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| Title | Size | Download |
|---|---|---|
| 05-MPLS L2VPN configuration | 553.93 KB |
Contents
Remote connection establishment
Local connection establishment
Configuring a remote connection
Configuring a local connection
Configuring a multi-segment PW
Configuring an Ethernet service instance on an interface
Configuring a remote CCC connection
Restrictions and guidelines for configuring PW redundancy
Configuring static PW redundancy
Performing a manual PW switchover
Enabling MPLS L2VPN statistics
Enabling packet statistics on an AC
Setting the L2VPN traffic statistics collection interval
Enabling SNMP notifications for L2VPN PW
Display and maintenance commands for MPLS L2VPN
MPLS L2VPN configuration examples
Example: Configuring local MPLS L2VPN connections
Example: Configuring a static PW
Example: Configuring an LDP PW
Example: Configuring a remote CCC connection
Example: Configuring LDP PW redundancy
Example: Configuring an intra-domain multi-segment PW
Example: Configuring an inter-domain multi-segment PW
Configuring MPLS L2VPN
MPLS L2VPN provides point-to-point and point-to-multipoint connections. This chapter describes only the MPLS L2VPN technologies that provide point-to-point connections. For information about the MPLS L2VPN technologies that provide point-to-multipoint connections, see "Configuring VPLS."
About MPLS L2VPN
MPLS L2VPN is an implementation of Pseudo Wire Emulation Edge-to-Edge (PWE3). It offers Layer 2 VPN services over an MPLS or IP backbone. MPLS L2VPN can transparently transmit Layer 2 data for different data link layer protocols such as Ethernet and ATM.
Basic concepts of MPLS L2VPN
CE
A customer edge (CE) is a customer device directly connected to the service provider network.
PE
A provider edge (PE) is a service provider device connected to one or more CEs. It provides VPN access by mapping and forwarding packets between user networks and public tunnels.
AC
An attachment circuit (AC) is a link between a CE and a PE, such as an FR DLCI, ATM VPI/VCI, Ethernet interface, VLAN, or PPP connection.
PW
A Pseudowire (PW) is a virtual bidirectional connection between two PEs. An MPLS PW comprises a pair of LSPs in opposite directions.
Public tunnel
A public tunnel is a connection that carries one or more PWs across the MPLS or IP backbone. It can be an LSP tunnel, a GRE tunnel, or an MPLS TE tunnel.
Cross-connect
A cross-connect connects two physical or virtual circuits such as ACs and PWs. It switches packets between the two physical or virtual circuits. Cross-connects include AC to AC cross-connect, AC to PW cross-connect, and PW to PW cross-connect.
Site ID
A site ID uniquely identifies a site in a VPN. Sites in different VPNs can have the same site ID.
RD
A route distinguisher (RD) is added before a site ID to distinguish the sites that have the same site ID but reside in different VPNs. An RD and a site ID uniquely identify a VPN site.
Label block
A label block is a set of labels. It includes the following parameters:
· Label base—The LB specifies the initial label value of the label block. A PE automatically selects an LB value that cannot be manually modified.
· Label range—The LR specifies the number of labels that the label block contains. The LB and LR determine the labels contained in the label block. For example, if the LB is 1000 and the LR is 5, the label block contains labels 1000 through 1004.
· Label-block offset—The LO specifies the offset of a label block. If the existing label block becomes insufficient as the VPN sites increase, you can add a new label block to enlarge the label range. A PE uses an LO to identify the position of the new label block. The LO value of a label block is the sum of the LRs of all previously assigned label blocks. For example, if the LR and LO of the first label block are 10 and 0, the LO of the second label block is 10. If the LR of the second label block is 20, the LO of the third label block is 30.
A label block with LB, LO, and LR as 1000, 10, and 5, respectively, is represented as 1000/10/5.
For example, a VPN has 10 sites, and a PE assigns the first label block LB1/0/10 to the VPN. When another 15 sites are added, the PE keeps the first label block and assigns the second label block LB2/10/15 to extend the network. LB1 and LB2 are the initial label values that are randomly selected by the PE.
Route target
PEs use the BGP route target attribute (also called VPN target attribute) to manage BGP L2VPN information advertisement. PEs support the following types of route target attributes:
· Export target attribute—When a PE sends L2VPN information to the peer PE in a BGP update message, it sets the route target attribute in the update message to an export target. L2VPN information includes the site ID, RD, and label block.
· Import target attribute—When a PE receives an update message from the peer PE, it checks the route target attribute in the update message. If the route target value matches an import target, the PE accepts the L2VPN information in the update message.
Route target attributes determine from which PEs a PE can receive L2VPN information.
MPLS L2VPN network models
MPLS L2VPN network models include the remote connection and local connection models.
As shown in Figure 1, the remote connection model connects two CEs through a PW on an MPLS or IP backbone.
Figure 1 Remote connection model
As shown in Figure 2, the local connection model connects two CEs to the same PE so the CEs can communicate through the PE.
Figure 2 Local connection model
Remote connection establishment
To set up a remote MPLS L2VPN connection:
1. Set up a public tunnel to carry one or more PWs between PEs.
2. Set up a PW to connect customer networks.
3. Set up an AC between a PE and a CE.
4. Bind the AC to the PW.
After the PE receives packets from the AC, it adds the PW label into the packets and sends the packets to the peer PE through the public tunnel.
After the peer PE receives the packets from the public tunnel, it removes the PW label of the packets and forwards the packets to the AC bound to the PW.
Setting up a public tunnel
The public tunnel can be an LSP, MPLS TE, or GRE tunnel.
If multiple public tunnels exist between two PEs, you can configure a tunnel policy to control tunnel selection. For more information about tunnel policies, see "Configuring tunnel policies."
If a PW is established over an LSP or MPLS TE tunnel, packets on the PW have two labels. The outer label is the public LSP or MPLS TE tunnel label that MPLS uses to forward the packet to the peer PE. The inner label is the PW label that the peer PE uses to forward the packet to the destination CE.
Setting up a PW
PWs include static PWs, LDP PWs, BGP PWs, and Circuit Cross Connect (CCC) PWs.
· Static PW establishment
To establish a static PW, configure the peer PE address, and the incoming and outgoing PW labels for the PW on the two PEs. Static PWs consume a small amount of resources but have complex configurations.
· LDP PW establishment
To establish an LDP PW, configure LDP and specify the peer PE address on the two PEs. LDP defines a new FEC type named PW ID FEC for PEs to exchange PW-label bindings. The new FEC type uses a PW ID and a PW data encapsulation type to identify a PW. The PW ID is the ID of the PW between PEs. The PW data encapsulation type specifies the encapsulation type for data transmitted over the PW, such as ATM, FR, Ethernet, or VLAN. PEs advertise the PW label and PW ID FEC in label mapping messages to create a PW. Dynamic PWs have simple configurations but consume more resources than static PWs.
· BGP PW establishment
To establish BGP PWs, BGP advertises label block information in an extended BGP update to PEs in the same VPN. Each PE uses the received label block information to calculate outgoing labels and uses its own label block to calculate incoming labels. After two PEs complete label calculation, a BGP PW is established between them.
BGP PWs have the following features:
Simplified configuration—There is no need to manually specify peer PEs. A PE automatically find peer PEs after receiving label block information from the peer PEs.
Reduced workload—Label block advertisement enables assigning labels for multiple PWs at one time.
· CCC PW establishment
To establish a CCC PW, manually specify the incoming and outgoing labels for the PW on the PEs, and create two static LSPs in opposite directions on P devices between PEs. There is no need to configure a public tunnel for the CCC PW. CCC employs only one level of label to transfer packets. The static LSPs on the P devices transfer data only for the CCC PW. They cannot be used by other connections or MPLS L3VPN.
Setting up an AC
Set up an AC by configuring a link layer connection (such as a PPP connection) between a PE and a CE.
On a PE, an AC can be an Ethernet service instance on a Layer 2 Ethernet interface or Layer 2 aggregate interface. An AC forwards packets that are received on the interface and meet the match criteria of the Ethernet service instance to the bound PW. If the match criterion is VLAN ID, the VLAN is unique on a per interface basis rather than on a global basis.
|
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NOTE: When VLANs are globally unique, packets with the same VLAN ID are forwarded over the PW bound with that VLAN ID regardless of the receiving interfaces. If VLANs are unique on a per interface basis, packets with the same VLAN ID from different interfaces can be forwarded over different PWs. |
Binding the AC to the PW
Bind the AC (Ethernet service instance) to the PW, so the PE forwards packets between the AC and the PW.
Local connection establishment
To set up a local MPLS L2VPN connection between two CEs:
1. Set up ACs:
Configure the link layer protocol to set up an AC between the PE and each CE. For more information, see "Setting up an AC."
2. Bind the two ACs:
Bind the PE's Ethernet service instances (ACs) connected to the two CEs so the PE can forward packets between CEs.
PW data encapsulation types
MPLS L2VPN transports Layer 2 data of different data link layer protocols through PWs. A PE encapsulates a Layer 2 packet received from an AC according to the PW data encapsulation type.
Relationship between AC types and PW data encapsulation types
The PW data encapsulation type is determined by the link type of the AC, as shown in Table 1.
Table 1 Relationship between AC types and PW data encapsulation types
|
AC type |
PW data encapsulation type |
|
Ethernet |
Ethernet |
|
VLAN |
Ethernet over MPLS
Ethernet over MPLS uses MPLS L2VPN to connect Ethernets, and delivers Ethernet packets through a PW over the MPLS backbone.
The following PW data encapsulation types are available for Ethernet over MPLS:
· Ethernet—P-tag is not transferred on a PW. For a packet from a CE:
If the packet contains a P-tag, the PE removes the P-tag, and adds a PW label and an outer tag into the packet before forwarding it.
If the packet contains no P-tag, the PE directly adds a PW label and an outer tag into the packet before forwarding it.
· VLAN—Packets transmitted over a PW must carry a P-tag. For a packet from a CE:
If the peer PE does not require the ingress to rewrite the P-tag, the PE keeps the P-tag unchanged for the packet, and then encapsulates the packet. If the packet contains no P-tag, the PE adds a null label (the label value is 0) into the packet, and then encapsulates the packet.
If the peer PE requires the ingress to rewrite the P-tag, the PE changes the P-tag to the expected VLAN tag (the tag value might be 0), and then adds a PW label and an outer tag into the packet. If the packet contains no P-tag, the PE adds a VLAN tag expected by the peer PE (the tag value might be 0), and then adds a PW label and an outer tag into the packet.
Ethernet over MPLS supports the flexible mode. In flexbile mode, an Ethernet service instance on a Layer 2 Ethernet interface or Layer 2 aggregate interface is bound to a PW. Packets that are received from the interface and meet the match criteria of the Ethernet service instance are forwarded through the bound PW. You can configure flexible match criteria for the Ethernet service instance. For example, configure the Ethernet service instance to match all packets, tagged packets, or untagged packets. The default PW data encapsulation type for flexible mode is VLAN.
Control word
The control word field is between the MPLS label stack and the Layer 2 data. It carries control information for the Layer 2 frame, for example, the sequence number.
The control word feature has the following functions:
· Avoids fragment disorder. In multipath forwarding, fragments received might be disordered. The control word feature reorders the fragments according to the sequence number carried in the control word field.
· Transfers specific Layer 2 frame flags, such as the FECN bit and BECN bit of Frame Relay.
· Identifies the original payload length for packets that include padding.
When the PW data encapsulation type is FR DLCI or ATM AAL5 SDU VCC, packets on the PW always carry the control word field, and the control word feature cannot be disabled.
When the PW data encapsulation type is Ethernet or VLAN, the control word field is optional. You can configure whether to carry the control word field in packets sent on the PW. If you enable the control word feature on both PEs, packets transmitted on the PW carry the control word field. Otherwise, the packets do not carry the control word field.
PW redundancy
PW redundancy provides redundant links between PEs so that the customer networks can communicate when the path over one PW fails. As shown in Figure 3, PE 1 establishes two PWs (one primary and one backup). The CEs communicate through the primary PW. When the primary PW fails, PE 1 brings up the backup PW and forwards packets from CE 1 to CE 2 through the backup PW. When CE 2 receives the packets, it updates its MAC address table, so that packets from CE 2 to CE 1 also travel through the backup PW. Only static PWs and LDP PWs support PW redundancy.
The MPLS L2VPN determines whether the primary PW fails according to the LDP session status or the BFD result. The backup PW is used when one of the following conditions exists:
· The public tunnel of the primary PW is deleted, or BFD detects that the public tunnel has failed.
