Configuring Wireless High Availability

Finding Feature Information

Your software release may not support all the features documented in this module. For the latest feature information and caveats, see the release notes for your platform and software release.

Use Cisco Feature Navigator to find information about platform support and Cisco software image support. To access Cisco Feature Navigator, go to http:/​/​www.cisco.com/​go/​cfn. An account on Cisco.com is not required.

Information about High Availability

The high availability feature is enabled by default when the switches are connected using the stack cable and the Cisco StackWise-160 technology is enabled. You cannot disable it; however, you can initiate a manual graceful-switchover using the command line interface to use the high availability feature enabled in the switch.

In Cisco Wireless LAN Controllers, high availability is achieved with redundancy.

In Cisco Wireless LAN Controllers, redundancy is achieved in two ways— n+1 and AP SSO redundancy.

Keepalive messages are sent and received between the active and standby controllers.
  • If the standby controller does not respond, a new standby controller is elected.

  • If the active controller does not respond, the standby controller becomes the active controller.

In addition, hello messages are sent and received by all stack members.
  • If a stack member does not respond, that member is removed from the stack.

  • If the standby controller does not respond, a new standby controller is elected.

  • If the active controller does not respond, the standby controller becomes the active controller.

Information About Redundancy

In case of n+1 redundancy, access points are configured with primary, secondary, and tertiary controllers. When the primary controller fails, depending upon the number of access points managed by a controller, the access point fails over to the secondary controller. In case of AP SSO redundancy, once the primary controller is unavailable, the access points re-discovers the controller and reestablishes the CAPWAP tunnel with the secondary controller. However, all clients must disconnect and a re-authentication is performed to rejoin the controller.

You can configure primary, secondary, and tertiary controllers for a selected access point and a selected controller.

In an ideal high availability deployment, you can have access points connected to primary and secondary controllers and one controller can remain with out connection to any access points. This way the controller that does not have any access points can take over when a failure occurs and resume services of active controller.

Configuring Redundancy in Access Points

You must use the commands explained in this section to configure primary, secondary, or tertiary controllers for a selected access point.

Before you begin

SUMMARY STEPS

  1. conf t
  2. ap capwap backup primary
  3. ap capwap backup secondary
  4. ap capwap backup tertiary

DETAILED STEPS

  Command or Action Purpose
Step 1

conf t

Example:

Controller # conf t

Configures the terminal

Step 2

ap capwap backup primary

Example:

Controller # ap capwap backup primary WLAN-Controller-A

Configures the primary controller for the selected access point.

Step 3

ap capwap backup secondary

Example:

Controller # ap capwap backup secondary WLAN-Controller-B

Configures the secondary controller for the selected access point.

Step 4

ap capwap backup tertiary

Example:

Controller # ap capwap backup tertiary WLAN-Controller-C

Configures the tertiary controller for the selected access point.

What to do next

Once you complete configuration of the primary, secondary, and tertiary controllers for a selected access point, you must verify the configuration using the show ap name AP-NAME command. For more details on, show ap name AP-NAME command, see the Lightweight Access Point Configuration Guide for Cisco Wireless LAN Controller.

Configuring Heartbeat Messages

Hearbeat messages enable you to reduce the controller failure detection time. When a failure occurs, a switchover from active to hot standby happens after the controller waits for the heartbeat timer. If the controller does not function within the heartbeat time, then the standby takes over as then active controller. Ideally the access point generates three heartbeat messages within the time out value specified, and when the controller does not respond within the timeout value, the standby controller takes over as active. You can specify the timeout value depending on your network. Ideally the timer value is not a higher value as some chaos will occur while performing a switchover. This section explains on how to configure heartbeat interval between the controller and the access points using a timeout value to reduce the controller failure detection time.

Before you begin

SUMMARY STEPS

  1. conf t
  2. ap capwap timers heartbeat-timeout

DETAILED STEPS

  Command or Action Purpose
Step 1

conf t

Example:

controller # conf t

Configures the terminal.

Step 2

ap capwap timers heartbeat-timeout

Example:

controller #  ap capwap timers heartbeat-timeout 

Configures the heartbeat interval between the controller and access points. The timeout value ranges from 1 to 30.

