- Book Index
- Preface
- Product Overview
- Command-Line Interfaces
- Configuring the Switch for the First Time
- Administering the Switch
- Configuring the Cisco IOS In-Service Software Upgrade Process
- Configuring the Cisco IOS XE In Service Software Upgrade Process
- Configuring Interfaces
- Checking Port Status and Connectivity
- Configuring Supervisor Engine Redundancy Using RPR and SSO on Supervisor Engine 6-E and 6L-E
- Configuring Supervisor Engine Redundancy Using RPR and SSO on Supervisor Engine 7-E and 7L-E
- Configuring Cisco NSF with SSO Supervisor Engine Redundancy
- Environmental Monitoring and Power Management
- Configuring Power over Ethernet
- Configuring the Catalyst 4500 Series Switch with Cisco Network Assistant
- Configuring VLANs, VTP, and VMPS
- Configuring IP Unnumbered Interface
- Configuring Layer 2 Ethernet Interfaces
- Configuring SmartPort Macros
- Configuring Auto SmartPort Macros
- Configuring STP and MST
- Configuring Flex Links and MAC Address-Table Move Update
- Configuring Resilient Ethernet Protocol
- Configuring Optional STP Features
- Configuring EtherChannel and Link State Tracking
- Configuring IGMP Snooping and Filtering
- Configuring IPv6 MLD Snooping
- Configuring 802.1Q Tunneling, VLAN Mapping, and Layer 2 Protocol Tunneling
- Configuring CDP
- Configuring LLDP, LLDP-MED, and Location Service
- Configuring UDLD
- Configuring Unidirectional Ethernet
- Configuring Layer 3 Interfaces
- Configuring Cisco Express Forwarding
- Configuring Unicast Reverse Path Forwarding
- Configuring IP Multicast
- Configuring ANCP Client
- Configuring Bidirectional Forwarding Detection
- Configuring Policy-Based Routing
- Configuring VRF-lite
- Configuring Quality of Service
- Configuring Voice Interfaces
- Configuring Private VLANs
- Configurig MACsec Encryption
- Configuring 802.1X Port-Based Authentication
- Configuring the PPPoE Intermediate Agent
- Configuring Web-Based Authentication
- Configuring Port Security
- Configuring Control Plane Policing and Layer 2 Control Packet QoS
- Configuring Dynamic ARP Inspection
- Configuring DHCP Snooping, IP Source Guard, and IPSG for Static Hosts
- Configuring Network Security with ACLs
- Support for IPv6
- Port Unicast and Multicast Flood Blocking
- Configuring Storm Control
- Configuring SPAN and RSPAN
- Configuring Wireshark
- Configuring Enhanced Object Tracking
- Configuring System Message Logging
- Configuring OBFL
- Configuring SNMP
- Configuring Netflow-lite
- Configuring Flexible NetFlow
- Configuring Ethernet OAM and CFM
- Configuring Y.1731 (AIS and RDI)
- Configuring Call Home
- Configuring Cisco IOS IP SLA Operations
- Configuring RMON
- Performing Diagnostics
- Configuring WCCP Version 2 Services
- Configuring MIB Support
- ROM Monitor
- Acronyms and Abbreviations
Onboard Failure Logging (OBFL)
•Configuration Examples for OBFL
Note For complete syntax and usage information for the commands used in this chapter, see these publications:
http://www.cisco.com/en/US/docs/ios/12_0s/feature/guide/12sobfl.html
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
Prerequisites for OBFL
None.
Restrictions for OBFL
They include:
•Software Restrictions—If a device (router or switch) intends to use linear flash memory as its OBFL storage media, Cisco IOS software must reserve a minimum of two physical sectors (or physical blocks) for the OBFL feature. Because an erase operation for a linear flash device is done on per-sector (or per-block) basis, one extra physical sector is needed. Otherwise, the minimum amount of space reserved for the OBFL feature on any device must be at least 8 KB.
•Firmware Restrictions—If a line card or port adapter runs an operating system or firmware that is different from the Cisco IOS operating system, the line card or port adapter must provide device driver level support or an interprocess communications (IPC) layer that allows the OBFL file system to communicate to the line card or port adapter. This requirement is enforced to allow OBFL data to be recorded on a storage device attached to the line card or port adapter.
•Hardware Restrictions—To support the OBFL feature, a device must have at least 8 KB of nonvolatile memory space reserved for OBFL data logging.
Information About OBFL
•Information about Data Collected by OBFL
Overview of OBFL
The Onboard Failure Logging (OBFL) feature collects data such as operating temperatures, hardware uptime, interrupts, and other important events and messages from system hardware installed in a Cisco router or switch. The data is stored in nonvolatile memory and helps technical personnel diagnose hardware problems.
