EVPN L3VPN over SRv6 uses SRv6 tunnels to carry EVPN L3VPN services. This technology establishes SRv6 tunnels among geographically dispersed customer sites over the IPv6 backbone network and transparently forwards EVPN L3VPN customer traffic through the tunnels. For more information about EVPN L3VPN configuration, see EVPN Configuration Guide.

Basic principle

Figure 1 shows a typical EVPN L3VPN over SRv6 network.

· PE 1 and PE 2 use MP-BGP to advertise EVPN IP advertisement routes to each other over the IPv6 backbone network. The EVPN IP advertisement routes contain IPv4 or IPv6 VPN routing information and SID information.

· The PEs have a single-hop SRv6 tunnel between them and they use the SRv6 tunnel to forward EVPN L3VPN traffic across sites.

· The devices in the IPv6 backbone network forward the SRv6-encapsulated EVPN L3VPN traffic through the optimal path calculated by IGP.

EVPN L3VPN over SRv6 connects geographically dispersed sites that belong to the same VPN over the IPv6 backbone network.

Figure 1 Network diagram

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Route advertisement

The route advertisement process of IPv4 EVPN L3VPN over SRv6 is similar to that of IPv6 EVPN L3VPN over SRv6. This section uses IPv4 EVPN L3VPN over SRv6 to illustrate the process.

As shown in Figure 1, local routes of CE 1 are advertised to CE 2 by using the following process:

1. CE 1 uses static routing, RIP, OSPF, IS-IS, EBGP, or IBGP to advertise routes of the local site to PE 1.

2. PE 1 stores the routes advertised by CE 1 to the routing table of VPN 1. Then, PE 1 converts the routes to BGP EVPN IP advertisement routes and advertises the IP advertisement routes to PE 2 by using MP-BGP. The IP advertisement routes carry RD, RT, and SID attributes (the SID attribute is used as the private network label).

¡ If next hop-based dynamic SID allocation is not used, all private network routes of the VPN instance are allocated the same End.DT4 or End.DT46 SID.

¡ If next hop-based dynamic SID allocation is used, private network routes with the same next hop are allocated the same End.DX4 SID in the VPN instance.

3. PE 2 adds the IP advertisement routes to the routing table of VPN 1, converts the IP advertisement routes to IPv4 routes, and advertises the IPv4 routes to CE 2.

4. By adding the received IPv4 routes to the routing table, CE 2 learns the private network routes of CE 1.

Packet forwarding

EVPN L3VPN over SRv6 supports the following route recursion modes:

· SRv6 BE mode.

· SRv6 TE mode.

· SRv6 TE and SRv6 BE hybrid mode.

· SRv6 TE and SRv6 BE FRR mode.

· SRv6 TE and SRv6 BE multilevel FRR modes.

The packet forwarding process differs by the route recursion mode in use.

SRv6 BE mode

This mode is also called SID-based forwarding mode. In this mode, a PE forwards an SRv6 packet by searching the IPv6 routing table based on the SRv6 SID encapsulated in the packet.

The packet forwarding process of IPv4 EVPN L3VPN over SRv6 is similar to that of IPv6 EVPN L3VPN over SRv6. This section uses IPv4 EVPN L3VPN over SRv6 to illustrate the process.

As shown in Figure 1, CE 2 forwards an IPv4 packet to CE 1 as follows:

1. CE 2 sends the IPv4 packet to PE 2.

2. PE 2 receives the packet on an interface associated with VPN 1. PE 2 searches for a route that matches the destination IPv4 address of the packet in the routing table of VPN 1. The corresponding End.DT4, End.DT46, or End.DX4 SID is found. Then, PE 2 encapsulates an outer IPv6 header for the packet. The End.DT4, End.DT46, or End.DX4 SID is encapsulated in the outer IPv6 header as the destination address.

3. PE 2 searches the IPv6 routing table based on the End.DT4, End.DT46, or End.DX4 SID for the optimal IGP route and forwards the packet to P through the route.

4. P searches the IPv6 routing table based on the End.DT4, End.DT46, or End.DX4 SID for the optimal IGP route and forwards the packet to PE 1 through the route.

5. When PE 1 receives the packet, it processes the packet as follows:

¡ If the packet header contains an End.DT4 or End.DT46 SID, PE 1 searches the local SID forwarding table for the SID and removes the outer IPv6 header. Then, PE 1 matches the packet to VPN 1 based on the SID, searches the routing table of VPN 1 for the optimal route and forwards the packet to CE 1.

¡ If the packet header contains an End.DX4 SID, PE 1 searches the local SID forwarding table for the SID and removes the outer IPv6 header. Then, PE 1 forwards the packet to CE 1 according to the next hop and output interface bound to the SID.

SRv6 TE mode

This mode is also called SRv6 TE policy-based forwarding mode. In this mode, when a PE forwards a customer packet, it first searches for a matching SRv6 TE policy based on the packet attributes. Then, the PE adds an SRH to the packet. The SRH includes the destination SRv6 SID and the SID list of the SRv6 TE policy. Finally, the PE forwards the encapsulated packet based on the SRv6 TE policy.

The following modes are available to steer traffic to an SRv6 TE policy:

· Color—The device searches for an SRv6 TE policy that has the same color and endpoint address as the color and nexthop address of a BGP EVPN route. If a matching SRv6 TE policy exists, the device recurses the BGP EVPN route to that SRv6 TE policy. When the device receives packets that match the BGP EVPN route, it forwards the packets through the SRv6 TE policy.

· Tunnel policy—The device searches the tunnel policies for a matching SRv6 TE policy based on the next hop of a matching route. Configure a preferred tunnel or load sharing tunnel policy that uses the SRv6 TE policy. In this way, the SRv6 TE policy will be used as the public tunnel to forward the packets of private network packets.

For more information about tunnel policies, see MPLS Configuration Guide. For more information about SRv6 TE policies, see "Configuring SRv6 TE policies."

SRv6 TE and SRv6 BE hybrid mode

In this mode, the PE preferentially uses the SRv6 TE mode to forward a packet. If no SRv6 TE policy is available for the packet, the PE performs IPv6 routing table lookup based on the encapsulated SRv6 SID, and forwards the packet in SRv6 BE mode.

SRv6 TE and SRv6 BE FRR mode

This mode implements FRR by using the SRv6 TE path (primary path) and SRv6 BE path (backup path). If the SRv6 TE path fails or does not exist, traffic is immediately switched to the SRv6 BE path to ensure service continuity.

Inter-AS option B VPN

If the EVPN routes at one site must pass through both SRv6 and MPLS networks to reach another site, ensure that the SRv6 and MPLS networks can communicate with each other. For this purpose, you can use inter-AS option B VPN.

As shown in Figure 2, an MPLS network and an SRv6 network are in different ASs. For inter-AS communication, the devices must support SRv6 SID and MPLS label exchange.

Figure 2 Inter-AS option B VPN network diagram

End.T SID

The ASBR in the SRv6 network allocates End.T SIDs based on FECs and advertises the SIDs to other SRv6 nodes through an IGP. An FEC is a destination IP address/mask or destination IPv6 address/prefix length.

The function of an End.T SID is removing the outer IPv6 header and looking up the IPv6 FIB table based on the End.T SID to forward packets.

The ASBR in the SRv6 network encapsulates an End.T SID to the packets forwarded from the SRv6 network to the MPLS network.

Route advertisement

As shown in Figure 2, the route of CE 1 is advertised to CE 2 in the following process:

1. After PE 1 learns the private network route of CE 1, it assigns MPLS label L1 to the private network route. Then, PE 1 advertises the route to ASBR 1 through MP-IBGP.

2. ASBR 1 receives the EVPN IP prefix advertisement route from PE 1 and reoriginates the route. ASBR 1 changes the next hop address of the route to its address, assign MPLS label L2 to the route, and maps MPLS label L2 and MPLS label L1. Then, the ASBR advertises the EVPN IP prefix advertisement route to ASBR 2 through MP-EBGP.

3. ASBR 2 receives the EVPN IP prefix advertisement route from ASBR 1 and reoriginates the route. ASBR 2 changes the next hop address of the route to its address, allocates an End.T SID to the route, and maps the End.T SID and MPLS label L2. Then, the ASBR advertises the route to PE 2 through MP-IBGP.

4. PE 2 advertises the route to CE 2.

As shown in Figure 2, the route of CE 2 is advertised to CE 1 in the following process:

1. After PE 2 learns the private network route of CE 2, it assigns an SRv6 SID to the private network route. Then, PE 2 advertises the route to ASBR 2 through MP-IBGP. The supported SRv6 SIDs include End.DT4, End.DT6, End.DT46, End.DX4, and End.DX6 SIDs.

2. ASBR 2 receives the EVPN IP prefix advertisement route from PE 2 and reoriginates the route. ASBR 2 changes the next hop address of the route to its address, assign MPLS label L2 to the route, and maps MPLS label L2 and the SRv6 SID. Then, the ASBR advertises the EVPN IP prefix advertisement route to ASBR 1 through MP-EBGP.

3. ASBR 1 receives the EVPN IP prefix advertisement route from ASBR 2 and reoriginates the route. ASBR 1 changes the next hop address of the route to its address, allocates MPLS label L1 to the route, and maps MPLS label 1 and MPLS label L2. Then, the ASBR advertises the route to PE 1 through MP-IBGP.

4. PE 1 advertises the route to CE 1.

In the inter-AS option B VPN scenario, the ASBRs need to receive all inter-AS VPN routes. On the ASBRs, do not filter received EVPN IP prefix advertisement routes based on route targets.

Traffic forwarding

As shown in Figure 2, packets are forwarded from CE 2 to CE 1 in the following process:

1. When PE 2 receives a packet from CE 2, it encapsulates an End.T SID to the packet and forwards the packet to ASBR 2.

2. When ASBR 2 receives the packet, it removes the outer IPv6 header and looks up the IPv6 FIB table based on the End.T SID. ASBR 2 finds that the out label is L2. Then, the ASBR reencapsulates MPLS label 2 to the packet and forwards the packet to ASBR 1. The packet includes only one layer of MPLS label.

3. ASBR 1 replaces MPLS label L2 with MPLS label L1 and adds the public label that identifies the public tunnel from ASBR 1 to PE 1 to the packet. Then, ASBR 1 forwards the packet to PE 1.

4. PE 1 removes the public and private labels from the packet and forwards the packet to CE 1.

Packets are forwarded from CE 1 to CE 2 in the following process:

1. When PE 1 receives a packet from CE 1, it encapsulates two layers of MPLS labels to the packet and forwards the packet to ASBR 1. The private label is L1 and the public label identifies the public tunnel from PE 1 to ASBR 1.

2. When ASBR 1 receives the packet, it removes the public label from the packet and replaces private label L1 with private label L2. Then, ASBR 1 forwards the packet to ASBR 2. The packet includes only one layer of MPLS label.

3. ASBR 2 replaces private label L2 with an SRv6 SID and forwards the packet to PE 2 according to the SRv6 SID.

4. PE 2 executes the function of the SRv6 SID and forwards the packet to CE 2.

Intercommunication between SRv6 and MPLS L3VPN networks

As shown in Figure 3, MPLS L3VPN networks are deployed for the data centers connected through an EVPN L3VPN over SRv6 network. For communication between the data centers, you need to implement intercommunication between SRv6 and MPLS L3VPN networks on the ASBRs of the data centers.

Figure 3 Intercommunication between SRv6 and MPLS L3VPN networks

After you configure intercommunication between SRv6 and MPLS L3VPN networks on the ASBR, the ASBR performs the following operations:

· After receiving BGP VPNv4 routes from the MPLS L3VPN network, the ASBR performs the following operations:

a. Matches the route targets of the routes with the import route targets of local VPN instances.

b. Adds the routes to the routing tables of the VPN instances, and reoriginates EVPN IP prefix advertisement routes. In addition, the ASBR adds an SRv6 SID to the routes.

c. Advertises the reoriginated EVPN IP prefix advertisement routes with the SRv6 SID to the EVPN L3VPN over SRv6 network.

· After receiving EVPN IP prefix advertisement routes from the EVPN L3VPN over SRv6 network, the ASBR performs the following operations:

a. Matches the route targets of the routes with the import route targets of local VPN instances.

b. Adds the routes to the routing tables of the VPN instances, and reoriginates VPNv4 routes. In addition, the ASBR adds an MPLS label to the routes.

c. Advertises the reoriginated VPNv4 routes with the MPLS label to the MPLS L3VPN network.

After route reorigination, you need to enable intercommunication between SRv6 and MPLS networks on the ASBR to associate SRv6 SIDs with MPLS labels.

Figure 4 Packet forwarding between SRv6 and MPLS L3VPN networks

As shown in Figure 4, after the PEs and ASBRs complete route learning, packets between site 1 and site 2 are forwarded as follows:

1. Upon receiving a packet from site 2, PE 2 adds a private network label to the packet, and forwards the packet to ASBR 2 through the public network tunnel.

2. ASBR 2 performs a routing table lookup in the VPN instance associated with the private network label of the packet, encapsulates an SRv6 SID, and forwards the packet to ASBR 1 in SRv6 BE or SRv6 TE mode.

3. ASBR 1 determines the VPN instance associated with the SRv6 SID of the packet, removes the SRv6 SID, performs a routing table lookup in the VPN instance, and adds a private network label to the packet. Then ASBR 1 forwards the packet to PE 1 through the public network tunnel.

4. Upon receiving the packet, PE 1 performs a routing table lookup in the VPN instance associated with the private network label of the packet, locates the output interface, removes the private network label, and forwards the packet to site 1.

EVPN L3VPN over SRv6 FRR

EVPN L3VPN over SRv6 Fast Reroute (FRR) is applicable to a dualhomed scenario, as shown in Figure 5. By using static BFD to detect the primary link, FRR enables a PE to use the backup link when the primary link fails. The PE then selects a new optimal route, and uses the new optimal route to forward traffic.

EVPN L3VPN over SRv6 uses EVPN route backup for an EVPN route.

Figure 5 Network diagram of EVPN route backup for an EVPN route

As shown in Figure 5, configure FRR on the ingress node PE 1, and specify the backup next hop for VPN 1 as PE 3. When PE 1 receives an EVPN route to CE 2 from both PE 2 and PE 3, it uses the route from PE 2 as the primary link, and the route from PE 3 as the backup link.

Configure static BFD for public tunnels on PE 1 to detect the connectivity of the public tunnel from PE 1 to PE 2. When the tunnel PE 1—PE 2 operates correctly, traffic from CE 1 to CE 2 goes through the path CE 1—PE 1—PE 2—CE 2. When the tunnel fails, the traffic goes through the path CE 1—PE 1—PE 3—CE 2.

In this scenario, PE 1 is responsible for primary link detection and traffic switchover.

For more information about static BFD, see BFD configuration in High Availability Configuration Guide.

Restrictions and guidelines: EVPN L3VPN over SRv6 configuration

In standard system operating mode, only the following cards support this feature:

Card category	Cards
CEPC	CEPC-CQ8L, CEPC-CQ8LA, CEPC-CQ8L1A, CEPC-CQ16L1
CSPEX	CSPEX-1802X, CSPEX-1802XA, CSPEX-2612XA, CSPEX-1812X-E, CSPEX-2304X-G, CSPEX-1502XA
SPE	RX-SPE200-E

In SDN-WAN system operating mode, only the following cards support this feature:

Card category	Cards
CEPC	CEPC-XP4LX, CEPC-XP24LX, CEPC-XP48RX, CEPC-CP4RX, CEPC-CP4RXA, CEPC-CP4RX-L, CEPC-CQ8L, CEPC-CQ8LA, CEPC-CQ8L1A, CEPC-CQ16L1
CSPEX	CSPEX-1304X, CSPEX-1404X, CSPEX-1502X, CSPEX-1504X, CSPEX-1504XA, CSPEX-1602X, CSPEX-1602XA, CSPEX-1804X, CSPEX-1512X, CSPEX-1612X, CSPEX-1812X, CSPEX-1802X, CSPEX-1802XA, CSPEX-2612XA, CSPEX-1812X-E, CSPEX-2304X-G, CSPEX-1502XA
SPE	RX-SPE200, RX-SPE200-E
OAA	IM-NGFWX-IV

EVPN L3VPN over SRv6 networks do not support configuring the MPLS DiffServ mode. For more information about MPLS DiffServ modes, see the MPLS QoS configuration in ACL and QoS Configuration Guide.

EVPN L3VPN over SRv6 tasks at a glance

To configure EVPN L3VPN over SRv6, perform the following tasks:

1. Configuring a VPN instance and associating interfaces connected to CEs with the VPN instance

Perform this task on PEs. For more information, see MPLS L3VPN in MPLS Configuration Guide.

