Dell Configuration Guide for the S4048–ON System 9.8(0.
Notes, cautions, and warnings NOTE: A NOTE indicates important information that helps you make better use of your computer. CAUTION: A CAUTION indicates either potential damage to hardware or loss of data and tells you how to avoid the problem. WARNING: A WARNING indicates a potential for property damage, personal injury, or death. Copyright © 2015 Dell Inc. All rights reserved. This product is protected by U.S. and international copyright and intellectual property laws.
Contents 1 About this Guide................................................................................................. 36 Audience..............................................................................................................................................36 Conventions........................................................................................................................................ 36 Related Documents...............................................................
Managing the File System...................................................................................................................60 Enabling Software Features on Devices Using a Command Option.................................................61 View Command History......................................................................................................................62 Upgrading Dell Networking OS.........................................................................................
Enabling the FTP Server................................................................................................................ 82 Configuring FTP Server Parameters............................................................................................. 82 Configuring FTP Client Parameters.............................................................................................. 83 Terminal Lines..................................................................................................
Related Configuration Tasks.......................................................................................................108 Important Points to Remember....................................................................................................... 109 Enabling 802.1X.................................................................................................................................109 Configuring Request Identity Re-Transmissions.................................................
Configure Layer 2 and Layer 3 ACLs.................................................................................................141 Assign an IP ACL to an Interface.......................................................................................................142 Applying an IP ACL............................................................................................................................ 142 Counting ACL Hits..........................................................................
Sessions and Peers............................................................................................................................ 193 Establish a Session.......................................................................................................................194 Route Reflectors................................................................................................................................194 BGP Attributes.............................................................
Changing the NEXT_HOP Attribute........................................................................................... 233 Changing the WEIGHT Attribute................................................................................................ 234 Enabling Multipath...................................................................................................................... 234 Filtering BGP Routes..............................................................................................
Enhanced Transmission Selection..............................................................................................275 Data Center Bridging Exchange Protocol (DCBx)..................................................................... 276 Data Center Bridging in a Traffic Flow....................................................................................... 277 Priority-Based Flow Control...........................................................................................................
Configuring DCBx.......................................................................................................................303 Verifying the DCB Configuration......................................................................................................307 QoS dot1p Traffic Classification and Queue Assignment............................................................... 319 Configuring the Dynamic Buffer Method..............................................................................
Enabling Deterministic ECMP Next Hop.................................................................................... 347 Configuring the Hash Algorithm Seed....................................................................................... 348 Link Bundle Monitoring.................................................................................................................... 348 Managing ECMP Group Paths............................................................................................
Creating the FRRP Group............................................................................................................375 Configuring the Control VLAN................................................................................................... 376 Configuring and Adding the Member VLANs............................................................................. 377 Setting the FRRP Timers.....................................................................................................
IGMP Version 2............................................................................................................................393 IGMP Version 3............................................................................................................................395 Configure IGMP................................................................................................................................ 398 Related Configuration Tasks......................................................
Configuring Layer 2 (Interface) Mode........................................................................................ 422 Configuring Layer 3 (Network) Mode.........................................................................................422 Configuring Layer 3 (Interface) Mode........................................................................................ 423 Egress Interface Selection (EIS)...............................................................................................
Important Points to Remember................................................................................................. 447 Enabling Link Dampening...........................................................................................................447 Link Bundle Monitoring.................................................................................................................... 448 Using Ethernet Pause Frames for Flow Control.............................................................
ARP Learning via ARP Request......................................................................................................... 472 Configuring ARP Retries................................................................................................................... 473 ICMP.................................................................................................................................................. 473 Configuration Tasks for ICMP................................................
Showing an IPv6 Interface..........................................................................................................496 Showing IPv6 Routes.................................................................................................................. 497 Showing the Running-Configuration for an Interface..............................................................498 Clearing IPv6 Routes.......................................................................................................
Change the IS-IS Metric Style in One Level Only...................................................................... 532 Leaks from One Level to Another.............................................................................................. 534 Sample Configurations..................................................................................................................... 535 28 Link Aggregation Control Protocol (LACP)...............................................
Debugging FEFD......................................................................................................................... 566 30 Link Layer Discovery Protocol (LLDP)........................................................568 802.1AB (LLDP) Overview.................................................................................................................568 Protocol Data Units.................................................................................................................
Enable MSDP..................................................................................................................................... 601 Manage the Source-Active Cache...................................................................................................602 Viewing the Source-Active Cache............................................................................................. 602 Limiting the Source-Active Cache.....................................................................
34 Multicast Features..........................................................................................636 Enabling IP Multicast........................................................................................................................ 636 Implementation Information............................................................................................................636 Multicast Policies...............................................................................................
Configuration Task List for Policy-based Routing.......................................................................... 700 PBR Exceptions (Permit)............................................................................................................. 700 Create a Redirect List..................................................................................................................700 Create a Rule for a Redirect-list...........................................................................
Configuring the Encapsulated Remote Port Mirroring.................................................................... 731 Changes to Default BehaviorConfiguration steps for ERPM .................................................... 731 ERPM Behavior on a typical Dell Networking OS ........................................................................... 733 Decapsulation of ERPM packets at the Destination IP/ Analyzer..............................................733 41 Private VLANs (PVLAN)..............
DSCP Color Maps..............................................................................................................................770 Creating a DSCP Color Map....................................................................................................... 770 Displaying DSCP Color Maps...................................................................................................... 771 Displaying a DSCP Color Policy Configuration ........................................................
Configuring RMON Collection Statistics....................................................................................810 Configuring the RMON Collection History................................................................................ 810 46 Rapid Spanning Tree Protocol (RSTP)........................................................812 Protocol Overview............................................................................................................................
Configuring When to Re-generate an SSH Key ........................................................................843 Configuring the SSH Server Key Exchange Algorithm.............................................................. 843 Configuring the HMAC Algorithm for the SSH Server...............................................................844 Configuring the SSH Server Cipher List..................................................................................... 844 Secure Shell Authentication......
50 sFlow.................................................................................................................881 Overview............................................................................................................................................881 Implementation Information............................................................................................................ 881 Important Points to Remember....................................................................
Additional MIB Objects to View Copy Statistics........................................................................ 906 Obtaining a Value for MIB Objects............................................................................................ 906 MIB Support to Display the Available Memory Size on Flash..........................................................907 Viewing the Available Flash Memory Size..................................................................................
Verify a Stack Configuration.............................................................................................................936 Displaying the Status of Stacking Ports...................................................................................... 937 Remove Units or Front End Ports from a Stack...............................................................................938 Removing a Unit from an S-Series Stack............................................................................
Disabling NTP on an Interface....................................................................................................962 Configuring a Source IP Address for NTP Packets.................................................................... 962 Configuring NTP Authentication................................................................................................962 Dell Networking OS Time and Date.................................................................................................
60 VLT Proxy Gateway........................................................................................993 Proxy Gateway in VLT Domains....................................................................................................... 993 Guidelines for Enabling the VLT Proxy Gateway....................................................................... 994 Enabling the VLT Proxy Gateway...............................................................................................
Association of VLTi as a Member of a PVLAN..........................................................................1039 MAC Synchronization for VLT Nodes in a PVLAN................................................................... 1040 PVLAN Operations When One VLT Peer is Down................................................................... 1040 PVLAN Operations When a VLT Peer is Restarted...................................................................
View VRF Instance Information................................................................................................ 1072 Assigning an OSPF Process to a VRF Instance.........................................................................1073 Configuring VRRP on a VRF Instance.......................................................................................1073 Configuring Management VRF.................................................................................................
Displaying Drop Counters.........................................................................................................1130 Dataplane Statistics....................................................................................................................1135 Display Stack Port Statistics.......................................................................................................1137 Display Stack Member Counters.......................................................................
1 About this Guide This guide describes the protocols and features the Dell Networking Operating System (OS) supports and provides configuration instructions and examples for implementing them. The S4048–ON platform is available with Dell Networking OS version 9.7.(0.1) and beyond.S4048–ON stacking is supported with Dell Networking OS version 9.7(0.1) and beyond. Though this guide contains information on protocols, it is not intended to be a complete reference.
Configuration Fundamentals 2 The Dell Networking Operating System (OS) command line interface (CLI) is a text-based interface you can use to configure interfaces and protocols. The CLI is largely the same for each platform except for some commands and command outputs. The CLI is structured in modes for security and management purposes. Different sets of commands are available in each mode, and you can limit user access to modes using privilege levels.
The Dell Networking OS CLI is divided into three major mode levels: • EXEC mode is the default mode and has a privilege level of 1, which is the most restricted level. Only a limited selection of commands is available, notably the show commands, which allow you to view system information. • EXEC Privilege mode has commands to view configurations, clear counters, manage configuration files, run diagnostics, and enable or disable debug operations. The privilege level is 15, which is unrestricted.
uBoot MAC ACCESS-LIST LINE AUXILLIARY CONSOLE VIRTUAL TERMINAL LLDP LLDP MANAGEMENT INTERFACE MONITOR SESSION MULTIPLE SPANNING TREE OPENFLOW INSTANCE PVST PORT-CHANNEL FAILOVER-GROUP PREFIX-LIST PRIORITY-GROUP PROTOCOL GVRP QOS POLICY RSTP ROUTE-MAP ROUTER BGP BGP ADDRESS-FAMILY ROUTER ISIS ISIS ADDRESS-FAMILY ROUTER OSPF ROUTER OSPFV3 ROUTER RIP SPANNING TREE TRACE-LIST VLT DOMAIN VRRP UPLINK STATE GROUP Navigating CLI Modes The Dell Networking OS prompt changes to indicate the CLI mode.
CLI Command Mode Prompt Access Command • From every mode except EXEC and EXEC Privilege, enter the exit command. NOTE: Access all of the following modes from CONFIGURATION mode.
CLI Command Mode Prompt Access Command Per-VLAN SPANNING TREE Plus Dell(config-pvst)# protocol spanning-tree pvst PREFIX-LIST Dell(conf-nprefixl)# ip prefix-list RAPID SPANNING TREE Dell(config-rstp)# protocol spanning-tree rstp REDIRECT Dell(conf-redirect-list)# ip redirect-list ROUTE-MAP Dell(config-route-map)# route-map ROUTER BGP Dell(conf-router_bgp)# router bgp BGP ADDRESS-FAMILY Dell(conf-router_bgp_af)# address-family {ipv4 multicast | ipv6 unicast} (for IPv4) (ROUTER BGP Mode)
CLI Command Mode Prompt Access Command LLDP MANAGEMENT INTERFACE Dell(conf-lldp-mgmtIf)# management-interface (LLDP Mode) LINE Dell(config-line-console) or Dell(config-line-vty) line console orline vty MONITOR SESSION Dell(conf-mon-sesssessionID)# monitor session OPENFLOW INSTANCE Dell(conf-of-instance-ofid)# openflow of-instance PORT-CHANNEL FAILOVERGROUP Dell(conf-po-failovergrp)# port-channel failovergroup PRIORITY GROUP Dell(conf-pg)# priority-group PROTOCOL GVRP Dell(config-gvrp)#
---1 72 2 3 4 5 6 Management online Member Member Member Member Member not not not not not S4048-ON S4048-ON 1-0(0-3932) present present present present present -- Power Supplies -Unit Bay Status Type FanStatus FanSpeed(rpm) --------------------------------------------------------------------------1 1 up AC absent 0 1 2 absent absent 0 -- Fan Status -Unit Bay TrayStatus Fan0 Speed Fan1 Speed ----------------------------------------------------------------------------------1 1 up up 0 up 0 1 2 up up
Obtaining Help Obtain a list of keywords and a brief functional description of those keywords at any CLI mode using the ? or help command: • To list the keywords available in the current mode, enter ? at the prompt or after a keyword. • Enter ? after a prompt lists all of the available keywords. The output of this command is the same for the help command.
Short-Cut Key Combination Action CNTL-E Moves the cursor to the end of the line. CNTL-F Moves the cursor forward one character. CNTL-I Completes a keyword. CNTL-K Deletes all characters from the cursor to the end of the command line. CNTL-L Re-enters the previous command. CNTL-N Return to more recent commands in the history buffer after recalling commands with CTRL-P or the UP arrow key. CNTL-P Recalls commands, beginning with the last command. CNTL-R Re-enters the previous command.
• show run | grep Ethernet ignore-case returns instances containing both “Ethernet” and “ethernet.” The grep command displays only the lines containing specified text. The following example shows this command used in combination with the show linecard all command. Dell(conf)#do show system brief | grep 0 0 not present NOTE: Dell Networking OS accepts a space or no space before and after the pipe. To filter a phrase with spaces, underscores, or ranges, enclose the phrase with double quotation marks.
Speed in RPM The display command displays additional configuration information. The no-more command displays the output all at once rather than one screen at a time. This is similar to the terminal length command except that the no-more option affects the output of the specified command only. The save command copies the output to a file for future reference. NOTE: You can filter a single command output multiple times. The save option must be the last option entered.
3 Getting Started This chapter describes how you start configuring your system. When you power up the chassis, the system performs a power-on self test (POST) during which the line card status light emitting diodes (LEDs) blink green. The system then loads the Dell Networking Operating System (OS). Boot messages scroll up the terminal window during this process. No user interaction is required if the boot process proceeds without interruption.
Accessing the Console Port To access the console port, follow these steps: For the console port pinout, refer to Accessing the RJ-45 Console Port with a DB-9 Adapter. 1. Install an RJ-45 copper cable into the console port.Use a rollover (crossover) cable to connect the S4810 console port to a terminal server. 2. Connect the other end of the cable to the DTE terminal server. 3.
Entering CLI commands Using an SSH Connection You can run CLI commands by entering any one of the following syntax to connect to a switch using the preconfigured user credentials using SSH: ssh username@hostname or echo | ssh admin@hostname The SSH server transmits the terminal commands to the CLI shell and the results are displayed on the screen non-interactively.
Default Configuration A version of Dell Networking OS is pre-loaded onto the chassis; however, the system is not configured when you power up for the first time (except for the default hostname, which is Dell). You must configure the system using the CLI. Configuring a Host Name The host name appears in the prompt. The default host name is Dell. • Host names must start with a letter and end with a letter or digit. • Characters within the string can be letters, digits, and hyphens.
ip address ip-address/mask 3. • ip-address: an address in dotted-decimal format (A.B.C.D). • mask: a subnet mask in /prefix-length format (/ xx). Enable the interface. INTERFACE mode no shutdown Configure a Management Route Define a path from the system to the network from which you are accessing the system remotely. Management routes are separate from IP routes and are only used to manage the system through the management port. To configure a management route, use the following command.
To configure an enable password, use the following command. • Create a password to access EXEC Privilege mode. CONFIGURATION mode enable [password | secret] [level level] [encryption-type] password – level: is the privilege level, is 15 by default, and is not required – encryption-type: specifies how you are inputting the password, is 0 by default, and is not required. * 0 is for inputting the password in clear text. * 7 is for inputting a password that is already encrypted using a DES hash.
• You may not copy a file from one location to the same location. • When copying to a server, you can only use a hostname if a domain name server (DNS) server is configured. Example of Copying a File to an FTP Server Dell#copy flash://Dell-EF-8.2.1.0.bin ftp://myusername:mypassword@10.10.10.10/ /Dell/Dell-EF-8.2.1.
Important Points to Remember • You cannot copy a file from one remote system to another. • You cannot copy a file from one location to the same location. • When copying to a server, you can only use a hostname if a domain name server (DNS) server is configured. Example of Copying a File to current File System Dell#copy tftp://10.16.127.
Save the Running-Configuration The running-configuration contains the current system configuration. Dell Networking recommends coping your running-configuration to the startup-configuration. The commands in this section follow the same format as those commands in the Copy Files to and from the System section but use the filenames startup-configuration and running-configuration. These commands assume that current directory is the internal flash, which is the system default.
Example of the dir Command The output of the dir command also shows the read/write privileges, size (in bytes), and date of modification for each file.
Compressing Configuration Files The functionality to optimize and reduce the sizes of the configuration files is supported on the device. You can compress the running configuration by grouping all the VLANs and the physical interfaces with the same property. Support to store the operating configuration to the startup config in the compressed mode and to perform an image downgrade without any configuration loss are provided. You can create groups of VLANs using the interface group command.
interface TenGigabitEthernet 1/2 no ip address shutdown ! interface TenGigabitEthernet 1/3 no ip address shutdown ! interface TenGigabitEthernet 1/4 no ip address shutdown ! interface TenGigabitEthernet 1/10 no ip address shutdown ! interface TenGigabitEthernet 1/34 ip address 2.1.1.1/16 shutdown ! interface Vlan 2 no ip address no shutdown ! Interface group TenGigabitEthernet 1/2 – 4 , TenGigabitEthernet 1/10 no ip address shutdown ! interface TenGigabitEthernet 1/34 ip address 2.1.1.
tagged te 1/1 no ip address shutdown ! interface Vlan 5 tagged te 1/1 no ip address shutdown ! interface Vlan 100 no ip address no shutdown ! interface Vlan 1000 ip address 1.1.1.1/16 no shutdown Uncompressed config size – 52 lines write memory compressed The write memory compressed CLI will write the operating configuration to the startup-config file in the compressed mode. In stacking scenario, it will also take care of syncing it to all the standby and member units.
To view file system information, use the following command. • View information about each file system. EXEC Privilege mode show file-systems The output of the show file-systems command in the following example shows the total capacity, amount of free memory, file structure, media type, read/write privileges for each storage device in use. Dell#show file-systems Size(b) Free(b) Feature Type Flags 520962048 213778432 dosFs2.0 USERFLASH 127772672 21936128 dosFs2.
Based on whether VRF feature is identified as supported in the Feature Configuration file, configuration command feature vrf becomes available for usage. This command will be stored in running-configuration and will precede all other VRF-related configurations. NOTE: The MXL and Z9000 platforms currently do not support VRF. These platforms support only the management and default VRFs, which are available by default. As a result, the feature vrf command is not available for these platforms.
The MD5 or SHA256 hash provides a method of validating that you have downloaded the original software. Calculating the hash on the local image file, and comparing the result to the hash published for that file on iSupport, provides a high level of confidence that the local copy is exactly the same as the published software image. This validation procedure, and the verify {md5 | sha256} command to support it, can prevent the installation of corrupted or modified images.
SHA256 Dell# verify sha256 flash://FTOS-SE-9.5.0.0.bin e6328c06faf814e6899ceead219afbf9360e986d692988023b749e6b2093e933 SHA256 hash VERIFIED for FTOS-SE-9.5.0.0.bin Using HTTP for File Transfers Stating with Release 9.3(0.1), you can use HTTP to copy files or configuration details to a remote server. Use the copy source-file-url http://host[:port]/file-path command to transfer files to an external server.
Management 4 This chapter describes the different protocols or services used to manage the Dell Networking system. Configuring Privilege Levels Privilege levels restrict access to commands based on user or terminal line. There are 16 privilege levels, of which three are pre-defined. The default privilege level is 1. Level Description Level 0 Access to the system begins at EXEC mode, and EXEC mode commands are limited to enable, disable, and exit.
Moving a Command from EXEC Privilege Mode to EXEC Mode To move a command from EXEC Privilege to EXEC mode for a privilege level, use the privilege exec command from CONFIGURATION mode. In the command, specify the privilege level of the user or terminal line and specify all keywords in the command to which you want to allow access. Allowing Access to CONFIGURATION Mode Commands To allow access to CONFIGURATION mode, use the privilege exec level level configure command from CONFIGURATION mode.
• Allow access to INTERFACE, LINE, ROUTE-MAP, and/or ROUTER mode. Specify all the keywords in the command. CONFIGURATION mode • privilege configure level level {interface | line | route-map | router} {command-keyword ||...|| command-keyword} Allow access to a CONFIGURATION, INTERFACE, LINE, ROUTE-MAP, and/or ROUTER mode command. CONFIGURATION mode privilege {configure |interface | line | route-map | router} level level {command ||...
vlan VLAN interface Dell(conf)#interface tengigabitethernet 1/1 Dell(conf-if-te-1/1)#? end Exit from configuration mode exit Exit from interface configuration mode Dell(conf-if-te-1/1)#exit Dell(conf)#line ? aux Auxiliary line console Primary terminal line vty Virtual terminal Dell(conf)#line vty 0 Dell(config-line-vty)#? exit Exit from line configuration mode Dell(config-line-vty)# Dell(conf)#interface group ? fortyGigE FortyGigabit Ethernet interface gigabitethernet GigabitEthernet interface IEEE 802.
• no logging on Disable logging to the logging buffer. CONFIGURATION mode • no logging buffer Disable logging to terminal lines. CONFIGURATION mode • no logging monitor Disable console logging. CONFIGURATION mode no logging console Audit and Security Logs This section describes how to configure, display, and clear audit and security logs.
• Adding and deleting of users. • User access and configuration changes to the security and crypto parameters (not the key information but the crypto configuration) Important Points to Remember When you enabled RBAC and extended logging: • Only the system administrator user role can execute this command. • The system administrator and system security administrator user roles can view security events and system events.
Configuring Logging Format To display syslog messages in a RFC 3164 or RFC 5424 format, use the logging version [0 | 1} command in CONFIGURATION mode. By default, the system log version is set to 0.
To view any changes made, use the show running-config logging command in EXEC privilege mode. Setting Up a Secure Connection to a Syslog Server You can use reverse tunneling with the port forwarding to securely connect to a syslog server. Pre-requisites To configure a secure connection from the switch to the syslog server: 1. On the switch, enable the SSH server Dell(conf)#ip ssh server enable 2.
In the following example the syslog server IP address is 10.156.166.48 and the listening port is 5141. The switch IP address is 10.16.131.141 and the listening port is 5140 ssh -R 5140:10.156.166.48:5141 admin@10.16.131.141 -nNf 3. Configure logging to a local host. locahost is “127.0.0.1” or “::1”. If you do not, the system displays an error when you attempt to enable role-based only AAA authorization. Dell(conf)# logging localhost tcp port Dell(conf)#logging 127.0.0.
login statistics enable After enabling login statistics, the system stores the login activity details for the last 30 days. 2. (Optional) Configure the number of days for which the system stores the user login statistics. The range is from 1 to 30. CONFIGURATION mode login statistics time-period days Example of Configuring Login Activity Tracking The following example enables login activity tracking. The system stores the login activity details for the last 30 days.
Unsuccessful login attempt(s) in last 7 day(s): 0 -----------------------------------------------------------------Example of the show login statistics user user-id command The show login statistics user user-id command displays the successful and failed login details of a specific user in the last 30 days or the custom defined time period.
Enabling the System to Clear Existing Sessions To enable the system to clear existing login sessions, follow this procedure: • Use the following command. CONFIGURATION mode login concurrent-session clear-line enable Example of Enabling the System to Clear Existing Sessions The following example enables you to clear your existing login sessions.
Configuration Task List for System Log Management There are two configuration tasks for system log management: • Disable System Logging • Send System Messages to a Syslog Server Disabling System Logging By default, logging is enabled and log messages are sent to the logging buffer, all terminal lines, the console, and the syslog servers. To disable system logging, use the following commands. • Disable all logging except on the console.
– Add line on a 4.1 BSD UNIX system. local7.debugging /var/log/ftos.log – Add line on a 5.7 SunOS UNIX system. local7.debugging /var/adm/ftos.log In the previous lines, local7 is the logging facility level and debugging is the severity level. Changing System Logging Settings You can change the default settings of the system logging by changing the severity level and the storage location. The default is to log all messages up to debug level, that is, all system messages.
To view the logging configuration, use the show running-config logging command in privilege mode, as shown in the example for Configure a UNIX Logging Facility Level. Display the Logging Buffer and the Logging Configuration To display the current contents of the logging buffer and the logging settings for the system, use the show logging command in EXEC privilege mode. When RBAC is enabled, the security logs are filtered based on the user roles.
CONFIGURATION mode logging facility [facility-type] – auth (for authorization messages) – cron (for system scheduler messages) – daemon (for system daemons) – kern (for kernel messages) – local0 (for local use) – local1 (for local use) – local2 (for local use) – local3 (for local use) – local4 (for local use) – local5 (for local use) – local6 (for local use) – local7 (for local use) – lpr (for line printer system messages) – mail (for mail system messages) – news (for USENET news messages) – sys9 (system us
Synchronizing Log Messages You can configure Dell Networking OS to filter and consolidate the system messages for a specific line by synchronizing the message output. Only the messages with a severity at or below the set level appear. This feature works on the terminal and console connections available on the system. 1. Enter LINE mode.
To disable time stamping on syslog messages, use the no service timestamps [log | debug] command. File Transfer Services With Dell Networking OS, you can configure the system to transfer files over the network using the file transfer protocol (FTP). One FTP application is copying the system image files over an interface on to the system; however, FTP is not supported on virtual local area network (VLAN) interfaces.
• Specify the directory for users using FTP to reach the system. CONFIGURATION mode ftp-server topdir dir • The default is the internal flash directory. Specify a user name for all FTP users and configure either a plain text or encrypted password. CONFIGURATION mode ftp-server username username password [encryption-type] password Configure the following optional and required parameters: – username: enter a text string. – encryption-type: enter 0 for plain text or 7 for encrypted text.
Terminal Lines You can access the system remotely and restrict access to the system by creating user profiles. Terminal lines on the system provide different means of accessing the system. The console line (console) connects you through the console port in the route processor modules (RPMs). The virtual terminal lines (VTYs) connect you through Telnet to the system. The auxiliary line (aux) connects secondary devices such as modems.
ip access-list extended testdeny seq 10 deny ip 30.1.1.
CONFIGURATION mode login authentication {method-list-name | default} 3. If you used the line authentication method in the method list you applied to the terminal line, configure a password for the terminal line. LINE mode password Example of Terminal Line Authentication In the following example, VTY lines 0-2 use a single authentication method, line.
exec-timeout 0 0 Dell(config-line-console)# Using Telnet to get to Another Network Device To telnet to another device, use the following commands. NOTE: The device allows 120 Telnet sessions per minute, allowing the login and logout of 10 Telnet sessions, 12 times in a minute. If the system reaches this non-practical limit, the Telnet service is stopped for 10 minutes. You can use console and SSH service to access the system during downtime. • Telnet to the peer RPM.
other users are denied access. This means that you can exit to EXEC Privilege mode, and re-enter CONFIGURATION mode without having to set the lock again. • Set manual lock using the configure terminal lock command from CONFIGURATION mode. When you configure a manual lock, which is the default, you must enter this command each time you want to enter CONFIGURATION mode and deny access to others.
Important Points to Remember • When you restore all the units in a stack, these units are placed in standalone mode. • When you restore a single unit in a stack, only that unit is placed in standalone mode. No other units in the stack are affected. • When you restore the units in standalone mode, the units remain in standalone mode after the restoration. • After the restore is complete, the units power cycle immediately.
Important Points to Remember • The Chassis remains in boot prompt if none of the partitions contain valid images. • To enable TFTP boot after restoring factory default settings, you must stop the boot process in BLI. In case the system fails to reload the image from the partition, perform the following steps: 1. Power-cycle the chassis (pull the power cord and reinsert it). 2. Hit any key to abort the boot process. You enter uBoot immediately, the => prompt indicates success.
uBoot mode reset Management 91
5 802.1ag Ethernet operations, administration, and maintenance (OAM) are a set of tools used to install, monitor, troubleshoot, and manage Ethernet infrastructure deployments. Ethernet OAM consists of three main areas: • Service layer OAM — IEEE 802.1ag connectivity fault management (CFM) • Link layer OAM — IEEE 802.
In addition to providing end-to-end OAM in native Layer 2 Ethernet Service Provider/Metro networks, you can also use CFM to manage and troubleshoot any Layer 2 network including enterprise, datacenter, and cluster networks. Maintenance Domains Connectivity fault management (CFM) divides a network into hierarchical maintenance domains, as shown in the following illustration. A CFM maintenance domain is a management space on a network that a single management entity owns and operates.
Figure 3. Maintenance Points Maintenance End Points A maintenance end point (MEP) is a logical entity that marks the end point of a domain. There are two types of MEPs defined in 802.1ag for an 802.1 bridge: • Up-MEP — monitors the forwarding path internal to a bridge on the customer or provider edge. On Dell Networking systems, the internal forwarding path is effectively the switch fabric and forwarding engine. • Down-MEP — monitors the forwarding path external another bridge.
Implementation Information Because the S-Series has a single MAC address for all physical/LAG interfaces, only one MEP is allowed per MA (per VLAN or per MD level). Configuring the CFM To configure the CFM, follow these steps: 1. Configure the ecfmacl CAM region using the cam-acl command. 2. Enable Ethernet CFM. 3. Create a Maintenance Domain. 4. Create a Maintenance Association. 5. Create Maintenance Points. 6. Use CFM tools: a. Continuity Check Messages. b. Loopback Message and Response.
The range is from 0 to 7. 2. Display maintenance domain information.
• Up-MEP — monitors the forwarding path internal to a bridge on the customer or provider edge. On Dell Networking systems, the internal forwarding path is effectively the switch fabric and forwarding engine. • Down-MEP — monitors the forwarding path external another bridge. Configure Up- MEPs on ingress ports, ports that send traffic towards the bridge relay. Configure DownMEPs on egress ports, ports that send traffic away from the bridge relay. 1. Create an MEP.
0 service1 Your_MA 4 3333 MIP UP Te 1/5 Disabled 00:01:e8:0b:c6:36 Displaying the MP Databases CFM maintains two MP databases: • MEP Database (MEP-DB): Every MEP must maintain a database of all other MEPs in the MA that have announced their presence via CCM. • MIP Database (MIP-DB): Every MIP must maintain a database of all other MEPs in the MA that have announced their presence via CCM. To display the MEP and MIP databases, use the following commands. • Display the MEP Database.
Continuity Check Messages Continuity check messages (CCM) are periodic hellos. Continuity check messages: • discover MEPs and MIPs within a maintenance domain • detect loss of connectivity between MEPs • detect misconfiguration, such as VLAN ID mismatch between MEPs • to detect unauthorized MEPs in a maintenance domain CCMs are multicast Ethernet frames sent at regular intervals from each MEP.
Enabling CCM To enable CCM, use the following commands. 1. Enable CCM. ECFM DOMAIN mode no ccm disable The default is Disabled. 2. Configure the transmit interval (mandatory). The interval specified applies to all MEPs in the domain. ECFM DOMAIN mode ccm transmit-interval seconds The default is 10 seconds. Enabling Cross-Checking To enable cross-checking, use the following commands. 1. Enable cross-checking. ETHERNET CFM mode mep cross-check enable The default is Disabled. 2.
Sending Linktrace Messages and Responses Linktrace message and response (LTM, LTR), also called Layer 2 Traceroute, is an administratively sent multicast frames transmitted by MEPs to track, hop-by-hop, the path to another MEP or MIP within the maintenance domain. All MEPs and MIPs in the same domain respond to an LTM with a unicast LTR. Intermediate MIPs forward the LTM toward the target MEP. Figure 5.
• Set the amount of time a trace result is cached. ETHERNET CFM mode traceroute cache hold-time minutes The default is 100 minutes. • The range is from 10 to 65535 minutes. Set the size of the Link Trace Cache. ETHERNET CFM mode traceroute cache size entries The default is 100. • The range is from 1 to 4095 entries. Display the Link Trace Cache. EXEC Privilege mode • show ethernet cfm traceroute-cache Delete all Link Trace Cache entries.
Priority Defects Trap Message MAC Status defect %ECFM-5-ECFM_MAC_STATUS_ALARM: MAC Status Defect detected by MEP 1 in Domain provider at Level 4 VLAN 3000 Remote CCM defect %ECFM-5-ECFM_REMOTE_ALARM: Remote CCM Defect detected by MEP 3 in Domain customer1 at Level 7 VLAN 1000 RDI defect %ECFM-5-ECFM_RDI_ALARM: RDI Defect detected by MEP 3 in Domain customer1 at Level 7 VLAN 1000 Three values are given within the trap messages: MD Index, MA Index, and MPID.
Displaying Ethernet CFM Statistics To display Ethernet CFM statistics, use the following commands. • Display MEP CCM statistics. EXEC Privilege mode • show ethernet cfm statistics [domain {name | level} vlan-id vlan-id mpid mpid Display CFM statistics by port.
802.1X 6 802.1X is a method of port security. A device connected to a port that is enabled with 802.1X is disallowed from sending or receiving packets on the network until its identity can be verified (through a username and password, for example). This feature is named for its IEEE specification. 802.
Figure 7. EAP Frames Encapsulated in Ethernet and RADUIS The authentication process involves three devices: • The device attempting to access the network is the supplicant. The supplicant is not allowed to communicate on the network until the authenticator authorizes the port. It can only communicate with the authenticator in response to 802.1X requests. • The device with which the supplicant communicates is the authenticator. The authenticator is the gate keeper of the network.
3. The authenticator decapsulates the EAP response from the EAPOL frame, encapsulates it in a RADIUS Access-Request frame and forwards the frame to the authentication server. 4. The authentication server replies with an Access-Challenge frame. The Access-Challenge frame requests that the supplicant prove that it is who it claims to be, using a specified method (an EAPMethod). The challenge is translated and forwarded to the supplicant by the authenticator. 5.
EAP over RADIUS 802.1X uses RADIUS to shuttle EAP packets between the authenticator and the authentication server, as defined in RFC 3579. EAP messages are encapsulated in RADIUS packets as a type of attribute in Type, Length, Value (TLV) format. The Type value for EAP messages is 79. Figure 9. EAP Over RADIUS RADIUS Attributes for 802.1 Support Dell Networking systems include the following RADIUS attributes in all 802.
Important Points to Remember • Dell Networking OS supports 802.1X with EAP-MD5, EAP-OTP, EAP-TLS, EAP-TTLS, PEAPv0, PEAPv1, and MS-CHAPv2 with PEAP. • All platforms support only RADIUS as the authentication server. • If the primary RADIUS server becomes unresponsive, the authenticator begins using a secondary RADIUS server, if configured. • 802.1X is not supported on port-channels or port-channel members. Enabling 802.1X Enable 802.1X globally. Figure 10. 802.1X Enabled 1. Enable 802.1X globally.
dot1x authentication 2. Enter INTERFACE mode on an interface or a range of interfaces. INTERFACE mode interface [range] 3. Enable 802.1X on the supplicant interface only. INTERFACE mode dot1x authentication Examples of Verifying that 802.1X is Enabled Globally and on an Interface Verify that 802.1X is enabled globally and at the interface level using the show running-config | find dot1x command from EXEC Privilege mode. In the following example, the bold lines show that 802.1X is enabled.
Configuring Request Identity Re-Transmissions If the authenticator sends a Request Identity frame, but the supplicant does not respond, the authenticator waits 30 seconds and then re-transmits the frame. The amount of time that the authenticator waits before re-transmitting and the maximum number of times that the authenticator re-transmits are configurable.
Example of Configuring and Verifying Port Authentication The following example shows configuration information for a port for which the authenticator retransmits an EAP Request Identity frame: • after 90 seconds and a maximum of 10 times for an unresponsive supplicant • re-transmits an EAP Request Identity frame The bold lines show the new re-transmit interval, new quiet period, and new maximum re-transmissions.
Example of Placing a Port in Force-Authorized State and Viewing the Configuration The example shows configuration information for a port that has been force-authorized. The bold line shows the new port-control state. Dell(conf-if-Te-1/1)#dot1x port-control force-authorized Dell(conf-if-Te-1/1)#show dot1x interface TenGigabitEthernet 1/1 802.
The bold lines show that re-authentication is enabled and the new maximum and re-authentication time period. Dell(conf-if-Te-1/1)#dot1x reauthentication interval 7200 Dell(conf-if-Te-1/1)#dot1x reauth-max 10 Dell(conf-if-Te-1/1)#do show dot1x interface TenGigabitEthernet 1/1 802.
The bold lines show the new supplicant and server timeouts. Dell(conf-if-Te-1/1)#dot1x port-control force-authorized Dell(conf-if-Te-1/1)#do show dot1x interface TenGigabitEthernet 1/1 802.
Figure 11. Dynamic VLAN Assignment 1. Configure 8021.x globally (refer to Enabling 802.1X) along with relevant RADIUS server configurations (refer to the illustration inDynamic VLAN Assignment with Port Authentication). 2. Make the interface a switchport so that it can be assigned to a VLAN. 3. Create the VLAN to which the interface will be assigned. 4. Connect the supplicant to the port configured for 802.1X. 5.
to be authenticated, but still need access to the network. Also, some dumb-terminals, such as network printers, do not have 802.1X capability and therefore cannot authenticate themselves. To be able to connect such devices, they must be allowed access the network without compromising network security. The Guest VLAN 802.1X extension addresses this limitation with regard to non-802.1X capable devices and the Authentication-fail VLAN 802.1X extension addresses this limitation with regard to external users.
dot1x authentication dot1x guest-vlan 200 no shutdown Dell(conf-if-Te-2/1)# Dell(conf-if-Te-2/1)#dot1x auth-fail-vlan 100 max-attempts 5 Dell(conf-if-Te-2/1)#show config ! interface TenGigabitEthernet 2/1 switchport dot1x authentication dot1x guest-vlan 200 dot1x auth-fail-vlan 100 max-attempts 5 no shutdown Dell(conf-if-Te-2/1)# Example of Viewing Configured Authentication View your configuration using the show config command from INTERFACE mode, as shown in the example in Configuring a Guest VLAN or using
7 Access Control List (ACL) VLAN Groups and Content Addressable Memory (CAM) This chapter describes the access control list (ACL) virtual local area network (VLAN) group and content addressable memory (CAM) enhancements. Optimizing CAM Utilization During the Attachment of ACLs to VLANs To minimize the number of entries in CAM, enable and configure the ACL CAM feature. Use this feature when you apply ACLs to a VLAN (or a set of VLANs) and when you apply ACLs to a set of ports.
• The egress ACL is applied or removed from the group and the group contains VLAN members. • VLAN members are added or deleted from a VLAN, which itself is a group member. • A line card returns to the active state after going down and this line card contains a VLAN that is a member of an ACL group. • The ACL VLAN group is deleted and it contains VLAN members. The ACL manager does not notify the ACL agent in the following cases: • The ACL VLAN group is created.
space. Enable optimization using the optimized option in the ip access-group command. This option is not valid for VLAN and link aggregation group (LAG) interfaces. Configuring ACL VLAN Groups and Configuring FP Blocks for VLAN Parameters This section describes how to optimize CAM blocks by configuring ACL VLAN groups that you can attach to VLAN interfaces. It also describes how to configure FP blocks for different VLAN operations.
Group Name : HostGroup Egress IP Acl : Group5 Vlan Members : 1,1000 Dell# Configuring FP Blocks for VLAN Parameters To allocate the number of FP blocks for the various VLAN processes on the system, use the cam-aclvlan command. To reset the number of FP blocks to the default, use the no version of this command. By default, 0 groups are allocated for the ACL in VLAN contentaware processor (VCAP). ACL VLAN groups or CAM optimization is not enabled by default.
| | | | | | | | | | | | | | | 1 | | | | | --More-- 1 | | | | | | | | | | | | | | | | | | | | IN-L2 FIB IN-L3 ACL IN-L3 FIB IN-L3-SysFlow IN-L3-TrcList IN-L3-McastFib IN-L3-Qos IN-L3-PBR IN-V6 ACL IN-V6 FIB IN-V6-SysFlow IN-V6-McastFib OUT-L2 ACL OUT-L3 ACL OUT-V6 ACL IN-L2 ACL IN-L2 FIB IN-L3 ACL IN-L3 FIB IN-L3-SysFlow | | | | | | | | | | | | | | | | | | | | 32768 12288 262141 2878 1024 9215 8192 1024 0 0 0 0 1024 1024 0 320 32768 12288 262141 2878 | | | | | | | | | | | | | | | | | | | | 1132 2 14 4
| | | | IN-L3-Qos | IN-L3-PBR | OUT-L3 ACL | | | 8192 1024 16384 | | | 0 0 0 | | | 8192 1024 16384 Allocating FP Blocks for VLAN Processes The VLAN contentaware processor (VCAP) application is a pre-ingress CAP that modifies the VLAN settings before packets are forwarded. To support ACL CAM optimization, the CAM carving feature is enhanced. A total of four VCAP groups are present: two fixed groups and two dynamic groups.
Access Control Lists (ACLs) 8 This chapter describes access control lists (ACLs), prefix lists, and route-maps. At their simplest, access control lists (ACLs), prefix lists, and route-maps permit or deny traffic based on MAC and/or IP addresses. This chapter describes implementing IP ACLs, IP prefix lists and route-maps. For MAC ACLS, refer to Layer 2.
accommodate the new entries. Hot lock ACLs are enabled by default and support both standard and extended ACLs and on all platforms. NOTE: Hot lock ACLs are supported for Ingress ACLs only. CAM Usage The following section describes CAM allocation and CAM optimization. • User Configurable CAM Allocation • CAM Optimization User Configurable CAM Allocation Allocate space for IPV6 ACLs by using the cam-acl command in CONFIGURATION mode. The CAM space is allotted in filter processor (FP) blocks.
Implementing ACLs on Dell Networking OS You can assign one IP ACL per interface with Dell Networking OS. If you do not assign an IP ACL to an interface, it is not used by the software in any other capacity. The number of entries allowed per ACL is hardware-dependent. For detailed specification on entries allowed per ACL, refer to your line card documentation.
closer to 0) before rules with higher-order numbers so that packets are matched as you intended. By default, all ACL rules have an order of 255. Example of the order Keyword to Determine ACL Sequence Dell(conf)#ip access-list standard acl1 Dell(config-std-nacl)#permit 20.0.0.0/8 Dell(config-std-nacl)#exit Dell(conf)#ip access-list standard acl2 Dell(config-std-nacl)#permit 20.1.1.
To create a route map, use the following command. • Create a route map and assign it a unique name. The optional permit and deny keywords are the action of the route map. CONFIGURATION mode route-map map-name [permit | deny] [sequence-number] The default is permit. The optional seq keyword allows you to assign a sequence number to the route map instance. Configured Route Map Examples The default action is permit and the default sequence number starts at 10.
The following example shows a route map with multiple instances. The show config command displays only the configuration of the current route map instance. To view all instances of a specific route map, use the show route-map command.
Example of the match Command to Permit and Deny Routes Dell(conf)#route-map force permit 10 Dell(config-route-map)#match tag 1000 Dell(conf)#route-map force deny 20 Dell(config-route-map)#match tag 1000 Dell(conf)#route-map force deny 30 Dell(config-route-map)#match tag 1000 Configuring Match Routes To configure match criterion for a route map, use the following commands. • Match routes with the same AS-PATH numbers.
CONFIG-ROUTE-MAP mode • match ip route-source {access-list-name | prefix-list prefix-list-name} Match source routes specified in a prefix list (IPv6). CONFIG-ROUTE-MAP mode • match ipv6 route-source {access-list-name | prefix-list prefix-list-name} Match routes with a specific value. CONFIG-ROUTE-MAP mode • match metric metric-value Match BGP routes based on the ORIGIN attribute.
• set metric {+ | - | metric-value} Specify an OSPF or ISIS type for redistributed routes. CONFIG-ROUTE-MAP mode • set metric-type {external | internal | type-1 | type-2} Assign an IP address as the route’s next hop. CONFIG-ROUTE-MAP mode • set next-hop ip-address Assign an IPv6 address as the route’s next hop. CONFIG-ROUTE-MAP mode • set ipv6 next-hop ip-address Assign an ORIGIN attribute. CONFIG-ROUTE-MAP mode • set origin {egp | igp | incomplete} Specify a tag for the redistributed routes.
NOTE: When re-distributing routes using route-maps, you must create the route-map defined in the redistribute command under the routing protocol. If you do not create a route-map, NO routes are redistributed.
set as-path prepend 1 2 3 4 5 continue 30! IP Fragment Handling Dell Networking OS supports a configurable option to explicitly deny IP fragmented packets, particularly second and subsequent packets. It extends the existing ACL command syntax with the fragments keyword for all Layer 3 rules applicable to all Layer protocols (permit/deny ip/tcp/udp/icmp). • Both standard and extended ACLs support IP fragments.
If a packet’s L3 information matches the L3 information in the ACL line, the packet's FO is checked. • If a packet's FO > 0, the packet is permitted. • If a packet's FO = 0, the next ACL entry is processed. Deny ACL line with L3 information only, and the fragments keyword is present: If a packet's L3 information does match the L3 information in the ACL line, the packet's FO is checked. • If a packet's FO > 0, the packet is denied. • If a packet's FO = 0, the next ACL line is processed.
CONFIGURATION mode ip access-list standard access-listname 2. Configure a drop or forward filter. CONFIG-STD-NACL mode seq sequence-number {deny | permit} {source [mask] | any | host ip-address} [count [byte] [dscp] [order] [fragments] NOTE: When assigning sequence numbers to filters, keep in mind that you might need to insert a new filter. To prevent reconfiguring multiple filters, assign sequence numbers in multiples of five.
Configuring a Standard IP ACL Filter If you are creating a standard ACL with only one or two filters, you can let Dell Networking OS assign a sequence number based on the order in which the filters are configured. The software assigns filters in multiples of five. 1. Configure a standard IP ACL and assign it a unique name. CONFIGURATION mode ip access-list standard access-list-name 2. Configure a drop or forward IP ACL filter.
Configure an Extended IP ACL Extended IP ACLs filter on source and destination IP addresses, IP host addresses, TCP addresses, TCP host addresses, UDP addresses, and UDP host addresses. Because traffic passes through the filter in the order of the filter’s sequence, you can configure the extended IP ACL by first entering IP ACCESS LIST mode and then assigning a sequence number to the filter. Configuring Filters with a Sequence Number To configure filters with a sequence number, use the following commands.
CONFIG-EXT-NACL mode seq sequence-number {deny | permit} tcp {source mask | any | host ipaddress}} [count [byte]] [order] [fragments] Example of the seq Command When you create the filters with a specific sequence number, you can create the filters in any order and the filters are placed in the correct order. NOTE: When assigning sequence numbers to filters, you may have to insert a new filter. To prevent reconfiguring multiple filters, assign sequence numbers in multiples of five or another number.
(for example, the first filter was given the lowest sequence number). The show config command in IP ACCESS LIST mode displays the two filters with the sequence numbers 5 and 10. Example of Viewing Filter Sequence for a Specified Extended ACL Dell(config-ext-nacl)#deny tcp host 123.55.34.0 any Dell(config-ext-nacl)#permit udp 154.44.123.34 0.0.255.255 host 34.6.0.0 Dell(config-ext-nacl)#show config ! ip access-list extended nimule seq 5 deny tcp host 123.55.34.0 any seq 10 permit udp 154.44.0.0 0.0.255.
Assign an IP ACL to an Interface To pass traffic through a configured IP ACL, assign that ACL to a physical interface, a port channel interface, or a VLAN. The IP ACL is applied to all traffic entering a physical or port channel interface and the traffic is either forwarded or dropped depending on the criteria and actions specified in the ACL. The same ACL may be applied to different interfaces and that changes its functionality.
interface TenGigabitEthernet 1/1 ip address 10.2.1.100 255.255.255.0 ip access-group nimule in no shutdown Dell(conf-if)# To filter traffic on Telnet sessions, use only standard ACLs in the access-class command. Counting ACL Hits You can view the number of packets matching the ACL by using the count option when creating ACL entries. 1. Create an ACL that uses rules with the count option. Refer to Configure a Standard IP ACL Filter. 2. Apply the ACL as an inbound or outbound ACL on an interface. 3.
Dell(conf-if-te1/1/1)#show config ! tengogabitethernet 1/1/1 no ip address ip access-group abcd in no shutdown Dell(conf-if-te1/1/1)#end Dell#configure terminal Dell(conf)#ip access-list extended abcd Dell(config-ext-nacl)#permit tcp any any Dell(config-ext-nacl)#deny icmp any any Dell(config-ext-nacl)#permit 1.1.1.
Extended Ingress IP access list abcd on tengigabitethernet 0/0 seq 5 permit tcp any any seq 10 deny icmp any any seq 15 permit 1.1.1.
filter (if configured) is applied. When the route prefix matches a filter, Dell Networking OS drops or forwards the packet based on the filter’s designated action. If the route prefix does not match any of the filters in the prefix list, the route is dropped (that is, implicit deny). A route prefix is an IP address pattern that matches on bits within the IP address. The format of a route prefix is A.B.C.D/X where A.B.C.
ip prefix-list prefix-name 2. Create a prefix list with a sequence number and a deny or permit action. CONFIG-NPREFIXL mode seq sequence-number {deny | permit} ip-prefix [ge min-prefix-length] [le max-prefix-length] The optional parameters are: • ge min-prefix-length: the minimum prefix length to match (from 0 to 32). • le max-prefix-length: the maximum prefix length to match (from 0 to 32).
• ge min-prefix-length: is the minimum prefix length to be matched (0 to 32). • le max-prefix-length: is the maximum prefix length to be matched (0 to 32). Example of Creating a Filter with Dell Networking OS-Assigned Sequence Numbers The example shows a prefix list in which the sequence numbers were assigned by the software. The filters were assigned sequence numbers based on the order in which they were configured (for example, the first filter was given the lowest sequence number).
ip prefix-list filter_in: count: 3, range entries: 3, sequences: 5 - 10 ip prefix-list filter_ospf: count: 4, range entries: 1, sequences: 5 - 10 Dell> Applying a Prefix List for Route Redistribution To pass traffic through a configured prefix list, use the prefix list in a route redistribution command. Apply the prefix list to all traffic redistributed into the routing process. The traffic is either forwarded or dropped, depending on the criteria and actions specified in the prefix list.
• Apply a configured prefix list to incoming routes. You can specify which type of routes are affected. If you enter the name of a non-existent prefix list, all routes are forwarded. CONFIG-ROUTER-OSPF mode distribute-list prefix-list-name out [connected | rip | static] Example of Viewing Configured Prefix Lists (ROUTER OSPF mode) To view the configuration, use the show config command in ROUTER OSPF mode, or the show running-config ospf command in EXEC mode.
Resequencing an ACL or Prefix List Resequencing is available for IPv4 and IPv6 ACLs, prefix lists, and MAC ACLs. To resequence an ACL or prefix list, use the following commands. You must specify the list name, starting number, and increment when using these commands.
ip access-list extended test remark 4 XYZ remark 5 this remark corresponds to permit any host 1.1.1.1 seq 5 permit ip any host 1.1.1.1 remark 9 ABC remark 10 this remark corresponds to permit ip any host 1.1.1.2 seq 10 permit ip any host 1.1.1.2 seq 15 permit ip any host 1.1.1.3 seq 20 permit ip any host 1.1.1.4 Dell# end Dell# resequence access-list ipv4 test 2 2 Dell# show running-config acl ! ip access-list extended test remark 2 XYZ remark 4 this remark corresponds to permit any host 1.1.1.
When you enable ACL log messages, at times, depending on the volume of traffic, it is possible that a large number of logs might be generated that can impact the system performance and efficiency. To avoid an overload of ACL logs from being recorded, you can configure the rate-limiting functionality. Specify the interval or frequency at which ACL logs must be triggered and also the threshold or limit for the maximum number of logs to be generated.
• A separate set of match indices is preserved by the ACL logging application for the permit and deny actions. Depending on the action of an ACL entry, the corresponding match index is allocated from the particular set that is maintained for permit and deny actions. • A maximum of 125 ACL entries with permit action can be logged. A maximum of 126 ACL entries with deny action can be logged. • For virtual ACL entries, the same match rule number is reused.
seq sequence-number {deny | permit} {source [mask] | any | host ip-address} [log [interval minutes]] Flow-Based Monitoring Support for ACLs Flow-based monitoring is supported on the platform. Flow-based monitoring conserves bandwidth by monitoring only the specified traffic instead of all traffic on the interface. It is available for Layer 2 and Layer 3 ingress traffic. You can specify traffic using standard or extended access-lists.
The ACL agent module saves monitoring details in its local database and also in the CAM region to monitor packets that match the specified criterion. The ACL agent maintains data on the source port, the destination port, and the endpoint to which the packet must be forwarded when a match occurs with the ACL entry. If you configure the flow-based enable command and do not apply an ACL on the source port or the monitored port, both flow-based monitoring and port mirroring do not function.
Enabling Flow-Based Monitoring Flow-based monitoring is supported on the platform. Flow-based monitoring conserves bandwidth by monitoring only specified traffic instead of all traffic on the interface. This feature is particularly useful when looking for malicious traffic. It is available for Layer 2 and Layer 3 ingress and egress traffic. You can specify traffic using standard or extended access-lists. 1. Enable flow-based monitoring for a monitoring session. MONITOR SESSION mode flow-based enable 2.
-----0 A -----Te 1/1 ----------Te 1/2 --rx ---- --------Flow N/A -------N/ Configuring UDF ACL To configure a User Defined Field (UDF) ACL: 1. Enable the UDF ACL feature on a switch. CONFIGURATION mode feature udf-acl Dell(conf)#feature udf-acl 2. Change the default CAM allocation or reconfigure new CAM allocation settings and enable IPV4 UDF.
L2Acl : Ipv4Acl : Ipv6Acl : Ipv4Qos : L2Qos : L2PT : IpMacAcl : VmanQos : EcfmAcl : FcoeAcl : iscsiOptAcl : ipv4pbr : vrfv4Acl : Openflow : fedgovacl : nlbclusteracl: 1 block = 256 entries 2 2 0 2 1 0 0 0 2 4 0 0 0 0 0 0 1 8(UdfEnabled) 2 0 2 0 0 0 0 0 0 0 0 0 0 0 Dell# 4. Create a UDF packet format in the UDF TCAM table. CONFIGURATION mode udf-tcam name seq number Dell(conf)#udf-tcam ipnip seq 1 5. Configure a UDF ID to parse packet headers using the specified number of offset and required bytes.
udf-tcam ipnip seq 1 match l2ethertype ipv4 ipprotocol 4 vlantag any Dell(conf-udf-tcam)# 9. Create a UDF qualifier to assign values to UDF IDs. CONFIGURATION-UDF TCAM mode udf-qualifier-value name Dell(conf-udf-tcam)# udf-qualifier-value ipnip_val1 10. Assign a value to a UDF ID. CONFIGURATION-UDF-Qualifier-Value Profile mode udf-id 1-12 value mask Dell(conf-udf-tcam-qual-val)#udf-id 1 aa ff 11. Associate the UDF qualifier value with a UDF packet profile in an IP access list.
9 Bidirectional Forwarding Detection (BFD) BFD is a protocol that is used to rapidly detect communication failures between two adjacent systems. It is a simple and lightweight replacement for existing routing protocol link state detection mechanisms. It also provides a failure detection solution for links on which no routing protocol is used. BFD is a simple hello mechanism. Two neighboring systems running BFD establish a session using a three-way handshake.
NOTE: A session state change from Up to Down is the only state change that triggers a link state change in the routing protocol client. BFD Packet Format Control packets are encapsulated in user datagram protocol (UDP) packets. The following illustration shows the complete encapsulation of a BFD control packet inside an IPv4 packet. Figure 12. BFD in IPv4 Packet Format Field Description Diagnostic Code The reason that the last session failed. State The current local session state.
Field Description system clears the poll bit and sets the final bit in its response. The poll and final bits are used during the handshake and in Demand mode (refer to BFD Sessions). NOTE: Dell Networking OS does not currently support multi-point sessions, Demand mode, authentication, or control plane independence; these bits are always clear. Detection Multiplier The number of packets that must be missed in order to declare a session down. Length The entire length of the BFD packet.
