

Locator name : abc Forward type : L2

Encapsulation count: 2

Out-interface: GE1/0/1 In-interface : GE1/0/1

Out-S-VLAN : 100 Out-C-VLAN : -

In-S-VLAN : 200 In-C-VLAN : -

Out-interface: GE1/0/2 In-interface : GE1/0/2

Out-S-VLAN : 101 Out-C-VLAN : -

In-S-VLAN : 201 In-C-VLAN : -

Owner : SIDMGR State : Active

Flags : F

Create Time : May 19 17:21:15.687 2020

Table 18 Command output

Field	Description
SID	SRv6 SID.
Function type	SRv6 SID type: · End. · End.AM. · End.AS. · End.B6.Encaps. · End.B6.Encaps.Red · End.B6.Insert · End.B6.Insert.Red · End(COCNONE) · End (COC32). · End.DT2M. · End.DT2U. · End.DT2UL. · End.DT4. · End.DT46. · End.DT6. · End.DX2. · End.DX2L. · End.M. · End.OP. · End.X. · End.X(COCNONE) · End.X (COC32).
Flavor	SRv6 SID flavor type: · NO-FLAVOR—The SRv6 SID does not carry any flavors. · PSP—The penultimate SRv6 node removes the SRH. · PSP,USP,USD—The SRv6 SID carries the PSP, USP, and USD flavors. · NOPSP—The penultimate SRv6 node does not remove the SRH.
Interface	Output interface.
Interface index	Output interface index.
Next hop	Next hop address.
VPN instance	VPN instance name. For the public network, this field displays Public instance.
Xconnect group	Cross-connect group name.
Connection	Cross-connect name.
VSI name	VSI name.
Service ID	Ethernet service instance ID. If no Ethernet service instance ID exists, this field displays 0.
Allocation type	SID allocation type: · Static—Manually configured. · Dynamic—Dynamically allocated.
Network type	Type of the network to which the SRv6 SID is applied: · MPLS L3VPN—The SRv6 SID is applied to an MPLS L3VPN network. · EVPN L3VPN—The SRv6 SID is applied to an EVPN L3VPN network. · MPLS L3VPN, EVPN L3VPN—The SRv6 SID is applied to MPLS L3VPN and EVPN L3VPN networks.
Mirror locator number	Number of protected locators.
Mirror locator	IPv6 address prefix and prefix length of each protected locator.
Owner	Protocol that applies for the SID: · SIDMGR. · BGP. · SRPolicy. · IS-IS. · OSPFv3. · L2VPN. · LSM.
Paths	Number of paths.
Path index	Index of the path for the SID.
Weight	Load sharing weight of the path.
State	SID state: · Active. · Inactive.
Flags	Flags: · If traffic forwarding statistics collection is enabled for local SRv6 SIDs, this field displays F. · If traffic forwarding statistics collection is disabled for local SRv6 SIDs, this field displays a hyphen (-).
Create Time	SID creation time.
Forward type	SFF-to-SF packet forwarding type: · L2—Layer 2 forwarding. · L3—Layer 3 forwarding.
Inner type	Protocol type of the original SFF-to-SF packet.
Source address	Source IPv6 address re-encapsulated for the packet received by the SFF from the SF.
Backup SID	Backup End.AS SID.
Peer SID	Backup SFF SID, which is the an End SID.
Bypass	Bypass protection status: Enabled or disabled (-).
Bypass SID	Backup SID of the bypass path, which is the valid End.AS SID of other protection devices in the SF group.
TTL mode	TTL processing mode: · Uniform—After a packet is forwarded back to the SFF from the SF, the SFF uses the TTL value in the original packet minus 1 as the TTL in the newly encapsulated IPv6 header. · Pipe—After a packet is forwarded back to the SFF from the SF, the SFF uses the specified TTL value (ttl-value) minus 1 as the TTL in the newly encapsulated IPv6 header.
TTL value	TTL value: · In the Uniform TTL processing mode, a hyphen (-) is displayed. · In the Pipe TTL processing mode, the configured TTL value is displayed.
Diffserv mode	Differentiated services (Diffserv) mode: · Uniform—In the inbound direction (SF to SFF), the SFF maps the carried IP or DSCP value to the priority in the newly encapsulated IPv6 header. The packet color will not be changed. In the outbound direction (SFF to SF), the SFF removes the outer IPv6 and SRH header. Then it maps the priority in the outer IPv6 header to the IP or DSCP value in the original packet. The packet color will not be changed. · Pipe—In the inbound direction (SF to SFF), the SFF ignores the carried IP or DSCP value. It uses the configured service-class value as the priority in the newly encapsulated IPv6 header, and the configured color value as the color for the new packet. In SRv6 networks, QoS scheduling is performed for packets based on the priority and color values. In the outbound direction (SFF to SF), the SFF removes the outer IPv6 and SRH header without modifying the IP or DSCP value and color in the original packet.
Service class	Diffserv class of the service chain. Values include the following in ascending priority order: · be · af1 · af2 · af3 · af4 · ef · cs6 · cs7 If no Diffserv class is configured, a hyphen (-) is displayed.
Color	Packet color. Values include the following in ascending order of packet loss probability: · green—Indicates packet loss probability 0. · yellow—Indicates packet loss probability 1. · red—Indicates packet loss probability 2. If no Diffserv class is configured, a hyphen (-) is displayed.
Cache-SL	Segment left value, which indicates the number of nodes to access in the SID list before arrival at the final destination.
Cache list	SID list that needs to be encapsulated after the SFF receives the packet from the SF.
Encapsulation count	Number of equal-cost paths between the SFF and SF.
Out-Interface	Outbound interface for the SFF to forward packets to the SF.
In-Interface	Inbound interface for the SFF to receive packets from the SF.
Out-S-VLAN	Outer VLAN ID for SFF-to-SF (outbound) packets.
Out-C-VLAN	Inner VLAN ID for SFF-to-SF (outbound) packets.
In-S-VLAN	Outer VLAN ID for SF-to-SFF (inbound) packets.
In-C-VLAN	Inner VLAN ID for SF-to-SFF (inbound) packets.
Dest MAC	Destination MAC address encapsulated for packets from the SF to the remote backup SFF in Layer 2 forwarding.
Symmetric-index	Index that identifies a VM used for forwarding bidirectional traffic when multiple VMs exist on the SF. Both inbound and outbound traffic with the same source and destination addresses will traverse the same VM.

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display segment-routing ipv6 local-sid forwarding statistics

Use display segment-routing ipv6 local-sid forwarding statistics to display traffic forwarding statistics for local SRv6 SIDs.

Syntax

display segment-routing ipv6 local-sid forwarding statistics { end | end-dt2m | end-dt2u | end-dt2ul } [ sid ]

display segment-routing ipv6 local-sid forwarding statistics { end-dt4 | end-dt46 | end-dt6 | end-dx4 | end-dx6 } [ sid | vpn-instance vpn-instance-name ]

display segment-routing ipv6 local-sid forwarding statistics end-x [ sid | interface interface-type interface-number [ nexthop nexthop-ipv6-address ] ]

Views

Any view

Predefined user roles

network-admin

network-operator

Parameters

end: Specifies local End SIDs.

end-dt2m: Specifies local End.DT2M SIDs.

end-dt2u: Specifies local End.DT2U SIDs.

end-dt2ul: Specifies local End.DT2UL SIDs.

end-dt4: Specifies local End.DT4 SIDs.

end-dt46: Specifies local End.DT46 SIDs.

end-dt6: Specifies local End.DT6 SIDs.

end-dx4: Specifies local End.DX4 SIDs.

end-dx6: Specifies local End.DX6 SIDs.

end-x: Specifies local End.X SIDs.

sid: Specifies an SRv6 SID. If you do not specify an SRv6 SID, this command displays traffic forwarding statistics for all local SRv6 SIDs of the specified type.

vpn-instance vpn-instance-name: Specifies an MPLS L3VPN instance by its name, a case-sensitive string of 1 to 31 characters. If the local SRv6 SIDs belong to the public network, do not specify this option.

interface interface-type interface-number: Specifies an output interface by its type and number. If you do not specify an output interface, this command displays traffic forwarding statistics for all local End.X SIDs.

nexthop nexthop-ipv6-address: Specifies a next hop IPv6 address. If you do not specify a next hop IPv6 address, this command displays traffic forwarding statistics for all next hop IPv6 addresses of local SRv6 SIDs.

Examples

# Display traffic forwarding statistics for all local End SIDs.

<Sysname> display segment-routing ipv6 local-sid forwarding statistics end

Local SID forwarding table (End)

Total SIDs: 1

SID : 100:1::1

Function type : End

Inbound statistics:

Total octets : 0

Total packets : 0

Input rate in last 300 seconds:

0 bits/sec, 0 pkts/sec

Input rate in last statistical period (20 sec):

0 bits/sec, 0 pkts/sec

Table 19 Command output

Field	Description
Total SIDs	Total number of SIDs.
SID	SRv6 SID value.
Function type	SRv6 SID type: · End. · End.DT2M. · End.DT2U. · End.DT2UL. · End.DT4. · End.DT46. · End.DT6. · End.X.
Inbound statistics	Inbound traffic statistics.
Total octets	Total number of incoming octets.
Total packets	Total number of incoming packets.
Input rate in last 300 seconds: 0 bits/sec, 0 pkts/sec	Number of incoming bits per second and incoming packets per second in the last 300 seconds.
Input rate in last statistical period (20 sec): 0 bits/sec, 0 pkts/sec	Number of incoming bits per second and incoming packets per second in the last statistical interval. To set the statistical interval, use the local-sid forwarding statistics interval command.

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display segment-routing ipv6 local-sid statistics

Use display segment-routing ipv6 local-sid statistics to display statistics about SRv6 SIDs allocated for each protocol.

Syntax

display segment-routing ipv6 local-sid statistics [ locator [ locator-name ] ]

Views

Any view

Predefined user roles

network-admin

network-operator

Parameters

locator: Displays statistics about SRv6 SIDs allocated for each protocol by locator. If you do not specify this keyword, the command does not display statistics about SRv6 SIDs allocated for each protocol by locator.

locator-name: Specifies a locator by its name, a case-sensitive string of 1 to 31 characters. If you do not specify a locator, the command displays statistics about SRv6 SIDs for all locators.