2. Configuring route exchange between a PE and a CE

Configure an IPv4 routing protocol (static routing, RIP, OSPF, IS-IS, EBGP, or IBGP) or an IPv6 routing protocol (IPv6 static routing, RIPng, OSPFv3, IPv6 IS-IS, EBGP, or IBGP) to exchange routes between a PE and a CE

On the CE, configure an IPv4 or IPv6 routing protocol to advertise routes of the local site to the PE. On the PE, associate the routing protocol with the VPN instance. For more information about routing protocol configurations, see Layer 3—IP Routing Configuration Guide.

3. Configuring route exchange between PEs

a. Configuring an SRv6 SID

Perform this task to manually configure an End.DT4, End.DT6, End.DT46, End.DX4, or End.DX6 SID.

b. Applying a locator to a BGP VPN instance

BGP can advertise SRv6 SIDs through BGP routes only after you apply a locator to BGP.

c. Configuring SRv6-encapsulated EVPN route advertisement

Perform this task to advertise VPN routes as EVPN routes to a peer or peer group in the EVPN L3VPN over SRv6 network.

d. Configuring PEs to exchange BGP EVPN routes

e. (Optional.) Configuring next hop-based dynamic End.DX4 or End.DX6 SID allocation for BGP routes

This feature enables a PE to dynamically allocate End.DX4 or End.DX6 SIDs to BGP private network routes based on the route next hops.

f. (Optional.) Configuring BGP EVPN route settings

4. Configuring the route recursion mode

5. Specifying a source address for the outer IPv6 header of SRv6-encapsulated EVPN L3VPN packets

This feature specifies the source address of the outer IPv6 header for SRv6 packets forwarded between two private network sites over the backbone network.

6. (Optional.) Configuring inter-AS option B VPN

7. (Optional.) Configuring intercommunication between SRv6 and MPLS L3VPN networks

8. (Optional.) Configuring EVPN L3VPN over SRv6 FRR

9. (Optional.) Configuring a TTL processing mode for tunnels associated with a VPN instance

Configuring an SRv6 SID

1. Enter system view.

system-view

2. Enable SRv6 and enter SRv6 view.

segment-routing ipv6

3. Configure a locator and enter SRv6 locator view.

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

4. Configure an opcode. Perform one of the following tasks:

¡ Configure an End.DT4 SID.

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

The specified VPN instance must exist. An End.DT4 SID cannot be configured in different VPN instances.

¡ Configure an End.DT6 SID.

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

The specified VPN instance must exist. An End.DT6 SID cannot be configured in different VPN instances.

¡ Configure an End.DT46 SID.

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

The specified VPN instance must exist. An End.DT46 SID cannot be configured in different VPN instances.

¡ Configure an End.DX4 SID.

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

The specified VPN instance must exist. An End.DX4 SID cannot be configured with different output interfaces or next hops.

¡ Configure an End.DX6 SID.

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

The specified VPN instance must exist. An End.DX6 SID cannot be configured with different output interfaces or next hops.

Applying a locator to a BGP VPN instance

About this task

Use this feature in BGP-VPN IPv4 or IPv6 unicast address family view of a VPN instance to apply for SRv6 SIDs for the private network routes of the VPN instance.

Use this feature if the device will use End.DT4, End.DT6, End.DT46, End.DX4, or End.DX6 SIDs to deliver EVPN traffic across sites.

Restrictions and guidelines

The VPN instance of the specified locator must be the same as the VPN instance of the private network. To specify a VPN instance for a locator, use the opcode end-dt4, opcode end-dt6, opcode end-dt46, opcode end-dx4, or opcode end-dx6 command in SRv6 locator view.

Prerequisites

Before you perform this task, you must create the specified locator.

Procedure

1. Enter system view.

system-view

2. Enter BGP instance view.

bgp as-number [ instance instance-name ]

3. Enter BGP-VPN instance view.

ip vpn-instance vpn-instance-name

4. Enter BGP-VPN IPv4 unicast address family view or BGP-VPN IPv6 unicast address family view.

¡ Enter BGP-VPN IPv4 unicast address family view.

address-family ipv4 [ unicast ]

¡ Enter BGP-VPN IPv6 unicast address family view.

address-family ipv6 [ unicast ]

5. Apply a locator to the BGP VPN instance.

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

By default, no locator is applied to a BGP VPN instance.

Configuring SRv6-encapsulated EVPN route advertisement

About this task

Perform this task to ensure that a PE can advertise VPN routes as EVPN routes to a peer or peer group in an EVPN L3VPN over SRv6 network.

Restrictions and guidelines

Perform this task on the edge nodes of the EVPN L3VPN network and RRs.

Procedure

1. Enter system view.

system-view

2. Enter BGP instance view.

bgp as-number [ instance instance-name ]

3. Enter BGP EVPN address family view.

address-family l2vpn evpn

4. Enable SRv6 encapsulation for the EVPN IP prefix advertisement routes advertised to a peer or peer group.

peer { group-name | ipv6-address [ prefix-length ] } advertise encap-type srv6

By default, IP prefix advertisement routes use VXLAN encapsulation.

Configuring PEs to exchange BGP EVPN routes

Restrictions and guidelines

To ensure optimal route selection and SRv6 tunnel traffic forwarding, make sure a pair of PEs are not both IPv4 and IPv6 peers to each other.

Procedure

1. Enter system view.

system-view

2. Enter BGP instance view.

bgp as-number [ instance instance-name ]

3. Configure an IPv6 peer or peer group.

peer { group-name | ipv6-address [ prefix-length ] } as-number as-number

4. Specify the source interface of TCP connections to a peer or peer group.

peer { group-name | ipv6-address [ prefix-length ] } connect-interface interface-type interface-number

By default, BGP uses the IPv6 address of the output interface in the optimal route to the BGP peer or peer group as the source address of TCP connections to the peer or peer group.

5. Enter BGP EVPN address family view.

address-family l2vpn evpn

6. Enable BGP to exchange EVPN routes with an IPv6 peer or peer group.

peer { group-name | ipv6-address [ prefix-length ] } enable

By default, BGP cannot exchange EVPN routes with an IPv6 peer or peer group.

Configuring next hop-based dynamic End.DX4 or End.DX6 SID allocation for BGP routes

About this task

Perform this task to forward an SRv6 decapsulated VPN packet to the next hop without looking up the routing table of the VPN instance.

If you assign an End.DT4 SID, End.DT6 SID, or End.DT46 SID to a BGP VPN instance, all BGP private network routes of the instance are allocated that SID. When a PE removes the SRv6 encapsulation from a received packet, it looks up the routing table of the VPN instance based on the SID for an optimal route. Then, the PE forwards the packet to a CE. To forward the packet to the next hop without looking up the routing table of the VPN instance, perform this task.

This task dynamically allocates End.DX4 or End.DX6 SIDs to specific next hops or all next hops of the BGP private network routes in a VPN instance based on the next hop addresses. When forwarding a packet, the PE searches for the output interface and next hop based on the End.DX4 or End.DX6 SID of the packet. Then, the PE directly forwards the packet out of the output interface to the next hop.

Restrictions and guidelines

Before you perform this task in BGP-VPN IPv4 or IPv6 unicast address family view, execute the segment-routing ipv6 locator command in the same view to apply a locator to the view. This ensures successful dynamic End.DX4 or End.DX6 SID allocation.

This feature does not allocate End.DX4 or End.DX6 SIDs to direct routes.

Procedure

1. Enter system view.

system-view

2. Enter BGP instance view.

bgp as-number [ instance instance-name ]

3. Enter BGP-VPN instance view.

ip vpn-instance vpn-instance-name

4. Enter BGP-VPN IPv4 unicast address family view or BGP-VPN IPv6 unicast address family view.

¡ Enter BGP-VPN IPv4 unicast address family view.

address-family ipv4 [ unicast ]

¡ Enter BGP-VPN IPv6 unicast address family view.

address-family ipv6 [ unicast ]

5. Configure next hop-based dynamic End.DX4 or End.DX6 SID allocation for BGP private network routes. Choose one of the following tasks:

¡ Automatically allocate an End.DX4 or End.DX6 SID to each next hop of BGP private network routes.

segment-routing ipv6 apply-sid all-nexthop evpn

¡ Execute the following commands in sequence to automatically allocate an End.DX4 or End.DX6 SID to the specified next hop of BGP private network routes:

segment-routing ipv6 apply-sid specify-nexthop evpn

nexthop nexthop-address interface interface-type interface-number

By default, VPN instance-based SID allocation is used for private network routes.

Configuring BGP EVPN route settings

Restrictions and guidelines for BGP EVPN route configuration

For more information about the commands in this section, see BGP commands in Layer 3—IP Routing Command Reference.

Configuring BGP route reflection

1. Enter system view.

system-view

2. Enter BGP instance view.

bgp as-number [ instance instance-name ]

3. Enter BGP EVPN address family view.

address-family l2vpn evpn

4. Configure the device as an RR and specify a peer or peer group as its client.

peer { group-name | ipv6-address [ prefix-length ] } reflect-client

By default, no RR or client is configured.

5. (Optional.) Enable BGP EVPN route reflection between clients.

reflect between-clients

By default, BGP EVPN route reflection between clients is enabled.

6. (Optional.) Configure the cluster ID of the RR.

reflector cluster-id { cluster-id | ip-address }

By default, an RR uses its own router ID as the cluster ID.

7. (Optional.) Create a reflection policy for the RR to filter reflected BGP EVPN routes.

rr-filter { ext-comm-list-number | ext-comm-list-name }

By default, an RR does not filter reflected BGP EVPN routes.

8. (Optional.) Enable the RR to change the attributes of routes to be reflected.

reflect change-path-attribute

By default, an RR cannot change the attributes of routes to be reflected.

Configuring attributes of BGP EVPN routes

1. Enter system view.

system-view

2. Enter BGP instance view.

bgp as-number [ instance instance-name ]

3. Enter BGP EVPN address family view.

address-family l2vpn evpn

4. Set the local router as the next hop for routes advertised to a peer or peer group.

peer { group-name | ipv6-address [ prefix-length ] } next-hop-local

By default, BGP sets the local router as the next hop for all routes advertised to a peer or peer group.

5. Permit the local AS number to appear in routes from a peer or peer group and set the number of appearances.

peer { group-name | ipv6-address [ prefix-length ] } allow-as-loop [ number ]

By default, the local AS number is not allowed in routes from peers.

6. Advertise the COMMUNITY attribute to a peer or peer group.

peer { group-name | ipv6-address [ prefix-length ] } advertise-community

By default, the device does not advertise the COMMUNITY attribute to peers or peer groups.

7. Advertise the Large community attribute to a peer or peer group.

peer { group-name | ipv6-address [ prefix-length ] } advertise-large-community

By default, the Large community attribute is not advertised to a peer or peer group.

Filtering BGP EVPN routes

1. Enter system view.

system-view

2. Enter BGP instance view.

bgp as-number [ instance instance-name ]

3. Enter BGP EVPN address family view.

address-family l2vpn evpn

4. Filter routes advertised to a peer or peer group.

filter-policy { mac-acl-number | name mac-acl-name } export

By default, routes advertised to peers or peer groups are not filtered.

5. Filter routes received from a peer or peer group.

filter-policy { mac-acl-number | name mac-acl-name } import

By default, routes received from peers or peer groups are not filtered.

6. Apply a routing policy to routes received from or advertised to a peer or peer group.

peer { group-name | ipv6-address [ prefix-length ] } route-policy route-policy-name { export | import }

By default, no routing policies are applied to routes received from or advertised to peers or peer groups.

7. Enable route target filtering for BGP EVPN routes.

policy vpn-target

By default, route target filtering is enabled for BGP EVPN routes.

Configuring the BGP Additional Paths feature

1. Enter system view.

system-view

2. Enter BGP instance view.

bgp as-number [ instance instance-name ]

3. Enter BGP EVPN address family view.

address-family l2vpn evpn

4. Configure the BGP Additional Paths capabilities.

peer { group-name | ipv6-address [ prefix-length ] } additional-paths { receive | send } *

By default, no BGP Additional Paths capabilities are configured.

5. Set the maximum number of Add-Path optimal routes that can be advertised to a peer or peer group.

peer { group-name | ipv6-address [ prefix-length ] } advertise additional-paths best number

By default, a maximum of one Add-Path optimal route can be advertised to a peer or peer group.

6. (Optional.) Set the optimal route selection delay timer.

route-select delay delay-value

By default, the optimal route selection delay timer is 0 seconds, which means optimal route selection is not delayed.

Configuring the route recursion mode

About this task

After a PE receives a customer packet destined for an SRv6 SID, it forwards the packet according to the route recursion mode.

· SRv6 BE mode—This mode is also called SID-based forwarding mode. In this mode, the PE first encapsulates the End.DT4, End.DT6, or End.DT46 SID into the packet. Then, the PE searches the IPv6 routing table based on the SID encapsulated in the packet to forward the packet.

· SRv6 TE mode—This mode is also called SRv6 TE policy-based forwarding mode. In this mode, the PE first searches for a matching SRv6 TE policy based on the packet attributes. Then, the PE adds an SRH to the packet. The SRH includes the End.DT4, End.DT6, or End.DT46 SID and the SID list of the SRv6 TE policy. Finally, the PE forwards the encapsulated packet through the SRv6 TE policy. For more information, see "Configuring SRv6 TE policies."

· SRv6 TE and SRv6 BE hybrid mode—In this mode, the PE preferentially uses the SRv6 TE mode to forward the packet. If no SRv6 TE policy is available for the packet, the PE forwards the packet in SRv6 BE mode.

· SRv6 TE and SRv6 BE FRR mode—This mode implements FRR by using the SRv6 TE path (primary path) and SRv6 BE path (backup path). If the SRv6 TE path fails or does not exist, traffic is immediately switched to the SRv6 BE path to ensure service continuity.

Procedure

1. Enter system view.

system-view

2. Enter BGP instance view.

bgp as-number [ instance instance-name ]

3. Enter BGP-VPN instance view.

ip vpn-instance vpn-instance-name

4. Enter BGP-VPN IPv4 unicast address family view or BGP-VPN IPv6 unicast address family view.

¡ Enter BGP-VPN IPv4 unicast address family view.

address-family ipv4 [ unicast ]

¡ Enter BGP-VPN IPv6 unicast address family view.

address-family ipv6 [ unicast ]

5. Configure the route recursion mode.

segment-routing ipv6 { best-effort | traffic-engineering | traffic-engineering best-effort | traffic-engineering best-effort-backup } evpn

By default, a PE searches the IPv6 routing table based on the next hop of a matching route to forward traffic.

Specifying a source address for the outer IPv6 header of SRv6-encapsulated EVPN L3VPN packets

Restrictions and guidelines

To ensure correct VPN traffic forwarding in an EVPN L3VPN over SRv6 network, you must specify a source address for the outer IPv6 header of SRv6-encapsulated EVPN L3VPN packets.

You cannot specify a loopback address, link-local address, multicast address, or unspecified address as the source IPv6 address. 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.

Procedure

1. Enter system view.

system-view

2. Enter SRv6 view.

segment-routing ipv6

3. Specify a source address for the outer IPv6 header of SRv6-encapsulated EVPN L3VPN packets.

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

By default, no source address is specified for the outer IPv6 header of SRv6-encapsulated EVPN L3VPN packets.

Configuring inter-AS option B VPN

About this task

For intercommunication between an MPLS network in one AS and an SRv6 network in another AS, enable SRv6 and MPLS interworking on the ASBR in the SRv6 network. This feature enables End.T SID allocation and establishes mappings between End.T SIDs and MPLS labels.

Restrictions and guidelines

After you enable SRv6 and MPLS interworking, the per-next-hop label allocation mode applies to routes forwarded from SRv6 networks to MPLS networks. The label allocation mode is not affected by the label-allocation-mode or apply-label command. For more information about the label-allocation-mode command, see BGP commands in Layer 3—IP Routing Command Reference. For more information about the apply-label command, see MPLS L3VPN commands in MPLS Command Reference.

Procedure

1. Enter system view.

system-view

2. Enter BGP instance view.

bgp as-number [ instance instance-name ]

3. Enter BGP EVPN address family view.

address-family l2vpn evpn

4. Enable the device to reoriginate BGP EVPN routes based on the BGP EVPN routes received from a peer or peer group.

peer { group-name | ipv4-address [ mask-length ] | ipv6-address [ prefix-length ] } re-originated [ replace-rt ]

By default, the device does not reoriginate BGP EVPN routes based on received BGP EVPN routes.

5. (Optional.) Enable the device to advertise original BGP EVPN routes to a peer or peer group.

peer { group-name | ipv4-address [ mask-length ] | ipv6-address [ prefix-length ] } advertise original-route

By default, the device advertises only reoriginated BGP EVPN routes to peers and peer groups after the peer re-originated command is executed.