BFD Sessions BFD must be enabled on both sides of a link in order to establish a session. The two participating systems can assume either of two roles: Active The active system initiates the BFD session. Both systems can be active for the same session. Passive The passive system does not initiate a session. It only responds to a request for session initialization from the active system.
handshake. Now the discriminator values have been exchanged and the transmit intervals have been negotiated. 4. The passive system receives the control packet and changes its state to Up. Both systems agree that a session has been established. However, because both members must send a control packet — that requires a response — anytime there is a state change or change in a session parameter, the passive system sends a final response indicating the state change.
receives a Down status notification from the remote system, the session state on the local system changes to Init. Figure 14. Session State Changes Important Points to Remember • Dell Networking OS supports 128 sessions per stack unit at 200 minimum transmit and receive intervals with a multiplier of 3, and 64 sessions at 100 minimum transmit and receive intervals with a multiplier of 4. • Enable BFD on both ends of a link. • Demand mode, authentication, and the Echo function are not supported.
• Configure BFD for OSPFv3 • Configure BFD for IS-IS • Configure BFD for BGP • Configure BFD for VRRP • Configuring Protocol Liveness • Troubleshooting BFD Configure BFD for Physical Ports Configuring BFD for physical ports is supported on the C-Series and E-Series platforms only. BFD on physical ports is useful when you do not enable the routing protocol.
Establishing a Session on Physical Ports To establish a session, enable BFD at the interface level on both ends of the link, as shown in the following illustration. The configuration parameters do not need to match. Figure 15. Establishing a BFD Session on Physical Ports 1. Enter interface mode. CONFIGURATION mode interface 2. Assign an IP address to the interface if one is not already assigned. INTERFACE mode ip address ip-address 3.
Remote Addr: 2.2.2.
Number of messages from IFA about port state change: 0 Number of messages communicated b/w Manager and Agent: 7 Disabling and Re-Enabling BFD BFD is enabled on all interfaces by default, though sessions are not created unless explicitly configured. If you disable BFD, all of the sessions on that interface are placed in an Administratively Down state ( the first message example), and the remote systems are notified of the session state change (the second message example).
Establishing Sessions for Static Routes Sessions are established for all neighbors that are the next hop of a static route. Figure 16. Establishing Sessions for Static Routes To establish a BFD session, use the following command. • Establish BFD sessions for all neighbors that are the next hop of a static route. CONFIGURATION mode ip route bfd Example of the show bfd neighbors Command to Verify Static Routes To verify that sessions have been created for static routes, use the show bfd neighbors command.
• Change parameters for all static route sessions. CONFIGURATION mode ip route bfd interval milliseconds min_rx milliseconds multiplier value role [active | passive] To view session parameters, use the show bfd neighbors detail command, as shown in the examples in Displaying BFD for BGP Information Disabling BFD for Static Routes If you disable BFD, all static route BFD sessions are torn down.
Establishing Sessions with OSPF Neighbors BFD sessions can be established with all OSPF neighbors at once or sessions can be established with all neighbors out of a specific interface. Sessions are only established when the OSPF adjacency is in the Full state. Figure 17. Establishing Sessions with OSPF Neighbors To establish BFD with all OSPF neighbors or with OSPF neighbors on a single interface, use the following commands. • Establish sessions with all OSPF neighbors.
ip ospf bfd all-neighbors Example of Verifying Sessions with OSPF Neighbors To view the established sessions, use the show bfd neighbors command. The bold line shows the OSPF BFD sessions. R2(conf-router_ospf)#bfd all-neighbors R2(conf-router_ospf)#do show bfd neighbors * - Active session role Ad Dn - Admin Down C - CLI I - ISIS O - OSPF R - Static Route (RTM) LocalAddr * 2.2.2.2 * 2.2.3.1 RemoteAddr Interface State Rx-int Tx-int Mult Clients 2.2.2.1 Te 2/1 Up 100 100 3 O 2.2.3.
ROUTER-OSPFv3 mode • no bfd all-neighbors Disable BFD sessions with OSPFv3 neighbors on a single interface. INTERFACE mode ipv6 ospf bfd all-neighbors disable Configure BFD for OSPFv3 BFD for OSPFv3 provides support for IPV6. Configuring BFD for OSPFv3 is a two-step process: 1. Enable BFD globally. 2. Establish sessions with OSPFv3 neighbors.
• bfd all-neighbors interval milliseconds min_rx milliseconds multiplier value role [active | passive] Change parameters for all OSPF sessions on an interface. INTERFACE mode ip ospf bfd all-neighbors interval milliseconds min_rx milliseconds multiplier value role [active | passive] To view session parameters, use the show bfd neighbors detail command. Disabling BFD for OSPF If you disable BFD globally, all sessions are torn down and sessions on the remote system are placed in a Down state.
Establishing Sessions with IS-IS Neighbors BFD sessions can be established for all IS-IS neighbors at once or sessions can be established for all neighbors out of a specific interface. Figure 18. Establishing Sessions with IS-IS Neighbors To establish BFD with all IS-IS neighbors or with IS-IS neighbors on a single interface, use the following commands. • Establish sessions with all IS-IS neighbors. ROUTER-ISIS mode • bfd all-neighbors Establish sessions with IS-IS neighbors on a single interface.
The bold line shows that IS-IS BFD sessions are enabled. R2(conf-router_isis)#bfd all-neighbors R2(conf-router_isis)#do show bfd neighbors * - Active session role Ad Dn - Admin Down C - CLI I - ISIS O - OSPF R - Static Route (RTM) LocalAddr * 2.2.2.2 RemoteAddr Interface State Rx-int Tx-int Mult Clients 2.2.2.
Disabling BFD for IS-IS If you disable BFD globally, all sessions are torn down and sessions on the remote system are placed in a Down state. If you disable BFD on an interface, sessions on the interface are torn down and sessions on the remote system are placed in a Down state. Disabling BFD does not trigger a change in BFD clients; a final Admin Down packet is sent before the session is terminated. To disable BFD sessions, use the following commands. • Disable BFD sessions with all IS-IS neighbors.
Figure 19. Establishing Sessions with BGP Neighbors The sample configuration shows alternative ways to establish a BFD session with a BGP neighbor: • By establishing BFD sessions with all neighbors discovered by BGP (the bfd all-neighbors command). • By establishing a BFD session with a specified BGP neighbor (the neighbor {ip-address | peergroup-name} bfd command) BFD packets originating from a router are assigned to the highest priority egress queue to minimize transmission delays.
typical response is to terminate the peering session for the routing protocol and reconverge by bypassing the failed neighboring router. A log message is generated whenever BFD detects a failure condition. 1. Enable BFD globally. CONFIGURATION mode bfd enable 2. Specify the AS number and enter ROUTER BGP configuration mode. CONFIGURATION mode router bgp as-number 3. Add a BGP neighbor or peer group in a remote AS. CONFIG-ROUTERBGP mode neighbor {ip-address | peer-group name} remote-as as-number 4.
ROUTER BGP mode • neighbor {ip-address | peer-group-name} bfd disable Remove the disabled state of a BFD for BGP session with a specified neighbor. ROUTER BGP mode no neighbor {ip-address | peer-group-name} bfd disable Use BFD in a BGP Peer Group You can establish a BFD session for the members of a peer group (the neighbor peer-group-name bfd command in ROUTER BGP configuration mode).
Examples of the BFD show Commands The following example shows verifying a BGP configuration. R2# show running-config bgp ! router bgp 2 neighbor 1.1.1.2 remote-as 1 neighbor 1.1.1.2 no shutdown neighbor 2.2.2.2 remote-as 1 neighbor 2.2.2.2 no shutdown neighbor 3.3.3.2 remote-as 1 neighbor 3.3.3.2 no shutdown bfd all-neighbors The following example shows viewing all BFD neighbors.
Number of messages from IFA about port state change: 0 Number of messages communicated b/w Manager and Agent: 5 Session Discriminator: 10 Neighbor Discriminator: 11 Local Addr: 2.2.2.3 Local MAC Addr: 00:01:e8:66:da:34 Remote Addr: 2.2.2.
Down Admin Down : 0 : 2 The following example shows viewing BFD summary information. The bold line shows the message displayed when you enable BFD for BGP connections. R2# show ip bgp summary BGP router identifier 10.0.0.1, local AS number 2 BGP table version is 0, main routing table version 0 BFD is enabled, Interval 100 Min_rx 100 Multiplier 3 Role Active 3 neighbor(s) using 24168 bytes of memory Neighbor AS MsgRcvd MsgSent TblVer InQ OutQ Up/Down State/Pfx 1.1.1.2 2.2.2.2 3.3.3.
Connections established 1; dropped 0 Last reset never Local host: 2.2.2.3, Local port: 63805 Foreign host: 2.2.2.2, Foreign port: 179 E1200i_ExaScale# R2# show ip bgp neighbors 2.2.2.3 BGP neighbor is 2.2.2.3, remote AS 1, external link Member of peer-group pg1 for session parameters BGP version 4, remote router ID 12.0.0.4 BGP state ESTABLISHED, in this state for 00:05:33 ... Neighbor is using BGP neighbor mode BFD configuration Peer active in peer-group outbound optimization ...
Establishing Sessions with All VRRP Neighbors BFD sessions can be established for all VRRP neighbors at once, or a session can be established with a particular neighbor. Figure 20. Establishing Sessions with All VRRP Neighbors To establish sessions with all VRRP neighbors, use the following command. • Establish sessions with all VRRP neighbors.
The bold line shows that VRRP BFD sessions are enabled. Dell(conf-if-te-4/25)#vrrp bfd all-neighbors Dell(conf-if-te-4/25)#do show bfd neighbor * - Active session role Ad Dn - Admin Down C - CLI I - ISIS O - OSPF R - Static Route (RTM) V - VRRP LocalAddr * 2.2.5.1 RemoteAddr Interface State Rx-int Tx-int Mult Clients 2.2.5.2 Te 4/25 Down 1000 1000 3 V To view session state information, use the show vrrp command. The bold line shows the VRRP BFD session.
• vrrp bfd all-neighbors interval milliseconds min_rx milliseconds multiplier value role [active | passive] Change parameters for a particular VRRP session. INTERFACE mode vrrp bfd neighbor ip-address interval milliseconds min_rx milliseconds multiplier value role [active | passive] To view session parameters, use the show bfd neighbors detail command, as shown in the example in Verifying BFD Sessions with BGP Neighbors Using the show bfd neighbors command example in Displaying BFD for BGP Information.
• debug bfd detail Examine the control packets in hexadecimal format. CONFIGURATION debug bfd packet Examples of Output from the debug bfd Commands The following example shows a three-way handshake using the debug bfd detail command. R1(conf-if-te-4/24)#00:54:38: %RPM0-P:RP2 %BFDMGR-1-BFD_STATE_CHANGE: Changed session state to Down for neighbor 2.2.2.2 on interface Te 4/24 (diag: 0) 00:54:38 : Sent packet for session with neighbor 2.2.2.
10 Border Gateway Protocol IPv4 (BGPv4) This chapter provides a general description of BGPv4 as it is supported in the Dell Networking Operating System (OS). BGP protocol standards are listed in the Standards Compliance chapter. BGP is an external gateway protocol that transmits interdomain routing information within and between autonomous systems (AS). The primary function of the BGP is to exchange network reachability information with other BGP systems.
Figure 21. Internal BGP BGP version 4 (BGPv4) supports classless interdomain routing and aggregate routes and AS paths. BGP is a path vector protocol — a computer network in which BGP maintains the path that updated information takes as it diffuses through the network. Updates traveling through the network and returning to the same node are easily detected and discarded.
Figure 22. BGP Routers in Full Mesh The number of BGP speakers each BGP peer must maintain increases exponentially. Network management quickly becomes impossible. Sessions and Peers When two routers communicate using the BGP protocol, a BGP session is started. The two end-points of that session are Peers. A Peer is also called a Neighbor.
Establish a Session Information exchange between peers is driven by events and timers. The focus in BGP is on the traffic routing policies. In order to make decisions in its operations with other BGP peers, a BGP process uses a simple finite state machine that consists of six states: Idle, Connect, Active, OpenSent, OpenConfirm, and Established. For each peer-to-peer session, a BGP implementation tracks which of these six states the session is in.
Route reflection divides iBGP peers into two groups: client peers and nonclient peers. A route reflector and its client peers form a route reflection cluster. Because BGP speakers announce only the best route for a given prefix, route reflector rules are applied after the router makes its best path decision. • If a route was received from a nonclient peer, reflect the route to all client peers. • If the route was received from a client peer, reflect the route to all nonclient and all client peers.
• Next Hop NOTE: There are no hard coded limits on the number of attributes that are supported in the BGP. Taking into account other constraints such as the Packet Size, maximum number of attributes are supported in BGP. Communities BGP communities are sets of routes with one or more common attributes. Communities are a way to assign common attributes to multiple routes at the same time. NOTE: Duplicate communities are not rejected.
Figure 24. BGP Best Path Selection Best Path Selection Details 1. Prefer the path with the largest WEIGHT attribute. 2. Prefer the path with the largest LOCAL_PREF attribute. 3. Prefer the path that was locally Originated via a network command, redistribute command or aggregate-address command. a. 4. Routes originated with the Originated via a network or redistribute commands are preferred over routes originated with the aggregate-address command.
c. Paths with no MED are treated as “worst” and assigned a MED of 4294967295. 7. Prefer external (EBGP) to internal (IBGP) paths or confederation EBGP paths. 8. Prefer the path with the lowest IGP metric to the BGP if next-hop is selected when synchronization is disabled and only an internal path remains. 9. Dell Networking OS deems the paths as equal and does not perform steps 9 through 11, if the following criteria is met: a.
and AS300. This is advertised to all routers within AS100, causing all BGP speakers to prefer the path through Router B. Figure 25. BGP Local Preference Multi-Exit Discriminators (MEDs) If two ASs connect in more than one place, a multi-exit discriminator (MED) can be used to assign a preference to a preferred path. MED is one of the criteria used to determine the best path, so keep in mind that other criteria may impact selection, as shown in the illustration in Best Path Selection Criteria.
Figure 26. Multi-Exit Discriminators NOTE: Configuring the set metric-type internal command in a route-map advertises the IGP cost as MED to outbound EBGP peers when redistributing routes. The configured set metric value overwrites the default IGP cost. If the outbound route-map uses MED, it overwrites IGP MED. Origin The origin indicates the origin of the prefix, or how the prefix came into BGP. There are three origin codes: IGP, EGP, INCOMPLETE.
*> 7.0.0.0/30 *> 9.2.0.0/16 10.114.8.33 10.114.8.33 0 10 0 0 18508 18508 ? 701 i AS Path The AS path is the list of all ASs that all the prefixes listed in the update have passed through. The local AS number is added by the BGP speaker when advertising to a eBGP neighbor. NOTE: Any update that contains the AS path number 0 is valid. The AS path is shown in the following example. The origin attribute is shown following the AS path information (shown in bold).
Multiprotocol BGP Multiprotocol extensions for BGP (MBGP) is defined in IETF RFC 2858. MBGP allows different types of address families to be distributed in parallel. MBGP allows information about the topology of the IP multicast-capable routers to be exchanged separately from the topology of normal IPv4 and IPv6 unicast routers. It allows a multicast routing topology different from the unicast routing topology.
• If BGP peer outbound route-map has metric configured, all other metrics are overwritten by this configuration. NOTE: When redistributing static, connected, or OSPF routes, there is no metric option. Simply assign the appropriate route-map to the redistributed route. The following table lists some examples of these rules. Table 10.
AS4 Number Representation Dell Networking OS supports multiple representations of 4-byte AS numbers: asplain, asdot+, and asdot. NOTE: The ASDOT and ASDOT+ representations are supported only with the 4-Byte AS numbers feature. If 4-Byte AS numbers are not implemented, only ASPLAIN representation is supported. ASPLAIN is the method Dell Networking OS has used for all previous Dell Networking OS versions. ASPLAIN remains the default method with Dell Networking OS.
bgp asnotation asdot+ bgp four-octet-as-support neighbor 172.30.1.250 local-as 65057
Figure 27. Before and After AS Number Migration with Local-AS Enabled When you complete your migration, and you have reconfigured your network with the new information, disable this feature. If you use the “no prepend” option, the Local-AS does not prepend to the updates received from the eBGP peer. If you do not select “no prepend” (the default), the Local-AS is added to the first AS segment in the AS-PATH.
BGP4 Management Information Base (MIB) The FORCE10-BGP4-V2-MIB enhances Dell Networking OS BGP management information base (MIB) support with many new simple network management protocol (SNMP) objects and notifications (traps) defined in draft-ietf-idr-bgp4-mibv2-05. To see these enhancements, download the MIB from the Dell website. NOTE: For the Force10-BGP4-V2-MIB and other MIB documentation, refer to the Dell iSupport web page.
disabled, it is assumed that clients are in a full mesh and there is no need to advertise prefixes to the other clients. • High CPU utilization may be observed during an SNMP walk of a large BGP Loc-RIB. • To avoid SNMP timeouts with a large-scale configuration (large number of BGP neighbors and a large BGP Loc-RIB), Dell Networking recommends setting the timeout and retry count values to a relatively higher number. For example, t = 60 or r = 5.
NOTE: In Dell Networking OS, all newly configured neighbors and peer groups are disabled. To enable a neighbor or peer group, enter the neighbor {ip-address | peer-group-name} no shutdown command. The following table displays the default values for BGP on Dell Networking OS. Table 11. BGP Default Values Item Default BGP Neighbor Adjacency changes All BGP neighbor changes are logged.
1. Assign an AS number and enter ROUTER BGP mode. CONFIGURATION mode router bgp as-number • as-number: from 0 to 65535 (2 Byte) or from 1 to 4294967295 (4 Byte) or 0.1 to 65535.65535 (Dotted format). Only one AS is supported per system. NOTE: If you enter a 4-Byte AS number, 4-Byte AS support is enabled automatically. a. Enable 4-Byte support for the BGP process. NOTE: This command is OPTIONAL. Enable if you want to use 4-Byte AS numbers or if you support AS4 number representation.
Examples of the show ip bgp Commands NOTE: When you change the configuration of a BGP neighbor, always reset it by entering the clear ip bgp * command in EXEC Privilege mode. To view the BGP configuration, enter show config in CONFIGURATION ROUTER BGP mode. To view the BGP status, use the show ip bgp summary command in EXEC Privilege mode.
To view the status of BGP neighbors, use the show ip bgp neighbors command in EXEC Privilege mode as shown in the first example. For BGP neighbor configuration information, use the show running-config bgp command in EXEC Privilege mode as shown in the second example. NOTE: The showconfig command in CONFIGURATION ROUTER BGP mode gives the same information as the show running-config bgp command.
The following example shows verifying the BGP configuration using the show running-config bgp command.. Dell#show running-config bgp ! router bgp 65123 bgp router-id 192.168.10.2 network 10.10.21.0/24 network 10.10.32.0/24 network 100.10.92.0/24 network 192.168.10.0/24 bgp four-octet-as-support neighbor 10.10.21.1 remote-as 65123 neighbor 10.10.21.1 filter-list ISP1in neighbor 10.10.21.1 no shutdown neighbor 10.10.32.3 remote-as 65123 neighbor 10.10.32.3 no shutdown neighbor 100.10.92.
• NOTE: ASPLAIN is the default method Dell Networking OS uses and does not appear in the configuration display. Enable ASDOT AS Number representation. CONFIG-ROUTER-BGP mode • bgp asnotation asdot Enable ASDOT+ AS Number representation. CONFIG-ROUTER-BGP mode bgp asnotation asdot+ Examples of the bgp asnotation Commands The following example shows the bgp asnotation asplain command output.
Configuring Peer Groups To configure multiple BGP neighbors at one time, create and populate a BGP peer group. An advantage of peer groups is that members of a peer group inherit the configuration properties of the group and share same update policy. A maximum of 256 peer groups are allowed on the system. Create a peer group by assigning it a name, then adding members to the peer group. After you create a peer group, you can configure route policies for it.
To add an internal BGP (IBGP) neighbor, configure the as-number parameter with the same BGP asnumber configured in the router bgp as-number command. Examples of Viewing and Configuring Peer Groups After you create a peer group, you can use any of the commands beginning with the keyword neighbor to configure that peer group. When you add a peer to a peer group, it inherits all the peer group’s configured parameters.
neighbor 10.1.1.1 shutdown neighbor 10.14.8.60 remote-as 18505 neighbor 10.14.8.60 no shutdown Dell(conf-router_bgp)# To disable a peer group, use the neighbor peer-group-name shutdown command in CONFIGURATION ROUTER BGP mode. The configuration of the peer group is maintained, but it is not applied to the peer group members. When you disable a peer group, all the peers within the peer group that are in the ESTABLISHED state move to the IDLE state.
When you enable fall-over, BGP tracks IP reachability to the peer remote address and the peer local address. Whenever either address becomes unreachable (for example, no active route exists in the routing table for peer IPv6 destinations/local address), BGP brings down the session with the peer. The BGP fast fall-over feature is configured on a per-neighbor or peer-group basis and is disabled by default. To enable the BGP fast fall-over feature, use the following command.
Notification History 'Connection Reset' Sent : 5 Recv: 0 Local host: 200.200.200.200, Local port: 65519 Foreign host: 100.100.100.100, Foreign port: 179 Dell# To verify that fast fall-over is enabled on a peer-group, use the show ip bgp peer-group command (shown in bold).
CONFIG-ROUTER-BGP mode neighbor peer-group-name subnet subnet-number mask The peer group responds to OPEN messages sent on this subnet. 3. Enable the peer group. CONFIG-ROUTER-BGP mode neighbor peer-group-name no shutdown 4. Create and specify a remote peer for BGP neighbor. CONFIG-ROUTER-BGP mode neighbor peer-group-name remote-as as-number Only after the peer group responds to an OPEN message sent on the subnet does its BGP state change to ESTABLISHED.
network 100.10.92.0/24 network 192.168.10.0/24 bgp four-octet-as-support neighbor 10.10.21.1 remote-as 65123 neighbor 10.10.21.1 filter-list Laura in neighbor 10.10.21.1 no shutdown neighbor 10.10.32.3 remote-as 65123 neighbor 10.10.32.3 no shutdown neighbor 100.10.92.9 remote-as 65192 neighbor 100.10.92.9 local-as 6500 neighbor 100.10.92.9 no shutdown neighbor 192.168.10.1 remote-as 65123 neighbor 192.168.10.1 update-source Loopback 0 neighbor 192.168.10.1 no shutdown neighbor 192.168.12.
neighbor 100.10.92.9 local-as 6500 neighbor 100.10.92.9 no shutdown neighbor 192.168.10.1 remote-as 65123 neighbor 192.168.10.1 update-source Loopback 0 neighbor 192.168.10.1 no shutdown neighbor 192.168.12.2 remote-as 65123 neighbor 192.168.12.2 allowas-in 9 neighbor 192.168.12.2 update-source Loopback 0 neighbor 192.168.12.2 no shutdown R2(conf-router_bgp)#R2(conf-router_bgp)# Enabling Graceful Restart Use this feature to lessen the negative effects of a BGP restart.
• Set maximum time to retain the restarting peer’s stale paths. CONFIG-ROUTER-BGP mode bgp graceful-restart [stale-path-time time-in-seconds] • The default is 360 seconds. Local router supports graceful restart as a receiver only. CONFIG-ROUTER-BGP mode bgp graceful-restart [role receiver-only] Enabling Neighbor Graceful Restart BGP graceful restart is active only when the neighbor becomes established. Otherwise, it is disabled. Graceful-restart applies to all neighbors with established adjacency.
to affect interdomain routing. By identifying certain ASN in the AS_PATH, you can permit or deny routes based on the number in its AS_PATH. AS-PATH ACLs use regular expressions to search AS_PATH values. AS-PATH ACLs have an “implicit deny.” This means that routes that do not meet a deny or match filter are dropped. To configure an AS-PATH ACL to filter a specific AS_PATH value, use these commands in the following sequence. 1. Assign a name to a AS-PATH ACL and enter AS-PATH ACL mode.
0x6cc18d4 0x5982e44 0x67d4a14 0x559972c 0x59cd3b4 0x7128114 0x536a914 0x2ffe884 0x2ff7284 0x2ff7ec4 0x2ff8544 0x736c144 0x3b8d224 0x5eb1e44 0x5cd891c --More-- 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 1 162 2 31 2 10 3 1 99 4 3 1 10 1 9 18508 18508 18508 18508 18508 18508 18508 18508 18508 18508 18508 18508 18508 18508 18508 701 209 701 209 209 209 209 701 701 209 701 701 209 701 209 2914 4713 17935 i i 19878 ? 18756 i 7018 15227 i 3356 13845 i 701 6347 7781 i 3561 9116 21350 i 1239 577 855 ? 3561 4755 17426 i 574
The following example applies access list Eagle to routes inbound from BGP peer 10.5.5.2. Access list Eagle uses a regular expression to deny routes originating in AS 32. The first lines shown in bold create the access list and filter. The second lines shown in bold are the regular expression shown as part of the access list filter.
redistribute isis [level-1 | level-1-2 | level-2] [metric value] [route-map map-name] Configure the following parameters: – level-1, level-1-2, or level-2: Assign all redistributed routes to a level. The default is level-2. – metric value: The value is from 0 to 16777215. The default is 0. • – map-name: name of a configured route map. Include specific OSPF routes in IS-IS.
IETF RFC 1997 defines the COMMUNITY attribute and the predefined communities of INTERNET, NO_EXPORT_SUBCONFED, NO_ADVERTISE, and NO_EXPORT. All BGP routes belong to the INTERNET community. In the RFC, the other communities are defined as follows: • All routes with the NO_EXPORT_SUBCONFED (0xFFFFFF03) community attribute are not sent to CONFED-EBGP or EBGP peers, but are sent to IBGP peers within CONFED-SUB-AS. • All routes with the NO_ADVERTISE (0xFFFFFF02) community attribute must not be advertised.
deny deny deny deny deny deny Dell# 701:667 702:667 703:667 704:666 705:666 14551:666 Configuring an IP Extended Community List To configure an IP extended community list, use these commands. 1. Create a extended community list and enter the EXTCOMMUNITY-LIST mode. CONFIGURATION mode ip extcommunity-list extcommunity-list-name 2. Two types of extended communities are supported.
Filtering Routes with Community Lists To use an IP community list or IP extended community list to filter routes, you must apply a match community filter to a route map and then apply that route map to a BGP neighbor or peer group. 1. Enter the ROUTE-MAP mode and assign a name to a route map. CONFIGURATION mode route-map map-name [permit | deny] [sequence-number] 2. Configure a match filter for all routes meeting the criteria in the IP community or IP extended community list.
To view the BGP configuration, use the show config command in CONFIGURATION ROUTER BGP mode. If you want to remove or add a specific COMMUNITY number from a BGP path, you must create a route map with one or both of the following statements in the route map. Then apply that route map to a BGP neighbor or peer group. 1. Enter ROUTE-MAP mode and assign a name to a route map. CONFIGURATION mode route-map map-name [permit | deny] [sequence-number] 2.
Dell>show ip bgp community BGP table version is 3762622, local router ID is 10.114.8.48 Status codes: s suppressed, d damped, h history, * valid, > best, i - internal Origin codes: i - IGP, e - EGP, ? - incomplete Network * i 3.0.0.0/8 *>i 4.2.49.12/30 * i 4.21.132.0/23 *>i 4.24.118.16/30 *>i 4.24.145.0/30 *>i 4.24.187.12/30 *>i 4.24.202.0/30 *>i 4.25.88.0/30 *>i 6.1.0.0/16 *>i 6.2.0.0/22 *>i 6.3.0.0/18 *>i 6.4.0.0/16 *>i 6.5.0.0/19 *>i 6.8.0.0/20 *>i 6.9.0.0/20 *>i 6.10.0.0/15 *>i 6.14.0.0/15 *>i 6.133.0.
CONFIG-ROUTER-BGP mode bgp default local-preference value – value: the range is from 0 to 4294967295. The default is 100. To view the BGP configuration, use the show config command in CONFIGURATION ROUTER BGP mode or the show running-config bgp command in EXEC Privilege mode. A more flexible method for manipulating the LOCAL_PREF attribute value is to use a route map. 1. Enter the ROUTE-MAP mode and assign a name to a route map. CONFIGURATION mode route-map map-name [permit | deny] [sequence-number] 2.
set next-hop ip-address Changing the WEIGHT Attribute To change how the WEIGHT attribute is used, enter the first command. You can also use route maps to change this and other BGP attributes. For example, you can include the second command in a route map to specify the next hop address. • Assign a weight to the neighbor connection. CONFIG-ROUTER-BGP mode neighbor {ip-address | peer-group-name} weight weight – weight: the range is from 0 to 65535. • The default is 0. Sets weight for the route.
For inbound and outbound updates the order of preference is: • prefix lists (using the neighbor distribute-list command) • AS-PATH ACLs (using the neighbor filter-list command) • route maps (using the neighbor route-map command) Prior to filtering BGP routes, create the prefix list, AS-PATH ACL, or route map. For configuration information about prefix lists, AS-PATH ACLs, and route maps, refer to Access Control Lists (ACLs).
• If the prefix list contains no filters, all routes are permitted. • If none of the routes match any of the filters in the prefix list, the route is denied. This action is called an implicit deny. (If you want to forward all routes that do not match the prefix list criteria, you must configure a prefix list filter to permit all routes. For example, you could have the following filter as the last filter in your prefix list permit 0.0.0.0/0 le 32).
Filtering BGP Routes Using AS-PATH Information To filter routes based on AS-PATH information, use these commands. 1. Create a AS-PATH ACL and assign it a name. CONFIGURATION mode ip as-path access-list as-path-name 2. Create a AS-PATH ACL filter with a deny or permit action. AS-PATH ACL mode {deny | permit} as-regular-expression 3. Return to CONFIGURATION mode. AS-PATH ACL exit 4. Enter ROUTER BGP mode. CONFIGURATION mode router bgp as-number 5.
• Assign an ID to a router reflector cluster. CONFIG-ROUTER-BGP mode bgp cluster-id cluster-id • You can have multiple clusters in an AS. Configure the local router as a route reflector and the neighbor or peer group identified is the route reflector client. CONFIG-ROUTER-BGP mode neighbor {ip-address | peer-group-name} route-reflector-client When you enable a route reflector, Dell Networking OS automatically enables route reflection to all clients.
Configuring BGP Confederations Another way to organize routers within an AS and reduce the mesh for IBGP peers is to configure BGP confederations. As with route reflectors, BGP confederations are recommended only for IBGP peering involving many IBGP peering sessions per router. Basically, when you configure BGP confederations, you break the AS into smaller sub-AS, and to those outside your network, the confederations appear as one AS.
• history entry — an entry that stores information on a downed route • dampened path — a path that is no longer advertised • penalized path — a path that is assigned a penalty To configure route flap dampening parameters, set dampening parameters using a route map, clear information on route dampening and return suppressed routes to active state, view statistics on route flapping, or change the path selection from the default mode (deterministic) to non-deterministic, use the following commands.
show ip bgp flap-statistics [ip-address [mask]] [filter-list as-path-name] [regexp regular-expression] – ip-address [mask]: enter the IP address and mask. – filter-list as-path-name: enter the name of an AS-PATH ACL. – regexp regular-expression: enter a regular express to match on. • By default, the path selection in Dell Networking OS is deterministic, that is, paths are compared irrespective of the order of their arrival.
Dampening enabled. 0 history paths, 0 dampened paths, 0 penalized paths Neighbor AS MsgRcvd MsgSent TblVer 10.114.8.34 18508 82883 79977 780266 10.114.8.33 18508 117265 25069 780266 Dell> InQ OutQ Up/Down State/PfxRcd 0 2 00:38:51 118904 0 20 00:38:50 102759 To view which routes are dampened (non-active), use the show ip bgp dampened-routes command in EXEC Privilege mode. Changing BGP Timers To configure BGP timers, use either or both of the following commands.
To reset a BGP connection using BGP soft reconfiguration, use the clear ip bgp command in EXEC Privilege mode at the system prompt. When you enable soft-reconfiguration for a neighbor and you execute the clear ip bgp soft in command, the update database stored in the router is replayed and updates are reevaluated. With this command, the replay and update process is triggered only if a route-refresh request is not negotiated with the peer.
Route Map Continue The BGP route map continue feature, continue [sequence-number], (in ROUTE-MAP mode) allows movement from one route-map entry to a specific route-map entry (the sequence number). If you do not specify a sequence number, the continue feature moves to the next sequence number (also known as an “implied continue”). If a match clause exists, the continue feature executes only after a successful match occurs. If there are no successful matches, continue is ignored.
• Exchange of IPv4 multicast route information occurs through the use of two new attributes called MP_REACH_NLRI and MP_UNREACH_NLRI, for feasible and withdrawn routes, respectively. • If the peer has not been activated in any AFI/SAFI, the peer remains in Idle state. Most Dell Networking OS BGP IPv4 unicast commands are extended to support the IPv4 multicast RIB using extra options to the command.
• debug ip bgp [ip-address | peer-group peer-group-name] notifications [in | out] View information about BGP updates and filter by prefix name. EXEC Privilege mode • debug ip bgp [ip-address | peer-group peer-group-name] updates [in | out] [prefix-list name] Enable soft-reconfiguration debug.
MULTIPROTO_EXT(1) ROUTE_REFRESH(2) CISCO_ROUTE_REFRESH(128) For address family: IPv4 Unicast BGP table version 1395, neighbor version 1394 Prefixes accepted 1 (consume 4 bytes), 0 withdrawn by peer Prefixes advertised 0, rejected 0, 0 withdrawn from peer Connections established 3; dropped 2 Last reset 00:00:12, due to Missing well known attribute Notification History 'UPDATE error/Missing well-known attr' Sent : 1 Recv: 0 'Connection Reset' Sent : 1 Recv: 0 Last notification (len 21) sent 00:26:02 ago fffff
00000000 00000000 00000000 00000001 0181a1e4 0181a25c 41af9400 00000000 PDU[2] : len 19, captured 00:34:51 ago ffffffff ffffffff ffffffff ffffffff 00130400 PDU[3] : len 19, captured 00:34:51 ago ffffffff ffffffff ffffffff ffffffff 00130400 PDU[4] : len 19, captured 00:34:22 ago ffffffff ffffffff ffffffff ffffffff 00130400 [. . .] Outgoing packet capture enabled for BGP neighbor 20.20.20.
The following illustration shows the configurations described on the following examples. These configurations show how to create BGP areas using physical and virtual links. They include setting up the interfaces and peers groups with each other. Figure 28. Sample Configurations Example of Enabling BGP (Router 1) R1# conf R1(conf)#int loop 0 R1(conf-if-lo-0)#ip address 192.168.128.1/24 R1(conf-if-lo-0)#no shutdown R1(conf-if-lo-0)#show config ! interface Loopback 0 ip address 192.168.128.
! interface TengigabitEthernet 1/31 ip address 10.0.3.31/24 no shutdown R1(conf-if-te-1/31)#router bgp 99 R1(conf-router_bgp)#network 192.168.128.0/24 R1(conf-router_bgp)#neighbor 192.168.128.2 remote 99 R1(conf-router_bgp)#neighbor 192.168.128.2 no shut R1(conf-router_bgp)#neighbor 192.168.128.2 update-source loop 0 R1(conf-router_bgp)#neighbor 192.168.128.3 remote 100 R1(conf-router_bgp)#neighbor 192.168.128.3 no shut R1(conf-router_bgp)#neighbor 192.168.128.
Example of Enabling BGP (Router 3) R3# conf R3(conf)# R3(conf)#int loop 0 R3(conf-if-lo-0)#ip address 192.168.128.3/24 R3(conf-if-lo-0)#no shutdown R3(conf-if-lo-0)#show config ! interface Loopback 0 ip address 192.168.128.3/24 no shutdown R3(conf-if-lo-0)#int te 3/11 R3(conf-if-te-3/11)#ip address 10.0.3.33/24 R3(conf-if-te-3/11)#no shutdown R3(conf-if-te-3/11)#show config ! interface TengigabitEthernet 3/11 ip address 10.0.3.33/24 no shutdown R3(conf-if-lo-0)#int te 3/21 R3(conf-if-te-3/21)#ip address 10.
neighbor 192.168.128.2 no shutdown neighbor 192.168.128.3 remote-as 100 neighbor 192.168.128.3 peer-group BBB neighbor 192.168.128.3 update-source Loopback 0 neighbor 192.168.128.3 no shutdown R1# R1#show ip bgp summary BGP router identifier 192.168.128.
R2(conf-router_bgp)# neighbor 192.168.128.3 no shut R2(conf-router_bgp)#show conf ! router bgp 99 network 192.168.128.0/24 neighbor AAA peer-group neighbor AAA no shutdown neighbor BBB peer-group neighbor BBB no shutdown neighbor 192.168.128.1 remote-as 99 neighbor 192.168.128.1 peer-group CCC neighbor 192.168.128.1 update-source Loopback 0 neighbor 192.168.128.1 no shutdown neighbor 192.168.128.3 remote-as 100 neighbor 192.168.128.3 peer-group BBB neighbor 192.168.128.
Received 93 messages, 0 in queue 5 opens, 0 notifications, 5 updates 83 keepalives, 0 route refresh requests Sent 99 messages, 0 in queue 5 opens, 4 notifications, 5 updates 85 keepalives, 0 route refresh requestsCapabilities received from neighbor for IPv4 Unicast : MULTIPROTO_EXT(1) ROUTE_REFRESH(2) CISCO_ROUTE_REFRESH(128) Capabilities advertised to neighbor for IPv4 Unicast : MULTIPROTO_EXT(1) ROUTE_REFRESH(2) CISCO_ROUTE_REFRESH(128) Update source set to Loopback 0 Peer active in peer-group outbound op
Content Addressable Memory (CAM) 11 CAM is a type of memory that stores information in the form of a lookup table. On Dell Networking systems, CAM stores Layer 2 (L2) and Layer 3 (L3) forwarding information, access-lists (ACLs), flows, and routing policies. CAM Allocation CAM Allocation for Ingress To allocate the space for regions such has L2 ingress ACL, IPV4 ingress ACL, IPV6 ingress ACL, IPV4 QoS, L2 QoS, PBR, VRF ACL, and so forth, use the cam-acl command in CONFIGURATION mode.
CAM Allocation Setting Openflow 0 fedgovacl 0 NOTE: When you reconfigure CAM allocation, use the nlbclusteracl number command to change the number of NLB ARP entries. The range is from 0 to 2. The default value is 0. At the default value of 0, eight NLB ARP entries are available for use. This platform supports upto 256 CAM entries. Select 1 to configure 128 entries. Select 2 to configure 256 entries.
Dell(conf)# 1. Select a cam-acl action. CONFIGURATION mode cam-acl [default | l2acl] NOTE: Selecting default resets the CAM entries to the default settings. Select l2acl to allocate the desired space for all other regions. 2. Enter the number of FP blocks for each region.
Current Settings(in block sizes) Next Boot(in block sizes) 1 block = 128 entries L2Acl : 6 4 Ipv4Acl : 4 2 Ipv6Acl : 0 0 Ipv4Qos : 2 2 L2Qos : 1 1 L2PT : 0 0 IpMacAcl : 0 0 VmanQos : 0 0 VmanDualQos : 0 0 EcfmAcl : 0 0 FcoeAcl : 0 0 iscsiOptAcl : 0 0 ipv4pbr : 0 2 vrfv4Acl : 0 2 Openflow : 0 0 fedgovacl : 0 0 -- Stack unit 0 -Current Settings(in block sizes) Next Boot(in block sizes) 1 block = 128 entries L2Acl : 6 4 Ipv4Acl : 4 2 Ipv6Acl : 0 0 Ipv4Qos : 2 2 L2Qos : 1 1 L2PT : 0 0 IpMacAcl : 0 0 VmanQos : 0
EcfmAcl FcoeAcl iscsiOptAcl ipv4pbr vrfv4Acl Openflow fedgovacl : : : : : : : 0 0 0 0 0 0 0 -- Stack unit 0 -Current Settings(in block sizes) 1 block = 128 entries L2Acl : 6 Ipv4Acl : 4 Ipv6Acl : 0 Ipv4Qos : 2 L2Qos : 1 L2PT : 0 IpMacAcl : 0 VmanQos : 0 VmanDualQos : 0 EcfmAcl : 0 FcoeAcl : 0 iscsiOptAcl : 0 ipv4pbr : 0 vrfv4Acl : 0 Openflow : 0 fedgovacl : 0 -- Stack unit 7 -Current Settings(in block sizes) 1 block = 128 entries L2Acl : 6 Ipv4Acl : 4 Ipv6Acl : 0 Ipv4Qos : 2 L2Qos : 1 L2PT : 0 IpMacAcl :
| | | | | | | | 7 | 0 | | | | | | | | | | | Codes: * - cam usage Dell# IN-L2 ACL OUT-L3 ACL OUT-V6 ACL OUT-L2 ACL IN-L3 ACL IN-V6 ACL IN-L2 ACL OUT-L3 ACL OUT-V6 ACL OUT-L2 ACL is above 90%.
If you exceed the QoS CAM space, follow these steps. 1. Verify that you have configured a CAM profile that allocates 24 K entries to the IPv4 system flow region. 2. Allocate more entries in the IPv4Flow region to QoS. Dell Networking OS supports the ability to view the actual CAM usage before applying a service-policy. The test cam-usage service-policy command provides this test framework. For more information, refer to Pre-Calculating Available QoS CAM Space.
Control Plane Policing (CoPP) 12 Control plane policing (CoPP) uses access control list (ACL) rules and quality of service (QoS) policies to create filters for a system’s control plane. That filter prevents traffic not specifically identified as legitimate from reaching the system control plane, rate-limits, traffic to an acceptable level.
Figure 30. CoPP Implemented Versus CoPP Not Implemented Configure Control Plane Policing The system can process a maximum of 4200 packets per second (PPS). Protocols that share a single queue may experience flaps if one of the protocols receives a high rate of control traffic even though per protocol CoPP is applied. This happens because queue-based rate limiting is applied first.
queue rate limit value. You must complete queue bandwidth tuning carefully because the system cannot open up to handle any rate, including traffic coming at the line rate. CoPP policies are assigned on a per-protocol or a per-queue basis, and are assigned in CONTROLPLANE mode to each port-pipe. CoPP policies are configured by creating extended ACL rules and specifying rate-limits through QoS policies. The ACLs and QoS policies are assigned as service-policies.
CONTROL-PLANE mode service-policy rate-limit-protocols Examples of Configuring CoPP for Different Protocols The following example shows creating the IP/IPv6/MAC extended ACL.
The following example shows matching the QoS class map to the QoS policy.
The following example shows assigning the QoS policy to the queues. Dell(conf)#policy-map-input cpuq_rate_policy cpu-qos Dell(conf-qos-policy-in)#service-queue 5 qos-policy cpuq_1 Dell(conf-qos-policy-in)#service-queue 6 qos-policy cpuq_2 Dell(conf-qos-policy-in)#service-queue 7 qos-policy cpuq_1 The following example shows creating the control plane service policy.
points, and the queue (0 – 3) taken by the CPU bound data streams are uniform. In back-plane ports, queue 0 – 3 will carry both the front-end bound data streams as well as the CPU bound data streams which is acceptable but the well-known protocol streams must not be mixed with the data streams on queues 0 – 3 in back-plane ports.
NDP Packets Neighbor discovery protocol has 4 types of packets NS, NA, RA, RS. These packets need to be taken to CPU for neighbor discovery. • Unicast NDP packets: – Packets hitting the L3 host/route table and discovered as local terminated packets/CPU bound traffic. For CPU bound traffic route entry have CPU action. Below are packets are CPU bound traffic. • * Packets destined to chassis.
CPU Queue Weights Rate (pps) Protocol 4 127 2000 IPC/IRC, VLT Control frames 5 16 300 ARP Request, NS, RS, iSCSI OPT Snooping 6 16 400 ICMP, ARP Reply, NTP, Local terminated L3, NA, RA,ICMPv6 (other Than NDP and MLD) 7 64 400 xSTP, FRRP, LACP, 802.
To configure control-plane policing, perform the following: 1. Create an IPv6 ACL for control-plane traffic policing for ospfv3. CONFIGURATION mode Dell(conf)#ipv6 access-list ospfv3 cpu-qos Dell(conf-ipv6-acl-cpuqos)#permit ospf 2. Create a QoS input policy for the router and assign the policing. CONFIGURATION mode Dell(conf)#qos-policy-input ospfv3_rate cpu-qos Dell(conf-in-qos-policy-cpuqos)#rate-police 1500 16 peak 1500 16 3.
Q7 Dell# 1100 Example of Viewing Queue Mapping To view the queue mapping for each configured protocol, use the show ip protocol-queuemapping command.
Data Center Bridging (DCB) 13 Ethernet Enhancements in Data Center Bridging The following section describes DCB. The S4048–ON system supports loading two DCB_Config files: FCoE_DCB_Config and iSCSI_DCB_Config. These files are located in the root directory flash:/CONFIG_TEMPLATE. After copying the configuration files to the startup config and reloading the system.
generally insensitive to latency requirements, while certain applications, such as streaming video, are more sensitive to latency. Ethernet functions as a best-effort network that may drop packets in case of network congestion. IP networks rely on transport protocols (for example, TCP) for reliable data transmission with the associated cost of greater processing overhead and performance impact.
The system supports loading two DCB_Config files: • FCoE converged traffic with priority 3. • iSCSI storage traffic with priority 4. In the Dell Networking OS, PFC is implemented as follows: • PFC supports buffering to receive data that continues to arrive on an interface while the remote system reacts to the PFC operation. • PFC uses DCB MIB IEEE 802.1azd2.5 and PFC MIB IEEE 802.1bb-d2.2. • PFC uses DCB MIB IEEE 802.1azd2.5 and PFC MIB IEEE 802.1bb-d2.2. • PFC is supported on specified 802.
Figure 31. Enhanced Transmission Selection The following table lists the traffic groupings ETS uses to select multiprotocol traffic for transmission. Table 14. ETS Traffic Groupings Traffic Groupings Description Group ID A 4-bit identifier assigned to each priority group. The range is from 0 to 7 configurable; 8 - 14 reservation and 15.0 - 15.7 is strict priority group.. Group bandwidth Percentage of available bandwidth allocated to a priority group.
DCBx requires the link layer discovery protocol (LLDP) to provide the path to exchange DCB parameters with peer devices. Exchanged parameters are sent in organizationally specific TLVs in LLDP data units. The following LLDP TLVs are supported for DCB parameter exchange: PFC parameters PFC Configuration TLV and Application Priority Configuration TLV. ETS parameters ETS Configuration TLV and ETS Recommendation TLV.
The system supports loading two DCB_Config files: • FCoE converged traffic with priority 3. • iSCSI storage traffic with priority 4. In the Dell Networking OS, PFC is implemented as follows: • PFC supports buffering to receive data that continues to arrive on an interface while the remote system reacts to the PFC operation. • PFC uses DCB MIB IEEE 802.1azd2.5 and PFC MIB IEEE 802.1bb-d2.2. • PFC uses DCB MIB IEEE 802.1azd2.5 and PFC MIB IEEE 802.1bb-d2.2. • PFC is supported on specified 802.
Figure 33. Enhanced Transmission Selection The following table lists the traffic groupings ETS uses to select multiprotocol traffic for transmission. Table 15. ETS Traffic Groupings Traffic Groupings Description Group ID A 4-bit identifier assigned to each priority group. The range is from 0 to 7 configurable; 8 - 14 reservation and 15.0 - 15.7 is strict priority group.. Group bandwidth Percentage of available bandwidth allocated to a priority group.
DCBx requires the link layer discovery protocol (LLDP) to provide the path to exchange DCB parameters with peer devices. Exchanged parameters are sent in organizationally specific TLVs in LLDP data units. The following LLDP TLVs are supported for DCB parameter exchange: PFC parameters PFC Configuration TLV and Application Priority Configuration TLV. ETS parameters ETS Configuration TLV and ETS Recommendation TLV.
To enable DCB with PFC buffers on a switch, enter the following commands, save the configuration, and reboot the system to allow the changes to take effect. 1. Enable DCB. CONFIGURATION mode dcb enable 2. Set PFC buffering on the DCB stack unit. CONFIGURATION mode Dell(conf)#dcb enable pfc-queues NOTE: To save the pfc buffering configuration changes, save the configuration and reboot the system.
DCB map is applied. By default, PFC is not applied on specific 802.1p priorities; ETS assigns equal bandwidth to each 802.1p priority. As a result, PFC and lossless port queues are disabled on 802.1p priorities, and all priorities are mapped to the same priority queue and equally share the port bandwidth. • To change the ETS bandwidth allocation configured for a priority group in a DCB map, do not modify the existing DCB map configuration.
When traffic congestion occurs, PFC sends a pause frame to a peer device with the CoS priority values of the traffic that is to be stopped. Data Center Bridging Exchange protocol (DCBx) provides the link-level exchange of PFC parameters between peer devices. PFC allows network administrators to create zeroloss links for Storage Area Network (SAN) traffic that requires no-drop service, while retaining packetdrop congestion management for Local Area Network (LAN) traffic.
Example: Port A —> Port B Port C —> Port B PFC no-drop queues are configured for queues 1, 2 on Port B. PFC capability is enabled on priorities 3, 4 on PORT A and C. Port B acting as Egress During the congestion, [traffic pump on priorities 3 and 4 from PORT A and PORT C is at full line rate], PORT A and C send out the PFCs to rate the traffic limit. Egress drops are not observed on Port B since traffic flow on priorities is mapped to loss less queues.
NOTE: Dell Networking OS Behavior: By default, no lossless queues are configured on a port. A limit of two lossless queues is supported on a port. If the amount of priority traffic that you configure to be paused exceeds the two lossless queues, an error message displays. Configuring PFC in a DCB Map An S4048–ON switch supports the use of a DCB map in which you configure priority-based flow control (PFC) setting. To configure PFC parameters, you must apply a DCB map on an S4048–ON interface.
• For PFC to be applied, the configured priority traffic must be supported by a PFC peer (as detected by DCBx). • If you apply a DCB map with PFC disabled (pfc off), you can enable link-level flow control on the interface using the flowcontrol rx on tx on command. To delete the DCB map, first disable link-level flow control. PFC is then automatically enabled on the interface because an interface is PFC-enabled by default.
Step Task Command Command Mode fortygigabitEthernet slot/port} 2 Apply the DCB map on the Ethernet port to configure it with the PFC and ETS settings in the map; for example: dcb-map name INTERFACE Dell# interface tengigabitEthernet 1/1 Dell(config-if-te-1/1)# dcb-map SAN_A_dcb_map1 Repeat Steps 1 and 2 to apply a DCB map to more than one port.
Configuring Lossless Queues DCB also supports the manual configuration of lossless queues on an interface when PFC mode is disabled in a DCB map, apply the map on the interface. The configuration of no-drop queues provides flexibility for ports on which PFC is not needed, but lossless traffic should egress from the interface. Configuring no-drop queues is applicable only on the interfaces which do not need PFC.
Step Task Command Command Mode subport] | fortygigabitEthernet slot/port} 2 Open a DCB map and enter DCB map configuration mode. dcb-map name INTERFACE 3 Disable PFC. no pfc mode on DCB MAP 4 Return to interface configuration mode. exit DCB MAP 5 Apply the DCB map, created to disable the PFC operation, on the interface dcb-map {name | default} INTERFACE 6 Configure the port queues that still function as no-drop queues for lossless traffic. For the dot1p-queue assignments.
When a device sends a pause frame to another device, the time for which the sending of packets from the other device must be stopped is contained in the pause frame. The device that sent the pause frame empties the buffer to be less than the threshold value and restarts the acceptance of data packets. Dynamic ingress buffering enables the sending of pause frames at different thresholds based on the number of ports that experience congestion at a time.
The internal Priority assigned for the packet by Ingress FP is used by the memory management unit (MMU) to assign the packet to right queue by indexing the internal-priority to queue map table (TABLE 1) in hardware. PRIO2COS setting for honoring the PFC protocol packets from the Peer switches is as per above PacketDot1p->queue table (Table 2). The packets come in with packet-dot1p 2 alone are assign to PG6 on ingress.
Dot1p Priority : 0 Queue : 0 4. 1 0 2 0 3 1 4 2 5 3 6 3 7 3 Default dot1p-queue mapping is, Dell#show qos dot1p-queue-mapping Dot1p Priority : 0 1 2 3 4 5 Queue : 2 0 1 3 4 5 6 6 7 7 Interface Configurations on server connected ports. a. Enable DCB globally. Dell(conf)#dcb enable b. Apply PFC Priority configuration. Configure priorities on which PFC is enabled.
Creating an ETS Priority Group An ETS priority group specifies the range of 802.1p priority traffic to which a QoS output policy with ETS settings is applied on an egress interface. 1. Configure a DCB Map. CONFIGURATION mode dcb-map dcb-map-name The dcb-map-name variable can have a maximum of 32 characters. 2. Create an ETS priority group. CONFIGURATION mode priority-group group-num {bandwidth bandwidth | strict-priority} pfc off The range for priority group is from 0 to 7.
Dell Networking OS Behavior: A priority group consists of 802.1p priority values that are grouped for similar bandwidth allocation and scheduling, and that share latency and loss requirements. All 802.1p priorities mapped to the same queue must be in the same priority group. Configure all 802.1p priorities in priority groups associated with an ETS output policy. You can assign each dot1p priority to only one priority group. By default, all 802.
To create a QoS output policy that allocates different amounts of bandwidth to the different traffic types/ dot1p priorities assigned to a queue and apply the output policy to the interface, follow these steps. 1. Create a QoS output policy. CONFIGURATION mode Dell(conf)#qos-policy-output test12 The maximum 32 alphanumeric characters. 2. Configure the percentage of bandwidth to allocate to the dot1p priority/queue traffic in the associated L2 class map.
• Use the ETS configuration associated with 802.1p priority traffic in a DCB map in DCBx negotiation with ETS peers. • Traffic in priority groups is assigned to strict-queue or weighted round-robin (WRR) scheduling in an ETS configuration and is managed using the ETS bandwidth-assignment algorithm. Dell Networking OS de-queues all frames of strict-priority traffic before servicing any other queues. A queue with strict-priority traffic can starve other queues in the same port.
Priority-Group Configuration Notes When you configure priority groups in a DCB map: • A priority group consists of 802.1p priority values that are grouped together for similar bandwidth allocation and scheduling, and that share the same latency and loss requirements. All 802.1p priorities mapped to the same queue must be in the same priority group. • In a DCB map, each 802.1p priority must map to a priority group.
Using ETS to Manage Converged Ethernet Traffic To use ETS for managing converged Ethernet traffic, use the following command: dcb-map stack-unit all dcb-map-name Applying DCB Policies in a Switch Stack You can apply DCB policies with PFC and ETS configurations to all stacked ports in a switch stack or on a stacked switch. To apply DCB policies in a switch stack, follow this step. • Apply the specified DCB policy on all ports of the switch stack or a single stacked switch.
DCBx Port Roles To enable the auto-configuration of DCBx-enabled ports and propagate DCB configurations learned from peer DCBx devices internally to other switch ports, use the following DCBx port roles. Auto-upstream The port advertises its own configuration to DCBx peers and is willing to receive peer configuration. The port also propagates its configuration to other ports on the switch. The first auto-upstream that is capable of receiving a peer configuration is elected as the configuration source.
Configuration source The port is configured to serve as a source of configuration information on the switch. Peer DCB configurations received on the port are propagated to other DCBx auto-configured ports. If the peer configuration is compatible with a port configuration, DCBx is enabled on the port. On a configuration-source port, the link with a DCBx peer is enabled when the port receives a DCB configuration that can be internally propagated to other autoconfigured ports.
Asymmetric DCB parameters are exchanged between a DCBx-enabled port and a peer port without requiring that a peer port and the local port use the same configured values for the configurations to be compatible. For example, ETS uses an asymmetric exchange of parameters between DCBx peers. Symmetric DCB parameters are exchanged between a DCBx-enabled port and a peer port but requires that each configured parameter value be the same for the configurations in order to be compatible.