Examples

# Display statistics about SRv6 SIDs allocated for each protocol (not by locator).

<Sysname> display segment-routing ipv6 local-sid statistics

Total SIDs: 0

Funtion SIDMGR SRP IS-IS OSPFv3 BGP L2VPN Total

End 0 0 0 0 0 0 0

End.X 0 0 0 0 0 0 0

End.COC32 0 0 0 0 0 0 0

End.XCOC32 0 0 0 0 0 0 0

End.COCNONE 0 0 0 0 0 0 0

End.XCOCNONE 0 0 0 0 0 0 0

End.B6Encaps 0 0 0 0 0 0 0

End.B6EncapsRed 0 0 0 0 0 0 0

End.B6Insert 0 0 0 0 0 0 0

End.B6InsertRed 0 0 0 0 0 0 0

End.DT4 0 0 0 0 0 0 0

End.DT46 0 0 0 0 0 0 0

End.DT6 0 0 0 0 0 0 0

End.DX4 0 0 0 0 0 0 0

End.DX6 0 0 0 0 0 0 0

End.DX2 0 0 0 0 0 0 0

End.DX2L 0 0 0 0 0 0 0

End.DT2M 0 0 0 0 0 0 0

End.DT2U 0 0 0 0 0 0 0

End.DT2UL 0 0 0 0 0 0 0

End.AS 0 0 0 0 0 0 0

END.AM 0 0 0 0 0 0 0

End.M 0 0 0 0 0 0 0

End.OP 0 0 0 0 0 0 0

End.T 0 0 0 0 0 0 0

# Display statistics about SRv6 SIDs allocated for each protocol from locator abc.

<Sysname> display segment-routing ipv6 local-sid statistics locator abc

Locator: abc

Total SIDs: 1

Funtion SIDMGR SRP IS-IS OSPFv3 BGP L2VPN Total

End 0 0 0 0 0 0 0

End.X 0 0 0 0 0 0 0

End.COC32 0 0 0 0 0 0 0

End.XCOC32 0 0 0 0 0 0 0

End.COCNONE 0 0 0 0 0 0 0

End.XCOCNONE 0 0 0 0 0 0 0

End.B6Encaps 0 0 0 0 0 0 0

End.B6EncapsRed 0 0 0 0 0 0 0

End.B6Insert 0 0 0 0 0 0 0

End.B6InsertRed 0 0 0 0 0 0 0

End.DT4 0 0 0 0 0 0 0

End.DT46 0 0 0 0 0 0 0

End.DT6 0 0 0 0 0 0 0

End.DX4 0 0 0 0 0 0 0

End.DX6 0 0 0 0 0 0 0

End.DX2 0 0 0 0 0 0 0

End.DX2L 0 0 0 0 0 0 0

End.DT2M 0 0 0 0 0 0 0

End.DT2U 0 0 0 0 0 0 0

End.DT2UL 0 0 0 0 0 0 0

End.AS 0 0 0 0 0 0 0

END.AM 0 0 0 0 0 0 0

End.M 0 0 0 0 0 0 0

End.OP 0 0 0 0 0 0 0

End.T 0 0 0 0 0 0 0

Table 20 Command output

Field	Description
Total SIDs	Total number of SRv6 SIDs. If you specify a locator, this field displays the total number of SRv6 SIDs that belong to the specified locator.
Locator	Locator name.
Function	SRv6 SID type: · End. · End.X. · End.COC32—End (COC32) SID. · End.XCOC32—End.X (COC32) SID. · End.COCNONE—End (COCNONE) SRv6 SID. · End.XCOCNONE—End.X (COCNONE) SRv6 SID. · End.B6Encaps—End.B6.Encaps SID. · End.B6EncapsRed—End.B6.Encaps.Red SID. · End.B6Insert—End.B6.Insert SID. · End.B6InsertRed—End.B6.Insert.Red SID. · End.DT4. · End.DT6. · End.DT46. · End.DX4. · End.DX6. · End.DX2. · End.DX2L. · End.DT2M. · End.DT2U. · End.DT2UL. · End.AS. · End.AM. · End.M. · End.OP. · End.T.
SIDMGR	Static SIDs.
SRP	BSIDs dynamically allocated for SRv6 TE policies.
IS-IS	SRv6 SIDs allocated for IS-IS.
OSPFv3	SRv6 SIDs allocated for OSPFv3.
L2VPN	SRv6 SIDs allocated for L2VPN.
BGP	SRv6 SIDs allocated for BGP.
Total	Total number for a type of SRv6 SIDs.

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display segment-routing ipv6 locator

Use display segment-routing ipv6 locator to display SRv6 locator information.

Syntax

display segment-routing ipv6 locator [ locator-name ]

Views

Any view

Predefined user roles

network-admin

network-operator

Parameters

locator-name: Specifies a locator by its name, a case-sensitive string of 1 to 31 characters. If you do not specify a locator, this command displays information about all locators.

Examples

# Display information about all locators. (The coc-both keyword is not specified when you configure locators.)

<Sysname> display segment-routing ipv6 locator

Locator configuration table

Locator name : abc Flag(A) : 0

IPv6 prefix : 100:1:2:3:: Prefix length : 96

Static length : 24 Args length : 8

Common prefix length: 0

Algorithm : 0

Auto SID start : N/A

Auto SID end : N/A

Static SID start : 100:1:2:3::100

Static SID end : 100:1:2:3::FFFF:FF00

Compressed Auto SID count : 0

Compressed Static SID count : 0

Non-compressed Auto SID count : 0

Non-compressed Static SID count: 1

# Display information about all locators. (The coc-both keyword is specified when you configure locators.)

<Sysname> display segment-routing ipv6 locator

Locator configuration table

Locator name : test1 Flag(A) : 0

IPv6 prefix : 100:200:DB8:ABCD:: Prefix length : 64

Static length : 8 Args length : 16

Common prefix length: 48 Non-compressed static length : 16

Algorithm : 0

Compressed auto SID start : 100:200:DB8:ABCD:100::

Compressed auto SID end : 100:200:DB8:ABCD:FFFF::

Table 21 Command output

Field	Description
Flag(A)	Anycast locator flag (A-bit). If A-bit is set, the locator is an anycast locator.
IPv6 prefix	IPv6 address prefix of the locator.
Prefix length	Prefix length of the locator.
Static length	Static length of the locator.
Args length	Argument length.
Common prefix length	Common prefix length of the locator.
Non-compressed static length	Static length of the locator for non-compressible SRv6 SIDs.
Algorithm	Algorithm ID: · 0—SPF algorithm. · 128 to 255—Flex-Algo algorithm.
Auto SID start	Start dynamic SRv6 SID. If no dynamic SRv6 SIDs exist, this field displays N/A.
Auto SID end	End dynamic SRv6 SID. If no dynamic SRv6 SIDs exist, this field displays N/A.
Static SID start	Start static SRv6 SID. If no static SRv6 SIDs exist, this field displays N/A.
Static SID end	End static SRv6 SID. If no static SRv6 SIDs exist, this field displays N/A.
Compressed auto SID start	Start value for compressible dynamic SRv6 SIDs. If no compressible dynamic SRv6 SIDs exist, this field displays N/A.
Compressed auto SID end	End value for compressible dynamic SRv6 SIDs. If no compressible dynamic SRv6 SIDs exist, this field displays N/A.
Compressed static SID start	Start value for compressible static SRv6 SIDs. If no compressible static SRv6 SIDs exist, this field displays N/A.
Compressed static SID end	End value for compressible static SRv6 SIDs. If no compressible static SRv6 SIDs exist, this field displays N/A.
Non-compressed auto SID start	Start value for non-compressible dynamic SRv6 SIDs. If no non-compressible dynamic SRv6 SIDs exist, this field displays N/A.
Non-compressed auto SID end	End value for non-compressible dynamic SRv6 SIDs. If no non-compressible dynamic SRv6 SIDs exist, this field displays N/A.
Non-compressed static SID start	Start value for non-compressible static SRv6 SIDs. If no non-compressible static SRv6 SIDs exist, this field displays N/A.
Non-compressed static SID end	End value for non-compressible static SRv6 SIDs. If no non-compressible static SRv6 SIDs exist, this field displays N/A.
Reserved SID start	Start value for reserved SRv6 SIDs. If no start value is specified for SRv6 SID reservation, this field displays N/A.
Reserved SID count	Number of reserved SRv6 SIDs.
Reserved SID end	End value for reserved SRv6 SIDs. If no end value is specified for SRv6 SID reservation, this field displays N/A.
Compressed Auto SID count	Number of dynamic compressible SRv6 SIDs.
Compressed Static SID count	Number of static compressible SRv6 SIDs.
Non-compressed Auto SID count	Number of dynamic non-compressible SRv6 SIDs.
Non-compressed Static SID count	Number of static non-compressible SRv6 SIDs.

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display segment-routing ipv6 locator-statistics

Use display segment-routing ipv6 locator-statistics to display SRv6 locator configuration and statistics about allocated SRv6 SIDs in locators.

Syntax

display segment-routing ipv6 locator-statistics [ locator-name ]

Views

Any view

Predefined user roles

network-admin

network-operator

Parameters

locator-name: Specifies a locator by its name, a case-sensitive string of 1 to 31 characters. If you do not specify a locator, this command displays SRv6 locator configuration and statistics about allocated SRv6 SIDs in all locators.

Examples

# Display SRv6 locator configuration and statistics about allocated SRv6 SIDs in all locators.

<Sysname> display segment-routing ipv6 locator-statistics

Locator configuration table

Total Locators: 1 Total SIDs: 1

Name IPv6 prefix/Prefix length CDyn/CStatic/Dyn/Static Flag Algo

abc 100:1::/64 0 /0 /0 /1 0 0

Table 22 Command output

Field	Description
Total Locators	Total number of locators.
Total SIDs	Total number of SIDs that have been allocated in the locators.
Name	Locator name.
IPv6 prefix/Prefix length	Locator prefix and prefix length.
CDyn/CStatic/Dyn/Static	Number of dynamic compressible SRv6 SIDs, number of static compressible SRv6 SIDs, number of dynamic non-compressible SRv6 SIDs, and number of static non-compressible SRv6 SIDs.
Flag	Anycast locator flag (A flag). The value is 1 if this flag is set, which indicates that the locator is an anycast locator.
Algo	Algorithm ID: · 0—SPF algorithm. · 128 to 255—Flex-Algo algorithm.

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egress-engineering srv6 peer-set

Use egress-engineering srv6 peer-set to create a BGP-EPE SRv6 peer set.

Use undo egress-engineering srv6 peer-set to delete a BGP-EPE SRv6 peer set.

Syntax

egress-engineering srv6 peer-set peer-set-name [ static-sid { psp psp-sid | no-psp-usp no-psp-usp-sid } * ]

undo egress-engineering srv6 peer-set peer-set-name

Default

No BGP-EPE SRv6 peer sets exist.

Views

BGP instance view

Predefined user roles

network-admin

Parameters

peer-set-name: Specifies a name for the BGP-EPE SRv6 peer set, which is a case-sensitive string of 1 to 63 characters.

static-sid: Specifies a static SRv6 SID for the BGP-EPE SRv6 peer set. If you do not specify a static SRv6 SID, dynamic SRv6 SID allocation applies.

psp psp-sid: Specifies an End.X SID and enables PSP to remove the SRH on the penultimate segment.

no-psp-usp no-psp-usp-sid: Specifies an End.X SID and disables PSP and USP. The SRH is not removed on the penultimate segment or the ultimate segment.

Usage guidelines

BGP-EPE allocates BGP peer SIDs to inter-AS segments. The device advertises the peer SIDs to a network controller through BGP LS messages. The controller orchestrates the IGP SIDs and BGP peer SIDs to realize optimal inter-AS traffic forwarding.

If the device establishes BGP peer relationship with multiple devices, use this command to add the peer devices to a peer set and allocate a PeerSet SID to the peer set. When the device forwards traffic based on the PeerSet SID, it distributes the traffic among the peers for load sharing.

Before you use this command, apply a locator to BGP-EPE by using the segment-routing ipv6 egress-engineering locator command in BGP instance view.

· If automatic SID allocation is used, the device dynamically allocates an SRv6 SID to the BGP-EPE SRv6 peer set from the specified locator.

· If you specify a static SRv6 SID for the BGP-EPE SRv6 peer set, the specified static SRv6 SID must belong to the specified locator.

If you execute the egress-engineering srv6 peer-set command to specify multiple SRv6 SIDs for one peer set, the effective configuration depends on whether the SRv6 SIDs are the same type.

· If all the SRv6 SIDs belong to the same type, only the most recent configuration takes effect.

· If the SRv6 SIDs belong to different types, the configuration for all the SRv6 SID types takes effect. For the SRv6 SIDs that belong to the same type, only the most recent configuration takes effect. Make sure each SRv6 SID is unique among all the SRv6 SID types.