6. (Optional.) Suppress advertisement of reoriginated BGP EVPN routes to a peer or peer group.

peer { group-name | ipv4-address [ mask-length ] | ipv6-address [ prefix-length ] } suppress re-originated ip-prefix

By default, the device advertises reoriginated BGP EVPN routes to peers and peer groups after the peer re-originated command is executed.

7. Enable SRv6 and MPLS interworking.

srv6-mpls-interworking enable

By default, SRv6 and MPLS interworking is disabled.

8. Apply a locator to the BGP VPN instance.

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

By default, no locator is applied to a BGP VPN instance.

9. Configure the route recursion mode.

segment-routing ipv6 { best-effort | traffic-engineering | traffic-engineering best-effort } evpn

By default, a PE searches the IPv6 routing table based on the next hop of a matching route to forward traffic.

Configuring intercommunication between SRv6 and MPLS L3VPN networks

About this task

For communication between the data centers deployed with MPLS L3VPN networks and connected through an EVPN L3VPN over SRv6 network, configure this feature on the ASBRs of data centers.

Prerequisites

Before you perform this task, enable SRv6 and MPLS interworking on the ASBR.

Reoriginating VPNv4/VPNv6 routes as EVPN IP prefix advertisement routes

1. Enter system view.

system-view

2. Enter BGP instance view.

bgp as-number [ instance instance-name ]

3. Enter BGP VPNv4 address family view or BGP VPNv6 address family view.

¡ Enter BGP VPNv4 address family view.

address-family vpnv4

¡ Enter BGP VPNv6 address family view.

address-family vpnv6

4. Reoriginate routes received from a peer or peer group.

peer { group-name | ipv4-address [ mask-length ] | ipv6-address [ prefix-length ] } re-originated stitch-evpn

By default, routes received from a peer or peer group are not reoriginated.

Reoriginating EVPN IP prefix advertisement routes as VPNv4/VPNv6 routes

1. Enter system view.

system-view

2. Enter BGP instance view.

bgp as-number [ instance instance-name ]

3. Enter BGP EVPN address family view.

address-family l2vpn evpn

4. Reoriginate routes received from a peer or peer group.

peer { group-name | ipv4-address [ mask-length ] | ipv6-address [ prefix-length ] } re-originated [ ip-prefix ] stitch-l3vpn

By default, routes received from a peer or peer group are not reoriginated.

Configuring EVPN L3VPN over SRv6 FRR

About this task

EVPN L3VPN over SRv6 FRR enables the device to calculate backup routes for all routes of a VPN instance to reduce the traffic interruption caused by link or device failures on the backbone. If the device learns two unequal-cost routes destined for the same network from different peers, the optimal route is backed up by the other route. When the optimal route becomes unavailable, the device uses the backup route to forward traffic. At the same time, the device calculates a new optimal route and then uses it to direct traffic forwarding.

By default, the IP routing table of a VPN instance does not have SRv6 SID route information. As a result, to use BFD to detect the primary path between PEs, FRR can only use the static BFD session for the locator network address. If the address families of multiple VPN instances have used the same locator, FRR in these address families might use the same static BFD session to detect the primary path. Once the BFD session detects that the path is not available, the BGP routes in all these address families will perform path switching simultaneously.

For refined FRR management, use the segment-routing ipv6 primary-path-detect sid-bfd evpn command in BGP-VPN IPv4 unicast address family view or BGP-VPN IPv6 unicast address family view. After this command is executed, when the device adds an IP prefix advertisement route that contains an SRv6 SID to the IP routing table of a VPN instance, it adds the SRv6 SID as the next hop of the route. This allows FRR to automatically and preferentially associate the static BFD session for the SRv6 SID to detect the primary path. Once BFD detects that an SRv6 SID is not reachable, it triggers the BGP routes in only one address family to perform path switching. This mechanism provides a smaller control granularity for FRR.

Restrictions and guidelines

This feature might cause routing loops in certain conditions. Make sure you are fully aware of this feature when you use it on a live network.

The segment-routing ipv6 primary-path-detect sid-bfd evpn command applies only to routes that use the SRv6 BE route recursion mode. If the route recursion mode is SRv6 TE and SRv6 BE hybrid, SRv6 TE and SRv6 BE FRR, or SRv6 TE and SRv6 BE multilevel FRR, this command takes effect only when the SRv6 TE path is not available.

Procedure

1. Enter system view.

system-view

2. Configure static BFD.

bfd static session-name [ peer-ipv6 ipv6-address [ vpn-instance vpn-instance-name ] source-ipv6 ipv6-address [ discriminator local local-value remote remote-value ] [ track-interface interface-type interface-number ] ]

If the segment-routing ipv6 primary-path-detect sid-bfd command is not used, you must specify the locator addresses advertised by the two ends of the detected link as the peer IPv6 address and source IPv6 address.

If the segment-routing ipv6 primary-path-detect sid-bfd command is used, you can specify the SRv6 SIDs allocated in the specified VPN instance for the devices at the two ends of the detected link as the peer IPv6 address and source IPv6 address.

For more information about the bfd static command, see BFD commands in High Availability Command Reference.

3. Return to system view.

quit

4. Enter BGP instance view.

bgp as-number [ instance instance-name ]

5. Configure BGP FRR to use BFD to detect next hop connectivity for the primary routein control packet mode or echo packet mode.

primary-path-detect bfd { ctrl | echo }

By default, BGP FRR uses ARP to detect the connectivity to the next hop of the primary route.

For more information about this command, see BGP commands in Layer 3—IP Routing Command Reference.

6. (Optional.) Enable using the static BFD session for the SRv6 SID to detect the reachability of the primary path for SRv6 VPN FRR.

¡ Execute the following commands in sequence to enable using the static BFD session for the SRv6 SID to detect the reachability of the primary path for SRv6 VPN FRR in BGP-VPN IPv4 unicast address family view:

ip vpn-instance vpn-instance-name

address-family ipv4 [ unicast ]

segment-routing ipv6 primary-path-detect sid-bfd evpn

¡ Execute the following commands in sequence to enable using the static BFD session for the SRv6 SID to detect the reachability of the primary path for SRv6 VPN FRR in BGP-VPN IPv6 unicast address family view:

ip vpn-instance vpn-instance-name

address-family ipv6 [ unicast ]

segment-routing ipv6 primary-path-detect sid-bfd evpn

By default, the device uses the static BFD session for the locator to detect the reachability of the primary path for SRv6 VPN FRR.

7. (Optional.) Return to BGP instance view.

quit

8. Enter BGP EVPN address family view.

address-family l2vpn evpn

9. Enable FRR for the address family.

pic

By default, FRR is disabled.

For more information about this command, see BGP commands in Layer 3—IP Routing Command Reference.

Configuring a TTL processing mode for tunnels associated with a VPN instance

About this task

A tunnel associated with a VPN instance supports the following TTL processing modes:

· Pipe—When an IP or IPv6 packet enters the tunnel of the VPN instance, the ingress node adds a new header to the packet. The ingress node sets the TTL value or hop limit in the new header to 255 or the value specified by using the encapsulation source-address ip-ttl command in SRv6 view. When the packet leaves the tunnel of the VPN instance, the egress node removes the new header from the packet.The TTL value or hop limit in the original packet does not change when the packet is forwarded in the tunnel. Therefore, the public network nodes are invisible to user networks, and the tracert facility cannot show the real path in the public network.

· Uniform—When an IP or IPv6 packet enters the tunnel of the VPN instance, the ingress node adds a new header to the packet. The ingress node copies the TTL value or the hop limit of the original packet to the TTL or hop limit field of the new header. When the packet leaves the tunnel of the VPN instance, the egress node copies the remaining TTL value or hop limit in the new header back to the original packet. The TTL value or hop limit can reflect how many hops the packet has traversed in the public network. The tracert facility can show the real path along which the packet has traveled.

Restrictions and guidelines

In the current software version, you can configure a TTL processing mode only for SRv6 tunnels associated with VPN instances.

Procedure

1. Enter system view.

system-view

2. Enter VPN instance view.

ip vpn-instance vpn-instance-name [ index vpn-index ]

3. Configure a TTL processing mode for the tunnels associated with the VPN instance.

ttl-mode { pipe | uniform }

By default, the TTL processing mode for the tunnels associated with a VPN instance is pipe.

For more information about this command, see MPLS L3VPN commands in MPLS Command Reference.

Display and maintenance commands for EVPN L3VPN over SRv6

Resetting BGP sessions

For BGP setting changes to take effect, you must reset or soft-reset BGP sessions. Soft-resetting BGP sessions updates BGP routing information without tearing down the BGP sessions. Resetting BGP sessions updates BGP routing information by tearing down and re-establishing the BGP sessions. Soft-reset requires that both the local router and the peer support ROUTE-REFRESH messages.

Execute the commands in this section in user view. For more information about the commands, see BGP in Layer 3—IP Routing Command Reference.

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Task	Command
Soft-reset BGP sessions of the BGP VPNv4 address family.	refresh bgp [ instance instance-name ] ipv6-address [ prefix-length ] { export \| import } l2vpn evpn
Reset BGP sessions of the BGP VPNv4 address family.	reset bgp [ instance instance-name ] ipv6-address [ prefix-length ] l2vpn evpn

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Displaying and maintaining the running status of EVPN L3VPN over SRv6

Execute display commands in any view.

Task	Command
Display BGP EVPN route information.	display bgp [ instance instance-name ] l2vpn evpn [ peer ipv4-address { advertised-routes \| received-routes } [ statistics ] \| route-distinguisher route-distinguisher [ route-type ip-prefix ] [ evpn-route route-length [ advertise-info ] ] \| route-type { auto-discovery \| es \| imet \| ip-prefix \| mac-ip } \| statistics ]

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EVPN L3VPN over SRv6 configuration examples

Example: Configuring IPv4 EVPN L3VPN over SRv6 in SRv6 BE mode

Network configuration

As shown in Figure 6, the backbone network is an IPv6 network, and VPN 1 is an IPv4 network. Deploy EVPN L3VPN over SRv6 in SRv6 BE mode between PE 1 and PE 2 and use an SRv6 tunnel to transmit EVPN traffic between the PEs.

· Configure EBGP to exchange VPN routing information between the CEs and PEs.

· Configure IPv6 IS-IS on the PEs in the same AS to realize IPv6 network connectivity.

· Configure MP-IBGP to exchange EVPN routing information between the PEs.

Figure 6 Network diagram

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Table 1 Interface and IP address assignment

Device	Interface	IP address	Device	Interface	IP address
CE 1	XGE3/1/1	10.1.1.2/24	PE 2	Loop0	3::3/128
PE 1	Loop0	1::1/128		XGE3/1/1	10.2.1.1/24
	XGE3/1/1	10.1.1.1/24		XGE3/1/2	2002::1/96
	XGE3/1/2	2001::1/96	CE 2	XGE3/1/1	10.2.1.2/24
P	Loop0	2::2/128
	XGE3/1/1	2001::2/96
	XGE3/1/2	2002::2/96

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Procedure

1. Configure IPv6 IS-IS on the PEs and device P for network connectivity between the devices:

# Configure PE 1.

<PE1> system-view

[PE1] isis 1

[PE1-isis-1] is-level level-1

[PE1-isis-1] cost-style wide

[PE1-isis-1] network-entity 10.1111.1111.1111.00

[PE1-isis-1] address-family ipv6 unicast

[PE1-isis-1-ipv6] quit

[PE1-isis-1] quit

[PE1] interface loopback 0

[PE1-LoopBack0] ipv6 address 1::1 128

[PE1-LoopBack0] isis ipv6 enable 1

[PE1-LoopBack0] quit

[PE1] interface ten-gigabitethernet 3/1/2

[PE1-Ten-GigabitEthernet3/1/2] ipv6 address 2001::1 96

[PE1-Ten-GigabitEthernet3/1/2] isis ipv6 enable

[PE1-Ten-GigabitEthernet3/1/2] quit

# Configure P.

<P> system-view

[P] isis

[P-isis-1] is-level level-1

[P-isis-1] cost-style wide

[P-isis-1] network-entity 10.2222.2222.2222.00

[P-isis-1] address-family ipv6 unicast

[P-isis-1-ipv6] quit

[P-isis-1] quit

[P] interface loopback 0

[P-LoopBack0] ipv6 address 2::2 128

[P-LoopBack0] isis ipv6 enable

[P-LoopBack0] quit

[P] interface ten-gigabitethernet 3/1/1

[P-Ten-GigabitEthernet3/1/1] ipv6 address 2001::2 96

[P-Ten-GigabitEthernet3/1/1] isis ipv6 enable

[P-Ten-GigabitEthernet3/1/1] quit

[P] interface ten-gigabitethernet 3/1/2

[P-Ten-GigabitEthernet3/1/2] ipv6 address 2002::2 96

[P-Ten-GigabitEthernet3/1/2] isis ipv6 enable

[P-Ten-GigabitEthernet3/1/2] quit

# Configure PE 2.

<PE2> system-view

[PE2] isis

[PE2-isis-1] is-level level-1

[PE2-isis-1] cost-style wide

[PE2-isis-1] network-entity 10.3333.3333.3333.00

[PE2-isis-1] address-family ipv6 unicast

[PE2-isis-1-ipv6] quit

[PE2-isis-1] quit

[PE2] interface loopback 0

[PE2-LoopBack0] ipv6 address 3::3 128

[PE2-LoopBack0] isis ipv6 enable

[PE2-LoopBack0] quit

[PE2] interface ten-gigabitethernet 3/1/2

[PE2-Ten-GigabitEthernet3/1/2] ipv6 address 2002::1 96

[PE2-Ten-GigabitEthernet3/1/2] isis ipv6 enable

[PE2-Ten-GigabitEthernet3/1/2] quit

# Verify that PE 1, P, and PE 2 have established IPv6 IS-IS neighbor relationships and the neighbor state is up.

[PE1] display isis peer

[P] display isis peer

[PE2] display isis peer

# Verify that PE 1 and PE 2 each learn a route destined for the loopback interface of each other.

[PE1] display isis route ipv6

[PE2] display isis route ipv6

2. Configure VPN instance settings on PE 1 and PE 2 and verify that each CE can access its local PE:

# Configure PE 1.

[PE1] ip vpn-instance vpn1

[PE1-vpn-instance-vpn1] route-distinguisher 100:1

[PE1-vpn-instance-vpn1] vpn-target 111:1

[PE1-vpn-instance-vpn1] quit

[PE1] interface ten-gigabitethernet 3/1/1

[PE1-Ten-GigabitEthernet3/1/1] ip binding vpn-instance vpn1

[PE1-Ten-GigabitEthernet3/1/1] ip address 10.1.1.1 24

[PE1-Ten-GigabitEthernet3/1/1] quit

# Configure PE 2.

[PE2] ip vpn-instance vpn1

[PE2-vpn-instance-vpn1] route-distinguisher 100:1

[PE2-vpn-instance-vpn1] vpn-target 111:1

[PE2-vpn-instance-vpn1] quit

[PE2] interface ten-gigabitethernet 3/1/1

[PE2-Ten-GigabitEthernet3/1/1] ip binding vpn-instance vpn1

[PE2-Ten-GigabitEthernet3/1/1] ip address 10.2.1.1 24

[PE2-Ten-GigabitEthernet3/1/1] quit

# Configure IP addresses for the interfaces on the CEs, as shown in Figure 6. (Details not shown.)

# Display VPN instance settings on each PE. This step uses PE 1 as an example.

[PE1] display ip vpn-instance

Total VPN-Instances configured : 1

Total IPv4 VPN-Instances configured : 1

Total IPv6 VPN-Instances configured : 1

VPN-Instance Name RD Address family Create time

vpn1 100:1 N/A 2019/08/12 13:59:39

# Verify that each PE can ping its local CE. This step uses PE 1 and CE 1 as an example.

[PE1] ping -vpn-instance vpn1 10.1.1.2

Ping 10.1.1.2 (10.1.1.2): 56 data bytes, press CTRL+C to break

56 bytes from 10.1.1.2: icmp_seq=0 ttl=255 time=2.000 ms

56 bytes from 10.1.1.2: icmp_seq=1 ttl=255 time=0.000 ms

56 bytes from 10.1.1.2: icmp_seq=2 ttl=255 time=1.000 ms

56 bytes from 10.1.1.2: icmp_seq=3 ttl=255 time=0.000 ms

56 bytes from 10.1.1.2: icmp_seq=4 ttl=255 time=0.000 ms

--- Ping statistics for 10.1.1.2 in VPN instance vpn1 ---

5 packet(s) transmitted, 5 packet(s) received, 0.0% packet loss

round-trip min/avg/max/std-dev = 0.000/0.600/2.000/0.800 ms

3. Set up an EBGP peer relationship between each PE and its local CE and distribute VPN routes to EBGP:

# Configure CE 1.

<CE1> system-view

[CE1] bgp 65410

[CE1-bgp-default] peer 10.1.1.1 as-number 100

[CE1-bgp-default] address-family ipv4 unicast

[CE1-bgp-default-ipv4] peer 10.1.1.1 enable

[CE1-bgp-default-ipv4] import-route direct

[CE1-bgp-default-ipv4] quit

[CE1-bgp-default] quit

# Configure CE 2 in the same way as CE 1 is configured. (Details not shown.)

# Configure PE 1.

[PE1] bgp 100

[PE1-bgp-default] router-id 1.1.1.1

[PE1-bgp-default] ip vpn-instance vpn1

[PE1-bgp-default-vpn1] peer 10.1.1.2 as-number 65410

[PE1-bgp-default-vpn1] address-family ipv4 unicast

[PE1-bgp-default-ipv4-vpn1] peer 10.1.1.2 enable

[PE1-bgp-default-ipv4-vpn1] quit

[PE1-bgp-default-vpn1] quit

# Configure PE 2 in the same way PE 1 is configured. (Details not shown.)

# Verify that the PEs have established BGP peer relationships with their local CEs and the peers are in established state.