Information about Data Collected by OBFL
OBFL Data Overview
The OBFL feature records operating temperatures, hardware uptime, interrupts, and other important events and messages that can assist with diagnosing problems with hardware cards (or modules) installed in a Cisco router or switch. Data is logged to files stored in nonvolatile memory. When the onboard hardware is started up, a first record is made for each area monitored and becomes a base value for subsequent records. The OBFL feature provides a circular updating scheme for collecting continuous records and archiving older (historical) records, ensuring accurate data about the system. Data is recorded in one of two formats: continuous information that displays a snapshot of measurements and samples in a continuous file, and summary information that provides details about the data being collected. The data is displayed using the show logging onboard command. The message "No historical data to display" is seen when historical data is not available.
Temperature
Temperatures surrounding hardware modules can exceed recommended safe operating ranges and cause system problems such as packet drops. Higher than recommended operating temperatures can also accelerate component degradation and affect device reliability. Monitoring temperatures is important for maintaining environmental control and system reliability. Once a temperature sample is logged, the sample becomes the base value for the next record. From that point on, temperatures are recorded either when there are changes from the previous record or if the maximum storage time is exceeded. Temperatures are measured and recorded in degrees Celsius.
Temperature Example
Switch# sh logging onboard temperature
--------------------------------------------------------------------------------
TEMPERATURE SUMMARY INFORMATION
--------------------------------------------------------------------------------
Number of sensors : 7
Sampling frequency : 1 minutes
Maximum time of storage : 10 minutes
--------------------------------------------------------------------------------
Sensor | ID | Maximum Temperature 0C
--------------------------------------------------------------------------------
Stub A 0 43
Stub B 1 37
XPP 2 51
VFE 3 61
NFE 4 50
CPU 5 55
FPGA 6 44
--------------------------------------
Temp Sensor ID
0C 1 2 3 4 5 6 7
--------------------------------------
1 9y 9y 9y 9y 9y 9y 9y
15 0m 71h 0m 0m 0m 0m 0m
16 0m 183h 0m 0m 0m 0m 0m
--------------------------------------
Temp Sensor ID
0C 1 2 3 4 5 6 7
--------------------------------------
17 0m 142m 0m 0m 0m 0m 0m
18 0m 190m 0m 0m 0m 0m 0m
19 0m 30m 0m 0m 0m 0m 0m
20 113h 0m 0m 0m 0m 0m 0m
21 37h 0m 0m 0m 0m 0m 101h
22 107h 0m 0m 0m 0m 0m 106h
23 110m 12m 0m 0m 0m 0m 47h
24 10m 122m 0m 0m 0m 0m 182m
25 0m 0m 0m 0m 0m 0m 120m
26 0m 56h 0m 0m 0m 0m 30m
27 0m 368h 0m 0m 0m 0m 0m
28 0m 8y 0m 0m 0m 0m 0m
29 134m 8y 0m 0m 139h 0m 0m
30 0m 682h 83h 0m 116h 0m 0m
31 90m 738h 31h 0m 200m 0m 95m
32 209h 935h 138h 0m 120m 141h 258h
33 331h 934h 192m 0m 0m 113h 316h
34 579h 8y 190m 0m 0m 182m 432h
35 17y 149h 80m 0m 0m 150m 8y
36 914h 20m 0m 0m 0m 10m 8y
37 838h 270m 0m 140h 26m 0m 8y
38 47d 0m 0m 102h 108m 0m 790h
39 8y 0m 0m 948m 20m 0m 421h
--------------------------------------
Temp Sensor ID
0C 1 2 3 4 5 6 7
--------------------------------------
40 414h 0m 2m 100m 78h 0m 288h
41 74h 0m 113h 40m 340h 134m 113h
42 10m 0m 380h 0m 198h 0m 446m
43 270m 0m 8y 0m 373h 0m 0m
44 0m 0m 8y 0m 683h 45h 10m
45 0m 0m 8y 2m 17y 274h 0m
46 0m 0m 897h 105m 64d 257h 0m
47 0m 0m 785h 27m 8y 169h 0m
48 0m 0m 639h 4m 319h 666h 0m
49 0m 0m 379h 92h 786m 17y 0m
50 0m 0m 94h 330h 270m 61d 0m
51 0m 0m 106m 192h 0m 48d 0m
52 0m 0m 0m 190h 0m 8y 0m
53 0m 0m 0m 573h 0m 227h 0m
54 0m 0m 0m 736h 0m 180m 0m
55 0m 0m 0m 716h 0m 260m 0m
56 0m 0m 0m 902h 0m 0m 0m
57 0m 0m 0m 8y 0m 0m 0m
58 0m 0m 0m 8y 0m 0m 0m
59 0m 0m 0m 8y 0m 0m 0m
60 0m 0m 0m 226h 0m 0m 0m
61 0m 0m 0m 629m 0m 0m 0m
Switch#
To interpret this data:
•Number of sensors is the total number of temperature sensors that will be recorded. A column for each sensor is displayed with temperatures listed under the number of each sensor, as available.
•Sampling frequency is the time between measurements.
