Catalyst 6500 Series MSFC Command Reference 12.1E

User Manual: Catalyst 6500 Series MSFC Command Reference 12.1E

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Catalyst 6500 Series Switch
MSFC Command Reference
Cisco IOS Release 12.1(13)E
Text Part Number: OL-3354-01
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Catalyst 6500 Series Switch MSFC Command Reference
Copyright © 2002–2003 Cisco Systems, Inc. All rights reserved.
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CONTENTS
Preface vii
Audience vii
Organization vii
Related Documentation vii
Conventions viii
Obtaining Documentation ix
Obtaining Technical Assistance x
Obtaining Additional Publications and Information xii
CHAPTER
1Command-Line Interface 1-1
Getting Help 1-1
How to Find Command Options 1-2
Using the No and Default Forms of Commands 1-5
Using the CLI String Search 1-5
Saving Configuration Changes 1-11
MSFC CLI 1-11
CHAPTER
2Catalyst 6500 Series Switch MSFC Commands 2-1
clear ip auth-proxy watch-list 2-2
config-register 2-3
config-sync 2-4
define interface-range 2-5
high-availability 2-6
interface range 2-8
ip address 2-10
ip auth-proxy max-login-attempts 2-12
ip auth-proxy watch-list 2-13
ip local-proxy-arp 2-15
ip multicast rpf backoff 2-16
ip multicast rpf interval 2-18
ip verify unicast source reachable-via 2-19
ip wccp redirect 2-21
Contents
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ipx network 2-23
maximum-paths 2-27
mls aclmerge algorithm 2-28
mls ip 2-30
mls ip cef load-sharing full 2-31
mls ip cef rate-limit 2-32
mls ip delete-threshold 2-34
mls ip inspect 2-35
mls ip install-threshold 2-36
mls ip multicast consistency-check 2-37
mls ip multicast stub 2-39
mtu 2-40
redundancy 2-42
set traffic-index 2-43
show fm features 2-44
show fm inband-counters 2-46
show fm insp 2-47
show fm interface 2-48
show fm reflexive 2-50
show fm summary 2-51
show fm vlan 2-52
show ip auth-proxy watch-list 2-54
show ip wccp web-cache detail 2-55
show l3-mgr 2-57
show microcode 2-59
show msfc2 rom-monitor 2-60
show redundancy 2-61
show scp 2-62
show slot0: 2-64
show standby delay 2-67
snmp-server enable traps 2-68
standby delay minimum reload 2-71
standby ip 2-73
standby track 2-75
upgrade rom-monitor 2-77
Contents
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APPENDIX
AAcronyms A-1
APPENDIX
BAcknowledgments for Open-Source Software B-1
I
NDEX
Contents
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Preface
This preface describes the audience, organization, and conventions of this publication, and provides
information on how to obtain related documentation.
Audience
This publication is for experienced network administrators who are responsible for configuring and
maintaining Catalyst 6500 series switches.
Organization
This publication is organized as follows:
Related Documentation
The Catalyst 6500 series switch Cisco IOS documentation set includes these documents:
Catalyst 6500 Series Switch Module Installation Guide
Catalyst 6500 Series Switch IOS Software Configuration Guide
Catalyst 6500 Series Switch IOS System Message Guide
Release Notes for Catalyst 6500 Series Switch IOS Software Release X.X
Chapter Title Description
Chapter 1 Command-Line Interface Describes the Multilayer Switching Feature
Card command-line interface.
Chapter 2 Catalyst 6500 Series Switch
MSFC Commands Lists alphabetically and provides detailed
information for MSFC-specific commands.
Appendix A Acronyms Defines the acronyms used in this
publication.
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Preface
Conventions
The Cisco IOS documentation set includes these documents:
Configuration Fundamentals Configuration Guide
Command Reference
For information about MIBs, refer to this URL:
http://www.cisco.com/public/sw-center/netmgmt/cmtk/mibs.shtml
Conventions
This document uses the following conventions:
Notes use the following conventions:
Note Means reader take note. Notes contain helpful suggestions or references to material not covered in
the publication.
Convention Description
boldface font Commands, command options, and keywords are in
boldface.
italic font Arguments for which you supply values are in italics.
[ ] Elements in square brackets are optional.
{ x | y | z } Alternative keywords are grouped in braces and separated by
vertical bars. Braces can also be used to group keywords
and/or aguments; for example, {interface interface type}.
[ x | y | z ] Optional alternative keywords are grouped in brackets and
separated by vertical bars.
string A nonquoted set of characters. Do not use quotation marks
around the string or the string will include the quotation
marks.
screen font Terminal sessions and information the system displays are in
screen font.
boldface screen
font Information you must enter is in boldface screen font.
italic screen font Arguments for which you supply values are in italic screen
font.
^ The symbol ^ represents the key labeled Control—for
example, the key combination ^D in a screen display means
hold down the Control key while you press the D key.
< > Nonprinting characters, such as passwords are in angle
brackets.
[ ] Default responses to system prompts are in square brackets.
!, # An exclamation point (!) or a pound sign (#) at the beginning
of a line of code indicates a comment line.
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Preface Obtaining Documentation
Cautions use the following conventions:
Caution Means reader be careful. In this situation, you might do something that could result in equipment
damage or loss of data.
Obtaining Documentation
Cisco provides several ways to obtain documentation, technical assistance, and other technical
resources. These sections explain how to obtain technical information from Cisco Systems.
Cisco.com
You can access the most current Cisco documentation on the World Wide Web at this URL:
http://www.cisco.com/univercd/home/home.htm
You can access the Cisco website at this URL:
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International Cisco websites can be accessed from this URL:
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Cisco documentation and additional literature are available in a Cisco Documentation CD-ROM
package, which may have shipped with your product. The Documentation CD-ROM is updated regularly
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or through an annual or quarterly subscription.
Registered Cisco.com users can order a single Documentation CD-ROM (product number
DOC-CONDOCCD=) through the Cisco Ordering tool:
http://www.cisco.com/en/US/partner/ordering/ordering_place_order_ordering_tool_launch.html
All users can order monthly or quarterly subscriptions through the online Subscription Store:
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You can find instructions for ordering documentation at this URL:
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You can order Cisco documentation in these ways:
Registered Cisco.com users (Cisco direct customers) can order Cisco product documentation from
the Networking Products MarketPlace:
http://www.cisco.com/en/US/partner/ordering/index.shtml
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Preface
Obtaining Technical Assistance
Nonregistered Cisco.com users can order documentation through a local account representative by
calling Cisco Systems Corporate Headquarters (California, U.S.A.) at 408 526-7208 or, elsewhere
in North America, by calling 800 553-NETS (6387).
Documentation Feedback
You can submit comments electronically on Cisco.com. On the Cisco Documentation home page, click
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You can e-mail your comments to bug-doc@cisco.com.
You can submit comments by using the response card (if present) behind the front cover of your
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We appreciate your comments.
Obtaining Technical Assistance
Cisco provides Cisco.com, which includes the Cisco Technical Assistance Center (TAC) website, as a
starting point for all technical assistance. Customers and partners can obtain online documentation,
troubleshooting tips, and sample configurations from the Cisco TAC website. Cisco.com registered
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Cisco.com provides a broad range of features and services to help you with these tasks:
Streamline business processes and improve productivity
Resolve technical issues with online support
Download and test software packages
Order Cisco learning materials and merchandise
Register for online skill assessment, training, and certification programs
To obtain customized information and service, you can self-register on Cisco.com at this URL:
http://tools.cisco.com/RPF/register/register.do
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Preface Obtaining Technical Assistance
Technical Assistance Center
The Cisco TAC is available to all customers who need technical assistance with a Cisco product,
technology, or solution. Two types of support are available: the Cisco TAC website and the Cisco TAC
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Cisco TAC Website
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Obtaining Additional Publications and Information
Before calling, please check with your network operations center to determine the Cisco support services
to which your company is entitled: for example, SMARTnet, SMARTnet Onsite, or Network Supported
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CHAPTER
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1
Command-Line Interface
This chapter provides information for understanding and using the Catalyst 6500 series switch
Cisco IOS software using the command-line interface (CLI). This chapter includes the following
sections:
Getting Help, page 1-1
How to Find Command Options, page 1-2
MSFC CLI, page 1-11
For an overview of the Catalyst 6500 series switch Cisco IOS software configuration, refer to the
Catalyst 6500 Series IOS Software Configuration Guide.
Getting Help
To obtain a list of commands that are available for each command mode, enter a question mark (?) at the
system prompt. You also can obtain a list of any command’s associated keywords and arguments with
the context-sensitive help feature.
Table 1-1 lists commands you can enter to get help that is specific to a command mode, a command, a
keyword, or an argument.
Table 1-1 Getting Help
Command Purpose
abbreviated-command-entry?Obtain a list of commands that begin with a
particular character string. (Do not leave a space
between the command and question mark.)
abbreviated-command-entry<Tab> Complete a partial command name.
? List all commands available for a particular
command mode.
command ? List a command’s associated keywords. Leave a
space between the command and question mark.
command keyword ? List a keyword’s associated arguments. Leave a
space between the keyword and question mark.
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Chapter 1 Command-Line Interface
How to Find Command Options
How to Find Command Options
This section provides an example of how to display syntax for a command. The syntax can consist of
optional or required keywords. To display keywords for a command, enter a question mark (?) at the
configuration prompt or after entering part of a command followed by a space. The Catalyst 6500 series
switch software displays a list of available keywords along with a brief description of the keywords. For
example, if you are in global configuration mode and want to see all the keywords for the arap
command, you enter arap ?.
Table 1-2 shows examples of how you can use the question mark (?) to assist you in entering commands
and also guides you through entering the following commands:
interface gigabitethernet 1/1
channel-group 1 mode auto
Table 1-2 How to Find Command Options
Command Comment
Router> enable
Password: <password>
Router#
Enter the enable command and
password to access privileged EXEC
commands.
You are in privileged EXEC mode
when the prompt changes to Router#.
Router# configure terminal
Enter configuration commands, one per line. End with CNTL/Z.
Router(config)#
Enter global configuration mode.
You are in global configuration mode
when the prompt changes to
Router(config)#.
Router(config)# interface gigabitethernet ?
<1-9> GigabitEthernet interface number
Router(config)# interface gigabitethernet 1/1
Router(config-if)#
Enter interface configuration mode by
specifying the Gigabit Ethernet
interface that you want to configure
using the interface gigabitethernet
global configuration command.
Enter a ? to display what you must
enter next on the command line. In
this example, you must enter an
interface number from 1 to 9 in the
format module-number/port-number.
You are in interface configuration
mode when the prompt changes to
Router(config-if)#.
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Chapter 1 Command-Line Interface How to Find Command Options
Router(config-if)#?
Interface configuration commands:
access-expression Build a bridge boolean access expression
apollo Apollo interface subcommands
appletalk Appletalk interface subcommands
arp Set arp type (arpa, probe, snap) or timeout
backup Modify backup parameters
bandwidth Set bandwidth informational parameter
bgp-policy Apply policy propogated by bgp community string
bridge-group Transparent bridging interface parameters
carrier-delay Specify delay for interface transitions
cdp CDP interface subcommands
channel-group Etherchannel/port bundling configuration
clns CLNS interface subcommands
cmns OSI CMNS
custom-queue-list Assign a custom queue list to an interface
decnet Interface DECnet config commands
default Set a command to its defaults
delay Specify interface throughput delay
description Interface specific description
dlsw DLSw interface subcommands
dspu Down Stream PU
exit Exit from interface configuration mode
fair-queue Enable Fair Queuing on an Interface
flowcontrol Configure flow operation.
fras DLC Switch Interface Command
help Description of the interactive help system
hold-queue Set hold queue depth
ip Interface Internet Protocol config commands
ipx Novell/IPX interface subcommands
isis IS-IS commands
iso-igrp ISO-IGRP interface subcommands
.
.
.
Router(config-if)#
Enter a ? to display a list of all the
interface configuration commands
available for the Gigabit Ethernet
interface.
Router(config-if)# channel-group ?
group channel-group of the interface
Router(config-if)#channel-group
Enter the command that you want to
configure for the controller. In this
example, the channel-group
command is used.
Enter a ? to display what you must
enter next on the command line. In
this example, you must enter the
group keyword.
Because a <cr> is not displayed, it
indicates that you must enter more
information to complete the
command.
Table 1-2 How to Find Command Options (continued)
Command Comment
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Router(config-if)# channel-group ?
<1-256> Channel group number
Router(config-if)#channel-group
After you enter the group keyword,
enter a ? to display what you must
enter next on the command line. In
this example, you must enter a channel
group number from 1 to 256.
Because a <cr> is not displayed, it
indicates that you must enter more
information to complete the
command.
Router(config-if)# channel-group 1 ?
mode Etherchannel Mode of the interface
Router(config-if)#
After you enter the channel group
number, enter a ? to display what you
must enter next on the command line.
In this example, you must enter the
mode keyword.
Because a <cr> is not displayed, it
indicates that you must enter more
information to complete the
command.
Router(config-if)# channel-group 1 mode ?
auto Enable PAgP only if a PAgP device is detected
desirable Enable PAgP unconditionally
on Enable Etherchannel only
Router(config-if)#
After you enter the mode keyword,
enter a ? to display what you must
enter next on the command line. In
this example, you must enter the auto,
desirable, or on keyword.
Because a <cr> is not displayed, it
indicates that you must enter more
information to complete the
command.
Router(config-if)# channel-group 1 mode auto ?
<cr>
Router(config-if)#
In this example, the auto keyword is
entered. After you enter the auto
keyword, enter a ? to display what you
must enter next on the command line.
Because a <cr> is displayed, it
indicates that you can press Return to
complete the command. If additional
keywords are listed, you can enter
more keywords or press Return to
complete the command.
Router(config-if)# channel-group 1 mode auto
Router(config-if)#
In this example, press Return to
complete the command.
Table 1-2 How to Find Command Options (continued)
Command Comment
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Chapter 1 Command-Line Interface Using the No and Default Forms of Commands
Using the No and Default Forms of Commands
Almost every configuration command has a no form. In general, enter the no form to disable a function.
Use the command without the keyword no to reenable a disabled function or to enable a function that is
disabled by default. For example, IP routing is enabled by default. To disable IP routing, specify the
no ip routing command and specify ip routing to reenable it. This publication provides the complete
syntax for the configuration commands and describes what the no form of a command does.
Configuration commands can have a default form. The default form of a command returns the command
setting to its default. Most commands are disabled by default, so the default form is the same as the no
form. However, some commands are enabled by default and have variables set to certain default values.
In these cases, the default form of the command enables the command and sets variables to their default
values. This publication describes what the default form of a command does if the command is not the
same as the no form.
Using the CLI String Search
The pattern in the command output is referred to as a string. The CLI string search feature allows you to
search or filter any show or more command output and allows you to search and filter at --More--
prompts. This feature is useful when you need to sort though large amounts of output, or if you want to
exclude output that you do not need to see.
With the search function, you can begin unfiltered output at the first line that contains a regular
expression you specify. You can then specify a maximum of one filter per command or start a new search
from the --More-- prompt.
A regular expression is a pattern (a phrase, number, or more complex pattern) software uses to match
against show or more command output. Regular expressions are case sensitive and allow for complex
matching requirements. Examples of simple regular expressions are Serial, misses, and 138. Examples
of complex regular expressions are 00210..., ( is ), and [Oo]utput.
You can perform three types of filtering:
Use the begin keyword to begin output with the line that contains a specified regular expression.
Use the include keyword to include output lines that contain a specified regular expression.
Use the exclude keyword to exclude output lines that contain a specified regular expression.
You can then search this filtered output at the --More-- prompts.
Note The CLI string search function does not allow you to search or filter backward through previous output;
filtering cannot be specified using HTTP access to the CLI.
Regular Expressions
A regular expression can be a single character that matches the same single character in the command
output or multiple characters that match the same multiple characters in the command output. This
section describes how to create both single-character patterns and multiple-character patterns and how
to create more complex regular expressions using multipliers, alternation, anchoring, and parentheses.
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Using the CLI String Search
Single-Character Patterns
The simplest regular expression is a single character that matches the same single character in the
command output. You can use any letter (A-Z, a-z) or digit (0-9) as a single-character pattern. You can
also use other keyboard characters (such as ! or ~) as single-character patterns, but certain keyboard
characters have special meaning when used in regular expressions. Table 1-3 lists the keyboard
characters with special meaning.
To enter these special characters as single-character patterns, remove the special meaning by preceding
each character with a backslash (\). These examples are single-character patterns matching a dollar sign,
an underscore, and a plus sign, respectively.
\$ \_ \+
You can specify a range of single-character patterns to match against command output. For example,
you can create a regular expression that matches a string containing one of the following letters: a, e, i,
o, or u. One and only one of these characters must exist in the string for pattern matching to succeed. To
specify a range of single-character patterns, enclose the single-character patterns in square brackets
([ ]). For example,
[aeiou]
matches any one of the five vowels of the lowercase alphabet, while
[abcdABCD]
matches any one of the first four letters of the lower- or uppercase alphabet.
You can simplify ranges by entering only the end points of the range separated by a dash (-). Simplify
the previous range as follows:
[a-dA-D]
To add a dash as a single-character pattern in your range, include another dash and precede it with a
backslash:
[a-dA-D\-]
You can also include a right square bracket (]) as a single-character pattern in your range. To do so, enter
the following:
[a-dA-D\-\]]
Table 1-3 Characters with Special Meaning
Character Special Meaning
. Matches any single character, including white space.
* Matches 0 or more sequences of the pattern.
+ Matches 1 or more sequences of the pattern.
? Matches 0 or 1 occurrences of the pattern.
^ Matches the beginning of the string.
$ Matches the end of the string.
_ (underscore) Matches a comma (,), left brace ({), right brace (}), left parenthesis ( ( ),
right parenthesis ( ) ), the beginning of the string, the end of the string, or a
space.
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The previous example matches any one of the first four letters of the lower- or uppercase alphabet, a
dash, or a right square bracket.
