- Preface
- Configuring Profiles on the Cisco IOS XR Software
- Configuring Secure Domain Routers on the Cisco IOS XR Software
- Upgrading and Managing Cisco IOS XR Software
- Configuring Disk Backups and Disk Mirroring on the Cisco IOS XR Software
- Software Entitlement on the Cisco IOS XR Software
- Managing the Router Hardware
- Upgrading FPD
- Configuring Manageability
- Configuring Call Home on the Cisco IOS XR Software
- Implementing NTP
- Implementing Object Tracking on the Cisco IOS XR Software
- Implementing Physical and Virtual Terminals
- Implementing SNMP
- Configuring Periodic MIB Data Collection and Transfer on the Cisco IOS XR Software
- Implementing CDP
- Index
- Prerequisites for Managing Router Hardware
- Displaying Hardware Status
- Displaying SDR Hardware Version Information
- Displaying System Hardware Version Information
- Displaying Software and Hardware Information
- Displaying SDR Node IDs and Status
- Displaying Router Node IDs and Status
- Displaying Router Environment Information
- Displaying RP Redundancy Status
- Displaying Field-Programmable Device Compatibility
- Displaying Hardware Image Compatibility
- RP Redundancy and Switchover
- Reloading, Shutting Down, or Power Cycling a Node
- Flash Disk Recovery
- Using Controller Commands to Manage Hardware Components
- Formatting Hard Drives, Flash Drives, and Other Storage Devices
- Removing and Replacing Cards
- Upgrading the CPU Controller Bits
- Additional References
Managing the Router Hardware
This chapter describes the command-line interface (CLI) techniques and commands used to manage and configure the hardware components of a router running the Cisco IOS XR software.
For complete descriptions of the commands listed in this module, see Additional References. To locate documentation for other commands that might appear in the course of performing a configuration task, search online in Cisco IOS XR Commands Master List for the Cisco XR 12000 Series Router.
|
Release |
Modification |
|---|---|
|
Release 3.2 |
This feature was introduced. Logical router (LR) was first supported. |
|
Release 3.3.0 |
The term logical router (LR) was changed to secure domain router (SDR). |
|
Release 3.5.0 |
Flash disk recovery was implemented. |
This module contains the following topics:
- Prerequisites for Managing Router Hardware
- Displaying Hardware Status
- RP Redundancy and Switchover
- Reloading, Shutting Down, or Power Cycling a Node
- Flash Disk Recovery
- Using Controller Commands to Manage Hardware Components
- Formatting Hard Drives, Flash Drives, and Other Storage Devices
- Removing and Replacing Cards
- Upgrading the CPU Controller Bits
- Additional References
Prerequisites for Managing Router Hardware
You must be in a user group associated with a task group that includes the proper task IDs. The command reference guides include the task IDs required for each command. If you suspect user group assignment is preventing you from using a command, contact your AAA administrator for assistance.
Displaying Hardware Status
This section describes how to display different types of hardware status information.
- Displaying SDR Hardware Version Information
- Displaying System Hardware Version Information
- Displaying Software and Hardware Information
- Displaying SDR Node IDs and Status
- Displaying Router Node IDs and Status
- Displaying Router Environment Information
- Displaying RP Redundancy Status
- Displaying Field-Programmable Device Compatibility
- Displaying Hardware Image Compatibility
Displaying SDR Hardware Version Information
To display hardware version information for the components assigned to a secure domain router (SDR), connect to the appropriate designated secure domain router shelf controller (DSDRSC) and enter the show diag command in EXEC mode. The displayed information includes the card serial number and the ROMMON software version.
The syntax for the show diag command in EXEC mode is:
show diag [node-id | details | summary]
In the following example, the show diag command displays information for all nodes in the SDR:
RP/0/0/CPU0:router(admin)# show diag
Tue Jan 13 12:13:34.254 PST DST
SLOT 0 (RP/LC 0): Cisco 12000 Series - Multi-Service Blade
MAIN: type 150, 800-25972-02 rev A0 dev 0
HW config: 0x00 SW key: 00-00-00
PCA: 73-9289-04 rev A0 ver 3
HW version 1.0 S/N SAD11360218
MBUS: Embedded Agent
Test hist: 0x00 RMA#: 00-00-00 RMA hist: 0x00
DIAG: Test count: 0x00000000 Test results: 0x00000000
FRU: Linecard/Module: 12000-ServEngCard
L3 Engine: Service Engine - ISE OC192 (10 Gbps)
MBUS Agent Software version 4.4 (RAM) (ROM version is 4.4)
Using CAN Bus A
ROM Monitor version 1.3
Fabric Downloader version used 3.2 (ROM version is 3.2)
Primary clock is CSC0
Board State is IOS-XR RUN
Last Reset Reason: Initial load
Insertion time: Mon Jan 5 21:58:33 2009 (1w0d ago)
DRAM size: 2147483648 bytes
FrFab SDRAM size: 1610612736 bytes
ToFab SDRAM size: 268435456 bytes
0 resets since restart/fault forgive
SLOT 1 (RP/LC 1): Cisco 12000 Series - Multi-Service Blade
MAIN: type 150, 800-25972-02 rev A0 dev 90070
HW config: 0x00 SW key: 00-00-00
PCA: 73-9289-04 rev A0 ver 3
HW version 1.0 S/N SAD1124079R
MBUS: Embedded Agent
Test hist: 0x00 RMA#: 00-00-00 RMA hist: 0x00
DIAG: Test count: 0x00000000 Test results: 0x00000000
FRU: Linecard/Module: 12000-ServEngCard
L3 Engine: Service Engine - ISE OC192 (10 Gbps)
MBUS Agent Software version 4.4 (RAM) (ROM version is 4.4)
Using CAN Bus A
ROM Monitor version 1.3
Fabric Downloader version used 3.2 (ROM version is 3.2)
Primary clock is CSC0
Board State is IOS-XR RUN
Last Reset Reason: Card ungraceful reboot
Insertion time: Mon Jan 5 22:33:51 2009 (1w0d ago)
DRAM size: 2147483648 bytes
FrFab SDRAM size: 1610612736 bytes
ToFab SDRAM size: 268435456 bytes
0 resets since restart/fault forgive
SLOT 2 (RP/LC 2): Cisco 12000 Series SPA Interface Processor- 601
MAIN: type 149, 68-2647-01 rev A0 dev 85437
HW config: 0x20 SW key: 00-00-00
PCA: 73-9607-04 rev A0 ver 4
HW version 1.0 S/N SAD10330441
MBUS: Embedded Agent
Test hist: 0x00 RMA#: 00-00-00 RMA hist: 0x00
DIAG: Test count: 0x00000000 Test results: 0x00000000
FRU: Linecard/Module: 12000-SIP-601
Route Memory: MEM-LC5-2048=
Packet Memory: MEM-LC5-PKT-512=
L3 Engine: 5 (MultiRate) - ISE OC192 (10 Gbps)
Operational rate mode: 10 Gbps
MBUS Agent Software version 4.4 (RAM) (ROM version is 4.4)
Using CAN Bus A
ROM Monitor version 17.1
Fabric Downloader version used 4.7 (ROM version is 4.7)
Primary clock is CSC0
Board State is IOS-XR RUN
Last Reset Reason: Initial load
Insertion time: Mon Jan 5 21:58:33 2009 (1w0d ago)
DRAM size: 2147483648 bytes
FrFab SDRAM size: 268435456 bytes
ToFab SDRAM size: 268435456 bytes
0 resets since restart/fault forgive
SPA Information:
subslot 0/2/0: SPA-4XOC3-POS-V2 (0x526), status is ok
subslot 0/2/1: SPA-IPSEC-2G-2 (0x549), status is ok
subslot 0/2/2: SPA-8X1FE (0x4c5), status is ok
subslot 0/2/3: Empty
SLOT 4 (RP/LC 4): Cisco 12000 Series SPA Interface Processor- 601
MAIN: type 149, 68-2647-02 rev C0 dev 0
HW config: 0x20 SW key: 00-00-00
PCA: 73-9607-05 rev B0 ver 4
HW version 1.0 S/N SAD112709D6
MBUS: Embedded Agent
Test hist: 0x00 RMA#: 00-00-00 RMA hist: 0x00
DIAG: Test count: 0x00000000 Test results: 0x00000000
FRU: Linecard/Module: 12000-SIP-601
Route Memory: MEM-LC5-2048=
Packet Memory: MEM-LC5-PKT-512=
L3 Engine: 5 (MultiRate) - ISE OC192 (10 Gbps)
Operational rate mode: 10 Gbps
MBUS Agent Software version 4.4 (RAM) (ROM version is 4.4)
Using CAN Bus A
ROM Monitor version 17.1
Fabric Downloader version used 4.7 (ROM version is 4.7)
Primary clock is CSC0
Board State is IOS-XR RUN
Last Reset Reason: Initial load
Insertion time: Mon Jan 5 21:58:33 2009 (1w0d ago)
DRAM size: 2147483648 bytes
FrFab SDRAM size: 268435456 bytes
ToFab SDRAM size: 268435456 bytes
0 resets since restart/fault forgive
SPA Information:
subslot 0/4/0: SPA-2X1GE-V2 (0x50b), status is ok
subslot 0/4/1: SPA-2XOC48POS/RPR (0x46f), status is ok
subslot 0/4/2: SPA-2CHT3-CE-ATM (0x4fc), status is ok
subslot 0/4/3: SPA-4XT3/E3 (0x40b), status is ok
SLOT 5 (RP/LC 5): Cisco 12000 Series Performance Route Processor 2
MAIN: type 96, 800-23469-03 rev B0 dev 0
HW config: 0x10 SW key: 00-00-00
PCA: 73-8812-06 rev A0 ver 5
HW version 0.0 S/N SAD091702LB
MBUS: MBUS Agent (1) 73-8048-07 rev A0 dev 0
HW version 0.1 S/N SAL0852811R
Test hist: 0x00 RMA#: 00-00-00 RMA hist: 0x00
DIAG: Test count: 0x00000000 Test results: 0x00000000
FRU: Linecard/Module: PRP-2
Route Memory: MEM-PRP/LC-2048=
MBUS Agent Software version 4.4 (RAM) (ROM version is 3.54)
Using CAN Bus A
ROM Monitor version 1.17dev(0.5)
Primary clock is CSC0
Board State is IOS-XR RUN
Insertion time: Mon Jan 5 21:58:33 2009 (1w0d ago)
DRAM size: 2147483648 bytes
0 resets since restart/fault forgive
In the following example, the show diag command displays information for a single node:
RP/0/0/CPU0:router# show diag 0/2/1
Tue Jan 13 12:14:15.844 PST DST
SUBSLOT 0/2/1 (SPA-IPSEC-2G-2): IPSec Shared Port Adapter with 2 Gbps DES/3DES/AES
Product Number : SPA-IPSEC-2G-2
Version Identifier (VID) : V01
PCA Serial Number : JAB1043053B
Top Assy. Part Number : 68-2721-02
Top Assy. Revision : A0
Hardware Revision : 1.0
CLEI Code : IP9IAAVCAA
Operational Status : ok
Displaying System Hardware Version Information
To display hardware version information for all or some of the components assigned in a system, connect to the designated shelf controller (DSC) and enter the show diag command in administration EXEC mode. When this command is entered in administration EXEC mode, you can display information on RPs, line cards, and system components such as the chassis, fan trays, and power supplies.
