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Note | Stacking is supported only on Catalyst 2960-S switches running the LAN base image. |
Flex Links are a pair of a Layer 2 interfaces (controller ports or port channels) where one interface is configured to act as a backup to the other. The feature provides an alternative solution to the Spanning Tree Protocol (STP). Users can disable STP and still retain basic link redundancy. Flex Links are typically configured in service provider or enterprise networks where customers do not want to run STP on the controller. If the controller is running STP, Flex Links are not necessary because STP already provides link-level redundancy or backup.
You configure Flex Links on one Layer 2 interface (the active link) by assigning another Layer 2 interface as the Flex Links or backup link. On controllers, the Flex Links can be on the same controller or on another controller in the stack. When one of the links is up and forwarding traffic, the other link is in standby mode, ready to begin forwarding traffic if the other link shuts down. At any given time, only one of the interfaces is in the linkup state and forwarding traffic. If the primary link shuts down, the standby link starts forwarding traffic. When the active link comes back up, it goes into standby mode and does not forward traffic. STP is disabled on Flex Links interfaces.
In the following figure, ports 1 and 2 on controller A are connected to uplink switches B and C. Because they are configured as Flex Links, only one of the interfaces is forwarding traffic; the other is in standby mode. If port 1 is the active link, it begins forwarding traffic between port 1 and switch B; the link between port 2 (the backup link) and switch C is not forwarding traffic. If port 1 goes down, port 2 comes up and starts forwarding traffic to switch C. When port 1 comes back up, it goes into standby mode and does not forward traffic; port 2 continues forwarding traffic.
You can also configure a preemption function, specifying the preferred port for forwarding traffic. For example, you can configure the Flex Links pair with preemption mode. In the scenario shown, when port 1 comes back up and has more bandwidth than port 2, port 1 begins forwarding traffic after 60 seconds. Port 2 becomes the standby port. You do this by entering the switchport backup interface preemption mode bandwidth and switchport backup interface preemption delay interface configuration commands.
If a primary (forwarding) link goes down, a trap notifies the network management stations. If the standby link goes down, a trap notifies the users.
Flex Links are supported only on Layer 2 ports and port channels, not on VLANs or on Layer 3 ports.
VLAN Flex Links load balancing allows users to configure a Flex Links pair so that both ports simultaneously forward the traffic for some mutually exclusive VLANs. For example, if Flex Links ports are configured for 1 to 100 VLANs, the traffic of the first 50 VLANs can be forwarded on one port and the rest on the other port. If one of the ports fail, the other active port forwards all the traffic. When the failed port comes back up, it resumes forwarding traffic in the preferred VLANs. In addition to providing the redundancy, this Flex Links pair can be used for load balancing. Flex Links VLAN load balancing does not impose any restrictions on uplink controllers.
Multicast fast convergence reduces the multicast traffic convergence time after a Flex Links failure. Multicast fast convergence is implemented by a combination of learning the backup link as an mrouter port, generating IGMP reports, and leaking IGMP reports.
In a typical multicast network, there is a querier for each VLAN. A controller deployed at the edge of a network has one of its Flex Links ports receiving queries. Flex Links ports are also always forwarding at any given time.
A port that receives queries is added as an mrouter port on the controller. An mrouter port is part of all the multicast groups learned by the controller. After a changeover, queries are received by the other Flex Links port. The other Flex Links port is then learned as the mrouter port. After changeover, multicast traffic then flows through the other Flex Links port. To achieve faster convergence of traffic, both Flex Links ports are learned as mrouter ports whenever either Flex Links port is learned as the mrouter port. Both Flex Links ports are always part of multicast groups.
Although both Flex Links ports are part of the groups in normal operation mode, all traffic on the backup port is blocked. The normal multicast data flow is not affected by the addition of the backup port as an mrouter port. When the changeover happens, the backup port is unblocked, allowing the traffic to flow. In this case, the upstream multicast data flows as soon as the backup port is unblocked.
When the backup link comes up after the changeover, the upstream new distribution controller does not start forwarding multicast data, because the port on the upstream router, which is connected to the blocked Flex Links port, is not part of any multicast group. The reports for the multicast groups were not forwarded by the downstream controller because the backup link is blocked. The data does not flow on this port, until it learns the multicast groups, which occurs only after it receives reports.