· The primary PW is deleted because the LDP session between PEs goes down, or BFD detects that the primary PW has failed.
· A manual PW switchover is performed.
A PW can be in either of the following states:
· Active—The PW is in active state and can forward packets.
· Standby—The PW is in standby state and cannot forward packets.
LDP PWs support the independent and master/slave PW redundancy operation modes.
· Independent mode—The two PEs of a PW use LDP to advertise their respective PW active/standby state to each other. A PW can forward traffic only when it is up and active at both ends of the PW. In this mode, make sure both PEs of a PW use the independent PW redundancy operation mode.
· Master/slave mode—One PE of a PW operates as the master node and the other PE operates as the slave node. The master PE determines the PW active/standby state and then uses LDP to advertise the PW state to the slave PE. The slave PE uses the same PW state as the master PE based on the information received from the master PE. In this way, the master and slave PEs for the set of redundant PWs can use the same active PW to forward user packets.
A slave node does not advertise the PW active/standby state to the master node, and the master node ignores the PW active/standby state received from the slave nodes.
Multi-segment PW
Working mechanism
A multi-segment PW includes multiple concatenated static or LDP PWs. Creating two PWs for a cross-connect on a PE can concatenate the two PWs. Upon receiving a packet from one PW, the PE removes the tunnel ID and PW label of the packet, adds the PW label of the other PW, and forwards the packet over the public tunnel. Only static and LDP PWs can form a multi-segment PW.
As shown in Figure 4, to create a multi-segment PW between PE 1 and PE 4, you can concatenate PW 1 and PW 2 on PE 2, and PW 2 and PW 3 on PE 3.
Multi-segment PWs include intra-domain multi-segment PWs and inter-domain multi-segment PWs.
Intra-domain multi-segment PW
An intra-domain multi-segment PW has concatenated PWs within an AS. You can create an intra-domain multi-segment PW between two PEs that have no public tunnel to each other.
As shown in Figure 5, there is no public tunnel between PE 1 and PE 4. There is a public tunnel between PE 1 and PE 2 and a public tunnel between PE 2 and PE 4. To create an intra-domain multi-segment PW between PE 1 and PE 4, you can perform the following operations:
1. Create a PW between PE 1 and PE 2 (PW 1) and a PW between PE 2 and PE 4 (PW 2).
2. Concatenate the two PWs on PE 2.
Intra-domain multi-segment PWs can fully use existing public tunnels to reduce end-to-end public tunnels.
Figure 5 Intra-domain multi-segment PW
Inter-domain multi-segment PW
An inter-domain multi-segment PW has concatenated PWs in different ASs, and is a method for inter-AS option B networking.
As shown in Figure 6, to create an inter-domain multi-segment PW between PE 1 and PE 2 in different ASs, you can perform the following operations:
· Concatenate PW 1 and PW 2 on ASBR 1.
· Concatenate PW 2 and PW 3 on ASBR 2.
Figure 6 Inter-domain multi-segment PW
VCCV
Virtual Circuit Connectivity Verification (VCCV) is an OAM feature for L2VPN. It verifies the connectivity of PWs on the data plane. VCCV includes the following modes:
· Manual mode—Use the ping mpls pw command to manually test the connectivity of a PW.
· Auto mode—Configure BFD or Raw BFD to automatically test the connectivity of a PW.
For more information about VCCV, see "Configuring MPLS OAM."
MPLS L2VPN tasks at a glance
Configuring a remote connection
2. Configuring an AC
Configuring an Ethernet service instance on an interface
3. Configuring a cross-connect
Configure a static PW, LDP PW, BGP PW, and remote CCC connection as needed.
¡ (Optional.) Configuring a PW class
¡ Configuring a remote CCC connection
5. (Optional.) Configuring PW redundancy
6. (Optional.) Maintaining an MPLS L2VPN network
¡ Enabling MPLS L2VPN statistics
¡ Enabling SNMP notifications for L2VPN PW
Configuring a local connection
2. Configuring an AC
To create a local connection, you must configure two ACs.
Configuring an Ethernet service instance on an interface
3. Configuring a cross-connect
4. Enabling packet statistics on an AC
Configuring a multi-segment PW
2. Configuring a cross-connect
Configure two static or LDP PWs for a cross-connect to concatenate the two PWs.
¡ (Optional.) Configuring a PW class
4. (Optional.) Enabling SNMP notifications for L2VPN PW
Prerequisites for MPLS L2VPN
To establish an MPLS L2VPN, you must perform the following tasks:
1. Configure an IGP to achieve IP connectivity within the backbone.
2. Configure basic MPLS, LDP, GRE, or MPLS TE to set up public tunnels across the backbone.
Enabling L2VPN
Prerequisites
Before you enable L2VPN, perform the following tasks:
· Configure an LSR ID for the PE with the mpls lsr-id command.
· Enable MPLS with the mpls enable command on the core-facing interface of the PE.
For more information about the mpls lsr-id and mpls enable commands, see MPLS Command Reference.
Procedure
1. Enter system view.
system-view
2. Enable L2VPN.
l2vpn enable
By default, L2VPN is disabled.
Configuring an Ethernet service instance on an interface
About this task
When the PE is connected to a CE through a Layer 2 Ethernet interface or Layer 2 aggregate interface, you can configure an Ethernet service instance on the interface to match packets for the AC.
Restrictions and guidelines
For information about configuring the match criterion of an Ethernet service instance by using the encapsulation command, see MPLS L2VPN commands in MPLS Command Reference.
Procedure
1. Enter system view.
system-view
2. Enter interface view.
¡ Enter Layer 2 Ethernet interface view.
interface interface-type interface-number
¡ Enter Layer 2 aggregate interface view.
interface bridge-aggregation interface-number
3. Create an Ethernet service instance and enter Ethernet service instance view.
service-instance instance-id
4. Configure a packet match criterion for the Ethernet service instance.
¡ Match packets with the specified inner VLAN IDs.
encapsulation c-vid { vlan-id | vlan-id-list }
¡ Match packets with the specified outer VLAN IDs.
encapsulation s-vid { vlan-id | vlan-id-list } [ only-tagged ]
¡ Match packets with the specified outer VLAN IDs and the specified inner VLAN IDs.
encapsulation s-vid vlan-id c-vid { vlan-id-list | all }
¡ Match packets that have a VLAN tag or packets that do not have a VLAN tag.
encapsulation { tagged | untagged }
¡ Match packets that do not match any other Ethernet service instances on the interface.
encapsulation default
On an interface, you can configure the default criterion in only one Ethernet service instance. The Ethernet service instance matches all packets if it is the only instance on the interface.
By default, no packet match criterion is configured.
Configuring a cross-connect
1. Enter system view.
system-view
2. Create a cross-connect group and enter cross-connect group view.
xconnect-group group-name
3. (Optional.) Configure a description for the cross-connect group.
description text
By default, no description is configured for a cross-connect group.
4. (Optional.) Enable the cross-connect group.
undo shutdown
By default, the cross-connect group is enabled.
5. Create a cross-connect and enter cross-connect view.
connection connection-name
6. (Optional.) Set an MTU for the PW.
mtu size
The default MTU is 1500 bytes.
The two PEs on an LDP PW must have the same MTU configured for the PW. Otherwise, the PW cannot come up.
Configuring a PW
Configuring a PW class
About this task
You can configure PW attributes such as the PW data encapsulation type and enable control word in a PW class. PWs with the same attributes can use the same PW class.
Procedure
1. Enter system view.
system-view
2. Create a PW class and enter PW class view.
pw-class class-name
By default, no PW classes exist.
3. Enable control word.
control-word enable
By default, control word is disabled.
4. Specify the PW data encapsulation type.
pw-type { ethernet | vlan }
By default, the PW data encapsulation type is VLAN.
Configuring a static PW
1. Enter system view.
system-view
2. Enter cross-connect group view.
xconnect-group group-name
3. Enter cross-connect view.
connection connection-name
4. Configure a static PW, and enter cross-connect PW view.
peer ip-address pw-id pw-id in-label label-value out-label label-value [ pw-class class-name | tunnel-policy tunnel-policy-name ] *
Configuring an LDP PW
About this task
After an LDP PW is created, the PE automatically sends a targeted hello to create an LDP session to the peer PE. Then, the PE exchanges the PW ID FEC and PW label mapping with the peer.
Prerequisites
Before you configure an LDP PW, enable global and interface MPLS LDP on the PE. For information about MPLS LDP configuration, see "Configuring LDP."
Procedure
1. Enter system view.
system-view
2. Enter cross-connect group view.
xconnect-group group-name
3. Enter cross-connect view.
connection connection-name
4. Configure an LDP PW, and enter cross-connect PW view.
peer ip-address pw-id pw-id [ pw-class class-name | tunnel-policy tunnel-policy-name ] *
Configuring a BGP PW
Configuring BGP to advertise MPLS L2VPN label block information
1. Enter system view.
system-view
2. Enable BGP instance and enter BGP instance view.
bgp as-number [ instance instance-name ]
By default, BGP is disabled.
3. Configure the remote PE as a BGP peer.
peer { group-name | ip-address [ mask-length ] } as-number as-number
For more information about this command, see Layer 3—IP Routing Command Reference.
4. Create the BGP L2VPN address family and enter BGP L2VPN address family view.
address-family l2vpn
5. Enable BGP to exchange BGP L2VPN information with the specified peer or peer group.
peer { group-name | ip-address [ mask-length ] } enable
By default, BGP cannot exchange BGP L2VPN information with any peer or peer group.
For more information about this command, see Layer 3—IP Routing Command Reference.
6. Enable BGP to exchange label block information with the specified peer or peer group.
peer { group-name | ip-address [ mask-length ] } signaling [ non-standard ]
By default, BGP can exchange label block information with a BGP L2VPN peer or peer group by using RFC 4761 MP_REACH_NLRI.
7. Configure the BGP L2VPN address family.
For more information, see "Configuring BGP L2VPN address family."
8. Reset BGP L2VPN sessions.
For more information, see "Resetting BGP sessions."
Creating a BGP PW
1. Enter system view.
system-view
2. Enter cross-connect group view.
xconnect-group group-name
3. Configure the cross-connect group to automatically discover neighbors and create PWs through BGP and enter auto-discovery cross-connect group view.
auto-discovery bgp
By default, a cross-connect group does not automatically discover neighbors or create PWs through BGP.
4. Configure an RD for the cross-connect group.
route-distinguisher route-distinguisher
By default, no RD is configured for the cross-connect group.
5. Configure route targets for the cross-connect group.
vpn-target vpn-target&<1-8> [ both | export-extcommunity | import-extcommunity ]
By default, no route targets are configured for the cross-connect group.
6. (Optional.) Specify a PW class for the auto-discovery cross-connect group.
pw-class class-name
By default, no PW class is specified.
7. (Optional.) Set an MTU for the PW.
mtu size
The default MTU is 1500 bytes.
8. Create a local site and enter site view.
site site-id [ range range-value ] [ default-offset default-offset ]
9. Create a cross-connect and enter auto-discovery cross-connect view.
connection remote-site-id remote-site-id
After you execute this command, a PW to the specified remote site is created and is bound to the cross-connect.
10. (Optional.) Specify a tunnel policy for the auto-discovery cross-connect.
tunnel-policy tunnel-policy-name
By default, no tunnel policy is specified.
Configuring BGP L2VPN address family
1. Enter system view.
system-view
2. Enter BGP instance view.
bgp as-number [ instance instance-name ]
3. Enter BGP L2VPN address family view.
address-family l2vpn
4. Permit the local AS number to appear in routes from the specified peer or peer group and specify the appearance times.
peer { group-name | ip-address [ mask-length ] } allow-as-loop [ number ]
By default, the local AS number is not allowed in routes from a peer or peer group.
For more information about this command, see Layer 3—IP Routing Command Reference.
5. Enable route target-based filtering of incoming BGP L2VPN information.
policy vpn-target
By default, route target-based filtering of incoming BGP L2VPN information is enabled.
6. Configure BGP route reflection:
a. Configure the router as a route reflector and specify a peer or peer group as its client.
peer { group-name | ip-address [ mask-length ] } reflect-client
By default, no route reflector or client is configured.
b. Enable L2VPN information reflection between clients.
reflect between-clients
By default, L2VPN information reflection between clients is enabled.
c. Configure the cluster ID of the route reflector.
reflector cluster-id { cluster-id | ip-address }
By default, a route reflector uses its own router ID as the cluster ID.
d. Configure a filtering policy for reflected L2VPN information.
rr-filter ext-comm-list-number
By default, the route reflector does not filter reflected L2VPN information.