Auto-Detection and Manual Configuration of the DCBx Version When operating in Auto-Detection mode (the DCBx version auto command), a DCBx port automatically detects the DCBx version on a peer port. Legacy CIN and CEE versions are supported in addition to the standard IEEE version 2.5 DCBx. A DCBx port detects a peer version after receiving a valid frame for that version.
Figure 35. DCBx Sample Topology DCBx Prerequisites and Restrictions The following prerequisites and restrictions apply when you configure DCBx operation on a port: • For DCBx, on a port interface, enable LLDP in both Send (TX) and Receive (RX) mode (the protocol lldp mode command; refer to the example in CONFIGURATION versus INTERFACE Configurations in the Link Layer Discovery Protocol (LLDP) chapter). If multiple DCBx peer ports are detected on a local DCBx interface, LLDP is shut down.
[no] protocol lldp 3. Configure the DCBx version used on the interface, where: auto configures the port to operate using the DCBx version received from a peer. PROTOCOL LLDP mode [no] DCBx version {auto | cee | cin | ieee-v2.5} • cee: configures the port to use CEE (Intel 1.01). • cin: configures the port to use Cisco-Intel-Nuova (DCBx 1.0). • ieee-v2.5: configures the port to use IEEE 802.1Qaz (Draft 2.5). The default is Auto. 4.
• fcoe: enables the advertisement of FCoE in Application Priority TLVs. • iscsi: enables the advertisement of iSCSI in Application Priority TLVs. The default is Application Priority TLVs are enabled to advertise FCoE and iSCSI. NOTE: To disable TLV transmission, use the no form of the command; for example, no advertise DCBx-appln-tlv iscsi. For information about how to use iSCSI, refer to iSCSI Optimization To verify the DCBx configuration on a port, use the show interface DCBx detail command.
NOTE: You can configure the transmission of more than one TLV type at a time. You can only enable ETS recommend TLVs (ets-reco) if you enable ETS configuration TLVs (ets-conf). To disable TLV transmission, use the no form of the command; for example, no advertise DCBx-tlv pfc ets-reco. The default is All TLV types are enabled. 5. Configure the Application Priority TLVs that advertise on unconfigured interfaces with a manual portrole.
in a DCBx TLV from a remote peer but received a different, conflicting DCBx version. DSM_DCBx_PFC_PARAMETERS_MATCH and DSM_DCBx_PFC_PARAMETERS_MISMATCH: A local DCBx port received a compatible (match) or incompatible (mismatch) PFC configuration from a peer. DSM_DCBx_ETS_PARAMETERS_MATCH and DSM_DCBx_ETS_PARAMETERS_MISMATCH: A local DCBx port received a compatible (match) or incompatible (mismatch) ETS configuration from a peer.
Command Output show interface port-type slot/port pfc {summary | detail} Displays the PFC configuration applied to ingress traffic on an interface, including priorities and link delay. To clear PFC TLV counters, use the clear pfc counters interface port-type slot/port command. show interface port-type slot/port pfc statistics Displays counters for the PFC frames received and transmitted (by dot1p priority class) on an interface.
Priorities:0 1 2 5 6 7 PG:1 TSA:ETS BW:50 Priorities:3 4 PFC:ON The following example shows the show interfaces pfc summary command.
Fields Description is on, PFC advertisements are enabled to be sent and received from peers; received PFC configuration takes effect. The admin operational status for a DCBx exchange of PFC configuration is enabled or disabled. Remote is enabled; Priority list Remote Willing Status is enabled Operational status (enabled or disabled) of peer device for DCBx exchange of PFC configuration with a list of the configured PFC priorities.
Fields Description Application Priority TLV: Local ISCSI Priority Map Priority bitmap used by local DCBx port in ISCSI advertisements in application priority TLVs. Application Priority TLV: Remote FCOE Priority Map Status of FCoE advertisements in application priority TLVs from remote peer port: enabled or disabled. Application Priority TLV: Remote ISCSI Priority Map Status of iSCSI advertisements in application priority TLVs from remote peer port: enabled or disabled.
Remote Parameters : ------------------Remote is disabled Local Parameters : -----------------Local is enabled TC-grp Priority# Bandwidth TSA -----------------------------------------------0 1 0,1,2 100% ETS 2 3 0 % SP 3 4,5,6,7 0 % SP 4 5 6 7 Oper status is init ETS DCBx Oper status is Down State Machine Type is Asymmetric Conf TLV Tx Status is enabled Reco TLV Tx Status is enabled 0 Input Conf TLV Pkts, 1955 Output Conf TLV Pkts, 0 Error Conf TLV Pkts 0 Input Reco TLV Pkts, 1955 Output Reco TLV Pkts, 0 Err
4 0% ETS 5 0% ETS 6 0% ETS 7 0% ETS Priority# Bandwidth TSA 0 13% ETS 1 13% ETS 2 13% ETS 3 13% ETS 4 12% ETS 5 12% ETS 6 12% ETS 7 12% ETS Oper status is init Conf TLV Tx Status is disabled Traffic Class TLV Tx Status is disabled 0 Input Conf TLV Pkts, 0 Output Conf TLV Pkts, 0 Error Conf TLV Pkts 0T LIVnput Traffic Class TLV Pkts, 0 Output Traffic Class TLV Pkts, 0 Error Traffic Class Pkts The following example shows the show interface ets detail command.
5 6 7 0% 0% 0% Priority# Bandwidth 0 13% 1 13% 2 13% 3 13% 4 12% 5 12% 6 12% 7 12% Oper status is init Conf TLV Tx Status is disabled Traffic Class TLV Tx Status is disabled 0 Input Conf TLV Pkts, 0 Output Conf TLV 0 Input Traffic Class TLV Pkts, 0 Output Traffic Class TLV Pkts ETS ETS ETS TSA ETS ETS ETS ETS ETS ETS ETS ETS Pkts, 0 Error Conf TLV Pkts Traffic Class TLV Pkts, 0 Error The following table describes the show interface ets detail command fields. Table 19.
Field Description • Internally propagated: ETS configuration parameters were received from configuration source. ETS DCBx Oper status Operational status of ETS configuration on local port: match or mismatch. State Machine Type Type of state machine used for DCBx exchanges of ETS parameters: • • Feature: for legacy DCBx versions Asymmetric: for an IEEE version Conf TLV Tx Status Status of ETS Configuration TLV advertisements: enabled or disabled.
5 6 7 8 - - Stack unit 1 stack port all Max Supported TC Groups is 4 Number of Traffic Classes is 1 Admin mode is on Admin Parameters: -------------------Admin is enabled TC-grp Priority# Bandwidth TSA -----------------------------------------------0 0,1,2,3,4,5,6,7 100% ETS 1 2 3 4 5 6 7 8 Dell(conf)# show stack-unit all stack-ports all ets details Stack unit 1 stack port all Max Supported TC Groups is 4 Number of Traffic Classes is 1 Admin mode is on Admin Parameters: -------------------Admin is enable
The following example shows the show interface DCBx detail command (IEEE).
DCBx Operational Version is 0 DCBx Max Version Supported is 0 Sequence Number: 1 Acknowledgment Number: 1 Total DCBx Frames transmitted 994 Total DCBx Frames received 646 Total DCBx Frame errors 0 Total DCBx Frames unrecognized 0 The following table describes the show interface DCBx detail command fields. Table 20. show interface DCBx detail Command Description Field Description Interface Interface type with chassis slot and port number.
Field Description Peer DCBx Status: DCBx Max Version Supported Highest DCBx version supported in Control TLVs received from peer device. Peer DCBx Status: Sequence Number Sequence number transmitted in Control TLVs received from peer device. Peer DCBx Status: Acknowledgment Number Acknowledgement number transmitted in Control TLVs received from peer device. Total DCBx Frames transmitted Number of DCBx frames sent from local port.
dot1p Value in the Incoming Frame Egress Queue Assignment 2 0 3 1 4 2 5 3 6 3 7 3 dot1p Value in the Incoming Frame Egress Queue Assignment 0 2 1 0 2 1 3 3 4 4 5 5 6 6 7 7 Configuring the Dynamic Buffer Method Priority-based flow control using dynamic buffer spaces is supported on the platform. To configure the dynamic buffer capability, perform the following steps: 1. Enable the DCB application.
CONFIGURATION mode dcb enable pfc-queues pfc-queues The number of ports supported based on lossless queues configured will depend on the buffer. The default number of PFC queues in the system is two for S4810 and Z9500, and one for S6000 platforms. For each priority, you can specify the shared buffer threshold limit, the ingress buffer size, buffer limit for pausing the acceptance of packets, and the buffer offset limit for resuming the acceptance of received packets. 4.
Figure 36. PFC and ETS Applied to LAN, IPC, and SAN Priority Traffic QoS Traffic Classification: The service-class dynamic dot1p command has been used in Global Configuration mode to map ingress dot1p frames to the queues shown in the following table. For more information, refer to QoS dot1p Traffic Classification and Queue Assignment.
dot1p Value in the Incoming Frame Priority Group Assignment 3 SAN 4 IPC 5 LAN 6 LAN 7 LAN The following describes the priority group-bandwidth assignment. Priority Group Bandwidth Assignment IPC 5% SAN 50% LAN 45% PFC and ETS Configuration Command Examples The following examples show PFC and ETS configuration commands to manage your data center traffic. 1. Enabling DCB Dell(conf)#dcb enable 2.
Dynamic Host Configuration Protocol (DHCP) 14 DHCP is an application layer protocol that dynamically assigns IP addresses and other configuration parameters to network end-stations (hosts) based on configuration policies determined by network administrators.
Option Number and Description Subnet Mask Option 1 Specifies the client’s subnet mask. Router Option 3 Specifies the router IP addresses that may serve as the client’s default gateway. Domain Name Server Option 6 Domain Name Option 15 Specifies the domain name servers (DNSs) that are available to the client. Specifies the domain name that clients should use when resolving hostnames via DNS.
Option Number and Description Identifiers a user-defined string used by the Relay Agent to forward DHCP client packets to a specific server. L2 DHCP Snooping Option 82 User Port Stacking Option 230 Specifies IP addresses for DHCP messages received from the client that are to be monitored to build a DHCP snooping database. Set the stacking option variable to provide DHCP server stack-port detail when the DHCP offer is set. End Option 255 Signals the last option in the DHCP packet.
DHCPNAK A server sends this message to the client if it is not able to fulfill a DHCPREQUEST; for example, if the requested address is already in use. In this case, the client starts the configuration process over by sending a DHCPDISCOVER. Figure 38. Client and Server Messaging Implementation Information The following describes DHCP implementation. • Dell Networking implements DHCP based on RFC 2131 and RFC 3046.
Configure the System to be a DHCP Server A DHCP server is a network device that has been programmed to provide network configuration parameters to clients upon request. Servers typically serve many clients, making host management much more organized and efficient. The following table lists the key responsibilities of DHCP servers. Table 21. DHCP Server Responsibilities DHCP Server Responsibility Description Address Storage and Management DHCP servers are the owners of the addresses used by DHCP clients.
DHCP mode network network/prefix-length • network: the subnet address. • prefix-length: specifies the number of bits used for the network portion of the address you specify. The prefix-length range is from 17 to 31. 4. Display the current pool configuration. DHCP mode show config After an IP address is leased to a client, only that client may release the address. Dell Networking OS performs a IP + MAC source address validation to ensure that no client can release another clients address.
The default is 24 hours. Specifying a Default Gateway The IP address of the default router should be on the same subnet as the client. To specify a default gateway, follow this step. • Specify default gateway(s) for the clients on the subnet, in order of preference. DHCP default-router address Configure a Method of Hostname Resolution Dell systems are capable of providing DHCP clients with parameters for two methods of hostname resolution—using DNS or NetBIOS WINS.
useful when you want to guarantee that a particular network device receives a particular IP address. Manual bindings can be considered single-host address pools. There is no limit on the number of manual bindings, but you can only configure one manual binding per host. NOTE: Dell Networking OS does not prevent you from using a network IP as a host IP; be sure to not use a network IP as a host IP. 1. Create an address pool. DHCP mode pool name 2. Specify the client IP address. DHCP host address 3.
shown in the following illustration. Specify multiple DHCP servers by using the ip helper-address dhcp-address command multiple times. When you configure the ip helper-address command, the system listens for DHCP broadcast messages on port 67. The system rewrites packets received from the client and forwards them via unicast to the DHCP servers; the system rewrites the destination IP address and writes its own address as the relay device.
To view the ip helper-address configuration for an interface, use the show ip interface command from EXEC privilege mode. Example of the show ip interface Command R1_E600#show ip int tengigabitethernet 1/3 TenGigabitEthernet 1/3 is up, line protocol is down Internet address is 10.11.0.1/24 Broadcast address is 10.11.0.255 Address determined by user input IP MTU is 1500 bytes Helper address is 192.168.0.1 192.168.0.
Configuring the DHCP Client System This section describes how to configure and view an interface as a DHCP client to receive an IP address. Dell Networking OS Behavior: The ip address dhcp command enables DHCP server-assigned dynamic addresses on an interface. The setting persists after a switch reboot. To stop DHCP transactions and save the dynamically acquired IP address, use the shutdown command on the interface.
ip address dhcp Dynamically assigned IP addresses can be released without removing the DHCP client operation on the interface on a switch configured as a DHCP client. 3. Manually acquire a new IP address from the DHCP server by releasing a dynamically acquired IP address while retaining the DHCP client configuration on the interface. EXEC Privilege mode release dhcp interface type slot/port[/subport] 4. Acquire a new IP address with renewed lease time from a DHCP server.
NOTE: Management routes added by the DHCP client include the specific routes to reach a DHCP server in a different subnet and the management route. DHCP Client Operation with Other Features The DHCP client operates with other Dell Networking OS features, as the following describes. Stacking The DHCP client daemon runs only on the master unit and handles all DHCP packet transactions. It periodically synchronizes the lease file with the standby unit.
Configure the System for User Port Stacking (Option 230) Set the stacking-option variable to provide stack-port detail on the DHCP server when you set the DHCP offer. A stack can be formed when the units are connected. Option 230 is the option for user port stacking. Use it to create up to eight stack groups. Define the configuration parameters on the DHCP server for each chassis based on the chassis MAC address.
To insert Option 82 into DHCP packets, follow this step. • Insert Option 82 into DHCP packets. CONFIGURATION mode ip dhcp relay information-option [trust-downstream] • For routers between the relay agent and the DHCP server, enter the trust-downstream option. Manually reset the remote ID for Option 82. CONFIGURATION mode ip dhcp relay information-option remote-id DHCP Snooping DHCP snooping protects networks from spoofing. In the context of DHCP snooping, ports are either trusted or not trusted.
Enabling DHCP Snooping To enable DHCP snooping, use the following commands. 1. Enable DHCP snooping globally. CONFIGURATION mode ip dhcp snooping 2. Specify ports connected to DHCP servers as trusted. INTERFACE mode INTERFACE PORT EXTENDER mode ip dhcp snooping trust 3. Enable DHCP snooping on a VLAN. CONFIGURATION mode ip dhcp snooping vlan name Enabling IPv6 DHCP Snooping To enable IPv6 DHCP snooping, use the following commands. 1. Enable IPv6 DHCP snooping globally.
ipv6 dhcp snooping binding mac address vlan-id vlan-id ipv6 ipv6-address interface interface-type | interface-number lease value Clearing the Binding Table To clear the binding table, use the following command. • Delete all of the entries in the binding table. EXEC Privilege mode clear ip dhcp snooping binding Clearing the DHCP IPv6 Binding Table To clear the DHCP IPv6 binding table, use the following command. • Delete all of the entries in the binding table.
Displaying the Contents of the DHCPv6 Binding Table To display the contents of the DHCP IPv6 binding table, use the following command. • Display the contents of the binding table. EXEC Privilege mode show ipv6 dhcp snooping biniding Example of the show ipv6 dhcp snooping binding Command View the DHCP snooping statistics with the show ipv6 dhcp snooping command.
10.1.1.251 10.1.1.252 10.1.1.253 10.1.1.254 00:00:4d:57:f2:50 00:00:4d:57:e6:f6 00:00:4d:57:f8:e8 00:00:4d:69:e8:f2 172800 172800 172740 172740 D D D D Vl Vl Vl Vl 10 10 10 10 Te Te Te Te 1/2 1/1 1/3 1/5 Total number of Entries in the table : 4 Dynamic ARP Inspection Dynamic address resolution protocol (ARP) inspection prevents ARP spoofing by forwarding only ARP frames that have been validated against the DHCP binding table. ARP is a stateless protocol that provides no authentication mechanism.
NOTE: Dynamic ARP inspection (DAI) uses entries in the L2SysFlow CAM region, a sub-region of SystemFlow. One CAM entry is required for every DAI-enabled VLAN. You can enable DAI on up to 16 VLANs on a system. However, the ExaScale default CAM profile allocates only nine entries to the L2SysFlow region for DAI. You can configure 10 to 16 DAI-enabled VLANs by allocating more CAM space to the L2SysFlow region before enabling DAI. SystemFlow has 102 entries by default.
Invalid ARP Replies Dell# : 0 Bypassing the ARP Inspection You can configure a port to skip ARP inspection by defining the interface as trusted, which is useful in multi-switch environments. ARPs received on trusted ports bypass validation against the binding table. All ports are untrusted by default. To bypass the ARP inspection, use the following command. • Specify an interface as trusted so that ARPs are not validated against the binding table.
To enable IP source address validation, use the following command. NOTE: If you enable IP source guard using the ip dhcp source-address-validation command and if there are more entries in the current DHCP snooping binding table than the available CAM space, SAV may not be applied to all entries. To ensure that SAV is applied correctly to all entries, enable the ip dhcp source-address-validation command before adding entries to the binding table. • Enable IP source address validation.
4. Do one of the following. • Enable IP+MAC SAV. INTERFACE mode ip dhcp source-address-validation ipmac • Enable IP+MAC SAV with VLAN option. INTERFACE mode ip dhcp source-address-validation ipmac vlan vlan-id Dell Networking OS creates an ACL entry for each IP+MAC address pair and optionally with its VLAN ID in the binding table and applies it to the interface.
Equal Cost Multi-Path (ECMP) 15 This chapter describes configuring ECMP. ECMP for Flow-Based Affinity Flow-based affinity includes the following: • Link Bundle Monitoring Configuring the Hash Algorithm TeraScale has one algorithm that is used for link aggregation groups (LAGs), ECMP, and NH-ECMP, and ExaScale can use three different algorithms for each of these features. To adjust the ExaScale behavior to match TeraScale, use the following command.
Configuring the Hash Algorithm Seed Deterministic ECMP sorts ECMPs in order even though RTM provides them in a random order. However, the hash algorithm uses as a seed the lower 12 bits of the chassis MAC, which yields a different hash result for every chassis. This behavior means that for a given flow, even though the prefixes are sorted, two unrelated chassis can select different hops.
For link bundle monitoring with ECMP, to enable the link bundle monitoring feature, use the ecmpgroup command. In the following example, the ecmp-group with id 2, enabled for link bundle monitoring is user configured. This is different from the ecmp-group index 2 that is created by configuring routes and is automatically generated. These two ecmp-groups are not related in any way.
The range is from 1 to 64. 2. Add interfaces to the ECMP group bundle. CONFIGURATION ECMP-GROUP mode interface interface interface tengigabitethernet 1/1 interface port-channel 100 3. Enable monitoring for the bundle. CONFIGURATION ECMP-GROUP mode link-bundle-monitor enable Modifying the ECMP Group Threshold You can customize the threshold percentage for monitoring ECMP group bundles. To customize the ECMP group bundle threshold and to view the changes, use the following commands.
FCoE Transit 16 The Fibre Channel over Ethernet (FCoE) Transit feature is supported on Ethernet interfaces. When you enable the switch for FCoE transit, the switch functions as a FIP snooping bridge. NOTE: FIP snooping is not supported on Fibre Channel interfaces or in a S4048–ON switch stack.
requirement for point-to-point connections by creating a unique virtual link for each connection between an FCoE end-device and an FCF via a transit switch. FIP provides functionality for discovering and logging into an FCF. After discovering and logging in, FIP allows FCoE traffic to be sent and received between FCoE end-devices (ENodes) and the FCF. FIP uses its own EtherType and frame format. The following illustration shows the communication that occurs between an ENode server and an FCoE switch (FCF).
Figure 40. FIP Discovery and Login Between an ENode and an FCF FIP Snooping on Ethernet Bridges In a converged Ethernet network, intermediate Ethernet bridges can snoop on FIP packets during the login process on an FCF. Then, using ACLs, a transit bridge can permit only authorized FCoE traffic to be transmitted between an FCoE end-device and an FCF. An Ethernet bridge that provides these functions is called a FIP snooping bridge (FSB).
FCoE-generated ACLs These take precedence over user-configured ACLs. A user-configured ACL entry cannot deny FCoE and FIP snooping frames. The following illustration shows a switch used as a FIP snooping bridge in a converged Ethernet network. The top-of-rack (ToR) switch operates as an FCF for FCoE traffic. Converged LAN and SAN traffic is transmitted between the ToR switch and an S4048–ON switch.
• Perform FIP snooping (allowing and parsing FIP frames) globally on all VLANs or on a per-VLAN basis. • To assign a MAC address to an FCoE end-device (server ENode or storage device) after a server successfully logs in, set the FCoE MAC address prefix (FC-MAP) value an FCF uses. The FC-MAP value is used in the ACLs installed in bridge-to-bridge links on the switch.
• configure each FIP snooping port to operate in Hybrid mode so that it accepts both tagged and untagged VLAN frames (use the portmode hybrid command). • configure tagged VLAN membership on each FIP snooping port that sends and receives FCoE traffic and has links with an FCF, ENode server, or another FIP snooping bridge (use the tagged port-type slot/port command). The default VLAN membership of the port must continue to operate with untagged frames.
nlbclusteracl: 0 st-sjc-s5000-29# Enabling the FCoE Transit Feature The following sections describe how to enable FCoE transit. NOTE: FCoE transit is disabled by default. To enable this feature, you must follow the Configure FIP Snooping. As soon as you enable the FCoE transit feature on a switch-bridge, existing VLAN-specific and FIP snooping configurations are applied.
FCoE traffic is allowed on the port only after the switch learns the FC-MAP value associated with the specified FCF MAC address and verifies that it matches the configured FC-MAP value for the FCoE VLAN. Configure a Port for a Bridge-to-FCF Link If a port is directly connected to an FCF, configure the port mode as FCF. Initially, all FCoE traffic is blocked; only FIP frames are allowed to pass.
Configuring FIP Snooping You can enable FIP snooping globally on all FCoE VLANs on a switch or on an individual FCoE VLAN. By default, FIP snooping is disabled. To enable FCoE transit on the switch and configure the FCoE transit parameters on ports, follow these steps. 1. Configure FCoE. FCoE configuration: copy flash:/ CONFIG_TEMPLATE/ FCoE_DCB_Config running-config The configuration files are stored in the flash memory in the CONFIG_TEMPLATE file.
Command Output interface and MAC address, the FCF interface and MAC address, VLAN ID, FCoE MAC address and FCoE session ID number (FC-ID), worldwide node name (WWNN) and the worldwide port name (WWPN). show fip-snooping config Displays the FIP snooping status and configured FC-MAP values. show fip-snooping enode [enode-macaddress] Displays information on the ENodes in FIPsnooped sessions, including the ENode interface and MAC address, FCF MAC address, VLAN ID and FC-ID.
0e:fc:00:01:00:04 01:00:04 41:00:0e:fc:00:00:00:02 21:00:0e:fc:00:00:00:00 0e:fc:00:01:00:05 01:00:05 41:00:0e:fc:00:00:00:03 21:00:0e:fc:00:00:00:00 The following table describes the show fip-snooping sessions command fields. Table 26. show fip-snooping sessions Command Description Field Description ENode MAC MAC address of the ENode . ENode Interface Slot/port number of the interface connected to the ENode. FCF MAC MAC address of the FCF.
Field Description FC-ID Fibre Channel session ID assigned by the FCF. The following example shows the show fip-snooping fcf command. Dell# show fip-snooping fcf FCF MAC FCF Interface VLAN FC-MAP FKA_ADV_PERIOD No. of Enodes ------------------- ---- ------------------- ------------54:7f:ee:37:34:40 Po 22 100 0e:fc:00 4000 2 The following table describes the show fip-snooping fcf command fields. Table 28. show fip-snooping fcf Command Description Field Description FCF MAC MAC address of the FCF.
Dell# show fip-snooping statistics int tengigabitethernet 1/11 Number of Vlan Requests :1 Number of Vlan Notifications :0 Number of Multicast Discovery Solicits :1 Number of Unicast Discovery Solicits :0 Number of FLOGI :1 Number of FDISC :16 Number of FLOGO :0 Number of Enode Keep Alive :4416 Number of VN Port Keep Alive :3136 Number of Multicast Discovery Advertisement :0 Number of Unicast Discovery Advertisement :0 Number of FLOGI Accepts :0 Number of FLOGI Rejects :0 Number of FDISC Accepts :0 Number of
Field Description Number of Unicast Discovery Solicits Number of FIP-snooped unicast discovery solicit frames received on the interface. Number of FLOGI Number of FIP-snooped FLOGI request frames received on the interface. Number of FDISC Number of FIP-snooped FDISC request frames received on the interface. Number of FLOGO Number of FIP-snooped FLOGO frames received on the interface. Number of ENode Keep Alives Number of FIP-snooped ENode keep-alive frames received on the interface.
FCFs Enodes Sessions : 1 : 2 : 17 The following example shows the show fip-snooping vlan command. Dell# show fip-snooping vlan * = Default VLAN VLAN ---*1 100 FC-MAP -----0X0EFC00 FCFs ---1 Enodes -----2 Sessions -------17 FCoE Transit Configuration Example The following illustration shows a switch used as a FIP snooping bridge for FCoE traffic between an ENode (server blade) and an FCF (ToR switch). The ToR switch operates as an FCF and FCoE gateway. Figure 42.
The following example shows how to configure FIP snooping on FCoE VLAN 10, on an FCF-facing port (1/5), on an ENode server-facing port (1/1), and to configure the FIP snooping ports as tagged members of the FCoE VLAN enabled for FIP snooping.
FIPS Cryptography 17 This chapter describes how to enable FIPS cryptography requirements on Dell Networking platforms. This feature provides cryptographic algorithms conforming to various FIPS standards published by the National Institute of Standards and Technology (NIST), a non-regulatory agency of the US Department of Commerce. FIPS mode is also validated for numerous platforms to meet the FIPS-140-2 standard for a software-based cryptographic module.
Enabling FIPS Mode To enable or disable FIPS mode, use the console port. Secure the host attached to the console port against unauthorized access. Any attempts to enable or disable FIPS mode from a virtual terminal session are denied. When you enable FIPS mode, the following actions are taken: • If enabled, the SSH server is disabled. • All open SSH and Telnet sessions, as well as all SCP and FTP file transfers, are closed.
Monitoring FIPS Mode Status To view the status of the current FIPS mode (enabled/disabled), use the following commands. • Use either command to view the status of the current FIPS mode. show fips status show system Examples of the show fips status and show system Commands The following example shows the show fips status command. Dell#show fips status FIPS Mode : Enabled for the system using the show system command. The following example shows the show system command.
• To disable FIPS mode from a console port. CONFIGURATION mode no fips mode enable The following Warning message displays: WARNING: Disabling FIPS mode will close all SSH/Telnet connections, restart those servers, and destroy all configured host keys.
18 Force10 Resilient Ring Protocol (FRRP) FRRP provides fast network convergence to Layer 2 switches interconnected in a ring topology, such as a metropolitan area network (MAN) or large campuses. FRRP is similar to what can be achieved with the spanning tree protocol (STP), though even with optimizations, STP can take up to 50 seconds to converge (depending on the size of network and node of failure) may require 4 to 5 seconds to reconverge.
The Member VLAN is the VLAN used to transmit data as described earlier. The Control VLAN is used to perform the health checks on the ring. The Control VLAN can always pass through all ports in the ring, including the secondary port of the Master node. Ring Status The ring failure notification and the ring status checks provide two ways to ensure the ring remains up and active in the event of a switch or port failure.
Multiple FRRP Rings Up to 255 rings are allowed per system and multiple rings can be run on one system. More than the recommended number of rings may cause interface instability. You can configure multiple rings with a single switch connection; a single ring can have multiple FRRP groups; multiple rings can be connected with a common link. The platform supports up to 32 rings on a system (including stacked units).
Concept Explanation Control VLAN Each ring has a unique Control VLAN through which tagged ring health frames (RHF) are sent. Control VLANs are used only for sending RHF, and cannot be used for any other purpose. Member VLAN Each ring maintains a list of member VLANs. Member VLANs must be consistent across the entire ring. Port Role Each node has two ports for each ring: Primary and Secondary. The Master node Primary port generates RHFs. The Master node Secondary port receives the RHFs.
Concept Explanation There is no periodic transmission of TCRHFs. The TCRHFs are sent on triggered events of ring failure or ring restoration only. Implementing FRRP • FRRP is media and speed independent. • FRRP is a Dell proprietary protocol that does not interoperate with any other vendor. • You must disable the spanning tree protocol (STP) on both the Primary and Secondary interfaces before you can enable FRRP. • All ring ports must be Layer 2 ports.
Configuring the Control VLAN Control and member VLANS are configured normally for Layer 2. Their status as control or member is determined at the FRRP group commands. For more information about configuring VLANS in Layer 2 mode, refer to Layer 2. Be sure to follow these guidelines: • All VLANS must be in Layer 2 mode. • You can only add ring nodes to the VLAN. • A control VLAN can belong to one FRRP group only. • Tag control VLAN ports.
Slot/Port[/subport], Range: Slot and Port ID for the interface. Range is entered Slot/Port[/ subport]-Slot/Port[/subport]. VLAN ID: The VLAN identification of the control VLAN. 4. Configure the Master node. CONFIG-FRRP mode. mode master 5. Identify the Member VLANs for this FRRP group. CONFIG-FRRP mode. member-vlan vlan-id {range} VLAN-ID, Range: VLAN IDs for the ring’s member VLANS. 6. Enable FRRP. CONFIG-FRRP mode.
• For a 40-Gigabit Ethernet interface, enter the keyword fortyGigE then the slot/port information. Assign the Primary and Secondary ports and the Control VLAN for the ports on the ring. 3. CONFIG-FRRP mode. interface primary interface slot/port[/subport] secondary interface slot/ port[/subport] control-vlan vlan id Interface: • For a 10-Gigabit Ethernet interface, enter the keyword TenGigabitEthernet then the slot/ port[/subport] information.
EXEC PRIVELEGED mode. clear frrp ring-id • Ring ID: the range is from 1 to 255. Clear the counters associated with all FRRP groups. EXEC PRIVELEGED mode. clear frrp Viewing the FRRP Configuration To view the configuration for the FRRP group, use the following command. • Show the configuration for this FRRP group. CONFIG-FRRP mode. show configuration Viewing the FRRP Information To view general FRRP information, use one of the following commands. • Show the information for the identified FRRP group.
Sample Configuration and Topology The following example shows a basic FRRP topology.
Example of R3 TRANSIT interface TenGigabitEthernet 3/14 no ip address switchport no shutdown ! interface TenGigabitEthernet 3/21 no ip address switchport no shutdown ! interface Vlan 101 no ip address tagged TenGigabitEthernet 3/14,21 no shutdown ! interface Vlan 201 no ip address tagged TenGigabitEthernet 3/14,21 no shutdown ! protocol frrp 101 interface primary TenGigabitEthernet 3/21 secondary TenGigabitEthernet 3/14 control-vlan 101 member-vlan 201 mode transit no disable Force10 Resilient Ring Protoco
19 GARP VLAN Registration Protocol (GVRP) GARP VLAN registration protocol (GVRP) is supported on Dell Networking OS. Typical virtual local area network (VLAN) implementation involves manually configuring each Layer 2 switch that participates in a given VLAN. GVRP, defined by the IEEE 802.1q specification, is a Layer 2 network protocol that provides for automatic VLAN configuration of switches. GVRP-compliant switches use GARP to register and de-register attribute values, such as VLAN IDs, with each other.
Configure GVRP To begin, enable GVRP. To facilitate GVRP communications, enable GVRP globally on each switch. Then, GVRP configuration is per interface on a switch-by-switch basis. Enable GVRP on each port that connects to a switch where you want GVRP information exchanged. In the following example, that type of port is referred to as a VLAN trunk port, but it is not necessary to specifically identify to the Dell Networking OS that the port is a trunk port. Figure 43.
Enabling GVRP Globally To configure GVRP globally, use the following command. • Enable GVRP for the entire switch. CONFIGURATION mode gvrp enable Example of Configuring GVRP Dell(conf)#protocol gvrp Dell(config-gvrp)#no disable Dell(config-gvrp)#show config ! protocol gvrp no disable Dell(config-gvrp)# To inspect the global configuration, use the show gvrp brief command. Enabling GVRP on a Layer 2 Interface To enable GVRP on a Layer 2 interface, use the following command.
not be unconfigured when it receives a Leave PDU. Therefore, the registration mode on that interface is FIXED. • Forbidden Mode — Disables the port to dynamically register VLANs and to propagate VLAN information except information about VLAN 1. A port with forbidden registration type thus allows only VLAN 1 to pass through even though the PDU carries information for more VLANs.
LeaveAll Timer Dell(conf)# 5000 Dell Networking OS displays this message if an attempt is made to configure an invalid GARP timer: Dell(conf)#garp timers join 300 % Error: Leave timer should be >= 3*Join timer. RPM Redundancy The current version of Dell Networking OS supports 1+1 hitless route processor module (RPM) redundancy. The primary RPM performs all routing, switching, and control operations while the standby RPM monitors the primary RPM.
20 High Availability (HA) High availability (HA) is supported on Dell Networking OS. HA is a collection of features that preserves system continuity by maximizing uptime and minimizing packet loss during system disruptions. To support all the features within the HA collection, you should have the latest boot code. The following table lists the boot code requirements as of this Dell Networking OS release. Table 30. Boot Code Requirements Component Boot Code S4048–ON 1 2.0.
Mgmt ID: Stack-unit ID: Stack-unit Redundancy Role: Stack-unit State: Stack-unit SW Version: Link to Peer: Peer Stack-unit: 0 0 Primary Active 9.6(0.
Proceed with Stack-unit hot failover [confirm yes/no]:yes Dell# Specifying an Auto-Failover Limit When a non-recoverable fatal error is detected, an automatic failover occurs. However, Dell Networking OS is configured to auto-failover only three times within any 60 minute period. You may specify a different auto-failover count. To re-enable the auto-failover-limit with its default parameters, use the redundancy auto-failoverlimit command without parameters. • Set a different auto-failover count.
Removing a Provisioned Logical Stack Unit To remove the line card configuration, use the following command. • To remove a logical stack-unit configuration, use the following command: CONFIGURATION mode no stack-unit unit_id provision Hitless Behavior Hitless behavior is supported only on the platform. Hitless is a protocol-based system behavior that makes a stack unit failover on the local system transparent to remote systems.
Software Resiliency During normal operations, Dell Networking OS monitors the health of both hardware and software components in the background to identify potential failures, even before these failures manifest. Software Component Health Monitoring On each of the line cards and the stack unit, there are a number of software components.
System Log Event messages provide system administrators diagnostics and auditing information. Dell Networking OS sends event messages to the internal buffer, all terminal lines, the console, and optionally to a syslog server. For more information about event messages and configurable options, refer to Management. Hot-Lock Behavior Dell Networking OS hot-lock features allow you to append and delete their corresponding content addressable memory (CAM) entries dynamically without disrupting traffic.
Internet Group Management Protocol (IGMP) 21 Internet group management protocol (IGMP) is supported on Dell Networking OS. Multicast is premised on identifying many hosts by a single destination IP address; hosts represented by the same IP address are a multicast group. IGMP is a Layer 3 multicast protocol that hosts use to join or leave a multicast group.
Figure 44. IGMP Messages in IP Packets Join a Multicast Group There are two ways that a host may join a multicast group: it may respond to a general query from its querier or it may send an unsolicited report to its querier. Responding to an IGMP Query The following describes how a host can join a multicast group. 1. One router on a subnet is elected as the querier. The querier periodically multicasts (to all-multicastsystems address 224.0.0.1) a general query to all hosts on the subnet. 2.
response, the querier removes the group from the list associated with forwarding port and stops forwarding traffic for that group to the subnet. IGMP Version 3 Conceptually, IGMP version 3 behaves the same as version 2. However, there are differences. • Version 3 adds the ability to filter by multicast source, which helps multicast routing protocols avoid forwarding traffic to subnets where there are no interested receivers.
Figure 46. IGMP Version 3–Capable Multicast Routers Address Structure Joining and Filtering Groups and Sources The following illustration shows how multicast routers maintain the group and source information from unsolicited reports. 1. The first unsolicited report from the host indicates that it wants to receive traffic for group 224.1.1.1. 2. The host’s second report indicates that it is only interested in traffic from group 224.1.1.1, source 10.11.1.1.
Figure 47. Membership Reports: Joining and Filtering Leaving and Staying in Groups The following illustration shows how multicast routers track and refresh state changes in response to group-and-specific and general queries. 1. Host 1 sends a message indicating it is leaving group 224.1.1.1 and that the included filter for 10.11.1.1 and 10.11.1.2 are no longer necessary. 2.
Figure 48. Membership Queries: Leaving and Staying Configure IGMP Configuring IGMP is a two-step process. 1. Enable multicast routing using the ip multicast-routing command. 2. Enable a multicast routing protocol.
• Designating a Multicast Router Interface Viewing IGMP Enabled Interfaces Interfaces that are enabled with PIM-SM are automatically enabled with IGMP. To view IGMP-enabled interfaces, use the following command. • View IGMP-enabled interfaces. EXEC Privilege mode show ip igmp interface Example of the show ip igmp interface Command Dell#show ip igmp interface TenGigabitEthernet 3/10 Inbound IGMP access group is not set Internet address is 165.87.34.
IGMP querying router is 1.1.1.1 (this system) IGMP version is 3 Viewing IGMP Groups To view both learned and statically configured IGMP groups, use the following command. • View both learned and statically configured IGMP groups. EXEC Privilege mode show ip igmp groups Example of the show ip igmp groups Command Dell# show ip igmp groups Total Number of Groups: 2 IGMP Connected Group Membership Group Address Interface 225.1.1.1 TenGigabitEthernet 1/1 225.1.2.
INTERFACE mode • ip igmp query-interval Adjust the maximum response time. INTERFACE mode • ip igmp query-max-resp-time Adjust the last member query interval. INTERFACE mode ip igmp last-member-query-interval Preventing a Host from Joining a Group You can prevent a host from joining a particular group by blocking specific IGMP reports. Create an extended access list containing the permissible source-group pairs.
Figure 49. Preventing a Host from Joining a Group The following table lists the location and description shown in the previous illustration. Table 31. Preventing a Host from Joining a Group — Description Location Description 1/21 • • • • Interface TenGigabitEthernet 1/21 ip pim sparse-mode ip address 10.11.12.
Location Description • • ip address 10.11.13.1/24 no shutdown 2/1 • • • • Interface TenGigabitEthernet 2/1 ip pim sparse-mode ip address 10.11.1.1/24 no shutdown 2/11 • • • • Interface TenGigabitEthernet 2/11 ip pim sparse-mode ip address 10.11.12.2/24 no shutdown 2/31 • • • • Interface TenGigabitEthernet 2/31 ip pim sparse-mode ip address 10.11.23.1/24 no shutdown 3/1 • • • • Interface TenGigabitEthernet 3/1 ip pim sparse-mode ip address 10.11.5.
Enabling IGMP Immediate-Leave If the querier does not receive a response to a group-specific or group-and-source query, it sends another (querier robustness value). Then, after no response, it removes the group from the outgoing interface for the subnet. IGMP immediate leave reduces leave latency by enabling a router to immediately delete the group membership on an interface after receiving a Leave message (it does not send any group-specific or group-and-source queries before deleting the entry).
• View the configuration. CONFIGURATION mode • show running-config Disable snooping on a VLAN.
• Configure the switch to only forward unregistered packets to ports on a VLAN that are connected to mrouter ports. CONFIGURATION mode no ip igmp snooping flood Specifying a Port as Connected to a Multicast Router To statically specify or view a port in a VLAN, use the following commands. • Statically specify a port in a VLAN as connected to a multicast router. INTERFACE VLAN mode • ip igmp snooping mrouter View the ports that are connected to multicast routers. EXEC Privilege mode.
ip igmp snooping last-member-query-interval Fast Convergence after MSTP Topology Changes The following describes the fast convergence feature. When a port transitions to the Forwarding state as a result of an STP or MSTP topology change, Dell Networking OS sends a general query out of all ports except the multicast router ports. The host sends a response to the general query and the forwarding database is updated without having to wait for the query interval to expire.
routes. If SSH is specified as a management application, SSH links to and from an unknown destination uses the management default route. Protocol Separation When you configure the application application-type command to configure a set of management applications with TCP/UDP port numbers to the OS, the following table describes the association between applications and their port numbers. Table 32.
can configure two default routes, one configured on the management port and the other on the frontend port. Two tables, namely, Egress Interface Selection routing table and default routing table, are maintained. In the preceding table, the columns Client and Server indicate that the applications can act as both a client and a server within the switch. The Management Egress Interface Selection table contains all management routes (connected, static and default route).
When the feature is disabled using the no management egress-interface-selection command, the following operations are performed: • All management application configuration is removed. • All routes installed in the management EIS routing table are removed. Handling of Management Route Configuration When the EIS feature is enabled, the following processing occurs: • All existing management routes (connected, static and default) are duplicated and added to the management EIS routing table.
the show management application pkt-drop-cntr command. This counter is cleared using clear management application pkt-drop-cntr command. • Packets whose destination TCP/UDP port does not match a configured management application, take the regular route lookup flow in the IP stack. • In the ARP layer, for all ARP packets received through the management interface, a double route lookup is done, one in the default routing table and another in the management EIS routing table.
traffic for such end-user-originated sessions destined to management port ip1 is handled using the EIS route lookup. Handling of Transit Traffic (Traffic Separation) This is forwarded traffic where destination IP is not an IP address configured in the switch. • Packets received on the management port with destination on the front-end port is dropped. • Packets received on the front-end port with destination on the management port is dropped. • A separate drop counter is incremented for this case.
This phenomenon occurs where traffic is transiting the switch. Traffic has not originated from the switch and is not terminating on the switch. • Drop the packets that are received on the front-end data port with destination on the management port. • Drop the packets that received on the management port with destination as the front-end data port. Switch-Destined Traffic This phenomenon occurs where traffic is terminated on the switch.
Protocol Behavior when EIS is Enabled Behavior when EIS is Disabled dns EIS Behavior Default Behavior ftp EIS Behavior Default Behavior ntp EIS Behavior Default Behavior radius EIS Behavior Default Behavior Sflow-collector Default Behavior Snmp (SNMP Mib response and SNMP Traps) EIS Behavior Default Behavior ssh EIS Behavior Default Behavior syslog EIS Behavior Default Behavior tacacs EIS Behavior Default Behavior telnet EIS Behavior Default Behavior tftp EIS Behavior Defau
Default Behavior: Route lookup is done in the default routing table and appropriate egress port is selected.
Designating a Multicast Router Interface To designate an interface as a multicast router interface, use the following command. Dell Networking OS also has the capability of listening in on the incoming IGMP general queries and designate those interfaces as the multicast router interface when the frames have a non-zero IP source address. All IGMP control packets and IP multicast data traffic originating from receivers is forwarded to multicast router interfaces.
Interfaces 22 This chapter describes interface types, both physical and logical, and how to configure them with Dell Networking Operating System (OS). • 10 Gigabit Ethernet / 40 Gigabit Ethernet interfaces are supported on the S4048–ON platform.
Interface Types The following table describes different interface types.
Examples of the show Commands The following example shows the configuration and status information for one interface. Dell#show interfaces tengigabitethernet 1/1 TenGigabitEthernet 1/1 is up, line protocol is up Hardware is Force10Eth, address is 00:01:e8:05:f3:6a Current address is 00:01:e8:05:f3:6a Pluggable media present, XFP type is 10GBASE-LR. Medium is MultiRate, Wavelength is 1310nm XFP receive power reading is -3.7685 Interface index is 67436603 Internet address is 65.113.24.
To determine which physical interfaces are available, use the show running-config command in EXEC mode. This command displays all physical interfaces available on the line cards. Dell#show running Current Configuration ...
encapsulation support Layer 3 traffic. These interfaces can also become part of virtual interfaces such as virtual local area networks (VLANs) or port channels. For more information about VLANs, refer to Bulk Configuration. For more information on port channels, refer to Port Channel Interfaces. Dell Networking OS Behavior: The system uses a single MAC address for all physical interfaces.
• Enable Layer 2 data transmissions through an individual interface. INTERFACE mode switchport Example of a Basic Layer 2 Interface Configuration Dell(conf-if)#show config ! interface Port-channel 1 no ip address switchport no shutdown Dell(conf-if)# Configuring Layer 2 (Interface) Mode To configure an interface in Layer 2 mode, use the following commands. • Enable the interface. INTERFACE mode • no shutdown Place the interface in Layer 2 (switching) mode.
Dell(conf-if)#show config ! interface TenGigabitEthernet 1/2 no ip address switchport no shutdown Dell(conf-if)#ip address 10.10.1.1 /24 % Error: Port is in Layer 2 mode Te 1/2. Dell(conf-if)# To determine the configuration of an interface, use the show config command in INTERFACE mode or the various show interface commands in EXEC mode. Configuring Layer 3 (Interface) Mode To assign an IP address, use the following commands. • Enable the interface.
Egress Interface Selection (EIS) EIS allows you to isolate the management and front-end port domains by preventing switch-initiated traffic routing between the two domains. This feature provides additional security by preventing flooding attacks on front-end ports. The following protocols support EIS: DNS, FTP, NTP, RADIUS, sFlow, SNMP, SSH, Syslog, TACACS, Telnet, and TFTP. This feature does not support sFlow on stacked units.
Management Interfaces The system supports the Management Ethernet interface as well as the standard interface on any port. You can use either method to connect to the system. Configuring Management Interfaces The dedicated Management interface provides management access to the system. You can configure this interface with Dell Networking OS, but the configuration options on this interface are limited.
Link local IPv6 address: fe80::201:e8ff:fea0:bff3/64 Global IPv6 address: 1::1/ Global IPv6 address: 2::1/64 Virtual-IP is not set Virtual-IP IPv6 address is not set MTU 1554 bytes, IP MTU 1500 bytes LineSpeed 1000 Mbit, Mode full duplex ARP type: ARPA, ARP Timeout 04:00:00 Last clearing of "show interface" counters 00:06:14 Queueing strategy: fifo Input 791 packets, 62913 bytes, 775 multicast Received 0 errors, 0 discarded Output 21 packets, 3300 bytes, 20 multicast Output 0 errors, 0 invalid protocol Time
• Enable the interface. INTERFACE mode • no shutdown The interface is the management interface. INTEFACE mode description Example of the show interface and show ip route Commands To display the configuration for a given port, use the show interface command in EXEC Privilege mode, as shown in the following example. To display the routing table, use the show ip route command in EXEC Privilege mode.
A consideration for including VLANs in routing protocols is that you must configure the no shutdown command. (For routing traffic to flow, you must enable the VLAN.) NOTE: You cannot assign an IP address to the default VLAN, which is VLAN 1 (by default). To assign another VLAN ID to the default VLAN, use the default vlan-id vlan-id command. To assign an IP address to an interface, use the following command. • Configure an IP address and mask on the interface.
Many of the same commands found in the physical interface are also found in the Loopback interfaces. Null Interfaces The Null interface is another virtual interface. There is only one Null interface. It is always up, but no traffic is transmitted through this interface. To enter INTERFACE mode of the Null interface, use the following command. • Enter INTERFACE mode of the Null interface.
Port Channel Implementation Dell Networking OS supports static and dynamic port channels. • Static — Port channels that are statically configured. • Dynamic — Port channels that are dynamically configured using the link aggregation control protocol (LACP). For details, refer to Link Aggregation Control Protocol (LACP). There are 128 port-channels with 16 members per channel. As soon as you configure a port channel, Dell Networking OS treats it like a physical interface. For example, IEEE 802.
• Reassigning an Interface to a New Port Channel (optional) • Configuring the Minimum Oper Up Links in a Port Channel (optional) • Adding or Removing a Port Channel from a VLAN (optional) • Assigning an IP Address to a Port Channel (optional) • Deleting or Disabling a Port Channel (optional) • Load Balancing Through Port Channels (optional) Creating a Port Channel You can create up to 512 port channels with up to 16 port members per group on the platform.
To view the interface’s configuration, enter INTERFACE mode for that interface and use the show config command or from EXEC Privilege mode, use the show running-config interface interface command. When an interface is added to a port channel, Dell Networking OS recalculates the hash algorithm. To add a physical interface to a port, use the following commands. 1. Add the interface to a port channel.
Rate info (interval 5 minutes): Input 00.01Mbits/sec, 2 packets/sec Output 81.60Mbits/sec, 133658 packets/sec Time since last interface status change: 04:31:57 Dell> When more than one interface is added to a Layer 2-port channel, Dell Networking OS selects one of the active interfaces in the port channel to be the primary port. The primary port replies to flooding and sends protocol data units (PDUs). An asterisk in the show interfaces port-channel brief command indicates the primary port.
Dell(conf-if-po-4)#show config ! interface Port-channel 4 no ip address channel-member TenGigabitEthernet 1/8 no shutdown Dell(conf-if-po-4)#no chann tengi 1/8 Dell(conf-if-po-4)#int port 3 Dell(conf-if-po-3)#channel tengi 1/8 Dell(conf-if-po-3)#sho conf ! interface Port-channel 3 no ip address channel-member TenGigabitEthernet 1/8 shutdown Dell(conf-if-po-3)# Configuring the Minimum Oper Up Links in a Port Channel You can configure the minimum links in a port channel (LAG) that must be in “oper up” status
EXEC mode Dell(conf)# interface tengigabitethernet 1/1 Dell(conf-if-te-1/1)#switchport Dell(conf-if-te-1/1)# vlan tagged 2-5,100,4010 Dell#show interfaces switchport te 1/1 Codes: U x G i VLT tagged Untagged, T - Tagged Dot1x untagged, X - Dot1x tagged GVRP tagged, M - Trunk, H - VSN tagged Internal untagged, I - Internal tagged, v - VLT untagged, V - Name: TenGigabitEthernet 1/1 802.
Packet based hashing is used to load balance traffic across a port-channel based on the IP Identifier field within the packet. Load balancing uses source and destination packet information to get the greatest advantage of resources by distributing traffic over multiple paths when transferring data to a destination. Dell Networking OS allows you to modify the hashing algorithms used for flows and for fragments.
• Change the default (0) to another algorithm and apply it to ECMP, LAG hashing, or a particular line card. CONFIGURATION mode hash-algorithm | [ecmp{crc16|crc16cc|crc32LSB|crc32MSB|crc-upper|dest-ip |lsb |xor1| xor2| xor4| xor8| xor16}|lag{crc16|crc16cc|crc32LSB|crc32MSB|xor1| xor2|xor4|xor8|xor16}| seed ] • For more information about algorithm choices, refer to the command details in the IP Routing chapter of the Dell Networking OS Command Reference Guide.
Bulk Configuration Bulk configuration allows you to determine if interfaces are present for physical interfaces or configured for logical interfaces. Interface Range An interface range is a set of interfaces to which other commands may be applied and may be created if there is at least one valid interface within the range. Bulk configuration excludes from configuration any non-existing interfaces from an interface range.
Create a Multiple-Range The following is an example of multiple range. Example of the interface range Command (Multiple Ranges) Dell(conf)#interface range tengigabitethernet 1/5 - 1/10 , tengigabitethernet 1/1 , vlan 1 Dell(conf-if-range-te-1/1,te-1/5-1/10,vl-1)# Exclude Duplicate Entries The following is an example showing how duplicate entries are omitted from the interface-range prompt.
Add Ranges The following example shows how to use commas to add VLAN and port-channel interfaces to the range. Example of Adding VLAN and Port-Channel Interface Ranges Dell(config-if-range-te-1/1-2)# interface range Vlan 2 – 100 , Port 1 – 25 Dell(config-if-range-te-1/1-2-so-5/1-vl-2-100-po-1-25)# no shutdown Defining Interface Range Macros You can define an interface-range macro to automatically select a range of interfaces for configuration.
Monitoring and Maintaining Interfaces Monitor interface statistics with the monitor interface command. This command displays an ongoing list of the interface status (up/down), number of packets, traffic statistics, and so on. To view the interface’s statistics, use the following command. • View the interface’s statistics.
Output throttles: m l T q - 0 Change mode Page up Increase refresh interval Quit 0 pps 0 c - Clear screen a - Page down t - Decrease refresh interval q Dell# Maintenance Using TDR The time domain reflectometer (TDR) is supported on all Dell Networking switch/routers. TDR is an assistance tool to resolve link issues that helps detect obvious open or short conditions within any of the four copper pairs. TDR sends a signal onto the physical cable and examines the reflection of the signal that returns.
• 1G optics • QSA If you use any of the cables or adapters in the preceding list that is not Dell-qualified, the Dell Networking OS detects it and makes it operational.
To split a single 40G port into four 10G ports, use the following command. • Split a single 40G port into four 10G ports. CONFIGURATION mode stack-unit stack-unit port number portmode quad – stack-unit: enter the stack member unit identifier of the stack member to reset. The range is from 1 to 6. – number: enter the port number of the 40G port to be split. The range is from 1 to 48 for 10G ports and 49, 50, 51, 52, 53, and 54 for 40G ports.
• When you insert a QSA into a 40 Gigabit port, you can use only the first 10 Gigabit port in the fan-out mode to plug-in SFP or SFP+ cables. The remaining three 10 Gigabit ports are perceived to be in Link Down state and are unusable. • You cannot use QSFP Optical cables on the same port where QSA is used. • When you remove the QSA module alone from a 40 Gigabit port, without connecting any SFP or SFP + cables; Dell Networking OS does not generate any event.
SFP+ 1 Connector ………………………. = 0x23 Dell#show interfaces tengigabitethernet 1/2 transceiver SFP+ 1 Serial ID Base Fields SFP+ 1 Id = 0x0d SFP+ 1 Ext Id = 0x00 SFP+ 1 Connector = 0x23 ………………………. Dell#show interfaces tengigabitethernet 1/3 transceiver SFP+ 1 Serial ID Base Fields SFP+ 1 Id = 0x0d SFP+ 1 Ext Id = 0x00 SFP+ 1 Connector = 0x23 ……………………….
Important Points to Remember • Link dampening is not supported on VLAN interfaces. • Link dampening is disabled when the interface is configured for port monitoring. • You can apply link dampening to Layer 2 and Layer 3 interfaces. • You can configure link dampening on individual interfaces in a LAG. Enabling Link Dampening To enable link dampening, use the following command. • Enable link dampening.
Example of the clear dampening Command Dell# clear dampening interface Te 1/1 Dell# show interfaces dampening TenGigabitEthernet1/1 InterfaceStateFlapsPenaltyHalf-LifeReuseSuppressMax-Sup Te 1/1Up00205001500300 Link Dampening Support for XML View the output of the following show commands in XML by adding | display xml to the end of the command.
• View all LAG link bundles being monitored. show running-config ecmp-group Using Ethernet Pause Frames for Flow Control Ethernet pause frames and threshold settings are supported on the Dell Networking OS. Ethernet Pause Frames allow for a temporary stop in data transmission. A situation may arise where a sending device may transmit data faster than a destination device can accept it. The destination sends a PAUSE frame back to the source, stopping the sender’s transmission for a period of time.
Enabling Pause Frames Enable Ethernet pause frames flow control on all ports on a chassis or a line card. If not, the system may exhibit unpredictable behavior. NOTE: Changes in the flow-control values may not be reflected automatically in the show interface output. As a workaround, apply the new settings, execute shut then no shut on the interface, and then check the running-config of the port. NOTE: If you disable rx flow control, Dell Networking recommends rebooting the system.