The reports are sent by hosts when a general query is received, and a general query is sent within 60 seconds in normal scenarios. When the backup link starts forwarding, to achieve faster convergence of multicast data, the downstream controller immediately sends proxy reports for all the learned groups on this port without waiting for a general query.
To achieve multicast traffic convergence with minimal loss, a redundant data path must be set up before the Flex Links active link goes down. This can be achieved by leaking only IGMP report packets on the Flex Links backup link. These leaked IGMP report messages are processed by upstream distribution routers, so multicast data traffic gets forwarded to the backup interface. Because all incoming traffic on the backup interface is dropped at the ingress of the access controller, no duplicate multicast traffic is received by the host. When the Flex Links active link fails, the access controller starts accepting traffic from the backup link immediately. The only disadvantage of this scheme is that it consumes bandwidth on the link between the distribution controllers and on the backup link between the distribution and access controllers. This feature is disabled by default and can be configured by using the switchport backup interface interface-id multicast fast-convergence command.
When this feature has been enabled at changeover, the controller does not generate the proxy reports on the backup port, which became the forwarding port.
The MAC address-table move update feature allows the controller to provide rapid bidirectional convergence when a primary (forwarding) link goes down and the standby link begins forwarding traffic.
In the above figure, three wireless clients connect to an access point and communicate to the controller. The PC connected to switch A communicates with the wireless clients through the data path from port 3 to port 1. If the MAC address-table move update feature is not configured on the controller and port 3 goes down, port 4 starts forwarding traffic. However, for a short time the wireless clients will not be able to pass any traffic to the PC as port 3 is down.
If the MAC address-table move update feature is configured and enabled on the controller, and port 3 goes down, the controller sends a MAC address-table move update packet (MMU) from port 4. This MMU packet carries all the MAC addresses of the wireless clients. Switch C gets this packet on port 4 and immediately learns the MAC addresses of the wireless clients, which reduces the reconvergence time. The PC transmits data to the wireless clients using the path from port 2 to port 4. Switch C also bridges the same MMU packet in the VLAN so that all the switches in the network will update the MAC address table to ensure that the next packet to any wireless client towards controller comes on the right path. The controller learns only the MAC addresses of the wireless clients.
3.
switchport backup interface interface-id
4.
switchport backup interface interface-id preemption mode [forced | bandwidth | off]
5.
switchport backup interface interface-id preemption delay delay-time
Command or Action | Purpose | |
---|---|---|
Step 1 | configure terminal Example: Controller# configure terminal | |
Step 2 | interface interface-id Example: Controller (config)# interface gigabitethernet2/0/6 | Specifies the interface, and enters interface configuration mode. The interface can be a physical Layer 2 interface or a port channel (logical interface). |
Step 3 | switchport backup interface interface-id prefer vlan vlan-range Example: Controller (config-if)# switchport backup interface gigabitethernet2/0/8 prefer vlan 2 | Configures a physical Layer 2 interface (or port channel) as part of a Flex Links pair with the interface and specifies the VLANs carried on the interface. The VLAN ID range is 1 to 4094. |
Step 4 | end Example: Controller (config-if)# end |
Command or Action | Purpose | |
---|---|---|
Step 1 | configure
terminal
Example: Controller# configure terminal | |
Step 2 | interface
interface-id
Example: Controller#interface gigabitethernet1/0/1 |
Specifies the interface, and enters interface configuration mode. The interface can be a physical Layer 2 interface or a port channel (logical interface). |
Step 3 | Use one of the following:
Example: Controller(config-if)# switchport backup interface gigabitethernet0/2 mmu primary vlan 2 |
