Configuring Supervisor Engine Redundancy Using RPR and SSO on Supervisor Engine 7-E and Supervisor Engine 7L-E


Catalyst 4500 series switches allow a standby supervisor engine to take over if the active supervisor engine fails. In software, supervisor engine redundancy is enabled by running the redundant supervisor engine in route processor redundancy (RPR) or stateful switchover (SSO) operating mode.


Note The minimum ROMMON requirement for running SSO and RPR is 15.0(1r)SG1.


This chapter describes how to configure supervisor engine redundancy on the Catalyst 4507R and Catalyst 4510R switches.


Note For information on Cisco nonstop forwarding (NSF) with SSO, see Chapter 11 "Configuring Cisco NSF with SSO Supervisor Engine Redundancy."


This chapter contains these major sections:

About Supervisor Engine Redundancy

About Supervisor Engine Redundancy Synchronization

Supervisor Engine Redundancy Guidelines and Restrictions

Configuring Supervisor Engine Redundancy

Performing a Manual Switchover

Performing a Software Upgrade

Manipulating Bootflash on the Standby Supervisor Engine


Note For complete syntax and usage information for the switch commands used in this chapter, first look at the Cisco Catalyst 4500 Series Switch Command Reference and related publications at this location:

http://www.cisco.com/en/US/products//hw/switches/ps4324/index.html

If the command is not found in the Catalyst 4500 Series Switch Command Reference, it will be found in the larger Cisco IOS library. Refer to the
Catalyst 4500 Series Switch Cisco IOS Command Reference and related publications at this location:

http://www.cisco.com/en/US/products/ps6350/index.html


About Supervisor Engine Redundancy

These sections describe supervisor engine redundancy:

Overview

RPR Operation

SSO Operation

Overview

With supervisor engine redundancy enabled, if the active supervisor engine fails or if a manual switchover is performed, the standby supervisor engine becomes the "new" active supervisor engine. The standby supervisor engine has been automatically initialized with the startup configuration of the active supervisor engine, shortening the switchover time (30 seconds or longer in RPR mode, depending on the configuration; subsecond in SSO mode).

In addition to the reduced switchover time, supervisor engine redundancy supports the following:

Online insertion and removal (OIR) of the supervisor engine.

Supervisor engine redundancy allows OIR of the redundant supervisor engine for maintenance. When the redundant supervisor engine is inserted, the active supervisor engine detects its presence, and the redundant supervisor engine boots into a partially-initialized state in RPR mode and a fully-initialized state in SSO mode.

Software upgrade. (See the "Performing a Software Upgrade" section.)

To minimize down time during software changes on the supervisor engine, load the new image on the standby supervisor engine, and conduct a switchover.

When power is first applied to a switch, the supervisor engine that boots first becomes the active supervisor engine and remains active until a switchover occurs.

A switchover will occur when one or more of the following events take place:

The active supervisor engine fails (due to either hardware or software function) or is removed.

A user forces a switchover.

A user reloads the active supervisor engine.

Table 10-1 provides information about chassis and supervisor engine support for redundancy.

Table 10-1 Chassis and Supervisor Support 

Supported Switch es
Supported Supervisor Engines

WS-C4507R-E, WS-C4510R-E, WS-C4507R+E, WS-C4510R+E

Supervisor Engine 7-E (WS-X45-SUP7-E) and Supervisor Engine 7L-E (WS-X45-SUP7L-E)


RPR Operation

RPR is supported in Cisco IOS-XE Release 3.1.0SG and later releases. When a standby supervisor engine runs in RPR mode, it starts up in a partially-initialized state and is synchronized with the persistent configuration of the active supervisor engine.


Note Persistent configuration includes the following components: startup-config, boot variables, config-register, and VLAN database.


The standby supervisor engine pauses the startup sequence after basic system initialization, and in the event that the active supervisor engine fails, the standby supervisor engine becomes the new active supervisor engine.

In a supervisor engine switchover, traffic is disrupted because in the RPR mode all of the physical ports restart since there is no state maintained between supervisor engines relating to module types and statuses. Upon switchover, when the standby supervisor engine completes its initialization, it will read hardware information directly from the module and become the active supervisor engine.