The static SRv6 SIDs configured by using the following commands cannot be the same in a BGP instance:

· egress-engineering srv6 peer-set.

· peer egress-engineering srv6.

Examples

# Create a BGP-EPE SRv6 peer set named epe and configure the peer set to use a dynamically allocated SRv6 SID.

<Sysname> system-view

[Sysname] bgp 100

[Sysname-bgp-default] egress-engineering srv6 peer-set epe

Related commands

peer egress-engineering srv6

peer peer-set

segment-routing ipv6 egress-engineering locator

encapsulation source-address

Use encapsulation source-address to specify a source address for the outer IPv6 header of SRv6 packets.

Use undo encapsulation source-address to restore the default.

Syntax

encapsulation source-address ipv6-address [ ip-ttl ttl-value ]

undo encapsulation source-address

Default

No source address is specified for the outer IPv6 header of SRv6 packets.

Views

SRv6 view

Predefined user roles

network-admin

Parameters

ipv6-address: Specifies a source IPv6 address. The IPv6 address cannot be a loopback address (0:0:0:0:0:0:0:0 or ::), link-local address, multicast address, or unspecified address.

ip-ttl ttl-value: Specifies the TTL of the outer IPv6 header, in the range of 1 to 255. The default value is 255.

Usage guidelines

As a best practice to ensure correct traffic forwarding in an SRv6 network, specify a source address for the outer IPv6 header of SRv6 packets.

You must specify an IPv6 address of the local device as the source IPv6 address, and make sure the IPv6 address has been advertised by a routing protocol. As a best practice, specify a loopback interface address of the local device as the source IPv6 address.

Examples

# Specify 1::1 as the source address of SRv6 packets in the outer IPv6 header and set the TTL of the outer IPv6 header to 200.

<Sysname> system-view

[Sysname] segment-routing ipv6

[Sysname-segment-routing-ipv6] encapsulation source-address 1::1 ip-ttl 200

end-x update-delay

Use end-x update-delay to configure the delay time to flush static End.X SIDs to the FIB.

Use undo end-x update-delay to restore the default.

Syntax

end-x update-delay delay-time

undo end-x update-delay

Default

Static End.X SIDs are not delayed to flush to the FIB.

Views

SRv6 view

Predefined user roles

network-admin

Parameters

delay-time: Sets the delay time to flush static End.X SIDs to the FIB, in milliseconds. The value range is 0 to 600000.

Usage guidelines

When a neighbor fails, the interface connected to that neighbor goes down. The End.X SID associated with the interface cannot take effect. When the neighbor recovers, the interface also comes up and the static End.X SID associated with the interface takes effect. Because route convergence has not finished, the local device cannot forward packets according to the route entry of the static End.X SID. As a result, packet forwarding failure or packet loss occurs. (Dynamic End.X SIDs do not have this issue, because they are flushed to the FIB after route convergence is completed.) To avoid this issue, use this command to delay flushing the static End.X SID associated with the interface to the FIB. During the delay time, the local device does not forward traffic through the link attached to the interface. The delay configuration avoids packet loss within the delay time.

Examples

# Set the delay time to flush static End.X SIDs to the FIB to 60 milliseconds.

<Sysname> system-view

[Sysname] segment-routing ipv6

[Sysname-segment-routing-ipv6] end-x update-delay 60

fast-reroute microloop-avoidance enable

Use fast-reroute microloop-avoidance enable to enable FRR microloop avoidance.

Use undo fast-reroute microloop-avoidance enable to disable FRR microloop avoidance.

Syntax

fast-reroute microloop-avoidance enable [ level-1 | level-2 ]

undo fast-reroute microloop-avoidance enable [ level-1 | level-2 ]

Default

FRR microloop avoidance is disabled.

Views

IS-IS IPv6 unicast address family view

Predefined user roles

network-admin

Parameters

level-1: Specifies FRR microloop avoidance for IS-IS Level-1.

level-2: Specifies FRR microloop avoidance for IS-IS Level-2.

Usage guidelines

Use this command only on the source node.

On an network configured with TI-LFA FRR, if a node or link fails, traffic will be switched to the backup path calculated by TI-LFA. If a device along the backup path has not finished route convergence, a traffic loop will occur. Traffic will be looped between the device and the source node (the node prior to the node or link that failed) until the device finishes route convergence. The node performs the following operations only after all nodes on the backup path finish route convergence and the timer times out:

· Issues the forwarding path after route convergence to the FIB.

· Switches traffic from the backup path calculated by TI-LFA to the forwarding path after route convergence.

If you configure both the segment-routing microloop-avoidance enable and fast-reroute microloop-avoidance enable commands, FRR microloop avoidance takes precedence over SR microloop avoidance. The FRR microloop avoidance RIB-update-delay timer and SR microloop avoidance RIB-update-delay timer are started for the two features, respectively. The following situations exist depending on the configuration of the two timers:

· If the FRR microloop avoidance RIB-update-delay timer is equal to or greater than the SR microloop avoidance RIB-update-delay timer, traffic is switched to the post-convergence path immediately when the former timer times out.

· If the FRR microloop avoidance RIB-update-delay timer is larger than the SR microloop avoidance RIB-update-delay timer, traffic is switched to the post-convergence path until after the latter timer times out.

To resolve this problem, configure microloop avoidance on the source node. Then, when a node or link fails, traffic will be switched to the backup path calculated by TI-LFA. The source node waits for a period of time for other devices to finish route convergence. After the delay time elapses, the source node starts route convergence.

If you do not specify the level-1 or level-2 keyword, the command enables or disables FRR microloop avoidance on all IS-IS levels.

Examples

# Enable FRR microloop avoidance for IS-IS process 1.

<Sysname> system-view

[Sysname] isis 1

[Sysname-isis-1] address-family ipv6

[Sysname-isis-1-ipv6] fast-reroute microloop-avoidance enable

Related commands

fast-reroute microloop-avoidance rib-update-delay

segment-routing microloop-avoidance enable

fast-reroute microloop-avoidance rib-update-delay

Use fast-reroute microloop-avoidance rib-update-delay to set the FRR microloop avoidance RIB-update-delay time.

Use undo fast-reroute microloop-avoidance rib-update-delay to restore the default.

Syntax

fast-reroute microloop-avoidance rib-update-delay delay-time [ level-1 | level-2 ]

undo fast-reroute microloop-avoidance rib-update-delay [ level-1 | level-2 ]

Default

The FRR microloop avoidance RIB-update-delay time is 5000 ms.

Views

IS-IS IPv6 unicast address family view

Predefined user roles

network-admin

Parameters

delay-time: Specifies the FRR microloop avoidance RIB-update-delay time in milliseconds. The value range is 1 to 60000.

level-1: Specifies the FRR microloop avoidance RIB-update-delay time for IS-IS Level-1.

level-2: Specifies the FRR microloop avoidance RIB-update-delay time for IS-IS Level-2.

Usage guidelines

Use this command only on the source node.

If you do not specify the level-1 or level-2 keyword, the command sets the FRR microloop avoidance RIB-update-delay time for all IS-IS levels.

Examples

# Set the FRR microloop avoidance RIB-update-delay time to 6000 ms for Level-1 of IS-IS process 1.

<Sysname> system-view

[Sysname] isis 1

[Sysname-isis-1] address-family ipv6

[Sysname-isis-1-ipv6] fast-reroute microloop-avoidance rib-update-delay 6000 level-1

Related commands

fast-reroute microloop-avoidance

fast-reroute ti-lfa

Use fast-reroute ti-lfa to enable Topology-Independent Loop-free Alternate Fast Re-Route (TI-LFA FRR).

Use undo fast-refroute ti-lfa to disable TI-LFA FRR.

Syntax

In IS-IS IPv6 unicast address family view:

fast-reroute ti-lfa [ per-prefix ] [ route-policy route-policy-name | host ] [ level-1 | level-2 ]

undo fast-reroute ti-lfa [ level-1 | level-2 ]

In OSPFv3 process view:

fast-reroute ti-lfa [ per-prefix ] [ route-policy route-policy-name | host ]

undo fast-reroute ti-lfa

Default

TI-LFA FRR is disabled.

Views

IS-IS IPv6 unicast address family view

OSPFv3 process view

Predefined user roles

network-admin

Parameters

per-prefix: Calculates backup information for each advertising source of a route. Specify this keyword only if routes are advertised by multiple sources. If you do not specify this keyword, the device calculates backup information for each route.

route-policy route-policy-name: Enables TI-LFA FRR for prefixes identified by the routing policy. The route-policy-name argument specifies a routing policy by its name, a case-sensitive string of 1 to 63 characters.

host: Enables TI-LFA for host routes.

level-1: Specifies TI-LFA FRR for IS-IS Level-1.

level-2: Specifies TI-LFA FRR for IS-IS Level-2.

Usage guidelines

TI-LFA FRR provides link and node protection for SR tunnels. When a link or node fails, TI-LFA FRR switches the traffic to the backup path to ensure continuous data forwarding.

Before configuring TI-LFA FRR on a level, you must execute the fast-reroute lfa command in IS-IS IPv6 unicast address family view or OSPFv3 process view to enable LFA FRR on that level. TI-LFA FRR takes effect only after you enable LFA FRR.

If you do not specify the route-policy route-policy-name option or the host keyword, the device calculates backup information for all routes.

If you do not specify the level-1 or level-2 keyword, the command applies to both IS-IS levels.

Examples

# Enable TI-LFA FRR for IS-IS process 1 and calculate backup information for all routes.

<Sysname> system-view

[Sysname] isis 1

[Sysname-isis-1] address-family ipv4

[Sysname-isis-1-ipv4] fast-reroute ti-lfa

# Enable TI-LFA FRR for OSPFv3 process 1 and calculate backup information for all routes.

<Sysname> system-view

[Sysname] ospfv3 1

[Sysname-ospfv3-1] fast-reroute ti-lfa

Related commands

fast-reroute (IS-IS in Layer 3—IP Routing Command Reference)

fast-reroute (OSPFv3 in Layer 3—IP Routing Command Reference)

route-policy (Layer 3—IP Routing Command Reference)

isis ipv6 fast-reroute ti-lfa disable

Use isis ipv6 fast-reroute ti-lfa disable to prevent an IS-IS interface from participating in TI-LFA calculation.

Use undo isis ipv6 fast-reroute ti-lfa disable to allow an IS-IS interface to participate in TI-LFA calculation.

Syntax

isis ipv6 fast-reroute ti-lfa disable [ level-1 | level-2 ]

undo isis ipv6 fast-reroute ti-lfa disable [ level-1 | level-2 ]

Default

An IS-IS interface participates in TI-LFA calculation.

Views

Interface view

Predefined user roles

network-admin

Parameters

level-1: Specifies TI-LFA calculation on IS-IS Level-1.

level-2: Specifies TI-LFA calculation on IS-IS Level-2.

Usage guidelines

Disable the output interface to the primary next hop from participating in TI-LFA calculation.

If you do not specify the level-1 or level-2 keyword, this command applies to both IS-IS levels.

Examples

# Prevent GigabitEthernet1/0/1 from participating in TI-LFA calculation.

<Sysname> system-view

[Sysname] interface gigabitethernet 1/0/1

[Sysname-GigabitEthernet1/0/1] isis ipv6 fast-reroute ti-lfa disable

Related commands

fast-reroute ti-lfa

locator

Use locator to create an SRv6 locator and enter its view, or enter the view of an existing SRv6 locator.

Use undo locator to delete an SRv6 locator.