You can reverse the matching of the range by including a caret (^) at the start of the range. This example
matches any letter except the ones listed:
[^a-dqsv]
This example matches anything except a right square bracket (]) or the letter d:
[^\]d]
Multiple-Character Patterns
When creating regular expressions, you can also specify a pattern containing multiple characters. You
create multiple-character regular expressions by joining letters, digits, or keyboard characters that do not
have special meaning. For example, a4% is a multiple-character regular expression. Put a backslash in
front of the keyboard characters that have special meaning when you want to remove their special
meaning.
With multiple-character patterns, order is important. The regular expression a4% matches the character
a followed by a 4 followed by a % sign. If the string does not have a4%, in that order, pattern matching
fails. This multiple-character regular expression
a.
uses the special meaning of the period character to match the letter a followed by any single character.
With this example, the strings ab, a!, or a2 are all valid matches for the regular expression.
You can remove the special meaning of the period character by putting a backslash in front of it. In the
following expression
a\.
only the string a. matches this regular expression.
You can create a multiple-character regular expression containing all letters, all digits, all keyboard
characters, or a combination of letters, digits, and other keyboard characters. These examples are all
valid regular expressions:
telebit 3107 v32bis
Multipliers
You can create more complex regular expressions to match multiple occurrences of a specified regular
expression by using some special characters with your single- and multiple-character patterns. Table 1-4
lists the special characters that specify “multiples” of a regular expression.
This example matches any number of occurrences of the letter a, including none:
a*
Table 1-4 Special Characters Used as Multipliers
Character Description
* Matches 0 or more single- or multiple-character patterns.
+ Matches 1 or more single- or multiple-character patterns.
? Matches 0 or 1 occurrences of the single- or multiple-character patterns.
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This pattern requires that at least one letter a in the string is matched:
a+
This pattern matches the string bb or bab:
ba?b
This string matches any number of asterisks (*):
\**
To use multipliers with multiple-character patterns, you enclose the pattern in parentheses. In the
following example, the pattern matches any number of the multiple-character string ab:
(ab)*
As a more complex example, this pattern matches one or more instances of alphanumeric pairs (but not
none; that is, an empty string is not a match):
([A-Za-z][0-9])+
The order for matches using multipliers (*, +, or ?) is to put the longest construct first. Nested constructs
are matched from outside to inside. Concatenated constructs are matched beginning at the left side of
the construct. Thus, the regular expression matches A9b3, but not 9Ab3 because the letters are specified
before the numbers.
Alternation
Alternation allows you to specify alternative patterns to match against a string. You separate the
alternative patterns with a vertical bar (|). Exactly one of the alternatives can match the string. For
example, the regular expression
codex | telebit
matches the string codex or the string telebit, but not both codex and telebit.
Anchoring
You can match a regular expression pattern against the beginning or the end of the string. That is, you
can specify that the beginning or end of a string contains a specific pattern. You “anchor” these regular
expressions to a portion of the string using the special characters shown in Table 1-5.
This regular expression matches a string only if the string starts with abcd:
^abcd
In contrast, this expression is in a range that matches any single letter, as long as it is not the letters a,
b, c, or d:
[^abcd]
Table 1-5 Special Characters Used for Anchoring
Character Description
^ Matches the beginning of the string.
$ Matches the end of the string.
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With this example, the regular expression matches a string that ends with .12:
$\.12
Contrast these anchoring characters with the special character underscore (_). The underscore matches
the beginning of a string (^), the end of a string ($), parentheses ( ), space ( ), braces { }, comma (,), or
underscore (_). With the underscore character, you can specify that a pattern exist anywhere in the string.
For example:
_1300_
matches any string that has 1300 somewhere in the string. The strings 1300 can be preceded by or end
with a space, brace, comma, or underscore. For example:
{1300_
matches the regular expression, but 21300 and 13000 do not.
Using the underscore character, you can replace long regular expression lists, such as the following:
^1300$ ^1300(space) (space)1300 {1300, ,1300, {1300} ,1300, (1300
with
_1300_
Parentheses for Recall
As shown in the “Multipliers” section on page 1-7, you use parentheses with multiple-character regular
expressions to multiply the occurrence of a pattern. You can also use parentheses around a single- or
multiple-character pattern to remember a pattern for use elsewhere in the regular expression.
To create a regular expression that recalls a previous pattern, you use parentheses to indicate a
remembered specific pattern and a backslash (\) followed by an integer to reuse the remembered pattern.
The integer specifies the occurrence of the parentheses in the regular expression pattern. If you have
more than one remembered pattern in your regular expression, then \1 indicates the first remembered
pattern, \2 indicates the second remembered pattern, and so on.
This regular expression uses parentheses for recall:
a(.)bc(.)\1\2
This regular expression matches an a followed by any character (call it character 1), followed by bc
followed by any character (character 2), followed by character 1 again, followed by character 2 again.
The regular expression can match aZbcTZT. The software remembers that character 1 is Z and character
2 is T and then uses Z and T again later in the regular expression.
alt Keyword Usage
When you enable high-availability redundancy, every configuration command executed on the
designated MSFC is sent to the nondesignated MSFC. Also, the running configuration synchronization
is updated when you enter the copy source running-config command on the designated MSFC.
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The two states for the configuration synchronization are as follows:
Config Sync AdminStatus—Signifies what the user has configured for this feature at that moment
Config Sync RuntimeStatus—Enabled only when the following occurs:
The Config Sync AdminStatus is enabled on both the designated and nondesignated MSFCs
The designated and nondesignated MSFCs are running compatible images
To configure both MSFCs from a single console, enter the alt keyword to specify an alternate
configuration. When specifying the alternate configuration, the configuration that is specified before the
alt keyword relates to the MSFC on the supervisor engine in slot 1 of the switch; the configuration that
is specified after the alt keyword relates to the MSFC on the supervisor engine in slot 2.
Note You must enter the alt keyword when you enable Config Sync AdminStatus.
When you enable the Config Sync RuntimeStatus, the following occurs:
No configuration mode is available on the CLI of the nondesignated MSFC; EXEC mode is
available. Configuration of both MSFCs is made through the console or a Telnet session on the
designated MSFC.
The alt keyword is available and required (see the “alt Keyword Usage” section on page 1-9 for
more information on the alt keyword)
The running and startup configurations are synchronized
When the Config Sync RuntimeStatus is in disabled mode, the following occurs:
Configuration mode is available on the CLI of both MSFCs
The alt keyword is available but optional
The running and startup configurations are not synchronized
Table 1-6 shows the interface and global configuration commands that contain the alt keyword:
This example shows how the alt keyword is used when entering the ip address command:
Router-1(config-if)# ip address 1.2.3.4 255.255.255.0 alt ip address 1.2.3.5 255.255.255.0
Table 1-6 Interface and Global Configuration Commands Containing the alt Keyword
Interface Configuration Commands Global Configuration Commands
[no] standby [group_number] ip [ip_address
[secondary]] alt [no] standby [group_number] ip
[ip_address [secondary]]
[no] standby [group_number] priority priority
[preempt [delay delay]] alt [no] standby
[group_number] priority priority [preempt [delay
delay]]
[no] ip address ip_address mask [secondary] alt [no]
ip address ip_address mask [secondary]
[no] ipx network network [encapsulation
encapsulation_type [secondary]] [alt [no] ipx
network network [encapsulation encapsulation_type
[secondary]]]
[no] hostname hostname alt hostname hostname
[no] ip default-gateway ip_address alt [no] ip
default-gateway ip_address
router bgp autonomous_system
bgp router-id ip_address [alt ip_address]
router ospf process_id
router-id ip_address [alt ip_address]
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Saving Configuration Changes
To save your configuration changes to your startup configuration so that they will not be lost if there is
a system reload or power outage, enter the following command:
Router# copy system:running-config nvram:startup-config
Building configuration...
It might take a minute or two to save the configuration. After the configuration has been saved, the
following output appears:
[OK]
Router#
On most platforms, this step saves the configuration to NVRAM. On the Class A Flash file system
platforms, this step saves the configuration to the location specified by the CONFIG_FILE environment
variable. The CONFIG_FILE environment variable defaults to NVRAM.
MSFC CLI
You can access the Multilayer Switch Feature Card (MSFC) command-line interface (CLI) by entering
commands from the supervisor engine CLI. These sections describe the MSFC CLI:
Accessing the MSFC CLI from the Supervisor Engine CLI, page 1-11
Cisco IOS Command Modes, page 1-12
Cisco IOS Command-Line Interface, page 1-14
Accessing the MSFC CLI from the Supervisor Engine CLI
These sections describe how to access the MSFC CLI from a directly connected console port or from a
Telnet session:
Accessing the MSFC CLI from the Console Port, page 1-11
Accessing the MSFC CLI from a Telnet Session, page 1-12
Accessing the MSFC CLI from the Console Port
You can enter the switch console command to access the MSFC CLI from the supervisor engine CLI
directly connected to the console port. To exit from the MSFC CLI and return to the supervisor engine
CLI, enter ^C^C^C at the Router> prompt.
To access the MSFC CLI from the supervisor engine CLI, perform this task:
Task Command
Access the MSFC CLI from the supervisor engine CLI. switch console [mod]1
1. The mod variable specifies the module number of the MSFC; either 15 (if the MSFC is installed on the supervisor
engine in slot 1) or 16 (if the MSFC is installed on the supervisor engine in slot 2). If no module number is specified,
the console will switch to the MSFC on the active supervisor engine.
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Note To access the MSFC CLI on the standby MSFC, connect to the console port of the standby
supervisor engine.
This example shows how to access the active MSFC CLI from the active supervisor engine CLI, and
how to exit the MSFC CLI and return to the supervisor engine CLI:
Console> (enable) switch console 15
Trying Router-15...
Connected to Router-15.
Type ^C^C^C to switch back...
Router>^C^C^C
Console> (enable)
Accessing the MSFC CLI from a Telnet Session
You can enter the session mod command to access the MSFC CLI from the supervisor engine CLI using
a Telnet session. To exit from the MSFC CLI back to the supervisor engine CLI, enter the exit command
at the Router> prompt.
Note The supervisor engine software sees the MSFC as module 15 (when installed on a
supervisor engine in slot 1) or module 16 (when installed on a supervisor engine in slot 2).
This example shows how to access the MSFC from the supervisor engine CLI, and how to exit the MSFC
CLI and return to the supervisor engine CLI:
Console> (enable) session 15
Router> exit
Console> (enable)
Note In addition to the methods described in the Accessing the MSFC CLI from the Supervisor
Engine CLI” section on page 1-11, you can configure Cisco IOS software to support direct
Telnet access to the MSFC. Refer to “Configuring Authentication” in the Cisco IOS
Security Configuration Guide at this URL:
http://www.cisco.com/univercd/cc/td/doc/product/software/ios121/121cgcr/secur_c/scprt1/scdathen.
htm
Cisco IOS Command Modes
The Cisco IOS user interface is divided into many different modes. The commands available to you
depend on which mode you are currently in. To get a list of the commands in a given mode, type a
question mark (?) at the system prompt. For more information, see the “Getting a List of Cisco IOS
Commands and Syntax” section on page 2-14.
When you start a session on the supervisor engine, you begin in user mode, often called user EXEC
mode. Only a limited subset of the commands are available in EXEC mode. To have access to all
commands, you must enter privileged EXEC mode. Normally, you must type in a password to access
privileged EXEC mode. From privileged EXEC mode, you can type in any EXEC command or access
global configuration mode. Most of the EXEC commands are one-time commands, such as show
commands, which show the current configuration status, and clear commands, which clear counters or
interfaces. The EXEC commands are not saved across reboots of the supervisor engine.
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The configuration modes allow you to make changes to the running configuration. If you later save the
configuration, these commands are stored across supervisor engine reboots. You must start at global
configuration mode. From global configuration mode, you can enter interface configuration mode,
subinterface configuration mode, and a variety of protocol-specific modes.
ROM monitor mode is a separate mode used when the supervisor engine cannot boot properly. For
example, the supervisor engine might enter ROM monitor mode if it does not find a valid system image
when it is booting, or if its configuration file is corrupted at startup. For more information, see the
Catalyst 6500 Series IOS Command Reference.”
Table 1-7 lists and describes the most commonly used Cisco IOS modes.
The Cisco IOS command interpreter, called the EXEC, interprets and executes the commands that you
enter. You can abbreviate commands and keywords by entering just enough characters to make the
command unique from other commands. For example, you can abbreviate the show command to sh and
the configure terminal command to config t.
When you type exit, the MSFC backs out one level. To exit configuration mode completely and return
to privileged EXEC mode, press Ctrl-Z.
Table 1-7 Frequently Used Cisco IOS Command Modes
Mode Description of Use How to Access Prompt
User EXEC Connect to remote devices,
change terminal settings on a
temporary basis, perform basic
tests, and display system
information.
Log in. Router>
Privileged EXEC (enable) Set operating parameters. The
privileged command set
includes the commands in user
EXEC mode as well as the
configure command. Use this
command to access the other
command modes.
From the user EXEC mode,
enter the enable command and
the enable password.
Router#
Global configuration Configure features that affect
the system as a whole. From the privileged EXEC
mode, enter the configure
terminal command.
Router(config)#
Interface configuration Many features are enabled for a
particular interface. Interface
commands enable or modify the
operation of a Gigabit Ethernet
or Fast Ethernet interface.
From global configuration
mode, enter the interface type
location command.
Router(config-if)#
Console configuration From the directly connected
console or the virtual terminal
used with Telnet, use this
configuration mode to configure
the console interface.
From global configuration
mode, enter the line console 0
command.
Router(config-line)#
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Getting a List of Cisco IOS Commands and Syntax
In any command mode, you can get a list of available commands by entering a question mark (?).
Router> ?
To obtain a list of commands that begin with a particular character sequence, type in those characters
followed by the question mark (?). Do not include a space. This form of help is called word help, because
it completes a word for you.
Router# co?
configure
To list keywords or arguments, enter a question mark in place of a keyword or argument. Include a space
before the question mark. This form of help is called command syntax help, because it reminds you
which keywords or arguments are applicable based on the command, keywords, and arguments you have
already entered.
Router# configure ?
memory Configure from NV memory
network Configure from a TFTP network host
overwrite-network Overwrite NV memory from TFTP network host
terminal Configure from the terminal
To redisplay a command you previously entered, press the up-arrow key or Ctrl-P. You can continue to
press the up-arrow key to see the last 20 commands that you entered.
Tips If you are having trouble entering a command, check the system prompt, and enter the
question mark (?) for a list of available commands. You might be in the wrong command
mode or using incorrect syntax.
Press Ctrl-Z in any mode to immediately return to privileged EXEC mode. Enter exit to return to the
previous mode.
CiscoIOS Command-Line Interface
These sections describe basic Cisco IOS configuration tasks that you need to understand before you
configure routing:
Accessing Cisco IOS Configuration Mode, page 1-14
Viewing and Saving the Cisco IOS Configuration, page 1-15
Bringing Up an MSFC Interface, page 1-15
Accessing Cisco IOS Configuration Mode
To access the Cisco IOS configuration mode, perform this task:
Note Enter the switch console command to access the MSFC CLI from the supervisor engine
CLI when directly connected to the supervisor engine console port. To access the MSFC
from a Telnet session, see the Accessing the MSFC CLI from a Telnet Session” section
on page 1-12.
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Viewing and Saving the Cisco IOS Configuration
To view and save the configuration after you make changes, perform this task:
Bringing Up an MSFC Interface
In some cases, an MSFC interface might be administratively shut down. You can check the status of an
interface using the show interface command.
Note In a redundant supervisor engine setup, if an interface on one MSFC is shut down, the
matching VLAN interface on the redundant MSFC will stop forwarding packets.
Therefore, you should manually shut down the matching interface on the redundant MSFC.
To bring up an MSFC interface that is administratively shut down, perform this task in privileged mode:
Task Command
Step 1 If you are in the supervisor engine
CLI, enter the MSFC CLI. Console> switch console [mod_num]
Step 2 At the EXEC prompt, enter enable
mode. Router> enable
Step 3 At the privileged EXEC prompt,
enter global configuration mode. Router# configure terminal
Step 4 Enter the commands to configure
routing. (Refer to the appropriate configuration tasks in the Catalyst 6500
Series IOS Software Configuration Guide.)
Step 5 Exit configuration mode. Router(config)# Ctrl-Z
Task Command
Step 1 View the current operating
configuration at the privileged
EXEC prompt.
Router# show running-config
Step 2 View the configuration in
NVRAM. Router# show startup-config
Step 3 Save the current configuration to
NVRAM. Router# copy running-config startup-config
Task Command
Step 1 Specify the interface to bring up. Router(config)# interface interface_type interface_number
Step 2 Bring the interface up. Router(config-if)# no shutdown
Step 3 Exit configuration mode. Router(config-if)# Ctrl-Z
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Catalyst 6500 Series Switch MSFC Commands
This chapter contains an alphabetical listing of the Multilayer Switching Feature Card (MSFC)
commands that support the Cisco IOS software.
The Catalyst 6500 Series Switch MSFC Command Reference—Release 12.1(13)E contains only those
commands that are unique to the MSFC. For information about Cisco IOS commands not contained in
this publication, refer to the current Cisco IOS documentation including:
Cisco IOS Release 12.1 Configuration Fundamentals Configuration Guide
Catalyst 6500 Series Switch Cisco IOS Command Reference
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clear ip auth-proxy watch-list
clear ip auth-proxy watch-list
To delete a single watch-list entry or all watch-list entries, use the clear ip auth-proxy watch-list
command.
clear ip auth-proxy watch-list {ip-addr | *}
Syntax Description
Defaults This command has no default settings.
Command Modes Privilieged EXEC
Command History
Usage Guidelines If there are entries in the watch list that you suspect are not valid, you can enter the clear ip auth-proxy
watch-list command to clear them manually instead of waiting for the watch list expiry-time to expire.
Examples This example shows how to delete a single watch-list entry:
Router# clear ip auth-proxy watch-list 12.0.0.2
Router#
This example shows how to delete all watch-list entries:
Router# clear ip auth-proxy watch-list *
Router#
Related Commands ip auth-proxy max-login-attempts
ip auth-proxy watch-list
show ip auth-proxy watch-list
ip-addr Specifies the IP address to be deleted from the watch list.
*Removes all watch-list entries from the watch list.
Release Modification
12.1(13)E This command was introduced on the MSFC.