Link MTU and IP MTU considerations for port channels and VLANs are as follows. Port Channels: • • All members must have the same link MTU value and the same IP MTU value. The port channel link MTU and IP MTU must be less than or equal to the link MTU and IP MTU values configured on the channel members. For example, if the members have a link MTU of 2100 and an IP MTU 2000, the port channel’s MTU values cannot be higher than 2100 for link MTU or 2000 bytes for IP MTU.
Setting the Speed and Duplex Mode of Ethernet Interfaces To discover whether the remote and local interface requires manual speed synchronization, and to manually synchronize them if necessary, use the following command sequence. 1. Determine the local interface status. Refer to the following example. EXEC Privilege mode show interfaces [interface | stack—unit stack-unit-number] status 2. Determine the remote interface status.
Te 1/4 Force10Port Up Te 1/5 Down Te 1/6 Down Te 1/7 Up Te 1/8 Down Te 1/9 Down Te 1/10 Down Te 1/11 Down Te 1/12 Down [output omitted] 1000 Mbit Auto Auto 1000 Mbit Auto Auto Auto Auto Auto Auto Auto Auto Auto Auto Auto Auto Auto Auto 30-130 --1502,1504,1506-1508,1602 ------ In the previous example, several ports display “Auto” in the Speed field. In the following example, the speed of port 1/1 is set to 100Mb and then its auto-negotiation is disabled.
• Change the default interval between keepalive messages. INTERFACE mode • keepalive [seconds] View the new setting. INTERFACE mode show config View Advanced Interface Information The following options have been implemented for the show [ip | running-config] interfaces commands for (only) stack-unit interfaces. When you use the configured keyword, only interfaces that have non-default configurations are displayed.
Configuring the Interface Sampling Size Although you can enter any value between 30 and 299 seconds (the default), software polling is done once every 15 seconds. So, for example, if you enter “19”, you actually get a sample of the past 15 seconds. All LAG members inherit the rate interval configuration from the LAG. The following example shows how to configure rate interval when changing the default value.
0 64-byte pkts, 0 over 64-byte pkts, 0 over 127-byte pkts 0 over 255-byte pkts, 0 over 511-byte pkts, 0 over 1023-byte pkts Received 0 input symbol errors, 0 runts, 0 giants, 0 throttles 0 CRC, 0 IP Checksum, 0 overrun, 0 discarded 0 packets output, 0 bytes, 0 underruns Output 0 Multicasts, 0 Broadcasts, 0 Unicasts 0 IP Packets, 0 Vlans, 0 MPLS 0 throttles, 0 discarded Rate info (interval 100 seconds): Input 00.00 Mbits/sec, 0 packets/sec, 0.00% of line-rate Output 00.00 Mbits/sec, 0 packets/sec, 0.
– For a Loopback interface, enter the keyword loopback then a number from 0 to 16383. – For the Management interface on the stack-unit, enter the keyword ManagementEthernet then the slot/port information. The slot range is from 1 to 11. The port range is 1. – For a port channel interface, enter the keywords port-channel then a number. – For a VLAN interface, enter the keyword vlan then a number from 1 to 4094. – (OPTIONAL) To clear statistics for all VRRP groups configured, enter the keyword vrrp.
Internet Protocol Security (IPSec) 23 IPSec is an end-to-end security scheme for protecting IP communications by authenticating and encrypting all packets in a communication session. Use IPSec between hosts, between gateways, or between hosts and gateways. IPSec is compatible with Telnet and file transfer protocols (FTPs). It supports two operational modes: Transport and Tunnel. • Transport mode — (default) Use to encrypt only the payload of the packet. Routing information is unchanged.
Configuring IPSec The following sample configuration shows how to configure FTP and telnet for IPSec. 1. Define the transform set. CONFIGURATION mode crypto ipsec transform-set myXform-seta esp-authentication md5 espencryption des 2. Define the crypto policy.
IPv4 Routing 24 The Dell Networking Operating System (OS) supports various IP addressing features. This chapter describes the basics of domain name service (DNS), address resolution protocol (ARP), and routing principles and their implementation in the Dell Networking OS. IP Feature Default DNS Disabled Directed Broadcast Disabled Proxy ARP Enabled ICMP Unreachable Disabled ICMP Redirect Disabled IP Addresses Dell Networking OS supports IP version 4, as described in RFC 791.
Configuration Tasks for IP Addresses The following describes the tasks associated with IP address configuration. Configuration tasks for IP addresses includes: • Assigning IP Addresses to an Interface (mandatory) • Configuring Static Routes (optional) • Configure Static Routes for the Management Interface (optional) For a complete listing of all commands related to IP addressing, refer to the Dell Networking OS Command Line Interface Reference Guide.
Example the show config Command To view the configuration, use the show config command in INTERFACE mode or use the show ip interface command in EXEC privilege mode, as shown in the second example. Dell(conf-if)#show conf ! interface TenGigabitEthernet 1/1 ip address 10.11.1.1/24 no shutdown ! Configuring Static Routes A static route is an IP address that you manually configure and that the routing protocol does not learn, such as open shortest path first (OSPF).
S 6.1.2.6/32 S 6.1.2.7/32 S 6.1.2.8/32 S 6.1.2.9/32 S 6.1.2.10/32 S 6.1.2.11/32 S 6.1.2.12/32 S 6.1.2.13/32 S 6.1.2.14/32 S 6.1.2.15/32 S 6.1.2.16/32 S 6.1.2.17/32 S 11.1.1.0/24 Direct, Lo 0 --More-- via 6.1.20.2, via 6.1.20.2, via 6.1.20.2, via 6.1.20.2, via 6.1.20.2, via 6.1.20.2, via 6.1.20.2, via 6.1.20.2, via 6.1.20.2, via 6.1.20.2, via 6.1.20.2, via 6.1.20.2, Direct, Nu 0 Dell#show ip route static Destination Gateway ----------------S 2.1.2.0/24 Direct, Nu 0 S 6.1.2.0/24 via 6.1.20.2, S 6.1.2.
Direct, Lo 0 --More-Dell Networking OS installs a next hop that is on the directly connected subnet of current IP address on the interface (for example, if interface TenGigabitEthernet 1/1 is on 172.31.5.0 subnet, Dell Networking OS installs the static route). Dell Networking OS also installs a next hop that is not on the directly connected subnet but which recursively resolves to a next hop on the interface's configured subnet. For example, if te 1/1 has ip address on subnet 2.2.2.0 and if 172.31.5.
outgoing packets. When any device along the network path contains an MTU that is smaller than the size of the packet that it receives, the device drops the packet and sends an Internet Control Message Protocol (ICMP) Fragmentation Needed (Type 3, Code 4) message with its MTU value to the source or the sending device. This message enables the source to identify that the transmitted packet size must be reduced. The packet is retransmitted with a lower size than the previous value.
Configuring the Duration to Establish a TCP Connection This functionality is supported on the platform. You can configure the amount of time for which the device must wait before it attempts to establish a TCP connection. Using this capability, you can limit the wait times for TCP connection requests.
Resolution of Host Names Domain name service (DNS) maps host names to IP addresses. This feature simplifies such commands as Telnet and FTP by allowing you to enter a name instead of an IP address. Dynamic resolution of host names is disabled by default. Unless you enable the feature, the system resolves only host names entered into the host table with the ip host command. The following sections describe DNS and the resolution of host names.
Specifying the Local System Domain and a List of Domains If you enter a partial domain, Dell Networking OS can search different domains to finish or fully qualify that partial domain. A fully qualified domain name (FQDN) is any name that is terminated with a period/dot. Dell Networking OS searches the host table first to resolve the partial domain. The host table contains both statically configured and dynamically learnt host and IP addresses.
Dell#traceroute www.force10networks.com Translating "www.force10networks.com"...domain server (10.11.0.1) [OK] Type Ctrl-C to abort. ---------------------------------------------------------------------Tracing the route to www.force10networks.com (10.11.84.18), 30 hops max, 40 byte packets ---------------------------------------------------------------------TTL Hostname Probe1 Probe2 Probe3 1 10.11.199.190 001.000 ms 001.000 ms 002.000 ms 2 gwegress-sjc-02.force10networks.com (10.11.30.126) 005.000 ms 001.
Configuring Static ARP Entries ARP dynamically maps the MAC and IP addresses, and while most network host support dynamic mapping, you can configure an ARP entry (called a static ARP) for the ARP cache. To configure a static ARP entry, use the following command. • Configure an IP address and MAC address mapping for an interface. CONFIGURATION mode arp vrf vrf-name ip-address mac-address interface – vrf vrf-name: use the VRF option to configure a static ARP on that particular VRF.
• Clear the ARP caches for all interfaces or for a specific interface by entering the following information. EXEC privilege clear arp-cache [interface | ip ip-address] [no-refresh] – ip ip-address (OPTIONAL): enter the keyword ip then the IP address of the ARP entry you wish to clear. – no-refresh (OPTIONAL): enter the keywords no-refresh to delete the ARP entry from CAM. Or to specify which dynamic ARP entries you want to delete, use this option with interface or ip ip-address.
arp learn-enable ARP Learning via ARP Request In Dell Networking OS versions prior to 8.3.1.0, Dell Networking OS learns via ARP requests only if the target IP specified in the packet matches the IP address of the receiving router interface. This is the case when a host is attempting to resolve the gateway address. If the target IP does not match the incoming interface, the packet is dropped. If there is an existing entry for the requesting host, it is updated. Figure 50.
Configuring ARP Retries In Dell Networking OS versions prior to 8.3.1.0, the number of ARP retries is set to five and is not configurable. After five retries, Dell Networking OS backs off for 20 seconds before it sends a new request. Beginning with Dell Networking OS version 8.3.1.0, the number of ARP retries is configurable. The default backoff interval remains at 20 seconds. On the device, the time between ARP resend is configurable. This timer is an exponential backoff timer.
Enabling ICMP Unreachable Messages By default, ICMP unreachable messages are disabled. When enabled, ICMP unreachable messages are created and sent out all interfaces. To disable and re-enable ICMP unreachable messages, use the following commands. • To disable ICMP unreachable messages. INTERFACE mode • no ip unreachable Set FTOS to create and send ICMP unreachable messages on the interface.
• Enable UPD helper. ip udp-helper udp-ports Example of Enabling UDP Helper and Using the UDP Helper show Command Dell(conf-if-te-1/1)#ip udp-helper udp-port 1000 Dell(conf-if-te-1/1)#show config ! interface TenGigabitEthernet 1/1 ip address 2.1.1.1/24 ip udp-helper udp-port 1000 no shutdown To view the interfaces and ports on which you enabled UDP helper, use the show ip udp-helper command from EXEC Privilege mode.
Configurations Using UDP Helper When you enable UDP helper and the destination IP address of an incoming packet is a broadcast address, Dell Networking OS suppresses the destination address of the packet. The following sections describe various configurations that employ UDP helper to direct broadcasts.
Figure 52. UDP Helper with Broadcast-All Addresses UDP Helper with Subnet Broadcast Addresses When the destination IP address of an incoming packet matches the subnet broadcast address of any interface, the system changes the address to the configured broadcast address and sends it to matching interface. In the following illustration, Packet 1 has the destination IP address 1.1.1.255, which matches the subnet broadcast address of VLAN 101.
UDP Helper with Configured Broadcast Addresses Incoming packets with a destination IP address matching the configured broadcast address of any interface are forwarded to the matching interfaces. In the following illustration, Packet 1 has a destination IP address that matches the configured broadcast address of VLAN 100 and 101. If you enabled UDP helper and the UDP port number matches, the packet is flooded on both VLANs with an unchanged destination address. Packet 2 is sent from a host on VLAN 101.
When using the IP helper and UDP helper on the same interface, use the debug ip dhcp command. Example Output from the debug ip dhcp Command Packet 0.0.0.0:68 -> 255.255.255.255:67 TTL 128 2005-11-05 11:59:35 %RELAY-I-PACKET, BOOTP REQUEST (Unicast) received at interface 172.21.50.193 BOOTP Request, XID = 0x9265f901, secs = 0 hwaddr = 00:02:2D:8D: 46:DC, giaddr = 0.0.0.0, hops = 2 2005-11-05 11:59:35 %RELAY-I-BOOTREQUEST, Forwarded BOOTREQUEST for 00:02:2D:8D: 46:DC to 137.138.17.
IPv6 Routing 25 Internet protocol version 6 (IPv6) routing is the successor to IPv4. Due to the rapid growth in internet users and IP addresses, IPv4 is reaching its maximum usage. IPv6 will eventually replace IPv4 usage to allow for the constant expansion. This chapter provides a brief description of the differences between IPv4 and IPv6, and the Dell Networking support of IPv6. This chapter is not intended to be a comprehensive description of IPv6.
• Prefix Renumbering — Useful in transparent renumbering of hosts in the network when an organization changes its service provider. NOTE: As an alternative to stateless autoconfiguration, network hosts can obtain their IPv6 addresses using the dynamic host control protocol (DHCP) servers via stateful auto-configuration. NOTE: Dell Networking OS provides the flexibility to add prefixes on Router Advertisements (RA) to advertise responses to Router Solicitations (RS).
IPv6 Header Fields The 40 bytes of the IPv6 header are ordered, as shown in the following illustration. Figure 55. IPv6 Header Fields Version (4 bits) The Version field always contains the number 6, referring to the packet’s IP version. Traffic Class (8 bits) The Traffic Class field deals with any data that needs special handling. These bits define the packet priority and are defined by the packet Source. Sending and forwarding routers use this field to identify different IPv6 classes and priorities.
Value Description 0 Hop-by-Hop option header 4 IPv4 6 TCP 8 Exterior Gateway Protocol (EGP) 41 IPv6 43 Routing header 44 Fragmentation header 50 Encrypted Security 51 Authentication header 59 No Next Header 60 Destinations option header NOTE: This table is not a comprehensive list of Next Header field values. For a complete and current listing, refer to the Internet Assigned Numbers Authority (IANA) web page at .
Extension headers are processed in the order in which they appear in the packet header. Hop-by-Hop Options Header The Hop-by-Hop options header contains information that is examined by every router along the packet’s path. It follows the IPv6 header and is designated by the Next Header value 0 (zero). When a Hop-by-Hop Options header is not included, the router knows that it does not have to process any router specific information and immediately processes the packet to its final destination.
All the addresses in the following list are all valid and equivalent. • 2001:0db8:0000:0000:0000:0000:1428:57ab • 2001:0db8:0000:0000:0000::1428:57ab • 2001:0db8:0:0:0:0:1428:57ab • 2001:0db8:0:0::1428:57ab • 2001:0db8::1428:57ab • 2001:db8::1428:57ab IPv6 networks are written using classless inter-domain routing (CIDR) notation.
Feature and Functionality Dell Networking OS Release Introduction Documentation and Chapter Location S4048–ON Basic IPv6 Commands 9.8.(0.0) IPv6 Basic Commands in the Dell Networking OS Command Line Interface Reference Guide. IPv6 address types: Unicast 9.7.(0.1) Extended Address Space IPv6 neighbor discovery 9.7.(0.1) IPv6 Neighbor Discovery IPv6 stateless autoconfiguration 9.7.(0.1) Stateless Autoconfiguration IPv6 MTU path discovery 9.7.(0.1) Path MTU Discovery IPv6 ICMPv6 9.7.(0.
Feature and Functionality Dell Networking OS Release Introduction Documentation and Chapter Location S4048–ON IS-IS for IPv6 support for redistribution 9.7.(0.1) Intermediate System to Intermediate System IPv6 IS-IS in the Dell Networking OS Command Line Reference Guide. ISIS for IPv6 support for distribute lists and administrative distance 9.7.(0.1) OSPF for IPv6 (OSPFv3) 9.7.(0.1) Equal Cost Multipath for IPv6 9.7.(0.
Feature and Functionality Dell Networking OS Release Introduction Documentation and Chapter Location S4048–ON IPv6 Access Control Lists 9.7.(0.1) IPv6 Access Control Lists in the Dell Networking OS Command Line Reference Guide. 9.7.(0.1) IPv6 PIM in the Dell Networking OS Command Line Reference Guide. IPv6 Multicast MLDv1/v2 ICMPv6 ICMP for IPv6 combines the roles of ICMP, IGMP and ARP in IPv4.
Figure 56. Path MTU Discovery Process IPv6 Neighbor Discovery NDP is a top-level protocol for neighbor discovery on an IPv6 network. In lieu of address resolution protocol (ARP), NDP uses “Neighbor Solicitation” and “Neighbor Advertisement” ICMPv6 messages for determining relationships between neighboring nodes. Using these messages, an IPv6 device learns the link-layer addresses for neighbors known to reside on attached links, quickly purging cached values that become invalid.
Figure 57. NDP Router Redirect IPv6 Neighbor Discovery of MTU Packets You can set the MTU advertised through the RA packets to incoming routers, without altering the actual MTU setting on the interface. The ipv6 nd mtu command sets the value advertised to routers. It does not set the actual MTU rate. For example, if you set ipv6 nd mtu to 1280, the interface still passes 1500-byte packets, if that is what is set with the mtu command.
The DNS server address does not allow the following: • link local addresses • loopback addresses • prefix addresses • multicast addresses • invalid host addresses If you specify this information in the IPv6 RDNSS configuration, a DNS error is displayed. Example for Configuring an IPv6 Recursive DNS Server The following example configures a RDNNS server with an IPv6 address of 1000::1 and a lifetime of 1 second.
Displaying IPv6 RDNSS Information To display IPv6 interface information, including IPv6 RDNSS information, use the show ipv6 interface command in EXEC or EXEC Privilege mode. Examples of Displaying IPv6 RDNSS Information The following example displays IPv6 RDNSS information. The output in the last 3 lines indicates that the IPv6 RDNSS was correctly configured on interface te 1/1.
For SSH configuration details, refer to the Security chapter in the Dell Networking OS Command Line Interface Reference Guide. Configuration Tasks for IPv6 The following are configuration tasks for the IPv6 protocol.
• Provides information on FP groups allocated for the egress acl. CONFIGURATION mode show cam-acl-egress Allocate at least one group for L2ACL and IPv4 ACL. The total number of groups is 4. Assigning an IPv6 Address to an Interface Essentially, IPv6 is enabled in Dell Networking OS simply by assigning IPv6 addresses to individual router interfaces. You can use IPv6 and IPv4 together on a system, but be sure to differentiate that usage carefully.
– For a 10-Gigabit Ethernet interface, enter the keyword TenGigabitEthernet then the slot/port[/ subport] information. – For a 40-Gigabit Ethernet interface, enter the keyword fortyGigE then the slot/port information. – For a Loopback interface, enter the keyword loopback then a number from 0 to 16383. – For a port channel interface, enter the keywords port-channel then a number. – For a Null interface, enter the keyword null then the Null interface number.
Example of show ipv6 Command Options Dell#show ipv6 ? accounting IPv6 accounting information cam IPv6 CAM Entries fib IPv6 FIB Entries interface IPv6 interface information mbgproutes MBGP routing table mld MLD information mroute IPv6 multicast-routing table neighbors IPv6 neighbor information ospf OSPF information pim PIM V6 information prefix-list List IPv6 prefix lists route IPv6 routing information rpf RPF table Dell# Showing an IPv6 Interface To view the IPv6 configuration for a specific interface, use
ff02::1:ff8b:386e ND MTU is 0 ICMP redirects are not sent DAD is enabled, number of DAD attempts: 3 ND reachable time is 32000 milliseconds ND base reachable time is 30000 milliseconds ND retransmit interval is 1000 milliseconds ND hop limit is 64 Showing IPv6 Routes To view the global IPv6 routing information, use the following command. • Show IPv6 routing information for the specified route type.
----------------------------------------------------C 600::/64 [0/0] Direct, Te 1/24, 00:34:42 C 601::/64 [0/0] Direct, Te 1/24, 00:34:18 C 912::/64 [0/0] Direct, Lo 2, 00:02:33 O IA 999::1/128 [110/2] via fe80::201:e8ff:fe8b:3166, Te 1/24, 00:01:30 L fe80::/10 [0/0] Direct, Nu 0, 00:34:42 Dell# The following example shows the show ipv6 route static command.
– ipv6 address: the format is x:x:x:x::x. – mask: the prefix length is from 0 to 128. NOTE: IPv6 addresses are normally written as eight groups of four hexadecimal digits, where each group is separated by a colon (:). Omitting zeros is accepted as described in Addressing. Configuring IPv6 RA Guard The IPv6 Router Advertisement (RA) guard allows you to block or reject the unwanted router advertisement guard messages that arrive at the network device platform.
POLICY LIST CONFIGURATION mode other-config-flag {on | off} 9. Enable verification of the advertised default router preference value. The preference value must be less than or equal to the specified limit. POLICY LIST CONFIGURATION mode router-preference maximum {high | low | medium} 10. Set the router lifetime. POLICY LIST CONFIGURATION mode router—lifetime value The router lifetime range is from 0 to 9,000 seconds. 11. Apply the policy to trusted ports. POLICY LIST CONFIGURATION mode trusted-port 12.
reachable-time 540 retrans-timer 101 router-preference maximum medium trusted-port Dell(conf-ra_guard_policy_list)# IPv6 Routing 501
iSCSI Optimization 26 iSCSI optimization is supported on Dell Networking OS. This chapter describes how to configure internet small computer system interface (iSCSI) optimization, which enables quality-of-service (QoS) treatment for iSCSI traffic.
• If you configure flow-control, iSCSI uses the current configuration. If you do not configure flowcontrol, iSCSI auto-configures flow control settings so that receive-only is enabled and transmit-only is disabled. . • iSCSI monitoring sessions — the switch monitors and tracks active iSCSI sessions in connections on the switch, including port information and iSCSI session information. • iSCSI QoS — A user-configured iSCSI class of service (CoS) profile is applied to all iSCSI traffic.
Monitoring iSCSI Traffic Flows The switch snoops iSCSI session-establishment and termination packets by installing classifier rules that trap iSCSI protocol packets to the CPU for examination. Devices that initiate iSCSI sessions usually use well-known TCP ports 3260 or 860 to contact targets. When you enable iSCSI optimization, by default the switch identifies IP packets to or from these ports as iSCSI traffic.
If more than 256 simultaneous sessions are logged continuously, the following message displays indicating the queue rate limit has been reached: %STKUNIT2-M:CP %iSCSI-5-ISCSI_OPT_MAX_SESS_EXCEEDED: New iSCSI Session Ignored: ISID 400001370000 InitiatorName - iqn.1991-05.com.microsoft:dt-brcd-cna-2 TargetName iqn.2001-05.com.equallogic:4-52aed6-b90d9446c-162466364804fa49-wj-v1 TSIH - 0" NOTE: If you are using EqualLogic or Compellent storage arrays, more than 256 simultaneous iSCSI sessions are possible.
Configuring Detection and Ports for Dell Compellent Arrays To configure a port connected to a Dell Compellent storage array, use the following command. • Configure a port connected to a Dell Compellent storage array. INTERFACE Configuration mode iscsi profile-compellent The command configures a port for the best iSCSI traffic conditions.
iSCSI optimization, which can turn on flow control again on reboot, use the no iscsi enable command and save the configuration. When you enable iSCSI on the switch, the following actions occur: • Link-level flow control is globally enabled, if it is not already enabled, and PFC is disabled. • iSCSI session snooping is enabled. • iSCSI LLDP monitoring starts to automatically detect EqualLogic arrays.
Parameter Default Value but can be removed as any other configured target. iSCSI session monitoring Disabled. The CAM allocation for iSCSI is set to zero (0). iSCSI Optimization Prerequisites The following are iSCSI optimization prerequisites. • iSCSI optimization requires LLDP on the switch. LLDP is enabled by default (refer to Link Layer Discovery Protocol (LLDP)). • iSCSI optimization requires configuring two ingress ACL groups The ACL groups are allocated after iSCSI Optimization is configured.
EXEC Privilege mode write memory 5. Reload the switch. EXEC Privilege mode reload After the switch is reloaded, DCB/ DCBx and iSCSI monitoring are enabled. 6. (Optional) Configure the iSCSI target ports and optionally the IP addresses on which iSCSI communication is monitored. CONFIGURATION mode [no] iscsi target port tcp-port-1 [tcp-port-2...tcp-port-16] [ip-address address] • tcp-port-n is the TCP port number or a list of TCP port numbers on which the iSCSI target listens to requests.
8. (Optional) Set the aging time for iSCSI session monitoring. CONFIGURATION mode [no] iscsi aging time time. The range is from 5 to 43,200 minutes. The default is 10 minutes. 9. (Optional) Configures DCBX to send iSCSI TLV advertisements. LLDP CONFIGURATION mode or INTERFACE LLDP CONFIGURATION mode [no] advertise dcbx-app-tlv iscsi. You can send iSCSI TLVs either globally or on a specified interface. The interface configuration takes priority over global configuration. The default is Enabled. 10.
Maximum number of connections is 256 -----------------------------------------------iSCSI Targets and TCP Ports: -----------------------------------------------TCP Port Target IP Address 3260 860 The following example shows the show iscsi session command. VLT PEER1 Dell#show iscsi session Session 0: ---------------------------------------------------------------------------------Target: iqn.2001-05.com.equallogic:0-8a0906-0e70c2002-10a0018426a48c94-iom010 Initiator: iqn.1991-05.com.
Intermediate System to Intermediate System 27 Intermediate system to intermediate system (Is-IS) is supported on Dell Networking OS. • • • • IS-IS is supported on the S4048–ON with Dell Networking Operating System (OS) 9.7(0.1) The IS-IS protocol is an interior gateway protocol (IGP) that uses a shortest-path-first algorithm. Dell Networking supports both IPv4 and IPv6 versions of IS-IS. The IS-IS protocol standards are listed in the Standards Compliance chapter.
The NET length is variable, with a maximum of 20 bytes and a minimum of 8 bytes. It is composed of the following: • • • area address — within your routing domain or area, each area must have a unique area value. The first byte is called the authority and format indicator (AFI). system address — the router’s MAC address. N-selector — this is always 0. The following illustration is an example of the ISO-style address to show the address format IS-IS uses. In this example, the first five bytes (47.0005.
topological restrictions of the single-topology mode remain in effect). Transition mode stops after all routers in the area or domain have been upgraded to support multi-topology IPv6. After all routers in the area or domain are operating in multi-topology IPv6 mode, the topological restrictions of singletopology mode are no longer in effect.
• The T1 timer specifies the wait time before unacknowledged restart requests are generated. This is the interval before the system sends a Restart Request (an IIH with the RR bit set in Restart TLV) until the complete sequence number PDU (CSNP) is received from the helping router. You can set the duration to a specific amount of time (seconds) or a number of attempts. • The T2 timer is the maximum time that the system waits for LSP database synchronization.
IS-IS Parameter Default Value IS-IS interface metric 10 Metric style Narrow Designated Router priority 64 Circuit Type Level 1 and Level 2 IS Type Level 1 and Level 2 Equal Cost Multi Paths 16 Configuration Information To use IS-IS, you must configure and enable IS-IS in two or three modes: CONFIGURATION ROUTER ISIS, CONFIGURATION INTERFACE, and ( when configuring for IPv6) ADDRESS-FAMILY mode.
In IS-IS, neighbors form adjacencies only when they are same IS type. For example, a Level 1 router never forms an adjacency with a Level 2 router. A Level 1-2 router forms Level 1 adjacencies with a neighboring Level 1 router and forms Level 2 adjacencies with a neighboring Level 2 router. NOTE: Even though you enable IS-IS globally, enable the IS-IS process on an interface for the IS-IS process to exchange protocol information and form adjacencies. To configure IS-IS globally, use the following commands.
• mask: The prefix length is from 0 to 128. The IPv6 address must be on the same subnet as other IS-IS neighbors, but the IP address does not need to relate to the NET address. 6. Enable IS-IS on the IPv4 interface. ROUTER ISIS mode ip router isis [tag] If you configure a tag variable, it must be the same as the tag variable assigned in step 1. 7. Enable IS-IS on the IPv6 interface.
IS-IS: IS-IS: IS-IS: IS-IS: IS-IS: IS-IS: Dell# Level-1 DR Elections : 2 Level-2 DR Elections : 2 Level-1 SPF Calculations : 29 Level-2 SPF Calculations : 29 LSP checksum errors received : 0 LSP authentication failures : 0 You can assign more NET addresses, but the System ID portion of the NET address must remain the same. Dell Networking OS supports up to six area addresses. Some address considerations are: • In order to be neighbors, configure Level 1 routers with at least one common area address.
Configuring IS-IS Graceful Restart To enable IS-IS graceful restart globally, use the following commands. Additionally, you can implement optional commands to enable the graceful restart settings. • Enable graceful restart on ISIS processes. ROUTER-ISIS mode • graceful-restart ietf Configure the time during which the graceful restart attempt is prevented. ROUTER-ISIS mode graceful-restart interval minutes The range is from 1 to 120 minutes. • The default is 5 minutes.
– adjacency: the restarting router receives the remaining time value from its peer and adjusts its T3 value so if user has configured this option. – manual: allows you to specify a fixed value that the restarting router should use. The range is from 50 to 120 seconds. The default is 30 seconds. Examples of the show isis Commands NOTE: If this timer expires before the synchronization has completed, the restarting router sends the overload bit in the LSP.
Hello Interval: 10, Hello Multiplier: 3, CSNP Interval: 10 Number of active level-2 adjacencies: 1 Next IS-IS LAN Level-1 Hello in 4 seconds Next IS-IS LAN Level-2 Hello in 6 seconds LSP Interval: 33 Next IS-IS LAN Level-1 Hello in 4 seconds Next IS-IS LAN Level-2 Hello in 6 seconds LSP Interval: 33 Restart Capable Neighbors: 2, In Start: 0, In Restart: 0 Dell# Changing LSP Attributes IS-IS routers flood link state PDUs (LSPs) to exchange routing information.
router isis lsp-refresh-interval 902 net 47.0005.0001.000C.000A.4321.00 net 51.0005.0001.000C.000A.4321.00 Dell# Configuring the IS-IS Metric Style All IS-IS links or interfaces are associated with a cost that is used in the shortest path first (SPF) calculations. The possible cost varies depending on the metric style supported. If you configure narrow, transition, or narrow transition metric style, the cost can be a number between 0 and 63.
Example of Viewing IS-IS Metric Types Dell#show isis protocol IS-IS Router: System Id: EEEE.EEEE.EEEE IS-Type: level-1-2 Manual area address(es): 47.0004.004d.0001 Routing for area address(es): 21.2223.2425.2627.2829.3031.3233 47.0004.004d.
Metric Sytle Correct Value Range wide transition 0 to 16777215 narrow transition 0 to 63 transition 0 to 63 To view the interface’s current metric, use the show config command in INTERFACE mode or the show isis interface command in EXEC Privilege mode. Configuring the Distance of a Route To configure the distance for a route, use the following command. • Configure the distance for a route. ROUTER ISIS mode distance Changing the IS-Type To change the IS-type, use the following commands.
B233.00-00 eljefe.00-00 * eljefe.01-00 * eljefe.02-00 * Force10.00-00 0x00000006 0x0000000D 0x00000001 0x00000001 0x00000004 0xC38A 0x51C6 0x68DF 0x2E7F 0xCDA9 1124 1129 1122 1113 1107 0/0/0 0/0/0 0/0/0 0/0/0 0/0/0 Dell# Controlling Routing Updates To control the source of IS-IS route information, use the following command. • Disable a specific interface from sending or receiving IS-IS routing information.
distribute-list prefix-list-name out [bgp as-number | connected | ospf process-id | rip | static] You can configure one of the optional parameters: – connected: for directly connected routes. – ospf process-id: for OSPF routes only. – rip: for RIP routes only. – static: for user-configured routes. • – bgp: for BGP routes only. Deny RTM download for pre-existing redistributed IPv4 routes.
Redistributing IPv4 Routes In addition to filtering routes, you can add routes from other routing instances or protocols to the IS-IS process. With the redistribute command syntax, you can include BGP, OSPF, RIP, static, or directly connected routes in the IS-IS process. NOTE: Do not route iBGP routes to IS-IS unless there are route-maps associated with the IS-IS redistribution. To add routes from other routing instances or protocols, use the following commands.
redistribute {bgp as-number | connected | rip | static} [level-1 level-1-2 | level-2] [metric metric-value] [metric-type {external | internal}] [route-map map-name] Configure the following parameters: – level-1, level-1-2, or level-2: assign all redistributed routes to a level. The default is level-2. – metric-value: the range is from 0 to 16777215. The default is 0. – metric-type: choose either external or internal. The default is internal. • – map-name: enter the name of a configured route map.
FTOS supports both DES and HMAC-MD5 authentication methods. This password is inserted in Level 2 LSPs, Complete SNPs, and Partial SNPs. To view the passwords, use the show config command in ROUTER ISIS mode or the show runningconfig isis command in EXEC Privilege mode. To remove a password, use either the no area-password or no domain-password commands in ROUTER ISIS mode.
• View all IS-IS information. EXEC Privilege mode • debug isis View information on all adjacency-related activity (for example, hello packets that are sent and received). EXEC Privilege mode debug isis adj-packets [interface] To view specific information, enter the following optional parameter: • – interface: Enter the type of interface and slot/port information to view IS-IS information on that interface only. View information about IS-IS local update packets.
To disable all debugging, use the undebug all command. IS-IS Metric Styles The following sections provide additional information about the IS-IS metric styles.
Table 38. Metric Value When the Metric Style Changes Beginning Metric Style Final Metric Style Resulting IS-IS Metric Value wide narrow default value (10) if the original value is greater than 63. A message is sent to the console. wide transition truncated value (the truncated value appears in the LSP only). The original isis metric value is displayed in the show config and show running-config commands and is used if you change back to transition metric style.
Beginning Metric Style Final Metric Style Resulting IS-IS Metric Value wide transition narrow transition default value (10) if the original value is greater than 63. A message is sent to the console. wide transition transition truncated value (the truncated value appears in the LSP only). The original isis metric value is displayed in the show config and show running-config commands and is used if you change back to transition metric style.
Level-1 Metric Style Level-2 Metric Style Resulting Metric Value narrow transition wide original value narrow transition narrow original value narrow transition wide transition original value narrow transition transition original value transition wide original value transition narrow original value transition wide transition original value transition narrow transition original value wide transition wide original value wide transition narrow truncated value wide transition n
Figure 60. IPv6 IS-IS Sample Topography IS-IS Sample Configuration — Congruent Topology IS-IS Sample Configuration — Multi-topology IS-IS Sample Configuration — Multi-topology Transition The following is a sample configuration for enabling IPv6 IS-IS. Dell(conf-if-te-3/17)#show config ! interface TenGigabitEthernet 3/17 ip address 24.3.1.
router isis net 34.0000.0000.AAAA.00 ! address-family ipv6 unicast multi-topology exit-address-family Dell (conf-router_isis)# Dell (conf-if-te-3/17)#show config ! interface TenGigabitEthernet 3/17 ipv6 address 24:3::1/76 ipv6 router isis no shutdown Dell (conf-if-te-3/17)# Dell (conf-router_isis)#show config ! router isis net 34.0000.0000.AAAA.
28 Link Aggregation Control Protocol (LACP) Link aggregation control protocol (LACP) is supported on Dell Networking OS. Introduction to Dynamic LAGs and LACP A link aggregation group (LAG), referred to as a port channel by Dell Networking OS, can provide both load-sharing and port redundancy across line cards. You can enable LAGs as static or dynamic. The benefits and constraints are basically the same, as described in Port Channel Interfaces in the Interfaces chapter.
• There is a difference between the shutdown and no interface port-channel commands: – The shutdown command on LAG “xyz” disables the LAG and retains the user commands. However, the system does not allow the channel number “xyz” to be statically created. – The no interface port-channel channel-number command deletes the specified LAG, including a dynamically created LAG. This command removes all LACP-specific commands on the member interfaces.
• Configure LACP mode. LACP mode [no] port-channel number mode [active | passive | off] – number: cannot statically contain any links. • The default is LACP active. Configure port priority. LACP mode [no] lacp port-priority priority-value The range is from 1 to 65535 (the higher the number, the lower the priority). The default is 32768. LACP Configuration Tasks The following are LACP configuration tasks.
Configuring the LAG Interfaces as Dynamic After creating a LAG, configure the dynamic LAG interfaces. To configure the dynamic LAG interfaces, use the following command. • Configure the dynamic LAG interfaces. CONFIGURATION mode port-channel-protocol lacp Example of the port-channel-protocol lacp Command Dell(conf)#interface Gigabitethernet 3/15 Dell(conf-if-gi-3/15)#no shutdown Dell(conf-if-gi-3/15)#port-channel-protocol lacp Dell(conf-if-gi-3/15-lacp)#port-channel 32 mode active ...
Dell(conf-if-po-32)#switchport Dell(conf-if-po-32)#lacp long-timeout Dell(conf-if-po-32)#end Dell# show lacp 32 Port-channel 32 admin up, oper up, mode lacp Actor System ID: Priority 32768, Address 0001.e800.a12b Partner System ID: Priority 32768, Address 0001.e801.
Figure 61. Shared LAG State Tracking To avoid packet loss, redirect traffic through the next lowest-cost link (R3 to R4). Dell Networking OS has the ability to bring LAG 2 down if LAG 1 fails, so that traffic can be redirected. This redirection is what is meant by shared LAG state tracking. To achieve this functionality, you must group LAG 1 and LAG 2 into a single entity, called a failover group. Configuring Shared LAG State Tracking To configure shared LAG state tracking, you configure a failover group.
As shown in the following illustration, LAGs 1 and 2 are members of a failover group. LAG 1 fails and LAG 2 is brought down after the failure. This effect is logged by Message 1, in which a console message declares both LAGs down at the same time. Figure 62.
• • If a LAG that is part of a failover group is deleted, the failover group is deleted. If a LAG moves to the Down state due to this feature, its members may still be in the Up state. LACP Basic Configuration Example The screenshots in this section are based on the following example topology. Two routers are named ALPHA and BRAVO, and their hostname prompts reflect those names. Figure 63. LACP Basic Configuration Example Configure a LAG on ALPHA The following example creates a LAG on ALPHA.
Last clearing of "show interface" counters 00:02:11 Queueing strategy: fifo Input statistics: 132 packets, 163668 bytes 0 Vlans 0 64-byte pkts, 12 over 64-byte pkts, 120 over 127-byte pkts 0 over 255-byte pkts, 0 over 511-byte pkts, 0 over 1023-byte pkts 132 Multicasts, 0 Broadcasts 0 runts, 0 giants, 0 throttles 0 CRC, 0 overrun, 0 discarded Output Statistics 136 packets, 16718 bytes, 0 underruns 0 64-byte pkts, 15 over 64-byte pkts, 121 over 127-byte pkts 0 over 255-byte pkts, 0 over 511-byte pkts, 0 over
Figure 65.
Figure 66.
interface GigabitEthernet 2/31 no ip address Summary of the LAG Configuration on Bravo Bravo(conf-if-gi-3/21)#int port-channel 10 Bravo(conf-if-po-10)#no ip add Bravo(conf-if-po-10)#switch Bravo(conf-if-po-10)#no shut Bravo(conf-if-po-10)#show config ! interface Port-channel 10 no ip address switchport no shutdown ! Bravo(conf-if-po-10)#exit Bravo(conf)#int gig 3/21 Bravo(conf)#no ip address Bravo(conf)#no switchport Bravo(conf)#shutdown Bravo(conf-if-gi-3/21)#port-channel-protocol lacp Bravo(conf-if-gi-3/2
Figure 67.
Figure 68.
Figure 69. Inspecting the LAG Status Using the show lacp command The point-to-point protocol (PPP) is a connection-oriented protocol that enables layer two links over various different physical layer connections. It is supported on both synchronous and asynchronous lines, and can operate in Half-Duplex or Full-Duplex mode. It was designed to carry IP traffic but is general enough to allow any type of network layer datagram to be sent over a PPP connection.
Layer 2 29 Layer 2 features are supported on Dell Networking OS. Manage the MAC Address Table Dell Networking OS provides the following management activities for the MAC address table. • Clearing the MAC Address Table • Setting the Aging Time for Dynamic Entries • Configuring a Static MAC Address • Displaying the MAC Address Table Clearing the MAC Address Table You may clear the MAC address table of dynamic entries. To clear a MAC address table, use the following command.
The range is from 10 to 1000000. Configuring a Static MAC Address A static entry is one that is not subject to aging. Enter static entries manually. To create a static MAC address entry, use the following command. • Create a static MAC address entry in the MAC address table. CONFIGURATION mode mac-address-table static Displaying the MAC Address Table To display the MAC address table, use the following command. • Display the contents of the MAC address table.
interface) before the system verifies that sufficient CAM space exists. If the CAM check fails, a message is displayed: %E90MH:5 %ACL_AGENT-2-ACL_AGENT_LIST_ERROR: Unable to apply access-list MacLimit on TenGigabitEthernet 4/24 In this case, the configuration is still present in the running-config and show output. Remove the configuration before re-applying a MAC learning limit with a lower value. Also, ensure that you can view the Syslog messages on your session.
mac learning-limit mac-address-sticky Using sticky MAC addresses allows you to associate a specific port with MAC addresses from trusted devices. If you enable sticky MAC, the specified port retains any dynamically-learned addresses and prevents them from being transferred or learned on other ports. If you configure mac-learning-limit and you enabled sticky MAC, all dynamically-learned addresses are converted to sticky MAC addresses for the selected port.
switchport mac learning-limit 1 dynamic no-station-move mac learning-limit station-move-violation log no shutdown Learning Limit Violation Actions To configure the system to take an action when the MAC learning limit is reached on an interface and a new address is received using one the following options with the mac learning-limit command, use the following commands. • Generate a system log message when the MAC learning limit is exceeded.
Recovering from Learning Limit and Station Move Violations After a learning-limit or station-move violation shuts down an interface, you must manually reset it. To reset the learning limit, use the following commands. NOTE: Alternatively, you can reset the interface by shutting it down using the shutdown command and then re-enabling it using the no shutdown command. • Reset interfaces in the ERR_Disabled state caused by a learning limit violation or station move violation.
When you use NIC teaming, consider that the server MAC address is originally learned on Port 0/1 of the switch (shown in the following) and Port 0/5 is the failover port. When the NIC fails, the system automatically sends an ARP request for the gateway or host NIC to resolve the ARP and refresh the egress interface. When the ARP is resolved, the same MAC address is learned on the same port where the ARP is resolved (in the previous example, this location is Port 0/5 of the switch).
Apply all other configurations to each interface in the redundant pair such that their configurations are identical, so that transition to the backup interface in the event of a failure is transparent to rest of the network. Figure 72. Configuring Redundant Layer 2 Pairs without Spanning Tree You configure a redundant pair by assigning a backup interface to a primary interface with the switchport backup interface command.
LACP) port-channel interface as either the primary or backup link in a redundant pair with a physical interface. To ensure that existing network applications see no difference when a primary interface in a redundant pair transitions to the backup interface, be sure to apply identical configurations of other traffic parameters to each interface.
inactive: Vl 1 00:24:55: %RPM0-P:CP %IFMGR-5-OSTATE_UP: Changed interface state to up: Te 3/42 00:24:55: %RPM0-P:CP %IFMGR-5-ACTIVE: Changed Vlan interface state to active: Vl 1 00:24:55: %RPM0-P:CP %IFMGR-5-STATE_STBY_ACT: Changed interface state from standby to active: Te 3/42 Dell(conf-if-te-3/41)#do show ip int brief | find 3/41 TenGigabitEthernet 3/41 unassigned NO Manual administratively down down TenGigabitEthernet 3/42 unassigned YES Manual up up [output omitted] Example of Configuring Redundant Pai
Figure 73. Configuring Far-End Failure Detection The report consists of several packets in SNAP format that are sent to the nearest known MAC address. In the event of a far-end failure, the device stops receiving frames and, after the specified time interval, assumes that the far-end is not available. The connecting line protocol is brought down so that upper layer protocols can detect the neighbor unavailability faster. FEFD State Changes FEFD has two operational modes, Normal and Aggressive.
4. If the FEFD enabled system is configured to use FEFD in Normal mode and neighboring echoes are not received after three intervals, (you can set each interval can be set between 3 and 300 seconds) the state changes to unknown. 5. If the FEFD system has been set to Aggressive mode and neighboring echoes are not received after three intervals, the state changes to Err-disabled.
To report interval frequency and mode adjustments, use the following commands. 1. Setup two or more connected interfaces for Layer 2 or Layer 3. INTERFACE mode ip address ip address, switchport 2. Enable the necessary ports administratively. INTEFACE mode no shutdown 3. Enable fefd globally. CONFIGURATION mode Example of the show fefd Command To display information about the state of each interface, use the show fefd command in EXEC privilege mode.
To set up and activate two or more connected interfaces, use the following commands. 1. Setup two or more connected interfaces for Layer 2 or Layer 3. INTERFACE mode ip address ip address, switchport 2. Activate the necessary ports administratively. INTERFACE mode no shutdown 3.
Sender state -- Bi-directional Sender info -- Mgmt Mac(00:01:e8:14:89:25), Slot-Port(Te 1/1) Peer info -- Mgmt Mac (00:01:e8:14:89:25), Slot-Port(Te 4/1) Sender hold time -- 3 (second) 2w1d22h : FEFD packet received on interface Te 4/1 Sender state -- Bi-directional Sender info -- Mgmt Mac(00:01:e8:14:89:25), Slot-Port(Te 1/1) Peer info -- Mgmt Mac (00:01:e8:14:89:25), Slot-Port(Te 4/1) Sender hold time -- 3 (second) An RPM Failover In the event that an RPM failover occurs, FEFD becomes operationally down
Link Layer Discovery Protocol (LLDP) 30 The link layer discovery protocol (LLDP) is supported on Dell Networking OS. 802.1AB (LLDP) Overview LLDP — defined by IEEE 802.1AB — is a protocol that enables a local area network (LAN) device to advertise its configuration and receive configuration information from adjacent LLDP-enabled LAN infrastructure devices.
Table 42. Type, Length, Value (TLV) Types Type TLV Description 0 End of LLDPDU Marks the end of an LLDPDU. 1 Chassis ID An administratively assigned name that identifies the LLDP agent. 2 Port ID An administratively assigned name that identifies a port through which TLVs are sent and received. 3 Time to Live An administratively assigned name that identifies a port through which TLVs are sent and received.
Figure 76. Organizationally Specific TLV IEEE Organizationally Specific TLVs Eight TLV types have been defined by the IEEE 802.1 and 802.3 working groups as a basic part of LLDP; the IEEE OUI is 00-80-C2. You can configure the Dell Networking system to advertise any or all of these TLVs. Table 43. Optional TLV Types Type TLV Description 4 Port description A user-defined alphanumeric string that describes the port. Dell Networking OS does not currently support this TLV.
Type TLV Description 127 Protocol Identity Indicates the protocols that the port can process. Dell Networking OS does not currently support this TLV. 127 MAC/PHY Configuration/Status Indicates the capability and current setting of the duplex status and bit rate, and whether the current settings are the result of auto-negotiation. This TLV is not available in the Dell Networking OS implementation of LLDP, but is available and mandatory (non-configurable) in the LLDP-MED implementation.
Regarding connected endpoint devices, LLDP-MED provides network connectivity devices with the ability to: • manage inventory • manage Power over Ethernet (PoE) • identify physical location • identify network policy LLDP-MED is designed for, but not limited to, VoIP endpoints. TIA Organizationally Specific TLVs The Dell Networking system is an LLDP-MED Network Connectivity Device (Device Type 4).
Type SubType TLV Description None or all TLVs must be supported. Dell Networking OS does not currently support these TLVs. 127 5 Inventory — Hardware Revision Indicates the hardware revision of the LLDPMED device. 127 6 Inventory — Firmware Revision Indicates the firmware revision of the LLDPMED device. 127 7 Inventory — Software Revision Indicates the software revision of the LLDPMED device. 127 8 Inventory — Serial Number Indicates the device serial number of the LLDP-MED device.
Figure 77. LLDP-MED Capabilities TLV Table 45. Dell Networking OS LLDP-MED Capabilities Bit Position TLV Dell Networking OS Support 0 LLDP-MED Capabilities Yes 1 Network Policy Yes 2 Location Identification Yes 3 Extended Power via MDI-PSE Yes 4 Extended Power via MDI-PD No 5 Inventory No 6–15 reserved No Table 46.
NOTE: As shown in the following table, signaling is a series of control packets that are exchanged between an endpoint device and a network connectivity device to establish and maintain a connection. These signal packets might require a different network policy than the media packets for which a connection is made. In this case, configure the signaling application. Table 47.
Extended Power via MDI TLV The extended power via MDI TLV enables advanced PoE management between LLDP-MED endpoints and network connectivity devices. Advertise the extended power via MDI on all ports that are connected to an 802.3af powered, LLDP-MED endpoint device. • Power Type — there are two possible power types: power source entity (PSE) or power device (PD). The Dell Networking system is a PSE, which corresponds to a value of 0, based on the TIA-1057 specification.
• Dell Networking systems support up to eight neighbors per interface. • Dell Networking systems support a maximum of 8000 total neighbors per system. If the number of interfaces multiplied by eight exceeds the maximum, the system does not configure more than 8000. • INTERFACE level configurations override all CONFIGURATION level configurations. • LLDP is not hitless. LLDP Compatibility • Spanning tree and force10 ring protocol “blocked” ports allow LLDPDUs. • 802.
Enabling LLDP LLDP is enabled by default. Enable and disable LLDP globally or per interface. If you enable LLDP globally, all UP interfaces send periodic LLDPDUs. To enable LLDP, use the following command. 1. Enter Protocol LLDP mode. CONFIGURATION or INTERFACE mode protocol lldp 2. Enable LLDP. PROTOCOL LLDP mode no disable Disabling and Undoing LLDP To disable or undo LLDP, use the following command. • Disable LLDP globally or for an interface.
3. Enter the disable command. LLDP-MANAGEMENT-INTERFACE mode. To undo an LLDP management port configuration, precede the relevant command with the keyword no. Advertising TLVs You can configure the system to advertise TLVs out of all interfaces or out of specific interfaces. • If you configure the system globally, all interfaces send LLDPDUs with the specified TLVs. • If you configure an interface, only the interface sends LLDPDUs with the specified TLVs.
Figure 80. Configuring LLDP Viewing the LLDP Configuration To view the LLDP configuration, use the following command. • Display the LLDP configuration.
Viewing Information Advertised by Adjacent LLDP Agents To view brief information about adjacent devices or to view all the information that neighbors are advertising, use the following commands. • Display brief information about adjacent devices. • show lldp neighbors Display all of the information that neighbors are advertising.
Configuring LLDPDU Intervals LLDPDUs are transmitted periodically; the default interval is 30 seconds. To configure LLDPDU intervals, use the following command. • Configure a non-default transmit interval.
• Return to the default setting.
advertise dot1-tlv port-protocol-vlan-id port-vlan-id advertise dot3-tlv max-frame-size advertise management-tlv system-capabilities system-description no disable R1(conf-lldp)#multiplier ? <2-10> Multiplier (default=4) R1(conf-lldp)#multiplier 5 R1(conf-lldp)#show config ! protocol lldp advertise dot1-tlv port-protocol-vlan-id port-vlan-id advertise dot3-tlv max-frame-size advertise management-tlv system-capabilities system-description multiplier 5 no disable R1(conf-lldp)#no multiplier R1(conf-lldp)#show
Figure 81. The debug lldp detail Command — LLDPDU Packet Dissection Relevant Management Objects Dell Networking OS supports all IEEE 802.1AB MIB objects. The following tables list the objects associated with: • received and transmitted TLVs • the LLDP configuration on the local agent • IEEE 802.1AB Organizationally Specific TLVs • received and transmitted LLDP-MED TLVs Table 48.
MIB Object Category Basic TLV Selection LLDP Variable LLDP MIB Object Description msgTxInterval lldpMessageTxInterval Transmit Interval value. rxInfoTTL lldpRxInfoTTL Time to live for received TLVs. txInfoTTL lldpTxInfoTTL Time to live for transmitted TLVs. mibBasicTLVsTxEnable lldpPortConfigTLVsTxEnabl e Indicates which management TLVs are enabled for system ports.
Table 49.
TLV Type TLV Name TLV Variable System interface numbering Local subtype interface number OID LLDP MIB Object lldpLocManAddrIfSu btype Remote lldpRemManAddrIfS ubtype Local lldpLocManAddrIfId Remote lldpRemManAddrIfId Local lldpLocManAddrOID Remote lldpRemManAddrOI D Table 50. LLDP 802.
Table 51.
TLV Sub-Type TLV Name TLV Variable System LLDP-MED MIB Object 3 Location Data Format Local lldpXMedLocLocatio nSubtype Remote lldpXMedRemLocati onSubtype Local lldpXMedLocLocatio nInfo Remote lldpXMedRemLocati onInfo Local lldpXMedLocXPoED eviceType Remote lldpXMedRemXPoED eviceType Local lldpXMedLocXPoEPS EPowerSource Location Identifier Location ID Data 4 Extended Power via MDI Power Device Type Power Source lldpXMedLocXPoEP DPowerSource Remote lldpXMedRemXPoEP SEPowerSource lld
Microsoft Network Load Balancing 31 Network load balancing (NLB) is a clustering functionality that is implemented by Microsoft on Windows 2000 Server and Windows Server 2003 operating systems (OSs). NLB uses a distributed methodology or pattern to equally split and balance the network traffic load across a set of servers that are part of the cluster or group.
With NLB, the data frame forwards to all the servers for them to perform load-balancing. NLB Multicast Mode Scenario Consider a sample topology in which you configure four servers, S1 through S4, as a cluster or a farm. This set of servers connects to a Layer 3 switch, which connects to the end-clients. They contain a single multicast MAC address (MAC-Cluster: 03-00-5E-11-11-11).
Enable and Disable VLAN Flooding • The older ARP entries are overwritten whenever newer NLB entries are learned. • All ARP entries, learned after you enable VLAN flooding, are deleted when you disable VLAN flooding, and RP2 triggers an ARP resolution. Disable VLAN flooding with the no ip vlan-flooding command. • When you add a port to the VLAN, the port automatically receives traffic if you enabled VLAN flooding. Old ARP entries are not deleted or updated.
mac-address-table static multicast-mac-address vlan vlan-id output-range interface 594 Microsoft Network Load Balancing
Multicast Source Discovery Protocol (MSDP) 32 Multicast source discovery protocol (MSDP) is supported on Dell Networking OS. Protocol Overview MSDP is a Layer 3 protocol that connects IPv4 protocol-independent multicast-sparse mode (PIM-SM) domains. A domain in the context of MSDP is a contiguous set of routers operating PIM within a common boundary defined by an exterior gateway protocol, such as border gateway protocol (BGP).
Figure 82. Multicast Source Discovery Protocol (MSDP) RPs advertise each (S,G) in its domain in type, length, value (TLV) format. The total number of TLVs contained in the SA is indicated in the “Entry Count” field. SA messages are transmitted every 60 seconds, and immediately when a new source is detected. Figure 83.
Anycast RP Using MSDP, anycast RP provides load sharing and redundancy in PIM-SM networks. Anycast RP allows two or more rendezvous points (RPs) to share the load for source registration and the ability to act as hot backup routers for each other. Anycast RP allows you to configure two or more RPs with the same IP address on Loopback interfaces. The Anycast RP Loopback address are configured with a 32-bit mask, making it a host address.
• Accept Source-Active Messages that Fail the RFP Check • Specifying Source-Active Messages • Limiting the Source-Active Cache • Preventing MSDP from Caching a Local Source • Preventing MSDP from Caching a Remote Source • Preventing MSDP from Advertising a Local Source • Terminating a Peership • Clearing Peer Statistics • Debugging MSDP • MSDP with Anycast RP • MSDP Sample Configurations Figure 84.