 Note | If you enter the show diag command in EXEC mode, the software displays only the hardware assigned to the SDR to which you are connected. |
The syntax for the show diag command in administration EXEC mode is:
show diag [node-id | chassis | details | fans | memory | power-supply | summary]
 Tip | For information on the software version, use the show version command. |
In the following example, the show diag command displays information for all nodes in the system:
RP/0/0/CPU0:router(admin)# show diag
Tue Jan 13 12:47:57.509 PST DST
SLOT 0 (RP/LC 0): Cisco 12000 Series - Multi-Service Blade
MAIN: type 150, 800-25972-02 rev A0 dev 0
HW config: 0x00 SW key: 00-00-00
PCA: 73-9289-04 rev A0 ver 3
HW version 1.0 S/N SAD11360218
MBUS: Embedded Agent
Test hist: 0x00 RMA#: 00-00-00 RMA hist: 0x00
DIAG: Test count: 0x00000000 Test results: 0x00000000
FRU: Linecard/Module: 12000-ServEngCard
L3 Engine: Service Engine - ISE OC192 (10 Gbps)
MBUS Agent Software version 4.4 (RAM) (ROM version is 4.4)
Using CAN Bus A
ROM Monitor version 1.3
Fabric Downloader version used 3.2 (ROM version is 3.2)
Primary clock is CSC0
Board State is IOS-XR RUN
Last Reset Reason: Initial load
Insertion time: Mon Jan 5 21:58:33 2009 (1w0d ago)
DRAM size: 2147483648 bytes
FrFab SDRAM size: 1610612736 bytes
ToFab SDRAM size: 268435456 bytes
0 resets since restart/fault forgive
SLOT 1 (RP/LC 1): Cisco 12000 Series - Multi-Service Blade
MAIN: type 150, 800-25972-02 rev A0 dev 90070
HW config: 0x00 SW key: 00-00-00
PCA: 73-9289-04 rev A0 ver 3
HW version 1.0 S/N SAD1124079R
MBUS: Embedded Agent
Test hist: 0x00 RMA#: 00-00-00 RMA hist: 0x00
DIAG: Test count: 0x00000000 Test results: 0x00000000
FRU: Linecard/Module: 12000-ServEngCard
L3 Engine: Service Engine - ISE OC192 (10 Gbps)
MBUS Agent Software version 4.4 (RAM) (ROM version is 4.4)
Using CAN Bus A
ROM Monitor version 1.3
Fabric Downloader version used 3.2 (ROM version is 3.2)
Primary clock is CSC0
Board State is IOS-XR RUN
Last Reset Reason: Card ungraceful reboot
Insertion time: Mon Jan 5 22:33:51 2009 (1w0d ago)
DRAM size: 2147483648 bytes
FrFab SDRAM size: 1610612736 bytes
ToFab SDRAM size: 268435456 bytes
0 resets since restart/fault forgive
SLOT 2 (RP/LC 2): Cisco 12000 Series SPA Interface Processor- 601
MAIN: type 149, 68-2647-01 rev A0 dev 85437
HW config: 0x20 SW key: 00-00-00
PCA: 73-9607-04 rev A0 ver 4
HW version 1.0 S/N SAD10330441
MBUS: Embedded Agent
Test hist: 0x00 RMA#: 00-00-00 RMA hist: 0x00
DIAG: Test count: 0x00000000 Test results: 0x00000000
FRU: Linecard/Module: 12000-SIP-601
Route Memory: MEM-LC5-2048=
Packet Memory: MEM-LC5-PKT-512=
L3 Engine: 5 (MultiRate) - ISE OC192 (10 Gbps)
Operational rate mode: 10 Gbps
MBUS Agent Software version 4.4 (RAM) (ROM version is 4.4)
Using CAN Bus A
ROM Monitor version 17.1
Fabric Downloader version used 4.7 (ROM version is 4.7)
Primary clock is CSC0
Board State is IOS-XR RUN
Last Reset Reason: Initial load
Insertion time: Mon Jan 5 21:58:33 2009 (1w0d ago)
DRAM size: 2147483648 bytes
FrFab SDRAM size: 268435456 bytes
ToFab SDRAM size: 268435456 bytes
0 resets since restart/fault forgive
SPA Information:
subslot 0/2/0: SPA-4XOC3-POS-V2 (0x526), status is ok
subslot 0/2/1: SPA-IPSEC-2G-2 (0x549), status is ok
subslot 0/2/2: SPA-8X1FE (0x4c5), status is ok
subslot 0/2/3: Empty
SLOT 5 (RP/LC 5): Cisco 12000 Series Performance Route Processor 2
MAIN: type 96, 800-23469-03 rev B0 dev 0
HW config: 0x10 SW key: 00-00-00
PCA: 73-8812-06 rev A0 ver 5
HW version 0.0 S/N SAD091702LB
MBUS: MBUS Agent (1) 73-8048-07 rev A0 dev 0
HW version 0.1 S/N SAL0852811R
Test hist: 0x00 RMA#: 00-00-00 RMA hist: 0x00
DIAG: Test count: 0x00000000 Test results: 0x00000000
FRU: Linecard/Module: PRP-2
Route Memory: MEM-PRP/LC-2048=
MBUS Agent Software version 4.4 (RAM) (ROM version is 3.54)
Using CAN Bus A
ROM Monitor version 1.17dev(0.5)
Primary clock is CSC0
Board State is IOS-XR RUN
Insertion time: Mon Jan 5 21:58:33 2009 (1w0d ago)
DRAM size: 2147483648 bytes
0 resets since restart/fault forgive
SLOT 16 (CSC 0): GSR 12406 Clock Scheduler Card
MAIN: type 29, 800-12096-03 rev A0 dev 86476
HW config: 0x00 SW key: 00-00-00
PCA: 73-5702-04 rev A0 ver 4
HW version 1.0 S/N SAL1049A6J7
MBUS: Embedded Agent
Test hist: 0x00 RMA#: 00-00-00 RMA hist: 0x00
DIAG: Test count: 0x00000000 Test results: 0x00000000
FRU: Linecard/Module: GSR6-CSC
MBUS Agent Software version 4.4 (RAM) (ROM version is 4.4)
Using CAN Bus A
Primary clock is CSC0
Insertion time: Mon Jan 5 21:58:33 2009 (1w0d ago)
SLOT 18 (SFC 0): GSR 12406 Switch Fabric Card
MAIN: type 30, 800-12097-03 rev A0 dev 0
HW config: 0x00 SW key: 00-00-00
PCA: 73-5703-05 rev A0 ver 5
HW version 1.0 S/N SAL10425BKW
MBUS: Embedded Agent
Test hist: 0x00 RMA#: 00-00-00 RMA hist: 0x00
DIAG: Test count: 0x00000000 Test results: 0x00000000
FRU: Linecard/Module: GSR6-SFC
MBUS Agent Software version 4.4 (RAM) (ROM version is 4.4)
Using CAN Bus A
Primary clock is CSC0
Insertion time: Mon Jan 5 21:58:33 2009 (1w0d ago)
SLOT 19 (SFC 1): GSR 12406 Switch Fabric Card
MAIN: type 30, 800-12097-03 rev A0 dev 0
HW config: 0x00 SW key: 00-00-00
PCA: 73-5703-05 rev A0 ver 5
HW version 1.0 S/N SAL10425BQ6
MBUS: Embedded Agent
Test hist: 0x00 RMA#: 00-00-00 RMA hist: 0x00
DIAG: Test count: 0x00000000 Test results: 0x00000000
FRU: Linecard/Module: GSR6-SFC
MBUS Agent Software version 4.4 (RAM) (ROM version is 4.4)
Using CAN Bus A
Primary clock is CSC0
Insertion time: Mon Jan 5 21:58:33 2009 (1w0d ago)
SLOT 20 (SFC 2): GSR 12406 Switch Fabric Card
MAIN: type 30, 800-12097-03 rev A0 dev 0
HW config: 0x00 SW key: 00-00-00
PCA: 73-5703-05 rev A0 ver 5
HW version 1.0 S/N SAL10425BQ0
MBUS: Embedded Agent
Test hist: 0x00 RMA#: 00-00-00 RMA hist: 0x00
DIAG: Test count: 0x00000000 Test results: 0x00000000
FRU: Linecard/Module: GSR6-SFC
MBUS Agent Software version 4.4 (RAM) (ROM version is 4.4)
Using CAN Bus A
Primary clock is CSC0
Insertion time: Mon Jan 5 21:58:33 2009 (1w0d ago)
SLOT 24 (PS A1): GSR 12406 Alarm Module
MAIN: type 15, 800-12098-02 rev A0 dev 0
HW config: 0x00 SW key: 00-00-00
PCA: 73-5704-03 rev A0 ver 2
HW version 1.0 S/N SAL10392V05
MBUS: MBUS Agent (1) 73-2146-07 rev B0 dev 0
HW version 1.2 S/N SAL1028UFU2
Test hist: 0x00 RMA#: 00-00-00 RMA hist: 0x00
DIAG: Test count: 0x00000000 Test results: 0x00000000
FRU: Linecard/Module: GSR6-ALRM
MBUS Agent Software version 4.4 (RAM) (ROM version is 4.4)
Using CAN Bus A
Insertion time: Mon Jan 5 21:58:33 2009 (1w0d ago)
SLOT 25 (PS A2): GSR 12406 Alarm Module
MAIN: type 15, 800-12098-02 rev A0 dev 0
HW config: 0x00 SW key: 00-00-00
PCA: 73-5704-03 rev A0 ver 2
HW version 1.0 S/N SAL10392V1A
MBUS: MBUS Agent (1) 73-2146-07 rev B0 dev 0
HW version 1.2 S/N SAL10360PKZ
Test hist: 0x00 RMA#: 00-00-00 RMA hist: 0x00
DIAG: Test count: 0x00000000 Test results: 0x00000000
FRU: Linecard/Module: GSR6-ALRM
MBUS Agent Software version 4.4 (RAM) (ROM version is 4.4)
Using CAN Bus A
Insertion time: Mon Jan 5 21:58:33 2009 (1w0d ago)
SLOT 28 (TOP FAN): GSR 12406 Blower Module
MAIN: type 112, 800-9324-01 rev 71 dev 0
HW config: 0x00 SW key: 00-00-00
PCA: 00-0000-00 rev 70 ver 0
HW version 1.0 S/N SAL095180NC
MBUS: MBUS Agent (1) 73-2146-07 rev B0 dev 0
HW version 1.2 S/N SAL095180NC
Test hist: 0x00 RMA#: 00-00-00 RMA hist: 0x00
DIAG: Test count: 0x00000000 Test results: 0x00000000
FRU: Linecard/Module: GSR6-BLOWER
MBUS Agent Software version 4.4 (RAM) (ROM version is 4.4)
Using CAN Bus A
Insertion time: Mon Jan 5 21:58:33 2009 (1w0d ago)
In the following example, the show diag command displays information for a single system component:
RP/0/0/CPU0:router(admin)# show diag 0/4/cpu0
Tue Jan 13 12:48:23.938 PST DST
SLOT 4 (RP/LC 4): Cisco 12000 Series SPA Interface Processor- 601
MAIN: type 149, 68-2647-02 rev C0 dev 0
HW config: 0x20 SW key: 00-00-00
PCA: 73-9607-05 rev B0 ver 4
HW version 1.0 S/N SAD112709D6
MBUS: Embedded Agent
Test hist: 0x00 RMA#: 00-00-00 RMA hist: 0x00
DIAG: Test count: 0x00000000 Test results: 0x00000000
FRU: Linecard/Module: 12000-SIP-601
Route Memory: MEM-LC5-2048=
Packet Memory: MEM-LC5-PKT-512=
L3 Engine: 5 (MultiRate) - ISE OC192 (10 Gbps)
Operational rate mode: 10 Gbps
MBUS Agent Software version 4.4 (RAM) (ROM version is 4.4)
Using CAN Bus A
ROM Monitor version 17.1
Fabric Downloader version used 4.7 (ROM version is 4.7)
Primary clock is CSC0
Board State is IOS-XR RUN
Last Reset Reason: Initial load
Insertion time: Mon Jan 5 21:58:33 2009 (1w0d ago)
DRAM size: 2147483648 bytes
FrFab SDRAM size: 268435456 bytes
ToFab SDRAM size: 268435456 bytes
0 resets since restart/fault forgive
SPA Information:
subslot 0/4/0: SPA-2X1GE-V2 (0x50b), status is ok
subslot 0/4/1: SPA-2XOC48POS/RPR (0x46f), status is ok
subslot 0/4/2: SPA-2CHT3-CE-ATM (0x4fc), status is ok
subslot 0/4/3: SPA-4XT3/E3 (0x40b), status is ok
Displaying Software and Hardware Information
The show version command displays a variety of system information, including the hardware and software versions, router uptime, boot settings (including the configuration register), and active software.