•Maximum time of storage determines the maximum amount of time, in minutes, that can pass when the temperature remains unchanged and the data is not saved to storage media. After this time, a temperature record will be saved even if the temperature has not changed.
•The Sensor column lists the name of the sensor.
•The ID column lists an assigned identifier for the sensor.
•Maximum Temperature 0C shows the highest recorded temperature per sensor.
•Temp indicates a recorded temperature in degrees Celsius in the historical record. Columns following show the total time each sensor has recorded that temperature.
•Sensor ID is an assigned number, so that temperatures for the same sensor can be stored together.
Operational Uptime
The operational uptime tracking begins when the module is powered on, and information is retained for the life of the module.
Operational Uptime Example
Switch# sh logging onboard uptime detail
--------------------------------------------------------------------------------
UPTIME SUMMARY INFORMATION
--------------------------------------------------------------------------------
First customer power on : 04/13/2010 19:45:08
Total uptime : 1 years 34 weeks 3 days 12 hours 50 minutes
Total downtime : 1 years 7 weeks 3 days 18 hours 12 minutes
Number of resets : 1409
Number of slot changes : 19
Current reset reason : 0x0
Current reset timestamp : 01/29/2013 21:56:43
Current slot : 5
Current subslot : 0
Current uptime : 0 years 0 weeks 0 days 0 hours 20 minutes
--------------------------------------------------------------------------------
Reset | |
Reason | Count |
--------------------------------------------------------------------------------
No historical data to display
--------------------------------------------------------------------------------
--------------------------------------------------------------------------------
UPTIME CONTINUOUS INFORMATION
--------------------------------------------------------------------------------
Time Stamp | Reset | Uptime
MM/DD/YYYY HH:MM:SS | Reason | years weeks days hours minutes
--------------------------------------------------------------------------------
04/13/2010 19:45:08 0x0 0 0 0 0 0
04/13/2010 22:26:50 0x9 0 0 0 2 0
04/14/2010 18:54:42 0x9 0 0 0 20 0
04/14/2010 21:31:00 0x9 0 0 0 2 0
04/14/2010 22:04:15 0x9 0 0 0 0 25
04/14/2010 22:22:20 0x9 0 0 0 0 5
04/14/2010 23:05:58 0x9 0 0 0 0 5
04/15/2010 19:03:11 0x9 0 0 0 19 0
04/15/2010 21:29:22 0x9 0 0 0 2 0
04/15/2010 21:49:49 0x8 0 0 0 0 10
04/16/2010 18:46:03 0x9 0 0 0 20 0
04/16/2010 19:25:37 0x9 0 0 0 0 25
04/16/2010 19:34:59 0x9 0 0 0 0 0
04/16/2010 19:46:06 0x9 0 0 0 0 0
04/16/2010 19:57:16 0x9 0 0 0 0 5
04/16/2010 20:17:55 0x9 0 0 0 0 0
--------------------------------------------------------------------------------
Time Stamp | Reset | Uptime
MM/DD/YYYY HH:MM:SS | Reason | years weeks days hours minutes
--------------------------------------------------------------------------------
04/16/2010 20:31:28 0x9 0 0 0 0 0
04/16/2010 20:50:07 0x9 0 0 0 0 10
04/16/2010 22:45:15 0x9 0 0 0 0 0
04/18/2010 19:55:25 0x9 0 0 0 0 0
04/18/2010 20:01:52 0x9 0 0 0 0 0
04/19/2010 00:21:42 0x9 0 0 0 0 0
04/19/2010 01:20:33 0x0 0 0 0 0 30
04/19/2010 19:25:04 0x9 0 0 0 15 0
04/19/2010 20:05:04 0x9 0 0 0 0 15
04/19/2010 20:55:43 0x9 0 0 0 0 0
04/19/2010 21:11:52 0x9 0 0 0 0 0
04/19/2010 21:20:35 0x9 0 0 0 0 0
04/19/2010 21:39:45 0x9 0 0 0 0 10
04/19/2010 21:54:50 0x9 0 0 0 0 5
04/19/2010 22:11:48 0x9 0 0 0 0 5
04/19/2010 22:35:38 0x9 0 0 0 0 5
04/19/2010 22:49:41 0x9 0 0 0 0 0
04/19/2010 23:12:58 0x9 0 0 0 0 10
04/20/2010 00:36:04 0x9 0 0 0 1 0
04/20/2010 00:49:19 0x9 0 0 0 0 5
04/20/2010 00:58:29 0x9 0 0 0 0 0
04/20/2010 16:51:06 0x9 0 0 0 15 0
Switch#
The operational uptime application tracks the following events:
•Date and time the customer first powered on a component.
•Total uptime and downtime for the component in years, weeks, days, hours, and minutes.
•Total number of component resets.
•Total number of slot (module) changes.
•Current reset timestamp to include the date and time.
•Current slot (module) number of the component.
•Current uptime in years, weeks, days, hours, and minutes.
