Cisco Systems RSP8 manual Configuring High System Availability, HSA Active and Standby Operation

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Configuring High System Availability

Configuring High System Availability

This section describes high system availability (HSA), a feature that enables a router to continue processing and forwarding packets after a planned or unplanned outage.

It includes the following topics:

HSA Active and Standby Operation, page 25

HSA Implementation Methods, page 26

HSA System Requirements, page 27

HSA Configuration Task List, page 27

Monitoring and Maintaining HSA Operation, page 40

HSA is the system default when two RSP8s, or an RSP8 and an RSP16 (one designated as the “active” and the other as the “standby”) are installed in a router and the active RSP8 fails. The standby RSP8 takes over in this situation, known as a “cold standby.” The router restarts without manual intervention (for example, without inserting a new RSP) by rebooting with the standby RSP. The standby has its own image and configuration file and acts as a single processor.

Caution To ensure proper functioning of the standby RSP8 in the event of an active RSP8 failure, the standby RSP8 should have the same boot image, the same ROM monitor, and the same DRAM configuration as the active RSP8.

Note An RSP8 can interoperate with another RSP8, or with an RSP16. It cannot interoperate with an RSP1, an RSP2, or an RSP4/4+. In the following text, you can substitute references to two RSP8s with an RSP8 and an RSP16.

When two new RSP8s (or an RSP8 and an RSP16) are installed at the same time, the RSP that occupies the first even RSP slot on the router is the active (normally the RSP16 if the RSP8 is used in conjunction with the RSP16), and the RSP that occupies the odd RSP slot is the standby. If a crash has occurred, the RSP in the odd slot becomes the active and the RSP in the even slot becomes the standby.

HSA is supported on the following routers: Cisco 7507, Cisco 7507-MX, Cisco 7513, and

Cisco 7513-MX. HSA is not supported on the Cisco 7505 or the Cisco 7576 routers.

The cold standby procedure, from initial failure to first packet transmission, currently takes approximately eight to ten minutes.

For more complete HSA configuration information, refer to the Cisco IOS Configuration Fundamentals Configuration Guide and the Cisco IOS Configuration Fundamentals Command Reference publications, which are available online, on the Cisco Documentation CD-ROM, or as printed copies.

HSA Active and Standby Operation

During HSA operation, the active RSP8 card functions as if it were a single processor, controlling all functions of the router. The standby RSP8 card does nothing but actively monitor the active RSP8 for failure.

When the standby RSP8 detects a nonfunctional active RSP8, the standby resets itself and takes part in active-standby arbitration. Active-standby arbitration is a ROM monitor process that determines which RSP8 card is the active and which is the standby upon startup (or reboot).

Route Switch Processor (RSP8) Installation and Configuration Guide

 