The following is sample output from the show version command:
RP/0/0/CPU0:router# show version
Tue Jan 13 13:16:39.905 PST DST
Cisco IOS XR Software, Version 3.8.0.26I[SIT_IMAGE]
Copyright (c) 2008 by Cisco Systems, Inc.
ROM: System Bootstrap, Version 12.0(20051020:160303) [sjabbar-CSCsa64979_4 1.17dev(0.5)] DEVELOPMENT SOFTWARE
Copyright (c) 1994-2005 by cisco Systems, Inc.
router uptime is 1 week, 15 hours, 20 minutes
System image file is "disk0:c12k-os-mbi-3.8.0.26I/mbiprp-rp.vm"
cisco 12406/PRP (7457) processor with 2097152K bytes of memory.
7457 processor at 1266Mhz, Revision 1.2
2 Cisco 12000 Series - Multi-Service Blade Controllers
2 Cisco 12000 Series SPA Interface Processor-601/501/401
1 Cisco 12000 Series Performance Route Processor
3 Management Ethernet
8 PLIM_QOS
6 SONET/SDH
6 Packet over SONET/SDH
6 T3
4 Serial network interface(s)
2 GigabitEthernet/IEEE 802.3 interface(s)
6 VLAN sub-interface(s)
4 FR point-to-point sub interface
28 T1
2 Asynchronous Transfer Mode
3 ATM network sub-interface(s)
8 FastEthernet
1018k bytes of non-volatile configuration memory.
800560k bytes of disk0: (Sector size 512 bytes).
800560k bytes of disk1: (Sector size 512 bytes).
65536k bytes of Flash internal SIMM (Sector size 256k).
Boot device on node 0/0/CPU0 is mem:
Package active on node 0/0/CPU0:
c12k-sbc, V 3.8.0.26I[SIT_IMAGE], Cisco Systems, at disk0:c12k-sbc-3.8.0.26I
Built on Thu Dec 11 07:08:15 PST 2008
By sjc-lds-364 in /auto/ioxbuild5/production/3.8.0.26I.SIT_IMAGE/c12k/workspace for c4.2.1-p0
c12k-ipsec-service, V 3.8.0.26I[SIT_IMAGE], Cisco Systems, at disk0:c12k-ipsec-service-3.8.0.26I
Built on Thu Dec 11 05:29:13 PST 2008
By sjc-lds-364 in /auto/ioxbuild5/production/3.8.0.26I.SIT_IMAGE/c12k/workspace for c4.2.1-p0
c12k-fpd, V 3.8.0.26I[SIT_IMAGE], Cisco Systems, at disk0:c12k-fpd-3.8.0.26I
Built on Thu Dec 11 06:17:16 PST 2008
By sjc-lds-364 in /auto/ioxbuild5/production/3.8.0.26I.SIT_IMAGE/c12k/workspace for c4.2.1-p0
c12k-firewall, V 3.8.0.26I[SIT_IMAGE], Cisco Systems, at disk0:c12k-firewall-3.8.0.26I
Built on Thu Dec 11 05:36:08 PST 2008
By sjc-lds-364 in /auto/ioxbuild5/production/3.8.0.26I.SIT_IMAGE/c12k/workspace for c4.2.1-p0
--More--
Displaying SDR Node IDs and Status
In EXEC mode, the show platform command displays information for all nodes assigned to a secure domain router (SDR) . For each node, this information includes the host card type, the operational state, and the configuration state. To display information on a single node, enter the command with a node ID.
The syntax for the show platform command is:
show platform
The following example displays the status for all nodes in the SDR to which you are connected:
RP/0/0/CPU0:router# show platform Tue Jan 13 13:48:51.823 PST DST Node Type PLIM State Config State ----------------------------------------------------------------------------- 0/0/CPU0 L3 Service Eng N/A IOS XR RUN PWR,NSHUT,MON 0/1/CPU0 L3 Service Eng N/A IOS XR RUN PWR,NSHUT,MON 0/2/CPU0 L3LC Eng 5+ Jacket Card IOS XR RUN PWR,NSHUT,MON 0/2/0 SPA SPA-4XOC3-POS-V READY PWR,NSHUT 0/2/1 SPA SPA-IPSEC-2G-2 READY PWR,NSHUT 0/2/2 SPA SPA-8XFE-TX READY PWR,NSHUT 0/4/CPU0 L3LC Eng 5+ Jacket Card IOS XR RUN PWR,NSHUT,MON 0/4/0 SPA SPA-2X1GE-V2 READY PWR,NSHUT 0/4/1 SPA SPA-2XOC48POS/R READY PWR,NSHUT 0/4/2 SPA SPA-2CHT3-CE-AT READY PWR,NSHUT 0/4/3 SPA SPA-4XT3/E3 READY PWR,NSHUT 0/5/CPU0 PRP(Active) N/A IOS XR RUN PWR,NSHUT,MON
The node-id appears in the rack/slot/module notation, and the node-id components are as follows:
-
rack —In a single-shelf system the rack number is always “0.”
-
slot —Number of the physical slot in which the card is installed.
-
module —Subslot number of a system hardware component.
Table 1 summarizes the node-id for each type of card.
|
Card Type (the card to which your are issuing commands) |
Rack (always “0”) |
Slot (the logical slot number reported in command displays) |
Module (the entity on the card that executes the command) |
|---|---|---|---|
| Route processor |
0 |
0-15, 2 |
CPU0 |
| Cisco XR 12000 Series line cards |
0 |
0–153, |
CPU0 |
| Cisco XR 12000 Series SPA Interface Processor (SIP)-600 |
0 |
0–154 |
CPU0 |
| 1-Port 10-Gigabit Ethernet SPA 5-Port Gigabit Ethernet SPA 10-Port Gigabit Ethernet SPA 1-Port OC-192c/STM-64c POS/RPR SPA |
0 |
0–155 |
0-1 (SPA module number on the Cisco XR 12000 and 12000 Series SIP-600) |
| Clock and scheduler cards (CSCs) |
0 |
CSC 0 and 1 |
CPU0 |
| Switch fabric cards (SFCs) |
0 |
CPU0 |
|
| Consolidated switch fabric (CSF) card |
0 |
Dedicated slot 179 |
CPU0 |
Displaying Router Node IDs and Status
In administration EXEC mode, the show platform command displays information for all router nodes. In administration EXEC mode, the command display also includes additional node IDs such as those for fabric cards, alarm modules, and fan controllers. For each node, this information includes the host card type, the operational state, and the configuration state. To display information on a single node, enter the command with a node ID.
The syntax for the show platform command is:
show platform
The following example displays the status for all nodes in the system:
RP/0/0/CPU0:router(admin)# show platform Wed Nov 4 18:52:49.040 PST Node Type PLIM State Config State ----------------------------------------------------------------------------- 0/0/CPU0 L3 Service Eng N/A Card Power down NPWR,NSHUT,MON 0/1/CPU0 L3 Service Eng N/A Card Power down NPWR,NSHUT,MON 0/2/CPU0 L3LC Eng 5+ Jacket Card IOS XR RUN PWR,NSHUT,MON 0/2/0 SPA SPA-4XOC3-POS-V READY PWR,NSHUT 0/2/1 SPA SPA-IPSEC-2G-2 READY PWR,NSHUT 0/2/2 SPA SPA-8XFE-TX READY PWR,NSHUT 0/4/CPU0 L3LC Eng 5+ Jacket Card IOS XR RUN PWR,NSHUT,MON 0/4/0 SPA SPA-2X1GE-V2 READY PWR,NSHUT 0/4/1 SPA SPA-2XOC48POS/R READY PWR,NSHUT 0/4/2 SPA SPA-2CHT3-CE-AT READY PWR,NSHUT 0/4/3 SPA SPA-4XT3/E3 READY PWR,NSHUT 0/5/CPU0 PRP(Active) N/A IOS XR RUN PWR,NSHUT,MON
The node-id appears in the rack/slot/module notation, and the node-id components are as follows:
-
rack —In a single-shelf system the rack number is always “0.”
-
slot —Number of the physical slot in which the card is installed.
-
module —Subslot number of a system hardware component.
Table 1 summarizes the node-id argument for each type of card.
Displaying Router Environment Information
The show environment command displays hardware information for the system, including fan speeds, power supply voltage and current information, and temperatures.