Information about Access Point Stateful Switch Over

An Access Point Stateful Switch Over (AP SSO) implies that all the access point sessions are switched over state-fully and the user session information is maintained during a switchover, and access points continue to operate in network with no loss of sessions, providing improved network availability. The active switch in the stack is equipped to perform all network functions, including IP functions and routing information exchange. The switch supports 1000 access points and 12000 clients.

However, all the clients are de-authenticated and need to be re-associated with the new active switch except for the locally switched clients in FlexConnect mode when a switchover occurs.

Once a redundancy pair is formed while in a stack, high availability is enabled, which includes that access points continue to remain connected during an active-to-standby switchover.


Note

You can not disable AP SSO while in a switch stack once the switches form a redundant pair.

Initiating Graceful Switchover

To perform a manual switchover and to use the high availability feature enabled in the switch, execute the redundancy force-switchover command. This command initiates a graceful switchover from the active to the standby switch.

Switch# redundancy force-switchover
System configuration has been modified. Save ? [yes/no] : yes
Building configuration …
Preparing for switchover …
Compressed configuration from 14977 bytes to 6592 bytes[OK]This will reload the active unit and force switchover to standby[confirm] : y

Configuring EtherChannels for High Availability

The LAG, or an EtherChannel, bundles all the existing ports in both the standby and active units into a single logical port to provide an aggregate bandwidth of 60 Gbps. The creation of an EtherChannel enables protection against failures. The EtherChannels or LAGs created are used for link redundancy to ensure high availability of access points.

For more details on configuring EtherChannel, and Etherchannel modes, see the Layer 2 (Link Aggregation) Configuration Guide, Cisco IOS XE Release 3SE (Cisco WLC 5700 Series)

Procedure


Step 1

Connect two switches that are in powered down state using the stack cable.

Step 2

Power up and perform a boot on both switches simultaneously or power and boot one switch.

The switches boot up successfully, and form a high availability pair.

Step 3

Configure EtherChannel or LAG on the units.

Step 4

Use the show etherchannel summary command to view the status of the configured EtherChannel.

On successful configuration, all the specified ports will be bundled in a single channel and listed in the command output of show etherchannel summary .

Step 5

Execute the show ap uptime command to verify the connected access points.


Configuring LACP

SUMMARY STEPS

  1. configure terminal
  2. interface port-channel number
  3. lacp max-bundle number
  4. lacp port-priority number
  5. switchport backup interface po2
  6. end
  7. show etherchannel summary
  8. show interfaces switchport backup

DETAILED STEPS

  Command or Action Purpose
Step 1

configure terminal

Example:

Switch# configure terminal
Enters global configuration mode.
Step 2

interface port-channel number

Example:

Switch(config)# interface Port-channel Po2
Enters port-channel interface configuration mode.
Step 3

lacp max-bundle number

Example:

Switch(config-if)# lacp max-bundle 6

Defines the maximum number of active bundled LACP ports allowed in a port channel. The value ranges from 1 to 8.

Step 4

lacp port-priority number

Example:

Switch(config-if)# lacp port-priority 4

Specifies port priority to be configured on the port using LACP. The value ranges from 0 to 65535.

Step 5

switchport backup interface po2

Example:

Switch(config-if)# switchport backup interface Po2

Specifies an interface as the backup interface.

Step 6

end

Exits the interface and configuration mode.
Step 7

show etherchannel summary

Example:

Switch# show etherchannel summary

Displays a summary of EtherChannel properties.

Step 8

show interfaces switchport backup

Example:

Switch# show interfaces switchport backup

Displays summary of backup EtherChannel properties.

Troubleshooting High Availability

Access the Standby Console

You can only access the console of the active switch in a stack. To access the standby switch, use the following commands.

Before you begin

Use this functionality only under supervision of Cisco Support.

SUMMARY STEPS

  1. configure terminal
  2. service internal
  3. redundancy
  4. main-cpu
  5. standby console enable
  6. exit

DETAILED STEPS

  Command or Action Purpose
Step 1

configure terminal

Example:

Switch# configure terminal
Enters global configuration mode.
Step 2

service internal

Example:

Switch(config)# service internal

Enables Cisco IOS debug commands.

Step 3

redundancy

Example:

Switch(config)# redundancy

Enters redundancy configuration mode.

Step 4

main-cpu

Example:

Switch(config)# main-cpu

Enters the redundancy main configuration submode.