Interrupts
Interrupts are generated by system components that require attention from the CPU such as ASICs and NMIs. Interrupts are generally related to hardware limit conditions or errors that need to be corrected.
The continuous format records each time a component is interrupted, and this record is stored and used as base information for subsequent records. Each time the list is saved, a timestamp is added. Time differences from the previous interrupt are counted, so that technical personnel can gain a complete record of the component's operational history when an error occurs.
Interrupts Example
Switch# sh logging onboard interrupt detail
--------------------------------------------------------------------------------
INTERRUPT SUMMARY INFORMATION
--------------------------------------------------------------------------------
Name | ID | Offset | Bit | Count
--------------------------------------------------------------------------------
dropped 2 0x0004 0 27323
ipp 6 0x5A00 0 983763
ipp high 10 0x700A 0 34105
ipp low 11 0x9000 0 30211
--------------------------------------------------------------------------------
--------------------------------------------------------------------------------
CONTINUOUS INTERRUPT INFORMATION
--------------------------------------------------------------------------------
MM/DD/YYYY HH:MM:SS mmm | Name | ID | Offset | Bit
--------------------------------------------------------------------------------
12/12/2011 16:06:43 0 ipp high 10 0x7AEA 7
12/12/2011 16:06:43 0 dropped 2 0x0006 0
12/12/2011 16:06:46 0 ipp high 10 0x7AEC 0
12/12/2011 16:06:46 0 ipp high 10 0x7AEC 1
12/12/2011 16:06:46 0 ipp high 10 0x7AEC 4
12/12/2011 16:06:46 0 ipp high 10 0x7AEC 5
12/12/2011 16:06:46 0 ipp low 11 0xC000 0
12/12/2011 16:06:46 0 ipp low 11 0xC000 1
12/12/2011 16:06:46 0 ipp low 11 0xC000 4
12/12/2011 16:06:46 0 ipp low 11 0xC000 5
12/12/2011 16:06:46 0 ipp high 10 0x7AEA 0
12/12/2011 16:06:46 0 ipp high 10 0x7AEA 2
12/12/2011 16:06:46 0 ipp high 10 0x7AEA 3
12/12/2011 16:06:46 0 ipp high 10 0x7AEA 4
12/12/2011 16:06:46 0 ipp high 10 0x7AEA 6
12/12/2011 16:06:46 0 ipp high 10 0x7AEA 7
12/12/2011 16:06:46 0 dropped 2 0x0006 0
12/12/2011 16:06:49 0 ipp high 10 0x7AEC 0
12/12/2011 16:06:49 0 ipp high 10 0x7AEC 1
--------------------------------------------------------------------------------
Switch#
To interpret this data:
•Name is a description of the component including its position in the device.
•ID is an assigned field for data storage.
•Offset is the register offset from a component register's base address.
•Bit is the interrupt bit number recorded from the component's internal register.
•The timestamp shows the date and time that an interrupt occurred down to the millisecond.
Message Logging
The OBFL feature logs standard system messages. Instead of displaying the message to a terminal, the message is written to and stored in a file, so the message can be accessed and read at a later time. System messages range from level 1 alerts to level 7 debug messages, and these levels can be specified in the hw module logging onboard command.
Error Message Log Example
Switch# sh logging onboard message det
--------------------------------------------------------------------------------
ERROR MESSAGE SUMMARY INFORMATION
--------------------------------------------------------------------------------
Facility-Sev-Name | Count | Persistence Flag
MM/DD/YYYY HH:MM:SS
--------------------------------------------------------------------------------
%CAT4K-3-DIAGNOSTICS_PASSED : 22 LAST
11/24/2010 15:46:20 module passed diagnostics
%CAT4K-2-DIAGNOSTIC_STATUS : 22 LAST
11/24/2010 15:46:20 diagnostic Packet memory Skipped
--------------------------------------------------------------------------------
--------------------------------------------------------------------------------
ERROR MESSAGE CONTINUOUS INFORMATION
--------------------------------------------------------------------------------
MM/DD/YYYY HH:MM:SS Facility-Sev-Name
--------------------------------------------------------------------------------
12/15/2010 11:32:39 %CAT4K-3-DIAGNOSTICS_PASSED : module passed diagnostics
12/15/2010 11:32:39 %CAT4K-2-DIAGNOSTIC_STATUS : diagnostic Packet memory Skipped
12/15/2010 13:03:41 %CAT4K-3-DIAGNOSTICS_PASSED : module passed diagnostics
12/15/2010 13:03:41 %CAT4K-2-DIAGNOSTIC_STATUS : diagnostic Packet memory Skipped
12/15/2010 13:25:02 %CAT4K-3-DIAGNOSTICS_PASSED : module passed diagnostics
12/15/2010 13:25:02 %CAT4K-2-DIAGNOSTIC_STATUS : diagnostic Packet memory Skipped
12/15/2010 13:45:34 %CAT4K-3-DIAGNOSTICS_PASSED : module passed diagnostics
12/15/2010 13:45:34 %CAT4K-2-DIAGNOSTIC_STATUS : diagnostic Packet memory Skipped
12/15/2010 14:05:01 %CAT4K-3-DIAGNOSTICS_PASSED : module passed diagnostics
12/15/2010 14:05:01 %CAT4K-2-DIAGNOSTIC_STATUS : diagnostic Packet memory Skipped
12/15/2010 14:35:51 %CAT4K-3-DIAGNOSTICS_PASSED : module passed diagnostics
12/15/2010 14:35:51 %CAT4K-2-DIAGNOSTIC_STATUS : diagnostic Packet memory Skipped
--------------------------------------------------------------------------------
Switch#
To interpret this data:
•A timestamp shows the date and time the message was logged.