The syntax for the show environment command is:
show environment [options]
You can use the show environment command options to limit the detail in the command display. To view the command options, enter the show environment ? command. The following example shows the full environment status report:
RP/0/0/CPU0:router# show environment
Temperature Information
---------------------------------------------
R/S/I Modules Sensor Temp. (deg C)
0/0/* host Inlet 23.0
host Hot 23.0
0/3/* host Inlet 24.0
host Hot 33.0
0/4/* host Inlet 24.5
host Hot 31.5
0/5/* host Inlet 23.5
host Hot 30.5
0/6/* host Hot 31.5
host Inlet 22.5
0/7/* host Inlet 20.0
host Hot 29.5
0/8/* host Inlet 20.5
host Hot 32.0
Threshold Information
---------------------------------------------
R/S/I Modules Sensor Minor Major Critical
(Lo/Hi) (Lo/Hi) (Lo/Hi)
0/0/* host InletTemp --/ 55 --/ 60 --/ --
host HotTemp --/ 66 --/ 69 --/ --
host PLIM_V4_1.6V --/ -- --/ -- --/ --
host PLIM_V5_1.8V --/ -- --/ -- --/ --
host PLIM_V3_2.5V --/ -- --/ -- --/ --
host 3.4V 2950/3500 2900/3600 --/ --
host 5V 4800/5150 4700/5200 --/ --
host Mbus5V 4700/5300 4500/5500 --/ --
0/3/* host InletTemp --/ 55 --/ 60 --/ 70
host HotTemp --/ 66 --/ 69 --/ 75
host PLIM_V3_1.5V --/ -- --/ -- --/ --
host PLIM_V8_1.8V --/ -- --/ -- --/ --
host PLIM_V7_2.5V --/ -- --/ -- --/ --
host 3.4V --/ -- --/ -- --/ --
host 5V 4800/5200 4700/5300 4600/5400
host Mbus5V 4700/5300 4600/5400 4500/5500
0/4/* host InletTemp --/ 55 --/ 60 --/ 70
host HotTemp --/ 66 --/ 69 --/ 75
host PLIM_V3_1.5V --/ -- --/ -- --/ --
host PLIM_V8_1.8V --/ -- --/ -- --/ --
host PLIM_V7_2.5V --/ -- --/ -- --/ --
host PLIM_V6_1.5V --/ -- --/ -- --/ --
host 5V --/ -- --/ -- --/ --
host 3.4V --/ -- --/ -- --/ --
host Mbus5V 4700/5300 4600/5400 4500/5500
0/5/* host InletTemp --/ 55 --/ 60 --/ 70
host HotTemp --/ 66 --/ 69 --/ 75
host PLIM_V3_1.5V --/ -- --/ -- --/ --
host PLIM_V8_1.8V --/ -- --/ -- --/ --
host PLIM_V7_2.5V --/ -- --/ -- --/ --
host PLIM_V6_1.5V --/ -- --/ -- --/ --
host 5V --/ -- --/ -- --/ --
host 3.4V --/ -- --/ -- --/ --
host Mbus5V 4700/5300 4600/5400 4500/5500
0/6/* host HotTemp --/ 66 --/ 69 --/ 75
host InletTemp --/ 55 --/ 60 --/ 70
host PLIM_V3_1.5V --/ -- --/ -- --/ --
host PLIM_V8_1.8V --/ -- --/ -- --/ --
host PLIM_V7_2.5V --/ -- --/ -- --/ --
host 3.4V --/ -- --/ -- --/ --
host Mbus5V 4700/5300 4600/5400 4500/5500
0/7/* host InletTemp --/ 55 --/ 60 --/ 70
host HotTemp --/ 66 --/ 69 --/ 75
host PLIM_V3_1.5V --/ -- --/ -- --/ --
host PLIM_V8_1.8V --/ -- --/ -- --/ --
host PLIM_V7_2.5V --/ -- --/ -- --/ --
host PLIM_V6_1.5V --/ -- --/ -- --/ --
host 5V --/ -- --/ -- --/ --
host 3.4V --/ -- --/ -- --/ --
host Mbus5V 4700/5300 4600/5400 4500/5500
0/8/* host InletTemp --/ 55 --/ 60 --/ 70
host HotTemp --/ 66 --/ 69 --/ 75
host PLIM_V3_1.5V --/ -- --/ -- --/ --
host PLIM_V8_1.8V --/ -- --/ -- --/ --
host PLIM_V7_2.5V --/ -- --/ -- --/ --
host 3.4V --/ -- --/ -- --/ --
host 5V 4800/5200 4700/5300 4600/5400
host Mbus5V 4700/5300 4600/5400 4500/5500
Voltage Information
---------------------------------------------
R/S/I Modules Sensor Voltage (mV) Margin
0/0/* host PLIM_V4_1.6V 1612 nominal
host PLIM_V5_1.8V 1804 nominal
host PLIM_V3_2.5V 2504 nominal
host 3.4V 3296 nominal
host 5V 5048 nominal
host Mbus5V 5048 n/a
0/3/* host PLIM_V3_1.5V 1496 nominal
host PLIM_V8_1.8V 1788 nominal
host PLIM_V7_2.5V 2492 nominal
host 3.4V 3284 nominal
host 5V 5000 nominal
host Mbus5V 5024 n/a
0/4/* host PLIM_V3_1.5V 1500 nominal
host PLIM_V8_1.8V 1796 nominal
host PLIM_V7_2.5V 2488 nominal
host PLIM_V6_1.5V 1508 nominal
host 5V 4976 nominal
host 3.4V 3288 nominal
host Mbus5V 5048 n/a
0/5/* host PLIM_V3_1.5V 1504 nominal
host PLIM_V8_1.8V 1792 nominal
host PLIM_V7_2.5V 2488 nominal
host PLIM_V6_1.5V 1504 nominal
host 5V 4976 nominal
host 3.4V 3284 nominal
host Mbus5V 4984 n/a
0/6/* host PLIM_V3_1.5V 1496 nominal
host PLIM_V8_1.8V 1792 nominal
host PLIM_V7_2.5V 2476 nominal
host 3.4V 3300 nominal
host Mbus5V 5016 n/a
0/7/* host PLIM_V3_1.5V 1504 nominal
host PLIM_V8_1.8V 1796 nominal
host PLIM_V7_2.5V 2484 nominal
host PLIM_V6_1.5V 1504 nominal
host 5V 4976 nominal
host 3.4V 3276 nominal
host Mbus5V 4984 n/a
0/8/* host PLIM_V3_1.5V 1496 nominal
host PLIM_V8_1.8V 1792 nominal
host PLIM_V7_2.5V 2492 nominal
host 3.4V 3280 nominal
host 5V 5000 nominal
host Mbus5V 5024 n/a
Displaying RP Redundancy Status
The show redundancy command displays the redundancy status of the route processors (RPs) . This command also displays the boot and switch-over history for the RPs.
The show redundancy operates in EXEC and administration EXEC mode.
In the following example, the show redundancy command displays the redundancy status for a redundant RP pair:
RP/0/0/CPU0:router# show redundancy Tue Jan 13 13:57:34.696 PST DST Redundancy information for node 0/5/CPU0: ========================================== Node 0/5/CPU0 is in ACTIVE role Node 0/5/CPU0 has no valid partner Reload and boot info ---------------------- PRP reloaded Mon Jan 5 21:56:06 2009: 1 week, 16 hours, 1 minute ago Active node booted Mon Jan 5 21:56:06 2009: 1 week, 16 hours, 1 minute ago Active node reload "Cause: Turboboot completed successfully"
Displaying Field-Programmable Device Compatibility
The show hw-module fpd command displays field-programmable device (FPD) compatibility for all modules or a specific module.
The syntax for the show hw-module fpd command is:
show hw-module fpd location {all | node-id}
The show hw-module fpd operates in EXEC and administration EXEC mode.
The following example shows how to display FPD compatibility for all modules in the router:
RP/0/0/CPU0:router# show hw-module fpd location all
===================================== ==========================================
Existing Field Programmable Devices
==========================================
HW Current SW Upg/
Location Card Type Version Type Subtype Inst Version Dng?
============ ======================== ======= ==== ======= ==== =========== ====
0/1/0 SPA-4XT3/E3 1.0 spa fpga 0 0.24 No
spa rommon 0 2.12 No
spa fpga2 0 1.0 No
spa fpga3 0 1.0 No
--------------------------------------------------------------------------------
0/1/1 SPA-4XCT3/DS0 0.253 spa fpga 1 2.1 No
spa rommon 1 2.12 No
spa fpga2 1 0.15 No
--------------------------------------------------------------------------------
0/3/0 SPA-2XOC48POS/RPR 1.0 spa fpga 0 1.0 No
--------------------------------------------------------------------------------
0/3/1 SPA-1XTENGE-XFP 3.2 spa fpga 1 1.7 No
--------------------------------------------------------------------------------
RP/0/0/CPU0:router# show hw-module fpd location 0/1/0
Sun Apr 18 10:51:33.776 DST
===================================== ==========================================
Existing Field Programmable Devices
==========================================
HW Current SW Upg/
Location Card Type Version Type Subtype Inst Version Dng?
============ ======================== ======= ==== ======= ==== =========== ====
0/1/0 SPA-1XTENGE-XFP 3.2 spa fpga1 0 1.09 No
--------------------------------------------------------------------------------
Displaying Hardware Image Compatibility
The show upgrade command displays the compatibility of hardware-related images running on various hardware modules and the hardware-related images bundled in the Cisco IOS XR software image currently running on the system. Use the show upgrade command to determine if you need to perform an upgrade of any of the following images:
The syntax for the show upgrade command is:
show upgrade {all | fabric-downloader | mbus-rom | rommon} location {all | node-id}
The show upgrade command operates in administration EXEC mode.
If the output from the show upgrade command indicates that an upgrade is required, use the upgrade command in administration EXEC mode to perform the required upgrade.
The following example shows sample output from the show upgrade command for all modules in the router:
RP/0/0/CPU0:router(admin)# show upgrade all location all
Wed Jan 28 19:59:26.373 UTC
Node Type PLIM Fab-Dwnldr Mbus-Rom Rommon
Upgrade Upgrade Upgrade
Required Required Required
---------------------------------------------------------------------------------------
0/0/CPU0 PRP(Active) N/A N/A Yes Yes
0/1/CPU0 L3LC Eng 5+ Jacket Card No Yes No
0/2/CPU0 L3LC Eng 5+ Jacket Card Yes Yes No
0/3/CPU0 L3LC Eng 5+ Jacket Card Yes Yes No
0/4/CPU0 L3 Service Eng N/A Yes Yes No
0/5/CPU0 L3LC Eng 5+ Jacket Card No Yes No
0/6/CPU0 L3LC Eng 5 Jacket Card Yes Yes No
0/7/CPU0 L3LC Eng 3 OC12-ATM-4 No Yes No
0/8/CPU0 PRP(Standby) N/A N/A Yes Yes
0/9/CPU0 L3LC Eng 3 OC3-POS-4 No Yes No
0/16/CPU0 CSC10 N/A N/A Yes N/A
0/17/CPU0 CSC10(P) N/A N/A Yes N/A
0/18/CPU0 SFC10 N/A N/A Yes N/A
0/19/CPU0 SFC10 N/A N/A Yes N/A
0/20/CPU0 SFC10 N/A N/A Yes N/A
0/21/CPU0 SFC10 N/A N/A Yes N/A
0/22/CPU0 SFC10 N/A N/A Yes N/A
0/24/CPU0 ALARM10 N/A N/A Yes N/A
0/25/CPU0 ALARM10 N/A N/A Yes N/A
0/29/CPU0 GSR16-BLOWER N/A N/A Yes N/A
For more information regarding the show upgrade command, refer to the Hardware Redundancy and Node Administration Commands on the Cisco IOS XR Software module in Cisco IOS XR System Management Command Reference for the Cisco XR 12000 Series Router.
RP Redundancy and Switchover
This section describes RP redundancy and switchover commands and issues.
- Establishing RP Redundancy
- Determining the Active RP in a Redundant Pair
- Role of the Standby RP
- Summary of Redundancy Commands
- Automatic Switchover
- RP Redundancy During RP Reload
- Manual Switchover
- Communicating with a Standby RP
Establishing RP Redundancy
Redundant RPs are formed when you insert two RP cards into paired redundancy slots. Redundancy slots are paired as follows:
- Slot 0 and Slot 1
- Slot 2 and Slot 3
- Slot 4 and Slot 5
- Slot 6 and Slot 7
- Slot 8 and Slot 9
- Slot 10 and Slot 11
- Slot 12 and Slot 13
- Slot 14 and Slot 15
RPs that are seated in paired redundancy slots cannot be assigned to different SDRs. For example, an RP that is installed in Slot 3 can be assigned to one SDR, whereas an RP that is installed in Slot 4 can be assigned to a different SDR because Slot 3 and Slot 4 are not a redundant pair. However, you cannot have the RP in Slot 3 assigned to an SDR other that of the RP in Slot 2 because Slot 2 and Slot 3 are a redundant pair.
RP redundancy is established when the Cisco IOS XR software is brought up on both cards in paired redundancy slots. For example, if you install the Cisco IOS XR software on the DSC, an RP in the paired redundancy slot comes up as the standby DSC after the minimum boot image (MBI) is loaded and the redundant RP synchronizes with the DSC.
Determining the Active RP in a Redundant Pair
During system startup, one RP in each redundant pair becomes the active RP. You can tell which RP is the active RP in the following ways:
- The alphanumeric LED display on the active Performance Route Processor (PRP) displays: PRI RP.
-
The slot of the active RP is indicated in the CLI prompt. For example:
RP/0/1/CPU0:router#
In this example, the prompt indicates that you are communicating with the active RP in slot RP1. See Cisco IOS XR Getting Started Guide for the Cisco XR 12000 Series Router for a complete description of the CLI prompt.
-
Enter the show redundancy command in EXEC mode to display a summary of the active and standby RP status. For example:
RP/0/0/CPU0:router# show redundancy Tue Jan 13 13:57:34.696 PST DST Redundancy information for node 0/5/CPU0: ========================================== Node 0/5/CPU0 is in ACTIVE role Node 0/5/CPU0 has no valid partner Reload and boot info ---------------------- PRP reloaded Mon Jan 5 21:56:06 2009: 1 week, 16 hours, 1 minute ago Active node booted Mon Jan 5 21:56:06 2009: 1 week, 16 hours, 1 minute ago Active node reload "Cause: Turboboot completed successfully"
Role of the Standby RP
The second RP to boot in a redundant pair automatically becomes the standby RP. While the active RP manages the system and communicates with the user interface, the standby RP maintains a complete backup of the software and configurations for all cards in the system. If the active RP fails or goes off line for any reason, the standby RP immediately takes control of the system.