Step 5

standby console enable

Example:

Switch(config)# standby console enable

Enables the standby console.

Step 6

exit

Example:

Switch(config)# exit

Exits the configuration mode.

Before a Switchover

A switchover happens when the active switch fails; however, while performing a manual switchover, you can execute these commands to initiate a successful switchover:

SUMMARY STEPS

  1. show redundancy states
  2. show switch detail
  3. show platform ses states
  4. show ap summary
  5. show capwap detail
  6. show dtls database-brief
  7. show power inline

DETAILED STEPS

  Command or Action Purpose
Step 1

show redundancy states

Example:

Switch# show redundancy states

Displays the high availability role of the active and standby switches.

Step 2

show switch detail

Example:

Switch# show switch detail

Display physical property of the stack. Verify if the physical states of the stacks are "Ready" or "Port".

Step 3

show platform ses states

Example:

Switch# show platform ses states

Displays the sequences of the stack manager.

Step 4

show ap summary

Example:

Switch# show ap summary

Displays all the access points in the active and standby switches.

Step 5

show capwap detail

Example:

Switch# show capwap detail

Displays the details of the CAPWAP tunnel in the active and standby switches.

Step 6

show dtls database-brief

Example:

Switch# show dtls database-brief

Displays DTLS details in the active and standby switches.

Step 7

show power inline

Example:

Switch# show power inline

Displays the power on Ethernet power state.

Note 
When a failover occurs, the standby controller must be in a standby-hot state and the redundant port in a terminal state in SSO for successful switchover to occur.

After a Switchover

This section defines the steps that you must perform to ensure that successful switchover from the active to standby switch is performed. On successful switchover of the standby switch as active, all access points connected to the active need to re-join the standby (then active) switch.

SUMMARY STEPS

  1. show ap uptime
  2. show wireless summary
  3. show wcdb database all
  4. show power inline

DETAILED STEPS

  Command or Action Purpose
Step 1

show ap uptime

Example:

Switch# show ap uptime

Verify if the uptime of the access point after the switchover is large enough.

Step 2

show wireless summary

Example:

Switch# show wireless summary

Display the clients connected in the active switch.

Step 3

show wcdb database all

Example:

Switch# show wcdb database all

Display if the client has reached the uptime.

Step 4

show power inline

Example:

Switch# show power inline

Display the power over Ethernet power state.

Viewing Redundancy Switchover History (GUI)

Procedure


Step 1

Click Monitor > Controller > Redundancy > States.

The Redundancy States page is displayed. The values for the following parameters are displayed in the page:

Parameter Description
Index Displays the index number of the of the redundant unit.
Previous Active Displays the Switches that was active before.
Current Active Displays the Switches that is currently active.
Switch Over Time Displays the system time when the switchover occurs.
Switch Over Reason Displays the cause of the switchover.
Step 2

Click Apply.


Viewing Switchover States (GUI)

Procedure


Step 1

Click Monitor > Controller > Redundancy > States.

The Redundancy States page is displayed. The values for the following parameters are displayed in the page:

Parameter Description
My State Shows the state of the active CPU Switch module. Values are as follows:
  • Active
  • Standby HOT
  • Disable
Peer State Displays the state of the peer (or standby) CPU Switch module. Values are as follows:
  • Standby HOT
  • Disable
Mode Displays the current state of the redundancy peer. Values are as follows:
  • Simplex— Single CPU switch module
  • Duplex— Two CPU switch modules
Unit ID Displays the unit ID of the CPU switch module.
Redundancy Mode (Operational) Displays the current operational redundancy mode supported on the unit.
Redundancy Mode (Configured) Displays the current configured redundancy mode supported on the unit.
Redundancy State Displays the current functioning redundancy state of the unit. Values are as follows:
  • SSP
  • Not Redundant
Manual SWACT Displays whether manual switchovers have been enabled without the force option.
Communications Displays whether communications are up or down between the two CPU Switch modules.
Client Count Displays the number of redundancy subsystems that are registered as RF clients.
Client Notification TMR Displays, in milliseconds, the time that an internal RF timer has for notifying RF client subsystems.
Keep Alive TMR Displays, in milliseconds, the time interval the RF manager has for sending keep-alive messages to its peer on the standby CPU switch module.
Keep Alive Count Displays the number of keep-alive messages sent without receiving a response from the standby CPU Switch module.
Keep Alive Threshold Displays the threshold for declaring that interprocessor communications are down when keep-alive messages have been enabled (which is the default).
RF Debug Mask Displays an internal mask used by the RF to keep track of which debug modes are on.
Step 2

Click Apply.