Figure 85.
Figure 86.
Figure 87. Configuring MSDP Enable MSDP Enable MSDP by peering RPs in different administrative domains. 1. Enable MSDP. CONFIGURATION mode ip multicast-msdp 2. Peer PIM systems in different administrative domains.
Examples of Configuring and Viewing MSDP R3_E600(conf)#ip multicast-msdp R3_E600(conf)#ip msdp peer 192.168.0.1 connect-source Loopback 0 R3_E600(conf)#do show ip msdp summary Peer Addr Description Local Addr State Source SA Up/Down To view details about a peer, use the show ip msdp peer command in EXEC privilege mode. Multicast sources in remote domains are stored on the RP in the source-active cache (SA cache).
Limiting the Source-Active Cache Set the upper limit of the number of active sources that the Dell Networking OS caches. The default active source limit is 500K messages. When the total number of active sources reaches the specified limit, subsequent active sources are dropped even if they pass the reverse path forwarding (RPF) and policy check. To limit the number of sources that SA cache stores, use the following command. • Limit the number of sources that can be stored in the SA cache.
Figure 88.
Figure 89.
Figure 90.
Figure 91. MSDP Default Peer, Scenario 4 Specifying Source-Active Messages To specify messages, use the following command. • Specify the forwarding-peer and originating-RP from which all active sources are accepted without regard for the RPF check. CONFIGURATION mode ip msdp default-peer ip-address list If you do not specify an access list, the peer accepts all sources that peer advertises. All sources from RPs that the ACL denies are subject to the normal RPF check.
Dell(conf)#ip access-list standard fifty Dell(conf)#seq 5 permit host 200.0.0.50 Dell#ip msdp sa-cache MSDP Source-Active Cache - 3 entries GroupAddr SourceAddr RPAddr LearnedFrom 229.0.50.2 24.0.50.2 200.0.0.50 10.0.50.2 229.0.50.3 24.0.50.3 200.0.0.50 10.0.50.2 229.0.50.4 24.0.50.4 200.0.0.50 10.0.50.2 Dell#ip msdp sa-cache rejected-sa MSDP Rejected SA Cache 3 rejected SAs received, cache-size 32766 UpTime GroupAddr SourceAddr RPAddr 00:33:18 229.0.50.64 24.0.50.64 200.0.1.50 00:33:18 229.0.50.65 24.0.50.
Example of Verifying the System is not Caching Local Sources When you apply this filter, the SA cache is not affected immediately. When sources that are denied by the ACL time out, they are not refreshed. Until they time out, they continue to reside in the cache. To apply the redistribute filter to entries already present in the SA cache, first clear the SA cache. You may optionally store denied sources in the rejected SA cache. R1_E600(conf)#do show run msdp ! ip multicast-msdp ip msdp peer 192.168.0.
R3_E600(conf)#do show ip msdp sa-cache R3_E600(conf)# R3_E600(conf)#do show ip msdp peer Peer Addr: 192.168.0.1 Local Addr: 0.0.0.0(639) Connect Source: Lo 0 State: Listening Up/Down Time: 00:01:19 Timers: KeepAlive 30 sec, Hold time 75 sec SourceActive packet count (in/out): 0/0 SAs learned from this peer: 0 SA Filtering: Input (S,G) filter: myremotefilter Output (S,G) filter: none Preventing MSDP from Advertising a Local Source To prevent MSDP from advertising a local source, use the following command.
Logging Changes in Peership States To log changes in peership states, use the following command. • Log peership state changes. CONFIGURATION mode ip msdp log-adjacency-changes Terminating a Peership MSDP uses TCP as its transport protocol. In a peering relationship, the peer with the lower IP address initiates the TCP session, while the peer with the higher IP address listens on port 639. • Terminate the TCP connection with a peer.
Example of the clear ip msdp peer Command and Verifying Statistics are Cleared R3_E600(conf)#do show ip msdp peer Peer Addr: 192.168.0.1 Local Addr: 192.168.0.3(639) Connect Source: Lo 0 State: Established Up/Down Time: 00:04:26 Timers: KeepAlive 30 sec, Hold time 75 sec SourceActive packet count (in/out): 5/0 SAs learned from this peer: 0 SA Filtering: Input (S,G) filter: myremotefilter Output (S,G) filter: none R3_E600(conf)#do clear ip msdp peer 192.168.0.
technique is less effective as traffic increases because preemptive load balancing requires prior knowledge of traffic distributions. • lack of scalable register decasulation: With only a single RP per group, all joins are sent to that RP regardless of the topological distance between the RP, sources, and receivers, and data is transmitted to the RP until the SPT switch threshold is reached.
Configuring Anycast RP To configure anycast RP, use the following commands. 1. In each routing domain that has multiple RPs serving a group, create a Loopback interface on each RP serving the group with the same IP address. CONFIGURATION mode interface loopback 2. Make this address the RP for the group. CONFIGURATION mode ip pim rp-address 3. In each routing domain that has multiple RPs serving a group, create another Loopback interface on each RP serving the group with a unique IP address.
CONFIGURATION mode ip msdp originator-id Examples of R1, R2, and R3 Configuration for MSDP with Anycast RP The following example shows an R1 configuration for MSDP with Anycast RP. ip multicast-routing ! interface TenGigabitEthernet 1/1 ip pim sparse-mode ip address 10.11.3.1/24 no shutdown ! interface TenGigabitEthernet 1/2 ip address 10.11.2.1/24 no shutdown ! interface TenGigabitEthernet 1/21 ip pim sparse-mode ip address 10.11.1.12/24 no shutdown ! interface Loopback 0 ip pim sparse-mode ip address 192.
no shutdown ! interface Loopback 0 ip pim sparse-mode ip address 192.168.0.1/32 no shutdown ! interface Loopback 1 ip address 192.168.0.22/32 no shutdown ! router ospf 1 network 10.11.1.0/24 area 0 network 10.11.4.0/24 area 0 network 192.168.0.22/32 area 0 redistribute static redistribute connected redistribute bgp 100 ! router bgp 100 redistribute ospf 1 neighbor 192.168.0.3 remote-as 200 neighbor 192.168.0.3 ebgp-multihop 255 neighbor 192.168.0.3 no shutdown ! ip multicast-msdp ip msdp peer 192.168.0.
neighbor neighbor neighbor neighbor ! ip ip ip ip ! ip ip ! ip 192.168.0.22 192.168.0.22 192.168.0.22 192.168.0.22 remote-as 100 ebgp-multihop 255 update-source Loopback 0 no shutdown multicast-msdp msdp peer 192.168.0.11 connect-source Loopback 0 msdp peer 192.168.0.22 connect-source Loopback 0 msdp sa-filter out 192.168.0.22 route 192.168.0.1/32 10.11.0.23 route 192.168.0.22/32 10.11.0.23 pim rp-address 192.168.0.3 group-address 224.0.0.
MSDP Sample Configuration: R1 Running-Config MSDP Sample Configuration: R2 Running-Config MSDP Sample Configuration: R3 Running-Config MSDP Sample Configuration: R4 Running-Config ip multicast-routing ! interface TenGigabitEthernet 1/1 ip pim sparse-mode ip address 10.11.3.1/24 no shutdown ! interface TenGigabitEthernet 1/2 ip address 10.11.2.1/24 no shutdown ! interface TenGigabitEthernet 1/21 ip pim sparse-mode ip address 10.11.1.12/24 no shutdown ! interface Loopback 0 ip pim sparse-mode ip address 192.
network 192.168.0.2/32 area 0 redistribute static redistribute connected redistribute bgp 100 ! router bgp 100 redistribute ospf 1 neighbor 192.168.0.3 remote-as 200 neighbor 192.168.0.3 ebgp-multihop 255 neighbor 192.168.0.3 update-source Loopback 0 neighbor 192.168.0.3 no shutdown ! ip route 192.168.0.3/32 10.11.0.32 ! ip pim rp-address 192.168.0.1 group-address 224.0.0.0/4 ip multicast-routing ! interface TenGigabitEthernet 3/21 ip pim sparse-mode ip address 10.11.0.
! interface TenGigabitEthernet 4/22 ip address 10.10.42.1/24 no shutdown ! interface TenGigabitEthernet 4/31 ip pim sparse-mode ip address 10.11.6.43/24 no shutdown ! interface Loopback 0 ip address 192.168.0.4/32 no shutdown ! router ospf 1 network 10.11.5.0/24 area 0 network 10.11.6.0/24 area 0 network 192.168.0.4/32 area 0 ! ip pim rp-address 192.168.0.3 group-address 224.0.0.
33 Multiple Spanning Tree Protocol (MSTP) Multiple spanning tree protocol (MSTP) is supported on Dell Networking OS. Protocol Overview MSTP — specified in IEEE 802.1Q-2003 — is a rapid spanning tree protocol (RSTP)-based spanning tree variation that improves on per-VLAN spanning tree plus (PVST+). MSTP allows multiple spanning tree instances and allows you to map many VLANs to one spanning tree instance to reduce the total number of required instances.
Spanning Tree Variations The Dell Networking OS supports four variations of spanning tree, as shown in the following table. Table 52. Spanning Tree Variations Dell Networking Term IEEE Specification Spanning Tree Protocol (STP) 802 .1d Rapid Spanning Tree Protocol (RSTP) 802 .1w Multiple Spanning Tree Protocol (MSTP) 802 .1s Per-VLAN Spanning Tree Plus (PVST+) Third Party Implementation Information The following describes the MSTP implementation information.
• Enabling SNMP Traps for Root Elections and Topology Changes • Configuring Spanning Trees as Hitless Enable Multiple Spanning Tree Globally MSTP is not enabled by default. To enable MSTP globally, use the following commands. When you enable MSTP, all physical, VLAN, and port-channel interfaces that are enabled and in Layer 2 mode are automatically part of the MSTI 0. • Within an MSTI, only one path from any bridge to any other bridge is enabled.
msti Specify the keyword vlan then the VLANs that you want to participate in the MSTI. Examples of Configuring and Viewing MSTI The following examples shows the msti command. Dell(conf)#protocol spanning-tree mstp Dell(conf-mstp)#msti 1 vlan 100 Dell(conf-mstp)#msti 2 vlan 200-300 Dell(conf-mstp)#show config ! protocol spanning-tree mstp no disable MSTI 1 VLAN 100 MSTI 2 VLAN 200-300 All bridges in the MSTP region must have the same VLAN-to-instance mapping.
Influencing MSTP Root Selection MSTP determines the root bridge, but you can assign one bridge a lower priority to increase the probability that it becomes the root bridge. To change the bridge priority, use the following command. • Assign a number as the bridge priority. PROTOCOL MSTP mode msti instance bridge-priority priority A lower number increases the probability that the bridge becomes the root bridge. The range is from 0 to 61440, in increments of 4096. The default is 32768.
NOTE: Some non-Dell Networking OS equipment may implement a non-null default region name. SFTOS, for example, uses the Bridge ID, while others may use a MAC address. Changing the Region Name or Revision To change the region name or revision, use the following commands. • Change the region name. PROTOCOL MSTP mode • name name Change the region revision number.
The default is 15 seconds. 2. Change the hello-time parameter. PROTOCOL MSTP mode hello-time seconds NOTE: With large configurations (especially those configurations with more ports) Dell Networking recommends increasing the hello-time. The range is from 1 to 10. The default is 2 seconds. 3. Change the max-age parameter. PROTOCOL MSTP mode max-age seconds The range is from 6 to 40. The default is 20 seconds. 4. Change the max-hops parameter. PROTOCOL MSTP mode max-hops number The range is from 1 to 40.
• Port priority influences the likelihood that a port is selected to be a forwarding port in case that several ports have the same port cost. The following lists the default values for port cost by interface. Table 53.
• Enable EdgePort on an interface. INTERFACE mode spanning-tree mstp edge-port [bpduguard | shutdown-on-violation] Dell Networking OS Behavior: Regarding bpduguard shutdown-on-violation behavior: – If the interface to be shut down is a port channel, all the member ports are disabled in the hardware. – When you add a physical port to a port channel already in the Error Disable state, the new member port is also disabled in the hardware.
Figure 94. MSTP with Three VLANs Mapped to Two Spanning Tree Instances Router 1 Running-Configuration This example uses the following steps: 1. Enable MSTP globally and set the region name and revision map MSTP instances to the VLANs. 2. Assign Layer-2 interfaces to the MSTP topology. 3. Create VLANs mapped to MSTP instances tag interfaces to the VLANs.
no shutdown ! interface Vlan 300 no ip address tagged TenGigabitEthernet 1/21,31 no shutdown Router 2 Running-Configuration This example uses the following steps: 1. Enable MSTP globally and set the region name and revision map MSTP instances to the VLANs. 2. Assign Layer-2 interfaces to the MSTP topology. 3. Create VLANs mapped to MSTP instances tag interfaces to the VLANs.
name Tahiti revision 123 MSTI 1 VLAN 100 MSTI 2 VLAN 200,300 ! (Step 2) interface TenGigabitEthernet 3/11 no ip address switchport no shutdown ! interface TenGigabitEthernet 3/21 no ip address switchport no shutdown ! (Step 3) interface Vlan 100 no ip address tagged TenGigabitEthernet 3/11,21 no shutdown ! interface Vlan 200 no ip address tagged TenGigabitEthernet 3/11,21 no shutdown ! interface Vlan 300 no ip address tagged TenGigabitEthernet 3/11,21 no shutdown SFTOS Example Running-Configuration This e
(Step 3) interface vlan 100 tagged 1/0/31 tagged 1/0/32 exit interface vlan 200 tagged 1/0/31 tagged 1/0/32 exit interface vlan 300 tagged 1/0/31 tagged 1/0/32 exit Debugging and Verifying MSTP Configurations To debut and verify MSTP configuration, use the following commands. • Display BPDUs. EXEC Privilege mode • debug spanning-tree mstp bpdu Display MSTP-triggered topology change messages.
– Are there “extra” MSTP instances in the Sending or Received logs? This may mean that an additional MSTP instance was configured on one router but not the others. The following example shows the show run spanning-tree mstp command. Dell#show run spanning-tree mstp ! protocol spanning-tree mstp name Tahiti revision 123 MSTI 1 VLAN 100 MSTI 2 VLAN 200,300 The following example shows viewing the debug log of a successful MSTP configuration.
INST 2: Flags: 0x70, Reg Root: 32768:0001.e8d5.
Multicast Features 34 NOTE: Multicast routing is supported on secondary IP addresses; it is not supported on IPv6. NOTE: Multicast routing is supported across default and non-default VRFs. The Dell Networking operating system (OS) supports the following multicast protocols: • PIM Sparse-Mode (PIM-SM) • Internet Group Management Protocol (IGMP) • Multicast Source Discovery Protocol (MSDP) Enabling IP Multicast Prior to enabling any multicast protocols, you must enable multicast routing.
Protocol Ethernet Address RIP 01:00:5e:00:00:09 NTP 01:00:5e:00:01:01 VRRP 01:00:5e:00:00:12 PIM-SM 01:00:5e:00:00:0d • The Dell Networking OS implementation of MTRACE is in accordance with IETF draft draft-fennertraceroute-ipm. • Multicast is not supported on secondary IP addresses. • If you enable multicast routing, Egress L3 ACL is not applied to multicast data traffic. Multicast Policies Dell Networking OS offers parallel multicast features for IPv4.
• Limit the total number of multicast routes on the system. CONFIGURATION mode ip multicast-limit The range if from 1 to 16000. The default is 4000. NOTE: The IN-L3-McastFib CAM partition is used to store multicast routes and is a separate hardware limit that exists per port-pipe. Any software-configured limit may supersede this hardware space limitation.
Figure 95. Preventing a Host from Joining a Group The following table lists the location and description shown in the previous illustration. Table 54. Preventing a Host from Joining a Group — Description Location Description 1/21 • • • • Interface TenGigabitEthernet 1/21 ip pim sparse-mode ip address 10.11.12.
Location Description • • ip address 10.11.13.1/24 no shutdown 2/1 • • • • Interface TenGigabitEthernet 2/1 ip pim sparse-mode ip address 10.11.1.1/24 no shutdown 2/11 • • • • Interface TenGigabitEthernet 2/11 ip pim sparse-mode ip address 10.11.12.2/24 no shutdown 2/31 • • • • Interface TenGigabitEthernet 2/31 ip pim sparse-mode ip address 10.11.23.1/24 no shutdown 3/1 • • • • Interface TenGigabitEthernet 3/1 ip pim sparse-mode ip address 10.11.5.
Preventing a PIM Router from Forming an Adjacency To prevent a router from participating in PIM (for example, to configure stub multicast routing), use the following command. • Prevent a router from participating in PIM. INTERFACE mode ip pim neighbor-filter Preventing a Source from Registering with the RP To prevent the PIM source DR from sending register packets to RP for the specified multicast source and group, use the following command.
Figure 96. Preventing a Source from Transmitting to a Group The following table lists the location and description shown in the previous illustration. Table 55. Preventing a Source from Transmitting to a Group — Description Location Description 1/21 • • • • Interface TenGigabitEthernet 1/21 ip pim sparse-mode ip address 10.11.12.
Location Description • • ip address 10.11.13.1/24 no shutdown 2/1 • • • • Interface TenGigabitEthernet 2/1 ip pim sparse-mode ip address 10.11.1.1/24 no shutdown 2/11 • • • • Interface TenGigabitEthernet 2/11 ip pim sparse-mode ip address 10.11.12.2/24 no shutdown 2/31 • • • • Interface TenGigabitEthernet 2/31 ip pim sparse-mode ip address 10.11.23.1/24 no shutdown 3/1 • • • • Interface TenGigabitEthernet 3/1 ip pim sparse-mode ip address 10.11.5.
Preventing a PIM Router from Processing a Join To permit or deny PIM Join/Prune messages on an interface using an extended IP access list, use the following command. NOTE: Dell Networking recommends not using the ip pim join-filter command on an interface between a source and the RP router. Using this command in this scenario could cause problems with the PIM-SM source registration process resulting in excessive traffic being sent to the CPU of both the RP and PIM DR of the source.
Object Tracking 35 IPv4/IPv6 object tracking is available on Dell Networking OS. Object tracking allows the Dell Networking Operating System (OS) client processes, such as virtual router redundancy protocol (VRRP), to monitor tracked objects (for example, interface or link status) and take appropriate action when the state of an object changes. NOTE: In Dell Networking OS release version 8.4.1.0, object tracking is supported only on VRRP.
Figure 97. Object Tracking Example When you configure a tracked object, such as an IPv4/IPv6 a route or interface, you specify an object number to identify the object. Optionally, you can also specify: • UP and DOWN thresholds used to report changes in a route metric. • A time delay before changes in a tracked object’s state are reported to a client. Track Layer 2 Interfaces You can create an object to track the line-protocol state of a Layer 2 interface.
Track IPv4 and IPv6 Routes You can create an object that tracks an IPv4 or IPv6 route entry in the routing table. Specify a tracked route by its IPv4/IPv6 address and prefix-length, and optionally, by a virtual routing and forwarding (VRF) instance name if the route to be tracked is part of a VRF. The next-hop address is not part of the definition of the tracked object. A tracked route matches a route in the routing table only if the exact address and prefix length match an entry in the routing table.
• For OSPF, you can set the resolution in the range from 1 to 1592, where the default is 1. • The resolution value used to map static routes is not configurable. By default, Dell Networking OS assigns a metric of 0 to static routes. • The resolution value used to map router information protocol (RIP) routes is not configurable. The RIP hop-count is automatically multiplied by 16 to scale it; a RIP metric of 16 (unreachable) scales to 256, which considers the route to be DOWN.
• 10 Gigabit Ethernet: Enter tengigabitethernet slot/port. • Port channel: Enter port-channel number, where valid port-channel numbers are: – For the C-Series and S-Series, from 1 to 128. – For the E-Series, from 1 to 255 (TeraScale and ExaScale) • SONET: Enter sonet slot/port. • VLAN: Enter vlan vlan-id, where valid VLAN IDs are from 1 to 4094 A line-protocol object only tracks the link-level (UP/DOWN) status of a specified interface.
Tracking a Layer 3 Interface You can create an object that tracks the routing status of an IPv4 or IPv6 Layer 3 interface. You can track the routing status of any of the following Layer 3 interfaces: • For a 10-Gigabit Ethernet interface, enter the keyword TenGigabitEthernet then the slot/port[/ subport] information. • For a port channel interface, enter the keywords port-channel then a number. • For a VLAN interface, enter the keyword vlan then a number from 1 to 4094.
EXEC Privilege mode show track object-id Example of Configuring Object Tracking (IPv4 Interface) Example of Configuring Object Tracking (IPv6 Interface) Dell(conf)#track 101 interface tengigabitethernet 7/2 ip routing Dell(conf-track-101)#delay up 20 Dell(conf-track-101)#description NYC metro Dell(conf-track-101)#end Dell#show track 101 Track 101 Interface TenGigabitEthernet 7/2 ip routing Description: NYC metro Dell(conf)#track 103 interface tengigabitethernet 7/11 ipv6 routing Dell(conf-track-103)#descrip
To provide a common tracking interface for different clients, route metrics are scaled in the range from 0 to 255, where 0 is connected and 255 is inaccessible. The scaled metric value communicated to a client always considers a lower value to have priority over a higher value.
The default is 0. 3. (Optional) Identify the tracked object with a text description. OBJECT TRACKING mode description text The text string can be up to 80 characters. 4. (Optional) Display the tracking configuration and the tracked object’s status. EXEC Privilege mode show track object-id Example of the track ip route reachability Command Example of the track ipv6 route reachability Command Dell(conf)#track 104 ip route 10.0.0.
2. • OSPF routes - 1 to 1592. The efault is 1. Configure object tracking on the metric of an IPv4 or IPv6 route. CONFIGURATION mode track object-id {ip route ip-address/prefix-len | ipv6 route ipv6-address/ prefix-len} metric threshold [vrf vrf-name] Valid object IDs are from 1 to 65535. Enter an IPv4 address in dotted decimal format. Valid IPv4 prefix lengths are from /0 to /32. Enter an IPv6 address in X:X:X:X::X format. Valid IPv6 prefix lengths are from /0 to /128.
Dell(conf-track-6)#threshold metric down 40 Dell(conf-track-6)#threshold metric up 40 Dell(conf-track-6)#exit Dell(conf)#track 10 ip route 3.1.1.0/24 metric threshold vrf vrf1 Dell(conf)#track 8 ipv6 route 2::/64 metric threshold Dell(conf-track-8)#threshold metric up 30 Dell(conf-track-8)#threshold metric down 40 Displaying Tracked Objects To display the currently configured objects used to track Layer 2 and Layer 3 interfaces, and IPv4 and IPv6 routes, use the following show commands.
Example of the show track brief Command Router# show track brief ResId State 1 Resource LastChange IP route reachability Parameter 10.16.0.0/16 Example of the show track resolution Command Dell#show track resolution IP Route Resolution ISIS 1 OSPF 1 IPv6 Route Resolution ISIS 1 Example of the show track vrf Command Dell#show track vrf red Track 5 IP route 192.168.0.
Open Shortest Path First (OSPFv2 and OSPFv3) 36 Open shortest path first (OSPFv2 for IPv4) and OSPF version 3 (OSPF for IPv6) are supported on Dell Networking OS. This chapter provides a general description of OSPFv2 (OSPF for IPv4) and OSPFv3 (OSPF for IPv6) as supported in the Dell Networking Operating System (OS). NOTE: The fundamental mechanisms of OSPF (flooding, DR election, area support, SPF calculations, and so on) are the same between OSPFv2 and OSPFv3.
Areas allow you to further organize your routers within in the AS. One or more areas are required within the AS. Areas are valuable in that they allow sub-networks to "hide" within the AS, thus minimizing the size of the routing tables on all routers. An area within the AS may not see the details of another area’s topology. AS areas are known by their area number or the router’s IP address. Figure 98. Autonomous System Areas Area Types The backbone of the network is Area 0. It is also called Area 0.0.0.
The backbone is the only area with a default area number. All other areas can have their Area ID assigned in the configuration. In the previous example, Routers A, B, C, G, H, and I are the Backbone. • A stub area (SA) does not receive external route information, except for the default route. These areas do receive information from inter-area (IA) routes. NOTE: Configure all routers within an assigned stub area as stubby, and not generate LSAs that do not apply.
Figure 99. OSPF Routing Examples Backbone Router (BR) A backbone router (BR) is part of the OSPF Backbone, Area 0. This includes all ABRs. It can also include any routers that connect only to the backbone and another ABR, but are only part of Area 0, such as Router I in the previous example. Area Border Router (ABR) Within an AS, an area border router (ABR) connects one or more areas to the backbone.
An ABR can connect to many areas in an AS, and is considered a member of each area it connects to. Autonomous System Border Router (ASBR) The autonomous system border area router (ASBR) connects to more than one AS and exchanges information with the routers in other ASs. Generally, the ASBR connects to a non-interior gate protocol (IGP) such as BGP or uses static routes.
• Type 5: LSA — These LSAs contain information imported into OSPF from other routing processes. They are flooded to all areas, except stub areas. The link-state ID of the Type 5 LSA is the external network number. • Type 7: External LSA — Routers in an NSSA do not receive external LSAs from ABRs, but are allowed to send external routing information for redistribution.
Router Priority and Cost Router priority and cost is the method the system uses to “rate” the routers. For example, if not assigned, the system selects the router with the highest priority as the DR. The second highest priority is the BDR. • • Priority is a numbered rating 0 to 255. The higher the number, the higher the priority. Cost is a numbered rating 1 to 65535. The higher the number, the greater the cost. The cost assigned reflects the cost should the router fail.
Dell Networking OS supports stub areas, totally stub (no summary) and not so stubby areas (NSSAs) and supports the following LSAs, as described earlier.
• Helper-reject role in which OSPF does not participate in the graceful restart of a neighbor. OSPFv2 supports helper-only and restarting-only roles. By default, both helper and restarting roles are enabled. OSPFv2 supports the helper-reject role globally on a router. OSPFv3 supports helper-only and restarting-only roles. The helper-only role is enabled by default. To enable the restarting role in addition to the helper-only role, configure a grace period.
example, if you create five OSPFv2 processes on a system, there must be at least five interfaces assigned in Layer 3 mode. Each OSPFv2 process is independent. If one process loses adjacency, the other processes continue to function. Processing SNMP and Sending SNMP Traps Though there are may be several OSPFv2 processes, only one process can process simple network management protocol (SNMP) requests and send SNMP traps.
Hello due in 00:00:04 Neighbor Count is 1, Adjacent neighbor count is 1 Adjacent with neighbor 1.1.1.1 (Backup Designated Router) Dell (conf-if-te-2/2)# Configuration Information The interfaces must be in Layer-3 mode (assigned an IP address) and enabled so that they can send and receive traffic. The OSPF process must know about these interfaces. To make the OSPF process aware of these interfaces, they must be assigned to OSPF areas. You must configure OSPF GLOBALLY on the system in CONFIGURATION mode.
Dell(conf)#router ospf 1 Dell(conf-router_ospf-1)#timer spf 2 5 Dell(conf-router_ospf-1)# Dell(conf-router_ospf-1)#show config ! router ospf 1 timers spf 2 5 Dell(conf-router_ospf-1)# Dell(conf-router_ospf-1)#end Dell# For a complete list of the OSPF commands, refer to the OSPF section in the Dell Networking OS Command Line Reference Guide document. Enabling OSPFv2 To enable Layer 3 routing, assign an IP address to an interface (physical or Loopback).
If you try to enter an OSPF process ID, or if you try to enable more OSPF processes than available Layer 3 interfaces, prior to assigning an IP address to an interface and setting the no shutdown command, the following message displays: C300(conf)#router ospf 1 % Error: No router ID available. Assigning a Router ID In CONFIGURATION ROUTER OSPF mode, assign the router ID. The router ID is not required to be the router’s IP address.
• Enable OSPFv2 on an interface and assign a network address range to a specific OSPF area. CONFIG-ROUTER-OSPF-id mode network ip-address mask area area-id The IP Address Format is A.B.C.D/M. The area ID range is from 0 to 65535 or A.B.C.D/M. Enable OSPFv2 on Interfaces Enable and configure OSPFv2 on each interface (configure for Layer 3 protocol), and not shutdown. You can also assign OSPFv2 to a Loopback interface as a virtual interface.
Transmit Delay is 1 sec, State DR, Priority 1 Designated Router (ID) 11.1.2.1, Interface address 10.2.2.1 Backup Designated Router (ID) 0.0.0.0, Interface address 0.0.0.0 Timer intervals configured, Hello 10, Dead 40, Wait 40, Retransmit 5 Hello due in 00:00:04 Neighbor Count is 0, Adjacent neighbor count is 0 TenGigabitEthernet 1/21 is up, line protocol is up Internet Address 10.2.3.1/24, Area 0.0.0.0 Process ID 1, Router ID 11.1.2.
3. Enter ROUTER OSPF mode. CONFIGURATION mode router ospf process-id [vrf] Process ID is the ID assigned when configuring OSPFv2 globally. 4. Configure the area as a stub area. CONFIG-ROUTER-OSPF-id mode area area-id stub [no-summary] Use the keywords no-summary to prevent transmission into the area of summary ASBR LSAs. Area ID is the number or IP address assigned when creating the area.
– For a VLAN interface, enter the keyword vlan then a number from 1 to 4094. The keyword default sets all interfaces on this OSPF process as passive. To remove the passive interface from select interfaces, use the no passive-interface interface command while passive interface default is configured. To enable both receiving and sending routing updates, use the no passive-interface interface command.
fast-convergence {number} The parameter range is from 1 to 4. The higher the number, the faster the convergence. When disabled, the parameter is set at 0. NOTE: A higher convergence level can result in occasional loss of OSPF adjacency. Generally, convergence level 1 meets most convergence requirements. Only select higher convergence levels following consultation with Dell Technical Support.
ip ospf dead-interval seconds – seconds: the range is from 1 to 65535 (the default is 40 seconds). The dead interval must be four times the hello interval. • The dead interval must be the same on all routers in the OSPF network. Change the time interval between hello-packet transmission. CONFIG-INTERFACE mode ip ospf hello-interval seconds – seconds: the range is from 1 to 65535 (the default is 10 seconds). • The hello interval must be the same on all routers in the OSPF network.
Example of Changing and Verifying the cost Parameter and Viewing Interface Status To view interface configurations, use the show config command in CONFIGURATION INTERFACE mode. To view interface status in the OSPF process, use the show ip ospf interface command in EXEC mode. The bold lines in the example show the change on the interface. The change is reflected in the OSPF configuration. Dell(conf-if)#ip ospf cost 45 Dell(conf-if)#show config ! interface TenGigabitEthernet 1/1 ip address 10.1.2.100 255.255.
This transmission stops when the period ends. The default is 0 seconds. Enabling OSPFv2 Graceful Restart Graceful restart is enabled for the global OSPF process. The Dell Networking implementation of OSPFv2 graceful restart enables you to specify: • grace period — the length of time the graceful restart process can last before OSPF terminates it. • helper-reject neighbors — the router ID of each restart router that does not receive assistance from the configured router.
By default, OSPFv2 supports both restarting and helper roles. Selecting one or the other role restricts OSPFv2 to the single selected role. To disable OSPFv2 graceful-restart after you have enabled it, use the no graceful-restart graceperiod command in CONFIG-ROUTEROSPF- id mode. The command returns OSPF graceful-restart to its default state. NOTE: The Helper mode is enabled by default on the device.
Applying Prefix Lists To apply prefix lists to incoming or outgoing OSPF routes, use the following commands. • Apply a configured prefix list to incoming OSPF routes. CONFIG-ROUTEROSPF-id mode • distribute-list prefix-list-name in [interface] Assign a configured prefix list to outgoing OSPF routes. CONFIG-ROUTEROSPF-id distribute-list prefix-list-name out [connected | isis | rip | static] Redistributing Routes You can add routes from other routing instances or protocols to the OSPF process.
NOTE: The following tasks are not a comprehensive; they provide some examples of typical troubleshooting checks.
To view debug messages for a specific operation, enter one of the optional keywords: – event: view OSPF event messages. – packet: view OSPF packet information. – spf: view SPF information. – database-timers rate-limit: view the LSAs currently in the queue. Example of Viewing OSPF Configuration Dell#show run ospf ! router ospf 4 router-id 4.4.4.4 network 4.4.4.0/28 area 1 ! ipv6 router ospf 999 default-information originate always router-id 10.10.10.
network 192.168.100.0/24 area 0 ! interface TenGigabitEthernet 1/1 ip address 10.1.11.1/24 no shutdown ! interface TenGigabitEthernet 1/2 ip address 10.2.12.2/24 no shutdown ! interface Loopback 10 ip address 192.168.100.100/24 no shutdown OSPF Area 0 — Te 3/1 and 3/2 router ospf 33333 network 192.168.100.0/24 area 0 network 10.0.13.0/24 area 0 network 10.0.23.0/24 area 0 ! interface Loopback 30 ip address 192.168.100.100/24 no shutdown ! interface TenGigabitEthernet 3/1 ip address 10.1.13.
The OSPFv3 ipv6 ospf area command enables OSPFv3 on the interface and places the interface in an area. With OSPFv2, two commands are required to accomplish the same tasks — the router ospf command to create the OSPF process, then the network area command to enable OSPF on an interface. NOTE: The OSPFv2 network area command enables OSPF on multiple interfaces with the single command. Use the OSPFv3 ipv6 ospf area command on each interface that runs OSPFv3.
The format is A:B:C::F/128. 2. Bring up the interface. CONF-INT-type slot/port mode no shutdown Assigning Area ID on an Interface To assign the OSPFv3 process to an interface, use the following command. The ipv6 ospf area command enables OSPFv3 on an interface and places the interface in the specified area. Additionally, the command creates the OSPFv3 process with ID on the router.
Assigning OSPFv3 Process ID and Router ID to a VRF To assign, disable, or reset OSPFv3 on a non-default VRF, use the following commands. • Enable the OSPFv3 process on a non-default VRF and enter OSPFv3 mode. CONFIGURATION mode ipv6 router ospf {process ID}} • The process ID range is from 0 to 65535. Assign the router ID for this OSPFv3 process. CONF-IPV6-ROUTER-OSPF mode router-id {number} – number: the IPv4 address. The format is A.B.C.D.
– For a 10-Gigabit Ethernet interface, enter the keyword TenGigabitEthernet then the slot/port[/ subport] information. – For a 40-Gigabit Ethernet interface, enter the keyword fortyGigE then the slot/port information. – For a port channel interface, enter the keywords port-channel then a number. – For a VLAN interface, enter the keyword vlan then a number from 1 to 4094. To enable both receiving and sending routing updates, use the no passive-interface interface command.
Enabling OSPFv3 Graceful Restart For more information about graceful restart, refer to Graceful Restart. By default, OSPFv3 graceful restart is disabled and functions only in a helper role to help restarting neighbor routers in their graceful restarts when it receives a Grace LSA. To enable OSPFv3 graceful restart, enter the ipv6 router ospf process-id command to enter OSPFv3 configuration mode. Then configure a grace period using the graceful-restart graceperiod command.
Displaying Graceful Restart To display information on the use and configuration of OSPFv3 graceful restart, enter any of the following commands. • Display the graceful-restart configuration for OSPFv2 and OSPFv3 (shown in the following example). EXEC Privilege mode • show run ospf Display the Type-11 Grace LSAs sent and received on an OSPFv3 router (shown in the following example).
Brd Rtr Count AS Bdr Rtr Count LSA count Summary LSAs Rtr LSA Count Net LSA Count Inter Area Pfx LSA Count Inter Area Rtr LSA Count Group Mem LSA Count 2 2 12010 1 4 3 12000 0 0 The following example shows the show ipv6 ospf database grace-lsa command. Dell#show ipv6 ospf database grace-lsa ! Type-11 Grace LSA (Area 0) LS Age Link State ID Advertising Router LS Seq Number Checksum Length Associated Interface Restart Interval Restart Reason : : : : : : : : : 10 6.16.192.66 100.1.1.
header after the IP header and before the next layer protocol header in Transport mode. It is possible to insert the ESP header between the next layer protocol header and encapsulated IP header in Tunnel mode. However, Tunnel mode is not supported in Dell Networking OS. For detailed information about the IP ESP protocol, refer to RFC 4303. In OSPFv3 communication, IPsec provides security services between a pair of communicating hosts or security gateways using either AH or ESP.
NOTE: To encrypt all keys on a router, use the service password-encryption command in Global Configuration mode. However, this command does not provide a high level of network security. To enable key encryption in an IPsec security policy at an interface or area level, specify 7 for [key-encryption-type] when you enter the ipv6 ospf authentication ipsec or ipv6 ospf encryption ipsec command.
Configuring IPsec Encryption on an Interface To configure, remove, or display IPsec encryption on an interface, use the following commands. Prerequisite: Before you enable IPsec encryption on an OSPFv3 interface, first enable IPv6 unicast routing globally, configure an IPv6 address and enable OSPFv3 on the interface, and assign it to an area (refer to Configuration Task List for OSPFv3 (OSPF for IPv6)).
Configuring IPSec Authentication for an OSPFv3 Area To configure, remove, or display IPSec authentication for an OSPFv3 area, use the following commands. Prerequisite: Before you enable IPsec authentication on an OSPFv3 area, first enable OSPFv3 globally on the router (refer to Configuration Task List for OSPFv3 (OSPF for IPv6)). The security policy index (SPI) value must be unique to one IPSec security policy (authentication or encryption) on the router.
The configuration of IPsec encryption on an interface-level takes precedence over an area-level configuration. If you remove an interface configuration, an area encryption policy that has been configured is applied to the interface. • Enable IPsec encryption for OSPFv3 packets in an area.
To display information on the SAs used on a specific interface, enter interface interface, where interface is one of the following values: – For a 10-Gigabit Ethernet interface, enter the keyword TenGigabitEthernet then the slot/port[/ subport] information. – For a 40-Gigabit Ethernet interface, enter the keyword fortyGigE then the slot/port information. – For a port channel interface, enter the keywords port-channel then a number. – For a VLAN interface, enter the keyword vlan then a number from 1 to 4094.
Interface: TenGigabitEthernet 1/1 Link Local address: fe80::201:e8ff:fe40:4d10 IPSecv6 policy name: OSPFv3-1-500 inbound ah sas spi : 500 (0x1f4) transform : ah-md5-hmac in use settings : {Transport, } replay detection support : N STATUS : ACTIVE outbound ah sas spi : 500 (0x1f4) transform : ah-md5-hmac in use settings : {Transport, } replay detection support : N STATUS : ACTIVE inbound esp sas outbound esp sas Interface: TenGigabitEthernet 1/2 Link Local address: fe80::201:e8ff:fe40:4d11 IPSecv6 policy nam
• show ipv6 interfaces • show ipv6 protocols • debug ipv6 ospf events and/or packets • show ipv6 neighbors • show ipv6 routes Viewing Summary Information To get general route, configuration, links status, and debug information, use the following commands. • View the summary information of the IPv6 routes. EXEC Privilege mode • show ipv6 route summary View the summary information for the OSPFv3 database. EXEC Privilege mode • show ipv6 ospf database View the configuration of OSPFv3 neighbors.
Policy-based Routing (PBR) 37 Policy-based Routing (PBR) allows a switch to make routing decisions based on policies applied to an interface. Overview When a router receives a packet, the router normally decides where to forward the packet based on the destination address in the packet, which is used to look up an entry in a routing table. However, in some cases, there may be a need to forward the packet based on other criteria: size, source, protocol type, destination, and so forth.
To enable a PBR, create a redirect list. Redirect lists are defined by rules, or routing policies. You can define following parameters in routing policies or rules: • • • • • • • IP address of the forwarding router (next-hop IP address) Protocol as defined in the header Source IP address and mask Destination IP address and mask Source port Destination port TCP Flags After a redirect-list is applied to an interface, all traffic passing through it is subjected to the rules defined in the redirect-list.
Defined as: seq 5 permit ip 200.200.200.200 200.200.200.200 199.199.199.199 199.199.199.199 seq 10 redirect 1.1.1.2 tcp 234.224.234.234 255.234.234.234 222.222.222.222/24 seq 40 ack, Next-hop reachable(via Te 8/1) Applied interfaces: Te 8/2 Hot-Lock PBR Ingress and egress Hot Lock PBR allows you to add or delete new rules into an existing policy (already written into content address memory [CAM]) without disruption to traffic flow. Existing entries in CAM are adjusted to accommodate the new entries.
CONFIGURATION mode ip redirect-list redirect-list-name redirect-list-name: 16 characters. To delete the redirect list, use the no ip redirect-list command. The following example creates a redirect list by the name of xyz. Dell(conf)#ip redirect-list ? WORD Redirect-list name (max 16 chars) Dell(conf)#ip redirect-list xyz Create a Rule for a Redirect-list To set the rules for the redirect list, use the following command. You can enter the command multiple times and create a sequence of redirect rules.
• Destination address with mask information Example: Creating a Rule Dell(conf-redirect-list)#redirect ? A.B.C.D Forwarding router's address Dell(conf-redirect-list)#redirect 3.3.3.3 ? <0-255> An IP protocol number icmp Internet Control Message Protocol ip Any Internet Protocol tcp Transmission Control Protocol udp User Datagram Protocol Dell(conf-redirect-list)#redirect 3.3.3.3 ip ? A.B.C.D Source address any Any source host host A single source host Dell(conf-redirect-list)#redirect 3.3.3.3 ip 222.1.1.
A recursive route is a route for which the immediate next-hop address is learned dynamically through a routing protocol and acquired through a route lookup in the routing table. You can configure multiple recursive routes in a redirect list by entering multiple seq redirect commands with the same source and destination address and specify a different next-hop IP address. In this way, the recursive routes are used as different forwarding routes for dynamic failover.
no ip address ip redirect-group test ip redirect-group xyz shutdown Dell(conf-if-te-1/2)# In addition to supporting multiple redirect-lists in a redirect-group, multiple redirect-groups are supported on a single interface. Dell Networking OS has the capability to support multiple groups on an interface for backup purposes. Show Redirect List Configuration To view the configuration redirect list configuration, use the following commands. 1.
Use the show ip redirect-list (without the list name) to display all the redirect-lists configured on the device. Dell#show ip redirect-list IP redirect-list rcl0: Defined as: seq 5 permit ip 200.200.200.200 200.200.200.200 199.199.199.199 199.199.199.199 seq 10 redirect 1.1.1.2 tcp 234.224.234.234 255.234.234.234 222.222.222.
Policy-based Routing (PBR)
PIM Sparse-Mode (PIM-SM) 38 Protocol-independent multicast sparse-mode (PIM-SM) is supported on Dell Networking OS. PIM-SM is a multicast protocol that forwards multicast traffic to a subnet only after a request using a PIM Join message; this behavior is the opposite of PIM-Dense mode, which forwards multicast traffic to all subnets until a request to stop. Implementation Information The following information is necessary for implementing PIM-SM.
received becomes the outgoing interface associated with the (*,G) entry. This process constructs an RPT branch to the RP. 3. If a host on the same subnet as another multicast receiver sends an IGMP report for the same multicast group, the gateway takes no action.
Important Point to Remember If you use a Loopback interface with a /32 mask as the RP, you must enable PIM Sparse-mode on the interface. Configuring PIM-SM Configuring PIM-SM is a three-step process. 1. Enable multicast routing (refer to the following step). 2. Select a rendezvous point. 3. Enable PIM-SM on an interface. Enable multicast routing. CONFIGURATION mode ip multicast-routing Related Configuration Tasks The following are related PIM-SM configuration tasks.
NOTE: You can influence the selection of the Rendezvous Point by enabling PIM-Sparse mode on a Loopback interface and assigning a low IP address. To display PIM neighbors for each interface, use the show ip pim neighbor command EXEC Privilege mode. Dell#show ip Neighbor Address 127.87.5.5 127.87.3.5 127.87.50.
The default is 210. 2. Set the expiry time for a specific (S,G) entry (as shown in the following example). CONFIGURATION mode ip pim sparse-mode sg-expiry-timer seconds sg-list access-list-name The range is from 211 to 86,400 seconds. The default is 210.
Overriding Bootstrap Router Updates PIM-SM routers must know the address of the RP for each group for which they have (*,G) entry. This address is obtained automatically through the bootstrap router (BSR) mechanism or a static RP configuration. Use the following command if you have configured a static RP for a group. If you do not use the override option with the following command, the RPs advertised in the BSR updates take precedence over any statically configured RPs.
Creating Multicast Boundaries and Domains A PIM domain is a contiguous set of routers that all implement PIM and are configured to operate within a common boundary defined by PIM multicast border routers (PMBRs). PMBRs connect each PIM domain to the rest of the Internet. Create multicast boundaries and domains by filtering inbound and outbound bootstrap router (BSR) messages per interface. The following command is applied to the subsequent inbound and outbound updates.
PIM Source-Specific Mode (PIM-SSM) 39 PIM source-specific mode (PIM-SSM) is supported on Dell Networking OS. PIM-SSM is a multicast protocol that forwards multicast traffic from a single source to a subnet. In the other versions of protocol independent multicast (PIM), a receiver subscribes to a group only. The receiver receives traffic not just from the source in which it is interested but from all sources sending to that group.
Configure PIM-SSM Configuring PIM-SSM is a two-step process. 1. Configure PIM-SSM. 2. Enable PIM-SSM for a range of addresses. Related Configuration Tasks • Use PIM-SSM with IGMP Version 2 Hosts Enabling PIM-SSM To enable PIM-SSM, follow these steps. 1. Create an ACL that uses permit rules to specify what range of addresses should use SSM. CONFIGURATION mode ip access-list standard name 2. Enter the ip pim ssm-range command and specify the ACL you created.
• • • When you remove the mapping configuration, Dell Networking OS removes the corresponding (S,G) states that it created and re-establishes the original (*,G) states. You may enter multiple ssm-map commands for different access lists. You may also enter multiple ssm-map commands for the same access list, as long as they use different source addresses. When an extended ACL is associated with this command, Dell Networking OS displays an error message.
Router mode Last reporter Group source list Source address 165.87.32.21 INCLUDE 165.87.34.100 Expires Never R1(conf)#do show run pim ! ip pim rp-address 10.11.12.2 group-address 224.0.0.0/4 ip pim ssm-range ssm R1(conf)#do show run acl ! ip access-list standard map seq 5 permit host 239.0.0.2 ! ip access-list standard ssm seq 5 permit host 239.0.0.2 R1(conf)#ip igmp ssm-map map 10.11.5.
40 Port Monitoring Port monitoring is supported on Dell Networking OS. Mirroring is used for monitoring Ingress or Egress or both Ingress and Egress traffic on a specific port(s). This mirrored traffic can be sent to a port where a network sniffer can connect and monitor the traffic.
Port Monitoring The S4048–ON supports multiple source-destination statements in a single monitor session. The maximum number of source ports that can be supported in a session is 128. The maximum number of destination ports that can be supported is 4 per port pipe. In the following examples, ports 1/13, 1/14, 1/15, and 1/16 all belong to the same port-pipe. They are pointing to four different destinations (1/1, 1/2, 1/3, and 1/37).
Example of Viewing a Monitoring Session In the example below, 0/25 and 0/26 belong to Port-pipe 1. This port-pipe has the same restriction of only four destination ports, new or used.
show interface 2. Create a monitoring session using the command monitor session from CONFIGURATION mode, as shown in the following example. CONFIGURATION mode monitor session monitor session type rpm/erpm type is an optional keyword, required only for rpm and erpm 3. Specify the source and destination port and direction of traffic, as shown in the following example.
Figure 103. Port Monitoring Example Configuring Monitor Multicast Queue To configure monitor QoS multicast queue ID, use the following commands. 1. Configure monitor QoS multicast queue ID. CONFIGURATION mode monitor multicast-queue queue-id Dell(conf)#monitor multicast-queue 7 2. Verify information about monitor configurations.
Enabling Flow-Based Monitoring Flow-based monitoring is supported only on the S-Series platform. Flow-based monitoring conserves bandwidth by monitoring only specified traffic instead of all traffic on the interface. This feature is particularly useful when looking for malicious traffic. It is available for Layer 2 and Layer 3 ingress and egress traffic. You can specify traffic using standard or extended access-lists. 1. Enable flow-based monitoring for a monitoring session.
--------- ------ ----------- --------- ------0 Te 1/1 Te 1/2 rx interface Flow-based Remote Port Mirroring While local port monitoring allows you to monitor traffic from one or more source ports by directing it to a destination port on the same switch/router, remote port mirroring allows you to monitor Layer 2 and Layer 3 ingress and/or egress traffic on multiple source ports on different switches and forward the mirrored traffic to multiple destination ports on different switches.
Configuring Remote Port Mirroring Remote port mirroring requires a source session (monitored ports on different source switches), a reserved tagged VLAN for transporting mirrored traffic (configured on source, intermediate, and destination switches), and a destination session (destination ports connected to analyzers on destination switches).
• The member port of the reserved VLAN should have MTU and IPMTU value as MAX+4 (to hold the VLAN tag parameter). • To associate with source session, the reserved VLAN can have at max of only 4 member ports. • To associate with destination session, the reserved VLAN can have multiple member ports. • Reserved Vlan cannot have untagged ports In the reserved L2 VLAN used for remote port mirroring: • MAC address learning in the reserved VLAN is automatically disabled.
• A destination port cannot be used in any spanning tree instance. • The reserved VLAN used to transport mirrored traffic must be a L2 VLAN. L3 VLANs are not supported. • On a source switch on which you configure source ports for remote port mirroring, you can add only one port to the dedicated RPM VLAN which is used to transport mirrored traffic. You can configure multiple ports for the dedicated RPM VLAN on intermediate and destination switches.
2 monitor session type rpm The needs to be unique and not already defined in the box specifying type as 'rpm' defines a RPM session. 3 source Interface | Range Specify the port or list of ports that needs to be monitored 4 direction Specify rx, tx or both in case to monitor ingress/ egress or both ingress and egress packets on the specified port.. 5 rpm source-ip dest-ip Specify the source ip address and the destination ip where the packet needs to be sent.
Dell(conf)#interface port-channel 10 Dell(conf-if-po-10)#channel-member te 1/28-29 Dell(conf-if-po-10)#no shutdown Dell(conf-if-po-10)#exit Dell(conf)#monitor session 3 type rpm Dell(conf-mon-sess-3)#source port-channel 10 dest remote-vlan 30 dir both Dell(conf-mon-sess-3)#no disable Dell(conf-mon-sess-3)# Dell(conf-mon-sess-3)#exit Dell(conf)#end Dell# Dell#show monitor session SessID Source Destination ------ ---------------1 Te 1/5 remote-vlan 10 2 Vl 100 remote-vlan 20 3 Po 10 remote-vlan 30 Dell# Dir
Dell(conf)#monitor session 3 type rpm Dell(conf-mon-sess-3)#source remote-vlan 30 destination te 1/6 Dell(conf-mon-sess-3)#tagged destination te 1/6 Dell(conf-mon-sess-3)#end Dell# Dell#show monitor session SessID Source Destination Dir Mode Source IP ------ ------------------ ---- --------1 remote-vlan 10 Te 1/4 N/A N/A N/A 2 remote-vlan 20 Te 1/5 N/A N/A N/A 3 remote-vlan 30 Te 1/6 N/A N/A N/A Dell# Dest IP -------N/A N/A N/A Configuring RSPAN Source Sessions to Avoid BPD Issues When ever you configure
Configuring the Encapsulated Remote Port Mirroring The ERPM session copies traffic from the source ports/lags or source VLANs and forwards the traffic using routable GRE-encapsulated packets to the destination ip address specified in the session. Important: The steps to be followed for the ERPM Encapsulation : • Dell Networking OS supports ERPM Source session only. The Encapsulated packets terminate at the destination ip or at the analyzer.
4 direction Specify rx, tx or both in case to monitor ingress/egress or both ingress and egress packets on the specified port.. 5 erpm source-ip dest-ip Specify the source ip address and the destination ip where the packet needs to be sent. 6 flow-based enable Specify flow-based enable for mirroring on a flow by flow basis and also for vlan as source. 7 no disable No disable command is mandatory in order for a erpm session to be active.
ERPM Behavior on a typical Dell Networking OS The Dell Networking OS is designed to support only the Encapsulation of the data received / transmitted at the specified source port (Port A). An ERPM destination session / decapsulation of the ERPM packets at the destination Switch are not supported. As seen in the above figure, the packets received/transmitted on Port A will be encapsulated with an IP/GRE header plus a new L2 header and sent to the destination ip address (Port D’s ip address) on the sniffer.
39th byte in a given ERPM packet. The first 38/42 bytes of the header needs to be ignored/ chopped off. – Some tools support options to edit the capture file. We can make use of such features (for example: editcap ) and chop the ERPM header part and save it to a new trace file. This new file (i.e. the original mirrored packet) can be converted back into stream and fed to any egress interface. b.
Private VLANs (PVLAN) 41 The private VLAN (PVLAN) feature is supported on Dell Networking OS. For syntax details about the commands described in this chapter, refer to the Private VLANs commands chapter in the Dell Networking OS Command Line Reference Guide. Private VLANs extend the Dell Networking OS security suite by providing Layer 2 isolation between ports within the same virtual local area network (VLAN).
– A switch can have one or more primary VLANs, and it can have none. – A primary VLAN has one or more secondary VLANs. – A primary VLAN and each of its secondary VLANs decrement the available number of VLAN IDs in the switch. – A primary VLAN has one or more promiscuous ports. – A primary VLAN might have one or more trunk ports, or none. • Secondary VLAN — a subdomain of the primary VLAN. – There are two types of secondary VLAN — community VLAN and isolated VLAN.
• Map secondary VLANs to the selected primary VLAN. INTERFACE VLAN mode • [no] private-vlan mapping secondary-vlan vlan-list Display type and status of PVLAN interfaces. EXEC mode or EXEC Privilege mode • show interfaces private-vlan [interface interface] Display PVLANs and/or interfaces that are part of a PVLAN. EXEC mode or EXEC Privilege mode • show vlan private-vlan [community | interface | isolated | primary | primary_vlan | interface interface] Display primary-secondary VLAN mapping.
switchport 4. Select the PVLAN mode. INTERFACE mode switchport mode private-vlan {host | promiscuous | trunk} • host (isolated or community VLAN port) • promiscuous (intra-VLAN communication port) • trunk (inter-switch PVLAN hub port) Example of the switchport mode private-vlan Command For interface details, refer to Enabling a Physical Interface in the Interfaces chapter. NOTE: You cannot add interfaces that are configured as PVLAN ports to regular VLANs.
4. Map secondary VLANs to the selected primary VLAN. INTERFACE VLAN mode private-vlan mapping secondary-vlan vlan-list The list of secondary VLANs can be: 5. • Specified in comma-delimited (VLAN-ID,VLAN-ID) or hyphenated-range format (VLAN-IDVLAN-ID). • Specified with this command even before they have been created. • Amended by specifying the new secondary VLAN to be added to the list. Add promiscuous ports as tagged or untagged interfaces.
4. Add one or more host ports to the VLAN. INTERFACE VLAN mode tagged interface or untagged interface You can enter the interfaces singly or in range format, either comma-delimited (slot/ port,port,port) or hyphenated (slot/ port-port). You can only add host (isolated) ports to the VLAN. Creating an Isolated VLAN An isolated VLAN is a secondary VLAN of a primary VLAN. An isolated VLAN port can only talk with the promiscuous ports in that primary VLAN. 1.
Dell(conf-vlan-100)# private-vlan mode isolated Dell(conf-vlan-100)# untagged Te 2/2 Private VLAN Configuration Example The following example shows a private VLAN topology. Figure 104. Sample Private VLAN Topology The following configuration is based on the example diagram for the Z9500: • Te 1/1 and Te 1/23 are configured as promiscuous ports, assigned to the primary VLAN, VLAN 4000. • Te 1/25 is configured as a PVLAN trunk port, also assigned to the primary VLAN 4000.