Summary of Redundancy Commands
RP redundancy is enabled by default in the Cisco IOS XR software, but you can use the commands described in Table 1 to display the redundancy status of the cards or force a manual switchover.
|
Command |
Description |
|---|---|
|
show redundancy |
Displays the redundancy status of the RPs. This command also displays the boot and switch-over history for the RPs. |
|
redundancy switchover |
Forces a manual switchover to the standby RP. This command works only if the standby RP is installed and in the “ready” state. |
|
show platform |
Displays the status for node, including the redundancy status of the RP cards. In EXEC mode, this command displays status for the nodes assigned to the SDR. In administration EXEC mode, this command displays status for all nodes in the system. |
Automatic Switchover
Automatic switchover from the active RP to the standby RP occurs only if the active RP encounters a serious system error, such as the loss of a mandatory process or a hardware failure. When an automatic switchover occurs, the RPs respond as follows:
RP Redundancy During RP Reload
The reload command causes the active RP to reload the Cisco IOS XR software. When an RP reload occurs, the RPs respond as follows:
- If a standby RP is installed and “ready” for switchover, the standby RP becomes the active RP. The original active RP reboots and becomes the standby RP.
- If the standby RP is not in the “ready” state, then both RPs reboot. The first RP to boot successfully assumes the role of active RP.
 Caution | You should not use the reload command to force an RP switchover because the result could be a significant loss of router operations. Instead, use the redundancy switchover command to fail over to the standby RP, then use the hw-module location node-id reload command to reload the new standby RP. |
Manual Switchover
You can force a manual switchover from the active RP to the standby RP using the redundancy switchover command.
If a standby RP is installed and ready for switchover, the standby RP becomes the active RP. The original active RP becomes the standby RP. In the following example, partial output for a successful redundancy switchover operation is shown:
RP/0/0/CPU0:router# show redundancy This node (0/0/CPU0) is in ACTIVE role Partner node (0/1/CPU0) is in STANDBY role Standby node in 0/1/CPU0 is ready RP/0/0/CPU0:router# redundancy switchover Updating Commit Database. Please wait...[OK] Proceed with switchover 0/0/CPU0 -> 0/1/CPU0? [confirm] Initiating switch-over. RP/0/0/CPU0:router# <Your 'TELNET' connection has terminated>
In the preceding example, the Telnet connection is lost when the previously active RP resets. To continue management of the router, you must connect to the newly activated RP as shown in the following example:
User Access Verification
Username: xxxxx
Password: xxxxx
Last switch-over Sat Apr 15 12:26:47 2009: 1 minute ago
RP/0/1/CPU0:router#
If the standby RP is not in “ready” state, the switchover operation is not allowed. In the following example, partial output for a failed redundancy switchover attempt is shown:
RP/0/0/CPU0:router# show redundancy Redundancy information for node 0/1/CPU0: ========================================== Node 0/0/CPU0 is in ACTIVE role Partner node (0/1/CPU0) is in UNKNOWN role Reload and boot info ---------------------- RP reloaded Wed Mar 29 17:22:08 2006: 2 weeks, 2 days, 19 hours, 14 minutes ago Active node booted Sat Apr 15 12:27:58 2006: 8 minutes ago Last switch-over Sat Apr 15 12:35:42 2006: 1 minute ago There have been 4 switch-overs since reload RP/0/0/CPU0:router# redundancy switchover Switchover disallowed: Standby node is not ready.
Communicating with a Standby RP
The active RP automatically synchronizes all system software, settings, and configurations with the standby RP.
If you connect to the standby RP through the console port, you can view the status messages for the standby RP. The standby RP does not display a CLI prompt, so you cannot manage the standby card while it is in standby mode.
If you connect to the standby RP through the management Ethernet port, the prompt that appears is for the active RP, and you can manage the router the same as if you had connected through the management Ethernet port on the active RP.
Reloading, Shutting Down, or Power Cycling a Node
Use the commands described in this section to reload the Cisco IOS XR software on the active RP or on any specified node in the system. This section also describes the commands used to administratively shut down a node and power a node on or off.
Table 1 summarizes the commands described in this section.
|
Command |
Description |
||
|---|---|---|---|
|
hw-module location node-id power disable |
This command administratively turns the power off for a node. It is entered in administration configuration mode. The changes do not take effect until you enter the commit command. To power on a node, use the no form of this command.
|
||
|
hw-module location node-id reload |
This command works in EXEC mode and reloads the Cisco IOS XR software on a specific node or all nodes. To specify all nodes, enter the all keyword in place of the node-id argument. The node reloads with the current running configuration and active software set for that node. |
||
|
hw-module shutdown location node-id |
This command must be entered in administration configuration mode and administratively shuts down the specified node. Nodes that are shut down still have power but cannot load or operate Cisco IOS XR software. To return a node to the up state, use the no form of this command.
|
- Reloading the Active RP
- Administratively Shutting Down or Powering On or Off a Node
- Configuring the Power Manager
Reloading the Active RP
The reload command causes the active RP to reload the Cisco IOS XR software according to the configuration register setting. This setting determines how the active RP acts when reloaded.
This section contains instructions to reload the Cisco IOS XR software and return to EXEC mode. For instructions to use the reload command for entering ROM Monitor bootstrap mode, see Cisco IOS XR ROM Monitor Guide for the Cisco XR 12000 Series Router.
Caution | Because the reload command causes the active RP to go off line and either reload the Cisco IOS XR software or enter ROM Monitor mode, the router experiences a loss of service unless a redundant standby RP is installed and in “ready” state. To display the status of the standby RP, use the show redundancy command in EXEC mode. |
1.
show
redundancy
2.
admin
3.
show
variables
boot
4.
(Optional)
config-register
0x2102
5.
admin
6.
reload
DETAILED STEPS
| Command or Action | Purpose | |||
|---|---|---|---|---|
| Step 1 |
show
redundancy
Example:
RP/0/0/CPU0:router# show redundancy
|
Displays the RP redundancy status. | ||
| Step 2 |
admin
Example:
RP/0/0/CPU0:router# admin
|
Enters administration EXEC mode. | ||
| Step 3 |
show
variables
boot
Example:
RP/0/0/CPU0:router(admin)# show variables boot
|
Displays the configuration register setting.
| ||
| Step 4 |
config-register
0x2102
Example:
RP/0/0/CPU0:router(admin)# config-register 0x2102
| (Optional)
Sets the configuration register to 0x2102. This step is necessary only if the register is not set to 0x2102 in the running configuration. | ||
| Step 5 |
admin
Example:
RP/0/0/CPU0:router# admin
|
Enters administration EXEC mode. | ||
| Step 6 |
reload
Example:
RP/0/0/CPU0:router# reload
|
Reloads the active RP according to the configuration register setting.
|
Administratively Shutting Down or Powering On or Off a Node
A node can be administratively shut down by entering the hw-module location node-id shutdown command in administration configuration mode. A node that is shut down still has power, but it cannot load or run the Cisco IOS XR software.
You can also administratively turn power off for a node using the hw-module location node-id power disable command in administration configuration mode.
For more information on the use of these commands, see Cisco IOS XR System Management Command Reference for the Cisco XR 12000 Series Router.
Configuring the Power Manager
Cisco IOS XR software manages the power of the chassis by keeping track of the available wattage for use and how much is necessary, in the worst case scenario. The manager prevents newly discovered or inserted modules or line cards from powering up unless there is sufficient surplus power available to operate them. This means that some line cards may be held in the power down or low power state to permit the remaining cards to run. Restricting which cards come up guarantees that the chassis continues to operate if a single power supply (or several power supplies) fail.
The power manager is enabled by default to operate in redundancy mode, which means that the failure of at least one power supply is already assumed in the calculation of the available wattage for the chassis. This means that only those cards that can be powered by the redundant power supplies are allowed to power up. In this way, operation is guaranteed even if one or more power supplies fail.
Alternatively, you can configure the power management to be additive, meaning that the wattage of all power sources is summed together to compute the total available power. The decision of whether to power up a line card is based on whether there is surplus power remaining from the total sum of all the power supplies. This mode cannot guarantee any sort of power redundancy, because no power has been reserved for coping with a power supply failure. However, with sufficient power supplies, the probability of a failure is statistically lower due to the larger number of independent power supplies. The additive mode is best for power-hungry applications where card density is more important than absolute protection from a power supply fault.
1.
admin
2.
configure
3.
(Optional)
power-mgr
additive
4.
(Optional)
power-mgr
disable
5.
(Optional)
power-mgr
scale-factor
percentage
6.
show power-mgr
7.
commit
DETAILED STEPS
show power-mgr Output: Example
The following example shows sample output from the show power-mgr command:
RP/0/5/CPU0:router(admin)# show power-mgr trace Sun Jun 28 12:25:40.763 PST 97 wrapping entries (1152 possible, 0 filtered, 97 total) Jun 12 04:27:12.426 power_manager/debug 0/5/CPU0 t33 -------power_manager starting-------- Jun 12 04:27:12.426 power_manager/debug 0/5/CPU0 t33 PM Spawning main Process Jun 12 04:27:12.426 power_manager/debug 0/5/CPU0 t33 Performing pre-config monvar parsing Jun 12 04:27:12.626 power_manager/debug 0/5/CPU0 t35 Power Manager EDM Bind successful Jun 12 04:27:12.658 power_manager/debug 0/5/CPU0 t35 Power Manager Bag registration done Jun 12 04:27:12.715 power_manager/debug 0/5/CPU0 t35 Power Manager EDM Registration is done Jun 12 04:27:14.516 power_manager/debug 0/5/CPU0 t1 Event: DISCOVERY_DONE on zone=2 with data 0x00000000 Jun 12 04:27:14.517 power_manager/debug 0/5/CPU0 t33 PM Dequeued Event = DISCOVERY_DONE Jun 12 04:27:14.520 power_manager/debug 0/5/CPU0 t36 Running on primary RP Jun 12 04:27:14.539 power_manager/debug 0/5/CPU0 t36 MBus path to PEMs now available Jun 12 04:27:14.539 power_manager/debug 0/5/CPU0 t36 Attempting to discover powershelf type Jun 12 04:27:15.073 power_manager/debug 0/5/CPU0 t36 PEM FAMILY determined to be =0 Jun 12 04:27:15.240 power_manager/debug 0/5/CPU0 t36 Successfully discovered powershelf type=2 Jun 12 04:27:15.240 power_manager/debug 0/5/CPU0 t36 Discovering installed PEMs Jun 12 04:27:19.550 power_manager/debug 0/5/CPU0 t22 Discarding LC_OIR_INSERTED for slot 25; in DISCOVERY_PHASE Jun 12 04:27:19.551 power_manager/debug 0/5/CPU0 t16 Discarding LC_OIR_INSERTED for slot 16; in DISCOVERY_PHASE Jun 12 04:27:19.551 power_manager/debug 0/5/CPU0 t19 Discarding LC_OIR_INSERTED for slot 19; in DISCOVERY_PHASE Jun 12 04:27:19.552 power_manager/debug 0/5/CPU0 t25 Discarding LC_OIR_INSERTED for slot 28; in DISCOVERY_PHASE Jun 12 04:27:19.562 power_manager/debug 0/5/CPU0 t20 Discarding LC_OIR_INSERTED for slot 20; in DISCOVERY_PHASE Jun 12 04:27:19.564 power_manager/debug 0/5/CPU0 t12 Discarding LC_OIR_INSERTED for slot 2; in DISCOVERY_PHASE Jun 12 04:27:19.565 power_manager/debug 0/5/CPU0 t15 Discarding LC_OIR_INSERTED for slot 5; in DISCOVERY_PHASE Jun 12 04:27:19.565 power_manager/debug 0/5/CPU0 t10 Discarding LC_OIR_INSERTED for slot 0; in DISCOVERY_PHASE Jun 12 04:27:19.566 power_manager/debug 0/5/CPU0 t13 Discarding LC_OIR_INSERTED for slot 3; in DISCOVERY_PHASE Jun 12 04:27:19.575 power_manager/debug 0/5/CPU0 t21 Discarding LC_OIR_INSERTED for slot 24; in DISCOVERY_PHASE Jun 12 04:27:19.577 power_manager/debug 0/5/CPU0 t14 Discarding LC_OIR_INSERTED for slot 4; in DISCOVERY_PHASE Jun 12 04:27:19.583 power_manager/debug 0/5/CPU0 t11 Discarding LC_OIR_INSERTED for slot 1; in DISCOVERY_PHASE Jun 12 04:27:19.598 power_manager/debug 0/5/CPU0 t18 Discarding LC_OIR_INSERTED for slot 18; in DISCOVERY_PHASE Jun 12 04:27:23.418 power_manager/debug 0/5/CPU0 t36 PEM 2 open part failed ; retry count=25 Jun 12 04:27:31.335 power_manager/debug 0/5/CPU0 t36 PEM 2 open part failed ; retry count=25 Jun 12 04:27:31.536 power_manager/err 0/5/CPU0 t36 Intelligence check for pem 2 failed with result =4 Jun 12 04:27:31.536 power_manager/debug 0/5/CPU0 t36 PEM2 discovered as GSR6 legacy AC Jun 12 04:27:31.683 power_manager/debug 0/5/CPU0 t36 PEM2 can supply up to 1600 watts Jun 12 04:27:31.683 power_manager/debug 0/5/CPU0 t36 Zone discovery found 1 power zone for this chassis Jun 12 04:27:31.683 power_manager/debug 0/5/CPU0 t36 Discovering cards present and populating slot data Jun 12 04:27:36.684 power_manager/debug 0/5/CPU0 t36 Cardtype 150 found in slot 0, needing 134 W Jun 12 04:27:36.684 power_manager/debug 0/5/CPU0 t36 Cardtype 150 found in slot 1, needing 134 W Jun 12 04:27:36.702 power_manager/debug 0/5/CPU0 t36 Cardtype 149 found in slot 2, needing 240 W Jun 12 04:27:36.717 power_manager/debug 0/5/CPU0 t36 Cardtype 149 found in slot 3, needing 240 W Jun 12 04:27:36.735 power_manager/debug 0/5/CPU0 t36 Cardtype 149 found in slot 4, needing 240 W Jun 12 04:27:36.735 power_manager/debug 0/5/CPU0 t36 Cardtype 96 found in slot 5, needing 60 W Jun 12 04:27:36.735 power_manager/debug 0/5/CPU0 t36 No card present in slot 6; skipping Jun 12 04:27:36.735 power_manager/debug 0/5/CPU0 t36 No card present in slot 7; skipping Jun 12 04:27:36.735 power_manager/debug 0/5/CPU0 t36 No card present in slot 8; skipping Jun 12 04:27:36.735 power_manager/debug 0/5/CPU0 t36 No card present in slot 9; skipping Jun 12 04:27:36.735 power_manager/debug 0/5/CPU0 t36 No card present in slot 10; skipping Jun 12 04:27:36.735 power_manager/debug 0/5/CPU0 t36 No card present in slot 11; skipping Jun 12 04:27:36.735 power_manager/debug 0/5/CPU0 t36 No card present in slot 12; skipping Jun 12 04:27:36.735 power_manager/debug 0/5/CPU0 t36 No card present in slot 13; skipping Jun 12 04:27:36.735 power_manager/debug 0/5/CPU0 t36 No card present in slot 14; skipping Jun 12 04:27:36.735 power_manager/debug 0/5/CPU0 t36 No card present in slot 15; skipping Jun 12 04:27:36.735 power_manager/debug 0/5/CPU0 t36 Cardtype 29 found in slot 16, needing 56 W Jun 12 04:27:36.735 power_manager/debug 0/5/CPU0 t36 No card present in slot 17; marking phantom Jun 12 04:27:36.735 power_manager/debug 0/5/CPU0 t36 Cardtype 30 found in slot 18, needing 45 W Jun 12 04:27:36.735 power_manager/debug 0/5/CPU0 t36 Cardtype 30 found in slot 19, needing 45 W Jun 12 04:27:36.735 power_manager/debug 0/5/CPU0 t36 Cardtype 30 found in slot 20, needing 45 W Jun 12 04:27:36.735 power_manager/debug 0/5/CPU0 t36 No card present in slot 21; skipping Jun 12 04:27:36.735 power_manager/debug 0/5/CPU0 t36 No card present in slot 22; skipping Jun 12 04:27:36.735 power_manager/debug 0/5/CPU0 t36 No card present in slot 23; skipping Jun 12 04:27:36.735 power_manager/debug 0/5/CPU0 t36 Cardtype 15 found in slot 24, needing 26 W Jun 12 04:27:36.735 power_manager/debug 0/5/CPU0 t36 Cardtype 15 found in slot 25, needing 26 W Jun 12 04:27:36.735 power_manager/debug 0/5/CPU0 t36 No card present in slot 26; skipping Jun 12 04:27:36.735 power_manager/debug 0/5/CPU0 t36 No card present in slot 27; skipping Jun 12 04:27:36.735 power_manager/debug 0/5/CPU0 t36 Cardtype 112 found in slot 28, needing 178 W Jun 12 04:27:36.735 power_manager/debug 0/5/CPU0 t36 No card present in slot 29; skipping Jun 12 04:27:36.735 power_manager/debug 0/5/CPU0 t36 No card present in slot 30; skipping Jun 12 04:27:36.735 power_manager/debug 0/5/CPU0 t36 No card present in slot 31; skipping Jun 12 04:27:36.735 power_manager/debug 0/5/CPU0 t36 Changing phase to INIT_DECISION_PHASE Jun 12 04:27:36.738 power_manager/debug 0/5/CPU0 t36 Powershelf capacity at 1600 watts zone1, 0 watts zone2 Jun 12 04:27:36.738 power_manager/debug 0/5/CPU0 t36 Reserved chassis power is 477 W zone1, 0 W zone2 Jun 12 04:27:36.738 power_manager/debug 0/5/CPU0 t36 Available power for chassis is 1123 W zone1,0 W zone2, Jun 12 04:27:36.738 power_manager/debug 0/5/CPU0 t36 Starting power-on decision process with 1123/0 W Jun 12 04:27:36.738 power_manager/debug 0/5/CPU0 t36 Starting power-on decision process with 5/60 W Jun 12 04:27:36.738 power_manager/debug 0/5/CPU0 t36 After accounting for RPs, 1063/0 W avail Jun 12 04:27:36.738 power_manager/debug 0/5/CPU0 t36 After accounting for priority slots, 1063/0 W avail Jun 12 04:28:46.718 power_manager/debug 0/5/CPU0 t36 slot 0 needs 134 W, 929 avail; Jun 12 04:28:46.718 power_manager/debug 0/5/CPU0 t36 slot 1 needs 134 W, 795 avail; Jun 12 04:28:46.735 power_manager/debug 0/5/CPU0 t36 slot 2 needs 240 W, 555 avail; Jun 12 04:28:46.750 power_manager/debug 0/5/CPU0 t36 slot 3 needs 240 W, 315 avail; Jun 12 04:28:46.777 power_manager/debug 0/5/CPU0 t36 slot 4 needs 240 W, 75 avail; Jun 12 04:28:46.777 power_manager/debug 0/5/CPU0 t36 After accounting for normal slots, 75/0 W avail Jun 12 04:28:46.777 power_manager/debug 0/5/CPU0 t36 RP in-use power is 60 W zone1, 0 W zone2 Jun 12 04:28:46.777 power_manager/debug 0/5/CPU0 t36 Linecard in-use power is 988 W zone1, 0 W zone2 Jun 12 04:28:46.777 power_manager/debug 0/5/CPU0 t36 Available power for chassis is 75 W zone1,0 W zone2, Jun 12 04:28:46.777 power_manager/debug 0/5/CPU0 t36 Starting periodic task to monitor PEMs Jun 12 04:28:46.778 power_manager/debug 0/5/CPU0 t36 Changing phase to RUNNING_PHASE Jun 12 04:28:47.706 power_manager/debug 0/5/CPU0 t11 Sufficient power available to bringup slot 1 Jun 12 04:28:47.711 power_manager/debug 0/5/CPU0 t10 Sufficient power available to bringup slot 0 Jun 12 04:28:47.713 power_manager/debug 0/5/CPU0 t12 Sufficient power available to bringup slot 2 Jun 12 04:28:47.715 power_manager/debug 0/5/CPU0 t14 Sufficient power available to bringup slot 4 Jun 12 04:28:47.718 power_manager/debug 0/5/CPU0 t13 Sufficient power available to bringup slot 3 Jun 12 04:28:59.467 power_manager/debug 0/5/CPU0 t33 PEM2 busy; skipping polling Jun 12 04:29:10.161 power_manager/debug 0/5/CPU0 t33 PEM2 no longer busy; resuming polling Jun 12 04:36:30.950 power_manager/debug 0/5/CPU0 t10 Sufficient power available to bringup slot 0 Jun 12 04:36:54.291 power_manager/debug 0/5/CPU0 t11 Sufficient power available to bringup slot 1 Jun 12 09:13:43.219 power_manager/debug 0/5/CPU0 t10 Sufficient power available to bringup slot 0 Jun 12 09:13:44.514 power_manager/debug 0/5/CPU0 t11 Sufficient power available to bringup slot 1 Jun 12 09:14:29.463 power_manager/debug 0/5/CPU0 t11 Sufficient power available to bringup slot 1
Flash Disk Recovery
When an RP is power cycled or experiences an ungraceful reset, the boot disk (PCMCIA flash disk used to boot the card) may experience a file-system corruption. If this occurs, an error message is displayed and the RP fails to boot. The corrupted flash disk is automatically reformatted and the Cisco IOS XR software is restored from the designated system controller (DSC) for the system.
For example, if a flash disk for an RP is corrupted, the RP fails to boot and the following error message is displayed:
#########################################################
Restricted Rights Legend
Use, duplication, or disclosure by the Government is
subject to restrictions as set forth in subparagraph
(c) of the Commercial Computer Software - Restricted
Rights clause at FAR sec. 52.227-19 and subparagraph
(c) (1) (ii) of the Rights in Technical Data and Computer
Software clause at DFARS sec. 252.227-7013.
cisco Systems, Inc.
170 West Tasman Drive
San Jose, California 95134-1706
Cisco IOS XR Software for the Cisco XR Cisco XR 12000 Series Router-mbirp,
Copyright (c) 2009 by Cisco Systems, Inc.
Unable to mount /disk0:, filesystem is corrupted.
Check fsck log at /tmp/chkfs_fd0.log
init: special_commands:wait for disk0: failed
If this occurs, then the flash disk is automatically reformatted and the Cisco IOS XR software is restored to the flash disk.
Note | If the flash disk is badly damaged and cannot be reformatted, the disk must be replaced. If the corrupted flash disk is the DSC, then the router fails over to the standby DSC. If no standby DSC is installed, then the system fails to boot. |
Using Controller Commands to Manage Hardware Components
The controller , controllers , and show controllers commands are used to manage and display settings for various hardware components, including the switch fabric management, Ethernet control plane, and interface manager. These commands are primarily diagnostic and related to driver-level details. The information available with these commands varies widely and is hardware specific.
For information on the use of these commands, see Cisco IOS XR Interface and Hardware Component Command Reference for the Cisco XR 12000 Series Router.
Formatting Hard Drives, Flash Drives, and Other Storage Devices
To format a storage device on the router, use the format command in EXEC mode.
Caution | Formatting a storage device deletes all data on that device. |
The following command syntax is used:
format filesystem: [options]
Table 1 describes the format command syntax.
|
Variable |
Description |
|---|---|
|
filesystem |
Specifies the memory device to format. The supported file systems are: Enter format ? to see the devices supported on your router. |
|
options |
Enter format filesystem: ? to see the available options. For more information, see Cisco IOS XR System Management Command Reference for the Cisco XR 12000 Series Router. |
In the following example, the format command is used to format the hard disk:
RP/0/0/CPU0:router# format harddisk:
Removing and Replacing Cards
This section describes card replacement issues and procedures.