•Facility-Sev-Name is a coded naming scheme for a system message, as follows:
–The Facility code consists of two or more uppercase letters that indicate the hardware device (facility) to which the message refers.
–Sev is a single-digit code from 1 to 7 that reflects the severity of the message.
–Name is one or two code names separated by a hyphen that describe the part of the system from where the message is coming.
•The error message follows the Facility-Sev-Name codes. For more information about system messages, see the Cisco IOS System and Error Messages guide.
•Count indicates the number of instances of this message that is allowed in the history file. Once that number of instances has been recorded, the oldest instance will be removed from the history file to make room for new ones.
•The Persistence Flag gives a message priority over others that do not have the flag set.
Default Settings for OBFL
The OBFL feature is enabled by default. Because of the valuable information this feature offers technical personnel, it should not be disabled.
Enabling OBFL
To enable OBFL, perform this task:
Configuration Examples for OBFL
The important OBFL feature is the information that is displayed by the show logging onboard module privileged EXEC command. This section provides the following examples of how to enable and display OBFL records.
•Enabling OBFL Message Logging: Example
•OBFL Component Uptime Report: Example
•OBFL Report for a Specific Time: Example
Enabling OBFL Message Logging: Example
The following example shows how to configure OBFL message logging at level 3:
Router(config)# hw-module module 1 logging onboard message level 3
OBFL Message Log: Example
The following example shows how to display the system messages that are being logged for module 2:
Switch# show logging onboard module 2 message continuous
----------------------------------------------------------------------------- ---
ERROR MESSAGE CONTINUOUS INFORMATION
----------------------------------------------------------------------------- ---
MM/DD/YYYY HH:MM:SS Facility-Sev-Name
----------------------------------------------------------------------------- ---
12/13/2012 18:12:32 %CAT4K-3-DIAGNOSTICS_PASSED : module passed diagnostics
12/14/2012 17:50:55 %CAT4K-3-DIAGNOSTICS_PASSED : module passed diagnostics
12/20/2012 17:45:55 %CAT4K-3-DIAGNOSTICS_PASSED : module passed diagnostics
12/20/2012 19:55:27 %CAT4K-3-DIAGNOSTICS_PASSED : module passed diagnostics
12/20/2012 20:37:27 %CAT4K-3-DIAGNOSTICS_PASSED : module passed diagnostics
12/21/2012 16:09:15 %CAT4K-3-DIAGNOSTICS_PASSED : module passed diagnostics
01/07/2013 02:43:06 %CAT4K-3-DIAGNOSTICS_PASSED : module passed diagnostics
01/07/2013 04:59:38 %CAT4K-3-DIAGNOSTICS_PASSED : module passed diagnostics
01/16/2013 15:36:34 %CAT4K-3-DIAGNOSTICS_PASSED : module passed diagnostics
01/17/2013 12:41:44 %CAT4K-3-DIAGNOSTICS_PASSED : module passed diagnostics
01/18/2013 14:03:24 %CAT4K-3-DIAGNOSTICS_PASSED : module passed diagnostics
01/18/2013 14:16:09 %CAT4K-3-DIAGNOSTICS_PASSED : module passed diagnostics
01/18/2013 14:21:59 %CAT4K-3-DIAGNOSTICS_PASSED : module passed diagnostics
01/18/2013 15:23:04 %CAT4K-3-DIAGNOSTICS_PASSED : module passed diagnostics
01/18/2013 15:41:29 %CAT4K-3-DIAGNOSTICS_PASSED : module passed diagnostics
01/22/2013 14:59:10 %CAT4K-3-DIAGNOSTICS_PASSED : module passed diagnostics
01/24/2013 11:47:27 %CAT4K-3-DIAGNOSTICS_PASSED : module passed diagnostics
01/24/2013 16:40:58 %CAT4K-3-DIAGNOSTICS_PASSED : module passed diagnostics
-----------------------------------------------------------------------------
Switch#
OBFL Component Uptime Report: Example
The following example shows how to display a summary report for component uptimes for module 2:
Switch# show logging onboard module 2 uptime
----------------------------------------------------------------------------- ---
UPTIME SUMMARY INFORMATION
----------------------------------------------------------------------------- ---
First customer power on : 12/13/2012 18:12:53
Total uptime : 0 years 0 weeks 4 days 15 hours 55 minutes
Total downtime : 0 years 6 weeks 0 days 12 hours 18 minutes
Number of resets : 20
Number of slot changes : 1
Current reset reason : 0x0
Current reset timestamp : 01/29/2013 21:56:18
Current slot : 2
Current subslot : 0
Current uptime : 0 years 0 weeks 0 days 0 hours 30 minutes
----------------------------------------------------------------------------- ---
Reset | |
Reason | Count |
----------------------------------------------------------------------------- ---
No historical data to display
-------------------------------------------------------------------------
Switch#
OBFL Report for a Specific Time: Example
The following example shows how to display continuous reports for all components during a specific time period:
Switch# show logging onboard module 2 continuous start 18:12:32 13 Dec 2012 end 16:40:58
24 Jan 2013
PID: WS-C4510R+E , VID: 6 , SN: FOX1503GL5V
--------------------------------------------------------------------------------
UPTIME CONTINUOUS INFORMATION
--------------------------------------------------------------------------------
Time Stamp | Reset | Uptime
MM/DD/YYYY HH:MM:SS | Reason | years weeks days hours minutes
--------------------------------------------------------------------------------
12/13/2012 18:12:53 0x0 0 0 0 0 0
12/14/2012 17:51:14 0x0 0 0 0 23 0
12/20/2012 17:45:52 0x0 0 0 0 1 0
12/20/2012 19:55:22 0x0 0 0 0 2 0
12/20/2012 20:37:26 0x0 0 0 0 0 40
12/21/2012 16:09:14 0x0 0 0 0 0 10
01/07/2013 02:43:04 0x0 0 0 0 2 0
01/07/2013 04:59:35 0x0 0 0 0 2 0
01/16/2013 15:36:32 0x0 0 0 1 17 0
01/17/2013 12:41:42 0x0 0 0 0 3 0
01/18/2013 14:03:21 0x0 0 0 1 1 0
01/18/2013 14:16:08 0x0 0 0 0 0 10
01/18/2013 14:21:58 0x0 0 0 0 0 0
01/18/2013 15:23:02 0x0 0 0 0 1 0
01/18/2013 15:41:25 0x0 0 0 0 0 15
01/22/2013 14:59:05 0x0 0 0 0 3 0
--------------------------------------------------------------------------------
Time Stamp | Reset | Uptime
MM/DD/YYYY HH:MM:SS | Reason | years weeks days hours minutes
--------------------------------------------------------------------------------
01/24/2013 11:47:25 0x0 0 0 0 3 0
01/24/2013 16:40:56 0x0 0 0 0 3 0
--------------------------------------------------------------------------------
--------------------------------------------------------------------------------
ENVIRONMENT CONTINUOUS INFORMATION
--------------------------------------------------------------------------------
MM/DD/YYYY HH:MM:SS Device Name IOS Version F/W Ver RAM(KB) Event
------------------------------------------------------------
VID PID TAN Serial No
--------------------------------------------------------------------------------
12/13/2012 18:12:57 slot-2: NA NA 0 Inserted
Cis WS-C4510R+E NA FOX1503GL5V
12/14/2012 17:50:55 slot-2: NA NA 0 Inserted
Cis WS-C4510R+E NA FOX1503GL5V
12/20/2012 17:45:55 slot-2: NA NA 0 Inserted
Cis WS-C4510R+E NA FOX1503GL5V
12/20/2012 19:55:27 slot-2: NA NA 0 Inserted
Cis WS-C4510R+E NA FOX1503GL5V
12/20/2012 20:37:27 slot-2: NA NA 0 Inserted
Cis WS-C4510R+E NA FOX1503GL5V
12/21/2012 16:09:15 slot-2: NA NA 0 Inserted
Cis WS-C4510R+E NA FOX1503GL5V
01/07/2013 02:43:06 slot-2: NA NA 0 Inserted
Cis WS-C4510R+E NA FOX1503GL5V
01/07/2013 04:59:38 slot-2: NA NA 0 Inserted
--------------------------------------------------------------------------------
ENVIRONMENT CONTINUOUS INFORMATION
--------------------------------------------------------------------------------