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config-register
To change the configuration register settings, use the config-register command.
config-register value
Syntax Description
Defaults Refer to the documentation for your platform for the default configuration register value. For many
newer platforms, the default is 0x2102, which causes the router to boot from Flash memory and the
Break key to be ignored.
Command Modes Global configuration
Command History
Usage Guidelines This command applies only to platforms that use a software configuration register.
The lowest four bits of the configuration register (bits 3, 2, 1, and 0) form the boot field. The boot field
determines if the router boots manually, from ROM, or from Flash or the network.
To change the boot field value and leave all other bits set to their default values, follow these guidelines:
If you set the configuration register boot field value to 0x0, you must boot the operating system
manually with the boot command.
If you set the configuration register boot field value to 0x1, the router boots using the default ROM
software.
If you set the configuration register boot field to any value from 0x2 to 0xF, the router uses the boot
field value to form a default boot filename for booting from a network server.
For more information about the configuration register bit settings and default filenames, see the
appropriate router hardware installation guide.
Examples This example shows how to set the configuration register to boot the system image from Flash memory:
Router(config)# config-register 0x2102
Router(config)#
value Hexadecimal or decimal value that represents the 16-bit configuration register
value that you want to use the next time the router is restarted; vaild values are from
0x0 to 0xFFFF (0 to 65535 in decimal).
Release Modification
12.1E This command was introduced on the MSFC.
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config-sync
config-sync
To enable configuration synchronization, use the config-sync command. Use the no form of this
command to disable configuration synchronization.
config-sync
no config-sync
Syntax Description This command has no arguments or keywords.
Defaults This command has no default settings.
Command Modes High-availability redundancy submode
Command History
Examples This example shows how to enable configuration synchronization:
Router(config)# redundancy
Router(config-r)# high-availability
Router(config-r-ha)# config-sync
Router(config-r-ha)#
This example shows how to disable configuration synchronization:
Router(config)# redundancy
Router(config-r)# high-availability
Router(config-r-ha)# no config-sync
Router(config-r-ha)#
Release Modification
12.1E This command was introduced on the MSFC.
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define interface-range
To create an interface-range macro, use the define interface-range command.
define interface-range macro-name interface-range
Syntax Description
Defaults This command has no default settings.
Command Modes Global configuration
Command History
Usage Guidelines The macro name is a 32-character maximum character string.
A macro can contain up to five ranges. An interface range cannot span slots. When entering the
interface-range, these formats can be used:
card-type {slot}/{first-interface} - {last-interface}
card-type {slot}/{first-interface} - {last-interface}
Valid values for card-type are as follows:
ge-wan
pos
vlan vlan-id (valid values are from 1 to 4094)
Examples This example shows how to create a multiple-interface macro:
Router(config)# define interface-range macro1 vlan 223, pos 6/1
Router(config)#
Related Commands interface range
macro-name Name of the interface range macro; the macro name can contain up to
32 characters.
interface-range Interface range; for a list of valid values for interface ranges, see the
“Usage Guidelines” section.
Release Modification
12.1E This command was introduced on the MSFC.
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high-availability
high-availability
To enable high-availability redundancy and enter the high-availability redundancy submode, use the
high-availability command.
high-availability
Syntax Description This command has no arguments or keywords.
Defaults This command has no default settings.
Command Modes Redundancy configuration submode
Command History
Usage Guidelines Once you enter high-availability redundancy configuration submode, these options are available:
[no] config-syncEnables automatic startup and running-configuration synchronization. Use the
no form of this command to disable automatic startup and running-configuration synchronization.
When you enable the Config Sync RuntimeStatus, the following occurs:
No configuration mode is available on the CLI of the nondesignated MSFC; EXEC mode is
available
The alt keyword is available and required (see the “alt Keyword Usage” section on page 1-9 for
information on the alt keyword)
The running and startup configurations are synchronized
When the Config Sync RuntimeStatus is in disabled mode, the following occurs:
Configuration mode is available on the CLI of both MSFCs
The alt keyword is available but optional
The running and startup configurations are not synchronized
exit—Exits from high-availability configuration mode
no—Negates a command or set its defaults
[no] single-router-modeEnters single router mode. Use the no form of this command to exit out
of single router mode. Once you enter single-router mode, this option is available:
failover table-update-delay time—Sets the delay in seconds between the switch over detection
and the hardware FIB reload. The valid values for time are from 0 to 4294967295 seconds.
When you enable high-availability redundancy, every configuration command executed on the
designated MSFC is sent to the nondesignated MSFC. Also, the running configuration synchronization
is updated when you enter the copy source running-config command on the designated MSFC.
Release Modification
12.1E This command was introduced on the MSFC.
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When you enable high-availability redundancy, the configuration mode is disabled on the nondesignated
MSFC; only the EXEC mode is available. For example, in the following, Router-16 is the nondesignated
MSFC; high-availability redundancy and configuration synchronization are enabled:
Console>(enable) session 16
Trying Router-16...
Connected to Router-16.
Escape character is ’^]’.
Router-16> enable
Router-16# configure terminal
Config mode is disabled on non-designated Router, please configure from designated Router
Router-16>
Examples This example shows how to enable high-availability redundancy and enter the high-availability
redundancy submode:
Router(config)# redundancy
Router(config-r)# high-availability
Router(config-r-ha)#
Related Commands redundancy
show redundancy (See the Catalyst 6500 Series Switch Cisco IOS Command Reference)
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interface range
interface range
To execute a command on multiple ports at the same time, use the interface range command.
interface range {port-range | macro name}
Syntax Description
Defaults This command has no default settings.
Command Modes Global or interface configuration
Command History
Usage Guidelines You can use the interface range command on existing VLAN SVIs only. To display VLAN SVIs, enter
the show running config command. VLANs not displayed cannot be used in the interface range
command.
The values entered with the interface range command are applied to all existing VLAN SVIs.
Before you can use a macro, you must define a range using the define interface-range command.
All configuration changes made to a port range are saved to NVRAM, but port ranges created with the
interface range command do not get saved to NVRAM.
You can enter the port range in two ways:
Specifying up to five port ranges
Specifying a previously defined macro
You can either specify the ports or the name of a port range macro. A port range must consist of the same
port type, and the ports within a range cannot span slots.
You can define up to five port ranges on a single command, with each range separated by a comma.
When you define a range, you must enter a white space between the first port and the hyphen (-):
When you define a range, you must enter a white space before and after the hyphen (-) as follows:
interface range pos 7/1 - 7, pos9/5 - 408
If your system is configured with a Supervisor Engine 1, valid values for vlan-id are from 1 to 1005. If
your system is configured with a Supervisor Engine 2, valid values for vlan-id are from 1 to 4094.
Extended-range VLANs are not supported on systems configured with a Supervisor Engine 1.
port-range Port range; for a list of valid values for port-range, see the “Usage
Guidelines” section.
macro name Specifies the name of a macro.
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When entering the port-range, these formats can be used:
card-type {slot}/{first-port} - {last-port}
card-type {slot}/{first-port} - {last-port}
Valid values for card-type are as follows:
ge-wan
pos
vlan vlan-id
You cannot specify both a macro and an interface range in the same command. After creating a macro,
the CLI does not allow you to enter additional ranges. If you have already entered an interface range, the
CLI does not allow you to enter a macro.
You can also specify a single interface in port-range.
Examples This example shows how to execute a command on two port ranges:
Router(config)# interface range pos 7/1 - 7, pos 9/5 - 408
Router(config-if)#
This example shows how to execute a port-range macro:
Router(config)# interface range macro macro1
Router(config-if)#
Related Commands define interface-range
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ip address
ip address
To set a primary or secondary IP address for an interface, use the ip address command. Use the no form
of this command to remove an IP address or disable IP processing..
ip address ip_address mask [secondary]
no ip address ip_address mask [secondary]
Syntax Description
Defaults No IP address is defined for the interface.
Command Modes Interface configuration
Command History
Usage Guidelines The alt keyword is used to specify an alternate configuration and is used in the following:
[no] ip address ip-address mask [secondary] alt [no] ip address ip-address mask [secondary]
An interface can have one primary IP address and multiple secondary IP addresses. Packets generated
by the Cisco IOS software always use the primary IP address. Therefore, all routers and access servers
on a segment should share the same primary network number.
Hosts can determine subnet masks using the Internet Control Message Protocol (ICMP) Mask Request
message. Routers respond to this request with an ICMP Mask Reply message.
You can disable IP processing on a particular interface by removing its IP address with the no ip address
command. If the software detects another host using one of its IP addresses, it will print an error message
on the console.
The optional keyword secondary allows you to specify an unlimited number of secondary addresses.
Secondary addresses are treated like primary addresses, except the system never generates datagrams
other than routing updates with secondary source addresses. IP broadcasts and ARP requests are handled
properly, as are interface routes in the IP routing table.
Secondary IP addresses can be used in a variety of situations. The following are the most common
applications:
ip-address IP address.
mask Mask for the associated IP subnet.
secondary (Optional) Specifies that the configured address is a secondary IP address. If this
keyword is omitted, the configured address is the primary IP address.
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There may not be enough host addresses for a particular network segment. For example, your
subnetting allows up to 254 hosts per logical subnet, but on one physical subnet you need to have
300 host addresses. Using secondary IP addresses on the routers or access servers allows you to have
two logical subnets using one physical subnet.
Many older networks were built using Level 2 bridges. The judicious use of secondary addresses can
aid in the transition to a subnetted, router-based network. Routers on an older, bridged segment can
be easily made aware that there are many subnets on that segment.
Two subnets of a single network might otherwise be separated by another network. This situation is
not permitted when subnets are in use. In these instances, the first network is extended, or layered
on top of the second network using secondary addresses.
Note If any router on a network segment uses a secondary address, all other devices on that same
segment must also use a secondary address from the same network or subnet. Inconsistent
use of secondary addresses on a network segment can very quickly cause routing loops.
Note When you are routing Open Shortest Path First (OSPF), ensure that all secondary addresses
of an interface fall into the same OSPF area as the primary addresses.
To transparently bridge IP on an interface, you must do two things:
Disable IP routing (specify no ip routing).
Add the interface to a bridge group. (See the bridge-group command.)
To concurrently route and transparently bridge IP on an interface, see the bridge crb command.
Examples In the following example, 131.108.1.27 is the primary address and 192.31.7.17 and 192.31.8.17 are
secondary addresses for Ethernet interface 0:
interface ethernet 0
ip address 131.108.1.27 255.255.255.0
ip address 192.31.7.17 255.255.255.0 secondary
ip address 192.31.8.17 255.255.255.0 secondary
Related Commands Command Description
bridge crb Enables the Cisco IOS software to both route and bridge a given protocol on
separate interfaces within a single router.
bridge-group Assigns each network interface to a bridge group.
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ip auth-proxy max-login-attempts
ip auth-proxy max-login-attempts
To limit the number of login attempts at a firewall interface, use the ip auth-proxy max-login-attempts
command. Use the no form of this command to return to the default setting.
ip auth-proxy max-login-attempts 1-maxint
no ip auth-proxy max-login-attempts
Syntax Description
Defaults 1-maxint is 5
Command Modes Interface configuration
Command History
Usage Guidelines This command is supported on firewall interfaces only.
The maximum login attempt functionality is independent of the watch-list feature. If you do not
configure the watch-list feature (using the ip access-list hardware permit fragments command) and
you configure the maximum login attempt functionality, the existing authentication proxy behavior
occurs but with the new number for retries. If you configure the watch-list feature, once the configured
number of attempts has been reached, the IP address is put in the watch list.
Examples This example shows how to set a limit to the number of login attempts at a firewall interface:
Router(config-if)# ip auth-proxy watch-list max-login-attempts 4
Router(config-if)#
Related Commands clear ip auth-proxy watch-list
ip access-list hardware permit fragments (see the Catalyst 6500 Series Switch Cisco IOS Command
Reference)
ip auth-proxy watch-list
show ip auth-proxy watch-list
1-maxint Specifies the maximum number of login attempts: valid values are from 1
to 2147483647 attempts.
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Chapter 2 Catalyst 6500 Series Switch MSFC Commands ip auth-proxy watch-list
ip auth-proxy watch-list
To enable and configure the authentication proxy watch list functionality, use the ip auth-proxy
watch-list command. See the “Usage Guidelines” section for the no form of this command usage.
ip auth-proxy watch-list {{add-item ip-addr} | enable | {expiry-time minutes}}
no ip auth-proxy watch-list [add-item ip-addr} | expiry-time]
Syntax Description
Defaults The defaults are as follows:
minutes is 30 minutes.
The watch-list functionality is disabled.
Command Modes Interface configuration
Command History
Usage Guidelines The valid values for minutes are from 0 to the largest 32-bit positive number (0x7FFFFFFF or
2147483647 in decimal). Setting the minutes to 0 (zero) places the entries in the list permanently.
This command is supported on firewall interfaces only.
Use the no form of this command to do the following:
no ip auth-proxy watch-list—Disables the watch-list functionality.
no ip auth-proxy watch-list add-item ip-addr—Removes the IP address from the watch list.
no ip auth-proxy watch-list expiry-time—Returns to the default setting.
A watch list consists of IP addresses that have opened TCP connections to port 80 and have not sent any
data is implemented. No new connection are accepted from this type of IP address (to port 80) and the
packet is dropped.
The watch-list entry remains in the watch list for the time specified by expiry-time minutes.
When you disable the watch-list functionality, no entries are put into the watch list, but the sessions are
put in SERVICE_DENIED state. The sessions are deleted after 2 minutes by the timer.
add-item ip-addr Adds an IP address to the watch list.
enable Enables the watch list feature.
expiry-time minutes Specifies the duration of time an entry is in the watch list; see the “Usage
Guidelines” section for valid values.
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ip auth-proxy watch-list
Examples This example shows how to enable the authentication proxy watch list functionality:
Router(config-if)# ip auth-proxy watch-list enable
Router(config-if)#
This example shows how to disable the authentication proxy watch list functionality:
Router(config-if)# no ip auth-proxy watch-list
Router(config-if)#
This example shows how to add an IP address to the watch list:
Router(config-if)# ip auth-proxy watch-list add-item 12.0.0.2
Router(config-if)#
This example shows how to set the duration of time an entry is in the watch list:
Router(config-if)# ip auth-proxy watch-list expiry-time 29
Router(config-if)#
Related Commands clear ip auth-proxy watch-list
ip auth-proxy max-login-attempts
show ip auth-proxy watch-list
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ip local-proxy-arp
To enable the local proxy ARP feature, use the ip local-proxy-arp command. Use the no form of this
command to disable the feature.
ip local-proxy-arp
no ip local-proxy-arp
Syntax Description This command has no arguments or keywords.
Defaults Disabled
Command Modes Interface configuration
Command History
Usage Guidelines The local proxy ARP feature allows the MSFC to respond to ARP requests for IP addresses within a
subnet where normally no routing is required. With the local proxy ARP feature enabled, the MSFC
responds to all ARP requests for IP addresses within the subnet and forwards all traffic between hosts in
the subnet. Use this feature only on subnets where hosts are intentionally prevented from communicating
directly to the Catalyst 6500 series switch on which they are connected.
ICMP redirects are disabled on interfaces where the local proxy ARP feature is enabled.
Examples This example shows how to enable the local proxy ARP feature:
Router(config-if)# ip local-proxy-arp
Router(config-if)#
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ip multicast rpf backoff
ip multicast rpf backoff
To set the PIM backoff interval, use the ip multicast rpf backoff command. Use the no form of this
command to return to the default settings.
ip multicast rpf backoff {{min max} | disable}
no ip multicast rpf backoff
Syntax Description
Defaults If triggered RPF check is enabled, the defaults are as follows:
min is 50 milliseconds.
max is 5000 milliseconds.
Command Modes Global configuration
Command History
Usage Guidelines If you do not enable the triggered RPF check, PIM periodically polls the routing tables for changes (set
using the ip multicast rpf interval command). When you enable the triggered RPF check, PIM polls the
routing tables when a change in the routing tables occurs. The min argument sets the initial backoff time.
Once triggered, PIM waits for additional routing table changes. If the min period expires without further
routing table changes, PIM scans for routing changes. If additional routing changes occur during the
backoff period, PIM doubles the length of the backoff period. You can set the maximum interval for the
doubled backoff period with the max argument.
Use this command in the following situation:
You have frequent route changes in your router (for example, on a dial-in router).
You want to either reduce the maximum RPF-check interval (for faster availability of IP multicast
on newly established routes).
You want to increase the RPF-check interval to reduce the CPU load that is introduced by the RPF
check.
min Initial RPF backoff delay in milliseconds; valid values are from 1 to
65535 milliseconds.
max Maximum RPF backoff delay in milliseconds; valid values are from 1 to
65535 milliseconds.
disable Disables triggered RPF check.
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Examples This example shows how to set the PIM backoff interval in milliseconds:
Router(config)# ip multicast rpf backoff 100
Router(config)#
Related Commands ip multicast rpf interval
show ip rpf events (refer to Cisco IOS documentation)
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ip multicast rpf interval
ip multicast rpf interval
To set the RPF consistency-check interval, use the ip multicast rpf interval command. Use the no form
of this command to return to the default setting.
ip multicast rpf interval interval
no ip multicast rpf interval
Syntax Description
Defaults 10 seconds
Command Modes Global configuration
Command History
Usage Guidelines The ip multicast rfp interval command sets the interval PIM and polls the routing tables for changes.
Examples This example shows how to set the RPF check interval in seconds:
Router(config)# ip multicast rpf interval 5
Router(config)#
Related Commands ip multicast rfp backoff
interval Interval in seconds between RPF checks; valid values are from 1 to
10 seconds.
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ip verify unicast source reachable-via
To enable and configure RPF checks, use the ip verify unicast source reachable-via command. Use the
no form of this command to disable RPF.
ip verify unicast source reachable-via {rx | any} [allow-default] [allow-self-ping] [list]
no ip verify unicast source reachable-via
Syntax Description
Defaults Unicast RPF is disabled.
Command Modes Interface configuration
Command History
Usage Guidelines Unicast RPF provides three basic modes:
Exists-only mode—A source address needs only to be present in the FIB and reachable through a
“real” interface; this situation also applies to the ip verify unicast source reachable-via any
allow-default command. The exists-only mode requires that a resolved and reachable source
address is present in the FIB table. The source address must be reachable through a configured
interface.