[PE1] display bgp peer ipv4 vpn-instance

[PE2] display bgp peer ipv4 vpn-instance

4. Set up an MP-IBGP peer relationship between PE 1 and PE 2:

# Configure PE 1.

[PE1] bgp 100

[PE1-bgp-default] peer 3::3 as-number 100

[PE1-bgp-default] peer 3::3 connect-interface loopback 0

[PE1-bgp-default] address-family l2vpn evpn

[PE1-bgp-default-evpn] peer 3::3 enable

[PE1-bgp-default-evpn] quit

[PE1-bgp-default] quit

# Configure PE 2.

[PE2] bgp 100

[PE2-bgp-default] peer 1::1 as-number 100

[PE2-bgp-default] peer 1::1 connect-interface loopback 0

[PE2-bgp-default] address-family l2vpn evpn

[PE2-bgp-default-evpn] peer 1::1 enable

[PE2-bgp-default-evpn] quit

[PE2-bgp-default] quit

# Verify that the PEs have established a BGP peer relationship and the peers are in established state.

[PE1] display bgp peer l2vpn evpn

[PE2] display bgp peer l2vpn evpn

5. Specify a source address for the outer IPv6 header of SRv6-encapsulated IPv4 EVPN L3VPN packets on PE 1 and PE 2:

# Configure PE 1.

[PE1] segment-routing ipv6

[PE1-segment-routing-ipv6] encapsulation source-address 1::1

# Configure PE 2.

[PE2] segment-routing ipv6

[PE2-segment-routing-ipv6] encapsulation source-address 3::3

6. Configure SRv6 locators advertised through IGP:

# Configure PE 1.

[PE1-segment-routing-ipv6] locator aaa ipv6-prefix 1:2::1:0 96 static 8

[PE1-segment-routing-ipv6-locator-aaa] quit

[PE1-segment-routing-ipv6] quit

[PE1] isis 1

[PE1-isis-1] address-family ipv6 unicast

[PE1-isis-1-ipv6] segment-routing ipv6 locator aaa

[PE1-isis-1-ipv6] quit

[PE1-isis-1] quit

# Configure PE 2.

[PE2-segment-routing-ipv6] locator bbb ipv6-prefix 6:5::1:0 96 static 8

[PE2-segment-routing-ipv6-locator-bbb] quit

[PE2-segment-routing-ipv6] quit

[PE2] isis 1

[PE2-isis-1] address-family ipv6 unicast

[PE2-isis-1-ipv6] segment-routing ipv6 locator bbb

[PE2-isis-1-ipv6] quit

[PE2-isis-1] quit

7. Add End.DT4 SIDs to private network routes on PE 1 and PE 2:

# Configure PE 1.

[PE1] bgp 100

[PE1-bgp-default] ip vpn-instance vpn1

[PE1-bgp-default-vpn1] address-family ipv4 unicast

[PE1-bgp-default-ipv4-vpn1] segment-routing ipv6 locator aaa evpn

[PE1-bgp-default-ipv4-vpn1] quit

[PE1-bgp-default-vpn1] quit

[PE1-bgp-default] quit

# Configure PE 2.

[PE2] bgp 100

[PE2-bgp-default] ip vpn-instance vpn1

[PE2-bgp-default-vpn1] address-family ipv4 unicast

[PE2-bgp-default-ipv4-vpn1] segment-routing ipv6 locator bbb evpn

[PE2-bgp-default-ipv4-vpn1] quit

[PE2-bgp-default-vpn1] quit

[PE2-bgp-default] quit

# Verify that the PEs have distributed the End.DT4 SIDs to the routing table and generated SRv6 routes. This step uses PE 1 as an example.

[PE1] display ipv6 routing-table protocol srv6

Summary count : 1

SRv6 Routing table status : <Active>

Summary count : 1

Destination: 1:2::101/128 Protocol : SRv6

NextHop : ::1 Preference: 4

Interface : InLoop0 Cost : 0

SRv6 Routing table status : <Inactive>

Summary count : 0

8. Enable IPv6 peers on the PEs to exchange End.DT4 SIDs and enable SRv6 BE mode:

# Configure PE 1.

[PE1] bgp 100

[PE1-bgp-default] address-family l2vpn evpn

[PE1-bgp-default-evpn] peer 3::3 advertise encap-type srv6

[PE1-bgp-default-evpn] quit

[PE1-bgp-default] ip vpn-instance vpn1

[PE1-bgp-default-vpn1] address-family ipv4 unicast

[PE1-bgp-default-ipv4-vpn1] segment-routing ipv6 best-effort evpn

[PE1-bgp-default-ipv4-vpn1] quit

[PE1-bgp-default-vpn1] quit

[PE1-bgp-default] quit

# Configure PE 2.

[PE2] bgp 100

[PE2-bgp-default] address-family l2vpn evpn

[PE2-bgp-default-evpn] peer 1::1 advertise encap-type srv6

[PE2-bgp-default-evpn] quit

[PE2-bgp-default] ip vpn-instance vpn1

[PE2-bgp-default-vpn1] address-family ipv4 unicast

[PE2-bgp-default-ipv4-vpn1] segment-routing ipv6 best-effort evpn

[PE2-bgp-default-ipv4-vpn1] quit

[PE2-bgp-default-vpn1] quit

[PE2-bgp-default] quit

# Display BGP EVPN routing information on each PE and verify that the routes advertised by the PEs have the SID attribute. This step uses PE 1 as an example.

[PE1] display bgp l2vpn evpn [5][0][24][10.2.1.0]/80

BGP local router ID: 1.1.1.1

Local AS number: 100

Route distinguisher: 100:1(vpn1)

Total number of routes: 1

Paths: 1 available, 1 best

BGP routing table information of [5][0][24][10.2.1.0]/80:

From : 3::3 (3.3.3.3)

Rely nexthop : FE80::2A96:34FF:FE9D:216

Original nexthop: 3::3

Out interface : Ten-GigabitEthernet3/1/2

Route age : 00h14m23s

OutLabel : NULL

Ext-Community : <RT: 111:1>

RxPathID : 0x0

TxPathID : 0x0

PrefixSID : End.DT4 SID <6:5::101>

…

Verifying the configuration

# Display IPv4 routing table information on the PEs and verify that each PE has a route destined for the remote CE and the next hop of the route is the locator of the End.DT4 SID. This step uses PE 1 as an example.

[PE1] display ip routing-table vpn-instance vpn1

Destinations : 11 Routes : 11

Destination/Mask Proto Pre Cost NextHop Interface

0.0.0.0/32 Direct 0 0 127.0.0.1 InLoop0

10.1.1.0/24 Direct 0 0 10.1.1.1 XGE3/1/1

10.1.1.0/32 Direct 0 0 10.1.1.1 XGE3/1/1

10.1.1.1/32 Direct 0 0 127.0.0.1 InLoop0

10.1.1.255/32 Direct 0 0 10.1.1.1 XGE3/1/1

10.2.1.0/24 BGP 255 0 6:5:: XGE3/1/2

127.0.0.0/8 Direct 0 0 127.0.0.1 InLoop0

127.0.0.0/32 Direct 0 0 127.0.0.1 InLoop0

127.0.0.1/32 Direct 0 0 127.0.0.1 InLoop0

127.255.255.255/32 Direct 0 0 127.0.0.1 InLoop0

255.255.255.255/32 Direct 0 0 127.0.0.1 InLoop0

# Verify that CE 1 and CE 2 can ping each other. (Details not shown.)

Example: Configuring inter-AS option B VPN

Network configuration

As shown in Figure 7, an EVPN L3VPN network is deployed in AS 100 and an EVPN L3VPN over SRv6 network is deployed in AS 200. Configure inter-AS option B VPN to permit users in the same VPN instance to communicate with each other across the EVPN L3VPN and EVPN L3VPN over SRv6 networks.

Figure 7 Network diagram

‌

Device	Interface	IP address	Device	Interface	IP address
CE 1	XGE3/1/1	10.1.1.2/24	CE 2	XGE3/1/1	20.1.1.2/24
PE 1	Loop0	1.1.1.1/32	PE 2	Loop0	1::1/128
	XGE3/1/1	10.1.1.1/24		XGE3/1/1	20.1.1.1/24
	XGE3/1/2	11.1.1.1/24		XGE3/1/2	100::1/96
ASBR 1	Loop0	2.2.2.2/32	ASBR 2	Loop0	2::2/128
	XGE3/1/1	11.1.1.2/24		XGE3/1/1	100::2/96
	XGE3/1/2	12.1.1.1/24		XGE3/1/2	12.1.1.2/24