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Contents Document Contents Cisco.com, Obtaining Documentation, Related DocumentationTopics discussed in this section are Product DescriptionRSP8-Horizontal Front-Panel View Monitoring interface and environmental statusU12 Flash Eprom ROMmon Bus connectors Auxiliary portShows the memory components on the RSP8 Memory ComponentsType Size Quantity Description Location Jumpers There are no user-configurable jumpers on the RSP8LEDs Flash Memory Cards and Flash DisksSerial Ports PC Card SlotsLED Label Color State Indication Lists the physical specifications for the RSP8 SpecificationsSpecifications System SoftwareSafety Guidelines Installation PrerequisitesSafety Warnings Installation Prerequisites Electrical Equipment Guidelines Telephone Wiring GuidelinesPreventing Electrostatic Discharge Damage Chassis Slot and Dram Requirements Compatibility RequirementsMemory Requirements Hardware Prerequisites Software PrerequisitesMicrocode Requirements List of Parts and ToolsRemoving the RSP8 Installing the RSP8Ejector Levers and Captive Installation Screw Replacing the RSP8 Handling the RSP8 During Removal and Installation Connecting to the Auxiliary Port Connecting a Console TerminalUsing the Y-Cables for Console and Auxiliary Connections Shows the console Y-cable and shows the auxiliary Y-cable Restarting the SystemInstalling the RSP8 Router show version Using the Exec Command Interpreter Configuring the Router for a Single RSP8HSA Active and Standby Operation Configuring High System AvailabilityHSA Implementation Methods HSA System Requirements HSA Configuration Task ListCommand Purpose Specifying the Default Standby RSPRouter# configure terminal Router# copy system running-config nvramstartup-configEnsuring that Both RSPs Contain the Same System Image Router# show controller cbus Ensuring that Both RSPs Contain the Same Microcode ImageRouter# copy bootflashfilename slot0filename Router# dir slavebootflash slaveslot0 slaveslot1Slot1filename slavebootslotfilename Determines whether the standby RSP contains the same Router# copy source bootflash slot0 slot1Copies a different system image to the active RSP Upgrading to a New Software Version Example Now view the standby software image location and version BootflashRouter# copy tftp slot0rsp-pv-mz.120-22.3.S1 Routerconfig# config-register 0x010F Routerconfig# boot system tftp rsp-pv-mz.120-23.SBacking Up with an Older Software Version Example ANB Delete the rsp-pv-mz.120-22.3.S1image from the standby RSP Router# show bootflashRouter# delete slaveslot0rsp-pv-mz.120-22.3.S1 Router# copy system running-config startup-config Manually Setting Environment Variables on the Standby RSPRouterconfig# slave sync config Router# copy running-config startup-configMonitoring and Maintaining HSA Operation Routerconfig# hw-module slot imageInformation under that RSP’s ROM monitor control Specifies which image the standby runsHigh Availability Feature Overview Enabling High Availability FeaturesRouter# slave sync config Enabling High Availability Features Hardware and Software Prerequisites Installation ProceduresEnabling the Router This completes the procedure to enable the routerCopying an Image onto an RSP Router# copy tftp slaveslot slot-number Router# copy tftp slot slot-numberConfiguring RPR and RPR+ Setting the Config-Register Boot VariableRouterconfig# boot system flash Router# show versionRouter# hw-module sec-cpu reset Routerconfig# hw-module slot slot-numberimage file-specVerifying RPR and RPR+ Configuring RPR and RPR+ ExampleRouter# show redundancy Configuring a Stateful Switchover SSO Configuration file Saves the configuration changes to the startupVerifying SSO Router# show redundancy client Router# show redundancy states my state = 13 -ACTIVEConfiguring CEF NSF Configuring Nonstop Forwarding NSFConfiguring BGP NSF Configuring IS-IS NSF Configuring Ospf NSFAs-number Graceful-restartSeconds adjacency Verifying CEF NSFRouter# show ip bgp neighbors Verifying BGP NSFThis example, note the presence of NSF restart enabled Running-config commandVerifying Ospf NSF Verifying IS-IS NSFNetworking device NSF Troubleshooting Tips Troubleshooting NSF FeaturesBGP NSF Neighbor Device Configuration Example BGP NSF Configuration ExampleOspf NSF Configuration Example IS-IS NSF Configuration ExamplePerforming a Fast Software Upgrade Specifies the image to be used by the standby RSP at Routerconfig# hw-module slot slot-number imageName of the image of the standby RSP Fast Software Upgrade Example Configuring SlcrRouter# redundancy force-switchover Routerconfig# service single-slot-reload-enableSlcr Configuration Example RPR, RPR+, SSO, and FSU Troubleshooting TipsSlcr Troubleshooting Tips Disabling SlcrSystem Power LEDs Troubleshooting the InstallationMonitoring and Maintaining the Active and Standby RSPs Verifying LEDsNormal RSP8 LEDsVerifying System Startup Sequence Troubleshooting the Installation Troubleshooting a Failed RSP8 Troubleshooting a Router That is Failing to BootSaving and Retrieving a Configuration File Maintenance InformationReloading a Failed RSP Displaying a Stack Trace of an RSPRouter# ping Using the ping Command to Ensure ConnectivitySection on page 24 to enable the privileged level Copying the Configuration FileMight include the name or address of a default file server Copy to this fileRouter# show startup-config Retrieving the Configuration File Replacing and Upgrading Dram DIMMs Sdram Dimm Product Numbers Quantity Dram Sockets TotalsPolarization notch Removing DIMMsInserting the Dimm Installing New DIMMsChecking the RSP Memory Upgrade Recovering a Lost PasswordInitialize the router using the i command as follows Pin Signal Direction Description Console Port SignalsReference Information Female DB-25 Pins Male DB-25 Pins Signal Description Auxiliary Port SignalsConsole and Auxiliary Y-Cable Pinouts Male DB-25 Pins Female DB-25 Pins Signal Description Software Configuration Register SettingsP1-5 J1-5 and J2-5 P1-7 J1-7 and J2-7 Ground P1-8 J1-8 and J2-8Stays at the system bootstrap prompt Boot Field MeaningBoots the first system image in onboard Flash memory Bit Number Hexadecimal MeaningRouterconfig# config-register 0xvalue Changing SettingsBit Meanings Tftp flash filenameAction/Filename Bit Routerconfig# boot system flash devicefilename Enabling a Boot from Flash MemoryBit Address net host Baud BitEnabling a Boot from the Flash Disk System# copy running-config startup-config Using Flash MemoryObtaining Documentation Cisco.comDocumentation CD-ROM Obtaining Technical AssistanceOrdering Documentation Documentation FeedbackTAC Case Priority Definitions Cisco TAC Website Opening a TAC CaseObtaining Additional Publications and Information Copyright 2004 Cisco Systems, Inc. All rights reserved
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