Any mode—The source must be reachable through any of the paths. For example, the source has
per-destination load balancing.
Rx mode—A source address must be reachable on the arrived interface. For example, the source
must be reachable without load balancing.
Note Unicast RPF is an input function and is applied only on the input interface of a router at the upstream
end of a connection.
rx Checks that the source address is reachable on the interface that the packet
was received.
any Checks that the source address is reachable on any path.
allow-default (Optional) Checks that the default route matches the source address.
allow-self-ping (Optional) Allows the router to ping itself.
list (Optional) Access list number; valid values are from 1 to 199 for a
standard IP access list number and from 1300 to 2699 for a standard IP
expanded access list number.
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ip verify unicast source reachable-via
To use Unicast RPF, enable CEF switching or dCEF switching in the router. You do not need to configure
the input interface for CEF switching. As long as CEF is running on the router, you can configure
individual interfaces with other switching modes.
Note Unicast RPF will not work without CEF.
Do not use Unicast RPF on interfaces that are internal to the network. Internal interfaces are likely to
have routing asymmetry, which means that there are multiple routes to the source of a packet. You should
apply Unicast RPF only where there is natural or configured symmetry.
Examples This example shows how to enable Unicast RPF exist-only checking mode:
Router(config-if)# ip verify unicast source reachable-via any
Router(config-if)#
Related Commands ip cef (refer to Cisco IOS documentation)
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ip wccp group-listen
To enable the reception of IP multicast packets for the WCCP feature, use the ip wccp group-listen
command mode. Use the no form of this command to disable the reception of IP multicast packets for
the WCCP feature.
ip wccp {web-cache | {service-number | service-name}} group-listen
no ip wccp {web-cache | {service-number | service-name}} group-listen
Syntax Description
Defaults Disabled
Command Modes Interface configuration
Command History
Usage Guidelines
Note To ensure correct operation, you must enter the ip pim mode command in addition to the ip wccp
group-listen command.
The service-number may be either one of the provided standard keyword definitions or a number
representing a cache engine dynamically defined definition. Once the service is enabled, the
Catalyst 6500 series switch can participate in the establishment of a service group.
On Catalyst 6500 series switches that are to be members of a service group when IP multicast is used,
the following configuration is required:
You must configure the IP multicast address for use by the WCCP service group.
You must configure the ip wccp {web-cache | service-number} group-listen command on the
interfaces that are to receive the IP multicast address.
web-cache Directs the router to send packets to the web cache service.
service-number WCCP service number; valid values are from 0 to 99.
service-name WCCP service name; the valid value is web-cache.
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ip wccp group-listen
Examples This example shows how to enable the multicast packets for a web cache with a multicast address of
224.1.1.100:
router# configure terminal
router(config)# ip wccp web-cache group-address 244.1.1.100
router(config)# interface ethernet 0
router(config-if)# ip wccp web-cache group listen
Related Commands ip wccp
ip wccp redirect
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ip wccp redirect
To enable packet redirection on an outbound or inbound interface using Web Cache Communication
Protocol (WCCP), use the ip wccp redirect command. To disable WCCP redirection, use the no form
of this command.
ip wccp service redirect {out | in}
no ip wccp service redirect {out | in}
Syntax Description
Defaults WCCP redirect is disabled.
Command Modes Interface configuration
Command History
Usage Guidelines The ip wccp service redirect in command allows you to configure WCCP redirection on an interface
receiving inbound network traffic. When the command is applied to an interface, all packets arriving at
that interface will be compared against the criteria that is defined by the specified WCCP service. If the
packets match the criteria, they will be redirected.
The ip wccp service redirect out command allows you to configure the WCCP redirection check at an
outbound interface.
Caution Be careful not to confuse the ip wccp service redirect {out | in} interface configuration command with
the ip wccp redirect exclude in interface configuration command.
Note This command has the potential to affect the ip wccp redirect exclude in command. (These
commands have opposite functions.) If you have ip wccp redirect exclude in set on an interface and
you subsequently configure the ip wccp service redirect in command, the ip wccp redirect
exclude in command will be overridden. The opposite is also true: Configuring the ip wccp
redirect exclude in command will override the ip wccp service redirect in command.
service Specifies the service group; valid values are web-cache or the identification
number (from 0 to 99) of the service.
out Specifies packet redirection on an outbound interface.
in Specifies packet redirection on an inbound interface.
Release Modification
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ip wccp redirect
Examples This example shows how to configure a session in which reverse proxy packets on Ethernet interface 0
are being checked for redirection and redirected to a Cisco Cache Engine:
Router# configure terminal
Router(config)# ip wccp 99
Router(config)# interface ethernet 0
Router(config-if)# ip wccp 99 redirect ?
in Redirect to a Cache Engine appropriate inbound packets
out Redirect to a Cache Engine appropriate outbound packets
Router(config-if)# ip wccp 99 redirect out
This example shows how to configure a session in which HTTP traffic arriving on Ethernet interface 0/1
will be redirected to a Cisco Cache Engine:
Router# configure terminal
Router(config)# ip wccp web-cache
Router(config)# interface ethernet 0/1
Router(config-if)# ip wccp web-cache redirect in
Related Commands ip wccp redirect exclude in (refer to Cisco IOS documentation)
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Chapter 2 Catalyst 6500 Series Switch MSFC Commands ipx network
ipx network
To enable IPX routing on a particular interface and to optionally select the type of encapsulation
(framing), use the ipx network command in interface configuration mode. To disable IPX routing, use
the no form of this command.
ipx network network [encapsulation encapsulation-type [secondary]]
no ipx network network [encapsulation encapsulation-type]
Syntax Description
Defaults The defaults are as follows:
IPX routing is disabled.
Encapsulation types:
For Ethernet: novell-ether
For Token Ring: sap
For FDDI: snap
For Serial: hdlc
If you use NetWare Version 4.0 and Ethernet, you must change the default encapsulation type from
novell-ether to sap.
Command Modes Interface configuration
Command History
Usage Guidelines The network is an eight-digit hexadecimal number that uniquely identifies a network cable segment. It
can be a number in the range 1 to FFFFFFFD. You do not need to specify leading zeros in the network
number. For example, for the network number 000000AA you can enter AA.
The alt keyword is used to specify an alternate configuration and is used in the following:
[no] ipx network network [encapsulation encapsulation-type [secondary]] [alt [no] ipx network
network [encapsulation encapsulation-type [secondary]]]
Table 2-1 describes the types of encapsulation available for specific interfaces.
network Network number.
encapsulation
encapsulation-type (Optional) Type of encapsulation (framing). For a list of possible
encapsulation types, see Table 2-1.
secondary (Optional) Indicates an additional (secondary) network configured after
the first (primary) network.
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ipx network
The ipx network command allows you to configure a single logical network on a physical network or
more than one logical network on the same physical network (network cable segment). Each network on
a given interface must have a different encapsulation type.
Note You cannot configure more than 200 IPX interfaces on a router using the ipx network
command.
The first network you configure on an interface is considered to be the primary network. Any additional
networks are considered to be secondary networks; these must include the secondary keyword.
Note In future Cisco IOS software releases, primary and secondary networks may not be
supported.
NLSP does not support secondary networks. You must use subinterfaces in order to use multiple
encapsulations with NLSP.
Table 2-1 Encapsulation Types
Encapsulation Type Description
arpa For Ethernet interfaces only—Use Novell’s Ethernet_II encapsulation.
This encapsulation is recommended for networks that handle both TCP/IP
and IPX traffic.
hdlc For Serial interfaces only—Use HDLC encapsulation.
novell-ether For Ethernet interfaces only—Use Novell’s “Ethernet_802.3”
encapsulation. This encapsulation consists of a standard 802.3 Media
Access Control (MAC) header followed directly by the IPX header with a
checksum of FFFF. It is the default encapsulation used by all versions of
NetWare up to and including Version 3.11.
novell-fddi For FDDI interfaces only—Use Novell’s “FDDI_RAW” encapsulation.
This encapsulation consists of a standard FDDI MAC header followed
directly by the IPX header with a checksum of 0xFFFF.
sap For Ethernet interfaces—Use Novell’s Ethernet_802.2
encapsulation.This encapsulation consists of a standard 802.3 MAC
header followed by an 802.2 LLC header. This is the default
encapsulation used by NetWare Version 3.12 and 4.0.
For Token Ring interfaces—This encapsulation consists of a standard
802.5 MAC header followed by an 802.2 LLC header.
For FDDI interfaces—This encapsulation consists of a standard FDDI
MAC header followed by an 802.2 LLC header.
snap For Ethernet interfaces—Use Novell Ethernet_Snap encapsulation.
This encapsulation consists of a standard 802.3 MAC header followed
by an 802.2 SNAP LLC header.
For Token Ring and FDDI interfaces—This encapsulation consists of
a standard 802.5 or FDDI MAC header followed by an 802.2 SNAP
LLC header.
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Note When enabling NLSP and configuring multiple encapsulations on the same physical LAN
interface, you must use subinterfaces. You cannot use secondary networks.
You can configure an IPX network on any supported interface as long as all the networks on the same
physical interface use a distinct encapsulation type. For example, you can configure up to four IPX
networks on a single Ethernet cable because Ethernet supports four encapsulation types.
The interface processes only packets with the correct encapsulation and the correct network number. IPX
networks using other encapsulations can be present on the physical network. The only effect on the
router is that it uses some processing time to examine packets to determine whether they have the correct
encapsulation.
All logical networks on an interface share the same set of configuration parameters. For example, if you
change the IPX RIP update time on an interface, you change it for all networks on that interface.
When you define multiple logical networks on the same physical network, IPX treats each encapsulation
as if it were a separate physical network. This means, for example, that IPX sends RIP updates and SAP
updates for each logical network.
The ipx network command is useful when migrating from one type of encapsulation to another. If you
are using it for this purpose, you should define the new encapsulation on the primary network.
To delete all networks on an interface, use the following command:
no ipx network
Deleting the primary network with the following command also deletes all networks on that interface.
The argument number is the number of the primary network.
no ipx network number
To delete a secondary network on an interface, use one of the following commands. The argument
number is the number of a secondary network.
no ipx network number
no ipx network number encapsulation encapsulation-type
Novell’s FDDI_RAW encapsulation is common in bridged or switched environments that connect
Ethernet-based Novell end hosts via a FDDI backbone. Packets with FDDI_RAW encapsulation are
classified as Novell packets, and are not automatically bridged when you enable both bridging and IPX
routing. Additionally, you cannot configure FDDI_RAW encapsulation on an interface configured for
IPX autonomous or SSE switching. Similarly, you cannot enable IPX autonomous or SSE switching on
an interface configured with FDDI_RAW encapsulation.
With FDDI_RAW encapsulation, platforms that do not use CBUS architecture support fast switching.
Platforms using CBUS architecture support only process switching of novell-fddi packets received on
an FDDI interface.
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ipx network
Examples The following example uses subinterfaces to create four logical networks on Ethernet interface 0. Each
subinterface has a different encapsulation. Any interface configuration parameters that you specify on
an individual subinterface are applied to that subinterface only.
ipx routing
interface ethernet 0
ipx network 1 encapsulation novell-ether
interface ethernet 0.1
ipx network 2 encapsulation snap
interface ethernet 0.2
ipx network 3 encapsulation arpa
interface ethernet 0
ipx network 4 encapsulation sap
The following example uses primary and secondary networks to create the same four logical networks
as shown previously in this section. Any interface configuration parameters that you specify on this
interface are applied to all the logical networks. For example, if you set the routing update timer to
120 seconds, this value is used on all four networks.
ipx routing
ipx network 1 encapsulation novell-ether
ipx network 2 encapsulation snap secondary
ipx network 3 encapsulation arpa secondary
ipx network 4 encapsulation sap secondary
The following example enables IPX routing on FDDI interfaces 0.2 and 0.3. On FDDI interface 0.2, the
encapsulation type is SNAP. On FDDI interface 0.3, the encapsulation type is Novell’s FDDI_RAW.
ipx routing
interface fddi 0.2 enc sde 2
ipx network f02 encapsulation snap
interface fddi 0.3 enc sde 3
ipx network f03 encapsulation novell-fddi
Related Commands Command Description
ipx routing Enables IPX routing.
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maximum-paths
To control the maximum number of parallel routes that an IP routing protocol can support, use the
maximum-paths command. Use the no form of this command to restore the default values.
maximum-paths maximum
no maximum-paths
Syntax Description
Defaults The defaults are as follows:
BGP is one path.
All other IP routing protocols is four paths.
Command Modes Routing protocol configuration
Command History
Examples This example shows how to allow a maximum of two paths to a destination:
Router(config)# maximum-paths 2
Router(config)
maximum Maximum number of parallel routes that an IP routing protocol installs in a
routing table; valid values are from 1 to 8.
Release Modification
12.0(7)XE Support for this command was introduced on the MSFC.
12.1(1)E Support for this command on the MSFC was extended to the E train.
12.1(8a)E This command was modified to change the maximum number of parallel
routes from six to eight paths.
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mls aclmerge algorithm
mls aclmerge algorithm
To select the type of ACL merge method to use, use the mls aclmerge algorithm command.
mls aclmerge algorithm {bdd | odm}
Syntax Description
Defaults bdd
Command Modes Global configuration
Command History
Usage Guidelines The BDD-based ACL merge function uses a method of representing Boolean functions to condense entries
into a single merged list of TCAM entries that can be programmed into the TCAM.
The ODM-based ACL merge function uses an order-dependent merge algorithm to process entries that can
be programmed into the TCAM.
Note In Cisco IOS Release12.2(14)SX, the bdd option is supported on systems configured with a Supervisor
Engine 1 or a Supervisor Engine 2. The bdd option is not supported on systems configured with a
Supervisor Engine 3.
Note In releases earlier than Cisco IOS Release 12.1(12c)E1, the ODM-based ACL merge function supports
only security ACLs and does not apply to ACLs used for QoS filtering. In Cisco IOS Release
12.1(12c)E1 and later releases, the ODM-based ACL merge function supports both security ACLs and
ACLs used for QoS filtering.
If you change the algorithm method, the change is not retroactive. For example, ACLs that have had the
merge applied are not affected. The merge change applies to future merges only.
Use the show fm summary command to see the status of the current merge method.
bdd Specifies the BDD-based ACL merge function.
odm Specifies the ODM-based ACL merge function.
Release Modification
12.1(8a)EX2 Support for this command was introduced on the MSFC.
12.1(12c)E1 Support for this command was extended to the E train. This command was
change to support the ODM-based ACL merge function on both security
ACLs and ACLs used for QoS filtering.
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Examples This example shows how to select the BDD-based ACL merge function to process ACLs:
Router(config)# mls aclmerge algorithm bdd
The algorithm chosen will take effect for new ACLs which are being applied, not
for already applied ACLs.
Router(config)
This example shows how to select the ODM-based ACL merge function to process ACLs:
Router(config)# mls aclmerge algorithm odm
The algorithm chosen will take effect for new ACLs which are being applied, not
for already applied ACLs.
Router(config)#
Related Commands show fm summary
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mls ip
mls ip
To enable MLS IP for the internal router on the interface, use the mls ip command. Use the no form of
this command to disable MLS IP on the interface.
mls ip
no mls ip
Syntax Description This command has no arguments or keywords.
Defaults Multicast is disabled
Command Modes Interface configuration
Command History
Examples This example shows how to enable MLS IP shortcuts:
Router(config-if)# mls ip
Router(config-if)#
Related Commands mls rp ip (interface configuration mode) (refer to the Catalyst 6500 Series Switch Cisco IOS Command
Reference)
show mls ip multicast (refer to the Catalyst 6500 Series Switch Cisco IOS Command Reference)
Release Modification
12.0(7)XE Support for this command was introduced on the MSFC.
12.1(12c)E This command was changed to support the Supervisor Engine 2.
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mls ip cef load-sharing full
To set CEF load balancing to include Layer 4 ports and source IP/destination IP addresses (Layer 3), use
the mls ip cef load-sharing full command. Use the no form of this command to return to the default
setting.
mls ip cef load-sharing full
no mls ip cef load-sharing full
Syntax Description This command has no arguments or keywords.
Defaults Load balancing is based on the source IP/destination IP addresses only.
Command Modes Global configuration
Command History
Usage Guidelines The mls ip cef load-sharing full command is supported on systems configured with the Supervisor
Engine 2 only.
For additional guidelines, refer to the Catalyst 6500 Series Switch Cisco IOS Software Configuration
Guide.
Examples This example shows how to set load balancing to include Layer 3 and Layer 4 ports:
Router(config)# mls ip cef load-sharing full
Router(config)#
This example shows how to return to the default setting:
Router(config)# no mls ip cef load-sharing full
Router(config)#
Related Commands show running-config (refer to the Catalyst 6500 Series Switch Cisco IOS Command Reference)
Release Modification
12.1(11b)E Support for this command was introduced on the MSFC.
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mls ip cef rate-limit
mls ip cef rate-limit
To rate limit CEF-punted data packets, use the mls ip cef rate-limit command. Use the no form of this
command to disable this feature.
mls ip cef rate-limit pps
no mls ip cef rate-limit
Syntax Description
Defaults No rate limit is configured.
Command Modes Global configuration
Command History
Usage Guidelines The mls ip cef rate-limit command is supported on systems configured with the Supervisor Engine 2
only.
Certain denial-of-service attacks target the route processing engines of routers. Certain packets that
cannot be forwarded by the PFC2 are directed to the MSFC2 for processing. Denial-of-service attacks
can overload the route processing engine and cause routing instability when running dynamic routing
protocols. The mls ip cef rate-limit command can be used to limit the amount of traffic sent to the
MSFC2 to prevent denial-of-service attacks against the route processing engine.
This command rate limits all CEF-punted data packets including the following:
Data packets going to the local interface IP address
Data packets requiring ARP
Setting the rate to a low value could impact handling of packets destined to the IP addresses of the local
interfaces and packets requiring ARP.
You should use this command to limit these packets to a normal rate and to avoid abnormal incoming
rates.
For additional guidelines, refer to the Catalyst 6500 Series Switch Cisco IOS Software Configuration
Guide.
pps Number of data packets; valid values are from 0 to 1000000.