- Removing Line Cards
- Removing and Replacing CSC and SFC Cards
- Adding a Standby PRP to a Cisco XR 12000 Series Router
Removing Line Cards
Line cards are designed for online insertion and removal (OIR). A line card is a single card that contains all service processing functions and physical line interfaces.
The OIR feature allows you to remove and replace cards without removing power to the card or chassis. Removing a card interrupts all traffic passing through the card, but it does not remove the card configuration.
When you remove a card, the configuration remains for all interfaces, but the interfaces do not appear in the output of the show interfaces command. You can view interface configurations by entering the show running-config command. The following example shows how the configuration appears when a card is removed:
RP/0/0/CPU0:router# show running-config
Building configuration...
hostname router
router ospf 3269
area 0
interface POS0/3/0/0
cost 20
!
interface preconfigure POS0/3/0/0
ipv4 address 10.10.50.1 255.255.255.0
!
interface preconfigure POS0/3/0/1
description POS0/3/0/1
shutdown
!
interface preconfigure POS0/3/0/2
description POS0/3/0/2
shutdown
!
interface preconfigure POS0/3/0/3
description POS0/3/0/3
shutdown
!
In this example, the line card in slot 3 is removed, and the interface configuration for all four interfaces changes to “interface preconfigure.” However, the “router ospf” reference to a slot 3 interface does not change. If you replace a line card with another line card that uses the same media type and port count, the configuration becomes active on the replacement card.
To remove the configuration for a slot after a card is removed, use the no interface preconfigure command to remove all interface configuration statements for that card in the running configuration. In addition, search the configuration for any references to the removed interfaces, such as the “router ospf” reference to slot 3 in the preceding example.
To remove the configuration for a slot when a card is installed, use the no interface command to remove all interface configuration statements for that card in the running configuration. In addition, search the configuration for any references to the removed interfaces.
Each line card supports a specific media type (Packet over SONET/SDH [POS] or Ethernet, for example) and port count. If you replace a line card with one that supports a different media type or port count, you should review the configuration and revise it to support the replacement line card.
- Replacing a Line Card with the Same Media Type and Port Count
- Replacing a Line Card with the Same Media Type and a Different Port Count
- Replacing a Line Card or PLIM with a Different Media Type
Replacing a Line Card with the Same Media Type and Port Count
When you replace a line card or PLIM with a card that is of the same media type and has the same port count as the replaced card, the guidelines in the Removing Line Cards apply. Because the replacement card is of the same media type and port count, no special procedures are required for card removal and replacement.
Replacing a Line Card with the Same Media Type and a Different Port Count
When you replace a line card with a card that is of the same media type with a different port count, the guidelines in Removing Line Cards apply.
If the new card has a greater port count than the replaced card, the configuration applies to the corresponding lower port numbers, and the ports that did not exist on the replaced card have no configuration and come up in the shutdown state.
If the new card supports fewer ports, the existing configuration for the corresponding number of ports on the new card set is applied. The previous configuration for the removed ports remains in interface preconfigure state, as shown in the following example:
RP/0/0/CPU0:router# show running-config
Building configuration...
hostname rtp-gsr1
interface POS0/3/0/0
ipv4 address 10.10.50.1 255.255.255.0
!
interface preconfigure POS0/3/0/1
description POS0/3/0/1
shutdown
!
interface preconfigure POS0/3/0/2
description POS0/3/0/2
shutdown
!
interface preconfigure POS0/3/0/3
description POS0/3/0/3
shutdown
!
In the preceding example, a four-port card has been replaced with a single-port card. The configuration from port 1 on the four-port card is applied to the single port on the replacement card, and the remaining port configurations change to “interface preconfigure.” To remove the configuration for the missing interfaces, use the no interface preconfigure command. In addition, search for and remove any configuration references to the removed interfaces.
Whenever you replace a line card with the same media type and a different port count, review the running configuration in the router and revise the configuration as necessary.
Replacing a Line Card or PLIM with a Different Media Type
When you replace a line card or PLIM with a card that is of a different media type (for example, if you replace a POS PLIM with an Ethernet PLIM), the guidelines in Removing Line Cards apply. Review the running configuration in the router and revise the configuration as necessary for the new media type.
Removing and Replacing CSC and SFC Cards
On Cisco XR 12000 Series Routers that use clock and scheduler cards (CSCs) and switch fabric cards (SFCs), the CSCs and SFCs work together to provide the switch fabric for the router. Although some router cards can be removed without software preparation, it is best to shut down and remove the power from a CSC or an SFC slot before removing a card. When the new card is inserted, you can restore the power to the slot and bring up the replacement card. This section describes how to properly remove and replace CSCs and SFCs for repairs.
Note | On Cisco XR 12404 routers, which use consolidated switch fabric cards (CSFCs), you must power off the router before changing a CSFC card. |
You must log in as root-system before starting the procedure. To confirm your login status, use the show user group command:
RP/0/0/CPU0:router# show user group root-system, cisco-support
To confirm your login status including root, use the show user all | include root command:
RP/0/0/CPU0:router# show user all | include root Groups: root-system, cisco-support Task: root-lr : READ WRITE EXECUTE DEBUG (reserved) Task: root-system : READ WRITE EXECUTE DEBUG (reserved)
1.
admin
2.
show
platform
3.
admin
4.
hw-module
location
slot
shutdown
5.
hw-module
location
slot
power
disable
6.
commit
7.
end
8.
(Optional)
show
platform
9. Remove and replace the CSC or SFC.
10.
admin
11.
no
hw-module
location
slot
power
disable
12.
commit
13.
end
14.
(Optional)
show
platform
15.
admin
16.
no
hw-module
location
slot
shutdown
17.
commit
18.
end
19.
(Optional)
show
platform
DETAILED STEPS
| Command or Action | Purpose | |||
|---|---|---|---|---|
| Step 1 |
admin
Example:
RP/0/0/CPU0:router# admin
|
Enters administration EXEC mode. | ||
| Step 2 |
show
platform
Example: RP/0/0/CPU0:router(admin)# show platform |
Displays the state of all cards on the router. | ||
| Step 3 |
admin
Example:
RP/0/0/CPU0:router# admin
|
Enters administration EXEC mode. | ||
| Step 4 |
hw-module
location
slot
shutdown
Example: RP/0/0/CPU0:router(admin-config)# hw-module location 0/16/CPU0 shutdown Example: |
Configures a slot to shut down when the configuration is committed.
| ||
| Step 5 |
hw-module
location
slot
power
disable
Example: RP/0/0/CPU0:router(admin-config)# hw-module location 0/16/CPU0 power disable |
Configures a slot to power down when the configuration is committed. | ||
| Step 6 |
commit
Example:
RP/0/0/CPU0:router(admin-config)# commit
|
Commits the target configuration to the router running configuration. | ||
| Step 7 |
end
Example:
RP/0/0/CPU0:router(admin-config)# end
|
Exits administration configuration mode and returns to administration EXEC mode. | ||
| Step 8 |
show
platform
Example: RP/0/0/CPU0:router(admin)# show platform | (Optional)
Displays the state of all cards on the router. | ||
| Step 9 | Remove and replace the CSC or SFC. |
Replaces the physical card. | ||
| Step 10 |
admin
Example:
RP/0/0/CPU0:router# admin
|
Enters administration EXEC mode. | ||
| Step 11 |
no
hw-module
location
slot
power
disable
Example: RP/0/0/CPU0:router(admin-config)# no hw-module location 0/16/CPU0 power disable |
Configures a slot to power up when the configuration is committed. | ||
| Step 12 |
commit
Example:
RP/0/0/CPU0:router(admin-config)# commit
|
Commits the target configuration to the router running configuration. | ||
| Step 13 |
end
Example:
RP/0/0/CPU0:router(admin-config)# end
|
Exits administration configuration mode and returns to administration EXEC mode. | ||
| Step 14 |
show
platform
Example: RP/0/0/CPU0:router(admin)# show platform | (Optional)
Displays the state of all cards on the router. | ||
| Step 15 |
admin
Example:
RP/0/0/CPU0:router# admin
|
Enters administration EXEC mode. | ||
| Step 16 |
no
hw-module
location
slot
shutdown
Example: RP/0/0/CPU0:router(admin-config)# no hw-module location 0/16/CPU0 shutdown |
Configures a slot to start when the configuration is committed. | ||
| Step 17 |
commit
Example:
RP/0/0/CPU0:router(admin-config)# commit
|
Commits the target configuration to the router running configuration. | ||
| Step 18 |
end
Example:
RP/0/0/CPU0:router(admin-config)# end
|
Exits administration configuration mode and returns to administration EXEC mode. | ||
| Step 19 |
show
platform
Example: RP/0/0/CPU0:router(admin)# show platform | (Optional)
Displays the state of all cards on the router. |
Examples
The following example shows commands to change a CSC:
RP/0/0/CPU0:router# admin RP/0/0/CPU0:router(admin)# show platform Node Type PLIM State Config State ----------------------------------------------------------------------------- 0/0/CPU0 PRP(Active) N/A IOS XR RUN PWR,NSHUT,MON 0/3/CPU0 L3LC Eng 3 OC3-POS-8 IOS XR RUN PWR,NSHUT,MON 0/4/CPU0 L3LC Eng 3 GE-4 IOS XR RUN PWR,NSHUT,MON 0/5/CPU0 L3LC Eng 3 GE-4 IOS XR RUN PWR,NSHUT,MON 0/6/CPU0 L3LC Eng 3 OC48-POS IOS XR RUN PWR,NSHUT,MON 0/7/CPU0 L3LC Eng 3 GE-4 IOS XR RUN PWR,NSHUT,MON 0/8/CPU0 L3LC Eng 3 OC12-POS-4 IOS XR RUN PWR,NSHUT,MON 0/16/CPU0 CSC10 N/A PWD PWR,NSHUT,MON 0/17/CPU0 CSC10(P) N/A PWD PWR,NSHUT,MON 0/18/CPU0 SFC10 N/A PWD PWR,NSHUT,MON 0/19/CPU0 SFC10 N/A PWD PWR,NSHUT,MON 0/20/CPU0 SFC10 N/A PWD PWR,NSHUT,MON 0/21/CPU0 SFC10 N/A PWD PWR,NSHUT,MON 0/22/CPU0 SFC10 N/A PWD PWR,NSHUT,MON 0/24/CPU0 ALARM10 N/A PWD PWR,NSHUT,MON 0/25/CPU0 ALARM10 N/A PWD PWR,NSHUT,MON 0/29/CPU0 GSR16-BLOWER N/A PWD PWR,NSHUT,MON RP/0/0/CPU0:router(admin)# configure RP/0/0/CPU0:router(admin-config)# hw-module location 0/16/CPU0 shutdown RP/0/0/CPU0:router(admin-config)# hw-module location 0/16/CPU0 power disable RP/0/0/CPU0:router(admin-config)# commit Primary Clock is CSC_1 Fabric Clock is Non Redundant Bandwidth Mode : Full Bandwidth RP/0/0/CPU0:router(admin-config)# end RP/0/0/CPU0:router(admin)# show platform Node Type PLIM State Config State ----------------------------------------------------------------------------- 0/0/CPU0 PRP(Active) N/A IOS XR RUN PWR,NSHUT,MON 0/3/CPU0 L3LC Eng 3 OC3-POS-8 IOS XR RUN PWR,NSHUT,MON 0/4/CPU0 L3LC Eng 3 GE-4 IOS XR RUN PWR,NSHUT,MON 0/5/CPU0 L3LC Eng 3 GE-4 IOS XR RUN PWR,NSHUT,MON 0/6/CPU0 L3LC Eng 3 OC48-POS IOS XR RUN PWR,NSHUT,MON 0/7/CPU0 L3LC Eng 3 GE-4 IOS XR RUN PWR,NSHUT,MON 0/8/CPU0 L3LC Eng 3 OC12-POS-4 IOS XR RUN PWR,NSHUT,MON 0/16/CPU0 CSC10 N/A Admin Down NPWR,SHUT,MON 0/17/CPU0 CSC10(P) N/A PWD PWR,NSHUT,MON 0/18/CPU0 SFC10 N/A PWD PWR,NSHUT,MON 0/19/CPU0 SFC10 N/A PWD PWR,NSHUT,MON 0/20/CPU0 SFC10 N/A PWD PWR,NSHUT,MON 0/21/CPU0 SFC10 N/A PWD PWR,NSHUT,MON 0/22/CPU0 SFC10 N/A PWD PWR,NSHUT,MON 0/24/CPU0 ALARM10 N/A PWD PWR,NSHUT,MON 0/25/CPU0 ALARM10 N/A PWD PWR,NSHUT,MON 0/29/CPU0 GSR16-BLOWER N/A PWD PWR,NSHUT,MON
Replace the CSC or SFC at this point.