Configures a physical Layer 2 interface (or port channel), as part of a Flex Links pair with the interface. The MAC address-table move update VLAN is the lowest VLAN ID on the interface. Configure a physical Layer 2 interface (or port channel) and specifies the VLAN ID on the interface, which is used for sending the MAC address-table move update. When one link is forwarding traffic, the other interface is in standby mode. |
Step 4 | end
Example: Controller(config-if)# end | |
Step 5 | mac address-table
move update transmit
Example:
Controller(config)#
mac address-table move update
transmit
|
Enables the access controller to send MAC address-table move updates to other controllers in the network if the primary link goes down and the controller starts forwarding traffic through the standby link. |
Step 6 | end
Example: Controller(config)# end | Returns to privileged EXEC mode. |
Command or Action | Purpose | |
---|---|---|
Step 1 |
configure terminal Example:
Controller# configure terminal
|
Enters global configuration mode |
Step 2 | mac address-table move update receive Example:
Controller (config)# mac address-table move update receive
| Enables the controller to obtain and processes the MAC address-table move updates. |
Step 3 | end Example:
Controller (config)# end
| Returns to privileged EXEC mode. |
Command |
Purpose |
---|---|
Displays the Flex Links backup interface configured for an interface or all the configured Flex Links and the state of each active and backup interface (up or standby mode). |
|
show ip igmp profile address-table move update profile-id |
Displays the specified IGMP profile or all the IGMP profiles defined on the controller. |
Displays the MAC address-table move update information on the controller. |
This example shows how to verify the configuration after you configure an interface with a backup interface:
Controller# show interface switchport backup Switch Backup Interface Pairs: Active Interface Backup Interface State ------------------------------------------------------------------------ GigabitEthernet1/0/1 GigabitEthernet1/0/2 Active Up/Backup Standby
This example shows how to verify the configuration after you configure the preemption mode as forced for a backup interface pair:
Controller# show interface switchport backup detail Switch Backup Interface Pairs: Active Interface Backup Interface State ------------------------------------------------------------------------ GigabitEthernet1/0/211 GigabitEthernet1/0/2 Active Up/Backup Standby Interface Pair : Gi1/0/1, Gi1/0/2 Preemption Mode : forced Preemption Delay : 50 seconds Bandwidth : 100000 Kbit (Gi1/0/1), 100000 Kbit (Gi1/0/2) Mac Address Move Update Vlan : auto
In the following example, VLANs 1 to 50, 60, and 100 to 120 are configured on the controller:
Controller(config)# interface gigabitethernet 2/0/6 Controller(config-if)# switchport backup interface gigabitethernet 2/0/8 prefer vlan 60,100-120
When both interfaces are up, Gi2/0/8 forwards traffic for VLANs 60 and 100 to 120 and Gi2/0/6 forwards traffic for VLANs 1 to 50.
Controller# show interfaces switchport backup Switch Backup Interface Pairs: Active Interface Backup Interface State ------------------------------------------------------------------------ GigabitEthernet2/0/6 GigabitEthernet2/0/8 Active Up/Backup Standby Vlans Preferred on Active Interface: 1-50 Vlans Preferred on Backup Interface: 60, 100-120
When a Flex Links interface goes down (LINK_DOWN), VLANs preferred on this interface are moved to the peer interface of the Flex Links pair. In this example, if interface Gi2/0/6 goes down, Gi2/0/8 carries all VLANs of the Flex Links pair.
Controller# show interfaces switchport backup Switch Backup Interface Pairs: Active Interface Backup Interface State ------------------------------------------------------------------------ GigabitEthernet2/0/6 GigabitEthernet2/0/8 Active Down/Backup Up Vlans Preferred on Active Interface: 1-50 Vlans Preferred on Backup Interface: 60, 100-120
When a Flex Links interface comes up, VLANs preferred on this interface are blocked on the peer interface and moved to the forwarding state on the interface that has just come up. In this example, if interface Gi2/0/6 comes up, VLANs preferred on this interface are blocked on the peer interface Gi2/0/8 and forwarded on Gi2/0/6.