• The ports in isolated VLAN 4003 can only communicate with the promiscuous ports in the primary VLAN 4000. • All the ports in the secondary VLANs (both community and isolated VLANs) can only communicate with ports in the other secondary VLANs of that PVLAN over Layer 3, and only when the ip localproxy-arp command is invoked in the primary VLAN.
• The following examples show the results of using this command without the command options on the C300 and S50V switches in the topology diagram previously shown. Display the primary-secondary VLAN mapping. The following example shows the output from the S50V. show vlan private-vlan mapping This command is specific to the PVLAN feature. Examples of Viewing a Private VLAN using the show Commands The show arp and show vlan commands are revised to display PVLAN data.
! interface TenGigabitEthernet 1/5 no ip address switchport switchport mode private-vlan host no shutdown ! interface TenGigabitEthernet 1/6 no ip address switchport switchport mode private-vlan host no shutdown ! interface TenGigabitEthernet 1/25 no ip address switchport switchport mode private-vlan trunk no shutdown ! interface Vlan 4000 private-vlan mode primary private-vlan mapping secondary-vlan 4001-4003 no ip address tagged TenGigabitEthernet 1/3,25 no shutdown ! interface Vlan 4001 private-vlan mode
Per-VLAN Spanning Tree Plus (PVST+) 42 Per-VLAN spanning tree plus (PVST+) is supported on Dell Networking OS. Protocol Overview PVST+ is a variation of spanning tree — developed by a third party — that allows you to configure a separate spanning tree instance for each virtual local area network (VLAN). For more information about spanning tree, refer to the Spanning Tree Protocol (STP) chapter. Figure 105.
Table 56. Spanning Tree Variations Dell Networking OS Supports Dell Networking Term IEEE Specification Spanning Tree Protocol (STP) 802 .1d Rapid Spanning Tree Protocol (RSTP) 802 .1w Multiple Spanning Tree Protocol (MSTP) 802 .1s Per-VLAN Spanning Tree Plus (PVST+) Third Party Implementation Information • The Dell Networking OS implementation of PVST+ is based on IEEE Standard 802.1w. • The Dell Networking OS implementation of PVST+ uses IEEE 802.
protocol spanning-tree pvst 2. Enable PVST+. PROTOCOL PVST mode no disable Disabling PVST+ To disable PVST+ globally or on an interface, use the following commands. • Disable PVST+ globally. PROTOCOL PVST mode • disable Disable PVST+ on an interface, or remove a PVST+ parameter configuration. INTERFACE mode no spanning-tree pvst Example of Viewing PVST+ Configuration To display your PVST+ configuration, use the show config command from PROTOCOL PVST mode.
Figure 106. Load Balancing with PVST+ The bridge with the bridge value for bridge priority is elected root. Because all bridges use the default priority (until configured otherwise), the lowest MAC address is used as a tie-breaker. To increase the likelihood that a bridge is selected as the STP root, assign bridges a low non-default value for bridge priority. To assign a bridge priority, use the following command. • Assign a bridge priority.
Root Identifier has priority 4096, Address 0001.e80d.b6d6 Root Bridge hello time 2, max age 20, forward delay 15 Bridge Identifier has priority 4096, Address 0001.e80d.b6d6 Configured hello time 2, max age 20, forward delay 15 We are the root of VLAN 100 Current root has priority 4096, Address 0001.e80d.b6d6 Number of topology changes 5, last change occurred 00:34:37 ago on Te 1/32 Port 375 (TenGigabitEthernet 1/22) is designated Forwarding Port path cost 20000, Port priority 128, Port Identifier 128.
PROTOCOL PVST mode vlan max-age The range is from 6 to 40. The default is 20 seconds. The values for global PVST+ parameters are given in the output of the show spanning-tree pvst command. Modifying Interface PVST+ Parameters You can adjust two interface parameters (port cost and port priority) to increase or decrease the probability that a port becomes a forwarding port. • Port cost — a value that is based on the interface type.
The range is from 0 to 240, in increments of 16. The default is 128. The values for interface PVST+ parameters are given in the output of the show spanning-tree pvst command, as previously shown. Configuring an EdgePort The EdgePort feature enables interfaces to begin forwarding traffic approximately 30 seconds sooner. In this mode an interface forwards frames by default until it receives a BPDU that indicates that it should behave otherwise; it does not go through the Learning and Listening states.
PVST+ in Multi-Vendor Networks Some non-Dell Networking systems which have hybrid ports participating in PVST+ transmit two kinds of BPDUs: an 802.1D BPDU and an untagged PVST+ BPDU. Dell Networking systems do not expect PVST+ BPDU (tagged or untagged) on an untagged port. If this situation occurs, Dell Networking OS places the port in an Error-Disable state. This behavior might result in the network not converging.
Example of Viewing the Extend System ID in a PVST+ Configuration Dell(conf-pvst)#do show spanning-tree pvst vlan 5 brief VLAN 5 Executing IEEE compatible Spanning Tree Protocol Root ID Priority 32773, Address 0001.e832.73f7 Root Bridge hello time 2, max age 20, forward delay 15 Bridge ID Priority 32773 (priority 32768 sys-id-ext 5), Address 0001.e832.
no ip address tagged TenGigabitEthernet 2/12,32 no shutdown ! interface Vlan 200 no ip address tagged TenGigabitEthernet 2/12,32 no shutdown ! interface Vlan 300 no ip address tagged TenGigabitEthernet 2/12,32 no shutdown ! protocol spanning-tree pvst no disable vlan 200 bridge-priority 4096 Example of PVST+ Configuration (R3) interface TenGigabitEthernet 3/12 no ip address switchport no shutdown ! interface TenGigabitEthernet 3/22 no ip address switchport no shutdown ! interface Vlan 100 no ip address tag
Quality of Service (QoS) 43 Quality of service (QoS) is supported on Dell Networking OS. Differentiated service is accomplished by classifying and queuing traffic, and assigning priorities to those queues. Table 58.
Feature Direction Configure a Scheduler to Queue Egress Specify WRED Drop Precedence Egress Create Policy Maps Ingress + Egress Create Input Policy Maps Ingress Honor DSCP Values on Ingress Packets Ingress Honoring dot1p Values on Ingress Packets Ingress Create Output Policy Maps Egress Specify an Aggregate QoS Policy Egress Create Output Policy Maps Egress Enabling QoS Rate Adjustment Enabling StrictPriority Queueing Weighted Random Early Detection Egress Create WRED Profiles Egress
Figure 108. Dell Networking QoS Architecture Implementation Information The Dell Networking QoS implementation complies with IEEE 802.1p User Priority Bits for QoS Indication.
• Configuring Port-Based Rate Shaping Setting dot1p Priorities for Incoming Traffic Dell Networking OS places traffic marked with a priority in a queue based on the following table. If you set a dot1p priority for a port-channel, all port-channel members are configured with the same value. You cannot assign a dot1p value to an individual interface in a port-channel. Table 59.
Example of Configuring an Interface to Honor dot1p Priorities on Ingress Traffic Dell#configure terminal Dell(conf)#interface tengigabitethernet 1/1 Dell(conf-if-te-1/1)#service-class dynamic dot1p Dell(conf-if-te-1/1)#end Priority-Tagged Frames on the Default VLAN Priority-tagged frames are 802.1Q tagged frames with VLAN ID 0. For VLAN classification, these packets are treated as untagged. However, the dot1p value is still honored when you configure service-class dynamic dot1p or trust dot1p.
QoS Policy mode rate-shape Example of rate shape Command Dell#configure terminal Dell(conf)#interface tengigabitethernet 1/1 Dell(conf-if-te-1/1)#rate shape 500 50 Dell(conf-if-te-1/1)#end Policy-Based QoS Configurations Policy-based QoS configurations consist of the components shown in the following example. Figure 109.
Classify Traffic Class maps differentiate traffic so that you can apply separate quality of service policies to different types of traffic. For both class maps, Layer 2 and Layer 3, Dell Networking OS matches packets against match criteria in the order that you configure them. Creating a Layer 3 Class Map A Layer 3 class map differentiates ingress packets based on the DSCP value or IP precedence, and characteristics defined in an IP ACL.
Dell(conf)#policy-map-input pmap Dell(conf-policy-map-in)#service-queue 3 class-map cmap1 Dell(conf-policy-map-in)#service-queue 1 class-map cmap2 Dell(conf-policy-map-in)#exit Dell(conf)#interface tengigabitethernet 1/1 Dell(conf-if-te-1/1)#service-policy input pmap Examples of Creating a Layer 3 IPv6 Class Map The following example matches IPv6 traffic with a DSCP value of 40.
ACLs acl1 and acl2 have overlapping rules because the address range 20.1.1.0/24 is within 20.0.0.0/8. Therefore (without the keyword order), packets within the range 20.1.1.0/24 match positive against cmap1 and are buffered in queue 7, though you intended for these packets to match positive against cmap2 and be buffered in queue 4. In cases such as these, where class-maps with overlapping ACL rules are applied to different queues, use the keyword order.
seq 10 deny ip any any ! ip access-list extended AF2 seq 5 permit ip host 23.64.0.5 any seq 10 deny ip any any Dell# show cam layer3-qos interface tengigabitethernet 2/4 Cam Port Dscp Proto Tcp Src Dst SrcIp DstIp DSCP Queue Index Flag Port Port Marking ----------------------------------------------------------------------20416 1 18 IP 0x0 0 0 23.64.0.5/32 0.0.0.0/0 20 2 20417 1 18 IP 0x0 0 0 0.0.0.0/0 0.0.0.0/0 0 20418 1 0 IP 0x0 0 0 23.64.0.2/32 0.0.0.0/0 10 1 20419 1 0 IP 0x0 0 0 0.0.0.0/0 0.0.0.
NOTE: To avoid issues misconfiguration causes, Dell Networking recommends configuring either DCBX or Egress QoS features, but not both simultaneously. If you enable both DCBX and Egress QoS at the same time, the DCBX configuration is applied and unexpected behavior occurs on the Egress QoS. Creating an Input QoS Policy To create an input QoS policy, use the following steps. 1. Create a Layer 3 input QoS policy.
Configuring Policy-Based Rate Shaping To configure policy-based rate shaping, use the following command. • Configure rate shape egress traffic. QOS-POLICY-OUT mode rate-shape Allocating Bandwidth to Queue Schedule packets for egress based on Deficit Round Robin (DRR). These strategies both offer a guaranteed data rate. The following table lists the default bandwidth weights for each queue, and their equivalent percentage which is derived by dividing the bandwidth weight by the sum of all queue weights.
Honoring DSCP Values on Ingress Packets Honoring dot1p Values on Ingress Packets 3. Apply the input policy map to an interface. Applying a Class-Map or Input QoS Policy to a Queue To apply a class-map or input QoS policy to a queue, use the following command. • Assign an input QoS policy to a queue. POLICY-MAP-IN mode service-queue Applying an Input QoS Policy to an Input Policy Map To apply an input QoS policy to an input policy map, use the following command.
Honoring dot1p Values on Ingress Packets Dell Networking OS honors dot1p values on ingress packets with the Trust dot1p feature. The following table specifies the queue to which the classified traffic is sent based on the dot1p value. Table 62. Default dot1p to Queue Mapping dot1p Queue ID 0 2 1 0 2 1 3 3 4 4 5 5 6 6 7 7 Table 63. Default dot1p to Queue Mapping dot1p Queue ID 0 0 1 0 2 0 3 1 4 2 5 3 6 3 7 3 The dot1p value is also honored for frames on the default VLAN.
INTERFACE mode service-class dynamic dot1p Guaranteeing Bandwidth to dot1p-Based Service Queues To guarantee bandwidth to dot1p-based service queues, use the following command. Apply this command in the same way as the bandwidth-percentage command in an output QoS policy (refer to Allocating Bandwidth to Queue). The bandwidth-percentage command in QOSPOLICY-OUT mode supersedes the service-class bandwidth-percentage command. • Guarantee a minimum bandwidth to queues globally.
Specifying an Aggregate QoS Policy To specify an aggregate QoS policy, use the following command. • Specify an aggregate QoS policy. POLICY-MAP-OUT mode policy-aggregate Applying an Output Policy Map to an Interface To apply an output policy map to an interface, use the following command. • Apply an input policy map to an interface. INTERFACE mode service-policy output You can apply the same policy map to multiple interfaces, and you can modify a policy map after you apply it.
• If you configured a DSCP color map on an interface that does not exist or you delete a DSCP color map that is configured on an interface, that interface uses an all green color policy. To create a DSCP color map: 1. Create the color-aware map QoS DSCP color map. CONFIGURATION mode qos dscp-color-map color-map-name 2. Create the color aware map profile. DSCP-COLOR-MAP dscp {yellow | red} {list-dscp-values} 3. Apply the map profile to the interface.
Display a specific DSCP color map. Dell# show qos dscp-color-map mapTWO Dscp-color-map mapTWO yellow 16,55 Displaying a DSCP Color Policy Configuration To display the DSCP color policy configuration for one or all interfaces, use the show qos dscpcolor-policy {summary [interface] | detail {interface}} command in EXEC mode. summary: Displays summary information about a color policy on one or more interfaces.
You can optionally include overhead fields in rate metering calculations by enabling QoS rate adjustment. QoS rate adjustment is disabled by default. • Specify the number of bytes of packet overhead to include in rate limiting, policing, and shaping calculations. CONFIGURATION mode qos-rate-adjust overhead-bytes For example, to include the Preamble and SFD, type qos-rate-adjust 8. For variable length overhead fields, know the number of bytes you want to include. The default is disabled.
Figure 110. Packet Drop Rate for WRED You can create a custom WRED profile or use one of the five pre-defined profiles. Table 64. Pre-Defined WRED Profiles Default Profile Name Minimum Threshold Maximum Threshold Maximum Drop Rate wred_drop 0 0 100 wred_teng_y 467 4671 100 wred_teng_g 467 4671 50 wred_fortyg_y 467 4671 50 wred_fortyg_g 467 4671 25 Creating WRED Profiles To create WRED profiles, use the following commands. 1. Create a WRED profile.
Applying a WRED Profile to Traffic After you create a WRED profile, you must specify to which traffic Dell Networking OS should apply the profile. Dell Networking OS assigns a color (also called drop precedence) — red, yellow, or green — to each packet based on it DSCP value before queuing it. DSCP is a 6–bit field. Dell Networking uses the first three bits (LSB) of this field (DP) to determine the drop precedence. • DP values of 110 and 100, 101 map to yellow; all other values map to green.
Dell# Displaying egress-queue Statistics To display the number of transmitted and dropped packets on the egress queues of a WRED-configured interface, use the following command. • Display the number of packets and number of bytes on the egress-queue profile. EXEC Privilege mode show qos statistics egress-queue Example of the show qos statistics egress-queue Command Pre-Calculating Available QoS CAM Space Before Dell Networking OS version 7.3.
– Allowed — indicates that the policy-map can be applied because the estimated number of CAM entries is less or equal to the available number of CAM entries. The number of interfaces in the port-pipe to which the policy-map can be applied is given in parentheses. – Exception — indicates that the number of CAM entries required to write the policy-map to the CAM is greater than the number of available CAM entries, and therefore the policy-map cannot be applied to an interface in the specified port-pipe.
The weight factor is set to zero by default, which causes the same behavior as dropping of packets by WRED during network loads or also called instantaneous ECN marking. In a topology in which congestion of the network varies over time, you can specify a weight to enable a smooth, seamless averaging of packets to handle the sudden overload of packets based on the previous time sampling performed. You can specify the weight parameter for front-end and backplane ports separately in the range of 0 through 15.
Table 65. Scenarios of WRED and ECN Configuration Queue Configuration Service-Pool Configuration WRED Threshold Relationship Q threshold = QT, Service pool threshold = SP-T Expected Functionality WRED ECN WRED ECN 0 0 X X X WRED/ECN not applicable 1 0 0 X X Queue based WRED, 1 X Q-T < SP-T No ECN marking SP-T < Q-T SP based WRED, No ECN marking 1 1 0 X X 1 X Q-T < SP-T SP-T < Q-T Queue-based ECN marking above queue threshold.
3. Configure another WRED profile, and specify the threshold and maximum drop rate. WRED mode Dell(conf-wred) #wred—profile thresh-2 Dell(conf-wred) #threshold min 300 max 400 max-drop-rate 80 4. Create a global buffer pool that is a shared buffer pool accessed by multiple queues when the minimum guaranteed buffers for the queue are consumed.
Sample configuration to mark non-ecn packets as “yellow” with Multiple traffic class Consider the example where there are no different traffic classes that is all the packets are egressing on the default ‘queue0’. Dell Networking OS can be configured as below to mark the non-ecn packets as yellow packets.
Until Release 9.3(0.0), support is available for classifying traffic based on the 6-bit DSCP field of the IPv4 packet. As a part of this feature, the 2-bit ECN field of the IPv4 packet will also be available to be configured as one of the match qualifier. This way the entire 8-bit ToS field of the IPv4 header shall be used to classify traffic. The Dell Networking OS Release 9.3(0.0) supports the following QOS actions in the ingress policy based QOS: 1. Rate Policing 2. Queuing 3.
• Classification based on ECN and DSCP concurrently You can now use the set-color yellow keyword with the match ip access-group command to mark the color of the traffic as ‘yellow’ would be added in the ‘match ip’ sequence of the class-map configuration. By default, all packets are considered as ‘green’ (without the rate-policer and trust-diffserve configuration) and hence support would be provided to mark the packets as ‘yellow’ alone will be provided.
match ip access-group dscp_40_non_ecn set-color yellow match ip access-group dscp_40 ! class-map match-any class_dscp_50 match ip access-group dscp_50_non_ecn set-color yellow match ip access-group dscp_50 ! policy-map-input pmap_dscp_40_50 service-queue 2 class-map class_dscp_40 service-queue 3 class-map class_dscp_50 Approach with explicit ECN match qualifiers for ECN packets: ! ip access-list standard dscp_50_ecn seq 5 permit any dscp 50 ecn 1 seq 10 permit any dscp 50 ecn 2 seq 15 permit any dscp 50 ec
Dell(conf)# interface fo 1/4 INTERFACE mode Dell(conf-if-fo-1/4)# ip address 90.1.1.1/16 2. Configure a Layer 2 QoS policy with Layer 2 (Dot1p or source MAC-based) match criteria. CONFIGURATION mode Dell(conf)# policy-map-input l2p layer2 3. Apply the Layer 2 policy on a Layer 3 interface.
QOS-POLICY-IN mode Dell(conf-qos-policy-in)#set ip-dscp 5 6. Create an input policy map. CONFIGURATION mode Dell(conf)#policy-map-input pp_policmap 7. Create a service queue to associate the class map and QoS policy map.
As a part of this feature, the 2-bit ECN field of the IPv4 packet will also be available to be configured as one of the match qualifier. This way the entire 8-bit ToS field of the IPv4 header shall be used to classify traffic. The Dell Networking OS Release 9.3(0.0) supports the following QOS actions in the ingress policy based QOS: 1. Rate Policing 2. Queuing 3. Marking For the L3 Routed packets, the DSCP marking is the only marking action supported in the software.
By default, all packets are considered as ‘green’ (without the rate-policer and trust-diffserve configuration) and hence support would be provided to mark the packets as ‘yellow’ alone will be provided. By default Dell Networking OS drops all the ‘RED’ or ‘violate’ packets.
– CIR < x< PIR – will be marked as “Yellow” – PIR < x – will be marked as “Red” But ‘Green’ packets matching the specific match criteria for which ‘color-marking’ is configured will be over-written and marked as “Yellow”. Sample configuration to mark non-ecn packets as “yellow” with Multiple traffic class Consider the example where there are no different traffic classes that is all the packets are egressing on the default ‘queue0’.
! class-map match-any class_dscp_50 match ip access-group dscp_50_non_ecn set-color yellow match ip access-group dscp_50 ! policy-map-input pmap_dscp_40_50 service-queue 2 class-map class_dscp_40 service-queue 3 class-map class_dscp_50 Approach with explicit ECN match qualifiers for ECN packets: ! ip access-list standard dscp_50_ecn seq 5 permit any dscp 50 ecn 1 seq 10 permit any dscp 50 ecn 2 seq 15 permit any dscp 50 ecn 3 ! ip access-list standard dscp_40_ecn seq 5 permit any dscp 40 ecn 1 seq 10 permit
Enable this utility to be able to configure the parameters for buffer statistics tracking. By default, buffer statistics tracking is disabled. 2. Enable the buffer statistics tracking utility and enter the Buffer Statistics Snapshot configuration mode. CONFIGURATION mode Dell(conf)#buffer-stats-snapshot Dell(conf)#no disable Enable this utility to be able to configure the parameters for buffer statistics tracking. By default, buffer statistics tracking is disabled. 3.
Q# TYPE Q# TOTAL BUFFERED CELLS --------------------------------------MCAST 3 0 Unit 1 unit: 3 port: 29 (interface Fo 1/172) --------------------------------------Q# TYPE Q# TOTAL BUFFERED CELLS --------------------------------------MCAST 3 0 Unit 1 unit: 3 port: 33 (interface Fo 1/176) --------------------------------------Q# TYPE Q# TOTAL BUFFERED CELLS --------------------------------------MCAST 3 0 Unit 1 unit: 3 port: 37 (interface Fo 1/180) --------------------------------------Q# TYPE Q# TOTAL BUFFER
Routing Information Protocol (RIP) 44 Routing information protocol (RIP) is supported on Dell Networking OS. RIP is based on a distance-vector algorithm; it tracks distances or hop counts to nearby routers when establishing network connections. RIP protocol standards are listed in the Standards Compliance chapter. Protocol Overview RIP is the oldest interior gateway protocol. There are two versions of RIP: RIP version 1 (RIPv1) and RIP version 2 (RIPv2).
Implementation Information Dell Networking OS supports both versions of RIP and allows you to configure one version globally and the other version on interfaces or both versions on the interfaces. The following table lists the defaults for RIP in Dell Networking OS. Table 66.
Enabling RIP Globally By default, RIP is not enabled in Dell Networking OS. To enable RIP globally, use the following commands. 1. Enter ROUTER RIP mode and enable the RIP process on Dell Networking OS. CONFIGURATION mode router rip 2. Assign an IP network address as a RIP network to exchange routing information.
192.162.2.0/24 [120/1] via 29.10.10.12, 00:01:21, Fa 1/49 192.162.2.0/24 auto-summary 192.161.1.0/24 [120/1] via 29.10.10.12, 00:00:27, Fa 1/49 192.161.1.0/24 auto-summary 192.162.3.0/24 [120/1] via 29.10.10.12, 00:01:22, Fa 1/49 192.162.3.0/24 auto-summary To disable RIP globally, use the no router rip command in CONFIGURATION mode. Configure RIP on Interfaces When you enable RIP globally on the system, interfaces meeting certain conditions start receiving RIP routes.
• Assign a configured prefix list to all outgoing RIP routes. ROUTER RIP mode distribute-list prefix-list-name out To view the current RIP configuration, use the show running-config command in EXEC mode or the show config command in ROUTER RIP mode. Adding RIP Routes from Other Instances In addition to filtering routes, you can add routes from other routing instances or protocols to the RIP process.
You can set one RIP version globally on the system using system. This command sets the RIP version for RIP traffic on the interfaces participating in RIP unless the interface was specifically configured for a specific RIP version. • Set the RIP version sent and received on the system. ROUTER RIP mode • version {1 | 2} Set the RIP versions received on that interface. INTERFACE mode • ip rip receive version [1] [2] Set the RIP versions sent out on that interface.
The following example of the show ip protocols command confirms that both versions are sent out that interface. This interface no longer sends and receives the same RIP versions as Dell Networking OS does globally (shown in bold).
The autosummary command requires no other configuration commands. To disable automatic route summarization, enter no autosummary in ROUTER RIP mode. NOTE: If you enable the ip split-horizon command on an interface, the system does not advertise the summarized address. Controlling Route Metrics As a distance-vector protocol, RIP uses hop counts to determine the best route, but sometimes the shortest hop count is a route over the lowest-speed link.
Enable debugging of RIP. Example of the debug ip rip Command The following example shows the confirmation when you enable the debug function. Dell#debug ip rip RIP protocol debug is ON Dell# To disable RIP, use the no debug ip rip command. RIP Configuration Example The examples in this section show the command sequence to configure RIPv2 on the two routers shown in the following illustration — Core 2 and Core 3. The host prompts used in the following example reflect those names.
Core 2 RIP Output The examples in the section show the core 2 RIP output. Examples of the show ip Commands to View Core 2 Information • To display Core 2 RIP database, use the show ip rip database command. • To display Core 2 RIP setup, use the show ip route command. • To display Core 2 RIP activity, use the show ip protocols command. The following example shows the show ip rip database command to view the learned RIP routes on Core 2.
The following example shows the show ip protocols command to show the RIP configuration activity on Core 2.
Examples of the show ip Commands to View Learned RIP Routes on Core 3 The following example shows the show ip rip database command to view the learned RIP routes on Core 3. Core3#show ip rip database Total number of routes in RIP database: 7 10.11.10.0/24 [120/1] via 10.11.20.2, 00:00:13, TenGigabitEthernet 10.200.10.0/24 [120/1] via 10.11.20.2, 00:00:13, TenGigabitEthernet 10.300.10.0/24 [120/1] via 10.11.20.2, 00:00:13, TenGigabitEthernet 10.11.20.0/24 directly connected,TenGigabitEthernet 10.11.30.
TenGigabitEthernet 3/24 2 2 TenGigabitEthernet 3/23 2 2 Routing for Networks: 10.11.20.0 10.11.30.0 192.168.2.0 192.168.1.0 Routing Information Sources: Gateway Distance Last Update 10.11.20.2 120 00:00:22 Distance: (default is 120) Core3# RIP Configuration Summary Examples of Viewing RIP Configuration on Core 2 and Core 3 The following example shows viewing the RIP configuration on Core 2. ! interface TenGigabitEthernet ip address 10.11.10.1/24 no shutdown ! interface TenGigabitEthernet ip address 10.11.
ip address 192.168.2.1/24 no shutdown ! router rip version 2 network 10.11.20.0 network 10.11.30.0 network 192.168.1.0 network 192.168.2.
Remote Monitoring (RMON) 45 Remote monitoring (RMON) is supported on Dell Networking OS. RMON is an industry-standard implementation that monitors network traffic by sharing network monitoring information. RMON provides both 32-bit and 64-bit monitoring facility and long-term statistics collection on Dell Networking Ethernet interfaces. RMON operates with the simple network management protocol (SNMP) and monitors all nodes on a local area network (LAN) segment.
• RPM Down, RPM Failover — Master and standby route processor modules (RPMs) run the RMON sampling process in the background. Therefore, when an RPM goes down, the other RPM maintains the sampled data — the new master RPM provides the same sampled data as did the old master — as long as the master RPM had been running long enough to sample all the data. NMS backs up all the long-term data collection and displays the failover downtime from the performance graph.
– owner string: (Optional) specifies an owner for the alarm, this setting is the alarmOwner object in the alarmTable of the RMON MIB. Default is a null-terminated string. Example of the rmon alarm Command To disable the alarm, use the no form of the command. The following example configures RMON alarm number 10. The alarm monitors the MIB variable 1.3.6.1.2.1.2.2.1.20.1 (ifEntry.ifOutErrors) once every 20 seconds until the alarm is disabled, and checks the rise or fall of the variable.
Configuring RMON Collection Statistics To enable RMON MIB statistics collection on an interface, use the RMON collection statistics command in INTERFACE CONFIGURATION mode. • Enable RMON MIB statistics collection. CONFIGURATION INTERFACE (config-if) mode [no] rmon collection statistics {controlEntry integer} [owner ownername] – controlEntry: specifies the RMON group of statistics using a value. – integer: a value from 1 to 65,535 that identifies the RMON Statistics Table.
The following command example enables an RMON MIB collection history group of statistics with an ID number of 20 and an owner of john, both the sampling interval and the number of buckets use their respective defaults.
Rapid Spanning Tree Protocol (RSTP) 46 Rapid spanning tree protocol (RSTP) is supported on Dell Networking OS. Protocol Overview RSTP is a Layer 2 protocol — specified by IEEE 802.1w — that is essentially the same as spanning-tree protocol (STP) but provides faster convergence and interoperability with switches configured with STP and multiple spanning tree protocol (MSTP). The Dell Networking OS supports three other variations of spanning tree, as shown in the following table. Table 67.
Important Points to Remember • RSTP is disabled by default. • Dell Networking OS supports only one Rapid Spanning Tree (RST) instance. • All interfaces in virtual local area networks (VLANs) and all enabled interfaces in Layer 2 mode are automatically added to the RST topology. • Adding a group of ports to a range of VLANs sends multiple messages to the rapid spanning tree protocol (RSTP) task, avoid using the range command.
INTERFACE mode no shutdown Example of Verifying an Interface is in Layer 2 Mode and Enabled To verify that an interface is in Layer 2 mode and enabled, use the show config command from INTERFACE mode. The bold lines indicate that the interface is in Layer 2 mode. Enabling Rapid Spanning Tree Protocol Globally Enable RSTP globally on all participating bridges; it is not enabled by default.
Figure 112. Rapid Spanning Tree Enabled Globally To view the interfaces participating in RSTP, use the show spanning-tree rstp command from EXEC privilege mode. If a physical interface is part of a port channel, only the port channel is listed in the command output. Dell#show spanning-tree rstp Root Identifier has priority 32768, Address 0001.e801.cbb4 Root Bridge hello time 2, max age 20, forward delay 15, max hops 0 Bridge Identifier has priority 32768, Address 0001.e801.
The port is not in the Edge port mode Port 379 (TenGigabitEthernet 2/3) is designated Forwarding Port path cost 20000, Port priority 128, Port Identifier 128.379 Designated root has priority 32768, address 0001.e801.cbb4 Designated bridge has priority 32768, address 0001.e801.cbb4 Designated port id is 128.
Modifying Global Parameters You can modify RSTP parameters. The root bridge sets the values for forward-delay, hello-time, and max-age and overwrites the values set on other bridges participating in the Rapid Spanning Tree group. • Forward-delay — the amount of time an interface waits in the Listening state and the Learning state before it transitions to the Forwarding state. • Hello-time — the time interval in which the bridge sends RSTP BPDUs.
NOTE: With large configurations (especially those configurations with more ports) Dell Networking recommends increasing the hello-time. The range is from 1 to 10. • The default is 2 seconds. Change the max-age parameter. PROTOCOL SPANNING TREE RSTP mode max-age seconds The range is from 6 to 40. The default is 20 seconds. To view the current values for global parameters, use the show spanning-tree rstp command from EXEC privilege mode.
To view the current values for interface parameters, use the show spanning-tree rstp command from EXEC privilege mode. Enabling SNMP Traps for Root Elections and Topology Changes To enable SNMP traps collectively, use this command. Enable SNMP traps for RSTP, MSTP, and PVST+ collectively. snmp-server enable traps xstp Influencing RSTP Root Selection RSTP determines the root bridge, but you can assign one bridge a lower priority to increase the likelihood that it is selected as the root bridge.
• If the interface to be shut down is a port channel, all the member ports are disabled in the hardware. • When you add a physical port to a port channel already in the Error Disable state, the new member port is also disabled in the hardware. • When you remove a physical port from a port channel in the Error Disable state, the error disabled state is cleared on this physical port (the physical port is enabled in the hardware).
The range is from 50 to 950 milliseconds. Example of Verifying Hello-Time Interval Dell(conf-rstp)#do show spanning-tree rstp brief Executing IEEE compatible Spanning Tree Protocol Root ID Priority 0, Address 0001.e811.2233 Root Bridge hello time 50 ms, max age 20, forward delay 15 Bridge ID Priority 0, Address 0001.e811.2233 We are the root Configured hello time 50 ms, max age 20, forward delay 15 NOTE: The hello time is encoded in BPDUs in increments of 1/256ths of a second.
Software-Defined Networking (SDN) 47 Dell Networking operating software supports Software-Defined Networking (SDN). For more information, refer to the SDN Deployment Guide.
Security 48 Security features are supported on Dell Networking OS. This chapter describes several ways to provide security to the Dell Networking system. For details about all the commands described in this chapter, refer to the Security chapter in the Dell Networking OS Command Reference Guide. AAA Accounting Accounting, authentication, and authorization (AAA) accounting is part of the AAA security model.
– system: sends accounting information of any other AAA configuration. – exec: sends accounting information when a user has logged in to EXEC mode. – command level: sends accounting of commands executed at the specified privilege level. – suppress: Do not generate accounting records for a specific type of user. – default | name: enter the name of a list of accounting methods.
accounting commands 15 com15 accounting exec execAcct Example of Enabling AAA Accounting with a Named Method List Dell(config-line-vty)# accounting commands 15 com15 Dell(config-line-vty)# accounting exec execAcct Monitoring AAA Accounting Dell Networking OS does not support periodic interim accounting because the periodic command can cause heavy congestion when many users are logged in to the network. No specific show command exists for TACACS+ accounting.
NOTE: RADIUS and TACACS servers support VRF-awareness functionality. You can create RADIUS and TACACS groups and then map multiple servers to a group. The group to which you map multiple servers is bound to a single VRF. Configuration Task List for AAA Authentication The following sections provide the configuration tasks.
3. Assign a method-list-name or the default list to the terminal line. LINE mode login authentication {method-list-name | default} To view the configuration, use the show config command in LINE mode or the show runningconfig in EXEC Privilege mode. NOTE: Dell Networking recommends using the none method only as a backup. This method does not authenticate users. The none and enable methods do not work with secure shell (SSH). You can create multiple method lists and assign them to different terminal lines.
Dell(config)# radius-server host x.x.x.x key Dell(config)# tacacs-server host x.x.x.x key To use local authentication for enable secret on the console, while using remote authentication on VTY lines, issue the following commands. The following example shows enabling local authentication for console and remote authentication for the VTY lines.
AAA Authorization Dell Networking OS enables AAA new-model by default. You can set authorization to be either local or remote. Different combinations of authentication and authorization yield different results. By default, Dell Networking OS sets both to local. Privilege Levels Overview Limiting access to the system is one method of protecting the system and your network. However, at times, you might need to allow others access to the router and you can limit that access to a subset of commands.
For a complete listing of all commands related to Dell Networking OS privilege levels and passwords, refer to the Security chapter in the Dell Networking OS Command Reference Guide. Configuring a Username and Password In Dell Networking OS, you can assign a specific username to limit user access to the system. To configure a username and password, use the following command. • Assign a user name and password.
Configuring Custom Privilege Levels In addition to assigning privilege levels to the user, you can configure the privilege levels of commands so that they are visible in different privilege levels. Within Dell Networking OS, commands have certain privilege levels. With the privilege command, you can change the default level or you can reset their privilege level back to the default. • Assign the launch keyword (for example, configure) for the keyword’s command mode.
• • command: an Dell Networking OS CLI keyword (up to five keywords allowed). reset: return the command to its default privilege mode. Examples of Privilege Level Commands To view the configuration, use the show running-config command in EXEC Privilege mode. The following example shows a configuration to allow a user john to view only EXEC mode commands and all snmp-server commands.
end exit no snmp-server Dell(conf)# Exit from Configuration mode Exit from Configuration mode Reset a command Modify SNMP parameters Specifying LINE Mode Password and Privilege You can specify a password authentication of all users on different terminal lines. The user’s privilege level is the same as the privilege level assigned to the terminal line, unless a more specific privilege level is assigned to the user. To specify a password for the terminal line, use the following commands.
the RADIUS server and requests authentication of the user and password. The RADIUS server returns one of the following responses: • Access-Accept — the RADIUS server authenticates the user. • Access-Reject — the RADIUS server does not authenticate the user. If an error occurs in the transmission or reception of RADIUS packets, you can view the error by enabling the debug radius command. Transactions between the RADIUS server and the client are encrypted (the users’ passwords are not sent in plain text).
Privilege Levels Through the RADIUS server, you can configure a privilege level for the user to enter into when they connect to a session. This value is configured on the client system. • Set a privilege level. privilege level Configuration Task List for RADIUS To authenticate users using RADIUS, you must specify at least one RADIUS server so that the system can communicate with and configure RADIUS as one of your authentication methods. The following list includes the configuration tasks for RADIUS.
Applying the Method List to Terminal Lines To enable RADIUS AAA login authentication for a method list, apply it to a terminal line. To configure a terminal line for RADIUS authentication and authorization, use the following commands. • Enter LINE mode. CONFIGURATION mode • line {aux 0 | console 0 | vty number [end-number]} Enable AAA login authentication for the specified RADIUS method list.
If you want to change an optional parameter setting for a specific host, use the radius-server host command. To change the global communication settings to all RADIUS server hosts, refer to Setting Global Communication Parameters for all RADIUS Server Hosts. To view the RADIUS configuration, use the show running-config radius command in EXEC Privilege mode. To delete a RADIUS server host, use the no radius-server host {hostname | ip-address} command.
debug radius TACACS+ Dell Networking OS supports terminal access controller access control system (TACACS+ client, including support for login authentication. Configuration Task List for TACACS+ The following list includes the configuration task for TACACS+ functions.
Example of a Failed Authentication To view the configuration, use the show config in LINE mode or the show running-config tacacs + command in EXEC Privilege mode. If authentication fails using the primary method, Dell Networking OS employs the second method (or third method, if necessary) automatically. For example, if the TACACS+ server is reachable, but the server key is invalid, Dell Networking OS proceeds to the next authentication method.
Example of Specifying a TACACS+ Server Host Dell(conf)# Dell(conf)#aaa authentication login tacacsmethod tacacs+ Dell(conf)#aaa authentication exec tacacsauthorization tacacs+ Dell(conf)#tacacs-server host 25.1.1.2 key Force Dell(conf)# Dell(conf)#line vty 0 9 Dell(config-line-vty)#login authentication tacacsmethod Dell(config-line-vty)#end Specifying a TACACS+ Server Host To specify a TACACS+ server host and configure its communication parameters, use the following command.
Command Authorization The AAA command authorization feature configures Dell Networking OS to send each configuration command to a TACACS server for authorization before it is added to the running configuration. By default, the AAA authorization commands configure the system to check both EXEC mode and CONFIGURATION mode commands. Use the no aaa authorization config-commands command to enable only EXEC mode command checking.
Specifying an SSH Version The following example uses the ip ssh server version 2 command to enable SSH version 2 and the show ip ssh command to confirm the setting. Dell(conf)#ip ssh server version 2 Dell(conf)#do show ip ssh SSH server : enabled. SSH server version : v2. SSH server vrf : default. SSH server ciphers : 3des-cbc,aes128-cbc,aes192-cbc,aes256-cbc,aes128ctr,aes192-ctr,aes256-ctr. SSH server macs : hmac-md5,hmac-md5-96,hmac-sha1,hmac-sha1-96,hmacsha2-256,hmac-sha2-256-96.
Configuring When to Re-generate an SSH Key You can configure the time-based or volume-based rekey threshold for an SSH session. If both threshold types are configured, the session rekeys when either one of the thresholds is reached. To configure the time or volume rekey threshold at which to re-generate the SSH key during an SSH session, use the ip ssh rekey [time rekey-interval] [volume rekey-limit] command. CONFIGURATION mode.
The following example shows you how to configure a key exchange algorithm. Dell(conf)# ip ssh server hellman-group14-sha1 kex diffie-hellman-group-exchange-sha1 diffie- Configuring the HMAC Algorithm for the SSH Server To configure the HMAC algorithm for the SSH server, use the ip ssh server mac hmac-algorithm command in CONFIGURATION mode. hmac-algorithm: Enter a space-delimited list of keyed-hash message authentication code (HMAC) algorithms supported by the SSH server.
• aes192-cbc • aes256-cbc • aes128-ctr • aes192-ctr • aes256-ctr The default cipher list is 3des-cbc,aes128-cbc,aes192-cbc,aes256-cbc,aes128-ctr,aes192-ctr,aes256-ctr Example of Configuring a Cipher List The following example shows you how to configure a cipher list. Dell(conf)#ip ssh server cipher 3des-cbc aes128-cbc aes128-ctr Secure Shell Authentication Secure Shell (SSH) is enabled by default using the SSH Password Authentication method.
3. Disable password authentication if enabled. CONFIGURATION mode no ip ssh password-authentication enable 4. Bind the public keys to RSA authentication. EXEC Privilege mode ip ssh rsa-authentication enable 5. Bind the public keys to RSA authentication. EXEC Privilege mode ip ssh rsa-authentication my-authorized-keys flash://public_key Example of Generating RSA Keys admin@Unix_client#ssh-keygen -t rsa Generating public/private rsa key pair. Enter file in which to save the key (/home/admin/.
Examples of Creating shosts and rhosts The following example shows creating shosts. admin@Unix_client# cd /etc/ssh admin@Unix_client# ls moduli sshd_config ssh_host_dsa_key.pub ssh_host_key.pub ssh_host_rsa_key.pub ssh_config ssh_host_dsa_key ssh_host_key ssh_host_rsa_key admin@Unix_client# cat ssh_host_rsa_key.
In this case, verify that host-based authentication is set to “Yes” in the file ssh_config (root permission is required to edit this file): permission denied (host based). If the IP address in the RSA key does not match the IP address from which you attempt to log in, the following message appears. In this case, verify that the name and IP address of the client is contained in the file /etc/hosts: RSA Authentication Error. Telnet To use Telnet with SSH, first enable SSH, as previously described.
1. Create a username. 2. Enter a password. 3. Assign an access class. 4. Enter a privilege level. You can assign line authentication on a per-VTY basis; it is a simple password authentication, using an access-class as authorization. Configure local authentication globally and configure access classes on a per-user basis. Dell Networking OS can assign different access classes to different users by username.
Dell(conf)#tacacs-server host 256.1.1.2 key Force10 Dell(conf)# Dell(conf)#line vty 0 9 Dell(config-line-vty)#login authentication tacacsmethod Dell(config-line-vty)# Dell(config-line-vty)#access-class deny10 Dell(config-line-vty)#end (same applies for radius and line authentication) VTY MAC-SA Filter Support Dell Networking OS supports MAC access lists which permit or deny users based on their source MAC address. With this approach, you can implement a security policy based on the source MAC address.
• Displaying Active Accounting Sessions for Roles • Configuring TACACS+ and RADIUS VSA Attributes for RBAC • Displaying User Roles • Displaying Accounting for User Roles • Displaying Information About Roles Logged into the Switch • Display Role Permissions Assigned to a Command Overview of RBAC With Role-Based Access Control (RBAC), access and authorization is controlled based on a user’s role. Users are granted permissions based on their user roles, not on their individual user ID.
Configuration mode, the Dell Networking OS checks to ensure that you do not lock yourself out and that the user authentication is available for all terminal lines. Pre-requisites Before you enable role-based only AAA authorization: 1. Locally define a system administrator user role. This will give you access to login with full permissions even if network connectivity to remote authentication servers is not available. 2. Configure login authentication on the console.
To enable role-based only AAA authorization: Dell(conf)#aaa authorization role-only System-Defined RBAC User Roles By default, the Dell Networking OS provides 4 system defined user roles. You can create up to 8 additional user roles. NOTE: You cannot delete any system defined roles. The system defined user roles are as follows: • Network Operator (netoperator) - This user role has no privilege to modify any configuration on the switch.
defined roles. Otherwise you would have to create a user role’s command permissions from scratch. You then restrict commands or add commands to that role. For more information about this topic, see Modifying Command Permissions for Roles. NOTE: You can change user role permissions on system pre-defined user roles or user-defined user roles.
myrole secadmin Exec Config Line Modifying Command Permissions for Roles You can modify (add or delete) command permissions for newly created user roles and system defined roles using the role mode { { { addrole | deleterole } role-name } | reset } command command in Configuration mode. NOTE: You cannot modify system administrator command permissions. If you add or delete command permissions using the role command, those changes only apply to the specific user role.
Example: Allow Security Administrator to Access Only 10-Gigabit Ethernet Interfaces The following example allows the security administrator (secadmin) to only access 10-Gigabit Ethernett interfaces and then shows that the secadmin, highlighted in bold, can now access Interface mode. However, the secadmin can only access 10-Gigabit Ethernet interfaces.
The following example resets only the secadmin role to its original setting. Dell(conf)#no role configure addrole secadmin protocol Example: Reset System-Defined Roles and Roles that Inherit Permissions In the following example the command protocol permissions are reset to their original setting or one or more of the system-defined roles and any roles that inherited permissions from them.
NOTE: Authentication services only validate the user ID and password combination. To determine which commands are permitted for users, configure authorization. For information about how to configure authorization for roles, see Configure AAA Authorization for Roles. To configure AAA authentication, use the aaa authentication command in CONFIGURATION mode.
NOTE: Note that the methods were not applied to the console so the default methods (if configured) are applied there.
Example for Configuring a VSA Attribute for a Privilege Level 15 The following example configures an AV pair which allows a user to login from a network access server with a privilege level of 15, to have access to EXEC commands. The format to create a Dell Network OS AV pair for privilege level is shell:priv-lvl= where number is a value between 0 and 15.
Applying an Accounting Method to a Role To apply an accounting method list to a role executed by a user with that user role, use the accounting command in LINE mode. accounting {exec | commands {level | role role-name}} method-list Example of Applying an Accounting Method to a Role The following example applies the accounting default method to the user role secadmin (security administrator).
Protocol MAC testadmin netadmin Protocol MAC Exec Config Interface Line Router IP Routemap Displaying Role Permissions Assigned to a Command To display permissions assigned to a command, use the show role command in EXEC Privilege mode. The output displays the user role and or permission level.
Service Provider Bridging 49 Service provider bridging is supported on Dell Networking OS. VLAN Stacking VLAN stacking, also called Q-in-Q, is defined in IEEE 802.1ad — Provider Bridges, which is an amendment to IEEE 802.1Q — Virtual Bridged Local Area Networks. It enables service providers to use 802.1Q architecture to offer separate VLANs to customers with no coordination between customers, and minimal coordination between customers and the provider. Using only 802.
Figure 113. VLAN Stacking in a Service Provider Network Important Points to Remember • Interfaces that are members of the Default VLAN and are configured as VLAN-Stack access or trunk ports do not switch untagged traffic. To switch traffic, add these interfaces to a non-default VLANStack-enabled VLAN. • Dell Networking cautions against using the same MAC address on different customer VLANs, on the same VLAN-Stack VLAN.
Configure VLAN Stacking Configuring VLAN-Stacking is a three-step process. 1. Creating Access and Trunk Ports 2. Assign access and trunk ports to a VLAN (Creating Access and Trunk Ports). 3. Enabling VLAN-Stacking for a VLAN.
interface TenGigabitEthernet 1/2 no ip address switchport vlan-stack trunk no shutdown Enable VLAN-Stacking for a VLAN To enable VLAN-Stacking for a VLAN, use the following command. • Enable VLAN-Stacking for the VLAN. INTERFACE VLAN mode vlan-stack compatible Example of Viewing VLAN Stack Member Status To display the status and members of a VLAN, use the show vlan command from EXEC Privilege mode. Members of a VLAN-Stacking-enabled VLAN are marked with an M in column Q.
To configure trunk ports, use the following commands. 1. Configure a trunk port to carry untagged, single-tagged, and double-tagged traffic by making it a hybrid port. INTERFACE mode portmode hybrid NOTE: You can add a trunk port to an 802.1Q VLAN as well as a Stacking VLAN only when the TPID 0x8100. 2. Add the port to a 802.1Q VLAN as tagged or untagged.
Example of Debugging a VLAN and its Ports The port notations are as follows: • MT — stacked trunk • MU — stacked access port • T — 802.1Q trunk port • U — 802.
untagged traffic and maps each to the appropriate VLAN, as shown by the packet originating from Building A. Therefore, a mismatched TPID results in the port not differentiating between tagged and untagged traffic. Figure 114.
Figure 115.
Figure 116. Single and Double-Tag TPID Mismatch The following table details the outcome of matched and mismatched TPIDs in a VLAN-stacking network with the S-Series. Table 70. Behaviors for Mismatched TPID Network Position Incoming Packet TPID System TPID Match Type Pre-Version 8.2.1.0 Version 8.2.1.
Network Position Core Egress Access Point Incoming Packet TPID System TPID Match Type Pre-Version 8.2.1.0 Version 8.2.1.
• Make packets eligible for dropping based on their DEI value. CONFIGURATION mode dei enable By default, packets are colored green, and DEI is marked 0 on egress. Honoring the Incoming DEI Value To honor the incoming DEI value, you must explicitly map the DEI bit to an Dell Networking OS drop precedence. Precedence can have one of three colors. Precedence Description Green High-priority packets that are the least preferred to be dropped. Yellow Lower-priority packets that are treated as best-effort.
Example of Viewing DEI-Marking Configuration To display the DEI-marking configuration, use the show interface dei-mark [interface slot/ port[/subport] | linecard number port-set number] in EXEC Privilege mode.
configuration, the queue selected by Dynamic Mode CoS takes precedence. However, rate policing for the queue is determined by QoS configuration. For example, the following access-port configuration maps all traffic to Queue 0: vlan-stack dot1p-mapping c-tag-dot1p 0-7 sp-tag-dot1p 1 However, if the following QoS configuration also exists on the interface, traffic is queued to Queue 0 but is policed at 40Mbps (qos-policy-input for queue 3) because class-map "a" of Queue 3 also matches the traffic.
cam-acl l2acl number ipv4acl number ipv6acl number ipv4qos number l2qos number l2pt number ipmacacl number ecfmacl number {vman-qos | vman-qos-dualfp} number • vman-qos: mark the S-Tag dot1p and queue the frame according to the original C-Tag dot1p. This method requires half as many CAM entries as vman-qos-dual-fp. • vman-qos-dual-fp: mark the S-Tag dot1p and queue the frame according to the S-Tag dot1p. This method requires twice as many CAM entries as vman-qos and FP blocks in multiples of 2.
Figure 118. VLAN Stacking without L2PT You might need to transport control traffic transparently through the intermediate network to the other region. Layer 2 protocol tunneling enables BPDUs to traverse the intermediate network by identifying frames with the Bridge Group Address, rewriting the destination MAC to a user-configured non-reserved address, and forwarding the frames.
the intermediate network because only Dell Networking OS could recognize the significance of the destination MAC address and rewrite it to the original Bridge Group Address. In Dell Networking OS version 8.2.1.0 and later, the L2PT MAC address is user-configurable, so you can specify an address that non-Dell Networking systems can recognize and rewrite the address at egress edge. Figure 119. VLAN Stacking with L2PT Implementation Information • L2PT is available for STP, RSTP, MSTP, and PVST+ BPDUs.
Enabling Layer 2 Protocol Tunneling To enable Layer 2 protocol tunneling, use the following command. 1. Verify that the system is running the default CAM profile. Use this CAM profile for L2PT. EXEC Privilege mode show cam-profile 2. Enable protocol tunneling globally on the system. CONFIGURATION mode protocol-tunnel enable 3. Tunnel BPDUs the VLAN.
4. Set a maximum rate at which the RPM processes BPDUs for L2PT. VLAN STACKING mode protocol-tunnel rate-limit The default is: no rate limiting. The range is from 64 to 320 kbps. Debugging Layer 2 Protocol Tunneling To debug Layer 2 protocol tunneling, use the following command. • Display debugging information for L2PT. EXEC Privilege mode debug protocol-tunnel Provider Backbone Bridging IEEE 802.1ad—Provider Bridges amends 802.
sFlow 50 Configuring sFlow is supported on Dell Networking OS. Overview The Dell Networking Operating System (OS) supports sFlow version 5. sFlow is a standard-based sampling technology embedded within switches and routers which is used to monitor network traffic. It is designed to provide traffic monitoring for high-speed networks with many switches and routers. sFlow uses two types of sampling: • Statistical packet-based sampling of switched or routed packet flows.
Important Points to Remember • The Dell Networking OS implementation of the sFlow MIB supports sFlow configuration via snmpset. • By default, sFlow collection is supported only on data ports. If you want to enable sFlow collection through management ports, use the management egress-interface-selection and application sflow-collector commands in Configuration and EIS modes respectively. • Dell Networking OS exports all sFlow packets to the collector.
1 collectors configured Collector IP addr: 100.1.1.1, Agent IP addr: 1.1.1.2, UDP port: 6343 VRF: Default 0 UDP packets exported 0 UDP packets dropped 0 sFlow samples collected stack-unit 1 Port set 0 Te 1/1: configured rate 16384, actual rate 16384 Dell# If you did not enable any extended information, the show output displays the following (shown in bold).
• View the maximum header size of a packet. show running-config sflow Example of the show sflow command when the sflow max-header-size extended is configured globally Dell(conf-if-te-1/10)#show sflow sFlow services are enabled Egress Management Interface sFlow services are disabled Global default sampling rate: 32768 Global default counter polling interval: 86400 Global default extended maximum header size: 256 bytes Global extended information enabled: none 1 collectors configured Collector IP addr: 100.
Displaying Show sFlow Global To view sFlow statistics, use the following command. • Display sFlow configuration information and statistics. EXEC mode show sflow Example of Viewing sFlow Configuration (Global) The first bold line indicates sFlow is globally enabled. The second bold lines indicate sFlow is enabled on Te 1/16 and Te 1/17 Dell#show sflow sFlow services are enabled Global default sampling rate: 32768 Global default counter polling interval: 20 1 collectors configured Collector IP addr: 133.33.
ip mtu 9234 switchport sflow ingress-enable sflow sample-rate 8192 no shutdown Displaying Show sFlow on a Stack-unit To view sFlow statistics on a specified stack-unit, use the following command. • Display sFlow configuration information and statistics on the specified interface.
– interval value: in seconds. The range is from 15 to 86400 seconds. The default is 20 seconds. Back-Off Mechanism If the sampling rate for an interface is set to a very low value, the CPU can get overloaded with flow samples under high-traffic conditions. In such a scenario, a binary back-off mechanism gets triggered, which doubles the sampling-rate (halves the number of samples per second) for all interfaces. The backoff mechanism continues to double the sampling-rate until the CPU condition is cleared.
1 collectors configured Collector IP addr: 100.1.1.1, Agent IP addr: 1.1.1.2, UDP port: 6343 VRF: Default 0 UDP packets exported 0 UDP packets dropped 0 sFlow samples collected stack-unit 1 Port set 0 Te 1/1: configured rate 16384, actual rate 16384 Dell# If you did not enable any extended information, the show output displays the following (shown in bold).
IP SA IP DA srcAS and srcPeerAS dstAS and dstPeerAS Description Exported Exported version 7.8.1.0, extended gateway data is not exported because IP DA is not learned via BGP. Version 7.8.1.0 allows extended gateway information in cases where the source and destination IP addresses are learned by different routing protocols, and for cases where is source is reachable over ECMP. BGP sFlow BGP Exported Exported Extended gateway data is packed.
51 Simple Network Management Protocol (SNMP) Simple network management protocol (SNMP) is supported on Dell Networking OS. NOTE: On Dell Networking routers, standard and private SNMP management information bases (MIBs) are supported, including all Get and a limited number of Set operations (such as set vlan and copy cmd). Protocol Overview Network management stations use SNMP to retrieve or alter management data from network elements.
The SNMPv3 feature also uses a FIPS-validated cryptographic module for all of its cryptographic operations when the system is configured with the fips mode enable command in Global Configuration mode. When the FIPS mode is enabled on the system, SNMPv3 operates in a FIPScompliant manner, and only the FIPS-approved algorithm options are available for SNMPv3 user configuration. When the FIPS mode is disabled on the system, all options are available for SNMPv3 user configuration.
Configuration Task List for SNMP Configuring SNMP version 1 or version 2 requires a single step. NOTE: The configurations in this chapter use a UNIX environment with net-snmp version 5.4. This environment is only one of many RFC-compliant SNMP utilities you can use to manage your Dell Networking system using SNMP. Also, these configurations use SNMP version 2c. • Creating a Community Configuring SNMP version 3 requires configuring SNMP users in one of three methods.