Procedure

1. Configure CE 1:

# Establish EBGP peer relationship with PE 1 and import VPN routes.

<CE1> system-view

[CE1] bgp 101

[CE1-bgp-default] peer 10.1.1.1 as-number 100

[CE1-bgp-default] address-family ipv4 unicast

[CE1-bgp-default-ipv4] peer 10.1.1.1 enable

[CE1-bgp-default-ipv4] import-route direct

[CE1-bgp-default-ipv4] quit

[CE1-bgp-default] quit

2. Configure PE 1:

# Run IS-IS on PE 1.

<PE1> system-view

[PE1] isis 1

[PE1-isis-1] cost-style wide

[PE1-isis-1] network-entity 10.1111.1111.1111.00

[PE1-isis-1] quit

# Specify an LSR ID and enable MPLS and LDP.

[PE1] mpls lsr-id 1.1.1.1

[PE1] mpls ldp

[PE1-ldp] quit

# On interface Ten-GigabitEthernet 3/1/2, specify an IP address, run IS-IS, and enable MPLS and LDP.

[PE1] interface ten-gigabitethernet 3/1/2

[PE1-Ten-GigabitEthernet3/1/2] ip address 11.1.1.1 255.0.0.0

[PE1-Ten-GigabitEthernet3/1/2] isis enable 1

[PE1-Ten-GigabitEthernet3/1/2] mpls enable

[PE1-Ten-GigabitEthernet3/1/2] mpls ldp enable

[PE1-Ten-GigabitEthernet3/1/2] quit

# Create interface Loopback 0, specify an IP address for the interface, and run IS-IS on the interface.

[PE1] interface loopback 0

[PE1-LoopBack0] ip address 1.1.1.1 32

[PE1-LoopBack0] isis enable 1

[PE1-LoopBack0] quit

# Create a VPN instance named vpn1 and configure a RD and route target for the VPN instance.

[PE1] ip vpn-instance vpn1

[PE1-vpn-instance-vpn1] route-distinguisher 100:1

[PE1-vpn-instance-vpn1] vpn-target 100:1

[PE1-vpn-instance-vpn1] quit

# Associate the interface connected to CE 1 with VPN instance vpn1.

[PE1] interface ten-gigabitethernet 3/1/1

[PE1-Ten-GigabitEthernet3/1/1] ip binding vpn-instance vpn1

[PE1-Ten-GigabitEthernet3/1/1] ip address 10.1.1.1 24

[PE1-Ten-GigabitEthernet3/1/1] quit

# Run BGP on PE 1.

[PE1] bgp 100

[PE1-bgp-default] router-id 1.1.1.1

# Configure PE 1 to exchange BGP EVPN routes with peer 2.2.2.2.

[PE1-bgp-default] peer 2.2.2.2 as-number 100

[PE1-bgp-default] peer 2.2.2.2 connect-interface loopback 0

[PE1-bgp-default] address-family l2vpn evpn

[PE1-bgp-default-evpn] peer 2.2.2.2 enable

[PE1-bgp-default-evpn] quit

# Establish EBGP peer relationship with CE 1 and import VPN routes.

[PE1-bgp-default] ip vpn-instance vpn1

[PE1-bgp-default-vpn1] peer 10.1.1.2 as-number 101

[PE1-bgp-default-vpn1] address-family ipv4 unicast

[PE1-bgp-default-ipv4-vpn1] peer 10.1.1.2 enable

[PE1-bgp-default-ipv4-vpn1] quit

[PE1-bgp-default-vpn1] quit

3. Configure ASBR 1:

# Run IS-IS on ASBR 1.

<ASBR1> system-view

[ASBR1] isis 1

[ASBR1-isis-1] cost-style wide

[ASBR1-isis-1] network-entity 10.2222.2222.2222.00

[ASBR1-isis-1] quit

# Specify an LSR ID and enable MPLS and LDP.

[ASBR1] mpls lsr-id 2.2.2.2

[ASBR1] mpls ldp

[ASBR1-ldp] quit

# On interface Ten-GigabitEthernet 3/1/1, specify an IP address, run IS-IS, and enable MPLS and LDP.

[ASBR1] interface ten-gigabitethernet 3/1/1

[ASBR1-Ten-GigabitEthernet3/1/1] ip address 11.1.1.2 255.0.0.0

[ASBR1-Ten-GigabitEthernet3/1/1] isis enable 1

[ASBR1-Ten-GigabitEthernet3/1/1] mpls enable

[ASBR1-Ten-GigabitEthernet3/1/1] mpls ldp enable

[ASBR1-Ten-GigabitEthernet3/1/1] quit

# On interface Ten-GigabitEthernet 3/1/2, specify an IP address and enable MPLS.

[ASBR1] interface ten-gigabitethernet 3/1/2

[ASBR1-Ten-GigabitEthernet3/1/2] ip address 12.1.1.1 255.0.0.0

[ASBR1-Ten-GigabitEthernet3/1/2] mpls enable

[ASBR1-Ten-GigabitEthernet3/1/2] quit

# Create interface Loopback 0, specify an IP address and run IS-IS on the interface.

[ASBR1] interface loopback 0

[ASBR1-LoopBack0] ip address 2.2.2.2 32

[ASBR1-LoopBack0] isis enable 1

[ASBR1-LoopBack0] quit

# Run BGP on ASBR 1.

[ASBR1] bgp 100

[ASBR1-bgp-default] router-id 2.2.2.2

[ASBR1-bgp-default] peer 1.1.1.1 as-number 100

[ASBR1-bgp-default] peer 1.1.1.1 connect-interface loopback 0

[ASBR1-bgp-default] peer 12.1.1.2 as-number 200

[ASBR1-bgp-default] peer 12.1.1.2 connect-interface ten-gigabitethernet 3/1/2

# Configure BGP to not filter received BGP EVPN routes based on route targets.

[ASBR1-bgp-default] address-family l2vpn evpn

[ASBR1-bgp-default-evpn] undo policy vpn-target

# Configure ASBR 1 to exchange BGP EVPN routes with IBGP peer 1.1.1.1 and EBGP peer 12.1.1.2.

[ASBR1-bgp-default-evpn] peer 12.1.1.2 enable

[ASBR1-bgp-default-evpn] peer 1.1.1.1 enable

[ASBR1-bgp-default-evpn] quit

[ASBR1-bgp-default] quit

4. Configure ASBR 2:

# Run IPv6 IS-IS on ASBR 2.

<ASBR2> system-view

[ASBR2] isis 1

[ASBR2-isis-1] cost-style wide

[ASBR2-isis-1] network-entity 10.3333.3333.3333.00

[ASBR2-isis-1] address-family ipv6 unicast

[ASBR2-isis-1-ipv6] quit

[ASBR2-isis-1] quit

# On interface Ten-GigabitEthernet 3/1/1, specify an IPv6 address and run IPv6 IS-IS.

[ASBR2] interface ten-gigabitethernet 3/1/1

[ASBR2-Ten-GigabitEthernet3/1/1] ipv6 address 100::2 96

[ASBR2-Ten-GigabitEthernet3/1/1] isis ipv6 enable 1

[ASBR2-Ten-GigabitEthernet3/1/1] quit

# On interface Ten-GigabitEthernet 3/1/2, specify an IP address and enable MPLS.

[ASBR2] interface ten-gigabitethernet 3/1/2

[ASBR2-Ten-GigabitEthernet3/1/2] ip address 12.1.1.2 255.0.0.0

[ASBR2-Ten-GigabitEthernet3/1/2] mpls enable

[ASBR2-Ten-GigabitEthernet3/1/2] quit

# Create interface Loopback 0, specify an IPv6 address for the interface, and run IPv6 IS-IS on the interface.

[ASBR2] interface loopback 0

[ASBR2-LoopBack0] ipv6 address 2::2 128

[ASBR2-LoopBack0] isis ipv6 enable 1

[ASBR2-LoopBack0] quit

# Run BGP on ASBR 2.

[ASBR2] bgp 200

[ASBR2-bgp-default] router-id 3.3.3.3

[ASBR2-bgp-default] peer 12.1.1.1 as-number 100

[ASBR2-bgp-default] peer 12.1.1.1 connect-interface ten-gigabitethernet 3/1/2

[ASBR2-bgp-default] peer 1::1 as-number 200

[ASBR2-bgp-default] peer 1::1 connect-interface loopback 0

# Configure BGP to not filter received BGP EVPN routes based on route targets.

[ASBR2-bgp-default] address-family l2vpn evpn

[ASBR2-bgp-default-evpn] undo policy vpn-target

# Configure ASBR 2 to exchange BGP EVPN routes with IBGP peer 1::1 and EBGP peer 12.1.1.1.

[ASBR2-bgp-default-evpn] peer 12.1.1.1 enable

[ASBR2-bgp-default-evpn] peer 1::1 enable

[ASBR2-bgp-default-evpn] quit

[ASBR2-bgp-default] quit

# Configure EVPN L3VPN over SRv6 BE.

[ASBR2] segment-routing ipv6

[ASBR2-segment-routing-ipv6] encapsulation source-address 2::2

[ASBR2-segment-routing-ipv6] locator abc ipv6-prefix 43:1:: 64 static 32

[ASBR2-segment-routing-ipv6-locator-abc] quit

[ASBR2-segment-routing-ipv6] quit

[ASBR2] bgp 200

[ASBR2-bgp-default] address-family l2vpn evpn

[ASBR2-bgp-default-evpn] peer 1::1 advertise encap-type srv6

[ASBR2-bgp-default-evpn] segment-routing ipv6 best-effort evpn

[ASBR2-bgp-default-evpn] segment-routing ipv6 locator abc evpn

# Enable SRv6 and MPLS interworking.

[ASBR2-bgp-default-evpn] srv6-mpls-interworking enable

[ASBR2-bgp-default-evpn] quit

[ASBR2-bgp-default] quit

# Apply a locator to IPv6 IS-IS.

[ASBR2] isis 1

[ASBR2-isis-1] address-family ipv6 unicast

[ASBR2-isis-1-ipv6] segment-routing ipv6 locator abc

[ASBR2-isis-1-ipv6] quit

[ASBR2-isis-1] quit

5. Configure PE 2:

# Run IPv6 IS-IS on PE 2.

<PE2> system-view

[PE2] isis 1

[PE2-isis-1] cost-style wide

[PE2-isis-1] network-entity 10.4444.4444.4444.00

[PE2-isis-1] address-family ipv6 unicast

[PE2-isis-1-ipv6] quit

[PE2-isis-1] quit

# On interface Ten-GigabitEthernet 3/1/2, specify an IPv6 address and run IPv6 IS-IS.

[PE2] interface ten-gigabitethernet 3/1/2

[PE2-Ten-GigabitEthernet3/1/2] ipv6 address 100::1 96

[PE2-Ten-GigabitEthernet3/1/2] isis ipv6 enable 1

[PE2-Ten-GigabitEthernet3/1/2] quit

# Create interface Loopback 0, specify an IPv6 address and run IPv6 IS-IS on the interface.

[PE2] interface loopback 0

[PE2-LoopBack0] ipv6 address 1::1 128

[PE2-LoopBack0] isis ipv6 enable 1

[PE2-LoopBack0] quit

# Create a VPN instance named vpn1 and configure a RD and route target for the VPN instance.

[PE2] ip vpn-instance vpn1

[PE2-vpn-instance-vpn1] route-distinguisher 100:1

[PE2-vpn-instance-vpn1] vpn-target 100:1

[PE2-vpn-instance-vpn1] quit

# Associate the interface connected to CE 2 with VPN instance vpn1.

[PE2] interface ten-gigabitethernet 3/1/1

[PE2-Ten-GigabitEthernet3/1/1] ip binding vpn-instance vpn1

[PE2-Ten-GigabitEthernet3/1/1] ip address 20.1.1.1 24

[PE2-Ten-GigabitEthernet3/1/1] quit

# Run BGP on PE 2.

[PE2] bgp 200

[PE2-bgp-default] router-id 4.4.4.4

# Configure PE 2 to exchange BGP EVPN routes with IBGP peer 2::2.

[PE2-bgp-default] peer 2::2 as-number 200

[PE2-bgp-default] peer 2::2 connect-interface loopback 0

[PE2-bgp-default] address-family l2vpn evpn

[PE2-bgp-default-evpn] peer 2::2 enable

[PE2-bgp-default-evpn] quit

# Establish EBGP peer relationship with CE 2 and import VPN routes.

[PE2-bgp-default] ip vpn-instance vpn1

[PE2-bgp-default-vpn1] peer 20.1.1.2 as-number 201

[PE2-bgp-default-vpn1] address-family ipv4 unicast

[PE2-bgp-default-ipv4-vpn1] peer 20.1.1.2 enable

[PE2-bgp-default-ipv4-vpn1] quit

[PE2-bgp-default-vpn1] quit

# Configure L3VPN over SRv6 BE.

[PE2] segment-routing ipv6

[PE2-segment-routing-ipv6] encapsulation source-address 1::1

[PE2-segment-routing-ipv6] locator abc ipv6-prefix 42:1:: 64 static 32

[PE2-segment-routing-ipv6-locator-abc] quit

[PE2-segment-routing-ipv6] quit

[PE2] bgp 200

[PE2-bgp-default] ip vpn-instance vpn1

[PE2-bgp-default-vpn1] address-family ipv4 unicast

[PE2-bgp-default-ipv4-vpn1] segment-routing ipv6 best-effort evpn

[PE2-bgp-default-ipv4-vpn1] segment-routing ipv6 locator abc evpn

[PE2-bgp-default-ipv4-vpn1] quit

[PE2-bgp-default-vpn1] quit

[PE2-bgp-default] address-family l2vpn evpn

[PE2-bgp-default-evpn] peer 2::2 advertise encap-type srv6

[PE2-bgp-default-evpn] quit

[PE2-bgp-default] quit

# Apply a locator to IPv6 IS-IS.

[PE2] isis 1

[PE2-isis-1] address-family ipv6 unicast

[PE2-isis-1-ipv6] segment-routing ipv6 locator abc

[PE2-isis-1-ipv6] quit

[PE2-isis-1] quit

6. Configure CE 2:

# Establish EBGP peer relationship with PE 2 and import VPN routes.

<CE2> system-view

[CE2] bgp 201

[CE2-bgp-default] peer 20.1.1.1 as-number 200

[CE2-bgp-default] address-family ipv4 unicast

[CE2-bgp-default-ipv4] peer 20.1.1.1 enable

[CE2-bgp-default-ipv4] import-route direct

[CE2-bgp-default-ipv4] quit

[CE2-bgp-default] quit

Verifying the configuration

# On ASBR 2, verify that the MPLS label and SRv6 SID have established mapping relationship. The LSP out label is the SRv6 SID.

[ASBR2] display mpls lsp srv6-mpls-interworking

FEC : 3::3/43:1::1:0:2

Protocol : BGP

In Label : 600127

Out SRv6 SID : 43:1::1:0:2

Path ID : 0x16000000.1

# Verify that CE 1 and CE 2 can ping each other. (Details not shown.)

Example: Configuring IPv4 EVPN L3VPN over G-SRv6 (with COC32 locators)

Network configuration

As shown in Figure 9, the backbone network is an IPv6 network, and VPN aaa is an IPv4 network. Deploy an SRv6 TE policy tunnel between PE 1 and PE 2 in the IPv6 network and use the SRv6 TE policy tunnel to transmit end-to-end VPN traffic.

· Because a large number of devices exist in the backbone network, the SID list for the optimal candidate path of the SRv6 TE policy contains many SRv6 SIDs. To reduce the SRH length for packets, use the G-SRv6 compression solution.

· The SRv6 nodes in the backbone network use COC32 locators, and assign SIDs with the COC flag from the COC32 locators.

· As shown in Figure 8, to prevent packet forwarding issues, appropriately plan the common prefix for the locators in the AS. Specify the common prefix as A:1:1:A:: with 64-bit length for COC32 locators on all devices. In addition, specify the IPv6 address prefix length for the locators as 80 bits, the static portion length for COC32 locators as 8 bits, and the Args portion length as 16 bits. Through calculation, the dynamic portion length in COC32 locators is 8 bits, and the MBZ length is 16 bits.

Figure 8 COC32 locator plan in the AS

Figure 9 Network diagram

‌

Device	Interfaces	IP address	Device	Interfaces	IP address
CE 1	XGE3/1/1	10.1.1.1/30	CE 2	XGE3/1/2	20.1.1.1/30
	Loop0	11.11.11.11/32		Loop0	22.22.22.22/32
PE 1	Loop0	1::1/128	PE 2	Loop0	5::5/128
	XGE3/1/1	10.1.1.2/30		XGE3/1/2	20.1.1.2/30
	XGE3/1/2	12:1:1::1/126		XGE3/1/1	45:1:1::2/126
P 1	Loop0	2::2/128	P 2	Loop0	3::3/128
	XGE3/1/1	23:1:1::1/126		XGE3/1/1	23:1:1::2/126
	XGE3/1/2	12:1:1::2/126		XGE3/1/2	34:1:1::1/126
P 3	Loop0	4::4/128
	XGE3/1/1	45:1:1::1/126
	XGE3/1/2	34:1:1::2/126

‌

Procedure

1. Configure CE 1:

# Configure IP addresses for the interfaces.

<CE1> system-view

[CE1] sysname CE1

[CE1] interface ten-gigabitethernet 3/1/1

[CE1-Ten-GigabitEthernet3/1/1] ip address 10.1.1.1 30

[CE1-Ten-GigabitEthernet3/1/1] quit

[CE1] interface loopback 0

[CE1-LoopBack0] ip address 11.11.11.11 32

[CE1-LoopBack0] quit

# Create EBGP peers between the PE and CE, and import direct routes.

[CE1] bgp 10

[CE1-bgp-default] router-id 11.11.11.11

[CE1-bgp-default] peer 10.1.1.2 as-number 100

[CE1-bgp-default] address-family ipv4 unicast

[CE1-bgp-default-ipv4] peer 10.1.1.2 enable

[CE1-bgp-default-ipv4] import-route direct

[CE1-bgp-default-ipv4] quit

[CE1-bgp-default] quit

2. Configure CE 2:

# Configure IP addresses for the interfaces.

<CE2> system-view

[CE2] sysname CE2

[CE2] interface ten-gigabitethernet 3/1/2

[CE2-Ten-GigabitEthernet3/1/2] ip address 20.1.1.1 30

[CE2-Ten-GigabitEthernet3/1/2] quit

[CE2] interface loopback 0

[CE2-LoopBack0] ip address 22.22.22.22 32

[CE2-LoopBack0] quit

# Create EBGP peers between the PE and CE, and import direct routes.

[CE2] bgp 20

[CE2-bgp-default] router-id 22.22.22.22

[CE2-bgp-default] peer 20.1.1.2 as-number 100

[CE2-bgp-default] address-family ipv4 unicast

[CE2-bgp-default-ipv4] peer 20.1.1.2 enable

[CE2-bgp-default-ipv4] import-route direct

[CE2-bgp-default-ipv4] quit

[CE2-bgp-default] quit

3. Configure PE 1:

# Configure the VPN instance on PE 1 to connect the CE to PE.

<PE1> system-view

[PE1] sysname PE1

[PE1] ip vpn-instance aaa

[PE1-vpn-instance-aaa] route-distinguisher 100:1

[PE1-vpn-instance-aaa] vpn-target 200:1 both

[PE1-vpn-instance-aaa] quit

# Configure IP addresses for the interfaces.

[PE1] interface loopback 0

[PE1-LoopBack0] ipv6 address 1::1 128

[PE1-LoopBack0] quit

[PE1] interface ten-gigabitethernet 3/1/1

[PE1-Ten-GigabitEthernet3/1/1] ip binding vpn-instance aaa

[PE1-Ten-GigabitEthernet3/1/1] ip address 10.1.1.2 30

[PE1-Ten-GigabitEthernet3/1/1] quit

[PE1] interface ten-gigabitethernet 3/1/2

[PE1-Ten-GigabitEthernet3/1/2] ipv6 address 12:1:1::1 126

[PE1-Ten-GigabitEthernet3/1/2] quit

# Configure IPv6 IS-IS to implement backbone network intercommunication.

[PE1] isis 1

[PE1-isis-1] is-level level-2

[PE1-isis-1] cost-style wide

[PE1-isis-1] network-entity 00.0000.0000.0001.00

[PE1-isis-1] address-family ipv6 unicast

[PE1-isis-1-ipv6] quit

[PE1-isis-1] quit

[PE1] interface ten-gigabitethernet 3/1/2

[PE1-Ten-GigabitEthernet3/1/2] isis ipv6 enable 1

[PE1-Ten-GigabitEthernet3/1/2] quit

[PE1] interface loopback 0

[PE1-LoopBack0] isis ipv6 enable 1

[PE1-LoopBack0] quit

# Configure an SRv6 locator on the PE to be advertised by IGP, and enable SRv6 compression.

[PE1] segment-routing-ipv6

[PE1-segment-routing-ipv6] srv6 compress enable

[PE1-segment-routing-ipv6] locator a ipv6-prefix A:1:1:A:1:: 80 common-prefix 64 coc32 static 8 args 16

[PE1-segment-routing-ipv6-locator-a] quit

[PE1-segment-routing-ipv6] quit

[PE1] isis 1

[PE1-isis-1] address-family ipv6 unicast

[PE1-isis-1-ipv6] segment-routing ipv6 locator a auto-sid-coc32

[PE1-isis-1-ipv6] srv6 compress enable

[PE1-isis-1-ipv6] quit

[PE1-isis-1] quit

# Specify a source address for the outer IPv6 header of SRv6-encapsulated IPv4 EVPN L3VPN packets on the PE.

[PE1] segment-routing ipv6

[PE1-segment-routing-ipv6] encapsulation source-address 1::1

# Configure the source address of SBFD packets on PE 1.

[PE1] sbfd source-ipv6 1::1

# Configure a static SID list on the PE that contains SRv6 SIDs with the COC flag, specify the static SID list for an SRv6 TE policy, and enable SBFD for the SRv6 TE policy, ensuring that the SRv6 TE policy tunnel can forward services correctly.

In the static SID list:

¡ The first hop is the End.X(COC32) SID of the link from P 1 to P 2. The SRv6 SID in the encapsulated SRH is still 128 bits long without being compressed. The next SID will be compressed.

¡ The second hop is the End(COC32) SID of P 2. The SRv6 SID in the encapsulated SRH is compressed to 32 bits long.

¡ The third hop is the End.X(COC32) SID of the link from P 3 to PE 2. The SRv6 SID in the encapsulated SRH is compressed to 32 bits long.

¡ The fourth hop is the End SID of PE 2. The SRv6 SID in the encapsulated SRH is compressed to 32 bits long. The next SID will not be compressed.