SSO Operation

SSO is supported in Cisco IOS-XE Release 3.1.0SG and later releases. When a standby supervisor engine runs in SSO mode, the standby supervisor engine starts up in a fully-initialized state and synchronizes with the persistent configuration and the running configuration of the active supervisor engine. It subsequently maintains the state on the protocols listed below, and all changes in hardware and software states for features that support stateful switchover are kept in synchronization. Consequently, it offers zero interruption to Layer 2 sessions in a redundant supervisor engine configuration.

Because the standby supervisor engine recognizes the hardware link status of every link, ports that were active before the switchover will remain active, including the uplink ports. However, because uplink ports are physically on the supervisor engine, they will be disconnected if the supervisor engine is removed.

If the active supervisor engine fails, the standby supervisor engine become active. This newly active supervisor engine uses existing Layer 2 switching information to continue forwarding traffic. Layer 3 forwarding will be delayed until the routing tables have been repopulated in the newly active supervisor engine.

SSO supports stateful switchover of the following Layer 2 features.


Note SSO is not supported if the IOS-XE software is running in the LAN Base mode.


The state of these features is preserved between both the active and standby supervisor engines:

802.3

802.3u

802.3x (Flow Control)

802.3ab (GE)

802.3z (Gigabit Ethernet including CWDM)

802.3ad (LACP)

802.1p (Layer 2 QoS)

802.1q

802.1X (Authentication)

802.1D (Spanning Tree Protocol)

802.3af (Inline power)

PAgP

VTP

Dynamic ARP Inspection

DHCP snooping

IP source guard

IGMP snooping (versions 1 and 2)

DTP (802.1q and ISL)

MST

PVST+

Rapid-PVST

PortFast/UplinkFast/BackboneFast

BPDU guard and filtering

Voice VLAN

Port security

Unicast MAC filtering

ACL (VACLS, PACLS, RACLS)

QOS (DBL)

Multicast storm control/broadcast storm control

SSO is compatible with the following list of features. However, the protocol database for these features is not synchronized between the standby and active supervisor engines:

802.1Q tunneling with Layer 2 Protocol Tunneling (L2PT)

Baby giants

Jumbo frame support

CDP

Flood blocking

UDLD

SPAN/RSPAN

NetFlow

The following features are learned on the standby supervisor engine if the SSO feature is enabled:

All Layer 3 protocols on Catalyst 4500 series switches (Switch Virtual Interfaces)

About Supervisor Engine Redundancy Synchronization

During normal operation, the persistent configuration (RPR and SSO) and the running configuration (SSO only) are synchronized by default between the two supervisor engines. In a switchover, the new active supervisor engine uses the current configuration.


Note You cannot enter CLI commands on the standby supervisor engine console.


These sections describe supervisor engine redundancy synchronization:

RPR Supervisor Engine Configuration Synchronization

SSO Supervisor Engine Configuration Synchronization

RPR Supervisor Engine Configuration Synchronization

Because the standby supervisor engine is only partially initialized in RPR mode, it interacts with the active supervisor engine only to receive configuration changes at startup and upon saving the configuration changes.

When a standby supervisor engine is running in RPR mode, the following events trigger synchronization of the configuration information:

When the standby supervisor engine boots, the auto-sync command synchronizes the persistent configuration. This command is enabled by default. For details, refer to "Synchronizing the Supervisor Engine Configurations" section.

When the active supervisor engine detects the standby supervisor engine, the configuration information is synchronized from the active supervisor engine to the standby supervisor engine. This synchronization overwrites any existing startup configuration file on the standby supervisor engine.

When you make changes to the configuration, you must use the write command to save and synchronize the startup configuration to the standby supervisor engine.

SSO Supervisor Engine Configuration Synchronization

When a standby supervisor engine runs in SSO mode, the following events trigger synchronization of the configuration information:

When the active supervisor detects the standby supervisor engine, synchronization of the persistent and running configuration takes place, allowing the standby supervisor engine to arrive at a fully-initiated state.