MM/DD/YYYY HH:MM:SS Device Name IOS Version F/W Ver RAM(KB) Event
------------------------------------------------------------
VID PID TAN Serial No
--------------------------------------------------------------------------------
Cis WS-C4510R+E NA FOX1503GL5V
01/16/2013 15:36:34 slot-2: NA NA 0 Inserted
Cis WS-C4510R+E NA FOX1503GL5V
01/17/2013 12:41:44 slot-2: NA NA 0 Inserted
Cis WS-C4510R+E NA FOX1503GL5V
01/18/2013 14:03:24 slot-2: NA NA 0 Inserted
Cis WS-C4510R+E NA FOX1503GL5V
01/18/2013 14:16:09 slot-2: NA NA 0 Inserted
Cis WS-C4510R+E NA FOX1503GL5V
01/18/2013 14:21:59 slot-2: NA NA 0 Inserted
Cis WS-C4510R+E NA FOX1503GL5V
01/18/2013 15:23:04 slot-2: NA NA 0 Inserted
Cis WS-C4510R+E NA FOX1503GL5V
01/18/2013 15:41:29 slot-2: NA NA 0 Inserted
Cis WS-C4510R+E NA FOX1503GL5V
01/22/2013 14:59:10 slot-2: NA NA 0 Inserted
Cis WS-C4510R+E NA FOX1503GL5V
01/24/2013 11:47:27 slot-2: NA NA 0 Inserted
Cis WS-C4510R+E NA FOX1503GL5V
01/24/2013 16:40:58 slot-2: NA NA 0 Inserted
Cis WS-C4510R+E NA FOX1503GL5V
--------------------------------------------------------------------------------
--------------------------------------------------------------------------------
TEMPERATURE CONTINUOUS INFORMATION
--------------------------------------------------------------------------------
Sensor | ID |
--------------------------------------------------------------------------------
Air inlet 0
Air inlet remote 1
Air outlet 2
Air outlet remote 3
--------------------------------------------
Time Stamp |Sensor Temperature 0C
MM/DD/YYYY HH:MM:SS | 0 1 2 3
--------------------------------------------
01/18/2013 12:18:59 32 23 33 27
01/18/2013 12:28:59 32 23 33 27
01/18/2013 12:38:59 32 23 33 27
01/18/2013 12:48:00 32 23 33 27
01/18/2013 12:58:00 32 23 33 27
01/18/2013 13:08:00 32 23 33 27
01/18/2013 13:18:00 32 23 33 27
01/18/2013 13:28:00 32 23 33 27
01/18/2013 13:38:00 32 23 33 27
01/18/2013 13:48:00 32 23 33 27
01/18/2013 13:58:00 32 23 33 27
01/18/2013 14:03:21 30 23 31 27
01/18/2013 14:12:22 32 23 33 27
01/18/2013 14:16:08 30 23 31 27
01/18/2013 14:21:58 30 23 31 26
01/18/2013 14:31:58 32 23 33 28
01/18/2013 14:40:59 32 23 33 28
--------------------------------------------
Time Stamp |Sensor Temperature 0C
MM/DD/YYYY HH:MM:SS | 0 1 2 3
--------------------------------------------
01/18/2013 14:47:04 26 23 26 25
01/18/2013 14:57:04 24 22 24 23
01/18/2013 15:07:04 24 22 24 23
01/18/2013 15:17:04 24 22 24 23
01/18/2013 15:23:03 25 22 26 23
01/18/2013 15:25:03 30 22 31 25
01/18/2013 15:35:03 32 23 33 27
01/18/2013 15:41:25 30 23 31 26
01/18/2013 15:51:25 32 23 33 27
01/18/2013 16:00:27 32 23 33 27
01/18/2013 16:10:27 32 23 33 27
01/18/2013 16:20:27 32 23 33 28
01/18/2013 16:30:27 32 23 33 27
01/18/2013 16:40:27 32 23 33 27
01/18/2013 16:50:27 32 23 33 27
01/18/2013 17:00:27 31 23 33 27
01/18/2013 17:10:27 32 23 33 27
01/18/2013 17:20:27 32 23 33 27
01/18/2013 17:30:27 31 23 33 27
01/18/2013 17:40:27 31 23 33 27
01/18/2013 17:50:27 31 23 33 28
01/18/2013 18:00:27 32 24 34 30
01/18/2013 18:09:28 32 24 34 31
--------------------------------------------
Time Stamp |Sensor Temperature 0C
MM/DD/YYYY HH:MM:SS | 0 1 2 3
--------------------------------------------
01/18/2013 18:19:28 33 24 35 32
01/18/2013 18:29:28 33 25 35 33
01/18/2013 18:39:28 32 25 36 34
01/18/2013 18:49:28 32 25 36 34
01/18/2013 18:54:28 34 26 39 39
01/18/2013 19:04:28 35 27 42 44
01/18/2013 19:14:28 35 27 42 44
01/22/2013 14:59:05 25 22 26 22
01/22/2013 15:02:05 30 23 31 26
01/22/2013 15:09:06 32 24 34 31
01/22/2013 15:12:06 33 26 37 36
01/22/2013 15:15:06 34 27 40 41
01/22/2013 15:25:06 36 28 43 46
01/22/2013 15:35:06 36 28 43 46
01/22/2013 15:45:06 36 28 43 46
01/22/2013 15:55:06 36 28 44 46
01/22/2013 16:05:06 36 28 43 46
01/22/2013 16:14:07 36 28 43 46