[PE1] segment-routing ipv6

[PE1-segment-routing-ipv6] traffic-engineering

[PE1-srv6-te] srv6-policy locator a

[PE1-srv6-te] segment-list a

[PE1-srv6-te-sl-a] index 10 coc32 ipv6 A:1:1:A:2:20:: 64

[PE1-srv6-te-sl-a] index 20 coc32 ipv6 A:1:1:A:3:10:: 64

[PE1-srv6-te-sl-a] index 30 coc32 ipv6 A:1:1:A:4:20:: 64

[PE1-srv6-te-sl-a] index 40 ipv6 A:1:1:A:5:10::

[PE1-srv6-te-sl-a] quit

[PE1-srv6-te] policy a

[PE1-srv6-te-policy-a] color 10 end-point ipv6 5::5

[PE1-srv6-te-policy-a] sbfd enable remote 1000001

[PE1-srv6-te-policy-a] candidate-paths

[PE1-srv6-te-policy-a-path] preference 200

[PE1-srv6-te-policy-a-path-pref-200] explicit segment-list a

[PE1-srv6-te-policy-a-path-pref-200] quit

[PE1-srv6-te-policy-a-path] quit

[PE1-srv6-te-policy-a] quit

[PE1-srv6-te] quit

[PE1-segment-routing-ipv6] quit

# Create EBGP peers between the PE and CE, and import VPN routes.

[PE1] bgp 100

[PE1-bgp-default] router-id 1.1.1.1

[PE1-bgp-default] ip vpn-instance aaa

[PE1-bgp-default-aaa] peer 10.1.1.1 as-number 10

[PE1-bgp-default-aaa] address-family ipv4 unicast

[PE1-bgp-default-ipv4-aaa] peer 10.1.1.1 enable

[PE1-bgp-default-ipv4-aaa] quit

[PE1-bgp-default-aaa] quit

# Create MP-IBGP peers between PE 1 and PE 2.

[PE1-bgp-default] peer 5::5 as-number 100

[PE1-bgp-default] peer 5::5 connect-interface loopback 0

[PE1-bgp-default] address-family l2vpn evpn

[PE1-bgp-default-evpn] peer 5::5 enable

[PE1-bgp-default-evpn] quit

[PE1-bgp-default] quit

# Enable exchange of SRv6-encapsulated EVPN routes between MP-IBGP peers on PE 1, and enable recursion of VPN routes to the SRv6 TE policy tunnel.

[PE1] bgp 100

[PE1-bgp-default] address-family l2vpn evpn

[PE1-bgp-default-evpn] peer 5::5 advertise encap-type srv6

[PE1-bgp-default-evpn] quit

[PE1-bgp-default] ip vpn-instance aaa

[PE1-bgp-default-aaa] address-family ipv4 unicast

[PE1-bgp-default-ipv4-aaa] segment-routing ipv6 locator a evpn

[PE1-bgp-default-ipv4-aaa] segment-routing ipv6 traffic-engineering evpn

[PE1-bgp-default-ipv4-aaa] quit

[PE1-bgp-default-aaa] quit

[PE1-bgp-default] quit

# Configure a routing policy and a tunnel policy on PE 1 to steer VPN service traffic to the specified SRv6 TE policy through the routing policy and ensure that the SRv6 TE policy is the optimal tunnel.

[PE1] route-policy a permit node 10

[PE1-route-policy-a-10] apply extcommunity color 00:10

[PE1-route-policy-a-10] quit

[PE1] bgp 100

[PE1-bgp-default] address-family l2vpn evpn

[PE1-bgp-default-evpn] peer 5::5 route-policy a import

[PE1-bgp-default-evpn] quit

[PE1-bgp-default] quit

[PE1] tunnel-policy a

[PE1-tunnel-policy-a] select-seq srv6-policy load-balance-number 1

[PE1-tunnel-policy-a] quit

[PE1] ip vpn-instance vpn1

[PE1-vpn-instance-vpn1] tnl-policy a

[PE1-vpn-instance-vpn1] quit

4. Configure P 1:

# Configure IP addresses for the interfaces.

[P1] interface loopback 0

[P1-LoopBack0] ipv6 address 2::2 128

[P1-LoopBack0] quit

[P1] interface ten-gigabitethernet 3/1/1

[P1-Ten-GigabitEthernet3/1/1] ipv6 address 23:1:1::1 126

[P1-Ten-GigabitEthernet3/1/1] quit

[P1] interface ten-gigabitethernet 3/1/2

[P1-Ten-GigabitEthernet3/1/2] ipv6 address 12:1:1::2 126

[P1-Ten-GigabitEthernet3/1/2] quit

# Configure IPv6 IS-IS to implement backbone network intercommunication.

[P1] isis 1

[P1-isis-1] is-level level-2

[P1-isis-1] cost-style wide

[P1-isis-1] network-entity 00.0000.0000.0002.00

[P1-isis-1] address-family ipv6 unicast

[P1-isis-1-ipv6] quit

[P1-isis-1] quit

[P1] interface ten-gigabitethernet 3/1/1

[P1-Ten-GigabitEthernet3/1/1] isis ipv6 enable 1

[P1-Ten-GigabitEthernet3/1/1] quit

[P1] interface ten-gigabitethernet 3/1/2

[P1-Ten-GigabitEthernet3/1/2] isis ipv6 enable 1

[P1-Ten-GigabitEthernet3/1/2] quit

[P1] interface loopback 0

[P1-LoopBack0] isis ipv6 enable 1

[P1-LoopBack0] quit

# Configure an SRv6 locator on P 1 to be advertised by IGP, and enable SRv6 compression.

[P1] segment-routing-ipv6

[P1-segment-routing-ipv6] srv6 compress enable

[P1-segment-routing-ipv6] locator b ipv6-prefix A:1:1:A:2:: 80 common-prefix 64 coc32 static 8 args 16

[P1-segment-routing-ipv6-locator-b] opcode 32 end-x-coc32 interface Ten-GigabitEthernet3/1/1 nexthop 23:1:1::2 no-flavor

[P1-segment-routing-ipv6-locator-b] quit

[P1-segment-routing-ipv6] quit

[P1] isis 1

[P1-isis-1] address-family ipv6 unicast

[P1-isis-1-ipv6] segment-routing ipv6 locator b auto-sid-coc32

[P1-isis-1-ipv6] srv6 compress enable

[P1-isis-1-ipv6] quit

[P1-isis-1] quit

5. Configure P 2:

# Configure IP addresses for the interfaces.

[P2] interface loopback 0

[P2-LoopBack0] ipv6 address 3::3 128

[P2-LoopBack0] quit

[P2] interface ten-gigabitethernet 3/1/1

[P2-Ten-GigabitEthernet3/1/1] ipv6 address 23:1:1::2 126

[P2-Ten-GigabitEthernet3/1/1] quit

[P2] interface ten-gigabitethernet 3/1/2

[P2-Ten-GigabitEthernet3/1/2] ipv6 address 34:1:1::1 126

[P2-Ten-GigabitEthernet3/1/2] quit

# Configure IPv6 IS-IS to implement backbone network intercommunication.

[P2] isis 1

[P2-isis-1] is-level level-2

[P2-isis-1] cost-style wide

[P2-isis-1] network-entity 00.0000.0000.0003.00

[P2-isis-1] address-family ipv6 unicast

[P2-isis-1-ipv6] quit

[P2-isis-1] quit

[P2] interface ten-gigabitethernet 3/1/1

[P2-Ten-GigabitEthernet3/1/1] isis ipv6 enable 1

[P2-Ten-GigabitEthernet3/1/1] quit

[P2] interface ten-gigabitethernet 3/1/2

[P2-Ten-GigabitEthernet3/1/2] isis ipv6 enable 1

[P2-Ten-GigabitEthernet3/1/2] quit

[P2] interface loopback 0

[P2-LoopBack0] isis ipv6 enable 1

[P2-LoopBack0] quit

# Configure an SRv6 locator on P 2 to be advertised by IGP, and enable SRv6 compression.

[P2] segment-routing-ipv6

[P2-segment-routing-ipv6] srv6 compress enable

[P2-segment-routing-ipv6] locator c ipv6-prefix A:1:1:A:3:: 80 common-prefix 64 coc32 static 8 args 16

[P2-segment-routing-ipv6-locator-c] opcode 16 end-coc32 no-flavor

[P2-segment-routing-ipv6-locator-c] quit

[P2-segment-routing-ipv6] quit

[P2] isis 1

[P2-isis-1] address-family ipv6 unicast

[P2-isis-1-ipv6] segment-routing ipv6 locator c auto-sid-coc32

[P2-isis-1-ipv6] srv6 compress enable

[P2-isis-1-ipv6] quit

[P2-isis-1] quit

6. Configure P 3:

# Configure IP addresses for the interfaces.

[P3] interface loopback 0

[P3-LoopBack0] ipv6 address 4::4 128

[P3-LoopBack0] quit

[P3] interface ten-gigabitethernet 3/1/1

[P3-Ten-GigabitEthernet3/1/1] ipv6 address 45:1:1::1 126

[P3-Ten-GigabitEthernet3/1/1] quit

[P3] interface ten-gigabitethernet 3/1/2

[P3-Ten-GigabitEthernet3/1/2] ipv6 address 34:1:1::2 126

[P3-Ten-GigabitEthernet3/1/2] quit

# Configure IPv6 IS-IS to implement backbone network intercommunication.

[P3] isis 1

[P3-isis-1] is-level level-2

[P3-isis-1] cost-style wide

[P3-isis-1] network-entity 00.0000.0000.0004.00

[P3-isis-1] address-family ipv6 unicast

[P3-isis-1-ipv6] quit

[P3-isis-1] quit

[P3] interface ten-gigabitethernet 3/1/1

[P3-Ten-GigabitEthernet3/1/1] isis ipv6 enable 1

[P3-Ten-GigabitEthernet3/1/1] quit

[P3] interface ten-gigabitethernet 3/1/2

[P3-Ten-GigabitEthernet3/1/2] isis ipv6 enable 1

[P3-Ten-GigabitEthernet3/1/2] quit

[P3] interface loopback 0

[P3-LoopBack0] isis ipv6 enable 1

[P3-LoopBack0] quit

# Configure an SRv6 locator on P 3 to be advertised by IGP, and enable SRv6 compression.

[P3] segment-routing-ipv6

[P3-segment-routing-ipv6] srv6 compress enable

[P3-segment-routing-ipv6] locator d ipv6-prefix A:1:1:A:4:: 80 common-prefix 64 coc32 static 8 args 16

[P3-segment-routing-ipv6-locator-d] opcode 32 end-x-coc32 interface Ten-GigabitEthernet3/1/1 nexthop 45:1:1::2 no-flavor

[P3-segment-routing-ipv6-locator-d] quit

[P3-segment-routing-ipv6] quit

[P3] isis 1

[P3-isis-1] address-family ipv6 unicast

[P3-isis-1-ipv6] segment-routing ipv6 locator d auto-sid-coc32

[P3-isis-1-ipv6] srv6 compress enable

[P3-isis-1-ipv6] quit

[P3-isis-1] quit

7. Configure PE 2:

# Configure the VPN instance on PE 2 to connect the CE to PE.

<PE2> system-view

[PE2] sysname PE2

[PE2] ip vpn-instance aaa

[PE2-vpn-instance-aaa] route-distinguisher 100:1

[PE2-vpn-instance-aaa] vpn-target 200:1 both

[PE2-vpn-instance-aaa] quit

# Configure IP addresses for the interfaces.

[PE2] interface loopback 0

[PE2-LoopBack0] ipv6 address 5::5 128

[PE2-LoopBack0] quit

[PE2] interface ten-gigabitethernet 3/1/2

[PE2-Ten-GigabitEthernet3/1/2] ip binding vpn-instance aaa

[PE2-Ten-GigabitEthernet3/1/2] ip address 20.1.1.2 30

[PE2-Ten-GigabitEthernet3/1/2] quit

[PE2] interface ten-gigabitethernet 3/1/1

[PE2-Ten-GigabitEthernet3/1/1] ipv6 address 45:1:1::2 126

[PE2-Ten-GigabitEthernet3/1/1] quit

# Configure IPv6 IS-IS to implement backbone network intercommunication.

[PE2] isis 1

[PE2-isis-1] is-level level-2

[PE2-isis-1] cost-style wide

[PE2-isis-1] network-entity 00.0000.0000.0005.00

[PE2-isis-1] address-family ipv6 unicast

[PE2-isis-1-ipv6] quit

[PE2-isis-1] quit

[PE2] interface ten-gigabitethernet 3/1/1

[PE2-Ten-GigabitEthernet3/1/1] isis ipv6 enable 1

[PE2-Ten-GigabitEthernet3/1/1] quit

[PE2] interface loopback 0

[PE2-LoopBack0] isis ipv6 enable 1

[PE2-LoopBack0] quit

# Configure an SRv6 locator on the PE to be advertised by IGP, and enable SRv6 compression.

[PE2] segment-routing-ipv6

[PE2-segment-routing-ipv6] srv6 compress enable

[PE2-segment-routing-ipv6] locator e ipv6-prefix A:1:1:A:5:: 80 common-prefix 64 coc32 static 8 args 16

[PE2-segment-routing-ipv6-locator-e] opcode 16 end no-flavor

[PE2-segment-routing-ipv6-locator-e] quit

[PE2-segment-routing-ipv6] quit

[PE2] isis 1

[PE2-isis-1] address-family ipv6 unicast

[PE2-isis-1-ipv6] segment-routing ipv6 locator e auto-sid-coc32

[PE2-isis-1-ipv6] srv6 compress enable

[PE2-isis-1-ipv6] quit

[PE2-isis-1] quit

# Specify a source address for the outer IPv6 header of SRv6-encapsulated EVPN L3VPN packets on the PE.

[PE2] segment-routing ipv6

[PE2-segment-routing-ipv6] encapsulation source-address 5::5

# Create EBGP peers between the PE and CE, and import VPN routes.

[PE2] bgp 100

[PE2-bgp-default] router-id 5.5.5.5

[PE2-bgp-default] ip vpn-instance aaa

[PE2-bgp-default-aaa] peer 20.1.1.1 as-number 20

[PE2-bgp-default-aaa] address-family ipv4 unicast

[PE2-bgp-default-ipv4-aaa] peer 20.1.1.1 enable

[PE2-bgp-default-ipv4-aaa] quit

[PE2-bgp-default-aaa] quit

# Create MP-IBGP peers between PE 1 and PE 2.

[PE2-bgp-default] peer 1::1 as-number 100

[PE2-bgp-default] peer 1::1 connect-interface loopback 0

[PE2-bgp-default] address-family l2vpn evpn

[PE2-bgp-default-evpn] peer 1::1 enable

[PE2-bgp-default-evpn] quit

[PE2-bgp-default] quit

# Enable exchange of SRv6-encapsulated EVPN routes between MP-IBGP peers on PE 2, and enable recursion of VPN routes to the SRv6 BE tunnel.

[PE2] bgp 100

[PE2-bgp-default] address-family l2vpn evpn

[PE2-bgp-default-evpn] peer 1::1 advertise encap-type srv6

[PE2-bgp-default-evpn] quit

[PE2-bgp-default] ip vpn-instance aaa

[PE2-bgp-default-aaa] address-family ipv4 unicast

[PE2-bgp-default-ipv4-aaa] segment-routing ipv6 locator e evpn

[PE2-bgp-default-ipv4-aaa] segment-routing ipv6 best-effort evpn

[PE2-bgp-default-ipv4-aaa] quit

[PE2-bgp-default-aaa] quit

[PE2-bgp-default] quit

# Specify the local discriminator for the SBFD session on PE 2, and make sure it is the same as the remote discriminator on PE 1.

[PE2] sbfd local-discriminator 1000001

Verifying the configuration

# On PE 1, execute the display segment-routing ipv6 te policy command to display detailed SRv6 TE policy information. Verify that the Status field for the SRv6 TE policy is Up, and the SID list state is Up.

[PE1] display segment-routing ipv6 te policy

Name/ID: a/0

Color: 10

End-point: 5::5

Name from BGP:

Name from PCE:

BSID:

Mode: Dynamic Type: Type_2 Request state: Succeeded

Current BSID: A:1:1:A:1:104:: Explicit BSID: - Dynamic BSID: A:1:1:A:1:104::

Reference counts: 5

Flags: A/BS/NC

Status: Up

AdminStatus: Up

Up time: 2023-08-04 16:21:25

Down time: 2023-08-04 16:13:02

Hot backup: Disabled

Statistics: Disabled

Statistics by service class: Disabled

Path verification: Not configured

Drop-upon-invalid: Disabled

BFD trigger path-down: Disabled

SBFD: Enabled

Encapsulation mode: -

Remote: 1000001

SBFD template name: -

SBFD backup template name: -

OAM SID: -

Reverse path type: None

BFD Echo: Disabled

BFD no-bypass: Disabled

Forward no-bypass: Disabled

Forwarding index: 2150629377

Association ID: 0

Service-class: -

Rate-limit: -

PCE delegation: Disabled

PCE delegate report-only: Disabled

Reoptimization: Disabled

Encapsulation mode: -

Flapping suppression Remaining interval: -

Candidate paths state: Configured

Candidate paths statistics:

CLI paths: 1 BGP paths: 0 PCEP paths: 0 ODN paths: 0

Candidate paths:

Preference : 200

Network slice ID: -

CPathName:

CPathPolicyName:

ProtoOrigin: CLI Discriminator: 200

Instance ID: 0 Node address: 0.0.0.0

Originator: 0, ::

Optimal: Y Flags: V/A

Dynamic: Not configured

PCEP: Not configured

Explicit SID list:

ID: 1 Name: a

Weight: 1 Forwarding index: 2149580802

State: Up State(SBFD): Up

Verification State: -

Path MTU: 1500 Path MTU Reserved: 0

SID list flags: None

Local BSID: -

Reverse BSID: -

# On PE 1, execute the display bgp l2vpn evpn command to display detailed information about the route sent by PE 2. Verify that the route sent by PE 2 carries the PrefixSID attribute data.