Syntax

locator locator-name [ ipv6-prefix ipv6-address prefix-length [ args args-length | static static-length ] * ]

locator locator-name [ ipv6-prefix ipv6-address prefix-length common-prefix common-prefix-length coc32 [ args args-length | static static-length ] * ]

locator locator-name [ ipv6-prefix ipv6-address prefix-length common-prefix common-prefix-length coc-both [ non-compress-static non-compress-static-length ] [ args args-length | static static-length ] * ]

undo locator locator-name

Default

No SRv6 locators exist.

Views

SRv6 view

Predefined user roles

network-admin

Parameters

locator-name: Specifies a locator name, a case-sensitive string of 1 to 31 characters.

ipv6-prefix ipv6-address prefix-length: Specifies an IPv6 address prefix and the prefix length. The ipv6-address argument represents the IPv6 address prefix. The prefix-length argument represents the prefix length, in the range of 32 to 120.

args args-length: Specifies an argument length. The value range for the args-length argument depends on the value of the prefix-length argument and varies by device model. If you do not specify an argument length, the argument length is 0.

static static-length: Specifies the static length. The value range for the static-length argument varies by the value of the prefix-length argument and varies by device model. If you do not specify a static length, the static length is 0.

common-prefix common-prefix-length: Specifies the G-SID common prefix length. The value range for the common-prefix-length argument varies by the value of the prefix-length argument and varies by device model. If you do not specify a G-SID common prefix length, the common prefix length is 0.

coc32: Enables 32-bit G-SID compression.

coc-both: Enables the locator to allocate both compressible and non-compressible SRv6 SIDs.

non-compress-static non-compress-static-length: Specifies a static length for non-compressible SRv6 SIDs. If you do not specify a static length, the static length for non-compressible SRv6 SIDs is 0.

Usage guidelines

An SRv6 locator can be one of the following types:

· COC32 type—An SRv6 locator with the coc32 keyword specified.

· COC-both locator—To create a COC-both locator, specify the coc-both keyword in this command.

· Common type—An SRv6 locator without the coc32 keyword specified.

For more information about the SRv6 SID fields, see SRv6 configuration in Segment Routing Configuration Guide.

If SRv6 compression is enabled, use the locator command to configure the G-SID common prefix length and specify the G-SID compression mode. Only the 32-bit G-SID compression mode is supported in the current software version. In this mode, a standard 128-bit SRv6 SID is compressed to a 32-bit G-SID.

If a static opcode has been configured, a routing protocol preferentially uses the static opcode to construct SRv6 SIDs. If no static opcode exists, the routing protocol dynamically allocates SRv6 SIDs.

By applying a locator to IGP and BGP, you can use IGP and BGP to advertise the SRv6 SIDs on the locator.

When you create a locator, you must specify an IPv6 address prefix, prefix length, and static length for the locator. When you enter the view of an existing SRv6 locator, you do not need to specify the IPv6 address prefix, prefix length, or static length of the locator.

Each locator must have a unique name.

Do not specify the same IPv6 address prefix and prefix length for different locators. In addition, the IPv6 address prefixes of different locators cannot overlap.

You cannot delete a locator if that locator has dynamic SRv6 SIDs that are being used.

You can change a COC-both locator to a common locator or vice versa without deleting the configured locator but directly editing the command parameters, as follows:

· Change a common locator to a COC-both locator by adding the common-prefix and non-compress-static parameters. Other parameters cannot be edited.

For example, assume you configure a common locator as locator test ipv6-prefix 100:1:: 80 static 8 args 8. You can change the locator to a COC-both locator by executing locator test ipv6-prefix 100:1:: 80 common-prefix 64 coc-both non-compress-static 8 static 8 args 8.

· Change a COC-both locator to a common locator by deleting the common-prefix and non-compress-static parameters. Other parameters cannot be edited. For example, assume you configure a COC-both locator as locator test ipv6-prefix 100:1:: 80 common-prefix 64 coc-both non-compress-static 8 static 8 args 8. You can change the locator to a common locator by executing locator test ipv6-prefix 100:1:: 80 static 8 args 8.

Examples

# Configure locator test1, setting the IPv6 address prefix to 100::, prefix length to 64, and static length to 32, and enter the SRv6 locator view of this locator.

<Sysname> system-view

[Sysname] segment-routing ipv6

[Sysname-segment-routing-ipv6] locator test1 ipv6-prefix 100:: 64 static 32

[Sysname-segment-routing-ipv6-locator-test1]

Related commands

opcode

srv6 compress enable

local-sid forwarding statistics enable

Use local-sid forwarding statistics enable to enable traffic forwarding statistics collection for local SRv6 SIDs.

Use undo local-sid forwarding statistics enable to disable traffic forwarding statistics collection for local SRv6 SIDs.

Syntax

local-sid forwarding statistics enable

undo local-sid forwarding statistics enable

Default

Traffic forwarding statistics collection is disabled for local SRv6 SIDs.

Views

SRv6 view

Predefined user roles

network-admin

Usage guidelines

This command cannot take effect on traffic that is forwarded through End.B6.Encaps, End (COC32), End.X (COC32), End.DX2, End.DX2L, End.OP, End.AS, End.AM, and End.M SIDs.

Examples

# Enable traffic forwarding statistics collection for local SRv6 SIDs.

<Sysname> system-view

[Sysname] segment-routing ipv6

[Sysname-segment-routing-ipv6] local-sid forwarding statistics enable

Related commands

display segment-routing ipv6 local-sid forwarding statistics

local-sid forwarding statistics interval

reset segment-routing ipv6 local-sid forwarding statistics

local-sid forwarding statistics interval

Use local-sid forwarding statistics interval to set the interval at which traffic forwarding statistics are collected for local SRv6 SIDs.

Use undo local-sid forwarding statistics interval to restore the default.

Syntax

local-sid forwarding statistics interval interval

undo local-sid forwarding statistics interval

Default

Traffic forwarding statistics are collected at intervals of 30 seconds for local SRv6 SIDs.

Views

SRv6 view

Predefined user roles

network-admin

Parameters

interval: Sets the interval at which traffic forwarding statistics are collected for local SRv6 SIDs. The value range is 5 to 65535, in seconds.

Examples

# Configure the device to collect traffic forwarding statistics for local SRv6 SIDs at intervals of 90 seconds.

<Sysname> system-view

[Sysname] segment-routing ipv6

[Sysname-segment-routing-ipv6] local-sid forwarding statistics interval 90

Related commands

display segment-routing ipv6 local-sid forwarding statistics

local-sid forwarding statistics enable

reset segment-routing ipv6 local-sid forwarding statistics

opcode

Use opcode to configure the opcode of SRv6 SIDs for a locator.

Use undo opcode to delete the opcode of SRv6 SIDs for a locator.

Syntax

opcode { opcode | hex hex-opcode } end { no-flavor | psp | psp-usp-usd }

opcode { opcode | hex hex-opcode } end-x interface interface-type interface-number nexthop nexthop-ipv6-address { no-flavor | psp | psp-usp-usd }

opcode { opcode | hex hex-opcode } end-coc32 { no-flavor | psp }

opcode { opcode | hex hex-opcode } end-x-coc32 interface interface-type interface-number nexthop nexthop-ipv6-address { no-flavor | psp }

opcode { opcode | hex hex-opcode } end-coc-none { no-flavor | psp | psp-usp-usd }

opcode { opcode | hex hex-opcode } end-x-coc-none interface interface-type interface-number nexthop nexthop-ipv6-address { no-flavor | psp | psp-usp-usd }

opcode { opcode | hex hex-opcode } end-dt4 [ vpn-instance vpn-instance-name [ evpn | l3vpn-evpn ] ]

opcode { opcode | hex hex-opcode } end-dt46 [ vpn-instance vpn-instance-name [ evpn | l3vpn-evpn ] ]

opcode { opcode | hex hex-opcode } end-dt6 [ vpn-instance vpn-instance-name [ evpn | l3vpn-evpn ] ]

opcode { opcode | hex hex-opcode } end-dx4 interface interface-type interface-number nexthop nexthop-ipv4-address [ vpn-instance vpn-instance-name [ evpn ] ]

opcode { opcode | hex hex-opcode } end-dx6 interface interface-type interface-number nexthop np-ipv6-address [ vpn-instance vpn-instance-name [ evpn ] ]

opcode { opcode | hex hex-opcode } end-dx2 xconnect-group group-name connection connection-name

opcode { opcode | hex hex-opcode } end-dx2 vsi vsi-name interface interface-type interface-number

opcode { opcode | hex hex-opcode } end-dx2l xconnect-group group-name connection connection-name

opcode { opcode | hex hex-opcode } end-dx2l vsi vsi-name interface interface-type interface-number

opcode { opcode | hex hex-opcode } end-dt2m vsi vsi-name

opcode { opcode | hex hex-opcode } end-dt2u vsi vsi-name

opcode { opcode | hex hex-opcode } end-dt2ul vsi vsi-name

opcode { opcode | hex hex-opcode } end-m mirror-locator ipv6-address prefix-length

opcode { opcode | hex hex-opcode } end-op

Default

No opcode exists.

Views

SRv6 locator view

Predefined user roles

network-admin

Parameters

opcode: Specifies an opcode in the range of 1 to 2static-length-1, in which the static-length argument is configured by using the locator command.

end: Specifies the End type.

end-x: Specifies the End.X type.

end-coc32: Specifies the End (COC32) type.

end-x-coc32: Specifies the End.X (COC32) type.

end-coc-none: Specifies the End (COCNONE) type.

end-x-coc-none: Specifies the End.X (COCNONE) type.

end-dt4: Specifies the End.DT4 type.

end-dt46: Specifies the End.DT46 type.

end-dt6: Specifies the End.DT6 type.

end-dx4: Specifies the End.DX4 type.

end-dx6: Specifies the End.DX6 type.

end-dx2: Specifies the End.DX2 type.

end-dx2l: Specifies the End.DX2L type.

end-dt2m: Specifies the End.DT2M type.

end-dt2u: Specifies the End.DT2U type.

end-dt2ul: Specifies the End.DT2UL type.

end-m: Specifies the End.M type.

end-op: Specifies the End.OP type.

no-flavor: Specifies an SRv6 SID that does not carry any flavors.

psp: Enables the penultimate SRv6 node to remove the SRH.

psp-usp-usd: Specifies an SRv6 SID that carries the PSP, USP, and USD flavors.

interface interface-type interface-number: Specifies an output interface.

nexthop nexthop-ipv4-address: Specifies a next hop IPv4 address.

nexthop nexthop-ipv6-address: Specifies a next hop IPv6 address.

vpn-instance vpn-instance-name: Specifies the MPLS L3VPN instance to which the SRv6 SIDs belong. The vpn-instance-name argument is a case-sensitive string of 1 to 31 characters. The specified VPN instance must exist. If the SRv6 SIDs belong to the public network, do not specify this option.

evpn: Specifies EVPN routes. If you do not specify this keyword, the command specifies the SRv6 SIDs of VPNv4 or VPNv6 routes.

l3vpn-evpn: Specifies EVPN routes, VPNv4 routes, and VPNv6 routes.

xconnect-group group-name: Specifies the cross-connect group to which the SRv6 SIDs belong. The group-name argument represents the cross-connect group name, a case-sensitive string of 1 to 31 characters. The name cannot contain a hyphen (-). The specified cross-connect group must exist.

connection connection-name: Specifies the cross-connect to which the SRv6 SIDs belong. The connection-name argument represents the cross-connect name, a case-sensitive string of 1 to 20 characters. The name cannot contain a hyphen (-). The specified cross-connect must exist.

vsi vsi-name: Specifies the VSI to which the SRv6 SIDs belong. The vsi-name argument represents the VSI name, a case-sensitive string of 1 to 31 characters. The specified VSI must exist.

mirror-locator ipv6-address prefix-length: Specifies a protected locator by its IPv6 address prefix and prefix length. The ipv6-address argument represents the IPv6 address prefix. The prefix-length argument represents the prefix length, in the range of 32 to 120. Make sure the specified locator is the same as the locator on a protected node.