When real-time changes occur, the active supervisor engine synchronizes the running-config and (or) the persistent configuration (if necessary) with the standby supervisor engine.

When you change the configuration, you must use the write command to allow the active supervisor engine to save and synchronize the startup configuration to the standby supervisor engine.

Supervisor Engine Redundancy Guidelines and Restrictions

The following guidelines and restrictions apply to supervisor engine redundancy:

If SSO mode cannot be established between the active and standby supervisor engines because of an incompatibility in the configuration file, a mismatched command list (MCL) is generated at the active supervisor engine and a reload into RPR mode is forced for the standby supervisor engine. Subsequent attempts to establish SSO, after removing the offending configuration and rebooting the standby supervisor engine with the exact same image, might cause the C4K_REDUNDANCY-2-IOS_VERSION_CHECK_FAIL and ISSU-3-PEER_IMAGE_INCOMPATIBLE messages to appear because the peer image is listed as incompatible. If the configuration problem can be corrected, you can clear the peer image from the incompatible list with the redundancy config-sync ignore mismatched-commands EXEC command while the peer is in a standby cold (RPR) state. This action allows the standby supervisor engine to boot in standby hot (SSO) state when it reloads.

Here are the steps:


Step 1 Clear the offending configuration (that caused an MCL) while the standby supervisor engine is in standby cold (RPR) state.

Step 2 Enter the redundancy config-sync ignore mismatched-commands EXEC command at the active standby supervisor engine.

Step 3 Perform write memory.

Step 4 Reload the standby supervisor engine with the redundancy reload peer command.


RPR and SSO requires Cisco IOS-XE Release 3.1.0SG and later releases.

SSO is not supported if the IOS-XE software is running in the LAN Base mode.

WS-C4507R-E, WS-C4510R-E, WS-C4507R+E, and WS-C4510R+E are the only Catalyst 4500 series switches that support Supervisor Engine 7-E and Supervisor Engine 7L-E redundancy.

SSO requires both supervisor engines in the chassis to have the same components (model and memory), and to use the same Cisco IOS XE software image.

When you use WS-X45-SUP7-E and WS-X45-SUP7L-E in RPR or SSO mode, only the first two uplinks on each supervisor engine are available. The second two uplinks are unavailable.

The active and standby supervisor engines in the chassis must be in slots 3 and 4 for 7-slot chassis and slot 5 and 6 for 10-slot chassis.

Each supervisor engine in the chassis must have its own flash device and console port connections to operate the switch on its own.

Each supervisor engine must have a unique console connection. Do not connect a Y cable to the console ports.

Supervisor engine redundancy does not provide supervisor engine load balancing.

The Cisco Express Forwarding (CEF) table is cleared on a switchover. As a result, routed traffic is interrupted until route tables reconverge. This reconvergence time is minimal because the SSO feature reduces the supervisor engine redundancy switchover time from 30+ seconds to subsecond, so Layer 3 also has a faster failover time if the switch is configured for SSO.

Static IP routes are maintained across a switchover because they are configured from entries in the configuration file.

Information about Layer 3 dynamic states that is maintained on the active supervisor engine is not synchronized to the standby supervisor engine and is lost on switchover.

If configuration changes on a redundant switch are made through SNMP set operations, the changes are not synchronized to the standby supervisor engine even in SSO mode. You might experience unexpected behavior.

After you configure the switch through SNMP in SSO mode, copy the running-config file to the startup-config file on the active supervisor engine to trigger synchronization of the startup-config file to the standby supervisor engine. Then, reload the standby supervisor engine so that the new configuration is applied on the standby supervisor engine.

You cannot perform configuration changes during the startup (bulk) synchronization. If you attempt to make configuration changes during this process, the following message is generated:

Config mode locked out till standby initializes
 
   

If configuration changes occur at the same time as a supervisor engine switchover, these configuration changes are lost.

If you remove a line card from a redundant switch and initiate an SSO switchover, then reinsert the line card, and all interfaces are shutdown. The rest of the original line card configuration is preserved.

This situation only occurs if a switch had reached SSO before you removed the line card.