[PE1] display bgp l2vpn evpn [5][0][32][22.22.22.22] 80

BGP local router ID: 1.1.1.1

Local AS number: 100

Route distinguisher: 100:1(aaa)

Total number of routes: 1

Paths: 1 available, 1 best

BGP routing table information of [5][0][32][22.22.22.22]/80:

From : 5::5 (5.5.5.5)

Rely nexthop : FE80::1AF8:23FF:FE50:207

Original nexthop: 5::5

Out interface : Ten-GigabitEthernet3/1/2

Route age : 00h00m39s

OutLabel : 3

Ext-Community : <RT: 200:1>, <CO-Flag:Color(00:10)>

RxPathID : 0x0

TxPathID : 0x0

PrefixSID : End.DT4 SID <A:1:1:A:5:104::>

SRv6 Service TLV (37 bytes):

Type: SRV6 L3 Service TLV (5)

Length: 34 bytes, Reserved: 0x0

SRv6 Service Information Sub-TLV (33 bytes):

Type: 1 Length: 30, Rsvdl: 0x0

SID Flags: 0x0 Endpoint behavior: 0x13 Rsvd2: 0x0

SRv6 SID Sub-Sub-TLV:

Type: 1 Len: 6

BL: 64 NL: 16 FL: 16 AL: 16 TL: 0 TO: 0

AS-path : 20

Origin : incomplete

Attribute value : MED 0, localpref 100, pref-val 0

State : valid, internal, best

Source type : local

IP precedence : N/A

QoS local ID : N/A

Traffic index : N/A

EVPN route type : IP prefix advertisement route

ESI : 0000.0000.0000.0000.0000

Ethernet tag ID : 0

IP prefix : 22.22.22.22/32

Gateway address : 0.0.0.0

MPLS label : 3

Tunnel policy : NULL

Rely tunnel IDs : N/A

Re-orignination : Disable

# On PE 1, execute the display ip routing-table vpn-instance command. Verify that VPN route 22.22.22.22 is available to CE 2, and the output interface for the route is SRv6 TE policy tunnel a.

Take PE 1 as an example:

[PE1] display ip routing-table vpn-instance aaa

Destinations : 8 Routes : 8

Destination/Mask Proto Pre Cost NextHop Interface

10.1.1.0/30 Direct 0 0 10.1.1.2 XGE3/1/1

10.1.1.2/32 Direct 0 0 127.0.0.1 XGE3/1/1

10.1.1.3/32 Direct 0 0 10.1.1.2 XGE3/1/1

11.11.11.11/32 BGP 255 0 10.1.1.1 XGE3/1/1

20.1.1.0/30 BGP 255 0 5::5 a

22.22.22.22/32 BGP 255 0 5::5 a

127.0.0.0/8 Direct 0 0 127.0.0.1 InLoop0

255.255.255.255/32 Direct 0 0 127.0.0.1 InLoop0

# From source IP address 11.11.11.11 on CE 1, ping destination IP address 22.22.22.22 on CE 2. Verify that the ping operation is successful. Capture packets on the forwarding interfaces of the devices such as PE 1 to verify that the second-, third-, and fourth-hop SIDs are all compressed to 32 bits in the static SID list of the SRH. Compression is implemented through G-SRv6.

Example: Configuring IPv4 EVPN L3VPN over G-SRv6 (with COC-both locators)

Network configuration

As shown in Figure 11, the backbone network is an IPv6 network, and VPN aaa is an IPv4 network. Deploy an SRv6 TE policy tunnel between PE 1 and PE 2 in the IPv6 network and use the SRv6 TE policy tunnel to transmit end-to-end VPN traffic.

· The SRv6 nodes in the backbone network use COC-both locators, and dynamically assign various types of SRv6 SIDs from the COC-both locators. Execute the display segment-routing ipv6 local-sid command on each SRv6 node to display local Srv6 SIDs. Add the SRv6 SIDs in the appropriate order to the SID list of the SRv6 TE policy.

· As shown in Figure 10, to prevent packet forwarding issues, appropriately plan the common prefix for the locators in the AS. Specify the common prefix as A:2:2:A:: with 64-bit length for COC-both locators on all devices. In addition, specify the IPv6 address prefix length for the locators as 80 bits, the compressible static portion length (C-SID Static) for COC-both locators as 8 bits, the non-compressible static portion length (NC-SID Static) as 8 bits, and the Args portion length as 16 bits. Through calculation, the compressible dynamic portion length (C-SID Dynamic) is 8 bits, and the non-compressible static portion length (NC-SID Static) is 8 bits.

· In the compressible SID (C-SID) range, you can dynamically assign or statically specify SIDs with the COC flag, for example, End(COC32) SIDs and End.X(COC32) SIDs. You can also dynamically assign or statically specify SIDs without the COC flag, for example, End(COCNONE) SIDs and End.X(COCNONE) SIDs. In the non-compressible SID (NC-SID) range, you can assign common SIDs, for example, End SIDs and End.X SIDs.

Figure 10 COC-both locator plan in the AS

Figure 11 Network diagram

‌

Device	Interfaces	IP address	Device	Interfaces	IP address
CE 1	XGE3/1/1	10.1.1.1/30	CE 2	XGE3/1/2	20.1.1.1/30
	Loop0	11.11.11.11/32		Loop0	22.22.22.22/32
PE 1	Loop0	1::1/128	PE 2	Loop0	5::5/128
	XGE3/1/1	10.1.1.2/30		XGE3/1/2	20.1.1.2/30
	XGE3/1/2	12:1:1::1/126		XGE3/1/1	45:1:1::2/126
P 1	Loop0	2::2/128	P 2	Loop0	3::3/128
	XGE3/1/1	23:1:1::1/126		XGE3/1/1	23:1:1::2/126
	XGE3/1/2	12:1:1::2/126		XGE3/1/2	34:1:1::1/126
P 3	Loop0	4::4/128
	XGE3/1/1	45:1:1::1/126
	XGE3/1/2	34:1:1::2/126

Procedure

1. Configure CE 1:

# Configure IP addresses for the interfaces.

<CE1> system-view

[CE1] sysname CE1

[CE1] interface ten-gigabitethernet 3/1/1

[CE1-Ten-GigabitEthernet3/1/1] ip address 10.1.1.1 30

[CE1-Ten-GigabitEthernet3/1/1] quit

[CE1] interface loopback 0

[CE1-LoopBack0] ip address 11.11.11.11 32

[CE1-LoopBack0] quit

# Create EBGP peers between the PE and CE, and import direct routes.

[CE1] bgp 10

[CE1-bgp-default] router-id 11.11.11.11

[CE1-bgp-default] peer 10.1.1.2 as-number 100

[CE1-bgp-default] address-family ipv4 unicast

[CE1-bgp-default-ipv4] peer 10.1.1.2 enable

[CE1-bgp-default-ipv4] import-route direct

[CE1-bgp-default-ipv4] quit

[CE1-bgp-default] quit

2. Configure CE 2:

# Configure IP addresses for the interfaces.

<CE2> system-view

[CE2] sysname CE2

[CE2] interface ten-gigabitethernet 3/1/2

[CE2-Ten-GigabitEthernet3/1/2] ip address 20.1.1.1 30

[CE2-Ten-GigabitEthernet3/1/2] quit

[CE2] interface loopback 0

[CE2-LoopBack0] ip address 22.22.22.22 32

[CE2-LoopBack0] quit

# Create EBGP peers between the PE and CE, and import direct routes.

[CE2] bgp 20

[CE2-bgp-default] router-id 22.22.22.22

[CE2-bgp-default] peer 20.1.1.2 as-number 100

[CE2-bgp-default] address-family ipv4 unicast

[CE2-bgp-default-ipv4] peer 20.1.1.2 enable

[CE2-bgp-default-ipv4] import-route direct

[CE2-bgp-default-ipv4] quit

[CE2-bgp-default] quit

3. Configure PE 1:

# Configure the VPN instance on PE 1 to connect the CE to PE.

<PE1> system-view

[PE1] sysname PE1

[PE1] ip vpn-instance aaa

[PE1-vpn-instance-aaa] route-distinguisher 100:1

[PE1-vpn-instance-aaa] vpn-target 200:1 both

[PE1-vpn-instance-aaa] quit

# Configure IP addresses for the interfaces.

[PE1] interface loopback 0

[PE1-LoopBack0] ipv6 address 1::1 128

[PE1-LoopBack0] quit

[PE1] interface ten-gigabitethernet 3/1/1

[PE1-Ten-GigabitEthernet3/1/1] ip binding vpn-instance aaa

[PE1-Ten-GigabitEthernet3/1/1] ip address 10.1.1.2 30

[PE1-Ten-GigabitEthernet3/1/1] quit

[PE1] interface ten-gigabitethernet 3/1/2

[PE1-Ten-GigabitEthernet3/1/2] ipv6 address 12:1:1::1 126

[PE1-Ten-GigabitEthernet3/1/2] quit

# Configure IPv6 IS-IS to implement backbone network intercommunication.

[PE1] isis 1

[PE1-isis-1] is-level level-2

[PE1-isis-1] cost-style wide

[PE1-isis-1] network-entity 00.0000.0000.0001.00

[PE1-isis-1] address-family ipv6 unicast

[PE1-isis-1-ipv6] quit

[PE1-isis-1] quit

[PE1] interface ten-gigabitethernet 3/1/2

[PE1-Ten-GigabitEthernet3/1/2] isis ipv6 enable 1

[PE1-Ten-GigabitEthernet3/1/2] quit

[PE1] interface loopback 0

[PE1-LoopBack0] isis ipv6 enable 1

[PE1-LoopBack0] quit

# Configure an SRv6 locator on the PE to be advertised by IGP, and enable SRv6 compression.

[PE1] segment-routing-ipv6

[PE1-segment-routing-ipv6] srv6 compress enable

[PE1-segment-routing-ipv6] locator ax ipv6-prefix A:2:2:A:1:: 80 common-prefix 64 coc-both non-compress-static 8 static 8 args 16

[PE1-segment-routing-ipv6-locator-ax] quit

[PE1-segment-routing-ipv6] quit

[PE1] isis 1

[PE1-isis-1] address-family ipv6 unicast

[PE1-isis-1-ipv6] segment-routing ipv6 locator ax auto-sid-coc-both coc32

[PE1-isis-1-ipv6] srv6 compress enable

[PE1-isis-1-ipv6] quit

[PE1-isis-1] quit

# Specify a source address for the outer IPv6 header of SRv6-encapsulated IPv4 EVPN L3VPN packets on the PE.

[PE1] segment-routing ipv6

[PE1-segment-routing-ipv6] encapsulation source-address 1::1

# Configure the source address of SBFD packets on PE 1.

[PE1] sbfd source-ipv6 1::1

In the static SID list:

¡ The first hop is the End.X(COC32) SID of the link from P 1 to P 2. The SRv6 SID in the encapsulated SRH is still 128 bits long without being compressed. The next SID will be compressed. After configuring P1, you can execute the display segment-routing ipv6 local-sid command to obtain information about dynamically allocated End.X(COC32) SIDs.

¡ The second hop is the End(COC32) SID of P 2. The SRv6 SID in the encapsulated SRH is compressed to 32 bits long. After configuring P 2, you can execute the display segment-routing ipv6 local-sid command to obtain information about dynamically allocated End(COC32) SIDs.

¡ The third hop is the End.X(COC32) SID of the link from P 3 to PE 2. The SRv6 SID in the encapsulated SRH is compressed to 32 bits long. After configuring P 3, you can execute the display segment-routing ipv6 local-sid command to obtain information about dynamically allocated End.X(COC32) SIDs.

¡ The fourth hop is the End SID of PE 2. The SRv6 SID in the encapsulated SRH is compressed to 32 bits long. The next SID will not be compressed. After configuring PE 2, you can execute the display segment-routing ipv6 local-sid command to obtain information about dynamically allocated End(COCNONE) SIDs.

[PE1] segment-routing ipv6

[PE1-segment-routing-ipv6] traffic-engineering

[PE1-srv6-te] srv6-policy locator ax

[PE1-srv6-te] segment-list b

[PE1-srv6-te-sl-b] index 10 coc32 ipv6 A:2:2:A:2:10A:: 64

[PE1-srv6-te-sl-b] index 20 coc32 ipv6 A:2:2:A:3:101:: 64

[PE1-srv6-te-sl-b] index 30 coc32 ipv6 A:2:2:A:4:104:: 64

[PE1-srv6-te-sl-b] index 40 ipv6 A:2:2:A:5:103::

[PE1-srv6-te-sl-b] quit

[PE1-srv6-te] policy a

[PE1-srv6-te-policy-a] color 10 end-point ipv6 5::5

[PE1-srv6-te-policy-a] sbfd enable remote 1000001

[PE1-srv6-te-policy-a] candidate-paths

[PE1-srv6-te-policy-a-path] preference 200

[PE1-srv6-te-policy-a-path-pref-200] explicit segment-list b

[PE1-srv6-te-policy-a-path-pref-200] quit

[PE1-srv6-te-policy-a-path] quit

[PE1-srv6-te-policy-a] quit

[PE1-srv6-te] quit

[PE1-segment-routing-ipv6] quit

# Create EBGP peers between the PE and CE, and import VPN routes.

[PE1] bgp 100

[PE1-bgp-default] router-id 1.1.1.1

[PE1-bgp-default] ip vpn-instance aaa

[PE1-bgp-default-aaa] peer 10.1.1.1 as-number 10

[PE1-bgp-default-aaa] address-family ipv4 unicast

[PE1-bgp-default-ipv4-aaa] peer 10.1.1.1 enable

[PE1-bgp-default-ipv4-aaa] quit

[PE1-bgp-default-aaa] quit

# Create MP-IBGP peers between PE 1 and PE 2.

[PE1-bgp-default] peer 5::5 as-number 100

[PE1-bgp-default] peer 5::5 connect-interface loopback 0

[PE1-bgp-default] address-family l2vpn evpn

[PE1-bgp-default-evpn] peer 5::5 enable

[PE1-bgp-default-evpn] quit

[PE1-bgp-default] quit

# Enable exchange of SRv6-encapsulated EVPN routes between MP-IBGP peers on PE 1, and enable recursion of VPN routes to the SRv6 TE policy tunnel.