Creating a Community For SNMPv1 and SNMPv2, create a community to enable the community-based security in Dell Networking OS. The management station generates requests to either retrieve or alter the value of a management object and is called the SNMP manager. A network element that processes SNMP requests is called an SNMP agent. An SNMP community is a group of SNMP agents and managers that are allowed to interact.
• snmp-server group group-name 3 noauth auth read name write name Configure an SNMPv3 view. CONFIGURATION mode snmp-server view view-name oid-tree {included | excluded} NOTE: To give a user read and write view privileges, repeat this step for each privilege type. • Configure the user with an authorization password (password privileges only). CONFIGURATION mode • snmp-server user name group-name 3 noauth auth md5 auth-password Configure an SNMP group (password privileges only).
• Read the value of a single managed object. • snmpget -v version -c community agent-ip {identifier.instance | descriptor.instance} Read the value of the managed object directly below the specified object. • snmpgetnext -v version -c community agent-ip {identifier.instance | descriptor.instance} Read the value of many objects at once. snmpwalk -v version -c community agent-ip {identifier.instance | descriptor.
Configuring Contact and Location Information using SNMP You may configure system contact and location information from the Dell Networking system or from the management station using SNMP. To configure system contact and location information from the Dell Networking system and from the management station using SNMP, use the following commands. • (From a Dell Networking system) Identify the system manager along with this person’s contact information (for example, an email address or phone number).
Subscribing to Managed Object Value Updates using SNMP By default, the Dell Networking system displays some unsolicited SNMP messages (traps) upon certain events and conditions. You can also configure the system to send the traps to a management station. Traps cannot be saved on the system. Dell Networking OS supports the following three sets of traps: • • • RFC 1157-defined traps — coldStart, warmStart, linkDown, linkUp, authenticationFailure, and egpNeighbborLoss.
snmp coldstart snmp linkdown snmp linkup SNMP_COLD_START: Agent Initialized - SNMP COLD_START. SNMP_WARM_START:Agent Initialized - SNMP WARM_START. PORT_LINKDN:changed interface state to down:%d PORT_LINKUP:changed interface state to up:%d Enabling a Subset of SNMP Traps You can enable a subset of Dell Networking enterprise-specific SNMP traps using one of the following listed command options. To enable a subset of Dell Networking enterprise-specific SNMP traps, use the following command.
envmon fan FAN_TRAY_BAD: Major alarm: fantray %d is missing or down FAN_TRAY_OK: Major alarm cleared: fan tray %d present FAN_BAD: Minor alarm: some fans in fan tray %d are down FAN_OK: Minor alarm cleared: all fans in fan tray %d are good vlt Enable VLT traps. vrrp Enable VRRP state change traps xstp %SPANMGR-5-STP_NEW_ROOT: New Spanning Tree Root, Bridge ID Priority 32768, Address 0001.e801.fc35.
threshold alarm from SNMP OID Enabling an SNMP Agent to Notify Syslog Server Failure You can configure a network device to send an SNMP trap if an audit processing failure occurs due to loss of connectivity with the syslog server. If a connectivity failure occurs on a syslog server that is configured for reliable transmission, an SNMP trap is sent and a message is displayed on the console.
10.11.226.121 (port: 9140) is reachable"SNMPv2-SMI::enterprises. 6027.3.6.1.1.2.0 = INTEGER: 2 Following is the sample audit log message that other syslog servers that are reachable receive: Oct 21 05:26:04: dv-fedgov-s4810-6: %EVL-6-REACHABLE:Syslog server 10.11.226.121 (port: 9140) is reachable Copy Configuration Files Using SNMP To do the following, use SNMP from a remote client.
MIB Object OID Object Values Description is set to runningconfig or startupconfig, copySrcFileName is not required. copyDestFileType . 1.3.6.1.4.1.6027.3.5.1.1.1. 1.5 1 = Dell Networking OS file Specifies the type of file to copy to. 2 = running-config • 3 = startup-config • copyDestFileLocation . 1.3.6.1.4.1.6027.3.5.1.1.1. 1.6 1 = flash If copySourceFileType is running-config or startup-config, the default copyDestFileLocatio n is flash.
Copying a Configuration File To copy a configuration file, use the following commands. NOTE: In UNIX, enter the snmpset command for help using the following commands. Place the f10-copy-config.mib file in the directory from which you are executing the snmpset command or in the snmpset tool path. 1. Create an SNMP community string with read/write privileges. CONFIGURATION mode snmp-server community community-name rw 2. Copy the f10-copy-config.
• Copy the running-config to the startup-config from the UNIX machine. snmpset -v 2c -c public force10system-ip-address copySrcFileType.index i 2 copyDestFileType.index i 3 Examples of Copying Configuration Files The following examples show the command syntax using MIB object names and the same command using the object OIDs. In both cases, a unique index number follows the object. The following example shows copying configuration files using MIB object names. > snmpset -v 2c -r 0 -t 60 -c private -m .
copyUserName.index s server-login-id copyUserPassword.index s server-loginpassword • precede server-ip-address by the keyword a. • precede the values for copyUsername and copyUserPassword by the keyword s. Example of Copying Configuration Files via FTP From a UNIX Machine > snmpset -v 2c -c private -m ./f10-copy-config.mib 10.10.10.10 copySrcFileType. 110 i 2 copyDestFileName.110 s /home/startup-config copyDestFileLocation.110 i 4 copyServerAddress.110 a 11.11.11.11 copyUserName.
myfilename copyServerAddress.10 a 172.16.1.56 copyUserName.10 s mylogin copyUserPassword. 10 s mypass Additional MIB Objects to View Copy Statistics Dell Networking provides more MIB objects to view copy statistics, as shown in the following table. Table 75. Additional MIB Objects for Copying Configuration Files via SNMP MIB Object OID Values Description copyState . 1.3.6.1.4.1.6027.3.5.1.1.1. 1.11 1= running Specifies the state of the copy operation. 2 = successful 3 = failed copyTimeStarted .
index: the index value used in the snmpset command used to complete the copy operation. NOTE: You can use the entire OID rather than the object name. Use the form: OID.index. Examples of Getting MIB Object Values The following examples show the snmpget command to obtain a MIB object value. These examples assume that: • the server OS is UNIX • you are using SNMP version 2c • the community name is public • the file f10-copy-config.
snmpget -v2c -c public 192.168.60.120 .1.3.6.1.4.1.6027.3.10.1.2.9.1.6.1 enterprises.6027.3.10.1.2.9.1.5.1 = Gauge32: 24 The output above displays that 24% of the flash memory is used. MIB Support to Display the Software Core Files Generated by the System Dell Networking provides MIB objects to display the software core files generated by the system. The chSysSwCoresTable contains the list of software core files generated by the system. The following table lists the related MIB objects. Table 77.
f10cp_vrrp_140522124357_Stk1.acore.gz" enterprises.6027.3.10.1.2.10.1.2.2.1 = "/CORE_DUMP_DIR/FTP_STK_MEMBER/f10cp_sysd_140617134445_Stk0.acore.gz" enterprises.6027.3.10.1.2.10.1.3.1.1 = "Fri Mar 14 11:51:46 2014" enterprises.6027.3.10.1.2.10.1.3.1.2 = "Fri Nov 8 08:11:16 2013" enterprises.6027.3.10.1.2.10.1.3.1.3 = "Fri May 23 05:05:16 2014" enterprises.6027.3.10.1.2.10.1.3.2.1 = "Tue Jun 17 14:19:26 2014" enterprises.6027.3.10.1.2.10.1.4.1.1 = 0 enterprises.6027.3.10.1.2.10.1.4.1.2 = 1 enterprises.6027.3.
Displaying the Ports in a VLAN Dell Networking OS identifies VLAN interfaces using an interface index number that is displayed in the output of the show interface vlan command. Examples of Viewing VLAN Ports Using SNMP The following example shows viewing the VLAN interface index number using SNMP. Dell(conf)#do show interface vlan id 10 % Error: No such interface name.
NUM Status Description 10 Inactive Q Ports U Te 1/2 [Unix system output] > snmpget -v2c -c mycommunity 10.11.131.185 . 1.3.6.1.2.1.17.7.1.4.3.1.2.1107787786 SNMPv2-SMI::mib-2.17.7.1.4.3.1.2.1107787786 = Hex-STRING: 40 00 00 00 00 00 00 00 00 00 00 The value 40 is in the first set of 7 hex pairs, indicating that these ports are in Stack Unit 1. The hex value 40 is 0100 0000 in binary. As described, the left-most position in the string represents Port 1.
Example of Adding a Tagged Port to a VLAN using SNMP In the following example, Port 0/2 is added as a tagged member of VLAN 10. >snmpset -v2c -c mycommunity 10.11.131.185 . 1.3.6.1.2.1.17.7.1.4.3.1.2.1107787786 x "40 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00" .1.3.6.1.2.1.17.7.1.4.3.1.4.
CONFIGURATION mode snmp-server community 2. From the Dell Networking system, identify the interface index of the port for which you want to change the admin status. EXEC Privilege mode show interface Or, from the management system, use the snmpwwalk command to identify the interface index. 3. Enter the snmpset command to change the admin status using either the object descriptor or the OID. snmpset with descriptor: snmpset -v version -c community agent-ip ifAdminStatus.
In the following example, R1 has one dynamic MAC address, learned off of port TenGigabitEthernet 1/21, which a member of the default VLAN, VLAN 1. The SNMP walk returns the values for dot1dTpFdbAddress, dot1dTpFdbPort, and dot1dTpFdbStatus. Each object comprises an OID concatenated with an instance number. In the case of these objects, the instance number is the decimal equivalent of the MAC address; derive the instance number by converting each hex pair to its decimal equivalent.
Deriving Interface Indices Dell Networking OS assigns an interface number to each (configured or unconfigured) physical and logical interface. The interface index is a binary number with bits that indicate the slot number, port number, interface type, and card type of the interface. Dell Networking OS converts this binary index number to decimal, and displays it in the output of the show interface command.
Dell#show interface Tengigabitethernet 1/21 TenGigabitEthernet 1/21 is up, line protocol is up Monitor Port-Channels To check the status of a Layer 2 port-channel, use f10LinkAggMib (.1.3.6.1.4.1.6027.3.2). In the following example, Po 1 is a switchport and Po 2 is in Layer 3 mode. Example of SNMP Trap for Monitored Port-Channels [senthilnathan@lithium ~]$ snmpwalk -v 2c -c public 10.11.1.1 . 1.3.6.1.4.1.6027.3.2.1.1 SNMPv2-SMI::enterprises.6027.3.2.1.1.1.1.1.1 = INTEGER: 1 SNMPv2-SMI::enterprises.6027.3.
SNMPv2-MIB::sysUpTime.0 = Timeticks: (8500842) 23:36:48.42 SNMPv2-MIB::snmpTrapOID.0 = OID: IF-MIB::linkDown IF-MIB::ifIndex.1107755009 = INTEGER: 1107755009 SNMPv2-SMI::enterprises.6027.3.1.1.4.1.2 = STRING: "OSTATE_DN: Changed interface state to down: Po 1" 2010-02-10 14:22:40 10.16.130.4 [10.16.130.4]: SNMPv2-MIB::sysUpTime.0 = Timeticks: (8500932) 23:36:49.32 SNMPv2MIB::snmpTrapOID.0 = OID: IF-MIB::linkUp IF-MIB::ifIndex.33865785 = INTEGER: 33865785 SNMPv2SMI::enterprises.6027.3.1.1.4.1.
SMI::enterprises.6027.3.30.1.1.1 SNMPv2-SMI::enterprises.6027.3.30.1.1 = STRING: "NOT_REACHABLE: Syslog server 10.11.226.121 (port: 9140) is not reachable" SNMPv2-SMI::enterprises. 6027.3.6.1.1.2.0 = INTEGER: 2 Following is the sample audit log message that other syslog servers that are reachable receive: Oct 21 00:46:13: dv-fedgov-s4810-6: %EVL-6-NOT_REACHABLE:Syslog server 10.11.226.
Stacking 52 Stacking is supported on the S4048-ON platform with the Dell Networking Operating System (OS) version 9.8(0.0). NOTE: The S4048-ON commands accept Unit ID numbers 0-11, though The S4048-ON supports stacking up to six units with Dell Networking OS version 9.7(0.1). Using the Dell Networking OS stacking feature, you can interconnect multiple S-Series switch units with dedicated stacking ports or front end user ports.
• Inter-switch stacking link failure • Switch insertion • Switch removal If the master switch goes off line, the standby replaces it as the new master and the switch with the next highest priority or MAC address becomes standby. Stack Master Election The stack elects a master and standby unit at bootup time based on two criteria. • Unit priority — User-configurable. The range is from 1 to 14. A higher value (14) means a higher priority. The default is 1.
Use the following command to configure a virtual IP: Dell(conf)#virtual-ip {ip-address | ipv6–address | dhcp} Failover Roles If the stack master fails (for example, is powered off), it is removed from the stack topology. The standby unit detects the loss of peering communication and takes ownership of the stack management, switching from the standby role to the master role. The distributed forwarding tables are retained during the failover, as is the stack MAC address.
-- Stack Info -Unit UnitType Status ReqTyp CurTyp Version --------------------------------------------------0 Standby online S4048-ON S4048-ON 1 Management online 2 Member not present 3 Member not present 4 Member not present 5 Member not present 6 Member not present 7 Member not present [output omitted] Stack#show system stack-unit 1 | grep priority Master priority : 0 Stack#show system stack-unit 2 | grep priority Master priority : 0 Ports Example of Adding a Standalone with a Lower MAC Address and Equa
Supported Stacking Topologies The device supports stacking in a ring or a daisy chain topology. Dell Networking recommends the ring topology when stacking the switches to provide redundant connectivity. Figure 120. High Availability on S-Series Stacks S-Series stacks have master and standby management units analogous to Dell Networking route processor modules (RPM).
-- PEER Stack-unit Status ------------------------------------------------Stack-unit State: Standby Peer Stack-unit ID: 2 Stack-unit SW Version: 1-0(0-3387) -- Stack-unit Redundancy Configuration ------------------------------------------------Primary Stack-unit: mgmt-id 0 Auto Data Sync: Full Failover Type: Hot Failover Auto reboot Stack-unit: Disabled Auto failover limit: 3 times in 60 minutes -- Stack-unit Failover Record ------------------------------------------------Failover Count: 0 Last failover tim
start telnet-peer-stack-unit terminal upload Dell(standby)# Start shell Open a telnet connection to the peer stack-unit Set terminal line parameters Upload file -----------------CONSOLE ACCESS ON A MEMBER---------------------------Stack(stack-member-0)#? reset-self Reset this unit alone show Show running system information You can connect two units with two or more stacking cables in case of a stacking port or cable failure. Removal of only one of the cables does not trigger a reset.
NOTE: After a port is allocated for stacking, you can only use it for stacking. If stack-group 1 is allocated for stacking, you can use ports 1, 2, 3, and 4 for stacking but not for Ethernet anymore. If only port 1 is used for stacking, ports 2, 3, and 4 are spare; they cannot be used for Ethernet. 1. Assign a stack group for each unit. CONFIGURATION mode stack-unit id stack-group id Begin with the first port on the management unit. Next, configure both ports on each subsequent unit.
CONFIGURATION mode stack-unit stack—unit—number priority priority 5. Assign a stack group for each unit. CONFIGURATION mode stack-unit stack-unit—id stack-group stack-group—id Begin with the first port on the management unit. Next, configure both ports on each subsequent unit. Finally, return to the management unit and configure the last port. (refer to the following example.) 6. Connect the units using stacking cables. NOTE: The device does not require special stacking cables.
• • • Configure the stack groups on unit 3: stack-unit 3 stack-group 12 and stack-unit 3 stack-group 13 Configure the stack groups on unit 4: stack-unit 4 stack-group 13 and stack-unit 4 stack-group 31 Configure the final stack-group on unit 1 to complete the stack: stack-unit 1 stack-group 31 When the stack-group configuration is complete, the system prints a syslog for reload.
3 2 4 1 4 2 Speed in up up up RPM up up up 9360 9120 9120 up up up 9360 9120 9360 The following example shows how to configure two new switches for stacking using 10G ports. Dell-1(conf)#stack-unit 0 stack-group 0 Setting ports Te 1/1 Te 1/2 Te 1/3 as stack group will make their interface configs obsolete after a reload. [confirm yes/no]:yes Dell-2(conf)#stack-unit 0 stack-group 0 Setting ports Te 1/1 Te 1/2 Te 1/3 as stack group will make their interface configs obsolete after a reload.
show system brief or show system stack-unit 2. On the new unit, number it the next available stack-unit number. EXEC Privilege mode stack-unit renumber 3. (OPTIONAL) On the new unit, assign a management priority based on whether you want the new unit to be the stack manager. CONFIGURATION mode stack-unit priority 4. Assign a stack group to each unit. CONFIGURATION mode stack-unitstack-unit-number stack-group stack-group-number 5. Connect the new unit to the stack using stacking cables.
Adding a Configured Unit to an Existing Stack To add a configured unit to an existing stack, use the following commands. If a stack unit goes down and is removed from the stack, the logical provisioning configured for that stack-unit number is saved on the master and standby units. When a new unit is added to the stack, if a stack group configuration conflict occurs between the new unit and the provisioned stack unit, the configuration of the new unit takes precedence. 1.
Merge Two S-Series Stacks You may merge two stacks while they are powered and online. To merge two stacks, connect one stack to the other using user port cables from the front end user port. • Dell Networking OS selects a master stack manager from the two existing managers based on the priority of the stack. • Dell Networking OS resets all the units in the losing stack; they all become stack members. • If there is no unit numbering conflict, the stack members retain their previous unit numbers.
Renumbering the stack manager triggers the whole stack to reload, as shown in the message below. When the stack comes back online, the master unit remains the management unit. Renumbering master unit will reload the stack. WARNING: Interface configuration for current unit will be lost! Proceed to renumber [confirm yes/no]: yes Creating a Virtual Stack Unit on an S-Series Stack Use virtual stack units to configure ports on the stack before adding a new unit. • Create a virtual stack unit.
Next Boot Required Type Current Type Master priority Hardware Rev Num Ports Up Time Dell Networking Jumbo Capable POE Capable Burned In MAC : No Of MACs : 3 : online : S4810 - 52-port GE/TE/FG (SE) : S4810 - 52-port GE/TE/FG (SE) : 0 : 3.
-- Stack Info -Unit UnitType Status ReqTyp CurTyp Version Ports -------------------------------------------------------0 Member not present 1 Member not present 2 Member not present 3 Management online S4810 S4810 8-3-12-13 64 4 Member not present 5 Member not present 6 Member not present 7 Member not present 8 Member not present 9 Member not present 10 Member not present 11 Member not present The following example shows the show system stack-ports command.
Managing Redundancy on an S-Series Stack Use the following commands to manage the redundancy on an S-Series stack. • Reset the current management unit and make the standby unit the new master unit. EXEC Privilege mode redundancy force-failover stack-unit • A new standby is elected. When the former stack master comes back online, it becomes a member unit. Prevent the stack master from rebooting after a failover.
Displaying the Status of Stacking Ports To display the status of the stacking ports, including the topology, use the following command. • Display the stacking ports. EXEC Privilege mode show system stack-ports Examples of Viewing the Status for Stacked Switches The following example shows four switches stacked together with two 40G links in a ring topology.
-- Power Supplies -Unit Bay Status Type FanStatus --------------------------------------------Unit Bay Status Type FanStatus --------------------------------------------1 0 absent absent 1 1 up AC up -- Fan Status -Unit Bay TrayStatus Fan0 Speed Fan1 Speed -------------------------------------------1 0 up up 7200 up 7200 1 1 up up 7200 up 7440 Speed in RP The following example shows three switches stacked together in a daisy chain topology.
Examples of Removing a Stack Member (Before and After) The following examples shows removing a stack member (before).
After the units are reloaded, the system reboots. The units come up as standalone units after the reboot completes. Troubleshoot an S-Series Stack To troubleshoot an S-Series stack, use the following recovery tasks. • • Recover from Stack Link Flaps Recover from a Card Problem State on an S-Series Stack Recover from Stack Link Flaps S-Series stack link integrity monitoring enables units to monitor their own stack ports and disable any stack port that flaps five times within 10 seconds.
Reload Type : normal-reload [Next boot : normal-reload] -- Stack Info -Unit UnitType Status ReqTyp CurTyp Version Ports ----------------------------------------------------------0 Standby card problem S4810 unknown 64 1 Management online S4810 S4810 8-3-10-223 64 2 Member not present 3 Member not present 4 Member not present 5 Member not present 6 Member not present 7 Member not present 8 Member not present 9 Member not present 10 Member not present 11 Member not present -- Power Supplies -Unit Bay Status T
53 Storm Control Storm control is supported on Dell Networking OS. The storm control feature allows you to control unknown-unicast and broadcast traffic on Layer 2 and Layer 3 physical interfaces. Dell Networking Operating System (OS) Behavior: Dell Networking OS supports broadcast control (the storm-control broadcast command) for Layer 2 and Layer 3 traffic. Dell Networking OS Behavior: The minimum number of packets per second (PPS) that storm control can limit on the device is two.
Spanning Tree Protocol (STP) 54 The spanning tree protocol (STP) is supported on Dell Networking OS. Protocol Overview STP is a Layer 2 protocol — specified by IEEE 802.1d — that eliminates loops in a bridged topology by enabling only a single path through the network. By eliminating loops, the protocol improves scalability in a large network and allows you to implement redundant paths, which can be activated after the failure of active paths.
Important Points to Remember • • • • • STP is disabled by default. The Dell Networking OS supports only one spanning tree instance (0). For multiple instances, enable the multiple spanning tree protocol (MSTP) or per-VLAN spanning tree plus (PVST+). You may only enable one flavor of spanning tree at any one time. All ports in virtual local area networks (VLANs) and all enabled interfaces in Layer 2 mode are automatically added to the spanning tree topology at the time you enable the protocol.
To configure and enable the interfaces for Layer 2, use the following command. 1. If the interface has been assigned an IP address, remove it. INTERFACE mode no ip address 2. Place the interface in Layer 2 mode. INTERFACE switchport 3. Enable the interface. INTERFACE mode no shutdown Example of the show config Command To verify that an interface is in Layer 2 mode and enabled, use the show config command from INTERFACE mode.
Figure 123. Spanning Tree Enabled Globally To enable STP globally, use the following commands. 1. Enter PROTOCOL SPANNING TREE mode. CONFIGURATION mode protocol spanning-tree 0 2. Enable STP. PROTOCOL SPANNING TREE mode no disable Examples of Verifying Spanning Tree Information To disable STP globally for all Layer 2 interfaces, use the disable command from PROTOCOL SPANNING TREE mode. To verify that STP is enabled, use the show config command from PROTOCOL SPANNING TREE mode.
To view the spanning tree configuration and the interfaces that are participating in STP, use the show spanning-tree 0 command from EXEC privilege mode. If a physical interface is part of a port channel, only the port channel is listed in the command output. R2#show spanning-tree 0 Executing IEEE compatible Spanning Tree Protocol Bridge Identifier has priority 32768, address 0001.e826.ddb7 Configured hello time 2, max age 20, forward delay 15 Current root has priority 32768, address 0001.e80d.
spanning-tree 0 Modifying Global Parameters You can modify the spanning tree parameters. The root bridge sets the values for forward-delay, hellotime, and max-age and overwrites the values set on other bridges participating in STP. NOTE: Dell Networking recommends that only experienced network administrators change the spanning tree parameters. Poorly planned modification of the spanning tree parameters can negatively affect network performance. The following table displays the default values for STP.
PROTOCOL SPANNING TREE mode max-age seconds The range is from 6 to 40. The default is 20 seconds. To view the current values for global parameters, use the show spanning-tree 0 command from EXEC privilege mode. Refer to the second example in Enabling Spanning Tree Protocol Globally. Modifying Interface STP Parameters You can set the port cost and port priority values of interfaces in Layer 2 mode. • Port cost — a value that is based on the interface type.
CAUTION: Enable PortFast only on links connecting to an end station. PortFast can cause loops if it is enabled on an interface connected to a network. To enable PortFast on an interface, use the following command. • Enable PortFast on an interface.
• When you add a physical port to a port channel already in the Error Disable state, the new member port is also disabled in the hardware. • When you remove a physical port from a port channel in the Error Disable state, the Error Disabled state is cleared on this physical port (the physical port is enabled in the hardware). • The reset linecard command does not clear the Error Disabled state of the port or the Hardware Disabled state. The interface continues to be disables in the hardware.
• disables spanning tree on an interface • drops all BPDUs at the line card without generating a console message Example of Blocked BPDUs Dell(conf-if-te-1/7)#do show spanning-tree rstp brief Executing IEEE compatible Spanning Tree Protocol Root ID Priority 32768, Address 0001.e805.fb07 Root Bridge hello time 2, max age 20, forward delay 15 Bridge ID Priority 32768, Address 0001.e85d.0e90 Configured hello time 2, max age 20, forward delay 15 Interface Name PortID Prio ---------- -------Te 1/6 128.
Root Bridge hello time 2, max age 20, forward delay 15 Dell# STP Root Guard Use the STP root guard feature in a Layer 2 network to avoid bridging loops. In STP, the switch in the network with the lowest priority (as determined by STP or set with the bridge-priority command) is selected as the root bridge. If two switches have the same priority, the switch with the lower MAC address is selected as the root.
Figure 125. STP Root Guard Prevents Bridging Loops Configuring Root Guard Enable STP root guard on a per-port or per-port-channel basis. Dell Networking OS Behavior: The following conditions apply to a port enabled with STP root guard: • Root guard is supported on any STP-enabled port or port-channel interface except when used as a stacking port.
• Enable root guard on a port or port-channel interface. INTERFACE mode or INTERFACE PORT-CHANNEL mode spanning-tree {0 | mstp | rstp | pvst} rootguard – 0: enables root guard on an STP-enabled port assigned to instance 0. – mstp: enables root guard on an MSTP-enabled port. – rstp: enables root guard on an RSTP-enabled port. – pvst: enables root guard on a PVST-enabled port.
STP Loop Guard The STP loop guard feature provides protection against Layer 2 forwarding loops (STP loops) caused by a hardware failure, such as a cable failure or an interface fault. When a cable or interface fails, a participating STP link may become unidirectional (STP requires links to be bidirectional) and an STP port does not receive BPDUs. When an STP blocking port does not receive BPDUs, it transitions to a Forwarding state. This condition can create a loop in the network.
Figure 126. STP Loop Guard Prevents Forwarding Loops Configuring Loop Guard Enable STP loop guard on a per-port or per-port channel basis. Dell Networking OS Behavior: The following conditions apply to a port enabled with loop guard: • Loop guard is supported on any STP-enabled port or port-channel interface.
• You cannot enable root guard and loop guard at the same time on an STP port. For example, if you configure loop guard on a port on which root guard is already configured, the following error message is displayed: % Error: RootGuard is configured. Cannot configure LoopGuard. • Enabling Portfast BPDU guard and loop guard at the same time on a port results in a port that remains in a blocking state and prevents traffic from flowing through it.
System Time and Date 55 System time and date settings and the network time protocol (NTP) are supported on Dell Networking OS. You can set system times and dates and maintained through the NTP. They are also set through the Dell Networking Operating System (OS) command line interfaces (CLIs) and hardware settings. In the release 9.4.(0.0), support for reaching an NTP server through different VRFs is included. You can configure a maximum of eight logging servers across different VRFs or the same VRF.
In what may be the most common client/server model, a client sends an NTP message to one or more servers and processes the replies as received. The server interchanges addresses and ports, overwrites certain fields in the message, recalculates the checksum and returns the message immediately. Information included in the NTP message allows the client to determine the server time regarding local time and adjust the local clock accordingly.
Implementation Information Dell Networking systems can only be an NTP client. Configure the Network Time Protocol Configuring NTP is a one-step process. • Enabling NTP Related Configuration Tasks • Configuring NTP Broadcasts • Disabling NTP on an Interface • Configuring a Source IP Address for NTP Packets (optional) Enabling NTP NTP is disabled by default. To enable NTP, specify an NTP server to which the Dell Networking system synchronizes.
• Set the interface to receive NTP packets. INTERFACE mode ntp broadcast client Example of Configuring NTP Broadcasts 2w1d11h : NTP: Maximum Slew:-0.000470, Remainder = -0.496884 Disabling NTP on an Interface By default, NTP is enabled on all active interfaces. If you disable NTP on an interface, Dell Networking OS drops any NTP packets sent to that interface. To disable NTP on an interface, use the following command. • Disable NTP on the interface.
Dell Networking OS Behavior: Dell Networking OS uses an encryption algorithm to store the authentication key that is different from previous Dell Networking OS versions; Dell Networking OS uses data encryption standard (DES) encryption to store the key in the startup-config when you enter the ntp authentication-key command.
ntp master To configure the switch as NTP Server use the ntp master command. stratum number identifies the NTP Server's hierarchy. Examples of Configuring and Viewing an NTP Configuration The following example shows configuring an NTP server. R6_E300(conf)#1w6d23h : NTP: xmit packet to 192.168.1.1: leap 0, mode 3, version 3, stratum 2, ppoll 1024 rtdel 0219 (8.193970), rtdsp AF928 (10973.266602), refid C0A80101 (192.168.1.1) ref CD7F4F63.6BE8F000 (14:51:15.
NOTE: • Leap Indicator (sys.leap, peer.leap, pkt.leap) — This is a two-bit code warning of an impending leap second to be inserted in the NTP time scale. The bits are set before 23:59 on the day of insertion and reset after 00:00 on the following day. This causes the number of seconds (rollover interval) in the day of insertion to be increased or decreased by one.
Dell Networking OS Time and Date You can set the time and date using the Dell Networking OS CLI. Configuration Task List The following is a configuration task list for configuring the time and date settings.
– timezone-name: enter the name of the timezone. Do not use spaces. – offset: enter one of the following: * a number from 1 to 23 as the number of hours in addition to UTC for the timezone. * a minus sign (-) then a number from 1 to 23 as the number of hours.
00:00:00 pacific Sat Nov 7 2009" Setting Recurring Daylight Saving Time Set a date (and time zone) on which to convert the switch to daylight saving time on a specific day every year. If you have already set daylight saving for a one-time setting, you can set that date and time as the recurring setting with the clock summer-time time-zone recurring command. To set a recurring daylight saving time, use the following command.
Examples of the clock summer-time recurring Command The following example shows the clock summer-time recurring command.
Tunneling 56 Tunnel interfaces create a logical tunnel for IPv4 or IPv6 traffic. Tunneling supports RFC 2003, RFC 2473, and 4213. DSCP, hop-limits, flow label values, open shortest path first (OSPF) v2, and OSPFv3 are supported. Internet control message protocol (ICMP) error relay, PATH MTU transmission, and fragmented packets are not supported. Configuring a Tunnel You can configure a tunnel in IPv6 mode, IPv6IP mode, and IPIP mode.
! interface Tunnel 2 no ip address ipv6 address 2::1/64 tunnel destination 90.1.1.1 tunnel source 60.1.1.1 tunnel mode ipv6ip no shutdown The following sample configuration shows a tunnel configured in IPIP mode (IPv4 tunnel carries IPv4 and IPv6 traffic): Dell(conf)#interface tunnel 3 Dell(conf-if-tu-3)#tunnel source 5::5 Dell(conf-if-tu-3)#tunnel destination 8::9 Dell(conf-if-tu-3)#tunnel mode ipv6 Dell(conf-if-tu-3)#ip address 3.1.1.
Configuring a Tunnel Interface You can configure the tunnel interface using the ip unnumbered and ipv6 unnumbered commands. To configure the tunnel interface to operate without a unique explicit IP or IPv6 address, select the interface from which the tunnel borrows its address. The following sample configuration shows how to use the interface tunnel configuration commands. Dell(conf-if-te-1/1)#show config ! interface TenGigabitEthernet 1/1 ip address 20.1.1.
tunnel mode ipip decapsulate-any no shutdown Configuring the Tunnel Source Anylocal You can use the anylocal argument in place of the ip address or interface, but only with multipoint receive-only mode tunnels. The tunnel source anylocal command allows the multipoint receiveonly tunnel to decapsulate tunnel packets addressed to any IPv4 or IPv6 (depending on the tunnel mode) address configured on the switch that is operationally UP.
Uplink Failure Detection (UFD) 57 Uplink failure detection (UFD) provides detection of the loss of upstream connectivity and, if used with network interface controller (NIC) teaming, automatic recovery from a failed link. Feature Description A switch provides upstream connectivity for devices, such as servers. If a switch loses its upstream connectivity, downstream devices also lose their connectivity.
Figure 128. Uplink Failure Detection How Uplink Failure Detection Works UFD creates an association between upstream and downstream interfaces. The association of uplink and downlink interfaces is called an uplink-state group. An interface in an uplink-state group can be a physical interface or a port-channel (LAG) aggregation of physical interfaces. An enabled uplink-state group tracks the state of all assigned upstream interfaces.
Figure 129. Uplink Failure Detection Example If only one of the upstream interfaces in an uplink-state group goes down, a specified number of downstream ports associated with the upstream interface are put into a Link-Down state. You can configure this number and is calculated by the ratio of the upstream port bandwidth to the downstream port bandwidth in the same uplink-state group.
– An uplink-state group is considered to be operationally down if it has no upstream interfaces in the Link-Up state. No uplink-state tracking is performed when a group is disabled or in an Operationally Down state. • You can assign a physical port or port-channel interfaces to an uplink-state group. – You can assign an interface to only one uplink-state group. Configure each interface assigned to an uplink-state group as either an upstream or downstream interface, but not both.
Where port-range and port-channel-range specify a range of ports separated by a dash (-) and/or individual ports/port channels in any order; for example: upstream tengigabitethernet 1/1-2,5,9,11-12 downstream port-channel 1-3,5 • A comma is required to separate each port and port-range entry. To delete an interface from the group, use the no {upstream | downstream} interface command. 3.
Clearing a UFD-Disabled Interface You can manually bring up a downstream interface in an uplink-state group that UFD disabled and is in a UFD-Disabled Error state. To re-enable one or more disabled downstream interfaces and clear the UFD-Disabled Error state, use the following command. • Re-enable a downstream interface on the switch/router that is in a UFD-Disabled Error State so that it can send and receive traffic.
down: Te 1/7 02:37:29: %RPM0-P:CP %IFMGR-5-OSTATE_DN: Changed interface state to down: Te 1/7 02:37:29 : UFD: Group:3, UplinkState: DOWN 02:37:29: %RPM0-P:CP %IFMGR-5-OSTATE_DN: Changed uplink state group state to down: Group 3 02:37:29: %RPM0-P:CP %IFMGR-5-OSTATE_DN: Downstream interface set to UFD error-disabled: Fo 3/52 02:37:29: %RPM0-P:CP %IFMGR-5-OSTATE_DN: Changed interface state to down: Fo 3/52 02:38:31 : UFD: Group:3, UplinkState: UP 02:38:31: %RPM0-P:CP %IFMGR-5-OSTATE_UP: Changed uplink state gr
• If a downstream interface in an uplink-state group is disabled (Oper Down state) by uplink-state tracking because an upstream port is down, the message error-disabled[UFD] displays in the output. Display the current configuration of all uplink-state groups or a specified group. EXEC mode or UPLINK-STATE-GROUP mode (For EXEC mode) show running-config uplink-state-group [group-id] (For UPLINK-STATE-GROUP mode) show configuration – group-id: The values are from 1 to 16.
Interface index is 280544512 Internet address is not set MTU 1554 bytes, IP MTU 1500 bytes LineSpeed 1000 Mbit, Mode auto Flowcontrol rx off tx off ARP type: ARPA, ARP Timeout 04:00:00 Last clearing of "show interface" counters 00:25:46 Queueing strategy: fifo Input Statistics: 0 packets, 0 bytes 0 64-byte pkts, 0 over 64-byte pkts, 0 over 127-byte pkts 0 over 255-byte pkts, 0 over 511-byte pkts, 0 over 1023-byte pkts 0 Multicasts, 0 Broadcasts 0 runts, 0 giants, 0 throttles 0 CRC, 0 overrun, 0 discarded Ou
• Verify the configuration with various show commands.
58 Upgrade Procedures To find the upgrade procedures, go to the Dell Networking OS Release Notes for your system type to see all the requirements needed to upgrade to the desired Dell Networking OS version. To upgrade your system type, follow the procedures in the Dell Networking OS Release Notes. Get Help with Upgrades Direct any questions or concerns about the Dell Networking OS upgrade procedures to the Dell Technical Support Center. You can reach Technical Support: • On the web: http://www.dell.
Virtual LANs (VLANs) 59 Virtual LANs (VLANs) are supported on Dell Networking OS. VLANs are a logical broadcast domain or logical grouping of interfaces in a local area network (LAN) in which all data received is kept locally and broadcast to all members of the group. When in Layer 2 mode, VLANs move traffic at wire speed and can span multiple devices. The Dell Networking Operating System (OS) supports up to 4093 port-based VLANs and one default VLAN, as specified in IEEE 802.1Q.
command places the interface in Layer 2 mode and the show vlan command in EXEC privilege mode indicates that the interface is now part of the Default VLAN (VLAN 1). By default, VLAN 1 is the Default VLAN. To change that designation, use the default vlan-id command in CONFIGURATION mode. You cannot delete the Default VLAN. NOTE: You cannot assign an IP address to the Default VLAN. To assign an IP address to a VLAN that is currently the Default VLAN, create another VLAN and assign it to be the Default VLAN.
VLANs and Port Tagging To add an interface to a VLAN, the interface must be in Layer 2 mode. After you place an interface in Layer 2 mode, the interface is automatically placed in the Default VLAN. Dell Networking OS supports IEEE 802.1Q tagging at the interface level to filter traffic. When you enable tagging, a tag header is added to the frame after the destination and source MAC addresses. That information is preserved as the frame moves through the network.
NOTE: In a VLAN, the shutdown command stops Layer 3 (routed) traffic only. Layer 2 traffic continues to pass through the VLAN. If the VLAN is not a routed VLAN (that is, configured with an IP address), the shutdown command has no affect on VLAN traffic. When you delete a VLAN (using the no interface vlan vlan-id command), any interfaces assigned to that VLAN are assigned to the Default VLAN as untagged interfaces. To create a port-based VLAN, use the following command.
interface vlan vlan-id 2. Enable an interface to include the IEEE 802.1Q tag header. INTERFACE mode tagged interface Add an Interface to Another VLAN To view just the interfaces that are in Layer 2 mode, use the show interfaces switchport command in EXEC Privilege mode or EXEC mode. The following example shows the steps to add a tagged interface (in this case, port channel 1) to VLAN 4. To view the interface’s status. Interface (po 1) is tagged and in VLAN 2 and 3, use the show vlan command.
Moving Untagged Interfaces To move untagged interfaces from the Default VLAN to another VLAN, use the following commands. 1. Access INTERFACE VLAN mode of the VLAN to which you want to assign the interface. CONFIGURATION mode interface vlan vlan-id 2. Configure an interface as untagged. INTERFACE mode untagged interface This command is available only in VLAN interfaces.
4 Active T U Te 1/1 Te 1/2 The only way to remove an interface from the Default VLAN is to place the interface in Default mode by using the no switchport command in INTERFACE mode. Assigning an IP Address to a VLAN VLANs are a Layer 2 feature. For two physical interfaces on different VLANs to communicate, you must assign an IP address to the VLANs to route traffic between the two interfaces.
To configure a port so that it can be a member of an untagged and tagged VLANs, use the following commands. 1. Remove any Layer 2 or Layer 3 configurations from the interface. INTERFACE mode 2. Configure the interface for Hybrid mode. INTERFACE mode portmode hybrid 3. Configure the interface for Switchport mode. INTERFACE mode switchport 4. Add the interface to a tagged or untagged VLAN.
VLT Proxy Gateway 60 The Virtual link trucking (VLT) proxy gateway feature allows a VLT domain to locally terminate and route L3 packets that are destined to a Layer 3 (L3) end point in another VLT domain. Enable the VLT proxy gateway using the link layer discover protocol (LLDP) method or the static configuration. For more information, refer to Dell Networking OS Command Line Reference Guide.
Guidelines for Enabling the VLT Proxy Gateway Keep the following points in mind when you enable a VLT proxy gateway: • • • • • • • Proxy gateway is supported only for VLT; for example, across a VLT domain. You must enable the VLT peer-routing command for the VLT proxy gateway to function. Asymmetric virtual local area network (VLAN) configuration, such as the same VLAN configured with Layer 2 (L2) mode on one VLT domain and L3 mode on another VLT domain is not supported.
• If the port-channel specified in the proxy-gateway command is not a VLT LAG, the configuration is rejected by the CLI. • You cannot change the VLT LAG to a legacy LAG when it is part of proxy-gateway. • You cannot change the link layer discovery protocol (LLDP) port channel interface to a legacy LAG when you enable a proxy gateway. • Dell Networking recommends the vlt-peer-mac transmit command only for square VLTs without diagonal links.
• LLDP uses the existing infrastructure and adds a new TLV for sending and receiving on the configured ports. • There are only a few MAC addresses for each unit transmitted. All currently active MAC addresses are carried on the newly defined TLV. • Dell Networking devices not configured with VLT proxy gateway process standard TLVs and ignore TLVs configured with VLT proxy gateway.
Sample Configuration for a VLT Proxy Gateway • The above figure shows a sample VLT Proxy gateway scenario. There are no diagonal links in the square VLT connection between the C and D in VLT domain 1 and C1 and D1 in the VLT domain 2. This causes sub-optimal routing with the VLT Proxy Gateway LLDP method. For VLT Proxy Gateway to work in this scenario you must configure the VLT-peer-mac transmit command under VLT Domain Proxy Gateway LLDP mode, in both C and D (VLT domain 1) and C1 and D1 (VLT domain 2).
address of D1, it may be dropped. This behavior is applicable only in an LLDP configuration; in a static configuration, the packet is forwarded. • Any L3 packet, when it gets an L3 hit and is routed, it has a time to live (TTL) decrement as expected. • You can disable the VLT Proxy Gateway for a particular VLAN using an "Exclude-VLAN" configuration. The configuration has to be done in both the VLT domains [C and D in VLT domain 1 and C1 and D1 in VLT domain 2].
2. Configure remote-mac-address in VLT Domain Proxy Gateway LLDP mode. Configure the system mac-addresses of both C and D in C1 and also in D1 in the remote VLT domain and vice versa. Sample Static Configuration on C switch or C1 switch Switch_C#conf Switch_C(conf)#vlt domain 1 Switch_C(conf-vlt-domain1)#proxy-gateway static Switch_C(conf-vlt-domain1-pxy-gw-static)#remote-mac-address ....
Virtual Link Trunking (VLT) 61 Overview VLT allows physical links between two chassis to appear as a single virtual link to the network core or other switches such as Edge, Access, or top-of-rack (ToR). VLT reduces the role of spanning tree protocols (STPs) by allowing link aggregation group (LAG) terminations on two separate distribution or core switches, and by supporting a loop-free topology. (To prevent the initial loop that may occur prior to VLT being established, use a spanning tree protocol.
Figure 131. VLT on S4048–ON Switches VLT on Core Switches Uplinks from servers to the access layer and from access layer to the aggregation layer are bundled in LAG groups with end-to-end Layer 2 multipathing. This set up requires “horizontal” stacking at the access layer and VLT at the aggregation layer such that all the uplinks from servers to access and access to aggregation are in Active-Active Load Sharing mode.
Figure 132. Enhanced VLT VLT Terminology The following are key VLT terms. • Virtual link trunk (VLT) — The combined port channel between an attached device and the VLT peer switches. • VLT backup link — The backup link monitors the vitality of VLT peer switches. The backup link sends configurable, periodic keep alive messages between the VLT peer switches. • VLT interconnect (VLTi) — The link used to synchronize states between the VLT peer switches.
Configure Virtual Link Trunking VLT requires that you enable the feature and then configure the same VLT domain, backup link, and VLT interconnect on both peer switches. Important Points to Remember • VLT port channel interfaces must be switch ports. • If you include RSTP on the system, configure it before VLT. Refer to Configure Rapid Spanning Tree. • If you include PVST on the system, configure it before VLT. Refer to PVST Configuration.
• VLT Heartbeat is supported only on default VRFs. • In a scenario where one hundred hosts are connected to a Peer1 on a non-VLT domain and traffic flows through Peer1 to Peer2; when you move these hosts from a non-VLT domain to a VLT domain and send ARP requests to Peer1, only half of these ARP requests reach Peer1, while the remaining half reach Peer2 (because of LAG hashing).
– The VLT interconnect must consist of either 10G or 40G ports. A maximum of eight 10G or four 40G ports is supported. A combination of 10G and 40G ports is not supported. – A VLT interconnect over 1G ports is not supported. – The port channel must be in Default mode (not Switchport mode) to have VLTi recognize it. – The system automatically includes the required VLANs in VLTi. You do not need to manually select VLANs.
– In order that the chassis backup link does not share the same physical path as the interconnect trunk, Dell Networking recommends using the management ports on the chassis and traverse an out-of-band management network. The backup link can use user ports, but not the same ports the interconnect trunk uses. – The chassis backup link does not carry control plane information or data traffic. Its use is restricted to health checks only.
– Enable Layer 3 VLAN connectivity VLT peers by configuring a VLAN network interface for the same VLAN on both switches. – Dell Networking does not recommend enabling peer-routing if the CAM is full. To enable peerrouting, a minimum of two local DA spaces for wild card functionality are required. • Software features supported on VLT physical ports – In a VLT domain, the following software features are supported on VLT physical ports: 802.
Primary and Secondary VLT Peers To prevent issues when connectivity between peers is lost, you can designate Primary and Secondary roles for VLT peers . You can elect or configure the Primary Peer. By default, the peer with the lowest MAC address is selected as the Primary Peer. You can configure another peer as the Primary Peer using the VLT domain domain-id role priority priority-value command. If the VLTi link fails, the status of the remote VLT Primary Peer is checked using the backup link.
When the bandwidth usage drops below the 80% threshold, the system generates another syslog message (shown in the following message) and an SNMP trap. %STKUNIT0-M:CP %VLTMGR-6-VLT-LAG-ICL: Overall Bandwidth utilization of VLT-ICLLAG (port-channel 25) reaches below threshold. Bandwidth usage (74 )VLT show remote port channel status VLT and Stacking You cannot enable stacking on S4048–ON units with VLT.
This delay in bringing up the VLT ports also applies when the VLTi link recovers from a failure that caused the VLT ports on the secondary VLT peer node to be disabled. PIM-Sparse Mode Support on VLT The designated router functionality of the PIM Sparse-Mode multicast protocol is supported on VLT peer switches for multicast sources and receivers that are connected to VLT ports. VLT peer switches can act as a last-hop router for IGMP receivers and as a first-hop router for multicast sources. Figure 133.
ensures that for first hop routers, the packets from the source are redirected to the designated router (DR) if they are incorrectly hashed. In addition to being first-hop or last -hop routers, the peer node can also act as an intermediate router. On a VLT-enabled PIM router, if any PIM neighbor is reachable through a Spanned Layer 3 (L3) VLAN interface, this must be the only PIM-enabled interface to reach that neighbor. A Spanned L3 VLAN is any L3 VLAN configured on both peers in a VLT domain.
time needed for peer recovery provides resiliency. You can enable VLT unicast across multiple configurations using VLT links. You can enable ECMP on VLT nodes using VLT unicast. VLT unicast routing is supported on both IPv6/IPv4. To enable VLT unicast routing, both VLT peers must be in L3 mode. Static route and routing protocols such as RIP, OSPF, ISIS, and BGP are supported. However, point-to-point configuration is not supported. To enable VLT unicast, VLAN configuration must be symmetrical on both peers.
• • • VLT resiliency — After a VLT link or peer failure, if the traffic hashes to the VLT peer, the traffic continues to be routed using multicast until the PIM protocol detects the failure and adjusts the multicast distribution tree. Optimal routing — The VLT peer that receives the incoming traffic can directly route traffic to all downstream routers connected on VLT ports.
NOTE: ARP entries learned on non-VLT, non-spanned VLANs are not synced with VLT peers. RSTP Configuration RSTP is supported in a VLT domain. Before you configure VLT on peer switches, configure RSTP in the network. RSTP is required for initial loop prevention during the VLT startup phase. You may also use RSTP for loop prevention in the network outside of the VLT port channel. For information about how to configure RSTP, Rapid Spanning Tree Protocol (RSTP). Run RSTP on both VLT peer switches.
VLT switch determines the RSTP roles and states on VLT ports and ensures that the VLT interconnect link is never blocked. In the case of a primary VLT switch failure, the secondary switch starts sending BPDUs with its own bridge ID and inherits all the port states from the last synchronization with the primary switch. An access device never detects the change in primary/secondary roles and does not see it as a topology change.
Enter the same port-channel number configured with the peer-link port-channel command as described in Enabling VLT and Creating a VLT Domain. NOTE: To be included in the VLTi, the port channel must be in Default mode (no switchport or VLAN assigned). 2. Remove an IP address from the interface. INTERFACE PORT-CHANNEL mode no ip address 3. Add one or more port interfaces to the port channel.
You can optionally specify the time interval used to send hello messages. The range is from 1 to 5 seconds. 3. Configure the port channel to be used as the VLT interconnect between VLT peers in the domain. VLT DOMAIN CONFIGURATION mode peer-link port-channel id-number 4. (Optional) Prevent a possible loop during the bootup of a VLT peer switch or a device that accesses the VLT domain.
Configuring a VLT Port Delay Period To configure a VLT port delay period, use the following commands. 1. Enter VLT-domain configuration mode for a specified VLT domain. CONFIGURATION mode vlt domain domain-id The range of domain IDs from 1 to 1000. 2. Enter an amount of time, in seconds, to delay the restoration of the VLT ports after the system is rebooted. CONFIGURATION mode delay-restore delay-restore-time The range is from 1 to 1200. The default is 90 seconds.
Use this command to minimize the time required for the VLT system to synchronize the default MAC address of the VLT domain on both peer switches when one peer switch reboots. 4. (Optional) When you create a VLT domain on a switch, Dell Networking OS automatically assigns a unique unit ID (0 or 1) to each peer switch. VLT DOMAIN CONFIGURATION mode unit-id {0 | 1} To explicitly configure the default values on each peer switch, use the unit-id command.
vlt-peer-lag port-channel id-number The valid port-channel ID numbers are from 1 to 128. 7. Repeat Steps 1 to 6 on the VLT peer switch to configure the same port channel as part of the VLT domain. 8. On an attached switch or server: To connect to the VLT domain and add port channels to it, configure a port channel. For an example of how to verify the port-channel configuration, refer to VLT Sample Configuration.
INTERFACE PORT-CHANNEL mode channel-member interface interface: specify one of the following interface types: • For a 10-Gigabit Ethernet interface, enter the keyword TenGigabitEthernet then the slot/ port[/subport] information. • 3. For a 40-Gigabit Ethernet interface, enter the keyword fortyGigE then the slot/port information. Enter VLT-domain configuration mode for a specified VLT domain. CONFIGURATION mode vlt domain domain-id The range of domain IDs is from 1 to 1000. 4.
Configure a different unit ID (0 or 1) on each peer switch. Use this command to minimize the time required for the VLT system to determine the unit ID assigned to each peer switch when one peer switch reboots. 8. Configure enhanced VLT. Configure the port channel to be used for the VLT interconnect on a VLT switch and enter interface configuration mode.
VLT Sample Configuration To review a sample VLT configuration setup, study these steps. 1. Configure the VLT domain with the same ID in VLT peer 1 and VLT peer 2. VLT DOMAIN mode vlt domain domain id 2. Configure the VLTi between VLT peer 1 and VLT peer 2. 3. You can configure LACP/static LAG between the peer units (not shown).
EXEC mode or EXEC Privilege mode show interfaces interface Example of Configuring VLT In the following sample VLT configuration steps, VLT peer 1 is Dell-2, VLT peer 2 is Dell-4, and the ToR is S60-1. NOTE: If you use a third-party ToR unit, Dell Networking recommends using static LAGs with VLT peers to avoid potential problems if you reboot the VLT peers. Configure the VLT domain with the same ID in VLT peer 1 and VLT peer 2.
Configure the VLT links between VLT peer 1 and VLT peer 2 to the Top of Rack unit. In the following example, port Te 1/4 in VLT peer 1 is connected to Te 1/8 of TOR and port Te 1/18 in VLT peer 2 is connected to Te 1/30 of TOR. 1. Configure the static LAG/LACP between the ports connected from VLT peer 1 and VLT peer 2 to the Top of Rack unit. 2. Configure the VLT peer link port channel id in VLT peer 1 and VLT peer 2. 3.
switchport no shutdown s60-1#show interfaces port-channel 100 brief Codes: L - LACP Port-channel L LAG 100 Mode L2 Status up Uptime 03:33:48 Ports Te 1/8 (Up) Te 1/30 (Up) Verify VLT is up. Verify that the VLTi (ICL) link, backup link connectivity (heartbeat status), and VLT peer link (peer chassis) are all up.
Secondary peers. Only the Primary VLT switch determines the PVST+ roles and states on VLT ports and ensures that the VLT interconnect link is never blocked. PVST+ instance in Primary peer will send the role/state of VLT-LAGs for all VLANs to the Secondary peer. Secondary peer will use this information to program the hardware. PVST+ instance running in Secondary peer will not control the VLT-LAGs.
eVLT Configuration Example The following example demonstrates the steps to configure enhanced VLT (eVLT) in a network. In this example, you are configuring two domains. Domain 1 consists of Peer 1 and Peer 2; Domain 2 consists of Peer 3 and Peer 4, as shown in the following example. In Domain 1, configure Peer 1 fist, then configure Peer 2. When that is complete, perform the same steps for the peer nodes in Domain 2. The interface used in this example is TenGigabitEthernet. Figure 134.
Domain_1_Peer1(conf-if-range-te-1/16-17)# port-channel 100 mode active Domain_1_Peer1(conf-if-range-te-1/16-17)# no shutdown Next, configure the VLT domain and VLTi on Peer 2.
Next, configure the VLT domain and VLTi on Peer 4. Domain_2_Peer4#configure Domain_2_Peer4(conf)#interface port-channel 1 Domain_2_Peer4(conf-if-po-1)# channel-member TenGigabitEthernet 1/8-9 Domain_1_Peer4#no shutdown Domain_2_Peer4(conf)#vlt domain 200 Domain_2_Peer4(conf-vlt-domain)# peer-link port-channel 1 Domain_2_Peer4(conf-vlt-domain)# back-up destination 10.18.130.
The following example shows how to repeat these steps on VLT Peer Node 2. VLT_Peer2(conf)#ip multicast-routing VLT_Peer2(conf)#interface vlan 4001 VLT_Peer2(conf-if-vl-4001)#ip address 140.0.0.
show interfaces interface – interface: specify one of the following interface types: * For a 10-Gigabit Ethernet interface, enter the keyword TenGigabitEthernet then the slot/ port[/subport] information. * For a 40-Gigabit Ethernet interface, enter the keyword fortyGigE then the slot/port information. * For a port channel interface, enter the keywords port-channel then a number. Examples of the show vlt and show spanning-tree rstp Commands The following example shows the show vlt backup-link command.
The following example shows the show vlt detail command. Dell_VLTpeer1# show vlt detail Local LAG Id -----------100 127 Peer LAG Id ----------100 2 Local Status Peer Status Active VLANs ------------ ----------- ------------UP UP 10, 20, 30 UP UP 20, 30 Dell_VLTpeer2# show vlt detail Local LAG Id -----------2 100 Peer LAG Id ----------127 100 Local Status -----------UP UP Peer Status ----------UP UP Active VLANs ------------20, 30 10, 20, 30 The following example shows the show vlt role command.