Configuring Supervisor Engine Redundancy

These sections describe how to configure supervisor engine redundancy:

Configuring Redundancy

Virtual Console for Standby Supervisor Engine

Synchronizing the Supervisor Engine Configurations

Configuring Redundancy


Note IOS XE software can be booted at three different levels (Enterprise Services, IP Base, and LAN Base), based on the licenses available on the supervisor engine. If you are booting the image in LAN Base mode, only RPR redundancy mode is available.


To configure redundancy, perform this task:

 
Command
Purpose

Step 1 

Switch(config)# redundancy 

Enters redundancy configuration mode.

Step 2 

Switch(config-red)# mode {sso | rpr}

Configures SSO or RPR. When this command is entered, the standby supervisor engine is reloaded and begins to work in SSO or RPR mode.

Step 3 

Switch# show running-config

Verifies that SSO or RPR is configured.

Step 4 

Switch# show redundancy  
[clients | counters | history | states]

Displays the redundancy information (counter, state, and so on) for the active and standby supervisor engines.

This example shows how to configure the system for SSO and display the redundancy facility information:

Switch> enable 
Switch# configure terminal 
Enter configuration commands, one per line. End with CNTL/Z.
Switch(config)# redundancy 
Switch(config-red)# mode sso 
Switch(config-red)# end
 
   
Switch# show redundancy
Redundant System Information :
 
   
------------------------------
       Available system uptime = 10 minutes Switchovers system experienced = 0
              Standby failures = 1
        Last switchover reason = none
 
   
                 Hardware Mode = Duplex
    Configured Redundancy Mode = Stateful Switchover
     Operating Redundancy Mode = Stateful Switchover
              Maintenance Mode = Disabled
                Communications = Up
 
   
Current Processor Information :
------------------------------
               Active Location = slot 3
        Current Software state = ACTIVE
       Uptime in current state = 9 minutes
                 Image Version = Cisco IOS Software, Catalyst 4500 L3 Switch Software 
(cat4500e-UNIVERSALK9-M), Version 15.0(100)XO(1.42), INTERIM SOFTWARE Copyright (c) 
1986-2010 by Cisco Systems, Inc.
Compiled Sun 01-Aug-10 04:12 by gsbuprod
        Configuration register = 0x920
 
   
Peer Processor Information :
------------------------------
              Standby Location = slot 4
        Current Software state = STANDBY HOT
       Uptime in current state = 0 minute
                 Image Version = Cisco IOS Software, Catalyst 4500 L3 Switch Software 
(cat4500e-UNIVERSALK9-M), Version 15.0(100)XO(1.42), INTERIM SOFTWARE Copyright (c) 
1986-2010 by Cisco Systems, Inc.
Compiled Sun 01-Aug-10 04:12 by gsbuprod
        Configuration register = 0x920
 
   

This example shows how to display redundancy facility state information:

Switch# show redundancy states
         my state = 13 -ACTIVE
       peer state =  8 -STANDBY HOT 
             Mode = Duplex
             Unit = Primary
          Unit ID = 3
 
   
  Redundancy Mode (Operational) = Stateful Switchover
   Redundancy Mode (Configured) = Stateful Switchover
               Redundancy State = Stateful Switchover
                   Manual Swact = enabled
 
   
   Communications = Up
 
   
     client count = 64
   client_notification_TMR = 240000 milliseconds
            keep_alive TMR = 9000 milliseconds
          keep_alive count = 1 
      keep_alive threshold = 18 
             RF debug mask = 0   
 
   

This example shows how to change the system configuration from RPR to SSO mode:

Switch(config)# redundancy 
Switch(config-red)# mode
Switch(config-red)# mode sso
Changing to sso mode will reset the standby. Do you want to continue?[confirm]
Switch(config-red)# end
Switch#
*Aug  1 13:11:16: %C4K_REDUNDANCY-3-COMMUNICATION: Communication with the peer Supervisor 
has been lost
*Aug  1 13:11:16: %C4K_REDUNDANCY-3-SIMPLEX_MODE: The peer Supervisor has been lost
 
   