For more information about the commands, see Layer 3—IP Routing Command Reference.
7. 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. For more information about this command, see BGP commands in Layer 3—IP Routing Command Reference.
Resetting BGP sessions of L2VPN address family
To reset BGP sessions of the L2VPN address family, execute one of the following command in user view:
· Perform manual soft-reset for BGP sessions of the L2VPN address family.
refresh bgp [ instance instance-name ] { ip-address [ mask-length ] | all | external | group group-name | internal } { export | import } l2vpn
· Reset BGP sessions of the L2VPN address family.
reset bgp [ instance instance-name ] { as-number | ip-address [ mask-length ] | all | external | group group-name | internal } l2vpn
For more information about the commands, see Layer 3—IP Routing Command Reference.
Configuring a remote CCC connection
Restrictions and guidelines
The outgoing label specified on a device must be the same as the incoming label specified on the next-hop device.
CCC connection settings such as the encapsulation type and control word feature must be consistent on the two PEs. Otherwise, the PEs might fail to forward packets over the CCC connection.
Procedure
1. Configure the PE devices of the CCC connection:
a. Enter system view.
system-view
b. Enter cross-connect group view.
xconnect-group group-name
c. Enter cross-connect view.
connection connection-name
d. Create a remote CCC connection.
ccc in-label in-label-value out-label out-label-value { nexthop nexthop | out-interface interface-type interface-number } [ pw-class class-name ]
Use the out-interface keyword to specify the outgoing interface only on a point-to-point link. On other types of interfaces such as Layer 3 Ethernet interfaces and VLAN interfaces, you must use the nexthop keyword to specify the IP address of the next hop.
2. Configure P devices of the CCC connection:
a. Enter system view.
system-view
b. Configure a static LSP for each direction of the CCC connection.
static-lsp transit lsp-name in-label in-label { nexthop next-hop-ip-address | outgoing-interface interface-type interface-number } out-label out-label
For more information about this command, see MPLS Command Reference.
Configuring PW redundancy
Restrictions and guidelines for configuring PW redundancy
PW redundancy is mutually exclusive from the multi-segment PW feature. If you have configured two PWs by using the peer command, you cannot configure a backup PW by using the backup-peer command for the PWs, and vice versa.
Configuring static PW redundancy
1. Enter system view.
system-view
2. Enter cross-connect group view.
xconnect-group group-name
3. Enter cross-connect view.
connection connection-name
4. (Optional.) Specify the switchover mode and set the wait time for the switchover.
revertive { wtr wtr-time | never }
By default, the switchover mode is revertive and the switchover wait time is 0 seconds.
5. Enter cross-connect PW view.
peer ip-address pw-id pw-id [ in-label label-value out-label label-value ] [ pw-class class-name | tunnel-policy tunnel-policy-name ] *
6. Configure a backup cross-connect PW and enter backup cross-connect PW view.
backup-peer ip-address pw-id pw-id in-label label-value out-label label-value [ pw-class class-name | tunnel-policy tunnel-policy-name ] *
Configuring LDP PW redundancy
1. Enter system view.
system-view
2. Enter cross-connect group view.
xconnect-group group-name
3. Enter cross-connect view.
connection connection-name
4. (Optional.) Specify a PW redundancy operation mode.
pw-redundancy { independent | master }
By default, the PW redundancy operation mode is master/slave and the local PE operates as the slave node.
Do not execute this command on the local PE if the remote PE does not support the PW redundancy operation mode configuration.
5. (Optional.) Specify the switchover mode and set the wait time for the switchover.
revertive { wtr wtr-time | never }
By default, the switchover mode is revertive and the switchover wait time is 0 seconds.
6. Enter cross-connect PW view.
peer ip-address pw-id pw-id [ ignore-standby-state | pw-class class-name | tunnel-policy tunnel-policy-name ] *
For the local PE to ignore the PW active/standby states received from the remote PE, specify the ignore-standby-state keyword.
7. Configure a backup LDP PW and enter backup cross-connect PW view.
backup-peer ip-address pw-id pw-id [ pw-class class-name | tunnel-policy tunnel-policy-name ] *
Performing a manual PW switchover
About this task
After you perform this task, if a PW has a backup PW or primary PW, this command switches traffic from the PW to the backup or primary PW. If the PW does not have a backup or primary PW, traffic switchover will not be performed.
Procedure
To manually switch the traffic of a PW to its backup PW, execute the following command in user view:
l2vpn switchover peer ip-address pw-id pw-id
Enabling MPLS L2VPN statistics
Enabling packet statistics on an AC
Restrictions and guidelines for enabling AC packet statistics
Follow these restrictions and guidelines when you configure this feature on an Ethernet service instance:
· You can display packet statistics of an Ethernet service instance only after packet statistics is enabled on the Ethernet service instance. To display packet statistics for the Ethernet service instance, use the display l2vpn service-instance verbose command. To clear packet statistics for the Ethernet service instance, use the reset l2vpn statistics ac command.
· This feature takes effect on the Ethernet service instance only when the instance has been configured with a packet match criterion and bound to a cross-connect. If you change the packet match criterion or the bound cross-connect during the statistics collection, the packet statistics are re-collected.
Enabling packet statistics for an Ethernet service instance
1. Enter system view.
system-view
2. Enter interface view.
¡ Enter Layer 2 Ethernet interface view.
interface interface-type interface-number
¡ Enter Layer 2 aggregate interface view.
interface bridge-aggregation interface-number
3. Enter Ethernet service instance view.
service-instance instance-id
4. Enable packet statistics for the Ethernet service instance.
statistics enable
By default, packet statistics is disabled for an Ethernet service instance.
Setting the L2VPN traffic statistics collection interval
About this task
Perform this task to set the L2VPN traffic statistics collection interval for both PWs and ACs.
Procedure
1. Enter system view.
system-view
2. Set the L2VPN traffic statistics collection interval.
l2vpn statistics interval interval
By default, the L2VPN traffic statistics collection interval is 15 minutes.
Enabling SNMP notifications for L2VPN PW
About this task
This feature enables L2VPN to generate SNMP notifications when PW deletions, PW switchovers, or PW status changes occur. For L2VPN event notifications to be sent correctly, you must also configure SNMP on the device. For more information about SNMP configuration, see the network management and monitoring configuration guide for the device.
Procedure
1. Enter system view.
system-view
2. Enable SNMP notifications for L2VPN PW.
snmp-agent trap enable l2vpn [ pw-delete | pw-switch | pw-up-down ] *
By default, SNMP notifications for L2VPN PW are disabled.
Display and maintenance commands for MPLS L2VPN
Execute display commands in any view and reset commands in user view.
|
Task |
Command |
|
Display BGP L2VPN peer group information. |
display bgp [ instance instance-name ] group l2vpn [ group-name group-name ] |
|
Display L2VPN label block information discovered by BGP. |
display bgp [ instance instance-name ] l2vpn signaling [ peer ip-address { advertised | received } [ statistics ] | route-distinguisher route-distinguisher [ site-id site-id [ label-offset label-offset [ advertise-info ] ] ] | statistics ] |
|
Display BGP L2VPN peer information. |
display bgp [ instance instance-name ] peer l2vpn [ ip-address mask-length | group-name group-name log-info | ip-address { log-info | verbose } | verbose ] |
|
Display BGP L2VPN update group information. |
display bgp [ instance instance-name ] update-group l2vpn [ ip-address ] |
|
Display L2VPN label block information. |
display l2vpn bgp [ peer ip-address | local ] [ xconnect-group group-name ] [ verbose ] |
|
Display cross-connect forwarding information. |
display l2vpn forwarding { ac | pw } [ xconnect-group group-name ] [ slot slot-number ] [ verbose ] |
|
Display LDP PW label information. |
display l2vpn ldp [ peer ip-address [ pw-id pw-id ] | xconnect-group group-name ] [ verbose ] |
|
Display L2VPN PW information. |
display l2vpn pw [ xconnect-group group-name ] [ protocol { bgp | ldp | static } ] [ verbose ] |
|
Display L2VPN PW state machine information. |
display l2vpn pw state-machine [ vsi vsi-name | xconnect-group group-name ] |
|
Display PW class information. |
display l2vpn pw-class [ class-name ] |
|
Display Ethernet service instance information. |
display l2vpn service-instance [ interface interface-type interface-number [ service-instance instance-id ] ] [ verbose ] |
|
Display cross-connect group information. |
display l2vpn xconnect-group [ name group-name ] [ verbose ] |
|
Reset BGP sessions for L2VPN. |
reset bgp [ instance instance-name ] { as-number | ip-address [ mask-length ] | all | external | group group-name | internal } l2vpn |
|
Clear packet statistics for ACs. |
reset l2vpn statistics ac [ interface interface-type interface-number [ service-instance instance-id ] ] |
For more information about the display bgp group l2vpn, display bgp peer l2vpn, display bgp update-group l2vpn, and reset bgp l2vpn commands, see Layer 3—IP Routing Command Reference.
MPLS L2VPN configuration examples
Example: Configuring local MPLS L2VPN connections
Network configuration
Configure local MPLS L2VPN connections between the PE and CEs to allow communication between CE 1 and CE 2, and between CE 1 and CE 3, without consuming VLAN resources on the PE.
Figure 7 Network diagram
Procedure
1. Configure CE 1:
# Configure Ten-GigabitEthernet 1/1/11 as a trunk port and permit VLAN 10 and VLAN 20.
<CE1> system-view
[CE1] interface ten-gigabitethernet 1/1/11
[CE1-Ten-GigabitEthernet1/1/11] port link-type trunk
[CE1-Ten-GigabitEthernet1/1/11] port trunk permit vlan 10 20
[CE1-Ten-GigabitEthernet1/1/11] quit
# Create VLAN 10 and configure an IP address for VLAN-interface 10.
[CE1] vlan 10
[CE1-vlan10] quit
[CE1] interface vlan-interface 10
[CE1-Vlan-interface10] ip address 10.1.1.1 24
[CE1-Vlan-interface10] quit
# Create VLAN 20 and configure an IP address for VLAN-interface 20.
[CE1] vlan 20
[CE1-vlan20] quit
[CE1] interface vlan-interface 20
[CE1-Vlan-interface20] ip address 10.2.1.1 24
[CE1-Vlan-interface20] quit
2. On CE 2, create VLAN 10 and configure an IP address for VLAN-interface 10.
<CE2> system-view
[CE2] vlan 10
[CE2-vlan10] port ten-gigabitethernet 1/1/11
[CE2-vlan10] quit
[CE2] interface vlan-interface 10
[CE2-Vlan-interface10] ip address 10.1.1.2 24
3. On CE 3, create VLAN 20 and configure an IP address for VLAN-interface 20.
<CE3> system-view
[CE3] vlan 20
[CE3-vlan20] port ten-gigabitethernet 1/1/11
[CE3-vlan20] quit
[CE3] interface vlan-interface 20
[CE3-Vlan-interface20] ip address 10.2.1.2 24
4. Configure the PE:
# Enable L2VPN.
<PE> system-view
[PE] l2vpn enable
# Create Ethernet service instance 10 on Ten-GigabitEthernet 1/1/11 to match packets from VLAN 10.
[PE] interface ten-gigabitethernet 1/1/11
[PE-Ten-GigabitEthernet1/1/11] service-instance 10
[PE-Ten-GigabitEthernet1/1/11-srv10] encapsulation s-vid 10
[PE-Ten-GigabitEthernet1/1/11-srv10] quit
# Create Ethernet service instance 20 on Ten-GigabitEthernet 1/1/11 to match packets from VLAN 20.
[PE-Ten-GigabitEthernet1/1/11] service-instance 20
[PE-Ten-GigabitEthernet1/1/11-srv20] encapsulation s-vid 20
[PE-Ten-GigabitEthernet1/1/11-srv20] quit
[PE-Ten-GigabitEthernet1/1/11] quit
Verifying the configuration
# Verify that four AC forwarding entries exist on the PE.
[PE] display l2vpn forwarding ac
Total number of cross-connections: 2
Total number of ACs: 4
AC Xconnect-group Name Link ID
XGE1/1/11 srv10 vpn1 0
XGE1/1/11 srv20 vpn1 0
XGE1/1/12 vpn1 1
XGE1/1/13 vpn1 1
Example: Configuring a static PW
Network configuration
Create a static PW between PE 1 and PE 2 over the backbone to allow communication between CE 1 and CE 2 within VLAN 10.
Create Ethernet service instance 10 on Ten-GigabitEthernet 1/1/11 to match packets with an outer VLAN ID of 10 on each PE.