Monitoring the Switch Stack

Table 1. Commands for Displaying Stack Information

Command

Description

show switch

Displays summary information about the stack, including the status of provisioned switches and switches in version-mismatch mode.

show switch stack-member-number

Displays information about a specific member.

show switch detail

Displays detailed information about the stack.

show switch neighbors

Displays the stack neighbors.

show switch stack-ports [summary ]

Displays port information for the stack.

show redundancy

Displays the redundant system and the current processor information. The redundant system information includes the system uptime, standby failures, switchover reason, hardware, configured and operating redundancy mode. The current processor information displayed includes the active location, the software state, the uptime in the current state and so on.

show redundancy state

Displays all the redundancy states of the active and standby switches.

LACP Configuration: Example

This example shows how to configure LACP and to verify creation of the LACP bundle and the status:

Switch(config)# !
interface TenGigabitEthernet1/0/1
 switchport mode trunk
 channel-group 1 mode active
 lacp port-priority 10
 ip dhcp snooping trust
!
interface TenGigabitEthernet1/0/2
 switchport mode trunk
 channel-group 1 mode active
 lacp port-priority 10
 ip dhcp snooping trust
!
interface TenGigabitEthernet1/0/3
 switchport mode trunk
 channel-group 1 mode active
 lacp port-priority 10
 ip dhcp snooping trust
!
interface TenGigabitEthernet1/0/4
 switchport mode trunk
 channel-group 1 mode active
 ip dhcp snooping trust
!
interface TenGigabitEthernet1/0/5
 switchport mode trunk
 channel-group 1 mode active
 ip dhcp snooping trust
!
interface TenGigabitEthernet1/0/6
 switchport mode trunk
 channel-group 1 mode active
 ip dhcp snooping trust
!
interface TenGigabitEthernet2/0/1
 switchport mode trunk
 channel-group 1 mode active
 lacp port-priority 10
 ip dhcp snooping trust
!
interface TenGigabitEthernet2/0/2
 switchport mode trunk
 channel-group 1 mode active
 lacp port-priority 10
 ip dhcp snooping trust
!
interface TenGigabitEthernet2/0/3
 switchport mode trunk
 channel-group 1 mode active
 lacp port-priority 10
 ip dhcp snooping trust
!
interface TenGigabitEthernet2/0/4
 switchport mode trunk
 channel-group 1 mode active
 ip dhcp snooping trust
!
interface TenGigabitEthernet2/0/5
 switchport mode trunk
 channel-group 1 mode active
 ip dhcp snooping trust
!
interface TenGigabitEthernet2/0/6
 switchport mode trunk
 channel-group 1 mode active
 ip dhcp snooping trust
!
interface Vlan1
 no ip address
 ip igmp version 1
 shutdown
!

Switch#  show etherchannel summary
		 
		Flags:  D - down        P - bundled in port-channel
        I - stand-alone s - suspended
        H - Hot-standby (LACP only)
        R - Layer3      S - Layer2
        U - in use      f - failed to allocate aggregator

        M - not in use, minimum links not met
        u - unsuitable for bundling
        w - waiting to be aggregated
        d - default port


Number of channel-groups in use: 1
Number of aggregators:           1

Group  Port-channel  Protocol    Ports
------+-------------+-----------+-----------------------------------------------
1      Po1(SU)         LACP      Te1/0/1(P)  Te1/0/2(P)  Te1/0/3(P)
                                 Te1/0/4(H)  Te1/0/5(H)  Te1/0/6(H)
                                 Te2/0/1(P)  Te2/0/2(P)  Te2/0/3(P)
                                 Te2/0/4(H)  Te2/0/5(H)  Te2/0/6(H)

This example shows the switch backup interface pairs:

Switch# show interfaces switchport backup

Switch Backup Interface Pairs:

Active Interface        Backup Interface        State
------------------------------------------------------------------------
Port-channel1             Port-channel2             Active Standby/Backup Up