This example shows how to change the system configuration from SSO to RPR mode:

Switch(config)# redundancy 
Switch(config-red)# mode rpr
Changing to rpr mode will reset the standby. Do you want to continue?[confirm]
Switch(config-red)# end
*Aug  1 13:11:16: %C4K_REDUNDANCY-3-COMMUNICATION: Communication with the peer Supervisor 
has been lost
*Aug  1 13:11:16: %C4K_REDUNDANCY-3-SIMPLEX_MODE: The peer Supervisor has been lost

Virtual Console for Standby Supervisor Engine

Catalyst 4500 series switches can be configured with 2 supervisor engines to provide redundancy. When the switch is powered, one of the supervisor engines becomes active and remains active until a switchover occurs. The other supervisor engine remains in standby mode.

Each supervisor engine has its own console port. Access to the standby supervisor engine is possible only through the console port of the standby supervisor engine. Therefore, you must connect to the standby console to access, monitor or debug the standby supervisor.

Virtual Console for Standby Supervisor Engine enables you to access the standby console from the active supervisor engine without requiring a physical connection to the standby console. It uses IPC over EOBC to communicate with the standby supervisor engine and thus emulate the standby console on the active supervisor engine. Only one standby console session is active at any time.

The Virtual Console for Standby Supervisor Engine allows users who are logged onto the active supervisor engine to remotely execute show commands on the standby supervisor engine and view the results on the active supervisor engine. Virtual Console is available only from the active supervisor engine.

You can access the standby virtual console from the active supervisor engine with the attach module, session module, or remote login commands on the active supervisor engine. You must be in privilege EXEC mode (level 15) to run these commands to access the standby console.

Once you enter the standby virtual console, the terminal prompt automatically changes to
hostname-standby-console where hostname is the configured name of the switch. The prompt is restored to the original setting when you exit the virtual console.

You exit the virtual console with the exit or quit commands. When the inactivity period of the terminal on the active supervisor engine where you logged in exceeds the configured idle time, you are automatically logged out of the terminal on the active supervisor engine. In this instance, the virtual console session is also terminated. Virtual console session is also automatically terminated when the standby is rebooted. After the standby boots up, you need to create another virtual console session.

To log in to the standby supervisor engine using a virtual console, do the following:

Switch# session module 4
Connecting to standby virtual console
Type "exit" or "quit" to end this session
 
   
Switch-standby-console# exit
Switch#
 
   

If the standby console is not enabled, the following message appears:

Switch-standby-console#
Standby console disabled.
Valid commands are: exit, logout

Note The standby virtual console provides the standard features that are available from the supervisor console such as command history, command completion, command help and partial command keywords.


The following limitations apply to the standby virtual console:

All commands on the virtual console run to completion. It does not provide the auto-more feature; it behaves as if the terminal length 0 command has been executed. It is also non-interactive. Therefore, a running command cannot be interrupted or aborted by any key sequence on the active supervisor engine. If a command produces considerable output, the virtual console displays it on the supervisor engine screen.

The virtual console is non-interactive. Because the virtual console does not detect the interactive nature of a command, any command that requires user interaction causes the virtual console to wait until the RPC timer aborts the command.

The virtual console timer is set to 60 seconds. The virtual console returns to its prompt after 60 seconds. During this time, you cannot abort the command from the key board. You must wait for the timer to expire before you continue.

You cannot use virtual console to view debug and syslog messages that are being displayed on the standby supervisor engine. The virtual console only displays the output of commands that are executed from the virtual console. Other information that is displayed on the real standby console does not appear on the virtual console.

Synchronizing the Supervisor Engine Configurations

To manually synchronize the configurations used by the two supervisor engines, perform this task on the active supervisor engine:

 
Command
Purpose

Step 1 

Switch(config)# redundancy

Enters redundancy configuration mode.

Step 2 

Switch(config-red)# main-cpu

Enters main-cpu configuration submode.

Step 3 

Switch(config-r-mc)# auto-sync {startup-config | 
config-register | bootvar | standard}

Synchronizes the configuration elements.

Step 4 

Switch(config-r-mc)# end

Returns to privileged EXEC mode.