Figure 8 Network diagram
Table 2 Interface and IP address assignment
|
Device |
Interface |
IP address |
Device |
Interface |
IP address |
|
CE 1 |
Vlan-int10 |
100.1.1.1/24 |
P |
Loop0 |
192.4.4.4/32 |
|
PE 1 |
Loop0 |
192.2.2.2/32 |
|
Vlan-int30 |
10.2.2.2/24 |
|
|
Vlan-int20 |
10.1.1.1/24 |
|
Vlan-int20 |
10.1.1.2/24 |
|
CE 2 |
Vlan-int10 |
100.1.1.2/24 |
PE 2 |
Loop0 |
192.3.3.3/32 |
|
|
|
|
|
Vlan-int30 |
10.2.2.1/24 |
Procedure
1. Configure VLANs and add ports to VLANs on each switch module. (Details not shown.)
2. Configure CE 1.
<CE1> system-view
[CE1] interface vlan-interface 10
[CE1-Vlan-interface10] ip address 100.1.1.1 24
[CE1-Vlan-interface10] quit
3. Configure PE 1:
# Configure an LSR ID.
<PE1> system-view
[PE1] interface loopback 0
[PE1-LoopBack0] ip address 192.2.2.2 32
[PE1-LoopBack0] quit
[PE1] mpls lsr-id 192.2.2.2
# Enable L2VPN.
[PE1] l2vpn enable
# Enable global LDP.
[PE1] mpls ldp
[PE1-ldp] quit
# Configure VLAN-interface 20 (the interface connected to the P device), and enable LDP on the interface.
[PE1] interface vlan-interface 20
[PE1-Vlan-interface20] ip address 10.1.1.1 24
[PE1-Vlan-interface20] mpls enable
[PE1-Vlan-interface20] mpls ldp enable
[PE1-Vlan-interface20] quit
# Configure OSPF for LDP to create LSPs.
[PE1] ospf
[PE1-ospf-1] area 0
[PE1-ospf-1-area-0.0.0.0] network 10.1.1.1 0.0.0.255
[PE1-ospf-1-area-0.0.0.0] network 192.2.2.2 0.0.0.0
[PE1-ospf-1-area-0.0.0.0] quit
[PE1-ospf-1] quit
# Create VLAN 10 and assign Ten-GigabitEthernet 1/1/11 to the VLAN.
[PE1] vlan 10
[PE1-vlan10] port ten-gigabitethernet 1/1/11
[PE1-vlan10] quit
# Create Ethernet service instance 10 on Ten-GigabitEthernet 1/1/11 to match packets with an outer VLAN ID of 10.
[PE1] interface ten-gigabitethernet 1/1/11
[PE1-Ten-GigabitEthernet1/1/11] service-instance 10
[PE1-Ten-GigabitEthernet1/1/11-srv10] encapsulation s-vid 10
[PE1-Ten-GigabitEthernet1/1/11-srv10] quit
[PE1-Ten-GigabitEthernet1/1/11] quit
4. Configure the P device:
# Configure an LSR ID.
<P> system-view
[P] interface loopback 0
[P-LoopBack0] ip address 192.4.4.4 32
[P-LoopBack0] quit
[P] mpls lsr-id 192.4.4.4
# Enable global LDP.
[P] mpls ldp
[P-ldp] quit
# Configure VLAN-interface 20 (the interface connected to PE 1), and enable LDP on the interface.
[P] interface vlan-interface 20
[P-Vlan-interface20] ip address 10.1.1.2 24
[P-Vlan-interface20] mpls enable
[P-Vlan-interface20] mpls ldp enable
[P-Vlan-interface20] quit
# Configure VLAN-interface 30 (the interface connected to PE 2), and enable LDP on the interface.
[P] interface vlan-interface 30
[P-Vlan-interface30] ip address 10.2.2.2 24
[P-Vlan-interface30] mpls enable
[P-Vlan-interface30] mpls ldp enable
[P-Vlan-interface30] quit
# Configure OSPF for LDP to create LSPs.
[P] ospf
[P-ospf-1] area 0
[P-ospf-1-area-0.0.0.0] network 10.1.1.2 0.0.0.255
[P-ospf-1-area-0.0.0.0] network 10.2.2.2 0.0.0.255
[P-ospf-1-area-0.0.0.0] network 192.4.4.4 0.0.0.0
[P-ospf-1-area-0.0.0.0] quit
[P-ospf-1] quit
5. Configure PE 2:
# Configure an LSR ID.
<PE2> system-view
[PE2] interface loopback 0
[PE2-LoopBack0] ip address 192.3.3.3 32
[PE2-LoopBack0] quit
[PE2] mpls lsr-id 192.3.3.3
# Enable L2VPN.
[PE2] l2vpn enable
# Enable global LDP.
[PE2] mpls ldp
[PE2-ldp] quit
# Configure VLAN-interface 30 (the interface connected to the P device), and enable LDP on the interface.
[PE2] interface vlan-interface 30
[PE2-Vlan-interface30] ip address 10.2.2.1 24
[PE2-Vlan-interface30] mpls enable
[PE2-Vlan-interface30] mpls ldp enable
[PE2-Vlan-interface30] quit
# Configure OSPF for LDP to create LSPs.
[PE2] ospf
[PE2-ospf-1] area 0
[PE2-ospf-1-area-0.0.0.0] network 10.2.2.1 0.0.0.255
[PE2-ospf-1-area-0.0.0.0] network 192.3.3.3 0.0.0.0
[PE2-ospf-1-area-0.0.0.0] quit
[PE2-ospf-1] quit
# Create VLAN 10 and assign Ten-GigabitEthernet 1/1/11 to the VLAN.
[PE2] vlan 10
[PE2-vlan10] port ten-gigabitethernet 1/1/11
[PE2-vlan10] quit
# Create Ethernet service instance 10 on Ten-GigabitEthernet 1/1/11 to match packets with an outer VLAN ID of 10.
[PE2] interface ten-gigabitethernet 1/1/11
[PE2-Ten-GigabitEthernet1/1/11] service-instance 10
[PE2-Ten-GigabitEthernet1/1/11-srv10]encapsulation s-vid 10
[PE2-Ten-GigabitEthernet1/1/11-srv10] quit
[PE2-Ten-GigabitEthernet1/1/11] quit
6. Configure CE 2.
<CE2> system-view
[CE2] interface vlan-interface 10
[CE2-Vlan-interface10] ip address 100.1.1.2 24
[CE2-Vlan-interface10] quit
Verifying the configuration
# Verify that a static PW has been established on PE 1.
[PE1] display l2vpn pw
Flags: M - main, B - backup, E - ecmp, BY - bypass, H - hub link, S - spoke link
N - no split horizon, A - administration, ABY - ac-bypass
PBY - pw-bypass
Total number of PWs: 1
1 up, 0 blocked, 0 down, 0 defect, 0 idle, 0 duplicate
Xconnect-group Name: vpna
Peer PWID/RmtSite/SrvID In/Out Label Proto Flag Link ID State
192.3.3.3 3 100/200 Static M 0 Up
# Verify that a static PW has been established on PE 2.
[PE2] display l2vpn pw
Flags: M - main, B - backup, E - ecmp, BY - bypass, H - hub link, S - spoke link
N - no split horizon, A - administration, ABY - ac-bypass
PBY - pw-bypass
Total number of PWs: 1
1 up, 0 blocked, 0 down, 0 defect, 0 idle, 0 duplicate
Xconnect-group Name: vpna
Peer PWID/RmtSite/SrvID In/Out Label Proto Flag Link ID State
192.2.2.2 3 200/100 Static M 0 Up
# Verify that CE 1 and CE 2 can ping each other. (Details not shown.)
Example: Configuring an LDP PW
Network configuration
Create an LDP PW between PE 1 and PE 2, and use flexible mode to match packets from each AC to allow communication between CE 1 and CE 2 within VLAN 10 without consuming VLAN resources on PEs.