Usage guidelines

An SRv6 locator and its opcode and argument generate unique SRv6 SIDs. SRv6 SIDs form local SID forwarding table entries.

Use this command to configure the opcode of static SRv6 SIDs on a locator. The number of static SRv6 SIDs is determined by the static static-length option in the locator command.

You can execute the opcode command multiple times with the end-m keyword to specify multiple protected locators for the same opcode. Each protected locator represents one or multiple remote SRv6 SIDs that require protection. A protected locator can be specified only for one opcode. Different opcodes cannot have protected locators belonging to the same subnet.

To modify the opcode of static SRv6 SIDs on a locator, you must first delete the original opcode by using the undo opcode command.

To configure End (COC32) SRv6 SIDs or End.X (COC32) SRv6 SIDs, you must also perform the following tasks:

· Enable SRv6 compression by using the srv6 compress enable command.

· Configure the G-SID common prefix length by using the locator command.

To configure End (COCNONE) SRv6 SIDs or End.X (COCNONE) SRv6 SIDs, you must also perform the following tasks:

· Enable SRv6 compression by using the srv6 compress enable command.

· Configure the locator to allocate both compressible and non-compressible SRv6 SIDs.

End (COCNONE) and End.X (COCNONE) SIDs are allocated from the compressible SRv6 SID space. End (COCNONE) SIDs and End.X (COCNONE) SIDs have the same function as End SIDs and End.X SIDs, respectively.

When you configure End.X SIDs or End.X_COC32 SIDs, you can specify different output interfaces and next hops for the same opcode. When packets are forwarded as instructed by the End.X SIDs or End.X_COC32 SIDs, they are load shared among those output interfaces based on the specified weights. For example, assume you configure End.X SID a, End.X SID b, and End.X SID c and set their weights for them as x, y, z, respectively. Then, the proportion of the traffic forwarded through End.X SID a is x/(x+y+z).

When you configure End.X SIDs or End.X_COC32 SIDs, follow these restrictions and guidelines:

· If you specify the same opcode and different output interfaces and next hops, you cannot configure the same path index for the SIDs.

· If you specify the same opcode and different output interfaces and next hops, you must configure the same no-psp and no-flavor setting for the SIDs.

· If you specify the same opcode and the same output interface and next hop, you cannot change the path index by repeating this command. To change the path index for a opcode, use the undo opcode command to delete the opcode, and then execute the opcode command again to specify a new path index.

For a COC-both locator, you can set the same opcode for the following SIDs:

· End SID and End (COC32) SID.

· End SID and End (COCNONE) SID.

· End.X SID and End.X (COC32) SID.

· End.X SID and End.X (COCNONE) SID.

Examples

# Configure End SRv6 SIDs, and set the opcode to 64. Configure End.X SRv6 SIDs, set the opcode to 128, and configure GigabitEthernet 1/0/1 as the output interface and 2001::1 as the next hop IPv6 address.

<Sysname> system-view

[Sysname] segment-routing ipv6

[Sysname-segment-routing-ipv6] locator test ipv6-prefix 100:: 64 static 32

[Sysname-segment-routing-ipv6-locator-test] opcode 64 end no-flavor

[Sysname-segment-routing-ipv6-locator-test] opcode 128 end-x interface gigabitethernet 1/0/1 nexthop 2001::1 no-flavor

Related commands

locator

segment-routing ipv6

srv6 compress enable

ospfv3 fast-reroute ti-lfa disable

Use ospfv3 fast-reroute ti-lfa disable to prevent an OSPFv3 interface from participating in TI-LFA calculation.

Use undo ospfv3 fast-reroute ti-lfa disable to allow an OSPFv3 interface to participate in TI-LFA calculation.

Syntax

ospfv3 fast-reroute ti-lfa disable [ instance instance-id ]

undo ospfv3 fast-reroute ti-lfa disable [ instance instance-id ]

Default

An OSPFv3 interface participates in TI-LFA calculation.

Views

Interface view

Predefined user roles

network-admin

Parameters

instance instance-id: Specifies an instance by its ID, in the range of 0 to 255. The default value is 0.

Examples

# Prevent GigabitEthernet1/0/1 from participating in TI-LFA calculation.

<Sysname> system-view

[Sysname] interface gigabitethernet 1/0/1

[Sysname-GigabitEthernet1/0/1] ospfv3 1 area 0

[Sysname-GigabitEthernet1/0/1] ospfv3 fast-reroute ti-lfa disable

path-mtu

Use path-mtu to set the SRv6 path MTU.

Use undo path-mtu to restore the default.

Syntax

path-mtu mtu-value

undo path-mtu

Default

The SRv6 path MTU is 9600 bytes.

Views

SRv6 view

Predefined user roles

network-admin

Parameters

mtu-value: Sets the path MTU, in bytes. The value range for this argument is 1280 to 9600.

Usage guidelines

This command specifies the maximum bytes that can be contained in an SRv6 tunneled packets.

The transit nodes do not fragment SRv6 tunneled packets. If a packet is larger than the MTU of the output interface, the packet will be discarded. If the MTU is too small, the bandwidth is not sufficiently used. To address these issues, use this command to set an appropriate SRv6 path MTU.

Examples

# Set the SRv6 path MTU to 2000 bytes.

<Sysname> system-view

[Sysname] segment-routing ipv6

[Sysname-segment-routing-ipv6] path-mtu 2000

path-mtu reserved

Use path-mtu reserved to specify a reserved MTU for SRv6 path MTU.

Use undo path-mtu reserved to restore the default.

Syntax

path-mtu reserved [ reserved-value ]

undo path-mtu reserved

Default

No reserved MTU is specified for SRv6 path MTU.

Views

SRv6 view

Predefined user roles

network-admin

Parameters

reserved-value: Specifies an MTU value, in bytes. The value range for this argument is 0 to 8320.The default value is 72 bytes if this argument is not specified.

Usage guidelines

Use this command in the TI-LFA scenario. When packets are switched to the backup path after the primary path fails, the device reconstrcts an IPv6 header and SRH for the packets. As a result, packet drop might occur because the packet size has exceeded the MTU. To resolve this issue, configure a reserved MTU on the source node to reserve bytes for adding a new SRH to SRv6 packets in case of primary path failure.

The SRv6 path MTU minus the reserved MTU is the active MTU. Make sure the active MTU is equal to or greater than 1280 bytes.

The effective MTU for SRv6 packets on the source node is the smaller value from the following values:

· The active MTU.

· The IPv6 MTU of the physical output interface.

For example, if the SRv6 path MTU is 1600 bytes and the reserved MTU is 100 bytes, the active MTU is 1500 bytes.

· If the IPv6 MTU of the physical output interface is equal to or greater than the 1500 bytes, the effective MTU on the source node is 1500 bytes.

· If the IPv6 MTU of the physical output interface is smaller than 1500 bytes, the effective MTU on the source node is the IPv6 MTU of the physical output interface.

Examples

# Reserve 200 bytes for SRv6 path MTU.

<Sysname> system-view

[Sysname] segment-routing ipv6

[Sysname-segment-routing-ipv6] path-mtu reserved 200

peer egress-engineering srv6

Use peer egress-engineering srv6 to enable SRv6 BGP-EPE.

Use undo peer egress-engineering srv6 to disable SRv6 BGP-EPE.

Syntax

peer group-name egress-engineering srv6

undo peer group-name egress-engineering srv6

peer ipv6-address [ prefix-length ] egress-engineering srv6 [ locator locator-name | static-sid { psp psp-sid | no-psp-usp no-psp-usp-sid } * ]

undo peer ipv6-address [ prefix-length ] egress-engineering srv6 [ locator | static-sid { psp | no-psp-usp } * ]

Default

SRv6 BGP-EPE is disabled.

Views

BGP instance view

Predefined user roles

network-admin

Parameters

group-name: Specifies a peer group by its name, a case-sensitive string of 1 to 47 characters. The specified peer group must already exist.

ipv6-address: Specifies a peer by its IPv6 address. The specified peer must already exist.

prefix-length: Specifies the prefix length, in the range of 0 to 128. To specify dynamic peers within a subnet, you must specify both the ipv6-address and prefix-length arguments.

locator locator-name: Specifies a locator by its name. If you specify a locator, the device can dynamically allocate an End.X SID in the locator to the peer.

static-sid: Specifies a static SRv6 SID for the peer.

psp psp-sid: Specifies an End.X SID and enables PSP to remove the SRH on penultimate segment.

no-psp-usp no-psp-usp-sid: Specifies an End.X SID and disables PSP and USP. The SRH is not removed on the penultimate segment or the ultimate segment.

Usage guidelines

This command enables the device to allocate PeerNode SIDs and PeerAdj SIDs to peers.

If you do not specify any parameters, the device will dynamically allocate SRv6 SIDs to peers. The SRv6 SIDs belong to the locator specified by using the segment-routing ipv6 egress-engineering locator command in BGP instance view.

When you use the peer egress-engineering srv6 command for a peer, follow these restrictions and guidelines:

· If you use this command to specify multiple locators for that peer, only the most recent configuration takes effect.

· If you use this command to specify multiple static SRv6 SIDs and the SIDs belong to different types, all types of SRv6 SIDs can take effect. For the same type of SRv6 SIDs, only the most recent configuration takes effect.

If you specify a static SRv6 SID for a peer, the specified static SRv6 SID must belong to the locator specified by using the segment-routing ipv6 egress-engineering locator command in BGP instance view. To identify whether the static SRv6 SID takes effect, use the display bgp egress-engineering ipv6 command. If the static SRv6 SID does not take effect, the static SRv6 SID has been used by other protocols. Before the static SRv6 SID is released, BGP-EPE does not allocate a dynamic SRv6 SID. After the static SRv6 SID is released, first use the undo peer egress-engineering srv6 command to remove the original static SRv6 SID configuration. Then, use the peer egress-engineering srv6 command to reconfigure the static SRv6 SID.

The static SRv6 SIDs specified by using the following commands cannot be the same:

· peer egress-engineering srv6.

· egress-engineering srv6 peer-set.

Examples

# Enable SRv6 BGP-EPE.

<Sysname> system-view

[Sysname] bgp 100

[Sysname-bgp-default] peer 1::1 egress-engineering srv6

Related commands

egress-engineering srv6 peer-set

segment-routing ipv6 egress-engineering locator

peer peer-set

Use peer peer-set to add a peer to a BGP-EPE SRv6 peer set.

Use undo peer peer-set to remove a peer from a BGP-EPE SRv6 peer set.

Syntax

peer { ipv6-address [ prefix-length ] } peer-set srv6-peer-set-name

undo peer { ipv6-address [ prefix-length ] } peer-set

Default

No peers are added to a BGP-EPE SRv6 peer set.

Views

BGP instance view

Predefined user roles

network-admin

Parameters

ipv6-address: Specifies a peer by its IPv6 address. The peer must exist.

prefix-length: Specifies a prefix length in the range of 0 to 128. To specify a subnet, you must specify both the ipv6-address and prefix-length arguments.

peer-set-name: Specifies a BGP-EPE SRv6 peer set by its name, a case-sensitive string of 1 to 63 characters.

Usage guidelines

A PeerSet SID can be allocated to a BGP-EPE SRv6 peer set. When the device forwards traffic based on the PeerSet SID, it distributes the traffic among the peers in the peer set for load sharing.