Release Modification
12.1(5c)EX Support for this command was introduced on the MSFC.
12.1(8a)E Support for this command was extended to the E train.
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Examples This example shows how to enable and set the rate-limiting feature:
Router(config)# mls ip cef rate-limit 50000
Router(config)#
Related Commands set mls rate (refer to the Catalyst 6500 Series Switch Command Reference)
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mls ip delete-threshold
mls ip delete-threshold
Use the mls ip delete-threshold command to delete configured ACL thresholds.
mls ip delete-threshold acl-num
Syntax Description
Defaults This command has no default settings.
Command Modes Global configuration
Command History
Usage Guidelines The mls ip delete-threshold command is active only when you enable the mls ip reflexive ndr-entry
tcam command.
Examples This example shows how to delete an ACL threshold:
Router(config)# mls ip delete-threshold 223
Router(config)#
Related Commands mls ip install-threshold
mls ip reflexive ndr-entry tcam (refer to the Catalyst 6500 Series IOS Command Reference)
acl-num Reflective ACL number; valid values are from 1 to 10000.
Release Modification
12.1(12c)E1 This command was introduced on the MSFC.
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mls ip inspect
Use the mls ip inspect command to permit traffic through any ACLs that would deny the traffic through
other interfaces. Use the no form of this command to return to the default setting.
mls ip inspect acl-name
no mls ip inspect acl-name
Syntax Description
Defaults Permit traffic is disabled.
Command Modes Global configuration
Command History
Usage Guidelines On a Catalyst 6500 series switch, when interfaces are configured to deny traffic, the CBAC permits
traffic to flow bidirectionally only through the interface that is configured with the ip inspect command.
Examples This example shows how to permit the traffic through a specific ACL (named deny_ftp_c):
Router(config)# mls ip inspect deny_ftp_c
Router(config)#
Related Commands ip inspect (refer to Cisco IOS documentation)
acl-name ACL name.
Release Modification
12.1E This command was introduced on the MSFC.
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mls ip install-threshold
mls ip install-threshold
Use the mls ip install-threshold command to install the configured ACL thresholds.
mls ip install-threshold acl-num
Syntax Description
Defaults This command has no default settings.
Command Modes Global configuration
Command History
Usage Guidelines The mls ip install-threshold command is active only when you enable the mls ip reflexive ndr-entry
tcam command.
Examples This example shows how to install an ACL threshold:
Router(config)# mls ip install-threshold 123
Router(config)#
Related Commands mls ip delete-threshold
mls ip reflexive ndr-entry tcam (refer to the Catalyst 6500 Series Switch Cisco IOS Command
Reference)
acl-num Reflective ACL number; valid values are from 1 to 10000.
Release Modification
12.1(12c)E1 This command was introduced on the MSFC.
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mls ip multicast consistency-check
To enable and configure the hardware shortcut consistency checker, use the mls ip multicast
consistency-check command. Use the no form of this command to disable the consistency checkers.
mls ip multicast consistency-check [{settle-time seconds} | {type scan-mroute [count
count-number] | {settle-time seconds}}]
no mls ip multicast consistency-check
Syntax Description
Defaults The defaults are as follows:
Consistency check is enabled.
count count-number is 20.
period seconds is 2 seconds.
settle-time seconds is 60 seconds.
Command Modes Global configuration
Command History
Usage Guidelines oif is the outgoing interface of a multicast {*,G} or {source, group} flow.
The consistency checker scans the mroute-table and assures that the multicast-hardware entries are
consistent with the mroute-table. Whenever an inconsistency is detected, the inconsistency is
automatically corrected.
To display the inconsistency error, use the show mls ip multicast consistency-check command.
settle-time
seconds (Optional) Specifies the settle time for entry/oif for the consistency
checker; valid values are from 2 to 3600 seconds.
type
scan-mroute (Optional) Specifies the type of consistency check as a scan check of the
mroute table.
count
count-number (Optional) Specifies the maximum number of prefixes to check per
scan; valid values are from 2 to 500.
period seconds Specifies the period between scans; valid values are from 2 to
3600 seconds.
Release Modification
12.1(12c)E4 Support for this command was introduced on the MSFC.
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mls ip multicast consistency-check
Examples This example shows how to enable the hardware shortcut consistency checker:
Router (config)# mls ip multicast consistency-check
Router (config)#
This example shows how to enable the hardware shortcut consistency checker and configure the scan
check of the mroute table:
Router (config)# mls ip multicast consistency-check type scan-mroute count 20 period 35
Router (config)#
This example shows how to enable the hardware shortcut consistency checker and specify the period
between scans:
Router (config)# mls ip multicast consistency-check type scan-mroute period 35
Router (config)#
Related Commands show mls ip multicast consistency-check (refer to the Catalyst 6500 Series Switch Cisco IOS Command
Reference
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mls ip multicast stub
To enable support for non-RPF traffic drops for PIM sparse-mode stub networks, use the mls ip
multicast stub command. Use the no form of this command to disable this feature.
mls ip multicast stub
no mls ip stub
Syntax Description This command has no arguments or keywords.
Defaults Multicast is disabled
Command Modes Interface configuration
Command History
Usage Guidelines When you enable the ACL-based method of filtering RPF failures by entering the mls ip multicast stub
command on the redundant router, the following ACLs automatically download to the PFC and are
applied to the interface that you specify:
access-list 100 permit ip A.B.C.0 0.0.0.255 any
access-list 100 permit ip A.B.D.0 0.0.0.255 any
access-list 100 permit ip any 224.0.0.0 0.0.0.255
access-list 100 permit ip any 224.0.1.0 0.0.0.255
access-list 100 deny ip any 224.0.0.0 15.255.255.255
The ACLs filter RPF failures and drop them in hardware so that they are not forwarded to the router.
Use the ACL-based method of filtering RPF failures only in sparse-mode stub networks where there are
no downstream routers. For dense mode groups, RPF failure packets have to be seen on the router for
the PIM assert mechanism to function properly. Use CEF-or NetFlow-based rate limiting to rate limit
RPF failures in dense-mode networks and sparse-mode transit networks.
Examples This example shows how to enable support for non-RPF traffic drops for PIM sparse-mode stub
networks:
Router(config-if)# mls ip multicast stub
Router(config-if)#
Related Commands show mls ip multicast (refer to the Catalyst 6500 Series Switch Cisco IOS Command Reference)
Release Modification
12.2(14)SX Support for this command was introduced on the MSFC.
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mtu
mtu
To adjust the maximum packet size or MTU size, use the mtu command. Use the no form of this
command to return to the default value.
mtu bytes
no mtu
Syntax Description
Defaults Table 2-2 lists the default MTU values if jumbo frame support is disabled.
If you enable jumbo frame support, the default is 64 for SVI ports and 9216 for all other ports. Jumbo
frame support is disabled by default.
Command Modes Interface configuration
Command History
bytes Byte size; valid values are from 64 to 9216 for SVI ports and from 1500
to 9216 for all other ports.
Table 2-2 Default MTU Values
Media Type Default MTU (bytes)
Ethernet 1500
Serial 1500
Token Ring 4464
ATM 4470
FDDI 4470
HSSI (HSA) 4470
Release Modification
12.1(8a)EX Support for this command was introduced on the MSFC.
12.1(11b)EX This command was changed to support jumbo frames.
12.1(13)E Support for this command was extended to the E train.
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Usage Guidelines For switch ports, only one larger-than-default MTU value is allowed globally. For Layer 3 ports,
including router ports and VLANs, you can configure nondefault MTU values on a per-interface basis.
For a complete list of modules that do not support jumbo frames, refer to the Catalyst 6500 Series Switch
Cisco IOS Software Configuration Guide.
Changing the MTU value with the mtu command can affect values for the protocol-specific versions of
the command (for example, the ip mtu command). If the values specified with the ip mtu command is
the same as the value specified with the mtu command, and you change the value for the mtu command,
the ip mtu value automatically matches the new mtu command value. However, changing the values for
the ip mtu command has no effect on the value for the mtu command.
Examples This example shows how to specify an MTU of 1800 bytes:
Router(config)# interface fastethernet 5/1
Router(config-if)# mtu 1800
Related Commands ip mtu (refer to the Cisco IOS Release 12.1 Command Reference)
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redundancy
redundancy
To enable redundancy and enter the redundancy configuration mode, use the redundancy command.
redundancy
Syntax Description This command has no arguments or keywords.
Defaults This command has no default settings.
Command Modes Global configuration
Command History
Usage Guidelines Once you enter redundancy configuration mode, these options are available:
exit—Exits from redundancy configuration mode.
high-availability—Enters high-availability redundancy configuration mode. See the
high-availability command for additional information.
no—Negates a command or set its defaults.
Examples This example shows how to enable redundancy and enter the redundancy configuration submode:
Router(config)# redundancy
Router(config-r)#
Related Commands high-availability
show redundancy
Release Modification
12.1E This command was introduced on the MSFC.
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set traffic-index
To create a BGP traffic classification number for accounting, use the set traffic-index command.
set traffic-index num
Syntax Description
Defaults This command has no default settings.
Command Modes Route map configuration
Command History
Usage Guidelines Inbound and outbound traffic-shaping is based on destination traffic-index called DSTS. Destination
sensitive billing provides packet and byte counters (seven sets per inbound interface), which represent
counts for IP packets by destination network. It uses route maps to classify the traffic into one of seven
possible indexes, which represent a traffic classification.
Examples This example shows how to create a BGP traffic index:
Router(config-route-map)# set traffic-index 3
Router(config-route-map)
num Number of the bucket; valid values are from 1 to 7.
Release Modification
12.1E This command was introduced on the MSFC.
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show fm features
show fm features
To display information about the general feature manager, use the show fm features command.
show fm features
Syntax Description This command has no keywords or arguments.
Defaults This command has no default settings.
Command Modes EXEC
Command History
Examples This example shows how to display information about the general feature manager:
Router> show fm features
Designated MSFC:1 Non-designated MSFC:1
Redundancy Status:designated
Interface:FastEthernet2/10 IP is enabled
hw[EGRESS] = 1, hw[INGRESS] = 1
hw_force_default[EGRESS] = 0, hw_force_default[INGRESS] = 0
mcast = 0
priority = 2
reflexive = 0
inbound label:1
protocol:ip
feature #:1
feature id:FM_IP_ACCESS
ACL:106
outbound label:2
protocol:ip
feature #:1
feature id:FM_IP_ACCESS
ACL:106
Interface:FastEthernet2/26 IP is enabled
hw[EGRESS] = 1, hw[INGRESS] = 0
hw_force_default[EGRESS] = 0, hw_force_default[INGRESS] = 1
mcast = 0
priority = 2
reflexive = 0
inbound label:24
protocol:ip
feature #:1
feature id:FM_IP_ACCESS
ACL:113
outbound label:3
protocol:ip
feature #:1 feature
Release Modification
12.1E This command was introduced on the MSFC.
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id:FM_IP_WCCP
Service ID:0
Service Type:0
Interface:Vlan55 IP is enabled
hw[EGRESS] = 1, hw[INGRESS] = 1
hw_force_default[EGRESS] = 0, hw_force_default[INGRESS] = 0
mcast = 0
priority = 2
reflexive = 0
inbound label:4
protocol:ip
feature #:1
feature id:FM_IP_ACCESS
ACL:111
Interface:Vlan101 IP is enabled
hw[EGRESS] = 1, hw[INGRESS] = 1
hw_force_default[EGRESS] = 0, hw_force_default[INGRESS] = 0
mcast = 0
priority = 2
reflexive = 0
inbound label:5
protocol:ip
feature #:1
feature id:FM_IP_ACCESS
ACL:101
outbound label:6
protocol:ip
feature #:1
feature id:FM_IP_ACCESS
ACL:101
Router>
This example shows how to display lines of general feature manager information beginning with the line
that begins with Redundancy:
Router> show fm features | begin Redundancy
Redundancy Status: designated
Router>
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show fm inband-counters
show fm inband-counters
To display the number of inband packets sent by the MSFC for SLB and WCCP, use the show fm
inband-counters command.
show fm inband-counters
Syntax Description This command has no keywords or arguments.
Defaults This command has no default settings.
Command Modes EXEC
Command History
Usage Guidelines The show fm inband-counters command output display includes the number of SLB inband packets
that were sent and the number of WCCP inband packets that were sent.
If CBAC is configured, the display includes the number of packets that were sent for CBAC.
Examples This example shows how to display the number of SLB and WCCP inband packets that were sent:
Router# show fm inband-counters
Inband Packets Sent
Slot WCCP SLB
1 0 0
2 0 0
3 0 0
4 0 0
5 0 0
6 0 0
7 0 0
8 0 0
9 0 0
10 0 0
11 0 0
12 0 0
13 0 0
Router#
Release Modification
12.1(8a)E2 Support for this command was introduced on the MSFC.
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show fm insp
To display the list and status of the ACLs and ports on which CBAC is configured, use the show fm insp
command.
show fm insp [detail]
Syntax Description
Defaults This command has no default settings.
Command Modes EXEC
Command History
Usage Guidelines If you can configure a VACL on the port before you configure CBAC, the status displayed is INACTIVE;
otherwise, it is ACTIVE. If PFC resources are exhausted, the command displays BRIDGE followed by
the number of failed currently active NetFlow requests that have been sent to the MSFC2 for processing.
The show fm insp command output includes this information:
interface:—Interface on which the IP inspect feature is enabled.
(direction)—Direction in which the IP inspect feature is enabled (IN or OUT).
acl name:—Name used to identify the packets that are being inspected.
status:—(ACTIVE or INACTIVE) tells you if HW-assist is provided for this interface+direction
(ACTIVE=hardware assisted or INACTIVE).
The detail option also displays the ACEs that are part of the ACL that is used for IP inspect on the given
interface direction.
Examples This example shows how to display the list and status of CBAC-configured ACLs and ports:
Router> show fm insp
interface:Vlan305(in) status :ACTIVE
acl name:deny
interfaces:
Vlan305(out):status ACTIVE
detail (Optional) Displays all of the flow information.
Release Modification
12.1(6)E Support for this command was introduced on the MSFC.
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show fm interface
show fm interface
To display the detailed information about the feature manager on a per-interface basis, use the show fm
interface command.
show fm interface {{interface interface-number} | {null interface-number} | {port-channel
number} | {vlan vlan-id}}
Syntax Description
Defaults This command has no default settings.
Command Modes EXEC
Command History
Usage Guidelines The interface-number argument designates the module and port number. Valid values for
interface-number depend on the specified interface type and the chassis and module used. For example,
if you specify a Gigabit Ethernet interface and have a 48-port 10/100BASE-T Ethernet module installed
in a Catalyst 6513 chassis, valid values for the module number are from 2 to 13 and valid values for the
port number are from 1 to 48.
If your system is configured with a Supervisor Engine 1, valid values for vlan-id are from 1 to 1005. If
your system is configured with a Supervisor Engine 2, valid values for vlan-id are from 1 to 4094.
Extended-range VLANs are not supported on systems configured with a Supervisor Engine 1.
Examples This example shows how to display the detailed information about the feature manager on a specified
interface:
Router> show fm interface fastethernet 2/26
Interface:FastEthernet2/26 IP is enabled
hw[EGRESS] = 1, hw[INGRESS] = 0
hw_force_default[EGRESS] = 0, hw_force_default[INGRESS] = 1
mcast = 0
priority = 2
reflexive = 0
inbound label:24
protocol:ip
interface Interface type; possible valid values are pos, atm, and ge-wan.
interface-number Module and port number; see the “Usage Guidelines” section for valid
values.
null
interface-number Specifies the null interface; the valid value is 0.
vlan vlan-id Specifies the VLAN; see the “Usage Guidelines” section for a list of
valid values.
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feature #:1
feature id:FM_IP_ACCESS
ACL:113
vmr IP value #1:0, 0, 0, 0, 0, 0, 0, 6 - 1
vmr IP mask #1:0, 0, FFFF, FFFF, 0, 0, 0, FF
vmr IP value #2:642D4122, 0, 0, 0, 1, 0, 0, 6 - 1
vmr IP mask #2:FFFFFFFF, 0, 0, 0, 1, 0, 0, FF
vmr IP value #3:0, 64020302, 0, 0, 6, 0, 0, 6 - 1
vmr IP mask #3:0, FFFFFFFF, 0, 0, 6, 0, 0, FF
vmr IP value #4:0, 64020302, 0, 0, A, 0, 0, 6 - 1
vmr IP mask #4:0, FFFFFFFF, 0, 0, A, 0, 0, FF
vmr IP value #5:0, 64020302, 0, 0, 12, 0, 0, 6 - 1
vmr IP mask #5:0, FFFFFFFF, 0, 0, 12, 0, 0, FF
vmr IP value #6:0, 0, 0, 0, 0, 0, 0, 0 - 2
vmr IP mask #6:0, 0, 0, 0, 0, 0, 0, 0
outbound label:3
protocol:ip
feature #:1
feature id:FM_IP_WCCP
Service ID:0
Service Type:0
Router>
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show fm reflexive
show fm reflexive
To display information about the dynamic feature manager reflexive entry, use the show fm reflexive
command.
show fm reflexive
Syntax Description This command has no keywords or arguments.
Defaults This command has no default settings.
Command Modes EXEC
Command History
Examples This example shows how to display information about the dynamic feature manager reflexive entry:
Router# show fm reflexive
Reflexive hash table:
Vlan613:refacl, OUT-REF, 64060E0A, 64060D0A, 0, 0, 7, 783, 6
Router#
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show fm summary
To display a summary of feature manager information, use the show fm summary command.
show fm summary
Syntax Description This command has no keywords or arguments.
Defaults This command has no default settings.
Command Modes EXEC
Command History
Examples This example shows how to display a summary of feature manager information:
Router# show fm summary
Current global ACL merge algorithm:BDD
Router#
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show fm vlan
show fm vlan
To display information about the per-VLAN feature manager, use the show fm vlan command.
show fm vlan vlan-id
Syntax Description
Defaults This command has no default settings.
Command Modes EXEC
Command History
Usage Guidelines If your system is configured with a Supervisor Engine 1, valid values for vlan-id are from 1 to 1005. If
your system is configured with a Supervisor Engine 2, valid values for vlan-id are from 1 to 4094.