Figure 9 Network diagram
Table 3 Interface and IP address assignment
|
Device |
Interface |
IP address |
Device |
Interface |
IP address |
|
CE 1 |
Vlan-int10 |
100.1.1.1/24 |
P |
Loop0 |
192.4.4.4/32 |
|
PE 1 |
Loop0 |
192.2.2.2/32 |
|
Vlan-int23 |
23.1.1.2/24 |
|
|
Vlan-int23 |
23.1.1.1/24 |
|
Vlan-int26 |
26.2.2.2/24 |
|
CE 2 |
Vlan-int10 |
100.1.1.2/24 |
PE 2 |
Loop0 |
192.3.3.3/32 |
|
|
|
|
|
Vlan-int26 |
26.2.2.1/24 |
Procedure
1. Configure VLANs and add ports to VLANs on each switch module. (Details not shown.)
2. Configure CE 1.
<CE1> system-view
[CE1] interface vlan-interface 10
[CE1-Vlan-interface10] ip address 100.1.1.1 24
[CE1-Vlan-interface10] quit
3. Configure PE 1:
# Configure an LSR ID.
<PE1> system-view
[PE1] interface loopback 0
[PE1-LoopBack0] ip address 192.2.2.2 32
[PE1-LoopBack0] quit
[PE1] mpls lsr-id 192.2.2.2
# Enable L2VPN.
[PE1] l2vpn enable
# Enable global LDP.
[PE1] mpls ldp
[PE1-ldp] quit
# Configure VLAN-interface 23 (the interface connected to the P device), and enable LDP on the interface.
[PE1] interface vlan-interface 23
[PE1-Vlan-interface23] ip address 23.1.1.1 24
[PE1-Vlan-interface23] mpls enable
[PE1-Vlan-interface23] mpls ldp enable
[PE1-Vlan-interface23] quit
# Configure OSPF for LDP to create LSPs.
[PE1] ospf
[PE1-ospf-1] area 0
[PE1-ospf-1-area-0.0.0.0] network 23.1.1.1 0.0.0.255
[PE1-ospf-1-area-0.0.0.0] network 192.2.2.2 0.0.0.0
[PE1-ospf-1-area-0.0.0.0] quit
[PE1-ospf-1] quit
# Create Ethernet service instance 1000 on Ten-GigabitEthernet 1/1/11 (the interface connected to CE 1).
[PE1] interface ten-gigabitethernet 1/1/11
[PE1-Ten-GigabitEthernet1/1/11] service-instance 1000
[PE1-Ten-GigabitEthernet1/1/11-srv1000] encapsulation s-vid 10
[PE1-Ten-GigabitEthernet1/1/11-srv1000] quit
[PE1-Ten-GigabitEthernet1/1/11] quit
4. Configure the P device:
# Configure an LSR ID.
<P> system-view
[P] interface loopback 0
[P-LoopBack0] ip address 192.4.4.4 32
[P-LoopBack0] quit
[P] mpls lsr-id 192.4.4.4
# Enable global LDP.
[P] mpls ldp
[P-ldp] quit
# Configure VLAN-interface 23 (the interface connected to PE 1), and enable LDP on the interface.
[P] interface vlan-interface 23
[P-Vlan-interface23] ip address 23.1.1.2 24
[P-Vlan-interface23] mpls enable
[P-Vlan-interface23] mpls ldp enable
[P-Vlan-interface23] quit
# Configure VLAN-interface 26 (the interface connected to PE 2), and enable LDP on the interface.
[P] interface vlan-interface 26
[P-Vlan-interface26] ip address 26.2.2.2 24
[P-Vlan-interface26] mpls enable
[P-Vlan-interface26] mpls ldp enable
[P-Vlan-interface26] quit
# Configure OSPF for LDP to create LSPs.
[P] ospf
[P-ospf-1] area 0
[P-ospf-1-area-0.0.0.0] network 23.1.1.2 0.0.0.255
[P-ospf-1-area-0.0.0.0] network 26.2.2.2 0.0.0.255
[P-ospf-1-area-0.0.0.0] network 192.4.4.4 0.0.0.0
[P-ospf-1-area-0.0.0.0] quit
[P-ospf-1] quit
5. Configure PE 2:
# Configure an LSR ID.
<PE2> system-view
[PE2] interface loopback 0
[PE2-LoopBack0] ip address 192.3.3.3 32
[PE2-LoopBack0] quit
[PE2] mpls lsr-id 192.3.3.3
# Enable L2VPN.
[PE2] l2vpn enable
# Enable global LDP.
[PE2] mpls ldp
[PE2-ldp] quit
# Configure VLAN-interface 26 (the interface connected to the P device), and enable LDP on the interface.
[PE2] interface vlan-interface 26
[PE2-Vlan-interface26] ip address 26.2.2.1 24
[PE2-Vlan-interface26] mpls enable
[PE2-Vlan-interface26] mpls ldp enable
[PE2-Vlan-interface26] quit
# Configure OSPF for LDP to create LSPs.
[PE2] ospf
[PE2-ospf-1] area 0
[PE2-ospf-1-area-0.0.0.0] network 192.3.3.3 0.0.0.0
[PE2-ospf-1-area-0.0.0.0] network 26.2.2.0 0.0.0.255
[PE2-ospf-1-area-0.0.0.0] quit
[PE2-ospf-1] quit
# Create Ethernet service instance 1000 on Ten-GigabitEthernet 1/1/11 (the interface connected to CE 2).
[PE2] interface ten-gigabitethernet 1/1/11
[PE2-Ten-GigabitEthernet1/1/11] service-instance 1000
[PE2-Ten-GigabitEthernet1/1/11-srv1000] encapsulation s-vid 10
[PE2-Ten-GigabitEthernet1/1/11-srv1000] quit
[PE2-Ten-GigabitEthernet1/1/11] quit
6. Configure CE 2.
<CE2> system-view
[CE2] interface vlan-interface 10
[CE2-Vlan-interface10] ip address 100.1.1.2 24
[CE2-Vlan-interface10] quit
Verifying the configuration
# Verify that an LDP PW has been established on PE 1.
[PE1] display l2vpn pw
Flags: M - main, B - backup, E - ecmp, BY - bypass, H - hub link, S - spoke link
N - no split horizon, A - administration, ABY - ac-bypass
PBY - pw-bypass
Total number of PWs: 1
1 up, 0 blocked, 0 down, 0 defect, 0 idle, 0 duplicate
Xconnect-group Name: vpn1
Peer PWID/RmtSite/SrvID In/Out Label Proto Flag Link ID State
192.3.3.3 1000 1151/1279 LDP M 1 Up
# Verify that an LDP PW has been established on PE 2.
[PE2] display l2vpn pw
Flags: M - main, B - backup, E - ecmp, BY - bypass, H - hub link, S - spoke link
N - no split horizon, A - administration, ABY - ac-bypass
PBY - pw-bypass
Total number of PWs: 1
1 up, 0 blocked, 0 down, 0 defect, 0 idle, 0 duplicate
Xconnect-group Name: vpn1
Peer PWID/RmtSite/SrvID In/Out Label Proto Flag Link ID State
192.2.2.2 1000 1279/1151 LDP M 1 Up
# Verify that CE 1 and CE 2 can ping each other. (Details not shown.)
Example: Configuring a BGP PW
Network configuration
Create a BGP PW between PE 1 and PE 2 to allow communication between CE 1 and CE 2 within VLAN 10.
Create Ethernet service instance 10 on Ten-GigabitEthernet 1/1/11 to match packets with an outer VLAN ID of 10 on each PE.
Figure 10 Network diagram
Table 4 Interface and IP address assignment
|
Device |
Interface |
IP address |
Device |
Interface |
IP address |
|
CE 1 |
Vlan-int10 |
100.1.1.1/24 |
P |
Loop0 |
192.4.4.4/32 |
|
PE 1 |
Loop0 |
192.2.2.2/32 |
|
Vlan-int20 |
10.1.1.2/24 |
|
|
Vlan-int20 |
10.1.1.1/24 |
|
Vlan-int30 |
10.2.2.2/24 |
|
CE 2 |
Vlan-int10 |
100.1.1.2/24 |
PE 2 |
Loop0 |
192.3.3.3/32 |
|
|
|
|
|
Vlan-int30 |
10.2.2.1/24 |
Procedure
1. Configure VLANs and add ports to VLANs on each switch module. (Details not shown.)
2. Configure CE 1.
<CE1> system-view
[CE1] interface vlan-interface 10
[CE1-Vlan-interface10] ip address 100.1.1.1 24
[CE1-Vlan-interface10] quit
3. Configure PE 1:
# Configure an LSR ID.
<PE1> system-view
[PE1] interface loopback 0
[PE1-LoopBack0] ip address 192.2.2.2 32
[PE1-LoopBack0] quit
[PE1] mpls lsr-id 192.2.2.2
# Enable L2VPN.
[PE1] l2vpn enable
# Enable LDP globally.
[PE1] mpls ldp
[PE1-ldp] quit
# Configure VLAN-interface 20 (the interface connected to the P device), and enable LDP on the interface.
[PE1] interface vlan-interface 20
[PE1-Vlan-interface20] ip address 10.1.1.1 24
[PE1-Vlan-interface20] mpls enable
[PE1-Vlan-interface20] mpls ldp enable
[PE1-Vlan-interface20] quit
# Enable OSPF for LSP establishment.
[PE1] ospf
[PE1-ospf-1] area 0
[PE1-ospf-1-area-0.0.0.0] network 10.1.1.1 0.0.0.255
[PE1-ospf-1-area-0.0.0.0] network 192.2.2.2 0.0.0.0
[PE1-ospf-1-area-0.0.0.0] quit
[PE1-ospf-1] quit
# Create an IBGP connection to PE 2, and enable BGP to advertise L2VPN information to PE 2.
[PE1] bgp 100
[PE1-bgp-default] peer 192.3.3.3 as-number 100
[PE1-bgp-default] peer 192.3.3.3 connect-interface loopback 0
[PE1-bgp-default] address-family l2vpn
[PE1-bgp-default-l2vpn] peer 192.3.3.3 enable
[PE1-bgp-default-l2vpn] quit
[PE1-bgp-default] quit
# Create VLAN 10 and assign Ten-GigabitEthernet 1/1/11 to the VLAN.
[PE1] vlan 10
[PE1-vlan10] port ten-gigabitethernet 1/1/11
[PE1-vlan10] quit
# Create Ethernet service instance 10 on Ten-GigabitEthernet 1/1/11 to match packets with an outer VLAN ID of 10.
[PE1] interface ten-gigabitethernet 1/1/11
[PE1-Ten-GigabitEthernet1/1/11] service-instance 10
[PE1-Ten-GigabitEthernet1/1/11-srv10]encapsulation s-vid 10
[PE1-Ten-GigabitEthernet1/1/11-srv10] quit
[PE1-Ten-GigabitEthernet1/1/11] quit
4. Configure the P device:
# Configure an LSR ID.
<P> system-view
[P] interface loopback 0
[P-LoopBack0] ip address 192.4.4.4 32
[P-LoopBack0] quit
[P] mpls lsr-id 192.4.4.4
# Enable LDP globally.
[P] mpls ldp
[P-ldp] quit
# Configure VLAN-interface 20 (the interface connected to PE 1), and enable LDP on the interface.
[P] interface vlan-interface 20
[P-Vlan-interface20] ip address 10.1.1.2 24
[P-Vlan-interface20] mpls enable
[P-Vlan-interface20] mpls ldp enable
[P-Vlan-interface20] quit
# Configure VLAN-interface 30 (the interface connected to PE 2), and enable LDP on the interface.
[P] interface vlan-interface 30
[P-Vlan-interface30] ip address 10.2.2.2 24
[P-Vlan-interface30] mpls enable
[P-Vlan-interface30] mpls ldp enable
[P-Vlan-interface30] quit
# Enable OSPF for LSP establishment.
[P] ospf
[P-ospf-1] area 0
[P-ospf-1-area-0.0.0.0] network 10.1.1.2 0.0.0.255
[P-ospf-1-area-0.0.0.0] network 10.2.2.2 0.0.0.255
[P-ospf-1-area-0.0.0.0] network 192.4.4.4 0.0.0.0
[P-ospf-1-area-0.0.0.0] quit
[P-ospf-1] quit
5. Configure PE 2:
# Configure an LSR ID.
<PE2> system-view
[PE2] interface loopback 0
[PE2-LoopBack0] ip address 192.3.3.3 32
[PE2-LoopBack0] quit
[PE2] mpls lsr-id 192.3.3.3
# Enable L2VPN.
[PE2] l2vpn enable
# Enable LDP globally.
[PE2] mpls ldp
[PE2-ldp] quit
# Configure VLAN-interface 30 (the interface connected to the P device), and enable LDP on the interface.
[PE2] interface vlan-interface 30
[PE2-Vlan-interface30] ip address 10.2.2.1 24
[PE2-Vlan-interface30] mpls enable
[PE2-Vlan-interface30] mpls ldp enable
[PE2-Vlan-interface30] quit
# Enable OSPF for LSP establishment.
[PE2] ospf
[PE2-ospf-1] area 0
[PE2-ospf-1-area-0.0.0.0] network 192.3.3.3 0.0.0.0
[PE2-ospf-1-area-0.0.0.0] network 10.2.2.0 0.0.0.255
[PE2-ospf-1-area-0.0.0.0] quit
[PE2-ospf-1] quit
# Create an IBGP connection to PE 1, and enable BGP to advertise L2VPN information to PE 1.
[PE2] bgp 100
[PE2-bgp-default] peer 192.2.2.2 as-number 100
[PE2-bgp-default] peer 192.2.2.2 connect-interface loopback 0
[PE2-bgp-default] address-family l2vpn
[PE2-bgp-default-l2vpn] peer 192.2.2.2 enable
[PE2-bgp-default-l2vpn] quit
[PE2-bgp-default] quit
# Create VLAN 10 and assign Ten-GigabitEthernet 1/1/11 to the VLAN.
[PE2] vlan 10
[PE2-vlan10] port ten-gigabitethernet 1/1/11
[PE2-vlan10] quit
# Create Ethernet service instance 10 on Ten-GigabitEthernet 1/1/11 to match packets with an outer VLAN ID of 10.
[PE2] interface ten-gigabitethernet 1/1/11
[PE2-Ten-GigabitEthernet1/1/11] service-instance 10
[PE2-Ten-GigabitEthernet1/1/11-srv10]encapsulation s-vid 10
[PE2-Ten-GigabitEthernet1/1/11-srv10] quit
[PE2-Ten-GigabitEthernet1/1/11] quit
6. Configure CE 2.
<CE2> system-view
[CE2] interface vlan-interface 10
[CE2-Vlan-interface10] ip address 100.1.1.2 24
[CE2-Vlan-interface10] quit
Verifying the configuration
# Verify that a BGP PW has been established on PE 1.
<PE1> display l2vpn pw
Flags: M - main, B - backup, E - ecmp, BY - bypass, H - hub link, S - spoke link
N - no split horizon, A - administration, ABY - ac-bypass
PBY - pw-bypass
Total number of PWs: 1
1 up, 0 blocked, 0 down, 0 defect, 0 idle, 0 duplicate
Xconnect-group Name: vpnb
Peer PW ID/Rmt Site In/Out Label Proto Flag Link ID State
192.3.3.3 2 1036/1025 BGP M 1 Up
# Verify that a BGP PW has been established on PE 2.
<PE2> display l2vpn pw
Flags: M - main, B - backup, E - ecmp, BY - bypass, H - hub link, S - spoke link
N - no split horizon, A - administration, ABY - ac-bypass
PBY - pw-bypass
Total number of PWs: 1
1 up, 0 blocked, 0 down, 0 defect, 0 idle, 0 duplicate
Xconnect-group Name: vpnb
Peer PW ID/Rmt Site In/Out Label Proto Flag Link ID State
192.2.2.2 1 1025/1036 BGP M 1 Up
# Verify that CE 1 and CE 2 can ping each other. (Details not shown.)
Example: Configuring a remote CCC connection
Network configuration
Create a remote CCC connection between PE 1 and PE 2 to allow communication between CE 1 and CE 2 within VLAN 10.
Create Ethernet service instance 10 on Ten-GigabitEthernet 1/1/11 to match packets with an outer VLAN ID of 10 on each PE.