[PE1] bgp 100

[PE1-bgp-default] address-family l2vpn evpn

[PE1-bgp-default-evpn] peer 5::5 advertise encap-type srv6

[PE1-bgp-default-evpn] quit

[PE1-bgp-default] ip vpn-instance aaa

[PE1-bgp-default-aaa] address-family ipv4 unicast

[PE1-bgp-default-ipv4-aaa] segment-routing ipv6 locator ax evpn

[PE1-bgp-default-ipv4-aaa] segment-routing ipv6 traffic-engineering evpn

[PE1-bgp-default-ipv4-aaa] quit

[PE1-bgp-default-aaa] quit

[PE1-bgp-default] quit

[PE1] route-policy a permit node 10

[PE1-route-policy-a-10] apply extcommunity color 00:10

[PE1-route-policy-a-10] quit

[PE1] bgp 100

[PE1-bgp-default] address-family l2vpn evpn

[PE1-bgp-default-evpn] peer 5::5 route-policy a import

[PE1-bgp-default-evpn] quit

[PE1-bgp-default] quit

[PE1] tunnel-policy a

[PE1-tunnel-policy-a] select-seq srv6-policy load-balance-number 1

[PE1-tunnel-policy-a] quit

[PE1] ip vpn-instance vpn1

[PE1-vpn-instance-vpn1] tnl-policy a

[PE1-vpn-instance-vpn1] quit

4. Configure P 1:

# Configure IP addresses for the interfaces.

[P1] interface loopback 0

[P1-LoopBack0] ipv6 address 2::2 128

[P1-LoopBack0] quit

[P1] interface ten-gigabitethernet 3/1/1

[P1-Ten-GigabitEthernet3/1/1] ipv6 address 23:1:1::1 126

[P1-Ten-GigabitEthernet3/1/1] quit

[P1] interface ten-gigabitethernet 3/1/2

[P1-Ten-GigabitEthernet3/1/2] ipv6 address 12:1:1::2 126

[P1-Ten-GigabitEthernet3/1/2] quit

# Configure IPv6 IS-IS to implement backbone network intercommunication.

[P1] isis 1

[P1-isis-1] is-level level-2

[P1-isis-1] cost-style wide

[P1-isis-1] network-entity 00.0000.0000.0002.00

[P1-isis-1] address-family ipv6 unicast

[P1-isis-1-ipv6] quit

[P1-isis-1] quit

[P1] interface ten-gigabitethernet 3/1/1

[P1-Ten-GigabitEthernet3/1/1] isis ipv6 enable 1

[P1-Ten-GigabitEthernet3/1/1] quit

[P1] interface ten-gigabitethernet 3/1/2

[P1-Ten-GigabitEthernet3/1/2] isis ipv6 enable 1

[P1-Ten-GigabitEthernet3/1/2] quit

[P1] interface loopback 0

[P1-LoopBack0] isis ipv6 enable 1

[P1-LoopBack0] quit

# Configure an SRv6 locator on P 1 to be advertised by IGP, and enable SRv6 compression.

[P1] segment-routing-ipv6

[P1-segment-routing-ipv6] srv6 compress enable

[P1-segment-routing-ipv6] locator bx ipv6-prefix A:2:2:A:2:: 80 common-prefix 64 coc-both non-compress-static 8 static 8 args 16

[P1-segment-routing-ipv6-locator-bx] quit

[P1-segment-routing-ipv6] quit

[P1] isis 1

[P1-isis-1] address-family ipv6 unicast

[P1-isis-1-ipv6] segment-routing ipv6 locator bx auto-sid-coc-both coc32-all

[P1-isis-1-ipv6] srv6 compress enable

[P1-isis-1-ipv6] quit

[P1-isis-1] quit

5. Configure P 2:

# Configure IP addresses for the interfaces.

[P2] interface loopback 0

[P2-LoopBack0] ipv6 address 3::3 128

[P2-LoopBack0] quit

[P2] interface ten-gigabitethernet 3/1/1

[P2-Ten-GigabitEthernet3/1/1] ipv6 address 23:1:1::2 126

[P2-Ten-GigabitEthernet3/1/1] quit

[P2] interface ten-gigabitethernet 3/1/2

[P2-Ten-GigabitEthernet3/1/2] ipv6 address 34:1:1::1 126

[P2-Ten-GigabitEthernet3/1/2] quit

# Configure IPv6 IS-IS to implement backbone network intercommunication.

[P2] isis 1

[P2-isis-1] is-level level-2

[P2-isis-1] cost-style wide

[P2-isis-1] network-entity 00.0000.0000.0003.00

[P2-isis-1] address-family ipv6 unicast

[P2-isis-1-ipv6] quit

[P2-isis-1] quit

[P2] interface ten-gigabitethernet 3/1/1

[P2-Ten-GigabitEthernet3/1/1] isis ipv6 enable 1

[P2-Ten-GigabitEthernet3/1/1] quit

[P2] interface ten-gigabitethernet 3/1/2

[P2-Ten-GigabitEthernet3/1/2] isis ipv6 enable 1

[P2-Ten-GigabitEthernet3/1/2] quit

[P2] interface loopback 0

[P2-LoopBack0] isis ipv6 enable 1

[P2-LoopBack0] quit

# Configure an SRv6 locator on P 2 to be advertised by IGP, and enable SRv6 compression.

[P2] segment-routing-ipv6

[P2-segment-routing-ipv6] srv6 compress enable

[P2-segment-routing-ipv6] locator cx ipv6-prefix A:2:2:A:3:: 80 common-prefix 64 coc-both non-compress-static 8 static 8 args 16

[P2-segment-routing-ipv6-locator-cx] quit

[P2-segment-routing-ipv6] quit

[P2] isis 1

[P2-isis-1] address-family ipv6 unicast

[P2-isis-1-ipv6] segment-routing ipv6 locator cx auto-sid-coc-both all

[P2-isis-1-ipv6] srv6 compress enable

[P2-isis-1-ipv6] quit

[P2-isis-1] quit

6. Configure P 3:

# Configure IP addresses for the interfaces.

[P3] interface loopback 0

[P3-LoopBack0] ipv6 address 4::4 128

[P3-LoopBack0] quit

[P3] interface ten-gigabitethernet 3/1/1

[P3-Ten-GigabitEthernet3/1/1] ipv6 address 45:1:1::1 126

[P3-Ten-GigabitEthernet3/1/1] quit

[P3] interface ten-gigabitethernet 3/1/2

[P3-Ten-GigabitEthernet3/1/2] ipv6 address 34:1:1::2 126

[P3-Ten-GigabitEthernet3/1/2] quit

# Configure IPv6 IS-IS to implement backbone network intercommunication.

[P3] isis 1

[P3-isis-1] is-level level-2

[P3-isis-1] cost-style wide

[P3-isis-1] network-entity 00.0000.0000.0004.00

[P3-isis-1] address-family ipv6 unicast

[P3-isis-1-ipv6] quit

[P3-isis-1] quit

[P3] interface ten-gigabitethernet 3/1/1

[P3-Ten-GigabitEthernet3/1/1] isis ipv6 enable 1

[P3-Ten-GigabitEthernet3/1/1] quit

[P3] interface ten-gigabitethernet 3/1/2

[P3-Ten-GigabitEthernet3/1/2] isis ipv6 enable 1

[P3-Ten-GigabitEthernet3/1/2] quit

[P3] interface loopback 0

[P3-LoopBack0] isis ipv6 enable 1

[P3-LoopBack0] quit

# Configure an SRv6 locator on P 3 to be advertised by IGP, and enable SRv6 compression.

[P3] segment-routing-ipv6

[P3-segment-routing-ipv6] srv6 compress enable

[P3-segment-routing-ipv6] locator dx ipv6-prefix A:2:2:A:4:: 80 common-prefix 64 coc-both non-compress-static 8 static 8 args 16

[P3-segment-routing-ipv6-locator-dx] quit

[P3-segment-routing-ipv6] quit

[P3] isis 1

[P3-isis-1] address-family ipv6 unicast

[P3-isis-1-ipv6] segment-routing ipv6 locator dx auto-sid-coc-both coc32

[P3-isis-1-ipv6] srv6 compress enable

[P3-isis-1-ipv6] quit

[P3-isis-1] quit

7. Configure PE 2:

# Configure the VPN instance on PE 2 to connect the CE to PE.

<PE2> system-view

[PE2] sysname PE2

[PE2] ip vpn-instance aaa

[PE2-vpn-instance-aaa] route-distinguisher 100:1

[PE2-vpn-instance-aaa] vpn-target 200:1 both

[PE2-vpn-instance-aaa] quit

# Configure IP addresses for the interfaces.

[PE2] interface loopback 0

[PE2-LoopBack0] ipv6 address 5::5 128

[PE2-LoopBack0] quit

[PE2] interface ten-gigabitethernet 3/1/2

[PE2-Ten-GigabitEthernet3/1/2] ip binding vpn-instance aaa

[PE2-Ten-GigabitEthernet3/1/2] ip address 20.1.1.2 30

[PE2-Ten-GigabitEthernet3/1/2] quit

[PE2] interface ten-gigabitethernet 3/1/1

[PE2-Ten-GigabitEthernet3/1/1] ipv6 address 45:1:1::2 126

[PE2-Ten-GigabitEthernet3/1/1] quit

# Configure IPv6 IS-IS to implement backbone network intercommunication.

[PE2] isis 1

[PE2-isis-1] is-level level-2

[PE2-isis-1] cost-style wide

[PE2-isis-1] network-entity 00.0000.0000.0005.00

[PE2-isis-1] address-family ipv6 unicast

[PE2-isis-1-ipv6] quit

[PE2-isis-1] quit

[PE2] interface ten-gigabitethernet 3/1/1

[PE2-Ten-GigabitEthernet3/1/1] isis ipv6 enable 1

[PE2-Ten-GigabitEthernet3/1/1] quit

[PE2] interface loopback 0

[PE2-LoopBack0] isis ipv6 enable 1

[PE2-LoopBack0] quit

# Configure an SRv6 locator on the PE to be advertised by IGP, and enable SRv6 compression.

[PE2] segment-routing-ipv6

[PE2-segment-routing-ipv6] srv6 compress enable

[PE2-segment-routing-ipv6] locator ex ipv6-prefix A:2:2:A:5:: 80 common-prefix 64 coc-both non-compress-static 8 static 8 args 16

[PE2-segment-routing-ipv6-locator-e] quit

[PE2-segment-routing-ipv6] quit

[PE2] isis 1

[PE2-isis-1] address-family ipv6 unicast

[PE2-isis-1-ipv6] segment-routing ipv6 locator ex auto-sid-coc-both all

[PE2-isis-1-ipv6] srv6 compress enable

[PE2-isis-1-ipv6] quit

[PE2-isis-1] quit

# Specify a source address for the outer IPv6 header of SRv6-encapsulated IPv4 EVPN L3VPN packets on the PE.

[PE2] segment-routing ipv6

[PE2-segment-routing-ipv6] encapsulation source-address 5::5

# Create EBGP peers between the PE and CE, and import VPN routes.

[PE2] bgp 100

[PE2-bgp-default] router-id 5.5.5.5

[PE2-bgp-default] ip vpn-instance aaa

[PE2-bgp-default-aaa] peer 20.1.1.1 as-number 20

[PE2-bgp-default-aaa] address-family ipv4 unicast

[PE2-bgp-default-ipv4-aaa] peer 20.1.1.1 enable

[PE2-bgp-default-ipv4-aaa] quit

[PE2-bgp-default-aaa] quit

# Create MP-IBGP peers between PE 1 and PE 2.

[PE2-bgp-default] peer 1::1 as-number 100

[PE2-bgp-default] peer 1::1 connect-interface loopback 0

[PE2-bgp-default] address-family l2vpn evpn

[PE2-bgp-default-evpn] peer 1::1 enable

[PE2-bgp-default-evpn] quit

[PE2-bgp-default] quit

# Enable exchange of SRv6-encapsulated EVPN routes between MP-IBGP peers on PE 2, and enable recursion of VPN routes to the SRv6 BE tunnel.

[PE2] bgp 100

[PE2-bgp-default] address-family l2vpn evpn

[PE2-bgp-default-evpn] peer 1::1 advertise encap-type srv6

[PE2-bgp-default-evpn] quit

[PE2-bgp-default] ip vpn-instance aaa

[PE2-bgp-default-aaa] address-family ipv4 unicast

[PE2-bgp-default-ipv4-aaa] segment-routing ipv6 locator ex evpn

[PE2-bgp-default-ipv4-aaa] segment-routing ipv6 best-effort evpn

[PE2-bgp-default-ipv4-aaa] quit

[PE2-bgp-default-aaa] quit

[PE2-bgp-default] quit

# Specify the local discriminator for the SBFD session on PE 2, and make sure it is the same as the remote discriminator on PE 1.

[PE2] sbfd local-discriminator 1000001

Verifying the configuration

[PE1] display segment-routing ipv6 te policy

Name/ID: a/0

Color: 10

End-point: 5::5

Name from BGP:

Name from PCE:

BSID:

Mode: Dynamic Type: Type_2 Request state: Succeeded

Current BSID: A:2:2:A:1:0:101:0 Explicit BSID: - Dynamic BSID: A:2:2:A:1:0:101:0

Reference counts: 5

Flags: A/BS/NC

Status: Up

AdminStatus: Up

Up time: 2023-08-06 16:31:34

Down time: 2023-08-06 16:29:20

Hot backup: Disabled

Statistics: Disabled

Statistics by service class: Disabled

Path verification: Not configured

Drop-upon-invalid: Disabled

BFD trigger path-down: Disabled

SBFD: Enabled

Encapsulation mode: -

Remote: 1000001

SBFD template name: -

SBFD backup template name: -

OAM SID: -

Reverse path type: None

BFD Echo: Disabled

BFD no-bypass: Disabled

Forward no-bypass: Disabled

Forwarding index: 2150629378

Association ID: 0

Service-class: -

Rate-limit: -

PCE delegation: Disabled

PCE delegate report-only: Disabled

Reoptimization: Disabled

Encapsulation mode: -

Flapping suppression Remaining interval: -

Candidate paths state: Configured

Candidate paths statistics:

CLI paths: 1 BGP paths: 0 PCEP paths: 0 ODN paths: 0

Candidate paths:

Preference : 100

Network slice ID: -

CPathName:

CPathPolicyName:

ProtoOrigin: CLI Discriminator: 100

Instance ID: 0 Node address: 0.0.0.0

Originator: 0, ::

Optimal: Y Flags: V/A

Dynamic: Not configured

PCEP: Not configured

Explicit SID list:

ID: 2 Name: b

Weight: 1 Forwarding index: 2149580805

State: Up State(SBFD): Up

Verification State: -

Path MTU: 1500 Path MTU Reserved: 0

SID list flags: None

Local BSID: -

Reverse BSID: -

# On PE 1, execute the display bgp l2vpn evpn command to display detailed information about the route sent by PE 2. Verify that the route sent by PE 2 carries the PrefixSID attribute data.

[PE1] display bgp l2vpn evpn [5][0][32][22.22.22.22] 80

BGP local router ID: 1.1.1.1

Local AS number: 100

Route distinguisher: 100:1(aaa)

Total number of routes: 1

Paths: 1 available, 1 best

BGP routing table information of [5][0][32][22.22.22.22]/80:

From : 5::5 (5.5.5.5)

Rely nexthop : FE80::1AF8:23FF:FE50:207

Original nexthop: 5::5

Out interface : Ten-GigabitEthernet3/1/2

Route age : 00h00m39s

OutLabel : 3

Ext-Community : <RT: 200:1>, <CO-Flag:Color(00:10)>

RxPathID : 0x0

TxPathID : 0x0

PrefixSID : End.DT4 SID <<A:2:2:A:5:0:107:0>

SRv6 Service TLV (37 bytes):

Type: SRV6 L3 Service TLV (5)

Length: 34 bytes, Reserved: 0x0

SRv6 Service Information Sub-TLV (33 bytes):

Type: 1 Length: 30, Rsvdl: 0x0

SID Flags: 0x0 Endpoint behavior: 0x13 Rsvd2: 0x0

SRv6 SID Sub-Sub-TLV:

Type: 1 Len: 6

BL: 64 NL: 16 FL: 16 AL: 16 TL: 0 TO: 0

AS-path : 20

Origin : incomplete

Attribute value : MED 0, localpref 100, pref-val 0

State : valid, internal, best

Source type : local

IP precedence : N/A

QoS local ID : N/A

Traffic index : N/A

EVPN route type : IP prefix advertisement route

ESI : 0000.0000.0000.0000.0000

Ethernet tag ID : 0

IP prefix : 22.22.22.22/32

Gateway address : 0.0.0.0

MPLS label : 3

Tunnel policy : NULL

Rely tunnel IDs : N/A

Re-orignination : Disable

# On PE 1, execute the display ip routing-table vpn-instance command. Verify that VPN route 22.22.22.22 is available to CE 2, and the output interface for the route is SRv6 TE policy tunnel a.

Take PE 1 as an example:

[PE1] display ip routing-table vpn-instance aaa

Destinations : 8 Routes : 8

Destination/Mask Proto Pre Cost NextHop Interface

10.1.1.0/30 Direct 0 0 10.1.1.2 XGE3/1/1

10.1.1.2/32 Direct 0 0 127.0.0.1 XGE3/1/1

10.1.1.3/32 Direct 0 0 10.1.1.2 XGE3/1/1

11.11.11.11/32 BGP 255 0 10.1.1.1 XGE3/1/1

20.1.1.0/30 BGP 255 0 5::5 a

22.22.22.22/32 BGP 255 0 5::5 a

127.0.0.0/8 Direct 0 0 127.0.0.1 InLoop0

255.255.255.255/32 Direct 0 0 127.0.0.1 InLoop0

11-Segment Routing Configuration Guide

About EVPN L3VPN over SRv6

SRv6 BE mode

SRv6 TE mode

SRv6 TE and SRv6 BE hybrid mode

SRv6 TE and SRv6 BE FRR mode

End.T SID

Route advertisement

Traffic forwarding

EVPN L3VPN over SRv6 tasks at a glance

About this task

Restrictions and guidelines

Prerequisites

Procedure

About this task

Restrictions and guidelines

Procedure

Restrictions and guidelines

Procedure

About this task

Restrictions and guidelines

Procedure

About this task

Procedure

Restrictions and guidelines

Procedure

About this task

Restrictions and guidelines

Procedure

About this task

Prerequisites

Reoriginating VPNv4/VPNv6 routes as EVPN IP prefix advertisement routes

Reoriginating EVPN IP prefix advertisement routes as VPNv4/VPNv6 routes

About this task

Restrictions and guidelines

Procedure

About this task

Restrictions and guidelines

Procedure

Display and maintenance commands for EVPN L3VPN over SRv6

Example: Configuring IPv4 EVPN L3VPN over SRv6 in SRv6 BE mode

Network configuration

Procedure

Verifying the configuration

Network configuration

Procedure

Verifying the configuration

Network configuration

Procedure

Verifying the configuration

Network configuration

Procedure

Verifying the configuration

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