Dell_VLTpeer2# show vlt statistics VLT Statistics ---------------HeartBeat Messages Sent: HeartBeat Messages Received: ICL Hello's Sent: ICL Hello's Received: 994 978 89 89 The following example shows the show spanning-tree rstp command. The bold section displays the RSTP state of port channels in the VLT domain. Port channel 100 is used in the VLT interconnect trunk (VLTi) to connect to VLT peer2. Port channels 110, 111, and 120 are used to connect to access switches or servers (vlt).
Configuring Virtual Link Trunking (VLT Peer 1) Enable VLT and create a VLT domain with a backup-link and interconnect trunk (VLTi). Dell_VLTpeer1(conf)#vlt domain 999 Dell_VLTpeer1(conf-vlt-domain)#peer-link port-channel 100 Dell_VLTpeer1(conf-vlt-domain)#back-up destination 10.11.206.35 Dell_VLTpeer1(conf-vlt-domain)#exit Configure the backup link. Dell_VLTpeer1(conf)#interface ManagementEthernet 1/1 Dell_VLTpeer1(conf-if-ma-1/1)#ip address 10.11.206.
Configure the VLT interconnect (VLTi). Dell_VLTpeer2(conf)#interface port-channel 100 Dell_VLTpeer2(conf-if-po-100)#no ip address Dell_VLTpeer2(conf-if-po-100)#channel-member fortyGigE 1/51,52 Dell_VLTpeer2(conf-if-po-100)#no shutdown Dell_VLTpeer2(conf-if-po-100)#exit Configure the port channel to an attached device.
Description Behavior at Peer Up Behavior During Run Time Action to Take The VLT peer does not boot up. The VLTi is forced to a down state. The VLT peer does not boot up. The VLTi is forced to a down state. Verify the domain ID matches on both VLT peers. A syslog error message and an SNMP trap are generated. A syslog error message and an SNMP trap are generated. Dell Networking OS Version mismatch A syslog error message is generated. A syslog error message is generated.
Description Behavior at Peer Up Behavior During Run Time Action to Take peers is compatible. For more information, refer to the Release Notes for this release. VLT LAG ID is not configured on one VLT peer A syslog error message is generated. The peer with the VLT configured remains active. A syslog error message is generated. The peer with the VLT configured remains active. Verify the VLT LAG ID is configured correctly on both VLT peers. VLT LAG ID mismatch The VLT port channel is brought down.
an automatic member of that PVLAN on both switches. This association helps the PVLAN data flow received on one VLT peer for a VLT LAG to be transmitted on that VLT LAG from the peer. You can associate either a VLT VLAN or a VLT LAG to a PVLAN. First configure the VLT interconnect (VLTi) or a VLT LAG by using the peer-link port-channel id-number command or the VLT VLAN by using the peer-link port-channel id-number peer-down-vlan vlan interface number command and the switchport command.
VLT VLAN on one peer and not a primary VLT VLAN on the other peer, VLTi is not made a part of that VLAN. MAC Synchronization for VLT Nodes in a PVLAN For the MAC addresses that are learned on non-VLT ports, MAC address synchronization is performed with the other peer if the VLTi (ICL) link is part of the same VLAN as the non-VLT port. For MAC addresses that are learned on VLT ports, the VLT LAG mode of operation and the primary to secondary association of the VLT nodes is determined on both the VLT peers.
Interoperation of VLT Nodes in a PVLAN with ARP Requests When an ARP request is received, and the following conditions are applicable, the IP stack performs certain operations. • The VLAN on which the ARP request is received is a secondary VLAN (community or isolated VLAN). • Layer 3 communication between secondary VLANs in a private VLAN is enabled by using the ip local-proxy-arp command in INTERFACE VLAN configuration mode.
VLT LAG Mode PVLAN Mode of VLT VLAN Peer1 Peer2 Peer1 Peer2 Access Access Secondary (Community) • Promiscuo us Promiscuo us Primary X ICL VLAN Membership Mac Synchronization Secondary (Isolated) No No • Yes Yes Primary X Primary Primary Yes Yes - Secondary (Community) - Secondary (Community) Yes Yes - Secondary (Isolated) - Secondary (Isolated) Yes Yes Promiscuo us Trunk Primary Normal No No Promiscuo us Trunk Primary Primary Yes No Access Access Secondary (Com
pair. With VLT being a Layer 2 redundancy feature, support for configuration of VLT nodes in a PVLAN enables Layer 2 security functionalities to be achieved. This section contains the following topics that describe how to configure a VLT VLAN or a VLT LAG (VLTi link) and assign that VLT interface to a PVLAN. Creating a VLT LAG or a VLT VLAN 1. Configure the port channel for the VLT interconnect on a VLT switch and enter interface configuration mode CONFIGURATION mode interface port-channel id-number.
peer-link port-channel id-number peer-down-vlan vlan interface number The range is from 1 to 4094. Associating the VLT LAG or VLT VLAN in a PVLAN 1. Access INTERFACE mode for the port that you want to assign to a PVLAN. CONFIGURATION mode interface interface 2. Enable the port. INTERFACE mode no shutdown 3. Set the port in Layer 2 mode. INTERFACE mode switchport 4. Select the PVLAN mode. INTERFACE mode switchport mode private-vlan {host | promiscuous | trunk} 5.
• Amended by specifying the new secondary VLAN to be added to the list. Proxy ARP Capability on VLT Peer Nodes The proxy ARP functionality is supported on VLT peer nodes. A proxy ARP-enabled device answers the ARP requests that are destined for another host or router. The local host forwards the traffic to the proxy ARP-enabled device, which in turn transmits the packets to the destination. By default, proxy ARP is enabled. To disable proxy ARP, use the no proxy-arp command in the interface mode.
secondary VLANs. When the ICL link or peer is down, and the ARP request for a private VLAN IP address reaches the wrong peer, then the wrong peer responds to the ARP request with the peer MAC address. The IP address of the VLT node VLAN interface is synchronized with the VLT peer over ICL when the VLT peers are up. Whenever an IP address is added or deleted, this updated information is synchronized with the VLT peer. IP address synchronization occurs regardless of the VLAN administrative state.
If the same source or RP can be accessed over both a VLT and a non-VLT VLAN, configure better metrics for the VLT VLANs. Otherwise, it is possible that one VLT node chooses a non-VLT VLAN (if the path through the VLT VLAN was not available when the route was learned) and another VLT node selects a VLT VLAN. Such a scenario can cause duplication of packets. ECMP is not supported when you configure VLT nodes as RPs. Backup RP is not supported if the VLT peer that functions as the RP is statically configured.
Dell#show running-config vlt ! vlt domain 1 peer-link port-channel 1 back-up destination 10.16.151.
Verify that the Port Channels used in the VLT Domain are Assigned to the VLAN-Stack VLAN Dell#show vlan id 50 Codes: * - Default VLAN, G - GVRP VLANs, R - Remote Port Mirroring VLANs, P Primary, C - Community, I - Isolated O - Openflow Q: U - Untagged, T - Tagged x - Dot1x untagged, X - Dot1x tagged o - OpenFlow untagged, O - OpenFlow tagged G - GVRP tagged, M - Vlan-stack i - Internal untagged, I - Internal tagged, v - VLT untagged, V - VLT tagged NUM 50 Status Active Description Dell# Q M M V Ports P
! interface Port-channel 20 no ip address switchport vlan-stack trunk vlt-peer-lag port-channel 20 no shutdown Dell# Configure the VLAN as VLAN-Stack VLAN and add the VLT LAG as members to the VLAN Dell(conf)#interface vlan 50 Dell(conf-if-vl-50)#vlan-stack compatible Dell(conf-if-vl-50-stack)#member port-channel 10 Dell(conf-if-vl-50-stack)#member port-channel 20 Dell(conf-if-vl-50-stack)# Dell#show running-config interface vlan 50 ! interface Vlan 50 vlan-stack compatible member Port-channel 10,20 shutdow
Peer routing for IPv6 packets in a VLT domain is supported. This mechanism of IPv6 peer routing is supported on all the platforms that are compatible with IPv6 routing and support VLT. This functionality performs the following operations: • Forwarding the control traffic to correct VLT node when the control traffic reaches wrong VLT node due to hashing at the VLT LAG level on the ToR. • Routing the data traffic which is destined to peer VLT node.
During failure cases, when a VLT node goes down and comes back up all the ND entries learned via VLT interface must be synchronized to the peer VLT node Synchronization of IPv6 ND Entries in a Non-VLT Domain L3 VLT provides a higher resiliency at the Layer 3 forwarding level. Routed VLT enables you to replace VRRP with routed VLT to route the traffic from L2 access nodes. With ND synchronization, both the VLT nodes perform Layer 3 forwarding on behalf of each other.
Sample Configuration of IPv6 Peer Routing in a VLT Domain Consider a sample scenario as shown in the following figure in which two VLT nodes, Unit1 and Unit2, are connected in a VLT domain using an ICL or VLTi link. To the south of the VLT domain, UNit1 and Unit2 are connected to a ToR switch named Node B. Also, Unit1 is connected to another node, Node A, and Unit2 is linked to a node, Node C. The network between TOR to VLT Nodes is purely L2 in nature.
Neighbor Solicitation from VLT Hosts Consider a case in which NS for VLT node1 IP reaches VLT node1 on VLT interface and NS for VLT node1 IP reaches VLT node2 due to LAG level hashing in TOR. When VLT node1 receives NS from VLT VLAN interface, it unicasts NA packet on the VLT interface. When NS reaches VLT node2 it is flooded on all interfaces including ICL. When VLT node 1 receives NS on ICL then it floods NA packet on the VLAN.
Consider a sample scenario in which NS for VLT node1 IP reaches VLT node1 on non-VLT interface and NS for VLT node1 IP reaches VLT node2 on non-VLT interface. When VLT node1 receives NS from nonVLT interface, it unicasts NA packet on the received interface. When NS reaches VLT node2 it is VLAN flooded on all interfaces including ICL. When VLT node 1 receives NS on ICL then it floods NA packet on the VLAN. If NS is unicast and if reaches wrong VLT peer it is lifted to CPU using ACL entry.
When VLT node receives traffic intended to non-VLT host, it routes the traffic over non-VLT interface. If the traffic intended to non-VLT host reaches wrong VLT peer due to LAG hashing in TOR, the wrong VLT node will resolve the destination over ICL and routes the traffic over ICL. When Correct VLT node receives this routed traffic over ICL it will switch traffic to non-VLT interface.
Virtual Extensible LAN (VXLAN) 62 Virtual Extensible LAN (VXLAN) is supported on Dell Networking OS. Overview The switch acts as the VXLAN gateway and performs the VXLAN Tunnel End Point (VTEP) functionality. VXLAN is a technology where in the data traffic from the virtualized servers is transparently transported over an existing legacy network. Components of VXLAN network VXLAN provides a mechanism to extend an L2 network over an L3 network.
• Network Virtualization Platform (NVP) Controller • VTEP (VXLAN Tunnel End Point) • VXLAN Gateway • VXLAN Hypervisor • Service Node (SN) • Legacy TOR Network Virtualization Platform (NVP) Controller NVP Controller is the network controller for managing cloud components. The OVSDB protocol is the protocol used for communication between VTEPs and the controller. In the current release, the qualified controller for the VXLAN Gateway function is NSX-from VMWare.
Functional Overview of VXLAN Gateway The following section is the functional overview of VXLAN Gateway: 1. Provides connectivity between a Virtual server infrastructure and a Physical server infrastructure. 2. Provides the functions performed by a VTEP in a virtual server infrastructure. The functions of a VTEP are: • VTEP is responsible for creating one or more logical networks.
Outer Ethernet Header: Outer IP Header: Outer UDP Header: VXLAN Header : Frame Check Sequence (FCS): The Outer Ethernet Header consists of the following components: • Destination Address: Generally, it is a first hop router's MAC address when the VTEP is on a different address. • Source Address : It is the source MAC address of the router that routes the packet. • VLAN: It is optional in a VXLAN implementation and will be designated by an ethertype of 0×8100 and has an associated VLAN ID tag.
2. Create Service Node To create service node, the required fields are the IP address and SSL certificate of the server. The Service node is responsible for broadcast/unknown unicast/multicast traffic replication.
3. Create VXLAN Gateway To create a VXLAN L2 Gateway, the IP address of the Gateway is mandatory. The following is the snapshot of the user interface in creating a VXLAN Gateway 4. Create Logical Switch You can create a logical network by creating a logical switch. The logical network acts as the forwarding domain for workloads on the physical as well as virtual infrastructure. 5.
Configuring VxLAN Gateway To configure the VxLAN gateway on the switch, follow these steps: 1. Connecting to NVP controller 2. Advertising VXLAN access ports to controller Connecting to an NVP Controller To connect to an NVP controller, use the following commands. 1. feature vxlan CONFIGURATION mode feature vxlan You must configure feature VXLAN to configure vxlan-instance. 2.
Advertising VXLAN Access Ports to Controller To advertise the access ports to the controller, use the following command. In INTERFACE mode, vxlan-instance command configures a VXLAN-Access Port into a VXLANinstance. INTERFACE mode vxlan-instance Examples of the show vxlan-instance Command Dell#show vxlan Instance Admin State Management IP Gateway IP MAX Backoff Controller 1 Fail Mode Port List Fo 1/49 Te vxlan-instance 1 : 1 : enabled : 192.168.200.200 : 3.3.3.3 : 30000 : 192.168.122.
Tunnel : count 1 36.1.1.1 : vxlan_over_ipv4 (up) The following example shows the show vxlan vxlan-instance unicast-mac-local command.
VFI : 28674 Unknown Multicast MAC Tunnels: 192.168.122.133 : vxlan_over_ipv4 (up) Port Vlan Bindings: Te 0/80: VLAN: 0 (0x80000001), Fo 0/124: VLAN: 0 (0x80000004), The following example shows the show vxlan vxlan-instance statistics interface command. Dell#show vxlan vxlan-instance 1 statistics interface fortyGigE 0/124 100 Port : Fo 0/124 Vlan : 100 Rx Packets : 13 Rx Bytes : 1317 Tx Packets : 13 Tx Bytes : 1321 The following example shows the show vxlan vxlan-instance physical-locator command.
Virtual Routing and Forwarding (VRF) 63 Virtual Routing and Forwarding (VRF) allows a physical router to partition itself into multiple Virtual Routers (VRs). The control and data plane are isolated in each VR so that traffic does NOT flow across VRs.Virtual Routing and Forwarding (VRF) allows multiple instances of a routing table to co-exist within the same router at the same time. VRF Overview VRF improves functionality by allowing network paths to be segmented without using multiple devices.
Figure 135. VRF Network Example VRF Configuration Notes Although there is no restriction on the number of VLANs that can be assigned to a VRF instance, the total number of routes supported in VRF is limited by the size of the IPv4 CAM. VRF is implemented in a network device by using Forwarding Information Bases (FIBs). A network device may have the ability to configure different virtual routers, where entries in the FIB that belong to one VRF cannot be accessed by another VRF on the same device.
Dell Networking OS uses both the VRF name and VRF ID to manage VRF instances. The VRF name and VRF ID number are assigned using the ip vrf command. The VRF ID is displayed in show ip vrf command output. The VRF ID is not exchanged between routers. VRF IDs are local to a router. VRF supports some routing protocols only on the default VRF (default-vrf) instance. Table 1 displays the software features supported in VRF and whether they are supported on all VRF instances or only the default VRF. Table 85.
Feature/Capability Support Status for Default VRF Support Status for Non-default VRF NOTE: ACLs supported on all VRF VLAN ports. IPv4 ACLs are supported on nondefault-VRFs also. IPv6 ACLs are supported on defaultVRF only. PBR supported on default-VRF only. QoS not supported on VLANs.
DHCP DHCP requests are not forwarded across VRF instances. The DHCP client and server must be on the same VRF instance. VRF Configuration The VRF configuration tasks are: 1. Enabling VRF in Configuration Mode 2. Creating a Non-Default VRF 3. Assign an Interface to a VRF You can also: • View VRF Instance Information • Connect an OSPF Process to a VRF Instance • Configure VRRP on a VRF Load VRF CAM VRF is enabled by default on the switch.
Task Command Syntax Command Mode Assign an interface to a VRF instance. ip vrf forwarding vrfname INTERFACE Assigning a Front-end Port to a Management VRF Starting in 9.7(0.0) release, you can assign a front-end port to a management VRF and make the port to act as a host interface. NOTE: You cannot assign loop-back and port-channel interfaces to a management port.
Assigning an OSPF Process to a VRF Instance OSPF routes are supported on all VRF instances. Refer toOpen Shortest Path First (OSPFv2) for complete OSPF configuration information. Assign an OSPF process to a VRF instance . Return to CONFIGURATION mode to enable the OSPF process. The OSPF Process ID is the identifying number assigned to the OSPF process, and the Router ID is the IP address associated with the OSPF process.
Task Command Syntax View VRRP command output for the VRF vrf1 show vrrp vrf vrf1 -----------------TenGigabitEthernet 1/13, IPv4 VRID: 10, Version: 2, Net: 10.1.1.1 VRF: 2 vrf1 State: Master, Priority: 100, Master: 10.1.1.1 (local) Hold Down: 0 sec, Preempt: TRUE, AdvInt: 1 sec Adv rcvd: 0, Bad pkts rcvd: 0, Adv sent: 43, Gratuitous ARP sent: 0 Virtual MAC address: 00:00:5e:00:01:0a Virtual IP address: 10.1.1.
NOTE: The command line help still displays relevant details corresponding to each of these commands. However, these interface range or interface group commands are not supported when Management VRF is configured. Configuring a Static Route To configure a static route, perform the following steps: Task Command Syntax Command Mode Configure a static route that points to a management interface.
Figure 136.
Figure 137. Setup VRF Interfaces The following example relates to the configuration shown in Figure1 and Figure 2. Router 1 ip vrf blue 1 ! ip vrf orange 2 ! ip vrf green 3 ! interface TenGigabitEthernet 3/1 no ip address switchport no shutdown ! interface TenGigabitEthernet 1/1 ip vrf forwarding blue ip address 10.0.0.
interface TenGigabitEthernet 1/2 ip vrf forwarding orange ip address 20.0.0.1/24 no shutdown ! interface TenGigabitEthernet 1/3 ip vrf forwarding green ip address 30.0.0.1/24 no shutdown ! interface Vlan 128 ip vrf forwarding blue ip address 1.0.0.1/24 tagged TenGigabitEthernet 3/1 no shutdown ! interface Vlan 192 ip vrf forwarding orange ip address 2.0.0.1/24 tagged TenGigabitEthernet 3/1 no shutdown ! interface Vlan 256 ip vrf forwarding green ip address 3.0.0.
interface TenGigabitEthernet 2/2 ip vrf forwarding orange ip address 21.0.0.1/24 no shutdown ! interface TenGigabitEthernet 2/3 ip vrf forwarding green ip address 31.0.0.1/24 no shutdown ! interface Vlan 128 ip vrf forwarding blue ip address 1.0.0.2/24 tagged TenGigabitEthernet 3/1 no shutdown interface Vlan 192 ip vrf forwarding orange ip address 2.0.0.2/24 tagged TenGigabitEthernet 3/1 no shutdown ! interface Vlan 256 ip vrf forwarding green ip address 3.0.0.
orange 2 green 3 Dell#show ip ospf 1 neighbor Neighbor ID Pri State 1.0.0.2 1 FULL/DR Dell#sh ip ospf 2 neighbor Neighbor ID Pri State 2.0.0.2 1 FULL/DR Dell#show ip route vrf blue Te Vl Te Vl 1/2, 192 1/3, 256 Dead Time Address Interface Area 00:00:32 1.0.0.2 Vl 128 0 Dead Time Address Interface Area 00:00:37 2.0.0.
O - OSPF, IA - OSPF inter area, N1 - OSPF NSSA external type 1, N2 - OSPF NSSA external type 2, E1 - OSPF external type 1, E2 - OSPF external type 2, i - IS-IS, L1 - IS-IS level-1, L2 - IS-IS level-2, IA - IS-IS inter area, * - candidate default, > - non-active route, + - summary route Gateway of last resort is not set Destination Gateway Dist/Metric Last Change ------------------------------------C 3.0.0.0/24 Direct, Vl 256 0/0 00:20:52 C 30.0.0.0/24 Direct, Te 1/3 0/0 00:09:45 S 31.0.0.0/24 via 3.0.0.
L2 - IS-IS level-2, IA - IS-IS inter area, * - candidate default, > - non-active route, + - summary route Gateway of last resort is not set Destination Gateway Last Change --------------------------C 1.0.0.0/24 Direct, Vl 128 0/0 00:27:21 O 10.0.0.0/24 via 1.0.0.1, Vl 128 110/2 00:14:24 C 11.0.0.
0/0 Dell# 00:20:19 Route Leaking VRFs Static routes can be used to redistribute routes between non-default to default/non-default VRF and vice-versa. You can configure route leaking between two VRFs using the following command: ip route vrf x.x.x.x s.s.s.s nh.nh.nh.nh vrf default. This command indicates that packets that are destined to x.x.x.x/s.s.s.s are reachable through nh.nh.nh.nh in the default VRF table. Meaning, the routes to x.x.x.x/s.s.s.
After the target VRF learns routes that are leaked by the source VRF, the source VRF in turn can leak the export target corresponding to the destination VRFs that have imported its routes. The source VRF learns the export target corresponding to the destinations VRF using the ip route-import tag or ipv6 route-import tag command. This mechanism enables reverse communication between destination VRF and the source VRF.
! ip vrf ip ip ! ip vrf ! ip vrf ip ip ip VRF-Blue route-export route-import 3:3 1:1 VRF-Green VRF-shared route-export route-import route-import 1:1 2:2 3:3 Show routing tables of all the VRFs (without any route-export and route-import tags being configured) Dell# show ip route vrf VRF-Red O 11.1.1.1/32 via 111.1.1.1 110/0 C 111.1.1.0/24 Direct, Te 1/11 0/0 00:00:10 22:39:59 Dell# show ip route vrf VRF-Blue O 22.2.2.2/32 via 122.2.2.2 110/0 00:00:11 C 122.2.2.
C 133.3.3.0/24 Direct, Te 1/13 0/0 22:39:61 Dell# show ip route vrf VRF-Shared O 11.1.1.1/32 via VRF-Red:111.1.1.1 110/0 C 111.1.1.0/24 Direct, VRF-Red:Te 1/11 0/0 O 22.2.2.2/32 via VRF-Blue:122.2.2.2 110/0 C 122.2.2.0/24 Direct, VRF-Blue:Te 1/22 0/0 O 44.4.4.4/32 via 144.4.4.4 110/0 00:00:11 C 144.4.4.
route-map import_ospf_protocol and then specify the match criteria as OSPF using the match sourceprotocol ospf command. You can then use the ip route-import route-map command to import routes matching the filtering criteria defined in the import_ospf_protocol route-map. For a reply communication, VRF-blue is configured with a route-export tag. This value is then configured as route-import tag on the VRF-Red. To configure route leaking using filtering criteria, perform the following steps: 1.
The show VRF commands displays the following output: Dell# show ip route vrf VRF-Blue C 122.2.2.0/24 Direct, Te 1/22 O 22.2.2.2/32 via 122.2.2.2 00:00:11 O 44.4.4.4/32 0/0 110/0 22:39:61 via vrf-red:144.4.4.4 0/0 00:32:36 << only OSPF and BGP leaked from VRF-red Important Points to Remember • Only Active routes are eligible for leaking. For example, if VRF-A has two routes from BGP and OSPF, in which the BGP route is not active. In this scenario, the OSPF route takes precedence over BGP.
Virtual Router Redundancy Protocol (VRRP) 64 Virtual router redundancy protocol (VRRP) is supported on Dell Networking OS. VRRP Overview VRRP is designed to eliminate a single point of failure in a statically routed network. VRRP specifies a MASTER router that owns the next hop IP and MAC address for end stations on a local area network (LAN). The MASTER router is chosen from the virtual routers by an election process and forwards packets sent to the next hop IP address.
Figure 138. Basic VRRP Configuration VRRP Benefits With VRRP configured on a network, end-station connectivity to the network is not subject to a single point-of-failure. End-station connections to the network are redundant and are not dependent on internal gateway protocol (IGP) protocols to converge or update routing tables. VRRP Implementation Within a single VRRP group, up to 12 virtual IP addresses are supported.
decreases based on the dynamics of the network, the advertisement intervals may increase or decrease accordingly. CAUTION: Increasing the advertisement interval increases the VRRP Master dead interval, resulting in an increased failover time for Master/Backup election. Take caution when increasing the advertisement interval, as the increased dead interval may cause packets to be dropped during that switch-over time. Table 86.
• Create a virtual router for that interface with a VRID. INTERFACE mode vrrp-group vrid The VRID range is from 1 to 255. • NOTE: The interface must already have a primary IP address defined and be enabled, as shown in the second example. Delete a VRRP group. INTERFACE mode no vrrp-group vrid Examples of Configuring and Verifying VRRP The following examples how to configure VRRP.
To migrate an IPv4 VRRP group from VRRPv2 to VRRPv3: 1. Set the switches with the lowest priority to “both”. 2. Set the switch with the highest priority to version to 3. 3. Set all the switches from both to version 3. NOTE: Do not run VRRP version 2 and version 3 in the same group for an extended period of time Example: Migrating an IPv4 VRRP Group from VRRPv2 to VRRPv3 NOTE: Carefully following this procedure, otherwise you might introduce dual master switches issues.
• • group and the interface’s physical MAC address is changed to that of the owner VRRP group’s MAC address. If you configure multiple VRRP groups on an interface, only one of the VRRP Groups can contain the interface primary or secondary IP address. On a stack system, if a force failover is performed on a master stack unit, the VRRP virtual addresses are disabled. To re-enable VRRP, execute the mac-address-table station-move refresh-arp command.
Adv rcvd: 0, Bad pkts rcvd: 0, Adv sent: 1768, Gratuitous ARP sent: 5 Virtual MAC address: 00:00:5e:00:01:6f Virtual IP address: 10.10.10.1 10.10.10.2 10.10.10.3 10.10.10.10 Authentication: (none) -----------------TenGigabitEthernet 1/2, VRID: 111, Net: 10.10.2.1 State: Master, Priority: 100, Master: 10.10.2.1 (local) Hold Down: 0 sec, Preempt: TRUE, AdvInt: 1 sec Adv rcvd: 0, Bad pkts rcvd: 0, Adv sent: 27, Gratuitous ARP sent: 2 Virtual MAC address: 00:00:5e:00:01:6f Virtual IP address: 10.10.2.2 10.10.2.
State: Master, Priority: 125, Master: 10.10.2.1 (local) Hold Down: 0 sec, Preempt: TRUE, AdvInt: 1 sec Adv rcvd: 0, Bad pkts rcvd: 0, Adv sent: 601, Gratuitous ARP sent: 2 Virtual MAC address: 00:00:5e:00:01:6f Virtual IP address: 10.10.2.2 10.10.2.3 Authentication: (none) Configuring VRRP Authentication Simple authentication of VRRP packets ensures that only trusted routers participate in VRRP processes. When you enable authentication, Dell Networking OS includes the password in its VRRP transmission.
• Prevent any BACKUP router with a higher priority from becoming the MASTER router. INTERFACE-VRID mode no preempt Examples of Disabling Preempt Re-enable preempt by entering the preempt command. When you enable preempt, it does not display in the show commands, because it is a default setting. The following example shows how to disable preempt using the no preempt command.
The range is from 1 to 255 seconds. • The default is 1 second. For VRRPv3, change the advertisement centisecs interval setting. INTERFACE-VRID mode advertise-interval centisecs centisecs The range is from 25 to 4075 centisecs in units of 25 centisecs. The default is 100 centisecs. Examples of the advertise-interval Command The following example shows how to change the advertise interval using the advertise-interval command.
• For a port channel interface, enter the keywords port-channel then a number. – For the S-Series, the valid port channel numbers are from 1 to 128. • For a VLAN interface, enter the keyword vlan then a number from 1 to 4094. For a virtual group, you can also track the status of a configured object (the track object-id command) by entering its object number.
The following example shows how to verify tracking using the show conf command. Dell(conf-if-te-1/1-vrid-111)#show conf ! vrrp-group 111 advertise-interval 10 authentication-type simple 7 387a7f2df5969da4 no preempt priority 255 track TenGigabitEthernet 1/2 virtual-address 10.10.10.1 virtual-address 10.10.10.2 virtual-address 10.10.10.3 virtual-address 10.10.10.10 The following example shows verifying the tracking status.
vrrp-ipv6-group 1 track 2 priority-cost 20 track 3 priority-cost 30 virtual-address 2007::1 virtual-address fe80::1 no shutdown Setting VRRP Initialization Delay When configured, VRRP is enabled immediately upon system reload or boot. You can delay VRRP initialization to allow the IGP and EGP protocols to be enabled prior to selecting the VRRP Master. This delay ensures that VRRP initializes with no errors or conflicts. You can configure the delay for up to 15 minutes, after which VRRP enables normally.
Sample Configurations Before you set up VRRP, review the following sample configurations. VRRP for an IPv4 Configuration The following configuration shows how to enable IPv4 VRRP. This example does not contain comprehensive directions and is intended to provide guidance for only a typical VRRP configuration. You can copy and paste from the example to your CLI. To support your own IP addresses, interfaces, names, and so on, be sure that you make the necessary changes.
Examples of Configuring VRRP for IPv4 and IPv6 The following example shows configuring VRRP for IPv4 Router 2. R2(conf)#interface tengigabitethernet 2/31 R2(conf-if-te-2/31)#ip address 10.1.1.1/24 R2(conf-if-te-2/31)#vrrp-group 99 R2(conf-if-te-2/31-vrid-99)#priority 200 R2(conf-if-te-2/31-vrid-99)#virtual 10.1.1.3 R2(conf-if-te-2/31-vrid-99)#no shut R2(conf-if-te-2/31)#show conf ! interface TenGigabitEthernet 2/31 ip address 10.1.1.1/24 ! vrrp-group 99 priority 200 virtual-address 10.1.1.
Figure 140. VRRP for an IPv6 Configuration NOTE: In a VRRP or VRRPv3 group, if two routers come up with the same priority and another router already has MASTER status, the router with master status continues to be MASTER even if one of two routers has a higher IP or IPv6 address. The following example shows configuring VRRP for IPv6 Router 2 and Router 3. Configure a virtual link local (fe80) address for each VRRPv3 group created for an interface.
Although R2 and R3 have the same default, priority (100), R2 is elected master in the VRRPv3 group because the TenGigabitethernet 1/1 interface has a higher IPv6 address than the TenGigabitethernet 1/2 interface on R3.
Virtual MAC address: 00:00:5e:00:02:0a VRRP in a VRF Configuration The following example shows how to enable VRRP operation in a VRF virtualized network for the following scenarios. • Multiple VRFs on physical interfaces running VRRP. • Multiple VRFs on VLAN interfaces running VRRP. To view a VRRP in a VRF configuration, use the show commands. VRRP in a VRF: Non-VLAN Scenario The following example shows how to enable VRRP in a non-VLAN.
Figure 141. VRRP in a VRF: Non-VLAN Example Example of Configuring VRRP in a VRF on Switch-1 (Non-VLAN) Switch-1 S1(conf)#ip vrf default-vrf 0 ! S1(conf)#ip vrf VRF-1 1 ! S1(conf)#ip vrf VRF-2 2 ! S1(conf)#ip vrf VRF-3 3 ! S1(conf)#interface TenGigabitEthernet 1/1 S1(conf-if-te-1/1)#ip vrf forwarding VRF-1 S1(conf-if-te-1/1)#ip address 10.10.1.5/24 S1(conf-if-te-1/1)#vrrp-group 11 % Info: The VRID used by the VRRP group 11 in VRF 1 will be 177.
S1(conf)#interface TenGigabitEthernet 1/3 S1(conf-if-te-1/3)#ip vrf forwarding VRF-3 S1(conf-if-te-1/3)#ip address 20.1.1.5/24 S1(conf-if-te-1/3)#vrrp-group 15 % Info: The VRID used by the VRRP group 15 in VRF 3 will be 243. S1(conf-if-te-1/3-vrid-105)#priority 255 S1(conf-if-te-1/3-vrid-105)#virtual-address 20.1.1.5 S1(conf-if-te-1/3)#no shutdown Dell#show vrrp tengigabitethernet 2/8 -----------------TenGigabitEthernet 2/8, IPv4 VRID: 1, Version: 2, Net: 10.1.1.
VLAN Scenario In another scenario, to connect to the LAN, VRF-1, VRF-2, and VRF-3 use a single physical interface with multiple tagged VLANs (instead of separate physical interfaces). In this case, you configure three VLANs: VLAN-100, VLAN-200, and VLAN-300. Each VLAN is a member of one VRF. A physical interface (tengigabitethernet 1/1 ) attaches to the LAN and is configured as a tagged interface in VLAN-100, VLAN-200, and VLAN-300. The rest of this example is similar to the nonVLAN scenario.
Vlan 400, IPv4 VRID: 1, Version: 2, Net: 10.1.1.1 VRF: 1 vrf1 State: Master, Priority: 100, Master: 10.1.1.1 (local) Hold Down: 0 sec, Preempt: TRUE, AdvInt: 1 sec Adv rcvd: 0, Bad pkts rcvd: 0, Adv sent: 278, Gratuitous ARP sent: 1 Virtual MAC address: 00:00:5e:00:01:01 Virtual IP address: 10.1.1.100 Authentication: (none) Dell#show vrrp vrf vrf2 port-channel 1 -----------------Port-channel 1, IPv4 VRID: 1, Version: 2, Net: 10.1.1.1 VRF: 2 vrf2 State: Master, Priority: 100, Master: 10.1.1.
S2(conf-if-vl-300-vrid-101)#virtual-address 20.1.1.5 S2(conf-if-vl-300)#no shutdown Dell#show vrrp vrf vrf1 vlan 400 -----------------Vlan 400, IPv4 VRID: 1, Version: 2, Net: 10.1.1.1 VRF: 1 vrf1 State: Master, Priority: 100, Master: 10.1.1.1 (local) Hold Down: 0 sec, Preempt: TRUE, AdvInt: 1 sec Adv rcvd: 0, Bad pkts rcvd: 0, Adv sent: 278, Gratuitous ARP sent: 1 Virtual MAC address: 00:00:5e:00:01:01 Virtual IP address: 10.1.1.100 Authentication: (none) Vlan 400, IPv4 VRID: 10, Version: 2, Net: 20.1.1.
Figure 142. VRRP for IPv6 Topology NOTE: In a VRRP or VRRPv3 group, if two routers come up with the same priority and another router already has MASTER status, the router with master status continues to be master even if one of two routers has a higher IP or IPv6 address.
NOTE: You must configure a virtual link local (fe80) address for each VRRPv3 group created for an interface. The VRRPv3 group becomes active as soon as you configure the link local address. Afterwards, you can configure the group’s virtual IPv6 address. R2(conf-if-te-1/1-vrid-10)#virtual-address fe80::10 NOTE: The virtual IPv6 address you configure should be the same as the IPv6 subnet to which the interface belongs.
Accept Mode: FALSE, Master AdvInt: 100 centisec Adv rcvd: 11, Bad pkts rcvd: 0, Adv sent: 0 Virtual MAC address: 00:00:5e:00:02:0a Virtual IP address: 1::10 fe80::10 Dell#show vrrp tengigabitethernet 0/0 TenGigabitEthernet 0/0, IPv6 VRID: 255, Version: 3, Net: fe80::201:e8ff:fe8a:fd76 VRF: 0 default State: Backup, Priority: 90, Master: fe80::201:e8ff:fe8a:e9ed Hold Down: 0 centisec, Preempt: TRUE, AdvInt: 100 centisec Accept Mode: FALSE, Master AdvInt: 100 centisec Adv rcvd: 214, Bad pkts rcvd: 0, Adv sent:
VRF: 2 vrf2 State: Master, Priority: 100, Master: fe80::201:e8ff:fe8a:e9ed (local) Hold Down: 0 centisec, Preempt: TRUE, AdvInt: 100 centisec Accept Mode: FALSE, Master AdvInt: 100 centisec Adv rcvd: 0, Bad pkts rcvd: 0, Adv sent: 443 Virtual MAC address: 00:00:5e:00:02:ff Virtual IP address: 10:1:1::255 fe80::255 Dell#show vrrp vrf vrf2 port-channel 1 Port-channel 1, IPv6 VRID: 255, Version: 3, Net: fe80::201:e8ff:fe8a:fd76 VRF: 2 vrf2 State: Backup, Priority: 90, Master: fe80::201:e8ff:fe8a:e9ed Hold Down
S-Series Debugging and Diagnostics 65 This chapter describes debugging and diagnostics for the device. Offline Diagnostics The offline diagnostics test suite is useful for isolating faults and debugging hardware. The diagnostics tests are grouped into three levels: • Level 0 — Level 0 diagnostics check for the presence of various components and perform essential path verifications. In addition, Level 0 diagnostics verify the identification registers of the components on the board.
NOTE: The system reboots when the offline diagnostics complete. This is an automatic process. The following warning message appears when you implement the offline stackunit command: Warning - Diagnostic execution will cause stack-unit to reboot after completion of diags. Proceed with Offline-Diags [confirm yes/no]:y After the system goes offline, you must reload or run the online stack-unit stack-unit-number command for the normal operation. 2. Confirm the offline status.
6 7 8 9 10 11 Member Member Member Member Member Member not not not not not not present present present present present present -- Power Supplies -Unit Bay Status Type FanSpeed(rpm) --------------------------------------------------------------------------0 0 down UNKNOWN 0 0 1 up AC 14000 -- Fan Status -Unit Bay TrayStatus Fan0 Speed Fan1 Speed ----------------------------------------------------------------------------------0 0 up up 13466 up 13466 0 1 up up 13653 up 13466 Speed in RPM The following e
The following example shows the show file flash:\\ command (standalone member). Dell#show file flash://TestReport-SU-0.txt *******************************S-Series Diagnostics*********************** Board Stack Unit Board Serial Number CPU Version CPLD REVISION CPLD BOARD TYPE Diag image based on build Stack Unit Board temperature Stack Unit Number : : : : : : : : S4810 Dell Inc. HADL112220111 MPC8536E, Version: 1.
Trace Logs In addition to the syslog buffer, Dell Networking OS buffers trace messages which are continuously written by various Dell Networking OS software tasks to report hardware and software events and status information. Each trace message provides the date, time, and name of the Dell Networking OS process. All messages are stored in a ring buffer. You can save the messages to a file either manually or automatically after failover.
• View internal interface status of the stack-unit CPU port which connects to the external management interface. EXEC Privilege mode • show hardware stack-unit {0-11} cpu management statistics View driver-level statistics for the data-plane port on the CPU for the specified stack-unit.
• View the details of the FP Devices and Hi gig ports on the stack-unit. EXEC Privilege mode • show hardware stack-unit {0-11} unit {0-1} details Execute a specified bShell command from the CLI without going into the bShell. EXEC Privilege mode • show hardware stack-unit {0-11} unit {0-1} execute-shell-cmd {command} View the Multicast IPMC replication table from the bShell.
When the system detects a genuine over-temperature condition, it powers off the card. To recognize this condition, look for the following system messages: CHMGR-2-MAJOR_TEMP: Major alarm: chassis temperature high (temperature reaches or exceeds threshold of [value]C) CHMGR-2-TEMP_SHUTDOWN_WARN: WARNING! temperature is [value]C; approaching shutdown threshold of [value]C To view the programmed alarm thresholds levels, including the shutdown value, use the show alarms threshold command.
Troubleshoot an Under-Voltage Condition To troubleshoot an under-voltage condition, check that the correct number of power supplies are installed and their Status light emitting diodes (LEDs) are lit. The following table lists information for SNMP traps and OIDs on S-Series environmental monitoring hardware and hardware components. Table 88. SNMP Traps and OIDs OID String OID Name Description chSysPortXfpRecvPower OID displays the receiving power of the connected optics.
Forwarding processor (FP) ASICs provide Ethernet MAC functions, queueing, and buffering, as well as store feature and forwarding tables for hardware-based lookup and forwarding decisions. 1G and 10G interfaces use different FPs. The following table describes the type and number of ASICs per platform. Table 89. ASICs by Platform Hardware FP CSF S50N, S50V 2 0 S25V, S25P, S25N 1 0 As shown in the following example, you can tune buffers at three locations. 1. CSF — Output queues going from the CSF.
Figure 143. Buffer Tuning Points Deciding to Tune Buffers Dell Networking recommends exercising caution when configuring any non-default buffer settings, as tuning can significantly affect system performance. The default values work for most cases. As a guideline, consider tuning buffers if traffic is bursty (and coming from several interfaces). In this case: • Reduce the dedicated buffer on all queues/interfaces. • Increase the dynamic buffer on all interfaces.
BUFFER PROFILE mode • buffer dedicated Change the maximum number of dynamic buffers an interface can request. BUFFER PROFILE mode • buffer dynamic Change the number of packet-pointers per queue. BUFFER PROFILE mode • buffer packet-pointers Apply the buffer profile to a line card. CONFIGURATION mode • buffer fp-uplink linecard Apply the buffer profile to a CSF to FP link.
The following example shows viewing the default buffer profile. Dell#show buffer-profile detail interface tengigabitethernet 1/1 Interface Te 1/1 Buffer-profile Dynamic buffer 194.88 (Kilobytes) Queue# Dedicated Buffer Buffer Packets (Kilobytes) 0 2.50 256 1 2.50 256 2 2.50 256 3 2.50 256 4 9.38 256 5 9.38 256 6 9.38 256 7 9.38 256 The following example shows viewing the buffer profile allocations.
Using a Pre-Defined Buffer Profile Dell Networking OS provides two pre-defined buffer profiles, one for single-queue (for example, nonquality-of-service [QoS]) applications, and one for four-queue (for example, QoS) applications. You must reload the system for the global buffer profile to take effect, a message similar to the following displays: % Info: For the global pre-defined buffer profile to take effect, please save the config and reload the system..
buffer fp-uplink stack-unit 1 port-set 1 buffer-policy fsqueue-hig ! Interface range tengigabitethernet 1/1 - 18 buffer-policy fsqueue-fp Dell#show run interface tengigabitethernet 1/10 ! interface TenGigabitEthernet 1/10 no ip address Troubleshooting Packet Loss The show hardware stack-unit command is intended primarily to troubleshoot packet loss. To troubleshoot packet loss, use the following commands.
Example of the show hardware stack-unit Command to View Drop Counters Statistics Example of show hardware drops interface interface Dell#show hardware drops interface tengigabitethernet 2/1 Drops in Interface Te 2/1: --- Ingress Drops --Ingress Drops IBP CBP Full Drops PortSTPnotFwd Drops IPv4 L3 Discards Policy Discards Packets dropped by FP (L2+L3) Drops Port bitmap zero Drops Rx VLAN Drops --- Ingress MAC counters--Ingress FCSDrops Ingress MTUExceeds --- MMU Drops --Ingress MMU Drops HOL DROPS(TOTAL) HOL
PortSTPnotFwd Drops IPv4 L3 Discards Policy Discards Packets dropped by FP (L2+L3) Drops Port bitmap zero Drops Rx VLAN Drops --- Ingress MAC counters--Ingress FCSDrops Ingress MTUExceeds --- MMU Drops --Ingress MMU Drops HOL DROPS(TOTAL) HOL DROPS on COS0 HOL DROPS on COS1 HOL DROPS on COS2 HOL DROPS on COS3 HOL DROPS on COS4 HOL DROPS on COS5 HOL DROPS on COS6 HOL DROPS on COS7 HOL DROPS on COS8 HOL DROPS on COS9 HOL DROPS on COS10 HOL DROPS on COS11 HOL DROPS on COS12 HOL DROPS on COS13 HOL DROPS on COS1
--- MMU Drops --Ingress MMU Drops HOL DROPS(TOTAL) HOL DROPS on COS0 HOL DROPS on COS1 HOL DROPS on COS2 HOL DROPS on COS3 HOL DROPS on COS4 HOL DROPS on COS5 HOL DROPS on COS6 HOL DROPS on COS7 HOL DROPS on COS8 HOL DROPS on COS9 HOL DROPS on COS10 HOL DROPS on COS11 HOL DROPS on COS12 HOL DROPS on COS13 HOL DROPS on COS14 HOL DROPS on COS15 HOL DROPS on COS16 HOL DROPS on COS17 TxPurge CellErr Aged Drops --- Egress MAC counters--Egress FCS Drops --- Egress FORWARD PROCESSOR IPv4 L3UC Aged & Drops TTL Thre
0 8 0 9 0 10 0 11 0 12 0 13 0 14 0 15 0 16 0 17 124904297 18 0 19 0 20 0 21 0 22 0 23 0 24 0 25 0 26 0 27 0 28 0 29 0 30 0 31 0 32 0 33 0 34 0 35 0 36 0 37 0 38 0 39 1134 0 8 0 9 0 10 0 11 0 12 0 13 0 14 0 15 0 16 0 17 0 18 0 19 0 20 0 21 0 22 0 23 0 24 0 25 0 26 0 27 0 28 0 29 0 30 0 31 0 32 0 33 0 34 0 35 0 36 0 37 0 38 0 39 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 2144854 0 0 0 0 0 0 0 0 0 0 0
0 40 0 41 0 42 0 43 0 44 0 45 0 46 0 47 0 48 0 49 0 49 0 49 0 49 0 52 0 52 0 52 0 52 0 53 0 53 0 53 0 53 0 54/1 0 54/2 0 54/3 0 54/4 0 Internal 0 Internal 0 0 40 0 41 0 42 0 43 0 44 0 45 0 46 0 47 0 48 0 49 0 50 0 51 0 52 0 61 0 62 0 63 0 64 0 65 0 66 0 67 0 68 0 69 0 70 0 71 0 72 0 53 0 57 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0
statistics command displays input and output statistics on the party bus, which carries inter-process communication traffic between CPUs. The command output in the following example has been augmented, providing detailed RX/ TX packet statistics on a per-queue basis. The objective is to see whether CPU-bound traffic is internal (so-called party bus or IPC traffic) or network control traffic, which the CPU must process.
Display Stack Port Statistics The show hardware stack-unit stack-port command displays input and output statistics for a stack-port interface.
Interface Te 0/0 : Description RX - IPV4 L3 Unicast Frame Counter RX - IPV4 L3 routed multicast Packets RX - IPV6 L3 Unicast Frame Counter RX - IPV6 L3 routed multicast Packets RX - Unicast Packet Counter RX - 64 Byte Frame Counter RX - 64 to 127 Byte Frame Counter RX - 128 to 255 Byte Frame Counter RX - 256 to 511 Byte Frame Counter RX - 512 to 1023 Byte Frame Counter RX - 1024 to 1518 Byte Frame Counter RX - 1519 to 1522 Byte Good VLAN Frame Counter RX - 1519 to 2047 Byte Frame Counter RX - 2048 to 4095 B
------------Interface Fo 0/60 : Description RX - IPV4 L3 Unicast Frame Counter RX - IPV4 L3 routed multicast Packets RX - IPV6 L3 Unicast Frame Counter RX - IPV6 L3 routed multicast Packets RX - Unicast Packet Counter RX - 64 Byte Frame Counter RX - 64 to 127 Byte Frame Counter RX - 128 to 255 Byte Frame Counter RX - 256 to 511 Byte Frame Counter RX - 512 to 1023 Byte Frame Counter RX - 1024 to 1518 Byte Frame Counter RX - 1519 to 1522 Byte Good VLAN Frame Counter RX - 1519 to 2047 Byte Frame Counter RX - 2
RX RX RX RX RX RX RX RX RX RX RX RX RX RX RX RX RX RX RX RX RX RX RX RX RX RX RX RX RX RX TX TX TX TX TX TX TX TX TX TX TX TX TX TX TX TX TX TX TX TX TX TX TX TX - IPV4 L3 Unicast Frame Counter IPV4 L3 routed multicast Packets IPV6 L3 Unicast Frame Counter IPV6 L3 routed multicast Packets Unicast Packet Counter 64 Byte Frame Counter 64 to 127 Byte Frame Counter 128 to 255 Byte Frame Counter 256 to 511 Byte Frame Counter 512 to 1023 Byte Frame Counter 1024 to 1518 Byte Frame Counter 1519 to 1522 Byte Good
--------Example of Displaying Counter Information for a Specific Interface Dell#show hardware counters interfac tengigabitethernet 5/1 unit: 0 port: 2 (interface Te 5/1) Description Value RX - IPV4 L3 Unicast Frame Counter RX - IPV4 L3 Routed Multicast Packets RX - IPV6 L3 Unicast Frame Counter RX - IPV6 L3 Routed Multicast Packets RX - Unicast Packet Counter RX - 64 Byte Frame Counter RX - 65 to 127 Byte Frame Counter RX - 128 to 255 Byte Frame Counter RX - 256 to 511 Byte Frame Counter RX - 512 to 1023 By
• Enable RPM core dumps and specify the Shutdown mode. CONFIGURATION mode logging coredump server To undo this command, use the no logging coredump server command. Mini Core Dumps Dell Networking OS supports mini core dumps on the application and kernel crashes. The mini core dump applies to Master, Standby, and Member units. Application and kernel mini core dumps are always enabled. The mini core dumps contain the stack space and some other minimal information that you can use to debug a crash.
0026a8d0 : 0026a00c : ----------------STACK TRACE END-----------------------------------FREE MEMORY--------------uvmexp.free = 0x2312 Enabling TCP Dumps A TCP dump captures CPU-bound control plane traffic to improve troubleshooting and system manageability. When you enable TCP dump, it captures all the packets on the local CPU, as specified in the CLI. You can save the traffic capture files to flash, FTP, SCP, or TFTP.
Standards Compliance 66 This chapter describes standards compliance for Dell Networking products. NOTE: Unless noted, when a standard cited here is listed as supported by the Dell Networking Operating System (OS), Dell Networking OS also supports predecessor standards. One way to search for predecessor standards is to use the http://tools.ietf.org/ website.
SFF-8431 SFP+ Direct Attach Cable (10GSFP+Cu) MTU 9,252 bytes RFC and I-D Compliance Dell Networking OS supports the following standards. The standards are grouped by related protocol. The columns showing support by platform indicate which version of Dell Networking OS first supports the standard. General Internet Protocols The following table lists the Dell Networking OS support per platform for general internet protocols. Table 90.
General IPv4 Protocols The following table lists the Dell Networking OS support per platform for general IPv4 protocols. Table 91. General IPv4 Protocols RFC# Full Name S-Series 791 Internet Protocol 7.6.1 792 Internet Control Message Protocol 7.6.1 826 An Ethernet Address Resolution Protocol 7.6.1 1027 Using ARP to Implement Transparent Subnet Gateways 7.6.1 1035 DOMAIN NAMES - IMPLEMENTATION AND SPECIFICATION (client) 7.6.
General IPv6 Protocols The following table lists the Dell Networking OS support per platform for general IPv6 protocols. Table 92. General IPv6 Protocols RFC# Full Name S-Series 1886 DNS Extensions to support IP version 6 7.8.1 1981 (Partial) Path MTU Discovery for IP version 6 7.8.1 2460 Internet Protocol, Version 6 (IPv6) Specification 7.8.1 2462 (Partial) IPv6 Stateless Address Autoconfiguration 7.8.1 2464 Transmission of IPv6 Packets over Ethernet Networks 7.8.
RFC# Full Name S-Series/Z-Series 2545 Use of BGP-4 Multiprotocol Extensions for IPv6 Inter-Domain Routing 2796 BGP Route Reflection: An Alternative to Full Mesh Internal BGP (IBGP) 2842 Capabilities Advertisement with BGP-4 7.8.1 2858 Multiprotocol Extensions for BGP-4 7.8.1 2918 Route Refresh Capability for BGP-4 7.8.1 3065 Autonomous System Confederations for BGP 7.8.1 4360 BGP Extended Communities Attribute 7.8.1 4893 BGP Support for Four-octet AS Number Space 7.8.
Intermediate System to Intermediate System (IS-IS) The following table lists the Dell Networking OS support per platform for IS-IS protocol. Table 95.
Multicast The following table lists the Dell Networking OS support per platform for Multicast protocol. Table 97. Multicast RFC# Full Name S-Series 1112 Host Extensions for IP Multicasting 7.8.1 2236 Internet Group Management Protocol, 7.8.1 Version 2 3376 Internet Group Management Protocol, 7.8.
RFC# Full Name S4810 S4820T Z-Series [except for the dot1dTpLearnedEntryDisc ards object] 1724 RIP Version 2 MIB Extension 1850 OSPF Version 2 7.6.1 Management Information Base 1901 Introduction to Community-based SNMPv2 7.6.1 2011 SNMPv2 Management Information Base for the Internet Protocol using SMIv2 7.6.1 2012 SNMPv2 Management Information Base for the Transmission Control Protocol using SMIv2 7.6.1 2013 SNMPv2 Management Information Base for the User Datagram Protocol using SMIv2 7.
RFC# Full Name S4810 2572 Message Processing and Dispatching for the Simple Network Management Protocol (SNMP) 7.6.1 2574 User-based Security 7.6.1 Model (USM) for version 3 of the Simple Network Management Protocol (SNMPv3) 2575 View-based Access 7.6.1 Control Model (VACM) for the Simple Network Management Protocol (SNMP) 2576 Coexistence Between Version 1, Version 2, and Version 3 of the Internetstandard Network Management Framework 2578 Structure of Management 7.6.
RFC# Full Name S4810 3635 Definitions of Managed Objects for the Ethernetlike Interface Types 7.6.1 2674 Definitions of Managed Objects for Bridges with Traffic Classes, Multicast Filtering and Virtual LAN Extensions 7.6.1 2787 Definitions of Managed Objects for the Virtual Router Redundancy Protocol 7.6.1 2819 Remote Network Monitoring Management Information Base: Ethernet Statistics Table, Ethernet History Control Table, Ethernet History Table, Alarm Table, Event Table, Log Table 7.6.
RFC# Full Name S4810 S4820T Z-Series Capacity Alarm Table (64 bits) 3580 IEEE 802.1X Remote Authentication Dial In User Service (RADIUS) Usage Guidelines 7.6.1 3815 Definitions of Managed Objects for the Multiprotocol Label Switching (MPLS), Label Distribution Protocol (LDP) 4001 Textual Conventions for Internet Network Addresses 8.3.12 4292 IP Forwarding Table MIB 9.5.(0.0) 9.5.(0.0) 9.5.(0.0) 4750 OSPF Version 2 9.5.(0.0) Management Information Base 9.5.(0.0) 9.5.(0.
RFC# Full Name S4810 S4820T Z-Series 9.2(0.0) 9.2(0.0) 9.2(0.0) 9.2.(0.0) 9.2.(0.0) isisISAdjAreaAddrTable isisISAdjIPAddrTable isisISAdjProtSuppTable draft-ietf-netmodinterfaces-cfg-03 Defines a YANG data model for the configuration of network interfaces. Used in the Programmatic Interface RESTAPI feature. IEEE 802.1AB Management Information 7.7.1 Base module for LLDP configuration, statistics, local system data and remote systems data components. IEEE 802.
RFC# Full Name S4810 FORCE10-FIB-MIB Force10 CIDR Multipath Routes MIB (The IP Forwarding Table provides information that you can use to determine the egress port of an IP packet and troubleshoot an IP reachability issue.
RFC# Full Name S4810 FORCE10-TRAPALARM-MIB Force10 Trap Alarm MIB 7.6.1 S4820T Z-Series MIB Location You can find Force10 MIBs under the Force10 MIBs subhead on the Documentation page of iSupport: https://www.force10networks.com/CSPortal20/KnowledgeBase/Documentation.aspx You also can obtain a list of selected MIBs and their OIDs at the following URL: https://www.force10networks.com/CSPortal20/Main/Login.aspx Some pages of iSupport require a login. To request an iSupport account, go to: https://www.