Figure 11 Network diagram
Table 5 Interface and IP address assignment
|
Device |
Interface |
IP address |
Device |
Interface |
IP address |
|
CE 1 |
Vlan-int10 |
100.1.1.1/24 |
P |
Loop0 |
192.4.4.4/32 |
|
PE 1 |
Loop0 |
192.2.2.2/32 |
|
Vlan-int20 |
10.1.1.2/24 |
|
|
Vlan-int20 |
10.1.1.1/24 |
|
Vlan-int30 |
10.2.2.2/24 |
|
CE 2 |
Vlan-int10 |
100.1.1.2/24 |
PE 2 |
Loop0 |
192.3.3.3/32 |
|
|
|
|
|
Vlan-int30 |
10.2.2.1/24 |
Procedure
1. Configure VLANs and add ports to VLANs on each switch module. (Details not shown.)
2. Configure CE 1.
<CE1> system-view
[CE1] interface vlan-interface 10
[CE1-Vlan-interface10] ip address 100.1.1.1 24
[CE1-Vlan-interface10] quit
3. Configure PE 1:
# Configure an LSR ID.
<PE1> system-view
[PE1] interface loopback 0
[PE1-LoopBack0] ip address 192.2.2.2 32
[PE1-LoopBack0] quit
[PE1] mpls lsr-id 192.2.2.2
# Enable L2VPN.
[PE1] l2vpn enable
# Configure VLAN-interface 20 (the interface connected to the P device), and enable MPLS on the interface.
[PE1] interface vlan-interface 20
[PE1-Vlan-interface20] ip address 10.1.1.1 24
[PE1-Vlan-interface20] mpls enable
[PE1-Vlan-interface20] quit
# Create VLAN 10 and assign Ten-GigabitEthernet 1/1/11 to the VLAN.
[PE1] vlan 10
[PE1-vlan10] port ten-gigabitethernet 1/1/11
[PE1-vlan10] quit
# Create Ethernet service instance 10 on Ten-GigabitEthernet 1/1/11 to match packets with an outer VLAN ID of 10.
[PE1] interface ten-gigabitethernet 1/1/11
[PE1-Ten-GigabitEthernet1/1/11] service-instance 10
[PE1-Ten-GigabitEthernet1/1/11-srv10]encapsulation s-vid 10
[PE1-Ten-GigabitEthernet1/1/11-srv10] quit
[PE1-Ten-GigabitEthernet1/1/11] quit
4. Configure the P device:
# Configure an LSR ID.
<P> system-view
[P] interface loopback 0
[P-LoopBack0] ip address 192.4.4.4 32
[P-LoopBack0] quit
[P] mpls lsr-id 192.4.4.4
# Configure VLAN-interface 20 (the interface connected to PE 1), and enable MPLS on the interface.
[P] interface vlan-interface 20
[P-Vlan-interface20] ip address 10.1.1.2 24
[P-Vlan-interface20] mpls enable
[P-Vlan-interface20] quit
# Configure VLAN-interface 30 (the interface connected to PE 2), and enable MPLS on the interface.
[P] interface vlan-interface 30
[P-Vlan-interface30] ip address 10.2.2.2 24
[P-Vlan-interface30] mpls enable
[P-Vlan-interface30] quit
# Configure a static LSP to forward packets from PE 1 to PE 2.
[P] static-lsp transit pe1-pe2 in-label 201 nexthop 10.2.2.1 out-label 202
# Configure a static LSP to forward packets from PE 2 to PE 1.
[P] static-lsp transit pe2-pe1 in-label 102 nexthop 10.1.1.1 out-label 101
5. Configure PE 2:
# Configure an LSR ID.
<PE2> system-view
[PE2] interface loopback 0
[PE2-LoopBack0] ip address 192.3.3.3 32
[PE2-LoopBack0] quit
[PE2] mpls lsr-id 192.3.3.3
# Enable L2VPN.
[PE2] l2vpn enable
# Configure VLAN-interface 30 (the interface connected to the P device), and enable MPLS on the interface.
[PE2] interface vlan-interface 30
[PE2-Vlan-interface30] ip address 10.2.2.1 24
[PE2-Vlan-interface30] mpls enable
[PE2-Vlan-interface30] quit
# Create VLAN 10 and assign Ten-GigabitEthernet 1/1/11 to the VLAN.
[PE2] vlan 10
[PE2-vlan10] port ten-gigabitethernet 1/1/11
[PE2-vlan10] quit
# Create Ethernet service instance 10 on Ten-GigabitEthernet 1/1/11 to match packets with an outer VLAN ID of 10.
[PE2] interface ten-gigabitethernet 1/1/11
[PE2-Ten-GigabitEthernet1/1/11] service-instance 10
[PE2-Ten-GigabitEthernet1/1/11-srv10]encapsulation s-vid 10
[PE2-Ten-GigabitEthernet1/1/11-srv10] quit
[PE2-Ten-GigabitEthernet1/1/11] quit
6. Configure CE 2.
<CE2> system-view
[CE2] interface vlan-interface 10
[CE2-Vlan-interface10] ip address 100.1.1.2 24
[CE2-Vlan-interface10] quit
Verifying the configuration
# Verify that a remote CCC connection (identified by PW ID/Rmt Site "-" and Proto Static) has been established on PE 1.
[PE1] display l2vpn pw
Flags: M - main, B - backup, E - ecmp, BY - bypass, H - hub link, S - spoke link
N - no split horizon, A - administration, ABY - ac-bypass
PBY - pw-bypass
Total number of PWs: 1
1 up, 0 blocked, 0 down, 0 defect, 0 idle, 0 duplicate
Xconnect-group Name: ccc
Peer PW ID/Rmt Site In/Out Label Proto Flag Link ID State
10.1.1.2 - 101/201 Static M 0 Up
# Verify that a remote CCC connection has been established on PE 2.
[PE2] display l2vpn pw
Flags: M - main, B - backup, E - ecmp, BY - bypass, H - hub link, S - spoke link
N - no split horizon, A - administration, ABY - ac-bypass
PBY - pw-bypass
Total number of PWs: 1
1 up, 0 blocked, 0 down, 0 defect, 0 idle, 0 duplicate
Xconnect-group Name: ccc
Peer PW ID/Rmt Site In/Out Label Proto Flag Link ID State
10.2.2.2 - 202/102 Static M 0 Up
# Verify that CE 1 and CE 2 can ping each other. (Details not shown.)
Example: Configuring LDP PW redundancy
Network configuration
Create two LDP PWs to implement PW redundancy between CE 1 and CE 2. The primary PW goes through PE 1—PE 2. The backup PW goes through PE 1—PE 3. When the primary PW fails, CE 1 and CE 2 communicate through the backup PW.
Figure 12 Network diagram
Table 6 Interface and IP address assignment
|
Device |
Interface |
IP address |
Device |
Interface |
IP address |
|
CE 1 |
Vlan-int10 |
100.1.1.1/24 |
PE 2 |
Loop0 |
2.2.2.2/32 |
|
PE 1 |
Loop0 |
1.1.1.1/32 |
|
Vlan-int12 |
12.1.1.2/24 |
|
|
Vlan-int12 |
12.1.1.1/24 |
PE 3 |
Loop0 |
3.3.3.3/32 |
|
|
Vlan-int13 |
13.1.1.1/24 |
|
Vlan-int13 |
13.1.1.3/24 |
|
CE 2 |
Vlan-int10 |
100.1.1.2/24 |
|
|
|
Procedure
1. Configure VLANs and add ports to VLANs on each switch module. (Details not shown.)
2. Disable the spanning tree feature globally or map each VLAN to an MSTI. (Details not shown.)
For more information, see Layer 2—LAN Switching Configuration Guide.
3. Configure CE 1.
<CE1> system-view
[CE1] interface vlan-interface 10
[CE1-Vlan-interface10] ip address 100.1.1.1 24
[CE1-Vlan-interface10] quit
4. Configure PE 1:
# Configure an LSR ID.
<PE1> system-view
[PE1] interface loopback 0
[PE1-LoopBack0] ip address 1.1.1.1 32
[PE1-LoopBack0] quit
[PE1] mpls lsr-id 1.1.1.1
# Enable global MPLS LDP.
[PE1] mpls ldp
[PE1-ldp] quit
# Configure VLAN interface 12 (the interface connected to PE 2) and VLAN interface 13 (the interface connected to PE 3), and enable LDP for the interfaces.