Extended-range VLANs are not supported on systems configured with a Supervisor Engine 1.
Examples This example shows how to display information about the per-VLAN feature manager:
Router# show fm vlan 1
hw[EGRESS] = 1, hw[INGRESS] = 1
hw_force_default[EGRESS] = 0, hw_force_default[INGRESS] = 0
mcast = 0
priority = 2
reflexive = 0
vacc_map : map1
inbound label: 5
merge_err: 0
protocol: ip
feature #: 1
feature id: FM_VACL
map_name: map1
seq #: 10
(only for IP_PROT) DestAddr SrcAddr Dpt Spt L4OP TOS Est prot Rslt
vmr IP value # 1: 0.0.0.0 0.0.0.0 0 0 0 0 0 6 permit
vmr IP mask # 1: 0.0.0.0 0.0.0.0 0 0 0 0 0 FF
vmr IP value # 2: 0.0.0.0 0.0.0.0 0 0 0 0 0 11 permit
vmr IP mask # 2: 0.0.0.0 0.0.0.0 0 0 0 0 0 FF
vmr IP value # 3: 0.0.0.0 0.0.0.0 0 0 0 0 0 0 deny
vmr IP mask # 3: 0.0.0.0 0.0.0.0 0 0 0 0 0 0
seq #: 65536
(only for IP_PROT) DestAddr SrcAddr Dpt Spt L4OP TOS Est prot Rslt
vlan-id VLAN number; see the “Usage Guidelines” section for valid values.
Release Modification
12.1(11b)EX Support for this command was introduced on the Catalyst 6500 series
switches.
12.1(13)E Support for this command on the Catalyst 6500 series switches was
extended to the E train.
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vmr IP value # 1: 0.0.0.0 0.0.0.0 0 0 0 0 0 0 permit
vmr IP mask # 1: 0.0.0.0 0.0.0.0 0 0 0 0 0 0
outbound label: 6
merge_err: 0
protocol: ip
feature #: 1
feature id: FM_VACL
map_name: map1
seq #: 10
(only for IP_PROT) DestAddr SrcAddr Dpt Spt L4OP TOS Est prot Rslt
vmr IP value # 1: 0.0.0.0 0.0.0.0 0 0 0 0 0 6 permit
vmr IP mask # 1: 0.0.0.0 0.0.0.0 0 0 0 0 0 FF
vmr IP value # 2: 0.0.0.0 0.0.0.0 0 0 0 0 0 11 permit
vmr IP mask # 2: 0.0.0.0 0.0.0.0 0 0 0 0 0 FF
vmr IP value # 3: 0.0.0.0 0.0.0.0 0 0 0 0 0 0 deny
vmr IP mask # 3: 0.0.0.0 0.0.0.0 0 0 0 0 0 0
seq #: 65536
(only for IP_PROT) DestAddr SrcAddr Dpt Spt L4OP TOS Est prot Rslt
vmr IP value # 1: 0.0.0.0 0.0.0.0 0 0 0 0 0 0 permit
vmr IP mask # 1: 0.0.0.0 0.0.0.0 0 0 0 0 0 0
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show ip auth-proxy watch-list
show ip auth-proxy watch-list
To display the authentication proxy watch list information, use the show ip auth-proxy watch-list
command.
show ip auth-proxy watch-list
Syntax Description This command has no arguments or keywords.
Defaults This command has no default settings.
Command Modes EXEC
Command History
Examples Router# show ip auth-proxy watch-list
Authentication Proxy Watch-list is enabled
Watch-list expiry timeout is 2 minutes
Total number of watch-list entries: 3
Source IP Type Violation-count
12.0.0.2 MAX_RETRY MAX_LIMIT
12.0.0.3 TCP_NO_DATA MAX_LIMIT
1.2.3.4 CFGED N/A
Total number of watch-listed users: 3
Router#
Related Commands clear ip auth-proxy watch-list
ip auth-proxy max-login-attempts
ip auth-proxy watch-list
Release Modification
12.1(13)E This command was introduced on the MSFC.
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show ip wccp web-cache detail
To display statistics for only the first packet of a Layer 2 redirected flow, use the show ip wccp
web-cache detail command.
show ip wccp web-cache detail
Syntax Description This command has no keywords or arguments.
Defaults This command has no default settings.
Command Modes EXEC
Command History
Usage Guidelines Use the show ip wccp web-cache detail command to provide an indication of how many flows, rather
than packets, are using Layer 2 redirection.
For additional information regarding IP WCCP commands, refer to the section “Configuring Web Cache
Services Using WCCP” in the Cisco IOS Configuration Fundamentals Configuration Guide.
Examples This example displays the connected cache engine using Layer 2 redirection:
Router# show ip wccp web-cache detail
WCCP Cache-Engine information:
IP Address: 10.11.1.1
Protocol Version: 2.0
State: Usable
Redirection: L2
Initial Hash Info: FFFFFFFFFFFFFFFFFFFFFFFFFFFFFFFF
FFFFFFFFFFFFFFFFFFFFFFFFFFFFFFFF
Assigned Hash Info: FFFFFFFFFFFFFFFFFFFFFFFFFFFFFFFF
FFFFFFFFFFFFFFFFFFFFFFFFFFFFFFFF
Hash Allotment: 256 (100.00%)
Packets Redirected: 10273
Connect Time: 17:05:44
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show ip wccp web-cache detail
Table 2-3 describes the fields shown in the example.
Related Commands clear ip wccp (refer to Cisco IOS documentation)
ip wccp (refer to Cisco IOS documentation)
show ip interface (refer to Cisco IOS documentation)
Table 2-3 show ip wccp web-cache detail Command Output Fields
Field Description
WCCP Cache-Engine information Header for the area that contains the fields for the IP address and
the version of WCCP associated with the router connected to the
cache engine in the service group.
IP Address IP address of the router connected to the cache engine in the
service group.
Protocol Version Version of WCCP that is used by the router in the service group.
WCCP Cache-Engine information Fields for information on the cache engines.
IP Address IP address of the cache engine in the service group.
Protocol Version Version of WCCP that is used by the cache engine in the service
group.
State Status of whether the cache engine is operating properly and can
be contacted by a router and other cache engines in the service
group.
Initial Hash Info Initial state of the hash bucket assignment.
Assigned Hash Info Current state of the hash bucket assignment.
Hash Allotment Percentage of buckets assigned to the current cache engine. Both
a value and a percent figure are displayed.
Packets Redirected Number of packets that have been redirected to the cache engine.
Connect Time Amount of time it took for the cache engine to connect to the
router.
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show l3-mgr
To display Layer 3 manager information, use the show l3-mgr command.
show l3-mgr status
show l3-mgr {interface {{interface interface-number} | {null interface-number} |
{port-channel number} | {vlan vlan-id} | status}}
Syntax Description
Defaults This command has no default settings.
Command Modes EXEC
Command History
Usage Guidelines This command is useful for debugging purposes and the output is intended for TAC and engineering use
only.
The interface-number argument designates the module and port number. Valid values for
interface-number depend on the specified interface type and the chassis and module used. For example,
if you specify a Gigabit Ethernet interface and have a 48-port 10/100BASE-T Ethernet module installed
in a Catalyst 6513 chassis, valid values for the module number are from 2 to 13 and valid values for the
port number are from 1 to 48.
If your system is configured with a Supervisor Engine 1, valid values for vlan-id are from 1 to 1005. If
your system is configured with a Supervisor Engine 2, valid values for vlan-id are from 1 to 4094.
Extended-range VLANs are not supported on systems configured with a Supervisor Engine 1.
status Displays the global argument information.
interface Displays the interface detailed Layer 3 manager information.
interface Interface type; possible valid values are pos, atm, and ge-wan.
interface-number Module and port number; see the “Usage Guidelines” section for valid
values.
null
interface-number Specifies the null interface; the valid value is 0.
vlan vlan-id Specifies the VLAN; see the “Usage Guidelines” section for valid values.
status Specifies the Layer 3 manager status information.
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show l3-mgr
Examples This example shows how to display Layer 3 manager status information:
Router# show l3-mgr status
l3_mgr_state: 2
l3_mgr_req_q.count: 0
l3_mgr_req_q.head: 0
l3_mgr_req_q.tail: 0
l3_mgr_max_queue_count: 1060
l3_mgr_shrunk_count: 0
l3_mgr_req_q.ip_inv_count: 303
l3_mgr_req_q.ipx_inv_count: 0
l3_mgr_outpak_count: 18871
l3_mgr_inpak_count: 18871
l3_mgr_max_pending_pak: 4
l3_mgr_pending_pak_count: 0
nde enable statue: 0
current nde addr: 0.0.0.0
Router#
This example shows how to display Layer 3 manager information for a specific interface:
Router# show l3-mgr interface ge-wan 5/40
vlan: 0
ip_enabled: 1
ipx_enabled: 1
bg_state: 0 0 0 0
hsrp_enabled: 0
hsrp_mac: 0000.0000.0000
state: 0
up: 0
Router#
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show microcode
To display the versions for all bundled MCP and LCP images for the runtime supervisor engine image, use
the show microcode command.
show microcode
Syntax Description This command has no arguments or keywords.
Defaults This command has no default settings.
Command Modes EXEC
Command History
Examples This example shows how to display microcode versions:
Console> (enable) show microcode
Bundled Images Version Size Built
--------------- -------------------- ------- -----------------
LCP SLCP 6.2(0.92) 330918 02/16/01 01:26:27
LCP LX1000 6.2(0.92) 312782 02/16/01 01:27:59
LCP LX10100 6.2(0.92) 364846 02/16/01 01:26:47
LCP AX10100 6.2(0.92) 380296 02/16/01 01:27:10
LCP AX1000 6.2(0.92) 338672 02/16/01 01:28:19
LCP VX10100 6.2(0.92) 378532 02/16/01 01:27:35
LCP CPSLCP 6.2(0.92) 585234 02/16/01 00:59:19
LCP CPFAB 6.2(0.92) 251186 02/16/01 01:02:58
LCP CPGBIT 6.2(0.92) 579282 02/16/01 01:00:49
LCP CP10G 6.2(0.92) 477778 02/16/01 01:02:17
LCP CPMBIT2 6.2(0.92) 777922 02/16/01 01:05:20
Console> (enable) show
Release Modification
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show msfc2 rom-monitor
show msfc2 rom-monitor
To display the ROMMON region status, use the show msfc2 rom-monitor command.
show msfc2 rom-monitor
Syntax Description This command has no arguments or keywords.
Defaults This command has no default settings.
Command Modes EXEC
Command History
Examples This example shows how to display ROMMON information:
Router# show msfc2 rom-monitor
Region region1: APPROVED, preferred
Region region2: INVALID
Currently running ROMMON from region1 region
Router#
Table 3-4 describes the possible output fields for the show msfc2 rom-monitor command.
Related Commands upgrade rom-monitor
Release Modification
12.1E This command was introduced on the MSFC.
Table 3-4 show msfc2 rom-monitor Command Output Fields
Field Description
Region region1 and
region2 ROMMON image status and the order of preference that
region1 or region2 images should be booted from.
First run ROMMON image status indicating a check of the new image
that is run.
Invalid ROMMON image status indicating the new image has been
checked and the upgrade process has started.
Approved ROMMON image status indicating the ROMMON field
upgrade process has completed.
Currently running Current running image and the region.
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show redundancy
To display redundancy high-availability setting information, use the show redundancy command.
show redundancy
Syntax Description This command has no arguments or keywords.
Defaults This command has no default settings.
Command Modes EXEC
Command History
Examples This example shows how to display information about the RF client:
Router# show redundancy
Designated Router: 2 Non-designated Router: 0
Redundancy Status: designated
Config Sync AdminStatus : enabled
Config Sync RuntimeStatus: disabled
Single Router Mode AdminStatus : disabled
Single Router Mode RuntimeStatus: disabled
Single Router Mode transition timer : 120 seconds
Router#
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show scp
show scp
To display SCP information, use the show scp command.
show scp {accounting | counters | {process [id]} | status}
Syntax Description
Defaults This command has no default settings.
Command Modes EXEC
Command History
Usage Guidelines This command is useful for debugging purposes and the output is intended for TAC and engineering use
only.
Examples This example shows how to display SCP accounting information:
Router> show scp accounting
Total 11 1D 1E 2C 82 100 105 10F 119 11C 11D 11E 127
----- ---- ---- ---- ---- ---- ---- ---- ---- ---- ---- ---- ---- ----
Tot: 10F8 FFC1 2 2 3 1 0 1 2 2 1 6 E 110E
10FB FFC1 2 2 3 1 2 1 2 3 1 6 E 110E
11: 10F8 FFC1 2 2 3 1 0 1 2 2 1 6 E 110E
10FA FFC1 2 2 3 1 1 1 2 3 1 6 E 110E
13: 0 0 0 0 0 0 0 0 0 0 0 0 0 0
1 0 0 0 0 0 1 0 0 0 0 0 0 0
12B 157 1FF
---- ---- ----
Tot: 1 4 2
1 4 2
11: 1 4 2
1 4 2
13: 0 0 0
0 0 0
Router>
accounting Displays SCP accounting information.
counters Displays SCP counter information.
process id Displays information for a specific process and process ID.
status Displays local SCP server status information.
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This example shows how to display SCP counter information:
Router> show scp counters
received packets = 69896
transmitted packets = 69894
retransmitted packets = 0
loop back packets = 0
transmit failures = 0
recv pkts not for me = 0
recv pkts to dead process = 0
recv pkts not enqueuable = 0
response has wrong opcode = 0
response has wrong seqnum = 0
response is not an ack = 0
response is too big = 0
Router>
This example shows how to display the process name and the number of messages received and transmitted:
Router# show scp process
PID Process Msgs Msgs NMP Tx Q Msgs Bufs Rx Q Rx Q
Sent Resent in Overflow Rcvd Held Size Oflow
--- ---------------- ---------- ---------- ------------ ---------- ----- ----- ----------
0 Kernel and Idle 2 0 0 0 0 0 0
1 Flash MIB Updat 0 0 0 0 0 0 0
2 SynDiags 1410 0 0 1410 0 4 0
3 SynConfig 2 0 0 3481603 0 64 0
4 Statuspoll 3481589 0 0 0 0 2 0
5 SL_TASK 0 0 0 0 0 24 0
.
.
.
This example shows how to display local SCP server status information:
Router> show scp status
Rx 69866, Tx 69864, Sap 6
Id Channel name # msgs pending # peak count
-- ------------------------- -------------- ------------
0 SCP async: TCAM MGR Chann 0 5
1 SCP async: l3_mgr scp cha 0 1
2 SCP async: l3_mgr scp cha 0 2
3 SCP async: Draco-NMP 0 1
Router>
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show slot0:
show slot0:
To display information about the slot0: file system, use the show slot0: command.
show slot0: [all | chips | filesys]
Syntax Description
Defaults This command has no default settings.
Command Modes EXEC
Command History
Examples This example shows how to display a summary of image information:
Router> show slot0:
-#- ED --type-- --crc--- -seek-- nlen -length- -----date/time------ name
1 .. image 6375DBB7 A4F144 6 10678468 Nov 09 1999 10:50:42 halley
5705404 bytes available (10678596 bytes used)
Router>
This example shows how to display Flash chip information:
Router> show slot0: chips
******** Intel Series 2+ Status/Register Dump ********
ATTRIBUTE MEMORY REGISTERS:
Config Option Reg (4000): 2
Config Status Reg (4002): 0
Card Status Reg (4100): 1
Write Protect Reg (4104): 4
Voltage Cntrl Reg (410C): 0
Rdy/Busy Mode Reg (4140): 2
COMMON MEMORY REGISTERS: Bank 0
Intelligent ID Code : 8989A0A0
Compatible Status Reg: 8080
Global Status Reg: B0B0
all (Optional) Displays all Flash information including the output from the
show slot0: chips and show slot0: filesys commands.
chips (Optional) Displays Flash chip information.
filesys (Optional) Displays file system information.
Release Modification
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Block Status Regs:
0 : B0B0 B0B0 B0B0 B0B0 B0B0 B0B0 B0B0 B0B0
8 : B0B0 B0B0 B0B0 B0B0 B0B0 B0B0 B0B0 B0B0
16 : B0B0 B0B0 B0B0 B0B0 B0B0 B0B0 B0B0 B0B0
24 : B0B0 B0B0 B0B0 B0B0 B0B0 B0B0 B0B0 B0B0
COMMON MEMORY REGISTERS: Bank 1
Intelligent ID Code : 8989A0A0
Compatible Status Reg: 8080
Global Status Reg: B0B0
Block Status Regs:
0 : B0B0 B0B0 B0B0 B0B0 B0B0 B0B0 B0B0 B0B0
8 : B0B0 B0B0 B0B0 B0B0 B0B0 B0B0 B0B0 B0B0
16 : B0B0 B0B0 B0B0 B0B0 B0B0 B0B0 B0B0 B0B0
24 : B0B0 B0B0 B0B0 B0B0 B0B0 B0B0 B0B0 B0B0
COMMON MEMORY REGISTERS: Bank 2
Intelligent ID Code : 8989A0A0
Compatible Status Reg: 8080
Global Status Reg: B0B0
Block Status Regs:
0 : B0B0 B0B0 B0B0 B0B0 B0B0 B0B0 B0B0 B0B0
8 : B0B0 B0B0 B0B0 B0B0 B0B0 B0B0 B0B0 B0B0
16 : B0B0 B0B0 B0B0 B0B0 B0B0 B0B0 B0B0 B0B0
24 : B0B0 B0B0 B0B0 B0B0 B0B0 B0B0 B0B0 B0B0
COMMON MEMORY REGISTERS: Bank 3
Intelligent ID Code : 8989A0A0
Compatible Status Reg: 8080
Global Status Reg: B0B0
Block Status Regs:
0 : B0B0 B0B0 B0B0 B0B0 B0B0 B0B0 B0B0 B0B0
8 : B0B0 B0B0 B0B0 B0B0 B0B0 B0B0 B0B0 B0B0
16 : B0B0 B0B0 B0B0 B0B0 B0B0 B0B0 B0B0 B0B0
24 : B0B0 B0B0 B0B0 B0B0 B0B0 B0B0 B0B0 B0B0
COMMON MEMORY REGISTERS: Bank 4
Intelligent ID Code : FFFFFFFF
IID Not Intel -- assuming bank not populated
Router>
This example shows how to display file system information:
Router> show slot0: filesys
-------- F I L E S Y S T E M S T A T U S --------
Device Number = 0
DEVICE INFO BLOCK: slot0
Magic Number = 6887635 File System Vers = 10000 (1.0)
Length = 1000000 Sector Size = 20000
Programming Algorithm = 4 Erased State = FFFFFFFF
File System Offset = 20000 Length = FA0000
MONLIB Offset = 100 Length = F568
Bad Sector Map Offset = 1FFF0 Length = 10
Squeeze Log Offset = FC0000 Length = 20000
Squeeze Buffer Offset = FE0000 Length = 20000
Num Spare Sectors = 0
Spares:
STATUS INFO:
Writable
NO File Open for Write
Complete Stats
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show slot0:
No Unrecovered Errors
No Squeeze in progress
USAGE INFO:
Bytes Used = 9F365C Bytes Available = 5AC9A4
Bad Sectors = 0 Spared Sectors = 0
OK Files = 1 Bytes = 9F35DC
Deleted Files = 0 Bytes = 0
Files w/Errors = 0 Bytes = 0
Router>
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Chapter 2 Catalyst 6500 Series Switch MSFC Commands show standby delay
show standby delay
To display HSRP information about delay periods, use the show standby delay command.
show standby delay [type number]
Syntax Description
Defaults This command has no default settings.