RP/0/0/CPU0:router(admin)# configure RP/0/0/CPU0:router(admin-config)# no hw-module location 0/16/CPU0 power disable RP/0/0/CPU0:router(admin-config)# commit Primary Clock is CSC_1 Fabric Clock is Redundant Bandwidth Mode : Full Bandwidth RP/0/0/CPU0:router(admin-config)# end RP/0/0/CPU0:router(admin)# show platform Node Type PLIM State Config State ----------------------------------------------------------------------------- 0/0/CPU0 PRP(Active) N/A IOS XR RUN PWR,NSHUT,MON 0/3/CPU0 L3LC Eng 3 OC3-POS-8 IOS XR RUN PWR,NSHUT,MON 0/4/CPU0 L3LC Eng 3 GE-4 IOS XR RUN PWR,NSHUT,MON 0/5/CPU0 L3LC Eng 3 GE-4 IOS XR RUN PWR,NSHUT,MON 0/6/CPU0 L3LC Eng 3 OC48-POS IOS XR RUN PWR,NSHUT,MON 0/7/CPU0 L3LC Eng 3 GE-4 IOS XR RUN PWR,NSHUT,MON 0/8/CPU0 L3LC Eng 3 OC12-POS-4 IOS XR RUN PWR,NSHUT,MON 0/16/CPU0 CSC10 N/A Admin Down PWR,SHUT,MON 0/17/CPU0 CSC10(P) N/A PWD PWR,NSHUT,MON 0/18/CPU0 SFC10 N/A PWD PWR,NSHUT,MON 0/19/CPU0 SFC10 N/A PWD PWR,NSHUT,MON 0/20/CPU0 SFC10 N/A PWD PWR,NSHUT,MON 0/21/CPU0 SFC10 N/A PWD PWR,NSHUT,MON 0/22/CPU0 SFC10 N/A PWD PWR,NSHUT,MON 0/24/CPU0 ALARM10 N/A PWD PWR,NSHUT,MON 0/25/CPU0 ALARM10 N/A PWD PWR,NSHUT,MON 0/29/CPU0 GSR16-BLOWER N/A PWD PWR,NSHUT,MON RP/0/0/CPU0:router(admin)# configure RP/0/0/CPU0:router(admin-config)# no hw-module location 0/16/CPU0 shutdown RP/0/0/CPU0:router(admin-config)# commit RP/0/0/CPU0:router(admin-config)# end RP/0/0/CPU0:router(admin)# show platform Node Type PLIM State Config State ----------------------------------------------------------------------------- 0/0/CPU0 PRP(Active) N/A IOS XR RUN PWR,NSHUT,MON 0/3/CPU0 L3LC Eng 3 OC3-POS-8 IOS XR RUN PWR,NSHUT,MON 0/4/CPU0 L3LC Eng 3 GE-4 IOS XR RUN PWR,NSHUT,MON 0/5/CPU0 L3LC Eng 3 GE-4 IOS XR RUN PWR,NSHUT,MON 0/6/CPU0 L3LC Eng 3 OC48-POS IOS XR RUN PWR,NSHUT,MON 0/7/CPU0 L3LC Eng 3 GE-4 IOS XR RUN PWR,NSHUT,MON 0/8/CPU0 L3LC Eng 3 OC12-POS-4 IOS XR RUN PWR,NSHUT,MON 0/16/CPU0 CSC10 N/A PWD PWR,NSHUT,MON 0/17/CPU0 CSC10(P) N/A PWD PWR,NSHUT,MON 0/18/CPU0 SFC10 N/A PWD PWR,NSHUT,MON 0/19/CPU0 SFC10 N/A PWD PWR,NSHUT,MON 0/20/CPU0 SFC10 N/A PWD PWR,NSHUT,MON 0/21/CPU0 SFC10 N/A PWD PWR,NSHUT,MON 0/22/CPU0 SFC10 N/A PWD PWR,NSHUT,MON 0/24/CPU0 ALARM10 N/A PWD PWR,NSHUT,MON 0/25/CPU0 ALARM10 N/A PWD PWR,NSHUT,MON 0/29/CPU0 GSR16-BLOWER N/A PWD PWR,NSHUT,MON
Adding a Standby PRP to a Cisco XR 12000 Series Router
A second PRP card can be added to a Cisco XR 12000 Series Router for redundancy. To add a standby PRP, boot the card from ROMMON mode with the minimum boot image (MBI) software package. This will bring up the PRP so it can be recognized by the DSC. The new standby PRP will download the appropriate software and configurations from the DSC, and reboot.
This section provides instructions to boot the standby RP after it is installed in the chassis.
-
The standby Performance Route Processor (PRP) must be installed in a slot next to the active PRP. For example, the PRPs can be installed in slot 0 and slot 1, slot 2 and slot 3, slot 4 and slot 5, slot 6 and slot 7, slot 8 and slot 9, and so on.
- MBI software package mbiprp-rp.vm. This package is used to boot any PRP other than the DSC, including the standby PRP and PRPs in named SDRs.
- ROMMON version bfprp_romupgrade-1.14.0.91 or higher
- Boothelper version c12kprp-boot-mz.120-30.S or higher
- The boothelper must be stored as the first file in the bootflash, or the ROMMON variable must be set to point to the boothelper. To set the ROMMON variable, enter the following command in ROM Monitor mode: BOOTLDR=bootflash:/c12kprp-boot-mz.120-30.S
- Each PRP must have at least 1024 MB of memory installed. The PRP-2 ships with 1024 MB of memory. Upgrade the memory in your PRP, if necessary.
- Flash disks:
-
The recommended flash disk setup for all PRPs is two 512-MB Sandisk flash disk in PCMCIA slot 0 and slot 1. The minimum requirement is one 512-MB Sandisk flash disk installed in slot 0 on every physical PRP card in the system. PRP cards use the flash disk to store the Cisco IOS XR software and running configurations.
-
The same flash disk size must be used in all PRPs in the Cisco XR 12000 Series Router.
-
Each flash disk must be formatted by the Cisco IOS XR software before use. To format a disk, insert the disk into a running PRP and enter the command format filesystem .
Example: format disk0: .
-
1. Attach a terminal to the standby PRP console port, and place the PRP in ROM Monitor mode.
2.
unset
TURBOBOOT
3.
unset
BOOT
4.
sync
5.
boot
tftp://
server/directory/filename
6. Wait for boot process to complete.
7.
show
platform
8.
show
redundancy
DETAILED STEPS
| Command or Action | Purpose | |
|---|---|---|
| Step 1 | Attach a terminal to the standby PRP console port, and place the PRP in ROM Monitor mode. |
See Cisco IOS XR ROM Monitor Guide for the Cisco XR 12000 Series Router for more information. |
| Step 2 |
unset
TURBOBOOT
Example: rommon># unset turboboot |
Clears the TURBOBOOT variable. The TURBOBOOT variable is only used on the DSC. |
| Step 3 |
unset
BOOT
Example: rommon># unset BOOT |
Clears the boot variable. |
| Step 4 |
sync
Example: rommon># sync |
Saves the changes. |
| Step 5 |
boot
tftp://
server/directory/filename
Example: rommon># boot tftp://192.168.1.1/dir/mbiprp-rp.vm |
Retrieves the file from the TFTP server and installs it on disk0:. |
| Step 6 | Wait for boot process to complete. |
The standby PRP boots and all ROMMON variables (such as confreg and BOOT) are set. Once the standby PRP is recognized by the DSC, the appropriate software is downloaded and the standby PRP card reloads the Cisco IOS XR software from disk. |
| Step 7 |
show
platform
Example: RP/0/0/CPU0:router# show platform |
Displays the status of all cards. Enter this command on the active PRP. The active and standby PRPs are operating properly when the state for each card is "IOS XR RUN." |
| Step 8 |
show
redundancy
Example: RP/0/0/CPU0:router# show redundancy |
Displays the redundancy status of the PRP cards. Enter this command on the active PRP. When redundancy is fully established, the partner node is in “standby role” and the standby node is “ready.” |
Upgrading the CPU Controller Bits
Use this procedure to upgrade the CPU controller bits on all nodes that are installed in the router or on a specific node.
1.
admin
2.
upgrade
cpuctrlbits {all |
location
node-id}
DETAILED STEPS
| Command or Action | Purpose | |
|---|---|---|
| Step 1 |
admin
Example:
RP/0/0/CPU0:router# admin
|
Enters administration EXEC mode. |
| Step 2 |
upgrade
cpuctrlbits {all |
location
node-id}
Example:
RP/0/0/CPU0:router(admin)# upgrade cpuctrlbits all
|
Upgrades the CPU controller bits on all nodes in the router. Use the location node-id keyword and argument to upgrade the CPU controller bits on a specific node. |
Examples
The following example shows how to upgrade the CPU controller bits on all nodes in a router:
RP/0/0/CPU0:router# admin RP/0/0/CPU0:router(admin)# upgrade cpucrtlbits all Please do not power cycle, reload the router or reset any nodes until all upgrades are completed. Please check the syslog to make sure that all nodes are upgraded successfully. If you need to perform multiple upgrades, please wait for current upgrade to be completed before proceeding to another upgrade. Failure to do so may render the cards under upgrade to be unusable.
Additional References
The following sections provide references related to hardware management on Cisco IOS XR software.
Related Documents
|
Related Topic |
Document Title |
|---|---|
|
Cisco IOS XR hardware commands |
Hardware Redundancy and Node Administration Commands on the Cisco IOS XR Software module of Cisco IOS XR System Management Command Reference for the Cisco XR 12000 Series Router |
|
Cisco IOS XR hardware documentation |
See Cisco Carrier Routing System Install and Upgrade Guides at: http://www.cisco.com/en/US/products/ ps5763/prod_installation_guides_list.html |
|
Information about getting started with Cisco IOS XR software |
Cisco IOS XR Getting Started Guide for the Cisco XR 12000 Series Router |
|
ROM Monitor |
Cisco IOS XR ROM Monitor Guide for the Cisco XR 12000 Series Router |
|
Cisco IOS XR command master list |
Cisco IOS XR Commands Master List for the Cisco XR 12000 Series Router |
|
Information about user groups and task IDs |
Configuring AAA Services on the Cisco IOS XR Software module of Cisco IOS XR System Security Configuration Guide for the Cisco XR 12000 Series Router |
Standards
|
Standards |
Title |
|---|---|
|
No new or modified standards are supported by this feature, and support for existing standards has not been modified by this feature. |
— |
MIBs
|
MIBs |
MIBs Link |
|---|---|
| — |
To locate and download MIBs using Cisco IOS XR software, use the Cisco MIB Locator found at the following URL and choose a platform under the Cisco Access Products menu: http://cisco.com/public/sw-center/netmgmt/cmtk/mibs.shtml |
RFCs
|
RFCs |
Title |
|---|---|
|
No new or modified RFCs are supported by this feature, and support for existing RFCs has not been modified by this feature. |
— |
Technical Assistance
|
Description |
Link |
|---|---|
|
The Cisco Technical Support website contains thousands of pages of searchable technical content, including links to products, technologies, solutions, technical tips, and tools. Registered Cisco.com users can log in from this page to access even more content. |
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