Controller# show interfaces switchport backup Switch Backup Interface Pairs: Active Interface Backup Interface State ------------------------------------------------------------------------ GigabitEthernet2/0/6 GigabitEthernet2/0/8 Active Up/Backup Standby Vlans Preferred on Active Interface: 1-50 Vlans Preferred on Backup Interface: 60, 100-120 Controller# show interfaces switchport backup detail Switch Backup Interface Pairs: Active Interface Backup Interface State ------------------------------------------------------------------------ FastEthernet1/0/3 FastEthernet1/0/4 Active Down/Backup Up Vlans Preferred on Active Interface: 1-2,5-4094 Vlans Preferred on Backup Interface: 3-4 Preemption Mode : off Bandwidth : 10000 Kbit (Fa1/0/3), 100000 Kbit (Fa1/0/4) Mac Address Move Update Vlan : auto
This example shows how to verify the configuration after you configure an access controller to send MAC address-table move updates:
Controller# show mac address-table move update Switch-ID : 010b.4630.1780 Dst mac-address : 0180.c200.0010 Vlans/Macs supported : 1023/8320 Default/Current settings: Rcv Off/On, Xmt Off/On Max packets per min : Rcv 40, Xmt 60 Rcv packet count : 5 Rcv conforming packet count : 5 Rcv invalid packet count : 0 Rcv packet count this min : 0 Rcv threshold exceed count : 0 Rcv last sequence# this min : 0 Rcv last interface : Po2 Rcv last src-mac-address : 000b.462d.c502 Rcv last switch-ID : 0403.fd6a.8700 Xmt packet count : 0 Xmt packet count this min : 0 Xmt threshold exceed count : 0 Xmt pak buf unavail cnt : 0 Xmt last interface : None
These are configuration examples for learning the other Flex Links port as the mrouter port when Flex Links is configured on GigabitEthernet1/0/11 and GigabitEthernet1/0/12, and output for the show interfaces switchport backup command:
Controller# configure terminal Enter configuration commands, one per line. End with CNTL/Z. Controller(config)# interface GigabitEthernet1/0/11 Controller(config-if)# switchport trunk encapsulation dot1q Controller(config-if)# switchport mode trunk Controller(config-if)# switchport backup interface GigabitEthernet1/0/12 Controller(config-if)# exit Controller(config)# interface GigabitEthernet1/0/12 Controller(config-if)# switchport trunk encapsulation dot1q Controller(config-if)# switchport mode trunk Controller(config-if)# end Controller# show interfaces switchport backup detail Switch Backup Interface Pairs: Active Interface Backup Interface State GigabitEthernet1/0/11 GigabitEthernet1/0/12 Active Up/Backup Standby Preemption Mode : off Multicast Fast Convergence : Off Bandwidth : 100000 Kbit (Gi1/0/11), 100000 Kbit (Gi1/0/12) Mac Address Move Update Vlan : auto
This output shows a querier for VLANs 1 and 401, with their queries reaching the controller through GigabitEthernet1/0/11:
Controller# show ip igmp snooping querier Vlan IP Address IGMP Version Port ------------------------------------------------------------- 1 1.1.1.1 v2 Gi1/0/11 401 41.41.41.1 v2 Gi1/0/11
This example is output for the show ip igmp snooping mrouter command for VLANs 1 and 401:
Controller# show ip igmp snooping mrouter Vlan ports ---- ----- 1 Gi1/0/11(dynamic), Gi1/0/12(dynamic) 401 Gi1/0/11(dynamic), Gi1/0/12(dynamic)
Similarly, both Flex Links ports are part of learned groups. In this example, GigabitEthernet2/0/11 is a receiver/host in VLAN 1, which is interested in two multicast groups:
Controller# show ip igmp snooping groups Vlan Group Type Version Port List ----------------------------------------------------------------------- 1 228.1.5.1 igmp v2 Gi1/0/11, Gi1/0/12, Gi2/0/11 1 228.1.5.2 igmp v2 Gi1/0/11, Gi1/0/12, Gi2/0/11
When a host responds to the general query, the controller forwards this report on all the mrouter ports. In this example, when a host sends a report for the group 228.1.5.1, it is forwarded only on GigabitEthernet1/0/11, because the backup port GigabitEthernet1/0/12 is blocked. When the active link, GigabitEthernet1/0/11, goes down, the backup port, GigabitEthernet1/0/12, begins forwarding.