Step 5 

Switch# copy running-config startup-config

Synchronizes the running configuration in dynamic random-access memory (DRAM) to the startup configuration file in NVRAM.

Note This step is not required to synchronize the running configuration file in (DRAM).


Note Configuration changes made to the active supervisor engine through SNMP are not synchronized to the redundant supervisor engine. For information on how to handle this situation, see the "Supervisor Engine Redundancy Guidelines and Restrictions" section.



Note The auto-sync command controls the synchronization of the config-reg, bootvar, and startup/private configuration files only. The calendar and VLAN database files are always synchronized when they change. In SSO mode, the running-config is always synchronized.


This example shows how to reenable the default automatic synchronization feature using the auto-sync standard command to synchronize the startup-config and config-register configuration of the active supervisor engine with the standby supervisor engine. Updates for the boot variables are automatic and cannot be disabled.

Switch(config)# redundancy
Switch(config-red)# main-cpu
Switch(config-r-mc)# auto-sync standard
Switch(config-r-mc)# end
Switch# copy running-config startup-config

Note To manually synchronize individual elements of the standard auto-sync configuration, disable the default automatic synchronization feature.



Note When you configure the auto-sync standard, the individual sync options such as no auto-sync startup-config are ignored.


This example shows how to disable default automatic synchronization and allow only automatic synchronization of the config-registers of the active supervisor engine to the standby supervisor engine, while disallowing synchronization of the startup configuration:

Switch(config)# redundancy
Switch(config-red)# main-cpu
Switch(config-r-mc)# no auto-sync standard
Switch(config-r-mc)# auto-sync config-register
Switch(config-r-mc)# end

Performing a Manual Switchover

This section describes how to perform a manual switchover (from the active supervisor engine to the standby supervisor engine) for test purposes. We recommend that you perform a manual switchover prior to deploying SSO in your production environment.


Note This discussion assumes that SSO has been configured as the redundant mode.


To perform a manual switchover, perform this task on the active supervisor engine:

 
Command
Purpose

Step 1 

Switch# show redundancy

Verifies that the peer state is in the standby hot state.

See the example of the show redundancy states command on page 6-10.

Step 2 

Switch# redundancy force-switchover

Launches switchover from the active supervisor engine to the standby supervisor engine.

Be aware of these usage guidelines:

force a switchover, the redundant supervisor engine must be in a standby hot (SSO) or standby cold (RPR) state. You can verify the state with the show redundancy command. If the state is not standby hot or standby cold, the redundancy force-switchover command will not execute.

Use the redundancy force-switchover command, rather than the reload command, to initiate a switchover. The redundancy force-switchover command will first check that the redundant supervisor engine is in the correct state. If you issue the reload command and the status is not standby hot or standby cold, the reload command will reset the current supervisor engine and the peer supervisor may not be able to take over because it was not in a terminal state (standby hot or cold).

After a normal switchover, you might want to make the supervisor engine in a lower slot number of the chassis the active supervisor engine. Use the show module command to see which slot contains the active supervisor engine, and force another switchover if necessary.

Performing a Software Upgrade

This is useful only if IOS -XE software is running in LAN Base mode. For Enterprise Services or IP Base mode, use ISSU to upgrade software for both RPR and SSO redundant mode.

The software upgrade procedure supported by supervisor engine redundancy allows you to reload the Cisco IOS software image on the redundant supervisor engine, and once complete, reload the active supervisor engine once.

To perform a software upgrade, perform this task:

 
Command
Purpose

Step 1 

Switch# copy source_device:source_filename 
slot0:target_filename
 
        

Or:

Switch# copy source_device:source_filename 
bootflash:target_filename 

Copies the new Cisco IOS-XE software image to bootflash on the supervisor engine.

Step 2 

Switch# copy source_device:source_filename 
slaveslot0:target_filename
 
        

Or:

Switch# copy source_device:source_filename 
slavebootflash:target_filename 

Copies the new image to a device on the standby supervisor engine (such as slavebootflash and slaveslot0).