Command Modes Privileged EXEC
Command History
Examples This example shows the output from the show standby delay command:
Router# show standby delay
Interface Minimum Reload
VLAN100 1 5
Router#
Related Commands standby delay minimum reload
type number (Optional) Interface type and number for which output is displayed.
Release Modification
12.1(13)E Support for this command was introduced on the MSFC.
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snmp-server enable traps
snmp-server enable traps
To enable SNMP notifications (traps or informs) available on your system, use the snmp-server enable
traps command. To disable all available SNMP notifications, use the no form of this command.
snmp-server enable traps [notification-type]
no snmp-server enable traps [notification-type]
Syntax Description
Defaults This command is disabled by default. Most notification types are disabled. However, some notification
types cannot be controlled with this command.
If you enter this command without a notification-type, all notification types controlled by this command
are enabled.
If enabled, the default settings are as follows:
interval seconds is 30
fail-interval seconds is 0
Command Modes Global configuration
Command History
Usage Guidelines For additional notification types, refer to Cisco IOS documentation.
SNMP notifications can be sent as traps or inform requests. This command enables both traps and inform
requests for the specified notification types. To specify whether the notifications should be sent as traps
or informs, use the snmp-server host [traps | informs] command.
If you do not enter an snmp-server enable traps command, no notifications controlled by this command
are sent. In order to configure the router to send these SNMP notifications, you must enter at least one
snmp-server enable traps command. If you enter the command with no keywords, all notification types
are enabled. If you enter the command with a keyword, only the notification type related to that keyword
is enabled. In order to enable multiple types of notifications, you must issue a separate
snmp-server enable traps command for each notification type and notification option.
The snmp-server enable traps command is used in conjunction with the snmp-server host command.
Use the snmp-server host command to specify which host or hosts receive SNMP notifications. In order
to send notifications, you must configure at least one snmp-server host command.
notification-type (Optional) Type of notification (trap or inform) to enable or disable. If no
type is specified, all notifications available on your device are enabled or
disabled. See the “Usage Guidelines” section for valid values.
notification-option (Optional) Notification option. See the “Usage Guidelines” section for valid
values.
Release Modification
12.1(11b)E Support for this command was introduced on the Catalyst 6500 series switches.
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Valid values for the notification-type are as follows:
atm—Enables ATM PVC notifications. When you enter atm pvc, you can specify additional
notifcation-option values.
bgp—Enables the BGP state change notifications
config—Enables the configuration notifications
dlsw—Enables the DLSw notifications
entity—Enables the entity notifications
frame-relay—Enables the frame-relay notifications
hsrp—Enables the HSRP notifications
isdn—Enables the ISDN traps. When you enter isdn, you can specify a notification-option value.
rsvp—Enables the RSVP flow change notifications
rtr—Enables the Response Time Reporter notifications
snmp—Enables the SNMP notifications. When you enter snmp, you can specify additional
notifcation-option values
syslog—Enables error message notifications (Cisco Syslog MIB)
Valid values for the notification-option are as follows:
atm pvc [interval seconds] [fail-interval seconds]
The optional interval seconds specifies the minimum period between successive traps, in the
range from 1 to 3600. Generation of PVC traps is dampened by the notification interval in order
to prevent trap storms. No traps are sent until the interval lapses.
The optional fail-interval seconds specifies the minimum period for storing the failed time
stamp, in the range from 0 to 3600.
dlsw [circuit] [tconn]
The optional circuit enables SNMP DLSw circuit traps.
The optional tconn enables SNMP DLSw peer transport connection traps
isdn [call-information] | [layer2]
The optional call-information enables an SNMP ISDN call information notification for the
ISDN MIB subsystem.
The optional layer2 enables SNMP ISDN Layer 2 transition traps.
snmp [authentication] | [warmstart]
The optional authentication enables the authentication trap.
The optional warmstart enables the warmStart trap.
Use of the authentication keyword produces the same effect as not using the authentication
keyword. Both the snmp-server enable traps snmp and snmp-server enable traps snmp
authentication forms of this command will globally enable (or, if using the no form, disable) the
following SNMP traps:
authentication Failure
linkUp
linkDown
coldstart
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snmp-server enable traps
Examples This example shows how to send all traps to the host specified by the name myhost.cisco.com, using the
community string defined as public:
Router(config)# snmp-server enable traps
Router(config)# snmp-server host myhost.cisco.com public
Related Commands Refer to Cisco IOS documentation for additional snmp-server enable traps commands.
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Chapter 2 Catalyst 6500 Series Switch MSFC Commands standby delay minimum reload
standby delay minimum reload
To configure the delay period before the initialization of HSRP groups, use the standby delay minimum
reload command. Use the no form of this command to disable the delay period.
standby delay minimum [min-delay] reload [reload-delay]
no standby delay minimum [min-delay] reload [reload-delay]
Syntax Description
Defaults The defaults are as follows:
min-delay is 1 second
reload-delay is 5 seconds
Command Modes Interface configuration
Command History
Usage Guidelines The minimum delay period applies to all subsequent interface events.
The delay period applies only to the first interface-up event after the router has reloaded.
If the active router fails or is removed from the network, the standby router automatically becomes the
new active router. If the former active router comes back online, you can control whether it takes over
as the active router by using the standby preempt command.
However, even if the standby preempt command is not configured, the former active router resumes the
active role after it reloads and comes back online. Use the standby delay minimum reload command
to set a delay period for HSRP group initialization. This command allows time for the packets to get
through before the router resumes the active role.
We recommend that you use the standby delay minimum reload command if the standby timers
command is configured in milliseconds or if HSRP is configured on a VLAN interface of a switch.
In most configurations, the default values provide sufficient time for the packets to get through and it is
not necessary to configure longer delay values.
The delay is canceled if an HSRP packet is received on an interface.
min-delay (Optional) Minimum time, in seconds, to delay HSRP group initialization after
an interface comes up; valid values are from 0 to 10000.
reload-delay (Optional) Time, in seconds, to delay after the router has reloaded; valid values
are from 0 to 10000.
Release Modification
12.1(13)E Support for this command was introduced on the MSFC.
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standby delay minimum reload
Examples This example shows how to set the minimum delay period to 30 seconds and the delay period after the
first reload to 120 seconds:
Router(config-if) # standby delay minimum 30 reload 120
Router(config-if) #
Related Commands show standby delay
standby delay minimum reload (refer to Cisco IOS documentation)
standby preempt (refer to Cisco IOS documentation)
standby timers (refer to Cisco IOS documentation)
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standby ip
To enable HSRP and set the virtual IP address, use the standby ip command. Use the no form of this
command to disable HSRP.
standby [group-number] ip [ip-addr [secondary]]
no standby [group-number] ip [ip-addr]
Syntax Description
Defaults The defaults are as follows:
HSRP is disabled
group-number—If you do not specify a group-number, group 0 is used
priority10
delay0
hellotime3 seconds
holdtime10 seconds
Command Modes Interface configuration
Command History
Usage Guidelines The standby ip command activates HSRP on the configured interface. If an IP address is specified, that
address is used as the designated address for the Hot Standby group. If no IP address is specified, the
designated address is learned through the standby function. For HSRP to elect a designated router, at
least one router on the cable must have been configured with, or have learned, the designated address.
Configuring the designated address on the active router always overrides a designated address that is
currently in use.
When the standby ip command is enabled on an interface, the handling of proxy ARP requests is
changed (unless proxy ARP was disabled). If the Hot Standby state of the interface is active, proxy ARP
requests are answered using the MAC address of the Hot Standby group. If the interface is in a different
state, proxy ARP responses are suppressed.
When group number 0 is used, no group number is written to NVRAM, providing backward
compatibility.
group-number (Optional) Group number on the interface for which HSRP is being activated;
valid values are from 0 to 255.
ip-addr (Optional) IP address of the Hot Standby router interface.
secondary (Optional) Specifies a secondary virtual IP address.
Release Modification
12.1E Support for this command was introduced on the MSFC.
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standby ip
To assist in troubleshooting, configure the group-number to match the VLAN number.
Increase the priority of at least one interface in the HSRP group. The interface with the highest priority
becomes active for that HSRP group.
All interfaces in the HSRP group should use the same timer values.
All interfaces in the HSRP group should use the same authentication string.
The alt keyword is used to specify an alternate configuration and is used in the following:
[no] standby [group-number] ip [ip-address [secondary]] alt [no] standby [group-number] ip
[ip-address [secondary]]
[no] standby [group-number] priority priority [preempt [delay delay]] alt [no] standby
[group-number] priority priority [preempt [delay delay]]
For additional information, see the “alt Keyword Usage” section on page 2-9.
Examples This example shows how to enable HSRP for group 1 on an interface. The IP address used by the Hot
Standby group will be learned using HSRP.
Router(config-if) # standby 1 ip
Router(config-if) #
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Chapter 2 Catalyst 6500 Series Switch MSFC Commands standby track
standby track
To configure an interface so that the Hot Standby priority changes are based on the availability of other
interfaces, use the standby track command. Use the no standby group-number track command to
delete all tracking configuration for a group.
standby [group-number] track {interface-type interface-number | designated-router}
[priority-decrement]
no standby group-number track
Syntax Description
Defaults The defaults are as follows:
The group is 0.
The priority-decrement is 10.
The designated-router option is disabled.
Command Modes Interface configuration
Command History
Usage Guidelines This command is supported on systems configured with an MSFC2 only. This command is not supported
on systems configured with an MSFC1.
Prior to entering the designated-router option, you must ensure that the new designated router has a
higher HSRP priority than the current designated router to take over.
When a tracked interface goes down, the Hot Standby priority decreases by the number specified by the
priority-decrement argument. If an interface is not tracked, its state changes do not affect the Hot
Standby priority. For each interface configured for Hot Standby, you can configure a separate list of
interfaces to be tracked.
group (Optional) Specifies the group number on the interface to which the tracking
applies; valid values are from 0 to 255.
interface-type
interface-number Specifies the interface type and number to be tracked.
designated-router Specifies that if the designated router becomes nondesignated, the active HSRP
router becomes the designated router.
priority-decrement (Optional) Specifies the amount that the Hot Standby priority for the router is
decremented (or incremented) when the interface goes down (or comes
back up); valid values are from 1 to 255.
Release Modification
12.1(14)E This command was introduced on the MSFC2.
12.1(13.05)E0 This command was changed to include the designated-router option.
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standby track
When multiple tracked interfaces are down, the decrements are cumulative whether they are configured
with priority-decrement values or not.
A tracked interface is considered down if the IP address is disabled on that interface.
You must enter the group-number when using the no form of this command.
If you configure HSRP to track an interface, and that interface is physically removed as in the case of an
OIR operation, then HSRP regards the interface as always down. You cannot remove the HSRP interface
tracking configuration. To prevent this situation, use the no standby track interface-type
interface-number command before you physically remove the interface.
When you enter a group-number 0, no group number is written to NVRAM, providing backward
compatibility.
Examples This example shows how to enable HSRP tracking for group 1 on an interface:
Router(config-if)# standby 1 track Ethernet0/2
Router(config-if)#
This example shows how to specify that if the designated router becomes nondesignated, the active
HSRP router becomes the designated router:
Router(config-if)# standby 1 track designated-router 15
Router(config-if)#
Related Commands show standby (refer to the Catalyst 6500 Series Switch Cisco IOS Command Reference)
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upgrade rom-monitor
To set the execution preference on a ROMMON, use the upgrade rom-monitor command.
upgrade rom-monitor {{rp | sp} {invalidate | preference} {region1 | region2}
upgrade rom-monitor {{rp | sp} file {device:filename}
Syntax Description
Defaults This command has no default settings.
Command Modes Privileged EXEC
Command History
Usage Guidelines
Caution If you enter the upgrade rom-monitor command with no parameters, service may be
interrupted.
Caution If you enter the upgrade rom-monitor command from a Telnet session instead of a console connection,
service may be interrupted.
rp Specifies the route processor.
sp Specifies the Catalyst 6500 series switch processor.
invalidate Invalidates the MAGIC and sequence code of the selected region.
preference Sets the execution preference on a ROMMON to the selected region.
region1 Selects the ROMMON in region 1.
region2 Selects the ROMMON in region 2.
file Specifies the name of the Flash file.
device:filename Name of the device and filename of the Flash file.
Release Modification
12.1E This command was introduced on the MSFC.
12.1(3a)E1 Initial support of the MSFC2 on the Supervisor Engine 2.
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upgrade rom-monitor
Note Releases 12.1(8a)EX and earlier do not support the field-upgradable ROMMON feature on a Supervisor
Engine 2. If you revert to a release prior to 12.1(8a)EX on a Supervisor Engine 2, the previously
upgraded ROMMON will be invalidated and returned to run the ROMMON stored on the PROM. If you
wish to use releases prior to 12.1(8a)EX on a Supervisor Engine 2, but upgrade your ROMMON, you
must physically replace a ROMMON PROM with a ROMMON PROM that is programmed with the new
ROMMON image. Contact Cisco TAC for additional information.
The slot num is required for this command to function properly.
The sp keyword is not supported.
You can enter the upgrade rom-monitor rp {invalidate | preference} {region1 | region2} command to
manually set the execution preference on a ROMMON in region1 or region2. This command is entered in
EXEC privileged mode only.
You can enter the upgrade rom-monitor rp file {device:filename} command to program a new
ROMMON into a FLASH (region1 or region2) region.
Examples This example shows how to program the new ROMMON into the MSFC2 ROMMON flash file:
Router# upgrade rom-monitor rp file bootflash:FUR_173.srec
ROMMON image upgrade in progress
Erasing flash
Programming flash
Verifying new image
ROMMON image upgrade complete, MSFC2 must be reloaded.
Related Commands show msfc2 rom-monitor
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APPENDIX
A
Acronyms
Table A-1 defines the acronyms used in this publication.