Before adding a peer to a BGP-EPE SRv6 peer set, you must enable SRv6 BGP-EPE for that peer.

To change the BGP-EPE SRv6 peer set for a peer, you must first use undo peer peer-set command to remove that peer from the original BGP-EPE SRv6 peer set.

Examples

# Add peer 10::1 to the BGP-EPE SRv6 peer set named abc.

<Sysname> system-view

[Sysname] bgp 100

[Sysname-bgp-default] peer 10::1 peer-set abc

Related commands

egress-engineering srv6 peer-set

peer egress-engineering srv6

remote-locator

Use remote-locator to create a remote SRv6 locator and enter its view, or enter the view of an existing remote SRv6 locator.

Use undo remote-locator to delete a remote SRv6 locator.

Syntax

remote-locator remote-locator-name [ ipv6-prefix ipv6-address prefix-length [ args args-length | static static-length ] * ]

undo remote-locator remote-locator-name

Default

No remote SRv6 locators exist.

Views

SRv6 view

Predefined user roles

network-admin

Parameters

remote-locator-name: Specifies a remote locator name, a case-sensitive string of 1 to 31 characters.

args args-length: Specifies an argument length. The value range for the args-length argument depends on the value of the prefix-length argument and varies by device model.

static static-length: Specifies the static length. The value range for the static-length argument varies by the value of the prefix-length argument and varies by device model.

Usage guidelines

In the EVPN VPWS over SRv6 scenario, if the PEs cannot use BGP routes to establish SRv6 PWs, you need to establish a static SRv6 PW between the PEs to ensure correct packet forwarding. Because the PEs cannot transmit SRv6 SID information through BGP routes, you need to configure the SRv6 SIDs assigned by the local and remote ends to the cross-connect. To configure the SRv6 SID assigned by the local end, configure the opcode command for the associated locator. To configure the SRv6 SID assigned by the remote end, create the remote locator, and then use the peer command to specify the remote locator in static SRv6 configuration view of the cross-connect.

The remote locator setting on the local PE must be the same as the locator setting on the remote PE. The local and remote PEs must use consistent locator, remote locator, and SRv6 SID settings. For example:

· Configuration on the local PE (PE 1):

locator pe1 ipv6-prefix 100:: 64 static 32

opcode 1 end.dx2 xconnect-group pe1 connection pe1

remote-locator pe2 ipv6-prefix 200:: 64 static 32

xconnect-group pe1

connection pe1

static-srv6 local-service-id 1 remote-service-id 2

peer 2::2 end-dx2-sid remote-locator pe2 opcode 1

· Configuration on the remote PE (PE 2):

locator pe2 ipv6-prefix 200:: 64 static 32

opcode 1 end.dx2 xconnect-group pe2 connection pe2

remote-locator pe1 ipv6-prefix 100:: 64 static 32

xconnect-group pe2

connection pe2

static-srv6 local-service-id 1 remote-service-id 2

peer 1::1 end-dx2-sid remote-locator pe1 opcode 1

The locator for the local PE is 100::/64, and the remote locator is 200::/6. The locator for the remote PE is 200::/64, and the remote locator is 100::/6. The SRv6 SID assigned by the local PE to the cross-connect is End.DX2 SID 100::1. The SRv6 SID assigned by the remote PE to the cross-connect is End.DX2 SID 200::1.

When deploying an SRv6 PW in the EVPN VPWS over SRv6 scenario for packet forwarding, make sure the destination IPv6 address for packets is the SRv6 SID of the remote locator. Upon receiving the packets, the remote PE searches the local locator SID forwarding table, and perform one of the following operations:

· If a matching SRv6 SID is found in the local locator, the remote PE forwards the packets based on the SRv6 SID.

· If no matching SRv6 SID is found in the local locator, the remote PE discards the packets.

When you create a remote locator, you must specify an IPv6 address prefix, prefix length, and static length for the remote locator. When you enter the view of an existing remote SRv6 locator, you only need to specify the remote locator name.

Each remote locator must have a unique name.

Do not specify the same IPv6 address prefix for different remote locators. In addition, the IPv6 address prefixes of different remote locators cannot overlap.

Do not specify the same IPv6 address prefix for the remote locator and local locator. In addition, the IPv6 address prefixes of the remote locator and local locator cannot overlap.

Examples

# Configure remote locator test1, setting the IPv6 address prefix to 100::, prefix length to 64, and static length to 32, and enter the remote SRv6 locator view of this locator.

<Sysname> system-view

[Sysname] segment-routing ipv6

[Sysname-segment-routing-ipv6] remote-locator test1 ipv6-prefix 200:: 64 static 32

[Sysname-segment-routing-ipv6-rmtlocator-test1]

Related commands

locator

opcode

peer

reserved-sid-start

Use reserved-sid-start to reserve SRv6 SIDs.

Use undo reserved-sid-start to restore the default.

Syntax

reserved-sid-start sid-value count reserved-sid-count

undo reserved-sid-start

Default

No SRv6 SIDs are reserved.

Views

SRv6 locator view

Predefined user roles

network-admin

Parameters

sid-value: Specifies the start SRv6 SID for reservation.

count reserved-sid-count: Specifies the number of reserved SRv6 SIDs, in the range of 1 to 4294967295.

Usage guidelines

Application scenarios

When the device generates an SRv6 TE policy based on received SRv6 TE policy routes, it must assign a BSID to the SRv6 TE policy. Use this command to reserve SRv6 SIDs in COC-both locators. The reserve SRv6 SIDs can only be assigned to SRv6 TE policies as BSIDs.

Restrictions and guidelines

To use this command on a locator, you must enable the locator to allocate both compressible and non-compressible SRv6 SIDs. In addition, make sure all reserved SRv6 SIDs belong to the non-compressible dynamic SRv6 SID range for the locator. To obtain the range, use the display segment-routing ipv6 locator command.

When you allocate reserved SRv6 SIDs in the non-compressible dynamic SRv6 SID range, make sure the length of the reserved SRv6 SIDs does not exceed 32 bits (all 32 bits are set to 1). If the length exceeds 32 bits, the reserved SIDs might not be allocated correctly or might not be as expected. Assume that the start value for non-compressible dynamic SRv6 SIDs is 100:0:0:1::100 and the end value is 100::1:0:FFFF:FFFF:FFFF, the dynamic portion length is 40 bits, and the static portion length is 8 bits, without the Args portion. If the start SRv6 SID for reservation is 100::1:0:FF:FFFF:FFFE , the start SRv6 SID for reservation occupies 32 bits (all 32 bits are set to 1) in the nonocmpressible dynamic SRv6 SID range. If you set the number of reserved SRv6 SIDs is 20, no reserved SRv6 SIDs can be allocated.

Examples

# Configure the device to reserve 1000 SRv6 SIDs starting from 100:200:DB8:ABCD::1:0 for locator abc.

<Sysname> system-view

[Sysname] segment-routing ipv6

[Sysname-segment-routing-ipv6] locator abc

[Sysname-segment-routing-ipv6-locator-abc] reserved-sid-start 100:200:DB8:ABCD::1:0 count 1000

Related commands

display segment-routing ipv6 locator

reset segment-routing ipv6 local-sid forwarding statistics

Use reset segment-routing ipv6 local-sid forwarding statistics to clear traffic forwarding statistics for all local SRv6 SIDs.

Syntax

reset segment-routing ipv6 local-sid forwarding statistics

Views

User view

Predefined user roles

network-admin

Examples

# Clear traffic forwarding statistics for all local SRv6 SIDs.

<Sysname> reset segment-routing ipv6 local-sid forwarding statistics

Related commands

display segment-routing ipv6 local-sid forwarding statistics

local-sid forwarding statistics enable

local-sid forwarding statistics interval

router-id

Use router-id to configure the router ID for an IPv6 IS-IS process and enable IPv6 TE.

Use undo router-id to remove the router ID from an IPv6 IS-IS process and disable IPv6 TE.

Syntax

router-id ipv6-address

undo router-id

Default

No router ID is configured for an IPv6 IS-IS process and IPv6 TE is disabled.

Views

IS-IS IPv6 address family view

Predefined user roles

network-admin

Parameters

ipv6-address: Specifies an IPv6 router ID.

Usage guidelines

The IPv6 router ID must be unique in the IPv6 network.

The IPv6 router ID determines the source and destination addresses of the SRv6 tunnel distributed to the IGP. The destination address of the SRv6 tunnel must be the same as the IPv6 router ID of the destination node.

To avoid route calculation errors when multiple IS-IS P2P neighbors exist between two devices, configure the advertise link-attributes or router-id command to enable IS-IS to advertise the IP address of the local interface connected to the peer to the neighbors.

Configuring an IPv6 route ID on a router also enables the IPv6 TE feature on that router. After the SRv6 tunnel participates in IGP route calculation, traffic can be directed to the SRv6 tunnel.

Examples

# Configure the router ID for an IPv6 IS-IS process and enable IPv6 TE.

<Sysname> system-view

[Sysname] isis 1

[Sysname-isis-1] cost-style wide

[Sysname-isis-1] address-family ipv6

[Sysname-isis-1-ipv6] router-id 1000::1

segment-routing ipv6 (system view)

Use segment-routing ipv6 to enable SRv6 and enter SRv6 view.

Use undo segment-routing ipv6 to disable SRv6.

Syntax

segment-routing ipv6

undo segment-routing ipv6

Default

SRv6 is disabled.

Views

System view

Predefined user roles

network-admin

Usage guidelines

After you execute this command, you can configure locators in SRv6 view. Then, you can configure the opcode portion in SRv6 locator view to generate local SID forwarding table entries.

You cannot disable SRv6 when a locator in SRv6 view has dynamic SRv6 SIDs that are being used.

Examples

# Enable SRv6 and enter SRv6 view.

<Sysname> system-view

[Sysname] segment-routing ipv6

[Sysname-segment-routing-ipv6]

segment-routing ipv6 advertise l3-service-sid

Use segment-routing ipv6 advertise l3-service-sid to configure IS-IS to advertise SRv6 SIDs for L3 services.

Use undo segment-routing ipv6 advertise l3-service-sid to restore the default.

Syntax

segment-routing ipv6 advertise l3-service-sid

undo segment-routing ipv6 advertise l3-service-sid

Default

IS-IS does not advertise SRv6 SIDs for L3 services.

Views

IS-IS IPv6 unicast address family view

Predefined user roles

network-admin

Usage guidelines

Use this command only when the cost style of IS-IS is wide, compatible, or wide-compatible.

This command is supported only by the IS-IS processes in the public network.

This command enables IS-IS to advertise SRv6 SIDs for L3 services in LSPs. With this command, IS-IS reports link state information for L3 service-related SRv6 SIDs to the controller to meet the requirements for applications that need the information. IS-IS can advertise only End.DT4 SIDs, End.DT6 SIDs, and End.DT46 SIDs in the current software version.

Examples

# Configure IS-IS to advertise SRv6 SIDs for L3 services.

<Sysname> system-view

[Sysname] isis 1

[Sysname-isis-1] address-family ipv6

[Sysname-isis-1-ipv6] segment-routing ipv6 advertise l3-service-sid

Related commands

cost-style (Layer 3—IP Routing Command Reference)

segment-routing ipv6 compatible locator-fixed-length

Use segment-routing ipv6 compatible locator-fixed-length to enable compatibility of the Locator field in SRv6 Locator TLVs with earlier drafts.

Use undo segment-routing ipv6 compatible locator-fixed-length to restore the default.

Syntax

segment-routing ipv6 compatible locator-fixed-length

undo segment-routing ipv6 compatible locator-fixed-length

Default

The Locator field in SRv6 locator LSAs is of variable length, with a maximum of 128 bytes.