Step 3 

Switch# config terminal
Switch(config)# config-register 0x2
Switch(config)# boot system flash 
device:file_name 
 
        
 
        

Configures the supervisor engines to boot the new image.

If your system was configured to autoboot an earlier image, issue the following command string to boot the new image instead:
no boot system flash device:old_file_name

Step 4 

Switch(config)# redundancy

Enters redundancy configuration mode.

Step 5 

Switch(config-red)# main-cpu

Enters main-cpu configuration submode.

Step 6 

Switch(config-r-mc)# auto-syn standard

Synchronizes the configuration elements.

Step 7 

Switch(config-r-mc)# end

Returns to privileged EXEC mode.

Step 8 

Switch# copy running-config start-config

Saves the configuration.

Step 9 

Switch# redundancy reload peer

Reloads the standby supervisor engine and brings it back online (using the new release of the Cisco IOS-XE software).

Step 10 

Switch# redundancy force-switchover

Conducts a manual switchover to the standby supervisor engine. The standby supervisor engine becomes the new active supervisor engine using the new Cisco IOS-XE software image.

The old active supervisor engine reboots with the new image and becomes the standby supervisor engine.

This example shows how to perform a software upgrade:

Switch# config terminal
Switch(config)# config-register 0x2
Switch(config)# boot system flash 
bootflash0:cat4500e-universalk9.SSA.03.01.00.150.1.XO.bin
Switch(config)# redundancy
Switch(config-red)# main-cpu
Switch(config-r-mc)# auto-syn standard
Switch(config-r-mc)# end
Switch# copy running-config start-config
Switch# redundancy reload peer
Switch# redundancy force-switchover 
Switch#
 
   

This example illustrates how to verify that the running configuration on the active supervisor engine has successfully synchronized with the redundant supervisor engine:

Switch# config terminal
Switch(config)# redundancy
Switch(config-red)# main-cpu
Switch(config-r-mc)# auto-sync standard
4d01h: %C4K_REDUNDANCY-5-CONFIGSYNC: The bootvar has been successfully synchronized to the 
standby supervisor
4d01h: %C4K_REDUNDANCY-5-CONFIGSYNC: The config-reg has been successfully synchronized to 
the standby supervisor
4d01h: %C4K_REDUNDANCY-5-CONFIGSYNC: The startup-config has been successfully synchronized 
to the standby supervisor
4d01h: %C4K_REDUNDANCY-5-CONFIGSYNC: The private-config has been successfully synchronized 
to the standby supervisor
 
   

The example above shows that the boot variable, the config-register, and the startup configuration from the active supervisor engine have successfully synchronized to the redundant supervisor engine.

Manipulating Bootflash on the Standby Supervisor Engine


Note The console port on the standby supervisor engine is not available.


To manipulate the standby supervisor engine bootflash, perform one or more of the following tasks:

Command
Purpose
Switch# dir slaveslot0:target_filename 

or
Switch# dir slavebootflash:target_filename

Lists the contents of the slot0: device on the standby supervisor engine.

Lists the contents of the bootflash: device on the standby supervisor engine.

Switch# delete slaveslot0:target_filename
 
        
or 
Switch# delete slavebootflash:target_filename 

Deletes specific files from the slot0: device on the standby supervisor engine.

Deletes specific files from the bootflash: device on the standby supervisor engine.

Switch# squeeze slaveslot0:target_filename
 
        
or 
Switch# squeeze slavebootflash:target_filename 

Squeezes the slot0: device on the standby supervisor engine.

Squeezes the bootflash: device on the standby supervisor engine.

Switch# format slaveslot0:target_filename
 
        
or 
Switch# format slavebootflash:target_filename 

Formats the slot0: device on the standby supervisor engine.

Formats the bootflash: device on the standby supervisor engine.

Switch# copy source_device:source_filename 
slaveslot0:target_filename
 
        
or 
Switch# copy source_device:source_filename 
slavebootflash:target_filename 

Copies a file from the active supervisor engine to the slot0: device on the standby supervisor engine.

Copies a file to the bootflash: device on a standby supervisor engine.

Note Source could be the active supervisor engine or a TFTP server.