[PE1] interface vlan-interface 12
[PE1-Vlan-interface12] ip address 12.1.1.1 24
[PE1-Vlan-interface12] mpls enable
[PE1-Vlan-interface12] mpls ldp enable
[PE1-Vlan-interface12] quit
[PE1] interface vlan-interface 13
[PE1-Vlan-interface13] ip address 13.1.1.1 24
[PE1-Vlan-interface13] mpls enable
[PE1-Vlan-interface13] mpls ldp enable
[PE1-Vlan-interface13] quit
# Configure OSPF for LDP to create LSPs.
[PE1] ospf
[PE1-ospf-1] area 0
[PE1-ospf-1-area-0.0.0.0] network 1.1.1.1 0.0.0.0
[PE1-ospf-1-area-0.0.0.0] network 12.1.1.0 0.0.0.255
[PE1-ospf-1-area-0.0.0.0] network 13.1.1.0 0.0.0.255
[PE1-ospf-1-area-0.0.0.0] quit
[PE1-ospf-1] quit
# Enable L2VPN.
[PE1] l2vpn enable
# Create Ethernet service instance 10 on Ten-GigabitEthernet 1/1/11 to match packets with an outer VLAN ID of 10.
[PE1] interface ten-gigabitethernet 1/1/11
[PE1-Ten-GigabitEthernet1/1/11] port link-type trunk
[PE1-Ten-GigabitEthernet1/1/11] port trunk permit vlan 10
[PE1-Ten-GigabitEthernet1/1/11] service-instance 10
[PE1-Ten-GigabitEthernet1/1/11-srv10] encapsulation s-vid 10
[PE1-Ten-GigabitEthernet1/1/11-srv10] quit
[PE1-Ten-GigabitEthernet1/1/11] quit
5. Configure PE 2:
# Configure LSR ID.
<PE2> system-view
[PE2] interface loopback 0
[PE2-LoopBack0] ip address 2.2.2.2 32
[PE2-LoopBack0] quit
[PE2] mpls lsr-id 2.2.2.2
# Enable global MPLS LDP.
[PE2] mpls ldp
[PE2-ldp] quit
# Configure VLAN interface 12 (the interface connected to PE 1), and enable LDP on it.
[PE2] interface vlan-interface 12
[PE2-Vlan-interface12] ip address 12.1.1.2 24
[PE2-Vlan-interface12] mpls enable
[PE2-Vlan-interface12] mpls ldp enable
[PE2-Vlan-interface12] quit
# Configure OSPF for LDP to create LSPs.
[PE2] ospf
[PE2-ospf-1] area 0
[PE2-ospf-1-area-0.0.0.0] network 12.1.1.0 0.0.0.255
[PE2-ospf-1-area-0.0.0.0] network 2.2.2.2 0.0.0.0
[PE2-ospf-1-area-0.0.0.0] quit
[PE2-ospf-1] quit
# Enable L2VPN.
[PE2] l2vpn enable
# Create Ethernet service instance 10 on Ten-GigabitEthernet 1/1/11 to match packets with an outer VLAN ID of 10.
[PE2] interface ten-gigabitethernet 1/1/11
[PE2-Ten-GigabitEthernet1/1/11] port link-type trunk
[PE2-Ten-GigabitEthernet1/1/11] port trunk permit vlan 10
[PE2-Ten-GigabitEthernet1/1/11] service-instance 10
[PE2-Ten-GigabitEthernet1/1/11-srv10] encapsulation s-vid 10
[PE2-Ten-GigabitEthernet1/1/11-srv10] quit
[PE2-Ten-GigabitEthernet1/1/11] quit
6. Configure PE 3:
# Configure an LSR ID.
<PE3> system-view
[PE3] interface loopback 0
[PE3-LoopBack0] ip address 3.3.3.3 32
[PE3-LoopBack0] quit
[PE3] mpls lsr-id 3.3.3.3
# Enable global MPLS LDP.
[PE3] mpls ldp
[PE3-ldp] quit
# Configure VLAN interface 13 (the interface connected to PE 1), and enable LDP on it.
[PE3] interface vlan-interface 13
[PE3-Vlan-interface13] ip address 13.1.1.3 24
[PE3-Vlan-interface13] mpls enable
[PE3-Vlan-interface13] mpls ldp enable
[PE3-Vlan-interface13] quit
# Configure OSPF on PE 3 for LDP to create LSPs.
[PE3] ospf
[PE3-ospf-1] area 0
[PE3-ospf-1-area-0.0.0.0] network 13.1.1.0 0.0.0.255
[PE3-ospf-1-area-0.0.0.0] network 3.3.3.3 0.0.0.0
[PE3-ospf-1-area-0.0.0.0] quit
[PE3-ospf-1] quit
# Enable L2VPN.
[PE3] l2vpn enable
# Create Ethernet service instance 10 on Ten-GigabitEthernet 1/1/11 to match packets with an outer VLAN ID of 10.
[PE3] interface ten-gigabitethernet 1/1/11
[PE3-Ten-GigabitEthernet1/1/11] port link-type trunk
[PE3-Ten-GigabitEthernet1/1/11] port trunk permit vlan 10
[PE3-Ten-GigabitEthernet1/1/11] service-instance 10
[PE3-Ten-GigabitEthernet1/1/11-srv10] encapsulation s-vid 10
[PE3-Ten-GigabitEthernet1/1/11-srv10] quit
[PE3-Ten-GigabitEthernet1/1/11] quit
7. Configure CE 2.
<CE2> system-view
[CE2] interface vlan-interface 10
[CE2-Vlan-interface10] ip address 100.1.1.2 24
[CE2-Vlan-interface10] quit
Verifying the configuration
# Verify that two LDP PWs have been established on PE 1.
<PE1> display l2vpn pw
Flags: M - main, B - backup, E - ecmp, BY - bypass, H - hub link, S - spoke link
N - no split horizon, A - administration, ABY - ac-bypass
PBY - pw-bypass
Total number of PWs: 2
1 up, 1 blocked, 0 down, 0 defect, 0 idle, 0 duplicate
Xconnect-group Name: vpna
Peer PWID/RmtSite/SrvID In/Out Label Proto Flag Link ID State
2.2.2.2 20 1151/1279 LDP M 1 Up
3.3.3.3 30 1150/1279 LDP B 1 Blocked
# Display detailed information about the primary and backup PWs on PE 1.
<PE1> display l2vpn pw verbose
Xconnect-group Name: vpna
Connection Name: ldp
Peer: 2.2.2.2 PW ID: 20
Signaling Protocol : LDP
Link ID : 1 PW State : Up
In Label : 1151 Out Label: 1279
Wait to Restore Time: 0 sec
MTU : 1500
PW Attributes : Main
VCCV CC : -
VCCV BFD : -
Flow Label : -
Tunnel Group ID : 0x260000002
Tunnel NHLFE IDs : 1025
Admin PW : -
Peer: 3.3.3.3 PW ID: 30
Signaling Protocol : LDP
Link ID : 1 PW State : Blocked
In Label : 1150 Out Label: 1279
MTU : 1500
PW Attributes : Backup
VCCV CC : -
VCCV BFD : -
Flow Label : -
Tunnel Group ID : 0x360000003
Tunnel NHLFE IDs : 1027
Admin PW : -
# Verify that an LDP PW has been established on PE 2.
[PE2] display l2vpn pw
Flags: M - main, B - backup, E - ecmp, BY - bypass, H - hub link, S - spoke link
N - no split horizon, A - administration, ABY - ac-bypass
PBY - pw-bypass
Total number of PWs: 1
1 up, 0 blocked, 0 down, 0 defect, 0 idle, 0 duplicate
Xconnect-group Name: vpna
Peer PWID/RmtSite/SrvID In/Out Label Proto Flag Link ID State
1.1.1.1 20 1279/1151 LDP M 1 Up
# Verify that an LDP PW has been established on PE 3.
[PE3] display l2vpn pw
Flags: M - main, B - backup, E - ecmp, BY - bypass, H - hub link, S - spoke link
N - no split horizon, A - administration, ABY - ac-bypass
PBY - pw-bypass
Total number of PWs: 1
1 up, 0 blocked, 0 down, 0 defect, 0 idle, 0 duplicate
Xconnect-group Name: vpna
Peer PWID/RmtSite/SrvID In/Out Label Proto Flag Link ID State
1.1.1.1 30 1279/1150 LDP M 1 Up
# Verify that CE 1 and CE 2 can ping each other. (Details not shown.)
# Manually switch to the backup PW on PE 1.
<PE1> l2vpn switchover peer 2.2.2.2 pw-id 20
# Verify that the PW switchover is successful on PE 1.
<PE1> display l2vpn pw
Flags: M - main, B - backup, E - ecmp, BY - bypass, H - hub link, S - spoke link
N - no split horizon, A - administration, ABY - ac-bypass
PBY - pw-bypass
Total number of PWs: 2
1 up, 1 blocked, 0 down, 0 defect, 0 idle, 0 duplicate
Xconnect-group Name: vpna
Peer PWID/RmtSite/SrvID In/Out Label Proto Flag Link ID State
2.2.2.2 20 1151/1279 LDP M 1 Blocked
3.3.3.3 30 1150/1279 LDP B 1 Up
# Verify that CE 1 and CE 2 can ping each other. (Details not shown.)
Example: Configuring an intra-domain multi-segment PW
Network configuration
As shown in Figure 13, there is no public tunnel between PE 1 and PE 2, and there is an MPLS TE tunnel between PE 1 and P, and an MPLS TE tunnel between P and PE 2.
Configure a multi-segment PW within the backbone to allow communication between CE 1 and CE 2. The multi-segment PW includes a PW between PE 1 and P, and a PW between P and PE 2. The two PWs are concatenated on P.
Table 7 Interface and IP address assignment
|
Device |
Interface |
IP address |
Device |
Interface |
IP address |
|
CE 1 |
Vlan-int10 |
100.1.1.1/24 |
P |
Loop0 |
192.4.4.4/32 |
|
PE 1 |
Loop0 |
192.2.2.2/32 |
|
Vlan-int23 |
23.1.1.2/24 |
|
|
Vlan-int23 |
23.1.1.1/24 |
|
Vlan-int26 |
26.2.2.2/24 |
|
CE 2 |
Vlan-int10 |
100.1.1.2/24 |
PE 2 |
Loop0 |
192.3.3.3/32 |
|
|
|
|
|
Vlan-int26 |
26.2.2.1/24 |
Procedure
1. Configure VLANs and add ports to VLANs on each switch module. (Details not shown.)
2. Configure CE 1.
<CE1> system-view
[CE1] interface vlan-interface 10
[CE1-Vlan-interface10] ip address 100.1.1.1 24
[CE1-Vlan-interface10] quit
3. Configure PE 1:
# Configure an LSR ID.
<PE1> system-view
[PE1] interface loopback 0
[PE1-LoopBack0] ip address 192.2.2.2 32
[PE1-LoopBack0] quit
[PE1] mpls lsr-id 192.2.2.2
# Enable L2VPN.
[PE1] l2vpn enable
# Enable LDP globally.
[PE1] mpls ldp
[PE1-ldp] quit
# Configure MPLS TE to establish an MPLS TE tunnel between PE 1 and P. For more information, see "Configuring MPLS TE."
# Create Ethernet service instance 1000 on Ten-GigabitEthernet 1/1/11 (the interface connected to CE 1).
[PE1] interface ten-gigabitethernet 1/1/11
[PE1-Ten-GigabitEthernet1/1/11] service-instance 1000
[PE1-Ten-GigabitEthernet1/1/11-srv1000] encapsulation s-vid 10
[PE1-Ten-GigabitEthernet1/1/11-srv1000] quit
[PE1-Ten-GigabitEthernet1/1/11] quit
4. Configure the P device:
# Configure an LSR ID.
<P> system-view
[P] interface loopback 0
[P-LoopBack0] ip address 192.4.4.4 32
[P-LoopBack0] quit
[P] mpls lsr-id 192.4.4.4
# Enable L2VPN.
[P] l2vpn enable
# Enable LDP globally.
[P] mpls ldp
[P-ldp] quit
# Configure MPLS TE to establish an MPLS TE tunnel between PE 1 and P, and between P and PE 2. For more information, see "Configuring MPLS TE."
# Create a cross-connect group named vpn1, create a cross-connect named ldpsvc in the group, and create an LDP PW and a static PW for the cross-connect to form a multi-segment PW.
[P] xconnect-group vpn1
[P-xcg-vpn1] connection ldpsvc
[P-xcg-vpn1-ldpsvc] peer 192.2.2.2 pw-id 1000
[P-xcg-vpn1-ldpsvc-192.2.2.2-1000] quit
[P-xcg-vpn1-ldpsvc] peer 192.3.3.3 pw-id 1000 in-label 100 out-label 200
[P-xcg-vpn1-ldpsvc-192.3.3.3-1000] quit
[P-xcg-vpn1-ldpsvc] quit
[P-xcg-vpn1] quit
5. Configure PE 2:
# Configure an LSR ID.
<PE2> system-view
[PE2] interface loopback 0
[PE2-LoopBack0] ip address 192.3.3.3 32
[PE2-LoopBack0] quit
[PE2] mpls lsr-id 192.3.3.3
# Enable L2VPN.
[PE2] l2vpn enable
# Configure MPLS TE to establish an MPLS TE tunnel between P and PE 2. For more information, see "Configuring MPLS TE."
# Create Ethernet service instance 1000 on Ten-GigabitEthernet 1/1/11 (the interface connected to CE 2).
[PE2] interface ten-gigabitethernet 1/1/11
[PE2-Ten-GigabitEthernet1/1/11] service-instance 1000
[PE2-Ten-GigabitEthernet1/1/11-srv1000] encapsulation s-vid 10
[PE2-Ten-GigabitEthernet1/1/11-srv1000] quit
[PE2-Ten-GigabitEthernet1/1/11] quit
6. Configure CE 2.
<CE2> system-view
[CE2] interface vlan-interface 10
[CE2-Vlan-interface10] ip address 100.1.1.2 24
[CE2-Vlan-interface10] quit
Verifying the configuration
# Verify that two PWs have been created to form a multi-segment PW on the P device.
[P] display l2vpn pw
Flags: M - main, B - backup, E - ecmp, BY - bypass, H - hub link, S - spoke link
N - no split horizon, A - administration, ABY - ac-bypass
PBY - pw-bypass
Total number of PWs: 2
2 up, 0 blocked, 0 down, 0 defect, 0 idle, 0 duplicate
Xconnect-group Name: vpn1
Peer PWID/RmtSite/SrvID In/Out Label Proto Flag Link ID State
192.2.2.2 1000 1279/1150 LDP M 0 Up
192.3.3.3 1000 100/200 Static M 1 Up
# Verify that a PW has been created on PE 1.
[PE1] display l2vpn pw
Flags: M - main, B - backup, E - ecmp, BY - bypass, H - hub link, S - spoke link
N - no split horizon, A - administration, ABY - ac-bypass
PBY - pw-bypass
Total number of PWs: 1
1 up, 0 blocked, 0 down, 0 defect, 0 idle, 0 duplicate
Xconnect-group Name: vpn1
Peer PWID/RmtSite/SrvID In/Out Label Proto Flag Link ID State
192.4.4.4 1000 1150/1279 LDP M 1 Up
# Verify that a PW has been created on PE 2.
[PE2] display l2vpn pw
Flags: M - main, B - backup, E - ecmp, BY - bypass, H - hub link, S - spoke link
N - no split horizon, A - administration, ABY - ac-bypass
PBY - pw-bypass
Total number of PWs: 1
1 up, 0 blocked, 0 down, 0 defect, 0 idle, 0 duplicate
Xconnect-group Name: vpn1
Peer PWID/RmtSite/SrvID In/Out Label Proto Flag Link ID State
192.4.4.4 1000 200/100 Static M 1 Up
# Verify that CE 1 and CE 2 can ping each other. (Details not shown.)
Example: Configuring an inter-domain multi-segment PW
Network configuration
PE 1 and ASBR 1 belong to AS 100. PE 2 and ASBR 2 belong to AS 200.
Set up an inter-domain multi-segment PW (a method for inter-AS Option B networking) within the backbone to allow communication between CE 1 and CE 2.
Configure the inter-domain multi-segment PW as follows:
· Configure LDP PWs between PE 1 and ASBR 1, and between PE 2 and ASBR 2, and configure public tunnels through LDP to carry the PWs.
· Configure an LDP PW between ASBR 1 and ASBR 2. Advertise labeled IPv4 routes between ASBR 1 and ASBR 2 through BGP to set up the public tunnel to carry the LDP PW.
· Concatenate the two PWs on ASBR 1.
· Concatenate the two PWs on ASBR 2.