Table A-1 List of Acronyms
Acronym Expansion
AAL ATM adaptation layer
ACE access control entry
ACL access control list
ACNS Application and Content Networking System
AFI authority and format identifier
Agport aggregation port
ALPS Airline Protocol Support
AMP Active Monitor Present
APaRT Automated Packet Recognition and Translation
ARP Address Resolution Protocol
ATA Analog Telephone Adaptor
ATM Asynchronous Transfer Mode
AV attribute value
BDD binary decision diagrams
BECN backward explicit congestion notification
BGP Border Gateway Protocol
BPDU bridge protocol data unit
BRF bridge relay function
BSC Bisync
BSTUN Block Serial Tunnel
BUS broadcast and unknown server
BVI bridge-group virtual interface
CAM content-addressable memory
CAR committed access rate
CBAC context based access control
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Appendix A Acronyms
CCA circuit card assembly
CDP Cisco Discovery Protocol
CEF Cisco Express Forwarding
CHAP Challenge Handshake Authentication Protocol
CIR committed information rate
CIST Common and Internal Spanning Tree
CLI command-line interface
CLNS Connection-Less Network Service
CMNS Connection-Mode Network Service
COPS Common Open Policy Server
COPS-DS Common Open Policy Server Differentiated Services
CoS class of service
CPLD Complex Programmable Logic Device
CRC cyclic redundancy check
CRF concentrator relay function
CST Common Spanning Tree
CUDD University of Colorado Decision Diagram
DCC Data Country Code
dCEF distributed Cisco Express Forwarding
DDR dial-on-demand routing
DE discard eligibility
DEC Digital Equipment Corporation
DFC Distributed Forwarding Card
DFI Domain-Specific Part Format Identifier
DFP Dynamic Feedback Protocol
DISL Dynamic Inter-Switch Link
DLC Data Link Control
DLSw Data Link Switching
DMP data movement processor
DNS Domain Name System
DoD Department of Defense
DOS denial of service
dot1q 802.1Q
dot1x 802.1x
DRAM dynamic RAM
DRiP Dual Ring Protocol
Table A-1 List of Acronyms (continued)
Acronym Expansion
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Appendix A Acronyms
DSAP destination service access point
DSCP differentiated services code point
DSPU downstream SNA Physical Units
DSTS Destination-Specific Traffic-Shaping
DTP Dynamic Trunking Protocol
DTR data terminal ready
DXI data exchange interface
EAP Extensible Authentication Protocol
EARL Enhanced Address Recognition Logic
EEPROM electrically erasable programmable read-only memory
EHSA enhanced high system availability
EIA Electronic Industries Association
ELAN Emulated Local Area Network
EOBC Ethernet out-of-band channel
EOF end of file
EoMPLS Ethernet over Multiprotocol Label Switching
ESI end-system identifier
FAT File Allocation Table
FECN forward explicit congestion notification
FIB Forwarding Information Base
FM feature manager
FRU field replaceable unit
fsck file system consistency check
FSM feasible successor metrics
FSU fast software upgrade
GARP General Attribute Registration Protocol
GBIC Gigabit Interface Converter
GMRP GARP Multicast Registration Protocol
GVRP GARP VLAN Registration Protocol
HSRP Hot Standby Routing Protocol
ICC Inter-card Communication or interface controller card
ICD International Code Designator
ICMP Internet Control Message Protocol
IDB interface descriptor block
IDP initial domain part or Internet Datagram Protocol
IDSM Intrusion Detection System Module
Table A-1 List of Acronyms (continued)
Acronym Expansion
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Appendix A Acronyms
IFS IOS File System
IGMP Internet Group Management Protocol
IGRP Interior Gateway Routing Protocol
ILMI Integrated Local Management Interface
IP Internet Protocol
IPC interprocessor communication
IPX Internetwork Packet Exchange
IS-IS Intermediate System-to-Intermediate System Intradomain Routing
Protocol
ISL Inter-Switch Link
ISL VLANs Inter-Switch Link VLANs
ISO International Organization of Standardization
ISR Integrated SONET router
LACP Link Aggregation Control Protocol
LACPDU Link Aggregation Control Protocol data unit
LAN local area network
LANE LAN Emulation
LAPB Link Access Procedure, Balanced
LCP Link Control Protocol
LDA Local Director Acceleration
LEC LAN Emulation Client
LECS LAN Emulation Configuration Server
LEM link error monitor
LER link error rate
LES LAN Emulation Server
LLC Logical Link Control
LTL Local Target Logic
MAC Media Access Control
MD5 message digest 5
MFD multicast fast drop
MIB Management Information Base
MII media-independent interface
MLS Multilayer Switching
MLSE maintenance loop signaling entity
MOP Maintenance Operation Protocol
MOTD message-of-the-day
Table A-1 List of Acronyms (continued)
Acronym Expansion
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Appendix A Acronyms
MLSE maintenance loops signaling entity
MPLS Multiprotocol Label Switching
MRM multicast routing monitor
MSDP Multicast Source Discovery Protocol
MSFC Multilayer Switching Feature Card
MSM Multilayer Switch Module
MST Multiple Spanning Tree (802.1s)
MTU maximum transmission unit
MVAP multiple VLAN access port
NAM Network Analysis Module
NBP Name Binding Protocol
NCIA Native Client Interface Architecture
NDE NetFlow Data Export
NET network entity title
NetBIOS Network Basic Input/Output System
NFFC NetFlow Feature Card
NMP Network Management Processor
NSAP network service access point
NTP Network Time Protocol
NVGEN nonvolatile generation
NVRAM nonvolatile RAM
OAM Operation, Administration, and Maintenance
ODM order dependent merge
OSI Open System Interconnection
OSM Optical Services Module
OSPF open shortest path first
PAE port access entity
PAgP Port Aggregation Protocol
PBD packet buffer daughterboard
PC Personal Computer (formerly PCMCIA)
PCM pulse code modulation
PCR peak cell rate
PDP policy decision point
PDU protocol data unit
PEP policy enforcement point
PFC Policy Feature Card
Table A-1 List of Acronyms (continued)
Acronym Expansion
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Appendix A Acronyms
PGM Pragmatic General Multicast
PHY physical sublayer
PIB policy information base
PIM protocol independent multicast
PPP Point-to-Point Protocol
PRID Policy Rule Identifiers
PVLANs private VLANs
PVST+ Per-VLAN Spanning Tree+
QDM QoS device manager
QM QoS manager
QM-SP SP QoS manager
QoS quality of service
Q-in-Q 802.1Q in 802.1Q
RACL router interface access control list
RADIUS Remote Access Dial-In User Service
RAM random-access memory
RCP Remote Copy Protocol
RF Redundancy Facility
RGMP Router-Ports Group Management Protocol
RIB routing information base
RIF Routing Information Field
RMON remote network monitor
ROM read-only memory
ROMMON ROM monitor
RP route processor or rendezvous point
RPC remote procedure call
RPF reverse path forwarding
RPR Route Processor Redundancy
RPR+ Route Processor Redundancy+
RSPAN remote SPAN
RST reset
RSTP Rapid Spanning Tree Protocol
RSTP+ Rapid Spanning Tree Protocol plus
RSVP ReSerVation Protocol
SAID Security Association Identifier
SAP service access point
Table A-1 List of Acronyms (continued)
Acronym Expansion
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SCM service connection manager
SCP Switch-Module Configuration Protocol
SDLC Synchronous Data Link Control
SGBP Stack Group Bidding Protocol
SIMM single in-line memory module
SLB server load balancing
SLCP Supervisor Line-Card Processor
SLIP Serial Line Internet Protocol
SMDS Software Management and Delivery Systems
SMF software MAC filter
SMP Standby Monitor Present
SMRP Simple Multicast Routing Protocol
SMT Station Management
SNAP Subnetwork Access Protocol
SNMP Simple Network Management Protocol
SPAN Switched Port Analyzer
SREC S-Record format, Motorola defined format for ROM contents
SSTP Cisco Shared Spanning Tree
STP Spanning Tree Protocol
SVC switched virtual circuit
SVI switched virtual interface
TACACS+ Terminal Access Controller Access Control System Plus
TARP Target Identifier Address Resolution Protocol
TCAM Ternary Content Addressable Memory
TCL table contention level
TCP/IP Transmission Control Protocol/Internet Protocol
TFTP Trivial File Transfer Protocol
TIA Telecommunications Industry Association
TopN Utility that allows the user to analyze port traffic by reports
TOS type of service
TLV type-length-value
TTL Time To Live
TVX valid transmission
UDLD UniDirectional Link Detection Protocol
UDP User Datagram Protocol
UNI User-Network Interface
Table A-1 List of Acronyms (continued)
Acronym Expansion
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Appendix A Acronyms
UTC Coordinated Universal Time
VACL VLAN access control list
VCC virtual channel circuit
VCI virtual circuit identifier
VCR Virtual Configuration Register
VINES Virtual Network System
VLAN virtual LAN
VMPS VLAN Membership Policy Server
VPN virtual private network
VRF VPN routing and forwarding
VTP VLAN Trunking Protocol
VVID voice VLAN ID
WAN wide area network
WCCP Web Cache Coprocessor Protocol
WFQ weighted fair queueing
WRED weighted random early detection
WRR weighted round-robin
XNS Xerox Network System
Table A-1 List of Acronyms (continued)
Acronym Expansion
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APPENDIX
B
Acknowledgments for Open-Source Software
The Cisco IOS software on the Catalyst 6500 series switches software pipe command uses Henry
Spencer’s regular expression library (regex).
Henry Spencer’s regular expression library (regex). Copyright 1992, 1993, 1994, 1997 Henry Spencer.
All rights reserved. This software is not subject to any license of the American Telephone and Telegraph
Company or of the Regents of the University of California.
Permission is granted to anyone to use this software for any purpose on any computer system, and to
alter it and redistribute it, subject to the following restrictions:
1. The author is not responsible for the consequences of use of this software, no matter how awful, even
if they arise from flaws in it.
2. The origin of this software must not be misrepresented, either by explicit claim or by omission.
Since few users ever read sources, credits must appear in the documentation.
3. Altered versions must be plainly marked as such, and must not be misrepresented as being the
original software. Since few users ever read sources, credits must appear in the documentation.
4. This notice may not be removed or altered.
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Appendix B Acknowledgments for Open-Source Software
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INDEX
Symbols
?
command completion 1-14
listing available commands 1-14
? command 1-1
Numerics
802.3ad
See LACP
A
abbreviating commands 1-13
context-sensitive help 1-1
access control lists
See ACLs
accessing MSFC
console port 1-11
Telnet session 1-12
ACLs
merge
displaying current method 2-51
selecting
BDD-based merge method 2-28
ODM-based merge method 2-28
acronyms, list of A-1
addresses
primary IP 2-10
secondary IP 2-10
Address Resolution Protocol
See ARP
audience vii
authentication proxy
watch list
adding IP address 2-13
clearing entries 2-2
configuring 2-13
disabling 2-13
displaying 2-54
enabling 2-13
setting maximum login attempts 2-12
B
BDD
selecting ACL merge method 2-28
BGP
configuring maximum number of parallel routes 2-27
creating traffic classification 2-43
binary decision diagrams
See BDD
boot field
default values, changing 2-3
booting
system software, configuration register 2-3
boot register 2-3
Border Gateway Protocol
See BGP
bridge crb command 2-11
bridge group command 2-11
bridge protocol data unit
See BPDU
bundled images
displaying 2-59
Index
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C
CEF
disabling
rate-limiting 2-32
enabling
rate-limiting 2-32
setting
load balancing to include Layer 4 ports 2-31
rate-limiting 2-32
Cisco Express Forwarding
See CEF
CLI
backing out one level 1-13
configuration mode 1-12
console configuration mode 1-13
getting list of commands 1-14
global configuration mode 1-13
interface configuration mode (IOS) 1-13
levels of access 1-12
MSFC CLI
accessing 1-11
privileged EXEC mode 1-13
software basics 1-12
string search
alternation 1-8
anchoring 1-8
expressions 1-5
filtering 1-5
multiple-character patterns 1-7
multipliers 1-7
parentheses for recall 1-9
searching outputs 1-5
single-character patterns 1-6
using 1-5
command execution
multiple interfaces simultaneously 2-8
command-line interface
See CLI
commands, getting list of 1-14
committed information rate
See CIR
configuration, saving 1-11
configuration mode 1-12
consistency checker
configuring 2-37
disabling 2-37
enabling 2-37
console configuration mode 1-13
accessing 1-13
description 1-13
prompt 1-13
console port
accessing MSFC 1-11
D
default form of a command, using 1-5
Distributed Forwarding Card
See DFC
document conventions viii
document organization vii
dot1q
See 802.1Q tunneling
dot1x
See 802.1x
E
enable mode 1-13
encapsulation
IPX 2-23
Enhanced Address Recognition Logic
See EARL
Ethernet over Multiprotocol Label Switching
See EoMPLS
executing a command on multiple interfaces 2-8
Index
IN-3
Catalyst 6500 Series Switch MSFC Command Reference—Release 12.1(13)E
OL-3354-01
expressions
matching multiple expression occurrences 1-7
multiple-character patterns 1-7
multiplying pattern occurrence 1-9
single-character patterns 1-6
specifying alternative patterns 1-8
extended networks
IP, using secondary addresses 2-11
F
fast software upgrade
See FSU
FDDI
raw, IPX encapsulation 2-24
feature manager
displaying
CBAC-configured ACL lists and ports 2-47
dynamic reflexive entries 2-50
general information 2-44
inband packet count 2-46
per-interface information 2-48
per-VLAN information 2-52
summaries 2-51
field-replaceable unit
See FRU
file system consistency check
See fsck
fm
See feature manager
framing
IPX
See IPX, encapsulations
G
global configuration mode
accessing 1-13
description 1-13
prompt 1-13
H
hardware switching
configuring
consistency checker 2-37
disabling consistency checker 2-37
enabling consistency checker 2-37
Hot Standby Router Protocol
See HSRP
HSRP
configuring
initialization delay 2-71
tracking 2-75
disabling delay period 2-71
displaying delay period information 2-67
I
ICMP subnet masks 2-10
informs, enabling 2-68
inter-card communication
See ICC
interface configuration mode
accessing 1-13
description 1-13
prompt 1-13
interface-range macro
creating 2-5
interfaces
addresses, secondary 2-10
intermediate system-to-intermediate system
See IS-IS
Internet Control Message Protocol (ICMP)
See ICMP entries
Internet Group Management Protocol
Index
IN-4
Catalyst 6500 Series Switch MSFC Command Reference—Release 12.1(13)E OL-3354-01
See IGMP
Internetwork Packet Exchange
See IPX
interprocessor communication
See IPC
Inter-Switch Link VLANs
See ISL VLANs
IOS
bringing up interface 1-15
viewing and saving configuration 1-15
IP
addresses
primary 2-10
secondary 2-10
primary address, setting 2-10
secondary address, specifying 2-10
IP routing protocols
configuring maximum number of parallel routes 2-27
IP WCCP
disabling
packet redirection on an interface 2-21
enabling
packet redirection on an interface 2-21
IPX
encapsulations 2-23
ARPA 2-24
Ethernet_802.2 2-24
Ethernet_802.3 2-24
Ethernet_II 2-24
Ethernet_Snap 2-24
FDDI raw 2-24
HDLC 2-24
Novell-Ether 2-24
SAP 2-24
SNAP 2-24
framing
See IPX, encapsulations
multiple logical networks 2-24
routing
disabling 2-23
enabling 2-23
enabling on multiple networks (example) 2-26
secondary networks 2-23
subinterfaces 2-24
configuration (example) 2-26
J
jumbo frames
default value 2-40
restoring default value 2-40
setting maximum packet size 2-40
setting maximum transmission unit size 2-40
L
Layer 3 manager
displaying information 2-57
LCP
displaying bundled images 2-59
Link Aggregation Control Protocol
See LACP
M
macro
creating an interface-range macro 2-5
maintenance loop signaling entity
See MLSE
maximum transmission unit
See MTU
MCP
displaying bundles images 2-59
Media Access Control
See MAC address table
message digest 5
See MD5
Index
IN-5
Catalyst 6500 Series Switch MSFC Command Reference—Release 12.1(13)E
OL-3354-01
message-of-the-day
See MOTD
MLS
displaying
ACL merge method 2-51
MSFC command
permitting traffic 2-35
selecting ACL merge method 2-28
MLS IP
deleting
ACL threshold 2-34
global
disabling consistency checker 2-37
enabling consistency checker 2-37
installing
ACL threshold 2-36
interface
disabling internal router 2-30
enabling internal router 2-30
enabling non-RPF multicast fastdrop 2-39
more commands
filter 1-5
search 1-5
--More-- prompt
filter 1-5
search 1-5
MSFC
accessing from supervisor engine
console port 1-11
telnet session 1-12
configuration mode 1-14
programing new ROMMON into Flash 2-77
session command and 1-12
setting execution preference 2-77
supervisor engine console command 1-11
MSFC CLI
accessing 1-11
MSFC commands
interface range 2-8
mls ip inspect 2-35
set traffic-index 2-43
show microcode 2-59
show msfc2 rom-monitor 2-60
show scp 2-62
upgrade rom-monitor 2-77
MTU
default values 2-40
restoring default value 2-40
setting maximum packet size 2-40
setting maximum size 2-40
Multilayer Switch Feature Card
See MSFC
Multilayer Switching
See MLS
multiple-character patterns 1-7
Multiple Spanning Tree
See MST
Multiprotocol Label Switching
See MPLS
N
NetFlow Data Export
See NDE
network entity title
See NET
NLSP
subinterfaces 2-24
configuration (example) 2-26
no form of a command, using 1-5
non-RPF multicast fastdrop
enabling 2-39
O
ODM
selecting ACL merge method 2-28
Index
IN-6
Catalyst 6500 Series Switch MSFC Command Reference—Release 12.1(13)E OL-3354-01
order-dependent merge algorithm
See ODD
P
paging prompt
see --More-- prompt
parallel router 2-11
per-VLAN spanning tree
See PVST+
PIM
disabling triggered RPF check 2-16
setting back-off interval 2-16
setting check interval 2-18
setting triggered check interval 2-16
port range
executing 2-8
primary address
IP, setting 2-10
private VLANs
See PVLANs
privileged EXEC mode
accessing 1-13
description 1-13
prompt 1-13
Protocol Independent Multicast
See PIM
Q
Q-in-Q
802.1Q in 802.1Q
See 802.1Q tunneling
QoS Device Manager
See QDM
question command 1-1
R
Rapid Spanning Tree Protocol
See RSTP
Rapid Spanning Tree Protocol+
See RSTP+
redundancy
displaying
configuration information 2-61
related documentation vii
remote procedure call
See RPC
remote SPAN
See RSPAN
Reverse Path Forwarding
See RPF
ROMMON
displaying status 2-60
programing new ROMMON into Flash 2-77
setting execution preference 2-77
Route Processor Redundancy
See RPR
Route Processor Redundancy+
See RPR+
router, parallel 2-11
RPF
disabling exists-only checks 2-19
disabling triggered check 2-16
enabling exists-only checks 2-19
setting check interval 2-18
setting PIM back-off interval 2-16
setting triggered check interval 2-16
S
saving configuration changes 1-11
SCP
displaying information 2-62
secondary address, IP, using 2-10
Index
IN-7
Catalyst 6500 Series Switch MSFC Command Reference—Release 12.1(13)E
OL-3354-01
secondary networks, IPX 2-23
server load balancing
See SLB
session command, MSFC and 1-12
show commands
filter 1-5
search 1-5
single-character patterns
special characters
single-character patterns, table 1-6
SLB
displaying inband packet count 2-46
slot0
displaying information 2-64
SNMP
informs
disabling 2-68
enabling 2-68
traps
disabling 2-68
enabling 2-68
software configuration boot register 2-3
special characters
anchoring, table 1-8
SP QoS manager
See QM-SP
stub
enabling non-RPF multicast fastdrop 2-39
subinterfaces
IPX 2-24
NLSP 2-24
configuring (example) 2-26
subnet masks, using ICMP 2-10
supervisor engine image
displaying bundled images 2-59
Switch-Module Configuration Protocol
See SCP
T
Tab key
command completion 1-1
table contention level
See TCL
tables
characters with special meaning 1-6
default MTU values 2-40
show ip wccp web-cache detail command output
fields 2-56
special characters
multipliers, table 1-7
special characters used for anchoring 1-8
Telnet, accessing MSFC 1-12
Ternary Content Addressable Memory
See TCAM
tracking
configuring
designated router 2-75
traps, enabling 2-68
U
user EXEC mode
accessing 1-13
description 1-13
prompt 1-13
V
VLAN access control lists
See VACL
W
watch list
adding IP address 2-13
clearing entries 2-2
Index
IN-8
Catalyst 6500 Series Switch MSFC Command Reference—Release 12.1(13)E OL-3354-01
configuring 2-13
disabling 2-13
displaying 2-54
enabling 2-13
setting
maximum login attempts 2-12
WCCP
displaying
global statistics 2-55
inband packet count 2-46
Web Cache Coprocessor Protocol
See WCCP
weighted random early detection
See WRED
weighted round robin
See WRR

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