Views

OSPFv3 view

Predefined user roles

network-admin

Usage guidelines

Application scenarios

To avoid interoperability issues caused by differences in the Locator field length in the SRv6 Locator TLV when a third-party device or an H3C device with an older software version interoperates with an H3C device with a newer software version, you can this command to have the new devices compatible with older draft standards.

Operating mechanism

In the OSPFv3 protocol, the SRv6 Locator TLV is carried in the SRv6 Locator LSA, used to announce the network segment and mask of the locator to which the SRv6 SID belongs, as well as the End SID related to that locator.

The length of the Locator field in SRv6 Locator TLVs is defined as variable in draft-ietf-lsr-ospfv3-srv6-extensions-12 and later drafts and can be up to 128 bits. The length of the Locator field can vary based on the configured locator segment length. However, the length is fixed at 128 bits in draft-ietf-lsr-ospfv3-srv6-extensions-11 and earlier drafts. For example, if you specify the prefix-length argument as 96 in the locator command, the default Locator field length is 96 bits and the remaining 32 bits are not required in the TLV when you apply the locator to OSPFv3 and advertise it. After this command is configured, the Locator field must be 128-bit long and the remaining 32 bits are all set to zero.

Restrictions and guidelines

For compatibility with draft-ietf-lsr-ospfv3-srv6-extensions-08 and earlier drafts, you must both this command and the segment-routing ipv6 private-srv6-extensions compatible command.

Examples

# Enable compatibility of the Locator field in SRv6 Locator TLVs with earlier drafts.

<Sysname> system-view

[Sysname] ospfv3 1

[Sysname-ospfv3-1] segment-routing ipv6 compatible locator-fixed-length

Related commands

segment-routing ipv6 private-srv6-extensions compatible

segment-routing ipv6 egress-engineering locator

Use segment-routing ipv6 egress-engineering locator to apply a locator to BGP-EPE.

Use undo segment-routing ipv6 egress-engineering locator to restore the default.

Syntax

segment-routing ipv6 egress-engineering locator locator-name

undo segment-routing ipv6 egress-engineering locator

Default

No locator is applied to BGP-EPE.

Views

BGP instance view

Predefined user roles

network-admin

Parameters

locator-name: Specifies a locator by its name, a case-sensitive string of 1 to 31 characters.

Usage guidelines

Use this command to restrict the range of End.X SIDs that can be allocated to BGP-EPE SRv6 peer sets and BGP-EPE-enabled peers in a BGP instance. All static SRv6 SIDs configured for the BGP-EPE SRv6 peer sets and peers must belong to the locator specified by using this command.

To dynamically allocate End.X SIDs from the specified locator:

· Do not configure a static SRv6 SID when you create a BGP-EPE SRv6 peer set by using the egress-engineering srv6 peer-set command.

· Do not specify a locator or configure a static SRv6 SID when you enable SRv6 BGP-EPE for a peer by using the peer egress-engineering srv6 command.

When you execute this command to apply a locator to BGP-EPE, BGP-EPE takes the following actions:

· If static SRv6 SIDs are configured in the locator, BGP-EPE preferentially uses static SRv6 SIDs.

· If the static SRv6 SIDs configured in the locator are End.X SIDs with the same opcode and different output interfaces and next hops, BGP-EPE does not use the static SRv6 SIDs but dynamically collocates SRv6 SIDs.

· If no static SRv6 SIDs are configured, BGP-EPE dynamically allocates SRv6 SIDs.

Examples

# Apply locator test to BGP-EPE.

<Sysname> system-view

[Sysname] bgp 100

[Sysname-bgp-default] segment-routing ipv6 egress-engineering locator test

Related commands

egress-engineering srv6 peer-set

peer egress-engineering srv6

segment-routing ipv6 end-x delete-delay

Use segment-routing ipv6 end-x delete-delay to enable dynamic End.X SID deletion delay and set the delay time.

Use undo segment-routing ipv6 end-x delete-delay to disable dynamic End.X SID deletion delay.

Syntax

segment-routing ipv6 end-x delete-delay [ time-value ]

undo segment-routing ipv6 end-x delete-delay

Default

Dynamic End.X SID deletion delay is enabled. The delay time is 1800 seconds.

Views

IS-IS IPv6 address family view

OSPFv3 process view

Predefined user roles

network-admin

Parameters

time-value: Sets the dynamic End.X SID deletion delay time in seconds, in the range of 1 to 3600. The default value is 1800.

Usage guidelines

Packet loss occurs between OSPFv3 or IS-IS neighbors if the neighbors frequently delete and request dynamically allocated End.X SIDs for the links between them because of neighbor flapping. To resolve this issue, set a delay timer for deleting dynamically allocated End.X SIDs when the neighbors are disconnected. If the neighbors are still disconnected when the delay timer expires, the device deletes the dynamically allocated End.X SIDs.

The device always immediately deletes automatically allocated End.X SIDs without any delay in the following situations:

· The reset ospfv3 process command is executed.

· The reset isis all command is executed.

· Interfaces are deleted or removed. For example, an interface module is removed, or a subinterface is deleted.

Examples

# Enable dynamic End.X SID deletion delay for IPv6 IS-IS process 1.

<Sysname> system-view

[Sysname] isis 1

[Sysname-isis-1] address-family ipv6

[Sysname-isis-1-ipv6] segment-routing ipv6 end-x delete-delay

# Enable dynamic End.X SID deletion delay for OSPFv3 process 1.

<Sysname> system-view

[Sysname] ospfv3 1

[Sysname-ospfv3-1] segment-routing ipv6 end-x delete-delay

Related commands

reset isis all (Layer 3—IP Routing Command Reference)

reset ospfv3 process (Layer 3—IP Routing Command Reference)

segment-routing ipv6 locator (IS-IS IPv6 address family view)

Use segment-routing ipv6 locator to apply an SRv6 locator to an IPv6 IS-IS process.

Use undo segment-routing ipv6 locator to remove the specified SRv6 locator from an IPv6 IS-IS process.

Syntax

segment-routing ipv6 locator locator-name [ level-1 | level-2 ] [ auto-sid-coc32 [ additive ] | auto-sid-coc-both { all | coc32 | coc32-all | coc32-none } | auto-sid-disable ]

undo segment-routing ipv6 locator locator-name

Default

No SRv6 locators are applied to an IPv6 IS-IS process.

Views

IS-IS IPv6 address family view

Predefined user roles

network-admin

Parameters

locator-name: Specifies a locator by its name, a case-sensitive string of 1 to 31 characters.

level-1: Specifies the level-1 area.

level-2: Specifies the level-2 area.

auto-sid-coc32: Dynamically allocates a compressible End (COC32) or End.X (COC32) SRv6 SID from the specified COC32 locator.

· For dynamic End SID allocation, IS-IS will allocate two End (COC32) SIDs of the no-flavor and psp flavor types.

· For dynamic End.X SID allocation, IS-IS will allocate two End.X (COC32) SIDs of the no-flavor and psp flavor types.

additive: Dynamically allocates a common SRv6 SID from the specified COC32 locator in addition to the compressible SRv6 SID.

· For dynamic End SID allocation, IS-IS will allocate the following SIDs:

¡ Two End (COC32) SIDs of the no-flavor and psp flavor types.

¡ Three End SIDs of the no-flavor, psp, and psp-usp-usd flavor types.

· For dynamic End.X SID allocation, IS-IS will allocate the following SIDs:

¡ Two End.X (COC32) SIDs of the no-flavor and psp flavor types.

¡ Three End.X SIDs of the no-flavor, psp, and psp-usp-usd flavor types.

If you do not specify the additive keyword, the device only dynamically allocates a compressible End (COC32) or End.X (COC32) SRv6 SID.

auto-sid-coc-both: Dynamically allocates the specified type of SRv6 SIDs from the specified COC-both locator.

· coc32: Specifies the compressible SRv6 SID type.

¡ For dynamic End SID allocation, IS-IS will allocate two End (COC32) SIDs of the no-flavor and psp flavor types.

¡ For dynamic End.X SID allocation, IS-IS will allocate two End.X (COC32) SIDs of the no-flavor and psp flavor types.

· coc32-none: Specifies the non-compressible End (COCNONE) and End.X (COCNONE) SRv6 SID types.

¡ For dynamic End SID allocation, IS-IS will allocate three End (COCNONE) SIDs of the no-flavor, psp, and psp-usp-usd flavor types.

¡ For dynamic End.X SID allocation, IS-IS will allocate three End.X (COCNONE) SIDs of the no-flavor, psp, and psp-usp-usd flavor types.

· coc32-all: Specifies both the compressible and non-compressible SRv6 SID types.

¡ For dynamic End SID allocation, IS-IS will allocate the following SIDs:

- Two End (COC32) SIDs of the no-flavor and psp flavor types.

- Three End (COCNONE) SIDs of the no-flavor, psp, and psp-usp-usd flavor types.

¡ For dynamic End.X SID allocation, IS-IS will allocate the following SIDs:

- Two End.X (COC32) SIDs of the no-flavor and psp flavor types.

- Three End.X (COCNONE) SIDs of the no-flavor, psp, and psp-usp-usd flavor types.

· all: Specifies the common, compressible, and non-compressible SRv6 SID types.

¡ For dynamic End SID allocation, IS-IS will allocate the following SIDs:

- Two End (COC32) SIDs of the no-flavor and psp flavor types.

- Three End (COCNONE) SIDs of the no-flavor, psp, and psp-usp-usd flavor types.

- Three End SIDs of the no-flavor, psp, and psp-usp-usd flavor types.

¡ For dynamic End.X SID allocation, IS-IS will allocate the following SIDs:

- Two End.X (COC32) SIDs of the no-flavor and psp flavor types.

- Three End.X (COCNONE) SIDs of the no-flavor, psp, and psp-usp-usd flavor types.

- Three End.X SIDs of the no-flavor, psp, and psp-usp-usd flavor types.

auto-sid-disable: Disables automatic SRv6 SID allocation, immediately releases allocated End SIDs, and releases allocated End.X SIDs in 1800 seconds. If you do not specify this keyword, the device allows dynamically allocated SRv6 SIDs. If static SRv6 SIDs are configured when automatic SRv6 SID allocation is enabled, the static SRv6 SIDs take precedence. If no static SRv6 SIDs are configured when automatic SRv6 SID allocation is enabled, the system dynamically allocates SRv6 SIDs.

Usage guidelines

Use this command to enable IPv6 IS-IS to advertise SRv6 SIDs.

If you do not specify a level, this command applies the specified locator to both level-1 and level-2 areas.

Use this command only when the cost style of IS-IS is wide, compatible, or wide-compatible.

Execute this command multiple times to apply multiple locators to an IPv6 IS-IS process so that the process can advertise multiple SRv6 SIDs.

The auto-sid-coc32 keyword takes effect only when the specified locator is a COC32 locator.

The auto-sid-coc-both { all | coc32 | coc32-all | coc32-none } keyword takes effect only when the specified locator is a COC-both locator.

Examples

# Apply locator abc to an IPv6 IS-IS process.

<Sysname> system-view

[Sysname] isis 1

[Sysname-isis-1] cost-style wide

[Sysname-isis-1] address-family ipv6

[Sysname-isis-1-ipv6] segment-routing ipv6 locator abc

Related commands

display segment-routing ipv6 locator

locator

segment-routing ipv6 locator (OSPFv3 process view)

Use segment-routing ipv6 locator to apply an SRv6 locator to an OSPFv3 process.