Figure 14 Network diagram
Table 8 Interface and IP address assignment
|
Device |
Interface |
IP address |
Device |
Interface |
IP address |
|
CE 1 |
Vlan-int10 |
100.1.1.1/24 |
ASBR 1 |
Loop0 |
192.2.2.2/32 |
|
PE 1 |
Loop0 |
192.1.1.1/32 |
|
Vlan-int23 |
23.1.1.2/24 |
|
|
Vlan-int23 |
23.1.1.1/24 |
|
Vlan-int26 |
26.2.2.2/24 |
|
PE 2 |
Loop0 |
192.4.4.4/32 |
ASBR 2 |
Loop0 |
192.3.3.3/32 |
|
|
Vlan-int22 |
22.2.2.1/24 |
|
Vlan-int26 |
26.2.2.3/24 |
|
CE 2 |
Vlan-int10 |
100.1.1.2/24 |
|
Vlan-int22 |
22.2.2.3/24 |
Procedure
1. Configure VLANs and add ports to VLANs on each switch module. (Details not shown.)
2. Configure CE 1.
<CE1> system-view
[CE1] interface vlan-interface 10
[CE1-Vlan-interface10] ip address 100.1.1.1 24
[CE1-Vlan-interface10] quit
3. Configure PE 1:
# Configure an LSR ID.
<PE1> system-view
[PE1] interface loopback 0
[PE1-LoopBack0] ip address 192.1.1.1 32
[PE1-LoopBack0] quit
[PE1] mpls lsr-id 192.1.1.1
# Enable L2VPN.
[PE1] l2vpn enable
# Enable global LDP.
[PE1] mpls ldp
[PE1-ldp] quit
# Configure VLAN-interface 23 (the interface connected to ASBR 1), and enable LDP on the interface.
[PE1] interface vlan-interface 23
[PE1-Vlan-interface23] ip address 23.1.1.1 24
[PE1-Vlan-interface23] mpls enable
[PE1-Vlan-interface23] mpls ldp enable
[PE1-Vlan-interface23] quit
# Configure OSPF for LDP to create LSPs.
[PE1] ospf
[PE1-ospf-1] area 0
[PE1-ospf-1-area-0.0.0.0] network 23.1.1.1 0.0.0.255
[PE1-ospf-1-area-0.0.0.0] network 192.1.1.1 0.0.0.0
[PE1-ospf-1-area-0.0.0.0] quit
[PE1-ospf-1] quit
# Create Ethernet service instance 1000 on Ten-GigabitEthernet 1/1/11 (the interface connected to CE 1).
[PE1] interface ten-gigabitethernet 1/1/11
[PE1-Ten-GigabitEthernet1/1/11] service-instance 1000
[PE1-Ten-GigabitEthernet1/1/11-srv1000] encapsulation s-vid 10
[PE1-Ten-GigabitEthernet1/1/11-srv1000] quit
[PE1-Ten-GigabitEthernet1/1/11] quit
4. Configure ASBR 1:
# Configure an LSR ID.
<ASBR1> system-view
[ASBR1] interface loopback 0
[ASBR1-LoopBack0] ip address 192.2.2.2 32
[ASBR1-LoopBack0] quit
[ASBR1] mpls lsr-id 192.2.2.2
# Enable L2VPN.
[ASBR1] l2vpn enable
# Enable global LDP.
[ASBR1] mpls ldp
[ASBR1-ldp] quit
# Configure VLAN-interface 23 (the interface connected to PE 1), and enable LDP on the interface.
[ASBR1] interface vlan-interface 23
[ASBR1-Vlan-interface23] ip address 23.1.1.2 24
[ASBR1-Vlan-interface23] mpls enable
[ASBR1-Vlan-interface23] mpls ldp enable
[ASBR1-Vlan-interface23] quit
# Configure VLAN-interface 26 (the interface connected to ASBR 2), and enable MPLS on the interface.
[ASBR1] interface vlan-interface 26
[ASBR1-Vlan-interface26] ip address 26.2.2.2 24
[ASBR1-Vlan-interface26] mpls enable
[ASBR1-Vlan-interface26] quit
# Configure OSPF for LDP to create LSPs.
[ASBR1] ospf
[ASBR1-ospf-1] area 0
[ASBR1-ospf-1-area-0.0.0.0] network 23.1.1.2 0.0.0.255
[ASBR1-ospf-1-area-0.0.0.0] network 192.2.2.2 0.0.0.0
[ASBR1-ospf-1-area-0.0.0.0] quit
[ASBR1-ospf-1] quit
# Configure BGP to advertise labeled routes on ASBR1.
[ASBR1] bgp 100
[ASBR1-bgp-default] peer 26.2.2.3 as-number 200
[ASBR1-bgp-default] address-family ipv4 unicast
[ASBR1-bgp-default-ipv4] import-route direct
[ASBR1-bgp-default-ipv4] peer 26.2.2.3 enable
[ASBR1-bgp-default-ipv4] peer 26.2.2.3 route-policy policy1 export
[ASBR1-bgp-default-ipv4] peer 26.2.2.3 label-route-capability
[ASBR1-bgp-default-ipv4] quit
[ASBR1-bgp-default] quit
[ASBR1] route-policy policy1 permit node 1
[ASBR1-route-policy-policy1-1] apply mpls-label
[ASBR1-route-policy-policy1-1] quit
# Create a cross-connect group named vpn1, create a cross-connect named ldp in the group, and create two LDP PWs for the cross-connect to form a multi-segment PW.
[ASBR1] xconnect-group vpn1
[ASBR1-xcg-vpn1] connection ldp
[ASBR1-xcg-vpn1-ldp] peer 192.1.1.1 pw-id 1000
[ASBR1-xcg-vpn1-ldp-192.1.1.1-1000] quit
[ASBR1-xcg-vpn1-ldp] peer 192.3.3.3 pw-id 1000
[ASBR1-xcg-vpn1-ldp-192.3.3.3-1000] quit
[ASBR1-xcg-vpn1-ldp] quit
[ASBR1-xcg-vpn1] quit
5. Configure ASBR 2:
# Configure an LSR ID.
<ASBR2> system-view
[ASBR2] interface loopback 0
[ASBR2-LoopBack0] ip address 192.3.3.3 32
[ASBR2-LoopBack0] quit
[ASBR2] mpls lsr-id 192.3.3.3
# Enable L2VPN.
[ASBR2] l2vpn enable
# Enable global LDP.
[ASBR2] mpls ldp
[ASBR2-ldp] quit
# Configure VLAN-interface 22 (the interface connected to PE 2), and enable LDP on the interface.
[ASBR2] interface vlan-interface 22
[ASBR2-Vlan-interface22] ip address 22.2.2.3 24
[ASBR2-Vlan-interface22] mpls enable
[ASBR2-Vlan-interface22] mpls ldp enable
[ASBR2-Vlan-interface22] quit
# Configure VLAN-interface 26 (the interface connected to ASBR 1), and enable MPLS on the interface.
[ASBR2] interface vlan-interface 26
[ASBR2-Vlan-interface26] ip address 26.2.2.3 24
[ASBR2-Vlan-interface26] mpls enable
[ASBR2-Vlan-interface26] quit
# Configure OSPF for LDP to create LSPs.
[ASBR2] ospf
[ASBR2-ospf-1] area 0
[ASBR2-ospf-1-area-0.0.0.0] network 22.2.2.3 0.0.0.255
[ASBR2-ospf-1-area-0.0.0.0] network 192.3.3.3 0.0.0.0
[ASBR2-ospf-1-area-0.0.0.0] quit
[ASBR2-ospf-1] quit
# Configure BGP to advertise labeled routes on ASBR 2.
[ASBR2] bgp 200
[ASBR2-bgp-default] peer 26.2.2.2 as-number 100
[ASBR2-bgp-default] address-family ipv4 unicast
[ASBR2-bgp-default-ipv4] import-route direct
[ASBR2-bgp-default-ipv4] peer 26.2.2.2 enable
[ASBR2-bgp-default-ipv4] peer 26.2.2.2 route-policy policy1 export
[ASBR2-bgp-default-ipv4] peer 26.2.2.2 label-route-capability
[ASBR2-bgp-default-ipv4] quit
[ASBR2-bgp-default] quit
[ASBR2] route-policy policy1 permit node 1
[ASBR2-route-policy-policy1-1] apply mpls-label
[ASBR2-route-policy-policy1-1] quit
# Create a cross-connect group named vpn1, create a cross-connect named ldp in the group, and create two LDP PWs for the cross-connect to form a multi-segment PW.
[ASBR2] xconnect-group vpn1
[ASBR2-xcg-vpn1] connection ldp
[ASBR2-xcg-vpn1-ldp] peer 192.2.2.2 pw-id 1000
[ASBR2-xcg-vpn1-ldp-192.2.2.2-1000] quit
[ASBR2-xcg-vpn1-ldp] peer 192.4.4.4 pw-id 1000
[ASBR2-xcg-vpn1-ldp-192.4.4.4-1000] quit
[ASBR2-xcg-vpn1-ldp] quit
[ASBR2-xcg-vpn1] quit
6. Configure PE 2:
# Configure an LSR ID.
<PE2> system-view
[PE2] interface loopback 0
[PE2-LoopBack0] ip address 192.4.4.4 32
[PE2-LoopBack0] quit
[PE2] mpls lsr-id 192.4.4.4
# Enable L2VPN.
[PE2] l2vpn enable
# Enable global LDP.
[PE2] mpls ldp
[PE2-ldp] quit
# Configure VLAN-interface 22 (the interface connected to ASBR 1), and enable LDP on the interface.
[PE2] interface vlan-interface 22
[PE2-Vlan-interface22] ip address 22.2.2.1 24
[PE2-Vlan-interface22] mpls enable
[PE2-Vlan-interface22] mpls ldp enable
[PE2-Vlan-interface22] quit
# Configure OSPF for LDP to create LSPs.
[PE2] ospf
[PE2-ospf-1] area 0
[PE2-ospf-1-area-0.0.0.0] network 192.4.4.4 0.0.0.0
[PE2-ospf-1-area-0.0.0.0] network 22.2.2.1 0.0.0.255
[PE2-ospf-1-area-0.0.0.0] quit
[PE2-ospf-1] quit
# Create Ethernet service instance 1000 on Ten-GigabitEthernet 1/1/11 (the interface connected to CE 2).
[PE2] interface ten-gigabitethernet 1/1/11
[PE2-Ten-GigabitEthernet1/1/11] service-instance 1000
[PE2-Ten-GigabitEthernet1/1/11-srv1000] encapsulation s-vid 10
[PE2-Ten-GigabitEthernet1/1/11-srv1000] quit
[PE2-Ten-GigabitEthernet1/1/11] quit
7. Configure CE 2.
<CE2> system-view
[CE2] interface vlan-interface 10
[CE2-Vlan-interface10] ip address 100.1.1.2 24
[CE2-Vlan-interface10] quit
Verifying the configuration
# Verify that a PW has been created on PE 1.
[PE1] display l2vpn pw
Flags: M - main, B - backup, E - ecmp, BY - bypass, H - hub link, S - spoke link
N - no split horizon, A - administration, ABY - ac-bypass
PBY - pw-bypass
Total number of PWs: 1
1 up, 0 blocked, 0 down, 0 defect, 0 idle, 0 duplicate
Xconnect-group Name: vpn1
Peer PWID/RmtSite/SrvID In/Out Label Proto Flag Link ID State
192.2.2.2 1000 1151/1279 LDP M 1 Up
# Verify that two PWs have been created to form a multi-segment PW on ASBR 1.
[ASBR1] display l2vpn pw
Flags: M - main, B - backup, E - ecmp, BY - bypass, H - hub link, S - spoke link
N - no split horizon, A - administration, ABY - ac-bypass
PBY - pw-bypass
Total number of PWs: 2
2 up, 0 blocked, 0 down, 0 defect, 0 idle, 0 duplicate
Xconnect-group Name: vpn1
Peer PWID/RmtSite/SrvID In/Out Label Proto Flag Link ID State
192.1.1.1 1000 1279/1151 LDP M 0 Up
192.3.3.3 1000 1278/1151 LDP M 1 Up
# Verify that two PWs have been created to form a multi-segment PW on ASBR 2.
[ASBR2] display l2vpn pw
Flags: M - main, B - backup, E - ecmp, BY - bypass, H - hub link, S - spoke link
N - no split horizon, A - administration, ABY - ac-bypass
PBY - pw-bypass
Total number of PWs: 2
2 up, 0 blocked, 0 down, 0 defect, 0 idle, 0 duplicate
Xconnect-group Name: vpn1
Peer PWID/RmtSite/SrvID In/Out Label Proto Flag Link ID State
192.2.2.2 1000 1151/1278 LDP M 0 Up
192.4.4.4 1000 1150/1279 LDP M 1 Up
# Verify that a PW has been created on PE 2.
[PE2] display l2vpn pw
Flags: M - main, B - backup, E - ecmp, BY - bypass, H - hub link, S - spoke link
N - no split horizon, A - administration, ABY - ac-bypass
PBY - pw-bypass
Total number of PWs: 1
1 up, 0 blocked, 0 down, 0 defect, 0 idle, 0 duplicate
Xconnect-group Name: vpn1
Peer PWID/RmtSite/SrvID In/Out Label Proto Flag Link ID State
192.3.3.3 1000 1279/1150 LDP M 1 Up
# Verify that CE 1 and CE 2 can ping each other. (Details not shown.)