This example shows the summary of the EtherChannel configured in the switch:

Switch# show ethernet summary

Flags:  D - down        P - bundled in port-channel
        I - stand-alone s - suspended
        H - Hot-standby (LACP only)
        R - Layer3      S - Layer2
        U - in use      f - failed to allocate aggregator

        M - not in use, minimum links not met
        u - unsuitable for bundling
        w - waiting to be aggregated
        d - default port


Number of channel-groups in use: 2
Number of aggregators:           2

Group  Port-channel  Protocol    Ports
------+-------------+-----------+-----------------------------------------------
1      Po1(SU)         LACP      Te1/0/1(P)  Te1/0/2(P)  Te1/0/3(P)
                                 Te1/0/4(P)  Te1/0/5(P)  Te1/0/6(P)
2      Po2(SU)         LACP      Te2/0/1(P)  Te2/0/2(P)  Te2/0/3(P)
                                 Te2/0/4(P)  Te2/0/5(P)  Te2/0/6(P)

Flex Link Configuration: Example

This example shows how to configure flex link and to verify creation and the status of the created link:

Switch(config)# !
interface Port-channel1
 description Ports 1-6 connected to NW-55-SW
 switchport mode trunk
 switchport backup interface Po2
 switchport backup interface Po2 preemption mode forced
 switchport backup interface Po2 preemption delay 1
 ip dhcp snooping trust
!
interface Port-channel2
 description Ports 7-12connected to NW-55-SW
 switchport mode trunk
 ip dhcp snooping trust
!
interface GigabitEthernet0/0
 vrf forwarding Mgmt-vrf
 no ip address
 negotiation auto
!
interface TenGigabitEthernet1/0/1
 switchport mode trunk
 channel-group 1 mode on
 ip dhcp snooping trust
!
interface TenGigabitEthernet1/0/2
 switchport mode trunk
 channel-group 1 mode on
 ip dhcp snooping trust
!
interface TenGigabitEthernet1/0/3
 switchport mode trunk
 channel-group 1 mode on
 ip dhcp snooping trust
!
interface TenGigabitEthernet1/0/4
 switchport mode trunk
 channel-group 1 mode on
 ip dhcp snooping trust
!
interface TenGigabitEthernet1/0/5
 switchport mode trunk
 channel-group 1 mode on
 ip dhcp snooping trust
!
interface TenGigabitEthernet1/0/6
 switchport mode trunk
 channel-group 1 mode on
 ip dhcp snooping trust
!
interface TenGigabitEthernet2/0/1
 switchport mode trunk
 channel-group 2 mode on
 ip dhcp snooping trust
!
interface TenGigabitEthernet2/0/2
 switchport mode trunk
 channel-group 2 mode on
 ip dhcp snooping trust
!
interface TenGigabitEthernet2/0/3
 switchport mode trunk
 channel-group 2 mode on
 ip dhcp snooping trust
!
interface TenGigabitEthernet2/0/4
 switchport mode trunk
 channel-group 2 mode on
 ip dhcp snooping trust
!
interface TenGigabitEthernet2/0/5
 switchport mode trunk
 channel-group 2 mode on
 ip dhcp snooping trust
!
interface TenGigabitEthernet2/0/6
 switchport mode trunk
 channel-group 2 mode on
 ip dhcp snooping trust
!
interface Vlan1
 no ip address


		Switch#  show etherchannel summary
		 
		Flags:  D - down        P - bundled in port-channel
        I - stand-alone s - suspended
        H - Hot-standby (LACP only)
        R - Layer3      S - Layer2
        U - in use      f - failed to allocate aggregator

        M - not in use, minimum links not met
        u - unsuitable for bundling
        w - waiting to be aggregated
        d - default port


Number of channel-groups in use: 2
Number of aggregators:           2

Group  Port-channel  Protocol    Ports
------+-------------+-----------+-----------------------------------------------
1      Po1(SU)          -        Te1/0/1(P)  Te1/0/2(P)  Te1/0/3(P)
                                 Te1/0/4(P)  Te1/0/5(P)  Te1/0/6(P)
2      Po2(SU)          -        Te2/0/1(P)  Te2/0/2(P)  Te2/0/3(D)
                                 Te2/0/4(P)  Te2/0/5(P)  Te2/0/6(P)