As soon as this port starts forwarding, the controller sends proxy reports for the groups 228.1.5.1 and 228.1.5.2 on behalf of the host. The upstream router learns the groups and starts forwarding multicast data. This is the default behavior of Flex Links. This behavior changes when the user configures fast convergence using the switchport backup interface gigabitEthernet 1/0/12 multicast fast-convergence command. This example shows turning on this feature:
Controller# configure terminal Enter configuration commands, one per line. End with CNTL/Z. Controller(config)# interface gigabitEthernet 1/0/11 Controller(config-if)# switchport backup interface gigabitEthernet 1/0/12 multicast fast-convergence Controller(config-if)# exit Controller# show interfaces switchport backup detail Switch Backup Interface Pairs: Active Interface Backup Interface State ------------------------------------------------------------------------ GigabitEthernet1/0/11 GigabitEthernet1/0/12 Active Up/Backup Standby Preemption Mode : off Multicast Fast Convergence : On Bandwidth : 100000 Kbit (Gi1/0/11), 100000 Kbit (Gi1/0/12) Mac Address Move Update Vlan : auto
This output shows a querier for VLAN 1 and 401 with their queries reaching the controller through GigabitEthernet1/0/11:
Controller# show ip igmp snooping querier Vlan IP Address IGMP Version Port ------------------------------------------------------------- 1 1.1.1.1 v2 Gi1/0/11 401 41.41.41.1 v2 Gi1/0/11
This is output for the show ip igmp snooping mrouter command for VLAN 1 and 401:
Controller# show ip igmp snooping mrouter Vlan ports ---- ----- 1 Gi1/0/11(dynamic), Gi1/0/12(dynamic) 401 Gi1/0/11(dynamic), Gi1/0/12(dynamic)
Similarly, both the Flex Links ports are a part of the learned groups. In this example, GigabitEthernet2/0/11 is a receiver/host in VLAN 1, which is interested in two multicast groups:
Controller# show ip igmp snooping groups Vlan Group Type Version Port List ----------------------------------------------------------------------- 1 228.1.5.1 igmp v2 Gi1/0/11, Gi1/0/12, Gi2/0/11 1 228.1.5.2 igmp v2 Gi1/0/11, Gi1/0/12, Gi2/0/11
Whenever a host responds to the general query, the controller forwards this report on all the mrouter ports. When you turn on this feature through the command-line port, and when a report is forwarded by the controller on GigabitEthernet1/0/11, it is also leaked to the backup port GigabitEthernet1/0/12. The upstream router learns the groups and starts forwarding multicast data, which is dropped at the ingress because GigabitEthernet1/0/12 is blocked. When the active link, GigabitEthernet1/0/11, goes down, the backup port, GigabitEthernet1/0/12, begins forwarding. You do not need to send any proxy reports as the multicast data is already being forwarded by the upstream router. By leaking reports to the backup port, a redundant multicast path has been set up, and the time taken for the multicast traffic convergence is very minimal.
Related Topic | Document Title |
---|---|
Layer 2 command reference |
Layer 2 Command Reference (Cisco WLC 5700 Series) |
switchport backup interface command |
Interface Command Reference (Cisco WLC 5700 Series) |
Description | Link |
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To help you research and resolve system error messages in this release, use the Error Message Decoder tool. |
https://www.cisco.com/cgi-bin/Support/Errordecoder/index.cgi |
Standard/RFC | Title |
---|---|
None |
— |
MIB | MIBs Link |
---|---|
All supported MIBs for this release. |
To locate and download MIBs for selected platforms, Cisco IOS releases, and feature sets, use Cisco MIB Locator found at the following URL: |
Description | Link |
---|---|
The Cisco Support website provides extensive online resources, including documentation and tools for troubleshooting and resolving technical issues with Cisco products and technologies. To receive security and technical information about your products, you can subscribe to various services, such as the Product Alert Tool (accessed from Field Notices), the Cisco Technical Services Newsletter, and Really Simple Syndication (RSS) Feeds. Access to most tools on the Cisco Support website requires a Cisco.com user ID and password. |
Release |
Modification |
---|---|
Cisco IOS XE 3.2SE |
This feature was introduced. |
Cisco IOS XE 3.3SE |
Support for multicast fast convergence with Flex Links failover was added. |