Use undo segment-routing ipv6 locator to remove the specified SRv6 locator from an OSPFv3 process.

Syntax

segment-routing ipv6 locator locator-name [ auto-sid-disable ]

undo segment-routing ipv6 locator locator-name

Default

No SRv6 locators are applied to an OSPFv3 process.

Views

OSPFv3 process view

Predefined user roles

network-admin

Parameters

locator-name: Specifies a locator by its name, a case-sensitive string of 1 to 31 characters.

auto-sid-disable: Disables automatic SRv6 SID allocation. If you do not specify this keyword, the device allows dynamically allocated SRv6 SIDs. If static SRv6 SIDs are configured when automatic SRv6 SID allocation is enabled, the static SRv6 SIDs take precedence. If no static SRv6 SIDs are configured when automatic SRv6 SID allocation is enabled, the system dynamically allocates SRv6 SIDs.

Usage guidelines

Use this command to enable OSPFv3 to advertise SRv6 SIDs.

Execute this command multiple times to apply multiple locators to an OSPFv3 process so that the process can advertise multiple SRv6 SIDs.

Examples

# Apply locator abc to an OSPFv3 process.

<Sysname> system-view

[Sysname] ospfv3 1

[Sysname-ospfv3-1] segment-routing ipv6 locator abc

Related commands

display segment-routing ipv6 locator

locator

segment-routing ipv6 private-srv6-extensions compatible

Use segment-routing ipv6 private-srv6-extensions compatible to configure the TLVs and flag bits in the OSPFv3 extensions for SRv6 to be compatible with the private protocol.

Use undo segment-routing ipv6 private-srv6-extensions compatible to restore the default.

Syntax

segment-routing ipv6 private-srv6-extensions compatible

undo segment-routing ipv6 private-srv6-extensions compatible

Default

The SRv6 Capabilities TLV type values, Sub TLV type values, and flag bits in OSPFv3 packets follow the definitions in draft-ietf-lsr-ospfv3-srv6-extensions-09.

Views

OSPFv3 view

Predefined user roles

network-admin

Usage guidelines

Operating mechanism

· By default, OSPFv3 protocol packets comply with the most recent OSPFv3 draft standard, and the TLVs and flag bits in the OSPFv3 extensions for SRv6 follow the definitions in draft-ietf-lsr-ospfv3-srv6-extensions-09. The values for SRv6 Capabilities TLV Type, End.X SID Sub-TLV Type, and LAN End.X SID Sub-TLV Type are 20, 31, and 32, respectively. The N flag of the PrefixOptions field in the SRv6 Locator TLV is in the third bit, and the AC flag is in the first bit. In this case, the TLV information in the OSPFv3 extensions for SRv6 is similar to that of other vendors, allowing interoperability.

· With this command configured, the TLVs and flag bits in the OSPFv3 extensions for SRv6 follow the definition in the private protocol. The values for SRv6 Capabilities TLV Type, End.X SID Sub-TLV Type, and LAN End.X SID Sub-TLV Type are 17, 11, and 12, respectively. The N flag of the PrefixOptions field in the SRv6 Locator TLV is in the first bit, and the AC flag is in the second bit. In this case, the TLV information in the OSPFv3 extensions for SRv6 is the same as that on devices that do not use the most recent software version, allowing interoperability.

Restrictions and guidelines

For a successful advertisement of SRv6 locators and SRv6 SIDs, make sure OSPFv3 neighbors follow the same standard.

Examples

# Configure the TLVs and flag bits in the OSPFv3 extensions for SRv6 to be compatible with the private protocol.

<Sysname> system-view

[Sysname] opsfv3 1

[Sysname-ospfv3-1] segment-routing ipv6 private-srv6-extensions compatible

Related commands

segment-routing ipv6 locator (OSPFv3 view)

srv6 compress enable

segment-routing microloop-avoidance enable

Use segment-routing microloop-avoidance enable to enable SR microloop avoidance.

Use undo segment-routing microloop-avoidance enable to disable SR microloop avoidance.

Syntax

In IS-IS IPv6 unicast address family view:

segment-routing microloop-avoidance enable [ level-1 | level-2 ]

undo segment-routing microloop-avoidance enable [ level-1 | level-2 ]

In OSPFv3 process view:

segment-routing microloop-avoidance enable

undo segment-routing microloop-avoidance enable

Default

SR microloop avoidance is disabled.

Views

IS-IS IPv6 unicast address family view

OSPFv3 process view

Predefined user roles

network-admin

Parameters

level-1: Specifies IS-IS Level-1.

level-2: Specifies IS-IS Level-2.

Usage guidelines

After a network failure occurs or recovers, route convergence occurs on relevant network devices. Because of nonsimultaneous convergence on network devices, microloops might be formed. After you configure SR microloop avoidance, the devices will forward traffic along the specified path before route convergence is finished on all the relevant network devices. Because the forwarding path is independent of route convergence, microloops are avoided.

Microloop avoidance after a network failure and a failure recovery is as follows:

· When a network failure occurs, a node enabled with this feature issues the calculated forwarding path to the FIB after route convergence and switches the traffic to the forwarding path after the delay timer times out. Before the timer times out, traffic is forwarded along the TI-LFA FRR backup path to avoid microloops.

· When the failure recovers, a node enabled with this feature also calculates an explicit path that contains SIDs except for the primary forwarding path. Before the timer times out, traffic is forwarded along the backup path to avoid microloops.

If you do not specify the level-1 or level-2 keyword, this command applies to both IS-IS levels.

Examples

# Enable SR microloop avoidance for IPv6 IS-IS process 1.

<Sysname> system-view

[Sysname] isis 1

[Sysname-isis-1] address-family ipv6

[Sysname-isis-1-ipv6] segment-routing microloop-avoidance enable

# Enable SR microloop avoidance for OSPFv3 process 1.

<Sysname> system-view

[Sysname] ospfv3 1

[Sysname-isis-1] address-family ipv6

[Sysname-ospfv3-1] segment-routing microloop-avoidance enable

Related commands

fast-reroute microloop-avoidance enable

segment-routing microloop-avoidance rib-update-delay

Use segment-routing microloop-avoidance rib-update-delay to set the SR microloop avoidance RIB-update-delay time.

Use undo segment-routing microloop-avoidance rib-update-delay to restore the default.

Syntax

In IS-IS IPv6 unicast address family view:

segment-routing microloop-avoidance rib-update-delay delay-time [ level-1 | level-2 ]

undo segment-routing microloop-avoidance rib-update-delay [ level-1 | level-2 ]

In OSPFv3 process view:

segment-routing microloop-avoidance rib-update-delay delay-time

undo segment-routing microloop-avoidance rib-update-delay

Default

The SR microloop avoidance RIB-update-delay time is 5000 milliseconds.

Views

IS-IS IPv6 unicast address family view

OSPFv3 process view

Predefined user roles

network-admin

Parameters

delay-time: Sets the delay time in milliseconds, in the range of 1 to 60000.

level-1: Specifies IS-IS Level-1.

level-2: Specifies IS-IS Level-2.

Usage guidelines

To ensure sufficient time for IGP to complete route convergence, set the SR microloop avoidance RIB-update-delay time. Before the timer expires, faulty relevant devices will forward traffic along the specified path. Upon expiration of the timer and completion of IGP route convergence, traffic will traverse along the IGP-calculated path.

If you do not specify the level-1 or level-2 keyword, this command applies to both IS-IS levels.

Examples

# Set the SR microloop avoidance RIB-update-delay time to 6000 milliseconds for IPv6 IS-IS process 1.

<Sysname> system-view

[Sysname] isis 1

[Sysname-isis-1] address-family ipv6

[Sysname-isis-1-ipv6] segment-routing microloop-avoidance rib-update-delay 6000

# Set the SR microloop avoidance RIB-update-delay time to 6000 milliseconds for OSPFv3 process 1.

<Sysname> system-view

[Sysname] ospfv3 1

[Sysname-isis-1] address-family ipv6

[Sysname-ospfv3-1] segment-routing microloop-avoidance rib-update-delay 6000

Related commands

segment-routing microloop-avoidance enable

snmp-agent trap enable srv6

Use snmp-agent trap enable srv6 to enable SNMP notifications for SRv6.

Use undo snmp-agent trap enable srv6 to disable SNMP notifications for SRv6.

Syntax

snmp-agent trap enable srv6

undo snmp-agent trap enable srv6

Default

SNMP notifications are disabled for SRv6.

Views

System view

Predefined user roles

network-admin

Usage guidelines

To report critical SRv6 events to an NMS, enable SNMP notifications for SRv6. For SRv6 event notifications to be sent correctly, you must also configure SNMP on the device. For more information about SNMP configuration, see Network Management and Monitoring Configuration Guide.

Examples

# Enable SNMP notifications for SRv6.

<Sysname> system-view

[Sysname] snmp-agent trap enable srv6

srv6 compress enable (IS-IS IPv6 address family view)

Use srv6 compress enable to enable SRv6 compression for IPv6 IS-IS.

Use undo srv6 compress enable to disable SRv6 compression for IPv6 IS-IS.

Syntax

srv6 compress enable [ level-1 | level-2 ]

undo srv6 compress enable

Default

SRv6 compression is disabled for IPv6 IS-IS.

Views

IS-IS IPv6 address family view

Predefined user roles

network-admin

Parameters

level-1: Specifies the level-1 area.

level-2: Specifies the level-2 area.

Usage guidelines

If you do not specify a level, this command enables SRv6 compression for both level-1 and level-2 areas.

If IPv6 IS-IS is used to advertise G-SIDs to neighbors, you must use this command to enable SRv6 compression for IPv6 IS-IS.

Use this command only when the cost style of IS-IS is wide, compatible, or wide-compatible.

Before you use this command, apply a locator to IS-IS IPv6 address family view by using the segment-routing ipv6 locator command.

Examples

# Enable SRv6 compression for IPv6 IS-IS.

<Sysname> system-view

[Sysname] isis 1

[Sysname-isis-1] cost-style wide

[Sysname-isis-1] address-family ipv6

[Sysname-isis-1-ipv6] srv6 compress enable

Related commands

segment-routing ipv6 locator (IS-IS IPv6 address family view)

srv6 compress enable (SRv6 view)

Use srv6 compress enable to enable SRv6 compression.

Use undo srv6 compress enable to disable SRv6 compression.

Syntax

srv6 compress enable

undo srv6 compress enable

Default

SRv6 compression is disabled.

Views

SRv6 view

Predefined user roles

network-admin

Usage guidelines

Typically, an address space is reserved for SRv6 SID allocation in an SRv6 subnet. This address space is called an SID space. In the SRv6 subnet, all SIDs are allocated from the SID space. The SIDs have the same prefix (common prefix). The SID common prefix is redundant information in the SRH.

SRv6 compression removes the common prefix from the SIDs in the SID list of the SRH. The remaining part of an SID is called a G-SID. G-SIDs reduce the cost of SRH.

When SRv6 uses the SID list in the SRH to replace the destination address of a packet, it combines the common prefix and the destination G-SID to form a new SID. This new SID is used as the destination address of the packet.

Examples

# Enable SRv6 compression.

<Sysname> system-view

[Sysname] segment-routing ipv6

[Sysname-segment-routing-ipv6] srv6 compress enable

11-Segment Routing Command Reference

anycast enable

display bgp egress-engineering ipv6

display segment-routing ipv6 brief

peer egress-engineering srv6

Application scenarios

Restrictions and guidelines

Application scenarios

Operating mechanism

Restrictions and guidelines

segment-routing ipv6 end-x delete-delay

Operating mechanism

Restrictions and guidelines

srv6 compress enable (SRv6 view)

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