01/22/2013 16:24:07 35 28 43 46
01/22/2013 16:34:07 36 28 44 46
01/22/2013 16:44:07 36 28 43 46
01/22/2013 16:54:07 36 28 43 46
01/22/2013 16:58:07 34 26 41 41
--------------------------------------------
Time Stamp |Sensor Temperature 0C
MM/DD/YYYY HH:MM:SS | 0 1 2 3
--------------------------------------------
01/22/2013 17:00:07 32 24 37 34
01/22/2013 17:10:07 31 24 34 32
01/22/2013 17:20:07 31 23 34 30
01/22/2013 17:30:07 32 24 35 33
01/22/2013 17:40:07 32 24 35 33
01/22/2013 17:49:08 32 24 35 33
01/22/2013 17:59:08 32 24 35 33
01/24/2013 11:47:25 26 22 26 23
01/24/2013 11:49:25 30 24 31 28
01/24/2013 11:56:25 33 25 35 33
01/24/2013 12:06:25 32 25 35 33
01/24/2013 12:16:25 33 25 35 33
01/24/2013 12:26:25 33 25 35 33
01/24/2013 12:36:25 33 25 36 33
01/24/2013 12:46:25 33 25 36 33
01/24/2013 12:56:25 34 27 39 38
01/24/2013 13:01:25 35 28 42 43
01/24/2013 13:11:25 36 29 44 46
01/24/2013 13:21:25 37 29 45 47
01/24/2013 13:30:26 37 29 45 47
01/24/2013 13:40:26 37 29 45 47
01/24/2013 13:50:26 37 29 45 47
01/24/2013 14:00:26 36 29 45 47
--------------------------------------------
Time Stamp |Sensor Temperature 0C
MM/DD/YYYY HH:MM:SS | 0 1 2 3
--------------------------------------------
01/24/2013 14:10:26 37 29 45 47
01/24/2013 14:20:26 37 29 45 47
01/24/2013 14:30:26 36 28 43 45
01/24/2013 14:32:26 34 26 39 39
01/24/2013 14:38:26 33 25 36 33
01/24/2013 14:48:26 34 26 37 36
01/24/2013 14:58:26 34 26 38 36
01/24/2013 15:08:26 34 26 38 37
01/24/2013 15:17:27 34 26 38 37
01/24/2013 15:27:27 34 26 38 37
01/24/2013 16:40:56 26 22 27 24
--------------------------------------------
--------------------------------------------------------------------------------
ERROR MESSAGE CONTINUOUS INFORMATION
--------------------------------------------------------------------------------
MM/DD/YYYY HH:MM:SS Facility-Sev-Name
--------------------------------------------------------------------------------
12/13/2012 18:12:32 %CAT4K-3-DIAGNOSTICS_PASSED : module passed diagnostics
12/14/2012 17:50:55 %CAT4K-3-DIAGNOSTICS_PASSED : module passed diagnostics
12/20/2012 17:45:55 %CAT4K-3-DIAGNOSTICS_PASSED : module passed diagnostics
12/20/2012 19:55:27 %CAT4K-3-DIAGNOSTICS_PASSED : module passed diagnostics
12/20/2012 20:37:27 %CAT4K-3-DIAGNOSTICS_PASSED : module passed diagnostics
12/21/2012 16:09:15 %CAT4K-3-DIAGNOSTICS_PASSED : module passed diagnostics
01/07/2013 02:43:06 %CAT4K-3-DIAGNOSTICS_PASSED : module passed diagnostics
01/07/2013 04:59:38 %CAT4K-3-DIAGNOSTICS_PASSED : module passed diagnostics
01/16/2013 15:36:34 %CAT4K-3-DIAGNOSTICS_PASSED : module passed diagnostics
01/17/2013 12:41:44 %CAT4K-3-DIAGNOSTICS_PASSED : module passed diagnostics
01/18/2013 14:03:24 %CAT4K-3-DIAGNOSTICS_PASSED : module passed diagnostics
01/18/2013 14:16:09 %CAT4K-3-DIAGNOSTICS_PASSED : module passed diagnostics
01/18/2013 14:21:59 %CAT4K-3-DIAGNOSTICS_PASSED : module passed diagnostics
01/18/2013 15:23:04 %CAT4K-3-DIAGNOSTICS_PASSED : module passed diagnostics
01/18/2013 15:41:29 %CAT4K-3-DIAGNOSTICS_PASSED : module passed diagnostics
01/22/2013 14:59:10 %CAT4K-3-DIAGNOSTICS_PASSED : module passed diagnostics
01/24/2013 11:47:27 %CAT4K-3-DIAGNOSTICS_PASSED : module passed diagnostics
--------------------------------------------------------------------------------
ERROR MESSAGE CONTINUOUS INFORMATION
--------------------------------------------------------------------------------
MM/DD/YYYY HH:MM:SS Facility-Sev-Name
--------------------------------------------------------------------------------
01/24/2013 16:40:58 %CAT4K-3-DIAGNOSTICS_PASSED : module passed diagnostics
--------------------------------------------------------------------------------
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